From 62225b036c1b7ad5ed389e36783ae4906e14ba94 Mon Sep 17 00:00:00 2001 From: Regia König Date: Thu, 1 Sep 2022 11:45:13 +0200 Subject: Remove memtest_old --- GNU_efi_HelloWorld/Makefile | 4 +- GNU_efi_HelloWorld/hello.c | 9 +- GNU_efi_HelloWorld/hello.debug | Bin 123240 -> 123240 bytes GNU_efi_HelloWorld/hello.efi | Bin 46888 -> 46888 bytes Makefile_for_memtest_gdb | 151 -- memtest86+_old/FAQ | 310 --- memtest86+_old/Makefile | 88 - memtest86+_old/README | 925 -------- memtest86+_old/README.background | 156 -- memtest86+_old/README.build-process | 39 - memtest86+_old/bootsect.S | 383 ---- memtest86+_old/build-number.txt | 1 - memtest86+_old/build.number | 1 - memtest86+_old/build_number.h | 9 - memtest86+_old/buildnumber.mak | 10 - memtest86+_old/changelog | 25 - memtest86+_old/config.c | 531 ----- memtest86+_old/config.h | 52 - memtest86+_old/controller.c | 4155 ----------------------------------- memtest86+_old/controller.h | 23 - memtest86+_old/cpuid.c | 87 - memtest86+_old/cpuid.h | 205 -- memtest86+_old/defs.h | 26 - memtest86+_old/dmi.c | 438 ---- memtest86+_old/dmi.h | 7 - memtest86+_old/elf.h | 590 ----- memtest86+_old/error.c | 629 ------ memtest86+_old/extra.c | 981 --------- memtest86+_old/extra.h | 27 - memtest86+_old/head.S | 847 ------- memtest86+_old/init.c | 1296 ----------- memtest86+_old/io.h | 133 -- memtest86+_old/jedec_id.h | 985 --------- memtest86+_old/lib.c | 1199 ---------- memtest86+_old/linuxbios.c | 165 -- memtest86+_old/linuxbios_tables.h | 89 - memtest86+_old/main.c | 1299 ----------- memtest86+_old/major_version | 1 - memtest86+_old/make_buildnum.sh | 20 - memtest86+_old/makedos.sh | 10 - memtest86+_old/makeiso.sh | 45 - memtest86+_old/memsize.c | 346 --- memtest86+_old/memtest.bin.lds | 15 - memtest86+_old/memtest.lds | 11 - memtest86+_old/memtest_shared.lds | 53 - memtest86+_old/msr.h | 145 -- memtest86+_old/mt86+_loader | Bin 784 -> 0 bytes memtest86+_old/mt86+_loader.asm | 231 -- memtest86+_old/patn.c | 144 -- memtest86+_old/pci.c | 177 -- memtest86+_old/pci.h | 96 - memtest86+_old/precomp.bin | Bin 153868 -> 0 bytes memtest86+_old/random.c | 38 - memtest86+_old/reloc.c | 268 --- memtest86+_old/screen_buffer.c | 127 -- memtest86+_old/screen_buffer.h | 20 - memtest86+_old/self_test.c | 209 -- memtest86+_old/serial.h | 162 -- memtest86+_old/setup.S | 154 -- memtest86+_old/smp.c | 692 ------ memtest86+_old/smp.h | 366 --- memtest86+_old/spd.c | 541 ----- memtest86+_old/spd.h | 17 - memtest86+_old/stddef.h | 8 - memtest86+_old/stdin.h | 52 - memtest86+_old/stdint.h | 60 - memtest86+_old/test.c | 1549 ------------- memtest86+_old/test.h | 346 --- memtest86+_old/version.number | 1 - memtest86+_old/vmem.c | 159 -- memtest_efi_modified.lds | 75 - test_code/OVMF_VARS.fd | Bin 540672 -> 540672 bytes test_code/memtest_gdbscript | 4 +- test_code/test.sh | 7 +- 74 files changed, 15 insertions(+), 22009 deletions(-) delete mode 100644 Makefile_for_memtest_gdb delete mode 100644 memtest86+_old/FAQ delete mode 100644 memtest86+_old/Makefile delete mode 100644 memtest86+_old/README delete mode 100644 memtest86+_old/README.background delete mode 100644 memtest86+_old/README.build-process delete mode 100644 memtest86+_old/bootsect.S delete mode 100644 memtest86+_old/build-number.txt delete mode 100644 memtest86+_old/build.number delete mode 100644 memtest86+_old/build_number.h delete mode 100644 memtest86+_old/buildnumber.mak delete mode 100644 memtest86+_old/changelog delete mode 100644 memtest86+_old/config.c delete mode 100644 memtest86+_old/config.h delete mode 100644 memtest86+_old/controller.c delete mode 100644 memtest86+_old/controller.h delete mode 100644 memtest86+_old/cpuid.c delete mode 100644 memtest86+_old/cpuid.h delete mode 100644 memtest86+_old/defs.h delete mode 100644 memtest86+_old/dmi.c delete mode 100644 memtest86+_old/dmi.h delete mode 100644 memtest86+_old/elf.h delete mode 100644 memtest86+_old/error.c delete mode 100644 memtest86+_old/extra.c delete mode 100644 memtest86+_old/extra.h delete mode 100644 memtest86+_old/head.S delete mode 100644 memtest86+_old/init.c delete mode 100644 memtest86+_old/io.h delete mode 100644 memtest86+_old/jedec_id.h delete mode 100644 memtest86+_old/lib.c delete mode 100644 memtest86+_old/linuxbios.c delete mode 100644 memtest86+_old/linuxbios_tables.h delete mode 100644 memtest86+_old/main.c delete mode 100644 memtest86+_old/major_version delete mode 100755 memtest86+_old/make_buildnum.sh delete mode 100755 memtest86+_old/makedos.sh delete mode 100755 memtest86+_old/makeiso.sh delete mode 100644 memtest86+_old/memsize.c delete mode 100644 memtest86+_old/memtest.bin.lds delete mode 100644 memtest86+_old/memtest.lds delete mode 100644 memtest86+_old/memtest_shared.lds delete mode 100644 memtest86+_old/msr.h delete mode 100644 memtest86+_old/mt86+_loader delete mode 100644 memtest86+_old/mt86+_loader.asm delete mode 100644 memtest86+_old/patn.c delete mode 100644 memtest86+_old/pci.c delete mode 100644 memtest86+_old/pci.h delete mode 100755 memtest86+_old/precomp.bin delete mode 100644 memtest86+_old/random.c delete mode 100644 memtest86+_old/reloc.c delete mode 100644 memtest86+_old/screen_buffer.c delete mode 100644 memtest86+_old/screen_buffer.h delete mode 100644 memtest86+_old/self_test.c delete mode 100644 memtest86+_old/serial.h delete mode 100644 memtest86+_old/setup.S delete mode 100644 memtest86+_old/smp.c delete mode 100644 memtest86+_old/smp.h delete mode 100644 memtest86+_old/spd.c delete mode 100644 memtest86+_old/spd.h delete mode 100644 memtest86+_old/stddef.h delete mode 100644 memtest86+_old/stdin.h delete mode 100644 memtest86+_old/stdint.h delete mode 100644 memtest86+_old/test.c delete mode 100644 memtest86+_old/test.h delete mode 100644 memtest86+_old/version.number delete mode 100644 memtest86+_old/vmem.c delete mode 100644 memtest_efi_modified.lds diff --git a/GNU_efi_HelloWorld/Makefile b/GNU_efi_HelloWorld/Makefile index 80f1398..63deda2 100644 --- a/GNU_efi_HelloWorld/Makefile +++ b/GNU_efi_HelloWorld/Makefile @@ -12,7 +12,9 @@ EFI_LDS = $(EFILIB)/elf_$(ARCH)_efi.lds CFLAGS = $(EFFINCS) -fno-stack-protector -fpic \ -fshort-wchar -mno-red-zone -Wall -CFLAGS += -ggdb3 -O0 -DDEBUG -DEFI_DEBUG=1 +CFLAGS += -ggdb3 -O0 -DEFI_DEBUG=1 +# -DDEBUG + ifeq ($(ARCH),x86_64) CFLAGS += -DEFI_FUNCTION_WRAPPER diff --git a/GNU_efi_HelloWorld/hello.c b/GNU_efi_HelloWorld/hello.c index 06b2b0b..f135c21 100644 --- a/GNU_efi_HelloWorld/hello.c +++ b/GNU_efi_HelloWorld/hello.c @@ -22,13 +22,16 @@ efi_main (EFI_HANDLE ImageHandle, EFI_SYSTEM_TABLE *SystemTable) { } Print(L"Image base: 0x%lx\n", loaded_image->ImageBase); + Print(L"UefiMain: 0x%1x\n", (unsigned long)efi_main); - DEBUG((D_ERROR, "AllocatePool: out of pool %x\n", status)); + DEBUG((D_ERROR, (CHAR8*)"DEBUG_TEST DEBUG_TEST\r\n")); - volatile int wait = 1; + DEBUG((D_ERROR, (CHAR8*)"My Entry Point: 0x%08x\r\n",(CHAR16*)efi_main)); + +/* volatile int wait = 1; while(wait) { __asm__ __volatile__("pause"); } - +*/ return EFI_SUCCESS; } diff --git a/GNU_efi_HelloWorld/hello.debug b/GNU_efi_HelloWorld/hello.debug index f7fd077..eb4117a 100755 Binary files a/GNU_efi_HelloWorld/hello.debug and b/GNU_efi_HelloWorld/hello.debug differ diff --git a/GNU_efi_HelloWorld/hello.efi b/GNU_efi_HelloWorld/hello.efi index 59e1a03..90ef0e9 100755 Binary files a/GNU_efi_HelloWorld/hello.efi and b/GNU_efi_HelloWorld/hello.efi differ diff --git a/Makefile_for_memtest_gdb b/Makefile_for_memtest_gdb deleted file mode 100644 index aa1e692..0000000 --- a/Makefile_for_memtest_gdb +++ /dev/null @@ -1,151 +0,0 @@ -AS = as -64 - -# NEW PART -AS += -g - -CC = gcc - -GIT = git - -ifeq ($(GIT),none) - GIT_AVAILABLE = false -else - GIT_AVAILABLE = true -endif - -CFLAGS = -std=c11 -Wall -Wextra -Wshadow -m64 -march=x86-64 -mno-mmx -mno-sse -mno-sse2 \ - -fno-builtin -ffreestanding -fomit-frame-pointer -fno-stack-protector - -#-fpic - -## NEW PART -CFLAGS += -ggdb3 -O0 -DEFI_DEBUG=1 -CFLAGS += -DDEBUG - -INC_DIRS = -I../boot -I../system -I../lib -I../tests -I../app -Iapp - -SYS_OBJS = system/acpi.o \ - system/cpuid.o \ - system/cpuinfo.o \ - system/cpulocal.o \ - system/ehci.o \ - system/font.o \ - system/hwctrl.o \ - system/heap.o \ - system/hwquirks.o \ - system/keyboard.o \ - system/ohci.o \ - system/pci.o \ - system/pmem.o \ - system/reloc.o \ - system/screen.o \ - system/serial.o \ - system/smbios.o \ - system/smbus.o \ - system/smp.o \ - system/temperature.o \ - system/timers.o \ - system/uhci.o \ - system/usbhcd.o \ - system/vmem.o \ - system/xhci.o - -LIB_OBJS = lib/barrier.o \ - lib/print.o \ - lib/read.o \ - lib/string.o \ - lib/unistd.o - -TST_OBJS = tests/addr_walk1.o \ - tests/bit_fade.o \ - tests/block_move.o \ - tests/modulo_n.o \ - tests/mov_inv_fixed.o \ - tests/mov_inv_random.o \ - tests/mov_inv_walk1.o \ - tests/own_addr.o \ - tests/test_helper.o \ - tests/tests.o - -APP_OBJS = app/badram.o \ - app/config.o \ - app/display.o \ - app/error.o \ - app/interrupt.o \ - app/main.o - -OBJS = boot/startup.o boot/efisetup.o $(SYS_OBJS) $(LIB_OBJS) $(TST_OBJS) $(APP_OBJS) - -all: memtest.efi - --include boot/efisetup.d --include $(subst .o,.d,$(SYS_OBJS)) --include $(subst .o,.d,$(LIB_OBJS)) --include $(subst .o,.d,$(TST_OBJS)) --include $(subst .o,.d,$(APP_OBJS)) - -boot/%.o: boot/%.s - $(AS) $< -o $@ - -boot/startup.s: ../boot/startup64.S ../boot/boot.h - @mkdir -p boot - $(CC) -E -traditional -I../boot -o $@ $< - -boot/%.s: ../boot/%.S ../boot/boot.h - @mkdir -p boot - $(CC) -E -traditional -I../boot -o $@ $< - -boot/efisetup.o: ../boot/efisetup.c - @mkdir -p boot - $(CC) -c $(CFLAGS) -Os $(INC_DIRS) -o $@ $< -MMD -MP -MT $@ -MF $(@:.o=.d) - -system/reloc.o: ../system/reloc64.c - @mkdir -p system - $(CC) -c $(CFLAGS) -fno-strict-aliasing -Os $(INC_DIRS) -o $@ $< -MMD -MP -MT $@ -MF $(@:.o=.d) - -system/%.o: ../system/%.c - @mkdir -p system - $(CC) -c $(CFLAGS) -Os $(INC_DIRS) -o $@ $< -MMD -MP -MT $@ -MF $(@:.o=.d) - -lib/%.o: ../lib/%.c - @mkdir -p lib - $(CC) -c $(CFLAGS) -Os $(INC_DIRS) -o $@ $< -MMD -MP -MT $@ -MF $(@:.o=.d) - -tests/%.o: ../tests/%.c - @mkdir -p tests - $(CC) -c $(CFLAGS) -O3 $(INC_DIRS) -o $@ $< -MMD -MP -MT $@ -MF $(@:.o=.d) - -app/%.o: ../app/%.c app/githash.h - @mkdir -p app - $(CC) -c $(CFLAGS) -Os $(INC_DIRS) -o $@ $< -MMD -MP -MT $@ -MF $(@:.o=.d) - -app/githash.h: FORCE - @mkdir -p app - @( \ - if $(GIT_AVAILABLE) && test -d ../.git ; then \ - hash=`git rev-parse HEAD | cut -c1-7`; \ - else \ - hash="unknown"; \ - fi; \ - define=`echo "#define GIT_HASH \"$$hash\""`; \ - echo $$define | diff - $@ > /dev/null 2>&1 || echo $$define > $@; \ - ) - -FORCE: - -# Link it statically once so I know I don't have undefined symbols and -# then link it dynamically so I have full relocation information. - -memtest_shared: $(OBJS) ldscripts/memtest_shared.lds Makefile - $(LD) --warn-constructors --warn-common -static -T ldscripts/memtest_shared.lds -o $@ $(OBJS) && \ - $(LD) -shared -Bsymbolic -T ldscripts/memtest_shared.lds -o $@ $(OBJS) - -memtest_shared.bin: memtest_shared - objcopy -O binary $< memtest_shared.bin - -memtest.efi: memtest_shared.bin boot/header.o boot/setup.o ldscripts/memtest_efi.lds - $(eval SIZES=$(shell size -B -d memtest_shared | grep memtest_shared)) - $(LD) --defsym=_bss_size=$(word 3,$(SIZES)) -T ldscripts/memtest_efi.lds boot/header.o boot/setup.o -b binary memtest_shared.bin -o memtest.efi - -clean: - rm -rf boot system lib tests app *.img *.iso memtest* iso grub-* \ No newline at end of file diff --git a/memtest86+_old/FAQ b/memtest86+_old/FAQ deleted file mode 100644 index 3c2a01c..0000000 --- a/memtest86+_old/FAQ +++ /dev/null @@ -1,310 +0,0 @@ -- What is memtest86+, what do I use it for? - - Memtest86+ is a utility designed to test whether your memory is in working - order. It repeatedly writes an enormous amount of different patterns to all - memory locations and reads them back again and verifies whether the result - of the read is the same as what was written to memory. - - There can be a multitude of reasons for running memtest, but foremost of all - is of course to test whether your memory modules might be bad. Whenever you - suspect your modules to be bad because of system crashes, lockups or reboots - it would be nice to know whether the modules are in working order. - Memtest86+ is a utility which tries to answer that question for you. - - Another common use exists in the overclocking scene. When overclocking a - system you are essentially pushing your system to the limits and at some - point it will simply give way and break. Unfortunately there isn't a clear - cut way of deciding whether a system is still working correctly. Because of - the complexity of a computer a system which is pushed to the limits doesn't - just break completely when it starts to fail, instead little errors start - showing up in many different places in the system growing more frequent and - widespread the more the system is pushed. Each one of these little errors - can lead to a crash of your system but can also go unnoticed for days or - weeks in a running system. The art so to speak of overclocking is thus to - push the system as far as it can go without introducing any such errors. As - memory is usually one of the first places these such errors start coming up - a memory test is very useful. - -- How do I get it to run? - - There are several ways to use memtest, which are described below: - - + Run from floppydisk - - Memtest86+ is directly executable by any modern x86 compatible machine, by - writing the bootable binary to a floppy disk one can boot from the disk to - run memtest. - - Simply download the appropriate package, the Pre-Compiled Bootable Binary - (.gz) package for Linux users and the Pre-Compiled package for Floppy (DOS - - Win) for Windows users. - - For Windows, unzip the package into a directory like C:\memtest, insert a - blank floppy into your a: disk drive and run the install.bat file. As the - install prompts you, to use memtest directly, leave the disk in the drive - and reboot your machine. - - For Linux, unpack the package into your home directory, insert a blank - floppy into your floppy drive and execute 'dd if=~/memtest+-1.xx.bin.gz - of=/dev/fd0 conv=osync' replacing 1.xx with the correct version number of - the memtest86+ you downloaded. To run memtest immediately reboot your - machine. - - Your machine should now boot from the disk, display the word Loading - folowed by a series of periods and then show a screen much like the - screenshots on the memtest86+ web page. The test is automatically started. - - If your machine simply boots back into Windows/Linux you will most likely - have to configure your BIOS to attempt to boot from floppy disk on - startup, refer to your computer's/mainboard's manual how to do this. - - When you are done testing simply remove the floppy and reset your - computer, if ever you want to execure the test again simply reinsert the - disk and reboot/start your computer. - - + Run from CD - - Memtest86+ is directly executable by any modern x86 compatible machine, by - writing the iso to a CD one can boot from the CD to run memtest. - - Simply download the appropriate package, the Download - Pre-Compiled - Bootable ISO (.gz) for Linux users and the Pre-Compiled Bootable ISO - (.zip) for Windows users. - - For Windows, unzip the package into a directory like C:\memtest. You will - now see a file called memtest86+-1.xx.iso in this directory. You will need - to burn this file to a CD with a CD recording program. Do note however - that you should not make a regular data CD on which you for instance write - your text documents and holiday photographs. Instead the iso file is a so - called image of a CD, it is a direct copy of a CD. Your CD recording - program will most likely have a feature called burn image or something to - that effect which you should use to burn the CD. - - For linux, unzip the package into your home directory. and execute - 'cdrecord dev= ~/memtest86+-1.xx.iso' where you replace with the scsi address of your CD burner and replace 1.xx with the - correct version number of the memtest86+ your downloaded. - - When the burning completed your drive will most likely have ejected the CD - and you should have a bootable memtest86+ CD. To run the test directly - reinsert the CD and reboot your machine. - - Your machine should now boot from the CD, display the word Loading folowed - by a series of periods and then show a screen much like the screenshots on - the memtest86+ web page. The test is automatically started. - - If your machine simply boots back into Windows/Linux you will most likely - have to configure your BIOS to attempt to boot from CD-ROM drive on - startup, refer to your computer's/mainboard's manual how to do this. - - When you are done testing simply remove the CD and reset your computer, if - ever you want to execure the test again simply reinsert the CD and - reboot/start your computer. - - + Run from USB Flash drive - - FIXME - - + Run from boot manager - - FIXME - -- How long does memtest86+ run? How do I stop it? - - Memtest86+ runs indefinately unless you stop it. It does however repeat the - same tests over and over again. Memtest86+ contains a number of different - tests which each take different approaches in trying to expose any errors in - your memory. In the top right of your screen you can see the progress of - each test in the lower of the two progress bars. The topmost progress bar - shows the progress of a pass, each pass consists of all the tests in the - memtest suite. - - Thus all tests are executed in one pass, so does that mean that no errors - will show after the first pass if that pass didn't reveal any errors? Well - no, there are several reasons why errors might only show up after a number - of passes. Firstly as of this writing, the latest version of memtest also - includes a test which uses random test patterns, each pass these patterns - will of course be different. Secondly some types of errors simply don't show - up until the system has been running for a while or are very critical on a - certain timing condition, or other such conditions. - - To conclude, one successful pass of memtest will give you a pretty good idea - that your memory is ok, only in rare cases will there be errors showing - after the first pass. To be sure though simply have the test run overnight - or even for a couple of days depending on the level of importance of the - system. - -- How many errors are acceptable? - - No errors are acceptable. Even if there is just one error, something is - amiss which can cause your system to crash. Of course what the cause of the - errors is you will still have to determine. - -- What do I do when I get errors? - - Firstly, don't start drawing any conclusions. You only know that memtest86+ - is giving your errors, not what the cause is. Unfortunately it is not a - straightforward exercise to decisively test the memory in an actual system. - This is because a computer is not just built up of some memory, but also - includes many other elements such as a memory controller, cache, a cache - controller, algorithmic and logic units, etc, all of which contribute to the - machine. If there are faults in any of these other parts of the computer you - will likely also see errors showing up in memtest. - - So what to do? First verify that the BIOS settings of your machine are - correctly configured. Look up the memory timing settings applicable to the - brand and type of memory modules you have and check they match your BIOS - settings, correct them if they don't and run memtest again - - Ok, you have all the settings correctly set and you're still getting errors. - Well of course a very likely cause are the memory modules and the logical - course of action is to look into them further. - - If you are well stocked, have a few other machines at your disposal, or just - want to spend the cash for some new modules the best way to test if the - cause are your memory modules is just to replace them and test again. If you - are less fortunate though there is still something you can do. - - If you have more then one module in your system, test them one by one, if - one is consistently giving errors and another is consistently showing no - errors it's a pretty good bet that the module giving the errors is simply - defective. To exclude the possibility that a defective slot is throwing your - results, use the same slot to test each different module. - - If each module by itself shows no errors, but when you place two or more - modules into the machine at the same time you do get errors, you are most - likely stuck with a compatibility issue and unfortunately there isn't a - whole lot you can do about it. Be sure to check your computer/motherboard - manual to see if the setup you are trying is allowed, some boards require - special restrictions in the sizes of modules, the order of modules, the - placement of double sided and single sides modules and more of such things. - - If you have only one module in your system, or all modules are giving - errors, there are only very few options left. The only thing you can do - really is to try the module(s) in another slot. Finally simply try out - different orders of the memory modules, although your manual might not - mention anything on the matter sometimes there simply exist timing or other - issues which can be resolved by changing the order of your modules. And of - course test each slot by putting a single module into that slot and running - memtest on it. - - In the end if you still have not been able to localize the problem you will - have to find a replacement module to establish whether the problem lies in - your modules. See if you can borrow a module from someone else. - - When you have replaced the memory by new memory and the errors still - persist, first check if you can rule out any compatibility issues or timing - issues. If you are sure the memory should work in the system the cause of - the errors must obviously lie someplace else in the system. - - The only way to find out where, is by trial and error really. Simply start - replacing and/or removing parts of your computer one by one, running memtest - each time you changed anything, until the errors are resolved. - -- I'm getting errors in test #x, what doest that mean? - - Interpreting memtest results is as scientific an endeavour as testing - whether a person is a witch by the methods used in Monty Python's Holy - Grail. In short, don't even start, it's not going to get you anywhere. Just - interpret any error as you should any other and use the methods descibed in - the previous question to determine the cause. - -- I'm getting errors in test #5 and/or #8 and have read a lot about it. - - Yes there are just about enough discussions on the topic to fill a book, but - it all boils down to the answer given above. The only thing that can be said - is that many a times, when memory latencies are incorrectly set in the BIOS - you will experience errors in test #5 and #8. (Though #8 does not exist - anymore as of version 1.40 and might be reinstated as a different test in a - later version.) This does however NOT mean that errors in these tests are - always the cause of incorrect settings, your memory might just as well be - defective. - -- I'm getting errors in memtest on one machine, but not when I put the same - memory in another, what does that mean? - - It can mean one of two things: - - The machine that is giving the errors is defective. Errors don't just - orginate from the memory module itself, but can also be caused by - defects in the cpu, chipset, motherboard, PSU and even by timing issues - introduced by any other component in the machine. - - The machine giving the errors is imposing stricter timing than the other - which the memory module simply can't cope with. If the module should - work with the machine according to its specifications then it most - likely is defective. - -- Which memory is tested? - - As much as possible of the system memory is tested. Unfortunately memtest86+ - can usually not test all of the memory. The reason for this is that todays - processors have become so complex that they require a small amount of memory - to keep accounting data of the processor state. If memtest were to write - over these areas the state of the processor becomes invalid and it's - behaviour unpredictable. Alas it is also impossible to relocate these areas - in the memory. - - This means that a small area of your memory can not be tested by memtest. If - this part of the memory is defective you will know soon enough though as the - processor, or parts of the processor simply won't work correctly if this - part of your memory is defective. Do realise though that in very rare cases - memtest will show no errors even though the module is defective, not because - memtest can't detect the error, but because memtest can't test the area the - error is located in. - -- When I select BIOS-ALL I get many errors / my machine crashes. - - This is normal. With todays computers this option should never be selected. - See the previous question about the reason for the errors. - -- I want to use memtest on a multiboot CD, how do I do this? - - This is of course very dependent on which boot loader you use for your CD. - Below is a description of how to set up a multiboot CD including memtest+ - with isolinux, if you have experience with any other bootloader(s) please - consider writing a small description of using memtest with that bootloader - for the FAQ. - - -isolinux - - For general instructions on how to make a bootable CD with isolinux see - the syslinux website and the manual. What you need to do to get memtest - working is as follows. - - Download the Pre-Compiled Bootable Binary, the .gz if you are working - under linux, the .zip if you are working under windows. Unpack the file - from the package and rename it to an 8.3 filename with an extension other - than .bin, renaming to memtest. (without an extension) is a good choice. - - Put the file somewhere in your CD directory structure, for example in - images/memtest and edit your config file to include the following: - - label memtest - kernel /images/memtest - - If you want to boot memtest automatically insert or change a line at the - top to: - - default memtest - - If you want to display a prompt from which you can start memtest add or - change the lines at the top to: (Change the timeout to suit your needs) - - prompt 1 - timeout 200 - -- If memtest86+ shows no errors does that mean my memory is not defective? - - Of course no answers are definitive, no matter how good memtest86+ will - eventually become there is always the possibility that a particular type of - error will go unnoticed. As long as you are having no problems with the - system it will be pretty safe to say that the modules are good. If you are - having problems with the system however you will just have to check by trial - and error, ie swapping the modules for new ones and/or testing with modules - of a different brand/type. - -- When I run install.bat it doesn't write anything to floppy. - - You most likely have unpacked the memtest+-2.xx.floppy.zip file into a - folder with a long pathname and/or containing + and - signs. It seems - rawrite doesn't like that. Just move the files you unpacked to a directory - like c:\memtest and execure it from there. diff --git a/memtest86+_old/Makefile b/memtest86+_old/Makefile deleted file mode 100644 index 9295258..0000000 --- a/memtest86+_old/Makefile +++ /dev/null @@ -1,88 +0,0 @@ -# Makefile for MemTest86+ -# -# Author: Chris Brady -# Created: January 1, 1996 - - -# -# Path for the floppy disk device -# -FDISK=/dev/fd0 - -AS=as -32 -CC=gcc - -CFLAGS= -Wall -Werror -march=i486 -m32 -O1 -fomit-frame-pointer -fno-builtin \ - -ffreestanding -fPIC $(SMP_FL) -fno-stack-protector - -SELF_TEST_CFLAGS = -Wall -Werror -march=i486 -m32 -O1 -g - -OBJS= head.o reloc.o main.o test.o init.o lib.o patn.o screen_buffer.o \ - config.o cpuid.o linuxbios.o pci.o spd.o error.o dmi.o controller.o \ - smp.o vmem.o memsize.o random.o - -SELF_TEST_OBJS = test.o self_test.o cpuid.o random.o - -all: clean memtest.bin memtest - -run_self_test : self_test - ./self_test && touch run_self_test - -# Link it statically once so I know I don't have undefined -# symbols and then link it dynamically so I have full -# relocation information -memtest_shared: $(OBJS) memtest_shared.lds Makefile - $(LD) --warn-constructors --warn-common -static -T memtest_shared.lds \ - -o $@ $(OBJS) && \ - $(LD) -shared -Bsymbolic -T memtest_shared.lds -o $@ $(OBJS) - -memtest_shared.bin: memtest_shared - objcopy -O binary $< memtest_shared.bin - -memtest: memtest_shared.bin memtest.lds - $(LD) -s -T memtest.lds -b binary memtest_shared.bin -o $@ - -self_test : $(SELF_TEST_OBJS) - $(CC) $(SELF_TEST_CFLAGS) -o $@ $(SELF_TEST_OBJS) - -head.s: head.S config.h defs.h test.h - $(CC) -E -traditional $< -o $@ - -bootsect.s: bootsect.S config.h defs.h - $(CC) -E -traditional $< -o $@ - -setup.s: setup.S config.h defs.h - $(CC) -E -traditional $< -o $@ - -memtest.bin: memtest_shared.bin bootsect.o setup.o memtest.bin.lds - $(LD) -T memtest.bin.lds bootsect.o setup.o -b binary \ - memtest_shared.bin -o memtest.bin - -self_test.o : self_test.c - $(CC) -c $(SELF_TEST_CFLAGS) self_test.c - -memsize.o: memsize.c - $(CC) -Wall -Werror -march=i486 -m32 -O0 -fomit-frame-pointer -fno-builtin -ffreestanding -fPIC $(SMP_FL) -fno-stack-protector -c -o memsize.o memsize.c - -random.o: random.c - $(CC) -c -Wall -march=i486 -m32 -O3 -fomit-frame-pointer -fno-builtin -ffreestanding random.c - -clean: - rm -f *.o *.s *.iso memtest.bin memtest memtest_shared \ - memtest_shared.bin memtest.iso run_self_test self_test - -iso: - make all - ./makeiso.sh - -install: all - dd $(FDISK) bs=8192 - -install-precomp: - dd $(FDISK) bs=8192 - -dos: all - cat mt86+_loader memtest.bin > memtest.exe - -debug2pxe: all - cp memtest.bin /srv/tftp/memtest/memtest diff --git a/memtest86+_old/README b/memtest86+_old/README deleted file mode 100644 index f9df887..0000000 --- a/memtest86+_old/README +++ /dev/null @@ -1,925 +0,0 @@ - ==================== - = MemTest-86 v4.0 = - = 28 Mar, 2011 = - = Chris Brady = - ==================== -Table of Contents -================= - 1) Introduction - 2) Licensing - 3) Installation - 4) Serial Port Console - 5) Online Commands - 6) Memory Sizing - 7) Error Display - 8) Trouble-shooting Memory Errors - 9) Execution Time - 10) Memory Testing Philosophy - 11) Memtest86 Test Algorithms - 12) Individual Test Descriptions - 13) Problem Reporting - Contact Information - 14) Known Problems - 15) Planned Features List - 16) Change Log - 17) Acknowledgments - - -1) Introduction -=============== -Memtest86 is thorough, stand alone memory test for Intel/AMD x86 architecture -systems. BIOS based memory tests are only a quick check and often miss -failures that are detected by Memtest86. - -For updates go to the Memtest86 web page: - - http://www.memtest86.com - - -2) Licensing -============ -Memtest86 is released under the terms of the Gnu Public License (GPL). Other -than the provisions of the GPL there are no restrictions for use, private or -commercial. See: http://www.gnu.org/licenses/gpl.html for details. - - -3) Linux Installation -============================ -Memtest86 is a stand alone program and can be loaded from either a disk -partition or from a floppy disk. - -To build Memtest86: - 1) Review the Makefile and adjust options as needed. - 2) Type "make" - -This creates a file named "memtest.bin" which is a bootable image. This -image file may be copied to a floppy disk or may be loaded from a disk -partition via Lilo or Grub image from a hard disk partition. - - To create a Memtest86 bootdisk - 1) Insert a blank write enabled floppy disk. - 2) As root, Type "make install" - - To boot from a disk partition via Grub - 1) Copy the image file to a permanent location (ie. /boot/memtest.bin). - 2) Add an entry in the Grub config file (/boot/grub/menu.lst) to boot - memtest86. Only the title and kernel fields need to be specified. - The following is a sample Grub entry for booting memtest86: - - title Memtest86 - kernel (hd0,0)/memtest.bin - - To boot from a disk partition via Lilo - 1) Copy the image file to a permanent location (ie. /boot/memtest.bin). - 2) Add an entry in the lilo config file (usually /etc/lilo.conf) to boot - memtest86. Only the image and label fields need to be specified. - The following is a sample Lilo entry for booting memtest86: - - image = /boot/memtest.bin - label = memtest86 - - 3) As root, type "lilo" - -If you encounter build problems a binary image has been included (precomp.bin). -To create a boot-disk with this pre-built image do the following: - 1) Insert a blank write enabled floppy disk. - 2) Type "make install-precomp" - - -4) Serial Console -================= -Memtest86 can be used on PC's equipped with a serial port for the console. -By default serial port console support is not enabled since it slows -down testing. To enable change the SERIAL_CONSOLE_DEFAULT define in -config.h from a zero to a one. The serial console baud rate may also -be set in config.h with the SERIAL_BAUD_RATE define. The other serial -port settings are no parity, 8 data bits, 1 stop bit. All of the features -used by memtest86 are accessible via the serial console. However, the -screen sometimes is garbled when the online commands are used. - - -5) Online Commands -================== -Memtest86 has a limited number of online commands. Online commands -provide control over caching, test selection, address range and error -scrolling. A help bar is displayed at the bottom of the screen listing -the available on-line commands. - - Command Description - - ESC Exits the test and does a warm restart via the BIOS. - - c Enters test configuration menu - Menu options are: - 1) Test selection - 2) Address Range - 3) Error Report Mode - 4) CPU Selection Mode - 5) Refresh Screen - - SP Set scroll lock (Stops scrolling of error messages) - Note: Testing is stalled when the scroll lock is - set and the scroll region is full. - - CR Clear scroll lock (Enables error message scrolling) - - -6) Error Information -====================== -Memtest has three options for reporting errors. The default is an an error -summary that displays the most relevant error information. The second option -is reporting of individual errors. In BadRAM Patterns mode patterns are -created for use with the Linux BadRAM feature. This slick feature allows -Linux to avoid bad memory pages. Details about the BadRAM feature can be -found at: - - http://home.zonnet.nl/vanrein/badram - -The error summary mode displays the following information: - - Error Confidence Value: - A value that indicates the validity of the errors being reported with - larger values indicating greater validity. There is a high probability - that all errors reported are valid regardless of this value. However, - when this value exceeds 100 it is nearly impossible that the reported - errors will be invalid. - - Lowest Error Address: - The lowest address that where an error has been reported. - - Highest Error Address: - The highest address that where an error has been reported. - - Bits in Error Mask: - A mask of all bits that have been in error (hexadecimal). - - Bits in Error: - Total bit in error for all error instances and the min, max and average - bit in error of each individual occurrence. - - Max Contiguous Errors: - The maximum of contiguous addresses with errors. - - ECC Correctable Errors: - The number of errors that have been corrected by ECC hardware. - - Test Errors: - On the right hand side of the screen the number of errors for each test - are displayed. - -For individual errors the following information is displayed when a memory -error is detected. An error message is only displayed for errors with a -different address or failing bit pattern. All displayed values are in -hexadecimal. - - Tst: Test number - Failing Address: Failing memory address - Good: Expected data pattern - Bad: Failing data pattern - Err-Bits: Exclusive or of good and bad data (this shows the - position of the failing bit(s)) - Count: Number of consecutive errors with the same address - and failing bits - CPU: CPU that detected the error - -In BadRAM Patterns mode, Lines are printed in a form badram=F1,M1,F2,M2. -In each F/M pair, the F represents a fault address, and the corresponding M -is a bitmask for that address. These patterns state that faults have -occurred in addresses that equal F on all "1" bits in M. Such a pattern may -capture more errors that actually exist, but at least all the errors are -captured. These patterns have been designed to capture regular patterns of -errors caused by the hardware structure in a terse syntax. - -The BadRAM patterns are `grown' increment-ally rather than `designed' from an -overview of all errors. The number of pairs is constrained to five for a -number of practical reasons. As a result, handcrafting patterns from the -output in address printing mode may, in exceptional cases, yield better -results. - - -7) Trouble-shooting Memory Errors -================================ -Please be aware that not all errors reported by Memtest86 are due to -bad memory. The test implicitly tests the CPU, L1 and L2 caches as well as -the motherboard. It is impossible for the test to determine what causes -the failure to occur. Most failures will be due to a problem with memory. -When it is not, the only option is to replace parts until the failure is -corrected. - -Once a memory error has been detected, determining the failing -module is not a clear cut procedure. With the large number of motherboard -vendors and possible combinations of simm slots it would be difficult if -not impossible to assemble complete information about how a particular -error would map to a failing memory module. However, there are steps -that may be taken to determine the failing module. Here are three -techniques that you may wish to use: - -1) Removing modules -This is simplest method for isolating a failing modules, but may only be -employed when one or more modules can be removed from the system. By -selectively removing modules from the system and then running the test -you will be able to find the bad module(s). Be sure to note exactly which -modules are in the system when the test passes and when the test fails. - -2) Rotating modules -When none of the modules can be removed then you may wish to rotate modules -to find the failing one. This technique can only be used if there are -three or more modules in the system. Change the location of two modules -at a time. For example put the module from slot 1 into slot 2 and put -the module from slot 2 in slot 1. Run the test and if either the failing -bit or address changes then you know that the failing module is one of the -ones just moved. By using several combinations of module movement you -should be able to determine which module is failing. - -3) Replacing modules -If you are unable to use either of the previous techniques then you are -left to selective replacement of modules to find the failure. - -4) Avoiding allocation -The printing mode for BadRAM patterns is intended to construct boot time -parameters for a Linux kernel that is compiled with BadRAM support. This -work-around makes it possible for Linux to reliably run on defective -RAM. For more information on BadRAM support -for Linux, sail to - - http://home.zonnet.nl/vanrein/badram - -Sometimes memory errors show up due to component incompatibility. A memory -module may work fine in one system and not in another. This is not -uncommon and is a source of confusion. The components are not necessarily -bad but certain combinations may need to be avoided. - -I am often asked about the reliability of errors reported by Mestest86. -In the vast majority of cases errors reported by the test are valid. -There are some systems that cause Memtest86 to be confused about the size of -memory and it will try to test non-existent memory. This will cause a large -number of consecutive addresses to be reported as bad and generally there -will be many bits in error. If you have a relatively small number of -failing addresses and only one or two bits in error you can be certain -that the errors are valid. Also intermittent errors are always valid. - -All valid memory errors should be corrected. It is possible that a -particular error will never show up in normal operation. However, operating -with marginal memory is risky and can result in data loss and even -disk corruption. You can be sure that Murphy will get you if you know -about a memory error and ignore it. - -Memtest86 can not diagnose many types of PC failures. For example a -faulty CPU that causes Windows to crash will most likely just cause -Memtest86 to crash in the same way. - - -8) Execution Time -================== -The time required for a complete pass of Memtest86 will vary greatly -depending on CPU speed, memory speed and memory size. Memtest86 executes -indefinitely. The pass counter increments each time that all of the -selected tests have been run. Generally a single pass is sufficient to -catch all but the most obscure errors. However, for complete confidence -when intermittent errors are suspected testing for a longer period is advised. - -9) Memory Testing Philosophy -============================= -There are many good approaches for testing memory. However, many tests -simply throw some patterns at memory without much thought or knowledge -of memory architecture or how errors can best be detected. This -works fine for hard memory failures but does little to find intermittent -errors. BIOS based memory tests are useless for finding intermittent -memory errors. - -Memory chips consist of a large array of tightly packed memory cells, -one for each bit of data. The vast majority of the intermittent failures -are a result of interaction between these memory cells. Often writing a -memory cell can cause one of the adjacent cells to be written with the -same data. An effective memory test attempts to test for this -condition. Therefore, an ideal strategy for testing memory would be -the following: - - 1) write a cell with a zero - 2) write all of the adjacent cells with a one, one or more times - 3) check that the first cell still has a zero - -It should be obvious that this strategy requires an exact knowledge -of how the memory cells are laid out on the chip. In addition there is a -never ending number of possible chip layouts for different chip types -and manufacturers making this strategy impractical. However, there -are testing algorithms that can approximate this ideal strategy. - - -11) Memtest86 Test Algorithms -============================= -Memtest86 uses two algorithms that provide a reasonable approximation -of the ideal test strategy above. The first of these strategies is called -moving inversions. The moving inversion test works as follows: - - 1) Fill memory with a pattern - 2) Starting at the lowest address - 2a check that the pattern has not changed - 2b write the patterns complement - 2c increment the address - repeat 2a - 2c - 3) Starting at the highest address - 3a check that the pattern has not changed - 3b write the patterns complement - 3c decrement the address - repeat 3a - 3c - -This algorithm is a good approximation of an ideal memory test but -there are some limitations. Most high density chips today store data -4 to 16 bits wide. With chips that are more than one bit wide it -is impossible to selectively read or write just one bit. This means -that we cannot guarantee that all adjacent cells have been tested -for interaction. In this case the best we can do is to use some -patterns to insure that all adjacent cells have at least been written -with all possible one and zero combinations. - -It can also be seen that caching, buffering and out of order execution -will interfere with the moving inversions algorithm and make less effective. -It is possible to turn off cache but the memory buffering in new high -performance chips can not be disabled. To address this limitation a new -algorithm I call Modulo-X was created. This algorithm is not affected by -cache or buffering. The algorithm works as follows: - 1) For starting offsets of 0 - 20 do - 1a write every 20th location with a pattern - 1b write all other locations with the patterns complement - repeat 1b one or more times - 1c check every 20th location for the pattern - -This algorithm accomplishes nearly the same level of adjacency testing -as moving inversions but is not affected by caching or buffering. Since -separate write passes (1a, 1b) and the read pass (1c) are done for all of -memory we can be assured that all of the buffers and cache have been -flushed between passes. The selection of 20 as the stride size was somewhat -arbitrary. Larger strides may be more effective but would take longer to -execute. The choice of 20 seemed to be a reasonable compromise between -speed and thoroughness. - - -11) Individual Test Descriptions -================================ -Memtest86 executes a series of numbered test sections to check for -errors. These test sections consist of a combination of test -algorithm, data pattern and caching. The execution order for these tests -were arranged so that errors will be detected as rapidly as possible. -A description of each of the test sections follows: - -Test 0 [Address test, walking ones, no cache] - Tests all address bits in all memory banks by using a walking ones - address pattern. Errors from this test are not used to calculate - BadRAM patterns. - -Test 1 [Address test, own address Sequential] - Each address is written with its own address and then is checked - for consistency. In theory previous tests should have caught any - memory addressing problems. This test should catch any addressing - errors that somehow were not previously detected. This test is done - sequentially with each available CPU. - -Test 2 [Address test, own address Parallel] - Same as test 1 but the testing is done in parallel using all CPUs using - overlapping addresses. - -Test 3 [Moving inversions, ones&zeros Sequential] - This test uses the moving inversions algorithm with patterns of all - ones and zeros. Cache is enabled even though it interferes to some - degree with the test algorithm. With cache enabled this test does not - take long and should quickly find all "hard" errors and some more - subtle errors. This test is done sequentially with each available CPU. - -Test 4 [Moving inversions, ones&zeros Parallel] - Same as test 3 but the testing is done in parallel using all CPUs. - -Test 5 [Moving inversions, 8 bit pat] - This is the same as test 4 but uses a 8 bit wide pattern of - "walking" ones and zeros. This test will better detect subtle errors - in "wide" memory chips. A total of 20 data patterns are used. - -Test 6 [Moving inversions, random pattern] - Test 6 uses the same algorithm as test 4 but the data pattern is a - random number and it's complement. This test is particularly effective - in finding difficult to detect data sensitive errors. - The random number sequence is different with each pass - so multiple passes increase effectiveness. - -Test 7 [Block move, 64 moves] - This test stresses memory by using block move (movsl) instructions - and is based on Robert Redelmeier's burnBX test. Memory is initialized - with shifting patterns that are inverted every 8 bytes. Then 4MB blocks - of memory are moved around using the movsl instruction. After the moves - are completed the data patterns are checked. Because the data is checked - only after the memory moves are completed it is not possible to know - where the error occurred. The addresses reported are only for where the - bad pattern was found. Since the moves are constrained to a 8MB segment - of memory the failing address will always be lest than 8MB away from the - reported address. Errors from this test are not used to calculate - BadRAM patterns. - -Test 8 [Moving inversions, 32 bit pat] - This is a variation of the moving inversions algorithm that shifts the data - pattern left one bit for each successive address. The starting bit position - is shifted left for each pass. To use all possible data patterns 32 passes - are required. This test is quite effective at detecting data sensitive - errors but the execution time is long. - -Test 9 [Random number sequence] - This test writes a series of random numbers into memory. By resetting the - seed for the random number the same sequence of number can be created for - a reference. The initial pattern is checked and then complemented and - checked again on the next pass. However, unlike the moving inversions test - writing and checking can only be done in the forward direction. - -Test 10 [Modulo 20, random pattern] - Using the Modulo-X algorithm should uncover errors that are not - detected by moving inversions due to cache and buffering interference - with the the algorithm. A 32 bit random pattern is used. - -Test 11 [Bit fade test, 2 patterns] - The bit fade test initializes all of memory with a pattern and then - sleeps for 5 minutes. Then memory is examined to see if any memory bits - have changed. All ones and all zero patterns are used. - - -12) Problem Reporting - Contact Information -=========================================== -Due to the growing popularity of Memtest86 (more than 200,000 downloads per -month) I have been inundated by, questions, feedback, problem reports and -requests for enhancements. I simply do not have time to respond to ANY Memtest86 -emails. Bug reports and suggestions are welcome but will typically not be -responded to. - -*** NOTE: *** The Keyword MEM86 must appear in the subject of all emails or -the message will be automaticly deleted before it gets to me. This thanks to -spam and viruses! - -Problems/Bugs: -Before submitting a problem report please check the Known Problems section -to see if this problem has already been reported. Be sure to include the -version number and also any details that may be relevant. - -Chris Brady, Email: bugs@memtest86.com - -With some PC's Memtest86 will just die with no hints as to what went wrong. -Without any details it is impossible to fix these failures. Fixing these -problems will require debugging on your part. There is no point in reporting -these failures unless you have a Linux system and would be willing to debug -the failure. - -Enhancements: -If you would like to request an enhancement please see if is already on -the Planned Features List before sending your request. All requests will -be considered, but not all can be implemented. If you are be interested in -contributing code please contact me so that the integration can be -co-ordinated. - -Chris Brady, Email: enhance@memtest86.com - -Questions: -Unfortunately, I do not have time to respond to any questions or provide -assistance with troubleshooting problems. Please read the Troubleshooting -and Known Problems sections for assistance with problems. These sections have -the answers for the questions that I have answers to. If there is not an -answer for your problem in these sections it is probably not something I can -help you with. - - -15) Known Problems -================== -Sometimes when booting from a floppy disk the following messages scroll up -on the screen: - X:8000 - AX:0212 - BX:8600 - CX:0201 - DX:0000 -This the BIOS reporting floppy disk read errors. Either re-write or toss -the floppy disk. - -Memtest86 can not diagnose many types of PC failures. For example a -faulty CPU that causes Windows to crash will most likely just cause -Memtest86 to crash in the same way. - -There have been numerous reports of errors in only the block move test. Often -the memory works in a different system or the vendor insists that it is good. -In these cases the memory is not necessarily bad but is not able to operate -reliably high speeds. Sometimes more conservative memory timings on the -motherboard will correct these errors. In other cases the only option is to -replace the memory with better quality, higher speed memory. Don't buy cheap -memory and expect it to work at full speed. - -Memtest86 supports all types of memory. If fact the test has absolutely -no knowledge of the memory type nor does it need to. This not a problem -or bug but is listed here due to the many questions I get about this issue. - -Changes in the compiler and loader have caused problems with -Memtest86 resulting in both build failures and errors in execution. A -binary image (precomp.bin) of the test is included and may be used if -problems are encountered. - - -15) Planned Features List -========================= -This is a list of enhancements planned for future releases of Memtest86. -There is no timetable for when these will be implemented. - - - Testing in 64 bit mode with 64 data patterns - - Support for reporting ECC errors was removed in the 4.0 release. A - simplified implementation of ECC reporting is planned for a future release. - - -16) Change Log -============== -Enhancements in v4.0 (28/Mar/2011) - - Full support for testing with multiple CPUs. All tests except for #11 (Bit - Fade) have been multi-threaded. A maximum of 16 CPUs will be used for testing. - - CPU detection has been completely re-written to use the brand ID string - rather than the cumbersome, difficult to maintain and often out of date - CPUID family information. All new processors will now be correctly - identified without requiring code support. - - All code related to controller identification, PCI and DMI has been removed. - This may be a controversial decision and was not made lightly. The following - are justifications for the decision: - - 1. Controller identification has nothing to do with actual testing of - memory, the core purpose of Memtest86. - 2. This code needed to be updated with every new chipset. With the ever - growing number of chipsets it is not possible to keep up with the - changes. The result is that new chipsets were more often than not - reported in-correctly. In the authors opinion incorrect information is - worse than no information. - 3. Probing for chipset information carries the risk of making the program - crash. - 4. The amount of code involved with controller identification was quite - large, making support more difficult. - - Removing this code also had the unfortunate effect of removing reporting of - correctable ECC errors. The code to support ECC was hopelessly intertwined - the controller identification code. A fresh, streamlined implementation of - ECC reporting is planned for a future release. - - A surprising number of conditions existed that potentially cause problems - when testing more than 4 GB of memory. Most if not all of these conditions - have been identified and corrected. - - A number of cases were corrected where not all of memory was being tested. - For most tests the last word of each test block was not tested. In addition - an error in the paging code was fixed that omitted from testing the last 256 - bytes of each block above 2 GB. - - The information display has been simplified and a number of details that were - not relevant to testing were removed. - - Memory speed reporting has been parallelized for more accurate reporting for - multi channel memory controllers. - - This is a major re-write of the Memtest86 with a large number of minor - bug-fixes and substantial cleanup and re-organization of the code. - - -Enhancements in v3.5 (3/Jan/2008) - - Limited support for execution with multiple CPUs. CPUs are selected - round-robin or sequential for each test. - - Support for additional chipsets. (from Memtest86+ v2.11). - - Additions and corrections for CPU detection including reporting of L3 cache. - - Reworked information display for better readability and new information. - - Abbreviated iterations for first pass. - - Enhancements to memory sizing. - - Misc fixes. - -Enhancements in v3.4 (2/Aug/2007) - - A new error summary display with error confidence analysis. - - Support for additional chipsets. (from Memtest86+ v1.70). - - Additions and corrections for CPU detection. - - Support for memory module information reporting. - - Misc bug fixes. - -Enhancements in v3.3 (12/Jan/2007) - - Added support for additional chipsets. (from Memtest86+ v1.60) - - Changed Modulo 20 test (#8) to use a more effective random pattern rather - than simple ones and zeros. - - Fixed a bug that prevented testing of low memory. - - Added an advanced menu option to display SPD info (only for selected - chipsets). - - Updated CPU detection for new CPUs and corrected some bugs. - - Reworked online command text for better clarity. - - Added a fix to correct a Badram pattern bug. - - -Enhancements in v3.2 (11/Nov/2004) - - Added two new, highly effective tests that use random number patterns - (tests 4 and 6). - - Reworked the online commands: - - Changed wording for better clarity - - Dropped Cache Mode menu - - Updated CPU detection for newer AMD, Intel and Cyrix CPUs. - - Reworked test sequence: - - Dropped ineffective non cached tests (Numbers 7-11) - - Changed cache mode to "cached" for test 2 - - Fixed bug that did not allow some tests to be skipped - - Added bailout for Bit fade test - - Error reports are highlighted in red to provide a more vivid error - indication. - - Added support for a large number of additional chipsets. (from Memtest86+ - v1.30) - - Added an advanced setup feature that with new chiset allows memory timings - to be altered from inside Memtest86. (from Memtest86+ v1.30) - - -Enhancements in v3.1 (11/Mar/2004) - - Added processor detection for newer AMD processors. - - Added new "Bit Fade" extended test. - - Fixed a compile time bug with gcc version 3.x. - - E7500 memory controller ECC support - - Added support for 16bit ECC syndromes - - Option to keep the serial port baud rate of the boot loader - - -Enhancements in v3.0 (22/May/2002) Provided by Eric Biederman - - Testing of more than 2gb of memory is at last fixed (tested with 6Gb) - - The infrastructure is to poll ecc error reporting chipset regisets, - and the support has been done for some chipsets. - - Uses dynamic relocation information records to make itself PIC - instead of requiring 2 copies of memtest86 in the binary. - - The serial console code does not do redundant writes to the serial port - Very little slow down at 9600 baud. - - You can press ^l or just l to get a screen refresh, when you are - connecting and UN-connecting a serial cable. - - Net-booting is working again - - Linux-BIOS support (To get the memory size) - - Many bug-fixes and code cleanup. - -Enhancements in v2.9 (29/Feb/2002) - - The memory sizing code has been completely rewritten. By default - Memtest86 gets a memory map from the BIOS that is now used to find - available memory. A new online configuration option provides three - choices for how memory will be sized, including the old "probe" method. - The default mode generally will not test all of memory, but should be more - stable. See the "Memory Sizing" section for details. - - Testing of more than 2gb of memory should now work. A number of bugs - were found and corrected that prevented testing above 2gb. Testing - with more than 2gb has been limited and there could be problems with a - full 4gb of memory. - - Memory is divided into segments for testing. This allow for frequent - progress updates and responsiveness to interactive commands. The - memory segment size has been increased from 8 to 32mb. This should - improve testing effectiveness but progress reports will be less frequent. - - Minor bug fixes. - -Enhancements in v2.8 (18/Oct/2001) - Eric Biederman reworked the build process making it far simpler and also - to produce a network bootable ELF image. - - Re-wrote the memory and cache speed detection code. Previously the - reported numbers were inaccurate for Intel CPU's and completely wrong - for Athlon/Duron CPU's. - - By default the serial console is disabled since this was slowing - down testing. - - Added CPU detection for Pentium 4. - - -Enhancements in v2.7 (12/Jul/2001) - Expanded workaround for errors caused by BIOS USB keyboard support to - include test #5. - - Re-worked L1 / L2 cache detection code to provide clearer reporting. - - Fixed an obvious bug in the computation of cache and memory speeds. - - Changed on-line menu to stay in the menu between option selections. - - Fixed bugs in the test restart and redraw code. - - Adjusted code size to fix compilation problems with RedHat 7.1. - - Misc updates to the documentation. - -Enhancements in v2.6 (25/May/2001) - Added workaround for errors caused by BIOS USB keyboard support. - - Fixed problems with reporting of 1 GHZ + processor speeds. - - Fixed Duron cache detection. - - Added screen buffer so that menus will work correctly from a serial - console. - - The Memtest86 image is now built in ELF format. - -Enhancements in v2.5 (14/Dec/00) - Enhanced CPU and cache detection to correctly identify Duron CPU - and K6-III 1MB cache. - - Added code to report cache-able memory size. - - Added limited support for parity memory. - - Support was added to allow use of on-line commands from a serial - port. - - Dropped option for changing refresh rates. This was not useful - and did not work on newer motherboards. - - Improved fatal exception reporting to include a register and stack - dump. - - The pass number is now displayed in the error report. - - Fixed a bug that crashed the test when selecting one of the extended - tests. - -Enhancements in v2.4 - The error report format was reworked for better clarity and now - includes a decimal address in megabytes. - - A new memory move test was added (from Robert Redelmeier's CPU-Burn) - - The test sequence and iterations were modified. - - Fixed scrolling problems with the BadRAM patterns. - - -Enhancements in v2.3 - A progress meter was added to replace the spinner and dots. - - Measurement and reporting of memory and cache performance - was added. - - Support for creating BadRAM patterns was added. - - All of the test routines were rewritten in assembler to - improve both test performance and speed. - - The screen layout was reworked to hopefully be more readable. - - An error summary option was added to the online commands. - - -Enhancements in v2.2 - Added two new address tests - - Added an on-line command for setting test address range - - Optimized test code for faster execution (-O3, -funroll-loops and - -fomit-frame-pointer) - - Added and elapsed time counter. - - Adjusted menu options for better consistency - - -Enhancements in v2.1 - Fixed a bug in the CPU detection that caused the test to - hang or crash with some 486 and Cryrix CPU's - - Added CPU detection for Cyrix CPU's - - Extended and improved CPU detection for Intel and AMD CPU's - - Added a compile time option (BIOS_MEMSZ) for obtaining the last - memory address from the BIOS. This should fix problems with memory - sizing on certain motherboards. This option is not enabled by default. - It may be enabled be default in a future release. - -Enhancements in v2.0 - Added new Modulo-20 test algorithm. - - Added a 32 bit shifting pattern to the moving inversions algorithm. - - Created test sections to specify algorithm, pattern and caching. - - Improved test progress indicators. - - Created popup menus for configuration. - - Added menu for test selection. - - Added CPU and cache identification. - - Added a "bail out" feature to quit the current test when it does not - fit the test selection parameters. - - Re-arranged the screen layout and colors. - - Created local include files for I/O and serial interface definitions - rather than using the sometimes incompatible system include files. - - Broke up the "C" source code into four separate source modules. - -Enhancements in v1.5 - Some additional changes were made to fix obscure memory sizing - problems. - - The 4 bit wide data pattern was increased to 8 bits since 8 bit - wide memory chips are becoming more common. - - A new test algorithm was added to improve detection of data - pattern sensitive errors. - - -Enhancements in v1.4 - Changes to the memory sizing code to avoid problems with some - motherboards where memtest would find more memory than actually - exists. - - Added support for a console serial port. (thanks to Doug Sisk) - - On-line commands are now available for configuring Memtest86 on - the fly (see On-line Commands). - - -Enhancements in v1.3 - Scrolling of memory errors is now provided. Previously, only one screen - of error information was displayed. - - Memtest86 can now be booted from any disk via lilo. - - Testing of up to 4gb of memory has been fixed is now enabled by default. - This capability was clearly broken in v1.2a and should work correctly - now but has not been fully tested (4gb PC's are a bit rare). - - The maximum memory size supported by the motherboard is now being - calculated correctly. In previous versions there were cases where not - all of memory would be tested and the maximum memory size supported - was incorrect. - - For some types of failures the good and bad values were reported to be - same with an Xor value of 0. This has been fixed by retaining the data - read from memory and not re-reading the bad data in the error reporting - routine. - - APM (advanced power management) is now disabled by Memtest86. This - keeps the screen from blanking while the test is running. - - Problems with enabling & disabling cache on some motherboards have been - corrected. - - -17) Acknowledgments -=================== -Memtest86 was developed by Chris Brady with the resources and assistance -listed below: - -- The initial versions of the source files bootsect.S, setup.S, head.S and - build.c are from the Linux 1.2.1 kernel and have been heavily modified. - -- Doug Sisk provided code to support a console connected via a serial port. - -- Code to create BadRAM patterns was provided by Rick van Rein. - -- Tests 5 and 8 are based on Robert Redelmeier's burnBX test. - -- Screen buffer code was provided by Jani Averbach. - -- Eric Biederman provided all of the feature content for version 3.0 - plus many bugfixes and significant code cleanup. - -- Major enhancements to hardware detection and reporting in version 3.2, - 3.3 pnd 3.4 rovided by Samuel Demeulemeester (from Memtest86+ v1.11, v1.60 - and v1.70). diff --git a/memtest86+_old/README.background b/memtest86+_old/README.background deleted file mode 100644 index 4acab8e..0000000 --- a/memtest86+_old/README.background +++ /dev/null @@ -1,156 +0,0 @@ - The Anatomy & Physiology of Memtest86-SMP - ----------------------------------------- - -1. Binary layout - - --------------------------------------------------------------- - | bootsect.o | setup.o | head.o memtest_shared | - --------------------------------------------------------------- -Labels _start<-------memtest---------->_end - ----------------------------------------------------------- -addr 0 512 512+4*512 | - ----------------------------------------------------------- - -2. The following steps occur after we power on. - a. The bootsect.o code gets loaded at 0x7c00 - and copies - i. itself to 0x90000 - ii. setup.o to 0x90200 - iii. everything between _start and _end i.e memtest - to 0x10000 - b. jumps somewhere into the copied bootsect.o code at 0x90000 - ,does some trivial stuff and jumps to setup.o - c. setup.o puts the processor in protected mode, with a basic - gdt and idt and does a long jump to the start of the - memtest code (startup_32, see 4 below). The code and data - segment base address are all set to 0x0. So a linear - address range and no paging is enabled. - d. From now on we no longer required the bootsect.o and setup.o - code. -3. The code in memtest is compiled as position independent - code. Which implies that the code can be moved dynamically in - the address space and can still work. Since we are now in head.o, - which is compiled with PIC , we no longer should use absolute - addresses references while accessing functions or globals. - All symbols are stored in a table called Global Offset Table(GOT) - and %ebx is set to point to the base of that table. So to get/set - the value of a symbol we need to read (%ebx + symbolOffsetIntoGOT) to - get the symbol value. For eg. if foo is global varible the assembly - code to store %eax value into foo will be changed from - mov %eax, foo - to - mov %eax, foo@GOTOFF(%ebx) -4. (startup_32) The first step done in head.o is to change - the gdtr and idtr register values to point to the final(!) - gdt and ldt tables in head.o, since we can no longer use the - gdt and ldt tables in setup.o, and call the dynamic linker - stub in memtest_shared (see call _dl_start in head.S). This - dynamic linker stub relocates all the code in memtest w.r.t - the new base location i.e 0x1000. Finally we call the test_start() - 'C' routine. -5. The test_start() C routine is the main routine which lets the BSP - bring up the APs from their halt state, relocate the code - (if necessary) to new address, move the APs to the newly - relocated address and execute the tests. The BSP is the - master which controls the execution of the APs, and mostly - it is the one which manupulates the global variables. - i. we change the stack to a private per cpu stack. - (this step happens every time we move to a new location) - ii. We kick start the APs in the system by - a. Putting a temporary real mode code - (_ap_trampoline_start - _ap_trampoline_protmode) - at 0x9000, which puts the AP in protected mode and jumps - to _ap_trampoline_protmode in head.o. The code in - _ap_trampoline_protmode calls start_32 in head.o which - reinitialises the AP's gdt and idt to point to the - final(!) gdt and idt. (see step 4 above) - b. Since the APs also traverse through the same initialisation - code(startup_32 in head.o), the APs also call test_start(). - The APs just spin wait (see AP_SpinWaitStart) till the - are instructed by the BSP to jump to a new location, - which can either be a test execution or spin wait at a - new location. - iii. The base address at which memtest tries to execute as far - as possible is 0x2000. This is the lowest possible address - memtest can put itself at. So the next step is to - move to 0x2000, which it cannot directly, since copying - code to 0x2000 will override the existing code at 0x1000. - 0x2000 +sizeof(memtest) will usually be greater than 0x1000. - so we temporarily relocated to 0x200000 and then relocate - back to 0x2000. Every time the BSP relocates the code to the - new location, it pulls up the APs spin waiting at the old - location to spin wait at the corresponding relocated - spin wait location, by making them jump to the new - statup_32 relocated location(see 4 above). - Hence forth during the tests 0x200000 is the only place - we relocate to if we need to test a memory window - (see v. below to get a description of what a window is) - which includes address range 0x2000. - - Address map during normal execution. - -------------------------------------------------------------------- - | head.o memtest_shared | |RAM_END - -------------------------------------------------------------------- -Labels _start<-------memtest---------->_end - -------------------------------------------------------------------- -addr 0x0 0x2000 | Memory that is being tested.. |RAM_END - -------------------------------------------------------------------- - - Address map during relocated state. - -------------------------------------------------------------------- - | head.o memtest_shared | |RAM_END - -------------------------------------------------------------------- -Labels _start<-------memtest---------->_end - -------------------------------------------------------------------- -addr memory that is being tested... |0x200000 | |RAM_END - -------------------------------------------------------------------- - - iv. Once we are at 0x2000 we initialise the system, and - determine the memory map ,usually via the bios e820 map. - The sorted, and non-overlapping RAM page ranges are - placed in v->pmap[] array. This array is the reference - of the RAM memory map on the system. - v. The memory range(in page numbers) which the - memtest86 can test is partitioned into windows. - the current version of memtest86-smp has the capability - to test the memory from 0x0 - 0xFFFFFFFFF (max address - when pae mode is enabled). - We then compute the linear memory address ranges(called - segments) for the window we are currently about to - test. The windows are - a. 0 - 640K - b. (0x2000 + (_end - _start)) - 4G (since the code is at 0x2000). - c. >4G to test pae address range, each window with size - of 0x80000(2G), large enough to be mapped in one page directory - entry. So a window size of 0x80000 means we can map 1024 page - table entries, with page size of 2M(pae mode), with one - page directory entry. Something similar to kseg entry - in linux. The upper bound page number is 0x1000000 which - corresponds to linear address 0xFFFFFFFFF + 1 which uses - all the 36 address bits. - Each window is compared against the sorted & non-overlapping - e820 map which we have stored in v->pmap[] array, since all - memory in the selected window address range may correspond to - RAM or can be usable. A list of segments within the window is - created, which contain the usable portions of the window. - This is stored in v->mmap[] array. - vi. Once the v->mmap[] array is populated, we have the list of - non-overlapping segments in the current window which are the - final address ranges that can be tested. The BSP executes the - test first and lets each AP execute the test one by one. Once - all the APs finish execting the same test, the BSP moves to the - next window follows the same procedure till all the windows - are done. Once all the windows are done, the BSP moves to the - next test. Before executing in any window the BSP checks if - the window overlaps with the code/data of memtest86, if so - tries to relocate to 0x200000. If the window includes both - 0x2000 as well as 0x200000 the BSP skips that window. - Looking at the window values the only time the memtest - relocates is when testing the 0 - 640K window. - -Known Issues: -* Memtest86-smp does not work on IBM-NUMA machines, x440 and friends. - -email comments to: -Kalyan Rajasekharuni -Sub: Memtest86-SMP diff --git a/memtest86+_old/README.build-process b/memtest86+_old/README.build-process deleted file mode 100644 index 12158d6..0000000 --- a/memtest86+_old/README.build-process +++ /dev/null @@ -1,39 +0,0 @@ -During memory testing memtest86 relocates itself in memory so it can test the -memory it was previously running from. memtest86 is compiled as position mostly -independent code. Some relocations records must be processed to achieve the -affect of position independent code. A 16 bit loader is prepended to memtest86 -so it can be loaded from a floppy, or from lilo. - -In restructuring the build process I had several goals. Maintainability and -comprehensibility of the build process. Simplicity of the toolset. And the -ability to build images bootable by both the legacy x86 bootloader, -and images bootable by bootloaders that directly load static ELF images. - -With the ability to process relocation records, memtest.bin has been -reduced in size from 84480 bytes to 49308 bytes. And now only requires one copy -of memtest86. A reduction in size of 35K. And the build process can now ignore -the size of memtest86. - -BIOS calls have been moved from setup.S to head.S making bootsect.S and -setup.S exclusively for booting. - -memtest86 is built in three stages. In the first stage the relocatable object -files are built as with any program. In the second stage the relocatable object -files are linked together into memtest_shared, a shared library version -of memtest86. In the third stage a raw memory image of memtest_shared is formed -and linked into memtest.bin, and memtest. - -memtest.bin is the floppy/lilo bootable target. - -memtest is the ELF bootable target. - -Another major change is now data in the bss segment is also preserved -when memtest86 is relocated, and memtest86 can be relocated to any address. - -The one thing to watch out for is pointers to data inside of memtest86. Except -for constant pointers to static data there is not enough information to generate -relocation records for pointers so they will not change when memtest86 is -relocated, which might lead to nasty surprises. - -Eric Biederman - diff --git a/memtest86+_old/bootsect.S b/memtest86+_old/bootsect.S deleted file mode 100644 index 96aa22b..0000000 --- a/memtest86+_old/bootsect.S +++ /dev/null @@ -1,383 +0,0 @@ -/* - * bootsect.s Copyright (C) 1991, 1992 Linus Torvalds - * - * bootsect.s is loaded at 0x7c00 by the bios-startup routines, and moves - * itself out of the way to address 0x90000, and jumps there. - * - * It then loads 'setup' directly after itself (0x90200), and the system - * at 0x10000, using BIOS interrupts. - * - * The loader has been made as simple as possible, and continuos - * read errors will result in a unbreakable loop. Reboot by hand. It - * loads pretty fast by getting whole tracks at a time whenever possible. - * - * 1-Jan-96 Modified by Chris Brady for use as a boot loader for MemTest-86. - */ - -#include "defs.h" - -ROOT_DEV = 0 - -.code16 -.section ".bootsect", "ax", @progbits -_boot: - - -# ld86 requires an entry symbol. This may as well be the usual one. -.globl _main -_main: - movw $BOOTSEG, %ax - movw %ax, %ds - movw $INITSEG, %ax - movw %ax, %es - movw $256, %cx - subw %si, %si - subw %di, %di - cld - rep - movsw - ljmp $INITSEG, $go - _boot - -go: - movw %cs, %ax - movw $(0x4000-12), %dx # 0x4000 is arbitrary value >= length of - # bootsect + length of setup + room for stack - # 12 is disk parm size - -# bde - changed 0xff00 to 0x4000 to use debugger at 0x6400 up (bde). We -# wouldn't have to worry about this if we checked the top of memory. Also -# my BIOS can be configured to put the wini drive tables in high memory -# instead of in the vector table. The old stack might have clobbered the -# drive table. - - movw %ax, %ds - movw %ax, %es - movw %ax, %ss # put stack at INITSEG:0x4000-12. - movw %dx, %sp - -/* - * Many BIOS's default disk parameter tables will not - * recognize multi-sector reads beyond the maximum sector number - * specified in the default diskette parameter tables - this may - * mean 7 sectors in some cases. - * - * Since single sector reads are slow and out of the question, - * we must take care of this by creating new parameter tables - * (for the first disk) in RAM. We will set the maximum sector - * count to 18 - the most we will encounter on an HD 1.44. - * - * High doesn't hurt. Low does. - * - * Segments are as follows: ds=es=ss=cs - INITSEG, - * fs = 0, gs = parameter table segment - */ - pushw $0 - popw %fs - movw $0x78, %bx # fs:bx is parameter table address - lgs %fs:(%bx),%si # gs:si is source - - movw %dx, %di # es:di is destination - movw $6, %cx # copy 12 bytes - cld - - rep movsw %gs:(%si), (%di) - - movw %dx, %di - movb $18, 4(%di) # patch sector count - - movw %di, %fs:(%bx) - movw %es, %fs:2(%bx) - - movw %cs, %ax - movw %ax, %fs - movw %ax, %gs - - xorb %ah, %ah # reset FDC - xorb %dl, %dl - int $0x13 - -# load the setup-sectors directly after the bootblock. -# Note that 'es' is already set up. - -load_setup: - xorw %dx, %dx # drive 0, head 0 - movw $0x0002, %cx # sector 2, track 0 - movw $0x0200, %bx # address = 512, in INITSEG - movw $(0x0200 + SETUPSECS), %ax # service 2, nr of sectors - # (assume all on head 0, track 0) - int $0x13 # read it - jnc ok_load_setup # ok - continue - - pushw %ax # dump error code - call print_nl - movw %sp, %bp - call print_hex - popw %ax - - xorb %dl, %dl # reset FDC - xorb %ah, %ah - int $0x13 - jmp load_setup - -ok_load_setup: - -# Get disk drive parameters, specifically nr of sectors/track - - -/* It seems that there is no BIOS call to get the number of sectors. Guess - * 18 sectors if sector 18 can be read, 15 if sector 15 can be read. - * Otherwise guess 9 - */ - - xorw %dx, %dx # drive 0, head 0 - movw $0x0012, %cx # sector 18, track 0 - movw $(0x200+(SETUPSECS*0x200)), %bx # address after setup (es = cs) - movw $0x0201, %ax # service 2, 1 sector - int $0x13 - jnc got_sectors - movb $0x0f, %cl # sector 15 - movw $0x0201, %ax # service 2, 1 sector - int $0x13 - jnc got_sectors - movb $0x09, %cl - -got_sectors: - movw %cx, %cs:sectors - _boot - movw $INITSEG, %ax - movw %ax, %es - -# Print some inane message - - movb $0x03, %ah # read cursor pos - xorb %bh, %bh - int $0x10 - - movw $9, %cx - movw $0x0007, %bx # page 0, attribute 7 (normal) - movw $msg1 - _boot, %bp - movw $0x1301, %ax # write string, move cursor - int $0x10 - -# ok, we've written the message, now -# we want to load the system (at 0x10000) - - movw $TSTLOAD, %ax - movw %ax, %es # segment of 0x010000 - call read_it - call kill_motor - call turnoffcursor - call print_nl - -# after that (everyting loaded), we jump to -# the setup-routine loaded directly after -# the bootblock: - - ljmp $SETUPSEG,$0 - -# This routine loads the system at address 0x10000, making sure -# no 64kB boundaries are crossed. We try to load it as fast as -# possible, loading whole tracks whenever we can. -# -# in: es - starting address segment (normally 0x1000) -# -sread: .word 1+SETUPSECS # sectors read of current track -head: .word 0 # current head -track: .word 0 # current track - -read_it: - movw %es, %ax - testw $0x0fff, %ax -die: - jne die # es must be at 64kB boundary - xorw %bx,%bx # bx is starting address within segment -rp_read: - movw %es, %ax - subw $TSTLOAD, %ax # have we loaded all yet? - cmpw syssize - _boot, %ax - jbe ok1_read - ret -ok1_read: - movw %cs:sectors - _boot, %ax - subw sread - _boot, %ax - movw %ax, %cx - shlw $9, %cx - addw %bx, %cx - jnc ok2_read - je ok2_read - xorw %ax, %ax - subw %bx, %ax - shrw $9, %ax -ok2_read: - call read_track - movw %ax, %cx - add sread - _boot, %ax - cmpw %cs:sectors - _boot, %ax - jne ok3_read - movw $1, %ax - subw head - _boot, %ax - jne ok4_read - incw track - _boot -ok4_read: - movw %ax, head - _boot - xorw %ax, %ax -ok3_read: - movw %ax, sread - _boot - shlw $9, %cx - addw %cx, %bx - jnc rp_read - movw %es, %ax - addb $0x10, %ah - movw %ax, %es - xorw %bx, %bx - jmp rp_read - -read_track: - pusha - pusha - movw $0xe2e, %ax # loading... message 2e = . - movw $7, %bx - int $0x10 - popa - - movw track - _boot, %dx - movw sread - _boot, %cx - incw %cx - movb %dl, %ch - movw head - _boot, %dx - movb %dl, %dh - andw $0x0100, %dx - movb $2, %ah - - pushw %dx # save for error dump - pushw %cx - pushw %bx - pushw %ax - - int $0x13 - jc bad_rt - addw $8, %sp - popa - ret - -bad_rt: - pushw %ax # save error code - call print_all # ah = error, al = read - - xorb %ah, %ah - xorb %dl, %dl - int $0x13 - - addw $10, %sp - popa - jmp read_track - -/* - * print_all is for debugging purposes. - * It will print out all of the registers. The assumption is that this is - * called from a routine, with a stack frame like - * dx - * cx - * bx - * ax - * error - * ret <- sp - * -*/ - -print_all: - movw $5, %cx # error code + 4 registers - movw %sp, %bp - -print_loop: - pushw %cx # save count left - call print_nl # nl for readability - - cmpb 5, %cl # see if register name is needed - jae no_reg - - movw $(0xe05 + 'A' - 1), %ax - subb %cl, %al - int $0x10 - movb $'X', %al - int $0x10 - movb $':', %al - int $0x10 - -no_reg: - addw $2, %bp # next register - call print_hex # print it - popw %cx - loop print_loop - ret - -print_nl: - movw $0xe0d, %ax # CR - int $0x10 - movb $0x0a, %al # LF - int $0x10 - ret - -/* - * print_hex is for debugging purposes, and prints the word - * pointed to by ss:bp in hexadecmial. - */ - -print_hex: - movw $4, %cx # 4 hex digits - movw (%bp), %dx # load word into dx - -print_digit: - rolw $4, %dx # rotate so that lowest 4 bits are used - movb $0xe, %ah - movb %dl, %al # mask off so we have only next nibble - andb $0xf, %al - addb $'0', %al # convert to 0-based digit - cmpb $'9', %al # check for overflow - jbe good_digit - addb $('A' - '0' - 10), %al - -good_digit: - int $0x10 - loop print_digit - ret - - -/* - * This procedure turns off the floppy drive motor, so - * that we enter the kernel in a known state, and - * don't have to worry about it later. - */ -kill_motor: - pushw %dx - movw $0x3f2, %dx - xorb %al, %al - outb %al, %dx - popw %dx - ret - -turnoffcursor: - movb $0x01, %ah # turn off the cursor - movb $0x00, %bh - movw $0x2000, %cx - int $0x10 - ret - -sectors: - .word 0 - -msg1: - .byte 13,10 - .ascii "Loading" - -.org 497 -setup_sects: - .byte SETUPSECS -.org 500 -syssize: - .word _syssize -.org 508 -root_dev: - .word ROOT_DEV -boot_flag: - .word 0xAA55 -_eboot: diff --git a/memtest86+_old/build-number.txt b/memtest86+_old/build-number.txt deleted file mode 100644 index 7f8f011..0000000 --- a/memtest86+_old/build-number.txt +++ /dev/null @@ -1 +0,0 @@ -7 diff --git a/memtest86+_old/build.number b/memtest86+_old/build.number deleted file mode 100644 index e110e8d..0000000 --- a/memtest86+_old/build.number +++ /dev/null @@ -1 +0,0 @@ -617 diff --git a/memtest86+_old/build_number.h b/memtest86+_old/build_number.h deleted file mode 100644 index d1f2abc..0000000 --- a/memtest86+_old/build_number.h +++ /dev/null @@ -1,9 +0,0 @@ -#ifndef BUILD_NUMBER_STR -#define BUILD_NUMBER_STR "617" -#endif -#ifndef VERSION_STR -#define VERSION_STR "4.99617 - Thu May 3 11:45:57 CEST 2012" -#endif -#ifndef VERSION_STR_SHORT -#define VERSION_STR_SHORT "4.99617" -#endif diff --git a/memtest86+_old/buildnumber.mak b/memtest86+_old/buildnumber.mak deleted file mode 100644 index 8d5b85d..0000000 --- a/memtest86+_old/buildnumber.mak +++ /dev/null @@ -1,10 +0,0 @@ -# Create an auto-incrementing build number. - -BUILD_NUMBER_LDFLAGS = -Xlinker --defsym -Xlinker __BUILD_DATE=$$(date +'%Y%m%d') -BUILD_NUMBER_LDFLAGS += -Xlinker --defsym -Xlinker __BUILD_NUMBER=$$(cat $(BUILD_NUMBER_FILE)) - -# Build number file. Increment if any object file changes. -$(BUILD_NUMBER_FILE): $(OBJS) - @if ! test -f $(BUILD_NUMBER_FILE); then echo 0 > $(BUILD_NUMBER_FILE); fi - @echo $$(($$(cat $(BUILD_NUMBER_FILE)) + 1)) > $(BUILD_NUMBER_FILE) - diff --git a/memtest86+_old/changelog b/memtest86+_old/changelog deleted file mode 100644 index 9379a5b..0000000 --- a/memtest86+_old/changelog +++ /dev/null @@ -1,25 +0,0 @@ -Memtest86+ V5.01 changelog ----------------------------- - - - Added support for up to 2 TB of RAM on X64 CPUs - - Added experimental SMT support up to 32 cores - - Added complete detection for memory controllers. - - Added Motherboard Manufacturer & Model reporting - - Added CPU temperature reporting - - Added enhanced Fail Safe Mode (Press F1 at startup) - - Added support for Intel "Sandy Bridge-E" CPUs - - Added support for Intel "Ivy Bridge" CPUs - - Added preliminary support for Intel "Haswell" CPUs - - Added preliminary support for Intel "Haswell-ULT" CPUs - - Added support for AMD "Kabini" (K16) CPUs - - Added support for AMD "Bulldozer" CPUs - - Added support for AMD "Trinity" CPUs - - Added support for AMD E-/C-/G-/Z- "Bobcat" CPUs - - Added support for Intel Atom "Pineview" CPUs - - Added support for Intel Atom "Cedar Trail" CPUs - - Added SPD detection on most AMD Chipsets - - Enforced Coreboot support - - Optimized run time for faster memory error detection - - Rewriten lots of memory timings detection code - - Corrected bugs, bugs and more bugs - diff --git a/memtest86+_old/config.c b/memtest86+_old/config.c deleted file mode 100644 index d5af37f..0000000 --- a/memtest86+_old/config.c +++ /dev/null @@ -1,531 +0,0 @@ -/* config.c - MemTest-86 Version 3.4 - * - * Released under version 2 of the Gnu Public License. - * By Chris Brady - * ---------------------------------------------------- - * MemTest86+ V5.00 Specific code (GPL V2.0) - * By Samuel DEMEULEMEESTER, sdemeule@memtest.org - * http://www.x86-secret.com - http://www.memtest.org - */ -#include "test.h" -#include "screen_buffer.h" -#include "dmi.h" - -extern int bail, beepmode; -extern struct tseq tseq[]; -extern short e820_nr; -void performance(); -extern volatile short cpu_mode; -extern volatile int test; -extern void find_chunks(); -extern volatile short start_seq; -extern short restart_flag; -extern short onepass; -extern short btflag; - -extern void get_list(int x, int y, int len, char *buf); - -char save[2][POP_H][POP_W]; -char save2[2][POP2_H][POP2_W]; - -void get_config() -{ - int flag = 0, sflag = 0, i, j, k, n, m, prt = 0; - int reprint_screen = 0; - char cp[64]; - ulong page; - - popup(); - wait_keyup(); - while(!flag) { - cprint(POP_Y+1, POP_X+2, "Settings:"); - cprint(POP_Y+3, POP_X+6, "(1) Test Selection"); - cprint(POP_Y+4, POP_X+6, "(2) Address Range"); - cprint(POP_Y+5, POP_X+6, "(3) Error Report Mode"); - cprint(POP_Y+6, POP_X+6, "(4) Core Selection"); - cprint(POP_Y+7, POP_X+6, "(5) Refresh Screen"); - cprint(POP_Y+8, POP_X+6, "(6) Display DMI Data"); - cprint(POP_Y+9, POP_X+6, "(7) Display SPD Data"); - cprint(POP_Y+11, POP_X+6, "(0) Continue"); - - /* Wait for key release */ - /* Fooey! This nuts'es up the serial input. */ - sflag = 0; - switch(get_key()) { - case 2: - /* 1 - Test Selection */ - popclear(); - cprint(POP_Y+1, POP_X+2, "Test Selection:"); - cprint(POP_Y+3, POP_X+6, "(1) Default Tests"); - cprint(POP_Y+4, POP_X+6, "(2) Skip Current Test"); - cprint(POP_Y+5, POP_X+6, "(3) Select Test"); - cprint(POP_Y+6, POP_X+6, "(4) Enter Test List"); - cprint(POP_Y+7, POP_X+6, "(0) Cancel"); - if (vv->testsel < 0) { - cprint(POP_Y+3, POP_X+5, ">"); - } else { - cprint(POP_Y+5, POP_X+5, ">"); - } - wait_keyup(); - while (!sflag) { - switch(get_key()) { - case 2: - /* Default - All tests */ - i = 0; - while (tseq[i].cpu_sel) { - tseq[i].sel = 1; - i++; - } - find_ticks_for_pass(); - sflag++; - break; - case 3: - /* Skip test */ - bail++; - sflag++; - break; - case 4: - /* Select test */ - popclear(); - cprint(POP_Y+1, POP_X+3, - "Test Selection:"); - cprint(POP_Y+4, POP_X+5, - "Test Number [1-11]: "); - n = getval(POP_Y+4, POP_X+24, 0) - 1; - if (n <= 11) - { - /* Deselect all tests */ - i = 0; - while (tseq[i].cpu_sel) { - tseq[i].sel = 0; - i++; - } - /* Now set the selection */ - tseq[n].sel = 1; - vv->pass = -1; - test = n; - find_ticks_for_pass(); - sflag++; - bail++; - } - break; - case 5: - /* Enter a test list */ - popclear(); - cprint(POP_Y+1, POP_X+3, - "Enter a comma separated list"); - cprint(POP_Y+2, POP_X+3, - "of tests to execute:"); - cprint(POP_Y+5, POP_X+5, "List: "); - /* Deselect all tests */ - k = 0; - while (tseq[k].cpu_sel) { - tseq[k].sel = 0; - k++; - } - - /* Get the list */ - for (i=0; i<64; i++) cp[i] = 0; - get_list(POP_Y+5, POP_X+10, 64, cp); - - /* Now enable all of the tests in the - * list */ - i = j = m = 0; - while (1) { - if (mt86_isdigit(cp[i])) { - n = cp[i]-'0'; - j = j*10 + n; - i++; - if (cp[i] == ',' || cp[i] == 0){ - if (j < k) { - tseq[j].sel = 1; - m++; - } - if (cp[i] == 0) break; - j = 0; - i++; - } - } - } - - /* If we didn't select at least one - * test turn them all back on */ - if (m == 0) { - k = 0; - while (tseq[k].cpu_sel) { - tseq[k].sel = 1; - k++; - } - } - vv->pass = -1; - test = n; - find_ticks_for_pass(); - sflag++; - bail++; - break; - case 11: - case 57: - sflag++; - break; - } - } - popclear(); - break; - case 3: - /* 2 - Address Range */ - popclear(); - cprint(POP_Y+1, POP_X+2, "Test Address Range:"); - cprint(POP_Y+3, POP_X+6, "(1) Set Lower Limit"); - cprint(POP_Y+4, POP_X+6, "(2) Set Upper Limit"); - cprint(POP_Y+5, POP_X+6, "(3) Test All Memory"); - cprint(POP_Y+6, POP_X+6, "(0) Cancel"); - wait_keyup(); - while (!sflag) { - switch(get_key()) { - case 2: - /* Lower Limit */ - popclear(); - cprint(POP_Y+2, POP_X+4, - "Lower Limit: "); - cprint(POP_Y+4, POP_X+4, - "Current: "); - aprint(POP_Y+4, POP_X+13, vv->plim_lower); - cprint(POP_Y+6, POP_X+4, - "New: "); - page = getval(POP_Y+6, POP_X+9, 12); - if (page + 1 <= vv->plim_upper) { - vv->plim_lower = page; - test--; - bail++; - } - adj_mem(); - find_chunks(); - find_ticks_for_pass(); - sflag++; - break; - case 3: - /* Upper Limit */ - popclear(); - cprint(POP_Y+2, POP_X+4, - "Upper Limit: "); - cprint(POP_Y+4, POP_X+4, - "Current: "); - aprint(POP_Y+4, POP_X+13, vv->plim_upper); - cprint(POP_Y+6, POP_X+4, - "New: "); - page = getval(POP_Y+6, POP_X+9, 12); - if (page - 1 >= vv->plim_lower) { - vv->plim_upper = page; - bail++; - test--; - } - adj_mem(); - find_chunks(); - find_ticks_for_pass(); - sflag++; - break; - case 4: - /* All of memory */ - vv->plim_lower = 0; - vv->plim_upper = - vv->pmap[vv->msegs - 1].end; - test--; - bail++; - adj_mem(); - find_chunks(); - find_ticks_for_pass(); - sflag++; - break; - case 11: - case 57: - /* 0/CR - Continue */ - sflag++; - break; - } - } - popclear(); - break; - case 4: - /* Error Mode */ - popclear(); - cprint(POP_Y+1, POP_X+2, "Printing Mode:"); - cprint(POP_Y+3, POP_X+6, "(1) Error Summary"); - cprint(POP_Y+4, POP_X+6, "(2) Individual Errors"); - cprint(POP_Y+5, POP_X+6, "(3) BadRAM Patterns"); - cprint(POP_Y+6, POP_X+6, "(4) Error Counts Only"); - cprint(POP_Y+7, POP_X+6, "(5) Beep on Error"); - cprint(POP_Y+8, POP_X+6, "(0) Cancel"); - cprint(POP_Y+3+vv->printmode, POP_X+5, ">"); - if (beepmode) { cprint(POP_Y+7, POP_X+5, ">"); } - wait_keyup(); - while (!sflag) { - switch(get_key()) { - case 2: - /* Error Summary */ - vv->printmode=PRINTMODE_SUMMARY; - vv->erri.eadr = 0; - vv->erri.hdr_flag = 0; - sflag++; - break; - case 3: - /* Separate Addresses */ - vv->printmode=PRINTMODE_ADDRESSES; - vv->erri.eadr = 0; - vv->erri.hdr_flag = 0; - vv->msg_line = LINE_SCROLL-1; - sflag++; - break; - case 4: - /* BadRAM Patterns */ - vv->printmode=PRINTMODE_PATTERNS; - vv->erri.hdr_flag = 0; - sflag++; - prt++; - break; - case 5: - /* Error Counts Only */ - vv->printmode=PRINTMODE_NONE; - vv->erri.hdr_flag = 0; - sflag++; - break; - case 6: - /* Set Beep On Error mode */ - beepmode = !beepmode; - sflag++; - break; - case 11: - case 57: - /* 0/CR - Continue */ - sflag++; - break; - } - } - popclear(); - break; - case 5: - /* CPU Mode */ - reprint_screen = 1; - popclear(); - cprint(POP_Y+1, POP_X+2, "CPU Selection Mode:"); - cprint(POP_Y+3, POP_X+6, "(1) Parallel (All)"); - cprint(POP_Y+4, POP_X+6, "(2) Round Robin (RRb)"); - cprint(POP_Y+5, POP_X+6, "(3) Sequential (Seq)"); - cprint(POP_Y+6, POP_X+6, "(0) Cancel"); - cprint(POP_Y+2+cpu_mode, POP_X+5, ">"); - wait_keyup(); - while(!sflag) { - switch(get_key()) { - case 2: - if (cpu_mode != CPM_ALL) bail++; - cpu_mode = CPM_ALL; - sflag++; - popdown(); - cprint(9,34,"All"); - popup(); - break; - case 3: - if (cpu_mode != CPM_RROBIN) bail++; - cpu_mode = CPM_RROBIN; - sflag++; - popdown(); - cprint(9,34,"RRb"); - popup(); - break; - case 4: - if (cpu_mode != CPM_SEQ) bail++; - cpu_mode = CPM_SEQ; - sflag++; - popdown(); - cprint(9,34,"Seq"); - popup(); - break; - case 11: - case 57: - /* 0/CR - Continue */ - sflag++; - break; - } - } - popclear(); - break; - case 6: - reprint_screen = 1; - flag++; - break; - case 7: - /* Display DMI Memory Info */ - pop2up(); - print_dmi_info(); - pop2down(); - break; - case 8: - /* Display SPD Data */ - popdown(); - show_spd(); - popup(); - sflag++; - break; - case 11: - case 57: - case 28: - /* 0/CR/SP - Continue */ - flag++; - break; - } - } - popdown(); - if (prt) { - printpatn(); - } - if (reprint_screen){ - tty_print_screen(); - } -} - -void popup() -{ - int i, j; - char *pp; - - for (i=POP_Y; iselected_pages = 0; - for (i=0; i< vv->msegs; i++) { - /* Segment inside limits ? */ - if (vv->pmap[i].start >= vv->plim_lower && - vv->pmap[i].end <= vv->plim_upper) { - vv->selected_pages += (vv->pmap[i].end - vv->pmap[i].start); - continue; - } - /* Segment starts below limit? */ - if (vv->pmap[i].start < vv->plim_lower) { - /* Also ends below limit? */ - if (vv->pmap[i].end < vv->plim_lower) { - continue; - } - - /* Ends past upper limit? */ - if (vv->pmap[i].end > vv->plim_upper) { - vv->selected_pages += - vv->plim_upper - vv->plim_lower; - } else { - /* Straddles lower limit */ - vv->selected_pages += - (vv->pmap[i].end - vv->plim_lower); - } - continue; - } - /* Segment ends above limit? */ - if (vv->pmap[i].end > vv->plim_upper) { - /* Also starts above limit? */ - if (vv->pmap[i].start > vv->plim_upper) { - continue; - } - /* Straddles upper limit */ - vv->selected_pages += - (vv->plim_upper - vv->pmap[i].start); - } - } -} diff --git a/memtest86+_old/config.h b/memtest86+_old/config.h deleted file mode 100644 index aa4c9fb..0000000 --- a/memtest86+_old/config.h +++ /dev/null @@ -1,52 +0,0 @@ -/* - * MemTest86+ V5 Specific code (GPL V2.0) - * By Samuel DEMEULEMEESTER, sdemeule@memtest.org - * http://www.canardpc.com - http://www.memtest.org - * ------------------------------------------------ - * config.h - MemTest-86 Version 3.3 - * - * Compile time configuration options - * - * Released under version 2 of the Gnu Public License. - * By Chris Brady - */ - -/* CONSERVATIVE_SMP - If set to 0, SMP will be enabled by default */ -/* Might be enabled in future revision after extensive testing */ -/* In all cases, SMP is disabled by defaut on server platform */ -#define CONSERVATIVE_SMP 1 - -/* BEEP_MODE - Beep on error. Default off, Change to 1 to enable */ -#define BEEP_MODE 0 - -/* BEEP_END_NO_ERROR - Beep at end of each pass without error. Default off, Change to 1 to enable */ -#define BEEP_END_NO_ERROR 0 - -/* PARITY_MEM - Enables support for reporting memory parity errors */ -/* Experimental, normally enabled */ -#define PARITY_MEM - -/* SERIAL_CONSOLE_DEFAULT - The default state of the serial console. */ -/* This is normally off since it slows down testing. Change to a 1 */ -/* to enable. */ -#define SERIAL_CONSOLE_DEFAULT 0 - -/* SERIAL_TTY - The default serial port to use. 0=ttyS0, 1=ttyS1 */ -#define SERIAL_TTY 0 - -/* SERIAL_BAUD_RATE - Baud rate for the serial console */ -#define SERIAL_BAUD_RATE 9600 - -/* SCRN_DEBUG - extra check for SCREEN_BUFFER - */ -/* #define SCRN_DEBUG */ - -/* APM - Turns off APM at boot time to avoid blanking the screen */ -/* Normally enabled */ -#define APM_OFF - -/* USB_WAR - Enables a workaround for errors caused by BIOS USB keyboard */ -/* and mouse support*/ -/* Normally enabled */ -#define USB_WAR - diff --git a/memtest86+_old/controller.c b/memtest86+_old/controller.c deleted file mode 100644 index 6d3f202..0000000 --- a/memtest86+_old/controller.c +++ /dev/null @@ -1,4155 +0,0 @@ -/* - * MemTest86+ V5 Specific code (GPL V2.0) - * By Samuel DEMEULEMEESTER, sdemeule@memtest.org - * http://www.canardpc.com - http://www.memtest.org - */ - -//#include "defs.h" -#include "config.h" -//#include "test.h" -#include "pci.h" -#include "controller.h" -#include "spd.h" -#include "test.h" -#include "stdint.h" -#include "cpuid.h" -#include "msr.h" -#include "dmi.h" - -int col, col2; -int nhm_bus = 0x3F; - -extern ulong extclock; -extern unsigned long imc_type; -extern struct cpu_ident cpu_id; -/* - #define rdmsr(msr,val1,val2) \ - __asm__ __volatile__("rdmsr" \ - : "=a" (val1), "=d" (val2) \ - : "c" (msr) : "edi") - - #define wrmsr(msr,val1,val2) \ - __asm__ __volatile__("wrmsr" \ - : \ - : "c" (msr), "a" (val1), "d" (val2) : "edi") -*/ -/* controller ECC capabilities and mode */ -#define __ECC_UNEXPECTED 1 /* Unknown ECC capability present */ -#define __ECC_DETECT 2 /* Can detect ECC errors */ -#define __ECC_CORRECT 4 /* Can correct some ECC errors */ -#define __ECC_SCRUB 8 /* Can scrub corrected ECC errors */ -#define __ECC_CHIPKILL 16 /* Can corrected multi-errors */ - -#define ECC_UNKNOWN (~0UL) /* Unknown error correcting ability/status */ -#define ECC_NONE 0 /* Doesnt support ECC (or is BIOS disabled) */ -#define ECC_RESERVED __ECC_UNEXPECTED /* Reserved ECC type */ -#define ECC_DETECT __ECC_DETECT -#define ECC_CORRECT (__ECC_DETECT | __ECC_CORRECT) -#define ECC_CHIPKILL (__ECC_DETECT | __ECC_CORRECT | __ECC_CHIPKILL) -#define ECC_SCRUB (__ECC_DETECT | __ECC_CORRECT | __ECC_SCRUB) - - -static struct ecc_info { - int index; - int poll; - unsigned bus; - unsigned dev; - unsigned fn; - unsigned cap; - unsigned mode; -} ctrl = - { - .index = 0, - /* I know of no case where the memory controller is not on the - * host bridge, and the host bridge is not on bus 0 device 0 - * fn 0. But just in case leave these as variables. - */ - .bus = 0, - .dev = 0, - .fn = 0, - /* Properties of the current memory controller */ - .cap = ECC_UNKNOWN, - .mode = ECC_UNKNOWN, - }; - - -void coretemp(void) -{ - unsigned int msrl, msrh; - unsigned int tjunc, tabs, tnow; - unsigned long rtcr; - double amd_raw_temp; - - // Only enable coretemp if IMC is known - if(imc_type == 0) { return; } - - tnow = 0; - - // Intel CPU - if(cpu_id.vend_id.char_array[0] == 'G' && cpu_id.max_cpuid >= 6) - { - if(cpu_id.dts_pmp & 1){ - rdmsr(MSR_IA32_THERM_STATUS, msrl, msrh); - tabs = ((msrl >> 16) & 0x7F); - rdmsr(MSR_IA32_TEMPERATURE_TARGET, msrl, msrh); - tjunc = ((msrl >> 16) & 0x7F); - if(tjunc < 50 || tjunc > 125) { tjunc = 90; } // assume Tjunc = 90°C if boggus value received. - tnow = tjunc - tabs; - dprint(LINE_CPU+1, 30, vv->check_temp, 3, 0); - vv->check_temp = tnow; - } - return; - } - - // AMD CPU - if(cpu_id.vend_id.char_array[0] == 'A' && cpu_id.vers.bits.extendedFamily > 0) - { - pci_conf_read(0, 24, 3, 0xA4, 4, &rtcr); - amd_raw_temp = ((rtcr >> 21) & 0x7FF); - vv->check_temp = (int)(amd_raw_temp / 8); - dprint(LINE_CPU+1, 30, vv->check_temp, 3, 0); - } - - -} - -void print_cpu_line(float dram_freq, float fsb_freq, int ram_type) -{ - int cur_col = COL_SPEC; - - cprint(LINE_CPU, cur_col, "RAM: "); - cur_col += 5; - dprint(LINE_CPU, cur_col, dram_freq, 4, 1); - cur_col += 4; - cprint(LINE_CPU, cur_col, "MHz ("); - cur_col += 5; - - switch(ram_type) - { - default: - case 1: - cprint(LINE_CPU, cur_col, "DDR-"); - cur_col += 4; - break; - case 2: - cprint(LINE_CPU, cur_col, "DDR2-"); - cur_col += 5; - break; - case 3: - cprint(LINE_CPU, cur_col, "DDR3-"); - cur_col += 5; - break; - } - - if(dram_freq < 500) - { - dprint(LINE_CPU, cur_col, dram_freq*2, 3, 0); - cur_col += 3; - } else { - dprint(LINE_CPU, cur_col, dram_freq*2, 4, 0); - cur_col += 4; - } - cprint(LINE_CPU, cur_col, ")"); - cur_col++; - - if(fsb_freq > 10) - { - cprint(LINE_CPU, cur_col, " - BCLK: "); - cur_col += 9; - - dprint(LINE_CPU, cur_col, fsb_freq, 3, 0); - } - -} - -void print_ram_line(float cas, int rcd, int rp, int ras, int chan) -{ - int cur_col = COL_SPEC; - - cprint(LINE_RAM, cur_col, "Timings: CAS "); - cur_col += 13; - - // CAS Latency (tCAS) - if (cas == 1.5) { - cprint(LINE_RAM, cur_col, "1.5"); cur_col += 3; - } else if (cas == 2.5) { - cprint(LINE_RAM, cur_col, "2.5"); cur_col += 3; - } else if (cas < 10) { - dprint(LINE_RAM, cur_col, cas, 1, 0); cur_col += 1; - } else { - dprint(LINE_RAM, cur_col, cas, 2, 0); cur_col += 2; - } - cprint(LINE_RAM, cur_col, "-"); cur_col += 1; - - // RAS-To-CAS (tRCD) - if (rcd < 10) { - dprint(LINE_RAM, cur_col, rcd, 1, 0); - cur_col += 1; - } else { - dprint(LINE_RAM, cur_col, rcd, 2, 0); - cur_col += 2; - } - cprint(LINE_RAM, cur_col, "-"); cur_col += 1; - - // RAS Precharge (tRP) - if (rp < 10) { - dprint(LINE_RAM, cur_col, rp, 1, 0); - cur_col += 1; - } else { - dprint(LINE_RAM, cur_col, rp, 2, 0); - cur_col += 2; - } - cprint(LINE_RAM, cur_col, "-"); cur_col += 1; - - // RAS Active to precharge (tRAS) - if (ras < 10) { - dprint(LINE_RAM, cur_col, ras, 1, 0); - cur_col += 1; - } else { - dprint(LINE_RAM, cur_col, ras, 2, 0); - cur_col += 2; - } - - - switch(chan) - { - case 0: - break; - case 1: - cprint(LINE_RAM, cur_col, " @ 64-bit Mode"); - break; - case 2: - cprint(LINE_RAM, cur_col, " @ 128-bit Mode"); - break; - case 3: - cprint(LINE_RAM, cur_col, " @ 192-bit Mode"); - break; - case 4: - cprint(LINE_RAM, cur_col, " @ 256-bit Mode"); - break; - } -} - -static void poll_fsb_nothing(void) -{ - - char *name; - - /* Print the controller name */ - name = controllers[ctrl.index].name; - cprint(LINE_CPU, COL_SPEC, "Chipset: "); - cprint(LINE_CPU, COL_SPEC+9, name); - return; -} - -static void poll_timings_nothing(void) -{ - char *ram_type; - - /* Print the controller name */ - ram_type = controllers[ctrl.index].ram_type; - cprint(LINE_RAM, COL_SPEC, "RAM Type: "); - cprint(LINE_RAM, COL_SPEC+10, ram_type); - return; -} - -static void setup_nothing(void) -{ - ctrl.cap = ECC_NONE; - ctrl.mode = ECC_NONE; -} - -static void poll_nothing(void) -{ - /* Code to run when we don't know how, or can't ask the memory - * controller about memory errors. - */ - return; -} - -static void setup_wmr(void) -{ - ulong dev0; - - // Activate MMR I/O - pci_conf_read( 0, 0, 0, 0x48, 4, &dev0); - if (!(dev0 & 0x1)) { - pci_conf_write( 0, 0, 0, 0x48, 1, dev0 | 1); - } - -} - - -static void setup_nhm(void) -{ - static float possible_nhm_bus[] = {0xFF, 0x7F, 0x3F}; - unsigned long did, vid, mc_control, mc_ssrcontrol; - int i; - - //Nehalem supports Scrubbing */ - ctrl.cap = ECC_SCRUB; - ctrl.mode = ECC_NONE; - - /* First, locate the PCI bus where the MCH is located */ - - for(i = 0; i < (sizeof(possible_nhm_bus) / - sizeof(possible_nhm_bus[0])); i++) { - pci_conf_read( possible_nhm_bus[i], 3, 4, 0x00, 2, &vid); - pci_conf_read( possible_nhm_bus[i], 3, 4, 0x02, 2, &did); - vid &= 0xFFFF; - did &= 0xFF00; - if(vid == 0x8086 && did >= 0x2C00) { - nhm_bus = possible_nhm_bus[i]; - } - } - - /* Now, we have the last IMC bus number in nhm_bus */ - /* Check for ECC & Scrub */ - - pci_conf_read(nhm_bus, 3, 0, 0x4C, 2, &mc_control); - if((mc_control >> 4) & 1) { - ctrl.mode = ECC_CORRECT; - pci_conf_read(nhm_bus, 3, 2, 0x48, 2, &mc_ssrcontrol); - if(mc_ssrcontrol & 3) { - ctrl.mode = ECC_SCRUB; - } - } - -} - -static void setup_nhm32(void) -{ - static float possible_nhm_bus[] = {0xFF, 0x7F, 0x3F}; - unsigned long did, vid, mc_control, mc_ssrcontrol; - int i; - - //Nehalem supports Scrubbing */ - ctrl.cap = ECC_SCRUB; - ctrl.mode = ECC_NONE; - - /* First, locate the PCI bus where the MCH is located */ - for(i = 0; i < (sizeof(possible_nhm_bus) / - sizeof(possible_nhm_bus[0])); i++) { - pci_conf_read( possible_nhm_bus[i], 3, 4, 0x00, 2, &vid); - pci_conf_read( possible_nhm_bus[i], 3, 4, 0x02, 2, &did); - vid &= 0xFFFF; - did &= 0xFF00; - if(vid == 0x8086 && did >= 0x2C00) { - nhm_bus = possible_nhm_bus[i]; - } - } - - /* Now, we have the last IMC bus number in nhm_bus */ - /* Check for ECC & Scrub */ - pci_conf_read(nhm_bus, 3, 0, 0x48, 2, &mc_control); - if((mc_control >> 1) & 1) { - ctrl.mode = ECC_CORRECT; - pci_conf_read(nhm_bus, 3, 2, 0x48, 2, &mc_ssrcontrol); - if(mc_ssrcontrol & 1) { - ctrl.mode = ECC_SCRUB; - } - } - -} - -static void setup_amd64(void) -{ - static const int ddim[] = { ECC_NONE, ECC_CORRECT, ECC_RESERVED, ECC_CHIPKILL }; - unsigned long nbxcfg; - unsigned int mcgsrl; - unsigned int mcgsth; - unsigned long mcanb; - unsigned long dramcl; - - /* All AMD64 support Chipkill */ - ctrl.cap = ECC_CHIPKILL; - - /* Check First if ECC DRAM Modules are used */ - pci_conf_read(0, 24, 2, 0x90, 4, &dramcl); - - if (cpu_id.vers.bits.extendedModel >= 4) { - /* NEW K8 0Fh Family 90 nm */ - - if ((dramcl >> 19)&1){ - /* Fill in the correct memory capabilites */ - pci_conf_read(0, 24, 3, 0x44, 4, &nbxcfg); - ctrl.mode = ddim[(nbxcfg >> 22)&3]; - } else { - ctrl.mode = ECC_NONE; - } - /* Enable NB ECC Logging by MSR Write */ - rdmsr(0x017B, mcgsrl, mcgsth); - wrmsr(0x017B, 0x10, mcgsth); - - /* Clear any previous error */ - pci_conf_read(0, 24, 3, 0x4C, 4, &mcanb); - pci_conf_write(0, 24, 3, 0x4C, 4, mcanb & 0x7FFFFFFF ); - - } else { - /* OLD K8 130 nm */ - - if ((dramcl >> 17)&1){ - /* Fill in the correct memory capabilites */ - pci_conf_read(0, 24, 3, 0x44, 4, &nbxcfg); - ctrl.mode = ddim[(nbxcfg >> 22)&3]; - } else { - ctrl.mode = ECC_NONE; - } - /* Enable NB ECC Logging by MSR Write */ - rdmsr(0x017B, mcgsrl, mcgsth); - wrmsr(0x017B, 0x10, mcgsth); - - /* Clear any previous error */ - pci_conf_read(0, 24, 3, 0x4C, 4, &mcanb); - pci_conf_write(0, 24, 3, 0x4C, 4, mcanb & 0x7F801EFC ); - } -} - -static void setup_k10(void) -{ - static const int ddim[] = { ECC_NONE, ECC_CORRECT, ECC_CHIPKILL, ECC_CHIPKILL }; - unsigned long nbxcfg; - unsigned int mcgsrl; - unsigned int mcgsth; - unsigned long mcanb; - unsigned long dramcl; - ulong msr_low, msr_high; - - // All AMD64 support Chipkill */ - ctrl.cap = ECC_CHIPKILL; - - // Check First if ECC DRAM Modules are used */ - pci_conf_read(0, 24, 2, 0x90, 4, &dramcl); - - if ((dramcl >> 19)&1){ - // Fill in the correct memory capabilites */ - pci_conf_read(0, 24, 3, 0x44, 4, &nbxcfg); - ctrl.mode = ddim[(nbxcfg >> 22)&3]; - } else { - ctrl.mode = ECC_NONE; - } - // Enable NB ECC Logging by MSR Write */ - rdmsr(0x017B, mcgsrl, mcgsth); - wrmsr(0x017B, 0x10, mcgsth); - - // Clear any previous error */ - pci_conf_read(0, 24, 3, 0x4C, 4, &mcanb); - pci_conf_write(0, 24, 3, 0x4C, 4, mcanb & 0x7FFFFFFF ); - - /* Enable ECS */ - rdmsr(0xC001001F, msr_low, msr_high); - wrmsr(0xC001001F, msr_low, (msr_high | 0x4000)); - rdmsr(0xC001001F, msr_low, msr_high); - -} - -static void setup_apu(void) -{ - - ulong msr_low, msr_high; - - /* Enable ECS */ - rdmsr(0xC001001F, msr_low, msr_high); - wrmsr(0xC001001F, msr_low, (msr_high | 0x4000)); - rdmsr(0xC001001F, msr_low, msr_high); - -} - -/* - static void poll_amd64(void) - { - - unsigned long mcanb; - unsigned long page, offset; - unsigned long celog_syndrome; - unsigned long mcanb_add; - - pci_conf_read(0, 24, 3, 0x4C, 4, &mcanb); - - if (((mcanb >> 31)&1) && ((mcanb >> 14)&1)) { - // Find out about the first correctable error - // Syndrome code -> bits use a complex matrix. Will add this later - // Read the error location - pci_conf_read(0, 24, 3, 0x50, 4, &mcanb_add); - - // Read the syndrome - celog_syndrome = (mcanb >> 15)&0xFF; - - // Parse the error location - page = (mcanb_add >> 12); - offset = (mcanb_add >> 3) & 0xFFF; - - // Report the error - print_ecc_err(page, offset, 1, celog_syndrome, 0); - - // Clear the error registers - pci_conf_write(0, 24, 3, 0x4C, 4, mcanb & 0x7FFFFFFF ); - } - if (((mcanb >> 31)&1) && ((mcanb >> 13)&1)) { - // Found out about the first uncorrectable error - // Read the error location - pci_conf_read(0, 24, 3, 0x50, 4, &mcanb_add); - - // Parse the error location - page = (mcanb_add >> 12); - offset = (mcanb_add >> 3) & 0xFFF; - - // Report the error - print_ecc_err(page, offset, 0, 0, 0); - - // Clear the error registers - pci_conf_write(0, 24, 3, 0x4C, 4, mcanb & 0x7FFFFFF ); - - } - - } -*/ - -static void setup_amd751(void) -{ - unsigned long dram_status; - - /* Fill in the correct memory capabilites */ - pci_conf_read(ctrl.bus, ctrl.dev, ctrl.fn, 0x5a, 2, &dram_status); - ctrl.cap = ECC_CORRECT; - ctrl.mode = (dram_status & (1 << 2))?ECC_CORRECT: ECC_NONE; -} - -/* - static void poll_amd751(void) - { - unsigned long ecc_status; - unsigned long bank_addr; - unsigned long bank_info; - unsigned long page; - int bits; - int i; - - // Read the error status - pci_conf_read(ctrl.bus, ctrl.dev, ctrl.fn, 0x58, 2, &ecc_status); - if (ecc_status & (3 << 8)) { - for(i = 0; i < 6; i++) { - if (!(ecc_status & (1 << i))) { - continue; - } - // Find the bank the error occured on - bank_addr = 0x40 + (i << 1); - - // Now get the information on the erroring bank - pci_conf_read(ctrl.bus, ctrl.dev, ctrl.fn, bank_addr, 2, &bank_info); - - // Parse the error location and error type - page = (bank_info & 0xFF80) << 4; - bits = (((ecc_status >> 8) &3) == 2)?1:2; - - // Report the error - print_ecc_err(page, 0, bits==1?1:0, 0, 0); - - } - - // Clear the error status - pci_conf_write(ctrl.bus, ctrl.dev, ctrl.fn, 0x58, 2, 0); - } - } - - // Still waiting for the CORRECT intel datasheet - static void setup_i85x(void) - { - unsigned long drc; - ctrl.cap = ECC_CORRECT; - - pci_conf_read(ctrl.bus, ctrl.dev, 1, 0x70, 4, &drc); - ctrl.mode = ((drc>>20)&1)?ECC_CORRECT:ECC_NONE; - - } -*/ - -static void setup_amd76x(void) -{ - static const int ddim[] = { ECC_NONE, ECC_DETECT, ECC_CORRECT, ECC_CORRECT }; - unsigned long ecc_mode_status; - - /* Fill in the correct memory capabilites */ - pci_conf_read(ctrl.bus, ctrl.dev, ctrl.fn, 0x48, 4, &ecc_mode_status); - ctrl.cap = ECC_CORRECT; - ctrl.mode = ddim[(ecc_mode_status >> 10)&3]; -} - -/* - static void poll_amd76x(void) - { - unsigned long ecc_mode_status; - unsigned long bank_addr; - unsigned long bank_info; - unsigned long page; - - // Read the error status - pci_conf_read(ctrl.bus, ctrl.dev, ctrl.fn, 0x48, 4, &ecc_mode_status); - // Multibit error - if (ecc_mode_status & (1 << 9)) { - // Find the bank the error occured on - bank_addr = 0xC0 + (((ecc_mode_status >> 4) & 0xf) << 2); - - // Now get the information on the erroring bank - pci_conf_read(ctrl.bus, ctrl.dev, ctrl.fn, bank_addr, 4, &bank_info); - - // Parse the error location and error type - page = (bank_info & 0xFF800000) >> 12; - - // Report the error - print_ecc_err(page, 0, 1, 0, 0); - - } - // Singlebit error - if (ecc_mode_status & (1 << 8)) { - // Find the bank the error occured on - bank_addr = 0xC0 + (((ecc_mode_status >> 0) & 0xf) << 2); - - // Now get the information on the erroring bank - pci_conf_read(ctrl.bus, ctrl.dev, ctrl.fn, bank_addr, 4, &bank_info); - - // Parse the error location and error type - page = (bank_info & 0xFF800000) >> 12; - - // Report the error - print_ecc_err(page, 0, 0, 0, 0); - - } - // Clear the error status - if (ecc_mode_status & (3 << 8)) { - pci_conf_write(ctrl.bus, ctrl.dev, ctrl.fn, 0x48, 4, ecc_mode_status); - } - } -*/ - -static void setup_cnb20(void) -{ - /* Fill in the correct memory capabilites */ - ctrl.cap = ECC_CORRECT; - - /* FIXME add ECC error polling. I don't have the documentation - * do it right now. - */ -} - -static void setup_E5400(void) -{ - unsigned long mcs; - - - /* Read the hardware capabilities */ - pci_conf_read(ctrl.bus, 16, 1, 0x40, 4, &mcs); - - /* Fill in the correct memory capabilities */ - ctrl.mode = 0; - ctrl.cap = ECC_SCRUB; - - /* Checking and correcting enabled */ - if (((mcs >> 5) & 1) == 1) { - ctrl.mode |= ECC_CORRECT; - } - - /* scrub enabled */ - if (((mcs >> 7) & 1) == 1) { - ctrl.mode |= __ECC_SCRUB; - } -} - - -static void setup_iE7xxx(void) -{ - unsigned long mchcfgns; - unsigned long drc; - unsigned long device; - unsigned long dvnp; - - /* Read the hardare capabilities */ - pci_conf_read(ctrl.bus, ctrl.dev, ctrl.fn, 0x52, 2, &mchcfgns); - pci_conf_read(ctrl.bus, ctrl.dev, ctrl.fn, 0x7C, 4, &drc); - - /* This is a check for E7205 */ - pci_conf_read(ctrl.bus, ctrl.dev, ctrl.fn, 0x02, 2, &device); - - /* Fill in the correct memory capabilities */ - ctrl.mode = 0; - ctrl.cap = ECC_CORRECT; - - /* checking and correcting enabled */ - if (((drc >> 20) & 3) == 2) { - ctrl.mode |= ECC_CORRECT; - } - - /* E7205 doesn't support scrubbing */ - if (device != 0x255d) { - /* scrub enabled */ - /* For E7501, valid SCRUB operations is bit 0 / D0:F0:R70-73 */ - ctrl.cap = ECC_SCRUB; - if (mchcfgns & 1) { - ctrl.mode |= __ECC_SCRUB; - } - - /* Now, we can active Dev1/Fun1 */ - /* Thanks to Tyan for providing us the board to solve this */ - pci_conf_read(ctrl.bus, ctrl.dev, ctrl.fn, 0xE0, 2, &dvnp); - pci_conf_write(ctrl.bus, ctrl.dev, ctrl.fn , 0xE0, 2, (dvnp & 0xFE)); - - /* Clear any routing of ECC errors to interrupts that the BIOS might have set up */ - pci_conf_write(ctrl.bus, ctrl.dev, ctrl.fn +1, 0x88, 1, 0x0); - pci_conf_write(ctrl.bus, ctrl.dev, ctrl.fn +1, 0x8A, 1, 0x0); - pci_conf_write(ctrl.bus, ctrl.dev, ctrl.fn +1, 0x8C, 1, 0x0); - - - } - - /* Clear any prexisting error reports */ - pci_conf_write(ctrl.bus, ctrl.dev, ctrl.fn +1, 0x80, 1, 3); - pci_conf_write(ctrl.bus, ctrl.dev, ctrl.fn +1, 0x82, 1, 3); - - -} - -static void setup_iE7520(void) -{ - unsigned long mchscrb; - unsigned long drc; - unsigned long dvnp1; - - /* Read the hardare capabilities */ - pci_conf_read(ctrl.bus, ctrl.dev, ctrl.fn, 0x52, 2, &mchscrb); - pci_conf_read(ctrl.bus, ctrl.dev, ctrl.fn, 0x7C, 4, &drc); - - /* Fill in the correct memory capabilities */ - ctrl.mode = 0; - ctrl.cap = ECC_CORRECT; - - /* Checking and correcting enabled */ - if (((drc >> 20) & 3) != 0) { - ctrl.mode |= ECC_CORRECT; - } - - /* scrub enabled */ - ctrl.cap = ECC_SCRUB; - if ((mchscrb & 3) == 2) { - ctrl.mode |= __ECC_SCRUB; - } - - /* Now, we can activate Fun1 */ - pci_conf_read(ctrl.bus, ctrl.dev, ctrl.fn, 0xF4, 1, &dvnp1); - pci_conf_write(ctrl.bus, ctrl.dev, ctrl.fn , 0xF4, 1, (dvnp1 | 0x20)); - - /* Clear any prexisting error reports */ - pci_conf_write(ctrl.bus, ctrl.dev, ctrl.fn +1, 0x80, 2, 0x4747); - pci_conf_write(ctrl.bus, ctrl.dev, ctrl.fn +1, 0x82, 2, 0x4747); - -} - -/* - static void poll_iE7xxx(void) - { - unsigned long ferr; - unsigned long nerr; - - pci_conf_read(ctrl.bus, ctrl.dev, ctrl.fn +1, 0x80, 1, &ferr); - pci_conf_read(ctrl.bus, ctrl.dev, ctrl.fn +1, 0x82, 1, &nerr); - - if (ferr & 1) { - // Find out about the first correctable error - unsigned long celog_add; - unsigned long celog_syndrome; - unsigned long page; - - // Read the error location - pci_conf_read(ctrl.bus, ctrl.dev, ctrl.fn +1, 0xA0, 4, &celog_add); - // Read the syndrome - pci_conf_read(ctrl.bus, ctrl.dev, ctrl.fn +1, 0xD0, 2, &celog_syndrome); - - // Parse the error location - page = (celog_add & 0x0FFFFFC0) >> 6; - - // Report the error - print_ecc_err(page, 0, 1, celog_syndrome, 0); - - // Clear Bit - pci_conf_write(ctrl.bus, ctrl.dev, ctrl.fn +1, 0x80, 1, ferr & 3); - } - - if (ferr & 2) { - // Found out about the first uncorrectable error - unsigned long uccelog_add; - unsigned long page; - - // Read the error location - pci_conf_read(ctrl.bus, ctrl.dev, ctrl.fn +1, 0xB0, 4, &uccelog_add); - - // Parse the error location - page = (uccelog_add & 0x0FFFFFC0) >> 6; - - // Report the error - print_ecc_err(page, 0, 0, 0, 0); - - // Clear Bit - pci_conf_write(ctrl.bus, ctrl.dev, ctrl.fn +1, 0x80, 1, ferr & 3); - } - - // Check if DRAM_NERR contains data - if (nerr & 3) { - pci_conf_write(ctrl.bus, ctrl.dev, ctrl.fn +1, 0x82, 1, nerr & 3); - } - - } -*/ - -static void setup_i440gx(void) -{ - static const int ddim[] = { ECC_NONE, ECC_DETECT, ECC_CORRECT, ECC_CORRECT }; - unsigned long nbxcfg; - - /* Fill in the correct memory capabilites */ - pci_conf_read(ctrl.bus, ctrl.dev, ctrl.fn, 0x50, 4, &nbxcfg); - ctrl.cap = ECC_CORRECT; - ctrl.mode = ddim[(nbxcfg >> 7)&3]; -} - -/* - static void poll_i440gx(void) - { - unsigned long errsts; - unsigned long page; - int bits; - // Read the error status - pci_conf_read(ctrl.bus, ctrl.dev, ctrl.fn, 0x91, 2, &errsts); - if (errsts & 0x11) { - unsigned long eap; - // Read the error location - pci_conf_read(ctrl.bus, ctrl.dev, ctrl.fn, 0x80, 4, &eap); - - // Parse the error location and error type - page = (eap & 0xFFFFF000) >> 12; - bits = 0; - if (eap &3) { - bits = ((eap & 3) == 1)?1:2; - } - - if (bits) { - // Report the error - print_ecc_err(page, 0, bits==1?1:0, 0, 0); - } - - // Clear the error status - pci_conf_write(ctrl.bus, ctrl.dev, ctrl.fn, 0x91, 2, 0x11); - pci_conf_write(ctrl.bus, ctrl.dev, ctrl.fn, 0x80, 4, 3); - } - - } -*/ - - -static void setup_i840(void) -{ - static const int ddim[] = { ECC_NONE, ECC_RESERVED, ECC_CORRECT, ECC_CORRECT }; - unsigned long mchcfg; - - /* Fill in the correct memory capabilites */ - pci_conf_read(ctrl.bus, ctrl.dev, ctrl.fn, 0x50, 2, &mchcfg); - ctrl.cap = ECC_CORRECT; - ctrl.mode = ddim[(mchcfg >> 7)&3]; -} - -/* - static void poll_i840(void) - { - unsigned long errsts; - unsigned long page; - unsigned long syndrome; - int channel; - int bits; - // Read the error status - pci_conf_read(ctrl.bus, ctrl.dev, ctrl.fn, 0xC8, 2, &errsts); - if (errsts & 3) { - unsigned long eap; - unsigned long derrctl_sts; - // Read the error location - pci_conf_read(ctrl.bus, ctrl.dev, ctrl.fn, 0xE4, 4, &eap); - pci_conf_read(ctrl.bus, ctrl.dev, ctrl.fn, 0xE2, 2, &derrctl_sts); - - // Parse the error location and error type - page = (eap & 0xFFFFF800) >> 11; - channel = eap & 1; - syndrome = derrctl_sts & 0xFF; - bits = ((errsts & 3) == 1)?1:2; - - // Report the error - print_ecc_err(page, 0, bits==1?1:0, syndrome, channel); - - // Clear the error status - pci_conf_write(ctrl.bus, ctrl.dev, ctrl.fn, 0xE2, 2, 3 << 10); - pci_conf_write(ctrl.bus, ctrl.dev, ctrl.fn, 0xC8, 2, 3); - } - } -*/ - - -static void setup_i875(void) -{ - - long *ptr; - ulong dev0, dev6 ; - - /* Fill in the correct memory capabilites */ - - ctrl.cap = ECC_CORRECT; - ctrl.mode = ECC_NONE; - - /* From my article : http://www.x86-secret.com/articles/tweak/pat/patsecrets-2.htm */ - /* Activate Device 6 */ - pci_conf_read( 0, 0, 0, 0xF4, 1, &dev0); - pci_conf_write( 0, 0, 0, 0xF4, 1, (dev0 | 0x2)); - - /* Activate Device 6 MMR */ - pci_conf_read( 0, 6, 0, 0x04, 2, &dev6); - pci_conf_write( 0, 6, 0, 0x04, 2, (dev6 | 0x2)); - - /* Read the MMR Base Address & Define the pointer*/ - pci_conf_read( 0, 6, 0, 0x10, 4, &dev6); - ptr=(long*)(dev6+0x68); - - if (((*ptr >> 18)&1) == 1) { ctrl.mode = ECC_CORRECT; } - - /* Reseting state */ - pci_conf_write(ctrl.bus, ctrl.dev, ctrl.fn, 0xC8, 2, 0x81); -} - -static void setup_i925(void) -{ - - // Activate MMR I/O - ulong dev0, drc; - unsigned long tolm; - long *ptr; - - pci_conf_read( 0, 0, 0, 0x54, 4, &dev0); - dev0 = dev0 | 0x10000000; - pci_conf_write( 0, 0, 0, 0x54, 4, dev0); - - // CDH start - pci_conf_read( 0, 0, 0, 0x44, 4, &dev0); - if (!(dev0 & 0xFFFFC000)) { - pci_conf_read( 0, 0, 0, 0x9C, 1, &tolm); - pci_conf_write( 0, 0, 0, 0x47, 1, tolm & 0xF8); - } - // CDH end - - // ECC Checking - ctrl.cap = ECC_CORRECT; - - dev0 &= 0xFFFFC000; - ptr=(long*)(dev0+0x120); - drc = *ptr & 0xFFFFFFFF; - - if (((drc >> 20) & 3) == 2) { - pci_conf_write(ctrl.bus, ctrl.dev, ctrl.fn, 0xC8, 2, 3); - ctrl.mode = ECC_CORRECT; - } else { - ctrl.mode = ECC_NONE; - } - -} - -static void setup_p35(void) -{ - - // Activate MMR I/O - ulong dev0, capid0; - - pci_conf_read( 0, 0, 0, 0x48, 4, &dev0); - if (!(dev0 & 0x1)) { - pci_conf_write( 0, 0, 0, 0x48, 1, dev0 | 1); - } - - // ECC Checking (No poll on X38/48 for now) - pci_conf_read( 0, 0, 0, 0xE4, 4, &capid0); - if ((capid0 >> 8) & 1) { - ctrl.cap = ECC_NONE; - } else { - ctrl.cap = ECC_CORRECT; - } - - ctrl.mode = ECC_NONE; - - /* - ulong toto; - pci_conf_write(0, 31, 3, 0x40, 1, 0x1); - pci_conf_read(0, 31, 3, 0x0, 4, &toto); - hprint(11,0,toto); - pci_conf_read(0, 31, 3, 0x10, 4, &toto); - hprint(11,10,toto) ; - pci_conf_read(0, 31, 3, 0x20, 4, &toto); - hprint(11,20,toto) ; - pci_conf_read(0, 28, 0, 0x0, 4, &toto); - hprint(11,30,toto); - pci_conf_read(0, 31, 0, 0x0, 4, &toto); - hprint(11,40,toto) ; - pci_conf_read(0, 31, 1, 0x0, 4, &toto); - hprint(11,50,toto) ; - pci_conf_read(0, 31, 2, 0x0, 4, &toto); - hprint(11,60,toto) ; - */ -} - -/* - static void poll_i875(void) - { - unsigned long errsts; - unsigned long page; - unsigned long des; - unsigned long syndrome; - int channel; - int bits; - // Read the error status - pci_conf_read(ctrl.bus, ctrl.dev, ctrl.fn, 0xC8, 2, &errsts); - if (errsts & 0x81) { - unsigned long eap; - unsigned long derrsyn; - // Read the error location, syndrome and channel - pci_conf_read(ctrl.bus, ctrl.dev, ctrl.fn, 0x58, 4, &eap); - pci_conf_read(ctrl.bus, ctrl.dev, ctrl.fn, 0x5C, 1, &derrsyn); - pci_conf_read(ctrl.bus, ctrl.dev, ctrl.fn, 0x5D, 1, &des); - - // Parse the error location and error type - page = (eap & 0xFFFFF000) >> 12; - syndrome = derrsyn; - channel = des & 1; - bits = (errsts & 0x80)?0:1; - - // Report the error - print_ecc_err(page, 0, bits, syndrome, channel); - - // Clear the error status - pci_conf_write(ctrl.bus, ctrl.dev, ctrl.fn, 0xC8, 2, 0x81); - } - } -*/ - -static void setup_i845(void) -{ - static const int ddim[] = { ECC_NONE, ECC_RESERVED, ECC_CORRECT, ECC_RESERVED }; - unsigned long drc; - - // Fill in the correct memory capabilites - pci_conf_read(ctrl.bus, ctrl.dev, ctrl.fn, 0x7C, 4, &drc); - ctrl.cap = ECC_CORRECT; - ctrl.mode = ddim[(drc >> 20)&3]; -} - -/* - static void poll_i845(void) - { - unsigned long errsts; - unsigned long page, offset; - unsigned long syndrome; - int bits; - // Read the error status - pci_conf_read(ctrl.bus, ctrl.dev, ctrl.fn, 0xC8, 2, &errsts); - if (errsts & 3) { - unsigned long eap; - unsigned long derrsyn; - // Read the error location - pci_conf_read(ctrl.bus, ctrl.dev, ctrl.fn, 0x8C, 4, &eap); - pci_conf_read(ctrl.bus, ctrl.dev, ctrl.fn, 0x86, 1, &derrsyn); - - // Parse the error location and error type - offset = (eap & 0xFE) << 4; - page = (eap & 0x3FFFFFFE) >> 8; - syndrome = derrsyn; - bits = ((errsts & 3) == 1)?1:2; - - // Report the error - print_ecc_err(page, offset, bits==1?1:0, syndrome, 0); - - // Clear the error status - pci_conf_write(ctrl.bus, ctrl.dev, ctrl.fn, 0xC8, 2, 3); - } - } -*/ - - -static void setup_i820(void) -{ - static const int ddim[] = { ECC_NONE, ECC_RESERVED, ECC_CORRECT, ECC_CORRECT }; - unsigned long mchcfg; - - // Fill in the correct memory capabilites - pci_conf_read(ctrl.bus, ctrl.dev, ctrl.fn, 0xbe, 2, &mchcfg); - ctrl.cap = ECC_CORRECT; - ctrl.mode = ddim[(mchcfg >> 7)&3]; -} - -/* - static void poll_i820(void) - { - unsigned long errsts; - unsigned long page; - unsigned long syndrome; - int bits; - // Read the error status - pci_conf_read(ctrl.bus, ctrl.dev, ctrl.fn, 0xC8, 2, &errsts); - if (errsts & 3) { - unsigned long eap; - // Read the error location - pci_conf_read(ctrl.bus, ctrl.dev, ctrl.fn, 0xc4, 4, &eap); - - // Parse the error location and error type - page = (eap & 0xFFFFF000) >> 4; - syndrome = eap & 0xFF; - bits = ((errsts & 3) == 1)?1:2; - - // Report the error - print_ecc_err(page, 0, bits==1?1:0, syndrome, 0); - - // Clear the error status - pci_conf_write(ctrl.bus, ctrl.dev, ctrl.fn, 0xC8, 2, 3); - } - } -*/ - -static void setup_i850(void) -{ - static const int ddim[] = { ECC_NONE, ECC_RESERVED, ECC_CORRECT, ECC_RESERVED }; - unsigned long mchcfg; - - // Fill in the correct memory capabilites - pci_conf_read(ctrl.bus, ctrl.dev, ctrl.fn, 0x50, 2, &mchcfg); - ctrl.cap = ECC_CORRECT; - ctrl.mode = ddim[(mchcfg >> 7)&3]; -} - -/* - static void poll_i850(void) - { - unsigned long errsts; - unsigned long page; - unsigned long syndrome; - int channel; - int bits; - // Read the error status - pci_conf_read(ctrl.bus, ctrl.dev, ctrl.fn, 0xC8, 2, &errsts); - if (errsts & 3) { - unsigned long eap; - unsigned long derrctl_sts; - // Read the error location - pci_conf_read(ctrl.bus, ctrl.dev, ctrl.fn, 0xE4, 4, &eap); - pci_conf_read(ctrl.bus, ctrl.dev, ctrl.fn, 0xE2, 2, &derrctl_sts); - - // Parse the error location and error type - page = (eap & 0xFFFFF800) >> 11; - channel = eap & 1; - syndrome = derrctl_sts & 0xFF; - bits = ((errsts & 3) == 1)?1:2; - - // Report the error - print_ecc_err(page, 0, bits==1?1:0, syndrome, channel); - - // Clear the error status - pci_conf_write(ctrl.bus, ctrl.dev, ctrl.fn, 0xC8, 2, errsts & 3); - } - } -*/ - -static void setup_i860(void) -{ - static const int ddim[] = { ECC_NONE, ECC_RESERVED, ECC_CORRECT, ECC_RESERVED }; - unsigned long mchcfg; - unsigned long errsts; - - // Fill in the correct memory capabilites - pci_conf_read(ctrl.bus, ctrl.dev, ctrl.fn, 0x50, 2, &mchcfg); - ctrl.cap = ECC_CORRECT; - ctrl.mode = ddim[(mchcfg >> 7)&3]; - - // Clear any prexisting error reports - pci_conf_read(ctrl.bus, ctrl.dev, ctrl.fn, 0xC8, 2, &errsts); - pci_conf_write(ctrl.bus, ctrl.dev, ctrl.fn, 0xC8, 2, errsts & 3); -} - -/* - static void poll_i860(void) - { - unsigned long errsts; - unsigned long page; - unsigned char syndrome; - int channel; - int bits; - // Read the error status - pci_conf_read(ctrl.bus, ctrl.dev, ctrl.fn, 0xC8, 2, &errsts); - if (errsts & 3) { - unsigned long eap; - unsigned long derrctl_sts; - // Read the error location - pci_conf_read(ctrl.bus, ctrl.dev, ctrl.fn, 0xE4, 4, &eap); - pci_conf_read(ctrl.bus, ctrl.dev, ctrl.fn, 0xE2, 2, &derrctl_sts); - - // Parse the error location and error type - page = (eap & 0xFFFFFE00) >> 9; - channel = eap & 1; - syndrome = derrctl_sts & 0xFF; - bits = ((errsts & 3) == 1)?1:2; - - // Report the error - print_ecc_err(page, 0, bits==1?1:0, syndrome, channel); - - // Clear the error status - pci_conf_write(ctrl.bus, ctrl.dev, ctrl.fn, 0xC8, 2, errsts & 3); - } - } - - - static void poll_iE7221(void) - { - unsigned long errsts; - unsigned long page; - unsigned char syndrome; - int channel; - int bits; - int errocc; - - pci_conf_read(ctrl.bus, ctrl.dev, ctrl.fn, 0xC8, 2, &errsts); - - errocc = errsts & 3; - - if ((errocc == 1) || (errocc == 2)) { - unsigned long eap, offset; - unsigned long derrctl_sts; - - // Read the error location - pci_conf_read(ctrl.bus, ctrl.dev, ctrl.fn, 0x58, 4, &eap); - pci_conf_read(ctrl.bus, ctrl.dev, ctrl.fn, 0x5C, 1, &derrctl_sts); - - // Parse the error location and error type - channel = eap & 1; - eap = eap & 0xFFFFFF80; - page = eap >> 12; - offset = eap & 0xFFF; - syndrome = derrctl_sts & 0xFF; - bits = errocc & 1; - - // Report the error - print_ecc_err(page, offset, bits, syndrome, channel); - - // Clear the error status - pci_conf_write(ctrl.bus, ctrl.dev, ctrl.fn, 0xC8, 2, errsts & 3); - } - - else if (errocc == 3) { - - pci_conf_write(ctrl.bus, ctrl.dev, ctrl.fn, 0xC8, 2, errsts & 3); - - } - } - - - static void poll_iE7520(void) - { - unsigned long ferr; - unsigned long nerr; - - pci_conf_read(ctrl.bus, ctrl.dev, ctrl.fn +1, 0x80, 2, &ferr); - pci_conf_read(ctrl.bus, ctrl.dev, ctrl.fn +1, 0x82, 2, &nerr); - - if (ferr & 0x0101) { - // Find out about the first correctable error - unsigned long celog_add; - unsigned long celog_syndrome; - unsigned long page; - - // Read the error location - pci_conf_read(ctrl.bus, ctrl.dev, ctrl.fn +1, 0xA0, 4,&celog_add); - // Read the syndrome - pci_conf_read(ctrl.bus, ctrl.dev, ctrl.fn +1, 0xC4, 2, &celog_syndrome); - - // Parse the error location - page = (celog_add & 0x7FFFFFFC) >> 2; - - // Report the error - print_ecc_err(page, 0, 1, celog_syndrome, 0); - - // Clear Bit - pci_conf_write(ctrl.bus, ctrl.dev, ctrl.fn +1, 0x80, 2, ferr& 0x0101); - } - - if (ferr & 0x4646) { - // Found out about the first uncorrectable error - unsigned long uccelog_add; - unsigned long page; - - // Read the error location - pci_conf_read(ctrl.bus, ctrl.dev, ctrl.fn +1, 0xA4, 4, &uccelog_add); - - // Parse the error location - page = (uccelog_add & 0x7FFFFFFC) >> 2; - - // Report the error - print_ecc_err(page, 0, 0, 0, 0); - - // Clear Bit - pci_conf_write(ctrl.bus, ctrl.dev, ctrl.fn +1, 0x80, 2, ferr & 0x4646); - } - - // Check if DRAM_NERR contains data - if (nerr & 0x4747) { - pci_conf_write(ctrl.bus, ctrl.dev, ctrl.fn +1, 0x82, 2, nerr & 0x4747); - } - } -*/ - - - -/* ----------------- Here's the code for FSB detection ----------------- */ -/* --------------------------------------------------------------------- */ - -static float athloncoef[] = {11, 11.5, 12.0, 12.5, 5.0, 5.5, 6.0, 6.5, 7.0, 7.5, 8.0, 8.5, 9.0, 9.5, 10.0, 10.5}; -static float athloncoef2[] = {12, 19.0, 12.0, 20.0, 13.0, 13.5, 14.0, 21.0, 15.0, 22, 16.0, 16.5, 17.0, 18.0, 23.0, 24.0}; -static float p4model1ratios[] = {16, 17, 18, 19, 20, 21, 22, 23, 8, 9, 10, 11, 12, 13, 14, 15}; - -static float getP4PMmultiplier(void) -{ - //unsigned int msr_lo, msr_hi; - int msr_lo, msr_hi; - float coef; - - - /* Find multiplier (by MSR) */ - if (cpu_id.vers.bits.family == 6) - { - if(cpu_id.fid.bits.eist & 1) - { - rdmsr(0x198, msr_lo, msr_hi); - coef = ((msr_lo) >> 8) & 0x1F; - if ((msr_lo >> 14) & 0x1) { coef += 0.5f; } - // Atom Fix - if(coef == 6) - { - coef = ((msr_hi) >> 8) & 0x1F; - if ((msr_hi >> 14) & 0x1) { coef += 0.5f; } - } - } else { - rdmsr(0x2A, msr_lo, msr_hi); - coef = (msr_lo >> 22) & 0x1F; - } - } - else - { - if (cpu_id.vers.bits.model < 2) - { - rdmsr(0x2A, msr_lo, msr_hi); - coef = (msr_lo >> 8) & 0xF; - coef = p4model1ratios[(int)coef]; - } - else - { - rdmsr(0x2C, msr_lo, msr_hi); - coef = (msr_lo >> 24) & 0x1F; - } - } - - return coef; -} - -static float getNHMmultiplier(void) -{ - unsigned int msr_lo, msr_hi; - float coef; - - /* Find multiplier (by MSR) */ - /* First, check if Flexible Ratio is Enabled */ - rdmsr(0x194, msr_lo, msr_hi); - if((msr_lo >> 16) & 1){ - coef = (msr_lo >> 8) & 0xFF; - } else { - rdmsr(0xCE, msr_lo, msr_hi); - coef = (msr_lo >> 8) & 0xFF; - } - - return coef; -} -static float getSNBmultiplier(void) -{ - unsigned int msr_lo, msr_hi; - float coef; - - rdmsr(0xCE, msr_lo, msr_hi); - coef = (msr_lo >> 8) & 0xFF; - - return coef; -} - -static void poll_fsb_ct(void) -{ - unsigned long mcr, mdr; - double dramratio, dramclock, fsb; - float coef = getP4PMmultiplier(); - - /* Build the MCR Message*/ - mcr = (0x10 << 24); // 10h = Read - 11h = Write - mcr += (0x01 << 16); // DRAM Registers located on port 01h - mcr += (0x01 << 8); // DRP = 00h, DTR0 = 01h, DTR1 = 02h, DTR2 = 03h - mcr &= 0xFFFFFFF0; // bit 03:00 RSVD - - /* Send Message to GMCH */ - pci_conf_write(0, 0, 0, 0xD0, 4, mcr); - - /* Read Answer from Sideband bus */ - pci_conf_read(0, 0, 0, 0xD4, 4, &mdr); - - /* Get RAM ratio */ - switch (mdr & 0x3) { - default: - case 0: dramratio = 3.0f; break; - case 1: dramratio = 4.0f; break; - case 2: dramratio = 5.0f; break; - case 3: dramratio = 6.0f; break; - } - - // Compute FSB & RAM Frequency - fsb = ((extclock / 1000) / coef); - dramclock = fsb * dramratio; - - // Print'em all. Whoa ! - print_cpu_line(dramclock, fsb, 3); - -} - -static void poll_fsb_amd64(void) { - - unsigned int mcgsrl; - unsigned int mcgsth; - unsigned long fid, temp2; - unsigned long dramchr; - float clockratio; - double dramclock; - unsigned int dummy[3]; - int ram_type; - - float coef = 10; - - cpuid(0x80000007, &dummy[0], &dummy[1], &dummy[2], &dummy[3]); - - /* First, got the FID by MSR */ - /* First look if Cool 'n Quiet is supported to choose the best msr */ - if (((dummy[3] >> 1) & 1) == 1) { - rdmsr(0xc0010042, mcgsrl, mcgsth); - fid = (mcgsrl & 0x3F); - } else { - rdmsr(0xc0010015, mcgsrl, mcgsth); - fid = ((mcgsrl >> 24)& 0x3F); - } - - /* Extreme simplification. */ - coef = ( fid / 2 ) + 4.0; - - /* Support for .5 coef */ - if (fid & 1) { coef = coef + 0.5; } - - /* Next, we need the clock ratio */ - if (cpu_id.vers.bits.extendedModel >= 4) { - /* K8 0FH */ - pci_conf_read(0, 24, 2, 0x94, 4, &dramchr); - temp2 = (dramchr & 0x7); - clockratio = coef; - ram_type = 2; - - switch (temp2) { - case 0x0: - clockratio = (int)(coef); - break; - case 0x1: - clockratio = (int)(coef * 3.0f/4.0f); - break; - case 0x2: - clockratio = (int)(coef * 3.0f/5.0f); - break; - case 0x3: - clockratio = (int)(coef * 3.0f/6.0f); - break; - } - - } else { - /* OLD K8 */ - pci_conf_read(0, 24, 2, 0x94, 4, &dramchr); - temp2 = (dramchr >> 20) & 0x7; - ram_type = 1; - clockratio = coef; - - switch (temp2) { - case 0x0: - clockratio = (int)(coef * 2.0f); - break; - case 0x2: - clockratio = (int)((coef * 3.0f/2.0f) + 0.81f); - break; - case 0x4: - clockratio = (int)((coef * 4.0f/3.0f) + 0.81f); - break; - case 0x5: - clockratio = (int)((coef * 6.0f/5.0f) + 0.81f); - break; - case 0x6: - clockratio = (int)((coef * 10.0f/9.0f) + 0.81f); - break; - case 0x7: - clockratio = (int)(coef + 0.81f); - break; - } - } - - /* Compute the final DRAM Clock */ - dramclock = (extclock / 1000) / clockratio; - - /* ...and print */ - print_cpu_line(dramclock, (extclock / 1000 / coef), ram_type); - -} - -static void poll_fsb_k10(void) { - - unsigned int mcgsrl; - unsigned int mcgsth; - unsigned long temp2; - unsigned long dramchr; - unsigned long mainPllId; - double dramclock; - ulong offset = 0; - int ram_type = 2; - - /* First, we need the clock ratio */ - pci_conf_read(0, 24, 2, 0x94, 4, &dramchr); - temp2 = (dramchr & 0x7); - - switch (temp2) { - case 0x7: temp2++; - case 0x6: temp2++; - case 0x5: temp2++; - case 0x4: temp2++; - default: temp2 += 3; - } - - /* Compute the final DRAM Clock */ - if (((cpu_id.vers.bits.extendedModel >> 4) & 0xFF) == 1) { - dramclock = ((temp2 * 200) / 3.0) + 0.25; - } else { - unsigned long target; - unsigned long dx; - unsigned divisor; - - target = temp2 * 400; - - /* Get the FID by MSR */ - rdmsr(0xc0010071, mcgsrl, mcgsth); - - pci_conf_read(0, 24, 3, 0xD4, 4, &mainPllId); - - if ( mainPllId & 0x40 ) - mainPllId &= 0x3F; - else - mainPllId = 8; /* FID for 1600 */ - - mcgsth = (mcgsth >> 17) & 0x3F; - if ( mcgsth ) { - if ( mainPllId > mcgsth ) - mainPllId = mcgsth; - } - - dx = (mainPllId + 8) * 1200; - for ( divisor = 3; divisor < 100; divisor++ ) - if ( (dx / divisor) <= target ) - break; - - - pci_conf_read(0, 24, 2, 0x94, 4, &dramchr); - - // If Channel A not enabled, switch to channel B - if(((dramchr>>14) & 0x1)) - { - offset = 0x100; - pci_conf_read(0, 24, 2, 0x94+offset, 4, &dramchr); - } - - //DDR2 or DDR3 - if ((dramchr >> 8)&1) { - ram_type = 3; - } else { - ram_type = 2;; - } - - dramclock = ((dx / divisor) / 6.0) + 0.25; - } - - /* ...and print */ - print_cpu_line(dramclock, 0, ram_type); - -} - -static void poll_fsb_k12(void) { - - unsigned long temp2; - unsigned long dramchr; - double dramratio, dramclock, fsb, did; - unsigned int mcgsrl,mcgsth, fid, did_raw; - - // Get current FID & DID - rdmsr(0xc0010071, mcgsrl, mcgsth); - did_raw = mcgsrl & 0xF; - fid = (mcgsrl >> 4) & 0xF; - - switch(did_raw) - { - default: - case 0x0: - did = 1.0f; - break; - case 0x1: - did = 1.5f; - break; - case 0x2: - did = 2.0f; - break; - case 0x3: - did = 3.0f; - break; - case 0x4: - did = 4.0f; - break; - case 0x5: - did = 6.0f; - break; - case 0x6: - did = 8.0f; - break; - case 0x7: - did = 12.0f; - break; - case 0x8: - did = 16.0f; - break; - } - - fsb = ((extclock / 1000.0f) / ((fid + 16.0f) / did)); - - /* Finaly, we need the clock ratio */ - pci_conf_read(0, 24, 2, 0x94, 4, &dramchr); - - if(((dramchr >> 14) & 0x1) == 1) - { - pci_conf_read(0, 24, 2, 0x194, 4, &dramchr); - } - - temp2 = (dramchr & 0x1F); - - switch (temp2) { - default: - case 0x06: - dramratio = 4.0f; - break; - case 0x0A: - dramratio = 16.0f / 3.0f; - break; - case 0x0E: - dramratio = 20.0f / 3.0f; - break; - case 0x12: - dramratio = 8.0f; - break; - case 0x16: - dramratio = 28.0f / 3.0f; - break; - } - - dramclock = fsb * dramratio; - - /* print */ - print_cpu_line(dramclock, fsb, 3); - -} - -static void poll_fsb_k16(void) -{ - - unsigned long dramchr; - double dramratio, dramclock, fsb; - - // FIXME: Unable to find a real way to detect multiplier. - fsb = 100.0f; - - /* Clock ratio */ - pci_conf_read(0, 24, 2, 0x94, 4, &dramchr); - - switch (dramchr & 0x1F) { - default: - case 0x04: /* 333 */ - dramratio = 10.0f / 3.0f; - break; - case 0x06: /* 400 */ - dramratio = 4.0f; - break; - case 0x0A: /* 533 */ - dramratio = 16.0f / 3.0f; - break; - case 0x0E: /* 667 */ - dramratio = 20.0f / 3.0f; - break; - case 0x12: /* 800 */ - dramratio = 8.0f; - break; - case 0x16: /* 933 */ - dramratio = 28.0f / 3.0f; - break; - case 0x19: /* 1050 */ - dramratio = 21.0f / 2.0f; - break; - case 0x1A: /* 1066 */ - dramratio = 32.0f / 3.0f; - break; - } - - dramclock = fsb * dramratio; - - /* print */ - print_cpu_line(dramclock, fsb, 3); - -} - -static void poll_fsb_k15(void) { - - unsigned long temp2; - unsigned long dramchr; - double dramratio, dramclock, fsb; - unsigned int mcgsrl,mcgsth, fid, did; - - // Get current FID & DID - rdmsr(0xc0010071, mcgsrl, mcgsth); - fid = mcgsrl & 0x3F; - did = (mcgsrl >> 6) & 0x7; - - fsb = ((extclock / 1000.0f) / ((fid + 16.0f) / (2^did)) / 2); - - /* Finaly, we need the clock ratio */ - pci_conf_read(0, 24, 2, 0x94, 4, &dramchr); - - if(((dramchr >> 14) & 0x1) == 1) - { - pci_conf_read(0, 24, 2, 0x194, 4, &dramchr); - } - - temp2 = (dramchr & 0x1F); - - switch (temp2) { - case 0x04: - dramratio = 10.0f / 3.0f; - break; - default: - case 0x06: - dramratio = 4.0f; - break; - case 0x0A: - dramratio = 16.0f / 3.0f; - break; - case 0x0E: - dramratio = 20.0f / 3.0f; - break; - case 0x12: - dramratio = 8.0f; - break; - case 0x16: - dramratio = 28.0f / 3.0f; - break; - case 0x1A: - dramratio = 32.0f / 3.0f; - break; - case 0x1F: - dramratio = 36.0f / 3.0f; - break; - } - - dramclock = fsb * dramratio; - - /* print */ - print_cpu_line(dramclock, fsb, 3); - -} - -static void poll_fsb_k14(void) -{ - - unsigned long dramchr; - double dramratio, dramclock, fsb; - - // FIXME: Unable to find a real way to detect multiplier. - fsb = 100.0f; - - /* Clock ratio */ - pci_conf_read(0, 24, 2, 0x94, 4, &dramchr); - - switch (dramchr & 0x1F) { - default: - case 0x06: - dramratio = 4.0f; - break; - case 0x0A: - dramratio = 16.0f / 3.0f; - break; - case 0x0E: - dramratio = 20.0f / 3.0f; - break; - case 0x12: - dramratio = 8.0f; - break; - } - - dramclock = fsb * dramratio; - - /* print */ - print_cpu_line(dramclock, fsb, 3); - -} - - -static void poll_fsb_i925(void) { - - double dramclock, dramratio, fsb; - unsigned long mchcfg, mchcfg2, dev0, drc, idetect; - float coef = getP4PMmultiplier(); - long *ptr; - int ddr_type; - - pci_conf_read( 0, 0, 0, 0x02, 2, &idetect); - - /* Find dramratio */ - pci_conf_read( 0, 0, 0, 0x44, 4, &dev0); - dev0 = dev0 & 0xFFFFC000; - ptr=(long*)(dev0+0xC00); - mchcfg = *ptr & 0xFFFF; - ptr=(long*)(dev0+0x120); - drc = *ptr & 0xFFFF; - dramratio = 1; - - mchcfg2 = (mchcfg >> 4)&3; - - if ((drc&3) != 2) { - // We are in DDR1 Mode - if (mchcfg2 == 1) { dramratio = 0.8; } else { dramratio = 1; } - ddr_type = 1; - } else { - // We are in DDR2 Mode - ddr_type = 2; - if ((mchcfg >> 2)&1) { - // We are in FSB1066 Mode - if (mchcfg2 == 2) { dramratio = 0.75; } else { dramratio = 1; } - } else { - switch (mchcfg2) { - case 1: - dramratio = 0.66667; - break; - case 2: - if (idetect != 0x2590) { dramratio = 1; } else { dramratio = 1.5; } - break; - case 3: - // Checking for FSB533 Mode & Alviso - if ((mchcfg & 1) == 0) { dramratio = 1.33334; } - else if (idetect == 0x2590) { dramratio = 2; } - else { dramratio = 1.5; } - } - } - } - // Compute RAM Frequency - fsb = ((extclock / 1000) / coef); - dramclock = fsb * dramratio; - - - print_cpu_line(dramclock, fsb, ddr_type); - -} - -static void poll_fsb_i945(void) { - - double dramclock, dramratio, fsb; - unsigned long mchcfg, dev0; - float coef = getP4PMmultiplier(); - long *ptr; - - /* Find dramratio */ - pci_conf_read( 0, 0, 0, 0x44, 4, &dev0); - dev0 &= 0xFFFFC000; - ptr=(long*)(dev0+0xC00); - mchcfg = *ptr & 0xFFFF; - dramratio = 1; - - switch ((mchcfg >> 4)&7) { - case 1: dramratio = 1.0; break; - case 2: dramratio = 1.33334; break; - case 3: dramratio = 1.66667; break; - case 4: dramratio = 2.0; break; - } - - // Compute RAM Frequency - fsb = ((extclock / 1000) / coef); - - dramclock = fsb * dramratio; - - // Print - print_cpu_line(dramclock, fsb, 2); - -} - -static void poll_fsb_i945gme(void) { - - double dramclock, dramratio, fsb; - unsigned long mchcfg, dev0, fsb_mch; - float coef = getP4PMmultiplier(); - long *ptr; - - /* Find dramratio */ - pci_conf_read( 0, 0, 0, 0x44, 4, &dev0); - dev0 &= 0xFFFFC000; - ptr=(long*)(dev0+0xC00); - mchcfg = *ptr & 0xFFFF; - dramratio = 1; - - switch (mchcfg & 7) { - case 0: fsb_mch = 400; break; - default: - case 1: fsb_mch = 533; break; - case 2: fsb_mch = 667; break; - } - - - switch (fsb_mch) { - case 400: - switch ((mchcfg >> 4)&7) { - case 2: dramratio = 1.0f; break; - case 3: dramratio = 4.0f/3.0f; break; - case 4: dramratio = 5.0f/3.0f; break; - } - break; - - default: - case 533: - switch ((mchcfg >> 4)&7) { - case 2: dramratio = 3.0f/4.0f; break; - case 3: dramratio = 1.0f; break; - case 4: dramratio = 5.0f/4.0f; break; - } - break; - - case 667: - switch ((mchcfg >> 4)&7) { - case 2: dramratio = 3.0f/5.0f; break; - case 3: dramratio = 4.0f/5.0f; break; - case 4: dramratio = 1.0f; break; - } - break; - } - - // Compute RAM Frequency - fsb = ((extclock / 1000) / coef); - dramclock = fsb * dramratio * 2; - - print_cpu_line(dramclock, fsb, 2); - -} - - -static void poll_fsb_i975(void) { - - double dramclock, dramratio, fsb; - unsigned long mchcfg, dev0, fsb_mch; - float coef = getP4PMmultiplier(); - long *ptr; - - /* Find dramratio */ - pci_conf_read( 0, 0, 0, 0x44, 4, &dev0); - dev0 &= 0xFFFFC000; - ptr=(long*)(dev0+0xC00); - mchcfg = *ptr & 0xFFFF; - dramratio = 1; - - switch (mchcfg & 7) { - case 1: fsb_mch = 533; break; - case 2: fsb_mch = 800; break; - case 3: fsb_mch = 667; break; - default: fsb_mch = 1066; break; - } - - - switch (fsb_mch) { - case 533: - switch ((mchcfg >> 4)&7) { - case 0: dramratio = 1.25; break; - case 1: dramratio = 1.5; break; - case 2: dramratio = 2.0; break; - } - break; - - default: - case 800: - switch ((mchcfg >> 4)&7) { - case 1: dramratio = 1.0; break; - case 2: dramratio = 1.33334; break; - case 3: dramratio = 1.66667; break; - case 4: dramratio = 2.0; break; - } - break; - - case 1066: - switch ((mchcfg >> 4)&7) { - case 1: dramratio = 0.75; break; - case 2: dramratio = 1.0; break; - case 3: dramratio = 1.25; break; - case 4: dramratio = 1.5; break; - } - break; - } - - // Compute RAM Frequency - fsb = ((extclock / 1000) / coef); - dramclock = fsb * dramratio; - - print_cpu_line(dramclock, fsb, 2); - -} - -static void poll_fsb_i965(void) { - - double dramclock, dramratio, fsb; - unsigned long mchcfg, dev0, fsb_mch; - float coef = getP4PMmultiplier(); - long *ptr; - - /* Find dramratio */ - pci_conf_read( 0, 0, 0, 0x48, 4, &dev0); - dev0 &= 0xFFFFC000; - ptr=(long*)(dev0+0xC00); - mchcfg = *ptr & 0xFFFF; - dramratio = 1; - - switch (mchcfg & 7) { - case 0: fsb_mch = 1066; break; - case 1: fsb_mch = 533; break; - default: case 2: fsb_mch = 800; break; - case 3: fsb_mch = 667; break; - case 4: fsb_mch = 1333; break; - case 6: fsb_mch = 1600; break; - } - - - switch (fsb_mch) { - case 533: - switch ((mchcfg >> 4)&7) { - case 1: dramratio = 2.0; break; - case 2: dramratio = 2.5; break; - case 3: dramratio = 3.0; break; - } - break; - - default: - case 800: - switch ((mchcfg >> 4)&7) { - case 0: dramratio = 1.0; break; - case 1: dramratio = 5.0f/4.0f; break; - case 2: dramratio = 5.0f/3.0f; break; - case 3: dramratio = 2.0f; break; - case 4: dramratio = 8.0f/3.0f; break; - case 5: dramratio = 10.0f/3.0f; break; - } - break; - - case 1066: - switch ((mchcfg >> 4)&7) { - case 1: dramratio = 1.0f; break; - case 2: dramratio = 5.0f/4.0f; break; - case 3: dramratio = 3.0f/2.0f; break; - case 4: dramratio = 2.0f; break; - case 5: dramratio = 5.0f/2.0f; break; - } - break; - - case 1333: - switch ((mchcfg >> 4)&7) { - case 2: dramratio = 1.0f; break; - case 3: dramratio = 6.0f/5.0f; break; - case 4: dramratio = 8.0f/5.0f; break; - case 5: dramratio = 2.0f; break; - } - break; - - case 1600: - switch ((mchcfg >> 4)&7) { - case 3: dramratio = 1.0f; break; - case 4: dramratio = 4.0f/3.0f; break; - case 5: dramratio = 3.0f/2.0f; break; - case 6: dramratio = 2.0f; break; - } - break; - - } - - // Compute RAM Frequency - fsb = ((extclock / 1000) / coef); - dramclock = fsb * dramratio; - - // Print DRAM Freq - print_cpu_line(dramclock, fsb, 2); - -} - -static void poll_fsb_p35(void) { - - double dramclock, dramratio, fsb; - unsigned long mchcfg, dev0, fsb_mch, Device_ID, Memory_Check, c0ckectrl, offset; - float coef = getP4PMmultiplier(); - long *ptr; - int ram_type; - - pci_conf_read( 0, 0, 0, 0x02, 2, &Device_ID); - Device_ID &= 0xFFFF; - - /* Find dramratio */ - pci_conf_read( 0, 0, 0, 0x48, 4, &dev0); - dev0 &= 0xFFFFC000; - - ptr = (long*)(dev0+0x260); - c0ckectrl = *ptr & 0xFFFFFFFF; - - - // If DIMM 0 not populated, check DIMM 1 - ((c0ckectrl) >> 20 & 0xF)?(offset = 0):(offset = 0x400); - - ptr=(long*)(dev0+0xC00); - mchcfg = *ptr & 0xFFFF; - dramratio = 1; - - switch (mchcfg & 7) { - case 0: fsb_mch = 1066; break; - case 1: fsb_mch = 533; break; - default: case 2: fsb_mch = 800; break; - case 3: fsb_mch = 667; break; - case 4: fsb_mch = 1333; break; - case 6: fsb_mch = 1600; break; - } - - - switch (fsb_mch) { - case 533: - switch ((mchcfg >> 4)&7) { - case 1: dramratio = 2.0; break; - case 2: dramratio = 2.5; break; - case 3: dramratio = 3.0; break; - } - break; - - default: - case 800: - switch ((mchcfg >> 4)&7) { - case 0: dramratio = 1.0; break; - case 1: dramratio = 5.0f/4.0f; break; - case 2: dramratio = 5.0f/3.0f; break; - case 3: dramratio = 2.0; break; - case 4: dramratio = 8.0f/3.0f; break; - case 5: dramratio = 10.0f/3.0f; break; - } - break; - - case 1066: - switch ((mchcfg >> 4)&7) { - case 1: dramratio = 1.0f; break; - case 2: dramratio = 5.0f/4.0f; break; - case 3: dramratio = 3.0f/2.0f; break; - case 4: dramratio = 2.0f; break; - case 5: dramratio = 5.0f/2.0f; break; - } - break; - - case 1333: - switch ((mchcfg >> 4)&7) { - case 2: dramratio = 1.0f; break; - case 3: dramratio = 6.0f/5.0f; break; - case 4: dramratio = 8.0f/5.0f; break; - case 5: dramratio = 2.0f; break; - } - break; - - case 1600: - switch ((mchcfg >> 4)&7) { - case 3: dramratio = 1.0f; break; - case 4: dramratio = 4.0f/3.0f; break; - case 5: dramratio = 3.0f/2.0f; break; - case 6: dramratio = 2.0f; break; - } - break; - - } - - // On P45, check 1A8 - if(Device_ID > 0x2E00 && imc_type != 8) { - ptr = (long*)(dev0+offset+0x1A8); - Memory_Check = *ptr & 0xFFFFFFFF; - Memory_Check >>= 2; - Memory_Check &= 1; - Memory_Check = !Memory_Check; - } else if (imc_type == 8) { - ptr = (long*)(dev0+offset+0x224); - Memory_Check = *ptr & 0xFFFFFFFF; - Memory_Check &= 1; - Memory_Check = !Memory_Check; - } else { - ptr = (long*)(dev0+offset+0x1E8); - Memory_Check = *ptr & 0xFFFFFFFF; - } - - //Determine DDR-II or DDR-III - if (Memory_Check & 1) { - ram_type = 2; - } else { - ram_type = 3; - } - - // Compute RAM Frequency - fsb = ((extclock / 1000) / coef); - dramclock = fsb * dramratio; - - // Print DRAM Freq - print_cpu_line(dramclock, fsb, ram_type); - -} - -static void poll_fsb_im965(void) { - - double dramclock, dramratio, fsb; - unsigned long mchcfg, dev0, fsb_mch; - float coef = getP4PMmultiplier(); - long *ptr; - - /* Find dramratio */ - pci_conf_read( 0, 0, 0, 0x48, 4, &dev0); - dev0 &= 0xFFFFC000; - ptr=(long*)(dev0+0xC00); - mchcfg = *ptr & 0xFFFF; - dramratio = 1; - - switch (mchcfg & 7) { - case 1: fsb_mch = 533; break; - default: case 2: fsb_mch = 800; break; - case 3: fsb_mch = 667; break; - case 6: fsb_mch = 1066; break; - } - - - switch (fsb_mch) { - case 533: - switch ((mchcfg >> 4)&7) { - case 1: dramratio = 5.0f/4.0f; break; - case 2: dramratio = 3.0f/2.0f; break; - case 3: dramratio = 2.0f; break; - } - break; - - case 667: - switch ((mchcfg >> 4)&7) { - case 1: dramratio = 1.0f; break; - case 2: dramratio = 6.0f/5.0f; break; - case 3: dramratio = 8.0f/5.0f; break; - case 4: dramratio = 2.0f; break; - case 5: dramratio = 12.0f/5.0f; break; - } - break; - default: - case 800: - switch ((mchcfg >> 4)&7) { - case 1: dramratio = 5.0f/6.0f; break; - case 2: dramratio = 1.0f; break; - case 3: dramratio = 4.0f/3.0f; break; - case 4: dramratio = 5.0f/3.0f; break; - case 5: dramratio = 2.0f; break; - } - break; - case 1066: - switch ((mchcfg >> 4)&7) { - case 5: dramratio = 3.0f/2.0f; break; - case 6: dramratio = 2.0f; break; - } - break; - } - - // Compute RAM Frequency - fsb = ((extclock / 1000) / coef); - dramclock = fsb * dramratio; - - // Print DRAM Freq - print_cpu_line(dramclock, fsb, 2); - -} - - -static void poll_fsb_5400(void) { - - double dramclock, dramratio, fsb; - unsigned long ambase_low, ambase_high, ddrfrq; - float coef = getP4PMmultiplier(); - - /* Find dramratio */ - pci_conf_read( 0, 16, 0, 0x48, 4, &ambase_low); - ambase_low &= 0xFFFE0000; - pci_conf_read( 0, 16, 0, 0x4C, 4, &ambase_high); - ambase_high &= 0xFF; - pci_conf_read( 0, 16, 1, 0x56, 1, &ddrfrq); - ddrfrq &= 7; - dramratio = 1; - - switch (ddrfrq) { - case 0: - case 1: - case 4: - dramratio = 1.0; - break; - case 2: - dramratio = 5.0f/4.0f; - break; - case 3: - case 7: - dramratio = 4.0f/5.0f; - break; - } - - - // Compute RAM Frequency - fsb = ((extclock / 1000) / coef); - dramclock = fsb * dramratio; - - // Print DRAM Freq - print_cpu_line(dramclock, fsb, 2); - -} - - -static void poll_fsb_nf4ie(void) { - - double dramclock, dramratio, fsb; - float mratio, nratio; - unsigned long reg74, reg60; - float coef = getP4PMmultiplier(); - - /* Find dramratio */ - pci_conf_read(0, 0, 2, 0x74, 2, ®74); - pci_conf_read(0, 0, 2, 0x60, 4, ®60); - mratio = reg74 & 0xF; - nratio = (reg74 >> 4) & 0xF; - - // If M or N = 0, then M or N = 16 - if (mratio == 0) { mratio = 16; } - if (nratio == 0) { nratio = 16; } - - // Check if synchro or pseudo-synchro mode - if((reg60 >> 22) & 1) { - dramratio = 1; - } else { - dramratio = nratio / mratio; - } - - /* Compute RAM Frequency */ - fsb = ((extclock /1000) / coef); - dramclock = fsb * dramratio; - - // Print DRAM Freq - print_cpu_line(dramclock, fsb, 2); - -} - -static void poll_fsb_i875(void) { - - double dramclock, dramratio, fsb; - unsigned long mchcfg, smfs; - float coef = getP4PMmultiplier(); - - /* Find dramratio */ - pci_conf_read(0, 0, 0, 0xC6, 2, &mchcfg); - smfs = (mchcfg >> 10)&3; - dramratio = 1; - - if ((mchcfg&3) == 3) { dramratio = 1; } - if ((mchcfg&3) == 2) { - if (smfs == 2) { dramratio = 1; } - if (smfs == 1) { dramratio = 1.25; } - if (smfs == 0) { dramratio = 1.5; } - } - if ((mchcfg&3) == 1) { - if (smfs == 2) { dramratio = 0.6666666666; } - if (smfs == 1) { dramratio = 0.8; } - if (smfs == 0) { dramratio = 1; } - } - if ((mchcfg&3) == 0) { dramratio = 0.75; } - - - /* Compute RAM Frequency */ - dramclock = ((extclock /1000) / coef) / dramratio; - fsb = ((extclock /1000) / coef); - - /* Print DRAM Freq */ - print_cpu_line(dramclock, fsb, 2); -} - -static void poll_fsb_p4(void) { - - ulong fsb, idetect; - float coef = getP4PMmultiplier(); - char *name; - int col,temp; - - fsb = ((extclock /1000) / coef); - - /* For synchro only chipsets */ - pci_conf_read( 0, 0, 0, 0x02, 2, &idetect); - if (idetect == 0x2540 || idetect == 0x254C) - { - print_cpu_line(fsb, fsb, 1); - } else { - /* Print the controller name */ - col = COL_SPEC; - cprint(LINE_CPU, col, "Chipset: "); - col += 9; - /* Print the controller name */ - name = controllers[ctrl.index].name; - cprint(LINE_CPU, col, name); - /* Now figure out how much I just printed */ - temp = 20; - while(name[temp - 20] != '\0') { - col++; - temp++; - } - - if(temp < 36){ - cprint(LINE_CPU, col +1, "- FSB : "); - col += 9; - dprint(LINE_CPU, col, fsb, 3,0); - col += 3; - } - - } -} - -static void poll_fsb_i855(void) { - - - double dramclock, dramratio, fsb ; - unsigned int msr_lo, msr_hi; - ulong mchcfg, idetect; - int coef; - - pci_conf_read( 0, 0, 0, 0x02, 2, &idetect); - - /* Find multiplier (by MSR) */ - - /* Is it a Pentium M ? */ - if (cpu_id.vers.bits.family == 6) { - rdmsr(0x2A, msr_lo, msr_hi); - coef = (msr_lo >> 22) & 0x1F; - } else { - rdmsr(0x2C, msr_lo, msr_hi); - coef = (msr_lo >> 24) & 0x1F; - } - - fsb = ((extclock /1000) / coef); - - - /* Compute DRAM Clock */ - - dramratio = 1; - if (idetect == 0x3580) { - pci_conf_read( 0, 0, 3, 0xC0, 2, &mchcfg); - mchcfg = mchcfg & 0x7; - - if (mchcfg == 1 || mchcfg == 2 || mchcfg == 4 || mchcfg == 5) { dramratio = 1; } - if (mchcfg == 0 || mchcfg == 3) { dramratio = 1.333333333; } - if (mchcfg == 6) { dramratio = 1.25; } - if (mchcfg == 7) { dramratio = 1.666666667; } - - } else { - pci_conf_read( 0, 0, 0, 0xC6, 2, &mchcfg); - if (((mchcfg >> 10)&3) == 0) { dramratio = 1; } - else if (((mchcfg >> 10)&3) == 1) { dramratio = 1.666667; } - else { dramratio = 1.333333333; } - } - - - dramclock = fsb * dramratio; - - /* ...and print */ - print_cpu_line(dramclock, fsb, 1); - -} - -static void poll_fsb_amd32(void) { - - unsigned int mcgsrl; - unsigned int mcgsth; - unsigned long temp; - double dramclock; - double coef2; - int col; - char *name; - - /* First, got the FID */ - rdmsr(0x0c0010015, mcgsrl, mcgsth); - temp = (mcgsrl >> 24)&0x0F; - - if ((mcgsrl >> 19)&1) { coef2 = athloncoef2[temp]; } - else { coef2 = athloncoef[temp]; } - - if (coef2 == 0) { coef2 = 1; }; - - /* Compute the final FSB Clock */ - dramclock = (extclock /1000) / coef2; - - /* Print the controller name */ - col = COL_SPEC; - cprint(LINE_CPU, col, "Chipset: "); - col += 9; - /* Print the controller name */ - name = controllers[ctrl.index].name; - cprint(LINE_CPU, col, name); - /* Now figure out how much I just printed */ - temp = 20; - while(name[temp - 20] != '\0') { - col++; - temp++; - } - - if(temp < 36){ - cprint(LINE_CPU, col +1, "- FSB : "); - col += 9; - dprint(LINE_CPU, col, dramclock, 3,0); - col += 3; - } - - -} - -static void poll_fsb_nf2(void) { - - unsigned int mcgsrl; - unsigned int mcgsth; - unsigned long temp, mempll; - double dramclock, fsb; - double mem_m, mem_n; - float coef; - coef = 10; - - /* First, got the FID */ - rdmsr(0x0c0010015, mcgsrl, mcgsth); - temp = (mcgsrl >> 24)&0x0F; - - if ((mcgsrl >> 19)&1) { coef = athloncoef2[temp]; } - else { coef = athloncoef[temp]; } - - /* Get the coef (COEF = N/M) - Here is for Crush17 */ - pci_conf_read(0, 0, 3, 0x70, 4, &mempll); - mem_m = (mempll&0x0F); - mem_n = ((mempll >> 4) & 0x0F); - - /* If something goes wrong, the chipset is probably a Crush18 */ - if ( mem_m == 0 || mem_n == 0 ) { - pci_conf_read(0, 0, 3, 0x7C, 4, &mempll); - mem_m = (mempll&0x0F); - mem_n = ((mempll >> 4) & 0x0F); - } - - /* Compute the final FSB Clock */ - dramclock = ((extclock /1000) / coef) * (mem_n/mem_m); - fsb = ((extclock /1000) / coef); - - /* ...and print */ - print_cpu_line(dramclock, fsb, 1); - -} - -static void poll_fsb_us15w(void) { - - double dramclock, dramratio, fsb; - unsigned long msr; - - /* Find dramratio */ - /* D0 MsgRd, 05 Zunit, 03 MSR */ - pci_conf_write(0, 0, 0, 0xD0, 4, 0xD0050300 ); - pci_conf_read(0, 0, 0, 0xD4, 4, &msr ); - fsb = ( msr >> 3 ) & 1; - - dramratio = 0.5; - - // Compute RAM Frequency - if (( msr >> 3 ) & 1) { - fsb = 533; - } else { - fsb = 400; - } - - /* - switch (( msr >> 0 ) & 7) { - case 0: - gfx = 100; - break; - case 1: - gfx = 133; - break; - case 2: - gfx = 150; - break; - case 3: - gfx = 178; - break; - case 4: - gfx = 200; - break; - case 5: - gfx = 266; - break; - default: - gfx = 0; - break; - } - */ - - dramclock = fsb * dramratio; - - // Print DRAM Freq - print_cpu_line(dramclock, fsb, 1); - -} - -static void poll_fsb_nhm(void) { - - double dramclock, dramratio, fsb; - unsigned long mc_dimm_clk_ratio; - float coef = getNHMmultiplier(); - //unsigned long qpi_pll_status; - //float qpi_speed; - - - fsb = ((extclock /1000) / coef); - - /* Print QPI Speed (if ECC not supported) */ - /* - if(ctrl.mode == ECC_NONE && cpu_id.vers.bits.model == 10) { - pci_conf_read(nhm_bus, 2, 1, 0x50, 2, &qpi_pll_status); - qpi_speed = (qpi_pll_status & 0x7F) * ((extclock / 1000) / coef) * 2; - cprint(LINE_CPU+5, col +1, "/ QPI : "); - col += 9; - dprint(LINE_CPU+5, col, qpi_speed/1000, 1,0); - col += 1; - cprint(LINE_CPU+5, col, "."); - col += 1; - qpi_speed = ((qpi_speed / 1000) - (int)(qpi_speed / 1000)) * 10; - dprint(LINE_CPU+5, col, qpi_speed, 1,0); - col += 1; - cprint(LINE_CPU+5, col +1, "GT/s"); - col += 5; - } - */ - - /* Get the clock ratio */ - - pci_conf_read(nhm_bus, 3, 4, 0x54, 2, &mc_dimm_clk_ratio); - dramratio = (mc_dimm_clk_ratio & 0x1F); - - // Compute RAM Frequency - fsb = ((extclock / 1000) / coef); - dramclock = fsb * dramratio / 2; - - // Print DRAM Freq - print_cpu_line(dramclock, fsb, 3); - -} - -static void poll_fsb_nhm32(void) { - - double dramclock, dramratio, fsb; - unsigned long mc_dimm_clk_ratio; - float coef = getNHMmultiplier(); - //unsigned long qpi_pll_status; - //float qpi_speed; - - fsb = ((extclock /1000) / coef); - - /* Print QPI Speed (if ECC not supported) */ - /* - if(ctrl.mode == ECC_NONE && cpu_id.vers.bits.model == 12) { - pci_conf_read(nhm_bus, 2, 1, 0x50, 2, &qpi_pll_status); - qpi_speed = (qpi_pll_status & 0x7F) * ((extclock / 1000) / coef) * 2; - cprint(LINE_CPU+5, col +1, "/ QPI : "); - col += 9; - dprint(LINE_CPU+5, col, qpi_speed/1000, 1,0); - col += 1; - cprint(LINE_CPU+5, col, "."); - col += 1; - qpi_speed = ((qpi_speed / 1000) - (int)(qpi_speed / 1000)) * 10; - dprint(LINE_CPU+5, col, qpi_speed, 1,0); - col += 1; - cprint(LINE_CPU+5, col +1, "GT/s"); - col += 5; - } - */ - - /* Get the clock ratio */ - - pci_conf_read(nhm_bus, 3, 4, 0x50, 2, &mc_dimm_clk_ratio); - dramratio = (mc_dimm_clk_ratio & 0x1F); - - // Compute RAM Frequency - fsb = ((extclock / 1000) / coef); - dramclock = fsb * dramratio / 2; - - // Print DRAM Freq - print_cpu_line(dramclock, fsb, 3); - -} - -static void poll_fsb_wmr(void) { - - double dramclock, dramratio, fsb; - unsigned long dev0; - float coef = getNHMmultiplier(); - long *ptr; - - fsb = ((extclock / 1000) / coef); - - /* Find dramratio */ - pci_conf_read( 0, 0, 0, 0x48, 4, &dev0); - dev0 &= 0xFFFFC000; - ptr=(long*)(dev0+0x2C20); - dramratio = 1; - - /* Get the clock ratio */ - dramratio = 0.25 * (float)(*ptr & 0x1F); - - // Compute RAM Frequency - dramclock = fsb * dramratio; - - // Print DRAM Freq - print_cpu_line(dramclock, fsb, 3); - -} - -static void poll_fsb_snb(void) { - - double dramclock, dramratio, fsb; - unsigned long dev0; - float coef = getSNBmultiplier(); - long *ptr; - - fsb = ((extclock / 1000) / coef); - - /* Find dramratio */ - pci_conf_read( 0, 0, 0, 0x48, 4, &dev0); - dev0 &= 0xFFFFC000; - ptr=(long*)(dev0+0x5E04); - dramratio = 1; - - /* Get the clock ratio */ - dramratio = (float)(*ptr & 0x1F) * (133.34f / 100.0f); - - // Compute RAM Frequency - dramclock = fsb * dramratio; - - // Print DRAM Freq - print_cpu_line(dramclock, fsb, 3); - -} - -static void poll_fsb_ivb(void) { - - double dramclock, dramratio, fsb; - unsigned long dev0, mchcfg; - float coef = getSNBmultiplier(); - long *ptr; - - fsb = ((extclock / 1000) / coef); - - /* Find dramratio */ - pci_conf_read( 0, 0, 0, 0x48, 4, &dev0); - dev0 &= 0xFFFFC000; - ptr=(long*)(dev0+0x5E04); - mchcfg = *ptr & 0xFFFF; - dramratio = 1; - - /* Get the clock ratio */ - switch((mchcfg >> 8) & 0x01) - { - case 0x0: - dramratio = (float)(*ptr & 0x1F) * (133.34f / 100.0f); - break; - case 0x1: - dramratio = (float)(*ptr & 0x1F) * (100.0f / 100.0f); - break; - } - - // Compute RAM Frequency - dramclock = fsb * dramratio; - - // Print DRAM Freq - print_cpu_line(dramclock, fsb, 3); - -} - -static void poll_fsb_snbe(void) { - - double dramclock, dramratio, fsb; - unsigned long dev0; - float coef = getSNBmultiplier(); - - fsb = ((extclock / 1000) / coef); - - /* Find dramratio */ - pci_conf_read( 0xFF, 10, 1, 0x98, 4, &dev0); - dev0 &= 0xFFFFFFFF; - dramratio = 1; - - /* Get the clock ratio */ - dramratio = (float)(dev0 & 0x3F) * (66.67f / 100.0f); - - // Compute RAM Frequency - dramclock = fsb * dramratio; - - // Print DRAM Freq - print_cpu_line(dramclock, fsb, 3); - - - -} - -/* ------------------ Here the code for Timings detection ------------------ */ -/* ------------------------------------------------------------------------- */ - -static void poll_timings_nf4ie(void) { - - - ulong regd0, reg8c, reg9c, reg80; - int cas, rcd, rp, ras, chan; - - //Now, read Registers - pci_conf_read( 0, 1, 1, 0xD0, 4, ®d0); - pci_conf_read( 0, 1, 1, 0x80, 1, ®80); - pci_conf_read( 0, 1, 0, 0x8C, 4, ®8c); - pci_conf_read( 0, 1, 0, 0x9C, 4, ®9c); - - // Then, detect timings - cas = (regd0 >> 4) & 0x7; - rcd = (reg8c >> 24) & 0xF; - rp = (reg9c >> 8) & 0xF; - ras = (reg8c >> 16) & 0x3F; - - if (reg80 & 0x3) { - chan = 2; - } else { - chan = 1; - } - print_ram_line(cas, rcd, rp, ras, chan); -} - -static void poll_timings_i875(void) { - - ulong dev6, dev62; - ulong temp; - float cas; - int rcd, rp, ras, chan; - long *ptr, *ptr2; - - pci_conf_read( 0, 6, 0, 0x40, 4, &dev62); - ptr2=(long*)(dev6+0x68); - - /* Read the MMR Base Address & Define the pointer */ - pci_conf_read( 0, 6, 0, 0x10, 4, &dev6); - - /* Now, we could check some additionnals timings infos) */ - ptr=(long*)(dev6+0x60); - // CAS Latency (tCAS) - temp = ((*ptr >> 5)& 0x3); - if (temp == 0x0) { cas = 2.5; } else if (temp == 0x1) { cas = 2; } else { cas = 3; } - - // RAS-To-CAS (tRCD) - temp = ((*ptr >> 2)& 0x3); - if (temp == 0x0) { rcd = 4; } else if (temp == 0x1) { rcd = 3; } else { rcd = 2; } - - // RAS Precharge (tRP) - temp = (*ptr&0x3); - if (temp == 0x0) { rp = 4; } else if (temp == 0x1) { rp = 3; } else { rp = 2; } - - // RAS Active to precharge (tRAS) - temp = ((*ptr >> 7)& 0x7); - ras = 10 - temp; - - // Print 64 or 128 bits mode - if (((*ptr2 >> 21)&3) > 0) { - chan = 2; - } else { - chan = 1; - } - print_ram_line(cas, rcd, rp, ras, chan); -} - -static void poll_timings_i925(void) { - - // Thanks for CDH optis - float cas; - int rcd,rp,ras,chan; - ulong dev0, drt, drc, dcc, idetect, temp; - long *ptr; - - //Now, read MMR Base Address - pci_conf_read( 0, 0, 0, 0x44, 4, &dev0); - pci_conf_read( 0, 0, 0, 0x02, 2, &idetect); - dev0 &= 0xFFFFC000; - - //Set pointer for DRT - ptr=(long*)(dev0+0x114); - drt = *ptr & 0xFFFFFFFF; - - //Set pointer for DRC - ptr=(long*)(dev0+0x120); - drc = *ptr & 0xFFFFFFFF; - - //Set pointer for DCC - ptr=(long*)(dev0+0x200); - dcc = *ptr & 0xFFFFFFFF; - - // CAS Latency (tCAS) - temp = ((drt >> 8)& 0x3); - - if ((drc & 3) == 2){ - // Timings DDR-II - if (temp == 0x0) { cas = 5; } - else if (temp == 0x1) { cas = 4; } - else if (temp == 0x2) { cas = 3; } - else { cas = 6; } - } else { - // Timings DDR-I - if (temp == 0x0) { cas = 3; } - else if (temp == 0x1) { cas = 2.5f;} - else { cas = 2; } - } - - // RAS-To-CAS (tRCD) - rcd = ((drt >> 4)& 0x3)+2; - - // RAS Precharge (tRP) - rp = (drt&0x3)+2; - - // RAS Active to precharge (tRAS) - // If Lakeport, than change tRAS computation (Thanks to CDH, again) - if (idetect > 0x2700) - ras = ((drt >> 19)& 0x1F); - else - ras = ((drt >> 20)& 0x0F); - - - temp = (dcc&0x3); - if (temp == 1) { chan = 2; } - else if (temp == 2) { chan = 2; } - else { chan = 1; } - - print_ram_line(cas, rcd, rp, ras, chan); - -} - -static void poll_timings_i965(void) { - - // Thanks for CDH optis - ulong dev0, c0ckectrl, c1ckectrl, offset; - ulong ODT_Control_Register, Precharge_Register, ACT_Register, Read_Register; - long *ptr; - int rcd,rp,ras,chan; - float cas; - - //Now, read MMR Base Address - pci_conf_read( 0, 0, 0, 0x48, 4, &dev0); - dev0 &= 0xFFFFC000; - - ptr = (long*)(dev0+0x260); - c0ckectrl = *ptr & 0xFFFFFFFF; - - ptr = (long*)(dev0+0x660); - c1ckectrl = *ptr & 0xFFFFFFFF; - - // If DIMM 0 not populated, check DIMM 1 - ((c0ckectrl) >> 20 & 0xF)?(offset = 0):(offset = 0x400); - - ptr = (long*)(dev0+offset+0x29C); - ODT_Control_Register = *ptr & 0xFFFFFFFF; - - ptr = (long*)(dev0+offset+0x250); - Precharge_Register = *ptr & 0xFFFFFFFF; - - ptr = (long*)(dev0+offset+0x252); - ACT_Register = *ptr & 0xFFFFFFFF; - - ptr = (long*)(dev0+offset+0x258); - Read_Register = *ptr & 0xFFFFFFFF; - - - // CAS Latency (tCAS) - cas = ((ODT_Control_Register >> 17)& 7) + 3.0f; - - // RAS-To-CAS (tRCD) - rcd = (Read_Register >> 16) & 0xF; - - // RAS Precharge (tRP) - rp = (ACT_Register >> 13) & 0xF; - - // RAS Active to precharge (tRAS) - ras = (Precharge_Register >> 11) & 0x1F; - - if ((c0ckectrl >> 20 & 0xF) && (c1ckectrl >> 20 & 0xF)) { - chan = 2; - } else { - chan = 1; - } - - print_ram_line(cas, rcd, rp, ras, chan); -} - -static void poll_timings_im965(void) { - - // Thanks for CDH optis - ulong dev0, c0ckectrl, c1ckectrl, offset; - ulong ODT_Control_Register, Precharge_Register; - long *ptr; - int rcd,rp,ras,chan; - float cas; - - //Now, read MMR Base Address - pci_conf_read( 0, 0, 0, 0x48, 4, &dev0); - dev0 &= 0xFFFFC000; - - ptr = (long*)(dev0+0x1200); - c0ckectrl = *ptr & 0xFFFFFFFF; - - ptr = (long*)(dev0+0x1300); - c1ckectrl = *ptr & 0xFFFFFFFF; - - // If DIMM 0 not populated, check DIMM 1 - ((c0ckectrl) >> 20 & 0xF)?(offset = 0):(offset = 0x100); - - ptr = (long*)(dev0+offset+0x121C); - ODT_Control_Register = *ptr & 0xFFFFFFFF; - - ptr = (long*)(dev0+offset+0x1214); - Precharge_Register = *ptr & 0xFFFFFFFF; - - // CAS Latency (tCAS) - cas = ((ODT_Control_Register >> 23)& 7) + 3.0f; - - // RAS-To-CAS (tRCD) - rcd = ((Precharge_Register >> 5)& 7) + 2.0f; - - // RAS Precharge (tRP) - rp = (Precharge_Register & 7) + 2.0f; - - // RAS Active to precharge (tRAS) - ras = (Precharge_Register >> 21) & 0x1F; - - - if ((c0ckectrl >> 20 & 0xF) && (c1ckectrl >> 20 & 0xF)) { - chan = 2; - } else { - chan = 1; - } - print_ram_line(cas, rcd, rp, ras, chan); -} - -static void poll_timings_p35(void) { - - // Thanks for CDH optis - float cas; - int rcd, rp, ras, chan; - ulong dev0, Device_ID, c0ckectrl, c1ckectrl, offset; - ulong ODT_Control_Register, Precharge_Register, ACT_Register, Read_Register; - long *ptr; - - pci_conf_read( 0, 0, 0, 0x02, 2, &Device_ID); - Device_ID &= 0xFFFF; - - //Now, read MMR Base Address - pci_conf_read( 0, 0, 0, 0x48, 4, &dev0); - dev0 &= 0xFFFFC000; - - ptr = (long*)(dev0+0x260); - c0ckectrl = *ptr & 0xFFFFFFFF; - - ptr = (long*)(dev0+0x660); - c1ckectrl = *ptr & 0xFFFFFFFF; - - // If DIMM 0 not populated, check DIMM 1 - ((c0ckectrl) >> 20 & 0xF)?(offset = 0):(offset = 0x400); - - ptr = (long*)(dev0+offset+0x265); - ODT_Control_Register = *ptr & 0xFFFFFFFF; - - ptr = (long*)(dev0+offset+0x25D); - Precharge_Register = *ptr & 0xFFFFFFFF; - - ptr = (long*)(dev0+offset+0x252); - ACT_Register = *ptr & 0xFFFFFFFF; - - ptr = (long*)(dev0+offset+0x258); - Read_Register = *ptr & 0xFFFFFFFF; - - - // CAS Latency (tCAS) - if(Device_ID > 0x2E00 && imc_type != 8) { - cas = ((ODT_Control_Register >> 8)& 0x3F) - 6.0f; - } else { - cas = ((ODT_Control_Register >> 8)& 0x3F) - 9.0f; - } - - // RAS-To-CAS (tRCD) - rcd = (Read_Register >> 17) & 0xF; - - // RAS Precharge (tRP) - rp = (ACT_Register >> 13) & 0xF; - - // RAS Active to precharge (tRAS) - ras = Precharge_Register & 0x3F; - - if ((c0ckectrl >> 20 & 0xF) && (c1ckectrl >> 20 & 0xF)) { - chan = 2; - } else { - chan = 1; - } - print_ram_line(cas, rcd, rp, ras, chan); -} - -static void poll_timings_wmr(void) { - - float cas; - int rcd, rp, ras, chan; - ulong dev0, c0ckectrl, c1ckectrl, offset; - ulong ODT_Control_Register, Precharge_Register, ACT_Register, Read_Register, MRC_Register; - long *ptr; - - //Now, read MMR Base Address - pci_conf_read( 0, 0, 0, 0x48, 4, &dev0); - dev0 &= 0xFFFFC000; - - ptr = (long*)(dev0+0x260); - c0ckectrl = *ptr & 0xFFFFFFFF; - - ptr = (long*)(dev0+0x660); - c1ckectrl = *ptr & 0xFFFFFFFF; - - // If DIMM 0 not populated, check DIMM 1 - ((c0ckectrl) >> 20 & 0xF)?(offset = 0):(offset = 0x400); - - ptr = (long*)(dev0+offset+0x265); - ODT_Control_Register = *ptr & 0xFFFFFFFF; - - ptr = (long*)(dev0+offset+0x25D); - Precharge_Register = *ptr & 0xFFFFFFFF; - - ptr = (long*)(dev0+offset+0x252); - ACT_Register = *ptr & 0xFFFFFFFF; - - ptr = (long*)(dev0+offset+0x258); - Read_Register = *ptr & 0xFFFFFFFF; - - ptr = (long*)(dev0+offset+0x240); - MRC_Register = *ptr & 0xFFFFFFFF; - - // CAS Latency (tCAS) - if(MRC_Register & 0xF) { - cas = (MRC_Register & 0xF) + 3.0f; - } else { - cas = ((ODT_Control_Register >> 8)& 0x3F) - 5.0f; - } - - // RAS-To-CAS (tRCD) - rcd = (Read_Register >> 17) & 0xF; - - // RAS Precharge (tRP) - rp = (ACT_Register >> 13) & 0xF; - - // RAS Active to precharge (tRAS) - ras = Precharge_Register & 0x3F; - - if ((c0ckectrl >> 20 & 0xF) && (c1ckectrl >> 20 & 0xF)) { - chan = 2; - } else { - chan = 1; - } - - print_ram_line(cas, rcd, rp, ras, chan); - -} - -static void poll_timings_snb(void) { - - float cas; - int rcd, rp, ras, chan; - ulong dev0, offset; - ulong IMC_Register, MCMain0_Register, MCMain1_Register; - long *ptr; - - //Now, read MMR Base Address - pci_conf_read( 0, 0, 0, 0x48, 4, &dev0); - dev0 &= 0xFFFFC000; - - offset = 0x0000; - - ptr = (long*)(dev0+offset+0x4000); - IMC_Register = *ptr & 0xFFFFFFFF; - - // CAS Latency (tCAS) - cas = (float)((IMC_Register >> 8) & 0x0F); - - // RAS-To-CAS (tRCD) - rcd = IMC_Register & 0x0F; - - // RAS Precharge (tRP) - rp = (IMC_Register >> 4) & 0x0F; - - // RAS Active to precharge (tRAS) - ras = (IMC_Register >> 16) & 0xFF; - - // Channels - ptr = (long*)(dev0+offset+0x5004); - MCMain0_Register = *ptr & 0xFFFF; - ptr = (long*)(dev0+offset+0x5008); - MCMain1_Register = *ptr & 0xFFFF; - - if(MCMain0_Register == 0 || MCMain1_Register == 0) { - chan = 1; - } else { - chan = 2; - } - - print_ram_line(cas, rcd, rp, ras, chan); -} - -static void poll_timings_hsw(void) { - - float cas; - int rcd, rp, ras, chan; - ulong dev0, offset = 0; - ulong IMC_Register, MCMain0_Register, MCMain1_Register; - long *ptr; - - //Now, read MMR Base Address - pci_conf_read( 0, 0, 0, 0x48, 4, &dev0); - dev0 &= 0xFFFFC000; - - // Channels - ptr = (long*)(dev0+offset+0x5004); - MCMain0_Register = *ptr & 0xFFFF; - - ptr = (long*)(dev0+offset+0x5008); - MCMain1_Register = *ptr & 0xFFFF; - - if(MCMain0_Register && MCMain1_Register) { - chan = 2; - } else { - chan = 1; - } - - if(MCMain0_Register) { offset = 0x0000; } else { offset = 0x0400; } - - // CAS Latency (tCAS) - ptr = (long*)(dev0+offset+0x4014); - IMC_Register = *ptr & 0xFFFFFFFF; - cas = (float)(IMC_Register & 0x1F); - - ptr = (long*)(dev0+offset+0x4000); - IMC_Register = *ptr & 0xFFFFFFFF; - - // RAS-To-CAS (tRCD) - rcd = IMC_Register & 0x1F; - - // RAS Precharge (tRP) - rp = (IMC_Register >> 5) & 0x1F; - - // RAS Active to precharge (tRAS) - ras = (IMC_Register >> 10) & 0x3F; - - - print_ram_line(cas, rcd, rp, ras, chan); -} - -static void poll_timings_snbe(void) { - - float cas; - int rcd, rp, ras; - int nb_channel = 0, current_channel = 0; - ulong temp, IMC_Register; - long *ptr; - - //Read Channel #1 - pci_conf_read(0xFF, 16, 2, 0x80, 4, &temp); - temp &= 0x3F; - if(temp != 0xB) { current_channel = 0; nb_channel++; } - - //Read Channel #2 - pci_conf_read(0xFF, 16, 3, 0x80, 4, &temp); - temp &= 0x3F; - if(temp != 0xB) { current_channel = 1; nb_channel++; } - - //Read Channel #3 - pci_conf_read(0xFF, 16, 6, 0x80, 4, &temp); - temp &= 0x3F; - if(temp != 0xB) { current_channel = 4; nb_channel++; } - - //Read Channel #4 - pci_conf_read(0xFF, 16, 7, 0x80, 4, &temp); - temp &= 0x3F; - if(temp != 0xB) { current_channel = 5; nb_channel++; } - - - pci_conf_read(0, 5, 0, 0x84, 4, &temp); - ptr = (long*)((temp & 0xFC000000) + (MAKE_PCIE_ADDRESS(0xFF,16,current_channel) | 0x200)); - IMC_Register = *ptr & 0xFFFFFFFF; - - // CAS Latency (tCAS) - cas = (float)((IMC_Register >> 9) & 0x1F); - - // RAS-To-CAS (tRCD) - rcd = IMC_Register & 0x1F; - - // RAS Precharge (tRP) - rp = (IMC_Register >> 5) & 0x0F; - - // RAS Active to precharge (tRAS) - ras = (IMC_Register >> 19) & 0x3F; - - - print_ram_line(cas, rcd, rp, ras, nb_channel); - -} - -static void poll_timings_5400(void) { - - // Thanks for CDH optis - ulong ambase, mtr1, mtr2, offset, mca; - long *ptr; - float cas; - int rcd, rp, ras, chan; - - //Hard-coded Ambase value (should not be realocated by software when using Memtest86+ - ambase = 0xFE000000; - offset = mtr1 = mtr2 = 0; - - // Will loop until a valid populated channel is found - // Bug : DIMM 0 must be populated or it will fall in an endless loop - while(((mtr2 & 0xF) < 3) || ((mtr2 & 0xF) > 6)) { - ptr = (long*)(ambase+0x378+offset); - mtr1 = *ptr & 0xFFFFFFFF; - - ptr = (long*)(ambase+0x37C+offset); - mtr2 = *ptr & 0xFFFFFFFF; - offset += 0x8000; - } - - pci_conf_read( 0, 16, 1, 0x58, 4, &mca); - - //This chipset only supports FB-DIMM (Removed => too long) - //cprint(LINE_CPU+5, col +1, "- Type : FBD"); - - // Now, detect timings - - // CAS Latency (tCAS) - cas = mtr2 & 0xF; - - // RAS-To-CAS (tRCD) - rcd = 6 - ((mtr1 >> 10) & 3); - - // RAS Precharge (tRP) - rp = 6 - ((mtr1 >> 8) & 3); - - // RAS Active to precharge (tRAS) - ras = 16 - (3 * ((mtr1 >> 29) & 3)) + ((mtr1 >> 12) & 3); - if(((mtr1 >> 12) & 3) == 3 && ((mtr1 >> 29) & 3) == 2) { ras = 9; } - - - if ((mca >> 14) & 1) { - chan = 1; - } else { - chan = 2; - } - - print_ram_line(cas, rcd, rp, ras, chan); - -} - -static void poll_timings_E7520(void) { - - ulong drt, ddrcsr; - float cas; - int rcd, rp, ras, chan; - - pci_conf_read( 0, 0, 0, 0x78, 4, &drt); - pci_conf_read( 0, 0, 0, 0x9A, 2, &ddrcsr); - - cas = ((drt >> 2) & 3) + 2; - rcd = ((drt >> 10) & 1) + 3; - rp = ((drt >> 9) & 1) + 3; - ras = ((drt >> 14) & 3) + 11; - - if ((ddrcsr & 0xF) >= 0xC) { - chan = 2; - } else { - chan = 1; - } - - print_ram_line(cas, rcd, rp, ras, chan); -} - - -static void poll_timings_i855(void) { - - ulong drt, temp; - float cas; - int rcd, rp, ras; - - pci_conf_read( 0, 0, 0, 0x78, 4, &drt); - - /* Now, we could print some additionnals timings infos) */ - cprint(LINE_CPU+6, col2 +1, "/ CAS : "); - col2 += 9; - - // CAS Latency (tCAS) - temp = ((drt >> 4)&0x1); - if (temp == 0x0) { cas = 2.5; } - else { cas = 2; } - - // RAS-To-CAS (tRCD) - temp = ((drt >> 2)& 0x1); - if (temp == 0x0) { rcd = 3; } - else { rcd = 2; } - - // RAS Precharge (tRP) - temp = (drt&0x1); - if (temp == 0x0) { rp = 3 ; } - else { rp = 2; } - - // RAS Active to precharge (tRAS) - temp = 7-((drt >> 9)& 0x3); - if (temp == 0x0) { ras = 7; } - if (temp == 0x1) { ras = 6; } - if (temp == 0x2) { ras = 5; } - - print_ram_line(cas, rcd, rp, ras, 1); - -} - -static void poll_timings_E750x(void) { - - ulong drt, drc, temp; - float cas; - int rcd, rp, ras, chan; - - pci_conf_read( 0, 0, 0, 0x78, 4, &drt); - pci_conf_read( 0, 0, 0, 0x7C, 4, &drc); - - if ((drt >> 4) & 1) { cas = 2; } else { cas = 2.5; }; - if ((drt >> 1) & 1) { rcd = 2; } else { rcd = 3; }; - if (drt & 1) { rp = 2; } else { rp = 3; }; - - temp = ((drt >> 9) & 3); - if (temp == 2) { ras = 5; } else if (temp == 1) { ras = 6; } else { ras = 7; } - - if (((drc >> 22)&1) == 1) { - chan = 2; - } else { - chan = 1; - } - - print_ram_line(cas, rcd, rp, ras, chan); - -} - -static void poll_timings_i852(void) { - - ulong drt, temp; - float cas; - int rcd, rp, ras; - - pci_conf_read( 0, 0, 1, 0x60, 4, &drt); - - /* Now, we could print some additionnals timings infos) */ - cprint(LINE_CPU+6, col2 +1, "/ CAS : "); - col2 += 9; - - // CAS Latency (tCAS) - temp = ((drt >> 5)&0x1); - if (temp == 0x0) { cas = 2.5; } - else { cas = 2; } - - // RAS-To-CAS (tRCD) - temp = ((drt >> 2)& 0x3); - if (temp == 0x0) { rcd = 4; } - if (temp == 0x1) { rcd = 3; } - else { rcd = 2; } - - // RAS Precharge (tRP) - temp = (drt&0x3); - if (temp == 0x0) { rp = 4; } - if (temp == 0x1) { rp = 3; } - else { rp = 2; } - - // RAS Active to precharge (tRAS) - temp = ((drt >> 9)& 0x3); - if (temp == 0x0) { ras = 8; } - if (temp == 0x1) { ras = 7; } - if (temp == 0x2) { ras = 6; } - if (temp == 0x3) { ras = 5; } - - print_ram_line(cas, rcd, rp, ras, 1); - -} - -static void poll_timings_amd64(void) { - - ulong dramtlr, dramclr; - int temp, chan; - float tcas; - int trcd, trp, tras ; - - pci_conf_read(0, 24, 2, 0x88, 4, &dramtlr); - pci_conf_read(0, 24, 2, 0x90, 4, &dramclr); - - if (cpu_id.vers.bits.extendedModel >= 4) { - /* NEW K8 0Fh Family 90 nm (DDR2) */ - - // CAS Latency (tCAS) - tcas = (dramtlr & 0x7) + 1; - - // RAS-To-CAS (tRCD) - trcd = ((dramtlr >> 4) & 0x3) + 3; - - // RAS Precharge (tRP) - trp = ((dramtlr >> 8) & 0x3) + 3; - - // RAS Active to precharge (tRAS) - tras = ((dramtlr >> 12) & 0xF) + 3; - - // Print 64 or 128 bits mode - if ((dramclr >> 11)&1) { - chan = 2; - } else { - chan = 1; - } - - } else { - /* OLD K8 (DDR1) */ - - // CAS Latency (tCAS) - temp = (dramtlr & 0x7); - if (temp == 0x1) { tcas = 2; } - if (temp == 0x2) { tcas = 3; } - if (temp == 0x5) { tcas = 2.5; } - - // RAS-To-CAS (tRCD) - trcd = ((dramtlr >> 12) & 0x7); - - // RAS Precharge (tRP) - trp = ((dramtlr >> 24) & 0x7); - - // RAS Active to precharge (tRAS) - tras = ((dramtlr >> 20) & 0xF); - - // Print 64 or 128 bits mode - if (((dramclr >> 16)&1) == 1) { - chan = 2; - } else { - chan = 1; - } - } - - print_ram_line(tcas, trcd, trp, tras, chan); - -} - -static void poll_timings_k10(void) { - - ulong dramtlr, dramclr, dramchr, dramchrb; - ulong offset = 0; - int cas, rcd, rp, ras, chan; - - pci_conf_read(0, 24, 2, 0x94, 4, &dramchr); - pci_conf_read(0, 24, 2, 0x194, 4, &dramchrb); - - if(((dramchr>>14) & 0x1) || ((dramchr>>14) & 0x1)) { chan = 1; } else { chan = 2; } - - // If Channel A not enabled, switch to channel B - if(((dramchr>>14) & 0x1)) - { - offset = 0x100; - pci_conf_read(0, 24, 2, 0x94+offset, 4, &dramchr); - } - - pci_conf_read(0, 24, 2, 0x88+offset, 4, &dramtlr); - pci_conf_read(0, 24, 2, 0x110, 4, &dramclr); - - // CAS Latency (tCAS) - if(((dramchr >> 8)&1) || ((dramchr & 0x7) == 0x4)){ - // DDR3 or DDR2-1066 - cas = (dramtlr & 0xF) + 4; - rcd = ((dramtlr >> 4) & 0x7) + 5; - rp = ((dramtlr >> 7) & 0x7) + 5; - ras = ((dramtlr >> 12) & 0xF) + 15; - } else { - // DDR2-800 or less - cas = (dramtlr & 0xF) + 1; - rcd = ((dramtlr >> 4) & 0x3) + 3; - rp = ((dramtlr >> 8) & 0x3) + 3; - ras = ((dramtlr >> 12) & 0xF) + 3; - } - - print_ram_line(cas, rcd, rp, ras, chan); -} - -static void poll_timings_k12(void) { - - ulong dramt0, dramlow, dimma, dimmb; - int cas, rcd, rp, ras, chan = 0; - - pci_conf_read(0, 24, 2, 0x94, 4, &dimma); - pci_conf_read(0, 24, 2, 0x194, 4, &dimmb); - - if(((dimma >> 14) & 0x1) == 0) - { - chan++; - pci_conf_read(0, 24, 2, 0x88, 4, &dramlow); - pci_conf_write(0, 24, 2, 0xF0, 4, 0x00000040); - pci_conf_read(0, 24, 2, 0xF4, 4, &dramt0); - } - - if(((dimmb >> 14) & 0x1) == 0) - { - chan++; - pci_conf_read(0, 24, 2, 0x188, 4, &dramlow); - pci_conf_write(0, 24, 2, 0x1F0, 4, 0x00000040); - pci_conf_read(0, 24, 2, 0x1F4, 4, &dramt0); - } - - cas = (dramlow & 0xF) + 4; - rcd = (dramt0 & 0xF) + 5; - rp = ((dramt0 >> 8) & 0xF) + 5; - ras = ((dramt0 >> 16) & 0x1F) + 15; - - print_ram_line(cas, rcd, rp, ras, chan); -} - - -static void poll_timings_k14(void) { - - ulong dramt0, dramlow; - int cas, rcd, rp, ras; - - pci_conf_read(0, 24, 2, 0x88, 4, &dramlow); - pci_conf_write(0, 24, 2, 0xF0, 4, 0x00000040); - pci_conf_read(0, 24, 2, 0xF4, 4, &dramt0); - - cas = (dramlow & 0xF) + 4; - rcd = (dramt0 & 0xF) + 5; - rp = ((dramt0 >> 8) & 0xF) + 5; - ras = ((dramt0 >> 16) & 0x1F) + 15; - - print_ram_line(cas, rcd, rp, ras, 1); -} - -static void poll_timings_k15(void) { - - ulong dramp1, dramp2, dimma, dimmb; - int cas, rcd, rp, ras, chan = 0; - - pci_conf_read(0, 24, 2, 0x94, 4, &dimma); - pci_conf_read(0, 24, 2, 0x194, 4, &dimmb); - if(((dimma>>14) & 0x1) || ((dimmb>>14) & 0x1)) { chan = 1; } else { chan = 2; } - - pci_conf_read(0, 24, 2, 0x200, 4, &dramp1); - pci_conf_read(0, 24, 2, 0x204, 4, &dramp2); - - cas = dramp1 & 0x1F; - rcd = (dramp1 >> 8) & 0x1F; - rp = (dramp1 >> 16) & 0x1F; - ras = (dramp1 >> 24) & 0x3F; - - print_ram_line(cas, rcd, rp, ras, chan); -} - -static void poll_timings_k16(void) { - - ulong dramt0, dramt1; - int cas, rcd, rp, /*rc,*/ ras; - - pci_conf_read(0, 24, 2, 0x200, 4, &dramt0); - pci_conf_read(0, 24, 2, 0x204, 4, &dramt1); - - cas = (dramt0 & 0x1F); - rcd = ((dramt0 >> 8) & 0x1F); - rp = ((dramt0 >> 16) & 0x1F); - ras = ((dramt0 >> 24) & 0x3F); - - // rc = (dramt1 & 0x3F); - - print_ram_line(cas, rcd, rp, ras, 1); -} - -static void poll_timings_EP80579(void) { - - ulong drt1, drt2; - float cas; - int rcd, rp, ras; - - pci_conf_read( 0, 0, 0, 0x78, 4, &drt1); - pci_conf_read( 0, 0, 0, 0x64, 4, &drt2); - - cas = ((drt1 >> 3) & 0x7) + 3; - rcd = ((drt1 >> 9) & 0x7) + 3; - rp = ((drt1 >> 6) & 0x7) + 3; - ras = ((drt2 >> 28) & 0xF) + 8; - - print_ram_line(cas, rcd, rp, ras, 0); -} - -static void poll_timings_nf2(void) { - - ulong dramtlr, dramtlr2, dramtlr3, temp; - ulong dimm1p, dimm2p, dimm3p; - float cas; - int rcd, rp, ras, chan; - - pci_conf_read(0, 0, 1, 0x90, 4, &dramtlr); - pci_conf_read(0, 0, 1, 0xA0, 4, &dramtlr2); - pci_conf_read(0, 0, 1, 0x84, 4, &dramtlr3); - pci_conf_read(0, 0, 2, 0x40, 4, &dimm1p); - pci_conf_read(0, 0, 2, 0x44, 4, &dimm2p); - pci_conf_read(0, 0, 2, 0x48, 4, &dimm3p); - - // CAS Latency (tCAS) - temp = ((dramtlr2 >> 4) & 0x7); - if (temp == 0x2) { cas = 2; } - if (temp == 0x3) { cas = 3; } - if (temp == 0x6) { cas = 2.5; } - - // RAS-To-CAS (tRCD) - rcd = ((dramtlr >> 20) & 0xF); - - // RAS Precharge (tRP) - rp = ((dramtlr >> 28) & 0xF); - - // RAS Active to precharge (tRAS) - ras = ((dramtlr >> 15) & 0xF); - - // Print 64 or 128 bits mode - // If DIMM1 & DIMM3 or DIMM1 & DIMM2 populated, than Dual Channel. - - if ((dimm3p&1) + (dimm2p&1) == 2 || (dimm3p&1) + (dimm1p&1) == 2 ) { - chan = 2; - } else { - chan = 1; - } - print_ram_line(cas, rcd, rp, ras, chan); -} - -static void poll_timings_us15w(void) { - - // Thanks for CDH optis - ulong dtr; - float cas; - int rcd, rp; - - /* Find dramratio */ - /* D0 MsgRd, 01 Dunit, 01 DTR */ - pci_conf_write(0, 0, 0, 0xD0, 4, 0xD0010100 ); - pci_conf_read(0, 0, 0, 0xD4, 4, &dtr ); - - // CAS Latency (tCAS) - cas = ((dtr >> 4) & 0x3) + 3; - - // RAS-To-CAS (tRCD) - rcd = ((dtr >> 2) & 0x3) + 3; - - // RAS Precharge (tRP) - rp = ((dtr >> 0) & 0x3) + 3; - - print_ram_line(cas, rcd, rp, 9, 1); - -} - -static void poll_timings_nhm(void) { - - ulong mc_channel_bank_timing, mc_control, mc_channel_mrs_value; - float cas; - int rcd, rp, ras, chan; - int fvc_bn = 4; - - /* Find which channels are populated */ - pci_conf_read(nhm_bus, 3, 0, 0x48, 2, &mc_control); - mc_control = (mc_control >> 8) & 0x7; - - /* Get the first valid channel */ - if(mc_control & 1) { - fvc_bn = 4; - } else if(mc_control & 2) { - fvc_bn = 5; - } else if(mc_control & 4) { - fvc_bn = 6; - } - - // Now, detect timings - // CAS Latency (tCAS) / RAS-To-CAS (tRCD) / RAS Precharge (tRP) / RAS Active to precharge (tRAS) - pci_conf_read(nhm_bus, fvc_bn, 0, 0x88, 4, &mc_channel_bank_timing); - pci_conf_read(nhm_bus, fvc_bn, 0, 0x70, 4, &mc_channel_mrs_value); - cas = ((mc_channel_mrs_value >> 4) & 0xF ) + 4.0f; - rcd = (mc_channel_bank_timing >> 9) & 0xF; - ras = (mc_channel_bank_timing >> 4) & 0x1F; - rp = mc_channel_bank_timing & 0xF; - - // Print 1, 2 or 3 Channels - if (mc_control == 1 || mc_control == 2 || mc_control == 4 ) { - chan = 1; - } else if (mc_control == 7) { - chan = 3; - } else { - chan = 2; - } - print_ram_line(cas, rcd, rp, ras, chan); - -} - -static void poll_timings_ct(void) -{ - - unsigned long mcr,mdr; - float cas; - int rcd, rp, ras; - - /* Build the MCR Message*/ - mcr = (0x10 << 24); // 10h = Read - 11h = Write - mcr += (0x01 << 16); // DRAM Registers located on port 01h - mcr += (0x01 << 8); // DRP = 00h, DTR0 = 01h, DTR1 = 02h, DTR2 = 03h - mcr &= 0xFFFFFFF0; // bit 03:00 RSVD - - /* Send Message to GMCH */ - pci_conf_write(0, 0, 0, 0xD0, 4, mcr); - - /* Read Answer from Sideband bus */ - pci_conf_read(0, 0, 0, 0xD4, 4, &mdr); - - // CAS Latency (tCAS) - cas = ((mdr >> 12)& 0x7) + 5.0f; - - // RAS-To-CAS (tRCD) - rcd = ((mdr >> 8)& 0x7) + 5; - - // RAS Precharge (tRP) - rp = ((mdr >> 4)& 0x7) + 5; - - // RAS is in DTR1. Read Again. - mcr = 0x10010200; // Quick Mode ! Awesome ! - pci_conf_write(0, 0, 0, 0xD0, 4, mcr); - pci_conf_read(0, 0, 0, 0xD4, 4, &mdr); - - // RAS Active to precharge (tRAS) - ras = (mdr >> 20) & 0xF; - - // Print - print_ram_line(cas, rcd, rp, ras, 1); - -} - -/* ------------------ Let's continue ------------------ */ -/* ---------------------------------------------------- */ - -struct pci_memory_controller controllers[] = { - /* Default unknown chipset */ - { 0, 0, "","", 0, poll_fsb_nothing, poll_timings_nothing, setup_nothing, poll_nothing }, - - /* AMD */ - { 0x1022, 0x7006, "AMD 751","SDRAM PC-100", 0, poll_fsb_nothing, poll_timings_nothing, setup_amd751, poll_nothing }, - { 0x1022, 0x700c, "AMD 762","DDR-SDRAM", 0, poll_fsb_nothing, poll_timings_nothing, setup_amd76x, poll_nothing }, - { 0x1022, 0x700e, "AMD 761","DDR-SDRAM", 0, poll_fsb_nothing, poll_timings_nothing, setup_amd76x, poll_nothing }, - - /* SiS */ - { 0x1039, 0x0600, "SiS 600","EDO/SDRAM", 0, poll_fsb_nothing, poll_timings_nothing, setup_nothing, poll_nothing }, - { 0x1039, 0x0620, "SiS 620","SDRAM", 0, poll_fsb_nothing, poll_timings_nothing, setup_nothing, poll_nothing }, - { 0x1039, 0x5600, "SiS 5600","SDRAM", 0, poll_fsb_nothing, poll_timings_nothing, setup_nothing, poll_nothing }, - { 0x1039, 0x0645, "SiS 645","DDR-SDRAM", 0, poll_fsb_p4, poll_timings_nothing, setup_nothing, poll_nothing }, - { 0x1039, 0x0646, "SiS 645DX","DDR-SDRAM", 0, poll_fsb_p4, poll_timings_nothing, setup_nothing, poll_nothing }, - { 0x1039, 0x0630, "SiS 630","SDRAM", 0, poll_fsb_nothing, poll_timings_nothing, setup_nothing, poll_nothing }, - { 0x1039, 0x0650, "SiS 650","DDR-SDRAM", 0, poll_fsb_p4, poll_timings_nothing, setup_nothing, poll_nothing }, - { 0x1039, 0x0651, "SiS 651","DDR-SDRAM", 0, poll_fsb_p4, poll_timings_nothing, setup_nothing, poll_nothing }, - { 0x1039, 0x0730, "SiS 730","SDRAM", 0, poll_fsb_nothing, poll_timings_nothing, setup_nothing, poll_nothing }, - { 0x1039, 0x0735, "SiS 735","DDR-SDRAM", 0, poll_fsb_amd32, poll_timings_nothing, setup_nothing, poll_nothing }, - { 0x1039, 0x0740, "SiS 740","DDR-SDRAM", 0, poll_fsb_amd32, poll_timings_nothing, setup_nothing, poll_nothing }, - { 0x1039, 0x0745, "SiS 745","DDR-SDRAM", 0, poll_fsb_amd32, poll_timings_nothing, setup_nothing, poll_nothing }, - { 0x1039, 0x0748, "SiS 748","DDR-SDRAM", 0, poll_fsb_amd32, poll_timings_nothing, setup_nothing, poll_nothing }, - { 0x1039, 0x0655, "SiS 655","DDR-SDRAM", 0, poll_fsb_p4, poll_timings_nothing, setup_nothing, poll_nothing }, - { 0x1039, 0x0656, "SiS 656","DDR/DDR2-SDRAM", 0, poll_fsb_p4, poll_timings_nothing, setup_nothing, poll_nothing }, - { 0x1039, 0x0648, "SiS 648","DDR-SDRAM", 0, poll_fsb_p4, poll_timings_nothing, setup_nothing, poll_nothing }, - { 0x1039, 0x0649, "SiS 649","DDR-SDRAM", 0, poll_fsb_p4, poll_timings_nothing, setup_nothing, poll_nothing }, - { 0x1039, 0x0661, "SiS 661","DDR-SDRAM", 0, poll_fsb_p4, poll_timings_nothing, setup_nothing, poll_nothing }, - { 0x1039, 0x0671, "SiS 671","DDR2-SDRAM", 0, poll_fsb_p4, poll_timings_nothing, setup_nothing, poll_nothing }, - { 0x1039, 0x0672, "SiS 672","DDR2-SDRAM", 0, poll_fsb_p4, poll_timings_nothing, setup_nothing, poll_nothing }, - - /* ALi */ - { 0x10b9, 0x1531, "ALi Aladdin 4","EDO/SDRAM", 0, poll_fsb_nothing, poll_timings_nothing, setup_nothing, poll_nothing }, - { 0x10b9, 0x1541, "ALi Aladdin 5","EDO/SDRAM", 0, poll_fsb_nothing, poll_timings_nothing, setup_nothing, poll_nothing }, - { 0x10b9, 0x1644, "ALi Aladdin M1644","SDRAM", 0, poll_fsb_nothing, poll_timings_nothing, setup_nothing, poll_nothing }, - - /* ATi */ - { 0x1002, 0x5830, "ATi Radeon 9100 IGP","DDR-SDRAM", 0, poll_fsb_p4, poll_timings_nothing, setup_nothing, poll_nothing }, - { 0x1002, 0x5831, "ATi Radeon 9100 IGP","DDR-SDRAM", 0, poll_fsb_p4, poll_timings_nothing, setup_nothing, poll_nothing }, - { 0x1002, 0x5832, "ATi Radeon 9100 IGP","DDR-SDRAM", 0, poll_fsb_p4, poll_timings_nothing, setup_nothing, poll_nothing }, - { 0x1002, 0x5833, "ATi Radeon 9100 IGP","DDR-SDRAM", 0, poll_fsb_p4, poll_timings_nothing, setup_nothing, poll_nothing }, - { 0x1002, 0x5954, "ATi Xpress 200","DDR-SDRAM", 0, poll_fsb_p4, poll_timings_nothing, setup_nothing, poll_nothing }, - { 0x1002, 0x5A41, "ATi Xpress 200","DDR-SDRAM", 0, poll_fsb_p4, poll_timings_nothing, setup_nothing, poll_nothing }, - - /* nVidia */ - { 0x10de, 0x01A4, "nVidia nForce","DDR-SDRAM", 0, poll_fsb_nothing, poll_timings_nothing, setup_nothing, poll_nothing }, - { 0x10de, 0x01E0, "nVidia nForce2 SPP","", 0, poll_fsb_nf2, poll_timings_nf2, setup_nothing, poll_nothing }, - { 0x10de, 0x0071, "nForce4 SLI","", 0, poll_fsb_nf4ie, poll_timings_nf4ie, setup_nothing, poll_nothing }, - - /* VIA */ - { 0x1106, 0x0305, "VIA KT133/KT133A","SDRAM", 0, poll_fsb_nothing, poll_timings_nothing, setup_nothing, poll_nothing }, - { 0x1106, 0x0391, "VIA KX133","SDRAM", 0, poll_fsb_nothing, poll_timings_nothing, setup_nothing, poll_nothing }, - { 0x1106, 0x0501, "VIA MVP4","EDO/SDRAM", 0, poll_fsb_nothing, poll_timings_nothing, setup_nothing, poll_nothing }, - { 0x1106, 0x0585, "VIA VP/VPX","EDO/SDRAM", 0, poll_fsb_nothing, poll_timings_nothing, setup_nothing, poll_nothing }, - { 0x1106, 0x0595, "VIA VP2","EDO/SDRAM", 0, poll_fsb_nothing, poll_timings_nothing, setup_nothing, poll_nothing }, - { 0x1106, 0x0597, "VIA VP3","EDO/SDRAM", 0, poll_fsb_nothing, poll_timings_nothing, setup_nothing, poll_nothing }, - { 0x1106, 0x0598, "VIA MVP3","EDO/SDRAM", 0, poll_fsb_nothing, poll_timings_nothing, setup_nothing, poll_nothing }, - { 0x1106, 0x0691, "VIA Apollo Pro 133(A)","SDRAM", 0, poll_fsb_nothing, poll_timings_nothing, setup_nothing, poll_nothing }, - { 0x1106, 0x0693, "VIA Apollo Pro+","SDRAM", 0, poll_fsb_nothing, poll_timings_nothing, setup_nothing, poll_nothing }, - { 0x1106, 0x0601, "VIA PLE133","SDRAM", 0, poll_fsb_nothing, poll_timings_nothing, setup_nothing, poll_nothing }, - { 0x1106, 0x3099, "VIA KT266(A)/KT333","DDR-SDRAM", 0, poll_fsb_nothing, poll_timings_nothing, setup_nothing, poll_nothing }, - { 0x1106, 0x3189, "VIA KT400(A)/600","DDR-SDRAM", 0, poll_fsb_nothing, poll_timings_nothing, setup_nothing, poll_nothing }, - { 0x1106, 0x0269, "VIA KT880","DDR-SDRAM", 0, poll_fsb_nothing, poll_timings_nothing, setup_nothing, poll_nothing }, - { 0x1106, 0x3205, "VIA KM400","DDR-SDRAM", 0, poll_fsb_nothing, poll_timings_nothing, setup_nothing, poll_nothing }, - { 0x1106, 0x3116, "VIA KM266","DDR-SDRAM", 0, poll_fsb_nothing, poll_timings_nothing, setup_nothing, poll_nothing }, - { 0x1106, 0x3156, "VIA KN266","DDR-SDRAM", 0, poll_fsb_nothing, poll_timings_nothing, setup_nothing, poll_nothing }, - { 0x1106, 0x3123, "VIA CLE266","DDR-SDRAM", 0, poll_fsb_nothing, poll_timings_nothing, setup_nothing, poll_nothing }, - { 0x1106, 0x0198, "VIA PT800","DDR-SDRAM", 0, poll_fsb_nothing, poll_timings_nothing, setup_nothing, poll_nothing }, - { 0x1106, 0x3258, "VIA PT880","DDR2-SDRAM", 0, poll_fsb_nothing, poll_timings_nothing, setup_nothing, poll_nothing }, - - /* Serverworks */ - { 0x1166, 0x0008, "CNB20HE","SDRAM", 0, poll_fsb_nothing, poll_timings_nothing, setup_cnb20, poll_nothing }, - { 0x1166, 0x0009, "CNB20LE","SDRAM", 0, poll_fsb_nothing, poll_timings_nothing, setup_cnb20, poll_nothing }, - - /* Intel */ - { 0x8086, 0x1130, "Intel i815","SDRAM", 0, poll_fsb_nothing, poll_timings_nothing, setup_nothing, poll_nothing }, - { 0x8086, 0x122d, "Intel i430FX","EDO DRAM",0, poll_fsb_nothing, poll_timings_nothing, setup_nothing, poll_nothing }, - { 0x8086, 0x1235, "Intel i430MX","EDO DRAM",0, poll_fsb_nothing, poll_timings_nothing, setup_nothing, poll_nothing }, - { 0x8086, 0x1237, "Intel i440FX","EDO DRAM",0, poll_fsb_nothing, poll_timings_nothing, setup_nothing, poll_nothing }, - { 0x8086, 0x1250, "Intel i430HX","EDO DRAM",0, poll_fsb_nothing, poll_timings_nothing, setup_nothing, poll_nothing }, - { 0x8086, 0x1A21, "Intel i840","RDRAM", 0, poll_fsb_nothing, poll_timings_nothing, setup_i840, poll_nothing }, - { 0x8086, 0x1A30, "Intel i845","SDR/DDR", 0, poll_fsb_p4, poll_timings_nothing, setup_i845, poll_nothing }, - { 0x8086, 0x2560, "Intel i845E/G/PE/GE","", 0, poll_fsb_p4, poll_timings_nothing, setup_i845, poll_nothing }, - { 0x8086, 0x2500, "Intel i820","RDRAM", 0, poll_fsb_nothing, poll_timings_nothing, setup_i820, poll_nothing }, - { 0x8086, 0x2530, "Intel i850","RDRAM", 0, poll_fsb_p4, poll_timings_nothing, setup_i850, poll_nothing }, - { 0x8086, 0x2531, "Intel i860","RDRAM", 0, poll_fsb_nothing, poll_timings_nothing, setup_i860, poll_nothing }, - { 0x8086, 0x7030, "Intel i430VX","SDRAM", 0, poll_fsb_nothing, poll_timings_nothing, setup_nothing, poll_nothing }, - { 0x8086, 0x7100, "Intel i430TX","SDRAM", 0, poll_fsb_nothing, poll_timings_nothing, setup_nothing, poll_nothing }, - { 0x8086, 0x7120, "Intel i810","SDRAM", 0, poll_fsb_nothing, poll_timings_nothing, setup_nothing, poll_nothing }, - { 0x8086, 0x7122, "Intel i810","SDRAM", 0, poll_fsb_nothing, poll_timings_nothing, setup_nothing, poll_nothing }, - { 0x8086, 0x7124, "Intel i810E","SDRAM", 0, poll_fsb_nothing, poll_timings_nothing, setup_nothing, poll_nothing }, - { 0x8086, 0x7180, "Intel i440[LE]X","SDRAM",0, poll_fsb_nothing, poll_timings_nothing, setup_nothing, poll_nothing }, - { 0x8086, 0x7190, "Intel i440BX","SDRAM", 0, poll_fsb_nothing, poll_timings_nothing, setup_nothing, poll_nothing }, - { 0x8086, 0x7192, "Intel i440BX","SDRAM", 0, poll_fsb_nothing, poll_timings_nothing, setup_nothing, poll_nothing }, - { 0x8086, 0x71A0, "Intel i440GX","SDRAM", 0, poll_fsb_nothing, poll_timings_nothing, setup_i440gx, poll_nothing }, - { 0x8086, 0x71A2, "Intel i440GX","SDRAM", 0, poll_fsb_nothing, poll_timings_nothing, setup_i440gx, poll_nothing }, - { 0x8086, 0x84C5, "Intel i450GX","SDRAM", 0, poll_fsb_nothing, poll_timings_nothing, setup_nothing, poll_nothing }, - { 0x8086, 0x2540, "Intel E7500","DDR-SDRAM",0, poll_fsb_p4, poll_timings_E750x, setup_iE7xxx, poll_nothing }, - { 0x8086, 0x254C, "Intel E7501","DDR-SDRAM",0, poll_fsb_p4, poll_timings_E750x, setup_iE7xxx, poll_nothing }, - { 0x8086, 0x255d, "Intel E7205","DDR-SDRAM",0, poll_fsb_p4, poll_timings_nothing, setup_iE7xxx, poll_nothing }, - { 0x8086, 0x3592, "Intel E7320","DDR-SDRAM",0, poll_fsb_p4, poll_timings_E7520, setup_iE7520, poll_nothing }, - { 0x8086, 0x2588, "Intel E7221","DDR-SDRAM",0, poll_fsb_i925, poll_timings_i925, setup_i925, poll_nothing }, - { 0x8086, 0x3590, "Intel E7520","DDR-SDRAM",0, poll_fsb_p4, poll_timings_E7520, setup_iE7520, poll_nothing }, - { 0x8086, 0x2600, "Intel E8500","DDR-SDRAM",0, poll_fsb_p4, poll_timings_nothing, setup_nothing, poll_nothing }, - { 0x8086, 0x2570, "Intel i848/i865","", 0, poll_fsb_i875, poll_timings_i875, setup_i875, poll_nothing }, - { 0x8086, 0x2578, "Intel i875P","", 0, poll_fsb_i875, poll_timings_i875, setup_i875, poll_nothing }, - { 0x8086, 0x2550, "Intel E7505","DDR-SDRAM",0, poll_fsb_p4, poll_timings_nothing, setup_iE7xxx, poll_nothing }, - { 0x8086, 0x3580, "Intel i852P/i855G","", 0, poll_fsb_i855, poll_timings_i852, setup_nothing, poll_nothing }, - { 0x8086, 0x3340, "Intel i855PM","", 0, poll_fsb_i855, poll_timings_i855, setup_nothing, poll_nothing }, - { 0x8086, 0x2580, "Intel i915P/G","", 0, poll_fsb_i925, poll_timings_i925, setup_i925, poll_nothing }, - { 0x8086, 0x2590, "Intel i915PM/GM","", 0, poll_fsb_i925, poll_timings_i925, setup_i925, poll_nothing }, - { 0x8086, 0x2584, "Intel i925X/XE","", 0, poll_fsb_i925, poll_timings_i925, setup_i925, poll_nothing }, - { 0x8086, 0x2770, "Intel i945P/G","", 0, poll_fsb_i945, poll_timings_i925, setup_i925, poll_nothing }, - { 0x8086, 0x27A0, "Intel i945GM/PM","", 0, poll_fsb_i945, poll_timings_i925, setup_i925, poll_nothing }, - { 0x8086, 0x27AC, "Intel i945GME","", 0, poll_fsb_i945gme, poll_timings_i925, setup_i925, poll_nothing }, - { 0x8086, 0x2774, "Intel i955X","", 0, poll_fsb_i945, poll_timings_i925, setup_i925, poll_nothing}, - { 0x8086, 0x277C, "Intel i975X","", 0, poll_fsb_i975, poll_timings_i925, setup_i925, poll_nothing}, - { 0x8086, 0x2970, "Intel i946PL/GZ","", 0, poll_fsb_i965, poll_timings_i965, setup_p35, poll_nothing}, - { 0x8086, 0x2990, "Intel Q963/Q965","", 0, poll_fsb_i965, poll_timings_i965, setup_p35, poll_nothing}, - { 0x8086, 0x29A0, "Intel P965/G965","", 0, poll_fsb_i965, poll_timings_i965, setup_p35, poll_nothing}, - { 0x8086, 0x2A00, "Intel GM965/GL960","", 0, poll_fsb_im965, poll_timings_im965, setup_p35, poll_nothing}, - { 0x8086, 0x2A10, "Intel GME965/GLE960","", 0, poll_fsb_im965, poll_timings_im965, setup_p35, poll_nothing}, - { 0x8086, 0x2A40, "Intel PM/GM45/47","", 0, poll_fsb_im965, poll_timings_im965, setup_p35, poll_nothing}, - { 0x8086, 0x29B0, "Intel Q35","", 0, poll_fsb_p35, poll_timings_p35, setup_p35, poll_nothing}, - { 0x8086, 0x29C0, "Intel P35/G33","", 0, poll_fsb_p35, poll_timings_p35, setup_p35, poll_nothing}, - { 0x8086, 0x29D0, "Intel Q33","", 0, poll_fsb_p35, poll_timings_p35, setup_p35, poll_nothing}, - { 0x8086, 0x29E0, "Intel X38/X48","", 0, poll_fsb_p35, poll_timings_p35, setup_p35, poll_nothing}, - { 0x8086, 0x29F0, "Intel 3200/3210","", 0, poll_fsb_p35, poll_timings_p35, setup_p35, poll_nothing}, - { 0x8086, 0x2E10, "Intel Q45/Q43","", 0, poll_fsb_p35, poll_timings_p35, setup_p35, poll_nothing}, - { 0x8086, 0x2E20, "Intel P45/G45","", 0, poll_fsb_p35, poll_timings_p35, setup_p35, poll_nothing}, - { 0x8086, 0x2E30, "Intel G41","", 0, poll_fsb_p35, poll_timings_p35, setup_p35, poll_nothing}, - { 0x8086, 0x4001, "Intel 5400A","", 0, poll_fsb_5400, poll_timings_5400, setup_E5400, poll_nothing}, - { 0x8086, 0x4003, "Intel 5400B","", 0, poll_fsb_5400, poll_timings_5400, setup_E5400, poll_nothing}, - { 0x8086, 0x25D8, "Intel 5000P","", 0, poll_fsb_5400, poll_timings_5400, setup_E5400, poll_nothing}, - { 0x8086, 0x25D4, "Intel 5000V","", 0, poll_fsb_5400, poll_timings_5400, setup_E5400, poll_nothing}, - { 0x8086, 0x25C0, "Intel 5000X","", 0, poll_fsb_5400, poll_timings_5400, setup_E5400, poll_nothing}, - { 0x8086, 0x25D0, "Intel 5000Z","", 0, poll_fsb_5400, poll_timings_5400, setup_E5400, poll_nothing}, - { 0x8086, 0x5020, "Intel EP80579","", 0, poll_fsb_p4, poll_timings_EP80579, setup_nothing, poll_nothing }, - { 0x8086, 0x8100, "Intel US15W","", 0, poll_fsb_us15w, poll_timings_us15w, setup_nothing, poll_nothing}, - { 0x8086, 0x8101, "Intel UL11L/US15L","", 0, poll_fsb_us15w, poll_timings_us15w, setup_nothing, poll_nothing}, - - /* INTEL IMC (Integrated Memory Controllers) */ - { 0xFFFF, 0x0001, "Core IMC","", 0, poll_fsb_nhm, poll_timings_nhm, setup_nhm, poll_nothing}, - { 0xFFFF, 0x0002, "Core IMC","", 0, poll_fsb_nhm32, poll_timings_nhm, setup_nhm32, poll_nothing}, - { 0xFFFF, 0x0003, "Core IMC","", 0, poll_fsb_wmr, poll_timings_wmr, setup_wmr, poll_nothing}, - { 0xFFFF, 0x0004, "SNB IMC","", 0, poll_fsb_snb, poll_timings_snb, setup_wmr, poll_nothing}, - { 0xFFFF, 0x0005, "SNB-E IMC","", 0, poll_fsb_snbe, poll_timings_snbe, setup_wmr, poll_nothing}, - { 0xFFFF, 0x0006, "IVB IMC","", 0, poll_fsb_ivb, poll_timings_snb, setup_wmr, poll_nothing}, - { 0xFFFF, 0x0007, "HSW IMC","", 0, poll_fsb_ivb, poll_timings_hsw, setup_wmr, poll_nothing}, - { 0xFFFF, 0x0008, "PineView IMC","", 0, poll_fsb_p35, poll_timings_p35, setup_p35, poll_nothing}, - { 0xFFFF, 0x0009, "CedarTrail IMC","", 0, poll_fsb_ct, poll_timings_ct, setup_nothing, poll_nothing}, - - /* AMD IMC (Integrated Memory Controllers) */ - { 0xFFFF, 0x0100, "AMD K8 IMC","", 0, poll_fsb_amd64, poll_timings_amd64, setup_amd64, poll_nothing }, - { 0xFFFF, 0x0101, "AMD K10 IMC","", 0, poll_fsb_k10, poll_timings_k10, setup_k10, poll_nothing }, - { 0xFFFF, 0x0102, "AMD K12 IMC","", 0, poll_fsb_k12, poll_timings_k12, setup_apu, poll_nothing }, - { 0xFFFF, 0x0103, "AMD K14 IMC","", 0, poll_fsb_k14, poll_timings_k14, setup_apu, poll_nothing }, - { 0xFFFF, 0x0104, "AMD K15 IMC","", 0, poll_fsb_k15, poll_timings_k15, setup_apu, poll_nothing }, - { 0xFFFF, 0x0105, "AMD K16 IMC","", 0, poll_fsb_k16, poll_timings_k16, setup_apu, poll_nothing } -}; - -static void print_memory_controller(void) -{ - - /* Print memory controller info */ - if (ctrl.index == 0) { - return; - } - - /* Now print the memory controller capabilities */ - /* - cprint(LINE_CPU+5, col, " "); col++; - if (ctrl.cap == ECC_UNKNOWN) { - return; - } - if (ctrl.cap & __ECC_DETECT) { - int on; - on = ctrl.mode & __ECC_DETECT; - cprint(LINE_CPU+5, col, "(ECC : "); - cprint(LINE_CPU+5, col +7, on?"Detect":"Disabled)"); - on?(col += 13):(col += 16); - } - if (ctrl.mode & __ECC_CORRECT) { - int on; - on = ctrl.mode & __ECC_CORRECT; - cprint(LINE_CPU+5, col, " / "); - if (ctrl.cap & __ECC_CHIPKILL) { - cprint(LINE_CPU+5, col +3, on?"Correct -":""); - on?(col += 12):(col +=3); - } else { - cprint(LINE_CPU+5, col +3, on?"Correct)":""); - on?(col += 11):(col +=3); - } - } - if (ctrl.mode & __ECC_DETECT) { - if (ctrl.cap & __ECC_CHIPKILL) { - int on; - on = ctrl.mode & __ECC_CHIPKILL; - cprint(LINE_CPU+5, col, " Chipkill : "); - cprint(LINE_CPU+5, col +12, on?"On)":"Off)"); - on?(col += 15):(col +=16); - }} - if (ctrl.mode & __ECC_SCRUB) { - int on; - on = ctrl.mode & __ECC_SCRUB; - cprint(LINE_CPU+5, col, " Scrub"); - cprint(LINE_CPU+5, col +6, on?"+ ":"- "); - col += 7; - } - if (ctrl.cap & __ECC_UNEXPECTED) { - int on; - on = ctrl.mode & __ECC_UNEXPECTED; - cprint(LINE_CPU+5, col, "Unknown"); - cprint(LINE_CPU+5, col +7, on?"+ ":"- "); - col += 9; - } - */ - - - - /* Print advanced caracteristics */ - col2 = 0; - - controllers[ctrl.index].poll_fsb(); - controllers[ctrl.index].poll_timings(); - -} - - -void find_controller(void) -{ - unsigned long vendor; - unsigned long device; - int i; - int result; - result = pci_conf_read(ctrl.bus, ctrl.dev, ctrl.fn, PCI_VENDOR_ID, 2, &vendor); - result = pci_conf_read(ctrl.bus, ctrl.dev, ctrl.fn, PCI_DEVICE_ID, 2, &device); - - // Detect IMC by CPUID - if(imc_type) { vendor = 0xFFFF; device = imc_type; } - if(vv->fail_safe & 1) { vendor = 0xFFFF; device = 0xFFFF; } - - //hprint(11,0,vendor); hprint(11,10,device); - - ctrl.index = 0; - if (result == 0 || imc_type) { - for(i = 1; i < sizeof(controllers)/sizeof(controllers[0]); i++) { - if ((controllers[i].vendor == vendor) && (controllers[i].device == device)) { - ctrl.index = i; - break; - } - } - } - - controllers[ctrl.index].setup_ecc(); - /* Don't enable ECC polling by default unless it has - * been well tested. - */ - //set_ecc_polling(-1); - print_memory_controller(); - - if(imc_type) { print_dmi_startup_info(); } - -} - -void poll_errors(void) -{ - if (ctrl.poll) { - controllers[ctrl.index].poll_errors(); - } -} - -/* - void set_ecc_polling(int val) - { - int tested = controllers[ctrl.index].tested; - if (val == -1) { - val = tested; - } - if (val && (ctrl.mode & __ECC_DETECT)) { - ctrl.poll = 1; - cprint(LINE_INFO, COL_ECC, tested? " on": " ON"); - } else { - ctrl.poll = 0; - cprint(LINE_INFO, COL_ECC, "off"); - } - } -*/ - diff --git a/memtest86+_old/controller.h b/memtest86+_old/controller.h deleted file mode 100644 index da64ef1..0000000 --- a/memtest86+_old/controller.h +++ /dev/null @@ -1,23 +0,0 @@ -#ifndef MEMTEST_CONTROLLER_H -#define MEMTEST_CONTROLLER_H - -struct pci_memory_controller { - unsigned vendor; - unsigned device; - char *name; - char *ram_type; - int tested; - void (*poll_fsb)(void); - void (*poll_timings)(void); - void (*setup_ecc)(void); - void (*poll_errors)(void); -}; - -void find_controller(void); -void poll_errors(void); -void set_ecc_polling(int val); -void coretemp(void); -extern struct pci_memory_controller controllers[]; - - -#endif /* MEMTEST_CONTROLLER_H */ diff --git a/memtest86+_old/cpuid.c b/memtest86+_old/cpuid.c deleted file mode 100644 index 4c25ede..0000000 --- a/memtest86+_old/cpuid.c +++ /dev/null @@ -1,87 +0,0 @@ -/* - * cpuid.c -- - * - * Implements CPUID querying functions - * - */ -#include "stdin.h" -#include "cpuid.h" - -struct cpu_ident cpu_id; - -void get_cpuid() -{ - unsigned int *v, dummy[3]; - char *p, *q; - - /* Get max std cpuid & vendor ID */ - cpuid(0x0, &cpu_id.max_cpuid, &cpu_id.vend_id.uint32_array[0], - &cpu_id.vend_id.uint32_array[2], &cpu_id.vend_id.uint32_array[1]); - cpu_id.vend_id.char_array[11] = 0; - - /* Get processor family information & feature flags */ - if (cpu_id.max_cpuid >= 1) { - cpuid(0x00000001, &cpu_id.vers.flat, &cpu_id.info.flat, - &cpu_id.fid.uint32_array[1], &cpu_id.fid.uint32_array[0]); - } - - /* Get the digital thermal sensor & power management status bits */ - if(cpu_id.max_cpuid >= 6) { - cpuid(0x00000006, &cpu_id.dts_pmp, &dummy[0], &dummy[1], &dummy[2]); - } - - /* Get the max extended cpuid */ - cpuid(0x80000000, &cpu_id.max_xcpuid, &dummy[0], &dummy[1], &dummy[2]); - - /* Get extended feature flags, only save EDX */ - if (cpu_id.max_xcpuid >= 0x80000001) { - cpuid(0x80000001, &dummy[0], &dummy[1], - &dummy[2], &cpu_id.fid.uint32_array[2]); - } - - /* Get the brand ID */ - if (cpu_id.max_xcpuid >= 0x80000004) { - v = (unsigned int *)&cpu_id.brand_id; - cpuid(0x80000002, &v[0], &v[1], &v[2], &v[3]); - cpuid(0x80000003, &v[4], &v[5], &v[6], &v[7]); - cpuid(0x80000004, &v[8], &v[9], &v[10], &v[11]); - cpu_id.brand_id.char_array[47] = 0; - } - /* - * Intel chips right-justify this string for some dumb reason; - * undo that brain damage: - */ - p = q = &cpu_id.brand_id.char_array[0]; - while (*p == ' ') - p++; - if (p != q) { - while (*p) - *q++ = *p++; - while (q <= &cpu_id.brand_id.char_array[48]) - *q++ = '\0'; /* Zero-pad the rest */ - } - - /* Get cache information */ - switch(cpu_id.vend_id.char_array[0]) { - case 'A': - /* AMD Processors */ - /* The cache information is only in ecx and edx so only save - * those registers */ - if (cpu_id.max_xcpuid >= 0x80000005) { - cpuid(0x80000005, &dummy[0], &dummy[1], - &cpu_id.cache_info.uint[0], &cpu_id.cache_info.uint[1]); - } - if (cpu_id.max_xcpuid >= 0x80000006) { - cpuid(0x80000006, &dummy[0], &dummy[1], - &cpu_id.cache_info.uint[2], &cpu_id.cache_info.uint[3]); - } - break; - case 'G': - /* Intel Processors, Need to do this in init.c */ - break; - } - - /* Turn off mon bit since monitor based spin wait may not be reliable */ - cpu_id.fid.bits.mon = 0; - -} diff --git a/memtest86+_old/cpuid.h b/memtest86+_old/cpuid.h deleted file mode 100644 index 0feb56e..0000000 --- a/memtest86+_old/cpuid.h +++ /dev/null @@ -1,205 +0,0 @@ - - -#ifndef CPUID_H_ -#define CPUID_H_ - - -/* - * cpuid.h -- - * contains the data structures required for CPUID - * implementation. - */ - -#define CPUID_VENDOR_LENGTH 3 /* 3 GPRs hold vendor ID */ -#define CPUID_VENDOR_STR_LENGTH (CPUID_VENDOR_LENGTH * sizeof(uint32_t) + 1) -#define CPUID_BRAND_LENGTH 12 /* 12 GPRs hold vendor ID */ -#define CPUID_BRAND_STR_LENGTH (CPUID_BRAND_LENGTH * sizeof(uint32_t) + 1) - -extern struct cpu_ident cpu_id; - -static inline void __cpuid(unsigned int *eax, unsigned int *ebx, - unsigned int *ecx, unsigned int *edx) -{ - /* ecx is often an input as well as an output. */ - asm volatile("\t" - "push %%ebx; cpuid; mov %%ebx, %%edi; pop %%ebx" - : "=a" (*eax), - "=D" (*ebx), - "=c" (*ecx), - "=d" (*edx) - : "0" (*eax), "2" (*ecx)); -} - -static inline void cpuid(unsigned int op, - unsigned int *eax, unsigned int *ebx, - unsigned int *ecx, unsigned int *edx) -{ - *eax = op; - *ecx = 0; - __cpuid(eax, ebx, ecx, edx); -} - -/* Some CPUID calls want 'count' to be placed in ecx */ -static inline void cpuid_count(unsigned int op, int count, - unsigned int *eax, unsigned int *ebx, - unsigned int *ecx, unsigned int *edx) -{ - *eax = op; - *ecx = count; - __cpuid(eax, ebx, ecx, edx); -} - -/* Typedef for storing the Cache Information */ -typedef union { - unsigned char ch[48]; - uint32_t uint[12]; - struct { - uint32_t fill1:24; /* Bit 0 */ - uint32_t l1_i_sz:8; - uint32_t fill2:24; - uint32_t l1_d_sz:8; - uint32_t fill3:16; - uint32_t l2_sz:16; - uint32_t fill4:18; - uint32_t l3_sz:14; - uint32_t fill5[8]; - } amd; -} cpuid_cache_info_t; - -/* Typedef for storing the CPUID Vendor String */ -typedef union { - /* Note: the extra byte in the char array is for '\0'. */ - char char_array[CPUID_VENDOR_STR_LENGTH]; - uint32_t uint32_array[CPUID_VENDOR_LENGTH]; -} cpuid_vendor_string_t; - -/* Typedef for storing the CPUID Brand String */ -typedef union { - /* Note: the extra byte in the char array is for '\0'. */ - char char_array[CPUID_BRAND_STR_LENGTH]; - uint32_t uint32_array[CPUID_BRAND_LENGTH]; -} cpuid_brand_string_t; - -/* Typedef for storing CPUID Version */ -typedef union { - uint32_t flat; - struct { - uint32_t stepping:4; /* Bit 0 */ - uint32_t model:4; - uint32_t family:4; - uint32_t processorType:2; - uint32_t reserved1514:2; - uint32_t extendedModel:4; - uint32_t extendedFamily:8; - uint32_t reserved3128:4; /* Bit 31 */ - } bits; -} cpuid_version_t; - -/* Typedef for storing CPUID Processor Information */ -typedef union { - uint32_t flat; - struct { - uint32_t brandIndex:8; /* Bit 0 */ - uint32_t cflushLineSize:8; - uint32_t logicalProcessorCount:8; - uint32_t apicID:8; /* Bit 31 */ - } bits; -} cpuid_proc_info_t; - -/* Typedef for storing CPUID Feature flags */ -typedef union { - uint32_t flat; - struct { - uint32_t :1; - } bits; -} cpuid_custom_features; - -/* Typedef for storing CPUID Feature flags */ -typedef union { - uint32_t uint32_array[3]; - struct { - uint32_t fpu:1; /* EDX feature flags, bit 0 */ - uint32_t vme:1; - uint32_t de:1; - uint32_t pse:1; - uint32_t rdtsc:1; - uint32_t msr:1; - uint32_t pae:1; - uint32_t mce:1; - uint32_t cx8:1; - uint32_t apic:1; - uint32_t bit10:1; - uint32_t sep:1; - uint32_t mtrr:1; - uint32_t pge:1; - uint32_t mca:1; - uint32_t cmov:1; - uint32_t pat:1; - uint32_t pse36:1; - uint32_t psn:1; - uint32_t cflush:1; - uint32_t bit20:1; - uint32_t ds:1; - uint32_t acpi:1; - uint32_t mmx:1; - uint32_t fxsr:1; - uint32_t sse:1; - uint32_t sse2:1; - uint32_t ss:1; - uint32_t htt:1; - uint32_t tm:1; - uint32_t bit30:1; - uint32_t pbe:1; /* EDX feature flags, bit 31 */ - uint32_t sse3:1; /* ECX feature flags, bit 0 */ - uint32_t mulq:1; - uint32_t bit2:1; - uint32_t mon:1; - uint32_t dscpl:1; - uint32_t vmx:1; - uint32_t smx:1; - uint32_t eist:1; - uint32_t tm2:1; - uint32_t bits_9_31:23; - uint32_t bits0_28:29; /* EDX extended feature flags, bit 0 */ - uint32_t lm:1; /* Long Mode */ - uint32_t bits_30_31:2; /* EDX extended feature flags, bit 32 */ - } bits; -} cpuid_feature_flags_t; - -/* An overall structure to cache all of the CPUID information */ -struct cpu_ident { - uint32_t max_cpuid; - uint32_t max_xcpuid; - uint32_t dts_pmp; - cpuid_version_t vers; - cpuid_proc_info_t info; - cpuid_feature_flags_t fid; - cpuid_vendor_string_t vend_id; - cpuid_brand_string_t brand_id; - cpuid_cache_info_t cache_info; - cpuid_custom_features custom; -}; - -struct cpuid4_eax { - uint32_t ctype:5; - uint32_t level:3; - uint32_t is_self_initializing:1; - uint32_t is_fully_associative:1; - uint32_t reserved:4; - uint32_t num_threads_sharing:12; - uint32_t num_cores_on_die:6; -}; - -struct cpuid4_ebx { - uint32_t coherency_line_size:12; - uint32_t physical_line_partition:10; - uint32_t ways_of_associativity:10; -}; - -struct cpuid4_ecx { - uint32_t number_of_sets:32; -}; - -void get_cpuid(); - -#endif // CPUID_H_ diff --git a/memtest86+_old/defs.h b/memtest86+_old/defs.h deleted file mode 100644 index 1b77f2c..0000000 --- a/memtest86+_old/defs.h +++ /dev/null @@ -1,26 +0,0 @@ -/* defs.h - MemTest-86 Version 3.3 - * assembler/compiler definitions - * - * Released under version 2 of the Gnu Public License. - * By Chris Brady - */ - -#define SETUPSECS 4 /* Number of setup sectors */ - -/* - * Caution!! There is magic in the build process. Read - * README.build-process before you change anything. - * Unlike earlier versions all of the settings are in defs.h - * so the build process should be more robust. - */ -#define LOW_TEST_ADR 0x00010000 /* Final adrs for test code */ - -#define BOOTSEG 0x07c0 /* Segment adrs for initial boot */ -#define INITSEG 0x9000 /* Segment adrs for relocated boot */ -#define SETUPSEG (INITSEG+0x20) /* Segment adrs for relocated setup */ -#define TSTLOAD 0x1000 /* Segment adrs for load of test */ - -#define KERNEL_CS 0x10 /* 32 bit segment adrs for code */ -#define KERNEL_DS 0x18 /* 32 bit segment adrs for data */ -#define REAL_CS 0x20 /* 16 bit segment adrs for code */ -#define REAL_DS 0x28 /* 16 bit segment adrs for data */ diff --git a/memtest86+_old/dmi.c b/memtest86+_old/dmi.c deleted file mode 100644 index 41b0347..0000000 --- a/memtest86+_old/dmi.c +++ /dev/null @@ -1,438 +0,0 @@ -/* dmi.c using the DMI from SMBIOS to read information about the hardware's - * memory devices capabilities and where they are mapped into the address space - * - * Copyright (c) Joachim Deguara, AMD 2006 - * - * Release under the GPL version 2 - * ---------------------------------------------------- - * Memtest86+ V4.00 - Added compliance with SMBIOS Spec V2.6.1 - */ - - -#include "test.h" -#include "stdint.h" - -#define round_up(x,y) (((x) + (y) - 1) & ~((y)-1)) -#define round_down(x,y) ((x) & ~((y)-1)) - -struct dmi_eps { - uint8_t anchor[4]; - int8_t checksum; - uint8_t length; - uint8_t majorversion; - uint8_t minorversion; - uint16_t maxstructsize; - uint8_t revision; - uint8_t pad[5]; - uint8_t intanchor[5]; - int8_t intchecksum; - uint16_t tablelength; - uint32_t tableaddress; - uint16_t numstructs; - uint8_t SMBIOSrev; -} __attribute__((packed)); - -struct tstruct_header{ - uint8_t type; - uint8_t length; - uint16_t handle; -} __attribute__((packed)); - -struct system_map { - struct tstruct_header header; - uint8_t manufacturer; - uint8_t productname; - uint8_t version; - uint8_t serialnumber; - uint8_t uuidbytes[16]; - uint8_t wut; -} __attribute__((packed)); - -struct cpu_map { - struct tstruct_header header; - uint8_t cpu_socket; - uint8_t cpu_type; - uint8_t cpu_family; - uint8_t cpu_manufacturer; - uint32_t cpu_id; - uint8_t cpu_version; - uint8_t cpu_voltage; - uint16_t ext_clock; - uint16_t max_speed; - uint16_t cur_speed; - uint8_t cpu_status; - uint8_t cpu_upgrade; - uint16_t l1_handle; - uint16_t l2_handle; - uint16_t l3_handle; - uint8_t cpu_serial; - uint8_t cpu_asset_tag; - uint8_t cpu_part_number; - uint8_t core_count; - uint8_t core_enabled; - uint8_t thread_count; - uint16_t cpu_specs; - uint16_t cpu_family_2; -} __attribute__((packed)); - -struct mem_dev { - struct tstruct_header header; - uint16_t pma_handle; - uint16_t err_handle; - uint16_t tot_width; - uint16_t dat_width; - uint16_t size; - uint8_t form; - uint8_t set; - uint8_t dev_locator; - uint8_t bank_locator; - uint8_t type; - uint16_t typedetail; - uint16_t speed; - uint8_t manufacturer; - uint8_t serialnum; - uint8_t asset; - uint8_t partnum; - uint8_t attributes; - uint8_t ext_size; - uint8_t conf_ram_speed; - uint8_t min_voltage; - uint8_t max_votage; - uint8_t conf_voltage; -} __attribute__((packed)); - -struct md_map{ - struct tstruct_header header; - uint32_t start; - uint32_t end; - uint16_t md_handle; - uint16_t mama_handle; - uint8_t row_pos; - uint8_t interl_pos; - uint8_t interl_depth; -} __attribute__((packed)); - -struct pma{ - struct tstruct_header header; - uint8_t location; - uint8_t use; - uint8_t ecc; - uint32_t capacity; - uint16_t errhandle; - uint16_t numdevs; -} __attribute__((packed)); - -static char *form_factors[] = { - "?", - "Other", "Unknown", "SIMM", "SIP", "Chip", "DIP", "ZIP", - "Proprietary Card", "DIMM", "TSOP", "Row of chips", "RIMM", - "SODIMM", "SRIMM", "FB-DIMM", "Die" -}; - - -static char *memory_types[] = { - "?", - "Other", "????", "DRAM", "EDRAM", "VRAM", "SRAM", "RAM", - "ROM", "FLASH", "EEPROM", "FEPROM", "EPROM", "CDRAM", "3DRAM", - "SDRAM", "SGRAM", "RDRAM", "DDR", "DDR2", "DDR2 FB", "RSVD", - "RSVD","RSVD","DDR3","FBD2", "DDR4", "LPDDR", "LPDDR2", "LPDDR3", - "LPDDR4", "LNVD", "HBM", "HBM2", "DDR5", "LPDDR5" -}; - - -struct mem_dev * mem_devs[MAX_DMI_MEMDEVS]; -int mem_devs_count=0; -struct md_map * md_maps[MAX_DMI_MEMDEVS]; -struct system_map * dmi_system_info; -struct cpu_map * dmi_cpu_info; -int md_maps_count=0; -int dmi_err_cnts[MAX_DMI_MEMDEVS]; -short dmi_initialized=0; - -char * get_tstruct_string(struct tstruct_header *header, int n){ - if(n<1) - return 0; - char * a = (char *)header + header->length; - n--; - do{ - if (!*a) - n--; - if (!n && *a) - return a; - a++; - }while (!(*a==0 && *(a-1)==0)); - return 0; -} - - -int open_dmi(void){ - char *dmi, *dmi_search_start, *dmi_start; - int found=0; - struct dmi_eps *eps; - char *table_start; - int tstruct_count=0; - dmi_search_start = (char *)DMI_SEARCH_START; - - //find anchor - for(dmi = dmi_search_start; dmi < dmi_search_start + 0xf0000; dmi +=16){ - if( *dmi == '_' && - *(dmi+1) == 'S' && - *(dmi+2) == 'M' && - *(dmi+3) == '_'){ - found =1; - break; - } - } - if (!found) { - return -1; - } - dmi_start=dmi; - eps=(struct dmi_eps *)dmi; - - //check checksum - int8_t checksum=0; - for (; dmi < dmi_start + eps->length; dmi++) - checksum += *dmi; - if (checksum){ - return -1; - } - - //we need at least revision 2.1 of SMBIOS - if ( eps->majorversion < 2 && - eps->minorversion < 1){ - return -1; - } - - table_start=(char *)eps->tableaddress; - dmi=table_start; -//look at all structs - while(dmi < table_start + eps->tablelength){ - struct tstruct_header *header = (struct tstruct_header *)dmi; - - if (header->type == 17) - mem_devs[mem_devs_count++] = (struct mem_dev *)dmi; - - // Mem Dev Map - if (header->type == 20) - md_maps[md_maps_count++] = (struct md_map *)dmi; - - // MB_SPEC - if (header->type == 2) - { - dmi_system_info = (struct system_map *)dmi; - } - - // CPU_SPEC - if (header->type == 4) - { - dmi_cpu_info = (struct cpu_map *)dmi; - } - - dmi+=header->length; - - while( ! (*dmi == 0 && *(dmi+1) == 0 ) ) - dmi++; - dmi+=2; - - if (++tstruct_count > eps->numstructs) - return -1; - } - return 0; -} - -void init_dmi(void){ - int i; - for(i=0; i < MAX_DMI_MEMDEVS; i++) - dmi_err_cnts[i]=0; - open_dmi(); - dmi_initialized=1; -} - -void print_dmi_startup_info(void) -{ - char *string1; - char *string2; - char *string3; - int dmicol = 78; - int slenght; - int sl1, sl2, sl3; - - if(!dmi_initialized) { init_dmi(); } - - string1 = get_tstruct_string(&dmi_system_info->header,dmi_system_info->manufacturer); - sl1 = mt86_strlen(string1); - string2 = get_tstruct_string(&dmi_system_info->header,dmi_system_info->productname); - sl2 = mt86_strlen(string2); - string3 = get_tstruct_string(&dmi_cpu_info->header,dmi_cpu_info->cpu_socket); - sl3 = mt86_strlen(string3); - - slenght = sl1 + sl2; - if(sl3 > 2) { slenght += sl3 + 4; } else { slenght++; } - - if(sl1 && sl2) - { - //dmicol -= slenght; // right align - dmicol = 39 - slenght/2; // center align - cprint(LINE_DMI, dmicol, string1); - dmicol += sl1 + 1; - cprint(LINE_DMI, dmicol, string2); - dmicol += sl2 + 1; - - if(sl3 > 2){ - cprint(LINE_DMI, dmicol, "("); - dmicol++; - cprint(LINE_DMI, dmicol, string3); - dmicol += sl3; - cprint(LINE_DMI, dmicol, ")"); - } - } -} - -void print_dmi_info(void){ - int i,j,page; - char * string=0; - - if(!dmi_initialized) - init_dmi(); - - if (mem_devs_count == 0){ - cprint(POP2_Y+1, POP2_X+2, "No valid DMI Memory Devices info found"); - while (get_key() == 0); - return; - } - - for(page=1; page <= 1 + (mem_devs_count-1)/8; page++){ - pop2clear(); - cprint(POP2_Y+1, POP2_X+2, "DMI Memory Device Info (page "); - itoa(string,page); - cprint(POP2_Y+1, POP2_X+32, string); - cprint(POP2_Y+1, POP2_X+33, "/"); - itoa(string,1 + (mem_devs_count-1)/8); - cprint(POP2_Y+1, POP2_X+34, string); - cprint(POP2_Y+1, POP2_X+35, ")"); - - cprint(POP2_Y+3, POP2_X+4, "Location Size(MB) Speed(MHz) Type Form"); - cprint(POP2_Y+4, POP2_X+4, "--------------------------------------------------------------"); - - for(i=8*(page-1); iheader), mem_devs[i]->dev_locator)); - - if (mem_devs[i]->size == 0){ - cprint(yof, POP2_X+4+18, "Empty"); - }else if (mem_devs[i]->size == 0xFFFF){ - cprint(yof, POP2_X+4+18, "Unknown"); - }else if (mem_devs[i]->size == 0x7FFF){ - // SMBIOS 2.7+ - size_in_mb = mem_devs[i]->ext_size; - itoa(string, size_in_mb); - cprint(yof, POP2_X+4+18, string); - }else{ - size_in_mb = 0xFFFF & mem_devs[i]->size; - if (mem_devs[i]->size & 0x8000) - size_in_mb <<= 10; - itoa(string, size_in_mb); - cprint(yof, POP2_X+4+18, string); - } - - //this is the only field that needs to be SMBIOS 2.3+ - if ( mem_devs[i]->speed && - mem_devs[i]->header.length > 21){ - itoa(string, mem_devs[i]->speed); - cprint(yof, POP2_X+4+27, string); - }else{ - cprint(yof, POP2_X+4+27, "Unknown"); - } - cprint(yof, POP2_X+4+37, memory_types[mem_devs[i]->type]); - cprint(yof, POP2_X+4+44, form_factors[mem_devs[i]->form]); - - //print mappings - int mapped=0,of=0; - cprint(yof+1, POP2_X+6,"mapped to: "); - for(j=0; jheader.handle != md_maps[j]->md_handle) - continue; - if (mapped++){ - cprint(yof+1, POP2_X+17+of, ","); - of++; - } - hprint3(yof+1, POP2_X+17+of, md_maps[j]->start>>22, 4); - of += 4; - hprint3(yof+1, POP2_X+17+of, md_maps[j]->start<<10, 8); - of += 8; - cprint(yof+1, POP2_X+17+of, "-"); - of++; - hprint3(yof+1, POP2_X+17+of, md_maps[j]->end>>22, 4); - of += 4; - hprint3(yof+1, POP2_X+17+of, ((md_maps[j]->end+1)<<10) - 1, 8); - of += 8; - if(md_maps[j]->end == 0) { hprint3(yof+1, POP2_X+17+of-8,0,8); } - } - if (!mapped) - { - cprint(yof+1, POP2_X+17, "No mapping (Interleaved Device)"); - } - - } - - wait_keyup(); - while (get_key() == 0); - } -} - -//return 1 if the list of bad memory devices changes, 0 otherwise, -1 if no mapped -int add_dmi_err(ulong adr){ - int i,j,found=-1; - - if(!dmi_initialized) - init_dmi(); - - for(i=0; i < md_maps_count; i++){ - if ( adr < (md_maps[i]->start<<10) || - adr > (md_maps[i]->end<<10) ) - continue; - - //matching map found, now check find corresponding dev - for(j=0; j < mem_devs_count; j++){ - if (mem_devs[j]->header.handle != md_maps[i]->md_handle) - continue; - if (dmi_err_cnts[j]){ - found=0; - }else{ - found = dmi_err_cnts[j] = 1; - } - } - } - - return found; -} - -void print_dmi_err(void){ - int i,count,of; - char *string; - - scroll(); - - cprint(vv->msg_line, 0,"Bad Memory Devices: "); - of=20; - for ( i=count=0; i < MAX_DMI_MEMDEVS; i++){ - if (!dmi_err_cnts[i]) - continue; - struct mem_dev *md = mem_devs[i]; - if(count++){ - cprint(vv->msg_line, of, ", "); - of+=2; - } - string=get_tstruct_string((struct tstruct_header *)md,md->dev_locator); - if (mt86_strlen(string) + of > 80){ - scroll(); - of=7; - } - cprint(vv->msg_line, of, string); - of += mt86_strlen(string); - } -} diff --git a/memtest86+_old/dmi.h b/memtest86+_old/dmi.h deleted file mode 100644 index c90fedd..0000000 --- a/memtest86+_old/dmi.h +++ /dev/null @@ -1,7 +0,0 @@ -#ifndef __DMI_H__ -#define __DMI_H__ -int add_dmi_err(ulong adr); -void print_dmi_err(void); -void print_dmi_info(void); -void print_dmi_startup_info(void); -#endif diff --git a/memtest86+_old/elf.h b/memtest86+_old/elf.h deleted file mode 100644 index 72efaac..0000000 --- a/memtest86+_old/elf.h +++ /dev/null @@ -1,590 +0,0 @@ -#ifndef ELF_H -#define ELF_H - -#define EI_NIDENT 16 /* Size of e_ident array. */ - -/* Values for e_type. */ -#define ET_NONE 0 /* No file type */ -#define ET_REL 1 /* Relocatable file */ -#define ET_EXEC 2 /* Executable file */ -#define ET_DYN 3 /* Shared object file */ -#define ET_CORE 4 /* Core file */ - -/* Values for e_machine (architecute). */ -#define EM_NONE 0 /* No machine */ -#define EM_M32 1 /* AT&T WE 32100 */ -#define EM_SPARC 2 /* SUN SPARC */ -#define EM_386 3 /* Intel 80386+ */ -#define EM_68K 4 /* Motorola m68k family */ -#define EM_88K 5 /* Motorola m88k family */ -#define EM_486 6 /* Perhaps disused */ -#define EM_860 7 /* Intel 80860 */ -#define EM_MIPS 8 /* MIPS R3000 big-endian */ -#define EM_S370 9 /* IBM System/370 */ -#define EM_MIPS_RS3_LE 10 /* MIPS R3000 little-endian */ - -#define EM_PARISC 15 /* HPPA */ -#define EM_VPP500 17 /* Fujitsu VPP500 */ -#define EM_SPARC32PLUS 18 /* Sun's "v8plus" */ -#define EM_960 19 /* Intel 80960 */ -#define EM_PPC 20 /* PowerPC */ -#define EM_PPC64 21 /* PowerPC 64-bit */ -#define EM_S390 22 /* IBM S390 */ - -#define EM_V800 36 /* NEC V800 series */ -#define EM_FR20 37 /* Fujitsu FR20 */ -#define EM_RH32 38 /* TRW RH-32 */ -#define EM_RCE 39 /* Motorola RCE */ -#define EM_ARM 40 /* ARM */ -#define EM_FAKE_ALPHA 41 /* Digital Alpha */ -#define EM_SH 42 /* Hitachi SH */ -#define EM_SPARCV9 43 /* SPARC v9 64-bit */ -#define EM_TRICORE 44 /* Siemens Tricore */ -#define EM_ARC 45 /* Argonaut RISC Core */ -#define EM_H8_300 46 /* Hitachi H8/300 */ -#define EM_H8_300H 47 /* Hitachi H8/300H */ -#define EM_H8S 48 /* Hitachi H8S */ -#define EM_H8_500 49 /* Hitachi H8/500 */ -#define EM_IA_64 50 /* Intel Merced */ -#define EM_MIPS_X 51 /* Stanford MIPS-X */ -#define EM_COLDFIRE 52 /* Motorola Coldfire */ -#define EM_68HC12 53 /* Motorola M68HC12 */ -#define EM_MMA 54 /* Fujitsu MMA Multimedia Accelerator*/ -#define EM_PCP 55 /* Siemens PCP */ -#define EM_NCPU 56 /* Sony nCPU embeeded RISC */ -#define EM_NDR1 57 /* Denso NDR1 microprocessor */ -#define EM_STARCORE 58 /* Motorola Start*Core processor */ -#define EM_ME16 59 /* Toyota ME16 processor */ -#define EM_ST100 60 /* STMicroelectronic ST100 processor */ -#define EM_TINYJ 61 /* Advanced Logic Corp. Tinyj emb.fam*/ -#define EM_X86_64 62 /* AMD x86-64 architecture */ -#define EM_PDSP 63 /* Sony DSP Processor */ - -#define EM_FX66 66 /* Siemens FX66 microcontroller */ -#define EM_ST9PLUS 67 /* STMicroelectronics ST9+ 8/16 mc */ -#define EM_ST7 68 /* STmicroelectronics ST7 8 bit mc */ -#define EM_68HC16 69 /* Motorola MC68HC16 microcontroller */ -#define EM_68HC11 70 /* Motorola MC68HC11 microcontroller */ -#define EM_68HC08 71 /* Motorola MC68HC08 microcontroller */ -#define EM_68HC05 72 /* Motorola MC68HC05 microcontroller */ -#define EM_SVX 73 /* Silicon Graphics SVx */ -#define EM_AT19 74 /* STMicroelectronics ST19 8 bit mc */ -#define EM_VAX 75 /* Digital VAX */ -#define EM_CRIS 76 /* Axis Communications 32-bit embedded processor */ -#define EM_JAVELIN 77 /* Infineon Technologies 32-bit embedded processor */ -#define EM_FIREPATH 78 /* Element 14 64-bit DSP Processor */ -#define EM_ZSP 79 /* LSI Logic 16-bit DSP Processor */ -#define EM_MMIX 80 /* Donald Knuth's educational 64-bit processor */ -#define EM_HUANY 81 /* Harvard University machine-independent object files */ -#define EM_PRISM 82 /* SiTera Prism */ -#define EM_AVR 83 /* Atmel AVR 8-bit microcontroller */ -#define EM_FR30 84 /* Fujitsu FR30 */ -#define EM_D10V 85 /* Mitsubishi D10V */ -#define EM_D30V 86 /* Mitsubishi D30V */ -#define EM_V850 87 /* NEC v850 */ -#define EM_M32R 88 /* Mitsubishi M32R */ -#define EM_MN10300 89 /* Matsushita MN10300 */ -#define EM_MN10200 90 /* Matsushita MN10200 */ -#define EM_PJ 91 /* picoJava */ -#define EM_OPENRISC 92 /* OpenRISC 32-bit embedded processor */ -#define EM_ARC_A5 93 /* ARC Cores Tangent-A5 */ -#define EM_XTENSA 94 /* Tensilica Xtensa Architecture */ -#define EM_NUM 95 - -/* Values for p_type. */ -#define PT_NULL 0 /* Unused entry. */ -#define PT_LOAD 1 /* Loadable segment. */ -#define PT_DYNAMIC 2 /* Dynamic linking information segment. */ -#define PT_INTERP 3 /* Pathname of interpreter. */ -#define PT_NOTE 4 /* Auxiliary information. */ -#define PT_SHLIB 5 /* Reserved (not used). */ -#define PT_PHDR 6 /* Location of program header itself. */ - -/* Values for p_flags. */ -#define PF_X 0x1 /* Executable. */ -#define PF_W 0x2 /* Writable. */ -#define PF_R 0x4 /* Readable. */ - - -#define ELF_PROGRAM_RETURNS_BIT 0x8000000 /* e_flags bit 31 */ - -#define EI_MAG0 0 -#define ELFMAG0 0x7f - -#define EI_MAG1 1 -#define ELFMAG1 'E' - -#define EI_MAG2 2 -#define ELFMAG2 'L' - -#define EI_MAG3 3 -#define ELFMAG3 'F' - -#define ELFMAG "\177ELF" - -#define EI_CLASS 4 /* File class byte index */ -#define ELFCLASSNONE 0 /* Invalid class */ -#define ELFCLASS32 1 /* 32-bit objects */ -#define ELFCLASS64 2 /* 64-bit objects */ - -#define EI_DATA 5 /* Data encodeing byte index */ -#define ELFDATANONE 0 /* Invalid data encoding */ -#define ELFDATA2LSB 1 /* 2's complement little endian */ -#define ELFDATA2MSB 2 /* 2's complement big endian */ - -#define EI_VERSION 6 /* File version byte index */ - /* Value must be EV_CURRENT */ - -#define EV_NONE 0 /* Invalid ELF Version */ -#define EV_CURRENT 1 /* Current version */ - -#define ELF32_PHDR_SIZE (8*4) /* Size of an elf program header */ - -#ifndef ASSEMBLY - -#include "stdint.h" - -/* - * ELF definitions common to all 32-bit architectures. - */ - -typedef uint32_t Elf32_Addr; -typedef uint16_t Elf32_Half; -typedef uint32_t Elf32_Off; -typedef uint16_t Elf32_Section; -typedef int32_t Elf32_Sword; -typedef uint32_t Elf32_Word; -typedef uint32_t Elf32_Size; - -typedef uint64_t Elf64_Addr; -typedef uint16_t Elf64_Half; -typedef uint64_t Elf64_Off; -typedef uint16_t Elf64_Section; -typedef int32_t Elf64_Sword; -typedef uint32_t Elf64_Word; -typedef uint64_t Elf64_Size; -typedef uint64_t Elf64_Xword; -typedef int64_t Elf64_Sxword; - -/* - * ELF header. - */ -typedef struct { - unsigned char e_ident[EI_NIDENT]; /* File identification. */ - Elf32_Half e_type; /* File type. */ - Elf32_Half e_machine; /* Machine architecture. */ - Elf32_Word e_version; /* ELF format version. */ - Elf32_Addr e_entry; /* Entry point. */ - Elf32_Off e_phoff; /* Program header file offset. */ - Elf32_Off e_shoff; /* Section header file offset. */ - Elf32_Word e_flags; /* Architecture-specific flags. */ - Elf32_Half e_ehsize; /* Size of ELF header in bytes. */ - Elf32_Half e_phentsize; /* Size of program header entry. */ - Elf32_Half e_phnum; /* Number of program header entries. */ - Elf32_Half e_shentsize; /* Size of section header entry. */ - Elf32_Half e_shnum; /* Number of section header entries. */ - Elf32_Half e_shstrndx; /* Section name strings section. */ -} Elf32_Ehdr; - -typedef struct { - unsigned char e_ident[EI_NIDENT]; /* File identification. */ - Elf64_Half e_type; /* File type. */ - Elf64_Half e_machine; /* Machine architecture. */ - Elf64_Word e_version; /* ELF format version. */ - Elf64_Addr e_entry; /* Entry point. */ - Elf64_Off e_phoff; /* Program header file offset. */ - Elf64_Off e_shoff; /* Section header file offset. */ - Elf64_Word e_flags; /* Architecture-specific flags. */ - Elf64_Half e_ehsize; /* Size of ELF header in bytes. */ - Elf64_Half e_phentsize; /* Size of program header entry. */ - Elf64_Half e_phnum; /* Number of program header entries. */ - Elf64_Half e_shentsize; /* Size of section header entry. */ - Elf64_Half e_shnum; /* Number of section header entries. */ - Elf64_Half e_shstrndx; /* Section name strings section. */ -} Elf64_Ehdr; - -/* - * Program header. - */ -typedef struct { - Elf32_Word p_type; /* Entry type. */ - Elf32_Off p_offset; /* File offset of contents. */ - Elf32_Addr p_vaddr; /* Virtual address (not used). */ - Elf32_Addr p_paddr; /* Physical address. */ - Elf32_Size p_filesz; /* Size of contents in file. */ - Elf32_Size p_memsz; /* Size of contents in memory. */ - Elf32_Word p_flags; /* Access permission flags. */ - Elf32_Size p_align; /* Alignment in memory and file. */ -} Elf32_Phdr; - -typedef struct { - Elf64_Word p_type; /* Entry type. */ - Elf64_Word p_flags; /* Access permission flags. */ - Elf64_Off p_offset; /* File offset of contents. */ - Elf64_Addr p_vaddr; /* Virtual address (not used). */ - Elf64_Addr p_paddr; /* Physical address. */ - Elf64_Size p_filesz; /* Size of contents in file. */ - Elf64_Size p_memsz; /* Size of contents in memory. */ - Elf64_Size p_align; /* Alignment in memory and file. */ -} Elf64_Phdr; - - -/* Dynamic section entry. */ - -typedef struct -{ - Elf32_Sword d_tag; /* Dynamic entry type */ - union - { - Elf32_Word d_val; /* Integer value */ - Elf32_Addr d_ptr; /* Address value */ - } d_un; -} Elf32_Dyn; - -typedef struct -{ - Elf64_Sxword d_tag; /* Dynamic entry type */ - union - { - Elf64_Xword d_val; /* Integer value */ - Elf64_Addr d_ptr; /* Address value */ - } d_un; -} Elf64_Dyn; - -/* Legal values for d_tag (dynamic entry type). */ - -#define DT_NULL 0 /* Marks end of dynamic section */ -#define DT_NEEDED 1 /* Name of needed library */ -#define DT_PLTRELSZ 2 /* Size in bytes of PLT relocs */ -#define DT_PLTGOT 3 /* Processor defined value */ -#define DT_HASH 4 /* Address of symbol hash table */ -#define DT_STRTAB 5 /* Address of string table */ -#define DT_SYMTAB 6 /* Address of symbol table */ -#define DT_RELA 7 /* Address of Rela relocs */ -#define DT_RELASZ 8 /* Total size of Rela relocs */ -#define DT_RELAENT 9 /* Size of one Rela reloc */ -#define DT_STRSZ 10 /* Size of string table */ -#define DT_SYMENT 11 /* Size of one symbol table entry */ -#define DT_INIT 12 /* Address of init function */ -#define DT_FINI 13 /* Address of termination function */ -#define DT_SONAME 14 /* Name of shared object */ -#define DT_RPATH 15 /* Library search path (deprecated) */ -#define DT_SYMBOLIC 16 /* Start symbol search here */ -#define DT_REL 17 /* Address of Rel relocs */ -#define DT_RELSZ 18 /* Total size of Rel relocs */ -#define DT_RELENT 19 /* Size of one Rel reloc */ -#define DT_PLTREL 20 /* Type of reloc in PLT */ -#define DT_DEBUG 21 /* For debugging; unspecified */ -#define DT_TEXTREL 22 /* Reloc might modify .text */ -#define DT_JMPREL 23 /* Address of PLT relocs */ -#define DT_BIND_NOW 24 /* Process relocations of object */ -#define DT_INIT_ARRAY 25 /* Array with addresses of init fct */ -#define DT_FINI_ARRAY 26 /* Array with addresses of fini fct */ -#define DT_INIT_ARRAYSZ 27 /* Size in bytes of DT_INIT_ARRAY */ -#define DT_FINI_ARRAYSZ 28 /* Size in bytes of DT_FINI_ARRAY */ -#define DT_RUNPATH 29 /* Library search path */ -#define DT_FLAGS 30 /* Flags for the object being loaded */ -#define DT_ENCODING 32 /* Start of encoded range */ -#define DT_PREINIT_ARRAY 32 /* Array with addresses of preinit fct*/ -#define DT_PREINIT_ARRAYSZ 33 /* size in bytes of DT_PREINIT_ARRAY */ -#define DT_NUM 34 /* Number used */ -#define DT_LOOS 0x6000000d /* Start of OS-specific */ -#define DT_HIOS 0x6ffff000 /* End of OS-specific */ -#define DT_LOPROC 0x70000000 /* Start of processor-specific */ -#define DT_HIPROC 0x7fffffff /* End of processor-specific */ -#define DT_PROCNUM 0x32 /* Most used by any processor */ - -/* DT_* entries which fall between DT_VALRNGHI & DT_VALRNGLO use the - Dyn.d_un.d_val field of the Elf*_Dyn structure. This follows Sun's - approach. */ -#define DT_VALRNGLO 0x6ffffd00 -#define DT_GNU_PRELINKED 0x6ffffdf5 /* Prelinking timestamp */ -#define DT_GNU_CONFLICTSZ 0x6ffffdf6 /* Size of conflict section */ -#define DT_GNU_LIBLISTSZ 0x6ffffdf7 /* Size of library list */ -#define DT_CHECKSUM 0x6ffffdf8 -#define DT_PLTPADSZ 0x6ffffdf9 -#define DT_MOVEENT 0x6ffffdfa -#define DT_MOVESZ 0x6ffffdfb -#define DT_FEATURE_1 0x6ffffdfc /* Feature selection (DTF_*). */ -#define DT_POSFLAG_1 0x6ffffdfd /* Flags for DT_* entries, effecting - the following DT_* entry. */ -#define DT_SYMINSZ 0x6ffffdfe /* Size of syminfo table (in bytes) */ -#define DT_SYMINENT 0x6ffffdff /* Entry size of syminfo */ -#define DT_VALRNGHI 0x6ffffdff -#define DT_VALTAGIDX(tag) (DT_VALRNGHI - (tag)) /* Reverse order! */ -#define DT_VALNUM 12 - -/* DT_* entries which fall between DT_ADDRRNGHI & DT_ADDRRNGLO use the - Dyn.d_un.d_ptr field of the Elf*_Dyn structure. - - If any adjustment is made to the ELF object after it has been - built these entries will need to be adjusted. */ -#define DT_ADDRRNGLO 0x6ffffe00 -#define DT_GNU_CONFLICT 0x6ffffef8 /* Start of conflict section */ -#define DT_GNU_LIBLIST 0x6ffffef9 /* Library list */ -#define DT_CONFIG 0x6ffffefa /* Configuration information. */ -#define DT_DEPAUDIT 0x6ffffefb /* Dependency auditing. */ -#define DT_AUDIT 0x6ffffefc /* Object auditing. */ -#define DT_PLTPAD 0x6ffffefd /* PLT padding. */ -#define DT_MOVETAB 0x6ffffefe /* Move table. */ -#define DT_SYMINFO 0x6ffffeff /* Syminfo table. */ -#define DT_ADDRRNGHI 0x6ffffeff -#define DT_ADDRTAGIDX(tag) (DT_ADDRRNGHI - (tag)) /* Reverse order! */ -#define DT_ADDRNUM 10 - -/* The versioning entry types. The next are defined as part of the - GNU extension. */ -#define DT_VERSYM 0x6ffffff0 - -#define DT_RELACOUNT 0x6ffffff9 -#define DT_RELCOUNT 0x6ffffffa - -/* These were chosen by Sun. */ -#define DT_FLAGS_1 0x6ffffffb /* State flags, see DF_1_* below. */ -#define DT_VERDEF 0x6ffffffc /* Address of version definition - table */ -#define DT_VERDEFNUM 0x6ffffffd /* Number of version definitions */ -#define DT_VERNEED 0x6ffffffe /* Address of table with needed - versions */ -#define DT_VERNEEDNUM 0x6fffffff /* Number of needed versions */ -#define DT_VERSIONTAGIDX(tag) (DT_VERNEEDNUM - (tag)) /* Reverse order! */ -#define DT_VERSIONTAGNUM 16 - -/* Sun added these machine-independent extensions in the "processor-specific" - range. Be compatible. */ -#define DT_AUXILIARY 0x7ffffffd /* Shared object to load before self */ -#define DT_FILTER 0x7fffffff /* Shared object to get values from */ -#define DT_EXTRATAGIDX(tag) ((Elf32_Word)-((Elf32_Sword) (tag) <<1>>1)-1) -#define DT_EXTRANUM 3 - -/* Values of `d_un.d_val' in the DT_FLAGS entry. */ -#define DF_ORIGIN 0x00000001 /* Object may use DF_ORIGIN */ -#define DF_SYMBOLIC 0x00000002 /* Symbol resolutions starts here */ -#define DF_TEXTREL 0x00000004 /* Object contains text relocations */ -#define DF_BIND_NOW 0x00000008 /* No lazy binding for this object */ -#define DF_STATIC_TLS 0x00000010 /* Module uses the static TLS model */ - -/* State flags selectable in the `d_un.d_val' element of the DT_FLAGS_1 - entry in the dynamic section. */ -#define DF_1_NOW 0x00000001 /* Set RTLD_NOW for this object. */ -#define DF_1_GLOBAL 0x00000002 /* Set RTLD_GLOBAL for this object. */ -#define DF_1_GROUP 0x00000004 /* Set RTLD_GROUP for this object. */ -#define DF_1_NODELETE 0x00000008 /* Set RTLD_NODELETE for this object.*/ -#define DF_1_LOADFLTR 0x00000010 /* Trigger filtee loading at runtime.*/ -#define DF_1_INITFIRST 0x00000020 /* Set RTLD_INITFIRST for this object*/ -#define DF_1_NOOPEN 0x00000040 /* Set RTLD_NOOPEN for this object. */ -#define DF_1_ORIGIN 0x00000080 /* $ORIGIN must be handled. */ -#define DF_1_DIRECT 0x00000100 /* Direct binding enabled. */ -#define DF_1_TRANS 0x00000200 -#define DF_1_INTERPOSE 0x00000400 /* Object is used to interpose. */ -#define DF_1_NODEFLIB 0x00000800 /* Ignore default lib search path. */ -#define DF_1_NODUMP 0x00001000 /* Object can't be dldump'ed. */ -#define DF_1_CONFALT 0x00002000 /* Configuration alternative created.*/ -#define DF_1_ENDFILTEE 0x00004000 /* Filtee terminates filters search. */ -#define DF_1_DISPRELDNE 0x00008000 /* Disp reloc applied at build time. */ -#define DF_1_DISPRELPND 0x00010000 /* Disp reloc applied at run-time. */ - -/* Flags for the feature selection in DT_FEATURE_1. */ -#define DTF_1_PARINIT 0x00000001 -#define DTF_1_CONFEXP 0x00000002 - -/* Flags in the DT_POSFLAG_1 entry effecting only the next DT_* entry. */ -#define DF_P1_LAZYLOAD 0x00000001 /* Lazyload following object. */ -#define DF_P1_GROUPPERM 0x00000002 /* Symbols from next object are not - generally available. */ - -/* Special section indices. */ - -#define SHN_UNDEF 0 /* Undefined section */ -#define SHN_LORESERVE 0xff00 /* Start of reserved indices */ -#define SHN_LOPROC 0xff00 /* Start of processor-specific */ -#define SHN_HIPROC 0xff1f /* End of processor-specific */ -#define SHN_LOOS 0xff20 /* Start of OS-specific */ -#define SHN_HIOS 0xff3f /* End of OS-specific */ -#define SHN_ABS 0xfff1 /* Associated symbol is absolute */ -#define SHN_COMMON 0xfff2 /* Associated symbol is common */ -#define SHN_XINDEX 0xffff /* Index is in extra table. */ -#define SHN_HIRESERVE 0xffff /* End of reserved indices */ - -/* Legal values for sh_type (section type). */ - -#define SHT_NULL 0 /* Section header table entry unused */ -#define SHT_PROGBITS 1 /* Program data */ -#define SHT_SYMTAB 2 /* Symbol table */ -#define SHT_STRTAB 3 /* String table */ -#define SHT_RELA 4 /* Relocation entries with addends */ -#define SHT_HASH 5 /* Symbol hash table */ -#define SHT_DYNAMIC 6 /* Dynamic linking information */ -#define SHT_NOTE 7 /* Notes */ -#define SHT_NOBITS 8 /* Program space with no data (bss) */ -#define SHT_REL 9 /* Relocation entries, no addends */ -#define SHT_SHLIB 10 /* Reserved */ -#define SHT_DYNSYM 11 /* Dynamic linker symbol table */ -#define SHT_INIT_ARRAY 14 /* Array of constructors */ -#define SHT_FINI_ARRAY 15 /* Array of destructors */ -#define SHT_PREINIT_ARRAY 16 /* Array of pre-constructors */ -#define SHT_GROUP 17 /* Section group */ -#define SHT_SYMTAB_SHNDX 18 /* Extended section indeces */ -#define SHT_NUM 19 /* Number of defined types. */ -#define SHT_LOOS 0x60000000 /* Start OS-specific */ -#define SHT_GNU_LIBLIST 0x6ffffff7 /* Prelink library list */ -#define SHT_CHECKSUM 0x6ffffff8 /* Checksum for DSO content. */ -#define SHT_LOSUNW 0x6ffffffa /* Sun-specific low bound. */ -#define SHT_SUNW_move 0x6ffffffa -#define SHT_SUNW_COMDAT 0x6ffffffb -#define SHT_SUNW_syminfo 0x6ffffffc -#define SHT_GNU_verdef 0x6ffffffd /* Version definition section. */ -#define SHT_GNU_verneed 0x6ffffffe /* Version needs section. */ -#define SHT_GNU_versym 0x6fffffff /* Version symbol table. */ -#define SHT_HISUNW 0x6fffffff /* Sun-specific high bound. */ -#define SHT_HIOS 0x6fffffff /* End OS-specific type */ -#define SHT_LOPROC 0x70000000 /* Start of processor-specific */ -#define SHT_HIPROC 0x7fffffff /* End of processor-specific */ -#define SHT_LOUSER 0x80000000 /* Start of application-specific */ -#define SHT_HIUSER 0x8fffffff /* End of application-specific */ - -/* Legal values for sh_flags (section flags). */ - -#define SHF_WRITE (1 << 0) /* Writable */ -#define SHF_ALLOC (1 << 1) /* Occupies memory during execution */ -#define SHF_EXECINSTR (1 << 2) /* Executable */ -#define SHF_MERGE (1 << 4) /* Might be merged */ -#define SHF_STRINGS (1 << 5) /* Contains nul-terminated strings */ -#define SHF_INFO_LINK (1 << 6) /* `sh_info' contains SHT index */ -#define SHF_LINK_ORDER (1 << 7) /* Preserve order after combining */ -#define SHF_OS_NONCONFORMING (1 << 8) /* Non-standard OS specific handling - required */ -#define SHF_GROUP (1 << 9) /* Section is member of a group. */ -#define SHF_TLS (1 << 10) /* Section hold thread-local data. */ -#define SHF_MASKOS 0x0ff00000 /* OS-specific. */ -#define SHF_MASKPROC 0xf0000000 /* Processor-specific */ - -/* Section group handling. */ -#define GRP_COMDAT 0x1 /* Mark group as COMDAT. */ - -/* Symbol table entry. */ - -typedef struct -{ - Elf32_Word st_name; /* Symbol name (string tbl index) */ - Elf32_Addr st_value; /* Symbol value */ - Elf32_Word st_size; /* Symbol size */ - unsigned char st_info; /* Symbol type and binding */ - unsigned char st_other; /* Symbol visibility */ - Elf32_Section st_shndx; /* Section index */ -} Elf32_Sym; - -typedef struct -{ - Elf64_Word st_name; /* Symbol name (string tbl index) */ - unsigned char st_info; /* Symbol type and binding */ - unsigned char st_other; /* Symbol visibility */ - Elf64_Section st_shndx; /* Section index */ - Elf64_Addr st_value; /* Symbol value */ - Elf64_Xword st_size; /* Symbol size */ -} Elf64_Sym; - -/* Relocation table entry without addend (in section of type SHT_REL). */ - -typedef struct -{ - Elf32_Addr r_offset; /* Address */ - Elf32_Word r_info; /* Relocation type and symbol index */ -} Elf32_Rel; - -/* I have seen two different definitions of the Elf64_Rel and - Elf64_Rela structures, so we'll leave them out until Novell (or - whoever) gets their act together. */ -/* The following, at least, is used on Sparc v9, MIPS, and Alpha. */ - -typedef struct -{ - Elf64_Addr r_offset; /* Address */ - Elf64_Xword r_info; /* Relocation type and symbol index */ -} Elf64_Rel; - -/* Relocation table entry with addend (in section of type SHT_RELA). */ - -typedef struct -{ - Elf32_Addr r_offset; /* Address */ - Elf32_Word r_info; /* Relocation type and symbol index */ - Elf32_Sword r_addend; /* Addend */ -} Elf32_Rela; - -typedef struct -{ - Elf64_Addr r_offset; /* Address */ - Elf64_Xword r_info; /* Relocation type and symbol index */ - Elf64_Sxword r_addend; /* Addend */ -} Elf64_Rela; - -/* How to extract and insert information held in the r_info field. */ - -#define ELF32_R_SYM(val) ((val) >> 8) -#define ELF32_R_TYPE(val) ((val) & 0xff) -#define ELF32_R_INFO(sym, type) (((sym) << 8) + ((type) & 0xff)) - -#define ELF64_R_SYM(i) ((i) >> 32) -#define ELF64_R_TYPE(i) ((i) & 0xffffffff) -#define ELF64_R_INFO(sym,type) ((((Elf64_Xword) (sym)) << 32) + (type)) - - -/* Intel 80386 specific definitions. */ - -/* i386 relocs. */ - -#define R_386_NONE 0 /* No reloc */ -#define R_386_32 1 /* Direct 32 bit */ -#define R_386_PC32 2 /* PC relative 32 bit */ -#define R_386_GOT32 3 /* 32 bit GOT entry */ -#define R_386_PLT32 4 /* 32 bit PLT address */ -#define R_386_COPY 5 /* Copy symbol at runtime */ -#define R_386_GLOB_DAT 6 /* Create GOT entry */ -#define R_386_JMP_SLOT 7 /* Create PLT entry */ -#define R_386_RELATIVE 8 /* Adjust by program base */ -#define R_386_GOTOFF 9 /* 32 bit offset to GOT */ -#define R_386_GOTPC 10 /* 32 bit PC relative offset to GOT */ -#define R_386_32PLT 11 -#define R_386_TLS_TPOFF 14 /* Offset in static TLS block */ -#define R_386_TLS_IE 15 /* Address of GOT entry for static TLS - block offset */ -#define R_386_TLS_GOTIE 16 /* GOT entry for static TLS block - offset */ -#define R_386_TLS_LE 17 /* Offset relative to static TLS - block */ -#define R_386_TLS_GD 18 /* Direct 32 bit for GNU version of - general dynamic thread local data */ -#define R_386_TLS_LDM 19 /* Direct 32 bit for GNU version of - local dynamic thread local data - in LE code */ -#define R_386_16 20 -#define R_386_PC16 21 -#define R_386_8 22 -#define R_386_PC8 23 -#define R_386_TLS_GD_32 24 /* Direct 32 bit for general dynamic - thread local data */ -#define R_386_TLS_GD_PUSH 25 /* Tag for pushl in GD TLS code */ -#define R_386_TLS_GD_CALL 26 /* Relocation for call to - __tls_get_addr() */ -#define R_386_TLS_GD_POP 27 /* Tag for popl in GD TLS code */ -#define R_386_TLS_LDM_32 28 /* Direct 32 bit for local dynamic - thread local data in LE code */ -#define R_386_TLS_LDM_PUSH 29 /* Tag for pushl in LDM TLS code */ -#define R_386_TLS_LDM_CALL 30 /* Relocation for call to - __tls_get_addr() in LDM code */ -#define R_386_TLS_LDM_POP 31 /* Tag for popl in LDM TLS code */ -#define R_386_TLS_LDO_32 32 /* Offset relative to TLS block */ -#define R_386_TLS_IE_32 33 /* GOT entry for negated static TLS - block offset */ -#define R_386_TLS_LE_32 34 /* Negated offset relative to static - TLS block */ -#define R_386_TLS_DTPMOD32 35 /* ID of module containing symbol */ -#define R_386_TLS_DTPOFF32 36 /* Offset in TLS block */ -#define R_386_TLS_TPOFF32 37 /* Negated offset in static TLS block */ -/* Keep this the last entry. */ -#define R_386_NUM 38 - -#endif /* ASSEMBLY */ - -#endif /* ELF_H */ diff --git a/memtest86+_old/error.c b/memtest86+_old/error.c deleted file mode 100644 index 4b4f1f0..0000000 --- a/memtest86+_old/error.c +++ /dev/null @@ -1,629 +0,0 @@ -/* error.c - MemTest-86 Version 4.1 - * - * Released under version 2 of the Gnu Public License. - * By Chris Brady - */ -#include "stddef.h" -#include "stdint.h" -#include "test.h" -#include "config.h" -#include "cpuid.h" -#include "smp.h" -#include "dmi.h" -#include "controller.h" - -extern int dmi_err_cnts[MAX_DMI_MEMDEVS]; -extern int beepmode; -extern short dmi_initialized; -extern struct cpu_ident cpu_id; -extern struct barrier_s *barr; -extern int test_ticks, nticks; -extern struct tseq tseq[]; -extern volatile int test; -void poll_errors(); -extern int num_cpus; - -static void update_err_counts(void); -static void print_err_counts(void); -static void common_err(); -static int syn, chan, len=1; - -static void paint_line(int msg_line, unsigned vga_color) { - if (msg_line < 24) { - char* pp; - int i; - for(i=0, pp=(char *)((SCREEN_ADR+msg_line*160+1)); - i<76; i++, pp+=2) { - *pp = vga_color; - } - } -} - -/* - * Report an assertion failure. This is typically NOT a memory error. - */ -void assert_fail(const char* file, int line_no) { - spin_lock(&barr->mutex); - - scroll(); - cprint(vv->msg_line, 0, " *** INTERNAL ERROR *** line "); - dprint(vv->msg_line, 31, line_no, 5, 1); - cprint(vv->msg_line, 37, file); - paint_line(vv->msg_line, 0x0E /* yellow on black */); - - spin_unlock(&barr->mutex); - - // Ensure the message remains visible for a while - // before it scrolls away. Assert-fails should be rare - // and may indicate that subsequent result aren't valid. - sleep(60, 0, 0, 0); -} - -/* - * Display data error message. Don't display duplicate errors. - */ -void mt86_error(ulong *adr, ulong good, ulong bad) -{ - ulong xor; - - spin_lock(&barr->mutex); - - xor = good ^ bad; - -#ifdef USB_WAR - /* Skip any errors that appear to be due to the BIOS using location - * 0x4e0 for USB keyboard support. This often happens with Intel - * 810, 815 and 820 chipsets. It is possible that we will skip - * a real error but the odds are very low. - */ - if ((ulong)adr == 0x4e0 || (ulong)adr == 0x410) { - return; - } -#endif - - common_err(adr, good, bad, xor, 0); - spin_unlock(&barr->mutex); -} - -/* - * Display address error message. - * Since this is strictly an address test, trying to create BadRAM - * patterns does not make sense. Just report the error. - */ -void ad_err1(ulong *adr1, ulong *mask, ulong bad, ulong good) -{ - spin_lock(&barr->mutex); - common_err(adr1, good, bad, (ulong)mask, 1); - spin_unlock(&barr->mutex); -} - -/* - * Display address error message. - * Since this type of address error can also report data errors go - * ahead and generate BadRAM patterns. - */ -void ad_err2(ulong *adr, ulong bad) -{ - spin_lock(&barr->mutex); - common_err(adr, (ulong)adr, bad, ((ulong)adr) ^ bad, 0); - spin_unlock(&barr->mutex); -} - -static void update_err_counts(void) -{ - if (beepmode){ - beep(600); - beep(1000); - } - - if (vv->pass && vv->ecount == 0) { - cprint(LINE_MSG, COL_MSG, - " "); - } - ++(vv->ecount); - tseq[test].errors++; -} - -static void print_err_counts(void) -{ - if ((vv->ecount > 4096) && (vv->ecount % 256 != 0)) return; - - dprint(LINE_INFO, 72, vv->ecount, 6, 0); - /* - dprint(LINE_INFO, 56, vv->ecc_ecount, 6, 0); - */ - - /* Paint the error messages on the screen red to provide a vivid */ - /* indicator that an error has occured */ - if ((vv->printmode == PRINTMODE_ADDRESSES || - vv->printmode == PRINTMODE_PATTERNS)) { - paint_line(vv->msg_line, 0x47 /* gray-on-red */); - } -} - -/* - * Print an individual error - */ -void common_err( ulong *adr, ulong good, ulong bad, ulong xor, int type) -{ - int i, j, n, x, flag=0; - ulong page, offset; - int patnchg; - ulong mb; - - update_err_counts(); - - switch(vv->printmode) { - case PRINTMODE_SUMMARY: - /* Don't do anything for a parity error. */ - if (type == 3) { - return; - } - - /* Address error */ - if (type == 1) { - xor = good ^ bad; - } - - /* Ecc correctable errors */ - if (type == 2) { - /* the bad value is the corrected flag */ - if (bad) { - vv->erri.cor_err++; - } - page = (ulong)adr; - offset = good; - } else { - page = page_of(adr); - offset = (ulong)adr & 0xFFF; - } - - /* Calc upper and lower error addresses */ - if (vv->erri.low_addr.page > page) { - vv->erri.low_addr.page = page; - vv->erri.low_addr.offset = offset; - flag++; - } else if (vv->erri.low_addr.page == page && - vv->erri.low_addr.offset > offset) { - vv->erri.low_addr.offset = offset; - vv->erri.high_addr.offset = offset; - flag++; - } else if (vv->erri.high_addr.page < page) { - vv->erri.high_addr.page = page; - flag++; - } - if (vv->erri.high_addr.page == page && - vv->erri.high_addr.offset < offset) { - vv->erri.high_addr.offset = offset; - flag++; - } - - /* Calc bits in error */ - for (i=0, n=0; i<32; i++) { - if (xor>>i & 1) { - n++; - } - } - vv->erri.tbits += n; - if (n > vv->erri.max_bits) { - vv->erri.max_bits = n; - flag++; - } - if (n < vv->erri.min_bits) { - vv->erri.min_bits = n; - flag++; - } - if (vv->erri.ebits ^ xor) { - flag++; - } - vv->erri.ebits |= xor; - - /* Calc max contig errors */ - len = 1; - if ((ulong)adr == (ulong)vv->erri.eadr+4 || - (ulong)adr == (ulong)vv->erri.eadr-4 ) { - len++; - } - if (len > vv->erri.maxl) { - vv->erri.maxl = len; - flag++; - } - vv->erri.eadr = (ulong)adr; - - if (vv->erri.hdr_flag == 0) { - clear_scroll(); - cprint(LINE_HEADER+0, 1, "Error Confidence Value:"); - cprint(LINE_HEADER+1, 1, " Lowest Error Address:"); - cprint(LINE_HEADER+2, 1, " Highest Error Address:"); - cprint(LINE_HEADER+3, 1, " Bits in Error Mask:"); - cprint(LINE_HEADER+4, 1, " Bits in Error - Total:"); - cprint(LINE_HEADER+4, 29, "Min: Max: Avg:"); - cprint(LINE_HEADER+5, 1, " Max Contiguous Errors:"); - x = 24; - if (dmi_initialized) { - for ( i=0; i < MAX_DMI_MEMDEVS;){ - n = LINE_HEADER+7; - for (j=0; j<4; j++) { - if (dmi_err_cnts[i] >= 0) { - dprint(n, x, i, 2, 0); - cprint(n, x+2, ": 0"); - } - i++; - n++; - } - x += 10; - } - } - - cprint(LINE_HEADER+0, 64, "Test Errors"); - vv->erri.hdr_flag++; - } - if (flag) { - /* Calc bits in error */ - for (i=0, n=0; i<32; i++) { - if (vv->erri.ebits>>i & 1) { - n++; - } - } - page = vv->erri.low_addr.page; - offset = vv->erri.low_addr.offset; - mb = page >> 8; - hprint(LINE_HEADER+1, 25, page); - hprint2(LINE_HEADER+1, 33, offset, 3); - cprint(LINE_HEADER+1, 36, " - . MB"); - dprint(LINE_HEADER+1, 39, mb, 5, 0); - dprint(LINE_HEADER+1, 45, ((page & 0xF)*10)/16, 1, 0); - page = vv->erri.high_addr.page; - offset = vv->erri.high_addr.offset; - mb = page >> 8; - hprint(LINE_HEADER+2, 25, page); - hprint2(LINE_HEADER+2, 33, offset, 3); - cprint(LINE_HEADER+2, 36, " - . MB"); - dprint(LINE_HEADER+2, 39, mb, 5, 0); - dprint(LINE_HEADER+2, 45, ((page & 0xF)*10)/16, 1, 0); - hprint(LINE_HEADER+3, 25, vv->erri.ebits); - dprint(LINE_HEADER+4, 25, n, 2, 1); - dprint(LINE_HEADER+4, 34, vv->erri.min_bits, 2, 1); - dprint(LINE_HEADER+4, 42, vv->erri.max_bits, 2, 1); - dprint(LINE_HEADER+4, 50, vv->erri.tbits/vv->ecount, 2, 1); - dprint(LINE_HEADER+5, 25, vv->erri.maxl, 7, 1); - x = 28; - for ( i=0; i < MAX_DMI_MEMDEVS;){ - n = LINE_HEADER+7; - for (j=0; j<4; j++) { - if (dmi_err_cnts[i] > 0) { - dprint (n, x, dmi_err_cnts[i], 7, 1); - } - i++; - n++; - } - x += 10; - } - - for (i=0; tseq[i].msg != NULL; i++) { - dprint(LINE_HEADER+1+i, 66, i, 2, 0); - dprint(LINE_HEADER+1+i, 68, tseq[i].errors, 8, 0); - } - } - if (vv->erri.cor_err) { - dprint(LINE_HEADER+6, 25, vv->erri.cor_err, 8, 1); - } - break; - - case PRINTMODE_ADDRESSES: - /* Don't display duplicate errors */ - if ((ulong)adr == (ulong)vv->erri.eadr && - xor == vv->erri.exor) { - return; - } - if (vv->erri.hdr_flag == 0) { - clear_scroll(); - cprint(LINE_HEADER, 0, - "Tst Pass Failing Address Good Bad Err-Bits Count CPU"); - cprint(LINE_HEADER+1, 0, - "--- ---- ----------------------- -------- -------- -------- ----- ----"); - vv->erri.hdr_flag++; - } - /* Check for keyboard input */ - check_input(); - scroll(); - - if ( type == 2 || type == 3) { - page = (ulong)adr; - offset = good; - } else { - page = page_of(adr); - offset = ((unsigned long)adr) & 0xFFF; - } - mb = page >> 8; - dprint(vv->msg_line, 0, test+1, 3, 0); - dprint(vv->msg_line, 4, vv->pass, 5, 0); - hprint(vv->msg_line, 11, page); - hprint2(vv->msg_line, 19, offset, 3); - cprint(vv->msg_line, 22, " - . MB"); - dprint(vv->msg_line, 25, mb, 5, 0); - dprint(vv->msg_line, 31, ((page & 0xF)*10)/16, 1, 0); - - if (type == 3) { - /* ECC error */ - cprint(vv->msg_line, 36, - bad?"corrected ": "uncorrected "); - hprint2(vv->msg_line, 60, syn, 4); - cprint(vv->msg_line, 68, "ECC"); - dprint(vv->msg_line, 74, chan, 2, 0); - } else if (type == 2) { - cprint(vv->msg_line, 36, "Parity error detected "); - } else { - hprint(vv->msg_line, 36, good); - hprint(vv->msg_line, 46, bad); - hprint(vv->msg_line, 56, xor); - dprint(vv->msg_line, 66, vv->ecount, 5, 0); - dprint(vv->msg_line, 74, smp_my_cpu_num(), 2,1); - vv->erri.exor = xor; - } - vv->erri.eadr = (ulong)adr; - print_err_counts(); - break; - - case PRINTMODE_PATTERNS: - if (vv->erri.hdr_flag == 0) { - clear_scroll(); - vv->erri.hdr_flag++; - } - /* Do not do badram patterns from test 0 or 5 */ - if (test == 0 || test == 5) { - return; - } - /* Only do patterns for data errors */ - if ( type != 0) { - return; - } - /* Process the address in the pattern administration */ - patnchg=insertaddress ((ulong) adr); - if (patnchg) { - printpatn(); - } - break; - - case PRINTMODE_NONE: - if (vv->erri.hdr_flag == 0) { - clear_scroll(); - vv->erri.hdr_flag++; - } - break; - } -} - -/* - * Print an ecc error - */ -void print_ecc_err(unsigned long page, unsigned long offset, - int corrected, unsigned short syndrome, int channel) -{ - ++(vv->ecc_ecount); - syn = syndrome; - chan = channel; - common_err((ulong *)page, offset, corrected, 0, 2); -} - -#ifdef PARITY_MEM -/* - * Print a parity error message - */ -void parity_err( unsigned long edi, unsigned long esi) -{ - unsigned long addr; - - if (test == 5) { - addr = esi; - } else { - addr = edi; - } - common_err((ulong *)addr, addr & 0xFFF, 0, 0, 3); -} -#endif - -/* - * Print the pattern array as a LILO boot option addressing BadRAM support. - */ -void printpatn (void) -{ - int idx=0; - int x; - - /* Check for keyboard input */ - check_input(); - - if (vv->numpatn == 0) - return; - - scroll(); - - cprint (vv->msg_line, 0, "badram="); - x=7; - - for (idx = 0; idx < vv->numpatn; idx++) { - - if (x > 80-22) { - scroll(); - x=7; - } - cprint (vv->msg_line, x, "0x"); - hprint (vv->msg_line, x+2, vv->patn[idx].adr ); - cprint (vv->msg_line, x+10, ",0x"); - hprint (vv->msg_line, x+13, vv->patn[idx].mask); - if (idx+1 < vv->numpatn) - cprint (vv->msg_line, x+21, ","); - x+=22; - } -} - -/* - * Show progress by displaying elapsed time and update bar graphs - */ -short spin_idx[MAX_CPUS]; -char spin[4] = {'|','/','-','\\'}; - -void do_tick(int me) -{ - int i, j, pct; - ulong h, l, n, t; - extern int mstr_cpu; - - if (++spin_idx[me] > 3) { - spin_idx[me] = 0; - } - cplace(8, me+7, spin[spin_idx[me]]); - - - /* Check for keyboard input */ - if (me == mstr_cpu) { - check_input(); - } - /* A barrier here holds the other CPUs until the configuration - * changes are done */ - s_barrier(); - - /* Only the first selected CPU does the update */ - if (me != mstr_cpu) { - return; - } - - /* FIXME only print serial error messages from the tick handler */ - if (vv->ecount) { - print_err_counts(); - } - - nticks++; - vv->total_ticks++; - - if (test_ticks) { - pct = 100*nticks/test_ticks; - if (pct > 100) { - pct = 100; - } - } else { - pct = 0; - } - dprint(2, COL_MID+4, pct, 3, 0); - i = (BAR_SIZE * pct) / 100; - while (i > vv->tptr) { - if (vv->tptr >= BAR_SIZE) { - break; - } - cprint(2, COL_MID+9+vv->tptr, "#"); - vv->tptr++; - } - - if (vv->pass_ticks) { - pct = 100*vv->total_ticks/vv->pass_ticks; - if (pct > 100) { - pct = 100; - } - } else { - pct = 0; - } - dprint(1, COL_MID+4, pct, 3, 0); - i = (BAR_SIZE * pct) / 100; - while (i > vv->pptr) { - if (vv->pptr >= BAR_SIZE) { - break; - } - cprint(1, COL_MID+9+vv->pptr, "#"); - vv->pptr++; - } - - if (vv->ecount && vv->printmode == PRINTMODE_SUMMARY) { - /* Compute confidence score */ - pct = 0; - - /* If there are no errors within 1mb of start - end addresses */ - h = vv->pmap[vv->msegs - 1].end - 0x100; - if (vv->erri.low_addr.page > 0x100 && - vv->erri.high_addr.page < h) { - pct += 8; - } - - /* Errors for only some tests */ - if (vv->pass) { - for (i=0, n=0; tseq[i].msg != NULL; i++) { - if (tseq[i].errors == 0) { - n++; - } - } - pct += n*3; - } else { - for (i=0, n=0; ierri.ebits & 0xf) n++; - if (vv->erri.ebits & 0xf0) n++; - if (vv->erri.ebits & 0xf00) n++; - if (vv->erri.ebits & 0xf000) n++; - if (vv->erri.ebits & 0xf0000) n++; - if (vv->erri.ebits & 0xf00000) n++; - if (vv->erri.ebits & 0xf000000) n++; - if (vv->erri.ebits & 0xf0000000) n++; - pct += (8-n)*2; - - /* Adjust the score */ - pct = pct*100/22; - /* - if (pct > 100) { - pct = 100; - } - */ - dprint(LINE_HEADER+0, 25, pct, 3, 1); - } - - - /* We can't do the elapsed time unless the rdtsc instruction - * is supported - */ - if (cpu_id.fid.bits.rdtsc) { - asm __volatile__( - "rdtsc":"=a" (l),"=d" (h)); - asm __volatile__ ( - "subl %2,%0\n\t" - "sbbl %3,%1" - :"=a" (l), "=d" (h) - :"g" (vv->startl), "g" (vv->starth), - "0" (l), "1" (h)); - t = h * ((unsigned)0xffffffff / vv->clks_msec) / 1000; - t += (l / vv->clks_msec) / 1000; - i = t % 60; - j = i % 10; - - if(j != vv->each_sec) - { - - dprint(LINE_TIME, COL_TIME+9, i % 10, 1, 0); - dprint(LINE_TIME, COL_TIME+8, i / 10, 1, 0); - t /= 60; - i = t % 60; - dprint(LINE_TIME, COL_TIME+6, i % 10, 1, 0); - dprint(LINE_TIME, COL_TIME+5, i / 10, 1, 0); - t /= 60; - dprint(LINE_TIME, COL_TIME, t, 4, 0); - - if(vv->check_temp > 0 && !(vv->fail_safe & 4)) - { - coretemp(); - } - vv->each_sec = j; - } - } - - /* Poll for ECC errors */ - /* - poll_errors(); - */ -} diff --git a/memtest86+_old/extra.c b/memtest86+_old/extra.c deleted file mode 100644 index ff580f2..0000000 --- a/memtest86+_old/extra.c +++ /dev/null @@ -1,981 +0,0 @@ -// This is the extra stuff added to the memtest+ from memtest.org -// Code from Eric Nelson and Wee -// (Checked without vendor-specific optimization before adding) -/* extra.c - - * - * Released under version 2 of the Gnu Public License. - * - */ - -#include "test.h" -#include "screen_buffer.h" -#include "pci.h" -#include "extra.h" - -static int ctrl = -1; - -struct memory_controller { - unsigned vendor; - unsigned device; - int worked; - void (*change_timing)(int cas, int rcd, int rp, int ras); -}; - -static struct memory_controller mem_ctr[] = { - - /* AMD 64*/ - { 0x1022, 0x1100, 1, change_timing_amd64}, //AMD64 hypertransport link - - /* nVidia */ - { 0x10de, 0x01E0, 0, change_timing_nf2}, // nforce2 - - /* Intel */ - { 0x8086, 0x2570, 0, change_timing_i875}, //Intel i848/i865 - { 0x8086, 0x2578, 0, change_timing_i875}, //Intel i875P - { 0x8086, 0x2580, 0, change_timing_i925}, //Intel i915P/G - { 0x8086, 0x2584, 0, change_timing_i925}, //Intel i925X - { 0x8086, 0x2770, 0, change_timing_i925}, //Intel Lakeport - { 0x8086, 0x3580, 0, change_timing_i852}, //Intel i852GM - i855GM/GME (But not i855PM) -}; - -struct drc { - unsigned t_rwt; - unsigned t_wrt; - unsigned t_ref; - unsigned t_en2t; - unsigned t_rwqb; - unsigned t_rct; - unsigned t_rrd; - unsigned t_wr; -}; - -static struct drc a64; - -void find_memctr(void) // Basically copy from the find_controller function -{ - unsigned long vendor; - unsigned long device; - unsigned long a64; - int i= 0; - int result; - - result = pci_conf_read(0, 0, 0, PCI_VENDOR_ID, 2, &vendor); - result = pci_conf_read(0, 0, 0, PCI_DEVICE_ID, 2, &device); - - pci_conf_read(0, 24, 0, 0x00, 4, &a64); - - if( a64 == 0x11001022) { - ctrl = 0; - return; - } - - if (result == 0) { - for(i = 1; i < sizeof(mem_ctr)/sizeof(mem_ctr[0]); i++) { - if ((mem_ctr[i].vendor == vendor) && - (mem_ctr[i].device == device)) - { - ctrl = i; - return; - } - } - } - ctrl = -1; -} - -void a64_parameter(void) -{ - - ulong dramtlr; - - if ( 0 == pci_conf_read(0, 24, 2, 0x88, 4, &dramtlr) ) - { - a64.t_rct = 7 + ((dramtlr>>4) & 0x0F); - a64.t_rrd = 0 + ((dramtlr>>16) & 0x7); - a64.t_wr = 2 + ((dramtlr>>28) & 0x1); - } - - if ( 0 == pci_conf_read(0, 24, 2, 0x8C, 4, &dramtlr) ) - { - a64.t_rwt = 1 + ((dramtlr>>4) & 0x07); - a64.t_wrt = 1 + (dramtlr & 0x1); - a64.t_ref = 1 + ((dramtlr>>11) & 0x3); - } - - if ( 0 == pci_conf_read(0, 24, 2, 0x90, 4, &dramtlr) ) - { - a64.t_en2t = 1 + ((dramtlr>>28) & 0x1); - a64.t_rwqb = 2 << ((dramtlr>>14) & 0x3); - } -} - - - -void change_timing(int cas, int rcd, int rp, int ras) -{ - find_memctr(); - if ((ctrl == -1) || ( ctrl > sizeof(mem_ctr)/sizeof(mem_ctr[0]))) - { - return; - } - - mem_ctr[ctrl].change_timing(cas, rcd, rp, ras); - restart(); -} - -void amd64_option() -{ - int rwt=0, wrt=0, ref=0, en2t=0, rct=0, rrd=0, rwqb=0, wr = 0, flag=0; - - if ((ctrl == -1) || ( ctrl > sizeof(mem_ctr)/sizeof(mem_ctr[0]))) - { - return; - } - - if (mem_ctr[ctrl].worked) - { - a64_parameter(); - cprint(POP_Y+1, POP_X+4, "AMD64 options"); - - cprint(POP_Y+3, POP_X+4, "(1) Rd-Wr Delay : "); - dprint(POP_Y+3, POP_X+24, a64.t_rwt, 2, 0); - - cprint(POP_Y+4, POP_X+4, "(2) Wr-Rd Delay : "); - dprint(POP_Y+4, POP_X+24, a64.t_wrt, 2, 0); - - cprint(POP_Y+5, POP_X+4, "(3) Rd/Wr Bypass : "); - dprint(POP_Y+5, POP_X+24, a64.t_rwqb, 2, 0); - - cprint(POP_Y+6, POP_X+4, "(4) Refresh Rate : "); - switch ( a64.t_ref) - { - case 1 : cprint(POP_Y+6, POP_X+23, "15.6us"); break; - case 2 : cprint(POP_Y+6, POP_X+23, " 7.8us"); break; - case 3 : cprint(POP_Y+6, POP_X+23, " 3.9us"); break; - } - cprint(POP_Y+7, POP_X+4, "(5) Command Rate :"); - dprint(POP_Y+7, POP_X+24, a64.t_en2t, 2, 0); - cprint(POP_Y+7, POP_X+26, "T "); - - cprint(POP_Y+8, POP_X+4, "(6) Row Cycle Time: "); - dprint(POP_Y+8, POP_X+24, a64.t_rct, 2, 0); - - cprint(POP_Y+9, POP_X+4, "(7) RAS-RAS Delay : "); - dprint(POP_Y+9, POP_X+24, a64.t_rrd, 2, 0); - - cprint(POP_Y+10, POP_X+4, "(8) Write Recovery: "); - dprint(POP_Y+10, POP_X+24, a64.t_wr, 2, 0); - - cprint(POP_Y+11, POP_X+4,"(0) Cancel "); - - while(!flag) - { - switch(get_key()) - { - case 2: - popclear(); - // read-to-write delay - cprint(POP_Y+3, POP_X+4, "Rd-Wr delay "); - cprint(POP_Y+4, POP_X+4, " (2 - 6 cycles)"); - cprint(POP_Y+5, POP_X+4, "Current: "); - dprint(POP_Y+5, POP_X+14, a64.t_rwt, 4, 0); - cprint(POP_Y+7, POP_X+4, "New: "); - rwt = getval(POP_Y+7, POP_X+12, 0); - amd64_tweak(rwt, wrt, ref,en2t, rct, rrd, rwqb, wr); - break; - - case 3: - popclear(); - // read-to-write delay - cprint(POP_Y+3, POP_X+4, "Wr-Rd delay "); - cprint(POP_Y+4, POP_X+4, " (1 - 2 cycles)"); - cprint(POP_Y+5, POP_X+4, "Current: "); - dprint(POP_Y+5, POP_X+14, a64.t_wrt, 4, 0); - cprint(POP_Y+7, POP_X+4, "New: "); - wrt = getval(POP_Y+7, POP_X+12, 0); - amd64_tweak(rwt, wrt, ref,en2t, rct, rrd, rwqb, wr); - break; - - case 4: - popclear(); - // Read write queue bypass count - cprint(POP_Y+3, POP_X+4, "Rd/Wr bypass "); - cprint(POP_Y+4, POP_X+4, " (2, 4 or 8 )"); - cprint(POP_Y+5, POP_X+4, "Current: "); - dprint(POP_Y+5, POP_X+14, a64.t_rwqb, 2, 0); - cprint(POP_Y+7, POP_X+4, "New: "); - rwqb = getval(POP_Y+7, POP_X+11, 0); - amd64_tweak(rwt, wrt, ref,en2t, rct, rrd, rwqb, wr); - break; - - case 5: - popclear(); - // refresh rate - cprint(POP_Y+3, POP_X+4, "Refresh rate "); - cprint(POP_Y+4, POP_X+4, "Current: "); - switch ( a64.t_ref){ - case 1 : cprint(POP_Y+4, POP_X+14, "15.6us"); break; - case 2 : cprint(POP_Y+4, POP_X+14, "7.8us "); break; - case 3 : cprint(POP_Y+4, POP_X+14, "3.9us "); break; - } - cprint(POP_Y+6, POP_X+4, "New: "); - cprint(POP_Y+7, POP_X+4, "(1) 15.6us"); - cprint(POP_Y+8, POP_X+4, "(2) 7.8us "); - cprint(POP_Y+9, POP_X+4, "(3) 3.9us "); - ref = getval(POP_Y+6, POP_X+11, 0); - amd64_tweak(rwt, wrt, ref,en2t, rct, rrd, rwqb, wr); - break; - - case 6: - popclear(); - //Enable 2T command and addressing - cprint(POP_Y+3, POP_X+4, "Command rate:"); - cprint(POP_Y+5, POP_X+4, "(1) 1T "); //only supoprted by CG revision and later - cprint(POP_Y+6, POP_X+4, "(2) 2T "); - en2t = getval(POP_Y+3, POP_X+22, 0); - amd64_tweak(rwt, wrt, ref,en2t, rct, rrd, rwqb, wr); - break; - - case 7: - popclear(); - //Row cycle time - cprint(POP_Y+3, POP_X+4, "Row cycle time: "); - cprint(POP_Y+4, POP_X+4, " (7 - 20 cycles)"); - cprint(POP_Y+5, POP_X+4, "Current: "); - dprint(POP_Y+5, POP_X+14, a64.t_rct, 4, 0); - cprint(POP_Y+7, POP_X+4, "New: "); - rct = getval(POP_Y+7, POP_X+12, 0); - amd64_tweak(rwt, wrt, ref,en2t, rct, rrd, rwqb, wr); - break; - - case 8: - popclear(); - //Active-to-Active RAS Delay - cprint(POP_Y+3, POP_X+4, "RAS-RAS Delay: "); - cprint(POP_Y+4, POP_X+4, " (2 - 4 cycles)"); - cprint(POP_Y+5, POP_X+4, "Current: "); - dprint(POP_Y+5, POP_X+14, a64.t_rrd, 2, 0); - cprint(POP_Y+7, POP_X+4, "New: "); - rrd = getval(POP_Y+7, POP_X+12, 0); - amd64_tweak(rwt, wrt, ref,en2t, rct, rrd, rwqb, wr); - break; - - case 9: - popclear(); - //Active-to-Active RAS Delay - cprint(POP_Y+3, POP_X+4, "Write Recovery: "); - cprint(POP_Y+4, POP_X+4, " (2 - 3 cycles)"); - cprint(POP_Y+5, POP_X+4, "Current: "); - dprint(POP_Y+5, POP_X+14, a64.t_wr, 2, 0); - cprint(POP_Y+7, POP_X+4, "New: "); - wr = getval(POP_Y+7, POP_X+12, 0); - amd64_tweak(rwt, wrt, ref,en2t, rct, rrd, rwqb, wr); - break; - - case 11: - case 57: - flag++; - /* 0/CR - Cancel */ - break; - } - } - } -} - -void get_option() -{ - int cas =0, rp=0, rcd=0, ras=0, sflag = 0 ; - - while(!sflag) - { - switch(get_key()) - { - case 2: - popclear(); - cas = get_cas(); - popclear(); - - cprint(POP_Y+3, POP_X+8, "tRCD: "); - rcd = getval(POP_Y+3, POP_X+15, 0); - popclear(); - - cprint(POP_Y+3, POP_X+8, "tRP: "); - rp = getval(POP_Y+3, POP_X+15, 0); - popclear(); - - cprint(POP_Y+3, POP_X+8, "tRAS: "); - ras = getval(POP_Y+3, POP_X+15, 0); - popclear(); - change_timing(cas, rcd, rp, ras); - break; - - case 3: - popclear(); - cas = get_cas(); - change_timing(cas, 0, 0, 0); - sflag++; - break; - - case 4: - popclear(); - cprint(POP_Y+3, POP_X+8, "tRCD: "); - rcd =getval(POP_Y+3, POP_X+15, 0); - change_timing(0, rcd, 0, 0); - sflag++; - break; - - case 5: - popclear(); - cprint(POP_Y+3, POP_X+8, "tRP: "); - rp =getval(POP_Y+3, POP_X+15, 0); - change_timing(0, 0, rp, 0); - sflag++; - break; - - case 6: - popclear(); - cprint(POP_Y+3, POP_X+8, "tRAS: "); - ras =getval(POP_Y+3, POP_X+15, 0); - change_timing(0, 0, 0, ras); - sflag++; - break; - - case 7: - popclear(); - amd64_option(); - sflag++; - popclear(); - break; - - case 8: - break; - - case 11: - case 57: - sflag++; - /* 0/CR - Cancel */ - break; - } - } -} - -void get_option_1() -{ - int rp=0, rcd=0, ras=0, sflag = 0 ; - - while(!sflag) - { - switch(get_key()) - { - case 2: - popclear(); - cprint(POP_Y+3, POP_X+8, "tRCD: "); - rcd = getval(POP_Y+3, POP_X+15, 0); - popclear(); - - cprint(POP_Y+3, POP_X+8, "tRP: "); - rp = getval(POP_Y+3, POP_X+15, 0); - popclear(); - - cprint(POP_Y+3, POP_X+8, "tRAS: "); - ras = getval(POP_Y+3, POP_X+15, 0); - popclear(); - change_timing(0, rcd, rp, ras); - break; - - case 3: - popclear(); - cprint(POP_Y+3, POP_X+8, "tRCD: "); - rcd =getval(POP_Y+3, POP_X+15, 0); - change_timing(0, rcd, 0, 0); - break; - - case 4: - popclear(); - cprint(POP_Y+3, POP_X+8, "tRP: "); - rp =getval(POP_Y+3, POP_X+15, 0); - change_timing(0, 0, rp, 0); - break; - - case 5: - popclear(); - cprint(POP_Y+3, POP_X+8, "tRAS: "); - ras =getval(POP_Y+3, POP_X+15, 0); - change_timing(0, 0, 0, ras); - break; - - case 6: - popclear(); - amd64_option(); - sflag++; - popclear(); - break; - - case 7: - break; - - case 11: - case 57: - sflag++; - /* 0/CR - Cancel */ - break; - } - } -} - - -void get_menu(void) -{ - int menu ; - - find_memctr(); - - switch(ctrl) - { - case 0: menu = 2; break; - case 1: - case 2: - case 3: - case 4: menu = 0; break; - case 5: menu = 1; break; - case 6: menu = 0; break; - default: menu = -1; break; - } - - if (menu == -1) - { - popclear(); - } - else if (menu == 0) - { - cprint(POP_Y+1, POP_X+2, "Modify Timing:"); - cprint(POP_Y+3, POP_X+5, "(1) Modify All "); - cprint(POP_Y+4, POP_X+5, "(2) Modify tCAS "); - cprint(POP_Y+5, POP_X+5, "(3) Modify tRCD "); - cprint(POP_Y+6, POP_X+5, "(4) Modify tRP "); - cprint(POP_Y+7, POP_X+5, "(5) Modify tRAS "); - cprint(POP_Y+8, POP_X+5, "(0) Cancel"); - wait_keyup(); - get_option(); - } - else if (menu == 1) - { - cprint(POP_Y+1, POP_X+2, "Modify Timing:"); - cprint(POP_Y+3, POP_X+5, "(1) Modify All "); - cprint(POP_Y+4, POP_X+5, "(2) Modify tRCD "); - cprint(POP_Y+5, POP_X+5, "(3) Modify tRP "); - cprint(POP_Y+6, POP_X+5, "(4) Modify tRAS "); - cprint(POP_Y+7, POP_X+5, "(0) Cancel"); - wait_keyup(); - get_option(); - } - else // AMD64 special menu - { - cprint(POP_Y+1, POP_X+2, "Modify Timing:"); - cprint(POP_Y+3, POP_X+5, "(1) Modify All "); - cprint(POP_Y+4, POP_X+5, "(2) Modify tRCD "); - cprint(POP_Y+5, POP_X+5, "(3) Modify tRP "); - cprint(POP_Y+6, POP_X+5, "(4) Modify tRAS "); - cprint(POP_Y+7, POP_X+5, "(5) AMD64 Options"); - cprint(POP_Y+8, POP_X+5, "(0) Cancel"); - wait_keyup(); - get_option_1(); - } -} - -int get_cas(void) -{ - int i852=0, cas=0; - ulong drc, ddr; - long *ptr; - - switch(ctrl) - { - case 0: ddr = 1; break; - case 1: - case 2: - case 3: ddr = 1; break; - case 4: - pci_conf_read( 0, 0, 0, 0x44, 4, &ddr); - ddr &= 0xFFFFC000; - ptr=(long*)(ddr+0x120); - drc = *ptr; - - if ((drc & 3) == 2) ddr = 2; - else ddr = 1; - break; - case 5: ddr = 2; break; - case 6: ddr = 1; i852 = 1; break; - default: ddr = 1; - } - - if (ddr == 1) - { - cprint(POP_Y+3, POP_X+8, "tCAS: "); - cprint(POP_Y+5, POP_X+8, "(1) CAS 2.5 "); - cprint(POP_Y+6, POP_X+8, "(2) CAS 2 "); - if(!i852) { - cprint(POP_Y+7, POP_X+8, "(3) CAS 3 "); - } - cas = getval(POP_Y+3, POP_X+15, 0); - } - else if (ddr == 2) - { - cprint(POP_Y+3, POP_X+8, "tCAS: "); - cprint(POP_Y+5, POP_X+8, "(1) CAS 4 "); - cprint(POP_Y+6, POP_X+8, "(2) CAS 3 "); - cprint(POP_Y+7, POP_X+8, "(3) CAS 5 "); - cas = getval(POP_Y+3, POP_X+15, 0); - } - else - { - cas = -1; - } - - popclear(); - return (cas); -} - -///////////////////////////////////////////////////////// -// here we go for the exciting timing change part... // -///////////////////////////////////////////////////////// - -void change_timing_i852(int cas, int rcd, int rp, int ras) { - - ulong dramtlr; - ulong int1, int2; - - pci_conf_read(0, 0, 1, 0x60, 4, &dramtlr); - - // CAS Latency (tCAS) - int1 = dramtlr & 0xFF9F; - if (cas == 2) { int2 = int1 ^ 0x20; } - else if (cas == 1) { int2 = int1; } - else { int2 = dramtlr; } - - - // RAS-To-CAS (tRCD) - int1 = int2 & 0xFFF3; - if (rcd == 2) { int2 = int1 ^ 0x8; } - else if (rcd == 3) { int2 = int1 ^ 0x4; } - else if (rcd == 4) { int2 = int1; } - // else { int2 = int2; } - - - // RAS Precharge (tRP) - int1 = int2 & 0xFFFC; - if (rp == 2) { int2 = int1 ^ 0x2; } - else if (rp == 3) { int2 = int1 ^ 0x1; } - else if (rp == 4) { int2 = int1; } - // else { int2 = int2; } - - - // RAS Active to precharge (tRAS) - int1 = int2 & 0xF9FF; - if (ras == 5) { int2 = int1 ^ 0x0600; } - else if (ras == 6) { int2 = int1 ^ 0x0400; } - else if (ras == 7) { int2 = int1 ^ 0x0200; } - else if (ras == 8) { int2 = int1; } - // else { int2 = int2; } - - pci_conf_write(0, 0, 1, 0x60, 4, int2); - __delay(500); -} - -void change_timing_i925(int cas, int rcd, int rp, int ras) -{ - ulong int1, dev0, temp; - long *ptr; - - //read MMRBAR - pci_conf_read( 0, 0, 0, 0x44, 4, &dev0); - dev0 &= 0xFFFFC000; - - ptr=(long*)(dev0+0x114); - temp = *ptr; - - // RAS-To-CAS (tRCD) - int1 = temp | 0x70; - if (rcd == 2) { temp = int1 ^ 0x70; } - else if (rcd == 3) { temp = int1 ^ 0x60; } - else if (rcd == 4) { temp = int1 ^ 0x50; } - else if (rcd == 5) { temp = int1 ^ 0x40; } - // else { temp = temp;} - - //RAS precharge (tRP) - int1 = temp | 0x7; - if (rp == 2) { temp = int1 ^ 0x7; } - else if (rp == 3) { temp = int1 ^ 0x6; } - else if (rp == 4) { temp = int1 ^ 0x5; } - else if (rp == 5) { temp = int1 ^ 0x4; } - // else { temp = temp;} - - if (mem_ctr[ctrl].device == 0x2770 ) // Lakeport? - { - // RAS Active to precharge (tRAS) - int1 = temp | 0xF80000; // bits 23:19 - if (ras == 4) { temp = int1 ^ 0xD80000; } - else if (ras == 5) { temp = int1 ^ 0xD00000; } - else if (ras == 6) { temp = int1 ^ 0xC80000; } - else if (ras == 7) { temp = int1 ^ 0xC00000; } - else if (ras == 8) { temp = int1 ^ 0xB80000; } - else if (ras == 9) { temp = int1 ^ 0xB00000; } - else if (ras == 10) { temp = int1 ^ 0xA80000; } - else if (ras == 11) { temp = int1 ^ 0xA00000; } - else if (ras == 12) { temp = int1 ^ 0x980000; } - else if (ras == 13) { temp = int1 ^ 0x900000; } - else if (ras == 14) { temp = int1 ^ 0x880000; } - else if (ras == 15) { temp = int1 ^ 0x800000; } - // else { temp = temp;} - } - else - { - // RAS Active to precharge (tRAS) - int1 = temp | 0xF00000; // bits 23:20 - if (ras == 4) { temp = int1 ^ 0xB00000; } - else if (ras == 5) { temp = int1 ^ 0xA00000; } - else if (ras == 6) { temp = int1 ^ 0x900000; } - else if (ras == 7) { temp = int1 ^ 0x800000; } - else if (ras == 8) { temp = int1 ^ 0x700000; } - else if (ras == 9) { temp = int1 ^ 0x600000; } - else if (ras == 10) { temp = int1 ^ 0x500000; } - else if (ras == 11) { temp = int1 ^ 0x400000; } - else if (ras == 12) { temp = int1 ^ 0x300000; } - else if (ras == 13) { temp = int1 ^ 0x200000; } - else if (ras == 14) { temp = int1 ^ 0x100000; } - else if (ras == 15) { temp = int1 ^ 0x000000; } - // else { temp = temp;} - } - - // CAS Latency (tCAS) - int1 = temp | 0x0300; - if (cas == 1) { temp = int1 ^ 0x200; } // cas 2.5 - else if (cas == 2) { temp = int1 ^ 0x100; } - else if (cas == 3) { temp = int1 ^ 0x300; } - // else { temp = temp;} - - *ptr = temp; - __delay(500); - return; -} - -void change_timing_Lakeport(int cas, int rcd, int rp, int ras) -{ - ulong int1, dev0, temp; - long *ptr; - - //read MMRBAR - pci_conf_read( 0, 0, 0, 0x44, 4, &dev0); - dev0 &= 0xFFFFC000; - - ptr=(long*)(dev0+0x114); - temp = *ptr; - - // RAS-To-CAS (tRCD) - int1 = temp | 0x70; - if (rcd == 2) { temp = int1 ^ 0x70; } - else if (rcd == 3) { temp = int1 ^ 0x60; } - else if (rcd == 4) { temp = int1 ^ 0x50; } - else if (rcd == 5) { temp = int1 ^ 0x40; } - // else { temp = temp;} - - //RAS precharge (tRP) - int1 = temp | 0x7; - if (rp == 2) { temp = int1 ^ 0x7; } - else if (rp == 3) { temp = int1 ^ 0x6; } - else if (rp == 4) { temp = int1 ^ 0x5; } - else if (rp == 5) { temp = int1 ^ 0x4; } - // else { temp = temp;} - - - // CAS Latency (tCAS) - int1 = temp | 0x0300; - if (cas == 1) { temp = int1 ^ 0x200; } // cas 2.5 - else if (cas == 2) { temp = int1 ^ 0x100; } - else if (cas == 3) { temp = int1 ^ 0x300; } - // else { temp = temp;} - - *ptr = temp; - __delay(500); - return; -} - -void change_timing_i875(int cas, int rcd, int rp, int ras){ - - ulong int1, dev6, temp; - long *ptr; - - /* Read the MMR Base Address & Define the pointer from the BAR6 overflow register */ - pci_conf_read( 0, 6, 0, 0x10, 4, &dev6); - - ptr=(long*)(dev6+0x60); - - temp = *ptr; - - // RAS-To-CAS (tRCD) - int1 = temp | 0xC; - if (rcd == 2) { temp = int1 ^ 0x4; } - else if (rcd == 3) { temp = int1 ^ 0x8; } - else if (rcd == 4) { temp = int1 ^ 0xC; } - else if (rcd == 5) { temp = int1 ^ 0xC; } - // else { temp = temp;} - - - //RAS precharge (tRP) - int1 = temp | 0x3; - if (rp == 2) { temp = int1 ^ 0x1; } - else if (rp == 3) { temp = int1 ^ 0x2; } - else if (rp == 4) { temp = int1 ^ 0x3; } - else if (rp == 5) { temp = int1 ^ 0x3; } - // else { temp = temp;} - - - // RAS Active to precharge (tRAS) - int1 = temp | 0x380; - if (ras == 5) { temp = int1 ^ 0x100; } - else if (ras == 6) { temp = int1 ^ 0x180; } - else if (ras == 7) { temp = int1 ^ 0x200; } - else if (ras == 8) { temp = int1 ^ 0x280; } - else if (ras == 9) { temp = int1 ^ 0x300; } - else if (ras == 10) { temp = int1 ^ 0x380; } - // else { temp = temp;} - - // CAS Latency (tCAS) - int1 = temp | 0x60; - if (cas == 1) { temp = int1 ^ 0x60; } // cas 2.5 - else if (cas == 2) { temp = int1 ^ 0x40; } - else if (cas == 3) { temp = int1 ^ 0x20; } - // else { temp = temp; } - - *ptr = temp; - __delay(500); - return; -} - - -void change_timing_nf2(int cas, int rcd, int rp, int ras) { - - ulong dramtlr, dramtlr2; - ulong int1, int2; - - pci_conf_read(0, 0, 1, 0x90, 4, &dramtlr); - pci_conf_read(0, 0, 1, 0xA0, 4, &dramtlr2); - - - // CAS Latency (tCAS) - int1 = dramtlr2 | 0x0070; - if (cas == 1) { int2 = int1 ^ 0x10; } // cas = 2.5 - else if (cas == 2) { int2 = int1 ^ 0x50; } - else if (cas == 3) { int2 = int1 ^ 0x40; } - else { int2 = dramtlr2; } - - pci_conf_write(0, 0, 1, 0xA0, 4, int2); - - // RAS-To-CAS (tRCD) - - int1 = dramtlr | 0x700000; - if (rcd == 2) { int2 = int1 ^ 0x500000; } - else if (rcd == 3) { int2 = int1 ^ 0x400000; } - else if (rcd == 4) { int2 = int1 ^ 0x300000; } - else if (rcd == 5) { int2 = int1 ^ 0x200000; } - else if (rcd == 6) { int2 = int1 ^ 0x100000; } - else { int2 = dramtlr;} - - - // RAS Precharge (tRP) - int1 = int2 | 0x70000000; - if (rp == 2) { int2 = int1 ^ 0x50000000; } - else if (rp == 3) { int2 = int1 ^ 0x40000000; } - else if (rp == 4) { int2 = int1 ^ 0x30000000; } - else if (rp == 5) { int2 = int1 ^ 0x20000000; } - else if (rp == 6) { int2 = int1 ^ 0x10000000; } - // else { int2 = int2;} - - - // RAS Active to precharge (tRAS) - - int1 = int2 | 0x78000; - if (ras == 4) { int2 = int1 ^ 0x58000; } - else if (ras == 5) { int2 = int1 ^ 0x50000; } - else if (ras == 6) { int2 = int1 ^ 0x48000; } - else if (ras == 7) { int2 = int1 ^ 0x40000; } - else if (ras == 8) { int2 = int1 ^ 0x38000; } - else if (ras == 9) { int2 = int1 ^ 0x30000; } - else if (ras == 10) { int2 = int1 ^ 0x28000; } - else if (ras == 11) { int2 = int1 ^ 0x20000; } - else if (ras == 12) { int2 = int1 ^ 0x18000; } - else if (ras == 13) { int2 = int1 ^ 0x10000; } - else if (ras == 14) { int2 = int1 ^ 0x08000; } - // else { int2 = int2;} - - - pci_conf_write(0, 0, 1, 0x90, 4, int2); - __delay(500); -} - - -void change_timing_amd64(int cas, int rcd, int rp, int ras) { - - ulong dramtlr; - ulong int1= 0x0; - - pci_conf_read(0, 24, 2, 0x88, 4, &dramtlr); - - // RAS-To-CAS (tRCD) - int1 = dramtlr | 0x7000; - if (rcd == 2) { dramtlr = int1 ^ 0x5000; } - else if (rcd == 3) { dramtlr = int1 ^ 0x4000; } - else if (rcd == 4) { dramtlr = int1 ^ 0x3000; } - else if (rcd == 5) { dramtlr = int1 ^ 0x2000; } - else if (rcd == 6) { dramtlr = int1 ^ 0x1000; } - else if (rcd == 1) { dramtlr = int1 ^ 0x6000; } - // else { dramtlr = dramtlr;} - - - //RAS precharge (tRP) - int1 = dramtlr | 0x7000000; - if (rp == 2) { dramtlr = int1 ^ 0x5000000; } - else if (rp == 3) { dramtlr = int1 ^ 0x4000000; } - else if (rp == 1) { dramtlr = int1 ^ 0x6000000; } - else if (rp == 4) { dramtlr = int1 ^ 0x3000000; } - else if (rp == 5) { dramtlr = int1 ^ 0x2000000; } - else if (rp == 6) { dramtlr = int1 ^ 0x1000000; } - // else { dramtlr = dramtlr;} - - - // RAS Active to precharge (tRAS) - int1 = dramtlr | 0xF00000; - if (ras == 5) { dramtlr = int1 ^ 0xA00000; } - else if (ras == 6) { dramtlr = int1 ^ 0x900000; } - else if (ras == 7) { dramtlr = int1 ^ 0x800000; } - else if (ras == 8) { dramtlr = int1 ^ 0x700000; } - else if (ras == 9) { dramtlr = int1 ^ 0x600000; } - else if (ras == 10) { dramtlr = int1 ^ 0x500000; } - else if (ras == 11) { dramtlr = int1 ^ 0x400000; } - else if (ras == 12) { dramtlr = int1 ^ 0x300000; } - else if (ras == 13) { dramtlr = int1 ^ 0x200000; } - else if (ras == 14) { dramtlr = int1 ^ 0x100000; } - // else { dramtlr = dramtlr;} - - - // CAS Latency (tCAS) - int1 = dramtlr | 0x7; // some changes will cause the system hang, tried Draminit to no avail - if (cas == 1) { dramtlr = int1 ^ 0x2; } // cas 2.5 - else if (cas == 2) { dramtlr = int1 ^ 0x6; } - else if (cas == 3) { dramtlr = int1 ^ 0x5; } - else if (cas == 4) { dramtlr = int1 ^ 0x7; } //cas 1.5 on a64 - // else { dramtlr = dramtlr; } - -// pci_conf_read(0, 24, 2, 0x90, 4, &dramcr);// use dram init - pci_conf_write(0, 24, 2, 0x88, 4, dramtlr); - __delay(500); - -//////////////////////////////////////////////////////////////// -// trying using the draminit, but do not work -} - -// copy from lib.c code to add delay to chipset timing modification -void __delay(ulong loops) -{ - int d0; - __asm__ __volatile__( - "\tjmp 1f\n" - ".align 16\n" - "1:\tjmp 2f\n" - ".align 16\n" - "2:\tdecl %0\n\tjns 2b" - :"=&a" (d0) - :"0" (loops)); -} - -void amd64_tweak(int rwt, int wrt, int ref, int en2t, int rct, int rrd, int rwqb, int wr) -{ - ulong dramtlr; - ulong int1= 0x0; - - pci_conf_read(0, 24, 2, 0x88, 4, &dramtlr); - - // Row Cycle time - int1 = dramtlr | 0xF0; - if (rct == 7 ) { dramtlr = int1 ^ 0xF0; } - else if (rct == 8 ) { dramtlr = int1 ^ 0xE0; } - else if (rct == 9 ) { dramtlr = int1 ^ 0xD0; } - else if (rct == 10) { dramtlr = int1 ^ 0xC0; } - else if (rct == 11) { dramtlr = int1 ^ 0xB0; } - else if (rct == 12) { dramtlr = int1 ^ 0xA0; } - else if (rct == 13) { dramtlr = int1 ^ 0x90; } - else if (rct == 14) { dramtlr = int1 ^ 0x80; } - else if (rct == 15) { dramtlr = int1 ^ 0x70; } - else if (rct == 16) { dramtlr = int1 ^ 0x60; } - else if (rct == 17) { dramtlr = int1 ^ 0x50; } - else if (rct == 18) { dramtlr = int1 ^ 0x40; } - else if (rct == 19) { dramtlr = int1 ^ 0x30; } - else if (rct == 20) { dramtlr = int1 ^ 0x20; } - // else { dramtlr = dramtlr;} - - //Active-avtive ras-ras delay - int1 = dramtlr | 0x70000; - if (rrd == 2) { dramtlr = int1 ^ 0x50000; } // 2 bus clocks - else if (rrd == 3) { dramtlr = int1 ^ 0x40000; } // 3 bus clocks - else if (rrd == 4) { dramtlr = int1 ^ 0x30000; } // 4 bus clocks - // else { dramtlr = dramtlr;} - - //Write recovery time - int1 = dramtlr | 0x10000000; - if (wr == 2) { dramtlr = int1 ^ 0x10000000; } // 2 bus clocks - else if (wr == 3) { dramtlr = int1 ^ 0x00000000; } // 3 bus clocks - // else { dramtlr = dramtlr;} - - pci_conf_write(0, 24, 2, 0x88, 4, dramtlr); - __delay(500); - ////////////////////////////////////////////// - - pci_conf_read(0, 24, 2, 0x8C, 4, &dramtlr); - - // Write-to read delay - int1 = dramtlr | 0x1; - if (wrt == 2) { dramtlr = int1 ^ 0x0; } - else if (wrt == 1) { dramtlr = int1 ^ 0x1; } - // else { dramtlr = dramtlr;} - - // Read-to Write delay - int1 = dramtlr | 0x70; - if (rwt == 1) { dramtlr = int1 ^ 0x70; } - else if (rwt == 2) { dramtlr = int1 ^ 0x60; } - else if (rwt == 3) { dramtlr = int1 ^ 0x50; } - else if (rwt == 4) { dramtlr = int1 ^ 0x40; } - else if (rwt == 5) { dramtlr = int1 ^ 0x30; } - else if (rwt == 6) { dramtlr = int1 ^ 0x20; } - // else { dramtlr = dramtlr;} - - //Refresh Rate - int1 = dramtlr | 0x1800; - if (ref == 1) { dramtlr = int1 ^ 0x1800; } // 15.6us - else if (ref == 2) { dramtlr = int1 ^ 0x1000; } // 7.8us - else if (ref == 3) { dramtlr = int1 ^ 0x0800; } // 3.9us - // else { dramtlr = dramtlr;} - - pci_conf_write(0, 24, 2, 0x8c, 4, dramtlr); - __delay(500); - ///////////////////////////////////// - - pci_conf_read(0, 24, 2, 0x90, 4, &dramtlr); - - // Enable 2t command - int1 = dramtlr | 0x10000000; - if (en2t == 2) { dramtlr = int1 ^ 0x00000000; } // 2T - else if (en2t == 1) { dramtlr = int1 ^ 0x10000000; } // 1T - // else { dramtlr = dramtlr;} - - // Read Write queue bypass count - int1 = dramtlr | 0xC000; - if (rwqb == 2) { dramtlr = int1 ^ 0xC000; } - else if (rwqb == 4) { dramtlr = int1 ^ 0x8000; } - else if (rwqb == 8) { dramtlr = int1 ^ 0x4000; } - else if (rwqb == 16) { dramtlr = int1 ^ 0x0000; } - // else { dramtlr = dramtlr;} - - pci_conf_write(0, 24, 2, 0x90, 4, dramtlr); - __delay(500); - restart(); -} - diff --git a/memtest86+_old/extra.h b/memtest86+_old/extra.h deleted file mode 100644 index 9bd7045..0000000 --- a/memtest86+_old/extra.h +++ /dev/null @@ -1,27 +0,0 @@ -// This is the extra stuff added to the memtest+ from memtest.org -// Code from Eric Nelson and Wee -/* extra.c - * - * Released under version 2 of the Gnu Public License. - * - */ - -#ifndef MEMTEST_EXTRA_H -#define MEMTEST_EXTRA_H - -void change_timing(int cas, int rcd, int rp, int ras); -void find_memctr(void); -void disclaimer(void); -void get_option(void); -void get_menu(void); -void a64_parameter(void); -int get_cas(void); -void change_timing_i852(int cas, int rcd, int rp, int ras); -void change_timing_i925(int cas, int rcd, int rp, int ras); -void change_timing_i875(int cas, int rcd, int rp, int ras); -void change_timing_nf2(int cas, int rcd, int rp, int ras); -void change_timing_amd64(int cas, int rcd, int rp, int ras); -void amd64_tweak(int rwt, int wrt, int ref, int en2t, int rct, int rrd, int rwqb, int wr); -void __delay(ulong loops); - -#endif /* MEMTEST_EXTRA_H */ diff --git a/memtest86+_old/head.S b/memtest86+_old/head.S deleted file mode 100644 index d551336..0000000 --- a/memtest86+_old/head.S +++ /dev/null @@ -1,847 +0,0 @@ -/* - * linux/boot/head.S - * Copyright (C) 1991, 1992 Linus Torvalds - */ - -/* - * head.S contains the 32-bit startup code. - * - * 1-Jan-96 Modified by Chris Brady for use as a boot/loader for MemTest-86. - * Setup the memory management for flat non-paged linear addressing. - * 17 May 2004 : Added X86_PWRCAP for AMD64 (Memtest86+ - Samuel D.) - */ - -.text -#define __ASSEMBLY__ -#include "defs.h" -#include "config.h" -#include "test.h" - - .code32 - .globl startup_32 -startup_32: - cld - cli - - /* Ensure I have a boot_stack pointer */ - testl %esp, %esp - jnz 0f - movl $(LOW_TEST_ADR + _GLOBAL_OFFSET_TABLE_), %esp - leal boot_stack_top@GOTOFF(%esp), %esp -0: - - /* Load the GOT pointer */ - call 0f -0: popl %ebx - addl $_GLOBAL_OFFSET_TABLE_+[.-0b], %ebx - - /* Pick the appropriate boot_stack address */ - leal boot_stack_top@GOTOFF(%ebx), %esp - - /* Reload all of the segment registers */ - leal gdt@GOTOFF(%ebx), %eax - movl %eax, 2 + gdt_descr@GOTOFF(%ebx) - lgdt gdt_descr@GOTOFF(%ebx) - leal flush@GOTOFF(%ebx), %eax - pushl $KERNEL_CS - pushl %eax - lret -flush: movl $KERNEL_DS, %eax - movw %ax, %ds - movw %ax, %es - movw %ax, %fs - movw %ax, %gs - movw %ax, %ss - -/* - * Zero BSS - */ - cmpl $1, zerobss@GOTOFF(%ebx) - jnz zerobss_done - xorl %eax, %eax - leal _bss@GOTOFF(%ebx), %edi - leal _end@GOTOFF(%ebx), %ecx - subl %edi, %ecx -1: movl %eax, (%edi) - addl $4, %edi - subl $4, %ecx - jnz 1b - movl $0, zerobss@GOTOFF(%ebx) -zerobss_done: - -/* - * Setup an exception handler - */ - leal idt@GOTOFF(%ebx), %edi - - leal vec0@GOTOFF(%ebx), %edx - movl $(KERNEL_CS << 16),%eax - movw %dx, %ax /* selector = 0x0010 = cs */ - movw $0x8E00, %dx /* interrupt gate - dpl=0, present */ - movl %eax, (%edi) - movl %edx, 4(%edi) - addl $8, %edi - - leal vec1@GOTOFF(%ebx),%edx - movl $(KERNEL_CS << 16),%eax - movw %dx,%ax /* selector = 0x0010 = cs */ - movw $0x8E00,%dx /* interrupt gate - dpl=0, present */ - movl %eax,(%edi) - movl %edx,4(%edi) - addl $8,%edi - - leal vec2@GOTOFF(%ebx),%edx - movl $(KERNEL_CS << 16),%eax - movw %dx,%ax /* selector = 0x0010 = cs */ - movw $0x8E00,%dx /* interrupt gate - dpl=0, present */ - movl %eax,(%edi) - movl %edx,4(%edi) - addl $8,%edi - - leal vec3@GOTOFF(%ebx),%edx - movl $(KERNEL_CS << 16),%eax - movw %dx,%ax /* selector = 0x0010 = cs */ - movw $0x8E00,%dx /* interrupt gate - dpl=0, present */ - movl %eax,(%edi) - movl %edx,4(%edi) - addl $8,%edi - - leal vec4@GOTOFF(%ebx),%edx - movl $(KERNEL_CS << 16),%eax - movw %dx,%ax /* selector = 0x0010 = cs */ - movw $0x8E00,%dx /* interrupt gate - dpl=0, present */ - movl %eax,(%edi) - movl %edx,4(%edi) - addl $8,%edi - - leal vec5@GOTOFF(%ebx),%edx - movl $(KERNEL_CS << 16),%eax - movw %dx,%ax /* selector = 0x0010 = cs */ - movw $0x8E00,%dx /* interrupt gate - dpl=0, present */ - movl %eax,(%edi) - movl %edx,4(%edi) - addl $8,%edi - - leal vec6@GOTOFF(%ebx),%edx - movl $(KERNEL_CS << 16),%eax - movw %dx,%ax /* selector = 0x0010 = cs */ - movw $0x8E00,%dx /* interrupt gate - dpl=0, present */ - movl %eax,(%edi) - movl %edx,4(%edi) - addl $8,%edi - - leal vec7@GOTOFF(%ebx),%edx - movl $(KERNEL_CS << 16),%eax - movw %dx,%ax /* selector = 0x0010 = cs */ - movw $0x8E00,%dx /* interrupt gate - dpl=0, present */ - movl %eax,(%edi) - movl %edx,4(%edi) - addl $8,%edi - - leal vec8@GOTOFF(%ebx),%edx - movl $(KERNEL_CS << 16),%eax - movw %dx,%ax /* selector = 0x0010 = cs */ - movw $0x8E00,%dx /* interrupt gate - dpl=0, present */ - movl %eax,(%edi) - movl %edx,4(%edi) - addl $8,%edi - - leal vec9@GOTOFF(%ebx),%edx - movl $(KERNEL_CS << 16),%eax - movw %dx,%ax /* selector = 0x0010 = cs */ - movw $0x8E00,%dx /* interrupt gate - dpl=0, present */ - movl %eax,(%edi) - movl %edx,4(%edi) - addl $8,%edi - - leal vec10@GOTOFF(%ebx),%edx - movl $(KERNEL_CS << 16),%eax - movw %dx,%ax /* selector = 0x0010 = cs */ - movw $0x8E00,%dx /* interrupt gate - dpl=0, present */ - movl %eax,(%edi) - movl %edx,4(%edi) - addl $8,%edi - - leal vec11@GOTOFF(%ebx),%edx - movl $(KERNEL_CS << 16),%eax - movw %dx,%ax /* selector = 0x0010 = cs */ - movw $0x8E00,%dx /* interrupt gate - dpl=0, present */ - movl %eax,(%edi) - movl %edx,4(%edi) - addl $8,%edi - - leal vec12@GOTOFF(%ebx),%edx - movl $(KERNEL_CS << 16),%eax - movw %dx,%ax /* selector = 0x0010 = cs */ - movw $0x8E00,%dx /* interrupt gate - dpl=0, present */ - movl %eax,(%edi) - movl %edx,4(%edi) - addl $8,%edi - - leal vec13@GOTOFF(%ebx),%edx - movl $(KERNEL_CS << 16),%eax - movw %dx,%ax /* selector = 0x0010 = cs */ - movw $0x8E00,%dx /* interrupt gate - dpl=0, present */ - movl %eax,(%edi) - movl %edx,4(%edi) - addl $8,%edi - - leal vec14@GOTOFF(%ebx),%edx - movl $(KERNEL_CS << 16),%eax - movw %dx,%ax /* selector = 0x0010 = cs */ - movw $0x8E00,%dx /* interrupt gate - dpl=0, present */ - movl %eax,(%edi) - movl %edx,4(%edi) - addl $8,%edi - - leal vec15@GOTOFF(%ebx),%edx - movl $(KERNEL_CS << 16),%eax - movw %dx,%ax /* selector = 0x0010 = cs */ - movw $0x8E00,%dx /* interrupt gate - dpl=0, present */ - movl %eax,(%edi) - movl %edx,4(%edi) - addl $8,%edi - - leal vec16@GOTOFF(%ebx),%edx - movl $(KERNEL_CS << 16),%eax - movw %dx,%ax /* selector = 0x0010 = cs */ - movw $0x8E00,%dx /* interrupt gate - dpl=0, present */ - movl %eax,(%edi) - movl %edx,4(%edi) - addl $8,%edi - - leal vec17@GOTOFF(%ebx),%edx - movl $(KERNEL_CS << 16),%eax - movw %dx,%ax /* selector = 0x0010 = cs */ - movw $0x8E00,%dx /* interrupt gate - dpl=0, present */ - movl %eax,(%edi) - movl %edx,4(%edi) - addl $8,%edi - - leal vec18@GOTOFF(%ebx),%edx - movl $(KERNEL_CS << 16),%eax - movw %dx,%ax /* selector = 0x0010 = cs */ - movw $0x8E00,%dx /* interrupt gate - dpl=0, present */ - movl %eax,(%edi) - movl %edx,4(%edi) - addl $8,%edi - - leal vec19@GOTOFF(%ebx),%edx - movl $(KERNEL_CS << 16),%eax - movw %dx,%ax /* selector = 0x0010 = cs */ - movw $0x8E00,%dx /* interrupt gate - dpl=0, present */ - movl %eax,(%edi) - movl %edx,4(%edi) - addl $8,%edi - - /* Now that it is initialized load the interrupt descriptor table */ - leal idt@GOTOFF(%ebx), %eax - movl %eax, 2 + idt_descr@GOTOFF(%ebx) - lidt idt_descr@GOTOFF(%ebx) - - leal _dl_start@GOTOFF(%ebx), %eax - call *%eax - - /* Never forget to initialize the FPU ... Never ! */ - finit - - call test_start - - /* In case we return simulate an exception */ - pushfl - pushl %cs - call 0f -0: pushl $0 /* error code */ - pushl $257 /* vector */ - jmp int_hand - -vec0: - pushl $0 /* error code */ - pushl $0 /* vector */ - jmp int_hand -vec1: - pushl $0 /* error code */ - pushl $1 /* vector */ - jmp int_hand - -vec2: - pushl $0 /* error code */ - pushl $2 /* vector */ - jmp int_hand - -vec3: - pushl $0 /* error code */ - pushl $3 /* vector */ - jmp int_hand - -vec4: - pushl $0 /* error code */ - pushl $4 /* vector */ - jmp int_hand - -vec5: - pushl $0 /* error code */ - pushl $5 /* vector */ - jmp int_hand - -vec6: - pushl $0 /* error code */ - pushl $6 /* vector */ - jmp int_hand - -vec7: - pushl $0 /* error code */ - pushl $7 /* vector */ - jmp int_hand - -vec8: - /* error code */ - pushl $8 /* vector */ - jmp int_hand - -vec9: - pushl $0 /* error code */ - pushl $9 /* vector */ - jmp int_hand - -vec10: - /* error code */ - pushl $10 /* vector */ - jmp int_hand - -vec11: - /* error code */ - pushl $11 /* vector */ - jmp int_hand - -vec12: - /* error code */ - pushl $12 /* vector */ - jmp int_hand - -vec13: - /* error code */ - pushl $13 /* vector */ - jmp int_hand - -vec14: - /* error code */ - pushl $14 /* vector */ - jmp int_hand - -vec15: - pushl $0 /* error code */ - pushl $15 /* vector */ - jmp int_hand - -vec16: - pushl $0 /* error code */ - pushl $16 /* vector */ - jmp int_hand - -vec17: - /* error code */ - pushl $17 /* vector */ - jmp int_hand - -vec18: - pushl $0 /* error code */ - pushl $18 /* vector */ - jmp int_hand - -vec19: - pushl $0 /* error code */ - pushl $19 /* vector */ - jmp int_hand - -int_hand: - pushl %eax - pushl %ebx - pushl %ecx - pushl %edx - pushl %edi - pushl %esi - pushl %ebp - - /* original boot_stack pointer */ - leal 48(%esp), %eax - pushl %eax - pushl %ds - pushl %ss - pushl %esp /* pointer to trap regs struct on the boot_stack */ - call inter - addl $8, %esp - - popl %ebp - popl %esi - popl %edi - popl %edx - popl %ecx - popl %ebx - popl %eax - iret - -/* - * The interrupt descriptor table has room for 32 idt's - */ -.align 4 -.word 0 -idt_descr: - .word 20*8-1 # idt contains 32 entries - .long 0 - -idt: - .fill 20,8,0 # idt is uninitialized - -gdt_descr: - .word gdt_end - gdt - 1 - .long 0 - -.align 4 -.globl gdt, gdt_end -gdt: - .quad 0x0000000000000000 /* NULL descriptor */ - .quad 0x0000000000000000 /* not used */ - .quad 0x00cf9b000000ffff /* 0x10 main 4gb code at 0x000000 */ - .quad 0x00cf93000000ffff /* 0x18 main 4gb data at 0x000000 */ - - .word 0xFFFF # 16bit 64KB - (0x10000*1 = 64KB) - .word 0 # base address = SETUPSEG - .byte 0x00, 0x9b # code read/exec/accessed - .byte 0x00, 0x00 # granularity = bytes - - - .word 0xFFFF # 16bit 64KB - (0x10000*1 = 64KB) - .word 0 # base address = SETUPSEG - .byte 0x00, 0x93 # data read/write/accessed - .byte 0x00, 0x00 # granularity = bytes - -gdt_end: - -.data - -.macro ptes64 start, count=64 -.quad \start + 0x0000000 + 0xE3 -.quad \start + 0x0200000 + 0xE3 -.quad \start + 0x0400000 + 0xE3 -.quad \start + 0x0600000 + 0xE3 -.quad \start + 0x0800000 + 0xE3 -.quad \start + 0x0A00000 + 0xE3 -.quad \start + 0x0C00000 + 0xE3 -.quad \start + 0x0E00000 + 0xE3 -.if \count-1 -ptes64 "(\start+0x01000000)",\count-1 -.endif -.endm - -.macro maxdepth depth=1 -.if \depth-1 -maxdepth \depth-1 -.endif -.endm - -maxdepth - -# Page Directory Tables: -# There are 4 tables, the first two map the first 2 GB of memory. The last two are used with # PAE to map -# the rest of memory in 2 GB segments. The last two tables are changed in vmem.c to map each segment. -# We use 2 MB pages so only the Page Directory Table is used (no page tables). -.balign 4096 -.globl pd0 -pd0: - ptes64 0x0000000000000000 - -.balign 4096 -.globl pd1 -pd1: - ptes64 0x0000000040000000 - -.balign 4096 -.globl pd2 -pd2: - ptes64 0x0000000080000000 - -.balign 4096 -.globl pd3 -pd3: - ptes64 0x00000000C0000000 - -# Legacy Mode Page Directory Pointer Table: -# 4 Entries, pointing to the Page Directory Tables -.balign 4096 -.globl pdp -pdp: - .long pd0 + 1 - .long 0 - .long pd1 + 1 - .long 0 - .long pd2 + 1 - .long 0 - .long pd3 + 1 - .long 0 - -# Long Mode Page Directory Pointer Table: -# 4 Entries, pointing to the Page Directory Tables -.balign 4096 -lpdp: - .long pd0 + 3 - .long 0 - .long pd1 + 3 - .long 0 - .long pd2 + 3 - .long 0 - .long pd3 + 3 - .long 0 - - -# The long mode level 4 page map table -.balign 4096 -.globl pml4 -pml4: - .long lpdp + 3 - .long 0 -.previous - -#define RSTART startup_32 - - .globl query_pcbios -query_pcbios: - /* Save the caller save registers */ - pushl %ebx - pushl %esi - pushl %edi - pushl %ebp - call 1f -1: popl %ebx - addl $_GLOBAL_OFFSET_TABLE_+[.-1b], %ebx - - /* Compute the reloc address */ - leal RSTART@GOTOFF(%ebx), %esi - - /* Fixup real code pointer */ - movl %esi, %eax - shrl $4, %eax - movw %ax, 2 + realptr@GOTOFF(%ebx) - - /* Fixup protected code pointer */ - leal prot@GOTOFF(%ebx), %eax - movl %eax, protptr@GOTOFF(%ebx) - - /* Compute the gdt fixup */ - movl %esi, %eax - shll $16, %eax # Base low - - movl %esi, %ecx - shrl $16, %ecx - andl $0xff, %ecx - - movl %esi, %edx - andl $0xff000000, %edx - orl %edx, %ecx - - /* Fixup the gdt */ - andl $0x0000ffff, REAL_CS + 0 + gdt@GOTOFF(%ebx) - orl %eax, REAL_CS + 0 + gdt@GOTOFF(%ebx) - andl $0x00ffff00, REAL_CS + 4 + gdt@GOTOFF(%ebx) - orl %ecx, REAL_CS + 4 + gdt@GOTOFF(%ebx) - andl $0x0000ffff, REAL_DS + 0 + gdt@GOTOFF(%ebx) - orl %eax, REAL_DS + 0 + gdt@GOTOFF(%ebx) - andl $0x00ffff00, REAL_DS + 4 + gdt@GOTOFF(%ebx) - orl %ecx, REAL_DS + 4 + gdt@GOTOFF(%ebx) - - /* Fixup the gdt_descr */ - leal gdt@GOTOFF(%ebx), %eax - movl %eax, 2 + gdt_descr@GOTOFF(%ebx) - - lidt idt_real@GOTOFF(%ebx) - - /* Don't disable the a20 line */ - - /* Load 16bit data segments, to ensure the segment limits are set */ - movl $REAL_DS, %eax - movl %eax, %ds - movl %eax, %es - movl %eax, %ss - movl %eax, %fs - movl %eax, %gs - - /* Compute the boot_stack base */ - leal boot_stack@GOTOFF(%ebx), %ecx - /* Compute the address of meminfo */ - leal mem_info@GOTOFF(%ebx), %edi - - /* switch to 16bit mode */ - ljmp $REAL_CS, $1f - RSTART -1: - .code16 - /* Disable Paging and protected mode */ - /* clear the PG & PE bits of CR0 */ - movl %cr0,%eax - andl $~((1 << 31)|(1<<0)),%eax - movl %eax,%cr0 - - /* make intersegment jmp to flush the processor pipeline - * and reload %cs:%eip (to clear upper 16 bits of %eip). - */ - ljmp *(realptr - RSTART) -real: - /* we are in real mode now - * set up the real mode segment registers : %ds, %ss, %es, %gs, %fs - */ - movw %cs, %ax - movw %ax, %ds - movw %ax, %es - movw %ax, %fs - movw %ax, %gs - movw %ax, %ss - - /* Adjust the boot_stack pointer */ - movl %ecx, %eax - shrl $4, %eax - movw %ax, %ss - subl %ecx, %esp - - /* Save my base pointer */ - pushl %ebx - - /* Setup %ds to point to my data area */ - shrl $4, %edi - movl %edi, %ds - - /* Enable interrupts or BIOS's go crazy */ - sti - -# Get memory size (extended mem, kB) - -#define SMAP 0x534d4150 - - xorl %eax, %eax - movl %eax, (E88) - movl %eax, (E801) - movl %eax, (E820NR) - -# Try three different memory detection schemes. First, try -# e820h, which lets us assemble a memory map, then try e801h, -# which returns a 32-bit memory size, and finally 88h, which -# returns 0-64m - -# method E820H: -# the memory map from hell. e820h returns memory classified into -# a whole bunch of different types, and allows memory holes and -# everything. We scan through this memory map and build a list -# of the first 32 memory areas, which we return at [E820MAP]. -# This is documented at http://www.teleport.com/~acpi/acpihtml/topic245.htm - -meme820: - xorl %ebx, %ebx # continuation counter - movw $E820MAP, %di # point into the whitelist - # so we can have the bios - # directly write into it. - -jmpe820: - movl $0x0000e820, %eax # e820, upper word zeroed - movl $SMAP, %edx # ascii 'SMAP' - movl $20, %ecx # size of the e820rec - pushw %ds # data record. - popw %es - int $0x15 # make the call - jc bail820 # fall to e801 if it fails - - cmpl $SMAP, %eax # check the return is `SMAP' - jne bail820 # fall to e801 if it fails - -# cmpl $1, 16(%di) # is this usable memory? -# jne again820 - - # If this is usable memory, we save it by simply advancing %di by - # sizeof(e820rec). - # -good820: - movb (E820NR), %al # up to 32 entries - cmpb $E820MAX, %al - jnl bail820 - - incb (E820NR) - movw %di, %ax - addw $E820ENTRY_SIZE, %ax - movw %ax, %di -again820: - cmpl $0, %ebx # check to see if - jne jmpe820 # %ebx is set to EOF -bail820: - - -# method E801H: -# memory size is in 1k chunksizes, to avoid confusing loadlin. -# we store the 0xe801 memory size in a completely different place, -# because it will most likely be longer than 16 bits. - -meme801: - stc # fix to work around buggy - xorw %cx,%cx # BIOSes which dont clear/set - xorw %dx,%dx # carry on pass/error of - # e801h memory size call - # or merely pass cx,dx though - # without changing them. - movw $0xe801, %ax - int $0x15 - jc mem88 - - cmpw $0x0, %cx # Kludge to handle BIOSes - jne e801usecxdx # which report their extended - cmpw $0x0, %dx # memory in AX/BX rather than - jne e801usecxdx # CX/DX. The spec I have read - movw %ax, %cx # seems to indicate AX/BX - movw %bx, %dx # are more reasonable anyway... - -e801usecxdx: - andl $0xffff, %edx # clear sign extend - shll $6, %edx # and go from 64k to 1k chunks - movl %edx, (E801) # store extended memory size - andl $0xffff, %ecx # clear sign extend - addl %ecx, (E801) # and add lower memory into - # total size. - -# Ye Olde Traditional Methode. Returns the memory size (up to 16mb or -# 64mb, depending on the bios) in ax. -mem88: - - movb $0x88, %ah - int $0x15 - movw %ax, (E88) - -#ifdef APM_OFF -# check for APM BIOS - movw $0x5300, %ax # APM BIOS installation check - xorw %bx, %bx - int $0x15 - jc done_apm_bios # error -> no APM BIOS - - cmpw $0x504d, %bx # check for "PM" signature - jne done_apm_bios # no signature -> no APM BIOS - - movw $0x5304, %ax # Disconnect first just in case - xorw %bx, %bx - int $0x15 # ignore return code - - movw $0x5301, %ax # Real Mode connect - xorw %bx, %bx - int $0x15 - jc done_apm_bios # error - - movw $0x5308, %ax # Disable APM - mov $0xffff, %bx - xorw %cx, %cx - int $0x15 - -done_apm_bios: -#endif - - /* O.k. the BIOS query is done switch back to protected mode */ - cli - - /* Restore my saved variables */ - popl %ebx - - /* Get an convinient %ds */ - movw %cs, %ax - movw %ax, %ds - - /* Load the global descriptor table */ - addr32 lgdt gdt_descr - RSTART - - /* Turn on protected mode */ - /* Set the PE bit in CR0 */ - movl %cr0,%eax - orl $(1<<0),%eax - movl %eax,%cr0 - - /* flush the prefetch queue, and relaod %cs:%eip */ - data32 ljmp *(protptr - RSTART) -prot: - .code32 - /* Reload other segment registers */ - movl $KERNEL_DS, %eax - movl %eax, %ds - movl %eax, %es - movl %eax, %fs - movl %eax, %gs - movl %eax, %ss - - /* Adjust the boot_stack pointer */ - leal boot_stack@GOTOFF(%ebx), %eax - addl %eax, %esp - - /* Restore the caller saved registers */ - popl %ebp - popl %edi - popl %esi - popl %ebx - movl $1, %eax - ret - -realptr: - .word real - RSTART - .word 0x0000 -protptr: - .long 0 - .long KERNEL_CS - -idt_real: - .word 0x400 - 1 # idt limit ( 256 entries) - .word 0, 0 # idt base = 0L - -/* _ap_trampoline_start is the entry point for cpus other than the - * bootstrap cpu. The code between _ap_trampoline_start to - * _ap_trampoline_protmode is copied to BootCodeStart(0x9000). - * The ljmp after turning on CR0.PE will jump to the - * relocatable code which usually resides at 0x10000 + _ap_trampoline_protmode. - * - * The trampoline code uses a temporary GDT. The entries of this temporary - * GDT must match the first few entries of the GDT used by the relocatble - * memtest code(see 'gdt' sybmol in this file). - * - */ - .globl _ap_trampoline_start - .globl _ap_trampoline_protmode - .code16 -_ap_trampoline_start: - lgdt 0x0 /* will be fixed up later, see smp.c:BootAP()*/ - movl %cr0, %eax - orl $1, %eax - movl %eax, %cr0 - data32 ljmp $KERNEL_CS, $_ap_trampoline_protmode -_ap_trampoline_protmode: - .code32 - movw $KERNEL_DS, %ax - movw %ax, %ds - movw %ax, %es - movw %ax, %fs - movw %ax, %gs - movw %ax, %ss - movl $(LOW_TEST_ADR + _GLOBAL_OFFSET_TABLE_), %esp - leal boot_stack_top@GOTOFF(%esp), %esp - pushl $0 - popf - call startup_32 - /* if we ever return, we'll just loop forever */ - cli -2: hlt - jmp 2b -.data -zerobss: .long 1 -.previous -.data -.balign 16 - .globl mem_info -mem_info: - . = . + MEMINFO_SIZE -.previous -.bss -.balign 16 -boot_stack: - .globl boot_stack - . = . + 4096 -boot_stack_top: - .globl boot_stack_top -.previous diff --git a/memtest86+_old/init.c b/memtest86+_old/init.c deleted file mode 100644 index 32bff7f..0000000 --- a/memtest86+_old/init.c +++ /dev/null @@ -1,1296 +0,0 @@ -/* - * MemTest86+ V5 Specific code (GPL V2.0) - * By Samuel DEMEULEMEESTER, sdemeule@memtest.org - * http://www.canardpc.com - http://www.memtest.org - * ------------------------------------------------ - * init.c - MemTest-86 Version 3.6 - * - * Released under version 2 of the Gnu Public License. - * By Chris Brady - */ - - -#include "stdin.h" -#include "stddef.h" -#include "test.h" -#include "defs.h" -#include "config.h" -#include "cpuid.h" -#include "smp.h" -#include "io.h" -#include "spd.h" -#include "pci.h" -#include "controller.h" - -extern struct tseq tseq[]; -extern short memsz_mode; -extern int num_cpus; -extern int act_cpus; -extern int found_cpus; -unsigned long imc_type = 0; -extern int maxcpus; -extern char cpu_mask[]; -extern void initialise_cpus(); - -/* Here we store all of the cpuid data */ -extern struct cpu_ident cpu_id; - -int l1_cache=0, l2_cache=0, l3_cache=0; -int tsc_invariable = 0; -ulong extclock; - -ulong memspeed(ulong src, ulong len, int iter); -static void cpu_type(void); -static int cpuspeed(void); -static void get_cache_size(); -static void cpu_cache_speed(); -void get_cpuid(); -int beepmode; -extern short dmi_initialized; -extern int dmi_err_cnts[MAX_DMI_MEMDEVS]; - -/* Failsafe function */ -/* msec: number of ms to wait - scs: scancode expected to stop */ -/* bits: 0 = extended detection - 1: SMP - 2: Temp Check */ -/* 3: MP SMP - 4-7: RSVD */ -void failsafe(int msec, int scs) -{ - int i; - ulong sh, sl, l, h, t; - unsigned char c; - volatile char *pp; - - for(i=0, pp=(char *)(SCREEN_ADR+(18*160)+(18*2)+1); i<40; i++, pp+=2) { - *pp = 0x1E; - } - for(i=0, pp=(char *)(SCREEN_ADR+(18*160)+(18*2)+1); i<3; i++, pp+=2) { - *pp = 0x9E; - } - for(i=0, pp=(char *)(SCREEN_ADR+(18*160)+(55*2)+1); i<3; i++, pp+=2) { - *pp = 0x9E; - } - - cprint(18, 18, "==> Press F1 to enter Fail-Safe Mode <=="); - - if(vv->fail_safe & 2) - { - cprint(19, 15, "==> Press F2 to force Multi-Threading (SMP) <=="); - } - - /* save the starting time */ - asm __volatile__ - ("rdtsc":"=a" (sl),"=d" (sh)); - - /* loop for n seconds */ - while (1) { - asm __volatile__( - "rdtsc":"=a" (l),"=d" (h)); - asm __volatile__ ( - "subl %2,%0\n\t" - "sbbl %3,%1" - :"=a" (l), "=d" (h) - :"g" (sl), "g" (sh), - "0" (l), "1" (h)); - - t = h * ((unsigned)0xffffffff / vv->clks_msec); - t += (l / vv->clks_msec); - - /* Is the time up? */ - if (t >= msec) { break; } - - /* Is expected Scan code pressed? */ - c = get_key(); - c &= 0x7f; - - /* F1 */ - if(c == scs) { vv->fail_safe |= 1; break; } - - /* F2 */ - if(c == scs+1) - { - vv->fail_safe ^= 2; - break; - - } - - /* F3 */ - if(c == scs+2) - { - if(vv->fail_safe & 2) { vv->fail_safe ^= 2; } - vv->fail_safe |= 8; - break; - } - } - - cprint(18, 18, " "); - cprint(19, 15, " "); - - for(i=0, pp=(char *)(SCREEN_ADR+(18*160)+(18*2)+1); i<40; i++, pp+=2) { - *pp = 0x17; - } -} - -static void display_init(void) -{ - int i; - volatile char *pp; - - /* Set HW cursor out of screen boundaries */ - __outb(0x0F, 0x03D4); - __outb(0xFF, 0x03D5); - - __outb(0x0E, 0x03D4); - __outb(0xFF, 0x03D5); - - - serial_echo_init(); - serial_echo_print("INE_SCROLL;24r"); /* Set scroll area row 7-23 */ - serial_echo_print(""); /* Clear Screen */ - serial_echo_print(""); - serial_echo_print(""); - serial_echo_print(""); - - /* Clear screen & set background to blue */ - for(i=0, pp=(char *)(SCREEN_ADR); i<80*24; i++) { - *pp++ = ' '; - *pp++ = 0x17; - } - - /* Make the name background green */ - for(i=0, pp=(char *)(SCREEN_ADR+1); itest_pages); - - vv->pass = 0; - vv->msg_line = 0; - vv->ecount = 0; - vv->ecc_ecount = 0; - vv->testsel = -1; - vv->msg_line = LINE_SCROLL-1; - vv->scroll_start = vv->msg_line * 160; - vv->erri.low_addr.page = 0x7fffffff; - vv->erri.low_addr.offset = 0xfff; - vv->erri.high_addr.page = 0; - vv->erri.high_addr.offset = 0; - vv->erri.min_bits = 32; - vv->erri.max_bits = 0; - vv->erri.min_bits = 32; - vv->erri.max_bits = 0; - vv->erri.maxl = 0; - vv->erri.cor_err = 0; - vv->erri.ebits = 0; - vv->erri.hdr_flag = 0; - vv->erri.tbits = 0; - for (i=0; tseq[i].msg != NULL; i++) { - tseq[i].errors = 0; - } - if (dmi_initialized) { - for (i=0; i < MAX_DMI_MEMDEVS; i++){ - if (dmi_err_cnts[i] > 0) { - dmi_err_cnts[i] = 0; - } - } - } - - /* setup beep mode */ - beepmode = BEEP_MODE; - - /* Get the cpu and cache information */ - get_cpuid(); - - /* setup pci */ - pci_init(); - - get_cache_size(); - - cpu_type(); - - cpu_cache_speed(); - - /* Check fail safe */ - failsafe(5000, 0x3B); - - /* Initalize SMP */ - initialise_cpus(); - - for (i = 0; i fail_safe & 3) == 2) - { - cprint(LINE_CPU,9, "(SMP: Disabled)"); - cprint(LINE_RAM,9, "Running..."); - } - // dprint(10, 5, found_cpus, 2, 0); - - /* Find Memory Specs */ - if(vv->fail_safe & 1) - { - cprint(LINE_CPU, COL_SPEC, " **** FAIL SAFE **** FAIL SAFE **** "); - cprint(LINE_RAM, COL_SPEC, " No detection, same reliability "); - } else { - find_controller(); - get_spd_spec(); - if(num_cpus <= 16 && !(vv->fail_safe & 4)) { coretemp(); } - } - - if(vv->check_temp > 0 && !(vv->fail_safe & 4)) - { - cprint(LINE_CPU, 26, "| CPU Temp"); - cprint(LINE_CPU+1, 26, "| øC"); - } - - beep(600); - beep(1000); - - /* Record the start time */ - asm __volatile__ ("rdtsc":"=a" (vv->startl),"=d" (vv->starth)); - vv->snapl = vv->startl; - vv->snaph = vv->starth; - if (l1_cache == 0) { l1_cache = 64; } - if (l2_cache == 0) { l1_cache = 512; } - vv->printmode=PRINTMODE_ADDRESSES; - vv->numpatn=0; -} - -/* Get cache sizes for most AMD and Intel CPUs, exceptions for old CPUs are - * handled in CPU detection */ -void get_cache_size() -{ - int i, j, n, size; - unsigned int v[4]; - unsigned char *dp = (unsigned char *)v; - struct cpuid4_eax *eax = (struct cpuid4_eax *)&v[0]; - struct cpuid4_ebx *ebx = (struct cpuid4_ebx *)&v[1]; - struct cpuid4_ecx *ecx = (struct cpuid4_ecx *)&v[2]; - - switch(cpu_id.vend_id.char_array[0]) { - /* AMD Processors */ - case 'A': - //l1_cache = cpu_id.cache_info.amd.l1_i_sz; - l1_cache = cpu_id.cache_info.amd.l1_d_sz; - l2_cache = cpu_id.cache_info.amd.l2_sz; - l3_cache = cpu_id.cache_info.amd.l3_sz; - l3_cache *= 512; - break; - case 'G': - /* Intel Processors */ - l1_cache = 0; - l2_cache = 0; - l3_cache = 0; - - /* Use CPUID(4) if it is available */ - if (cpu_id.max_cpuid > 3) { - - /* figure out how many cache leaves */ - n = -1; - do - { - ++n; - /* Do cpuid(4) loop to find out num_cache_leaves */ - cpuid_count(4, n, &v[0], &v[1], &v[2], &v[3]); - } while ((eax->ctype) != 0); - - /* loop through all of the leaves */ - for (i=0; ictype == 1 || eax->ctype == 3) - { - - /* Compute the cache size */ - size = (ecx->number_of_sets + 1) * - (ebx->coherency_line_size + 1) * - (ebx->physical_line_partition + 1) * - (ebx->ways_of_associativity + 1); - size /= 1024; - - switch (eax->level) - { - case 1: - l1_cache += size; - break; - case 2: - l2_cache += size; - break; - case 3: - l3_cache += size; - break; - } - } - } - return; - } - - /* No CPUID(4) so we use the older CPUID(2) method */ - /* Get number of times to iterate */ - cpuid(2, &v[0], &v[1], &v[2], &v[3]); - n = v[0] & 0xff; - for (i=0 ; ifail_safe |= 4; } // Atom Clover Trail - if(cpu_id.vers.bits.extendedModel == 4) { imc_type = 0x0007; } // HSW-ULT - break; - case 0x6: - if(cpu_id.vers.bits.extendedModel == 3) { - imc_type = 0x0009; // Atom Cedar Trail - vv->fail_safe |= 4; // Disable Core temp - } - break; - case 0xA: - switch(cpu_id.vers.bits.extendedModel) - { - case 0x1: - imc_type = 0x0001; // Core i7 1st Gen 45 nm (NHME) - break; - case 0x2: - imc_type = 0x0004; // Core 2nd Gen (SNB) - break; - case 0x3: - imc_type = 0x0006; // Core 3nd Gen (IVB) - break; - } - break; - case 0xC: - switch(cpu_id.vers.bits.extendedModel) - { - case 0x1: - if(cpu_id.vers.bits.stepping > 9) { imc_type = 0x0008; } // Atom PineView - vv->fail_safe |= 4; // Disable Core temp - break; - case 0x2: - imc_type = 0x0002; // Core i7 1st Gen 32 nm (WMR) - break; - case 0x3: - imc_type = 0x0007; // Core 4nd Gen (HSW) - break; - } - break; - case 0xD: - imc_type = 0x0005; // SNB-E - break; - case 0xE: - imc_type = 0x0001; // Core i7 1st Gen 45 nm (NHM) - break; - } - - if(imc_type) { tsc_invariable = 1; } - return; - } -} - -void smp_default_mode(void) -{ - int i, result; - char *cpupsn = cpu_id.brand_id.char_array; - char *disabledcpu[] = { "Opteron", "Xeon", "EPYC", "Genuine Intel" }; - - for(i = 0; i < 3; i++) - { - result = mt86_strstr(cpupsn , disabledcpu[i]); - if(result != -1) { vv->fail_safe |= 0b10; } - } - - // For 5.01 release, SMP disabled by defualt by config.h toggle - if(CONSERVATIVE_SMP) { vv->fail_safe |= 0b10; } - -} - -/* - * Find CPU type - */ -void cpu_type(void) -{ - /* If we can get a brand string use it, and we are done */ - if (cpu_id.max_xcpuid >= 0x80000004) { - cprint(0, COL_MID, cpu_id.brand_id.char_array); - //If we have a brand string, maybe we have an IMC. Check that. - detect_imc(); - smp_default_mode(); - return; - } - - /* The brand string is not available so we need to figure out - * CPU what we have */ - switch(cpu_id.vend_id.char_array[0]) { - /* AMD Processors */ - case 'A': - switch(cpu_id.vers.bits.family) { - case 4: - switch(cpu_id.vers.bits.model) { - case 3: - cprint(0, COL_MID, "AMD 486DX2"); - break; - case 7: - cprint(0, COL_MID, "AMD 486DX2-WB"); - break; - case 8: - cprint(0, COL_MID, "AMD 486DX4"); - break; - case 9: - cprint(0, COL_MID, "AMD 486DX4-WB"); - break; - case 14: - cprint(0, COL_MID, "AMD 5x86-WT"); - break; - case 15: - cprint(0, COL_MID, "AMD 5x86-WB"); - break; - } - /* Since we can't get CPU speed or cache info return */ - return; - case 5: - switch(cpu_id.vers.bits.model) { - case 0: - case 1: - case 2: - case 3: - cprint(0, COL_MID, "AMD K5"); - l1_cache = 8; - break; - case 6: - case 7: - cprint(0, COL_MID, "AMD K6"); - break; - case 8: - cprint(0, COL_MID, "AMD K6-2"); - break; - case 9: - cprint(0, COL_MID, "AMD K6-III"); - break; - case 13: - cprint(0, COL_MID, "AMD K6-III+"); - break; - } - break; - case 6: - - switch(cpu_id.vers.bits.model) { - case 1: - cprint(0, COL_MID, "AMD Athlon (0.25)"); - break; - case 2: - case 4: - cprint(0, COL_MID, "AMD Athlon (0.18)"); - break; - case 6: - if (l2_cache == 64) { - cprint(0, COL_MID, "AMD Duron (0.18)"); - } else { - cprint(0, COL_MID, "Athlon XP (0.18)"); - } - break; - case 8: - case 10: - if (l2_cache == 64) { - cprint(0, COL_MID, "AMD Duron (0.13)"); - } else { - cprint(0, COL_MID, "Athlon XP (0.13)"); - } - break; - case 3: - case 7: - cprint(0, COL_MID, "AMD Duron"); - /* Duron stepping 0 CPUID for L2 is broken */ - /* (AMD errata T13)*/ - if (cpu_id.vers.bits.stepping == 0) { /* stepping 0 */ - /* Hard code the right L2 size */ - l2_cache = 64; - } else { - } - break; - } - break; - - /* All AMD family values >= 10 have the Brand ID - * feature so we don't need to find the CPU type */ - } - break; - - /* Intel or Transmeta Processors */ - case 'G': - if ( cpu_id.vend_id.char_array[7] == 'T' ) { /* GenuineTMx86 */ - if (cpu_id.vers.bits.family == 5) { - cprint(0, COL_MID, "TM 5x00"); - } else if (cpu_id.vers.bits.family == 15) { - cprint(0, COL_MID, "TM 8x00"); - } - l1_cache = cpu_id.cache_info.ch[3] + cpu_id.cache_info.ch[7]; - l2_cache = (cpu_id.cache_info.ch[11]*256) + cpu_id.cache_info.ch[10]; - } else { /* GenuineIntel */ - if (cpu_id.vers.bits.family == 4) { - switch(cpu_id.vers.bits.model) { - case 0: - case 1: - cprint(0, COL_MID, "Intel 486DX"); - break; - case 2: - cprint(0, COL_MID, "Intel 486SX"); - break; - case 3: - cprint(0, COL_MID, "Intel 486DX2"); - break; - case 4: - cprint(0, COL_MID, "Intel 486SL"); - break; - case 5: - cprint(0, COL_MID, "Intel 486SX2"); - break; - case 7: - cprint(0, COL_MID, "Intel 486DX2-WB"); - break; - case 8: - cprint(0, COL_MID, "Intel 486DX4"); - break; - case 9: - cprint(0, COL_MID, "Intel 486DX4-WB"); - break; - } - /* Since we can't get CPU speed or cache info return */ - return; - } - - - switch(cpu_id.vers.bits.family) { - case 5: - switch(cpu_id.vers.bits.model) { - case 0: - case 1: - case 2: - case 3: - case 7: - cprint(0, COL_MID, "Pentium"); - if (l1_cache == 0) { - l1_cache = 8; - } - break; - case 4: - case 8: - cprint(0, COL_MID, "Pentium-MMX"); - if (l1_cache == 0) { - l1_cache = 16; - } - break; - } - break; - case 6: - switch(cpu_id.vers.bits.model) { - case 0: - case 1: - cprint(0, COL_MID, "Pentium Pro"); - break; - case 3: - case 4: - cprint(0, COL_MID, "Pentium II"); - break; - case 5: - if (l2_cache == 0) { - cprint(0, COL_MID, "Celeron"); - } else { - cprint(0, COL_MID, "Pentium II"); - } - break; - case 6: - if (l2_cache == 128) { - cprint(0, COL_MID, "Celeron"); - } else { - cprint(0, COL_MID, "Pentium II"); - } - } - break; - case 7: - case 8: - case 11: - if (l2_cache == 128) { - cprint(0, COL_MID, "Celeron"); - } else { - cprint(0, COL_MID, "Pentium III"); - } - break; - case 9: - if (l2_cache == 512) { - cprint(0, COL_MID, "Celeron M (0.13)"); - } else { - cprint(0, COL_MID, "Pentium M (0.13)"); - } - break; - case 10: - cprint(0, COL_MID, "Pentium III Xeon"); - break; - case 12: - l1_cache = 24; - cprint(0, COL_MID, "Atom (0.045)"); - break; - case 13: - if (l2_cache == 1024) { - cprint(0, COL_MID, "Celeron M (0.09)"); - } else { - cprint(0, COL_MID, "Pentium M (0.09)"); - } - break; - case 14: - cprint(0, COL_MID, "Intel Core"); - break; - case 15: - if (l2_cache == 1024) { - cprint(0, COL_MID, "Pentium E"); - } else { - cprint(0, COL_MID, "Intel Core 2"); - } - break; - } - break; - case 15: - switch(cpu_id.vers.bits.model) { - case 0: - case 1: - case 2: - if (l2_cache == 128) { - cprint(0, COL_MID, "Celeron"); - } else { - cprint(0, COL_MID, "Pentium 4"); - } - break; - case 3: - case 4: - if (l2_cache == 256) { - cprint(0, COL_MID, "Celeron (0.09)"); - } else { - cprint(0, COL_MID, "Pentium 4 (0.09)"); - } - break; - case 6: - cprint(0, COL_MID, "Pentium D (65nm)"); - break; - default: - cprint(0, COL_MID, "Unknown Intel"); - break; - break; - } - - } - break; - - /* VIA/Cyrix/Centaur Processors with CPUID */ - case 'C': - if ( cpu_id.vend_id.char_array[1] == 'e' ) { /* CentaurHauls */ - l1_cache = cpu_id.cache_info.ch[3] + cpu_id.cache_info.ch[7]; - l2_cache = cpu_id.cache_info.ch[11]; - switch(cpu_id.vers.bits.family){ - case 5: - cprint(0, COL_MID, "Centaur 5x86"); - break; - case 6: // VIA C3 - switch(cpu_id.vers.bits.model){ - default: - if (cpu_id.vers.bits.stepping < 8) { - cprint(0, COL_MID, "VIA C3 Samuel2"); - } else { - cprint(0, COL_MID, "VIA C3 Eden"); - } - break; - case 10: - cprint(0, COL_MID, "VIA C7 (C5J)"); - l1_cache = 64; - l2_cache = 128; - break; - case 13: - cprint(0, COL_MID, "VIA C7 (C5R)"); - l1_cache = 64; - l2_cache = 128; - break; - case 15: - cprint(0, COL_MID, "VIA Isaiah (CN)"); - l1_cache = 64; - l2_cache = 128; - break; - } - } - } else { /* CyrixInstead */ - switch(cpu_id.vers.bits.family) { - case 5: - switch(cpu_id.vers.bits.model) { - case 0: - cprint(0, COL_MID, "Cyrix 6x86MX/MII"); - break; - case 4: - cprint(0, COL_MID, "Cyrix GXm"); - break; - } - return; - - case 6: // VIA C3 - switch(cpu_id.vers.bits.model) { - case 6: - cprint(0, COL_MID, "Cyrix III"); - break; - case 7: - if (cpu_id.vers.bits.stepping < 8) { - cprint(0, COL_MID, "VIA C3 Samuel2"); - } else { - cprint(0, COL_MID, "VIA C3 Ezra-T"); - } - break; - case 8: - cprint(0, COL_MID, "VIA C3 Ezra-T"); - break; - case 9: - cprint(0, COL_MID, "VIA C3 Nehemiah"); - break; - } - // L1 = L2 = 64 KB from Cyrix III to Nehemiah - l1_cache = 64; - l2_cache = 64; - break; - } - } - break; - /* Unknown processor */ - default: - /* Make a guess at the family */ - switch(cpu_id.vers.bits.family) { - case 5: - cprint(0, COL_MID, "586"); - case 6: - cprint(0, COL_MID, "686"); - default: - cprint(0, COL_MID, "Unidentified Processor"); - } - } -} - -#define STEST_ADDR 0x100000 /* Measure memory speed starting at 1MB */ - -/* Measure and display CPU and cache sizes and speeds */ -void cpu_cache_speed() -{ - int i, off = 4; - ulong speed; - - - /* Print CPU speed */ - if ((speed = cpuspeed()) > 0) { - if (speed < 999499) { - speed += 50; /* for rounding */ - cprint(1, off, " . MHz"); - dprint(1, off+1, speed/1000, 3, 1); - dprint(1, off+5, (speed/100)%10, 1, 0); - } else { - speed += 500; /* for rounding */ - cprint(1, off, " MHz"); - dprint(1, off, speed/1000, 5, 0); - } - extclock = speed; - } - - /* Print out L1 cache info */ - /* To measure L1 cache speed we use a block size that is 1/4th */ - /* of the total L1 cache size since half of it is for instructions */ - if (l1_cache) { - cprint(2, 0, "L1 Cache: K "); - dprint(2, 11, l1_cache, 3, 0); - if ((speed=memspeed(STEST_ADDR, (l1_cache/2)*1024, 200))) { - cprint(2, 16, " MB/s"); - dprint(2, 16, speed, 6, 0); - } - } - - /* Print out L2 cache info */ - /* We measure the L2 cache speed by using a block size that is */ - /* the size of the L1 cache. We have to fudge if the L1 */ - /* cache is bigger than the L2 */ - if (l2_cache) { - cprint(3, 0, "L2 Cache: K "); - dprint(3, 10, l2_cache, 4, 0); - - if (l2_cache < l1_cache) { - i = l1_cache / 4 + l2_cache / 4; - } else { - i = l1_cache; - } - if ((speed=memspeed(STEST_ADDR, i*1024, 200))) { - cprint(3, 16, " MB/s"); - dprint(3, 16, speed, 6, 0); - } - } - /* Print out L3 cache info */ - /* We measure the L3 cache speed by using a block size that is */ - /* 2X the size of the L2 cache. */ - - if (l3_cache) - { - cprint(4, 0, "L3 Cache: K "); - aprint(4, 10, l3_cache/4); - //dprint(4, 10, l3_cache, 4, 0); - - i = l2_cache*2; - - if ((speed=memspeed(STEST_ADDR, i*1024, 150))) { - cprint(4, 16, " MB/s"); - dprint(4, 16, speed, 6, 0); - } - } -} - -/* Measure and display memory speed, multitasked using all CPUs */ -ulong spd[MAX_CPUS]; -void get_mem_speed(int me, int ncpus) -{ - int i; - ulong speed=0; - - /* Determine memory speed. To find the memory speed we use - * A block size that is the sum of all the L1, L2 & L3 caches - * in all cpus * 6 */ - i = (l3_cache + l2_cache + l1_cache) * 4; - - /* Make sure that we have enough memory to do the test */ - /* If not use all we have */ - if ((1 + (i * 2)) > (vv->plim_upper << 2)) { - i = ((vv->plim_upper <<2) - 1) / 2; - } - - speed = memspeed(STEST_ADDR, i * 1024, 100); - cprint(5, 16, " MB/s"); - dprint(5, 16, speed, 6, 0); - -} - -/* #define TICKS 5 * 11832 (count = 6376)*/ -/* #define TICKS (65536 - 12752) */ -#define TICKS 59659 /* 50 ms */ - -/* Returns CPU clock in khz */ -ulong stlow, sthigh; -static int cpuspeed(void) -{ - int loops; - ulong end_low, end_high; - - if (cpu_id.fid.bits.rdtsc == 0 ) { - return(-1); - } - - /* Setup timer */ - outb((inb(0x61) & ~0x02) | 0x01, 0x61); - outb(0xb0, 0x43); - outb(TICKS & 0xff, 0x42); - outb(TICKS >> 8, 0x42); - - asm __volatile__ ("rdtsc":"=a" (stlow),"=d" (sthigh)); - - loops = 0; - do { - loops++; - } while ((inb(0x61) & 0x20) == 0); - - asm __volatile__ ( - "rdtsc\n\t" \ - "subl stlow,%%eax\n\t" \ - "sbbl sthigh,%%edx\n\t" \ - :"=a" (end_low), "=d" (end_high) - ); - - /* Make sure we have a credible result */ - if (loops < 4 || end_low < 50000) { - return(-1); - } - vv->clks_msec = end_low/50; - - if (tsc_invariable) end_low = correct_tsc(end_low); - - return(vv->clks_msec); -} - -/* Measure cache speed by copying a block of memory. */ -/* Returned value is kbytes/second */ -ulong memspeed(ulong src, ulong len, int iter) -{ - int i; - ulong dst, wlen; - ulong st_low, st_high; - ulong end_low, end_high; - ulong cal_low, cal_high; - - if (cpu_id.fid.bits.rdtsc == 0 ) { - return(-1); - } - if (len == 0) return(-2); - - dst = src + len; - wlen = len / 4; /* Length is bytes */ - - /* Calibrate the overhead with a zero word copy */ - asm __volatile__ ("rdtsc":"=a" (st_low),"=d" (st_high)); - for (i=0; iclks_msec)/end_low); -} - -#define rdmsr(msr,val1,val2) \ - __asm__ __volatile__("rdmsr" \ - : "=a" (val1), "=d" (val2) \ - : "c" (msr)) - - -ulong correct_tsc(ulong el_org) -{ - float coef_now, coef_max; - int msr_lo, msr_hi, is_xe; - - rdmsr(0x198, msr_lo, msr_hi); - is_xe = (msr_lo >> 31) & 0x1; - - if(is_xe){ - rdmsr(0x198, msr_lo, msr_hi); - coef_max = ((msr_hi >> 8) & 0x1F); - if ((msr_hi >> 14) & 0x1) { coef_max = coef_max + 0.5f; } - } else { - rdmsr(0x17, msr_lo, msr_hi); - coef_max = ((msr_lo >> 8) & 0x1F); - if ((msr_lo >> 14) & 0x1) { coef_max = coef_max + 0.5f; } - } - - if(cpu_id.fid.bits.eist) { - rdmsr(0x198, msr_lo, msr_hi); - coef_now = ((msr_lo >> 8) & 0x1F); - if ((msr_lo >> 14) & 0x1) { coef_now = coef_now + 0.5f; } - } else { - rdmsr(0x2A, msr_lo, msr_hi); - coef_now = (msr_lo >> 22) & 0x1F; - } - if(coef_max && coef_now) { - el_org = (ulong)(el_org * coef_now / coef_max); - } - return el_org; -} - diff --git a/memtest86+_old/io.h b/memtest86+_old/io.h deleted file mode 100644 index ae70dcf..0000000 --- a/memtest86+_old/io.h +++ /dev/null @@ -1,133 +0,0 @@ -#ifndef _ASM_IO_H -#define _ASM_IO_H - -/* - * This file contains the definitions for the x86 IO instructions - * inb/inw/inl/outb/outw/outl and the "string versions" of the same - * (insb/insw/insl/outsb/outsw/outsl). You can also use "pausing" - * versions of the single-IO instructions (inb_p/inw_p/..). - * - * This file is not meant to be obfuscating: it's just complicated - * to (a) handle it all in a way that makes gcc able to optimize it - * as well as possible and (b) trying to avoid writing the same thing - * over and over again with slight variations and possibly making a - * mistake somewhere. - */ - -#ifdef SLOW_IO_BY_JUMPING -#define __SLOW_DOWN_IO __asm__ __volatile__("jmp 1f\n1:\tjmp 1f\n1:") -#else -#define __SLOW_DOWN_IO __asm__ __volatile__("outb %al,$0x80") -#endif - -#ifdef REALLY_SLOW_IO -#define SLOW_DOWN_IO { __SLOW_DOWN_IO; __SLOW_DOWN_IO; __SLOW_DOWN_IO; __SLOW_DOWN_IO; } -#else -#define SLOW_DOWN_IO __SLOW_DOWN_IO -#endif - -/* - * Talk about misusing macros.. - */ - -#define __OUT1(s,x) \ -static inline void __out##s(unsigned x value, unsigned short port) { - -#define __OUT2(s,s1,s2) \ -__asm__ __volatile__ ("out" #s " %" s1 "0,%" s2 "1" - -#define __OUT(s,s1,x) \ -__OUT1(s,x) __OUT2(s,s1,"w") : : "a" (value), "d" (port)); } \ -__OUT1(s##c,x) __OUT2(s,s1,"") : : "a" (value), "id" (port)); } \ -__OUT1(s##_p,x) __OUT2(s,s1,"w") : : "a" (value), "d" (port)); SLOW_DOWN_IO; } \ -__OUT1(s##c_p,x) __OUT2(s,s1,"") : : "a" (value), "id" (port)); SLOW_DOWN_IO; } - -#define __IN1(s) \ -static inline RETURN_TYPE __in##s(unsigned short port) { RETURN_TYPE _v; - -#define __IN2(s,s1,s2) \ -__asm__ __volatile__ ("in" #s " %" s2 "1,%" s1 "0" - -#define __IN(s,s1,i...) \ -__IN1(s) __IN2(s,s1,"w") : "=a" (_v) : "d" (port) ,##i ); return _v; } \ -__IN1(s##c) __IN2(s,s1,"") : "=a" (_v) : "id" (port) ,##i ); return _v; } \ -__IN1(s##_p) __IN2(s,s1,"w") : "=a" (_v) : "d" (port) ,##i ); SLOW_DOWN_IO; return _v; } \ -__IN1(s##c_p) __IN2(s,s1,"") : "=a" (_v) : "id" (port) ,##i ); SLOW_DOWN_IO; return _v; } - -#define __OUTS(s) \ -static inline void outs##s(unsigned short port, const void * addr, unsigned long count) \ -{ __asm__ __volatile__ ("cld ; rep ; outs" #s \ -: "=S" (addr), "=c" (count) : "d" (port),"0" (addr),"1" (count)); } - -#define RETURN_TYPE unsigned char -/* __IN(b,"b","0" (0)) */ -__IN(b,"") -#undef RETURN_TYPE -#define RETURN_TYPE unsigned short -/* __IN(w,"w","0" (0)) */ -__IN(w,"") -#undef RETURN_TYPE -#define RETURN_TYPE unsigned int -__IN(l,"") -#undef RETURN_TYPE - -__OUT(b,"b",char) -__OUT(w,"w",short) -__OUT(l,,int) - -__OUTS(b) -__OUTS(w) -__OUTS(l) - -/* - * Note that due to the way __builtin_constant_p() works, you - * - can't use it inside a inline function (it will never be true) - * - you don't have to worry about side effects within the __builtin.. - */ -#define outb(val,port) \ -((__builtin_constant_p((port)) && (port) < 256) ? \ - __outbc((val),(port)) : \ - __outb((val),(port))) - -#define inb(port) \ -((__builtin_constant_p((port)) && (port) < 256) ? \ - __inbc(port) : \ - __inb(port)) - - -#define outw(val,port) \ -((__builtin_constant_p((port)) && (port) < 256) ? \ - __outwc((val),(port)) : \ - __outw((val),(port))) - -#define inw(port) \ -((__builtin_constant_p((port)) && (port) < 256) ? \ - __inwc(port) : \ - __inw(port)) - - -#define outl(val,port) \ -((__builtin_constant_p((port)) && (port) < 256) ? \ - __outlc((val),(port)) : \ - __outl((val),(port))) - -#define inl(port) \ -((__builtin_constant_p((port)) && (port) < 256) ? \ - __inlc(port) : \ - __inl(port)) -#endif - -static __inline void -outb_p (unsigned char __value, unsigned short int __port ) -{ - __asm__ __volatile__ ("outb %b0,%w1\noutb %%al,$0x80": :"a" (__value), - "Nd" (__port)); -} - -static __inline unsigned char -inb_p (unsigned short int __port) -{ - unsigned char _v; - __asm__ __volatile__ ("inb %w1,%0\noutb %%al,$0x80":"=a" (_v):"Nd" (__port)); - return _v; -} \ No newline at end of file diff --git a/memtest86+_old/jedec_id.h b/memtest86+_old/jedec_id.h deleted file mode 100644 index 240876c..0000000 --- a/memtest86+_old/jedec_id.h +++ /dev/null @@ -1,985 +0,0 @@ -/* MemTest86+ V5 Specific code (GPL V2.0) - * By Samuel DEMEULEMEESTER, sdemeule@memtest.org - * http://www.canardpc.com - http://www.memtest.org - * ------------------------------------------------ - * Based on JEDEC JEP106-AG - January 2012 - */ - -struct spd_jedec_manufacturer { - unsigned cont_code; - unsigned hex_byte; - char *name; -}; - -static struct spd_jedec_manufacturer jep106[] = - { - { 0, 0x01, "AMD"}, - { 0, 0x02, "AMI"}, - { 0, 0x83, "Fairchild"}, - { 0, 0x04, "Fujitsu"}, - // { 0, 0x85, "GTE"}, - { 0, 0x86, "Harris"}, - { 0, 0x07, "Hitachi"}, - { 0, 0x08, "Inmos"}, - { 0, 0x89, "Intel"}, - { 0, 0x8a, "I.T.T."}, - { 0, 0x0b, "Intersil"}, - { 0, 0x8c, "Monolithic Memories"}, - { 0, 0x0d, "Mostek"}, - { 0, 0x0e, "Freescale"}, - { 0, 0x8f, "National"}, - { 0, 0x10, "NEC"}, - { 0, 0x91, "RCA"}, - { 0, 0x92, "Raytheon"}, - { 0, 0x13, "Conexant"}, - // { 0, 0x94, "Seeq"}, - { 0, 0x15, "NXP"}, - { 0, 0x16, "Synertek"}, - { 0, 0x97, "Texas Instruments"}, - { 0, 0x98, "Toshiba"}, - { 0, 0x19, "Xicor"}, - { 0, 0x1a, "Zilog"}, - // { 0, 0x9b, "Eurotechnique"}, - { 0, 0x1c, "Mitsubishi"}, - { 0, 0x9d, "Lucent (AT&T)"}, - // { 0, 0x9e, "Exel"}, - { 0, 0x1f, "Atmel"}, - { 0, 0x20, "SGS/Thomson"}, - // { 0, 0xa1, "Lattice Semi."}, - { 0, 0xa2, "NCR"}, - // { 0, 0x23, "Wafer Scale Integration"}, - { 0, 0xa4, "IBM"}, - { 0, 0x25, "Tristar"}, - // { 0, 0x26, "Visic"}, - { 0, 0xa7, "Intl. CMOS Technology"}, - // { 0, 0xa8, "SSSI"}, - { 0, 0x29, "MicrochipTechnology"}, - // { 0, 0x2a, "Ricoh"}, - // { 0, 0xab, "VLSI"}, - { 0, 0x2c, "Micron"}, - { 0, 0xad, "Hynix"}, - { 0, 0xae, "OKI Semiconductor"}, - // { 0, 0x2f, "ACTEL"}, - { 0, 0xb0, "Sharp"}, - { 0, 0x31, "Catalyst"}, - { 0, 0x32, "Panasonic"}, - { 0, 0xb3, "IDT"}, - { 0, 0x34, "Cypress"}, - { 0, 0xb5, "DEC"}, - { 0, 0xb6, "LSI Logic"}, - // { 0, 0x37, "Zarlink (Plessey)"}, - { 0, 0x38, "UTMC"}, - // { 0, 0xb9, "Thinking Machine"}, - { 0, 0xba, "Thomson CSF"}, - // { 0, 0x3b, "Integrated CMOS (Vertex)"}, - // { 0, 0xbc, "Honeywell"}, - { 0, 0x3d, "Tektronix"}, - // { 0, 0x3e, "Oracle"}, - // { 0, 0xbf, "Silicon Storage Technology"}, - { 0, 0x40, "ProMos/Mosel"}, - { 0, 0xc1, "Infineon"}, - // { 0, 0xc2, "Macronix"}, - { 0, 0x43, "Xerox"}, - // { 0, 0xc4, "Plus Logic"}, - { 0, 0x45, "SanDisk"}, - // { 0, 0x46, "Elan Circuit Tech."}, - // { 0, 0xc7, "European Silicon Str."}, - { 0, 0xc8, "Apple Computer"}, - { 0, 0x49, "Xilinx"}, - { 0, 0x4a, "Compaq"}, - // { 0, 0xcb, "Protocol Engines"}, - // { 0, 0x4c, "SCI"}, - { 0, 0xcd, "Seiko Instruments"}, - { 0, 0xce, "Samsung"}, - // { 0, 0x4f, "I3 Design System"}, - // { 0, 0xd0, "Klic"}, - // { 0, 0x51, "Crosspoint Solutions"}, - // { 0, 0x52, "Alliance Semiconductor"}, - // { 0, 0xd3, "Tandem"}, - { 0, 0x54, "Hewlett-Packard"}, - { 0, 0xd5, "Integrated Silicon Solutions"}, - // { 0, 0xd6, "Brooktree"}, - // { 0, 0x57, "New Media"}, - // { 0, 0x58, "MHS Electronic"}, - // { 0, 0xd9, "Performance Semi."}, - { 0, 0xda, "Winbond Electronic"}, - // { 0, 0x5b, "Kawasaki Steel"}, - // { 0, 0xdc, "Bright Micro"}, - // { 0, 0x5d, "TECMAR"}, - { 0, 0x5e, "Exar"}, - // { 0, 0xdf, "PCMCIA"}, - { 0, 0xe0, "LG"}, - // { 0, 0x61, "Northern Telecom"}, - { 0, 0x62, "Sanyo"}, - // { 0, 0xe3, "Array Microsystems"}, - // { 0, 0x64, "Crystal Semiconductor"}, - { 0, 0xe5, "Analog Devices"}, - // { 0, 0xe6, "PMC-Sierra"}, - // { 0, 0x67, "Asparix"}, - // { 0, 0x68, "Convex Computer"}, - // { 0, 0xe9, "Quality Semiconductor"}, - // { 0, 0xea, "Nimbus Technology"}, - // { 0, 0x6b, "Transwitch"}, - // { 0, 0xec, "Micronas (ITT Intermetall)"}, - { 0, 0x6d, "Cannon"}, - // { 0, 0x6e, "Altera"}, - // { 0, 0xef, "NEXCOM"}, - // { 0, 0x70, "QUALCOMM"}, - { 0, 0xf1, "Sony"}, - // { 0, 0xf2, "Cray Research"}, - // { 0, 0x73, "AMS(Austria Micro)"}, - // { 0, 0xf4, "Vitesse"}, - // { 0, 0x75, "Aster Electronics"}, - // { 0, 0x76, "Bay Networks (Synoptic)"}, - // { 0, 0xf7, "Zentrum/ZMD"}, - // { 0, 0xf8, "TRW"}, - // { 0, 0x79, "Thesys"}, - // { 0, 0x7a, "Solbourne Computer"}, - { 0, 0xfb, "Allied-Signal"}, - { 0, 0x7c, "Dialog"}, - { 0, 0xfd, "Media Vision"}, - // { 0, 0xfe, "Numonyx"}, - { 1, 0x01, "Cirrus Logic"}, - { 1, 0x02, "National Instruments"}, - // { 1, 0x83, "ILC Data Device"}, - // { 1, 0x04, "Alcatel Mietec"}, - // { 1, 0x85, "Micro Linear"}, - // { 1, 0x86, "Univ. of NC"}, - // { 1, 0x07, "JTAG Technologies"}, - // { 1, 0x08, "BAE Systems (Loral)"}, - // { 1, 0x89, "Nchip"}, - // { 1, 0x8a, "Galileo Tech"}, - // { 1, 0x0b, "Bestlink Systems"}, - // { 1, 0x8c, "Graychip"}, - // { 1, 0x0d, "GENNUM"}, - // { 1, 0x0e, "VideoLogic"}, - // { 1, 0x8f, "Robert Bosch"}, - // { 1, 0x10, "Chip Express"}, - { 1, 0x91, "DATARAM"}, - // { 1, 0x92, "United Microelectronics Corp."}, - // { 1, 0x13, "TCSI"}, - { 1, 0x94, "Smart Modular"}, - // { 1, 0x15, "Hughes Aircraft"}, - // { 1, 0x16, "Lanstar Semiconductor"}, - // { 1, 0x97, "Qlogic"}, - { 1, 0x98, "Kingston"}, - // { 1, 0x19, "Music Semi"}, - // { 1, 0x1a, "Ericsson Components"}, - // { 1, 0x9b, "SpaSE"}, - // { 1, 0x1c, "Eon Silicon Devices"}, - // { 1, 0x9d, "Programmable Micro Corp"}, - // { 1, 0x9e, "DoD"}, - // { 1, 0x1f, "Integ. Memories Tech."}, - // { 1, 0x20, "Corollary"}, - // { 1, 0xa1, "Dallas Semiconductor"}, - // { 1, 0xa2, "Omnivision"}, - // { 1, 0x23, "EIV(Switzerland)"}, - // { 1, 0xa4, "Novatel Wireless"}, - // { 1, 0x25, "Zarlink (Mitel)"}, - // { 1, 0x26, "Clearpoint"}, - // { 1, 0xa7, "Cabletron"}, - // { 1, 0xa8, "STEC (Silicon Tech)"}, - // { 1, 0x29, "Vanguard"}, - // { 1, 0x2a, "Hagiwara Sys-Com"}, - // { 1, 0xab, "Vantis"}, - // { 1, 0x2c, "Celestica"}, - // { 1, 0xad, "Century"}, - // { 1, 0xae, "Hal Computers"}, - // { 1, 0x2f, "Rohm Company"}, - // { 1, 0xb0, "Juniper Networks"}, - // { 1, 0x31, "Libit Signal Processing"}, - { 1, 0x32, "Mushkin"}, - // { 1, 0xb3, "Tundra Semiconductor"}, - { 1, 0x34, "Adaptec"}, - // { 1, 0xb5, "LightSpeed Semi."}, - // { 1, 0xb6, "ZSP Corp."}, - // { 1, 0x37, "AMIC Technology"}, - // { 1, 0x38, "Adobe Systems"}, - // { 1, 0xb9, "Dynachip"}, - { 1, 0xba, "PNY"}, - // { 1, 0x3b, "Newport Digital"}, - // { 1, 0xbc, "MMC Networks"}, - // { 1, 0x3d, "T Square"}, - // { 1, 0x3e, "Seiko Epson"}, - // { 1, 0xbf, "Broadcom"}, - // { 1, 0x40, "Viking Components"}, - // { 1, 0xc1, "V3 Semiconductor"}, - // { 1, 0xc2, "Flextronics (Orbit Semiconductor)"}, - // { 1, 0x43, "Suwa Electronics"}, - { 1, 0xc4, "Transmeta"}, - { 1, 0x45, "Micron CMS"}, - // { 1, 0x46, "American Computer & Digital Components"}, - // { 1, 0xc7, "Enhance 3000"}, - { 1, 0xc8, "Tower Semiconductor"}, - // { 1, 0x49, "CPU Design"}, - // { 1, 0x4a, "Price Point"}, - { 1, 0xcb, "Maxim Integrated Product"}, - // { 1, 0x4c, "Tellabs"}, - // { 1, 0xcd, "Centaur Technology"}, - { 1, 0xce, "Unigen"}, - { 1, 0x4f, "Transcend"}, - { 1, 0xd0, "Memory Card"}, - // { 1, 0x51, "CKD"}, - // { 1, 0x52, "Capital Instruments"}, - // { 1, 0xd3, "Aica Kogyo"}, - // { 1, 0x54, "Linvex Technology"}, - { 1, 0xd5, "MSC"}, - // { 1, 0xd6, "AKM Company"}, - // { 1, 0x57, "Dynamem"}, - // { 1, 0x58, "NERA ASA"}, - // { 1, 0xd9, "GSI Technology"}, - { 1, 0xda, "Dane-Elec"}, - // { 1, 0x5b, "Acorn Computers"}, - // { 1, 0xdc, "Lara Technology"}, - // { 1, 0x5d, "Oak Technology"}, - { 1, 0x5e, "Itec Memory"}, - // { 1, 0xdf, "Tanisys Technology"}, - // { 1, 0xe0, "Truevision"}, - { 1, 0x61, "Wintec"}, - // { 1, 0x62, "Super PC Memory"}, - // { 1, 0xe3, "MGV Memory"}, - // { 1, 0x64, "Galvantech"}, - // { 1, 0xe5, "Gadzoox Networks"}, - // { 1, 0xe6, "Multi Dimensional Cons."}, - // { 1, 0x67, "GateField"}, - { 1, 0x68, "Integrated Memory System"}, - // { 1, 0xe9, "Triscend"}, - // { 1, 0xea, "XaQti"}, - // { 1, 0x6b, "Goldenram"}, - // { 1, 0xec, "Clear Logic"}, - // { 1, 0x6d, "Cimaron Communications"}, - // { 1, 0x6e, "Nippon Steel Semi. Corp."}, - // { 1, 0xef, "Advantage Memory"}, - // { 1, 0x70, "AMCC"}, - { 1, 0xf1, "LeCroy"}, - // { 1, 0xf2, "Yamaha"}, - // { 1, 0x73, "Digital Microwave"}, - // { 1, 0xf4, "NetLogic Microsystems"}, - // { 1, 0x75, "MIMOS Semiconductor"}, - // { 1, 0x76, "Advanced Fibre"}, - // { 1, 0xf7, "BF Goodrich Data."}, - // { 1, 0xf8, "Epigram"}, - // { 1, 0x79, "Acbel Polytech"}, - { 1, 0x7a, "Apacer Technology"}, - // { 1, 0xfb, "Admor Memory"}, - { 1, 0x7c, "FOXCONN"}, - // { 1, 0xfd, "Quadratics Superconductor"}, - // { 1, 0xfe, "3COM"}, - // { 2, 0x01, "Camintonn"}, - // { 2, 0x02, "ISOA"}, - // { 2, 0x83, "Agate Semiconductor"}, - // { 2, 0x04, "ADMtek"}, - // { 2, 0x85, "HYPERTEC"}, - // { 2, 0x86, "Adhoc Technologies"}, - // { 2, 0x07, "MOSAID Technologies"}, - // { 2, 0x08, "Ardent Technologies"}, - // { 2, 0x89, "Switchcore"}, - // { 2, 0x8a, "Cisco Systems"}, - // { 2, 0x0b, "Allayer Technologies"}, - // { 2, 0x8c, "WorkX AG (Wichman)"}, - // { 2, 0x0d, "Oasis Semiconductor"}, - // { 2, 0x0e, "Novanet Semiconductor"}, - // { 2, 0x8f, "E-M Solutions"}, - // { 2, 0x10, "Power General"}, - // { 2, 0x91, "Advanced Hardware Arch."}, - // { 2, 0x92, "Inova Semiconductors"}, - // { 2, 0x13, "Telocity"}, - // { 2, 0x94, "Delkin Devices"}, - // { 2, 0x15, "Symagery Microsystems"}, - // { 2, 0x16, "C-Port"}, - // { 2, 0x97, "SiberCore Technologies"}, - // { 2, 0x98, "Southland Microsystems"}, - // { 2, 0x19, "Malleable Technologies"}, - // { 2, 0x1a, "Kendin Communications"}, - // { 2, 0x9b, "Great Technology Microcomputer"}, - // { 2, 0x1c, "Sanmina"}, - // { 2, 0x9d, "HADCO"}, - { 2, 0x9e, "Corsair"}, - // { 2, 0x1f, "Actrans System"}, - // { 2, 0x20, "ALPHA Technologies"}, - // { 2, 0xa1, "Silicon Laboratories (Cygnal)"}, - // { 2, 0xa2, "Artesyn Technologies"}, - // { 2, 0x23, "Align Manufacturing"}, - // { 2, 0xa4, "Peregrine Semiconductor"}, - // { 2, 0x25, "Chameleon Systems"}, - // { 2, 0x26, "Aplus Flash Technology"}, - { 2, 0xa7, "MIPS Technologies"}, - // { 2, 0xa8, "Chrysalis ITS"}, - // { 2, 0x29, "ADTEC"}, - { 2, 0x2a, "Kentron Technologies"}, - // { 2, 0xab, "Win Technologies"}, - // { 2, 0x2c, "Tachyon Semiconductor (ASIC)"}, - // { 2, 0xad, "Extreme Packet Devices"}, - // { 2, 0xae, "RF Micro Devices"}, - { 2, 0x2f, "Siemens AG"}, - // { 2, 0xb0, "Sarnoff"}, - // { 2, 0x31, "Itautec SA"}, - // { 2, 0x32, "Radiata"}, - // { 2, 0xb3, "Benchmark Elect. (AVEX)"}, - // { 2, 0x34, "Legend"}, - { 2, 0xb5, "SpecTek"}, - // { 2, 0xb6, "Hi/fn"}, - // { 2, 0x37, "Enikia"}, - // { 2, 0x38, "SwitchOn Networks"}, - // { 2, 0xb9, "AANetcom"}, - // { 2, 0xba, "Micro Memory Bank"}, - { 2, 0x3b, "ESS Technology"}, - // { 2, 0xbc, "Virata"}, - // { 2, 0x3d, "Excess Bandwidth"}, - // { 2, 0x3e, "West Bay Semiconductor"}, - // { 2, 0xbf, "DSP Group"}, - // { 2, 0x40, "Newport Communications"}, - // { 2, 0xc1, "Chip2Chip"}, - // { 2, 0xc2, "Phobos"}, - // { 2, 0x43, "Intellitech"}, - // { 2, 0xc4, "Nordic VLSI ASA"}, - // { 2, 0x45, "Ishoni Networks"}, - // { 2, 0x46, "Silicon Spice"}, - // { 2, 0xc7, "Alchemy Semiconductor"}, - { 2, 0xc8, "Agilent Technologies"}, - // { 2, 0x49, "Centillium Communications"}, - // { 2, 0x4a, "W.L. Gore"}, - // { 2, 0xcb, "HanBit Electronics"}, - // { 2, 0x4c, "GlobeSpan"}, - // { 2, 0xcd, "Element 14"}, - // { 2, 0xce, "Pycon"}, - // { 2, 0x4f, "Saifun Semiconductors"}, - // { 2, 0xd0, "Sibyte,"}, - // { 2, 0x51, "MetaLink Technologies"}, - // { 2, 0x52, "Feiya Technology"}, - // { 2, 0xd3, "I & C Technology"}, - // { 2, 0x54, "Shikatronics"}, - // { 2, 0xd5, "Elektrobit"}, - // { 2, 0xd6, "Megic"}, - // { 2, 0x57, "Com-Tier"}, - // { 2, 0x58, "Malaysia Micro Solutions"}, - // { 2, 0xd9, "Hyperchip"}, - // { 2, 0xda, "Gemstone Communications"}, - // { 2, 0x5b, "Anadigm (Anadyne)"}, - // { 2, 0xdc, "3ParData"}, - // { 2, 0x5d, "Mellanox Technologies"}, - // { 2, 0x5e, "Tenx Technologies"}, - // { 2, 0xdf, "Helix AG"}, - // { 2, 0xe0, "Domosys"}, - // { 2, 0x61, "Skyup Technology"}, - // { 2, 0x62, "HiNT"}, - // { 2, 0xe3, "Chiaro"}, - { 2, 0x64, "MDT"}, - // { 2, 0xe5, "Exbit Technology A/S"}, - // { 2, 0xe6, "Integrated Technology Express"}, - // { 2, 0x67, "AVED Memory"}, - // { 2, 0x68, "Legerity"}, - // { 2, 0xe9, "Jasmine Networks"}, - // { 2, 0xea, "Caspian Networks"}, - // { 2, 0x6b, "nCUBE"}, - // { 2, 0xec, "Silicon Access Networks"}, - // { 2, 0x6d, "FDK"}, - // { 2, 0x6e, "High Bandwidth Access"}, - // { 2, 0xef, "MultiLink Technology"}, - // { 2, 0x70, "BRECIS"}, - // { 2, 0xf1, "World Wide Packets"}, - // { 2, 0xf2, "APW"}, - // { 2, 0x73, "Chicory Systems"}, - // { 2, 0xf4, "Xstream Logic"}, - // { 2, 0x75, "Fast-Chip"}, - // { 2, 0x76, "Zucotto Wireless"}, - // { 2, 0xf7, "Realchip"}, - // { 2, 0xf8, "Galaxy Power"}, - // { 2, 0x79, "eSilicon"}, - // { 2, 0x7a, "Morphics Technology"}, - // { 2, 0xfb, "Accelerant Networks"}, - // { 2, 0x7c, "Silicon Wave"}, - // { 2, 0xfd, "SandCraft"}, - { 2, 0xfe, "Elpida"}, - // { 3, 0x01, "Solectron"}, - { 3, 0x02, "Optosys Technologies"}, - { 3, 0x83, "Buffalo"}, - // { 3, 0x04, "TriMedia Technologies"}, - // { 3, 0x85, "Cyan Technologies"}, - // { 3, 0x86, "Global Locate"}, - // { 3, 0x07, "Optillion"}, - // { 3, 0x08, "Terago Communications"}, - // { 3, 0x89, "Ikanos Communications"}, - { 3, 0x8a, "Princeton"}, - { 3, 0x0b, "Nanya"}, - // { 3, 0x8c, "Elite Flash Storage"}, - // { 3, 0x0d, "Mysticom"}, - // { 3, 0x0e, "LightSand Communications"}, - { 3, 0x8f, "ATI"}, - // { 3, 0x10, "Agere Systems"}, - // { 3, 0x91, "NeoMagic"}, - // { 3, 0x92, "AuroraNetics"}, - // { 3, 0x13, "Golden Empire"}, - { 3, 0x94, "Mushkin"}, - // { 3, 0x15, "Tioga Technologies"}, - { 3, 0x16, "Netlist"}, - // { 3, 0x97, "TeraLogic"}, - // { 3, 0x98, "Cicada Semiconductor"}, - { 3, 0x19, "Centon"}, - { 3, 0x1a, "Tyco Electronics"}, - // { 3, 0x9b, "Magis Works"}, - // { 3, 0x1c, "Zettacom"}, - // { 3, 0x9d, "Cogency Semiconductor"}, - // { 3, 0x9e, "Chipcon AS"}, - // { 3, 0x1f, "Aspex Technology"}, - // { 3, 0x20, "F5 Networks"}, - // { 3, 0xa1, "Programmable Silicon Solutions"}, - // { 3, 0xa2, "ChipWrights"}, - // { 3, 0x23, "Acorn Networks"}, - // { 3, 0xa4, "Quicklogic"}, - { 3, 0x25, "Kingmax"}, - // { 3, 0x26, "BOPS"}, - // { 3, 0xa7, "Flasys"}, - // { 3, 0xa8, "BitBlitz Communications"}, - { 3, 0x29, "eMemory Technology"}, - // { 3, 0x2a, "Procket Networks"}, - // { 3, 0xab, "Purple Ray"}, - // { 3, 0x2c, "Trebia Networks"}, - // { 3, 0xad, "Delta Electronics"}, - // { 3, 0xae, "Onex Communications"}, - // { 3, 0x2f, "Ample Communications"}, - { 3, 0xb0, "Memory Experts"}, - // { 3, 0x31, "Astute Networks"}, - // { 3, 0x32, "Azanda Network Devices"}, - // { 3, 0xb3, "Dibcom"}, - // { 3, 0x34, "Tekmos"}, - // { 3, 0xb5, "API NetWorks"}, - // { 3, 0xb6, "Bay Microsystems"}, - // { 3, 0x37, "Firecron"}, - // { 3, 0x38, "Resonext Communications"}, - // { 3, 0xb9, "Tachys Technologies"}, - // { 3, 0xba, "Equator Technology"}, - // { 3, 0x3b, "Concept Computer"}, - // { 3, 0xbc, "SILCOM"}, - // { 3, 0x3d, "3Dlabs"}, - // { 3, 0x3e, "c’t Magazine"}, - // { 3, 0xbf, "Sanera Systems"}, - // { 3, 0x40, "Silicon Packets"}, - { 3, 0xc1, "Viasystems Group"}, - { 3, 0xc2, "Simtek"}, - // { 3, 0x43, "Semicon Devices Singapore"}, - // { 3, 0xc4, "Satron Handelsges"}, - // { 3, 0x45, "Improv Systems"}, - // { 3, 0x46, "INDUSYS"}, - // { 3, 0xc7, "Corrent"}, - // { 3, 0xc8, "Infrant Technologies"}, - // { 3, 0x49, "Ritek Corp"}, - // { 3, 0x4a, "empowerTel Networks"}, - // { 3, 0xcb, "Hypertec"}, - // { 3, 0x4c, "Cavium Networks"}, - { 3, 0xcd, "PLX Technology"}, - // { 3, 0xce, "Massana Design"}, - // { 3, 0x4f, "Intrinsity"}, - // { 3, 0xd0, "Valence Semiconductor"}, - // { 3, 0x51, "Terawave Communications"}, - // { 3, 0x52, "IceFyre Semiconductor"}, - // { 3, 0xd3, "Primarion"}, - // { 3, 0x54, "Picochip Designs"}, - // { 3, 0xd5, "Silverback Systems"}, - { 3, 0xd6, "Jade Star"}, - // { 3, 0x57, "Pijnenburg Securealink"}, - { 3, 0x58, "takeMS"}, - // { 3, 0xd9, "Cambridge Silicon Radio"}, - { 3, 0xda, "Swissbit"}, - // { 3, 0x5b, "Nazomi Communications"}, - // { 3, 0xdc, "eWave System"}, - // { 3, 0x5d, "Rockwell Collins"}, - // { 3, 0x5e, "Picocel (Paion)"}, - // { 3, 0xdf, "Alphamosaic"}, - // { 3, 0xe0, "Sandburst"}, - // { 3, 0x61, "SiCon Video"}, - // { 3, 0x62, "NanoAmp Solutions"}, - // { 3, 0xe3, "Ericsson Technology"}, - // { 3, 0x64, "PrairieComm"}, - { 3, 0xe5, "Mitac International"}, - // { 3, 0xe6, "Layer N Networks"}, - // { 3, 0x67, "MtekVision (Atsana)"}, - // { 3, 0x68, "Allegro Networks"}, - // { 3, 0xe9, "Marvell Semiconductors"}, - // { 3, 0xea, "Netergy Microelectronic"}, - { 3, 0x6b, "nVidia"}, - // { 3, 0xec, "Internet Machines"}, - // { 3, 0x6d, "Peak Electronics"}, - // { 3, 0x6e, "Litchfield Communication"}, - { 3, 0xef, "Accton"}, - // { 3, 0x70, "Teradiant Networks"}, - // { 3, 0xf1, "Scaleo Chip"}, - // { 3, 0xf2, "Cortina Systems"}, - { 3, 0x73, "RAM Components"}, - // { 3, 0xf4, "Raqia Networks"}, - // { 3, 0x75, "ClearSpeed"}, - // { 3, 0x76, "Matsushita Battery"}, - // { 3, 0xf7, "Xelerated"}, - // { 3, 0xf8, "SimpleTech"}, - { 3, 0x79, "Utron"}, - // { 3, 0x7a, "Astec International"}, - // { 3, 0xfb, "AVM"}, - // { 3, 0x7c, "Redux Communications"}, - // { 3, 0xfd, "Dot Hill Systems"}, - { 3, 0xfe, "TeraChip"}, - { 4, 0x01, "T-RAM"}, - // { 4, 0x02, "Innovics Wireless"}, - // { 4, 0x83, "Teknovus"}, - // { 4, 0x04, "KeyEye Communications"}, - // { 4, 0x85, "Runcom Technologies"}, - // { 4, 0x86, "RedSwitch"}, - // { 4, 0x07, "Dotcast"}, - { 4, 0x08, "Silicon Mountain Memory"}, - // { 4, 0x89, "Signia Technologies"}, - // { 4, 0x8a, "Pixim"}, - // { 4, 0x0b, "Galazar Networks"}, - // { 4, 0x8c, "White Electronic Designs"}, - // { 4, 0x0d, "Patriot Scientific"}, - // { 4, 0x0e, "Neoaxiom"}, - // { 4, 0x8f, "3Y Power Technology"}, - { 4, 0x10, "Scaleo Chip"}, - // { 4, 0x91, "Potentia Power Systems"}, - // { 4, 0x92, "C-guys"}, - // { 4, 0x13, "Digital Communications Technology"}, - // { 4, 0x94, "Silicon-Based Technology"}, - // { 4, 0x15, "Fulcrum Microsystems"}, - // { 4, 0x16, "Positivo Informatica"}, - // { 4, 0x97, "XIOtech"}, - // { 4, 0x98, "PortalPlayer"}, - // { 4, 0x19, "Zhiying Software"}, - // { 4, 0x1a, "ParkerVision"}, - // { 4, 0x9b, "Phonex Broadband"}, - // { 4, 0x1c, "Skyworks Solutions"}, - // { 4, 0x9d, "Entropic Communications"}, - // { 4, 0x9e, "Pacific Force Technology"}, - // { 4, 0x1f, "Zensys A/S"}, - // { 4, 0x20, "Legend Silicon Corp."}, - // { 4, 0xa1, "Sci-worx"}, - // { 4, 0xa2, "SMSC (Standard Microsystems)"}, - { 4, 0x23, "Renesas"}, - // { 4, 0xa4, "Raza Microelectronics"}, - // { 4, 0x25, "Phyworks"}, - // { 4, 0x26, "MediaTek"}, - // { 4, 0xa7, "Non-cents Productions"}, - // { 4, 0xa8, "US Modular"}, - // { 4, 0x29, "Wintegra"}, - // { 4, 0x2a, "Mathstar"}, - // { 4, 0xab, "StarCore"}, - // { 4, 0x2c, "Oplus Technologies"}, - // { 4, 0xad, "Mindspeed"}, - // { 4, 0xae, "Just Young Computer"}, - // { 4, 0x2f, "Radia Communications"}, - { 4, 0xb0, "OCZ"}, - // { 4, 0x31, "Emuzed"}, - // { 4, 0x32, "LOGIC Devices"}, - // { 4, 0xb3, "Inphi"}, - // { 4, 0x34, "Quake Technologies"}, - // { 4, 0xb5, "Vixel"}, - // { 4, 0xb6, "SolusTek"}, - // { 4, 0x37, "Kongsberg Maritime"}, - // { 4, 0x38, "Faraday Technology"}, - { 4, 0xb9, "Altium"}, - // { 4, 0xba, "Insyte"}, - { 4, 0x3b, "ARM"}, - // { 4, 0xbc, "DigiVision"}, - // { 4, 0x3d, "Vativ Technologies"}, - // { 4, 0x3e, "Endicott Interconnect Technologies"}, - { 4, 0xbf, "Pericom"}, - // { 4, 0x40, "Bandspeed"}, - // { 4, 0xc1, "LeWiz Communications"}, - // { 4, 0xc2, "CPU Technology"}, - { 4, 0x43, "Ramaxel"}, - // { 4, 0xc4, "DSP Group"}, - // { 4, 0x45, "Axis Communications"}, - { 4, 0x46, "Legacy Electronics"}, - // { 4, 0xc7, "Chrontel"}, - // { 4, 0xc8, "Powerchip Semiconductor"}, - // { 4, 0x49, "MobilEye Technologies"}, - { 4, 0x4a, "Excel Semiconductor"}, - { 4, 0xcb, "A-DATA"}, - // { 4, 0x4c, "VirtualDigm"}, - { 4, 0xcd, "G.Skill"}, - // { 4, 0xce, "Quanta Computer"}, - // { 4, 0x4f, "Yield Microelectronics"}, - // { 4, 0xd0, "Afa Technologies"}, - { 4, 0x51, "Kingbox"}, - // { 4, 0x52, "Ceva"}, - // { 4, 0xd3, "iStor Networks"}, - // { 4, 0x54, "Advance Modules"}, - { 4, 0xd5, "Microsoft"}, - // { 4, 0xd6, "Open-Silicon"}, - // { 4, 0x57, "Goal Semiconductor"}, - // { 4, 0x58, "ARC International"}, - { 4, 0xd9, "Simmtec"}, - // { 4, 0xda, "Metanoia"}, - // { 4, 0x5b, "Key Stream"}, - // { 4, 0xdc, "Lowrance Electronics"}, - // { 4, 0x5d, "Adimos"}, - // { 4, 0x5e, "SiGe Semiconductor"}, - // { 4, 0xdf, "Fodus Communications"}, - // { 4, 0xe0, "Credence Systems Corp."}, - // { 4, 0x61, "Genesis Microchip"}, - // { 4, 0x62, "Vihana"}, - // { 4, 0xe3, "WIS Technologies"}, - // { 4, 0x64, "GateChange Technologies"}, - // { 4, 0xe5, "High Density Devices AS"}, - // { 4, 0xe6, "Synopsys"}, - // { 4, 0x67, "Gigaram"}, - // { 4, 0x68, "Enigma Semiconductor"}, - // { 4, 0xe9, "Century Micro"}, - // { 4, 0xea, "Icera Semiconductor"}, - // { 4, 0x6b, "Mediaworks Integrated Systems"}, - // { 4, 0xec, "O’Neil Product Development"}, - // { 4, 0x6d, "Supreme Top Technology"}, - // { 4, 0x6e, "MicroDisplay"}, - { 4, 0xef, "Team Group"}, - // { 4, 0x70, "Sinett"}, - { 4, 0xf1, "Toshiba"}, - // { 4, 0xf2, "Tensilica"}, - // { 4, 0x73, "SiRF Technology"}, - // { 4, 0xf4, "Bacoc"}, - // { 4, 0x75, "SMaL Camera Technologies"}, - { 4, 0x76, "Thomson SC"}, - // { 4, 0xf7, "Airgo Networks"}, - // { 4, 0xf8, "Wisair"}, - // { 4, 0x79, "SigmaTel"}, - // { 4, 0x7a, "Arkados"}, - // { 4, 0xfb, "Compete IT KG"}, - // { 4, 0x7c, "Eudar Technology"}, - // { 4, 0xfd, "Focus Enhancements"}, - // { 4, 0xfe, "Xyratex"}, - // { 5, 0x01, "Specular Networks"}, - { 5, 0x02, "Patriot Memory"}, - // { 5, 0x83, "U-Chip Technology Corp."}, - // { 5, 0x04, "Silicon Optix"}, - // { 5, 0x85, "Greenfield Networks"}, - { 5, 0x86, "CompuRAM"}, - // { 5, 0x07, "Stargen"}, - // { 5, 0x08, "NetCell"}, - // { 5, 0x89, "Excalibrus Technologies"}, - // { 5, 0x8a, "SCM Microsystems"}, - // { 5, 0x0b, "Xsigo Systems"}, - // { 5, 0x8c, "CHIPS & Systems"}, - // { 5, 0x0d, "Tier"}, - // { 5, 0x0e, "CWRL Labs"}, - // { 5, 0x8f, "Teradici"}, - // { 5, 0x10, "Gigaram"}, - // { 5, 0x91, "g2 Microsystems"}, - // { 5, 0x92, "PowerFlash Semiconductor"}, - // { 5, 0x13, "P.A. Semi"}, - { 5, 0x94, "NovaTech"}, - // { 5, 0x15, "c2 Microsystems"}, - // { 5, 0x16, "Level5 Networks"}, - { 5, 0x97, "COS Memory"}, - // { 5, 0x98, "Innovasic Semiconductor"}, - // { 5, 0x19, "02IC"}, - // { 5, 0x1a, "Tabula"}, - { 5, 0x9b, "Crucial"}, - // { 5, 0x1c, "Chelsio Communications"}, - // { 5, 0x9d, "Solarflare Communications"}, - // { 5, 0x9e, "Xambala"}, - // { 5, 0x1f, "EADS Astrium"}, - // { 5, 0x20, "Terra Semiconductor"}, - // { 5, 0xa1, "Imaging Works"}, - // { 5, 0xa2, "Astute Networks"}, - // { 5, 0x23, "Tzero"}, - // { 5, 0xa4, "Emulex"}, - // { 5, 0x25, "Power-One"}, - // { 5, 0x26, "Pulse~LINK"}, - // { 5, 0xa7, "Hon Hai Precision Industry"}, - // { 5, 0xa8, "White Rock Networks"}, - // { 5, 0x29, "Telegent Systems USA"}, - // { 5, 0x2a, "Atrua Technologies"}, - // { 5, 0xab, "Acbel Polytech"}, - // { 5, 0x2c, "eRide"}, - { 5, 0xad, "ULi"}, - // { 5, 0xae, "Magnum Semiconductor"}, - // { 5, 0x2f, "neoOne Technology"}, - // { 5, 0xb0, "Connex Technology"}, - // { 5, 0x31, "Stream Processors"}, - // { 5, 0x32, "Focus Enhancements"}, - // { 5, 0xb3, "Telecis Wireless"}, - // { 5, 0x34, "uNav Microelectronics"}, - // { 5, 0xb5, "Tarari"}, - // { 5, 0xb6, "Ambric"}, - // { 5, 0x37, "Newport Media"}, - // { 5, 0x38, "VMTS"}, - // { 5, 0xb9, "Enuclia Semiconductor"}, - // { 5, 0xba, "Virtium Technology"}, - // { 5, 0x3b, "Solid State System"}, - // { 5, 0xbc, "Kian Tech LLC"}, - // { 5, 0x3d, "Artimi"}, - { 5, 0x3e, "PQI"}, - // { 5, 0xbf, "Avago Technologies"}, - // { 5, 0x40, "ADTechnology"}, - { 5, 0xc1, "Sigma Designs"}, - // { 5, 0xc2, "SiCortex"}, - // { 5, 0x43, "Ventura Technology Group"}, - // { 5, 0xc4, "eASIC"}, - // { 5, 0x45, "M.H.S. SAS"}, - { 5, 0x46, "MSI"}, - // { 5, 0xc7, "Rapport"}, - // { 5, 0xc8, "Makway International"}, - // { 5, 0x49, "Broad Reach Engineering"}, - // { 5, 0x4a, "Semiconductor Mfg Intl Corp"}, - // { 5, 0xcb, "SiConnect"}, - // { 5, 0x4c, "FCI USA"}, - // { 5, 0xcd, "Validity Sensors"}, - // { 5, 0xce, "Coney Technology"}, - // { 5, 0x4f, "Spans Logic"}, - // { 5, 0xd0, "Neterion"}, - { 5, 0x51, "Qimonda"}, - // { 5, 0x52, "New Japan Radio"}, - // { 5, 0xd3, "Velogix"}, - // { 5, 0x54, "Montalvo Systems"}, - // { 5, 0xd5, "iVivity"}, - { 5, 0xd6, "Walton Chaintech"}, - { 5, 0x57, "AENEON"}, - // { 5, 0x58, "Lorom Industrial"}, - // { 5, 0xd9, "Radiospire Networks"}, - // { 5, 0xda, "Sensio Technologies"}, - // { 5, 0x5b, "Nethra Imaging"}, - { 5, 0xdc, "Hexon"}, - // { 5, 0x5d, "CompuStocx (CSX)"}, - // { 5, 0x5e, "Methode Electronics"}, - // { 5, 0xdf, "Connect One"}, - // { 5, 0xe0, "Opulan Technologies"}, - // { 5, 0x61, "Septentrio NV"}, - { 5, 0x62, "Goldenmars"}, - { 5, 0xe3, "Kreton"}, - // { 5, 0x64, "Cochlear"}, - // { 5, 0xe5, "Altair Semiconductor"}, - // { 5, 0xe6, "NetEffect"}, - // { 5, 0x67, "Spansion"}, - // { 5, 0x68, "Taiwan Semiconductor Mfg"}, - // { 5, 0xe9, "Emphany Systems"}, - // { 5, 0xea, "ApaceWave Technologies"}, - // { 5, 0x6b, "Mobilygen"}, - // { 5, 0xec, "Tego"}, - // { 5, 0x6d, "Cswitch"}, - // { 5, 0x6e, "Haier (Beijing) IC Design"}, - // { 5, 0xef, "MetaRAM"}, - // { 5, 0x70, "Axel Electronics"}, - // { 5, 0xf1, "Tilera"}, - // { 5, 0xf2, "Aquantia"}, - // { 5, 0x73, "Vivace Semiconductor"}, - // { 5, 0xf4, "Redpine Signals"}, - // { 5, 0x75, "Octalica"}, - // { 5, 0x76, "InterDigital Communications"}, - { 5, 0xf7, "Avant Technology"}, - { 5, 0xf8, "Asrock"}, - // { 5, 0x79, "Availink"}, - // { 5, 0x7a, "Quartics"}, - // { 5, 0xfb, "Element CXI"}, - // { 5, 0x7c, "Innovaciones Microelectronicas"}, - // { 5, 0xfd, "VeriSilicon Microelectronics"}, - // { 5, 0xfe, "W5 Networks"}, - // { 6, 0x01, "MOVEKING"}, - // { 6, 0x02, "Mavrix Technology"}, - // { 6, 0x83, "CellGuide"}, - // { 6, 0x04, "Faraday Technology"}, - // { 6, 0x85, "Diablo Technologies"}, - // { 6, 0x86, "Jennic"}, - // { 6, 0x07, "Octasic"}, - { 6, 0x08, "Molex"}, - // { 6, 0x89, "3Leaf Networks"}, - // { 6, 0x8a, "Bright Micron Technology"}, - // { 6, 0x0b, "Netxen"}, - // { 6, 0x8c, "NextWave Broadband"}, - // { 6, 0x0d, "DisplayLink"}, - // { 6, 0x0e, "ZMOS Technology"}, - // { 6, 0x8f, "Tec-Hill"}, - // { 6, 0x10, "Multigig"}, - // { 6, 0x91, "Amimon"}, - // { 6, 0x92, "Euphonic Technologies"}, - // { 6, 0x13, "BRN Phoenix"}, - // { 6, 0x94, "InSilica"}, - // { 6, 0x15, "Ember"}, - { 6, 0x16, "Avexir"}, - // { 6, 0x97, "Echelon"}, - // { 6, 0x98, "Edgewater Computer Systems"}, - // { 6, 0x19, "XMOS Semiconductor"}, - // { 6, 0x1a, "GENUSION"}, - { 6, 0x9b, "Memory Corp NV"}, - // { 6, 0x1c, "SiliconBlue Technologies"}, - // { 6, 0x9d, "Rambus"}, - // { 6, 0x9e, "Andes Technology"}, - // { 6, 0x1f, "Coronis Systems"}, - // { 6, 0x20, "Achronix Semiconductor"}, - // { 6, 0xa1, "Siano Mobile Silicon"}, - // { 6, 0xa2, "Semtech"}, - // { 6, 0x23, "Pixelworks"}, - // { 6, 0xa4, "Gaisler Research AB"}, - // { 6, 0x25, "Teranetics"}, - // { 6, 0x26, "Toppan Printing"}, - // { 6, 0xa7, "Kingxcon"}, - { 6, 0xa8, "SiS"}, - // { 6, 0x29, "I-O Data Device"}, - // { 6, 0x2a, "NDS Americas"}, - // { 6, 0xab, "Solomon Systech Limited"}, - // { 6, 0x2c, "On Demand Microelectronics"}, - // { 6, 0xad, "Amicus Wireless"}, - // { 6, 0xae, "SMARDTV SNC"}, - // { 6, 0x2f, "Comsys Communication"}, - // { 6, 0xb0, "Movidia"}, - // { 6, 0x31, "Javad GNSS"}, - // { 6, 0x32, "Montage Technology Group"}, - { 6, 0xb3, "Trident"}, - { 6, 0x34, "Super Talent"}, - // { 6, 0xb5, "Optichron"}, - // { 6, 0xb6, "Future Waves UK"}, - // { 6, 0x37, "SiBEAM"}, - // { 6, 0x38, "Inicore,"}, - // { 6, 0xb9, "Virident Systems"}, - // { 6, 0xba, "M2000"}, - // { 6, 0x3b, "ZeroG Wireless"}, - { 6, 0xbc, "Gingle"}, - // { 6, 0x3d, "Space Micro"}, - // { 6, 0x3e, "Wilocity"}, - // { 6, 0xbf, "Novafora, Ic."}, - // { 6, 0x40, "iKoa"}, - { 6, 0xc1, "ASint"}, - { 6, 0xc2, "Ramtron"}, - // { 6, 0x43, "Plato Networks"}, - // { 6, 0xc4, "IPtronics AS"}, - // { 6, 0x45, "Infinite-Memories"}, - // { 6, 0x46, "Parade Technologies"}, - // { 6, 0xc7, "Dune Networks"}, - // { 6, 0xc8, "GigaDevice Semiconductor"}, - // { 6, 0x49, "Modu"}, - // { 6, 0x4a, "CEITEC"}, - // { 6, 0xcb, "Northrop Grumman"}, - // { 6, 0x4c, "XRONET"}, - // { 6, 0xcd, "Sicon Semiconductor AB"}, - // { 6, 0xce, "Atla Electronics"}, - { 6, 0x4f, "TOPRAM"}, - // { 6, 0xd0, "Silego Technology"}, - { 6, 0x51, "Kinglife"}, - // { 6, 0x52, "Ability Industries"}, - // { 6, 0xd3, "Silicon Power Computer & Communications"}, - // { 6, 0x54, "Augusta Technology"}, - // { 6, 0xd5, "Nantronics Semiconductors"}, - // { 6, 0xd6, "Hilscher Gesellschaft"}, - // { 6, 0x57, "Quixant"}, - // { 6, 0x58, "Percello"}, - // { 6, 0xd9, "NextIO"}, - // { 6, 0xda, "Scanimetrics"}, - // { 6, 0x5b, "FS-Semi Company"}, - // { 6, 0xdc, "Infinera"}, - { 6, 0x5d, "SandForce"}, - { 6, 0x5e, "Lexar Media"}, - // { 6, 0xdf, "Teradyne"}, - { 6, 0xe0, "Memory Exchange Corp."}, - // { 6, 0x61, "Suzhou Smartek Electronics"}, - { 6, 0x62, "Avantium"}, - // { 6, 0xe3, "ATP Electronics"}, - // { 6, 0x64, "Valens Semiconductor"}, - // { 6, 0xe5, "Agate Logic"}, - // { 6, 0xe6, "Netronome"}, - // { 6, 0x67, "Zenverge"}, - // { 6, 0x68, "N-trig"}, - // { 6, 0xe9, "SanMax Technologies"}, - // { 6, 0xea, "Contour Semiconductor"}, - { 6, 0x6b, "TwinMOS"}, - { 6, 0xec, "Silicon Systems"}, - // { 6, 0x6d, "V-Color Technology"}, - // { 6, 0x6e, "Certicom"}, - // { 6, 0xef, "JSC ICC Milandr"}, - // { 6, 0x70, "PhotoFast Global"}, - { 6, 0xf1, "InnoDisk"}, - { 6, 0xf2, "Muscle Power"}, - // { 6, 0x73, "Energy Micro"}, - // { 6, 0xf4, "Innofidei"}, - // { 6, 0x75, "CopperGate Communications"}, - // { 6, 0x76, "Holtek Semiconductor"}, - // { 6, 0xf7, "Myson Century"}, - // { 6, 0xf8, "FIDELIX"}, - // { 6, 0x79, "Red Digital Cinema"}, - // { 6, 0x7a, "Densbits Technology"}, - // { 6, 0xfb, "Zempro"}, - // { 6, 0x7c, "MoSys"}, - // { 6, 0xfd, "Provigent"}, - // { 6, 0xfe, "Triad Semiconductor"}, - // { 8, 0x01, "Siklu Communication"}, - // { 8, 0x02, "A Force Manufacturing"}, - { 8, 0x83, "Strontium"}, - // { 8, 0x04, "Abilis Systems"}, - // { 8, 0x85, "Siglead"}, - // { 8, 0x86, "Ubicom"}, - // { 8, 0x07, "Unifosa"}, - // { 8, 0x08, "Stretch"}, - // { 8, 0x89, "Lantiq Deutschland"}, - // { 8, 0x8a, "Visipro."}, - { 8, 0x0b, "EKMemory"}, - // { 8, 0x8c, "Microelectronics Institute ZTE"}, - // { 8, 0x0d, "Cognovo"}, - // { 8, 0x0e, "Carry Technology"}, - { 8, 0x8f, "Nokia"}, - { 8, 0x10, "King Tiger"}, - // { 8, 0x91, "Sierra Wireless"}, - { 8, 0x92, "HT Micron"}, - { 8, 0x13, "Albatron"}, - // { 8, 0x94, "Leica Geosystems AG"}, - // { 8, 0x15, "BroadLight"}, - // { 8, 0x16, "AEXEA"}, - // { 8, 0x97, "ClariPhy Communications"}, - // { 8, 0x98, "Green Plug"}, - // { 8, 0x19, "Design Art Networks"}, - // { 8, 0x1a, "Mach Xtreme Technology"}, - // { 8, 0x9b, "ATO Solutions"}, - // { 8, 0x1c, "Ramsta"}, - // { 8, 0x9d, "Greenliant Systems"}, - // { 8, 0x9e, "Teikon"}, - // { 8, 0x1f, "Antec Hadron"}, - // { 8, 0x20, "NavCom Technology"}, - // { 8, 0xa1, "Shanghai Fudan Microelectronics"}, - // { 8, 0xa2, "Calxeda"}, - // { 8, 0x23, "JSC EDC Electronics"}, - // { 8, 0xa4, "Kandit Technology"}, - // { 8, 0x25, "Ramos Technology"}, - // { 8, 0x26, "Goldenmars Technology"}, - // { 8, 0xa7, "XeL Technology"}, - // { 8, 0xa8, "Newzone"}, - { 8, 0x29, "MercyPower"}, - // { 8, 0x2a, "Nanjing Yihuo Technology."}, - // { 8, 0xab, "Nethra Imaging"}, - // { 8, 0x2c, "SiTel Semiconductor BV"}, - // { 8, 0xad, "SolidGear"}, - { 8, 0xae, "Topower"}, - // { 8, 0x2f, "Wilocity"}, - // { 8, 0xb0, "Profichip"}, - // { 8, 0x31, "Gerad Technologies"}, - { 8, 0x32, "Ritek"}, - // { 8, 0xb3, "Gomos Technology Limited"}, - { 8, 0x34, "Memoright"}, - // { 8, 0xb5, "D-Broad"}, - // { 8, 0xb6, "HiSilicon Technologies"}, - // { 8, 0x37, "Syndiant ."}, - // { 8, 0x38, "Enverv"}, - // { 8, 0xb9, "Cognex"}, - // { 8, 0xba, "Xinnova Technology"}, - { 8, 0x3b, "Ultron"}, - // { 8, 0xbc, "Concord Idea"}, - // { 8, 0x3d, "AIM"}, - // { 8, 0x3e, "Lifetime Memory Products"}, - // { 8, 0xbf, "Ramsway"}, - // { 8, 0x40, "Recore Systems B.V."}, - // { 8, 0xc1, "Haotian Jinshibo Science Tech"}, - // { 8, 0xc2, "Being Advanced Memory"}, - // { 8, 0x43, "Adesto Technologies"}, - // { 8, 0xc4, "Giantec Semiconductor"}, - // { 8, 0x45, "HMD Electronics AG"}, - // { 8, 0x46, "Gloway International (HK)"}, - // { 8, 0xc7, "Kingcore"}, - // { 8, 0xc8, "Anucell Technology Holding"}, - // { 8, 0x49, "Accord Software & Systems Pvt."}, - // { 8, 0x4a, "Active-Semi"}, - // { 8, 0xcb, "Denso"}, - // { 8, 0x4c, "TLSI"}, - // { 8, 0xcd, "Shenzhen Daling Electronic"}, - // { 8, 0xce, "Mustang"}, - // { 8, 0x4f, "Orca Systems"}, - // { 8, 0xd0, "Passif Semiconductor"}, - // { 8, 0x51, "GigaDevice Semiconductor (Beijing)"}, - // { 8, 0x52, "Memphis Electronic"}, - // { 8, 0xd3, "Beckhoff Automation"}, - // { 8, 0x54, "Harmony Semiconductor Corp"}, - // { 8, 0xd5, "Air Computers SRL"}, - { 8, 0xd6, "TMT Memory"}, - { 9, 0xff, ""} - }; diff --git a/memtest86+_old/lib.c b/memtest86+_old/lib.c deleted file mode 100644 index 64da2b7..0000000 --- a/memtest86+_old/lib.c +++ /dev/null @@ -1,1199 +0,0 @@ -/* lib.c - MemTest-86 Version 3.4 - * - * Released under version 2 of the Gnu Public License. - * By Chris Brady - */ -#include "io.h" -#include "serial.h" -#include "test.h" -#include "config.h" -#include "screen_buffer.h" -#include "stdint.h" -#include "cpuid.h" -#include "smp.h" - - -int slock = 0, lsr = 0; -short serial_cons = SERIAL_CONSOLE_DEFAULT; -#if SERIAL_TTY != 0 && SERIAL_TTY != 1 -#error Bad SERIAL_TTY. Only ttyS0 and ttyS1 are supported. -#endif -short serial_tty = SERIAL_TTY; -const short serial_base_ports[] = {0x3f8, 0x2f8}; - -#if ((115200%SERIAL_BAUD_RATE) != 0) -#error Bad default baud rate -#endif -int serial_baud_rate = SERIAL_BAUD_RATE; -unsigned char serial_parity = 0; -unsigned char serial_bits = 8; - -struct ascii_map_str { - int ascii; - int keycode; -}; - -void reboot(void) -{ - - /* tell the BIOS to do a cold start */ - *((unsigned short *)0x472) = 0x0; - - while(1) - { - outb(0xFE, 0x64); - outb(0x02, 0xcf9); /* reset that doesn't rely on the keyboard controller */ - outb(0x04, 0xcf9); - outb(0x0E, 0xcf9); - } -} - -int mt86_strlen(char * string){ - int i=0; - while(*string++){i++;}; - return i; -} - -int mt86_strstr(char *haystack, char * needle) -{ - int i=0,j=0; - int here=0; - while(1){ - if(needle[i]==haystack[j]) - { - if(here==0) - here=j; - i++;j++; - if(i>=mt86_strlen(needle)) - { - return here; - } - if(j>=mt86_strlen(haystack)) - { - return -1; - } - } else { - j++;i=0;here=0; - } - } -} - -int mt86_memcmp(const void *s1, const void *s2, ulong count) -{ - const unsigned char *src1 = s1, *src2 = s2; - int i; - for(i = 0; i < count; i++) { - if (src1[i] != src2[i]) { - return (int)src1[i] - (int)src2[i]; - } - } - return 0; -} - -int mt86_strncmp(const char *s1, const char *s2, ulong n) { - signed char res = 0; - while (n) { - res = *s1 - *s2; - if (res != 0) - return res; - if (*s1 == '\0') - return 0; - ++s1, ++s2; - --n; - } - return res; -} - -void *mt86_memmove(void *dest, const void *src, ulong n) -{ - long i; - char *d = (char *)dest, *s = (char *)src; - - /* If src == dest do nothing */ - if (dest < src) { - for(i = 0; i < n; i++) { - d[i] = s[i]; - } - } - else if (dest > src) { - for(i = n -1; i >= 0; i--) { - d[i] = s[i]; - } - } - return dest; -} - -char toupper(char c) -{ - if (c >= 'a' && c <= 'z') - return c + 'A' -'a'; - else - return c; -} - -int mt86_isdigit(char c) -{ - return c >= '0' && c <= '9'; -} - -int isxdigit(char c) -{ - return mt86_isdigit(c) || (toupper(c) >= 'A' && toupper(c) <= 'F'); } - -unsigned long simple_strtoul(const char *cp, char **endp, unsigned int base) { - unsigned long result = 0, value; - - if (!base) { - base = 10; - if (*cp == '0') { - base = 8; - cp++; - if (toupper(*cp) == 'X' && isxdigit(cp[1])) { - cp++; - base = 16; - } - } - } else if (base == 16) { - if (cp[0] == '0' && toupper(cp[1]) == 'X') - cp += 2; - } - while (isxdigit(*cp) && - (value = mt86_isdigit(*cp) ? *cp-'0' : toupper(*cp)-'A'+10) < base) { - result = result*base + value; - cp++; - } - if (endp) - *endp = (char *)cp; - return result; -} - -/* - * Scroll the error message area of the screen as needed - * Starts at line LINE_SCROLL and ends at line 23 - */ -void scroll(void) -{ - int i, j; - char *s, tmp; - - /* Only scroll if at the bottom of the screen */ - if (vv->msg_line < 23) { - vv->msg_line++; - } else { - /* If scroll lock is on, loop till it is cleared */ - while (slock) { - check_input(); - } - for (i=LINE_SCROLL; i<23; i++) { - s = (char *)(SCREEN_ADR + ((i+1) * 160)); - for (j=0; j<160; j+=2, s+=2) { - *(s-160) = *s; - tmp = get_scrn_buf(i+1, j/2); - set_scrn_buf(i, j/2, tmp); - } - } - /* Clear the newly opened line */ - s = (char *)(SCREEN_ADR + (23 * 160)); - for (j=0; j<80; j++) { - *s = ' '; - set_scrn_buf(23, j, ' '); - s += 2; - } - tty_print_region(LINE_SCROLL, 0, 23, 79); - } -} - -/* - * Clear scroll region - */ -void clear_scroll(void) -{ - int i; - char *s; - - s = (char*)(SCREEN_ADR+LINE_HEADER*160); - for(i=0; i<80*(24-LINE_HEADER); i++) { - *s++ = ' '; - *s++ = 0x17; - } -} - -/* - * Place a single character on screen - */ -void cplace(int y, int x, const char c) -{ - char *dptr; - - dptr = (char *)(SCREEN_ADR + (160*y) + (2*x)); - *dptr = c; -} - -/* - * Print characters on screen - */ -void cprint(int y, int x, const char *text) -{ - register int i; - char *dptr; - - dptr = (char *)(SCREEN_ADR + (160*y) + (2*x)); - for (i=0; text[i]; i++) { - *dptr = text[i]; - dptr += 2; - } - tty_print_line(y, x, text); -} - -void itoa(char s[], int n) -{ - int i, sign; - - if((sign = n) < 0) - n = -n; - i=0; - do { - s[i++] = n % 10 + '0'; - } while ((n /= 10) > 0); - if(sign < 0) - s[i++] = '-'; - s[i] = '\0'; - reverse(s); -} - -void reverse(char s[]) -{ - int c, i, j; - for(j = 0; s[j] != 0; j++) - ; - - for(i=0, j = j - 1; i < j; i++, j--) { - c = s[i]; - s[i] = s[j]; - s[j] = c; - } -} -void memcpy (void *dst, void *src, int len) -{ - char *s = (char*)src; - char *d = (char*)dst; - int i; - - if (len <= 0) { - return; - } - for (i = 0 ; i < len; i++) { - *d++ = *s++; - } -} - -/* - * Print a people friendly address - */ -void aprint(int y, int x, ulong page) -{ - /* page is in multiples of 4K */ - if ((page << 2) < 9999) { - dprint(y, x, page << 2, 4, 0); - cprint(y, x+4, "K"); - } - else if ((page >>8) < 9999) { - dprint(y, x, (page + (1 << 7)) >> 8, 4, 0); - cprint(y, x+4, "M"); - } - else if ((page >>18) < 9999) { - dprint(y, x, (page + (1 << 17)) >> 18, 4, 0); - cprint(y, x+4, "G"); - } - else { - dprint(y, x, (page + (1 << 27)) >> 28, 4, 0); - cprint(y, x+4, "T"); - } -} - -/* - * Print a decimal number on screen - */ -void dprint(int y, int x, ulong val, int len, int right) -{ - ulong j, k; - int i, flag=0; - char buf[18]; - - if (val > 999999999 || len > 9) { - return; - } - for(i=0, j=1; i0; j/=10) { - k = val/j; - if (k > 9) { - j *= 100; - continue; - } - if (flag || k || j == 1) { - buf[i++] = k + '0'; - flag++; - } else { - buf[i++] = ' '; - } - val -= k * j; - } - } else { - for(i=0; i 9) { - j *= 100; - len++; - continue; - } - if (k == 0 && flag == 0) { - continue; - } - buf[i++] = k + '0'; - val -= k * j; - } else { - if (flag == 0 && i < len-1) { - buf[i++] = '0'; - } else { - buf[i++] = ' '; - } - } - flag++; - } - } - buf[i] = 0; - cprint(y,x,buf); -} - -/* - * Print a hex number on screen at least digits long - */ -void hprint2(int y,int x, unsigned long val, int digits) -{ - unsigned long j; - int i, idx, flag = 0; - char buf[18]; - - for (i=0, idx=0; i<8; i++) { - j = val >> (28 - (4 * i)); - j &= 0xf; - if (j < 10) { - if (flag || j || i == 7) { - buf[idx++] = j + '0'; - flag++; - } else { - buf[idx++] = '0'; - } - } else { - buf[idx++] = j + 'a' - 10; - flag++; - } - } - if (digits > 8) { - digits = 8; - } - if (flag > digits) { - digits = flag; - } - buf[idx] = 0; - cprint(y,x,buf + (idx - digits)); -} - -/* - * Print a hex number on screen exactly digits long - */ -void hprint3(int y,int x, unsigned long val, int digits) -{ - unsigned long j; - int i, idx, flag = 0; - char buf[18]; - - for (i=0, idx=0; i> 20; - dprint(y, x, j, 4, 0); - cprint(y, x+4, "m"); - j = (val & 0xffc00) >> 10; - dprint(y, x+5, j, 4, 0); - cprint(y, x+9, "k"); - j = val & 0x3ff; - dprint(y, x+10, j, 4, 0); -} - -char *codes[] = { - " Divide", - " Debug", - " NMI", - " Brkpnt", - "Overflow", - " Bound", - " Inv_Op", - " No_Math", - "Double_Fault", - "Seg_Over", - " Inv_TSS", - " Seg_NP", - "Stack_Fault", - "Gen_Prot", - "Page_Fault", - " Resvd", - " FPE", - "Alignment", - " Mch_Chk", - "SIMD FPE" -}; - -struct eregs { - ulong ss; - ulong ds; - ulong esp; - ulong ebp; - ulong esi; - ulong edi; - ulong edx; - ulong ecx; - ulong ebx; - ulong eax; - ulong vect; - ulong code; - ulong eip; - ulong cs; - ulong eflag; -}; - -/* Handle an interrupt */ -void inter(struct eregs *trap_regs) -{ - int i, line; - unsigned char *pp; - ulong address = 0; - int my_cpu_num = smp_my_cpu_num(); - - /* Get the page fault address */ - if (trap_regs->vect == 14) { - __asm__("movl %%cr2,%0":"=r" (address)); - } -#ifdef PARITY_MEM - - /* Check for a parity error */ - if (trap_regs->vect == 2) { - parity_err(trap_regs->edi, trap_regs->esi); - return; - } -#endif - - /* clear scrolling region */ - pp=(unsigned char *)(SCREEN_ADR+(2*80*(LINE_SCROLL-2))); - for(i=0; i<2*80*(24-LINE_SCROLL-2); i++, pp+=2) { - *pp = ' '; - } - line = LINE_SCROLL-2; - - cprint(line, 0, "Unexpected Interrupt - Halting CPU"); - dprint(line, COL_MID + 4, my_cpu_num, 2, 1); - cprint(line+2, 0, " Type: "); - if (trap_regs->vect <= 19) { - cprint(line+2, 7, codes[trap_regs->vect]); - } else { - hprint(line+2, 7, trap_regs->vect); - } - cprint(line+3, 0, " PC: "); - hprint(line+3, 7, trap_regs->eip); - cprint(line+4, 0, " CS: "); - hprint(line+4, 7, trap_regs->cs); - cprint(line+5, 0, "Eflag: "); - hprint(line+5, 7, trap_regs->eflag); - cprint(line+6, 0, " Code: "); - hprint(line+6, 7, trap_regs->code); - cprint(line+7, 0, " DS: "); - hprint(line+7, 7, trap_regs->ds); - cprint(line+8, 0, " SS: "); - hprint(line+8, 7, trap_regs->ss); - if (trap_regs->vect == 14) { - /* Page fault address */ - cprint(line+7, 0, " Addr: "); - hprint(line+7, 7, address); - } - - cprint(line+2, 20, "eax: "); - hprint(line+2, 25, trap_regs->eax); - cprint(line+3, 20, "ebx: "); - hprint(line+3, 25, trap_regs->ebx); - cprint(line+4, 20, "ecx: "); - hprint(line+4, 25, trap_regs->ecx); - cprint(line+5, 20, "edx: "); - hprint(line+5, 25, trap_regs->edx); - cprint(line+6, 20, "edi: "); - hprint(line+6, 25, trap_regs->edi); - cprint(line+7, 20, "esi: "); - hprint(line+7, 25, trap_regs->esi); - cprint(line+8, 20, "ebp: "); - hprint(line+8, 25, trap_regs->ebp); - cprint(line+9, 20, "esp: "); - hprint(line+9, 25, trap_regs->esp); - - cprint(line+1, 38, "Stack:"); - for (i=0; i<10; i++) { - hprint(line+2+i, 38, trap_regs->esp+(4*i)); - hprint(line+2+i, 47, *(ulong*)(trap_regs->esp+(4*i))); - hprint(line+2+i, 57, trap_regs->esp+(4*(i+10))); - hprint(line+2+i, 66, *(ulong*)(trap_regs->esp+(4*(i+10)))); - } - - cprint(line+11, 0, "CS:EIP: "); - pp = (unsigned char *)trap_regs->eip; - for(i = 0; i < 9; i++) { - hprint2(line+11, 8+(3*i), pp[i], 2); - } - - while(1) { - check_input(); - } -} - -void set_cache(int val) -{ - switch(val) { - case 0: - cache_off(); - break; - case 1: - cache_on(); - break; - } -} - -int get_key() { - int c; - - c = inb(0x64); - if ((c & 1) == 0) { - if (serial_cons) { - int comstat; - comstat = serial_echo_inb(UART_LSR); - if (comstat & UART_LSR_DR) { - c = serial_echo_inb(UART_RX); - /* Pressing '.' has same effect as 'c' - on a keyboard. - Oct 056 Dec 46 Hex 2E Ascii . - */ - return (ascii_to_keycode(c)); - } - } - return(0); - } - c = inb(0x60); - return((c)); -} - -void check_input(void) -{ - unsigned char c; - - if ((c = get_key())) { - switch(c & 0x7f) { - case 1: - /* "ESC" key was pressed, bail out. */ - cprint(LINE_RANGE, COL_MID+23, "Halting... "); - reboot(); - break; - case 46: - /* c - Configure */ - get_config(); - break; - case 28: - /* CR - clear scroll lock */ - slock = 0; - footer(); - break; - case 57: - /* SP - set scroll lock */ - slock = 1; - footer(); - break; - case 0x26: - /* ^L/L - redraw the display */ - tty_print_screen(); - break; - } - } -} - -void footer() -{ - cprint(24, 0, "(ESC)exit (c)configuration (SP)scroll_lock (CR)scroll_unlock"); - if (slock) { - cprint(24, 74, "Locked"); - } else { - cprint(24, 74, " "); - } -} - -ulong getval(int x, int y, int result_shift) -{ - unsigned long val; - int done; - int c; - int i, n; - int base; - int shift; - char buf[16]; - - for(i = 0; i < sizeof(buf)/sizeof(buf[0]); i++ ) { - buf[i] = ' '; - } - buf[sizeof(buf)/sizeof(buf[0]) -1] = '\0'; - - wait_keyup(); - done = 0; - n = 0; - base = 10; - while(!done) { - /* Read a new character and process it */ - c = get_key(); - switch(c) { - case 0x26: /* ^L/L - redraw the display */ - tty_print_screen(); - break; - case 0x1c: /* CR */ - /* If something has been entered we are done */ - if(n) done = 1; - break; - case 0x19: /* p */ buf[n] = 'p'; break; - case 0x22: /* g */ buf[n] = 'g'; break; - case 0x32: /* m */ buf[n] = 'm'; break; - case 0x25: /* k */ buf[n] = 'k'; break; - case 0x2d: /* x */ - /* Only allow 'x' after an initial 0 */ - if (n == 1 && (buf[0] == '0')) { - buf[n] = 'x'; - } - break; - case 0x0e: /* BS */ - if (n > 0) { - n -= 1; - buf[n] = ' '; - } - break; - /* Don't allow entering a number not in our current base */ - case 0x0B: if (base >= 1) buf[n] = '0'; break; - case 0x02: if (base >= 2) buf[n] = '1'; break; - case 0x03: if (base >= 3) buf[n] = '2'; break; - case 0x04: if (base >= 4) buf[n] = '3'; break; - case 0x05: if (base >= 5) buf[n] = '4'; break; - case 0x06: if (base >= 6) buf[n] = '5'; break; - case 0x07: if (base >= 7) buf[n] = '6'; break; - case 0x08: if (base >= 8) buf[n] = '7'; break; - case 0x09: if (base >= 9) buf[n] = '8'; break; - case 0x0A: if (base >= 10) buf[n] = '9'; break; - case 0x1e: if (base >= 11) buf[n] = 'a'; break; - case 0x30: if (base >= 12) buf[n] = 'b'; break; - case 0x2e: if (base >= 13) buf[n] = 'c'; break; - case 0x20: if (base >= 14) buf[n] = 'd'; break; - case 0x12: if (base >= 15) buf[n] = 'e'; break; - case 0x21: if (base >= 16) buf[n] = 'f'; break; - default: - break; - } - /* Don't allow anything to be entered after a suffix */ - if (n > 0 && ( - (buf[n-1] == 'p') || (buf[n-1] == 'g') || - (buf[n-1] == 'm') || (buf[n-1] == 'k'))) { - buf[n] = ' '; - } - /* If we have entered a character increment n */ - if (buf[n] != ' ') { - n++; - } - buf[n] = ' '; - /* Print the current number */ - cprint(x, y, buf); - - /* Find the base we are entering numbers in */ - base = 10; - if ((buf[0] == '0') && (buf[1] == 'x')) { - base = 16; - } - else if (buf[0] == '0') { - base = 8; - } - } - /* Compute our current shift */ - shift = 0; - switch(buf[n-1]) { - case 'g': /* gig */ shift = 30; break; - case 'm': /* meg */ shift = 20; break; - case 'p': /* page */ shift = 12; break; - case 'k': /* kilo */ shift = 10; break; - } - shift -= result_shift; - - /* Compute our current value */ - val = simple_strtoul(buf, 0, base); - if (shift > 0) { - if (shift >= 32) { - val = 0xffffffff; - } else { - val <<= shift; - } - } else { - if (-shift >= 32) { - val = 0; - } - else { - val >>= -shift; - } - } - return val; -} - -void ttyprint(int y, int x, const char *p) -{ - static char sx[3]; - static char sy[3]; - - sx[0]='\0'; - sy[0]='\0'; - x++; y++; - itoa(sx, x); - itoa(sy, y); - serial_echo_print("["); - serial_echo_print(sy); - serial_echo_print(";"); - serial_echo_print(sx); - serial_echo_print("H"); - serial_echo_print(p); -} - -void serial_echo_init(void) -{ - int comstat, serial_div; - unsigned char lcr; - - /* read the Divisor Latch */ - comstat = serial_echo_inb(UART_LCR); - serial_echo_outb(comstat | UART_LCR_DLAB, UART_LCR); - /*hi =*/ serial_echo_inb(UART_DLM); - /*lo =*/ serial_echo_inb(UART_DLL); - serial_echo_outb(comstat, UART_LCR); - - /* now do hardwired init */ - lcr = serial_parity | (serial_bits - 5); - serial_echo_outb(lcr, UART_LCR); /* No parity, 8 data bits, 1 stop */ - serial_div = 115200 / serial_baud_rate; - serial_echo_outb(0x80|lcr, UART_LCR); /* Access divisor latch */ - serial_echo_outb(serial_div & 0xff, UART_DLL); /* baud rate divisor */ - serial_echo_outb((serial_div >> 8) & 0xff, UART_DLM); - serial_echo_outb(lcr, UART_LCR); /* Done with divisor */ - - /* Prior to disabling interrupts, read the LSR and RBR - * registers */ - comstat = serial_echo_inb(UART_LSR); /* COM? LSR */ - comstat = serial_echo_inb(UART_RX); /* COM? RBR */ - serial_echo_outb(0x00, UART_IER); /* Disable all interrupts */ - - clear_screen_buf(); - - return; -} - -/* - * Get_number of digits - */ -int getnum(ulong val) -{ - int len = 0; - int i = 1; - - while(i <= val) - { - len++; - i *= 10; - } - - return len; - -} - - -void serial_echo_print(const char *p) -{ - if (!serial_cons) { - return; - } - /* Now, do each character */ - while (*p) { - WAIT_FOR_XMITR; - - /* Send the character out. */ - serial_echo_outb(*p, UART_TX); - if(*p==10) { - WAIT_FOR_XMITR; - serial_echo_outb(13, UART_TX); - } - p++; - } -} - -/* Except for multi-character key sequences this mapping - * table is complete. So it should not need to be updated - * when new keys are searched for. However the key handling - * should really be turned around and only in get_key should - * we worry about the exact keycode that was pressed. Everywhere - * else we should switch on the character... - */ -struct ascii_map_str ser_map[] = - /*ascii keycode ascii keycode*/ - { - /* Special cases come first so I can leave - * their ``normal'' mapping in the table, - * without it being activated. - */ - { 27, 0x01}, /* ^[/ESC -> ESC */ - { 127, 0x0e}, /* DEL -> BS */ - { 8, 0x0e}, /* ^H/BS -> BS */ - { 10, 0x1c}, /* ^L/NL -> CR */ - { 13, 0x1c}, /* ^M/CR -> CR */ - { 9, 0x0f}, /* ^I/TAB -> TAB */ - { 19, 0x39}, /* ^S -> SP */ - { 17, 28}, /* ^Q -> CR */ - - { ' ', 0x39}, /* SP -> SP */ - { 'a', 0x1e}, - { 'A', 0x1e}, - { 1, 0x1e}, /* ^A -> A */ - { 'b', 0x30}, - { 'B', 0x30}, - { 2, 0x30}, /* ^B -> B */ - { 'c', 0x2e}, - { 'C', 0x2e}, - { 3, 0x2e}, /* ^C -> C */ - { 'd', 0x20}, - { 'D', 0x20}, - { 4, 0x20}, /* ^D -> D */ - { 'e', 0x12}, - { 'E', 0x12}, - { 5, 0x12}, /* ^E -> E */ - { 'f', 0x21}, - { 'F', 0x21}, - { 6, 0x21}, /* ^F -> F */ - { 'g', 0x22}, - { 'G', 0x22}, - { 7, 0x22}, /* ^G -> G */ - { 'h', 0x23}, - { 'H', 0x23}, - { 8, 0x23}, /* ^H -> H */ - { 'i', 0x17}, - { 'I', 0x17}, - { 9, 0x17}, /* ^I -> I */ - { 'j', 0x24}, - { 'J', 0x24}, - { 10, 0x24}, /* ^J -> J */ - { 'k', 0x25}, - { 'K', 0x25}, - { 11, 0x25}, /* ^K -> K */ - { 'l', 0x26}, - { 'L', 0x26}, - { 12, 0x26}, /* ^L -> L */ - { 'm', 0x32}, - { 'M', 0x32}, - { 13, 0x32}, /* ^M -> M */ - { 'n', 0x31}, - { 'N', 0x31}, - { 14, 0x31}, /* ^N -> N */ - { 'o', 0x18}, - { 'O', 0x18}, - { 15, 0x18}, /* ^O -> O */ - { 'p', 0x19}, - { 'P', 0x19}, - { 16, 0x19}, /* ^P -> P */ - { 'q', 0x10}, - { 'Q', 0x10}, - { 17, 0x10}, /* ^Q -> Q */ - { 'r', 0x13}, - { 'R', 0x13}, - { 18, 0x13}, /* ^R -> R */ - { 's', 0x1f}, - { 'S', 0x1f}, - { 19, 0x1f}, /* ^S -> S */ - { 't', 0x14}, - { 'T', 0x14}, - { 20, 0x14}, /* ^T -> T */ - { 'u', 0x16}, - { 'U', 0x16}, - { 21, 0x16}, /* ^U -> U */ - { 'v', 0x2f}, - { 'V', 0x2f}, - { 22, 0x2f}, /* ^V -> V */ - { 'w', 0x11}, - { 'W', 0x11}, - { 23, 0x11}, /* ^W -> W */ - { 'x', 0x2d}, - { 'X', 0x2d}, - { 24, 0x2d}, /* ^X -> X */ - { 'y', 0x15}, - { 'Y', 0x15}, - { 25, 0x15}, /* ^Y -> Y */ - { 'z', 0x2c}, - { 'Z', 0x2c}, - { 26, 0x2c}, /* ^Z -> Z */ - { '-', 0x0c}, - { '_', 0x0c}, - { 31, 0x0c}, /* ^_ -> _ */ - { '=', 0x0c}, - { '+', 0x0c}, - { '[', 0x1a}, - { '{', 0x1a}, - { 27, 0x1a}, /* ^[ -> [ */ - { ']', 0x1b}, - { '}', 0x1b}, - { 29, 0x1b}, /* ^] -> ] */ - { ';', 0x27}, - { ':', 0x27}, - { '\'', 0x28}, - { '"', 0x28}, - { '`', 0x29}, - { '~', 0x29}, - { '\\', 0x2b}, - { '|', 0x2b}, - { 28, 0x2b}, /* ^\ -> \ */ - { ',', 0x33}, - { '<', 0x33}, - { '.', 0x34}, - { '>', 0x34}, - { '/', 0x35}, - { '?', 0x35}, - { '1', 0x02}, - { '!', 0x02}, - { '2', 0x03}, - { '@', 0x03}, - { '3', 0x04}, - { '#', 0x04}, - { '4', 0x05}, - { '$', 0x05}, - { '5', 0x06}, - { '%', 0x06}, - { '6', 0x07}, - { '^', 0x07}, - { 30, 0x07}, /* ^^ -> 6 */ - { '7', 0x08}, - { '&', 0x08}, - { '8', 0x09}, - { '*', 0x09}, - { '9', 0x0a}, - { '(', 0x0a}, - { '0', 0x0b}, - { ')', 0x0b}, - { 0, 0} - }; - -/* - * Given an ascii character, return the keycode - * - * Uses ser_map definition above. - * - * It would be more efficient to use an array of 255 characters - * and directly index into it. - */ -int ascii_to_keycode (int in) -{ - struct ascii_map_str *p; - for (p = ser_map; p->ascii; p++) { - if (in ==p->ascii) - return p->keycode; - } - return 0; -} - -/* - * Call this when you want to wait for the user to lift the - * finger off of a key. It is a noop if you are using a - * serial console. - */ -void wait_keyup( void ) { - /* Check to see if someone lifted the keyboard key */ - while (1) { - if ((get_key() & 0x80) != 0) { - return; - } - /* Trying to simulate waiting for a key release with - * the serial port is to nasty to let live. - * In particular some menus don't even display until - * you release the key that caused to to get there. - * With the serial port this results in double pressing - * or something worse for just about every key. - */ - if (serial_cons) { - return; - } - } -} - -/* - * Handles "console=" command line option - * - * Examples of accepted params: - * ttyS0 - * ttyS1 - * ttyS0,115200 - * ttyS0,9600e8 - */ -void serial_console_setup(char *param) -{ - char *option, *end; - unsigned long tty; - unsigned long baud_rate; - unsigned char parity, bits; - - if (mt86_strncmp(param, "ttyS", 4)) - return; /* not a serial port */ - - param += 4; - - tty = simple_strtoul(param, &option, 10); - - if (option == param) - return; /* there were no digits */ - - if (tty > 1) - return; /* only ttyS0 and ttyS1 supported */ - - if (*option == '\0' || *option == ' ') - goto save_tty; /* no options given, just ttyS? */ - - if (*option != ',') - return; /* missing the comma separator */ - - /* baud rate must follow */ - option++; - baud_rate = simple_strtoul(option, &end, 10); - - if (end == option) - return; /* no baudrate after comma */ - - if (baud_rate == 0 || (115200 % baud_rate) != 0) - return; /* wrong baud rate */ - - if (*end == '\0' || *end == ' ') - goto save_baud_rate; /* no more options given */ - - switch (toupper(*end)) { - case 'N': - parity = 0; - break; - case 'O': - parity = UART_LCR_PARITY; - break; - case 'E': - parity = UART_LCR_PARITY | UART_LCR_EPAR; - break; - default: - /* Unknown parity */ - return; - } - - end++; - if (*end == '\0' || *end == ' ') - goto save_parity; - - /* word length (bits) */ - if (*end < '7' || *end > '8') - return; /* invalid number of bits */ - - bits = *end - '0'; - - end++; - - if (*end != '\0' || *end != ' ') - return; /* garbage at the end */ - - serial_bits = bits; - save_parity: - serial_parity = parity; - save_baud_rate: - serial_baud_rate = (int) baud_rate; - save_tty: - serial_tty = (short) tty; - serial_cons = 1; -} - -/* Get a comma seperated list of numbers */ -void get_list(int x, int y, int len, char *buf) -{ - int c, n = 0; - - len--; - wait_keyup(); - while(1) { - /* Read a new character and process it */ - c = get_key(); - switch(c) { - case 0x1c: /* CR */ - /* If something has been entered we are done */ - if(n) { - buf[n] = 0; - return; - } - break; - case 0x0e: /* BS */ - if (n > 0) { - n -= 1; - buf[n] = ' '; - } - break; - case 0x0B: buf[n++] = '0'; break; - case 0x02: buf[n++] = '1'; break; - case 0x03: buf[n++] = '2'; break; - case 0x04: buf[n++] = '3'; break; - case 0x05: buf[n++] = '4'; break; - case 0x06: buf[n++] = '5'; break; - case 0x07: buf[n++] = '6'; break; - case 0x08: buf[n++] = '7'; break; - case 0x09: buf[n++] = '8'; break; - case 0x0a: buf[n++] = '9'; break; - case 0x33: buf[n++] = ','; break; - } - cprint(x, y, buf); - if (n >= len) { - buf[n] = 0; - return; - } - } -} diff --git a/memtest86+_old/linuxbios.c b/memtest86+_old/linuxbios.c deleted file mode 100644 index 4804b31..0000000 --- a/memtest86+_old/linuxbios.c +++ /dev/null @@ -1,165 +0,0 @@ -#include "linuxbios_tables.h" -#include "test.h" - -static unsigned long ip_compute_csum(void *addr, unsigned long length) -{ - uint16_t *ptr; - unsigned long sum; - unsigned long len; - unsigned long laddr; - /* compute an ip style checksum */ - laddr = (unsigned long )addr; - sum = 0; - if (laddr & 1) { - uint16_t buffer; - unsigned char *ptr; - /* copy the first byte into a 2 byte buffer. - * This way automatically handles the endian question - * of which byte (low or high) the last byte goes in. - */ - buffer = 0; - ptr = addr; - mt86_memmove(&buffer, ptr, 1); - sum += buffer; - if (sum > 0xFFFF) - sum -= 0xFFFF; - length -= 1; - addr = ptr +1; - - } - len = length >> 1; - ptr = addr; - while (len--) { - sum += *(ptr++); - if (sum > 0xFFFF) - sum -= 0xFFFF; - } - addr = ptr; - if (length & 1) { - uint16_t buffer; - unsigned char *ptr; - /* copy the last byte into a 2 byte buffer. - * This way automatically handles the endian question - * of which byte (low or high) the last byte goes in. - */ - buffer = 0; - ptr = addr; - mt86_memmove(&buffer, ptr, 1); - sum += buffer; - if (sum > 0xFFFF) - sum -= 0xFFFF; - } - return (~sum) & 0xFFFF; - -} - -#define for_each_lbrec(head, rec) \ - for(rec = (struct lb_record *)(((char *)head) + sizeof(*head)); \ - (((char *)rec) < (((char *)head) + sizeof(*head) + head->table_bytes)) && \ - (rec->size >= 1) && \ - ((((char *)rec) + rec->size) <= (((char *)head) + sizeof(*head) + head->table_bytes)); \ - rec = (struct lb_record *)(((char *)rec) + rec->size)) - - -static int count_lb_records(struct lb_header *head) -{ - struct lb_record *rec; - int count; - count = 0; - for_each_lbrec(head, rec) { - count++; - } - return count; -} - -static struct lb_header * __find_lb_table(unsigned long start, unsigned long end) -{ - unsigned long addr; - /* For now be stupid.... */ - for(addr = start; addr < end; addr += 16) { - struct lb_header *head = (struct lb_header *)addr; - struct lb_record *recs = (struct lb_record *)(addr + sizeof(*head)); - if (mt86_memcmp(head->signature, "LBIO", 4) != 0) - continue; - if (head->header_bytes != sizeof(*head)) - continue; - if (ip_compute_csum((unsigned char *)head, sizeof(*head)) != 0) - continue; - if (ip_compute_csum((unsigned char *)recs, head->table_bytes) - != head->table_checksum) - continue; - if (count_lb_records(head) != head->table_entries) - continue; - return head; - }; - return 0; -} - -static struct lb_header * find_lb_table(void) -{ - struct lb_header *head; - head = 0; - if (!head) { - /* First try at address 0 */ - head = __find_lb_table(0x00000, 0x1000); - } - if (!head) { - /* Then try at address 0xf0000 */ - head = __find_lb_table(0xf0000, 0x100000); - } - return head; -} - -int query_linuxbios(void) -{ - struct lb_header *head; - struct lb_record *rec; - struct lb_memory *mem; - struct lb_forward *forward; - int i, entries; - - head = find_lb_table(); - if (!head) { - return 0; - } - - /* coreboot also can forward the table to the high tables area. */ - rec = (struct lb_record *)(((char *)head) + sizeof(*head)); - if (rec->tag == LB_TAG_FORWARD) { - forward = (struct lb_forward *)rec; - head = (struct lb_header *)(unsigned long)(forward->forward); - if (!head) { return 0; } - } - - mem = 0; - for_each_lbrec(head, rec) { - if (rec->tag == LB_TAG_MEMORY) { - mem = (struct lb_memory *)rec; - break; - } - } - if (!mem) { - return 1; - } - entries = (mem->size - sizeof(*mem))/sizeof(mem->map[0]); - if (entries == 0) - return 1; - mem_info.e820_nr = 0; - for(i = 0; i < entries; i++) { - unsigned long long start; - unsigned long long size; - unsigned long type; - if (i >= E820MAX) { - break; - } - start = mem->map[i].start; - size = mem->map[i].size; - type = (mem->map[i].type == LB_MEM_RAM)?E820_RAM: E820_RESERVED; - mem_info.e820[mem_info.e820_nr].addr = start; - mem_info.e820[mem_info.e820_nr].size = size; - mem_info.e820[mem_info.e820_nr].type = type; - mem_info.e820_nr++; - } - return 1; -} - diff --git a/memtest86+_old/linuxbios_tables.h b/memtest86+_old/linuxbios_tables.h deleted file mode 100644 index 38f2038..0000000 --- a/memtest86+_old/linuxbios_tables.h +++ /dev/null @@ -1,89 +0,0 @@ -#ifndef LINUXBIOS_TABLES_H -#define LINUXBIOS_TABLES_H - -#include "stdint.h" - -/* The linuxbios table information is for conveying information - * from the firmware to the loaded OS image. Primarily this - * is expected to be information that cannot be discovered by - * other means, such as quering the hardware directly. - * - * All of the information should be Position Independent Data. - * That is it should be safe to relocated any of the information - * without it's meaning/correctnes changing. For table that - * can reasonably be used on multiple architectures the data - * size should be fixed. This should ease the transition between - * 32 bit and 64 bit architectures etc. - * - * The completeness test for the information in this table is: - * - Can all of the hardware be detected? - * - Are the per motherboard constants available? - * - Is there enough to allow a kernel to run that was written before - * a particular motherboard is constructed? (Assuming the kernel - * has drivers for all of the hardware but it does not have - * assumptions on how the hardware is connected together). - * - * With this test it should be straight forward to determine if a - * table entry is required or not. This should remove much of the - * long term compatibility burden as table entries which are - * irrelevant or have been replaced by better alternatives may be - * dropped. Of course it is polite and expidite to include extra - * table entries and be backwards compatible, but it is not required. - */ - - -struct lb_header -{ - uint8_t signature[4]; /* LBIO */ - uint32_t header_bytes; - uint32_t header_checksum; - uint32_t table_bytes; - uint32_t table_checksum; - uint32_t table_entries; -}; - -/* Every entry in the boot enviroment list will correspond to a boot - * info record. Encoding both type and size. The type is obviously - * so you can tell what it is. The size allows you to skip that - * boot enviroment record if you don't know what it easy. This allows - * forward compatibility with records not yet defined. - */ -struct lb_record { - uint32_t tag; /* tag ID */ - uint32_t size; /* size of record (in bytes) */ -}; - -#define LB_TAG_UNUSED 0x0000 - -#define LB_TAG_MEMORY 0x0001 -#define LB_TAG_FORWARD 0x0011 - -struct lb_memory_range { - uint64_t start; - uint64_t size; - uint32_t type; -#define LB_MEM_RAM 1 -#define LB_MEM_RESERVED 2 - -}; - -struct lb_memory { - uint32_t tag; - uint32_t size; - struct lb_memory_range map[0]; -}; - -#define LB_TAG_HWRPB 0x0002 -struct lb_hwrpb { - uint32_t tag; - uint32_t size; - uint64_t hwrpb; -}; - -struct lb_forward { - uint32_t tag; - uint32_t size; - uint64_t forward; -}; - -#endif /* LINUXBIOS_TABLES_H */ diff --git a/memtest86+_old/main.c b/memtest86+_old/main.c deleted file mode 100644 index d0c9289..0000000 --- a/memtest86+_old/main.c +++ /dev/null @@ -1,1299 +0,0 @@ -/* - * MemTest86+ V5 Specific code (GPL V2.0) - * By Samuel DEMEULEMEESTER, sdemeule@memtest.org - * http://www.canardpc.com - http://www.memtest.org - * ------------------------------------------------ - * main.c - MemTest-86 Version 3.5 - * - * Released under version 2 of the Gnu Public License. - * By Chris Brady - */ - -#include "stdint.h" -#include "stddef.h" -#include "test.h" -#include "defs.h" -#include "cpuid.h" -#include "smp.h" -#include "config.h" -#undef TEST_TIMES -#define DEFTESTS 9 -#define FIRST_DIVISER 3 - -/* The main stack is allocated during boot time. The stack size should - * preferably be a multiple of page size(4Kbytes) - */ - -extern struct cpu_ident cpu_id; -extern char toupper(char c); -extern int isxdigit(char c); -extern void reboot(); -extern void bzero(); -extern void smp_set_ordinal(int me, int ord); -extern int smp_my_ord_num(int me); -extern int smp_ord_to_cpu(int me); -extern void get_cpuid(); -extern void initialise_cpus(); -extern ulong rand(int cpu); -extern void get_mem_speed(int cpu, int ncpus); -extern void rand_seed(unsigned int seed1, unsigned int seed2, int cpu); -extern struct barrier_s *barr; -extern int num_cpus; -extern int act_cpus; - -static int find_ticks_for_test(int test); -void find_ticks_for_pass(void); -int find_chunks(int test); -static void test_setup(void); -static int compute_segments(struct pmap map, int cpu); -int do_test(int ord); -struct tseq tseq[] = - { - {1, -1, 0, 6, 0, "[Address test, walking ones, no cache] "}, - {1, -1, 1, 6, 0, "[Address test, own address Sequential] "}, - {1, 32, 2, 6, 0, "[Address test, own address Parallel] "}, - {1, 32, 3, 6, 0, "[Moving inversions, 1s & 0s Parallel] "}, - {1, 32, 5, 3, 0, "[Moving inversions, 8 bit pattern] "}, - {1, 32, 6, 30, 0, "[Moving inversions, random pattern] "}, - {1, 32, 7, 81, 0, "[Block move] "}, - {1, 1, 8, 3, 0, "[Moving inversions, 32 bit pattern] "}, - {1, 32, 9, 48, 0, "[Random number sequence] "}, - {1, 32, 10, 6, 0, "[Modulo 20, Random pattern] "}, - {1, 1, 11, 240, 0, "[Bit fade test, 2 patterns] "}, - {1, 0, 0, 0, 0, NULL} -}; - -volatile int mstr_cpu; -volatile int run_cpus; -volatile int cpu_ord=0; -int maxcpus=MAX_CPUS; -volatile short cpu_sel; -volatile short cpu_mode; -char cpu_mask[MAX_CPUS]; -long bin_mask=0xffffffff; -short onepass; -volatile short btflag = 0; -volatile int test; -short restart_flag; -uint8_t volatile stacks[MAX_CPUS][STACKSIZE_BYTES]; -int bitf_seq = 0; -char cmdline_parsed = 0; -struct vars variables = {}; -struct vars * const vv = &variables; -volatile int bail; -int nticks; -int test_ticks; -volatile int segs; /* number of entries in vv->map[] - (Why not be a member of vars then?) */ -static int ltest; -static int pass_flag = 0; -volatile short start_seq = 0; -static int c_iter; -ulong high_test_adr; -volatile static int window; -volatile static unsigned long win_next; -volatile static ulong win0_start; /* Start test address for window 0 */ -volatile static ulong win1_end; /* End address for relocation */ -volatile static struct pmap winx; /* Window struct for mapping windows */ - -/* Find the next selected test to run */ -void next_test() -{ - test++; - while (tseq[test].sel == 0 && tseq[test].cpu_sel != 0) { - test++; - } - - if (tseq[test].cpu_sel == 0) { - /* We hit the end of the list so we completed a pass */ - pass_flag++; - /* Find the next test to run, start searching from 0 */ - test = 0; - while (tseq[test].sel == 0 && tseq[test].cpu_sel != 0) { - test++; - } - } -} - -/* Set default values for all parameters */ -void set_defaults() -{ - int i; - - if (start_seq == 2) { - /* This is a restart so we reset everything */ - onepass = 0; - i = 0; - while (tseq[i].cpu_sel) { - tseq[i].sel = 1; - i++; - } - test = 0; - if (tseq[0].sel == 0) { - next_test(); - } - } - ltest = -1; - win_next = 0; - window = 0; - bail = 0; - cpu_mode = CPM_ALL; - cpu_sel = 0; - vv->printmode=PRINTMODE_ADDRESSES; - vv->numpatn=0; - vv->plim_lower = 0; - vv->plim_upper = vv->pmap[vv->msegs-1].end; - vv->pass = 0; - vv->msg_line = 0; - vv->ecount = 0; - vv->ecc_ecount = 0; - vv->msg_line = LINE_SCROLL-1; - vv->scroll_start = vv->msg_line * 160; - vv->debugging = 0; - vv->erri.low_addr.page = 0x7fffffff; - vv->erri.low_addr.offset = 0xfff; - vv->erri.high_addr.page = 0; - vv->erri.high_addr.offset = 0; - vv->erri.min_bits = 32; - vv->erri.max_bits = 0; - vv->erri.min_bits = 32; - vv->erri.max_bits = 0; - vv->erri.maxl = 0; - vv->erri.cor_err = 0; - vv->erri.ebits = 0; - vv->erri.hdr_flag = 0; - vv->erri.tbits = 0; - for (i=0; tseq[i].msg != NULL; i++) { - tseq[i].errors = 0; - } - restart_flag = 0; - tseq[10].sel = 0; -} - -/* Boot trace function */ -short tidx = 25; -void btrace(int me, int line, char *msg, int wait, long v1, long v2) -{ - int y, x; - - /* Is tracing turned on? */ - if (btflag == 0) return; - - spin_lock(&barr->mutex); - y = tidx%13; - x = tidx/13*40; - cplace(y+11, x+1, ' '); - if (++tidx > 25) { - tidx = 0; - } - y = tidx%13; - x = tidx/13*40; - - cplace(y+11, x+1, '>'); - dprint(y+11, x+2, me, 2, 0); - dprint(y+11, x+5, line, 4, 0); - cprint(y+11, x+10, msg); - hprint(y+11, x+22, v1); - hprint(y+11, x+31, v2); - if (wait) { - wait_keyup(); - } - spin_unlock(&barr->mutex); -} - -/* Relocate the test to a new address. Be careful to not overlap! */ -static void run_at(unsigned long addr, int cpu) -{ - ulong *ja = (ulong *)(addr + startup_32 - _start); - - /* CPU 0, Copy memtest86+ code */ - if (cpu == 0) { - mt86_memmove((void *)addr, &_start, _end - _start); - } - - /* Wait for the copy */ - barrier(); - - /* We use a lock to insure that only one CPU at a time jumps to - * the new code. Some of the startup stuff is not thread safe! */ - spin_lock(&barr->mutex); - - /* Jump to the start address */ - goto *ja; -} - -/* Switch from the boot stack to the main stack. First the main stack - * is allocated, then the contents of the boot stack are copied, then - * ESP is adjusted to point to the new stack. - */ -static void -switch_to_main_stack(unsigned cpu_num) -{ - extern uintptr_t boot_stack; - extern uintptr_t boot_stack_top; - uintptr_t *src, *dst; - int offs; - uint8_t * stackAddr, *stackTop; - - stackAddr = (uint8_t *) &stacks[cpu_num][0]; - - stackTop = stackAddr + STACKSIZE_BYTES; - - src = (uintptr_t*)&boot_stack_top; - dst = (uintptr_t*)stackTop; - do { - src--; dst--; - *dst = *src; - } while ((uintptr_t *)src > (uintptr_t *)&boot_stack); - - offs = (uint8_t *)&boot_stack_top - stackTop; - __asm__ __volatile__ ( - "subl %%eax, %%esp" - : /*no output*/ - : "a" (offs) : "memory" - ); -} - -/* command line passing using the 'old' boot protocol */ -#define MK_PTR(seg,off) ((void*)(((unsigned long)(seg) << 4) + (off))) -#define OLD_CL_MAGIC_ADDR ((unsigned short*) MK_PTR(INITSEG,0x20)) -#define OLD_CL_MAGIC 0xA33F -#define OLD_CL_OFFSET_ADDR ((unsigned short*) MK_PTR(INITSEG,0x22)) - -static void parse_command_line(void) -{ - long simple_strtoul(char *cmd, char *ptr, int base); - char *cp, dummy; - int i, j, k; - - if (cmdline_parsed) - return; - - /* Fill in the cpu mask array with the default */ - for (i=0; ipmap[vv->msegs-1].end > 0x2f00) { - high_test_adr = 0x2000000; - } else { - high_test_adr = 0x300000; - } - win1_end = (high_test_adr >> 12); - - /* Adjust the map to not test the page at 939k, - * reserved for locks */ - vv->pmap[0].end--; - - find_ticks_for_pass(); - } else { - /* APs only, Register the APs */ - btrace(my_cpu_num, __LINE__, "AP_Start ", 0, my_cpu_num, - cpu_ord); - smp_ap_booted(my_cpu_num); - /* Asign a sequential CPU ordinal to each active cpu */ - spin_lock(&barr->mutex); - my_cpu_ord = cpu_ord++; - smp_set_ordinal(my_cpu_num, my_cpu_ord); - spin_unlock(&barr->mutex); - btrace(my_cpu_num, __LINE__, "AP_Done ", 0, my_cpu_num, - my_cpu_ord); - } - - } else { - /* Unlock after a relocation */ - spin_unlock(&barr->mutex); - /* Get the CPU ordinal since it is lost during relocation */ - my_cpu_ord = smp_my_ord_num(my_cpu_num); - btrace(my_cpu_num, __LINE__, "Reloc_Done",0,my_cpu_num,my_cpu_ord); - } - - /* A barrier to insure that all of the CPUs are done with startup */ - barrier(); - btrace(my_cpu_num, __LINE__, "1st Barr ", 1, my_cpu_num, my_cpu_ord); - - - /* Setup Memory Management and measure memory speed, we do it here - * because we need all of the available CPUs */ - if (start_seq < 2) { - - /* Enable floating point processing */ - if (cpu_id.fid.bits.fpu) - __asm__ __volatile__ - ( - "movl %%cr0, %%eax\n\t" - "andl $0x7, %%eax\n\t" - "movl %%eax, %%cr0\n\t" - : : - : "ax" - ); - if (cpu_id.fid.bits.sse) - __asm__ __volatile__ - ( - "movl %%cr4, %%eax\n\t" - "orl $0x00000200, %%eax\n\t" - "movl %%eax, %%cr4\n\t" - : : - : "ax" - ); - - btrace(my_cpu_num, __LINE__, "Mem Mgmnt ", - 1, cpu_id.fid.bits.pae, cpu_id.fid.bits.lm); - /* Setup memory management modes */ - /* If we have PAE, turn it on */ - if (cpu_id.fid.bits.pae == 1) { - __asm__ __volatile__ - ( - "movl %%cr4, %%eax\n\t" - "orl $0x00000020, %%eax\n\t" - "movl %%eax, %%cr4\n\t" - : : - : "ax" - ); - cprint(LINE_TITLE+1, COL_MODE, "(PAE Mode)"); - } - /* If this is a 64 CPU enable long mode */ - if (cpu_id.fid.bits.lm == 1) { - __asm__ __volatile__ - ( - "movl $0xc0000080, %%ecx\n\t" - "rdmsr\n\t" - "orl $0x00000100, %%eax\n\t" - "wrmsr\n\t" - : : - : "ax", "cx" - ); - cprint(LINE_TITLE+1, COL_MODE, "(X64 Mode)"); - } - /* Get the memory Speed with all CPUs */ - get_mem_speed(my_cpu_num, num_cpus); - } - - /* Set the initialized flag only after all of the CPU's have - * Reached the barrier. This insures that relocation has - * been completed for each CPU. */ - btrace(my_cpu_num, __LINE__, "Start Done", 1, 0, 0); - start_seq = 2; - - /* Loop through all tests */ - while (1) { - /* If the restart flag is set all initial params */ - if (restart_flag) { - set_defaults(); - continue; - } - /* Skip single CPU tests if we are using only one CPU */ - if (tseq[test].cpu_sel == -1 && - (num_cpus == 1 || cpu_mode != CPM_ALL)) { - test++; - continue; - } - - test_setup(); - - /* Loop through all possible windows */ - while (win_next <= ((ulong)vv->pmap[vv->msegs-1].end + WIN_SZ_PAGES)) { - - /* Main scheduling barrier */ - cprint(8, my_cpu_num+7, "W"); - btrace(my_cpu_num, __LINE__, "Sched_Barr", 1,window,win_next); - barrier(); - - /* Don't go over the 8TB PAE limit */ - if (win_next > MAX_MEM_PAGES) { - break; - } - - /* For the bit fade test, #11, we cannot relocate so bump the - * window to 1 */ - if (tseq[test].pat == 11 && window == 0) { - window = 1; - } - - /* Relocate if required */ - if (window != 0 && (ulong)&_start != LOW_TEST_ADR) { - btrace(my_cpu_num, __LINE__, "Sched_RelL", 1,0,0); - run_at(LOW_TEST_ADR, my_cpu_num); - } - if (window == 0 && vv->plim_lower >= win0_start) { - window++; - } - if (window == 0 && (ulong)&_start == LOW_TEST_ADR) { - btrace(my_cpu_num, __LINE__, "Sched_RelH", 1,0,0); - run_at(high_test_adr, my_cpu_num); - } - - /* Decide which CPU(s) to use */ - btrace(my_cpu_num, __LINE__, "Sched_CPU0",1,cpu_sel, - tseq[test].cpu_sel); - run = 1; - switch(cpu_mode) { - case CPM_RROBIN: - case CPM_SEQ: - /* Select a single CPU */ - if (my_cpu_ord == cpu_sel) { - mstr_cpu = cpu_sel; - run_cpus = 1; - } else { - run = 0; - } - break; - case CPM_ALL: - /* Use all CPUs */ - if (tseq[test].cpu_sel == -1) { - /* Round robin through all of the CPUs */ - if (my_cpu_ord == cpu_sel) { - mstr_cpu = cpu_sel; - run_cpus = 1; - } else { - run = 0; - } - } else { - /* Use the number of CPUs specified by the test, - * Starting with zero */ - if (my_cpu_ord >= tseq[test].cpu_sel) { - run = 0; - } - /* Set the master CPU to the highest CPU number - * that has been selected */ - if (act_cpus < tseq[test].cpu_sel) { - mstr_cpu = act_cpus-1; - run_cpus = act_cpus; - } else { - mstr_cpu = tseq[test].cpu_sel-1; - run_cpus = tseq[test].cpu_sel; - } - } - } - btrace(my_cpu_num, __LINE__, "Sched_CPU1",1,run_cpus,run); - barrier(); - dprint(9, 7, run_cpus, 2, 0); - - /* Setup a sub barrier for only the selected CPUs */ - if (my_cpu_ord == mstr_cpu) { - s_barrier_init(run_cpus); - } - - /* Make sure the the sub barrier is ready before proceeding */ - barrier(); - - /* Not selected CPUs go back to the scheduling barrier */ - if (run == 0 ) { - continue; - } - cprint(8, my_cpu_num+7, "-"); - btrace(my_cpu_num, __LINE__, "Sched_Win0",1,window,win_next); - - if (my_cpu_ord == mstr_cpu) { - switch (window) { - /* Special case for relocation */ - case 0: - winx.start = 0; - winx.end = win1_end; - window++; - break; - /* Special case for first segment */ - case 1: - winx.start = win0_start; - winx.end = WIN_SZ_PAGES; - win_next += WIN_SZ_PAGES; - window++; - break; - /* For all other windows */ - default: - winx.start = win_next; - win_next += WIN_SZ_PAGES; - winx.end = win_next; - } - btrace(my_cpu_num,__LINE__,"Sched_Win1",1,winx.start, - winx.end); - - /* Find the memory areas to test */ - segs = compute_segments(winx, my_cpu_num); - } - s_barrier(); - btrace(my_cpu_num,__LINE__,"Sched_Win2",1,segs, - vv->map[0].pbase_addr); - - if (segs == 0) { - /* No memory in this window so skip it */ - continue; - } - - /* map in the window... */ - if (map_page(vv->map[0].pbase_addr) < 0) { - /* Either there is no PAE or we are at the PAE limit */ - break; - } - - btrace(my_cpu_num, __LINE__, "Strt_Test ",1,my_cpu_num, - my_cpu_ord); - do_test(my_cpu_ord); - btrace(my_cpu_num, __LINE__, "End_Test ",1,my_cpu_num, - my_cpu_ord); - - paging_off(); - - } /* End of window loop */ - - s_barrier(); - btrace(my_cpu_num, __LINE__, "End_Win ",1,test, window); - - /* Setup for the next set of windows */ - win_next = 0; - window = 0; - bail = 0; - - /* Only the master CPU does the end of test housekeeping */ - if (my_cpu_ord != mstr_cpu) { - continue; - } - - /* Special handling for the bit fade test #11 */ - if (tseq[test].pat == 11 && bitf_seq != 6) { - /* Keep going until the sequence is complete. */ - bitf_seq++; - continue; - } else { - bitf_seq = 0; - } - - /* Select advancement of CPUs and next test */ - switch(cpu_mode) { - case CPM_RROBIN: - if (++cpu_sel >= act_cpus) { - cpu_sel = 0; - } - next_test(); - break; - case CPM_SEQ: - if (++cpu_sel >= act_cpus) { - cpu_sel = 0; - next_test(); - } - break; - case CPM_ALL: - if (tseq[test].cpu_sel == -1) - { - /* Do the same test for each CPU */ - if (++cpu_sel >= act_cpus) - { - cpu_sel = 0; - next_test(); - } else { - continue; - } - } else { - next_test(); - } - } //???? - btrace(my_cpu_num, __LINE__, "Next_CPU ",1,cpu_sel,test); - - /* If this was the last test then we finished a pass */ - if (pass_flag) - { - pass_flag = 0; - - vv->pass++; - - dprint(LINE_INFO, 49, vv->pass, 5, 0); - find_ticks_for_pass(); - ltest = -1; - - if (vv->ecount == 0) - { - /* If onepass is enabled and we did not get any errors - * reboot to exit the test */ - if (onepass) { reboot(); } - if (!btflag) - cprint(LINE_MSG, COL_MSG-8, - "** Pass complete, no errors, press Esc to exit **"); - if(BEEP_END_NO_ERROR) - { - beep(1000); - beep(2000); - beep(1000); - beep(2000); - } - } - } - - bail=0; - } /* End test loop */ -} - -void test_setup() -{ - static int ltest = -1; - - /* See if a specific test has been selected */ - if (vv->testsel >= 0) { - test = vv->testsel; - } - - /* Only do the setup if this is a new test */ - if (test == ltest) { - return; - } - ltest = test; - - /* Now setup the test parameters based on the current test number */ - if (vv->pass == 0) { - /* Reduce iterations for first pass */ - c_iter = tseq[test].iter/FIRST_DIVISER; - } else { - c_iter = tseq[test].iter; - } - - /* Set the number of iterations. We only do half of the iterations */ - /* on the first pass */ - //dprint(LINE_INFO, 28, c_iter, 3, 0); - test_ticks = find_ticks_for_test(test); - nticks = 0; - vv->tptr = 0; - - cprint(LINE_PAT, COL_PAT, " "); - cprint(LINE_PAT, COL_PAT-3, " "); - dprint(LINE_TST, COL_MID+6, tseq[test].pat, 2, 1); - cprint(LINE_TST, COL_MID+9, tseq[test].msg); - cprint(2, COL_MID+8, " "); -} - -/* A couple static variables for when all cpus share the same pattern */ -static ulong sp1, sp2; - -int do_test(int my_ord) -{ - int i=0, j=0; - static int bitf_sleep; - unsigned long p0=0, p1=0, p2=0; - - if (my_ord == mstr_cpu) { - if ((ulong)&_start > LOW_TEST_ADR) { - /* Relocated so we need to test all selected lower memory */ - vv->map[0].start = mapping(vv->plim_lower); - - /* Good 'ol Legacy USB_WAR */ - if (vv->map[0].start < (ulong*)0x500) - { - vv->map[0].start = (ulong*)0x500; - } - - cprint(LINE_PAT, COL_MID+25, " R"); - } else { - cprint(LINE_PAT, COL_MID+25, " "); - } - - /* Update display of memory segments being tested */ - p0 = page_of(vv->map[0].start); - p1 = page_of(vv->map[segs-1].end); - aprint(LINE_RANGE, COL_MID+9, p0); - cprint(LINE_RANGE, COL_MID+14, " - "); - aprint(LINE_RANGE, COL_MID+17, p1); - aprint(LINE_RANGE, COL_MID+25, p1-p0); - cprint(LINE_RANGE, COL_MID+30, " of "); - aprint(LINE_RANGE, COL_MID+34, vv->selected_pages); - } - - switch(tseq[test].pat) { - - /* do the testing according to the selected pattern */ - - case 0: /* Address test, walking ones (test #0) */ - /* Run with cache turned off */ - set_cache(0); - addr_tst1(my_ord); - set_cache(1); - BAILOUT; - break; - - case 1: - case 2: /* Address test, own address (test #1, 2) */ - addr_tst2(my_ord); - BAILOUT; - break; - - case 3: - case 4: /* Moving inversions, all ones and zeros (tests #3, 4) */ - p1 = 0; - p2 = ~p1; - s_barrier(); - movinv1(c_iter,p1,p2,my_ord); - BAILOUT; - - /* Switch patterns */ - s_barrier(); - movinv1(c_iter,p2,p1,my_ord); - BAILOUT; - break; - - case 5: /* Moving inversions, 8 bit walking ones and zeros (test #5) */ - p0 = 0x80; - for (i=0; i<8; i++, p0=p0>>1) { - p1 = p0 | (p0<<8) | (p0<<16) | (p0<<24); - p2 = ~p1; - s_barrier(); - movinv1(c_iter,p1,p2, my_ord); - BAILOUT; - - /* Switch patterns */ - s_barrier(); - movinv1(c_iter,p2,p1, my_ord); - BAILOUT; - } - break; - - case 6: /* Random Data (test #6) */ - /* Seed the random number generator */ - if (my_ord == mstr_cpu) { - if (cpu_id.fid.bits.rdtsc) { - asm __volatile__ ("rdtsc":"=a" (sp1),"=d" (sp2)); - } else { - sp1 = 521288629 + vv->pass; - sp2 = 362436069 - vv->pass; - } - rand_seed(sp1, sp2, 0); - } - - s_barrier(); - for (i=0; i < c_iter; i++) { - if (my_ord == mstr_cpu) { - sp1 = rand(0); - sp2 = ~p1; - } - s_barrier(); - movinv1(2,sp1,sp2, my_ord); - BAILOUT; - } - break; - - - case 7: /* Block move (test #7) */ - block_move(c_iter, my_ord); - BAILOUT; - break; - - case 8: /* Moving inversions, 32 bit shifting pattern (test #8) */ - for (i=0, p1=1; p1; p1=p1<<1, i++) { - s_barrier(); - movinv32(c_iter,p1, 1, 0x80000000, 0, i, my_ord); - { BAILOUT } - s_barrier(); - movinv32(c_iter,~p1, 0xfffffffe, - 0x7fffffff, 1, i, my_ord); - { BAILOUT } - } - break; - - case 9: /* Random Data Sequence (test #9) */ - for (i=0; i < c_iter; i++) { - s_barrier(); - movinvr(my_ord); - BAILOUT; - } - break; - - case 10: /* Modulo 20 check, Random pattern (test #10) */ - for (j=0; j>1) { - p1 = p0 | (p0<<8) | (p0<<16) | (p0<<24); - for (i=0; i 1) { - twin.start = wnxt; - wnxt += WIN_SZ_PAGES; - twin.end = wnxt; - } - - /* Find the memory areas I am going to test */ - sg = compute_segments(twin, -1); - for(i = 0; i < sg; i++) { - len = vv->map[i].end - vv->map[i].start; - - if (cpu_mode == CPM_ALL && num_cpus > 1) { - switch(tseq[tst].pat) { - case 2: - case 4: - case 5: - case 6: - case 9: - case 10: - len /= act_cpus; - break; - case 7: - case 8: - len /= act_cpus; - break; - } - } - ch += (len + SPINSZ_DWORDS -1)/SPINSZ_DWORDS; - } - } - return(ch); -} - -/* Compute the total number of ticks per pass */ -void find_ticks_for_pass(void) -{ - int i; - - vv->pptr = 0; - vv->pass_ticks = 0; - vv->total_ticks = 0; - cprint(1, COL_MID+8, " "); - i = 0; - while (tseq[i].cpu_sel != 0) { - /* Skip tests 2 and 4 if we are using 1 cpu */ - if (act_cpus == 1 && (i == 2 || i == 4)) { - i++; - continue; - } - vv->pass_ticks += find_ticks_for_test(i); - i++; - } -} - -static int find_ticks_for_test(int tst) -{ - int ticks=0, iter, ch; - - if (tseq[tst].sel == 0) { - return(0); - } - - /* Determine the number of SPINSZ chunks for this test */ - ch = find_chunks(tst); - - /* Set the number of iterations. We only do 1/2 of the iterations */ - /* on the first pass */ - if (vv->pass == 0) { - iter = tseq[tst].iter/FIRST_DIVISER; - } else { - iter = tseq[tst].iter; - } - - switch(tseq[tst].pat) { - case 0: /* Address test, walking ones */ - ticks = ch; - break; - case 1: /* Address test, own address */ - case 2: - ticks = ch * 2; - break; - case 3: /* Moving inversions, all ones and zeros */ - case 4: { - const int each_movinv1 = ch * (1 + 2 * iter); // each movinv1() - ticks = 2 * each_movinv1; // which we call twice - break; - } - case 5: { /* Moving inversions, 8 bit walking ones and zeros */ - const int each_movinv1 = ch * (1 + 2 * iter); // same as above - ticks = 16 * each_movinv1; // but here we call it 16x - break; - } - case 6: { /* Random Data */ - const int each_movinv1 = ch * 5; // movinv1() does only 5 ticks here - ticks = iter * each_movinv1; // and we call it 'iter' times. - break; - } - case 7: /* Block move */ - ticks = ch * (2 + iter); - break; - case 8: { /* Moving inversions, 32 bit shifting pattern */ - const int each_movinv32 = ch * (1 + 2 * iter); // Each movinv32() - ticks = each_movinv32 * 64; // We call it 64x - break; - } - case 9: { /* Random Data Sequence */ - const int each_movinvr = 3 * ch; // Each movinvr() ticks 3*ch times - ticks = each_movinvr * iter; // We call it iter times - break; - } - case 10: { /* Modulo 20 check, Random pattern */ - const int each_modtst = ch * 4; - ticks = iter * MOD_SZ * each_modtst; - break; - } - case 11: { /* Bit fade test */ - // Each call to bit_fade_fill() and bit_fade_chk() ticks ch times. - const int each_bit_fade_fill = ch; - const int each_bit_fade_chk = ch; - // We call each twice: fill 0s, check, fill 1s, check. - const int loop_ticks = 2 * each_bit_fade_chk + 2 * each_bit_fade_fill; - // We also sleep for '2*iter' seconds and tick once per second - const int sleep_ticks = iter * 2; - ticks = loop_ticks + sleep_ticks; - break; - } - case 90: { /* Modulo 20 check, all ones and zeros (unused) */ - const int each_modtst = ch * (2 + iter); - ticks = each_modtst * 2 * MOD_SZ; - break; - } - case 91: { /* Modulo 20 check, 8 bit pattern (unused) */ - const int each_modtst = ch * (2 + iter); - ticks = each_modtst * 2 * MOD_SZ * 8; - break; - } - default: - ASSERT(0); - break; - } - if (cpu_mode == CPM_SEQ || tseq[tst].cpu_sel == -1) { - ticks *= act_cpus; - } - return ticks; -} - -static int compute_segments(struct pmap win, int me) -{ - unsigned long wstart, wend; - int i, sg; - - /* Compute the window I am testing memory in */ - wstart = win.start; - wend = win.end; - sg = 0; - - /* Now reduce my window to the area of memory I want to test */ - if (wstart < vv->plim_lower) { - wstart = vv->plim_lower; - } - if (wend > vv->plim_upper) { - wend = vv->plim_upper; - } - if (wstart >= wend) { - return(0); - } - /* List the segments being tested */ - for (i=0; i< vv->msegs; i++) { - unsigned long start, end; - start = vv->pmap[i].start; - end = vv->pmap[i].end; - if (start <= wstart) { - start = wstart; - } - if (end >= wend) { - end = wend; - } -#if 0 - cprint(LINE_SCROLL+(2*i), 0, " ("); - hprint(LINE_SCROLL+(2*i), 2, start); - cprint(LINE_SCROLL+(2*i), 10, ", "); - hprint(LINE_SCROLL+(2*i), 12, end); - cprint(LINE_SCROLL+(2*i), 20, ") "); - - cprint(LINE_SCROLL+(2*i), 22, "r("); - hprint(LINE_SCROLL+(2*i), 24, wstart); - cprint(LINE_SCROLL+(2*i), 32, ", "); - hprint(LINE_SCROLL+(2*i), 34, wend); - cprint(LINE_SCROLL+(2*i), 42, ") "); - - cprint(LINE_SCROLL+(2*i), 44, "p("); - hprint(LINE_SCROLL+(2*i), 46, vv->plim_lower); - cprint(LINE_SCROLL+(2*i), 54, ", "); - hprint(LINE_SCROLL+(2*i), 56, vv->plim_upper); - cprint(LINE_SCROLL+(2*i), 64, ") "); - - cprint(LINE_SCROLL+(2*i+1), 0, "w("); - hprint(LINE_SCROLL+(2*i+1), 2, win.start); - cprint(LINE_SCROLL+(2*i+1), 10, ", "); - hprint(LINE_SCROLL+(2*i+1), 12, win.end); - cprint(LINE_SCROLL+(2*i+1), 20, ") "); - - cprint(LINE_SCROLL+(2*i+1), 22, "m("); - hprint(LINE_SCROLL+(2*i+1), 24, vv->pmap[i].start); - cprint(LINE_SCROLL+(2*i+1), 32, ", "); - hprint(LINE_SCROLL+(2*i+1), 34, vv->pmap[i].end); - cprint(LINE_SCROLL+(2*i+1), 42, ") "); - - cprint(LINE_SCROLL+(2*i+1), 44, "i="); - hprint(LINE_SCROLL+(2*i+1), 46, i); - - cprint(LINE_SCROLL+(2*i+2), 0, - " " - " "); - cprint(LINE_SCROLL+(2*i+3), 0, - " " - " "); -#endif - if ((start < end) && (start < wend) && (end > wstart)) { - vv->map[sg].pbase_addr = start; - vv->map[sg].start = mapping(start); - vv->map[sg].end = emapping(end); -#if 0 - hprint(LINE_SCROLL+(sg+1), 0, sg); - hprint(LINE_SCROLL+(sg+1), 12, vv->map[sg].pbase_addr); - hprint(LINE_SCROLL+(sg+1), 22, start); - hprint(LINE_SCROLL+(sg+1), 32, end); - hprint(LINE_SCROLL+(sg+1), 42, mapping(start)); - hprint(LINE_SCROLL+(sg+1), 52, emapping(end)); - cprint(LINE_SCROLL+(sg+2), 0, - " " - " "); -#endif -#if 0 - cprint(LINE_SCROLL+(2*i+1), 54, ", sg="); - hprint(LINE_SCROLL+(2*i+1), 59, sg); -#endif - sg++; - } - } - return (sg); -} - diff --git a/memtest86+_old/major_version b/memtest86+_old/major_version deleted file mode 100644 index c6aaf52..0000000 --- a/memtest86+_old/major_version +++ /dev/null @@ -1 +0,0 @@ -4.99 diff --git a/memtest86+_old/make_buildnum.sh b/memtest86+_old/make_buildnum.sh deleted file mode 100755 index 93927cd..0000000 --- a/memtest86+_old/make_buildnum.sh +++ /dev/null @@ -1,20 +0,0 @@ -#!sh -# FILE: make_buildnum.sh -version="`sed 's/^ *//' major_version`" -old="`sed 's/^ *//' build.number` +1" -echo $old | bc > build.number.temp -mv build.number.temp build.number -#versión.. -echo "$version`sed 's/^ *//' build.number` - `date`" > version.number -#header -echo "#ifndef BUILD_NUMBER_STR" > build_number.h -echo "#define BUILD_NUMBER_STR \"`sed 's/^ *//' build.number`\"" >> build_number.h -echo "#endif" >> build_number.h - -echo "#ifndef VERSION_STR" >> build_number.h -echo "#define VERSION_STR \"$version`sed 's/^ *//' build.number` - `date`\"" >> build_number.h -echo "#endif" >> build_number.h - -echo "#ifndef VERSION_STR_SHORT" >> build_number.h -echo "#define VERSION_STR_SHORT \"$version`sed 's/^ *//' build.number`\"" >> build_number.h -echo "#endif" >> build_number.h diff --git a/memtest86+_old/makedos.sh b/memtest86+_old/makedos.sh deleted file mode 100755 index adeb29d..0000000 --- a/memtest86+_old/makedos.sh +++ /dev/null @@ -1,10 +0,0 @@ -#!/bin/bash - -if [ -f memtest.bin ] -then -CSIZE="$(awk 'NR==16' mt86+_loader.asm | awk '{print $2}')"; -NSIZE="$(ls -l memtest.bin | awk '{print $5}')"; -sed "s/$CSIZE/$NSIZE/" mt86+_loader.asm > mt86+_loader.asm.new; -mv mt86+_loader.asm.new mt86+_loader.asm; -nasm mt86+_loader.asm; -fi diff --git a/memtest86+_old/makeiso.sh b/memtest86+_old/makeiso.sh deleted file mode 100755 index d6b329e..0000000 --- a/memtest86+_old/makeiso.sh +++ /dev/null @@ -1,45 +0,0 @@ -#!/bin/sh - -# check to see if the correct tools are installed -for X in wc genisoimage -do - if [ "$(which $X)" = "" ]; then - echo "makeiso.sh error: $X is not in your path." >&2 - exit 1 - elif [ ! -x $(which $X) ]; then - echo "makeiso.sh error: $X is not executable." >&2 - exit 1 - fi -done - -#check to see if memtest.bin is present -if [ ! -w memtest.bin ]; then - echo "makeiso.sh error: cannot find memtest.bin, did you compile it?" >&2 - exit 1 -fi - - -# enlarge the size of memtest.bin -SIZE=$(wc -c memtest.bin | awk '{print $1}') -FILL=$((1474560 - $SIZE)) -dd if=/dev/zero of=fill.tmp bs=$FILL count=1 -cat memtest.bin fill.tmp > memtest.img -rm -f fill.tmp - -echo "Generating iso image ..." - -mkdir "cd" -mkdir "cd/boot" -mv memtest.img cd/boot -cd cd - -# Create the cd.README -echo -e "There is nothing to do here\r\r\nMemtest86+ is located on the bootsector of this CD\r\r\n" > README.TXT -echo -e "Just boot from this CD and Memtest86+ will launch" >> README.TXT - -genisoimage -A "MKISOFS 1.1.2" -p "Memtest86+ 5.31b" -publisher "Samuel D. " -b boot/memtest.img -c boot/boot.catalog -V "MT531" -o memtest.iso . -mv memtest.iso ../mt531b.iso -cd .. -rm -rf cd - -echo "Done! Memtest86+ 5.31b ISO is mt501.iso" diff --git a/memtest86+_old/memsize.c b/memtest86+_old/memsize.c deleted file mode 100644 index 84230d5..0000000 --- a/memtest86+_old/memsize.c +++ /dev/null @@ -1,346 +0,0 @@ -/* memsize.c - MemTest-86 Version 3.3 - * - * Released under version 2 of the Gnu Public License. - * By Chris Brady - */ - -#include "test.h" -#include "defs.h" -#include "config.h" - -short e820_nr = 0; -short memsz_mode = SZ_MODE_BIOS; - -static ulong alt_mem_k = 0; -static ulong ext_mem_k = 0; -static struct e820entry e820[E820MAX]; - -static void sort_pmap(void); -static void memsize_820(void); -static void memsize_801(void); -static int sanitize_e820_map(struct e820entry *orig_map, struct e820entry *new_bios, short old_nr); -static void memsize_linuxbios(); - -/* - * Find out how much memory there is. - */ -#pragma GCC push_options -#pragma GCC optimize ("O0") -void mem_size(void) -{ - int i = 0, flag = 0; - vv->test_pages = 0; - - /* Get the memory size from the BIOS */ - /* Determine the memory map */ - - if (query_linuxbios()) { - flag = 1; - } else if (query_pcbios()) { - flag = 2; - } - - /* On the first time thru only */ - /* Make a copy of the memory info table so that we can re-evaluate */ - /* The memory map later */ - if (e820_nr == 0 && alt_mem_k == 0 && ext_mem_k == 0) { - ext_mem_k = mem_info.e88_mem_k; - alt_mem_k = mem_info.e801_mem_k; - e820_nr = mem_info.e820_nr; - for (i=0; i< mem_info.e820_nr; i++) { - e820[i].addr = mem_info.e820[i].addr; - e820[i].size = mem_info.e820[i].size; - e820[i].type = mem_info.e820[i].type; - } - } - if (flag == 1) { - memsize_linuxbios(); - } else if (flag == 2) { - memsize_820(); - } - - /* Guarantee that pmap entries are in ascending order */ - sort_pmap(); - vv->plim_lower = 0; - vv->plim_upper = vv->pmap[vv->msegs-1].end; - - adj_mem(); -} -#pragma GCC pop_options - -static void sort_pmap(void) -{ - int i, j; - /* Do an insertion sort on the pmap, on an already sorted - * list this should be a O(1) algorithm. - */ - for(i = 0; i < vv->msegs; i++) { - /* Find where to insert the current element */ - for(j = i -1; j >= 0; j--) { - if (vv->pmap[i].start > vv->pmap[j].start) { - j++; - break; - } - } - /* Insert the current element */ - if (i != j) { - struct pmap temp; - temp = vv->pmap[i]; - mt86_memmove(&vv->pmap[j], &vv->pmap[j+1], - (i -j)* sizeof(temp)); - vv->pmap[j] = temp; - } - } -} -static void memsize_linuxbios(void) -{ - int i, n; - /* Build the memory map for testing */ - n = 0; - for (i=0; i < e820_nr; i++) { - unsigned long long end; - - if (e820[i].type != E820_RAM) { - continue; - } - end = e820[i].addr; - end += e820[i].size; - vv->pmap[n].start = (e820[i].addr + 4095) >> 12; - vv->pmap[n].end = end >> 12; - vv->test_pages += vv->pmap[n].end - vv->pmap[n].start; - n++; - } - vv->msegs = n; -} -static void memsize_820() -{ - int i, n, nr; - struct e820entry nm[E820MAX]; - unsigned long long start; - unsigned long long end; - - /* Clean up, adjust and copy the BIOS-supplied E820-map. */ - nr = sanitize_e820_map(e820, nm, e820_nr); - - /* If there is not a good 820 map use the BIOS 801/88 info */ - if (nr < 1 || nr > E820MAX) { - memsize_801(); - return; - } - - /* Build the memory map for testing */ - n = 0; - for (i=0; i RES_START && start < RES_END) { - if (end < RES_END) { - continue; - } - start = RES_END; - } - if (end > RES_START && end < RES_END) { - end = RES_START; - } - vv->pmap[n].start = (start + 4095) >> 12; - vv->pmap[n].end = end >> 12; - vv->test_pages += vv->pmap[n].end - vv->pmap[n].start; - n++; -#if 0 - int epmap = 0; - int lpmap = 0; - if(n > 12) { epmap = 34; lpmap = -12; } - hprint (11+n+lpmap,0+epmap,vv->pmap[n-1].start); - hprint (11+n+lpmap,10+epmap,vv->pmap[n-1].end); - hprint (11+n+lpmap,20+epmap,vv->pmap[n-1].end - vv->pmap[n-1].start); - dprint (11+n+lpmap,30+epmap,nm[i].type,0,0); -#endif - } - } - vv->msegs = n; -} - -static void memsize_801(void) -{ - ulong mem_size; - - /* compare results from 88 and 801 methods and take the greater */ - /* These sizes are for extended memory in 1k units. */ - - if (alt_mem_k < ext_mem_k) { - mem_size = ext_mem_k; - } else { - mem_size = alt_mem_k; - } - /* First we map in the first 640k */ - vv->pmap[0].start = 0; - vv->pmap[0].end = RES_START >> 12; - vv->test_pages = RES_START >> 12; - - /* Now the extended memory */ - vv->pmap[1].start = (RES_END + 4095) >> 12; - vv->pmap[1].end = (mem_size + 1024) >> 2; - vv->test_pages += mem_size >> 2; - vv->msegs = 2; -} - -/* - * Sanitize the BIOS e820 map. - * - * Some e820 responses include overlapping entries. The following - * replaces the original e820 map with a new one, removing overlaps. - * - */ -static int sanitize_e820_map(struct e820entry *orig_map, struct e820entry *new_bios, - short old_nr) -{ - struct change_member { - struct e820entry *pbios; /* pointer to original bios entry */ - unsigned long long addr; /* address for this change point */ - }; - struct change_member change_point_list[2*E820MAX]; - struct change_member *change_point[2*E820MAX]; - struct e820entry *overlap_list[E820MAX]; - struct e820entry biosmap[E820MAX]; - struct change_member *change_tmp; - ulong current_type, last_type; - unsigned long long last_addr; - int chgidx, still_changing; - int overlap_entries; - int new_bios_entry; - int i; - - /* - Visually we're performing the following (1,2,3,4 = memory types)... - Sample memory map (w/overlaps): - ____22__________________ - ______________________4_ - ____1111________________ - _44_____________________ - 11111111________________ - ____________________33__ - ___________44___________ - __________33333_________ - ______________22________ - ___________________2222_ - _________111111111______ - _____________________11_ - _________________4______ - - Sanitized equivalent (no overlap): - 1_______________________ - _44_____________________ - ___1____________________ - ____22__________________ - ______11________________ - _________1______________ - __________3_____________ - ___________44___________ - _____________33_________ - _______________2________ - ________________1_______ - _________________4______ - ___________________2____ - ____________________33__ - ______________________4_ - */ - /* First make a copy of the map */ - for (i=0; iaddr = biosmap[i].addr; - change_point[chgidx++]->pbios = &biosmap[i]; - change_point[chgidx]->addr = biosmap[i].addr + biosmap[i].size; - change_point[chgidx++]->pbios = &biosmap[i]; - } - - /* sort change-point list by memory addresses (low -> high) */ - still_changing = 1; - while (still_changing) { - still_changing = 0; - for (i=1; i < 2*old_nr; i++) { - /* if > , swap */ - /* or, if current= & last=, swap */ - if ((change_point[i]->addr < change_point[i-1]->addr) || - ((change_point[i]->addr == change_point[i-1]->addr) && - (change_point[i]->addr == change_point[i]->pbios->addr) && - (change_point[i-1]->addr != change_point[i-1]->pbios->addr)) - ) - { - change_tmp = change_point[i]; - change_point[i] = change_point[i-1]; - change_point[i-1] = change_tmp; - still_changing=1; - } - } - } - - /* create a new bios memory map, removing overlaps */ - overlap_entries=0; /* number of entries in the overlap table */ - new_bios_entry=0; /* index for creating new bios map entries */ - last_type = 0; /* start with undefined memory type */ - last_addr = 0; /* start with 0 as last starting address */ - /* loop through change-points, determining affect on the new bios map */ - for (chgidx=0; chgidx < 2*old_nr; chgidx++) - { - /* keep track of all overlapping bios entries */ - if (change_point[chgidx]->addr == change_point[chgidx]->pbios->addr) - { - /* add map entry to overlap list (> 1 entry implies an overlap) */ - overlap_list[overlap_entries++]=change_point[chgidx]->pbios; - } - else - { - /* remove entry from list (order independent, so swap with last) */ - for (i=0; ipbios) - overlap_list[i] = overlap_list[overlap_entries-1]; - } - overlap_entries--; - } - /* if there are overlapping entries, decide which "type" to use */ - /* (larger value takes precedence -- 1=usable, 2,3,4,4+=unusable) */ - current_type = 0; - for (i=0; itype > current_type) - current_type = overlap_list[i]->type; - /* continue building up new bios map based on this information */ - if (current_type != last_type) { - if (last_type != 0) { - new_bios[new_bios_entry].size = - change_point[chgidx]->addr - last_addr; - /* move forward only if the new size was non-zero */ - if (new_bios[new_bios_entry].size != 0) - if (++new_bios_entry >= E820MAX) - break; /* no more space left for new bios entries */ - } - if (current_type != 0) { - new_bios[new_bios_entry].addr = change_point[chgidx]->addr; - new_bios[new_bios_entry].type = current_type; - last_addr=change_point[chgidx]->addr; - } - last_type = current_type; - } - } - return(new_bios_entry); -} diff --git a/memtest86+_old/memtest.bin.lds b/memtest86+_old/memtest.bin.lds deleted file mode 100644 index 702cdb1..0000000 --- a/memtest86+_old/memtest.bin.lds +++ /dev/null @@ -1,15 +0,0 @@ -OUTPUT_FORMAT("binary") -OUTPUT_ARCH("i386") - -ENTRY(_main); -SECTIONS { - . = 0; - .bootsect : { *(.bootsect) } - .setup : { *(.setup) } - .memtest : { - _start = . ; - *(.data) - _end = . ; - } - _syssize = (_end - _start + 15) >> 4; -} diff --git a/memtest86+_old/memtest.lds b/memtest86+_old/memtest.lds deleted file mode 100644 index bbb190a..0000000 --- a/memtest86+_old/memtest.lds +++ /dev/null @@ -1,11 +0,0 @@ -OUTPUT_FORMAT("elf32-i386"); -OUTPUT_ARCH(i386); - -ENTRY(_start); -SECTIONS { - . = 0x10000; - _start = . ; - .data : { - *(.data) - } -} diff --git a/memtest86+_old/memtest_shared.lds b/memtest86+_old/memtest_shared.lds deleted file mode 100644 index 603f012..0000000 --- a/memtest86+_old/memtest_shared.lds +++ /dev/null @@ -1,53 +0,0 @@ -OUTPUT_FORMAT("elf32-i386"); -OUTPUT_ARCH(i386); - -ENTRY(startup_32); -SECTIONS { - . = 0; - .text : { - _start = .; - *(.text) - *(.text.*) - *(.plt) - _etext = . ; - } = 0x9090 - .rodata : { - *(.rodata) - *(.rodata.*) - } - .dynsym : { *(.dynsym) } - .dynstr : { *(.dynstr) } - .hash : { *(.hash) } - .gnu.hash : { *(.gnu.hash) } - .dynamic : { *(.dynamic) } - - .rel.text : { *(.rel.text .rel.text.*) } - .rel.rodata : { *(.rel.rodata .rel.rodata.*) } - .rel.data : { *(.rel.data .rel.data.*) } - .rel.got : { *(.rel.got .rel.got.*) } - .rel.plt : { *(.rel.plt .rel.plt.*) } - - . = ALIGN(4); - .data : { - _data = .; - *(.data) - *(.data.*) - } - .got : { - *(.got.plt) - *(.got) - _edata = . ; - } - . = ALIGN(4); - .bss : { - _bss = .; - *(.dynbss) - *(.bss) - *(.bss.*) - *(COMMON) - /* _end must be at least 256 byte aligned */ - . = ALIGN(256); - _end = .; - } - /DISCARD/ : { *(*) } -} diff --git a/memtest86+_old/msr.h b/memtest86+_old/msr.h deleted file mode 100644 index af873a0..0000000 --- a/memtest86+_old/msr.h +++ /dev/null @@ -1,145 +0,0 @@ -#ifndef __ASM_MSR_H -#define __ASM_MSR_H - -/* - * Access to machine-specific registers (available on 586 and better only) - * Note: the rd* operations modify the parameters directly (without using - * pointer indirection), this allows gcc to optimize better - */ - -#define __FIXUP_ALIGN ".align 8" -#define __FIXUP_WORD ".quad" -#define EFAULT 14 /* Bad address */ - -#define rdmsr(msr,val1,val2) \ - __asm__ __volatile__("rdmsr" \ - : "=a" (val1), "=d" (val2) \ - : "c" (msr) : "edi") - -/* -#define rdmsr_safe(msr,val1,val2) ({\ - int _rc; \ - __asm__ __volatile__( \ - "1: rdmsr\n2:\n" \ - ".section .fixup,\"ax\"\n" \ - "3: movl %5,%2\n; jmp 2b\n" \ - ".previous\n" \ - ".section __ex_table,\"a\"\n" \ - " "__FIXUP_ALIGN"\n" \ - ".previous\n" \ - : "=a" (val1), "=d" (val2), "=&r" (_rc) \ - : "c" (msr), "2" (0), "i" (-EFAULT)); \ - _rc; }) -*/ - -#define wrmsr(msr,val1,val2) \ - __asm__ __volatile__("wrmsr" \ - : /* no outputs */ \ - : "c" (msr), "a" (val1), "d" (val2)) - -#define rdtsc(low,high) \ - __asm__ __volatile__("rdtsc" : "=a" (low), "=d" (high)) - -#define rdtscl(low) \ - __asm__ __volatile__("rdtsc" : "=a" (low) : : "edx") - -#define rdtscll(val) \ - __asm__ __volatile__("rdtsc" : "=A" (val)) - -#define write_tsc(val1,val2) wrmsr(0x10, val1, val2) - -#define rdpmc(counter,low,high) \ - __asm__ __volatile__("rdpmc" \ - : "=a" (low), "=d" (high) \ - : "c" (counter)) - -/* symbolic names for some interesting MSRs */ -/* Intel defined MSRs. */ -#define MSR_IA32_P5_MC_ADDR 0 -#define MSR_IA32_P5_MC_TYPE 1 -#define MSR_IA32_PLATFORM_ID 0x17 -#define MSR_IA32_EBL_CR_POWERON 0x2a - -#define MSR_IA32_APICBASE 0x1b -#define MSR_IA32_APICBASE_BSP (1<<8) -#define MSR_IA32_APICBASE_ENABLE (1<<11) -#define MSR_IA32_APICBASE_BASE (0xfffff<<12) - -#define MSR_IA32_UCODE_WRITE 0x79 -#define MSR_IA32_UCODE_REV 0x8b - -#define MSR_IA32_BBL_CR_CTL 0x119 - -#define MSR_IA32_MCG_CAP 0x179 -#define MSR_IA32_MCG_STATUS 0x17a -#define MSR_IA32_MCG_CTL 0x17b - -#define MSR_IA32_THERM_CONTROL 0x19a -#define MSR_IA32_THERM_INTERRUPT 0x19b -#define MSR_IA32_THERM_STATUS 0x19c -#define MSR_IA32_MISC_ENABLE 0x1a0 -#define MSR_IA32_TEMPERATURE_TARGET 0x1a2 - -#define MSR_IA32_DEBUGCTLMSR 0x1d9 -#define MSR_IA32_LASTBRANCHFROMIP 0x1db -#define MSR_IA32_LASTBRANCHTOIP 0x1dc -#define MSR_IA32_LASTINTFROMIP 0x1dd -#define MSR_IA32_LASTINTTOIP 0x1de - -#define MSR_IA32_MC0_CTL 0x400 -#define MSR_IA32_MC0_STATUS 0x401 -#define MSR_IA32_MC0_ADDR 0x402 -#define MSR_IA32_MC0_MISC 0x403 - -#define MSR_P6_PERFCTR0 0xc1 -#define MSR_P6_PERFCTR1 0xc2 -#define MSR_P6_EVNTSEL0 0x186 -#define MSR_P6_EVNTSEL1 0x187 - -#define MSR_IA32_PERF_STATUS 0x198 -#define MSR_IA32_PERF_CTL 0x199 - -/* AMD Defined MSRs */ -#define MSR_K6_EFER 0xC0000080 -#define MSR_K6_STAR 0xC0000081 -#define MSR_K6_WHCR 0xC0000082 -#define MSR_K6_UWCCR 0xC0000085 -#define MSR_K6_EPMR 0xC0000086 -#define MSR_K6_PSOR 0xC0000087 -#define MSR_K6_PFIR 0xC0000088 - -#define MSR_K7_EVNTSEL0 0xC0010000 -#define MSR_K7_PERFCTR0 0xC0010004 -#define MSR_K7_HWCR 0xC0010015 -#define MSR_K7_CLK_CTL 0xC001001b -#define MSR_K7_FID_VID_CTL 0xC0010041 -#define MSR_K7_VID_STATUS 0xC0010042 - -/* Centaur-Hauls/IDT defined MSRs. */ -#define MSR_IDT_FCR1 0x107 -#define MSR_IDT_FCR2 0x108 -#define MSR_IDT_FCR3 0x109 -#define MSR_IDT_FCR4 0x10a - -#define MSR_IDT_MCR0 0x110 -#define MSR_IDT_MCR1 0x111 -#define MSR_IDT_MCR2 0x112 -#define MSR_IDT_MCR3 0x113 -#define MSR_IDT_MCR4 0x114 -#define MSR_IDT_MCR5 0x115 -#define MSR_IDT_MCR6 0x116 -#define MSR_IDT_MCR7 0x117 -#define MSR_IDT_MCR_CTRL 0x120 - -/* VIA Cyrix defined MSRs*/ -#define MSR_VIA_FCR 0x1107 -#define MSR_VIA_LONGHAUL 0x110a -#define MSR_VIA_BCR2 0x1147 - -/* Transmeta defined MSRs */ -#define MSR_TMTA_LONGRUN_CTRL 0x80868010 -#define MSR_TMTA_LONGRUN_FLAGS 0x80868011 -#define MSR_TMTA_LRTI_READOUT 0x80868018 -#define MSR_TMTA_LRTI_VOLT_MHZ 0x8086801a - -#endif /* __ASM_MSR_H */ diff --git a/memtest86+_old/mt86+_loader b/memtest86+_old/mt86+_loader deleted file mode 100644 index 030ea1a..0000000 Binary files a/memtest86+_old/mt86+_loader and /dev/null differ diff --git a/memtest86+_old/mt86+_loader.asm b/memtest86+_old/mt86+_loader.asm deleted file mode 100644 index 8472262..0000000 --- a/memtest86+_old/mt86+_loader.asm +++ /dev/null @@ -1,231 +0,0 @@ -; A loader for www.memtest.org images, by Eric Auer 2003. -; This assumes that the image starts with the boot sector, -; which has the size of setup.S in sectors in a byte at offset -; 1f1h (497). Further, I assume setup.S directly after the boot -; sector and the actual memtest head.S after setup.S ... - -; This version is derived from memtestL loader, which loads -; memtest.bin from a separate file. This version is meant to -; be used like (DOS / Unix variants): -; copy /b memteste.bin + memtest.bin memtest.exe -; cat memteste.bin memtest.bin > memtest.exe -; The good thing is that you get a single file which can be -; compressed, for example with http://upx.sf.net/ (UPX). - -%define fullsize (150024 + buffer - exeh) - ; 150024 is the size of memtest86+ V5.01, adjust as needed! - -%define stacksize 2048 -%define stackpara ((stacksize + 15) / 16) - - ; the trick is that NASM believes the header would be part - ; of the loaded image, so we "org 20h bytes too early" to fix: - org 0e0h ; NASM thinks after header we have 100h - ; which is what we want it to think. - -exeh: db "MZ" - dw fullsize % 512 ; how much to load from - dw (fullsize + 511) / 512 ; .exe to RAM - dw 0 ; no relocations used - dw 2 ; header size is 2 * 16 bytes - dw stackpara ; minimum heap is 128 * 16 bytes, for stack - dw stackpara ; we do not need more heap either - dw (fullsize + 15) / 16 ; SS is after file - ; segment offsets are relative to PSPseg+10h - ; initial DS and ES point to PSPseg, and file - ; except headers is loaded to PSPseg+10h. - - dw stacksize-4 ; initial SP value - dw 0 ; no checksum - dw 100h ; initial IP - dw -10h ; initial CS relative to PSPseg+10h - dw 0 ; no relocation table, "offset 0 in file" - dw 0 ; this is not an overlay - db "MEMT" ; padding to a multiple of 16 bytes - - ; loaded part begins here (set CS so that IP is 100h here) - -start: ; entry point ; if you use obj + linker, use "..start:" - mov ah, 01h - mov bh, 00h - mov cx, 2000h - int 10h - - mov ax,cs ; *** - mov ds,ax ; *** - mov es,ax ; *** - - ; test if we have 386 or better: - pushf ; save flags - xor ax,ax - push ax - popf ; try to clear all bits - pushf - pop ax - and ax,0f000h - cmp ax,0f000h - jz noinst1 ; 4 msb stuck to 1: 808x or 80186 - mov ax,0f000h - push ax - popf ; try to set 4 msb - pushf - pop ax - test ax,0f000h - jz noinst1 ; 4 msb stuck to 0: 80286 - popf ; restore flags - jmp short found386 - -noinst1: - popf ; restore flags - mov dx,need386 - jmp generror - - -found386: ; now test if the system is in real mode: - smsw ax ; MSW is the low half of CR0 - ; (smsw is not priv'd, unlike mov eax,cr0) - test al,1 ; if the PE (protected mode) flag on? -%ifndef DEBUG ; ignore findings in debug mode - jnz foundprotected -%endif - jmp foundreal - -foundprotected: - mov dx,noreal - jmp generror - -; ------------ - -need386 db "Sorry, you need at least a 386 CPU to use Memtest86+." - db 13,10,"$" -noreal db "You cannot run Memtest86+ if the system already is in" - db " protected mode.",13,10,"$" - -; ------------ - -generror: ; generic error exit - push cs - pop ds - push cs - pop es - mov ah,9 - int 21h - mov ax,4c01h - int 21h - -; ------------ - -foundreal: - mov cx,buffer+15 - shr cx,4 ; buffer offset in paragraphs - mov ax,cs - add ax,cx ; buffer offset in paragraphs - ; now AX is the buffer segment - mov [cs:bufsetup+2],ax ; far pointer to boot sector now - mov cx,20h ; size of boot sector in paragraphs - add [cs:bufsetup+2],cx ; far pointer to setup now - movzx eax,ax - shl eax,4 ; linear buffer offset - mov [cs:buflinear],eax - -findpoint: ; now patch the loader! - mov al,[buffer+1f1h] ; size of setup.S in sectors - ; should be 4 ... - inc al ; the boot sector itself - movzx eax,al - shl eax,9 ; log 2 of sector size - add [cs:buflinear],eax ; linear address of head.S now - mov ax,[buffer+251h] ; should be jmp far dword (ofs, seg) - cmp ax,0ea66h - jz foundpatch -patchbug: ; could not patch the jump - mov dx,nopatch - jmp generror - -gdtbug: - mov dx,nogdt - jmp generror - -foundpatch: - mov eax,[cs:buflinear] - mov [buffer+253h],eax ; patch the protected mode entry jump - ; (offset only - segment selector unchanged: flat linear CS) - -findgdt: - mov eax,[cs:buffer+20ch] ; should be lgdt offset - and eax,00ffffffh - cmp eax,0016010fh ; lgdt ... - jnz gdtbug - - mov ax,[cs:buffer+20fh] ; GDTR contents pointer - mov bx,ax - mov eax,[cs:buffer+200h+bx+2] ; GDT linear offset - and eax,1ffh ; assume GDT in first sector of setup.S - ; *** WARNING: this is needed because setup.S contains - ; *** HARDCODED offset of setup.S on linear 90200h, which - ; *** is 90000h + bootsect.S ... flaw in Memtest86! - - mov cx,[cs:bufsetup+2] ; setup.S segment - movzx ecx,cx - shl ecx,4 ; linear setup.S address - add eax,ecx ; fixed GDT linear offset - mov [cs:buffer+200h+bx+2],eax ; patch it - - ;mov dx,trying - ;mov ah,9 - ;int 21h - - ;xor ax,ax - ;int 16h ; wait for a keypress from the user - - mov ax,[cs:bufsetup+2] ; setup segment - mov ds,ax ; set nice data segments for setup.S ... - mov es,ax - xor ax,ax - mov fs,ax - mov gs,ax - - cli - lss sp,[cs:newstack] ; stack in first 64k now! - movzx esp,sp ; ensure 16bit stack pointer - ; Memtest86 head.S assumes that it can just turn SS to - ; linear. This would put the stack at 0:200h or so for us - ; if we fail to move the stack around ... - -%ifdef DEBUG - mov ebp,[cs:buflinear] ; will show up in debugging logs - mov esi,[cs:bufsetup] ; will show up in debugging logs -%endif - - jmp far [cs:bufsetup] - ; setup.S will enable the A20 (ignoring HIMEM, just using - ; the classic 8042 programming trick) and turn on protected - ; mode. Then it will jump to head.S, which luckily can run - ; from any offset inside the linear 4 GB CS ... - -; ------------ - -buflinear dd 0 ; linear address of head.S entry point -bufsetup dw 0,0 ; far pointer to setup.S entry point - -newstack dw 03fch,0 ; beware, stack will overwrite IDT. - -; ------------ - -nopatch db "jmp far dword not found at setup.S offset 37h,",13,10 - db "(file offset 237h is not 66h, 0eah)",13,10 - db "please adjust and recompile memtestl...",13,10,"$" - -nogdt db "lgdt [...] not found at setup.S offset 0ch,",13,10 - db "(file offset 20ch is not 0fh, 01h, 16h)",13,10 - db "please adjust and recompile memtestl...",13,10,"$" - -trying db "Now trying to start Memtest86...",13,10 - db "You have to reboot to leave Memtest86 again.",13,10 - db "Press a key to go on.",13,10,"$" - -; ------------ - - align 16 -buffer: ; a label pointing to where in the file memtest.bin will be. - diff --git a/memtest86+_old/patn.c b/memtest86+_old/patn.c deleted file mode 100644 index fabd2ea..0000000 --- a/memtest86+_old/patn.c +++ /dev/null @@ -1,144 +0,0 @@ -/* Pattern extension for memtest86 - * - * Generates patterns for the Linux kernel's BadRAM extension that avoids - * allocation of faulty pages. - * - * Released under version 2 of the Gnu Public License. - * - * By Rick van Rein, vanrein@zonnet.nl - * ---------------------------------------------------- - * MemTest86+ V1.60 Specific code (GPL V2.0) - * By Samuel DEMEULEMEESTER, sdemeule@memtest.org - * http://www.x86-secret.com - http://www.memtest.org - */ - - -#include "test.h" - - -/* - * DEFAULT_MASK covers a longword, since that is the testing granularity. - */ -#define DEFAULT_MASK ((~0L) << 2) - - -/* extern struct vars *v; */ - - -/* What it does: - * - Keep track of a number of BadRAM patterns in an array; - * - Combine new faulty addresses with it whenever possible; - * - Keep masks as selective as possible by minimising resulting faults; - * - Print a new pattern only when the pattern array is changed. - */ - -#define COMBINE_MASK(a,b,c,d) ((a & b & c & d) | (~a & b & ~c & d)) - -/* Combine two adr/mask pairs to one adr/mask pair. - */ -void combine (ulong adr1, ulong mask1, ulong adr2, ulong mask2, - ulong *adr, ulong *mask) { - - *mask = COMBINE_MASK (adr1, mask1, adr2, mask2); - - *adr = adr1 | adr2; - *adr &= *mask; // Normalise, no fundamental need for this -} - -/* Count the number of addresses covered with a mask. - */ -ulong addresses (ulong mask) { - ulong ctr=1; - int i=32; - while (i-- > 0) { - if (! (mask & 1)) { - ctr += ctr; - } - mask >>= 1; - } - return ctr; -} - -/* Count how much more addresses would be covered by adr1/mask1 when combined - * with adr2/mask2. - */ -ulong combicost (ulong adr1, ulong mask1, ulong adr2, ulong mask2) { - ulong cost1=addresses (mask1); - ulong tmp, mask; - combine (adr1, mask1, adr2, mask2, &tmp, &mask); - return addresses (mask) - cost1; -} - -/* Find the cheapest array index to extend with the given adr/mask pair. - * Return -1 if nothing below the given minimum cost can be found. - */ -int cheapindex (ulong adr1, ulong mask1, ulong mincost) { - int i=vv->numpatn; - int idx=-1; - while (i-- > 0) { - ulong tmpcost=combicost(vv->patn[i].adr, vv->patn[i].mask, adr1, mask1); - if (tmpcost < mincost) { - mincost=tmpcost; - idx=i; - } - } - return idx; -} - -/* Try to find a relocation index for idx if it costs nothing. - * Return -1 if no such index exists. - */ -int relocateidx (int idx) { - ulong adr =vv->patn[idx].adr; - ulong mask=vv->patn[idx].mask; - int new; - vv->patn[idx].adr ^= ~0L; // Never select idx - new=cheapindex (adr, mask, 1+addresses (mask)); - vv->patn[idx].adr = adr; - return new; -} - -/* Relocate the given index idx only if free of charge. - * This is useful to combine to `neighbouring' sections to integrate. - * Inspired on the Buddy memalloc principle in the Linux kernel. - */ -void relocateiffree (int idx) { - int newidx=relocateidx (idx); - if (newidx>=0) { - ulong cadr, cmask; - combine (vv->patn [newidx].adr, vv->patn[newidx].mask, - vv->patn [ idx].adr, vv->patn[ idx].mask, - &cadr, &cmask); - vv->patn[newidx].adr =cadr; - vv->patn[newidx].mask=cmask; - if (idx < --vv->numpatn) { - vv->patn[idx].adr =vv->patn[vv->numpatn].adr; - vv->patn[idx].mask=vv->patn[vv->numpatn].mask; - } - relocateiffree (newidx); - } -} - -/* Insert a single faulty address in the pattern array. - * Return 1 only if the array was changed. - */ -int insertaddress (ulong adr) { - if (cheapindex (adr, DEFAULT_MASK, 1L) != -1) - return 0; - - if (vv->numpatn < BADRAM_MAXPATNS) { - vv->patn[vv->numpatn].adr =adr; - vv->patn[vv->numpatn].mask=DEFAULT_MASK; - vv->numpatn++; - relocateiffree (vv->numpatn-1); - } else { - int idx=cheapindex (adr, DEFAULT_MASK, ~0L); - ulong cadr, cmask; - combine (vv->patn [idx].adr, vv->patn[idx].mask, - adr, DEFAULT_MASK, &cadr, &cmask); - vv->patn[idx].adr =cadr; - vv->patn[idx].mask=cmask; - relocateiffree (idx); - } - return 1; -} diff --git a/memtest86+_old/pci.c b/memtest86+_old/pci.c deleted file mode 100644 index 075a07f..0000000 --- a/memtest86+_old/pci.c +++ /dev/null @@ -1,177 +0,0 @@ -/* pci.c - MemTest-86 Version 3.2 - * - * Released under version 2 of the Gnu Public License. - * By Chris Brady - * ---------------------------------------------------- - * MemTest86+ V5.00 Specific code (GPL V2.0) - * By Samuel DEMEULEMEESTER, sdemeule@memtest.org - * http://www.x86-secret.com - http://www.memtest.org - */ - -#include "io.h" -#include "pci.h" -#include "test.h" -#include "stdint.h" -#include "cpuid.h" - -#define PCI_CONF_TYPE_NONE 0 -#define PCI_CONF_TYPE_1 1 -#define PCI_CONF_TYPE_2 2 - -extern struct cpu_ident cpu_id; - -static unsigned char pci_conf_type = PCI_CONF_TYPE_NONE; - -#define PCI_CONF1_ADDRESS(bus, dev, fn, reg) \ - (0x80000000 | (bus << 16) | (dev << 11) | (fn << 8) | (reg & ~3)) - -#define PCI_CONF2_ADDRESS(dev, reg) (unsigned short)(0xC000 | (dev << 8) | reg) - -#define PCI_CONF3_ADDRESS(bus, dev, fn, reg) \ - (0x80000000 | (((reg >> 8) & 0xF) << 24) | (bus << 16) | ((dev & 0x1F) << 11) | (fn << 8) | (reg & 0xFF)) - -int pci_conf_read(unsigned bus, unsigned dev, unsigned fn, unsigned reg, unsigned len, unsigned long *value) -{ - int result; - - if (!value || (bus > 255) || (dev > 31) || (fn > 7) || (reg > 255 && pci_conf_type != PCI_CONF_TYPE_1)) - return -1; - - result = -1; - switch(pci_conf_type) { - case PCI_CONF_TYPE_1: - if(reg < 256){ - outl(PCI_CONF1_ADDRESS(bus, dev, fn, reg), 0xCF8); - }else{ - outl(PCI_CONF3_ADDRESS(bus, dev, fn, reg), 0xCF8); - } - switch(len) { - case 1: *value = inb(0xCFC + (reg & 3)); result = 0; break; - case 2: *value = inw(0xCFC + (reg & 2)); result = 0; break; - case 4: *value = inl(0xCFC); result = 0; break; - } - break; - case PCI_CONF_TYPE_2: - outb(0xF0 | (fn << 1), 0xCF8); - outb(bus, 0xCFA); - - switch(len) { - case 1: *value = inb(PCI_CONF2_ADDRESS(dev, reg)); result = 0; break; - case 2: *value = inw(PCI_CONF2_ADDRESS(dev, reg)); result = 0; break; - case 4: *value = inl(PCI_CONF2_ADDRESS(dev, reg)); result = 0; break; - } - outb(0, 0xCF8); - break; - } - return result; -} - -int pci_conf_write(unsigned bus, unsigned dev, unsigned fn, unsigned reg, unsigned len, unsigned long value) -{ - int result; - - if (!value || (bus > 255) || (dev > 31) || (fn > 7) || (reg > 255 && pci_conf_type != PCI_CONF_TYPE_1)) - return -1; - - result = -1; - - switch(pci_conf_type) - { - case PCI_CONF_TYPE_1: - if(reg < 256){ - outl(PCI_CONF1_ADDRESS(bus, dev, fn, reg), 0xCF8); - }else{ - outl(PCI_CONF3_ADDRESS(bus, dev, fn, reg), 0xCF8); - } - switch(len) { - case 1: outb(value, 0xCFC + (reg & 3)); result = 0; break; - case 2: outw(value, 0xCFC + (reg & 2)); result = 0; break; - case 4: outl(value, 0xCFC); result = 0; break; - } - break; - case PCI_CONF_TYPE_2: - outb(0xF0 | (fn << 1), 0xCF8); - outb(bus, 0xCFA); - - switch(len) { - case 1: outb(value, PCI_CONF2_ADDRESS(dev, reg)); result = 0; break; - case 2: outw(value, PCI_CONF2_ADDRESS(dev, reg)); result = 0; break; - case 4: outl(value, PCI_CONF2_ADDRESS(dev, reg)); result = 0; break; - } - outb(0, 0xCF8); - break; - } - return result; -} - -static int pci_sanity_check(void) -{ - unsigned long value; - int result; - /* Do a trivial check to make certain we can see a host bridge. - * There are reportedly some buggy chipsets from intel and - * compaq where this test does not work, I will worry about - * that when we support them. - */ - result = pci_conf_read(0, 0, 0, PCI_CLASS_DEVICE, 2, &value); - if (result == 0) { - result = -1; - if (value == PCI_CLASS_BRIDGE_HOST) { - result = 0; - } - } - return result; -} - -static int pci_check_direct(void) -{ - unsigned char tmpCFB; - unsigned int tmpCF8; - - if (cpu_id.vend_id.char_array[0] == 'A' && cpu_id.vers.bits.family == 0xF) { - pci_conf_type = PCI_CONF_TYPE_1; - return 0; - } else { - /* Check if configuration type 1 works. */ - pci_conf_type = PCI_CONF_TYPE_1; - tmpCFB = inb(0xCFB); - outb(0x01, 0xCFB); - tmpCF8 = inl(0xCF8); - outl(0x80000000, 0xCF8); - if ((inl(0xCF8) == 0x80000000) && (pci_sanity_check() == 0)) { - outl(tmpCF8, 0xCF8); - outb(tmpCFB, 0xCFB); - return 0; - } - outl(tmpCF8, 0xCF8); - - /* Check if configuration type 2 works. */ - - pci_conf_type = PCI_CONF_TYPE_2; - outb(0x00, 0xCFB); - outb(0x00, 0xCF8); - outb(0x00, 0xCFA); - if (inb(0xCF8) == 0x00 && inb(0xCFA) == 0x00 && (pci_sanity_check() == 0)) { - outb(tmpCFB, 0xCFB); - return 0; - - } - - outb(tmpCFB, 0xCFB); - - /* Nothing worked return an error */ - pci_conf_type = PCI_CONF_TYPE_NONE; - return -1; - - } -} - -int pci_init(void) -{ - int result; - /* For now just make certain we can directly - * use the pci functions. - */ - result = pci_check_direct(); - return result; -} diff --git a/memtest86+_old/pci.h b/memtest86+_old/pci.h deleted file mode 100644 index f21c478..0000000 --- a/memtest86+_old/pci.h +++ /dev/null @@ -1,96 +0,0 @@ -#ifndef MEMTEST_PCI_H -#define MEMTEST_PCI_H - -int pci_conf_read(unsigned bus, unsigned dev, unsigned fn, unsigned reg, - unsigned len, unsigned long *value); -int pci_conf_write(unsigned bus, unsigned dev, unsigned fn, unsigned reg, - unsigned len, unsigned long value); -int pci_init(void); - -#define MAKE_PCIE_ADDRESS(bus, device, function) (((bus) & 0xFF)<<20) | (((device) & 0x1F)<<15) | (((function) & 0x7)<<12) - -/* - * Under PCI, each device has 256 bytes of configuration address space, - * of which the first 64 bytes are standardized as follows: - */ -#define PCI_VENDOR_ID 0x00 /* 16 bits */ -#define PCI_DEVICE_ID 0x02 /* 16 bits */ -#define PCI_COMMAND 0x04 /* 16 bits */ -#define PCI_COMMAND_IO 0x1 /* Enable response in I/O space */ -#define PCI_COMMAND_MEMORY 0x2 /* Enable response in Memory space */ -#define PCI_COMMAND_MASTER 0x4 /* Enable bus mastering */ -#define PCI_COMMAND_SPECIAL 0x8 /* Enable response to special cycles */ -#define PCI_COMMAND_INVALIDATE 0x10 /* Use memory write and invalidate */ -#define PCI_COMMAND_VGA_PALETTE 0x20 /* Enable palette snooping */ -#define PCI_COMMAND_PARITY 0x40 /* Enable parity checking */ -#define PCI_COMMAND_WAIT 0x80 /* Enable address/data stepping */ -#define PCI_COMMAND_SERR 0x100 /* Enable SERR */ -#define PCI_COMMAND_FAST_BACK 0x200 /* Enable back-to-back writes */ - -#define PCI_STATUS 0x06 /* 16 bits */ -#define PCI_STATUS_CAP_LIST 0x10 /* Support Capability List */ -#define PCI_STATUS_66MHZ 0x20 /* Support 66 Mhz PCI 2.1 bus */ -#define PCI_STATUS_UDF 0x40 /* Support User Definable Features [obsolete] */ -#define PCI_STATUS_FAST_BACK 0x80 /* Accept fast-back to back */ -#define PCI_STATUS_PARITY 0x100 /* Detected parity error */ -#define PCI_STATUS_DEVSEL_MASK 0x600 /* DEVSEL timing */ -#define PCI_STATUS_DEVSEL_FAST 0x000 -#define PCI_STATUS_DEVSEL_MEDIUM 0x200 -#define PCI_STATUS_DEVSEL_SLOW 0x400 -#define PCI_STATUS_SIG_TARGET_ABORT 0x800 /* Set on target abort */ -#define PCI_STATUS_REC_TARGET_ABORT 0x1000 /* Master ack of " */ -#define PCI_STATUS_REC_MASTER_ABORT 0x2000 /* Set on master abort */ -#define PCI_STATUS_SIG_SYSTEM_ERROR 0x4000 /* Set when we drive SERR */ -#define PCI_STATUS_DETECTED_PARITY 0x8000 /* Set on parity error */ - -#define PCI_CLASS_REVISION 0x08 /* High 24 bits are class, low 8 - revision */ -#define PCI_REVISION_ID 0x08 /* Revision ID */ -#define PCI_CLASS_PROG 0x09 /* Reg. Level Programming Interface */ -#define PCI_CLASS_DEVICE 0x0a /* Device class */ - -#define PCI_CACHE_LINE_SIZE 0x0c /* 8 bits */ -#define PCI_LATENCY_TIMER 0x0d /* 8 bits */ -#define PCI_HEADER_TYPE 0x0e /* 8 bits */ -#define PCI_HEADER_TYPE_NORMAL 0 -#define PCI_HEADER_TYPE_BRIDGE 1 -#define PCI_HEADER_TYPE_CARDBUS 2 - -#define PCI_BIST 0x0f /* 8 bits */ -#define PCI_BIST_CODE_MASK 0x0f /* Return result */ -#define PCI_BIST_START 0x40 /* 1 to start BIST, 2 secs or less */ -#define PCI_BIST_CAPABLE 0x80 /* 1 if BIST capable */ - -/* - * Base addresses specify locations in memory or I/O space. - * Decoded size can be determined by writing a value of - * 0xffffffff to the register, and reading it back. Only - * 1 bits are decoded. - */ -#define PCI_BASE_ADDRESS_0 0x10 /* 32 bits */ -#define PCI_BASE_ADDRESS_1 0x14 /* 32 bits [htype 0,1 only] */ -#define PCI_BASE_ADDRESS_2 0x18 /* 32 bits [htype 0 only] */ -#define PCI_BASE_ADDRESS_3 0x1c /* 32 bits */ -#define PCI_BASE_ADDRESS_4 0x20 /* 32 bits */ -#define PCI_BASE_ADDRESS_5 0x24 /* 32 bits */ -#define PCI_BASE_ADDRESS_SPACE 0x01 /* 0 = memory, 1 = I/O */ -#define PCI_BASE_ADDRESS_SPACE_IO 0x01 -#define PCI_BASE_ADDRESS_SPACE_MEMORY 0x00 -#define PCI_BASE_ADDRESS_MEM_TYPE_MASK 0x06 -#define PCI_BASE_ADDRESS_MEM_TYPE_32 0x00 /* 32 bit address */ -#define PCI_BASE_ADDRESS_MEM_TYPE_1M 0x02 /* Below 1M [obsolete] */ -#define PCI_BASE_ADDRESS_MEM_TYPE_64 0x04 /* 64 bit address */ -#define PCI_BASE_ADDRESS_MEM_PREFETCH 0x08 /* prefetchable? */ -#define PCI_BASE_ADDRESS_MEM_MASK (~0x0fUL) -#define PCI_BASE_ADDRESS_IO_MASK (~0x03UL) -/* bit 1 is reserved if address_space = 1 */ - - -/* Device classes and subclasses */ -#define PCI_CLASS_NOT_DEFINED 0x0000 -#define PCI_CLASS_NOT_DEFINED_VGA 0x0001 - -#define PCI_BASE_CLASS_BRIDGE 0x06 -#define PCI_CLASS_BRIDGE_HOST 0x0600 - -#endif /* MEMTEST_PCI_H */ diff --git a/memtest86+_old/precomp.bin b/memtest86+_old/precomp.bin deleted file mode 100755 index 5738e08..0000000 Binary files a/memtest86+_old/precomp.bin and /dev/null differ diff --git a/memtest86+_old/random.c b/memtest86+_old/random.c deleted file mode 100644 index 69dd140..0000000 --- a/memtest86+_old/random.c +++ /dev/null @@ -1,38 +0,0 @@ -/******************************************************************/ -/* Random number generator */ -/* concatenation of following two 16-bit multiply with carry generators */ -/* x(n)=a*x(n-1)+carry mod 2^16 and y(n)=b*y(n-1)+carry mod 2^16, */ -/* number and carry packed within the same 32 bit integer. */ -/******************************************************************/ -#include "stdint.h" -#include "cpuid.h" -#include "smp.h" - -/* Keep a separate seed for each CPU */ -/* Space the seeds by at least a cache line or performance suffers big time! */ -static unsigned int SEED_X[MAX_CPUS*16]; -static unsigned int SEED_Y[MAX_CPUS*16]; - -unsigned long rand (int cpu) -{ - static unsigned int a = 18000, b = 30903; - int me; - - me = cpu*16; - - SEED_X[me] = a*(SEED_X[me]&65535) + (SEED_X[me]>>16); - SEED_Y[me] = b*(SEED_Y[me]&65535) + (SEED_Y[me]>>16); - - return ((SEED_X[me]<<16) + (SEED_Y[me]&65535)); -} - - -void rand_seed( unsigned int seed1, unsigned int seed2, int cpu) -{ - int me; - - me = cpu*16; - SEED_X[me] = seed1; - SEED_Y[me] = seed2; -} - diff --git a/memtest86+_old/reloc.c b/memtest86+_old/reloc.c deleted file mode 100644 index bde268f..0000000 --- a/memtest86+_old/reloc.c +++ /dev/null @@ -1,268 +0,0 @@ -/* reloc.c - MemTest-86 Version 3.3 - * - * Released under version 2 of the Gnu Public License. - * By Eric Biederman - */ - -#include "stddef.h" -#include "stdint.h" -#include "elf.h" - -#define __ELF_NATIVE_CLASS 32 -#define ELF_MACHINE_NO_RELA 1 - -/* We use this macro to refer to ELF types independent of the native wordsize. - `ElfW(TYPE)' is used in place of `Elf32_TYPE' or `Elf64_TYPE'. */ -#define ElfW(type) _ElfW (Elf, __ELF_NATIVE_CLASS, type) -#define _ElfW(e,w,t) _ElfW_1 (e, w, _##t) -#define _ElfW_1(e,w,t) e##w##t -#define ELFW(type) _ElfW (ELF, __ELF_NATIVE_CLASS, type) - -static inline void __attribute__ ((unused)) -fail_assert(unsigned line_num, unsigned code) { - // Put line num in low bits of %edx and a sentinel in the high bits. - line_num |= 0xEEEC0000; // eek! - asm __volatile__ ("movl %%edx, %%edx" - : "=d"(line_num), "=c" (code) - : "d" (line_num), "c" (code)); - - // Now observe %edx in a virtual machine's debugger. - // Have a nice day. - while(1) {} -} - -// TODO(jcoiner): It would be nice to try to print a message here, -// even though we don't have function calls yet, maybe we can write -// to the screen before going into our infinite loop. -#define assert(expr, code) do { \ - if (!(expr)) { fail_assert(__LINE__, code); } \ - } while(0) - -/* This #define produces dynamic linking inline functions for - bootstrap relocation instead of general-purpose relocation. */ -#define RTLD_BOOTSTRAP - -struct link_map { - ElfW(Addr) l_addr; /* Current load address */ - ElfW(Addr) ll_addr; /* Last load address */ - ElfW(Dyn) *l_ld; - /* Indexed pointers to dynamic section. - [0,DT_NUM) are indexed by the processor-independent tags. - [DT_NUM,DT_NUM+DT_PROCNUM) are indexed by the tag minus DT_LOPROC. - [DT_NUM+DT_PROCNUM, - DT_NUM+DT_PROCNUM+DT_EXTRANUM) - are indexed by DT_EXTRATAGIDX(tagvalue) (see ). */ - ElfW(Dyn) *l_info[DT_NUM + DT_PROCNUM + DT_EXTRANUM]; -}; - -/* Return the link-time address of _DYNAMIC. Conveniently, this is the - first element of the GOT. This must be inlined in a function which - uses global data. */ -static inline Elf32_Addr __attribute__ ((unused)) -elf_machine_dynamic(void) { - register Elf32_Addr *got asm ("%ebx"); - return *got; -} - -/* Return the run-time load address of the shared object. */ -static inline Elf32_Addr __attribute__ ((unused)) -elf_machine_load_address(void) { - Elf32_Addr addr; - asm volatile ("leal _start@GOTOFF(%%ebx), %0\n" - : "=r" (addr) : : "cc"); - return addr; -} - -/* Perform the relocation specified by RELOC and SYM (which is fully resolved). - MAP is the object containing the reloc. */ -static inline void -elf_machine_rel(struct link_map *map, const Elf32_Rel *reloc, - const Elf32_Sym *sym, Elf32_Addr *const reloc_addr) { - Elf32_Addr ls_addr, s_addr; - Elf32_Addr value; - if (ELF32_R_TYPE (reloc->r_info) == R_386_RELATIVE) - { - *reloc_addr += map->l_addr - map->ll_addr; - return; - } - if (ELF32_R_TYPE(reloc->r_info) == R_386_NONE) { - return; - } - value = sym->st_value; - /* Every section except the undefined section has a base of map->l_addr */ - ls_addr = sym->st_shndx == SHN_UNDEF ? 0 : map->ll_addr; - s_addr = sym->st_shndx == SHN_UNDEF ? 0 : map->l_addr; - - switch (ELF32_R_TYPE (reloc->r_info)) - { - case R_386_COPY: { - /* Roll memcpy by hand as we don't have function calls yet. */ - unsigned char *dest, *src; - long i; - dest = (unsigned char *)reloc_addr; - src = (unsigned char *)(value + s_addr); - for(i = 0; i < sym->st_size; i++) { - dest[i] = src[i]; - } - break; - } - case R_386_GLOB_DAT: - *reloc_addr = s_addr + value; - break; - case R_386_JMP_SLOT: - *reloc_addr = s_addr + value; - break; - case R_386_32: - if (map->ll_addr == 0) { - *reloc_addr += value; - } - *reloc_addr += s_addr - ls_addr; - break; - case R_386_PC32: - if (map->ll_addr == 0) { - *reloc_addr += value - reloc->r_offset; - } - *reloc_addr += (s_addr - map->l_addr) - (ls_addr - map->ll_addr); - break; - default: - assert (! "unexpected dynamic reloc type", 0); - break; - } -} - -/* Read the dynamic section at DYN and fill in INFO with indices DT_*. */ - -static inline void __attribute__ ((unused)) -elf_get_dynamic_info(ElfW(Dyn) *dyn, ElfW(Addr) l_addr, - ElfW(Dyn) *info[DT_NUM + DT_PROCNUM + DT_EXTRANUM]) { - if (! dyn) - return; - - while (dyn->d_tag != DT_NULL) { - if (dyn->d_tag < DT_NUM) - info[dyn->d_tag] = dyn; - else if (dyn->d_tag >= DT_LOPROC && - dyn->d_tag < DT_LOPROC + DT_PROCNUM) - info[dyn->d_tag - DT_LOPROC + DT_NUM] = dyn; - else if ((Elf32_Word) DT_EXTRATAGIDX (dyn->d_tag) < DT_EXTRANUM) - info[DT_EXTRATAGIDX (dyn->d_tag) + DT_NUM + DT_PROCNUM] = dyn; -#if 0 - else { - // JPC this is failing, BOZO! - // Not surprising, there are a bunch of sections we don't - // handle and which modern ELF relocation code in glibc - // will handle and relocate. Bah. - assert (! "bad dynamic tag", dyn->d_tag); - } -#endif - ++dyn; - } - - if (info[DT_PLTGOT] != NULL) - info[DT_PLTGOT]->d_un.d_ptr += l_addr; - if (info[DT_STRTAB] != NULL) - info[DT_STRTAB]->d_un.d_ptr += l_addr; - if (info[DT_SYMTAB] != NULL) - info[DT_SYMTAB]->d_un.d_ptr += l_addr; -#if ! ELF_MACHINE_NO_RELA - if (info[DT_RELA] != NULL) { - assert (info[DT_RELAENT]->d_un.d_val == sizeof (ElfW(Rela)), 0); - info[DT_RELA]->d_un.d_ptr += l_addr; - } -#endif -#if ! ELF_MACHINE_NO_REL - if (info[DT_REL] != NULL) { - assert (info[DT_RELENT]->d_un.d_val == sizeof (ElfW(Rel)), 0); - info[DT_REL]->d_un.d_ptr += l_addr; - } -#endif - if (info[DT_PLTREL] != NULL) { -#if ELF_MACHINE_NO_RELA - assert (info[DT_PLTREL]->d_un.d_val == DT_REL, 0); -#elif ELF_MACHINE_NO_REL - assert (info[DT_PLTREL]->d_un.d_val == DT_RELA, 0); -#else - assert (info[DT_PLTREL]->d_un.d_val == DT_REL - || info[DT_PLTREL]->d_un.d_val == DT_RELA, 0); -#endif - } - if (info[DT_JMPREL] != NULL) - info[DT_JMPREL]->d_un.d_ptr += l_addr; -} - -/* Perform the relocations in MAP on the running program image as specified - by RELTAG, SZTAG. If LAZY is nonzero, this is the first pass on PLT - relocations; they should be set up to call _dl_runtime_resolve, rather - than fully resolved now. */ - -static inline void -elf_dynamic_do_rel(struct link_map *map, - ElfW(Addr) reladdr, ElfW(Addr) relsize) { - const ElfW(Rel) *r = (const void *) reladdr; - const ElfW(Rel) *end = (const void *) (reladdr + relsize); - - const ElfW(Sym) *const symtab = - (const void *) map->l_info[DT_SYMTAB]->d_un.d_ptr; - - for (; r < end; ++r) { - elf_machine_rel (map, r, &symtab[ELFW(R_SYM) (r->r_info)], - (void *) (map->l_addr + r->r_offset)); - } -} - -void _dl_start(void) { - static Elf32_Addr last_load_address = 0; - struct link_map map; - size_t cnt; - - /* Partly clean the `map' structure up. Don't use `memset' - since it might nor be built in or inlined and we cannot make function - calls at this point. */ - for (cnt = 0; cnt < sizeof(map.l_info) / sizeof(map.l_info[0]); ++cnt) { - map.l_info[cnt] = 0; - } - - /* Get the last load address */ - map.ll_addr = last_load_address; - - /* Figure out the run-time load address of the dynamic linker itself. */ - last_load_address = map.l_addr = elf_machine_load_address(); - - /* Read our own dynamic section and fill in the info array. */ - map.l_ld = (void *)map.l_addr + elf_machine_dynamic(); - - elf_get_dynamic_info (map.l_ld, map.l_addr - map.ll_addr, map.l_info); - - /* Relocate ourselves so we can do normal function calls and - * data access using the global offset table. - */ -#if !ELF_MACHINE_NO_REL - elf_dynamic_do_rel(&map, - map.l_info[DT_REL]->d_un.d_ptr, - map.l_info[DT_RELSZ]->d_un.d_val); - if (map.l_info[DT_PLTREL]->d_un.d_val == DT_REL) { - elf_dynamic_do_rel(&map, - map.l_info[DT_JMPREL]->d_un.d_ptr, - map.l_info[DT_PLTRELSZ]->d_un.d_val); - } -#endif - -#if !ELF_MACHINE_NO_RELA - elf_dynamic_do_rela(&map, - map.l_info[DT_RELA]->d_un.d_ptr, - map.l_info[DT_RELASZ]->d_un.d_val); - if (map.l_info[DT_PLTREL]->d_un.d_val == DT_RELA) { - elf_dynamic_do_rela(&map, - map.l_info[DT_JMPREL]->d_un.d_ptr, - map.l_info[DT_PLTRELSZ]->d_un.d_val); - } -#endif - - /* Now life is sane; we can call functions and access global data. - Set up to use the operating system facilities, and find out from - the operating system's program loader where to find the program - header table in core. Put the rest of _dl_start into a separate - function, that way the compiler cannot put accesses to the GOT - before ELF_DYNAMIC_RELOCATE. */ - return; -} diff --git a/memtest86+_old/screen_buffer.c b/memtest86+_old/screen_buffer.c deleted file mode 100644 index f9e01be..0000000 --- a/memtest86+_old/screen_buffer.c +++ /dev/null @@ -1,127 +0,0 @@ -/* screen_buffer.c - MemTest-86 Version 3.3 - * - * Released under version 2 of the Gnu Public License. - * By Jani Averbach, Jaa@iki.fi, 2001 - */ - -#include "test.h" -#include "screen_buffer.h" - -#define SCREEN_X 80 -#define SCREEN_Y 25 -#define Y_SIZE SCREEN_Y -/* - * X-size should by one of by screen size, - * so that there is room for ending '\0' - */ -#define X_SIZE SCREEN_X+1 - -static char screen_buf[Y_SIZE][X_SIZE]; - -#ifdef SCRN_DEBUG - -char *padding = "12345678901234567890123456789012345678901234567890123456789012345678901234567890"; - -#define CHECK_BOUNDS(y,x) do {if (y < 0 || Y_SIZE <= y || x < 0 || X_SIZE <= x) print_error("out of index");}while(0) - -#else /* ! SCRN_DEBUG */ - -#define CHECK_BOUNDS(y,x) - -#endif /* SCRN_DEBUG */ - -char -get_scrn_buf(const int y, - const int x) -{ - CHECK_BOUNDS(y,x); - return screen_buf[y][x]; -} - - -void -set_scrn_buf(const int y, - const int x, - const char val) -{ - CHECK_BOUNDS(y,x); - screen_buf[y][x] = val; -} - -void clear_screen_buf() -{ - int y, x; - - for (y=0; y < SCREEN_Y; ++y){ - for (x=0; x < SCREEN_X; ++x){ - CHECK_BOUNDS(y,x); - screen_buf[y][x] = ' '; - } - CHECK_BOUNDS(y,SCREEN_X); - screen_buf[y][SCREEN_X] = '\0'; - } -} - -void tty_print_region(const int pi_top, - const int pi_left, - const int pi_bottom, - const int pi_right) -{ - int y; - char tmp; - - for (y=pi_top; y < pi_bottom; ++y){ - CHECK_BOUNDS(y, pi_right); - - tmp = screen_buf[y][pi_right]; - screen_buf[y][pi_right] = '\0'; - - CHECK_BOUNDS(y, pi_left); - ttyprint(y, pi_left, &(screen_buf[y][pi_left])); - - screen_buf[y][pi_right] = tmp; - } -} - -void tty_print_line( - int y, int x, const char *text) -{ - for(; *text && (x < SCREEN_X); x++, text++) { - if (*text != screen_buf[y][x]) { - break; - } - } - /* If there is nothing to do return */ - if (*text == '\0') { - return; - } - ttyprint(y, x, text); - for(; *text && (x < SCREEN_X); x++, text++) { - screen_buf[y][x] = *text; - } -} - - -void tty_print_screen(void) -{ -#ifdef SCRN_DEBUG - int i; - - for (i=0; i < SCREEN_Y; ++i) - ttyprint(i,0, padding); -#endif /* SCRN_DEBUG */ - - tty_print_region(0, 0, SCREEN_Y, SCREEN_X); -} - -void print_error(char *pstr) -{ - -#ifdef SCRN_DEBUG - ttyprint(0,0, padding); -#endif /* SCRN_DEBUG */ - - ttyprint(0,35, pstr); - - while(1); -} diff --git a/memtest86+_old/screen_buffer.h b/memtest86+_old/screen_buffer.h deleted file mode 100644 index 8ceba03..0000000 --- a/memtest86+_old/screen_buffer.h +++ /dev/null @@ -1,20 +0,0 @@ -/* --*- C -*-- - * - * By Jani Averbach, Jaa@iki.fi, 2001 - * - * Released under version 2 of the Gnu Public License. - * - */ -#ifndef SCREEN_BUFFER_H_1D10F83B_INCLUDED -#define SCREEN_BUFFER_H_1D10F83B_INCLUDED - -#include "config.h" - -char get_scrn_buf(const int y, const int x); -void set_scrn_buf(const int y, const int x, const char val); -void clear_screen_buf(void); -void tty_print_region(const int pi_top,const int pi_left, const int pi_bottom,const int pi_right); -void tty_print_line(int y, int x, const char *text); -void tty_print_screen(void); -void print_error(char *pstr); -#endif /* SCREEN_BUFFER_H_1D10F83B_INCLUDED */ diff --git a/memtest86+_old/self_test.c b/memtest86+_old/self_test.c deleted file mode 100644 index 975ec40..0000000 --- a/memtest86+_old/self_test.c +++ /dev/null @@ -1,209 +0,0 @@ -/* Usermode self-test. - * - * This is a unit test for memtest86+ itself, - * not a standalone usermode memory tester. Sorry. - * - * It covers the main test routines in test.c, allows running them - * in a debugger or adding printfs as needed. - * - * It does not cover: - * - SMP functionality. There's no fundamental obstacle - * to this, it's just not here yet. - * - Every .c file. Some of them do things that will be - * difficult to test in user mode (eg set page tables) - * without some refactoring. - */ - -#ifdef NDEBUG - #error "Someone disabled asserts, but we want asserts for the self test." -#endif -#include -#include -#include -#include - -#include "stdint.h" -#include "cpuid.h" -#include "test.h" - -/* Provide alternate versions of the globals */ -volatile int run_cpus = 1; -volatile int bail = 0; -volatile int segs = 0; -struct vars variables; -struct vars* const vv = &variables; -// Self-test only supports single CPU (ordinal 0) for now: -volatile int mstr_cpu = 0; - -void assert_fail(const char* file, int line_no) { - printf("Failing assert at %s:%d\n", file, line_no); - assert(0); -} - -void do_tick(int me) {} -void hprint(int y, int x, ulong val) {} -void cprint(int y,int x, const char *s) {} -void dprint(int y,int x,ulong val,int len, int right) {} -void s_barrier() {} // No SMP support in selftest yet - -// Selftest doesn't have error injection yet, and thus, we -// never expect to detect any error. Fail an assert in these -// error-reporting routines: -void ad_err1(ulong *adr1, ulong *adr2, ulong good, ulong bad) { - assert(0); -} -void ad_err2(ulong *adr, ulong bad) { - assert(0); -} -void mt86_error(ulong* adr, ulong good, ulong bad) { - assert(0); -} - -typedef struct { - ulong* va; - ulong len_dw; -} foreach_chunk; - -#define MAX_CHUNK 16 - -typedef struct { - foreach_chunk chunks[MAX_CHUNK]; - int index; -} foreach_ctx; - -void record_chunks(ulong* va, ulong len_dw, const void* vctx) { - foreach_ctx* ctx = (foreach_ctx*)vctx; - - ctx->chunks[ctx->index].va = va; - ctx->chunks[ctx->index].len_dw = len_dw; - ctx->index++; -} - -void foreach_tests() { - foreach_ctx ctx; - const int me = 0; - - // mapped segment is 3G to 4G exact - memset(&ctx, 0, sizeof(ctx)); - foreach_segment((ulong*)0xc0000000, - (ulong*)0xfffffffc, me, &ctx, record_chunks); - - assert(ctx.index == 4); - assert(ctx.chunks[0].va == (ulong*)0xc0000000); - assert(ctx.chunks[0].len_dw == SPINSZ_DWORDS); - assert(ctx.chunks[1].va == (ulong*)0xd0000000); - assert(ctx.chunks[1].len_dw == SPINSZ_DWORDS); - assert(ctx.chunks[2].va == (ulong*)0xe0000000); - assert(ctx.chunks[2].len_dw == SPINSZ_DWORDS); - assert(ctx.chunks[3].va == (ulong*)0xf0000000); - assert(ctx.chunks[3].len_dw == SPINSZ_DWORDS); - - // mapped segment is 256 bytes, 128 byte aligned - memset(&ctx, 0, sizeof(ctx)); - foreach_segment((ulong*)0xc0000080, - (ulong*)0xc000017c, me, &ctx, record_chunks); - assert(ctx.index == 1); - assert(ctx.chunks[0].va == (ulong*)0xc0000080); - assert(ctx.chunks[0].len_dw == 64); - - // mapped segment starts a bit below 3.75G - // and goes up to the 4G boundary - memset(&ctx, 0, sizeof(ctx)); - foreach_segment((ulong*)0xeffff800, - (ulong*)0xfffffffc, me, &ctx, record_chunks); - assert(ctx.index == 2); - assert(ctx.chunks[0].va == (ulong*)0xeffff800); - assert(ctx.chunks[0].len_dw == SPINSZ_DWORDS); - assert(ctx.chunks[1].va == (ulong*)0xfffff800); - assert(ctx.chunks[1].len_dw == 0x200); - - // mapped segment is 0 to 32M - memset(&ctx, 0, sizeof(ctx)); - foreach_segment((ulong*)0x0, - (ulong*)0x1fffffc, me, &ctx, record_chunks); - assert(ctx.index == 1); - assert(ctx.chunks[0].va == (ulong*)0x0); - assert(ctx.chunks[0].len_dw == 0x800000); -} - -int main() { - memset(&variables, 0, sizeof(variables)); - vv->debugging = 1; - - get_cpuid(); - - // add a non-power-of-2 pad to the size, so things don't line - // up too nicely. Chose 508 because it's not 512. - const int kTestSizeDwords = SPINSZ_DWORDS * 2 + 508; - - // Allocate an extra cache line on each end, where we'll - // write a sentinel pattern to detect overflow or underflow: - const int kRawBufSizeDwords = kTestSizeDwords + 32; - - segs = 1; - ulong raw_start = (ulong)malloc(kRawBufSizeDwords * sizeof(ulong)); - ulong raw_end = raw_start + kRawBufSizeDwords * sizeof(ulong); - - // align to a cache line: - if (raw_start & 0x3f) { - raw_start &= ~0x3f; - raw_start += 0x40; - } - // align to a cache line: - if (raw_end & 0x3f) { - raw_end &= ~0x3f; - } - - const int kSentinelBytes = 48; - ulong start = raw_start + kSentinelBytes; // exclude low sentinel - ulong end = raw_end - kSentinelBytes; // exclude high sentinel - - // setup sentinels - memset((ulong*)raw_start, 'z', kSentinelBytes); - memset((ulong*)end, 'z', kSentinelBytes); - - vv->map[0].start = (ulong*)start; - vv->map[0].end = ((ulong*)end) - 1; // map.end points to xxxxxfc - - const int iter = 2; - const int me = 0; // cpu ordinal - - foreach_tests(); - - // TEST 0 - addr_tst1(me); - - // TEST 1, 2 - addr_tst2(me); - - // TEST 3, 4, 5, 6 - const ulong pat = 0x112211ee; - movinv1(iter, pat, ~pat, 0); - - // TEST 7 - block_move(iter, me); - - // TEST 8 - movinv32(iter, 0x2, 0x1, 0x80000000, 0, 1, me); - - // TEST 9 - movinvr(me); - - // TEST 10 - modtst(2, 1, 0x5555aaaa, 0xaaaa5555, me); - - // TEST 11 - bit_fade_fill(0xdeadbeef, me); - bit_fade_chk(0xdeadbeef, me); - - - // Check sentinels, they should not have been overwritten. Do this last. - for (int j=0; jlck.slock = 1; - barr->mutex.slock = 1; - barr->maxproc = max; - barr->count = max; - barr->st1.slock = 1; - barr->st2.slock = 0; -} - -void s_barrier_init(int max) -{ - barr->s_lck.slock = 1; - barr->s_maxproc = max; - barr->s_count = max; - barr->s_st1.slock = 1; - barr->s_st2.slock = 0; -} - -void barrier() -{ - if (num_cpus == 1 || vv->fail_safe & 3) { - return; - } - spin_wait(&barr->st1); /* Wait if the barrier is active */ - spin_lock(&barr->lck); /* Get lock for barr struct */ - if (--barr->count == 0) { /* Last process? */ - barr->st1.slock = 0; /* Hold up any processes re-entering */ - barr->st2.slock = 1; /* Release the other processes */ - barr->count++; - spin_unlock(&barr->lck); - } else { - spin_unlock(&barr->lck); - spin_wait(&barr->st2); /* wait for peers to arrive */ - spin_lock(&barr->lck); - if (++barr->count == barr->maxproc) { - barr->st1.slock = 1; - barr->st2.slock = 0; - } - spin_unlock(&barr->lck); - } -} - -void s_barrier() -{ - if (run_cpus == 1 || vv->fail_safe & 3) { - return; - } - spin_wait(&barr->s_st1); /* Wait if the barrier is active */ - spin_lock(&barr->s_lck); /* Get lock for barr struct */ - if (--barr->s_count == 0) { /* Last process? */ - barr->s_st1.slock = 0; /* Hold up any processes re-entering */ - barr->s_st2.slock = 1; /* Release the other processes */ - barr->s_count++; - spin_unlock(&barr->s_lck); - } else { - spin_unlock(&barr->s_lck); - spin_wait(&barr->s_st2); /* wait for peers to arrive */ - spin_lock(&barr->s_lck); - if (++barr->s_count == barr->s_maxproc) { - barr->s_st1.slock = 1; - barr->s_st2.slock = 0; - } - spin_unlock(&barr->s_lck); - } -} - -typedef struct { - bool started; -} ap_info_t; - -volatile apic_register_t *APIC = NULL; -/* CPU number to APIC ID mapping table. CPU 0 is the BSP. */ -static unsigned cpu_num_to_apic_id[MAX_CPUS]; -volatile ap_info_t AP[MAX_CPUS]; - -void PUT_MEM16(uintptr_t addr, uint16_t val) -{ - *((volatile uint16_t *)addr) = val; -} - -void PUT_MEM32(uintptr_t addr, uint32_t val) -{ - *((volatile uint32_t *)addr) = val; -} - -static void inline -APIC_WRITE(unsigned reg, uint32_t val) -{ - APIC[reg][0] = val; -} - -static inline uint32_t -APIC_READ(unsigned reg) -{ - return APIC[reg][0]; -} - - -static void -SEND_IPI(unsigned apic_id, unsigned trigger, unsigned level, unsigned mode, - uint8_t vector) -{ - uint32_t v; - - v = APIC_READ(APICR_ICRHI) & 0x00ffffff; - APIC_WRITE(APICR_ICRHI, v | (apic_id << 24)); - - v = APIC_READ(APICR_ICRLO) & ~0xcdfff; - v |= (APIC_DEST_DEST << APIC_ICRLO_DEST_OFFSET) - | (trigger << APIC_ICRLO_TRIGGER_OFFSET) - | (level << APIC_ICRLO_LEVEL_OFFSET) - | (mode << APIC_ICRLO_DELMODE_OFFSET) - | (vector); - APIC_WRITE(APICR_ICRLO, v); -} - - -// Silly way of busywaiting, but we don't have a timer -void delay(unsigned us) -{ - unsigned freq = 1000; // in MHz, assume 1GHz CPU speed - uint64_t cycles = us * freq; - uint64_t t0 = RDTSC(); - uint64_t t1; - volatile unsigned k; - - do { - for (k = 0; k < 1000; k++) continue; - t1 = RDTSC(); - } while (t1 - t0 < cycles); -} - -static inline void -memset (volatile void *dst, - char value, - int len) -{ - int i; - for (i = 0 ; i < len ; i++ ) { - *((char *) dst + i) = value; - } -} -void initialise_cpus(void) -{ - int i; - - act_cpus = 0; - - if (maxcpus > 1) { - smp_find_cpus(); - /* The total number of CPUs may be limited */ - if (num_cpus > maxcpus) { - num_cpus = maxcpus; - } - /* Determine how many cpus have been selected */ - for(i = 0; i < num_cpus; i++) { - if (cpu_mask[i]) { - act_cpus++; - } - } - } else { - act_cpus = found_cpus = num_cpus = 1; - } - - /* Initialize the barrier before starting AP's */ - barrier_init(act_cpus); - - /* let the BSP initialise the APs. */ - for(i = 1; i < num_cpus; i++) { - /* Only start this CPU if it is selected by the mask */ - if (cpu_mask[i]) { - smp_boot_ap(i); - } - } - -} -void kick_cpu(unsigned cpu_num) -{ - unsigned num_sipi, apic_id; - apic_id = cpu_num_to_apic_id[cpu_num]; - - // clear the APIC ESR register - APIC_WRITE(APICR_ESR, 0); - APIC_READ(APICR_ESR); - - // asserting the INIT IPI - SEND_IPI(apic_id, APIC_TRIGGER_LEVEL, 1, APIC_DELMODE_INIT, 0); - delay(100000 / DELAY_FACTOR); - - // de-assert the INIT IPI - SEND_IPI(apic_id, APIC_TRIGGER_LEVEL, 0, APIC_DELMODE_INIT, 0); - - for (num_sipi = 0; num_sipi < 2; num_sipi++) { - unsigned timeout; - bool send_pending; - unsigned err; - - APIC_WRITE(APICR_ESR, 0); - - SEND_IPI(apic_id, 0, 0, APIC_DELMODE_STARTUP, (unsigned)startup_32 >> 12); - - timeout = 0; - do { - delay(10); - timeout++; - send_pending = (APIC_READ(APICR_ICRLO) & APIC_ICRLO_STATUS_MASK) != 0; - } while (send_pending && timeout < 1000); - - if (send_pending) { - cprint(LINE_STATUS+3, 0, "SMP: STARTUP IPI was never sent"); - } - - delay(100000 / DELAY_FACTOR); - - err = APIC_READ(APICR_ESR) & 0xef; - if (err) { - cprint(LINE_STATUS+3, 0, "SMP: After STARTUP IPI: err = 0x"); - hprint(LINE_STATUS+3, COL_MID, err); - } - } -} - -// These memory locations are used for the trampoline code and data. - -#define BOOTCODESTART 0x9000 -#define GDTPOINTERADDR 0x9100 -#define GDTADDR 0x9110 - -void boot_ap(unsigned cpu_num) -{ - unsigned num_sipi, apic_id; - extern uint8_t gdt; - extern uint8_t _ap_trampoline_start; - extern uint8_t _ap_trampoline_protmode; - unsigned len = &_ap_trampoline_protmode - &_ap_trampoline_start; - apic_id = cpu_num_to_apic_id[cpu_num]; - - - memcpy((uint8_t*)BOOTCODESTART, &_ap_trampoline_start, len); - - // Fixup the LGDT instruction to point to GDT pointer. - PUT_MEM16(BOOTCODESTART + 3, GDTPOINTERADDR); - - // Copy a pointer to the temporary GDT to addr GDTPOINTERADDR. - // The temporary gdt is at addr GDTADDR - PUT_MEM16(GDTPOINTERADDR, 4 * 8); - PUT_MEM32(GDTPOINTERADDR + 2, GDTADDR); - - // Copy the first 4 gdt entries from the currently used GDT to the - // temporary GDT. - memcpy((uint8_t *)GDTADDR, &gdt, 32); - - // clear the APIC ESR register - APIC_WRITE(APICR_ESR, 0); - APIC_READ(APICR_ESR); - - // asserting the INIT IPI - SEND_IPI(apic_id, APIC_TRIGGER_LEVEL, 1, APIC_DELMODE_INIT, 0); - delay(100000 / DELAY_FACTOR); - - // de-assert the INIT IPI - SEND_IPI(apic_id, APIC_TRIGGER_LEVEL, 0, APIC_DELMODE_INIT, 0); - - for (num_sipi = 0; num_sipi < 2; num_sipi++) { - unsigned timeout; - bool send_pending; - unsigned err; - - APIC_WRITE(APICR_ESR, 0); - - SEND_IPI(apic_id, 0, 0, APIC_DELMODE_STARTUP, BOOTCODESTART >> 12); - - timeout = 0; - do { - delay(10); - timeout++; - send_pending = (APIC_READ(APICR_ICRLO) & APIC_ICRLO_STATUS_MASK) != 0; - } while (send_pending && timeout < 1000); - - if (send_pending) { - cprint(LINE_STATUS+3, 0, "SMP: STARTUP IPI was never sent"); - } - - delay(100000 / DELAY_FACTOR); - - err = APIC_READ(APICR_ESR) & 0xef; - if (err) { - cprint(LINE_STATUS+3, 0, "SMP: After STARTUP IPI: err = 0x"); - hprint(LINE_STATUS+3, COL_MID, err); - } - } -} - -static int checksum(unsigned char *mp, int len) -{ - int sum = 0; - - while (len--) { - sum += *mp++; - } - return (sum & 0xFF); -} - -/* Parse an MP config table for CPU information */ -bool read_mp_config_table(uintptr_t addr) -{ - mp_config_table_header_t *mpc = (mp_config_table_header_t*)addr; - uint8_t *tab_entry_ptr; - uint8_t *mpc_table_end; - - if (mpc->signature != MPCSignature) { - return FALSE; - } - if (checksum((unsigned char*)mpc, mpc->length) != 0) { - return FALSE; - } - - /* FIXME: the uintptr_t cast here works around a compilation problem on - * AMD64, but it ignores the real problem, which is that lapic_addr - * is only 32 bits. Maybe that's OK, but it should be investigated. - */ - APIC = (volatile apic_register_t*)(uintptr_t)mpc->lapic_addr; - - tab_entry_ptr = ((uint8_t*)mpc) + sizeof(mp_config_table_header_t); - mpc_table_end = ((uint8_t*)mpc) + mpc->length; - - while (tab_entry_ptr < mpc_table_end) { - switch (*tab_entry_ptr) { - case MP_PROCESSOR: { - mp_processor_entry_t *pe = (mp_processor_entry_t*)tab_entry_ptr; - - if (pe->cpu_flag & CPU_BOOTPROCESSOR) { - // BSP is CPU 0 - cpu_num_to_apic_id[0] = pe->apic_id; - } else if (num_cpus < MAX_CPUS) { - cpu_num_to_apic_id[num_cpus] = pe->apic_id; - num_cpus++; - } - found_cpus++; - - // we cannot handle non-local 82489DX apics - if ((pe->apic_ver & 0xf0) != 0x10) { - return 0; - } - - tab_entry_ptr += sizeof(mp_processor_entry_t); - break; - } - case MP_BUS: { - tab_entry_ptr += sizeof(mp_bus_entry_t); - break; - } - case MP_IOAPIC: { - tab_entry_ptr += sizeof(mp_io_apic_entry_t); - break; - } - case MP_INTSRC: - tab_entry_ptr += sizeof(mp_interrupt_entry_t); - break; - case MP_LINTSRC: - tab_entry_ptr += sizeof(mp_local_interrupt_entry_t); - break; - default: - return FALSE; - } - } - return TRUE; -} - -/* Search for a Floating Pointer structure */ -floating_pointer_struct_t * -scan_for_floating_ptr_struct(uintptr_t addr, uint32_t length) -{ - floating_pointer_struct_t *fp; - uintptr_t end = addr + length; - - - while ((uintptr_t)addr < end) { - fp = (floating_pointer_struct_t*)addr; - if (*(unsigned int *)addr == FPSignature && fp->length == 1 && checksum((unsigned char*)addr, 16) == 0 && ((fp->spec_rev == 1) || (fp->spec_rev == 4))) { - return fp; - } - addr += 4; - } - return NULL; -} - -/* Search for a Root System Descriptor Pointer */ -rsdp_t *scan_for_rsdp(uintptr_t addr, uint32_t length) -{ - rsdp_t *rp; - uintptr_t end = addr + length; - - - while ((uintptr_t)addr < end) { - rp = (rsdp_t*)addr; - if (*(unsigned int *)addr == RSDPSignature && - checksum((unsigned char*)addr, rp->length) == 0) { - return rp; - } - addr += 4; - } - return NULL; -} - -/* Parse a MADT table for processor entries */ -int parse_madt(uintptr_t addr) { - - mp_config_table_header_t *mpc = (mp_config_table_header_t*)addr; - uint8_t *tab_entry_ptr; - uint8_t *mpc_table_end; - - if (checksum((unsigned char*)mpc, mpc->length) != 0) { - return FALSE; - } - - APIC = (volatile apic_register_t*)(uintptr_t)mpc->lapic_addr; - - tab_entry_ptr = ((uint8_t*)mpc) + sizeof(mp_config_table_header_t); - mpc_table_end = ((uint8_t*)mpc) + mpc->length; - while (tab_entry_ptr < mpc_table_end) { - - madt_processor_entry_t *pe = (madt_processor_entry_t*)tab_entry_ptr; - if (pe->type == MP_PROCESSOR) { - if (pe->enabled) { - if (num_cpus < MAX_CPUS) { - cpu_num_to_apic_id[num_cpus] = pe->apic_id; - - /* the first CPU is the BSP, don't increment */ - if (found_cpus) { - num_cpus++; - } - } - found_cpus++; - } - } - tab_entry_ptr += pe->length; - } - return TRUE; -} - -/* This is where we search for SMP information in the following order - * look for a floating MP pointer - * found: - * check for a default configuration - * found: - * setup config, return - * check for a MP config table - * found: - * validate: - * good: - * parse the MP config table - * good: - * setup config, return - * - * find & validate ACPI RSDP (Root System Descriptor Pointer) - * found: - * find & validate RSDT (Root System Descriptor Table) - * found: - * find & validate MSDT - * found: - * parse the MADT table - * good: - * setup config, return - */ -void smp_find_cpus() -{ - floating_pointer_struct_t *fp; - rsdp_t *rp; - rsdt_t *rt; - uint8_t *tab_ptr, *tab_end; - unsigned int *ptr; - unsigned int uiptr; - - if(vv->fail_safe & 3) { return; } - - memset(&AP, 0, sizeof AP); - - if(vv->fail_safe & 8) - { - // Search for the Floating MP structure pointer - fp = scan_for_floating_ptr_struct(0x0, 0x400); - if (fp == NULL) { - fp = scan_for_floating_ptr_struct(639*0x400, 0x400); - } - if (fp == NULL) { - fp = scan_for_floating_ptr_struct(0xf0000, 0x10000); - } - if (fp == NULL) { - // Search the BIOS ESDS area - unsigned int address = *(unsigned short *)0x40E; - address <<= 4; - if (address) { - fp = scan_for_floating_ptr_struct(address, 0x400); - } - } - - if (fp != NULL) { - // We have a floating MP pointer - // Is this a default configuration? - - if (fp->feature[0] > 0 && fp->feature[0] <=7) { - // This is a default config so plug in the numbers - num_cpus = 2; - APIC = (volatile apic_register_t*)0xFEE00000; - cpu_num_to_apic_id[0] = 0; - cpu_num_to_apic_id[1] = 1; - return; - } - - // Do we have a pointer to a MP configuration table? - if ( fp->phys_addr != 0) { - if (read_mp_config_table(fp->phys_addr)) { - // Found a good MP table, done - return; - } - } - } - } - - - /* No MP table so far, try to find an ACPI MADT table - * We try to use the MP table first since there is no way to distinguish - * real cores from hyper-threads in the MADT */ - - /* Search for the RSDP */ - rp = scan_for_rsdp(0xE0000, 0x20000); - if (rp == NULL) { - /* Search the BIOS ESDS area */ - unsigned int address = *(unsigned short *)0x40E; - address <<= 4; - if (address) { - rp = scan_for_rsdp(address, 0x400); - } - } - - if (rp == NULL) { - /* RSDP not found, give up */ - return; - } - - /* Found the RSDP, now get either the RSDT or XSDT */ - if (rp->revision >= 2) { - rt = (rsdt_t *)rp->xrsdt[0]; - - if (rt == 0) { - return; - } - // Validate the XSDT - if (*(unsigned int *)rt != XSDTSignature) { - return; - } - if ( checksum((unsigned char*)rt, rt->length) != 0) { - return; - } - - } else { - rt = (rsdt_t *)rp->rsdt; - if (rt == 0) { - return; - } - /* Validate the RSDT */ - if (*(unsigned int *)rt != RSDTSignature) { - return; - } - if ( checksum((unsigned char*)rt, rt->length) != 0) { - return; - } - } - - /* Scan the RSDT or XSDT for a pointer to the MADT */ - tab_ptr = ((uint8_t*)rt) + sizeof(rsdt_t); - tab_end = ((uint8_t*)rt) + rt->length; - - while (tab_ptr < tab_end) { - - uiptr = *((unsigned int *)tab_ptr); - ptr = (unsigned int *)uiptr; - - /* Check for the MADT signature */ - if (ptr && *ptr == MADTSignature) { - /* Found it, now parse it */ - if (parse_madt((uintptr_t)ptr)) { - return; - } - } - tab_ptr += 4; - } -} - -unsigned my_apic_id() -{ - return (APIC[APICR_ID][0]) >> 24; -} - -void smp_ap_booted(unsigned cpu_num) -{ - AP[cpu_num].started = TRUE; -} - -void smp_boot_ap(unsigned cpu_num) -{ - unsigned timeout; - - boot_ap(cpu_num); - timeout = 0; - do { - delay(1000 / DELAY_FACTOR); - timeout++; - } while (!AP[cpu_num].started && timeout < 100000 / DELAY_FACTOR); - - if (!AP[cpu_num].started) { - cprint(LINE_STATUS+3, 0, "SMP: Boot timeout for"); - dprint(LINE_STATUS+3, COL_MID, cpu_num,2,1); - cprint(LINE_STATUS+3, 26, "Turning off SMP"); - } -} - -unsigned smp_my_cpu_num() -{ - unsigned apicid = my_apic_id(); - unsigned i; - - for (i = 0; i < MAX_CPUS; i++) { - if (apicid == cpu_num_to_apic_id[i]) { - break; - } - } - if (i == MAX_CPUS) { - i = 0; - } - return i; -} - -/* A set of simple functions used to preserve assigned CPU ordinals since - * they are lost after relocation (the stack is reloaded). - */ -int num_to_ord[MAX_CPUS]; -void smp_set_ordinal(int me, int ord) -{ - num_to_ord[me] = ord; -} - -int smp_my_ord_num(int me) -{ - return num_to_ord[me]; -} - -int smp_ord_to_cpu(int me) -{ - int i; - for (i=0; islock): "memory" - ); - } -} - -static inline void spin_lock(spinlock_t *lck) -{ - if (cpu_id.fid.bits.mon) { - /* Use monitor/mwait for a low power, low contention spin */ - asm volatile( - "\n1:\t" - " ; lock;decb (%%edi)\n\t" - "jns 3f\n" - "movl $0,%%ecx\n\t" - "movl %%ecx, %%edx\n\t" - "2:\t" - "movl %%edi,%%eax\n\t" - "monitor\n\t" - "movl %%ecx, %%eax\n\t" - "mwait\n\t" - "cmpb $0,(%%edi)\n\t" - "jle 2b\n\t" - "jmp 1b\n" - "3:\n\t" - : : "D" (lck): "%eax", "%ecx", "%edx" - ); - } else { - /* No monitor/mwait so just spin with a lot of nop's */ - int inc = 0x400; - asm volatile( - "\n1:\t" - " ; lock;decb %0\n\t" - "jns 3f\n" - "2:\t" - "rep;nop\n\t" - "cmpb $0,%0\n\t" - "jle 2b\n\t" - "jmp 1b\n" - "3:\n\t" - : "+m" (lck->slock) : "c" (inc) : "memory" - ); - } -} - -static inline void spin_unlock(spinlock_t *lock) -{ - asm volatile("movb $1,%0" : "+m" (lock->slock) :: "memory"); -} - - -#endif /* _SMP_H_ */ diff --git a/memtest86+_old/spd.c b/memtest86+_old/spd.c deleted file mode 100644 index 197db56..0000000 --- a/memtest86+_old/spd.c +++ /dev/null @@ -1,541 +0,0 @@ -/* - * MemTest86+ V5 Specific code (GPL V2.0) - * By Samuel DEMEULEMEESTER, sdemeule@memtest.org - * http://www.canardpc.com - http://www.memtest.org - */ - - -#include "test.h" -#include "io.h" -#include "pci.h" -#include "msr.h" -#include "spd.h" -#include "screen_buffer.h" -#include "jedec_id.h" - -#define NULL 0 - -#define SMBHSTSTS smbusbase -#define SMBHSTCNT smbusbase + 2 -#define SMBHSTCMD smbusbase + 3 -#define SMBHSTADD smbusbase + 4 -#define SMBHSTDAT smbusbase + 5 - -extern void wait_keyup(); - -int smbdev, smbfun; -unsigned short smbusbase; -unsigned char spd_raw[256]; -char s[] = {'/', 0, '-', 0, '\\', 0, '|', 0}; - -static void ich5_get_smb(void) -{ - unsigned long x; - int result; - result = pci_conf_read(0, smbdev, smbfun, 0x20, 2, &x); - if (result == 0) smbusbase = (unsigned short) x & 0xFFFE; -} - -static void piix4_get_smb(void) -{ - unsigned long x; - int result; - - result = pci_conf_read(0, smbdev, smbfun, 0x08, 1, &x); - - if(x < 0x40){ - // SB600/700 - result = pci_conf_read(0, smbdev, smbfun, 0x90, 2, &x); - if (result == 0) smbusbase = (unsigned short) x & 0xFFFE; - } else { - // SB800 - sb800_get_smb(); - } -} - -void sb800_get_smb(void) -{ - int lbyte, hbyte; - - __outb(AMD_SMBUS_BASE_REG + 1, AMD_INDEX_IO_PORT); - lbyte = __inb(AMD_DATA_IO_PORT); - __outb(AMD_SMBUS_BASE_REG, AMD_INDEX_IO_PORT); - hbyte = __inb(AMD_DATA_IO_PORT); - - smbusbase = lbyte; - smbusbase <<= 8; - smbusbase += hbyte; - smbusbase &= 0xFFE0; - - if (smbusbase == 0xFFE0) { smbusbase = 0; } -} - -unsigned char ich5_smb_read_byte(unsigned char adr, unsigned char cmd) -{ - int l1, h1, l2, h2; - unsigned long long t; - __outb(0x1f, SMBHSTSTS); // reset SMBus Controller - __outb(0xff, SMBHSTDAT); - while(__inb(SMBHSTSTS) & 0x01); // wait until ready - __outb(cmd, SMBHSTCMD); - __outb((adr << 1) | 0x01, SMBHSTADD); - __outb(0x48, SMBHSTCNT); - rdtsc(l1, h1); - //cprint(POP2_Y, POP2_X + 16, s + cmd % 8); // progress bar - while (!(__inb(SMBHSTSTS) & 0x02)) { // wait til command finished - rdtsc(l2, h2); - t = ((h2 - h1) * 0xffffffff + (l2 - l1)) / vv->clks_msec; - if (t > 10) break; // break after 10ms - } - return __inb(SMBHSTDAT); -} - -static int ich5_read_spd(int dimmadr) -{ - int x; - spd_raw[0] = ich5_smb_read_byte(0x50 + dimmadr, 0); - if (spd_raw[0] == 0xff) return -1; // no spd here - for (x = 1; x < 256; x++) { - spd_raw[x] = ich5_smb_read_byte(0x50 + dimmadr, (unsigned char) x); - } - return 0; -} - -static void us15w_get_smb(void) -{ - unsigned long x; - int result; - result = pci_conf_read(0, 0x1f, 0, 0x40, 2, &x); - if (result == 0) smbusbase = (unsigned short) x & 0xFFC0; -} - -unsigned char us15w_smb_read_byte(unsigned char adr, unsigned char cmd) -{ - int l1, h1, l2, h2; - unsigned long long t; - //__outb(0x00, smbusbase + 1); // reset SMBus Controller - //__outb(0x00, smbusbase + 6); - //while((__inb(smbusbase + 1) & 0x08) != 0); // wait until ready - __outb(0x02, smbusbase + 0); // Byte read - __outb(cmd, smbusbase + 5); // Command - __outb(0x07, smbusbase + 1); // Clear status - __outb((adr << 1) | 0x01, smbusbase + 4); // DIMM address - __outb(0x12, smbusbase + 0); // Start - //while (((__inb(smbusbase + 1) & 0x08) == 0)) {} // wait til busy - rdtsc(l1, h1); - cprint(POP2_Y, POP2_X + 16, s + cmd % 8); // progress bar - while (((__inb(smbusbase + 1) & 0x01) == 0) || - ((__inb(smbusbase + 1) & 0x08) != 0)) { // wait til command finished - rdtsc(l2, h2); - t = ((h2 - h1) * 0xffffffff + (l2 - l1)) / vv->clks_msec; - if (t > 10) break; // break after 10ms - } - return __inb(smbusbase + 6); -} - -static int us15w_read_spd(int dimmadr) -{ - int x; - spd_raw[0] = us15w_smb_read_byte(0x50 + dimmadr, 0); - if (spd_raw[0] == 0xff) return -1; // no spd here - for (x = 1; x < 256; x++) { - spd_raw[x] = us15w_smb_read_byte(0x50 + dimmadr, (unsigned char) x); - } - return 0; -} - -struct pci_smbus_controller { - unsigned vendor; - unsigned device; - char *name; - void (*get_adr)(void); - int (*read_spd)(int dimmadr); -}; - -static struct pci_smbus_controller smbcontrollers[] = - { - // Intel SMBUS - {0x8086, 0x9C22, "Intel HSW-ULT", ich5_get_smb, ich5_read_spd}, - {0x8086, 0x8C22, "Intel HSW", ich5_get_smb, ich5_read_spd}, - {0x8086, 0x1E22, "Intel Z77", ich5_get_smb, ich5_read_spd}, - {0x8086, 0x1C22, "Intel P67", ich5_get_smb, ich5_read_spd}, - {0x8086, 0x3B30, "Intel P55", ich5_get_smb, ich5_read_spd}, - {0x8086, 0x3A60, "Intel ICH10B", ich5_get_smb, ich5_read_spd}, - {0x8086, 0x3A30, "Intel ICH10R", ich5_get_smb, ich5_read_spd}, - {0x8086, 0x2930, "Intel ICH9", ich5_get_smb, ich5_read_spd}, - {0x8086, 0x283E, "Intel ICH8", ich5_get_smb, ich5_read_spd}, - {0x8086, 0x27DA, "Intel ICH7", ich5_get_smb, ich5_read_spd}, - {0x8086, 0x266A, "Intel ICH6", ich5_get_smb, ich5_read_spd}, - {0x8086, 0x24D3, "Intel ICH5", ich5_get_smb, ich5_read_spd}, - {0x8086, 0x24C3, "Intel ICH4", ich5_get_smb, ich5_read_spd}, - {0x8086, 0x25A4, "Intel 6300ESB", ich5_get_smb, ich5_read_spd}, - {0x8086, 0x269B, "Intel ESB2", ich5_get_smb, ich5_read_spd}, - {0x8086, 0x8119, "Intel US15W", us15w_get_smb, us15w_read_spd}, - {0x8086, 0x5032, "Intel EP80579", ich5_get_smb, ich5_read_spd}, - - // AMD SMBUS - {0x1002, 0x4385, "AMD SB600/700", piix4_get_smb, ich5_read_spd}, - {0x1022, 0x780B, "AMD SB800/900", sb800_get_smb, ich5_read_spd}, - {0, 0, "", NULL, NULL} - }; - -int find_smb_controller(void) -{ - int i = 0; - unsigned long valuev, valued; - - for (smbdev = 0; smbdev < 32; smbdev++) { - for (smbfun = 0; smbfun < 8; smbfun++) { - pci_conf_read(0, smbdev, smbfun, 0, 2, &valuev); - if (valuev != 0xFFFF) { // if there is something look what's it.. - for (i = 0; smbcontrollers[i].vendor > 0; i++) { // check if this is a known smbus controller - if (valuev == smbcontrollers[i].vendor) { - pci_conf_read(0, smbdev, smbfun, 2, 2, &valued); // read the device id - if (valued == smbcontrollers[i].device) { - return i; - } - } - } - } - } - } - return -1; -} - -void get_spd_spec(void) -{ - int index; - int h, i, j, z; - int k = 0; - int module_size; - int curcol; - int temp_nbd; - int tck; - - index = find_smb_controller(); - - if (index == -1) - { - // Unknown SMBUS Controller, exit - return; - } - - smbcontrollers[index].get_adr(); - cprint(LINE_SPD-2, 0, "Memory SPD Informations"); - cprint(LINE_SPD-1, 0, "--------------------------"); - - for (j = 0; j < 8; j++) { - if (smbcontrollers[index].read_spd(j) == 0) { - curcol = 1; - if(spd_raw[2] == 0x0b){ - // We are here if DDR3 present - - // First print slot#, module capacity - cprint(LINE_SPD+k, curcol, " - Slot :"); - dprint(LINE_SPD+k, curcol+8, k, 1, 0); - - module_size = get_ddr3_module_size(spd_raw[4] & 0xF, spd_raw[8] & 0x7, spd_raw[7] & 0x7, spd_raw[7] >> 3); - temp_nbd = getnum(module_size); curcol += 12; - dprint(LINE_SPD+k, curcol, module_size, temp_nbd, 0); curcol += temp_nbd; - cprint(LINE_SPD+k, curcol, " MB"); curcol += 4; - - // If XMP is supported, check Tck in XMP reg - if(spd_raw[176] == 0x0C && spd_raw[177] == 0x4A && spd_raw[12]) - { - tck = spd_raw[186]; - } else { - tck = spd_raw[12]; - } - - // Then module jedec speed - switch(tck) - { - default: - cprint(LINE_SPD+k, curcol, "DDR3-????"); - break; - case 20: - cprint(LINE_SPD+k, curcol, "DDR3-800"); - curcol--; - break; - case 15: - cprint(LINE_SPD+k, curcol, "DDR3-1066"); - break; - case 12: - cprint(LINE_SPD+k, curcol, "DDR3-1333"); - break; - case 10: - cprint(LINE_SPD+k, curcol, "DDR3-1600"); - break; - case 9: - cprint(LINE_SPD+k, curcol, "DDR3-1866"); - break; - case 8: - cprint(LINE_SPD+k, curcol, "DDR3-2133"); - break; - case 7: - cprint(LINE_SPD+k, curcol, "DDR3-2400"); - break; - case 6: - cprint(LINE_SPD+k, curcol, "DDR3-2533"); - break; - case 5: - cprint(LINE_SPD+k, curcol, "DDR3-2666"); - break; - } - - curcol += 10; - - if((spd_raw[8] >> 3) == 1) { cprint(LINE_SPD+k, curcol, "ECC"); curcol += 4; } - - // Then print module infos (manufacturer & part number) - spd_raw[117] &= 0x0F; // Parity odd or even - for (i = 0; jep106[i].cont_code < 9; i++) { - if (spd_raw[117] == jep106[i].cont_code && spd_raw[118] == jep106[i].hex_byte) { - // We are here if a Jedec manufacturer is detected - cprint(LINE_SPD+k, curcol, "-"); curcol += 2; - cprint(LINE_SPD+k, curcol, jep106[i].name); - for(z = 0; jep106[i].name[z] != '\0'; z++) { curcol++; } - curcol++; - // Display module serial number - for (h = 128; h < 146; h++) { - cprint(LINE_SPD+k, curcol, convert_hex_to_char(spd_raw[h])); - curcol++; - } - - // Detect Week and Year of Manufacturing (Think to upgrade after 2015 !!!) - if(curcol <= 72 && spd_raw[120] > 3 && spd_raw[120] < 16 && spd_raw[121] < 55) - { - cprint(LINE_SPD+k, curcol, "(W"); - dprint(LINE_SPD+k, curcol+2, spd_raw[121], 2, 0); - if(spd_raw[121] < 10) { cprint(LINE_SPD+k, curcol+2, "0"); } - cprint(LINE_SPD+k, curcol+4, "'"); - dprint(LINE_SPD+k, curcol+5, spd_raw[120], 2, 0); - if(spd_raw[120] < 10) { cprint(LINE_SPD+k, curcol+5, "0"); } - cprint(LINE_SPD+k, curcol+7, ")"); - curcol += 9; - } - - // Detect XMP Memory - if(spd_raw[176] == 0x0C && spd_raw[177] == 0x4A) - { - cprint(LINE_SPD+k, curcol, "*XMP*"); - } - } - } - } - // We enter this function if DDR2 is detected - if(spd_raw[2] == 0x08){ - // First print slot#, module capacity - cprint(LINE_SPD+k, curcol, " - Slot :"); - dprint(LINE_SPD+k, curcol+8, k, 1, 0); - - module_size = get_ddr2_module_size(spd_raw[31], spd_raw[5]); - temp_nbd = getnum(module_size); curcol += 12; - dprint(LINE_SPD+k, curcol, module_size, temp_nbd, 0); curcol += temp_nbd; - cprint(LINE_SPD+k, curcol, " MB"); curcol += 4; - - // Then module jedec speed - float ddr2_speed, byte1, byte2; - - byte1 = (spd_raw[9] >> 4) * 10; - byte2 = spd_raw[9] & 0xF; - - ddr2_speed = 1 / (byte1 + byte2) * 10000 * 2; - - temp_nbd = getnum(ddr2_speed); - cprint(LINE_SPD+k, curcol, "DDR2-"); curcol += 5; - dprint(LINE_SPD+k, curcol, ddr2_speed, temp_nbd, 0); curcol += temp_nbd; - - if((spd_raw[11] >> 1) == 1) { cprint(LINE_SPD+k, curcol+1, "ECC"); curcol += 4; } - - // Then print module infos (manufacturer & part number) - int ccode = 0; - - for(i = 64; i < 72; i++) - { - if(spd_raw[i] == 0x7F) { ccode++; } - } - - curcol++; - - for (i = 0; jep106[i].cont_code < 9; i++) { - if (ccode == jep106[i].cont_code && spd_raw[64+ccode] == jep106[i].hex_byte) { - // We are here if a Jedec manufacturer is detected - cprint(LINE_SPD+k, curcol, "-"); curcol += 2; - cprint(LINE_SPD+k, curcol, jep106[i].name); - for(z = 0; jep106[i].name[z] != '\0'; z++) { curcol++; } - curcol++; - // Display module serial number - for (h = 73; h < 91; h++) { - cprint(LINE_SPD+k, curcol, convert_hex_to_char(spd_raw[h])); - curcol++; - } - } - } - } - k++; - } - } -} - -void show_spd(void) -{ - int index; - int i, j; - int flag = 0; - pop2up(); - wait_keyup(); - index = find_smb_controller(); - if (index == -1) { - cprint(POP2_Y, POP2_X+1, "SMBus Controller not known"); - while (!get_key()); - wait_keyup(); - pop2down(); - return; - } - else cprint(POP2_Y, POP2_X+1, "SPD Data: Slot"); - smbcontrollers[index].get_adr(); - for (j = 0; j < 16; j++) { - if (smbcontrollers[index].read_spd(j) == 0) { - dprint(POP2_Y, POP2_X + 15, j, 2, 0); - for (i = 0; i < 256; i++) { - hprint2(2 + POP2_Y + i / 16, 3 + POP2_X + (i % 16) * 3, spd_raw[i], 2); - } - flag = 0; - while(!flag) { - if (get_key()) flag++; - } - wait_keyup(); - } - } - pop2down(); -} - -int get_ddr3_module_size(int sdram_capacity, int prim_bus_width, int sdram_width, int ranks) -{ - int module_size; - - switch(sdram_capacity) - { - case 0: - module_size = 256; - break; - case 1: - module_size = 512; - break; - default: - case 2: - module_size = 1024; - break; - case 3: - module_size = 2048; - break; - case 4: - module_size = 4096; - break; - case 5: - module_size = 8192; - break; - case 6: - module_size = 16384; - break; - } - - module_size /= 8; - - switch(prim_bus_width) - { - case 0: - module_size *= 8; - break; - case 1: - module_size *= 16; - break; - case 2: - module_size *= 32; - break; - case 3: - module_size *= 64; - break; - } - - switch(sdram_width) - { - case 0: - module_size /= 4; - break; - case 1: - module_size /= 8; - break; - case 2: - module_size /= 16; - break; - case 3: - module_size /= 32; - break; - - } - - module_size *= (ranks + 1); - - return module_size; -} - - -int get_ddr2_module_size(int rank_density_byte, int rank_num_byte) -{ - int module_size; - - switch(rank_density_byte) - { - case 1: - module_size = 1024; - break; - case 2: - module_size = 2048; - break; - case 4: - module_size = 4096; - break; - case 8: - module_size = 8192; - break; - case 16: - module_size = 16384; - break; - case 32: - module_size = 128; - break; - case 64: - module_size = 256; - break; - default: - case 128: - module_size = 512; - break; - } - - module_size *= (rank_num_byte & 7) + 1; - - return module_size; - -} - - -struct ascii_map { - unsigned hex_code; - char *name; -}; - - -char* convert_hex_to_char(unsigned hex_org) { - static char buf[2] = " "; - if (hex_org >= 0x20 && hex_org < 0x80) { - buf[0] = hex_org; - } else { - //buf[0] = '\0'; - buf[0] = ' '; - } - - return buf; -} diff --git a/memtest86+_old/spd.h b/memtest86+_old/spd.h deleted file mode 100644 index 55f164f..0000000 --- a/memtest86+_old/spd.h +++ /dev/null @@ -1,17 +0,0 @@ -/* - * MemTest86+ V5.00 Specific code (GPL V2.0) - * By Samuel DEMEULEMEESTER, sdemeule@memtest.org - * http://www.canardpc.com - http://www.memtest.org - */ - -#define AMD_INDEX_IO_PORT 0xCD6 -#define AMD_DATA_IO_PORT 0xCD7 -#define AMD_SMBUS_BASE_REG 0x2C - -void get_spd_spec(void); -int get_ddr2_module_size(int rank_density_byte, int rank_num_byte); -int get_ddr3_module_size(int sdram_capacity, int prim_bus_width, int sdram_width, int ranks); -char* convert_hex_to_char(unsigned hex_org); -void sb800_get_smb(void); - - diff --git a/memtest86+_old/stddef.h b/memtest86+_old/stddef.h deleted file mode 100644 index 213c89b..0000000 --- a/memtest86+_old/stddef.h +++ /dev/null @@ -1,8 +0,0 @@ -#ifndef I386_STDDEF_H -#define I386_STDDEF_H - -#define NULL ((void *)0) - -typedef unsigned long size_t; - -#endif /* I386_STDDEF_H */ diff --git a/memtest86+_old/stdin.h b/memtest86+_old/stdin.h deleted file mode 100644 index e3a08e1..0000000 --- a/memtest86+_old/stdin.h +++ /dev/null @@ -1,52 +0,0 @@ -#ifndef I386_STDINT_H -#define I386_STDINT_H - -/* Exact integral types */ -typedef unsigned char uint8_t; -typedef signed char int8_t; - -typedef unsigned short uint16_t; -typedef signed short int16_t; - -typedef unsigned int uint32_t; -typedef signed int int32_t; - -typedef unsigned long long uint64_t; -typedef signed long long int64_t; - -/* Small types */ -typedef unsigned char uint_least8_t; -typedef signed char int_least8_t; - -typedef unsigned short uint_least16_t; -typedef signed short int_least16_t; - -typedef unsigned int uint_least32_t; -typedef signed int int_least32_t; - -typedef unsigned long long uint_least64_t; -typedef signed long long int_least64_t; - -/* Fast Types */ -typedef unsigned char uint_fast8_t; -typedef signed char int_fast8_t; - -typedef unsigned int uint_fast16_t; -typedef signed int int_fast16_t; - -typedef unsigned int uint_fast32_t; -typedef signed int int_fast32_t; - -typedef unsigned long long uint_fast64_t; -typedef signed long long int_fast64_t; - -/* Types for `void *' pointers. */ -typedef int intptr_t; -typedef unsigned int uintptr_t; - -/* Largest integral types */ -typedef long long int intmax_t; -typedef unsigned long long uintmax_t; - - -#endif /* I386_STDINT_H */ \ No newline at end of file diff --git a/memtest86+_old/stdint.h b/memtest86+_old/stdint.h deleted file mode 100644 index 1c136e0..0000000 --- a/memtest86+_old/stdint.h +++ /dev/null @@ -1,60 +0,0 @@ -#ifndef I386_STDINT_H -#define I386_STDINT_H - -/* Exact integral types */ -typedef unsigned char uint8_t; -typedef signed char int8_t; - -typedef unsigned short uint16_t; -typedef signed short int16_t; - -typedef unsigned int uint32_t; -typedef signed int int32_t; - -typedef unsigned long long uint64_t; -typedef signed long long int64_t; - -/* Small types */ -typedef unsigned char uint_least8_t; -typedef signed char int_least8_t; - -typedef unsigned short uint_least16_t; -typedef signed short int_least16_t; - -typedef unsigned int uint_least32_t; -typedef signed int int_least32_t; - -typedef unsigned long long uint_least64_t; -typedef signed long long int_least64_t; - -/* Fast Types */ -typedef unsigned char uint_fast8_t; -typedef signed char int_fast8_t; - -typedef unsigned int uint_fast16_t; -typedef signed int int_fast16_t; - -typedef unsigned int uint_fast32_t; -typedef signed int int_fast32_t; - -typedef unsigned long long uint_fast64_t; -typedef signed long long int_fast64_t; - -/* Types for `void *' pointers. */ -typedef int intptr_t; -typedef unsigned int uintptr_t; - -/* Largest integral types */ -typedef long long int intmax_t; -typedef unsigned long long uintmax_t; - -typedef char bool; -#ifndef FALSE -#define FALSE 0 -#endif - -#ifndef TRUE -#define TRUE 1 -#endif - -#endif /* I386_STDINT_H */ diff --git a/memtest86+_old/test.c b/memtest86+_old/test.c deleted file mode 100644 index 864dfcc..0000000 --- a/memtest86+_old/test.c +++ /dev/null @@ -1,1549 +0,0 @@ -/* test.c - MemTest-86 Version 3.4 - * - * Released under version 2 of the Gnu Public License. - * By Chris Brady - * ---------------------------------------------------- - * MemTest86+ V5 Specific code (GPL V2.0) - * By Samuel DEMEULEMEESTER, sdemeule@memtest.org - * http://www.canardpc.com - http://www.memtest.org - * Thanks to Passmark for calculate_chunk() and various comments ! - */ - -#include "test.h" -#include "config.h" -#include "stdint.h" -#include "cpuid.h" -#include "smp.h" -#include "io.h" - -extern struct cpu_ident cpu_id; -extern volatile int mstr_cpu; -extern volatile int run_cpus; -extern volatile int test; -extern volatile int segs, bail; -extern int test_ticks, nticks; -extern struct tseq tseq[]; -extern void update_err_counts(void); -extern void print_err_counts(void); -void rand_seed( unsigned int seed1, unsigned int seed2, int me); -ulong rand(int me); -void poll_errors(); - -// NOTE(jcoiner): -// Defining 'STATIC' to empty string results in crashes. (It should -// work fine, of course.) I suspect relocation problems in reloc.c. -// When we declare these routines static, we use relative addresses -// for them instead of looking up their addresses in (supposedly -// relocated) global elf tables, which avoids the crashes. - -#define STATIC static -//#define STATIC - -#define PREFER_C 0 - -static const void* const nullptr = 0x0; - -// Writes *start and *end with the VA range to test. -// -// me - this threads CPU number -// j - index into v->map for current segment we are testing -// align - number of bytes to align each block to -STATIC void calculate_chunk(ulong** start, ulong** end, int me, - int j, int makeMultipleOf) { - ulong chunk; - - // If we are only running 1 CPU then test the whole block - if (run_cpus == 1) { - *start = vv->map[j].start; - *end = vv->map[j].end; - } else { - - // Divide the current segment by the number of CPUs - chunk = (ulong)vv->map[j].end-(ulong)vv->map[j].start; - chunk /= run_cpus; - - // Round down to the nearest desired bitlength multiple - chunk = (chunk + (makeMultipleOf-1)) & ~(makeMultipleOf-1); - - // Figure out chunk boundaries - *start = (ulong*)((ulong)vv->map[j].start+(chunk*me)); - /* Set end addrs for the highest CPU num to the - * end of the segment for rounding errors */ - /* Also rounds down to boundary if needed, may miss some ram but - better than crashing or producing false errors. */ - /* This rounding probably will never happen as the segments should - be in 4096 bytes pages if I understand correctly. */ - if (me == mstr_cpu) { - *end = (ulong*)(vv->map[j].end); - } else { - *end = (ulong*)((ulong)(*start) + chunk); - (*end)--; - } - } -} - -/* Call segment_fn() for each up-to-SPINSZ segment between - * 'start' and 'end'. - */ -void foreach_segment -(ulong* start, ulong* end, - int me, const void* ctx, segment_fn func) { - - ASSERT(start < end); - - // Confirm 'start' points to an even dword, and 'end' - // should point to an odd dword - ASSERT(0 == (((ulong)start) & 0x7)); - ASSERT(0x4 == (((ulong)end) & 0x7)); - - // 'end' may be exactly 0xfffffffc, right at the 4GB boundary. - // - // To avoid overflow in our loop tests and length calculations, - // use dword indices (the '_dw' vars) to avoid overflows. - ulong start_dw = ((ulong)start) >> 2; - ulong end_dw = ((ulong) end) >> 2; - - // end is always xxxxxffc, but increment end_dw to an - // address beyond the segment for easier boundary calculations. - ++end_dw; - - ulong seg_dw = start_dw; - ulong seg_end_dw = start_dw; - - int done = 0; - do { - do_tick(me); - { BAILR } - - // ensure no overflow - ASSERT((seg_end_dw + SPINSZ_DWORDS) > seg_end_dw); - seg_end_dw += SPINSZ_DWORDS; - - if (seg_end_dw >= end_dw) { - seg_end_dw = end_dw; - done++; - } - if (seg_dw == seg_end_dw) { - break; - } - - ASSERT(((ulong)seg_end_dw) <= 0x40000000); - ASSERT(seg_end_dw > seg_dw); - ulong seg_len_dw = seg_end_dw - seg_dw; - - func((ulong*)(seg_dw << 2), seg_len_dw, ctx); - - seg_dw = seg_end_dw; - } while (!done); -} - -/* Calls segment_fn() for each segment in vv->map. - * - * Does not slice by CPU number, so it covers the entire memory. - * Contrast to sliced_foreach_segment(). - */ -STATIC void unsliced_foreach_segment -(const void* ctx, int me, segment_fn func) { - int j; - for (j=0; jmap[j].start, - vv->map[j].end, - me, ctx, func); - } -} - -/* Calls segment_fn() for each segment to be tested by CPU 'me'. - * - * In multicore mode, slices the segments by 'me' (the CPU ordinal - * number) so that each call will cover only 1/Nth of memory. - */ -STATIC void sliced_foreach_segment -(const void *ctx, int me, segment_fn func) { - int j; - ulong *start, *end; // VAs - ulong* prev_end = 0; - for (j=0; j start); - if (prev_end > 0) { - ASSERT(prev_end < start); - } - prev_end = end; - - foreach_segment(start, end, me, ctx, func); - } -} - -STATIC void addr_tst1_seg(ulong* restrict buf, - ulong len_dw, const void* unused) { - // Within each segment: - // - choose a low dword offset 'off' - // - write pat to *off - // - write ~pat to addresses that are above off by - // 1, 2, 4, ... dwords up to the top of the segment. None - // should alias to the original dword. - // - write ~pat to addresses that are below off by - // 1, 2, 4, etc dwords, down to the start of the segment. None - // should alias to the original dword. If adding a given offset - // doesn't produce a single bit address flip (because it produced - // a carry) subtracting the same offset should give a single bit flip. - // - repeat this, moving off ahead in increments of 1MB; - // this covers address bits within physical memory banks, we hope? - - ulong pat; - int k; - - for (pat=0x5555aaaa, k=0; k<2; k++) { - hprint(LINE_PAT, COL_PAT, pat); - - for (ulong off_dw = 0; off_dw < len_dw; off_dw += (1 << 18)) { - buf[off_dw] = pat; - pat = ~pat; - - for (ulong more_off_dw = 1; off_dw + more_off_dw < len_dw; - more_off_dw = more_off_dw << 1) { - ASSERT(more_off_dw); // it should never get to zero - buf[off_dw + more_off_dw] = pat; - ulong bad; - if ((bad = buf[off_dw]) != ~pat) { - ad_err1(buf + off_dw, - buf + off_dw + more_off_dw, - bad, ~pat); - break; - } - } - for (ulong more_off_dw = 1; off_dw > more_off_dw; - more_off_dw = more_off_dw << 1) { - ASSERT(more_off_dw); // it should never get to zero - buf[off_dw - more_off_dw] = pat; - ulong bad; - if ((bad = buf[off_dw]) != ~pat) { - ad_err1(buf + off_dw, - buf + off_dw - more_off_dw, - bad, ~pat); - break; - } - } - } - } -} - -/* - * Memory address test, walking ones - */ -void addr_tst1(int me) -{ - unsliced_foreach_segment(nullptr, me, addr_tst1_seg); -} - -STATIC void addr_tst2_init_segment(ulong* p, - ulong len_dw, const void* unused) { - ulong* pe = p + (len_dw - 1); - - /* Original C code replaced with hand tuned assembly code - * for (; p <= pe; p++) { - * *p = (ulong)p; - * } - */ - asm __volatile__ ( - "jmp L91\n\t" - ".p2align 4,,7\n\t" - "L90:\n\t" - "addl $4,%%edi\n\t" - "L91:\n\t" - "movl %%edi,(%%edi)\n\t" - "cmpl %%edx,%%edi\n\t" - "jb L90\n\t" - : : "D" (p), "d" (pe) - ); -} - -STATIC void addr_tst2_check_segment(ulong* p, - ulong len_dw, const void* unused) { - ulong* pe = p + (len_dw - 1); - - /* Original C code replaced with hand tuned assembly code - * for (; p <= pe; p++) { - * if((bad = *p) != (ulong)p) { - * ad_err2((ulong)p, bad); - * } - * } - */ - asm __volatile__ - ( - "jmp L95\n\t" - ".p2align 4,,7\n\t" - "L99:\n\t" - "addl $4,%%edi\n\t" - "L95:\n\t" - "movl (%%edi),%%ecx\n\t" - "cmpl %%edi,%%ecx\n\t" - "jne L97\n\t" - "L96:\n\t" - "cmpl %%edx,%%edi\n\t" - "jb L99\n\t" - "jmp L98\n\t" - - "L97:\n\t" - "pushl %%edx\n\t" - "pushl %%ecx\n\t" - "pushl %%edi\n\t" - "call ad_err2\n\t" - "popl %%edi\n\t" - "popl %%ecx\n\t" - "popl %%edx\n\t" - "jmp L96\n\t" - - "L98:\n\t" - : : "D" (p), "d" (pe) - : "ecx" - ); -} - -/* - * Memory address test, own address - */ -void addr_tst2(int me) -{ - cprint(LINE_PAT, COL_PAT, "address "); - - /* Write each address with its own address */ - unsliced_foreach_segment(nullptr, me, addr_tst2_init_segment); - { BAILR } - - /* Each address should have its own address */ - unsliced_foreach_segment(nullptr, me, addr_tst2_check_segment); -} - -typedef struct { - int me; - ulong xorVal; -} movinvr_ctx; - -STATIC void movinvr_init(ulong* p, - ulong len_dw, const void* vctx) { - ulong* pe = p + (len_dw - 1); - const movinvr_ctx* ctx = (const movinvr_ctx*)vctx; - /* Original C code replaced with hand tuned assembly code */ - /* - for (; p <= pe; p++) { - *p = rand(me); - } - */ - - asm __volatile__ - ( - "jmp L200\n\t" - ".p2align 4,,7\n\t" - "L201:\n\t" - "addl $4,%%edi\n\t" - "L200:\n\t" - "pushl %%ecx\n\t" - "call rand\n\t" - "popl %%ecx\n\t" - "movl %%eax,(%%edi)\n\t" - "cmpl %%ebx,%%edi\n\t" - "jb L201\n\t" - : : "D" (p), "b" (pe), "c" (ctx->me) - : "eax" - ); -} - -STATIC void movinvr_body(ulong* p, ulong len_dw, const void* vctx) { - ulong* pe = p + (len_dw - 1); - const movinvr_ctx* ctx = (const movinvr_ctx*)vctx; - - /* Original C code replaced with hand tuned assembly code */ - - /*for (; p <= pe; p++) { - num = rand(me); - if (i) { - num = ~num; - } - if ((bad=*p) != num) { - mt86_error((ulong*)p, num, bad); - } - *p = ~num; - }*/ - - asm __volatile__ - ( - "pushl %%ebp\n\t" - - // Skip first increment - "jmp L26\n\t" - ".p2align 4,,7\n\t" - - // increment 4 bytes (32-bits) - "L27:\n\t" - "addl $4,%%edi\n\t" - - // Check this byte - "L26:\n\t" - - // Get next random number, pass in me(edx), random value returned in num(eax) - // num = rand(me); - // cdecl call maintains all registers except eax, ecx, and edx - // We maintain edx with a push and pop here using it also as an input - // we don't need the current eax value and want it to change to the return value - // we overwrite ecx shortly after this discarding its current value - "pushl %%edx\n\t" // Push function inputs onto stack - "call rand\n\t" - "popl %%edx\n\t" // Remove function inputs from stack - - // XOR the random number with xorVal(ebx), which is either 0xffffffff or 0 depending on the outer loop - // if (i) { num = ~num; } - "xorl %%ebx,%%eax\n\t" - - // Move the current value of the current position p(edi) into bad(ecx) - // (bad=*p) - "movl (%%edi),%%ecx\n\t" - - // Compare bad(ecx) to num(eax) - "cmpl %%eax,%%ecx\n\t" - - // If not equal jump the error case - "jne L23\n\t" - - // Set a new value or not num(eax) at the current position p(edi) - // *p = ~num; - "L25:\n\t" - "movl $0xffffffff,%%ebp\n\t" - "xorl %%ebp,%%eax\n\t" - "movl %%eax,(%%edi)\n\t" - - // Loop until current position p(edi) equals the end position pe(esi) - "cmpl %%esi,%%edi\n\t" - "jb L27\n\t" - "jmp L24\n" - - // Error case - "L23:\n\t" - // Must manually maintain eax, ecx, and edx as part of cdecl call convention - "pushl %%edx\n\t" - "pushl %%ecx\n\t" // Next three pushes are functions input - "pushl %%eax\n\t" - "pushl %%edi\n\t" - "call mt86_error\n\t" - "popl %%edi\n\t" // Remove function inputs from stack and restore register values - "popl %%eax\n\t" - "popl %%ecx\n\t" - "popl %%edx\n\t" - "jmp L25\n" - - "L24:\n\t" - "popl %%ebp\n\t" - :: "D" (p), "S" (pe), "b" (ctx->xorVal), - "d" (ctx->me) - : "eax", "ecx" - ); -} - -/* - * Test all of memory using a "half moving inversions" algorithm using random - * numbers and their complement as the data pattern. Since we are not able to - * produce random numbers in reverse order testing is only done in the forward - * direction. - */ -void movinvr(int me) -{ - int i, seed1, seed2; - - movinvr_ctx ctx; - ctx.me = me; - ctx.xorVal = 0; - - /* Initialize memory with initial sequence of random numbers. */ - if (cpu_id.fid.bits.rdtsc) { - asm __volatile__ ("rdtsc":"=a" (seed1),"=d" (seed2)); - } else { - seed1 = 521288629 + vv->pass; - seed2 = 362436069 - vv->pass; - } - - /* Display the current seed */ - if (mstr_cpu == me) hprint(LINE_PAT, COL_PAT, seed1); - rand_seed(seed1, seed2, me); - - sliced_foreach_segment(&ctx, me, movinvr_init); - { BAILR } - - /* Do moving inversions test. Check for initial pattern and then - * write the complement for each memory location. - */ - for (i=0; i<2; i++) { - rand_seed(seed1, seed2, me); - - if (i) { - ctx.xorVal = 0xffffffff; - } else { - ctx.xorVal = 0; - } - - sliced_foreach_segment(&ctx, me, movinvr_body); - { BAILR } - } -} - -typedef struct { - ulong p1; - ulong p2; -} movinv1_ctx; - -STATIC void movinv1_init(ulong* start, - ulong len_dw, const void* vctx) { - const movinv1_ctx* ctx = (const movinv1_ctx*)vctx; - - ulong p1 = ctx->p1; - ulong* p = start; - - asm __volatile__ - ( - "rep\n\t" - "stosl\n\t" - : : "c" (len_dw), "D" (p), "a" (p1) - ); -} - -STATIC void movinv1_bottom_up(ulong* start, - ulong len_dw, const void* vctx) { - const movinv1_ctx* ctx = (const movinv1_ctx*)vctx; - ulong p1 = ctx->p1; - ulong p2 = ctx->p2; - ulong* p = start; - ulong* pe = p + (len_dw - 1); - - // Original C code replaced with hand tuned assembly code - // seems broken - /*for (; p <= pe; p++) { - if ((bad=*p) != p1) { - mt86_error((ulong*)p, p1, bad); - } - *p = p2; - }*/ - - asm __volatile__ - ( - "jmp L2\n\t" - ".p2align 4,,7\n\t" - "L0:\n\t" - "addl $4,%%edi\n\t" - "L2:\n\t" - "movl (%%edi),%%ecx\n\t" - "cmpl %%eax,%%ecx\n\t" - "jne L3\n\t" - "L5:\n\t" - "movl %%ebx,(%%edi)\n\t" - "cmpl %%edx,%%edi\n\t" - "jb L0\n\t" - "jmp L4\n" - - "L3:\n\t" - "pushl %%edx\n\t" - "pushl %%ebx\n\t" - "pushl %%ecx\n\t" - "pushl %%eax\n\t" - "pushl %%edi\n\t" - "call mt86_error\n\t" - "popl %%edi\n\t" - "popl %%eax\n\t" - "popl %%ecx\n\t" - "popl %%ebx\n\t" - "popl %%edx\n\t" - "jmp L5\n" - - "L4:\n\t" - :: "a" (p1), "D" (p), "d" (pe), "b" (p2) - : "ecx" - ); -} - -STATIC void movinv1_top_down(ulong* start, - ulong len_dw, const void* vctx) { - const movinv1_ctx* ctx = (const movinv1_ctx*)vctx; - ulong p1 = ctx->p1; - ulong p2 = ctx->p2; - ulong* p = start + (len_dw - 1); - ulong* pe = start; - - //Original C code replaced with hand tuned assembly code - // seems broken - /*do { - if ((bad=*p) != p2) { - mt86_error((ulong*)p, p2, bad); - } - *p = p1; - } while (--p >= pe);*/ - - asm __volatile__ - ( - "jmp L9\n\t" - ".p2align 4,,7\n\t" - "L11:\n\t" - "subl $4, %%edi\n\t" - "L9:\n\t" - "movl (%%edi),%%ecx\n\t" - "cmpl %%ebx,%%ecx\n\t" - "jne L6\n\t" - "L10:\n\t" - "movl %%eax,(%%edi)\n\t" - "cmpl %%edi, %%edx\n\t" - "jne L11\n\t" - "jmp L7\n\t" - - "L6:\n\t" - "pushl %%edx\n\t" - "pushl %%eax\n\t" - "pushl %%ecx\n\t" - "pushl %%ebx\n\t" - "pushl %%edi\n\t" - "call mt86_error\n\t" - "popl %%edi\n\t" - "popl %%ebx\n\t" - "popl %%ecx\n\t" - "popl %%eax\n\t" - "popl %%edx\n\t" - "jmp L10\n" - - "L7:\n\t" - :: "a" (p1), "D" (p), "d" (pe), "b" (p2) - : "ecx" - ); -} - -/* - * Test all of memory using a "moving inversions" algorithm using the - * pattern in p1 and its complement in p2. - */ -void movinv1 (int iter, ulong p1, ulong p2, int me) -{ - int i; - - /* Display the current pattern */ - if (mstr_cpu == me) hprint(LINE_PAT, COL_PAT, p1); - - movinv1_ctx ctx; - ctx.p1 = p1; - ctx.p2 = p2; - sliced_foreach_segment(&ctx, me, movinv1_init); - { BAILR } - - /* Do moving inversions test. Check for initial pattern and then - * write the complement for each memory location. Test from bottom - * up and then from the top down. */ - for (i=0; ioff; - ulong pat = ctx->p1; - ulong lb = ctx->lb; - int sval = ctx->sval; - - /* Original C code replaced with hand tuned assembly code - * while (p <= pe) { - * *p = pat; - * if (++k >= 32) { - * pat = lb; - * k = 0; - * } else { - * pat = pat << 1; - * pat |= sval; - * } - * p++; - * } - */ - asm __volatile__ - ( - "jmp L20\n\t" - ".p2align 4,,7\n\t" - "L923:\n\t" - "addl $4,%%edi\n\t" - "L20:\n\t" - "movl %%ecx,(%%edi)\n\t" - "addl $1,%%ebx\n\t" - "cmpl $32,%%ebx\n\t" - "jne L21\n\t" - "movl %%esi,%%ecx\n\t" - "xorl %%ebx,%%ebx\n\t" - "jmp L22\n" - "L21:\n\t" - "shll $1,%%ecx\n\t" - "orl %%eax,%%ecx\n\t" - "L22:\n\t" - "cmpl %%edx,%%edi\n\t" - "jb L923\n\t" - :: "D" (p),"d" (pe),"b" (k),"c" (pat), - "a" (sval), "S" (lb) - ); -} - -STATIC void movinv32_bottom_up(ulong* restrict buf, ulong len_dw, - const void* vctx) { - const movinv32_ctx* restrict ctx = (const movinv32_ctx*)vctx; - - ulong* p = buf; - ulong* pe = buf + (len_dw - 1); - - int k = ctx->off; - ulong pat = ctx->p1; - ulong lb = ctx->lb; - int sval = ctx->sval; - - /* Original C code replaced with hand tuned assembly code - * while (1) { - * if ((bad=*p) != pat) { - * mt86_error((ulong*)p, pat, bad); - * } - * *p = ~pat; - * if (p >= pe) break; - * p++; - * - * if (++k >= 32) { - * pat = lb; - * k = 0; - * } else { - * pat = pat << 1; - * pat |= sval; - * } - * } - */ - asm __volatile__ - ( - "pushl %%ebp\n\t" - "jmp L30\n\t" - ".p2align 4,,7\n\t" - "L930:\n\t" - "addl $4,%%edi\n\t" - "L30:\n\t" - "movl (%%edi),%%ebp\n\t" - "cmpl %%ecx,%%ebp\n\t" - "jne L34\n\t" - - "L35:\n\t" - "notl %%ecx\n\t" - "movl %%ecx,(%%edi)\n\t" - "notl %%ecx\n\t" - "incl %%ebx\n\t" - "cmpl $32,%%ebx\n\t" - "jne L31\n\t" - "movl %%esi,%%ecx\n\t" - "xorl %%ebx,%%ebx\n\t" - "jmp L32\n" - "L31:\n\t" - "shll $1,%%ecx\n\t" - "orl %%eax,%%ecx\n\t" - "L32:\n\t" - "cmpl %%edx,%%edi\n\t" - "jb L930\n\t" - "jmp L33\n\t" - - "L34:\n\t" - "pushl %%esi\n\t" - "pushl %%eax\n\t" - "pushl %%ebx\n\t" - "pushl %%edx\n\t" - "pushl %%ebp\n\t" - "pushl %%ecx\n\t" - "pushl %%edi\n\t" - "call mt86_error\n\t" - "popl %%edi\n\t" - "popl %%ecx\n\t" - "popl %%ebp\n\t" - "popl %%edx\n\t" - "popl %%ebx\n\t" - "popl %%eax\n\t" - "popl %%esi\n\t" - "jmp L35\n" - - "L33:\n\t" - "popl %%ebp\n\t" - : "=b" (k),"=c" (pat) - : "D" (p),"d" (pe),"b" (k),"c" (pat), - "a" (sval), "S" (lb) - ); -} - -STATIC void movinv32_top_down(ulong* restrict buf, - ulong len_dw, const void* vctx) { - const movinv32_ctx* restrict ctx = (const movinv32_ctx*)vctx; - - ulong* pe = buf; - ulong* p = buf + (len_dw - 1); - - int k = ctx->off; - ulong pat = ctx->p1; - ulong hb = ctx->hb; - int sval = ctx->sval; - ulong p3 = (ulong)sval << 31; - - // Advance 'k' and 'pat' to where they would have been - // at the end of the corresponding bottom_up segment. - // - // The '-1' is because we didn't advance 'k' or 'pat' - // on the final bottom_up loop, so they're off by one... - ulong mod_len = (len_dw - 1) % 32; - for (int i = 0; i < mod_len; i++) { - if (++k >= 32) { - pat = ctx->lb; - k = 0; - } else { - pat = pat << 1; - pat |= sval; - } - } - - // Increment 'k' only because the code below has an off-by-one - // interpretation of 'k' relative to the bottom_up routine. - // There it ranges from 0:31, and here it ranges from 1:32. - k++; - - /* Original C code replaced with hand tuned assembly code */ -#if PREFER_C - ulong bad; - while(1) { - if ((bad=*p) != ~pat) { - mt86_error((ulong*)p, ~pat, bad); - } - *p = pat; - if (p <= pe) break; - p--; - - if (--k <= 0) { - k = 32; - pat = hb; - } else { - pat = pat >> 1; - pat |= p3; - } - }; -#else - asm __volatile__ - ( - "pushl %%ebp\n\t" - "jmp L40\n\t" - ".p2align 4,,7\n\t" - "L49:\n\t" - "subl $4,%%edi\n\t" - "L40:\n\t" - "movl (%%edi),%%ebp\n\t" - "notl %%ecx\n\t" - "cmpl %%ecx,%%ebp\n\t" - "jne L44\n\t" - - "L45:\n\t" - "notl %%ecx\n\t" - "movl %%ecx,(%%edi)\n\t" - "decl %%ebx\n\t" - "cmpl $0,%%ebx\n\t" - "jg L41\n\t" - "movl %%esi,%%ecx\n\t" - "movl $32,%%ebx\n\t" - "jmp L42\n" - "L41:\n\t" - "shrl $1,%%ecx\n\t" - "orl %%eax,%%ecx\n\t" - "L42:\n\t" - "cmpl %%edx,%%edi\n\t" - "ja L49\n\t" - "jmp L43\n\t" - - "L44:\n\t" - "pushl %%esi\n\t" - "pushl %%eax\n\t" - "pushl %%ebx\n\t" - "pushl %%edx\n\t" - "pushl %%ebp\n\t" - "pushl %%ecx\n\t" - "pushl %%edi\n\t" - "call mt86_error\n\t" - "popl %%edi\n\t" - "popl %%ecx\n\t" - "popl %%ebp\n\t" - "popl %%edx\n\t" - "popl %%ebx\n\t" - "popl %%eax\n\t" - "popl %%esi\n\t" - "jmp L45\n" - - "L43:\n\t" - "popl %%ebp\n\t" - : : "D" (p),"d" (pe),"b" (k),"c" (pat), - "a" (p3), "S" (hb) - ); -#endif -} - -void movinv32(int iter, ulong p1, ulong lb, ulong hb, int sval, int off,int me) -{ - // First callsite: - // - p1 has 1 bit set (somewhere) - // - lb = 1 ("low bit") - // - hb = 0x80000000 ("high bit") - // - sval = 0 - // - 'off' indicates the position of the set bit in p1 - // - // Second callsite is the same, but inverted: - // - p1 has 1 bit clear (somewhere) - // - lb = 0xfffffffe - // - hb = 0x7fffffff - // - sval = 1 - // - 'off' indicates the position of the cleared bit in p1 - - movinv32_ctx ctx; - ctx.p1 = p1; - ctx.lb = lb; - ctx.hb = hb; - ctx.sval = sval; - ctx.off = off; - - /* Display the current pattern */ - if (mstr_cpu == me) hprint(LINE_PAT, COL_PAT, p1); - - sliced_foreach_segment(&ctx, me, movinv32_init); - { BAILR } - - /* Do moving inversions test. Check for initial pattern and then - * write the complement for each memory location. Test from bottom - * up and then from the top down. */ - for (int i=0; ip1; - ulong offset = ctx->offset; - -#if PREFER_C - for (ulong i = offset; i < len_dw; i += MOD_SZ) { - start[i] = p1; - } -#else - ulong* p = start + offset; - ulong* pe = start + len_dw; - asm __volatile__ - ( - "jmp L60\n\t" - ".p2align 4,,7\n\t" - - "L60:\n\t" - "movl %%eax,(%%edi)\n\t" - "addl $80,%%edi\n\t" - "cmpl %%edx,%%edi\n\t" - "jb L60\n\t" - :: "D" (p), "d" (pe), "a" (p1) - ); -#endif -} - -STATIC void modtst_dense_writes(ulong* restrict start, ulong len_dw, - const void* vctx) { - const modtst_ctx* restrict ctx = (const modtst_ctx*)vctx; - ulong p2 = ctx->p2; - ulong offset = ctx->offset; - - ASSERT(offset < MOD_SZ); - - ulong k = 0; -#if PREFER_C - for (ulong i = 0; i < len_dw; i++) { - if (k != offset) { - start[i] = p2; - } - if (++k >= MOD_SZ) { - k = 0; - } - } -#else - ulong* pe = start + (len_dw - 1); - asm __volatile__ - ( - "jmp L50\n\t" - ".p2align 4,,7\n\t" - - "L54:\n\t" - "addl $4,%%edi\n\t" - "L50:\n\t" - "cmpl %%ebx,%%ecx\n\t" - "je L52\n\t" - "movl %%eax,(%%edi)\n\t" - "L52:\n\t" - "incl %%ebx\n\t" - "cmpl $19,%%ebx\n\t" - "jle L53\n\t" - "xorl %%ebx,%%ebx\n\t" - "L53:\n\t" - "cmpl %%edx,%%edi\n\t" - "jb L54\n\t" - : : "D" (start), "d" (pe), "a" (p2), - "b" (k), "c" (offset) - ); -#endif -} - -STATIC void modtst_check(ulong* restrict start, - ulong len_dw, const void* vctx) { - const modtst_ctx* restrict ctx = (const modtst_ctx*)vctx; - ulong p1 = ctx->p1; - ulong offset = ctx->offset; - - ASSERT(offset < MOD_SZ); - -#if PREFER_C - ulong bad; - for (ulong i = offset; i < len_dw; i += MOD_SZ) { - if ((bad = start[i]) != p1) - mt86_error(start + i, p1, bad); - } -#else - ulong* p = start + offset; - ulong* pe = start + len_dw; - asm __volatile__ - ( - "jmp L70\n\t" - ".p2align 4,,7\n\t" - - "L70:\n\t" - "movl (%%edi),%%ecx\n\t" - "cmpl %%eax,%%ecx\n\t" - "jne L71\n\t" - "L72:\n\t" - "addl $80,%%edi\n\t" - "cmpl %%edx,%%edi\n\t" - "jb L70\n\t" - "jmp L73\n\t" - - "L71:\n\t" - "pushl %%edx\n\t" - "pushl %%ecx\n\t" - "pushl %%eax\n\t" - "pushl %%edi\n\t" - "call mt86_error\n\t" - "popl %%edi\n\t" - "popl %%eax\n\t" - "popl %%ecx\n\t" - "popl %%edx\n\t" - "jmp L72\n" - - "L73:\n\t" - : : "D" (p), "d" (pe), "a" (p1) - : "ecx" - ); -#endif -} - -/* - * Test all of memory using modulo X access pattern. - */ -void modtst(int offset, int iter, ulong p1, ulong p2, int me) -{ - modtst_ctx ctx; - ctx.offset = offset; - ctx.p1 = p1; - ctx.p2 = p2; - - /* Display the current pattern */ - if (mstr_cpu == me) { - hprint(LINE_PAT, COL_PAT-2, p1); - cprint(LINE_PAT, COL_PAT+6, "-"); - dprint(LINE_PAT, COL_PAT+7, offset, 2, 1); - } - - /* Write every nth location with pattern */ - sliced_foreach_segment(&ctx, me, modtst_sparse_writes); - { BAILR } - - /* Write the rest of memory "iter" times with the pattern complement */ - for (ulong i=0; i> 5) << 5; - ASSERT(result > 0); - return result; -} - -STATIC void block_move_init(ulong* restrict buf, - ulong len_dw, const void* unused_ctx) { - len_dw = block_move_normalize_len_dw(len_dw); - - // Compute 'len' in units of 64-byte chunks: - ulong len = len_dw >> 4; - - // We only need to initialize len/2, since we'll just copy - // the first half onto the second half in the move step. - len = len >> 1; - - ulong base_val = 1; -#if PREFER_C - while(len > 0) { - ulong neg_val = ~base_val; - - // Set a block of 64 bytes // first block DWORDS are: - buf[0] = base_val; // 0x00000001 - buf[1] = base_val; // 0x00000001 - buf[2] = base_val; // 0x00000001 - buf[3] = base_val; // 0x00000001 - buf[4] = neg_val; // 0xfffffffe - buf[5] = neg_val; // 0xfffffffe - buf[6] = base_val; // 0x00000001 - buf[7] = base_val; // 0x00000001 - buf[8] = base_val; // 0x00000001 - buf[9] = base_val; // 0x00000001 - buf[10] = neg_val; // 0xfffffffe - buf[11] = neg_val; // 0xfffffffe - buf[12] = base_val; // 0x00000001 - buf[13] = base_val; // 0x00000001 - buf[14] = neg_val; // 0xfffffffe - buf[15] = neg_val; // 0xfffffffe - - buf += 16; // advance to next 64-byte block - len--; - - // Rotate the bit left, including an all-zero state. - // It can't hurt to have a periodicity of 33 instead of - // a power of two. - if (base_val == 0) { - base_val = 1; - } else if (base_val & 0x80000000) { - base_val = 0; - } else { - base_val = base_val << 1; - } - } -#else - asm __volatile__ - ( - "jmp L100\n\t" - - ".p2align 4,,7\n\t" - "L100:\n\t" - - // First loop eax is 0x00000001, edx is 0xfffffffe - "movl %%eax, %%edx\n\t" - "notl %%edx\n\t" - - // Set a block of 64-bytes // First loop DWORDS are - "movl %%eax,0(%%edi)\n\t" // 0x00000001 - "movl %%eax,4(%%edi)\n\t" // 0x00000001 - "movl %%eax,8(%%edi)\n\t" // 0x00000001 - "movl %%eax,12(%%edi)\n\t" // 0x00000001 - "movl %%edx,16(%%edi)\n\t" // 0xfffffffe - "movl %%edx,20(%%edi)\n\t" // 0xfffffffe - "movl %%eax,24(%%edi)\n\t" // 0x00000001 - "movl %%eax,28(%%edi)\n\t" // 0x00000001 - "movl %%eax,32(%%edi)\n\t" // 0x00000001 - "movl %%eax,36(%%edi)\n\t" // 0x00000001 - "movl %%edx,40(%%edi)\n\t" // 0xfffffffe - "movl %%edx,44(%%edi)\n\t" // 0xfffffffe - "movl %%eax,48(%%edi)\n\t" // 0x00000001 - "movl %%eax,52(%%edi)\n\t" // 0x00000001 - "movl %%edx,56(%%edi)\n\t" // 0xfffffffe - "movl %%edx,60(%%edi)\n\t" // 0xfffffffe - - // rotate left with carry, - // second loop eax is 0x00000002 - // second loop edx is (~eax) 0xfffffffd - "rcll $1, %%eax\n\t" - - // Move current position forward 64-bytes (to start of next block) - "leal 64(%%edi), %%edi\n\t" - - // Loop until end - "decl %%ecx\n\t" - "jnz L100\n\t" - - : : "D" (buf), "c" (len), "a" (base_val) - : "edx" - ); -#endif -} - -typedef struct { - int iter; - int me; -} block_move_ctx; - -STATIC void block_move_move(ulong* restrict buf, - ulong len_dw, const void* vctx) { - const block_move_ctx* restrict ctx = (const block_move_ctx*)vctx; - ulong iter = ctx->iter; - int me = ctx->me; - - len_dw = block_move_normalize_len_dw(len_dw); - - /* Now move the data around - * First move the data up half of the segment size we are testing - * Then move the data to the original location + 32 bytes - */ - ulong half_len_dw = len_dw / 2; // Half the size of this block in DWORDS - ASSERT(half_len_dw > 8); - - ulong* mid = buf + half_len_dw; // VA at mid-point of this block. - for (int i=0; i 0) { - // foreach_segment() called this before the 0th iteration, - // so don't tick twice in quick succession. - do_tick(me); - } - { BAILR } - -#if PREFER_C - // Move first half to 2nd half: - movsl(/*dest=*/ mid, /*src=*/ buf, half_len_dw); - - // Move the second half, less the last 8 dwords - // to the first half plus an offset of 8 dwords. - movsl(/*dest=*/ buf + 8, /*src=*/ mid, half_len_dw - 8); - - // Finally, move the last 8 dwords of the 2nd half - // to the first 8 dwords of the first half. - movsl(/*dest=*/ mid + half_len_dw - 8, /*src=*/ buf, 8); -#else - asm __volatile__ - ( - "cld\n" - "jmp L110\n\t" - - ".p2align 4,,7\n\t" - "L110:\n\t" - - // - // At the end of all this - // - the second half equals the inital value of the first half - // - the first half is right shifted 32-bytes (with wrapping) - // - - // Move first half to second half - "movl %1,%%edi\n\t" // Destination 'mid' (mid point) - "movl %0,%%esi\n\t" // Source, 'buf' (start point) - "movl %2,%%ecx\n\t" // Length, 'half_len_dw' (size of a half in DWORDS) - "rep\n\t" - "movsl\n\t" - - // Move the second half, less the last 32-bytes. To the first half, offset plus 32-bytes - "movl %0,%%edi\n\t" - "addl $32,%%edi\n\t" // Destination 'buf' plus 32 bytes - "movl %1,%%esi\n\t" // Source, 'mid' - "movl %2,%%ecx\n\t" - "subl $8,%%ecx\n\t" // Length, 'half_len_dw' - "rep\n\t" - "movsl\n\t" - - // Move last 8 DWORDS (32-bytes) of the second half to the start of the first half - "movl %0,%%edi\n\t" // Destination 'buf' - // Source, 8 DWORDS from the end of the second half, left over by the last rep/movsl - "movl $8,%%ecx\n\t" // Length, 8 DWORDS (32-bytes) - "rep\n\t" - "movsl\n\t" - - :: "g" (buf), "g" (mid), "g" (half_len_dw) - : "edi", "esi", "ecx" - ); -#endif - } -} - -STATIC void block_move_check(ulong* restrict buf, - ulong len_dw, const void* unused_ctx) { - len_dw = block_move_normalize_len_dw(len_dw); - - /* Now check the data. - * This is rather crude, we just check that the - * adjacent words are the same. - */ -#if PREFER_C - for (ulong i = 0; i < len_dw; i = i + 2) { - if (buf[i] != buf[i+1]) { - mt86_error(buf+i, buf[i], buf[i+1]); - } - } -#else - ulong* pe = buf + (len_dw - 2); - asm __volatile__ - ( - "jmp L120\n\t" - - ".p2align 4,,7\n\t" - "L124:\n\t" - "addl $8,%%edi\n\t" // Next QWORD - "L120:\n\t" - - // Compare adjacent DWORDS - "movl (%%edi),%%ecx\n\t" - "cmpl 4(%%edi),%%ecx\n\t" - "jnz L121\n\t" // Print error if they don't match - - // Loop until end of block - "L122:\n\t" - "cmpl %%edx,%%edi\n\t" - "jb L124\n" - "jmp L123\n\t" - - "L121:\n\t" - // eax not used so we don't need to save it as per cdecl - // ecx is used but not restored, however we don't need it's value anymore after this point - "pushl %%edx\n\t" - "pushl 4(%%edi)\n\t" - "pushl %%ecx\n\t" - "pushl %%edi\n\t" - "call mt86_error\n\t" - "popl %%edi\n\t" - "addl $8,%%esp\n\t" - "popl %%edx\n\t" - "jmp L122\n" - "L123:\n\t" - :: "D" (buf), "d" (pe) - : "ecx" - ); -#endif -} - -/* - * Test memory using block moves - * Adapted from Robert Redelmeier's burnBX test - */ -void block_move(int iter, int me) -{ - cprint(LINE_PAT, COL_PAT-2, " "); - - block_move_ctx ctx; - ctx.iter = iter; - ctx.me = me; - - /* Initialize memory with the initial pattern. */ - sliced_foreach_segment(&ctx, me, block_move_init); - { BAILR } - s_barrier(); - - /* Now move the data around */ - sliced_foreach_segment(&ctx, me, block_move_move); - { BAILR } - s_barrier(); - - /* And check it. */ - sliced_foreach_segment(&ctx, me, block_move_check); -} - -typedef struct { - ulong pat; -} bit_fade_ctx; - -STATIC void bit_fade_fill_seg(ulong* restrict p, - ulong len_dw, const void* vctx) { - const bit_fade_ctx* restrict ctx = (const bit_fade_ctx*)vctx; - ulong pat = ctx->pat; - - for (ulong i = 0; i < len_dw; i++) { - p[i] = pat; - } -} - -/* - * Test memory for bit fade, fill memory with pattern. - */ -void bit_fade_fill(ulong p1, int me) -{ - /* Display the current pattern */ - hprint(LINE_PAT, COL_PAT, p1); - - /* Initialize memory with the initial pattern. */ - bit_fade_ctx ctx; - ctx.pat = p1; - unsliced_foreach_segment(&ctx, me, bit_fade_fill_seg); -} - -STATIC void bit_fade_chk_seg(ulong* restrict p, - ulong len_dw, const void* vctx) { - const bit_fade_ctx* restrict ctx = (const bit_fade_ctx*)vctx; - ulong pat = ctx->pat; - - for (ulong i = 0; i < len_dw; i++) { - ulong bad; - if ((bad=p[i]) != pat) { - mt86_error(p+i, pat, bad); - } - } -} - -void bit_fade_chk(ulong p1, int me) -{ - bit_fade_ctx ctx; - ctx.pat = p1; - - /* Make sure that nothing changed while sleeping */ - unsliced_foreach_segment(&ctx, me, bit_fade_chk_seg); -} - -/* Sleep for N seconds */ -void sleep(long n, int flag, int me, - int sms /* interpret 'n' as milliseconds instead */) -{ - ulong sh, sl, l, h, t, ip=0; - - /* save the starting time */ - asm __volatile__( - "rdtsc":"=a" (sl),"=d" (sh)); - - /* loop for n seconds */ - while (1) { - asm __volatile__( - "rep ; nop\n\t" - "rdtsc":"=a" (l),"=d" (h)); - asm __volatile__ ( - "subl %2,%0\n\t" - "sbbl %3,%1" - :"=a" (l), "=d" (h) - :"g" (sl), "g" (sh), - "0" (l), "1" (h)); - - if (sms != 0) { - t = h * ((unsigned)0xffffffff / vv->clks_msec); - t += (l / vv->clks_msec); - } else { - t = h * ((unsigned)0xffffffff / vv->clks_msec) / 1000; - t += (l / vv->clks_msec) / 1000; - } - - /* Is the time up? */ - if (t >= n) { - break; - } - - /* Only display elapsed time if flag is set */ - if (flag == 0) { - continue; - } - - if (t != ip) { - do_tick(me); - { BAILR } - ip = t; - } - } -} - -void beep(unsigned int frequency) -{ -#if 0 - // BOZO(jcoiner) - // Removed this, we need to define outb_p() and inb_p() - // before reintroducing it. -#else - unsigned int count = 1193180 / frequency; - - // Switch on the speaker - outb_p(inb_p(0x61)|3, 0x61); - - // Set command for counter 2, 2 byte write - outb_p(0xB6, 0x43); - - // Select desired Hz - outb_p(count & 0xff, 0x42); - outb((count >> 8) & 0xff, 0x42); - - // Block for 100 microseconds - sleep(100, 0, 0, 1); - - // Switch off the speaker - outb(inb_p(0x61)&0xFC, 0x61); -#endif -} diff --git a/memtest86+_old/test.h b/memtest86+_old/test.h deleted file mode 100644 index 8b2e924..0000000 --- a/memtest86+_old/test.h +++ /dev/null @@ -1,346 +0,0 @@ -/* test.h - MemTest-86 Version 3.4 - * - * Released under version 2 of the Gnu Public License. - * By Chris Brady - */ - -#ifndef _TEST_H_ -#define _TEST_H_ -#define E88 0x00 -#define E801 0x04 -#define E820NR 0x08 /* # entries in E820MAP */ -#define E820MAP 0x0c /* our map */ -#define E820MAX 127 /* number of entries in E820MAP */ -#define E820ENTRY_SIZE 20 -#define MEMINFO_SIZE (E820MAP + E820MAX * E820ENTRY_SIZE) - -#ifndef __ASSEMBLY__ - -#define E820_RAM 1 -#define E820_RESERVED 2 -#define E820_ACPI 3 /* usable as RAM once ACPI tables have been read */ -#define E820_NVS 4 - -struct e820entry { - unsigned long long addr; /* start of memory segment */ - unsigned long long size; /* size of memory segment */ - unsigned long type; /* type of memory segment */ -}; - -struct mem_info_t { - unsigned long e88_mem_k; /* 0x00 */ - unsigned long e801_mem_k; /* 0x04 */ - unsigned long e820_nr; /* 0x08 */ - struct e820entry e820[E820MAX]; /* 0x0c */ - /* 0x28c */ -}; - -typedef unsigned long ulong; -#define STACKSIZE_BYTES (8*1024) -#define MAX_MEM_PAGES 0x7FF00000 /* 8 TB; units are 4K pages */ -#define WIN_SZ_PAGES 0x80000 /* 2 GB; units are 4K pages */ -#define UNMAP_SZ_PAGES (0x100000-WIN_SZ_PAGES) /* Size of unmapped first segment */ - -#define SPINSZ_DWORDS 0x4000000 /* 256 MB; units are dwords (32-bit words) */ -#define MOD_SZ 20 -#define BAILOUT if (bail) return(1); -#define BAILR if (bail) return; - -#define RES_START 0xa0000 -#define RES_END 0x100000 -#define SCREEN_ADR 0xb8000 -#define SCREEN_END_ADR (SCREEN_ADR + 80*25*2) - -#define DMI_SEARCH_START 0x0000F000 -#define DMI_SEARCH_LENGTH 0x000F0FFF -#define MAX_DMI_MEMDEVS 16 - -#define TITLE_WIDTH 28 -#define LINE_TITLE 0 -#define LINE_TST 3 -#define LINE_RANGE 4 -#define LINE_PAT 5 -#define LINE_TIME 5 -#define LINE_STATUS 8 -#define LINE_INFO 9 -#define LINE_HEADER 12 -#define LINE_SCROLL 14 -#define LINE_SPD 14 -#define LINE_MSG 22 -#define LINE_CPU 7 -#define LINE_RAM 8 -#define LINE_DMI 23 -#define COL_INF1 15 -#define COL_INF2 32 -#define COL_INF3 51 -#define COL_INF4 70 -#define COL_MODE 15 -#define COL_MID 30 -#define COL_PAT 41 -#define BAR_SIZE (78-COL_MID-9) -#define COL_MSG 23 -#define COL_TIME 67 -#define COL_SPEC 41 - -#define POP_W 34 -#define POP_H 15 -#define POP_X 11 -#define POP_Y 8 -#define POP2_W 74 -#define POP2_H 21 -#define POP2_X 3 -#define POP2_Y 2 - -/* CPU mode types */ -#define CPM_ALL 1 -#define CPM_RROBIN 2 -#define CPM_SEQ 3 - -/* memspeed operations */ -#define MS_COPY 1 -#define MS_WRITE 2 -#define MS_READ 3 - -#define SZ_MODE_BIOS 1 -#define SZ_MODE_PROBE 2 - -#define getCx86(reg) ({ outb((reg), 0x22); inb(0x23); }) - -int mt86_memcmp(const void *s1, const void *s2, ulong count); -void *mt86_memmove(void *dest, const void *src, ulong n); -int mt86_strncmp(const char *s1, const char *s2, ulong n); -int mt86_strstr(char *str1, char *str2); -int mt86_strlen(char *string); -int query_linuxbios(void); -int query_pcbios(void); -int insertaddress(ulong); -void printpatn(void); -void printpatn(void); -void itoa(char s[], int n); -void reverse(char *p); -void serial_console_setup(char *param); -void serial_echo_init(void); -void serial_echo_print(const char *s); -void ttyprint(int y, int x, const char *s); -void ttyprintc(int y, int x, char c); -void cprint(int y,int x, const char *s); -void cplace(int y,int x, const char s); -void hprint(int y,int x, ulong val); -void hprint2(int y,int x, ulong val, int len); -void hprint3(int y,int x, ulong val, int len); -void xprint(int y,int x,ulong val); -void aprint(int y,int x,ulong page); -void dprint(int y,int x,ulong val,int len, int right); -void movinv1(int iter, ulong p1, ulong p2, int cpu); -void movinvr(int cpu); -void movinv32(int iter, ulong p1, ulong lb, ulong mb, int sval, int off, - int cpu); -void modtst(int off, int iter, ulong p1, ulong p2, int cpu); -#define ASSERT(n) do { \ - if (!(n)) { \ - assert_fail(__FILE__, __LINE__); \ - } } while(0) -void assert_fail(const char* file, int line_no); -void mt86_error(ulong* adr, ulong good, ulong bad); -void ad_err1(ulong *adr1, ulong *adr2, ulong good, ulong bad); -void ad_err2(ulong *adr, ulong bad); -void do_tick(); -void init(void); -struct eregs; -void inter(struct eregs *trap_regs); -void set_cache(int val); -void check_input(void); -void footer(void); -void scroll(void); -void clear_scroll(void); -void popup(void); -void popdown(void); -void popclear(void); -void pop2up(void); -void pop2down(void); -void pop2clear(void); -void get_config(void); -void get_menu(void); -void get_printmode(void); -void addr_tst1(int cpu); -void addr_tst2(int cpu); -int getnum(ulong val); -void sleep(long sec, int flag, int cpu, int sms); -void block_move(int iter, int cpu); -void find_ticks(void); -void print_err(ulong *adr, ulong good, ulong bad, ulong xor); -void print_ecc_err(ulong page, ulong offset, int corrected, - unsigned short syndrome, int channel); -void mem_size(void); -void adj_mem(void); -ulong getval(int x, int y, int result_shift); -int get_key(void); -int ascii_to_keycode(int in); -void wait_keyup(void); -void print_hdr(void); -void restart(void); -void parity_err(ulong edi, ulong esi); -void start_config(void); -void clear_screen(void); -void paging_off(void); -void show_spd(void); -int map_page(unsigned long page); -void *mapping(unsigned long phys_page); // get VA for a physical page -void *emapping(unsigned long phys_page); -int mt86_isdigit(char c); -ulong memspeed(ulong src, ulong len, int iter); -unsigned long page_of(void *ptr); -ulong correct_tsc(ulong el_org); -void bit_fade_fill(unsigned long n, int cpu); -void bit_fade_chk(unsigned long n, int cpu); -void find_ticks_for_pass(void); -void beep(unsigned int frequency); - -// Expose foreach_segment here for self_test, otherwise -// it would be local to test.c: -typedef void(*segment_fn)(ulong* start, // start address - ulong len_dw, // length of segment in dwords - const void* ctx); // any context data needed -void foreach_segment(ulong* start, ulong* end, - int me, const void* ctx, segment_fn func); - - -// In self-test, DEBUGF wraps libc's printf. -// In memtest standalone, printf will be a stub -// and 'vv->debugging' is false to avoid call overhead. -int printf(const char *format, ...); -#define DEBUGF(...) { \ - if (vv->debugging) { \ - printf(__VA_ARGS__); \ - } \ - } - -#define PRINTMODE_SUMMARY 0 -#define PRINTMODE_ADDRESSES 1 -#define PRINTMODE_PATTERNS 2 -#define PRINTMODE_NONE 3 - -#define BADRAM_MAXPATNS 10 - -struct pair { - ulong adr; - ulong mask; -}; - -static inline void cache_off(void) -{ - asm( - "push %eax\n\t" - "movl %cr0,%eax\n\t" - "orl $0x40000000,%eax\n\t" /* Set CD */ - "movl %eax,%cr0\n\t" - "wbinvd\n\t" - "pop %eax\n\t"); -} - -static inline void cache_on(void) -{ - asm( - "push %eax\n\t" - "movl %cr0,%eax\n\t" - "andl $0x9fffffff,%eax\n\t" /* Clear CD and NW */ - "movl %eax,%cr0\n\t" - "pop %eax\n\t"); -} - -struct mmap { - ulong pbase_addr; - ulong *start; // VA of segment start - ulong *end; // VA of the last dword within the segment. -}; - -struct pmap { - ulong start; /* phys page number of RAM segment start, - in 4K pages. */ - ulong end; // phys page number (past the end? or inclusive?) -}; - -struct tseq { - short sel; // enabled - short cpu_sel; // cpu_sel == 0 indicates end of tseq[] array - short pat; // the test # - short iter; // # of iterations to run - short errors; // error count, updated as tests run - char *msg; -}; - -struct xadr { - ulong page; - ulong offset; -}; - -struct err_info { - struct xadr low_addr; - struct xadr high_addr; - unsigned long ebits; - long tbits; - short min_bits; - short max_bits; - unsigned long maxl; - unsigned long eadr; - unsigned long exor; - unsigned long cor_err; - short hdr_flag; -}; - - - -#define X86_FEATURE_PAE (0*32+ 6) /* Physical Address Extensions */ - -#define MAX_MEM_SEGMENTS E820MAX - -/* Define common variables across relocations of memtest86 */ -struct vars { - int pass; - int msg_line; - int ecount; - int ecc_ecount; - int msegs; // number of entries in pmap[] - int testsel; - int scroll_start; - int pass_ticks; - int total_ticks; - int pptr; - int tptr; - struct err_info erri; - // PA ranges from e820 table: - struct pmap pmap[MAX_MEM_SEGMENTS]; - // VA mappings: - volatile struct mmap map[MAX_MEM_SEGMENTS]; - ulong plim_lower; // phys page number - ulong plim_upper; // phys page number - ulong clks_msec; - ulong starth; - ulong startl; - ulong snaph; - ulong snapl; - int printmode; - int numpatn; - struct pair patn [BADRAM_MAXPATNS]; - ulong test_pages; - ulong selected_pages; - ulong reserved_pages; - int check_temp; - int fail_safe; - int each_sec; - int beepmode; - int debugging; // Set in selftest only -}; - -#define FIRMWARE_UNKNOWN 0 -#define FIRMWARE_PCBIOS 1 -#define FIRMWARE_LINUXBIOS 2 - -extern struct vars * const vv; -extern unsigned char _start[], _end[], startup_32[]; -extern unsigned char _size, _pages; - -extern struct mem_info_t mem_info; - -#endif /* __ASSEMBLY__ */ -#endif /* _TEST_H_ */ diff --git a/memtest86+_old/version.number b/memtest86+_old/version.number deleted file mode 100644 index 6b0b9f8..0000000 --- a/memtest86+_old/version.number +++ /dev/null @@ -1 +0,0 @@ -4.99617 - Thu May 3 11:45:57 CEST 2012 diff --git a/memtest86+_old/vmem.c b/memtest86+_old/vmem.c deleted file mode 100644 index 6125e0d..0000000 --- a/memtest86+_old/vmem.c +++ /dev/null @@ -1,159 +0,0 @@ -/* vmem.c - MemTest-86 - * - * Virtual memory handling (PAE) - * - * Released under version 2 of the Gnu Public License. - * By Chris Brady - */ -#include "stdint.h" -#include "test.h" -#include "cpuid.h" - -extern struct cpu_ident cpu_id; - -static unsigned long mapped_win = 1; -void paging_off(void) -{ - if (!cpu_id.fid.bits.pae) - return; - __asm__ __volatile__ - ( - /* Disable paging */ - "movl %%cr0, %%eax\n\t" - "andl $0x7FFFFFFF, %%eax\n\t" - "movl %%eax, %%cr0\n\t" - : : - : "ax" - ); -} - -static void paging_on(void *pdp) -{ - if (!cpu_id.fid.bits.pae) - return; - __asm__ __volatile__ - ( - /* Load the page table address */ - "movl %0, %%cr3\n\t" - /* Enable paging */ - "movl %%cr0, %%eax\n\t" - "orl $0x80000000, %%eax\n\t" - "movl %%eax, %%cr0\n\t" - : - : "r" (pdp) - : "ax" - ); -} - -static void paging_on_lm(void *pml) -{ - if (!cpu_id.fid.bits.pae) - return; - __asm__ __volatile__ - ( - /* Load the page table address */ - "movl %0, %%cr3\n\t" - /* Enable paging */ - "movl %%cr0, %%eax\n\t" - "orl $0x80000000, %%eax\n\t" - "movl %%eax, %%cr0\n\t" - : - : "r" (pml) - : "ax" - ); -} - -int map_page(unsigned long page) -{ - unsigned long i; - struct pde { - unsigned long addr_lo; - unsigned long addr_hi; - }; - extern unsigned char pdp[]; - extern unsigned char pml4[]; - extern struct pde pd2[]; - unsigned long win = page >> 19; - - /* Less than 2 GB so no mapping is required */ - if (win == 0) { - return 0; - } - if (cpu_id.fid.bits.pae == 0) { - /* Fail, we don't have PAE */ - return -1; - } - if (cpu_id.fid.bits.lm == 0 && (page > 0x1000000)) { - /* Fail, we want an address that is out of bounds (> 64GB) - * for PAE and no long mode (ie. 32 bit CPU). - */ - return -1; - } - /* Compute the page table entries... */ - for(i = 0; i < 1024; i++) { - /*-----------------10/30/2004 12:37PM--------------- - * 0xE3 -- - * Bit 0 = Present bit. 1 = PDE is present - * Bit 1 = Read/Write. 1 = memory is writable - * Bit 2 = Supervisor/User. 0 = Supervisor only (CPL 0-2) - * Bit 3 = Writethrough. 0 = writeback cache policy - * Bit 4 = Cache Disable. 0 = page level cache enabled - * Bit 5 = Accessed. 1 = memory has been accessed. - * Bit 6 = Dirty. 1 = memory has been written to. - * Bit 7 = Page Size. 1 = page size is 2 MBytes - * --------------------------------------------------*/ - pd2[i].addr_lo = ((win & 1) << 31) + ((i & 0x3ff) << 21) + 0xE3; - pd2[i].addr_hi = (win >> 1); - } - paging_off(); - if (cpu_id.fid.bits.lm == 1) { - paging_on_lm(pml4); - } else { - paging_on(pdp); - } - mapped_win = win; - return 0; -} - -void *mapping(unsigned long phys_page) -{ - void *result; - if (phys_page < WIN_SZ_PAGES) { - /* If the page is below 2GB, address it directly */ - result = (void *)(phys_page << 12); - } - else { - // Higher physical pages map to a virtual address - // in the 2G-4G range. - unsigned long alias; - alias = phys_page & 0x7FFFF; - alias += 0x80000; - result = (void *)(alias << 12); - } - return result; -} - -void *emapping(unsigned long phys_page) -{ - void *result; - result = mapping(phys_page - 1); - /* Fill in the low address bits */ - result = ((unsigned char *)result) + 0xffc; - return result; -} - -unsigned long page_of(void *addr) -{ - unsigned long page; - page = ((unsigned long)addr) >> 12; - if (page >= 0x80000) { - page &= 0x7FFFF; - page += mapped_win << 19; - } -#if 0 - cprint(LINE_SCROLL -2, 0, "page_of( )-> "); - hprint(LINE_SCROLL -2, 8, ((unsigned long)addr)); - hprint(LINE_SCROLL -2, 20, page); -#endif - return page; -} diff --git a/memtest_efi_modified.lds b/memtest_efi_modified.lds deleted file mode 100644 index 6f035c8..0000000 --- a/memtest_efi_modified.lds +++ /dev/null @@ -1,75 +0,0 @@ -OUTPUT_FORMAT("elf64-x86-64"); -OUTPUT_ARCH(i386:x86-64); - - -ENTRY(boot); -SECTIONS { - . = 0; - .header : { - *(.header) - } - .setup : { - *(.setup) - } - . = ALIGN(512); - .text : { - _text_start = . ; - _start = .; - *(.text) - *(.text.*) - *(.plt) - _etext = . ; - _text_end = . ; - }= 0x9090 - - .rodata : { - *(.rodata) - *(.rodata.*) - } - .dynsym : { *(.dynsym) } - .dynstr : { *(.dynstr) } - .hash : { *(.hash) } - .gnu.hash : { *(.gnu.hash) } - .dynamic : { *(.dynamic) } - - .rela.text : { *(.rela.text .rela.text.*) } - .rela.rodata : { *(.rela.rodata .rela.rodata.*) } - .rela.data : { *(.rela.data .rela.data.*) } - .rela.got : { *(.rela.got .rela.got.*) } - .rela.plt : { *(.rela.plt .rela.plt.*) } - - . = ALIGN(4); - .data : { - _data = .; - *(.data) - *(.data.*) - } - .got : { - *(.got.plt) - *(.got) - _edata = . ; - } - . = ALIGN(4); - .bss : { - _bss = .; - *(.dynbss) - *(.bss) - *(.bss.*) - *(COMMON) - . = ALIGN(16); - _stacks = .; - *(.stacks) - /* _end must be at least 256 byte aligned */ - . = ALIGN(256); - _end = .; - } - - .debug : { - *(.debug*) - } - - _text_size = (_text_end - _text_start); - - _sys_size = _text_size >> 4; - _init_size = _text_size + _bss_size; -} diff --git a/test_code/OVMF_VARS.fd b/test_code/OVMF_VARS.fd index 6252fc6..4b8f765 100644 Binary files a/test_code/OVMF_VARS.fd and b/test_code/OVMF_VARS.fd differ diff --git a/test_code/memtest_gdbscript b/test_code/memtest_gdbscript index 3295919..94a7f53 100644 --- a/test_code/memtest_gdbscript +++ b/test_code/memtest_gdbscript @@ -1,4 +1,4 @@ -add-symbol-file ../../memtest86plus_debug/build64/memtest.debug 0x20000 +add-symbol-file ../../memtest86plus_debug/build64/memtest.debug 0x201000 b main # while loop @@ -6,3 +6,5 @@ b *0x21414a # supposed main b *0x21412a + +target remote localhost:1234 diff --git a/test_code/test.sh b/test_code/test.sh index 1a72eb7..267a46a 100755 --- a/test_code/test.sh +++ b/test_code/test.sh @@ -6,9 +6,8 @@ sudo qemu-system-x86_64 -s -bios ./OVMF.fd \ -drive if=pflash,format=raw,readonly,file=OVMF_CODE.fd \ -drive if=pflash,format=raw,file=OVMF_VARS.fd \ -net none -debugcon file:debug.log -global isa-debugcon.iobase=0x402 \ - -monitor stdio - -# -D ./qemu_log.txt -# -d ... + -monitor stdio \ + -D ./qemu_log.txt +# -d # --trace "memory_region*" # -S -- cgit v1.2.3-55-g7522