/* * Copyright (C) 2015 Michael Brown . * * This program is free software; you can redistribute it and/or * modify it under the terms of the GNU General Public License as * published by the Free Software Foundation; either version 2 of the * License, or (at your option) any later version. * * This program is distributed in the hope that it will be useful, but * WITHOUT ANY WARRANTY; without even the implied warranty of * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU * General Public License for more details. * * You should have received a copy of the GNU General Public License * along with this program; if not, write to the Free Software * Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, MA * 02110-1301, USA. * * You can also choose to distribute this program under the terms of * the Unmodified Binary Distribution Licence (as given in the file * COPYING.UBDL), provided that you have satisfied its requirements. */ FILE_LICENCE ( GPL2_OR_LATER_OR_UBDL ); #include #include #include #include #include #include /** @file * * EFI entropy source * */ /** Random number generator protocol */ static EFI_RNG_PROTOCOL *efirng; EFI_REQUEST_PROTOCOL ( EFI_RNG_PROTOCOL, &efirng ); /** Minimum number of bytes to request from RNG * * The UEFI spec states (for no apparently good reason) that "When a * Deterministic Random Bit Generator (DRBG) is used on the output of * a (raw) entropy source, its security level must be at least 256 * bits." The EDK2 codebase (mis)interprets this to mean that the * call to GetRNG() should fail if given a buffer less than 32 bytes. * * Incidentally, nothing in the EFI RNG protocol provides any way to * report the actual amount of entropy returned by GetRNG(). */ #define EFI_ENTROPY_RNG_LEN 32 /** Time (in 100ns units) to delay waiting for timer tick * * In theory, UEFI allows us to specify a trigger time of zero to * simply wait for the next timer tick. In practice, specifying zero * seems to often return immediately, which produces almost no * entropy. Specify a delay of 1000ns to try to force an existent * delay. */ #define EFI_ENTROPY_TRIGGER_TIME 10 /** Event used to wait for timer tick */ static EFI_EVENT tick; /** * Enable entropy gathering * * @ret rc Return status code */ static int efi_entropy_enable ( void ) { EFI_BOOT_SERVICES *bs = efi_systab->BootServices; EFI_STATUS efirc; int rc; DBGC ( &tick, "ENTROPY %s RNG protocol\n", ( efirng ? "has" : "has no" ) ); /* Drop to TPL_APPLICATION to allow timer tick event to take place */ bs->RestoreTPL ( TPL_APPLICATION ); /* Create timer tick event */ if ( ( efirc = bs->CreateEvent ( EVT_TIMER, TPL_NOTIFY, NULL, NULL, &tick ) ) != 0 ) { rc = -EEFI ( efirc ); DBGC ( &tick, "ENTROPY could not create event: %s\n", strerror ( rc ) ); return rc; } return 0; } /** * Disable entropy gathering * */ static void efi_entropy_disable ( void ) { EFI_BOOT_SERVICES *bs = efi_systab->BootServices; /* Close timer tick event */ bs->CloseEvent ( tick ); /* Return to TPL_CALLBACK */ bs->RaiseTPL ( TPL_CALLBACK ); } /** * Wait for a timer tick * * @ret low CPU profiling low-order bits, or negative error */ static int efi_entropy_tick ( void ) { EFI_BOOT_SERVICES *bs = efi_systab->BootServices; UINTN index; uint16_t low; EFI_STATUS efirc; int rc; /* Wait for next timer tick */ if ( ( efirc = bs->SetTimer ( tick, TimerRelative, EFI_ENTROPY_TRIGGER_TIME ) ) != 0 ) { rc = -EEFI ( efirc ); DBGC ( &tick, "ENTROPY could not set timer: %s\n", strerror ( rc ) ); return rc; } if ( ( efirc = bs->WaitForEvent ( 1, &tick, &index ) ) != 0 ) { rc = -EEFI ( efirc ); DBGC ( &tick, "ENTROPY could not wait for timer tick: %s\n", strerror ( rc ) ); return rc; } /* Get current CPU profiling timestamp low-order bits */ low = profile_timestamp(); return low; } /** * Get noise sample from timer ticks * * @ret noise Noise sample * @ret rc Return status code */ static int efi_get_noise_ticks ( noise_sample_t *noise ) { int before; int after; int rc; /* Wait for a timer tick */ before = efi_entropy_tick(); if ( before < 0 ) { rc = before; return rc; } /* Wait for another timer tick */ after = efi_entropy_tick(); if ( after < 0 ) { rc = after; return rc; } /* Use TSC delta as noise sample */ *noise = ( after - before ); return 0; } /** * Get noise sample from RNG protocol * * @ret noise Noise sample * @ret rc Return status code */ static int efi_get_noise_rng ( noise_sample_t *noise ) { uint8_t buf[EFI_ENTROPY_RNG_LEN]; EFI_STATUS efirc; int rc; /* Fail if we have no EFI RNG protocol */ if ( ! efirng ) return -ENOTSUP; /* Get the minimum allowed number of random bytes */ if ( ( efirc = efirng->GetRNG ( efirng, NULL, EFI_ENTROPY_RNG_LEN, buf ) ) != 0 ) { rc = -EEFI ( efirc ); DBGC ( &tick, "ENTROPY could not read from RNG: %s\n", strerror ( rc ) ); return rc; } /* Reduce random bytes to a single noise sample. This seems * like overkill, but we have no way of knowing how much * entropy is actually present in the bytes returned by the * RNG protocol. */ *noise = crc32_le ( 0, buf, sizeof ( buf ) ); return 0; } /** * Get noise sample * * @ret noise Noise sample * @ret rc Return status code */ static int efi_get_noise ( noise_sample_t *noise ) { int rc; /* Try RNG first, falling back to timer ticks */ if ( ( ( rc = efi_get_noise_rng ( noise ) ) != 0 ) && ( ( rc = efi_get_noise_ticks ( noise ) ) != 0 ) ) return rc; return 0; } PROVIDE_ENTROPY_INLINE ( efi, min_entropy_per_sample ); PROVIDE_ENTROPY ( efi, entropy_enable, efi_entropy_enable ); PROVIDE_ENTROPY ( efi, entropy_disable, efi_entropy_disable ); PROVIDE_ENTROPY ( efi, get_noise, efi_get_noise );