net/sunrpc/auth_gss/gss_krb5_mech.c


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/*
 *  linux/net/sunrpc/gss_krb5_mech.c
 *
 *  Copyright (c) 2001-2008 The Regents of the University of Michigan.
 *  All rights reserved.
 *
 *  Andy Adamson <andros@umich.edu>
 *  J. Bruce Fields <bfields@umich.edu>
 *
 *  Redistribution and use in source and binary forms, with or without
 *  modification, are permitted provided that the following conditions
 *  are met:
 *
 *  1. Redistributions of source code must retain the above copyright
 *     notice, this list of conditions and the following disclaimer.
 *  2. Redistributions in binary form must reproduce the above copyright
 *     notice, this list of conditions and the following disclaimer in the
 *     documentation and/or other materials provided with the distribution.
 *  3. Neither the name of the University nor the names of its
 *     contributors may be used to endorse or promote products derived
 *     from this software without specific prior written permission.
 *
 *  THIS SOFTWARE IS PROVIDED ``AS IS'' AND ANY EXPRESS OR IMPLIED
 *  WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES OF
 *  MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE
 *  DISCLAIMED. IN NO EVENT SHALL THE REGENTS OR CONTRIBUTORS BE LIABLE
 *  FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR
 *  CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF
 *  SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR
 *  BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF
 *  LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING
 *  NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS
 *  SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
 *
 */

#include <crypto/hash.h>
#include <crypto/skcipher.h>
#include <linux/err.h>
#include <linux/module.h>
#include <linux/init.h>
#include <linux/types.h>
#include <linux/slab.h>
#include <linux/sunrpc/auth.h>
#include <linux/sunrpc/gss_krb5.h>
#include <linux/sunrpc/xdr.h>
#include <linux/sunrpc/gss_krb5_enctypes.h>

#if IS_ENABLED(CONFIG_SUNRPC_DEBUG)
# define RPCDBG_FACILITY	RPCDBG_AUTH
#endif

static struct gss_api_mech gss_kerberos_mech;	/* forward declaration */

static const struct gss_krb5_enctype supported_gss_krb5_enctypes[] = {
	/*
	 * DES (All DES enctypes are mapped to the same gss functionality)
	 */
	{
	  .etype = ENCTYPE_DES_CBC_RAW,
	  .ctype = CKSUMTYPE_RSA_MD5,
	  .name = "des-cbc-crc",
	  .encrypt_name = "cbc(des)",
	  .cksum_name = "md5",
	  .encrypt = krb5_encrypt,
	  .decrypt = krb5_decrypt,
	  .mk_key = NULL,
	  .signalg = SGN_ALG_DES_MAC_MD5,
	  .sealalg = SEAL_ALG_DES,
	  .keybytes = 7,
	  .keylength = 8,
	  .blocksize = 8,
	  .conflen = 8,
	  .cksumlength = 8,
	  .keyed_cksum = 0,
	},
	/*
	 * RC4-HMAC
	 */
	{
	  .etype = ENCTYPE_ARCFOUR_HMAC,
	  .ctype = CKSUMTYPE_HMAC_MD5_ARCFOUR,
	  .name = "rc4-hmac",
	  .encrypt_name = "ecb(arc4)",
	  .cksum_name = "hmac(md5)",
	  .encrypt = krb5_encrypt,
	  .decrypt = krb5_decrypt,
	  .mk_key = NULL,
	  .signalg = SGN_ALG_HMAC_MD5,
	  .sealalg = SEAL_ALG_MICROSOFT_RC4,
	  .keybytes = 16,
	  .keylength = 16,
	  .blocksize = 1,
	  .conflen = 8,
	  .cksumlength = 8,
	  .keyed_cksum = 1,
	},
	/*
	 * 3DES
	 */
	{
	  .etype = ENCTYPE_DES3_CBC_RAW,
	  .ctype = CKSUMTYPE_HMAC_SHA1_DES3,
	  .name = "des3-hmac-sha1",
	  .encrypt_name = "cbc(des3_ede)",
	  .cksum_name = "hmac(sha1)",
	  .encrypt = krb5_encrypt,
	  .decrypt = krb5_decrypt,
	  .mk_key = gss_krb5_des3_make_key,
	  .signalg = SGN_ALG_HMAC_SHA1_DES3_KD,
	  .sealalg = SEAL_ALG_DES3KD,
	  .keybytes = 21,
	  .keylength = 24,
	  .blocksize = 8,
	  .conflen = 8,
	  .cksumlength = 20,
	  .keyed_cksum = 1,
	},
	/*
	 * AES128
	 */
	{
	  .etype = ENCTYPE_AES128_CTS_HMAC_SHA1_96,
	  .ctype = CKSUMTYPE_HMAC_SHA1_96_AES128,
	  .name = "aes128-cts",
	  .encrypt_name = "cts(cbc(aes))",
	  .cksum_name = "hmac(sha1)",
	  .encrypt = krb5_encrypt,
	  .decrypt = krb5_decrypt,
	  .mk_key = gss_krb5_aes_make_key,
	  .encrypt_v2 = gss_krb5_aes_encrypt,
	  .decrypt_v2 = gss_krb5_aes_decrypt,
	  .signalg = -1,
	  .sealalg = -1,
	  .keybytes = 16,
	  .keylength = 16,
	  .blocksize = 16,
	  .conflen = 16,
	  .cksumlength = 12,
	  .keyed_cksum = 1,
	},
	/*
	 * AES256
	 */
	{
	  .etype = ENCTYPE_AES256_CTS_HMAC_SHA1_96,
	  .ctype = CKSUMTYPE_HMAC_SHA1_96_AES256,
	  .name = "aes256-cts",
	  .encrypt_name = "cts(cbc(aes))",
	  .cksum_name = "hmac(sha1)",
	  .encrypt = krb5_encrypt,
	  .decrypt = krb5_decrypt,
	  .mk_key = gss_krb5_aes_make_key,
	  .encrypt_v2 = gss_krb5_aes_encrypt,
	  .decrypt_v2 = gss_krb5_aes_decrypt,
	  .signalg = -1,
	  .sealalg = -1,
	  .keybytes = 32,
	  .keylength = 32,
	  .blocksize = 16,
	  .conflen = 16,
	  .cksumlength = 12,
	  .keyed_cksum = 1,
	},
};

static const int num_supported_enctypes =
	ARRAY_SIZE(supported_gss_krb5_enctypes);

static int
supported_gss_krb5_enctype(int etype)
{
	int i;
	for (i = 0; i < num_supported_enctypes; i++)
		if (supported_gss_krb5_enctypes[i].etype == etype)
			return 1;
	return 0;
}

static const struct gss_krb5_enctype *
get_gss_krb5_enctype(int etype)
{
	int i;
	for (i = 0; i < num_supported_enctypes; i++)
		if (supported_gss_krb5_enctypes[i].etype == etype)
			return &supported_gss_krb5_enctypes[i];
	return NULL;
}

static const void *
simple_get_bytes(const void *p, const void *end, void *res, int len)
{
	const void *q = (const void *)((const char *)p + len);
	if (unlikely(q > end || q < p))
		return ERR_PTR(-EFAULT);
	memcpy(res, p, len);
	return q;
}

static const void *
simple_get_netobj(const void *p, const void *end, struct xdr_netobj *res)
{
	const void *q;
	unsigned int len;

	p = simple_get_bytes(p, end, &len, sizeof(len));
	if (IS_ERR(p))
		return p;
	q = (const void *)((const char *)p + len);
	if (unlikely(q > end || q < p))
		return ERR_PTR(-EFAULT);
	res->data = kmemdup(p, len, GFP_NOFS);
	if (unlikely(res->data == NULL))
		return ERR_PTR(-ENOMEM);
	res->len = len;
	return q;
}

static inline const void *
get_key(const void *p, const void *end,
	struct krb5_ctx *ctx, struct crypto_skcipher **res)
{
	struct xdr_netobj	key;
	int			alg;

	p = simple_get_bytes(p, end, &alg, sizeof(alg));
	if (IS_ERR(p))
		goto out_err;

	switch (alg) {
	case ENCTYPE_DES_CBC_CRC:
	case ENCTYPE_DES_CBC_MD4:
	case ENCTYPE_DES_CBC_MD5:
		/* Map all these key types to ENCTYPE_DES_CBC_RAW */
		alg = ENCTYPE_DES_CBC_RAW;
		break;
	}

	if (!supported_gss_krb5_enctype(alg)) {
		printk(KERN_WARNING "gss_kerberos_mech: unsupported "
			"encryption key algorithm %d\n", alg);
		p = ERR_PTR(-EINVAL);
		goto out_err;
	}
	p = simple_get_netobj(p, end, &key);
	if (IS_ERR(p))
		goto out_err;

	*res = crypto_alloc_skcipher(ctx->gk5e->encrypt_name, 0,
							CRYPTO_ALG_ASYNC);
	if (IS_ERR(*res)) {
		printk(KERN_WARNING "gss_kerberos_mech: unable to initialize "
			"crypto algorithm %s\n", ctx->gk5e->encrypt_name);
		*res = NULL;
		goto out_err_free_key;
	}
	if (crypto_skcipher_setkey(*res, key.data, key.len)) {
		printk(KERN_WARNING "gss_kerberos_mech: error setting key for "
			"crypto algorithm %s\n", ctx->gk5e->encrypt_name);
		goto out_err_free_tfm;
	}

	kfree(key.data);
	return p;

out_err_free_tfm:
	crypto_free_skcipher(*res);
out_err_free_key:
	kfree(key.data);
	p = ERR_PTR(-EINVAL);
out_err:
	return p;
}

static int
gss_import_v1_context(const void *p, const void *end, struct krb5_ctx *ctx)
{
	int tmp;

	p = simple_get_bytes(p, end, &ctx->initiate, sizeof(ctx->initiate));
	if (IS_ERR(p))
		goto out_err;

	/* Old format supports only DES!  Any other enctype uses new format */
	ctx->enctype = ENCTYPE_DES_CBC_RAW;

	ctx->gk5e = get_gss_krb5_enctype(ctx->enctype);
	if (ctx->gk5e == NULL) {
		p = ERR_PTR(-EINVAL);
		goto out_err;
	}

	/* The downcall format was designed before we completely understood
	 * the uses of the context fields; so it includes some stuff we
	 * just give some minimal sanity-checking, and some we ignore
	 * completely (like the next twenty bytes): */
	if (unlikely(p + 20 > end || p + 20 < p)) {
		p = ERR_PTR(-EFAULT);
		goto out_err;
	}
	p += 20;
	p = simple_get_bytes(p, end, &tmp, sizeof(tmp));
	if (IS_ERR(p))
		goto out_err;
	if (tmp != SGN_ALG_DES_MAC_MD5) {
		p = ERR_PTR(-ENOSYS);
		goto out_err;
	}
	p = simple_get_bytes(p, end, &tmp, sizeof(tmp));
	if (IS_ERR(p))
		goto out_err;
	if (tmp != SEAL_ALG_DES) {
		p = ERR_PTR(-ENOSYS);
		goto out_err;
	}
	p = simple_get_bytes(p, end, &ctx->endtime, sizeof(ctx->endtime));
	if (IS_ERR(p))
		goto out_err;
	p = simple_get_bytes(p, end, &ctx->seq_send, sizeof(ctx->seq_send));
	if (IS_ERR(p))
		goto out_err;
	p = simple_get_netobj(p, end, &ctx->mech_used);
	if (IS_ERR(p))
		goto out_err;
	p = get_key(p, end, ctx, &ctx->enc);
	if (IS_ERR(p))
		goto out_err_free_mech;
	p = get_key(p, end, ctx, &ctx->seq);
	if (IS_ERR(p))
		goto out_err_free_key1;
	if (p != end) {
		p = ERR_PTR(-EFAULT);
		goto out_err_free_key2;
	}

	return 0;

out_err_free_key2:
	crypto_free_skcipher(ctx->seq);
out_err_free_key1:
	crypto_free_skcipher(ctx->enc);
out_err_free_mech:
	kfree(ctx->mech_used.data);
out_err:
	return PTR_ERR(p);
}

static struct crypto_skcipher *
context_v2_alloc_cipher(struct krb5_ctx *ctx, const char *cname, u8 *key)
{
	struct crypto_skcipher *cp;

	cp = crypto_alloc_skcipher(cname, 0, CRYPTO_ALG_ASYNC);
	if (IS_ERR(cp)) {
		dprintk("gss_kerberos_mech: unable to initialize "
			"crypto algorithm %s\n", cname);
		return NULL;
	}
	if (crypto_skcipher_setkey(cp, key, ctx->gk5e->keylength)) {
		dprintk("gss_kerberos_mech: error setting key for "
			"crypto algorithm %s\n", cname);
		crypto_free_skcipher(cp);
		return NULL;
	}
	return cp;
}

static inline void
set_cdata(u8 cdata[GSS_KRB5_K5CLENGTH], u32 usage, u8 seed)
{
	cdata[0] = (usage>>24)&0xff;
	cdata[1] = (usage>>16)&0xff;
	cdata[2] = (usage>>8)&0xff;
	cdata[3] = usage&0xff;
	cdata[4] = seed;
}

static int
context_derive_keys_des3(struct krb5_ctx *ctx, gfp_t gfp_mask)
{
	struct xdr_netobj c, keyin, keyout;
	u8 cdata[GSS_KRB5_K5CLENGTH];
	u32 err;

	c.len = GSS_KRB5_K5CLENGTH;
	c.data = cdata;

	keyin.data = ctx->Ksess;
	keyin.len = ctx->gk5e->keylength;
	keyout.len = ctx->gk5e->keylength;

	/* seq uses the raw key */
	ctx->seq = context_v2_alloc_cipher(ctx, ctx->gk5e->encrypt_name,
					   ctx->Ksess);
	if (ctx->seq == NULL)
		goto out_err;

	ctx->enc = context_v2_alloc_cipher(ctx, ctx->gk5e->encrypt_name,
					   ctx->Ksess);
	if (ctx->enc == NULL)
		goto out_free_seq;

	/* derive cksum */
	set_cdata(cdata, KG_USAGE_SIGN, KEY_USAGE_SEED_CHECKSUM);
	keyout.data = ctx->cksum;
	err = krb5_derive_key(ctx->gk5e, &keyin, &keyout, &c, gfp_mask);
	if (err) {
		dprintk("%s: Error %d deriving cksum key\n",
			__func__, err);
		goto out_free_enc;
	}

	return 0;

out_free_enc:
	crypto_free_skcipher(ctx->enc);
out_free_seq:
	crypto_free_skcipher(ctx->seq);
out_err:
	return -EINVAL;
}

/*
 * Note that RC4 depends on deriving keys using the sequence
 * number or the checksum of a token.  Therefore, the final keys
 * cannot be calculated until the token is being constructed!
 */
static int
context_derive_keys_rc4(struct krb5_ctx *ctx)
{
	struct crypto_shash *hmac;
	char sigkeyconstant[] = "signaturekey";
	int slen = strlen(sigkeyconstant) + 1;	/* include null terminator */
	struct shash_desc *desc;
	int err;

	dprintk("RPC:       %s: entered\n", __func__);
	/*
	 * derive cksum (aka Ksign) key
	 */
	hmac = crypto_alloc_shash(ctx->gk5e->cksum_name, 0, 0);
	if (IS_ERR(hmac)) {
		dprintk("%s: error %ld allocating hash '%s'\n",
			__func__, PTR_ERR(hmac), ctx->gk5e->cksum_name);
		err = PTR_ERR(hmac);
		goto out_err;
	}

	err = crypto_shash_setkey(hmac, ctx->Ksess, ctx->gk5e->keylength);
	if (err)
		goto out_err_free_hmac;


	desc = kmalloc(sizeof(*desc), GFP_KERNEL);
	if (!desc) {
		dprintk("%s: failed to allocate hash descriptor for '%s'\n",
			__func__, ctx->gk5e->cksum_name);
		err = -ENOMEM;
		goto out_err_free_hmac;
	}

	desc->tfm = hmac;
	desc->flags = 0;

	err = crypto_shash_digest(desc, sigkeyconstant, slen, ctx->cksum);
	kzfree(desc);
	if (err)
		goto out_err_free_hmac;
	/*
	 * allocate hash, and skciphers for data and seqnum encryption
	 */
	ctx->enc = crypto_alloc_skcipher(ctx->gk5e->encrypt_name, 0,
					 CRYPTO_ALG_ASYNC);
	if (IS_ERR(ctx->enc)) {
		err = PTR_ERR(ctx->enc);
		goto out_err_free_hmac;
	}

	ctx->seq = crypto_alloc_skcipher(ctx->gk5e->encrypt_name, 0,
					 CRYPTO_ALG_ASYNC);
	if (IS_ERR(ctx->seq)) {
		crypto_free_skcipher(ctx->enc);
		err = PTR_ERR(ctx->seq);
		goto out_err_free_hmac;
	}

	dprintk("RPC:       %s: returning success\n", __func__);

	err = 0;

out_err_free_hmac:
	crypto_free_shash(hmac);
out_err:
	dprintk("RPC:       %s: returning %d\n", __func__, err);
	return err;
}

static int
context_derive_keys_new(struct krb5_ctx *ctx, gfp_t gfp_mask)
{
	struct xdr_netobj c, keyin, keyout;
	u8 cdata[GSS_KRB5_K5CLENGTH];
	u32 err;

	c.len = GSS_KRB5_K5CLENGTH;
	c.data = cdata;

	keyin.data = ctx->Ksess;
	keyin.len = ctx->gk5e->keylength;
	keyout.len = ctx->gk5e->keylength;

	/* initiator seal encryption */
	set_cdata(cdata, KG_USAGE_INITIATOR_SEAL, KEY_USAGE_SEED_ENCRYPTION);
	keyout.data = ctx->initiator_seal;
	err = krb5_derive_key(ctx->gk5e, &keyin, &keyout, &c, gfp_mask);
	if (err) {
		dprintk("%s: Error %d deriving initiator_seal key\n",
			__func__, err);
		goto out_err;
	}
	ctx->initiator_enc = context_v2_alloc_cipher(ctx,
						     ctx->gk5e->encrypt_name,
						     ctx->initiator_seal);
	if (ctx->initiator_enc == NULL)
		goto out_err;

	/* acceptor seal encryption */
	set_cdata(cdata, KG_USAGE_ACCEPTOR_SEAL, KEY_USAGE_SEED_ENCRYPTION);
	keyout.data = ctx->acceptor_seal;
	err = krb5_derive_key(ctx->gk5e, &keyin, &keyout, &c, gfp_mask);
	if (err) {
		dprintk("%s: Error %d deriving acceptor_seal key\n",
			__func__, err);
		goto out_free_initiator_enc;
	}
	ctx->acceptor_enc = context_v2_alloc_cipher(ctx,
						    ctx->gk5e->encrypt_name,
						    ctx->acceptor_seal);
	if (ctx->acceptor_enc == NULL)
		goto out_free_initiator_enc;

	/* initiator sign checksum */
	set_cdata(cdata, KG_USAGE_INITIATOR_SIGN, KEY_USAGE_SEED_CHECKSUM);
	keyout.data = ctx->initiator_sign;
	err = krb5_derive_key(ctx->gk5e, &keyin, &keyout, &c, gfp_mask);
	if (err) {
		dprintk("%s: Error %d deriving initiator_sign key\n",
			__func__, err);
		goto out_free_acceptor_enc;
	}

	/* acceptor sign checksum */
	set_cdata(cdata, KG_USAGE_ACCEPTOR_SIGN, KEY_USAGE_SEED_CHECKSUM);
	keyout.data = ctx->acceptor_sign;
	err = krb5_derive_key(ctx->gk5e, &keyin, &keyout, &c, gfp_mask);
	if (err) {
		dprintk("%s: Error %d deriving acceptor_sign key\n",
			__func__, err);
		goto out_free_acceptor_enc;
	}

	/* initiator seal integrity */
	set_cdata(cdata, KG_USAGE_INITIATOR_SEAL, KEY_USAGE_SEED_INTEGRITY);
	keyout.data = ctx->initiator_integ;
	err = krb5_derive_key(ctx->gk5e, &keyin, &keyout, &c, gfp_mask);
	if (err) {
		dprintk("%s: Error %d deriving initiator_integ key\n",
			__func__, err);
		goto out_free_acceptor_enc;
	}

	/* acceptor seal integrity */
	set_cdata(cdata, KG_USAGE_ACCEPTOR_SEAL, KEY_USAGE_SEED_INTEGRITY);
	keyout.data = ctx->acceptor_integ;
	err = krb5_derive_key(ctx->gk5e, &keyin, &keyout, &c, gfp_mask);
	if (err) {
		dprintk("%s: Error %d deriving acceptor_integ key\n",
			__func__, err);
		goto out_free_acceptor_enc;
	}

	switch (ctx->enctype) {
	case ENCTYPE_AES128_CTS_HMAC_SHA1_96:
	case ENCTYPE_AES256_CTS_HMAC_SHA1_96:
		ctx->initiator_enc_aux =
			context_v2_alloc_cipher(ctx, "cbc(aes)",
						ctx->initiator_seal);
		if (ctx->initiator_enc_aux == NULL)
			goto out_free_acceptor_enc;
		ctx->acceptor_enc_aux =
			context_v2_alloc_cipher(ctx, "cbc(aes)",
						ctx->acceptor_seal);
		if (ctx->acceptor_enc_aux == NULL) {
			crypto_free_skcipher(ctx->initiator_enc_aux);
			goto out_free_acceptor_enc;
		}
	}

	return 0;

out_free_acceptor_enc:
	crypto_free_skcipher(ctx->acceptor_enc);
out_free_initiator_enc:
	crypto_free_skcipher(ctx->initiator_enc);
out_err:
	return -EINVAL;
}

static int
gss_import_v2_context(const void *p, const void *end, struct krb5_ctx *ctx,
		gfp_t gfp_mask)
{
	int keylen;

	p = simple_get_bytes(p, end, &ctx->flags, sizeof(ctx->flags));
	if (IS_ERR(p))
		goto out_err;
	ctx->initiate = ctx->flags & KRB5_CTX_FLAG_INITIATOR;

	p = simple_get_bytes(p, end, &ctx->endtime, sizeof(ctx->endtime));
	if (IS_ERR(p))
		goto out_err;
	p = simple_get_bytes(p, end, &ctx->seq_send64, sizeof(ctx->seq_send64));
	if (IS_ERR(p))
		goto out_err;
	/* set seq_send for use by "older" enctypes */
	ctx->seq_send = ctx->seq_send64;
	if (ctx->seq_send64 != ctx->seq_send) {
		dprintk("%s: seq_send64 %lx, seq_send %x overflow?\n", __func__,
			(unsigned long)ctx->seq_send64, ctx->seq_send);
		p = ERR_PTR(-EINVAL);
		goto out_err;
	}
	p = simple_get_bytes(p, end, &ctx->enctype, sizeof(ctx->enctype));
	if (IS_ERR(p))
		goto out_err;
	/* Map ENCTYPE_DES3_CBC_SHA1 to ENCTYPE_DES3_CBC_RAW */
	if (ctx->enctype == ENCTYPE_DES3_CBC_SHA1)
		ctx->enctype = ENCTYPE_DES3_CBC_RAW;
	ctx->gk5e = get_gss_krb5_enctype(ctx->enctype);
	if (ctx->gk5e == NULL) {
		dprintk("gss_kerberos_mech: unsupported krb5 enctype %u\n",
			ctx->enctype);
		p = ERR_PTR(-EINVAL);
		goto out_err;
	}
	keylen = ctx->gk5e->keylength;

	p = simple_get_bytes(p, end, ctx->Ksess, keylen);
	if (IS_ERR(p))
		goto out_err;

	if (p != end) {
		p = ERR_PTR(-EINVAL);
		goto out_err;
	}

	ctx->mech_used.data = kmemdup(gss_kerberos_mech.gm_oid.data,
				      gss_kerberos_mech.gm_oid.len, gfp_mask);
	if (unlikely(ctx->mech_used.data == NULL)) {
		p = ERR_PTR(-ENOMEM);
		goto out_err;
	}
	ctx->mech_used.len = gss_kerberos_mech.gm_oid.len;

	switch (ctx->enctype) {
	case ENCTYPE_DES3_CBC_RAW:
		return context_derive_keys_des3(ctx, gfp_mask);
	case ENCTYPE_ARCFOUR_HMAC:
		return context_derive_keys_rc4(ctx);
	case ENCTYPE_AES128_CTS_HMAC_SHA1_96:
	case ENCTYPE_AES256_CTS_HMAC_SHA1_96:
		return context_derive_keys_new(ctx, gfp_mask);
	default:
		return -EINVAL;
	}

out_err:
	return PTR_ERR(p);
}

static int
gss_import_sec_context_kerberos(const void *p, size_t len,
				struct gss_ctx *ctx_id,
				time_t *endtime,
				gfp_t gfp_mask)
{
	const void *end = (const void *)((const char *)p + len);
	struct  krb5_ctx *ctx;
	int ret;

	ctx = kzalloc(sizeof(*ctx), gfp_mask);
	if (ctx == NULL)
		return -ENOMEM;

	if (len == 85)
		ret = gss_import_v1_context(p, end, ctx);
	else
		ret = gss_import_v2_context(p, end, ctx, gfp_mask);

	if (ret == 0) {
		ctx_id->internal_ctx_id = ctx;
		if (endtime)
			*endtime = ctx->endtime;
	} else
		kfree(ctx);

	dprintk("RPC:       %s: returning %d\n", __func__, ret);
	return ret;
}

static void
gss_delete_sec_context_kerberos(void *internal_ctx) {
	struct krb5_ctx *kctx = internal_ctx;

	crypto_free_skcipher(kctx->seq);
	crypto_free_skcipher(kctx->enc);
	crypto_free_skcipher(kctx->acceptor_enc);
	crypto_free_skcipher(kctx->initiator_enc);
	crypto_free_skcipher(kctx->acceptor_enc_aux);
	crypto_free_skcipher(kctx->initiator_enc_aux);
	kfree(kctx->mech_used.data);
	kfree(kctx);
}

static const struct gss_api_ops gss_kerberos_ops = {
	.gss_import_sec_context	= gss_import_sec_context_kerberos,
	.gss_get_mic		= gss_get_mic_kerberos,
	.gss_verify_mic		= gss_verify_mic_kerberos,
	.gss_wrap		= gss_wrap_kerberos,
	.gss_unwrap		= gss_unwrap_kerberos,
	.gss_delete_sec_context	= gss_delete_sec_context_kerberos,
};

static struct pf_desc gss_kerberos_pfs[] = {
	[0] = {
		.pseudoflavor = RPC_AUTH_GSS_KRB5,
		.qop = GSS_C_QOP_DEFAULT,
		.service = RPC_GSS_SVC_NONE,
		.name = "krb5",
	},
	[1] = {
		.pseudoflavor = RPC_AUTH_GSS_KRB5I,
		.qop = GSS_C_QOP_DEFAULT,
		.service = RPC_GSS_SVC_INTEGRITY,
		.name = "krb5i",
	},
	[2] = {
		.pseudoflavor = RPC_AUTH_GSS_KRB5P,
		.qop = GSS_C_QOP_DEFAULT,
		.service = RPC_GSS_SVC_PRIVACY,
		.name = "krb5p",
	},
};

MODULE_ALIAS("rpc-auth-gss-krb5");
MODULE_ALIAS("rpc-auth-gss-krb5i");
MODULE_ALIAS("rpc-auth-gss-krb5p");
MODULE_ALIAS("rpc-auth-gss-390003");
MODULE_ALIAS("rpc-auth-gss-390004");
MODULE_ALIAS("rpc-auth-gss-390005");
MODULE_ALIAS("rpc-auth-gss-1.2.840.113554.1.2.2");

static struct gss_api_mech gss_kerberos_mech = {
	.gm_name	= "krb5",
	.gm_owner	= THIS_MODULE,
	.gm_oid		= { 9, "\x2a\x86\x48\x86\xf7\x12\x01\x02\x02" },
	.gm_ops		= &gss_kerberos_ops,
	.gm_pf_num	= ARRAY_SIZE(gss_kerberos_pfs),
	.gm_pfs		= gss_kerberos_pfs,
	.gm_upcall_enctypes = KRB5_SUPPORTED_ENCTYPES,
};

static int __init init_kerberos_module(void)
{
	int status;

	status = gss_mech_register(&gss_kerberos_mech);
	if (status)
		printk("Failed to register kerberos gss mechanism!\n");
	return status;
}

static void __exit cleanup_kerberos_module(void)
{
	gss_mech_unregister(&gss_kerberos_mech);
}

MODULE_LICENSE("GPL");
module_init(init_kerberos_module);
module_exit(cleanup_kerberos_module);
/*
   drbd_receiver.c

   This file is part of DRBD by Philipp Reisner and Lars Ellenberg.

   Copyright (C) 2001-2008, LINBIT Information Technologies GmbH.
   Copyright (C) 1999-2008, Philipp Reisner <philipp.reisner@linbit.com>.
   Copyright (C) 2002-2008, Lars Ellenberg <lars.ellenberg@linbit.com>.

   drbd 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, or (at your option)
   any later version.

   drbd 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 drbd; see the file COPYING.  If not, write to
   the Free Software Foundation, 675 Mass Ave, Cambridge, MA 02139, USA.
 */


#include <linux/module.h>

#include <asm/uaccess.h>
#include <net/sock.h>

#include <linux/drbd.h>
#include <linux/fs.h>
#include <linux/file.h>
#include <linux/in.h>
#include <linux/mm.h>
#include <linux/memcontrol.h>
#include <linux/mm_inline.h>
#include <linux/slab.h>
#include <linux/pkt_sched.h>
#define __KERNEL_SYSCALLS__
#include <linux/unistd.h>
#include <linux/vmalloc.h>
#include <linux/random.h>
#include <linux/string.h>
#include <linux/scatterlist.h>
#include "drbd_int.h"
#include "drbd_req.h"

#include "drbd_vli.h"

enum finish_epoch {
	FE_STILL_LIVE,
	FE_DESTROYED,
	FE_RECYCLED,
};

static int drbd_do_handshake(struct drbd_conf *mdev);
static int drbd_do_auth(struct drbd_conf *mdev);

static enum finish_epoch drbd_may_finish_epoch(struct drbd_conf *, struct drbd_epoch *, enum epoch_event);
static int e_end_block(struct drbd_conf *, struct drbd_work *, int);


#define GFP_TRY	(__GFP_HIGHMEM | __GFP_NOWARN)

/*
 * some helper functions to deal with single linked page lists,
 * page->private being our "next" pointer.
 */

/* If at least n pages are linked at head, get n pages off.
 * Otherwise, don't modify head, and return NULL.
 * Locking is the responsibility of the caller.
 */
static struct page *page_chain_del(struct page **head, int n)
{
	struct page *page;
	struct page *tmp;

	BUG_ON(!n);
	BUG_ON(!head);

	page = *head;

	if (!page)
		return NULL;

	while (page) {
		tmp = page_chain_next(page);
		if (--n == 0)
			break; /* found sufficient pages */
		if (tmp == NULL)
			/* insufficient pages, don't use any of them. */
			return NULL;
		page = tmp;
	}

	/* add end of list marker for the returned list */
	set_page_private(page, 0);
	/* actual return value, and adjustment of head */
	page = *head;
	*head = tmp;
	return page;
}

/* may be used outside of locks to find the tail of a (usually short)
 * "private" page chain, before adding it back to a global chain head
 * with page_chain_add() under a spinlock. */
static struct page *page_chain_tail(struct page *page, int *len)
{
	struct page *tmp;
	int i = 1;
	while ((tmp = page_chain_next(page)))
		++i, page = tmp;
	if (len)
		*len = i;
	return page;
}

static int page_chain_free(struct page *page)
{
	struct page *tmp;
	int i = 0;
	page_chain_for_each_safe(page, tmp) {
		put_page(page);
		++i;
	}
	return i;
}

static void page_chain_add(struct page **head,
		struct page *chain_first, struct page *chain_last)
{
#if 1
	struct page *tmp;
	tmp = page_chain_tail(chain_first, NULL);
	BUG_ON(tmp != chain_last);
#endif

	/* add chain to head */
	set_page_private(chain_last, (unsigned long)*head);
	*head = chain_first;
}

static struct page *drbd_pp_first_pages_or_try_alloc(struct drbd_conf *mdev, int number)
{
	struct page *page = NULL;
	struct page *tmp = NULL;
	int i = 0;

	/* Yes, testing drbd_pp_vacant outside the lock is racy.
	 * So what. It saves a spin_lock. */
	if (drbd_pp_vacant >= number) {
		spin_lock(&drbd_pp_lock);
		page = page_chain_del(&drbd_pp_pool, number);
		if (page)
			drbd_pp_vacant -= number;
		spin_unlock(&drbd_pp_lock);
		if (page)
			return page;
	}

	/* GFP_TRY, because we must not cause arbitrary write-out: in a DRBD
	 * "criss-cross" setup, that might cause write-out on some other DRBD,
	 * which in turn might block on the other node at this very place.  */
	for (i = 0; i < number; i++) {
		tmp = alloc_page(GFP_TRY);
		if (!tmp)
			break;
		set_page_private(tmp, (unsigned long)page);
		page = tmp;
	}

	if (i == number)
		return page;

	/* Not enough pages immediately available this time.
	 * No need to jump around here, drbd_pp_alloc will retry this
	 * function "soon". */
	if (page) {
		tmp = page_chain_tail(page, NULL);
		spin_lock(&drbd_pp_lock);
		page_chain_add(&drbd_pp_pool, page, tmp);
		drbd_pp_vacant += i;
		spin_unlock(&drbd_pp_lock);
	}
	return NULL;
}

/* kick lower level device, if we have more than (arbitrary number)
 * reference counts on it, which typically are locally submitted io
 * requests.  don't use unacked_cnt, so we speed up proto A and B, too. */
static void maybe_kick_lo(struct drbd_conf *mdev)
{
	if (atomic_read(&mdev->local_cnt) >= mdev->net_conf->unplug_watermark)
		drbd_kick_lo(mdev);
}

static void reclaim_net_ee(struct drbd_conf *mdev, struct list_head *to_be_freed)
{
	struct drbd_epoch_entry *e;
	struct list_head *le, *tle;

	/* The EEs are always appended to the end of the list. Since
	   they are sent in order over the wire, they have to finish
	   in order. As soon as we see the first not finished we can
	   stop to examine the list... */

	list_for_each_safe(le, tle, &mdev->net_ee) {
		e = list_entry(le, struct drbd_epoch_entry, w.list);
		if (drbd_ee_has_active_page(e))
			break;
		list_move(le, to_be_freed);
	}
}

static void drbd_kick_lo_and_reclaim_net(struct drbd_conf *mdev)
{
	LIST_HEAD(reclaimed);
	struct drbd_epoch_entry *e, *t;

	maybe_kick_lo(mdev);
	spin_lock_irq(&mdev->req_lock);
	reclaim_net_ee(mdev, &reclaimed);
	spin_unlock_irq(&mdev->req_lock);

	list_for_each_entry_safe(e, t, &reclaimed, w.list)
		drbd_free_net_ee(mdev, e);
}

/**
 * drbd_pp_alloc() - Returns @number pages, retries forever (or until signalled)
 * @mdev:	DRBD device.
 * @number:	number of pages requested
 * @retry:	whether to retry, if not enough pages are available right now
 *
 * Tries to allocate number pages, first from our own page pool, then from
 * the kernel, unless this allocation would exceed the max_buffers setting.
 * Possibly retry until DRBD frees sufficient pages somewhere else.
 *
 * Returns a page chain linked via page->private.
 */
static struct page *drbd_pp_alloc(struct drbd_conf *mdev, unsigned number, bool retry)
{
	struct page *page = NULL;
	DEFINE_WAIT(wait);

	/* Yes, we may run up to @number over max_buffers. If we
	 * follow it strictly, the admin will get it wrong anyways. */
	if (atomic_read(&mdev->pp_in_use) < mdev->net_conf->max_buffers)
		page = drbd_pp_first_pages_or_try_alloc(mdev, number);

	while (page == NULL) {
		prepare_to_wait(&drbd_pp_wait, &wait, TASK_INTERRUPTIBLE);

		drbd_kick_lo_and_reclaim_net(mdev);

		if (atomic_read(&mdev->pp_in_use) < mdev->net_conf->max_buffers) {
			page = drbd_pp_first_pages_or_try_alloc(mdev, number);
			if (page)
				break;
		}

		if (!retry)
			break;

		if (signal_pending(current)) {
			dev_warn(DEV, "drbd_pp_alloc interrupted!\n");
			break;
		}

		schedule();
	}
	finish_wait(&drbd_pp_wait, &wait);

	if (page)
		atomic_add(number, &mdev->pp_in_use);
	return page;
}

/* Must not be used from irq, as that may deadlock: see drbd_pp_alloc.
 * Is also used from inside an other spin_lock_irq(&mdev->req_lock);
 * Either links the page chain back to the global pool,
 * or returns all pages to the system. */
static void drbd_pp_free(struct drbd_conf *mdev, struct page *page, int is_net)
{
	atomic_t *a = is_net ? &mdev->pp_in_use_by_net : &mdev->pp_in_use;
	int i;

	if (drbd_pp_vacant > (DRBD_MAX_SEGMENT_SIZE/PAGE_SIZE)*minor_count)
		i = page_chain_free(page);
	else {
		struct page *tmp;
		tmp = page_chain_tail(page, &i);
		spin_lock(&drbd_pp_lock);
		page_chain_add(&drbd_pp_pool, page, tmp);
		drbd_pp_vacant += i;
		spin_unlock(&drbd_pp_lock);
	}
	i = atomic_sub_return(i, a);
	if (i < 0)
		dev_warn(DEV, "ASSERTION FAILED: %s: %d < 0\n",
			is_net ? "pp_in_use_by_net" : "pp_in_use", i);
	wake_up(&drbd_pp_wait);
}

/*
You need to hold the req_lock:
 _drbd_wait_ee_list_empty()

You must not have the req_lock:
 drbd_free_ee()
 drbd_alloc_ee()
 drbd_init_ee()
 drbd_release_ee()
 drbd_ee_fix_bhs()
 drbd_process_done_ee()
 drbd_clear_done_ee()
 drbd_wait_ee_list_empty()
*/

struct drbd_epoch_entry *drbd_alloc_ee(struct drbd_conf *mdev,
				     u64 id,
				     sector_t sector,
				     unsigned int data_size,
				     gfp_t gfp_mask) __must_hold(local)
{
	struct drbd_epoch_entry *e;
	struct page *page;
	unsigned nr_pages = (data_size + PAGE_SIZE -1) >> PAGE_SHIFT;

	if (FAULT_ACTIVE(mdev, DRBD_FAULT_AL_EE))
		return NULL;

	e = mempool_alloc(drbd_ee_mempool, gfp_mask & ~__GFP_HIGHMEM);
	if (!e) {
		if (!(gfp_mask & __GFP_NOWARN))
			dev_err(DEV, "alloc_ee: Allocation of an EE failed\n");
		return NULL;
	}

	page = drbd_pp_alloc(mdev, nr_pages, (gfp_mask & __GFP_WAIT));
	if (!page)
		goto fail;

	INIT_HLIST_NODE(&e->colision);
	e->epoch = NULL;
	e->mdev = mdev;
	e->pages = page;
	atomic_set(&e->pending_bios, 0);
	e->size = data_size;
	e->flags = 0;
	e->sector = sector;
	e->block_id = id;

	return e;

 fail:
	mempool_free(e, drbd_ee_mempool);
	return NULL;
}

void drbd_free_some_ee(struct drbd_conf *mdev, struct drbd_epoch_entry *e, int is_net)
{
	if (e->flags & EE_HAS_DIGEST)
		kfree(e->digest);
	drbd_pp_free(mdev, e->pages, is_net);
	D_ASSERT(atomic_read(&e->pending_bios) == 0);
	D_ASSERT(hlist_unhashed(&e->colision));
	mempool_free(e, drbd_ee_mempool);
}

int drbd_release_ee(struct drbd_conf *mdev, struct list_head *list)
{
	LIST_HEAD(work_list);
	struct drbd_epoch_entry *e, *t;
	int count = 0;
	int is_net = list == &mdev->net_ee;

	spin_lock_irq(&mdev->req_lock);
	list_splice_init(list, &work_list);
	spin_unlock_irq(&mdev->req_lock);

	list_for_each_entry_safe(e, t, &work_list, w.list) {
		drbd_free_some_ee(mdev, e, is_net);
		count++;
	}
	return count;
}


/*
 * This function is called from _asender only_
 * but see also comments in _req_mod(,barrier_acked)
 * and receive_Barrier.
 *
 * Move entries from net_ee to done_ee, if ready.
 * Grab done_ee, call all callbacks, free the entries.
 * The callbacks typically send out ACKs.
 */
static int drbd_process_done_ee(struct drbd_conf *mdev)
{
	LIST_HEAD(work_list);
	LIST_HEAD(reclaimed);
	struct drbd_epoch_entry *e, *t;
	int ok = (mdev->state.conn >= C_WF_REPORT_PARAMS);

	spin_lock_irq(&mdev->req_lock);
	reclaim_net_ee(mdev, &reclaimed);
	list_splice_init(&mdev->done_ee, &work_list);
	spin_unlock_irq(&mdev->req_lock);

	list_for_each_entry_safe(e, t, &reclaimed, w.list)
		drbd_free_net_ee(mdev, e);

	/* possible callbacks here:
	 * e_end_block, and e_end_resync_block, e_send_discard_ack.
	 * all ignore the last argument.
	 */
	list_for_each_entry_safe(e, t, &work_list, w.list) {
		/* list_del not necessary, next/prev members not touched */
		ok = e->w.cb(mdev, &e->w, !ok) && ok;
		drbd_free_ee(mdev, e);
	}
	wake_up(&mdev->ee_wait);

	return ok;
}

void _drbd_wait_ee_list_empty(struct drbd_conf *mdev, struct list_head *head)
{
	DEFINE_WAIT(wait);

	/* avoids spin_lock/unlock
	 * and calling prepare_to_wait in the fast path */
	while (!list_empty(head)) {
		prepare_to_wait(&mdev->ee_wait, &wait, TASK_UNINTERRUPTIBLE);
		spin_unlock_irq(&mdev->req_lock);
		drbd_kick_lo(mdev);
		schedule();
		finish_wait(&mdev->ee_wait, &wait);
		spin_lock_irq(&mdev->req_lock);
	}
}

void drbd_wait_ee_list_empty(struct drbd_conf *mdev, struct list_head *head)
{
	spin_lock_irq(&mdev->req_lock);
	_drbd_wait_ee_list_empty(mdev, head);
	spin_unlock_irq(&mdev->req_lock);
}

/* see also kernel_accept; which is only present since 2.6.18.
 * also we want to log which part of it failed, exactly */
static int drbd_accept(struct drbd_conf *mdev, const char **what,
		struct socket *sock, struct socket **newsock)
{
	struct sock *sk = sock->sk;
	int err = 0;

	*what = "listen";
	err = sock->ops->listen(sock, 5);
	if (err < 0)
		goto out;

	*what = "sock_create_lite";
	err = sock_create_lite(sk->sk_family, sk->sk_type, sk->sk_protocol,
			       newsock);
	if (err < 0)
		goto out;

	*what = "accept";
	err = sock->ops->accept(sock, *newsock, 0);
	if (err < 0) {
		sock_release(*newsock);
		*newsock = NULL;
		goto out;
	}
	(*newsock)->ops  = sock->ops;

out:
	return err;
}

static int drbd_recv_short(struct drbd_conf *mdev, struct socket *sock,
		    void *buf, size_t size, int flags)
{
	mm_segment_t oldfs;
	struct kvec iov = {
		.iov_base = buf,
		.iov_len = size,
	};
	struct msghdr msg = {
		.msg_iovlen = 1,
		.msg_iov = (struct iovec *)&iov,
		.msg_flags = (flags ? flags : MSG_WAITALL | MSG_NOSIGNAL)
	};
	int rv;

	oldfs = get_fs();
	set_fs(KERNEL_DS);
	rv = sock_recvmsg(sock, &msg, size, msg.msg_flags);
	set_fs(oldfs);

	return rv;
}

static int drbd_recv(struct drbd_conf *mdev, void *buf, size_t size)
{
	mm_segment_t oldfs;
	struct kvec iov = {
		.iov_base = buf,
		.iov_len = size,
	};
	struct msghdr msg = {
		.msg_iovlen = 1,
		.msg_iov = (struct iovec *)&iov,
		.msg_flags = MSG_WAITALL | MSG_NOSIGNAL
	};
	int rv;

	oldfs = get_fs();
	set_fs(KERNEL_DS);

	for (;;) {
		rv = sock_recvmsg(mdev->data.socket, &msg, size, msg.msg_flags);
		if (rv == size)
			break;

		/* Note:
		 * ECONNRESET	other side closed the connection
		 * ERESTARTSYS	(on  sock) we got a signal
		 */

		if (rv < 0) {
			if (rv == -ECONNRESET)
				dev_info(DEV, "sock was reset by peer\n");
			else if (rv != -ERESTARTSYS)
				dev_err(DEV, "sock_recvmsg returned %d\n", rv);
			break;
		} else if (rv == 0) {
			dev_info(DEV, "sock was shut down by peer\n");
			break;
		} else	{
			/* signal came in, or peer/link went down,
			 * after we read a partial message
			 */
			/* D_ASSERT(signal_pending(current)); */
			break;
		}
	};

	set_fs(oldfs);

	if (rv != size)
		drbd_force_state(mdev, NS(conn, C_BROKEN_PIPE));

	return rv;
}

/* quoting tcp(7):
 *   On individual connections, the socket buffer size must be set prior to the
 *   listen(2) or connect(2) calls in order to have it take effect.
 * This is our wrapper to do so.
 */
static void drbd_setbufsize(struct socket *sock, unsigned int snd,
		unsigned int rcv)
{
	/* open coded SO_SNDBUF, SO_RCVBUF */
	if (snd) {
		sock->sk->sk_sndbuf = snd;
		sock->sk->sk_userlocks |= SOCK_SNDBUF_LOCK;
	}
	if (rcv) {
		sock->sk->sk_rcvbuf = rcv;
		sock->sk->sk_userlocks |= SOCK_RCVBUF_LOCK;
	}
}

static struct socket *drbd_try_connect(struct drbd_conf *mdev)
{
	const char *what;
	struct socket *sock;
	struct sockaddr_in6 src_in6;
	int err;
	int disconnect_on_error = 1;

	if (!get_net_conf(mdev))
		return NULL;

	what = "sock_create_kern";
	err = sock_create_kern(((struct sockaddr *)mdev->net_conf->my_addr)->sa_family,
		SOCK_STREAM, IPPROTO_TCP, &sock);
	if (err < 0) {
		sock = NULL;
		goto out;
	}

	sock->sk->sk_rcvtimeo =
	sock->sk->sk_sndtimeo =  mdev->net_conf->try_connect_int*HZ;
	drbd_setbufsize(sock, mdev->net_conf->sndbuf_size,
			mdev->net_conf->rcvbuf_size);

       /* explicitly bind to the configured IP as source IP
	*  for the outgoing connections.
	*  This is needed for multihomed hosts and to be
	*  able to use lo: interfaces for drbd.
	* Make sure to use 0 as port number, so linux selects
	*  a free one dynamically.
	*/
	memcpy(&src_in6, mdev->net_conf->my_addr,
	       min_t(int, mdev->net_conf->my_addr_len, sizeof(src_in6)));
	if (((struct sockaddr *)mdev->net_conf->my_addr)->sa_family == AF_INET6)
		src_in6.sin6_port = 0;
	else
		((struct sockaddr_in *)&src_in6)->sin_port = 0; /* AF_INET & AF_SCI */

	what = "bind before connect";
	err = sock->ops->bind(sock,
			      (struct sockaddr *) &src_in6,
			      mdev->net_conf->my_addr_len);
	if (err < 0)
		goto out;

	/* connect may fail, peer not yet available.
	 * stay C_WF_CONNECTION, don't go Disconnecting! */
	disconnect_on_error = 0;
	what = "connect";
	err = sock->ops->connect(sock,
				 (struct sockaddr *)mdev->net_conf->peer_addr,
				 mdev->net_conf->peer_addr_len, 0);

out:
	if (err < 0) {
		if (sock) {
			sock_release(sock);
			sock = NULL;
		}
		switch (-err) {
			/* timeout, busy, signal pending */
		case ETIMEDOUT: case EAGAIN: case EINPROGRESS:
		case EINTR: case ERESTARTSYS:
			/* peer not (yet) available, network problem */
		case ECONNREFUSED: case ENETUNREACH:
		case EHOSTDOWN:    case EHOSTUNREACH:
			disconnect_on_error = 0;
			break;
		default:
			dev_err(DEV, "%s failed, err = %d\n", what, err);
		}
		if (disconnect_on_error)
			drbd_force_state(mdev, NS(conn, C_DISCONNECTING));
	}
	put_net_conf(mdev);
	return sock;
}

static struct socket *drbd_wait_for_connect(struct drbd_conf *mdev)
{
	int timeo, err;
	struct socket *s_estab = NULL, *s_listen;
	const char *what;

	if (!get_net_conf(mdev))
		return NULL;

	what = "sock_create_kern";
	err = sock_create_kern(((struct sockaddr *)mdev->net_conf->my_addr)->sa_family,
		SOCK_STREAM, IPPROTO_TCP, &s_listen);
	if (err) {
		s_listen = NULL;
		goto out;
	}

	timeo = mdev->net_conf->try_connect_int * HZ;
	timeo += (random32() & 1) ? timeo / 7 : -timeo / 7; /* 28.5% random jitter */

	s_listen->sk->sk_reuse    = 1; /* SO_REUSEADDR */
	s_listen->sk->sk_rcvtimeo = timeo;
	s_listen->sk->sk_sndtimeo = timeo;
	drbd_setbufsize(s_listen, mdev->net_conf->sndbuf_size,
			mdev->net_conf->rcvbuf_size);

	what = "bind before listen";
	err = s_listen->ops->bind(s_listen,
			      (struct sockaddr *) mdev->net_conf->my_addr,
			      mdev->net_conf->my_addr_len);
	if (err < 0)
		goto out;

	err = drbd_accept(mdev, &what, s_listen, &s_estab);

out:
	if (s_listen)
		sock_release(s_listen);
	if (err < 0) {
		if (err != -EAGAIN && err != -EINTR && err != -ERESTARTSYS) {
			dev_err(DEV, "%s failed, err = %d\n", what, err);
			drbd_force_state(mdev, NS(conn, C_DISCONNECTING));
		}
	}
	put_net_conf(mdev);

	return s_estab;
}

static int drbd_send_fp(struct drbd_conf *mdev,
	struct socket *sock, enum drbd_packets cmd)
{
	struct p_header80 *h = &mdev->data.sbuf.header.h80;

	return _drbd_send_cmd(mdev, sock, cmd, h, sizeof(*h), 0);
}

static enum drbd_packets drbd_recv_fp(struct drbd_conf *mdev, struct socket *sock)
{
	struct p_header80 *h = &mdev->data.rbuf.header.h80;
	int rr;

	rr = drbd_recv_short(mdev, sock, h, sizeof(*h), 0);

	if (rr == sizeof(*h) && h->magic == BE_DRBD_MAGIC)
		return be16_to_cpu(h->command);

	return 0xffff;
}

/**
 * drbd_socket_okay() - Free the socket if its connection is not okay
 * @mdev:	DRBD device.
 * @sock:	pointer to the pointer to the socket.
 */
static int drbd_socket_okay(struct drbd_conf *mdev, struct socket **sock)
{
	int rr;
	char tb[4];

	if (!*sock)
		return FALSE;

	rr = drbd_recv_short(mdev, *sock, tb, 4, MSG_DONTWAIT | MSG_PEEK);

	if (rr > 0 || rr == -EAGAIN) {
		return TRUE;
	} else {
		sock_release(*sock);
		*sock = NULL;
		return FALSE;
	}
}

/*
 * return values:
 *   1 yes, we have a valid connection
 *   0 oops, did not work out, please try again
 *  -1 peer talks different language,
 *     no point in trying again, please go standalone.
 *  -2 We do not have a network config...
 */
static int drbd_connect(struct drbd_conf *mdev)
{
	struct socket *s, *sock, *msock;
	int try, h, ok;

	D_ASSERT(!mdev->data.socket);

	if (drbd_request_state(mdev, NS(conn, C_WF_CONNECTION)) < SS_SUCCESS)
		return -2;

	clear_bit(DISCARD_CONCURRENT, &mdev->flags);

	sock  = NULL;
	msock = NULL;

	do {
		for (try = 0;;) {
			/* 3 tries, this should take less than a second! */
			s = drbd_try_connect(mdev);
			if (s || ++try >= 3)
				break;
			/* give the other side time to call bind() & listen() */
			__set_current_state(TASK_INTERRUPTIBLE);
			schedule_timeout(HZ / 10);
		}

		if (s) {
			if (!sock) {
				drbd_send_fp(mdev, s, P_HAND_SHAKE_S);
				sock = s;
				s = NULL;
			} else if (!msock) {
				drbd_send_fp(mdev, s, P_HAND_SHAKE_M);
				msock = s;
				s = NULL;
			} else {
				dev_err(DEV, "Logic error in drbd_connect()\n");
				goto out_release_sockets;
			}
		}

		if (sock && msock) {
			__set_current_state(TASK_INTERRUPTIBLE);
			schedule_timeout(HZ / 10);
			ok = drbd_socket_okay(mdev, &sock);
			ok = drbd_socket_okay(mdev, &msock) && ok;
			if (ok)
				break;
		}

retry:
		s = drbd_wait_for_connect(mdev);
		if (s) {
			try = drbd_recv_fp(mdev, s);
			drbd_socket_okay(mdev, &sock);
			drbd_socket_okay(mdev, &msock);
			switch (try) {
			case P_HAND_SHAKE_S:
				if (sock) {
					dev_warn(DEV, "initial packet S crossed\n");
					sock_release(sock);
				}
				sock = s;
				break;
			case P_HAND_SHAKE_M:
				if (msock) {
					dev_warn(DEV, "initial packet M crossed\n");
					sock_release(msock);
				}
				msock = s;
				set_bit(DISCARD_CONCURRENT, &mdev->flags);
				break;
			default:
				dev_warn(DEV, "Error receiving initial packet\n");
				sock_release(s);
				if (random32() & 1)
					goto retry;
			}
		}

		if (mdev->state.conn <= C_DISCONNECTING)
			goto out_release_sockets;
		if (signal_pending(current)) {
			flush_signals(current);
			smp_rmb();
			if (get_t_state(&mdev->receiver) == Exiting)
				goto out_release_sockets;
		}

		if (sock && msock) {
			ok = drbd_socket_okay(mdev, &sock);
			ok = drbd_socket_okay(mdev, &msock) && ok;
			if (ok)
				break;
		}
	} while (1);

	msock->sk->sk_reuse = 1; /* SO_REUSEADDR */
	sock->sk->sk_reuse = 1; /* SO_REUSEADDR */

	sock->sk->sk_allocation = GFP_NOIO;
	msock->sk->sk_allocation = GFP_NOIO;

	sock->sk->sk_priority = TC_PRIO_INTERACTIVE_BULK;
	msock->sk->sk_priority = TC_PRIO_INTERACTIVE;

	/* NOT YET ...
	 * sock->sk->sk_sndtimeo = mdev->net_conf->timeout*HZ/10;
	 * sock->sk->sk_rcvtimeo = MAX_SCHEDULE_TIMEOUT;
	 * first set it to the P_HAND_SHAKE timeout,
	 * which we set to 4x the configured ping_timeout. */
	sock->sk->sk_sndtimeo =
	sock->sk->sk_rcvtimeo = mdev->net_conf->ping_timeo*4*HZ/10;

	msock->sk->sk_sndtimeo = mdev->net_conf->timeout*HZ/10;
	msock->sk->sk_rcvtimeo = mdev->net_conf->ping_int*HZ;

	/* we don't want delays.
	 * we use TCP_CORK where apropriate, though */
	drbd_tcp_nodelay(sock);
	drbd_tcp_nodelay(msock);

	mdev->data.socket = sock;
	mdev->meta.socket = msock;
	mdev->last_received = jiffies;

	D_ASSERT(mdev->asender.task == NULL);

	h = drbd_do_handshake(mdev);
	if (h <= 0)
		return h;

	if (mdev->cram_hmac_tfm) {
		/* drbd_request_state(mdev, NS(conn, WFAuth)); */
		switch (drbd_do_auth(mdev)) {
		case -1:
			dev_err(DEV, "Authentication of peer failed\n");
			return -1;
		case 0:
			dev_err(DEV, "Authentication of peer failed, trying again.\n");
			return 0;
		}
	}

	if (drbd_request_state(mdev, NS(conn, C_WF_REPORT_PARAMS)) < SS_SUCCESS)
		return 0;

	sock->sk->sk_sndtimeo = mdev->net_conf->timeout*HZ/10;
	sock->sk->sk_rcvtimeo = MAX_SCHEDULE_TIMEOUT;

	atomic_set(&mdev->packet_seq, 0);
	mdev->peer_seq = 0;

	drbd_thread_start(&mdev->asender);

	if (mdev->agreed_pro_version < 95 && get_ldev(mdev)) {
		drbd_setup_queue_param(mdev, DRBD_MAX_SIZE_H80_PACKET);
		put_ldev(mdev);
	}

	if (!drbd_send_protocol(mdev))
		return -1;
	drbd_send_sync_param(mdev, &mdev->sync_conf);
	drbd_send_sizes(mdev, 0, 0);
	drbd_send_uuids(mdev);
	drbd_send_state(mdev);
	clear_bit(USE_DEGR_WFC_T, &mdev->flags);
	clear_bit(RESIZE_PENDING, &mdev->flags);

	return 1;

out_release_sockets:
	if (sock)
		sock_release(sock);
	if (msock)
		sock_release(msock);
	return -1;
}

static int drbd_recv_header(struct drbd_conf *mdev, enum drbd_packets *cmd, unsigned int *packet_size)
{
	union p_header *h = &mdev->data.rbuf.header;
	int r;

	r = drbd_recv(mdev, h, sizeof(*h));
	if (unlikely(r != sizeof(*h))) {
		dev_err(DEV, "short read expecting header on sock: r=%d\n", r);
		return FALSE;
	}

	if (likely(h->h80.magic == BE_DRBD_MAGIC)) {
		*cmd = be16_to_cpu(h->h80.command);
		*packet_size = be16_to_cpu(h->h80.length);
	} else if (h->h95.magic == BE_DRBD_MAGIC_BIG) {
		*cmd = be16_to_cpu(h->h95.command);
		*packet_size = be32_to_cpu(h->h95.length);
	} else {
		dev_err(DEV, "magic?? on data m: 0x%08x c: %d l: %d\n",
		    be32_to_cpu(h->h80.magic),
		    be16_to_cpu(h->h80.command),
		    be16_to_cpu(h->h80.length));
		return FALSE;
	}
	mdev->last_received = jiffies;

	return TRUE;
}

static void drbd_flush(struct drbd_conf *mdev)
{
	int rv;

	if (mdev->write_ordering >= WO_bdev_flush && get_ldev(mdev)) {
		rv = blkdev_issue_flush(mdev->ldev->backing_bdev, GFP_KERNEL,
					NULL);
		if (rv) {
			dev_err(DEV, "local disk flush failed with status %d\n", rv);
			/* would rather check on EOPNOTSUPP, but that is not reliable.
			 * don't try again for ANY return value != 0
			 * if (rv == -EOPNOTSUPP) */
			drbd_bump_write_ordering(mdev, WO_drain_io);
		}
		put_ldev(mdev);
	}
}

/**
 * drbd_may_finish_epoch() - Applies an epoch_event to the epoch's state, eventually finishes it.
 * @mdev:	DRBD device.
 * @epoch:	Epoch object.
 * @ev:		Epoch event.
 */
static enum finish_epoch drbd_may_finish_epoch(struct drbd_conf *mdev,
					       struct drbd_epoch *epoch,
					       enum epoch_event ev)
{
	int epoch_size;
	struct drbd_epoch *next_epoch;
	enum finish_epoch rv = FE_STILL_LIVE;

	spin_lock(&mdev->epoch_lock);
	do {
		next_epoch = NULL;

		epoch_size = atomic_read(&epoch->epoch_size);

		switch (ev & ~EV_CLEANUP) {
		case EV_PUT:
			atomic_dec(&epoch->active);
			break;
		case EV_GOT_BARRIER_NR:
			set_bit(DE_HAVE_BARRIER_NUMBER, &epoch->flags);
			break;
		case EV_BECAME_LAST:
			/* nothing to do*/
			break;
		}

		if (epoch_size != 0 &&
		    atomic_read(&epoch->active) == 0 &&
		    test_bit(DE_HAVE_BARRIER_NUMBER, &epoch->flags)) {
			if (!(ev & EV_CLEANUP)) {
				spin_unlock(&mdev->epoch_lock);
				drbd_send_b_ack(mdev, epoch->barrier_nr, epoch_size);
				spin_lock(&mdev->epoch_lock);
			}
			dec_unacked(mdev);

			if (mdev->current_epoch != epoch) {
				next_epoch = list_entry(epoch->list.next, struct drbd_epoch, list);
				list_del(&epoch->list);
				ev = EV_BECAME_LAST | (ev & EV_CLEANUP);
				mdev->epochs--;
				kfree(epoch);

				if (rv == FE_STILL_LIVE)
					rv = FE_DESTROYED;
			} else {
				epoch->flags = 0;
				atomic_set(&epoch->epoch_size, 0);
				/* atomic_set(&epoch->active, 0); is already zero */
				if (rv == FE_STILL_LIVE)
					rv = FE_RECYCLED;
				wake_up(&mdev->ee_wait);
			}
		}

		if (!next_epoch)
			break;

		epoch = next_epoch;
	} while (1);

	spin_unlock(&mdev->epoch_lock);

	return rv;
}

/**
 * drbd_bump_write_ordering() - Fall back to an other write ordering method
 * @mdev:	DRBD device.
 * @wo:		Write ordering method to try.
 */
void drbd_bump_write_ordering(struct drbd_conf *mdev, enum write_ordering_e wo) __must_hold(local)
{
	enum write_ordering_e pwo;
	static char *write_ordering_str[] = {
		[WO_none] = "none",
		[WO_drain_io] = "drain",
		[WO_bdev_flush] = "flush",
	};

	pwo = mdev->write_ordering;
	wo = min(pwo, wo);
	if (wo == WO_bdev_flush && mdev->ldev->dc.no_disk_flush)
		wo = WO_drain_io;
	if (wo == WO_drain_io && mdev->ldev->dc.no_disk_drain)
		wo = WO_none;
	mdev->write_ordering = wo;
	if (pwo != mdev->write_ordering || wo == WO_bdev_flush)
		dev_info(DEV, "Method to ensure write ordering: %s\n", write_ordering_str[mdev->write_ordering]);
}

/**
 * drbd_submit_ee()
 * @mdev:	DRBD device.
 * @e:		epoch entry
 * @rw:		flag field, see bio->bi_rw
 */
/* TODO allocate from our own bio_set. */
int drbd_submit_ee(struct drbd_conf *mdev, struct drbd_epoch_entry *e,
		const unsigned rw, const int fault_type)
{
	struct bio *bios = NULL;
	struct bio *bio;
	struct page *page = e->pages;
	sector_t sector = e->sector;
	unsigned ds = e->size;
	unsigned n_bios = 0;
	unsigned nr_pages = (ds + PAGE_SIZE -1) >> PAGE_SHIFT;

	/* In most cases, we will only need one bio.  But in case the lower
	 * level restrictions happen to be different at this offset on this
	 * side than those of the sending peer, we may need to submit the
	 * request in more than one bio. */
next_bio:
	bio = bio_alloc(GFP_NOIO, nr_pages);
	if (!bio) {
		dev_err(DEV, "submit_ee: Allocation of a bio failed\n");
		goto fail;
	}
	/* > e->sector, unless this is the first bio */
	bio->bi_sector = sector;
	bio->bi_bdev = mdev->ldev->backing_bdev;
	/* we special case some flags in the multi-bio case, see below
	 * (REQ_UNPLUG) */
	bio->bi_rw = rw;
	bio->bi_private = e;
	bio->bi_end_io = drbd_endio_sec;

	bio->bi_next = bios;
	bios = bio;
	++n_bios;

	page_chain_for_each(page) {
		unsigned len = min_t(unsigned, ds, PAGE_SIZE);
		if (!bio_add_page(bio, page, len, 0)) {
			/* a single page must always be possible! */
			BUG_ON(bio->bi_vcnt == 0);
			goto next_bio;
		}
		ds -= len;
		sector += len >> 9;
		--nr_pages;
	}
	D_ASSERT(page == NULL);
	D_ASSERT(ds == 0);

	atomic_set(&e->pending_bios, n_bios);
	do {
		bio = bios;
		bios = bios->bi_next;
		bio->bi_next = NULL;

		/* strip off REQ_UNPLUG unless it is the last bio */
		if (bios)
			bio->bi_rw &= ~REQ_UNPLUG;

		drbd_generic_make_request(mdev, fault_type, bio);
	} while (bios);
	maybe_kick_lo(mdev);
	return 0;

fail:
	while (bios) {
		bio = bios;
		bios = bios->bi_next;
		bio_put(bio);
	}
	return -ENOMEM;
}

static int receive_Barrier(struct drbd_conf *mdev, enum drbd_packets cmd, unsigned int data_size)
{
	int rv;
	struct p_barrier *p = &mdev->data.rbuf.barrier;
	struct drbd_epoch *epoch;

	inc_unacked(mdev);

	if (mdev->net_conf->wire_protocol != DRBD_PROT_C)
		drbd_kick_lo(mdev);

	mdev->current_epoch->barrier_nr = p->barrier;
	rv = drbd_may_finish_epoch(mdev, mdev->current_epoch, EV_GOT_BARRIER_NR);

	/* P_BARRIER_ACK may imply that the corresponding extent is dropped from
	 * the activity log, which means it would not be resynced in case the
	 * R_PRIMARY crashes now.
	 * Therefore we must send the barrier_ack after the barrier request was
	 * completed. */
	switch (mdev->write_ordering) {
	case WO_none:
		if (rv == FE_RECYCLED)
			return TRUE;

		/* receiver context, in the writeout path of the other node.
		 * avoid potential distributed deadlock */
		epoch = kmalloc(sizeof(struct drbd_epoch), GFP_NOIO);
		if (epoch)
			break;
		else
			dev_warn(DEV, "Allocation of an epoch failed, slowing down\n");
			/* Fall through */

	case WO_bdev_flush:
	case WO_drain_io:
		drbd_wait_ee_list_empty(mdev, &mdev->active_ee);
		drbd_flush(mdev);

		if (atomic_read(&mdev->current_epoch->epoch_size)) {
			epoch = kmalloc(sizeof(struct drbd_epoch), GFP_NOIO);
			if (epoch)
				break;
		}

		epoch = mdev->current_epoch;
		wait_event(mdev->ee_wait, atomic_read(&epoch->epoch_size) == 0);

		D_ASSERT(atomic_read(&epoch->active) == 0);
		D_ASSERT(epoch->flags == 0);

		return TRUE;
	default:
		dev_err(DEV, "Strangeness in mdev->write_ordering %d\n", mdev->write_ordering);
		return FALSE;
	}

	epoch->flags = 0;
	atomic_set(&epoch->epoch_size, 0);
	atomic_set(&epoch->active, 0);

	spin_lock(&mdev->epoch_lock);
	if (atomic_read(&mdev->current_epoch->epoch_size)) {
		list_add(&epoch->list, &mdev->current_epoch->list);
		mdev->current_epoch = epoch;
		mdev->epochs++;
	} else {
		/* The current_epoch got recycled while we allocated this one... */
		kfree(epoch);
	}
	spin_unlock(&mdev->epoch_lock);

	return TRUE;
}

/* used from receive_RSDataReply (recv_resync_read)
 * and from receive_Data */
static struct drbd_epoch_entry *
read_in_block(struct drbd_conf *mdev, u64 id, sector_t sector, int data_size) __must_hold(local)
{
	const sector_t capacity = drbd_get_capacity(mdev->this_bdev);
	struct drbd_epoch_entry *e;
	struct page *page;
	int dgs, ds, rr;
	void *dig_in = mdev->int_dig_in;
	void *dig_vv = mdev->int_dig_vv;
	unsigned long *data;

	dgs = (mdev->agreed_pro_version >= 87 && mdev->integrity_r_tfm) ?
		crypto_hash_digestsize(mdev->integrity_r_tfm) : 0;

	if (dgs) {
		rr = drbd_recv(mdev, dig_in, dgs);
		if (rr != dgs) {
			dev_warn(DEV, "short read receiving data digest: read %d expected %d\n",
			     rr, dgs);
			return NULL;
		}
	}

	data_size -= dgs;

	ERR_IF(data_size &  0x1ff) return NULL;
	ERR_IF(data_size >  DRBD_MAX_SEGMENT_SIZE) return NULL;

	/* even though we trust out peer,
	 * we sometimes have to double check. */
	if (sector + (data_size>>9) > capacity) {
		dev_err(DEV, "capacity: %llus < sector: %llus + size: %u\n",
			(unsigned long long)capacity,
			(unsigned long long)sector, data_size);
		return NULL;
	}

	/* GFP_NOIO, because we must not cause arbitrary write-out: in a DRBD
	 * "criss-cross" setup, that might cause write-out on some other DRBD,
	 * which in turn might block on the other node at this very place.  */
	e = drbd_alloc_ee(mdev, id, sector, data_size, GFP_NOIO);
	if (!e)
		return NULL;

	ds = data_size;
	page = e->pages;
	page_chain_for_each(page) {
		unsigned len = min_t(int, ds, PAGE_SIZE);
		data = kmap(page);
		rr = drbd_recv(mdev, data, len);
		if (FAULT_ACTIVE(mdev, DRBD_FAULT_RECEIVE)) {
			dev_err(DEV, "Fault injection: Corrupting data on receive\n");
			data[0] = data[0] ^ (unsigned long)-1;
		}
		kunmap(page);
		if (rr != len) {
			drbd_free_ee(mdev, e);
			dev_warn(DEV, "short read receiving data: read %d expected %d\n",
			     rr, len);
			return NULL;
		}
		ds -= rr;
	}

	if (dgs) {
		drbd_csum_ee(mdev, mdev->integrity_r_tfm, e, dig_vv);
		if (memcmp(dig_in, dig_vv, dgs)) {
			dev_err(DEV, "Digest integrity check FAILED.\n");
			drbd_bcast_ee(mdev, "digest failed",
					dgs, dig_in, dig_vv, e);
			drbd_free_ee(mdev, e);
			return NULL;
		}
	}
	mdev->recv_cnt += data_size>>9;
	return e;
}

/* drbd_drain_block() just takes a data block
 * out of the socket input buffer, and discards it.
 */
static int drbd_drain_block(struct drbd_conf *mdev, int data_size)
{
	struct page *page;
	int rr, rv = 1;
	void *data;

	if (!data_size)
		return TRUE;

	page = drbd_pp_alloc(mdev, 1, 1);

	data = kmap(page);
	while (data_size) {
		rr = drbd_recv(mdev, data, min_t(int, data_size, PAGE_SIZE));
		if (rr != min_t(int, data_size, PAGE_SIZE)) {
			rv = 0;
			dev_warn(DEV, "short read receiving data: read %d expected %d\n",
			     rr, min_t(int, data_size, PAGE_SIZE));
			break;
		}
		data_size -= rr;
	}
	kunmap(page);
	drbd_pp_free(mdev, page, 0);
	return rv;
}

static int recv_dless_read(struct drbd_conf *mdev, struct drbd_request *req,
			   sector_t sector, int data_size)
{
	struct bio_vec *bvec;
	struct bio *bio;
	int dgs, rr, i, expect;
	void *dig_in = mdev->int_dig_in;
	void *dig_vv = mdev->int_dig_vv;

	dgs = (mdev->agreed_pro_version >= 87 && mdev->integrity_r_tfm) ?
		crypto_hash_digestsize(mdev->integrity_r_tfm) : 0;

	if (dgs) {
		rr = drbd_recv(mdev, dig_in, dgs);
		if (rr != dgs) {
			dev_warn(DEV, "short read receiving data reply digest: read %d expected %d\n",
			     rr, dgs);
			return 0;
		}
	}

	data_size -= dgs;

	/* optimistically update recv_cnt.  if receiving fails below,
	 * we disconnect anyways, and counters will be reset. */
	mdev->recv_cnt += data_size>>9;

	bio = req->master_bio;
	D_ASSERT(sector == bio->bi_sector);

	bio_for_each_segment(bvec, bio, i) {
		expect = min_t(int, data_size, bvec->bv_len);
		rr = drbd_recv(mdev,
			     kmap(bvec->bv_page)+bvec->bv_offset,
			     expect);
		kunmap(bvec->bv_page);
		if (rr != expect) {
			dev_warn(DEV, "short read receiving data reply: "
			     "read %d expected %d\n",
			     rr, expect);
			return 0;
		}
		data_size -= rr;
	}

	if (dgs) {
		drbd_csum_bio(mdev, mdev->integrity_r_tfm, bio, dig_vv);
		if (memcmp(dig_in, dig_vv, dgs)) {
			dev_err(DEV, "Digest integrity check FAILED. Broken NICs?\n");
			return 0;
		}
	}

	D_ASSERT(data_size == 0);
	return 1;
}

/* e_end_resync_block() is called via
 * drbd_process_done_ee() by asender only */
static int e_end_resync_block(struct drbd_conf *mdev, struct drbd_work *w, int unused)
{
	struct drbd_epoch_entry *e = (struct drbd_epoch_entry *)w;
	sector_t sector = e->sector;
	int ok;

	D_ASSERT(hlist_unhashed(&e->colision));

	if (likely((e->flags & EE_WAS_ERROR) == 0)) {
		drbd_set_in_sync(mdev, sector, e->size);
		ok = drbd_send_ack(mdev, P_RS_WRITE_ACK, e);
	} else {
		/* Record failure to sync */
		drbd_rs_failed_io(mdev, sector, e->size);

		ok  = drbd_send_ack(mdev, P_NEG_ACK, e);
	}
	dec_unacked(mdev);

	return ok;
}

static int recv_resync_read(struct drbd_conf *mdev, sector_t sector, int data_size) __releases(local)
{
	struct drbd_epoch_entry *e;

	e = read_in_block(mdev, ID_SYNCER, sector, data_size);
	if (!e)
		goto fail;

	dec_rs_pending(mdev);

	inc_unacked(mdev);
	/* corresponding dec_unacked() in e_end_resync_block()
	 * respective _drbd_clear_done_ee */

	e->w.cb = e_end_resync_block;

	spin_lock_irq(&mdev->req_lock);
	list_add(&e->w.list, &mdev->sync_ee);
	spin_unlock_irq(&mdev->req_lock);

	atomic_add(data_size >> 9, &mdev->rs_sect_ev);
	if (drbd_submit_ee(mdev, e, WRITE, DRBD_FAULT_RS_WR) == 0)
		return TRUE;

	/* drbd_submit_ee currently fails for one reason only:
	 * not being able to allocate enough bios.
	 * Is dropping the connection going to help? */
	spin_lock_irq(&mdev->req_lock);
	list_del(&e->w.list);
	spin_unlock_irq(&mdev->req_lock);

	drbd_free_ee(mdev, e);
fail:
	put_ldev(mdev);
	return FALSE;
}

static int receive_DataReply(struct drbd_conf *mdev, enum drbd_packets cmd, unsigned int data_size)
{
	struct drbd_request *req;
	sector_t sector;
	int ok;
	struct p_data *p = &mdev->data.rbuf.data;

	sector = be64_to_cpu(p->sector);

	spin_lock_irq(&mdev->req_lock);
	req = _ar_id_to_req(mdev, p->block_id, sector);
	spin_unlock_irq(&mdev->req_lock);
	if (unlikely(!req)) {
		dev_err(DEV, "Got a corrupt block_id/sector pair(1).\n");
		return FALSE;
	}

	/* hlist_del(&req->colision) is done in _req_may_be_done, to avoid
	 * special casing it there for the various failure cases.
	 * still no race with drbd_fail_pending_reads */
	ok = recv_dless_read(mdev, req, sector, data_size);

	if (ok)
		req_mod(req, data_received);
	/* else: nothing. handled from drbd_disconnect...
	 * I don't think we may complete this just yet
	 * in case we are "on-disconnect: freeze" */

	return ok;
}

static int receive_RSDataReply(struct drbd_conf *mdev, enum drbd_packets cmd, unsigned int data_size)
{
	sector_t sector;
	int ok;
	struct p_data *p = &mdev->data.rbuf.data;

	sector = be64_to_cpu(p->sector);
	D_ASSERT(p->block_id == ID_SYNCER);

	if (get_ldev(mdev)) {
		/* data is submitted to disk within recv_resync_read.
		 * corresponding put_ldev done below on error,
		 * or in drbd_endio_write_sec. */
		ok = recv_resync_read(mdev, sector, data_size);
	} else {
		if (__ratelimit(&drbd_ratelimit_state))
			dev_err(DEV, "Can not write resync data to local disk.\n");

		ok = drbd_drain_block(mdev, data_size);

		drbd_send_ack_dp(mdev, P_NEG_ACK, p, data_size);
	}

	atomic_add(data_size >> 9, &mdev->rs_sect_in);

	return ok;
}

/* e_end_block() is called via drbd_process_done_ee().
 * this means this function only runs in the asender thread
 */
static int e_end_block(struct drbd_conf *mdev, struct drbd_work *w, int cancel)
{
	struct drbd_epoch_entry *e = (struct drbd_epoch_entry *)w;
	sector_t sector = e->sector;
	int ok = 1, pcmd;

	if (mdev->net_conf->wire_protocol == DRBD_PROT_C) {
		if (likely((e->flags & EE_WAS_ERROR) == 0)) {
			pcmd = (mdev->state.conn >= C_SYNC_SOURCE &&
				mdev->state.conn <= C_PAUSED_SYNC_T &&
				e->flags & EE_MAY_SET_IN_SYNC) ?
				P_RS_WRITE_ACK : P_WRITE_ACK;
			ok &= drbd_send_ack(mdev, pcmd, e);
			if (pcmd == P_RS_WRITE_ACK)
				drbd_set_in_sync(mdev, sector, e->size);
		} else {
			ok  = drbd_send_ack(mdev, P_NEG_ACK, e);
			/* we expect it to be marked out of sync anyways...
			 * maybe assert this?  */
		}
		dec_unacked(mdev);
	}
	/* we delete from the conflict detection hash _after_ we sent out the
	 * P_WRITE_ACK / P_NEG_ACK, to get the sequence number right.  */
	if (mdev->net_conf->two_primaries) {
		spin_lock_irq(&mdev->req_lock);
		D_ASSERT(!hlist_unhashed(&e->colision));
		hlist_del_init(&e->colision);
		spin_unlock_irq(&mdev->req_lock);
	} else {
		D_ASSERT(hlist_unhashed(&e->colision));
	}

	drbd_may_finish_epoch(mdev, e->epoch, EV_PUT + (cancel ? EV_CLEANUP : 0));

	return ok;
}

static int e_send_discard_ack(struct drbd_conf *mdev, struct drbd_work *w, int unused)
{
	struct drbd_epoch_entry *e = (struct drbd_epoch_entry *)w;
	int ok = 1;

	D_ASSERT(mdev->net_conf->wire_protocol == DRBD_PROT_C);
	ok = drbd_send_ack(mdev, P_DISCARD_ACK, e);

	spin_lock_irq(&mdev->req_lock);
	D_ASSERT(!hlist_unhashed(&e->colision));
	hlist_del_init(&e->colision);
	spin_unlock_irq(&mdev->req_lock);

	dec_unacked(mdev);

	return ok;
}

/* Called from receive_Data.
 * Synchronize packets on sock with packets on msock.
 *
 * This is here so even when a P_DATA packet traveling via sock overtook an Ack
 * packet traveling on msock, they are still processed in the order they have
 * been sent.
 *
 * Note: we don't care for Ack packets overtaking P_DATA packets.
 *
 * In case packet_seq is larger than mdev->peer_seq number, there are
 * outstanding packets on the msock. We wait for them to arrive.
 * In case we are the logically next packet, we update mdev->peer_seq
 * ourselves. Correctly handles 32bit wrap around.
 *
 * Assume we have a 10 GBit connection, that is about 1<<30 byte per second,
 * about 1<<21 sectors per second. So "worst" case, we have 1<<3 == 8 seconds
 * for the 24bit wrap (historical atomic_t guarantee on some archs), and we have
 * 1<<9 == 512 seconds aka ages for the 32bit wrap around...
 *
 * returns 0 if we may process the packet,
 * -ERESTARTSYS if we were interrupted (by disconnect signal). */
static int drbd_wait_peer_seq(struct drbd_conf *mdev, const u32 packet_seq)
{
	DEFINE_WAIT(wait);
	unsigned int p_seq;
	long timeout;
	int ret = 0;
	spin_lock(&mdev->peer_seq_lock);
	for (;;) {
		prepare_to_wait(&mdev->seq_wait, &wait, TASK_INTERRUPTIBLE);
		if (seq_le(packet_seq, mdev->peer_seq+1))
			break;
		if (signal_pending(current)) {
			ret = -ERESTARTSYS;
			break;
		}
		p_seq = mdev->peer_seq;
		spin_unlock(&mdev->peer_seq_lock);
		timeout = schedule_timeout(30*HZ);
		spin_lock(&mdev->peer_seq_lock);
		if (timeout == 0 && p_seq == mdev->peer_seq) {
			ret = -ETIMEDOUT;
			dev_err(DEV, "ASSERT FAILED waited 30 seconds for sequence update, forcing reconnect\n");
			break;
		}
	}
	finish_wait(&mdev->seq_wait, &wait);
	if (mdev->peer_seq+1 == packet_seq)
		mdev->peer_seq++;
	spin_unlock(&mdev->peer_seq_lock);
	return ret;
}

static unsigned long write_flags_to_bio(struct drbd_conf *mdev, u32 dpf)
{
	if (mdev->agreed_pro_version >= 95)
		return  (dpf & DP_RW_SYNC ? REQ_SYNC : 0) |
			(dpf & DP_UNPLUG ? REQ_UNPLUG : 0) |
			(dpf & DP_FUA ? REQ_FUA : 0) |
			(dpf & DP_FLUSH ? REQ_FUA : 0) |
			(dpf & DP_DISCARD ? REQ_DISCARD : 0);
	else
		return dpf & DP_RW_SYNC ? (REQ_SYNC | REQ_UNPLUG) : 0;
}

/* mirrored write */
static int receive_Data(struct drbd_conf *mdev, enum drbd_packets cmd, unsigned int data_size)
{
	sector_t sector;
	struct drbd_epoch_entry *e;
	struct p_data *p = &mdev->data.rbuf.data;
	int rw = WRITE;
	u32 dp_flags;

	if (!get_ldev(mdev)) {
		if (__ratelimit(&drbd_ratelimit_state))
			dev_err(DEV, "Can not write mirrored data block "
			    "to local disk.\n");
		spin_lock(&mdev->peer_seq_lock);
		if (mdev->peer_seq+1 == be32_to_cpu(p->seq_num))
			mdev->peer_seq++;
		spin_unlock(&mdev->peer_seq_lock);

		drbd_send_ack_dp(mdev, P_NEG_ACK, p, data_size);
		atomic_inc(&mdev->current_epoch->epoch_size);
		return drbd_drain_block(mdev, data_size);
	}

	/* get_ldev(mdev) successful.
	 * Corresponding put_ldev done either below (on various errors),
	 * or in drbd_endio_write_sec, if we successfully submit the data at
	 * the end of this function. */

	sector = be64_to_cpu(p->sector);
	e = read_in_block(mdev, p->block_id, sector, data_size);
	if (!e) {
		put_ldev(mdev);
		return FALSE;
	}

	e->w.cb = e_end_block;

	spin_lock(&mdev->epoch_lock);
	e->epoch = mdev->current_epoch;
	atomic_inc(&e->epoch->epoch_size);
	atomic_inc(&e->epoch->active);
	spin_unlock(&mdev->epoch_lock);

	dp_flags = be32_to_cpu(p->dp_flags);
	rw |= write_flags_to_bio(mdev, dp_flags);

	if (dp_flags & DP_MAY_SET_IN_SYNC)
		e->flags |= EE_MAY_SET_IN_SYNC;

	/* I'm the receiver, I do hold a net_cnt reference. */
	if (!mdev->net_conf->two_primaries) {
		spin_lock_irq(&mdev->req_lock);
	} else {
		/* don't get the req_lock yet,
		 * we may sleep in drbd_wait_peer_seq */
		const int size = e->size;
		const int discard = test_bit(DISCARD_CONCURRENT, &mdev->flags);
		DEFINE_WAIT(wait);
		struct drbd_request *i;
		struct hlist_node *n;
		struct hlist_head *slot;
		int first;

		D_ASSERT(mdev->net_conf->wire_protocol == DRBD_PROT_C);
		BUG_ON(mdev->ee_hash == NULL);
		BUG_ON(mdev->tl_hash == NULL);

		/* conflict detection and handling:
		 * 1. wait on the sequence number,
		 *    in case this data packet overtook ACK packets.
		 * 2. check our hash tables for conflicting requests.
		 *    we only need to walk the tl_hash, since an ee can not
		 *    have a conflict with an other ee: on the submitting
		 *    node, the corresponding req had already been conflicting,
		 *    and a conflicting req is never sent.
		 *
		 * Note: for two_primaries, we are protocol C,
		 * so there cannot be any request that is DONE
		 * but still on the transfer log.
		 *
		 * unconditionally add to the ee_hash.
		 *
		 * if no conflicting request is found:
		 *    submit.
		 *
		 * if any conflicting request is found
		 * that has not yet been acked,
		 * AND I have the "discard concurrent writes" flag:
		 *	 queue (via done_ee) the P_DISCARD_ACK; OUT.
		 *
		 * if any conflicting request is found:
		 *	 block the receiver, waiting on misc_wait
		 *	 until no more conflicting requests are there,
		 *	 or we get interrupted (disconnect).
		 *
		 *	 we do not just write after local io completion of those
		 *	 requests, but only after req is done completely, i.e.
		 *	 we wait for the P_DISCARD_ACK to arrive!
		 *
		 *	 then proceed normally, i.e. submit.
		 */
		if (drbd_wait_peer_seq(mdev, be32_to_cpu(p->seq_num)))
			goto out_interrupted;

		spin_lock_irq(&mdev->req_lock);

		hlist_add_head(&e->colision, ee_hash_slot(mdev, sector));

#define OVERLAPS overlaps(i->sector, i->size, sector, size)
		slot = tl_hash_slot(mdev, sector);
		first = 1;
		for (;;) {
			int have_unacked = 0;
			int have_conflict = 0;
			prepare_to_wait(&mdev->misc_wait, &wait,
				TASK_INTERRUPTIBLE);
			hlist_for_each_entry(i, n, slot, colision) {
				if (OVERLAPS) {
					/* only ALERT on first iteration,
					 * we may be woken up early... */
					if (first)
						dev_alert(DEV, "%s[%u] Concurrent local write detected!"
						      "	new: %llus +%u; pending: %llus +%u\n",
						      current->comm, current->pid,
						      (unsigned long long)sector, size,
						      (unsigned long long)i->sector, i->size);
					if (i->rq_state & RQ_NET_PENDING)
						++have_unacked;
					++have_conflict;
				}
			}
#undef OVERLAPS
			if (!have_conflict)
				break;

			/* Discard Ack only for the _first_ iteration */
			if (first && discard && have_unacked) {
				dev_alert(DEV, "Concurrent write! [DISCARD BY FLAG] sec=%llus\n",
				     (unsigned long long)sector);
				inc_unacked(mdev);
				e->w.cb = e_send_discard_ack;
				list_add_tail(&e->w.list, &mdev->done_ee);

				spin_unlock_irq(&mdev->req_lock);

				/* we could probably send that P_DISCARD_ACK ourselves,
				 * but I don't like the receiver using the msock */

				put_ldev(mdev);
				wake_asender(mdev);
				finish_wait(&mdev->misc_wait, &wait);
				return TRUE;
			}

			if (signal_pending(current)) {
				hlist_del_init(&e->colision);

				spin_unlock_irq(&mdev->req_lock);

				finish_wait(&mdev->misc_wait, &wait);
				goto out_interrupted;
			}

			spin_unlock_irq(&mdev->req_lock);
			if (first) {
				first = 0;
				dev_alert(DEV, "Concurrent write! [W AFTERWARDS] "
				     "sec=%llus\n", (unsigned long long)sector);
			} else if (discard) {
				/* we had none on the first iteration.
				 * there must be none now. */
				D_ASSERT(have_unacked == 0);
			}
			schedule();
			spin_lock_irq(&mdev->req_lock);
		}
		finish_wait(&mdev->misc_wait, &wait);
	}

	list_add(&e->w.list, &mdev->active_ee);
	spin_unlock_irq(&mdev->req_lock);

	switch (mdev->net_conf->wire_protocol) {
	case DRBD_PROT_C:
		inc_unacked(mdev);
		/* corresponding dec_unacked() in e_end_block()
		 * respective _drbd_clear_done_ee */
		break;
	case DRBD_PROT_B:
		/* I really don't like it that the receiver thread
		 * sends on the msock, but anyways */
		drbd_send_ack(mdev, P_RECV_ACK, e);
		break;
	case DRBD_PROT_A:
		/* nothing to do */
		break;
	}

	if (mdev->state.pdsk < D_INCONSISTENT) {
		/* In case we have the only disk of the cluster, */
		drbd_set_out_of_sync(mdev, e->sector, e->size);
		e->flags |= EE_CALL_AL_COMPLETE_IO;
		e->flags &= ~EE_MAY_SET_IN_SYNC;
		drbd_al_begin_io(mdev, e->sector);
	}

	if (drbd_submit_ee(mdev, e, rw, DRBD_FAULT_DT_WR) == 0)
		return TRUE;

	/* drbd_submit_ee currently fails for one reason only:
	 * not being able to allocate enough bios.
	 * Is dropping the connection going to help? */
	spin_lock_irq(&mdev->req_lock);
	list_del(&e->w.list);
	hlist_del_init(&e->colision);
	spin_unlock_irq(&mdev->req_lock);
	if (e->flags & EE_CALL_AL_COMPLETE_IO)
		drbd_al_complete_io(mdev, e->sector);

out_interrupted:
	/* yes, the epoch_size now is imbalanced.
	 * but we drop the connection anyways, so we don't have a chance to
	 * receive a barrier... atomic_inc(&mdev->epoch_size); */
	put_ldev(mdev);
	drbd_free_ee(mdev, e);
	return FALSE;
}

/* We may throttle resync, if the lower device seems to be busy,
 * and current sync rate is above c_min_rate.
 *
 * To decide whether or not the lower device is busy, we use a scheme similar
 * to MD RAID is_mddev_idle(): if the partition stats reveal "significant"
 * (more than 64 sectors) of activity we cannot account for with our own resync
 * activity, it obviously is "busy".
 *
 * The current sync rate used here uses only the most recent two step marks,
 * to have a short time average so we can react faster.
 */
int drbd_rs_should_slow_down(struct drbd_conf *mdev)
{
	struct gendisk *disk = mdev->ldev->backing_bdev->bd_contains->bd_disk;
	unsigned long db, dt, dbdt;
	int curr_events;
	int throttle = 0;

	/* feature disabled? */
	if (mdev->sync_conf.c_min_rate == 0)
		return 0;

	curr_events = (int)part_stat_read(&disk->part0, sectors[0]) +
		      (int)part_stat_read(&disk->part0, sectors[1]) -
			atomic_read(&mdev->rs_sect_ev);
	if (!mdev->rs_last_events || curr_events - mdev->rs_last_events > 64) {
		unsigned long rs_left;
		int i;

		mdev->rs_last_events = curr_events;

		/* sync speed average over the last 2*DRBD_SYNC_MARK_STEP,
		 * approx. */
		i = (mdev->rs_last_mark + DRBD_SYNC_MARKS-2) % DRBD_SYNC_MARKS;
		rs_left = drbd_bm_total_weight(mdev) - mdev->rs_failed;

		dt = ((long)jiffies - (long)mdev->rs_mark_time[i]) / HZ;
		if (!dt)
			dt++;
		db = mdev->rs_mark_left[i] - rs_left;
		dbdt = Bit2KB(db/dt);

		if (dbdt > mdev->sync_conf.c_min_rate)
			throttle = 1;
	}
	return throttle;
}


static int receive_DataRequest(struct drbd_conf *mdev, enum drbd_packets cmd, unsigned int digest_size)
{
	sector_t sector;
	const sector_t capacity = drbd_get_capacity(mdev->this_bdev);
	struct drbd_epoch_entry *e;
	struct digest_info *di = NULL;
	int size, verb;
	unsigned int fault_type;
	struct p_block_req *p =	&mdev->data.rbuf.block_req;

	sector = be64_to_cpu(p->sector);
	size   = be32_to_cpu(p->blksize);

	if (size <= 0 || (size & 0x1ff) != 0 || size > DRBD_MAX_SEGMENT_SIZE) {
		dev_err(DEV, "%s:%d: sector: %llus, size: %u\n", __FILE__, __LINE__,
				(unsigned long long)sector, size);
		return FALSE;
	}
	if (sector + (size>>9) > capacity) {
		dev_err(DEV, "%s:%d: sector: %llus, size: %u\n", __FILE__, __LINE__,
				(unsigned long long)sector, size);
		return FALSE;
	}

	if (!get_ldev_if_state(mdev, D_UP_TO_DATE)) {
		verb = 1;
		switch (cmd) {
		case P_DATA_REQUEST:
			drbd_send_ack_rp(mdev, P_NEG_DREPLY, p);
			break;
		case P_RS_DATA_REQUEST:
		case P_CSUM_RS_REQUEST:
		case P_OV_REQUEST:
			drbd_send_ack_rp(mdev, P_NEG_RS_DREPLY , p);
			break;
		case P_OV_REPLY:
			verb = 0;
			dec_rs_pending(mdev);
			drbd_send_ack_ex(mdev, P_OV_RESULT, sector, size, ID_IN_SYNC);
			break;
		default:
			dev_err(DEV, "unexpected command (%s) in receive_DataRequest\n",
				cmdname(cmd));
		}
		if (verb && __ratelimit(&drbd_ratelimit_state))
			dev_err(DEV, "Can not satisfy peer's read request, "
			    "no local data.\n");

		/* drain possibly payload */
		return drbd_drain_block(mdev, digest_size);
	}

	/* GFP_NOIO, because we must not cause arbitrary write-out: in a DRBD
	 * "criss-cross" setup, that might cause write-out on some other DRBD,
	 * which in turn might block on the other node at this very place.  */
	e = drbd_alloc_ee(mdev, p->block_id, sector, size, GFP_NOIO);
	if (!e) {
		put_ldev(mdev);
		return FALSE;
	}

	switch (cmd) {
	case P_DATA_REQUEST:
		e->w.cb = w_e_end_data_req;
		fault_type = DRBD_FAULT_DT_RD;
		/* application IO, don't drbd_rs_begin_io */
		goto submit;

	case P_RS_DATA_REQUEST:
		e->w.cb = w_e_end_rsdata_req;
		fault_type = DRBD_FAULT_RS_RD;
		break;

	case P_OV_REPLY:
	case P_CSUM_RS_REQUEST:
		fault_type = DRBD_FAULT_RS_RD;
		di = kmalloc(sizeof(*di) + digest_size, GFP_NOIO);
		if (!di)
			goto out_free_e;

		di->digest_size = digest_size;
		di->digest = (((char *)di)+sizeof(struct digest_info));

		e->digest = di;
		e->flags |= EE_HAS_DIGEST;

		if (drbd_recv(mdev, di->digest, digest_size) != digest_size)
			goto out_free_e;

		if (cmd == P_CSUM_RS_REQUEST) {
			D_ASSERT(mdev->agreed_pro_version >= 89);
			e->w.cb = w_e_end_csum_rs_req;
		} else if (cmd == P_OV_REPLY) {
			e->w.cb = w_e_end_ov_reply;
			dec_rs_pending(mdev);
			/* drbd_rs_begin_io done when we sent this request,
			 * but accounting still needs to be done. */
			goto submit_for_resync;
		}
		break;

	case P_OV_REQUEST:
		if (mdev->ov_start_sector == ~(sector_t)0 &&
		    mdev->agreed_pro_version >= 90) {
			mdev->ov_start_sector = sector;
			mdev->ov_position = sector;
			mdev->ov_left = mdev->rs_total - BM_SECT_TO_BIT(sector);
			dev_info(DEV, "Online Verify start sector: %llu\n",
					(unsigned long long)sector);
		}
		e->w.cb = w_e_end_ov_req;
		fault_type = DRBD_FAULT_RS_RD;
		break;

	default:
		dev_err(DEV, "unexpected command (%s) in receive_DataRequest\n",
		    cmdname(cmd));
		fault_type = DRBD_FAULT_MAX;
		goto out_free_e;
	}

	/* Throttle, drbd_rs_begin_io and submit should become asynchronous
	 * wrt the receiver, but it is not as straightforward as it may seem.
	 * Various places in the resync start and stop logic assume resync
	 * requests are processed in order, requeuing this on the worker thread
	 * introduces a bunch of new code for synchronization between threads.
	 *
	 * Unlimited throttling before drbd_rs_begin_io may stall the resync
	 * "forever", throttling after drbd_rs_begin_io will lock that extent
	 * for application writes for the same time.  For now, just throttle
	 * here, where the rest of the code expects the receiver to sleep for
	 * a while, anyways.
	 */

	/* Throttle before drbd_rs_begin_io, as that locks out application IO;
	 * this defers syncer requests for some time, before letting at least
	 * on request through.  The resync controller on the receiving side
	 * will adapt to the incoming rate accordingly.
	 *
	 * We cannot throttle here if remote is Primary/SyncTarget:
	 * we would also throttle its application reads.
	 * In that case, throttling is done on the SyncTarget only.
	 */
	if (mdev->state.peer != R_PRIMARY && drbd_rs_should_slow_down(mdev))
		msleep(100);
	if (drbd_rs_begin_io(mdev, e->sector))
		goto out_free_e;

submit_for_resync:
	atomic_add(size >> 9, &mdev->rs_sect_ev);

submit:
	inc_unacked(mdev);
	spin_lock_irq(&mdev->req_lock);
	list_add_tail(&e->w.list, &mdev->read_ee);
	spin_unlock_irq(&mdev->req_lock);

	if (drbd_submit_ee(mdev, e, READ, fault_type) == 0)
		return TRUE;

	/* drbd_submit_ee currently fails for one reason only:
	 * not being able to allocate enough bios.
	 * Is dropping the connection going to help? */
	spin_lock_irq(&mdev->req_lock);
	list_del(&e->w.list);
	spin_unlock_irq(&mdev->req_lock);
	/* no drbd_rs_complete_io(), we are dropping the connection anyways */

out_free_e:
	put_ldev(mdev);
	drbd_free_ee(mdev, e);
	return FALSE;
}

static int drbd_asb_recover_0p(struct drbd_conf *mdev) __must_hold(local)
{
	int self, peer, rv = -100;
	unsigned long ch_self, ch_peer;

	self = mdev->ldev->md.uuid[UI_BITMAP] & 1;
	peer = mdev->p_uuid[UI_BITMAP] & 1;

	ch_peer = mdev->p_uuid[UI_SIZE];
	ch_self = mdev->comm_bm_set;

	switch (mdev->net_conf->after_sb_0p) {
	case ASB_CONSENSUS:
	case ASB_DISCARD_SECONDARY:
	case ASB_CALL_HELPER:
		dev_err(DEV, "Configuration error.\n");
		break;
	case ASB_DISCONNECT:
		break;
	case ASB_DISCARD_YOUNGER_PRI:
		if (self == 0 && peer == 1) {
			rv = -1;
			break;
		}
		if (self == 1 && peer == 0) {
			rv =  1;
			break;
		}
		/* Else fall through to one of the other strategies... */
	case ASB_DISCARD_OLDER_PRI:
		if (self == 0 && peer == 1) {
			rv = 1;
			break;
		}
		if (self == 1 && peer == 0) {
			rv = -1;
			break;
		}
		/* Else fall through to one of the other strategies... */
		dev_warn(DEV, "Discard younger/older primary did not find a decision\n"
		     "Using discard-least-changes instead\n");
	case ASB_DISCARD_ZERO_CHG:
		if (ch_peer == 0 && ch_self == 0) {
			rv = test_bit(DISCARD_CONCURRENT, &mdev->flags)
				? -1 : 1;
			break;
		} else {
			if (ch_peer == 0) { rv =  1; break; }
			if (ch_self == 0) { rv = -1; break; }
		}
		if (mdev->net_conf->after_sb_0p == ASB_DISCARD_ZERO_CHG)
			break;
	case ASB_DISCARD_LEAST_CHG:
		if	(ch_self < ch_peer)
			rv = -1;
		else if (ch_self > ch_peer)
			rv =  1;
		else /* ( ch_self == ch_peer ) */
		     /* Well, then use something else. */
			rv = test_bit(DISCARD_CONCURRENT, &mdev->flags)
				? -1 : 1;
		break;
	case ASB_DISCARD_LOCAL:
		rv = -1;
		break;
	case ASB_DISCARD_REMOTE:
		rv =  1;
	}

	return rv;
}

static int drbd_asb_recover_1p(struct drbd_conf *mdev) __must_hold(local)
{
	int self, peer, hg, rv = -100;

	self = mdev->ldev->md.uuid[UI_BITMAP] & 1;
	peer = mdev->p_uuid[UI_BITMAP] & 1;

	switch (mdev->net_conf->after_sb_1p) {
	case ASB_DISCARD_YOUNGER_PRI:
	case ASB_DISCARD_OLDER_PRI:
	case ASB_DISCARD_LEAST_CHG:
	case ASB_DISCARD_LOCAL:
	case ASB_DISCARD_REMOTE:
		dev_err(DEV, "Configuration error.\n");
		break;
	case ASB_DISCONNECT:
		break;
	case ASB_CONSENSUS:
		hg = drbd_asb_recover_0p(mdev);
		if (hg == -1 && mdev->state.role == R_SECONDARY)
			rv = hg;
		if (hg == 1  && mdev->state.role == R_PRIMARY)
			rv = hg;
		break;
	case ASB_VIOLENTLY:
		rv = drbd_asb_recover_0p(mdev);
		break;
	case ASB_DISCARD_SECONDARY:
		return mdev->state.role == R_PRIMARY ? 1 : -1;
	case ASB_CALL_HELPER:
		hg = drbd_asb_recover_0p(mdev);
		if (hg == -1 && mdev->state.role == R_PRIMARY) {
			self = drbd_set_role(mdev, R_SECONDARY, 0);
			 /* drbd_change_state() does not sleep while in SS_IN_TRANSIENT_STATE,
			  * we might be here in C_WF_REPORT_PARAMS which is transient.
			  * we do not need to wait for the after state change work either. */
			self = drbd_change_state(mdev, CS_VERBOSE, NS(role, R_SECONDARY));
			if (self != SS_SUCCESS) {
				drbd_khelper(mdev, "pri-lost-after-sb");
			} else {
				dev_warn(DEV, "Successfully gave up primary role.\n");
				rv = hg;
			}
		} else
			rv = hg;
	}

	return rv;
}

static int drbd_asb_recover_2p(struct drbd_conf *mdev) __must_hold(local)
{
	int self, peer, hg, rv = -100;

	self = mdev->ldev->md.uuid[UI_BITMAP] & 1;
	peer = mdev->p_uuid[UI_BITMAP] & 1;

	switch (mdev->net_conf->after_sb_2p) {
	case ASB_DISCARD_YOUNGER_PRI:
	case ASB_DISCARD_OLDER_PRI:
	case ASB_DISCARD_LEAST_CHG:
	case ASB_DISCARD_LOCAL:
	case ASB_DISCARD_REMOTE:
	case ASB_CONSENSUS:
	case ASB_DISCARD_SECONDARY:
		dev_err(DEV, "Configuration error.\n");
		break;
	case ASB_VIOLENTLY:
		rv = drbd_asb_recover_0p(mdev);
		break;
	case ASB_DISCONNECT:
		break;
	case ASB_CALL_HELPER:
		hg = drbd_asb_recover_0p(mdev);
		if (hg == -1) {
			 /* drbd_change_state() does not sleep while in SS_IN_TRANSIENT_STATE,
			  * we might be here in C_WF_REPORT_PARAMS which is transient.
			  * we do not need to wait for the after state change work either. */
			self = drbd_change_state(mdev, CS_VERBOSE, NS(role, R_SECONDARY));
			if (self != SS_SUCCESS) {
				drbd_khelper(mdev, "pri-lost-after-sb");
			} else {
				dev_warn(DEV, "Successfully gave up primary role.\n");
				rv = hg;
			}
		} else
			rv = hg;
	}

	return rv;
}

static void drbd_uuid_dump(struct drbd_conf *mdev, char *text, u64 *uuid,
			   u64 bits, u64 flags)
{
	if (!uuid) {
		dev_info(DEV, "%s uuid info vanished while I was looking!\n", text);
		return;
	}
	dev_info(DEV, "%s %016llX:%016llX:%016llX:%016llX bits:%llu flags:%llX\n",
	     text,
	     (unsigned long long)uuid[UI_CURRENT],
	     (unsigned long long)uuid[UI_BITMAP],
	     (unsigned long long)uuid[UI_HISTORY_START],
	     (unsigned long long)uuid[UI_HISTORY_END],
	     (unsigned long long)bits,
	     (unsigned long long)flags);
}

/*
  100	after split brain try auto recover
    2	C_SYNC_SOURCE set BitMap
    1	C_SYNC_SOURCE use BitMap
    0	no Sync
   -1	C_SYNC_TARGET use BitMap
   -2	C_SYNC_TARGET set BitMap
 -100	after split brain, disconnect
-1000	unrelated data
 */
static int drbd_uuid_compare(struct drbd_conf *mdev, int *rule_nr) __must_hold(local)
{
	u64 self, peer;
	int i, j;

	self = mdev->ldev->md.uuid[UI_CURRENT] & ~((u64)1);
	peer = mdev->p_uuid[UI_CURRENT] & ~((u64)1);

	*rule_nr = 10;
	if (self == UUID_JUST_CREATED && peer == UUID_JUST_CREATED)
		return 0;

	*rule_nr = 20;
	if ((self == UUID_JUST_CREATED || self == (u64)0) &&
	     peer != UUID_JUST_CREATED)
		return -2;

	*rule_nr = 30;
	if (self != UUID_JUST_CREATED &&
	    (peer == UUID_JUST_CREATED || peer == (u64)0))
		return 2;

	if (self == peer) {
		int rct, dc; /* roles at crash time */

		if (mdev->p_uuid[UI_BITMAP] == (u64)0 && mdev->ldev->md.uuid[UI_BITMAP] != (u64)0) {

			if (mdev->agreed_pro_version < 91)
				return -1001;

			if ((mdev->ldev->md.uuid[UI_BITMAP] & ~((u64)1)) == (mdev->p_uuid[UI_HISTORY_START] & ~((u64)1)) &&
			    (mdev->ldev->md.uuid[UI_HISTORY_START] & ~((u64)1)) == (mdev->p_uuid[UI_HISTORY_START + 1] & ~((u64)1))) {
				dev_info(DEV, "was SyncSource, missed the resync finished event, corrected myself:\n");
				drbd_uuid_set_bm(mdev, 0UL);

				drbd_uuid_dump(mdev, "self", mdev->ldev->md.uuid,
					       mdev->state.disk >= D_NEGOTIATING ? drbd_bm_total_weight(mdev) : 0, 0);
				*rule_nr = 34;
			} else {
				dev_info(DEV, "was SyncSource (peer failed to write sync_uuid)\n");
				*rule_nr = 36;
			}

			return 1;
		}

		if (mdev->ldev->md.uuid[UI_BITMAP] == (u64)0 && mdev->p_uuid[UI_BITMAP] != (u64)0) {

			if (mdev->agreed_pro_version < 91)
				return -1001;

			if ((mdev->ldev->md.uuid[UI_HISTORY_START] & ~((u64)1)) == (mdev->p_uuid[UI_BITMAP] & ~((u64)1)) &&
			    (mdev->ldev->md.uuid[UI_HISTORY_START + 1] & ~((u64)1)) == (mdev->p_uuid[UI_HISTORY_START] & ~((u64)1))) {
				dev_info(DEV, "was SyncTarget, peer missed the resync finished event, corrected peer:\n");

				mdev->p_uuid[UI_HISTORY_START + 1] = mdev->p_uuid[UI_HISTORY_START];
				mdev->p_uuid[UI_HISTORY_START] = mdev->p_uuid[UI_BITMAP];
				mdev->p_uuid[UI_BITMAP] = 0UL;

				drbd_uuid_dump(mdev, "peer", mdev->p_uuid, mdev->p_uuid[UI_SIZE], mdev->p_uuid[UI_FLAGS]);
				*rule_nr = 35;
			} else {
				dev_info(DEV, "was SyncTarget (failed to write sync_uuid)\n");
				*rule_nr = 37;
			}

			return -1;
		}

		/* Common power [off|failure] */
		rct = (test_bit(CRASHED_PRIMARY, &mdev->flags) ? 1 : 0) +
			(mdev->p_uuid[UI_FLAGS] & 2);
		/* lowest bit is set when we were primary,
		 * next bit (weight 2) is set when peer was primary */
		*rule_nr = 40;

		switch (rct) {
		case 0: /* !self_pri && !peer_pri */ return 0;
		case 1: /*  self_pri && !peer_pri */ return 1;
		case 2: /* !self_pri &&  peer_pri */ return -1;
		case 3: /*  self_pri &&  peer_pri */
			dc = test_bit(DISCARD_CONCURRENT, &mdev->flags);
			return dc ? -1 : 1;
		}
	}

	*rule_nr = 50;
	peer = mdev->p_uuid[UI_BITMAP] & ~((u64)1);
	if (self == peer)
		return -1;

	*rule_nr = 51;
	peer = mdev->p_uuid[UI_HISTORY_START] & ~((u64)1);
	if (self == peer) {
		self = mdev->ldev->md.uuid[UI_HISTORY_START] & ~((u64)1);
		peer = mdev->p_uuid[UI_HISTORY_START + 1] & ~((u64)1);
		if (self == peer) {
			/* The last P_SYNC_UUID did not get though. Undo the last start of
			   resync as sync source modifications of the peer's UUIDs. */

			if (mdev->agreed_pro_version < 91)
				return -1001;

			mdev->p_uuid[UI_BITMAP] = mdev->p_uuid[UI_HISTORY_START];
			mdev->p_uuid[UI_HISTORY_START] = mdev->p_uuid[UI_HISTORY_START + 1];
			return -1;
		}
	}

	*rule_nr = 60;
	self = mdev->ldev->md.uuid[UI_CURRENT] & ~((u64)1);
	for (i = UI_HISTORY_START; i <= UI_HISTORY_END; i++) {
		peer = mdev->p_uuid[i] & ~((u64)1);
		if (self == peer)
			return -2;
	}

	*rule_nr = 70;
	self = mdev->ldev->md.uuid[UI_BITMAP] & ~((u64)1);
	peer = mdev->p_uuid[UI_CURRENT] & ~((u64)1);
	if (self == peer)
		return 1;

	*rule_nr = 71;
	self = mdev->ldev->md.uuid[UI_HISTORY_START] & ~((u64)1);
	if (self == peer) {
		self = mdev->ldev->md.uuid[UI_HISTORY_START + 1] & ~((u64)1);
		peer = mdev->p_uuid[UI_HISTORY_START] & ~((u64)1);
		if (self == peer) {
			/* The last P_SYNC_UUID did not get though. Undo the last start of
			   resync as sync source modifications of our UUIDs. */

			if (mdev->agreed_pro_version < 91)
				return -1001;

			_drbd_uuid_set(mdev, UI_BITMAP, mdev->ldev->md.uuid[UI_HISTORY_START]);
			_drbd_uuid_set(mdev, UI_HISTORY_START, mdev->ldev->md.uuid[UI_HISTORY_START + 1]);

			dev_info(DEV, "Undid last start of resync:\n");

			drbd_uuid_dump(mdev, "self", mdev->ldev->md.uuid,
				       mdev->state.disk >= D_NEGOTIATING ? drbd_bm_total_weight(mdev) : 0, 0);

			return 1;
		}
	}


	*rule_nr = 80;
	peer = mdev->p_uuid[UI_CURRENT] & ~((u64)1);
	for (i = UI_HISTORY_START; i <= UI_HISTORY_END; i++) {
		self = mdev->ldev->md.uuid[i] & ~((u64)1);
		if (self == peer)
			return 2;
	}

	*rule_nr = 90;
	self = mdev->ldev->md.uuid[UI_BITMAP] & ~((u64)1);
	peer = mdev->p_uuid[UI_BITMAP] & ~((u64)1);
	if (self == peer && self != ((u64)0))
		return 100;

	*rule_nr = 100;
	for (i = UI_HISTORY_START; i <= UI_HISTORY_END; i++) {
		self = mdev->ldev->md.uuid[i] & ~((u64)1);
		for (j = UI_HISTORY_START; j <= UI_HISTORY_END; j++) {
			peer = mdev->p_uuid[j] & ~((u64)1);
			if (self == peer)
				return -100;
		}
	}

	return -1000;
}

/* drbd_sync_handshake() returns the new conn state on success, or
   CONN_MASK (-1) on failure.
 */
static enum drbd_conns drbd_sync_handshake(struct drbd_conf *mdev, enum drbd_role peer_role,
					   enum drbd_disk_state peer_disk) __must_hold(local)
{
	int hg, rule_nr;
	enum drbd_conns rv = C_MASK;
	enum drbd_disk_state mydisk;

	mydisk = mdev->state.disk;
	if (mydisk == D_NEGOTIATING)
		mydisk = mdev->new_state_tmp.disk;

	dev_info(DEV, "drbd_sync_handshake:\n");
	drbd_uuid_dump(mdev, "self", mdev->ldev->md.uuid, mdev->comm_bm_set, 0);
	drbd_uuid_dump(mdev, "peer", mdev->p_uuid,
		       mdev->p_uuid[UI_SIZE], mdev->p_uuid[UI_FLAGS]);

	hg = drbd_uuid_compare(mdev, &rule_nr);

	dev_info(DEV, "uuid_compare()=%d by rule %d\n", hg, rule_nr);

	if (hg == -1000) {
		dev_alert(DEV, "Unrelated data, aborting!\n");
		return C_MASK;
	}
	if (hg == -1001) {
		dev_alert(DEV, "To resolve this both sides have to support at least protocol\n");
		return C_MASK;
	}

	if    ((mydisk == D_INCONSISTENT && peer_disk > D_INCONSISTENT) ||
	    (peer_disk == D_INCONSISTENT && mydisk    > D_INCONSISTENT)) {
		int f = (hg == -100) || abs(hg) == 2;
		hg = mydisk > D_INCONSISTENT ? 1 : -1;
		if (f)
			hg = hg*2;
		dev_info(DEV, "Becoming sync %s due to disk states.\n",
		     hg > 0 ? "source" : "target");
	}

	if (abs(hg) == 100)
		drbd_khelper(mdev, "initial-split-brain");

	if (hg == 100 || (hg == -100 && mdev->net_conf->always_asbp)) {
		int pcount = (mdev->state.role == R_PRIMARY)
			   + (peer_role == R_PRIMARY);
		int forced = (hg == -100);

		switch (pcount) {
		case 0:
			hg = drbd_asb_recover_0p(mdev);
			break;
		case 1:
			hg = drbd_asb_recover_1p(mdev);
			break;
		case 2:
			hg = drbd_asb_recover_2p(mdev);
			break;
		}
		if (abs(hg) < 100) {
			dev_warn(DEV, "Split-Brain detected, %d primaries, "
			     "automatically solved. Sync from %s node\n",
			     pcount, (hg < 0) ? "peer" : "this");
			if (forced) {
				dev_warn(DEV, "Doing a full sync, since"
				     " UUIDs where ambiguous.\n");
				hg = hg*2;
			}
		}
	}

	if (hg == -100) {
		if (mdev->net_conf->want_lose && !(mdev->p_uuid[UI_FLAGS]&1))
			hg = -1;
		if (!mdev->net_conf->want_lose && (mdev->p_uuid[UI_FLAGS]&1))
			hg = 1;

		if (abs(hg) < 100)
			dev_warn(DEV, "Split-Brain detected, manually solved. "
			     "Sync from %s node\n",
			     (hg < 0) ? "peer" : "this");
	}

	if (hg == -100) {
		/* FIXME this log message is not correct if we end up here
		 * after an attempted attach on a diskless node.
		 * We just refuse to attach -- well, we drop the "connection"
		 * to that disk, in a way... */
		dev_alert(DEV, "Split-Brain detected but unresolved, dropping connection!\n");
		drbd_khelper(mdev, "split-brain");
		return C_MASK;
	}

	if (hg > 0 && mydisk <= D_INCONSISTENT) {
		dev_err(DEV, "I shall become SyncSource, but I am inconsistent!\n");
		return C_MASK;
	}

	if (hg < 0 && /* by intention we do not use mydisk here. */
	    mdev->state.role == R_PRIMARY && mdev->state.disk >= D_CONSISTENT) {
		switch (mdev->net_conf->rr_conflict) {
		case ASB_CALL_HELPER:
			drbd_khelper(mdev, "pri-lost");
			/* fall through */
		case ASB_DISCONNECT:
			dev_err(DEV, "I shall become SyncTarget, but I am primary!\n");
			return C_MASK;
		case ASB_VIOLENTLY:
			dev_warn(DEV, "Becoming SyncTarget, violating the stable-data"
			     "assumption\n");
		}
	}

	if (mdev->net_conf->dry_run || test_bit(CONN_DRY_RUN, &mdev->flags)) {
		if (hg == 0)
			dev_info(DEV, "dry-run connect: No resync, would become Connected immediately.\n");
		else
			dev_info(DEV, "dry-run connect: Would become %s, doing a %s resync.",
				 drbd_conn_str(hg > 0 ? C_SYNC_SOURCE : C_SYNC_TARGET),
				 abs(hg) >= 2 ? "full" : "bit-map based");
		return C_MASK;
	}

	if (abs(hg) >= 2) {
		dev_info(DEV, "Writing the whole bitmap, full sync required after drbd_sync_handshake.\n");
		if (drbd_bitmap_io(mdev, &drbd_bmio_set_n_write, "set_n_write from sync_handshake"))
			return C_MASK;
	}

	if (hg > 0) { /* become sync source. */
		rv = C_WF_BITMAP_S;
	} else if (hg < 0) { /* become sync target */
		rv = C_WF_BITMAP_T;
	} else {
		rv = C_CONNECTED;
		if (drbd_bm_total_weight(mdev)) {
			dev_info(DEV, "No resync, but %lu bits in bitmap!\n",
			     drbd_bm_total_weight(mdev));
		}
	}

	return rv;
}

/* returns 1 if invalid */
static int cmp_after_sb(enum drbd_after_sb_p peer, enum drbd_after_sb_p self)
{
	/* ASB_DISCARD_REMOTE - ASB_DISCARD_LOCAL is valid */
	if ((peer == ASB_DISCARD_REMOTE && self == ASB_DISCARD_LOCAL) ||
	    (self == ASB_DISCARD_REMOTE && peer == ASB_DISCARD_LOCAL))
		return 0;

	/* any other things with ASB_DISCARD_REMOTE or ASB_DISCARD_LOCAL are invalid */
	if (peer == ASB_DISCARD_REMOTE || peer == ASB_DISCARD_LOCAL ||
	    self == ASB_DISCARD_REMOTE || self == ASB_DISCARD_LOCAL)
		return 1;

	/* everything else is valid if they are equal on both sides. */
	if (peer == self)
		return 0;

	/* everything es is invalid. */
	return 1;
}

static int receive_protocol(struct drbd_conf *mdev, enum drbd_packets cmd, unsigned int data_size)
{
	struct p_protocol *p = &mdev->data.rbuf.protocol;
	int p_proto, p_after_sb_0p, p_after_sb_1p, p_after_sb_2p;
	int p_want_lose, p_two_primaries, cf;
	char p_integrity_alg[SHARED_SECRET_MAX] = "";

	p_proto		= be32_to_cpu(p->protocol);
	p_after_sb_0p	= be32_to_cpu(p->after_sb_0p);
	p_after_sb_1p	= be32_to_cpu(p->after_sb_1p);
	p_after_sb_2p	= be32_to_cpu(p->after_sb_2p);
	p_two_primaries = be32_to_cpu(p->two_primaries);
	cf		= be32_to_cpu(p->conn_flags);
	p_want_lose = cf & CF_WANT_LOSE;

	clear_bit(CONN_DRY_RUN, &mdev->flags);

	if (cf & CF_DRY_RUN)
		set_bit(CONN_DRY_RUN, &mdev->flags);

	if (p_proto != mdev->net_conf->wire_protocol) {
		dev_err(DEV, "incompatible communication protocols\n");
		goto disconnect;
	}

	if (cmp_after_sb(p_after_sb_0p, mdev->net_conf->after_sb_0p)) {
		dev_err(DEV, "incompatible after-sb-0pri settings\n");
		goto disconnect;
	}

	if (cmp_after_sb(p_after_sb_1p, mdev->net_conf->after_sb_1p)) {
		dev_err(DEV, "incompatible after-sb-1pri settings\n");
		goto disconnect;
	}

	if (cmp_after_sb(p_after_sb_2p, mdev->net_conf->after_sb_2p)) {
		dev_err(DEV, "incompatible after-sb-2pri settings\n");
		goto disconnect;
	}

	if (p_want_lose && mdev->net_conf->want_lose) {
		dev_err(DEV, "both sides have the 'want_lose' flag set\n");
		goto disconnect;
	}

	if (p_two_primaries != mdev->net_conf->two_primaries) {
		dev_err(DEV, "incompatible setting of the two-primaries options\n");
		goto disconnect;
	}

	if (mdev->agreed_pro_version >= 87) {
		unsigned char *my_alg = mdev->net_conf->integrity_alg;

		if (drbd_recv(mdev, p_integrity_alg, data_size) != data_size)
			return FALSE;

		p_integrity_alg[SHARED_SECRET_MAX-1] = 0;
		if (strcmp(p_integrity_alg, my_alg)) {
			dev_err(DEV, "incompatible setting of the data-integrity-alg\n");
			goto disconnect;
		}
		dev_info(DEV, "data-integrity-alg: %s\n",
		     my_alg[0] ? my_alg : (unsigned char *)"<not-used>");
	}

	return TRUE;

disconnect:
	drbd_force_state(mdev, NS(conn, C_DISCONNECTING));
	return FALSE;
}

/* helper function
 * input: alg name, feature name
 * return: NULL (alg name was "")
 *         ERR_PTR(error) if something goes wrong
 *         or the crypto hash ptr, if it worked out ok. */
struct crypto_hash *drbd_crypto_alloc_digest_safe(const struct drbd_conf *mdev,
		const char *alg, const char *name)
{
	struct crypto_hash *tfm;

	if (!alg[0])
		return NULL;

	tfm = crypto_alloc_hash(alg, 0, CRYPTO_ALG_ASYNC);
	if (IS_ERR(tfm)) {
		dev_err(DEV, "Can not allocate \"%s\" as %s (reason: %ld)\n",
			alg, name, PTR_ERR(tfm));
		return tfm;
	}
	if (!drbd_crypto_is_hash(crypto_hash_tfm(tfm))) {
		crypto_free_hash(tfm);
		dev_err(DEV, "\"%s\" is not a digest (%s)\n", alg, name);
		return ERR_PTR(-EINVAL);
	}
	return tfm;
}

static int receive_SyncParam(struct drbd_conf *mdev, enum drbd_packets cmd, unsigned int packet_size)
{
	int ok = TRUE;
	struct p_rs_param_95 *p = &mdev->data.rbuf.rs_param_95;
	unsigned int header_size, data_size, exp_max_sz;
	struct crypto_hash *verify_tfm = NULL;
	struct crypto_hash *csums_tfm = NULL;
	const int apv = mdev->agreed_pro_version;
	int *rs_plan_s = NULL;
	int fifo_size = 0;

	exp_max_sz  = apv <= 87 ? sizeof(struct p_rs_param)
		    : apv == 88 ? sizeof(struct p_rs_param)
					+ SHARED_SECRET_MAX
		    : apv <= 94 ? sizeof(struct p_rs_param_89)
		    : /* apv >= 95 */ sizeof(struct p_rs_param_95);

	if (packet_size > exp_max_sz) {
		dev_err(DEV, "SyncParam packet too long: received %u, expected <= %u bytes\n",
		    packet_size, exp_max_sz);
		return FALSE;
	}

	if (apv <= 88) {
		header_size = sizeof(struct p_rs_param) - sizeof(struct p_header80);
		data_size   = packet_size  - header_size;
	} else if (apv <= 94) {
		header_size = sizeof(struct p_rs_param_89) - sizeof(struct p_header80);
		data_size   = packet_size  - header_size;
		D_ASSERT(data_size == 0);
	} else {
		header_size = sizeof(struct p_rs_param_95) - sizeof(struct p_header80);
		data_size   = packet_size  - header_size;
		D_ASSERT(data_size == 0);
	}

	/* initialize verify_alg and csums_alg */
	memset(p->verify_alg, 0, 2 * SHARED_SECRET_MAX);

	if (drbd_recv(mdev, &p->head.payload, header_size) != header_size)
		return FALSE;

	mdev->sync_conf.rate	  = be32_to_cpu(p->rate);

	if (apv >= 88) {
		if (apv == 88) {
			if (data_size > SHARED_SECRET_MAX) {
				dev_err(DEV, "verify-alg too long, "
				    "peer wants %u, accepting only %u byte\n",
						data_size, SHARED_SECRET_MAX);
				return FALSE;
			}