/*
* Copyright (C) Internet Systems Consortium, Inc. ("ISC")
*
* This Source Code Form is subject to the terms of the Mozilla Public
* License, v. 2.0. If a copy of the MPL was not distributed with this
* file, You can obtain one at http://mozilla.org/MPL/2.0/.
*
* See the COPYRIGHT file distributed with this work for additional
* information regarding copyright ownership.
*/
/* $Id$ */
/*
* This code implements the HMAC-SHA1, HMAC-SHA224, HMAC-SHA256, HMAC-SHA384
* and HMAC-SHA512 keyed hash algorithm described in RFC 2104 and
* draft-ietf-dnsext-tsig-sha-01.txt.
*/
#include "config.h"
#include <stdbool.h>
#include <isc/assertions.h>
#include <isc/hmacsha.h>
#include <isc/platform.h>
#include <isc/safe.h>
#include <isc/sha1.h>
#include <isc/sha2.h>
#include <isc/string.h>
#include <isc/types.h>
#include <isc/util.h>
#if PKCS11CRYPTO
#include <pk11/internal.h>
#include <pk11/pk11.h>
#endif
#ifdef ISC_PLATFORM_OPENSSLHASH
#if OPENSSL_VERSION_NUMBER < 0x10100000L || defined(LIBRESSL_VERSION_NUMBER)
#define HMAC_CTX_new() &(ctx->_ctx), HMAC_CTX_init(&(ctx->_ctx))
#define HMAC_CTX_free(ptr) HMAC_CTX_cleanup(ptr)
#endif
void
isc_hmacsha1_init(isc_hmacsha1_t *ctx, const unsigned char *key,
unsigned int len)
{
ctx->ctx = HMAC_CTX_new();
RUNTIME_CHECK(ctx->ctx != NULL);
RUNTIME_CHECK(HMAC_Init_ex(ctx->ctx, (const void *) key,
(int) len, EVP_sha1(), NULL) == 1);
}
void
isc_hmacsha1_invalidate(isc_hmacsha1_t *ctx) {
if (ctx->ctx == NULL)
return;
HMAC_CTX_free(ctx->ctx);
ctx->ctx = NULL;
}
void
isc_hmacsha1_update(isc_hmacsha1_t *ctx, const unsigned char *buf,
unsigned int len)
{
RUNTIME_CHECK(HMAC_Update(ctx->ctx, buf, (int) len) == 1);
}
void
isc_hmacsha1_sign(isc_hmacsha1_t *ctx, unsigned char *digest, size_t len) {
unsigned char newdigest[ISC_SHA1_DIGESTLENGTH];
REQUIRE(len <= ISC_SHA1_DIGESTLENGTH);
RUNTIME_CHECK(HMAC_Final(ctx->ctx, newdigest, NULL) == 1);
HMAC_CTX_free(ctx->ctx);
ctx->ctx = NULL;
memmove(digest, newdigest, len);
isc_safe_memwipe(newdigest, sizeof(newdigest));
}
void
isc_hmacsha224_init(isc_hmacsha224_t *ctx, const unsigned char *key,
unsigned int len)
{
ctx->ctx = HMAC_CTX_new();
RUNTIME_CHECK(ctx->ctx != NULL);
RUNTIME_CHECK(HMAC_Init_ex(ctx->ctx, (const void *) key,
(int) len, EVP_sha224(), NULL) == 1);
}
void
isc_hmacsha224_invalidate(isc_hmacsha224_t *ctx) {
if (ctx->ctx == NULL)
return;
HMAC_CTX_free(ctx->ctx);
ctx->ctx = NULL;
}
void
isc_hmacsha224_update(isc_hmacsha224_t *ctx, const unsigned char *buf,
unsigned int len)
{
RUNTIME_CHECK(HMAC_Update(ctx->ctx, buf, (int) len) == 1);
}
void
isc_hmacsha224_sign(isc_hmacsha224_t *ctx, unsigned char *digest, size_t len) {
unsigned char newdigest[ISC_SHA224_DIGESTLENGTH];
REQUIRE(len <= ISC_SHA224_DIGESTLENGTH);
RUNTIME_CHECK(HMAC_Final(ctx->ctx, newdigest, NULL) == 1);
HMAC_CTX_free(ctx->ctx);
ctx->ctx = NULL;
memmove(digest, newdigest, len);
isc_safe_memwipe(newdigest, sizeof(newdigest));
}
void
isc_hmacsha256_init(isc_hmacsha256_t *ctx, const unsigned char *key,
unsigned int len)
{
ctx->ctx = HMAC_CTX_new();
RUNTIME_CHECK(ctx->ctx != NULL);
RUNTIME_CHECK(HMAC_Init_ex(ctx->ctx, (const void *) key,
(int) len, EVP_sha256(), NULL) == 1);
}
void
isc_hmacsha256_invalidate(isc_hmacsha256_t *ctx) {
if (ctx->ctx == NULL)
return;
HMAC_CTX_free(ctx->ctx);
ctx->ctx = NULL;
}
void
isc_hmacsha256_update(isc_hmacsha256_t *ctx, const unsigned char *buf,
unsigned int len)
{
RUNTIME_CHECK(HMAC_Update(ctx->ctx, buf, (int) len) == 1);
}
void
isc_hmacsha256_sign(isc_hmacsha256_t *ctx, unsigned char *digest, size_t len) {
unsigned char newdigest[ISC_SHA256_DIGESTLENGTH];
REQUIRE(len <= ISC_SHA256_DIGESTLENGTH);
RUNTIME_CHECK(HMAC_Final(ctx->ctx, newdigest, NULL) == 1);
HMAC_CTX_free(ctx->ctx);
ctx->ctx = NULL;
memmove(digest, newdigest, len);
isc_safe_memwipe(newdigest, sizeof(newdigest));
}
void
isc_hmacsha384_init(isc_hmacsha384_t *ctx, const unsigned char *key,
unsigned int len)
{
ctx->ctx = HMAC_CTX_new();
RUNTIME_CHECK(ctx->ctx != NULL);
RUNTIME_CHECK(HMAC_Init_ex(ctx->ctx, (const void *) key,
(int) len, EVP_sha384(), NULL) == 1);
}
void
isc_hmacsha384_invalidate(isc_hmacsha384_t *ctx) {
if (ctx->ctx == NULL)
return;
HMAC_CTX_free(ctx->ctx);
ctx->ctx = NULL;
}
void
isc_hmacsha384_update(isc_hmacsha384_t *ctx, const unsigned char *buf,
unsigned int len)
{
RUNTIME_CHECK(HMAC_Update(ctx->ctx, buf, (int) len) == 1);
}
void
isc_hmacsha384_sign(isc_hmacsha384_t *ctx, unsigned char *digest, size_t len) {
unsigned char newdigest[ISC_SHA384_DIGESTLENGTH];
REQUIRE(len <= ISC_SHA384_DIGESTLENGTH);
RUNTIME_CHECK(HMAC_Final(ctx->ctx, newdigest, NULL) == 1);
HMAC_CTX_free(ctx->ctx);
ctx->ctx = NULL;
memmove(digest, newdigest, len);
isc_safe_memwipe(newdigest, sizeof(newdigest));
}
void
isc_hmacsha512_init(isc_hmacsha512_t *ctx, const unsigned char *key,
unsigned int len)
{
ctx->ctx = HMAC_CTX_new();
RUNTIME_CHECK(ctx->ctx != NULL);
RUNTIME_CHECK(HMAC_Init_ex(ctx->ctx, (const void *) key,
(int) len, EVP_sha512(), NULL) == 1);
}
void
isc_hmacsha512_invalidate(isc_hmacsha512_t *ctx) {
if (ctx->ctx == NULL)
return;
HMAC_CTX_free(ctx->ctx);
ctx->ctx = NULL;
}
void
isc_hmacsha512_update(isc_hmacsha512_t *ctx, const unsigned char *buf,
unsigned int len)
{
RUNTIME_CHECK(HMAC_Update(ctx->ctx, buf, (int) len) == 1);
}
void
isc_hmacsha512_sign(isc_hmacsha512_t *ctx, unsigned char *digest, size_t len) {
unsigned char newdigest[ISC_SHA512_DIGESTLENGTH];
REQUIRE(len <= ISC_SHA512_DIGESTLENGTH);
RUNTIME_CHECK(HMAC_Final(ctx->ctx, newdigest, NULL) == 1);
HMAC_CTX_free(ctx->ctx);
ctx->ctx = NULL;
memmove(digest, newdigest, len);
isc_safe_memwipe(newdigest, sizeof(newdigest));
}
#elif PKCS11CRYPTO
#if defined(PK11_SHA_1_HMAC_REPLACE) || \
defined(PK11_SHA224_HMAC_REPLACE) || \
defined(PK11_SHA256_HMAC_REPLACE) || \
defined(PK11_SHA384_HMAC_REPLACE) || \
defined(PK11_SHA512_HMAC_REPLACE)
#define IPAD 0x36
#define OPAD 0x5C
#endif
#if !defined(PK11_SHA_1_HMAC_REPLACE) && \
!defined(PK11_SHA224_HMAC_REPLACE) && \
!defined(PK11_SHA256_HMAC_REPLACE) && \
!defined(PK11_SHA384_HMAC_REPLACE) && \
!defined(PK11_SHA512_HMAC_REPLACE)
static CK_BBOOL truevalue = TRUE;
static CK_BBOOL falsevalue = FALSE;
#endif
#ifndef PK11_SHA_1_HMAC_REPLACE
void
isc_hmacsha1_init(isc_hmacsha1_t *ctx, const unsigned char *key,
unsigned int len)
{
CK_RV rv;
CK_MECHANISM mech = { CKM_SHA_1_HMAC, NULL, 0 };
CK_OBJECT_CLASS keyClass = CKO_SECRET_KEY;
CK_KEY_TYPE keyType = CKK_SHA_1_HMAC;
CK_ATTRIBUTE keyTemplate[] =
{
{ CKA_CLASS, &keyClass, (CK_ULONG) sizeof(keyClass) },
{ CKA_KEY_TYPE, &keyType, (CK_ULONG) sizeof(keyType) },
{ CKA_TOKEN, &falsevalue, (CK_ULONG) sizeof(falsevalue) },
{ CKA_PRIVATE, &falsevalue, (CK_ULONG) sizeof(falsevalue) },
{ CKA_SIGN, &truevalue, (CK_ULONG) sizeof(truevalue) },
{ CKA_VALUE, NULL, (CK_ULONG) len }
};
#ifdef PK11_PAD_HMAC_KEYS
CK_BYTE keypad[ISC_SHA1_DIGESTLENGTH];
if (len < ISC_SHA1_DIGESTLENGTH) {
memset(keypad, 0, ISC_SHA1_DIGESTLENGTH);
memmove(keypad, key, len);
keyTemplate[5].pValue = keypad;
keyTemplate[5].ulValueLen = ISC_SHA1_DIGESTLENGTH;
} else
DE_CONST(key, keyTemplate[5].pValue);
#else
DE_CONST(key, keyTemplate[5].pValue);
#endif
RUNTIME_CHECK(pk11_get_session(ctx, OP_DIGEST, true, false,
false, NULL, 0) == ISC_R_SUCCESS);
ctx->object = CK_INVALID_HANDLE;
PK11_FATALCHECK(pkcs_C_CreateObject,
(ctx->session, keyTemplate,
(CK_ULONG) 6, &ctx->object));
INSIST(ctx->object != CK_INVALID_HANDLE);
PK11_FATALCHECK(pkcs_C_SignInit, (ctx->session, &mech, ctx->object));
}
void
isc_hmacsha1_invalidate(isc_hmacsha1_t *ctx) {
CK_BYTE garbage[ISC_SHA1_DIGESTLENGTH];
CK_ULONG len = ISC_SHA1_DIGESTLENGTH;
if (ctx->handle == NULL)
return;
(void) pkcs_C_SignFinal(ctx->session, garbage, &len);
isc_safe_memwipe(garbage, sizeof(garbage));
if (ctx->object != CK_INVALID_HANDLE)
(void) pkcs_C_DestroyObject(ctx->session, ctx->object);
ctx->object = CK_INVALID_HANDLE;
pk11_return_session(ctx);
}
void
isc_hmacsha1_update(isc_hmacsha1_t *ctx, const unsigned char *buf,
unsigned int len)
{
CK_RV rv;
CK_BYTE_PTR pPart;
DE_CONST(buf, pPart);
PK11_FATALCHECK(pkcs_C_SignUpdate,
(ctx->session, pPart, (CK_ULONG) len));
}
void
isc_hmacsha1_sign(isc_hmacsha1_t *ctx, unsigned char *digest, size_t len) {
CK_RV rv;
CK_BYTE newdigest[ISC_SHA1_DIGESTLENGTH];
CK_ULONG psl = ISC_SHA1_DIGESTLENGTH;
REQUIRE(len <= ISC_SHA1_DIGESTLENGTH);
PK11_FATALCHECK(pkcs_C_SignFinal, (ctx->session, newdigest, &psl));
if (ctx->object != CK_INVALID_HANDLE)
(void) pkcs_C_DestroyObject(ctx->session, ctx->object);
ctx->object = CK_INVALID_HANDLE;
pk11_return_session(ctx);
memmove(digest, newdigest, len);
isc_safe_memwipe(newdigest, sizeof(newdigest));
}
#else
void
isc_hmacsha1_init(isc_hmacsha1_t *ctx, const unsigned char *key,
unsigned int len)
{
CK_RV rv;
CK_MECHANISM mech = { CKM_SHA_1, NULL, 0 };
unsigned char ipad[ISC_SHA1_BLOCK_LENGTH];
unsigned int i;
RUNTIME_CHECK(pk11_get_session(ctx, OP_DIGEST, true, false,
false, NULL, 0) == ISC_R_SUCCESS);
RUNTIME_CHECK((ctx->key = pk11_mem_get(ISC_SHA1_BLOCK_LENGTH))
!= NULL);
if (len > ISC_SHA1_BLOCK_LENGTH) {
CK_BYTE_PTR kPart;
CK_ULONG kl;
PK11_FATALCHECK(pkcs_C_DigestInit, (ctx->session, &mech));
DE_CONST(key, kPart);
PK11_FATALCHECK(pkcs_C_DigestUpdate,
(ctx->session, kPart, (CK_ULONG) len));
kl = ISC_SHA1_DIGESTLENGTH;
PK11_FATALCHECK(pkcs_C_DigestFinal,
(ctx->session, (CK_BYTE_PTR) ctx->key, &kl));
} else
memmove(ctx->key, key, len);
PK11_FATALCHECK(pkcs_C_DigestInit, (ctx->session, &mech));
memset(ipad, IPAD, ISC_SHA1_BLOCK_LENGTH);
for (i = 0; i < ISC_SHA1_BLOCK_LENGTH; i++)
ipad[i] ^= ctx->key[i];
PK11_FATALCHECK(pkcs_C_DigestUpdate,
(ctx->session, ipad,
(CK_ULONG) ISC_SHA1_BLOCK_LENGTH));
}
void
isc_hmacsha1_invalidate(isc_hmacsha1_t *ctx) {
if (ctx->key != NULL)
pk11_mem_put(ctx->key, ISC_SHA1_BLOCK_LENGTH);
ctx->key = NULL;
isc_sha1_invalidate(ctx);
}
void
isc_hmacsha1_update(isc_hmacsha1_t *ctx, const unsigned char *buf,
unsigned int len)
{
CK_RV rv;
CK_BYTE_PTR pPart;
DE_CONST(buf, pPart);
PK11_FATALCHECK(pkcs_C_DigestUpdate,
(ctx->session, pPart, (CK_ULONG) len));
}
void
isc_hmacsha1_sign(isc_hmacsha1_t *ctx, unsigned char *digest, size_t len) {
CK_RV rv;
CK_BYTE newdigest[ISC_SHA1_DIGESTLENGTH];
CK_ULONG psl = ISC_SHA1_DIGESTLENGTH;
CK_MECHANISM mech = { CKM_SHA_1, NULL, 0 };
CK_BYTE opad[ISC_SHA1_BLOCK_LENGTH];
unsigned int i;
REQUIRE(len <= ISC_SHA1_DIGESTLENGTH);
PK11_FATALCHECK(pkcs_C_DigestFinal, (ctx->session, newdigest, &psl));
memset(opad, OPAD, ISC_SHA1_BLOCK_LENGTH);
for (i = 0; i < ISC_SHA1_BLOCK_LENGTH; i++)
opad[i] ^= ctx->key[i];
pk11_mem_put(ctx->key, ISC_SHA1_BLOCK_LENGTH);
ctx->key = NULL;
PK11_FATALCHECK(pkcs_C_DigestInit, (ctx->session, &mech));
PK11_FATALCHECK(pkcs_C_DigestUpdate,
(ctx->session, opad,
(CK_ULONG) ISC_SHA1_BLOCK_LENGTH));
PK11_FATALCHECK(pkcs_C_DigestUpdate,
(ctx->session, (CK_BYTE_PTR) newdigest, psl));
PK11_FATALCHECK(pkcs_C_DigestFinal, (ctx->session, newdigest, &psl));
pk11_return_session(ctx);
memmove(digest, newdigest, len);
isc_safe_memwipe(newdigest, sizeof(newdigest));
}
#endif
#ifndef PK11_SHA224_HMAC_REPLACE
void
isc_hmacsha224_init(isc_hmacsha224_t *ctx, const unsigned char *key,
unsigned int len)
{
CK_RV rv;
CK_MECHANISM mech = { CKM_SHA224_HMAC, NULL, 0 };
CK_OBJECT_CLASS keyClass = CKO_SECRET_KEY;
CK_KEY_TYPE keyType = CKK_SHA224_HMAC;
CK_ATTRIBUTE keyTemplate[] =
{
{ CKA_CLASS, &keyClass, (CK_ULONG) sizeof(keyClass) },
{ CKA_KEY_TYPE, &keyType, (CK_ULONG) sizeof(keyType) },
{ CKA_TOKEN, &falsevalue, (CK_ULONG) sizeof(falsevalue) },
{ CKA_PRIVATE, &falsevalue, (CK_ULONG) sizeof(falsevalue) },
{ CKA_SIGN, &truevalue, (CK_ULONG) sizeof(truevalue) },
{ CKA_VALUE, NULL, (CK_ULONG) len }
};
#ifdef PK11_PAD_HMAC_KEYS
CK_BYTE keypad[ISC_SHA224_DIGESTLENGTH];
if (len < ISC_SHA224_DIGESTLENGTH) {
memset(keypad, 0, ISC_SHA224_DIGESTLENGTH);
memmove(keypad, key, len);
keyTemplate[5].pValue = keypad;
keyTemplate[5].ulValueLen = ISC_SHA224_DIGESTLENGTH;
} else
DE_CONST(key, keyTemplate[5].pValue);
#else
DE_CONST(key, keyTemplate[5].pValue);
#endif
RUNTIME_CHECK(pk11_get_session(ctx, OP_DIGEST, true, false,
false, NULL, 0) == ISC_R_SUCCESS);
ctx->object = CK_INVALID_HANDLE;
PK11_FATALCHECK(pkcs_C_CreateObject,
(ctx->session, keyTemplate,
(CK_ULONG) 6, &ctx->object));
INSIST(ctx->object != CK_INVALID_HANDLE);
PK11_FATALCHECK(pkcs_C_SignInit, (ctx->session, &mech, ctx->object));
}
void
isc_hmacsha224_invalidate(isc_hmacsha224_t *ctx) {
CK_BYTE garbage[ISC_SHA224_DIGESTLENGTH];
CK_ULONG len = ISC_SHA224_DIGESTLENGTH;
if (ctx->handle == NULL)
return;
(void) pkcs_C_SignFinal(ctx->session, garbage, &len);
isc_safe_memwipe(garbage, sizeof(garbage));
if (ctx->object != CK_INVALID_HANDLE)
(void) pkcs_C_DestroyObject(ctx->session, ctx->object);
ctx->object = CK_INVALID_HANDLE;
pk11_return_session(ctx);
}
void
isc_hmacsha224_update(isc_hmacsha224_t *ctx, const unsigned char *buf,
unsigned int len)
{
CK_RV rv;
CK_BYTE_PTR pPart;
DE_CONST(buf, pPart);
PK11_FATALCHECK(pkcs_C_SignUpdate,
(ctx->session, pPart, (CK_ULONG) len));
}
void
isc_hmacsha224_sign(isc_hmacsha224_t *ctx, unsigned char *digest, size_t len) {
CK_RV rv;
CK_BYTE newdigest[ISC_SHA224_DIGESTLENGTH];
CK_ULONG psl = ISC_SHA224_DIGESTLENGTH;
REQUIRE(len <= ISC_SHA224_DIGESTLENGTH);
PK11_FATALCHECK(pkcs_C_SignFinal, (ctx->session, newdigest, &psl));
if (ctx->object != CK_INVALID_HANDLE)
(void) pkcs_C_DestroyObject(ctx->session, ctx->object);
ctx->object = CK_INVALID_HANDLE;
pk11_return_session(ctx);
memmove(digest, newdigest, len);
isc_safe_memwipe(newdigest, sizeof(newdigest));
}
#else
void
isc_hmacsha224_init(isc_hmacsha224_t *ctx, const unsigned char *key,
unsigned int len)
{
CK_RV rv;
CK_MECHANISM mech = { CKM_SHA224, NULL, 0 };
unsigned char ipad[ISC_SHA224_BLOCK_LENGTH];
unsigned int i;
RUNTIME_CHECK(pk11_get_session(ctx, OP_DIGEST, true, false,
false, NULL, 0) == ISC_R_SUCCESS);
RUNTIME_CHECK((ctx->key = pk11_mem_get(ISC_SHA224_BLOCK_LENGTH))
!= NULL);
if (len > ISC_SHA224_BLOCK_LENGTH) {
CK_BYTE_PTR kPart;
CK_ULONG kl;
PK11_FATALCHECK(pkcs_C_DigestInit, (ctx->session, &mech));
DE_CONST(key, kPart);
PK11_FATALCHECK(pkcs_C_DigestUpdate,
(ctx->session, kPart, (CK_ULONG) len));
kl = ISC_SHA224_DIGESTLENGTH;
PK11_FATALCHECK(pkcs_C_DigestFinal,
(ctx->session, (CK_BYTE_PTR) ctx->key, &kl));
} else
memmove(ctx->key, key, len);
PK11_FATALCHECK(pkcs_C_DigestInit, (ctx->session, &mech));
memset(ipad, IPAD, ISC_SHA224_BLOCK_LENGTH);
for (i = 0; i < ISC_SHA224_BLOCK_LENGTH; i++)
ipad[i] ^= ctx->key[i];
PK11_FATALCHECK(pkcs_C_DigestUpdate,
(ctx->session, ipad,
(CK_ULONG) ISC_SHA224_BLOCK_LENGTH));
}
void
isc_hmacsha224_invalidate(isc_hmacsha224_t *ctx) {
if (ctx->key != NULL)
pk11_mem_put(ctx->key, ISC_SHA224_BLOCK_LENGTH);
ctx->key = NULL;
isc_sha224_invalidate(ctx);
}
void
isc_hmacsha224_update(isc_hmacsha224_t *ctx, const unsigned char *buf,
unsigned int len)
{
CK_RV rv;
CK_BYTE_PTR pPart;
DE_CONST(buf, pPart);
PK11_FATALCHECK(pkcs_C_DigestUpdate,
(ctx->session, pPart, (CK_ULONG) len));
}
void
isc_hmacsha224_sign(isc_hmacsha224_t *ctx, unsigned char *digest, size_t len) {
CK_RV rv;
CK_BYTE newdigest[ISC_SHA224_DIGESTLENGTH];
CK_ULONG psl = ISC_SHA224_DIGESTLENGTH;
CK_MECHANISM mech = { CKM_SHA224, NULL, 0 };
CK_BYTE opad[ISC_SHA224_BLOCK_LENGTH];
unsigned int i;
REQUIRE(len <= ISC_SHA224_DIGESTLENGTH);
PK11_FATALCHECK(pkcs_C_DigestFinal, (ctx->session, newdigest, &psl));
memset(opad, OPAD, ISC_SHA224_BLOCK_LENGTH);
for (i = 0; i < ISC_SHA224_BLOCK_LENGTH; i++)
opad[i] ^= ctx->key[i];
pk11_mem_put(ctx->key, ISC_SHA224_BLOCK_LENGTH);
ctx->key = NULL;
PK11_FATALCHECK(pkcs_C_DigestInit, (ctx->session, &mech));
PK11_FATALCHECK(pkcs_C_DigestUpdate,
(ctx->session, opad,
(CK_ULONG) ISC_SHA224_BLOCK_LENGTH));
PK11_FATALCHECK(pkcs_C_DigestUpdate,
(ctx->session, (CK_BYTE_PTR) newdigest, psl));
PK11_FATALCHECK(pkcs_C_DigestFinal, (ctx->session, newdigest, &psl));
pk11_return_session(ctx);
memmove(digest, newdigest, len);
isc_safe_memwipe(newdigest, sizeof(newdigest));
}
#endif
#ifndef PK11_SHA256_HMAC_REPLACE
void
isc_hmacsha256_init(isc_hmacsha256_t *ctx, const unsigned char *key,
unsigned int len)
{
CK_RV rv;
CK_MECHANISM mech = { CKM_SHA256_HMAC, NULL, 0 };
CK_OBJECT_CLASS keyClass = CKO_SECRET_KEY;
CK_KEY_TYPE keyType = CKK_SHA256_HMAC;
CK_ATTRIBUTE keyTemplate[] =
{
{ CKA_CLASS, &keyClass, (CK_ULONG) sizeof(keyClass) },
{ CKA_KEY_TYPE, &keyType, (CK_ULONG) sizeof(keyType) },
{ CKA_TOKEN, &falsevalue, (CK_ULONG) sizeof(falsevalue) },
{ CKA_PRIVATE, &falsevalue, (CK_ULONG) sizeof(falsevalue) },
{ CKA_SIGN, &truevalue, (CK_ULONG) sizeof(truevalue) },
{ CKA_VALUE, NULL, (CK_ULONG) len }
};
#ifdef PK11_PAD_HMAC_KEYS
CK_BYTE keypad[ISC_SHA256_DIGESTLENGTH];
if (len < ISC_SHA256_DIGESTLENGTH) {
memset(keypad, 0, ISC_SHA256_DIGESTLENGTH);
memmove(keypad, key, len);
keyTemplate[5].pValue = keypad;
keyTemplate[5].ulValueLen = ISC_SHA256_DIGESTLENGTH;
} else
DE_CONST(key, keyTemplate[5].pValue);
#else
DE_CONST(key, keyTemplate[5].pValue);
#endif
RUNTIME_CHECK(pk11_get_session(ctx, OP_DIGEST, true, false,
false, NULL, 0) == ISC_R_SUCCESS);
ctx->object = CK_INVALID_HANDLE;
PK11_FATALCHECK(pkcs_C_CreateObject,
(ctx->session, keyTemplate,
(CK_ULONG) 6, &ctx->object));
INSIST(ctx->object != CK_INVALID_HANDLE);
PK11_FATALCHECK(pkcs_C_SignInit, (ctx->session, &mech, ctx->object));
}
void
isc_hmacsha256_invalidate(isc_hmacsha256_t *ctx) {
CK_BYTE garbage[ISC_SHA256_DIGESTLENGTH];
CK_ULONG len = ISC_SHA256_DIGESTLENGTH;
if (ctx->handle == NULL)
return;
(void) pkcs_C_SignFinal(ctx->session, garbage, &len);
isc_safe_memwipe(garbage, sizeof(garbage));
if (ctx->object != CK_INVALID_HANDLE)
(void) pkcs_C_DestroyObject(ctx->session, ctx->object);
ctx->object = CK_INVALID_HANDLE;
pk11_return_session(ctx);
}
void
isc_hmacsha256_update(isc_hmacsha256_t *ctx, const unsigned char *buf,
unsigned int len)
{
CK_RV rv;
CK_BYTE_PTR pPart;
DE_CONST(buf, pPart);
PK11_FATALCHECK(pkcs_C_SignUpdate,
(ctx->session, pPart, (CK_ULONG) len));
}
void
isc_hmacsha256_sign(isc_hmacsha256_t *ctx, unsigned char *digest, size_t len) {
CK_RV rv;
CK_BYTE newdigest[ISC_SHA256_DIGESTLENGTH];
CK_ULONG psl = ISC_SHA256_DIGESTLENGTH;
REQUIRE(len <= ISC_SHA256_DIGESTLENGTH);
PK11_FATALCHECK(pkcs_C_SignFinal, (ctx->session, newdigest, &psl));
if (ctx->object != CK_INVALID_HANDLE)
(void) pkcs_C_DestroyObject(ctx->session, ctx->object);
ctx->object = CK_INVALID_HANDLE;
pk11_return_session(ctx);
memmove(digest, newdigest, len);
isc_safe_memwipe(newdigest, sizeof(newdigest));
}
#else
void
isc_hmacsha256_init(isc_hmacsha256_t *ctx, const unsigned char *key,
unsigned int len)
{
CK_RV rv;
CK_MECHANISM mech = { CKM_SHA256, NULL, 0 };
unsigned char ipad[ISC_SHA256_BLOCK_LENGTH];
unsigned int i;
RUNTIME_CHECK(pk11_get_session(ctx, OP_DIGEST, true, false,
false, NULL, 0) == ISC_R_SUCCESS);
RUNTIME_CHECK((ctx->key = pk11_mem_get(ISC_SHA256_BLOCK_LENGTH))
!= NULL);
if (len > ISC_SHA256_BLOCK_LENGTH) {
CK_BYTE_PTR kPart;
CK_ULONG kl;
PK11_FATALCHECK(pkcs_C_DigestInit, (ctx->session, &mech));
DE_CONST(key, kPart);
PK11_FATALCHECK(pkcs_C_DigestUpdate,
(ctx->session, kPart, (CK_ULONG) len));
kl = ISC_SHA256_DIGESTLENGTH;
PK11_FATALCHECK(pkcs_C_DigestFinal,
(ctx->session, (CK_BYTE_PTR) ctx->key, &kl));
} else
memmove(ctx->key, key, len);
PK11_FATALCHECK(pkcs_C_DigestInit, (ctx->session, &mech));
memset(ipad, IPAD, ISC_SHA256_BLOCK_LENGTH);
for (i = 0; i < ISC_SHA256_BLOCK_LENGTH; i++)
ipad[i] ^= ctx->key[i];
PK11_FATALCHECK(pkcs_C_DigestUpdate,
(ctx->session, ipad,
(CK_ULONG) ISC_SHA256_BLOCK_LENGTH));
}
void
isc_hmacsha256_invalidate(isc_hmacsha256_t *ctx) {
if (ctx->key != NULL)
pk11_mem_put(ctx->key, ISC_SHA256_BLOCK_LENGTH);
ctx->key = NULL;
isc_sha256_invalidate(ctx);
}
void
isc_hmacsha256_update(isc_hmacsha256_t *ctx, const unsigned char *buf,
unsigned int len)
{
CK_RV rv;
CK_BYTE_PTR pPart;
DE_CONST(buf, pPart);
PK11_FATALCHECK(pkcs_C_DigestUpdate,
(ctx->session, pPart, (CK_ULONG) len));
}
void
isc_hmacsha256_sign(isc_hmacsha256_t *ctx, unsigned char *digest, size_t len) {
CK_RV rv;
CK_BYTE newdigest[ISC_SHA256_DIGESTLENGTH];
CK_ULONG psl = ISC_SHA256_DIGESTLENGTH;
CK_MECHANISM mech = { CKM_SHA256, NULL, 0 };
CK_BYTE opad[ISC_SHA256_BLOCK_LENGTH];
unsigned int i;
REQUIRE(len <= ISC_SHA256_DIGESTLENGTH);
PK11_FATALCHECK(pkcs_C_DigestFinal, (ctx->session, newdigest, &psl));
memset(opad, OPAD, ISC_SHA256_BLOCK_LENGTH);
for (i = 0; i < ISC_SHA256_BLOCK_LENGTH; i++)
opad[i] ^= ctx->key[i];
pk11_mem_put(ctx->key, ISC_SHA256_BLOCK_LENGTH);
ctx->key = NULL;
PK11_FATALCHECK(pkcs_C_DigestInit, (ctx->session, &mech));
PK11_FATALCHECK(pkcs_C_DigestUpdate,
(ctx->session, opad,
(CK_ULONG) ISC_SHA256_BLOCK_LENGTH));
PK11_FATALCHECK(pkcs_C_DigestUpdate,
(ctx->session, (CK_BYTE_PTR) newdigest, psl));
PK11_FATALCHECK(pkcs_C_DigestFinal, (ctx->session, newdigest, &psl));
pk11_return_session(ctx);
memmove(digest, newdigest, len);
isc_safe_memwipe(newdigest, sizeof(newdigest));
}
#endif
#ifndef PK11_SHA384_HMAC_REPLACE
void
isc_hmacsha384_init(isc_hmacsha384_t *ctx, const unsigned char *key,
unsigned int len)
{
CK_RV rv;
CK_MECHANISM mech = { CKM_SHA384_HMAC, NULL, 0 };
CK_OBJECT_CLASS keyClass = CKO_SECRET_KEY;
CK_KEY_TYPE keyType = CKK_SHA384_HMAC;
CK_ATTRIBUTE keyTemplate[] =
{
{ CKA_CLASS, &keyClass, (CK_ULONG) sizeof(keyClass) },
{ CKA_KEY_TYPE, &keyType, (CK_ULONG) sizeof(keyType) },
{ CKA_TOKEN, &falsevalue, (CK_ULONG) sizeof(falsevalue) },
{ CKA_PRIVATE, &falsevalue, (CK_ULONG) sizeof(falsevalue) },
{ CKA_SIGN, &truevalue, (CK_ULONG) sizeof(truevalue) },
{ CKA_VALUE, NULL, (CK_ULONG) len }
};
#ifdef PK11_PAD_HMAC_KEYS
CK_BYTE keypad[ISC_SHA384_DIGESTLENGTH];
if (len < ISC_SHA384_DIGESTLENGTH) {
memset(keypad, 0, ISC_SHA384_DIGESTLENGTH);
memmove(keypad, key, len);
keyTemplate[5].pValue = keypad;
keyTemplate[5].ulValueLen = ISC_SHA384_DIGESTLENGTH;
} else
DE_CONST(key, keyTemplate[5].pValue);
#else
DE_CONST(key, keyTemplate[5].pValue);
#endif
RUNTIME_CHECK(pk11_get_session(ctx, OP_DIGEST, true, false,
false, NULL, 0) == ISC_R_SUCCESS);
ctx->object = CK_INVALID_HANDLE;
PK11_FATALCHECK(pkcs_C_CreateObject,
(ctx->session, keyTemplate,
(CK_ULONG) 6, &ctx->object));
INSIST(ctx->object != CK_INVALID_HANDLE);
PK11_FATALCHECK(pkcs_C_SignInit, (ctx->session, &mech, ctx->object));
}
void
isc_hmacsha384_invalidate(isc_hmacsha384_t *ctx) {
CK_BYTE garbage[ISC_SHA384_DIGESTLENGTH];
CK_ULONG len = ISC_SHA384_DIGESTLENGTH;
if (ctx->handle == NULL)
return;
(void) pkcs_C_SignFinal(ctx->session, garbage, &len);
isc_safe_memwipe(garbage, sizeof(garbage));
if (ctx->object != CK_INVALID_HANDLE)
(void) pkcs_C_DestroyObject(ctx->session, ctx->object);
ctx->object = CK_INVALID_HANDLE;
pk11_return_session(ctx);
}
void
isc_hmacsha384_update(isc_hmacsha384_t *ctx, const unsigned char *buf,
unsigned int len)
{
CK_RV rv;
CK_BYTE_PTR pPart;
DE_CONST(buf, pPart);
PK11_FATALCHECK(pkcs_C_SignUpdate,
(ctx->session, pPart, (CK_ULONG) len));
}
void
isc_hmacsha384_sign(isc_hmacsha384_t *ctx, unsigned char *digest, size_t len) {
CK_RV rv;
CK_BYTE newdigest[ISC_SHA384_DIGESTLENGTH];
CK_ULONG psl = ISC_SHA384_DIGESTLENGTH;
REQUIRE(len <= ISC_SHA384_DIGESTLENGTH);
PK11_FATALCHECK(pkcs_C_SignFinal, (ctx->session, newdigest, &psl));
if (ctx->object != CK_INVALID_HANDLE)
(void) pkcs_C_DestroyObject(ctx->session, ctx->object);
ctx->object = CK_INVALID_HANDLE;
pk11_return_session(ctx);
memmove(digest, newdigest, len);
isc_safe_memwipe(newdigest, sizeof(newdigest));
}
#else
void
isc_hmacsha384_init(isc_hmacsha384_t *ctx, const unsigned char *key,
unsigned int len)
{
CK_RV rv;
CK_MECHANISM mech = { CKM_SHA384, NULL, 0 };
unsigned char ipad[ISC_SHA384_BLOCK_LENGTH];
unsigned int i;
RUNTIME_CHECK(pk11_get_session(ctx, OP_DIGEST, true, false,
false, NULL, 0) == ISC_R_SUCCESS);
RUNTIME_CHECK((ctx->key = pk11_mem_get(ISC_SHA384_BLOCK_LENGTH))
!= NULL);
if (len > ISC_SHA384_BLOCK_LENGTH) {
CK_BYTE_PTR kPart;
CK_ULONG kl;
PK11_FATALCHECK(pkcs_C_DigestInit, (ctx->session, &mech));
DE_CONST(key, kPart);
PK11_FATALCHECK(pkcs_C_DigestUpdate,
(ctx->session, kPart, (CK_ULONG) len));
kl = ISC_SHA384_DIGESTLENGTH;
PK11_FATALCHECK(pkcs_C_DigestFinal,
(ctx->session, (CK_BYTE_PTR) ctx->key, &kl));
} else
memmove(ctx->key, key, len);
PK11_FATALCHECK(pkcs_C_DigestInit, (ctx->session, &mech));
memset(ipad, IPAD, ISC_SHA384_BLOCK_LENGTH);
for (i = 0; i < ISC_SHA384_BLOCK_LENGTH; i++)
ipad[i] ^= ctx->key[i];
PK11_FATALCHECK(pkcs_C_DigestUpdate,
(ctx->session, ipad,
(CK_ULONG) ISC_SHA384_BLOCK_LENGTH));
}
void
isc_hmacsha384_invalidate(isc_hmacsha384_t *ctx) {
if (ctx->key != NULL)
pk11_mem_put(ctx->key, ISC_SHA384_BLOCK_LENGTH);
ctx->key = NULL;
isc_sha384_invalidate(ctx);
}
void
isc_hmacsha384_update(isc_hmacsha384_t *ctx, const unsigned char *buf,
unsigned int len)
{
CK_RV rv;
CK_BYTE_PTR pPart;
DE_CONST(buf, pPart);
PK11_FATALCHECK(pkcs_C_DigestUpdate,
(ctx->session, pPart, (CK_ULONG) len));
}
void
isc_hmacsha384_sign(isc_hmacsha384_t *ctx, unsigned char *digest, size_t len) {
CK_RV rv;
CK_BYTE newdigest[ISC_SHA384_DIGESTLENGTH];
CK_ULONG psl = ISC_SHA384_DIGESTLENGTH;
CK_MECHANISM mech = { CKM_SHA384, NULL, 0 };
CK_BYTE opad[ISC_SHA384_BLOCK_LENGTH];
unsigned int i;
REQUIRE(len <= ISC_SHA384_DIGESTLENGTH);
PK11_FATALCHECK(pkcs_C_DigestFinal, (ctx->session, newdigest, &psl));
memset(opad, OPAD, ISC_SHA384_BLOCK_LENGTH);
for (i = 0; i < ISC_SHA384_BLOCK_LENGTH; i++)
opad[i] ^= ctx->key[i];
pk11_mem_put(ctx->key, ISC_SHA384_BLOCK_LENGTH);
ctx->key = NULL;
PK11_FATALCHECK(pkcs_C_DigestInit, (ctx->session, &mech));
PK11_FATALCHECK(pkcs_C_DigestUpdate,
(ctx->session, opad,
(CK_ULONG) ISC_SHA384_BLOCK_LENGTH));
PK11_FATALCHECK(pkcs_C_DigestUpdate,
(ctx->session, (CK_BYTE_PTR) newdigest, psl));
PK11_FATALCHECK(pkcs_C_DigestFinal, (ctx->session, newdigest, &psl));
pk11_return_session(ctx);
memmove(digest, newdigest, len);
isc_safe_memwipe(newdigest, sizeof(newdigest));
}
#endif
#ifndef PK11_SHA512_HMAC_REPLACE
void
isc_hmacsha512_init(isc_hmacsha512_t *ctx, const unsigned char *key,
unsigned int len)
{
CK_RV rv;
CK_MECHANISM mech = { CKM_SHA512_HMAC, NULL, 0 };
CK_OBJECT_CLASS keyClass = CKO_SECRET_KEY;
CK_KEY_TYPE keyType = CKK_SHA512_HMAC;
CK_ATTRIBUTE keyTemplate[] =
{
{ CKA_CLASS, &keyClass, (CK_ULONG) sizeof(keyClass) },
{ CKA_KEY_TYPE, &keyType, (CK_ULONG) sizeof(keyType) },
{ CKA_TOKEN, &falsevalue, (CK_ULONG) sizeof(falsevalue) },
{ CKA_PRIVATE, &falsevalue, (CK_ULONG) sizeof(falsevalue) },
{ CKA_SIGN, &truevalue, (CK_ULONG) sizeof(truevalue) },
{ CKA_VALUE, NULL, (CK_ULONG) len }
};
#ifdef PK11_PAD_HMAC_KEYS
CK_BYTE keypad[ISC_SHA512_DIGESTLENGTH];
if (len < ISC_SHA512_DIGESTLENGTH) {
memset(keypad, 0, ISC_SHA512_DIGESTLENGTH);
memmove(keypad, key, len);
keyTemplate[5].pValue = keypad;
keyTemplate[5].ulValueLen = ISC_SHA512_DIGESTLENGTH;
} else
DE_CONST(key, keyTemplate[5].pValue);
#else
DE_CONST(key, keyTemplate[5].pValue);
#endif
RUNTIME_CHECK(pk11_get_session(ctx, OP_DIGEST, true, false,
false, NULL, 0) == ISC_R_SUCCESS);
ctx->object = CK_INVALID_HANDLE;
PK11_FATALCHECK(pkcs_C_CreateObject,
(ctx->session, keyTemplate,
(CK_ULONG) 6, &ctx->object));
INSIST(ctx->object != CK_INVALID_HANDLE);
PK11_FATALCHECK(pkcs_C_SignInit, (ctx->session, &mech, ctx->object));
}
void
isc_hmacsha512_invalidate(isc_hmacsha512_t *ctx) {
CK_BYTE garbage[ISC_SHA512_DIGESTLENGTH];
CK_ULONG len = ISC_SHA512_DIGESTLENGTH;
if (ctx->handle == NULL)
return;
(void) pkcs_C_SignFinal(ctx->session, garbage, &len);
isc_safe_memwipe(garbage, sizeof(garbage));
if (ctx->object != CK_INVALID_HANDLE)
(void) pkcs_C_DestroyObject(ctx->session, ctx->object);
ctx->object = CK_INVALID_HANDLE;
pk11_return_session(ctx);
}
void
isc_hmacsha512_update(isc_hmacsha512_t *ctx, const unsigned char *buf,
unsigned int len)
{
CK_RV rv;
CK_BYTE_PTR pPart;
DE_CONST(buf, pPart);
PK11_FATALCHECK(pkcs_C_SignUpdate,
(ctx->session, pPart, (CK_ULONG) len));
}
void
isc_hmacsha512_sign(isc_hmacsha512_t *ctx, unsigned char *digest, size_t len) {
CK_RV rv;
CK_BYTE newdigest[ISC_SHA512_DIGESTLENGTH];
CK_ULONG psl = ISC_SHA512_DIGESTLENGTH;
REQUIRE(len <= ISC_SHA512_DIGESTLENGTH);
PK11_FATALCHECK(pkcs_C_SignFinal, (ctx->session, newdigest, &psl));
if (ctx->object != CK_INVALID_HANDLE)
(void) pkcs_C_DestroyObject(ctx->session, ctx->object);
ctx->object = CK_INVALID_HANDLE;
pk11_return_session(ctx);
memmove(digest, newdigest, len);
isc_safe_memwipe(newdigest, sizeof(newdigest));
}
#else
void
isc_hmacsha512_init(isc_hmacsha512_t *ctx, const unsigned char *key,
unsigned int len)
{
CK_RV rv;
CK_MECHANISM mech = { CKM_SHA512, NULL, 0 };
unsigned char ipad[ISC_SHA512_BLOCK_LENGTH];
unsigned int i;
RUNTIME_CHECK(pk11_get_session(ctx, OP_DIGEST, true, false,
false, NULL, 0) == ISC_R_SUCCESS);
RUNTIME_CHECK((ctx->key = pk11_mem_get(ISC_SHA512_BLOCK_LENGTH))
!= NULL);
if (len > ISC_SHA512_BLOCK_LENGTH) {
CK_BYTE_PTR kPart;
CK_ULONG kl;
PK11_FATALCHECK(pkcs_C_DigestInit, (ctx->session, &mech));
DE_CONST(key, kPart);
PK11_FATALCHECK(pkcs_C_DigestUpdate,
(ctx->session, kPart, (CK_ULONG) len));
kl = ISC_SHA512_DIGESTLENGTH;
PK11_FATALCHECK(pkcs_C_DigestFinal,
(ctx->session, (CK_BYTE_PTR) ctx->key, &kl));
} else
memmove(ctx->key, key, len);
PK11_FATALCHECK(pkcs_C_DigestInit, (ctx->session, &mech));
memset(ipad, IPAD, ISC_SHA512_BLOCK_LENGTH);
for (i = 0; i < ISC_SHA512_BLOCK_LENGTH; i++)
ipad[i] ^= ctx->key[i];
PK11_FATALCHECK(pkcs_C_DigestUpdate,
(ctx->session, ipad,
(CK_ULONG) ISC_SHA512_BLOCK_LENGTH));
}
void
isc_hmacsha512_invalidate(isc_hmacsha512_t *ctx) {
if (ctx->key != NULL)
pk11_mem_put(ctx->key, ISC_SHA512_BLOCK_LENGTH);
ctx->key = NULL;
isc_sha512_invalidate(ctx);
}
void
isc_hmacsha512_update(isc_hmacsha512_t *ctx, const unsigned char *buf,
unsigned int len)
{
CK_RV rv;
CK_BYTE_PTR pPart;
DE_CONST(buf, pPart);
PK11_FATALCHECK(pkcs_C_DigestUpdate,
(ctx->session, pPart, (CK_ULONG) len));
}
void
isc_hmacsha512_sign(isc_hmacsha512_t *ctx, unsigned char *digest, size_t len) {
CK_RV rv;
CK_BYTE newdigest[ISC_SHA512_DIGESTLENGTH];
CK_ULONG psl = ISC_SHA512_DIGESTLENGTH;
CK_MECHANISM mech = { CKM_SHA512, NULL, 0 };
CK_BYTE opad[ISC_SHA512_BLOCK_LENGTH];
unsigned int i;
REQUIRE(len <= ISC_SHA512_DIGESTLENGTH);
PK11_FATALCHECK(pkcs_C_DigestFinal, (ctx->session, newdigest, &psl));
memset(opad, OPAD, ISC_SHA512_BLOCK_LENGTH);
for (i = 0; i < ISC_SHA512_BLOCK_LENGTH; i++)
opad[i] ^= ctx->key[i];
pk11_mem_put(ctx->key, ISC_SHA512_BLOCK_LENGTH);
ctx->key = NULL;
PK11_FATALCHECK(pkcs_C_DigestInit, (ctx->session, &mech));
PK11_FATALCHECK(pkcs_C_DigestUpdate,
(ctx->session, opad,
(CK_ULONG) ISC_SHA512_BLOCK_LENGTH));
PK11_FATALCHECK(pkcs_C_DigestUpdate,
(ctx->session, (CK_BYTE_PTR) newdigest, psl));
PK11_FATALCHECK(pkcs_C_DigestFinal, (ctx->session, newdigest, &psl));
pk11_return_session(ctx);
memmove(digest, newdigest, len);
isc_safe_memwipe(newdigest, sizeof(newdigest));
}
#endif
#else
#define IPAD 0x36
#define OPAD 0x5C
/*
* Start HMAC-SHA1 process. Initialize an sha1 context and digest the key.
*/
void
isc_hmacsha1_init(isc_hmacsha1_t *ctx, const unsigned char *key,
unsigned int len)
{
unsigned char ipad[ISC_SHA1_BLOCK_LENGTH];
unsigned int i;
memset(ctx->key, 0, sizeof(ctx->key));
if (len > sizeof(ctx->key)) {
isc_sha1_t sha1ctx;
isc_sha1_init(&sha1ctx);
isc_sha1_update(&sha1ctx, key, len);
isc_sha1_final(&sha1ctx, ctx->key);
} else
memmove(ctx->key, key, len);
isc_sha1_init(&ctx->sha1ctx);
memset(ipad, IPAD, sizeof(ipad));
for (i = 0; i < ISC_SHA1_BLOCK_LENGTH; i++)
ipad[i] ^= ctx->key[i];
isc_sha1_update(&ctx->sha1ctx, ipad, sizeof(ipad));
}
void
isc_hmacsha1_invalidate(isc_hmacsha1_t *ctx) {
isc_sha1_invalidate(&ctx->sha1ctx);
isc_safe_memwipe(ctx, sizeof(*ctx));
}
/*
* Update context to reflect the concatenation of another buffer full
* of bytes.
*/
void
isc_hmacsha1_update(isc_hmacsha1_t *ctx, const unsigned char *buf,
unsigned int len)
{
isc_sha1_update(&ctx->sha1ctx, buf, len);
}
/*
* Compute signature - finalize SHA1 operation and reapply SHA1.
*/
void
isc_hmacsha1_sign(isc_hmacsha1_t *ctx, unsigned char *digest, size_t len) {
unsigned char opad[ISC_SHA1_BLOCK_LENGTH];
unsigned char newdigest[ISC_SHA1_DIGESTLENGTH];
unsigned int i;
REQUIRE(len <= ISC_SHA1_DIGESTLENGTH);
isc_sha1_final(&ctx->sha1ctx, newdigest);
memset(opad, OPAD, sizeof(opad));
for (i = 0; i < ISC_SHA1_BLOCK_LENGTH; i++)
opad[i] ^= ctx->key[i];
isc_sha1_init(&ctx->sha1ctx);
isc_sha1_update(&ctx->sha1ctx, opad, sizeof(opad));
isc_sha1_update(&ctx->sha1ctx, newdigest, ISC_SHA1_DIGESTLENGTH);
isc_sha1_final(&ctx->sha1ctx, newdigest);
isc_hmacsha1_invalidate(ctx);
memmove(digest, newdigest, len);
isc_safe_memwipe(newdigest, sizeof(newdigest));
}
/*
* Start HMAC-SHA224 process. Initialize an sha224 context and digest the key.
*/
void
isc_hmacsha224_init(isc_hmacsha224_t *ctx, const unsigned char *key,
unsigned int len)
{
unsigned char ipad[ISC_SHA224_BLOCK_LENGTH];
unsigned int i;
memset(ctx->key, 0, sizeof(ctx->key));
if (len > sizeof(ctx->key)) {
isc_sha224_t sha224ctx;
isc_sha224_init(&sha224ctx);
isc_sha224_update(&sha224ctx, key, len);
isc_sha224_final(ctx->key, &sha224ctx);
} else
memmove(ctx->key, key, len);
isc_sha224_init(&ctx->sha224ctx);
memset(ipad, IPAD, sizeof(ipad));
for (i = 0; i < ISC_SHA224_BLOCK_LENGTH; i++)
ipad[i] ^= ctx->key[i];
isc_sha224_update(&ctx->sha224ctx, ipad, sizeof(ipad));
}
void
isc_hmacsha224_invalidate(isc_hmacsha224_t *ctx) {
isc_safe_memwipe(ctx, sizeof(*ctx));
}
/*
* Update context to reflect the concatenation of another buffer full
* of bytes.
*/
void
isc_hmacsha224_update(isc_hmacsha224_t *ctx, const unsigned char *buf,
unsigned int len)
{
isc_sha224_update(&ctx->sha224ctx, buf, len);
}
/*
* Compute signature - finalize SHA224 operation and reapply SHA224.
*/
void
isc_hmacsha224_sign(isc_hmacsha224_t *ctx, unsigned char *digest, size_t len) {
unsigned char opad[ISC_SHA224_BLOCK_LENGTH];
unsigned char newdigest[ISC_SHA224_DIGESTLENGTH];
unsigned int i;
REQUIRE(len <= ISC_SHA224_DIGESTLENGTH);
isc_sha224_final(newdigest, &ctx->sha224ctx);
memset(opad, OPAD, sizeof(opad));
for (i = 0; i < ISC_SHA224_BLOCK_LENGTH; i++)
opad[i] ^= ctx->key[i];
isc_sha224_init(&ctx->sha224ctx);
isc_sha224_update(&ctx->sha224ctx, opad, sizeof(opad));
isc_sha224_update(&ctx->sha224ctx, newdigest, ISC_SHA224_DIGESTLENGTH);
isc_sha224_final(newdigest, &ctx->sha224ctx);
memmove(digest, newdigest, len);
isc_safe_memwipe(newdigest, sizeof(newdigest));
}
/*
* Start HMAC-SHA256 process. Initialize an sha256 context and digest the key.
*/
void
isc_hmacsha256_init(isc_hmacsha256_t *ctx, const unsigned char *key,
unsigned int len)
{
unsigned char ipad[ISC_SHA256_BLOCK_LENGTH];
unsigned int i;
memset(ctx->key, 0, sizeof(ctx->key));
if (len > sizeof(ctx->key)) {
isc_sha256_t sha256ctx;
isc_sha256_init(&sha256ctx);
isc_sha256_update(&sha256ctx, key, len);
isc_sha256_final(ctx->key, &sha256ctx);
} else
memmove(ctx->key, key, len);
isc_sha256_init(&ctx->sha256ctx);
memset(ipad, IPAD, sizeof(ipad));
for (i = 0; i < ISC_SHA256_BLOCK_LENGTH; i++)
ipad[i] ^= ctx->key[i];
isc_sha256_update(&ctx->sha256ctx, ipad, sizeof(ipad));
}
void
isc_hmacsha256_invalidate(isc_hmacsha256_t *ctx) {
isc_safe_memwipe(ctx, sizeof(*ctx));
}
/*
* Update context to reflect the concatenation of another buffer full
* of bytes.
*/
void
isc_hmacsha256_update(isc_hmacsha256_t *ctx, const unsigned char *buf,
unsigned int len)
{
isc_sha256_update(&ctx->sha256ctx, buf, len);
}
/*
* Compute signature - finalize SHA256 operation and reapply SHA256.
*/
void
isc_hmacsha256_sign(isc_hmacsha256_t *ctx, unsigned char *digest, size_t len) {
unsigned char opad[ISC_SHA256_BLOCK_LENGTH];
unsigned char newdigest[ISC_SHA256_DIGESTLENGTH];
unsigned int i;
REQUIRE(len <= ISC_SHA256_DIGESTLENGTH);
isc_sha256_final(newdigest, &ctx->sha256ctx);
memset(opad, OPAD, sizeof(opad));
for (i = 0; i < ISC_SHA256_BLOCK_LENGTH; i++)
opad[i] ^= ctx->key[i];
isc_sha256_init(&ctx->sha256ctx);
isc_sha256_update(&ctx->sha256ctx, opad, sizeof(opad));
isc_sha256_update(&ctx->sha256ctx, newdigest, ISC_SHA256_DIGESTLENGTH);
isc_sha256_final(newdigest, &ctx->sha256ctx);
memmove(digest, newdigest, len);
isc_safe_memwipe(newdigest, sizeof(newdigest));
}
/*
* Start HMAC-SHA384 process. Initialize an sha384 context and digest the key.
*/
void
isc_hmacsha384_init(isc_hmacsha384_t *ctx, const unsigned char *key,
unsigned int len)
{
unsigned char ipad[ISC_SHA384_BLOCK_LENGTH];
unsigned int i;
memset(ctx->key, 0, sizeof(ctx->key));
if (len > sizeof(ctx->key)) {
isc_sha384_t sha384ctx;
isc_sha384_init(&sha384ctx);
isc_sha384_update(&sha384ctx, key, len);
isc_sha384_final(ctx->key, &sha384ctx);
} else
memmove(ctx->key, key, len);
isc_sha384_init(&ctx->sha384ctx);
memset(ipad, IPAD, sizeof(ipad));
for (i = 0; i < ISC_SHA384_BLOCK_LENGTH; i++)
ipad[i] ^= ctx->key[i];
isc_sha384_update(&ctx->sha384ctx, ipad, sizeof(ipad));
}
void
isc_hmacsha384_invalidate(isc_hmacsha384_t *ctx) {
isc_safe_memwipe(ctx, sizeof(*ctx));
}
/*
* Update context to reflect the concatenation of another buffer full
* of bytes.
*/
void
isc_hmacsha384_update(isc_hmacsha384_t *ctx, const unsigned char *buf,
unsigned int len)
{
isc_sha384_update(&ctx->sha384ctx, buf, len);
}
/*
* Compute signature - finalize SHA384 operation and reapply SHA384.
*/
void
isc_hmacsha384_sign(isc_hmacsha384_t *ctx, unsigned char *digest, size_t len) {
unsigned char opad[ISC_SHA384_BLOCK_LENGTH];
unsigned char newdigest[ISC_SHA384_DIGESTLENGTH];
unsigned int i;
REQUIRE(len <= ISC_SHA384_DIGESTLENGTH);
isc_sha384_final(newdigest, &ctx->sha384ctx);
memset(opad, OPAD, sizeof(opad));
for (i = 0; i < ISC_SHA384_BLOCK_LENGTH; i++)
opad[i] ^= ctx->key[i];
isc_sha384_init(&ctx->sha384ctx);
isc_sha384_update(&ctx->sha384ctx, opad, sizeof(opad));
isc_sha384_update(&ctx->sha384ctx, newdigest, ISC_SHA384_DIGESTLENGTH);
isc_sha384_final(newdigest, &ctx->sha384ctx);
memmove(digest, newdigest, len);
isc_safe_memwipe(newdigest, sizeof(newdigest));
}
/*
* Start HMAC-SHA512 process. Initialize an sha512 context and digest the key.
*/
void
isc_hmacsha512_init(isc_hmacsha512_t *ctx, const unsigned char *key,
unsigned int len)
{
unsigned char ipad[ISC_SHA512_BLOCK_LENGTH];
unsigned int i;
memset(ctx->key, 0, sizeof(ctx->key));
if (len > sizeof(ctx->key)) {
isc_sha512_t sha512ctx;
isc_sha512_init(&sha512ctx);
isc_sha512_update(&sha512ctx, key, len);
isc_sha512_final(ctx->key, &sha512ctx);
} else
memmove(ctx->key, key, len);
isc_sha512_init(&ctx->sha512ctx);
memset(ipad, IPAD, sizeof(ipad));
for (i = 0; i < ISC_SHA512_BLOCK_LENGTH; i++)
ipad[i] ^= ctx->key[i];
isc_sha512_update(&ctx->sha512ctx, ipad, sizeof(ipad));
}
void
isc_hmacsha512_invalidate(isc_hmacsha512_t *ctx) {
isc_safe_memwipe(ctx, sizeof(*ctx));
}
/*
* Update context to reflect the concatenation of another buffer full
* of bytes.
*/
void
isc_hmacsha512_update(isc_hmacsha512_t *ctx, const unsigned char *buf,
unsigned int len)
{
isc_sha512_update(&ctx->sha512ctx, buf, len);
}
/*
* Compute signature - finalize SHA512 operation and reapply SHA512.
*/
void
isc_hmacsha512_sign(isc_hmacsha512_t *ctx, unsigned char *digest, size_t len) {
unsigned char opad[ISC_SHA512_BLOCK_LENGTH];
unsigned char newdigest[ISC_SHA512_DIGESTLENGTH];
unsigned int i;
REQUIRE(len <= ISC_SHA512_DIGESTLENGTH);
isc_sha512_final(newdigest, &ctx->sha512ctx);
memset(opad, OPAD, sizeof(opad));
for (i = 0; i < ISC_SHA512_BLOCK_LENGTH; i++)
opad[i] ^= ctx->key[i];
isc_sha512_init(&ctx->sha512ctx);
isc_sha512_update(&ctx->sha512ctx, opad, sizeof(opad));
isc_sha512_update(&ctx->sha512ctx, newdigest, ISC_SHA512_DIGESTLENGTH);
isc_sha512_final(newdigest, &ctx->sha512ctx);
memmove(digest, newdigest, len);
isc_safe_memwipe(newdigest, sizeof(newdigest));
}
#endif /* !ISC_PLATFORM_OPENSSLHASH */
/*
* Verify signature - finalize SHA1 operation and reapply SHA1, then
* compare to the supplied digest.
*/
bool
isc_hmacsha1_verify(isc_hmacsha1_t *ctx, unsigned char *digest, size_t len) {
unsigned char newdigest[ISC_SHA1_DIGESTLENGTH];
REQUIRE(len <= ISC_SHA1_DIGESTLENGTH);
isc_hmacsha1_sign(ctx, newdigest, ISC_SHA1_DIGESTLENGTH);
return (isc_safe_memequal(digest, newdigest, len));
}
/*
* Verify signature - finalize SHA224 operation and reapply SHA224, then
* compare to the supplied digest.
*/
bool
isc_hmacsha224_verify(isc_hmacsha224_t *ctx, unsigned char *digest, size_t len) {
unsigned char newdigest[ISC_SHA224_DIGESTLENGTH];
REQUIRE(len <= ISC_SHA224_DIGESTLENGTH);
isc_hmacsha224_sign(ctx, newdigest, ISC_SHA224_DIGESTLENGTH);
return (isc_safe_memequal(digest, newdigest, len));
}
/*
* Verify signature - finalize SHA256 operation and reapply SHA256, then
* compare to the supplied digest.
*/
bool
isc_hmacsha256_verify(isc_hmacsha256_t *ctx, unsigned char *digest, size_t len) {
unsigned char newdigest[ISC_SHA256_DIGESTLENGTH];
REQUIRE(len <= ISC_SHA256_DIGESTLENGTH);
isc_hmacsha256_sign(ctx, newdigest, ISC_SHA256_DIGESTLENGTH);
return (isc_safe_memequal(digest, newdigest, len));
}
/*
* Verify signature - finalize SHA384 operation and reapply SHA384, then
* compare to the supplied digest.
*/
bool
isc_hmacsha384_verify(isc_hmacsha384_t *ctx, unsigned char *digest, size_t len) {
unsigned char newdigest[ISC_SHA384_DIGESTLENGTH];
REQUIRE(len <= ISC_SHA384_DIGESTLENGTH);
isc_hmacsha384_sign(ctx, newdigest, ISC_SHA384_DIGESTLENGTH);
return (isc_safe_memequal(digest, newdigest, len));
}
/*
* Verify signature - finalize SHA512 operation and reapply SHA512, then
* compare to the supplied digest.
*/
bool
isc_hmacsha512_verify(isc_hmacsha512_t *ctx, unsigned char *digest, size_t len) {
unsigned char newdigest[ISC_SHA512_DIGESTLENGTH];
REQUIRE(len <= ISC_SHA512_DIGESTLENGTH);
isc_hmacsha512_sign(ctx, newdigest, ISC_SHA512_DIGESTLENGTH);
return (isc_safe_memequal(digest, newdigest, len));
}
/*
* Check for SHA-1 support; if it does not work, raise a fatal error.
*
* Use the first test vector from RFC 2104, with a second round using
* a too-short key.
*
* Standard use is testing 0 and expecting result true.
* Testing use is testing 1..4 and expecting result false.
*/
bool
isc_hmacsha1_check(int testing) {
isc_hmacsha1_t ctx;
unsigned char key[] = { /* 20*0x0b */
0x0b, 0x0b, 0x0b, 0x0b, 0x0b, 0x0b, 0x0b, 0x0b,
0x0b, 0x0b, 0x0b, 0x0b, 0x0b, 0x0b, 0x0b, 0x0b,
0x0b, 0x0b, 0x0b, 0x0b
};
unsigned char input[] = { /* "Hi There" */
0x48, 0x69, 0x20, 0x54, 0x68, 0x65, 0x72, 0x65
};
unsigned char expected[] = {
0xb6, 0x17, 0x31, 0x86, 0x55, 0x05, 0x72, 0x64,
0xe2, 0x8b, 0xc0, 0xb6, 0xfb, 0x37, 0x8c, 0x8e,
0xf1, 0x46, 0xbe, 0x00
};
unsigned char expected2[] = {
0xa0, 0x75, 0xe0, 0x5f, 0x7f, 0x17, 0x9d, 0x34,
0xb2, 0xab, 0xc5, 0x19, 0x8f, 0x38, 0x62, 0x36,
0x42, 0xbd, 0xec, 0xde
};
bool result;
/*
* Introduce a fault for testing.
*/
switch (testing) {
case 0:
default:
break;
case 1:
key[0] ^= 0x01;
break;
case 2:
input[0] ^= 0x01;
break;
case 3:
expected[0] ^= 0x01;
break;
case 4:
expected2[0] ^= 0x01;
break;
}
/*
* These functions do not return anything; any failure will be fatal.
*/
isc_hmacsha1_init(&ctx, key, 20U);
isc_hmacsha1_update(&ctx, input, 8U);
result = isc_hmacsha1_verify(&ctx, expected, sizeof(expected));
if (!result) {
return (result);
}
/* Second round using a byte key */
isc_hmacsha1_init(&ctx, key, 1U);
isc_hmacsha1_update(&ctx, input, 8U);
return (isc_hmacsha1_verify(&ctx, expected2, sizeof(expected2)));
}