/* * Nettle crypto backend implementation * * Copyright (C) 2011-2021 Red Hat, Inc. All rights reserved. * Copyright (C) 2011-2021 Milan Broz * * This file is free software; you can redistribute it and/or * modify it under the terms of the GNU Lesser General Public * License as published by the Free Software Foundation; either * version 2.1 of the License, or (at your option) any later version. * * This file 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 * Lesser General Public License for more details. * * You should have received a copy of the GNU Lesser General Public * License along with this file; if not, write to the Free Software * Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA. */ #include #include #include #include #include #include #include #include "crypto_backend_internal.h" #if HAVE_NETTLE_VERSION_H #include #define VSTR(s) STR(s) #define STR(s) #s static const char *version = "Nettle "VSTR(NETTLE_VERSION_MAJOR)"."VSTR(NETTLE_VERSION_MINOR); #else static const char *version = "Nettle"; #endif typedef void (*init_func) (void *); typedef void (*update_func) (void *, size_t, const uint8_t *); typedef void (*digest_func) (void *, size_t, uint8_t *); typedef void (*set_key_func) (void *, size_t, const uint8_t *); struct hash_alg { const char *name; int length; init_func init; update_func update; digest_func digest; update_func hmac_update; digest_func hmac_digest; set_key_func hmac_set_key; }; /* Missing HMAC wrappers in Nettle */ #define HMAC_FCE(xxx) \ struct xhmac_##xxx##_ctx HMAC_CTX(struct xxx##_ctx); \ static void xhmac_##xxx##_set_key(struct xhmac_##xxx##_ctx *ctx, \ size_t key_length, const uint8_t *key) \ {HMAC_SET_KEY(ctx, &nettle_##xxx, key_length, key);} \ static void xhmac_##xxx##_update(struct xhmac_##xxx##_ctx *ctx, \ size_t length, const uint8_t *data) \ {xxx##_update(&ctx->state, length, data);} \ static void xhmac_##xxx##_digest(struct xhmac_##xxx##_ctx *ctx, \ size_t length, uint8_t *digest) \ {HMAC_DIGEST(ctx, &nettle_##xxx, length, digest);} HMAC_FCE(sha3_224); HMAC_FCE(sha3_256); HMAC_FCE(sha3_384); HMAC_FCE(sha3_512); static struct hash_alg hash_algs[] = { { "sha1", SHA1_DIGEST_SIZE, (init_func) sha1_init, (update_func) sha1_update, (digest_func) sha1_digest, (update_func) hmac_sha1_update, (digest_func) hmac_sha1_digest, (set_key_func) hmac_sha1_set_key, }, { "sha224", SHA224_DIGEST_SIZE, (init_func) sha224_init, (update_func) sha224_update, (digest_func) sha224_digest, (update_func) hmac_sha224_update, (digest_func) hmac_sha224_digest, (set_key_func) hmac_sha224_set_key, }, { "sha256", SHA256_DIGEST_SIZE, (init_func) sha256_init, (update_func) sha256_update, (digest_func) sha256_digest, (update_func) hmac_sha256_update, (digest_func) hmac_sha256_digest, (set_key_func) hmac_sha256_set_key, }, { "sha384", SHA384_DIGEST_SIZE, (init_func) sha384_init, (update_func) sha384_update, (digest_func) sha384_digest, (update_func) hmac_sha384_update, (digest_func) hmac_sha384_digest, (set_key_func) hmac_sha384_set_key, }, { "sha512", SHA512_DIGEST_SIZE, (init_func) sha512_init, (update_func) sha512_update, (digest_func) sha512_digest, (update_func) hmac_sha512_update, (digest_func) hmac_sha512_digest, (set_key_func) hmac_sha512_set_key, }, { "ripemd160", RIPEMD160_DIGEST_SIZE, (init_func) ripemd160_init, (update_func) ripemd160_update, (digest_func) ripemd160_digest, (update_func) hmac_ripemd160_update, (digest_func) hmac_ripemd160_digest, (set_key_func) hmac_ripemd160_set_key, }, /* Nettle prior to version 3.2 has incompatible SHA3 implementation */ #if NETTLE_SHA3_FIPS202 { "sha3-224", SHA3_224_DIGEST_SIZE, (init_func) sha3_224_init, (update_func) sha3_224_update, (digest_func) sha3_224_digest, (update_func) xhmac_sha3_224_update, (digest_func) xhmac_sha3_224_digest, (set_key_func) xhmac_sha3_224_set_key, }, { "sha3-256", SHA3_256_DIGEST_SIZE, (init_func) sha3_256_init, (update_func) sha3_256_update, (digest_func) sha3_256_digest, (update_func) xhmac_sha3_256_update, (digest_func) xhmac_sha3_256_digest, (set_key_func) xhmac_sha3_256_set_key, }, { "sha3-384", SHA3_384_DIGEST_SIZE, (init_func) sha3_384_init, (update_func) sha3_384_update, (digest_func) sha3_384_digest, (update_func) xhmac_sha3_384_update, (digest_func) xhmac_sha3_384_digest, (set_key_func) xhmac_sha3_384_set_key, }, { "sha3-512", SHA3_512_DIGEST_SIZE, (init_func) sha3_512_init, (update_func) sha3_512_update, (digest_func) sha3_512_digest, (update_func) xhmac_sha3_512_update, (digest_func) xhmac_sha3_512_digest, (set_key_func) xhmac_sha3_512_set_key, }, #endif { NULL, 0, NULL, NULL, NULL, NULL, NULL, NULL, } }; struct crypt_hash { const struct hash_alg *hash; union { struct sha1_ctx sha1; struct sha224_ctx sha224; struct sha256_ctx sha256; struct sha384_ctx sha384; struct sha512_ctx sha512; struct ripemd160_ctx ripemd160; struct sha3_224_ctx sha3_224; struct sha3_256_ctx sha3_256; struct sha3_384_ctx sha3_384; struct sha3_512_ctx sha3_512; } nettle_ctx; }; struct crypt_hmac { const struct hash_alg *hash; union { struct hmac_sha1_ctx sha1; struct hmac_sha224_ctx sha224; struct hmac_sha256_ctx sha256; struct hmac_sha384_ctx sha384; struct hmac_sha512_ctx sha512; struct hmac_ripemd160_ctx ripemd160; struct xhmac_sha3_224_ctx sha3_224; struct xhmac_sha3_256_ctx sha3_256; struct xhmac_sha3_384_ctx sha3_384; struct xhmac_sha3_512_ctx sha3_512; } nettle_ctx; size_t key_length; uint8_t *key; }; struct crypt_cipher { struct crypt_cipher_kernel ck; }; uint32_t crypt_backend_flags(void) { return 0; } static struct hash_alg *_get_alg(const char *name) { int i = 0; while (name && hash_algs[i].name) { if (!strcmp(name, hash_algs[i].name)) return &hash_algs[i]; i++; } return NULL; } int crypt_backend_init(void) { return 0; } void crypt_backend_destroy(void) { return; } const char *crypt_backend_version(void) { return version; } /* HASH */ int crypt_hash_size(const char *name) { struct hash_alg *ha = _get_alg(name); return ha ? ha->length : -EINVAL; } int crypt_hash_init(struct crypt_hash **ctx, const char *name) { struct crypt_hash *h; h = malloc(sizeof(*h)); if (!h) return -ENOMEM; h->hash = _get_alg(name); if (!h->hash) { free(h); return -EINVAL; } h->hash->init(&h->nettle_ctx); *ctx = h; return 0; } static void crypt_hash_restart(struct crypt_hash *ctx) { ctx->hash->init(&ctx->nettle_ctx); } int crypt_hash_write(struct crypt_hash *ctx, const char *buffer, size_t length) { ctx->hash->update(&ctx->nettle_ctx, length, (const uint8_t*)buffer); return 0; } int crypt_hash_final(struct crypt_hash *ctx, char *buffer, size_t length) { if (length > (size_t)ctx->hash->length) return -EINVAL; ctx->hash->digest(&ctx->nettle_ctx, length, (uint8_t *)buffer); crypt_hash_restart(ctx); return 0; } void crypt_hash_destroy(struct crypt_hash *ctx) { memset(ctx, 0, sizeof(*ctx)); free(ctx); } /* HMAC */ int crypt_hmac_size(const char *name) { return crypt_hash_size(name); } int crypt_hmac_init(struct crypt_hmac **ctx, const char *name, const void *key, size_t key_length) { struct crypt_hmac *h; h = malloc(sizeof(*h)); if (!h) return -ENOMEM; memset(ctx, 0, sizeof(*ctx)); h->hash = _get_alg(name); if (!h->hash) goto bad; h->key = malloc(key_length); if (!h->key) goto bad; memcpy(h->key, key, key_length); h->key_length = key_length; h->hash->init(&h->nettle_ctx); h->hash->hmac_set_key(&h->nettle_ctx, h->key_length, h->key); *ctx = h; return 0; bad: free(h); return -EINVAL; } static void crypt_hmac_restart(struct crypt_hmac *ctx) { ctx->hash->hmac_set_key(&ctx->nettle_ctx, ctx->key_length, ctx->key); } int crypt_hmac_write(struct crypt_hmac *ctx, const char *buffer, size_t length) { ctx->hash->hmac_update(&ctx->nettle_ctx, length, (const uint8_t *)buffer); return 0; } int crypt_hmac_final(struct crypt_hmac *ctx, char *buffer, size_t length) { if (length > (size_t)ctx->hash->length) return -EINVAL; ctx->hash->hmac_digest(&ctx->nettle_ctx, length, (uint8_t *)buffer); crypt_hmac_restart(ctx); return 0; } void crypt_hmac_destroy(struct crypt_hmac *ctx) { memset(ctx->key, 0, ctx->key_length); free(ctx->key); memset(ctx, 0, sizeof(*ctx)); free(ctx); } /* RNG - N/A */ int crypt_backend_rng(char *buffer, size_t length, int quality, int fips) { return -EINVAL; } /* PBKDF */ int crypt_pbkdf(const char *kdf, const char *hash, const char *password, size_t password_length, const char *salt, size_t salt_length, char *key, size_t key_length, uint32_t iterations, uint32_t memory, uint32_t parallel) { struct crypt_hmac *h; int r; if (!kdf) return -EINVAL; if (!strcmp(kdf, "pbkdf2")) { r = crypt_hmac_init(&h, hash, password, password_length); if (r < 0) return r; nettle_pbkdf2(&h->nettle_ctx, h->hash->hmac_update, h->hash->hmac_digest, h->hash->length, iterations, salt_length, (const uint8_t *)salt, key_length, (uint8_t *)key); crypt_hmac_destroy(h); return 0; } else if (!strncmp(kdf, "argon2", 6)) { return argon2(kdf, password, password_length, salt, salt_length, key, key_length, iterations, memory, parallel); } return -EINVAL; } /* Block ciphers */ int crypt_cipher_init(struct crypt_cipher **ctx, const char *name, const char *mode, const void *key, size_t key_length) { struct crypt_cipher *h; int r; h = malloc(sizeof(*h)); if (!h) return -ENOMEM; r = crypt_cipher_init_kernel(&h->ck, name, mode, key, key_length); if (r < 0) { free(h); return r; } *ctx = h; return 0; } void crypt_cipher_destroy(struct crypt_cipher *ctx) { crypt_cipher_destroy_kernel(&ctx->ck); free(ctx); } int crypt_cipher_encrypt(struct crypt_cipher *ctx, const char *in, char *out, size_t length, const char *iv, size_t iv_length) { return crypt_cipher_encrypt_kernel(&ctx->ck, in, out, length, iv, iv_length); } int crypt_cipher_decrypt(struct crypt_cipher *ctx, const char *in, char *out, size_t length, const char *iv, size_t iv_length) { return crypt_cipher_decrypt_kernel(&ctx->ck, in, out, length, iv, iv_length); } bool crypt_cipher_kernel_only(struct crypt_cipher *ctx) { return true; } int crypt_bitlk_decrypt_key(const void *key, size_t key_length, const char *in, char *out, size_t length, const char *iv, size_t iv_length, const char *tag, size_t tag_length) { return crypt_bitlk_decrypt_key_kernel(key, key_length, in, out, length, iv, iv_length, tag, tag_length); }