/** * Construct a new x509 object. * @return 0 if ok. < 0 if there was a problem. */ int x509_new(const uint8_t *cert, int *len, X509_CTX **ctx) { int begin_tbs, end_tbs; int ret = X509_NOT_OK, offset = 0, cert_size = 0; X509_CTX *x509_ctx; BI_CTX *bi_ctx; *ctx = (X509_CTX *)calloc(1, sizeof(X509_CTX)); x509_ctx = *ctx; /* get the certificate size */ asn1_skip_obj(cert, &cert_size, ASN1_SEQUENCE); if (asn1_next_obj(cert, &offset, ASN1_SEQUENCE) < 0) goto end_cert; begin_tbs = offset; /* start of the tbs */ end_tbs = begin_tbs; /* work out the end of the tbs */ asn1_skip_obj(cert, &end_tbs, ASN1_SEQUENCE); if (asn1_next_obj(cert, &offset, ASN1_SEQUENCE) < 0) goto end_cert; if (cert[offset] == ASN1_EXPLICIT_TAG) /* optional version */ { if (asn1_version(cert, &offset, x509_ctx)) goto end_cert; } if (asn1_skip_obj(cert, &offset, ASN1_INTEGER) || /* serial number */ asn1_next_obj(cert, &offset, ASN1_SEQUENCE) < 0) goto end_cert; /* make sure the signature is ok */ if (asn1_signature_type(cert, &offset, x509_ctx)) { ret = X509_VFY_ERROR_UNSUPPORTED_DIGEST; goto end_cert; } if (asn1_name(cert, &offset, x509_ctx->ca_cert_dn) || asn1_validity(cert, &offset, x509_ctx) || asn1_name(cert, &offset, x509_ctx->cert_dn) || asn1_public_key(cert, &offset, x509_ctx)) { goto end_cert; } bi_ctx = x509_ctx->rsa_ctx->bi_ctx; x509_ctx->fingerprint = malloc(SHA1_SIZE); SHA1_CTX sha_fp_ctx; SHA1_Init(&sha_fp_ctx); SHA1_Update(&sha_fp_ctx, &cert[0], cert_size); SHA1_Final(x509_ctx->fingerprint, &sha_fp_ctx); #ifdef CONFIG_SSL_CERT_VERIFICATION /* only care if doing verification */ /* use the appropriate signature algorithm (SHA1/MD5/MD2) */ if (x509_ctx->sig_type == SIG_TYPE_MD5) { MD5_CTX md5_ctx; uint8_t md5_dgst[MD5_SIZE]; MD5_Init(&md5_ctx); MD5_Update(&md5_ctx, &cert[begin_tbs], end_tbs-begin_tbs); MD5_Final(md5_dgst, &md5_ctx); x509_ctx->digest = bi_import(bi_ctx, md5_dgst, MD5_SIZE); } else if (x509_ctx->sig_type == SIG_TYPE_SHA1) { SHA1_CTX sha_ctx; uint8_t sha_dgst[SHA1_SIZE]; SHA1_Init(&sha_ctx); SHA1_Update(&sha_ctx, &cert[begin_tbs], end_tbs-begin_tbs); SHA1_Final(sha_dgst, &sha_ctx); x509_ctx->digest = bi_import(bi_ctx, sha_dgst, SHA1_SIZE); } else if (x509_ctx->sig_type == SIG_TYPE_MD2) { MD2_CTX md2_ctx; uint8_t md2_dgst[MD2_SIZE]; MD2_Init(&md2_ctx); MD2_Update(&md2_ctx, &cert[begin_tbs], end_tbs-begin_tbs); MD2_Final(md2_dgst, &md2_ctx); x509_ctx->digest = bi_import(bi_ctx, md2_dgst, MD2_SIZE); } if (cert[offset] == ASN1_V3_DATA) { int suboffset; ++offset; get_asn1_length(cert, &offset); if ((suboffset = asn1_find_subjectaltname(cert, offset)) > 0) { if (asn1_next_obj(cert, &suboffset, ASN1_OCTET_STRING) > 0) { int altlen; if ((altlen = asn1_next_obj(cert, &suboffset, ASN1_SEQUENCE)) > 0) { int endalt = suboffset + altlen; int totalnames = 0; while (suboffset < endalt) { int type = cert[suboffset++]; int dnslen = get_asn1_length(cert, &suboffset); if (type == ASN1_CONTEXT_DNSNAME) { x509_ctx->subject_alt_dnsnames = (char**) realloc(x509_ctx->subject_alt_dnsnames, (totalnames + 2) * sizeof(char*)); x509_ctx->subject_alt_dnsnames[totalnames] = (char*)malloc(dnslen + 1); x509_ctx->subject_alt_dnsnames[totalnames+1] = NULL; memcpy(x509_ctx->subject_alt_dnsnames[totalnames], cert + suboffset, dnslen); x509_ctx->subject_alt_dnsnames[ totalnames][dnslen] = 0; ++totalnames; } suboffset += dnslen; } } } } } offset = end_tbs; /* skip the rest of v3 data */ if (asn1_skip_obj(cert, &offset, ASN1_SEQUENCE) || asn1_signature(cert, &offset, x509_ctx)) goto end_cert; #endif ret = X509_OK; end_cert: if (len) { *len = cert_size; } if (ret) { #ifdef CONFIG_SSL_FULL_MODE printf("Error: Invalid X509 ASN.1 file (%s)\n", x509_display_error(ret)); #endif x509_free(x509_ctx); *ctx = NULL; } return ret; }
/** * Construct a new x509 object. * @return 0 if ok. < 0 if there was a problem. */ int x509_new(const uint8_t *cert, int *len, X509_CTX **ctx) { int begin_tbs, end_tbs, begin_spki, end_spki; int ret = X509_NOT_OK, offset = 0, cert_size = 0; int version = 0; X509_CTX *x509_ctx; #ifdef CONFIG_SSL_CERT_VERIFICATION /* only care if doing verification */ BI_CTX *bi_ctx; #endif *ctx = (X509_CTX *)calloc(1, sizeof(X509_CTX)); x509_ctx = *ctx; /* get the certificate size */ asn1_skip_obj(cert, &cert_size, ASN1_SEQUENCE); if (asn1_next_obj(cert, &offset, ASN1_SEQUENCE) < 0) goto end_cert; begin_tbs = offset; /* start of the tbs */ end_tbs = begin_tbs; /* work out the end of the tbs */ asn1_skip_obj(cert, &end_tbs, ASN1_SEQUENCE); if (asn1_next_obj(cert, &offset, ASN1_SEQUENCE) < 0) goto end_cert; /* optional version */ if (cert[offset] == ASN1_EXPLICIT_TAG && asn1_version(cert, &offset, &version) == X509_NOT_OK) goto end_cert; if (asn1_skip_obj(cert, &offset, ASN1_INTEGER) || /* serial number */ asn1_next_obj(cert, &offset, ASN1_SEQUENCE) < 0) goto end_cert; /* make sure the signature is ok */ if (asn1_signature_type(cert, &offset, x509_ctx)) { ret = X509_VFY_ERROR_UNSUPPORTED_DIGEST; goto end_cert; } if (asn1_name(cert, &offset, x509_ctx->ca_cert_dn) || asn1_validity(cert, &offset, x509_ctx) || asn1_name(cert, &offset, x509_ctx->cert_dn)) { goto end_cert; } begin_spki = offset; if (asn1_public_key(cert, &offset, x509_ctx)) goto end_cert; end_spki = offset; x509_ctx->fingerprint = malloc(SHA1_SIZE); SHA1_CTX sha_fp_ctx; SHA1_Init(&sha_fp_ctx); SHA1_Update(&sha_fp_ctx, &cert[0], cert_size); SHA1_Final(x509_ctx->fingerprint, &sha_fp_ctx); x509_ctx->spki_sha256 = malloc(SHA256_SIZE); SHA256_CTX spki_hash_ctx; SHA256_Init(&spki_hash_ctx); SHA256_Update(&spki_hash_ctx, &cert[begin_spki], end_spki-begin_spki); SHA256_Final(x509_ctx->spki_sha256, &spki_hash_ctx); #ifdef CONFIG_SSL_CERT_VERIFICATION /* only care if doing verification */ bi_ctx = x509_ctx->rsa_ctx->bi_ctx; /* use the appropriate signature algorithm */ switch (x509_ctx->sig_type) { case SIG_TYPE_MD5: { MD5_CTX md5_ctx; uint8_t md5_dgst[MD5_SIZE]; MD5_Init(&md5_ctx); MD5_Update(&md5_ctx, &cert[begin_tbs], end_tbs-begin_tbs); MD5_Final(md5_dgst, &md5_ctx); x509_ctx->digest = bi_import(bi_ctx, md5_dgst, MD5_SIZE); } break; case SIG_TYPE_SHA1: { SHA1_CTX sha_ctx; uint8_t sha_dgst[SHA1_SIZE]; SHA1_Init(&sha_ctx); SHA1_Update(&sha_ctx, &cert[begin_tbs], end_tbs-begin_tbs); SHA1_Final(sha_dgst, &sha_ctx); x509_ctx->digest = bi_import(bi_ctx, sha_dgst, SHA1_SIZE); } break; case SIG_TYPE_SHA256: { SHA256_CTX sha256_ctx; uint8_t sha256_dgst[SHA256_SIZE]; SHA256_Init(&sha256_ctx); SHA256_Update(&sha256_ctx, &cert[begin_tbs], end_tbs-begin_tbs); SHA256_Final(sha256_dgst, &sha256_ctx); x509_ctx->digest = bi_import(bi_ctx, sha256_dgst, SHA256_SIZE); } break; case SIG_TYPE_SHA384: { SHA384_CTX sha384_ctx; uint8_t sha384_dgst[SHA384_SIZE]; SHA384_Init(&sha384_ctx); SHA384_Update(&sha384_ctx, &cert[begin_tbs], end_tbs-begin_tbs); SHA384_Final(sha384_dgst, &sha384_ctx); x509_ctx->digest = bi_import(bi_ctx, sha384_dgst, SHA384_SIZE); } break; case SIG_TYPE_SHA512: { SHA512_CTX sha512_ctx; uint8_t sha512_dgst[SHA512_SIZE]; SHA512_Init(&sha512_ctx); SHA512_Update(&sha512_ctx, &cert[begin_tbs], end_tbs-begin_tbs); SHA512_Final(sha512_dgst, &sha512_ctx); x509_ctx->digest = bi_import(bi_ctx, sha512_dgst, SHA512_SIZE); } break; } if (version == 2 && asn1_next_obj(cert, &offset, ASN1_V3_DATA) > 0) { x509_v3_subject_alt_name(cert, offset, x509_ctx); x509_v3_basic_constraints(cert, offset, x509_ctx); x509_v3_key_usage(cert, offset, x509_ctx); } offset = end_tbs; /* skip the rest of v3 data */ if (asn1_skip_obj(cert, &offset, ASN1_SEQUENCE) || asn1_signature(cert, &offset, x509_ctx)) goto end_cert; /* Saves a few bytes of memory */ bi_clear_cache(bi_ctx); #endif ret = X509_OK; end_cert: if (len) { *len = cert_size; } if (ret) { #ifdef CONFIG_SSL_FULL_MODE char buff[64]; printf("Error: Invalid X509 ASN.1 file (%s)\n", x509_display_error(ret, buff)); #endif x509_free(x509_ctx); *ctx = NULL; } return ret; }