/* * Copyright 1995-2020 The OpenSSL Project Authors. All Rights Reserved. * * Licensed under the OpenSSL license (the "License"). You may not use * this file except in compliance with the License. You can obtain a copy * in the file LICENSE in the source distribution or at * https://www.openssl.org/source/license.html */ #include #include "internal/cryptlib.h" #include #include #include #include #include "crypto/x509.h" int X509_issuer_and_serial_cmp(const X509 *a, const X509 *b) { int i; const X509_CINF *ai, *bi; ai = &a->cert_info; bi = &b->cert_info; i = ASN1_INTEGER_cmp(&ai->serialNumber, &bi->serialNumber); if (i) return i; return X509_NAME_cmp(ai->issuer, bi->issuer); } #ifndef OPENSSL_NO_MD5 unsigned long X509_issuer_and_serial_hash(X509 *a) { unsigned long ret = 0; EVP_MD_CTX *ctx = EVP_MD_CTX_new(); unsigned char md[16]; char *f; if (ctx == NULL) goto err; f = X509_NAME_oneline(a->cert_info.issuer, NULL, 0); if (f == NULL) goto err; if (!EVP_DigestInit_ex(ctx, EVP_md5(), NULL)) goto err; if (!EVP_DigestUpdate(ctx, (unsigned char *)f, strlen(f))) goto err; OPENSSL_free(f); if (!EVP_DigestUpdate (ctx, (unsigned char *)a->cert_info.serialNumber.data, (unsigned long)a->cert_info.serialNumber.length)) goto err; if (!EVP_DigestFinal_ex(ctx, &(md[0]), NULL)) goto err; ret = (((unsigned long)md[0]) | ((unsigned long)md[1] << 8L) | ((unsigned long)md[2] << 16L) | ((unsigned long)md[3] << 24L) ) & 0xffffffffL; err: EVP_MD_CTX_free(ctx); return ret; } #endif int X509_issuer_name_cmp(const X509 *a, const X509 *b) { return X509_NAME_cmp(a->cert_info.issuer, b->cert_info.issuer); } int X509_subject_name_cmp(const X509 *a, const X509 *b) { return X509_NAME_cmp(a->cert_info.subject, b->cert_info.subject); } int X509_CRL_cmp(const X509_CRL *a, const X509_CRL *b) { return X509_NAME_cmp(a->crl.issuer, b->crl.issuer); } int X509_CRL_match(const X509_CRL *a, const X509_CRL *b) { return memcmp(a->sha1_hash, b->sha1_hash, 20); } X509_NAME *X509_get_issuer_name(const X509 *a) { return a->cert_info.issuer; } unsigned long X509_issuer_name_hash(X509 *x) { return X509_NAME_hash(x->cert_info.issuer); } #ifndef OPENSSL_NO_MD5 unsigned long X509_issuer_name_hash_old(X509 *x) { return X509_NAME_hash_old(x->cert_info.issuer); } #endif X509_NAME *X509_get_subject_name(const X509 *a) { return a->cert_info.subject; } ASN1_INTEGER *X509_get_serialNumber(X509 *a) { return &a->cert_info.serialNumber; } const ASN1_INTEGER *X509_get0_serialNumber(const X509 *a) { return &a->cert_info.serialNumber; } unsigned long X509_subject_name_hash(X509 *x) { return X509_NAME_hash(x->cert_info.subject); } #ifndef OPENSSL_NO_MD5 unsigned long X509_subject_name_hash_old(X509 *x) { return X509_NAME_hash_old(x->cert_info.subject); } #endif /* * Compare two certificates: they must be identical for this to work. NB: * Although "cmp" operations are generally prototyped to take "const" * arguments (eg. for use in STACKs), the way X509 handling is - these * operations may involve ensuring the hashes are up-to-date and ensuring * certain cert information is cached. So this is the point where the * "depth-first" constification tree has to halt with an evil cast. */ int X509_cmp(const X509 *a, const X509 *b) { int rv; /* ensure hash is valid */ if (X509_check_purpose((X509 *)a, -1, 0) != 1) return -2; if (X509_check_purpose((X509 *)b, -1, 0) != 1) return -2; rv = memcmp(a->sha1_hash, b->sha1_hash, SHA_DIGEST_LENGTH); if (rv) return rv; /* Check for match against stored encoding too */ if (!a->cert_info.enc.modified && !b->cert_info.enc.modified) { if (a->cert_info.enc.len < b->cert_info.enc.len) return -1; if (a->cert_info.enc.len > b->cert_info.enc.len) return 1; return memcmp(a->cert_info.enc.enc, b->cert_info.enc.enc, a->cert_info.enc.len); } return rv; } int X509_NAME_cmp(const X509_NAME *a, const X509_NAME *b) { int ret; /* Ensure canonical encoding is present and up to date */ if (!a->canon_enc || a->modified) { ret = i2d_X509_NAME((X509_NAME *)a, NULL); if (ret < 0) return -2; } if (!b->canon_enc || b->modified) { ret = i2d_X509_NAME((X509_NAME *)b, NULL); if (ret < 0) return -2; } ret = a->canon_enclen - b->canon_enclen; if (ret != 0 || a->canon_enclen == 0) return ret; return memcmp(a->canon_enc, b->canon_enc, a->canon_enclen); } unsigned long X509_NAME_hash(X509_NAME *x) { unsigned long ret = 0; unsigned char md[SHA_DIGEST_LENGTH]; /* Make sure X509_NAME structure contains valid cached encoding */ i2d_X509_NAME(x, NULL); if (!EVP_Digest(x->canon_enc, x->canon_enclen, md, NULL, EVP_sha1(), NULL)) return 0; ret = (((unsigned long)md[0]) | ((unsigned long)md[1] << 8L) | ((unsigned long)md[2] << 16L) | ((unsigned long)md[3] << 24L) ) & 0xffffffffL; return ret; } #ifndef OPENSSL_NO_MD5 /* * I now DER encode the name and hash it. Since I cache the DER encoding, * this is reasonably efficient. */ unsigned long X509_NAME_hash_old(X509_NAME *x) { EVP_MD_CTX *md_ctx = EVP_MD_CTX_new(); unsigned long ret = 0; unsigned char md[16]; if (md_ctx == NULL) return ret; /* Make sure X509_NAME structure contains valid cached encoding */ i2d_X509_NAME(x, NULL); EVP_MD_CTX_set_flags(md_ctx, EVP_MD_CTX_FLAG_NON_FIPS_ALLOW); if (EVP_DigestInit_ex(md_ctx, EVP_md5(), NULL) && EVP_DigestUpdate(md_ctx, x->bytes->data, x->bytes->length) && EVP_DigestFinal_ex(md_ctx, md, NULL)) ret = (((unsigned long)md[0]) | ((unsigned long)md[1] << 8L) | ((unsigned long)md[2] << 16L) | ((unsigned long)md[3] << 24L) ) & 0xffffffffL; EVP_MD_CTX_free(md_ctx); return ret; } #endif /* Search a stack of X509 for a match */ X509 *X509_find_by_issuer_and_serial(STACK_OF(X509) *sk, X509_NAME *name, ASN1_INTEGER *serial) { int i; X509 x, *x509 = NULL; if (!sk) return NULL; x.cert_info.serialNumber = *serial; x.cert_info.issuer = name; for (i = 0; i < sk_X509_num(sk); i++) { x509 = sk_X509_value(sk, i); if (X509_issuer_and_serial_cmp(x509, &x) == 0) return x509; } return NULL; } X509 *X509_find_by_subject(STACK_OF(X509) *sk, X509_NAME *name) { X509 *x509; int i; for (i = 0; i < sk_X509_num(sk); i++) { x509 = sk_X509_value(sk, i); if (X509_NAME_cmp(X509_get_subject_name(x509), name) == 0) return x509; } return NULL; } EVP_PKEY *X509_get0_pubkey(const X509 *x) { if (x == NULL) return NULL; return X509_PUBKEY_get0(x->cert_info.key); } EVP_PKEY *X509_get_pubkey(X509 *x) { if (x == NULL) return NULL; return X509_PUBKEY_get(x->cert_info.key); } int X509_check_private_key(const X509 *x, const EVP_PKEY *k) { const EVP_PKEY *xk; int ret; xk = X509_get0_pubkey(x); if (xk) ret = EVP_PKEY_cmp(xk, k); else ret = -2; switch (ret) { case 1: break; case 0: X509err(X509_F_X509_CHECK_PRIVATE_KEY, X509_R_KEY_VALUES_MISMATCH); break; case -1: X509err(X509_F_X509_CHECK_PRIVATE_KEY, X509_R_KEY_TYPE_MISMATCH); break; case -2: X509err(X509_F_X509_CHECK_PRIVATE_KEY, X509_R_UNKNOWN_KEY_TYPE); } if (ret > 0) return 1; return 0; } /* * Check a suite B algorithm is permitted: pass in a public key and the NID * of its signature (or 0 if no signature). The pflags is a pointer to a * flags field which must contain the suite B verification flags. */ #ifndef OPENSSL_NO_EC static int check_suite_b(EVP_PKEY *pkey, int sign_nid, unsigned long *pflags) { const EC_GROUP *grp = NULL; int curve_nid; if (pkey && EVP_PKEY_id(pkey) == EVP_PKEY_EC) grp = EC_KEY_get0_group(EVP_PKEY_get0_EC_KEY(pkey)); if (!grp) return X509_V_ERR_SUITE_B_INVALID_ALGORITHM; curve_nid = EC_GROUP_get_curve_name(grp); /* Check curve is consistent with LOS */ if (curve_nid == NID_secp384r1) { /* P-384 */ /* * Check signature algorithm is consistent with curve. */ if (sign_nid != -1 && sign_nid != NID_ecdsa_with_SHA384) return X509_V_ERR_SUITE_B_INVALID_SIGNATURE_ALGORITHM; if (!(*pflags & X509_V_FLAG_SUITEB_192_LOS)) return X509_V_ERR_SUITE_B_LOS_NOT_ALLOWED; /* If we encounter P-384 we cannot use P-256 later */ *pflags &= ~X509_V_FLAG_SUITEB_128_LOS_ONLY; } else if (curve_nid == NID_X9_62_prime256v1) { /* P-256 */ if (sign_nid != -1 && sign_nid != NID_ecdsa_with_SHA256) return X509_V_ERR_SUITE_B_INVALID_SIGNATURE_ALGORITHM; if (!(*pflags & X509_V_FLAG_SUITEB_128_LOS_ONLY)) return X509_V_ERR_SUITE_B_LOS_NOT_ALLOWED; } else return X509_V_ERR_SUITE_B_INVALID_CURVE; return X509_V_OK; } int X509_chain_check_suiteb(int *perror_depth, X509 *x, STACK_OF(X509) *chain, unsigned long flags) { int rv, i, sign_nid; EVP_PKEY *pk; unsigned long tflags = flags; if (!(flags & X509_V_FLAG_SUITEB_128_LOS)) return X509_V_OK; /* If no EE certificate passed in must be first in chain */ if (x == NULL) { x = sk_X509_value(chain, 0); i = 1; } else i = 0; pk = X509_get0_pubkey(x); /* * With DANE-EE(3) success, or DANE-EE(3)/PKIX-EE(1) failure we don't build * a chain all, just report trust success or failure, but must also report * Suite-B errors if applicable. This is indicated via a NULL chain * pointer. All we need to do is check the leaf key algorithm. */ if (chain == NULL) return check_suite_b(pk, -1, &tflags); if (X509_get_version(x) != 2) { rv = X509_V_ERR_SUITE_B_INVALID_VERSION; /* Correct error depth */ i = 0; goto end; } /* Check EE key only */ rv = check_suite_b(pk, -1, &tflags); if (rv != X509_V_OK) { /* Correct error depth */ i = 0; goto end; } for (; i < sk_X509_num(chain); i++) { sign_nid = X509_get_signature_nid(x); x = sk_X509_value(chain, i); if (X509_get_version(x) != 2) { rv = X509_V_ERR_SUITE_B_INVALID_VERSION; goto end; } pk = X509_get0_pubkey(x); rv = check_suite_b(pk, sign_nid, &tflags); if (rv != X509_V_OK) goto end; } /* Final check: root CA signature */ rv = check_suite_b(pk, X509_get_signature_nid(x), &tflags); end: if (rv != X509_V_OK) { /* Invalid signature or LOS errors are for previous cert */ if ((rv == X509_V_ERR_SUITE_B_INVALID_SIGNATURE_ALGORITHM || rv == X509_V_ERR_SUITE_B_LOS_NOT_ALLOWED) && i) i--; /* * If we have LOS error and flags changed then we are signing P-384 * with P-256. Use more meaningful error. */ if (rv == X509_V_ERR_SUITE_B_LOS_NOT_ALLOWED && flags != tflags) rv = X509_V_ERR_SUITE_B_CANNOT_SIGN_P_384_WITH_P_256; if (perror_depth) *perror_depth = i; } return rv; } int X509_CRL_check_suiteb(X509_CRL *crl, EVP_PKEY *pk, unsigned long flags) { int sign_nid; if (!(flags & X509_V_FLAG_SUITEB_128_LOS)) return X509_V_OK; sign_nid = OBJ_obj2nid(crl->crl.sig_alg.algorithm); return check_suite_b(pk, sign_nid, &flags); } #else int X509_chain_check_suiteb(int *perror_depth, X509 *x, STACK_OF(X509) *chain, unsigned long flags) { return 0; } int X509_CRL_check_suiteb(X509_CRL *crl, EVP_PKEY *pk, unsigned long flags) { return 0; } #endif /* * Not strictly speaking an "up_ref" as a STACK doesn't have a reference * count but it has the same effect by duping the STACK and upping the ref of * each X509 structure. */ STACK_OF(X509) *X509_chain_up_ref(STACK_OF(X509) *chain) { STACK_OF(X509) *ret; int i; ret = sk_X509_dup(chain); if (ret == NULL) return NULL; for (i = 0; i < sk_X509_num(ret); i++) { X509 *x = sk_X509_value(ret, i); if (!X509_up_ref(x)) goto err; } return ret; err: while (i-- > 0) X509_free (sk_X509_value(ret, i)); sk_X509_free(ret); return NULL; } #ifndef OPENSSL_NO_DELEGATED_CREDENTIAL int DC_check_private_key(DELEGATED_CREDENTIAL *dc, EVP_PKEY *pkey) { EVP_PKEY *pub_key; int ret; pub_key = dc->pkey; if (pub_key) ret = EVP_PKEY_cmp(pub_key, pkey); else ret = -2; switch (ret) { case 1: break; case 0: X509err(X509_F_DC_CHECK_PRIVATE_KEY, X509_R_KEY_VALUES_MISMATCH); break; case -1: X509err(X509_F_DC_CHECK_PRIVATE_KEY, X509_R_KEY_TYPE_MISMATCH); break; case -2: X509err(X509_F_DC_CHECK_PRIVATE_KEY, X509_R_UNKNOWN_KEY_TYPE); } if (ret > 0) return 1; return 0; } int DC_check_valid(X509 *parent_cert, DELEGATED_CREDENTIAL *dc) { /* * check if dc time expire */ if (!DC_check_time_valid(parent_cert, dc)) return 0; /* * check dc parent_cert has DelegationUsage extension. * check dc parent_cert has the digitalSignature KeyUsage * see https://tools.ietf.org/html/draft-ietf-tls-subcerts-07#section-4.2 */ if (!DC_check_parent_cert_valid(parent_cert)) return 0; return 1; } int DC_check_time_valid(X509 *parent_cert, DELEGATED_CREDENTIAL *dc) { ASN1_TIME *time; struct tm tm; int ret = 0; time = ASN1_STRING_dup(X509_get0_notBefore(parent_cert)); if (time == NULL) goto err; if (!ASN1_TIME_to_tm(time, &tm)) goto err; if (ASN1_TIME_adj(time, mktime(&tm), 0, DC_get_valid_time(dc)) == NULL) goto err; if (X509_cmp_time(time, NULL) <= 0) goto err; ret = 1; err: ASN1_STRING_clear_free(time); return ret; } int DC_check_parent_cert_valid(X509 *parent_cert) { const STACK_OF(X509_EXTENSION) *exts; int i; if ((X509_get_key_usage(parent_cert) & X509v3_KU_DIGITAL_SIGNATURE) == 0) return 0; exts = X509_get0_extensions(parent_cert); for (i = 0; i < sk_X509_EXTENSION_num(exts); i++) { ASN1_OBJECT *obj; X509_EXTENSION *ex; ex = sk_X509_EXTENSION_value(exts, i); obj = X509_EXTENSION_get_object(ex); if (OBJ_obj2nid(obj) == NID_delegation_usage) { int critical; critical = X509_EXTENSION_get_critical(ex); if (critical == 1) return 0; return 1; } } return 0; } unsigned long DC_get_valid_time(DELEGATED_CREDENTIAL *dc) { return dc->valid_time; } unsigned int DC_get_expected_cert_verify_algorithm(DELEGATED_CREDENTIAL *dc) { return dc->expected_cert_verify_algorithm; } unsigned long DC_get_dc_publickey_raw_len(DELEGATED_CREDENTIAL *dc) { return dc->dc_publickey_raw_len; } unsigned char *DC_get0_dc_publickey_raw(DELEGATED_CREDENTIAL *dc) { return dc->dc_publickey_raw; } unsigned int DC_get_signature_sign_algorithm(DELEGATED_CREDENTIAL *dc) { return dc->signature_sign_algorithm; } unsigned int DC_get_dc_signature_len(DELEGATED_CREDENTIAL *dc) { return dc->dc_signature_len; } unsigned char *DC_get0_dc_signature(DELEGATED_CREDENTIAL *dc) { return dc->dc_signature; } EVP_PKEY *DC_get0_publickey(DELEGATED_CREDENTIAL *dc) { return dc->pkey; } unsigned char *DC_get0_raw_byte(DELEGATED_CREDENTIAL *dc) { return dc->raw_byte; } unsigned long DC_get_raw_byte_len(DELEGATED_CREDENTIAL *dc) { return dc->raw_byte_len; } int DC_set_valid_time(DELEGATED_CREDENTIAL *dc, unsigned long valid_time) { if (dc == NULL) return 0; dc->valid_time = valid_time; return 1; } int DC_set_expected_cert_verify_algorithm(DELEGATED_CREDENTIAL *dc, unsigned int alg) { if (dc == NULL) return 0; dc->expected_cert_verify_algorithm = alg; return 1; } int DC_set_dc_publickey_len(DELEGATED_CREDENTIAL *dc, unsigned long len) { if (dc == NULL) return 0; dc->dc_publickey_raw_len = len; return 1; } int DC_set0_dc_publickey(DELEGATED_CREDENTIAL *dc, unsigned char *pub_key) { if (dc == NULL) return 0; dc->dc_publickey_raw = pub_key; return 1; } int DC_set_signature_sign_algorithm(DELEGATED_CREDENTIAL *dc, unsigned int alg) { if (dc == NULL) return 0; dc->signature_sign_algorithm = alg; return 1; } int DC_set_dc_signature_len(DELEGATED_CREDENTIAL *dc, unsigned int len) { if (dc == NULL) return 0; dc->dc_signature_len = len; return 1; } int DC_set0_dc_signature(DELEGATED_CREDENTIAL *dc, unsigned char *sig) { if (dc == NULL) return 0; dc->dc_signature = sig; return 1; } int DC_set0_publickey(DELEGATED_CREDENTIAL *dc, EVP_PKEY *pkey) { if (dc == NULL) return 0; dc->pkey = pkey; return 1; } int DC_set0_raw_byte(DELEGATED_CREDENTIAL *dc, unsigned char *byte, unsigned long len) { if (dc == NULL) return 0; if (dc->raw_byte && dc->raw_byte != byte) OPENSSL_free(dc->raw_byte); dc->raw_byte = byte; dc->raw_byte_len = len; return 1; } int DC_set1_raw_byte(DELEGATED_CREDENTIAL *dc, const unsigned char *byte, unsigned long len) { unsigned char *raw_byte = NULL; if (dc == NULL || byte == NULL || len <= 0) return 0; if (dc->raw_byte == byte) { dc->raw_byte_len = len; return 1; } raw_byte = OPENSSL_malloc(len); if (raw_byte == NULL) return 0; if (dc->raw_byte) { OPENSSL_free(dc->raw_byte); } memcpy(raw_byte, byte, len); dc->raw_byte = raw_byte; dc->raw_byte_len = len; return 1; } #endif