\ Copyright (c) 2016 Thomas Pornin \ \ Permission is hereby granted, free of charge, to any person obtaining \ a copy of this software and associated documentation files (the \ "Software"), to deal in the Software without restriction, including \ without limitation the rights to use, copy, modify, merge, publish, \ distribute, sublicense, and/or sell copies of the Software, and to \ permit persons to whom the Software is furnished to do so, subject to \ the following conditions: \ \ The above copyright notice and this permission notice shall be \ included in all copies or substantial portions of the Software. \ \ THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, \ EXPRESS OR IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF \ MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE AND \ NONINFRINGEMENT. IN NO EVENT SHALL THE AUTHORS OR COPYRIGHT HOLDERS \ BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER LIABILITY, WHETHER IN AN \ ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM, OUT OF OR IN \ CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE \ SOFTWARE. preamble { #include "inner.h" /* * Implementation Notes * -------------------- * * The C code pushes the data by chunks; all decoding is done in the * T0 code. The cert_length value is set to the certificate length when * a new certificate is started; the T0 code picks it up as outer limit, * and decoding functions use it to ensure that no attempt is made at * reading past it. The T0 code also checks that once the certificate is * decoded, there are no trailing bytes. * * The T0 code sets cert_length to 0 when the certificate is fully * decoded. * * The C code must still perform two checks: * * -- If the certificate length is 0, then the T0 code will not be * invoked at all. This invalid condition must thus be reported by the * C code. * * -- When reaching the end of certificate, the C code must verify that * the certificate length has been set to 0, thereby signaling that * the T0 code properly decoded a certificate. * * Processing of a chain works in the following way: * * -- The error flag is set to a non-zero value when validation is * finished. The value is either BR_ERR_X509_OK (validation is * successful) or another non-zero error code. When a non-zero error * code is obtained, the remaining bytes in the current certificate and * the subsequent certificates (if any) are completely ignored. * * -- Each certificate is decoded in due course, with the following * "interesting points": * * -- Start of the TBS: the multihash engine is reset and activated. * * -- Start of the issuer DN: the secondary hash engine is started, * to process the encoded issuer DN. * * -- End of the issuer DN: the secondary hash engine is stopped. The * resulting hash value is computed and then copied into the * next_dn_hash[] buffer. * * -- Start of the subject DN: the secondary hash engine is started, * to process the encoded subject DN. * * -- For the EE certificate only: the Common Name, if any, is matched * against the expected server name. * * -- End of the subject DN: the secondary hash engine is stopped. The * resulting hash value is computed into the pad. It is then processed: * * -- If this is the EE certificate, then the hash is ignored * (except for direct trust processing, see later; the hash is * simply left in current_dn_hash[]). * * -- Otherwise, the hashed subject DN is compared with the saved * hash value (in saved_dn_hash[]). They must match. * * Either way, the next_dn_hash[] value is then copied into the * saved_dn_hash[] value. Thus, at that point, saved_dn_hash[] * contains the hash of the issuer DN for the current certificate, * and current_dn_hash[] contains the hash of the subject DN for the * current certificate. * * -- Public key: it is decoded into the cert_pkey[] buffer. Unknown * key types are reported at that point. * * -- If this is the EE certificate, then the key type is compared * with the expected key type (initialization parameter). The public * key data is copied to ee_pkey_data[]. The key and hashed subject * DN are also compared with the "direct trust" keys; if the key * and DN are matched, then validation ends with a success. * * -- Otherwise, the saved signature (cert_sig[]) is verified * against the saved TBS hash (tbs_hash[]) and that freshly * decoded public key. Failure here ends validation with an error. * * -- Extensions: extension values are processed in due order. * * -- Basic Constraints: for all certificates except EE, must be * present, indicate a CA, and have a path length compatible with * the chain length so far. * * -- Key Usage: for the EE, if present, must allow signatures * or encryption/key exchange, as required for the cipher suite. * For non-EE, if present, must have the "certificate sign" bit. * * -- Subject Alt Name: for the EE, dNSName names are matched * against the server name. Ignored for non-EE. * * -- Authority Key Identifier, Subject Key Identifier, Issuer * Alt Name, Subject Directory Attributes, CRL Distribution Points * Freshest CRL, Authority Info Access and Subject Info Access * extensions are always ignored: they either contain only * informative data, or they relate to revocation processing, which * we explicitly do not support. * * -- All other extensions are ignored if non-critical. If a * critical extension other than the ones above is encountered, * then a failure is reported. * * -- End of the TBS: the multihash engine is stopped. * * -- Signature algorithm: the signature algorithm on the * certificate is decoded. A failure is reported if that algorithm * is unknown. The hashed TBS corresponding to the signature hash * function is computed and stored in tbs_hash[] (if not supported, * then a failure is reported). The hash OID and length are stored * in cert_sig_hash_oid and cert_sig_hash_len. * * -- Signature value: the signature value is copied into the * cert_sig[] array. * * -- Certificate end: the hashed issuer DN (saved_dn_hash[]) is * looked up in the trust store (CA trust anchors only); for all * that match, the signature (cert_sig[]) is verified against the * anchor public key (hashed TBS is in tbs_hash[]). If one of these * signatures is valid, then validation ends with a success. * * -- If the chain end is reached without obtaining a validation success, * then validation is reported as failed. */ #if BR_USE_UNIX_TIME #include #endif #if BR_USE_WIN32_TIME #include #endif /* * The T0 compiler will produce these prototypes declarations in the * header. * void br_x509_minimal_init_main(void *ctx); void br_x509_minimal_run(void *ctx); */ /* see bearssl_x509.h */ void br_x509_minimal_init(br_x509_minimal_context *ctx, const br_hash_class *dn_hash_impl, const br_x509_trust_anchor *trust_anchors, size_t trust_anchors_num) { memset(ctx, 0, sizeof *ctx); ctx->vtable = &br_x509_minimal_vtable; ctx->dn_hash_impl = dn_hash_impl; ctx->trust_anchors = trust_anchors; ctx->trust_anchors_num = trust_anchors_num; } static void xm_start_chain(const br_x509_class **ctx, const char *server_name) { br_x509_minimal_context *cc; size_t u; cc = (br_x509_minimal_context *)(void *)ctx; for (u = 0; u < cc->num_name_elts; u ++) { cc->name_elts[u].status = 0; cc->name_elts[u].buf[0] = 0; } memset(&cc->pkey, 0, sizeof cc->pkey); cc->num_certs = 0; cc->err = 0; cc->cpu.dp = cc->dp_stack; cc->cpu.rp = cc->rp_stack; br_x509_minimal_init_main(&cc->cpu); if (server_name == NULL || *server_name == 0) { cc->server_name = NULL; } else { cc->server_name = server_name; } } static void xm_start_cert(const br_x509_class **ctx, uint32_t length) { br_x509_minimal_context *cc; cc = (br_x509_minimal_context *)(void *)ctx; if (cc->err != 0) { return; } if (length == 0) { cc->err = BR_ERR_X509_TRUNCATED; return; } cc->cert_length = length; } static void xm_append(const br_x509_class **ctx, const unsigned char *buf, size_t len) { br_x509_minimal_context *cc; cc = (br_x509_minimal_context *)(void *)ctx; if (cc->err != 0) { return; } cc->hbuf = buf; cc->hlen = len; br_x509_minimal_run(&cc->cpu); } static void xm_end_cert(const br_x509_class **ctx) { br_x509_minimal_context *cc; cc = (br_x509_minimal_context *)(void *)ctx; if (cc->err == 0 && cc->cert_length != 0) { cc->err = BR_ERR_X509_TRUNCATED; } cc->num_certs ++; } static unsigned xm_end_chain(const br_x509_class **ctx) { br_x509_minimal_context *cc; cc = (br_x509_minimal_context *)(void *)ctx; if (cc->err == 0) { if (cc->num_certs == 0) { cc->err = BR_ERR_X509_EMPTY_CHAIN; } else { cc->err = BR_ERR_X509_NOT_TRUSTED; } } else if (cc->err == BR_ERR_X509_OK) { return 0; } return (unsigned)cc->err; } static const br_x509_pkey * xm_get_pkey(const br_x509_class *const *ctx, unsigned *usages) { br_x509_minimal_context *cc; cc = (br_x509_minimal_context *)(void *)ctx; if (cc->err == BR_ERR_X509_OK || cc->err == BR_ERR_X509_NOT_TRUSTED) { if (usages != NULL) { *usages = cc->key_usages; } return &((br_x509_minimal_context *)(void *)ctx)->pkey; } else { return NULL; } } /* see bearssl_x509.h */ const br_x509_class br_x509_minimal_vtable = { sizeof(br_x509_minimal_context), xm_start_chain, xm_start_cert, xm_append, xm_end_cert, xm_end_chain, xm_get_pkey }; #define CTX ((br_x509_minimal_context *)(void *)((unsigned char *)t0ctx - offsetof(br_x509_minimal_context, cpu))) #define CONTEXT_NAME br_x509_minimal_context #define DNHASH_LEN ((CTX->dn_hash_impl->desc >> BR_HASHDESC_OUT_OFF) & BR_HASHDESC_OUT_MASK) /* * Hash a DN (from a trust anchor) into the provided buffer. This uses the * DN hash implementation and context structure from the X.509 engine * context. */ static void hash_dn(br_x509_minimal_context *ctx, const void *dn, size_t len, unsigned char *out) { ctx->dn_hash_impl->init(&ctx->dn_hash.vtable); ctx->dn_hash_impl->update(&ctx->dn_hash.vtable, dn, len); ctx->dn_hash_impl->out(&ctx->dn_hash.vtable, out); } /* * Compare two big integers for equality. The integers use unsigned big-endian * encoding; extra leading bytes (of value 0) are allowed. */ static int eqbigint(const unsigned char *b1, size_t len1, const unsigned char *b2, size_t len2) { while (len1 > 0 && *b1 == 0) { b1 ++; len1 --; } while (len2 > 0 && *b2 == 0) { b2 ++; len2 --; } if (len1 != len2) { return 0; } return memcmp(b1, b2, len1) == 0; } /* * Compare two strings for equality, in a case-insensitive way. This * function handles casing only for ASCII letters. */ static int eqnocase(const void *s1, const void *s2, size_t len) { const unsigned char *buf1, *buf2; buf1 = s1; buf2 = s2; while (len -- > 0) { int x1, x2; x1 = *buf1 ++; x2 = *buf2 ++; if (x1 >= 'A' && x1 <= 'Z') { x1 += 'a' - 'A'; } if (x2 >= 'A' && x2 <= 'Z') { x2 += 'a' - 'A'; } if (x1 != x2) { return 0; } } return 1; } static int verify_signature(br_x509_minimal_context *ctx, const br_x509_pkey *pk); } postamble { /* * Verify the signature on the certificate with the provided public key. * This function checks the public key type with regards to the expected * type. Returned value is either 0 on success, or a non-zero error code. */ static int verify_signature(br_x509_minimal_context *ctx, const br_x509_pkey *pk) { int kt; kt = ctx->cert_signer_key_type; if ((pk->key_type & 0x0F) != kt) { return BR_ERR_X509_WRONG_KEY_TYPE; } switch (kt) { unsigned char tmp[64]; case BR_KEYTYPE_RSA: if (ctx->irsa == 0) { return BR_ERR_X509_UNSUPPORTED; } if (!ctx->irsa(ctx->cert_sig, ctx->cert_sig_len, &t0_datablock[ctx->cert_sig_hash_oid], ctx->cert_sig_hash_len, &pk->key.rsa, tmp)) { return BR_ERR_X509_BAD_SIGNATURE; } if (memcmp(ctx->tbs_hash, tmp, ctx->cert_sig_hash_len) != 0) { return BR_ERR_X509_BAD_SIGNATURE; } return 0; case BR_KEYTYPE_EC: if (ctx->iecdsa == 0) { return BR_ERR_X509_UNSUPPORTED; } if (!ctx->iecdsa(ctx->iec, ctx->tbs_hash, ctx->cert_sig_hash_len, &pk->key.ec, ctx->cert_sig, ctx->cert_sig_len)) { return BR_ERR_X509_BAD_SIGNATURE; } return 0; default: return BR_ERR_X509_UNSUPPORTED; } } } cc: read8-low ( -- x ) { if (CTX->hlen == 0) { T0_PUSHi(-1); } else { unsigned char x = *CTX->hbuf ++; if (CTX->do_mhash) { br_multihash_update(&CTX->mhash, &x, 1); } if (CTX->do_dn_hash) { CTX->dn_hash_impl->update(&CTX->dn_hash.vtable, &x, 1); } CTX->hlen --; T0_PUSH(x); } } addr: cert_length addr: num_certs cc: read-blob-inner ( addr len -- addr len ) { uint32_t len = T0_POP(); uint32_t addr = T0_POP(); size_t clen = CTX->hlen; if (clen > len) { clen = (size_t)len; } if (addr != 0) { memcpy((unsigned char *)CTX + addr, CTX->hbuf, clen); } if (CTX->do_mhash) { br_multihash_update(&CTX->mhash, CTX->hbuf, clen); } if (CTX->do_dn_hash) { CTX->dn_hash_impl->update( &CTX->dn_hash.vtable, CTX->hbuf, clen); } CTX->hbuf += clen; CTX->hlen -= clen; T0_PUSH(addr + clen); T0_PUSH(len - clen); } \ Compute the TBS hash, using the provided hash ID. The hash value is \ written in the tbs_hash[] array, and the hash length is returned. If \ the requested hash function is not supported, then 0 is returned. cc: compute-tbs-hash ( id -- hashlen ) { int id = T0_POPi(); size_t len; len = br_multihash_out(&CTX->mhash, id, CTX->tbs_hash); T0_PUSH(len); } \ Push true (-1) if no server name is expected in the EE certificate. cc: zero-server-name ( -- bool ) { T0_PUSHi(-(CTX->server_name == NULL)); } addr: key_usages addr: cert_sig addr: cert_sig_len addr: cert_signer_key_type addr: cert_sig_hash_oid addr: cert_sig_hash_len addr: tbs_hash addr: min_rsa_size \ Start TBS hash computation. The hash functions are reinitialised. cc: start-tbs-hash ( -- ) { br_multihash_init(&CTX->mhash); CTX->do_mhash = 1; } \ Stop TBS hash computation. cc: stop-tbs-hash ( -- ) { CTX->do_mhash = 0; } \ Start DN hash computation. cc: start-dn-hash ( -- ) { CTX->dn_hash_impl->init(&CTX->dn_hash.vtable); CTX->do_dn_hash = 1; } \ Terminate DN hash computation and write the DN hash into the \ current_dn_hash buffer. cc: compute-dn-hash ( -- ) { CTX->dn_hash_impl->out(&CTX->dn_hash.vtable, CTX->current_dn_hash); CTX->do_dn_hash = 0; } \ Get the length of hash values obtained with the DN hasher. cc: dn-hash-length ( -- len ) { T0_PUSH(DNHASH_LEN); } \ Copy data between two areas in the context. cc: blobcopy ( addr-dst addr-src len -- ) { size_t len = T0_POP(); unsigned char *src = (unsigned char *)CTX + T0_POP(); unsigned char *dst = (unsigned char *)CTX + T0_POP(); memcpy(dst, src, len); } addr: current_dn_hash addr: next_dn_hash addr: saved_dn_hash \ Read a DN, hashing it into current_dn_hash. The DN contents are not \ inspected (only the outer tag, for SEQUENCE, is checked). : read-DN ( lim -- lim ) start-dn-hash read-sequence-open skip-close-elt compute-dn-hash ; cc: offset-name-element ( san -- n ) { unsigned san = T0_POP(); size_t u; for (u = 0; u < CTX->num_name_elts; u ++) { if (CTX->name_elts[u].status == 0) { const unsigned char *oid; size_t len, off; oid = CTX->name_elts[u].oid; if (san) { if (oid[0] != 0 || oid[1] != 0) { continue; } off = 2; } else { off = 0; } len = oid[off]; if (len != 0 && len == CTX->pad[0] && memcmp(oid + off + 1, CTX->pad + 1, len) == 0) { T0_PUSH(u); T0_RET(); } } } T0_PUSHi(-1); } cc: copy-name-element ( bool offbuf -- ) { size_t len; int32_t off = T0_POPi(); int ok = T0_POPi(); if (off >= 0) { br_name_element *ne = &CTX->name_elts[off]; if (ok) { len = CTX->pad[0]; if (len < ne->len) { memcpy(ne->buf, CTX->pad + 1, len); ne->buf[len] = 0; ne->status = 1; } else { ne->status = -1; } } else { ne->status = -1; } } } cc: copy-name-SAN ( bool tag -- ) { unsigned tag = T0_POP(); unsigned ok = T0_POP(); size_t u, len; len = CTX->pad[0]; for (u = 0; u < CTX->num_name_elts; u ++) { br_name_element *ne; ne = &CTX->name_elts[u]; if (ne->status == 0 && ne->oid[0] == 0 && ne->oid[1] == tag) { if (ok && ne->len > len) { memcpy(ne->buf, CTX->pad + 1, len); ne->buf[len] = 0; ne->status = 1; } else { ne->status = -1; } break; } } } \ Read a value, decoding string types. If the string type is recognised \ and the value could be converted to UTF-8 into the pad, then true (-1) \ is returned; in all other cases, false (0) is returned. Either way, the \ object is consumed. : read-string ( lim -- lim bool ) read-tag case \ UTF8String 12 of check-primitive read-value-UTF8 endof \ NumericString 18 of check-primitive read-value-latin1 endof \ PrintableString 19 of check-primitive read-value-latin1 endof \ TeletexString 20 of check-primitive read-value-latin1 endof \ IA5String 22 of check-primitive read-value-latin1 endof \ BMPString 30 of check-primitive read-value-UTF16 endof 2drop read-length-skip 0 0 endcase ; \ Read a DN for the EE. The normalized DN hash is computed and stored in the \ current_dn_hash. \ Name elements are gathered. Also, the Common Name is matched against the \ intended server name. \ Returned value is true (-1) if the CN matches the intended server name, \ false (0) otherwise. : read-DN-EE ( lim -- lim bool ) \ Flag will be set to true if there is a CN and it matches the \ intended server name. 0 { eename-matches } \ Activate DN hashing. start-dn-hash \ Parse the DN structure: it is a SEQUENCE of SET of \ AttributeTypeAndValue. Each AttributeTypeAndValue is a \ SEQUENCE { OBJECT IDENTIFIER, ANY }. read-sequence-open begin dup while read-tag 0x11 check-tag-constructed read-length-open-elt dup ifnot ERR_X509_BAD_DN fail then begin dup while read-sequence-open \ Read the OID. If the OID could not be read (too \ long) then the first pad byte will be 0. read-OID drop \ If it is the Common Name then we'll need to \ match it against the intended server name (if \ applicable). id-at-commonName eqOID { isCN } \ Get offset for reception buffer for that element \ (or -1). 0 offset-name-element { offbuf } \ Try to read the value as a string. read-string \ If the value could be decoded as a string, \ copy it and/or match it, as appropriate. dup isCN and if match-server-name if -1 >eename-matches then then offbuf copy-name-element \ Close the SEQUENCE close-elt repeat close-elt repeat close-elt \ Compute DN hash and deactivate DN hashing. compute-dn-hash \ Return the CN match flag. eename-matches ; \ Check the provided validity range against the current (or configured) \ date and time ("na" = notAfter, "nb = notBefore). Returned value: \ -1 current date/time is before the notBefore date \ 0 current date/time is within the allowed range \ +1 current date/time is after the notAfter range \ If the current date/time is not available, then this function triggers a \ failure and does not return. cc: check-validity-range ( na-days na-seconds nb-days nb-seconds -- int ) { uint32_t nbs = T0_POP(); uint32_t nbd = T0_POP(); uint32_t nas = T0_POP(); uint32_t nad = T0_POP(); int r; if (CTX->itime != 0) { r = CTX->itime(CTX->itime_ctx, nbd, nbs, nad, nas); if (r < -1 || r > 1) { CTX->err = BR_ERR_X509_TIME_UNKNOWN; T0_CO(); } } else { uint32_t vd = CTX->days; uint32_t vs = CTX->seconds; if (vd == 0 && vs == 0) { #if BR_USE_UNIX_TIME time_t x = time(NULL); vd = (uint32_t)(x / 86400) + 719528; vs = (uint32_t)(x % 86400); #elif BR_USE_WIN32_TIME FILETIME ft; uint64_t x; GetSystemTimeAsFileTime(&ft); x = ((uint64_t)ft.dwHighDateTime << 32) + (uint64_t)ft.dwLowDateTime; x = (x / 10000000); vd = (uint32_t)(x / 86400) + 584754; vs = (uint32_t)(x % 86400); #else CTX->err = BR_ERR_X509_TIME_UNKNOWN; T0_CO(); #endif } if (vd < nbd || (vd == nbd && vs < nbs)) { r = -1; } else if (vd > nad || (vd == nad && vs > nas)) { r = 1; } else { r = 0; } } T0_PUSHi(r); } \ Swap the top two elements with the two elements immediately below. : swap2 ( a b c d -- c d a b ) 3 roll 3 roll ; \ Match the name in the pad with the expected server name. Returned value \ is true (-1) on match, false (0) otherwise. If there is no expected \ server name, then 0 is returned. \ Match conditions: either an exact match (case insensitive), or a \ wildcard match, if the found name starts with "*.". We only match a \ starting wildcard, and only against a complete DN name component. cc: match-server-name ( -- bool ) { size_t n1, n2; if (CTX->server_name == NULL) { T0_PUSH(0); T0_RET(); } n1 = strlen(CTX->server_name); n2 = CTX->pad[0]; if (n1 == n2 && eqnocase(&CTX->pad[1], CTX->server_name, n1)) { T0_PUSHi(-1); T0_RET(); } if (n2 >= 2 && CTX->pad[1] == '*' && CTX->pad[2] == '.') { size_t u; u = 0; while (u < n1 && CTX->server_name[u] != '.') { u ++; } u ++; n1 -= u; if ((n2 - 2) == n1 && eqnocase(&CTX->pad[3], CTX->server_name + u, n1)) { T0_PUSHi(-1); T0_RET(); } } T0_PUSH(0); } \ Get the address and length for the pkey_data buffer. : addr-len-pkey_data ( -- addr len ) CX 0 8191 { offsetof(br_x509_minimal_context, pkey_data) } CX 0 8191 { BR_X509_BUFSIZE_KEY } ; \ Copy the EE public key to the permanent buffer (RSA). cc: copy-ee-rsa-pkey ( nlen elen -- ) { size_t elen = T0_POP(); size_t nlen = T0_POP(); memcpy(CTX->ee_pkey_data, CTX->pkey_data, nlen + elen); CTX->pkey.key_type = BR_KEYTYPE_RSA; CTX->pkey.key.rsa.n = CTX->ee_pkey_data; CTX->pkey.key.rsa.nlen = nlen; CTX->pkey.key.rsa.e = CTX->ee_pkey_data + nlen; CTX->pkey.key.rsa.elen = elen; } \ Copy the EE public key to the permanent buffer (EC). cc: copy-ee-ec-pkey ( curve qlen -- ) { size_t qlen = T0_POP(); uint32_t curve = T0_POP(); memcpy(CTX->ee_pkey_data, CTX->pkey_data, qlen); CTX->pkey.key_type = BR_KEYTYPE_EC; CTX->pkey.key.ec.curve = curve; CTX->pkey.key.ec.q = CTX->ee_pkey_data; CTX->pkey.key.ec.qlen = qlen; } \ Check whether the current certificate (EE) is directly trusted. cc: check-direct-trust ( -- ) { size_t u; for (u = 0; u < CTX->trust_anchors_num; u ++) { const br_x509_trust_anchor *ta; unsigned char hashed_DN[64]; int kt; ta = &CTX->trust_anchors[u]; if (ta->flags & BR_X509_TA_CA) { continue; } hash_dn(CTX, ta->dn.data, ta->dn.len, hashed_DN); if (memcmp(hashed_DN, CTX->current_dn_hash, DNHASH_LEN)) { continue; } kt = CTX->pkey.key_type; if ((ta->pkey.key_type & 0x0F) != kt) { continue; } switch (kt) { case BR_KEYTYPE_RSA: if (!eqbigint(CTX->pkey.key.rsa.n, CTX->pkey.key.rsa.nlen, ta->pkey.key.rsa.n, ta->pkey.key.rsa.nlen) || !eqbigint(CTX->pkey.key.rsa.e, CTX->pkey.key.rsa.elen, ta->pkey.key.rsa.e, ta->pkey.key.rsa.elen)) { continue; } break; case BR_KEYTYPE_EC: if (CTX->pkey.key.ec.curve != ta->pkey.key.ec.curve || CTX->pkey.key.ec.qlen != ta->pkey.key.ec.qlen || memcmp(CTX->pkey.key.ec.q, ta->pkey.key.ec.q, ta->pkey.key.ec.qlen) != 0) { continue; } break; default: continue; } /* * Direct trust match! */ CTX->err = BR_ERR_X509_OK; T0_CO(); } } \ Check the signature on the certificate with regards to all trusted CA. \ We use the issuer hash (in saved_dn_hash[]) as CA identifier. cc: check-trust-anchor-CA ( -- ) { size_t u; for (u = 0; u < CTX->trust_anchors_num; u ++) { const br_x509_trust_anchor *ta; unsigned char hashed_DN[64]; ta = &CTX->trust_anchors[u]; if (!(ta->flags & BR_X509_TA_CA)) { continue; } hash_dn(CTX, ta->dn.data, ta->dn.len, hashed_DN); if (memcmp(hashed_DN, CTX->saved_dn_hash, DNHASH_LEN)) { continue; } if (verify_signature(CTX, &ta->pkey) == 0) { CTX->err = BR_ERR_X509_OK; T0_CO(); } } } \ Verify RSA signature. This uses the public key that was just decoded \ into CTX->pkey_data; the modulus and exponent length are provided as \ parameters. The resulting hash value is compared with the one in \ tbs_hash. Returned value is 0 on success, or a non-zero error code. cc: do-rsa-vrfy ( nlen elen -- err ) { size_t elen = T0_POP(); size_t nlen = T0_POP(); br_x509_pkey pk; pk.key_type = BR_KEYTYPE_RSA; pk.key.rsa.n = CTX->pkey_data; pk.key.rsa.nlen = nlen; pk.key.rsa.e = CTX->pkey_data + nlen; pk.key.rsa.elen = elen; T0_PUSH(verify_signature(CTX, &pk)); } \ Verify ECDSA signature. This uses the public key that was just decoded \ into CTX->pkey_dayta; the curve ID and public point length are provided \ as parameters. The hash value in tbs_hash is used. Returned value is 0 \ on success, or non-zero error code. cc: do-ecdsa-vrfy ( curve qlen -- err ) { size_t qlen = T0_POP(); int curve = T0_POP(); br_x509_pkey pk; pk.key_type = BR_KEYTYPE_EC; pk.key.ec.curve = curve; pk.key.ec.q = CTX->pkey_data; pk.key.ec.qlen = qlen; T0_PUSH(verify_signature(CTX, &pk)); } cc: print-bytes ( addr len -- ) { extern int printf(const char *fmt, ...); size_t len = T0_POP(); unsigned char *buf = (unsigned char *)CTX + T0_POP(); size_t u; for (u = 0; u < len; u ++) { printf("%02X", buf[u]); } } cc: printOID ( -- ) { extern int printf(const char *fmt, ...); size_t u, len; len = CTX->pad[0]; if (len == 0) { printf("*"); T0_RET(); } printf("%u.%u", CTX->pad[1] / 40, CTX->pad[1] % 40); u = 2; while (u <= len) { unsigned long ul; ul = 0; for (;;) { int x; if (u > len) { printf("BAD"); T0_RET(); } x = CTX->pad[u ++]; ul = (ul << 7) + (x & 0x7F); if (!(x & 0x80)) { break; } } printf(".%lu", ul); } } \ Extensions with specific processing. OID: basicConstraints 2.5.29.19 OID: keyUsage 2.5.29.15 OID: subjectAltName 2.5.29.17 OID: certificatePolicies 2.5.29.32 \ Policy qualifier "pointer to CPS" OID: id-qt-cps 1.3.6.1.5.5.7.2.1 \ Extensions which are ignored when encountered, even if critical. OID: authorityKeyIdentifier 2.5.29.35 OID: subjectKeyIdentifier 2.5.29.14 OID: issuerAltName 2.5.29.18 OID: subjectDirectoryAttributes 2.5.29.9 OID: crlDistributionPoints 2.5.29.31 OID: freshestCRL 2.5.29.46 OID: authorityInfoAccess 1.3.6.1.5.5.7.1.1 OID: subjectInfoAccess 1.3.6.1.5.5.7.1.11 \ Process a Basic Constraints extension. This should be called only if \ the certificate is not the EE. We check that the extension contains \ the "CA" flag, and that the path length, if specified, is compatible \ with the current chain length. : process-basicConstraints ( lim -- lim ) read-sequence-open read-tag-or-end dup 0x01 = if read-boolean ifnot ERR_X509_NOT_CA fail then read-tag-or-end else ERR_X509_NOT_CA fail then dup 0x02 = if drop check-primitive read-small-int-value addr-num_certs get32 1- < if ERR_X509_NOT_CA fail then read-tag-or-end then -1 <> if ERR_X509_UNEXPECTED fail then drop close-elt ; \ Process a Key Usage extension. \ For the EE certificate: \ -- if the key usage contains keyEncipherment (2), dataEncipherment (3) \ or keyAgreement (4), then the "key exchange" usage is allowed; \ -- if the key usage contains digitalSignature (0) or nonRepudiation (1), \ then the "signature" usage is allowed. \ For CA certificates, the extension must contain keyCertSign (5). : process-keyUsage ( lim ee -- lim ) { ee } \ Read tag for the BIT STRING and open it. read-tag 0x03 check-tag-primitive read-length-open-elt \ First byte indicates number of ignored bits in the last byte. It \ must be between 0 and 7. read8 { ign } ign 7 > if ERR_X509_UNEXPECTED fail then \ Depending on length, we have either 0, 1 or more bytes to read. dup case 0 of ERR_X509_FORBIDDEN_KEY_USAGE fail endof 1 of read8 ign >> ign << endof drop read8 0 endcase \ Check bits. ee if \ EE: get usages. 0 over 0x38 and if 0x10 or then swap 0xC0 and if 0x20 or then addr-key_usages set8 else \ Not EE: keyCertSign must be set. 0x04 and ifnot ERR_X509_FORBIDDEN_KEY_USAGE fail then then \ We don't care about subsequent bytes. skip-close-elt ; \ Process a Certificate Policies extension. \ \ Since we don't actually support full policies processing, this function \ only checks that the extension contents can be safely ignored. Indeed, \ we don't validate against a specific set of policies (in RFC 5280 \ terminology, user-initial-policy-set only contains the special value \ any-policy). Moreover, we don't support policy constraints (if a \ critical Policy Constraints extension is encountered, the validation \ will fail). Therefore, we can safely ignore the contents of this \ extension, except if it is critical AND one of the policy OID has a \ qualifier which is distinct from id-qt-cps (because id-qt-cps is \ specially designated by RFC 5280 has having no mandated action). \ \ This function is called only if the extension is critical. : process-certPolicies ( lim -- lim ) \ Extension value is a SEQUENCE OF PolicyInformation. read-sequence-open begin dup while \ PolicyInformation ::= SEQUENCE { \ policyIdentifier OBJECT IDENTIFIER, \ policyQualifiers SEQUENCE OF PolicyQualifierInfo OPTIONAL \ } read-sequence-open read-OID drop dup if read-sequence-open begin dup while \ PolicyQualifierInfo ::= SEQUENCE { \ policyQualifierId OBJECT IDENTIFIER, \ qualifier ANY \ } read-sequence-open read-OID drop id-qt-cps eqOID ifnot ERR_X509_CRITICAL_EXTENSION fail then skip-close-elt repeat close-elt then close-elt repeat close-elt ; \ Process a Subject Alt Name extension. Returned value is a boolean set \ to true if the expected server name was matched against a dNSName in \ the extension. : process-SAN ( lim -- lim bool ) 0 { m } read-sequence-open begin dup while \ Read the tag. If the tag is context-0, then parse an \ 'otherName'. If the tag is context-2, then parse a \ dNSName. If the tag is context-1 or context-6, \ parse read-tag case \ OtherName 0x20 of \ OtherName ::= SEQUENCE { \ type-id OBJECT IDENTIFIER, \ value [0] EXPLICIT ANY \ } check-constructed read-length-open-elt read-OID drop -1 offset-name-element { offbuf } read-tag 0x20 check-tag-constructed read-length-open-elt read-string offbuf copy-name-element close-elt close-elt endof \ rfc822Name (IA5String) 0x21 of check-primitive read-value-UTF8 1 copy-name-SAN endof \ dNSName (IA5String) 0x22 of check-primitive read-value-UTF8 dup if match-server-name m or >m then 2 copy-name-SAN endof \ uniformResourceIdentifier (IA5String) 0x26 of check-primitive read-value-UTF8 6 copy-name-SAN endof 2drop read-length-skip 0 endcase \ We check only names of type dNSName; they use IA5String, \ which is basically ASCII. \ read-tag 0x22 = if \ check-primitive \ read-small-value drop \ match-server-name m or >m \ else \ drop read-length-skip \ then repeat close-elt m ; \ Decode a certificate. The "ee" boolean must be true for the EE. : decode-certificate ( ee -- ) { ee } \ Obtain the total certificate length. addr-cert_length get32 \ Open the outer SEQUENCE. read-sequence-open \ TBS \ Activate hashing. start-tbs-hash read-sequence-open \ First element may be an explicit version. We accept only \ versions 0 to 2 (certificates v1 to v3). read-tag dup 0x20 = if drop check-constructed read-length-open-elt read-tag 0x02 check-tag-primitive read-small-int-value 2 > if ERR_X509_UNSUPPORTED fail then close-elt read-tag then \ Serial number. We just check that the tag is correct. 0x02 check-tag-primitive read-length-skip \ Signature algorithm. This structure is redundant with the one \ on the outside; we just skip it. read-sequence-open skip-close-elt \ Issuer name: hashed, then copied into next_dn_hash[]. read-DN addr-next_dn_hash addr-current_dn_hash dn-hash-length blobcopy \ Validity dates. read-sequence-open read-date { nbd nbs } read-date nbd nbs check-validity-range if ERR_X509_EXPIRED fail then close-elt \ Subject name. ee if \ For the EE, we must check whether the Common Name, if \ any, matches the expected server name. read-DN-EE { eename } else \ For a non-EE certificate, the hashed subject DN must match \ the saved hashed issuer DN from the previous certificate. read-DN addr-current_dn_hash addr-saved_dn_hash dn-hash-length eqblob ifnot ERR_X509_DN_MISMATCH fail then then \ Move the hashed issuer DN for this certificate into the \ saved_dn_hash[] array. addr-saved_dn_hash addr-next_dn_hash dn-hash-length blobcopy \ Public Key. read-sequence-open \ Algorithm Identifier. Right now we are only interested in the \ OID, since we only support RSA keys. read-sequence-open read-OID ifnot ERR_X509_UNSUPPORTED fail then { ; pkey-type } choice \ RSA public key. rsaEncryption eqOID uf skip-close-elt \ Public key itself: the BIT STRING contains bytes \ (no partial byte) and these bytes encode the \ actual value. read-bits-open \ RSA public key is a SEQUENCE of two \ INTEGER. We get both INTEGER values into \ the pkey_data[] buffer, if they fit. read-sequence-open addr-len-pkey_data read-integer { nlen } addr-len-pkey_data swap nlen + swap nlen - read-integer { elen } close-elt \ Check that the public key fits our minimal \ size requirements. Note that the integer \ decoder already skipped the leading bytes \ of value 0, so we are working on the true \ modulus length here. addr-min_rsa_size get16 128 + nlen > if ERR_X509_WEAK_PUBLIC_KEY fail then close-elt KEYTYPE_RSA >pkey-type enduf \ EC public key. id-ecPublicKey eqOID uf \ We support only named curves, for which the \ "parameters" field in the AlgorithmIdentifier \ field should be an OID. read-OID ifnot ERR_X509_UNSUPPORTED fail then choice ansix9p256r1 eqOID uf 23 enduf ansix9p384r1 eqOID uf 24 enduf ansix9p521r1 eqOID uf 25 enduf ERR_X509_UNSUPPORTED fail endchoice { curve } close-elt read-bits-open dup { qlen } dup addr-len-pkey_data rot < if ERR_X509_LIMIT_EXCEEDED fail then read-blob KEYTYPE_EC >pkey-type enduf \ Not a recognised public key type. ERR_X509_UNSUPPORTED fail endchoice close-elt \ Process public key. ee if \ For the EE certificate, copy the key data to the \ relevant buffer. pkey-type case KEYTYPE_RSA of nlen elen copy-ee-rsa-pkey endof KEYTYPE_EC of curve qlen copy-ee-ec-pkey endof ERR_X509_UNSUPPORTED fail endcase else \ Verify signature on previous certificate. We invoke \ the RSA implementation. pkey-type case KEYTYPE_RSA of nlen elen do-rsa-vrfy endof KEYTYPE_EC of curve qlen do-ecdsa-vrfy endof ERR_X509_UNSUPPORTED fail endcase dup if fail then drop then \ This flag will be set to true if the Basic Constraints extension \ is encountered. 0 { seenBC } \ Skip issuerUniqueID and subjectUniqueID, and process extensions \ if present. Extensions are an explicit context tag of value 3 \ around a SEQUENCE OF extensions. Each extension is a SEQUENCE \ with an OID, an optional boolean, and a value; the value is \ an OCTET STRING. read-tag-or-end 0x21 iftag-skip 0x22 iftag-skip dup 0x23 = if drop check-constructed read-length-open-elt read-sequence-open begin dup while 0 { critical } read-sequence-open read-OID drop read-tag dup 0x01 = if read-boolean >critical read-tag then 0x04 check-tag-primitive read-length-open-elt choice \ Extensions with specific processing. basicConstraints eqOID uf ee if skip-remaining else process-basicConstraints -1 >seenBC then enduf keyUsage eqOID uf ee process-keyUsage enduf subjectAltName eqOID uf ee if 0 >eename process-SAN >eename else skip-remaining then enduf \ We don't implement full processing of \ policies. The call below mostly checks \ that the contents of the Certificate \ Policies extension can be safely ignored. certificatePolicies eqOID uf critical if process-certPolicies else skip-remaining then enduf \ Extensions which are always ignored, \ even if critical. authorityKeyIdentifier eqOID uf skip-remaining enduf subjectKeyIdentifier eqOID uf skip-remaining enduf issuerAltName eqOID uf skip-remaining enduf subjectDirectoryAttributes eqOID uf skip-remaining enduf crlDistributionPoints eqOID uf skip-remaining enduf freshestCRL eqOID uf skip-remaining enduf authorityInfoAccess eqOID uf skip-remaining enduf subjectInfoAccess eqOID uf skip-remaining enduf \ Unrecognized extensions trigger a failure \ if critical; otherwise, they are just \ ignored. critical if ERR_X509_CRITICAL_EXTENSION fail then skip-remaining endchoice close-elt close-elt repeat close-elt close-elt else -1 = ifnot ERR_X509_UNEXPECTED fail then drop then close-elt \ Terminate hashing. stop-tbs-hash \ For the EE certificate, verify that the intended server name \ was matched. ee if eename zero-server-name or ifnot ERR_X509_BAD_SERVER_NAME fail then then \ If this is the EE certificate, then direct trust may apply. \ Note: we do this at this point, not immediately after decoding \ the public key, because even in case of direct trust we still \ want to check the server name with regards to the SAN extension. \ However, we want to check direct trust before trying to decode \ the signature algorithm, because it should work even if that \ algorithm is not supported. ee if check-direct-trust then \ Non-EE certificates MUST have a Basic Constraints extension \ (that marks them as being CA). ee seenBC or ifnot ERR_X509_NOT_CA fail then \ signature algorithm read-tag check-sequence read-length-open-elt \ Read and understand the OID. Right now, we support only \ RSA with PKCS#1 v1.5 padding, and hash functions SHA-1, \ SHA-224, SHA-256, SHA-384 and SHA-512. We purposely do NOT \ support MD5 here. \ TODO: add support for RSA/PSS read-OID if \ Based on the signature OID, we get: \ -- the signing key type \ -- the hash function numeric identifier \ -- the hash function OID choice sha1WithRSAEncryption eqOID uf 2 KEYTYPE_RSA id-sha1 enduf sha224WithRSAEncryption eqOID uf 3 KEYTYPE_RSA id-sha224 enduf sha256WithRSAEncryption eqOID uf 4 KEYTYPE_RSA id-sha256 enduf sha384WithRSAEncryption eqOID uf 5 KEYTYPE_RSA id-sha384 enduf sha512WithRSAEncryption eqOID uf 6 KEYTYPE_RSA id-sha512 enduf ecdsa-with-SHA1 eqOID uf 2 KEYTYPE_EC id-sha1 enduf ecdsa-with-SHA224 eqOID uf 3 KEYTYPE_EC id-sha224 enduf ecdsa-with-SHA256 eqOID uf 4 KEYTYPE_EC id-sha256 enduf ecdsa-with-SHA384 eqOID uf 5 KEYTYPE_EC id-sha384 enduf ecdsa-with-SHA512 eqOID uf 6 KEYTYPE_EC id-sha512 enduf ERR_X509_UNSUPPORTED fail endchoice addr-cert_sig_hash_oid set16 addr-cert_signer_key_type set8 \ Compute the TBS hash into tbs_hash. compute-tbs-hash dup ifnot ERR_X509_UNSUPPORTED fail then addr-cert_sig_hash_len set8 else ERR_X509_UNSUPPORTED fail then \ We ignore the parameters, whether they are present or not, \ because we got all the information from the OID. skip-close-elt \ signature value read-bits-open dup CX 0 8191 { BR_X509_BUFSIZE_SIG } > if ERR_X509_LIMIT_EXCEEDED fail then dup addr-cert_sig_len set16 addr-cert_sig read-blob \ Close the outer SEQUENCE. close-elt \ Close the advertised total certificate length. This checks that \ there is no trailing garbage after the certificate. close-elt \ Flag the certificate as fully processed. 0 addr-cert_length set32 \ Check whether the issuer for the current certificate is known \ as a trusted CA; in which case, verify the signature. check-trust-anchor-CA ; : main \ Unless restricted by a Key Usage extension, all usages are \ deemed allowed. 0x30 addr-key_usages set8 -1 decode-certificate co begin 0 decode-certificate co again ;