/* $OpenBSD: x509.c,v 1.104 2005/11/14 23:25:11 deraadt Exp $ */ /* $EOM: x509.c,v 1.54 2001/01/16 18:42:16 ho Exp $ */ /* * Copyright (c) 1998, 1999 Niels Provos. All rights reserved. * Copyright (c) 1999, 2000, 2001 Niklas Hallqvist. All rights reserved. * Copyright (c) 1999, 2000, 2001 Angelos D. Keromytis. All rights reserved. * * Redistribution and use in source and binary forms, with or without * modification, are permitted provided that the following conditions * are met: * 1. Redistributions of source code must retain the above copyright * notice, this list of conditions and the following disclaimer. * 2. Redistributions in binary form must reproduce the above copyright * notice, this list of conditions and the following disclaimer in the * documentation and/or other materials provided with the distribution. * * THIS SOFTWARE IS PROVIDED BY THE AUTHOR ``AS IS'' AND ANY EXPRESS OR * IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES * OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE DISCLAIMED. * IN NO EVENT SHALL THE AUTHOR BE LIABLE FOR ANY DIRECT, INDIRECT, * INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT * NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, * DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY * THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT * (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF * THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE. */ /* * This code was written under funding by Ericsson Radio Systems. */ #include #include #include #include #include #include #include #include #include #include #include #include #include "cert.h" #include "conf.h" #include "exchange.h" #include "hash.h" #include "ike_auth.h" #include "ipsec.h" #include "log.h" #include "math_mp.h" #include "monitor.h" #include "policy.h" #include "sa.h" #include "util.h" #include "x509.h" static u_int16_t x509_hash(u_int8_t *, size_t); static void x509_hash_init(void); static X509 *x509_hash_find(u_int8_t *, size_t); static int x509_hash_enter(X509 *); /* * X509_STOREs do not support subjectAltNames, so we have to build * our own hash table. */ /* * XXX Actually this store is not really useful, we never use it as we have * our own hash table. It also gets collisons if we have several certificates * only differing in subjectAltName. */ static X509_STORE *x509_certs = 0; static X509_STORE *x509_cas = 0; /* Initial number of bits used as hash. */ #define INITIAL_BUCKET_BITS 6 struct x509_hash { LIST_ENTRY(x509_hash) link; X509 *cert; }; static LIST_HEAD(x509_list, x509_hash) *x509_tab = 0; /* Works both as a maximum index and a mask. */ static int bucket_mask; /* * Given an X509 certificate, create a KeyNote assertion where * Issuer/Subject -> Authorizer/Licensees. * XXX RSA-specific. */ int x509_generate_kn(int id, X509 *cert) { char *fmt = "Authorizer: \"rsa-hex:%s\"\nLicensees: \"rsa-hex:%s" "\"\nConditions: %s >= \"%s\" && %s <= \"%s\";\n"; char *ikey = NULL, *skey = NULL, *buf = NULL; char isname[256], subname[256]; char *fmt2 = "Authorizer: \"DN:%s\"\nLicensees: \"DN:%s\"\n" "Conditions: %s >= \"%s\" && %s <= \"%s\";\n"; X509_NAME *issuer, *subject; struct keynote_deckey dc; X509_STORE_CTX csc; X509_OBJECT obj; X509 *icert; RSA *key = NULL; time_t tt; char before[15], after[15], *timecomp, *timecomp2; ASN1_TIME *tm; int i; LOG_DBG((LOG_POLICY, 90, "x509_generate_kn: generating KeyNote policy for certificate %p", cert)); issuer = X509_get_issuer_name(cert); subject = X509_get_subject_name(cert); /* Missing or self-signed, ignore cert but don't report failure. */ if (!issuer || !subject || !X509_name_cmp(issuer, subject)) return 1; if (!x509_cert_get_key(cert, &key)) { LOG_DBG((LOG_POLICY, 30, "x509_generate_kn: failed to get public key from cert")); return 0; } dc.dec_algorithm = KEYNOTE_ALGORITHM_RSA; dc.dec_key = key; ikey = kn_encode_key(&dc, INTERNAL_ENC_PKCS1, ENCODING_HEX, KEYNOTE_PUBLIC_KEY); if (keynote_errno == ERROR_MEMORY) { log_print("x509_generate_kn: failed to get memory for " "public key"); LOG_DBG((LOG_POLICY, 30, "x509_generate_kn: cannot get " "subject key")); goto fail; } if (!ikey) { LOG_DBG((LOG_POLICY, 30, "x509_generate_kn: cannot get " "subject key")); goto fail; } RSA_free(key); key = NULL; /* Now find issuer's certificate so we can get the public key. */ X509_STORE_CTX_init(&csc, x509_cas, cert, NULL); if (X509_STORE_get_by_subject(&csc, X509_LU_X509, issuer, &obj) != X509_LU_X509) { X509_STORE_CTX_cleanup(&csc); X509_STORE_CTX_init(&csc, x509_certs, cert, NULL); if (X509_STORE_get_by_subject(&csc, X509_LU_X509, issuer, &obj) != X509_LU_X509) { X509_STORE_CTX_cleanup(&csc); LOG_DBG((LOG_POLICY, 30, "x509_generate_kn: no certificate found for " "issuer")); goto fail; } } X509_STORE_CTX_cleanup(&csc); icert = obj.data.x509; if (icert == NULL) { LOG_DBG((LOG_POLICY, 30, "x509_generate_kn: " "missing certificates, cannot construct X509 chain")); goto fail; } if (!x509_cert_get_key(icert, &key)) { LOG_DBG((LOG_POLICY, 30, "x509_generate_kn: failed to get public key from cert")); goto fail; } X509_OBJECT_free_contents(&obj); dc.dec_algorithm = KEYNOTE_ALGORITHM_RSA; dc.dec_key = key; skey = kn_encode_key(&dc, INTERNAL_ENC_PKCS1, ENCODING_HEX, KEYNOTE_PUBLIC_KEY); if (keynote_errno == ERROR_MEMORY) { log_error("x509_generate_kn: failed to get memory for public " "key"); LOG_DBG((LOG_POLICY, 30, "x509_generate_kn: cannot get issuer " "key")); goto fail; } if (!skey) { LOG_DBG((LOG_POLICY, 30, "x509_generate_kn: cannot get issuer " "key")); goto fail; } RSA_free(key); key = NULL; if (((tm = X509_get_notBefore(cert)) == NULL) || (tm->type != V_ASN1_UTCTIME && tm->type != V_ASN1_GENERALIZEDTIME)) { tt = time(0); strftime(before, 14, "%Y%m%d%H%M%S", localtime(&tt)); timecomp = "LocalTimeOfDay"; } else { if (tm->data[tm->length - 1] == 'Z') { timecomp = "GMTTimeOfDay"; i = tm->length - 2; } else { timecomp = "LocalTimeOfDay"; i = tm->length - 1; } for (; i >= 0; i--) { if (tm->data[i] < '0' || tm->data[i] > '9') { LOG_DBG((LOG_POLICY, 30, "x509_generate_kn: invalid data in " "NotValidBefore time field")); goto fail; } } if (tm->type == V_ASN1_UTCTIME) { if ((tm->length < 10) || (tm->length > 13)) { LOG_DBG((LOG_POLICY, 30, "x509_generate_kn: invalid length " "of NotValidBefore time field (%d)", tm->length)); goto fail; } /* Validity checks. */ if ((tm->data[2] != '0' && tm->data[2] != '1') || (tm->data[2] == '0' && tm->data[3] == '0') || (tm->data[2] == '1' && tm->data[3] > '2') || (tm->data[4] > '3') || (tm->data[4] == '0' && tm->data[5] == '0') || (tm->data[4] == '3' && tm->data[5] > '1') || (tm->data[6] > '2') || (tm->data[6] == '2' && tm->data[7] > '3') || (tm->data[8] > '5')) { LOG_DBG((LOG_POLICY, 30, "x509_generate_kn: invalid value in " "NotValidBefore time field")); goto fail; } /* Stupid UTC tricks. */ if (tm->data[0] < '5') snprintf(before, sizeof before, "20%s", tm->data); else snprintf(before, sizeof before, "19%s", tm->data); } else { /* V_ASN1_GENERICTIME */ if ((tm->length < 12) || (tm->length > 15)) { LOG_DBG((LOG_POLICY, 30, "x509_generate_kn: invalid length of " "NotValidBefore time field (%d)", tm->length)); goto fail; } /* Validity checks. */ if ((tm->data[4] != '0' && tm->data[4] != '1') || (tm->data[4] == '0' && tm->data[5] == '0') || (tm->data[4] == '1' && tm->data[5] > '2') || (tm->data[6] > '3') || (tm->data[6] == '0' && tm->data[7] == '0') || (tm->data[6] == '3' && tm->data[7] > '1') || (tm->data[8] > '2') || (tm->data[8] == '2' && tm->data[9] > '3') || (tm->data[10] > '5')) { LOG_DBG((LOG_POLICY, 30, "x509_generate_kn: invalid value in " "NotValidBefore time field")); goto fail; } snprintf(before, sizeof before, "%s", tm->data); } /* Fix missing seconds. */ if (tm->length < 12) { before[12] = '0'; before[13] = '0'; } /* This will overwrite trailing 'Z'. */ before[14] = '\0'; } tm = X509_get_notAfter(cert); if (tm == NULL && (tm->type != V_ASN1_UTCTIME && tm->type != V_ASN1_GENERALIZEDTIME)) { tt = time(0); strftime(after, 14, "%Y%m%d%H%M%S", localtime(&tt)); timecomp2 = "LocalTimeOfDay"; } else { if (tm->data[tm->length - 1] == 'Z') { timecomp2 = "GMTTimeOfDay"; i = tm->length - 2; } else { timecomp2 = "LocalTimeOfDay"; i = tm->length - 1; } for (; i >= 0; i--) { if (tm->data[i] < '0' || tm->data[i] > '9') { LOG_DBG((LOG_POLICY, 30, "x509_generate_kn: invalid data in " "NotValidAfter time field")); goto fail; } } if (tm->type == V_ASN1_UTCTIME) { if ((tm->length < 10) || (tm->length > 13)) { LOG_DBG((LOG_POLICY, 30, "x509_generate_kn: invalid length of " "NotValidAfter time field (%d)", tm->length)); goto fail; } /* Validity checks. */ if ((tm->data[2] != '0' && tm->data[2] != '1') || (tm->data[2] == '0' && tm->data[3] == '0') || (tm->data[2] == '1' && tm->data[3] > '2') || (tm->data[4] > '3') || (tm->data[4] == '0' && tm->data[5] == '0') || (tm->data[4] == '3' && tm->data[5] > '1') || (tm->data[6] > '2') || (tm->data[6] == '2' && tm->data[7] > '3') || (tm->data[8] > '5')) { LOG_DBG((LOG_POLICY, 30, "x509_generate_kn: invalid value in " "NotValidAfter time field")); goto fail; } /* Stupid UTC tricks. */ if (tm->data[0] < '5') snprintf(after, sizeof after, "20%s", tm->data); else snprintf(after, sizeof after, "19%s", tm->data); } else { /* V_ASN1_GENERICTIME */ if ((tm->length < 12) || (tm->length > 15)) { LOG_DBG((LOG_POLICY, 30, "x509_generate_kn: invalid length of " "NotValidAfter time field (%d)", tm->length)); goto fail; } /* Validity checks. */ if ((tm->data[4] != '0' && tm->data[4] != '1') || (tm->data[4] == '0' && tm->data[5] == '0') || (tm->data[4] == '1' && tm->data[5] > '2') || (tm->data[6] > '3') || (tm->data[6] == '0' && tm->data[7] == '0') || (tm->data[6] == '3' && tm->data[7] > '1') || (tm->data[8] > '2') || (tm->data[8] == '2' && tm->data[9] > '3') || (tm->data[10] > '5')) { LOG_DBG((LOG_POLICY, 30, "x509_generate_kn: invalid value in " "NotValidAfter time field")); goto fail; } snprintf(after, sizeof after, "%s", tm->data); } /* Fix missing seconds. */ if (tm->length < 12) { after[12] = '0'; after[13] = '0'; } after[14] = '\0'; /* This will overwrite trailing 'Z' */ } if (asprintf(&buf, fmt, skey, ikey, timecomp, before, timecomp2, after) == -1) { log_error("x509_generate_kn: " "failed to allocate memory for KeyNote credential"); goto fail; } free(ikey); ikey = NULL; free(skey); skey = NULL; if (kn_add_assertion(id, buf, strlen(buf), ASSERT_FLAG_LOCAL) == -1) { LOG_DBG((LOG_POLICY, 30, "x509_generate_kn: failed to add new KeyNote credential")); goto fail; } /* We could print the assertion here, but log_print() truncates... */ LOG_DBG((LOG_POLICY, 60, "x509_generate_kn: added credential")); free(buf); buf = NULL; if (!X509_NAME_oneline(issuer, isname, 256)) { LOG_DBG((LOG_POLICY, 50, "x509_generate_kn: " "X509_NAME_oneline (issuer, ...) failed")); goto fail; } if (!X509_NAME_oneline(subject, subname, 256)) { LOG_DBG((LOG_POLICY, 50, "x509_generate_kn: " "X509_NAME_oneline (subject, ...) failed")); goto fail; } if (asprintf(&buf, fmt2, isname, subname, timecomp, before, timecomp2, after) == -1) { log_error("x509_generate_kn: malloc failed"); return 0; } if (kn_add_assertion(id, buf, strlen(buf), ASSERT_FLAG_LOCAL) == -1) { LOG_DBG((LOG_POLICY, 30, "x509_generate_kn: failed to add new KeyNote credential")); goto fail; } LOG_DBG((LOG_POLICY, 80, "x509_generate_kn: added credential:\n%s", buf)); free(buf); return 1; fail: if (buf) free(buf); if (skey) free(skey); if (ikey) free(ikey); if (key) RSA_free(key); return 0; } static u_int16_t x509_hash(u_int8_t *id, size_t len) { u_int16_t bucket = 0; size_t i; /* XXX We might resize if we are crossing a certain threshold. */ for (i = 4; i < (len & ~1); i += 2) { /* Doing it this way avoids alignment problems. */ bucket ^= (id[i] + 1) * (id[i + 1] + 257); } /* Hash in the last character of odd length IDs too. */ if (i < len) bucket ^= (id[i] + 1) * (id[i] + 257); bucket &= bucket_mask; return bucket; } static void x509_hash_init(void) { struct x509_hash *certh; int i; bucket_mask = (1 << INITIAL_BUCKET_BITS) - 1; /* If reinitializing, free existing entries. */ if (x509_tab) { for (i = 0; i <= bucket_mask; i++) for (certh = LIST_FIRST(&x509_tab[i]); certh; certh = LIST_FIRST(&x509_tab[i])) { LIST_REMOVE(certh, link); free(certh); } free(x509_tab); } x509_tab = malloc((bucket_mask + 1) * sizeof(struct x509_list)); if (!x509_tab) log_fatal("x509_hash_init: malloc (%lu) failed", (bucket_mask + 1) * (unsigned long)sizeof(struct x509_list)); for (i = 0; i <= bucket_mask; i++) { LIST_INIT(&x509_tab[i]); } } /* Lookup a certificate by an ID blob. */ static X509 * x509_hash_find(u_int8_t *id, size_t len) { struct x509_hash *cert; u_int8_t **cid; u_int32_t *clen; int n, i, id_found; for (cert = LIST_FIRST(&x509_tab[x509_hash(id, len)]); cert; cert = LIST_NEXT(cert, link)) { if (!x509_cert_get_subjects(cert->cert, &n, &cid, &clen)) continue; id_found = 0; for (i = 0; i < n; i++) { LOG_DBG_BUF((LOG_CRYPTO, 70, "cert_cmp", id, len)); LOG_DBG_BUF((LOG_CRYPTO, 70, "cert_cmp", cid[i], clen[i])); /* * XXX This identity predicate needs to be * understood. */ if (clen[i] == len && id[0] == cid[i][0] && memcmp(id + 4, cid[i] + 4, len - 4) == 0) { id_found++; break; } } cert_free_subjects(n, cid, clen); if (!id_found) continue; LOG_DBG((LOG_CRYPTO, 70, "x509_hash_find: return X509 %p", cert->cert)); return cert->cert; } LOG_DBG((LOG_CRYPTO, 70, "x509_hash_find: no certificate matched query")); return 0; } static int x509_hash_enter(X509 *cert) { u_int16_t bucket = 0; u_int8_t **id; u_int32_t *len; struct x509_hash *certh; int n, i; if (!x509_cert_get_subjects(cert, &n, &id, &len)) { log_print("x509_hash_enter: cannot retrieve subjects"); return 0; } for (i = 0; i < n; i++) { certh = calloc(1, sizeof *certh); if (!certh) { cert_free_subjects(n, id, len); log_error("x509_hash_enter: calloc (1, %lu) failed", (unsigned long)sizeof *certh); return 0; } certh->cert = cert; bucket = x509_hash(id[i], len[i]); LIST_INSERT_HEAD(&x509_tab[bucket], certh, link); LOG_DBG((LOG_CRYPTO, 70, "x509_hash_enter: cert %p added to bucket %d", cert, bucket)); } cert_free_subjects(n, id, len); return 1; } /* X509 Certificate Handling functions. */ int x509_read_from_dir(X509_STORE *ctx, char *name, int hash) { FILE *certfp; X509 *cert; struct stat sb; char fullname[PATH_MAX]; char file[PATH_MAX]; int fd; if (strlen(name) >= sizeof fullname - 1) { log_print("x509_read_from_dir: directory name too long"); return 0; } LOG_DBG((LOG_CRYPTO, 40, "x509_read_from_dir: reading certs from %s", name)); if (monitor_req_readdir(name) == -1) { LOG_DBG((LOG_CRYPTO, 10, "x509_read_from_dir: opendir (\"%s\") failed: %s", name, strerror(errno))); return 0; } while ((fd = monitor_readdir(file, sizeof file)) != -1) { LOG_DBG((LOG_CRYPTO, 60, "x509_read_from_dir: reading certificate %s", file)); if (fstat(fd, &sb) == -1) { log_error("x509_read_from_dir: fstat failed"); close(fd); continue; } if (!(sb.st_mode & S_IFREG)) { close(fd); continue; } if ((certfp = fdopen(fd, "r")) == NULL) { log_error("x509_read_from_dir: fdopen failed"); close(fd); continue; } #if SSLEAY_VERSION_NUMBER >= 0x00904100L cert = PEM_read_X509(certfp, NULL, NULL, NULL); #else cert = PEM_read_X509(certfp, NULL, NULL); #endif fclose(certfp); if (cert == NULL) { log_print("x509_read_from_dir: PEM_read_X509 " "failed for %s", file); continue; } if (!X509_STORE_add_cert(ctx, cert)) { /* * This is actually expected if we have several * certificates only differing in subjectAltName, * which is not an something that is strange. * Consider multi-homed machines. */ LOG_DBG((LOG_CRYPTO, 50, "x509_read_from_dir: X509_STORE_add_cert failed " "for %s", file)); } if (hash) if (!x509_hash_enter(cert)) log_print("x509_read_from_dir: " "x509_hash_enter (%s) failed", file); } return 1; } /* XXX share code with x509_read_from_dir() ? */ int x509_read_crls_from_dir(X509_STORE *ctx, char *name) { #if OPENSSL_VERSION_NUMBER >= 0x00907000L FILE *crlfp; X509_CRL *crl; struct stat sb; char fullname[PATH_MAX]; char file[PATH_MAX]; int fd, off, size; if (strlen(name) >= sizeof fullname - 1) { log_print("x509_read_crls_from_dir: directory name too long"); return 0; } LOG_DBG((LOG_CRYPTO, 40, "x509_read_crls_from_dir: reading CRLs " "from %s", name)); if (monitor_req_readdir(name) == -1) { LOG_DBG((LOG_CRYPTO, 10, "x509_read_crls_from_dir: opendir " "(\"%s\") failed: %s", name, strerror(errno))); return 0; } strlcpy(fullname, name, sizeof fullname); off = strlen(fullname); size = sizeof fullname - off; while ((fd = monitor_readdir(file, sizeof file)) != -1) { LOG_DBG((LOG_CRYPTO, 60, "x509_read_crls_from_dir: reading " "CRL %s", file)); if (fstat(fd, &sb) == -1) { log_error("x509_read_crls_from_dir: fstat failed"); close(fd); continue; } if (!(sb.st_mode & S_IFREG)) { close(fd); continue; } if ((crlfp = fdopen(fd, "r")) == NULL) { log_error("x509_read_crls_from_dir: fdopen failed"); close(fd); continue; } crl = PEM_read_X509_CRL(crlfp, NULL, NULL, NULL); fclose(crlfp); if (crl == NULL) { log_print("x509_read_crls_from_dir: " "PEM_read_X509_CRL failed for %s", file); continue; } if (!X509_STORE_add_crl(ctx, crl)) { LOG_DBG((LOG_CRYPTO, 50, "x509_read_crls_from_dir: " "X509_STORE_add_crl failed for %s", file)); continue; } /* * XXX This is to make x509_cert_validate set this (and * XXX another) flag when validating certificates. Currently, * XXX OpenSSL defaults to reject an otherwise valid * XXX certificate (chain) if these flags are set but there * XXX are no CRLs to check. The current workaround is to only * XXX set the flags if we actually loaded some CRL data. */ X509_STORE_set_flags(ctx, X509_V_FLAG_CRL_CHECK); } #endif /* OPENSSL_VERSION_NUMBER >= 0x00907000L */ return 1; } /* Initialize our databases and load our own certificates. */ int x509_cert_init(void) { char *dirname; x509_hash_init(); /* Process CA certificates we will trust. */ dirname = conf_get_str("X509-certificates", "CA-directory"); if (!dirname) { log_print("x509_cert_init: no CA-directory"); return 0; } /* Free if already initialized. */ if (x509_cas) X509_STORE_free(x509_cas); x509_cas = X509_STORE_new(); if (!x509_cas) { log_print("x509_cert_init: creating new X509_STORE failed"); return 0; } if (!x509_read_from_dir(x509_cas, dirname, 0)) { log_print("x509_cert_init: x509_read_from_dir failed"); return 0; } /* Process client certificates we will accept. */ dirname = conf_get_str("X509-certificates", "Cert-directory"); if (!dirname) { log_print("x509_cert_init: no Cert-directory"); return 0; } /* Free if already initialized. */ if (x509_certs) X509_STORE_free(x509_certs); x509_certs = X509_STORE_new(); if (!x509_certs) { log_print("x509_cert_init: creating new X509_STORE failed"); return 0; } if (!x509_read_from_dir(x509_certs, dirname, 1)) { log_print("x509_cert_init: x509_read_from_dir failed"); return 0; } return 1; } int x509_crl_init(void) { /* * XXX I'm not sure if the method to use CRLs in certificate validation * is valid for OpenSSL versions prior to 0.9.7. For now, simply do not * support it. */ #if OPENSSL_VERSION_NUMBER >= 0x00907000L char *dirname; dirname = conf_get_str("X509-certificates", "CRL-directory"); if (!dirname) { log_print("x509_crl_init: no CRL-directory"); return 0; } if (!x509_read_crls_from_dir(x509_cas, dirname)) { LOG_DBG((LOG_MISC, 10, "x509_crl_init: x509_read_crls_from_dir failed")); return 0; } #else LOG_DBG((LOG_CRYPTO, 10, "x509_crl_init: CRL support only " "with OpenSSL v0.9.7 or later")); #endif return 1; } void * x509_cert_get(u_int8_t *asn, u_int32_t len) { return x509_from_asn(asn, len); } int x509_cert_validate(void *scert) { X509_STORE_CTX csc; X509_NAME *issuer, *subject; X509 *cert = (X509 *) scert; EVP_PKEY *key; int res, err; /* * Validate the peer certificate by checking with the CA certificates * we trust. */ X509_STORE_CTX_init(&csc, x509_cas, cert, NULL); #if OPENSSL_VERSION_NUMBER >= 0x00907000L /* XXX See comment in x509_read_crls_from_dir. */ if (x509_cas->flags & X509_V_FLAG_CRL_CHECK) { X509_STORE_CTX_set_flags(&csc, X509_V_FLAG_CRL_CHECK); X509_STORE_CTX_set_flags(&csc, X509_V_FLAG_CRL_CHECK_ALL); } #endif res = X509_verify_cert(&csc); err = csc.error; X509_STORE_CTX_cleanup(&csc); /* * Return if validation succeeded or self-signed certs are not * accepted. * * XXX X509_verify_cert seems to return -1 if the validation should be * retried somehow. We take this as an error and give up. */ if (res > 0) return 1; else if (res < 0 || (res == 0 && err != X509_V_ERR_DEPTH_ZERO_SELF_SIGNED_CERT)) { if (err) log_print("x509_cert_validate: %.100s", X509_verify_cert_error_string(err)); return 0; } else if (!conf_get_str("X509-certificates", "Accept-self-signed")) { if (err) log_print("x509_cert_validate: %.100s", X509_verify_cert_error_string(err)); return 0; } issuer = X509_get_issuer_name(cert); subject = X509_get_subject_name(cert); if (!issuer || !subject || X509_name_cmp(issuer, subject)) return 0; key = X509_get_pubkey(cert); if (!key) { log_print("x509_cert_validate: could not get public key from " "self-signed cert"); return 0; } if (X509_verify(cert, key) == -1) { log_print("x509_cert_validate: self-signed cert is bad"); return 0; } return 1; } int x509_cert_insert(int id, void *scert) { X509 *cert; int res; cert = X509_dup((X509 *)scert); if (!cert) { log_print("x509_cert_insert: X509_dup failed"); return 0; } if (x509_generate_kn(id, cert) == 0) { LOG_DBG((LOG_POLICY, 50, "x509_cert_insert: x509_generate_kn failed")); X509_free(cert); return 0; } res = x509_hash_enter(cert); if (!res) X509_free(cert); return res; } static struct x509_hash * x509_hash_lookup(X509 *cert) { struct x509_hash *certh; int i; for (i = 0; i <= bucket_mask; i++) for (certh = LIST_FIRST(&x509_tab[i]); certh; certh = LIST_NEXT(certh, link)) if (certh->cert == cert) return certh; return 0; } void x509_cert_free(void *cert) { struct x509_hash *certh = x509_hash_lookup((X509 *) cert); if (certh) LIST_REMOVE(certh, link); X509_free((X509 *) cert); } /* Validate the BER Encoding of a RDNSequence in the CERT_REQ payload. */ int x509_certreq_validate(u_int8_t *asn, u_int32_t len) { int res = 1; #if 0 struct norm_type name = SEQOF("issuer", RDNSequence); if (!asn_template_clone(&name, 1) || (asn = asn_decode_sequence(asn, len, &name)) == 0) { log_print("x509_certreq_validate: can not decode 'acceptable " "CA' info"); res = 0; } asn_free(&name); #endif /* XXX - not supported directly in SSL - later. */ return res; } /* Decode the BER Encoding of a RDNSequence in the CERT_REQ payload. */ void * x509_certreq_decode(u_int8_t *asn, u_int32_t len) { #if 0 /* XXX This needs to be done later. */ struct norm_type aca = SEQOF("aca", RDNSequence); struct norm_type *tmp; struct x509_aca naca, *ret; if (!asn_template_clone(&aca, 1) || (asn = asn_decode_sequence(asn, len, &aca)) == 0) { log_print("x509_certreq_decode: can not decode 'acceptable " "CA' info"); goto fail; } bzero(&naca, sizeof(naca)); tmp = asn_decompose("aca.RelativeDistinguishedName." "AttributeValueAssertion", &aca); if (!tmp) goto fail; x509_get_attribval(tmp, &naca.name1); tmp = asn_decompose("aca.RelativeDistinguishedName[1]" ".AttributeValueAssertion", &aca); if (tmp) x509_get_attribval(tmp, &naca.name2); asn_free(&aca); ret = malloc(sizeof(struct x509_aca)); if (ret) memcpy(ret, &naca, sizeof(struct x509_aca)); else { log_error("x509_certreq_decode: malloc (%lu) failed", (unsigned long) sizeof(struct x509_aca)); x509_free_aca(&aca); } return ret; fail: asn_free(&aca); #endif return 0; } void x509_free_aca(void *blob) { struct x509_aca *aca = blob; if (aca->name1.type) free(aca->name1.type); if (aca->name1.val) free(aca->name1.val); if (aca->name2.type) free(aca->name2.type); if (aca->name2.val) free(aca->name2.val); } X509 * x509_from_asn(u_char *asn, u_int len) { BIO *certh; X509 *scert = 0; certh = BIO_new(BIO_s_mem()); if (!certh) { log_error("x509_from_asn: BIO_new (BIO_s_mem ()) failed"); return 0; } if (BIO_write(certh, asn, len) == -1) { log_error("x509_from_asn: BIO_write failed\n"); goto end; } scert = d2i_X509_bio(certh, NULL); if (!scert) { log_print("x509_from_asn: d2i_X509_bio failed\n"); goto end; } end: BIO_free(certh); return scert; } /* * Obtain a certificate from an acceptable CA. * XXX We don't check if the certificate we find is from an accepted CA. */ int x509_cert_obtain(u_int8_t *id, size_t id_len, void *data, u_int8_t **cert, u_int32_t *certlen) { struct x509_aca *aca = data; X509 *scert; if (aca) LOG_DBG((LOG_CRYPTO, 60, "x509_cert_obtain: " "acceptable certificate authorities here")); /* We need our ID to find a certificate. */ if (!id) { log_print("x509_cert_obtain: ID is missing"); return 0; } scert = x509_hash_find(id, id_len); if (!scert) return 0; x509_serialize(scert, cert, certlen); if (!*cert) return 0; return 1; } /* Returns a pointer to the subjectAltName information of X509 certificate. */ int x509_cert_subjectaltname(X509 *scert, u_int8_t **altname, u_int32_t *len) { X509_EXTENSION *subjectaltname; u_int8_t *sandata; int extpos, santype, sanlen; extpos = X509_get_ext_by_NID(scert, NID_subject_alt_name, -1); if (extpos == -1) { log_print("x509_cert_subjectaltname: " "certificate does not contain subjectAltName"); return 0; } subjectaltname = X509_get_ext(scert, extpos); if (!subjectaltname || !subjectaltname->value || !subjectaltname->value->data || subjectaltname->value->length < 4) { log_print("x509_cert_subjectaltname: invalid " "subjectaltname extension"); return 0; } /* SSL does not handle unknown ASN stuff well, do it by hand. */ sandata = subjectaltname->value->data; santype = sandata[2] & 0x3f; sanlen = sandata[3]; sandata += 4; if (sanlen + 4 != subjectaltname->value->length) { log_print("x509_cert_subjectaltname: subjectaltname invalid " "length"); return 0; } *len = sanlen; *altname = sandata; return santype; } int x509_cert_get_subjects(void *scert, int *cnt, u_int8_t ***id, u_int32_t **id_len) { X509 *cert = scert; X509_NAME *subject; int type; u_int8_t *altname; u_int32_t altlen; u_int8_t *buf = 0; unsigned char *ubuf; int i; *id = 0; *id_len = 0; /* * XXX There can be a collection of subjectAltNames, but for now I * only return the subjectName and a single subjectAltName, if * present. */ type = x509_cert_subjectaltname(cert, &altname, &altlen); if (!type) { *cnt = 1; altlen = 0; } else *cnt = 2; *id = calloc(*cnt, sizeof **id); if (!*id) { log_print("x509_cert_get_subject: malloc (%lu) failed", *cnt * (unsigned long)sizeof **id); goto fail; } *id_len = malloc(*cnt * sizeof **id_len); if (!*id_len) { log_print("x509_cert_get_subject: malloc (%lu) failed", *cnt * (unsigned long)sizeof **id_len); goto fail; } /* Stash the subjectName into the first slot. */ subject = X509_get_subject_name(cert); if (!subject) goto fail; (*id_len)[0] = ISAKMP_ID_DATA_OFF + i2d_X509_NAME(subject, NULL) - ISAKMP_GEN_SZ; (*id)[0] = malloc((*id_len)[0]); if (!(*id)[0]) { log_print("x509_cert_get_subject: malloc (%d) failed", (*id_len)[0]); goto fail; } SET_ISAKMP_ID_TYPE((*id)[0] - ISAKMP_GEN_SZ, IPSEC_ID_DER_ASN1_DN); ubuf = (*id)[0] + ISAKMP_ID_DATA_OFF - ISAKMP_GEN_SZ; i2d_X509_NAME(subject, &ubuf); if (altlen) { /* Stash the subjectAltName into the second slot. */ buf = malloc(altlen + ISAKMP_ID_DATA_OFF); if (!buf) { log_print("x509_cert_get_subject: malloc (%d) failed", altlen + ISAKMP_ID_DATA_OFF); goto fail; } switch (type) { case X509v3_DNS_NAME: SET_ISAKMP_ID_TYPE(buf, IPSEC_ID_FQDN); break; case X509v3_RFC_NAME: SET_ISAKMP_ID_TYPE(buf, IPSEC_ID_USER_FQDN); break; case X509v3_IP_ADDR: /* * XXX I dislike the numeric constants, but I don't * know what we should use otherwise. */ switch (altlen) { case 4: SET_ISAKMP_ID_TYPE(buf, IPSEC_ID_IPV4_ADDR); break; case 16: SET_ISAKMP_ID_TYPE(buf, IPSEC_ID_IPV6_ADDR); break; default: log_print("x509_cert_get_subject: invalid " "subjectAltName IPaddress length %d ", altlen); goto fail; } break; } SET_IPSEC_ID_PROTO(buf + ISAKMP_ID_DOI_DATA_OFF, 0); SET_IPSEC_ID_PORT(buf + ISAKMP_ID_DOI_DATA_OFF, 0); memcpy(buf + ISAKMP_ID_DATA_OFF, altname, altlen); (*id_len)[1] = ISAKMP_ID_DATA_OFF + altlen - ISAKMP_GEN_SZ; (*id)[1] = malloc((*id_len)[1]); if (!(*id)[1]) { log_print("x509_cert_get_subject: malloc (%d) failed", (*id_len)[1]); goto fail; } memcpy((*id)[1], buf + ISAKMP_GEN_SZ, (*id_len)[1]); free(buf); buf = 0; } return 1; fail: for (i = 0; i < *cnt; i++) if ((*id)[i]) free((*id)[i]); if (*id) free(*id); if (*id_len) free(*id_len); if (buf) free(buf); return 0; } int x509_cert_get_key(void *scert, void *keyp) { X509 *cert = scert; EVP_PKEY *key; key = X509_get_pubkey(cert); /* Check if we got the right key type. */ if (key->type != EVP_PKEY_RSA) { log_print("x509_cert_get_key: public key is not a RSA key"); X509_free(cert); return 0; } *(RSA **)keyp = RSAPublicKey_dup(key->pkey.rsa); return *(RSA **)keyp == NULL ? 0 : 1; } void * x509_cert_dup(void *scert) { return X509_dup(scert); } void x509_serialize(void *scert, u_int8_t **data, u_int32_t *datalen) { u_int8_t *p; *datalen = i2d_X509((X509 *)scert, NULL); *data = p = malloc(*datalen); if (!p) { log_error("x509_serialize: malloc (%d) failed", *datalen); return; } *datalen = i2d_X509((X509 *)scert, &p); } /* From cert to printable */ char * x509_printable(void *cert) { char *s; u_int8_t *data; u_int32_t datalen, i; x509_serialize(cert, &data, &datalen); if (!data) return 0; s = malloc(datalen * 2 + 1); if (!s) { free(data); log_error("x509_printable: malloc (%d) failed", datalen * 2 + 1); return 0; } for (i = 0; i < datalen; i++) snprintf(s + (2 * i), 2 * (datalen - i) + 1, "%02x", data[i]); free(data); return s; } /* From printable to cert */ void * x509_from_printable(char *cert) { u_int8_t *buf; int plen, ret; void *foo; plen = (strlen(cert) + 1) / 2; buf = malloc(plen); if (!buf) { log_error("x509_from_printable: malloc (%d) failed", plen); return 0; } ret = hex2raw(cert, buf, plen); if (ret == -1) { free(buf); log_print("x509_from_printable: badly formatted cert"); return 0; } foo = x509_cert_get(buf, plen); free(buf); if (!foo) log_print("x509_from_printable: " "could not retrieve certificate"); return foo; } char * x509_DN_string(u_int8_t *asn1, size_t sz) { X509_NAME *name; u_int8_t *p = asn1; char buf[256]; /* XXX Just a guess at a maximum length. */ name = d2i_X509_NAME(NULL, &p, sz); if (!name) { log_print("x509_DN_string: d2i_X509_NAME failed"); return 0; } if (!X509_NAME_oneline(name, buf, sizeof buf - 1)) { log_print("x509_DN_string: X509_NAME_oneline failed"); X509_NAME_free(name); return 0; } X509_NAME_free(name); buf[sizeof buf - 1] = '\0'; return strdup(buf); }