/* * pkcs15-tool.c: Tool for poking with PKCS #15 smart cards * * Copyright (C) 2001 Juha Yrjölä * Copyright (C) 2008 Andreas Jellinghaus * * This library is free software; you can redistribute it and/or * modify it under the terms of the GNU Lesser General Public * License as published by the Free Software Foundation; either * version 2.1 of the License, or (at your option) any later version. * * This library is distributed in the hope that it will be useful, * but WITHOUT ANY WARRANTY; without even the implied warranty of * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU * Lesser General Public License for more details. * * You should have received a copy of the GNU Lesser General Public * License along with this library; if not, write to the Free Software * Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA */ #include "config.h" #ifdef ENABLE_OPENSSL #if defined(HAVE_INTTYPES_H) #include #elif defined(HAVE_STDINT_H) #include #elif defined(_MSC_VER) typedef unsigned __int32 uint32_t; #else #warning no uint32_t type available, please contact opensc-devel@opensc-project.org #endif #include #include #endif #include #include "libopensc/pkcs15.h" #include "libopensc/asn1.h" #include "util.h" static const char *app_name = "pkcs15-tool"; static int opt_wait = 0; static int opt_no_cache = 0; static char * opt_auth_id; static char * opt_reader = NULL; static char * opt_cert = NULL; static char * opt_data = NULL; static char * opt_pubkey = NULL; static char * opt_outfile = NULL; static char * opt_bind_to_aid = NULL; static u8 * opt_newpin = NULL; static u8 * opt_pin = NULL; static u8 * opt_puk = NULL; static int verbose = 0; enum { OPT_CHANGE_PIN = 0x100, OPT_LIST_PINS, OPT_READER, OPT_PIN_ID, OPT_NO_CACHE, OPT_LIST_PUB, OPT_READ_PUB, #if defined(ENABLE_OPENSSL) && (defined(_WIN32) || defined(HAVE_INTTYPES_H)) OPT_READ_SSH, #endif OPT_PIN, OPT_NEWPIN, OPT_PUK, OPT_VERIFY_PIN, OPT_BIND_TO_AID, OPT_LIST_APPLICATIONS, }; #define NELEMENTS(x) (sizeof(x)/sizeof((x)[0])) static int authenticate(sc_pkcs15_object_t *obj); static int pem_encode(int, sc_pkcs15_der_t *, sc_pkcs15_der_t *); static const struct option options[] = { { "learn-card", no_argument, NULL, 'L' }, { "list-applications", no_argument, NULL, OPT_LIST_APPLICATIONS }, { "read-certificate", required_argument, NULL, 'r' }, { "list-certificates", no_argument, NULL, 'c' }, { "read-data-object", required_argument, NULL, 'R' }, { "list-data-objects", no_argument, NULL, 'C' }, { "list-pins", no_argument, NULL, OPT_LIST_PINS }, { "dump", no_argument, NULL, 'D' }, { "unblock-pin", no_argument, NULL, 'u' }, { "change-pin", no_argument, NULL, OPT_CHANGE_PIN }, { "list-keys", no_argument, NULL, 'k' }, { "list-public-keys", no_argument, NULL, OPT_LIST_PUB }, { "read-public-key", required_argument, NULL, OPT_READ_PUB }, #if defined(ENABLE_OPENSSL) && (defined(_WIN32) || defined(HAVE_INTTYPES_H)) { "read-ssh-key", required_argument, NULL, OPT_READ_SSH }, #endif { "test-update", no_argument, NULL, 'T' }, { "update", no_argument, NULL, 'U' }, { "reader", required_argument, NULL, OPT_READER }, { "pin", required_argument, NULL, OPT_PIN }, { "new-pin", required_argument, NULL, OPT_NEWPIN }, { "puk", required_argument, NULL, OPT_PUK }, { "verify-pin", no_argument, NULL, OPT_VERIFY_PIN }, { "output", required_argument, NULL, 'o' }, { "no-cache", no_argument, NULL, OPT_NO_CACHE }, { "auth-id", required_argument, NULL, 'a' }, { "aid", required_argument, NULL, OPT_BIND_TO_AID }, { "wait", no_argument, NULL, 'w' }, { "verbose", no_argument, NULL, 'v' }, { NULL, 0, NULL, 0 } }; static const char *option_help[] = { "Stores card info to cache", "List the on-card PKCS#15 applications", "Reads certificate with ID ", "Lists certificates", "Reads data object with OID, applicationName or label ", "Lists data objects", "Lists PIN codes", "Dump card objects", "Unblock PIN code", "Change PIN or PUK code", "Lists private keys", "Lists public keys", "Reads public key with ID ", #if defined(ENABLE_OPENSSL) && (defined(_WIN32) || defined(HAVE_INTTYPES_H)) "Reads public key with ID , outputs ssh format", #endif "Test if the card needs a security update", "Update the card with a security update", "Uses reader number ", "Specify PIN", "Specify New PIN (when changing or unblocking)", "Specify Unblock PIN", "Verify PIN after card binding (without 'auth-id' the first non-SO, non-Unblock PIN will be verified)", "Outputs to file ", "Disable card caching", "The auth ID of the PIN to use", "Specify AID of the on-card PKCS#15 application to be binded to (in hexadecimal form)", "Wait for card insertion", "Verbose operation. Use several times to enable debug output.", }; static sc_context_t *ctx = NULL; static sc_card_t *card = NULL; static struct sc_pkcs15_card *p15card = NULL; struct _access_rule_text { unsigned flag; const char *label; } _access_rules_text[] = { {SC_PKCS15_ACCESS_RULE_MODE_READ, "read"}, {SC_PKCS15_ACCESS_RULE_MODE_UPDATE, "update"}, {SC_PKCS15_ACCESS_RULE_MODE_EXECUTE, "execute"}, {SC_PKCS15_ACCESS_RULE_MODE_DELETE, "delete"}, {SC_PKCS15_ACCESS_RULE_MODE_ATTRIBUTE, "attribute"}, {SC_PKCS15_ACCESS_RULE_MODE_PSO_CDS, "pso_cds"}, {SC_PKCS15_ACCESS_RULE_MODE_PSO_VERIFY, "pso_verify"}, {SC_PKCS15_ACCESS_RULE_MODE_PSO_DECRYPT, "pso_decrypt"}, {SC_PKCS15_ACCESS_RULE_MODE_PSO_ENCRYPT, "pso_encrypt"}, {SC_PKCS15_ACCESS_RULE_MODE_INT_AUTH, "int_auth"}, {SC_PKCS15_ACCESS_RULE_MODE_EXT_AUTH, "ext_auth"}, {0, NULL}, }; static void print_access_rules(const struct sc_pkcs15_accessrule *rules, int num) { int i, j; if (!rules->access_mode) return; printf("\tAccess Rules:\t"); for (i = 0; i < num; i++) { int next_coma = 0; if (!(rules + i)->access_mode) break; printf(" "); for (j = 0; _access_rules_text[j].label;j++) { if ((rules + i)->access_mode & (_access_rules_text[j].flag)) { printf("%s%s", next_coma ? "," : "", _access_rules_text[j].label); next_coma = 1; } } printf(":%s;", (rules + i)->auth_id.len ? sc_pkcs15_print_id(&(rules + i)->auth_id) : ""); } printf("\n"); } static void print_common_flags(const struct sc_pkcs15_object *obj) { const char *common_flags[] = {"private", "modifiable"}; unsigned int i; printf("\tObject Flags : [0x%X]", obj->flags); for (i = 0; i < NELEMENTS(common_flags); i++) { if (obj->flags & (1 << i)) { printf(", %s", common_flags[i]); } } printf("\n"); } static void print_cert_info(const struct sc_pkcs15_object *obj) { struct sc_pkcs15_cert_info *cert_info = (struct sc_pkcs15_cert_info *) obj->data; struct sc_pkcs15_cert *cert_parsed = NULL; char guid[39]; int rv; printf("X.509 Certificate [%s]\n", obj->label); print_common_flags(obj); printf("\tAuthority : %s\n", cert_info->authority ? "yes" : "no"); printf("\tPath : %s\n", sc_print_path(&cert_info->path)); printf("\tID : %s\n", sc_pkcs15_print_id(&cert_info->id)); rv = sc_pkcs15_get_guid(p15card, obj, guid, sizeof(guid)); if (!rv) printf("\tGUID : %s\n", guid); print_access_rules(obj->access_rules, SC_PKCS15_MAX_ACCESS_RULES); rv = sc_pkcs15_read_certificate(p15card, cert_info, &cert_parsed); if (rv >= 0 && cert_parsed) { printf("\tEncoded serial : %02X %02X ", *(cert_parsed->serial), *(cert_parsed->serial + 1)); util_hex_dump(stdout, cert_parsed->serial + 2, cert_parsed->serial_len - 2, ""); printf("\n"); sc_pkcs15_free_certificate(cert_parsed); } } static int list_certificates(void) { int r, i; struct sc_pkcs15_object *objs[32]; r = sc_pkcs15_get_objects(p15card, SC_PKCS15_TYPE_CERT_X509, objs, 32); if (r < 0) { fprintf(stderr, "Certificate enumeration failed: %s\n", sc_strerror(r)); return 1; } if (verbose) printf("Card has %d certificate(s).\n\n", r); for (i = 0; i < r; i++) { print_cert_info(objs[i]); printf("\n"); } return 0; } static int print_pem_object(const char *kind, const u8*data, size_t data_len) { FILE *outf; unsigned char *buf = NULL; size_t buf_len = 1024; int r; /* With base64, every 3 bytes yield 4 characters, and with * 64 chars per line we know almost exactly how large a buffer we * will need. */ buf_len = (data_len + 2) / 3 * 4; buf_len += 2 * (buf_len / 64 + 2); /* certain platforms use CRLF */ buf_len += 64; /* slack for checksum etc */ if (!(buf = malloc(buf_len))) { perror("print_pem_object"); return 1; } r = sc_base64_encode(data, data_len, buf, buf_len, 64); if (r < 0) { fprintf(stderr, "Base64 encoding failed: %s\n", sc_strerror(r)); free(buf); return 1; } if (opt_outfile != NULL) { outf = fopen(opt_outfile, "w"); if (outf == NULL) { fprintf(stderr, "Error opening file '%s': %s\n", opt_outfile, strerror(errno)); free(buf); return 2; } } else outf = stdout; fprintf(outf, "-----BEGIN %s-----\n" "%s" "-----END %s-----\n", kind, buf, kind); if (outf != stdout) fclose(outf); free(buf); return 0; } static int list_data_object(const char *kind, const u8*data, size_t data_len) { size_t i; printf("%s (%lu bytes): <", kind, (unsigned long) data_len); for (i = 0; i < data_len; i++) printf(" %02X", data[i]); printf(" >\n"); return 0; } static int print_data_object(const char *kind, const u8*data, size_t data_len) { size_t i; if (opt_outfile != NULL) { FILE *outf; outf = fopen(opt_outfile, "w"); if (outf == NULL) { fprintf(stderr, "Error opening file '%s': %s\n", opt_outfile, strerror(errno)); return 2; } for (i=0; i < data_len; i++) fprintf(outf, "%c", data[i]); printf("Dumping (%lu bytes) to file <%s>: <", (unsigned long) data_len, opt_outfile); for (i=0; i < data_len; i++) printf(" %02X", data[i]); printf(" >\n"); fclose(outf); } else { printf("%s (%lu bytes): <", kind, (unsigned long) data_len); for (i=0; i < data_len; i++) printf(" %02X", data[i]); printf(" >\n"); } return 0; } static int read_certificate(void) { int r, i, count; struct sc_pkcs15_id id; struct sc_pkcs15_object *objs[32]; id.len = SC_PKCS15_MAX_ID_SIZE; sc_pkcs15_hex_string_to_id(opt_cert, &id); r = sc_pkcs15_get_objects(p15card, SC_PKCS15_TYPE_CERT_X509, objs, 32); if (r < 0) { fprintf(stderr, "Certificate enumeration failed: %s\n", sc_strerror(r)); return 1; } count = r; for (i = 0; i < count; i++) { struct sc_pkcs15_cert_info *cinfo = (struct sc_pkcs15_cert_info *) objs[i]->data; struct sc_pkcs15_cert *cert; if (sc_pkcs15_compare_id(&id, &cinfo->id) != 1) continue; if (verbose) printf("Reading certificate with ID '%s'\n", opt_cert); r = sc_pkcs15_read_certificate(p15card, cinfo, &cert); if (r) { fprintf(stderr, "Certificate read failed: %s\n", sc_strerror(r)); return 1; } r = print_pem_object("CERTIFICATE", cert->data, cert->data_len); sc_pkcs15_free_certificate(cert); return r; } fprintf(stderr, "Certificate with ID '%s' not found.\n", opt_cert); return 2; } static int read_data_object(void) { int r, i, count, oid_len = 0; struct sc_pkcs15_object *objs[32]; struct sc_object_id oid; r = sc_pkcs15_get_objects(p15card, SC_PKCS15_TYPE_DATA_OBJECT, objs, 32); if (r < 0) { fprintf(stderr, "Data object enumeration failed: %s\n", sc_strerror(r)); return 1; } count = r; r = sc_format_oid(&oid, opt_data); if (r == SC_SUCCESS) { while (oid.value[oid_len] >= 0) oid_len++; } for (i = 0; i < count; i++) { struct sc_pkcs15_data_info *cinfo = (struct sc_pkcs15_data_info *) objs[i]->data; struct sc_pkcs15_data *data_object; if (oid_len) { if (memcmp(oid.value, cinfo->app_oid.value, sizeof(int) * oid_len)) continue; } else { if (strcmp(opt_data, cinfo->app_label) && strcmp(opt_data, objs[i]->label)) continue; } if (verbose) printf("Reading data object with label '%s'\n", opt_data); r = authenticate(objs[i]); if (r >= 0) { r = sc_pkcs15_read_data_object(p15card, cinfo, &data_object); if (r) { fprintf(stderr, "Data object read failed: %s\n", sc_strerror(r)); if (r == SC_ERROR_FILE_NOT_FOUND) continue; /* DEE emulation may say there is a file */ return 1; } r = print_data_object("Data Object", data_object->data, data_object->data_len); sc_pkcs15_free_data_object(data_object); return r; } else { fprintf(stderr, "Authentication error: %s\n", sc_strerror(r)); return 1; } } fprintf(stderr, "Data object with label '%s' not found.\n", opt_data); return 2; } static int list_data_objects(void) { int r, i, count; struct sc_pkcs15_object *objs[32]; r = sc_pkcs15_get_objects(p15card, SC_PKCS15_TYPE_DATA_OBJECT, objs, 32); if (r < 0) { fprintf(stderr, "Data object enumeration failed: %s\n", sc_strerror(r)); return 1; } count = r; for (i = 0; i < count; i++) { int idx; struct sc_pkcs15_data_info *cinfo = (struct sc_pkcs15_data_info *) objs[i]->data; printf("Reading data object <%i>\n", i); printf("applicationName: %s\n", cinfo->app_label); printf("Label: %s\n", objs[i]->label); printf("applicationOID: "); if (cinfo->app_oid.value[0] >= 0) { printf("%i", cinfo->app_oid.value[0]); idx = 1; while (idx < SC_MAX_OBJECT_ID_OCTETS) { if (cinfo->app_oid.value[idx] < 0) break; printf(".%i", cinfo->app_oid.value[idx++]); } printf("\n"); } else printf("NONE\n"); printf("Path: %s\n", sc_print_path(&cinfo->path)); if (objs[i]->auth_id.len == 0) { struct sc_pkcs15_data *data_object; r = sc_pkcs15_read_data_object(p15card, cinfo, &data_object); if (r) { fprintf(stderr, "Data object read failed: %s\n", sc_strerror(r)); if (r == SC_ERROR_FILE_NOT_FOUND) continue; /* DEE emulation may say there is a file */ return 1; } r = list_data_object("Data Object", data_object->data, data_object->data_len); sc_pkcs15_free_data_object(data_object); } else { printf("Auth ID: %s\n", sc_pkcs15_print_id(&objs[i]->auth_id)); } } return 0; } static void print_prkey_info(const struct sc_pkcs15_object *obj) { unsigned int i; struct sc_pkcs15_prkey_info *prkey = (struct sc_pkcs15_prkey_info *) obj->data; const char *types[] = { "", "RSA", "DSA", "GOSTR3410", "EC", "", "", "" }; const char *usages[] = { "encrypt", "decrypt", "sign", "signRecover", "wrap", "unwrap", "verify", "verifyRecover", "derive", "nonRepudiation" }; const size_t usage_count = NELEMENTS(usages); const char *access_flags[] = { "sensitive", "extract", "alwaysSensitive", "neverExtract", "local" }; const unsigned int af_count = NELEMENTS(access_flags); char guid[39]; printf("Private %s Key [%s]\n", types[7 & obj->type], obj->label); print_common_flags(obj); printf("\tUsage : [0x%X]", prkey->usage); for (i = 0; i < usage_count; i++) if (prkey->usage & (1 << i)) { printf(", %s", usages[i]); } printf("\n"); printf("\tAccess Flags : [0x%X]", prkey->access_flags); for (i = 0; i < af_count; i++) if (prkey->access_flags & (1 << i)) printf(", %s", access_flags[i]); printf("\n"); print_access_rules(obj->access_rules, SC_PKCS15_MAX_ACCESS_RULES); if (prkey->modulus_length) printf("\tModLength : %lu\n", (unsigned long)prkey->modulus_length); else printf("\tFieldLength : %lu\n", (unsigned long)prkey->field_length); printf("\tKey ref : %d (0x%X)\n", prkey->key_reference, prkey->key_reference); printf("\tNative : %s\n", prkey->native ? "yes" : "no"); if (prkey->path.len || prkey->path.aid.len) printf("\tPath : %s\n", sc_print_path(&prkey->path)); if (obj->auth_id.len != 0) printf("\tAuth ID : %s\n", sc_pkcs15_print_id(&obj->auth_id)); printf("\tID : %s\n", sc_pkcs15_print_id(&prkey->id)); if (!sc_pkcs15_get_guid(p15card, obj, guid, sizeof(guid))) printf("\tGUID : %s\n", guid); } static int list_private_keys(void) { int r, i; struct sc_pkcs15_object *objs[32]; r = sc_pkcs15_get_objects(p15card, SC_PKCS15_TYPE_PRKEY, objs, 32); if (r < 0) { fprintf(stderr, "Private key enumeration failed: %s\n", sc_strerror(r)); return 1; } if (verbose) printf("Card has %d private key(s).\n\n", r); for (i = 0; i < r; i++) { print_prkey_info(objs[i]); printf("\n"); } return 0; } static void print_pubkey_info(const struct sc_pkcs15_object *obj) { unsigned int i; const struct sc_pkcs15_pubkey_info *pubkey = (const struct sc_pkcs15_pubkey_info *) obj->data; const char *types[] = { "", "RSA", "DSA", "GOSTR3410", "EC", "", "", "" }; const char *usages[] = { "encrypt", "decrypt", "sign", "signRecover", "wrap", "unwrap", "verify", "verifyRecover", "derive", "nonRepudiation" }; const unsigned int usage_count = NELEMENTS(usages); const char *access_flags[] = { "sensitive", "extract", "alwaysSensitive", "neverExtract", "local" }; const unsigned int af_count = NELEMENTS(access_flags); printf("Public %s Key [%s]\n", types[7 & obj->type], obj->label); print_common_flags(obj); printf("\tUsage : [0x%X]", pubkey->usage); for (i = 0; i < usage_count; i++) if (pubkey->usage & (1 << i)) { printf(", %s", usages[i]); } printf("\n"); printf("\tAccess Flags : [0x%X]", pubkey->access_flags); for (i = 0; i < af_count; i++) if (pubkey->access_flags & (1 << i)) printf(", %s", access_flags[i]); printf("\n"); print_access_rules(obj->access_rules, SC_PKCS15_MAX_ACCESS_RULES); if (pubkey->modulus_length) printf("\tModLength : %lu\n", (unsigned long)pubkey->modulus_length); else printf("\tFieldLength : %lu\n", (unsigned long)pubkey->field_length); printf("\tKey ref : %d\n", pubkey->key_reference); printf("\tNative : %s\n", pubkey->native ? "yes" : "no"); if (pubkey->path.len) printf("\tPath : %s\n", sc_print_path(&pubkey->path)); if (obj->auth_id.len != 0) printf("\tAuth ID : %s\n", sc_pkcs15_print_id(&obj->auth_id)); printf("\tID : %s\n", sc_pkcs15_print_id(&pubkey->id)); } static int list_public_keys(void) { int r, i; struct sc_pkcs15_object *objs[32]; r = sc_pkcs15_get_objects(p15card, SC_PKCS15_TYPE_PUBKEY, objs, 32); if (r < 0) { fprintf(stderr, "Public key enumeration failed: %s\n", sc_strerror(r)); return 1; } if (verbose) printf("Card has %d public key(s).\n\n", r); for (i = 0; i < r; i++) { print_pubkey_info(objs[i]); printf("\n"); } return 0; } static int read_public_key(void) { int r; struct sc_pkcs15_id id; struct sc_pkcs15_object *obj; sc_pkcs15_pubkey_t *pubkey = NULL; sc_pkcs15_cert_t *cert = NULL; sc_pkcs15_der_t pem_key; id.len = SC_PKCS15_MAX_ID_SIZE; sc_pkcs15_hex_string_to_id(opt_pubkey, &id); r = sc_pkcs15_find_pubkey_by_id(p15card, &id, &obj); if (r >= 0) { if (verbose) printf("Reading public key with ID '%s'\n", opt_pubkey); r = authenticate(obj); if (r >= 0) r = sc_pkcs15_read_pubkey(p15card, obj, &pubkey); } else if (r == SC_ERROR_OBJECT_NOT_FOUND) { /* No pubkey - try if there's a certificate */ r = sc_pkcs15_find_cert_by_id(p15card, &id, &obj); if (r >= 0) { if (verbose) printf("Reading certificate with ID '%s'\n", opt_pubkey); r = sc_pkcs15_read_certificate(p15card, (sc_pkcs15_cert_info_t *) obj->data, &cert); } if (r >= 0) pubkey = cert->key; } if (r == SC_ERROR_OBJECT_NOT_FOUND) { fprintf(stderr, "Public key with ID '%s' not found.\n", opt_pubkey); return 2; } if (r < 0) { fprintf(stderr, "Public key enumeration failed: %s\n", sc_strerror(r)); return 1; } if (!pubkey) { fprintf(stderr, "Public key not available\n"); return 1; } r = pem_encode(pubkey->algorithm, &pubkey->data, &pem_key); if (r < 0) { fprintf(stderr, "Error encoding PEM key: %s\n", sc_strerror(r)); r = 1; } else { r = print_pem_object("PUBLIC KEY", pem_key.value, pem_key.len); free(pem_key.value); } if (cert) sc_pkcs15_free_certificate(cert); else if (pubkey) sc_pkcs15_free_pubkey(pubkey); return r; } #if defined(ENABLE_OPENSSL) && (defined(_WIN32) || defined(HAVE_INTTYPES_H)) static int read_ssh_key(void) { int r; struct sc_pkcs15_id id; struct sc_pkcs15_object *obj; sc_pkcs15_pubkey_t *pubkey = NULL; sc_pkcs15_cert_t *cert = NULL; FILE *outf; if (opt_outfile != NULL) { outf = fopen(opt_outfile, "w"); if (outf == NULL) { fprintf(stderr, "Error opening file '%s': %s\n", opt_outfile, strerror(errno)); goto fail2; } } else outf = stdout; id.len = SC_PKCS15_MAX_ID_SIZE; sc_pkcs15_hex_string_to_id(opt_pubkey, &id); r = sc_pkcs15_find_pubkey_by_id(p15card, &id, &obj); if (r >= 0) { if (verbose) fprintf(stderr,"Reading ssh key with ID '%s'\n", opt_pubkey); r = authenticate(obj); if (r >= 0) r = sc_pkcs15_read_pubkey(p15card, obj, &pubkey); } else if (r == SC_ERROR_OBJECT_NOT_FOUND) { /* No pubkey - try if there's a certificate */ r = sc_pkcs15_find_cert_by_id(p15card, &id, &obj); if (r >= 0) { if (verbose) fprintf(stderr,"Reading certificate with ID '%s'\n", opt_pubkey); r = sc_pkcs15_read_certificate(p15card, (sc_pkcs15_cert_info_t *) obj->data, &cert); } if (r >= 0) pubkey = cert->key; } if (r == SC_ERROR_OBJECT_NOT_FOUND) { fprintf(stderr, "Public key with ID '%s' not found.\n", opt_pubkey); return 2; } if (r < 0) { fprintf(stderr, "Public key enumeration failed: %s\n", sc_strerror(r)); return 1; } /* rsa1 keys */ if (pubkey->algorithm == SC_ALGORITHM_RSA) { int bits; BIGNUM *bn; char *exp,*mod; bn = BN_new(); BN_bin2bn((unsigned char*)pubkey->u.rsa.modulus.data, pubkey->u.rsa.modulus.len, bn); bits = BN_num_bits(bn); exp = BN_bn2dec(bn); BN_free(bn); bn = BN_new(); BN_bin2bn((unsigned char*)pubkey->u.rsa.exponent.data, pubkey->u.rsa.exponent.len, bn); mod = BN_bn2dec(bn); BN_free(bn); if (bits && exp && mod) { fprintf(outf, "%u %s %s\n", bits,mod,exp); } else { fprintf(stderr, "decoding rsa key failed!\n"); } OPENSSL_free(exp); OPENSSL_free(mod); } /* rsa and des keys - ssh2 */ /* key_to_blob */ if (pubkey->algorithm == SC_ALGORITHM_RSA) { unsigned char buf[2048]; unsigned char *uu; uint32_t len; uint32_t n; buf[0]=0; buf[1]=0; buf[2]=0; buf[3]=7; len = sprintf((char *) buf+4,"ssh-rsa"); len+=4; if (sizeof(buf)-len < 4+pubkey->u.rsa.exponent.len) goto fail; n = pubkey->u.rsa.exponent.len; if (pubkey->u.rsa.exponent.data[0] & 0x80) n++; buf[len++]=(n >>24) & 0xff; buf[len++]=(n >>16) & 0xff; buf[len++]=(n >>8) & 0xff; buf[len++]=(n) & 0xff; if (pubkey->u.rsa.exponent.data[0] & 0x80) buf[len++]= 0; memcpy(buf+len,pubkey->u.rsa.exponent.data, pubkey->u.rsa.exponent.len); len += pubkey->u.rsa.exponent.len; if (sizeof(buf)-len < 5+pubkey->u.rsa.modulus.len) goto fail; n = pubkey->u.rsa.modulus.len; if (pubkey->u.rsa.modulus.data[0] & 0x80) n++; buf[len++]=(n >>24) & 0xff; buf[len++]=(n >>16) & 0xff; buf[len++]=(n >>8) & 0xff; buf[len++]=(n) & 0xff; if (pubkey->u.rsa.modulus.data[0] & 0x80) buf[len++]= 0; memcpy(buf+len,pubkey->u.rsa.modulus.data, pubkey->u.rsa.modulus.len); len += pubkey->u.rsa.modulus.len; uu = malloc(len*2); r = sc_base64_encode(buf, len, uu, 2*len, 2*len); fprintf(outf,"ssh-rsa %s", uu); free(uu); } if (pubkey->algorithm == SC_ALGORITHM_DSA) { unsigned char buf[2048]; unsigned char *uu; uint32_t len; uint32_t n; buf[0]=0; buf[1]=0; buf[2]=0; buf[3]=7; len = sprintf((char *) buf+4,"ssh-dss"); len+=4; if (sizeof(buf)-len < 5+pubkey->u.dsa.p.len) goto fail; n = pubkey->u.dsa.p.len; if (pubkey->u.dsa.p.data[0] & 0x80) n++; buf[len++]=(n >>24) & 0xff; buf[len++]=(n >>16) & 0xff; buf[len++]=(n >>8) & 0xff; buf[len++]=(n) & 0xff; if (pubkey->u.dsa.p.data[0] & 0x80) buf[len++]= 0; memcpy(buf+len,pubkey->u.dsa.p.data, pubkey->u.dsa.p.len); len += pubkey->u.dsa.p.len; if (sizeof(buf)-len < 5+pubkey->u.dsa.q.len) goto fail; n = pubkey->u.dsa.q.len; if (pubkey->u.dsa.q.data[0] & 0x80) n++; buf[len++]=(n >>24) & 0xff; buf[len++]=(n >>16) & 0xff; buf[len++]=(n >>8) & 0xff; buf[len++]=(n) & 0xff; if (pubkey->u.dsa.q.data[0] & 0x80) buf[len++]= 0; memcpy(buf+len,pubkey->u.dsa.q.data, pubkey->u.dsa.q.len); len += pubkey->u.dsa.q.len; if (sizeof(buf)-len < 5+pubkey->u.dsa.g.len) goto fail; n = pubkey->u.dsa.g.len; if (pubkey->u.dsa.g.data[0] & 0x80) n++; buf[len++]=(n >>24) & 0xff; buf[len++]=(n >>16) & 0xff; buf[len++]=(n >>8) & 0xff; buf[len++]=(n) & 0xff; if (pubkey->u.dsa.g.data[0] & 0x80) buf[len++]= 0; memcpy(buf+len,pubkey->u.dsa.g.data, pubkey->u.dsa.g.len); len += pubkey->u.dsa.g.len; if (sizeof(buf)-len < 5+pubkey->u.dsa.pub.len) goto fail; n = pubkey->u.dsa.pub.len; if (pubkey->u.dsa.pub.data[0] & 0x80) n++; buf[len++]=(n >>24) & 0xff; buf[len++]=(n >>16) & 0xff; buf[len++]=(n >>8) & 0xff; buf[len++]=(n) & 0xff; if (pubkey->u.dsa.pub.data[0] & 0x80) buf[len++]= 0; memcpy(buf+len,pubkey->u.dsa.pub.data, pubkey->u.dsa.pub.len); len += pubkey->u.dsa.pub.len; uu = malloc(len*2); r = sc_base64_encode(buf, len, uu, 2*len, 2*len); fprintf(outf,"ssh-dss %s", uu); free(uu); } if (outf != stdout) fclose(outf); if (cert) sc_pkcs15_free_certificate(cert); else if (pubkey) sc_pkcs15_free_pubkey(pubkey); return 0; fail: printf("can't convert key: buffer too small\n"); fail2: if (outf != stdout) fclose(outf); if (cert) sc_pkcs15_free_certificate(cert); else if (pubkey) sc_pkcs15_free_pubkey(pubkey); return SC_ERROR_OUT_OF_MEMORY; } #endif static sc_pkcs15_object_t * get_pin_info(void) { sc_pkcs15_object_t *objs[32], *obj; int r; if (opt_auth_id == NULL) { r = sc_pkcs15_get_objects(p15card, SC_PKCS15_TYPE_AUTH_PIN, objs, 32); if (r < 0) { fprintf(stderr, "PIN code enumeration failed: %s\n", sc_strerror(r)); return NULL; } if (r == 0) { fprintf(stderr, "No PIN codes found.\n"); return NULL; } obj = objs[0]; } else { struct sc_pkcs15_id auth_id; sc_pkcs15_hex_string_to_id(opt_auth_id, &auth_id); r = sc_pkcs15_find_pin_by_auth_id(p15card, &auth_id, &obj); if (r) { fprintf(stderr, "Unable to find PIN code: %s\n", sc_strerror(r)); return NULL; } } return obj; } static u8 * get_pin(const char *prompt, sc_pkcs15_object_t *pin_obj) { sc_pkcs15_pin_info_t *pinfo = (sc_pkcs15_pin_info_t *) pin_obj->data; char *pincode = NULL; size_t len = 0; int r; printf("%s [%s]: ", prompt, pin_obj->label); while (1) { r = util_getpass(&pincode, &len, stdin); if (r < 0) return NULL; if (!pincode || strlen(pincode) == 0) return NULL; if (strlen(pincode) < pinfo->min_length) { printf("PIN code too short, try again.\n"); continue; } if (strlen(pincode) > pinfo->max_length) { printf("PIN code too long, try again.\n"); continue; } return (u8 *) strdup(pincode); } } static int verify_pin(void) { struct sc_pkcs15_object *pin_obj = NULL; unsigned char *pin; int r; if (!opt_auth_id) { struct sc_pkcs15_object *objs[32]; int ii; r = sc_pkcs15_get_objects(p15card, SC_PKCS15_TYPE_AUTH_PIN, objs, 32); if (r < 0) { fprintf(stderr, "PIN code enumeration failed: %s\n", sc_strerror(r)); return -1; } for (ii=0;iidata; if (pin_info->flags & SC_PKCS15_PIN_FLAG_SO_PIN) continue; if (pin_info->flags & SC_PKCS15_PIN_FLAG_UNBLOCKING_PIN) continue; pin_obj = objs[ii]; break; } } else { pin_obj = get_pin_info(); } if (!pin_obj) { fprintf(stderr, "PIN object '%s' not found\n", opt_auth_id); return -1; } if (opt_pin != NULL) pin = opt_pin; else pin = get_pin("Please enter PIN", pin_obj); r = sc_pkcs15_verify_pin(p15card, pin_obj, pin, pin ? strlen((char *) pin) : 0); if (r < 0) { fprintf(stderr, "Operation failed: %s\n", sc_strerror(r)); return -1; } return 0; } static int authenticate(sc_pkcs15_object_t *obj) { sc_pkcs15_object_t *pin_obj; u8 *pin; int r; if (obj->auth_id.len == 0) return 0; r = sc_pkcs15_find_pin_by_auth_id(p15card, &obj->auth_id, &pin_obj); if (r) return r; if (opt_pin != NULL) pin = opt_pin; else pin = get_pin("Please enter PIN", pin_obj); return sc_pkcs15_verify_pin(p15card, pin_obj, pin, pin? strlen((char *) pin) : 0); } static void print_pin_info(const struct sc_pkcs15_object *obj) { const char *pin_flags[] = { "case-sensitive", "local", "change-disabled", "unblock-disabled", "initialized", "needs-padding", "unblockingPin", "soPin", "disable_allowed", "integrity-protected", "confidentiality-protected", "exchangeRefData" }; const char *pin_types[] = {"bcd", "ascii-numeric", "UTF-8", "halfnibble bcd", "iso 9664-1"}; const struct sc_pkcs15_pin_info *pin = (const struct sc_pkcs15_pin_info *) obj->data; const size_t pf_count = NELEMENTS(pin_flags); size_t i; printf("PIN [%s]\n", obj->label); print_common_flags(obj); if (obj->auth_id.len) printf("\tAuth ID : %s\n", sc_pkcs15_print_id(&obj->auth_id)); printf("\tID : %s\n", sc_pkcs15_print_id(&pin->auth_id)); printf("\tFlags : [0x%02X]", pin->flags); for (i = 0; i < pf_count; i++) if (pin->flags & (1 << i)) { printf(", %s", pin_flags[i]); } printf("\n"); printf("\tLength : min_len:%lu, max_len:%lu, stored_len:%lu\n", (unsigned long)pin->min_length, (unsigned long)pin->max_length, (unsigned long)pin->stored_length); printf("\tPad char : 0x%02X\n", pin->pad_char); printf("\tReference : %d\n", pin->reference); if (pin->type < NELEMENTS(pin_types)) printf("\tType : %s\n", pin_types[pin->type]); else printf("\tType : [encoding %d]\n", pin->type); if (pin->path.len || pin->path.aid.len) printf("\tPath : %s\n", sc_print_path(&pin->path)); if (pin->tries_left >= 0) printf("\tTries left : %d\n", pin->tries_left); } static int list_pins(void) { int r, i; struct sc_pkcs15_object *objs[32]; r = sc_pkcs15_get_objects(p15card, SC_PKCS15_TYPE_AUTH_PIN, objs, 32); if (r < 0) { fprintf(stderr, "PIN enumeration failed: %s\n", sc_strerror(r)); return 1; } if (verbose) printf("Card has %d PIN code(s).\n\n", r); for (i = 0; i < r; i++) { print_pin_info(objs[i]); printf("\n"); } return 0; } static int list_apps(FILE *fout) { unsigned j; int i; for (i=0; icard->app_count; i++) { struct sc_app_info *info = p15card->card->app[i]; fprintf(fout, "Application '%s':\n", info->label); fprintf(fout, "\tAID: "); for(j=0;jaid.len;j++) fprintf(fout, "%02X", info->aid.value[j]); fprintf(fout, "\n"); if (info->ddo.value && info->ddo.len) { fprintf(fout, "\tDDO: "); for(j=0;jddo.len;j++) fprintf(fout, "%02X", info->ddo.value[j]); fprintf(fout, "\n"); } fprintf(fout, "\n"); } return 0; } static int dump(void) { const char *flags[] = { "Read-only", "Login required", "PRN generation", "EID compliant" }; int i, count = 0; printf("PKCS#15 Card [%s]:\n", p15card->tokeninfo->label); printf("\tVersion : %d\n", p15card->tokeninfo->version); printf("\tSerial number : %s\n", p15card->tokeninfo->serial_number); printf("\tManufacturer ID: %s\n", p15card->tokeninfo->manufacturer_id); if (p15card->tokeninfo->last_update) printf("\tLast update : %s\n", p15card->tokeninfo->last_update); if (p15card->tokeninfo->preferred_language) printf("\tLanguage : %s\n", p15card->tokeninfo->preferred_language); printf("\tFlags : "); for (i = 0; i < 4; i++) { if ((p15card->tokeninfo->flags >> i) & 1) { if (count) printf(", "); printf("%s", flags[i]); count++; } } printf("\n\n"); list_pins(); list_private_keys(); list_public_keys(); list_certificates(); list_data_objects(); return 0; } static int unblock_pin(void) { struct sc_pkcs15_pin_info *pinfo = NULL; sc_pkcs15_object_t *pin_obj; u8 *pin, *puk; int r, pinpad_present = 0; pinpad_present = p15card->card->reader->capabilities & SC_READER_CAP_PIN_PAD; if (!(pin_obj = get_pin_info())) return 2; pinfo = (sc_pkcs15_pin_info_t *) pin_obj->data; puk = opt_puk; if (puk == NULL) { puk = get_pin("Enter PUK", pin_obj); if (!pinpad_present && puk == NULL) return 2; } if (puk == NULL && verbose) printf("PUK value will be prompted with pinpad.\n"); pin = opt_pin ? opt_pin : opt_newpin; while (pin == NULL) { u8 *pin2; pin = get_pin("Enter new PIN", pin_obj); if (pinpad_present && pin == NULL) { if (verbose) printf("New PIN value will be prompted with pinpad.\n"); break; } if (pin == NULL || strlen((char *) pin) == 0) return 2; pin2 = get_pin("Enter new PIN again", pin_obj); if (pin2 == NULL || strlen((char *) pin2) == 0) return 2; if (strcmp((char *) pin, (char *) pin2) != 0) { printf("PIN codes do not match, try again.\n"); free(pin); pin = NULL; } free(pin2); } r = sc_pkcs15_unblock_pin(p15card, pin_obj, puk, puk ? strlen((char *) puk) : 0, pin, pin ? strlen((char *) pin) : 0); if (r == SC_ERROR_PIN_CODE_INCORRECT) { fprintf(stderr, "PUK code incorrect; tries left: %d\n", pinfo->tries_left); return 3; } else if (r) { fprintf(stderr, "PIN unblocking failed: %s\n", sc_strerror(r)); return 2; } if (verbose) printf("PIN successfully unblocked.\n"); return 0; } static int change_pin(void) { sc_pkcs15_object_t *pin_obj; sc_pkcs15_pin_info_t *pinfo = NULL; u8 *pincode, *newpin; int r, pinpad_present = 0; pinpad_present = p15card->card->reader->capabilities & SC_READER_CAP_PIN_PAD; if (!(pin_obj = get_pin_info())) return 2; pinfo = (sc_pkcs15_pin_info_t *) pin_obj->data; if (pinfo->tries_left != -1) { if (pinfo->tries_left != pinfo->max_tries) { if (pinfo->tries_left == 0) { fprintf(stderr, "PIN code blocked!\n"); return 2; } else { fprintf(stderr, "%d PIN tries left.\n", pinfo->tries_left); } } } pincode = opt_pin; if (pincode == NULL) { pincode = get_pin("Enter old PIN", pin_obj); if (!pinpad_present && pincode == NULL) return 2; } if (pincode && strlen((char *) pincode) == 0) { fprintf(stderr, "No PIN code supplied.\n"); return 2; } if (pincode == NULL && verbose) printf("Old PIN value will be prompted with pinpad.\n"); newpin = opt_newpin; while (newpin == NULL) { u8 *newpin2; newpin = get_pin("Enter new PIN", pin_obj); if (pinpad_present && newpin == NULL) { if (verbose) printf("New PIN value will be prompted with pinpad.\n"); break; } if (newpin == NULL || strlen((char *) newpin) == 0) { fprintf(stderr, "No new PIN value supplied.\n"); return 2; } newpin2 = get_pin("Enter new PIN again", pin_obj); if (newpin2 && strlen((char *) newpin2) && strcmp((char *) newpin, (char *) newpin2) == 0) { free(newpin2); break; } printf("PIN codes do not match, try again.\n"); free(newpin); free(newpin2); newpin=NULL; } r = sc_pkcs15_change_pin(p15card, pin_obj, pincode, pincode ? strlen((char *) pincode) : 0, newpin, newpin ? strlen((char *) newpin) : 0); if (r == SC_ERROR_PIN_CODE_INCORRECT) { fprintf(stderr, "PIN code incorrect; tries left: %d\n", pinfo->tries_left); return 3; } else if (r) { fprintf(stderr, "PIN code change failed: %s\n", sc_strerror(r)); return 2; } if (verbose) printf("PIN code changed successfully.\n"); return 0; } static int read_and_cache_file(const sc_path_t *path) { sc_file_t *tfile; const sc_acl_entry_t *e; u8 *buf; int r; if (verbose) { printf("Reading file "); util_hex_dump(stdout, path->value, path->len, ""); printf("...\n"); } r = sc_select_file(card, path, &tfile); if (r != 0) { fprintf(stderr, "sc_select_file() failed: %s\n", sc_strerror(r)); return -1; } e = sc_file_get_acl_entry(tfile, SC_AC_OP_READ); if (e != NULL && e->method != SC_AC_NONE) { if (verbose) printf("Skipping; ACL for read operation is not NONE.\n"); return -1; } buf = malloc(tfile->size); if (!buf) { printf("out of memory!"); return -1; } r = sc_read_binary(card, 0, buf, tfile->size, 0); if (r < 0) { fprintf(stderr, "sc_read_binary() failed: %s\n", sc_strerror(r)); free(buf); return -1; } r = sc_pkcs15_cache_file(p15card, path, buf, r); if (r) { fprintf(stderr, "Unable to cache file: %s\n", sc_strerror(r)); free(buf); return -1; } sc_file_free(tfile); free(buf); return 0; } static int learn_card(void) { char dir[PATH_MAX]; int r, i, cert_count; struct sc_pkcs15_object *certs[32]; struct sc_pkcs15_df *df; r = sc_get_cache_dir(ctx, dir, sizeof(dir)); if (r) { fprintf(stderr, "Unable to find cache directory: %s\n", sc_strerror(r)); return 1; } printf("Using cache directory '%s'.\n", dir); r = sc_pkcs15_get_objects(p15card, SC_PKCS15_TYPE_CERT_X509, certs, 32); if (r < 0) { fprintf(stderr, "Certificate enumeration failed: %s\n", sc_strerror(r)); return 1; } cert_count = r; r = sc_pkcs15_get_objects(p15card, SC_PKCS15_TYPE_PRKEY, NULL, 0); if (r < 0) { fprintf(stderr, "Private key enumeration failed: %s\n", sc_strerror(r)); return 1; } r = sc_pkcs15_get_objects(p15card, SC_PKCS15_TYPE_AUTH_PIN, NULL, 0); if (r < 0) { fprintf(stderr, "PIN code enumeration failed: %s\n", sc_strerror(r)); return 1; } /* Cache all relevant DF files. The cache * directory is created automatically. */ for (df = p15card->df_list; df != NULL; df = df->next) read_and_cache_file(&df->path); printf("Caching %d certificate(s)...\n", cert_count); for (i = 0; i < cert_count; i++) { sc_path_t tpath; struct sc_pkcs15_cert_info *cinfo = (struct sc_pkcs15_cert_info *) certs[i]->data; printf("[%s]\n", certs[i]->label); memset(&tpath, 0, sizeof(tpath)); tpath = cinfo->path; if (tpath.type == SC_PATH_TYPE_FILE_ID) { /* prepend application DF path in case of a file id */ r = sc_concatenate_path(&tpath, &p15card->file_app->path, &tpath); if (r != SC_SUCCESS) return r; } read_and_cache_file(&tpath); } return 0; } static int test_update(sc_card_t *in_card) { sc_apdu_t apdu; static u8 cmd1[2] = { 0x50, 0x15}; u8 rbuf[258]; int rc; int r; static u8 fci_bad[] = { 0x00, 0xFF, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00 }; static u8 fci_good[] = { 0x00, 0xFF, 0x00, 0x00, 0x00, 0x00, 0xFF, 0x00, 0x00 }; if (strcmp("cardos",in_card->driver->short_name) != 0) { printf("not using the cardos driver, card is fine.\n"); rc = 0; goto end; } /* first select file on 5015 and get fci */ sc_format_apdu(in_card, &apdu, SC_APDU_CASE_4_SHORT, 0xa4, 0x08, 0x00); apdu.lc = sizeof(cmd1); apdu.datalen = sizeof(cmd1); apdu.data = cmd1; apdu.le = 256; apdu.resp = rbuf; apdu.resplen = sizeof(rbuf); r = sc_transmit_apdu(card, &apdu); if (r < 0) { printf("selecting folder failed: %s\n", sc_strerror(r)); rc = 2; goto end; } if (apdu.sw1 != 0x90) { printf("apdu command select file failed: card returned %02X %02X\n", apdu.sw1, apdu.sw2); rc = 2; goto end; } if (apdu.resplen < 6) { printf("select file did not return enough data (length %d)\n", (int) apdu.resplen); goto bad_fci; } if (rbuf[0] != 0x6f) { printf("select file did not return the information we need\n"); goto bad_fci; } if (rbuf[1] != apdu.resplen -2) { printf("select file returned inconsistent information\n"); goto bad_fci; } { size_t i=0; while(i < rbuf[1]) { if (rbuf[2+i] == 0x86) { /* found our buffer */ break; } /* other tag */ i += 2 + rbuf[2+i+1]; /* length of this tag*/ } if (rbuf[2+i+1] < 9 || 2+i+2+9 > apdu.resplen) { printf("select file returned short fci\n"); goto bad_fci; } if (memcmp(&rbuf[2+i+2],fci_good,sizeof(fci_good)) == 0) { printf("fci is up-to-date, card is fine\n"); rc = 0; goto end; } if (memcmp(&rbuf[2+i+2],fci_bad,sizeof(fci_bad)) == 0) { printf("fci is out-of-date, card is vulnerable\n"); rc = 1; goto end; } printf("select file returned fci with unknown data\n"); goto bad_fci; } end: /* 0 = card ok, 1 = card vulnerable, 2 = problem! */ return rc; bad_fci: util_hex_dump(stdout,rbuf,apdu.resplen," "); printf("\n"); return 2; } static int update(sc_card_t *in_card) { sc_apdu_t apdu; u8 rbuf[258]; static u8 cmd1[2] = { 0x50, 0x15}; static u8 cmd3[11] = { 0x86, 0x09, 0x00, 0xff, 0x00, 0x00, 0x00, 0x00, 0xff, 0x00, 0x00}; int r; /* first select file on 5015 */ sc_format_apdu(in_card, &apdu, SC_APDU_CASE_3_SHORT, 0xa4, 0x08, 0x00); apdu.lc = sizeof(cmd1); apdu.datalen = sizeof(cmd1); apdu.data = cmd1; r = sc_transmit_apdu(card, &apdu); if (r < 0) { printf("selecting folder failed: %s\n", sc_strerror(r)); goto end; } if (apdu.sw1 != 0x90) { printf("apdu command select file: card returned %02X %02X\n", apdu.sw1, apdu.sw2); goto end; } /* next get lifecycle */ memset(&apdu, 0, sizeof(apdu)); sc_format_apdu(in_card, &apdu, SC_APDU_CASE_2, 0xca, 0x01, 0x83); apdu.cla = 0x00; apdu.le = 256; apdu.resp = rbuf; apdu.resplen = sizeof(rbuf); r = sc_transmit_apdu(card, &apdu); if (r < 0) { printf("get lifecycle failed: %s\n", sc_strerror(r)); goto end; } if (apdu.sw1 != 0x90) { printf("get lifecycle failed: card returned %02X %02X\n", apdu.sw1, apdu.sw2); goto end; } if (apdu.resplen < 1) { printf("get lifecycle failed: lifecycle byte not in response\n"); goto end; } if (rbuf[0] != 0x10 && rbuf[0] != 0x20) { printf("lifecycle neither user nor admin, can't proceed\n"); goto end; } if (rbuf[0] == 0x20) goto skip_change_lifecycle; /* next phase control / change lifecycle to operational */ memset(&apdu, 0, sizeof(apdu)); sc_format_apdu(in_card, &apdu, SC_APDU_CASE_1, 0x10, 0x00, 0x00); apdu.cla = 0x80; r = sc_transmit_apdu(card, &apdu); if (r < 0) { printf("change lifecycle failed: %s\n", sc_strerror(r)); goto end; } if (apdu.sw1 != 0x90) { printf("apdu command change lifecycle failed: card returned %02X %02X\n", apdu.sw1, apdu.sw2); goto end; } skip_change_lifecycle: /* last update AC */ memset(&apdu, 0, sizeof(apdu)); sc_format_apdu(in_card, &apdu, SC_APDU_CASE_3_SHORT, 0xda, 0x01, 0x6f); apdu.lc = sizeof(cmd3); apdu.datalen = sizeof(cmd3); apdu.data = cmd3; apdu.le = 0; apdu.resplen = 0; apdu.resp = NULL; r = sc_transmit_apdu(card, &apdu); if (r < 0) { printf("update fci failed: %s\n", sc_strerror(r)); goto end; } if (apdu.sw1 != 0x90) { printf("apdu command update fci failed: card returned %02X %02X\n", apdu.sw1, apdu.sw2); goto end; } printf("security update applied successfully.\n"); end: return 0; } int main(int argc, char * const argv[]) { int err = 0, r, c, long_optind = 0; int do_read_cert = 0; int do_list_certs = 0; int do_read_data_object = 0; int do_list_data_objects = 0; int do_list_pins = 0; int do_list_apps = 0; int do_dump = 0; int do_list_prkeys = 0; int do_list_pubkeys = 0; int do_read_pubkey = 0; #if defined(ENABLE_OPENSSL) && (defined(_WIN32) || defined(HAVE_INTTYPES_H)) int do_read_sshkey = 0; #endif int do_verify_pin = 0; int do_change_pin = 0; int do_unblock_pin = 0; int do_learn_card = 0; int do_test_update = 0; int do_update = 0; int action_count = 0; sc_context_param_t ctx_param; while (1) { c = getopt_long(argc, argv, "r:cuko:va:LR:CwDTU", options, &long_optind); if (c == -1) break; if (c == '?') util_print_usage_and_die(app_name, options, option_help); switch (c) { case 'r': opt_cert = optarg; do_read_cert = 1; action_count++; break; case 'c': do_list_certs = 1; action_count++; break; case 'R': opt_data = optarg; do_read_data_object = 1; action_count++; break; case 'C': do_list_data_objects = 1; action_count++; break; case OPT_VERIFY_PIN: do_verify_pin = 1; break; case OPT_CHANGE_PIN: do_change_pin = 1; action_count++; break; case 'u': do_unblock_pin = 1; action_count++; break; case OPT_LIST_PINS: do_list_pins = 1; action_count++; break; case 'D': do_dump = 1; action_count++; break; case 'k': do_list_prkeys = 1; action_count++; break; case OPT_LIST_PUB: do_list_pubkeys = 1; action_count++; break; case OPT_READ_PUB: opt_pubkey = optarg; do_read_pubkey = 1; action_count++; break; #if defined(ENABLE_OPENSSL) && (defined(_WIN32) || defined(HAVE_INTTYPES_H)) case OPT_READ_SSH: opt_pubkey = optarg; do_read_sshkey = 1; action_count++; break; #endif case 'L': do_learn_card = 1; action_count++; break; case 'T': do_test_update = 1; action_count++; break; case 'U': do_update = 1; action_count++; break; case OPT_READER: opt_reader = optarg; break; case OPT_PIN: opt_pin = (u8 *) optarg; break; case OPT_NEWPIN: opt_newpin = (u8 *) optarg; break; case OPT_PUK: opt_puk = (u8 *) optarg; break; case 'o': opt_outfile = optarg; break; case 'v': verbose++; break; case 'a': opt_auth_id = optarg; break; case OPT_BIND_TO_AID: opt_bind_to_aid = optarg; break; case OPT_LIST_APPLICATIONS: do_list_apps = 1; action_count++; break; case OPT_NO_CACHE: opt_no_cache++; break; case 'w': opt_wait = 1; break; } } if (action_count == 0) util_print_usage_and_die(app_name, options, option_help); memset(&ctx_param, 0, sizeof(ctx_param)); ctx_param.ver = 0; ctx_param.app_name = app_name; r = sc_context_create(&ctx, &ctx_param); if (r) { fprintf(stderr, "Failed to establish context: %s\n", sc_strerror(r)); return 1; } if (verbose > 1) { ctx->debug = verbose; sc_ctx_log_to_file(ctx, "stderr"); } err = util_connect_card(ctx, &card, opt_reader, opt_wait, verbose); if (err) goto end; if (verbose) fprintf(stderr, "Trying to find a PKCS#15 compatible card...\n"); if (opt_bind_to_aid) { struct sc_aid aid; aid.len = sizeof(aid.value); if (sc_hex_to_bin(opt_bind_to_aid, aid.value, &aid.len)) { fprintf(stderr, "Invalid AID value: '%s'\n", opt_bind_to_aid); return 1; } r = sc_pkcs15_bind(card, &aid, &p15card); } else { r = sc_pkcs15_bind(card, NULL, &p15card); } if (r) { fprintf(stderr, "PKCS#15 binding failed: %s\n", sc_strerror(r)); err = 1; goto end; } if (opt_no_cache) p15card->opts.use_file_cache = 0; if (verbose) fprintf(stderr, "Found %s!\n", p15card->tokeninfo->label); if (do_verify_pin) if ((err = verify_pin())) goto end; if (do_learn_card) { if ((err = learn_card())) goto end; action_count--; } if (do_list_certs) { if ((err = list_certificates())) goto end; action_count--; } if (do_read_cert) { if ((err = read_certificate())) goto end; action_count--; } if (do_list_data_objects) { if ((err = list_data_objects())) goto end; action_count--; } if (do_read_data_object) { if ((err = read_data_object())) goto end; action_count--; } if (do_list_prkeys) { if ((err = list_private_keys())) goto end; action_count--; } if (do_list_pubkeys) { if ((err = list_public_keys())) goto end; action_count--; } if (do_read_pubkey) { if ((err = read_public_key())) goto end; action_count--; } #if defined(ENABLE_OPENSSL) && (defined(_WIN32) || defined(HAVE_INTTYPES_H)) if (do_read_sshkey) { if ((err = read_ssh_key())) goto end; action_count--; } #endif if (do_list_pins) { if ((err = list_pins())) goto end; action_count--; } if (do_list_apps) { if ((err = list_apps(stdout))) goto end; action_count--; } if (do_dump) { if ((err = dump())) goto end; action_count--; } if (do_change_pin) { if ((err = change_pin())) goto end; action_count--; } if (do_unblock_pin) { if ((err = unblock_pin())) goto end; action_count--; } if (do_test_update || do_update) { err = test_update(card); action_count--; if (err == 2) { /* problem */ err = 1; goto end; } if (do_update && err == 1) { /* card vulnerable */ if ((err = update(card))) goto end; } } end: if (p15card) sc_pkcs15_unbind(p15card); if (card) { sc_unlock(card); sc_disconnect_card(card); } if (ctx) sc_release_context(ctx); return err; } /* * Helper function for PEM encoding public key */ static const struct sc_asn1_entry c_asn1_pem_key_items[] = { { "algorithm", SC_ASN1_ALGORITHM_ID, SC_ASN1_CONS| SC_ASN1_TAG_SEQUENCE, 0, NULL, NULL}, { "key", SC_ASN1_BIT_STRING_NI, SC_ASN1_TAG_BIT_STRING, 0, NULL, NULL }, { NULL, 0, 0, 0, NULL, NULL } }; static const struct sc_asn1_entry c_asn1_pem_key[] = { { "publicKey", SC_ASN1_STRUCT, SC_ASN1_CONS | SC_ASN1_TAG_SEQUENCE, 0, NULL, NULL}, { NULL, 0, 0, 0, NULL, NULL } }; static int pem_encode(int alg_id, sc_pkcs15_der_t *key, sc_pkcs15_der_t *out) { struct sc_asn1_entry asn1_pem_key[2], asn1_pem_key_items[3]; struct sc_algorithm_id algorithm; size_t key_len; memset(&algorithm, 0, sizeof(algorithm)); algorithm.algorithm = alg_id; sc_copy_asn1_entry(c_asn1_pem_key, asn1_pem_key); sc_copy_asn1_entry(c_asn1_pem_key_items, asn1_pem_key_items); sc_format_asn1_entry(asn1_pem_key + 0, asn1_pem_key_items, NULL, 1); sc_format_asn1_entry(asn1_pem_key_items + 0, &algorithm, NULL, 1); key_len = 8 * key->len; sc_format_asn1_entry(asn1_pem_key_items + 1, key->value, &key_len, 1); return sc_asn1_encode(ctx, asn1_pem_key, &out->value, &out->len); }