/* app-openpgp.c - The OpenPGP card application. * Copyright (C) 2003, 2004, 2005, 2007, 2008, * 2009, 2013, 2014 Free Software Foundation, Inc. * * This file is part of GnuPG. * * GnuPG is free software; you can redistribute it and/or modify * it under the terms of the GNU General Public License as published by * the Free Software Foundation; either version 3 of the License, or * (at your option) any later version. * * GnuPG 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 General Public License for more details. * * You should have received a copy of the GNU General Public License * along with this program; if not, see . */ /* Some notes: CHV means Card Holder Verification and is nothing else than a PIN or password. That term seems to have been used originally with GSM cards. Version v2 of the specs changes the term to the clearer term PW for password. We use the terms here interchangeable because we do not want to change existing strings i18n wise. Version 2 of the specs also drops the separate PW2 which was required in v1 due to ISO requirements. It is now possible to have one physical PW but two reference to it so that they can be individually be verified (e.g. to implement a forced verification for one key). Thus you will noticed the use of PW2 with the verify command but not with change_reference_data because the latter operates directly on the physical PW. The Reset Code (RC) as implemented by v2 cards uses the same error counter as the PW2 of v1 cards. By default no RC is set and thus that error counter is set to 0. After setting the RC the error counter will be initialized to 3. */ #include #include #include #include #include #include #include #include #if GNUPG_MAJOR_VERSION == 1 /* This is used with GnuPG version < 1.9. The code has been source copied from the current GnuPG >= 1.9 and is maintained over there. */ #include "options.h" #include "errors.h" #include "memory.h" #include "util.h" #include "cardglue.h" #else /* GNUPG_MAJOR_VERSION != 1 */ #include "scdaemon.h" #endif /* GNUPG_MAJOR_VERSION != 1 */ #include "i18n.h" #include "iso7816.h" #include "app-common.h" #include "tlv.h" /* A table describing the DOs of the card. */ static struct { int tag; int constructed; int get_from; /* Constructed DO with this DO or 0 for direct access. */ int binary:1; int dont_cache:1; int flush_on_error:1; int get_immediate_in_v11:1; /* Enable a hack to bypass the cache of this data object if it is used in 1.1 and later versions of the card. This does not work with composite DO and is currently only useful for the CHV status bytes. */ int try_extlen:1; /* Large object; try to use an extended length APDU. */ char *desc; } data_objects[] = { { 0x005E, 0, 0, 1, 0, 0, 0, 0, "Login Data" }, { 0x5F50, 0, 0, 0, 0, 0, 0, 0, "URL" }, { 0x5F52, 0, 0, 1, 0, 0, 0, 0, "Historical Bytes" }, { 0x0065, 1, 0, 1, 0, 0, 0, 0, "Cardholder Related Data"}, { 0x005B, 0, 0x65, 0, 0, 0, 0, 0, "Name" }, { 0x5F2D, 0, 0x65, 0, 0, 0, 0, 0, "Language preferences" }, { 0x5F35, 0, 0x65, 0, 0, 0, 0, 0, "Sex" }, { 0x006E, 1, 0, 1, 0, 0, 0, 0, "Application Related Data" }, { 0x004F, 0, 0x6E, 1, 0, 0, 0, 0, "AID" }, { 0x0073, 1, 0, 1, 0, 0, 0, 0, "Discretionary Data Objects" }, { 0x0047, 0, 0x6E, 1, 1, 0, 0, 0, "Card Capabilities" }, { 0x00C0, 0, 0x6E, 1, 1, 0, 0, 0, "Extended Card Capabilities" }, { 0x00C1, 0, 0x6E, 1, 1, 0, 0, 0, "Algorithm Attributes Signature" }, { 0x00C2, 0, 0x6E, 1, 1, 0, 0, 0, "Algorithm Attributes Decryption" }, { 0x00C3, 0, 0x6E, 1, 1, 0, 0, 0, "Algorithm Attributes Authentication" }, { 0x00C4, 0, 0x6E, 1, 0, 1, 1, 0, "CHV Status Bytes" }, { 0x00C5, 0, 0x6E, 1, 0, 0, 0, 0, "Fingerprints" }, { 0x00C6, 0, 0x6E, 1, 0, 0, 0, 0, "CA Fingerprints" }, { 0x00CD, 0, 0x6E, 1, 0, 0, 0, 0, "Generation time" }, { 0x007A, 1, 0, 1, 0, 0, 0, 0, "Security Support Template" }, { 0x0093, 0, 0x7A, 1, 1, 0, 0, 0, "Digital Signature Counter" }, { 0x0101, 0, 0, 0, 0, 0, 0, 0, "Private DO 1"}, { 0x0102, 0, 0, 0, 0, 0, 0, 0, "Private DO 2"}, { 0x0103, 0, 0, 0, 0, 0, 0, 0, "Private DO 3"}, { 0x0104, 0, 0, 0, 0, 0, 0, 0, "Private DO 4"}, { 0x7F21, 1, 0, 1, 0, 0, 0, 1, "Cardholder certificate"}, { 0 } }; /* Type of keys. */ typedef enum { KEY_TYPE_ECDH, KEY_TYPE_ECDSA, KEY_TYPE_EDDSA, KEY_TYPE_RSA, } key_type_t; /* The format of RSA private keys. */ typedef enum { RSA_UNKNOWN_FMT, RSA_STD, RSA_STD_N, RSA_CRT, RSA_CRT_N } rsa_key_format_t; /* Elliptic Curves. */ enum { CURVE_NIST_P256, CURVE_NIST_P384, CURVE_NIST_P521, CURVE_SEC_P256K1, CURVE_ED25519, CURVE_UNKNOWN, }; /* One cache item for DOs. */ struct cache_s { struct cache_s *next; int tag; size_t length; unsigned char data[1]; }; /* Object with application (i.e. OpenPGP card) specific data. */ struct app_local_s { /* A linked list with cached DOs. */ struct cache_s *cache; /* Keep track of the public keys. */ struct { int read_done; /* True if we have at least tried to read them. */ unsigned char *key; /* This is a malloced buffer with a canonical encoded S-expression encoding a public key. Might be NULL if key is not available. */ size_t keylen; /* The length of the above S-expression. This is usually only required for cross checks because the length of an S-expression is implicitly available. */ } pk[3]; unsigned char status_indicator; /* The card status indicator. */ unsigned int manufacturer:16; /* Manufacturer ID from the s/n. */ /* Keep track of the ISO card capabilities. */ struct { unsigned int cmd_chaining:1; /* Command chaining is supported. */ unsigned int ext_lc_le:1; /* Extended Lc and Le are supported. */ } cardcap; /* Keep track of extended card capabilities. */ struct { unsigned int is_v2:1; /* This is a v2.0 compatible card. */ unsigned int get_challenge:1; unsigned int key_import:1; unsigned int change_force_chv:1; unsigned int private_dos:1; unsigned int algo_attr_change:1; /* Algorithm attributes changeable. */ unsigned int sm_supported:1; /* Secure Messaging is supported. */ unsigned int sm_aes128:1; /* Use AES-128 for SM. */ unsigned int max_certlen_3:16; unsigned int max_get_challenge:16; /* Maximum size for get_challenge. */ unsigned int max_cmd_data:16; /* Maximum data size for a command. */ unsigned int max_rsp_data:16; /* Maximum size of a response. */ } extcap; /* Flags used to control the application. */ struct { unsigned int no_sync:1; /* Do not sync CHV1 and CHV2 */ unsigned int def_chv2:1; /* Use 123456 for CHV2. */ } flags; /* Pinpad request specified on card. */ struct { unsigned int specified:1; int fixedlen_user; int fixedlen_admin; } pinpad; struct { key_type_t key_type; union { struct { unsigned int n_bits; /* Size of the modulus in bits. The rest of this strucuire is only valid if this is not 0. */ unsigned int e_bits; /* Size of the public exponent in bits. */ rsa_key_format_t format; } rsa; struct { int curve; } ecdsa; struct { int curve; } eddsa; struct { int curve; int hashalgo; int cipheralgo; } ecdh; }; } keyattr[3]; }; /***** Local prototypes *****/ static unsigned long convert_sig_counter_value (const unsigned char *value, size_t valuelen); static unsigned long get_sig_counter (app_t app); static gpg_error_t do_auth (app_t app, const char *keyidstr, gpg_error_t (*pincb)(void*, const char *, char **), void *pincb_arg, const void *indata, size_t indatalen, unsigned char **outdata, size_t *outdatalen); static void parse_algorithm_attribute (app_t app, int keyno); static gpg_error_t change_keyattr_from_string (app_t app, gpg_error_t (*pincb)(void*, const char *, char **), void *pincb_arg, const void *value, size_t valuelen); /* Deconstructor. */ static void do_deinit (app_t app) { if (app && app->app_local) { struct cache_s *c, *c2; int i; for (c = app->app_local->cache; c; c = c2) { c2 = c->next; xfree (c); } for (i=0; i < DIM (app->app_local->pk); i++) { xfree (app->app_local->pk[i].key); app->app_local->pk[i].read_done = 0; } xfree (app->app_local); app->app_local = NULL; } } /* Wrapper around iso7816_get_data which first tries to get the data from the cache. With GET_IMMEDIATE passed as true, the cache is bypassed. With TRY_EXTLEN extended lengths APDUs are use if supported by the card. */ static gpg_error_t get_cached_data (app_t app, int tag, unsigned char **result, size_t *resultlen, int get_immediate, int try_extlen) { gpg_error_t err; int i; unsigned char *p; size_t len; struct cache_s *c; int exmode; *result = NULL; *resultlen = 0; if (!get_immediate) { for (c=app->app_local->cache; c; c = c->next) if (c->tag == tag) { if(c->length) { p = xtrymalloc (c->length); if (!p) return gpg_error (gpg_err_code_from_errno (errno)); memcpy (p, c->data, c->length); *result = p; } *resultlen = c->length; return 0; } } if (try_extlen && app->app_local->cardcap.ext_lc_le) exmode = app->app_local->extcap.max_rsp_data; else exmode = 0; err = iso7816_get_data (app->slot, exmode, tag, &p, &len); if (err) return err; *result = p; *resultlen = len; /* Check whether we should cache this object. */ if (get_immediate) return 0; for (i=0; data_objects[i].tag; i++) if (data_objects[i].tag == tag) { if (data_objects[i].dont_cache) return 0; break; } /* Okay, cache it. */ for (c=app->app_local->cache; c; c = c->next) assert (c->tag != tag); c = xtrymalloc (sizeof *c + len); if (c) { memcpy (c->data, p, len); c->length = len; c->tag = tag; c->next = app->app_local->cache; app->app_local->cache = c; } return 0; } /* Remove DO at TAG from the cache. */ static void flush_cache_item (app_t app, int tag) { struct cache_s *c, *cprev; int i; if (!app->app_local) return; for (c=app->app_local->cache, cprev=NULL; c ; cprev=c, c = c->next) if (c->tag == tag) { if (cprev) cprev->next = c->next; else app->app_local->cache = c->next; xfree (c); for (c=app->app_local->cache; c ; c = c->next) { assert (c->tag != tag); /* Oops: duplicated entry. */ } return; } /* Try again if we have an outer tag. */ for (i=0; data_objects[i].tag; i++) if (data_objects[i].tag == tag && data_objects[i].get_from && data_objects[i].get_from != tag) flush_cache_item (app, data_objects[i].get_from); } /* Flush all entries from the cache which might be out of sync after an error. */ static void flush_cache_after_error (app_t app) { int i; for (i=0; data_objects[i].tag; i++) if (data_objects[i].flush_on_error) flush_cache_item (app, data_objects[i].tag); } /* Flush the entire cache. */ static void flush_cache (app_t app) { if (app && app->app_local) { struct cache_s *c, *c2; for (c = app->app_local->cache; c; c = c2) { c2 = c->next; xfree (c); } app->app_local->cache = NULL; } } /* Get the DO identified by TAG from the card in SLOT and return a buffer with its content in RESULT and NBYTES. The return value is NULL if not found or a pointer which must be used to release the buffer holding value. */ static void * get_one_do (app_t app, int tag, unsigned char **result, size_t *nbytes, int *r_rc) { int rc, i; unsigned char *buffer; size_t buflen; unsigned char *value; size_t valuelen; int dummyrc; int exmode; if (!r_rc) r_rc = &dummyrc; *result = NULL; *nbytes = 0; *r_rc = 0; for (i=0; data_objects[i].tag && data_objects[i].tag != tag; i++) ; if (app->card_version > 0x0100 && data_objects[i].get_immediate_in_v11) { if (data_objects[i].try_extlen && app->app_local->cardcap.ext_lc_le) exmode = app->app_local->extcap.max_rsp_data; else exmode = 0; rc = iso7816_get_data (app->slot, exmode, tag, &buffer, &buflen); if (rc) { *r_rc = rc; return NULL; } *result = buffer; *nbytes = buflen; return buffer; } value = NULL; rc = -1; if (data_objects[i].tag && data_objects[i].get_from) { rc = get_cached_data (app, data_objects[i].get_from, &buffer, &buflen, (data_objects[i].dont_cache || data_objects[i].get_immediate_in_v11), data_objects[i].try_extlen); if (!rc) { const unsigned char *s; s = find_tlv_unchecked (buffer, buflen, tag, &valuelen); if (!s) value = NULL; /* not found */ else if (valuelen > buflen - (s - buffer)) { log_error ("warning: constructed DO too short\n"); value = NULL; xfree (buffer); buffer = NULL; } else value = buffer + (s - buffer); } } if (!value) /* Not in a constructed DO, try simple. */ { rc = get_cached_data (app, tag, &buffer, &buflen, (data_objects[i].dont_cache || data_objects[i].get_immediate_in_v11), data_objects[i].try_extlen); if (!rc) { value = buffer; valuelen = buflen; } } if (!rc) { *nbytes = valuelen; *result = value; return buffer; } *r_rc = rc; return NULL; } static void dump_all_do (int slot) { int rc, i, j; unsigned char *buffer; size_t buflen; for (i=0; data_objects[i].tag; i++) { if (data_objects[i].get_from) continue; /* We don't try extended length APDU because such large DO would be pretty useless in a log file. */ rc = iso7816_get_data (slot, 0, data_objects[i].tag, &buffer, &buflen); if (gpg_err_code (rc) == GPG_ERR_NO_OBJ) ; else if (rc) log_info ("DO '%s' not available: %s\n", data_objects[i].desc, gpg_strerror (rc)); else { if (data_objects[i].binary) { log_info ("DO '%s': ", data_objects[i].desc); log_printhex ("", buffer, buflen); } else log_info ("DO '%s': '%.*s'\n", data_objects[i].desc, (int)buflen, buffer); /* FIXME: sanitize */ if (data_objects[i].constructed) { for (j=0; data_objects[j].tag; j++) { const unsigned char *value; size_t valuelen; if (j==i || data_objects[i].tag != data_objects[j].get_from) continue; value = find_tlv_unchecked (buffer, buflen, data_objects[j].tag, &valuelen); if (!value) ; /* not found */ else if (valuelen > buflen - (value - buffer)) log_error ("warning: constructed DO too short\n"); else { if (data_objects[j].binary) { log_info ("DO '%s': ", data_objects[j].desc); if (valuelen > 200) log_info ("[%u]\n", (unsigned int)valuelen); else log_printhex ("", value, valuelen); } else log_info ("DO '%s': '%.*s'\n", data_objects[j].desc, (int)valuelen, value); /* FIXME: sanitize */ } } } } xfree (buffer); buffer = NULL; } } /* Count the number of bits, assuming the A represents an unsigned big integer of length LEN bytes. */ static unsigned int count_bits (const unsigned char *a, size_t len) { unsigned int n = len * 8; int i; for (; len && !*a; len--, a++, n -=8) ; if (len) { for (i=7; i && !(*a & (1< Where FLAGS is a plain hexadecimal number representing flag values. The lsb is here the rightmost bit. Defined flags bits are: Bit 0 = CHV1 and CHV2 are not syncronized Bit 1 = CHV2 has been been set to the default PIN of "123456" (this implies that bit 0 is also set). P= Where PINPAD_REQUEST is in the format of: or ,. N for user PIN, M for admin PIN. If M is missing it means M=N. 0 means to force not to use pinpad. */ static void parse_login_data (app_t app) { unsigned char *buffer, *p; size_t buflen, len; void *relptr; /* Set defaults. */ app->app_local->flags.no_sync = 0; app->app_local->flags.def_chv2 = 0; app->app_local->pinpad.specified = 0; app->app_local->pinpad.fixedlen_user = -1; app->app_local->pinpad.fixedlen_admin = -1; /* Read the DO. */ relptr = get_one_do (app, 0x005E, &buffer, &buflen, NULL); if (!relptr) return; /* Ooops. */ for (; buflen; buflen--, buffer++) if (*buffer == '\n') break; if (buflen < 2 || buffer[1] != '\x14') { xfree (relptr); return; /* No control sequences. */ } buflen--; buffer++; do { buflen--; buffer++; if (buflen > 1 && *buffer == 'F' && buffer[1] == '=') { /* Flags control sequence found. */ int lastdig = 0; /* For now we are only interested in the last digit, so skip any leading digits but bail out on invalid characters. */ for (p=buffer+2, len = buflen-2; len && hexdigitp (p); p++, len--) lastdig = xtoi_1 (p); buffer = p; buflen = len; if (len && !(*p == '\n' || *p == '\x18')) goto next; /* Invalid characters in field. */ app->app_local->flags.no_sync = !!(lastdig & 1); app->app_local->flags.def_chv2 = (lastdig & 3) == 3; } else if (buflen > 1 && *buffer == 'P' && buffer[1] == '=') { /* Pinpad request control sequence found. */ buffer += 2; buflen -= 2; if (buflen) { if (digitp (buffer)) { char *q; int n, m; n = strtol (buffer, &q, 10); if (q >= (char *)buffer + buflen || *q == '\x18' || *q == '\n') m = n; else { if (*q++ != ',' || !digitp (q)) goto next; m = strtol (q, &q, 10); } if (buflen < ((unsigned char *)q - buffer)) break; buflen -= ((unsigned char *)q - buffer); buffer = q; if (buflen && !(*buffer == '\n' || *buffer == '\x18')) goto next; app->app_local->pinpad.specified = 1; app->app_local->pinpad.fixedlen_user = n; app->app_local->pinpad.fixedlen_admin = m; } } } next: /* Skip to FS (0x18) or LF (\n). */ for (; buflen && *buffer != '\x18' && *buffer != '\n'; buflen--) buffer++; } while (buflen && *buffer != '\n'); xfree (relptr); } static unsigned char get_algo_byte (key_type_t key_type) { if (key_type == KEY_TYPE_ECDSA) return 19; else if (key_type == KEY_TYPE_ECDH) return 18; else if (key_type == KEY_TYPE_EDDSA) return 105; /* (experimental) */ else return 1; /* RSA */ } #define MAX_ARGS_STORE_FPR 3 /* Note, that FPR must be at least 20 bytes. */ static gpg_error_t store_fpr (app_t app, int keynumber, u32 timestamp, unsigned char *fpr, unsigned int card_version, key_type_t key_type, ...) { unsigned int n, nbits; unsigned char *buffer, *p; int tag, tag2; int rc; const unsigned char *m[MAX_ARGS_STORE_FPR]; size_t mlen[MAX_ARGS_STORE_FPR]; va_list ap; int argc; int i; n = 6; /* key packet version, 4-byte timestamps, and algorithm */ if (key_type == KEY_TYPE_RSA || key_type == KEY_TYPE_ECDSA || key_type == KEY_TYPE_EDDSA) argc = 2; else if (key_type == KEY_TYPE_ECDH) argc = 3; else return gpg_error (GPG_ERR_NOT_IMPLEMENTED); va_start (ap, key_type); for (i = 0; i < argc; i++) { m[i] = va_arg (ap, const unsigned char *); mlen[i] = va_arg (ap, size_t); for (; mlen[i] && !*m[i]; mlen[i]--, m[i]++) /* strip leading zeroes */ ; if (key_type == KEY_TYPE_RSA || i == 1) n += 2; n += mlen[i]; } va_end (ap); p = buffer = xtrymalloc (3 + n); if (!buffer) return gpg_error_from_syserror (); *p++ = 0x99; /* ctb */ *p++ = n >> 8; /* 2 byte length header */ *p++ = n; *p++ = 4; /* key packet version */ *p++ = timestamp >> 24; *p++ = timestamp >> 16; *p++ = timestamp >> 8; *p++ = timestamp; *p++ = get_algo_byte (key_type); for (i = 0; i < argc; i++) { if (key_type == KEY_TYPE_RSA || i == 1) { nbits = count_bits (m[i], mlen[i]); *p++ = nbits >> 8; *p++ = nbits; } memcpy (p, m[i], mlen[i]); p += mlen[i]; } gcry_md_hash_buffer (GCRY_MD_SHA1, fpr, buffer, n+3); xfree (buffer); tag = (card_version > 0x0007? 0xC7 : 0xC6) + keynumber; flush_cache_item (app, 0xC5); tag2 = 0xCE + keynumber; flush_cache_item (app, 0xCD); rc = iso7816_put_data (app->slot, 0, tag, fpr, 20); if (rc) log_error (_("failed to store the fingerprint: %s\n"),gpg_strerror (rc)); if (!rc && card_version > 0x0100) { unsigned char buf[4]; buf[0] = timestamp >> 24; buf[1] = timestamp >> 16; buf[2] = timestamp >> 8; buf[3] = timestamp; rc = iso7816_put_data (app->slot, 0, tag2, buf, 4); if (rc) log_error (_("failed to store the creation date: %s\n"), gpg_strerror (rc)); } return rc; } static void send_fpr_if_not_null (ctrl_t ctrl, const char *keyword, int number, const unsigned char *fpr) { int i; char buf[41]; char numbuf[25]; for (i=0; i < 20 && !fpr[i]; i++) ; if (i==20) return; /* All zero. */ bin2hex (fpr, 20, buf); if (number == -1) *numbuf = 0; /* Don't print the key number */ else sprintf (numbuf, "%d", number); send_status_info (ctrl, keyword, numbuf, (size_t)strlen(numbuf), buf, (size_t)strlen (buf), NULL, 0); } static void send_fprtime_if_not_null (ctrl_t ctrl, const char *keyword, int number, const unsigned char *stamp) { char numbuf1[50], numbuf2[50]; unsigned long value; value = (stamp[0] << 24) | (stamp[1]<<16) | (stamp[2]<<8) | stamp[3]; if (!value) return; sprintf (numbuf1, "%d", number); sprintf (numbuf2, "%lu", value); send_status_info (ctrl, keyword, numbuf1, (size_t)strlen(numbuf1), numbuf2, (size_t)strlen(numbuf2), NULL, 0); } static void send_key_data (ctrl_t ctrl, const char *name, const unsigned char *a, size_t alen) { char *buffer, *buf; size_t buflen; buffer = buf = bin2hex (a, alen, NULL); if (!buffer) { log_error ("memory allocation error in send_key_data\n"); return; } buflen = strlen (buffer); /* 768 is the hexified size for the modulus of an 3072 bit key. We use extra chunks to transmit larger data (i.e for 4096 bit). */ for ( ;buflen > 768; buflen -= 768, buf += 768) send_status_info (ctrl, "KEY-DATA", "-", 1, buf, 768, NULL, 0); send_status_info (ctrl, "KEY-DATA", name, (size_t)strlen(name), buf, buflen, NULL, 0); xfree (buffer); } static void get_ecc_key_parameters (int curve, int *r_n_bits, const char **r_curve_oid) { if (curve == CURVE_NIST_P256) { *r_n_bits = 256; *r_curve_oid = "1.2.840.10045.3.1.7"; } else if (curve == CURVE_NIST_P384) { *r_n_bits = 384; *r_curve_oid = "1.3.132.0.34"; } else if (curve == CURVE_NIST_P521) { *r_n_bits = 521; *r_curve_oid = "1.3.132.0.35"; } else if (curve == CURVE_SEC_P256K1) { *r_n_bits = 256; *r_curve_oid = "1.3.132.0.10"; } else if (curve == CURVE_ED25519) { *r_n_bits = 255; *r_curve_oid = "1.3.6.1.4.1.11591.15.1"; } else { *r_n_bits = 0; *r_curve_oid = "1.3.6.1.4.1.11591.2.12242973"; /* gnu.gnupg.badoid */ } } static void send_key_attr (ctrl_t ctrl, app_t app, const char *keyword, int number) { char buffer[200]; int n_bits; const char *curve_oid; assert (number >=0 && number < DIM(app->app_local->keyattr)); if (app->app_local->keyattr[number].key_type == KEY_TYPE_RSA) snprintf (buffer, sizeof buffer, "%d 1 %u %u %d", number+1, app->app_local->keyattr[number].rsa.n_bits, app->app_local->keyattr[number].rsa.e_bits, app->app_local->keyattr[number].rsa.format); else if (app->app_local->keyattr[number].key_type == KEY_TYPE_ECDSA) { get_ecc_key_parameters (app->app_local->keyattr[number].ecdsa.curve, &n_bits, &curve_oid); snprintf (buffer, sizeof buffer, "%d 19 %u %s", number+1, n_bits, curve_oid); } else if (app->app_local->keyattr[number].key_type == KEY_TYPE_ECDH) { get_ecc_key_parameters (app->app_local->keyattr[number].ecdh.curve, &n_bits, &curve_oid); snprintf (buffer, sizeof buffer, "%d 18 %u %s %d %d", number+1, n_bits, curve_oid, app->app_local->keyattr[number].ecdh.hashalgo, app->app_local->keyattr[number].ecdh.cipheralgo); } else if (app->app_local->keyattr[number].key_type == KEY_TYPE_EDDSA) { get_ecc_key_parameters (app->app_local->keyattr[number].eddsa.curve, &n_bits, &curve_oid); snprintf (buffer, sizeof buffer, "%d 105 %u %s", number+1, n_bits, curve_oid); } else snprintf (buffer, sizeof buffer, "0 0 UNKNOWN"); send_status_direct (ctrl, keyword, buffer); } /* Implement the GETATTR command. This is similar to the LEARN command but returns just one value via the status interface. */ static gpg_error_t do_getattr (app_t app, ctrl_t ctrl, const char *name) { static struct { const char *name; int tag; int special; } table[] = { { "DISP-NAME", 0x005B }, { "LOGIN-DATA", 0x005E }, { "DISP-LANG", 0x5F2D }, { "DISP-SEX", 0x5F35 }, { "PUBKEY-URL", 0x5F50 }, { "KEY-FPR", 0x00C5, 3 }, { "KEY-TIME", 0x00CD, 4 }, { "KEY-ATTR", 0x0000, -5 }, { "CA-FPR", 0x00C6, 3 }, { "CHV-STATUS", 0x00C4, 1 }, { "SIG-COUNTER", 0x0093, 2 }, { "SERIALNO", 0x004F, -1 }, { "AID", 0x004F }, { "EXTCAP", 0x0000, -2 }, { "PRIVATE-DO-1", 0x0101 }, { "PRIVATE-DO-2", 0x0102 }, { "PRIVATE-DO-3", 0x0103 }, { "PRIVATE-DO-4", 0x0104 }, { "$AUTHKEYID", 0x0000, -3 }, { "$DISPSERIALNO",0x0000, -4 }, { NULL, 0 } }; int idx, i, rc; void *relptr; unsigned char *value; size_t valuelen; for (idx=0; table[idx].name && strcmp (table[idx].name, name); idx++) ; if (!table[idx].name) return gpg_error (GPG_ERR_INV_NAME); if (table[idx].special == -1) { /* The serial number is very special. We could have used the AID DO to retrieve it, but we have it already in the app context and the stamp argument is required anyway which we can't by other means. The AID DO is available anyway but not hex formatted. */ char *serial; time_t stamp; char tmp[50]; if (!app_get_serial_and_stamp (app, &serial, &stamp)) { sprintf (tmp, "%lu", (unsigned long)stamp); send_status_info (ctrl, "SERIALNO", serial, strlen (serial), tmp, strlen (tmp), NULL, 0); xfree (serial); } return 0; } if (table[idx].special == -2) { char tmp[100]; snprintf (tmp, sizeof tmp, "gc=%d ki=%d fc=%d pd=%d mcl3=%u aac=%d sm=%d", app->app_local->extcap.get_challenge, app->app_local->extcap.key_import, app->app_local->extcap.change_force_chv, app->app_local->extcap.private_dos, app->app_local->extcap.max_certlen_3, app->app_local->extcap.algo_attr_change, (app->app_local->extcap.sm_supported ? (app->app_local->extcap.sm_aes128? 7 : 2) : 0)); send_status_info (ctrl, table[idx].name, tmp, strlen (tmp), NULL, 0); return 0; } if (table[idx].special == -3) { char const tmp[] = "OPENPGP.3"; send_status_info (ctrl, table[idx].name, tmp, strlen (tmp), NULL, 0); return 0; } if (table[idx].special == -4) { char *serial; time_t stamp; if (!app_get_serial_and_stamp (app, &serial, &stamp)) { if (strlen (serial) > 16+12) { send_status_info (ctrl, table[idx].name, serial+16, 12, NULL, 0); xfree (serial); return 0; } xfree (serial); } return gpg_error (GPG_ERR_INV_NAME); } if (table[idx].special == -5) { for (i=0; i < 3; i++) send_key_attr (ctrl, app, table[idx].name, i); return 0; } relptr = get_one_do (app, table[idx].tag, &value, &valuelen, &rc); if (relptr) { if (table[idx].special == 1) { char numbuf[7*23]; for (i=0,*numbuf=0; i < valuelen && i < 7; i++) sprintf (numbuf+strlen (numbuf), " %d", value[i]); send_status_info (ctrl, table[idx].name, numbuf, strlen (numbuf), NULL, 0); } else if (table[idx].special == 2) { char numbuf[50]; sprintf (numbuf, "%lu", convert_sig_counter_value (value, valuelen)); send_status_info (ctrl, table[idx].name, numbuf, strlen (numbuf), NULL, 0); } else if (table[idx].special == 3) { if (valuelen >= 60) for (i=0; i < 3; i++) send_fpr_if_not_null (ctrl, table[idx].name, i+1, value+i*20); } else if (table[idx].special == 4) { if (valuelen >= 12) for (i=0; i < 3; i++) send_fprtime_if_not_null (ctrl, table[idx].name, i+1, value+i*4); } else send_status_info (ctrl, table[idx].name, value, valuelen, NULL, 0); xfree (relptr); } return rc; } /* Retrieve the fingerprint from the card inserted in SLOT and write the according hex representation to FPR. Caller must have provide a buffer at FPR of least 41 bytes. Returns 0 on success or an error code. */ #if GNUPG_MAJOR_VERSION > 1 static gpg_error_t retrieve_fpr_from_card (app_t app, int keyno, char *fpr) { gpg_error_t err = 0; void *relptr; unsigned char *value; size_t valuelen; assert (keyno >=0 && keyno <= 2); relptr = get_one_do (app, 0x00C5, &value, &valuelen, NULL); if (relptr && valuelen >= 60) bin2hex (value+keyno*20, 20, fpr); else err = gpg_error (GPG_ERR_NOT_FOUND); xfree (relptr); return err; } #endif /*GNUPG_MAJOR_VERSION > 1*/ /* Retrieve the public key material for the RSA key, whose fingerprint is FPR, from gpg output, which can be read through the stream FP. The RSA modulus will be stored at the address of M and MLEN, the public exponent at E and ELEN. Returns zero on success, an error code on failure. Caller must release the allocated buffers at M and E if the function returns success. */ #if GNUPG_MAJOR_VERSION > 1 static gpg_error_t retrieve_key_material (FILE *fp, const char *hexkeyid, const unsigned char **m, size_t *mlen, const unsigned char **e, size_t *elen) { gcry_error_t err = 0; char *line = NULL; /* read_line() buffer. */ size_t line_size = 0; /* Helper for for read_line. */ int found_key = 0; /* Helper to find a matching key. */ unsigned char *m_new = NULL; unsigned char *e_new = NULL; size_t m_new_n = 0; size_t e_new_n = 0; /* Loop over all records until we have found the subkey corresponding to the fingerprint. Inm general the first record should be the pub record, but we don't rely on that. Given that we only need to look at one key, it is sufficient to compare the keyid so that we don't need to look at "fpr" records. */ for (;;) { char *p; char *fields[6]; int nfields; size_t max_length; gcry_mpi_t mpi; int i; max_length = 4096; i = read_line (fp, &line, &line_size, &max_length); if (!i) break; /* EOF. */ if (i < 0) { err = gpg_error_from_syserror (); goto leave; /* Error. */ } if (!max_length) { err = gpg_error (GPG_ERR_TRUNCATED); goto leave; /* Line truncated - we better stop processing. */ } /* Parse the line into fields. */ for (nfields=0, p=line; p && nfields < DIM (fields); nfields++) { fields[nfields] = p; p = strchr (p, ':'); if (p) *(p++) = 0; } if (!nfields) continue; /* No fields at all - skip line. */ if (!found_key) { if ( (!strcmp (fields[0], "sub") || !strcmp (fields[0], "pub") ) && nfields > 4 && !strcmp (fields[4], hexkeyid)) found_key = 1; continue; } if ( !strcmp (fields[0], "sub") || !strcmp (fields[0], "pub") ) break; /* Next key - stop. */ if ( strcmp (fields[0], "pkd") ) continue; /* Not a key data record. */ i = 0; /* Avoid erroneous compiler warning. */ if ( nfields < 4 || (i = atoi (fields[1])) < 0 || i > 1 || (!i && m_new) || (i && e_new)) { err = gpg_error (GPG_ERR_GENERAL); goto leave; /* Error: Invalid key data record or not an RSA key. */ } err = gcry_mpi_scan (&mpi, GCRYMPI_FMT_HEX, fields[3], 0, NULL); if (err) mpi = NULL; else if (!i) err = gcry_mpi_aprint (GCRYMPI_FMT_STD, &m_new, &m_new_n, mpi); else err = gcry_mpi_aprint (GCRYMPI_FMT_STD, &e_new, &e_new_n, mpi); gcry_mpi_release (mpi); if (err) goto leave; } if (m_new && e_new) { *m = m_new; *mlen = m_new_n; m_new = NULL; *e = e_new; *elen = e_new_n; e_new = NULL; } else err = gpg_error (GPG_ERR_GENERAL); leave: xfree (m_new); xfree (e_new); xfree (line); return err; } #endif /*GNUPG_MAJOR_VERSION > 1*/ static const char * get_curve_name (int curve) { if (curve == CURVE_NIST_P256) return "NIST P-256"; else if (curve == CURVE_NIST_P384) return "NIST P-384"; else if (curve == CURVE_NIST_P521) return "NIST P-521"; else if (curve == CURVE_SEC_P256K1) return "secp256k1"; else if (curve == CURVE_ED25519) return "Ed25519"; else return "unknown"; } /* Get the public key for KEYNO and store it as an S-expresion with the APP handle. On error that field gets cleared. If we already know about the public key we will just return. Note that this does not mean a key is available; this is soley indicated by the presence of the app->app_local->pk[KEYNO-1].key field. Note that GnuPG 1.x does not need this and it would be too time consuming to send it just for the fun of it. However, given that we use the same code in gpg 1.4, we can't use the gcry S-expresion here but need to open encode it. */ #if GNUPG_MAJOR_VERSION > 1 static gpg_error_t get_public_key (app_t app, int keyno) { gpg_error_t err = 0; unsigned char *buffer; const unsigned char *keydata, *m, *e; size_t buflen, keydatalen; size_t mlen = 0; size_t elen = 0; unsigned char *mbuf = NULL; unsigned char *ebuf = NULL; char *keybuf = NULL; gcry_sexp_t s_pkey; size_t len; if (keyno < 1 || keyno > 3) return gpg_error (GPG_ERR_INV_ID); keyno--; /* Already cached? */ if (app->app_local->pk[keyno].read_done) return 0; xfree (app->app_local->pk[keyno].key); app->app_local->pk[keyno].key = NULL; app->app_local->pk[keyno].keylen = 0; m = e = NULL; /* (avoid cc warning) */ if (app->card_version > 0x0100) { int exmode, le_value; /* We may simply read the public key out of these cards. */ if (app->app_local->cardcap.ext_lc_le) { exmode = 1; /* Use extended length. */ le_value = app->app_local->extcap.max_rsp_data; } else { exmode = 0; le_value = 256; /* Use legacy value. */ } err = iso7816_read_public_key (app->slot, exmode, (const unsigned char*)(keyno == 0? "\xB6" : keyno == 1? "\xB8" : "\xA4"), 2, le_value, &buffer, &buflen); if (err) { log_error (_("reading public key failed: %s\n"), gpg_strerror (err)); goto leave; } keydata = find_tlv (buffer, buflen, 0x7F49, &keydatalen); if (!keydata) { err = gpg_error (GPG_ERR_CARD); log_error (_("response does not contain the public key data\n")); goto leave; } if (app->app_local->keyattr[keyno].key_type == KEY_TYPE_RSA) { m = find_tlv (keydata, keydatalen, 0x0081, &mlen); if (!m) { err = gpg_error (GPG_ERR_CARD); log_error (_("response does not contain the RSA modulus\n")); goto leave; } e = find_tlv (keydata, keydatalen, 0x0082, &elen); if (!e) { err = gpg_error (GPG_ERR_CARD); log_error (_("response does not contain the RSA public exponent\n")); goto leave; } } else { m = find_tlv (keydata, keydatalen, 0x0086, &mlen); if (!m) { err = gpg_error (GPG_ERR_CARD); log_error (_("response does not contain the EC public point\n")); goto leave; } } } else { /* Due to a design problem in v1.0 cards we can't get the public key out of these cards without doing a verify on CHV3. Clearly that is not an option and thus we try to locate the key using an external helper. The helper we use here is gpg itself, which should know about the key in any case. */ char fpr[41]; char *hexkeyid; char *command = NULL; FILE *fp; int ret; buffer = NULL; /* We don't need buffer. */ err = retrieve_fpr_from_card (app, keyno, fpr); if (err) { log_error ("error while retrieving fpr from card: %s\n", gpg_strerror (err)); goto leave; } hexkeyid = fpr + 24; ret = gpgrt_asprintf (&command, "gpg --list-keys --with-colons --with-key-data '%s'", fpr); if (ret < 0) { err = gpg_error_from_syserror (); goto leave; } fp = popen (command, "r"); xfree (command); if (!fp) { err = gpg_error_from_syserror (); log_error ("running gpg failed: %s\n", gpg_strerror (err)); goto leave; } err = retrieve_key_material (fp, hexkeyid, &m, &mlen, &e, &elen); fclose (fp); if (err) { log_error ("error while retrieving key material through pipe: %s\n", gpg_strerror (err)); goto leave; } } mbuf = xtrymalloc ( mlen + 1); if (!mbuf) { err = gpg_error_from_syserror (); goto leave; } /* Prepend numbers with a 0 if needed. */ if (app->app_local->keyattr[keyno].key_type != KEY_TYPE_EDDSA && mlen && (*m & 0x80)) { *mbuf = 0; memcpy (mbuf+1, m, mlen); mlen++; } else memcpy (mbuf, m, mlen); ebuf = xtrymalloc ( elen + 1); if (!ebuf) { err = gpg_error_from_syserror (); goto leave; } /* Prepend numbers with a 0 if needed. */ if (elen && (*e & 0x80)) { *ebuf = 0; memcpy (ebuf+1, e, elen); elen++; } else memcpy (ebuf, e, elen); if (app->app_local->keyattr[keyno].key_type == KEY_TYPE_RSA) { err = gcry_sexp_build (&s_pkey, NULL, "(public-key(rsa(n%b)(e%b)))", mlen, mbuf, elen, ebuf); if (err) goto leave; len = gcry_sexp_sprint (s_pkey, GCRYSEXP_FMT_CANON, NULL, 0); keybuf = xtrymalloc (len); if (!keybuf) { gcry_sexp_release (s_pkey); err = gpg_error_from_syserror (); goto leave; } gcry_sexp_sprint (s_pkey, GCRYSEXP_FMT_CANON, keybuf, len); gcry_sexp_release (s_pkey); } else if (app->app_local->keyattr[keyno].key_type == KEY_TYPE_ECDSA) { const char *curve_name = get_curve_name (app->app_local->keyattr[keyno].ecdsa.curve); err = gcry_sexp_build (&s_pkey, NULL, "(public-key(ecc(curve%s)(q%b)))", curve_name, mlen, mbuf); if (err) goto leave; len = gcry_sexp_sprint (s_pkey, GCRYSEXP_FMT_CANON, NULL, 0); keybuf = xtrymalloc (len); if (!keybuf) { gcry_sexp_release (s_pkey); err = gpg_error_from_syserror (); goto leave; } gcry_sexp_sprint (s_pkey, GCRYSEXP_FMT_CANON, keybuf, len); gcry_sexp_release (s_pkey); } else if (app->app_local->keyattr[keyno].key_type == KEY_TYPE_EDDSA) { const char *curve_name = get_curve_name (app->app_local->keyattr[keyno].eddsa.curve); err = gcry_sexp_build (&s_pkey, NULL, "(public-key(ecc(curve%s)(flags eddsa)(q%b)))", curve_name, mlen, mbuf); if (err) goto leave; len = gcry_sexp_sprint (s_pkey, GCRYSEXP_FMT_CANON, NULL, 0); keybuf = xtrymalloc (len); if (!keybuf) { gcry_sexp_release (s_pkey); err = gpg_error_from_syserror (); goto leave; } gcry_sexp_sprint (s_pkey, GCRYSEXP_FMT_CANON, keybuf, len); gcry_sexp_release (s_pkey); } else { err = gpg_error (GPG_ERR_NOT_IMPLEMENTED); goto leave; } app->app_local->pk[keyno].key = (unsigned char*)keybuf; app->app_local->pk[keyno].keylen = len - 1; /* Decrement for trailing '\0' */ leave: /* Set a flag to indicate that we tried to read the key. */ app->app_local->pk[keyno].read_done = 1; xfree (buffer); xfree (mbuf); xfree (ebuf); return 0; } #endif /* GNUPG_MAJOR_VERSION > 1 */ /* Send the KEYPAIRINFO back. KEYNO needs to be in the range [1,3]. This is used by the LEARN command. */ static gpg_error_t send_keypair_info (app_t app, ctrl_t ctrl, int keyno) { gpg_error_t err = 0; /* Note that GnuPG 1.x does not need this and it would be too time consuming to send it just for the fun of it. */ #if GNUPG_MAJOR_VERSION > 1 unsigned char grip[20]; char gripstr[41]; char idbuf[50]; err = get_public_key (app, keyno); if (err) goto leave; assert (keyno >= 1 && keyno <= 3); if (!app->app_local->pk[keyno-1].key) goto leave; /* No such key - ignore. */ err = keygrip_from_canon_sexp (app->app_local->pk[keyno-1].key, app->app_local->pk[keyno-1].keylen, grip); if (err) goto leave; bin2hex (grip, 20, gripstr); sprintf (idbuf, "OPENPGP.%d", keyno); send_status_info (ctrl, "KEYPAIRINFO", gripstr, 40, idbuf, strlen (idbuf), NULL, (size_t)0); leave: #endif /* GNUPG_MAJOR_VERSION > 1 */ return err; } /* Handle the LEARN command for OpenPGP. */ static gpg_error_t do_learn_status (app_t app, ctrl_t ctrl, unsigned int flags) { (void)flags; do_getattr (app, ctrl, "EXTCAP"); do_getattr (app, ctrl, "DISP-NAME"); do_getattr (app, ctrl, "DISP-LANG"); do_getattr (app, ctrl, "DISP-SEX"); do_getattr (app, ctrl, "PUBKEY-URL"); do_getattr (app, ctrl, "LOGIN-DATA"); do_getattr (app, ctrl, "KEY-FPR"); if (app->card_version > 0x0100) do_getattr (app, ctrl, "KEY-TIME"); do_getattr (app, ctrl, "CA-FPR"); do_getattr (app, ctrl, "CHV-STATUS"); do_getattr (app, ctrl, "SIG-COUNTER"); if (app->app_local->extcap.private_dos) { do_getattr (app, ctrl, "PRIVATE-DO-1"); do_getattr (app, ctrl, "PRIVATE-DO-2"); if (app->did_chv2) do_getattr (app, ctrl, "PRIVATE-DO-3"); if (app->did_chv3) do_getattr (app, ctrl, "PRIVATE-DO-4"); } send_keypair_info (app, ctrl, 1); send_keypair_info (app, ctrl, 2); send_keypair_info (app, ctrl, 3); /* Note: We do not send the Cardholder Certificate, because that is relativly long and for OpenPGP applications not really needed. */ return 0; } /* Handle the READKEY command for OpenPGP. On success a canonical encoded S-expression with the public key will get stored at PK and its length (for assertions) at PKLEN; the caller must release that buffer. On error PK and PKLEN are not changed and an error code is returned. */ static gpg_error_t do_readkey (app_t app, const char *keyid, unsigned char **pk, size_t *pklen) { #if GNUPG_MAJOR_VERSION > 1 gpg_error_t err; int keyno; unsigned char *buf; if (!strcmp (keyid, "OPENPGP.1")) keyno = 1; else if (!strcmp (keyid, "OPENPGP.2")) keyno = 2; else if (!strcmp (keyid, "OPENPGP.3")) keyno = 3; else return gpg_error (GPG_ERR_INV_ID); err = get_public_key (app, keyno); if (err) return err; buf = app->app_local->pk[keyno-1].key; if (!buf) return gpg_error (GPG_ERR_NO_PUBKEY); *pklen = app->app_local->pk[keyno-1].keylen;; *pk = xtrymalloc (*pklen); if (!*pk) { err = gpg_error_from_syserror (); *pklen = 0; return err; } memcpy (*pk, buf, *pklen); return 0; #else return gpg_error (GPG_ERR_NOT_IMPLEMENTED); #endif } /* Read the standard certificate of an OpenPGP v2 card. It is returned in a freshly allocated buffer with that address stored at CERT and the length of the certificate stored at CERTLEN. CERTID needs to be set to "OPENPGP.3". */ static gpg_error_t do_readcert (app_t app, const char *certid, unsigned char **cert, size_t *certlen) { #if GNUPG_MAJOR_VERSION > 1 gpg_error_t err; unsigned char *buffer; size_t buflen; void *relptr; *cert = NULL; *certlen = 0; if (strcmp (certid, "OPENPGP.3")) return gpg_error (GPG_ERR_INV_ID); if (!app->app_local->extcap.is_v2) return gpg_error (GPG_ERR_NOT_FOUND); relptr = get_one_do (app, 0x7F21, &buffer, &buflen, NULL); if (!relptr) return gpg_error (GPG_ERR_NOT_FOUND); if (!buflen) err = gpg_error (GPG_ERR_NOT_FOUND); else if (!(*cert = xtrymalloc (buflen))) err = gpg_error_from_syserror (); else { memcpy (*cert, buffer, buflen); *certlen = buflen; err = 0; } xfree (relptr); return err; #else return gpg_error (GPG_ERR_NOT_IMPLEMENTED); #endif } /* Decide if we use the pinpad of the reader for PIN input according to the user preference on the card, and the capability of the reader. This routine is only called when the reader has pinpad. Returns 0 if we use pinpad, 1 otherwise. */ static int check_pinpad_request (app_t app, pininfo_t *pininfo, int admin_pin) { if (app->app_local->pinpad.specified == 0) /* No preference on card. */ { if (pininfo->fixedlen == 0) /* Reader has varlen capability. */ return 0; /* Then, use pinpad. */ else /* * Reader has limited capability, and it may not match PIN of * the card. */ return 1; } if (admin_pin) pininfo->fixedlen = app->app_local->pinpad.fixedlen_admin; else pininfo->fixedlen = app->app_local->pinpad.fixedlen_user; if (pininfo->fixedlen == 0 /* User requests disable pinpad. */ || pininfo->fixedlen < pininfo->minlen || pininfo->fixedlen > pininfo->maxlen /* Reader doesn't have the capability to input a PIN which * length is FIXEDLEN. */) return 1; return 0; } /* Verify a CHV either using using the pinentry or if possibile by using a pinpad. PINCB and PINCB_ARG describe the usual callback for the pinentry. CHVNO must be either 1 or 2. SIGCOUNT is only used with CHV1. PINVALUE is the address of a pointer which will receive a newly allocated block with the actual PIN (this is useful in case that PIN shall be used for another verify operation). The caller needs to free this value. If the function returns with success and NULL is stored at PINVALUE, the caller should take this as an indication that the pinpad has been used. */ static gpg_error_t verify_a_chv (app_t app, gpg_error_t (*pincb)(void*, const char *, char **), void *pincb_arg, int chvno, unsigned long sigcount, char **pinvalue) { int rc = 0; char *prompt_buffer = NULL; const char *prompt; pininfo_t pininfo; int minlen = 6; assert (chvno == 1 || chvno == 2); *pinvalue = NULL; if (chvno == 2 && app->app_local->flags.def_chv2) { /* Special case for def_chv2 mechanism. */ if (opt.verbose) log_info (_("using default PIN as %s\n"), "CHV2"); rc = iso7816_verify (app->slot, 0x82, "123456", 6); if (rc) { /* Verification of CHV2 with the default PIN failed, although the card pretends to have the default PIN set as CHV2. We better disable the def_chv2 flag now. */ log_info (_("failed to use default PIN as %s: %s" " - disabling further default use\n"), "CHV2", gpg_strerror (rc)); app->app_local->flags.def_chv2 = 0; } return rc; } memset (&pininfo, 0, sizeof pininfo); pininfo.fixedlen = -1; pininfo.minlen = minlen; if (chvno == 1) { #define PROMPTSTRING _("||Please enter the PIN%%0A[sigs done: %lu]") size_t promptsize = strlen (PROMPTSTRING) + 50; prompt_buffer = xtrymalloc (promptsize); if (!prompt_buffer) return gpg_error_from_syserror (); snprintf (prompt_buffer, promptsize-1, PROMPTSTRING, sigcount); prompt = prompt_buffer; #undef PROMPTSTRING } else prompt = _("||Please enter the PIN"); if (!opt.disable_pinpad && !iso7816_check_pinpad (app->slot, ISO7816_VERIFY, &pininfo) && !check_pinpad_request (app, &pininfo, 0)) { /* The reader supports the verify command through the pinpad. Note that the pincb appends a text to the prompt telling the user to use the pinpad. */ rc = pincb (pincb_arg, prompt, NULL); prompt = NULL; xfree (prompt_buffer); prompt_buffer = NULL; if (rc) { log_info (_("PIN callback returned error: %s\n"), gpg_strerror (rc)); return rc; } rc = iso7816_verify_kp (app->slot, 0x80+chvno, &pininfo); /* Dismiss the prompt. */ pincb (pincb_arg, NULL, NULL); assert (!*pinvalue); } else { /* The reader has no pinpad or we don't want to use it. */ rc = pincb (pincb_arg, prompt, pinvalue); prompt = NULL; xfree (prompt_buffer); prompt_buffer = NULL; if (rc) { log_info (_("PIN callback returned error: %s\n"), gpg_strerror (rc)); return rc; } if (strlen (*pinvalue) < minlen) { log_error (_("PIN for CHV%d is too short;" " minimum length is %d\n"), chvno, minlen); xfree (*pinvalue); *pinvalue = NULL; return gpg_error (GPG_ERR_BAD_PIN); } rc = iso7816_verify (app->slot, 0x80+chvno, *pinvalue, strlen (*pinvalue)); } if (rc) { log_error (_("verify CHV%d failed: %s\n"), chvno, gpg_strerror (rc)); xfree (*pinvalue); *pinvalue = NULL; flush_cache_after_error (app); } return rc; } /* Verify CHV2 if required. Depending on the configuration of the card CHV1 will also be verified. */ static gpg_error_t verify_chv2 (app_t app, gpg_error_t (*pincb)(void*, const char *, char **), void *pincb_arg) { int rc; char *pinvalue; if (app->did_chv2) return 0; /* We already verified CHV2. */ rc = verify_a_chv (app, pincb, pincb_arg, 2, 0, &pinvalue); if (rc) return rc; app->did_chv2 = 1; if (!app->did_chv1 && !app->force_chv1 && pinvalue) { /* For convenience we verify CHV1 here too. We do this only if the card is not configured to require a verification before each CHV1 controlled operation (force_chv1) and if we are not using the pinpad (PINVALUE == NULL). */ rc = iso7816_verify (app->slot, 0x81, pinvalue, strlen (pinvalue)); if (gpg_err_code (rc) == GPG_ERR_BAD_PIN) rc = gpg_error (GPG_ERR_PIN_NOT_SYNCED); if (rc) { log_error (_("verify CHV%d failed: %s\n"), 1, gpg_strerror (rc)); flush_cache_after_error (app); } else app->did_chv1 = 1; } xfree (pinvalue); return rc; } /* Build the prompt to enter the Admin PIN. The prompt depends on the current sdtate of the card. */ static gpg_error_t build_enter_admin_pin_prompt (app_t app, char **r_prompt) { void *relptr; unsigned char *value; size_t valuelen; int remaining; char *prompt; *r_prompt = NULL; relptr = get_one_do (app, 0x00C4, &value, &valuelen, NULL); if (!relptr || valuelen < 7) { log_error (_("error retrieving CHV status from card\n")); xfree (relptr); return gpg_error (GPG_ERR_CARD); } if (value[6] == 0) { log_info (_("card is permanently locked!\n")); xfree (relptr); return gpg_error (GPG_ERR_BAD_PIN); } remaining = value[6]; xfree (relptr); log_info(_("%d Admin PIN attempts remaining before card" " is permanently locked\n"), remaining); if (remaining < 3) { /* TRANSLATORS: Do not translate the "|A|" prefix but keep it at the start of the string. Use %%0A to force a linefeed. */ prompt = xtryasprintf (_("|A|Please enter the Admin PIN%%0A" "[remaining attempts: %d]"), remaining); } else prompt = xtrystrdup (_("|A|Please enter the Admin PIN")); if (!prompt) return gpg_error_from_syserror (); *r_prompt = prompt; return 0; } /* Verify CHV3 if required. */ static gpg_error_t verify_chv3 (app_t app, gpg_error_t (*pincb)(void*, const char *, char **), void *pincb_arg) { int rc = 0; #if GNUPG_MAJOR_VERSION != 1 if (!opt.allow_admin) { log_info (_("access to admin commands is not configured\n")); return gpg_error (GPG_ERR_EACCES); } #endif if (!app->did_chv3) { pininfo_t pininfo; int minlen = 8; char *prompt; memset (&pininfo, 0, sizeof pininfo); pininfo.fixedlen = -1; pininfo.minlen = minlen; rc = build_enter_admin_pin_prompt (app, &prompt); if (rc) return rc; if (!opt.disable_pinpad && !iso7816_check_pinpad (app->slot, ISO7816_VERIFY, &pininfo) && !check_pinpad_request (app, &pininfo, 1)) { /* The reader supports the verify command through the pinpad. */ rc = pincb (pincb_arg, prompt, NULL); xfree (prompt); prompt = NULL; if (rc) { log_info (_("PIN callback returned error: %s\n"), gpg_strerror (rc)); return rc; } rc = iso7816_verify_kp (app->slot, 0x83, &pininfo); /* Dismiss the prompt. */ pincb (pincb_arg, NULL, NULL); } else { char *pinvalue; rc = pincb (pincb_arg, prompt, &pinvalue); xfree (prompt); prompt = NULL; if (rc) { log_info (_("PIN callback returned error: %s\n"), gpg_strerror (rc)); return rc; } if (strlen (pinvalue) < minlen) { log_error (_("PIN for CHV%d is too short;" " minimum length is %d\n"), 3, minlen); xfree (pinvalue); return gpg_error (GPG_ERR_BAD_PIN); } rc = iso7816_verify (app->slot, 0x83, pinvalue, strlen (pinvalue)); xfree (pinvalue); } if (rc) { log_error (_("verify CHV%d failed: %s\n"), 3, gpg_strerror (rc)); flush_cache_after_error (app); return rc; } app->did_chv3 = 1; } return rc; } /* Handle the SETATTR operation. All arguments are already basically checked. */ static gpg_error_t do_setattr (app_t app, const char *name, gpg_error_t (*pincb)(void*, const char *, char **), void *pincb_arg, const unsigned char *value, size_t valuelen) { gpg_error_t rc; int idx; static struct { const char *name; int tag; int need_chv; int special; unsigned int need_v2:1; } table[] = { { "DISP-NAME", 0x005B, 3 }, { "LOGIN-DATA", 0x005E, 3, 2 }, { "DISP-LANG", 0x5F2D, 3 }, { "DISP-SEX", 0x5F35, 3 }, { "PUBKEY-URL", 0x5F50, 3 }, { "CHV-STATUS-1", 0x00C4, 3, 1 }, { "CA-FPR-1", 0x00CA, 3 }, { "CA-FPR-2", 0x00CB, 3 }, { "CA-FPR-3", 0x00CC, 3 }, { "PRIVATE-DO-1", 0x0101, 2 }, { "PRIVATE-DO-2", 0x0102, 3 }, { "PRIVATE-DO-3", 0x0103, 2 }, { "PRIVATE-DO-4", 0x0104, 3 }, { "CERT-3", 0x7F21, 3, 0, 1 }, { "SM-KEY-ENC", 0x00D1, 3, 0, 1 }, { "SM-KEY-MAC", 0x00D2, 3, 0, 1 }, { "KEY-ATTR", 0, 0, 3, 1 }, { NULL, 0 } }; int exmode; for (idx=0; table[idx].name && strcmp (table[idx].name, name); idx++) ; if (!table[idx].name) return gpg_error (GPG_ERR_INV_NAME); if (table[idx].need_v2 && !app->app_local->extcap.is_v2) return gpg_error (GPG_ERR_NOT_SUPPORTED); /* Not yet supported. */ if (table[idx].special == 3) return change_keyattr_from_string (app, pincb, pincb_arg, value, valuelen); switch (table[idx].need_chv) { case 2: rc = verify_chv2 (app, pincb, pincb_arg); break; case 3: rc = verify_chv3 (app, pincb, pincb_arg); break; default: rc = 0; } if (rc) return rc; /* Flush the cache before writing it, so that the next get operation will reread the data from the card and thus get synced in case of errors (e.g. data truncated by the card). */ flush_cache_item (app, table[idx].tag); if (app->app_local->cardcap.ext_lc_le && valuelen > 254) exmode = 1; /* Use extended length w/o a limit. */ else if (app->app_local->cardcap.cmd_chaining && valuelen > 254) exmode = -254; /* Command chaining with max. 254 bytes. */ else exmode = 0; rc = iso7816_put_data (app->slot, exmode, table[idx].tag, value, valuelen); if (rc) log_error ("failed to set '%s': %s\n", table[idx].name, gpg_strerror (rc)); if (table[idx].special == 1) app->force_chv1 = (valuelen && *value == 0); else if (table[idx].special == 2) parse_login_data (app); return rc; } /* Handle the WRITECERT command for OpenPGP. This rites the standard certifciate to the card; CERTID needs to be set to "OPENPGP.3". PINCB and PINCB_ARG are the usual arguments for the pinentry callback. */ static gpg_error_t do_writecert (app_t app, ctrl_t ctrl, const char *certidstr, gpg_error_t (*pincb)(void*, const char *, char **), void *pincb_arg, const unsigned char *certdata, size_t certdatalen) { (void)ctrl; #if GNUPG_MAJOR_VERSION > 1 if (strcmp (certidstr, "OPENPGP.3")) return gpg_error (GPG_ERR_INV_ID); if (!certdata || !certdatalen) return gpg_error (GPG_ERR_INV_ARG); if (!app->app_local->extcap.is_v2) return gpg_error (GPG_ERR_NOT_SUPPORTED); if (certdatalen > app->app_local->extcap.max_certlen_3) return gpg_error (GPG_ERR_TOO_LARGE); return do_setattr (app, "CERT-3", pincb, pincb_arg, certdata, certdatalen); #else return gpg_error (GPG_ERR_NOT_IMPLEMENTED); #endif } /* Handle the PASSWD command. The following combinations are possible: Flags CHVNO Vers. Description RESET 1 1 Verify CHV3 and set a new CHV1 and CHV2 RESET 1 2 Verify PW3 and set a new PW1. RESET 2 1 Verify CHV3 and set a new CHV1 and CHV2. RESET 2 2 Verify PW3 and set a new Reset Code. RESET 3 any Returns GPG_ERR_INV_ID. - 1 1 Verify CHV2 and set a new CHV1 and CHV2. - 1 2 Verify PW1 and set a new PW1. - 2 1 Verify CHV2 and set a new CHV1 and CHV2. - 2 2 Verify Reset Code and set a new PW1. - 3 any Verify CHV3/PW3 and set a new CHV3/PW3. */ static gpg_error_t do_change_pin (app_t app, ctrl_t ctrl, const char *chvnostr, unsigned int flags, gpg_error_t (*pincb)(void*, const char *, char **), void *pincb_arg) { int rc = 0; int chvno = atoi (chvnostr); char *resetcode = NULL; char *oldpinvalue = NULL; char *pinvalue = NULL; int reset_mode = !!(flags & APP_CHANGE_FLAG_RESET); int set_resetcode = 0; pininfo_t pininfo; int use_pinpad = 0; int minlen = 6; (void)ctrl; memset (&pininfo, 0, sizeof pininfo); pininfo.fixedlen = -1; pininfo.minlen = minlen; if (reset_mode && chvno == 3) { rc = gpg_error (GPG_ERR_INV_ID); goto leave; } if (!app->app_local->extcap.is_v2) { /* Version 1 cards. */ if (reset_mode || chvno == 3) { /* We always require that the PIN is entered. */ app->did_chv3 = 0; rc = verify_chv3 (app, pincb, pincb_arg); if (rc) goto leave; } else if (chvno == 1 || chvno == 2) { /* On a v1.x card CHV1 and CVH2 should always have the same value, thus we enforce it here. */ int save_force = app->force_chv1; app->force_chv1 = 0; app->did_chv1 = 0; app->did_chv2 = 0; rc = verify_chv2 (app, pincb, pincb_arg); app->force_chv1 = save_force; if (rc) goto leave; } else { rc = gpg_error (GPG_ERR_INV_ID); goto leave; } } else { /* Version 2 cards. */ if (!opt.disable_pinpad && !iso7816_check_pinpad (app->slot, ISO7816_CHANGE_REFERENCE_DATA, &pininfo) && !check_pinpad_request (app, &pininfo, chvno == 3)) use_pinpad = 1; if (reset_mode) { /* To reset a PIN the Admin PIN is required. */ use_pinpad = 0; app->did_chv3 = 0; rc = verify_chv3 (app, pincb, pincb_arg); if (rc) goto leave; if (chvno == 2) set_resetcode = 1; } else if (chvno == 1 || chvno == 3) { if (!use_pinpad) { char *promptbuf = NULL; const char *prompt; if (chvno == 3) { minlen = 8; rc = build_enter_admin_pin_prompt (app, &promptbuf); if (rc) goto leave; prompt = promptbuf; } else prompt = _("||Please enter the PIN"); rc = pincb (pincb_arg, prompt, &oldpinvalue); xfree (promptbuf); promptbuf = NULL; if (rc) { log_info (_("PIN callback returned error: %s\n"), gpg_strerror (rc)); goto leave; } if (strlen (oldpinvalue) < minlen) { log_info (_("PIN for CHV%d is too short;" " minimum length is %d\n"), chvno, minlen); rc = gpg_error (GPG_ERR_BAD_PIN); goto leave; } } } else if (chvno == 2) { /* There is no PW2 for v2 cards. We use this condition to allow a PW reset using the Reset Code. */ void *relptr; unsigned char *value; size_t valuelen; int remaining; use_pinpad = 0; minlen = 8; relptr = get_one_do (app, 0x00C4, &value, &valuelen, NULL); if (!relptr || valuelen < 7) { log_error (_("error retrieving CHV status from card\n")); xfree (relptr); rc = gpg_error (GPG_ERR_CARD); goto leave; } remaining = value[5]; xfree (relptr); if (!remaining) { log_error (_("Reset Code not or not anymore available\n")); rc = gpg_error (GPG_ERR_BAD_PIN); goto leave; } rc = pincb (pincb_arg, _("||Please enter the Reset Code for the card"), &resetcode); if (rc) { log_info (_("PIN callback returned error: %s\n"), gpg_strerror (rc)); goto leave; } if (strlen (resetcode) < minlen) { log_info (_("Reset Code is too short; minimum length is %d\n"), minlen); rc = gpg_error (GPG_ERR_BAD_PIN); goto leave; } } else { rc = gpg_error (GPG_ERR_INV_ID); goto leave; } } if (chvno == 3) app->did_chv3 = 0; else app->did_chv1 = app->did_chv2 = 0; if (!use_pinpad) { /* TRANSLATORS: Do not translate the "|*|" prefixes but keep it at the start of the string. We need this elsewhere to get some infos on the string. */ rc = pincb (pincb_arg, set_resetcode? _("|RN|New Reset Code") : chvno == 3? _("|AN|New Admin PIN") : _("|N|New PIN"), &pinvalue); if (rc) { log_error (_("error getting new PIN: %s\n"), gpg_strerror (rc)); goto leave; } } if (resetcode) { char *buffer; buffer = xtrymalloc (strlen (resetcode) + strlen (pinvalue) + 1); if (!buffer) rc = gpg_error_from_syserror (); else { strcpy (stpcpy (buffer, resetcode), pinvalue); rc = iso7816_reset_retry_counter_with_rc (app->slot, 0x81, buffer, strlen (buffer)); wipememory (buffer, strlen (buffer)); xfree (buffer); } } else if (set_resetcode) { if (strlen (pinvalue) < 8) { log_error (_("Reset Code is too short; minimum length is %d\n"), 8); rc = gpg_error (GPG_ERR_BAD_PIN); } else rc = iso7816_put_data (app->slot, 0, 0xD3, pinvalue, strlen (pinvalue)); } else if (reset_mode) { rc = iso7816_reset_retry_counter (app->slot, 0x81, pinvalue, strlen (pinvalue)); if (!rc && !app->app_local->extcap.is_v2) rc = iso7816_reset_retry_counter (app->slot, 0x82, pinvalue, strlen (pinvalue)); } else if (!app->app_local->extcap.is_v2) { /* Version 1 cards. */ if (chvno == 1 || chvno == 2) { rc = iso7816_change_reference_data (app->slot, 0x81, NULL, 0, pinvalue, strlen (pinvalue)); if (!rc) rc = iso7816_change_reference_data (app->slot, 0x82, NULL, 0, pinvalue, strlen (pinvalue)); } else /* CHVNO == 3 */ { rc = iso7816_change_reference_data (app->slot, 0x80 + chvno, NULL, 0, pinvalue, strlen (pinvalue)); } } else { /* Version 2 cards. */ assert (chvno == 1 || chvno == 3); if (use_pinpad) { rc = pincb (pincb_arg, chvno == 3 ? _("||Please enter the Admin PIN and New Admin PIN") : _("||Please enter the PIN and New PIN"), NULL); if (rc) { log_info (_("PIN callback returned error: %s\n"), gpg_strerror (rc)); goto leave; } rc = iso7816_change_reference_data_kp (app->slot, 0x80 + chvno, 0, &pininfo); pincb (pincb_arg, NULL, NULL); /* Dismiss the prompt. */ } else rc = iso7816_change_reference_data (app->slot, 0x80 + chvno, oldpinvalue, strlen (oldpinvalue), pinvalue, strlen (pinvalue)); } if (pinvalue) { wipememory (pinvalue, strlen (pinvalue)); xfree (pinvalue); } if (rc) flush_cache_after_error (app); leave: if (resetcode) { wipememory (resetcode, strlen (resetcode)); xfree (resetcode); } if (oldpinvalue) { wipememory (oldpinvalue, strlen (oldpinvalue)); xfree (oldpinvalue); } return rc; } /* Check whether a key already exists. KEYIDX is the index of the key (0..2). If FORCE is TRUE a diagnositic will be printed but no error returned if the key already exists. The flag GENERATING is only used to print correct messages. */ static gpg_error_t does_key_exist (app_t app, int keyidx, int generating, int force) { const unsigned char *fpr; unsigned char *buffer; size_t buflen, n; int i; assert (keyidx >=0 && keyidx <= 2); if (iso7816_get_data (app->slot, 0, 0x006E, &buffer, &buflen)) { log_error (_("error reading application data\n")); return gpg_error (GPG_ERR_GENERAL); } fpr = find_tlv (buffer, buflen, 0x00C5, &n); if (!fpr || n < 60) { log_error (_("error reading fingerprint DO\n")); xfree (buffer); return gpg_error (GPG_ERR_GENERAL); } fpr += 20*keyidx; for (i=0; i < 20 && !fpr[i]; i++) ; xfree (buffer); if (i!=20 && !force) { log_error (_("key already exists\n")); return gpg_error (GPG_ERR_EEXIST); } else if (i!=20) log_info (_("existing key will be replaced\n")); else if (generating) log_info (_("generating new key\n")); else log_info (_("writing new key\n")); return 0; } /* Create a TLV tag and value and store it at BUFFER. Return the length of tag and length. A LENGTH greater than 65535 is truncated. */ static size_t add_tlv (unsigned char *buffer, unsigned int tag, size_t length) { unsigned char *p = buffer; assert (tag <= 0xffff); if ( tag > 0xff ) *p++ = tag >> 8; *p++ = tag; if (length < 128) *p++ = length; else if (length < 256) { *p++ = 0x81; *p++ = length; } else { if (length > 0xffff) length = 0xffff; *p++ = 0x82; *p++ = length >> 8; *p++ = length; } return p - buffer; } static gpg_error_t build_privkey_template (app_t app, int keyno, const unsigned char *rsa_n, size_t rsa_n_len, const unsigned char *rsa_e, size_t rsa_e_len, const unsigned char *rsa_p, size_t rsa_p_len, const unsigned char *rsa_q, size_t rsa_q_len, const unsigned char *rsa_u, size_t rsa_u_len, const unsigned char *rsa_dp, size_t rsa_dp_len, const unsigned char *rsa_dq, size_t rsa_dq_len, unsigned char **result, size_t *resultlen) { size_t rsa_e_reqlen; unsigned char privkey[7*(1+3+3)]; size_t privkey_len; unsigned char exthdr[2+2+3]; size_t exthdr_len; unsigned char suffix[2+3]; size_t suffix_len; unsigned char *tp; size_t datalen; unsigned char *template; size_t template_size; *result = NULL; *resultlen = 0; switch (app->app_local->keyattr[keyno].rsa.format) { case RSA_STD: case RSA_STD_N: case RSA_CRT: case RSA_CRT_N: break; default: return gpg_error (GPG_ERR_INV_VALUE); } /* Get the required length for E. Rounded up to the nearest byte */ rsa_e_reqlen = (app->app_local->keyattr[keyno].rsa.e_bits + 7) / 8; assert (rsa_e_len <= rsa_e_reqlen); /* Build the 7f48 cardholder private key template. */ datalen = 0; tp = privkey; tp += add_tlv (tp, 0x91, rsa_e_reqlen); datalen += rsa_e_reqlen; tp += add_tlv (tp, 0x92, rsa_p_len); datalen += rsa_p_len; tp += add_tlv (tp, 0x93, rsa_q_len); datalen += rsa_q_len; if (app->app_local->keyattr[keyno].rsa.format == RSA_CRT || app->app_local->keyattr[keyno].rsa.format == RSA_CRT_N) { tp += add_tlv (tp, 0x94, rsa_u_len); datalen += rsa_u_len; tp += add_tlv (tp, 0x95, rsa_dp_len); datalen += rsa_dp_len; tp += add_tlv (tp, 0x96, rsa_dq_len); datalen += rsa_dq_len; } if (app->app_local->keyattr[keyno].rsa.format == RSA_STD_N || app->app_local->keyattr[keyno].rsa.format == RSA_CRT_N) { tp += add_tlv (tp, 0x97, rsa_n_len); datalen += rsa_n_len; } privkey_len = tp - privkey; /* Build the extended header list without the private key template. */ tp = exthdr; *tp++ = keyno ==0 ? 0xb6 : keyno == 1? 0xb8 : 0xa4; *tp++ = 0; tp += add_tlv (tp, 0x7f48, privkey_len); exthdr_len = tp - exthdr; /* Build the 5f48 suffix of the data. */ tp = suffix; tp += add_tlv (tp, 0x5f48, datalen); suffix_len = tp - suffix; /* Now concatenate everything. */ template_size = (1 + 3 /* 0x4d and len. */ + exthdr_len + privkey_len + suffix_len + datalen); tp = template = xtrymalloc_secure (template_size); if (!template) return gpg_error_from_syserror (); tp += add_tlv (tp, 0x4d, exthdr_len + privkey_len + suffix_len + datalen); memcpy (tp, exthdr, exthdr_len); tp += exthdr_len; memcpy (tp, privkey, privkey_len); tp += privkey_len; memcpy (tp, suffix, suffix_len); tp += suffix_len; memcpy (tp, rsa_e, rsa_e_len); if (rsa_e_len < rsa_e_reqlen) { /* Right justify E. */ memmove (tp + rsa_e_reqlen - rsa_e_len, tp, rsa_e_len); memset (tp, 0, rsa_e_reqlen - rsa_e_len); } tp += rsa_e_reqlen; memcpy (tp, rsa_p, rsa_p_len); tp += rsa_p_len; memcpy (tp, rsa_q, rsa_q_len); tp += rsa_q_len; if (app->app_local->keyattr[keyno].rsa.format == RSA_CRT || app->app_local->keyattr[keyno].rsa.format == RSA_CRT_N) { memcpy (tp, rsa_u, rsa_u_len); tp += rsa_u_len; memcpy (tp, rsa_dp, rsa_dp_len); tp += rsa_dp_len; memcpy (tp, rsa_dq, rsa_dq_len); tp += rsa_dq_len; } if (app->app_local->keyattr[keyno].rsa.format == RSA_STD_N || app->app_local->keyattr[keyno].rsa.format == RSA_CRT_N) { memcpy (tp, rsa_n, rsa_n_len); tp += rsa_n_len; } /* Sanity check. We don't know the exact length because we allocated 3 bytes for the first length header. */ assert (tp - template <= template_size); *result = template; *resultlen = tp - template; return 0; } static gpg_error_t build_ecc_privkey_template (app_t app, int keyno, const unsigned char *ecc_d, size_t ecc_d_len, unsigned char **result, size_t *resultlen) { unsigned char privkey[2]; size_t privkey_len; unsigned char exthdr[2+2+1]; size_t exthdr_len; unsigned char suffix[2+1]; size_t suffix_len; unsigned char *tp; size_t datalen; unsigned char *template; size_t template_size; (void)app; *result = NULL; *resultlen = 0; /* Build the 7f48 cardholder private key template. */ datalen = 0; tp = privkey; tp += add_tlv (tp, 0x91, ecc_d_len); /* Tag 0x91??? */ datalen += ecc_d_len; privkey_len = tp - privkey; /* Build the extended header list without the private key template. */ tp = exthdr; *tp++ = keyno ==0 ? 0xb6 : keyno == 1? 0xb8 : 0xa4; *tp++ = 0; tp += add_tlv (tp, 0x7f48, privkey_len); exthdr_len = tp - exthdr; /* Build the 5f48 suffix of the data. */ tp = suffix; tp += add_tlv (tp, 0x5f48, datalen); suffix_len = tp - suffix; /* Now concatenate everything. */ template_size = (1 + 1 /* 0x4d and len. */ + exthdr_len + privkey_len + suffix_len + datalen); tp = template = xtrymalloc_secure (template_size); if (!template) return gpg_error_from_syserror (); tp += add_tlv (tp, 0x4d, exthdr_len + privkey_len + suffix_len + datalen); memcpy (tp, exthdr, exthdr_len); tp += exthdr_len; memcpy (tp, privkey, privkey_len); tp += privkey_len; memcpy (tp, suffix, suffix_len); tp += suffix_len; memcpy (tp, ecc_d, ecc_d_len); tp += ecc_d_len; assert (tp - template == template_size); *result = template; *resultlen = tp - template; return 0; } /* Helper for do_writekley to change the size of a key. Not ethat this deletes the entire key without asking. */ static gpg_error_t change_keyattr (app_t app, int keyno, unsigned int nbits, gpg_error_t (*pincb)(void*, const char *, char **), void *pincb_arg) { gpg_error_t err; unsigned char *buffer; size_t buflen; void *relptr; assert (keyno >=0 && keyno <= 2); if (nbits > 4096) return gpg_error (GPG_ERR_TOO_LARGE); /* Read the current attributes into a buffer. */ relptr = get_one_do (app, 0xC1+keyno, &buffer, &buflen, NULL); if (!relptr) return gpg_error (GPG_ERR_CARD); if (buflen < 6 || buffer[0] != 1) { /* Attriutes too short or not an RSA key. */ xfree (relptr); return gpg_error (GPG_ERR_CARD); } /* We only change n_bits and don't touch anything else. Before we do so, we round up NBITS to a sensible way in the same way as gpg's key generation does it. This may help to sort out problems with a few bits too short keys. */ nbits = ((nbits + 31) / 32) * 32; buffer[1] = (nbits >> 8); buffer[2] = nbits; /* Prepare for storing the key. */ err = verify_chv3 (app, pincb, pincb_arg); if (err) { xfree (relptr); return err; } /* Change the attribute. */ err = iso7816_put_data (app->slot, 0, 0xC1+keyno, buffer, buflen); xfree (relptr); if (err) log_error ("error changing size of key %d to %u bits\n", keyno+1, nbits); else log_info ("size of key %d changed to %u bits\n", keyno+1, nbits); flush_cache (app); parse_algorithm_attribute (app, keyno); app->did_chv1 = 0; app->did_chv2 = 0; app->did_chv3 = 0; return err; } /* Helper to process an setattr command for name KEY-ATTR. It expects a string "--force " in (VALUE,VALUELEN). */ static gpg_error_t change_keyattr_from_string (app_t app, gpg_error_t (*pincb)(void*, const char *, char **), void *pincb_arg, const void *value, size_t valuelen) { gpg_error_t err; char *string; int keyno, algo; unsigned int nbits; /* VALUE is expected to be a string but not guaranteed to be terminated. Thus copy it to an allocated buffer first. */ string = xtrymalloc (valuelen+1); if (!string) return gpg_error_from_syserror (); memcpy (string, value, valuelen); string[valuelen] = 0; /* Because this function deletes the key we require the string "--force" in the data to make clear that something serious might happen. */ if (sscanf (string, " --force %d %d %u", &keyno, &algo, &nbits) != 3) err = gpg_error (GPG_ERR_INV_DATA); else if (keyno < 1 || keyno > 3) err = gpg_error (GPG_ERR_INV_ID); else if (algo != 1) err = gpg_error (GPG_ERR_PUBKEY_ALGO); /* Not RSA. */ else if (nbits < 1024) err = gpg_error (GPG_ERR_TOO_SHORT); else err = change_keyattr (app, keyno-1, nbits, pincb, pincb_arg); xfree (string); return err; } static gpg_error_t rsa_writekey (app_t app, gpg_error_t (*pincb)(void*, const char *, char **), void *pincb_arg, int keyno, const unsigned char *buf, size_t buflen, int depth) { gpg_error_t err; const unsigned char *tok; size_t toklen; int last_depth1, last_depth2; const unsigned char *rsa_n = NULL; const unsigned char *rsa_e = NULL; const unsigned char *rsa_p = NULL; const unsigned char *rsa_q = NULL; size_t rsa_n_len, rsa_e_len, rsa_p_len, rsa_q_len; unsigned int nbits; unsigned int maxbits; unsigned char *template = NULL; unsigned char *tp; size_t template_len; unsigned char fprbuf[20]; u32 created_at = 0; last_depth1 = depth; while (!(err = parse_sexp (&buf, &buflen, &depth, &tok, &toklen)) && depth && depth >= last_depth1) { if (tok) { err = gpg_error (GPG_ERR_UNKNOWN_SEXP); goto leave; } if ((err = parse_sexp (&buf, &buflen, &depth, &tok, &toklen))) goto leave; if (tok && toklen == 1) { const unsigned char **mpi; size_t *mpi_len; switch (*tok) { case 'n': mpi = &rsa_n; mpi_len = &rsa_n_len; break; case 'e': mpi = &rsa_e; mpi_len = &rsa_e_len; break; case 'p': mpi = &rsa_p; mpi_len = &rsa_p_len; break; case 'q': mpi = &rsa_q; mpi_len = &rsa_q_len;break; default: mpi = NULL; mpi_len = NULL; break; } if (mpi && *mpi) { err = gpg_error (GPG_ERR_DUP_VALUE); goto leave; } if ((err = parse_sexp (&buf, &buflen, &depth, &tok, &toklen))) goto leave; if (tok && mpi) { /* Strip off leading zero bytes and save. */ for (;toklen && !*tok; toklen--, tok++) ; *mpi = tok; *mpi_len = toklen; } } /* Skip until end of list. */ last_depth2 = depth; while (!(err = parse_sexp (&buf, &buflen, &depth, &tok, &toklen)) && depth && depth >= last_depth2) ; if (err) goto leave; } /* Parse other attributes. */ last_depth1 = depth; while (!(err = parse_sexp (&buf, &buflen, &depth, &tok, &toklen)) && depth && depth >= last_depth1) { if (tok) { err = gpg_error (GPG_ERR_UNKNOWN_SEXP); goto leave; } if ((err = parse_sexp (&buf, &buflen, &depth, &tok, &toklen))) goto leave; if (tok && toklen == 10 && !memcmp ("created-at", tok, toklen)) { if ((err = parse_sexp (&buf,&buflen,&depth,&tok,&toklen))) goto leave; if (tok) { for (created_at=0; toklen && *tok && *tok >= '0' && *tok <= '9'; tok++, toklen--) created_at = created_at*10 + (*tok - '0'); } } /* Skip until end of list. */ last_depth2 = depth; while (!(err = parse_sexp (&buf, &buflen, &depth, &tok, &toklen)) && depth && depth >= last_depth2) ; if (err) goto leave; } /* Check that we have all parameters and that they match the card description. */ if (!created_at) { log_error (_("creation timestamp missing\n")); err = gpg_error (GPG_ERR_INV_VALUE); goto leave; } maxbits = app->app_local->keyattr[keyno].rsa.n_bits; nbits = rsa_n? count_bits (rsa_n, rsa_n_len) : 0; if (opt.verbose) log_info ("RSA modulus size is %u bits (%u bytes)\n", nbits, (unsigned int)rsa_n_len); if (nbits && nbits != maxbits && app->app_local->extcap.algo_attr_change) { /* Try to switch the key to a new length. */ err = change_keyattr (app, keyno, nbits, pincb, pincb_arg); if (!err) maxbits = app->app_local->keyattr[keyno].rsa.n_bits; } if (nbits != maxbits) { log_error (_("RSA modulus missing or not of size %d bits\n"), (int)maxbits); err = gpg_error (GPG_ERR_BAD_SECKEY); goto leave; } maxbits = app->app_local->keyattr[keyno].rsa.e_bits; if (maxbits > 32 && !app->app_local->extcap.is_v2) maxbits = 32; /* Our code for v1 does only support 32 bits. */ nbits = rsa_e? count_bits (rsa_e, rsa_e_len) : 0; if (nbits < 2 || nbits > maxbits) { log_error (_("RSA public exponent missing or larger than %d bits\n"), (int)maxbits); err = gpg_error (GPG_ERR_BAD_SECKEY); goto leave; } maxbits = app->app_local->keyattr[keyno].rsa.n_bits/2; nbits = rsa_p? count_bits (rsa_p, rsa_p_len) : 0; if (nbits != maxbits) { log_error (_("RSA prime %s missing or not of size %d bits\n"), "P", (int)maxbits); err = gpg_error (GPG_ERR_BAD_SECKEY); goto leave; } nbits = rsa_q? count_bits (rsa_q, rsa_q_len) : 0; if (nbits != maxbits) { log_error (_("RSA prime %s missing or not of size %d bits\n"), "Q", (int)maxbits); err = gpg_error (GPG_ERR_BAD_SECKEY); goto leave; } /* We need to remove the cached public key. */ xfree (app->app_local->pk[keyno].key); app->app_local->pk[keyno].key = NULL; app->app_local->pk[keyno].keylen = 0; app->app_local->pk[keyno].read_done = 0; if (app->app_local->extcap.is_v2) { unsigned char *rsa_u, *rsa_dp, *rsa_dq; size_t rsa_u_len, rsa_dp_len, rsa_dq_len; gcry_mpi_t mpi_e, mpi_p, mpi_q; gcry_mpi_t mpi_u = gcry_mpi_snew (0); gcry_mpi_t mpi_dp = gcry_mpi_snew (0); gcry_mpi_t mpi_dq = gcry_mpi_snew (0); gcry_mpi_t mpi_tmp = gcry_mpi_snew (0); int exmode; /* Calculate the u, dp and dq components needed by RSA_CRT cards */ gcry_mpi_scan (&mpi_e, GCRYMPI_FMT_USG, rsa_e, rsa_e_len, NULL); gcry_mpi_scan (&mpi_p, GCRYMPI_FMT_USG, rsa_p, rsa_p_len, NULL); gcry_mpi_scan (&mpi_q, GCRYMPI_FMT_USG, rsa_q, rsa_q_len, NULL); gcry_mpi_invm (mpi_u, mpi_q, mpi_p); gcry_mpi_sub_ui (mpi_tmp, mpi_p, 1); gcry_mpi_invm (mpi_dp, mpi_e, mpi_tmp); gcry_mpi_sub_ui (mpi_tmp, mpi_q, 1); gcry_mpi_invm (mpi_dq, mpi_e, mpi_tmp); gcry_mpi_aprint (GCRYMPI_FMT_USG, &rsa_u, &rsa_u_len, mpi_u); gcry_mpi_aprint (GCRYMPI_FMT_USG, &rsa_dp, &rsa_dp_len, mpi_dp); gcry_mpi_aprint (GCRYMPI_FMT_USG, &rsa_dq, &rsa_dq_len, mpi_dq); gcry_mpi_release (mpi_e); gcry_mpi_release (mpi_p); gcry_mpi_release (mpi_q); gcry_mpi_release (mpi_u); gcry_mpi_release (mpi_dp); gcry_mpi_release (mpi_dq); gcry_mpi_release (mpi_tmp); /* Build the private key template as described in section 4.3.3.7 of the OpenPGP card specs version 2.0. */ err = build_privkey_template (app, keyno, rsa_n, rsa_n_len, rsa_e, rsa_e_len, rsa_p, rsa_p_len, rsa_q, rsa_q_len, rsa_u, rsa_u_len, rsa_dp, rsa_dp_len, rsa_dq, rsa_dq_len, &template, &template_len); xfree(rsa_u); xfree(rsa_dp); xfree(rsa_dq); if (err) goto leave; /* Prepare for storing the key. */ err = verify_chv3 (app, pincb, pincb_arg); if (err) goto leave; /* Store the key. */ if (app->app_local->cardcap.ext_lc_le && template_len > 254) exmode = 1; /* Use extended length w/o a limit. */ else if (app->app_local->cardcap.cmd_chaining && template_len > 254) exmode = -254; else exmode = 0; err = iso7816_put_data_odd (app->slot, exmode, 0x3fff, template, template_len); } else { /* Build the private key template as described in section 4.3.3.6 of the OpenPGP card specs version 1.1: 0xC0 public exponent 0xC1 prime p 0xC2 prime q */ assert (rsa_e_len <= 4); template_len = (1 + 1 + 4 + 1 + 1 + rsa_p_len + 1 + 1 + rsa_q_len); template = tp = xtrymalloc_secure (template_len); if (!template) { err = gpg_error_from_syserror (); goto leave; } *tp++ = 0xC0; *tp++ = 4; memcpy (tp, rsa_e, rsa_e_len); if (rsa_e_len < 4) { /* Right justify E. */ memmove (tp+4-rsa_e_len, tp, rsa_e_len); memset (tp, 0, 4-rsa_e_len); } tp += 4; *tp++ = 0xC1; *tp++ = rsa_p_len; memcpy (tp, rsa_p, rsa_p_len); tp += rsa_p_len; *tp++ = 0xC2; *tp++ = rsa_q_len; memcpy (tp, rsa_q, rsa_q_len); tp += rsa_q_len; assert (tp - template == template_len); /* Prepare for storing the key. */ err = verify_chv3 (app, pincb, pincb_arg); if (err) goto leave; /* Store the key. */ err = iso7816_put_data (app->slot, 0, (app->card_version > 0x0007? 0xE0:0xE9)+keyno, template, template_len); } if (err) { log_error (_("failed to store the key: %s\n"), gpg_strerror (err)); goto leave; } err = store_fpr (app, keyno, created_at, fprbuf, app->card_version, KEY_TYPE_RSA, rsa_n, rsa_n_len, rsa_e, rsa_e_len); if (err) goto leave; leave: xfree (template); return err; } static gpg_error_t ecdh_writekey (app_t app, gpg_error_t (*pincb)(void*, const char *, char **), void *pincb_arg, int keyno, const unsigned char *buf, size_t buflen, int depth) { (void)app; (void)pincb; (void)pincb_arg; (void)keyno; (void)buf; (void)buflen; (void)depth; return GPG_ERR_NOT_IMPLEMENTED; } static gpg_error_t ecc_writekey (app_t app, gpg_error_t (*pincb)(void*, const char *, char **), void *pincb_arg, int keyno, const unsigned char *buf, size_t buflen, int depth) { gpg_error_t err; const unsigned char *tok; size_t toklen; int last_depth1, last_depth2; const unsigned char *ecc_q = NULL; const unsigned char *ecc_d = NULL; size_t ecc_q_len, ecc_d_len; unsigned char *template = NULL; size_t template_len; unsigned char fprbuf[20]; u32 created_at = 0; int curve = CURVE_UNKNOWN; /* (private-key(ecdsa(curve%s)(q%m)(d%m))(created-at%d)): curve = "1.2.840.10045.3.1.7" */ /* (private-key(ecc(curve%s)(q%m)(d%m))(created-at%d)): curve = "secp256k1" */ /* (private-key(ecc(curve%s)(flags eddsa)(q%m)(d%m))(created-at%d)): curve = "Ed25519" */ last_depth1 = depth; while (!(err = parse_sexp (&buf, &buflen, &depth, &tok, &toklen)) && depth && depth >= last_depth1) { if (tok) { err = gpg_error (GPG_ERR_UNKNOWN_SEXP); goto leave; } if ((err = parse_sexp (&buf, &buflen, &depth, &tok, &toklen))) goto leave; if (tok && toklen == 5 && !memcmp (tok, "curve", 5)) { if ((err = parse_sexp (&buf, &buflen, &depth, &tok, &toklen))) goto leave; if (tok && toklen == 19 && !memcmp (tok, "1.2.840.10045.3.1.7", 19)) curve = CURVE_NIST_P256; else if (tok && toklen == 9 && !memcmp (tok, "secp256k1", 9)) curve = CURVE_SEC_P256K1; else if (tok && toklen == 7 && !memcmp (tok, "Ed25519", 7)) curve = CURVE_ED25519; } else if (tok && toklen == 1) { const unsigned char **buf2; size_t *buf2len; switch (*tok) { case 'q': buf2 = &ecc_q; buf2len = &ecc_q_len; break; case 'd': buf2 = &ecc_d; buf2len = &ecc_d_len; break; default: buf2 = NULL; buf2len = NULL; break; } if (buf2 && *buf2) { err = gpg_error (GPG_ERR_DUP_VALUE); goto leave; } if ((err = parse_sexp (&buf, &buflen, &depth, &tok, &toklen))) goto leave; if (tok && buf2 && curve != CURVE_ED25519) /* It's MPI. Strip off leading zero bytes and save. */ for (;toklen && !*tok; toklen--, tok++) ; *buf2 = tok; *buf2len = toklen; } /* Skip until end of list. */ last_depth2 = depth; while (!(err = parse_sexp (&buf, &buflen, &depth, &tok, &toklen)) && depth && depth >= last_depth2) ; if (err) goto leave; } /* Parse other attributes. */ last_depth1 = depth; while (!(err = parse_sexp (&buf, &buflen, &depth, &tok, &toklen)) && depth && depth >= last_depth1) { if (tok) { err = gpg_error (GPG_ERR_UNKNOWN_SEXP); goto leave; } if ((err = parse_sexp (&buf, &buflen, &depth, &tok, &toklen))) goto leave; if (tok && toklen == 10 && !memcmp ("created-at", tok, toklen)) { if ((err = parse_sexp (&buf,&buflen,&depth,&tok,&toklen))) goto leave; if (tok) { for (created_at=0; toklen && *tok && *tok >= '0' && *tok <= '9'; tok++, toklen--) created_at = created_at*10 + (*tok - '0'); } } /* Skip until end of list. */ last_depth2 = depth; while (!(err = parse_sexp (&buf, &buflen, &depth, &tok, &toklen)) && depth && depth >= last_depth2) ; if (err) goto leave; } /* Check that we have all parameters and that they match the card description. */ if (!created_at) { log_error (_("creation timestamp missing\n")); err = gpg_error (GPG_ERR_INV_VALUE); goto leave; } if (opt.verbose) log_info ("ECC private key size is %u bytes\n", (unsigned int)ecc_d_len); /* We need to remove the cached public key. */ xfree (app->app_local->pk[keyno].key); app->app_local->pk[keyno].key = NULL; app->app_local->pk[keyno].keylen = 0; app->app_local->pk[keyno].read_done = 0; if (app->app_local->extcap.is_v2) { /* Build the private key template as described in section 4.3.3.7 of the OpenPGP card specs version 2.0. */ int exmode; err = build_ecc_privkey_template (app, keyno, ecc_d, ecc_d_len, &template, &template_len); if (err) goto leave; /* Prepare for storing the key. */ err = verify_chv3 (app, pincb, pincb_arg); if (err) goto leave; /* Store the key. */ if (app->app_local->cardcap.ext_lc_le && template_len > 254) exmode = 1; /* Use extended length w/o a limit. */ else if (app->app_local->cardcap.cmd_chaining && template_len > 254) exmode = -254; else exmode = 0; err = iso7816_put_data_odd (app->slot, exmode, 0x3fff, template, template_len); } else return gpg_error (GPG_ERR_NOT_SUPPORTED); if (err) { log_error (_("failed to store the key: %s\n"), gpg_strerror (err)); goto leave; } err = store_fpr (app, keyno, created_at, fprbuf, app->card_version, curve == CURVE_ED25519 ? KEY_TYPE_EDDSA : KEY_TYPE_ECDSA, curve == CURVE_ED25519 ? "\x09\x2b\x06\x01\x04\x01\xda\x47\x0f\x01" : curve == CURVE_NIST_P256 ? "\x08\x2a\x86\x48\xce\x3d\x03\x01\x07" : "\05\x2b\x81\x04\x00\x0a", curve == CURVE_ED25519 ? 10 : curve == CURVE_NIST_P256? 9 : 6, ecc_q, ecc_q_len); if (err) goto leave; leave: xfree (template); return err; } /* Handle the WRITEKEY command for OpenPGP. This function expects a canonical encoded S-expression with the secret key in KEYDATA and its length (for assertions) in KEYDATALEN. KEYID needs to be the usual keyid which for OpenPGP is the string "OPENPGP.n" with n=1,2,3. Bit 0 of FLAGS indicates whether an existing key shall get overwritten. PINCB and PINCB_ARG are the usual arguments for the pinentry callback. */ static gpg_error_t do_writekey (app_t app, ctrl_t ctrl, const char *keyid, unsigned int flags, gpg_error_t (*pincb)(void*, const char *, char **), void *pincb_arg, const unsigned char *keydata, size_t keydatalen) { gpg_error_t err; int force = (flags & 1); int keyno; const unsigned char *buf, *tok; size_t buflen, toklen; int depth; (void)ctrl; if (!strcmp (keyid, "OPENPGP.1")) keyno = 0; else if (!strcmp (keyid, "OPENPGP.2")) keyno = 1; else if (!strcmp (keyid, "OPENPGP.3")) keyno = 2; else return gpg_error (GPG_ERR_INV_ID); err = does_key_exist (app, keyno, 0, force); if (err) return err; /* Parse the S-expression */ buf = keydata; buflen = keydatalen; depth = 0; if ((err = parse_sexp (&buf, &buflen, &depth, &tok, &toklen))) goto leave; if ((err = parse_sexp (&buf, &buflen, &depth, &tok, &toklen))) goto leave; if (!tok || toklen != 11 || memcmp ("private-key", tok, toklen)) { if (!tok) ; else if (toklen == 21 && !memcmp ("protected-private-key", tok, toklen)) log_info ("protected-private-key passed to writekey\n"); else if (toklen == 20 && !memcmp ("shadowed-private-key", tok, toklen)) log_info ("shadowed-private-key passed to writekey\n"); err = gpg_error (GPG_ERR_BAD_SECKEY); goto leave; } if ((err = parse_sexp (&buf, &buflen, &depth, &tok, &toklen))) goto leave; if ((err = parse_sexp (&buf, &buflen, &depth, &tok, &toklen))) goto leave; if (tok && toklen == 3 && memcmp ("rsa", tok, toklen) == 0) rsa_writekey (app, pincb, pincb_arg, keyno, buf, buflen, depth); else if ((tok && toklen == 3 && memcmp ("ecc", tok, toklen) == 0 && (keyno == 0 || keyno == 2)) || (tok && toklen == 5 && memcmp ("ecdsa", tok, toklen) == 0)) ecc_writekey (app, pincb, pincb_arg, keyno, buf, buflen, depth); else if ((tok && toklen == 3 && memcmp ("ecc", tok, toklen) == 0 && keyno == 1) || (tok && toklen == 4 && memcmp ("ecdh", tok, toklen) == 0)) ecdh_writekey (app, pincb, pincb_arg, keyno, buf, buflen, depth); else { err = gpg_error (GPG_ERR_WRONG_PUBKEY_ALGO); goto leave; } leave: return err; } /* Handle the GENKEY command. */ static gpg_error_t do_genkey (app_t app, ctrl_t ctrl, const char *keynostr, unsigned int flags, time_t createtime, gpg_error_t (*pincb)(void*, const char *, char **), void *pincb_arg) { int rc; char numbuf[30]; unsigned char fprbuf[20]; const unsigned char *keydata, *m, *e; unsigned char *buffer = NULL; size_t buflen, keydatalen, mlen, elen; time_t created_at; int keyno = atoi (keynostr); int force = (flags & 1); time_t start_at; int exmode; int le_value; unsigned int keybits; if (keyno < 1 || keyno > 3) return gpg_error (GPG_ERR_INV_ID); keyno--; /* We flush the cache to increase the traffic before a key generation. This _might_ help a card to gather more entropy. */ flush_cache (app); /* Obviously we need to remove the cached public key. */ xfree (app->app_local->pk[keyno].key); app->app_local->pk[keyno].key = NULL; app->app_local->pk[keyno].keylen = 0; app->app_local->pk[keyno].read_done = 0; /* Check whether a key already exists. */ rc = does_key_exist (app, keyno, 1, force); if (rc) return rc; /* Because we send the key parameter back via status lines we need to put a limit on the max. allowed keysize. 2048 bit will already lead to a 527 byte long status line and thus a 4096 bit key would exceed the Assuan line length limit. */ keybits = app->app_local->keyattr[keyno].rsa.n_bits; if (keybits > 4096) return gpg_error (GPG_ERR_TOO_LARGE); /* Prepare for key generation by verifying the Admin PIN. */ rc = verify_chv3 (app, pincb, pincb_arg); if (rc) goto leave; /* Test whether we will need extended length mode. (1900 is an arbitrary length which for sure fits into a short apdu.) */ if (app->app_local->cardcap.ext_lc_le && keybits > 1900) { exmode = 1; /* Use extended length w/o a limit. */ le_value = app->app_local->extcap.max_rsp_data; /* No need to check le_value because it comes from a 16 bit value and thus can't create an overflow on a 32 bit system. */ } else { exmode = 0; le_value = 256; /* Use legacy value. */ } log_info (_("please wait while key is being generated ...\n")); start_at = time (NULL); rc = iso7816_generate_keypair /* # warning key generation temporary replaced by reading an existing key. */ /* rc = iso7816_read_public_key */ (app->slot, exmode, (const unsigned char*)(keyno == 0? "\xB6" : keyno == 1? "\xB8" : "\xA4"), 2, le_value, &buffer, &buflen); if (rc) { rc = gpg_error (GPG_ERR_CARD); log_error (_("generating key failed\n")); goto leave; } log_info (_("key generation completed (%d seconds)\n"), (int)(time (NULL) - start_at)); keydata = find_tlv (buffer, buflen, 0x7F49, &keydatalen); if (!keydata) { rc = gpg_error (GPG_ERR_CARD); log_error (_("response does not contain the public key data\n")); goto leave; } m = find_tlv (keydata, keydatalen, 0x0081, &mlen); if (!m) { rc = gpg_error (GPG_ERR_CARD); log_error (_("response does not contain the RSA modulus\n")); goto leave; } /* log_printhex ("RSA n:", m, mlen); */ send_key_data (ctrl, "n", m, mlen); e = find_tlv (keydata, keydatalen, 0x0082, &elen); if (!e) { rc = gpg_error (GPG_ERR_CARD); log_error (_("response does not contain the RSA public exponent\n")); goto leave; } /* log_printhex ("RSA e:", e, elen); */ send_key_data (ctrl, "e", e, elen); created_at = createtime? createtime : gnupg_get_time (); sprintf (numbuf, "%lu", (unsigned long)created_at); send_status_info (ctrl, "KEY-CREATED-AT", numbuf, (size_t)strlen(numbuf), NULL, 0); rc = store_fpr (app, keyno, (u32)created_at, fprbuf, app->card_version, KEY_TYPE_RSA, m, mlen, e, elen); if (rc) goto leave; send_fpr_if_not_null (ctrl, "KEY-FPR", -1, fprbuf); leave: xfree (buffer); return rc; } static unsigned long convert_sig_counter_value (const unsigned char *value, size_t valuelen) { unsigned long ul; if (valuelen == 3 ) ul = (value[0] << 16) | (value[1] << 8) | value[2]; else { log_error (_("invalid structure of OpenPGP card (DO 0x93)\n")); ul = 0; } return ul; } static unsigned long get_sig_counter (app_t app) { void *relptr; unsigned char *value; size_t valuelen; unsigned long ul; relptr = get_one_do (app, 0x0093, &value, &valuelen, NULL); if (!relptr) return 0; ul = convert_sig_counter_value (value, valuelen); xfree (relptr); return ul; } static gpg_error_t compare_fingerprint (app_t app, int keyno, unsigned char *sha1fpr) { const unsigned char *fpr; unsigned char *buffer; size_t buflen, n; int rc, i; assert (keyno >= 1 && keyno <= 3); rc = get_cached_data (app, 0x006E, &buffer, &buflen, 0, 0); if (rc) { log_error (_("error reading application data\n")); return gpg_error (GPG_ERR_GENERAL); } fpr = find_tlv (buffer, buflen, 0x00C5, &n); if (!fpr || n != 60) { xfree (buffer); log_error (_("error reading fingerprint DO\n")); return gpg_error (GPG_ERR_GENERAL); } fpr += (keyno-1)*20; for (i=0; i < 20; i++) if (sha1fpr[i] != fpr[i]) { xfree (buffer); log_info (_("fingerprint on card does not match requested one\n")); return gpg_error (GPG_ERR_WRONG_SECKEY); } xfree (buffer); return 0; } /* If a fingerprint has been specified check it against the one on the card. This allows for a meaningful error message in case the key on the card has been replaced but the shadow information known to gpg has not been updated. If there is no fingerprint we assume that this is okay. */ static gpg_error_t check_against_given_fingerprint (app_t app, const char *fpr, int keyno) { unsigned char tmp[20]; const char *s; int n; for (s=fpr, n=0; hexdigitp (s); s++, n++) ; if (n != 40) return gpg_error (GPG_ERR_INV_ID); else if (!*s) ; /* okay */ else return gpg_error (GPG_ERR_INV_ID); for (s=fpr, n=0; n < 20; s += 2, n++) tmp[n] = xtoi_2 (s); return compare_fingerprint (app, keyno, tmp); } /* Compute a digital signature on INDATA which is expected to be the raw message digest. For this application the KEYIDSTR consists of the serialnumber and the fingerprint delimited by a slash. Note that this function may return the error code GPG_ERR_WRONG_CARD to indicate that the card currently present does not match the one required for the requested action (e.g. the serial number does not match). As a special feature a KEYIDSTR of "OPENPGP.3" redirects the operation to the auth command. */ static gpg_error_t do_sign (app_t app, const char *keyidstr, int hashalgo, gpg_error_t (*pincb)(void*, const char *, char **), void *pincb_arg, const void *indata, size_t indatalen, unsigned char **outdata, size_t *outdatalen ) { static unsigned char rmd160_prefix[15] = /* Object ID is 1.3.36.3.2.1 */ { 0x30, 0x21, 0x30, 0x09, 0x06, 0x05, 0x2b, 0x24, 0x03, 0x02, 0x01, 0x05, 0x00, 0x04, 0x14 }; static unsigned char sha1_prefix[15] = /* (1.3.14.3.2.26) */ { 0x30, 0x21, 0x30, 0x09, 0x06, 0x05, 0x2b, 0x0e, 0x03, 0x02, 0x1a, 0x05, 0x00, 0x04, 0x14 }; static unsigned char sha224_prefix[19] = /* (2.16.840.1.101.3.4.2.4) */ { 0x30, 0x2D, 0x30, 0x0d, 0x06, 0x09, 0x60, 0x86, 0x48, 0x01, 0x65, 0x03, 0x04, 0x02, 0x04, 0x05, 0x00, 0x04, 0x1C }; static unsigned char sha256_prefix[19] = /* (2.16.840.1.101.3.4.2.1) */ { 0x30, 0x31, 0x30, 0x0d, 0x06, 0x09, 0x60, 0x86, 0x48, 0x01, 0x65, 0x03, 0x04, 0x02, 0x01, 0x05, 0x00, 0x04, 0x20 }; static unsigned char sha384_prefix[19] = /* (2.16.840.1.101.3.4.2.2) */ { 0x30, 0x41, 0x30, 0x0d, 0x06, 0x09, 0x60, 0x86, 0x48, 0x01, 0x65, 0x03, 0x04, 0x02, 0x02, 0x05, 0x00, 0x04, 0x30 }; static unsigned char sha512_prefix[19] = /* (2.16.840.1.101.3.4.2.3) */ { 0x30, 0x51, 0x30, 0x0d, 0x06, 0x09, 0x60, 0x86, 0x48, 0x01, 0x65, 0x03, 0x04, 0x02, 0x03, 0x05, 0x00, 0x04, 0x40 }; int rc; unsigned char data[19+64]; size_t datalen; unsigned char tmp_sn[20]; /* Actually 16 bytes but also for the fpr. */ const char *s; int n; const char *fpr = NULL; unsigned long sigcount; int use_auth = 0; int exmode, le_value; if (!keyidstr || !*keyidstr) return gpg_error (GPG_ERR_INV_VALUE); /* Strip off known prefixes. */ #define X(a,b,c,d) \ if (hashalgo == GCRY_MD_ ## a \ && (d) \ && indatalen == sizeof b ## _prefix + (c) \ && !memcmp (indata, b ## _prefix, sizeof b ## _prefix)) \ { \ indata = (const char*)indata + sizeof b ## _prefix; \ indatalen -= sizeof b ## _prefix; \ } if (indatalen == 20) ; /* Assume a plain SHA-1 or RMD160 digest has been given. */ else X(SHA1, sha1, 20, 1) else X(RMD160, rmd160, 20, 1) else X(SHA224, sha224, 28, app->app_local->extcap.is_v2) else X(SHA256, sha256, 32, app->app_local->extcap.is_v2) else X(SHA384, sha384, 48, app->app_local->extcap.is_v2) else X(SHA512, sha512, 64, app->app_local->extcap.is_v2) else if ((indatalen == 28 || indatalen == 32 || indatalen == 48 || indatalen ==64) && app->app_local->extcap.is_v2) ; /* Assume a plain SHA-3 digest has been given. */ else { log_error (_("card does not support digest algorithm %s\n"), gcry_md_algo_name (hashalgo)); /* Or the supplied digest length does not match an algorithm. */ return gpg_error (GPG_ERR_INV_VALUE); } #undef X /* Check whether an OpenPGP card of any version has been requested. */ if (!strcmp (keyidstr, "OPENPGP.1")) ; else if (!strcmp (keyidstr, "OPENPGP.3")) use_auth = 1; else if (strlen (keyidstr) < 32 || strncmp (keyidstr, "D27600012401", 12)) return gpg_error (GPG_ERR_INV_ID); else { for (s=keyidstr, n=0; hexdigitp (s); s++, n++) ; if (n != 32) return gpg_error (GPG_ERR_INV_ID); else if (!*s) ; /* no fingerprint given: we allow this for now. */ else if (*s == '/') fpr = s + 1; else return gpg_error (GPG_ERR_INV_ID); for (s=keyidstr, n=0; n < 16; s += 2, n++) tmp_sn[n] = xtoi_2 (s); if (app->serialnolen != 16) return gpg_error (GPG_ERR_INV_CARD); if (memcmp (app->serialno, tmp_sn, 16)) return gpg_error (GPG_ERR_WRONG_CARD); } /* If a fingerprint has been specified check it against the one on the card. This is allows for a meaningful error message in case the key on the card has been replaced but the shadow information known to gpg was not updated. If there is no fingerprint, gpg will detect a bogus signature anyway due to the verify-after-signing feature. */ rc = fpr? check_against_given_fingerprint (app, fpr, 1) : 0; if (rc) return rc; /* Concatenate prefix and digest. */ #define X(a,b,d) \ if (hashalgo == GCRY_MD_ ## a && (d) ) \ { \ datalen = sizeof b ## _prefix + indatalen; \ assert (datalen <= sizeof data); \ memcpy (data, b ## _prefix, sizeof b ## _prefix); \ memcpy (data + sizeof b ## _prefix, indata, indatalen); \ } if (use_auth || app->app_local->keyattr[use_auth? 2: 0].key_type == KEY_TYPE_RSA) { X(SHA1, sha1, 1) else X(RMD160, rmd160, 1) else X(SHA224, sha224, app->app_local->extcap.is_v2) else X(SHA256, sha256, app->app_local->extcap.is_v2) else X(SHA384, sha384, app->app_local->extcap.is_v2) else X(SHA512, sha512, app->app_local->extcap.is_v2) else return gpg_error (GPG_ERR_UNSUPPORTED_ALGORITHM); } else { datalen = indatalen; memcpy (data, indata, indatalen); } #undef X /* Redirect to the AUTH command if asked to. */ if (use_auth) { return do_auth (app, "OPENPGP.3", pincb, pincb_arg, data, datalen, outdata, outdatalen); } /* Show the number of signature done using this key. */ sigcount = get_sig_counter (app); log_info (_("signatures created so far: %lu\n"), sigcount); /* Check CHV if needed. */ if (!app->did_chv1 || app->force_chv1 ) { char *pinvalue; rc = verify_a_chv (app, pincb, pincb_arg, 1, sigcount, &pinvalue); if (rc) return rc; app->did_chv1 = 1; /* For cards with versions < 2 we want to keep CHV1 and CHV2 in sync, thus we verify CHV2 here using the given PIN. Cards with version2 to not have the need for a separate CHV2 and internally use just one. Obviously we can't do that if the pinpad has been used. */ if (!app->did_chv2 && pinvalue && !app->app_local->extcap.is_v2) { rc = iso7816_verify (app->slot, 0x82, pinvalue, strlen (pinvalue)); if (gpg_err_code (rc) == GPG_ERR_BAD_PIN) rc = gpg_error (GPG_ERR_PIN_NOT_SYNCED); if (rc) { log_error (_("verify CHV%d failed: %s\n"), 2, gpg_strerror (rc)); xfree (pinvalue); flush_cache_after_error (app); return rc; } app->did_chv2 = 1; } xfree (pinvalue); } if (app->app_local->cardcap.ext_lc_le) { exmode = 1; /* Use extended length. */ le_value = app->app_local->extcap.max_rsp_data; } else { exmode = 0; le_value = 0; } rc = iso7816_compute_ds (app->slot, exmode, data, datalen, le_value, outdata, outdatalen); return rc; } /* Compute a digital signature using the INTERNAL AUTHENTICATE command on INDATA which is expected to be the raw message digest. For this application the KEYIDSTR consists of the serialnumber and the fingerprint delimited by a slash. Optionally the id OPENPGP.3 may be given. Note that this function may return the error code GPG_ERR_WRONG_CARD to indicate that the card currently present does not match the one required for the requested action (e.g. the serial number does not match). */ static gpg_error_t do_auth (app_t app, const char *keyidstr, gpg_error_t (*pincb)(void*, const char *, char **), void *pincb_arg, const void *indata, size_t indatalen, unsigned char **outdata, size_t *outdatalen ) { int rc; unsigned char tmp_sn[20]; /* Actually 16 but we use it also for the fpr. */ const char *s; int n; const char *fpr = NULL; if (!keyidstr || !*keyidstr) return gpg_error (GPG_ERR_INV_VALUE); if (app->app_local->keyattr[2].key_type == KEY_TYPE_RSA && indatalen > 101) /* For a 2048 bit key. */ return gpg_error (GPG_ERR_INV_VALUE); if (app->app_local->keyattr[2].key_type == KEY_TYPE_ECDSA && (indatalen == 51 || indatalen == 67 || indatalen == 83)) { const char *p = (const char *)indata + 19; indata = p; indatalen -= 19; } else if (app->app_local->keyattr[2].key_type == KEY_TYPE_EDDSA) { const char *p = (const char *)indata + 15; indata = p; indatalen -= 15; } /* Check whether an OpenPGP card of any version has been requested. */ if (!strcmp (keyidstr, "OPENPGP.3")) ; else if (strlen (keyidstr) < 32 || strncmp (keyidstr, "D27600012401", 12)) return gpg_error (GPG_ERR_INV_ID); else { for (s=keyidstr, n=0; hexdigitp (s); s++, n++) ; if (n != 32) return gpg_error (GPG_ERR_INV_ID); else if (!*s) ; /* no fingerprint given: we allow this for now. */ else if (*s == '/') fpr = s + 1; else return gpg_error (GPG_ERR_INV_ID); for (s=keyidstr, n=0; n < 16; s += 2, n++) tmp_sn[n] = xtoi_2 (s); if (app->serialnolen != 16) return gpg_error (GPG_ERR_INV_CARD); if (memcmp (app->serialno, tmp_sn, 16)) return gpg_error (GPG_ERR_WRONG_CARD); } /* If a fingerprint has been specified check it against the one on the card. This is allows for a meaningful error message in case the key on the card has been replaced but the shadow information known to gpg was not updated. If there is no fingerprint, gpg will detect a bogus signature anyway due to the verify-after-signing feature. */ rc = fpr? check_against_given_fingerprint (app, fpr, 3) : 0; if (rc) return rc; rc = verify_chv2 (app, pincb, pincb_arg); if (!rc) { int exmode, le_value; if (app->app_local->cardcap.ext_lc_le) { exmode = 1; /* Use extended length. */ le_value = app->app_local->extcap.max_rsp_data; } else { exmode = 0; le_value = 0; } rc = iso7816_internal_authenticate (app->slot, exmode, indata, indatalen, le_value, outdata, outdatalen); } return rc; } static gpg_error_t do_decipher (app_t app, const char *keyidstr, gpg_error_t (*pincb)(void*, const char *, char **), void *pincb_arg, const void *indata, size_t indatalen, unsigned char **outdata, size_t *outdatalen, unsigned int *r_info) { int rc; unsigned char tmp_sn[20]; /* actually 16 but we use it also for the fpr. */ const char *s; int n; const char *fpr = NULL; int exmode, le_value; if (!keyidstr || !*keyidstr || !indatalen) return gpg_error (GPG_ERR_INV_VALUE); /* Check whether an OpenPGP card of any version has been requested. */ if (!strcmp (keyidstr, "OPENPGP.2")) ; else if (strlen (keyidstr) < 32 || strncmp (keyidstr, "D27600012401", 12)) return gpg_error (GPG_ERR_INV_ID); else { for (s=keyidstr, n=0; hexdigitp (s); s++, n++) ; if (n != 32) return gpg_error (GPG_ERR_INV_ID); else if (!*s) ; /* no fingerprint given: we allow this for now. */ else if (*s == '/') fpr = s + 1; else return gpg_error (GPG_ERR_INV_ID); for (s=keyidstr, n=0; n < 16; s += 2, n++) tmp_sn[n] = xtoi_2 (s); if (app->serialnolen != 16) return gpg_error (GPG_ERR_INV_CARD); if (memcmp (app->serialno, tmp_sn, 16)) return gpg_error (GPG_ERR_WRONG_CARD); } /* If a fingerprint has been specified check it against the one on the card. This is allows for a meaningful error message in case the key on the card has been replaced but the shadow information known to gpg was not updated. If there is no fingerprint, the decryption won't produce the right plaintext anyway. */ rc = fpr? check_against_given_fingerprint (app, fpr, 2) : 0; if (rc) return rc; rc = verify_chv2 (app, pincb, pincb_arg); if (!rc) { int fixuplen; unsigned char *fixbuf = NULL; int padind = 0; /* We might encounter a couple of leading zeroes in the cryptogram. Due to internal use of MPIs these leading zeroes are stripped. However the OpenPGP card expects exactly 128 bytes for the cryptogram (for a 1k key). Thus we need to fix it up. We do this for up to 16 leading zero bytes; a cryptogram with more than this is with a very high probability anyway broken. If a signed conversion was used we may also encounter one leading zero followed by the correct length. We fix that as well. */ if (indatalen >= (128-16) && indatalen < 128) /* 1024 bit key. */ fixuplen = 128 - indatalen; else if (indatalen >= (192-16) && indatalen < 192) /* 1536 bit key. */ fixuplen = 192 - indatalen; else if (indatalen >= (256-16) && indatalen < 256) /* 2048 bit key. */ fixuplen = 256 - indatalen; else if (indatalen >= (384-16) && indatalen < 384) /* 3072 bit key. */ fixuplen = 384 - indatalen; else if (indatalen >= (512-16) && indatalen < 512) /* 4096 bit key. */ fixuplen = 512 - indatalen; else if (!*(const char *)indata && (indatalen == 129 || indatalen == 193 || indatalen == 257 || indatalen == 385 || indatalen == 513)) fixuplen = -1; else fixuplen = 0; if (fixuplen > 0) { /* While we have to prepend stuff anyway, we can also include the padding byte here so that iso1816_decipher does not need to do another data mangling. */ fixuplen++; fixbuf = xtrymalloc (fixuplen + indatalen); if (!fixbuf) return gpg_error_from_syserror (); memset (fixbuf, 0, fixuplen); memcpy (fixbuf+fixuplen, indata, indatalen); indata = fixbuf; indatalen = fixuplen + indatalen; padind = -1; /* Already padded. */ } else if (fixuplen < 0) { /* We use the extra leading zero as the padding byte. */ padind = -1; } if (app->app_local->cardcap.ext_lc_le && indatalen > 254 ) { exmode = 1; /* Extended length w/o a limit. */ le_value = app->app_local->extcap.max_rsp_data; } else if (app->app_local->cardcap.cmd_chaining && indatalen > 254) { exmode = -254; /* Command chaining with max. 254 bytes. */ le_value = 0; } else exmode = le_value = 0; rc = iso7816_decipher (app->slot, exmode, indata, indatalen, le_value, padind, outdata, outdatalen); xfree (fixbuf); if (gpg_err_code (rc) == GPG_ERR_CARD /* actual SW is 0x640a */ && app->app_local->manufacturer == 5 && app->card_version == 0x0200) log_info ("NOTE: Cards with manufacturer id 5 and s/n <= 346 (0x15a)" " do not work with encryption keys > 2048 bits\n"); *r_info |= APP_DECIPHER_INFO_NOPAD; } return rc; } /* Perform a simple verify operation for CHV1 and CHV2, so that further operations won't ask for CHV2 and it is possible to do a cheap check on the PIN: If there is something wrong with the PIN entry system, only the regular CHV will get blocked and not the dangerous CHV3. KEYIDSTR is the usual card's serial number; an optional fingerprint part will be ignored. There is a special mode if the keyidstr is "[CHV3]" with the "[CHV3]" being a literal string: The Admin Pin is checked if and only if the retry counter is still at 3. */ static gpg_error_t do_check_pin (app_t app, const char *keyidstr, gpg_error_t (*pincb)(void*, const char *, char **), void *pincb_arg) { unsigned char tmp_sn[20]; const char *s; int n; int admin_pin = 0; if (!keyidstr || !*keyidstr) return gpg_error (GPG_ERR_INV_VALUE); /* Check whether an OpenPGP card of any version has been requested. */ if (strlen (keyidstr) < 32 || strncmp (keyidstr, "D27600012401", 12)) return gpg_error (GPG_ERR_INV_ID); for (s=keyidstr, n=0; hexdigitp (s); s++, n++) ; if (n != 32) return gpg_error (GPG_ERR_INV_ID); else if (!*s) ; /* No fingerprint given: we allow this for now. */ else if (*s == '/') ; /* We ignore a fingerprint. */ else if (!strcmp (s, "[CHV3]") ) admin_pin = 1; else return gpg_error (GPG_ERR_INV_ID); for (s=keyidstr, n=0; n < 16; s += 2, n++) tmp_sn[n] = xtoi_2 (s); if (app->serialnolen != 16) return gpg_error (GPG_ERR_INV_CARD); if (memcmp (app->serialno, tmp_sn, 16)) return gpg_error (GPG_ERR_WRONG_CARD); /* Yes, there is a race conditions: The user might pull the card right here and we won't notice that. However this is not a problem and the check above is merely for a graceful failure between operations. */ if (admin_pin) { void *relptr; unsigned char *value; size_t valuelen; int count; relptr = get_one_do (app, 0x00C4, &value, &valuelen, NULL); if (!relptr || valuelen < 7) { log_error (_("error retrieving CHV status from card\n")); xfree (relptr); return gpg_error (GPG_ERR_CARD); } count = value[6]; xfree (relptr); if (!count) { log_info (_("card is permanently locked!\n")); return gpg_error (GPG_ERR_BAD_PIN); } else if (value[6] < 3) { log_info (_("verification of Admin PIN is currently prohibited " "through this command\n")); return gpg_error (GPG_ERR_GENERAL); } app->did_chv3 = 0; /* Force verification. */ return verify_chv3 (app, pincb, pincb_arg); } else return verify_chv2 (app, pincb, pincb_arg); } /* Show information about card capabilities. */ static void show_caps (struct app_local_s *s) { log_info ("Version-2 ......: %s\n", s->extcap.is_v2? "yes":"no"); log_info ("Get-Challenge ..: %s", s->extcap.get_challenge? "yes":"no"); if (s->extcap.get_challenge) log_printf (" (%u bytes max)", s->extcap.max_get_challenge); log_info ("Key-Import .....: %s\n", s->extcap.key_import? "yes":"no"); log_info ("Change-Force-PW1: %s\n", s->extcap.change_force_chv? "yes":"no"); log_info ("Private-DOs ....: %s\n", s->extcap.private_dos? "yes":"no"); log_info ("Algo-Attr-Change: %s\n", s->extcap.algo_attr_change? "yes":"no"); log_info ("SM-Support .....: %s", s->extcap.sm_supported? "yes":"no"); if (s->extcap.sm_supported) log_printf (" (%s)", s->extcap.sm_aes128? "AES-128":"3DES"); log_info ("Max-Cert3-Len ..: %u\n", s->extcap.max_certlen_3); log_info ("Max-Cmd-Data ...: %u\n", s->extcap.max_cmd_data); log_info ("Max-Rsp-Data ...: %u\n", s->extcap.max_rsp_data); log_info ("Cmd-Chaining ...: %s\n", s->cardcap.cmd_chaining?"yes":"no"); log_info ("Ext-Lc-Le ......: %s\n", s->cardcap.ext_lc_le?"yes":"no"); log_info ("Status Indicator: %02X\n", s->status_indicator); log_info ("GnuPG-No-Sync ..: %s\n", s->flags.no_sync? "yes":"no"); log_info ("GnuPG-Def-PW2 ..: %s\n", s->flags.def_chv2? "yes":"no"); } /* Parse the historical bytes in BUFFER of BUFLEN and store them in APPLOC. */ static void parse_historical (struct app_local_s *apploc, const unsigned char * buffer, size_t buflen) { /* Example buffer: 00 31 C5 73 C0 01 80 00 90 00 */ if (buflen < 4) { log_error ("warning: historical bytes are too short\n"); return; /* Too short. */ } if (*buffer) { log_error ("warning: bad category indicator in historical bytes\n"); return; } /* Skip category indicator. */ buffer++; buflen--; /* Get the status indicator. */ apploc->status_indicator = buffer[buflen-3]; buflen -= 3; /* Parse the compact TLV. */ while (buflen) { unsigned int tag = (*buffer & 0xf0) >> 4; unsigned int len = (*buffer & 0x0f); if (len+1 > buflen) { log_error ("warning: bad Compact-TLV in historical bytes\n"); return; /* Error. */ } buffer++; buflen--; if (tag == 7 && len == 3) { /* Card capabilities. */ apploc->cardcap.cmd_chaining = !!(buffer[2] & 0x80); apploc->cardcap.ext_lc_le = !!(buffer[2] & 0x40); } buffer += len; buflen -= len; } } static int parse_ecc_curve (const unsigned char *buffer, size_t buflen) { int curve; if (buflen == 5 && buffer[5] == 0x22) curve = CURVE_NIST_P384; else if (buflen == 5 && buffer[5] == 0x23) curve = CURVE_NIST_P521; else if (buflen == 8) curve = CURVE_NIST_P256; else if (buflen == 5 && buffer[5] == 0x0a) curve = CURVE_SEC_P256K1; else if (buflen == 9) curve = CURVE_ED25519; else curve = CURVE_UNKNOWN; return curve; } /* Parse and optionally show the algorithm attributes for KEYNO. KEYNO must be in the range 0..2. */ static void parse_algorithm_attribute (app_t app, int keyno) { unsigned char *buffer; size_t buflen; void *relptr; const char desc[3][5] = {"sign", "encr", "auth"}; assert (keyno >=0 && keyno <= 2); app->app_local->keyattr[keyno].key_type = KEY_TYPE_RSA; app->app_local->keyattr[keyno].rsa.n_bits = 0; relptr = get_one_do (app, 0xC1+keyno, &buffer, &buflen, NULL); if (!relptr) { log_error ("error reading DO 0x%02X\n", 0xc1+keyno); return; } if (buflen < 1) { log_error ("error reading DO 0x%02X\n", 0xc1+keyno); xfree (relptr); return; } if (opt.verbose) log_info ("Key-Attr-%s ..: ", desc[keyno]); if (*buffer == 1 && (buflen == 5 || buflen == 6)) { app->app_local->keyattr[keyno].rsa.n_bits = (buffer[1]<<8 | buffer[2]); app->app_local->keyattr[keyno].rsa.e_bits = (buffer[3]<<8 | buffer[4]); app->app_local->keyattr[keyno].rsa.format = 0; if (buflen < 6) app->app_local->keyattr[keyno].rsa.format = RSA_STD; else app->app_local->keyattr[keyno].rsa.format = (buffer[5] == 0? RSA_STD : buffer[5] == 1? RSA_STD_N : buffer[5] == 2? RSA_CRT : buffer[5] == 3? RSA_CRT_N : RSA_UNKNOWN_FMT); if (opt.verbose) log_printf ("RSA, n=%u, e=%u, fmt=%s\n", app->app_local->keyattr[keyno].rsa.n_bits, app->app_local->keyattr[keyno].rsa.e_bits, app->app_local->keyattr[keyno].rsa.format == RSA_STD? "std" : app->app_local->keyattr[keyno].rsa.format == RSA_STD_N?"std+n": app->app_local->keyattr[keyno].rsa.format == RSA_CRT? "crt" : app->app_local->keyattr[keyno].rsa.format == RSA_CRT_N?"crt+n":"?"); } else if (*buffer == 19) /* ECDSA */ { app->app_local->keyattr[keyno].key_type = KEY_TYPE_ECDSA; app->app_local->keyattr[keyno].ecdsa.curve = parse_ecc_curve (buffer + 1, buflen - 1); } else if (*buffer == 18 && buflen == 11) /* ECDH */ { app->app_local->keyattr[keyno].key_type = KEY_TYPE_ECDH; app->app_local->keyattr[keyno].ecdh.hashalgo = buffer[1]; app->app_local->keyattr[keyno].ecdh.cipheralgo = buffer[2]; app->app_local->keyattr[keyno].ecdh.curve = parse_ecc_curve (buffer + 3, buflen - 3); } else if (*buffer == 105) /* EdDSA (experimental) */ { app->app_local->keyattr[keyno].key_type = KEY_TYPE_EDDSA; app->app_local->keyattr[keyno].eddsa.curve = parse_ecc_curve (buffer + 1, buflen - 1); } else if (opt.verbose) log_printhex ("", buffer, buflen); xfree (relptr); } /* Select the OpenPGP application on the card in SLOT. This function must be used before any other OpenPGP application functions. */ gpg_error_t app_select_openpgp (app_t app) { static char const aid[] = { 0xD2, 0x76, 0x00, 0x01, 0x24, 0x01 }; int slot = app->slot; int rc; unsigned char *buffer; size_t buflen; void *relptr; /* Note that the card can't cope with P2=0xCO, thus we need to pass a special flag value. */ rc = iso7816_select_application (slot, aid, sizeof aid, 0x0001); if (!rc) { unsigned int manufacturer; app->apptype = "OPENPGP"; app->did_chv1 = 0; app->did_chv2 = 0; app->did_chv3 = 0; app->app_local = NULL; /* The OpenPGP card returns the serial number as part of the AID; because we prefer to use OpenPGP serial numbers, we replace a possibly already set one from a EF.GDO with this one. Note, that for current OpenPGP cards, no EF.GDO exists and thus it won't matter at all. */ rc = iso7816_get_data (slot, 0, 0x004F, &buffer, &buflen); if (rc) goto leave; if (opt.verbose) { log_info ("AID: "); log_printhex ("", buffer, buflen); } app->card_version = buffer[6] << 8; app->card_version |= buffer[7]; manufacturer = (buffer[8]<<8 | buffer[9]); xfree (app->serialno); app->serialno = buffer; app->serialnolen = buflen; buffer = NULL; app->app_local = xtrycalloc (1, sizeof *app->app_local); if (!app->app_local) { rc = gpg_error (gpg_err_code_from_errno (errno)); goto leave; } app->app_local->manufacturer = manufacturer; if (app->card_version >= 0x0200) app->app_local->extcap.is_v2 = 1; /* Read the historical bytes. */ relptr = get_one_do (app, 0x5f52, &buffer, &buflen, NULL); if (relptr) { if (opt.verbose) { log_info ("Historical Bytes: "); log_printhex ("", buffer, buflen); } parse_historical (app->app_local, buffer, buflen); xfree (relptr); } /* Read the force-chv1 flag. */ relptr = get_one_do (app, 0x00C4, &buffer, &buflen, NULL); if (!relptr) { log_error (_("can't access %s - invalid OpenPGP card?\n"), "CHV Status Bytes"); goto leave; } app->force_chv1 = (buflen && *buffer == 0); xfree (relptr); /* Read the extended capabilities. */ relptr = get_one_do (app, 0x00C0, &buffer, &buflen, NULL); if (!relptr) { log_error (_("can't access %s - invalid OpenPGP card?\n"), "Extended Capability Flags" ); goto leave; } if (buflen) { app->app_local->extcap.sm_supported = !!(*buffer & 0x80); app->app_local->extcap.get_challenge = !!(*buffer & 0x40); app->app_local->extcap.key_import = !!(*buffer & 0x20); app->app_local->extcap.change_force_chv = !!(*buffer & 0x10); app->app_local->extcap.private_dos = !!(*buffer & 0x08); app->app_local->extcap.algo_attr_change = !!(*buffer & 0x04); } if (buflen >= 10) { /* Available with v2 cards. */ app->app_local->extcap.sm_aes128 = (buffer[1] == 1); app->app_local->extcap.max_get_challenge = (buffer[2] << 8 | buffer[3]); app->app_local->extcap.max_certlen_3 = (buffer[4] << 8 | buffer[5]); app->app_local->extcap.max_cmd_data = (buffer[6] << 8 | buffer[7]); app->app_local->extcap.max_rsp_data = (buffer[8] << 8 | buffer[9]); } xfree (relptr); /* Some of the first cards accidently don't set the CHANGE_FORCE_CHV bit but allow it anyway. */ if (app->card_version <= 0x0100 && manufacturer == 1) app->app_local->extcap.change_force_chv = 1; parse_login_data (app); if (opt.verbose) show_caps (app->app_local); parse_algorithm_attribute (app, 0); parse_algorithm_attribute (app, 1); parse_algorithm_attribute (app, 2); if (opt.verbose > 1) dump_all_do (slot); app->fnc.deinit = do_deinit; app->fnc.learn_status = do_learn_status; app->fnc.readcert = do_readcert; app->fnc.readkey = do_readkey; app->fnc.getattr = do_getattr; app->fnc.setattr = do_setattr; app->fnc.writecert = do_writecert; app->fnc.writekey = do_writekey; app->fnc.genkey = do_genkey; app->fnc.sign = do_sign; app->fnc.auth = do_auth; app->fnc.decipher = do_decipher; app->fnc.change_pin = do_change_pin; app->fnc.check_pin = do_check_pin; } leave: if (rc) do_deinit (app); return rc; }