diff --git a/g10/export.c b/g10/export.c index 0187788f0..3d4413068 100644 --- a/g10/export.c +++ b/g10/export.c @@ -1,3021 +1,2976 @@ /* export.c - Export keys in the OpenPGP defined format. * Copyright (C) 1998, 1999, 2000, 2001, 2002, 2003, 2004, * 2005, 2010 Free Software Foundation, Inc. * Copyright (C) 1998-2016 Werner Koch * * 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 . */ #include #include #include #include #include #include "gpg.h" #include "options.h" #include "packet.h" #include "../common/status.h" #include "keydb.h" #include "../common/util.h" #include "main.h" #include "../common/i18n.h" #include "../common/membuf.h" #include "../common/host2net.h" #include "../common/zb32.h" #include "../common/recsel.h" #include "../common/mbox-util.h" #include "../common/init.h" #include "trustdb.h" #include "call-agent.h" #include "key-clean.h" #include "pkglue.h" /* An object to keep track of subkeys. */ struct subkey_list_s { struct subkey_list_s *next; u32 kid[2]; }; typedef struct subkey_list_s *subkey_list_t; /* An object to track statistics for export operations. */ struct export_stats_s { ulong count; /* Number of processed keys. */ ulong secret_count; /* Number of secret keys seen. */ ulong exported; /* Number of actual exported keys. */ }; /* Global variables to store the selectors created from * --export-filter keep-uid=EXPR. * --export-filter drop-subkey=EXPR. * --export-filter select=EXPR. * * FIXME: We should put this into the CTRL object but that requires a * lot more changes right now. */ static recsel_expr_t export_keep_uid; static recsel_expr_t export_drop_subkey; static recsel_expr_t export_select_filter; /* An object used for a linked list to implement the * push_export_filter/pop_export_filters functions. */ struct export_filter_attic_s { struct export_filter_attic_s *next; recsel_expr_t export_keep_uid; recsel_expr_t export_drop_subkey; recsel_expr_t export_select_filter; }; static struct export_filter_attic_s *export_filter_attic; /* Local prototypes. */ static int do_export (ctrl_t ctrl, strlist_t users, int secret, unsigned int options, export_stats_t stats); static int do_export_stream (ctrl_t ctrl, iobuf_t out, strlist_t users, int secret, kbnode_t *keyblock_out, unsigned int options, export_stats_t stats, int *any); static gpg_error_t print_dane_records /**/ (iobuf_t out, kbnode_t keyblock, PKT_public_key *pk, const void *data, size_t datalen); static void cleanup_export_globals (void) { recsel_release (export_keep_uid); export_keep_uid = NULL; recsel_release (export_drop_subkey); export_drop_subkey = NULL; recsel_release (export_select_filter); export_select_filter = NULL; } /* Option parser for export options. See parse_options for details. */ int parse_export_options(char *str,unsigned int *options,int noisy) { struct parse_options export_opts[]= { {"export-local-sigs",EXPORT_LOCAL_SIGS,NULL, N_("export signatures that are marked as local-only")}, {"export-attributes",EXPORT_ATTRIBUTES,NULL, N_("export attribute user IDs (generally photo IDs)")}, {"export-sensitive-revkeys",EXPORT_SENSITIVE_REVKEYS,NULL, N_("export revocation keys marked as \"sensitive\"")}, {"export-clean",EXPORT_CLEAN,NULL, N_("remove unusable parts from key during export")}, {"export-minimal",EXPORT_MINIMAL|EXPORT_CLEAN,NULL, N_("remove as much as possible from key during export")}, {"export-dane", EXPORT_DANE_FORMAT, NULL, NULL }, {"export-revocs", EXPORT_REVOCS, NULL, N_("export only revocation certificates") }, {"backup", EXPORT_BACKUP, NULL, N_("use the GnuPG key backup format")}, {"export-backup", EXPORT_BACKUP, NULL, NULL }, /* Aliases for backward compatibility */ {"include-local-sigs",EXPORT_LOCAL_SIGS,NULL,NULL}, {"include-attributes",EXPORT_ATTRIBUTES,NULL,NULL}, {"include-sensitive-revkeys",EXPORT_SENSITIVE_REVKEYS,NULL,NULL}, /* dummy */ {"export-unusable-sigs",0,NULL,NULL}, {"export-clean-sigs",0,NULL,NULL}, {"export-clean-uids",0,NULL,NULL}, {NULL,0,NULL,NULL} /* add tags for include revoked and disabled? */ }; int rc; rc = parse_options (str, options, export_opts, noisy); if (!rc) return 0; /* Alter other options we want or don't want for restore. */ if ((*options & EXPORT_BACKUP)) { *options |= (EXPORT_LOCAL_SIGS | EXPORT_ATTRIBUTES | EXPORT_SENSITIVE_REVKEYS); *options &= ~(EXPORT_CLEAN | EXPORT_MINIMAL | EXPORT_DANE_FORMAT); } return rc; } /* Parse and set an export filter from string. STRING has the format * "NAME=EXPR" with NAME being the name of the filter. Spaces before * and after NAME are not allowed. If this function is called several * times all expressions for the same NAME are concatenated. * Supported filter names are: * * - keep-uid :: If the expression evaluates to true for a certain * user ID packet, that packet and all it dependencies * will be exported. The expression may use these * variables: * * - uid :: The entire user ID. * - mbox :: The mail box part of the user ID. * - primary :: Evaluate to true for the primary user ID. * * - drop-subkey :: If the expression evaluates to true for a subkey * packet that subkey and all it dependencies will be * remove from the keyblock. The expression may use these * variables: * * - secret :: 1 for a secret subkey, else 0. * - key_algo :: Public key algorithm id * * - select :: The key is only exported if the filter returns true. */ gpg_error_t parse_and_set_export_filter (const char *string) { gpg_error_t err; /* Auto register the cleanup function. */ register_mem_cleanup_func (cleanup_export_globals); if (!strncmp (string, "keep-uid=", 9)) err = recsel_parse_expr (&export_keep_uid, string+9); else if (!strncmp (string, "drop-subkey=", 12)) err = recsel_parse_expr (&export_drop_subkey, string+12); else if (!strncmp (string, "select=", 7)) err = recsel_parse_expr (&export_select_filter, string+7); else err = gpg_error (GPG_ERR_INV_NAME); return err; } /* Push the current export filters onto a stack so that new export * filters can be defined which will be active until the next * pop_export_filters or another push_export_filters. */ void push_export_filters (void) { struct export_filter_attic_s *item; item = xcalloc (1, sizeof *item); item->export_keep_uid = export_keep_uid; export_keep_uid = NULL; item->export_drop_subkey = export_drop_subkey; export_drop_subkey = NULL; item->export_select_filter = export_select_filter; export_select_filter = NULL; item->next = export_filter_attic; export_filter_attic = item; } /* Revert the last push_export_filters. */ void pop_export_filters (void) { struct export_filter_attic_s *item; item = export_filter_attic; if (!item) BUG (); /* No corresponding push. */ export_filter_attic = item->next; cleanup_export_globals (); export_keep_uid = item->export_keep_uid; export_drop_subkey = item->export_drop_subkey; export_select_filter = item->export_select_filter; } /* Create a new export stats object initialized to zero. On error returns NULL and sets ERRNO. */ export_stats_t export_new_stats (void) { export_stats_t stats; return xtrycalloc (1, sizeof *stats); } /* Release an export stats object. */ void export_release_stats (export_stats_t stats) { xfree (stats); } /* Print export statistics using the status interface. */ void export_print_stats (export_stats_t stats) { if (!stats) return; if (is_status_enabled ()) { char buf[15*20]; snprintf (buf, sizeof buf, "%lu %lu %lu", stats->count, stats->secret_count, stats->exported ); write_status_text (STATUS_EXPORT_RES, buf); } } /* * Export public keys (to stdout or to --output FILE). * * Depending on opt.armor the output is armored. OPTIONS are defined * in main.h. If USERS is NULL, all keys will be exported. STATS is * either an export stats object for update or NULL. * * This function is the core of "gpg --export". */ int export_pubkeys (ctrl_t ctrl, strlist_t users, unsigned int options, export_stats_t stats) { return do_export (ctrl, users, 0, options, stats); } /* * Export secret keys (to stdout or to --output FILE). * * Depending on opt.armor the output is armored. OPTIONS are defined * in main.h. If USERS is NULL, all secret keys will be exported. * STATS is either an export stats object for update or NULL. * * This function is the core of "gpg --export-secret-keys". */ int export_seckeys (ctrl_t ctrl, strlist_t users, unsigned int options, export_stats_t stats) { return do_export (ctrl, users, 1, options, stats); } /* * Export secret sub keys (to stdout or to --output FILE). * * This is the same as export_seckeys but replaces the primary key by * a stub key. Depending on opt.armor the output is armored. OPTIONS * are defined in main.h. If USERS is NULL, all secret subkeys will * be exported. STATS is either an export stats object for update or * NULL. * * This function is the core of "gpg --export-secret-subkeys". */ int export_secsubkeys (ctrl_t ctrl, strlist_t users, unsigned int options, export_stats_t stats) { return do_export (ctrl, users, 2, options, stats); } /* * Export a single key into a memory buffer. STATS is either an * export stats object for update or NULL. If PREFIX is not NULL * PREFIXLEN bytes from PREFIX are prepended to the R_DATA. */ gpg_error_t export_pubkey_buffer (ctrl_t ctrl, const char *keyspec, unsigned int options, const void *prefix, size_t prefixlen, export_stats_t stats, kbnode_t *r_keyblock, void **r_data, size_t *r_datalen) { gpg_error_t err; iobuf_t iobuf; int any; strlist_t helplist; *r_keyblock = NULL; *r_data = NULL; *r_datalen = 0; helplist = NULL; if (!add_to_strlist_try (&helplist, keyspec)) return gpg_error_from_syserror (); iobuf = iobuf_temp (); if (prefix && prefixlen) iobuf_write (iobuf, prefix, prefixlen); err = do_export_stream (ctrl, iobuf, helplist, 0, r_keyblock, options, stats, &any); if (!err && !any) err = gpg_error (GPG_ERR_NOT_FOUND); if (!err) { const void *src; size_t datalen; iobuf_flush_temp (iobuf); src = iobuf_get_temp_buffer (iobuf); datalen = iobuf_get_temp_length (iobuf); if (!datalen) err = gpg_error (GPG_ERR_NO_PUBKEY); else if (!(*r_data = xtrymalloc (datalen))) err = gpg_error_from_syserror (); else { memcpy (*r_data, src, datalen); *r_datalen = datalen; } } iobuf_close (iobuf); free_strlist (helplist); if (err && *r_keyblock) { release_kbnode (*r_keyblock); *r_keyblock = NULL; } return err; } /* Export the keys identified by the list of strings in USERS. If Secret is false public keys will be exported. With secret true secret keys will be exported; in this case 1 means the entire secret keyblock and 2 only the subkeys. OPTIONS are the export options to apply. */ static int do_export (ctrl_t ctrl, strlist_t users, int secret, unsigned int options, export_stats_t stats) { IOBUF out = NULL; int any, rc; armor_filter_context_t *afx = NULL; compress_filter_context_t zfx; memset( &zfx, 0, sizeof zfx); rc = open_outfile (-1, NULL, 0, !!secret, &out ); if (rc) return rc; if ( opt.armor && !(options & EXPORT_DANE_FORMAT) ) { afx = new_armor_context (); afx->what = secret? 5 : 1; push_armor_filter (afx, out); } rc = do_export_stream (ctrl, out, users, secret, NULL, options, stats, &any); if ( rc || !any ) iobuf_cancel (out); else iobuf_close (out); release_armor_context (afx); return rc; } /* Release an entire subkey list. */ static void release_subkey_list (subkey_list_t list) { while (list) { subkey_list_t tmp = list->next;; xfree (list); list = tmp; } } /* Returns true if NODE is a subkey and contained in LIST. */ static int subkey_in_list_p (subkey_list_t list, KBNODE node) { if (node->pkt->pkttype == PKT_PUBLIC_SUBKEY || node->pkt->pkttype == PKT_SECRET_SUBKEY ) { u32 kid[2]; keyid_from_pk (node->pkt->pkt.public_key, kid); for (; list; list = list->next) if (list->kid[0] == kid[0] && list->kid[1] == kid[1]) return 1; } return 0; } /* Allocate a new subkey list item from NODE. */ static subkey_list_t new_subkey_list_item (KBNODE node) { subkey_list_t list = xcalloc (1, sizeof *list); if (node->pkt->pkttype == PKT_PUBLIC_SUBKEY || node->pkt->pkttype == PKT_SECRET_SUBKEY) keyid_from_pk (node->pkt->pkt.public_key, list->kid); return list; } /* Helper function to check whether the subkey at NODE actually matches the description at DESC. The function returns true if the key under question has been specified by an exact specification (keyID or fingerprint) and does match the one at NODE. It is assumed that the packet at NODE is either a public or secret subkey. */ int exact_subkey_match_p (KEYDB_SEARCH_DESC *desc, kbnode_t node) { u32 kid[2]; byte fpr[MAX_FINGERPRINT_LEN]; size_t fprlen; int result = 0; switch(desc->mode) { case KEYDB_SEARCH_MODE_SHORT_KID: case KEYDB_SEARCH_MODE_LONG_KID: keyid_from_pk (node->pkt->pkt.public_key, kid); break; case KEYDB_SEARCH_MODE_FPR: fingerprint_from_pk (node->pkt->pkt.public_key, fpr, &fprlen); break; default: break; } switch(desc->mode) { case KEYDB_SEARCH_MODE_SHORT_KID: if (desc->u.kid[1] == kid[1]) result = 1; break; case KEYDB_SEARCH_MODE_LONG_KID: if (desc->u.kid[0] == kid[0] && desc->u.kid[1] == kid[1]) result = 1; break; case KEYDB_SEARCH_MODE_FPR: if (fprlen == desc->fprlen && !memcmp (desc->u.fpr, fpr, desc->fprlen)) result = 1; break; default: break; } return result; } /* Return an error if the key represented by the S-expression S_KEY * and the OpenPGP key represented by PK do not use the same curve. */ static gpg_error_t match_curve_skey_pk (gcry_sexp_t s_key, PKT_public_key *pk) { gcry_sexp_t curve = NULL; gcry_sexp_t flags = NULL; char *curve_str = NULL; char *flag; const char *oidstr = NULL; gcry_mpi_t curve_as_mpi = NULL; gpg_error_t err; int is_eddsa = 0; int idx = 0; if (!(pk->pubkey_algo==PUBKEY_ALGO_ECDH || pk->pubkey_algo==PUBKEY_ALGO_ECDSA || pk->pubkey_algo==PUBKEY_ALGO_EDDSA)) return gpg_error (GPG_ERR_PUBKEY_ALGO); curve = gcry_sexp_find_token (s_key, "curve", 0); if (!curve) { log_error ("no reported curve\n"); return gpg_error (GPG_ERR_UNKNOWN_CURVE); } curve_str = gcry_sexp_nth_string (curve, 1); gcry_sexp_release (curve); curve = NULL; if (!curve_str) { log_error ("no curve name\n"); return gpg_error (GPG_ERR_UNKNOWN_CURVE); } if (!strcmp (curve_str, "Ed448")) is_eddsa = 1; oidstr = openpgp_curve_to_oid (curve_str, NULL, NULL); if (!oidstr) { log_error ("no OID known for curve '%s'\n", curve_str); xfree (curve_str); return gpg_error (GPG_ERR_UNKNOWN_CURVE); } xfree (curve_str); err = openpgp_oid_from_str (oidstr, &curve_as_mpi); if (err) return err; if (gcry_mpi_cmp (pk->pkey[0], curve_as_mpi)) { log_error ("curves do not match\n"); gcry_mpi_release (curve_as_mpi); return gpg_error (GPG_ERR_INV_CURVE); } gcry_mpi_release (curve_as_mpi); flags = gcry_sexp_find_token (s_key, "flags", 0); if (flags) { for (idx = 1; idx < gcry_sexp_length (flags); idx++) { flag = gcry_sexp_nth_string (flags, idx); if (flag && (strcmp ("eddsa", flag) == 0)) is_eddsa = 1; gcry_free (flag); } } if (is_eddsa != (pk->pubkey_algo == PUBKEY_ALGO_EDDSA)) { log_error ("disagreement about EdDSA\n"); err = gpg_error (GPG_ERR_INV_CURVE); } return err; } /* Return a canonicalized public key algorithms. This is used to compare different flavors of algorithms (e.g. ELG and ELG_E are considered the same). */ static enum gcry_pk_algos canon_pk_algo (enum gcry_pk_algos algo) { switch (algo) { case GCRY_PK_RSA: case GCRY_PK_RSA_E: case GCRY_PK_RSA_S: return GCRY_PK_RSA; case GCRY_PK_ELG: case GCRY_PK_ELG_E: return GCRY_PK_ELG; case GCRY_PK_ECC: case GCRY_PK_ECDSA: case GCRY_PK_ECDH: return GCRY_PK_ECC; default: return algo; } } /* Take a cleartext dump of a secret key in PK and change the * parameter array in PK to include the secret parameters. */ static gpg_error_t cleartext_secret_key_to_openpgp (gcry_sexp_t s_key, PKT_public_key *pk) { gpg_error_t err; gcry_sexp_t top_list; gcry_sexp_t key = NULL; char *key_type = NULL; enum gcry_pk_algos pk_algo; struct seckey_info *ski; int idx, sec_start; gcry_mpi_t pub_params[10] = { NULL }; /* we look for a private-key, then the first element in it tells us the type */ top_list = gcry_sexp_find_token (s_key, "private-key", 0); if (!top_list) goto bad_seckey; /* ignore all S-expression after the first sublist -- we assume that they are comments or otherwise irrelevant to OpenPGP */ if (gcry_sexp_length(top_list) < 2) goto bad_seckey; key = gcry_sexp_nth (top_list, 1); if (!key) goto bad_seckey; key_type = gcry_sexp_nth_string(key, 0); pk_algo = gcry_pk_map_name (key_type); log_assert (!pk->seckey_info); pk->seckey_info = ski = xtrycalloc (1, sizeof *ski); if (!ski) { err = gpg_error_from_syserror (); goto leave; } switch (canon_pk_algo (pk_algo)) { case GCRY_PK_RSA: if (!is_RSA (pk->pubkey_algo)) goto bad_pubkey_algo; err = gcry_sexp_extract_param (key, NULL, "ne", &pub_params[0], &pub_params[1], NULL); for (idx=0; idx < 2 && !err; idx++) if (gcry_mpi_cmp(pk->pkey[idx], pub_params[idx])) err = gpg_error (GPG_ERR_BAD_PUBKEY); if (!err) { for (idx = 2; idx < 6 && !err; idx++) { gcry_mpi_release (pk->pkey[idx]); pk->pkey[idx] = NULL; } err = gcry_sexp_extract_param (key, NULL, "dpqu", &pk->pkey[2], &pk->pkey[3], &pk->pkey[4], &pk->pkey[5], NULL); } if (!err) { for (idx = 2; idx < 6; idx++) ski->csum += checksum_mpi (pk->pkey[idx]); } break; case GCRY_PK_DSA: if (!is_DSA (pk->pubkey_algo)) goto bad_pubkey_algo; err = gcry_sexp_extract_param (key, NULL, "pqgy", &pub_params[0], &pub_params[1], &pub_params[2], &pub_params[3], NULL); for (idx=0; idx < 4 && !err; idx++) if (gcry_mpi_cmp(pk->pkey[idx], pub_params[idx])) err = gpg_error (GPG_ERR_BAD_PUBKEY); if (!err) { gcry_mpi_release (pk->pkey[4]); pk->pkey[4] = NULL; err = gcry_sexp_extract_param (key, NULL, "x", &pk->pkey[4], NULL); } if (!err) ski->csum += checksum_mpi (pk->pkey[4]); break; case GCRY_PK_ELG: if (!is_ELGAMAL (pk->pubkey_algo)) goto bad_pubkey_algo; err = gcry_sexp_extract_param (key, NULL, "pgy", &pub_params[0], &pub_params[1], &pub_params[2], NULL); for (idx=0; idx < 3 && !err; idx++) if (gcry_mpi_cmp(pk->pkey[idx], pub_params[idx])) err = gpg_error (GPG_ERR_BAD_PUBKEY); if (!err) { gcry_mpi_release (pk->pkey[3]); pk->pkey[3] = NULL; err = gcry_sexp_extract_param (key, NULL, "x", &pk->pkey[3], NULL); } if (!err) ski->csum += checksum_mpi (pk->pkey[3]); break; case GCRY_PK_ECC: err = match_curve_skey_pk (key, pk); if (err) goto leave; else err = sexp_extract_param_sos (key, "q", &pub_params[0]); if (!err && (gcry_mpi_cmp(pk->pkey[1], pub_params[0]))) err = gpg_error (GPG_ERR_BAD_PUBKEY); sec_start = 2; if (pk->pubkey_algo == PUBKEY_ALGO_ECDH) sec_start += 1; if (!err) { gcry_mpi_release (pk->pkey[sec_start]); pk->pkey[sec_start] = NULL; err = sexp_extract_param_sos (key, "d", &pk->pkey[sec_start]); } if (!err) ski->csum += checksum_mpi (pk->pkey[sec_start]); break; default: pk->seckey_info = NULL; xfree (ski); err = gpg_error (GPG_ERR_NOT_IMPLEMENTED); break; } leave: gcry_sexp_release (top_list); gcry_sexp_release (key); gcry_free (key_type); for (idx=0; idx < DIM(pub_params); idx++) gcry_mpi_release (pub_params[idx]); return err; bad_pubkey_algo: err = gpg_error (GPG_ERR_PUBKEY_ALGO); goto leave; bad_seckey: err = gpg_error (GPG_ERR_BAD_SECKEY); goto leave; } /* Use the key transfer format given in S_PGP to create the secinfo structure in PK and change the parameter array in PK to include the secret parameters. */ static gpg_error_t transfer_format_to_openpgp (gcry_sexp_t s_pgp, PKT_public_key *pk) { gpg_error_t err; gcry_sexp_t top_list; gcry_sexp_t list = NULL; char *curve = NULL; const char *value; size_t valuelen; char *string; int idx; int is_v4, is_protected; enum gcry_pk_algos pk_algo; int protect_algo = 0; char iv[16]; int ivlen = 0; int s2k_mode = 0; int s2k_algo = 0; byte s2k_salt[8]; u32 s2k_count = 0; int is_ecdh = 0; size_t npkey, nskey; gcry_mpi_t skey[10]; /* We support up to 9 parameters. */ int skeyidx = 0; struct seckey_info *ski; /* gcry_log_debugsxp ("transferkey", s_pgp); */ top_list = gcry_sexp_find_token (s_pgp, "openpgp-private-key", 0); if (!top_list) goto bad_seckey; list = gcry_sexp_find_token (top_list, "version", 0); if (!list) goto bad_seckey; value = gcry_sexp_nth_data (list, 1, &valuelen); if (!value || valuelen != 1 || !(value[0] == '3' || value[0] == '4')) goto bad_seckey; is_v4 = (value[0] == '4'); gcry_sexp_release (list); list = gcry_sexp_find_token (top_list, "protection", 0); if (!list) goto bad_seckey; value = gcry_sexp_nth_data (list, 1, &valuelen); if (!value) goto bad_seckey; if (valuelen == 4 && !memcmp (value, "sha1", 4)) is_protected = 2; else if (valuelen == 3 && !memcmp (value, "sum", 3)) is_protected = 1; else if (valuelen == 4 && !memcmp (value, "none", 4)) is_protected = 0; else goto bad_seckey; if (is_protected) { string = gcry_sexp_nth_string (list, 2); if (!string) goto bad_seckey; protect_algo = gcry_cipher_map_name (string); xfree (string); value = gcry_sexp_nth_data (list, 3, &valuelen); if (!value || !valuelen || valuelen > sizeof iv) goto bad_seckey; memcpy (iv, value, valuelen); ivlen = valuelen; string = gcry_sexp_nth_string (list, 4); if (!string) goto bad_seckey; s2k_mode = strtol (string, NULL, 10); xfree (string); string = gcry_sexp_nth_string (list, 5); if (!string) goto bad_seckey; s2k_algo = gcry_md_map_name (string); xfree (string); value = gcry_sexp_nth_data (list, 6, &valuelen); if (!value || !valuelen || valuelen > sizeof s2k_salt) goto bad_seckey; memcpy (s2k_salt, value, valuelen); string = gcry_sexp_nth_string (list, 7); if (!string) goto bad_seckey; s2k_count = strtoul (string, NULL, 10); xfree (string); } /* Parse the gcrypt PK algo and check that it is okay. */ gcry_sexp_release (list); list = gcry_sexp_find_token (top_list, "algo", 0); if (!list) goto bad_seckey; string = gcry_sexp_nth_string (list, 1); if (!string) goto bad_seckey; pk_algo = gcry_pk_map_name (string); xfree (string); string = NULL; if (gcry_pk_algo_info (pk_algo, GCRYCTL_GET_ALGO_NPKEY, NULL, &npkey) || gcry_pk_algo_info (pk_algo, GCRYCTL_GET_ALGO_NSKEY, NULL, &nskey) || !npkey || npkey >= nskey) goto bad_seckey; /* Check that the pubkey algo matches the one from the public key. */ switch (canon_pk_algo (pk_algo)) { case GCRY_PK_RSA: if (!is_RSA (pk->pubkey_algo)) pk_algo = 0; /* Does not match. */ break; case GCRY_PK_DSA: if (!is_DSA (pk->pubkey_algo)) pk_algo = 0; /* Does not match. */ break; case GCRY_PK_ELG: if (!is_ELGAMAL (pk->pubkey_algo)) pk_algo = 0; /* Does not match. */ break; case GCRY_PK_ECC: if (pk->pubkey_algo == PUBKEY_ALGO_ECDSA) ; else if (pk->pubkey_algo == PUBKEY_ALGO_ECDH) is_ecdh = 1; else if (pk->pubkey_algo == PUBKEY_ALGO_EDDSA) ; else pk_algo = 0; /* Does not match. */ /* For ECC we do not have the domain parameters thus fix our info. */ npkey = 1; nskey = 2; break; default: pk_algo = 0; /* Oops. */ break; } if (!pk_algo) { err = gpg_error (GPG_ERR_PUBKEY_ALGO); goto leave; } /* This check has to go after the ecc adjustments. */ if (nskey > PUBKEY_MAX_NSKEY) goto bad_seckey; /* Parse the key parameters. */ gcry_sexp_release (list); list = gcry_sexp_find_token (top_list, "skey", 0); if (!list) goto bad_seckey; for (idx=0;;) { int is_enc; value = gcry_sexp_nth_data (list, ++idx, &valuelen); if (!value && skeyidx >= npkey) break; /* Ready. */ /* Check for too many parameters. Note that depending on the protection mode and version number we may see less than NSKEY (but at least NPKEY+1) parameters. */ if (idx >= 2*nskey) goto bad_seckey; if (skeyidx >= DIM (skey)-1) goto bad_seckey; if (!value || valuelen != 1 || !(value[0] == '_' || value[0] == 'e')) goto bad_seckey; is_enc = (value[0] == 'e'); value = gcry_sexp_nth_data (list, ++idx, &valuelen); if (!value || !valuelen) goto bad_seckey; if (is_enc || pk->pubkey_algo == PUBKEY_ALGO_ECDSA || pk->pubkey_algo == PUBKEY_ALGO_EDDSA || pk->pubkey_algo == PUBKEY_ALGO_ECDH) { unsigned int nbits = valuelen*8; const unsigned char *p = value; if (*p && nbits >= 8 && !(*p & 0x80)) if (--nbits >= 7 && !(*p & 0x40)) if (--nbits >= 6 && !(*p & 0x20)) if (--nbits >= 5 && !(*p & 0x10)) if (--nbits >= 4 && !(*p & 0x08)) if (--nbits >= 3 && !(*p & 0x04)) if (--nbits >= 2 && !(*p & 0x02)) if (--nbits >= 1 && !(*p & 0x01)) --nbits; skey[skeyidx] = gcry_mpi_set_opaque_copy (NULL, value, nbits); if (!skey[skeyidx]) goto outofmem; if (is_enc) gcry_mpi_set_flag (skey[skeyidx], GCRYMPI_FLAG_USER1); else gcry_mpi_set_flag (skey[skeyidx], GCRYMPI_FLAG_USER2); } else { if (gcry_mpi_scan (skey + skeyidx, GCRYMPI_FMT_STD, value, valuelen, NULL)) goto bad_seckey; } skeyidx++; } skey[skeyidx++] = NULL; gcry_sexp_release (list); list = NULL; /* We have no need for the CSUM value thus we don't parse it. */ /* list = gcry_sexp_find_token (top_list, "csum", 0); */ /* if (list) */ /* { */ /* string = gcry_sexp_nth_string (list, 1); */ /* if (!string) */ /* goto bad_seckey; */ /* desired_csum = strtoul (string, NULL, 10); */ /* xfree (string); */ /* } */ /* else */ /* desired_csum = 0; */ /* gcry_sexp_release (list); list = NULL; */ /* Get the curve name if any, */ list = gcry_sexp_find_token (top_list, "curve", 0); if (list) { curve = gcry_sexp_nth_string (list, 1); gcry_sexp_release (list); list = NULL; } gcry_sexp_release (top_list); top_list = NULL; /* log_debug ("XXX is_v4=%d\n", is_v4); */ /* log_debug ("XXX pubkey_algo=%d\n", pubkey_algo); */ /* log_debug ("XXX is_protected=%d\n", is_protected); */ /* log_debug ("XXX protect_algo=%d\n", protect_algo); */ /* log_printhex ("XXX iv", iv, ivlen); */ /* log_debug ("XXX ivlen=%d\n", ivlen); */ /* log_debug ("XXX s2k_mode=%d\n", s2k_mode); */ /* log_debug ("XXX s2k_algo=%d\n", s2k_algo); */ /* log_printhex ("XXX s2k_salt", s2k_salt, sizeof s2k_salt); */ /* log_debug ("XXX s2k_count=%lu\n", (unsigned long)s2k_count); */ /* for (idx=0; skey[idx]; idx++) */ /* { */ /* int is_enc = gcry_mpi_get_flag (skey[idx], GCRYMPI_FLAG_OPAQUE); */ /* log_info ("XXX skey[%d]%s:", idx, is_enc? " (enc)":""); */ /* if (is_enc) */ /* { */ /* void *p; */ /* unsigned int nbits; */ /* p = gcry_mpi_get_opaque (skey[idx], &nbits); */ /* log_printhex (NULL, p, (nbits+7)/8); */ /* } */ /* else */ /* gcry_mpi_dump (skey[idx]); */ /* log_printf ("\n"); */ /* } */ if (!is_v4 || is_protected != 2 ) { /* We only support the v4 format and a SHA-1 checksum. */ err = gpg_error (GPG_ERR_NOT_IMPLEMENTED); goto leave; } /* We need to change the received parameters for ECC algorithms. The transfer format has the curve name and the parameters separate. We put them all into the SKEY array. */ if (canon_pk_algo (pk_algo) == GCRY_PK_ECC) { const char *oidstr; /* Assert that all required parameters are available. We also check that the array does not contain more parameters than needed (this was used by some beta versions of 2.1. */ if (!curve || !skey[0] || !skey[1] || skey[2]) { err = gpg_error (GPG_ERR_INTERNAL); goto leave; } oidstr = openpgp_curve_to_oid (curve, NULL, NULL); if (!oidstr) { log_error ("no OID known for curve '%s'\n", curve); err = gpg_error (GPG_ERR_UNKNOWN_CURVE); goto leave; } /* Put the curve's OID into the MPI array. This requires that we shift Q and D. For ECDH also insert the KDF parms. */ if (is_ecdh) { skey[4] = NULL; skey[3] = skey[1]; skey[2] = gcry_mpi_copy (pk->pkey[2]); } else { skey[3] = NULL; skey[2] = skey[1]; } skey[1] = skey[0]; skey[0] = NULL; err = openpgp_oid_from_str (oidstr, skey + 0); if (err) goto leave; /* Fixup the NPKEY and NSKEY to match OpenPGP reality. */ npkey = 2 + is_ecdh; nskey = 3 + is_ecdh; /* for (idx=0; skey[idx]; idx++) */ /* { */ /* log_info ("YYY skey[%d]:", idx); */ /* if (gcry_mpi_get_flag (skey[idx], GCRYMPI_FLAG_OPAQUE)) */ /* { */ /* void *p; */ /* unsigned int nbits; */ /* p = gcry_mpi_get_opaque (skey[idx], &nbits); */ /* log_printhex (NULL, p, (nbits+7)/8); */ /* } */ /* else */ /* gcry_mpi_dump (skey[idx]); */ /* log_printf ("\n"); */ /* } */ } /* Do some sanity checks. */ if (s2k_count > 255) { /* We expect an already encoded S2K count. */ err = gpg_error (GPG_ERR_INV_DATA); goto leave; } err = openpgp_cipher_test_algo (protect_algo); if (err) goto leave; err = openpgp_md_test_algo (s2k_algo); if (err) goto leave; /* Check that the public key parameters match. Note that since Libgcrypt 1.5 gcry_mpi_cmp handles opaque MPI correctly. */ for (idx=0; idx < npkey; idx++) if (gcry_mpi_cmp (pk->pkey[idx], skey[idx])) { err = gpg_error (GPG_ERR_BAD_PUBKEY); goto leave; } /* Check that the first secret key parameter in SKEY is encrypted and that there are no more secret key parameters. The latter is guaranteed by the v4 packet format. */ if (!gcry_mpi_get_flag (skey[npkey], GCRYMPI_FLAG_USER1)) goto bad_seckey; if (npkey+1 < DIM (skey) && skey[npkey+1]) goto bad_seckey; /* Check that the secret key parameters in PK are all set to NULL. */ for (idx=npkey; idx < nskey; idx++) if (pk->pkey[idx]) goto bad_seckey; /* Now build the protection info. */ pk->seckey_info = ski = xtrycalloc (1, sizeof *ski); if (!ski) { err = gpg_error_from_syserror (); goto leave; } ski->is_protected = 1; ski->sha1chk = 1; ski->algo = protect_algo; ski->s2k.mode = s2k_mode; ski->s2k.hash_algo = s2k_algo; log_assert (sizeof ski->s2k.salt == sizeof s2k_salt); memcpy (ski->s2k.salt, s2k_salt, sizeof s2k_salt); ski->s2k.count = s2k_count; log_assert (ivlen <= sizeof ski->iv); memcpy (ski->iv, iv, ivlen); ski->ivlen = ivlen; /* Store the protected secret key parameter. */ pk->pkey[npkey] = skey[npkey]; skey[npkey] = NULL; /* That's it. */ leave: gcry_free (curve); gcry_sexp_release (list); gcry_sexp_release (top_list); for (idx=0; idx < skeyidx; idx++) gcry_mpi_release (skey[idx]); return err; bad_seckey: err = gpg_error (GPG_ERR_BAD_SECKEY); goto leave; outofmem: err = gpg_error (GPG_ERR_ENOMEM); goto leave; } /* Print an "EXPORTED" status line. PK is the primary public key. */ static void print_status_exported (PKT_public_key *pk) { char *hexfpr; if (!is_status_enabled ()) return; hexfpr = hexfingerprint (pk, NULL, 0); write_status_text (STATUS_EXPORTED, hexfpr? hexfpr : "[?]"); xfree (hexfpr); } /* * Receive a secret key from agent specified by HEXGRIP. * * Since the key data from the agent is encrypted, decrypt it using * CIPHERHD context. Then, parse the decrypted key data into transfer * format, and put secret parameters into PK. * * If CLEARTEXT is 0, store the secret key material * passphrase-protected. Otherwise, store secret key material in the * clear. * * CACHE_NONCE_ADDR is used to share nonce for multiple key retrievals. + * + * If PK is NULL, the raw key is returned (e.g. for ssh export) at + * R_KEY. CLEARTEXT and CACHE_NONCE_ADDR ared ignored in this case. */ gpg_error_t receive_seckey_from_agent (ctrl_t ctrl, gcry_cipher_hd_t cipherhd, int cleartext, char **cache_nonce_addr, const char *hexgrip, - PKT_public_key *pk) + PKT_public_key *pk, gcry_sexp_t *r_key) { gpg_error_t err = 0; unsigned char *wrappedkey = NULL; size_t wrappedkeylen; unsigned char *key = NULL; size_t keylen, realkeylen; - gcry_sexp_t s_skey; + gcry_sexp_t s_skey = NULL; char *prompt; + if (r_key) + *r_key = NULL; if (opt.verbose) log_info ("key %s: asking agent for the secret parts\n", hexgrip); - prompt = gpg_format_keydesc (ctrl, pk, FORMAT_KEYDESC_EXPORT,1); - err = agent_export_key (ctrl, hexgrip, prompt, !cleartext, cache_nonce_addr, - &wrappedkey, &wrappedkeylen, - pk->keyid, pk->main_keyid, pk->pubkey_algo); + if (pk) + { + prompt = gpg_format_keydesc (ctrl, pk, FORMAT_KEYDESC_EXPORT, 1); + err = agent_export_key (ctrl, hexgrip, prompt, !cleartext, + cache_nonce_addr, + &wrappedkey, &wrappedkeylen, + pk->keyid, pk->main_keyid, pk->pubkey_algo); + } + else + { + prompt = gpg_format_keydesc (ctrl, NULL, FORMAT_KEYDESC_KEYGRIP, 1); + err = agent_export_key (ctrl, hexgrip, prompt, 0, + NULL, + &wrappedkey, &wrappedkeylen, + NULL, NULL, 0); + } xfree (prompt); if (err) goto unwraperror; if (wrappedkeylen < 24) { err = gpg_error (GPG_ERR_INV_LENGTH); goto unwraperror; } keylen = wrappedkeylen - 8; key = xtrymalloc_secure (keylen); if (!key) { err = gpg_error_from_syserror (); goto unwraperror; } err = gcry_cipher_decrypt (cipherhd, key, keylen, wrappedkey, wrappedkeylen); if (err) goto unwraperror; realkeylen = gcry_sexp_canon_len (key, keylen, NULL, &err); if (!realkeylen) goto unwraperror; /* Invalid csexp. */ err = gcry_sexp_sscan (&s_skey, NULL, key, realkeylen); if (!err) { - if (cleartext) + if (pk && cleartext) err = cleartext_secret_key_to_openpgp (s_skey, pk); - else + else if (pk) err = transfer_format_to_openpgp (s_skey, pk); - gcry_sexp_release (s_skey); + else if (r_key) + { + *r_key = s_skey; + s_skey = NULL; + } } unwraperror: + gcry_sexp_release (s_skey); xfree (key); xfree (wrappedkey); if (err) { log_error ("key %s: error receiving key from agent:" " %s%s\n", hexgrip, gpg_strerror (err), gpg_err_code (err) == GPG_ERR_FULLY_CANCELED? "":_(" - skipped")); } return err; } /* Write KEYBLOCK either to stdout or to the file set with the * --output option. This is a simplified version of do_export_stream * which supports only a few export options. */ gpg_error_t write_keyblock_to_output (kbnode_t keyblock, int with_armor, unsigned int options) { gpg_error_t err; const char *fname; iobuf_t out; kbnode_t node; armor_filter_context_t *afx = NULL; iobuf_t out_help = NULL; PKT_public_key *pk = NULL; fname = opt.outfile? opt.outfile : "-"; if (is_secured_filename (fname) ) return gpg_error (GPG_ERR_EPERM); out = iobuf_create (fname, 0); if (!out) { err = gpg_error_from_syserror (); log_error(_("can't create '%s': %s\n"), fname, gpg_strerror (err)); return err; } if (opt.verbose) log_info (_("writing to '%s'\n"), iobuf_get_fname_nonnull (out)); if ((options & EXPORT_DANE_FORMAT)) { with_armor = 0; out_help = iobuf_temp (); } if (with_armor) { afx = new_armor_context (); afx->what = 1; push_armor_filter (afx, out); } for (node = keyblock; node; node = node->next) { if (is_deleted_kbnode (node)) continue; if (node->pkt->pkttype == PKT_RING_TRUST) continue; /* Skip - they should not be here anyway. */ if (!pk && (node->pkt->pkttype == PKT_PUBLIC_KEY || node->pkt->pkttype == PKT_SECRET_KEY)) pk = node->pkt->pkt.public_key; if ((options & EXPORT_BACKUP)) err = build_packet_and_meta (out_help? out_help : out, node->pkt); else err = build_packet (out_help? out_help : out, node->pkt); if (err) { log_error ("build_packet(%d) failed: %s\n", node->pkt->pkttype, gpg_strerror (err) ); goto leave; } } err = 0; if (out_help && pk && (options & EXPORT_DANE_FORMAT)) { const void *data; size_t datalen; iobuf_flush_temp (out_help); data = iobuf_get_temp_buffer (out_help); datalen = iobuf_get_temp_length (out_help); err = print_dane_records (out, keyblock, pk, data, datalen); } leave: if (err) iobuf_cancel (out); else iobuf_close (out); iobuf_cancel (out_help); release_armor_context (afx); return err; } /* * Apply the keep-uid filter to the keyblock. The deleted nodes are * marked and thus the caller should call commit_kbnode afterwards. * KEYBLOCK must not have any blocks marked as deleted. */ static void apply_keep_uid_filter (ctrl_t ctrl, kbnode_t keyblock, recsel_expr_t selector) { kbnode_t node; struct impex_filter_parm_s parm; parm.ctrl = ctrl; for (node = keyblock->next; node; node = node->next ) { if (node->pkt->pkttype == PKT_USER_ID) { parm.node = node; if (!recsel_select (selector, impex_filter_getval, &parm)) { /* log_debug ("keep-uid: deleting '%s'\n", */ /* node->pkt->pkt.user_id->name); */ /* The UID packet and all following packets up to the * next UID or a subkey. */ delete_kbnode (node); for (; node->next && node->next->pkt->pkttype != PKT_USER_ID && node->next->pkt->pkttype != PKT_PUBLIC_SUBKEY && node->next->pkt->pkttype != PKT_SECRET_SUBKEY ; node = node->next) delete_kbnode (node->next); } /* else */ /* log_debug ("keep-uid: keeping '%s'\n", */ /* node->pkt->pkt.user_id->name); */ } } } /* * Apply the drop-subkey filter to the keyblock. The deleted nodes are * marked and thus the caller should call commit_kbnode afterwards. * KEYBLOCK must not have any blocks marked as deleted. */ static void apply_drop_subkey_filter (ctrl_t ctrl, kbnode_t keyblock, recsel_expr_t selector) { kbnode_t node; struct impex_filter_parm_s parm; parm.ctrl = ctrl; for (node = keyblock->next; node; node = node->next ) { if (node->pkt->pkttype == PKT_PUBLIC_SUBKEY || node->pkt->pkttype == PKT_SECRET_SUBKEY) { parm.node = node; if (recsel_select (selector, impex_filter_getval, &parm)) { /*log_debug ("drop-subkey: deleting a key\n");*/ /* The subkey packet and all following packets up to the * next subkey. */ delete_kbnode (node); for (; node->next && node->next->pkt->pkttype != PKT_PUBLIC_SUBKEY && node->next->pkt->pkttype != PKT_SECRET_SUBKEY ; node = node->next) delete_kbnode (node->next); } } } } /* Print DANErecords for all user IDs in KEYBLOCK to OUT. The data * for the record is taken from (DATA,DATELEN). PK is the public key * packet with the primary key. */ static gpg_error_t print_dane_records (iobuf_t out, kbnode_t keyblock, PKT_public_key *pk, const void *data, size_t datalen) { gpg_error_t err = 0; kbnode_t kbctx, node; PKT_user_id *uid; char *mbox = NULL; char hashbuf[32]; char *hash = NULL; char *domain; const char *s; unsigned int len; estream_t fp = NULL; char *hexdata = NULL; char *hexfpr; hexfpr = hexfingerprint (pk, NULL, 0); if (!hexfpr) { err = gpg_error_from_syserror (); goto leave; } hexdata = bin2hex (data, datalen, NULL); if (!hexdata) { err = gpg_error_from_syserror (); goto leave; } ascii_strlwr (hexdata); fp = es_fopenmem (0, "rw,samethread"); if (!fp) { err = gpg_error_from_syserror (); goto leave; } for (kbctx = NULL; (node = walk_kbnode (keyblock, &kbctx, 0));) { if (node->pkt->pkttype != PKT_USER_ID) continue; uid = node->pkt->pkt.user_id; if (uid->flags.expired || uid->flags.revoked) continue; xfree (mbox); mbox = mailbox_from_userid (uid->name, 0); if (!mbox) continue; domain = strchr (mbox, '@'); *domain++ = 0; if (1) { es_fprintf (fp, "$ORIGIN _openpgpkey.%s.\n; %s\n; ", domain, hexfpr); print_utf8_buffer (fp, uid->name, uid->len); es_putc ('\n', fp); gcry_md_hash_buffer (GCRY_MD_SHA256, hashbuf, mbox, strlen (mbox)); xfree (hash); hash = bin2hex (hashbuf, 28, NULL); if (!hash) { err = gpg_error_from_syserror (); goto leave; } ascii_strlwr (hash); len = strlen (hexdata)/2; es_fprintf (fp, "%s TYPE61 \\# %u (\n", hash, len); for (s = hexdata; ;) { es_fprintf (fp, "\t%.64s\n", s); if (strlen (s) < 64) break; s += 64; } es_fputs ("\t)\n\n", fp); } } /* Make sure it is a string and write it. */ es_fputc (0, fp); { void *vp; if (es_fclose_snatch (fp, &vp, NULL)) { err = gpg_error_from_syserror (); goto leave; } fp = NULL; iobuf_writestr (out, vp); es_free (vp); } err = 0; leave: xfree (hash); xfree (mbox); es_fclose (fp); xfree (hexdata); xfree (hexfpr); return err; } /* Helper for do_export_stream which writes one keyblock to OUT. */ static gpg_error_t do_export_one_keyblock (ctrl_t ctrl, kbnode_t keyblock, u32 *keyid, iobuf_t out, int secret, unsigned int options, export_stats_t stats, int *any, KEYDB_SEARCH_DESC *desc, size_t ndesc, size_t descindex, gcry_cipher_hd_t cipherhd) { gpg_error_t err = gpg_error (GPG_ERR_NOT_FOUND); char *cache_nonce = NULL; subkey_list_t subkey_list = NULL; /* Track already processed subkeys. */ int skip_until_subkey = 0; int cleartext = 0; char *hexgrip = NULL; char *serialno = NULL; PKT_public_key *pk; u32 subkidbuf[2], *subkid; kbnode_t kbctx, node; /* NB: walk_kbnode skips packets marked as deleted. */ for (kbctx=NULL; (node = walk_kbnode (keyblock, &kbctx, 0)); ) { if (skip_until_subkey) { if (node->pkt->pkttype == PKT_PUBLIC_SUBKEY) skip_until_subkey = 0; else continue; } /* We used to use comment packets, but not any longer. In * case we still have comments on a key, strip them here * before we call build_packet(). */ if (node->pkt->pkttype == PKT_COMMENT) continue; /* Skip ring trust packets - they should not be here anyway. */ if (node->pkt->pkttype == PKT_RING_TRUST) continue; /* If exact is set, then we only export what was requested * (plus the primary key, if the user didn't specifically * request it). */ if (desc[descindex].exact && node->pkt->pkttype == PKT_PUBLIC_SUBKEY) { if (!exact_subkey_match_p (desc+descindex, node)) { /* Before skipping this subkey, check whether any * other description wants an exact match on a * subkey and include that subkey into the output * too. Need to add this subkey to a list so that * it won't get processed a second time. * * So the first step here is to check that list and * skip in any case if the key is in that list. * * We need this whole mess because the import * function of GnuPG < 2.1 is not able to merge * secret keys and thus it is useless to output them * as two separate keys and have import merge them. */ if (subkey_in_list_p (subkey_list, node)) skip_until_subkey = 1; /* Already processed this one. */ else { size_t j; for (j=0; j < ndesc; j++) if (j != descindex && desc[j].exact && exact_subkey_match_p (desc+j, node)) break; if (!(j < ndesc)) skip_until_subkey = 1; /* No other one matching. */ } } if (skip_until_subkey) continue; /* Mark this one as processed. */ { subkey_list_t tmp = new_subkey_list_item (node); tmp->next = subkey_list; subkey_list = tmp; } } if (node->pkt->pkttype == PKT_SIGNATURE) { /* Do not export packets which are marked as not * exportable. */ if (!(options & EXPORT_LOCAL_SIGS) && !node->pkt->pkt.signature->flags.exportable) continue; /* not exportable */ /* Do not export packets with a "sensitive" revocation key * unless the user wants us to. Note that we do export * these when issuing the actual revocation (see revoke.c). */ if (!(options & EXPORT_SENSITIVE_REVKEYS) && node->pkt->pkt.signature->revkey) { int i; for (i = 0; i < node->pkt->pkt.signature->numrevkeys; i++) if ((node->pkt->pkt.signature->revkey[i].class & 0x40)) break; if (i < node->pkt->pkt.signature->numrevkeys) continue; } } /* Don't export attribs? */ if (!(options & EXPORT_ATTRIBUTES) && node->pkt->pkttype == PKT_USER_ID && node->pkt->pkt.user_id->attrib_data) { /* Skip until we get to something that is not an attrib or a * signature on an attrib. */ while (kbctx->next && kbctx->next->pkt->pkttype == PKT_SIGNATURE) kbctx = kbctx->next; continue; } if (secret && (node->pkt->pkttype == PKT_PUBLIC_KEY || node->pkt->pkttype == PKT_PUBLIC_SUBKEY)) { pk = node->pkt->pkt.public_key; if (node->pkt->pkttype == PKT_PUBLIC_KEY) subkid = NULL; else { keyid_from_pk (pk, subkidbuf); subkid = subkidbuf; } if (pk->seckey_info) { log_error ("key %s: oops: seckey_info already set" " - skipped\n", keystr_with_sub (keyid, subkid)); skip_until_subkey = 1; continue; } xfree (hexgrip); err = hexkeygrip_from_pk (pk, &hexgrip); if (err) { log_error ("key %s: error computing keygrip: %s" " - skipped\n", keystr_with_sub (keyid, subkid), gpg_strerror (err)); skip_until_subkey = 1; err = 0; continue; } xfree (serialno); serialno = NULL; if (secret == 2 && node->pkt->pkttype == PKT_PUBLIC_KEY) { /* We are asked not to export the secret parts of the * primary key. Make up an error code to create the * stub. */ err = GPG_ERR_NOT_FOUND; } else err = agent_get_keyinfo (ctrl, hexgrip, &serialno, &cleartext); if ((!err && serialno) && secret == 2 && node->pkt->pkttype == PKT_PUBLIC_KEY) { /* It does not make sense to export a key with its * primary key on card using a non-key stub. Thus we * skip those keys when used with --export-secret-subkeys. */ log_info (_("key %s: key material on-card - skipped\n"), keystr_with_sub (keyid, subkid)); skip_until_subkey = 1; } else if (gpg_err_code (err) == GPG_ERR_NOT_FOUND || (!err && serialno)) { /* Create a key stub. */ struct seckey_info *ski; const char *s; pk->seckey_info = ski = xtrycalloc (1, sizeof *ski); if (!ski) { err = gpg_error_from_syserror (); goto leave; } ski->is_protected = 1; if (err) ski->s2k.mode = 1001; /* GNU dummy (no secret key). */ else { ski->s2k.mode = 1002; /* GNU-divert-to-card. */ for (s=serialno; sizeof (ski->ivlen) && *s && s[1]; ski->ivlen++, s += 2) ski->iv[ski->ivlen] = xtoi_2 (s); } if ((options & EXPORT_BACKUP)) err = build_packet_and_meta (out, node->pkt); else err = build_packet (out, node->pkt); if (!err && node->pkt->pkttype == PKT_PUBLIC_KEY) { stats->exported++; print_status_exported (node->pkt->pkt.public_key); } } else if (!err) { err = receive_seckey_from_agent (ctrl, cipherhd, cleartext, &cache_nonce, - hexgrip, pk); + hexgrip, pk, NULL); if (err) { if (gpg_err_code (err) == GPG_ERR_FULLY_CANCELED) goto leave; write_status_error ("export_keys.secret", err); skip_until_subkey = 1; err = 0; } else { if ((options & EXPORT_BACKUP)) err = build_packet_and_meta (out, node->pkt); else err = build_packet (out, node->pkt); if (node->pkt->pkttype == PKT_PUBLIC_KEY) { stats->exported++; print_status_exported (node->pkt->pkt.public_key); } } } else { log_error ("key %s: error getting keyinfo from agent: %s" " - skipped\n", keystr_with_sub (keyid, subkid), gpg_strerror (err)); skip_until_subkey = 1; err = 0; } xfree (pk->seckey_info); pk->seckey_info = NULL; { int i; for (i = pubkey_get_npkey (pk->pubkey_algo); i < pubkey_get_nskey (pk->pubkey_algo); i++) { gcry_mpi_release (pk->pkey[i]); pk->pkey[i] = NULL; } } } else /* Not secret or common packets. */ { if ((options & EXPORT_BACKUP)) err = build_packet_and_meta (out, node->pkt); else err = build_packet (out, node->pkt); if (!err && node->pkt->pkttype == PKT_PUBLIC_KEY) { stats->exported++; print_status_exported (node->pkt->pkt.public_key); } } if (err) { log_error ("build_packet(%d) failed: %s\n", node->pkt->pkttype, gpg_strerror (err)); goto leave; } if (!skip_until_subkey) *any = 1; } leave: release_subkey_list (subkey_list); xfree (serialno); xfree (hexgrip); xfree (cache_nonce); return err; } /* Helper for do_export_stream which writes the own revocations * certificates (if any) from KEYBLOCK to OUT. */ static gpg_error_t do_export_revocs (ctrl_t ctrl, kbnode_t keyblock, u32 *keyid, iobuf_t out, unsigned int options, int *any) { gpg_error_t err = 0; kbnode_t kbctx, node; PKT_signature *sig; (void)ctrl; /* NB: walk_kbnode skips packets marked as deleted. */ for (kbctx=NULL; (node = walk_kbnode (keyblock, &kbctx, 0)); ) { if (node->pkt->pkttype != PKT_SIGNATURE) continue; sig = node->pkt->pkt.signature; /* We are only interested in revocation certifcates. */ if (!(IS_KEY_REV (sig) || IS_UID_REV (sig) || IS_SUBKEY_REV (sig))) continue; if (!(sig->keyid[0] == keyid[0] && sig->keyid[1] == keyid[1])) continue; /* Not a self-signature. */ /* Do not export signature packets which are marked as not * exportable. */ if (!(options & EXPORT_LOCAL_SIGS) && !sig->flags.exportable) continue; /* not exportable */ /* Do not export packets with a "sensitive" revocation key * unless the user wants us to. */ if (!(options & EXPORT_SENSITIVE_REVKEYS) && sig->revkey) { int i; for (i = 0; i < sig->numrevkeys; i++) if ((sig->revkey[i].class & 0x40)) break; if (i < sig->numrevkeys) continue; } if (!sig->flags.checked) { log_info ("signature not marked as checked - ignored\n"); continue; } if (!sig->flags.valid) { log_info ("signature not not valid - ignored\n"); continue; } err = build_packet (out, node->pkt); if (err) { log_error ("build_packet(%d) failed: %s\n", node->pkt->pkttype, gpg_strerror (err)); goto leave; } *any = 1; } leave: return err; } /* For secret key export we need to setup a decryption context. * Returns 0 and the context at r_cipherhd. */ static gpg_error_t get_keywrap_key (ctrl_t ctrl, gcry_cipher_hd_t *r_cipherhd) { #ifdef ENABLE_SELINUX_HACKS (void)ctrl; *r_cipherhd = NULL; log_error (_("exporting secret keys not allowed\n")); return gpg_error (GPG_ERR_NOT_SUPPORTED); #else gpg_error_t err; void *kek = NULL; size_t keklen; gcry_cipher_hd_t cipherhd; *r_cipherhd = NULL; err = agent_keywrap_key (ctrl, 1, &kek, &keklen); if (err) { log_error ("error getting the KEK: %s\n", gpg_strerror (err)); return err; } err = gcry_cipher_open (&cipherhd, GCRY_CIPHER_AES128, GCRY_CIPHER_MODE_AESWRAP, 0); if (!err) err = gcry_cipher_setkey (cipherhd, kek, keklen); if (err) log_error ("error setting up an encryption context: %s\n", gpg_strerror (err)); if (!err) *r_cipherhd = cipherhd; else gcry_cipher_close (cipherhd); xfree (kek); return err; #endif } /* Export the keys identified by the list of strings in USERS to the stream OUT. If SECRET is false public keys will be exported. With secret true secret keys will be exported; in this case 1 means the entire secret keyblock and 2 only the subkeys. OPTIONS are the export options to apply. If KEYBLOCK_OUT is not NULL, AND the exit code is zero, a pointer to the first keyblock found and exported will be stored at this address; no other keyblocks are exported in this case. The caller must free the returned keyblock. If any key has been exported true is stored at ANY. */ static int do_export_stream (ctrl_t ctrl, iobuf_t out, strlist_t users, int secret, kbnode_t *keyblock_out, unsigned int options, export_stats_t stats, int *any) { gpg_error_t err = 0; PACKET pkt; kbnode_t keyblock = NULL; kbnode_t node; size_t ndesc, descindex; KEYDB_SEARCH_DESC *desc = NULL; KEYDB_HANDLE kdbhd; strlist_t sl; gcry_cipher_hd_t cipherhd = NULL; struct export_stats_s dummystats; iobuf_t out_help = NULL; if (!stats) stats = &dummystats; *any = 0; init_packet (&pkt); kdbhd = keydb_new (ctrl); if (!kdbhd) return gpg_error_from_syserror (); /* For the DANE format open a helper iobuf and * enforce some options. */ if ((options & EXPORT_DANE_FORMAT)) { out_help = iobuf_temp (); options |= EXPORT_MINIMAL | EXPORT_CLEAN; } if (!users) { ndesc = 1; desc = xcalloc (ndesc, sizeof *desc); desc[0].mode = KEYDB_SEARCH_MODE_FIRST; } else { for (ndesc=0, sl=users; sl; sl = sl->next, ndesc++) ; desc = xmalloc ( ndesc * sizeof *desc); for (ndesc=0, sl=users; sl; sl = sl->next) { if (!(err=classify_user_id (sl->d, desc+ndesc, 1))) ndesc++; else log_error (_("key \"%s\" not found: %s\n"), sl->d, gpg_strerror (err)); } keydb_disable_caching (kdbhd); /* We are looping the search. */ /* It would be nice to see which of the given users did actually match one in the keyring. To implement this we need to have a found flag for each entry in desc. To set this flag we must check all those entries after a match to mark all matched one - currently we stop at the first match. To do this we need an extra flag to enable this feature. */ } /* For secret key export we need to setup a decryption context. */ if (secret && (err = get_keywrap_key (ctrl, &cipherhd))) goto leave; for (;;) { u32 keyid[2]; PKT_public_key *pk; err = keydb_search (kdbhd, desc, ndesc, &descindex); if (!users) desc[0].mode = KEYDB_SEARCH_MODE_NEXT; if (err) break; /* Read the keyblock. */ release_kbnode (keyblock); keyblock = NULL; err = keydb_get_keyblock (kdbhd, &keyblock); if (err) { log_error (_("error reading keyblock: %s\n"), gpg_strerror (err)); goto leave; } node = find_kbnode (keyblock, PKT_PUBLIC_KEY); if (!node) { log_error ("public key packet not found in keyblock - skipped\n"); continue; } stats->count++; setup_main_keyids (keyblock); /* gpg_format_keydesc needs it. */ pk = node->pkt->pkt.public_key; keyid_from_pk (pk, keyid); /* If a secret key export is required we need to check whether we have a secret key at all and if so create the seckey_info structure. */ if (secret) { if (agent_probe_any_secret_key (ctrl, keyblock)) continue; /* No secret key (neither primary nor subkey). */ /* No v3 keys with GNU mode 1001. */ if (secret == 2 && pk->version == 3) { log_info (_("key %s: PGP 2.x style key - skipped\n"), keystr (keyid)); continue; } /* The agent does not yet allow export of v3 packets. It is actually questionable whether we should allow them at all. */ if (pk->version == 3) { log_info ("key %s: PGP 2.x style key (v3) export " "not yet supported - skipped\n", keystr (keyid)); continue; } stats->secret_count++; } /* Always do the cleaning on the public key part if requested. * A designated revocation is never stripped, even with * export-minimal set. */ if ((options & EXPORT_CLEAN)) { merge_keys_and_selfsig (ctrl, keyblock); clean_all_uids (ctrl, keyblock, opt.verbose, (options&EXPORT_MINIMAL), NULL, NULL); clean_all_subkeys (ctrl, keyblock, opt.verbose, (options&EXPORT_MINIMAL)? KEY_CLEAN_ALL /**/ : KEY_CLEAN_AUTHENCR, NULL, NULL); commit_kbnode (&keyblock); } else if (export_keep_uid || export_drop_subkey || export_select_filter) { /* Need to merge so that for example the "usage" property * has been setup. */ merge_keys_and_selfsig (ctrl, keyblock); } if (export_select_filter) { int selected = 0; struct impex_filter_parm_s parm; parm.ctrl = ctrl; for (parm.node = keyblock; parm.node; parm.node = parm.node->next) { if (recsel_select (export_select_filter, impex_filter_getval, &parm)) { selected = 1; break; } } if (!selected) continue; /* Skip this keyblock. */ } if (export_keep_uid) { commit_kbnode (&keyblock); apply_keep_uid_filter (ctrl, keyblock, export_keep_uid); commit_kbnode (&keyblock); } if (export_drop_subkey) { commit_kbnode (&keyblock); apply_drop_subkey_filter (ctrl, keyblock, export_drop_subkey); commit_kbnode (&keyblock); } /* And write it. */ if ((options & EXPORT_REVOCS)) err = do_export_revocs (ctrl, keyblock, keyid, out_help? out_help : out, options, any); else err = do_export_one_keyblock (ctrl, keyblock, keyid, out_help? out_help : out, secret, options, stats, any, desc, ndesc, descindex, cipherhd); if (err) break; if (keyblock_out) { *keyblock_out = keyblock; break; } if (out_help && (options & EXPORT_DANE_FORMAT)) { /* We want to write DANE records. OUT_HELP has the * keyblock and we print a record for each uid to OUT. */ const void *data; size_t datalen; iobuf_flush_temp (out_help); data = iobuf_get_temp_buffer (out_help); datalen = iobuf_get_temp_length (out_help); err = print_dane_records (out, keyblock, pk, data, datalen); if (err) goto leave; iobuf_close (out_help); out_help = iobuf_temp (); } } if (gpg_err_code (err) == GPG_ERR_NOT_FOUND) err = 0; leave: iobuf_cancel (out_help); gcry_cipher_close (cipherhd); xfree(desc); keydb_release (kdbhd); if (err || !keyblock_out) release_kbnode( keyblock ); if( !*any ) log_info(_("WARNING: nothing exported\n")); return err; } /* Write the uint32 VALUE to MB in networ byte order. */ static void mb_write_uint32 (membuf_t *mb, u32 value) { unsigned char buffer[4]; ulongtobuf (buffer, (ulong)value); put_membuf (mb, buffer, 4); } /* Write the byte C to MB. */ static void mb_write_uint8 (membuf_t *mb, int c) { unsigned char buf[1]; buf[0] = c; put_membuf (mb, buf, 1); } /* Simple wrapper around put_membuf. */ static void mb_write_data (membuf_t *mb, const void *data, size_t datalen) { put_membuf (mb, data, datalen); } /* Write STRING with terminating Nul to MB. */ static void mb_write_cstring (membuf_t *mb, const char *string) { put_membuf (mb, string, strlen (string)+1); } /* Write an SSH style string to MB. */ static void mb_write_string (membuf_t *mb, const void *string, size_t n) { mb_write_uint32 (mb, (u32)n); mb_write_data (mb, string, n); } /* Write an MPI as SSH style string to MB */ static void mb_write_mpi (membuf_t *mb, gcry_mpi_t mpi, int strip_prefix) { unsigned int nbits; const unsigned char *p; size_t n; if (gcry_mpi_get_flag (mpi, GCRYMPI_FLAG_OPAQUE)) { p = gcry_mpi_get_opaque (mpi, &nbits); n = (nbits + 7) / 8; if (strip_prefix && n > 1 && p[0] == 0x40) { /* We need to strip our 0x40 prefix. */ p++; n--; } mb_write_string (mb, p, n); } else { gpg_error_t err; unsigned char *buf; err = gcry_mpi_aprint (GCRYMPI_FMT_SSH, &buf, &n, mpi); if (err) set_membuf_err (mb, err); else { mb_write_data (mb, buf, n); gcry_free (buf); } } } static gpg_error_t key_to_sshblob (membuf_t *mb, const char *identifier, ...) { va_list arg_ptr; gpg_error_t err = 0; unsigned char nbuf[4]; unsigned char *buf; size_t buflen; gcry_mpi_t a; buflen = strlen (identifier); ulongtobuf (nbuf, (ulong)buflen); put_membuf (mb, nbuf, 4); put_membuf (mb, identifier, buflen); if (buflen > 11 && !memcmp (identifier, "ecdsa-sha2-", 11)) { /* Store the name of the curve taken from the identifier. */ ulongtobuf (nbuf, (ulong)(buflen - 11)); put_membuf (mb, nbuf, 4); put_membuf (mb, identifier+11, buflen - 11); } va_start (arg_ptr, identifier); while ((a = va_arg (arg_ptr, gcry_mpi_t))) { if (gcry_mpi_get_flag (a, GCRYMPI_FLAG_OPAQUE)) { unsigned int nbits; const unsigned char *p; p = gcry_mpi_get_opaque (a, &nbits); buflen = (nbits + 7) / 8; if (!strcmp (identifier, "ssh-ed25519") && buflen > 1 && p[0] == 0x40) { /* We need to strip our 0x40 prefix. */ put_membuf (mb, "\x00\x00\x00\x20", 4); put_membuf (mb, p+1, buflen-1); } else { unsigned char c; c = buflen >> 24; put_membuf (mb, &c, 1); c = buflen >> 16; put_membuf (mb, &c, 1); c = buflen >> 8; put_membuf (mb, &c, 1); c = buflen; put_membuf (mb, &c, 1); put_membuf (mb, p, buflen); } } else { err = gcry_mpi_aprint (GCRYMPI_FMT_SSH, &buf, &buflen, a); if (err) break; put_membuf (mb, buf, buflen); gcry_free (buf); } } va_end (arg_ptr); return err; } static gpg_error_t export_one_ssh_key (estream_t fp, PKT_public_key *pk) { gpg_error_t err; const char *identifier = NULL; membuf_t mb; void *blob; size_t bloblen; init_membuf (&mb, 4096); switch (pk->pubkey_algo) { case PUBKEY_ALGO_DSA: identifier = "ssh-dss"; err = key_to_sshblob (&mb, identifier, pk->pkey[0], pk->pkey[1], pk->pkey[2], pk->pkey[3], NULL); break; case PUBKEY_ALGO_RSA: case PUBKEY_ALGO_RSA_S: identifier = "ssh-rsa"; err = key_to_sshblob (&mb, identifier, pk->pkey[1], pk->pkey[0], NULL); break; case PUBKEY_ALGO_ECDSA: { char *curveoid; const char *curve; curveoid = openpgp_oid_to_str (pk->pkey[0]); if (!curveoid) err = gpg_error_from_syserror (); else if (!(curve = openpgp_oid_to_curve (curveoid, 0))) err = gpg_error (GPG_ERR_UNKNOWN_CURVE); else { if (!strcmp (curve, "nistp256")) identifier = "ecdsa-sha2-nistp256"; else if (!strcmp (curve, "nistp384")) identifier = "ecdsa-sha2-nistp384"; else if (!strcmp (curve, "nistp521")) identifier = "ecdsa-sha2-nistp521"; if (!identifier) err = gpg_error (GPG_ERR_UNKNOWN_CURVE); else err = key_to_sshblob (&mb, identifier, pk->pkey[1], NULL); } xfree (curveoid); } break; case PUBKEY_ALGO_EDDSA: if (openpgp_oid_is_ed25519 (pk->pkey[0])) { identifier = "ssh-ed25519"; err = key_to_sshblob (&mb, identifier, pk->pkey[1], NULL); } else if (openpgp_oid_is_ed448 (pk->pkey[0])) { identifier = "ssh-ed448"; err = key_to_sshblob (&mb, identifier, pk->pkey[1], NULL); } else err = gpg_error (GPG_ERR_UNKNOWN_CURVE); break; case PUBKEY_ALGO_ELGAMAL_E: case PUBKEY_ALGO_ELGAMAL: err = gpg_error (GPG_ERR_UNUSABLE_PUBKEY); break; default: err = GPG_ERR_PUBKEY_ALGO; break; } if (err) goto leave; blob = get_membuf (&mb, &bloblen); if (blob) { struct b64state b64_state; es_fprintf (fp, "%s ", identifier); err = b64enc_start_es (&b64_state, fp, ""); if (err) { xfree (blob); goto leave; } err = b64enc_write (&b64_state, blob, bloblen); b64enc_finish (&b64_state); es_fprintf (fp, " openpgp:0x%08lX\n", (ulong)keyid_from_pk (pk, NULL)); xfree (blob); } leave: xfree (get_membuf (&mb, NULL)); return err; } /* Export the key identified by USERID in the SSH public key format. The function exports the latest subkey with Authentication capability unless the '!' suffix is used to export a specific key. */ gpg_error_t export_ssh_key (ctrl_t ctrl, const char *userid) { gpg_error_t err; kbnode_t keyblock = NULL; KEYDB_SEARCH_DESC desc; u32 latest_date; u32 curtime = make_timestamp (); kbnode_t latest_key, node; PKT_public_key *pk; estream_t fp = NULL; const char *fname = "-"; /* We need to know whether the key has been specified using the exact syntax ('!' suffix). Thus we need to run a classify_user_id on our own. */ err = classify_user_id (userid, &desc, 1); /* Get the public key. */ if (!err) { getkey_ctx_t getkeyctx; err = get_pubkey_byname (ctrl, GET_PUBKEY_NO_AKL, &getkeyctx, NULL, userid, &keyblock, NULL, 0 /* Only usable keys or given exact. */); if (!err) { err = getkey_next (ctrl, getkeyctx, NULL, NULL); if (!err) err = gpg_error (GPG_ERR_AMBIGUOUS_NAME); else if (gpg_err_code (err) == GPG_ERR_NO_PUBKEY) err = 0; } getkey_end (ctrl, getkeyctx); } if (err) { log_error (_("key \"%s\" not found: %s\n"), userid, gpg_strerror (err)); return err; } /* The finish_lookup code in getkey.c does not handle auth keys, thus we have to duplicate the code here to find the latest subkey. However, if the key has been found using an exact match ('!' notation) we use that key without any further checks and even allow the use of the primary key. */ latest_date = 0; latest_key = NULL; for (node = keyblock; node; node = node->next) { if ((node->pkt->pkttype == PKT_PUBLIC_SUBKEY || node->pkt->pkttype == PKT_PUBLIC_KEY) && node->pkt->pkt.public_key->flags.exact) { latest_key = node; break; } } if (!latest_key) { for (node = keyblock; node; node = node->next) { if (node->pkt->pkttype != PKT_PUBLIC_SUBKEY) continue; pk = node->pkt->pkt.public_key; if (DBG_LOOKUP) log_debug ("\tchecking subkey %08lX\n", (ulong) keyid_from_pk (pk, NULL)); if (!(pk->pubkey_usage & PUBKEY_USAGE_AUTH)) { if (DBG_LOOKUP) log_debug ("\tsubkey not usable for authentication\n"); continue; } if (!pk->flags.valid) { if (DBG_LOOKUP) log_debug ("\tsubkey not valid\n"); continue; } if (pk->flags.revoked) { if (DBG_LOOKUP) log_debug ("\tsubkey has been revoked\n"); continue; } if (pk->has_expired) { if (DBG_LOOKUP) log_debug ("\tsubkey has expired\n"); continue; } if (pk->timestamp > curtime && !opt.ignore_valid_from) { if (DBG_LOOKUP) log_debug ("\tsubkey not yet valid\n"); continue; } if (DBG_LOOKUP) log_debug ("\tsubkey might be fine\n"); /* In case a key has a timestamp of 0 set, we make sure that it is used. A better change would be to compare ">=" but that might also change the selected keys and is as such a more intrusive change. */ if (pk->timestamp > latest_date || (!pk->timestamp && !latest_date)) { latest_date = pk->timestamp; latest_key = node; } } /* If no subkey was suitable check the primary key. */ if (!latest_key && (node = keyblock) && node->pkt->pkttype == PKT_PUBLIC_KEY) { pk = node->pkt->pkt.public_key; if (DBG_LOOKUP) log_debug ("\tchecking primary key %08lX\n", (ulong) keyid_from_pk (pk, NULL)); if (!(pk->pubkey_usage & PUBKEY_USAGE_AUTH)) { if (DBG_LOOKUP) log_debug ("\tprimary key not usable for authentication\n"); } else if (!pk->flags.valid) { if (DBG_LOOKUP) log_debug ("\tprimary key not valid\n"); } else if (pk->flags.revoked) { if (DBG_LOOKUP) log_debug ("\tprimary key has been revoked\n"); } else if (pk->has_expired) { if (DBG_LOOKUP) log_debug ("\tprimary key has expired\n"); } else if (pk->timestamp > curtime && !opt.ignore_valid_from) { if (DBG_LOOKUP) log_debug ("\tprimary key not yet valid\n"); } else { if (DBG_LOOKUP) log_debug ("\tprimary key is fine\n"); latest_date = pk->timestamp; latest_key = node; } } } if (!latest_key) { err = gpg_error (GPG_ERR_UNUSABLE_PUBKEY); log_error (_("key \"%s\" not found: %s\n"), userid, gpg_strerror (err)); goto leave; } pk = latest_key->pkt->pkt.public_key; if (DBG_LOOKUP) log_debug ("\tusing key %08lX\n", (ulong) keyid_from_pk (pk, NULL)); if (opt.outfile && *opt.outfile && strcmp (opt.outfile, "-")) fp = es_fopen ((fname = opt.outfile), "w"); else fp = es_stdout; if (!fp) { err = gpg_error_from_syserror (); log_error (_("error creating '%s': %s\n"), fname, gpg_strerror (err)); goto leave; } err = export_one_ssh_key (fp, pk); if (err) goto leave; if (es_ferror (fp)) err = gpg_error_from_syserror (); else { if (fp != es_stdout && es_fclose (fp)) err = gpg_error_from_syserror (); fp = NULL; } if (err) log_error (_("error writing '%s': %s\n"), fname, gpg_strerror (err)); leave: if (fp != es_stdout) es_fclose (fp); release_kbnode (keyblock); return err; } -/* Simplified version of receive_seckey_from_agent used to get the raw - * key. */ -gpg_error_t -receive_raw_seckey_from_agent (ctrl_t ctrl, gcry_cipher_hd_t cipherhd, - const char *hexgrip, gcry_sexp_t *r_key) -{ - gpg_error_t err = 0; - unsigned char *wrappedkey = NULL; - size_t wrappedkeylen; - unsigned char *key = NULL; - size_t keylen, realkeylen; - gcry_sexp_t s_skey = NULL; - - *r_key = NULL; - if (opt.verbose) - log_info ("key %s: asking agent for the secret parts\n", hexgrip); - - { - char * prompt = gpg_format_keydesc (ctrl, NULL, FORMAT_KEYDESC_KEYGRIP, 1); - err = agent_export_key (ctrl, hexgrip, prompt, 0, NULL, - &wrappedkey, &wrappedkeylen, - NULL, NULL, 0); - xfree (prompt); - } - if (err) - goto leave; - - if (wrappedkeylen < 24) - { - err = gpg_error (GPG_ERR_INV_LENGTH); - goto leave; - } - keylen = wrappedkeylen - 8; - key = xtrymalloc_secure (keylen); - if (!key) - { - err = gpg_error_from_syserror (); - goto leave; - } - err = gcry_cipher_decrypt (cipherhd, key, keylen, wrappedkey, wrappedkeylen); - if (err) - goto leave; - realkeylen = gcry_sexp_canon_len (key, keylen, NULL, &err); - if (!realkeylen) - goto leave; /* Invalid csexp. */ - - err = gcry_sexp_sscan (&s_skey, NULL, key, realkeylen); - if (!err) - { - gcry_log_debugsxp ("skey", s_skey); - *r_key = s_skey; - s_skey = NULL; - } - - leave: - gcry_sexp_release (s_skey); - xfree (key); - xfree (wrappedkey); - if (err) - { - log_error ("key %s: error receiving key from agent:" - " %s%s\n", hexgrip, gpg_strerror (err), - ""); - } - return err; -} - - /* Export the key identified by USERID in the SSH secret key format. * The USERID must be given in keygrip format (prefixed with a '&') * and thus no OpenPGP key is required. The exported key is not * protected. */ gpg_error_t export_secret_ssh_key (ctrl_t ctrl, const char *userid) { gpg_error_t err; KEYDB_SEARCH_DESC desc; estream_t fp = NULL; const char *fname = "-"; gcry_cipher_hd_t cipherhd = NULL; char hexgrip[KEYGRIP_LEN * 2 + 1]; gcry_sexp_t skey = NULL; gcry_sexp_t skeyalgo = NULL; const char *identifier = NULL; membuf_t mb; membuf_t mb2; void *blob = NULL; size_t bloblen; const char *s; size_t n; char *p; int pkalgo; int i; gcry_mpi_t keyparam[10] = { NULL }; struct b64state b64_state; init_membuf_secure (&mb, 1024); init_membuf_secure (&mb2, 1024); /* Check that a keygrip has been given. */ err = classify_user_id (userid, &desc, 1); if (err || desc.mode != KEYDB_SEARCH_MODE_KEYGRIP ) { log_error (_("key \"%s\" not found: %s\n"), userid, err? gpg_strerror (err) : "Not a Keygrip" ); return err; } bin2hex (desc.u.grip, KEYGRIP_LEN, hexgrip); if ((err = get_keywrap_key (ctrl, &cipherhd))) goto leave; - err = receive_raw_seckey_from_agent (ctrl, cipherhd, hexgrip, &skey); + err = receive_seckey_from_agent (ctrl, cipherhd, 0, NULL, hexgrip, NULL, + &skey); if (err) goto leave; /* Get the type of the key expression. */ s = gcry_sexp_nth_data (skey, 0, &n); if (!s || !(n == 11 && !memcmp (s, "private-key", 11))) { log_info ("Note: only on-disk secret keys may be exported\n"); err = gpg_error (GPG_ERR_NO_SECKEY); goto leave; } mb_write_cstring (&mb, "openssh-key-v1"); /* Auth_Magic. */ mb_write_string (&mb, "none", 4); /* ciphername */ mb_write_string (&mb, "none", 4); /* kdfname */ mb_write_uint32 (&mb, 0); /* kdfoptions */ mb_write_uint32 (&mb, 1); /* number of keys */ pkalgo = get_pk_algo_from_key (skey); switch (pkalgo) { case PUBKEY_ALGO_RSA: case PUBKEY_ALGO_RSA_S: identifier = "ssh-rsa"; err = gcry_sexp_extract_param (skey, NULL, "nedpq", &keyparam[0], &keyparam[1], &keyparam[2], &keyparam[3], &keyparam[4], NULL); if (err) goto leave; mb_write_string (&mb2, identifier, strlen (identifier)); mb_write_mpi (&mb2, keyparam[1], 0); /* e (right, e is first here) */ mb_write_mpi (&mb2, keyparam[0], 0); /* n */ /* Append public to the output block as an SSH string. */ p = get_membuf (&mb2, &n); if (!p) { err = gpg_error_from_syserror (); goto leave; } mb_write_string (&mb, p, n); xfree (p); init_membuf_secure (&mb2, 1024); mb_write_string (&mb2, identifier, strlen (identifier)); { char checkbytes[4]; gcry_create_nonce (checkbytes, sizeof checkbytes); mb_write_data (&mb2, checkbytes, sizeof checkbytes); mb_write_data (&mb2, checkbytes, sizeof checkbytes); } mb_write_mpi (&mb2, keyparam[0], 0); /* n */ mb_write_mpi (&mb2, keyparam[1], 0); /* e */ /*FIXME: Fixup u,p,q to match the OpenSSH format. */ mb_write_mpi (&mb2, keyparam[2], 0); /* d */ mb_write_mpi (&mb2, keyparam[1], 0); /* iqmp1 */ mb_write_mpi (&mb2, keyparam[3], 0); /* p */ mb_write_mpi (&mb2, keyparam[4], 0); /* q */ /* Fixme: take the comment from skey. */ mb_write_string (&mb2, "", 9); /* Pad to a blocksize of 8 (for cipher "none"). */ i = 0; while (peek_membuf (&mb2, &n) && (n % 8)) mb_write_uint8 (&mb2, ++i); /* Append encrypted block to the output as an SSH string. */ p = get_membuf (&mb2, &n); if (!p) { err = gpg_error_from_syserror (); goto leave; } mb_write_string (&mb, p, n); xfree (p); err = gpg_error (GPG_ERR_NOT_IMPLEMENTED); break; /* case PUBKEY_ALGO_ECDSA: */ /* { */ /* char *curveoid; */ /* const char *curve; */ /* curveoid = openpgp_oid_to_str (pk->pkey[0]); */ /* if (!curveoid) */ /* err = gpg_error_from_syserror (); */ /* else if (!(curve = openpgp_oid_to_curve (curveoid, 0))) */ /* err = gpg_error (GPG_ERR_UNKNOWN_CURVE); */ /* else */ /* { */ /* if (!strcmp (curve, "nistp256")) */ /* identifier = "ecdsa-sha2-nistp256"; */ /* else if (!strcmp (curve, "nistp384")) */ /* identifier = "ecdsa-sha2-nistp384"; */ /* else if (!strcmp (curve, "nistp521")) */ /* identifier = "ecdsa-sha2-nistp521"; */ /* if (!identifier) */ /* err = gpg_error (GPG_ERR_UNKNOWN_CURVE); */ /* else */ /* err = key_to_sshblob (&mb, identifier, pk->pkey[1], NULL); */ /* } */ /* xfree (curveoid); */ /* } */ /* break; */ /* case PUBKEY_ALGO_EDDSA: */ /* if (openpgp_oid_is_ed25519 (pk->pkey[0])) */ /* { */ /* identifier = "ssh-ed25519"; */ /* err = key_to_sshblob (&mb, identifier, pk->pkey[1], NULL); */ /* } */ /* else if (openpgp_oid_is_ed448 (pk->pkey[0])) */ /* { */ /* identifier = "ssh-ed448"; */ /* err = key_to_sshblob (&mb, identifier, pk->pkey[1], NULL); */ /* } */ /* else */ /* err = gpg_error (GPG_ERR_UNKNOWN_CURVE); */ /* break; */ case PUBKEY_ALGO_DSA: log_info ("Note: export of ssh-dsa keys is not supported\n"); err = gpg_error (GPG_ERR_NOT_SUPPORTED); break; case PUBKEY_ALGO_ELGAMAL_E: case PUBKEY_ALGO_ELGAMAL: err = gpg_error (GPG_ERR_UNUSABLE_SECKEY); break; default: err = GPG_ERR_PUBKEY_ALGO; break; } if (err) goto leave; blob = get_membuf (&mb, &bloblen); if (!blob) { err = gpg_error_from_syserror (); goto leave; } if (opt.outfile && *opt.outfile && strcmp (opt.outfile, "-")) fp = es_fopen ((fname = opt.outfile), "w"); else fp = es_stdout; if (!fp) { err = gpg_error_from_syserror (); log_error (_("error creating '%s': %s\n"), fname, gpg_strerror (err)); goto leave; } err = b64enc_start_es (&b64_state, fp, "OPENSSH PRIVATE_KEY"); if (err) goto leave; err = b64enc_write (&b64_state, blob, bloblen); b64enc_finish (&b64_state); if (err) goto leave; if (es_ferror (fp)) err = gpg_error_from_syserror (); else { if (fp != es_stdout && es_fclose (fp)) err = gpg_error_from_syserror (); fp = NULL; } log_info ("Beware: the private key is not protected;" " use \"ssh-keygen -p\" to protect it\n"); if (err) log_error (_("error writing '%s': %s\n"), fname, gpg_strerror (err)); leave: xfree (blob); gcry_sexp_release (skey); gcry_sexp_release (skeyalgo); gcry_cipher_close (cipherhd); xfree (get_membuf (&mb2, NULL)); xfree (get_membuf (&mb, NULL)); if (fp != es_stdout) es_fclose (fp); return err; } diff --git a/g10/keygen.c b/g10/keygen.c index c2f2dcc9d..8e2c092fc 100644 --- a/g10/keygen.c +++ b/g10/keygen.c @@ -1,6207 +1,6207 @@ /* keygen.c - Generate a key pair * Copyright (C) 1998-2007, 2009-2011 Free Software Foundation, Inc. * Copyright (C) 2014, 2015, 2016, 2017, 2018 Werner Koch * Copyright (C) 2020 g10 Code GmbH * * 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 . */ #include #include #include #include #include #include #include #include #include #include "gpg.h" #include "../common/util.h" #include "main.h" #include "packet.h" #include "../common/ttyio.h" #include "options.h" #include "keydb.h" #include "trustdb.h" #include "../common/status.h" #include "../common/i18n.h" #include "keyserver-internal.h" #include "call-agent.h" #include "pkglue.h" #include "../common/shareddefs.h" #include "../common/host2net.h" #include "../common/mbox-util.h" /* The default algorithms. If you change them, you should ensure the value is inside the bounds enforced by ask_keysize and gen_xxx. See also get_keysize_range which encodes the allowed ranges. The default answer in ask_algo also needs to be adjusted. */ #define DEFAULT_STD_KEY_PARAM "ed25519/cert,sign+cv25519/encr" #define FUTURE_STD_KEY_PARAM "ed25519/cert,sign+cv25519/encr" /* When generating keys using the streamlined key generation dialog, use this as a default expiration interval. */ const char *default_expiration_interval = "2y"; /* Flag bits used during key generation. */ #define KEYGEN_FLAG_NO_PROTECTION 1 #define KEYGEN_FLAG_TRANSIENT_KEY 2 #define KEYGEN_FLAG_CREATE_V5_KEY 4 /* Maximum number of supported algorithm preferences. */ #define MAX_PREFS 30 enum para_name { pKEYTYPE, pKEYLENGTH, pKEYCURVE, pKEYUSAGE, pSUBKEYTYPE, pSUBKEYLENGTH, pSUBKEYCURVE, pSUBKEYUSAGE, pAUTHKEYTYPE, pNAMEREAL, pNAMEEMAIL, pNAMECOMMENT, pPREFERENCES, pREVOKER, pUSERID, pCREATIONDATE, pKEYCREATIONDATE, /* Same in seconds since epoch. */ pEXPIREDATE, pKEYEXPIRE, /* in n seconds */ pSUBKEYCREATIONDATE, pSUBKEYEXPIRE, /* in n seconds */ pAUTHKEYCREATIONDATE, /* Not yet used. */ pPASSPHRASE, pSERIALNO, pCARDBACKUPKEY, pHANDLE, pKEYSERVER, pKEYGRIP, pSUBKEYGRIP, pVERSION, /* Desired version of the key packet. */ pSUBVERSION, /* Ditto for the subpacket. */ pCARDKEY /* The keygrips have been taken from active card (bool). */ }; struct para_data_s { struct para_data_s *next; int lnr; enum para_name key; union { u32 expire; u32 creation; int abool; unsigned int usage; struct revocation_key revkey; char value[1]; } u; }; struct output_control_s { int lnr; int dryrun; unsigned int keygen_flags; int use_files; struct { char *fname; char *newfname; IOBUF stream; armor_filter_context_t *afx; } pub; }; struct opaque_data_usage_and_pk { unsigned int usage; PKT_public_key *pk; }; /* FIXME: These globals vars are ugly. And using MAX_PREFS even for * aeads is useless, given that we don't expects more than a very few * algorithms. */ static int prefs_initialized = 0; static byte sym_prefs[MAX_PREFS]; static int nsym_prefs; static byte hash_prefs[MAX_PREFS]; static int nhash_prefs; static byte zip_prefs[MAX_PREFS]; static int nzip_prefs; static byte aead_prefs[MAX_PREFS]; static int naead_prefs; static int mdc_available; static int ks_modify; static int aead_available; static gpg_error_t parse_algo_usage_expire (ctrl_t ctrl, int for_subkey, const char *algostr, const char *usagestr, const char *expirestr, int *r_algo, unsigned int *r_usage, u32 *r_expire, unsigned int *r_nbits, const char **r_curve, int *r_version, char **r_keygrip, u32 *r_keytime); static void do_generate_keypair (ctrl_t ctrl, struct para_data_s *para, struct output_control_s *outctrl, int card ); static int write_keyblock (iobuf_t out, kbnode_t node); static gpg_error_t gen_card_key (int keyno, int algo, int is_primary, kbnode_t pub_root, u32 *timestamp, u32 expireval, int keygen_flags); static unsigned int get_keysize_range (int algo, unsigned int *min, unsigned int *max); /* Return the algo string for a default new key. */ const char * get_default_pubkey_algo (void) { if (opt.def_new_key_algo) { if (*opt.def_new_key_algo && !strchr (opt.def_new_key_algo, ':')) return opt.def_new_key_algo; /* To avoid checking that option every time we delay that until * here. The only thing we really need to make sure is that * there is no colon in the string so that the --gpgconf-list * command won't mess up its output. */ log_info (_("invalid value for option '%s'\n"), "--default-new-key-algo"); } return DEFAULT_STD_KEY_PARAM; } static void print_status_key_created (int letter, PKT_public_key *pk, const char *handle) { byte array[MAX_FINGERPRINT_LEN], *s; char *buf, *p; size_t i, n; if (!handle) handle = ""; buf = xmalloc (MAX_FINGERPRINT_LEN*2+31 + strlen (handle) + 1); p = buf; if (letter || pk) { *p++ = letter; if (pk) { *p++ = ' '; fingerprint_from_pk (pk, array, &n); s = array; /* Fixme: Use bin2hex */ for (i=0; i < n ; i++, s++, p += 2) snprintf (p, 3, "%02X", *s); } } if (*handle) { *p++ = ' '; for (i=0; handle[i] && i < 100; i++) *p++ = isspace ((unsigned int)handle[i])? '_':handle[i]; } *p = 0; write_status_text ((letter || pk)?STATUS_KEY_CREATED:STATUS_KEY_NOT_CREATED, buf); xfree (buf); } static void print_status_key_not_created (const char *handle) { print_status_key_created (0, NULL, handle); } static gpg_error_t write_uid (kbnode_t root, const char *s) { PACKET *pkt = NULL; size_t n = strlen (s); if (n > MAX_UID_PACKET_LENGTH - 10) return gpg_error (GPG_ERR_INV_USER_ID); pkt = xmalloc_clear (sizeof *pkt); pkt->pkttype = PKT_USER_ID; pkt->pkt.user_id = xmalloc_clear (sizeof *pkt->pkt.user_id + n); pkt->pkt.user_id->len = n; pkt->pkt.user_id->ref = 1; strcpy (pkt->pkt.user_id->name, s); add_kbnode (root, new_kbnode (pkt)); return 0; } static void do_add_key_flags (PKT_signature *sig, unsigned int use) { byte buf[1]; buf[0] = 0; /* The spec says that all primary keys MUST be able to certify. */ if(sig->sig_class!=0x18) buf[0] |= 0x01; if (use & PUBKEY_USAGE_SIG) buf[0] |= 0x02; if (use & PUBKEY_USAGE_ENC) buf[0] |= 0x04 | 0x08; if (use & PUBKEY_USAGE_AUTH) buf[0] |= 0x20; build_sig_subpkt (sig, SIGSUBPKT_KEY_FLAGS, buf, 1); } int keygen_add_key_expire (PKT_signature *sig, void *opaque) { PKT_public_key *pk = opaque; byte buf[8]; u32 u; if (pk->expiredate) { if (pk->expiredate > pk->timestamp) u = pk->expiredate - pk->timestamp; else u = 1; buf[0] = (u >> 24) & 0xff; buf[1] = (u >> 16) & 0xff; buf[2] = (u >> 8) & 0xff; buf[3] = u & 0xff; build_sig_subpkt (sig, SIGSUBPKT_KEY_EXPIRE, buf, 4); } else { /* Make sure we don't leave a key expiration subpacket lying around */ delete_sig_subpkt (sig->hashed, SIGSUBPKT_KEY_EXPIRE); } return 0; } /* Add the key usage (i.e. key flags) in SIG from the public keys * pubkey_usage field. OPAQUE has the public key. */ int keygen_add_key_flags (PKT_signature *sig, void *opaque) { PKT_public_key *pk = opaque; do_add_key_flags (sig, pk->pubkey_usage); return 0; } static int keygen_add_key_flags_and_expire (PKT_signature *sig, void *opaque) { struct opaque_data_usage_and_pk *oduap = opaque; do_add_key_flags (sig, oduap->usage); return keygen_add_key_expire (sig, oduap->pk); } static int set_one_pref (int val, int type, const char *item, byte *buf, int *nbuf) { int i; for (i=0; i < *nbuf; i++ ) if (buf[i] == val) { log_info (_("preference '%s' duplicated\n"), item); return -1; } if (*nbuf >= MAX_PREFS) { if(type==1) log_info(_("too many cipher preferences\n")); else if(type==2) log_info(_("too many digest preferences\n")); else if(type==3) log_info(_("too many compression preferences\n")); else if(type==4) log_info(_("too many AEAD preferences\n")); else BUG(); return -1; } buf[(*nbuf)++] = val; return 0; } /* * Parse the supplied string and use it to set the standard * preferences. The string may be in a form like the one printed by * "pref" (something like: "S10 S3 H3 H2 Z2 Z1") or the actual * cipher/hash/compress names. Use NULL to set the default * preferences. Returns: 0 = okay */ int keygen_set_std_prefs (const char *string,int personal) { byte sym[MAX_PREFS], hash[MAX_PREFS], zip[MAX_PREFS], aead[MAX_PREFS]; int nsym=0, nhash=0, nzip=0, naead=0, val, rc=0; int mdc=1, modify=0; /* mdc defaults on, modify defaults off. */ char dummy_string[25*4+1]; /* Enough for 25 items. */ if (!string || !ascii_strcasecmp (string, "default")) { if (opt.def_preference_list) string=opt.def_preference_list; else { int any_compress = 0; dummy_string[0]='\0'; /* The rationale why we use the order AES256,192,128 is for compatibility reasons with PGP. If gpg would define AES128 first, we would get the somewhat confusing situation: gpg -r pgpkey -r gpgkey ---gives--> AES256 gpg -r gpgkey -r pgpkey ---gives--> AES Note that by using --personal-cipher-preferences it is possible to prefer AES128. */ /* Make sure we do not add more than 15 items here, as we could overflow the size of dummy_string. We currently have at most 12. */ if ( !openpgp_cipher_test_algo (CIPHER_ALGO_AES256) ) strcat(dummy_string,"S9 "); if ( !openpgp_cipher_test_algo (CIPHER_ALGO_AES192) ) strcat(dummy_string,"S8 "); if ( !openpgp_cipher_test_algo (CIPHER_ALGO_AES) ) strcat(dummy_string,"S7 "); strcat(dummy_string,"S2 "); /* 3DES */ if (!openpgp_aead_test_algo (AEAD_ALGO_OCB)) strcat(dummy_string,"A2 "); if (personal) { /* The default internal hash algo order is: * SHA-256, SHA-384, SHA-512, SHA-224, SHA-1. */ if (!openpgp_md_test_algo (DIGEST_ALGO_SHA256)) strcat (dummy_string, "H8 "); if (!openpgp_md_test_algo (DIGEST_ALGO_SHA384)) strcat (dummy_string, "H9 "); if (!openpgp_md_test_algo (DIGEST_ALGO_SHA512)) strcat (dummy_string, "H10 "); } else { /* The default advertised hash algo order is: * SHA-512, SHA-384, SHA-256, SHA-224, SHA-1. */ if (!openpgp_md_test_algo (DIGEST_ALGO_SHA512)) strcat (dummy_string, "H10 "); if (!openpgp_md_test_algo (DIGEST_ALGO_SHA384)) strcat (dummy_string, "H9 "); if (!openpgp_md_test_algo (DIGEST_ALGO_SHA256)) strcat (dummy_string, "H8 "); } if (!openpgp_md_test_algo (DIGEST_ALGO_SHA224)) strcat (dummy_string, "H11 "); strcat (dummy_string, "H2 "); /* SHA-1 */ if(!check_compress_algo(COMPRESS_ALGO_ZLIB)) { strcat(dummy_string,"Z2 "); any_compress = 1; } if(!check_compress_algo(COMPRESS_ALGO_BZIP2)) { strcat(dummy_string,"Z3 "); any_compress = 1; } if(!check_compress_algo(COMPRESS_ALGO_ZIP)) { strcat(dummy_string,"Z1 "); any_compress = 1; } /* In case we have no compress algo at all, declare that we prefer no compression. */ if (!any_compress) strcat(dummy_string,"Z0 "); /* Remove the trailing space. */ if (*dummy_string && dummy_string[strlen (dummy_string)-1] == ' ') dummy_string[strlen (dummy_string)-1] = 0; string=dummy_string; } } else if (!ascii_strcasecmp (string, "none")) string = ""; if(strlen(string)) { char *prefstringbuf; char *tok, *prefstring; /* We need a writable string. */ prefstring = prefstringbuf = xstrdup (string); while((tok=strsep(&prefstring," ,"))) { if (!*tok) ; else if((val=string_to_cipher_algo (tok))) { if(set_one_pref(val,1,tok,sym,&nsym)) rc=-1; } else if((val=string_to_digest_algo (tok))) { if(set_one_pref(val,2,tok,hash,&nhash)) rc=-1; } else if((val=string_to_compress_algo(tok))>-1) { if(set_one_pref(val,3,tok,zip,&nzip)) rc=-1; } else if ((val=string_to_aead_algo (tok))) { if (set_one_pref (val, 4, tok, aead, &naead)) rc = -1; } else if (!ascii_strcasecmp(tok, "mdc") || !ascii_strcasecmp(tok, "[mdc]")) mdc=1; else if (!ascii_strcasecmp(tok, "no-mdc") || !ascii_strcasecmp(tok, "[no-mdc]")) mdc=0; else if (!ascii_strcasecmp(tok, "ks-modify") || !ascii_strcasecmp(tok, "[ks-modify]")) modify=1; else if (!ascii_strcasecmp(tok,"no-ks-modify") || !ascii_strcasecmp(tok,"[no-ks-modify]")) modify=0; else if (!ascii_strcasecmp(tok,"aead") || !ascii_strcasecmp(tok,"[aead]")) { /* Ignore because this is set from the preferences but * shown in the in the preferences/features list. */ } else { log_info (_("invalid item '%s' in preference string\n"),tok); rc=-1; } } xfree (prefstringbuf); } if(!rc) { if(personal) { if(personal==PREFTYPE_SYM) { xfree(opt.personal_cipher_prefs); if(nsym==0) opt.personal_cipher_prefs=NULL; else { int i; opt.personal_cipher_prefs= xmalloc(sizeof(prefitem_t *)*(nsym+1)); for (i=0; iref=1; uid->prefs = xmalloc ((sizeof(prefitem_t *)* (nsym_prefs+naead_prefs+nhash_prefs+nzip_prefs+1))); for(i=0;iprefs[j].type=PREFTYPE_SYM; uid->prefs[j].value=sym_prefs[i]; } for (i=0; i < naead_prefs; i++, j++) { uid->prefs[j].type = PREFTYPE_AEAD; uid->prefs[j].value = aead_prefs[i]; } for(i=0;iprefs[j].type=PREFTYPE_HASH; uid->prefs[j].value=hash_prefs[i]; } for(i=0;iprefs[j].type=PREFTYPE_ZIP; uid->prefs[j].value=zip_prefs[i]; } uid->prefs[j].type=PREFTYPE_NONE; uid->prefs[j].value=0; uid->flags.mdc = mdc_available; uid->flags.aead = aead_available; uid->flags.ks_modify = ks_modify; return uid; } static void add_feature_mdc (PKT_signature *sig,int enabled) { const byte *s; size_t n; int i; char *buf; s = parse_sig_subpkt (sig, 1, SIGSUBPKT_FEATURES, &n ); /* Already set or cleared */ if (s && n && ((enabled && (s[0] & 0x01)) || (!enabled && !(s[0] & 0x01)))) return; if (!s || !n) { /* create a new one */ n = 1; buf = xmalloc_clear (n); } else { buf = xmalloc (n); memcpy (buf, s, n); } if(enabled) buf[0] |= 0x01; /* MDC feature */ else buf[0] &= ~0x01; /* Are there any bits set? */ for(i=0;ihashed, SIGSUBPKT_FEATURES); else build_sig_subpkt (sig, SIGSUBPKT_FEATURES, buf, n); xfree (buf); } static void add_feature_aead (PKT_signature *sig, int enabled) { const byte *s; size_t n; int i; char *buf; s = parse_sig_subpkt (sig, 1, SIGSUBPKT_FEATURES, &n ); if (s && n && ((enabled && (s[0] & 0x02)) || (!enabled && !(s[0] & 0x02)))) return; /* Already set or cleared */ if (!s || !n) { /* Create a new one */ n = 1; buf = xmalloc_clear (n); } else { buf = xmalloc (n); memcpy (buf, s, n); } if (enabled) buf[0] |= 0x02; /* AEAD supported */ else buf[0] &= ~0x02; /* Are there any bits set? */ for (i=0; i < n; i++) if (buf[i]) break; if (i == n) delete_sig_subpkt (sig->hashed, SIGSUBPKT_FEATURES); else build_sig_subpkt (sig, SIGSUBPKT_FEATURES, buf, n); xfree (buf); } static void add_feature_v5 (PKT_signature *sig, int enabled) { const byte *s; size_t n; int i; char *buf; s = parse_sig_subpkt (sig, 1, SIGSUBPKT_FEATURES, &n ); if (s && n && ((enabled && (s[0] & 0x04)) || (!enabled && !(s[0] & 0x04)))) return; /* Already set or cleared */ if (!s || !n) { /* Create a new one */ n = 1; buf = xmalloc_clear (n); } else { buf = xmalloc (n); memcpy (buf, s, n); } if (enabled) buf[0] |= 0x04; /* v5 key supported */ else buf[0] &= ~0x04; /* Are there any bits set? */ for (i=0; i < n; i++) if (buf[i]) break; if (i == n) delete_sig_subpkt (sig->hashed, SIGSUBPKT_FEATURES); else build_sig_subpkt (sig, SIGSUBPKT_FEATURES, buf, n); xfree (buf); } static void add_keyserver_modify (PKT_signature *sig,int enabled) { const byte *s; size_t n; int i; char *buf; /* The keyserver modify flag is a negative flag (i.e. no-modify) */ enabled=!enabled; s = parse_sig_subpkt (sig, 1, SIGSUBPKT_KS_FLAGS, &n ); /* Already set or cleared */ if (s && n && ((enabled && (s[0] & 0x80)) || (!enabled && !(s[0] & 0x80)))) return; if (!s || !n) { /* create a new one */ n = 1; buf = xmalloc_clear (n); } else { buf = xmalloc (n); memcpy (buf, s, n); } if(enabled) buf[0] |= 0x80; /* no-modify flag */ else buf[0] &= ~0x80; /* Are there any bits set? */ for(i=0;ihashed, SIGSUBPKT_KS_FLAGS); else build_sig_subpkt (sig, SIGSUBPKT_KS_FLAGS, buf, n); xfree (buf); } int keygen_upd_std_prefs (PKT_signature *sig, void *opaque) { (void)opaque; if (!prefs_initialized) keygen_set_std_prefs (NULL, 0); if (nsym_prefs) build_sig_subpkt (sig, SIGSUBPKT_PREF_SYM, sym_prefs, nsym_prefs); else { delete_sig_subpkt (sig->hashed, SIGSUBPKT_PREF_SYM); delete_sig_subpkt (sig->unhashed, SIGSUBPKT_PREF_SYM); } if (naead_prefs) build_sig_subpkt (sig, SIGSUBPKT_PREF_AEAD, aead_prefs, naead_prefs); else { delete_sig_subpkt (sig->hashed, SIGSUBPKT_PREF_AEAD); delete_sig_subpkt (sig->unhashed, SIGSUBPKT_PREF_AEAD); } if (nhash_prefs) build_sig_subpkt (sig, SIGSUBPKT_PREF_HASH, hash_prefs, nhash_prefs); else { delete_sig_subpkt (sig->hashed, SIGSUBPKT_PREF_HASH); delete_sig_subpkt (sig->unhashed, SIGSUBPKT_PREF_HASH); } if (nzip_prefs) build_sig_subpkt (sig, SIGSUBPKT_PREF_COMPR, zip_prefs, nzip_prefs); else { delete_sig_subpkt (sig->hashed, SIGSUBPKT_PREF_COMPR); delete_sig_subpkt (sig->unhashed, SIGSUBPKT_PREF_COMPR); } /* Make sure that the MDC feature flag is set if needed. */ add_feature_mdc (sig,mdc_available); add_feature_aead (sig, aead_available); add_feature_v5 (sig, 1); add_keyserver_modify (sig,ks_modify); keygen_add_keyserver_url(sig,NULL); return 0; } /**************** * Add preference to the self signature packet. * This is only called for packets with version > 3. */ int keygen_add_std_prefs (PKT_signature *sig, void *opaque) { PKT_public_key *pk = opaque; do_add_key_flags (sig, pk->pubkey_usage); keygen_add_key_expire (sig, opaque ); keygen_upd_std_prefs (sig, opaque); keygen_add_keyserver_url (sig,NULL); return 0; } int keygen_add_keyserver_url(PKT_signature *sig, void *opaque) { const char *url=opaque; if(!url) url=opt.def_keyserver_url; if(url) build_sig_subpkt(sig,SIGSUBPKT_PREF_KS,url,strlen(url)); else delete_sig_subpkt (sig->hashed,SIGSUBPKT_PREF_KS); return 0; } int keygen_add_notations(PKT_signature *sig,void *opaque) { struct notation *notation; /* We always start clean */ delete_sig_subpkt(sig->hashed,SIGSUBPKT_NOTATION); delete_sig_subpkt(sig->unhashed,SIGSUBPKT_NOTATION); sig->flags.notation=0; for(notation=opaque;notation;notation=notation->next) if(!notation->flags.ignore) { unsigned char *buf; unsigned int n1,n2; n1=strlen(notation->name); if(notation->altvalue) n2=strlen(notation->altvalue); else if(notation->bdat) n2=notation->blen; else n2=strlen(notation->value); buf = xmalloc( 8 + n1 + n2 ); /* human readable or not */ buf[0] = notation->bdat?0:0x80; buf[1] = buf[2] = buf[3] = 0; buf[4] = n1 >> 8; buf[5] = n1; buf[6] = n2 >> 8; buf[7] = n2; memcpy(buf+8, notation->name, n1 ); if(notation->altvalue) memcpy(buf+8+n1, notation->altvalue, n2 ); else if(notation->bdat) memcpy(buf+8+n1, notation->bdat, n2 ); else memcpy(buf+8+n1, notation->value, n2 ); build_sig_subpkt( sig, SIGSUBPKT_NOTATION | (notation->flags.critical?SIGSUBPKT_FLAG_CRITICAL:0), buf, 8+n1+n2 ); xfree(buf); } return 0; } int keygen_add_revkey (PKT_signature *sig, void *opaque) { struct revocation_key *revkey = opaque; byte buf[2+MAX_FINGERPRINT_LEN]; log_assert (revkey->fprlen <= MAX_FINGERPRINT_LEN); buf[0] = revkey->class; buf[1] = revkey->algid; memcpy (buf + 2, revkey->fpr, revkey->fprlen); memset (buf + 2 + revkey->fprlen, 0, sizeof (revkey->fpr) - revkey->fprlen); build_sig_subpkt (sig, SIGSUBPKT_REV_KEY, buf, 2+revkey->fprlen); /* All sigs with revocation keys set are nonrevocable. */ sig->flags.revocable = 0; buf[0] = 0; build_sig_subpkt (sig, SIGSUBPKT_REVOCABLE, buf, 1); parse_revkeys (sig); return 0; } /* Create a back-signature. If TIMESTAMP is not NULL, use it for the signature creation time. */ gpg_error_t make_backsig (ctrl_t ctrl, PKT_signature *sig, PKT_public_key *pk, PKT_public_key *sub_pk, PKT_public_key *sub_psk, u32 timestamp, const char *cache_nonce) { gpg_error_t err; PKT_signature *backsig; cache_public_key (sub_pk); err = make_keysig_packet (ctrl, &backsig, pk, NULL, sub_pk, sub_psk, 0x19, timestamp, 0, NULL, NULL, cache_nonce); if (err) log_error ("make_keysig_packet failed for backsig: %s\n", gpg_strerror (err)); else { /* Get it into a binary packed form. */ IOBUF backsig_out = iobuf_temp(); PACKET backsig_pkt; init_packet (&backsig_pkt); backsig_pkt.pkttype = PKT_SIGNATURE; backsig_pkt.pkt.signature = backsig; err = build_packet (backsig_out, &backsig_pkt); free_packet (&backsig_pkt, NULL); if (err) log_error ("build_packet failed for backsig: %s\n", gpg_strerror (err)); else { size_t pktlen = 0; byte *buf = iobuf_get_temp_buffer (backsig_out); /* Remove the packet header. */ if(buf[0]&0x40) { if (buf[1] < 192) { pktlen = buf[1]; buf += 2; } else if(buf[1] < 224) { pktlen = (buf[1]-192)*256; pktlen += buf[2]+192; buf += 3; } else if (buf[1] == 255) { pktlen = buf32_to_size_t (buf+2); buf += 6; } else BUG (); } else { int mark = 1; switch (buf[0]&3) { case 3: BUG (); break; case 2: pktlen = (size_t)buf[mark++] << 24; pktlen |= buf[mark++] << 16; /* fall through */ case 1: pktlen |= buf[mark++] << 8; /* fall through */ case 0: pktlen |= buf[mark++]; } buf += mark; } /* Now make the binary blob into a subpacket. */ build_sig_subpkt (sig, SIGSUBPKT_SIGNATURE, buf, pktlen); iobuf_close (backsig_out); } } return err; } /* Write a direct key signature to the first key in ROOT using the key PSK. REVKEY is describes the direct key signature and TIMESTAMP is the timestamp to set on the signature. */ static gpg_error_t write_direct_sig (ctrl_t ctrl, kbnode_t root, PKT_public_key *psk, struct revocation_key *revkey, u32 timestamp, const char *cache_nonce) { gpg_error_t err; PACKET *pkt; PKT_signature *sig; KBNODE node; PKT_public_key *pk; if (opt.verbose) log_info (_("writing direct signature\n")); /* Get the pk packet from the pub_tree. */ node = find_kbnode (root, PKT_PUBLIC_KEY); if (!node) BUG (); pk = node->pkt->pkt.public_key; /* We have to cache the key, so that the verification of the signature creation is able to retrieve the public key. */ cache_public_key (pk); /* Make the signature. */ err = make_keysig_packet (ctrl, &sig, pk, NULL,NULL, psk, 0x1F, timestamp, 0, keygen_add_revkey, revkey, cache_nonce); if (err) { log_error ("make_keysig_packet failed: %s\n", gpg_strerror (err) ); return err; } pkt = xmalloc_clear (sizeof *pkt); pkt->pkttype = PKT_SIGNATURE; pkt->pkt.signature = sig; add_kbnode (root, new_kbnode (pkt)); return err; } /* Write a self-signature to the first user id in ROOT using the key PSK. USE and TIMESTAMP give the extra data we need for the signature. */ static gpg_error_t write_selfsigs (ctrl_t ctrl, kbnode_t root, PKT_public_key *psk, unsigned int use, u32 timestamp, const char *cache_nonce) { gpg_error_t err; PACKET *pkt; PKT_signature *sig; PKT_user_id *uid; KBNODE node; PKT_public_key *pk; if (opt.verbose) log_info (_("writing self signature\n")); /* Get the uid packet from the list. */ node = find_kbnode (root, PKT_USER_ID); if (!node) BUG(); /* No user id packet in tree. */ uid = node->pkt->pkt.user_id; /* Get the pk packet from the pub_tree. */ node = find_kbnode (root, PKT_PUBLIC_KEY); if (!node) BUG(); pk = node->pkt->pkt.public_key; /* The usage has not yet been set - do it now. */ pk->pubkey_usage = use; /* We have to cache the key, so that the verification of the signature creation is able to retrieve the public key. */ cache_public_key (pk); /* Make the signature. */ err = make_keysig_packet (ctrl, &sig, pk, uid, NULL, psk, 0x13, timestamp, 0, keygen_add_std_prefs, pk, cache_nonce); if (err) { log_error ("make_keysig_packet failed: %s\n", gpg_strerror (err)); return err; } pkt = xmalloc_clear (sizeof *pkt); pkt->pkttype = PKT_SIGNATURE; pkt->pkt.signature = sig; add_kbnode (root, new_kbnode (pkt)); return err; } /* Write the key binding signature. If TIMESTAMP is not NULL use the signature creation time. PRI_PSK is the key use for signing. SUB_PSK is a key used to create a back-signature; that one is only used if USE has the PUBKEY_USAGE_SIG capability. */ static int write_keybinding (ctrl_t ctrl, kbnode_t root, PKT_public_key *pri_psk, PKT_public_key *sub_psk, unsigned int use, u32 timestamp, const char *cache_nonce) { gpg_error_t err; PACKET *pkt; PKT_signature *sig; KBNODE node; PKT_public_key *pri_pk, *sub_pk; struct opaque_data_usage_and_pk oduap; if (opt.verbose) log_info(_("writing key binding signature\n")); /* Get the primary pk packet from the tree. */ node = find_kbnode (root, PKT_PUBLIC_KEY); if (!node) BUG(); pri_pk = node->pkt->pkt.public_key; /* We have to cache the key, so that the verification of the * signature creation is able to retrieve the public key. */ cache_public_key (pri_pk); /* Find the last subkey. */ sub_pk = NULL; for (node = root; node; node = node->next ) { if (node->pkt->pkttype == PKT_PUBLIC_SUBKEY) sub_pk = node->pkt->pkt.public_key; } if (!sub_pk) BUG(); /* Make the signature. */ oduap.usage = use; oduap.pk = sub_pk; err = make_keysig_packet (ctrl, &sig, pri_pk, NULL, sub_pk, pri_psk, 0x18, timestamp, 0, keygen_add_key_flags_and_expire, &oduap, cache_nonce); if (err) { log_error ("make_keysig_packeto failed: %s\n", gpg_strerror (err)); return err; } /* Make a backsig. */ if (use & PUBKEY_USAGE_SIG) { err = make_backsig (ctrl, sig, pri_pk, sub_pk, sub_psk, timestamp, cache_nonce); if (err) return err; } pkt = xmalloc_clear ( sizeof *pkt ); pkt->pkttype = PKT_SIGNATURE; pkt->pkt.signature = sig; add_kbnode (root, new_kbnode (pkt) ); return err; } static gpg_error_t ecckey_from_sexp (gcry_mpi_t *array, gcry_sexp_t sexp, int algo) { gpg_error_t err; gcry_sexp_t list, l2; char *curve = NULL; int i; const char *oidstr; unsigned int nbits; array[0] = NULL; array[1] = NULL; array[2] = NULL; list = gcry_sexp_find_token (sexp, "public-key", 0); if (!list) return gpg_error (GPG_ERR_INV_OBJ); l2 = gcry_sexp_cadr (list); gcry_sexp_release (list); list = l2; if (!list) return gpg_error (GPG_ERR_NO_OBJ); l2 = gcry_sexp_find_token (list, "curve", 0); if (!l2) { err = gpg_error (GPG_ERR_NO_OBJ); goto leave; } curve = gcry_sexp_nth_string (l2, 1); if (!curve) { err = gpg_error (GPG_ERR_NO_OBJ); goto leave; } gcry_sexp_release (l2); oidstr = openpgp_curve_to_oid (curve, &nbits, NULL); if (!oidstr) { /* That can't happen because we used one of the curves gpg_curve_to_oid knows about. */ err = gpg_error (GPG_ERR_INV_OBJ); goto leave; } err = openpgp_oid_from_str (oidstr, &array[0]); if (err) goto leave; err = sexp_extract_param_sos (list, "q", &array[1]); if (err) goto leave; gcry_sexp_release (list); if (algo == PUBKEY_ALGO_ECDH) { array[2] = pk_ecdh_default_params (nbits); if (!array[2]) { err = gpg_error_from_syserror (); goto leave; } } leave: xfree (curve); if (err) { for (i=0; i < 3; i++) { gcry_mpi_release (array[i]); array[i] = NULL; } } return err; } /* Extract key parameters from SEXP and store them in ARRAY. ELEMS is a string where each character denotes a parameter name. TOPNAME is the name of the top element above the elements. */ static int key_from_sexp (gcry_mpi_t *array, gcry_sexp_t sexp, const char *topname, const char *elems) { gcry_sexp_t list, l2; const char *s; int i, idx; int rc = 0; list = gcry_sexp_find_token (sexp, topname, 0); if (!list) return gpg_error (GPG_ERR_INV_OBJ); l2 = gcry_sexp_cadr (list); gcry_sexp_release (list); list = l2; if (!list) return gpg_error (GPG_ERR_NO_OBJ); for (idx=0,s=elems; *s; s++, idx++) { l2 = gcry_sexp_find_token (list, s, 1); if (!l2) { rc = gpg_error (GPG_ERR_NO_OBJ); /* required parameter not found */ goto leave; } array[idx] = gcry_sexp_nth_mpi (l2, 1, GCRYMPI_FMT_USG); gcry_sexp_release (l2); if (!array[idx]) { rc = gpg_error (GPG_ERR_INV_OBJ); /* required parameter invalid */ goto leave; } } gcry_sexp_release (list); leave: if (rc) { for (i=0; itimestamp = timestamp; pk->version = (keygen_flags & KEYGEN_FLAG_CREATE_V5_KEY)? 5 : 4; if (expireval) pk->expiredate = pk->timestamp + expireval; pk->pubkey_algo = algo; if (algo == PUBKEY_ALGO_ECDSA || algo == PUBKEY_ALGO_EDDSA || algo == PUBKEY_ALGO_ECDH ) err = ecckey_from_sexp (pk->pkey, s_key, algo); else err = key_from_sexp (pk->pkey, s_key, "public-key", algoelem); if (err) { log_error ("key_from_sexp failed: %s\n", gpg_strerror (err) ); gcry_sexp_release (s_key); free_public_key (pk); return err; } gcry_sexp_release (s_key); pkt = xtrycalloc (1, sizeof *pkt); if (!pkt) { err = gpg_error_from_syserror (); free_public_key (pk); return err; } pkt->pkttype = is_subkey ? PKT_PUBLIC_SUBKEY : PKT_PUBLIC_KEY; pkt->pkt.public_key = pk; add_kbnode (pub_root, new_kbnode (pkt)); return 0; } /* Common code for the key generation function gen_xxx. */ static int common_gen (const char *keyparms, int algo, const char *algoelem, kbnode_t pub_root, u32 timestamp, u32 expireval, int is_subkey, int keygen_flags, const char *passphrase, char **cache_nonce_addr, char **passwd_nonce_addr) { int err; PACKET *pkt; PKT_public_key *pk; gcry_sexp_t s_key; err = agent_genkey (NULL, cache_nonce_addr, passwd_nonce_addr, keyparms, !!(keygen_flags & KEYGEN_FLAG_NO_PROTECTION), passphrase, timestamp, &s_key); if (err) { log_error ("agent_genkey failed: %s\n", gpg_strerror (err) ); return err; } pk = xtrycalloc (1, sizeof *pk); if (!pk) { err = gpg_error_from_syserror (); gcry_sexp_release (s_key); return err; } pk->timestamp = timestamp; pk->version = (keygen_flags & KEYGEN_FLAG_CREATE_V5_KEY)? 5 : 4; if (expireval) pk->expiredate = pk->timestamp + expireval; pk->pubkey_algo = algo; if (algo == PUBKEY_ALGO_ECDSA || algo == PUBKEY_ALGO_EDDSA || algo == PUBKEY_ALGO_ECDH ) err = ecckey_from_sexp (pk->pkey, s_key, algo); else err = key_from_sexp (pk->pkey, s_key, "public-key", algoelem); if (err) { log_error ("key_from_sexp failed: %s\n", gpg_strerror (err) ); gcry_sexp_release (s_key); free_public_key (pk); return err; } gcry_sexp_release (s_key); pkt = xtrycalloc (1, sizeof *pkt); if (!pkt) { err = gpg_error_from_syserror (); free_public_key (pk); return err; } pkt->pkttype = is_subkey ? PKT_PUBLIC_SUBKEY : PKT_PUBLIC_KEY; pkt->pkt.public_key = pk; add_kbnode (pub_root, new_kbnode (pkt)); return 0; } /* * Generate an Elgamal key. */ static int gen_elg (int algo, unsigned int nbits, KBNODE pub_root, u32 timestamp, u32 expireval, int is_subkey, int keygen_flags, const char *passphrase, char **cache_nonce_addr, char **passwd_nonce_addr) { int err; char *keyparms; char nbitsstr[35]; log_assert (is_ELGAMAL (algo)); if (nbits < 1024) { nbits = 2048; log_info (_("keysize invalid; using %u bits\n"), nbits ); } else if (nbits > 4096) { nbits = 4096; log_info (_("keysize invalid; using %u bits\n"), nbits ); } if ((nbits % 32)) { nbits = ((nbits + 31) / 32) * 32; log_info (_("keysize rounded up to %u bits\n"), nbits ); } /* Note that we use transient-key only if no-protection has also been enabled. */ snprintf (nbitsstr, sizeof nbitsstr, "%u", nbits); keyparms = xtryasprintf ("(genkey(%s(nbits %zu:%s)%s))", algo == GCRY_PK_ELG_E ? "openpgp-elg" : algo == GCRY_PK_ELG ? "elg" : "x-oops" , strlen (nbitsstr), nbitsstr, ((keygen_flags & KEYGEN_FLAG_TRANSIENT_KEY) && (keygen_flags & KEYGEN_FLAG_NO_PROTECTION))? "(transient-key)" : "" ); if (!keyparms) err = gpg_error_from_syserror (); else { err = common_gen (keyparms, algo, "pgy", pub_root, timestamp, expireval, is_subkey, keygen_flags, passphrase, cache_nonce_addr, passwd_nonce_addr); xfree (keyparms); } return err; } /* * Generate an DSA key */ static gpg_error_t gen_dsa (unsigned int nbits, KBNODE pub_root, u32 timestamp, u32 expireval, int is_subkey, int keygen_flags, const char *passphrase, char **cache_nonce_addr, char **passwd_nonce_addr) { int err; unsigned int qbits; char *keyparms; char nbitsstr[35]; char qbitsstr[35]; if (nbits < 768) { nbits = 2048; log_info(_("keysize invalid; using %u bits\n"), nbits ); } else if ( nbits > 3072 ) { nbits = 3072; log_info(_("keysize invalid; using %u bits\n"), nbits ); } if( (nbits % 64) ) { nbits = ((nbits + 63) / 64) * 64; log_info(_("keysize rounded up to %u bits\n"), nbits ); } /* To comply with FIPS rules we round up to the next value unless in expert mode. */ if (!opt.expert && nbits > 1024 && (nbits % 1024)) { nbits = ((nbits + 1023) / 1024) * 1024; log_info(_("keysize rounded up to %u bits\n"), nbits ); } /* Figure out a q size based on the key size. FIPS 180-3 says: L = 1024, N = 160 L = 2048, N = 224 L = 2048, N = 256 L = 3072, N = 256 2048/256 is an odd pair since there is also a 2048/224 and 3072/256. Matching sizes is not a very exact science. We'll do 256 qbits for nbits over 2047, 224 for nbits over 1024 but less than 2048, and 160 for 1024 (DSA1). */ if (nbits > 2047) qbits = 256; else if ( nbits > 1024) qbits = 224; else qbits = 160; if (qbits != 160 ) log_info (_("WARNING: some OpenPGP programs can't" " handle a DSA key with this digest size\n")); snprintf (nbitsstr, sizeof nbitsstr, "%u", nbits); snprintf (qbitsstr, sizeof qbitsstr, "%u", qbits); keyparms = xtryasprintf ("(genkey(dsa(nbits %zu:%s)(qbits %zu:%s)%s))", strlen (nbitsstr), nbitsstr, strlen (qbitsstr), qbitsstr, ((keygen_flags & KEYGEN_FLAG_TRANSIENT_KEY) && (keygen_flags & KEYGEN_FLAG_NO_PROTECTION))? "(transient-key)" : "" ); if (!keyparms) err = gpg_error_from_syserror (); else { err = common_gen (keyparms, PUBKEY_ALGO_DSA, "pqgy", pub_root, timestamp, expireval, is_subkey, keygen_flags, passphrase, cache_nonce_addr, passwd_nonce_addr); xfree (keyparms); } return err; } /* * Generate an ECC key */ static gpg_error_t gen_ecc (int algo, const char *curve, kbnode_t pub_root, u32 timestamp, u32 expireval, int is_subkey, int keygen_flags, const char *passphrase, char **cache_nonce_addr, char **passwd_nonce_addr) { gpg_error_t err; char *keyparms; log_assert (algo == PUBKEY_ALGO_ECDSA || algo == PUBKEY_ALGO_EDDSA || algo == PUBKEY_ALGO_ECDH); if (!curve || !*curve) return gpg_error (GPG_ERR_UNKNOWN_CURVE); /* Map the displayed short forms of some curves to their canonical * names. */ if (!ascii_strcasecmp (curve, "cv25519")) curve = "Curve25519"; else if (!ascii_strcasecmp (curve, "ed25519")) curve = "Ed25519"; else if (!ascii_strcasecmp (curve, "cv448")) curve = "X448"; else if (!ascii_strcasecmp (curve, "ed448")) curve = "Ed448"; /* Note that we use the "comp" flag with EdDSA to request the use of a 0x40 compression prefix octet. */ if (algo == PUBKEY_ALGO_EDDSA && !strcmp (curve, "Ed25519")) keyparms = xtryasprintf ("(genkey(ecc(curve %zu:%s)(flags eddsa comp%s)))", strlen (curve), curve, (((keygen_flags & KEYGEN_FLAG_TRANSIENT_KEY) && (keygen_flags & KEYGEN_FLAG_NO_PROTECTION))? " transient-key" : "")); else if (algo == PUBKEY_ALGO_EDDSA && !strcmp (curve, "Ed448")) keyparms = xtryasprintf ("(genkey(ecc(curve %zu:%s)(flags comp%s)))", strlen (curve), curve, (((keygen_flags & KEYGEN_FLAG_TRANSIENT_KEY) && (keygen_flags & KEYGEN_FLAG_NO_PROTECTION))? " transient-key" : "")); else if (algo == PUBKEY_ALGO_ECDH && !strcmp (curve, "Curve25519")) keyparms = xtryasprintf ("(genkey(ecc(curve %zu:%s)(flags djb-tweak comp%s)))", strlen (curve), curve, (((keygen_flags & KEYGEN_FLAG_TRANSIENT_KEY) && (keygen_flags & KEYGEN_FLAG_NO_PROTECTION))? " transient-key" : "")); else if (algo == PUBKEY_ALGO_ECDH && !strcmp (curve, "X448")) keyparms = xtryasprintf ("(genkey(ecc(curve %zu:%s)(flags comp%s)))", strlen (curve), curve, (((keygen_flags & KEYGEN_FLAG_TRANSIENT_KEY) && (keygen_flags & KEYGEN_FLAG_NO_PROTECTION))? " transient-key" : "")); else keyparms = xtryasprintf ("(genkey(ecc(curve %zu:%s)(flags nocomp%s)))", strlen (curve), curve, (((keygen_flags & KEYGEN_FLAG_TRANSIENT_KEY) && (keygen_flags & KEYGEN_FLAG_NO_PROTECTION))? " transient-key" : "")); if (!keyparms) err = gpg_error_from_syserror (); else { err = common_gen (keyparms, algo, "", pub_root, timestamp, expireval, is_subkey, keygen_flags, passphrase, cache_nonce_addr, passwd_nonce_addr); xfree (keyparms); } return err; } /* * Generate an RSA key. */ static int gen_rsa (int algo, unsigned int nbits, KBNODE pub_root, u32 timestamp, u32 expireval, int is_subkey, int keygen_flags, const char *passphrase, char **cache_nonce_addr, char **passwd_nonce_addr) { int err; char *keyparms; char nbitsstr[35]; const unsigned maxsize = (opt.flags.large_rsa ? 8192 : 4096); log_assert (is_RSA(algo)); if (!nbits) nbits = get_keysize_range (algo, NULL, NULL); if (nbits < 1024) { nbits = 3072; log_info (_("keysize invalid; using %u bits\n"), nbits ); } else if (nbits > maxsize) { nbits = maxsize; log_info (_("keysize invalid; using %u bits\n"), nbits ); } if ((nbits % 32)) { nbits = ((nbits + 31) / 32) * 32; log_info (_("keysize rounded up to %u bits\n"), nbits ); } snprintf (nbitsstr, sizeof nbitsstr, "%u", nbits); keyparms = xtryasprintf ("(genkey(rsa(nbits %zu:%s)%s))", strlen (nbitsstr), nbitsstr, ((keygen_flags & KEYGEN_FLAG_TRANSIENT_KEY) && (keygen_flags & KEYGEN_FLAG_NO_PROTECTION))? "(transient-key)" : "" ); if (!keyparms) err = gpg_error_from_syserror (); else { err = common_gen (keyparms, algo, "ne", pub_root, timestamp, expireval, is_subkey, keygen_flags, passphrase, cache_nonce_addr, passwd_nonce_addr); xfree (keyparms); } return err; } /**************** * check valid days: * return 0 on error or the multiplier */ static int check_valid_days( const char *s ) { if( !digitp(s) ) return 0; for( s++; *s; s++) if( !digitp(s) ) break; if( !*s ) return 1; if( s[1] ) return 0; /* e.g. "2323wc" */ if( *s == 'd' || *s == 'D' ) return 1; if( *s == 'w' || *s == 'W' ) return 7; if( *s == 'm' || *s == 'M' ) return 30; if( *s == 'y' || *s == 'Y' ) return 365; return 0; } static void print_key_flags(int flags) { if(flags&PUBKEY_USAGE_SIG) tty_printf("%s ",_("Sign")); if(flags&PUBKEY_USAGE_CERT) tty_printf("%s ",_("Certify")); if(flags&PUBKEY_USAGE_ENC) tty_printf("%s ",_("Encrypt")); if(flags&PUBKEY_USAGE_AUTH) tty_printf("%s ",_("Authenticate")); } /* Ask for the key flags and return them. CURRENT gives the current * usage which should normally be given as 0. MASK gives the allowed * flags. */ unsigned int ask_key_flags_with_mask (int algo, int subkey, unsigned int current, unsigned int mask) { /* TRANSLATORS: Please use only plain ASCII characters for the * translation. If this is not possible use single digits. The * string needs to 8 bytes long. Here is a description of the * functions: * * s = Toggle signing capability * e = Toggle encryption capability * a = Toggle authentication capability * q = Finish */ const char *togglers = _("SsEeAaQq"); char *answer = NULL; const char *s; unsigned int possible; if ( strlen(togglers) != 8 ) { tty_printf ("NOTE: Bad translation at %s:%d. " "Please report.\n", __FILE__, __LINE__); togglers = "11223300"; } /* Mask the possible usage flags. This is for example used for a * card based key. For ECDH we need to allows additional usages if * they are provided. */ possible = (openpgp_pk_algo_usage (algo) & mask); if (algo == PUBKEY_ALGO_ECDH) possible |= (current & (PUBKEY_USAGE_ENC |PUBKEY_USAGE_CERT |PUBKEY_USAGE_SIG |PUBKEY_USAGE_AUTH)); /* However, only primary keys may certify. */ if (subkey) possible &= ~PUBKEY_USAGE_CERT; /* Preload the current set with the possible set, without * authentication if CURRENT is 0. If CURRENT is non-zero we mask * with all possible usages. */ if (current) current &= possible; else current = (possible&~PUBKEY_USAGE_AUTH); for (;;) { tty_printf("\n"); tty_printf(_("Possible actions for this %s key: "), (algo == PUBKEY_ALGO_ECDH || algo == PUBKEY_ALGO_ECDSA || algo == PUBKEY_ALGO_EDDSA) ? "ECC" : openpgp_pk_algo_name (algo)); print_key_flags(possible); tty_printf("\n"); tty_printf(_("Current allowed actions: ")); print_key_flags(current); tty_printf("\n\n"); if(possible&PUBKEY_USAGE_SIG) tty_printf(_(" (%c) Toggle the sign capability\n"), togglers[0]); if(possible&PUBKEY_USAGE_ENC) tty_printf(_(" (%c) Toggle the encrypt capability\n"), togglers[2]); if(possible&PUBKEY_USAGE_AUTH) tty_printf(_(" (%c) Toggle the authenticate capability\n"), togglers[4]); tty_printf(_(" (%c) Finished\n"),togglers[6]); tty_printf("\n"); xfree(answer); answer = cpr_get("keygen.flags",_("Your selection? ")); cpr_kill_prompt(); if (*answer == '=') { /* Hack to allow direct entry of the capabilities. */ current = 0; for (s=answer+1; *s; s++) { if ((*s == 's' || *s == 'S') && (possible&PUBKEY_USAGE_SIG)) current |= PUBKEY_USAGE_SIG; else if ((*s == 'e' || *s == 'E') && (possible&PUBKEY_USAGE_ENC)) current |= PUBKEY_USAGE_ENC; else if ((*s == 'a' || *s == 'A') && (possible&PUBKEY_USAGE_AUTH)) current |= PUBKEY_USAGE_AUTH; else if (!subkey && *s == 'c') { /* Accept 'c' for the primary key because USAGE_CERT will be set anyway. This is for folks who want to experiment with a cert-only primary key. */ current |= PUBKEY_USAGE_CERT; } } break; } else if (strlen(answer)>1) tty_printf(_("Invalid selection.\n")); else if(*answer=='\0' || *answer==togglers[6] || *answer==togglers[7]) break; else if((*answer==togglers[0] || *answer==togglers[1]) && possible&PUBKEY_USAGE_SIG) { if(current&PUBKEY_USAGE_SIG) current&=~PUBKEY_USAGE_SIG; else current|=PUBKEY_USAGE_SIG; } else if((*answer==togglers[2] || *answer==togglers[3]) && possible&PUBKEY_USAGE_ENC) { if(current&PUBKEY_USAGE_ENC) current&=~PUBKEY_USAGE_ENC; else current|=PUBKEY_USAGE_ENC; } else if((*answer==togglers[4] || *answer==togglers[5]) && possible&PUBKEY_USAGE_AUTH) { if(current&PUBKEY_USAGE_AUTH) current&=~PUBKEY_USAGE_AUTH; else current|=PUBKEY_USAGE_AUTH; } else tty_printf(_("Invalid selection.\n")); } xfree(answer); return current; } unsigned int ask_key_flags (int algo, int subkey, unsigned int current) { return ask_key_flags_with_mask (algo, subkey, current, ~0); } /* Check whether we have a key for the key with HEXGRIP. Returns 0 if there is no such key or the OpenPGP algo number for the key. */ static int check_keygrip (ctrl_t ctrl, const char *hexgrip) { gpg_error_t err; unsigned char *public; size_t publiclen; int algo; if (hexgrip[0] == '&') hexgrip++; err = agent_readkey (ctrl, 0, hexgrip, &public); if (err) return 0; publiclen = gcry_sexp_canon_len (public, 0, NULL, NULL); algo = get_pk_algo_from_canon_sexp (public, publiclen); xfree (public); return map_gcry_pk_to_openpgp (algo); } /* Ask for an algorithm. The function returns the algorithm id to * create. If ADDMODE is false the function won't show an option to * create the primary and subkey combined and won't set R_USAGE * either. If a combined algorithm has been selected, the subkey * algorithm is stored at R_SUBKEY_ALGO. If R_KEYGRIP is given, the * user has the choice to enter the keygrip of an existing key. That * keygrip is then stored at this address. The caller needs to free * it. If R_CARDKEY is not NULL and the keygrip has been taken from * an active card, true is stored there; if R_KEYTIME is not NULL the * creation time of that key is then stored there. */ static int ask_algo (ctrl_t ctrl, int addmode, int *r_subkey_algo, unsigned int *r_usage, char **r_keygrip, int *r_cardkey, u32 *r_keytime) { gpg_error_t err; char *keygrip = NULL; u32 keytime = 0; char *answer = NULL; int cardkey = 0; int algo; int dummy_algo; if (!r_subkey_algo) r_subkey_algo = &dummy_algo; tty_printf (_("Please select what kind of key you want:\n")); #if GPG_USE_RSA if (!addmode) tty_printf (_(" (%d) RSA and RSA%s\n"), 1, ""); #endif if (!addmode && opt.compliance != CO_DE_VS) tty_printf (_(" (%d) DSA and Elgamal%s\n"), 2, ""); if (opt.compliance != CO_DE_VS) tty_printf (_(" (%d) DSA (sign only)%s\n"), 3, ""); #if GPG_USE_RSA tty_printf (_(" (%d) RSA (sign only)%s\n"), 4, ""); #endif if (addmode) { if (opt.compliance != CO_DE_VS) tty_printf (_(" (%d) Elgamal (encrypt only)%s\n"), 5, ""); #if GPG_USE_RSA tty_printf (_(" (%d) RSA (encrypt only)%s\n"), 6, ""); #endif } if (opt.expert) { if (opt.compliance != CO_DE_VS) tty_printf (_(" (%d) DSA (set your own capabilities)%s\n"), 7, ""); #if GPG_USE_RSA tty_printf (_(" (%d) RSA (set your own capabilities)%s\n"), 8, ""); #endif } #if GPG_USE_ECDSA || GPG_USE_ECDH || GPG_USE_EDDSA if (!addmode) tty_printf (_(" (%d) ECC (sign and encrypt)%s\n"), 9, _(" *default*") ); tty_printf (_(" (%d) ECC (sign only)\n"), 10 ); if (opt.expert) tty_printf (_(" (%d) ECC (set your own capabilities)%s\n"), 11, ""); if (addmode) tty_printf (_(" (%d) ECC (encrypt only)%s\n"), 12, ""); #endif if (opt.expert && r_keygrip) tty_printf (_(" (%d) Existing key%s\n"), 13, ""); if (r_keygrip) tty_printf (_(" (%d) Existing key from card%s\n"), 14, ""); for (;;) { *r_usage = 0; *r_subkey_algo = 0; xfree (answer); answer = cpr_get ("keygen.algo", _("Your selection? ")); cpr_kill_prompt (); algo = *answer? atoi (answer) : 9; /* Default algo is 9 */ if (opt.compliance == CO_DE_VS && (algo == 2 || algo == 3 || algo == 5 || algo == 7)) { tty_printf (_("Invalid selection.\n")); } else if ((algo == 1 || !strcmp (answer, "rsa+rsa")) && !addmode) { algo = PUBKEY_ALGO_RSA; *r_subkey_algo = PUBKEY_ALGO_RSA; break; } else if ((algo == 2 || !strcmp (answer, "dsa+elg")) && !addmode) { algo = PUBKEY_ALGO_DSA; *r_subkey_algo = PUBKEY_ALGO_ELGAMAL_E; break; } else if (algo == 3 || !strcmp (answer, "dsa")) { algo = PUBKEY_ALGO_DSA; *r_usage = PUBKEY_USAGE_SIG; break; } else if (algo == 4 || !strcmp (answer, "rsa/s")) { algo = PUBKEY_ALGO_RSA; *r_usage = PUBKEY_USAGE_SIG; break; } else if ((algo == 5 || !strcmp (answer, "elg")) && addmode) { algo = PUBKEY_ALGO_ELGAMAL_E; *r_usage = PUBKEY_USAGE_ENC; break; } else if ((algo == 6 || !strcmp (answer, "rsa/e")) && addmode) { algo = PUBKEY_ALGO_RSA; *r_usage = PUBKEY_USAGE_ENC; break; } else if ((algo == 7 || !strcmp (answer, "dsa/*")) && opt.expert) { algo = PUBKEY_ALGO_DSA; *r_usage = ask_key_flags (algo, addmode, 0); break; } else if ((algo == 8 || !strcmp (answer, "rsa/*")) && opt.expert) { algo = PUBKEY_ALGO_RSA; *r_usage = ask_key_flags (algo, addmode, 0); break; } else if ((algo == 9 || !strcmp (answer, "ecc+ecc")) && !addmode) { algo = PUBKEY_ALGO_ECDSA; *r_subkey_algo = PUBKEY_ALGO_ECDH; break; } else if ((algo == 10 || !strcmp (answer, "ecc/s"))) { algo = PUBKEY_ALGO_ECDSA; *r_usage = PUBKEY_USAGE_SIG; break; } else if ((algo == 11 || !strcmp (answer, "ecc/*")) && opt.expert) { algo = PUBKEY_ALGO_ECDSA; *r_usage = ask_key_flags (algo, addmode, 0); break; } else if ((algo == 12 || !strcmp (answer, "ecc/e")) && addmode) { algo = PUBKEY_ALGO_ECDH; *r_usage = PUBKEY_USAGE_ENC; break; } else if ((algo == 13 || !strcmp (answer, "keygrip")) && opt.expert && r_keygrip) { for (;;) { xfree (answer); answer = cpr_get ("keygen.keygrip", _("Enter the keygrip: ")); cpr_kill_prompt (); trim_spaces (answer); if (!*answer) { xfree (answer); answer = NULL; continue; } if (strlen (answer) != 40 && !(answer[0] == '&' && strlen (answer+1) == 40)) tty_printf (_("Not a valid keygrip (expecting 40 hex digits)\n")); else if (!(algo = check_keygrip (ctrl, answer)) ) tty_printf (_("No key with this keygrip\n")); else break; /* Okay. */ } xfree (keygrip); keygrip = answer; answer = NULL; *r_usage = ask_key_flags (algo, addmode, 0); break; } else if ((algo == 14 || !strcmp (answer, "cardkey")) && r_keygrip) { char *serialno; keypair_info_t keypairlist, kpi; int count, selection; err = agent_scd_serialno (&serialno, NULL); if (err) { tty_printf (_("error reading the card: %s\n"), gpg_strerror (err)); goto ask_again; } tty_printf (_("Serial number of the card: %s\n"), serialno); xfree (serialno); err = agent_scd_keypairinfo (ctrl, NULL, &keypairlist); if (err) { tty_printf (_("error reading the card: %s\n"), gpg_strerror (err)); goto ask_again; } do { char *authkeyref, *encrkeyref, *signkeyref; agent_scd_getattr_one ("$AUTHKEYID", &authkeyref); agent_scd_getattr_one ("$ENCRKEYID", &encrkeyref); agent_scd_getattr_one ("$SIGNKEYID", &signkeyref); tty_printf (_("Available keys:\n")); for (count=1, kpi=keypairlist; kpi; kpi = kpi->next, count++) { gcry_sexp_t s_pkey; char *algostr = NULL; enum gcry_pk_algos algoid = 0; const char *keyref = kpi->idstr; int any = 0; if (keyref && !agent_scd_readkey (ctrl, keyref, &s_pkey, NULL)) { algostr = pubkey_algo_string (s_pkey, &algoid); gcry_sexp_release (s_pkey); } /* We need to tweak the algo in case GCRY_PK_ECC is * returned because pubkey_algo_string is not aware * of the OpenPGP algo mapping. We need to * distinguish between ECDH and ECDSA but we can do * that only if we got usage flags. * Note: Keep this in sync with parse_key_parameter_part. */ if (algoid == GCRY_PK_ECC && algostr) { if (!strcmp (algostr, "ed25519")) kpi->algo = PUBKEY_ALGO_EDDSA; else if (!strcmp (algostr, "ed448")) kpi->algo = PUBKEY_ALGO_EDDSA; else if (!strcmp (algostr, "cv25519")) kpi->algo = PUBKEY_ALGO_ECDH; else if (!strcmp (algostr, "cv448")) kpi->algo = PUBKEY_ALGO_ECDH; else if ((kpi->usage & GCRY_PK_USAGE_ENCR)) kpi->algo = PUBKEY_ALGO_ECDH; else kpi->algo = PUBKEY_ALGO_ECDSA; } else kpi->algo = map_gcry_pk_to_openpgp (algoid); tty_printf (" (%d) %s %s %s", count, kpi->keygrip, keyref, algostr); if ((kpi->usage & GCRY_PK_USAGE_CERT)) { tty_printf ("%scert", any?",":" ("); any = 1; } if ((kpi->usage & GCRY_PK_USAGE_SIGN)) { tty_printf ("%ssign%s", any?",":" (", (signkeyref && keyref && !strcmp (signkeyref, keyref))? "*":""); any = 1; } if ((kpi->usage & GCRY_PK_USAGE_AUTH)) { tty_printf ("%sauth%s", any?",":" (", (authkeyref && keyref && !strcmp (authkeyref, keyref))? "*":""); any = 1; } if ((kpi->usage & GCRY_PK_USAGE_ENCR)) { tty_printf ("%sencr%s", any?",":" (", (encrkeyref && keyref && !strcmp (encrkeyref, keyref))? "*":""); any = 1; } tty_printf ("%s\n", any?")":""); xfree (algostr); } xfree (answer); answer = cpr_get ("keygen.cardkey", _("Your selection? ")); cpr_kill_prompt (); trim_spaces (answer); selection = atoi (answer); xfree (authkeyref); xfree (encrkeyref); xfree (signkeyref); } while (!(selection > 0 && selection < count)); for (count=1,kpi=keypairlist; kpi; kpi = kpi->next, count++) if (count == selection) break; if (!kpi) { /* Just in case COUNT is zero (no keys). */ free_keypair_info (keypairlist); goto ask_again; } xfree (keygrip); keygrip = xstrdup (kpi->keygrip); cardkey = 1; algo = kpi->algo; keytime = kpi->keytime; /* In expert mode allow to change the usage flags. */ if (opt.expert) *r_usage = ask_key_flags_with_mask (algo, addmode, kpi->usage, kpi->usage); else { *r_usage = kpi->usage; if (addmode) *r_usage &= ~GCRY_PK_USAGE_CERT; } free_keypair_info (keypairlist); break; } else tty_printf (_("Invalid selection.\n")); ask_again: ; } xfree(answer); if (r_keygrip) *r_keygrip = keygrip; if (r_cardkey) *r_cardkey = cardkey; if (r_keytime) *r_keytime = keytime; return algo; } static unsigned int get_keysize_range (int algo, unsigned int *min, unsigned int *max) { unsigned int def; unsigned int dummy1, dummy2; if (!min) min = &dummy1; if (!max) max = &dummy2; switch(algo) { case PUBKEY_ALGO_DSA: *min = opt.expert? 768 : 1024; *max=3072; def=2048; break; case PUBKEY_ALGO_ECDSA: case PUBKEY_ALGO_ECDH: *min=256; *max=521; def=256; break; case PUBKEY_ALGO_EDDSA: *min=255; *max=441; def=255; break; default: *min = opt.compliance == CO_DE_VS ? 2048: 1024; *max = 4096; def = 3072; break; } return def; } /* Return a fixed up keysize depending on ALGO. */ static unsigned int fixup_keysize (unsigned int nbits, int algo, int silent) { if (algo == PUBKEY_ALGO_DSA && (nbits % 64)) { nbits = ((nbits + 63) / 64) * 64; if (!silent) tty_printf (_("rounded up to %u bits\n"), nbits); } else if (algo == PUBKEY_ALGO_EDDSA) { if (nbits != 255 && nbits != 441) { if (nbits < 256) nbits = 255; else nbits = 441; if (!silent) tty_printf (_("rounded to %u bits\n"), nbits); } } else if (algo == PUBKEY_ALGO_ECDH || algo == PUBKEY_ALGO_ECDSA) { if (nbits != 256 && nbits != 384 && nbits != 521) { if (nbits < 256) nbits = 256; else if (nbits < 384) nbits = 384; else nbits = 521; if (!silent) tty_printf (_("rounded to %u bits\n"), nbits); } } else if ((nbits % 32)) { nbits = ((nbits + 31) / 32) * 32; if (!silent) tty_printf (_("rounded up to %u bits\n"), nbits ); } return nbits; } /* Ask for the key size. ALGO is the algorithm. If PRIMARY_KEYSIZE is not 0, the function asks for the size of the encryption subkey. */ static unsigned ask_keysize (int algo, unsigned int primary_keysize) { unsigned int nbits; unsigned int min, def, max; int for_subkey = !!primary_keysize; int autocomp = 0; def = get_keysize_range (algo, &min, &max); if (primary_keysize && !opt.expert) { /* Deduce the subkey size from the primary key size. */ if (algo == PUBKEY_ALGO_DSA && primary_keysize > 3072) nbits = 3072; /* For performance reasons we don't support more than 3072 bit DSA. However we won't see this case anyway because DSA can't be used as an encryption subkey ;-). */ else nbits = primary_keysize; autocomp = 1; goto leave; } tty_printf(_("%s keys may be between %u and %u bits long.\n"), openpgp_pk_algo_name (algo), min, max); for (;;) { char *prompt, *answer; if (for_subkey) prompt = xasprintf (_("What keysize do you want " "for the subkey? (%u) "), def); else prompt = xasprintf (_("What keysize do you want? (%u) "), def); answer = cpr_get ("keygen.size", prompt); cpr_kill_prompt (); nbits = *answer? atoi (answer): def; xfree(prompt); xfree(answer); if(nbitsmax) tty_printf(_("%s keysizes must be in the range %u-%u\n"), openpgp_pk_algo_name (algo), min, max); else break; } tty_printf (_("Requested keysize is %u bits\n"), nbits); leave: nbits = fixup_keysize (nbits, algo, autocomp); return nbits; } /* Ask for the curve. ALGO is the selected algorithm which this function may adjust. Returns a const string of the name of the curve. */ const char * ask_curve (int *algo, int *subkey_algo, const char *current) { /* NB: We always use a complete algo list so that we have stable numbers in the menu regardless on how Gpg was configured. */ struct { const char *name; const char* eddsa_curve; /* Corresponding EdDSA curve. */ const char *pretty_name; unsigned int supported : 1; /* Supported by gpg. */ unsigned int de_vs : 1; /* Allowed in CO_DE_VS. */ unsigned int expert_only : 1; /* Only with --expert */ unsigned int available : 1; /* Available in Libycrypt (runtime checked) */ } curves[] = { #if GPG_USE_ECDSA || GPG_USE_ECDH # define MY_USE_ECDSADH 1 #else # define MY_USE_ECDSADH 0 #endif { "Curve25519", "Ed25519", "Curve 25519", !!GPG_USE_EDDSA, 0, 0, 0 }, { "X448", "Ed448", "Curve 448", !!GPG_USE_EDDSA, 0, 1, 0 }, { "NIST P-256", NULL, NULL, MY_USE_ECDSADH, 0, 1, 0 }, { "NIST P-384", NULL, NULL, MY_USE_ECDSADH, 0, 0, 0 }, { "NIST P-521", NULL, NULL, MY_USE_ECDSADH, 0, 1, 0 }, { "brainpoolP256r1", NULL, "Brainpool P-256", MY_USE_ECDSADH, 1, 0, 0 }, { "brainpoolP384r1", NULL, "Brainpool P-384", MY_USE_ECDSADH, 1, 1, 0 }, { "brainpoolP512r1", NULL, "Brainpool P-512", MY_USE_ECDSADH, 1, 1, 0 }, { "secp256k1", NULL, NULL, MY_USE_ECDSADH, 0, 1, 0 }, }; #undef MY_USE_ECDSADH int idx; char *answer; const char *result = NULL; gcry_sexp_t keyparms; tty_printf (_("Please select which elliptic curve you want:\n")); keyparms = NULL; for (idx=0; idx < DIM(curves); idx++) { int rc; curves[idx].available = 0; if (!curves[idx].supported) continue; if (opt.compliance==CO_DE_VS) { if (!curves[idx].de_vs) continue; /* Not allowed. */ } else if (!opt.expert && curves[idx].expert_only) continue; /* We need to switch from the ECDH name of the curve to the EDDSA name of the curve if we want a signing key. */ gcry_sexp_release (keyparms); rc = gcry_sexp_build (&keyparms, NULL, "(public-key(ecc(curve %s)))", curves[idx].eddsa_curve? curves[idx].eddsa_curve /**/ : curves[idx].name); if (rc) continue; if (!gcry_pk_get_curve (keyparms, 0, NULL)) continue; if (subkey_algo && curves[idx].eddsa_curve) { /* Both Curve 25519 (or 448) keys are to be created. Check that Libgcrypt also supports the real Curve25519 (or 448). */ gcry_sexp_release (keyparms); rc = gcry_sexp_build (&keyparms, NULL, "(public-key(ecc(curve %s)))", curves[idx].name); if (rc) continue; if (!gcry_pk_get_curve (keyparms, 0, NULL)) continue; } curves[idx].available = 1; tty_printf (" (%d) %s%s\n", idx + 1, curves[idx].pretty_name? curves[idx].pretty_name:curves[idx].name, idx == 0? _(" *default*"):""); } gcry_sexp_release (keyparms); for (;;) { answer = cpr_get ("keygen.curve", _("Your selection? ")); cpr_kill_prompt (); idx = *answer? atoi (answer) : 1; if (!*answer && current) { xfree(answer); return NULL; } else if (*answer && !idx) { /* See whether the user entered the name of the curve. */ for (idx=0; idx < DIM(curves); idx++) { if (!opt.expert && curves[idx].expert_only) continue; if (!stricmp (curves[idx].name, answer) || (curves[idx].pretty_name && !stricmp (curves[idx].pretty_name, answer))) break; } if (idx == DIM(curves)) idx = -1; } else idx--; xfree(answer); answer = NULL; if (idx < 0 || idx >= DIM (curves) || !curves[idx].available) tty_printf (_("Invalid selection.\n")); else { /* If the user selected a signing algorithm and Curve25519 we need to set the algo to EdDSA and update the curve name. If switching away from EdDSA, we need to set the algo back to ECDSA. */ if (*algo == PUBKEY_ALGO_ECDSA || *algo == PUBKEY_ALGO_EDDSA) { if (curves[idx].eddsa_curve) { if (subkey_algo && *subkey_algo == PUBKEY_ALGO_ECDSA) *subkey_algo = PUBKEY_ALGO_EDDSA; *algo = PUBKEY_ALGO_EDDSA; result = curves[idx].eddsa_curve; } else { if (subkey_algo && *subkey_algo == PUBKEY_ALGO_EDDSA) *subkey_algo = PUBKEY_ALGO_ECDSA; *algo = PUBKEY_ALGO_ECDSA; result = curves[idx].name; } } else result = curves[idx].name; break; } } if (!result) result = curves[0].name; return result; } /**************** * Parse an expire string and return its value in seconds. * Returns (u32)-1 on error. * This isn't perfect since scan_isodatestr returns unix time, and * OpenPGP actually allows a 32-bit time *plus* a 32-bit offset. * Because of this, we only permit setting expirations up to 2106, but * OpenPGP could theoretically allow up to 2242. I think we'll all * just cope for the next few years until we get a 64-bit time_t or * similar. */ u32 parse_expire_string( const char *string ) { int mult; u32 seconds; u32 abs_date = 0; u32 curtime = make_timestamp (); time_t tt; if (!string || !*string || !strcmp (string, "none") || !strcmp (string, "never") || !strcmp (string, "-")) seconds = 0; else if (!strncmp (string, "seconds=", 8)) seconds = atoi (string+8); else if ((abs_date = scan_isodatestr(string)) && (abs_date+86400/2) > curtime) seconds = (abs_date+86400/2) - curtime; else if ((tt = isotime2epoch (string)) != (time_t)(-1)) seconds = (u32)tt - curtime; else if ((mult = check_valid_days (string))) seconds = atoi (string) * 86400L * mult; else seconds = (u32)(-1); return seconds; } /* Parse a Creation-Date string which is either "1986-04-26" or "19860426T042640". Returns 0 on error. */ static u32 parse_creation_string (const char *string) { u32 seconds; if (!*string) seconds = 0; else if ( !strncmp (string, "seconds=", 8) ) seconds = atoi (string+8); else if ( !(seconds = scan_isodatestr (string))) { time_t tmp = isotime2epoch (string); seconds = (tmp == (time_t)(-1))? 0 : tmp; } return seconds; } /* object == 0 for a key, and 1 for a sig */ u32 ask_expire_interval(int object,const char *def_expire) { u32 interval; char *answer; switch(object) { case 0: if(def_expire) BUG(); tty_printf(_("Please specify how long the key should be valid.\n" " 0 = key does not expire\n" " = key expires in n days\n" " w = key expires in n weeks\n" " m = key expires in n months\n" " y = key expires in n years\n")); break; case 1: if(!def_expire) BUG(); tty_printf(_("Please specify how long the signature should be valid.\n" " 0 = signature does not expire\n" " = signature expires in n days\n" " w = signature expires in n weeks\n" " m = signature expires in n months\n" " y = signature expires in n years\n")); break; default: BUG(); } /* Note: The elgamal subkey for DSA has no expiration date because * it must be signed with the DSA key and this one has the expiration * date */ answer = NULL; for(;;) { u32 curtime; xfree(answer); if(object==0) answer = cpr_get("keygen.valid",_("Key is valid for? (0) ")); else { char *prompt; prompt = xasprintf (_("Signature is valid for? (%s) "), def_expire); answer = cpr_get("siggen.valid",prompt); xfree(prompt); if(*answer=='\0') { xfree (answer); answer = xstrdup (def_expire); } } cpr_kill_prompt(); trim_spaces(answer); curtime = make_timestamp (); interval = parse_expire_string( answer ); if( interval == (u32)-1 ) { tty_printf(_("invalid value\n")); continue; } if( !interval ) { tty_printf((object==0) ? _("Key does not expire at all\n") : _("Signature does not expire at all\n")); } else { tty_printf(object==0 ? _("Key expires at %s\n") : _("Signature expires at %s\n"), asctimestamp((ulong)(curtime + interval) ) ); #if SIZEOF_TIME_T <= 4 && !defined (HAVE_UNSIGNED_TIME_T) if ( (time_t)((ulong)(curtime+interval)) < 0 ) tty_printf (_("Your system can't display dates beyond 2038.\n" "However, it will be correctly handled up to" " 2106.\n")); else #endif /*SIZEOF_TIME_T*/ if ( (time_t)((unsigned long)(curtime+interval)) < curtime ) { tty_printf (_("invalid value\n")); continue; } } if( cpr_enabled() || cpr_get_answer_is_yes("keygen.valid.okay", _("Is this correct? (y/N) ")) ) break; } xfree(answer); return interval; } u32 ask_expiredate (void) { u32 x = ask_expire_interval(0,NULL); return x? make_timestamp() + x : 0; } static PKT_user_id * uid_from_string (const char *string) { size_t n; PKT_user_id *uid; n = strlen (string); uid = xmalloc_clear (sizeof *uid + n); uid->len = n; strcpy (uid->name, string); uid->ref = 1; return uid; } /* Return true if the user id UID already exists in the keyblock. */ static int uid_already_in_keyblock (kbnode_t keyblock, const char *uid) { PKT_user_id *uidpkt = uid_from_string (uid); kbnode_t node; int result = 0; for (node=keyblock; node && !result; node=node->next) if (!is_deleted_kbnode (node) && node->pkt->pkttype == PKT_USER_ID && !cmp_user_ids (uidpkt, node->pkt->pkt.user_id)) result = 1; free_user_id (uidpkt); return result; } /* Ask for a user ID. With a MODE of 1 an extra help prompt is printed for use during a new key creation. If KEYBLOCK is not NULL the function prevents the creation of an already existing user ID. IF FULL is not set some prompts are not shown. */ static char * ask_user_id (int mode, int full, KBNODE keyblock) { char *answer; char *aname, *acomment, *amail, *uid; if ( !mode ) { /* TRANSLATORS: This is the new string telling the user what gpg is now going to do (i.e. ask for the parts of the user ID). Note that if you do not translate this string, a different string will be used, which might still have a correct translation. */ const char *s1 = N_("\n" "GnuPG needs to construct a user ID to identify your key.\n" "\n"); const char *s2 = _(s1); if (!strcmp (s1, s2)) { /* There is no translation for the string thus we to use the old info text. gettext has no way to tell whether a translation is actually available, thus we need to to compare again. */ /* TRANSLATORS: This string is in general not anymore used but you should keep your existing translation. In case the new string is not translated this old string will be used. */ const char *s3 = N_("\n" "You need a user ID to identify your key; " "the software constructs the user ID\n" "from the Real Name, Comment and Email Address in this form:\n" " \"Heinrich Heine (Der Dichter) \"\n\n"); const char *s4 = _(s3); if (strcmp (s3, s4)) s2 = s3; /* A translation exists - use it. */ } tty_printf ("%s", s2) ; } uid = aname = acomment = amail = NULL; for(;;) { char *p; int fail=0; if( !aname ) { for(;;) { xfree(aname); aname = cpr_get("keygen.name",_("Real name: ")); trim_spaces(aname); cpr_kill_prompt(); if( opt.allow_freeform_uid ) break; if( strpbrk( aname, "<>" ) ) { tty_printf(_("Invalid character in name\n")); tty_printf(_("The characters '%s' and '%s' may not " "appear in name\n"), "<", ">"); } else break; } } if( !amail ) { for(;;) { xfree(amail); amail = cpr_get("keygen.email",_("Email address: ")); trim_spaces(amail); cpr_kill_prompt(); if( !*amail || opt.allow_freeform_uid ) break; /* no email address is okay */ else if ( !is_valid_mailbox (amail) ) tty_printf(_("Not a valid email address\n")); else break; } } if (!acomment) { if (full) { for(;;) { xfree(acomment); acomment = cpr_get("keygen.comment",_("Comment: ")); trim_spaces(acomment); cpr_kill_prompt(); if( !*acomment ) break; /* no comment is okay */ else if( strpbrk( acomment, "()" ) ) tty_printf(_("Invalid character in comment\n")); else break; } } else { xfree (acomment); acomment = xstrdup (""); } } xfree(uid); uid = p = xmalloc(strlen(aname)+strlen(amail)+strlen(acomment)+12+10); if (!*aname && *amail && !*acomment && !random_is_faked ()) { /* Empty name and comment but with mail address. Use simplified form with only the non-angle-bracketed mail address. */ p = stpcpy (p, amail); } else { p = stpcpy (p, aname ); if (*acomment) p = stpcpy(stpcpy(stpcpy(p," ("), acomment),")"); if (*amail) p = stpcpy(stpcpy(stpcpy(p," <"), amail),">"); } /* Append a warning if the RNG is switched into fake mode. */ if ( random_is_faked () ) strcpy(p, " (insecure!)" ); /* print a note in case that UTF8 mapping has to be done */ for(p=uid; *p; p++ ) { if( *p & 0x80 ) { tty_printf(_("You are using the '%s' character set.\n"), get_native_charset() ); break; } } tty_printf(_("You selected this USER-ID:\n \"%s\"\n\n"), uid); if( !*amail && !opt.allow_freeform_uid && (strchr( aname, '@' ) || strchr( acomment, '@'))) { fail = 1; tty_printf(_("Please don't put the email address " "into the real name or the comment\n") ); } if (!fail && keyblock) { if (uid_already_in_keyblock (keyblock, uid)) { tty_printf (_("Such a user ID already exists on this key!\n")); fail = 1; } } for(;;) { /* TRANSLATORS: These are the allowed answers in lower and uppercase. Below you will find the matching string which should be translated accordingly and the letter changed to match the one in the answer string. n = Change name c = Change comment e = Change email o = Okay (ready, continue) q = Quit */ const char *ansstr = _("NnCcEeOoQq"); if( strlen(ansstr) != 10 ) BUG(); if( cpr_enabled() ) { answer = xstrdup (ansstr + (fail?8:6)); answer[1] = 0; } else if (full) { answer = cpr_get("keygen.userid.cmd", fail? _("Change (N)ame, (C)omment, (E)mail or (Q)uit? ") : _("Change (N)ame, (C)omment, (E)mail or (O)kay/(Q)uit? ")); cpr_kill_prompt(); } else { answer = cpr_get("keygen.userid.cmd", fail? _("Change (N)ame, (E)mail, or (Q)uit? ") : _("Change (N)ame, (E)mail, or (O)kay/(Q)uit? ")); cpr_kill_prompt(); } if( strlen(answer) > 1 ) ; else if( *answer == ansstr[0] || *answer == ansstr[1] ) { xfree(aname); aname = NULL; break; } else if( *answer == ansstr[2] || *answer == ansstr[3] ) { xfree(acomment); acomment = NULL; break; } else if( *answer == ansstr[4] || *answer == ansstr[5] ) { xfree(amail); amail = NULL; break; } else if( *answer == ansstr[6] || *answer == ansstr[7] ) { if( fail ) { tty_printf(_("Please correct the error first\n")); } else { xfree(aname); aname = NULL; xfree(acomment); acomment = NULL; xfree(amail); amail = NULL; break; } } else if( *answer == ansstr[8] || *answer == ansstr[9] ) { xfree(aname); aname = NULL; xfree(acomment); acomment = NULL; xfree(amail); amail = NULL; xfree(uid); uid = NULL; break; } xfree(answer); } xfree(answer); if (!amail && !acomment) break; xfree(uid); uid = NULL; } if( uid ) { char *p = native_to_utf8( uid ); xfree( uid ); uid = p; } return uid; } /* Basic key generation. Here we divert to the actual generation routines based on the requested algorithm. */ static int do_create (int algo, unsigned int nbits, const char *curve, kbnode_t pub_root, u32 timestamp, u32 expiredate, int is_subkey, int keygen_flags, const char *passphrase, char **cache_nonce_addr, char **passwd_nonce_addr) { gpg_error_t err; /* Fixme: The entropy collecting message should be moved to a libgcrypt progress handler. */ if (!opt.batch) tty_printf (_( "We need to generate a lot of random bytes. It is a good idea to perform\n" "some other action (type on the keyboard, move the mouse, utilize the\n" "disks) during the prime generation; this gives the random number\n" "generator a better chance to gain enough entropy.\n") ); if (algo == PUBKEY_ALGO_ELGAMAL_E) err = gen_elg (algo, nbits, pub_root, timestamp, expiredate, is_subkey, keygen_flags, passphrase, cache_nonce_addr, passwd_nonce_addr); else if (algo == PUBKEY_ALGO_DSA) err = gen_dsa (nbits, pub_root, timestamp, expiredate, is_subkey, keygen_flags, passphrase, cache_nonce_addr, passwd_nonce_addr); else if (algo == PUBKEY_ALGO_ECDSA || algo == PUBKEY_ALGO_EDDSA || algo == PUBKEY_ALGO_ECDH) err = gen_ecc (algo, curve, pub_root, timestamp, expiredate, is_subkey, keygen_flags, passphrase, cache_nonce_addr, passwd_nonce_addr); else if (algo == PUBKEY_ALGO_RSA) err = gen_rsa (algo, nbits, pub_root, timestamp, expiredate, is_subkey, keygen_flags, passphrase, cache_nonce_addr, passwd_nonce_addr); else BUG(); return err; } /* Generate a new user id packet or return NULL if canceled. If KEYBLOCK is not NULL the function prevents the creation of an already existing user ID. If UIDSTR is not NULL the user is not asked but UIDSTR is used to create the user id packet; if the user id already exists NULL is returned. UIDSTR is expected to be utf-8 encoded and should have already been checked for a valid length etc. */ PKT_user_id * generate_user_id (KBNODE keyblock, const char *uidstr) { PKT_user_id *uid; char *p; if (uidstr) { if (uid_already_in_keyblock (keyblock, uidstr)) return NULL; /* Already exists. */ uid = uid_from_string (uidstr); } else { p = ask_user_id (1, 1, keyblock); if (!p) return NULL; /* Canceled. */ uid = uid_from_string (p); xfree (p); } return uid; } /* Helper for parse_key_parameter_part_parameter_string for one part of the * specification string; i.e. ALGO/FLAGS. If STRING is NULL or empty * success is returned. On error an error code is returned. Note * that STRING may be modified by this function. NULL may be passed * for any parameter. FOR_SUBKEY shall be true if this is used as a * subkey. If CLEAR_CERT is set a default CERT usage will be cleared; * this is useful if for example the default algorithm is used for a * subkey. If R_KEYVERSION is not NULL it will receive the version of * the key; this is currently 4 but can be changed with the flag "v5" * to create a v5 key. If R_KEYTIME is not NULL and the key has been * taken from active OpenPGP card, its creation time is stored * there. */ static gpg_error_t parse_key_parameter_part (ctrl_t ctrl, char *string, int for_subkey, int clear_cert, int *r_algo, unsigned int *r_size, unsigned int *r_keyuse, char const **r_curve, int *r_keyversion, char **r_keygrip, u32 *r_keytime) { gpg_error_t err; char *flags; int algo; char *endp; const char *curve = NULL; int ecdh_or_ecdsa = 0; unsigned int size; int keyuse; int keyversion = 0; /* Not specified. */ int i; const char *s; int from_card = 0; char *keygrip = NULL; u32 keytime = 0; int is_448 = 0; if (!string || !*string) return 0; /* Success. */ flags = strchr (string, '/'); if (flags) *flags++ = 0; algo = 0; if (!ascii_strcasecmp (string, "card")) from_card = 1; else if (strlen (string) >= 3 && (digitp (string+3) || !string[3])) { if (!ascii_memcasecmp (string, "rsa", 3)) algo = PUBKEY_ALGO_RSA; else if (!ascii_memcasecmp (string, "dsa", 3)) algo = PUBKEY_ALGO_DSA; else if (!ascii_memcasecmp (string, "elg", 3)) algo = PUBKEY_ALGO_ELGAMAL_E; } if (from_card) ; /* We need the flags before we can figure out the key to use. */ else if (algo) { if (!string[3]) size = get_keysize_range (algo, NULL, NULL); else { size = strtoul (string+3, &endp, 10); if (size < 512 || size > 16384 || *endp) return gpg_error (GPG_ERR_INV_VALUE); } } else if ((curve = openpgp_is_curve_supported (string, &algo, &size))) { if (!algo) { algo = PUBKEY_ALGO_ECDH; /* Default ECC algorithm. */ ecdh_or_ecdsa = 1; /* We may need to switch the algo. */ } if (curve && (!strcmp (curve, "X448") || !strcmp (curve, "Ed448"))) is_448 = 1; } else return gpg_error (GPG_ERR_UNKNOWN_CURVE); /* Parse the flags. */ keyuse = 0; if (flags) { char **tokens = NULL; tokens = strtokenize (flags, ","); if (!tokens) return gpg_error_from_syserror (); for (i=0; (s = tokens[i]); i++) { if (!*s) ; else if (!ascii_strcasecmp (s, "sign")) keyuse |= PUBKEY_USAGE_SIG; else if (!ascii_strcasecmp (s, "encrypt") || !ascii_strcasecmp (s, "encr")) keyuse |= PUBKEY_USAGE_ENC; else if (!ascii_strcasecmp (s, "auth")) keyuse |= PUBKEY_USAGE_AUTH; else if (!ascii_strcasecmp (s, "cert")) keyuse |= PUBKEY_USAGE_CERT; else if (!ascii_strcasecmp (s, "ecdsa") && !from_card) { if (algo == PUBKEY_ALGO_ECDH || algo == PUBKEY_ALGO_ECDSA) algo = PUBKEY_ALGO_ECDSA; else { xfree (tokens); return gpg_error (GPG_ERR_INV_FLAG); } ecdh_or_ecdsa = 0; } else if (!ascii_strcasecmp (s, "ecdh") && !from_card) { if (algo == PUBKEY_ALGO_ECDH || algo == PUBKEY_ALGO_ECDSA) algo = PUBKEY_ALGO_ECDH; else { xfree (tokens); return gpg_error (GPG_ERR_INV_FLAG); } ecdh_or_ecdsa = 0; } else if (!ascii_strcasecmp (s, "eddsa") && !from_card) { /* Not required but we allow it for consistency. */ if (algo == PUBKEY_ALGO_EDDSA) ; else { xfree (tokens); return gpg_error (GPG_ERR_INV_FLAG); } } else if (!ascii_strcasecmp (s, "v5")) keyversion = 5; else if (!ascii_strcasecmp (s, "v4")) keyversion = 4; else { xfree (tokens); return gpg_error (GPG_ERR_UNKNOWN_FLAG); } } xfree (tokens); } /* If not yet decided switch between ecdh and ecdsa unless we want * to read the algo from the current card. */ if (from_card) { keypair_info_t keypairlist, kpi; char *reqkeyref; if (!keyuse) keyuse = (for_subkey? PUBKEY_USAGE_ENC /* */ : (PUBKEY_USAGE_CERT|PUBKEY_USAGE_SIG)); /* Access the card to make sure we have one and to show the S/N. */ { char *serialno; err = agent_scd_serialno (&serialno, NULL); if (err) { log_error (_("error reading the card: %s\n"), gpg_strerror (err)); return err; } if (!opt.quiet) log_info (_("Serial number of the card: %s\n"), serialno); xfree (serialno); } err = agent_scd_keypairinfo (ctrl, NULL, &keypairlist); if (err) { log_error (_("error reading the card: %s\n"), gpg_strerror (err)); return err; } agent_scd_getattr_one ((keyuse & (PUBKEY_USAGE_SIG|PUBKEY_USAGE_CERT)) ? "$SIGNKEYID":"$ENCRKEYID", &reqkeyref); algo = 0; /* Should already be the case. */ for (kpi=keypairlist; kpi && !algo; kpi = kpi->next) { gcry_sexp_t s_pkey; char *algostr = NULL; enum gcry_pk_algos algoid = 0; const char *keyref = kpi->idstr; if (!reqkeyref) continue; /* Card does not provide the info (skip all). */ if (!keyref) continue; /* Ooops. */ if (strcmp (reqkeyref, keyref)) continue; /* This is not the requested keyref. */ if ((keyuse & (PUBKEY_USAGE_SIG|PUBKEY_USAGE_CERT)) && (kpi->usage & (GCRY_PK_USAGE_SIGN|GCRY_PK_USAGE_CERT))) ; /* Okay */ else if ((keyuse & PUBKEY_USAGE_ENC) && (kpi->usage & GCRY_PK_USAGE_ENCR)) ; /* Okay */ else continue; /* Not usable for us. */ if (agent_scd_readkey (ctrl, keyref, &s_pkey, NULL)) continue; /* Could not read the key. */ algostr = pubkey_algo_string (s_pkey, &algoid); gcry_sexp_release (s_pkey); /* Map to OpenPGP algo number. * We need to tweak the algo in case GCRY_PK_ECC is * returned because pubkey_algo_string is not aware * of the OpenPGP algo mapping. We need to * distinguish between ECDH and ECDSA but we can do * that only if we got usage flags. * Note: Keep this in sync with ask_algo. */ if (algoid == GCRY_PK_ECC && algostr) { if (!strcmp (algostr, "ed25519")) algo = PUBKEY_ALGO_EDDSA; else if (!strcmp (algostr, "ed448")) { algo = PUBKEY_ALGO_EDDSA; is_448 = 1; } else if (!strcmp (algostr, "cv25519")) algo = PUBKEY_ALGO_ECDH; else if (!strcmp (algostr, "cv448")) { algo = PUBKEY_ALGO_ECDH; is_448 = 1; } else if ((kpi->usage & GCRY_PK_USAGE_ENCR)) algo = PUBKEY_ALGO_ECDH; else algo = PUBKEY_ALGO_ECDSA; } else algo = map_gcry_pk_to_openpgp (algoid); xfree (algostr); xfree (keygrip); keygrip = xtrystrdup (kpi->keygrip); if (!keygrip) { err = gpg_error_from_syserror (); xfree (reqkeyref); free_keypair_info (keypairlist); return err; } keytime = kpi->keytime; } xfree (reqkeyref); free_keypair_info (keypairlist); if (!algo || !keygrip) { err = gpg_error (GPG_ERR_PUBKEY_ALGO); log_error ("no usable key on the card: %s\n", gpg_strerror (err)); xfree (keygrip); return err; } } else if (ecdh_or_ecdsa && keyuse) algo = (keyuse & PUBKEY_USAGE_ENC)? PUBKEY_ALGO_ECDH : PUBKEY_ALGO_ECDSA; else if (ecdh_or_ecdsa) algo = for_subkey? PUBKEY_ALGO_ECDH : PUBKEY_ALGO_ECDSA; /* Set or fix key usage. */ if (!keyuse) { if (algo == PUBKEY_ALGO_ECDSA || algo == PUBKEY_ALGO_EDDSA || algo == PUBKEY_ALGO_DSA) keyuse = PUBKEY_USAGE_SIG; else if (algo == PUBKEY_ALGO_RSA) keyuse = for_subkey? PUBKEY_USAGE_ENC : PUBKEY_USAGE_SIG; else keyuse = PUBKEY_USAGE_ENC; } else if (algo == PUBKEY_ALGO_ECDSA || algo == PUBKEY_ALGO_EDDSA || algo == PUBKEY_ALGO_DSA) { keyuse &= ~PUBKEY_USAGE_ENC; /* Forbid encryption. */ } else if (algo == PUBKEY_ALGO_ECDH || algo == PUBKEY_ALGO_ELGAMAL_E) { keyuse = PUBKEY_USAGE_ENC; /* Allow only encryption. */ } /* Make sure a primary key can certify. */ if (!for_subkey) keyuse |= PUBKEY_USAGE_CERT; /* But if requested remove th cert usage. */ if (clear_cert) keyuse &= ~PUBKEY_USAGE_CERT; /* Check that usage is actually possible. */ if (/**/((keyuse & (PUBKEY_USAGE_SIG|PUBKEY_USAGE_AUTH|PUBKEY_USAGE_CERT)) && !pubkey_get_nsig (algo)) || ((keyuse & PUBKEY_USAGE_ENC) && !pubkey_get_nenc (algo)) || (for_subkey && (keyuse & PUBKEY_USAGE_CERT))) { xfree (keygrip); return gpg_error (GPG_ERR_WRONG_KEY_USAGE); } /* Ed448 and X448 must only be used as v5 keys. */ if (is_448) { if (keyversion == 4) log_info (_("WARNING: v4 is specified, but overridden by v5.\n")); keyversion = 5; } else if (keyversion == 0) keyversion = 4; /* Return values. */ if (r_algo) *r_algo = algo; if (r_size) { unsigned int min, def, max; /* Make sure the keysize is in the allowed range. */ def = get_keysize_range (algo, &min, &max); if (!size) size = def; else if (size < min) size = min; else if (size > max) size = max; *r_size = fixup_keysize (size, algo, 1); } if (r_keyuse) *r_keyuse = keyuse; if (r_curve) *r_curve = curve; if (r_keyversion) *r_keyversion = keyversion; if (r_keygrip) *r_keygrip = keygrip; else xfree (keygrip); if (r_keytime) *r_keytime = keytime; return 0; } /* Parse and return the standard key generation parameter. * The string is expected to be in this format: * * ALGO[/FLAGS][+SUBALGO[/FLAGS]] * * Here ALGO is a string in the same format as printed by the * keylisting. For example: * * rsa3072 := RSA with 3072 bit. * dsa2048 := DSA with 2048 bit. * elg2048 := Elgamal with 2048 bit. * ed25519 := EDDSA using curve Ed25519. * ed448 := EDDSA using curve Ed448. * cv25519 := ECDH using curve Curve25519. * cv448 := ECDH using curve X448. * nistp256:= ECDSA or ECDH using curve NIST P-256 * * All strings with an unknown prefix are considered an elliptic * curve. Curves which have no implicit algorithm require that FLAGS * is given to select whether ECDSA or ECDH is used; this can either * be done using an algorithm keyword or usage keywords. * * FLAGS is a comma delimited string of keywords: * * cert := Allow usage Certify * sign := Allow usage Sign * encr := Allow usage Encrypt * auth := Allow usage Authentication * encrypt := Alias for "encr" * ecdsa := Use algorithm ECDSA. * eddsa := Use algorithm EdDSA. * ecdh := Use algorithm ECDH. * v5 := Create version 5 key * * There are several defaults and fallbacks depending on the * algorithm. PART can be used to select which part of STRING is * used: * -1 := Both parts * 0 := Only the part of the primary key * 1 := If there is one part parse that one, if there are * two parts parse the part which best matches the * SUGGESTED_USE or in case that can't be evaluated the second part. * Always return using the args for the primary key (R_ALGO,....). * */ gpg_error_t parse_key_parameter_string (ctrl_t ctrl, const char *string, int part, unsigned int suggested_use, int *r_algo, unsigned int *r_size, unsigned int *r_keyuse, char const **r_curve, int *r_version, char **r_keygrip, u32 *r_keytime, int *r_subalgo, unsigned int *r_subsize, unsigned int *r_subkeyuse, char const **r_subcurve, int *r_subversion, char **r_subkeygrip, u32 *r_subkeytime) { gpg_error_t err = 0; char *primary, *secondary; if (r_algo) *r_algo = 0; if (r_size) *r_size = 0; if (r_keyuse) *r_keyuse = 0; if (r_curve) *r_curve = NULL; if (r_version) *r_version = 4; if (r_keygrip) *r_keygrip = NULL; if (r_keytime) *r_keytime = 0; if (r_subalgo) *r_subalgo = 0; if (r_subsize) *r_subsize = 0; if (r_subkeyuse) *r_subkeyuse = 0; if (r_subcurve) *r_subcurve = NULL; if (r_subversion) *r_subversion = 4; if (r_subkeygrip) *r_subkeygrip = NULL; if (r_subkeytime) *r_subkeytime = 0; if (!string || !*string || !ascii_strcasecmp (string, "default") || !strcmp (string, "-")) string = get_default_pubkey_algo (); else if (!ascii_strcasecmp (string, "future-default") || !ascii_strcasecmp (string, "futuredefault")) string = FUTURE_STD_KEY_PARAM; else if (!ascii_strcasecmp (string, "card")) string = "card/cert,sign+card/encr"; primary = xstrdup (string); secondary = strchr (primary, '+'); if (secondary) *secondary++ = 0; if (part == -1 || part == 0) { err = parse_key_parameter_part (ctrl, primary, 0, 0, r_algo, r_size, r_keyuse, r_curve, r_version, r_keygrip, r_keytime); if (!err && part == -1) err = parse_key_parameter_part (ctrl, secondary, 1, 0, r_subalgo, r_subsize, r_subkeyuse, r_subcurve, r_subversion, r_subkeygrip, r_subkeytime); } else if (part == 1) { /* If we have SECONDARY, use that part. If there is only one * part consider this to be the subkey algo. In case a * SUGGESTED_USE has been given and the usage of the secondary * part does not match SUGGESTED_USE try again using the primary * part. Note that when falling back to the primary key we need * to force clearing the cert usage. */ if (secondary) { err = parse_key_parameter_part (ctrl, secondary, 1, 0, r_algo, r_size, r_keyuse, r_curve, r_version, r_keygrip, r_keytime); if (!err && suggested_use && r_keyuse && !(suggested_use & *r_keyuse)) err = parse_key_parameter_part (ctrl, primary, 1, 1 /*(clear cert)*/, r_algo, r_size, r_keyuse, r_curve, r_version, r_keygrip, r_keytime); } else err = parse_key_parameter_part (ctrl, primary, 1, 0, r_algo, r_size, r_keyuse, r_curve, r_version, r_keygrip, r_keytime); } xfree (primary); return err; } /* Append R to the linked list PARA. */ static void append_to_parameter (struct para_data_s *para, struct para_data_s *r) { log_assert (para); while (para->next) para = para->next; para->next = r; } /* Release the parameter list R. */ static void release_parameter_list (struct para_data_s *r) { struct para_data_s *r2; for (; r ; r = r2) { r2 = r->next; if (r->key == pPASSPHRASE && *r->u.value) wipememory (r->u.value, strlen (r->u.value)); xfree (r); } } static struct para_data_s * get_parameter( struct para_data_s *para, enum para_name key ) { struct para_data_s *r; for( r = para; r && r->key != key; r = r->next ) ; return r; } static const char * get_parameter_value( struct para_data_s *para, enum para_name key ) { struct para_data_s *r = get_parameter( para, key ); return (r && *r->u.value)? r->u.value : NULL; } /* This is similar to get_parameter_value but also returns the empty string. This is required so that quick_generate_keypair can use an empty Passphrase to specify no-protection. */ static const char * get_parameter_passphrase (struct para_data_s *para) { struct para_data_s *r = get_parameter (para, pPASSPHRASE); return r ? r->u.value : NULL; } static int get_parameter_algo (ctrl_t ctrl, struct para_data_s *para, enum para_name key, int *r_default) { int i; struct para_data_s *r = get_parameter( para, key ); if (r_default) *r_default = 0; if (!r) return -1; /* Note that we need to handle the ECC algorithms specified as strings directly because Libgcrypt folds them all to ECC. */ if (!ascii_strcasecmp (r->u.value, "default")) { /* Note: If you change this default algo, remember to change it * also in gpg.c:gpgconf_list. */ /* FIXME: We only allow the algo here and have a separate thing * for the curve etc. That is a ugly but demanded for backward * compatibility with the batch key generation. It would be * better to make full use of parse_key_parameter_string. */ parse_key_parameter_string (ctrl, NULL, 0, 0, &i, NULL, NULL, NULL, NULL, NULL, NULL, NULL, NULL, NULL, NULL, NULL, NULL, NULL); if (r_default) *r_default = 1; } else if (digitp (r->u.value)) i = atoi( r->u.value ); else if (!strcmp (r->u.value, "ELG-E") || !strcmp (r->u.value, "ELG")) i = PUBKEY_ALGO_ELGAMAL_E; else if (!ascii_strcasecmp (r->u.value, "EdDSA")) i = PUBKEY_ALGO_EDDSA; else if (!ascii_strcasecmp (r->u.value, "ECDSA")) i = PUBKEY_ALGO_ECDSA; else if (!ascii_strcasecmp (r->u.value, "ECDH")) i = PUBKEY_ALGO_ECDH; else i = map_gcry_pk_to_openpgp (gcry_pk_map_name (r->u.value)); if (i == PUBKEY_ALGO_RSA_E || i == PUBKEY_ALGO_RSA_S) i = 0; /* we don't want to allow generation of these algorithms */ return i; } /* Parse a usage string. The usage keywords "auth", "sign", "encr" * may be delimited by space, tab, or comma. On error -1 is returned * instead of the usage flags. */ static int parse_usagestr (const char *usagestr) { gpg_error_t err; char **tokens = NULL; const char *s; int i; unsigned int use = 0; tokens = strtokenize (usagestr, " \t,"); if (!tokens) { err = gpg_error_from_syserror (); log_error ("strtokenize failed: %s\n", gpg_strerror (err)); return -1; } for (i=0; (s = tokens[i]); i++) { if (!*s) ; else if (!ascii_strcasecmp (s, "sign")) use |= PUBKEY_USAGE_SIG; else if (!ascii_strcasecmp (s, "encrypt") || !ascii_strcasecmp (s, "encr")) use |= PUBKEY_USAGE_ENC; else if (!ascii_strcasecmp (s, "auth")) use |= PUBKEY_USAGE_AUTH; else if (!ascii_strcasecmp (s, "cert")) use |= PUBKEY_USAGE_CERT; else if (!ascii_strcasecmp (s, "renc")) use |= PUBKEY_USAGE_RENC; else if (!ascii_strcasecmp (s, "time")) use |= PUBKEY_USAGE_TIME; else if (!ascii_strcasecmp (s, "group")) use |= PUBKEY_USAGE_GROUP; else { xfree (tokens); return -1; /* error */ } } xfree (tokens); return use; } /* * Parse the usage parameter and set the keyflags. Returns -1 on * error, 0 for no usage given or 1 for usage available. */ static int parse_parameter_usage (const char *fname, struct para_data_s *para, enum para_name key) { struct para_data_s *r = get_parameter( para, key ); int i; if (!r) return 0; /* none (this is an optional parameter)*/ i = parse_usagestr (r->u.value); if (i == -1) { log_error ("%s:%d: invalid usage list\n", fname, r->lnr ); return -1; /* error */ } r->u.usage = i; return 1; } static int parse_revocation_key (const char *fname, struct para_data_s *para, enum para_name key) { struct para_data_s *r = get_parameter( para, key ); struct revocation_key revkey; char *pn; int i; if( !r ) return 0; /* none (this is an optional parameter) */ pn = r->u.value; revkey.class=0x80; revkey.algid=atoi(pn); if(!revkey.algid) goto fail; /* Skip to the fpr */ while(*pn && *pn!=':') pn++; if(*pn!=':') goto fail; pn++; for(i=0;iu.revkey,&revkey,sizeof(struct revocation_key)); return 0; fail: log_error("%s:%d: invalid revocation key\n", fname, r->lnr ); return -1; /* error */ } static u32 get_parameter_u32( struct para_data_s *para, enum para_name key ) { struct para_data_s *r = get_parameter( para, key ); if( !r ) return 0; if (r->key == pKEYCREATIONDATE || r->key == pSUBKEYCREATIONDATE || r->key == pAUTHKEYCREATIONDATE) return r->u.creation; if( r->key == pKEYEXPIRE || r->key == pSUBKEYEXPIRE ) return r->u.expire; if( r->key == pKEYUSAGE || r->key == pSUBKEYUSAGE ) return r->u.usage; return (unsigned int)strtoul( r->u.value, NULL, 10 ); } static unsigned int get_parameter_uint( struct para_data_s *para, enum para_name key ) { return get_parameter_u32( para, key ); } static struct revocation_key * get_parameter_revkey( struct para_data_s *para, enum para_name key ) { struct para_data_s *r = get_parameter( para, key ); return r? &r->u.revkey : NULL; } static int get_parameter_bool (struct para_data_s *para, enum para_name key) { struct para_data_s *r = get_parameter (para, key); return (r && r->u.abool); } static int proc_parameter_file (ctrl_t ctrl, struct para_data_s *para, const char *fname, struct output_control_s *outctrl, int card ) { struct para_data_s *r; const char *s1, *s2, *s3; size_t n; char *p; int is_default = 0; int have_user_id = 0; int err, algo; /* Check that we have all required parameters. */ r = get_parameter( para, pKEYTYPE ); if(r) { algo = get_parameter_algo (ctrl, para, pKEYTYPE, &is_default); if (openpgp_pk_test_algo2 (algo, PUBKEY_USAGE_SIG)) { log_error ("%s:%d: invalid algorithm\n", fname, r->lnr ); return -1; } } else { log_error ("%s: no Key-Type specified\n",fname); return -1; } err = parse_parameter_usage (fname, para, pKEYUSAGE); if (!err) { /* Default to algo capabilities if key-usage is not provided and no default algorithm has been requested. */ r = xmalloc_clear(sizeof(*r)); r->key = pKEYUSAGE; r->u.usage = (is_default ? (PUBKEY_USAGE_CERT | PUBKEY_USAGE_SIG) : openpgp_pk_algo_usage(algo)); append_to_parameter (para, r); } else if (err == -1) return -1; else { r = get_parameter (para, pKEYUSAGE); if (r && (r->u.usage & ~openpgp_pk_algo_usage (algo))) { log_error ("%s:%d: specified Key-Usage not allowed for algo %d\n", fname, r->lnr, algo); return -1; } } is_default = 0; r = get_parameter( para, pSUBKEYTYPE ); if(r) { algo = get_parameter_algo (ctrl, para, pSUBKEYTYPE, &is_default); if (openpgp_pk_test_algo (algo)) { log_error ("%s:%d: invalid algorithm\n", fname, r->lnr ); return -1; } err = parse_parameter_usage (fname, para, pSUBKEYUSAGE); if (!err) { /* Default to algo capabilities if subkey-usage is not provided */ r = xmalloc_clear (sizeof(*r)); r->key = pSUBKEYUSAGE; r->u.usage = (is_default ? PUBKEY_USAGE_ENC : openpgp_pk_algo_usage (algo)); append_to_parameter (para, r); } else if (err == -1) return -1; else { r = get_parameter (para, pSUBKEYUSAGE); if (r && (r->u.usage & ~openpgp_pk_algo_usage (algo))) { log_error ("%s:%d: specified Subkey-Usage not allowed" " for algo %d\n", fname, r->lnr, algo); return -1; } } } if( get_parameter_value( para, pUSERID ) ) have_user_id=1; else { /* create the formatted user ID */ s1 = get_parameter_value( para, pNAMEREAL ); s2 = get_parameter_value( para, pNAMECOMMENT ); s3 = get_parameter_value( para, pNAMEEMAIL ); if( s1 || s2 || s3 ) { n = (s1?strlen(s1):0) + (s2?strlen(s2):0) + (s3?strlen(s3):0); r = xmalloc_clear( sizeof *r + n + 20 ); r->key = pUSERID; p = r->u.value; if( s1 ) p = stpcpy(p, s1 ); if( s2 ) p = stpcpy(stpcpy(stpcpy(p," ("), s2 ),")"); if( s3 ) { /* If we have only the email part, do not add the space * and the angle brackets. */ if (*r->u.value) p = stpcpy(stpcpy(stpcpy(p," <"), s3 ),">"); else p = stpcpy (p, s3); } append_to_parameter (para, r); have_user_id=1; } } if(!have_user_id) { log_error("%s: no User-ID specified\n",fname); return -1; } /* Set preferences, if any. */ keygen_set_std_prefs(get_parameter_value( para, pPREFERENCES ), 0); /* Set keyserver, if any. */ s1=get_parameter_value( para, pKEYSERVER ); if(s1) { struct keyserver_spec *spec; spec = parse_keyserver_uri (s1, 1); if(spec) { free_keyserver_spec(spec); opt.def_keyserver_url=s1; } else { r = get_parameter (para, pKEYSERVER); log_error("%s:%d: invalid keyserver url\n", fname, r->lnr ); return -1; } } /* Set revoker, if any. */ if (parse_revocation_key (fname, para, pREVOKER)) return -1; /* Make KEYCREATIONDATE from Creation-Date. We ignore this if the * key has been taken from a card and a keycreationtime has already * been set. This is so that we don't generate a key with a * fingerprint different from the one stored on the OpenPGP card. */ r = get_parameter (para, pCREATIONDATE); if (r && *r->u.value && !(get_parameter_bool (para, pCARDKEY) && get_parameter_u32 (para, pKEYCREATIONDATE))) { u32 seconds; seconds = parse_creation_string (r->u.value); if (!seconds) { log_error ("%s:%d: invalid creation date\n", fname, r->lnr ); return -1; } r->u.creation = seconds; r->key = pKEYCREATIONDATE; /* Change that entry. */ } /* Make KEYEXPIRE from Expire-Date. */ r = get_parameter( para, pEXPIREDATE ); if( r && *r->u.value ) { u32 seconds; seconds = parse_expire_string( r->u.value ); if( seconds == (u32)-1 ) { log_error("%s:%d: invalid expire date\n", fname, r->lnr ); return -1; } r->u.expire = seconds; r->key = pKEYEXPIRE; /* change hat entry */ /* also set it for the subkey */ r = xmalloc_clear( sizeof *r + 20 ); r->key = pSUBKEYEXPIRE; r->u.expire = seconds; append_to_parameter (para, r); } do_generate_keypair (ctrl, para, outctrl, card ); return 0; } /**************** * Kludge to allow non interactive key generation controlled * by a parameter file. * Note, that string parameters are expected to be in UTF-8 */ static void read_parameter_file (ctrl_t ctrl, const char *fname ) { static struct { const char *name; enum para_name key; } keywords[] = { { "Key-Type", pKEYTYPE}, { "Key-Length", pKEYLENGTH }, { "Key-Curve", pKEYCURVE }, { "Key-Usage", pKEYUSAGE }, { "Subkey-Type", pSUBKEYTYPE }, { "Subkey-Length", pSUBKEYLENGTH }, { "Subkey-Curve", pSUBKEYCURVE }, { "Subkey-Usage", pSUBKEYUSAGE }, { "Name-Real", pNAMEREAL }, { "Name-Email", pNAMEEMAIL }, { "Name-Comment", pNAMECOMMENT }, { "Expire-Date", pEXPIREDATE }, { "Creation-Date", pCREATIONDATE }, { "Passphrase", pPASSPHRASE }, { "Preferences", pPREFERENCES }, { "Revoker", pREVOKER }, { "Handle", pHANDLE }, { "Keyserver", pKEYSERVER }, { "Keygrip", pKEYGRIP }, { "Key-Grip", pKEYGRIP }, { "Subkey-grip", pSUBKEYGRIP }, { "Key-Version", pVERSION }, { "Subkey-Version", pSUBVERSION }, { NULL, 0 } }; IOBUF fp; byte *line; unsigned int maxlen, nline; char *p; int lnr; const char *err = NULL; struct para_data_s *para, *r; int i; struct output_control_s outctrl; memset( &outctrl, 0, sizeof( outctrl ) ); outctrl.pub.afx = new_armor_context (); if( !fname || !*fname) fname = "-"; fp = iobuf_open (fname); if (fp && is_secured_file (iobuf_get_fd (fp))) { iobuf_close (fp); fp = NULL; gpg_err_set_errno (EPERM); } if (!fp) { log_error (_("can't open '%s': %s\n"), fname, strerror(errno) ); return; } iobuf_ioctl (fp, IOBUF_IOCTL_NO_CACHE, 1, NULL); lnr = 0; err = NULL; para = NULL; maxlen = 1024; line = NULL; nline = 0; while ( iobuf_read_line (fp, &line, &nline, &maxlen) ) { char *keyword, *value; lnr++; if( !maxlen ) { err = "line too long"; break; } for( p = line; isspace(*(byte*)p); p++ ) ; if( !*p || *p == '#' ) continue; keyword = p; if( *keyword == '%' ) { for( ; !isspace(*(byte*)p); p++ ) ; if( *p ) *p++ = 0; for( ; isspace(*(byte*)p); p++ ) ; value = p; trim_trailing_ws( value, strlen(value) ); if( !ascii_strcasecmp( keyword, "%echo" ) ) log_info("%s\n", value ); else if( !ascii_strcasecmp( keyword, "%dry-run" ) ) outctrl.dryrun = 1; else if( !ascii_strcasecmp( keyword, "%ask-passphrase" ) ) ; /* Dummy for backward compatibility. */ else if( !ascii_strcasecmp( keyword, "%no-ask-passphrase" ) ) ; /* Dummy for backward compatibility. */ else if( !ascii_strcasecmp( keyword, "%no-protection" ) ) outctrl.keygen_flags |= KEYGEN_FLAG_NO_PROTECTION; else if( !ascii_strcasecmp( keyword, "%transient-key" ) ) outctrl.keygen_flags |= KEYGEN_FLAG_TRANSIENT_KEY; else if( !ascii_strcasecmp( keyword, "%commit" ) ) { outctrl.lnr = lnr; if (proc_parameter_file (ctrl, para, fname, &outctrl, 0 )) print_status_key_not_created (get_parameter_value (para, pHANDLE)); release_parameter_list( para ); para = NULL; } else if( !ascii_strcasecmp( keyword, "%pubring" ) ) { if( outctrl.pub.fname && !strcmp( outctrl.pub.fname, value ) ) ; /* still the same file - ignore it */ else { xfree( outctrl.pub.newfname ); outctrl.pub.newfname = xstrdup( value ); outctrl.use_files = 1; } } else if( !ascii_strcasecmp( keyword, "%secring" ) ) { /* Ignore this command. */ } else log_info("skipping control '%s' (%s)\n", keyword, value ); continue; } if( !(p = strchr( p, ':' )) || p == keyword ) { err = "missing colon"; break; } if( *p ) *p++ = 0; for( ; isspace(*(byte*)p); p++ ) ; if( !*p ) { err = "missing argument"; break; } value = p; trim_trailing_ws( value, strlen(value) ); for(i=0; keywords[i].name; i++ ) { if( !ascii_strcasecmp( keywords[i].name, keyword ) ) break; } if( !keywords[i].name ) { err = "unknown keyword"; break; } if( keywords[i].key != pKEYTYPE && !para ) { err = "parameter block does not start with \"Key-Type\""; break; } if( keywords[i].key == pKEYTYPE && para ) { outctrl.lnr = lnr; if (proc_parameter_file (ctrl, para, fname, &outctrl, 0 )) print_status_key_not_created (get_parameter_value (para, pHANDLE)); release_parameter_list( para ); para = NULL; } else { for( r = para; r; r = r->next ) { if( r->key == keywords[i].key ) break; } if( r ) { err = "duplicate keyword"; break; } } if ((keywords[i].key == pVERSION || keywords[i].key == pSUBVERSION)) ; /* Ignore version. */ else { r = xmalloc_clear( sizeof *r + strlen( value ) ); r->lnr = lnr; r->key = keywords[i].key; strcpy( r->u.value, value ); r->next = para; para = r; } } if( err ) log_error("%s:%d: %s\n", fname, lnr, err ); else if( iobuf_error (fp) ) { log_error("%s:%d: read error\n", fname, lnr); } else if( para ) { outctrl.lnr = lnr; if (proc_parameter_file (ctrl, para, fname, &outctrl, 0 )) print_status_key_not_created (get_parameter_value (para, pHANDLE)); } if( outctrl.use_files ) { /* close open streams */ iobuf_close( outctrl.pub.stream ); /* Must invalidate that ugly cache to actually close it. */ if (outctrl.pub.fname) iobuf_ioctl (NULL, IOBUF_IOCTL_INVALIDATE_CACHE, 0, (char*)outctrl.pub.fname); xfree( outctrl.pub.fname ); xfree( outctrl.pub.newfname ); } xfree (line); release_parameter_list( para ); iobuf_close (fp); release_armor_context (outctrl.pub.afx); } /* Helper for quick_generate_keypair. */ static struct para_data_s * quickgen_set_para (struct para_data_s *para, int for_subkey, int algo, int nbits, const char *curve, unsigned int use, int version, const char *keygrip, u32 keytime) { struct para_data_s *r; r = xmalloc_clear (sizeof *r + 50); r->key = for_subkey? pSUBKEYUSAGE : pKEYUSAGE; if (use) snprintf (r->u.value, 30, "%s%s%s%s%s%s%s", (use & PUBKEY_USAGE_ENC)? "encr " : "", (use & PUBKEY_USAGE_SIG)? "sign " : "", (use & PUBKEY_USAGE_AUTH)? "auth " : "", (use & PUBKEY_USAGE_CERT)? "cert " : "", (use & PUBKEY_USAGE_RENC)? "renc " : "", (use & PUBKEY_USAGE_TIME)? "time " : "", (use & PUBKEY_USAGE_GROUP)?"group ": ""); else strcpy (r->u.value, for_subkey ? "encr" : "sign"); r->next = para; para = r; r = xmalloc_clear (sizeof *r + 20); r->key = for_subkey? pSUBKEYTYPE : pKEYTYPE; snprintf (r->u.value, 20, "%d", algo); r->next = para; para = r; if (keygrip) { r = xmalloc_clear (sizeof *r + strlen (keygrip)); r->key = for_subkey? pSUBKEYGRIP : pKEYGRIP; strcpy (r->u.value, keygrip); r->next = para; para = r; } else if (curve) { r = xmalloc_clear (sizeof *r + strlen (curve)); r->key = for_subkey? pSUBKEYCURVE : pKEYCURVE; strcpy (r->u.value, curve); r->next = para; para = r; } else { r = xmalloc_clear (sizeof *r + 20); r->key = for_subkey? pSUBKEYLENGTH : pKEYLENGTH; sprintf (r->u.value, "%u", nbits); r->next = para; para = r; } r = xmalloc_clear (sizeof *r + 20); r->key = for_subkey? pSUBVERSION : pVERSION; snprintf (r->u.value, 20, "%d", version); r->next = para; para = r; if (keytime) { r = xmalloc_clear (sizeof *r); r->key = for_subkey? pSUBKEYCREATIONDATE : pKEYCREATIONDATE; r->u.creation = keytime; r->next = para; para = r; } return para; } /* * Unattended generation of a standard key. */ void quick_generate_keypair (ctrl_t ctrl, const char *uid, const char *algostr, const char *usagestr, const char *expirestr) { gpg_error_t err; struct para_data_s *para = NULL; struct para_data_s *r; struct output_control_s outctrl; int use_tty; memset (&outctrl, 0, sizeof outctrl); use_tty = (!opt.batch && !opt.answer_yes && !*algostr && !*usagestr && !*expirestr && !cpr_enabled () && gnupg_isatty (fileno (stdin)) && gnupg_isatty (fileno (stdout)) && gnupg_isatty (fileno (stderr))); r = xmalloc_clear (sizeof *r + strlen (uid)); r->key = pUSERID; strcpy (r->u.value, uid); r->next = para; para = r; uid = trim_spaces (r->u.value); if (!*uid || (!opt.allow_freeform_uid && !is_valid_user_id (uid))) { log_error (_("Key generation failed: %s\n"), gpg_strerror (GPG_ERR_INV_USER_ID)); goto leave; } /* If gpg is directly used on the console ask whether a key with the given user id shall really be created. */ if (use_tty) { tty_printf (_("About to create a key for:\n \"%s\"\n\n"), uid); if (!cpr_get_answer_is_yes_def ("quick_keygen.okay", _("Continue? (Y/n) "), 1)) goto leave; } /* Check whether such a user ID already exists. */ { KEYDB_HANDLE kdbhd; KEYDB_SEARCH_DESC desc; memset (&desc, 0, sizeof desc); desc.mode = KEYDB_SEARCH_MODE_EXACT; desc.u.name = uid; kdbhd = keydb_new (ctrl); if (!kdbhd) goto leave; err = keydb_search (kdbhd, &desc, 1, NULL); keydb_release (kdbhd); if (gpg_err_code (err) != GPG_ERR_NOT_FOUND) { log_info (_("A key for \"%s\" already exists\n"), uid); if (opt.answer_yes) ; else if (!use_tty || !cpr_get_answer_is_yes_def ("quick_keygen.force", _("Create anyway? (y/N) "), 0)) { write_status_error ("genkey", gpg_error (304)); log_inc_errorcount (); /* we used log_info */ goto leave; } log_info (_("creating anyway\n")); } } if (!*expirestr || strcmp (expirestr, "-") == 0) expirestr = default_expiration_interval; if ((!*algostr || !ascii_strcasecmp (algostr, "default") || !ascii_strcasecmp (algostr, "future-default") || !ascii_strcasecmp (algostr, "futuredefault") || !ascii_strcasecmp (algostr, "card")) && (!*usagestr || !ascii_strcasecmp (usagestr, "default") || !strcmp (usagestr, "-"))) { /* Use default key parameters. */ int algo, subalgo, version, subversion; unsigned int size, subsize; unsigned int keyuse, subkeyuse; const char *curve, *subcurve; char *keygrip, *subkeygrip; u32 keytime, subkeytime; err = parse_key_parameter_string (ctrl, algostr, -1, 0, &algo, &size, &keyuse, &curve, &version, &keygrip, &keytime, &subalgo, &subsize, &subkeyuse, &subcurve, &subversion, &subkeygrip, &subkeytime); if (err) { log_error (_("Key generation failed: %s\n"), gpg_strerror (err)); goto leave; } para = quickgen_set_para (para, 0, algo, size, curve, keyuse, version, keygrip, keytime); if (subalgo) para = quickgen_set_para (para, 1, subalgo, subsize, subcurve, subkeyuse, subversion, subkeygrip, subkeytime); if (*expirestr) { u32 expire; expire = parse_expire_string (expirestr); if (expire == (u32)-1 ) { err = gpg_error (GPG_ERR_INV_VALUE); log_error (_("Key generation failed: %s\n"), gpg_strerror (err)); goto leave; } r = xmalloc_clear (sizeof *r + 20); r->key = pKEYEXPIRE; r->u.expire = expire; r->next = para; para = r; } xfree (keygrip); xfree (subkeygrip); } else { /* Extended unattended mode. Creates only the primary key. */ int algo, version; unsigned int use; u32 expire; unsigned int nbits; const char *curve; char *keygrip; u32 keytime; err = parse_algo_usage_expire (ctrl, 0, algostr, usagestr, expirestr, &algo, &use, &expire, &nbits, &curve, &version, &keygrip, &keytime); if (err) { log_error (_("Key generation failed: %s\n"), gpg_strerror (err) ); goto leave; } para = quickgen_set_para (para, 0, algo, nbits, curve, use, version, keygrip, keytime); r = xmalloc_clear (sizeof *r + 20); r->key = pKEYEXPIRE; r->u.expire = expire; r->next = para; para = r; xfree (keygrip); } /* If the pinentry loopback mode is not and we have a static passphrase (i.e. set with --passphrase{,-fd,-file} while in batch mode), we use that passphrase for the new key. */ if (opt.pinentry_mode != PINENTRY_MODE_LOOPBACK && have_static_passphrase ()) { const char *s = get_static_passphrase (); r = xmalloc_clear (sizeof *r + strlen (s)); r->key = pPASSPHRASE; strcpy (r->u.value, s); r->next = para; para = r; } if (!ascii_strcasecmp (algostr, "card") || !ascii_strncasecmp (algostr, "card/", 5)) { r = xmalloc_clear (sizeof *r); r->key = pCARDKEY; r->u.abool = 1; r->next = para; para = r; } proc_parameter_file (ctrl, para, "[internal]", &outctrl, 0); leave: release_parameter_list (para); } /* * Generate a keypair (fname is only used in batch mode) If * CARD_SERIALNO is not NULL the function will create the keys on an * OpenPGP Card. If CARD_BACKUP_KEY has been set and CARD_SERIALNO is * NOT NULL, the encryption key for the card is generated on the host, * imported to the card and a backup file created by gpg-agent. If * FULL is not set only the basic prompts are used (except for batch * mode). */ void generate_keypair (ctrl_t ctrl, int full, const char *fname, const char *card_serialno, int card_backup_key) { gpg_error_t err; unsigned int nbits; char *uid = NULL; int algo; unsigned int use; int both = 0; u32 expire; struct para_data_s *para = NULL; struct para_data_s *r; struct output_control_s outctrl; #ifndef ENABLE_CARD_SUPPORT (void)card_backup_key; #endif memset( &outctrl, 0, sizeof( outctrl ) ); if (opt.batch && card_serialno) { /* We don't yet support unattended key generation with a card * serial number. */ log_error (_("can't do this in batch mode\n")); print_further_info ("key generation with card serial number"); return; } if (opt.batch) { read_parameter_file (ctrl, fname); return; } if (card_serialno) { #ifdef ENABLE_CARD_SUPPORT struct agent_card_info_s info; memset (&info, 0, sizeof (info)); err = agent_scd_getattr ("KEY-ATTR", &info); if (err) { log_error (_("error getting current key info: %s\n"), gpg_strerror (err)); return; } r = xcalloc (1, sizeof *r + strlen (card_serialno) ); r->key = pSERIALNO; strcpy( r->u.value, card_serialno); r->next = para; para = r; r = xcalloc (1, sizeof *r + 20 ); r->key = pKEYTYPE; sprintf( r->u.value, "%d", info.key_attr[0].algo ); r->next = para; para = r; r = xcalloc (1, sizeof *r + 20 ); r->key = pKEYUSAGE; strcpy (r->u.value, "sign"); r->next = para; para = r; r = xcalloc (1, sizeof *r + 20 ); r->key = pSUBKEYTYPE; sprintf( r->u.value, "%d", info.key_attr[1].algo ); r->next = para; para = r; r = xcalloc (1, sizeof *r + 20 ); r->key = pSUBKEYUSAGE; strcpy (r->u.value, "encrypt"); r->next = para; para = r; if (info.key_attr[1].algo == PUBKEY_ALGO_RSA) { r = xcalloc (1, sizeof *r + 20 ); r->key = pSUBKEYLENGTH; sprintf( r->u.value, "%u", info.key_attr[1].nbits); r->next = para; para = r; } else if (info.key_attr[1].algo == PUBKEY_ALGO_ECDSA || info.key_attr[1].algo == PUBKEY_ALGO_EDDSA || info.key_attr[1].algo == PUBKEY_ALGO_ECDH) { r = xcalloc (1, sizeof *r + strlen (info.key_attr[1].curve)); r->key = pSUBKEYCURVE; strcpy (r->u.value, info.key_attr[1].curve); r->next = para; para = r; } r = xcalloc (1, sizeof *r + 20 ); r->key = pAUTHKEYTYPE; sprintf( r->u.value, "%d", info.key_attr[2].algo ); r->next = para; para = r; if (card_backup_key) { r = xcalloc (1, sizeof *r + 1); r->key = pCARDBACKUPKEY; strcpy (r->u.value, "1"); r->next = para; para = r; } #endif /*ENABLE_CARD_SUPPORT*/ } else if (full) /* Full featured key generation. */ { int subkey_algo; char *key_from_hexgrip = NULL; int cardkey; u32 keytime; algo = ask_algo (ctrl, 0, &subkey_algo, &use, &key_from_hexgrip, &cardkey, &keytime); if (key_from_hexgrip) { r = xmalloc_clear( sizeof *r + 20 ); r->key = pKEYTYPE; sprintf( r->u.value, "%d", algo); r->next = para; para = r; if (use) { r = xmalloc_clear( sizeof *r + 25 ); r->key = pKEYUSAGE; sprintf( r->u.value, "%s%s%s", (use & PUBKEY_USAGE_SIG)? "sign ":"", (use & PUBKEY_USAGE_ENC)? "encrypt ":"", (use & PUBKEY_USAGE_AUTH)? "auth":"" ); r->next = para; para = r; } r = xmalloc_clear( sizeof *r + 40 ); r->key = pKEYGRIP; strcpy (r->u.value, key_from_hexgrip); r->next = para; para = r; r = xmalloc_clear (sizeof *r); r->key = pCARDKEY; r->u.abool = cardkey; r->next = para; para = r; if (cardkey) { r = xmalloc_clear (sizeof *r); r->key = pKEYCREATIONDATE; r->u.creation = keytime; r->next = para; para = r; } xfree (key_from_hexgrip); } else { const char *curve = NULL; if (subkey_algo) { /* Create primary and subkey at once. */ both = 1; if (algo == PUBKEY_ALGO_ECDSA || algo == PUBKEY_ALGO_EDDSA || algo == PUBKEY_ALGO_ECDH) { curve = ask_curve (&algo, &subkey_algo, NULL); r = xmalloc_clear( sizeof *r + 20 ); r->key = pKEYTYPE; sprintf( r->u.value, "%d", algo); r->next = para; para = r; nbits = 0; r = xmalloc_clear (sizeof *r + strlen (curve)); r->key = pKEYCURVE; strcpy (r->u.value, curve); r->next = para; para = r; if (!strcmp (curve, "Ed448")) { r = xmalloc_clear (sizeof *r + 20); r->key = pVERSION; snprintf (r->u.value, 20, "%d", 5); r->next = para; para = r; } } else { r = xmalloc_clear( sizeof *r + 20 ); r->key = pKEYTYPE; sprintf( r->u.value, "%d", algo); r->next = para; para = r; nbits = ask_keysize (algo, 0); r = xmalloc_clear( sizeof *r + 20 ); r->key = pKEYLENGTH; sprintf( r->u.value, "%u", nbits); r->next = para; para = r; } r = xmalloc_clear( sizeof *r + 20 ); r->key = pKEYUSAGE; strcpy( r->u.value, "sign" ); r->next = para; para = r; r = xmalloc_clear( sizeof *r + 20 ); r->key = pSUBKEYTYPE; sprintf( r->u.value, "%d", subkey_algo); r->next = para; para = r; r = xmalloc_clear( sizeof *r + 20 ); r->key = pSUBKEYUSAGE; strcpy( r->u.value, "encrypt" ); r->next = para; para = r; if (algo == PUBKEY_ALGO_ECDSA || algo == PUBKEY_ALGO_EDDSA || algo == PUBKEY_ALGO_ECDH) { if (algo == PUBKEY_ALGO_EDDSA && subkey_algo == PUBKEY_ALGO_ECDH) { /* Need to switch to a different curve for the encryption key. */ if (!strcmp (curve, "Ed25519")) curve = "Curve25519"; else { curve = "X448"; r = xmalloc_clear (sizeof *r + 20); r->key = pSUBVERSION; snprintf (r->u.value, 20, "%d", 5); r->next = para; para = r; } } r = xmalloc_clear (sizeof *r + strlen (curve)); r->key = pSUBKEYCURVE; strcpy (r->u.value, curve); r->next = para; para = r; } } else /* Create only a single key. */ { /* For ECC we need to ask for the curve before storing the algo because ask_curve may change the algo. */ if (algo == PUBKEY_ALGO_ECDSA || algo == PUBKEY_ALGO_EDDSA || algo == PUBKEY_ALGO_ECDH) { curve = ask_curve (&algo, NULL, NULL); r = xmalloc_clear (sizeof *r + strlen (curve)); r->key = pKEYCURVE; strcpy (r->u.value, curve); r->next = para; para = r; if (!strcmp (curve, "Ed448")) { r = xmalloc_clear (sizeof *r + 20); r->key = pVERSION; snprintf (r->u.value, 20, "%d", 5); r->next = para; para = r; } } r = xmalloc_clear( sizeof *r + 20 ); r->key = pKEYTYPE; sprintf( r->u.value, "%d", algo ); r->next = para; para = r; if (use) { r = xmalloc_clear( sizeof *r + 25 ); r->key = pKEYUSAGE; sprintf( r->u.value, "%s%s%s", (use & PUBKEY_USAGE_SIG)? "sign ":"", (use & PUBKEY_USAGE_ENC)? "encrypt ":"", (use & PUBKEY_USAGE_AUTH)? "auth":"" ); r->next = para; para = r; } nbits = 0; } if (algo == PUBKEY_ALGO_ECDSA || algo == PUBKEY_ALGO_EDDSA || algo == PUBKEY_ALGO_ECDH) { /* The curve has already been set. */ } else { nbits = ask_keysize (both? subkey_algo : algo, nbits); r = xmalloc_clear( sizeof *r + 20 ); r->key = both? pSUBKEYLENGTH : pKEYLENGTH; sprintf( r->u.value, "%u", nbits); r->next = para; para = r; } } } else /* Default key generation. */ { int subalgo, version, subversion; unsigned int size, subsize; unsigned int keyuse, subkeyuse; const char *curve, *subcurve; char *keygrip, *subkeygrip; u32 keytime, subkeytime; tty_printf ( _("Note: Use \"%s %s\"" " for a full featured key generation dialog.\n"), #if USE_GPG2_HACK GPG_NAME "2" #else GPG_NAME #endif , "--full-generate-key" ); err = parse_key_parameter_string (ctrl, NULL, -1, 0, &algo, &size, &keyuse, &curve, &version, &keygrip, &keytime, &subalgo, &subsize, &subkeyuse, &subcurve, &subversion, &subkeygrip, &subkeytime); if (err) { log_error (_("Key generation failed: %s\n"), gpg_strerror (err)); return; } para = quickgen_set_para (para, 0, algo, size, curve, keyuse, version, keygrip, keytime); if (subalgo) para = quickgen_set_para (para, 1, subalgo, subsize, subcurve, subkeyuse, subversion, subkeygrip, subkeytime); xfree (keygrip); xfree (subkeygrip); } expire = full? ask_expire_interval (0, NULL) : parse_expire_string (default_expiration_interval); r = xcalloc (1, sizeof *r + 20); r->key = pKEYEXPIRE; r->u.expire = expire; r->next = para; para = r; r = xcalloc (1, sizeof *r + 20); r->key = pSUBKEYEXPIRE; r->u.expire = expire; r->next = para; para = r; uid = ask_user_id (0, full, NULL); if (!uid) { log_error(_("Key generation canceled.\n")); release_parameter_list( para ); return; } r = xcalloc (1, sizeof *r + strlen (uid)); r->key = pUSERID; strcpy (r->u.value, uid); r->next = para; para = r; proc_parameter_file (ctrl, para, "[internal]", &outctrl, !!card_serialno); release_parameter_list (para); } /* Create and delete a dummy packet to start off a list of kbnodes. */ static void start_tree(KBNODE *tree) { PACKET *pkt; pkt=xmalloc_clear(sizeof(*pkt)); pkt->pkttype=PKT_NONE; *tree=new_kbnode(pkt); delete_kbnode(*tree); } /* Write the *protected* secret key to the file. */ static gpg_error_t card_write_key_to_backup_file (PKT_public_key *sk, const char *backup_dir) { gpg_error_t err = 0; int rc; char keyid_buffer[2 * 8 + 1]; char name_buffer[50]; char *fname; IOBUF fp; mode_t oldmask; PACKET *pkt = NULL; format_keyid (pk_keyid (sk), KF_LONG, keyid_buffer, sizeof (keyid_buffer)); snprintf (name_buffer, sizeof name_buffer, "sk_%s.gpg", keyid_buffer); fname = make_filename (backup_dir, name_buffer, NULL); /* Note that the umask call is not anymore needed because iobuf_create now takes care of it. However, it does not harm and thus we keep it. */ oldmask = umask (077); if (is_secured_filename (fname)) { fp = NULL; gpg_err_set_errno (EPERM); } else fp = iobuf_create (fname, 1); umask (oldmask); if (!fp) { err = gpg_error_from_syserror (); log_error (_("can't create backup file '%s': %s\n"), fname, strerror (errno) ); goto leave; } pkt = xcalloc (1, sizeof *pkt); pkt->pkttype = PKT_SECRET_KEY; pkt->pkt.secret_key = sk; rc = build_packet (fp, pkt); if (rc) { log_error ("build packet failed: %s\n", gpg_strerror (rc)); iobuf_cancel (fp); } else { char *fprbuf; iobuf_close (fp); iobuf_ioctl (NULL, IOBUF_IOCTL_INVALIDATE_CACHE, 0, (char*)fname); log_info (_("Note: backup of card key saved to '%s'\n"), fname); fprbuf = hexfingerprint (sk, NULL, 0); if (!fprbuf) { err = gpg_error_from_syserror (); goto leave; } write_status_text_and_buffer (STATUS_BACKUP_KEY_CREATED, fprbuf, fname, strlen (fname), 0); xfree (fprbuf); } leave: xfree (pkt); xfree (fname); return err; } /* Store key to card and make a backup file in OpenPGP format. */ static gpg_error_t card_store_key_with_backup (ctrl_t ctrl, PKT_public_key *sub_psk, const char *backup_dir) { PKT_public_key *sk; gnupg_isotime_t timestamp; gpg_error_t err; char *hexgrip; int rc; struct agent_card_info_s info; gcry_cipher_hd_t cipherhd = NULL; char *cache_nonce = NULL; void *kek = NULL; size_t keklen; sk = copy_public_key (NULL, sub_psk); if (!sk) return gpg_error_from_syserror (); epoch2isotime (timestamp, (time_t)sk->timestamp); err = hexkeygrip_from_pk (sk, &hexgrip); if (err) goto leave; memset(&info, 0, sizeof (info)); rc = agent_scd_getattr ("SERIALNO", &info); if (rc) { err = (gpg_error_t)rc; goto leave; } rc = agent_keytocard (hexgrip, 2, 1, info.serialno, timestamp); xfree (info.serialno); if (rc) { err = (gpg_error_t)rc; goto leave; } err = agent_keywrap_key (ctrl, 1, &kek, &keklen); if (err) { log_error ("error getting the KEK: %s\n", gpg_strerror (err)); goto leave; } err = gcry_cipher_open (&cipherhd, GCRY_CIPHER_AES128, GCRY_CIPHER_MODE_AESWRAP, 0); if (!err) err = gcry_cipher_setkey (cipherhd, kek, keklen); if (err) { log_error ("error setting up an encryption context: %s\n", gpg_strerror (err)); goto leave; } err = receive_seckey_from_agent (ctrl, cipherhd, 0, - &cache_nonce, hexgrip, sk); + &cache_nonce, hexgrip, sk, NULL); if (err) { log_error ("error getting secret key from agent: %s\n", gpg_strerror (err)); goto leave; } err = card_write_key_to_backup_file (sk, backup_dir); if (err) log_error ("writing card key to backup file: %s\n", gpg_strerror (err)); else /* Remove secret key data in agent side. */ agent_scd_learn (NULL, 1); leave: xfree (cache_nonce); gcry_cipher_close (cipherhd); xfree (kek); xfree (hexgrip); free_public_key (sk); return err; } static void do_generate_keypair (ctrl_t ctrl, struct para_data_s *para, struct output_control_s *outctrl, int card) { gpg_error_t err; KBNODE pub_root = NULL; const char *s; PKT_public_key *pri_psk = NULL; PKT_public_key *sub_psk = NULL; struct revocation_key *revkey; int did_sub = 0; u32 keytimestamp, subkeytimestamp, authkeytimestamp, signtimestamp; char *cache_nonce = NULL; int algo; u32 expire; const char *key_from_hexgrip = NULL; int cardkey; unsigned int keygen_flags; if (outctrl->dryrun) { log_info("dry-run mode - key generation skipped\n"); return; } if ( outctrl->use_files ) { if ( outctrl->pub.newfname ) { iobuf_close(outctrl->pub.stream); outctrl->pub.stream = NULL; if (outctrl->pub.fname) iobuf_ioctl (NULL, IOBUF_IOCTL_INVALIDATE_CACHE, 0, (char*)outctrl->pub.fname); xfree( outctrl->pub.fname ); outctrl->pub.fname = outctrl->pub.newfname; outctrl->pub.newfname = NULL; if (is_secured_filename (outctrl->pub.fname) ) { outctrl->pub.stream = NULL; gpg_err_set_errno (EPERM); } else outctrl->pub.stream = iobuf_create (outctrl->pub.fname, 0); if (!outctrl->pub.stream) { log_error(_("can't create '%s': %s\n"), outctrl->pub.newfname, strerror(errno) ); return; } if (opt.armor) { outctrl->pub.afx->what = 1; push_armor_filter (outctrl->pub.afx, outctrl->pub.stream); } } log_assert( outctrl->pub.stream ); if (opt.verbose) log_info (_("writing public key to '%s'\n"), outctrl->pub.fname ); } /* We create the packets as a tree of kbnodes. Because the structure we create is known in advance we simply generate a linked list. The first packet is a dummy packet which we flag as deleted. The very first packet must always be a KEY packet. */ start_tree (&pub_root); cardkey = get_parameter_bool (para, pCARDKEY); /* In the case that the keys are created from the card we need to * take the timestamps from the card. Only in this case a * pSUBKEYCREATIONDATE or pAUTHKEYCREATIONDATE might be defined and * then we need to use that so that the fingerprint of the subkey * also matches the pre-computed and stored one on the card. In * this case we also use the current time to create the * self-signatures. */ keytimestamp = get_parameter_u32 (para, pKEYCREATIONDATE); if (!keytimestamp) keytimestamp = make_timestamp (); subkeytimestamp = cardkey? get_parameter_u32 (para, pSUBKEYCREATIONDATE) : 0; if (!subkeytimestamp) subkeytimestamp = keytimestamp; authkeytimestamp = cardkey? get_parameter_u32 (para, pAUTHKEYCREATIONDATE): 0; if (!authkeytimestamp) authkeytimestamp = keytimestamp; signtimestamp = cardkey? make_timestamp () : keytimestamp; /* log_debug ("XXX: cardkey ..: %d\n", cardkey); */ /* log_debug ("XXX: keytime ..: %s\n", isotimestamp (keytimestamp)); */ /* log_debug ("XXX: subkeytime: %s\n", isotimestamp (subkeytimestamp)); */ /* log_debug ("XXX: authkeytim: %s\n", isotimestamp (authkeytimestamp)); */ /* log_debug ("XXX: signtime .: %s\n", isotimestamp (signtimestamp)); */ /* Fixme: Check that this comment is still valid: Note that, depending on the backend (i.e. the used scdaemon version), the card key generation may update TIMESTAMP for each key. Thus we need to pass TIMESTAMP to all signing function to make sure that the binding signature is done using the timestamp of the corresponding (sub)key and not that of the primary key. An alternative implementation could tell the signing function the node of the subkey but that is more work than just to pass the current timestamp. */ algo = get_parameter_algo (ctrl, para, pKEYTYPE, NULL ); expire = get_parameter_u32( para, pKEYEXPIRE ); key_from_hexgrip = get_parameter_value (para, pKEYGRIP); if (cardkey && !key_from_hexgrip) BUG (); keygen_flags = outctrl->keygen_flags; if (get_parameter_uint (para, pVERSION) == 5) keygen_flags |= KEYGEN_FLAG_CREATE_V5_KEY; if (key_from_hexgrip) err = do_create_from_keygrip (ctrl, algo, key_from_hexgrip, cardkey, pub_root, keytimestamp, expire, 0, keygen_flags); else if (!card) err = do_create (algo, get_parameter_uint( para, pKEYLENGTH ), get_parameter_value (para, pKEYCURVE), pub_root, keytimestamp, expire, 0, keygen_flags, get_parameter_passphrase (para), &cache_nonce, NULL); else err = gen_card_key (1, algo, 1, pub_root, &keytimestamp, expire, keygen_flags); /* Get the pointer to the generated public key packet. */ if (!err) { pri_psk = pub_root->next->pkt->pkt.public_key; log_assert (pri_psk); /* Make sure a few fields are correctly set up before going further. */ pri_psk->flags.primary = 1; keyid_from_pk (pri_psk, NULL); /* We don't use pk_keyid to get keyid, because it also asserts that main_keyid is set! */ keyid_copy (pri_psk->main_keyid, pri_psk->keyid); } if (!err && (revkey = get_parameter_revkey (para, pREVOKER))) err = write_direct_sig (ctrl, pub_root, pri_psk, revkey, signtimestamp, cache_nonce); if (!err && (s = get_parameter_value (para, pUSERID))) { err = write_uid (pub_root, s ); if (!err) err = write_selfsigs (ctrl, pub_root, pri_psk, get_parameter_uint (para, pKEYUSAGE), signtimestamp, cache_nonce); } /* Write the auth key to the card before the encryption key. This is a partial workaround for a PGP bug (as of this writing, all versions including 8.1), that causes it to try and encrypt to the most recent subkey regardless of whether that subkey is actually an encryption type. In this case, the auth key is an RSA key so it succeeds. */ if (!err && card && get_parameter (para, pAUTHKEYTYPE)) { err = gen_card_key (3, get_parameter_algo (ctrl, para, pAUTHKEYTYPE, NULL ), 0, pub_root, &authkeytimestamp, expire, keygen_flags); if (!err) err = write_keybinding (ctrl, pub_root, pri_psk, NULL, PUBKEY_USAGE_AUTH, signtimestamp, cache_nonce); } if (!err && get_parameter (para, pSUBKEYTYPE)) { int subkey_algo = get_parameter_algo (ctrl, para, pSUBKEYTYPE, NULL); s = NULL; key_from_hexgrip = get_parameter_value (para, pSUBKEYGRIP); keygen_flags = outctrl->keygen_flags; if (get_parameter_uint (para, pSUBVERSION) == 5) keygen_flags |= KEYGEN_FLAG_CREATE_V5_KEY; if (key_from_hexgrip) err = do_create_from_keygrip (ctrl, subkey_algo, key_from_hexgrip, cardkey, pub_root, subkeytimestamp, get_parameter_u32 (para, pSUBKEYEXPIRE), 1, keygen_flags); else if (!card || (s = get_parameter_value (para, pCARDBACKUPKEY))) { err = do_create (subkey_algo, get_parameter_uint (para, pSUBKEYLENGTH), get_parameter_value (para, pSUBKEYCURVE), pub_root, subkeytimestamp, get_parameter_u32 (para, pSUBKEYEXPIRE), 1, s? KEYGEN_FLAG_NO_PROTECTION : keygen_flags, get_parameter_passphrase (para), &cache_nonce, NULL); /* Get the pointer to the generated public subkey packet. */ if (!err) { kbnode_t node; for (node = pub_root; node; node = node->next) if (node->pkt->pkttype == PKT_PUBLIC_SUBKEY) sub_psk = node->pkt->pkt.public_key; log_assert (sub_psk); if (s) err = card_store_key_with_backup (ctrl, sub_psk, gnupg_homedir ()); } } else { err = gen_card_key (2, subkey_algo, 0, pub_root, &subkeytimestamp, expire, keygen_flags); } if (!err) err = write_keybinding (ctrl, pub_root, pri_psk, sub_psk, get_parameter_uint (para, pSUBKEYUSAGE), signtimestamp, cache_nonce); did_sub = 1; } if (!err && outctrl->use_files) /* Direct write to specified files. */ { err = write_keyblock (outctrl->pub.stream, pub_root); if (err) log_error ("can't write public key: %s\n", gpg_strerror (err)); } else if (!err) /* Write to the standard keyrings. */ { KEYDB_HANDLE pub_hd; pub_hd = keydb_new (ctrl); if (!pub_hd) err = gpg_error_from_syserror (); else { err = keydb_locate_writable (pub_hd); if (err) log_error (_("no writable public keyring found: %s\n"), gpg_strerror (err)); } if (!err && opt.verbose) { log_info (_("writing public key to '%s'\n"), keydb_get_resource_name (pub_hd)); } if (!err) { err = keydb_insert_keyblock (pub_hd, pub_root); if (err) log_error (_("error writing public keyring '%s': %s\n"), keydb_get_resource_name (pub_hd), gpg_strerror (err)); } keydb_release (pub_hd); if (!err) { int no_enc_rsa; PKT_public_key *pk; no_enc_rsa = ((get_parameter_algo (ctrl, para, pKEYTYPE, NULL) == PUBKEY_ALGO_RSA) && get_parameter_uint (para, pKEYUSAGE) && !((get_parameter_uint (para, pKEYUSAGE) & PUBKEY_USAGE_ENC)) ); pk = find_kbnode (pub_root, PKT_PUBLIC_KEY)->pkt->pkt.public_key; if (!opt.flags.no_auto_trust_new_key) update_ownertrust (ctrl, pk, ((get_ownertrust (ctrl, pk) & ~TRUST_MASK) | TRUST_ULTIMATE )); gen_standard_revoke (ctrl, pk, cache_nonce); /* Get rid of the first empty packet. */ commit_kbnode (&pub_root); if (!opt.batch) { tty_printf (_("public and secret key created and signed.\n") ); tty_printf ("\n"); merge_keys_and_selfsig (ctrl, pub_root); list_keyblock_direct (ctrl, pub_root, 0, 1, opt.fingerprint || opt.with_fingerprint, 1); } if (!opt.batch && (get_parameter_algo (ctrl, para, pKEYTYPE, NULL) == PUBKEY_ALGO_DSA || no_enc_rsa ) && !get_parameter (para, pSUBKEYTYPE) ) { tty_printf(_("Note that this key cannot be used for " "encryption. You may want to use\n" "the command \"--edit-key\" to generate a " "subkey for this purpose.\n") ); } } } if (err) { if (opt.batch) log_error ("key generation failed: %s\n", gpg_strerror (err) ); else tty_printf (_("Key generation failed: %s\n"), gpg_strerror (err) ); write_status_error (card? "card_key_generate":"key_generate", err); print_status_key_not_created ( get_parameter_value (para, pHANDLE) ); } else { PKT_public_key *pk = find_kbnode (pub_root, PKT_PUBLIC_KEY)->pkt->pkt.public_key; print_status_key_created (did_sub? 'B':'P', pk, get_parameter_value (para, pHANDLE)); } release_kbnode (pub_root); xfree (cache_nonce); } static gpg_error_t parse_algo_usage_expire (ctrl_t ctrl, int for_subkey, const char *algostr, const char *usagestr, const char *expirestr, int *r_algo, unsigned int *r_usage, u32 *r_expire, unsigned int *r_nbits, const char **r_curve, int *r_version, char **r_keygrip, u32 *r_keytime) { gpg_error_t err; int algo; unsigned int use, nbits; u32 expire; int wantuse; int version = 4; const char *curve = NULL; *r_curve = NULL; if (r_keygrip) *r_keygrip = NULL; if (r_keytime) *r_keytime = 0; nbits = 0; /* Parse the algo string. */ if (algostr && *algostr == '&' && strlen (algostr) == 41) { /* Take algo from existing key. */ algo = check_keygrip (ctrl, algostr+1); /* FIXME: We need the curve name as well. */ return gpg_error (GPG_ERR_NOT_IMPLEMENTED); } err = parse_key_parameter_string (ctrl, algostr, for_subkey? 1 : 0, usagestr? parse_usagestr (usagestr):0, &algo, &nbits, &use, &curve, &version, r_keygrip, r_keytime, NULL, NULL, NULL, NULL, NULL, NULL, NULL); if (err) { if (r_keygrip) { xfree (*r_keygrip); *r_keygrip = NULL; } return err; } /* Parse the usage string. */ if (!usagestr || !*usagestr || !ascii_strcasecmp (usagestr, "default") || !strcmp (usagestr, "-")) ; /* Keep usage from parse_key_parameter_string. */ else if ((wantuse = parse_usagestr (usagestr)) != -1) use = wantuse; else { if (r_keygrip) { xfree (*r_keygrip); *r_keygrip = NULL; } return gpg_error (GPG_ERR_INV_VALUE); } /* Make sure a primary key has the CERT usage. */ if (!for_subkey) use |= PUBKEY_USAGE_CERT; /* Check that usage is possible. NB: We have the same check in * parse_key_parameter_string but need it here again in case the * separate usage value has been given. */ if (/**/((use & (PUBKEY_USAGE_SIG|PUBKEY_USAGE_AUTH|PUBKEY_USAGE_CERT)) && !pubkey_get_nsig (algo)) || ((use & PUBKEY_USAGE_ENC) && !pubkey_get_nenc (algo)) || (for_subkey && (use & PUBKEY_USAGE_CERT))) { if (r_keygrip) { xfree (*r_keygrip); *r_keygrip = NULL; } return gpg_error (GPG_ERR_WRONG_KEY_USAGE); } /* Parse the expire string. */ expire = parse_expire_string (expirestr); if (expire == (u32)-1 ) { if (r_keygrip) { xfree (*r_keygrip); *r_keygrip = NULL; } return gpg_error (GPG_ERR_INV_VALUE); } if (curve) *r_curve = curve; *r_algo = algo; *r_usage = use; *r_expire = expire; *r_nbits = nbits; *r_version = version; return 0; } /* Add a new subkey to an existing key. Returns 0 if a new key has been generated and put into the keyblocks. If any of ALGOSTR, USAGESTR, or EXPIRESTR is NULL interactive mode is used. */ gpg_error_t generate_subkeypair (ctrl_t ctrl, kbnode_t keyblock, const char *algostr, const char *usagestr, const char *expirestr) { gpg_error_t err = 0; int interactive; kbnode_t node; PKT_public_key *pri_psk = NULL; PKT_public_key *sub_psk = NULL; int algo; unsigned int use; u32 expire; unsigned int nbits = 0; const char *curve = NULL; u32 cur_time; char *key_from_hexgrip = NULL; u32 keytime = 0; int cardkey = 0; char *hexgrip = NULL; char *serialno = NULL; char *cache_nonce = NULL; char *passwd_nonce = NULL; int keygen_flags = 0; interactive = (!algostr || !usagestr || !expirestr); /* Break out the primary key. */ node = find_kbnode (keyblock, PKT_PUBLIC_KEY); if (!node) { log_error ("Oops; primary key missing in keyblock!\n"); err = gpg_error (GPG_ERR_BUG); goto leave; } pri_psk = node->pkt->pkt.public_key; cur_time = make_timestamp (); if (pri_psk->timestamp > cur_time) { ulong d = pri_psk->timestamp - cur_time; log_info ( d==1 ? _("key has been created %lu second " "in future (time warp or clock problem)\n") : _("key has been created %lu seconds " "in future (time warp or clock problem)\n"), d ); if (!opt.ignore_time_conflict) { err = gpg_error (GPG_ERR_TIME_CONFLICT); goto leave; } } if (pri_psk->version < 4) { log_info (_("Note: creating subkeys for v3 keys " "is not OpenPGP compliant\n")); err = gpg_error (GPG_ERR_CONFLICT); goto leave; } err = hexkeygrip_from_pk (pri_psk, &hexgrip); if (err) goto leave; if (agent_get_keyinfo (NULL, hexgrip, &serialno, NULL)) { if (interactive) tty_printf (_("Secret parts of primary key are not available.\n")); else log_info ( _("Secret parts of primary key are not available.\n")); err = gpg_error (GPG_ERR_NO_SECKEY); goto leave; } if (serialno) { if (interactive) tty_printf (_("Secret parts of primary key are stored on-card.\n")); else log_info ( _("Secret parts of primary key are stored on-card.\n")); } if (interactive) { algo = ask_algo (ctrl, 1, NULL, &use, &key_from_hexgrip, &cardkey, &keytime); log_assert (algo); if (key_from_hexgrip) nbits = 0; else if (algo == PUBKEY_ALGO_ECDSA || algo == PUBKEY_ALGO_EDDSA || algo == PUBKEY_ALGO_ECDH) { curve = ask_curve (&algo, NULL, NULL); if (curve && (!strcmp (curve, "X448") || !strcmp (curve, "Ed448"))) keygen_flags |= KEYGEN_FLAG_CREATE_V5_KEY; } else nbits = ask_keysize (algo, 0); expire = ask_expire_interval (0, NULL); if (!cpr_enabled() && !cpr_get_answer_is_yes("keygen.sub.okay", _("Really create? (y/N) "))) { err = gpg_error (GPG_ERR_CANCELED); goto leave; } } else /* Unattended mode. */ { int version; err = parse_algo_usage_expire (ctrl, 1, algostr, usagestr, expirestr, &algo, &use, &expire, &nbits, &curve, &version, &key_from_hexgrip, &keytime); if (err) goto leave; if (version == 5) keygen_flags |= KEYGEN_FLAG_CREATE_V5_KEY; } /* Verify the passphrase now so that we get a cache item for the * primary key passphrase. The agent also returns a passphrase * nonce, which we can use to set the passphrase for the subkey to * that of the primary key. */ { char *desc = gpg_format_keydesc (ctrl, pri_psk, FORMAT_KEYDESC_NORMAL, 1); err = agent_passwd (ctrl, hexgrip, desc, 1 /*=verify*/, &cache_nonce, &passwd_nonce); xfree (desc); if (gpg_err_code (err) == GPG_ERR_NOT_IMPLEMENTED && gpg_err_source (err) == GPG_ERR_SOURCE_GPGAGENT) err = 0; /* Very likely that the key is on a card. */ if (err) goto leave; } /* Start creation. */ if (key_from_hexgrip) { err = do_create_from_keygrip (ctrl, algo, key_from_hexgrip, cardkey, keyblock, keytime? keytime : cur_time, expire, 1, keygen_flags); } else { const char *passwd; /* If the pinentry loopback mode is not and we have a static passphrase (i.e. set with --passphrase{,-fd,-file} while in batch mode), we use that passphrase for the new subkey. */ if (opt.pinentry_mode != PINENTRY_MODE_LOOPBACK && have_static_passphrase ()) passwd = get_static_passphrase (); else passwd = NULL; err = do_create (algo, nbits, curve, keyblock, cur_time, expire, 1, keygen_flags, passwd, &cache_nonce, &passwd_nonce); } if (err) goto leave; /* Get the pointer to the generated public subkey packet. */ for (node = keyblock; node; node = node->next) if (node->pkt->pkttype == PKT_PUBLIC_SUBKEY) sub_psk = node->pkt->pkt.public_key; /* Write the binding signature. */ err = write_keybinding (ctrl, keyblock, pri_psk, sub_psk, use, cur_time, cache_nonce); if (err) goto leave; print_status_key_created ('S', sub_psk, NULL); leave: xfree (key_from_hexgrip); xfree (hexgrip); xfree (serialno); xfree (cache_nonce); xfree (passwd_nonce); if (err) { log_error (_("Key generation failed: %s\n"), gpg_strerror (err) ); write_status_error (cardkey? "card_key_generate":"key_generate", err); print_status_key_not_created ( NULL ); } return err; } #ifdef ENABLE_CARD_SUPPORT /* Generate a subkey on a card. */ gpg_error_t generate_card_subkeypair (ctrl_t ctrl, kbnode_t pub_keyblock, int keyno, const char *serialno) { gpg_error_t err = 0; kbnode_t node; PKT_public_key *pri_pk = NULL; unsigned int use; u32 expire; u32 cur_time; struct para_data_s *para = NULL; PKT_public_key *sub_pk = NULL; int algo; struct agent_card_info_s info; int keygen_flags = 0; /* FIXME!!! */ log_assert (keyno >= 1 && keyno <= 3); memset (&info, 0, sizeof (info)); err = agent_scd_getattr ("KEY-ATTR", &info); if (err) { log_error (_("error getting current key info: %s\n"), gpg_strerror (err)); return err; } algo = info.key_attr[keyno-1].algo; para = xtrycalloc (1, sizeof *para + strlen (serialno) ); if (!para) { err = gpg_error_from_syserror (); goto leave; } para->key = pSERIALNO; strcpy (para->u.value, serialno); /* Break out the primary secret key */ node = find_kbnode (pub_keyblock, PKT_PUBLIC_KEY); if (!node) { log_error ("Oops; public key lost!\n"); err = gpg_error (GPG_ERR_INTERNAL); goto leave; } pri_pk = node->pkt->pkt.public_key; cur_time = make_timestamp(); if (pri_pk->timestamp > cur_time) { ulong d = pri_pk->timestamp - cur_time; log_info (d==1 ? _("key has been created %lu second " "in future (time warp or clock problem)\n") : _("key has been created %lu seconds " "in future (time warp or clock problem)\n"), d ); if (!opt.ignore_time_conflict) { err = gpg_error (GPG_ERR_TIME_CONFLICT); goto leave; } } if (pri_pk->version < 4) { log_info (_("Note: creating subkeys for v3 keys " "is not OpenPGP compliant\n")); err = gpg_error (GPG_ERR_NOT_SUPPORTED); goto leave; } expire = ask_expire_interval (0, NULL); if (keyno == 1) use = PUBKEY_USAGE_SIG; else if (keyno == 2) use = PUBKEY_USAGE_ENC; else use = PUBKEY_USAGE_AUTH; if (!cpr_enabled() && !cpr_get_answer_is_yes("keygen.cardsub.okay", _("Really create? (y/N) "))) { err = gpg_error (GPG_ERR_CANCELED); goto leave; } /* Note, that depending on the backend, the card key generation may update CUR_TIME. */ err = gen_card_key (keyno, algo, 0, pub_keyblock, &cur_time, expire, keygen_flags); /* Get the pointer to the generated public subkey packet. */ if (!err) { for (node = pub_keyblock; node; node = node->next) if (node->pkt->pkttype == PKT_PUBLIC_SUBKEY) sub_pk = node->pkt->pkt.public_key; log_assert (sub_pk); err = write_keybinding (ctrl, pub_keyblock, pri_pk, sub_pk, use, cur_time, NULL); } leave: if (err) log_error (_("Key generation failed: %s\n"), gpg_strerror (err) ); else print_status_key_created ('S', sub_pk, NULL); release_parameter_list (para); return err; } #endif /* !ENABLE_CARD_SUPPORT */ /* * Write a keyblock to an output stream */ static int write_keyblock( IOBUF out, KBNODE node ) { for( ; node ; node = node->next ) { if(!is_deleted_kbnode(node)) { int rc = build_packet( out, node->pkt ); if( rc ) { log_error("build_packet(%d) failed: %s\n", node->pkt->pkttype, gpg_strerror (rc) ); return rc; } } } return 0; } /* Note that timestamp is an in/out arg. * FIXME: Does not yet support v5 keys. */ static gpg_error_t gen_card_key (int keyno, int algo, int is_primary, kbnode_t pub_root, u32 *timestamp, u32 expireval, int keygen_flags) { #ifdef ENABLE_CARD_SUPPORT gpg_error_t err; PACKET *pkt; PKT_public_key *pk; char keyid[10]; unsigned char *public; gcry_sexp_t s_key; snprintf (keyid, DIM(keyid), "OPENPGP.%d", keyno); pk = xtrycalloc (1, sizeof *pk ); if (!pk) return gpg_error_from_syserror (); pkt = xtrycalloc (1, sizeof *pkt); if (!pkt) { xfree (pk); return gpg_error_from_syserror (); } /* Note: SCD knows the serialnumber, thus there is no point in passing it. */ err = agent_scd_genkey (keyno, 1, timestamp); /* The code below is not used because we force creation of * the a card key (3rd arg). * if (gpg_err_code (rc) == GPG_ERR_EEXIST) * { * tty_printf ("\n"); * log_error ("WARNING: key does already exists!\n"); * tty_printf ("\n"); * if ( cpr_get_answer_is_yes( "keygen.card.replace_key", * _("Replace existing key? "))) * rc = agent_scd_genkey (keyno, 1, timestamp); * } */ if (err) { log_error ("key generation failed: %s\n", gpg_strerror (err)); xfree (pkt); xfree (pk); return err; } /* Send the READKEY command so that the agent creates a shadow key for card key. We need to do that now so that we are able to create the self-signatures. */ err = agent_readkey (NULL, 1, keyid, &public); if (err) { xfree (pkt); xfree (pk); return err; } err = gcry_sexp_sscan (&s_key, NULL, public, gcry_sexp_canon_len (public, 0, NULL, NULL)); xfree (public); if (err) { xfree (pkt); xfree (pk); return err; } if (algo == PUBKEY_ALGO_RSA) err = key_from_sexp (pk->pkey, s_key, "public-key", "ne"); else if (algo == PUBKEY_ALGO_ECDSA || algo == PUBKEY_ALGO_EDDSA || algo == PUBKEY_ALGO_ECDH ) err = ecckey_from_sexp (pk->pkey, s_key, algo); else err = gpg_error (GPG_ERR_PUBKEY_ALGO); gcry_sexp_release (s_key); if (err) { log_error ("key_from_sexp failed: %s\n", gpg_strerror (err) ); free_public_key (pk); return err; } pk->timestamp = *timestamp; pk->version = (keygen_flags & KEYGEN_FLAG_CREATE_V5_KEY)? 5 : 4; if (expireval) pk->expiredate = pk->timestamp + expireval; pk->pubkey_algo = algo; pkt->pkttype = is_primary ? PKT_PUBLIC_KEY : PKT_PUBLIC_SUBKEY; pkt->pkt.public_key = pk; add_kbnode (pub_root, new_kbnode (pkt)); return 0; #else (void)keyno; (void)is_primary; (void)pub_root; (void)timestamp; (void)expireval; return gpg_error (GPG_ERR_NOT_SUPPORTED); #endif /*!ENABLE_CARD_SUPPORT*/ } diff --git a/g10/main.h b/g10/main.h index 6d5ba77ac..968465ebd 100644 --- a/g10/main.h +++ b/g10/main.h @@ -1,525 +1,525 @@ /* main.h * Copyright (C) 1998, 1999, 2000, 2001, 2002, 2003, 2004, 2005, 2006, 2007, * 2008, 2009, 2010 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 . */ #ifndef G10_MAIN_H #define G10_MAIN_H #include "../common/types.h" #include "../common/iobuf.h" #include "../common/util.h" #include "keydb.h" #include "keyedit.h" /* It could be argued that the default cipher should be 3DES rather than AES128, and the default compression should be 0 (i.e. uncompressed) rather than 1 (zip). However, the real world issues of speed and size come into play here. */ #if GPG_USE_AES256 # define DEFAULT_CIPHER_ALGO CIPHER_ALGO_AES256 #elif GPG_USE_AES128 # define DEFAULT_CIPHER_ALGO CIPHER_ALGO_AES #elif GPG_USE_CAST5 # define DEFAULT_CIPHER_ALGO CIPHER_ALGO_CAST5 #else # define DEFAULT_CIPHER_ALGO CIPHER_ALGO_3DES #endif #define DEFAULT_DIGEST_ALGO ((GNUPG)? DIGEST_ALGO_SHA256:DIGEST_ALGO_SHA1) #define DEFAULT_S2K_DIGEST_ALGO DIGEST_ALGO_SHA1 #ifdef HAVE_ZIP # define DEFAULT_COMPRESS_ALGO COMPRESS_ALGO_ZIP #else # define DEFAULT_COMPRESS_ALGO COMPRESS_ALGO_NONE #endif #define S2K_DIGEST_ALGO (opt.s2k_digest_algo?opt.s2k_digest_algo:DEFAULT_S2K_DIGEST_ALGO) /* Various data objects. */ typedef struct { ctrl_t ctrl; int header_okay; PK_LIST pk_list; DEK *symkey_dek; STRING2KEY *symkey_s2k; cipher_filter_context_t cfx; } encrypt_filter_context_t; struct groupitem { char *name; strlist_t values; struct groupitem *next; }; struct weakhash { enum gcry_md_algos algo; int rejection_shown; struct weakhash *next; }; /*-- gpg.c --*/ extern int g10_errors_seen; #if __GNUC__ > 2 || (__GNUC__ == 2 && __GNUC_MINOR__ >= 5 ) void g10_exit(int rc) __attribute__ ((__noreturn__)); #else void g10_exit(int rc); #endif void print_pubkey_algo_note (pubkey_algo_t algo); void print_cipher_algo_note (cipher_algo_t algo); void print_digest_algo_note (digest_algo_t algo); void print_digest_rejected_note (enum gcry_md_algos algo); void print_sha1_keysig_rejected_note (void); void print_reported_error (gpg_error_t err, gpg_err_code_t skip_if_ec); void print_further_info (const char *format, ...) GPGRT_ATTR_PRINTF(1,2); void additional_weak_digest (const char* digestname); int is_weak_digest (digest_algo_t algo); /*-- armor.c --*/ char *make_radix64_string( const byte *data, size_t len ); /*-- misc.c --*/ void trap_unaligned(void); void register_secured_file (const char *fname); void unregister_secured_file (const char *fname); int is_secured_file (int fd); int is_secured_filename (const char *fname); u16 checksum_u16( unsigned n ); u16 checksum( const byte *p, unsigned n ); u16 checksum_mpi( gcry_mpi_t a ); u32 buffer_to_u32( const byte *buffer ); const byte *get_session_marker( size_t *rlen ); enum gcry_cipher_algos map_cipher_openpgp_to_gcry (cipher_algo_t algo); #define openpgp_cipher_open(_a,_b,_c,_d) \ gcry_cipher_open((_a),map_cipher_openpgp_to_gcry((_b)),(_c),(_d)) #define openpgp_cipher_get_algo_keylen(_a) \ gcry_cipher_get_algo_keylen(map_cipher_openpgp_to_gcry((_a))) #define openpgp_cipher_get_algo_blklen(_a) \ gcry_cipher_get_algo_blklen(map_cipher_openpgp_to_gcry((_a))) int openpgp_cipher_blocklen (cipher_algo_t algo); int openpgp_cipher_test_algo(cipher_algo_t algo); const char *openpgp_cipher_algo_name (cipher_algo_t algo); const char *openpgp_cipher_algo_mode_name (cipher_algo_t algo, aead_algo_t aead); gpg_error_t openpgp_aead_test_algo (aead_algo_t algo); const char *openpgp_aead_algo_name (aead_algo_t algo); gpg_error_t openpgp_aead_algo_info (aead_algo_t algo, enum gcry_cipher_modes *r_mode, unsigned int *r_noncelen); int openpgp_pk_test_algo (pubkey_algo_t algo); int openpgp_pk_test_algo2 (pubkey_algo_t algo, unsigned int use); int openpgp_pk_algo_usage ( int algo ); const char *openpgp_pk_algo_name (pubkey_algo_t algo); enum gcry_md_algos map_md_openpgp_to_gcry (digest_algo_t algo); int openpgp_md_test_algo (digest_algo_t algo); const char *openpgp_md_algo_name (int algo); struct expando_args { PKT_public_key *pk; PKT_public_key *pksk; byte imagetype; int validity_info; const char *validity_string; const byte *namehash; }; char *pct_expando (ctrl_t ctrl, const char *string,struct expando_args *args); void deprecated_warning(const char *configname,unsigned int configlineno, const char *option,const char *repl1,const char *repl2); void deprecated_command (const char *name); void obsolete_scdaemon_option (const char *configname, unsigned int configlineno, const char *name); int string_to_cipher_algo (const char *string); aead_algo_t string_to_aead_algo (const char *string); int string_to_digest_algo (const char *string); const char *compress_algo_to_string(int algo); int string_to_compress_algo(const char *string); int check_compress_algo(int algo); int default_cipher_algo(void); int default_compress_algo(void); void compliance_failure(void); struct parse_options { char *name; unsigned int bit; char **value; char *help; }; char *optsep(char **stringp); char *argsplit(char *string); int parse_options(char *str,unsigned int *options, struct parse_options *opts,int noisy); const char *get_libexecdir (void); int path_access(const char *file,int mode); int pubkey_get_npkey (pubkey_algo_t algo); int pubkey_get_nskey (pubkey_algo_t algo); int pubkey_get_nsig (pubkey_algo_t algo); int pubkey_get_nenc (pubkey_algo_t algo); /* Temporary helpers. */ unsigned int pubkey_nbits( int algo, gcry_mpi_t *pkey ); int mpi_print (estream_t stream, gcry_mpi_t a, int mode); unsigned int ecdsa_qbits_from_Q (unsigned int qbits); /*-- cpr.c --*/ void set_status_fd ( int fd ); int is_status_enabled ( void ); void write_status ( int no ); void write_status_error (const char *where, gpg_error_t err); void write_status_errcode (const char *where, int errcode); void write_status_failure (const char *where, gpg_error_t err); void write_status_text ( int no, const char *text ); void write_status_printf (int no, const char *format, ...) GPGRT_ATTR_PRINTF(2,3); void write_status_strings (int no, const char *text, ...) GPGRT_ATTR_SENTINEL(0); gpg_error_t write_status_strings2 (ctrl_t dummy, int no, ...) GPGRT_ATTR_SENTINEL(0); void write_status_buffer ( int no, const char *buffer, size_t len, int wrap ); void write_status_text_and_buffer ( int no, const char *text, const char *buffer, size_t len, int wrap ); void write_status_begin_signing (gcry_md_hd_t md); int cpr_enabled(void); char *cpr_get( const char *keyword, const char *prompt ); char *cpr_get_no_help( const char *keyword, const char *prompt ); char *cpr_get_utf8( const char *keyword, const char *prompt ); char *cpr_get_hidden( const char *keyword, const char *prompt ); void cpr_kill_prompt(void); int cpr_get_answer_is_yes_def (const char *keyword, const char *prompt, int def_yes); int cpr_get_answer_is_yes( const char *keyword, const char *prompt ); int cpr_get_answer_yes_no_quit( const char *keyword, const char *prompt ); int cpr_get_answer_okay_cancel (const char *keyword, const char *prompt, int def_answer); /*-- helptext.c --*/ void display_online_help( const char *keyword ); /*-- encode.c --*/ gpg_error_t setup_symkey (STRING2KEY **symkey_s2k,DEK **symkey_dek); aead_algo_t use_aead (pk_list_t pk_list, int algo); int use_mdc (pk_list_t pk_list,int algo); int encrypt_symmetric (const char *filename ); int encrypt_store (const char *filename ); int encrypt_crypt (ctrl_t ctrl, int filefd, const char *filename, strlist_t remusr, int use_symkey, pk_list_t provided_keys, int outputfd); void encrypt_crypt_files (ctrl_t ctrl, int nfiles, char **files, strlist_t remusr); int encrypt_filter (void *opaque, int control, iobuf_t a, byte *buf, size_t *ret_len); int write_pubkey_enc (ctrl_t ctrl, PKT_public_key *pk, int throw_keyid, DEK *dek, iobuf_t out); /*-- sign.c --*/ int sign_file (ctrl_t ctrl, strlist_t filenames, int detached, strlist_t locusr, int do_encrypt, strlist_t remusr, const char *outfile ); int clearsign_file (ctrl_t ctrl, const char *fname, strlist_t locusr, const char *outfile); int sign_symencrypt_file (ctrl_t ctrl, const char *fname, strlist_t locusr); /*-- sig-check.c --*/ void sig_check_dump_stats (void); /* SIG is a revocation signature. Check if any of PK's designated revokers generated it. If so, return 0. Note: this function (correctly) doesn't care if the designated revoker is revoked. */ int check_revocation_keys (ctrl_t ctrl, PKT_public_key *pk, PKT_signature *sig); /* Check that the backsig BACKSIG from the subkey SUB_PK to its primary key MAIN_PK is valid. */ int check_backsig(PKT_public_key *main_pk,PKT_public_key *sub_pk, PKT_signature *backsig); /* Check that the signature SIG over a key (e.g., a key binding or a key revocation) is valid. (To check signatures over data, use check_signature.) */ int check_key_signature (ctrl_t ctrl, kbnode_t root, kbnode_t sig, int *is_selfsig ); /* Like check_key_signature, but with the ability to specify some additional parameters and get back additional information. See the documentation for the implementation for details. */ int check_key_signature2 (ctrl_t ctrl, kbnode_t root, kbnode_t node, PKT_public_key *check_pk, PKT_public_key *ret_pk, int *is_selfsig, u32 *r_expiredate, int *r_expired); /* Returns whether SIGNER generated the signature SIG over the packet PACKET, which is a key, subkey or uid, and comes from the key block KB. If SIGNER is NULL, it is looked up based on the information in SIG. If not NULL, sets *IS_SELFSIG to indicate whether the signature is a self-signature and *RET_PK to a copy of the signer's key. */ gpg_error_t check_signature_over_key_or_uid (ctrl_t ctrl, PKT_public_key *signer, PKT_signature *sig, KBNODE kb, PACKET *packet, int *is_selfsig, PKT_public_key *ret_pk); /*-- delkey.c --*/ gpg_error_t delete_keys (ctrl_t ctrl, strlist_t names, int secret, int allow_both); /*-- keygen.c --*/ const char *get_default_pubkey_algo (void); u32 parse_expire_string(const char *string); u32 ask_expire_interval(int object,const char *def_expire); u32 ask_expiredate(void); unsigned int ask_key_flags (int algo, int subkey, unsigned int current); const char *ask_curve (int *algo, int *subkey_algo, const char *current); void quick_generate_keypair (ctrl_t ctrl, const char *uid, const char *algostr, const char *usagestr, const char *expirestr); void generate_keypair (ctrl_t ctrl, int full, const char *fname, const char *card_serialno, int card_backup_key); int keygen_set_std_prefs (const char *string,int personal); PKT_user_id *keygen_get_std_prefs (void); int keygen_add_key_expire( PKT_signature *sig, void *opaque ); int keygen_add_key_flags (PKT_signature *sig, void *opaque); int keygen_add_std_prefs( PKT_signature *sig, void *opaque ); int keygen_upd_std_prefs( PKT_signature *sig, void *opaque ); int keygen_add_keyserver_url(PKT_signature *sig, void *opaque); int keygen_add_notations(PKT_signature *sig,void *opaque); int keygen_add_revkey(PKT_signature *sig, void *opaque); gpg_error_t make_backsig (ctrl_t ctrl, PKT_signature *sig, PKT_public_key *pk, PKT_public_key *sub_pk, PKT_public_key *sub_psk, u32 timestamp, const char *cache_nonce); gpg_error_t generate_subkeypair (ctrl_t ctrl, kbnode_t keyblock, const char *algostr, const char *usagestr, const char *expirestr); #ifdef ENABLE_CARD_SUPPORT gpg_error_t generate_card_subkeypair (ctrl_t ctrl, kbnode_t pub_keyblock, int keyno, const char *serialno); #endif /*-- openfile.c --*/ int overwrite_filep( const char *fname ); char *make_outfile_name( const char *iname ); char *ask_outfile_name( const char *name, size_t namelen ); int open_outfile (int out_fd, const char *iname, int mode, int restrictedperm, iobuf_t *a); char *get_matching_datafile (const char *sigfilename); iobuf_t open_sigfile (const char *sigfilename, progress_filter_context_t *pfx); void try_make_homedir( const char *fname ); char *get_openpgp_revocdir (const char *home); /*-- seskey.c --*/ void make_session_key( DEK *dek ); gcry_mpi_t encode_session_key( int openpgp_pk_algo, DEK *dek, unsigned nbits ); gcry_mpi_t encode_md_value (PKT_public_key *pk, gcry_md_hd_t md, int hash_algo ); /*-- import.c --*/ struct import_stats_s; typedef struct import_stats_s *import_stats_t; struct import_filter_s; typedef struct import_filter_s *import_filter_t; typedef gpg_error_t (*import_screener_t)(kbnode_t keyblock, void *arg); int parse_import_options(char *str,unsigned int *options,int noisy); gpg_error_t parse_and_set_import_filter (const char *string); import_filter_t save_and_clear_import_filter (void); void restore_import_filter (import_filter_t filt); gpg_error_t read_key_from_file_or_buffer (ctrl_t ctrl, const char *fname, const void *buffer, size_t buflen, kbnode_t *r_keyblock); gpg_error_t import_included_key_block (ctrl_t ctrl, kbnode_t keyblock); void import_keys (ctrl_t ctrl, char **fnames, int nnames, import_stats_t stats_hd, unsigned int options, int origin, const char *url); gpg_error_t import_keys_es_stream (ctrl_t ctrl, estream_t fp, import_stats_t stats_handle, unsigned char **fpr, size_t *fpr_len, unsigned int options, import_screener_t screener, void *screener_arg, int origin, const char *url); gpg_error_t import_old_secring (ctrl_t ctrl, const char *fname); import_stats_t import_new_stats_handle (void); void import_release_stats_handle (import_stats_t hd); void import_print_stats (import_stats_t hd); /* Communication for impex_filter_getval */ struct impex_filter_parm_s { ctrl_t ctrl; kbnode_t node; char hexfpr[2*MAX_FINGERPRINT_LEN + 1]; }; const char *impex_filter_getval (void *cookie, const char *propname); gpg_error_t transfer_secret_keys (ctrl_t ctrl, struct import_stats_s *stats, kbnode_t sec_keyblock, int batch, int force, int only_marked); int collapse_uids (kbnode_t *keyblock); int collapse_subkeys (kbnode_t *keyblock); int get_revocation_reason (PKT_signature *sig, char **r_reason, char **r_comment, size_t *r_commentlen); /*-- export.c --*/ struct export_stats_s; typedef struct export_stats_s *export_stats_t; export_stats_t export_new_stats (void); void export_release_stats (export_stats_t stats); void export_print_stats (export_stats_t stats); int parse_export_options(char *str,unsigned int *options,int noisy); gpg_error_t parse_and_set_export_filter (const char *string); void push_export_filters (void); void pop_export_filters (void); int exact_subkey_match_p (KEYDB_SEARCH_DESC *desc, kbnode_t node); int export_pubkeys (ctrl_t ctrl, strlist_t users, unsigned int options, export_stats_t stats); int export_seckeys (ctrl_t ctrl, strlist_t users, unsigned int options, export_stats_t stats); int export_secsubkeys (ctrl_t ctrl, strlist_t users, unsigned int options, export_stats_t stats); gpg_error_t export_pubkey_buffer (ctrl_t ctrl, const char *keyspec, unsigned int options, const void *prefix, size_t prefixlen, export_stats_t stats, kbnode_t *r_keyblock, void **r_data, size_t *r_datalen); gpg_error_t receive_seckey_from_agent (ctrl_t ctrl, gcry_cipher_hd_t cipherhd, int cleartext, char **cache_nonce_addr, const char *hexgrip, - PKT_public_key *pk); + PKT_public_key *pk, gcry_sexp_t *r_key); gpg_error_t write_keyblock_to_output (kbnode_t keyblock, int with_armor, unsigned int options); gpg_error_t export_ssh_key (ctrl_t ctrl, const char *userid); gpg_error_t export_secret_ssh_key (ctrl_t ctrl, const char *userid); /*-- dearmor.c --*/ int dearmor_file( const char *fname ); int enarmor_file( const char *fname ); /*-- revoke.c --*/ struct revocation_reason_info; int gen_standard_revoke (ctrl_t ctrl, PKT_public_key *psk, const char *cache_nonce); int gen_revoke (ctrl_t ctrl, const char *uname); int gen_desig_revoke (ctrl_t ctrl, const char *uname, strlist_t locusr); int revocation_reason_build_cb( PKT_signature *sig, void *opaque ); struct revocation_reason_info * ask_revocation_reason( int key_rev, int cert_rev, int hint ); struct revocation_reason_info * get_default_uid_revocation_reason (void); struct revocation_reason_info * get_default_sig_revocation_reason (void); void release_revocation_reason_info (struct revocation_reason_info *reason); /*-- keylist.c --*/ void public_key_list (ctrl_t ctrl, strlist_t list, int locate_mode, int no_local); void secret_key_list (ctrl_t ctrl, strlist_t list ); gpg_error_t parse_and_set_list_filter (const char *string); void print_subpackets_colon(PKT_signature *sig); void reorder_keyblock (KBNODE keyblock); void list_keyblock_direct (ctrl_t ctrl, kbnode_t keyblock, int secret, int has_secret, int fpr, int no_validity); int cmp_signodes (const void *av, const void *bv); void print_fingerprint (ctrl_t ctrl, estream_t fp, PKT_public_key *pk, int mode); void print_revokers (estream_t fp, PKT_public_key *pk); void show_preferences (PKT_user_id *uid, int indent, int mode, int verbose); void show_policy_url(PKT_signature *sig,int indent,int mode); void show_keyserver_url(PKT_signature *sig,int indent,int mode); void show_notation(PKT_signature *sig,int indent,int mode,int which); void dump_attribs (const PKT_user_id *uid, PKT_public_key *pk); void set_attrib_fd(int fd); void print_key_info (ctrl_t ctrl, estream_t fp, int indent, PKT_public_key *pk, int secret); void print_key_info_log (ctrl_t ctrl, int loglevel, int indent, PKT_public_key *pk, int secret); void print_card_key_info (estream_t fp, KBNODE keyblock); void print_key_line (ctrl_t ctrl, estream_t fp, PKT_public_key *pk, int secret); /*-- verify.c --*/ void print_file_status( int status, const char *name, int what ); int verify_signatures (ctrl_t ctrl, int nfiles, char **files ); int verify_files (ctrl_t ctrl, int nfiles, char **files ); int gpg_verify (ctrl_t ctrl, int sig_fd, int data_fd, estream_t out_fp); /*-- decrypt.c --*/ int decrypt_message (ctrl_t ctrl, const char *filename ); gpg_error_t decrypt_message_fd (ctrl_t ctrl, int input_fd, int output_fd); void decrypt_messages (ctrl_t ctrl, int nfiles, char *files[]); /*-- plaintext.c --*/ int hash_datafiles( gcry_md_hd_t md, gcry_md_hd_t md2, strlist_t files, const char *sigfilename, int textmode); int hash_datafile_by_fd ( gcry_md_hd_t md, gcry_md_hd_t md2, int data_fd, int textmode ); PKT_plaintext *setup_plaintext_name(const char *filename,IOBUF iobuf); /*-- server.c --*/ int gpg_server (ctrl_t); gpg_error_t gpg_proxy_pinentry_notify (ctrl_t ctrl, const unsigned char *line); #ifdef ENABLE_CARD_SUPPORT /*-- card-util.c --*/ void change_pin (int no, int allow_admin); void card_status (ctrl_t ctrl, estream_t fp, const char *serialno); void card_edit (ctrl_t ctrl, strlist_t commands); gpg_error_t card_generate_subkey (ctrl_t ctrl, kbnode_t pub_keyblock); int card_store_subkey (KBNODE node, int use); #endif /*-- migrate.c --*/ void migrate_secring (ctrl_t ctrl); #endif /*G10_MAIN_H*/