/* passphrase.c - Get a passphrase * Copyright (C) 1998, 1999, 2000, 2001, 2002, 2003, 2004, * 2005, 2006, 2007, 2009 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 . */ #include #include #include #include #include #include #include #include #ifdef HAVE_LOCALE_H #include #endif #ifdef HAVE_LANGINFO_CODESET #include #endif #include "gpg.h" #include "util.h" #include "options.h" #include "ttyio.h" #include "cipher.h" #include "keydb.h" #include "main.h" #include "i18n.h" #include "status.h" #include "call-agent.h" static char *fd_passwd = NULL; static char *next_pw = NULL; static char *last_pw = NULL; /* Pack an s2k iteration count into the form specified in 2440. If we're in between valid values, round up. With value 0 return the old default. */ unsigned char encode_s2k_iterations (int iterations) { gpg_error_t err; unsigned char c=0; unsigned char result; unsigned int count; if (!iterations) { unsigned long mycnt; /* Ask the gpg-agent for a useful iteration count. */ err = agent_get_s2k_count (&mycnt); if (err || mycnt < 65536) { /* Don't print an error if an older agent is used. */ if (err && gpg_err_code (err) != GPG_ERR_ASS_PARAMETER) log_error (_("problem with the agent: %s\n"), gpg_strerror (err)); /* Default to 65536 which we used up to 2.0.13. */ return 96; } else if (mycnt >= 65011712) return 255; /* Largest possible value. */ else return encode_s2k_iterations ((int)mycnt); } if (iterations <= 1024) return 0; /* Command line arg compatibility. */ if (iterations >= 65011712) return 255; /* Need count to be in the range 16-31 */ for (count=iterations>>6; count>=32; count>>=1) c++; result = (c<<4)|(count-16); if (S2K_DECODE_COUNT(result) < iterations) result++; return result; } /* Hash a passphrase using the supplied s2k. Always needs: dek->algo, s2k->mode, s2k->hash_algo. */ static void hash_passphrase ( DEK *dek, char *pw, STRING2KEY *s2k) { gcry_md_hd_t md; int pass, i; int used = 0; int pwlen = strlen(pw); assert ( s2k->hash_algo ); dek->keylen = openpgp_cipher_get_algo_keylen (dek->algo); if ( !(dek->keylen > 0 && dek->keylen <= DIM(dek->key)) ) BUG(); if (gcry_md_open (&md, s2k->hash_algo, 1)) BUG (); for (pass=0; used < dek->keylen ; pass++ ) { if ( pass ) { gcry_md_reset (md); for (i=0; i < pass; i++ ) /* Preset the hash context. */ gcry_md_putc (md, 0 ); } if ( s2k->mode == 1 || s2k->mode == 3 ) { int len2 = pwlen + 8; ulong count = len2; if ( s2k->mode == 3 ) { count = S2K_DECODE_COUNT(s2k->count); if ( count < len2 ) count = len2; } /* Fixme: To avoid DoS attacks by sending an sym-encrypted packet with a very high S2K count, we should either cap the iteration count or CPU seconds based timeout. */ /* A little bit complicated because we need a ulong for count. */ while ( count > len2 ) /* maybe iterated+salted */ { gcry_md_write ( md, s2k->salt, 8 ); gcry_md_write ( md, pw, pwlen ); count -= len2; } if ( count < 8 ) gcry_md_write ( md, s2k->salt, count ); else { gcry_md_write ( md, s2k->salt, 8 ); count -= 8; gcry_md_write ( md, pw, count ); } } else gcry_md_write ( md, pw, pwlen ); gcry_md_final( md ); i = gcry_md_get_algo_dlen ( s2k->hash_algo ); if ( i > dek->keylen - used ) i = dek->keylen - used; memcpy (dek->key+used, gcry_md_read (md, s2k->hash_algo), i); used += i; } gcry_md_close(md); } int have_static_passphrase() { return !!fd_passwd && opt.batch; } /**************** * Set the passphrase to be used for the next query and only for the next * one. */ void set_next_passphrase( const char *s ) { xfree(next_pw); next_pw = NULL; if ( s ) { next_pw = xmalloc_secure( strlen(s)+1 ); strcpy (next_pw, s ); } } /**************** * Get the last passphrase used in passphrase_to_dek. * Note: This removes the passphrase from this modules and * the caller must free the result. May return NULL: */ char * get_last_passphrase() { char *p = last_pw; last_pw = NULL; return p; } /* As if we had used the passphrase - make it the last_pw. */ void next_to_last_passphrase(void) { if (next_pw) { last_pw=next_pw; next_pw=NULL; } } /* Here's an interesting question: since this passphrase was passed in on the command line, is there really any point in using secure memory for it? I'm going with 'yes', since it doesn't hurt, and might help in some small way (swapping). */ void set_passphrase_from_string(const char *pass) { xfree (fd_passwd); fd_passwd = xmalloc_secure(strlen(pass)+1); strcpy (fd_passwd, pass); } void read_passphrase_from_fd( int fd ) { int i, len; char *pw; if ( !opt.batch ) { /* Not used but we have to do a dummy read, so that it won't end up at the begin of the message if the quite usual trick to prepend the passphtrase to the message is used. */ char buf[1]; while (!(read (fd, buf, 1) != 1 || *buf == '\n' )) ; *buf = 0; return; } for (pw = NULL, i = len = 100; ; i++ ) { if (i >= len-1 ) { char *pw2 = pw; len += 100; pw = xmalloc_secure( len ); if( pw2 ) { memcpy(pw, pw2, i ); xfree (pw2); } else i=0; } if (read( fd, pw+i, 1) != 1 || pw[i] == '\n' ) break; } pw[i] = 0; if (!opt.batch) tty_printf("\b\b\b \n" ); xfree ( fd_passwd ); fd_passwd = pw; } /* * Ask the GPG Agent for the passphrase. * Mode 0: Allow cached passphrase * 1: No cached passphrase; that is we are asking for a new passphrase * FIXME: Only partially implemented * * Note that TRYAGAIN_TEXT must not be translated. If CANCELED is not * NULL, the function does set it to 1 if the user canceled the * operation. If CACHEID is not NULL, it will be used as the cacheID * for the gpg-agent; if is NULL and a key fingerprint can be * computed, this will be used as the cacheid. */ static char * passphrase_get ( u32 *keyid, int mode, const char *cacheid, int repeat, const char *tryagain_text, const char *custom_description, const char *custom_prompt, int *canceled) { int rc; char *atext = NULL; char *pw = NULL; PKT_public_key *pk = xmalloc_clear( sizeof *pk ); byte fpr[MAX_FINGERPRINT_LEN]; int have_fpr = 0; char *orig_codeset; char *my_prompt; char hexfprbuf[20*2+1]; const char *my_cacheid; int check = (mode == 1); if (canceled) *canceled = 0; #if MAX_FINGERPRINT_LEN < 20 #error agent needs a 20 byte fingerprint #endif memset (fpr, 0, MAX_FINGERPRINT_LEN ); if( keyid && get_pubkey( pk, keyid ) ) { if (pk) free_public_key( pk ); pk = NULL; /* oops: no key for some reason */ } orig_codeset = i18n_switchto_utf8 (); if (custom_description) atext = native_to_utf8 (custom_description); else if ( !mode && pk && keyid ) { char *uid; size_t uidlen; const char *algo_name = gcry_pk_algo_name ( pk->pubkey_algo ); const char *timestr; char *maink; if ( !algo_name ) algo_name = "?"; #define KEYIDSTRING _(" (main key ID %s)") maink = xmalloc ( strlen (KEYIDSTRING) + keystrlen() + 20 ); if( keyid[2] && keyid[3] && keyid[0] != keyid[2] && keyid[1] != keyid[3] ) sprintf( maink, KEYIDSTRING, keystr(&keyid[2]) ); else *maink = 0; uid = get_user_id ( keyid, &uidlen ); timestr = strtimestamp (pk->timestamp); #undef KEYIDSTRING #define PROMPTSTRING _("Please enter the passphrase to unlock the" \ " secret key for the OpenPGP certificate:\n" \ "\"%.*s\"\n" \ "%u-bit %s key, ID %s,\n" \ "created %s%s.\n" ) atext = xmalloc ( 100 + strlen (PROMPTSTRING) + uidlen + 15 + strlen(algo_name) + keystrlen() + strlen (timestr) + strlen (maink) ); sprintf (atext, PROMPTSTRING, (int)uidlen, uid, nbits_from_pk (pk), algo_name, keystr(&keyid[0]), timestr, maink ); xfree (uid); xfree (maink); #undef PROMPTSTRING { size_t dummy; fingerprint_from_pk( pk, fpr, &dummy ); have_fpr = 1; } } else atext = xstrdup ( _("Enter passphrase\n") ); if (!mode && cacheid) my_cacheid = cacheid; else if (!mode && have_fpr) my_cacheid = bin2hex (fpr, 20, hexfprbuf); else my_cacheid = NULL; if (tryagain_text) tryagain_text = _(tryagain_text); my_prompt = custom_prompt ? native_to_utf8 (custom_prompt): NULL; rc = agent_get_passphrase (my_cacheid, tryagain_text, my_prompt, atext, repeat, check, &pw); xfree (my_prompt); xfree (atext); atext = NULL; i18n_switchback (orig_codeset); if (!rc) ; else if ( gpg_err_code (rc) == GPG_ERR_CANCELED ) { log_info (_("cancelled by user\n") ); if (canceled) *canceled = 1; } else { log_error (_("problem with the agent: %s\n"), gpg_strerror (rc)); /* Due to limitations in the API of the upper layers they consider an error as no passphrase entered. This works in most cases but not during key creation where this should definitely not happen and let it continue without requiring a passphrase. Given that now all the upper layers handle a cancel correctly, we simply set the cancel flag now for all errors from the agent. */ if (canceled) *canceled = 1; write_status_errcode ("get_passphrase", rc); } if (pk) free_public_key( pk ); if (rc) { xfree (pw); return NULL; } return pw; } /* * Clear the cached passphrase. If CACHEID is not NULL, it will be * used instead of a cache ID derived from KEYID. */ void passphrase_clear_cache ( u32 *keyid, const char *cacheid, int algo ) { int rc; (void)algo; if (!cacheid) { PKT_public_key *pk; # if MAX_FINGERPRINT_LEN < 20 # error agent needs a 20 byte fingerprint # endif byte fpr[MAX_FINGERPRINT_LEN]; char hexfprbuf[2*20+1]; size_t dummy; pk = xcalloc (1, sizeof *pk); if ( !keyid || get_pubkey( pk, keyid ) ) { log_error ("key not found in passphrase_clear_cache\n"); free_public_key (pk); return; } memset (fpr, 0, MAX_FINGERPRINT_LEN ); fingerprint_from_pk ( pk, fpr, &dummy ); bin2hex (fpr, 20, hexfprbuf); rc = agent_clear_passphrase (hexfprbuf); free_public_key ( pk ); } else rc = agent_clear_passphrase (cacheid); if (rc) log_error (_("problem with the agent: %s\n"), gpg_strerror (rc)); } /* Return a new DEK object Using the string-to-key sepcifier S2K. Use KEYID and PUBKEY_ALGO to prompt the user. Returns NULL is the user selected to cancel the passphrase entry and if CANCELED is not NULL, sets it to true. MODE 0: Allow cached passphrase 1: Ignore cached passphrase 2: Ditto, but create a new key 3: Allow cached passphrase; use the S2K salt as the cache ID 4: Ditto, but create a new key */ DEK * passphrase_to_dek_ext (u32 *keyid, int pubkey_algo, int cipher_algo, STRING2KEY *s2k, int mode, const char *tryagain_text, const char *custdesc, const char *custprompt, int *canceled) { char *pw = NULL; DEK *dek; STRING2KEY help_s2k; int dummy_canceled; char s2k_cacheidbuf[1+16+1], *s2k_cacheid = NULL; if (!canceled) canceled = &dummy_canceled; *canceled = 0; if ( !s2k ) { assert (mode != 3 && mode != 4); /* This is used for the old rfc1991 mode * Note: This must match the code in encode.c with opt.rfc1991 set */ s2k = &help_s2k; s2k->mode = 0; s2k->hash_algo = S2K_DIGEST_ALGO; } /* Create a new salt or what else to be filled into the s2k for a new key. */ if ((mode == 2 || mode == 4) && (s2k->mode == 1 || s2k->mode == 3)) { gcry_randomize (s2k->salt, 8, GCRY_STRONG_RANDOM); if ( s2k->mode == 3 ) { /* We delay the encoding until it is really needed. This is if we are going to dynamically calibrate it, we need to call out to gpg-agent and that should not be done during option processing in main(). */ if (!opt.s2k_count) opt.s2k_count = encode_s2k_iterations (0); s2k->count = opt.s2k_count; } } /* If we do not have a passphrase available in NEXT_PW and status information are request, we print them now. */ if ( !next_pw && is_status_enabled() ) { char buf[50]; if ( keyid ) { u32 used_kid[2]; char *us; if ( keyid[2] && keyid[3] ) { used_kid[0] = keyid[2]; used_kid[1] = keyid[3]; } else { used_kid[0] = keyid[0]; used_kid[1] = keyid[1]; } us = get_long_user_id_string ( keyid ); write_status_text ( STATUS_USERID_HINT, us ); xfree(us); snprintf (buf, sizeof buf -1, "%08lX%08lX %08lX%08lX %d 0", (ulong)keyid[0], (ulong)keyid[1], (ulong)used_kid[0], (ulong)used_kid[1], pubkey_algo ); write_status_text ( STATUS_NEED_PASSPHRASE, buf ); } else { snprintf (buf, sizeof buf -1, "%d %d %d", cipher_algo, s2k->mode, s2k->hash_algo ); write_status_text ( STATUS_NEED_PASSPHRASE_SYM, buf ); } } /* If we do have a keyID, we do not have a passphrase available in NEXT_PW, we are not running in batch mode and we do not want to ignore the passphrase cache (mode!=1), print a prompt with information on that key. */ if ( keyid && !opt.batch && !next_pw && mode!=1 ) { PKT_public_key *pk = xmalloc_clear( sizeof *pk ); char *p; p = get_user_id_native(keyid); tty_printf ("\n"); tty_printf (_("You need a passphrase to unlock the secret key for\n" "user: \"%s\"\n"),p); xfree(p); if ( !get_pubkey( pk, keyid ) ) { const char *s = gcry_pk_algo_name ( pk->pubkey_algo ); tty_printf (_("%u-bit %s key, ID %s, created %s"), nbits_from_pk( pk ), s?s:"?", keystr(keyid), strtimestamp(pk->timestamp) ); if ( keyid[2] && keyid[3] && keyid[0] != keyid[2] && keyid[1] != keyid[3] ) { if ( keystrlen () > 10 ) { tty_printf ("\n"); tty_printf (_(" (subkey on main key ID %s)"), keystr(&keyid[2]) ); } else tty_printf ( _(" (main key ID %s)"), keystr(&keyid[2]) ); } tty_printf("\n"); } tty_printf("\n"); if (pk) free_public_key( pk ); } if ( next_pw ) { /* Simply return the passphrase we already have in NEXT_PW. */ pw = next_pw; next_pw = NULL; } else if ( have_static_passphrase () ) { /* Return the passphrase we have stored in FD_PASSWD. */ pw = xmalloc_secure ( strlen(fd_passwd)+1 ); strcpy ( pw, fd_passwd ); } else { if ((mode == 3 || mode == 4) && (s2k->mode == 1 || s2k->mode == 3)) { memset (s2k_cacheidbuf, 0, sizeof s2k_cacheidbuf); *s2k_cacheidbuf = 'S'; bin2hex (s2k->salt, 8, s2k_cacheidbuf + 1); s2k_cacheid = s2k_cacheidbuf; } /* Divert to the gpg-agent. */ pw = passphrase_get (keyid, mode == 2, s2k_cacheid, (mode == 2 || mode == 4)? opt.passphrase_repeat : 0, tryagain_text, custdesc, custprompt, canceled); if (*canceled) { xfree (pw); write_status( STATUS_MISSING_PASSPHRASE ); return NULL; } } if ( !pw || !*pw ) write_status( STATUS_MISSING_PASSPHRASE ); /* Hash the passphrase and store it in a newly allocated DEK object. Keep a copy of the passphrase in LAST_PW for use by get_last_passphrase(). */ dek = xmalloc_secure_clear ( sizeof *dek ); dek->algo = cipher_algo; if ( (!pw || !*pw) && (mode == 2 || mode == 4)) dek->keylen = 0; else hash_passphrase (dek, pw, s2k); if (s2k_cacheid) memcpy (dek->s2k_cacheid, s2k_cacheid, sizeof dek->s2k_cacheid); xfree(last_pw); last_pw = pw; return dek; } DEK * passphrase_to_dek (u32 *keyid, int pubkey_algo, int cipher_algo, STRING2KEY *s2k, int mode, const char *tryagain_text, int *canceled) { return passphrase_to_dek_ext (keyid, pubkey_algo, cipher_algo, s2k, mode, tryagain_text, NULL, NULL, canceled); } /* Return an allocated utf-8 string describing the key PK. IF ESCAPED is true spaces and control characters are percent or plus escaped. */ char * gpg_format_keydesc (PKT_public_key *pk, int escaped) { char *uid; size_t uidlen; const char *algo_name; const char *timestr; char *orig_codeset; char *maink; char *desc; algo_name = gcry_pk_algo_name (pk->pubkey_algo); if (!algo_name) algo_name = "?"; timestr = strtimestamp (pk->timestamp); uid = get_user_id (pk->keyid, &uidlen); orig_codeset = i18n_switchto_utf8 (); if (pk->main_keyid[2] && pk->main_keyid[3] && pk->keyid[0] != pk->main_keyid[2] && pk->keyid[1] != pk->main_keyid[3]) maink = xtryasprintf (_(" (main key ID %s)"), keystr (pk->main_keyid)); else maink = NULL; desc = xtryasprintf (_("Please enter the passphrase to unlock the" " secret key for the OpenPGP certificate:\n" "\"%.*s\"\n" "%u-bit %s key, ID %s,\n" "created %s%s.\n"), (int)uidlen, uid, nbits_from_pk (pk), algo_name, keystr (pk->keyid), timestr, maink?maink:"" ); xfree (maink); xfree (uid); i18n_switchback (orig_codeset); if (escaped) { char *tmp = percent_plus_escape (desc); xfree (desc); desc = tmp; } return desc; }