/* * Copyright 2000-2017 The OpenSSL Project Authors. All Rights Reserved. * * Licensed under the OpenSSL license (the "License"). You may not use * this file except in compliance with the License. You can obtain a copy * in the file LICENSE in the source distribution or at * https://www.openssl.org/source/license.html */ #include #include "apps.h" #include #include #include #include #ifndef OPENSSL_NO_DES # include #endif #include #include static unsigned const char cov_2char[64] = { /* from crypto/des/fcrypt.c */ 0x2E, 0x2F, 0x30, 0x31, 0x32, 0x33, 0x34, 0x35, 0x36, 0x37, 0x38, 0x39, 0x41, 0x42, 0x43, 0x44, 0x45, 0x46, 0x47, 0x48, 0x49, 0x4A, 0x4B, 0x4C, 0x4D, 0x4E, 0x4F, 0x50, 0x51, 0x52, 0x53, 0x54, 0x55, 0x56, 0x57, 0x58, 0x59, 0x5A, 0x61, 0x62, 0x63, 0x64, 0x65, 0x66, 0x67, 0x68, 0x69, 0x6A, 0x6B, 0x6C, 0x6D, 0x6E, 0x6F, 0x70, 0x71, 0x72, 0x73, 0x74, 0x75, 0x76, 0x77, 0x78, 0x79, 0x7A }; static const char ascii_dollar[] = { 0x24, 0x00 }; typedef enum { passwd_unset = 0, passwd_crypt, passwd_md5, passwd_apr1, passwd_sha256, passwd_sha512, passwd_aixmd5 } passwd_modes; static int do_passwd(int passed_salt, char **salt_p, char **salt_malloc_p, char *passwd, BIO *out, int quiet, int table, int reverse, size_t pw_maxlen, passwd_modes mode); typedef enum OPTION_choice { OPT_ERR = -1, OPT_EOF = 0, OPT_HELP, OPT_IN, OPT_NOVERIFY, OPT_QUIET, OPT_TABLE, OPT_REVERSE, OPT_APR1, OPT_1, OPT_5, OPT_6, OPT_CRYPT, OPT_AIXMD5, OPT_SALT, OPT_STDIN, OPT_R_ENUM } OPTION_CHOICE; const OPTIONS passwd_options[] = { {"help", OPT_HELP, '-', "Display this summary"}, {"in", OPT_IN, '<', "Read passwords from file"}, {"noverify", OPT_NOVERIFY, '-', "Never verify when reading password from terminal"}, {"quiet", OPT_QUIET, '-', "No warnings"}, {"table", OPT_TABLE, '-', "Format output as table"}, {"reverse", OPT_REVERSE, '-', "Switch table columns"}, {"salt", OPT_SALT, 's', "Use provided salt"}, {"stdin", OPT_STDIN, '-', "Read passwords from stdin"}, {"6", OPT_6, '-', "SHA512-based password algorithm"}, {"5", OPT_5, '-', "SHA256-based password algorithm"}, {"apr1", OPT_APR1, '-', "MD5-based password algorithm, Apache variant"}, {"1", OPT_1, '-', "MD5-based password algorithm"}, {"aixmd5", OPT_AIXMD5, '-', "AIX MD5-based password algorithm"}, #ifndef OPENSSL_NO_DES {"crypt", OPT_CRYPT, '-', "Standard Unix password algorithm (default)"}, #endif OPT_R_OPTIONS, {NULL} }; int passwd_main(int argc, char **argv) { BIO *in = NULL; char *infile = NULL, *salt = NULL, *passwd = NULL, **passwds = NULL; char *salt_malloc = NULL, *passwd_malloc = NULL, *prog; OPTION_CHOICE o; int in_stdin = 0, pw_source_defined = 0; #ifndef OPENSSL_NO_UI_CONSOLE int in_noverify = 0; #endif int passed_salt = 0, quiet = 0, table = 0, reverse = 0; int ret = 1; passwd_modes mode = passwd_unset; size_t passwd_malloc_size = 0; size_t pw_maxlen = 256; /* arbitrary limit, should be enough for most * passwords */ prog = opt_init(argc, argv, passwd_options); while ((o = opt_next()) != OPT_EOF) { switch (o) { case OPT_EOF: case OPT_ERR: opthelp: BIO_printf(bio_err, "%s: Use -help for summary.\n", prog); goto end; case OPT_HELP: opt_help(passwd_options); ret = 0; goto end; case OPT_IN: if (pw_source_defined) goto opthelp; infile = opt_arg(); pw_source_defined = 1; break; case OPT_NOVERIFY: #ifndef OPENSSL_NO_UI_CONSOLE in_noverify = 1; #endif break; case OPT_QUIET: quiet = 1; break; case OPT_TABLE: table = 1; break; case OPT_REVERSE: reverse = 1; break; case OPT_1: if (mode != passwd_unset) goto opthelp; mode = passwd_md5; break; case OPT_5: if (mode != passwd_unset) goto opthelp; mode = passwd_sha256; break; case OPT_6: if (mode != passwd_unset) goto opthelp; mode = passwd_sha512; break; case OPT_APR1: if (mode != passwd_unset) goto opthelp; mode = passwd_apr1; break; case OPT_AIXMD5: if (mode != passwd_unset) goto opthelp; mode = passwd_aixmd5; break; case OPT_CRYPT: #ifndef OPENSSL_NO_DES if (mode != passwd_unset) goto opthelp; mode = passwd_crypt; #endif break; case OPT_SALT: passed_salt = 1; salt = opt_arg(); break; case OPT_STDIN: if (pw_source_defined) goto opthelp; in_stdin = 1; pw_source_defined = 1; break; case OPT_R_CASES: if (!opt_rand(o)) goto end; break; } } argc = opt_num_rest(); argv = opt_rest(); if (*argv != NULL) { if (pw_source_defined) goto opthelp; pw_source_defined = 1; passwds = argv; } if (mode == passwd_unset) { /* use default */ mode = passwd_crypt; } #ifdef OPENSSL_NO_DES if (mode == passwd_crypt) goto opthelp; #endif if (infile != NULL && in_stdin) { BIO_printf(bio_err, "%s: Can't combine -in and -stdin\n", prog); goto end; } if (infile != NULL || in_stdin) { /* * If in_stdin is true, we know that infile is NULL, and that * bio_open_default() will give us back an alias for stdin. */ in = bio_open_default(infile, 'r', FORMAT_TEXT); if (in == NULL) goto end; } if (mode == passwd_crypt) pw_maxlen = 8; if (passwds == NULL) { /* no passwords on the command line */ passwd_malloc_size = pw_maxlen + 2; /* longer than necessary so that we can warn about truncation */ passwd = passwd_malloc = app_malloc(passwd_malloc_size, "password buffer"); } if ((in == NULL) && (passwds == NULL)) { /* * we use the following method to make sure what * in the 'else' section is always compiled, to * avoid rot of not-frequently-used code. */ if (1) { #ifndef OPENSSL_NO_UI_CONSOLE /* build a null-terminated list */ static char *passwds_static[2] = { NULL, NULL }; passwds = passwds_static; if (in == NULL) { if (EVP_read_pw_string (passwd_malloc, passwd_malloc_size, "Password: ", !(passed_salt || in_noverify)) != 0) goto end; } passwds[0] = passwd_malloc; } else { #endif BIO_printf(bio_err, "password required\n"); goto end; } } if (in == NULL) { assert(passwds != NULL); assert(*passwds != NULL); do { /* loop over list of passwords */ passwd = *passwds++; if (!do_passwd(passed_salt, &salt, &salt_malloc, passwd, bio_out, quiet, table, reverse, pw_maxlen, mode)) goto end; } while (*passwds != NULL); } else { /* in != NULL */ int done; assert(passwd != NULL); do { int r = BIO_gets(in, passwd, pw_maxlen + 1); if (r > 0) { char *c = (strchr(passwd, '\n')); if (c != NULL) { *c = 0; /* truncate at newline */ } else { /* ignore rest of line */ char trash[BUFSIZ]; do r = BIO_gets(in, trash, sizeof trash); while ((r > 0) && (!strchr(trash, '\n'))); } if (!do_passwd (passed_salt, &salt, &salt_malloc, passwd, bio_out, quiet, table, reverse, pw_maxlen, mode)) goto end; } done = (r <= 0); } while (!done); } ret = 0; end: #if 0 ERR_print_errors(bio_err); #endif OPENSSL_free(salt_malloc); OPENSSL_free(passwd_malloc); BIO_free(in); return ret; } /* * MD5-based password algorithm (should probably be available as a library * function; then the static buffer would not be acceptable). For magic * string "1", this should be compatible to the MD5-based BSD password * algorithm. For 'magic' string "apr1", this is compatible to the MD5-based * Apache password algorithm. (Apparently, the Apache password algorithm is * identical except that the 'magic' string was changed -- the laziest * application of the NIH principle I've ever encountered.) */ static char *md5crypt(const char *passwd, const char *magic, const char *salt) { /* "$apr1$..salt..$.......md5hash..........\0" */ static char out_buf[6 + 9 + 24 + 2]; unsigned char buf[MD5_DIGEST_LENGTH]; char ascii_magic[5]; /* "apr1" plus '\0' */ char ascii_salt[9]; /* Max 8 chars plus '\0' */ char *ascii_passwd = NULL; char *salt_out; int n; unsigned int i; EVP_MD_CTX *md = NULL, *md2 = NULL; size_t passwd_len, salt_len, magic_len; passwd_len = strlen(passwd); out_buf[0] = 0; magic_len = strlen(magic); OPENSSL_strlcpy(ascii_magic, magic, sizeof ascii_magic); #ifdef CHARSET_EBCDIC if ((magic[0] & 0x80) != 0) /* High bit is 1 in EBCDIC alnums */ ebcdic2ascii(ascii_magic, ascii_magic, magic_len); #endif /* The salt gets truncated to 8 chars */ OPENSSL_strlcpy(ascii_salt, salt, sizeof ascii_salt); salt_len = strlen(ascii_salt); #ifdef CHARSET_EBCDIC ebcdic2ascii(ascii_salt, ascii_salt, salt_len); #endif #ifdef CHARSET_EBCDIC ascii_passwd = OPENSSL_strdup(passwd); if (ascii_passwd == NULL) return NULL; ebcdic2ascii(ascii_passwd, ascii_passwd, passwd_len); passwd = ascii_passwd; #endif if (magic_len > 0) { OPENSSL_strlcat(out_buf, ascii_dollar, sizeof out_buf); if (magic_len > 4) /* assert it's "1" or "apr1" */ goto err; OPENSSL_strlcat(out_buf, ascii_magic, sizeof out_buf); OPENSSL_strlcat(out_buf, ascii_dollar, sizeof out_buf); } OPENSSL_strlcat(out_buf, ascii_salt, sizeof out_buf); if (strlen(out_buf) > 6 + 8) /* assert "$apr1$..salt.." */ goto err; salt_out = out_buf; if (magic_len > 0) salt_out += 2 + magic_len; if (salt_len > 8) goto err; md = EVP_MD_CTX_new(); if (md == NULL || !EVP_DigestInit_ex(md, EVP_md5(), NULL) || !EVP_DigestUpdate(md, passwd, passwd_len)) goto err; if (magic_len > 0) if (!EVP_DigestUpdate(md, ascii_dollar, 1) || !EVP_DigestUpdate(md, ascii_magic, magic_len) || !EVP_DigestUpdate(md, ascii_dollar, 1)) goto err; if (!EVP_DigestUpdate(md, ascii_salt, salt_len)) goto err; md2 = EVP_MD_CTX_new(); if (md2 == NULL || !EVP_DigestInit_ex(md2, EVP_md5(), NULL) || !EVP_DigestUpdate(md2, passwd, passwd_len) || !EVP_DigestUpdate(md2, ascii_salt, salt_len) || !EVP_DigestUpdate(md2, passwd, passwd_len) || !EVP_DigestFinal_ex(md2, buf, NULL)) goto err; for (i = passwd_len; i > sizeof buf; i -= sizeof buf) { if (!EVP_DigestUpdate(md, buf, sizeof buf)) goto err; } if (!EVP_DigestUpdate(md, buf, i)) goto err; n = passwd_len; while (n) { if (!EVP_DigestUpdate(md, (n & 1) ? "\0" : passwd, 1)) goto err; n >>= 1; } if (!EVP_DigestFinal_ex(md, buf, NULL)) return NULL; for (i = 0; i < 1000; i++) { if (!EVP_DigestInit_ex(md2, EVP_md5(), NULL)) goto err; if (!EVP_DigestUpdate(md2, (i & 1) ? (unsigned const char *)passwd : buf, (i & 1) ? passwd_len : sizeof buf)) goto err; if (i % 3) { if (!EVP_DigestUpdate(md2, ascii_salt, salt_len)) goto err; } if (i % 7) { if (!EVP_DigestUpdate(md2, passwd, passwd_len)) goto err; } if (!EVP_DigestUpdate(md2, (i & 1) ? buf : (unsigned const char *)passwd, (i & 1) ? sizeof buf : passwd_len)) goto err; if (!EVP_DigestFinal_ex(md2, buf, NULL)) goto err; } EVP_MD_CTX_free(md2); EVP_MD_CTX_free(md); md2 = NULL; md = NULL; { /* transform buf into output string */ unsigned char buf_perm[sizeof buf]; int dest, source; char *output; /* silly output permutation */ for (dest = 0, source = 0; dest < 14; dest++, source = (source + 6) % 17) buf_perm[dest] = buf[source]; buf_perm[14] = buf[5]; buf_perm[15] = buf[11]; # ifndef PEDANTIC /* Unfortunately, this generates a "no * effect" warning */ assert(16 == sizeof buf_perm); # endif output = salt_out + salt_len; assert(output == out_buf + strlen(out_buf)); *output++ = ascii_dollar[0]; for (i = 0; i < 15; i += 3) { *output++ = cov_2char[buf_perm[i + 2] & 0x3f]; *output++ = cov_2char[((buf_perm[i + 1] & 0xf) << 2) | (buf_perm[i + 2] >> 6)]; *output++ = cov_2char[((buf_perm[i] & 3) << 4) | (buf_perm[i + 1] >> 4)]; *output++ = cov_2char[buf_perm[i] >> 2]; } assert(i == 15); *output++ = cov_2char[buf_perm[i] & 0x3f]; *output++ = cov_2char[buf_perm[i] >> 6]; *output = 0; assert(strlen(out_buf) < sizeof(out_buf)); #ifdef CHARSET_EBCDIC ascii2ebcdic(out_buf, out_buf, strlen(out_buf)); #endif } return out_buf; err: OPENSSL_free(ascii_passwd); EVP_MD_CTX_free(md2); EVP_MD_CTX_free(md); return NULL; } /* * SHA based password algorithm, describe by Ulrich Drepper here: * https://www.akkadia.org/drepper/SHA-crypt.txt * (note that it's in the public domain) */ static char *shacrypt(const char *passwd, const char *magic, const char *salt) { /* Prefix for optional rounds specification. */ static const char rounds_prefix[] = "rounds="; /* Maximum salt string length. */ # define SALT_LEN_MAX 16 /* Default number of rounds if not explicitly specified. */ # define ROUNDS_DEFAULT 5000 /* Minimum number of rounds. */ # define ROUNDS_MIN 1000 /* Maximum number of rounds. */ # define ROUNDS_MAX 999999999 /* "$6$rounds=$......salt......$...shahash(up to 86 chars)...\0" */ static char out_buf[3 + 17 + 17 + 86 + 1]; unsigned char buf[SHA512_DIGEST_LENGTH]; unsigned char temp_buf[SHA512_DIGEST_LENGTH]; size_t buf_size = 0; char ascii_magic[2]; char ascii_salt[17]; /* Max 16 chars plus '\0' */ char *ascii_passwd = NULL; size_t n; EVP_MD_CTX *md = NULL, *md2 = NULL; const EVP_MD *sha = NULL; size_t passwd_len, salt_len, magic_len; unsigned int rounds = 5000; /* Default */ char rounds_custom = 0; char *p_bytes = NULL; char *s_bytes = NULL; char *cp = NULL; passwd_len = strlen(passwd); magic_len = strlen(magic); /* assert it's "5" or "6" */ if (magic_len != 1) return NULL; switch (magic[0]) { case '5': sha = EVP_sha256(); buf_size = 32; break; case '6': sha = EVP_sha512(); buf_size = 64; break; default: return NULL; } if (strncmp(salt, rounds_prefix, sizeof(rounds_prefix) - 1) == 0) { const char *num = salt + sizeof(rounds_prefix) - 1; char *endp; unsigned long int srounds = strtoul (num, &endp, 10); if (*endp == '$') { salt = endp + 1; if (srounds > ROUNDS_MAX) rounds = ROUNDS_MAX; else if (srounds < ROUNDS_MIN) rounds = ROUNDS_MIN; else rounds = (unsigned int)srounds; rounds_custom = 1; } else { return NULL; } } OPENSSL_strlcpy(ascii_magic, magic, sizeof ascii_magic); #ifdef CHARSET_EBCDIC if ((magic[0] & 0x80) != 0) /* High bit is 1 in EBCDIC alnums */ ebcdic2ascii(ascii_magic, ascii_magic, magic_len); #endif /* The salt gets truncated to 16 chars */ OPENSSL_strlcpy(ascii_salt, salt, sizeof ascii_salt); salt_len = strlen(ascii_salt); #ifdef CHARSET_EBCDIC ebcdic2ascii(ascii_salt, ascii_salt, salt_len); #endif #ifdef CHARSET_EBCDIC ascii_passwd = OPENSSL_strdup(passwd); if (ascii_passwd == NULL) return NULL; ebcdic2ascii(ascii_passwd, ascii_passwd, passwd_len); passwd = ascii_passwd; #endif out_buf[0] = 0; OPENSSL_strlcat(out_buf, ascii_dollar, sizeof out_buf); OPENSSL_strlcat(out_buf, ascii_magic, sizeof out_buf); OPENSSL_strlcat(out_buf, ascii_dollar, sizeof out_buf); if (rounds_custom) { char tmp_buf[80]; /* "rounds=999999999" */ sprintf(tmp_buf, "rounds=%u", rounds); #ifdef CHARSET_EBCDIC /* In case we're really on a ASCII based platform and just pretend */ if (tmp_buf[0] != 0x72) /* ASCII 'r' */ ebcdic2ascii(tmp_buf, tmp_buf, strlen(tmp_buf)); #endif OPENSSL_strlcat(out_buf, tmp_buf, sizeof out_buf); OPENSSL_strlcat(out_buf, ascii_dollar, sizeof out_buf); } OPENSSL_strlcat(out_buf, ascii_salt, sizeof out_buf); /* assert "$5$rounds=999999999$......salt......" */ if (strlen(out_buf) > 3 + 17 * rounds_custom + salt_len ) goto err; md = EVP_MD_CTX_new(); if (md == NULL || !EVP_DigestInit_ex(md, sha, NULL) || !EVP_DigestUpdate(md, passwd, passwd_len) || !EVP_DigestUpdate(md, ascii_salt, salt_len)) goto err; md2 = EVP_MD_CTX_new(); if (md2 == NULL || !EVP_DigestInit_ex(md2, sha, NULL) || !EVP_DigestUpdate(md2, passwd, passwd_len) || !EVP_DigestUpdate(md2, ascii_salt, salt_len) || !EVP_DigestUpdate(md2, passwd, passwd_len) || !EVP_DigestFinal_ex(md2, buf, NULL)) goto err; for (n = passwd_len; n > buf_size; n -= buf_size) { if (!EVP_DigestUpdate(md, buf, buf_size)) goto err; } if (!EVP_DigestUpdate(md, buf, n)) goto err; n = passwd_len; while (n) { if (!EVP_DigestUpdate(md, (n & 1) ? buf : (unsigned const char *)passwd, (n & 1) ? buf_size : passwd_len)) goto err; n >>= 1; } if (!EVP_DigestFinal_ex(md, buf, NULL)) return NULL; /* P sequence */ if (!EVP_DigestInit_ex(md2, sha, NULL)) goto err; for (n = passwd_len; n > 0; n--) if (!EVP_DigestUpdate(md2, passwd, passwd_len)) goto err; if (!EVP_DigestFinal_ex(md2, temp_buf, NULL)) return NULL; if ((p_bytes = OPENSSL_zalloc(passwd_len)) == NULL) goto err; for (cp = p_bytes, n = passwd_len; n > buf_size; n -= buf_size, cp += buf_size) memcpy(cp, temp_buf, buf_size); memcpy(cp, temp_buf, n); /* S sequence */ if (!EVP_DigestInit_ex(md2, sha, NULL)) goto err; for (n = 16 + buf[0]; n > 0; n--) if (!EVP_DigestUpdate(md2, ascii_salt, salt_len)) goto err; if (!EVP_DigestFinal_ex(md2, temp_buf, NULL)) return NULL; if ((s_bytes = OPENSSL_zalloc(salt_len)) == NULL) goto err; for (cp = s_bytes, n = salt_len; n > buf_size; n -= buf_size, cp += buf_size) memcpy(cp, temp_buf, buf_size); memcpy(cp, temp_buf, n); for (n = 0; n < rounds; n++) { if (!EVP_DigestInit_ex(md2, sha, NULL)) goto err; if (!EVP_DigestUpdate(md2, (n & 1) ? (unsigned const char *)p_bytes : buf, (n & 1) ? passwd_len : buf_size)) goto err; if (n % 3) { if (!EVP_DigestUpdate(md2, s_bytes, salt_len)) goto err; } if (n % 7) { if (!EVP_DigestUpdate(md2, p_bytes, passwd_len)) goto err; } if (!EVP_DigestUpdate(md2, (n & 1) ? buf : (unsigned const char *)p_bytes, (n & 1) ? buf_size : passwd_len)) goto err; if (!EVP_DigestFinal_ex(md2, buf, NULL)) goto err; } EVP_MD_CTX_free(md2); EVP_MD_CTX_free(md); md2 = NULL; md = NULL; OPENSSL_free(p_bytes); OPENSSL_free(s_bytes); p_bytes = NULL; s_bytes = NULL; cp = out_buf + strlen(out_buf); *cp++ = ascii_dollar[0]; # define b64_from_24bit(B2, B1, B0, N) \ do { \ unsigned int w = ((B2) << 16) | ((B1) << 8) | (B0); \ int i = (N); \ while (i-- > 0) \ { \ *cp++ = cov_2char[w & 0x3f]; \ w >>= 6; \ } \ } while (0) switch (magic[0]) { case '5': b64_from_24bit (buf[0], buf[10], buf[20], 4); b64_from_24bit (buf[21], buf[1], buf[11], 4); b64_from_24bit (buf[12], buf[22], buf[2], 4); b64_from_24bit (buf[3], buf[13], buf[23], 4); b64_from_24bit (buf[24], buf[4], buf[14], 4); b64_from_24bit (buf[15], buf[25], buf[5], 4); b64_from_24bit (buf[6], buf[16], buf[26], 4); b64_from_24bit (buf[27], buf[7], buf[17], 4); b64_from_24bit (buf[18], buf[28], buf[8], 4); b64_from_24bit (buf[9], buf[19], buf[29], 4); b64_from_24bit (0, buf[31], buf[30], 3); break; case '6': b64_from_24bit (buf[0], buf[21], buf[42], 4); b64_from_24bit (buf[22], buf[43], buf[1], 4); b64_from_24bit (buf[44], buf[2], buf[23], 4); b64_from_24bit (buf[3], buf[24], buf[45], 4); b64_from_24bit (buf[25], buf[46], buf[4], 4); b64_from_24bit (buf[47], buf[5], buf[26], 4); b64_from_24bit (buf[6], buf[27], buf[48], 4); b64_from_24bit (buf[28], buf[49], buf[7], 4); b64_from_24bit (buf[50], buf[8], buf[29], 4); b64_from_24bit (buf[9], buf[30], buf[51], 4); b64_from_24bit (buf[31], buf[52], buf[10], 4); b64_from_24bit (buf[53], buf[11], buf[32], 4); b64_from_24bit (buf[12], buf[33], buf[54], 4); b64_from_24bit (buf[34], buf[55], buf[13], 4); b64_from_24bit (buf[56], buf[14], buf[35], 4); b64_from_24bit (buf[15], buf[36], buf[57], 4); b64_from_24bit (buf[37], buf[58], buf[16], 4); b64_from_24bit (buf[59], buf[17], buf[38], 4); b64_from_24bit (buf[18], buf[39], buf[60], 4); b64_from_24bit (buf[40], buf[61], buf[19], 4); b64_from_24bit (buf[62], buf[20], buf[41], 4); b64_from_24bit (0, 0, buf[63], 2); break; default: goto err; } *cp = '\0'; #ifdef CHARSET_EBCDIC ascii2ebcdic(out_buf, out_buf, strlen(out_buf)); #endif return out_buf; err: EVP_MD_CTX_free(md2); EVP_MD_CTX_free(md); OPENSSL_free(p_bytes); OPENSSL_free(s_bytes); OPENSSL_free(ascii_passwd); return NULL; } static int do_passwd(int passed_salt, char **salt_p, char **salt_malloc_p, char *passwd, BIO *out, int quiet, int table, int reverse, size_t pw_maxlen, passwd_modes mode) { char *hash = NULL; assert(salt_p != NULL); assert(salt_malloc_p != NULL); /* first make sure we have a salt */ if (!passed_salt) { size_t saltlen = 0; size_t i; #ifndef OPENSSL_NO_DES if (mode == passwd_crypt) saltlen = 2; #endif /* !OPENSSL_NO_DES */ if (mode == passwd_md5 || mode == passwd_apr1 || mode == passwd_aixmd5) saltlen = 8; if (mode == passwd_sha256 || mode == passwd_sha512) saltlen = 16; assert(saltlen != 0); if (*salt_malloc_p == NULL) *salt_p = *salt_malloc_p = app_malloc(saltlen + 1, "salt buffer"); if (RAND_bytes((unsigned char *)*salt_p, saltlen) <= 0) goto end; for (i = 0; i < saltlen; i++) (*salt_p)[i] = cov_2char[(*salt_p)[i] & 0x3f]; /* 6 bits */ (*salt_p)[i] = 0; # ifdef CHARSET_EBCDIC /* The password encryption funtion will convert back to ASCII */ ascii2ebcdic(*salt_p, *salt_p, saltlen); # endif } assert(*salt_p != NULL); /* truncate password if necessary */ if ((strlen(passwd) > pw_maxlen)) { if (!quiet) /* * XXX: really we should know how to print a size_t, not cast it */ BIO_printf(bio_err, "Warning: truncating password to %u characters\n", (unsigned)pw_maxlen); passwd[pw_maxlen] = 0; } assert(strlen(passwd) <= pw_maxlen); /* now compute password hash */ #ifndef OPENSSL_NO_DES if (mode == passwd_crypt) hash = DES_crypt(passwd, *salt_p); #endif if (mode == passwd_md5 || mode == passwd_apr1) hash = md5crypt(passwd, (mode == passwd_md5 ? "1" : "apr1"), *salt_p); if (mode == passwd_aixmd5) hash = md5crypt(passwd, "", *salt_p); if (mode == passwd_sha256 || mode == passwd_sha512) hash = shacrypt(passwd, (mode == passwd_sha256 ? "5" : "6"), *salt_p); assert(hash != NULL); if (table && !reverse) BIO_printf(out, "%s\t%s\n", passwd, hash); else if (table && reverse) BIO_printf(out, "%s\t%s\n", hash, passwd); else BIO_printf(out, "%s\n", hash); return 1; end: return 0; }