/* LibTomCrypt, modular cryptographic library -- Tom St Denis * * LibTomCrypt is a library that provides various cryptographic * algorithms in a highly modular and flexible manner. * * The library is free for all purposes without any express * guarantee it works. */ /* * Demo to do the rough equivalent of: * * openssl enc -aes-256-cbc -pass pass:foobar -in infile -out outfile -p * * Compilation: * * $(CC) -I /path/to/headers -L .../libs \ * -o openssl-enc \ * openssl-enc.c -ltomcrypt * * Usage: * * ./openssl-enc infile outfile "passphrase" [salt] * * If provided, the salt must be EXACTLY a 16-char hex string. * * Demo is an example of: * * - (When decrypting) yanking salt out of the OpenSSL "Salted__..." header * - OpenSSL-compatible key derivation (in OpenSSL's modified PKCS#5v1 approach) * - Grabbing an Initialization Vector from the key generator * - Performing simple block encryption using AES * - PKCS#7-type padding (which hopefully can get ripped out of this demo and * made a libtomcrypt thing someday). * * This program is free for all purposes without any express guarantee it * works. If you really want to see a license here, assume the WTFPL :-) * * BJ Black, bblack@barracuda.com, https://wjblack.com * * BUGS: * Passing a password on a command line is a HORRIBLE idea. Don't use * this program for serious work! */ #include #ifndef LTC_RIJNDAEL #error Cannot compile this demo; Rijndael (AES) required #endif #ifndef LTC_CBC_MODE #error Cannot compile this demo; CBC mode required #endif #ifndef LTC_PKCS_5 #error Cannot compile this demo; PKCS5 required #endif #ifndef LTC_RNG_GET_BYTES #error Cannot compile this demo; random generator required #endif #ifndef LTC_MD5 #error Cannot compile this demo; MD5 required #endif /* OpenSSL by default only runs one hash round */ #define OPENSSL_ITERATIONS 1 /* Use aes-256-cbc, so 256 bits of key, 128 of IV */ #define KEY_LENGTH (256>>3) #define IV_LENGTH (128>>3) /* PKCS#5v1 requires exactly an 8-byte salt */ #define SALT_LENGTH 8 /* The header OpenSSL puts on an encrypted file */ static char salt_header[] = { 'S', 'a', 'l', 't', 'e', 'd', '_', '_' }; #include #include #include /* A simple way to handle the possibility that a block may increase in size after padding. */ union paddable { unsigned char unpad[1024]; unsigned char pad[1024+MAXBLOCKSIZE]; }; /* * Print usage and exit with a bad status (and perror() if any errno). * * Input: argv[0] and the error string * Output: * Side Effects: print messages and barf (does exit(3)) */ void barf(char *pname, char *err) { printf("Usage: %s infile outfile passphrase [salt]\n", pname); printf("\n"); printf(" # encrypts infile->outfile, random salt\n"); printf(" %s enc infile outfile \"passphrase\"\n", pname); printf("\n"); printf(" # encrypts infile->outfile, salt from cmdline\n"); printf(" %s enc infile outfile pass 0123456789abcdef\n", pname); printf("\n"); printf(" # decrypts infile->outfile, pulls salt from infile\n"); printf(" %s dec infile outfile pass\n", pname); printf("\n"); printf(" # decrypts infile->outfile, salt specified\n"); printf(" # (don't try to read the salt from infile)\n"); printf(" %s dec infile outfile pass 0123456789abcdef" "\n", pname); printf("\n"); printf("Application Error: %s\n", err); if(errno) perror(" System Error"); exit(-1); } /* * Parse a salt value passed in on the cmdline. * * Input: string passed in and a buf to put it in (exactly 8 bytes!) * Output: CRYPT_OK if parsed OK, CRYPT_ERROR if not * Side Effects: none */ int parse_hex_salt(unsigned char *in, unsigned char *out) { int idx; for(idx=0; idxpad+nb, padval, padval); return nb+padval; } else { /* We are UNPADDING this block (and removing bytes) We really just need to verify that the pad bytes are correct, so start at the end of the string and work backwards. */ /* Figure out what the padlength should be by looking at the last byte */ idx = nb-1; padval = buf->pad[idx]; /* padval must be nonzero and <= block length */ if(padval <= 0 || padval > block_length) return 0; /* First byte's accounted for; do the rest */ idx--; while(idx >= (off_t)(nb-padval)) if(buf->pad[idx] != padval) return 0; else idx--; /* If we got here, the pad checked out, so return a smaller number of bytes than nb (basically where we left off+1) */ return idx+1; } } /* * Perform an encrypt/decrypt operation to/from files using AES+CBC+PKCS7 pad. * Set encrypt to 1 to encrypt, 0 to decrypt. * * Input: in/out files, key, iv, and mode * Output: CRYPT_OK if no error * Side Effects: bytes slurped from infile, pushed to outfile, fds updated. */ int do_crypt(FILE *infd, FILE *outfd, unsigned char *key, unsigned char *iv, int encrypt) { union paddable inbuf, outbuf; int cipher, ret; symmetric_CBC cbc; size_t nb; /* Register your cipher! */ cipher = register_cipher(&aes_desc); if(cipher == -1) return CRYPT_INVALID_CIPHER; /* Start a CBC session with cipher/key/val params */ ret = cbc_start(cipher, iv, key, KEY_LENGTH, 0, &cbc); if( ret != CRYPT_OK ) return -1; do { /* Get bytes from the source */ nb = fread(inbuf.unpad, 1, sizeof(inbuf.unpad), infd); if(!nb) return encrypt ? CRYPT_OK : CRYPT_ERROR; /* Barf if we got a read error */ if(ferror(infd)) return CRYPT_ERROR; if(encrypt) { /* We're encrypting, so pad first (if at EOF) and then crypt */ if(feof(infd)) nb = pkcs7_pad(&inbuf, nb, aes_desc.block_length, 1); ret = cbc_encrypt(inbuf.pad, outbuf.pad, nb, &cbc); if(ret != CRYPT_OK) return ret; } else { /* We're decrypting, so decrypt and then unpad if at EOF */ ret = cbc_decrypt(inbuf.unpad, outbuf.unpad, nb, &cbc); if( ret != CRYPT_OK ) return ret; if( feof(infd) ) nb = pkcs7_pad(&outbuf, nb, aes_desc.block_length, 0); if(nb == 0) /* The file didn't decrypt correctly */ return CRYPT_ERROR; } /* Push bytes to outfile */ if(fwrite(outbuf.unpad, 1, nb, outfd) != nb) return CRYPT_ERROR; } while(!feof(infd)); /* Close up */ cbc_done(&cbc); return CRYPT_OK; } /* Convenience macro for the various barfable places below */ #define BARF(a) { \ if(infd) fclose(infd); \ if(outfd) { fclose(outfd); remove(argv[3]); } \ barf(argv[0], a); \ } /* * The main routine. Mostly validate cmdline params, open files, run the KDF, * and do the crypt. */ int main(int argc, char *argv[]) { unsigned char salt[SALT_LENGTH]; FILE *infd = NULL, *outfd = NULL; int encrypt = -1; int hash = -1; int ret; unsigned char keyiv[KEY_LENGTH + IV_LENGTH]; unsigned long keyivlen = (KEY_LENGTH + IV_LENGTH); unsigned char *key, *iv; /* Check proper number of cmdline args */ if(argc < 5 || argc > 6) BARF("Invalid number of arguments"); /* Check proper mode of operation */ if (!strncmp(argv[1], "enc", 3)) encrypt = 1; else if(!strncmp(argv[1], "dec", 3)) encrypt = 0; else BARF("Bad command name"); /* Check we can open infile/outfile */ infd = fopen(argv[2], "rb"); if(infd == NULL) BARF("Could not open infile"); outfd = fopen(argv[3], "wb"); if(outfd == NULL) BARF("Could not open outfile"); /* Get the salt from wherever */ if(argc == 6) { /* User-provided */ if(parse_hex_salt((unsigned char*) argv[5], salt) != CRYPT_OK) BARF("Bad user-specified salt"); } else if(!strncmp(argv[1], "enc", 3)) { /* Encrypting; get from RNG */ if(rng_get_bytes(salt, sizeof(salt), NULL) != sizeof(salt)) BARF("Not enough random data"); } else { /* Parse from infile (decrypt only) */ if(parse_openssl_header(infd, salt) != CRYPT_OK) BARF("Invalid OpenSSL header in infile"); } /* Fetch the MD5 hasher for PKCS#5 */ hash = register_hash(&md5_desc); if(hash == -1) BARF("Could not register MD5 hash"); /* Set things to a sane initial state */ zeromem(keyiv, sizeof(keyiv)); key = keyiv + 0; /* key comes first */ iv = keyiv + KEY_LENGTH; /* iv comes next */ /* Run the key derivation from the provided passphrase. This gets us the key and iv. */ ret = pkcs_5_alg1_openssl((unsigned char*)argv[4], strlen(argv[4]), salt, OPENSSL_ITERATIONS, hash, keyiv, &keyivlen ); if(ret != CRYPT_OK) BARF("Could not derive key/iv from passphrase"); /* Display the salt/key/iv like OpenSSL cmdline does when -p */ printf("salt="); dump_bytes(salt, sizeof(salt)); printf("\n"); printf("key="); dump_bytes(key, KEY_LENGTH); printf("\n"); printf("iv ="); dump_bytes(iv, IV_LENGTH ); printf("\n"); /* If we're encrypting, write the salt header as OpenSSL does */ if(!strncmp(argv[1], "enc", 3)) { if(fwrite(salt_header, 1, sizeof(salt_header), outfd) != sizeof(salt_header) ) BARF("Error writing salt header to outfile"); if(fwrite(salt, 1, sizeof(salt), outfd) != sizeof(salt)) BARF("Error writing salt to outfile"); } /* At this point, the files are open, the salt has been figured out, and we're ready to pump data through crypt. */ /* Do the crypt operation */ if(do_crypt(infd, outfd, key, iv, encrypt) != CRYPT_OK) BARF("Error during crypt operation"); /* Clean up */ fclose(infd); fclose(outfd); return 0; } /* ref: $Format:%D$ */ /* git commit: $Format:%H$ */ /* commit time: $Format:%ai$ */