Mercurial > dropbear
view libtomcrypt/demos/tv_gen.c @ 447:278805938dcf
Patch from Nicolai Ehemann to try binding before going to the background,
so that if it exits early (because something's already listening etc)
then it will return an exitcode of 1.
author | Matt Johnston <matt@ucc.asn.au> |
---|---|
date | Thu, 19 Jul 2007 15:54:18 +0000 |
parents | 0cbe8f6dbf9e |
children | f849a5ca2efc |
line wrap: on
line source
#include <tomcrypt.h> void reg_algs(void) { int err; #ifdef RIJNDAEL register_cipher (&aes_desc); #endif #ifdef BLOWFISH register_cipher (&blowfish_desc); #endif #ifdef XTEA register_cipher (&xtea_desc); #endif #ifdef RC5 register_cipher (&rc5_desc); #endif #ifdef RC6 register_cipher (&rc6_desc); #endif #ifdef SAFERP register_cipher (&saferp_desc); #endif #ifdef TWOFISH register_cipher (&twofish_desc); #endif #ifdef SAFER register_cipher (&safer_k64_desc); register_cipher (&safer_sk64_desc); register_cipher (&safer_k128_desc); register_cipher (&safer_sk128_desc); #endif #ifdef RC2 register_cipher (&rc2_desc); #endif #ifdef DES register_cipher (&des_desc); register_cipher (&des3_desc); #endif #ifdef CAST5 register_cipher (&cast5_desc); #endif #ifdef NOEKEON register_cipher (&noekeon_desc); #endif #ifdef SKIPJACK register_cipher (&skipjack_desc); #endif #ifdef ANUBIS register_cipher (&anubis_desc); #endif #ifdef KHAZAD register_cipher (&khazad_desc); #endif #ifdef TIGER register_hash (&tiger_desc); #endif #ifdef MD2 register_hash (&md2_desc); #endif #ifdef MD4 register_hash (&md4_desc); #endif #ifdef MD5 register_hash (&md5_desc); #endif #ifdef SHA1 register_hash (&sha1_desc); #endif #ifdef SHA224 register_hash (&sha224_desc); #endif #ifdef SHA256 register_hash (&sha256_desc); #endif #ifdef SHA384 register_hash (&sha384_desc); #endif #ifdef SHA512 register_hash (&sha512_desc); #endif #ifdef RIPEMD128 register_hash (&rmd128_desc); #endif #ifdef RIPEMD160 register_hash (&rmd160_desc); #endif #ifdef WHIRLPOOL register_hash (&whirlpool_desc); #endif #ifdef CHC_HASH register_hash(&chc_desc); if ((err = chc_register(register_cipher(&aes_desc))) != CRYPT_OK) { printf("chc_register error: %s\n", error_to_string(err)); exit(EXIT_FAILURE); } #endif #ifdef USE_LTM ltc_mp = ltm_desc; #elif defined(USE_TFM) ltc_mp = tfm_desc; #elif defined(USE_GMP) ltc_mp = gmp_desc; #else extern ltc_math_descriptor EXT_MATH_LIB; ltc_mp = EXT_MATH_LIB; #endif } void hash_gen(void) { unsigned char md[MAXBLOCKSIZE], *buf; unsigned long outlen, x, y, z; FILE *out; int err; out = fopen("hash_tv.txt", "w"); if (out == NULL) { perror("can't open hash_tv"); } fprintf(out, "Hash Test Vectors:\n\nThese are the hashes of nn bytes '00 01 02 03 .. (nn-1)'\n\n"); for (x = 0; hash_descriptor[x].name != NULL; x++) { buf = XMALLOC(2 * hash_descriptor[x].blocksize + 1); if (buf == NULL) { perror("can't alloc mem"); exit(EXIT_FAILURE); } fprintf(out, "Hash: %s\n", hash_descriptor[x].name); for (y = 0; y <= (hash_descriptor[x].blocksize * 2); y++) { for (z = 0; z < y; z++) { buf[z] = (unsigned char)(z & 255); } outlen = sizeof(md); if ((err = hash_memory(x, buf, y, md, &outlen)) != CRYPT_OK) { printf("hash_memory error: %s\n", error_to_string(err)); exit(EXIT_FAILURE); } fprintf(out, "%3lu: ", y); for (z = 0; z < outlen; z++) { fprintf(out, "%02X", md[z]); } fprintf(out, "\n"); } fprintf(out, "\n"); XFREE(buf); } fclose(out); } void cipher_gen(void) { unsigned char *key, pt[MAXBLOCKSIZE]; unsigned long x, y, z, w; int err, kl, lastkl; FILE *out; symmetric_key skey; out = fopen("cipher_tv.txt", "w"); fprintf(out, "Cipher Test Vectors\n\nThese are test encryptions with key of nn bytes '00 01 02 03 .. (nn-1)' and original PT of the same style.\n" "The output of step N is used as the key and plaintext for step N+1 (key bytes repeated as required to fill the key)\n\n"); for (x = 0; cipher_descriptor[x].name != NULL; x++) { fprintf(out, "Cipher: %s\n", cipher_descriptor[x].name); /* three modes, smallest, medium, large keys */ lastkl = 10000; for (y = 0; y < 3; y++) { switch (y) { case 0: kl = cipher_descriptor[x].min_key_length; break; case 1: kl = (cipher_descriptor[x].min_key_length + cipher_descriptor[x].max_key_length)/2; break; case 2: kl = cipher_descriptor[x].max_key_length; break; } if ((err = cipher_descriptor[x].keysize(&kl)) != CRYPT_OK) { printf("keysize error: %s\n", error_to_string(err)); exit(EXIT_FAILURE); } if (kl == lastkl) break; lastkl = kl; fprintf(out, "Key Size: %d bytes\n", kl); key = XMALLOC(kl); if (key == NULL) { perror("can't malloc memory"); exit(EXIT_FAILURE); } for (z = 0; (int)z < kl; z++) { key[z] = (unsigned char)z; } if ((err = cipher_descriptor[x].setup(key, kl, 0, &skey)) != CRYPT_OK) { printf("setup error: %s\n", error_to_string(err)); exit(EXIT_FAILURE); } for (z = 0; (int)z < cipher_descriptor[x].block_length; z++) { pt[z] = (unsigned char)z; } for (w = 0; w < 50; w++) { cipher_descriptor[x].ecb_encrypt(pt, pt, &skey); fprintf(out, "%2lu: ", w); for (z = 0; (int)z < cipher_descriptor[x].block_length; z++) { fprintf(out, "%02X", pt[z]); } fprintf(out, "\n"); /* reschedule a new key */ for (z = 0; z < (unsigned long)kl; z++) { key[z] = pt[z % cipher_descriptor[x].block_length]; } if ((err = cipher_descriptor[x].setup(key, kl, 0, &skey)) != CRYPT_OK) { printf("cipher setup2 error: %s\n", error_to_string(err)); exit(EXIT_FAILURE); } } fprintf(out, "\n"); XFREE(key); } fprintf(out, "\n"); } fclose(out); } void hmac_gen(void) { unsigned char key[MAXBLOCKSIZE], output[MAXBLOCKSIZE], *input; int x, y, z, err; FILE *out; unsigned long len; out = fopen("hmac_tv.txt", "w"); fprintf(out, "HMAC Tests. In these tests messages of N bytes long (00,01,02,...,NN-1) are HMACed. The initial key is\n" "of the same format (the same length as the HASH output size). The HMAC key in step N+1 is the HMAC output of\n" "step N.\n\n"); for (x = 0; hash_descriptor[x].name != NULL; x++) { fprintf(out, "HMAC-%s\n", hash_descriptor[x].name); /* initial key */ for (y = 0; y < (int)hash_descriptor[x].hashsize; y++) { key[y] = (y&255); } input = XMALLOC(hash_descriptor[x].blocksize * 2 + 1); if (input == NULL) { perror("Can't malloc memory"); exit(EXIT_FAILURE); } for (y = 0; y <= (int)(hash_descriptor[x].blocksize * 2); y++) { for (z = 0; z < y; z++) { input[z] = (unsigned char)(z & 255); } len = sizeof(output); if ((err = hmac_memory(x, key, hash_descriptor[x].hashsize, input, y, output, &len)) != CRYPT_OK) { printf("Error hmacing: %s\n", error_to_string(err)); exit(EXIT_FAILURE); } fprintf(out, "%3d: ", y); for (z = 0; z <(int) len; z++) { fprintf(out, "%02X", output[z]); } fprintf(out, "\n"); /* forward the key */ memcpy(key, output, hash_descriptor[x].hashsize); } XFREE(input); fprintf(out, "\n"); } fclose(out); } void omac_gen(void) { unsigned char key[MAXBLOCKSIZE], output[MAXBLOCKSIZE], input[MAXBLOCKSIZE*2+2]; int err, x, y, z, kl; FILE *out; unsigned long len; out = fopen("omac_tv.txt", "w"); fprintf(out, "OMAC Tests. In these tests messages of N bytes long (00,01,02,...,NN-1) are OMAC'ed. The initial key is\n" "of the same format (length specified per cipher). The OMAC key in step N+1 is the OMAC output of\n" "step N (repeated as required to fill the array).\n\n"); for (x = 0; cipher_descriptor[x].name != NULL; x++) { kl = cipher_descriptor[x].block_length; /* skip ciphers which do not have 64 or 128 bit block sizes */ if (kl != 8 && kl != 16) continue; if (cipher_descriptor[x].keysize(&kl) != CRYPT_OK) { kl = cipher_descriptor[x].max_key_length; } fprintf(out, "OMAC-%s (%d byte key)\n", cipher_descriptor[x].name, kl); /* initial key/block */ for (y = 0; y < kl; y++) { key[y] = (y & 255); } for (y = 0; y <= (int)(cipher_descriptor[x].block_length*2); y++) { for (z = 0; z < y; z++) { input[z] = (unsigned char)(z & 255); } len = sizeof(output); if ((err = omac_memory(x, key, kl, input, y, output, &len)) != CRYPT_OK) { printf("Error omacing: %s\n", error_to_string(err)); exit(EXIT_FAILURE); } fprintf(out, "%3d: ", y); for (z = 0; z <(int)len; z++) { fprintf(out, "%02X", output[z]); } fprintf(out, "\n"); /* forward the key */ for (z = 0; z < kl; z++) { key[z] = output[z % len]; } } fprintf(out, "\n"); } fclose(out); } void pmac_gen(void) { unsigned char key[MAXBLOCKSIZE], output[MAXBLOCKSIZE], input[MAXBLOCKSIZE*2+2]; int err, x, y, z, kl; FILE *out; unsigned long len; out = fopen("pmac_tv.txt", "w"); fprintf(out, "PMAC Tests. In these tests messages of N bytes long (00,01,02,...,NN-1) are OMAC'ed. The initial key is\n" "of the same format (length specified per cipher). The OMAC key in step N+1 is the OMAC output of\n" "step N (repeated as required to fill the array).\n\n"); for (x = 0; cipher_descriptor[x].name != NULL; x++) { kl = cipher_descriptor[x].block_length; /* skip ciphers which do not have 64 or 128 bit block sizes */ if (kl != 8 && kl != 16) continue; if (cipher_descriptor[x].keysize(&kl) != CRYPT_OK) { kl = cipher_descriptor[x].max_key_length; } fprintf(out, "PMAC-%s (%d byte key)\n", cipher_descriptor[x].name, kl); /* initial key/block */ for (y = 0; y < kl; y++) { key[y] = (y & 255); } for (y = 0; y <= (int)(cipher_descriptor[x].block_length*2); y++) { for (z = 0; z < y; z++) { input[z] = (unsigned char)(z & 255); } len = sizeof(output); if ((err = pmac_memory(x, key, kl, input, y, output, &len)) != CRYPT_OK) { printf("Error omacing: %s\n", error_to_string(err)); exit(EXIT_FAILURE); } fprintf(out, "%3d: ", y); for (z = 0; z <(int)len; z++) { fprintf(out, "%02X", output[z]); } fprintf(out, "\n"); /* forward the key */ for (z = 0; z < kl; z++) { key[z] = output[z % len]; } } fprintf(out, "\n"); } fclose(out); } void eax_gen(void) { int err, kl, x, y1, z; FILE *out; unsigned char key[MAXBLOCKSIZE], nonce[MAXBLOCKSIZE*2], header[MAXBLOCKSIZE*2], plaintext[MAXBLOCKSIZE*2], tag[MAXBLOCKSIZE]; unsigned long len; out = fopen("eax_tv.txt", "w"); fprintf(out, "EAX Test Vectors. Uses the 00010203...NN-1 pattern for header/nonce/plaintext/key. The outputs\n" "are of the form ciphertext,tag for a given NN. The key for step N>1 is the tag of the previous\n" "step repeated sufficiently.\n\n"); for (x = 0; cipher_descriptor[x].name != NULL; x++) { kl = cipher_descriptor[x].block_length; /* skip ciphers which do not have 64 or 128 bit block sizes */ if (kl != 8 && kl != 16) continue; if (cipher_descriptor[x].keysize(&kl) != CRYPT_OK) { kl = cipher_descriptor[x].max_key_length; } fprintf(out, "EAX-%s (%d byte key)\n", cipher_descriptor[x].name, kl); /* the key */ for (z = 0; z < kl; z++) { key[z] = (z & 255); } for (y1 = 0; y1 <= (int)(cipher_descriptor[x].block_length*2); y1++){ for (z = 0; z < y1; z++) { plaintext[z] = (unsigned char)(z & 255); nonce[z] = (unsigned char)(z & 255); header[z] = (unsigned char)(z & 255); } len = sizeof(tag); if ((err = eax_encrypt_authenticate_memory(x, key, kl, nonce, y1, header, y1, plaintext, y1, plaintext, tag, &len)) != CRYPT_OK) { printf("Error EAX'ing: %s\n", error_to_string(err)); exit(EXIT_FAILURE); } fprintf(out, "%3d: ", y1); for (z = 0; z < y1; z++) { fprintf(out, "%02X", plaintext[z]); } fprintf(out, ", "); for (z = 0; z <(int)len; z++) { fprintf(out, "%02X", tag[z]); } fprintf(out, "\n"); /* forward the key */ for (z = 0; z < kl; z++) { key[z] = tag[z % len]; } } fprintf(out, "\n"); } fclose(out); } void ocb_gen(void) { int err, kl, x, y1, z; FILE *out; unsigned char key[MAXBLOCKSIZE], nonce[MAXBLOCKSIZE*2], plaintext[MAXBLOCKSIZE*2], tag[MAXBLOCKSIZE]; unsigned long len; out = fopen("ocb_tv.txt", "w"); fprintf(out, "OCB Test Vectors. Uses the 00010203...NN-1 pattern for nonce/plaintext/key. The outputs\n" "are of the form ciphertext,tag for a given NN. The key for step N>1 is the tag of the previous\n" "step repeated sufficiently. The nonce is fixed throughout.\n\n"); for (x = 0; cipher_descriptor[x].name != NULL; x++) { kl = cipher_descriptor[x].block_length; /* skip ciphers which do not have 64 or 128 bit block sizes */ if (kl != 8 && kl != 16) continue; if (cipher_descriptor[x].keysize(&kl) != CRYPT_OK) { kl = cipher_descriptor[x].max_key_length; } fprintf(out, "OCB-%s (%d byte key)\n", cipher_descriptor[x].name, kl); /* the key */ for (z = 0; z < kl; z++) { key[z] = (z & 255); } /* fixed nonce */ for (z = 0; z < cipher_descriptor[x].block_length; z++) { nonce[z] = z; } for (y1 = 0; y1 <= (int)(cipher_descriptor[x].block_length*2); y1++){ for (z = 0; z < y1; z++) { plaintext[z] = (unsigned char)(z & 255); } len = sizeof(tag); if ((err = ocb_encrypt_authenticate_memory(x, key, kl, nonce, plaintext, y1, plaintext, tag, &len)) != CRYPT_OK) { printf("Error OCB'ing: %s\n", error_to_string(err)); exit(EXIT_FAILURE); } fprintf(out, "%3d: ", y1); for (z = 0; z < y1; z++) { fprintf(out, "%02X", plaintext[z]); } fprintf(out, ", "); for (z = 0; z <(int)len; z++) { fprintf(out, "%02X", tag[z]); } fprintf(out, "\n"); /* forward the key */ for (z = 0; z < kl; z++) { key[z] = tag[z % len]; } } fprintf(out, "\n"); } fclose(out); } void ccm_gen(void) { int err, kl, x, y1, z; FILE *out; unsigned char key[MAXBLOCKSIZE], nonce[MAXBLOCKSIZE*2], plaintext[MAXBLOCKSIZE*2], tag[MAXBLOCKSIZE]; unsigned long len; out = fopen("ccm_tv.txt", "w"); fprintf(out, "CCM Test Vectors. Uses the 00010203...NN-1 pattern for nonce/header/plaintext/key. The outputs\n" "are of the form ciphertext,tag for a given NN. The key for step N>1 is the tag of the previous\n" "step repeated sufficiently. The nonce is fixed throughout at 13 bytes 000102...\n\n"); for (x = 0; cipher_descriptor[x].name != NULL; x++) { kl = cipher_descriptor[x].block_length; /* skip ciphers which do not have 128 bit block sizes */ if (kl != 16) continue; if (cipher_descriptor[x].keysize(&kl) != CRYPT_OK) { kl = cipher_descriptor[x].max_key_length; } fprintf(out, "CCM-%s (%d byte key)\n", cipher_descriptor[x].name, kl); /* the key */ for (z = 0; z < kl; z++) { key[z] = (z & 255); } /* fixed nonce */ for (z = 0; z < cipher_descriptor[x].block_length; z++) { nonce[z] = z; } for (y1 = 0; y1 <= (int)(cipher_descriptor[x].block_length*2); y1++){ for (z = 0; z < y1; z++) { plaintext[z] = (unsigned char)(z & 255); } len = sizeof(tag); if ((err = ccm_memory(x, key, kl, NULL, nonce, 13, plaintext, y1, plaintext, y1, plaintext, tag, &len, CCM_ENCRYPT)) != CRYPT_OK) { printf("Error CCM'ing: %s\n", error_to_string(err)); exit(EXIT_FAILURE); } fprintf(out, "%3d: ", y1); for (z = 0; z < y1; z++) { fprintf(out, "%02X", plaintext[z]); } fprintf(out, ", "); for (z = 0; z <(int)len; z++) { fprintf(out, "%02X", tag[z]); } fprintf(out, "\n"); /* forward the key */ for (z = 0; z < kl; z++) { key[z] = tag[z % len]; } } fprintf(out, "\n"); } fclose(out); } void gcm_gen(void) { int err, kl, x, y1, z; FILE *out; unsigned char key[MAXBLOCKSIZE], plaintext[MAXBLOCKSIZE*2], tag[MAXBLOCKSIZE]; unsigned long len; out = fopen("gcm_tv.txt", "w"); fprintf(out, "GCM Test Vectors. Uses the 00010203...NN-1 pattern for nonce/header/plaintext/key. The outputs\n" "are of the form ciphertext,tag for a given NN. The key for step N>1 is the tag of the previous\n" "step repeated sufficiently. The nonce is fixed throughout at 13 bytes 000102...\n\n"); for (x = 0; cipher_descriptor[x].name != NULL; x++) { kl = cipher_descriptor[x].block_length; /* skip ciphers which do not have 128 bit block sizes */ if (kl != 16) continue; if (cipher_descriptor[x].keysize(&kl) != CRYPT_OK) { kl = cipher_descriptor[x].max_key_length; } fprintf(out, "GCM-%s (%d byte key)\n", cipher_descriptor[x].name, kl); /* the key */ for (z = 0; z < kl; z++) { key[z] = (z & 255); } for (y1 = 0; y1 <= (int)(cipher_descriptor[x].block_length*2); y1++){ for (z = 0; z < y1; z++) { plaintext[z] = (unsigned char)(z & 255); } len = sizeof(tag); if ((err = gcm_memory(x, key, kl, plaintext, y1, plaintext, y1, plaintext, y1, plaintext, tag, &len, GCM_ENCRYPT)) != CRYPT_OK) { printf("Error GCM'ing: %s\n", error_to_string(err)); exit(EXIT_FAILURE); } fprintf(out, "%3d: ", y1); for (z = 0; z < y1; z++) { fprintf(out, "%02X", plaintext[z]); } fprintf(out, ", "); for (z = 0; z <(int)len; z++) { fprintf(out, "%02X", tag[z]); } fprintf(out, "\n"); /* forward the key */ for (z = 0; z < kl; z++) { key[z] = tag[z % len]; } } fprintf(out, "\n"); } fclose(out); } void base64_gen(void) { FILE *out; unsigned char dst[256], src[32]; unsigned long x, y, len; out = fopen("base64_tv.txt", "w"); fprintf(out, "Base64 vectors. These are the base64 encodings of the strings 00,01,02...NN-1\n\n"); for (x = 0; x <= 32; x++) { for (y = 0; y < x; y++) { src[y] = y; } len = sizeof(dst); base64_encode(src, x, dst, &len); fprintf(out, "%2lu: %s\n", x, dst); } fclose(out); } void math_gen(void) { } void ecc_gen(void) { FILE *out; unsigned char str[512]; void *k, *order, *modulus; ecc_point *G, *R; int x; out = fopen("ecc_tv.txt", "w"); fprintf(out, "ecc vectors. These are for kG for k=1,3,9,27,...,3**n until k > order of the curve outputs are <k,x,y> triplets\n\n"); G = ltc_ecc_new_point(); R = ltc_ecc_new_point(); mp_init(&k); mp_init(&order); mp_init(&modulus); for (x = 0; ltc_ecc_sets[x].size != 0; x++) { fprintf(out, "ECC-%d\n", ltc_ecc_sets[x].size*8); mp_set(k, 1); mp_read_radix(order, (char *)ltc_ecc_sets[x].order, 16); mp_read_radix(modulus, (char *)ltc_ecc_sets[x].prime, 16); mp_read_radix(G->x, (char *)ltc_ecc_sets[x].Gx, 16); mp_read_radix(G->y, (char *)ltc_ecc_sets[x].Gy, 16); mp_set(G->z, 1); while (mp_cmp(k, order) == LTC_MP_LT) { ltc_mp.ecc_ptmul(k, G, R, modulus, 1); mp_tohex(k, (char*)str); fprintf(out, "%s, ", (char*)str); mp_tohex(R->x, (char*)str); fprintf(out, "%s, ", (char*)str); mp_tohex(R->y, (char*)str); fprintf(out, "%s\n", (char*)str); mp_mul_d(k, 3, k); } } mp_clear_multi(k, order, modulus, NULL); ltc_ecc_del_point(G); ltc_ecc_del_point(R); fclose(out); } void lrw_gen(void) { FILE *out; unsigned char tweak[16], key[16], iv[16], buf[1024]; int x, y, err; symmetric_LRW lrw; /* initialize default key and tweak */ for (x = 0; x < 16; x++) { tweak[x] = key[x] = iv[x] = x; } out = fopen("lrw_tv.txt", "w"); for (x = 16; x < (int)(sizeof(buf)); x += 16) { if ((err = lrw_start(find_cipher("aes"), iv, key, 16, tweak, 0, &lrw)) != CRYPT_OK) { fprintf(stderr, "Error starting LRW-AES: %s\n", error_to_string(err)); exit(EXIT_FAILURE); } /* encrypt incremental */ for (y = 0; y < x; y++) { buf[y] = y & 255; } if ((err = lrw_encrypt(buf, buf, x, &lrw)) != CRYPT_OK) { fprintf(stderr, "Error encrypting with LRW-AES: %s\n", error_to_string(err)); exit(EXIT_FAILURE); } /* display it */ fprintf(out, "%d:", x); for (y = 0; y < x; y++) { fprintf(out, "%02x", buf[y]); } fprintf(out, "\n"); /* reset IV */ if ((err = lrw_setiv(iv, 16, &lrw)) != CRYPT_OK) { fprintf(stderr, "Error setting IV: %s\n", error_to_string(err)); exit(EXIT_FAILURE); } /* copy new tweak, iv and key */ for (y = 0; y < 16; y++) { key[y] = buf[y]; iv[y] = buf[(y+16)%x]; tweak[y] = buf[(y+32)%x]; } if ((err = lrw_decrypt(buf, buf, x, &lrw)) != CRYPT_OK) { fprintf(stderr, "Error decrypting with LRW-AES: %s\n", error_to_string(err)); exit(EXIT_FAILURE); } /* display it */ fprintf(out, "%d:", x); for (y = 0; y < x; y++) { fprintf(out, "%02x", buf[y]); } fprintf(out, "\n"); lrw_done(&lrw); } fclose(out); } int main(void) { reg_algs(); printf("Generating hash vectors..."); fflush(stdout); hash_gen(); printf("done\n"); printf("Generating cipher vectors..."); fflush(stdout); cipher_gen(); printf("done\n"); printf("Generating HMAC vectors..."); fflush(stdout); hmac_gen(); printf("done\n"); printf("Generating OMAC vectors..."); fflush(stdout); omac_gen(); printf("done\n"); printf("Generating PMAC vectors..."); fflush(stdout); pmac_gen(); printf("done\n"); printf("Generating EAX vectors..."); fflush(stdout); eax_gen(); printf("done\n"); printf("Generating OCB vectors..."); fflush(stdout); ocb_gen(); printf("done\n"); printf("Generating CCM vectors..."); fflush(stdout); ccm_gen(); printf("done\n"); printf("Generating GCM vectors..."); fflush(stdout); gcm_gen(); printf("done\n"); printf("Generating BASE64 vectors..."); fflush(stdout); base64_gen(); printf("done\n"); printf("Generating MATH vectors..."); fflush(stdout); math_gen(); printf("done\n"); printf("Generating ECC vectors..."); fflush(stdout); ecc_gen(); printf("done\n"); printf("Generating LRW vectors..."); fflush(stdout); lrw_gen(); printf("done\n"); return 0; } /* $Source: /cvs/libtom/libtomcrypt/demos/tv_gen.c,v $ */ /* $Revision: 1.15 $ */ /* $Date: 2006/06/09 22:10:27 $ */