int main() { int i, failures = 0; mpnumber m; mpnumber k; mpnumber inv_k; mpnumber inv; mpnzero(&m); mpnzero(&k); mpnzero(&inv_k); mpnzero(&inv); for (i = 0; i < NVECTORS; i++) { mpnsethex(&m, table[i].m); mpnsethex(&k, table[i].k); mpnsethex(&inv_k, table[i].inv_k); if (mpninv(&inv, &k, &m)) { if (mpnex(inv.size, inv.data, inv_k.size, inv_k.data)) { printf("mpninv return unexpected result\n"); failures++; } } else { printf("mpninv failed\n"); failures++; } } mpnfree(&m); mpnfree(&k); mpnfree(&inv_k); mpnfree(&inv); return failures; }
int main( int argc, char **argv ) { FILE *secblock; unsigned char packetType; unsigned short packetLen; unsigned char buffer[4096]; unsigned char hexrep[8192]; // for CRT computation mpbarrett psubone, qsubone; // for testing mpnumber m, cipher, decipher, holder; rsakp keypair; size_t bits = 2048; size_t pbits = (bits+1) >> 1; size_t qbits = (bits - pbits); size_t psize = MP_BITS_TO_WORDS(pbits+MP_WBITS-1); size_t qsize = MP_BITS_TO_WORDS(qbits+MP_WBITS-1); size_t pqsize = psize+qsize; mpw* temp = (mpw*) malloc((16*pqsize+6)*sizeof(mpw)); if( argc < 2 ) { printf( "usage: %s <secblock>\n", argv[0] ); exit( 1 ); } mpbzero(&psubone); mpbzero(&qsubone); secblock = fopen(argv[1], "rb"); if( secblock == NULL ) { printf( "Can't open %s\n", argv[1] ); exit(0); } packetType = fgetc(secblock); packetLen = 0; //big endianness... big16read(&packetLen, secblock); printf( "Packet type: 0x%02X\n", packetType ); printf( "Packet length: %04d\n", (int) packetLen ); // skip ahead six bytes, this includes key generation time and other attributes fread( buffer, 6, 1, secblock); rsakpInit(&keypair); big16read(&packetLen, secblock); printf( "n Packet length: %02d bits, %02d bytes\n", (int) packetLen, (int) bytesFromMpn(packetLen) ); printf( "offset: %x\n", ftell( secblock ) ); fread( buffer, bytesFromMpn(packetLen), 1, secblock ); mpbsetbin(&keypair.n, buffer, bytesFromMpn(packetLen)); mpprintln(packetLen/32, keypair.n.modl); big16read(&packetLen, secblock); printf( "e Packet length: %02d bits, %02d bytes\n", (int) packetLen, (int) bytesFromMpn(packetLen) ); printf( "offset: %x\n", ftell( secblock ) ); fread( buffer, bytesFromMpn(packetLen), 1, secblock ); mpnsetbin(&keypair.e, buffer, bytesFromMpn(packetLen)); mpprintln(keypair.e.size, keypair.e.data); packetType = fgetc(secblock); if( packetType == 0 ) { printf( "secret data is plaintext\n" ); } else { printf( "secret data is encrypted\n" ); } big16read(&packetLen, secblock); printf( "d Packet length: %02d bits, %02d bytes\n", (int) packetLen, (int) bytesFromMpn(packetLen) ); printf( "offset: %x\n", ftell( secblock ) ); fread( buffer, bytesFromMpn(packetLen), 1, secblock ); mpnsetbin(&keypair.d, buffer, bytesFromMpn(packetLen)); mpprintln(keypair.d.size, keypair.d.data); big16read(&packetLen, secblock); printf( "p Packet length: %02d bits, %02d bytes\n", (int) packetLen, (int) bytesFromMpn(packetLen) ); printf( "offset: %x\n", ftell( secblock ) ); fread( buffer, bytesFromMpn(packetLen), 1, secblock ); mpbsetbin(&keypair.p, buffer, bytesFromMpn(packetLen)); mpprintln(packetLen/32, keypair.p.modl); big16read(&packetLen, secblock); printf( "q Packet length: %02d bits, %02d bytes\n", (int) packetLen, (int) bytesFromMpn(packetLen) ); printf( "offset: %x\n", ftell( secblock ) ); fread( buffer, bytesFromMpn(packetLen), 1, secblock ); mpbsetbin(&keypair.q, buffer, bytesFromMpn(packetLen)); mpprintln(packetLen/32, keypair.q.modl); big16read(&packetLen, secblock); printf( "mystery packet length: %02d bits, %02d bytes\n", (int) packetLen, (int) bytesFromMpn(packetLen) ); printf( "offset: %x\n", ftell( secblock ) ); fread( buffer, bytesFromMpn(packetLen), 1, secblock ); mpnzero(&holder); mpnsetbin(&holder, buffer, bytesFromMpn(packetLen)); mpprintln(holder.size, holder.data); fread( buffer, 4, 1, secblock ); // advance by two bytes printf( "offset: %x\n", ftell( secblock ) ); fread( buffer, bytesFromMpn(packetLen), 1, secblock ); printf( "%s\n", buffer ); #ifdef USE_CRT // compute CRT elements /* compute p-1 */ mpbsubone(&keypair.p, temp); mpbset(&psubone, psize, temp); /* compute q-1 */ mpbsubone(&keypair.q, temp); mpbset(&qsubone, qsize, temp); /* compute dp = d mod (p-1) */ mpnsize(&keypair.dp, psize); mpbmod_w(&psubone, keypair.d.data, keypair.dp.data, temp); /* compute dq = d mod (q-1) */ mpnsize(&keypair.dq, qsize); mpbmod_w(&qsubone, keypair.d.data, keypair.dq.data, temp); /* compute qi = inv(q) mod p */ mpninv(&keypair.qi, (mpnumber*) &keypair.q, (mpnumber*) &keypair.p); #endif // now test mpnzero(&m); mpnzero(&cipher); mpnzero(&decipher); mpnsethex(&m, "d436e99569fd32a7c8a05bbc90d32c49"); printf( "Original: " ); mpprintln(m.size, m.data); rsapub(&keypair.n, &keypair.e, &m, &cipher); printf( "Encrypted: " ); mpprintln(cipher.size, cipher.data); #ifdef USE_CRT rsapricrt(&keypair.n, &keypair.p, &keypair.q, &keypair.dp, &keypair.dq, &keypair.qi, &cipher, &decipher); #else rsapri(&keypair.n, &keypair.d, &cipher, &decipher); #endif printf( "Recovered: " ); mpprintln(decipher.size, decipher.data); if (mpnex(m.size, m.data, decipher.size, decipher.data)) printf ( "results don't match\n" ); else printf ( "before and after encyrption sizes match\n" ); printf( "special test routine for STM32 validation\n" ); mpnzero(&cipher); mpnzero(&decipher); mpnsethex(&cipher, "6fa1bf55e15b47f4662f86e8fc7fadf0dc02c603c20c1090096fdbeafbd56897794ee106d0fcd8a58392ee7e14fd4e15b49c4adb02f0eebeb9587e9823e9e11048c1754c5e6ba273a08c35dd68f72bf4758b8c31dee196f683298cdbd259c28976c1459058c37be29b52589f3919dcb41cf57fd0c64796a056702be8c1f7574a005cad8b0aedb8f833d1fcfe5383b6d6695d766cc1a9a3413f7609fa18b0a1214486f8fec17febd3f4cbc177dd6f26568b715249853280c570e2ef8519f51fe78fb1978061a48fcc6730fb24e365120b54e6f4e2c3815997176167456b2a2b8f1a13b66967765fc42d4aeec2b4f8211e54ba9cbbbbfdd8ac7b2f20af8d44cd68" ); printf( "Decrypting: " ); mpprintln(cipher.size, cipher.data); rsapub(&keypair.n, &keypair.e, &cipher, &decipher); printf( "Recovered: " ); mpprintln(decipher.size, decipher.data); free(temp); return 0; }
int main() { int failures = 0; rsakp keypair; mpnumber m, cipher, decipher; randomGeneratorContext rngc; if (randomGeneratorContextInit(&rngc, randomGeneratorDefault()) == 0) { /* First we do the fixed value verification */ rsakpInit(&keypair); mpbsethex(&keypair.n, rsa_n); mpnsethex(&keypair.e, rsa_e); mpbsethex(&keypair.p, rsa_p); mpbsethex(&keypair.q, rsa_q); mpnsethex(&keypair.dp, rsa_d1); mpnsethex(&keypair.dq, rsa_d2); mpnsethex(&keypair.qi, rsa_c); mpnzero(&m); mpnzero(&cipher); mpnzero(&decipher); mpnsethex(&m, rsa_m); /* it's safe to cast the keypair to a public key */ if (rsapub(&keypair.n, &keypair.e, &m, &cipher)) failures++; if (rsapricrt(&keypair.n, &keypair.p, &keypair.q, &keypair.dp, &keypair.dq, &keypair.qi, &cipher, &decipher)) failures++; if (mpnex(m.size, m.data, decipher.size, decipher.data)) failures++; mpnfree(&decipher); mpnfree(&cipher); mpnfree(&m); rsakpFree(&keypair); mpnzero(&m); mpnzero(&cipher); mpnzero(&decipher); /* Now we generate a keypair and do some tests on it */ rsakpMake(&keypair, &rngc, 512); /* generate a random m in the range 0 < m < n */ mpbnrnd(&keypair.n, &rngc, &m); /* it's safe to cast the keypair to a public key */ if (rsapub(&keypair.n, &keypair.e, &m, &cipher)) failures++; if (rsapricrt(&keypair.n, &keypair.p, &keypair.q, &keypair.dp, &keypair.dq, &keypair.qi, &cipher, &decipher)) failures++; if (mpnex(m.size, m.data, decipher.size, decipher.data)) failures++; rsakpFree(&keypair); } return failures; }