void bp_tx_sighash(bu256_t *hash, const cstring *scriptCode,
const struct bp_tx *txTo, unsigned int nIn,
int nHashType)
{
if (nIn >= txTo->vin->len) {
// nIn out of range
bu256_set_u64(hash, 1);
return;
}
// Check for invalid use of SIGHASH_SINGLE
if ((nHashType & 0x1f) == SIGHASH_SINGLE) {
if (nIn >= txTo->vout->len) {
// nOut out of range
bu256_set_u64(hash, 1);
return;
}
}
cstring *s = cstr_new_sz(512);
// Serialize only the necessary parts of the transaction being signed
bp_tx_sigserializer(s, scriptCode, txTo, nIn, nHashType);
ser_s32(s, nHashType);
bu_Hash((unsigned char *) hash, s->str, s->len);
cstr_free(s, true);
}
void bu_Hash4(unsigned char *md32, const void *data, size_t data_len)
{
unsigned char md256[SHA256_DIGEST_LENGTH];
bu_Hash(md256, data, data_len);
memcpy(md32, md256, 4);
}
static void bp_tx_calc_sighash(bu256_t *hash, const struct bp_tx *tx,
int nHashType)
{
/* TODO: introduce hashing-only serialization mode */
GString *s = g_string_sized_new(512);
ser_bp_tx(s, tx);
ser_s32(s, nHashType);
bu_Hash((unsigned char *) hash, s->str, s->len);
g_string_free(s, TRUE);
}
std::vector<unsigned char> decrypt_bip38_ec(const std::vector<unsigned char> key, const std::string& passwd)
{
int i;
uint8_t passfactor[PASSFACTOR_SIZE];
memset(passfactor,0,PASSFACTOR_SIZE);
const unsigned char * s_key = reinterpret_cast<const unsigned char*>(key.data());
crypto_scrypt((const uint8_t *)passwd.c_str(), passwd.length(),
&s_key[3 + ADDRESSHASH_SIZE], OWNERSALT_SIZE,
16384, 8, 8, passfactor, PASSFACTOR_SIZE );
// compute EC point (passpoint) using passfactor
struct bp_key ec_point;
if(!bp_key_init(&ec_point)) {
fprintf(stderr,"%s","cannot init EC point key");
exit(3);
}
if(!bp_key_secret_set(&ec_point,passfactor,PASSFACTOR_SIZE)) {
fprintf(stderr,"%s","cannot set EC point from passfactor");
exit(3);
}
// get the passpoint as bytes
unsigned char * passpoint;
size_t passpoint_len;
if(!bp_pubkey_get(&ec_point,(unsigned char **)&passpoint,&passpoint_len)) {
fprintf(stderr,"%s","cannot get pubkey for EC point");
exit(4);
}
// now we need to decrypt seedb
uint8_t encryptedpart2[16];
memset(encryptedpart2,0,16);
memcpy(encryptedpart2, &s_key[3 + ADDRESSHASH_SIZE + OWNERSALT_SIZE + 8], 16);
uint8_t encryptedpart1[16];
memset(encryptedpart1,0,16);
memcpy(encryptedpart1, &s_key[3 + ADDRESSHASH_SIZE + OWNERSALT_SIZE], 8);
unsigned char derived[DERIVED_SIZE];
// get the encryption key for seedb using scrypt
// with passpoint as the key, salt is addresshash+ownersalt
unsigned char derived_scrypt_salt[ADDRESSHASH_SIZE + OWNERSALT_SIZE];
memcpy(derived_scrypt_salt, &s_key[3], ADDRESSHASH_SIZE); // copy the addresshash
memcpy(derived_scrypt_salt+ADDRESSHASH_SIZE, &s_key[3+ADDRESSHASH_SIZE], OWNERSALT_SIZE); // copy the ownersalt
crypto_scrypt( passpoint, passpoint_len,
derived_scrypt_salt, ADDRESSHASH_SIZE+OWNERSALT_SIZE,
1024, 1, 1, derived, DERIVED_SIZE );
//get decryption key
unsigned char derivedhalf2[DERIVED_SIZE/2];
memcpy(derivedhalf2, derived+(DERIVED_SIZE/2), DERIVED_SIZE/2);
unsigned char iv[32];
memset(iv,0,32);
EVP_CIPHER_CTX d;
EVP_CIPHER_CTX_init(&d);
EVP_DecryptInit_ex(&d, EVP_aes_256_ecb(), NULL, derivedhalf2, iv);
unsigned char unencryptedpart2[32];
int decrypt_len;
EVP_DecryptUpdate(&d, unencryptedpart2, &decrypt_len, encryptedpart2, 16);
EVP_DecryptUpdate(&d, unencryptedpart2, &decrypt_len, encryptedpart2, 16);
for(i=0; i<16; i++) {
unencryptedpart2[i] ^= derived[i + 16];
}
unsigned char unencryptedpart1[32];
memcpy(encryptedpart1+8, unencryptedpart2, 8);
EVP_DecryptUpdate(&d, unencryptedpart1, &decrypt_len, encryptedpart1, 16);
EVP_DecryptUpdate(&d, unencryptedpart1, &decrypt_len, encryptedpart1, 16);
for(i=0; i<16; i++) {
unencryptedpart1[i] ^= derived[i];
}
// recoved seedb
unsigned char seedb[24];
memcpy(seedb, unencryptedpart1, 16);
memcpy(&(seedb[16]), &(unencryptedpart2[8]), 8);
// turn seedb into factorb (factorb = SHA256(SHA256(seedb)))
unsigned char factorb[32];
bu_Hash(factorb, seedb, 24);
// multiply by passfactor (ec_point_pub)
const EC_GROUP * ec_group = EC_KEY_get0_group(ec_point.k);
const EC_POINT * ec_point_pub = EC_KEY_get0_public_key(ec_point.k);
BIGNUM * bn_passfactor = BN_bin2bn(passfactor,32,BN_new());
BIGNUM * bn_factorb = BN_bin2bn(factorb,32,BN_new());
BIGNUM * bn_res = BN_new();
BIGNUM * bn_final = BN_new();
BIGNUM * bn_n = BN_new();
BN_CTX * ctx = BN_CTX_new();
EC_GROUP_get_order(ec_group, bn_n, ctx);
BN_mul(bn_res, bn_passfactor, bn_factorb, ctx);
BN_mod(bn_final, bn_res, bn_n, ctx);
unsigned char finalKey[32];
memset(finalKey, 0, 32);
int n = BN_bn2bin(bn_final, finalKey);
BN_clear_free(bn_passfactor);
BN_clear_free(bn_factorb);
BN_clear_free(bn_res);
BN_clear_free(bn_n);
BN_clear_free(bn_final);
printf("\n");
print_hex((char *)finalKey, 32);
printf("\n");
std::vector<unsigned char> out;
out.assign(finalKey, finalKey + 32);
return out;
}
std::vector<unsigned char> encrypt_bip38(const std::vector<unsigned char> priv_key,
const std::string& address, const std::string& passwd)
{
unsigned char key[64];
unsigned char derivedhalf1[32], derivedhalf2[32];
unsigned char encryptedhalf1[16], encryptedhalf2[16];
unsigned char part1[32], part2[32];
const unsigned char * p_address = reinterpret_cast<const unsigned char*>(address.data());
const unsigned char * p_secret = reinterpret_cast<const unsigned char*>(priv_key.data());
// 1. take the first four bytes of SHA256(SHA256()) of it. Let's call this "addresshash".
// addresshash = hashlib.sha256(hashlib.sha256(address).digest()).digest()[:4] # salt
unsigned char addresshash[32];
bu_Hash(addresshash, &p_address[0], 34);
// #2. Derive a key from the passphrase using scrypt
// # a. Parameters: passphrase is the passphrase itself encoded in UTF-8.
// # addresshash came from the earlier step, n=16384, r=8, p=8, length=64
// # (n, r, p are provisional and subject to consensus)
// key = scrypt.hash(passphrase, addresshash, 16384, 8, p)
crypto_scrypt((const uint8_t *)passwd.c_str(), passwd.length(),
&addresshash[0], ADDRESSHASH_SIZE, 16384, 8, 8, key, 64);
memcpy(derivedhalf1, &key[0], 32);
memcpy(derivedhalf2, &key[32], 32);
// #3. Do AES256Encrypt(bitcoinprivkey[0...15] xor derivedhalf1[0...15], derivedhalf2), call the 16-byte result encryptedhalf1
// Aes = aes.Aes(derivedhalf2)
// encryptedhalf1 = Aes.enc(enc.sxor(privK[:16], derivedhalf1[:16]))
//
for (int i=0; i < 16; i++)
part1[i] = p_secret[i] ^ derivedhalf1[i];
for (int i=0; i < 16; i++)
part2[i] = p_secret[i + 16] ^ derivedhalf1[i + 16];
int encrypt_len;
EVP_CIPHER_CTX en;
EVP_CIPHER_CTX_init(&en);
EVP_EncryptInit_ex(&en, EVP_aes_256_cbc(), NULL, derivedhalf2, NULL);
EVP_EncryptUpdate(&en, encryptedhalf1, &encrypt_len, part1, 16);
EVP_EncryptInit_ex(&en, EVP_aes_256_cbc(), NULL, derivedhalf2, NULL);
EVP_EncryptUpdate(&en, encryptedhalf2, &encrypt_len, part2, 16);
// #5. The encrypted private key is the Base58Check-encoded concatenation of the following, which totals 39 bytes without Base58 checksum:
// # 0x01 0x42 + flagbyte + salt + encryptedhalf1 + encryptedhalf2
// flagbyte = chr(0b11100000) # 11 no-ec 1 compressed-pub 00 future 0 ec only 00 future
// privkey = ('\x01\x42' + flagbyte + addresshash + encryptedhalf1 + encryptedhalf2)
// check = hashlib.sha256(hashlib.sha256(privkey).digest()).digest()[:4]
// return enc.b58encode(privkey + check)
unsigned char flagbyte = 0xc0;// 0b11100000; // 11 no-ec 1 compressed-pub 00 future 0 ec only 00 future
unsigned char pref1 = 0x01;
unsigned char pref2 = 0x42;
unsigned char enc_key[128];
enc_key[0] = pref1;
enc_key[1] = pref2;
enc_key[2] = flagbyte;
memcpy(enc_key + 3, addresshash, ADDRESSHASH_SIZE);
memcpy(enc_key + 3 + ADDRESSHASH_SIZE, encryptedhalf1, 16);
memcpy(enc_key + 3 + ADDRESSHASH_SIZE + 16, encryptedhalf2, 16);
return std::vector<unsigned char>(&enc_key[0], &enc_key[3 + ADDRESSHASH_SIZE + 32]);
}
static bool bp_script_eval(parr *stack, const cstring *script,
const struct bp_tx *txTo, unsigned int nIn,
unsigned int flags, int nHashType)
{
struct const_buffer pc = { script->str, script->len };
struct const_buffer pend = { script->str + script->len, 0 };
struct const_buffer pbegincodehash = { script->str, script->len };
struct bscript_op op;
bool rc = false;
cstring *vfExec = cstr_new(NULL);
parr *altstack = parr_new(0, buffer_freep);
mpz_t bn, bn_Zero, bn_One;
mpz_init(bn);
mpz_init_set_ui(bn_Zero, 0);
mpz_init_set_ui(bn_One,1);
if (script->len > MAX_SCRIPT_SIZE)
goto out;
unsigned int nOpCount = 0;
bool fRequireMinimal = (flags & SCRIPT_VERIFY_MINIMALDATA) != 0;
struct bscript_parser bp;
bsp_start(&bp, &pc);
while (pc.p < pend.p) {
bool fExec = !count_false(vfExec);
if (!bsp_getop(&op, &bp))
goto out;
enum opcodetype opcode = op.op;
if (op.data.len > MAX_SCRIPT_ELEMENT_SIZE)
goto out;
if (opcode > OP_16 && ++nOpCount > MAX_OPS_PER_SCRIPT)
goto out;
if (disabled_op[opcode])
goto out;
if (fExec && 0 <= opcode && opcode <= OP_PUSHDATA4) {
if (fRequireMinimal && !CheckMinimalPush(&op.data, opcode))
goto out;
stack_push(stack, (struct buffer *) &op.data);
} else if (fExec || (OP_IF <= opcode && opcode <= OP_ENDIF))
switch (opcode) {
//
// Push value
//
case OP_1NEGATE:
case OP_1:
case OP_2:
case OP_3:
case OP_4:
case OP_5:
case OP_6:
case OP_7:
case OP_8:
case OP_9:
case OP_10:
case OP_11:
case OP_12:
case OP_13:
case OP_14:
case OP_15:
case OP_16:
mpz_set_si(bn, (int)opcode - (int)(OP_1 - 1));
stack_push_str(stack, bn_getvch(bn));
break;
//
// Control
//
case OP_NOP:
break;
case OP_CHECKLOCKTIMEVERIFY: {
if (!(flags & SCRIPT_VERIFY_CHECKLOCKTIMEVERIFY)) {
// not enabled; treat as a NOP2
if (flags & SCRIPT_VERIFY_DISCOURAGE_UPGRADABLE_NOPS)
goto out;
break;
}
if (stack->len < 1)
goto out;
// Note that elsewhere numeric opcodes are limited to
// operands in the range -2**31+1 to 2**31-1, however it is
// legal for opcodes to produce results exceeding that
// range. This limitation is implemented by CastToBigNum's
// default 4-byte limit.
//
// If we kept to that limit we'd have a year 2038 problem,
// even though the nLockTime field in transactions
// themselves is uint32 which only becomes meaningless
// after the year 2106.
//
// Thus as a special case we tell CastToBigNum to accept up
// to 5-byte bignums, which are good until 2**39-1, well
// beyond the 2**32-1 limit of the nLockTime field itself.
if (!CastToBigNum(bn, stacktop(stack, -1), fRequireMinimal, 5))
goto out;
// In the rare event that the argument may be < 0 due to
// some arithmetic being done first, you can always use
// 0 MAX CHECKLOCKTIMEVERIFY.
if (mpz_sgn(bn) < 0)
goto out;
uint64_t nLockTime = mpz_get_ui(bn);
// Actually compare the specified lock time with the transaction.
if (!CheckLockTime(nLockTime, txTo, nIn))
goto out;
break;
}
case OP_CHECKSEQUENCEVERIFY:
{
if (!(flags & SCRIPT_VERIFY_CHECKSEQUENCEVERIFY)) {
// not enabled; treat as a NOP3
if (flags & SCRIPT_VERIFY_DISCOURAGE_UPGRADABLE_NOPS)
goto out;
break;
}
if (stack->len < 1)
goto out;
// nSequence, like nLockTime, is a 32-bit unsigned integer
// field. See the comment in CHECKLOCKTIMEVERIFY regarding
// 5-byte numeric operands.
if (!CastToBigNum(bn, stacktop(stack, -1), fRequireMinimal, 5))
goto out;
// In the rare event that the argument may be < 0 due to
// some arithmetic being done first, you can always use
// 0 MAX CHECKSEQUENCEVERIFY.
if (mpz_sgn(bn) < 0)
goto out;
uint32_t nSequence = mpz_get_ui(bn);
// To provide for future soft-fork extensibility, if the
// operand has the disabled lock-time flag set,
// CHECKSEQUENCEVERIFY behaves as a NOP.
if ((nSequence & SEQUENCE_LOCKTIME_DISABLE_FLAG) != 0)
break;
// Compare the specified sequence number with the input.
if (!CheckSequence(nSequence, txTo, nIn))
goto out;
break;
}
case OP_NOP1: case OP_NOP4: case OP_NOP5:
case OP_NOP6: case OP_NOP7: case OP_NOP8: case OP_NOP9: case OP_NOP10:
if (flags & SCRIPT_VERIFY_DISCOURAGE_UPGRADABLE_NOPS)
goto out;
break;
case OP_IF:
case OP_NOTIF: {
// <expression> if [statements] [else [statements]] endif
bool fValue = false;
if (fExec) {
if (stack->len < 1)
goto out;
struct buffer *vch = stacktop(stack, -1);
fValue = CastToBool(vch);
if (opcode == OP_NOTIF)
fValue = !fValue;
popstack(stack);
}
uint8_t vc = (uint8_t) fValue;
cstr_append_c(vfExec, vc);
break;
}
case OP_ELSE: {
if (vfExec->len == 0)
goto out;
uint8_t *v = (uint8_t *) &vfExec->str[vfExec->len - 1];
*v = !(*v);
break;
}
case OP_ENDIF:
if (vfExec->len == 0)
goto out;
cstr_erase(vfExec, vfExec->len - 1, 1);
break;
case OP_VERIFY: {
if (stack->len < 1)
goto out;
bool fValue = CastToBool(stacktop(stack, -1));
if (fValue)
popstack(stack);
else
goto out;
break;
}
case OP_RETURN:
goto out;
//
// Stack ops
//
case OP_TOALTSTACK:
if (stack->len < 1)
goto out;
stack_push(altstack, stacktop(stack, -1));
popstack(stack);
break;
case OP_FROMALTSTACK:
if (altstack->len < 1)
goto out;
stack_push(stack, stacktop(altstack, -1));
popstack(altstack);
break;
case OP_2DROP:
// (x1 x2 -- )
if (stack->len < 2)
goto out;
popstack(stack);
popstack(stack);
break;
case OP_2DUP: {
// (x1 x2 -- x1 x2 x1 x2)
if (stack->len < 2)
goto out;
struct buffer *vch1 = stacktop(stack, -2);
struct buffer *vch2 = stacktop(stack, -1);
stack_push(stack, vch1);
stack_push(stack, vch2);
break;
}
case OP_3DUP: {
// (x1 x2 x3 -- x1 x2 x3 x1 x2 x3)
if (stack->len < 3)
goto out;
struct buffer *vch1 = stacktop(stack, -3);
struct buffer *vch2 = stacktop(stack, -2);
struct buffer *vch3 = stacktop(stack, -1);
stack_push(stack, vch1);
stack_push(stack, vch2);
stack_push(stack, vch3);
break;
}
case OP_2OVER: {
// (x1 x2 x3 x4 -- x1 x2 x3 x4 x1 x2)
if (stack->len < 4)
goto out;
struct buffer *vch1 = stacktop(stack, -4);
struct buffer *vch2 = stacktop(stack, -3);
stack_push(stack, vch1);
stack_push(stack, vch2);
break;
}
case OP_2ROT: {
// (x1 x2 x3 x4 x5 x6 -- x3 x4 x5 x6 x1 x2)
if (stack->len < 6)
goto out;
struct buffer *vch1 = stack_take(stack, -6);
struct buffer *vch2 = stack_take(stack, -5);
parr_remove_range(stack, stack->len - 6, 2);
stack_push_nocopy(stack, vch1);
stack_push_nocopy(stack, vch2);
break;
}
case OP_2SWAP:
// (x1 x2 x3 x4 -- x3 x4 x1 x2)
if (stack->len < 4)
goto out;
stack_swap(stack, -4, -2);
stack_swap(stack, -3, -1);
break;
case OP_IFDUP: {
// (x - 0 | x x)
if (stack->len < 1)
goto out;
struct buffer *vch = stacktop(stack, -1);
if (CastToBool(vch))
stack_push(stack, vch);
break;
}
case OP_DEPTH:
// -- stacksize
mpz_set_ui(bn, stack->len);
stack_push_str(stack, bn_getvch(bn));
break;
case OP_DROP:
// (x -- )
if (stack->len < 1)
goto out;
popstack(stack);
break;
case OP_DUP: {
// (x -- x x)
if (stack->len < 1)
goto out;
struct buffer *vch = stacktop(stack, -1);
stack_push(stack, vch);
break;
}
case OP_NIP:
// (x1 x2 -- x2)
if (stack->len < 2)
goto out;
parr_remove_idx(stack, stack->len - 2);
break;
case OP_OVER: {
// (x1 x2 -- x1 x2 x1)
if (stack->len < 2)
goto out;
struct buffer *vch = stacktop(stack, -2);
stack_push(stack, vch);
break;
}
case OP_PICK:
case OP_ROLL: {
// (xn ... x2 x1 x0 n - xn ... x2 x1 x0 xn)
// (xn ... x2 x1 x0 n - ... x2 x1 x0 xn)
if (stack->len < 2)
goto out;
int n = stackint(stack, -1, fRequireMinimal);
popstack(stack);
if (n < 0 || n >= (int)stack->len)
goto out;
struct buffer *vch = stacktop(stack, -n-1);
if (opcode == OP_ROLL) {
vch = buffer_copy(vch->p, vch->len);
parr_remove_idx(stack,
stack->len - n - 1);
stack_push_nocopy(stack, vch);
} else
stack_push(stack, vch);
break;
}
case OP_ROT: {
// (x1 x2 x3 -- x2 x3 x1)
// x2 x1 x3 after first swap
// x2 x3 x1 after second swap
if (stack->len < 3)
goto out;
stack_swap(stack, -3, -2);
stack_swap(stack, -2, -1);
break;
}
case OP_SWAP: {
// (x1 x2 -- x2 x1)
if (stack->len < 2)
goto out;
stack_swap(stack, -2, -1);
break;
}
case OP_TUCK: {
// (x1 x2 -- x2 x1 x2)
if (stack->len < 2)
goto out;
struct buffer *vch = stacktop(stack, -1);
stack_insert(stack, vch, -2);
break;
}
case OP_SIZE: {
// (in -- in size)
if (stack->len < 1)
goto out;
struct buffer *vch = stacktop(stack, -1);
mpz_set_ui(bn, vch->len);
stack_push_str(stack, bn_getvch(bn));
break;
}
case OP_EQUAL:
case OP_EQUALVERIFY: {
// (x1 x2 - bool)
if (stack->len < 2)
goto out;
struct buffer *vch1 = stacktop(stack, -2);
struct buffer *vch2 = stacktop(stack, -1);
bool fEqual = buffer_equal(vch1, vch2);
// OP_NOTEQUAL is disabled because it would be too easy to say
// something like n != 1 and have some wiseguy pass in 1 with extra
// zero bytes after it (numerically, 0x01 == 0x0001 == 0x000001)
//if (opcode == OP_NOTEQUAL)
// fEqual = !fEqual;
popstack(stack);
popstack(stack);
stack_push_str(stack, fEqual ? bn_getvch(bn_One) : bn_getvch(bn_Zero));
if (opcode == OP_EQUALVERIFY) {
if (fEqual)
popstack(stack);
else
goto out;
}
break;
}
//
// Numeric
//
case OP_1ADD:
case OP_1SUB:
case OP_NEGATE:
case OP_ABS:
case OP_NOT:
case OP_0NOTEQUAL: {
// (in -- out)
if (stack->len < 1)
goto out;
if (!CastToBigNum(bn, stacktop(stack, -1), fRequireMinimal, nDefaultMaxNumSize))
goto out;
switch (opcode)
{
case OP_1ADD:
mpz_add_ui(bn, bn, 1);
break;
case OP_1SUB:
mpz_sub_ui(bn, bn, 1);
break;
case OP_NEGATE:
mpz_neg(bn, bn);
break;
case OP_ABS:
mpz_abs(bn, bn);
break;
case OP_NOT:
mpz_set_ui(bn, mpz_sgn(bn) == 0 ? 1 : 0);
break;
case OP_0NOTEQUAL:
mpz_set_ui(bn, mpz_sgn(bn) == 0 ? 0 : 1);
break;
default:
// impossible
goto out;
}
popstack(stack);
stack_push_str(stack, bn_getvch(bn));
break;
}
case OP_ADD:
case OP_SUB:
case OP_BOOLAND:
case OP_BOOLOR:
case OP_NUMEQUAL:
case OP_NUMEQUALVERIFY:
case OP_NUMNOTEQUAL:
case OP_LESSTHAN:
case OP_GREATERTHAN:
case OP_LESSTHANOREQUAL:
case OP_GREATERTHANOREQUAL:
case OP_MIN:
case OP_MAX: {
// (x1 x2 -- out)
if (stack->len < 2)
goto out;
mpz_t bn1, bn2;
mpz_init(bn1);
mpz_init(bn2);
if (!CastToBigNum(bn1, stacktop(stack, -2), fRequireMinimal, nDefaultMaxNumSize) ||
!CastToBigNum(bn2, stacktop(stack, -1), fRequireMinimal, nDefaultMaxNumSize)) {
mpz_clear(bn1);
mpz_clear(bn2);
goto out;
}
switch (opcode)
{
case OP_ADD:
mpz_add(bn, bn1, bn2);
break;
case OP_SUB:
mpz_sub(bn, bn1, bn2);
break;
case OP_BOOLAND:
mpz_set_ui(bn,
!(mpz_sgn(bn1) == 0) && !(mpz_sgn(bn2) == 0) ?
1 : 0);
break;
case OP_BOOLOR:
mpz_set_ui(bn,
!(mpz_sgn(bn1) == 0) || !(mpz_sgn(bn2) == 0) ?
1 : 0);
break;
case OP_NUMEQUAL:
case OP_NUMEQUALVERIFY:
mpz_set_ui(bn,
mpz_cmp(bn1, bn2) == 0 ? 1 : 0);
break;
case OP_NUMNOTEQUAL:
mpz_set_ui(bn,
mpz_cmp(bn1, bn2) != 0 ? 1 : 0);
break;
case OP_LESSTHAN:
mpz_set_ui(bn,
mpz_cmp(bn1, bn2) < 0 ? 1 : 0);
break;
case OP_GREATERTHAN:
mpz_set_ui(bn,
mpz_cmp(bn1, bn2) > 0 ? 1 : 0);
break;
case OP_LESSTHANOREQUAL:
mpz_set_ui(bn,
mpz_cmp(bn1, bn2) <= 0 ? 1 : 0);
break;
case OP_GREATERTHANOREQUAL:
mpz_set_ui(bn,
mpz_cmp(bn1, bn2) >= 0 ? 1 : 0);
break;
case OP_MIN:
if (mpz_cmp(bn1, bn2) < 0)
mpz_set(bn, bn1);
else
mpz_set(bn, bn2);
break;
case OP_MAX:
if (mpz_cmp(bn1, bn2) > 0)
mpz_set(bn, bn1);
else
mpz_set(bn, bn2);
break;
default:
// impossible
break;
}
popstack(stack);
popstack(stack);
stack_push_str(stack, bn_getvch(bn));
mpz_clear(bn1);
mpz_clear(bn2);
if (opcode == OP_NUMEQUALVERIFY)
{
if (CastToBool(stacktop(stack, -1)))
popstack(stack);
else
goto out;
}
break;
}
case OP_WITHIN: {
// (x min max -- out)
if (stack->len < 3)
goto out;
mpz_t bn1, bn2, bn3;
mpz_init(bn1);
mpz_init(bn2);
mpz_init(bn3);
bool rc1 = CastToBigNum(bn1, stacktop(stack, -3), fRequireMinimal, nDefaultMaxNumSize);
bool rc2 = CastToBigNum(bn2, stacktop(stack, -2), fRequireMinimal, nDefaultMaxNumSize);
bool rc3 = CastToBigNum(bn3, stacktop(stack, -1), fRequireMinimal, nDefaultMaxNumSize);
bool fValue = (mpz_cmp(bn2, bn1) <= 0 &&
mpz_cmp(bn1, bn3) < 0);
popstack(stack);
popstack(stack);
popstack(stack);
stack_push_str(stack, fValue ? bn_getvch(bn_One) : bn_getvch(bn_Zero));
mpz_clear(bn1);
mpz_clear(bn2);
mpz_clear(bn3);
if (!rc1 || !rc2 || !rc3)
goto out;
break;
}
//
// Crypto
//
case OP_RIPEMD160:
case OP_SHA1:
case OP_SHA256:
case OP_HASH160:
case OP_HASH256: {
// (in -- hash)
if (stack->len < 1)
goto out;
struct buffer *vch = stacktop(stack, -1);
unsigned int hashlen;
unsigned char md[32];
switch (opcode) {
case OP_RIPEMD160:
hashlen = 20;
ripemd160(vch->p, vch->len, md);
break;
case OP_SHA1:
hashlen = 20;
sha1_Raw(vch->p, vch->len, md);
break;
case OP_SHA256:
hashlen = 32;
sha256_Raw(vch->p, vch->len, md);
break;
case OP_HASH160:
hashlen = 20;
bu_Hash160(md, vch->p, vch->len);
break;
case OP_HASH256:
hashlen = 32;
bu_Hash(md, vch->p, vch->len);
break;
default:
// impossible
goto out;
}
popstack(stack);
struct buffer buf = { md, hashlen };
stack_push(stack, &buf);
break;
}
case OP_CODESEPARATOR:
// Hash starts after the code separator
memcpy(&pbegincodehash, &pc, sizeof(pc));
break;
case OP_CHECKSIG:
case OP_CHECKSIGVERIFY: {
// (sig pubkey -- bool)
if (stack->len < 2)
goto out;
struct buffer *vchSig = stacktop(stack, -2);
struct buffer *vchPubKey = stacktop(stack, -1);
// Subset of script starting at the most recent codeseparator
cstring *scriptCode = cstr_new_buf(pbegincodehash.p,
pbegincodehash.len);
// Drop the signature, since there's no way for
// a signature to sign itself
string_find_del(scriptCode, vchSig);
if (!CheckSignatureEncoding(vchSig, flags) || !CheckPubKeyEncoding(vchPubKey, flags)) {
cstr_free(scriptCode, true);
goto out;
}
bool fSuccess = bp_checksig(vchSig, vchPubKey,
scriptCode,
txTo, nIn);
cstr_free(scriptCode, true);
popstack(stack);
popstack(stack);
stack_push_str(stack, fSuccess ? bn_getvch(bn_One) : bn_getvch(bn_Zero));
if (opcode == OP_CHECKSIGVERIFY)
{
if (fSuccess)
popstack(stack);
else
goto out;
}
break;
}
case OP_CHECKMULTISIG:
case OP_CHECKMULTISIGVERIFY: {
// ([sig ...] num_of_signatures [pubkey ...] num_of_pubkeys -- bool)
int i = 1;
if ((int)stack->len < i)
goto out;
int nKeysCount = stackint(stack, -i, fRequireMinimal);
if (nKeysCount < 0 || nKeysCount > MAX_PUBKEYS_PER_MULTISIG)
goto out;
nOpCount += nKeysCount;
if (nOpCount > MAX_OPS_PER_SCRIPT)
goto out;
int ikey = ++i;
i += nKeysCount;
if ((int)stack->len < i)
goto out;
int nSigsCount = stackint(stack, -i, fRequireMinimal);
if (nSigsCount < 0 || nSigsCount > nKeysCount)
goto out;
int isig = ++i;
i += nSigsCount;
if ((int)stack->len < i)
goto out;
// Subset of script starting at the most recent codeseparator
cstring *scriptCode = cstr_new_buf(pbegincodehash.p,
pbegincodehash.len);
// Drop the signatures, since there's no way for
// a signature to sign itself
int k;
for (k = 0; k < nSigsCount; k++)
{
struct buffer *vchSig =stacktop(stack, -isig-k);
string_find_del(scriptCode, vchSig);
}
bool fSuccess = true;
while (fSuccess && nSigsCount > 0)
{
struct buffer *vchSig = stacktop(stack, -isig);
struct buffer *vchPubKey = stacktop(stack, -ikey);
// Note how this makes the exact order of pubkey/signature evaluation
// distinguishable by CHECKMULTISIG NOT if the STRICTENC flag is set.
// See the script_(in)valid tests for details.
if (!CheckSignatureEncoding(vchSig, flags) || !CheckPubKeyEncoding(vchPubKey, flags)) {
cstr_free(scriptCode, true);
goto out;
}
// Check signature
bool fOk = bp_checksig(vchSig, vchPubKey,
scriptCode, txTo, nIn);
if (fOk) {
isig++;
nSigsCount--;
}
ikey++;
nKeysCount--;
// If there are more signatures left than keys left,
// then too many signatures have failed
if (nSigsCount > nKeysCount)
fSuccess = false;
}
cstr_free(scriptCode, true);
// Clean up stack of actual arguments
while (i-- > 1)
popstack(stack);
// A bug causes CHECKMULTISIG to consume one extra argument
// whose contents were not checked in any way.
//
// Unfortunately this is a potential source of mutability,
// so optionally verify it is exactly equal to zero prior
// to removing it from the stack.
if ((int)stack->len < 1)
goto out;
if ((flags & SCRIPT_VERIFY_NULLDUMMY) && stacktop(stack, -1)->len)
goto out;
popstack(stack);
stack_push_str(stack, fSuccess ? bn_getvch(bn_One) : bn_getvch(bn_Zero));
if (opcode == OP_CHECKMULTISIGVERIFY)
{
if (fSuccess)
popstack(stack);
else
goto out;
}
break;
}
default:
goto out;
}
// Size limits
if (stack->len + altstack->len > 1000)
goto out;
}
rc = (vfExec->len == 0 && bp.error == false);
out:
mpz_clears(bn, bn_Zero, bn_One, NULL);
parr_free(altstack, true);
cstr_free(vfExec, true);
return rc;
}
static bool bp_script_eval(GPtrArray *stack, const GString *script,
const struct bp_tx *txTo, unsigned int nIn,
unsigned int flags, int nHashType)
{
struct const_buffer pc = { script->str, script->len };
struct const_buffer pend = { script->str + script->len, 0 };
struct const_buffer pbegincodehash = { script->str, script->len };
struct bscript_op op;
bool rc = false;
GByteArray *vfExec = g_byte_array_new();
GPtrArray *altstack = g_ptr_array_new_with_free_func(
(GDestroyNotify) buffer_free);
BIGNUM bn;
BN_init(&bn);
if (script->len > 10000)
goto out;
bool fStrictEncodings = flags & SCRIPT_VERIFY_STRICTENC;
unsigned int nOpCount = 0;
struct bscript_parser bp;
bsp_start(&bp, &pc);
while (pc.p < pend.p) {
bool fExec = !count_false(vfExec);
if (!bsp_getop(&op, &bp))
goto out;
enum opcodetype opcode = op.op;
if (op.data.len > 520)
goto out;
if (opcode > OP_16 && ++nOpCount > 201)
goto out;
if (disabled_op[opcode])
goto out;
if (fExec && is_bsp_pushdata(opcode))
stack_push(stack, (struct buffer *) &op.data);
else if (fExec || (OP_IF <= opcode && opcode <= OP_ENDIF))
switch (opcode) {
//
// Push value
//
case OP_1NEGATE:
case OP_1:
case OP_2:
case OP_3:
case OP_4:
case OP_5:
case OP_6:
case OP_7:
case OP_8:
case OP_9:
case OP_10:
case OP_11:
case OP_12:
case OP_13:
case OP_14:
case OP_15:
case OP_16:
bn_set_int(&bn, (int)opcode - (int)(OP_1 - 1));
stack_push_str(stack, bn_getvch(&bn));
break;
//
// Control
//
case OP_NOP:
case OP_NOP1: case OP_NOP2: case OP_NOP3: case OP_NOP4: case
OP_NOP5:
case OP_NOP6: case OP_NOP7: case OP_NOP8: case OP_NOP9: case
OP_NOP10:
break;
case OP_IF:
case OP_NOTIF: {
// <expression> if [statements] [else [statements]] endif
bool fValue = false;
if (fExec) {
if (stack->len < 1)
goto out;
struct buffer *vch = stacktop(stack, -1);
fValue = CastToBool(vch);
if (opcode == OP_NOTIF)
fValue = !fValue;
popstack(stack);
}
guint8 vc = (guint8) fValue;
g_byte_array_append(vfExec, &vc, 1);
break;
}
case OP_ELSE: {
if (vfExec->len == 0)
goto out;
guint8 *v = &vfExec->data[vfExec->len - 1];
*v = !(*v);
break;
}
case OP_ENDIF:
if (vfExec->len == 0)
goto out;
g_byte_array_remove_index(vfExec, vfExec->len - 1);
break;
case OP_VERIFY: {
if (stack->len < 1)
goto out;
bool fValue = CastToBool(stacktop(stack, -1));
if (fValue)
popstack(stack);
else
goto out;
break;
}
case OP_RETURN:
goto out;
//
// Stack ops
//
case OP_TOALTSTACK:
if (stack->len < 1)
goto out;
stack_push(altstack, stacktop(stack, -1));
popstack(stack);
break;
case OP_FROMALTSTACK:
if (altstack->len < 1)
goto out;
stack_push(stack, stacktop(altstack, -1));
popstack(altstack);
break;
case OP_2DROP:
// (x1 x2 -- )
if (stack->len < 2)
goto out;
popstack(stack);
popstack(stack);
break;
case OP_2DUP: {
// (x1 x2 -- x1 x2 x1 x2)
if (stack->len < 2)
goto out;
struct buffer *vch1 = stacktop(stack, -2);
struct buffer *vch2 = stacktop(stack, -1);
stack_push(stack, vch1);
stack_push(stack, vch2);
break;
}
case OP_3DUP: {
// (x1 x2 x3 -- x1 x2 x3 x1 x2 x3)
if (stack->len < 3)
goto out;
struct buffer *vch1 = stacktop(stack, -3);
struct buffer *vch2 = stacktop(stack, -2);
struct buffer *vch3 = stacktop(stack, -1);
stack_push(stack, vch1);
stack_push(stack, vch2);
stack_push(stack, vch3);
break;
}
case OP_2OVER: {
// (x1 x2 x3 x4 -- x1 x2 x3 x4 x1 x2)
if (stack->len < 4)
goto out;
struct buffer *vch1 = stacktop(stack, -4);
struct buffer *vch2 = stacktop(stack, -3);
stack_push(stack, vch1);
stack_push(stack, vch2);
break;
}
case OP_2ROT: {
// (x1 x2 x3 x4 x5 x6 -- x3 x4 x5 x6 x1 x2)
if (stack->len < 6)
goto out;
struct buffer *vch1 = stack_take(stack, -6);
struct buffer *vch2 = stack_take(stack, -5);
g_ptr_array_remove_range(stack, stack->len - 6, 2);
stack_push(stack, vch1);
stack_push(stack, vch2);
break;
}
case OP_2SWAP:
// (x1 x2 x3 x4 -- x3 x4 x1 x2)
if (stack->len < 4)
goto out;
stack_swap(stack, -4, -2);
stack_swap(stack, -3, -1);
break;
case OP_IFDUP: {
// (x - 0 | x x)
if (stack->len < 1)
goto out;
struct buffer *vch = stacktop(stack, -1);
if (CastToBool(vch))
stack_push(stack, vch);
break;
}
case OP_DEPTH:
// -- stacksize
BN_set_word(&bn, stack->len);
stack_push_str(stack, bn_getvch(&bn));
break;
case OP_DROP:
// (x -- )
if (stack->len < 1)
goto out;
popstack(stack);
break;
case OP_DUP: {
// (x -- x x)
if (stack->len < 1)
goto out;
struct buffer *vch = stacktop(stack, -1);
stack_push(stack, vch);
break;
}
case OP_NIP:
// (x1 x2 -- x2)
if (stack->len < 2)
goto out;
g_ptr_array_remove_index(stack, stack->len - 2);
break;
case OP_OVER: {
// (x1 x2 -- x1 x2 x1)
if (stack->len < 2)
goto out;
struct buffer *vch = stacktop(stack, -2);
stack_push(stack, vch);
break;
}
case OP_PICK:
case OP_ROLL: {
// (xn ... x2 x1 x0 n - xn ... x2 x1 x0 xn)
// (xn ... x2 x1 x0 n - ... x2 x1 x0 xn)
if (stack->len < 2)
goto out;
int n = stackint(stack, -1);
popstack(stack);
if (n < 0 || n >= (int)stack->len)
goto out;
struct buffer *vch = stacktop(stack, -n-1);
if (opcode == OP_ROLL) {
vch = buffer_copy(vch->p, vch->len);
g_ptr_array_remove_index(stack,
stack->len - n - 1);
stack_push_nocopy(stack, vch);
} else
stack_push(stack, vch);
break;
}
case OP_ROT: {
// (x1 x2 x3 -- x2 x3 x1)
// x2 x1 x3 after first swap
// x2 x3 x1 after second swap
if (stack->len < 3)
goto out;
stack_swap(stack, -3, -2);
stack_swap(stack, -2, -1);
break;
}
case OP_SWAP: {
// (x1 x2 -- x2 x1)
if (stack->len < 2)
goto out;
stack_swap(stack, -2, -1);
break;
}
case OP_TUCK: {
// (x1 x2 -- x2 x1 x2)
if (stack->len < 2)
goto out;
struct buffer *vch = stacktop(stack, -1);
stack_insert(stack, vch, -2);
break;
}
case OP_SIZE: {
// (in -- in size)
if (stack->len < 1)
goto out;
struct buffer *vch = stacktop(stack, -1);
BN_set_word(&bn, vch->len);
stack_push_str(stack, bn_getvch(&bn));
break;
}
case OP_EQUAL:
case OP_EQUALVERIFY: {
// (x1 x2 - bool)
if (stack->len < 2)
goto out;
struct buffer *vch1 = stacktop(stack, -2);
struct buffer *vch2 = stacktop(stack, -1);
bool fEqual = ((vch1->len == vch2->len) &&
memcmp(vch1->p, vch2->p, vch1->len) == 0);
// OP_NOTEQUAL is disabled because it would be too easy to say
// something like n != 1 and have some wiseguy pass in 1 with extra
// zero bytes after it (numerically, 0x01 == 0x0001 == 0x000001)
//if (opcode == OP_NOTEQUAL)
// fEqual = !fEqual;
popstack(stack);
popstack(stack);
stack_push_char(stack, fEqual ? 1 : 0);
if (opcode == OP_EQUALVERIFY) {
if (fEqual)
popstack(stack);
else
goto out;
}
break;
}
//
// Numeric
//
case OP_1ADD:
case OP_1SUB:
case OP_NEGATE:
case OP_ABS:
case OP_NOT:
case OP_0NOTEQUAL: {
// (in -- out)
if (stack->len < 1)
goto out;
if (!CastToBigNum(&bn, stacktop(stack, -1)))
goto out;
switch (opcode)
{
case OP_1ADD:
BN_add_word(&bn, 1);
break;
case OP_1SUB:
BN_sub_word(&bn, 1);
break;
case OP_NEGATE:
BN_set_negative(&bn, !BN_is_negative(&bn));
break;
case OP_ABS:
if (BN_is_negative(&bn))
BN_set_negative(&bn, 0);
break;
case OP_NOT:
BN_set_word(&bn, BN_is_zero(&bn) ? 1 : 0);
break;
case OP_0NOTEQUAL:
BN_set_word(&bn, BN_is_zero(&bn) ? 0 : 1);
break;
default:
// impossible
goto out;
}
popstack(stack);
stack_push_str(stack, bn_getvch(&bn));
break;
}
case OP_ADD:
case OP_SUB:
case OP_BOOLAND:
case OP_BOOLOR:
case OP_NUMEQUAL:
case OP_NUMEQUALVERIFY:
case OP_NUMNOTEQUAL:
case OP_LESSTHAN:
case OP_GREATERTHAN:
case OP_LESSTHANOREQUAL:
case OP_GREATERTHANOREQUAL:
case OP_MIN:
case OP_MAX: {
// (x1 x2 -- out)
if (stack->len < 2)
goto out;
BIGNUM bn1, bn2;
BN_init(&bn1);
BN_init(&bn2);
if (!CastToBigNum(&bn1, stacktop(stack, -2)) ||
!CastToBigNum(&bn2, stacktop(stack, -1))) {
BN_clear_free(&bn1);
BN_clear_free(&bn2);
goto out;
}
switch (opcode)
{
case OP_ADD:
BN_add(&bn, &bn1, &bn2);
break;
case OP_SUB:
BN_sub(&bn, &bn1, &bn2);
break;
case OP_BOOLAND:
BN_set_word(&bn,
(!BN_is_zero(&bn1) && !BN_is_zero(&bn2)) ?
1 : 0);
break;
case OP_BOOLOR:
BN_set_word(&bn,
(!BN_is_zero(&bn1) || !BN_is_zero(&bn2)) ?
1 : 0);
break;
case OP_NUMEQUAL:
case OP_NUMEQUALVERIFY:
BN_set_word(&bn,
(BN_cmp(&bn1, &bn2) == 0) ? 1 : 0);
break;
case OP_NUMNOTEQUAL:
BN_set_word(&bn,
(BN_cmp(&bn1, &bn2) != 0) ? 1 : 0);
break;
case OP_LESSTHAN:
BN_set_word(&bn,
(BN_cmp(&bn1, &bn2) < 0) ? 1 : 0);
break;
case OP_GREATERTHAN:
BN_set_word(&bn,
(BN_cmp(&bn1, &bn2) > 0) ? 1 : 0);
break;
case OP_LESSTHANOREQUAL:
BN_set_word(&bn,
(BN_cmp(&bn1, &bn2) <= 0) ? 1 : 0);
break;
case OP_GREATERTHANOREQUAL:
BN_set_word(&bn,
(BN_cmp(&bn1, &bn2) >= 0) ? 1 : 0);
break;
case OP_MIN:
if (BN_cmp(&bn1, &bn2) < 0)
BN_copy(&bn, &bn1);
else
BN_copy(&bn, &bn2);
break;
case OP_MAX:
if (BN_cmp(&bn1, &bn2) > 0)
BN_copy(&bn, &bn1);
else
BN_copy(&bn, &bn2);
break;
default:
// impossible
break;
}
popstack(stack);
popstack(stack);
stack_push_str(stack, bn_getvch(&bn));
BN_clear_free(&bn1);
BN_clear_free(&bn2);
if (opcode == OP_NUMEQUALVERIFY)
{
if (CastToBool(stacktop(stack, -1)))
popstack(stack);
else
goto out;
}
break;
}
case OP_WITHIN: {
// (x min max -- out)
if (stack->len < 3)
goto out;
BIGNUM bn1, bn2, bn3;
BN_init(&bn1);
BN_init(&bn2);
BN_init(&bn3);
bool rc1 = CastToBigNum(&bn1, stacktop(stack, -3));
bool rc2 = CastToBigNum(&bn2, stacktop(stack, -2));
bool rc3 = CastToBigNum(&bn3, stacktop(stack, -1));
bool fValue = (BN_cmp(&bn2, &bn1) <= 0 &&
BN_cmp(&bn1, &bn3) < 0);
popstack(stack);
popstack(stack);
popstack(stack);
stack_push_char(stack, fValue ? 1 : 0);
BN_clear_free(&bn1);
BN_clear_free(&bn2);
BN_clear_free(&bn3);
if (!rc1 || !rc2 || !rc3)
goto out;
break;
}
//
// Crypto
//
case OP_RIPEMD160:
case OP_SHA1:
case OP_SHA256:
case OP_HASH160:
case OP_HASH256: {
// (in -- hash)
if (stack->len < 1)
goto out;
struct buffer *vch = stacktop(stack, -1);
unsigned int hashlen;
unsigned char md[32];
switch (opcode) {
case OP_RIPEMD160:
hashlen = 20;
RIPEMD160(vch->p, vch->len, md);
break;
case OP_SHA1:
hashlen = 20;
SHA1(vch->p, vch->len, md);
break;
case OP_SHA256:
hashlen = 32;
SHA256(vch->p, vch->len, md);
break;
case OP_HASH160:
hashlen = 20;
bu_Hash160(md, vch->p, vch->len);
break;
case OP_HASH256:
hashlen = 32;
bu_Hash(md, vch->p, vch->len);
break;
default:
// impossible
goto out;
}
popstack(stack);
struct buffer buf = { md, hashlen };
stack_push(stack, &buf);
break;
}
case OP_CODESEPARATOR:
// Hash starts after the code separator
memcpy(&pbegincodehash, &pc, sizeof(pc));
break;
case OP_CHECKSIG:
case OP_CHECKSIGVERIFY: {
// (sig pubkey -- bool)
if (stack->len < 2)
goto out;
struct buffer *vchSig = stacktop(stack, -2);
struct buffer *vchPubKey = stacktop(stack, -1);
////// debug print
//PrintHex(vchSig.begin(), vchSig.end(), "sig: %s\n");
//PrintHex(vchPubKey.begin(), vchPubKey.end(), "pubkey: %s\n");
// Subset of script starting at the most recent codeseparator
GString *scriptCode = g_string_sized_new(pbegincodehash.len);
g_string_append_len(scriptCode,
pbegincodehash.p,
pbegincodehash.len);
// Drop the signature, since there's no way for
// a signature to sign itself
string_find_del(scriptCode, vchSig);
bool fSuccess =
(!fStrictEncodings ||
(IsCanonicalSignature(vchSig) &&
IsCanonicalPubKey(vchPubKey)));
if (fSuccess)
fSuccess = bp_checksig(vchSig, vchPubKey,
scriptCode,
txTo, nIn, nHashType);
g_string_free(scriptCode, TRUE);
popstack(stack);
popstack(stack);
stack_push_char(stack, fSuccess ? 1 : 0);
if (opcode == OP_CHECKSIGVERIFY)
{
if (fSuccess)
popstack(stack);
else
goto out;
}
break;
}
case OP_CHECKMULTISIG:
case OP_CHECKMULTISIGVERIFY: {
// ([sig ...] num_of_signatures [pubkey ...] num_of_pubkeys -- bool)
int i = 1;
if ((int)stack->len < i)
goto out;
int nKeysCount = stackint(stack, -i);
if (nKeysCount < 0 || nKeysCount > 20)
goto out;
nOpCount += nKeysCount;
if (nOpCount > 201)
goto out;
int ikey = ++i;
i += nKeysCount;
if ((int)stack->len < i)
goto out;
int nSigsCount = stackint(stack, -i);
if (nSigsCount < 0 || nSigsCount > nKeysCount)
goto out;
int isig = ++i;
i += nSigsCount;
if ((int)stack->len < i)
goto out;
// Subset of script starting at the most recent codeseparator
GString *scriptCode = g_string_sized_new(pbegincodehash.len);
g_string_append_len(scriptCode,
pbegincodehash.p,
pbegincodehash.len);
// Drop the signatures, since there's no way for
// a signature to sign itself
int k;
for (k = 0; k < nSigsCount; k++)
{
struct buffer *vchSig =stacktop(stack, -isig-k);
string_find_del(scriptCode, vchSig);
}
bool fSuccess = true;
while (fSuccess && nSigsCount > 0)
{
struct buffer *vchSig = stacktop(stack, -isig);
struct buffer *vchPubKey = stacktop(stack, -ikey);
// Check signature
bool fOk =
(!fStrictEncodings ||
(IsCanonicalSignature(vchSig) &&
IsCanonicalPubKey(vchPubKey)));
if (fOk)
fOk = bp_checksig(vchSig, vchPubKey,
scriptCode, txTo, nIn,
nHashType);
if (fOk) {
isig++;
nSigsCount--;
}
ikey++;
nKeysCount--;
// If there are more signatures left than keys left,
// then too many signatures have failed
if (nSigsCount > nKeysCount)
fSuccess = false;
}
g_string_free(scriptCode, TRUE);
while (i-- > 0)
popstack(stack);
stack_push_char(stack, fSuccess ? 1 : 0);
if (opcode == OP_CHECKMULTISIGVERIFY)
{
if (fSuccess)
popstack(stack);
else
goto out;
}
break;
}
default:
goto out;
}
if (stack->len + altstack->len > 1000)
goto out;
}
rc = (vfExec->len == 0 && bp.error == false);
out:
BN_clear_free(&bn);
g_ptr_array_free(altstack, TRUE);
g_byte_array_unref(vfExec);
return rc;
}
