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BRAddress.c
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BRAddress.c
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//
// BRAddress.c
//
// Created by Aaron Voisine on 9/18/15.
// Copyright (c) 2015 breadwallet LLC
//
// Permission is hereby granted, free of charge, to any person obtaining a copy
// of this software and associated documentation files (the "Software"), to deal
// in the Software without restriction, including without limitation the rights
// to use, copy, modify, merge, publish, distribute, sublicense, and/or sell
// copies of the Software, and to permit persons to whom the Software is
// furnished to do so, subject to the following conditions:
//
// The above copyright notice and this permission notice shall be included in
// all copies or substantial portions of the Software.
//
// THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR
// IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY,
// FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE
// AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER
// LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM,
// OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN
// THE SOFTWARE.
#include "BRAddress.h"
#include "BRBase58.h"
#include "BRBech32.h"
#include "BRInt.h"
#include <inttypes.h>
#include <assert.h>
#define VAR_INT16_HEADER 0xfd
#define VAR_INT32_HEADER 0xfe
#define VAR_INT64_HEADER 0xff
#define MAX_SCRIPT_LENGTH 0x100 // scripts over this size will not be parsed for an address
// reads a varint from buf and stores its length in intLen if intLen is non-NULL
// returns the varint value
uint64_t BRVarInt(const uint8_t *buf, size_t bufLen, size_t *intLen) {
uint64_t r = 0;
uint8_t h = (buf && sizeof(uint8_t) <= bufLen) ? *buf : 0;
switch (h) {
case VAR_INT16_HEADER:
if (intLen) *intLen = sizeof(h) + sizeof(uint16_t);
r = (buf && sizeof(h) + sizeof(uint16_t) <= bufLen) ? UInt16GetLE(&buf[sizeof(h)]) : 0;
break;
case VAR_INT32_HEADER:
if (intLen) *intLen = sizeof(h) + sizeof(uint32_t);
r = (buf && sizeof(h) + sizeof(uint32_t) <= bufLen) ? UInt32GetLE(&buf[sizeof(h)]) : 0;
break;
case VAR_INT64_HEADER:
if (intLen) *intLen = sizeof(h) + sizeof(uint64_t);
r = (buf && sizeof(h) + sizeof(uint64_t) <= bufLen) ? UInt64GetLE(&buf[sizeof(h)]) : 0;
break;
default:
if (intLen) *intLen = sizeof(h);
r = h;
break;
}
return r;
}
// writes i to buf as a varint and returns the number of bytes written, or bufLen needed if buf is NULL
size_t BRVarIntSet(uint8_t *buf, size_t bufLen, uint64_t i) {
size_t r = 0;
if (i < VAR_INT16_HEADER) {
if (buf && sizeof(uint8_t) <= bufLen) *buf = (uint8_t)i;
r = (! buf || sizeof(uint8_t) <= bufLen) ? sizeof(uint8_t) : 0;
} else if (i <= UINT16_MAX) {
if (buf && sizeof(uint8_t) + sizeof(uint16_t) <= bufLen) {
*buf = VAR_INT16_HEADER;
UInt16SetLE(&buf[sizeof(uint8_t)], (uint16_t)i);
}
r = (! buf || sizeof(uint8_t) + sizeof(uint16_t) <= bufLen) ? sizeof(uint8_t) + sizeof(uint16_t) : 0;
} else if (i <= UINT32_MAX) {
if (buf && sizeof(uint8_t) + sizeof(uint32_t) <= bufLen) {
*buf = VAR_INT32_HEADER;
UInt32SetLE(&buf[sizeof(uint8_t)], (uint32_t)i);
}
r = (! buf || sizeof(uint8_t) + sizeof(uint32_t) <= bufLen) ? sizeof(uint8_t) + sizeof(uint32_t) : 0;
} else {
if (buf && sizeof(uint8_t) + sizeof(uint64_t) <= bufLen) {
*buf = VAR_INT64_HEADER;
UInt64SetLE(&buf[sizeof(uint8_t)], i);
}
r = (! buf || sizeof(uint8_t) + sizeof(uint64_t) <= bufLen) ? sizeof(uint8_t) + sizeof(uint64_t) : 0;
}
return r;
}
// returns the number of bytes needed to encode i as a varint
size_t BRVarIntSize(uint64_t i) {
return BRVarIntSet(NULL, 0, i);
}
// parses script and writes an array of pointers to the script elements (opcodes and data pushes) to elems
// returns the number of elements written, or elemsCount needed if elems is NULL
size_t BRScriptElements(const uint8_t *elems[], size_t elemsCount, const uint8_t *script, size_t scriptLen) {
size_t off = 0, i = 0, len = 0;
assert(script != NULL || scriptLen == 0);
while (script && off < scriptLen) {
if (elems && i < elemsCount) elems[i] = &script[off];
switch (script[off]) {
case OP_PUSHDATA1:
off++;
if (off + sizeof(uint8_t) <= scriptLen) len = script[off];
off += sizeof(uint8_t);
break;
case OP_PUSHDATA2:
off++;
if (off + sizeof(uint16_t) <= scriptLen) len = UInt16GetLE(&script[off]);
off += sizeof(uint16_t);
break;
case OP_PUSHDATA4:
off++;
if (off + sizeof(uint32_t) <= scriptLen) len = UInt32GetLE(&script[off]);
off += sizeof(uint32_t);
break;
default:
len = (script[off] > OP_PUSHDATA4) ? 0 : script[off];
off++;
break;
}
off += len;
i++;
}
return ((! elems || i <= elemsCount) && off == scriptLen) ? i : 0;
}
// given a data push script element, returns a pointer to the start of the data and writes its length to dataLen
const uint8_t *BRScriptData(const uint8_t *elem, size_t *dataLen) {
assert(elem != NULL);
assert(dataLen != NULL);
if (! elem || ! dataLen) return NULL;
switch (*elem) {
case OP_PUSHDATA1:
elem++;
*dataLen = *elem;
elem += sizeof(uint8_t);
break;
case OP_PUSHDATA2:
elem++;
*dataLen = UInt16GetLE(elem);
elem += sizeof(uint16_t);
break;
case OP_PUSHDATA4:
elem++;
*dataLen = UInt32GetLE(elem);
elem += sizeof(uint32_t);
break;
default:
*dataLen = (*elem > OP_PUSHDATA4) ? 0 : *elem;
elem++;
break;
}
return (*dataLen > 0) ? elem : NULL;
}
// writes a data push script element to script
// returns the number of bytes written, or scriptLen needed if script is NULL
size_t BRScriptPushData(uint8_t *script, size_t scriptLen, const uint8_t *data, size_t dataLen) {
size_t len = dataLen;
assert(data != NULL || dataLen == 0);
if (data == NULL && dataLen != 0) return 0;
if (dataLen < OP_PUSHDATA1) {
len += 1;
if (script && len <= scriptLen) script[0] = dataLen;
} else if (dataLen < UINT8_MAX) {
len += 1 + sizeof(uint8_t);
if (script && len <= scriptLen) {
script[0] = OP_PUSHDATA1;
script[1] = dataLen;
}
} else if (dataLen < UINT16_MAX) {
len += 1 + sizeof(uint16_t);
if (script && len <= scriptLen) {
script[0] = OP_PUSHDATA2;
UInt16SetLE(&script[1], dataLen);
}
} else {
len += 1 + sizeof(uint32_t);
if (script && len <= scriptLen) {
script[0] = OP_PUSHDATA4;
UInt32SetLE(&script[1], (uint32_t)dataLen);
}
}
if (script && len <= scriptLen) memcpy(script + len - dataLen, data, dataLen);
return (! script || len <= scriptLen) ? len : 0;
}
// returns a pointer to the 20byte pubkey-hash, or NULL if none
const uint8_t *BRScriptPKH(const uint8_t *script, size_t scriptLen) {
assert(script != NULL || scriptLen == 0);
if (! script || scriptLen == 0 || scriptLen > MAX_SCRIPT_LENGTH) return NULL;
const uint8_t *elems[BRScriptElements(NULL, 0, script, scriptLen)], *r = NULL;
size_t l, count = BRScriptElements(elems, sizeof(elems)/sizeof(*elems), script, scriptLen);
if (count == 5 && *elems[0] == OP_DUP && *elems[1] == OP_HASH160 && *elems[2] == 20 &&
*elems[3] == OP_EQUALVERIFY && *elems[4] == OP_CHECKSIG) {
r = BRScriptData(elems[2], &l); // pay-to-pubkey-hash
} else if (count == 3 && *elems[0] == OP_HASH160 && *elems[1] == 20 && *elems[2] == OP_EQUAL) {
r = BRScriptData(elems[1], &l); // pay-to-script-hash
} else if (count == 2 && (*elems[0] == OP_0 || (*elems[0] >= OP_1 && *elems[0] <= OP_16)) && *elems[1] == 20) {
r = BRScriptData(elems[1], &l); // pay-to-witness
}
return r;
}
// NOTE: It's important here to be permissive with scriptSig (spends) and strict with scriptPubKey (receives). If we
// miss a receive transaction, only that transaction's funds are missed, however if we accept a receive transaction that
// we are unable to correctly sign later, then the entire wallet balance after that point would become stuck with the
// current coin selection code
// writes the bitcoin address for a scriptPubKey to addr
// returns the number of bytes written, or addrLen needed if addr is NULL
size_t BRAddressFromScriptPubKey(char *addr, size_t addrLen, const uint8_t *script, size_t scriptLen) {
assert(script != NULL || scriptLen == 0);
if (! script || scriptLen == 0 || scriptLen > MAX_SCRIPT_LENGTH) return 0;
char a[91];
uint8_t data[21];
const uint8_t *d, *elems[BRScriptElements(NULL, 0, script, scriptLen)];
size_t r = 0, l = 0, count = BRScriptElements(elems, sizeof(elems)/sizeof(*elems), script, scriptLen);
if (count == 5 && *elems[0] == OP_DUP && *elems[1] == OP_HASH160 && *elems[2] == 20 &&
*elems[3] == OP_EQUALVERIFY && *elems[4] == OP_CHECKSIG) {
// pay-to-pubkey-hash scriptPubKey
data[0] = BITCOIN_PUBKEY_ADDRESS;
#if BITCOIN_TESTNET
data[0] = BITCOIN_PUBKEY_ADDRESS_TEST;
#endif
memcpy(&data[1], BRScriptData(elems[2], &l), 20);
r = BRBase58CheckEncode(addr, addrLen, data, 21);
} else if (count == 3 && *elems[0] == OP_HASH160 && *elems[1] == 20 && *elems[2] == OP_EQUAL) {
// pay-to-script-hash scriptPubKey
data[0] = BITCOIN_SCRIPT_ADDRESS;
#if BITCOIN_TESTNET
data[0] = BITCOIN_SCRIPT_ADDRESS_TEST;
#endif
memcpy(&data[1], BRScriptData(elems[1], &l), 20);
r = BRBase58CheckEncode(addr, addrLen, data, 21);
} else if (count == 2 && (*elems[0] == 65 || *elems[0] == 33) && *elems[1] == OP_CHECKSIG) {
// pay-to-pubkey scriptPubKey
data[0] = BITCOIN_PUBKEY_ADDRESS;
#if BITCOIN_TESTNET
data[0] = BITCOIN_PUBKEY_ADDRESS_TEST;
#endif
d = BRScriptData(elems[0], &l);
BRHash160(&data[1], d, l);
r = BRBase58CheckEncode(addr, addrLen, data, 21);
} else if (count == 2 && ((*elems[0] == OP_0 && (*elems[1] == 20 || *elems[1] == 32)) ||
(*elems[0] >= OP_1 && *elems[0] <= OP_16 && *elems[1] >= 2 && *elems[1] <= 40))) {
// pay-to-witness scriptPubKey
r = BRBech32Encode(a, "bc", script);
#if BITCOIN_TESTNET
r = BRBech32Encode(a, "tb", script);
#endif
if (addr && r > addrLen) r = 0;
if (addr) memcpy(addr, a, r);
}
return r;
}
// writes the bitcoin address for a scriptSig to addr
// returns the number of bytes written, or addrLen needed if addr is NULL
size_t BRAddressFromScriptSig(char *addr, size_t addrLen, const uint8_t *script, size_t scriptLen) {
assert(script != NULL || scriptLen == 0);
if (! script || scriptLen == 0 || scriptLen > MAX_SCRIPT_LENGTH) return 0;
uint8_t data[21];
const uint8_t *d = NULL, *elems[BRScriptElements(NULL, 0, script, scriptLen)];
size_t l = 0, count = BRScriptElements(elems, sizeof(elems)/sizeof(*elems), script, scriptLen);
data[0] = BITCOIN_PUBKEY_ADDRESS;
#if BITCOIN_TESTNET
data[0] = BITCOIN_PUBKEY_ADDRESS_TEST;
#endif
if (count >= 2 && *elems[count - 2] <= OP_PUSHDATA4 &&
(*elems[count - 1] == 65 || *elems[count - 1] == 33)) { // pay-to-pubkey-hash scriptSig
d = BRScriptData(elems[count - 1], &l);
if (l != 65 && l != 33) d = NULL;
if (d) BRHash160(&data[1], d, l);
} else if (count >= 2 && *elems[count - 2] <= OP_PUSHDATA4 && *elems[count - 1] <= OP_PUSHDATA4 &&
*elems[count - 1] > 0) { // pay-to-script-hash scriptSig
data[0] = BITCOIN_SCRIPT_ADDRESS;
#if BITCOIN_TESTNET
data[0] = BITCOIN_SCRIPT_ADDRESS_TEST;
#endif
d = BRScriptData(elems[count - 1], &l);
if (d) BRHash160(&data[1], d, l);
} else if (count >= 1 && *elems[count - 1] <= OP_PUSHDATA4 && *elems[count - 1] > 0) { // pay-to-pubkey scriptSig
// TODO: implement Peter Wullie's pubKey recovery from signature
}
// pay-to-witness scriptSig's are empty
return (d) ? BRBase58CheckEncode(addr, addrLen, data, 21) : 0;
}
// writes the bitcoin address for a witness to addr
// returns the number of bytes written, or addrLen needed if addr is NULL
size_t BRAddressFromWitness(char *addr, size_t addrLen, const uint8_t *witness, size_t witLen) {
return 0; // TODO: XXX implement
}
// writes the bech32 pay-to-witness-pubkey-hash address for a hash160 to addr
// returns the number of bytes written, or addrLen needed if addr is NULL
size_t BRAddressFromHash160(char *addr, size_t addrLen, const void *md20) {
uint8_t script[22] = { 0, 20 };
char a[91];
size_t r;
assert(md20 != NULL);
memcpy(&script[2], md20, 20);
r = BRBech32Encode(a, "bc", script);
#if BITCOIN_TESTNET
r = BRBech32Encode(a, "tb", script);
#endif
if (addr && r <= addrLen) memcpy(addr, a, r);
return (! addr || r <= addrLen) ? r : 0;
}
// writes the scriptPubKey for addr to script
// returns the number of bytes written, or scriptLen needed if script is NULL
size_t BRAddressScriptPubKey(uint8_t *script, size_t scriptLen, const char *addr) {
uint8_t data[42], pubkeyAddress = BITCOIN_PUBKEY_ADDRESS, scriptAddress = BITCOIN_SCRIPT_ADDRESS;
char hrp[84], *bech32Prefix = "bc";
size_t dataLen, r = 0;
assert(addr != NULL);
#if BITCOIN_TESTNET
pubkeyAddress = BITCOIN_PUBKEY_ADDRESS_TEST;
scriptAddress = BITCOIN_SCRIPT_ADDRESS_TEST;
bech32Prefix = "tb";
#endif
if (BRBase58CheckDecode(data, sizeof(data), addr) == 21) {
if (data[0] == pubkeyAddress) {
if (script && 25 <= scriptLen) {
script[0] = OP_DUP;
script[1] = OP_HASH160;
script[2] = 20;
memcpy(&script[3], &data[1], 20);
script[23] = OP_EQUALVERIFY;
script[24] = OP_CHECKSIG;
}
r = (! script || 25 <= scriptLen) ? 25 : 0;
} else if (data[0] == scriptAddress) {
if (script && 23 <= scriptLen) {
script[0] = OP_HASH160;
script[1] = 20;
memcpy(&script[2], &data[1], 20);
script[22] = OP_EQUAL;
}
r = (! script || 23 <= scriptLen) ? 23 : 0;
}
} else {
dataLen = BRBech32Decode(hrp, data, addr);
if (dataLen > 2 && strcmp(hrp, bech32Prefix) == 0 && (data[0] != OP_0 || data[1] == 20 || data[1] == 32)) {
if (script && dataLen <= scriptLen) memcpy(script, data, dataLen);
r = (! script || dataLen <= scriptLen) ? dataLen : 0;
}
}
return r;
}
// writes the 20 byte hash160 of addr to md20 and returns true on success
int BRAddressHash160(void *md20, const char *addr) {
char hrp[84];
uint8_t data[42];
int r = 0;
assert(md20 != NULL);
assert(addr != NULL);
r = (BRBase58CheckDecode(&data[1], sizeof(data) - 1, addr) == 21 || BRBech32Decode(hrp, data, addr) == 22);
if (r) memcpy(md20, &data[2], 20);
return r;
}
// returns true if addr is a valid bitcoin address
int BRAddressIsValid(const char *addr) {
uint8_t data[42];
char hrp[84];
int r = 0;
assert(addr != NULL);
if (BRBase58CheckDecode(data, sizeof(data), addr) == 21) {
r = (data[0] == BITCOIN_PUBKEY_ADDRESS || data[0] == BITCOIN_SCRIPT_ADDRESS);
#if BITCOIN_TESTNET
r = (data[0] == BITCOIN_PUBKEY_ADDRESS_TEST || data[0] == BITCOIN_SCRIPT_ADDRESS_TEST);
#endif
} else if (BRBech32Decode(hrp, data, addr) > 2) {
r = (strcmp(hrp, "bc") == 0 && (data[0] != OP_0 || data[1] == 20 || data[1] == 32));
#if BITCOIN_TESTNET
r = (strcmp(hrp, "tb") == 0 && (data[0] != OP_0 || data[1] == 20 || data[1] == 32));
#endif
}
return r;
}