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tap.cpp
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tap.cpp
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#include <cstdio>
#include <unistd.h>
#include <inttypes.h>
#include <secp256k1.h>
#include <secp256k1_schnorrsig.h>
#include <secp256k1_recovery.h>
#include <support/allocators/secure.h>
#include <tinyformat.h>
#include <cliargs.h>
#include <value.h>
#include <instance.h>
#include <functions.h>
// #include <config/bitcoin-config.h>
#include <debugger/version.h>
#include <hash.h>
#define abort(msg...) do { fprintf(stderr, msg); fputc('\n', stderr); exit(1); } while(0)
#define HEXC(v) HexStr(v).c_str()
extern secp256k1_context* secp256k1_context_sign;
void ECC_Start();
void ECC_Stop();
static const HashWriter HasherTapSighash = TaggedHash("TapSighash");
static const HashWriter HasherTapLeaf = TaggedHash("TapLeaf");
static const HashWriter HasherTapBranch = TaggedHash("TapBranch");
static const HashWriter HasherTapTweak = TaggedHash("TapTweak");
constexpr const char* DEFAULT_ADDR_PREFIX = "bcrt";
typedef std::vector<uint8_t> Item;
static Item PLACEHOLDER_SIGNATURE = ParseHex("000102030405060708090a0b0c0d0e0f000102030405060708090a0b0c0d0e0f000102030405060708090a0b0c0d0e0f000102030405060708090a0b0c0d0e0f");
bool quiet = false;
bool pipe_in = false; // xxx | btcdeb
bool pipe_out = false; // btcdeb xxx > file
inline bool checkenv(const std::string& flag, bool fallback = false) {
const auto& v = std::getenv(flag.c_str());
return v ? strcmp("0", v) : fallback;
}
struct TapNode {
size_t m_index;
uint256 m_hash;
TapNode* m_parent{nullptr};
TapNode(size_t index) : m_index(index) {}
virtual ~TapNode() {}
virtual std::string ToString() const { return strprintf("#%zu", m_index); }
virtual void Prove(const TapNode* child, Item& proof) const {
abort("this node type cannot make proofs");
}
};
struct TapBranch : public TapNode {
TapNode* m_l;
TapNode* m_r;
size_t m_index_r;
virtual ~TapBranch() {
if (m_l) delete m_l;
if (m_r) delete m_r;
}
virtual std::string ToString() const override { return strprintf("(%s, %s)", m_l->ToString(), m_r->ToString()); }
TapBranch(TapNode* l, TapNode* r) : TapNode(l->m_index), m_l(l), m_r(r), m_index_r(r->m_index) {
if (l->m_parent) abort("left node has a parent already");
if (r->m_parent) abort("right node has a parent already");
l->m_parent = r->m_parent = this;
auto hasher = HasherTapBranch;
auto h_l = m_l->m_hash;
auto h_r = m_r->m_hash;
if (std::lexicographical_compare(h_r.begin(), h_r.end(), h_l.begin(), h_l.end())) {
auto tmp = h_l; h_l = h_r; h_r = tmp;
}
hasher << h_l << h_r;
m_hash = hasher.GetSHA256();
}
virtual void Prove(const TapNode* child, Item& proof) const override {
uint256 hash;
if (child == m_l) {
hash = m_r->m_hash;
} else if (child == m_r) {
hash = m_l->m_hash;
} else abort("TapBranch::Prove failed to prove missing child %s (this branch has %s and %s)\n", child->ToString().c_str(), m_l->ToString().c_str(), m_r->ToString().c_str());
proof.insert(proof.end(), hash.begin(), hash.end());
if (m_parent) m_parent->Prove(this, proof);
}
};
struct TapLeaf : public TapNode {
TapLeaf(size_t index, const uint256& hash) : TapNode(index) { m_hash = hash; }
TapLeaf(size_t index, const CScript& script) : TapNode(index) {
auto hasher = HasherTapLeaf;
hasher << static_cast<uint8_t>(0xc0) << script;
m_hash = hasher.GetSHA256();
}
};
int main(int argc, char* const* argv)
{
ECC_Start();
pipe_in = !isatty(fileno(stdin)) || std::getenv("DEBUG_SET_PIPE_IN");
pipe_out = !isatty(fileno(stdout)) || std::getenv("DEBUG_SET_PIPE_OUT");
if (pipe_in || pipe_out) btc_logf = btc_logf_dummy;
cliargs ca;
ca.add_option("help", 'h', no_arg);
ca.add_option("quiet", 'q', no_arg);
ca.add_option("version", 'v', no_arg);
ca.add_option("addrprefix", 'p', req_arg);
ca.add_option("tx", 'x', req_arg);
ca.add_option("txin", 'i', req_arg);
ca.add_option("privkey", 'k', req_arg);
ca.add_option("sig", 's', req_arg);
ca.parse(argc, argv);
quiet = ca.m.count('q') || pipe_in || pipe_out;
if (quiet) btc_logf = btc_logf_dummy;
if (ca.m.count('v')) {
printf("tap (\"The Bitcoin Debugger Taproot Utility\") " VERSION() "\n");
return 0;
} else if (ca.m.count('h') || ca.l.size() < 3) {
fprintf(stderr, "Syntax: %s [-v|--version] [-q|--quiet] [--addrprefix=tb|-ptb] [--tx=<hex>|-x<hex>] [--txin=<hex>|-i<hex>] [--privkey=<key>|-k<key>] [--sig=<hex>|-s<hex>] <internal_pubkey> <script_count> <script1> <script2> ... [<spend index or sig> [<spend arg1> [<spend arg2> [...]]]]\n", argv[0]);
fprintf(stderr, "If spend index and args are omitted, and no transaction data is provided, this generates a tweaked pubkey for funding.\n");
fprintf(stderr, "If spend index and args are omitted, but transaction data is provided, this generates witness data for a Taproot spend and inserts this into the spending transaction.\n");
fprintf(stderr, "If spend index and args are included, this generates the spending witness based on the given input.\n");
fprintf(stderr, "If spend index, args, and transaction data are all included, the spending witness is inserted into the transaction.\n");
fprintf(stderr, "A signature is generated if --privkey is given. If a signature is provided via the --sig argument, it is used as is.\n");
fprintf(stderr, "The address prefix refers to the bech32m human readable part; this defaults to '%s'\n", DEFAULT_ADDR_PREFIX);
return 0;
}
btc_logf("tap " VERSION() " -- type `%s -h` for help\n", argv[0]);
fprintf(stderr, "WARNING: This is experimental software. Do not use this with real bitcoin, or you will most likely lose them all. You have been w a r n e d.\n");
if (!pipe_in) {
// temporarily defaulting all to ON
if (checkenv("DEBUG_SIGHASH")) btc_sighash_logf = btc_logf_stderr;
if (checkenv("DEBUG_SIGNING", true)) btc_sign_logf = btc_logf_stderr;
if (checkenv("DEBUG_SEGWIT", true)) btc_segwit_logf = btc_logf_stderr;
if (checkenv("DEBUG_TAPROOT", true)) btc_taproot_logf = btc_logf_stderr;
btc_logf("LOG:");
if (btc_enabled(btc_sighash_logf)) btc_logf(" sighash");
if (btc_enabled(btc_sign_logf)) btc_logf(" sign");
if (btc_enabled(btc_segwit_logf)) btc_logf(" segwit");
if (btc_enabled(btc_taproot_logf)) btc_logf(" taproot");
btc_logf("\n");
}
Item premade_sig;
Item privkey;
secp256k1_keypair keypair;
bech32_hrp = ca.m.count('p') ? ca.m['p'] : DEFAULT_ADDR_PREFIX;
bool have_txs = false;
if (ca.m.count('x') + ca.m.count('i') == 1) abort("provide either both --txin and --tx, or neither");
if (ca.m.count('x')) {
have_txs = true;
if (!instance.parse_transaction(ca.m['x'].c_str(), false)) {
abort("failed to parse transaction");
}
if (!instance.parse_input_transaction(ca.m['i'].c_str())) {
abort("failed to parse input transaction");
}
btc_logf("targeting transaction vin at index #%lld\n", instance.txin_index);
}
if (ca.m.count('k')) {
#if ENABLE_DANGEROUS
Value wif(ca.m['k'].c_str());
if (wif.type == Value::T_STRING) {
// WIF encoding?
wif.do_decode_wif();
}
if (wif.type != Value::T_DATA) {
abort("failed to parse private key (not raw data, and not WIF encoded): %s", ca.m['k'].c_str());
}
privkey = wif.data;
if (privkey.size() != 32) {
abort("invalid private key (wrong size: %zu, must be 32)", privkey.size());
}
if (!secp256k1_keypair_create(secp256k1_context_sign, &keypair, privkey.data())) {
abort("failed to derive keypair from private key");
}
#else
abort("this feature requires that you compile with --enable-dangerous set; either provide a signature yourself, or recompile tap");
#endif
}
if (ca.m.count('s')) {
if (!TryHex(ca.m['s'], premade_sig)) {
abort("failed to parse signature: %s", ca.m['s'].c_str());
}
if (privkey.size()) abort("cannot use --privkey and --sig simultaneously");
}
std::string internal_pubkey_str = ca.l[0];
Item internal_pubkey;
if (!TryHex(internal_pubkey_str, internal_pubkey)) {
abort("invalid internal pubkey %s: not parsable hex value", internal_pubkey_str.c_str());
}
if (internal_pubkey.size() != 32) {
abort("invalid internal pubkey %s -> %s: length %zu invalid (must be 32 bytes)", internal_pubkey_str.c_str(), HEXC(internal_pubkey), internal_pubkey.size());
}
btc_logf("Internal pubkey: %s\n", HEXC(internal_pubkey));
uint256 internal_pubkey_u256 = uint256(internal_pubkey);
size_t script_count = atol(ca.l[1]);
if (script_count < 1 || script_count > 1024) {
abort("invalid script count: %zu (allowed range 1..1024)", script_count);
}
if (ca.l.size() < 2 + script_count) {
abort("missing scripts (count %zu but only %zu arguments)", script_count, ca.l.size() - 2);
}
size_t sai = 2 + script_count;
size_t sargc = sai < ca.l.size() ? ca.l.size() - sai : 0;
size_t spending_index = (size_t)-1;
bool is_taproot = false, is_tapscript = false;
std::vector<Item> taproot_input_stack; // ScriptWitness variant
CScript taproot_inputs; // manual variant
size_t witness_stack_count = 0;
if (have_txs && sargc == 0) {
btc_logf("- no spend arguments; TAPROOT mode\n");
is_taproot = true;
}
if (sargc > 0) {
btc_logf("%zu spending argument%s present\n", sargc, sargc == 1 ? "" : "s");
// spend mode -- if 1 single argument, it's taproot, and the argument is the signature
btc_logf("- 1+ spend arguments; TAPSCRIPT mode\n");
is_tapscript = true;
spending_index = atol(ca.l[sai++]);
if (spending_index >= script_count) {
abort("invalid script index: %zu must be within range [0..%zu]\n", spending_index, script_count = 1);
}
while (sai < ca.l.size()) {
if (std::string(ca.l[sai]) == "%SIG%") {
taproot_input_stack.push_back(PLACEHOLDER_SIGNATURE);
taproot_inputs << PLACEHOLDER_SIGNATURE;
btc_logf(" #%zu: <placeholder signature>\n", witness_stack_count);
} else {
auto v = Value(ca.l[sai]).data_value();
taproot_input_stack.push_back(v);
taproot_inputs << v;
btc_logf(" #%zu: %s\n", witness_stack_count, HEXC(v));
}
++sai;
++witness_stack_count;
}
}
std::vector<CScript> scripts;
btc_logf("%zu scripts:\n", script_count);
for (size_t i = 0; i < script_count; ++i) {
Item scriptData = Value(ca.l[2 + i]).data_value();
CScript script = CScript(scriptData.begin(), scriptData.end());
if (!script.HasValidOps()) {
abort("invalid script #%zu: %s", i, HEXC(scriptData));
}
if (!quiet) {
btc_logf("- #%zu: %s\n", i, HEXC(script));
}
scripts.emplace_back(script);
}
// if we are doing a tapscript spend, we can add the program now that we know it
Item spending_script;
if (is_tapscript) {
spending_script = Item(scripts[spending_index].begin(), scripts[spending_index].end());
}
// generate tapscript commitment (always)
std::vector<TapNode*> branches;
TapLeaf* pending = nullptr;
TapLeaf* spending_leaf = nullptr;
for (size_t i = 0; i < script_count; ++i) {
TapLeaf* leaf = new TapLeaf(i, scripts[i]);
btc_logf("Script #%zu leaf hash = TapLeaf<<0xc0 || %s>>\n → %s\n", i, HexStr(scripts[i]).c_str(), HexStr(leaf->m_hash).c_str());
if (is_tapscript && i == spending_index) spending_leaf = leaf;
if (pending) {
// we've got a pair
branches.push_back(new TapBranch(pending, leaf));
btc_logf("Branch (%s, #%zu)\n → %s\n", pending->ToString().c_str(), i, HexStr(branches.back()->m_hash).c_str());
pending = nullptr;
} else {
pending = leaf;
}
}
if (pending) {
if (branches.size() == 0) {
branches.push_back(pending);
} else {
// we have [a,b] [c,d] and pending e
// we extend [c,d] to be [[c,d], e]
TapNode* rightmost = branches.back();
branches.pop_back();
branches.push_back(new TapBranch(rightmost, pending));
btc_logf("Leftover node %s baked into right-most (last) tree %s\n → %s\n", pending->ToString().c_str(), rightmost->ToString().c_str(), HexStr(branches.back()->m_hash).c_str());
}
pending = nullptr;
}
// now we pair things together until we have a root node
while (branches.size() > 1) {
// iterate
for (size_t i = 0; i < branches.size() - 1; ++i) {
TapNode* l = branches[i];
TapNode* r = branches[i + 1];
branches.erase(branches.begin() + i);
branches[i] = new TapBranch(l, r);
btc_logf("Merged at #%zu: %s and %s = %s\n → %s\n", i, l->ToString().c_str(), r->ToString().c_str(), branches[i]->ToString().c_str(), HexStr(branches[i]->m_hash).c_str());
}
}
if (branches.size() != 1) {
abort("Unable to generate tapscript commitment tree (branch size did not end up at 1, it is %zu)", branches.size());
}
// control block (if spending) -- note that we put the leaf version and negation bit in last, as we don't know if the pubkey was negated yet
Item ctl = internal_pubkey;
if (is_tapscript) {
btc_logf("Control object = (leaf), (internal pubkey = %s), ...\n", HEXC(internal_pubkey));
if (!spending_leaf) {
abort("Internal error: Spending leaf was not derived (this is a bug; please report)");
}
if (spending_leaf->m_parent) {
spending_leaf->m_parent->Prove(spending_leaf, ctl);
}
btc_logf("... with proof -> %s\n", HEXC(ctl));
}
// now TapTweak <pubkey> <root>
TapNode* root = branches[0];
auto hasher = HasherTapTweak;
hasher << internal_pubkey_u256 << root->m_hash;
auto tweak = hasher.GetSHA256();
btc_logf("Tweak value = TapTweak(%s || %s) = %s\n", HEXC(internal_pubkey_u256), HEXC(root->m_hash), HEXC(tweak));
// now tweak the pubkey
secp256k1_xonly_pubkey pubkey;
if (!secp256k1_xonly_pubkey_parse(secp256k1_context_sign, &pubkey, internal_pubkey.data())) {
abort("invalid input: pubkey invalid (parse failed)");
}
// int is_negated;
secp256k1_pubkey tweaked_pubkey;
if (!secp256k1_xonly_pubkey_tweak_add(secp256k1_context_sign, &tweaked_pubkey, &pubkey, tweak.begin())) {
abort("failure: secp256k1_xonly_pubkey_tweak_add call failed");
}
Item serialized_pk;
serialized_pk.resize(33);
size_t len = 33;
if (!secp256k1_ec_pubkey_serialize(secp256k1_context_sign, serialized_pk.data(), &len, &tweaked_pubkey, SECP256K1_EC_COMPRESSED)) {
// if (!secp256k1_xonly_pubkey_serialize(secp256k1_context_sign, serialized_pk.data(), &pubkey)) {
abort("failed to serialize pubkey");
}
int is_even = serialized_pk[0] == 0x02;
serialized_pk.erase(serialized_pk.begin(), serialized_pk.begin() + 1);
btc_logf("Tweaked pubkey = %s (%seven)\n", HEXC(serialized_pk), is_even ? "" : "not ");
// if we have a txin, we can now verify that our pubkey matches the pubkey in the output
if (have_txs) {
auto spk = instance.txin->vout[instance.txin_vout_index].scriptPubKey;
if (spk.size() < serialized_pk.size()) {
abort("pubkey mismatch: input transaction's vout[%" PRId64 "].scriptPubKey = %s, but our pubkey = %s\n", instance.txin_vout_index, HEXC(spk), HEXC(serialized_pk));
}
auto cmp = Item(spk.end() - serialized_pk.size(), spk.end());
if (cmp != serialized_pk) {
abort("pubkey mismatch: input transaction's vout[%" PRId64 "].scriptPubKey %s does not end (%s) with our pubkey %s\n", instance.txin_vout_index, HEXC(spk), HEXC(cmp), HEXC(serialized_pk));
}
btc_logf("Pubkey matches the scriptPubKey of the input transaction's output #%lld\n", instance.txin_vout_index);
}
Value v(serialized_pk);
v.do_bech32menc();
printf("Resulting Bech32m address: %s\n", v.str_value().c_str());
#if ENABLE_DANGEROUS
if (is_taproot && privkey.size() != 0) {
if (!secp256k1_keypair_xonly_tweak_add(secp256k1_context_sign, &keypair, tweak.begin())) {
abort("failure: secp256k1_keypair_xonly_tweak_add call failed");
}
// warning: not officially supported API (ab)use
memcpy(privkey.data(), keypair.data, 32);
if (!secp256k1_keypair_create(secp256k1_context_sign, &keypair, privkey.data())) {
abort("failure: could not re-create keypair from tweaked privkey");
}
btc_logf("tweaked privkey -> %s\n", HEXC(privkey));
Value v(privkey);
v.do_get_xpubkey();
if (v.data_value() != serialized_pk) {
abort("the provided private key has a corresponding public key %s\nhowever, the tweaked public key for this output is %s", HEXC(v.data), HEXC(serialized_pk));
}
btc_logf("The given private key matches the tweaked public key\n");
}
#endif
if (is_tapscript) {
// we can now finally put in the leaf/negation bit in the control object
uint8_t ctl_ln = is_even ? 0xc0 : 0xc1;
ctl.insert(ctl.begin(), &ctl_ln, &ctl_ln + 1);
btc_logf("Final control object = %s\n", HEXC(ctl));
}
// if we have transaction data, replace the witness stack for the appropriate input
if (have_txs) {
if (premade_sig.size()) {
// insert signature
taproot_input_stack.insert(taproot_input_stack.begin(), premade_sig);
} else if (privkey.size() == 0) {
// append a placeholder sig to the witness stack, or the instance system won't recognize the output type
taproot_input_stack.insert(taproot_input_stack.begin(), PLACEHOLDER_SIGNATURE);
}
if (is_tapscript) {
// append script to taproot inputs
taproot_input_stack.push_back(spending_script);
taproot_inputs << spending_script;
btc_logf("Adding selected script to taproot inputs: %s\n → %s\n", HEXC(scripts[spending_index]), HEXC(taproot_inputs));
++witness_stack_count;
// append control object
btc_logf("appending control object to taproot input stack: %s\n", HEXC(ctl));
taproot_input_stack.push_back(ctl);
taproot_inputs << ctl;
++witness_stack_count;
btc_logf("Tapscript spending witness: [\n");
for (auto& x : taproot_input_stack) btc_logf(" \"%s\",\n", HEXC(x));
btc_logf("]\n");
}
CMutableTransaction mtx(*instance.tx);
mtx.vin[instance.txin_index].scriptWitness.stack = taproot_input_stack;
if (taproot_input_stack.size() == 0) {
// we need *something* or the uses_bip341 flag will not be set when getting sighash
mtx.vin[instance.txin_index].scriptWitness.stack.push_back(std::vector<uint8_t>());
}
instance.tx = MakeTransactionRef(mtx);
instance.configure_tx_txin();
instance.execdata.m_codeseparator_pos = 0xFFFFFFFFUL;
instance.execdata.m_codeseparator_pos_init = true;
const uint256 sighash = instance.calc_sighash();
btc_logf("sighash (little endian) = %s\n", HEXC(sighash));
if (privkey.size()) {
Item sig;
sig.resize(64);
secp256k1_xonly_pubkey pubkey;
int pk_parity; // formerly 'is_negative'
if (!secp256k1_keypair_xonly_pub(secp256k1_context_sign, &pubkey, &pk_parity, &keypair)) {
// if (!secp256k1_xonly_pubkey_create(secp256k1_context_sign, &pubkey, privkey.data())) {
abort("failed to derive pubkey");
}
if (!secp256k1_schnorrsig_sign32(secp256k1_context_sign, sig.data(), sighash.begin(), &keypair, NULL)) {
abort("failed to create signature");
}
if (!secp256k1_schnorrsig_verify(secp256k1_context_sign, sig.data(), sighash.begin(), 32, &pubkey)) {
abort("failed to verify signature");
}
uint256 pk;
if (!secp256k1_xonly_pubkey_serialize(secp256k1_context_sign, pk.begin(), &pubkey)) assert(0);
btc_logf("sighash: %s\n", HEXC(sighash));
btc_logf("privkey: %s\n", HEXC(privkey));
btc_logf("pubkey: %s\n", HEXC(pk));
btc_logf("signature: %s\n", HEXC(sig));
taproot_input_stack.insert(taproot_input_stack.begin(), sig);
mtx.vin[instance.txin_index].scriptWitness.stack = taproot_input_stack;
instance.tx = MakeTransactionRef(mtx);
} else if (premade_sig.size() == 0) {
printf("NOTE: there is a placeholder signature at the end of the witness data for the resulting transaction below; this must be replaced with a 64 byte signature for the sighash given above\n");
}
mtx.vin[instance.txin_index].scriptWitness.stack = taproot_input_stack;
instance.tx = MakeTransactionRef(mtx);
CDataStream ssTx(SER_NETWORK, PROTOCOL_VERSION);
ssTx << *instance.tx;
printf("Resulting transaction: %s\n", HEXC(ssTx));
}
ECC_Stop();
}
static void GetRandBytes(unsigned char* buf, int num)
{
// TODO: Make this more cross platform
FILE* f = fopen("/dev/urandom", "rb");
if (!f) {
abort("unable to open /dev/urandom for GetRandBytes(): sorry! btcdeb does not currently work on your operating system for signature signing\n");
exit(1);
}
if (fread(buf, 1, num, f) != num) {
abort("unable to read from /dev/urandom\n");
exit(1);
}
fclose(f);
}