// Copyright (c) 2009-2021 The Bitcoin Core developers // Distributed under the MIT software license, see the accompanying // file COPYING or http://www.opensource.org/licenses/mit-license.php. #include #include #include PartiallySignedTransaction::PartiallySignedTransaction(const CMutableTransaction& tx) : tx(tx) { inputs.resize(tx.vin.size()); outputs.resize(tx.vout.size()); } bool PartiallySignedTransaction::IsNull() const { return !tx && inputs.empty() && outputs.empty() && unknown.empty(); } bool PartiallySignedTransaction::Merge(const PartiallySignedTransaction& psbt) { // Prohibited to merge two PSBTs over different transactions if (tx->GetHash() != psbt.tx->GetHash()) { return false; } for (unsigned int i = 0; i < inputs.size(); ++i) { inputs[i].Merge(psbt.inputs[i]); } for (unsigned int i = 0; i < outputs.size(); ++i) { outputs[i].Merge(psbt.outputs[i]); } for (auto& xpub_pair : psbt.m_xpubs) { if (m_xpubs.count(xpub_pair.first) == 0) { m_xpubs[xpub_pair.first] = xpub_pair.second; } else { m_xpubs[xpub_pair.first].insert(xpub_pair.second.begin(), xpub_pair.second.end()); } } unknown.insert(psbt.unknown.begin(), psbt.unknown.end()); return true; } bool PartiallySignedTransaction::AddInput(const CTxIn& txin, PSBTInput& psbtin) { if (std::find(tx->vin.begin(), tx->vin.end(), txin) != tx->vin.end()) { return false; } tx->vin.push_back(txin); psbtin.partial_sigs.clear(); psbtin.final_script_sig.clear(); psbtin.final_script_witness.SetNull(); inputs.push_back(psbtin); return true; } bool PartiallySignedTransaction::AddOutput(const CTxOut& txout, const PSBTOutput& psbtout) { tx->vout.push_back(txout); outputs.push_back(psbtout); return true; } bool PartiallySignedTransaction::GetInputUTXO(CTxOut& utxo, int input_index) const { const PSBTInput& input = inputs[input_index]; uint32_t prevout_index = tx->vin[input_index].prevout.n; if (input.non_witness_utxo) { if (prevout_index >= input.non_witness_utxo->vout.size()) { return false; } if (input.non_witness_utxo->GetHash() != tx->vin[input_index].prevout.hash) { return false; } utxo = input.non_witness_utxo->vout[prevout_index]; } else if (!input.witness_utxo.IsNull()) { utxo = input.witness_utxo; } else { return false; } return true; } bool PSBTInput::IsNull() const { return !non_witness_utxo && witness_utxo.IsNull() && partial_sigs.empty() && unknown.empty() && hd_keypaths.empty() && redeem_script.empty() && witness_script.empty(); } void PSBTInput::FillSignatureData(SignatureData& sigdata) const { if (!final_script_sig.empty()) { sigdata.scriptSig = final_script_sig; sigdata.complete = true; } if (!final_script_witness.IsNull()) { sigdata.scriptWitness = final_script_witness; sigdata.complete = true; } if (sigdata.complete) { return; } sigdata.signatures.insert(partial_sigs.begin(), partial_sigs.end()); if (!redeem_script.empty()) { sigdata.redeem_script = redeem_script; } if (!witness_script.empty()) { sigdata.witness_script = witness_script; } for (const auto& key_pair : hd_keypaths) { sigdata.misc_pubkeys.emplace(key_pair.first.GetID(), key_pair); } if (!m_tap_key_sig.empty()) { sigdata.taproot_key_path_sig = m_tap_key_sig; } for (const auto& [pubkey_leaf, sig] : m_tap_script_sigs) { sigdata.taproot_script_sigs.emplace(pubkey_leaf, sig); } if (!m_tap_internal_key.IsNull()) { sigdata.tr_spenddata.internal_key = m_tap_internal_key; } if (!m_tap_merkle_root.IsNull()) { sigdata.tr_spenddata.merkle_root = m_tap_merkle_root; } for (const auto& [leaf_script, control_block] : m_tap_scripts) { sigdata.tr_spenddata.scripts.emplace(leaf_script, control_block); } for (const auto& [pubkey, leaf_origin] : m_tap_bip32_paths) { sigdata.taproot_misc_pubkeys.emplace(pubkey, leaf_origin); } } void PSBTInput::FromSignatureData(const SignatureData& sigdata) { if (sigdata.complete) { partial_sigs.clear(); hd_keypaths.clear(); redeem_script.clear(); witness_script.clear(); if (!sigdata.scriptSig.empty()) { final_script_sig = sigdata.scriptSig; } if (!sigdata.scriptWitness.IsNull()) { final_script_witness = sigdata.scriptWitness; } return; } partial_sigs.insert(sigdata.signatures.begin(), sigdata.signatures.end()); if (redeem_script.empty() && !sigdata.redeem_script.empty()) { redeem_script = sigdata.redeem_script; } if (witness_script.empty() && !sigdata.witness_script.empty()) { witness_script = sigdata.witness_script; } for (const auto& entry : sigdata.misc_pubkeys) { hd_keypaths.emplace(entry.second); } if (!sigdata.taproot_key_path_sig.empty()) { m_tap_key_sig = sigdata.taproot_key_path_sig; } for (const auto& [pubkey_leaf, sig] : sigdata.taproot_script_sigs) { m_tap_script_sigs.emplace(pubkey_leaf, sig); } if (!sigdata.tr_spenddata.internal_key.IsNull()) { m_tap_internal_key = sigdata.tr_spenddata.internal_key; } if (!sigdata.tr_spenddata.merkle_root.IsNull()) { m_tap_merkle_root = sigdata.tr_spenddata.merkle_root; } for (const auto& [leaf_script, control_block] : sigdata.tr_spenddata.scripts) { m_tap_scripts.emplace(leaf_script, control_block); } for (const auto& [pubkey, leaf_origin] : sigdata.taproot_misc_pubkeys) { m_tap_bip32_paths.emplace(pubkey, leaf_origin); } } void PSBTInput::Merge(const PSBTInput& input) { if (!non_witness_utxo && input.non_witness_utxo) non_witness_utxo = input.non_witness_utxo; if (witness_utxo.IsNull() && !input.witness_utxo.IsNull()) { // TODO: For segwit v1, we will want to clear out the non-witness utxo when setting a witness one. For v0 and non-segwit, this is not safe witness_utxo = input.witness_utxo; } partial_sigs.insert(input.partial_sigs.begin(), input.partial_sigs.end()); ripemd160_preimages.insert(input.ripemd160_preimages.begin(), input.ripemd160_preimages.end()); sha256_preimages.insert(input.sha256_preimages.begin(), input.sha256_preimages.end()); hash160_preimages.insert(input.hash160_preimages.begin(), input.hash160_preimages.end()); hash256_preimages.insert(input.hash256_preimages.begin(), input.hash256_preimages.end()); hd_keypaths.insert(input.hd_keypaths.begin(), input.hd_keypaths.end()); unknown.insert(input.unknown.begin(), input.unknown.end()); if (redeem_script.empty() && !input.redeem_script.empty()) redeem_script = input.redeem_script; if (witness_script.empty() && !input.witness_script.empty()) witness_script = input.witness_script; if (final_script_sig.empty() && !input.final_script_sig.empty()) final_script_sig = input.final_script_sig; if (final_script_witness.IsNull() && !input.final_script_witness.IsNull()) final_script_witness = input.final_script_witness; } void PSBTOutput::FillSignatureData(SignatureData& sigdata) const { if (!redeem_script.empty()) { sigdata.redeem_script = redeem_script; } if (!witness_script.empty()) { sigdata.witness_script = witness_script; } for (const auto& key_pair : hd_keypaths) { sigdata.misc_pubkeys.emplace(key_pair.first.GetID(), key_pair); } if (m_tap_tree.has_value() && m_tap_internal_key.IsFullyValid()) { TaprootSpendData spenddata = m_tap_tree->GetSpendData(); sigdata.tr_spenddata.internal_key = m_tap_internal_key; sigdata.tr_spenddata.Merge(spenddata); } for (const auto& [pubkey, leaf_origin] : m_tap_bip32_paths) { sigdata.taproot_misc_pubkeys.emplace(pubkey, leaf_origin); } } void PSBTOutput::FromSignatureData(const SignatureData& sigdata) { if (redeem_script.empty() && !sigdata.redeem_script.empty()) { redeem_script = sigdata.redeem_script; } if (witness_script.empty() && !sigdata.witness_script.empty()) { witness_script = sigdata.witness_script; } for (const auto& entry : sigdata.misc_pubkeys) { hd_keypaths.emplace(entry.second); } if (!sigdata.tr_spenddata.internal_key.IsNull()) { m_tap_internal_key = sigdata.tr_spenddata.internal_key; } if (sigdata.tr_builder.has_value()) { m_tap_tree = sigdata.tr_builder; } for (const auto& [pubkey, leaf_origin] : sigdata.taproot_misc_pubkeys) { m_tap_bip32_paths.emplace(pubkey, leaf_origin); } } bool PSBTOutput::IsNull() const { return redeem_script.empty() && witness_script.empty() && hd_keypaths.empty() && unknown.empty(); } void PSBTOutput::Merge(const PSBTOutput& output) { hd_keypaths.insert(output.hd_keypaths.begin(), output.hd_keypaths.end()); unknown.insert(output.unknown.begin(), output.unknown.end()); if (redeem_script.empty() && !output.redeem_script.empty()) redeem_script = output.redeem_script; if (witness_script.empty() && !output.witness_script.empty()) witness_script = output.witness_script; } bool PSBTInputSigned(const PSBTInput& input) { return !input.final_script_sig.empty() || !input.final_script_witness.IsNull(); } size_t CountPSBTUnsignedInputs(const PartiallySignedTransaction& psbt) { size_t count = 0; for (const auto& input : psbt.inputs) { if (!PSBTInputSigned(input)) { count++; } } return count; } void UpdatePSBTOutput(const SigningProvider& provider, PartiallySignedTransaction& psbt, int index) { CMutableTransaction& tx = *Assert(psbt.tx); const CTxOut& out = tx.vout.at(index); PSBTOutput& psbt_out = psbt.outputs.at(index); // Fill a SignatureData with output info SignatureData sigdata; psbt_out.FillSignatureData(sigdata); // Construct a would-be spend of this output, to update sigdata with. // Note that ProduceSignature is used to fill in metadata (not actual signatures), // so provider does not need to provide any private keys (it can be a HidingSigningProvider). MutableTransactionSignatureCreator creator(tx, /*input_idx=*/0, out.nValue, SIGHASH_ALL); ProduceSignature(provider, creator, out.scriptPubKey, sigdata); // Put redeem_script, witness_script, key paths, into PSBTOutput. psbt_out.FromSignatureData(sigdata); } PrecomputedTransactionData PrecomputePSBTData(const PartiallySignedTransaction& psbt) { const CMutableTransaction& tx = *psbt.tx; bool have_all_spent_outputs = true; std::vector utxos(tx.vin.size()); for (size_t idx = 0; idx < tx.vin.size(); ++idx) { if (!psbt.GetInputUTXO(utxos[idx], idx)) have_all_spent_outputs = false; } PrecomputedTransactionData txdata; if (have_all_spent_outputs) { txdata.Init(tx, std::move(utxos), true); } else { txdata.Init(tx, {}, true); } return txdata; } bool SignPSBTInput(const SigningProvider& provider, PartiallySignedTransaction& psbt, int index, const PrecomputedTransactionData* txdata, int sighash, SignatureData* out_sigdata, bool finalize) { PSBTInput& input = psbt.inputs.at(index); const CMutableTransaction& tx = *psbt.tx; if (PSBTInputSigned(input)) { return true; } // Fill SignatureData with input info SignatureData sigdata; input.FillSignatureData(sigdata); // Get UTXO bool require_witness_sig = false; CTxOut utxo; if (input.non_witness_utxo) { // If we're taking our information from a non-witness UTXO, verify that it matches the prevout. COutPoint prevout = tx.vin[index].prevout; if (prevout.n >= input.non_witness_utxo->vout.size()) { return false; } if (input.non_witness_utxo->GetHash() != prevout.hash) { return false; } utxo = input.non_witness_utxo->vout[prevout.n]; } else if (!input.witness_utxo.IsNull()) { utxo = input.witness_utxo; // When we're taking our information from a witness UTXO, we can't verify it is actually data from // the output being spent. This is safe in case a witness signature is produced (which includes this // information directly in the hash), but not for non-witness signatures. Remember that we require // a witness signature in this situation. require_witness_sig = true; } else { return false; } sigdata.witness = false; bool sig_complete; if (txdata == nullptr) { sig_complete = ProduceSignature(provider, DUMMY_SIGNATURE_CREATOR, utxo.scriptPubKey, sigdata); } else { MutableTransactionSignatureCreator creator(tx, index, utxo.nValue, txdata, sighash); sig_complete = ProduceSignature(provider, creator, utxo.scriptPubKey, sigdata); } // Verify that a witness signature was produced in case one was required. if (require_witness_sig && !sigdata.witness) return false; // If we are not finalizing, set sigdata.complete to false to not set the scriptWitness if (!finalize && sigdata.complete) sigdata.complete = false; input.FromSignatureData(sigdata); // If we have a witness signature, put a witness UTXO. // TODO: For segwit v1, we should remove the non_witness_utxo if (sigdata.witness) { input.witness_utxo = utxo; // input.non_witness_utxo = nullptr; } // Fill in the missing info if (out_sigdata) { out_sigdata->missing_pubkeys = sigdata.missing_pubkeys; out_sigdata->missing_sigs = sigdata.missing_sigs; out_sigdata->missing_redeem_script = sigdata.missing_redeem_script; out_sigdata->missing_witness_script = sigdata.missing_witness_script; } return sig_complete; } bool FinalizePSBT(PartiallySignedTransaction& psbtx) { // Finalize input signatures -- in case we have partial signatures that add up to a complete // signature, but have not combined them yet (e.g. because the combiner that created this // PartiallySignedTransaction did not understand them), this will combine them into a final // script. bool complete = true; const PrecomputedTransactionData txdata = PrecomputePSBTData(psbtx); for (unsigned int i = 0; i < psbtx.tx->vin.size(); ++i) { complete &= SignPSBTInput(DUMMY_SIGNING_PROVIDER, psbtx, i, &txdata, SIGHASH_ALL, nullptr, true); } return complete; } bool FinalizeAndExtractPSBT(PartiallySignedTransaction& psbtx, CMutableTransaction& result) { // It's not safe to extract a PSBT that isn't finalized, and there's no easy way to check // whether a PSBT is finalized without finalizing it, so we just do this. if (!FinalizePSBT(psbtx)) { return false; } result = *psbtx.tx; for (unsigned int i = 0; i < result.vin.size(); ++i) { result.vin[i].scriptSig = psbtx.inputs[i].final_script_sig; result.vin[i].scriptWitness = psbtx.inputs[i].final_script_witness; } return true; } TransactionError CombinePSBTs(PartiallySignedTransaction& out, const std::vector& psbtxs) { out = psbtxs[0]; // Copy the first one // Merge for (auto it = std::next(psbtxs.begin()); it != psbtxs.end(); ++it) { if (!out.Merge(*it)) { return TransactionError::PSBT_MISMATCH; } } return TransactionError::OK; } std::string PSBTRoleName(PSBTRole role) { switch (role) { case PSBTRole::CREATOR: return "creator"; case PSBTRole::UPDATER: return "updater"; case PSBTRole::SIGNER: return "signer"; case PSBTRole::FINALIZER: return "finalizer"; case PSBTRole::EXTRACTOR: return "extractor"; // no default case, so the compiler can warn about missing cases } assert(false); } bool DecodeBase64PSBT(PartiallySignedTransaction& psbt, const std::string& base64_tx, std::string& error) { auto tx_data = DecodeBase64(base64_tx); if (!tx_data) { error = "invalid base64"; return false; } return DecodeRawPSBT(psbt, MakeByteSpan(*tx_data), error); } bool DecodeRawPSBT(PartiallySignedTransaction& psbt, Span tx_data, std::string& error) { CDataStream ss_data(tx_data, SER_NETWORK, PROTOCOL_VERSION); try { ss_data >> psbt; if (!ss_data.empty()) { error = "extra data after PSBT"; return false; } } catch (const std::exception& e) { error = e.what(); return false; } return true; } uint32_t PartiallySignedTransaction::GetVersion() const { if (m_version != std::nullopt) { return *m_version; } return 0; }