Exemplo n.º 1
0
def is_any_tx_output_on_change_branch(tx: Transaction):
    if not tx.output_info:
        return False
    for o in tx.outputs():
        info = tx.output_info.get(o.address)
        if info is not None:
            if info.address_index[0] == 1:
                return True
    return False
Exemplo n.º 2
0
def is_any_tx_output_on_change_branch(tx: Transaction):
    if not tx.output_info:
        return False
    for o in tx.outputs():
        info = tx.output_info.get(o.address)
        if info is not None:
            if info.address_index[0] == 1:
                return True
    return False
Exemplo n.º 3
0
    def build_psbt(self, tx: Transaction, wallet=None, xfp=None):
        # Render a PSBT file, for upload to Coldcard.
        # 
        if xfp is None:
            # need fingerprint of MASTER xpub, not the derived key
            xfp = self.ckcc_xfp

        inputs = tx.inputs()

        if 'prev_tx' not in inputs[0]:
            # fetch info about inputs, if needed?
            # - needed during export PSBT flow, not normal online signing
            assert wallet, 'need wallet reference'
            wallet.add_hw_info(tx)

        # wallet.add_hw_info installs this attr
        assert tx.output_info is not None, 'need data about outputs'

        # Build map of pubkey needed as derivation from master, in PSBT binary format
        # 1) binary version of the common subpath for all keys
        #       m/ => fingerprint LE32
        #       a/b/c => ints
        base_path = pack('<I', xfp)
        for x in self.get_derivation()[2:].split('/'):
            if x.endswith("'"):
                x = int(x[:-1]) | 0x80000000
            else:
                x = int(x)
            base_path += pack('<I', x)

        # 2) all used keys in transaction
        subkeys = {}
        derivations = self.get_tx_derivations(tx)
        for xpubkey in derivations:
            pubkey = xpubkey_to_pubkey(xpubkey)

            # assuming depth two, non-harded: change + index
            aa, bb = derivations[xpubkey]
            assert 0 <= aa < 0x80000000
            assert 0 <= bb < 0x80000000

            subkeys[bfh(pubkey)] = base_path + pack('<II', aa, bb)
            
        for txin in inputs:
            if txin['type'] == 'coinbase':
                self.give_error("Coinbase not supported")

            if txin['type'] in ['p2sh', 'p2wsh-p2sh', 'p2wsh']:
                self.give_error('No support yet for inputs of type: ' + txin['type'])

        # Construct PSBT from start to finish.
        out_fd = io.BytesIO()
        out_fd.write(b'psbt\xff')

        def write_kv(ktype, val, key=b''):
            # serialize helper: write w/ size and key byte
            out_fd.write(my_var_int(1 + len(key)))
            out_fd.write(bytes([ktype]) + key)

            if isinstance(val, str):
                val = bfh(val)

            out_fd.write(my_var_int(len(val)))
            out_fd.write(val)


        # global section: just the unsigned txn
        class CustomTXSerialization(Transaction):
            @classmethod
            def input_script(cls, txin, estimate_size=False):
                return ''

        unsigned = bfh(CustomTXSerialization(tx.serialize()).serialize_to_network(witness=False))
        write_kv(PSBT_GLOBAL_UNSIGNED_TX, unsigned)

        # end globals section
        out_fd.write(b'\x00')

        # inputs section
        for txin in inputs:
            if Transaction.is_segwit_input(txin):
                utxo = txin['prev_tx'].outputs()[txin['prevout_n']]
                spendable = txin['prev_tx'].serialize_output(utxo)
                write_kv(PSBT_IN_WITNESS_UTXO, spendable)
            else:
                write_kv(PSBT_IN_NON_WITNESS_UTXO, str(txin['prev_tx']))

            pubkeys, x_pubkeys = tx.get_sorted_pubkeys(txin)

            pubkeys = [bfh(k) for k in pubkeys]

            for k in pubkeys:
                write_kv(PSBT_IN_BIP32_DERIVATION, subkeys[k], k)

                if txin['type'] == 'p2wpkh-p2sh':
                    assert len(pubkeys) == 1, 'can be only one redeem script per input'
                    pa = hash_160(k)
                    assert len(pa) == 20
                    write_kv(PSBT_IN_REDEEM_SCRIPT, b'\x00\x14'+pa)

            out_fd.write(b'\x00')

        # outputs section
        for o in tx.outputs():
            # can be empty, but must be present, and helpful to show change inputs
            # wallet.add_hw_info() adds some data about change outputs into tx.output_info
            if o.address in tx.output_info:
                # this address "is_mine" but might not be change (I like to sent to myself)
                output_info = tx.output_info.get(o.address)
                index, xpubs = output_info.address_index, output_info.sorted_xpubs

                if index[0] == 1 and len(index) == 2:
                    # it is a change output (based on our standard derivation path)
                    assert len(xpubs) == 1      # not expecting multisig
                    xpubkey = xpubs[0]

                    # document its bip32 derivation in output section
                    aa, bb = index
                    assert 0 <= aa < 0x80000000
                    assert 0 <= bb < 0x80000000

                    deriv = base_path + pack('<II', aa, bb)
                    pubkey = bfh(self.get_pubkey_from_xpub(xpubkey, index))

                    write_kv(PSBT_OUT_BIP32_DERIVATION, deriv, pubkey)

                    if output_info.script_type == 'p2wpkh-p2sh':
                        pa = hash_160(pubkey)
                        assert len(pa) == 20
                        write_kv(PSBT_OUT_REDEEM_SCRIPT, b'\x00\x14' + pa)

            out_fd.write(b'\x00')

        return out_fd.getvalue()