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feature_taproot.py
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feature_taproot.py
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#!/usr/bin/env python3
# Copyright (c) 2019-2022 The Bitcoin Core developers
# Distributed under the MIT software license, see the accompanying
# file COPYING or http://www.opensource.org/licenses/mit-license.php.
# Test Taproot softfork (BIPs 340-342)
from test_framework.blocktools import (
COINBASE_MATURITY,
create_coinbase,
create_block,
add_witness_commitment,
MAX_BLOCK_SIGOPS_WEIGHT,
)
from test_framework.messages import (
COutPoint,
CTransaction,
CTxIn,
CTxInWitness,
CTxOut,
SEQUENCE_FINAL,
tx_from_hex,
WITNESS_SCALE_FACTOR,
)
from test_framework.script import (
ANNEX_TAG,
BIP341_sha_amounts,
BIP341_sha_outputs,
BIP341_sha_prevouts,
BIP341_sha_scriptpubkeys,
BIP341_sha_sequences,
CScript,
CScriptNum,
CScriptOp,
hash256,
LEAF_VERSION_TAPSCRIPT,
LegacySignatureMsg,
LOCKTIME_THRESHOLD,
MAX_SCRIPT_ELEMENT_SIZE,
OP_0,
OP_1,
OP_2,
OP_3,
OP_4,
OP_5,
OP_6,
OP_7,
OP_8,
OP_9,
OP_10,
OP_11,
OP_12,
OP_16,
OP_2DROP,
OP_2DUP,
OP_CHECKMULTISIG,
OP_CHECKMULTISIGVERIFY,
OP_CHECKSIG,
OP_CHECKSIGADD,
OP_CHECKSIGVERIFY,
OP_CODESEPARATOR,
OP_DROP,
OP_DUP,
OP_ELSE,
OP_ENDIF,
OP_EQUAL,
OP_EQUALVERIFY,
OP_IF,
OP_NOP,
OP_NOT,
OP_NOTIF,
OP_PUSHDATA1,
OP_RETURN,
OP_SWAP,
OP_VERIFY,
SIGHASH_DEFAULT,
SIGHASH_ALL,
SIGHASH_NONE,
SIGHASH_SINGLE,
SIGHASH_ANYONECANPAY,
SegwitV0SignatureMsg,
TaggedHash,
TaprootSignatureMsg,
is_op_success,
taproot_construct,
)
from test_framework.script_util import (
key_to_p2pk_script,
key_to_p2pkh_script,
key_to_p2wpkh_script,
keyhash_to_p2pkh_script,
script_to_p2sh_script,
script_to_p2wsh_script,
)
from test_framework.test_framework import BitcoinTestFramework
from test_framework.util import (
assert_raises_rpc_error,
assert_equal,
)
from test_framework.wallet_util import generate_keypair
from test_framework.key import (
generate_privkey,
compute_xonly_pubkey,
sign_schnorr,
tweak_add_privkey,
ECKey,
)
from test_framework.crypto import secp256k1
from test_framework.address import (
hash160,
program_to_witness,
)
from collections import OrderedDict, namedtuple
import json
import hashlib
import os
import random
# Whether or not to output generated test vectors, in JSON format.
GEN_TEST_VECTORS = False
# === Framework for building spending transactions. ===
#
# The computation is represented as a "context" dict, whose entries store potentially-unevaluated expressions that
# refer to lower-level ones. By overwriting these expression, many aspects - both high and low level - of the signing
# process can be overridden.
#
# Specifically, a context object is a dict that maps names to compositions of:
# - values
# - lists of values
# - callables which, when fed the context object as argument, produce any of these
#
# The DEFAULT_CONTEXT object specifies a standard signing process, with many overridable knobs.
#
# The get(ctx, name) function can evaluate a name, and cache its result in the context.
# getter(name) can be used to construct a callable that evaluates name. For example:
#
# ctx1 = {**DEFAULT_CONTEXT, inputs=[getter("sign"), b'\x01']}
#
# creates a context where the script inputs are a signature plus the bytes 0x01.
#
# override(expr, name1=expr1, name2=expr2, ...) can be used to cause an expression to be evaluated in a selectively
# modified context. For example:
#
# ctx2 = {**DEFAULT_CONTEXT, sighash=override(default_sighash, hashtype=SIGHASH_DEFAULT)}
#
# creates a context ctx2 where the sighash is modified to use hashtype=SIGHASH_DEFAULT. This differs from
#
# ctx3 = {**DEFAULT_CONTEXT, hashtype=SIGHASH_DEFAULT}
#
# in that ctx3 will globally use hashtype=SIGHASH_DEFAULT (including in the hashtype byte appended to the signature)
# while ctx2 only uses the modified hashtype inside the sighash calculation.
def deep_eval(ctx, expr):
"""Recursively replace any callables c in expr (including inside lists) with c(ctx)."""
while callable(expr):
expr = expr(ctx)
if isinstance(expr, list):
expr = [deep_eval(ctx, x) for x in expr]
return expr
# Data type to represent fully-evaluated expressions in a context dict (so we can avoid reevaluating them).
Final = namedtuple("Final", "value")
def get(ctx, name):
"""Evaluate name in context ctx."""
assert name in ctx, "Missing '%s' in context" % name
expr = ctx[name]
if not isinstance(expr, Final):
# Evaluate and cache the result.
expr = Final(deep_eval(ctx, expr))
ctx[name] = expr
return expr.value
def getter(name):
"""Return a callable that evaluates name in its passed context."""
return lambda ctx: get(ctx, name)
def override(expr, **kwargs):
"""Return a callable that evaluates expr in a modified context."""
return lambda ctx: deep_eval({**ctx, **kwargs}, expr)
# === Implementations for the various default expressions in DEFAULT_CONTEXT ===
def default_hashtype(ctx):
"""Default expression for "hashtype": SIGHASH_DEFAULT for taproot, SIGHASH_ALL otherwise."""
mode = get(ctx, "mode")
if mode == "taproot":
return SIGHASH_DEFAULT
else:
return SIGHASH_ALL
def default_tapleaf(ctx):
"""Default expression for "tapleaf": looking up leaf in tap[2]."""
return get(ctx, "tap").leaves[get(ctx, "leaf")]
def default_script_taproot(ctx):
"""Default expression for "script_taproot": tapleaf.script."""
return get(ctx, "tapleaf").script
def default_leafversion(ctx):
"""Default expression for "leafversion": tapleaf.version"""
return get(ctx, "tapleaf").version
def default_negflag(ctx):
"""Default expression for "negflag": tap.negflag."""
return get(ctx, "tap").negflag
def default_pubkey_internal(ctx):
"""Default expression for "pubkey_internal": tap.internal_pubkey."""
return get(ctx, "tap").internal_pubkey
def default_merklebranch(ctx):
"""Default expression for "merklebranch": tapleaf.merklebranch."""
return get(ctx, "tapleaf").merklebranch
def default_controlblock(ctx):
"""Default expression for "controlblock": combine leafversion, negflag, pubkey_internal, merklebranch."""
return bytes([get(ctx, "leafversion") + get(ctx, "negflag")]) + get(ctx, "pubkey_internal") + get(ctx, "merklebranch")
def default_sigmsg(ctx):
"""Default expression for "sigmsg": depending on mode, compute BIP341, BIP143, or legacy sigmsg."""
tx = get(ctx, "tx")
idx = get(ctx, "idx")
hashtype = get(ctx, "hashtype_actual")
mode = get(ctx, "mode")
if mode == "taproot":
# BIP341 signature hash
utxos = get(ctx, "utxos")
annex = get(ctx, "annex")
if get(ctx, "leaf") is not None:
codeseppos = get(ctx, "codeseppos")
leaf_ver = get(ctx, "leafversion")
script = get(ctx, "script_taproot")
return TaprootSignatureMsg(tx, utxos, hashtype, idx, scriptpath=True, leaf_script=script, leaf_ver=leaf_ver, codeseparator_pos=codeseppos, annex=annex)
else:
return TaprootSignatureMsg(tx, utxos, hashtype, idx, scriptpath=False, annex=annex)
elif mode == "witv0":
# BIP143 signature hash
scriptcode = get(ctx, "scriptcode")
utxos = get(ctx, "utxos")
return SegwitV0SignatureMsg(scriptcode, tx, idx, hashtype, utxos[idx].nValue)
else:
# Pre-segwit signature hash
scriptcode = get(ctx, "scriptcode")
return LegacySignatureMsg(scriptcode, tx, idx, hashtype)[0]
def default_sighash(ctx):
"""Default expression for "sighash": depending on mode, compute tagged hash or dsha256 of sigmsg."""
msg = get(ctx, "sigmsg")
mode = get(ctx, "mode")
if mode == "taproot":
return TaggedHash("TapSighash", msg)
else:
if msg is None:
return (1).to_bytes(32, 'little')
else:
return hash256(msg)
def default_tweak(ctx):
"""Default expression for "tweak": None if a leaf is specified, tap[0] otherwise."""
if get(ctx, "leaf") is None:
return get(ctx, "tap").tweak
return None
def default_key_tweaked(ctx):
"""Default expression for "key_tweaked": key if tweak is None, tweaked with it otherwise."""
key = get(ctx, "key")
tweak = get(ctx, "tweak")
if tweak is None:
return key
else:
return tweak_add_privkey(key, tweak)
def default_signature(ctx):
"""Default expression for "signature": BIP340 signature or ECDSA signature depending on mode."""
sighash = get(ctx, "sighash")
deterministic = get(ctx, "deterministic")
if get(ctx, "mode") == "taproot":
key = get(ctx, "key_tweaked")
flip_r = get(ctx, "flag_flip_r")
flip_p = get(ctx, "flag_flip_p")
aux = bytes([0] * 32)
if not deterministic:
aux = random.getrandbits(256).to_bytes(32, 'big')
return sign_schnorr(key, sighash, flip_r=flip_r, flip_p=flip_p, aux=aux)
else:
key = get(ctx, "key")
return key.sign_ecdsa(sighash, rfc6979=deterministic)
def default_hashtype_actual(ctx):
"""Default expression for "hashtype_actual": hashtype, unless mismatching SIGHASH_SINGLE in taproot."""
hashtype = get(ctx, "hashtype")
mode = get(ctx, "mode")
if mode != "taproot":
return hashtype
idx = get(ctx, "idx")
tx = get(ctx, "tx")
if hashtype & 3 == SIGHASH_SINGLE and idx >= len(tx.vout):
return (hashtype & ~3) | SIGHASH_NONE
return hashtype
def default_bytes_hashtype(ctx):
"""Default expression for "bytes_hashtype": bytes([hashtype_actual]) if not 0, b"" otherwise."""
return bytes([x for x in [get(ctx, "hashtype_actual")] if x != 0])
def default_sign(ctx):
"""Default expression for "sign": concatenation of signature and bytes_hashtype."""
return get(ctx, "signature") + get(ctx, "bytes_hashtype")
def default_inputs_keypath(ctx):
"""Default expression for "inputs_keypath": a signature."""
return [get(ctx, "sign")]
def default_witness_taproot(ctx):
"""Default expression for "witness_taproot", consisting of inputs, script, control block, and annex as needed."""
annex = get(ctx, "annex")
suffix_annex = []
if annex is not None:
suffix_annex = [annex]
if get(ctx, "leaf") is None:
return get(ctx, "inputs_keypath") + suffix_annex
else:
return get(ctx, "inputs") + [bytes(get(ctx, "script_taproot")), get(ctx, "controlblock")] + suffix_annex
def default_witness_witv0(ctx):
"""Default expression for "witness_witv0", consisting of inputs and witness script, as needed."""
script = get(ctx, "script_witv0")
inputs = get(ctx, "inputs")
if script is None:
return inputs
else:
return inputs + [script]
def default_witness(ctx):
"""Default expression for "witness", delegating to "witness_taproot" or "witness_witv0" as needed."""
mode = get(ctx, "mode")
if mode == "taproot":
return get(ctx, "witness_taproot")
elif mode == "witv0":
return get(ctx, "witness_witv0")
else:
return []
def default_scriptsig(ctx):
"""Default expression for "scriptsig", consisting of inputs and redeemscript, as needed."""
scriptsig = []
mode = get(ctx, "mode")
if mode == "legacy":
scriptsig = get(ctx, "inputs")
redeemscript = get(ctx, "script_p2sh")
if redeemscript is not None:
scriptsig += [bytes(redeemscript)]
return scriptsig
# The default context object.
DEFAULT_CONTEXT = {
# == The main expressions to evaluate. Only override these for unusual or invalid spends. ==
# The overall witness stack, as a list of bytes objects.
"witness": default_witness,
# The overall scriptsig, as a list of CScript objects (to be concatenated) and bytes objects (to be pushed)
"scriptsig": default_scriptsig,
# == Expressions you'll generally only override for intentionally invalid spends. ==
# The witness stack for spending a taproot output.
"witness_taproot": default_witness_taproot,
# The witness stack for spending a P2WPKH/P2WSH output.
"witness_witv0": default_witness_witv0,
# The script inputs for a taproot key path spend.
"inputs_keypath": default_inputs_keypath,
# The actual hashtype to use (usually equal to hashtype, but in taproot SIGHASH_SINGLE is not always allowed).
"hashtype_actual": default_hashtype_actual,
# The bytes object for a full signature (including hashtype byte, if needed).
"bytes_hashtype": default_bytes_hashtype,
# A full script signature (bytes including hashtype, if needed)
"sign": default_sign,
# An ECDSA or Schnorr signature (excluding hashtype byte).
"signature": default_signature,
# The 32-byte tweaked key (equal to key for script path spends, or key+tweak for key path spends).
"key_tweaked": default_key_tweaked,
# The tweak to use (None for script path spends, the actual tweak for key path spends).
"tweak": default_tweak,
# The sigmsg value (preimage of sighash)
"sigmsg": default_sigmsg,
# The sighash value (32 bytes)
"sighash": default_sighash,
# The information about the chosen script path spend (TaprootLeafInfo object).
"tapleaf": default_tapleaf,
# The script to push, and include in the sighash, for a taproot script path spend.
"script_taproot": default_script_taproot,
# The internal pubkey for a taproot script path spend (32 bytes).
"pubkey_internal": default_pubkey_internal,
# The negation flag of the internal pubkey for a taproot script path spend.
"negflag": default_negflag,
# The leaf version to include in the sighash (this does not affect the one in the control block).
"leafversion": default_leafversion,
# The Merkle path to include in the control block for a script path spend.
"merklebranch": default_merklebranch,
# The control block to push for a taproot script path spend.
"controlblock": default_controlblock,
# Whether to produce signatures with invalid P sign (Schnorr signatures only).
"flag_flip_p": False,
# Whether to produce signatures with invalid R sign (Schnorr signatures only).
"flag_flip_r": False,
# == Parameters that can be changed without invalidating, but do have a default: ==
# The hashtype (as an integer).
"hashtype": default_hashtype,
# The annex (only when mode=="taproot").
"annex": None,
# The codeseparator position (only when mode=="taproot").
"codeseppos": -1,
# The redeemscript to add to the scriptSig (if P2SH; None implies not P2SH).
"script_p2sh": None,
# The script to add to the witness in (if P2WSH; None implies P2WPKH)
"script_witv0": None,
# The leaf to use in taproot spends (if script path spend; None implies key path spend).
"leaf": None,
# The input arguments to provide to the executed script
"inputs": [],
# Use deterministic signing nonces
"deterministic": False,
# == Parameters to be set before evaluation: ==
# - mode: what spending style to use ("taproot", "witv0", or "legacy").
# - key: the (untweaked) private key to sign with (ECKey object for ECDSA, 32 bytes for Schnorr).
# - tap: the TaprootInfo object (see taproot_construct; needed in mode=="taproot").
# - tx: the transaction to sign.
# - utxos: the UTXOs being spent (needed in mode=="witv0" and mode=="taproot").
# - idx: the input position being signed.
# - scriptcode: the scriptcode to include in legacy and witv0 sighashes.
}
def flatten(lst):
ret = []
for elem in lst:
if isinstance(elem, list):
ret += flatten(elem)
else:
ret.append(elem)
return ret
def spend(tx, idx, utxos, **kwargs):
"""Sign transaction input idx of tx, provided utxos is the list of outputs being spent.
Additional arguments may be provided that override any aspect of the signing process.
See DEFAULT_CONTEXT above for what can be overridden, and what must be provided.
"""
ctx = {**DEFAULT_CONTEXT, "tx":tx, "idx":idx, "utxos":utxos, **kwargs}
def to_script(elem):
"""If fed a CScript, return it; if fed bytes, return a CScript that pushes it."""
if isinstance(elem, CScript):
return elem
else:
return CScript([elem])
scriptsig_list = flatten(get(ctx, "scriptsig"))
scriptsig = CScript(b"".join(bytes(to_script(elem)) for elem in scriptsig_list))
witness_stack = flatten(get(ctx, "witness"))
return (scriptsig, witness_stack)
# === Spender objects ===
#
# Each spender is a tuple of:
# - A scriptPubKey which is to be spent from (CScript)
# - A comment describing the test (string)
# - Whether the spending (on itself) is expected to be standard (bool)
# - A tx-signing lambda returning (scriptsig, witness_stack), taking as inputs:
# - A transaction to sign (CTransaction)
# - An input position (int)
# - The spent UTXOs by this transaction (list of CTxOut)
# - Whether to produce a valid spend (bool)
# - A string with an expected error message for failure case if known
# - The (pre-taproot) sigops weight consumed by a successful spend
# - Whether this spend cannot fail
# - Whether this test demands being placed in a txin with no corresponding txout (for testing SIGHASH_SINGLE behavior)
Spender = namedtuple("Spender", "script,comment,is_standard,sat_function,err_msg,sigops_weight,no_fail,need_vin_vout_mismatch")
def make_spender(comment, *, tap=None, witv0=False, script=None, pkh=None, p2sh=False, spk_mutate_pre_p2sh=None, failure=None, standard=True, err_msg=None, sigops_weight=0, need_vin_vout_mismatch=False, **kwargs):
"""Helper for constructing Spender objects using the context signing framework.
* tap: a TaprootInfo object (see taproot_construct), for Taproot spends (cannot be combined with pkh, witv0, or script)
* witv0: boolean indicating the use of witness v0 spending (needs one of script or pkh)
* script: the actual script executed (for bare/P2WSH/P2SH spending)
* pkh: the public key for P2PKH or P2WPKH spending
* p2sh: whether the output is P2SH wrapper (this is supported even for Taproot, where it makes the output unencumbered)
* spk_mutate_pre_psh: a callable to be applied to the script (before potentially P2SH-wrapping it)
* failure: a dict of entries to override in the context when intentionally failing to spend (if None, no_fail will be set)
* standard: whether the (valid version of) spending is expected to be standard
* err_msg: a string with an expected error message for failure (or None, if not cared about)
* sigops_weight: the pre-taproot sigops weight consumed by a successful spend
* need_vin_vout_mismatch: whether this test requires being tested in a transaction input that has no corresponding
transaction output.
"""
conf = dict()
# Compute scriptPubKey and set useful defaults based on the inputs.
if witv0:
assert tap is None
conf["mode"] = "witv0"
if pkh is not None:
# P2WPKH
assert script is None
pubkeyhash = hash160(pkh)
spk = key_to_p2wpkh_script(pkh)
conf["scriptcode"] = keyhash_to_p2pkh_script(pubkeyhash)
conf["script_witv0"] = None
conf["inputs"] = [getter("sign"), pkh]
elif script is not None:
# P2WSH
spk = script_to_p2wsh_script(script)
conf["scriptcode"] = script
conf["script_witv0"] = script
else:
assert False
elif tap is None:
conf["mode"] = "legacy"
if pkh is not None:
# P2PKH
assert script is None
pubkeyhash = hash160(pkh)
spk = keyhash_to_p2pkh_script(pubkeyhash)
conf["scriptcode"] = spk
conf["inputs"] = [getter("sign"), pkh]
elif script is not None:
# bare
spk = script
conf["scriptcode"] = script
else:
assert False
else:
assert script is None
conf["mode"] = "taproot"
conf["tap"] = tap
spk = tap.scriptPubKey
if spk_mutate_pre_p2sh is not None:
spk = spk_mutate_pre_p2sh(spk)
if p2sh:
# P2SH wrapper can be combined with anything else
conf["script_p2sh"] = spk
spk = script_to_p2sh_script(spk)
conf = {**conf, **kwargs}
def sat_fn(tx, idx, utxos, valid):
if valid:
return spend(tx, idx, utxos, **conf)
else:
assert failure is not None
return spend(tx, idx, utxos, **{**conf, **failure})
return Spender(script=spk, comment=comment, is_standard=standard, sat_function=sat_fn, err_msg=err_msg, sigops_weight=sigops_weight, no_fail=failure is None, need_vin_vout_mismatch=need_vin_vout_mismatch)
def add_spender(spenders, *args, **kwargs):
"""Make a spender using make_spender, and add it to spenders."""
spenders.append(make_spender(*args, **kwargs))
# === Helpers for the test ===
def random_checksig_style(pubkey):
"""Creates a random CHECKSIG* tapscript that would succeed with only the valid signature on witness stack."""
opcode = random.choice([OP_CHECKSIG, OP_CHECKSIGVERIFY, OP_CHECKSIGADD])
if opcode == OP_CHECKSIGVERIFY:
ret = CScript([pubkey, opcode, OP_1])
elif opcode == OP_CHECKSIGADD:
num = random.choice([0, 0x7fffffff, -0x7fffffff])
ret = CScript([num, pubkey, opcode, num + 1, OP_EQUAL])
else:
ret = CScript([pubkey, opcode])
return bytes(ret)
def bitflipper(expr):
"""Return a callable that evaluates expr and returns it with a random bitflip."""
def fn(ctx):
sub = deep_eval(ctx, expr)
assert isinstance(sub, bytes)
return (int.from_bytes(sub, 'little') ^ (1 << random.randrange(len(sub) * 8))).to_bytes(len(sub), 'little')
return fn
def zero_appender(expr):
"""Return a callable that evaluates expr and returns it with a zero added."""
return lambda ctx: deep_eval(ctx, expr) + b"\x00"
def byte_popper(expr):
"""Return a callable that evaluates expr and returns it with its last byte removed."""
return lambda ctx: deep_eval(ctx, expr)[:-1]
# Expected error strings
ERR_SIG_SIZE = {"err_msg": "Invalid Schnorr signature size"}
ERR_SIG_HASHTYPE = {"err_msg": "Invalid Schnorr signature hash type"}
ERR_SIG_SCHNORR = {"err_msg": "Invalid Schnorr signature"}
ERR_OP_RETURN = {"err_msg": "OP_RETURN was encountered"}
ERR_CONTROLBLOCK_SIZE = {"err_msg": "Invalid Taproot control block size"}
ERR_WITNESS_PROGRAM_MISMATCH = {"err_msg": "Witness program hash mismatch"}
ERR_PUSH_LIMIT = {"err_msg": "Push value size limit exceeded"}
ERR_DISABLED_OPCODE = {"err_msg": "Attempted to use a disabled opcode"}
ERR_TAPSCRIPT_CHECKMULTISIG = {"err_msg": "OP_CHECKMULTISIG(VERIFY) is not available in tapscript"}
ERR_MINIMALIF = {"err_msg": "OP_IF/NOTIF argument must be minimal in tapscript"}
ERR_UNKNOWN_PUBKEY = {"err_msg": "Public key is neither compressed or uncompressed"}
ERR_STACK_SIZE = {"err_msg": "Stack size limit exceeded"}
ERR_CLEANSTACK = {"err_msg": "Stack size must be exactly one after execution"}
ERR_STACK_EMPTY = {"err_msg": "Operation not valid with the current stack size"}
ERR_SIGOPS_RATIO = {"err_msg": "Too much signature validation relative to witness weight"}
ERR_UNDECODABLE = {"err_msg": "Opcode missing or not understood"}
ERR_NO_SUCCESS = {"err_msg": "Script evaluated without error but finished with a false/empty top stack element"}
ERR_EMPTY_WITNESS = {"err_msg": "Witness program was passed an empty witness"}
ERR_CHECKSIGVERIFY = {"err_msg": "Script failed an OP_CHECKSIGVERIFY operation"}
VALID_SIGHASHES_ECDSA = [
SIGHASH_ALL,
SIGHASH_NONE,
SIGHASH_SINGLE,
SIGHASH_ANYONECANPAY + SIGHASH_ALL,
SIGHASH_ANYONECANPAY + SIGHASH_NONE,
SIGHASH_ANYONECANPAY + SIGHASH_SINGLE
]
VALID_SIGHASHES_TAPROOT = [SIGHASH_DEFAULT] + VALID_SIGHASHES_ECDSA
VALID_SIGHASHES_TAPROOT_SINGLE = [
SIGHASH_SINGLE,
SIGHASH_ANYONECANPAY + SIGHASH_SINGLE
]
VALID_SIGHASHES_TAPROOT_NO_SINGLE = [h for h in VALID_SIGHASHES_TAPROOT if h not in VALID_SIGHASHES_TAPROOT_SINGLE]
SIGHASH_BITFLIP = {"failure": {"sighash": bitflipper(default_sighash)}}
SIG_POP_BYTE = {"failure": {"sign": byte_popper(default_sign)}}
SINGLE_SIG = {"inputs": [getter("sign")]}
SIG_ADD_ZERO = {"failure": {"sign": zero_appender(default_sign)}}
DUST_LIMIT = 600
MIN_FEE = 50000
# === Actual test cases ===
def spenders_taproot_active():
"""Return a list of Spenders for testing post-Taproot activation behavior."""
secs = [generate_privkey() for _ in range(8)]
pubs = [compute_xonly_pubkey(sec)[0] for sec in secs]
spenders = []
# == Tests for BIP340 signature validation. ==
# These are primarily tested through the test vectors implemented in libsecp256k1, and in src/tests/key_tests.cpp.
# Some things are tested programmatically as well here.
tap = taproot_construct(pubs[0])
# Test with key with bit flipped.
add_spender(spenders, "sig/key", tap=tap, key=secs[0], failure={"key_tweaked": bitflipper(default_key_tweaked)}, **ERR_SIG_SCHNORR)
# Test with sighash with bit flipped.
add_spender(spenders, "sig/sighash", tap=tap, key=secs[0], failure={"sighash": bitflipper(default_sighash)}, **ERR_SIG_SCHNORR)
# Test with invalid R sign.
add_spender(spenders, "sig/flip_r", tap=tap, key=secs[0], failure={"flag_flip_r": True}, **ERR_SIG_SCHNORR)
# Test with invalid P sign.
add_spender(spenders, "sig/flip_p", tap=tap, key=secs[0], failure={"flag_flip_p": True}, **ERR_SIG_SCHNORR)
# Test with signature with bit flipped.
add_spender(spenders, "sig/bitflip", tap=tap, key=secs[0], failure={"signature": bitflipper(default_signature)}, **ERR_SIG_SCHNORR)
# == Test involving an internal public key not on the curve ==
# X-only public keys are 32 bytes, but not every 32-byte array is a valid public key; only
# around 50% of them are. This does not affect users using correct software; these "keys" have
# no corresponding private key, and thus will never appear as output of key
# generation/derivation/tweaking.
#
# Using an invalid public key as P2TR output key makes the UTXO unspendable. Revealing an
# invalid public key as internal key in a P2TR script path spend also makes the spend invalid.
# These conditions are explicitly spelled out in BIP341.
#
# It is however hard to create test vectors for this, because it involves "guessing" how a
# hypothetical incorrect implementation deals with an obviously-invalid condition, and making
# sure that guessed behavior (accepting it in certain condition) doesn't occur.
#
# The test case added here tries to detect a very specific bug a verifier could have: if they
# don't verify whether or not a revealed internal public key in a script path spend is valid,
# and (correctly) implement output_key == tweak(internal_key, tweakval) but (incorrectly) treat
# tweak(invalid_key, tweakval) as equal the public key corresponding to private key tweakval.
# This may seem like a far-fetched edge condition to test for, but in fact, the BIP341 wallet
# pseudocode did exactly that (but obviously only triggerable by someone invoking the tweaking
# function with an invalid public key, which shouldn't happen).
# Generate an invalid public key
while True:
invalid_pub = random.randbytes(32)
if not secp256k1.GE.is_valid_x(int.from_bytes(invalid_pub, 'big')):
break
# Implement a test case that detects validation logic which maps invalid public keys to the
# point at infinity in the tweaking logic.
tap = taproot_construct(invalid_pub, [("true", CScript([OP_1]))], treat_internal_as_infinity=True)
add_spender(spenders, "output/invalid_x", tap=tap, key_tweaked=tap.tweak, failure={"leaf": "true", "inputs": []}, **ERR_WITNESS_PROGRAM_MISMATCH)
# Do the same thing without invalid point, to make sure there is no mistake in the test logic.
tap = taproot_construct(pubs[0], [("true", CScript([OP_1]))])
add_spender(spenders, "output/invalid_x_mock", tap=tap, key=secs[0], leaf="true", inputs=[])
# == Tests for signature hashing ==
# Run all tests once with no annex, and once with a valid random annex.
for annex in [None, lambda _: bytes([ANNEX_TAG]) + random.randbytes(random.randrange(0, 250))]:
# Non-empty annex is non-standard
no_annex = annex is None
# Sighash mutation tests (test all sighash combinations)
for hashtype in VALID_SIGHASHES_TAPROOT:
common = {"annex": annex, "hashtype": hashtype, "standard": no_annex}
# Pure pubkey
tap = taproot_construct(pubs[0])
add_spender(spenders, "sighash/purepk", tap=tap, key=secs[0], **common, **SIGHASH_BITFLIP, **ERR_SIG_SCHNORR)
# Pubkey/P2PK script combination
scripts = [("s0", CScript(random_checksig_style(pubs[1])))]
tap = taproot_construct(pubs[0], scripts)
add_spender(spenders, "sighash/keypath_hashtype_%x" % hashtype, tap=tap, key=secs[0], **common, **SIGHASH_BITFLIP, **ERR_SIG_SCHNORR)
add_spender(spenders, "sighash/scriptpath_hashtype_%x" % hashtype, tap=tap, leaf="s0", key=secs[1], **common, **SINGLE_SIG, **SIGHASH_BITFLIP, **ERR_SIG_SCHNORR)
# Test SIGHASH_SINGLE behavior in combination with mismatching outputs
if hashtype in VALID_SIGHASHES_TAPROOT_SINGLE:
add_spender(spenders, "sighash/keypath_hashtype_mis_%x" % hashtype, tap=tap, key=secs[0], annex=annex, standard=no_annex, hashtype_actual=random.choice(VALID_SIGHASHES_TAPROOT_NO_SINGLE), failure={"hashtype_actual": hashtype}, **ERR_SIG_HASHTYPE, need_vin_vout_mismatch=True)
add_spender(spenders, "sighash/scriptpath_hashtype_mis_%x" % hashtype, tap=tap, leaf="s0", key=secs[1], annex=annex, standard=no_annex, hashtype_actual=random.choice(VALID_SIGHASHES_TAPROOT_NO_SINGLE), **SINGLE_SIG, failure={"hashtype_actual": hashtype}, **ERR_SIG_HASHTYPE, need_vin_vout_mismatch=True)
# Test OP_CODESEPARATOR impact on sighashing.
hashtype = lambda _: random.choice(VALID_SIGHASHES_TAPROOT)
common = {"annex": annex, "hashtype": hashtype, "standard": no_annex}
scripts = [
("pk_codesep", CScript(random_checksig_style(pubs[1]) + bytes([OP_CODESEPARATOR]))), # codesep after checksig
("codesep_pk", CScript(bytes([OP_CODESEPARATOR]) + random_checksig_style(pubs[1]))), # codesep before checksig
("branched_codesep", CScript([random.randbytes(random.randrange(2, 511)), OP_DROP, OP_IF, OP_CODESEPARATOR, pubs[0], OP_ELSE, OP_CODESEPARATOR, pubs[1], OP_ENDIF, OP_CHECKSIG])), # branch dependent codesep
# Note that the first data push in the "branched_codesep" script has the purpose of
# randomizing the sighash, both by varying script size and content. In order to
# avoid MINIMALDATA script verification errors caused by not-minimal-encoded data
# pushes (e.g. `OP_PUSH1 1` instead of `OP_1`), we set a minimum data size of 2 bytes.
]
random.shuffle(scripts)
tap = taproot_construct(pubs[0], scripts)
add_spender(spenders, "sighash/pk_codesep", tap=tap, leaf="pk_codesep", key=secs[1], **common, **SINGLE_SIG, **SIGHASH_BITFLIP, **ERR_SIG_SCHNORR)
add_spender(spenders, "sighash/codesep_pk", tap=tap, leaf="codesep_pk", key=secs[1], codeseppos=0, **common, **SINGLE_SIG, **SIGHASH_BITFLIP, **ERR_SIG_SCHNORR)
add_spender(spenders, "sighash/branched_codesep/left", tap=tap, leaf="branched_codesep", key=secs[0], codeseppos=3, **common, inputs=[getter("sign"), b'\x01'], **SIGHASH_BITFLIP, **ERR_SIG_SCHNORR)
add_spender(spenders, "sighash/branched_codesep/right", tap=tap, leaf="branched_codesep", key=secs[1], codeseppos=6, **common, inputs=[getter("sign"), b''], **SIGHASH_BITFLIP, **ERR_SIG_SCHNORR)
# Reusing the scripts above, test that various features affect the sighash.
add_spender(spenders, "sighash/annex", tap=tap, leaf="pk_codesep", key=secs[1], hashtype=hashtype, standard=False, **SINGLE_SIG, annex=bytes([ANNEX_TAG]), failure={"sighash": override(default_sighash, annex=None)}, **ERR_SIG_SCHNORR)
add_spender(spenders, "sighash/script", tap=tap, leaf="pk_codesep", key=secs[1], **common, **SINGLE_SIG, failure={"sighash": override(default_sighash, script_taproot=tap.leaves["codesep_pk"].script)}, **ERR_SIG_SCHNORR)
add_spender(spenders, "sighash/leafver", tap=tap, leaf="pk_codesep", key=secs[1], **common, **SINGLE_SIG, failure={"sighash": override(default_sighash, leafversion=random.choice([x & 0xFE for x in range(0x100) if x & 0xFE != LEAF_VERSION_TAPSCRIPT]))}, **ERR_SIG_SCHNORR)
add_spender(spenders, "sighash/scriptpath", tap=tap, leaf="pk_codesep", key=secs[1], **common, **SINGLE_SIG, failure={"sighash": override(default_sighash, leaf=None)}, **ERR_SIG_SCHNORR)
add_spender(spenders, "sighash/keypath", tap=tap, key=secs[0], **common, failure={"sighash": override(default_sighash, leaf="pk_codesep")}, **ERR_SIG_SCHNORR)
# Test that invalid hashtypes don't work, both in key path and script path spends
hashtype = lambda _: random.choice(VALID_SIGHASHES_TAPROOT)
for invalid_hashtype in [x for x in range(0x100) if x not in VALID_SIGHASHES_TAPROOT]:
add_spender(spenders, "sighash/keypath_unk_hashtype_%x" % invalid_hashtype, tap=tap, key=secs[0], hashtype=hashtype, failure={"hashtype": invalid_hashtype}, **ERR_SIG_HASHTYPE)
add_spender(spenders, "sighash/scriptpath_unk_hashtype_%x" % invalid_hashtype, tap=tap, leaf="pk_codesep", key=secs[1], **SINGLE_SIG, hashtype=hashtype, failure={"hashtype": invalid_hashtype}, **ERR_SIG_HASHTYPE)
# Test that hashtype 0 cannot have a hashtype byte, and 1 must have one.
add_spender(spenders, "sighash/hashtype0_byte_keypath", tap=tap, key=secs[0], hashtype=SIGHASH_DEFAULT, failure={"bytes_hashtype": bytes([SIGHASH_DEFAULT])}, **ERR_SIG_HASHTYPE)
add_spender(spenders, "sighash/hashtype0_byte_scriptpath", tap=tap, leaf="pk_codesep", key=secs[1], **SINGLE_SIG, hashtype=SIGHASH_DEFAULT, failure={"bytes_hashtype": bytes([SIGHASH_DEFAULT])}, **ERR_SIG_HASHTYPE)
add_spender(spenders, "sighash/hashtype1_byte_keypath", tap=tap, key=secs[0], hashtype=SIGHASH_ALL, failure={"bytes_hashtype": b''}, **ERR_SIG_SCHNORR)
add_spender(spenders, "sighash/hashtype1_byte_scriptpath", tap=tap, leaf="pk_codesep", key=secs[1], **SINGLE_SIG, hashtype=SIGHASH_ALL, failure={"bytes_hashtype": b''}, **ERR_SIG_SCHNORR)
# Test that hashtype 0 and hashtype 1 cannot be transmuted into each other.
add_spender(spenders, "sighash/hashtype0to1_keypath", tap=tap, key=secs[0], hashtype=SIGHASH_DEFAULT, failure={"bytes_hashtype": bytes([SIGHASH_ALL])}, **ERR_SIG_SCHNORR)
add_spender(spenders, "sighash/hashtype0to1_scriptpath", tap=tap, leaf="pk_codesep", key=secs[1], **SINGLE_SIG, hashtype=SIGHASH_DEFAULT, failure={"bytes_hashtype": bytes([SIGHASH_ALL])}, **ERR_SIG_SCHNORR)
add_spender(spenders, "sighash/hashtype1to0_keypath", tap=tap, key=secs[0], hashtype=SIGHASH_ALL, failure={"bytes_hashtype": b''}, **ERR_SIG_SCHNORR)
add_spender(spenders, "sighash/hashtype1to0_scriptpath", tap=tap, leaf="pk_codesep", key=secs[1], **SINGLE_SIG, hashtype=SIGHASH_ALL, failure={"bytes_hashtype": b''}, **ERR_SIG_SCHNORR)
# Test aspects of signatures with unusual lengths
for hashtype in [SIGHASH_DEFAULT, random.choice(VALID_SIGHASHES_TAPROOT)]:
scripts = [
("csv", CScript([pubs[2], OP_CHECKSIGVERIFY, OP_1])),
("cs_pos", CScript([pubs[2], OP_CHECKSIG])),
("csa_pos", CScript([OP_0, pubs[2], OP_CHECKSIGADD, OP_1, OP_EQUAL])),
("cs_neg", CScript([pubs[2], OP_CHECKSIG, OP_NOT])),
("csa_neg", CScript([OP_2, pubs[2], OP_CHECKSIGADD, OP_2, OP_EQUAL]))
]
random.shuffle(scripts)
tap = taproot_construct(pubs[3], scripts)
# Empty signatures
add_spender(spenders, "siglen/empty_keypath", tap=tap, key=secs[3], hashtype=hashtype, failure={"sign": b""}, **ERR_SIG_SIZE)
add_spender(spenders, "siglen/empty_csv", tap=tap, key=secs[2], leaf="csv", hashtype=hashtype, **SINGLE_SIG, failure={"sign": b""}, **ERR_CHECKSIGVERIFY)
add_spender(spenders, "siglen/empty_cs", tap=tap, key=secs[2], leaf="cs_pos", hashtype=hashtype, **SINGLE_SIG, failure={"sign": b""}, **ERR_NO_SUCCESS)
add_spender(spenders, "siglen/empty_csa", tap=tap, key=secs[2], leaf="csa_pos", hashtype=hashtype, **SINGLE_SIG, failure={"sign": b""}, **ERR_NO_SUCCESS)
add_spender(spenders, "siglen/empty_cs_neg", tap=tap, key=secs[2], leaf="cs_neg", hashtype=hashtype, **SINGLE_SIG, sign=b"", failure={"sign": lambda _: random.randbytes(random.randrange(1, 63))}, **ERR_SIG_SIZE)
add_spender(spenders, "siglen/empty_csa_neg", tap=tap, key=secs[2], leaf="csa_neg", hashtype=hashtype, **SINGLE_SIG, sign=b"", failure={"sign": lambda _: random.randbytes(random.randrange(66, 100))}, **ERR_SIG_SIZE)
# Appending a zero byte to signatures invalidates them
add_spender(spenders, "siglen/padzero_keypath", tap=tap, key=secs[3], hashtype=hashtype, **SIG_ADD_ZERO, **(ERR_SIG_HASHTYPE if hashtype == SIGHASH_DEFAULT else ERR_SIG_SIZE))
add_spender(spenders, "siglen/padzero_csv", tap=tap, key=secs[2], leaf="csv", hashtype=hashtype, **SINGLE_SIG, **SIG_ADD_ZERO, **(ERR_SIG_HASHTYPE if hashtype == SIGHASH_DEFAULT else ERR_SIG_SIZE))
add_spender(spenders, "siglen/padzero_cs", tap=tap, key=secs[2], leaf="cs_pos", hashtype=hashtype, **SINGLE_SIG, **SIG_ADD_ZERO, **(ERR_SIG_HASHTYPE if hashtype == SIGHASH_DEFAULT else ERR_SIG_SIZE))
add_spender(spenders, "siglen/padzero_csa", tap=tap, key=secs[2], leaf="csa_pos", hashtype=hashtype, **SINGLE_SIG, **SIG_ADD_ZERO, **(ERR_SIG_HASHTYPE if hashtype == SIGHASH_DEFAULT else ERR_SIG_SIZE))
add_spender(spenders, "siglen/padzero_cs_neg", tap=tap, key=secs[2], leaf="cs_neg", hashtype=hashtype, **SINGLE_SIG, sign=b"", **SIG_ADD_ZERO, **(ERR_SIG_HASHTYPE if hashtype == SIGHASH_DEFAULT else ERR_SIG_SIZE))
add_spender(spenders, "siglen/padzero_csa_neg", tap=tap, key=secs[2], leaf="csa_neg", hashtype=hashtype, **SINGLE_SIG, sign=b"", **SIG_ADD_ZERO, **(ERR_SIG_HASHTYPE if hashtype == SIGHASH_DEFAULT else ERR_SIG_SIZE))
# Removing the last byte from signatures invalidates them
add_spender(spenders, "siglen/popbyte_keypath", tap=tap, key=secs[3], hashtype=hashtype, **SIG_POP_BYTE, **(ERR_SIG_SIZE if hashtype == SIGHASH_DEFAULT else ERR_SIG_SCHNORR))
add_spender(spenders, "siglen/popbyte_csv", tap=tap, key=secs[2], leaf="csv", hashtype=hashtype, **SINGLE_SIG, **SIG_POP_BYTE, **(ERR_SIG_SIZE if hashtype == SIGHASH_DEFAULT else ERR_SIG_SCHNORR))
add_spender(spenders, "siglen/popbyte_cs", tap=tap, key=secs[2], leaf="cs_pos", hashtype=hashtype, **SINGLE_SIG, **SIG_POP_BYTE, **(ERR_SIG_SIZE if hashtype == SIGHASH_DEFAULT else ERR_SIG_SCHNORR))
add_spender(spenders, "siglen/popbyte_csa", tap=tap, key=secs[2], leaf="csa_pos", hashtype=hashtype, **SINGLE_SIG, **SIG_POP_BYTE, **(ERR_SIG_SIZE if hashtype == SIGHASH_DEFAULT else ERR_SIG_SCHNORR))
add_spender(spenders, "siglen/popbyte_cs_neg", tap=tap, key=secs[2], leaf="cs_neg", hashtype=hashtype, **SINGLE_SIG, sign=b"", **SIG_POP_BYTE, **(ERR_SIG_SIZE if hashtype == SIGHASH_DEFAULT else ERR_SIG_SCHNORR))
add_spender(spenders, "siglen/popbyte_csa_neg", tap=tap, key=secs[2], leaf="csa_neg", hashtype=hashtype, **SINGLE_SIG, sign=b"", **SIG_POP_BYTE, **(ERR_SIG_SIZE if hashtype == SIGHASH_DEFAULT else ERR_SIG_SCHNORR))
# Verify that an invalid signature is not allowed, not even when the CHECKSIG* is expected to fail.
add_spender(spenders, "siglen/invalid_cs_neg", tap=tap, key=secs[2], leaf="cs_neg", hashtype=hashtype, **SINGLE_SIG, sign=b"", failure={"sign": default_sign, "sighash": bitflipper(default_sighash)}, **ERR_SIG_SCHNORR)
add_spender(spenders, "siglen/invalid_csa_neg", tap=tap, key=secs[2], leaf="csa_neg", hashtype=hashtype, **SINGLE_SIG, sign=b"", failure={"sign": default_sign, "sighash": bitflipper(default_sighash)}, **ERR_SIG_SCHNORR)
# == Test that BIP341 spending only applies to witness version 1, program length 32, no P2SH ==
for p2sh in [False, True]:
for witver in range(1, 17):
for witlen in [20, 31, 32, 33]:
def mutate(spk):
prog = spk[2:]
assert len(prog) == 32
if witlen < 32:
prog = prog[0:witlen]
elif witlen > 32:
prog += bytes([0 for _ in range(witlen - 32)])
return CScript([CScriptOp.encode_op_n(witver), prog])
scripts = [("s0", CScript([pubs[0], OP_CHECKSIG])), ("dummy", CScript([OP_RETURN]))]
tap = taproot_construct(pubs[1], scripts)
if not p2sh and witver == 1 and witlen == 32:
add_spender(spenders, "applic/keypath", p2sh=p2sh, spk_mutate_pre_p2sh=mutate, tap=tap, key=secs[1], **SIGHASH_BITFLIP, **ERR_SIG_SCHNORR)
add_spender(spenders, "applic/scriptpath", p2sh=p2sh, leaf="s0", spk_mutate_pre_p2sh=mutate, tap=tap, key=secs[0], **SINGLE_SIG, failure={"leaf": "dummy"}, **ERR_OP_RETURN)
else:
add_spender(spenders, "applic/keypath", p2sh=p2sh, spk_mutate_pre_p2sh=mutate, tap=tap, key=secs[1], standard=False)
add_spender(spenders, "applic/scriptpath", p2sh=p2sh, leaf="s0", spk_mutate_pre_p2sh=mutate, tap=tap, key=secs[0], **SINGLE_SIG, standard=False)
# == Test various aspects of BIP341 spending paths ==
# A set of functions that compute the hashing partner in a Merkle tree, designed to exercise
# edge cases. This relies on the taproot_construct feature that a lambda can be passed in
# instead of a subtree, to compute the partner to be hashed with.
PARTNER_MERKLE_FN = [
# Combine with itself
lambda h: h,
# Combine with hash 0
lambda h: bytes([0 for _ in range(32)]),
# Combine with hash 2^256-1
lambda h: bytes([0xff for _ in range(32)]),
# Combine with itself-1 (BE)
lambda h: (int.from_bytes(h, 'big') - 1).to_bytes(32, 'big'),
# Combine with itself+1 (BE)
lambda h: (int.from_bytes(h, 'big') + 1).to_bytes(32, 'big'),
# Combine with itself-1 (LE)
lambda h: (int.from_bytes(h, 'little') - 1).to_bytes(32, 'big'),
# Combine with itself+1 (LE)
lambda h: (int.from_bytes(h, 'little') + 1).to_bytes(32, 'little'),
# Combine with random bitflipped version of self.
lambda h: (int.from_bytes(h, 'little') ^ (1 << random.randrange(256))).to_bytes(32, 'little')
]
# Start with a tree of that has depth 1 for "128deep" and depth 2 for "129deep".
scripts = [("128deep", CScript([pubs[0], OP_CHECKSIG])), [("129deep", CScript([pubs[0], OP_CHECKSIG])), random.choice(PARTNER_MERKLE_FN)]]
# Add 127 nodes on top of that tree, so that "128deep" and "129deep" end up at their designated depths.
for _ in range(127):
scripts = [scripts, random.choice(PARTNER_MERKLE_FN)]
tap = taproot_construct(pubs[0], scripts)
# Test that spends with a depth of 128 work, but 129 doesn't (even with a tree with weird Merkle branches in it).
add_spender(spenders, "spendpath/merklelimit", tap=tap, leaf="128deep", **SINGLE_SIG, key=secs[0], failure={"leaf": "129deep"}, **ERR_CONTROLBLOCK_SIZE)
# Test that flipping the negation bit invalidates spends.
add_spender(spenders, "spendpath/negflag", tap=tap, leaf="128deep", **SINGLE_SIG, key=secs[0], failure={"negflag": lambda ctx: 1 - default_negflag(ctx)}, **ERR_WITNESS_PROGRAM_MISMATCH)
# Test that bitflips in the Merkle branch invalidate it.
add_spender(spenders, "spendpath/bitflipmerkle", tap=tap, leaf="128deep", **SINGLE_SIG, key=secs[0], failure={"merklebranch": bitflipper(default_merklebranch)}, **ERR_WITNESS_PROGRAM_MISMATCH)
# Test that bitflips in the internal pubkey invalidate it.
add_spender(spenders, "spendpath/bitflippubkey", tap=tap, leaf="128deep", **SINGLE_SIG, key=secs[0], failure={"pubkey_internal": bitflipper(default_pubkey_internal)}, **ERR_WITNESS_PROGRAM_MISMATCH)
# Test that empty witnesses are invalid.
add_spender(spenders, "spendpath/emptywit", tap=tap, leaf="128deep", **SINGLE_SIG, key=secs[0], failure={"witness": []}, **ERR_EMPTY_WITNESS)
# Test that adding garbage to the control block invalidates it.
add_spender(spenders, "spendpath/padlongcontrol", tap=tap, leaf="128deep", **SINGLE_SIG, key=secs[0], failure={"controlblock": lambda ctx: default_controlblock(ctx) + random.randbytes(random.randrange(1, 32))}, **ERR_CONTROLBLOCK_SIZE)
# Test that truncating the control block invalidates it.
add_spender(spenders, "spendpath/trunclongcontrol", tap=tap, leaf="128deep", **SINGLE_SIG, key=secs[0], failure={"controlblock": lambda ctx: default_merklebranch(ctx)[0:random.randrange(1, 32)]}, **ERR_CONTROLBLOCK_SIZE)
scripts = [("s", CScript([pubs[0], OP_CHECKSIG]))]
tap = taproot_construct(pubs[1], scripts)
# Test that adding garbage to the control block invalidates it.
add_spender(spenders, "spendpath/padshortcontrol", tap=tap, leaf="s", **SINGLE_SIG, key=secs[0], failure={"controlblock": lambda ctx: default_controlblock(ctx) + random.randbytes(random.randrange(1, 32))}, **ERR_CONTROLBLOCK_SIZE)
# Test that truncating the control block invalidates it.
add_spender(spenders, "spendpath/truncshortcontrol", tap=tap, leaf="s", **SINGLE_SIG, key=secs[0], failure={"controlblock": lambda ctx: default_merklebranch(ctx)[0:random.randrange(1, 32)]}, **ERR_CONTROLBLOCK_SIZE)
# Test that truncating the control block to 1 byte ("-1 Merkle length") invalidates it
add_spender(spenders, "spendpath/trunc1shortcontrol", tap=tap, leaf="s", **SINGLE_SIG, key=secs[0], failure={"controlblock": lambda ctx: default_merklebranch(ctx)[0:1]}, **ERR_CONTROLBLOCK_SIZE)
# == Test BIP342 edge cases ==
csa_low_val = random.randrange(0, 17) # Within range for OP_n
csa_low_result = csa_low_val + 1
csa_high_val = random.randrange(17, 100) if random.getrandbits(1) else random.randrange(-100, -1) # Outside OP_n range
csa_high_result = csa_high_val + 1
OVERSIZE_NUMBER = 2**31
assert_equal(len(CScriptNum.encode(CScriptNum(OVERSIZE_NUMBER))), 6)
assert_equal(len(CScriptNum.encode(CScriptNum(OVERSIZE_NUMBER-1))), 5)
big_choices = []
big_scriptops = []
for i in range(1000):
r = random.randrange(len(pubs))
big_choices.append(r)
big_scriptops += [pubs[r], OP_CHECKSIGVERIFY]
def big_spend_inputs(ctx):
"""Helper function to construct the script input for t33/t34 below."""
# Instead of signing 999 times, precompute signatures for every (key, hashtype) combination
sigs = {}
for ht in VALID_SIGHASHES_TAPROOT:
for k in range(len(pubs)):
sigs[(k, ht)] = override(default_sign, hashtype=ht, key=secs[k])(ctx)
num = get(ctx, "num")
return [sigs[(big_choices[i], random.choice(VALID_SIGHASHES_TAPROOT))] for i in range(num - 1, -1, -1)]
# Various BIP342 features
scripts = [
# 0) drop stack element and OP_CHECKSIG
("t0", CScript([OP_DROP, pubs[1], OP_CHECKSIG])),
# 1) normal OP_CHECKSIG
("t1", CScript([pubs[1], OP_CHECKSIG])),
# 2) normal OP_CHECKSIGVERIFY
("t2", CScript([pubs[1], OP_CHECKSIGVERIFY, OP_1])),
# 3) Hypothetical OP_CHECKMULTISIG script that takes a single sig as input
("t3", CScript([OP_0, OP_SWAP, OP_1, pubs[1], OP_1, OP_CHECKMULTISIG])),
# 4) Hypothetical OP_CHECKMULTISIGVERIFY script that takes a single sig as input
("t4", CScript([OP_0, OP_SWAP, OP_1, pubs[1], OP_1, OP_CHECKMULTISIGVERIFY, OP_1])),
# 5) OP_IF script that needs a true input
("t5", CScript([OP_IF, pubs[1], OP_CHECKSIG, OP_ELSE, OP_RETURN, OP_ENDIF])),
# 6) OP_NOTIF script that needs a true input
("t6", CScript([OP_NOTIF, OP_RETURN, OP_ELSE, pubs[1], OP_CHECKSIG, OP_ENDIF])),
# 7) OP_CHECKSIG with an empty key
("t7", CScript([OP_0, OP_CHECKSIG])),
# 8) OP_CHECKSIGVERIFY with an empty key
("t8", CScript([OP_0, OP_CHECKSIGVERIFY, OP_1])),
# 9) normal OP_CHECKSIGADD that also ensures return value is correct
("t9", CScript([csa_low_val, pubs[1], OP_CHECKSIGADD, csa_low_result, OP_EQUAL])),
# 10) OP_CHECKSIGADD with empty key
("t10", CScript([csa_low_val, OP_0, OP_CHECKSIGADD, csa_low_result, OP_EQUAL])),
# 11) OP_CHECKSIGADD with missing counter stack element
("t11", CScript([pubs[1], OP_CHECKSIGADD, OP_1, OP_EQUAL])),
# 12) OP_CHECKSIG that needs invalid signature
("t12", CScript([pubs[1], OP_CHECKSIGVERIFY, pubs[0], OP_CHECKSIG, OP_NOT])),
# 13) OP_CHECKSIG with empty key that needs invalid signature
("t13", CScript([pubs[1], OP_CHECKSIGVERIFY, OP_0, OP_CHECKSIG, OP_NOT])),
# 14) OP_CHECKSIGADD that needs invalid signature
("t14", CScript([pubs[1], OP_CHECKSIGVERIFY, OP_0, pubs[0], OP_CHECKSIGADD, OP_NOT])),
# 15) OP_CHECKSIGADD with empty key that needs invalid signature
("t15", CScript([pubs[1], OP_CHECKSIGVERIFY, OP_0, OP_0, OP_CHECKSIGADD, OP_NOT])),
# 16) OP_CHECKSIG with unknown pubkey type
("t16", CScript([OP_1, OP_CHECKSIG])),
# 17) OP_CHECKSIGADD with unknown pubkey type
("t17", CScript([OP_0, OP_1, OP_CHECKSIGADD])),
# 18) OP_CHECKSIGVERIFY with unknown pubkey type
("t18", CScript([OP_1, OP_CHECKSIGVERIFY, OP_1])),
# 19) script longer than 10000 bytes and over 201 non-push opcodes
("t19", CScript([OP_0, OP_0, OP_2DROP] * 10001 + [pubs[1], OP_CHECKSIG])),
# 20) OP_CHECKSIGVERIFY with empty key
("t20", CScript([pubs[1], OP_CHECKSIGVERIFY, OP_0, OP_0, OP_CHECKSIGVERIFY, OP_1])),
# 21) Script that grows the stack to 1000 elements
("t21", CScript([pubs[1], OP_CHECKSIGVERIFY, OP_1] + [OP_DUP] * 999 + [OP_DROP] * 999)),
# 22) Script that grows the stack to 1001 elements
("t22", CScript([pubs[1], OP_CHECKSIGVERIFY, OP_1] + [OP_DUP] * 1000 + [OP_DROP] * 1000)),
# 23) Script that expects an input stack of 1000 elements
("t23", CScript([OP_DROP] * 999 + [pubs[1], OP_CHECKSIG])),
# 24) Script that expects an input stack of 1001 elements
("t24", CScript([OP_DROP] * 1000 + [pubs[1], OP_CHECKSIG])),
# 25) Script that pushes a MAX_SCRIPT_ELEMENT_SIZE-bytes element
("t25", CScript([random.randbytes(MAX_SCRIPT_ELEMENT_SIZE), OP_DROP, pubs[1], OP_CHECKSIG])),
# 26) Script that pushes a (MAX_SCRIPT_ELEMENT_SIZE+1)-bytes element
("t26", CScript([random.randbytes(MAX_SCRIPT_ELEMENT_SIZE+1), OP_DROP, pubs[1], OP_CHECKSIG])),
# 27) CHECKSIGADD that must fail because numeric argument number is >4 bytes
("t27", CScript([CScriptNum(OVERSIZE_NUMBER), pubs[1], OP_CHECKSIGADD])),
# 28) Pushes random CScriptNum value, checks OP_CHECKSIGADD result
("t28", CScript([csa_high_val, pubs[1], OP_CHECKSIGADD, csa_high_result, OP_EQUAL])),
# 29) CHECKSIGADD that succeeds with proper sig because numeric argument number is <=4 bytes
("t29", CScript([CScriptNum(OVERSIZE_NUMBER-1), pubs[1], OP_CHECKSIGADD])),
# 30) Variant of t1 with "normal" 33-byte pubkey
("t30", CScript([b'\x03' + pubs[1], OP_CHECKSIG])),
# 31) Variant of t2 with "normal" 33-byte pubkey
("t31", CScript([b'\x02' + pubs[1], OP_CHECKSIGVERIFY, OP_1])),
# 32) Variant of t28 with "normal" 33-byte pubkey
("t32", CScript([csa_high_val, b'\x03' + pubs[1], OP_CHECKSIGADD, csa_high_result, OP_EQUAL])),
# 33) 999-of-999 multisig
("t33", CScript(big_scriptops[:1998] + [OP_1])),
# 34) 1000-of-1000 multisig
("t34", CScript(big_scriptops[:2000] + [OP_1])),
# 35) Variant of t9 that uses a non-minimally encoded input arg
("t35", CScript([bytes([csa_low_val]), pubs[1], OP_CHECKSIGADD, csa_low_result, OP_EQUAL])),
# 36) Empty script
("t36", CScript([])),
]
# Add many dummies to test huge trees
for j in range(100000):
scripts.append((None, CScript([OP_RETURN, random.randrange(100000)])))
random.shuffle(scripts)
tap = taproot_construct(pubs[0], scripts)