eb882f39f8
This commit corrects several typos in the comments found by misspell.
473 lines
14 KiB
Go
473 lines
14 KiB
Go
// Copyright (c) 2013-2015 The btcsuite developers
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// Use of this source code is governed by an ISC
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// license that can be found in the LICENSE file.
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package txscript
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import (
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"bytes"
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"encoding/binary"
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"fmt"
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"time"
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"github.com/btcsuite/btcd/wire"
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)
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// Bip16Activation is the timestamp where BIP0016 is valid to use in the
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// blockchain. To be used to determine if BIP0016 should be called for or not.
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// This timestamp corresponds to Sun Apr 1 00:00:00 UTC 2012.
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var Bip16Activation = time.Unix(1333238400, 0)
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// SigHashType represents hash type bits at the end of a signature.
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type SigHashType uint32
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// Hash type bits from the end of a signature.
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const (
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SigHashOld SigHashType = 0x0
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SigHashAll SigHashType = 0x1
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SigHashNone SigHashType = 0x2
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SigHashSingle SigHashType = 0x3
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SigHashAnyOneCanPay SigHashType = 0x80
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// sigHashMask defines the number of bits of the hash type which is used
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// to identify which outputs are signed.
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sigHashMask = 0x1f
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)
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// These are the constants specified for maximums in individual scripts.
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const (
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MaxOpsPerScript = 201 // Max number of non-push operations.
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MaxPubKeysPerMultiSig = 20 // Multisig can't have more sigs than this.
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MaxScriptElementSize = 520 // Max bytes pushable to the stack.
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)
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// isSmallInt returns whether or not the opcode is considered a small integer,
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// which is an OP_0, or OP_1 through OP_16.
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func isSmallInt(op *opcode) bool {
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if op.value == OP_0 || (op.value >= OP_1 && op.value <= OP_16) {
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return true
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}
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return false
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}
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// isScriptHash returns true if the script passed is a pay-to-script-hash
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// transaction, false otherwise.
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func isScriptHash(pops []parsedOpcode) bool {
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return len(pops) == 3 &&
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pops[0].opcode.value == OP_HASH160 &&
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pops[1].opcode.value == OP_DATA_20 &&
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pops[2].opcode.value == OP_EQUAL
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}
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// IsPayToScriptHash returns true if the script is in the standard
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// pay-to-script-hash (P2SH) format, false otherwise.
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func IsPayToScriptHash(script []byte) bool {
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pops, err := parseScript(script)
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if err != nil {
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return false
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}
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return isScriptHash(pops)
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}
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// isPushOnly returns true if the script only pushes data, false otherwise.
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func isPushOnly(pops []parsedOpcode) bool {
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// NOTE: This function does NOT verify opcodes directly since it is
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// internal and is only called with parsed opcodes for scripts that did
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// not have any parse errors. Thus, consensus is properly maintained.
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for _, pop := range pops {
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// All opcodes up to OP_16 are data push instructions.
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// NOTE: This does consider OP_RESERVED to be a data push
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// instruction, but execution of OP_RESERVED will fail anyways
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// and matches the behavior required by consensus.
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if pop.opcode.value > OP_16 {
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return false
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}
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}
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return true
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}
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// IsPushOnlyScript returns whether or not the passed script only pushes data.
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//
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// False will be returned when the script does not parse.
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func IsPushOnlyScript(script []byte) bool {
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pops, err := parseScript(script)
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if err != nil {
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return false
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}
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return isPushOnly(pops)
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}
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// parseScriptTemplate is the same as parseScript but allows the passing of the
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// template list for testing purposes. When there are parse errors, it returns
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// the list of parsed opcodes up to the point of failure along with the error.
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func parseScriptTemplate(script []byte, opcodes *[256]opcode) ([]parsedOpcode, error) {
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retScript := make([]parsedOpcode, 0, len(script))
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for i := 0; i < len(script); {
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instr := script[i]
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op := opcodes[instr]
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pop := parsedOpcode{opcode: &op}
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// Parse data out of instruction.
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switch {
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// No additional data. Note that some of the opcodes, notably
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// OP_1NEGATE, OP_0, and OP_[1-16] represent the data
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// themselves.
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case op.length == 1:
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i++
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// Data pushes of specific lengths -- OP_DATA_[1-75].
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case op.length > 1:
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if len(script[i:]) < op.length {
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return retScript, ErrStackShortScript
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}
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// Slice out the data.
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pop.data = script[i+1 : i+op.length]
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i += op.length
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// Data pushes with parsed lengths -- OP_PUSHDATAP{1,2,4}.
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case op.length < 0:
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var l uint
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off := i + 1
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if len(script[off:]) < -op.length {
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return retScript, ErrStackShortScript
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}
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// Next -length bytes are little endian length of data.
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switch op.length {
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case -1:
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l = uint(script[off])
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case -2:
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l = ((uint(script[off+1]) << 8) |
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uint(script[off]))
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case -4:
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l = ((uint(script[off+3]) << 24) |
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(uint(script[off+2]) << 16) |
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(uint(script[off+1]) << 8) |
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uint(script[off]))
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default:
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return retScript,
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fmt.Errorf("invalid opcode length %d",
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op.length)
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}
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// Move offset to beginning of the data.
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off += -op.length
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// Disallow entries that do not fit script or were
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// sign extended.
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if int(l) > len(script[off:]) || int(l) < 0 {
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return retScript, ErrStackShortScript
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}
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pop.data = script[off : off+int(l)]
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i += 1 - op.length + int(l)
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}
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retScript = append(retScript, pop)
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}
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return retScript, nil
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}
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// parseScript preparses the script in bytes into a list of parsedOpcodes while
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// applying a number of sanity checks.
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func parseScript(script []byte) ([]parsedOpcode, error) {
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return parseScriptTemplate(script, &opcodeArray)
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}
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// unparseScript reversed the action of parseScript and returns the
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// parsedOpcodes as a list of bytes
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func unparseScript(pops []parsedOpcode) ([]byte, error) {
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script := make([]byte, 0, len(pops))
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for _, pop := range pops {
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b, err := pop.bytes()
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if err != nil {
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return nil, err
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}
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script = append(script, b...)
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}
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return script, nil
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}
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// DisasmString formats a disassembled script for one line printing. When the
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// script fails to parse, the returned string will contain the disassembled
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// script up to the point the failure occurred along with the string '[error]'
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// appended. In addition, the reason the script failed to parse is returned
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// if the caller wants more information about the failure.
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func DisasmString(buf []byte) (string, error) {
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var disbuf bytes.Buffer
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opcodes, err := parseScript(buf)
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for _, pop := range opcodes {
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disbuf.WriteString(pop.print(true))
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disbuf.WriteByte(' ')
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}
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if disbuf.Len() > 0 {
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disbuf.Truncate(disbuf.Len() - 1)
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}
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if err != nil {
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disbuf.WriteString("[error]")
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}
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return disbuf.String(), err
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}
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// removeOpcode will remove any opcode matching ``opcode'' from the opcode
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// stream in pkscript
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func removeOpcode(pkscript []parsedOpcode, opcode byte) []parsedOpcode {
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retScript := make([]parsedOpcode, 0, len(pkscript))
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for _, pop := range pkscript {
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if pop.opcode.value != opcode {
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retScript = append(retScript, pop)
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}
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}
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return retScript
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}
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// canonicalPush returns true if the object is either not a push instruction
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// or the push instruction contained wherein is matches the canonical form
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// or using the smallest instruction to do the job. False otherwise.
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func canonicalPush(pop parsedOpcode) bool {
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opcode := pop.opcode.value
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data := pop.data
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dataLen := len(pop.data)
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if opcode > OP_16 {
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return true
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}
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if opcode < OP_PUSHDATA1 && opcode > OP_0 && (dataLen == 1 && data[0] <= 16) {
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return false
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}
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if opcode == OP_PUSHDATA1 && dataLen < OP_PUSHDATA1 {
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return false
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}
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if opcode == OP_PUSHDATA2 && dataLen <= 0xff {
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return false
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}
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if opcode == OP_PUSHDATA4 && dataLen <= 0xffff {
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return false
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}
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return true
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}
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// removeOpcodeByData will return the script minus any opcodes that would push
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// the passed data to the stack.
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func removeOpcodeByData(pkscript []parsedOpcode, data []byte) []parsedOpcode {
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retScript := make([]parsedOpcode, 0, len(pkscript))
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for _, pop := range pkscript {
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if !canonicalPush(pop) || !bytes.Contains(pop.data, data) {
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retScript = append(retScript, pop)
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}
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}
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return retScript
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}
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// calcSignatureHash will, given a script and hash type for the current script
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// engine instance, calculate the signature hash to be used for signing and
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// verification.
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func calcSignatureHash(script []parsedOpcode, hashType SigHashType, tx *wire.MsgTx, idx int) []byte {
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// The SigHashSingle signature type signs only the corresponding input
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// and output (the output with the same index number as the input).
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//
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// Since transactions can have more inputs than outputs, this means it
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// is improper to use SigHashSingle on input indices that don't have a
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// corresponding output.
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//
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// A bug in the original Satoshi client implementation means specifying
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// an index that is out of range results in a signature hash of 1 (as a
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// uint256 little endian). The original intent appeared to be to
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// indicate failure, but unfortunately, it was never checked and thus is
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// treated as the actual signature hash. This buggy behavior is now
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// part of the consensus and a hard fork would be required to fix it.
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//
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// Due to this, care must be taken by software that creates transactions
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// which make use of SigHashSingle because it can lead to an extremely
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// dangerous situation where the invalid inputs will end up signing a
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// hash of 1. This in turn presents an opportunity for attackers to
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// cleverly construct transactions which can steal those coins provided
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// they can reuse signatures.
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if hashType&sigHashMask == SigHashSingle && idx >= len(tx.TxOut) {
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var hash wire.ShaHash
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hash[0] = 0x01
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return hash[:]
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}
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// Remove all instances of OP_CODESEPARATOR from the script.
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script = removeOpcode(script, OP_CODESEPARATOR)
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// Make a deep copy of the transaction, zeroing out the script for all
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// inputs that are not currently being processed.
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txCopy := tx.Copy()
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for i := range txCopy.TxIn {
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if i == idx {
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// UnparseScript cannot fail here because removeOpcode
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// above only returns a valid script.
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sigScript, _ := unparseScript(script)
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txCopy.TxIn[idx].SignatureScript = sigScript
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} else {
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txCopy.TxIn[i].SignatureScript = nil
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}
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}
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switch hashType & sigHashMask {
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case SigHashNone:
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txCopy.TxOut = txCopy.TxOut[0:0] // Empty slice.
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for i := range txCopy.TxIn {
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if i != idx {
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txCopy.TxIn[i].Sequence = 0
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}
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}
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case SigHashSingle:
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// Resize output array to up to and including requested index.
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txCopy.TxOut = txCopy.TxOut[:idx+1]
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// All but current output get zeroed out.
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for i := 0; i < idx; i++ {
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txCopy.TxOut[i].Value = -1
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txCopy.TxOut[i].PkScript = nil
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}
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// Sequence on all other inputs is 0, too.
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for i := range txCopy.TxIn {
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if i != idx {
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txCopy.TxIn[i].Sequence = 0
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}
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}
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default:
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// Consensus treats undefined hashtypes like normal SigHashAll
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// for purposes of hash generation.
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fallthrough
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case SigHashOld:
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fallthrough
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case SigHashAll:
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// Nothing special here.
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}
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if hashType&SigHashAnyOneCanPay != 0 {
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txCopy.TxIn = txCopy.TxIn[idx : idx+1]
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idx = 0
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}
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// The final hash is the double sha256 of both the serialized modified
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// transaction and the hash type (encoded as a 4-byte little-endian
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// value) appended.
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var wbuf bytes.Buffer
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txCopy.Serialize(&wbuf)
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binary.Write(&wbuf, binary.LittleEndian, hashType)
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return wire.DoubleSha256(wbuf.Bytes())
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}
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// asSmallInt returns the passed opcode, which must be true according to
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// isSmallInt(), as an integer.
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func asSmallInt(op *opcode) int {
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if op.value == OP_0 {
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return 0
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}
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return int(op.value - (OP_1 - 1))
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}
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// getSigOpCount is the implementation function for counting the number of
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// signature operations in the script provided by pops. If precise mode is
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// requested then we attempt to count the number of operations for a multisig
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// op. Otherwise we use the maximum.
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func getSigOpCount(pops []parsedOpcode, precise bool) int {
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nSigs := 0
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for i, pop := range pops {
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switch pop.opcode.value {
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case OP_CHECKSIG:
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fallthrough
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case OP_CHECKSIGVERIFY:
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nSigs++
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case OP_CHECKMULTISIG:
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fallthrough
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case OP_CHECKMULTISIGVERIFY:
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// If we are being precise then look for familiar
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// patterns for multisig, for now all we recognize is
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// OP_1 - OP_16 to signify the number of pubkeys.
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// Otherwise, we use the max of 20.
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if precise && i > 0 &&
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pops[i-1].opcode.value >= OP_1 &&
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pops[i-1].opcode.value <= OP_16 {
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nSigs += asSmallInt(pops[i-1].opcode)
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} else {
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nSigs += MaxPubKeysPerMultiSig
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}
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default:
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// Not a sigop.
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}
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}
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return nSigs
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}
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// GetSigOpCount provides a quick count of the number of signature operations
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// in a script. a CHECKSIG operations counts for 1, and a CHECK_MULTISIG for 20.
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// If the script fails to parse, then the count up to the point of failure is
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// returned.
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func GetSigOpCount(script []byte) int {
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// Don't check error since parseScript returns the parsed-up-to-error
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// list of pops.
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pops, _ := parseScript(script)
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return getSigOpCount(pops, false)
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}
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// GetPreciseSigOpCount returns the number of signature operations in
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// scriptPubKey. If bip16 is true then scriptSig may be searched for the
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// Pay-To-Script-Hash script in order to find the precise number of signature
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// operations in the transaction. If the script fails to parse, then the count
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// up to the point of failure is returned.
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func GetPreciseSigOpCount(scriptSig, scriptPubKey []byte, bip16 bool) int {
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// Don't check error since parseScript returns the parsed-up-to-error
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// list of pops.
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pops, _ := parseScript(scriptPubKey)
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// Treat non P2SH transactions as normal.
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if !(bip16 && isScriptHash(pops)) {
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return getSigOpCount(pops, true)
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}
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// The public key script is a pay-to-script-hash, so parse the signature
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// script to get the final item. Scripts that fail to fully parse count
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// as 0 signature operations.
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sigPops, err := parseScript(scriptSig)
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if err != nil {
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return 0
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}
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// The signature script must only push data to the stack for P2SH to be
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// a valid pair, so the signature operation count is 0 when that is not
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// the case.
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if !isPushOnly(sigPops) || len(sigPops) == 0 {
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return 0
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}
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// The P2SH script is the last item the signature script pushes to the
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// stack. When the script is empty, there are no signature operations.
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shScript := sigPops[len(sigPops)-1].data
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if len(shScript) == 0 {
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return 0
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}
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// Parse the P2SH script and don't check the error since parseScript
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// returns the parsed-up-to-error list of pops and the consensus rules
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// dictate signature operations are counted up to the first parse
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// failure.
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shPops, _ := parseScript(shScript)
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return getSigOpCount(shPops, true)
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}
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// IsUnspendable returns whether the passed public key script is unspendable, or
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// guaranteed to fail at execution. This allows inputs to be pruned instantly
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// when entering the UTXO set.
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func IsUnspendable(pkScript []byte) bool {
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pops, err := parseScript(pkScript)
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if err != nil {
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return true
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}
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return len(pops) > 0 && pops[0].opcode.value == OP_RETURN
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}
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