// Copyright (c) 2013-2018 The btcsuite developers // Copyright (c) 2015-2018 The Decred developers // Use of this source code is governed by an ISC // license that can be found in the LICENSE file. package txscript import ( "bytes" "crypto/sha256" "fmt" "math/big" "strings" "github.com/btcsuite/btcd/btcec" "github.com/btcsuite/btcd/wire" ) // ScriptFlags is a bitmask defining additional operations or tests that will be // done when executing a script pair. type ScriptFlags uint32 const ( // ScriptBip16 defines whether the bip16 threshold has passed and thus // pay-to-script hash transactions will be fully validated. ScriptBip16 ScriptFlags = 1 << iota // ScriptStrictMultiSig defines whether to verify the stack item // used by CHECKMULTISIG is zero length. ScriptStrictMultiSig // ScriptDiscourageUpgradableNops defines whether to verify that // NOP1 through NOP10 are reserved for future soft-fork upgrades. This // flag must not be used for consensus critical code nor applied to // blocks as this flag is only for stricter standard transaction // checks. This flag is only applied when the above opcodes are // executed. ScriptDiscourageUpgradableNops // ScriptVerifyCheckLockTimeVerify defines whether to verify that // a transaction output is spendable based on the locktime. // This is BIP0065. ScriptVerifyCheckLockTimeVerify // ScriptVerifyCheckSequenceVerify defines whether to allow execution // pathways of a script to be restricted based on the age of the output // being spent. This is BIP0112. ScriptVerifyCheckSequenceVerify // ScriptVerifyCleanStack defines that the stack must contain only // one stack element after evaluation and that the element must be // true if interpreted as a boolean. This is rule 6 of BIP0062. // This flag should never be used without the ScriptBip16 flag nor the // ScriptVerifyWitness flag. ScriptVerifyCleanStack // ScriptVerifyDERSignatures defines that signatures are required // to compily with the DER format. ScriptVerifyDERSignatures // ScriptVerifyLowS defines that signtures are required to comply with // the DER format and whose S value is <= order / 2. This is rule 5 // of BIP0062. ScriptVerifyLowS // ScriptVerifyMinimalData defines that signatures must use the smallest // push operator. This is both rules 3 and 4 of BIP0062. ScriptVerifyMinimalData // ScriptVerifyNullFail defines that signatures must be empty if // a CHECKSIG or CHECKMULTISIG operation fails. ScriptVerifyNullFail // ScriptVerifySigPushOnly defines that signature scripts must contain // only pushed data. This is rule 2 of BIP0062. ScriptVerifySigPushOnly // ScriptVerifyStrictEncoding defines that signature scripts and // public keys must follow the strict encoding requirements. ScriptVerifyStrictEncoding // ScriptVerifyWitness defines whether or not to verify a transaction // output using a witness program template. ScriptVerifyWitness // ScriptVerifyDiscourageUpgradeableWitnessProgram makes witness // program with versions 2-16 non-standard. ScriptVerifyDiscourageUpgradeableWitnessProgram // ScriptVerifyMinimalIf makes a script with an OP_IF/OP_NOTIF whose // operand is anything other than empty vector or [0x01] non-standard. ScriptVerifyMinimalIf // ScriptVerifyWitnessPubKeyType makes a script within a check-sig // operation whose public key isn't serialized in a compressed format // non-standard. ScriptVerifyWitnessPubKeyType ) const ( // MaxStackSize is the maximum combined height of stack and alt stack // during execution. MaxStackSize = 1000 // MaxScriptSize is the maximum allowed length of a raw script. MaxScriptSize = 10000 // payToWitnessPubKeyHashDataSize is the size of the witness program's // data push for a pay-to-witness-pub-key-hash output. payToWitnessPubKeyHashDataSize = 20 // payToWitnessScriptHashDataSize is the size of the witness program's // data push for a pay-to-witness-script-hash output. payToWitnessScriptHashDataSize = 32 ) // halforder is used to tame ECDSA malleability (see BIP0062). var halfOrder = new(big.Int).Rsh(btcec.S256().N, 1) // Engine is the virtual machine that executes scripts. type Engine struct { // The following fields are set when the engine is created and must not be // changed afterwards. The entries of the signature cache are mutated // during execution, however, the cache pointer itself is not changed. // // flags specifies the additional flags which modify the execution behavior // of the engine. // // tx identifies the transaction that contains the input which in turn // contains the signature script being executed. // // txIdx identifies the input index within the transaction that contains // the signature script being executed. // // version specifies the version of the public key script to execute. Since // signature scripts redeem public keys scripts, this means the same version // also extends to signature scripts and redeem scripts in the case of // pay-to-script-hash. // // bip16 specifies that the public key script is of a special form that // indicates it is a BIP16 pay-to-script-hash and therefore the // execution must be treated as such. // // sigCache caches the results of signature verifications. This is useful // since transaction scripts are often executed more than once from various // contexts (e.g. new block templates, when transactions are first seen // prior to being mined, part of full block verification, etc). flags ScriptFlags tx wire.MsgTx txIdx int version uint16 bip16 bool sigCache *SigCache hashCache *TxSigHashes // The following fields handle keeping track of the current execution state // of the engine. // // scripts houses the raw scripts that are executed by the engine. This // includes the signature script as well as the public key script. It also // includes the redeem script in the case of pay-to-script-hash. // // scriptIdx tracks the index into the scripts array for the current program // counter. // // opcodeIdx tracks the number of the opcode within the current script for // the current program counter. Note that it differs from the actual byte // index into the script and is really only used for disassembly purposes. // // lastCodeSep specifies the position within the current script of the last // OP_CODESEPARATOR. // // tokenizer provides the token stream of the current script being executed // and doubles as state tracking for the program counter within the script. // // savedFirstStack keeps a copy of the stack from the first script when // performing pay-to-script-hash execution. // // dstack is the primary data stack the various opcodes push and pop data // to and from during execution. // // astack is the alternate data stack the various opcodes push and pop data // to and from during execution. // // condStack tracks the conditional execution state with support for // multiple nested conditional execution opcodes. // // numOps tracks the total number of non-push operations in a script and is // primarily used to enforce maximum limits. scripts [][]byte scriptIdx int opcodeIdx int lastCodeSep int tokenizer ScriptTokenizer savedFirstStack [][]byte dstack stack astack stack condStack []int numOps int witnessVersion int witnessProgram []byte inputAmount int64 } // hasFlag returns whether the script engine instance has the passed flag set. func (vm *Engine) hasFlag(flag ScriptFlags) bool { return vm.flags&flag == flag } // isBranchExecuting returns whether or not the current conditional branch is // actively executing. For example, when the data stack has an OP_FALSE on it // and an OP_IF is encountered, the branch is inactive until an OP_ELSE or // OP_ENDIF is encountered. It properly handles nested conditionals. func (vm *Engine) isBranchExecuting() bool { if len(vm.condStack) == 0 { return true } return vm.condStack[len(vm.condStack)-1] == OpCondTrue } // isOpcodeDisabled returns whether or not the opcode is disabled and thus is // always bad to see in the instruction stream (even if turned off by a // conditional). func isOpcodeDisabled(opcode byte) bool { switch opcode { case OP_CAT: return true case OP_SUBSTR: return true case OP_LEFT: return true case OP_RIGHT: return true case OP_INVERT: return true case OP_AND: return true case OP_OR: return true case OP_XOR: return true case OP_2MUL: return true case OP_2DIV: return true case OP_MUL: return true case OP_DIV: return true case OP_MOD: return true case OP_LSHIFT: return true case OP_RSHIFT: return true default: return false } } // isOpcodeAlwaysIllegal returns whether or not the opcode is always illegal // when passed over by the program counter even if in a non-executed branch (it // isn't a coincidence that they are conditionals). func isOpcodeAlwaysIllegal(opcode byte) bool { switch opcode { case OP_VERIF: return true case OP_VERNOTIF: return true default: return false } } // isOpcodeConditional returns whether or not the opcode is a conditional opcode // which changes the conditional execution stack when executed. func isOpcodeConditional(opcode byte) bool { switch opcode { case OP_IF: return true case OP_NOTIF: return true case OP_ELSE: return true case OP_ENDIF: return true default: return false } } // checkMinimalDataPush returns whether or not the provided opcode is the // smallest possible way to represent the given data. For example, the value 15 // could be pushed with OP_DATA_1 15 (among other variations); however, OP_15 is // a single opcode that represents the same value and is only a single byte // versus two bytes. func checkMinimalDataPush(op *opcode, data []byte) error { opcodeVal := op.value dataLen := len(data) switch { case dataLen == 0 && opcodeVal != OP_0: str := fmt.Sprintf("zero length data push is encoded with opcode %s "+ "instead of OP_0", op.name) return scriptError(ErrMinimalData, str) case dataLen == 1 && data[0] >= 1 && data[0] <= 16: if opcodeVal != OP_1+data[0]-1 { // Should have used OP_1 .. OP_16 str := fmt.Sprintf("data push of the value %d encoded with opcode "+ "%s instead of OP_%d", data[0], op.name, data[0]) return scriptError(ErrMinimalData, str) } case dataLen == 1 && data[0] == 0x81: if opcodeVal != OP_1NEGATE { str := fmt.Sprintf("data push of the value -1 encoded with opcode "+ "%s instead of OP_1NEGATE", op.name) return scriptError(ErrMinimalData, str) } case dataLen <= 75: if int(opcodeVal) != dataLen { // Should have used a direct push str := fmt.Sprintf("data push of %d bytes encoded with opcode %s "+ "instead of OP_DATA_%d", dataLen, op.name, dataLen) return scriptError(ErrMinimalData, str) } case dataLen <= 255: if opcodeVal != OP_PUSHDATA1 { str := fmt.Sprintf("data push of %d bytes encoded with opcode %s "+ "instead of OP_PUSHDATA1", dataLen, op.name) return scriptError(ErrMinimalData, str) } case dataLen <= 65535: if opcodeVal != OP_PUSHDATA2 { str := fmt.Sprintf("data push of %d bytes encoded with opcode %s "+ "instead of OP_PUSHDATA2", dataLen, op.name) return scriptError(ErrMinimalData, str) } } return nil } // executeOpcode peforms execution on the passed opcode. It takes into account // whether or not it is hidden by conditionals, but some rules still must be // tested in this case. func (vm *Engine) executeOpcode(pop *parsedOpcode) error { // Disabled opcodes are fail on program counter. if isOpcodeDisabled(pop.opcode.value) { str := fmt.Sprintf("attempt to execute disabled opcode %s", pop.opcode.name) return scriptError(ErrDisabledOpcode, str) } // Always-illegal opcodes are fail on program counter. if isOpcodeAlwaysIllegal(pop.opcode.value) { str := fmt.Sprintf("attempt to execute reserved opcode %s", pop.opcode.name) return scriptError(ErrReservedOpcode, str) } // Note that this includes OP_RESERVED which counts as a push operation. if pop.opcode.value > OP_16 { vm.numOps++ if vm.numOps > MaxOpsPerScript { str := fmt.Sprintf("exceeded max operation limit of %d", MaxOpsPerScript) return scriptError(ErrTooManyOperations, str) } } else if len(pop.data) > MaxScriptElementSize { str := fmt.Sprintf("element size %d exceeds max allowed size %d", len(pop.data), MaxScriptElementSize) return scriptError(ErrElementTooBig, str) } // Nothing left to do when this is not a conditional opcode and it is // not in an executing branch. if !vm.isBranchExecuting() && !isOpcodeConditional(pop.opcode.value) { return nil } // Ensure all executed data push opcodes use the minimal encoding when // the minimal data verification flag is set. if vm.dstack.verifyMinimalData && vm.isBranchExecuting() && pop.opcode.value >= 0 && pop.opcode.value <= OP_PUSHDATA4 { if err := checkMinimalDataPush(pop.opcode, pop.data); err != nil { return err } } return pop.opcode.opfunc(pop, vm) } // checkValidPC returns an error if the current script position is not valid for // execution. func (vm *Engine) checkValidPC() error { if vm.scriptIdx >= len(vm.scripts) { str := fmt.Sprintf("script index %d beyond total scripts %d", vm.scriptIdx, len(vm.scripts)) return scriptError(ErrInvalidProgramCounter, str) } return nil } // isWitnessVersionActive returns true if a witness program was extracted // during the initialization of the Engine, and the program's version matches // the specified version. func (vm *Engine) isWitnessVersionActive(version uint) bool { return vm.witnessProgram != nil && uint(vm.witnessVersion) == version } // verifyWitnessProgram validates the stored witness program using the passed // witness as input. func (vm *Engine) verifyWitnessProgram(witness [][]byte) error { if vm.isWitnessVersionActive(0) { switch len(vm.witnessProgram) { case payToWitnessPubKeyHashDataSize: // P2WKH // The witness stack should consist of exactly two // items: the signature, and the pubkey. if len(witness) != 2 { err := fmt.Sprintf("should have exactly two "+ "items in witness, instead have %v", len(witness)) return scriptError(ErrWitnessProgramMismatch, err) } // Now we'll resume execution as if it were a regular // p2pkh transaction. pkScript, err := payToPubKeyHashScript(vm.witnessProgram) if err != nil { return err } const scriptVersion = 0 err = checkScriptParses(vm.version, pkScript) if err != nil { return err } // Set the stack to the provided witness stack, then // append the pkScript generated above as the next // script to execute. vm.scripts = append(vm.scripts, pkScript) vm.SetStack(witness) case payToWitnessScriptHashDataSize: // P2WSH // Additionally, The witness stack MUST NOT be empty at // this point. if len(witness) == 0 { return scriptError(ErrWitnessProgramEmpty, "witness "+ "program empty passed empty witness") } // Obtain the witness script which should be the last // element in the passed stack. The size of the script // MUST NOT exceed the max script size. witnessScript := witness[len(witness)-1] if len(witnessScript) > MaxScriptSize { str := fmt.Sprintf("witnessScript size %d "+ "is larger than max allowed size %d", len(witnessScript), MaxScriptSize) return scriptError(ErrScriptTooBig, str) } // Ensure that the serialized pkScript at the end of // the witness stack matches the witness program. witnessHash := sha256.Sum256(witnessScript) if !bytes.Equal(witnessHash[:], vm.witnessProgram) { return scriptError(ErrWitnessProgramMismatch, "witness program hash mismatch") } // With all the validity checks passed, assert that the // script parses without failure. const scriptVersion = 0 err := checkScriptParses(vm.version, witnessScript) if err != nil { return err } // The hash matched successfully, so use the witness as // the stack, and set the witnessScript to be the next // script executed. vm.scripts = append(vm.scripts, witnessScript) vm.SetStack(witness[:len(witness)-1]) default: errStr := fmt.Sprintf("length of witness program "+ "must either be %v or %v bytes, instead is %v bytes", payToWitnessPubKeyHashDataSize, payToWitnessScriptHashDataSize, len(vm.witnessProgram)) return scriptError(ErrWitnessProgramWrongLength, errStr) } } else if vm.hasFlag(ScriptVerifyDiscourageUpgradeableWitnessProgram) { errStr := fmt.Sprintf("new witness program versions "+ "invalid: %v", vm.witnessProgram) return scriptError(ErrDiscourageUpgradableWitnessProgram, errStr) } else { // If we encounter an unknown witness program version and we // aren't discouraging future unknown witness based soft-forks, // then we de-activate the segwit behavior within the VM for // the remainder of execution. vm.witnessProgram = nil } if vm.isWitnessVersionActive(0) { // All elements within the witness stack must not be greater // than the maximum bytes which are allowed to be pushed onto // the stack. for _, witElement := range vm.GetStack() { if len(witElement) > MaxScriptElementSize { str := fmt.Sprintf("element size %d exceeds "+ "max allowed size %d", len(witElement), MaxScriptElementSize) return scriptError(ErrElementTooBig, str) } } } return nil } // DisasmPC returns the string for the disassembly of the opcode that will be // next to execute when Step is called. func (vm *Engine) DisasmPC() (string, error) { if err := vm.checkValidPC(); err != nil { return "", err } // Create a copy of the current tokenizer and parse the next opcode in the // copy to avoid mutating the current one. peekTokenizer := vm.tokenizer if !peekTokenizer.Next() { // Note that due to the fact that all scripts are checked for parse // failures before this code ever runs, there should never be an error // here, but check again to be safe in case a refactor breaks that // assumption or new script versions are introduced with different // semantics. if err := peekTokenizer.Err(); err != nil { return "", err } // Note that this should be impossible to hit in practice because the // only way it could happen would be for the final opcode of a script to // already be parsed without the script index having been updated, which // is not the case since stepping the script always increments the // script index when parsing and executing the final opcode of a script. // // However, check again to be safe in case a refactor breaks that // assumption or new script versions are introduced with different // semantics. str := fmt.Sprintf("program counter beyond script index %d (bytes %x)", vm.scriptIdx, vm.scripts[vm.scriptIdx]) return "", scriptError(ErrInvalidProgramCounter, str) } var buf strings.Builder disasmOpcode(&buf, peekTokenizer.op, peekTokenizer.Data(), false) return fmt.Sprintf("%02x:%04x: %s", vm.scriptIdx, vm.opcodeIdx, buf.String()), nil } // DisasmScript returns the disassembly string for the script at the requested // offset index. Index 0 is the signature script and 1 is the public key // script. In the case of pay-to-script-hash, index 2 is the redeem script once // the execution has progressed far enough to have successfully verified script // hash and thus add the script to the scripts to execute. func (vm *Engine) DisasmScript(idx int) (string, error) { if idx >= len(vm.scripts) { str := fmt.Sprintf("script index %d >= total scripts %d", idx, len(vm.scripts)) return "", scriptError(ErrInvalidIndex, str) } var disbuf strings.Builder script := vm.scripts[idx] tokenizer := MakeScriptTokenizer(vm.version, script) var opcodeIdx int for tokenizer.Next() { disbuf.WriteString(fmt.Sprintf("%02x:%04x: ", idx, opcodeIdx)) disasmOpcode(&disbuf, tokenizer.op, tokenizer.Data(), false) disbuf.WriteByte('\n') opcodeIdx++ } return disbuf.String(), tokenizer.Err() } // CheckErrorCondition returns nil if the running script has ended and was // successful, leaving a a true boolean on the stack. An error otherwise, // including if the script has not finished. func (vm *Engine) CheckErrorCondition(finalScript bool) error { // Check execution is actually done by ensuring the script index is after // the final script in the array script. if vm.scriptIdx < len(vm.scripts) { return scriptError(ErrScriptUnfinished, "error check when script unfinished") } // If we're in version zero witness execution mode, and this was the // final script, then the stack MUST be clean in order to maintain // compatibility with BIP16. if finalScript && vm.isWitnessVersionActive(0) && vm.dstack.Depth() != 1 { return scriptError(ErrEvalFalse, "witness program must "+ "have clean stack") } // The final script must end with exactly one data stack item when the // verify clean stack flag is set. Otherwise, there must be at least one // data stack item in order to interpret it as a boolean. if finalScript && vm.hasFlag(ScriptVerifyCleanStack) && vm.dstack.Depth() != 1 { str := fmt.Sprintf("stack must contain exactly one item (contains %d)", vm.dstack.Depth()) return scriptError(ErrCleanStack, str) } else if vm.dstack.Depth() < 1 { return scriptError(ErrEmptyStack, "stack empty at end of script execution") } v, err := vm.dstack.PopBool() if err != nil { return err } if !v { // Log interesting data. log.Tracef("%v", newLogClosure(func() string { var buf strings.Builder buf.WriteString("scripts failed:\n") for i := range vm.scripts { dis, _ := vm.DisasmScript(i) buf.WriteString(fmt.Sprintf("script%d:\n", i)) buf.WriteString(dis) } return buf.String() })) return scriptError(ErrEvalFalse, "false stack entry at end of script execution") } return nil } // Step executes the next instruction and moves the program counter to the next // opcode in the script, or the next script if the current has ended. Step will // return true in the case that the last opcode was successfully executed. // // The result of calling Step or any other method is undefined if an error is // returned. func (vm *Engine) Step() (done bool, err error) { // Verify the engine is pointing to a valid program counter. if err := vm.checkValidPC(); err != nil { return true, err } // Attempt to parse the next opcode from the current script. if !vm.tokenizer.Next() { // Note that due to the fact that all scripts are checked for parse // failures before this code ever runs, there should never be an error // here, but check again to be safe in case a refactor breaks that // assumption or new script versions are introduced with different // semantics. if err := vm.tokenizer.Err(); err != nil { return false, err } str := fmt.Sprintf("attempt to step beyond script index %d (bytes %x)", vm.scriptIdx, vm.scripts[vm.scriptIdx]) return true, scriptError(ErrInvalidProgramCounter, str) } // Execute the opcode while taking into account several things such as // disabled opcodes, illegal opcodes, maximum allowed operations per script, // maximum script element sizes, and conditionals. pop := parsedOpcode{opcode: vm.tokenizer.op, data: vm.tokenizer.Data()} err = vm.executeOpcode(&pop) if err != nil { return true, err } // The number of elements in the combination of the data and alt stacks // must not exceed the maximum number of stack elements allowed. combinedStackSize := vm.dstack.Depth() + vm.astack.Depth() if combinedStackSize > MaxStackSize { str := fmt.Sprintf("combined stack size %d > max allowed %d", combinedStackSize, MaxStackSize) return false, scriptError(ErrStackOverflow, str) } // Prepare for next instruction. vm.opcodeIdx++ if vm.tokenizer.Done() { // Illegal to have a conditional that straddles two scripts. if len(vm.condStack) != 0 { return false, scriptError(ErrUnbalancedConditional, "end of script reached in conditional execution") } // Alt stack doesn't persist between scripts. _ = vm.astack.DropN(vm.astack.Depth()) // The number of operations is per script. vm.numOps = 0 // Reset the opcode index for the next script. vm.opcodeIdx = 0 // Advance to the next script as needed. switch { case vm.scriptIdx == 0 && vm.bip16: vm.scriptIdx++ vm.savedFirstStack = vm.GetStack() case vm.scriptIdx == 1 && vm.bip16: // Put us past the end for CheckErrorCondition() vm.scriptIdx++ // Check script ran successfully. err := vm.CheckErrorCondition(false) if err != nil { return false, err } // Obtain the redeem script from the first stack and ensure it // parses. script := vm.savedFirstStack[len(vm.savedFirstStack)-1] if err := checkScriptParses(vm.version, script); err != nil { return false, err } vm.scripts = append(vm.scripts, script) // Set stack to be the stack from first script minus the redeem // script itself vm.SetStack(vm.savedFirstStack[:len(vm.savedFirstStack)-1]) case vm.scriptIdx == 1 && vm.witnessProgram != nil, vm.scriptIdx == 2 && vm.witnessProgram != nil && vm.bip16: // np2sh vm.scriptIdx++ witness := vm.tx.TxIn[vm.txIdx].Witness if err := vm.verifyWitnessProgram(witness); err != nil { return false, err } default: vm.scriptIdx++ } // Skip empty scripts. if vm.scriptIdx < len(vm.scripts) && len(vm.scripts[vm.scriptIdx]) == 0 { vm.scriptIdx++ } vm.lastCodeSep = 0 if vm.scriptIdx >= len(vm.scripts) { return true, nil } // Finally, update the current tokenizer used to parse through scripts // one opcode at a time to start from the beginning of the new script // associated with the program counter. vm.tokenizer = MakeScriptTokenizer(vm.version, vm.scripts[vm.scriptIdx]) } return false, nil } // Execute will execute all scripts in the script engine and return either nil // for successful validation or an error if one occurred. func (vm *Engine) Execute() (err error) { // All script versions other than 0 currently execute without issue, // making all outputs to them anyone can pay. In the future this // will allow for the addition of new scripting languages. if vm.version != 0 { return nil } done := false for !done { log.Tracef("%v", newLogClosure(func() string { dis, err := vm.DisasmPC() if err != nil { return fmt.Sprintf("stepping - failed to disasm pc: %v", err) } return fmt.Sprintf("stepping %v", dis) })) done, err = vm.Step() if err != nil { return err } log.Tracef("%v", newLogClosure(func() string { var dstr, astr string // Log the non-empty stacks when tracing. if vm.dstack.Depth() != 0 { dstr = "Stack:\n" + vm.dstack.String() } if vm.astack.Depth() != 0 { astr = "AltStack:\n" + vm.astack.String() } return dstr + astr })) } return vm.CheckErrorCondition(true) } // subScript returns the script since the last OP_CODESEPARATOR. func (vm *Engine) subScript() []byte { return vm.scripts[vm.scriptIdx][vm.lastCodeSep:] } // checkHashTypeEncoding returns whether or not the passed hashtype adheres to // the strict encoding requirements if enabled. func (vm *Engine) checkHashTypeEncoding(hashType SigHashType) error { if !vm.hasFlag(ScriptVerifyStrictEncoding) { return nil } sigHashType := hashType & ^SigHashAnyOneCanPay if sigHashType < SigHashAll || sigHashType > SigHashSingle { str := fmt.Sprintf("invalid hash type 0x%x", hashType) return scriptError(ErrInvalidSigHashType, str) } return nil } // isStrictPubKeyEncoding returns whether or not the passed public key adheres // to the strict encoding requirements. func isStrictPubKeyEncoding(pubKey []byte) bool { if len(pubKey) == 33 && (pubKey[0] == 0x02 || pubKey[0] == 0x03) { // Compressed return true } if len(pubKey) == 65 { switch pubKey[0] { case 0x04: // Uncompressed return true case 0x06, 0x07: // Hybrid return true } } return false } // checkPubKeyEncoding returns whether or not the passed public key adheres to // the strict encoding requirements if enabled. func (vm *Engine) checkPubKeyEncoding(pubKey []byte) error { if vm.hasFlag(ScriptVerifyWitnessPubKeyType) && vm.isWitnessVersionActive(0) && !btcec.IsCompressedPubKey(pubKey) { str := "only compressed keys are accepted post-segwit" return scriptError(ErrWitnessPubKeyType, str) } if !vm.hasFlag(ScriptVerifyStrictEncoding) { return nil } if len(pubKey) == 33 && (pubKey[0] == 0x02 || pubKey[0] == 0x03) { // Compressed return nil } if len(pubKey) == 65 && pubKey[0] == 0x04 { // Uncompressed return nil } return scriptError(ErrPubKeyType, "unsupported public key type") } // checkSignatureEncoding returns whether or not the passed signature adheres to // the strict encoding requirements if enabled. func (vm *Engine) checkSignatureEncoding(sig []byte) error { if !vm.hasFlag(ScriptVerifyDERSignatures) && !vm.hasFlag(ScriptVerifyLowS) && !vm.hasFlag(ScriptVerifyStrictEncoding) { return nil } // The format of a DER encoded signature is as follows: // // 0x30 0x02 0x02 // - 0x30 is the ASN.1 identifier for a sequence // - Total length is 1 byte and specifies length of all remaining data // - 0x02 is the ASN.1 identifier that specifies an integer follows // - Length of R is 1 byte and specifies how many bytes R occupies // - R is the arbitrary length big-endian encoded number which // represents the R value of the signature. DER encoding dictates // that the value must be encoded using the minimum possible number // of bytes. This implies the first byte can only be null if the // highest bit of the next byte is set in order to prevent it from // being interpreted as a negative number. // - 0x02 is once again the ASN.1 integer identifier // - Length of S is 1 byte and specifies how many bytes S occupies // - S is the arbitrary length big-endian encoded number which // represents the S value of the signature. The encoding rules are // identical as those for R. const ( asn1SequenceID = 0x30 asn1IntegerID = 0x02 // minSigLen is the minimum length of a DER encoded signature and is // when both R and S are 1 byte each. // // 0x30 + <1-byte> + 0x02 + 0x01 + + 0x2 + 0x01 + minSigLen = 8 // maxSigLen is the maximum length of a DER encoded signature and is // when both R and S are 33 bytes each. It is 33 bytes because a // 256-bit integer requires 32 bytes and an additional leading null byte // might required if the high bit is set in the value. // // 0x30 + <1-byte> + 0x02 + 0x21 + <33 bytes> + 0x2 + 0x21 + <33 bytes> maxSigLen = 72 // sequenceOffset is the byte offset within the signature of the // expected ASN.1 sequence identifier. sequenceOffset = 0 // dataLenOffset is the byte offset within the signature of the expected // total length of all remaining data in the signature. dataLenOffset = 1 // rTypeOffset is the byte offset within the signature of the ASN.1 // identifier for R and is expected to indicate an ASN.1 integer. rTypeOffset = 2 // rLenOffset is the byte offset within the signature of the length of // R. rLenOffset = 3 // rOffset is the byte offset within the signature of R. rOffset = 4 ) // The signature must adhere to the minimum and maximum allowed length. sigLen := len(sig) if sigLen < minSigLen { str := fmt.Sprintf("malformed signature: too short: %d < %d", sigLen, minSigLen) return scriptError(ErrSigTooShort, str) } if sigLen > maxSigLen { str := fmt.Sprintf("malformed signature: too long: %d > %d", sigLen, maxSigLen) return scriptError(ErrSigTooLong, str) } // The signature must start with the ASN.1 sequence identifier. if sig[sequenceOffset] != asn1SequenceID { str := fmt.Sprintf("malformed signature: format has wrong type: %#x", sig[sequenceOffset]) return scriptError(ErrSigInvalidSeqID, str) } // The signature must indicate the correct amount of data for all elements // related to R and S. if int(sig[dataLenOffset]) != sigLen-2 { str := fmt.Sprintf("malformed signature: bad length: %d != %d", sig[dataLenOffset], sigLen-2) return scriptError(ErrSigInvalidDataLen, str) } // Calculate the offsets of the elements related to S and ensure S is inside // the signature. // // rLen specifies the length of the big-endian encoded number which // represents the R value of the signature. // // sTypeOffset is the offset of the ASN.1 identifier for S and, like its R // counterpart, is expected to indicate an ASN.1 integer. // // sLenOffset and sOffset are the byte offsets within the signature of the // length of S and S itself, respectively. rLen := int(sig[rLenOffset]) sTypeOffset := rOffset + rLen sLenOffset := sTypeOffset + 1 if sTypeOffset >= sigLen { str := "malformed signature: S type indicator missing" return scriptError(ErrSigMissingSTypeID, str) } if sLenOffset >= sigLen { str := "malformed signature: S length missing" return scriptError(ErrSigMissingSLen, str) } // The lengths of R and S must match the overall length of the signature. // // sLen specifies the length of the big-endian encoded number which // represents the S value of the signature. sOffset := sLenOffset + 1 sLen := int(sig[sLenOffset]) if sOffset+sLen != sigLen { str := "malformed signature: invalid S length" return scriptError(ErrSigInvalidSLen, str) } // R elements must be ASN.1 integers. if sig[rTypeOffset] != asn1IntegerID { str := fmt.Sprintf("malformed signature: R integer marker: %#x != %#x", sig[rTypeOffset], asn1IntegerID) return scriptError(ErrSigInvalidRIntID, str) } // Zero-length integers are not allowed for R. if rLen == 0 { str := "malformed signature: R length is zero" return scriptError(ErrSigZeroRLen, str) } // R must not be negative. if sig[rOffset]&0x80 != 0 { str := "malformed signature: R is negative" return scriptError(ErrSigNegativeR, str) } // Null bytes at the start of R are not allowed, unless R would otherwise be // interpreted as a negative number. if rLen > 1 && sig[rOffset] == 0x00 && sig[rOffset+1]&0x80 == 0 { str := "malformed signature: R value has too much padding" return scriptError(ErrSigTooMuchRPadding, str) } // S elements must be ASN.1 integers. if sig[sTypeOffset] != asn1IntegerID { str := fmt.Sprintf("malformed signature: S integer marker: %#x != %#x", sig[sTypeOffset], asn1IntegerID) return scriptError(ErrSigInvalidSIntID, str) } // Zero-length integers are not allowed for S. if sLen == 0 { str := "malformed signature: S length is zero" return scriptError(ErrSigZeroSLen, str) } // S must not be negative. if sig[sOffset]&0x80 != 0 { str := "malformed signature: S is negative" return scriptError(ErrSigNegativeS, str) } // Null bytes at the start of S are not allowed, unless S would otherwise be // interpreted as a negative number. if sLen > 1 && sig[sOffset] == 0x00 && sig[sOffset+1]&0x80 == 0 { str := "malformed signature: S value has too much padding" return scriptError(ErrSigTooMuchSPadding, str) } // Verify the S value is <= half the order of the curve. This check is done // because when it is higher, the complement modulo the order can be used // instead which is a shorter encoding by 1 byte. Further, without // enforcing this, it is possible to replace a signature in a valid // transaction with the complement while still being a valid signature that // verifies. This would result in changing the transaction hash and thus is // a source of malleability. if vm.hasFlag(ScriptVerifyLowS) { sValue := new(big.Int).SetBytes(sig[sOffset : sOffset+sLen]) if sValue.Cmp(halfOrder) > 0 { return scriptError(ErrSigHighS, "signature is not canonical due "+ "to unnecessarily high S value") } } return nil } // getStack returns the contents of stack as a byte array bottom up func getStack(stack *stack) [][]byte { array := make([][]byte, stack.Depth()) for i := range array { // PeekByteArry can't fail due to overflow, already checked array[len(array)-i-1], _ = stack.PeekByteArray(int32(i)) } return array } // setStack sets the stack to the contents of the array where the last item in // the array is the top item in the stack. func setStack(stack *stack, data [][]byte) { // This can not error. Only errors are for invalid arguments. _ = stack.DropN(stack.Depth()) for i := range data { stack.PushByteArray(data[i]) } } // GetStack returns the contents of the primary stack as an array. where the // last item in the array is the top of the stack. func (vm *Engine) GetStack() [][]byte { return getStack(&vm.dstack) } // SetStack sets the contents of the primary stack to the contents of the // provided array where the last item in the array will be the top of the stack. func (vm *Engine) SetStack(data [][]byte) { setStack(&vm.dstack, data) } // GetAltStack returns the contents of the alternate stack as an array where the // last item in the array is the top of the stack. func (vm *Engine) GetAltStack() [][]byte { return getStack(&vm.astack) } // SetAltStack sets the contents of the alternate stack to the contents of the // provided array where the last item in the array will be the top of the stack. func (vm *Engine) SetAltStack(data [][]byte) { setStack(&vm.astack, data) } // NewEngine returns a new script engine for the provided public key script, // transaction, and input index. The flags modify the behavior of the script // engine according to the description provided by each flag. func NewEngine(scriptPubKey []byte, tx *wire.MsgTx, txIdx int, flags ScriptFlags, sigCache *SigCache, hashCache *TxSigHashes, inputAmount int64) (*Engine, error) { const scriptVersion = 0 // The provided transaction input index must refer to a valid input. if txIdx < 0 || txIdx >= len(tx.TxIn) { str := fmt.Sprintf("transaction input index %d is negative or "+ ">= %d", txIdx, len(tx.TxIn)) return nil, scriptError(ErrInvalidIndex, str) } scriptSig := tx.TxIn[txIdx].SignatureScript // When both the signature script and public key script are empty the result // is necessarily an error since the stack would end up being empty which is // equivalent to a false top element. Thus, just return the relevant error // now as an optimization. if len(scriptSig) == 0 && len(scriptPubKey) == 0 { return nil, scriptError(ErrEvalFalse, "false stack entry at end of script execution") } // The clean stack flag (ScriptVerifyCleanStack) is not allowed without // either the pay-to-script-hash (P2SH) evaluation (ScriptBip16) // flag or the Segregated Witness (ScriptVerifyWitness) flag. // // Recall that evaluating a P2SH script without the flag set results in // non-P2SH evaluation which leaves the P2SH inputs on the stack. // Thus, allowing the clean stack flag without the P2SH flag would make // it possible to have a situation where P2SH would not be a soft fork // when it should be. The same goes for segwit which will pull in // additional scripts for execution from the witness stack. vm := Engine{flags: flags, sigCache: sigCache, hashCache: hashCache, inputAmount: inputAmount} if vm.hasFlag(ScriptVerifyCleanStack) && (!vm.hasFlag(ScriptBip16) && !vm.hasFlag(ScriptVerifyWitness)) { return nil, scriptError(ErrInvalidFlags, "invalid flags combination") } // The signature script must only contain data pushes when the // associated flag is set. if vm.hasFlag(ScriptVerifySigPushOnly) && !IsPushOnlyScript(scriptSig) { return nil, scriptError(ErrNotPushOnly, "signature script is not push only") } // The signature script must only contain data pushes for PS2H which is // determined based on the form of the public key script. if vm.hasFlag(ScriptBip16) && isScriptHashScript(scriptPubKey) { // Only accept input scripts that push data for P2SH. // Notice that the push only checks have already been done when // the flag to verify signature scripts are push only is set // above, so avoid checking again. alreadyChecked := vm.hasFlag(ScriptVerifySigPushOnly) if !alreadyChecked && !IsPushOnlyScript(scriptSig) { return nil, scriptError(ErrNotPushOnly, "pay to script hash is not push only") } vm.bip16 = true } // The engine stores the scripts using a slice. This allows multiple // scripts to be executed in sequence. For example, with a // pay-to-script-hash transaction, there will be ultimately be a third // script to execute. scripts := [][]byte{scriptSig, scriptPubKey} for _, scr := range scripts { if len(scr) > MaxScriptSize { str := fmt.Sprintf("script size %d is larger than max allowed "+ "size %d", len(scr), MaxScriptSize) return nil, scriptError(ErrScriptTooBig, str) } const scriptVersion = 0 if err := checkScriptParses(scriptVersion, scr); err != nil { return nil, err } } vm.scripts = scripts // Advance the program counter to the public key script if the signature // script is empty since there is nothing to execute for it in that case. if len(scriptSig) == 0 { vm.scriptIdx++ } if vm.hasFlag(ScriptVerifyMinimalData) { vm.dstack.verifyMinimalData = true vm.astack.verifyMinimalData = true } // Check to see if we should execute in witness verification mode // according to the set flags. We check both the pkScript, and sigScript // here since in the case of nested p2sh, the scriptSig will be a valid // witness program. For nested p2sh, all the bytes after the first data // push should *exactly* match the witness program template. if vm.hasFlag(ScriptVerifyWitness) { // If witness evaluation is enabled, then P2SH MUST also be // active. if !vm.hasFlag(ScriptBip16) { errStr := "P2SH must be enabled to do witness verification" return nil, scriptError(ErrInvalidFlags, errStr) } var witProgram []byte switch { case IsWitnessProgram(vm.scripts[1]): // The scriptSig must be *empty* for all native witness // programs, otherwise we introduce malleability. if len(scriptSig) != 0 { errStr := "native witness program cannot " + "also have a signature script" return nil, scriptError(ErrWitnessMalleated, errStr) } witProgram = scriptPubKey case len(tx.TxIn[txIdx].Witness) != 0 && vm.bip16: // The sigScript MUST be *exactly* a single canonical // data push of the witness program, otherwise we // reintroduce malleability. sigPops := vm.scripts[0] if len(sigPops) > 2 && isCanonicalPush(sigPops[0], sigPops[1:]) && IsWitnessProgram(sigPops[1:]) { witProgram = sigPops[1:] } else { errStr := "signature script for witness " + "nested p2sh is not canonical" return nil, scriptError(ErrWitnessMalleatedP2SH, errStr) } } if witProgram != nil { var err error vm.witnessVersion, vm.witnessProgram, err = ExtractWitnessProgramInfo(witProgram) if err != nil { return nil, err } } else { // If we didn't find a witness program in either the // pkScript or as a datapush within the sigScript, then // there MUST NOT be any witness data associated with // the input being validated. if vm.witnessProgram == nil && len(tx.TxIn[txIdx].Witness) != 0 { errStr := "non-witness inputs cannot have a witness" return nil, scriptError(ErrWitnessUnexpected, errStr) } } } // Setup the current tokenizer used to parse through the script one opcode // at a time with the script associated with the program counter. vm.tokenizer = MakeScriptTokenizer(scriptVersion, scripts[vm.scriptIdx]) vm.tx = *tx vm.txIdx = txIdx return &vm, nil }