use std::cmp; use keys::{Public, Signature}; use hash::H256; use transaction::{Transaction, SEQUENCE_LOCKTIME_DISABLE_FLAG}; use crypto::{sha1, sha256, dhash160, dhash256, ripemd160}; use script::{script, Script, Num, VerificationFlags, Opcode, Error, read_usize, TransactionInputSigner}; #[derive(Debug, PartialEq, Clone, Copy)] #[repr(u8)] pub enum SighashBase { All = 1, None = 2, Single = 3, } impl From for u32 { fn from(s: SighashBase) -> Self { s as u32 } } /// Documentation /// https://en.bitcoin.it/wiki/OP_CHECKSIG#Procedure_for_Hashtype_SIGHASH_SINGLE #[derive(Debug, PartialEq, Clone, Copy)] pub struct Sighash { pub base: SighashBase, pub anyone_can_pay: bool, } impl From for u32 { fn from(s: Sighash) -> Self { let base = s.base as u32; match s.anyone_can_pay { true => base | 0x80, false => base, } } } impl From for Sighash { fn from(u: u32) -> Self { // use 0x9f istead of 0x1f to catch 0x80 match u & 0x9f { 1 => Sighash::new(SighashBase::All, false), 2 => Sighash::new(SighashBase::None, false), 3 => Sighash::new(SighashBase::Single, false), 0x81 => Sighash::new(SighashBase::All, true), 0x82 => Sighash::new(SighashBase::None, true), 0x83 => Sighash::new(SighashBase::Single, true), x if x & 0x80 == 0x80 => Sighash::new(SighashBase::All, true), // 0 is handled like all... _ => Sighash::new(SighashBase::All, false), } } } impl Sighash { pub fn new(base: SighashBase, anyone_can_pay: bool) -> Self { Sighash { base: base, anyone_can_pay: anyone_can_pay, } } pub fn from_u32(u: u32) -> Option { // use 0x9f istead of 0x1f to catch 0x80 let (base, anyone_can_pay) = match u & 0x9f { 1 => (SighashBase::All, false), 2 => (SighashBase::None, false), 3 => (SighashBase::Single, false), 0x81 => (SighashBase::All, true), 0x82 => (SighashBase::None, true), 0x83 => (SighashBase::Single, true), x if x & 0x80 == 0x80 => (SighashBase::All, true), _ => return None, }; Some(Sighash::new(base, anyone_can_pay)) } } #[derive(Debug, PartialEq, Clone, Copy)] pub enum SignatureVersion { Base, WitnessV0, } pub trait SignatureChecker { fn check_signature( &self, script_signature: &[u8], public: &[u8], script: &Script, version: SignatureVersion ) -> bool; fn check_lock_time(&self, lock_time: Num) -> bool; fn check_sequence(&self, sequence: Num) -> bool; } pub struct NoopSignatureChecker; impl SignatureChecker for NoopSignatureChecker { fn check_signature(&self, _: &[u8], _: &[u8], _: &Script, _: SignatureVersion) -> bool { false } fn check_lock_time(&self, _: Num) -> bool { false } fn check_sequence(&self, _: Num) -> bool { false } } pub struct TransactionSignatureChecker { pub signer: TransactionInputSigner, pub input_index: usize, } impl SignatureChecker for TransactionSignatureChecker { fn check_signature( &self, script_sig: &[u8], public: &[u8], script_code: &Script, _version: SignatureVersion ) -> bool { let public = match Public::from_slice(public) { Ok(public) => public, _ => return false, }; if script_sig.is_empty() { return false; } let hash_type = *script_sig.last().unwrap() as u32; let hash = self.signer.signature_hash(self.input_index, script_code, hash_type); public.verify(&hash, &script_sig[..script_sig.len() - 1].into()).unwrap_or(false) } fn check_lock_time(&self, _lock_time: Num) -> bool { unimplemented!(); } fn check_sequence(&self, _sequence: Num) -> bool { unimplemented!(); } } fn is_public_key(v: &[u8]) -> bool { match v.len() { 33 if v[0] == 2 || v[0] == 3 => true, 65 if v[0] == 4 => true, _ => false, } } /// A canonical signature exists of: <30> <02> <02> /// Where R and S are not negative (their first byte has its highest bit not set), and not /// excessively padded (do not start with a 0 byte, unless an otherwise negative number follows, /// in which case a single 0 byte is necessary and even required). /// /// See https://bitcointalk.org/index.php?topic=8392.msg127623#msg127623 /// /// This function is consensus-critical since BIP66. fn is_valid_signature_encoding(sig: &[u8]) -> bool { // Format: 0x30 [total-length] 0x02 [R-length] [R] 0x02 [S-length] [S] [sighash] // * total-length: 1-byte length descriptor of everything that follows, // excluding the sighash byte. // * R-length: 1-byte length descriptor of the R value that follows. // * R: arbitrary-length big-endian encoded R value. It must use the shortest // possible encoding for a positive integers (which means no null bytes at // the start, except a single one when the next byte has its highest bit set). // * S-length: 1-byte length descriptor of the S value that follows. // * S: arbitrary-length big-endian encoded S value. The same rules apply. // * sighash: 1-byte value indicating what data is hashed (not part of the DER // signature) // Minimum and maximum size constraints if sig.len() < 9 || sig.len() > 73 { return false; } // A signature is of type 0x30 (compound) if sig[0] != 0x30 { return false; } // Make sure the length covers the entire signature. if sig[1] as usize != sig.len() - 3 { return false; } // Extract the length of the R element. let len_r = sig[3] as usize; // Make sure the length of the S element is still inside the signature. if len_r + 5 >= sig.len() { return false; } // Extract the length of the S element. let len_s = sig[len_r + 5] as usize; // Verify that the length of the signature matches the sum of the length if len_r + len_s + 7 != sig.len() { return false; } // Check whether the R element is an integer. if sig[2] != 2 { return false; } // Zero-length integers are not allowed for R. if len_r == 0 { return false; } // Negative numbers are not allowed for R. if (sig[4] & 0x80) != 0 { return false; } // Null bytes at the start of R are not allowed, unless R would // otherwise be interpreted as a negative number. if len_r > 1 && sig[4] == 0 && (!(sig[5] & 0x80)) != 0 { return false; } // Check whether the S element is an integer. if sig[len_r + 4] != 2 { return false; } // Zero-length integers are not allowed for S. if len_s == 0 { return false; } // Negative numbers are not allowed for S. if (sig[len_r + 6] & 0x80) != 0 { return false; } // Null bytes at the start of S are not allowed, unless S would otherwise be // interpreted as a negative number. if len_s > 1 && (sig[len_r + 6] == 0) && (!(sig[len_r + 7] & 0x80)) != 0 { return false; } true } fn is_low_der_signature(sig: &[u8]) -> Result<(), Error> { if !is_valid_signature_encoding(sig) { return Err(Error::SignatureDer); } let signature: Signature = sig.into(); if !signature.check_low_s() { return Err(Error::SignatureHighS); } Ok(()) } fn is_defined_hashtype_signature(sig: &[u8]) -> bool { if sig.is_empty() { return false; } Sighash::from_u32(sig[sig.len() -1] as u32).is_some() } fn check_signature_encoding(sig: &[u8], flags: &VerificationFlags) -> Result<(), Error> { // Empty signature. Not strictly DER encoded, but allowed to provide a // compact way to provide an invalid signature for use with CHECK(MULTI)SIG if sig.is_empty() { return Ok(()); } if (flags.verify_dersig || flags.verify_low_s || flags.verify_strictenc) && !is_valid_signature_encoding(sig) { return Err(Error::SignatureDer); } if flags.verify_low_s { try!(is_low_der_signature(sig)); } if flags.verify_strictenc && !is_defined_hashtype_signature(sig) { Err(Error::SignatureHashtype) } else { Ok(()) } } fn check_pubkey_encoding(v: &[u8], flags: &VerificationFlags) -> Result<(), Error> { if flags.verify_strictenc && !is_public_key(v) { return Err(Error::PubkeyType); } Ok(()) } fn check_minimal_push(data: &[u8], opcode: Opcode) -> bool { if data.is_empty() { // Could have used OP_0. opcode == Opcode::OP_0 } else if data.len() == 1 && data[0] >= 1 && data[0] <= 16 { // Could have used OP_1 .. OP_16. opcode as u8 == Opcode::OP_1 as u8 + (data[0] - 1) } else if data.len() == 1 && data[0] == 0x81 { // Could have used OP_1NEGATE opcode == Opcode::OP_1NEGATE } else if data.len() <= 75 { // Could have used a direct push (opcode indicating number of bytes pushed + those bytes). opcode as usize == data.len() } else if data.len() <= 255 { // Could have used OP_PUSHDATA. opcode == Opcode::OP_PUSHDATA1 } else if data.len() <= 65535 { // Could have used OP_PUSHDATA2. opcode == Opcode::OP_PUSHDATA2 } else { true } } fn cast_to_bool(data: &[u8]) -> bool { if data.is_empty() { return false; } if data[..data.len() - 1].iter().any(|x| x != &0) { return true; } let last = data[data.len() - 1]; if last == 0 || last == 0x80 { false } else { true } } #[inline] fn require_not_empty(stack: &Vec>) -> Result<(), Error> { match stack.is_empty() { true => Err(Error::InvalidStackOperation), false => Ok(()), } } #[inline] fn require_len(stack: &Vec>, len: usize) -> Result<(), Error> { match stack.len() < len { true => Err(Error::InvalidStackOperation), false => Ok(()), } } pub fn eval_script( stack: &mut Vec>, script: &Script, flags: &VerificationFlags, checker: &SignatureChecker, version: SignatureVersion ) -> Result { if script.len() > script::MAX_SCRIPT_SIZE { return Err(Error::ScriptSize); } let mut pc = 0; let mut begincode = 0; let mut exec_stack = Vec::::new(); let mut altstack = Vec::>::new(); while pc < script.len() { let fexec = exec_stack.iter().find(|&x| !x).is_some(); let opcode = try!(script.get_opcode(pc)); match opcode { Opcode::OP_PUSHDATA1 | Opcode::OP_PUSHDATA2 | Opcode::OP_PUSHDATA4 => { let len = match opcode { Opcode::OP_PUSHDATA1 => 1, Opcode::OP_PUSHDATA2 => 2, _ => 4, }; let slice = try!(script.take(pc + 1, len)); let n = try!(read_usize(slice, len)); let bytes = try!(script.take_checked(pc + 1 + len, n)); if flags.verify_minimaldata && !check_minimal_push(bytes, opcode) { return Err(Error::Minimaldata); } stack.push(bytes.to_vec()); pc += len + n; }, Opcode::OP_0 | Opcode::OP_PUSHBYTES_1 | Opcode::OP_PUSHBYTES_2 | Opcode::OP_PUSHBYTES_3 | Opcode::OP_PUSHBYTES_4 | Opcode::OP_PUSHBYTES_5 | Opcode::OP_PUSHBYTES_6 | Opcode::OP_PUSHBYTES_7 | Opcode::OP_PUSHBYTES_8 | Opcode::OP_PUSHBYTES_9 | Opcode::OP_PUSHBYTES_10 | Opcode::OP_PUSHBYTES_11 | Opcode::OP_PUSHBYTES_12 | Opcode::OP_PUSHBYTES_13 | Opcode::OP_PUSHBYTES_14 | Opcode::OP_PUSHBYTES_15 | Opcode::OP_PUSHBYTES_16 | Opcode::OP_PUSHBYTES_17 | Opcode::OP_PUSHBYTES_18 | Opcode::OP_PUSHBYTES_19 | Opcode::OP_PUSHBYTES_20 | Opcode::OP_PUSHBYTES_21 | Opcode::OP_PUSHBYTES_22 | Opcode::OP_PUSHBYTES_23 | Opcode::OP_PUSHBYTES_24 | Opcode::OP_PUSHBYTES_25 | Opcode::OP_PUSHBYTES_26 | Opcode::OP_PUSHBYTES_27 | Opcode::OP_PUSHBYTES_28 | Opcode::OP_PUSHBYTES_29 | Opcode::OP_PUSHBYTES_30 | Opcode::OP_PUSHBYTES_31 | Opcode::OP_PUSHBYTES_32 | Opcode::OP_PUSHBYTES_33 | Opcode::OP_PUSHBYTES_34 | Opcode::OP_PUSHBYTES_35 | Opcode::OP_PUSHBYTES_36 | Opcode::OP_PUSHBYTES_37 | Opcode::OP_PUSHBYTES_38 | Opcode::OP_PUSHBYTES_39 | Opcode::OP_PUSHBYTES_40 | Opcode::OP_PUSHBYTES_41 | Opcode::OP_PUSHBYTES_42 | Opcode::OP_PUSHBYTES_43 | Opcode::OP_PUSHBYTES_44 | Opcode::OP_PUSHBYTES_45 | Opcode::OP_PUSHBYTES_46 | Opcode::OP_PUSHBYTES_47 | Opcode::OP_PUSHBYTES_48 | Opcode::OP_PUSHBYTES_49 | Opcode::OP_PUSHBYTES_50 | Opcode::OP_PUSHBYTES_51 | Opcode::OP_PUSHBYTES_52 | Opcode::OP_PUSHBYTES_53 | Opcode::OP_PUSHBYTES_54 | Opcode::OP_PUSHBYTES_55 | Opcode::OP_PUSHBYTES_56 | Opcode::OP_PUSHBYTES_57 | Opcode::OP_PUSHBYTES_58 | Opcode::OP_PUSHBYTES_59 | Opcode::OP_PUSHBYTES_60 | Opcode::OP_PUSHBYTES_61 | Opcode::OP_PUSHBYTES_62 | Opcode::OP_PUSHBYTES_63 | Opcode::OP_PUSHBYTES_64 | Opcode::OP_PUSHBYTES_65 | Opcode::OP_PUSHBYTES_66 | Opcode::OP_PUSHBYTES_67 | Opcode::OP_PUSHBYTES_68 | Opcode::OP_PUSHBYTES_69 | Opcode::OP_PUSHBYTES_70 | Opcode::OP_PUSHBYTES_71 | Opcode::OP_PUSHBYTES_72 | Opcode::OP_PUSHBYTES_73 | Opcode::OP_PUSHBYTES_74 | Opcode::OP_PUSHBYTES_75 => { let bytes = try!(script.take_checked(pc + 1, opcode as usize)); if flags.verify_minimaldata && !check_minimal_push(bytes, opcode) { return Err(Error::Minimaldata); } stack.push(bytes.to_vec()); pc += opcode as usize; }, Opcode::OP_1 | Opcode::OP_2 | Opcode::OP_3 | Opcode::OP_4 | Opcode::OP_5 | Opcode::OP_6 | Opcode::OP_7 | Opcode::OP_8 | Opcode::OP_9 | Opcode::OP_10 | Opcode::OP_11 | Opcode::OP_12 | Opcode::OP_13 | Opcode::OP_14 | Opcode::OP_15 | Opcode::OP_16 => { let value = opcode as u8 - (Opcode::OP_1 as u8 - 1); stack.push(Num::from(value).to_vec()); }, Opcode::OP_CAT | Opcode::OP_SUBSTR | Opcode::OP_LEFT | Opcode::OP_RIGHT | Opcode::OP_INVERT | Opcode::OP_AND | Opcode::OP_OR | Opcode::OP_XOR | Opcode::OP_2MUL | Opcode::OP_2DIV | Opcode::OP_MUL | Opcode::OP_DIV | Opcode::OP_MOD | Opcode::OP_LSHIFT | Opcode::OP_RSHIFT => { return Err(Error::DisabledOpcode(opcode)); }, Opcode::OP_NOP => break, Opcode::OP_CHECKLOCKTIMEVERIFY => { if !flags.verify_clocktimeverify { if flags.verify_discourage_upgradable_nops { return Err(Error::DiscourageUpgradableNops); } } try!(require_not_empty(stack)); // Note that elsewhere numeric opcodes are limited to // operands in the range -2**31+1 to 2**31-1, however it is // legal for opcodes to produce results exceeding that // range. This limitation is implemented by CScriptNum's // default 4-byte limit. // // If we kept to that limit we'd have a year 2038 problem, // even though the nLockTime field in transactions // themselves is uint32 which only becomes meaningless // after the year 2106. // // Thus as a special case we tell CScriptNum to accept up // to 5-byte bignums, which are good until 2**39-1, well // beyond the 2**32-1 limit of the nLockTime field itself. let lock_time = try!(Num::from_slice(stack.last().unwrap(), flags.verify_minimaldata, 5)); // In the rare event that the argument may be < 0 due to // some arithmetic being done first, you can always use // 0 MAX CHECKLOCKTIMEVERIFY. if lock_time.is_negative() { return Err(Error::NegativeLocktime); } if !checker.check_lock_time(lock_time) { return Err(Error::UnsatisfiedLocktime); } }, Opcode::OP_CHECKSEQUENCEVERIFY => { if !flags.verify_chechsequenceverify { if flags.verify_discourage_upgradable_nops { return Err(Error::DiscourageUpgradableNops); } } try!(require_not_empty(stack)); let sequence = try!(Num::from_slice(stack.last().unwrap(), flags.verify_minimaldata, 5)); if sequence.is_negative() { return Err(Error::NegativeLocktime); } if (sequence & (SEQUENCE_LOCKTIME_DISABLE_FLAG as i64).into()).is_zero() { if !checker.check_sequence(sequence) { return Err(Error::UnsatisfiedLocktime); } } }, Opcode::OP_NOP1 | Opcode::OP_NOP4 | Opcode::OP_NOP5 | Opcode::OP_NOP6 | Opcode::OP_NOP7 | Opcode::OP_NOP8 | Opcode::OP_NOP9 | Opcode::OP_NOP10 => { if flags.verify_discourage_upgradable_nops { return Err(Error::DiscourageUpgradableNops); } }, Opcode::OP_IF | Opcode::OP_NOTIF => { let mut exec_value = false; if fexec { try!(require_not_empty(stack).map_err(|_| Error::UnbalancedConditional)); exec_value = cast_to_bool(&stack.pop().unwrap()); if opcode == Opcode::OP_NOTIF { exec_value = !exec_value; } } exec_stack.push(exec_value); }, Opcode::OP_ELSE => { if exec_stack.is_empty() { return Err(Error::UnbalancedConditional); } let last = exec_stack[exec_stack.len() - 1]; exec_stack[exec_stack.len() - 1] == !last; }, Opcode::OP_ENDIF => { if exec_stack.is_empty() { return Err(Error::UnbalancedConditional); } exec_stack.pop(); }, Opcode::OP_VERIFY => { try!(require_not_empty(stack)); // should we return an error without popping the value? let exec_value = cast_to_bool(&stack.pop().unwrap()); if !exec_value { return Err(Error::Verify); } }, Opcode::OP_RETURN => { return Err(Error::ReturnOpcode); }, Opcode::OP_TOALTSTACK => { try!(require_not_empty(stack)); altstack.push(stack.pop().unwrap()); }, Opcode::OP_FROMALTSTACK => { try!(require_not_empty(&altstack).map_err(|_| Error::InvalidAltstackOperation)); stack.push(altstack.pop().unwrap()); }, Opcode::OP_2DROP => { try!(require_len(stack, 2)); stack.pop(); stack.pop(); }, Opcode::OP_2DUP => { try!(require_len(stack, 2)); let v1 = stack[stack.len() - 2].clone(); let v2 = stack[stack.len() - 1].clone(); stack.push(v1); stack.push(v2); }, Opcode::OP_3DUP => { try!(require_len(stack, 3)); let v1 = stack[stack.len() - 3].clone(); let v2 = stack[stack.len() - 2].clone(); let v3 = stack[stack.len() - 1].clone(); stack.push(v1); stack.push(v2); stack.push(v3); }, Opcode::OP_2OVER => { try!(require_len(stack, 4)); let v1 = stack[stack.len() - 4].clone(); let v2 = stack[stack.len() - 3].clone(); stack.push(v1); stack.push(v2); }, Opcode::OP_2ROT => { try!(require_len(stack, 6)); let v1 = stack[stack.len() - 6].clone(); let v2 = stack[stack.len() - 5].clone(); let len = stack.len(); stack.remove(len - 6); // -5 -just removed element stack.remove(len - 6); stack.push(v1); stack.push(v2); }, Opcode::OP_2SWAP => { try!(require_len(stack, 4)); let len = stack.len(); stack.swap(len - 4, len - 2); stack.swap(len - 3, len - 1); }, Opcode::OP_IFDUP => { try!(require_not_empty(stack)); if cast_to_bool(stack.last().unwrap()) { let last = stack.last().unwrap().clone(); stack.push(last); } }, Opcode::OP_DEPTH => { let depth = Num::from(stack.len()); stack.push(depth.to_vec()); }, Opcode::OP_DROP => { try!(require_not_empty(stack)); stack.pop(); }, Opcode::OP_DUP => { try!(require_not_empty(stack)); let v1 = stack[stack.len() - 1].clone(); stack.push(v1); }, Opcode::OP_NIP => { try!(require_len(stack, 2)); let len = stack.len(); stack.swap_remove(len - 2); }, Opcode::OP_OVER => { try!(require_len(stack, 2)); let v = stack[stack.len() - 2].clone(); stack.push(v); }, Opcode::OP_PICK | Opcode::OP_ROLL => { try!(require_len(stack, 2)); let n: i64 = try!(Num::from_slice(&stack.pop().unwrap(), flags.verify_minimaldata, 4)).into(); if n < 0 || n >= stack.len() as i64 { return Err(Error::InvalidStackOperation); } let v = stack[n as usize + 1].clone(); if opcode == Opcode::OP_ROLL { stack.remove(n as usize + 1); } stack.push(v); }, Opcode::OP_ROT => { try!(require_len(stack, 3)); let len = stack.len(); stack.swap(len - 3, len - 2); stack.swap(len - 2, len - 1); }, Opcode::OP_SWAP => { try!(require_len(stack, 2)); let len = stack.len(); stack.swap(len - 2, len - 1); }, Opcode::OP_TUCK => { try!(require_len(stack, 2)); let len = stack.len(); let v = stack[len - 1].clone(); stack.insert(len - 2, v); }, Opcode::OP_SIZE => { try!(require_not_empty(stack)); let n = Num::from(stack.last().unwrap().len()); stack.push(n.to_vec()); }, Opcode::OP_EQUAL => { try!(require_len(stack, 2)); let v1 = stack.pop(); let v2 = stack.pop(); let to_push = match v1 == v2 { true => vec![1], false => vec![0], }; stack.push(to_push); }, Opcode::OP_EQUALVERIFY => { try!(require_len(stack, 2)); let equal = stack.pop() == stack.pop(); if !equal { return Err(Error::EqualVerify); } }, Opcode::OP_1ADD => { try!(require_not_empty(stack)); let n = try!(Num::from_slice(&stack.pop().unwrap(), flags.verify_minimaldata, 4)) + 1.into(); stack.push(n.to_vec()); }, Opcode::OP_1SUB => { try!(require_not_empty(stack)); let n = try!(Num::from_slice(&stack.pop().unwrap(), flags.verify_minimaldata, 4)) - 1.into(); stack.push(n.to_vec()); }, Opcode::OP_NEGATE => { try!(require_not_empty(stack)); let n = -try!(Num::from_slice(&stack.pop().unwrap(), flags.verify_minimaldata, 4)); stack.push(n.to_vec()); }, Opcode::OP_ABS => { try!(require_not_empty(stack)); let n = try!(Num::from_slice(&stack.pop().unwrap(), flags.verify_minimaldata, 4)).abs(); stack.push(n.to_vec()); }, Opcode::OP_NOT => { try!(require_not_empty(stack)); let n = try!(Num::from_slice(&stack.pop().unwrap(), flags.verify_minimaldata, 4)).is_zero(); let n = Num::from(n); stack.push(n.to_vec()); }, Opcode::OP_0NOTEQUAL => { try!(require_not_empty(stack)); let n = !try!(Num::from_slice(&stack.pop().unwrap(), flags.verify_minimaldata, 4)).is_zero(); let n = Num::from(n); stack.push(n.to_vec()); }, Opcode::OP_ADD => { try!(require_len(stack, 2)); let v1 = try!(Num::from_slice(&stack.pop().unwrap(), flags.verify_minimaldata, 4)); let v2 = try!(Num::from_slice(&stack.pop().unwrap(), flags.verify_minimaldata, 4)); stack.push((v1 + v2).to_vec()); }, Opcode::OP_SUB => { try!(require_len(stack, 2)); let v1 = try!(Num::from_slice(&stack.pop().unwrap(), flags.verify_minimaldata, 4)); let v2 = try!(Num::from_slice(&stack.pop().unwrap(), flags.verify_minimaldata, 4)); stack.push((v2 - v1).to_vec()); }, Opcode::OP_BOOLAND => { try!(require_len(stack, 2)); let v1 = try!(Num::from_slice(&stack.pop().unwrap(), flags.verify_minimaldata, 4)); let v2 = try!(Num::from_slice(&stack.pop().unwrap(), flags.verify_minimaldata, 4)); let v = Num::from(!v1.is_zero() && !v2.is_zero()); stack.push(v.to_vec()); }, Opcode::OP_BOOLOR => { try!(require_len(stack, 2)); let v1 = try!(Num::from_slice(&stack.pop().unwrap(), flags.verify_minimaldata, 4)); let v2 = try!(Num::from_slice(&stack.pop().unwrap(), flags.verify_minimaldata, 4)); let v = Num::from(!v1.is_zero() || !v2.is_zero()); stack.push(v.to_vec()); }, Opcode::OP_NUMEQUAL => { try!(require_len(stack, 2)); let v1 = try!(Num::from_slice(&stack.pop().unwrap(), flags.verify_minimaldata, 4)); let v2 = try!(Num::from_slice(&stack.pop().unwrap(), flags.verify_minimaldata, 4)); let v = Num::from(v1 == v2); stack.push(v.to_vec()); }, Opcode::OP_NUMEQUALVERIFY => { try!(require_len(stack, 2)); let v1 = try!(Num::from_slice(&stack.pop().unwrap(), flags.verify_minimaldata, 4)); let v2 = try!(Num::from_slice(&stack.pop().unwrap(), flags.verify_minimaldata, 4)); if v1 != v2 { return Err(Error::NumEqualVerify); } }, Opcode::OP_NUMNOTEQUAL => { try!(require_len(stack, 2)); let v1 = try!(Num::from_slice(&stack.pop().unwrap(), flags.verify_minimaldata, 4)); let v2 = try!(Num::from_slice(&stack.pop().unwrap(), flags.verify_minimaldata, 4)); let v = Num::from(v1 != v2); stack.push(v.to_vec()); }, Opcode::OP_LESSTHAN => { try!(require_len(stack, 2)); let v1 = try!(Num::from_slice(&stack.pop().unwrap(), flags.verify_minimaldata, 4)); let v2 = try!(Num::from_slice(&stack.pop().unwrap(), flags.verify_minimaldata, 4)); let v = Num::from(v1 > v2); stack.push(v.to_vec()); }, Opcode::OP_GREATERTHAN => { try!(require_len(stack, 2)); let v1 = try!(Num::from_slice(&stack.pop().unwrap(), flags.verify_minimaldata, 4)); let v2 = try!(Num::from_slice(&stack.pop().unwrap(), flags.verify_minimaldata, 4)); let v = Num::from(v1 < v2); stack.push(v.to_vec()); }, Opcode::OP_LESSTHANOREQUAL => { try!(require_len(stack, 2)); let v1 = try!(Num::from_slice(&stack.pop().unwrap(), flags.verify_minimaldata, 4)); let v2 = try!(Num::from_slice(&stack.pop().unwrap(), flags.verify_minimaldata, 4)); let v = Num::from(v1 >= v2); stack.push(v.to_vec()); }, Opcode::OP_GREATERTHANOREQUAL => { try!(require_len(stack, 2)); let v1 = try!(Num::from_slice(&stack.pop().unwrap(), flags.verify_minimaldata, 4)); let v2 = try!(Num::from_slice(&stack.pop().unwrap(), flags.verify_minimaldata, 4)); let v = Num::from(v1 <= v2); stack.push(v.to_vec()); }, Opcode::OP_MIN => { try!(require_len(stack, 2)); let v1 = try!(Num::from_slice(&stack.pop().unwrap(), flags.verify_minimaldata, 4)); let v2 = try!(Num::from_slice(&stack.pop().unwrap(), flags.verify_minimaldata, 4)); stack.push(cmp::min(v1, v2).to_vec()); }, Opcode::OP_MAX => { try!(require_len(stack, 2)); let v1 = try!(Num::from_slice(&stack.pop().unwrap(), flags.verify_minimaldata, 4)); let v2 = try!(Num::from_slice(&stack.pop().unwrap(), flags.verify_minimaldata, 4)); stack.push(cmp::max(v1, v2).to_vec()); }, Opcode::OP_WITHIN => { try!(require_len(stack, 3)); let v1 = try!(Num::from_slice(&stack.pop().unwrap(), flags.verify_minimaldata, 4)); let v2 = try!(Num::from_slice(&stack.pop().unwrap(), flags.verify_minimaldata, 4)); let v3 = try!(Num::from_slice(&stack.pop().unwrap(), flags.verify_minimaldata, 4)); let to_push = match v2 <= v3 && v3 <= v1 { true => vec![1], false => vec![0], }; stack.push(to_push); }, Opcode::OP_RIPEMD160 => { try!(require_not_empty(stack)); let v = ripemd160(&stack.pop().unwrap()); stack.push(v.to_vec()); }, Opcode::OP_SHA1 => { try!(require_not_empty(stack)); let v = sha1(&stack.pop().unwrap()); stack.push(v.to_vec()); }, Opcode::OP_SHA256 => { try!(require_not_empty(stack)); let v = sha256(&stack.pop().unwrap()); stack.push(v.to_vec()); }, Opcode::OP_HASH160 => { try!(require_not_empty(stack)); let v = dhash160(&stack.pop().unwrap()); stack.push(v.to_vec()); }, Opcode::OP_HASH256 => { try!(require_not_empty(stack)); let v = dhash256(&stack.pop().unwrap()); stack.push(v.to_vec()); }, Opcode::OP_CODESEPARATOR => { begincode = pc; }, Opcode::OP_CHECKSIG | Opcode::OP_CHECKSIGVERIFY => { try!(require_len(stack, 2)); let pubkey = stack.pop().unwrap(); let signature = stack.pop().unwrap(); let mut subscript = script.subscript(begincode); if version == SignatureVersion::Base { subscript = script.find_and_delete(&signature); } try!(check_signature_encoding(&signature, flags)); try!(check_pubkey_encoding(&pubkey, flags)); let success = checker.check_signature(&signature, &pubkey, &subscript, version); match opcode { Opcode::OP_CHECKSIG => { let to_push = match success { true => vec![1], false => vec![0], }; stack.push(to_push); }, Opcode::OP_CHECKSIGVERIFY if !success => { return Err(Error::CheckSigVerify); }, _ => {}, } }, _ => {}, } pc += 1; } let success = !stack.is_empty() && { let last = stack.last().unwrap(); cast_to_bool(last) }; Ok(success) } #[cfg(test)] mod tests { use hex::FromHex; use transaction::Transaction; use script::{Opcode, Script, VerificationFlags, Builder, Error, Num, TransactionInputSigner}; use super::{is_public_key, eval_script, NoopSignatureChecker, SignatureVersion, TransactionSignatureChecker}; #[test] fn tests_is_public_key() { assert!(!is_public_key(&[])); assert!(!is_public_key(&[1])); assert!(is_public_key(&"0495dfb90f202c7d016ef42c65bc010cd26bb8237b06253cc4d12175097bef767ed6b1fcb3caf1ed57c98d92e6cb70278721b952e29a335134857acd4c199b9d2f".from_hex().unwrap())); assert!(is_public_key(&[2; 33])); assert!(is_public_key(&[3; 33])); assert!(!is_public_key(&[4; 33])); } // https://github.com/bitcoin/bitcoin/blob/d612837814020ae832499d18e6ee5eb919a87907/src/test/script_tests.cpp#L900 #[test] fn test_push_data() { let expected = vec![vec![0x5a]]; let flags = VerificationFlags::default() .verify_p2sh(true); let checker = NoopSignatureChecker; let version = SignatureVersion::Base; let direct = Script::new(vec![Opcode::OP_PUSHBYTES_1 as u8, 0x5a]); let pushdata1 = Script::new(vec![Opcode::OP_PUSHDATA1 as u8, 0x1, 0x5a]); let pushdata2 = Script::new(vec![Opcode::OP_PUSHDATA2 as u8, 0x1, 0, 0x5a]); let pushdata4 = Script::new(vec![Opcode::OP_PUSHDATA4 as u8, 0x1, 0, 0, 0, 0x5a]); let mut direct_stack = vec![]; let mut pushdata1_stack= vec![]; let mut pushdata2_stack= vec![]; let mut pushdata4_stack= vec![]; assert!(eval_script(&mut direct_stack, &direct, &flags, &checker, version).unwrap()); assert!(eval_script(&mut pushdata1_stack, &pushdata1, &flags, &checker, version).unwrap()); assert!(eval_script(&mut pushdata2_stack, &pushdata2, &flags, &checker, version).unwrap()); assert!(eval_script(&mut pushdata4_stack, &pushdata4, &flags, &checker, version).unwrap()); assert_eq!(expected, direct_stack); assert_eq!(expected, pushdata1_stack); assert_eq!(expected, pushdata2_stack); assert_eq!(expected, pushdata4_stack); } fn basic_test(script: &Script, expected: Result, expected_stack: Vec>) { let flags = VerificationFlags::default() .verify_p2sh(true); let checker = NoopSignatureChecker; let version = SignatureVersion::Base; let mut stack = vec![]; assert_eq!(eval_script(&mut stack, script, &flags, &checker, version), expected); if expected.is_ok() { assert_eq!(stack, expected_stack); } } #[test] fn test_equal() { let script = Builder::default() .push_data(&[0x4]) .push_data(&[0x4]) .push_opcode(Opcode::OP_EQUAL) .into_script(); let result = Ok(true); let stack = vec![vec![1]]; basic_test(&script, result, stack); } #[test] fn test_equal_false() { let script = Builder::default() .push_data(&[0x4]) .push_data(&[0x3]) .push_opcode(Opcode::OP_EQUAL) .into_script(); let result = Ok(false); let stack = vec![vec![0]]; basic_test(&script, result, stack); } #[test] fn test_equal_invalid_stack() { let script = Builder::default() .push_data(&[0x4]) .push_opcode(Opcode::OP_EQUAL) .into_script(); let result = Err(Error::InvalidStackOperation); basic_test(&script, result, vec![]); } #[test] fn test_equal_verify() { let script = Builder::default() .push_data(&[0x4]) .push_data(&[0x4]) .push_opcode(Opcode::OP_EQUALVERIFY) .into_script(); let result = Ok(false); let stack = vec![]; basic_test(&script, result, stack); } #[test] fn test_equal_verify_failed() { let script = Builder::default() .push_data(&[0x4]) .push_data(&[0x3]) .push_opcode(Opcode::OP_EQUALVERIFY) .into_script(); let result = Err(Error::EqualVerify); basic_test(&script, result, vec![]); } #[test] fn test_equal_verify_invalid_stack() { let script = Builder::default() .push_data(&[0x4]) .push_opcode(Opcode::OP_EQUALVERIFY) .into_script(); let result = Err(Error::InvalidStackOperation); basic_test(&script, result, vec![]); } #[test] fn test_size() { let script = Builder::default() .push_data(&[0x12, 0x34]) .push_opcode(Opcode::OP_SIZE) .into_script(); let result = Ok(true); let stack = vec![vec![0x12, 0x34], vec![0x2]]; basic_test(&script, result, stack); } #[test] fn test_size_false() { let script = Builder::default() .push_data(&[]) .push_opcode(Opcode::OP_SIZE) .into_script(); let result = Ok(false); let stack = vec![vec![], vec![]]; basic_test(&script, result, stack); } #[test] fn test_size_invalid_stack() { let script = Builder::default() .push_opcode(Opcode::OP_SIZE) .into_script(); let result = Err(Error::InvalidStackOperation); basic_test(&script, result, vec![]); } #[test] fn test_hash256() { let script = Builder::default() .push_data(b"hello") .push_opcode(Opcode::OP_HASH256) .into_script(); let result = Ok(true); let stack = vec!["9595c9df90075148eb06860365df33584b75bff782a510c6cd4883a419833d50".from_hex().unwrap()]; basic_test(&script, result, stack); } #[test] fn test_hash256_invalid_stack() { let script = Builder::default() .push_opcode(Opcode::OP_HASH256) .into_script(); let result = Err(Error::InvalidStackOperation); basic_test(&script, result, vec![]); } #[test] fn test_ripemd160() { let script = Builder::default() .push_data(b"hello") .push_opcode(Opcode::OP_RIPEMD160) .into_script(); let result = Ok(true); let stack = vec!["108f07b8382412612c048d07d13f814118445acd".from_hex().unwrap()]; basic_test(&script, result, stack); } #[test] fn test_ripemd160_invalid_stack() { let script = Builder::default() .push_opcode(Opcode::OP_RIPEMD160) .into_script(); let result = Err(Error::InvalidStackOperation); basic_test(&script, result, vec![]); } #[test] fn test_sha1() { let script = Builder::default() .push_data(b"hello") .push_opcode(Opcode::OP_SHA1) .into_script(); let result = Ok(true); let stack = vec!["aaf4c61ddcc5e8a2dabede0f3b482cd9aea9434d".from_hex().unwrap()]; basic_test(&script, result, stack); } #[test] fn test_sha1_invalid_stack() { let script = Builder::default() .push_opcode(Opcode::OP_SHA1) .into_script(); let result = Err(Error::InvalidStackOperation); basic_test(&script, result, vec![]); } #[test] fn test_sha256() { let script = Builder::default() .push_data(b"hello") .push_opcode(Opcode::OP_SHA256) .into_script(); let result = Ok(true); let stack = vec!["2cf24dba5fb0a30e26e83b2ac5b9e29e1b161e5c1fa7425e73043362938b9824".from_hex().unwrap()]; basic_test(&script, result, stack); } #[test] fn test_sha256_invalid_stack() { let script = Builder::default() .push_opcode(Opcode::OP_SHA256) .into_script(); let result = Err(Error::InvalidStackOperation); basic_test(&script, result, vec![]); } #[test] fn test_1add() { let script = Builder::default() .push_num(5.into()) .push_opcode(Opcode::OP_1ADD) .into_script(); let result = Ok(true); let stack = vec![Num::from(6).to_vec()]; basic_test(&script, result, stack); } #[test] fn test_1add_invalid_stack() { let script = Builder::default() .push_opcode(Opcode::OP_1ADD) .into_script(); let result = Err(Error::InvalidStackOperation); basic_test(&script, result, vec![]); } #[test] fn test_1sub() { let script = Builder::default() .push_num(5.into()) .push_opcode(Opcode::OP_1SUB) .into_script(); let result = Ok(true); let stack = vec![Num::from(4).to_vec()]; basic_test(&script, result, stack); } #[test] fn test_1sub_invalid_stack() { let script = Builder::default() .push_opcode(Opcode::OP_1SUB) .into_script(); let result = Err(Error::InvalidStackOperation); basic_test(&script, result, vec![]); } #[test] fn test_negate() { let script = Builder::default() .push_num(5.into()) .push_opcode(Opcode::OP_NEGATE) .into_script(); let result = Ok(true); let stack = vec![Num::from(-5).to_vec()]; basic_test(&script, result, stack); } #[test] fn test_negate_negative() { let script = Builder::default() .push_num((-5).into()) .push_opcode(Opcode::OP_NEGATE) .into_script(); let result = Ok(true); let stack = vec![Num::from(5).to_vec()]; basic_test(&script, result, stack); } #[test] fn test_negate_invalid_stack() { let script = Builder::default() .push_opcode(Opcode::OP_NEGATE) .into_script(); let result = Err(Error::InvalidStackOperation); basic_test(&script, result, vec![]); } #[test] fn test_abs() { let script = Builder::default() .push_num(5.into()) .push_opcode(Opcode::OP_ABS) .into_script(); let result = Ok(true); let stack = vec![Num::from(5).to_vec()]; basic_test(&script, result, stack); } #[test] fn test_abs_negative() { let script = Builder::default() .push_num((-5).into()) .push_opcode(Opcode::OP_ABS) .into_script(); let result = Ok(true); let stack = vec![Num::from(5).to_vec()]; basic_test(&script, result, stack); } #[test] fn test_abs_invalid_stack() { let script = Builder::default() .push_opcode(Opcode::OP_ABS) .into_script(); let result = Err(Error::InvalidStackOperation); basic_test(&script, result, vec![]); } #[test] fn test_not() { let script = Builder::default() .push_num(4.into()) .push_opcode(Opcode::OP_NOT) .into_script(); let result = Ok(false); let stack = vec![Num::from(0).to_vec()]; basic_test(&script, result, stack); } #[test] fn test_not_zero() { let script = Builder::default() .push_num(0.into()) .push_opcode(Opcode::OP_NOT) .into_script(); let result = Ok(true); let stack = vec![Num::from(1).to_vec()]; basic_test(&script, result, stack); } #[test] fn test_not_invalid_stack() { let script = Builder::default() .push_opcode(Opcode::OP_NOT) .into_script(); let result = Err(Error::InvalidStackOperation); basic_test(&script, result, vec![]); } #[test] fn test_0notequal() { let script = Builder::default() .push_num(4.into()) .push_opcode(Opcode::OP_0NOTEQUAL) .into_script(); let result = Ok(true); let stack = vec![Num::from(1).to_vec()]; basic_test(&script, result, stack); } #[test] fn test_0notequal_zero() { let script = Builder::default() .push_num(0.into()) .push_opcode(Opcode::OP_0NOTEQUAL) .into_script(); let result = Ok(false); let stack = vec![Num::from(0).to_vec()]; basic_test(&script, result, stack); } #[test] fn test_0notequal_invalid_stack() { let script = Builder::default() .push_opcode(Opcode::OP_0NOTEQUAL) .into_script(); let result = Err(Error::InvalidStackOperation); basic_test(&script, result, vec![]); } #[test] fn test_add() { let script = Builder::default() .push_num(2.into()) .push_num(3.into()) .push_opcode(Opcode::OP_ADD) .into_script(); let result = Ok(true); let stack = vec![Num::from(5).to_vec()]; basic_test(&script, result, stack); } #[test] fn test_add_invalid_stack() { let script = Builder::default() .push_num(2.into()) .push_opcode(Opcode::OP_ADD) .into_script(); let result = Err(Error::InvalidStackOperation); basic_test(&script, result, vec![]); } #[test] fn test_sub() { let script = Builder::default() .push_num(3.into()) .push_num(2.into()) .push_opcode(Opcode::OP_SUB) .into_script(); let result = Ok(true); let stack = vec![Num::from(1).to_vec()]; basic_test(&script, result, stack); } #[test] fn test_sub_invalid_stack() { let script = Builder::default() .push_num(2.into()) .push_opcode(Opcode::OP_SUB) .into_script(); let result = Err(Error::InvalidStackOperation); basic_test(&script, result, vec![]); } #[test] fn test_booland() { let script = Builder::default() .push_num(3.into()) .push_num(2.into()) .push_opcode(Opcode::OP_BOOLAND) .into_script(); let result = Ok(true); let stack = vec![Num::from(1).to_vec()]; basic_test(&script, result, stack); } #[test] fn test_booland_first() { let script = Builder::default() .push_num(2.into()) .push_num(0.into()) .push_opcode(Opcode::OP_BOOLAND) .into_script(); let result = Ok(false); let stack = vec![Num::from(0).to_vec()]; basic_test(&script, result, stack); } #[test] fn test_booland_second() { let script = Builder::default() .push_num(0.into()) .push_num(3.into()) .push_opcode(Opcode::OP_BOOLAND) .into_script(); let result = Ok(false); let stack = vec![Num::from(0).to_vec()]; basic_test(&script, result, stack); } #[test] fn test_booland_none() { let script = Builder::default() .push_num(0.into()) .push_num(0.into()) .push_opcode(Opcode::OP_BOOLAND) .into_script(); let result = Ok(false); let stack = vec![Num::from(0).to_vec()]; basic_test(&script, result, stack); } #[test] fn test_booland_invalid_stack() { let script = Builder::default() .push_num(0.into()) .push_opcode(Opcode::OP_BOOLAND) .into_script(); let result = Err(Error::InvalidStackOperation); basic_test(&script, result, vec![]); } #[test] fn test_boolor() { let script = Builder::default() .push_num(3.into()) .push_num(2.into()) .push_opcode(Opcode::OP_BOOLOR) .into_script(); let result = Ok(true); let stack = vec![Num::from(1).to_vec()]; basic_test(&script, result, stack); } #[test] fn test_boolor_first() { let script = Builder::default() .push_num(2.into()) .push_num(0.into()) .push_opcode(Opcode::OP_BOOLOR) .into_script(); let result = Ok(true); let stack = vec![Num::from(1).to_vec()]; basic_test(&script, result, stack); } #[test] fn test_boolor_second() { let script = Builder::default() .push_num(0.into()) .push_num(3.into()) .push_opcode(Opcode::OP_BOOLOR) .into_script(); let result = Ok(true); let stack = vec![Num::from(1).to_vec()]; basic_test(&script, result, stack); } #[test] fn test_boolor_none() { let script = Builder::default() .push_num(0.into()) .push_num(0.into()) .push_opcode(Opcode::OP_BOOLOR) .into_script(); let result = Ok(false); let stack = vec![Num::from(0).to_vec()]; basic_test(&script, result, stack); } #[test] fn test_boolor_invalid_stack() { let script = Builder::default() .push_num(0.into()) .push_opcode(Opcode::OP_BOOLOR) .into_script(); let result = Err(Error::InvalidStackOperation); basic_test(&script, result, vec![]); } #[test] fn test_numequal() { let script = Builder::default() .push_num(2.into()) .push_num(2.into()) .push_opcode(Opcode::OP_NUMEQUAL) .into_script(); let result = Ok(true); let stack = vec![Num::from(1).to_vec()]; basic_test(&script, result, stack); } #[test] fn test_numequal_not() { let script = Builder::default() .push_num(2.into()) .push_num(3.into()) .push_opcode(Opcode::OP_NUMEQUAL) .into_script(); let result = Ok(false); let stack = vec![Num::from(0).to_vec()]; basic_test(&script, result, stack); } #[test] fn test_numequal_invalid_stack() { let script = Builder::default() .push_num(2.into()) .push_opcode(Opcode::OP_NUMEQUAL) .into_script(); let result = Err(Error::InvalidStackOperation); basic_test(&script, result, vec![]); } #[test] fn test_numequalverify() { let script = Builder::default() .push_num(2.into()) .push_num(2.into()) .push_opcode(Opcode::OP_NUMEQUALVERIFY) .into_script(); let result = Ok(false); let stack = vec![]; basic_test(&script, result, stack); } #[test] fn test_numequalverify_failed() { let script = Builder::default() .push_num(2.into()) .push_num(3.into()) .push_opcode(Opcode::OP_NUMEQUALVERIFY) .into_script(); let result = Err(Error::NumEqualVerify); let stack = vec![]; basic_test(&script, result, stack); } #[test] fn test_numequalverify_invalid_stack() { let script = Builder::default() .push_num(2.into()) .push_opcode(Opcode::OP_NUMEQUALVERIFY) .into_script(); let result = Err(Error::InvalidStackOperation); let stack = vec![]; basic_test(&script, result, stack); } #[test] fn test_numnotequal() { let script = Builder::default() .push_num(2.into()) .push_num(3.into()) .push_opcode(Opcode::OP_NUMNOTEQUAL) .into_script(); let result = Ok(true); let stack = vec![Num::from(1).to_vec()]; basic_test(&script, result, stack); } #[test] fn test_numnotequal_not() { let script = Builder::default() .push_num(2.into()) .push_num(2.into()) .push_opcode(Opcode::OP_NUMNOTEQUAL) .into_script(); let result = Ok(false); let stack = vec![Num::from(0).to_vec()]; basic_test(&script, result, stack); } #[test] fn test_numnotequal_invalid_stack() { let script = Builder::default() .push_num(2.into()) .push_opcode(Opcode::OP_NUMNOTEQUAL) .into_script(); let result = Err(Error::InvalidStackOperation); basic_test(&script, result, vec![]); } #[test] fn test_lessthan() { let script = Builder::default() .push_num(2.into()) .push_num(3.into()) .push_opcode(Opcode::OP_LESSTHAN) .into_script(); let result = Ok(true); let stack = vec![Num::from(1).to_vec()]; basic_test(&script, result, stack); } #[test] fn test_lessthan_not() { let script = Builder::default() .push_num(2.into()) .push_num(2.into()) .push_opcode(Opcode::OP_LESSTHAN) .into_script(); let result = Ok(false); let stack = vec![Num::from(0).to_vec()]; basic_test(&script, result, stack); } #[test] fn test_lessthan_invalid_stack() { let script = Builder::default() .push_num(2.into()) .push_opcode(Opcode::OP_LESSTHAN) .into_script(); let result = Err(Error::InvalidStackOperation); basic_test(&script, result, vec![]); } #[test] fn test_greaterthan() { let script = Builder::default() .push_num(3.into()) .push_num(2.into()) .push_opcode(Opcode::OP_GREATERTHAN) .into_script(); let result = Ok(true); let stack = vec![Num::from(1).to_vec()]; basic_test(&script, result, stack); } #[test] fn test_greaterthan_not() { let script = Builder::default() .push_num(2.into()) .push_num(2.into()) .push_opcode(Opcode::OP_GREATERTHAN) .into_script(); let result = Ok(false); let stack = vec![Num::from(0).to_vec()]; basic_test(&script, result, stack); } #[test] fn test_greaterthan_invalid_stack() { let script = Builder::default() .push_num(2.into()) .push_opcode(Opcode::OP_GREATERTHAN) .into_script(); let result = Err(Error::InvalidStackOperation); basic_test(&script, result, vec![]); } #[test] fn test_lessthanorequal() { let script = Builder::default() .push_num(2.into()) .push_num(3.into()) .push_opcode(Opcode::OP_LESSTHANOREQUAL) .into_script(); let result = Ok(true); let stack = vec![Num::from(1).to_vec()]; basic_test(&script, result, stack); } #[test] fn test_lessthanorequal_equal() { let script = Builder::default() .push_num(2.into()) .push_num(2.into()) .push_opcode(Opcode::OP_LESSTHANOREQUAL) .into_script(); let result = Ok(true); let stack = vec![Num::from(1).to_vec()]; basic_test(&script, result, stack); } #[test] fn test_lessthanorequal_not() { let script = Builder::default() .push_num(2.into()) .push_num(1.into()) .push_opcode(Opcode::OP_LESSTHANOREQUAL) .into_script(); let result = Ok(false); let stack = vec![Num::from(0).to_vec()]; basic_test(&script, result, stack); } #[test] fn test_lessthanorequal_invalid_stack() { let script = Builder::default() .push_num(2.into()) .push_opcode(Opcode::OP_LESSTHANOREQUAL) .into_script(); let result = Err(Error::InvalidStackOperation); basic_test(&script, result, vec![]); } #[test] fn test_greaterthanorequal() { let script = Builder::default() .push_num(3.into()) .push_num(2.into()) .push_opcode(Opcode::OP_GREATERTHANOREQUAL) .into_script(); let result = Ok(true); let stack = vec![Num::from(1).to_vec()]; basic_test(&script, result, stack); } #[test] fn test_greaterthanorequal_equal() { let script = Builder::default() .push_num(2.into()) .push_num(2.into()) .push_opcode(Opcode::OP_GREATERTHANOREQUAL) .into_script(); let result = Ok(true); let stack = vec![Num::from(1).to_vec()]; basic_test(&script, result, stack); } #[test] fn test_greaterthanorequal_not() { let script = Builder::default() .push_num(1.into()) .push_num(2.into()) .push_opcode(Opcode::OP_GREATERTHANOREQUAL) .into_script(); let result = Ok(false); let stack = vec![Num::from(0).to_vec()]; basic_test(&script, result, stack); } #[test] fn test_greaterthanorequal_invalid_stack() { let script = Builder::default() .push_num(2.into()) .push_opcode(Opcode::OP_GREATERTHANOREQUAL) .into_script(); let result = Err(Error::InvalidStackOperation); basic_test(&script, result, vec![]); } #[test] fn test_min() { let script = Builder::default() .push_num(2.into()) .push_num(3.into()) .push_opcode(Opcode::OP_MIN) .into_script(); let result = Ok(true); let stack = vec![Num::from(2).to_vec()]; basic_test(&script, result, stack); } #[test] fn test_min_second() { let script = Builder::default() .push_num(4.into()) .push_num(3.into()) .push_opcode(Opcode::OP_MIN) .into_script(); let result = Ok(true); let stack = vec![Num::from(3).to_vec()]; basic_test(&script, result, stack); } #[test] fn test_min_invalid_stack() { let script = Builder::default() .push_num(4.into()) .push_opcode(Opcode::OP_MIN) .into_script(); let result = Err(Error::InvalidStackOperation); basic_test(&script, result, vec![]); } #[test] fn test_max() { let script = Builder::default() .push_num(2.into()) .push_num(3.into()) .push_opcode(Opcode::OP_MAX) .into_script(); let result = Ok(true); let stack = vec![Num::from(3).to_vec()]; basic_test(&script, result, stack); } #[test] fn test_max_second() { let script = Builder::default() .push_num(4.into()) .push_num(3.into()) .push_opcode(Opcode::OP_MAX) .into_script(); let result = Ok(true); let stack = vec![Num::from(4).to_vec()]; basic_test(&script, result, stack); } #[test] fn test_max_invalid_stack() { let script = Builder::default() .push_num(4.into()) .push_opcode(Opcode::OP_MAX) .into_script(); let result = Err(Error::InvalidStackOperation); basic_test(&script, result, vec![]); } #[test] fn test_within() { let script = Builder::default() .push_num(3.into()) .push_num(2.into()) .push_num(4.into()) .push_opcode(Opcode::OP_WITHIN) .into_script(); let result = Ok(true); let stack = vec![vec![1]]; basic_test(&script, result, stack); } #[test] fn test_within_not() { let script = Builder::default() .push_num(3.into()) .push_num(5.into()) .push_num(4.into()) .push_opcode(Opcode::OP_WITHIN) .into_script(); let result = Ok(false); let stack = vec![vec![0]]; basic_test(&script, result, stack); } #[test] fn test_within_invalid_stack() { let script = Builder::default() .push_num(5.into()) .push_num(4.into()) .push_opcode(Opcode::OP_WITHIN) .into_script(); let result = Err(Error::InvalidStackOperation); basic_test(&script, result, vec![]); } // https://blockchain.info/rawtx/3f285f083de7c0acabd9f106a43ec42687ab0bebe2e6f0d529db696794540fea #[test] fn test_check_transaction_signature() { let tx: Transaction = "0100000001484d40d45b9ea0d652fca8258ab7caa42541eb52975857f96fb50cd732c8b481000000008a47304402202cb265bf10707bf49346c3515dd3d16fc454618c58ec0a0ff448a676c54ff71302206c6624d762a1fcef4618284ead8f08678ac05b13c84235f1654e6ad168233e8201410414e301b2328f17442c0b8310d787bf3d8a404cfbd0704f135b6ad4b2d3ee751310f981926e53a6e8c39bd7d3fefd576c543cce493cbac06388f2651d1aacbfcdffffffff0162640100000000001976a914c8e90996c7c6080ee06284600c684ed904d14c5c88ac00000000".into(); let signer: TransactionInputSigner = tx.into(); let checker = TransactionSignatureChecker { signer: signer, input_index: 0, }; let input: Script = "47304402202cb265bf10707bf49346c3515dd3d16fc454618c58ec0a0ff448a676c54ff71302206c6624d762a1fcef4618284ead8f08678ac05b13c84235f1654e6ad168233e8201410414e301b2328f17442c0b8310d787bf3d8a404cfbd0704f135b6ad4b2d3ee751310f981926e53a6e8c39bd7d3fefd576c543cce493cbac06388f2651d1aacbfcd".into(); let output: Script = "76a914df3bd30160e6c6145baaf2c88a8844c13a00d1d588ac".into(); let flags = VerificationFlags::default() .verify_p2sh(true); let version = SignatureVersion::Base; let mut stack = vec![]; assert!(eval_script(&mut stack, &input, &flags, &checker, version).is_ok()); assert!(eval_script(&mut stack, &output, &flags, &checker, version).unwrap()); } }