import { addressUtils, BigNumber } from '@0xproject/utils';
import { OpCode, StructLog } from 'ethereum-types';
import { addHexPrefix } from 'ethereumjs-util';
import * as _ from 'lodash';
import { ContractData, LineColumn, SingleFileSourceRange } from './types';
// This is the minimum length of valid contract bytecode. The Solidity compiler
// metadata is 86 bytes. If you add the '0x' prefix, we get 88.
const MIN_CONTRACT_BYTECODE_LENGTH = 88;
export const utils = {
compareLineColumn(lhs: LineColumn, rhs: LineColumn): number {
return lhs.line !== rhs.line ? lhs.line - rhs.line : lhs.column - rhs.column;
},
removeHexPrefix(hex: string): string {
const hexPrefix = '0x';
return hex.startsWith(hexPrefix) ? hex.slice(hexPrefix.length) : hex;
},
isRangeInside(childRange: SingleFileSourceRange, parentRange: SingleFileSourceRange): boolean {
return (
utils.compareLineColumn(parentRange.start, childRange.start) <= 0 &&
utils.compareLineColumn(childRange.end, parentRange.end) <= 0
);
},
bytecodeToBytecodeRegex(bytecode: string): string {
const bytecodeRegex = bytecode
// Library linking placeholder: __ConvertLib____________________________
.replace(/_.*_/, '.*')
// Last 86 characters is solidity compiler metadata that's different between compilations
.replace(/.{86}$/, '')
// Libraries contain their own address at the beginning of the code and it's impossible to know it in advance
.replace(/^0x730000000000000000000000000000000000000000/, '0x73........................................');
// HACK: Node regexes can't be longer that 32767 characters. Contracts bytecode can. We just truncate the regexes. It's safe in practice.
const MAX_REGEX_LENGTH = 32767;
const truncatedBytecodeRegex = bytecodeRegex.slice(0, MAX_REGEX_LENGTH);
return truncatedBytecodeRegex;
},
getContractDataIfExists(contractsData: ContractData[], bytecode: string): ContractData | undefined {
if (!bytecode.startsWith('0x')) {
throw new Error(`0x hex prefix missing: ${bytecode}`);
}
const contractData = _.find(contractsData, contractDataCandidate => {
const bytecodeRegex = utils.bytecodeToBytecodeRegex(contractDataCandidate.bytecode);
// If the bytecode is less than the minimum length, we are probably
// dealing with an interface. This isn't what we're looking for.
if (bytecodeRegex.length < MIN_CONTRACT_BYTECODE_LENGTH) {
return false;
}
const runtimeBytecodeRegex = utils.bytecodeToBytecodeRegex(contractDataCandidate.runtimeBytecode);
if (runtimeBytecodeRegex.length < MIN_CONTRACT_BYTECODE_LENGTH) {
return false;
}
// We use that function to find by bytecode or runtimeBytecode. Those are quasi-random strings so
// collisions are practically impossible and it allows us to reuse that code
return !_.isNull(bytecode.match(bytecodeRegex)) || !_.isNull(bytecode.match(runtimeBytecodeRegex));
});
return contractData;
},
isCallLike(op: OpCode): boolean {
return _.includes([OpCode.CallCode, OpCode.StaticCall, OpCode.Call, OpCode.DelegateCall], op);
},
isEndOpcode(op: OpCode): boolean {
return _.includes([OpCode.Return, OpCode.Stop, OpCode.Revert, OpCode.Invalid, OpCode.SelfDestruct], op);
},
getAddressFromStackEntry(stackEntry: string): string {
const hexBase = 16;
return addressUtils.padZeros(new BigNumber(addHexPrefix(stackEntry)).toString(hexBase));
},
normalizeStructLogs(structLogs: StructLog[]): StructLog[] {
if (structLogs[0].depth === 1) {
// Geth uses 1-indexed depth counter whilst ganache starts from 0
const newStructLogs = _.map(structLogs, structLog => ({
...structLog,
depth: structLog.depth - 1,
}));
return newStructLogs;
}
return structLogs;
},
getRange(sourceCode: string, range: SingleFileSourceRange): string {
const lines = sourceCode.split('\n').slice(range.start.line - 1, range.end.line);
lines[lines.length - 1] = lines[lines.length - 1].slice(0, range.end.column);
lines[0] = lines[0].slice(range.start.column);
return lines.join('\n');
},
};
