/* This file is part of solidity. solidity is free software: you can redistribute it and/or modify it under the terms of the GNU General Public License as published by the Free Software Foundation, either version 3 of the License, or (at your option) any later version. solidity is distributed in the hope that it will be useful, but WITHOUT ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License for more details. You should have received a copy of the GNU General Public License along with solidity. If not, see . */ /** * @author Christian * @author Gav Wood * @date 2014 * Full-stack compiler that converts a source code string to bytecode. */ #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include using namespace std; using namespace dev; using namespace dev::solidity; CompilerStack::CompilerStack(ReadFileCallback const& _readFile): m_readFile(_readFile), m_parseSuccessful(false) {} void CompilerStack::setRemappings(vector const& _remappings) { vector remappings; for (auto const& remapping: _remappings) { auto eq = find(remapping.begin(), remapping.end(), '='); if (eq == remapping.end()) continue; // ignore auto colon = find(remapping.begin(), eq, ':'); Remapping r; r.context = colon == eq ? string() : string(remapping.begin(), colon); r.prefix = colon == eq ? string(remapping.begin(), eq) : string(colon + 1, eq); r.target = string(eq + 1, remapping.end()); remappings.push_back(r); } swap(m_remappings, remappings); } void CompilerStack::reset(bool _keepSources) { m_parseSuccessful = false; if (_keepSources) for (auto sourcePair: m_sources) sourcePair.second.reset(); else { m_sources.clear(); } m_optimize = false; m_optimizeRuns = 200; m_globalContext.reset(); m_sourceOrder.clear(); m_contracts.clear(); m_errors.clear(); } bool CompilerStack::addSource(string const& _name, string const& _content, bool _isLibrary) { bool existed = m_sources.count(_name) != 0; reset(true); m_sources[_name].scanner = make_shared(CharStream(_content), _name); m_sources[_name].isLibrary = _isLibrary; return existed; } void CompilerStack::setSource(string const& _sourceCode) { reset(); addSource("", _sourceCode); } bool CompilerStack::parse() { //reset m_errors.clear(); m_parseSuccessful = false; if (SemVerVersion{string(VersionString)}.isPrerelease()) { auto err = make_shared(Error::Type::Warning); *err << errinfo_comment("This is a pre-release compiler version, please do not use it in production."); m_errors.push_back(err); } vector sourcesToParse; for (auto const& s: m_sources) sourcesToParse.push_back(s.first); map sourceUnitsByName; for (size_t i = 0; i < sourcesToParse.size(); ++i) { string const& path = sourcesToParse[i]; Source& source = m_sources[path]; source.scanner->reset(); source.ast = Parser(m_errors).parse(source.scanner); sourceUnitsByName[path] = source.ast.get(); if (!source.ast) solAssert(!Error::containsOnlyWarnings(m_errors), "Parser returned null but did not report error."); else { source.ast->annotation().path = path; for (auto const& newSource: loadMissingSources(*source.ast, path)) { string const& newPath = newSource.first; string const& newContents = newSource.second; m_sources[newPath].scanner = make_shared(CharStream(newContents), newPath); sourcesToParse.push_back(newPath); } } } if (!Error::containsOnlyWarnings(m_errors)) // errors while parsing. should stop before type checking return false; resolveImports(); bool noErrors = true; SyntaxChecker syntaxChecker(m_errors); for (Source const* source: m_sourceOrder) if (!syntaxChecker.checkSyntax(*source->ast)) noErrors = false; DocStringAnalyser docStringAnalyser(m_errors); for (Source const* source: m_sourceOrder) if (!docStringAnalyser.analyseDocStrings(*source->ast)) noErrors = false; m_globalContext = make_shared(); NameAndTypeResolver resolver(m_globalContext->declarations(), m_errors); for (Source const* source: m_sourceOrder) if (!resolver.registerDeclarations(*source->ast)) return false; for (Source const* source: m_sourceOrder) if (!resolver.performImports(*source->ast, sourceUnitsByName)) return false; for (Source const* source: m_sourceOrder) for (ASTPointer const& node: source->ast->nodes()) if (ContractDefinition* contract = dynamic_cast(node.get())) { m_globalContext->setCurrentContract(*contract); if (!resolver.updateDeclaration(*m_globalContext->currentThis())) return false; if (!resolver.updateDeclaration(*m_globalContext->currentSuper())) return false; if (!resolver.resolveNamesAndTypes(*contract)) return false; m_contracts[contract->name()].contract = contract; } if (!checkLibraryNameClashes()) noErrors = false; for (Source const* source: m_sourceOrder) for (ASTPointer const& node: source->ast->nodes()) if (ContractDefinition* contract = dynamic_cast(node.get())) { m_globalContext->setCurrentContract(*contract); resolver.updateDeclaration(*m_globalContext->currentThis()); TypeChecker typeChecker(m_errors); if (typeChecker.checkTypeRequirements(*contract)) { contract->setDevDocumentation(InterfaceHandler::devDocumentation(*contract)); contract->setUserDocumentation(InterfaceHandler::userDocumentation(*contract)); } else noErrors = false; m_contracts[contract->name()].contract = contract; } if (noErrors) { StaticAnalyzer staticAnalyzer(m_errors); for (Source const* source: m_sourceOrder) if (!staticAnalyzer.analyze(*source->ast)) noErrors = false; } m_parseSuccessful = noErrors; return m_parseSuccessful; } bool CompilerStack::parse(string const& _sourceCode) { setSource(_sourceCode); return parse(); } vector CompilerStack::contractNames() const { if (!m_parseSuccessful) BOOST_THROW_EXCEPTION(CompilerError() << errinfo_comment("Parsing was not successful.")); vector contractNames; for (auto const& contract: m_contracts) contractNames.push_back(contract.first); return contractNames; } bool CompilerStack::compile(bool _optimize, unsigned _runs, map const& _libraries) { if (!m_parseSuccessful) if (!parse()) return false; m_optimize = _optimize; m_optimizeRuns = _runs; m_libraries = _libraries; map compiledContracts; for (Source const* source: m_sourceOrder) for (ASTPointer const& node: source->ast->nodes()) if (auto contract = dynamic_cast(node.get())) compileContract(*contract, compiledContracts); this->link(); return true; } bool CompilerStack::compile(string const& _sourceCode, bool _optimize, unsigned _runs) { return parse(_sourceCode) && compile(_optimize, _runs); } void CompilerStack::link() { for (auto& contract: m_contracts) { contract.second.object.link(m_libraries); contract.second.runtimeObject.link(m_libraries); contract.second.cloneObject.link(m_libraries); } } bool CompilerStack::prepareFormalAnalysis(ErrorList* _errors) { if (!_errors) _errors = &m_errors; Why3Translator translator(*_errors); for (Source const* source: m_sourceOrder) if (!translator.process(*source->ast)) return false; m_formalTranslation = translator.translation(); return true; } eth::AssemblyItems const* CompilerStack::assemblyItems(string const& _contractName) const { Contract const& currentContract = contract(_contractName); return currentContract.compiler ? &contract(_contractName).compiler->assemblyItems() : nullptr; } eth::AssemblyItems const* CompilerStack::runtimeAssemblyItems(string const& _contractName) const { Contract const& currentContract = contract(_contractName); return currentContract.compiler ? &contract(_contractName).compiler->runtimeAssemblyItems() : nullptr; } string const* CompilerStack::sourceMapping(string const& _contractName) const { Contract const& c = contract(_contractName); if (!c.sourceMapping) { if (auto items = assemblyItems(_contractName)) c.sourceMapping.reset(new string(computeSourceMapping(*items))); } return c.sourceMapping.get(); } string const* CompilerStack::runtimeSourceMapping(string const& _contractName) const { Contract const& c = contract(_contractName); if (!c.runtimeSourceMapping) { if (auto items = runtimeAssemblyItems(_contractName)) c.runtimeSourceMapping.reset(new string(computeSourceMapping(*items))); } return c.runtimeSourceMapping.get(); } eth::LinkerObject const& CompilerStack::object(string const& _contractName) const { return contract(_contractName).object; } eth::LinkerObject const& CompilerStack::runtimeObject(string const& _contractName) const { return contract(_contractName).runtimeObject; } eth::LinkerObject const& CompilerStack::cloneObject(string const& _contractName) const { return contract(_contractName).cloneObject; } dev::h256 CompilerStack::contractCodeHash(string const& _contractName) const { auto const& obj = runtimeObject(_contractName); if (obj.bytecode.empty() || !obj.linkReferences.empty()) return dev::h256(); else return dev::keccak256(obj.bytecode); } Json::Value CompilerStack::streamAssembly(ostream& _outStream, string const& _contractName, StringMap _sourceCodes, bool _inJsonFormat) const { Contract const& currentContract = contract(_contractName); if (currentContract.compiler) return currentContract.compiler->streamAssembly(_outStream, _sourceCodes, _inJsonFormat); else { _outStream << "Contract not fully implemented" << endl; return Json::Value(); } } vector CompilerStack::sourceNames() const { vector names; for (auto const& s: m_sources) names.push_back(s.first); return names; } map CompilerStack::sourceIndices() const { map indices; for (auto const& s: m_sources) indices[s.first] = indices.size(); return indices; } Json::Value const& CompilerStack::interface(string const& _contractName) const { return metadata(_contractName, DocumentationType::ABIInterface); } Json::Value const& CompilerStack::metadata(string const& _contractName, DocumentationType _type) const { if (!m_parseSuccessful) BOOST_THROW_EXCEPTION(CompilerError() << errinfo_comment("Parsing was not successful.")); return metadata(contract(_contractName), _type); } Json::Value const& CompilerStack::metadata(Contract const& _contract, DocumentationType _type) const { if (!m_parseSuccessful) BOOST_THROW_EXCEPTION(CompilerError() << errinfo_comment("Parsing was not successful.")); solAssert(_contract.contract, ""); std::unique_ptr* doc; // checks wheather we already have the documentation switch (_type) { case DocumentationType::NatspecUser: doc = &_contract.userDocumentation; break; case DocumentationType::NatspecDev: doc = &_contract.devDocumentation; break; case DocumentationType::ABIInterface: doc = &_contract.interface; break; default: BOOST_THROW_EXCEPTION(InternalCompilerError() << errinfo_comment("Illegal documentation type.")); } // caches the result if (!*doc) doc->reset(new Json::Value(InterfaceHandler::documentation(*_contract.contract, _type))); return *(*doc); } string const& CompilerStack::onChainMetadata(string const& _contractName) const { if (!m_parseSuccessful) BOOST_THROW_EXCEPTION(CompilerError() << errinfo_comment("Parsing was not successful.")); return contract(_contractName).onChainMetadata; } Scanner const& CompilerStack::scanner(string const& _sourceName) const { return *source(_sourceName).scanner; } SourceUnit const& CompilerStack::ast(string const& _sourceName) const { return *source(_sourceName).ast; } ContractDefinition const& CompilerStack::contractDefinition(string const& _contractName) const { return *contract(_contractName).contract; } size_t CompilerStack::functionEntryPoint( std::string const& _contractName, FunctionDefinition const& _function ) const { shared_ptr const& compiler = contract(_contractName).compiler; if (!compiler) return 0; eth::AssemblyItem tag = compiler->functionEntryLabel(_function); if (tag.type() == eth::UndefinedItem) return 0; eth::AssemblyItems const& items = compiler->runtimeAssemblyItems(); for (size_t i = 0; i < items.size(); ++i) if (items.at(i).type() == eth::Tag && items.at(i).data() == tag.data()) return i; return 0; } tuple CompilerStack::positionFromSourceLocation(SourceLocation const& _sourceLocation) const { int startLine; int startColumn; int endLine; int endColumn; tie(startLine, startColumn) = scanner(*_sourceLocation.sourceName).translatePositionToLineColumn(_sourceLocation.start); tie(endLine, endColumn) = scanner(*_sourceLocation.sourceName).translatePositionToLineColumn(_sourceLocation.end); return make_tuple(++startLine, ++startColumn, ++endLine, ++endColumn); } StringMap CompilerStack::loadMissingSources(SourceUnit const& _ast, std::string const& _sourcePath) { StringMap newSources; for (auto const& node: _ast.nodes()) if (ImportDirective const* import = dynamic_cast(node.get())) { string importPath = absolutePath(import->path(), _sourcePath); // The current value of `path` is the absolute path as seen from this source file. // We first have to apply remappings before we can store the actual absolute path // as seen globally. importPath = applyRemapping(importPath, _sourcePath); import->annotation().absolutePath = importPath; if (m_sources.count(importPath) || newSources.count(importPath)) continue; ReadFileResult result{false, string("File not supplied initially.")}; if (m_readFile) result = m_readFile(importPath); if (result.success) newSources[importPath] = result.contentsOrErrorMesage; else { auto err = make_shared(Error::Type::ParserError); *err << errinfo_sourceLocation(import->location()) << errinfo_comment("Source \"" + importPath + "\" not found: " + result.contentsOrErrorMesage); m_errors.push_back(std::move(err)); continue; } } return newSources; } string CompilerStack::applyRemapping(string const& _path, string const& _context) { // Try to find the longest prefix match in all remappings that are active in the current context. auto isPrefixOf = [](string const& _a, string const& _b) { if (_a.length() > _b.length()) return false; return std::equal(_a.begin(), _a.end(), _b.begin()); }; size_t longestPrefix = 0; size_t longestContext = 0; string bestMatchTarget; for (auto const& redir: m_remappings) { string context = sanitizePath(redir.context); string prefix = sanitizePath(redir.prefix); // Skip if current context is closer if (context.length() < longestContext) continue; // Skip if redir.context is not a prefix of _context if (!isPrefixOf(context, _context)) continue; // Skip if we already have a closer prefix match. if (prefix.length() < longestPrefix && context.length() == longestContext) continue; // Skip if the prefix does not match. if (!isPrefixOf(prefix, _path)) continue; longestContext = context.length(); longestPrefix = prefix.length(); bestMatchTarget = sanitizePath(redir.target); } string path = bestMatchTarget; path.append(_path.begin() + longestPrefix, _path.end()); return path; } void CompilerStack::resolveImports() { // topological sorting (depth first search) of the import graph, cutting potential cycles vector sourceOrder; set sourcesSeen; function toposort = [&](Source const* _source) { if (sourcesSeen.count(_source)) return; sourcesSeen.insert(_source); for (ASTPointer const& node: _source->ast->nodes()) if (ImportDirective const* import = dynamic_cast(node.get())) { string const& path = import->annotation().absolutePath; solAssert(!path.empty(), ""); solAssert(m_sources.count(path), ""); import->annotation().sourceUnit = m_sources[path].ast.get(); toposort(&m_sources[path]); } sourceOrder.push_back(_source); }; for (auto const& sourcePair: m_sources) if (!sourcePair.second.isLibrary) toposort(&sourcePair.second); swap(m_sourceOrder, sourceOrder); } bool CompilerStack::checkLibraryNameClashes() { bool clashFound = false; map libraries; for (Source const* source: m_sourceOrder) for (ASTPointer const& node: source->ast->nodes()) if (ContractDefinition* contract = dynamic_cast(node.get())) if (contract->isLibrary()) { if (libraries.count(contract->name())) { auto err = make_shared(Error::Type::DeclarationError); *err << errinfo_sourceLocation(contract->location()) << errinfo_comment( "Library \"" + contract->name() + "\" declared twice " "(will create ambiguities during linking)." ) << errinfo_secondarySourceLocation(SecondarySourceLocation().append( "The other declaration is here:", libraries[contract->name()] )); m_errors.push_back(err); clashFound = true; } else libraries[contract->name()] = contract->location(); } return !clashFound; } string CompilerStack::absolutePath(string const& _path, string const& _reference) const { using path = boost::filesystem::path; path p(_path); // Anything that does not start with `.` is an absolute path. if (p.begin() == p.end() || (*p.begin() != "." && *p.begin() != "..")) return _path; path result(_reference); result.remove_filename(); for (path::iterator it = p.begin(); it != p.end(); ++it) if (*it == "..") result = result.parent_path(); else if (*it != ".") result /= *it; return result.generic_string(); } void CompilerStack::compileContract( ContractDefinition const& _contract, map& _compiledContracts ) { if (_compiledContracts.count(&_contract) || !_contract.annotation().isFullyImplemented) return; for (auto const* dependency: _contract.annotation().contractDependencies) compileContract(*dependency, _compiledContracts); shared_ptr compiler = make_shared(m_optimize, m_optimizeRuns); Contract& compiledContract = m_contracts.at(_contract.name()); string onChainMetadata = createOnChainMetadata(compiledContract); bytes cborEncodedMetadata = // CBOR-encoding of {"bzzr0": dev::swarmHash(onChainMetadata)} bytes{0xa1, 0x65, 'b', 'z', 'z', 'r', '0', 0x58, 0x20} + dev::swarmHash(onChainMetadata).asBytes(); solAssert(cborEncodedMetadata.size() <= 0xffff, "Metadata too large"); // 16-bit big endian length cborEncodedMetadata += toCompactBigEndian(cborEncodedMetadata.size(), 2); compiler->compileContract(_contract, _compiledContracts, cborEncodedMetadata); compiledContract.compiler = compiler; compiledContract.object = compiler->assembledObject(); compiledContract.runtimeObject = compiler->runtimeObject(); compiledContract.onChainMetadata = onChainMetadata; _compiledContracts[compiledContract.contract] = &compiler->assembly(); try { Compiler cloneCompiler(m_optimize, m_optimizeRuns); cloneCompiler.compileClone(_contract, _compiledContracts); compiledContract.cloneObject = cloneCompiler.assembledObject(); } catch (eth::AssemblyException const&) { // In some cases (if the constructor requests a runtime function), it is not // possible to compile the clone. // TODO: Report error / warning } } std::string CompilerStack::defaultContractName() const { return contract("").contract->name(); } CompilerStack::Contract const& CompilerStack::contract(string const& _contractName) const { if (m_contracts.empty()) BOOST_THROW_EXCEPTION(CompilerError() << errinfo_comment("No compiled contracts found.")); string contractName = _contractName; if (_contractName.empty()) // try to find some user-supplied contract for (auto const& it: m_sources) for (ASTPointer const& node: it.second.ast->nodes()) if (auto contract = dynamic_cast(node.get())) contractName = contract->name(); auto it = m_contracts.find(contractName); if (it == m_contracts.end()) BOOST_THROW_EXCEPTION(CompilerError() << errinfo_comment("Contract " + _contractName + " not found.")); return it->second; } CompilerStack::Source const& CompilerStack::source(string const& _sourceName) const { auto it = m_sources.find(_sourceName); if (it == m_sources.end()) BOOST_THROW_EXCEPTION(CompilerError() << errinfo_comment("Given source file not found.")); return it->second; } string CompilerStack::createOnChainMetadata(Contract const& _contract) const { Json::Value meta; meta["version"] = 1; meta["language"] = "Solidity"; meta["compiler"]["version"] = VersionStringStrict; meta["sources"] = Json::objectValue; for (auto const& s: m_sources) { solAssert(s.second.scanner, "Scanner not available"); meta["sources"][s.first]["keccak256"] = "0x" + toHex(dev::keccak256(s.second.scanner->source()).asBytes()); meta["sources"][s.first]["urls"] = Json::arrayValue; meta["sources"][s.first]["urls"].append( "bzzr://" + toHex(dev::swarmHash(s.second.scanner->source()).asBytes()) ); } meta["settings"]["optimizer"]["enabled"] = m_optimize; meta["settings"]["optimizer"]["runs"] = m_optimizeRuns; meta["settings"]["compilationTarget"][_contract.contract->sourceUnitName()] = _contract.contract->annotation().canonicalName; meta["settings"]["remappings"] = Json::arrayValue; set remappings; for (auto const& r: m_remappings) remappings.insert(r.context + ":" + r.prefix + "=" + r.target); for (auto const& r: remappings) meta["settings"]["remappings"].append(r); meta["settings"]["libraries"] = Json::objectValue; for (auto const& library: m_libraries) meta["settings"]["libraries"][library.first] = "0x" + toHex(library.second.asBytes()); meta["output"]["abi"] = metadata(_contract, DocumentationType::ABIInterface); meta["output"]["userdoc"] = metadata(_contract, DocumentationType::NatspecUser); meta["output"]["devdoc"] = metadata(_contract, DocumentationType::NatspecDev); return jsonCompactPrint(meta); } string CompilerStack::computeSourceMapping(eth::AssemblyItems const& _items) const { string ret; map sourceIndicesMap = sourceIndices(); int prevStart = -1; int prevLength = -1; int prevSourceIndex = -1; char prevJump = 0; for (auto const& item: _items) { if (!ret.empty()) ret += ";"; SourceLocation const& location = item.location(); int length = location.start != -1 && location.end != -1 ? location.end - location.start : -1; int sourceIndex = location.sourceName && sourceIndicesMap.count(*location.sourceName) ? sourceIndicesMap.at(*location.sourceName) : -1; char jump = '-'; if (item.getJumpType() == eth::AssemblyItem::JumpType::IntoFunction) jump = 'i'; else if (item.getJumpType() == eth::AssemblyItem::JumpType::OutOfFunction) jump = 'o'; unsigned components = 4; if (jump == prevJump) { components--; if (sourceIndex == prevSourceIndex) { components--; if (length == prevLength) { components--; if (location.start == prevStart) components--; } } } if (components-- > 0) { if (location.start != prevStart) ret += std::to_string(location.start); if (components-- > 0) { ret += ':'; if (length != prevLength) ret += std::to_string(length); if (components-- > 0) { ret += ':'; if (sourceIndex != prevSourceIndex) ret += std::to_string(sourceIndex); if (components-- > 0) { ret += ':'; if (jump != prevJump) ret += jump; } } } } prevStart = location.start; prevLength = length; prevSourceIndex = sourceIndex; prevJump = jump; } return ret; }