solidity/libsolidity/codegen/CompilerContext.cpp
2021-03-23 11:47:19 +01:00

628 lines
20 KiB
C++

/*
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 <http://www.gnu.org/licenses/>.
*/
// SPDX-License-Identifier: GPL-3.0
/**
* @author Christian <c@ethdev.com>
* @date 2014
* Utilities for the solidity compiler.
*/
#include <libsolidity/codegen/CompilerContext.h>
#include <libsolidity/ast/AST.h>
#include <libsolidity/codegen/Compiler.h>
#include <libsolidity/codegen/CompilerUtils.h>
#include <libsolidity/interface/Version.h>
#include <libyul/AsmParser.h>
#include <libyul/AsmPrinter.h>
#include <libyul/AsmAnalysis.h>
#include <libyul/AsmAnalysisInfo.h>
#include <libyul/AST.h>
#include <libyul/backends/evm/AsmCodeGen.h>
#include <libyul/backends/evm/EVMDialect.h>
#include <libyul/backends/evm/EVMMetrics.h>
#include <libyul/optimiser/Suite.h>
#include <libyul/Object.h>
#include <libyul/YulString.h>
#include <libyul/Utilities.h>
#include <libsolutil/Whiskers.h>
#include <libsolutil/FunctionSelector.h>
#include <liblangutil/ErrorReporter.h>
#include <liblangutil/Scanner.h>
#include <liblangutil/SourceReferenceFormatter.h>
#include <boost/algorithm/string/replace.hpp>
#include <utility>
#include <numeric>
// Change to "define" to output all intermediate code
#undef SOL_OUTPUT_ASM
using namespace std;
using namespace solidity;
using namespace solidity::util;
using namespace solidity::evmasm;
using namespace solidity::frontend;
using namespace solidity::langutil;
void CompilerContext::addStateVariable(
VariableDeclaration const& _declaration,
u256 const& _storageOffset,
unsigned _byteOffset
)
{
m_stateVariables[&_declaration] = make_pair(_storageOffset, _byteOffset);
}
void CompilerContext::addImmutable(VariableDeclaration const& _variable)
{
solAssert(_variable.immutable(), "Attempted to register a non-immutable variable as immutable.");
solUnimplementedAssert(_variable.annotation().type->isValueType(), "Only immutable variables of value type are supported.");
solAssert(m_runtimeContext, "Attempted to register an immutable variable for runtime code generation.");
m_immutableVariables[&_variable] = CompilerUtils::generalPurposeMemoryStart + *m_reservedMemory;
solAssert(_variable.annotation().type->memoryHeadSize() == 32, "Memory writes might overlap.");
*m_reservedMemory += _variable.annotation().type->memoryHeadSize();
}
size_t CompilerContext::immutableMemoryOffset(VariableDeclaration const& _variable) const
{
solAssert(m_immutableVariables.count(&_variable), "Memory offset of unknown immutable queried.");
solAssert(m_runtimeContext, "Attempted to fetch the memory offset of an immutable variable during runtime code generation.");
return m_immutableVariables.at(&_variable);
}
vector<string> CompilerContext::immutableVariableSlotNames(VariableDeclaration const& _variable)
{
string baseName = to_string(_variable.id());
solAssert(_variable.annotation().type->sizeOnStack() > 0, "");
if (_variable.annotation().type->sizeOnStack() == 1)
return {baseName};
vector<string> names;
auto collectSlotNames = [&](string const& _baseName, Type const* type, auto const& _recurse) -> void {
for (auto const& [slot, type]: type->stackItems())
if (type)
_recurse(_baseName + " " + slot, type, _recurse);
else
names.emplace_back(_baseName);
};
collectSlotNames(baseName, _variable.annotation().type, collectSlotNames);
return names;
}
size_t CompilerContext::reservedMemory()
{
solAssert(m_reservedMemory.has_value(), "Reserved memory was used before ");
size_t reservedMemory = *m_reservedMemory;
m_reservedMemory = std::nullopt;
return reservedMemory;
}
void CompilerContext::startFunction(Declaration const& _function)
{
m_functionCompilationQueue.startFunction(_function);
*this << functionEntryLabel(_function);
}
void CompilerContext::callLowLevelFunction(
string const& _name,
unsigned _inArgs,
unsigned _outArgs,
function<void(CompilerContext&)> const& _generator
)
{
evmasm::AssemblyItem retTag = pushNewTag();
CompilerUtils(*this).moveIntoStack(_inArgs);
*this << lowLevelFunctionTag(_name, _inArgs, _outArgs, _generator);
appendJump(evmasm::AssemblyItem::JumpType::IntoFunction);
adjustStackOffset(static_cast<int>(_outArgs) - 1 - static_cast<int>(_inArgs));
*this << retTag.tag();
}
void CompilerContext::callYulFunction(
string const& _name,
unsigned _inArgs,
unsigned _outArgs
)
{
m_externallyUsedYulFunctions.insert(_name);
auto const retTag = pushNewTag();
CompilerUtils(*this).moveIntoStack(_inArgs);
appendJumpTo(namedTag(_name), evmasm::AssemblyItem::JumpType::IntoFunction);
adjustStackOffset(static_cast<int>(_outArgs) - 1 - static_cast<int>(_inArgs));
*this << retTag.tag();
}
evmasm::AssemblyItem CompilerContext::lowLevelFunctionTag(
string const& _name,
unsigned _inArgs,
unsigned _outArgs,
function<void(CompilerContext&)> const& _generator
)
{
auto it = m_lowLevelFunctions.find(_name);
if (it == m_lowLevelFunctions.end())
{
evmasm::AssemblyItem tag = newTag().pushTag();
m_lowLevelFunctions.insert(make_pair(_name, tag));
m_lowLevelFunctionGenerationQueue.push(make_tuple(_name, _inArgs, _outArgs, _generator));
return tag;
}
else
return it->second;
}
void CompilerContext::appendMissingLowLevelFunctions()
{
while (!m_lowLevelFunctionGenerationQueue.empty())
{
string name;
unsigned inArgs;
unsigned outArgs;
function<void(CompilerContext&)> generator;
tie(name, inArgs, outArgs, generator) = m_lowLevelFunctionGenerationQueue.front();
m_lowLevelFunctionGenerationQueue.pop();
setStackOffset(static_cast<int>(inArgs) + 1);
*this << m_lowLevelFunctions.at(name).tag();
generator(*this);
CompilerUtils(*this).moveToStackTop(outArgs);
appendJump(evmasm::AssemblyItem::JumpType::OutOfFunction);
solAssert(stackHeight() == outArgs, "Invalid stack height in low-level function " + name + ".");
}
}
void CompilerContext::appendYulUtilityFunctions(OptimiserSettings const& _optimiserSettings)
{
solAssert(!m_appendYulUtilityFunctionsRan, "requestedYulFunctions called more than once.");
m_appendYulUtilityFunctionsRan = true;
string code = m_yulFunctionCollector.requestedFunctions();
if (!code.empty())
{
appendInlineAssembly(
yul::reindent("{\n" + move(code) + "\n}"),
{},
m_externallyUsedYulFunctions,
true,
_optimiserSettings,
yulUtilityFileName()
);
solAssert(!m_generatedYulUtilityCode.empty(), "");
}
}
void CompilerContext::addVariable(
VariableDeclaration const& _declaration,
unsigned _offsetToCurrent
)
{
solAssert(m_asm->deposit() >= 0 && unsigned(m_asm->deposit()) >= _offsetToCurrent, "");
unsigned sizeOnStack = _declaration.annotation().type->sizeOnStack();
// Variables should not have stack size other than [1, 2],
// but that might change when new types are introduced.
solAssert(sizeOnStack == 1 || sizeOnStack == 2, "");
m_localVariables[&_declaration].push_back(unsigned(m_asm->deposit()) - _offsetToCurrent);
}
void CompilerContext::removeVariable(Declaration const& _declaration)
{
solAssert(m_localVariables.count(&_declaration) && !m_localVariables[&_declaration].empty(), "");
m_localVariables[&_declaration].pop_back();
if (m_localVariables[&_declaration].empty())
m_localVariables.erase(&_declaration);
}
void CompilerContext::removeVariablesAboveStackHeight(unsigned _stackHeight)
{
vector<Declaration const*> toRemove;
for (auto _var: m_localVariables)
{
solAssert(!_var.second.empty(), "");
solAssert(_var.second.back() <= stackHeight(), "");
if (_var.second.back() >= _stackHeight)
toRemove.push_back(_var.first);
}
for (auto _var: toRemove)
removeVariable(*_var);
}
unsigned CompilerContext::numberOfLocalVariables() const
{
return static_cast<unsigned>(m_localVariables.size());
}
shared_ptr<evmasm::Assembly> CompilerContext::compiledContract(ContractDefinition const& _contract) const
{
auto ret = m_otherCompilers.find(&_contract);
solAssert(ret != m_otherCompilers.end(), "Compiled contract not found.");
return ret->second->assemblyPtr();
}
shared_ptr<evmasm::Assembly> CompilerContext::compiledContractRuntime(ContractDefinition const& _contract) const
{
auto ret = m_otherCompilers.find(&_contract);
solAssert(ret != m_otherCompilers.end(), "Compiled contract not found.");
return ret->second->runtimeAssemblyPtr();
}
bool CompilerContext::isLocalVariable(Declaration const* _declaration) const
{
return !!m_localVariables.count(_declaration);
}
evmasm::AssemblyItem CompilerContext::functionEntryLabel(Declaration const& _declaration)
{
return m_functionCompilationQueue.entryLabel(_declaration, *this);
}
evmasm::AssemblyItem CompilerContext::functionEntryLabelIfExists(Declaration const& _declaration) const
{
return m_functionCompilationQueue.entryLabelIfExists(_declaration);
}
FunctionDefinition const& CompilerContext::superFunction(FunctionDefinition const& _function, ContractDefinition const& _base)
{
solAssert(m_mostDerivedContract, "No most derived contract set.");
ContractDefinition const* super = _base.superContract(mostDerivedContract());
solAssert(super, "Super contract not available.");
return _function.resolveVirtual(mostDerivedContract(), super);
}
ContractDefinition const& CompilerContext::mostDerivedContract() const
{
solAssert(m_mostDerivedContract, "Most derived contract not set.");
return *m_mostDerivedContract;
}
Declaration const* CompilerContext::nextFunctionToCompile() const
{
return m_functionCompilationQueue.nextFunctionToCompile();
}
unsigned CompilerContext::baseStackOffsetOfVariable(Declaration const& _declaration) const
{
auto res = m_localVariables.find(&_declaration);
solAssert(res != m_localVariables.end(), "Variable not found on stack.");
solAssert(!res->second.empty(), "");
return res->second.back();
}
unsigned CompilerContext::baseToCurrentStackOffset(unsigned _baseOffset) const
{
return static_cast<unsigned>(m_asm->deposit()) - _baseOffset - 1;
}
unsigned CompilerContext::currentToBaseStackOffset(unsigned _offset) const
{
return static_cast<unsigned>(m_asm->deposit()) - _offset - 1;
}
pair<u256, unsigned> CompilerContext::storageLocationOfVariable(Declaration const& _declaration) const
{
auto it = m_stateVariables.find(&_declaration);
solAssert(it != m_stateVariables.end(), "Variable not found in storage.");
return it->second;
}
CompilerContext& CompilerContext::appendJump(evmasm::AssemblyItem::JumpType _jumpType)
{
evmasm::AssemblyItem item(Instruction::JUMP);
item.setJumpType(_jumpType);
return *this << item;
}
CompilerContext& CompilerContext::appendPanic(util::PanicCode _code)
{
Whiskers templ(R"({
mstore(0, <selector>)
mstore(4, <code>)
revert(0, 0x24)
})");
templ("selector", util::selectorFromSignature("Panic(uint256)").str());
templ("code", u256(_code).str());
appendInlineAssembly(templ.render());
return *this;
}
CompilerContext& CompilerContext::appendConditionalPanic(util::PanicCode _code)
{
*this << Instruction::ISZERO;
evmasm::AssemblyItem afterTag = appendConditionalJump();
appendPanic(_code);
*this << afterTag;
return *this;
}
CompilerContext& CompilerContext::appendRevert(string const& _message)
{
appendInlineAssembly("{ " + revertReasonIfDebug(_message) + " }");
return *this;
}
CompilerContext& CompilerContext::appendConditionalRevert(bool _forwardReturnData, string const& _message)
{
if (_forwardReturnData && m_evmVersion.supportsReturndata())
appendInlineAssembly(R"({
if condition {
returndatacopy(0, 0, returndatasize())
revert(0, returndatasize())
}
})", {"condition"});
else
appendInlineAssembly("{ if condition { " + revertReasonIfDebug(_message) + " } }", {"condition"});
*this << Instruction::POP;
return *this;
}
void CompilerContext::resetVisitedNodes(ASTNode const* _node)
{
stack<ASTNode const*> newStack;
newStack.push(_node);
std::swap(m_visitedNodes, newStack);
updateSourceLocation();
}
void CompilerContext::appendInlineAssembly(
string const& _assembly,
vector<string> const& _localVariables,
set<string> const& _externallyUsedFunctions,
bool _system,
OptimiserSettings const& _optimiserSettings,
string _sourceName
)
{
unsigned startStackHeight = stackHeight();
set<yul::YulString> externallyUsedIdentifiers;
for (auto const& fun: _externallyUsedFunctions)
externallyUsedIdentifiers.insert(yul::YulString(fun));
for (auto const& var: _localVariables)
externallyUsedIdentifiers.insert(yul::YulString(var));
yul::ExternalIdentifierAccess identifierAccess;
identifierAccess.resolve = [&](
yul::Identifier const& _identifier,
yul::IdentifierContext,
bool _insideFunction
) -> bool
{
if (_insideFunction)
return false;
return contains(_localVariables, _identifier.name.str());
};
identifierAccess.generateCode = [&](
yul::Identifier const& _identifier,
yul::IdentifierContext _context,
yul::AbstractAssembly& _assembly
)
{
auto it = std::find(_localVariables.begin(), _localVariables.end(), _identifier.name.str());
solAssert(it != _localVariables.end(), "");
auto stackDepth = static_cast<size_t>(distance(it, _localVariables.end()));
size_t stackDiff = static_cast<size_t>(_assembly.stackHeight()) - startStackHeight + stackDepth;
if (_context == yul::IdentifierContext::LValue)
stackDiff -= 1;
if (stackDiff < 1 || stackDiff > 16)
BOOST_THROW_EXCEPTION(
StackTooDeepError() <<
errinfo_sourceLocation(_identifier.location) <<
util::errinfo_comment("Stack too deep (" + to_string(stackDiff) + "), try removing local variables.")
);
if (_context == yul::IdentifierContext::RValue)
_assembly.appendInstruction(dupInstruction(static_cast<unsigned>(stackDiff)));
else
{
_assembly.appendInstruction(swapInstruction(static_cast<unsigned>(stackDiff)));
_assembly.appendInstruction(Instruction::POP);
}
};
ErrorList errors;
ErrorReporter errorReporter(errors);
auto scanner = make_shared<langutil::Scanner>(langutil::CharStream(_assembly, _sourceName));
yul::EVMDialect const& dialect = yul::EVMDialect::strictAssemblyForEVM(m_evmVersion);
optional<langutil::SourceLocation> locationOverride;
if (!_system)
locationOverride = m_asm->currentSourceLocation();
shared_ptr<yul::Block> parserResult =
yul::Parser(errorReporter, dialect, std::move(locationOverride))
.parse(scanner, false);
#ifdef SOL_OUTPUT_ASM
cout << yul::AsmPrinter(&dialect)(*parserResult) << endl;
#endif
auto reportError = [&](string const& _context)
{
string message =
"Error parsing/analyzing inline assembly block:\n" +
_context + "\n"
"------------------ Input: -----------------\n" +
_assembly + "\n"
"------------------ Errors: ----------------\n";
for (auto const& error: errorReporter.errors())
message += SourceReferenceFormatter::formatErrorInformation(*error);
message += "-------------------------------------------\n";
solAssert(false, message);
};
yul::AsmAnalysisInfo analysisInfo;
bool analyzerResult = false;
if (parserResult)
analyzerResult = yul::AsmAnalyzer(
analysisInfo,
errorReporter,
dialect,
identifierAccess.resolve
).analyze(*parserResult);
if (!parserResult || !errorReporter.errors().empty() || !analyzerResult)
reportError("Invalid assembly generated by code generator.");
// Several optimizer steps cannot handle externally supplied stack variables,
// so we essentially only optimize the ABI functions.
if (_optimiserSettings.runYulOptimiser && _localVariables.empty())
{
yul::Object obj;
obj.code = parserResult;
obj.analysisInfo = make_shared<yul::AsmAnalysisInfo>(analysisInfo);
optimizeYul(obj, dialect, _optimiserSettings, externallyUsedIdentifiers);
if (_system)
{
// Store as generated sources, but first re-parse to update the source references.
solAssert(m_generatedYulUtilityCode.empty(), "");
m_generatedYulUtilityCode = yul::AsmPrinter(dialect)(*obj.code);
string code = yul::AsmPrinter{dialect}(*obj.code);
scanner = make_shared<langutil::Scanner>(langutil::CharStream(m_generatedYulUtilityCode, _sourceName));
obj.code = yul::Parser(errorReporter, dialect).parse(scanner, false);
*obj.analysisInfo = yul::AsmAnalyzer::analyzeStrictAssertCorrect(dialect, obj);
}
analysisInfo = std::move(*obj.analysisInfo);
parserResult = std::move(obj.code);
#ifdef SOL_OUTPUT_ASM
cout << "After optimizer:" << endl;
cout << yul::AsmPrinter(&dialect)(*parserResult) << endl;
#endif
}
else if (_system)
{
// Store as generated source.
solAssert(m_generatedYulUtilityCode.empty(), "");
m_generatedYulUtilityCode = _assembly;
}
if (!errorReporter.errors().empty())
reportError("Failed to analyze inline assembly block.");
solAssert(errorReporter.errors().empty(), "Failed to analyze inline assembly block.");
yul::CodeGenerator::assemble(
*parserResult,
analysisInfo,
*m_asm,
m_evmVersion,
identifierAccess,
_system,
_optimiserSettings.optimizeStackAllocation
);
// Reset the source location to the one of the node (instead of the CODEGEN source location)
updateSourceLocation();
}
void CompilerContext::optimizeYul(yul::Object& _object, yul::EVMDialect const& _dialect, OptimiserSettings const& _optimiserSettings, std::set<yul::YulString> const& _externalIdentifiers)
{
#ifdef SOL_OUTPUT_ASM
cout << yul::AsmPrinter(*dialect)(*_object.code) << endl;
#endif
bool const isCreation = runtimeContext() != nullptr;
yul::GasMeter meter(_dialect, isCreation, _optimiserSettings.expectedExecutionsPerDeployment);
yul::OptimiserSuite::run(
_dialect,
&meter,
_object,
_optimiserSettings.optimizeStackAllocation,
_optimiserSettings.yulOptimiserSteps,
_externalIdentifiers
);
#ifdef SOL_OUTPUT_ASM
cout << "After optimizer:" << endl;
cout << yul::AsmPrinter(*dialect)(*object.code) << endl;
#endif
}
string CompilerContext::revertReasonIfDebug(string const& _message)
{
return YulUtilFunctions::revertReasonIfDebug(m_revertStrings, _message);
}
void CompilerContext::updateSourceLocation()
{
m_asm->setSourceLocation(m_visitedNodes.empty() ? SourceLocation() : m_visitedNodes.top()->location());
}
evmasm::Assembly::OptimiserSettings CompilerContext::translateOptimiserSettings(OptimiserSettings const& _settings)
{
// Constructing it this way so that we notice changes in the fields.
evmasm::Assembly::OptimiserSettings asmSettings{false, false, false, false, false, false, false, m_evmVersion, 0};
asmSettings.isCreation = true;
asmSettings.runInliner = _settings.runInliner;
asmSettings.runJumpdestRemover = _settings.runJumpdestRemover;
asmSettings.runPeephole = _settings.runPeephole;
asmSettings.runDeduplicate = _settings.runDeduplicate;
asmSettings.runCSE = _settings.runCSE;
asmSettings.runConstantOptimiser = _settings.runConstantOptimiser;
asmSettings.expectedExecutionsPerDeployment = _settings.expectedExecutionsPerDeployment;
asmSettings.evmVersion = m_evmVersion;
return asmSettings;
}
evmasm::AssemblyItem CompilerContext::FunctionCompilationQueue::entryLabel(
Declaration const& _declaration,
CompilerContext& _context
)
{
auto res = m_entryLabels.find(&_declaration);
if (res == m_entryLabels.end())
{
evmasm::AssemblyItem tag(_context.newTag());
m_entryLabels.insert(make_pair(&_declaration, tag));
m_functionsToCompile.push(&_declaration);
return tag.tag();
}
else
return res->second.tag();
}
evmasm::AssemblyItem CompilerContext::FunctionCompilationQueue::entryLabelIfExists(Declaration const& _declaration) const
{
auto res = m_entryLabels.find(&_declaration);
return res == m_entryLabels.end() ? evmasm::AssemblyItem(evmasm::UndefinedItem) : res->second.tag();
}
Declaration const* CompilerContext::FunctionCompilationQueue::nextFunctionToCompile() const
{
while (!m_functionsToCompile.empty())
{
if (m_alreadyCompiledFunctions.count(m_functionsToCompile.front()))
m_functionsToCompile.pop();
else
return m_functionsToCompile.front();
}
return nullptr;
}
void CompilerContext::FunctionCompilationQueue::startFunction(Declaration const& _function)
{
if (!m_functionsToCompile.empty() && m_functionsToCompile.front() == &_function)
m_functionsToCompile.pop();
m_alreadyCompiledFunctions.insert(&_function);
}