mirror of
https://github.com/ethereum/solidity
synced 2023-10-03 13:03:40 +00:00
541 lines
20 KiB
C++
541 lines
20 KiB
C++
/*
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This file is part of solidity.
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solidity is free software: you can redistribute it and/or modify
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it under the terms of the GNU General Public License as published by
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the Free Software Foundation, either version 3 of the License, or
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(at your option) any later version.
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solidity is distributed in the hope that it will be useful,
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but WITHOUT ANY WARRANTY; without even the implied warranty of
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MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
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GNU General Public License for more details.
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You should have received a copy of the GNU General Public License
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along with solidity. If not, see <http://www.gnu.org/licenses/>.
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*/
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// SPDX-License-Identifier: GPL-3.0
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#include <libyul/backends/evm/OptimizedEVMCodeTransform.h>
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#include <libyul/backends/evm/ControlFlowGraphBuilder.h>
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#include <libyul/backends/evm/StackHelpers.h>
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#include <libyul/backends/evm/StackLayoutGenerator.h>
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#include <libyul/Utilities.h>
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#include <libevmasm/Instruction.h>
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#include <libsolutil/Visitor.h>
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#include <libsolutil/cxx20.h>
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#include <range/v3/view/drop.hpp>
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#include <range/v3/view/enumerate.hpp>
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#include <range/v3/view/filter.hpp>
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#include <range/v3/view/iota.hpp>
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#include <range/v3/view/map.hpp>
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#include <range/v3/view/reverse.hpp>
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#include <range/v3/view/take_last.hpp>
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using namespace solidity;
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using namespace solidity::yul;
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using namespace std;
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vector<StackTooDeepError> OptimizedEVMCodeTransform::run(
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AbstractAssembly& _assembly,
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AsmAnalysisInfo& _analysisInfo,
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Block const& _block,
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EVMDialect const& _dialect,
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BuiltinContext& _builtinContext,
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UseNamedLabels _useNamedLabelsForFunctions
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)
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{
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std::unique_ptr<CFG> dfg = ControlFlowGraphBuilder::build(_analysisInfo, _dialect, _block);
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StackLayout stackLayout = StackLayoutGenerator::run(*dfg);
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OptimizedEVMCodeTransform optimizedCodeTransform(
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_assembly,
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_builtinContext,
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_useNamedLabelsForFunctions,
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*dfg,
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stackLayout
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);
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// Create initial entry layout.
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optimizedCodeTransform.createStackLayout(debugDataOf(*dfg->entry), stackLayout.blockInfos.at(dfg->entry).entryLayout);
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optimizedCodeTransform(*dfg->entry);
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for (Scope::Function const* function: dfg->functions)
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optimizedCodeTransform(dfg->functionInfo.at(function));
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return std::move(optimizedCodeTransform.m_stackErrors);
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}
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void OptimizedEVMCodeTransform::operator()(CFG::FunctionCall const& _call)
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{
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// Validate stack.
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{
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yulAssert(m_assembly.stackHeight() == static_cast<int>(m_stack.size()), "");
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yulAssert(m_stack.size() >= _call.function.get().arguments.size() + (_call.canContinue ? 1 : 0), "");
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// Assert that we got the correct arguments on stack for the call.
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for (auto&& [arg, slot]: ranges::zip_view(
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_call.functionCall.get().arguments | ranges::views::reverse,
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m_stack | ranges::views::take_last(_call.functionCall.get().arguments.size())
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))
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validateSlot(slot, arg);
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// Assert that we got the correct return label on stack.
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if (_call.canContinue)
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{
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auto const* returnLabelSlot = get_if<FunctionCallReturnLabelSlot>(
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&m_stack.at(m_stack.size() - _call.functionCall.get().arguments.size() - 1)
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);
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yulAssert(returnLabelSlot && &returnLabelSlot->call.get() == &_call.functionCall.get(), "");
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}
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}
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// Emit code.
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{
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m_assembly.setSourceLocation(originLocationOf(_call));
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m_assembly.appendJumpTo(
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getFunctionLabel(_call.function),
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static_cast<int>(_call.function.get().returns.size() - _call.function.get().arguments.size()) - (_call.canContinue ? 1 : 0),
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AbstractAssembly::JumpType::IntoFunction
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);
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if (_call.canContinue)
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m_assembly.appendLabel(m_returnLabels.at(&_call.functionCall.get()));
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}
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// Update stack.
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{
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// Remove arguments and return label from m_stack.
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for (size_t i = 0; i < _call.function.get().arguments.size() + (_call.canContinue ? 1 : 0); ++i)
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m_stack.pop_back();
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// Push return values to m_stack.
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for (size_t index: ranges::views::iota(0u, _call.function.get().returns.size()))
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m_stack.emplace_back(TemporarySlot{_call.functionCall, index});
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yulAssert(m_assembly.stackHeight() == static_cast<int>(m_stack.size()), "");
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}
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}
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void OptimizedEVMCodeTransform::operator()(CFG::BuiltinCall const& _call)
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{
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// Validate stack.
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{
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yulAssert(m_assembly.stackHeight() == static_cast<int>(m_stack.size()), "");
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yulAssert(m_stack.size() >= _call.arguments, "");
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// Assert that we got a correct stack for the call.
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for (auto&& [arg, slot]: ranges::zip_view(
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_call.functionCall.get().arguments |
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ranges::views::enumerate |
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ranges::views::filter(util::mapTuple([&](size_t idx, auto&) -> bool {
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return !_call.builtin.get().literalArgument(idx);
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})) |
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ranges::views::reverse |
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ranges::views::values,
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m_stack | ranges::views::take_last(_call.arguments)
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))
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validateSlot(slot, arg);
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}
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// Emit code.
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{
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m_assembly.setSourceLocation(originLocationOf(_call));
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static_cast<BuiltinFunctionForEVM const&>(_call.builtin.get()).generateCode(
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_call.functionCall,
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m_assembly,
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m_builtinContext
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);
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}
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// Update stack.
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{
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// Remove arguments from m_stack.
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for (size_t i = 0; i < _call.arguments; ++i)
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m_stack.pop_back();
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// Push return values to m_stack.
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for (size_t index: ranges::views::iota(0u, _call.builtin.get().returns.size()))
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m_stack.emplace_back(TemporarySlot{_call.functionCall, index});
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yulAssert(m_assembly.stackHeight() == static_cast<int>(m_stack.size()), "");
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}
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}
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void OptimizedEVMCodeTransform::operator()(CFG::Assignment const& _assignment)
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{
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yulAssert(m_assembly.stackHeight() == static_cast<int>(m_stack.size()), "");
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// Invalidate occurrences of the assigned variables.
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for (auto& currentSlot: m_stack)
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if (VariableSlot const* varSlot = get_if<VariableSlot>(¤tSlot))
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if (util::contains(_assignment.variables, *varSlot))
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currentSlot = JunkSlot{};
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// Assign variables to current stack top.
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yulAssert(m_stack.size() >= _assignment.variables.size(), "");
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for (auto&& [currentSlot, varSlot]: ranges::zip_view(
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m_stack | ranges::views::take_last(_assignment.variables.size()),
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_assignment.variables
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))
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currentSlot = varSlot;
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}
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OptimizedEVMCodeTransform::OptimizedEVMCodeTransform(
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AbstractAssembly& _assembly,
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BuiltinContext& _builtinContext,
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UseNamedLabels _useNamedLabelsForFunctions,
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CFG const& _dfg,
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StackLayout const& _stackLayout
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):
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m_assembly(_assembly),
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m_builtinContext(_builtinContext),
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m_dfg(_dfg),
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m_stackLayout(_stackLayout),
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m_functionLabels([&](){
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map<CFG::FunctionInfo const*, AbstractAssembly::LabelID> functionLabels;
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set<YulString> assignedFunctionNames;
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for (Scope::Function const* function: m_dfg.functions)
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{
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CFG::FunctionInfo const& functionInfo = m_dfg.functionInfo.at(function);
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bool nameAlreadySeen = !assignedFunctionNames.insert(function->name).second;
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if (_useNamedLabelsForFunctions == UseNamedLabels::YesAndForceUnique)
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yulAssert(!nameAlreadySeen);
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bool useNamedLabel = _useNamedLabelsForFunctions != UseNamedLabels::Never && !nameAlreadySeen;
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functionLabels[&functionInfo] = useNamedLabel ?
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m_assembly.namedLabel(
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function->name.str(),
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function->arguments.size(),
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function->returns.size(),
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functionInfo.debugData ? functionInfo.debugData->astID : nullopt
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) :
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m_assembly.newLabelId();
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}
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return functionLabels;
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}())
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{
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}
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void OptimizedEVMCodeTransform::assertLayoutCompatibility(Stack const& _currentStack, Stack const& _desiredStack)
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{
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yulAssert(_currentStack.size() == _desiredStack.size(), "");
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for (auto&& [currentSlot, desiredSlot]: ranges::zip_view(_currentStack, _desiredStack))
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yulAssert(holds_alternative<JunkSlot>(desiredSlot) || currentSlot == desiredSlot, "");
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}
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AbstractAssembly::LabelID OptimizedEVMCodeTransform::getFunctionLabel(Scope::Function const& _function)
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{
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return m_functionLabels.at(&m_dfg.functionInfo.at(&_function));
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}
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void OptimizedEVMCodeTransform::validateSlot(StackSlot const& _slot, Expression const& _expression)
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{
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std::visit(util::GenericVisitor{
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[&](yul::Literal const& _literal) {
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auto* literalSlot = get_if<LiteralSlot>(&_slot);
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yulAssert(literalSlot && valueOfLiteral(_literal) == literalSlot->value, "");
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},
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[&](yul::Identifier const& _identifier) {
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auto* variableSlot = get_if<VariableSlot>(&_slot);
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yulAssert(variableSlot && variableSlot->variable.get().name == _identifier.name, "");
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},
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[&](yul::FunctionCall const& _call) {
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auto* temporarySlot = get_if<TemporarySlot>(&_slot);
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yulAssert(temporarySlot && &temporarySlot->call.get() == &_call && temporarySlot->index == 0, "");
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}
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}, _expression);
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}
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void OptimizedEVMCodeTransform::createStackLayout(std::shared_ptr<DebugData const> _debugData, Stack _targetStack)
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{
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static constexpr auto slotVariableName = [](StackSlot const& _slot) {
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return std::visit(util::GenericVisitor{
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[](VariableSlot const& _var) { return _var.variable.get().name; },
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[](auto const&) { return YulString{}; }
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}, _slot);
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};
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yulAssert(m_assembly.stackHeight() == static_cast<int>(m_stack.size()), "");
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// ::createStackLayout asserts that it has successfully achieved the target layout.
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langutil::SourceLocation sourceLocation = _debugData ? _debugData->originLocation : langutil::SourceLocation{};
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m_assembly.setSourceLocation(sourceLocation);
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::createStackLayout(
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m_stack,
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_targetStack | ranges::to<Stack>,
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// Swap callback.
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[&](unsigned _i)
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{
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yulAssert(static_cast<int>(m_stack.size()) == m_assembly.stackHeight(), "");
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yulAssert(_i > 0 && _i < m_stack.size(), "");
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if (_i <= 16)
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m_assembly.appendInstruction(evmasm::swapInstruction(_i));
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else
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{
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int deficit = static_cast<int>(_i) - 16;
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StackSlot const& deepSlot = m_stack.at(m_stack.size() - _i - 1);
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YulString varNameDeep = slotVariableName(deepSlot);
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YulString varNameTop = slotVariableName(m_stack.back());
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string msg =
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"Cannot swap " + (varNameDeep.empty() ? "Slot " + stackSlotToString(deepSlot) : "Variable " + varNameDeep.str()) +
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" with " + (varNameTop.empty() ? "Slot " + stackSlotToString(m_stack.back()) : "Variable " + varNameTop.str()) +
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": too deep in the stack by " + to_string(deficit) + " slots in " + stackToString(m_stack);
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m_stackErrors.emplace_back(StackTooDeepError(
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m_currentFunctionInfo ? m_currentFunctionInfo->function.name : YulString{},
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varNameDeep.empty() ? varNameTop : varNameDeep,
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deficit,
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msg
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));
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m_assembly.markAsInvalid();
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}
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},
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// Push or dup callback.
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[&](StackSlot const& _slot)
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{
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yulAssert(static_cast<int>(m_stack.size()) == m_assembly.stackHeight(), "");
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// Dup the slot, if already on stack and reachable.
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if (auto depth = util::findOffset(m_stack | ranges::views::reverse, _slot))
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{
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if (*depth < 16)
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{
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m_assembly.appendInstruction(evmasm::dupInstruction(static_cast<unsigned>(*depth + 1)));
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return;
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}
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else if (!canBeFreelyGenerated(_slot))
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{
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int deficit = static_cast<int>(*depth - 15);
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YulString varName = slotVariableName(_slot);
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string msg =
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(varName.empty() ? "Slot " + stackSlotToString(_slot) : "Variable " + varName.str())
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+ " is " + to_string(*depth - 15) + " too deep in the stack " + stackToString(m_stack);
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m_stackErrors.emplace_back(StackTooDeepError(
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m_currentFunctionInfo ? m_currentFunctionInfo->function.name : YulString{},
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varName,
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deficit,
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msg
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));
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m_assembly.markAsInvalid();
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m_assembly.appendConstant(u256(0xCAFFEE));
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return;
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}
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// else: the slot is too deep in stack, but can be freely generated, we fall through to push it again.
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}
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// The slot can be freely generated or is an unassigned return variable. Push it.
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std::visit(util::GenericVisitor{
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[&](LiteralSlot const& _literal)
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{
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m_assembly.setSourceLocation(originLocationOf(_literal));
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m_assembly.appendConstant(_literal.value);
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m_assembly.setSourceLocation(sourceLocation);
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},
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[&](FunctionReturnLabelSlot const&)
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{
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yulAssert(false, "Cannot produce function return label.");
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},
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[&](FunctionCallReturnLabelSlot const& _returnLabel)
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{
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if (!m_returnLabels.count(&_returnLabel.call.get()))
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m_returnLabels[&_returnLabel.call.get()] = m_assembly.newLabelId();
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m_assembly.setSourceLocation(originLocationOf(_returnLabel.call.get()));
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m_assembly.appendLabelReference(m_returnLabels.at(&_returnLabel.call.get()));
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m_assembly.setSourceLocation(sourceLocation);
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},
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[&](VariableSlot const& _variable)
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{
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if (m_currentFunctionInfo && util::contains(m_currentFunctionInfo->returnVariables, _variable))
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{
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m_assembly.setSourceLocation(originLocationOf(_variable));
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m_assembly.appendConstant(0);
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m_assembly.setSourceLocation(sourceLocation);
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return;
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}
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yulAssert(false, "Variable not found on stack.");
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},
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[&](TemporarySlot const&)
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{
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yulAssert(false, "Function call result requested, but not found on stack.");
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},
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[&](JunkSlot const&)
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{
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// Note: this will always be popped, so we can push anything.
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m_assembly.appendInstruction(evmasm::Instruction::CODESIZE);
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}
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}, _slot);
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},
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// Pop callback.
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[&]()
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{
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m_assembly.appendInstruction(evmasm::Instruction::POP);
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}
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);
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yulAssert(m_assembly.stackHeight() == static_cast<int>(m_stack.size()), "");
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}
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void OptimizedEVMCodeTransform::operator()(CFG::BasicBlock const& _block)
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{
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// Assert that this is the first visit of the block and mark as generated.
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yulAssert(m_generated.insert(&_block).second, "");
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m_assembly.setSourceLocation(originLocationOf(_block));
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auto const& blockInfo = m_stackLayout.blockInfos.at(&_block);
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// Assert that the stack is valid for entering the block.
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assertLayoutCompatibility(m_stack, blockInfo.entryLayout);
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m_stack = blockInfo.entryLayout; // Might set some slots to junk, if not required by the block.
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yulAssert(static_cast<int>(m_stack.size()) == m_assembly.stackHeight(), "");
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// Emit jump label, if required.
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if (auto label = util::valueOrNullptr(m_blockLabels, &_block))
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m_assembly.appendLabel(*label);
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for (auto const& operation: _block.operations)
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{
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// Create required layout for entering the operation.
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createStackLayout(debugDataOf(operation.operation), m_stackLayout.operationEntryLayout.at(&operation));
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// Assert that we have the inputs of the operation on stack top.
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yulAssert(static_cast<int>(m_stack.size()) == m_assembly.stackHeight(), "");
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yulAssert(m_stack.size() >= operation.input.size(), "");
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size_t baseHeight = m_stack.size() - operation.input.size();
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assertLayoutCompatibility(
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m_stack | ranges::views::take_last(operation.input.size()) | ranges::to<Stack>,
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operation.input
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);
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// Perform the operation.
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std::visit(*this, operation.operation);
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// Assert that the operation produced its proclaimed output.
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yulAssert(static_cast<int>(m_stack.size()) == m_assembly.stackHeight(), "");
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yulAssert(m_stack.size() == baseHeight + operation.output.size(), "");
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yulAssert(m_stack.size() >= operation.output.size(), "");
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assertLayoutCompatibility(
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m_stack | ranges::views::take_last(operation.output.size()) | ranges::to<Stack>,
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operation.output
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);
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}
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// Exit the block.
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m_assembly.setSourceLocation(originLocationOf(_block));
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std::visit(util::GenericVisitor{
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[&](CFG::BasicBlock::MainExit const&)
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{
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m_assembly.appendInstruction(evmasm::Instruction::STOP);
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},
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[&](CFG::BasicBlock::Jump const& _jump)
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{
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// Create the stack expected at the jump target.
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createStackLayout(debugDataOf(_jump), m_stackLayout.blockInfos.at(_jump.target).entryLayout);
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// If this is the only jump to the block, we do not need a label and can directly continue with the target block.
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if (!m_blockLabels.count(_jump.target) && _jump.target->entries.size() == 1)
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{
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yulAssert(!_jump.backwards, "");
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(*this)(*_jump.target);
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}
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else
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{
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// Generate a jump label for the target, if not already present.
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if (!m_blockLabels.count(_jump.target))
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m_blockLabels[_jump.target] = m_assembly.newLabelId();
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// If we already have generated the target block, jump to it, otherwise generate it in place.
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if (m_generated.count(_jump.target))
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m_assembly.appendJumpTo(m_blockLabels[_jump.target]);
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else
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(*this)(*_jump.target);
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}
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},
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[&](CFG::BasicBlock::ConditionalJump const& _conditionalJump)
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{
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// Create the shared entry layout of the jump targets, which is stored as exit layout of the current block.
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createStackLayout(debugDataOf(_conditionalJump), blockInfo.exitLayout);
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// Create labels for the targets, if not already present.
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if (!m_blockLabels.count(_conditionalJump.nonZero))
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m_blockLabels[_conditionalJump.nonZero] = m_assembly.newLabelId();
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if (!m_blockLabels.count(_conditionalJump.zero))
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m_blockLabels[_conditionalJump.zero] = m_assembly.newLabelId();
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// Assert that we have the correct condition on stack.
|
|
yulAssert(!m_stack.empty(), "");
|
|
yulAssert(m_stack.back() == _conditionalJump.condition, "");
|
|
|
|
// Emit the conditional jump to the non-zero label and update the stored stack.
|
|
m_assembly.appendJumpToIf(m_blockLabels[_conditionalJump.nonZero]);
|
|
m_stack.pop_back();
|
|
|
|
// Assert that we have a valid stack for both jump targets.
|
|
assertLayoutCompatibility(m_stack, m_stackLayout.blockInfos.at(_conditionalJump.nonZero).entryLayout);
|
|
assertLayoutCompatibility(m_stack, m_stackLayout.blockInfos.at(_conditionalJump.zero).entryLayout);
|
|
|
|
{
|
|
// Restore the stack afterwards for the non-zero case below.
|
|
ScopeGuard stackRestore([storedStack = m_stack, this]() {
|
|
m_stack = std::move(storedStack);
|
|
m_assembly.setStackHeight(static_cast<int>(m_stack.size()));
|
|
});
|
|
|
|
// If we have already generated the zero case, jump to it, otherwise generate it in place.
|
|
if (m_generated.count(_conditionalJump.zero))
|
|
m_assembly.appendJumpTo(m_blockLabels[_conditionalJump.zero]);
|
|
else
|
|
(*this)(*_conditionalJump.zero);
|
|
}
|
|
// Note that each block visit terminates control flow, so we cannot fall through from the zero case.
|
|
|
|
// Generate the non-zero block, if not done already.
|
|
if (!m_generated.count(_conditionalJump.nonZero))
|
|
(*this)(*_conditionalJump.nonZero);
|
|
},
|
|
[&](CFG::BasicBlock::FunctionReturn const& _functionReturn)
|
|
{
|
|
yulAssert(m_currentFunctionInfo);
|
|
yulAssert(m_currentFunctionInfo == _functionReturn.info);
|
|
yulAssert(m_currentFunctionInfo->canContinue);
|
|
|
|
// Construct the function return layout, which is fully determined by the function signature.
|
|
Stack exitStack = m_currentFunctionInfo->returnVariables | ranges::views::transform([](auto const& _varSlot){
|
|
return StackSlot{_varSlot};
|
|
}) | ranges::to<Stack>;
|
|
exitStack.emplace_back(FunctionReturnLabelSlot{_functionReturn.info->function});
|
|
|
|
// Create the function return layout and jump.
|
|
createStackLayout(debugDataOf(_functionReturn), exitStack);
|
|
m_assembly.appendJump(0, AbstractAssembly::JumpType::OutOfFunction);
|
|
},
|
|
[&](CFG::BasicBlock::Terminated const&)
|
|
{
|
|
yulAssert(!_block.operations.empty());
|
|
if (CFG::BuiltinCall const* builtinCall = get_if<CFG::BuiltinCall>(&_block.operations.back().operation))
|
|
yulAssert(builtinCall->builtin.get().controlFlowSideEffects.terminatesOrReverts(), "");
|
|
else if (CFG::FunctionCall const* functionCall = get_if<CFG::FunctionCall>(&_block.operations.back().operation))
|
|
yulAssert(!functionCall->canContinue);
|
|
else
|
|
yulAssert(false);
|
|
}
|
|
}, _block.exit);
|
|
// TODO: We could assert that the last emitted assembly item terminated or was an (unconditional) jump.
|
|
// But currently AbstractAssembly does not allow peeking at the last emitted assembly item.
|
|
m_stack.clear();
|
|
m_assembly.setStackHeight(0);
|
|
}
|
|
|
|
void OptimizedEVMCodeTransform::operator()(CFG::FunctionInfo const& _functionInfo)
|
|
{
|
|
yulAssert(!m_currentFunctionInfo, "");
|
|
ScopedSaveAndRestore currentFunctionInfoRestore(m_currentFunctionInfo, &_functionInfo);
|
|
|
|
yulAssert(m_stack.empty() && m_assembly.stackHeight() == 0, "");
|
|
|
|
// Create function entry layout in m_stack.
|
|
if (_functionInfo.canContinue)
|
|
m_stack.emplace_back(FunctionReturnLabelSlot{_functionInfo.function});
|
|
for (auto const& param: _functionInfo.parameters | ranges::views::reverse)
|
|
m_stack.emplace_back(param);
|
|
m_assembly.setStackHeight(static_cast<int>(m_stack.size()));
|
|
|
|
m_assembly.setSourceLocation(originLocationOf(_functionInfo));
|
|
m_assembly.appendLabel(getFunctionLabel(_functionInfo.function));
|
|
|
|
// Create the entry layout of the function body block and visit.
|
|
createStackLayout(debugDataOf(_functionInfo), m_stackLayout.blockInfos.at(_functionInfo.entry).entryLayout);
|
|
(*this)(*_functionInfo.entry);
|
|
|
|
m_stack.clear();
|
|
m_assembly.setStackHeight(0);
|
|
}
|