mirror of
https://github.com/ethereum/solidity
synced 2023-10-03 13:03:40 +00:00
1ebdab43d8
Signed-off-by: Jun Zhang <jun@junz.org>
848 lines
32 KiB
C++
848 lines
32 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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/**
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* Stack layout generator for Yul to EVM code generation.
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*/
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#include <libyul/backends/evm/StackLayoutGenerator.h>
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#include <libyul/backends/evm/StackHelpers.h>
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#include <libevmasm/GasMeter.h>
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#include <libsolutil/Algorithms.h>
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#include <libsolutil/cxx20.h>
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#include <libsolutil/Visitor.h>
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#include <range/v3/algorithm/any_of.hpp>
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#include <range/v3/algorithm/find.hpp>
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#include <range/v3/range/conversion.hpp>
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#include <range/v3/view/all.hpp>
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#include <range/v3/view/concat.hpp>
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#include <range/v3/view/drop.hpp>
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#include <range/v3/view/drop_last.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.hpp>
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#include <range/v3/view/take_last.hpp>
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#include <range/v3/view/transform.hpp>
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using namespace solidity;
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using namespace solidity::yul;
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StackLayout StackLayoutGenerator::run(CFG const& _cfg)
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{
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StackLayout stackLayout;
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StackLayoutGenerator{stackLayout, nullptr}.processEntryPoint(*_cfg.entry);
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for (auto& functionInfo: _cfg.functionInfo | ranges::views::values)
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StackLayoutGenerator{stackLayout, &functionInfo}.processEntryPoint(*functionInfo.entry, &functionInfo);
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return stackLayout;
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}
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std::map<YulString, std::vector<StackLayoutGenerator::StackTooDeep>> StackLayoutGenerator::reportStackTooDeep(CFG const& _cfg)
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{
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std::map<YulString, std::vector<StackLayoutGenerator::StackTooDeep>> stackTooDeepErrors;
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stackTooDeepErrors[YulString{}] = reportStackTooDeep(_cfg, YulString{});
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for (auto const& function: _cfg.functions)
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if (auto errors = reportStackTooDeep(_cfg, function->name); !errors.empty())
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stackTooDeepErrors[function->name] = std::move(errors);
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return stackTooDeepErrors;
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}
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std::vector<StackLayoutGenerator::StackTooDeep> StackLayoutGenerator::reportStackTooDeep(CFG const& _cfg, YulString _functionName)
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{
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StackLayout stackLayout;
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CFG::FunctionInfo const* functionInfo = nullptr;
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if (!_functionName.empty())
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{
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functionInfo = &ranges::find(
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_cfg.functionInfo,
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_functionName,
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util::mapTuple([](auto&&, auto&& info) { return info.function.name; })
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)->second;
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yulAssert(functionInfo, "Function not found.");
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}
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StackLayoutGenerator generator{stackLayout, functionInfo};
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CFG::BasicBlock const* entry = functionInfo ? functionInfo->entry : _cfg.entry;
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generator.processEntryPoint(*entry);
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return generator.reportStackTooDeep(*entry);
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}
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StackLayoutGenerator::StackLayoutGenerator(StackLayout& _layout, CFG::FunctionInfo const* _functionInfo):
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m_layout(_layout),
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m_currentFunctionInfo(_functionInfo)
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{
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}
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namespace
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{
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/// @returns all stack too deep errors that would occur when shuffling @a _source to @a _target.
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std::vector<StackLayoutGenerator::StackTooDeep> findStackTooDeep(Stack const& _source, Stack const& _target)
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{
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Stack currentStack = _source;
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std::vector<StackLayoutGenerator::StackTooDeep> stackTooDeepErrors;
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auto getVariableChoices = [](auto&& _range) {
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std::vector<YulString> result;
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for (auto const& slot: _range)
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if (auto const* variableSlot = std::get_if<VariableSlot>(&slot))
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if (!util::contains(result, variableSlot->variable.get().name))
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result.push_back(variableSlot->variable.get().name);
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return result;
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};
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::createStackLayout(
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currentStack,
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_target,
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[&](unsigned _i)
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{
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if (_i > 16)
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stackTooDeepErrors.emplace_back(StackLayoutGenerator::StackTooDeep{
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_i - 16,
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getVariableChoices(currentStack | ranges::views::take_last(_i + 1))
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});
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},
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[&](StackSlot const& _slot)
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{
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if (canBeFreelyGenerated(_slot))
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return;
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if (
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auto depth = util::findOffset(currentStack | ranges::views::reverse, _slot);
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depth && *depth >= 16
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)
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stackTooDeepErrors.emplace_back(StackLayoutGenerator::StackTooDeep{
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*depth - 15,
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getVariableChoices(currentStack | ranges::views::take_last(*depth + 1))
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});
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},
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[&]() {}
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);
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return stackTooDeepErrors;
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}
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/// @returns the ideal stack to have before executing an operation that outputs @a _operationOutput, s.t.
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/// shuffling to @a _post is cheap (excluding the input of the operation itself).
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/// If @a _generateSlotOnTheFly returns true for a slot, this slot should not occur in the ideal stack, but
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/// rather be generated on the fly during shuffling.
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template<typename Callable>
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Stack createIdealLayout(Stack const& _operationOutput, Stack const& _post, Callable _generateSlotOnTheFly)
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{
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struct PreviousSlot { size_t slot; };
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// Determine the number of slots that have to be on stack before executing the operation (excluding
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// the inputs of the operation itself).
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// That is slots that should not be generated on the fly and are not outputs of the operation.
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size_t preOperationLayoutSize = _post.size();
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for (auto const& slot: _post)
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if (util::contains(_operationOutput, slot) || _generateSlotOnTheFly(slot))
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--preOperationLayoutSize;
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// The symbolic layout directly after the operation has the form
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// PreviousSlot{0}, ..., PreviousSlot{n}, [output<0>], ..., [output<m>]
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auto layout = ranges::views::iota(0u, preOperationLayoutSize) |
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ranges::views::transform([](size_t _index) { return PreviousSlot{_index}; }) |
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ranges::to<std::vector<std::variant<PreviousSlot, StackSlot>>>;
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layout += _operationOutput;
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// Shortcut for trivial case.
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if (layout.empty())
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return Stack{};
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// Next we will shuffle the layout to the post stack using ShuffleOperations
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// that are aware of PreviousSlot's.
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struct ShuffleOperations
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{
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std::vector<std::variant<PreviousSlot, StackSlot>>& layout;
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Stack const& post;
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std::set<StackSlot> outputs;
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Multiplicity multiplicity;
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Callable generateSlotOnTheFly;
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ShuffleOperations(
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std::vector<std::variant<PreviousSlot, StackSlot>>& _layout,
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Stack const& _post,
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Callable _generateSlotOnTheFly
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): layout(_layout), post(_post), generateSlotOnTheFly(_generateSlotOnTheFly)
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{
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for (auto const& layoutSlot: layout)
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if (StackSlot const* slot = std::get_if<StackSlot>(&layoutSlot))
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outputs.insert(*slot);
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for (auto const& layoutSlot: layout)
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if (StackSlot const* slot = std::get_if<StackSlot>(&layoutSlot))
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--multiplicity[*slot];
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for (auto&& slot: post)
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if (outputs.count(slot) || generateSlotOnTheFly(slot))
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++multiplicity[slot];
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}
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bool isCompatible(size_t _source, size_t _target)
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{
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return
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_source < layout.size() &&
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_target < post.size() &&
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(
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std::holds_alternative<JunkSlot>(post.at(_target)) ||
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std::visit(util::GenericVisitor{
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[&](PreviousSlot const&) {
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return !outputs.count(post.at(_target)) && !generateSlotOnTheFly(post.at(_target));
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},
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[&](StackSlot const& _s) { return _s == post.at(_target); }
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}, layout.at(_source))
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);
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}
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bool sourceIsSame(size_t _lhs, size_t _rhs)
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{
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return std::visit(util::GenericVisitor{
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[&](PreviousSlot const&, PreviousSlot const&) { return true; },
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[&](StackSlot const& _lhs, StackSlot const& _rhs) { return _lhs == _rhs; },
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[&](auto const&, auto const&) { return false; }
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}, layout.at(_lhs), layout.at(_rhs));
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}
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int sourceMultiplicity(size_t _offset)
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{
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return std::visit(util::GenericVisitor{
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[&](PreviousSlot const&) { return 0; },
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[&](StackSlot const& _s) { return multiplicity.at(_s); }
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}, layout.at(_offset));
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}
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int targetMultiplicity(size_t _offset)
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{
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if (!outputs.count(post.at(_offset)) && !generateSlotOnTheFly(post.at(_offset)))
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return 0;
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return multiplicity.at(post.at(_offset));
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}
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bool targetIsArbitrary(size_t _offset)
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{
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return _offset < post.size() && std::holds_alternative<JunkSlot>(post.at(_offset));
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}
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void swap(size_t _i)
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{
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yulAssert(!std::holds_alternative<PreviousSlot>(layout.at(layout.size() - _i - 1)) || !std::holds_alternative<PreviousSlot>(layout.back()), "");
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std::swap(layout.at(layout.size() - _i - 1), layout.back());
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}
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size_t sourceSize() { return layout.size(); }
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size_t targetSize() { return post.size(); }
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void pop() { layout.pop_back(); }
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void pushOrDupTarget(size_t _offset) { layout.push_back(post.at(_offset)); }
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};
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Shuffler<ShuffleOperations>::shuffle(layout, _post, _generateSlotOnTheFly);
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// Now we can construct the ideal layout before the operation.
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// "layout" has shuffled the PreviousSlot{x} to new places using minimal operations to move the operation
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// output in place. The resulting permutation of the PreviousSlot yields the ideal positions of slots
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// before the operation, i.e. if PreviousSlot{2} is at a position at which _post contains VariableSlot{"tmp"},
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// then we want the variable tmp in the slot at offset 2 in the layout before the operation.
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std::vector<std::optional<StackSlot>> idealLayout(_post.size(), std::nullopt);
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for (auto&& [slot, idealPosition]: ranges::zip_view(_post, layout))
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if (PreviousSlot* previousSlot = std::get_if<PreviousSlot>(&idealPosition))
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idealLayout.at(previousSlot->slot) = slot;
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// The tail of layout must have contained the operation outputs and will not have been assigned slots in the last loop.
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while (!idealLayout.empty() && !idealLayout.back())
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idealLayout.pop_back();
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yulAssert(idealLayout.size() == preOperationLayoutSize, "");
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return idealLayout | ranges::views::transform([](std::optional<StackSlot> s) {
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yulAssert(s, "");
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return *s;
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}) | ranges::to<Stack>;
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}
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}
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Stack StackLayoutGenerator::propagateStackThroughOperation(Stack _exitStack, CFG::Operation const& _operation, bool _aggressiveStackCompression)
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{
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// Enable aggressive stack compression for recursive calls.
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if (auto const* functionCall = std::get_if<CFG::FunctionCall>(&_operation.operation))
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if (functionCall->recursive)
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_aggressiveStackCompression = true;
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// This is a huge tradeoff between code size, gas cost and stack size.
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auto generateSlotOnTheFly = [&](StackSlot const& _slot) {
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return _aggressiveStackCompression && canBeFreelyGenerated(_slot);
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};
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// Determine the ideal permutation of the slots in _exitLayout that are not operation outputs (and not to be
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// generated on the fly), s.t. shuffling the `stack + _operation.output` to _exitLayout is cheap.
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Stack stack = createIdealLayout(_operation.output, _exitStack, generateSlotOnTheFly);
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// Make sure the resulting previous slots do not overlap with any assignmed variables.
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if (auto const* assignment = std::get_if<CFG::Assignment>(&_operation.operation))
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for (auto& stackSlot: stack)
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if (auto const* varSlot = std::get_if<VariableSlot>(&stackSlot))
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yulAssert(!util::contains(assignment->variables, *varSlot), "");
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// Since stack+_operation.output can be easily shuffled to _exitLayout, the desired layout before the operation
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// is stack+_operation.input;
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stack += _operation.input;
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// Store the exact desired operation entry layout. The stored layout will be recreated by the code transform
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// before executing the operation. However, this recreation can produce slots that can be freely generated or
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// are duplicated, i.e. we can compress the stack afterwards without causing problems for code generation later.
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m_layout.operationEntryLayout[&_operation] = stack;
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// Remove anything from the stack top that can be freely generated or dupped from deeper on the stack.
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while (!stack.empty())
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{
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if (canBeFreelyGenerated(stack.back()))
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stack.pop_back();
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else if (auto offset = util::findOffset(stack | ranges::views::reverse | ranges::views::drop(1), stack.back()))
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{
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if (*offset + 2 < 16)
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stack.pop_back();
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else
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break;
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}
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else
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break;
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}
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return stack;
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}
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Stack StackLayoutGenerator::propagateStackThroughBlock(Stack _exitStack, CFG::BasicBlock const& _block, bool _aggressiveStackCompression)
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{
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Stack stack = _exitStack;
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for (auto&& [idx, operation]: _block.operations | ranges::views::enumerate | ranges::views::reverse)
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{
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Stack newStack = propagateStackThroughOperation(stack, operation, _aggressiveStackCompression);
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if (!_aggressiveStackCompression && !findStackTooDeep(newStack, stack).empty())
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// If we had stack errors, run again with aggressive stack compression.
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return propagateStackThroughBlock(std::move(_exitStack), _block, true);
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stack = std::move(newStack);
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}
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return stack;
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}
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void StackLayoutGenerator::processEntryPoint(CFG::BasicBlock const& _entry, CFG::FunctionInfo const* _functionInfo)
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{
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std::list<CFG::BasicBlock const*> toVisit{&_entry};
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std::set<CFG::BasicBlock const*> visited;
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// TODO: check whether visiting only a subset of these in the outer iteration below is enough.
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std::list<std::pair<CFG::BasicBlock const*, CFG::BasicBlock const*>> backwardsJumps = collectBackwardsJumps(_entry);
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while (!toVisit.empty())
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{
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// First calculate stack layouts without walking backwards jumps, i.e. assuming the current preliminary
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// entry layout of the backwards jump target as the initial exit layout of the backwards-jumping block.
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while (!toVisit.empty())
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{
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CFG::BasicBlock const *block = *toVisit.begin();
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toVisit.pop_front();
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if (visited.count(block))
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continue;
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if (std::optional<Stack> exitLayout = getExitLayoutOrStageDependencies(*block, visited, toVisit))
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{
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visited.emplace(block);
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auto& info = m_layout.blockInfos[block];
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info.exitLayout = *exitLayout;
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info.entryLayout = propagateStackThroughBlock(info.exitLayout, *block);
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for (auto entry: block->entries)
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toVisit.emplace_back(entry);
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}
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else
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continue;
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}
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// Determine which backwards jumps still require fixing and stage revisits of appropriate nodes.
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for (auto [jumpingBlock, target]: backwardsJumps)
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// This block jumps backwards, but does not provide all slots required by the jump target on exit.
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// Therefore we need to visit the subgraph between ``target`` and ``jumpingBlock`` again.
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if (ranges::any_of(
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m_layout.blockInfos[target].entryLayout,
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[exitLayout = m_layout.blockInfos[jumpingBlock].exitLayout](StackSlot const& _slot) {
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return !util::contains(exitLayout, _slot);
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}
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))
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{
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// In particular we can visit backwards starting from ``jumpingBlock`` and mark all entries to-be-visited-
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// again until we hit ``target``.
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toVisit.emplace_front(jumpingBlock);
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// Since we are likely to permute the entry layout of ``target``, we also visit its entries again.
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// This is not required for correctness, since the set of stack slots will match, but it may move some
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// required stack shuffling from the loop condition to outside the loop.
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for (CFG::BasicBlock const* entry: target->entries)
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visited.erase(entry);
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util::BreadthFirstSearch<CFG::BasicBlock const*>{{jumpingBlock}}.run(
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[&visited, target = target](CFG::BasicBlock const* _block, auto _addChild) {
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visited.erase(_block);
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if (_block == target)
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return;
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for (auto const* entry: _block->entries)
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_addChild(entry);
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}
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);
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// While the shuffled layout for ``target`` will be compatible, it can be worthwhile propagating
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// it further up once more.
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// This would mean not stopping at _block == target above, resp. even doing visited.clear() here, revisiting the entire graph.
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// This is a tradeoff between the runtime of this process and the optimality of the result.
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// Also note that while visiting the entire graph again *can* be helpful, it can also be detrimental.
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}
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}
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stitchConditionalJumps(_entry);
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fillInJunk(_entry, _functionInfo);
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}
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std::optional<Stack> StackLayoutGenerator::getExitLayoutOrStageDependencies(
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CFG::BasicBlock const& _block,
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std::set<CFG::BasicBlock const*> const& _visited,
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std::list<CFG::BasicBlock const*>& _toVisit
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) const
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{
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return std::visit(util::GenericVisitor{
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[&](CFG::BasicBlock::MainExit const&) -> std::optional<Stack>
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{
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// On the exit of the outermost block the stack can be empty.
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return Stack{};
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},
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[&](CFG::BasicBlock::Jump const& _jump) -> std::optional<Stack>
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{
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if (_jump.backwards)
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{
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// Choose the best currently known entry layout of the jump target as initial exit.
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// Note that this may not yet be the final layout.
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if (auto* info = util::valueOrNullptr(m_layout.blockInfos, _jump.target))
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return info->entryLayout;
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return Stack{};
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}
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// If the current iteration has already visited the jump target, start from its entry layout.
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if (_visited.count(_jump.target))
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return m_layout.blockInfos.at(_jump.target).entryLayout;
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// Otherwise stage the jump target for visit and defer the current block.
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_toVisit.emplace_front(_jump.target);
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return std::nullopt;
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},
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[&](CFG::BasicBlock::ConditionalJump const& _conditionalJump) -> std::optional<Stack>
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{
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bool zeroVisited = _visited.count(_conditionalJump.zero);
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bool nonZeroVisited = _visited.count(_conditionalJump.nonZero);
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if (zeroVisited && nonZeroVisited)
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{
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// If the current iteration has already visited both jump targets, start from its entry layout.
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Stack stack = combineStack(
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m_layout.blockInfos.at(_conditionalJump.zero).entryLayout,
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m_layout.blockInfos.at(_conditionalJump.nonZero).entryLayout
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);
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// Additionally, the jump condition has to be at the stack top at exit.
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stack.emplace_back(_conditionalJump.condition);
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return stack;
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}
|
|
// If one of the jump targets has not been visited, stage it for visit and defer the current block.
|
|
if (!zeroVisited)
|
|
_toVisit.emplace_front(_conditionalJump.zero);
|
|
if (!nonZeroVisited)
|
|
_toVisit.emplace_front(_conditionalJump.nonZero);
|
|
return std::nullopt;
|
|
},
|
|
[&](CFG::BasicBlock::FunctionReturn const& _functionReturn) -> std::optional<Stack>
|
|
{
|
|
// A function return needs the return variables and the function return label slot on stack.
|
|
yulAssert(_functionReturn.info, "");
|
|
Stack stack = _functionReturn.info->returnVariables | ranges::views::transform([](auto const& _varSlot){
|
|
return StackSlot{_varSlot};
|
|
}) | ranges::to<Stack>;
|
|
stack.emplace_back(FunctionReturnLabelSlot{_functionReturn.info->function});
|
|
return stack;
|
|
},
|
|
[&](CFG::BasicBlock::Terminated const&) -> std::optional<Stack>
|
|
{
|
|
// A terminating block can have an empty stack on exit.
|
|
return Stack{};
|
|
},
|
|
}, _block.exit);
|
|
}
|
|
|
|
std::list<std::pair<CFG::BasicBlock const*, CFG::BasicBlock const*>> StackLayoutGenerator::collectBackwardsJumps(CFG::BasicBlock const& _entry) const
|
|
{
|
|
std::list<std::pair<CFG::BasicBlock const*, CFG::BasicBlock const*>> backwardsJumps;
|
|
util::BreadthFirstSearch<CFG::BasicBlock const*>{{&_entry}}.run([&](CFG::BasicBlock const* _block, auto _addChild) {
|
|
std::visit(util::GenericVisitor{
|
|
[&](CFG::BasicBlock::MainExit const&) {},
|
|
[&](CFG::BasicBlock::Jump const& _jump)
|
|
{
|
|
if (_jump.backwards)
|
|
backwardsJumps.emplace_back(_block, _jump.target);
|
|
_addChild(_jump.target);
|
|
},
|
|
[&](CFG::BasicBlock::ConditionalJump const& _conditionalJump)
|
|
{
|
|
_addChild(_conditionalJump.zero);
|
|
_addChild(_conditionalJump.nonZero);
|
|
},
|
|
[&](CFG::BasicBlock::FunctionReturn const&) {},
|
|
[&](CFG::BasicBlock::Terminated const&) {},
|
|
}, _block->exit);
|
|
});
|
|
return backwardsJumps;
|
|
}
|
|
|
|
void StackLayoutGenerator::stitchConditionalJumps(CFG::BasicBlock const& _block)
|
|
{
|
|
util::BreadthFirstSearch<CFG::BasicBlock const*> breadthFirstSearch{{&_block}};
|
|
breadthFirstSearch.run([&](CFG::BasicBlock const* _block, auto _addChild) {
|
|
auto& info = m_layout.blockInfos.at(_block);
|
|
std::visit(util::GenericVisitor{
|
|
[&](CFG::BasicBlock::MainExit const&) {},
|
|
[&](CFG::BasicBlock::Jump const& _jump)
|
|
{
|
|
if (!_jump.backwards)
|
|
_addChild(_jump.target);
|
|
},
|
|
[&](CFG::BasicBlock::ConditionalJump const& _conditionalJump)
|
|
{
|
|
auto& zeroTargetInfo = m_layout.blockInfos.at(_conditionalJump.zero);
|
|
auto& nonZeroTargetInfo = m_layout.blockInfos.at(_conditionalJump.nonZero);
|
|
Stack exitLayout = info.exitLayout;
|
|
|
|
// The last block must have produced the condition at the stack top.
|
|
yulAssert(!exitLayout.empty(), "");
|
|
yulAssert(exitLayout.back() == _conditionalJump.condition, "");
|
|
// The condition is consumed by the jump.
|
|
exitLayout.pop_back();
|
|
|
|
auto fixJumpTargetEntry = [&](Stack const& _originalEntryLayout) -> Stack {
|
|
Stack newEntryLayout = exitLayout;
|
|
// Whatever the block being jumped to does not actually require, can be marked as junk.
|
|
for (auto& slot: newEntryLayout)
|
|
if (!util::contains(_originalEntryLayout, slot))
|
|
slot = JunkSlot{};
|
|
// Make sure everything the block being jumped to requires is actually present or can be generated.
|
|
for (auto const& slot: _originalEntryLayout)
|
|
yulAssert(canBeFreelyGenerated(slot) || util::contains(newEntryLayout, slot), "");
|
|
return newEntryLayout;
|
|
};
|
|
zeroTargetInfo.entryLayout = fixJumpTargetEntry(zeroTargetInfo.entryLayout);
|
|
nonZeroTargetInfo.entryLayout = fixJumpTargetEntry(nonZeroTargetInfo.entryLayout);
|
|
_addChild(_conditionalJump.zero);
|
|
_addChild(_conditionalJump.nonZero);
|
|
},
|
|
[&](CFG::BasicBlock::FunctionReturn const&) {},
|
|
[&](CFG::BasicBlock::Terminated const&) { },
|
|
}, _block->exit);
|
|
});
|
|
}
|
|
|
|
Stack StackLayoutGenerator::combineStack(Stack const& _stack1, Stack const& _stack2)
|
|
{
|
|
// TODO: it would be nicer to replace this by a constructive algorithm.
|
|
// Currently it uses a reduced version of the Heap Algorithm to partly brute-force, which seems
|
|
// to work decently well.
|
|
|
|
Stack commonPrefix;
|
|
for (auto&& [slot1, slot2]: ranges::zip_view(_stack1, _stack2))
|
|
{
|
|
if (!(slot1 == slot2))
|
|
break;
|
|
commonPrefix.emplace_back(slot1);
|
|
}
|
|
|
|
Stack stack1Tail = _stack1 | ranges::views::drop(commonPrefix.size()) | ranges::to<Stack>;
|
|
Stack stack2Tail = _stack2 | ranges::views::drop(commonPrefix.size()) | ranges::to<Stack>;
|
|
|
|
if (stack1Tail.empty())
|
|
return commonPrefix + compressStack(stack2Tail);
|
|
if (stack2Tail.empty())
|
|
return commonPrefix + compressStack(stack1Tail);
|
|
|
|
Stack candidate;
|
|
for (auto slot: stack1Tail)
|
|
if (!util::contains(candidate, slot))
|
|
candidate.emplace_back(slot);
|
|
for (auto slot: stack2Tail)
|
|
if (!util::contains(candidate, slot))
|
|
candidate.emplace_back(slot);
|
|
cxx20::erase_if(candidate, [](StackSlot const& slot) {
|
|
return std::holds_alternative<LiteralSlot>(slot) || std::holds_alternative<FunctionCallReturnLabelSlot>(slot);
|
|
});
|
|
|
|
auto evaluate = [&](Stack const& _candidate) -> size_t {
|
|
size_t numOps = 0;
|
|
Stack testStack = _candidate;
|
|
auto swap = [&](unsigned _swapDepth) { ++numOps; if (_swapDepth > 16) numOps += 1000; };
|
|
auto dupOrPush = [&](StackSlot const& _slot)
|
|
{
|
|
if (canBeFreelyGenerated(_slot))
|
|
return;
|
|
auto depth = util::findOffset(ranges::concat_view(commonPrefix, testStack) | ranges::views::reverse, _slot);
|
|
if (depth && *depth >= 16)
|
|
numOps += 1000;
|
|
};
|
|
createStackLayout(testStack, stack1Tail, swap, dupOrPush, [&](){});
|
|
testStack = _candidate;
|
|
createStackLayout(testStack, stack2Tail, swap, dupOrPush, [&](){});
|
|
return numOps;
|
|
};
|
|
|
|
// See https://en.wikipedia.org/wiki/Heap's_algorithm
|
|
size_t n = candidate.size();
|
|
Stack bestCandidate = candidate;
|
|
size_t bestCost = evaluate(candidate);
|
|
std::vector<size_t> c(n, 0);
|
|
size_t i = 1;
|
|
while (i < n)
|
|
{
|
|
if (c[i] < i)
|
|
{
|
|
if (i & 1)
|
|
std::swap(candidate.front(), candidate[i]);
|
|
else
|
|
std::swap(candidate[c[i]], candidate[i]);
|
|
size_t cost = evaluate(candidate);
|
|
if (cost < bestCost)
|
|
{
|
|
bestCost = cost;
|
|
bestCandidate = candidate;
|
|
}
|
|
++c[i];
|
|
// Note that for a proper implementation of the Heap algorithm this would need to revert back to ``i = 1.``
|
|
// However, the incorrect implementation produces decent result and the proper version would have n!
|
|
// complexity and is thereby not feasible.
|
|
++i;
|
|
}
|
|
else
|
|
{
|
|
c[i] = 0;
|
|
++i;
|
|
}
|
|
}
|
|
|
|
return commonPrefix + bestCandidate;
|
|
}
|
|
|
|
std::vector<StackLayoutGenerator::StackTooDeep> StackLayoutGenerator::reportStackTooDeep(CFG::BasicBlock const& _entry) const
|
|
{
|
|
std::vector<StackTooDeep> stackTooDeepErrors;
|
|
util::BreadthFirstSearch<CFG::BasicBlock const*> breadthFirstSearch{{&_entry}};
|
|
breadthFirstSearch.run([&](CFG::BasicBlock const* _block, auto _addChild) {
|
|
Stack currentStack = m_layout.blockInfos.at(_block).entryLayout;
|
|
|
|
for (auto const& operation: _block->operations)
|
|
{
|
|
Stack& operationEntry = m_layout.operationEntryLayout.at(&operation);
|
|
|
|
stackTooDeepErrors += findStackTooDeep(currentStack, operationEntry);
|
|
currentStack = operationEntry;
|
|
for (size_t i = 0; i < operation.input.size(); i++)
|
|
currentStack.pop_back();
|
|
currentStack += operation.output;
|
|
}
|
|
// Do not attempt to create the exit layout m_layout.blockInfos.at(_block).exitLayout here,
|
|
// since the code generator will directly move to the target entry layout.
|
|
|
|
std::visit(util::GenericVisitor{
|
|
[&](CFG::BasicBlock::MainExit const&) {},
|
|
[&](CFG::BasicBlock::Jump const& _jump)
|
|
{
|
|
Stack const& targetLayout = m_layout.blockInfos.at(_jump.target).entryLayout;
|
|
stackTooDeepErrors += findStackTooDeep(currentStack, targetLayout);
|
|
|
|
if (!_jump.backwards)
|
|
_addChild(_jump.target);
|
|
},
|
|
[&](CFG::BasicBlock::ConditionalJump const& _conditionalJump)
|
|
{
|
|
for (Stack const& targetLayout: {
|
|
m_layout.blockInfos.at(_conditionalJump.zero).entryLayout,
|
|
m_layout.blockInfos.at(_conditionalJump.nonZero).entryLayout
|
|
})
|
|
stackTooDeepErrors += findStackTooDeep(currentStack, targetLayout);
|
|
|
|
_addChild(_conditionalJump.zero);
|
|
_addChild(_conditionalJump.nonZero);
|
|
},
|
|
[&](CFG::BasicBlock::FunctionReturn const&) {},
|
|
[&](CFG::BasicBlock::Terminated const&) {},
|
|
}, _block->exit);
|
|
});
|
|
return stackTooDeepErrors;
|
|
}
|
|
|
|
Stack StackLayoutGenerator::compressStack(Stack _stack)
|
|
{
|
|
std::optional<size_t> firstDupOffset;
|
|
do
|
|
{
|
|
if (firstDupOffset)
|
|
{
|
|
std::swap(_stack.at(*firstDupOffset), _stack.back());
|
|
_stack.pop_back();
|
|
firstDupOffset.reset();
|
|
}
|
|
for (auto&& [depth, slot]: _stack | ranges::views::reverse | ranges::views::enumerate)
|
|
if (canBeFreelyGenerated(slot))
|
|
{
|
|
firstDupOffset = _stack.size() - depth - 1;
|
|
break;
|
|
}
|
|
else if (auto dupDepth = util::findOffset(_stack | ranges::views::reverse | ranges::views::drop(depth + 1), slot))
|
|
if (depth + *dupDepth <= 16)
|
|
{
|
|
firstDupOffset = _stack.size() - depth - 1;
|
|
break;
|
|
}
|
|
}
|
|
while (firstDupOffset);
|
|
return _stack;
|
|
}
|
|
|
|
void StackLayoutGenerator::fillInJunk(CFG::BasicBlock const& _block, CFG::FunctionInfo const* _functionInfo)
|
|
{
|
|
/// Recursively adds junk to the subgraph starting on @a _entry.
|
|
/// Since it is only called on cut-vertices, the full subgraph retains proper stack balance.
|
|
auto addJunkRecursive = [&](CFG::BasicBlock const* _entry, size_t _numJunk) {
|
|
util::BreadthFirstSearch<CFG::BasicBlock const*> breadthFirstSearch{{_entry}};
|
|
breadthFirstSearch.run([&](CFG::BasicBlock const* _block, auto _addChild) {
|
|
auto& blockInfo = m_layout.blockInfos.at(_block);
|
|
blockInfo.entryLayout = Stack{_numJunk, JunkSlot{}} + std::move(blockInfo.entryLayout);
|
|
for (auto const& operation: _block->operations)
|
|
{
|
|
auto& operationEntryLayout = m_layout.operationEntryLayout.at(&operation);
|
|
operationEntryLayout = Stack{_numJunk, JunkSlot{}} + std::move(operationEntryLayout);
|
|
}
|
|
blockInfo.exitLayout = Stack{_numJunk, JunkSlot{}} + std::move(blockInfo.exitLayout);
|
|
|
|
std::visit(util::GenericVisitor{
|
|
[&](CFG::BasicBlock::MainExit const&) {},
|
|
[&](CFG::BasicBlock::Jump const& _jump)
|
|
{
|
|
_addChild(_jump.target);
|
|
},
|
|
[&](CFG::BasicBlock::ConditionalJump const& _conditionalJump)
|
|
{
|
|
_addChild(_conditionalJump.zero);
|
|
_addChild(_conditionalJump.nonZero);
|
|
},
|
|
[&](CFG::BasicBlock::FunctionReturn const&) { yulAssert(false); },
|
|
[&](CFG::BasicBlock::Terminated const&) {},
|
|
}, _block->exit);
|
|
});
|
|
};
|
|
/// @returns the number of operations required to transform @a _source to @a _target.
|
|
auto evaluateTransform = [&](Stack _source, Stack const& _target) -> size_t {
|
|
size_t opGas = 0;
|
|
auto swap = [&](unsigned _swapDepth)
|
|
{
|
|
if (_swapDepth > 16)
|
|
opGas += 1000;
|
|
else
|
|
opGas += evmasm::GasMeter::runGas(evmasm::swapInstruction(_swapDepth), langutil::EVMVersion());
|
|
};
|
|
auto dupOrPush = [&](StackSlot const& _slot)
|
|
{
|
|
if (canBeFreelyGenerated(_slot))
|
|
opGas += evmasm::GasMeter::runGas(evmasm::pushInstruction(32), langutil::EVMVersion());
|
|
else
|
|
{
|
|
if (auto depth = util::findOffset(_source | ranges::views::reverse, _slot))
|
|
{
|
|
if (*depth < 16)
|
|
opGas += evmasm::GasMeter::runGas(evmasm::dupInstruction(static_cast<unsigned>(*depth + 1)), langutil::EVMVersion());
|
|
else
|
|
opGas += 1000;
|
|
}
|
|
else
|
|
{
|
|
// This has to be a previously unassigned return variable.
|
|
// We at least sanity-check that it is among the return variables at all.
|
|
yulAssert(m_currentFunctionInfo && std::holds_alternative<VariableSlot>(_slot));
|
|
yulAssert(util::contains(m_currentFunctionInfo->returnVariables, std::get<VariableSlot>(_slot)));
|
|
// Strictly speaking the cost of the PUSH0 depends on the targeted EVM version, but the difference
|
|
// will not matter here.
|
|
opGas += evmasm::GasMeter::runGas(evmasm::pushInstruction(0), langutil::EVMVersion());;
|
|
}
|
|
}
|
|
};
|
|
auto pop = [&]() { opGas += evmasm::GasMeter::runGas(evmasm::Instruction::POP,langutil::EVMVersion()); };
|
|
createStackLayout(_source, _target, swap, dupOrPush, pop);
|
|
return opGas;
|
|
};
|
|
/// @returns the number of junk slots to be prepended to @a _targetLayout for an optimal transition from
|
|
/// @a _entryLayout to @a _targetLayout.
|
|
auto getBestNumJunk = [&](Stack const& _entryLayout, Stack const& _targetLayout) -> size_t {
|
|
size_t bestCost = evaluateTransform(_entryLayout, _targetLayout);
|
|
size_t bestNumJunk = 0;
|
|
size_t maxJunk = _entryLayout.size();
|
|
for (size_t numJunk = 1; numJunk <= maxJunk; ++numJunk)
|
|
{
|
|
size_t cost = evaluateTransform(_entryLayout, Stack{numJunk, JunkSlot{}} + _targetLayout);
|
|
if (cost < bestCost)
|
|
{
|
|
bestCost = cost;
|
|
bestNumJunk = numJunk;
|
|
}
|
|
}
|
|
return bestNumJunk;
|
|
};
|
|
|
|
if (_functionInfo && !_functionInfo->canContinue && _block.allowsJunk())
|
|
{
|
|
size_t bestNumJunk = getBestNumJunk(
|
|
_functionInfo->parameters | ranges::views::reverse | ranges::to<Stack>,
|
|
m_layout.blockInfos.at(&_block).entryLayout
|
|
);
|
|
if (bestNumJunk > 0)
|
|
addJunkRecursive(&_block, bestNumJunk);
|
|
}
|
|
|
|
/// Traverses the CFG and at each block that allows junk, i.e. that is a cut-vertex that never leads to a function
|
|
/// return, checks if adding junk reduces the shuffling cost upon entering and if so recursively adds junk
|
|
/// to the spanned subgraph.
|
|
util::BreadthFirstSearch<CFG::BasicBlock const*>{{&_block}}.run([&](CFG::BasicBlock const* _block, auto _addChild) {
|
|
if (_block->allowsJunk())
|
|
{
|
|
auto& blockInfo = m_layout.blockInfos.at(_block);
|
|
Stack entryLayout = blockInfo.entryLayout;
|
|
Stack const& nextLayout = _block->operations.empty() ? blockInfo.exitLayout : m_layout.operationEntryLayout.at(&_block->operations.front());
|
|
if (entryLayout != nextLayout)
|
|
{
|
|
size_t bestNumJunk = getBestNumJunk(
|
|
entryLayout,
|
|
nextLayout
|
|
);
|
|
if (bestNumJunk > 0)
|
|
{
|
|
addJunkRecursive(_block, bestNumJunk);
|
|
blockInfo.entryLayout = entryLayout;
|
|
}
|
|
}
|
|
}
|
|
std::visit(util::GenericVisitor{
|
|
[&](CFG::BasicBlock::MainExit const&) {},
|
|
[&](CFG::BasicBlock::Jump const& _jump)
|
|
{
|
|
_addChild(_jump.target);
|
|
},
|
|
[&](CFG::BasicBlock::ConditionalJump const& _conditionalJump)
|
|
{
|
|
_addChild(_conditionalJump.zero);
|
|
_addChild(_conditionalJump.nonZero);
|
|
},
|
|
[&](CFG::BasicBlock::FunctionReturn const&) {},
|
|
[&](CFG::BasicBlock::Terminated const&) {},
|
|
}, _block->exit);
|
|
});
|
|
}
|