solidity/test/libyul/ControlFlowGraphTest.cpp

254 lines
8.6 KiB
C++

/*
This file is part of solidity.
solidity is free software: you can redistribute it and/or modify
it under the terms of the GNU General Public License as published by
the Free Software Foundation, either version 3 of the License, or
(at your option) any later version.
solidity is distributed in the hope that it will be useful,
but WITHOUT ANY WARRANTY; without even the implied warranty of
MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
GNU General Public License for more details.
You should have received a copy of the GNU General Public License
along with solidity. If not, see <http://www.gnu.org/licenses/>.
*/
// SPDX-License-Identifier: GPL-3.0
#include <test/libyul/ControlFlowGraphTest.h>
#include <test/libyul/Common.h>
#include <test/Common.h>
#include <libyul/backends/evm/ControlFlowGraph.h>
#include <libyul/backends/evm/ControlFlowGraphBuilder.h>
#include <libyul/backends/evm/StackHelpers.h>
#include <libyul/Object.h>
#include <libsolutil/AnsiColorized.h>
#include <libsolutil/Visitor.h>
#ifdef ISOLTEST
#include <boost/process.hpp>
#endif
using namespace solidity;
using namespace solidity::util;
using namespace solidity::langutil;
using namespace solidity::yul;
using namespace solidity::yul::test;
using namespace solidity::frontend;
using namespace solidity::frontend::test;
using namespace std;
ControlFlowGraphTest::ControlFlowGraphTest(string const& _filename):
TestCase(_filename)
{
m_source = m_reader.source();
auto dialectName = m_reader.stringSetting("dialect", "evm");
m_dialect = &dialect(dialectName, solidity::test::CommonOptions::get().evmVersion());
m_expectation = m_reader.simpleExpectations();
}
namespace
{
static std::string variableSlotToString(VariableSlot const& _slot)
{
return _slot.variable.get().name.str();
}
}
class ControlFlowGraphPrinter
{
public:
ControlFlowGraphPrinter(std::ostream& _stream):
m_stream(_stream)
{
}
void operator()(CFG::BasicBlock const& _block, bool _isMainEntry = true)
{
if (_isMainEntry)
{
m_stream << "Entry [label=\"Entry\"];\n";
m_stream << "Entry -> Block" << getBlockId(_block) << ";\n";
}
while (!m_blocksToPrint.empty())
{
CFG::BasicBlock const* block = *m_blocksToPrint.begin();
m_blocksToPrint.erase(m_blocksToPrint.begin());
printBlock(*block);
}
}
void operator()(
CFG::FunctionInfo const& _info
)
{
m_stream << "FunctionEntry_" << _info.function.name.str() << "_" << getBlockId(*_info.entry) << " [label=\"";
m_stream << "function " << _info.function.name.str() << "(";
m_stream << joinHumanReadable(_info.parameters | ranges::views::transform(variableSlotToString));
m_stream << ")";
if (!_info.returnVariables.empty())
{
m_stream << " -> ";
m_stream << joinHumanReadable(_info.returnVariables | ranges::views::transform(variableSlotToString));
}
m_stream << "\"];\n";
m_stream << "FunctionEntry_" << _info.function.name.str() << "_" << getBlockId(*_info.entry) << " -> Block" << getBlockId(*_info.entry) << ";\n";
(*this)(*_info.entry, false);
}
private:
void printBlock(CFG::BasicBlock const& _block)
{
m_stream << "Block" << getBlockId(_block) << " [label=\"\\\n";
// Verify that the entries of this block exit into this block.
for (auto const& entry: _block.entries)
std::visit(util::GenericVisitor{
[&](CFG::BasicBlock::Jump const& _jump)
{
soltestAssert(_jump.target == &_block, "Invalid control flow graph.");
},
[&](CFG::BasicBlock::ConditionalJump const& _conditionalJump)
{
soltestAssert(
_conditionalJump.zero == &_block || _conditionalJump.nonZero == &_block,
"Invalid control flow graph."
);
},
[&](auto const&)
{
soltestAssert(false, "Invalid control flow graph.");
}
}, entry->exit);
for (auto const& operation: _block.operations)
{
std::visit(util::GenericVisitor{
[&](CFG::FunctionCall const& _call) {
m_stream << _call.function.get().name.str() << ": ";
},
[&](CFG::BuiltinCall const& _call) {
m_stream << _call.functionCall.get().functionName.name.str() << ": ";
},
[&](CFG::Assignment const& _assignment) {
m_stream << "Assignment(";
m_stream << joinHumanReadable(_assignment.variables | ranges::views::transform(variableSlotToString));
m_stream << "): ";
}
}, operation.operation);
m_stream << stackToString(operation.input) << " => " << stackToString(operation.output) << "\\l\\\n";
}
m_stream << "\"];\n";
std::visit(util::GenericVisitor{
[&](CFG::BasicBlock::MainExit const&)
{
m_stream << "Block" << getBlockId(_block) << "Exit [label=\"MainExit\"];\n";
m_stream << "Block" << getBlockId(_block) << " -> Block" << getBlockId(_block) << "Exit;\n";
},
[&](CFG::BasicBlock::Jump const& _jump)
{
m_stream << "Block" << getBlockId(_block) << " -> Block" << getBlockId(_block) << "Exit [arrowhead=none];\n";
m_stream << "Block" << getBlockId(_block) << "Exit [label=\"";
if (_jump.backwards)
m_stream << "Backwards";
m_stream << "Jump\" shape=oval];\n";
m_stream << "Block" << getBlockId(_block) << "Exit -> Block" << getBlockId(*_jump.target) << ";\n";
},
[&](CFG::BasicBlock::ConditionalJump const& _conditionalJump)
{
m_stream << "Block" << getBlockId(_block) << " -> Block" << getBlockId(_block) << "Exit;\n";
m_stream << "Block" << getBlockId(_block) << "Exit [label=\"{ ";
m_stream << stackSlotToString(_conditionalJump.condition);
m_stream << "| { <0> Zero | <1> NonZero }}\" shape=Mrecord];\n";
m_stream << "Block" << getBlockId(_block);
m_stream << "Exit:0 -> Block" << getBlockId(*_conditionalJump.zero) << ";\n";
m_stream << "Block" << getBlockId(_block);
m_stream << "Exit:1 -> Block" << getBlockId(*_conditionalJump.nonZero) << ";\n";
},
[&](CFG::BasicBlock::FunctionReturn const& _return)
{
m_stream << "Block" << getBlockId(_block) << "Exit [label=\"FunctionReturn[" << _return.info->function.name.str() << "]\"];\n";
m_stream << "Block" << getBlockId(_block) << " -> Block" << getBlockId(_block) << "Exit;\n";
},
[&](CFG::BasicBlock::Terminated const&)
{
m_stream << "Block" << getBlockId(_block) << "Exit [label=\"Terminated\"];\n";
m_stream << "Block" << getBlockId(_block) << " -> Block" << getBlockId(_block) << "Exit;\n";
}
}, _block.exit);
m_stream << "\n";
}
size_t getBlockId(CFG::BasicBlock const& _block)
{
if (size_t* id = util::valueOrNullptr(m_blockIds, &_block))
return *id;
size_t id = m_blockIds[&_block] = m_blockCount++;
m_blocksToPrint.emplace_back(&_block);
return id;
}
std::ostream& m_stream;
std::map<CFG::BasicBlock const*, size_t> m_blockIds;
size_t m_blockCount = 0;
std::list<CFG::BasicBlock const*> m_blocksToPrint;
};
TestCase::TestResult ControlFlowGraphTest::run(ostream& _stream, string const& _linePrefix, bool const _formatted)
{
ErrorList errors;
auto [object, analysisInfo] = parse(m_source, *m_dialect, errors);
if (!object || !analysisInfo || Error::containsErrors(errors))
{
AnsiColorized(_stream, _formatted, {formatting::BOLD, formatting::RED}) << _linePrefix << "Error parsing source." << endl;
return TestResult::FatalError;
}
std::ostringstream output;
std::unique_ptr<CFG> cfg = ControlFlowGraphBuilder::build(*analysisInfo, *m_dialect, *object->code);
output << "digraph CFG {\nnodesep=0.7;\nnode[shape=box];\n\n";
ControlFlowGraphPrinter printer{output};
printer(*cfg->entry);
for (auto function: cfg->functions)
printer(cfg->functionInfo.at(function));
output << "}\n";
m_obtainedResult = output.str();
auto result = checkResult(_stream, _linePrefix, _formatted);
#ifdef ISOLTEST
char* graphDisplayer = nullptr;
// The environment variables specify an optional command that will receive the graph encoded in DOT through stdin.
// Examples for suitable commands are ``dot -Tx11:cairo`` or ``xdot -``.
if (result == TestResult::Failure)
// ISOLTEST_DISPLAY_GRAPHS_ON_FAILURE_COMMAND will run on all failing tests (intended for use during modifications).
graphDisplayer = getenv("ISOLTEST_DISPLAY_GRAPHS_ON_FAILURE_COMMAND");
else if (result == TestResult::Success)
// ISOLTEST_DISPLAY_GRAPHS_ON_FAILURE_COMMAND will run on all succeeding tests (intended for use during reviews).
graphDisplayer = getenv("ISOLTEST_DISPLAY_GRAPHS_ON_SUCCESS_COMMAND");
if (graphDisplayer)
{
if (result == TestResult::Success)
std::cout << std::endl << m_source << std::endl;
boost::process::opstream pipe;
boost::process::child child(graphDisplayer, boost::process::std_in < pipe);
pipe << output.str();
pipe.flush();
pipe.pipe().close();
if (result == TestResult::Success)
child.wait();
else
child.detach();
}
#endif
return result;
}