/*
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 .
*/
/**
* Optimiser component that turns subsequent assignments to variable declarations
* and assignments.
*/
#include
#include
#include
#include
#include
#include
using namespace std;
using namespace solidity;
using namespace solidity::yul;
using namespace solidity::langutil;
namespace
{
/**
* First step of SSA transform: Introduces new SSA variables for each assignment or
* declaration of a variable to be replaced.
*/
class IntroduceSSA: public ASTModifier
{
public:
explicit IntroduceSSA(
NameDispenser& _nameDispenser,
set const& _variablesToReplace,
TypeInfo& _typeInfo
):
m_nameDispenser(_nameDispenser),
m_variablesToReplace(_variablesToReplace),
m_typeInfo(_typeInfo)
{ }
void operator()(Block& _block) override;
private:
NameDispenser& m_nameDispenser;
set const& m_variablesToReplace;
TypeInfo const& m_typeInfo;
};
void IntroduceSSA::operator()(Block& _block)
{
util::iterateReplacing(
_block.statements,
[&](Statement& _s) -> std::optional>
{
if (holds_alternative(_s))
{
VariableDeclaration& varDecl = std::get(_s);
if (varDecl.value)
visit(*varDecl.value);
bool needToReplaceSome = false;
for (auto const& var: varDecl.variables)
if (m_variablesToReplace.count(var.name))
needToReplaceSome = true;
if (!needToReplaceSome)
return {};
// Replace "let a := v" by "let a_1 := v let a := a_1"
// Replace "let a, b := v" by "let a_1, b_1 := v let a := a_1 let b := b_2"
auto loc = varDecl.location;
vector statements;
statements.emplace_back(VariableDeclaration{loc, {}, std::move(varDecl.value)});
TypedNameList newVariables;
for (auto const& var: varDecl.variables)
{
YulString oldName = var.name;
YulString newName = m_nameDispenser.newName(oldName);
newVariables.emplace_back(TypedName{loc, newName, var.type});
statements.emplace_back(VariableDeclaration{
loc,
{TypedName{loc, oldName, var.type}},
make_unique(Identifier{loc, newName})
});
}
std::get(statements.front()).variables = std::move(newVariables);
return { std::move(statements) };
}
else if (holds_alternative(_s))
{
Assignment& assignment = std::get(_s);
visit(*assignment.value);
for (auto const& var: assignment.variableNames)
assertThrow(m_variablesToReplace.count(var.name), OptimizerException, "");
// Replace "a := v" by "let a_1 := v a := v"
// Replace "a, b := v" by "let a_1, b_1 := v a := a_1 b := b_2"
auto loc = assignment.location;
vector statements;
statements.emplace_back(VariableDeclaration{loc, {}, std::move(assignment.value)});
TypedNameList newVariables;
for (auto const& var: assignment.variableNames)
{
YulString oldName = var.name;
YulString newName = m_nameDispenser.newName(oldName);
newVariables.emplace_back(TypedName{
loc,
newName,
m_typeInfo.typeOfVariable(oldName)
});
statements.emplace_back(Assignment{
loc,
{Identifier{loc, oldName}},
make_unique(Identifier{loc, newName})
});
}
std::get(statements.front()).variables = std::move(newVariables);
return { std::move(statements) };
}
else
visit(_s);
return {};
}
);
}
/**
* Second step of SSA transform: Introduces new SSA variables at each control-flow join
* and at the beginning of functions.
*/
class IntroduceControlFlowSSA: public ASTModifier
{
public:
explicit IntroduceControlFlowSSA(
NameDispenser& _nameDispenser,
set const& _variablesToReplace,
TypeInfo const& _typeInfo
):
m_nameDispenser(_nameDispenser),
m_variablesToReplace(_variablesToReplace),
m_typeInfo(_typeInfo)
{ }
void operator()(FunctionDefinition& _function) override;
void operator()(ForLoop& _forLoop) override;
void operator()(Switch& _switch) override;
void operator()(Block& _block) override;
private:
NameDispenser& m_nameDispenser;
set const& m_variablesToReplace;
/// Variables (that are to be replaced) currently in scope.
set m_variablesInScope;
/// Set of variables that do not have a specific value.
set m_variablesToReassign;
TypeInfo const& m_typeInfo;
};
void IntroduceControlFlowSSA::operator()(FunctionDefinition& _function)
{
set varsInScope;
std::swap(varsInScope, m_variablesInScope);
set toReassign;
std::swap(toReassign, m_variablesToReassign);
for (auto const& param: _function.parameters)
if (m_variablesToReplace.count(param.name))
{
m_variablesInScope.insert(param.name);
m_variablesToReassign.insert(param.name);
}
ASTModifier::operator()(_function);
m_variablesInScope = std::move(varsInScope);
m_variablesToReassign = std::move(toReassign);
}
void IntroduceControlFlowSSA::operator()(ForLoop& _for)
{
(*this)(_for.pre);
Assignments assignments;
assignments(_for.body);
assignments(_for.post);
for (auto const& var: assignments.names())
if (m_variablesInScope.count(var))
m_variablesToReassign.insert(var);
(*this)(_for.body);
(*this)(_for.post);
}
void IntroduceControlFlowSSA::operator()(Switch& _switch)
{
yulAssert(m_variablesToReassign.empty(), "");
set toReassign;
for (auto& c: _switch.cases)
{
(*this)(c.body);
toReassign += m_variablesToReassign;
}
m_variablesToReassign += toReassign;
}
void IntroduceControlFlowSSA::operator()(Block& _block)
{
set variablesDeclaredHere;
set assignedVariables;
util::iterateReplacing(
_block.statements,
[&](Statement& _s) -> std::optional>
{
vector toPrepend;
for (YulString toReassign: m_variablesToReassign)
{
YulString newName = m_nameDispenser.newName(toReassign);
toPrepend.emplace_back(VariableDeclaration{
locationOf(_s),
{TypedName{locationOf(_s), newName, m_typeInfo.typeOfVariable(toReassign)}},
make_unique(Identifier{locationOf(_s), toReassign})
});
assignedVariables.insert(toReassign);
}
m_variablesToReassign.clear();
if (holds_alternative(_s))
{
VariableDeclaration& varDecl = std::get(_s);
for (auto const& var: varDecl.variables)
if (m_variablesToReplace.count(var.name))
{
variablesDeclaredHere.insert(var.name);
m_variablesInScope.insert(var.name);
}
}
else if (holds_alternative(_s))
{
Assignment& assignment = std::get(_s);
for (auto const& var: assignment.variableNames)
if (m_variablesToReplace.count(var.name))
assignedVariables.insert(var.name);
}
else
visit(_s);
if (toPrepend.empty())
return {};
else
{
toPrepend.emplace_back(std::move(_s));
return {std::move(toPrepend)};
}
}
);
m_variablesToReassign += assignedVariables;
m_variablesInScope -= variablesDeclaredHere;
m_variablesToReassign -= variablesDeclaredHere;
}
/**
* Third step of SSA transform: Replace the references to variables-to-be-replaced
* by their current values.
*/
class PropagateValues: public ASTModifier
{
public:
explicit PropagateValues(set const& _variablesToReplace):
m_variablesToReplace(_variablesToReplace)
{ }
void operator()(Identifier& _identifier) override;
void operator()(VariableDeclaration& _varDecl) override;
void operator()(Assignment& _assignment) override;
void operator()(ForLoop& _for) override;
void operator()(Block& _block) override;
private:
/// This is a set of all variables that are assigned to anywhere in the code.
/// Variables that are only declared but never re-assigned are not touched.
set const& m_variablesToReplace;
map m_currentVariableValues;
set m_clearAtEndOfBlock;
};
void PropagateValues::operator()(Identifier& _identifier)
{
if (m_currentVariableValues.count(_identifier.name))
_identifier.name = m_currentVariableValues[_identifier.name];
}
void PropagateValues::operator()(VariableDeclaration& _varDecl)
{
ASTModifier::operator()(_varDecl);
if (_varDecl.variables.size() != 1)
return;
YulString variable = _varDecl.variables.front().name;
if (m_variablesToReplace.count(variable))
{
// `let a := a_1` - regular declaration of non-SSA variable
yulAssert(holds_alternative(*_varDecl.value), "");
m_currentVariableValues[variable] = std::get(*_varDecl.value).name;
m_clearAtEndOfBlock.insert(variable);
}
else if (_varDecl.value && holds_alternative(*_varDecl.value))
{
// `let a_1 := a` - assignment to SSA variable after a branch.
YulString value = std::get(*_varDecl.value).name;
if (m_variablesToReplace.count(value))
{
// This is safe because `a_1` is not a "variable to replace" and thus
// will not be re-assigned.
m_currentVariableValues[value] = variable;
m_clearAtEndOfBlock.insert(value);
}
}
}
void PropagateValues::operator()(Assignment& _assignment)
{
visit(*_assignment.value);
if (_assignment.variableNames.size() != 1)
return;
YulString name = _assignment.variableNames.front().name;
if (!m_variablesToReplace.count(name))
return;
yulAssert(_assignment.value && holds_alternative(*_assignment.value), "");
m_currentVariableValues[name] = std::get(*_assignment.value).name;
m_clearAtEndOfBlock.insert(name);
}
void PropagateValues::operator()(ForLoop& _for)
{
// This will clear the current value in case of a reassignment inside the
// init part, although the new variable would still be in scope inside the whole loop.
// This small inefficiency is fine if we move the pre part of all for loops out
// of the for loop.
(*this)(_for.pre);
Assignments assignments;
assignments(_for.body);
assignments(_for.post);
for (auto const& var: assignments.names())
m_currentVariableValues.erase(var);
visit(*_for.condition);
(*this)(_for.body);
(*this)(_for.post);
}
void PropagateValues::operator()(Block& _block)
{
set clearAtParentBlock = std::move(m_clearAtEndOfBlock);
m_clearAtEndOfBlock.clear();
ASTModifier::operator()(_block);
for (auto const& var: m_clearAtEndOfBlock)
m_currentVariableValues.erase(var);
m_clearAtEndOfBlock = std::move(clearAtParentBlock);
}
}
void SSATransform::run(OptimiserStepContext& _context, Block& _ast)
{
TypeInfo typeInfo(_context.dialect, _ast);
Assignments assignments;
assignments(_ast);
IntroduceSSA{_context.dispenser, assignments.names(), typeInfo}(_ast);
IntroduceControlFlowSSA{_context.dispenser, assignments.names(), typeInfo}(_ast);
PropagateValues{assignments.names()}(_ast);
}