/*
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 .
*/
#pragma once
#include
#include
#include
namespace solidity::frontend
{
class VariableDeclaration;
class Type;
class Expression;
/**
* An IRVariable refers to a set of yul variables that correspond to the stack layout of a Solidity variable or expression
* of a specific S
* olidity type. If the Solidity type occupies a single stack slot, the IRVariable refers to a single yul variable.
* Otherwise the set of yul variables it refers to is (recursively) determined by @see ``Type::stackItems()``.
* For example, an IRVariable referring to a dynamically sized calldata array will consist of two parts named
* ``offset`` and ``length``, whereas an IRVariable referring to a statically sized calldata type, a storage reference
* type or a memory reference type will contain a single unnamed part containing an offset. An IRVariable referring to
* a value type will contain a single unnamed part containing the value, an IRVariable referring to a tuple will
* have the typed tuple components as parts.
*/
class IRVariable
{
public:
/// IR variable with explicit base name @a _baseName and type @a _type.
IRVariable(std::string _baseName, Type const& _type);
/// IR variable referring to the declaration @a _decl.
explicit IRVariable(VariableDeclaration const& _decl);
/// IR variable referring to the expression @a _expr.
/// Intentionally not defined as explicit to allow defining IRVariables for expressions directly via implicit conversions.
IRVariable(Expression const& _expression);
/// @returns the name of the variable, if it occupies a single stack slot (otherwise throws).
std::string name() const;
/// @returns a comma-separated list of the stack slots of the variable.
std::string commaSeparatedList() const;
/// @returns a comma-separated list of the stack slots of the variable that is
/// prefixed with a comma, unless it is empty.
std::string commaSeparatedListPrefixed() const;
/// @returns an IRVariable referring to the tuple component @a _i of a tuple variable.
IRVariable tupleComponent(std::size_t _i) const;
/// @returns the type of the variable.
Type const& type() const { return m_type; }
/// @returns an IRVariable referring to the stack component @a _slot of the variable.
/// @a _slot must be among the stack slots in ``m_type.stackItems()``.
/// The returned IRVariable is itself typed with the type of the stack slot as defined
/// in ``m_type.stackItems()`` and may again occupy multiple stack slots.
IRVariable part(std::string const& _slot) const;
private:
/// @returns a vector containing the names of the stack slots of the variable.
std::vector stackSlots() const;
/// @returns a name consisting of the base name appended with an underscore and @æ _suffix,
/// unless @a _suffix is empty, in which case the base name itself is returned.
std::string suffixedName(std::string const& _suffix) const;
std::string m_baseName;
Type const& m_type;
};
}