llvm-project/flang/lib/Lower/RTBuilder.h
River Riddle 1b97cdf885 [mlir][IR][NFC] Move context/location parameters of builtin Type::get methods to the start of the parameter list
This better matches the rest of the infrastructure, is much simpler, and makes it easier to move these types to being declaratively specified.

Differential Revision: https://reviews.llvm.org/D93432
2020-12-17 13:01:36 -08:00

269 lines
9.3 KiB
C++

//===-- RTBuilder.h ---------------------------------------------*- C++ -*-===//
//
// Part of the LLVM Project, under the Apache License v2.0 with LLVM Exceptions.
// See https://llvm.org/LICENSE.txt for license information.
// SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception
//
//===----------------------------------------------------------------------===//
///
/// \file
/// This file defines some C++17 template classes that are used to convert the
/// signatures of plain old C functions into a model that can be used to
/// generate MLIR calls to those functions. This can be used to autogenerate
/// tables at compiler compile-time to call runtime support code.
///
//===----------------------------------------------------------------------===//
#ifndef FORTRAN_LOWER_RTBUILDER_H
#define FORTRAN_LOWER_RTBUILDER_H
#include "flang/Lower/ConvertType.h"
#include "flang/Optimizer/Dialect/FIRType.h"
#include "mlir/IR/BuiltinTypes.h"
#include "mlir/IR/MLIRContext.h"
#include "llvm/ADT/SmallVector.h"
#include <functional>
// List the runtime headers we want to be able to dissect
#include "../../runtime/io-api.h"
namespace Fortran::lower {
using TypeBuilderFunc = mlir::Type (*)(mlir::MLIRContext *);
using FuncTypeBuilderFunc = mlir::FunctionType (*)(mlir::MLIRContext *);
//===----------------------------------------------------------------------===//
// Type builder models
//===----------------------------------------------------------------------===//
/// Return a function that returns the type signature model for the type `T`
/// when provided an MLIRContext*. This allows one to translate C(++) function
/// signatures from runtime header files to MLIR signatures into a static table
/// at compile-time.
///
/// For example, when `T` is `int`, return a function that returns the MLIR
/// standard type `i32` when `sizeof(int)` is 4.
template <typename T>
static constexpr TypeBuilderFunc getModel();
template <>
constexpr TypeBuilderFunc getModel<int>() {
return [](mlir::MLIRContext *context) -> mlir::Type {
return mlir::IntegerType::get(context, 8 * sizeof(int));
};
}
template <>
constexpr TypeBuilderFunc getModel<int &>() {
return [](mlir::MLIRContext *context) -> mlir::Type {
TypeBuilderFunc f{getModel<int>()};
return fir::ReferenceType::get(f(context));
};
}
template <>
constexpr TypeBuilderFunc getModel<Fortran::runtime::io::Iostat>() {
return [](mlir::MLIRContext *context) -> mlir::Type {
return mlir::IntegerType::get(context,
8 * sizeof(Fortran::runtime::io::Iostat));
};
}
template <>
constexpr TypeBuilderFunc getModel<char *>() {
return [](mlir::MLIRContext *context) -> mlir::Type {
return fir::ReferenceType::get(mlir::IntegerType::get(context, 8));
};
}
template <>
constexpr TypeBuilderFunc getModel<const char *>() {
return getModel<char *>();
}
template <>
constexpr TypeBuilderFunc getModel<const char16_t *>() {
return [](mlir::MLIRContext *context) -> mlir::Type {
return fir::ReferenceType::get(mlir::IntegerType::get(context, 16));
};
}
template <>
constexpr TypeBuilderFunc getModel<const char32_t *>() {
return [](mlir::MLIRContext *context) -> mlir::Type {
return fir::ReferenceType::get(mlir::IntegerType::get(context, 32));
};
}
template <>
constexpr TypeBuilderFunc getModel<void **>() {
return [](mlir::MLIRContext *context) -> mlir::Type {
return fir::ReferenceType::get(
fir::PointerType::get(mlir::IntegerType::get(context, 8)));
};
}
template <>
constexpr TypeBuilderFunc getModel<std::int64_t>() {
return [](mlir::MLIRContext *context) -> mlir::Type {
return mlir::IntegerType::get(context, 64);
};
}
template <>
constexpr TypeBuilderFunc getModel<std::int64_t &>() {
return [](mlir::MLIRContext *context) -> mlir::Type {
TypeBuilderFunc f{getModel<std::int64_t>()};
return fir::ReferenceType::get(f(context));
};
}
template <>
constexpr TypeBuilderFunc getModel<std::size_t>() {
return [](mlir::MLIRContext *context) -> mlir::Type {
return mlir::IntegerType::get(context, 8 * sizeof(std::size_t));
};
}
template <>
constexpr TypeBuilderFunc getModel<Fortran::runtime::io::IoStatementState *>() {
return getModel<char *>();
}
template <>
constexpr TypeBuilderFunc getModel<double>() {
return [](mlir::MLIRContext *context) -> mlir::Type {
return mlir::FloatType::getF64(context);
};
}
template <>
constexpr TypeBuilderFunc getModel<double &>() {
return [](mlir::MLIRContext *context) -> mlir::Type {
TypeBuilderFunc f{getModel<double>()};
return fir::ReferenceType::get(f(context));
};
}
template <>
constexpr TypeBuilderFunc getModel<float>() {
return [](mlir::MLIRContext *context) -> mlir::Type {
return mlir::FloatType::getF32(context);
};
}
template <>
constexpr TypeBuilderFunc getModel<float &>() {
return [](mlir::MLIRContext *context) -> mlir::Type {
TypeBuilderFunc f{getModel<float>()};
return fir::ReferenceType::get(f(context));
};
}
template <>
constexpr TypeBuilderFunc getModel<bool>() {
return [](mlir::MLIRContext *context) -> mlir::Type {
return mlir::IntegerType::get(context, 1);
};
}
template <>
constexpr TypeBuilderFunc getModel<bool &>() {
return [](mlir::MLIRContext *context) -> mlir::Type {
TypeBuilderFunc f{getModel<bool>()};
return fir::ReferenceType::get(f(context));
};
}
template <>
constexpr TypeBuilderFunc getModel<const Fortran::runtime::Descriptor &>() {
return [](mlir::MLIRContext *context) -> mlir::Type {
return fir::BoxType::get(mlir::NoneType::get(context));
};
}
template <>
constexpr TypeBuilderFunc getModel<const Fortran::runtime::NamelistGroup &>() {
return [](mlir::MLIRContext *context) -> mlir::Type {
// FIXME: a namelist group must be some well-defined data structure, use a
// tuple as a proxy for the moment
return mlir::TupleType::get(context);
};
}
template <>
constexpr TypeBuilderFunc getModel<void>() {
return [](mlir::MLIRContext *context) -> mlir::Type {
return mlir::NoneType::get(context);
};
}
template <typename...>
struct RuntimeTableKey;
template <typename RT, typename... ATs>
struct RuntimeTableKey<RT(ATs...)> {
static constexpr FuncTypeBuilderFunc getTypeModel() {
return [](mlir::MLIRContext *ctxt) {
TypeBuilderFunc ret = getModel<RT>();
std::array<TypeBuilderFunc, sizeof...(ATs)> args = {getModel<ATs>()...};
mlir::Type retTy = ret(ctxt);
llvm::SmallVector<mlir::Type, sizeof...(ATs)> argTys;
for (auto f : args)
argTys.push_back(f(ctxt));
return mlir::FunctionType::get(ctxt, argTys, {retTy});
};
}
};
//===----------------------------------------------------------------------===//
// Runtime table building (constexpr folded)
//===----------------------------------------------------------------------===//
template <char... Cs>
using RuntimeIdentifier = std::integer_sequence<char, Cs...>;
namespace details {
template <typename T, T... As, T... Bs>
static constexpr std::integer_sequence<T, As..., Bs...>
concat(std::integer_sequence<T, As...>, std::integer_sequence<T, Bs...>) {
return {};
}
template <typename T, T... As, T... Bs, typename... Cs>
static constexpr auto concat(std::integer_sequence<T, As...>,
std::integer_sequence<T, Bs...>, Cs...) {
return concat(std::integer_sequence<T, As..., Bs...>{}, Cs{}...);
}
template <typename T>
static constexpr std::integer_sequence<T> concat(std::integer_sequence<T>) {
return {};
}
template <typename T, T a>
static constexpr auto filterZero(std::integer_sequence<T, a>) {
if constexpr (a != 0) {
return std::integer_sequence<T, a>{};
} else {
return std::integer_sequence<T>{};
}
}
template <typename T, T... b>
static constexpr auto filter(std::integer_sequence<T, b...>) {
if constexpr (sizeof...(b) > 0) {
return details::concat(filterZero(std::integer_sequence<T, b>{})...);
} else {
return std::integer_sequence<T>{};
}
}
} // namespace details
template <typename...>
struct RuntimeTableEntry;
template <typename KT, char... Cs>
struct RuntimeTableEntry<RuntimeTableKey<KT>, RuntimeIdentifier<Cs...>> {
static constexpr FuncTypeBuilderFunc getTypeModel() {
return RuntimeTableKey<KT>::getTypeModel();
}
static constexpr const char name[sizeof...(Cs) + 1] = {Cs..., '\0'};
};
#undef E
#define E(L, I) (I < sizeof(L) / sizeof(*L) ? L[I] : 0)
#define QuoteKey(X) #X
#define MacroExpandKey(X) \
E(X, 0), E(X, 1), E(X, 2), E(X, 3), E(X, 4), E(X, 5), E(X, 6), E(X, 7), \
E(X, 8), E(X, 9), E(X, 10), E(X, 11), E(X, 12), E(X, 13), E(X, 14), \
E(X, 15), E(X, 16), E(X, 17), E(X, 18), E(X, 19), E(X, 20), E(X, 21), \
E(X, 22), E(X, 23), E(X, 24), E(X, 25), E(X, 26), E(X, 27), E(X, 28), \
E(X, 29), E(X, 30), E(X, 31), E(X, 32), E(X, 33), E(X, 34), E(X, 35), \
E(X, 36), E(X, 37), E(X, 38), E(X, 39), E(X, 40), E(X, 41), E(X, 42), \
E(X, 43), E(X, 44), E(X, 45), E(X, 46), E(X, 47), E(X, 48), E(X, 49)
#define ExpandKey(X) MacroExpandKey(QuoteKey(X))
#define FullSeq(X) std::integer_sequence<char, ExpandKey(X)>
#define AsSequence(X) decltype(Fortran::lower::details::filter(FullSeq(X){}))
#define mkKey(X) \
Fortran::lower::RuntimeTableEntry< \
Fortran::lower::RuntimeTableKey<decltype(X)>, AsSequence(X)>
} // namespace Fortran::lower
#endif // FORTRAN_LOWER_RTBUILDER_H