include/flang/Common/idioms.h - llvm-project/flang - Git at Google

 //===-- include/flang/Common/idioms.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
 //
 //===----------------------------------------------------------------------===//

 #ifndef FORTRAN_COMMON_IDIOMS_H_
 #define FORTRAN_COMMON_IDIOMS_H_

 // Defines anything that might ever be useful in more than one source file
 // or that is too weird or too specific to the host C++ compiler to be
 // exposed elsewhere.

 #ifndef __cplusplus
 #error this is a C++ program
 #endif
 #if __cplusplus < 201703L
 #error this is a C++17 program
 #endif
 #if !__clang__ && defined __GNUC__ && __GNUC__ < 7
 #error g++ >= 7.2 is required
 #endif

 #include "llvm/Support/Compiler.h"
 #include <functional>
 #include <list>
 #include <memory>
 #include <optional>
 #include <string>
 #include <tuple>
 #include <type_traits>
 #include <variant>

 #if __GNUC__ == 7
 // Avoid a deduction bug in GNU 7.x headers by forcing the answer.
 namespace std {
 template <typename A>
 struct is_trivially_copy_constructible<list<A>> : false_type {};
 template <typename A>
 struct is_trivially_copy_constructible<optional<list<A>>> : false_type {};
 } // namespace std
 #endif

 // enable "this is a std::string"s with the 's' suffix
 using namespace std::literals::string_literals;

 namespace Fortran::common {

 // Helper templates for combining a list of lambdas into an anonymous
 // struct for use with std::visit() on a std::variant<> sum type.
 // E.g.: std::visit(visitors{
 //         [&](const firstType &x) { ... },
 //         [&](const secondType &x) { ... },
 //         ...
 //         [&](const auto &catchAll) { ... }}, variantObject);

 template <typename... LAMBDAS> struct visitors : LAMBDAS... {
   using LAMBDAS::operator()...;
 };

 template <typename... LAMBDAS> visitors(LAMBDAS... x) -> visitors<LAMBDAS...>;

 // Calls std::fprintf(stderr, ...), then abort().
 [[noreturn]] void die(const char *, ...);

 #define DIE(x) Fortran::common::die(x " at " __FILE__ "(%d)", __LINE__)

 // For switch statement default: labels.
 #define CRASH_NO_CASE DIE("no case")

 // clang-format off
 // For switch statements whose cases have return statements for
 // all possibilities.  Clang emits warnings if the default: is
 // present, gcc emits warnings if it is absent.
 #if __clang__
 #define SWITCH_COVERS_ALL_CASES
 #else
 #define SWITCH_COVERS_ALL_CASES default: CRASH_NO_CASE;
 #endif
 // clang-format on

 // For cheap assertions that should be applied in production.
 // To disable, compile with '-DCHECK=(void)'
 #ifndef CHECK
 #define CHECK(x) ((x) || (DIE("CHECK(" #x ") failed"), false))
 #endif

 // User-defined type traits that default to false:
 // Invoke CLASS_TRAIT(traitName) to define a trait, then put
 //   using traitName = std::true_type;  (or false_type)
 // into the appropriate class definitions.  You can then use
 //   typename std::enable_if_t<traitName<...>, ...>
 // in template specialization definitions.
 #define CLASS_TRAIT(T) \
   namespace class_trait_ns_##T { \
     template <typename A> std::true_type test(typename A::T *); \
     template <typename A> std::false_type test(...); \
     template <typename A> \
     constexpr bool has_trait{decltype(test<A>(nullptr))::value}; \
     template <typename A> constexpr bool trait_value() { \
       if constexpr (has_trait<A>) { \
         using U = typename A::T; \
         return U::value; \
       } else { \
         return false; \
       } \
     } \
   } \
   template <typename A> constexpr bool T{class_trait_ns_##T::trait_value<A>()};

 // Define enum class NAME with the given enumerators, a static
 // function EnumToString() that maps enumerators to std::string,
 // and a constant NAME_enumSize that captures the number of items
 // in the enum class.

 std::string EnumIndexToString(int index, const char *names);

 template <typename A> struct ListItemCount {
   constexpr ListItemCount(std::initializer_list<A> list) : value{list.size()} {}
   const std::size_t value;
 };

 #define ENUM_CLASS(NAME, ...) \
   enum class NAME { __VA_ARGS__ }; \
   LLVM_ATTRIBUTE_UNUSED static constexpr std::size_t NAME##_enumSize{[] { \
     enum { __VA_ARGS__ }; \
     return Fortran::common::ListItemCount{__VA_ARGS__}.value; \
   }()}; \
   LLVM_ATTRIBUTE_UNUSED static inline std::string EnumToString(NAME e) { \
     return Fortran::common::EnumIndexToString( \
         static_cast<int>(e), #__VA_ARGS__); \
   }

 // Check that a pointer is non-null and dereference it
 #define DEREF(p) Fortran::common::Deref(p, __FILE__, __LINE__)

 template <typename T> constexpr T &Deref(T *p, const char *file, int line) {
   if (!p) {
     Fortran::common::die("nullptr dereference at %s(%d)", file, line);
   }
   return *p;
 }

 template <typename T>
 constexpr T &Deref(const std::unique_ptr<T> &p, const char *file, int line) {
   if (!p) {
     Fortran::common::die("nullptr dereference at %s(%d)", file, line);
   }
   return *p;
 }

 // Given a const reference to a value, return a copy of the value.
 template <typename A> A Clone(const A &x) { return x; }

 // C++ does a weird and dangerous thing when deducing template type parameters
 // from function arguments: lvalue references are allowed to match rvalue
 // reference arguments.  Template function declarations like
 //   template<typename A> int foo(A &&);
 // need to be protected against this C++ language feature when functions
 // may modify such arguments.  Use these type functions to invoke SFINAE
 // on a result type via
 //   template<typename A> common::IfNoLvalue<int, A> foo(A &&);
 // or, for constructors,
 //   template<typename A, typename = common::NoLvalue<A>> int foo(A &&);
 // This works with parameter packs too.
 template <typename A, typename... B>
 using IfNoLvalue = std::enable_if_t<(... && !std::is_lvalue_reference_v<B>), A>;
 template <typename... RVREF> using NoLvalue = IfNoLvalue<void, RVREF...>;
 } // namespace Fortran::common
 #endif // FORTRAN_COMMON_IDIOMS_H_
	//===-- include/flang/Common/idioms.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
	//
	//===----------------------------------------------------------------------===//

	#ifndef FORTRAN_COMMON_IDIOMS_H_
	#define FORTRAN_COMMON_IDIOMS_H_

	// Defines anything that might ever be useful in more than one source file
	// or that is too weird or too specific to the host C++ compiler to be
	// exposed elsewhere.

	#ifndef __cplusplus
	#error this is a C++ program
	#endif
	#if __cplusplus < 201703L
	#error this is a C++17 program
	#endif
	#if !__clang__ && defined __GNUC__ && __GNUC__ < 7
	#error g++ >= 7.2 is required
	#endif

	#include "llvm/Support/Compiler.h"
	#include <functional>
	#include <list>
	#include <memory>
	#include <optional>
	#include <string>
	#include <tuple>
	#include <type_traits>
	#include <variant>

	#if __GNUC__ == 7
	// Avoid a deduction bug in GNU 7.x headers by forcing the answer.
	namespace std {
	template <typename A>
	struct is_trivially_copy_constructible<list<A>> : false_type {};
	template <typename A>
	struct is_trivially_copy_constructible<optional<list<A>>> : false_type {};
	} // namespace std
	#endif

	// enable "this is a std::string"s with the 's' suffix
	using namespace std::literals::string_literals;

	namespace Fortran::common {

	// Helper templates for combining a list of lambdas into an anonymous
	// struct for use with std::visit() on a std::variant<> sum type.
	// E.g.: std::visit(visitors{
	// [&](const firstType &x) { ... },
	// [&](const secondType &x) { ... },
	// ...
	// [&](const auto &catchAll) { ... }}, variantObject);

	template <typename... LAMBDAS> struct visitors : LAMBDAS... {
	using LAMBDAS::operator()...;
	};

	template <typename... LAMBDAS> visitors(LAMBDAS... x) -> visitors<LAMBDAS...>;

	// Calls std::fprintf(stderr, ...), then abort().
	[[noreturn]] void die(const char *, ...);

	#define DIE(x) Fortran::common::die(x " at " __FILE__ "(%d)", __LINE__)

	// For switch statement default: labels.
	#define CRASH_NO_CASE DIE("no case")

	// clang-format off
	// For switch statements whose cases have return statements for
	// all possibilities. Clang emits warnings if the default: is
	// present, gcc emits warnings if it is absent.
	#if __clang__
	#define SWITCH_COVERS_ALL_CASES
	#else
	#define SWITCH_COVERS_ALL_CASES default: CRASH_NO_CASE;
	#endif
	// clang-format on

	// For cheap assertions that should be applied in production.
	// To disable, compile with '-DCHECK=(void)'
	#ifndef CHECK
	#define CHECK(x) ((x) \|\| (DIE("CHECK(" #x ") failed"), false))
	#endif

	// User-defined type traits that default to false:
	// Invoke CLASS_TRAIT(traitName) to define a trait, then put
	// using traitName = std::true_type; (or false_type)
	// into the appropriate class definitions. You can then use
	// typename std::enable_if_t<traitName<...>, ...>
	// in template specialization definitions.
	#define CLASS_TRAIT(T) \
	namespace class_trait_ns_##T { \
	template <typename A> std::true_type test(typename A::T *); \
	template <typename A> std::false_type test(...); \
	template <typename A> \
	constexpr bool has_trait{decltype(test<A>(nullptr))::value}; \
	template <typename A> constexpr bool trait_value() { \
	if constexpr (has_trait<A>) { \
	using U = typename A::T; \
	return U::value; \
	} else { \
	return false; \
	} \
	} \
	} \
	template <typename A> constexpr bool T{class_trait_ns_##T::trait_value<A>()};

	// Define enum class NAME with the given enumerators, a static
	// function EnumToString() that maps enumerators to std::string,
	// and a constant NAME_enumSize that captures the number of items
	// in the enum class.

	std::string EnumIndexToString(int index, const char *names);

	template <typename A> struct ListItemCount {
	constexpr ListItemCount(std::initializer_list<A> list) : value{list.size()} {}
	const std::size_t value;
	};

	#define ENUM_CLASS(NAME, ...) \
	enum class NAME { __VA_ARGS__ }; \
	LLVM_ATTRIBUTE_UNUSED static constexpr std::size_t NAME##_enumSize{[] { \
	enum { __VA_ARGS__ }; \
	return Fortran::common::ListItemCount{__VA_ARGS__}.value; \
	}()}; \
	LLVM_ATTRIBUTE_UNUSED static inline std::string EnumToString(NAME e) { \
	return Fortran::common::EnumIndexToString( \
	static_cast<int>(e), #__VA_ARGS__); \
	}

	// Check that a pointer is non-null and dereference it
	#define DEREF(p) Fortran::common::Deref(p, __FILE__, __LINE__)

	template <typename T> constexpr T &Deref(T p, const char file, int line) {
	if (!p) {
	Fortran::common::die("nullptr dereference at %s(%d)", file, line);
	}
	return *p;
	}

	template <typename T>
	constexpr T &Deref(const std::unique_ptr<T> &p, const char *file, int line) {
	if (!p) {
	Fortran::common::die("nullptr dereference at %s(%d)", file, line);
	}
	return *p;
	}

	// Given a const reference to a value, return a copy of the value.
	template <typename A> A Clone(const A &x) { return x; }

	// C++ does a weird and dangerous thing when deducing template type parameters
	// from function arguments: lvalue references are allowed to match rvalue
	// reference arguments. Template function declarations like
	// template<typename A> int foo(A &&);
	// need to be protected against this C++ language feature when functions
	// may modify such arguments. Use these type functions to invoke SFINAE
	// on a result type via
	// template<typename A> common::IfNoLvalue<int, A> foo(A &&);
	// or, for constructors,
	// template<typename A, typename = common::NoLvalue<A>> int foo(A &&);
	// This works with parameter packs too.
	template <typename A, typename... B>
	using IfNoLvalue = std::enable_if_t<(... && !std::is_lvalue_reference_v<B>), A>;
	template <typename... RVREF> using NoLvalue = IfNoLvalue<void, RVREF...>;
	} // namespace Fortran::common
	#endif // FORTRAN_COMMON_IDIOMS_H_