include/ftl/enum.h - platform/frameworks/native - Gitiles

 /*
  * Copyright 2021 The Android Open Source Project
  *
  * Licensed under the Apache License, Version 2.0 (the "License");
  * you may not use this file except in compliance with the License.
  * You may obtain a copy of the License at
  *
  *      http://www.apache.org/licenses/LICENSE-2.0
  *
  * Unless required by applicable law or agreed to in writing, software
  * distributed under the License is distributed on an "AS IS" BASIS,
  * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
  * See the License for the specific language governing permissions and
  * limitations under the License.
  */

 #pragma once

 #include <cstddef>
 #include <limits>
 #include <optional>
 #include <string_view>
 #include <type_traits>
 #include <utility>

 #include <ftl/string.h>

 // Returns the name of enumerator E::V (i.e. "V") as std::optional<std::string_view> by parsing the
 // compiler-generated string literal for the signature of this function. The function is defined in
 // the global namespace with a short name and inferred return type to reduce bloat in the read-only
 // data segment.
 template <typename E, E V>
 constexpr auto ftl_enum() {
   static_assert(std::is_enum_v<E>);

   using R = std::optional<std::string_view>;
   using namespace std::literals;

   // The "pretty" signature has the following format:
   //
   //   auto ftl_enum() [E = android::test::Enum, V = android::test::Enum::kValue]
   //
   std::string_view view = __PRETTY_FUNCTION__;
   const auto template_begin = view.rfind('[');
   const auto template_end = view.rfind(']');
   if (template_begin == view.npos || template_end == view.npos) return R{};

   // Extract the template parameters without the enclosing brackets. Example (cont'd):
   //
   //   E = android::test::Enum, V = android::test::Enum::kValue
   //
   view = view.substr(template_begin + 1, template_end - template_begin - 1);
   const auto value_begin = view.rfind("V = "sv);
   if (value_begin == view.npos) return R{};

   // Example (cont'd):
   //
   //   V = android::test::Enum::kValue
   //
   view = view.substr(value_begin);
   const auto name_begin = view.rfind("::"sv);
   if (name_begin == view.npos) return R{};

   // Chop off the leading "::".
   const auto name = view.substr(name_begin + 2);

   // A value that is not enumerated has the format "Enum)42".
   return name.find(')') == view.npos ? R{name} : R{};
 }

 namespace android::ftl {

 // Trait for determining whether a type is specifically a scoped enum or not. By definition, a
 // scoped enum is one that is not implicitly convertible to its underlying type.
 //
 // TODO: Replace with std::is_scoped_enum in C++23.
 //
 template <typename T, bool = std::is_enum_v<T>>
 struct is_scoped_enum : std::false_type {};

 template <typename T>
 struct is_scoped_enum<T, true> : std::negation<std::is_convertible<T, std::underlying_type_t<T>>> {
 };

 template <typename T>
 inline constexpr bool is_scoped_enum_v = is_scoped_enum<T>::value;

 // Shorthand for casting an enumerator to its integral value.
 //
 // TODO: Replace with std::to_underlying in C++23.
 //
 //   enum class E { A, B, C };
 //   static_assert(ftl::to_underlying(E::B) == 1);
 //
 template <typename E>
 constexpr auto to_underlying(E v) {
   return static_cast<std::underlying_type_t<E>>(v);
 }

 // Traits for retrieving an enum's range. An enum specifies its range by defining enumerators named
 // ftl_first and ftl_last. If omitted, ftl_first defaults to 0, whereas ftl_last defaults to N - 1
 // where N is the bit width of the underlying type, but only if that type is unsigned, assuming the
 // enumerators are flags. Also, note that unscoped enums must define both bounds, as casting out-of-
 // range values results in undefined behavior if the underlying type is not fixed.
 //
 //   enum class E { A, B, C, F = 5, ftl_last = F };
 //
 //   static_assert(ftl::enum_begin_v<E> == E::A);
 //   static_assert(ftl::enum_last_v<E> == E::F);
 //   static_assert(ftl::enum_size_v<E> == 6);
 //
 //   enum class F : std::uint16_t { X = 0b1, Y = 0b10, Z = 0b100 };
 //
 //   static_assert(ftl::enum_begin_v<F> == F{0});
 //   static_assert(ftl::enum_last_v<F> == F{15});
 //   static_assert(ftl::enum_size_v<F> == 16);
 //
 template <typename E, typename = void>
 struct enum_begin {
   static_assert(is_scoped_enum_v<E>, "Missing ftl_first enumerator");
   static constexpr E value{0};
 };

 template <typename E>
 struct enum_begin<E, std::void_t<decltype(E::ftl_first)>> {
   static constexpr E value = E::ftl_first;
 };

 template <typename E>
 inline constexpr E enum_begin_v = enum_begin<E>::value;

 template <typename E, typename = void>
 struct enum_end {
   using U = std::underlying_type_t<E>;
   static_assert(is_scoped_enum_v<E> && std::is_unsigned_v<U>, "Missing ftl_last enumerator");

   static constexpr E value{std::numeric_limits<U>::digits};
 };

 template <typename E>
 struct enum_end<E, std::void_t<decltype(E::ftl_last)>> {
   static constexpr E value = E{to_underlying(E::ftl_last) + 1};
 };

 template <typename E>
 inline constexpr E enum_end_v = enum_end<E>::value;

 template <typename E>
 inline constexpr E enum_last_v = E{to_underlying(enum_end_v<E>) - 1};

 template <typename E>
 struct enum_size {
   static constexpr auto kBegin = to_underlying(enum_begin_v<E>);
   static constexpr auto kEnd = to_underlying(enum_end_v<E>);
   static_assert(kBegin < kEnd, "Invalid range");

   static constexpr std::size_t value = kEnd - kBegin;
   static_assert(value <= 64, "Excessive range size");
 };

 template <typename E>
 inline constexpr std::size_t enum_size_v = enum_size<E>::value;

 namespace details {

 template <auto V>
 struct Identity {
   static constexpr auto value = V;
 };

 template <typename E>
 using make_enum_sequence = std::make_integer_sequence<std::underlying_type_t<E>, enum_size_v<E>>;

 template <typename E, template <E> class = Identity, typename = make_enum_sequence<E>>
 struct EnumRange;

 template <typename E, template <E> class F, typename T, T... Vs>
 struct EnumRange<E, F, std::integer_sequence<T, Vs...>> {
   static constexpr auto kBegin = to_underlying(enum_begin_v<E>);
   static constexpr auto kSize = enum_size_v<E>;

   using R = decltype(F<E{}>::value);
   const R values[kSize] = {F<static_cast<E>(Vs + kBegin)>::value...};

   constexpr const auto* begin() const { return values; }
   constexpr const auto* end() const { return values + kSize; }
 };

 template <auto V>
 struct EnumName {
   static constexpr auto value = ftl_enum<decltype(V), V>();
 };

 template <auto I>
 struct FlagName {
   using E = decltype(I);
   using U = std::underlying_type_t<E>;

   static constexpr E V{U{1} << to_underlying(I)};
   static constexpr auto value = ftl_enum<E, V>();
 };

 }  // namespace details

 // Returns an iterable over the range of an enum.
 //
 //   enum class E { A, B, C, F = 5, ftl_last = F };
 //
 //   std::string string;
 //   for (E v : ftl::enum_range<E>()) {
 //     string += ftl::enum_name(v).value_or("?");
 //   }
 //
 //   assert(string == "ABC??F");
 //
 template <typename E>
 constexpr auto enum_range() {
   return details::EnumRange<E>{};
 }

 // Returns a stringified enumerator at compile time.
 //
 //   enum class E { A, B, C };
 //   static_assert(ftl::enum_name<E::B>() == "B");
 //
 template <auto V>
 constexpr std::string_view enum_name() {
   constexpr auto kName = ftl_enum<decltype(V), V>();
   static_assert(kName, "Unknown enumerator");
   return *kName;
 }

 // Returns a stringified enumerator, possibly at compile time.
 //
 //   enum class E { A, B, C, F = 5, ftl_last = F };
 //
 //   static_assert(ftl::enum_name(E::C).value_or("?") == "C");
 //   static_assert(ftl::enum_name(E{3}).value_or("?") == "?");
 //
 template <typename E>
 constexpr std::optional<std::string_view> enum_name(E v) {
   const auto value = to_underlying(v);

   constexpr auto kBegin = to_underlying(enum_begin_v<E>);
   constexpr auto kLast = to_underlying(enum_last_v<E>);
   if (value < kBegin || value > kLast) return {};

   constexpr auto kRange = details::EnumRange<E, details::EnumName>{};
   return kRange.values[value - kBegin];
 }

 // Returns a stringified flag enumerator, possibly at compile time.
 //
 //   enum class F : std::uint16_t { X = 0b1, Y = 0b10, Z = 0b100 };
 //
 //   static_assert(ftl::flag_name(F::Z).value_or("?") == "Z");
 //   static_assert(ftl::flag_name(F{0b111}).value_or("?") == "?");
 //
 template <typename E>
 constexpr std::optional<std::string_view> flag_name(E v) {
   const auto value = to_underlying(v);

   // TODO: Replace with std::popcount and std::countr_zero in C++20.
   if (__builtin_popcountl(value) != 1) return {};

   constexpr auto kRange = details::EnumRange<E, details::FlagName>{};
   return kRange.values[__builtin_ctzl(value)];
 }

 // Returns a stringified enumerator, or its integral value if not named.
 //
 //   enum class E { A, B, C, F = 5, ftl_last = F };
 //
 //   assert(ftl::enum_string(E::C) == "C");
 //   assert(ftl::enum_string(E{3}) == "3");
 //
 template <typename E>
 inline std::string enum_string(E v) {
   if (const auto name = enum_name(v)) {
     return std::string(*name);
   }
   return to_string(to_underlying(v));
 }

 // Returns a stringified flag enumerator, or its integral value if not named.
 //
 //   enum class F : std::uint16_t { X = 0b1, Y = 0b10, Z = 0b100 };
 //
 //   assert(ftl::flag_string(F::Z) == "Z");
 //   assert(ftl::flag_string(F{7}) == "0b111");
 //
 template <typename E>
 inline std::string flag_string(E v) {
   if (const auto name = flag_name(v)) {
     return std::string(*name);
   }
   constexpr auto radix = sizeof(E) == 1 ? Radix::kBin : Radix::kHex;
   return to_string(to_underlying(v), radix);
 }

 }  // namespace android::ftl
	/*
	* Copyright 2021 The Android Open Source Project
	*
	* Licensed under the Apache License, Version 2.0 (the "License");
	* you may not use this file except in compliance with the License.
	* You may obtain a copy of the License at
	*
	* http://www.apache.org/licenses/LICENSE-2.0
	*
	* Unless required by applicable law or agreed to in writing, software
	* distributed under the License is distributed on an "AS IS" BASIS,
	* WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
	* See the License for the specific language governing permissions and
	* limitations under the License.
	*/

	#pragma once

	#include <cstddef>
	#include <limits>
	#include <optional>
	#include <string_view>
	#include <type_traits>
	#include <utility>

	#include <ftl/string.h>

	// Returns the name of enumerator E::V (i.e. "V") as std::optional<std::string_view> by parsing the
	// compiler-generated string literal for the signature of this function. The function is defined in
	// the global namespace with a short name and inferred return type to reduce bloat in the read-only
	// data segment.
	template <typename E, E V>
	constexpr auto ftl_enum() {
	static_assert(std::is_enum_v<E>);

	using R = std::optional<std::string_view>;
	using namespace std::literals;

	// The "pretty" signature has the following format:
	//
	// auto ftl_enum() [E = android::test::Enum, V = android::test::Enum::kValue]
	//
	std::string_view view = __PRETTY_FUNCTION__;
	const auto template_begin = view.rfind('[');
	const auto template_end = view.rfind(']');
	if (template_begin == view.npos \|\| template_end == view.npos) return R{};

	// Extract the template parameters without the enclosing brackets. Example (cont'd):
	//
	// E = android::test::Enum, V = android::test::Enum::kValue
	//
	view = view.substr(template_begin + 1, template_end - template_begin - 1);
	const auto value_begin = view.rfind("V = "sv);
	if (value_begin == view.npos) return R{};

	// Example (cont'd):
	//
	// V = android::test::Enum::kValue
	//
	view = view.substr(value_begin);
	const auto name_begin = view.rfind("::"sv);
	if (name_begin == view.npos) return R{};

	// Chop off the leading "::".
	const auto name = view.substr(name_begin + 2);

	// A value that is not enumerated has the format "Enum)42".
	return name.find(')') == view.npos ? R{name} : R{};
	}

	namespace android::ftl {

	// Trait for determining whether a type is specifically a scoped enum or not. By definition, a
	// scoped enum is one that is not implicitly convertible to its underlying type.
	//
	// TODO: Replace with std::is_scoped_enum in C++23.
	//
	template <typename T, bool = std::is_enum_v<T>>
	struct is_scoped_enum : std::false_type {};

	template <typename T>
	struct is_scoped_enum<T, true> : std::negation<std::is_convertible<T, std::underlying_type_t<T>>> {
	};

	template <typename T>
	inline constexpr bool is_scoped_enum_v = is_scoped_enum<T>::value;

	// Shorthand for casting an enumerator to its integral value.
	//
	// TODO: Replace with std::to_underlying in C++23.
	//
	// enum class E { A, B, C };
	// static_assert(ftl::to_underlying(E::B) == 1);
	//
	template <typename E>
	constexpr auto to_underlying(E v) {
	return static_cast<std::underlying_type_t<E>>(v);
	}

	// Traits for retrieving an enum's range. An enum specifies its range by defining enumerators named
	// ftl_first and ftl_last. If omitted, ftl_first defaults to 0, whereas ftl_last defaults to N - 1
	// where N is the bit width of the underlying type, but only if that type is unsigned, assuming the
	// enumerators are flags. Also, note that unscoped enums must define both bounds, as casting out-of-
	// range values results in undefined behavior if the underlying type is not fixed.
	//
	// enum class E { A, B, C, F = 5, ftl_last = F };
	//
	// static_assert(ftl::enum_begin_v<E> == E::A);
	// static_assert(ftl::enum_last_v<E> == E::F);
	// static_assert(ftl::enum_size_v<E> == 6);
	//
	// enum class F : std::uint16_t { X = 0b1, Y = 0b10, Z = 0b100 };
	//
	// static_assert(ftl::enum_begin_v<F> == F{0});
	// static_assert(ftl::enum_last_v<F> == F{15});
	// static_assert(ftl::enum_size_v<F> == 16);
	//
	template <typename E, typename = void>
	struct enum_begin {
	static_assert(is_scoped_enum_v<E>, "Missing ftl_first enumerator");
	static constexpr E value{0};
	};

	template <typename E>
	struct enum_begin<E, std::void_t<decltype(E::ftl_first)>> {
	static constexpr E value = E::ftl_first;
	};

	template <typename E>
	inline constexpr E enum_begin_v = enum_begin<E>::value;

	template <typename E, typename = void>
	struct enum_end {
	using U = std::underlying_type_t<E>;
	static_assert(is_scoped_enum_v<E> && std::is_unsigned_v<U>, "Missing ftl_last enumerator");

	static constexpr E value{std::numeric_limits<U>::digits};
	};

	template <typename E>
	struct enum_end<E, std::void_t<decltype(E::ftl_last)>> {
	static constexpr E value = E{to_underlying(E::ftl_last) + 1};
	};

	template <typename E>
	inline constexpr E enum_end_v = enum_end<E>::value;

	template <typename E>
	inline constexpr E enum_last_v = E{to_underlying(enum_end_v<E>) - 1};

	template <typename E>
	struct enum_size {
	static constexpr auto kBegin = to_underlying(enum_begin_v<E>);
	static constexpr auto kEnd = to_underlying(enum_end_v<E>);
	static_assert(kBegin < kEnd, "Invalid range");

	static constexpr std::size_t value = kEnd - kBegin;
	static_assert(value <= 64, "Excessive range size");
	};

	template <typename E>
	inline constexpr std::size_t enum_size_v = enum_size<E>::value;

	namespace details {

	template <auto V>
	struct Identity {
	static constexpr auto value = V;
	};

	template <typename E>
	using make_enum_sequence = std::make_integer_sequence<std::underlying_type_t<E>, enum_size_v<E>>;

	template <typename E, template <E> class = Identity, typename = make_enum_sequence<E>>
	struct EnumRange;

	template <typename E, template <E> class F, typename T, T... Vs>
	struct EnumRange<E, F, std::integer_sequence<T, Vs...>> {
	static constexpr auto kBegin = to_underlying(enum_begin_v<E>);
	static constexpr auto kSize = enum_size_v<E>;

	using R = decltype(F<E{}>::value);
	const R values[kSize] = {F<static_cast<E>(Vs + kBegin)>::value...};

	constexpr const auto* begin() const { return values; }
	constexpr const auto* end() const { return values + kSize; }
	};

	template <auto V>
	struct EnumName {
	static constexpr auto value = ftl_enum<decltype(V), V>();
	};

	template <auto I>
	struct FlagName {
	using E = decltype(I);
	using U = std::underlying_type_t<E>;

	static constexpr E V{U{1} << to_underlying(I)};
	static constexpr auto value = ftl_enum<E, V>();
	};

	} // namespace details

	// Returns an iterable over the range of an enum.
	//
	// enum class E { A, B, C, F = 5, ftl_last = F };
	//
	// std::string string;
	// for (E v : ftl::enum_range<E>()) {
	// string += ftl::enum_name(v).value_or("?");
	// }
	//
	// assert(string == "ABC??F");
	//
	template <typename E>
	constexpr auto enum_range() {
	return details::EnumRange<E>{};
	}

	// Returns a stringified enumerator at compile time.
	//
	// enum class E { A, B, C };
	// static_assert(ftl::enum_name<E::B>() == "B");
	//
	template <auto V>
	constexpr std::string_view enum_name() {
	constexpr auto kName = ftl_enum<decltype(V), V>();
	static_assert(kName, "Unknown enumerator");
	return *kName;
	}

	// Returns a stringified enumerator, possibly at compile time.
	//
	// enum class E { A, B, C, F = 5, ftl_last = F };
	//
	// static_assert(ftl::enum_name(E::C).value_or("?") == "C");
	// static_assert(ftl::enum_name(E{3}).value_or("?") == "?");
	//
	template <typename E>
	constexpr std::optional<std::string_view> enum_name(E v) {
	const auto value = to_underlying(v);

	constexpr auto kBegin = to_underlying(enum_begin_v<E>);
	constexpr auto kLast = to_underlying(enum_last_v<E>);
	if (value < kBegin \|\| value > kLast) return {};

	constexpr auto kRange = details::EnumRange<E, details::EnumName>{};
	return kRange.values[value - kBegin];
	}

	// Returns a stringified flag enumerator, possibly at compile time.
	//
	// enum class F : std::uint16_t { X = 0b1, Y = 0b10, Z = 0b100 };
	//
	// static_assert(ftl::flag_name(F::Z).value_or("?") == "Z");
	// static_assert(ftl::flag_name(F{0b111}).value_or("?") == "?");
	//
	template <typename E>
	constexpr std::optional<std::string_view> flag_name(E v) {
	const auto value = to_underlying(v);

	// TODO: Replace with std::popcount and std::countr_zero in C++20.
	if (__builtin_popcountl(value) != 1) return {};

	constexpr auto kRange = details::EnumRange<E, details::FlagName>{};
	return kRange.values[__builtin_ctzl(value)];
	}

	// Returns a stringified enumerator, or its integral value if not named.
	//
	// enum class E { A, B, C, F = 5, ftl_last = F };
	//
	// assert(ftl::enum_string(E::C) == "C");
	// assert(ftl::enum_string(E{3}) == "3");
	//
	template <typename E>
	inline std::string enum_string(E v) {
	if (const auto name = enum_name(v)) {
	return std::string(*name);
	}
	return to_string(to_underlying(v));
	}

	// Returns a stringified flag enumerator, or its integral value if not named.
	//
	// enum class F : std::uint16_t { X = 0b1, Y = 0b10, Z = 0b100 };
	//
	// assert(ftl::flag_string(F::Z) == "Z");
	// assert(ftl::flag_string(F{7}) == "0b111");
	//
	template <typename E>
	inline std::string flag_string(E v) {
	if (const auto name = flag_name(v)) {
	return std::string(*name);
	}
	constexpr auto radix = sizeof(E) == 1 ? Radix::kBin : Radix::kHex;
	return to_string(to_underlying(v), radix);
	}

	} // namespace android::ftl