include/ftl/small_map.h - android_frameworks_native - Gitiles

 /*
  * Copyright 2020 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 <ftl/initializer_list.h>
 #include <ftl/small_vector.h>

 #include <functional>
 #include <optional>
 #include <type_traits>
 #include <utility>

 namespace android::ftl {

 // Associative container with unique, unordered keys. Unlike std::unordered_map, key-value pairs are
 // stored in contiguous storage for cache efficiency. The map is allocated statically until its size
 // exceeds N, at which point mappings are relocated to dynamic memory.
 //
 // SmallMap<K, V, 0> unconditionally allocates on the heap.
 //
 // Example usage:
 //
 //   ftl::SmallMap<int, std::string, 3> map;
 //   assert(map.empty());
 //   assert(!map.dynamic());
 //
 //   map = ftl::init::map<int, std::string>(123, "abc")(-1)(42, 3u, '?');
 //   assert(map.size() == 3u);
 //   assert(!map.dynamic());
 //
 //   assert(map.contains(123));
 //   assert(map.find(42, [](const std::string& s) { return s.size(); }) == 3u);
 //
 //   const auto opt = map.find(-1);
 //   assert(opt);
 //
 //   std::string& ref = *opt;
 //   assert(ref.empty());
 //   ref = "xyz";
 //
 //   assert(map == SmallMap(ftl::init::map(-1, "xyz")(42, "???")(123, "abc")));
 //
 template <typename K, typename V, std::size_t N>
 class SmallMap final {
   using Map = SmallVector<std::pair<const K, V>, N>;

  public:
   using key_type = K;
   using mapped_type = V;

   using value_type = typename Map::value_type;
   using size_type = typename Map::size_type;
   using difference_type = typename Map::difference_type;

   using reference = typename Map::reference;
   using iterator = typename Map::iterator;

   using const_reference = typename Map::const_reference;
   using const_iterator = typename Map::const_iterator;

   // Creates an empty map.
   SmallMap() = default;

   // Constructs at most N key-value pairs in place by forwarding per-pair constructor arguments.
   // The template arguments K, V, and N are inferred using the deduction guide defined below.
   // The syntax for listing pairs is as follows:
   //
   //   ftl::SmallMap map = ftl::init::map<int, std::string>(123, "abc")(-1)(42, 3u, '?');
   //
   //   static_assert(std::is_same_v<decltype(map), ftl::SmallMap<int, std::string, 3>>);
   //   assert(map.size() == 3u);
   //   assert(map.contains(-1) && map.find(-1)->get().empty());
   //   assert(map.contains(42) && map.find(42)->get() == "???");
   //   assert(map.contains(123) && map.find(123)->get() == "abc");
   //
   // The types of the key and value are deduced if the first pair contains exactly two arguments:
   //
   //   ftl::SmallMap map = ftl::init::map(0, 'a')(1, 'b')(2, 'c');
   //   static_assert(std::is_same_v<decltype(map), ftl::SmallMap<int, char, 3>>);
   //
   template <typename U, std::size_t... Sizes, typename... Types>
   SmallMap(InitializerList<U, std::index_sequence<Sizes...>, Types...>&& list)
       : map_(std::move(list)) {
     // TODO: Enforce unique keys.
   }

   size_type max_size() const { return map_.max_size(); }
   size_type size() const { return map_.size(); }
   bool empty() const { return map_.empty(); }

   // Returns whether the map is backed by static or dynamic storage.
   bool dynamic() const { return map_.dynamic(); }

   iterator begin() { return map_.begin(); }
   const_iterator begin() const { return cbegin(); }
   const_iterator cbegin() const { return map_.cbegin(); }

   iterator end() { return map_.end(); }
   const_iterator end() const { return cend(); }
   const_iterator cend() const { return map_.cend(); }

   // Returns whether a mapping exists for the given key.
   bool contains(const key_type& key) const {
     return find(key, [](const mapped_type&) {});
   }

   // Returns a reference to the value for the given key, or std::nullopt if the key was not found.
   //
   //   ftl::SmallMap map = ftl::init::map('a', 'A')('b', 'B')('c', 'C');
   //
   //   const auto opt = map.find('c');
   //   assert(opt == 'C');
   //
   //   char d = 'd';
   //   const auto ref = map.find('d').value_or(std::ref(d));
   //   ref.get() = 'D';
   //   assert(d == 'D');
   //
   auto find(const key_type& key) const -> std::optional<std::reference_wrapper<const mapped_type>> {
     return find(key, [](const mapped_type& v) { return std::cref(v); });
   }

   auto find(const key_type& key) -> std::optional<std::reference_wrapper<mapped_type>> {
     return find(key, [](mapped_type& v) { return std::ref(v); });
   }

   // Returns the result R of a unary operation F on (a constant or mutable reference to) the value
   // for the given key, or std::nullopt if the key was not found. If F has a return type of void,
   // then the Boolean result indicates whether the key was found.
   //
   //   ftl::SmallMap map = ftl::init::map('a', 'x')('b', 'y')('c', 'z');
   //
   //   assert(map.find('c', [](char c) { return std::toupper(c); }) == 'Z');
   //   assert(map.find('c', [](char& c) { c = std::toupper(c); }));
   //
   template <typename F, typename R = std::invoke_result_t<F, const mapped_type&>>
   auto find(const key_type& key, F f) const
       -> std::conditional_t<std::is_void_v<R>, bool, std::optional<R>> {
     for (auto& [k, v] : *this) {
       if (k == key) {
         if constexpr (std::is_void_v<R>) {
           f(v);
           return true;
         } else {
           return f(v);
         }
       }
     }

     return {};
   }

   template <typename F>
   auto find(const key_type& key, F f) {
     return std::as_const(*this).find(
         key, [&f](const mapped_type& v) { return f(const_cast<mapped_type&>(v)); });
   }

  private:
   Map map_;
 };

 // Deduction guide for in-place constructor.
 template <typename K, typename V, std::size_t... Sizes, typename... Types>
 SmallMap(InitializerList<KeyValue<K, V>, std::index_sequence<Sizes...>, Types...>&&)
     -> SmallMap<K, V, sizeof...(Sizes)>;

 // Returns whether the key-value pairs of two maps are equal.
 template <typename K, typename V, std::size_t N, typename Q, typename W, std::size_t M>
 bool operator==(const SmallMap<K, V, N>& lhs, const SmallMap<Q, W, M>& rhs) {
   if (lhs.size() != rhs.size()) return false;

   for (const auto& [k, v] : lhs) {
     const auto& lv = v;
     if (!rhs.find(k, [&lv](const auto& rv) { return lv == rv; }).value_or(false)) {
       return false;
     }
   }

   return true;
 }

 // TODO: Remove in C++20.
 template <typename K, typename V, std::size_t N, typename Q, typename W, std::size_t M>
 inline bool operator!=(const SmallMap<K, V, N>& lhs, const SmallMap<Q, W, M>& rhs) {
   return !(lhs == rhs);
 }

 }  // namespace android::ftl
	/*
	* Copyright 2020 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 <ftl/initializer_list.h>
	#include <ftl/small_vector.h>

	#include <functional>
	#include <optional>
	#include <type_traits>
	#include <utility>

	namespace android::ftl {

	// Associative container with unique, unordered keys. Unlike std::unordered_map, key-value pairs are
	// stored in contiguous storage for cache efficiency. The map is allocated statically until its size
	// exceeds N, at which point mappings are relocated to dynamic memory.
	//
	// SmallMap<K, V, 0> unconditionally allocates on the heap.
	//
	// Example usage:
	//
	// ftl::SmallMap<int, std::string, 3> map;
	// assert(map.empty());
	// assert(!map.dynamic());
	//
	// map = ftl::init::map<int, std::string>(123, "abc")(-1)(42, 3u, '?');
	// assert(map.size() == 3u);
	// assert(!map.dynamic());
	//
	// assert(map.contains(123));
	// assert(map.find(42, [](const std::string& s) { return s.size(); }) == 3u);
	//
	// const auto opt = map.find(-1);
	// assert(opt);
	//
	// std::string& ref = *opt;
	// assert(ref.empty());
	// ref = "xyz";
	//
	// assert(map == SmallMap(ftl::init::map(-1, "xyz")(42, "???")(123, "abc")));
	//
	template <typename K, typename V, std::size_t N>
	class SmallMap final {
	using Map = SmallVector<std::pair<const K, V>, N>;

	public:
	using key_type = K;
	using mapped_type = V;

	using value_type = typename Map::value_type;
	using size_type = typename Map::size_type;
	using difference_type = typename Map::difference_type;

	using reference = typename Map::reference;
	using iterator = typename Map::iterator;

	using const_reference = typename Map::const_reference;
	using const_iterator = typename Map::const_iterator;

	// Creates an empty map.
	SmallMap() = default;

	// Constructs at most N key-value pairs in place by forwarding per-pair constructor arguments.
	// The template arguments K, V, and N are inferred using the deduction guide defined below.
	// The syntax for listing pairs is as follows:
	//
	// ftl::SmallMap map = ftl::init::map<int, std::string>(123, "abc")(-1)(42, 3u, '?');
	//
	// static_assert(std::is_same_v<decltype(map), ftl::SmallMap<int, std::string, 3>>);
	// assert(map.size() == 3u);
	// assert(map.contains(-1) && map.find(-1)->get().empty());
	// assert(map.contains(42) && map.find(42)->get() == "???");
	// assert(map.contains(123) && map.find(123)->get() == "abc");
	//
	// The types of the key and value are deduced if the first pair contains exactly two arguments:
	//
	// ftl::SmallMap map = ftl::init::map(0, 'a')(1, 'b')(2, 'c');
	// static_assert(std::is_same_v<decltype(map), ftl::SmallMap<int, char, 3>>);
	//
	template <typename U, std::size_t... Sizes, typename... Types>
	SmallMap(InitializerList<U, std::index_sequence<Sizes...>, Types...>&& list)
	: map_(std::move(list)) {
	// TODO: Enforce unique keys.
	}

	size_type max_size() const { return map_.max_size(); }
	size_type size() const { return map_.size(); }
	bool empty() const { return map_.empty(); }

	// Returns whether the map is backed by static or dynamic storage.
	bool dynamic() const { return map_.dynamic(); }

	iterator begin() { return map_.begin(); }
	const_iterator begin() const { return cbegin(); }
	const_iterator cbegin() const { return map_.cbegin(); }

	iterator end() { return map_.end(); }
	const_iterator end() const { return cend(); }
	const_iterator cend() const { return map_.cend(); }

	// Returns whether a mapping exists for the given key.
	bool contains(const key_type& key) const {
	return find(key, [](const mapped_type&) {});
	}

	// Returns a reference to the value for the given key, or std::nullopt if the key was not found.
	//
	// ftl::SmallMap map = ftl::init::map('a', 'A')('b', 'B')('c', 'C');
	//
	// const auto opt = map.find('c');
	// assert(opt == 'C');
	//
	// char d = 'd';
	// const auto ref = map.find('d').value_or(std::ref(d));
	// ref.get() = 'D';
	// assert(d == 'D');
	//
	auto find(const key_type& key) const -> std::optional<std::reference_wrapper<const mapped_type>> {
	return find(key, [](const mapped_type& v) { return std::cref(v); });
	}

	auto find(const key_type& key) -> std::optional<std::reference_wrapper<mapped_type>> {
	return find(key, [](mapped_type& v) { return std::ref(v); });
	}

	// Returns the result R of a unary operation F on (a constant or mutable reference to) the value
	// for the given key, or std::nullopt if the key was not found. If F has a return type of void,
	// then the Boolean result indicates whether the key was found.
	//
	// ftl::SmallMap map = ftl::init::map('a', 'x')('b', 'y')('c', 'z');
	//
	// assert(map.find('c', [](char c) { return std::toupper(c); }) == 'Z');
	// assert(map.find('c', [](char& c) { c = std::toupper(c); }));
	//
	template <typename F, typename R = std::invoke_result_t<F, const mapped_type&>>
	auto find(const key_type& key, F f) const
	-> std::conditional_t<std::is_void_v<R>, bool, std::optional<R>> {
	for (auto& [k, v] : *this) {
	if (k == key) {
	if constexpr (std::is_void_v<R>) {
	f(v);
	return true;
	} else {
	return f(v);
	}
	}
	}

	return {};
	}

	template <typename F>
	auto find(const key_type& key, F f) {
	return std::as_const(*this).find(
	key, [&f](const mapped_type& v) { return f(const_cast<mapped_type&>(v)); });
	}

	private:
	Map map_;
	};

	// Deduction guide for in-place constructor.
	template <typename K, typename V, std::size_t... Sizes, typename... Types>
	SmallMap(InitializerList<KeyValue<K, V>, std::index_sequence<Sizes...>, Types...>&&)
	-> SmallMap<K, V, sizeof...(Sizes)>;

	// Returns whether the key-value pairs of two maps are equal.
	template <typename K, typename V, std::size_t N, typename Q, typename W, std::size_t M>
	bool operator==(const SmallMap<K, V, N>& lhs, const SmallMap<Q, W, M>& rhs) {
	if (lhs.size() != rhs.size()) return false;

	for (const auto& [k, v] : lhs) {
	const auto& lv = v;
	if (!rhs.find(k, [&lv](const auto& rv) { return lv == rv; }).value_or(false)) {
	return false;
	}
	}

	return true;
	}

	// TODO: Remove in C++20.
	template <typename K, typename V, std::size_t N, typename Q, typename W, std::size_t M>
	inline bool operator!=(const SmallMap<K, V, N>& lhs, const SmallMap<Q, W, M>& rhs) {
	return !(lhs == rhs);
	}

	} // namespace android::ftl