Abseil Common Libraries (C++) (grcp 依赖)
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886 lines
33 KiB
886 lines
33 KiB
// Copyright 2018 The Abseil Authors. |
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// |
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// Licensed under the Apache License, Version 2.0 (the "License"); |
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// you may not use this file except in compliance with the License. |
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// You may obtain a copy of the License at |
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// |
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// http://www.apache.org/licenses/LICENSE-2.0 |
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// |
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// Unless required by applicable law or agreed to in writing, software |
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// distributed under the License is distributed on an "AS IS" BASIS, |
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// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. |
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// See the License for the specific language governing permissions and |
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// limitations under the License. |
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// |
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// ----------------------------------------------------------------------------- |
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// File: hash.h |
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// ----------------------------------------------------------------------------- |
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// |
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#ifndef ABSL_HASH_INTERNAL_HASH_H_ |
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#define ABSL_HASH_INTERNAL_HASH_H_ |
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#include <algorithm> |
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#include <array> |
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#include <cmath> |
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#include <cstring> |
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#include <deque> |
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#include <forward_list> |
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#include <functional> |
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#include <iterator> |
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#include <limits> |
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#include <list> |
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#include <map> |
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#include <memory> |
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#include <set> |
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#include <string> |
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#include <tuple> |
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#include <type_traits> |
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#include <utility> |
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#include <vector> |
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#include "absl/base/internal/endian.h" |
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#include "absl/base/port.h" |
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#include "absl/container/fixed_array.h" |
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#include "absl/meta/type_traits.h" |
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#include "absl/numeric/int128.h" |
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#include "absl/strings/string_view.h" |
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#include "absl/types/optional.h" |
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#include "absl/types/variant.h" |
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#include "absl/utility/utility.h" |
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#include "absl/hash/internal/city.h" |
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namespace absl { |
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namespace hash_internal { |
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// HashStateBase |
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// |
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// A hash state object represents an intermediate state in the computation |
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// of an unspecified hash algorithm. `HashStateBase` provides a CRTP style |
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// base class for hash state implementations. Developers adding type support |
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// for `absl::Hash` should not rely on any parts of the state object other than |
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// the following member functions: |
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// |
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// * HashStateBase::combine() |
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// * HashStateBase::combine_contiguous() |
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// |
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// A derived hash state class of type `H` must provide a static member function |
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// with a signature similar to the following: |
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// |
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// `static H combine_contiguous(H state, const unsigned char*, size_t)`. |
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// |
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// `HashStateBase` will provide a complete implementations for a hash state |
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// object in terms of this method. |
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// |
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// Example: |
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// |
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// // Use CRTP to define your derived class. |
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// struct MyHashState : HashStateBase<MyHashState> { |
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// static H combine_contiguous(H state, const unsigned char*, size_t); |
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// using MyHashState::HashStateBase::combine; |
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// using MyHashState::HashStateBase::combine_contiguous; |
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// }; |
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template <typename H> |
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class HashStateBase { |
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public: |
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// HashStateBase::combine() |
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// |
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// Combines an arbitrary number of values into a hash state, returning the |
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// updated state. |
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// |
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// Each of the value types `T` must be separately hashable by the Abseil |
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// hashing framework. |
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// |
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// NOTE: |
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// |
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// state = H::combine(std::move(state), value1, value2, value3); |
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// |
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// is guaranteed to produce the same hash expansion as: |
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// |
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// state = H::combine(std::move(state), value1); |
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// state = H::combine(std::move(state), value2); |
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// state = H::combine(std::move(state), value3); |
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template <typename T, typename... Ts> |
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static H combine(H state, const T& value, const Ts&... values); |
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static H combine(H state) { return state; } |
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// HashStateBase::combine_contiguous() |
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// |
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// Combines a contiguous array of `size` elements into a hash state, returning |
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// the updated state. |
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// |
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// NOTE: |
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// |
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// state = H::combine_contiguous(std::move(state), data, size); |
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// |
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// is NOT guaranteed to produce the same hash expansion as a for-loop (it may |
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// perform internal optimizations). If you need this guarantee, use the |
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// for-loop instead. |
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template <typename T> |
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static H combine_contiguous(H state, const T* data, size_t size); |
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}; |
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// is_uniquely_represented |
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// |
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// `is_uniquely_represented<T>` is a trait class that indicates whether `T` |
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// is uniquely represented. |
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// |
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// A type is "uniquely represented" if two equal values of that type are |
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// guaranteed to have the same bytes in their underlying storage. In other |
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// words, if `a == b`, then `memcmp(&a, &b, sizeof(T))` is guaranteed to be |
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// zero. This property cannot be detected automatically, so this trait is false |
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// by default, but can be specialized by types that wish to assert that they are |
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// uniquely represented. This makes them eligible for certain optimizations. |
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// |
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// If you have any doubt whatsoever, do not specialize this template. |
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// The default is completely safe, and merely disables some optimizations |
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// that will not matter for most types. Specializing this template, |
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// on the other hand, can be very hazardous. |
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// |
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// To be uniquely represented, a type must not have multiple ways of |
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// representing the same value; for example, float and double are not |
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// uniquely represented, because they have distinct representations for |
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// +0 and -0. Furthermore, the type's byte representation must consist |
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// solely of user-controlled data, with no padding bits and no compiler- |
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// controlled data such as vptrs or sanitizer metadata. This is usually |
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// very difficult to guarantee, because in most cases the compiler can |
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// insert data and padding bits at its own discretion. |
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// |
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// If you specialize this template for a type `T`, you must do so in the file |
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// that defines that type (or in this file). If you define that specialization |
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// anywhere else, `is_uniquely_represented<T>` could have different meanings |
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// in different places. |
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// |
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// The Enable parameter is meaningless; it is provided as a convenience, |
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// to support certain SFINAE techniques when defining specializations. |
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template <typename T, typename Enable = void> |
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struct is_uniquely_represented : std::false_type {}; |
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// is_uniquely_represented<unsigned char> |
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// |
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// unsigned char is a synonym for "byte", so it is guaranteed to be |
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// uniquely represented. |
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template <> |
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struct is_uniquely_represented<unsigned char> : std::true_type {}; |
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// is_uniquely_represented for non-standard integral types |
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// |
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// Integral types other than bool should be uniquely represented on any |
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// platform that this will plausibly be ported to. |
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template <typename Integral> |
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struct is_uniquely_represented< |
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Integral, typename std::enable_if<std::is_integral<Integral>::value>::type> |
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: std::true_type {}; |
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// is_uniquely_represented<bool> |
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// |
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// |
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template <> |
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struct is_uniquely_represented<bool> : std::false_type {}; |
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// hash_bytes() |
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// |
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// Convenience function that combines `hash_state` with the byte representation |
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// of `value`. |
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template <typename H, typename T> |
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H hash_bytes(H hash_state, const T& value) { |
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const unsigned char* start = reinterpret_cast<const unsigned char*>(&value); |
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return H::combine_contiguous(std::move(hash_state), start, sizeof(value)); |
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} |
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// ----------------------------------------------------------------------------- |
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// AbslHashValue for Basic Types |
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// ----------------------------------------------------------------------------- |
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// Note: Default `AbslHashValue` implementations live in `hash_internal`. This |
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// allows us to block lexical scope lookup when doing an unqualified call to |
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// `AbslHashValue` below. User-defined implementations of `AbslHashValue` can |
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// only be found via ADL. |
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// AbslHashValue() for hashing bool values |
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// |
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// We use SFINAE to ensure that this overload only accepts bool, not types that |
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// are convertible to bool. |
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template <typename H, typename B> |
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typename std::enable_if<std::is_same<B, bool>::value, H>::type AbslHashValue( |
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H hash_state, B value) { |
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return H::combine(std::move(hash_state), |
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static_cast<unsigned char>(value ? 1 : 0)); |
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} |
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// AbslHashValue() for hashing enum values |
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template <typename H, typename Enum> |
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typename std::enable_if<std::is_enum<Enum>::value, H>::type AbslHashValue( |
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H hash_state, Enum e) { |
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// In practice, we could almost certainly just invoke hash_bytes directly, |
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// but it's possible that a sanitizer might one day want to |
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// store data in the unused bits of an enum. To avoid that risk, we |
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// convert to the underlying type before hashing. Hopefully this will get |
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// optimized away; if not, we can reopen discussion with c-toolchain-team. |
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return H::combine(std::move(hash_state), |
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static_cast<typename std::underlying_type<Enum>::type>(e)); |
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} |
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// AbslHashValue() for hashing floating-point values |
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template <typename H, typename Float> |
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typename std::enable_if<std::is_floating_point<Float>::value, H>::type |
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AbslHashValue(H hash_state, Float value) { |
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return hash_internal::hash_bytes(std::move(hash_state), |
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value == 0 ? 0 : value); |
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} |
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// Long double has the property that it might have extra unused bytes in it. |
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// For example, in x86 sizeof(long double)==16 but it only really uses 80-bits |
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// of it. This means we can't use hash_bytes on a long double and have to |
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// convert it to something else first. |
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template <typename H> |
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H AbslHashValue(H hash_state, long double value) { |
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const int category = std::fpclassify(value); |
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switch (category) { |
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case FP_INFINITE: |
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// Add the sign bit to differentiate between +Inf and -Inf |
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hash_state = H::combine(std::move(hash_state), std::signbit(value)); |
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break; |
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case FP_NAN: |
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case FP_ZERO: |
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default: |
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// Category is enough for these. |
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break; |
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case FP_NORMAL: |
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case FP_SUBNORMAL: |
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// We can't convert `value` directly to double because this would have |
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// undefined behavior if the value is out of range. |
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// std::frexp gives us a value in the range (-1, -.5] or [.5, 1) that is |
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// guaranteed to be in range for `double`. The truncation is |
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// implementation defined, but that works as long as it is deterministic. |
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int exp; |
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auto mantissa = static_cast<double>(std::frexp(value, &exp)); |
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hash_state = H::combine(std::move(hash_state), mantissa, exp); |
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} |
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return H::combine(std::move(hash_state), category); |
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} |
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// AbslHashValue() for hashing pointers |
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template <typename H, typename T> |
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H AbslHashValue(H hash_state, T* ptr) { |
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auto v = reinterpret_cast<uintptr_t>(ptr); |
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// Due to alignment, pointers tend to have low bits as zero, and the next few |
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// bits follow a pattern since they are also multiples of some base value. |
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// Mixing the pointer twice helps prevent stuck low bits for certain alignment |
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// values. |
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return H::combine(std::move(hash_state), v, v); |
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} |
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// AbslHashValue() for hashing nullptr_t |
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template <typename H> |
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H AbslHashValue(H hash_state, std::nullptr_t) { |
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return H::combine(std::move(hash_state), static_cast<void*>(nullptr)); |
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} |
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// ----------------------------------------------------------------------------- |
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// AbslHashValue for Composite Types |
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// ----------------------------------------------------------------------------- |
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// is_hashable() |
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// |
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// Trait class which returns true if T is hashable by the absl::Hash framework. |
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// Used for the AbslHashValue implementations for composite types below. |
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template <typename T> |
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struct is_hashable; |
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// AbslHashValue() for hashing pairs |
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template <typename H, typename T1, typename T2> |
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typename std::enable_if<is_hashable<T1>::value && is_hashable<T2>::value, |
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H>::type |
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AbslHashValue(H hash_state, const std::pair<T1, T2>& p) { |
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return H::combine(std::move(hash_state), p.first, p.second); |
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} |
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// hash_tuple() |
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// |
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// Helper function for hashing a tuple. The third argument should |
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// be an index_sequence running from 0 to tuple_size<Tuple> - 1. |
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template <typename H, typename Tuple, size_t... Is> |
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H hash_tuple(H hash_state, const Tuple& t, absl::index_sequence<Is...>) { |
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return H::combine(std::move(hash_state), std::get<Is>(t)...); |
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} |
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// AbslHashValue for hashing tuples |
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template <typename H, typename... Ts> |
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#if defined(_MSC_VER) |
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// This SFINAE gets MSVC confused under some conditions. Let's just disable it |
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// for now. |
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H |
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#else // _MSC_VER |
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typename std::enable_if<absl::conjunction<is_hashable<Ts>...>::value, H>::type |
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#endif // _MSC_VER |
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AbslHashValue(H hash_state, const std::tuple<Ts...>& t) { |
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return hash_internal::hash_tuple(std::move(hash_state), t, |
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absl::make_index_sequence<sizeof...(Ts)>()); |
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} |
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// ----------------------------------------------------------------------------- |
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// AbslHashValue for Pointers |
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// ----------------------------------------------------------------------------- |
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// AbslHashValue for hashing unique_ptr |
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template <typename H, typename T, typename D> |
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H AbslHashValue(H hash_state, const std::unique_ptr<T, D>& ptr) { |
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return H::combine(std::move(hash_state), ptr.get()); |
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} |
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// AbslHashValue for hashing shared_ptr |
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template <typename H, typename T> |
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H AbslHashValue(H hash_state, const std::shared_ptr<T>& ptr) { |
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return H::combine(std::move(hash_state), ptr.get()); |
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} |
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// ----------------------------------------------------------------------------- |
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// AbslHashValue for String-Like Types |
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// ----------------------------------------------------------------------------- |
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// AbslHashValue for hashing strings |
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// |
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// All the string-like types supported here provide the same hash expansion for |
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// the same character sequence. These types are: |
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// |
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// - `std::string` (and std::basic_string<char, std::char_traits<char>, A> for |
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// any allocator A) |
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// - `absl::string_view` and `std::string_view` |
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// |
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// For simplicity, we currently support only `char` strings. This support may |
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// be broadened, if necessary, but with some caution - this overload would |
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// misbehave in cases where the traits' `eq()` member isn't equivalent to `==` |
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// on the underlying character type. |
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template <typename H> |
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H AbslHashValue(H hash_state, absl::string_view str) { |
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return H::combine( |
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H::combine_contiguous(std::move(hash_state), str.data(), str.size()), |
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str.size()); |
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} |
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// ----------------------------------------------------------------------------- |
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// AbslHashValue for Sequence Containers |
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// ----------------------------------------------------------------------------- |
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// AbslHashValue for hashing std::array |
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template <typename H, typename T, size_t N> |
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typename std::enable_if<is_hashable<T>::value, H>::type AbslHashValue( |
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H hash_state, const std::array<T, N>& array) { |
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return H::combine_contiguous(std::move(hash_state), array.data(), |
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array.size()); |
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} |
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// AbslHashValue for hashing std::deque |
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template <typename H, typename T, typename Allocator> |
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typename std::enable_if<is_hashable<T>::value, H>::type AbslHashValue( |
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H hash_state, const std::deque<T, Allocator>& deque) { |
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// TODO(gromer): investigate a more efficient implementation taking |
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// advantage of the chunk structure. |
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for (const auto& t : deque) { |
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hash_state = H::combine(std::move(hash_state), t); |
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} |
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return H::combine(std::move(hash_state), deque.size()); |
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} |
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// AbslHashValue for hashing std::forward_list |
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template <typename H, typename T, typename Allocator> |
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typename std::enable_if<is_hashable<T>::value, H>::type AbslHashValue( |
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H hash_state, const std::forward_list<T, Allocator>& list) { |
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size_t size = 0; |
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for (const T& t : list) { |
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hash_state = H::combine(std::move(hash_state), t); |
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++size; |
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} |
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return H::combine(std::move(hash_state), size); |
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} |
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// AbslHashValue for hashing std::list |
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template <typename H, typename T, typename Allocator> |
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typename std::enable_if<is_hashable<T>::value, H>::type AbslHashValue( |
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H hash_state, const std::list<T, Allocator>& list) { |
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for (const auto& t : list) { |
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hash_state = H::combine(std::move(hash_state), t); |
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} |
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return H::combine(std::move(hash_state), list.size()); |
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} |
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// AbslHashValue for hashing std::vector |
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// |
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// Do not use this for vector<bool>. It does not have a .data(), and a fallback |
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// for std::hash<> is most likely faster. |
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template <typename H, typename T, typename Allocator> |
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typename std::enable_if<is_hashable<T>::value && !std::is_same<T, bool>::value, |
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H>::type |
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AbslHashValue(H hash_state, const std::vector<T, Allocator>& vector) { |
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return H::combine(H::combine_contiguous(std::move(hash_state), vector.data(), |
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vector.size()), |
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vector.size()); |
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} |
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// ----------------------------------------------------------------------------- |
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// AbslHashValue for Ordered Associative Containers |
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// ----------------------------------------------------------------------------- |
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// AbslHashValue for hashing std::map |
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template <typename H, typename Key, typename T, typename Compare, |
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typename Allocator> |
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typename std::enable_if<is_hashable<Key>::value && is_hashable<T>::value, |
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H>::type |
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AbslHashValue(H hash_state, const std::map<Key, T, Compare, Allocator>& map) { |
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for (const auto& t : map) { |
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hash_state = H::combine(std::move(hash_state), t); |
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} |
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return H::combine(std::move(hash_state), map.size()); |
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} |
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// AbslHashValue for hashing std::multimap |
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template <typename H, typename Key, typename T, typename Compare, |
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typename Allocator> |
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typename std::enable_if<is_hashable<Key>::value && is_hashable<T>::value, |
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H>::type |
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AbslHashValue(H hash_state, |
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const std::multimap<Key, T, Compare, Allocator>& map) { |
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for (const auto& t : map) { |
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hash_state = H::combine(std::move(hash_state), t); |
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} |
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return H::combine(std::move(hash_state), map.size()); |
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} |
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// AbslHashValue for hashing std::set |
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template <typename H, typename Key, typename Compare, typename Allocator> |
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typename std::enable_if<is_hashable<Key>::value, H>::type AbslHashValue( |
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H hash_state, const std::set<Key, Compare, Allocator>& set) { |
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for (const auto& t : set) { |
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hash_state = H::combine(std::move(hash_state), t); |
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} |
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return H::combine(std::move(hash_state), set.size()); |
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} |
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// AbslHashValue for hashing std::multiset |
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template <typename H, typename Key, typename Compare, typename Allocator> |
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typename std::enable_if<is_hashable<Key>::value, H>::type AbslHashValue( |
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H hash_state, const std::multiset<Key, Compare, Allocator>& set) { |
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for (const auto& t : set) { |
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hash_state = H::combine(std::move(hash_state), t); |
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} |
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return H::combine(std::move(hash_state), set.size()); |
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} |
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// ----------------------------------------------------------------------------- |
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// AbslHashValue for Wrapper Types |
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// ----------------------------------------------------------------------------- |
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// AbslHashValue for hashing absl::optional |
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template <typename H, typename T> |
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typename std::enable_if<is_hashable<T>::value, H>::type AbslHashValue( |
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H hash_state, const absl::optional<T>& opt) { |
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if (opt) hash_state = H::combine(std::move(hash_state), *opt); |
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return H::combine(std::move(hash_state), opt.has_value()); |
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} |
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// VariantVisitor |
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template <typename H> |
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struct VariantVisitor { |
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H&& hash_state; |
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template <typename T> |
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H operator()(const T& t) const { |
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return H::combine(std::move(hash_state), t); |
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} |
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}; |
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// AbslHashValue for hashing absl::variant |
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template <typename H, typename... T> |
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typename std::enable_if<conjunction<is_hashable<T>...>::value, H>::type |
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AbslHashValue(H hash_state, const absl::variant<T...>& v) { |
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if (!v.valueless_by_exception()) { |
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hash_state = absl::visit(VariantVisitor<H>{std::move(hash_state)}, v); |
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} |
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return H::combine(std::move(hash_state), v.index()); |
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} |
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// ----------------------------------------------------------------------------- |
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// AbslHashValue for Other Types |
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// ----------------------------------------------------------------------------- |
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// AbslHashValue for hashing std::bitset is not defined, for the same reason as |
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// for vector<bool> (see std::vector above): It does not expose the raw bytes, |
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// and a fallback to std::hash<> is most likely faster. |
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// ----------------------------------------------------------------------------- |
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// hash_range_or_bytes() |
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// |
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// Mixes all values in the range [data, data+size) into the hash state. |
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// This overload accepts only uniquely-represented types, and hashes them by |
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// hashing the entire range of bytes. |
|
template <typename H, typename T> |
|
typename std::enable_if<is_uniquely_represented<T>::value, H>::type |
|
hash_range_or_bytes(H hash_state, const T* data, size_t size) { |
|
const auto* bytes = reinterpret_cast<const unsigned char*>(data); |
|
return H::combine_contiguous(std::move(hash_state), bytes, sizeof(T) * size); |
|
} |
|
|
|
// hash_range_or_bytes() |
|
template <typename H, typename T> |
|
typename std::enable_if<!is_uniquely_represented<T>::value, H>::type |
|
hash_range_or_bytes(H hash_state, const T* data, size_t size) { |
|
for (const auto end = data + size; data < end; ++data) { |
|
hash_state = H::combine(std::move(hash_state), *data); |
|
} |
|
return hash_state; |
|
} |
|
|
|
// InvokeHashTag |
|
// |
|
// InvokeHash(H, const T&) invokes the appropriate hash implementation for a |
|
// hasher of type `H` and a value of type `T`. If `T` is not hashable, there |
|
// will be no matching overload of InvokeHash(). |
|
// Note: Some platforms (eg MSVC) do not support the detect idiom on |
|
// std::hash. In those platforms the last fallback will be std::hash and |
|
// InvokeHash() will always have a valid overload even if std::hash<T> is not |
|
// valid. |
|
// |
|
// We try the following options in order: |
|
// * If is_uniquely_represented, hash bytes directly. |
|
// * ADL AbslHashValue(H, const T&) call. |
|
// * std::hash<T> |
|
#if defined(ABSL_INTERNAL_LEGACY_HASH_NAMESPACE) && \ |
|
ABSL_META_INTERNAL_STD_HASH_SFINAE_FRIENDLY_ |
|
#define ABSL_HASH_INTERNAL_SUPPORT_LEGACY_HASH_ 1 |
|
#else |
|
#define ABSL_HASH_INTERNAL_SUPPORT_LEGACY_HASH_ 0 |
|
#endif |
|
|
|
enum class InvokeHashTag { |
|
kUniquelyRepresented, |
|
kHashValue, |
|
#if ABSL_HASH_INTERNAL_SUPPORT_LEGACY_HASH_ |
|
kLegacyHash, |
|
#endif // ABSL_HASH_INTERNAL_SUPPORT_LEGACY_HASH_ |
|
kStdHash, |
|
kNone |
|
}; |
|
|
|
// HashSelect |
|
// |
|
// Type trait to select the appropriate hash implementation to use. |
|
// HashSelect<T>::value is an instance of InvokeHashTag that indicates the best |
|
// available hashing mechanism. |
|
// See `Note` above about MSVC. |
|
template <typename T> |
|
struct HashSelect { |
|
private: |
|
struct State : HashStateBase<State> { |
|
static State combine_contiguous(State hash_state, const unsigned char*, |
|
size_t); |
|
using State::HashStateBase::combine_contiguous; |
|
}; |
|
|
|
// `Probe<V, Tag>::value` evaluates to `V<T>::value` if it is a valid |
|
// expression, and `false` otherwise. |
|
// `Probe<V, Tag>::tag` always evaluates to `Tag`. |
|
template <template <typename> class V, InvokeHashTag Tag> |
|
struct Probe { |
|
private: |
|
template <typename U, typename std::enable_if<V<U>::value, int>::type = 0> |
|
static std::true_type Test(int); |
|
template <typename U> |
|
static std::false_type Test(char); |
|
|
|
public: |
|
static constexpr InvokeHashTag kTag = Tag; |
|
static constexpr bool value = decltype( |
|
Test<absl::remove_const_t<absl::remove_reference_t<T>>>(0))::value; |
|
}; |
|
|
|
template <typename U> |
|
using ProbeUniquelyRepresented = is_uniquely_represented<U>; |
|
|
|
template <typename U> |
|
using ProbeHashValue = |
|
std::is_same<State, decltype(AbslHashValue(std::declval<State>(), |
|
std::declval<const U&>()))>; |
|
|
|
#if ABSL_HASH_INTERNAL_SUPPORT_LEGACY_HASH_ |
|
template <typename U> |
|
using ProbeLegacyHash = |
|
std::is_convertible<decltype(ABSL_INTERNAL_LEGACY_HASH_NAMESPACE::hash< |
|
U>()(std::declval<const U&>())), |
|
size_t>; |
|
#endif // ABSL_HASH_INTERNAL_SUPPORT_LEGACY_HASH_ |
|
|
|
template <typename U> |
|
using ProbeStdHash = absl::type_traits_internal::IsHashable<U>; |
|
|
|
template <typename U> |
|
using ProbeNone = std::true_type; |
|
|
|
public: |
|
// Probe each implementation in order. |
|
// disjunction provides short circuting wrt instantiation. |
|
static constexpr InvokeHashTag value = absl::disjunction< |
|
Probe<ProbeUniquelyRepresented, InvokeHashTag::kUniquelyRepresented>, |
|
Probe<ProbeHashValue, InvokeHashTag::kHashValue>, |
|
#if ABSL_HASH_INTERNAL_SUPPORT_LEGACY_HASH_ |
|
Probe<ProbeLegacyHash, InvokeHashTag::kLegacyHash>, |
|
#endif // ABSL_HASH_INTERNAL_SUPPORT_LEGACY_HASH_ |
|
Probe<ProbeStdHash, InvokeHashTag::kStdHash>, |
|
Probe<ProbeNone, InvokeHashTag::kNone>>::kTag; |
|
}; |
|
|
|
template <typename T> |
|
struct is_hashable : std::integral_constant<bool, HashSelect<T>::value != |
|
InvokeHashTag::kNone> {}; |
|
|
|
template <typename H, typename T> |
|
absl::enable_if_t<HashSelect<T>::value == InvokeHashTag::kUniquelyRepresented, |
|
H> |
|
InvokeHash(H state, const T& value) { |
|
return hash_internal::hash_bytes(std::move(state), value); |
|
} |
|
|
|
template <typename H, typename T> |
|
absl::enable_if_t<HashSelect<T>::value == InvokeHashTag::kHashValue, H> |
|
InvokeHash(H state, const T& value) { |
|
return AbslHashValue(std::move(state), value); |
|
} |
|
|
|
#if ABSL_HASH_INTERNAL_SUPPORT_LEGACY_HASH_ |
|
template <typename H, typename T> |
|
absl::enable_if_t<HashSelect<T>::value == InvokeHashTag::kLegacyHash, H> |
|
InvokeHash(H state, const T& value) { |
|
return hash_internal::hash_bytes( |
|
std::move(state), ABSL_INTERNAL_LEGACY_HASH_NAMESPACE::hash<T>{}(value)); |
|
} |
|
#endif // ABSL_HASH_INTERNAL_SUPPORT_LEGACY_HASH_ |
|
|
|
template <typename H, typename T> |
|
absl::enable_if_t<HashSelect<T>::value == InvokeHashTag::kStdHash, H> |
|
InvokeHash(H state, const T& value) { |
|
return hash_internal::hash_bytes(std::move(state), std::hash<T>{}(value)); |
|
} |
|
|
|
// CityHashState |
|
class CityHashState : public HashStateBase<CityHashState> { |
|
// absl::uint128 is not an alias or a thin wrapper around the intrinsic. |
|
// We use the intrinsic when available to improve performance. |
|
#ifdef ABSL_HAVE_INTRINSIC_INT128 |
|
using uint128 = __uint128_t; |
|
#else // ABSL_HAVE_INTRINSIC_INT128 |
|
using uint128 = absl::uint128; |
|
#endif // ABSL_HAVE_INTRINSIC_INT128 |
|
|
|
static constexpr uint64_t kMul = |
|
sizeof(size_t) == 4 ? uint64_t{0xcc9e2d51} : uint64_t{0x9ddfea08eb382d69}; |
|
|
|
template <typename T> |
|
using IntegralFastPath = |
|
conjunction<std::is_integral<T>, is_uniquely_represented<T>>; |
|
|
|
public: |
|
// Move only |
|
CityHashState(CityHashState&&) = default; |
|
CityHashState& operator=(CityHashState&&) = default; |
|
|
|
// CityHashState::combine_contiguous() |
|
// |
|
// Fundamental base case for hash recursion: mixes the given range of bytes |
|
// into the hash state. |
|
static CityHashState combine_contiguous(CityHashState hash_state, |
|
const unsigned char* first, |
|
size_t size) { |
|
return CityHashState( |
|
CombineContiguousImpl(hash_state.state_, first, size, |
|
std::integral_constant<int, sizeof(size_t)>{})); |
|
} |
|
using CityHashState::HashStateBase::combine_contiguous; |
|
|
|
// CityHashState::hash() |
|
// |
|
// For performance reasons in non-opt mode, we specialize this for |
|
// integral types. |
|
// Otherwise we would be instantiating and calling dozens of functions for |
|
// something that is just one multiplication and a couple xor's. |
|
// The result should be the same as running the whole algorithm, but faster. |
|
template <typename T, absl::enable_if_t<IntegralFastPath<T>::value, int> = 0> |
|
static size_t hash(T value) { |
|
return static_cast<size_t>(Mix(Seed(), static_cast<uint64_t>(value))); |
|
} |
|
|
|
// Overload of CityHashState::hash() |
|
template <typename T, absl::enable_if_t<!IntegralFastPath<T>::value, int> = 0> |
|
static size_t hash(const T& value) { |
|
return static_cast<size_t>(combine(CityHashState{}, value).state_); |
|
} |
|
|
|
private: |
|
// Invoked only once for a given argument; that plus the fact that this is |
|
// move-only ensures that there is only one non-moved-from object. |
|
CityHashState() : state_(Seed()) {} |
|
|
|
// Workaround for MSVC bug. |
|
// We make the type copyable to fix the calling convention, even though we |
|
// never actually copy it. Keep it private to not affect the public API of the |
|
// type. |
|
CityHashState(const CityHashState&) = default; |
|
|
|
explicit CityHashState(uint64_t state) : state_(state) {} |
|
|
|
// Implementation of the base case for combine_contiguous where we actually |
|
// mix the bytes into the state. |
|
// Dispatch to different implementations of the combine_contiguous depending |
|
// on the value of `sizeof(size_t)`. |
|
static uint64_t CombineContiguousImpl(uint64_t state, |
|
const unsigned char* first, size_t len, |
|
std::integral_constant<int, 4> |
|
/* sizeof_size_t */); |
|
static uint64_t CombineContiguousImpl(uint64_t state, |
|
const unsigned char* first, size_t len, |
|
std::integral_constant<int, 8> |
|
/* sizeof_size_t*/); |
|
|
|
// Reads 9 to 16 bytes from p. |
|
// The first 8 bytes are in .first, the rest (zero padded) bytes are in |
|
// .second. |
|
static std::pair<uint64_t, uint64_t> Read9To16(const unsigned char* p, |
|
size_t len) { |
|
uint64_t high = little_endian::Load64(p + len - 8); |
|
return {little_endian::Load64(p), high >> (128 - len * 8)}; |
|
} |
|
|
|
// Reads 4 to 8 bytes from p. Zero pads to fill uint64_t. |
|
static uint64_t Read4To8(const unsigned char* p, size_t len) { |
|
return (static_cast<uint64_t>(little_endian::Load32(p + len - 4)) |
|
<< (len - 4) * 8) | |
|
little_endian::Load32(p); |
|
} |
|
|
|
// Reads 1 to 3 bytes from p. Zero pads to fill uint32_t. |
|
static uint32_t Read1To3(const unsigned char* p, size_t len) { |
|
return static_cast<uint32_t>((p[0]) | // |
|
(p[len / 2] << (len / 2 * 8)) | // |
|
(p[len - 1] << ((len - 1) * 8))); |
|
} |
|
|
|
ABSL_ATTRIBUTE_ALWAYS_INLINE static uint64_t Mix(uint64_t state, uint64_t v) { |
|
using MultType = |
|
absl::conditional_t<sizeof(size_t) == 4, uint64_t, uint128>; |
|
// We do the addition in 64-bit space to make sure the 128-bit |
|
// multiplication is fast. If we were to do it as MultType the compiler has |
|
// to assume that the high word is non-zero and needs to perform 2 |
|
// multiplications instead of one. |
|
MultType m = state + v; |
|
m *= kMul; |
|
return static_cast<uint64_t>(m ^ (m >> (sizeof(m) * 8 / 2))); |
|
} |
|
|
|
// Seed() |
|
// |
|
// A non-deterministic seed. |
|
// |
|
// The current purpose of this seed is to generate non-deterministic results |
|
// and prevent having users depend on the particular hash values. |
|
// It is not meant as a security feature right now, but it leaves the door |
|
// open to upgrade it to a true per-process random seed. A true random seed |
|
// costs more and we don't need to pay for that right now. |
|
// |
|
// On platforms with ASLR, we take advantage of it to make a per-process |
|
// random value. |
|
// See https://en.wikipedia.org/wiki/Address_space_layout_randomization |
|
// |
|
// On other platforms this is still going to be non-deterministic but most |
|
// probably per-build and not per-process. |
|
ABSL_ATTRIBUTE_ALWAYS_INLINE static uint64_t Seed() { |
|
return static_cast<uint64_t>(reinterpret_cast<uintptr_t>(kSeed)); |
|
} |
|
static const void* const kSeed; |
|
|
|
uint64_t state_; |
|
}; |
|
|
|
// CityHashState::CombineContiguousImpl() |
|
inline uint64_t CityHashState::CombineContiguousImpl( |
|
uint64_t state, const unsigned char* first, size_t len, |
|
std::integral_constant<int, 4> /* sizeof_size_t */) { |
|
// For large values we use CityHash, for small ones we just use a |
|
// multiplicative hash. |
|
uint64_t v; |
|
if (len > 8) { |
|
v = absl::hash_internal::CityHash32(reinterpret_cast<const char*>(first), len); |
|
} else if (len >= 4) { |
|
v = Read4To8(first, len); |
|
} else if (len > 0) { |
|
v = Read1To3(first, len); |
|
} else { |
|
// Empty ranges have no effect. |
|
return state; |
|
} |
|
return Mix(state, v); |
|
} |
|
|
|
// Overload of CityHashState::CombineContiguousImpl() |
|
inline uint64_t CityHashState::CombineContiguousImpl( |
|
uint64_t state, const unsigned char* first, size_t len, |
|
std::integral_constant<int, 8> /* sizeof_size_t */) { |
|
// For large values we use CityHash, for small ones we just use a |
|
// multiplicative hash. |
|
uint64_t v; |
|
if (len > 16) { |
|
v = absl::hash_internal::CityHash64(reinterpret_cast<const char*>(first), len); |
|
} else if (len > 8) { |
|
auto p = Read9To16(first, len); |
|
state = Mix(state, p.first); |
|
v = p.second; |
|
} else if (len >= 4) { |
|
v = Read4To8(first, len); |
|
} else if (len > 0) { |
|
v = Read1To3(first, len); |
|
} else { |
|
// Empty ranges have no effect. |
|
return state; |
|
} |
|
return Mix(state, v); |
|
} |
|
|
|
|
|
struct AggregateBarrier {}; |
|
|
|
// HashImpl |
|
|
|
// Add a private base class to make sure this type is not an aggregate. |
|
// Aggregates can be aggregate initialized even if the default constructor is |
|
// deleted. |
|
struct PoisonedHash : private AggregateBarrier { |
|
PoisonedHash() = delete; |
|
PoisonedHash(const PoisonedHash&) = delete; |
|
PoisonedHash& operator=(const PoisonedHash&) = delete; |
|
}; |
|
|
|
template <typename T> |
|
struct HashImpl { |
|
size_t operator()(const T& value) const { return CityHashState::hash(value); } |
|
}; |
|
|
|
template <typename T> |
|
struct Hash |
|
: absl::conditional_t<is_hashable<T>::value, HashImpl<T>, PoisonedHash> {}; |
|
|
|
template <typename H> |
|
template <typename T, typename... Ts> |
|
H HashStateBase<H>::combine(H state, const T& value, const Ts&... values) { |
|
return H::combine(hash_internal::InvokeHash(std::move(state), value), |
|
values...); |
|
} |
|
|
|
// HashStateBase::combine_contiguous() |
|
template <typename H> |
|
template <typename T> |
|
H HashStateBase<H>::combine_contiguous(H state, const T* data, size_t size) { |
|
return hash_internal::hash_range_or_bytes(std::move(state), data, size); |
|
} |
|
} // namespace hash_internal |
|
} // namespace absl |
|
|
|
#endif // ABSL_HASH_INTERNAL_HASH_H_
|
|
|