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Add 'third_party/abseil_cpp/' from commit '768eb2ca28'

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Vincent Ambo 2020-05-20 02:32:24 +01:00
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122
third_party/abseil_cpp/absl/hash/BUILD.bazel vendored Normal file
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#
# Copyright 2019 The Abseil Authors.
#
# 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
#
# https://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.
#
load("@rules_cc//cc:defs.bzl", "cc_library", "cc_test")
load(
"//absl:copts/configure_copts.bzl",
"ABSL_DEFAULT_COPTS",
"ABSL_DEFAULT_LINKOPTS",
"ABSL_TEST_COPTS",
)
package(default_visibility = ["//visibility:public"])
licenses(["notice"]) # Apache 2.0
cc_library(
name = "hash",
srcs = [
"internal/hash.cc",
"internal/hash.h",
],
hdrs = ["hash.h"],
copts = ABSL_DEFAULT_COPTS,
linkopts = ABSL_DEFAULT_LINKOPTS,
deps = [
":city",
"//absl/base:core_headers",
"//absl/base:endian",
"//absl/container:fixed_array",
"//absl/meta:type_traits",
"//absl/numeric:int128",
"//absl/strings",
"//absl/types:optional",
"//absl/types:variant",
"//absl/utility",
],
)
cc_library(
name = "hash_testing",
testonly = 1,
hdrs = ["hash_testing.h"],
linkopts = ABSL_DEFAULT_LINKOPTS,
deps = [
":spy_hash_state",
"//absl/meta:type_traits",
"//absl/strings",
"//absl/types:variant",
"@com_google_googletest//:gtest",
],
)
cc_test(
name = "hash_test",
srcs = ["hash_test.cc"],
copts = ABSL_TEST_COPTS,
linkopts = ABSL_DEFAULT_LINKOPTS,
deps = [
":hash",
":hash_testing",
":spy_hash_state",
"//absl/base:core_headers",
"//absl/container:flat_hash_set",
"//absl/meta:type_traits",
"//absl/numeric:int128",
"//absl/strings:cord_test_helpers",
"@com_google_googletest//:gtest_main",
],
)
cc_library(
name = "spy_hash_state",
testonly = 1,
hdrs = ["internal/spy_hash_state.h"],
copts = ABSL_DEFAULT_COPTS,
linkopts = ABSL_DEFAULT_LINKOPTS,
visibility = ["//visibility:private"],
deps = [
":hash",
"//absl/strings",
"//absl/strings:str_format",
],
)
cc_library(
name = "city",
srcs = ["internal/city.cc"],
hdrs = [
"internal/city.h",
],
copts = ABSL_DEFAULT_COPTS,
linkopts = ABSL_DEFAULT_LINKOPTS,
deps = [
"//absl/base:config",
"//absl/base:core_headers",
"//absl/base:endian",
],
)
cc_test(
name = "city_test",
srcs = ["internal/city_test.cc"],
copts = ABSL_TEST_COPTS,
linkopts = ABSL_DEFAULT_LINKOPTS,
deps = [
":city",
"@com_google_googletest//:gtest_main",
],
)

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third_party/abseil_cpp/absl/hash/CMakeLists.txt vendored Normal file
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#
# Copyright 2018 The Abseil Authors.
#
# 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
#
# https://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.
#
absl_cc_library(
NAME
hash
HDRS
"hash.h"
SRCS
"internal/hash.cc"
"internal/hash.h"
COPTS
${ABSL_DEFAULT_COPTS}
DEPS
absl::core_headers
absl::endian
absl::fixed_array
absl::meta
absl::int128
absl::strings
absl::optional
absl::variant
absl::utility
absl::city
PUBLIC
)
absl_cc_library(
NAME
hash_testing
HDRS
"hash_testing.h"
COPTS
${ABSL_TEST_COPTS}
DEPS
absl::spy_hash_state
absl::meta
absl::strings
absl::variant
gmock
TESTONLY
)
absl_cc_test(
NAME
hash_test
SRCS
"hash_test.cc"
COPTS
${ABSL_TEST_COPTS}
DEPS
absl::cord_test_helpers
absl::hash
absl::hash_testing
absl::core_headers
absl::flat_hash_set
absl::spy_hash_state
absl::meta
absl::int128
gmock_main
)
absl_cc_library(
NAME
spy_hash_state
HDRS
"internal/spy_hash_state.h"
COPTS
${ABSL_DEFAULT_COPTS}
DEPS
absl::hash
absl::strings
absl::str_format
TESTONLY
)
absl_cc_library(
NAME
city
HDRS
"internal/city.h"
SRCS
"internal/city.cc"
COPTS
${ABSL_DEFAULT_COPTS}
DEPS
absl::config
absl::core_headers
absl::endian
)
absl_cc_test(
NAME
city_test
SRCS
"internal/city_test.cc"
COPTS
${ABSL_TEST_COPTS}
DEPS
absl::city
gmock_main
)

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third_party/abseil_cpp/absl/hash/hash.h vendored Normal file
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// Copyright 2018 The Abseil Authors.
//
// 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
//
// https://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.
//
// -----------------------------------------------------------------------------
// File: hash.h
// -----------------------------------------------------------------------------
//
// This header file defines the Abseil `hash` library and the Abseil hashing
// framework. This framework consists of the following:
//
// * The `absl::Hash` functor, which is used to invoke the hasher within the
// Abseil hashing framework. `absl::Hash<T>` supports most basic types and
// a number of Abseil types out of the box.
// * `AbslHashValue`, an extension point that allows you to extend types to
// support Abseil hashing without requiring you to define a hashing
// algorithm.
// * `HashState`, a type-erased class which implements the manipulation of the
// hash state (H) itself, contains member functions `combine()` and
// `combine_contiguous()`, which you can use to contribute to an existing
// hash state when hashing your types.
//
// Unlike `std::hash` or other hashing frameworks, the Abseil hashing framework
// provides most of its utility by abstracting away the hash algorithm (and its
// implementation) entirely. Instead, a type invokes the Abseil hashing
// framework by simply combining its state with the state of known, hashable
// types. Hashing of that combined state is separately done by `absl::Hash`.
//
// One should assume that a hash algorithm is chosen randomly at the start of
// each process. E.g., `absl::Hash<int>{}(9)` in one process and
// `absl::Hash<int>{}(9)` in another process are likely to differ.
//
// `absl::Hash` is intended to strongly mix input bits with a target of passing
// an [Avalanche Test](https://en.wikipedia.org/wiki/Avalanche_effect).
//
// Example:
//
// // Suppose we have a class `Circle` for which we want to add hashing:
// class Circle {
// public:
// ...
// private:
// std::pair<int, int> center_;
// int radius_;
// };
//
// // To add hashing support to `Circle`, we simply need to add a free
// // (non-member) function `AbslHashValue()`, and return the combined hash
// // state of the existing hash state and the class state. You can add such a
// // free function using a friend declaration within the body of the class:
// class Circle {
// public:
// ...
// template <typename H>
// friend H AbslHashValue(H h, const Circle& c) {
// return H::combine(std::move(h), c.center_, c.radius_);
// }
// ...
// };
//
// For more information, see Adding Type Support to `absl::Hash` below.
//
#ifndef ABSL_HASH_HASH_H_
#define ABSL_HASH_HASH_H_
#include "absl/hash/internal/hash.h"
namespace absl {
ABSL_NAMESPACE_BEGIN
// -----------------------------------------------------------------------------
// `absl::Hash`
// -----------------------------------------------------------------------------
//
// `absl::Hash<T>` is a convenient general-purpose hash functor for any type `T`
// satisfying any of the following conditions (in order):
//
// * T is an arithmetic or pointer type
// * T defines an overload for `AbslHashValue(H, const T&)` for an arbitrary
// hash state `H`.
// - T defines a specialization of `HASH_NAMESPACE::hash<T>`
// - T defines a specialization of `std::hash<T>`
//
// `absl::Hash` intrinsically supports the following types:
//
// * All integral types (including bool)
// * All enum types
// * All floating-point types (although hashing them is discouraged)
// * All pointer types, including nullptr_t
// * std::pair<T1, T2>, if T1 and T2 are hashable
// * std::tuple<Ts...>, if all the Ts... are hashable
// * std::unique_ptr and std::shared_ptr
// * All string-like types including:
// * absl::Cord
// * std::string
// * std::string_view (as well as any instance of std::basic_string that
// uses char and std::char_traits)
// * All the standard sequence containers (provided the elements are hashable)
// * All the standard ordered associative containers (provided the elements are
// hashable)
// * absl types such as the following:
// * absl::string_view
// * absl::InlinedVector
// * absl::FixedArray
// * absl::uint128
// * absl::Time, absl::Duration, and absl::TimeZone
//
// Note: the list above is not meant to be exhaustive. Additional type support
// may be added, in which case the above list will be updated.
//
// -----------------------------------------------------------------------------
// absl::Hash Invocation Evaluation
// -----------------------------------------------------------------------------
//
// When invoked, `absl::Hash<T>` searches for supplied hash functions in the
// following order:
//
// * Natively supported types out of the box (see above)
// * Types for which an `AbslHashValue()` overload is provided (such as
// user-defined types). See "Adding Type Support to `absl::Hash`" below.
// * Types which define a `HASH_NAMESPACE::hash<T>` specialization (aka
// `__gnu_cxx::hash<T>` for gcc/Clang or `stdext::hash<T>` for MSVC)
// * Types which define a `std::hash<T>` specialization
//
// The fallback to legacy hash functions exists mainly for backwards
// compatibility. If you have a choice, prefer defining an `AbslHashValue`
// overload instead of specializing any legacy hash functors.
//
// -----------------------------------------------------------------------------
// The Hash State Concept, and using `HashState` for Type Erasure
// -----------------------------------------------------------------------------
//
// The `absl::Hash` framework relies on the Concept of a "hash state." Such a
// hash state is used in several places:
//
// * Within existing implementations of `absl::Hash<T>` to store the hashed
// state of an object. Note that it is up to the implementation how it stores
// such state. A hash table, for example, may mix the state to produce an
// integer value; a testing framework may simply hold a vector of that state.
// * Within implementations of `AbslHashValue()` used to extend user-defined
// types. (See "Adding Type Support to absl::Hash" below.)
// * Inside a `HashState`, providing type erasure for the concept of a hash
// state, which you can use to extend the `absl::Hash` framework for types
// that are otherwise difficult to extend using `AbslHashValue()`. (See the
// `HashState` class below.)
//
// The "hash state" concept contains two member functions for mixing hash state:
//
// * `H::combine(state, values...)`
//
// Combines an arbitrary number of values into a hash state, returning the
// updated state. Note that the existing hash state is move-only and must be
// passed by value.
//
// Each of the value types T must be hashable by H.
//
// NOTE:
//
// state = H::combine(std::move(state), value1, value2, value3);
//
// must be guaranteed to produce the same hash expansion as
//
// state = H::combine(std::move(state), value1);
// state = H::combine(std::move(state), value2);
// state = H::combine(std::move(state), value3);
//
// * `H::combine_contiguous(state, data, size)`
//
// Combines a contiguous array of `size` elements into a hash state,
// returning the updated state. Note that the existing hash state is
// move-only and must be passed by value.
//
// NOTE:
//
// state = H::combine_contiguous(std::move(state), data, size);
//
// need NOT be guaranteed to produce the same hash expansion as a loop
// (it may perform internal optimizations). If you need this guarantee, use a
// loop instead.
//
// -----------------------------------------------------------------------------
// Adding Type Support to `absl::Hash`
// -----------------------------------------------------------------------------
//
// To add support for your user-defined type, add a proper `AbslHashValue()`
// overload as a free (non-member) function. The overload will take an
// existing hash state and should combine that state with state from the type.
//
// Example:
//
// template <typename H>
// H AbslHashValue(H state, const MyType& v) {
// return H::combine(std::move(state), v.field1, ..., v.fieldN);
// }
//
// where `(field1, ..., fieldN)` are the members you would use on your
// `operator==` to define equality.
//
// Notice that `AbslHashValue` is not a class member, but an ordinary function.
// An `AbslHashValue` overload for a type should only be declared in the same
// file and namespace as said type. The proper `AbslHashValue` implementation
// for a given type will be discovered via ADL.
//
// Note: unlike `std::hash', `absl::Hash` should never be specialized. It must
// only be extended by adding `AbslHashValue()` overloads.
//
template <typename T>
using Hash = absl::hash_internal::Hash<T>;
// HashState
//
// A type erased version of the hash state concept, for use in user-defined
// `AbslHashValue` implementations that can't use templates (such as PImpl
// classes, virtual functions, etc.). The type erasure adds overhead so it
// should be avoided unless necessary.
//
// Note: This wrapper will only erase calls to:
// combine_contiguous(H, const unsigned char*, size_t)
//
// All other calls will be handled internally and will not invoke overloads
// provided by the wrapped class.
//
// Users of this class should still define a template `AbslHashValue` function,
// but can use `absl::HashState::Create(&state)` to erase the type of the hash
// state and dispatch to their private hashing logic.
//
// This state can be used like any other hash state. In particular, you can call
// `HashState::combine()` and `HashState::combine_contiguous()` on it.
//
// Example:
//
// class Interface {
// public:
// template <typename H>
// friend H AbslHashValue(H state, const Interface& value) {
// state = H::combine(std::move(state), std::type_index(typeid(*this)));
// value.HashValue(absl::HashState::Create(&state));
// return state;
// }
// private:
// virtual void HashValue(absl::HashState state) const = 0;
// };
//
// class Impl : Interface {
// private:
// void HashValue(absl::HashState state) const override {
// absl::HashState::combine(std::move(state), v1_, v2_);
// }
// int v1_;
// std::string v2_;
// };
class HashState : public hash_internal::HashStateBase<HashState> {
public:
// HashState::Create()
//
// Create a new `HashState` instance that wraps `state`. All calls to
// `combine()` and `combine_contiguous()` on the new instance will be
// redirected to the original `state` object. The `state` object must outlive
// the `HashState` instance.
template <typename T>
static HashState Create(T* state) {
HashState s;
s.Init(state);
return s;
}
HashState(const HashState&) = delete;
HashState& operator=(const HashState&) = delete;
HashState(HashState&&) = default;
HashState& operator=(HashState&&) = default;
// HashState::combine()
//
// Combines an arbitrary number of values into a hash state, returning the
// updated state.
using HashState::HashStateBase::combine;
// HashState::combine_contiguous()
//
// Combines a contiguous array of `size` elements into a hash state, returning
// the updated state.
static HashState combine_contiguous(HashState hash_state,
const unsigned char* first, size_t size) {
hash_state.combine_contiguous_(hash_state.state_, first, size);
return hash_state;
}
using HashState::HashStateBase::combine_contiguous;
private:
HashState() = default;
template <typename T>
static void CombineContiguousImpl(void* p, const unsigned char* first,
size_t size) {
T& state = *static_cast<T*>(p);
state = T::combine_contiguous(std::move(state), first, size);
}
template <typename T>
void Init(T* state) {
state_ = state;
combine_contiguous_ = &CombineContiguousImpl<T>;
}
// Do not erase an already erased state.
void Init(HashState* state) {
state_ = state->state_;
combine_contiguous_ = state->combine_contiguous_;
}
void* state_;
void (*combine_contiguous_)(void*, const unsigned char*, size_t);
};
ABSL_NAMESPACE_END
} // namespace absl
#endif // ABSL_HASH_HASH_H_

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// Copyright 2018 The Abseil Authors.
//
// 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
//
// https://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.
#include "absl/hash/hash.h"
#include <array>
#include <bitset>
#include <cstring>
#include <deque>
#include <forward_list>
#include <functional>
#include <iterator>
#include <limits>
#include <list>
#include <map>
#include <memory>
#include <numeric>
#include <random>
#include <set>
#include <string>
#include <tuple>
#include <type_traits>
#include <unordered_map>
#include <utility>
#include <vector>
#include "gmock/gmock.h"
#include "gtest/gtest.h"
#include "absl/container/flat_hash_set.h"
#include "absl/hash/hash_testing.h"
#include "absl/hash/internal/spy_hash_state.h"
#include "absl/meta/type_traits.h"
#include "absl/numeric/int128.h"
#include "absl/strings/cord_test_helpers.h"
namespace {
using absl::Hash;
using absl::hash_internal::SpyHashState;
template <typename T>
class HashValueIntTest : public testing::Test {
};
TYPED_TEST_SUITE_P(HashValueIntTest);
template <typename T>
SpyHashState SpyHash(const T& value) {
return SpyHashState::combine(SpyHashState(), value);
}
// Helper trait to verify if T is hashable. We use absl::Hash's poison status to
// detect it.
template <typename T>
using is_hashable = std::is_default_constructible<absl::Hash<T>>;
TYPED_TEST_P(HashValueIntTest, BasicUsage) {
EXPECT_TRUE((is_hashable<TypeParam>::value));
TypeParam n = 42;
EXPECT_EQ(SpyHash(n), SpyHash(TypeParam{42}));
EXPECT_NE(SpyHash(n), SpyHash(TypeParam{0}));
EXPECT_NE(SpyHash(std::numeric_limits<TypeParam>::max()),
SpyHash(std::numeric_limits<TypeParam>::min()));
}
TYPED_TEST_P(HashValueIntTest, FastPath) {
// Test the fast-path to make sure the values are the same.
TypeParam n = 42;
EXPECT_EQ(absl::Hash<TypeParam>{}(n),
absl::Hash<std::tuple<TypeParam>>{}(std::tuple<TypeParam>(n)));
}
REGISTER_TYPED_TEST_CASE_P(HashValueIntTest, BasicUsage, FastPath);
using IntTypes = testing::Types<unsigned char, char, int, int32_t, int64_t, uint32_t,
uint64_t, size_t>;
INSTANTIATE_TYPED_TEST_CASE_P(My, HashValueIntTest, IntTypes);
enum LegacyEnum { kValue1, kValue2, kValue3 };
enum class EnumClass { kValue4, kValue5, kValue6 };
TEST(HashValueTest, EnumAndBool) {
EXPECT_TRUE((is_hashable<LegacyEnum>::value));
EXPECT_TRUE((is_hashable<EnumClass>::value));
EXPECT_TRUE((is_hashable<bool>::value));
EXPECT_TRUE(absl::VerifyTypeImplementsAbslHashCorrectly(std::make_tuple(
LegacyEnum::kValue1, LegacyEnum::kValue2, LegacyEnum::kValue3)));
EXPECT_TRUE(absl::VerifyTypeImplementsAbslHashCorrectly(std::make_tuple(
EnumClass::kValue4, EnumClass::kValue5, EnumClass::kValue6)));
EXPECT_TRUE(absl::VerifyTypeImplementsAbslHashCorrectly(
std::make_tuple(true, false)));
}
TEST(HashValueTest, FloatingPoint) {
EXPECT_TRUE((is_hashable<float>::value));
EXPECT_TRUE((is_hashable<double>::value));
EXPECT_TRUE((is_hashable<long double>::value));
EXPECT_TRUE(absl::VerifyTypeImplementsAbslHashCorrectly(
std::make_tuple(42.f, 0.f, -0.f, std::numeric_limits<float>::infinity(),
-std::numeric_limits<float>::infinity())));
EXPECT_TRUE(absl::VerifyTypeImplementsAbslHashCorrectly(
std::make_tuple(42., 0., -0., std::numeric_limits<double>::infinity(),
-std::numeric_limits<double>::infinity())));
EXPECT_TRUE(absl::VerifyTypeImplementsAbslHashCorrectly(std::make_tuple(
// Add some values with small exponent to test that NORMAL values also
// append their category.
.5L, 1.L, 2.L, 4.L, 42.L, 0.L, -0.L,
17 * static_cast<long double>(std::numeric_limits<double>::max()),
std::numeric_limits<long double>::infinity(),
-std::numeric_limits<long double>::infinity())));
}
TEST(HashValueTest, Pointer) {
EXPECT_TRUE((is_hashable<int*>::value));
int i;
int* ptr = &i;
int* n = nullptr;
EXPECT_TRUE(absl::VerifyTypeImplementsAbslHashCorrectly(
std::make_tuple(&i, ptr, nullptr, ptr + 1, n)));
}
TEST(HashValueTest, PointerAlignment) {
// We want to make sure that pointer alignment will not cause bits to be
// stuck.
constexpr size_t kTotalSize = 1 << 20;
std::unique_ptr<char[]> data(new char[kTotalSize]);
constexpr size_t kLog2NumValues = 5;
constexpr size_t kNumValues = 1 << kLog2NumValues;
for (size_t align = 1; align < kTotalSize / kNumValues;
align < 8 ? align += 1 : align < 1024 ? align += 8 : align += 32) {
SCOPED_TRACE(align);
ASSERT_LE(align * kNumValues, kTotalSize);
size_t bits_or = 0;
size_t bits_and = ~size_t{};
for (size_t i = 0; i < kNumValues; ++i) {
size_t hash = absl::Hash<void*>()(data.get() + i * align);
bits_or |= hash;
bits_and &= hash;
}
// Limit the scope to the bits we would be using for Swisstable.
constexpr size_t kMask = (1 << (kLog2NumValues + 7)) - 1;
size_t stuck_bits = (~bits_or | bits_and) & kMask;
EXPECT_EQ(stuck_bits, 0) << "0x" << std::hex << stuck_bits;
}
}
TEST(HashValueTest, PairAndTuple) {
EXPECT_TRUE((is_hashable<std::pair<int, int>>::value));
EXPECT_TRUE((is_hashable<std::pair<const int&, const int&>>::value));
EXPECT_TRUE((is_hashable<std::tuple<int&, int&>>::value));
EXPECT_TRUE((is_hashable<std::tuple<int&&, int&&>>::value));
EXPECT_TRUE(absl::VerifyTypeImplementsAbslHashCorrectly(std::make_tuple(
std::make_pair(0, 42), std::make_pair(0, 42), std::make_pair(42, 0),
std::make_pair(0, 0), std::make_pair(42, 42), std::make_pair(1, 42))));
EXPECT_TRUE(absl::VerifyTypeImplementsAbslHashCorrectly(
std::make_tuple(std::make_tuple(0, 0, 0), std::make_tuple(0, 0, 42),
std::make_tuple(0, 23, 0), std::make_tuple(17, 0, 0),
std::make_tuple(42, 0, 0), std::make_tuple(3, 9, 9),
std::make_tuple(0, 0, -42))));
// Test that tuples of lvalue references work (so we need a few lvalues):
int a = 0, b = 1, c = 17, d = 23;
EXPECT_TRUE(absl::VerifyTypeImplementsAbslHashCorrectly(std::make_tuple(
std::tie(a, a), std::tie(a, b), std::tie(b, c), std::tie(c, d))));
// Test that tuples of rvalue references work:
EXPECT_TRUE(absl::VerifyTypeImplementsAbslHashCorrectly(std::make_tuple(
std::forward_as_tuple(0, 0, 0), std::forward_as_tuple(0, 0, 42),
std::forward_as_tuple(0, 23, 0), std::forward_as_tuple(17, 0, 0),
std::forward_as_tuple(42, 0, 0), std::forward_as_tuple(3, 9, 9),
std::forward_as_tuple(0, 0, -42))));
}
TEST(HashValueTest, CombineContiguousWorks) {
std::vector<std::tuple<int>> v1 = {std::make_tuple(1), std::make_tuple(3)};
std::vector<std::tuple<int>> v2 = {std::make_tuple(1), std::make_tuple(2)};
auto vh1 = SpyHash(v1);
auto vh2 = SpyHash(v2);
EXPECT_NE(vh1, vh2);
}
struct DummyDeleter {
template <typename T>
void operator() (T* ptr) {}
};
struct SmartPointerEq {
template <typename T, typename U>
bool operator()(const T& t, const U& u) const {
return GetPtr(t) == GetPtr(u);
}
template <typename T>
static auto GetPtr(const T& t) -> decltype(&*t) {
return t ? &*t : nullptr;
}
static std::nullptr_t GetPtr(std::nullptr_t) { return nullptr; }
};
TEST(HashValueTest, SmartPointers) {
EXPECT_TRUE((is_hashable<std::unique_ptr<int>>::value));
EXPECT_TRUE((is_hashable<std::unique_ptr<int, DummyDeleter>>::value));
EXPECT_TRUE((is_hashable<std::shared_ptr<int>>::value));
int i, j;
std::unique_ptr<int, DummyDeleter> unique1(&i);
std::unique_ptr<int, DummyDeleter> unique2(&i);
std::unique_ptr<int, DummyDeleter> unique_other(&j);
std::unique_ptr<int, DummyDeleter> unique_null;
std::shared_ptr<int> shared1(&i, DummyDeleter());
std::shared_ptr<int> shared2(&i, DummyDeleter());
std::shared_ptr<int> shared_other(&j, DummyDeleter());
std::shared_ptr<int> shared_null;
// Sanity check of the Eq function.
ASSERT_TRUE(SmartPointerEq{}(unique1, shared1));
ASSERT_FALSE(SmartPointerEq{}(unique1, shared_other));
ASSERT_TRUE(SmartPointerEq{}(unique_null, nullptr));
ASSERT_FALSE(SmartPointerEq{}(shared2, nullptr));
EXPECT_TRUE(absl::VerifyTypeImplementsAbslHashCorrectly(
std::forward_as_tuple(&i, nullptr, //
unique1, unique2, unique_null, //
absl::make_unique<int>(), //
shared1, shared2, shared_null, //
std::make_shared<int>()),
SmartPointerEq{}));
}
TEST(HashValueTest, FunctionPointer) {
using Func = int (*)();
EXPECT_TRUE(is_hashable<Func>::value);
Func p1 = [] { return 2; }, p2 = [] { return 1; };
EXPECT_TRUE(absl::VerifyTypeImplementsAbslHashCorrectly(
std::make_tuple(p1, p2, nullptr)));
}
struct WrapInTuple {
template <typename T>
std::tuple<int, T, size_t> operator()(const T& t) const {
return std::make_tuple(7, t, 0xdeadbeef);
}
};
absl::Cord FlatCord(absl::string_view sv) {
absl::Cord c(sv);
c.Flatten();
return c;
}
absl::Cord FragmentedCord(absl::string_view sv) {
if (sv.size() < 2) {
return absl::Cord(sv);
}
size_t halfway = sv.size() / 2;
std::vector<absl::string_view> parts = {sv.substr(0, halfway),
sv.substr(halfway)};
return absl::MakeFragmentedCord(parts);
}
TEST(HashValueTest, Strings) {
EXPECT_TRUE((is_hashable<std::string>::value));
const std::string small = "foo";
const std::string dup = "foofoo";
const std::string large = std::string(2048, 'x'); // multiple of chunk size
const std::string huge = std::string(5000, 'a'); // not a multiple
EXPECT_TRUE(absl::VerifyTypeImplementsAbslHashCorrectly(std::make_tuple( //
std::string(), absl::string_view(), absl::Cord(), //
std::string(""), absl::string_view(""), absl::Cord(""), //
std::string(small), absl::string_view(small), absl::Cord(small), //
std::string(dup), absl::string_view(dup), absl::Cord(dup), //
std::string(large), absl::string_view(large), absl::Cord(large), //
std::string(huge), absl::string_view(huge), FlatCord(huge), //
FragmentedCord(huge))));
// Also check that nested types maintain the same hash.
const WrapInTuple t{};
EXPECT_TRUE(absl::VerifyTypeImplementsAbslHashCorrectly(std::make_tuple( //
t(std::string()), t(absl::string_view()), t(absl::Cord()), //
t(std::string("")), t(absl::string_view("")), t(absl::Cord("")), //
t(std::string(small)), t(absl::string_view(small)), //
t(absl::Cord(small)), //
t(std::string(dup)), t(absl::string_view(dup)), t(absl::Cord(dup)), //
t(std::string(large)), t(absl::string_view(large)), //
t(absl::Cord(large)), //
t(std::string(huge)), t(absl::string_view(huge)), //
t(FlatCord(huge)), t(FragmentedCord(huge)))));
// Make sure that hashing a `const char*` does not use its string-value.
EXPECT_NE(SpyHash(static_cast<const char*>("ABC")),
SpyHash(absl::string_view("ABC")));
}
TEST(HashValueTest, WString) {
EXPECT_TRUE((is_hashable<std::wstring>::value));
EXPECT_TRUE(absl::VerifyTypeImplementsAbslHashCorrectly(std::make_tuple(
std::wstring(), std::wstring(L"ABC"), std::wstring(L"ABC"),
std::wstring(L"Some other different string"),
std::wstring(L"Iñtërnâtiônàlizætiøn"))));
}
TEST(HashValueTest, U16String) {
EXPECT_TRUE((is_hashable<std::u16string>::value));
EXPECT_TRUE(absl::VerifyTypeImplementsAbslHashCorrectly(std::make_tuple(
std::u16string(), std::u16string(u"ABC"), std::u16string(u"ABC"),
std::u16string(u"Some other different string"),
std::u16string(u"Iñtërnâtiônàlizætiøn"))));
}
TEST(HashValueTest, U32String) {
EXPECT_TRUE((is_hashable<std::u32string>::value));
EXPECT_TRUE(absl::VerifyTypeImplementsAbslHashCorrectly(std::make_tuple(
std::u32string(), std::u32string(U"ABC"), std::u32string(U"ABC"),
std::u32string(U"Some other different string"),
std::u32string(U"Iñtërnâtiônàlizætiøn"))));
}
TEST(HashValueTest, StdArray) {
EXPECT_TRUE((is_hashable<std::array<int, 3>>::value));
EXPECT_TRUE(absl::VerifyTypeImplementsAbslHashCorrectly(
std::make_tuple(std::array<int, 3>{}, std::array<int, 3>{{0, 23, 42}})));
}
TEST(HashValueTest, StdBitset) {
EXPECT_TRUE((is_hashable<std::bitset<257>>::value));
EXPECT_TRUE(absl::VerifyTypeImplementsAbslHashCorrectly(
{std::bitset<2>("00"), std::bitset<2>("01"), std::bitset<2>("10"),
std::bitset<2>("11")}));
EXPECT_TRUE(absl::VerifyTypeImplementsAbslHashCorrectly(
{std::bitset<5>("10101"), std::bitset<5>("10001"), std::bitset<5>()}));
constexpr int kNumBits = 256;
std::array<std::string, 6> bit_strings;
bit_strings.fill(std::string(kNumBits, '1'));
bit_strings[1][0] = '0';
bit_strings[2][1] = '0';
bit_strings[3][kNumBits / 3] = '0';
bit_strings[4][kNumBits - 2] = '0';
bit_strings[5][kNumBits - 1] = '0';
EXPECT_TRUE(absl::VerifyTypeImplementsAbslHashCorrectly(
{std::bitset<kNumBits>(bit_strings[0].c_str()),
std::bitset<kNumBits>(bit_strings[1].c_str()),
std::bitset<kNumBits>(bit_strings[2].c_str()),
std::bitset<kNumBits>(bit_strings[3].c_str()),
std::bitset<kNumBits>(bit_strings[4].c_str()),
std::bitset<kNumBits>(bit_strings[5].c_str())}));
} // namespace
template <typename T>
class HashValueSequenceTest : public testing::Test {
};
TYPED_TEST_SUITE_P(HashValueSequenceTest);
TYPED_TEST_P(HashValueSequenceTest, BasicUsage) {
EXPECT_TRUE((is_hashable<TypeParam>::value));
using ValueType = typename TypeParam::value_type;
auto a = static_cast<ValueType>(0);
auto b = static_cast<ValueType>(23);
auto c = static_cast<ValueType>(42);
EXPECT_TRUE(absl::VerifyTypeImplementsAbslHashCorrectly(
std::make_tuple(TypeParam(), TypeParam{}, TypeParam{a, b, c},
TypeParam{a, b}, TypeParam{b, c})));
}
REGISTER_TYPED_TEST_CASE_P(HashValueSequenceTest, BasicUsage);
using IntSequenceTypes =
testing::Types<std::deque<int>, std::forward_list<int>, std::list<int>,
std::vector<int>, std::vector<bool>, std::set<int>,
std::multiset<int>>;
INSTANTIATE_TYPED_TEST_CASE_P(My, HashValueSequenceTest, IntSequenceTypes);
// Private type that only supports AbslHashValue to make sure our chosen hash
// implementation is recursive within absl::Hash.
// It uses std::abs() on the value to provide different bitwise representations
// of the same logical value.
struct Private {
int i;
template <typename H>
friend H AbslHashValue(H h, Private p) {
return H::combine(std::move(h), std::abs(p.i));
}
friend bool operator==(Private a, Private b) {
return std::abs(a.i) == std::abs(b.i);
}
friend std::ostream& operator<<(std::ostream& o, Private p) {
return o << p.i;
}
};
// Test helper for combine_piecewise_buffer. It holds a string_view to the
// buffer-to-be-hashed. Its AbslHashValue specialization will split up its
// contents at the character offsets requested.
class PiecewiseHashTester {
public:
// Create a hash view of a buffer to be hashed contiguously.
explicit PiecewiseHashTester(absl::string_view buf)
: buf_(buf), piecewise_(false), split_locations_() {}
// Create a hash view of a buffer to be hashed piecewise, with breaks at the
// given locations.
PiecewiseHashTester(absl::string_view buf, std::set<size_t> split_locations)
: buf_(buf),
piecewise_(true),
split_locations_(std::move(split_locations)) {}
template <typename H>
friend H AbslHashValue(H h, const PiecewiseHashTester& p) {
if (!p.piecewise_) {
return H::combine_contiguous(std::move(h), p.buf_.data(), p.buf_.size());
}
absl::hash_internal::PiecewiseCombiner combiner;
if (p.split_locations_.empty()) {
h = combiner.add_buffer(std::move(h), p.buf_.data(), p.buf_.size());
return combiner.finalize(std::move(h));
}
size_t begin = 0;
for (size_t next : p.split_locations_) {
absl::string_view chunk = p.buf_.substr(begin, next - begin);
h = combiner.add_buffer(std::move(h), chunk.data(), chunk.size());
begin = next;
}
absl::string_view last_chunk = p.buf_.substr(begin);
if (!last_chunk.empty()) {
h = combiner.add_buffer(std::move(h), last_chunk.data(),
last_chunk.size());
}
return combiner.finalize(std::move(h));
}
private:
absl::string_view buf_;
bool piecewise_;
std::set<size_t> split_locations_;
};
// Dummy object that hashes as two distinct contiguous buffers, "foo" followed
// by "bar"
struct DummyFooBar {
template <typename H>
friend H AbslHashValue(H h, const DummyFooBar&) {
const char* foo = "foo";
const char* bar = "bar";
h = H::combine_contiguous(std::move(h), foo, 3);
h = H::combine_contiguous(std::move(h), bar, 3);
return h;
}
};
TEST(HashValueTest, CombinePiecewiseBuffer) {
absl::Hash<PiecewiseHashTester> hash;
// Check that hashing an empty buffer through the piecewise API works.
EXPECT_EQ(hash(PiecewiseHashTester("")), hash(PiecewiseHashTester("", {})));
// Similarly, small buffers should give consistent results
EXPECT_EQ(hash(PiecewiseHashTester("foobar")),
hash(PiecewiseHashTester("foobar", {})));
EXPECT_EQ(hash(PiecewiseHashTester("foobar")),
hash(PiecewiseHashTester("foobar", {3})));
// But hashing "foobar" in pieces gives a different answer than hashing "foo"
// contiguously, then "bar" contiguously.
EXPECT_NE(hash(PiecewiseHashTester("foobar", {3})),
absl::Hash<DummyFooBar>()(DummyFooBar{}));
// Test hashing a large buffer incrementally, broken up in several different
// ways. Arrange for breaks on and near the stride boundaries to look for
// off-by-one errors in the implementation.
//
// This test is run on a buffer that is a multiple of the stride size, and one
// that isn't.
for (size_t big_buffer_size : {1024 * 2 + 512, 1024 * 3}) {
SCOPED_TRACE(big_buffer_size);
std::string big_buffer;
for (int i = 0; i < big_buffer_size; ++i) {
// Arbitrary string
big_buffer.push_back(32 + (i * (i / 3)) % 64);
}
auto big_buffer_hash = hash(PiecewiseHashTester(big_buffer));
const int possible_breaks = 9;
size_t breaks[possible_breaks] = {1, 512, 1023, 1024, 1025,
1536, 2047, 2048, 2049};
for (unsigned test_mask = 0; test_mask < (1u << possible_breaks);
++test_mask) {
SCOPED_TRACE(test_mask);
std::set<size_t> break_locations;
for (int j = 0; j < possible_breaks; ++j) {
if (test_mask & (1u << j)) {
break_locations.insert(breaks[j]);
}
}
EXPECT_EQ(
hash(PiecewiseHashTester(big_buffer, std::move(break_locations))),
big_buffer_hash);
}
}
}
TEST(HashValueTest, PrivateSanity) {
// Sanity check that Private is working as the tests below expect it to work.
EXPECT_TRUE(is_hashable<Private>::value);
EXPECT_NE(SpyHash(Private{0}), SpyHash(Private{1}));
EXPECT_EQ(SpyHash(Private{1}), SpyHash(Private{1}));
}
TEST(HashValueTest, Optional) {
EXPECT_TRUE(is_hashable<absl::optional<Private>>::value);
using O = absl::optional<Private>;
EXPECT_TRUE(absl::VerifyTypeImplementsAbslHashCorrectly(
std::make_tuple(O{}, O{{1}}, O{{-1}}, O{{10}})));
}
TEST(HashValueTest, Variant) {
using V = absl::variant<Private, std::string>;
EXPECT_TRUE(is_hashable<V>::value);
EXPECT_TRUE(absl::VerifyTypeImplementsAbslHashCorrectly(std::make_tuple(
V(Private{1}), V(Private{-1}), V(Private{2}), V("ABC"), V("BCD"))));
#if ABSL_META_INTERNAL_STD_HASH_SFINAE_FRIENDLY_
struct S {};
EXPECT_FALSE(is_hashable<absl::variant<S>>::value);
#endif
}
TEST(HashValueTest, Maps) {
EXPECT_TRUE((is_hashable<std::map<int, std::string>>::value));
using M = std::map<int, std::string>;
EXPECT_TRUE(absl::VerifyTypeImplementsAbslHashCorrectly(std::make_tuple(
M{}, M{{0, "foo"}}, M{{1, "foo"}}, M{{0, "bar"}}, M{{1, "bar"}},
M{{0, "foo"}, {42, "bar"}}, M{{1, "foo"}, {42, "bar"}},
M{{1, "foo"}, {43, "bar"}}, M{{1, "foo"}, {43, "baz"}})));
using MM = std::multimap<int, std::string>;
EXPECT_TRUE(absl::VerifyTypeImplementsAbslHashCorrectly(std::make_tuple(
MM{}, MM{{0, "foo"}}, MM{{1, "foo"}}, MM{{0, "bar"}}, MM{{1, "bar"}},
MM{{0, "foo"}, {0, "bar"}}, MM{{0, "bar"}, {0, "foo"}},
MM{{0, "foo"}, {42, "bar"}}, MM{{1, "foo"}, {42, "bar"}},
MM{{1, "foo"}, {1, "foo"}, {43, "bar"}}, MM{{1, "foo"}, {43, "baz"}})));
}
TEST(HashValueTest, ReferenceWrapper) {
EXPECT_TRUE(is_hashable<std::reference_wrapper<Private>>::value);
Private p1{1}, p10{10};
EXPECT_TRUE(absl::VerifyTypeImplementsAbslHashCorrectly(std::make_tuple(
p1, p10, std::ref(p1), std::ref(p10), std::cref(p1), std::cref(p10))));
EXPECT_TRUE(is_hashable<std::reference_wrapper<int>>::value);
int one = 1, ten = 10;
EXPECT_TRUE(absl::VerifyTypeImplementsAbslHashCorrectly(std::make_tuple(
one, ten, std::ref(one), std::ref(ten), std::cref(one), std::cref(ten))));
EXPECT_TRUE(absl::VerifyTypeImplementsAbslHashCorrectly(
std::make_tuple(std::tuple<std::reference_wrapper<int>>(std::ref(one)),
std::tuple<std::reference_wrapper<int>>(std::ref(ten)),
std::tuple<int>(one), std::tuple<int>(ten))));
}
template <typename T, typename = void>
struct IsHashCallable : std::false_type {};
template <typename T>
struct IsHashCallable<T, absl::void_t<decltype(std::declval<absl::Hash<T>>()(
std::declval<const T&>()))>> : std::true_type {};
template <typename T, typename = void>
struct IsAggregateInitializable : std::false_type {};
template <typename T>
struct IsAggregateInitializable<T, absl::void_t<decltype(T{})>>
: std::true_type {};
TEST(IsHashableTest, ValidHash) {
EXPECT_TRUE((is_hashable<int>::value));
EXPECT_TRUE(std::is_default_constructible<absl::Hash<int>>::value);
EXPECT_TRUE(std::is_copy_constructible<absl::Hash<int>>::value);
EXPECT_TRUE(std::is_move_constructible<absl::Hash<int>>::value);
EXPECT_TRUE(absl::is_copy_assignable<absl::Hash<int>>::value);
EXPECT_TRUE(absl::is_move_assignable<absl::Hash<int>>::value);
EXPECT_TRUE(IsHashCallable<int>::value);
EXPECT_TRUE(IsAggregateInitializable<absl::Hash<int>>::value);
}
#if ABSL_META_INTERNAL_STD_HASH_SFINAE_FRIENDLY_
TEST(IsHashableTest, PoisonHash) {
struct X {};
EXPECT_FALSE((is_hashable<X>::value));
EXPECT_FALSE(std::is_default_constructible<absl::Hash<X>>::value);
EXPECT_FALSE(std::is_copy_constructible<absl::Hash<X>>::value);
EXPECT_FALSE(std::is_move_constructible<absl::Hash<X>>::value);
EXPECT_FALSE(absl::is_copy_assignable<absl::Hash<X>>::value);
EXPECT_FALSE(absl::is_move_assignable<absl::Hash<X>>::value);
EXPECT_FALSE(IsHashCallable<X>::value);
#if !defined(__GNUC__) || __GNUC__ < 9
// This doesn't compile on GCC 9.
EXPECT_FALSE(IsAggregateInitializable<absl::Hash<X>>::value);
#endif
}
#endif // ABSL_META_INTERNAL_STD_HASH_SFINAE_FRIENDLY_
// Hashable types
//
// These types exist simply to exercise various AbslHashValue behaviors, so
// they are named by what their AbslHashValue overload does.
struct NoOp {
template <typename HashCode>
friend HashCode AbslHashValue(HashCode h, NoOp n) {
return h;
}
};
struct EmptyCombine {
template <typename HashCode>
friend HashCode AbslHashValue(HashCode h, EmptyCombine e) {
return HashCode::combine(std::move(h));
}
};
template <typename Int>
struct CombineIterative {
template <typename HashCode>
friend HashCode AbslHashValue(HashCode h, CombineIterative c) {
for (int i = 0; i < 5; ++i) {
h = HashCode::combine(std::move(h), Int(i));
}
return h;
}
};
template <typename Int>
struct CombineVariadic {
template <typename HashCode>
friend HashCode AbslHashValue(HashCode h, CombineVariadic c) {
return HashCode::combine(std::move(h), Int(0), Int(1), Int(2), Int(3),
Int(4));
}
};
enum class InvokeTag {
kUniquelyRepresented,
kHashValue,
#if ABSL_HASH_INTERNAL_SUPPORT_LEGACY_HASH_
kLegacyHash,
#endif // ABSL_HASH_INTERNAL_SUPPORT_LEGACY_HASH_
kStdHash,
kNone
};
template <InvokeTag T>
using InvokeTagConstant = std::integral_constant<InvokeTag, T>;
template <InvokeTag... Tags>
struct MinTag;
template <InvokeTag a, InvokeTag b, InvokeTag... Tags>
struct MinTag<a, b, Tags...> : MinTag<(a < b ? a : b), Tags...> {};
template <InvokeTag a>
struct MinTag<a> : InvokeTagConstant<a> {};
template <InvokeTag... Tags>
struct CustomHashType {
explicit CustomHashType(size_t val) : value(val) {}
size_t value;
};
template <InvokeTag allowed, InvokeTag... tags>
struct EnableIfContained
: std::enable_if<absl::disjunction<
std::integral_constant<bool, allowed == tags>...>::value> {};
template <
typename H, InvokeTag... Tags,
typename = typename EnableIfContained<InvokeTag::kHashValue, Tags...>::type>
H AbslHashValue(H state, CustomHashType<Tags...> t) {
static_assert(MinTag<Tags...>::value == InvokeTag::kHashValue, "");
return H::combine(std::move(state),
t.value + static_cast<int>(InvokeTag::kHashValue));
}
} // namespace
namespace absl {
ABSL_NAMESPACE_BEGIN
namespace hash_internal {
template <InvokeTag... Tags>
struct is_uniquely_represented<
CustomHashType<Tags...>,
typename EnableIfContained<InvokeTag::kUniquelyRepresented, Tags...>::type>
: std::true_type {};
} // namespace hash_internal
ABSL_NAMESPACE_END
} // namespace absl
#if ABSL_HASH_INTERNAL_SUPPORT_LEGACY_HASH_
namespace ABSL_INTERNAL_LEGACY_HASH_NAMESPACE {
template <InvokeTag... Tags>
struct hash<CustomHashType<Tags...>> {
template <InvokeTag... TagsIn, typename = typename EnableIfContained<
InvokeTag::kLegacyHash, TagsIn...>::type>
size_t operator()(CustomHashType<TagsIn...> t) const {
static_assert(MinTag<Tags...>::value == InvokeTag::kLegacyHash, "");
return t.value + static_cast<int>(InvokeTag::kLegacyHash);
}
};
} // namespace ABSL_INTERNAL_LEGACY_HASH_NAMESPACE
#endif // ABSL_HASH_INTERNAL_SUPPORT_LEGACY_HASH_
namespace std {
template <InvokeTag... Tags> // NOLINT
struct hash<CustomHashType<Tags...>> {
template <InvokeTag... TagsIn, typename = typename EnableIfContained<
InvokeTag::kStdHash, TagsIn...>::type>
size_t operator()(CustomHashType<TagsIn...> t) const {
static_assert(MinTag<Tags...>::value == InvokeTag::kStdHash, "");
return t.value + static_cast<int>(InvokeTag::kStdHash);
}
};
} // namespace std
namespace {
template <typename... T>
void TestCustomHashType(InvokeTagConstant<InvokeTag::kNone>, T...) {
using type = CustomHashType<T::value...>;
SCOPED_TRACE(testing::PrintToString(std::vector<InvokeTag>{T::value...}));
EXPECT_TRUE(is_hashable<type>());
EXPECT_TRUE(is_hashable<const type>());
EXPECT_TRUE(is_hashable<const type&>());
const size_t offset = static_cast<int>(std::min({T::value...}));
EXPECT_EQ(SpyHash(type(7)), SpyHash(size_t{7 + offset}));
}
void TestCustomHashType(InvokeTagConstant<InvokeTag::kNone>) {
#if ABSL_META_INTERNAL_STD_HASH_SFINAE_FRIENDLY_
// is_hashable is false if we don't support any of the hooks.
using type = CustomHashType<>;
EXPECT_FALSE(is_hashable<type>());
EXPECT_FALSE(is_hashable<const type>());
EXPECT_FALSE(is_hashable<const type&>());
#endif // ABSL_META_INTERNAL_STD_HASH_SFINAE_FRIENDLY_
}
template <InvokeTag Tag, typename... T>
void TestCustomHashType(InvokeTagConstant<Tag> tag, T... t) {
constexpr auto next = static_cast<InvokeTag>(static_cast<int>(Tag) + 1);
TestCustomHashType(InvokeTagConstant<next>(), tag, t...);
TestCustomHashType(InvokeTagConstant<next>(), t...);
}
TEST(HashTest, CustomHashType) {
TestCustomHashType(InvokeTagConstant<InvokeTag{}>());
}
TEST(HashTest, NoOpsAreEquivalent) {
EXPECT_EQ(Hash<NoOp>()({}), Hash<NoOp>()({}));
EXPECT_EQ(Hash<NoOp>()({}), Hash<EmptyCombine>()({}));
}
template <typename T>
class HashIntTest : public testing::Test {
};
TYPED_TEST_SUITE_P(HashIntTest);
TYPED_TEST_P(HashIntTest, BasicUsage) {
EXPECT_NE(Hash<NoOp>()({}), Hash<TypeParam>()(0));
EXPECT_NE(Hash<NoOp>()({}),
Hash<TypeParam>()(std::numeric_limits<TypeParam>::max()));
if (std::numeric_limits<TypeParam>::min() != 0) {
EXPECT_NE(Hash<NoOp>()({}),
Hash<TypeParam>()(std::numeric_limits<TypeParam>::min()));
}
EXPECT_EQ(Hash<CombineIterative<TypeParam>>()({}),
Hash<CombineVariadic<TypeParam>>()({}));
}
REGISTER_TYPED_TEST_CASE_P(HashIntTest, BasicUsage);
using IntTypes = testing::Types<unsigned char, char, int, int32_t, int64_t, uint32_t,
uint64_t, size_t>;
INSTANTIATE_TYPED_TEST_CASE_P(My, HashIntTest, IntTypes);
struct StructWithPadding {
char c;
int i;
template <typename H>
friend H AbslHashValue(H hash_state, const StructWithPadding& s) {
return H::combine(std::move(hash_state), s.c, s.i);
}
};
static_assert(sizeof(StructWithPadding) > sizeof(char) + sizeof(int),
"StructWithPadding doesn't have padding");
static_assert(std::is_standard_layout<StructWithPadding>::value, "");
// This check has to be disabled because libstdc++ doesn't support it.
// static_assert(std::is_trivially_constructible<StructWithPadding>::value, "");
template <typename T>
struct ArraySlice {
T* begin;
T* end;
template <typename H>
friend H AbslHashValue(H hash_state, const ArraySlice& slice) {
for (auto t = slice.begin; t != slice.end; ++t) {
hash_state = H::combine(std::move(hash_state), *t);
}
return hash_state;
}
};
TEST(HashTest, HashNonUniquelyRepresentedType) {
// Create equal StructWithPadding objects that are known to have non-equal
// padding bytes.
static const size_t kNumStructs = 10;
unsigned char buffer1[kNumStructs * sizeof(StructWithPadding)];
std::memset(buffer1, 0, sizeof(buffer1));
auto* s1 = reinterpret_cast<StructWithPadding*>(buffer1);
unsigned char buffer2[kNumStructs * sizeof(StructWithPadding)];
std::memset(buffer2, 255, sizeof(buffer2));
auto* s2 = reinterpret_cast<StructWithPadding*>(buffer2);
for (int i = 0; i < kNumStructs; ++i) {
SCOPED_TRACE(i);
s1[i].c = s2[i].c = '0' + i;
s1[i].i = s2[i].i = i;
ASSERT_FALSE(memcmp(buffer1 + i * sizeof(StructWithPadding),
buffer2 + i * sizeof(StructWithPadding),
sizeof(StructWithPadding)) == 0)
<< "Bug in test code: objects do not have unequal"
<< " object representations";
}
EXPECT_EQ(Hash<StructWithPadding>()(s1[0]), Hash<StructWithPadding>()(s2[0]));
EXPECT_EQ(Hash<ArraySlice<StructWithPadding>>()({s1, s1 + kNumStructs}),
Hash<ArraySlice<StructWithPadding>>()({s2, s2 + kNumStructs}));
}
TEST(HashTest, StandardHashContainerUsage) {
std::unordered_map<int, std::string, Hash<int>> map = {{0, "foo"},
{42, "bar"}};
EXPECT_NE(map.find(0), map.end());
EXPECT_EQ(map.find(1), map.end());
EXPECT_NE(map.find(0u), map.end());
}
struct ConvertibleFromNoOp {
ConvertibleFromNoOp(NoOp) {} // NOLINT(runtime/explicit)
template <typename H>
friend H AbslHashValue(H hash_state, ConvertibleFromNoOp) {
return H::combine(std::move(hash_state), 1);
}
};
TEST(HashTest, HeterogeneousCall) {
EXPECT_NE(Hash<ConvertibleFromNoOp>()(NoOp()),
Hash<NoOp>()(NoOp()));
}
TEST(IsUniquelyRepresentedTest, SanityTest) {
using absl::hash_internal::is_uniquely_represented;
EXPECT_TRUE(is_uniquely_represented<unsigned char>::value);
EXPECT_TRUE(is_uniquely_represented<int>::value);
EXPECT_FALSE(is_uniquely_represented<bool>::value);
EXPECT_FALSE(is_uniquely_represented<int*>::value);
}
struct IntAndString {
int i;
std::string s;
template <typename H>
friend H AbslHashValue(H hash_state, IntAndString int_and_string) {
return H::combine(std::move(hash_state), int_and_string.s,
int_and_string.i);
}
};
TEST(HashTest, SmallValueOn64ByteBoundary) {
Hash<IntAndString>()(IntAndString{0, std::string(63, '0')});
}
struct TypeErased {
size_t n;
template <typename H>
friend H AbslHashValue(H hash_state, const TypeErased& v) {
v.HashValue(absl::HashState::Create(&hash_state));
return hash_state;
}
void HashValue(absl::HashState state) const {
absl::HashState::combine(std::move(state), n);
}
};
TEST(HashTest, TypeErased) {
EXPECT_TRUE((is_hashable<TypeErased>::value));
EXPECT_TRUE((is_hashable<std::pair<TypeErased, int>>::value));
EXPECT_EQ(SpyHash(TypeErased{7}), SpyHash(size_t{7}));
EXPECT_NE(SpyHash(TypeErased{7}), SpyHash(size_t{13}));
EXPECT_EQ(SpyHash(std::make_pair(TypeErased{7}, 17)),
SpyHash(std::make_pair(size_t{7}, 17)));
}
struct ValueWithBoolConversion {
operator bool() const { return false; }
int i;
};
} // namespace
namespace std {
template <>
struct hash<ValueWithBoolConversion> {
size_t operator()(ValueWithBoolConversion v) { return v.i; }
};
} // namespace std
namespace {
TEST(HashTest, DoesNotUseImplicitConversionsToBool) {
EXPECT_NE(absl::Hash<ValueWithBoolConversion>()(ValueWithBoolConversion{0}),
absl::Hash<ValueWithBoolConversion>()(ValueWithBoolConversion{1}));
}
} // namespace

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// Copyright 2018 The Abseil Authors.
//
// 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
//
// https://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.
#ifndef ABSL_HASH_HASH_TESTING_H_
#define ABSL_HASH_HASH_TESTING_H_
#include <initializer_list>
#include <tuple>
#include <type_traits>
#include <vector>
#include "gmock/gmock.h"
#include "gtest/gtest.h"
#include "absl/hash/internal/spy_hash_state.h"
#include "absl/meta/type_traits.h"
#include "absl/strings/str_cat.h"
#include "absl/types/variant.h"
namespace absl {
ABSL_NAMESPACE_BEGIN
// Run the absl::Hash algorithm over all the elements passed in and verify that
// their hash expansion is congruent with their `==` operator.
//
// It is used in conjunction with EXPECT_TRUE. Failures will output information
// on what requirement failed and on which objects.
//
// Users should pass a collection of types as either an initializer list or a
// container of cases.
//
// EXPECT_TRUE(absl::VerifyTypeImplementsAbslHashCorrectly(
// {v1, v2, ..., vN}));
//
// std::vector<MyType> cases;
// // Fill cases...
// EXPECT_TRUE(absl::VerifyTypeImplementsAbslHashCorrectly(cases));
//
// Users can pass a variety of types for testing heterogeneous lookup with
// `std::make_tuple`:
//
// EXPECT_TRUE(absl::VerifyTypeImplementsAbslHashCorrectly(
// std::make_tuple(v1, v2, ..., vN)));
//
//
// Ideally, the values passed should provide enough coverage of the `==`
// operator and the AbslHashValue implementations.
// For dynamically sized types, the empty state should usually be included in
// the values.
//
// The function accepts an optional comparator function, in case that `==` is
// not enough for the values provided.
//
// Usage:
//
// EXPECT_TRUE(absl::VerifyTypeImplementsAbslHashCorrectly(
// std::make_tuple(v1, v2, ..., vN), MyCustomEq{}));
//
// It checks the following requirements:
// 1. The expansion for a value is deterministic.
// 2. For any two objects `a` and `b` in the sequence, if `a == b` evaluates
// to true, then their hash expansion must be equal.
// 3. If `a == b` evaluates to false their hash expansion must be unequal.
// 4. If `a == b` evaluates to false neither hash expansion can be a
// suffix of the other.
// 5. AbslHashValue overloads should not be called by the user. They are only
// meant to be called by the framework. Users should call H::combine() and
// H::combine_contiguous().
// 6. No moved-from instance of the hash state is used in the implementation
// of AbslHashValue.
//
// The values do not have to have the same type. This can be useful for
// equivalent types that support heterogeneous lookup.
//
// A possible reason for breaking (2) is combining state in the hash expansion
// that was not used in `==`.
// For example:
//
// struct Bad2 {
// int a, b;
// template <typename H>
// friend H AbslHashValue(H state, Bad2 x) {
// // Uses a and b.
// return H::combine(std::move(state), x.a, x.b);
// }
// friend bool operator==(Bad2 x, Bad2 y) {
// // Only uses a.
// return x.a == y.a;
// }
// };
//
// As for (3), breaking this usually means that there is state being passed to
// the `==` operator that is not used in the hash expansion.
// For example:
//
// struct Bad3 {
// int a, b;
// template <typename H>
// friend H AbslHashValue(H state, Bad3 x) {
// // Only uses a.
// return H::combine(std::move(state), x.a);
// }
// friend bool operator==(Bad3 x, Bad3 y) {
// // Uses a and b.
// return x.a == y.a && x.b == y.b;
// }
// };
//
// Finally, a common way to break 4 is by combining dynamic ranges without
// combining the size of the range.
// For example:
//
// struct Bad4 {
// int *p, size;
// template <typename H>
// friend H AbslHashValue(H state, Bad4 x) {
// return H::combine_contiguous(std::move(state), x.p, x.p + x.size);
// }
// friend bool operator==(Bad4 x, Bad4 y) {
// // Compare two ranges for equality. C++14 code can instead use std::equal.
// return absl::equal(x.p, x.p + x.size, y.p, y.p + y.size);
// }
// };
//
// An easy solution to this is to combine the size after combining the range,
// like so:
// template <typename H>
// friend H AbslHashValue(H state, Bad4 x) {
// return H::combine(
// H::combine_contiguous(std::move(state), x.p, x.p + x.size), x.size);
// }
//
template <int&... ExplicitBarrier, typename Container>
ABSL_MUST_USE_RESULT testing::AssertionResult
VerifyTypeImplementsAbslHashCorrectly(const Container& values);
template <int&... ExplicitBarrier, typename Container, typename Eq>
ABSL_MUST_USE_RESULT testing::AssertionResult
VerifyTypeImplementsAbslHashCorrectly(const Container& values, Eq equals);
template <int&..., typename T>
ABSL_MUST_USE_RESULT testing::AssertionResult
VerifyTypeImplementsAbslHashCorrectly(std::initializer_list<T> values);
template <int&..., typename T, typename Eq>
ABSL_MUST_USE_RESULT testing::AssertionResult
VerifyTypeImplementsAbslHashCorrectly(std::initializer_list<T> values,
Eq equals);
namespace hash_internal {
struct PrintVisitor {
size_t index;
template <typename T>
std::string operator()(const T* value) const {
return absl::StrCat("#", index, "(", testing::PrintToString(*value), ")");
}
};
template <typename Eq>
struct EqVisitor {
Eq eq;
template <typename T, typename U>
bool operator()(const T* t, const U* u) const {
return eq(*t, *u);
}
};
struct ExpandVisitor {
template <typename T>
SpyHashState operator()(const T* value) const {
return SpyHashState::combine(SpyHashState(), *value);
}
};
template <typename Container, typename Eq>
ABSL_MUST_USE_RESULT testing::AssertionResult
VerifyTypeImplementsAbslHashCorrectly(const Container& values, Eq equals) {
using V = typename Container::value_type;
struct Info {
const V& value;
size_t index;
std::string ToString() const {
return absl::visit(PrintVisitor{index}, value);
}
SpyHashState expand() const { return absl::visit(ExpandVisitor{}, value); }
};
using EqClass = std::vector<Info>;
std::vector<EqClass> classes;
// Gather the values in equivalence classes.
size_t i = 0;
for (const auto& value : values) {
EqClass* c = nullptr;
for (auto& eqclass : classes) {
if (absl::visit(EqVisitor<Eq>{equals}, value, eqclass[0].value)) {
c = &eqclass;
break;
}
}
if (c == nullptr) {
classes.emplace_back();
c = &classes.back();
}
c->push_back({value, i});
++i;
// Verify potential errors captured by SpyHashState.
if (auto error = c->back().expand().error()) {
return testing::AssertionFailure() << *error;
}
}
if (classes.size() < 2) {
return testing::AssertionFailure()
<< "At least two equivalence classes are expected.";
}
// We assume that equality is correctly implemented.
// Now we verify that AbslHashValue is also correctly implemented.
for (const auto& c : classes) {
// All elements of the equivalence class must have the same hash
// expansion.
const SpyHashState expected = c[0].expand();
for (const Info& v : c) {
if (v.expand() != v.expand()) {
return testing::AssertionFailure()
<< "Hash expansion for " << v.ToString()
<< " is non-deterministic.";
}
if (v.expand() != expected) {
return testing::AssertionFailure()
<< "Values " << c[0].ToString() << " and " << v.ToString()
<< " evaluate as equal but have an unequal hash expansion.";
}
}
// Elements from other classes must have different hash expansion.
for (const auto& c2 : classes) {
if (&c == &c2) continue;
const SpyHashState c2_hash = c2[0].expand();
switch (SpyHashState::Compare(expected, c2_hash)) {
case SpyHashState::CompareResult::kEqual:
return testing::AssertionFailure()
<< "Values " << c[0].ToString() << " and " << c2[0].ToString()
<< " evaluate as unequal but have an equal hash expansion.";
case SpyHashState::CompareResult::kBSuffixA:
return testing::AssertionFailure()
<< "Hash expansion of " << c2[0].ToString()
<< " is a suffix of the hash expansion of " << c[0].ToString()
<< ".";
case SpyHashState::CompareResult::kASuffixB:
return testing::AssertionFailure()
<< "Hash expansion of " << c[0].ToString()
<< " is a suffix of the hash expansion of " << c2[0].ToString()
<< ".";
case SpyHashState::CompareResult::kUnequal:
break;
}
}
}
return testing::AssertionSuccess();
}
template <typename... T>
struct TypeSet {
template <typename U, bool = disjunction<std::is_same<T, U>...>::value>
struct Insert {
using type = TypeSet<U, T...>;
};
template <typename U>
struct Insert<U, true> {
using type = TypeSet;
};
template <template <typename...> class C>
using apply = C<T...>;
};
template <typename... T>
struct MakeTypeSet : TypeSet<> {};
template <typename T, typename... Ts>
struct MakeTypeSet<T, Ts...> : MakeTypeSet<Ts...>::template Insert<T>::type {};
template <typename... T>
using VariantForTypes = typename MakeTypeSet<
const typename std::decay<T>::type*...>::template apply<absl::variant>;
template <typename Container>
struct ContainerAsVector {
using V = absl::variant<const typename Container::value_type*>;
using Out = std::vector<V>;
static Out Do(const Container& values) {
Out out;
for (const auto& v : values) out.push_back(&v);
return out;
}
};
template <typename... T>
struct ContainerAsVector<std::tuple<T...>> {
using V = VariantForTypes<T...>;
using Out = std::vector<V>;
template <size_t... I>
static Out DoImpl(const std::tuple<T...>& tuple, absl::index_sequence<I...>) {
return Out{&std::get<I>(tuple)...};
}
static Out Do(const std::tuple<T...>& values) {
return DoImpl(values, absl::index_sequence_for<T...>());
}
};
template <>
struct ContainerAsVector<std::tuple<>> {
static std::vector<VariantForTypes<int>> Do(std::tuple<>) { return {}; }
};
struct DefaultEquals {
template <typename T, typename U>
bool operator()(const T& t, const U& u) const {
return t == u;
}
};
} // namespace hash_internal
template <int&..., typename Container>
ABSL_MUST_USE_RESULT testing::AssertionResult
VerifyTypeImplementsAbslHashCorrectly(const Container& values) {
return hash_internal::VerifyTypeImplementsAbslHashCorrectly(
hash_internal::ContainerAsVector<Container>::Do(values),
hash_internal::DefaultEquals{});
}
template <int&..., typename Container, typename Eq>
ABSL_MUST_USE_RESULT testing::AssertionResult
VerifyTypeImplementsAbslHashCorrectly(const Container& values, Eq equals) {
return hash_internal::VerifyTypeImplementsAbslHashCorrectly(
hash_internal::ContainerAsVector<Container>::Do(values), equals);
}
template <int&..., typename T>
ABSL_MUST_USE_RESULT testing::AssertionResult
VerifyTypeImplementsAbslHashCorrectly(std::initializer_list<T> values) {
return hash_internal::VerifyTypeImplementsAbslHashCorrectly(
hash_internal::ContainerAsVector<std::initializer_list<T>>::Do(values),
hash_internal::DefaultEquals{});
}
template <int&..., typename T, typename Eq>
ABSL_MUST_USE_RESULT testing::AssertionResult
VerifyTypeImplementsAbslHashCorrectly(std::initializer_list<T> values,
Eq equals) {
return hash_internal::VerifyTypeImplementsAbslHashCorrectly(
hash_internal::ContainerAsVector<std::initializer_list<T>>::Do(values),
equals);
}
ABSL_NAMESPACE_END
} // namespace absl
#endif // ABSL_HASH_HASH_TESTING_H_

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// Copyright 2018 The Abseil Authors.
//
// 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
//
// https://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.
//
// This file provides CityHash64() and related functions.
//
// It's probably possible to create even faster hash functions by
// writing a program that systematically explores some of the space of
// possible hash functions, by using SIMD instructions, or by
// compromising on hash quality.
#include "absl/hash/internal/city.h"
#include <string.h> // for memcpy and memset
#include <algorithm>
#include "absl/base/config.h"
#include "absl/base/internal/endian.h"
#include "absl/base/internal/unaligned_access.h"
#include "absl/base/optimization.h"
namespace absl {
ABSL_NAMESPACE_BEGIN
namespace hash_internal {
#ifdef ABSL_IS_BIG_ENDIAN
#define uint32_in_expected_order(x) (absl::gbswap_32(x))
#define uint64_in_expected_order(x) (absl::gbswap_64(x))
#else
#define uint32_in_expected_order(x) (x)
#define uint64_in_expected_order(x) (x)
#endif
static uint64_t Fetch64(const char *p) {
return uint64_in_expected_order(ABSL_INTERNAL_UNALIGNED_LOAD64(p));
}
static uint32_t Fetch32(const char *p) {
return uint32_in_expected_order(ABSL_INTERNAL_UNALIGNED_LOAD32(p));
}
// Some primes between 2^63 and 2^64 for various uses.
static const uint64_t k0 = 0xc3a5c85c97cb3127ULL;
static const uint64_t k1 = 0xb492b66fbe98f273ULL;
static const uint64_t k2 = 0x9ae16a3b2f90404fULL;
// Magic numbers for 32-bit hashing. Copied from Murmur3.
static const uint32_t c1 = 0xcc9e2d51;
static const uint32_t c2 = 0x1b873593;
// A 32-bit to 32-bit integer hash copied from Murmur3.
static uint32_t fmix(uint32_t h) {
h ^= h >> 16;
h *= 0x85ebca6b;
h ^= h >> 13;
h *= 0xc2b2ae35;
h ^= h >> 16;
return h;
}
static uint32_t Rotate32(uint32_t val, int shift) {
// Avoid shifting by 32: doing so yields an undefined result.
return shift == 0 ? val : ((val >> shift) | (val << (32 - shift)));
}
#undef PERMUTE3
#define PERMUTE3(a, b, c) \
do { \
std::swap(a, b); \
std::swap(a, c); \
} while (0)
static uint32_t Mur(uint32_t a, uint32_t h) {
// Helper from Murmur3 for combining two 32-bit values.
a *= c1;
a = Rotate32(a, 17);
a *= c2;
h ^= a;
h = Rotate32(h, 19);
return h * 5 + 0xe6546b64;
}
static uint32_t Hash32Len13to24(const char *s, size_t len) {
uint32_t a = Fetch32(s - 4 + (len >> 1));
uint32_t b = Fetch32(s + 4);
uint32_t c = Fetch32(s + len - 8);
uint32_t d = Fetch32(s + (len >> 1));
uint32_t e = Fetch32(s);
uint32_t f = Fetch32(s + len - 4);
uint32_t h = len;
return fmix(Mur(f, Mur(e, Mur(d, Mur(c, Mur(b, Mur(a, h)))))));
}
static uint32_t Hash32Len0to4(const char *s, size_t len) {
uint32_t b = 0;
uint32_t c = 9;
for (size_t i = 0; i < len; i++) {
signed char v = s[i];
b = b * c1 + v;
c ^= b;
}
return fmix(Mur(b, Mur(len, c)));
}
static uint32_t Hash32Len5to12(const char *s, size_t len) {
uint32_t a = len, b = len * 5, c = 9, d = b;
a += Fetch32(s);
b += Fetch32(s + len - 4);
c += Fetch32(s + ((len >> 1) & 4));
return fmix(Mur(c, Mur(b, Mur(a, d))));
}
uint32_t CityHash32(const char *s, size_t len) {
if (len <= 24) {
return len <= 12
? (len <= 4 ? Hash32Len0to4(s, len) : Hash32Len5to12(s, len))
: Hash32Len13to24(s, len);
}
// len > 24
uint32_t h = len, g = c1 * len, f = g;
uint32_t a0 = Rotate32(Fetch32(s + len - 4) * c1, 17) * c2;
uint32_t a1 = Rotate32(Fetch32(s + len - 8) * c1, 17) * c2;
uint32_t a2 = Rotate32(Fetch32(s + len - 16) * c1, 17) * c2;
uint32_t a3 = Rotate32(Fetch32(s + len - 12) * c1, 17) * c2;
uint32_t a4 = Rotate32(Fetch32(s + len - 20) * c1, 17) * c2;
h ^= a0;
h = Rotate32(h, 19);
h = h * 5 + 0xe6546b64;
h ^= a2;
h = Rotate32(h, 19);
h = h * 5 + 0xe6546b64;
g ^= a1;
g = Rotate32(g, 19);
g = g * 5 + 0xe6546b64;
g ^= a3;
g = Rotate32(g, 19);
g = g * 5 + 0xe6546b64;
f += a4;
f = Rotate32(f, 19);
f = f * 5 + 0xe6546b64;
size_t iters = (len - 1) / 20;
do {
uint32_t b0 = Rotate32(Fetch32(s) * c1, 17) * c2;
uint32_t b1 = Fetch32(s + 4);
uint32_t b2 = Rotate32(Fetch32(s + 8) * c1, 17) * c2;
uint32_t b3 = Rotate32(Fetch32(s + 12) * c1, 17) * c2;
uint32_t b4 = Fetch32(s + 16);
h ^= b0;
h = Rotate32(h, 18);
h = h * 5 + 0xe6546b64;
f += b1;
f = Rotate32(f, 19);
f = f * c1;
g += b2;
g = Rotate32(g, 18);
g = g * 5 + 0xe6546b64;
h ^= b3 + b1;
h = Rotate32(h, 19);
h = h * 5 + 0xe6546b64;
g ^= b4;
g = absl::gbswap_32(g) * 5;
h += b4 * 5;
h = absl::gbswap_32(h);
f += b0;
PERMUTE3(f, h, g);
s += 20;
} while (--iters != 0);
g = Rotate32(g, 11) * c1;
g = Rotate32(g, 17) * c1;
f = Rotate32(f, 11) * c1;
f = Rotate32(f, 17) * c1;
h = Rotate32(h + g, 19);
h = h * 5 + 0xe6546b64;
h = Rotate32(h, 17) * c1;
h = Rotate32(h + f, 19);
h = h * 5 + 0xe6546b64;
h = Rotate32(h, 17) * c1;
return h;
}
// Bitwise right rotate. Normally this will compile to a single
// instruction, especially if the shift is a manifest constant.
static uint64_t Rotate(uint64_t val, int shift) {
// Avoid shifting by 64: doing so yields an undefined result.
return shift == 0 ? val : ((val >> shift) | (val << (64 - shift)));
}
static uint64_t ShiftMix(uint64_t val) { return val ^ (val >> 47); }
static uint64_t HashLen16(uint64_t u, uint64_t v) {
return Hash128to64(uint128(u, v));
}
static uint64_t HashLen16(uint64_t u, uint64_t v, uint64_t mul) {
// Murmur-inspired hashing.
uint64_t a = (u ^ v) * mul;
a ^= (a >> 47);
uint64_t b = (v ^ a) * mul;
b ^= (b >> 47);
b *= mul;
return b;
}
static uint64_t HashLen0to16(const char *s, size_t len) {
if (len >= 8) {
uint64_t mul = k2 + len * 2;
uint64_t a = Fetch64(s) + k2;
uint64_t b = Fetch64(s + len - 8);
uint64_t c = Rotate(b, 37) * mul + a;
uint64_t d = (Rotate(a, 25) + b) * mul;
return HashLen16(c, d, mul);
}
if (len >= 4) {
uint64_t mul = k2 + len * 2;
uint64_t a = Fetch32(s);
return HashLen16(len + (a << 3), Fetch32(s + len - 4), mul);
}
if (len > 0) {
uint8_t a = s[0];
uint8_t b = s[len >> 1];
uint8_t c = s[len - 1];
uint32_t y = static_cast<uint32_t>(a) + (static_cast<uint32_t>(b) << 8);
uint32_t z = len + (static_cast<uint32_t>(c) << 2);
return ShiftMix(y * k2 ^ z * k0) * k2;
}
return k2;
}
// This probably works well for 16-byte strings as well, but it may be overkill
// in that case.
static uint64_t HashLen17to32(const char *s, size_t len) {
uint64_t mul = k2 + len * 2;
uint64_t a = Fetch64(s) * k1;
uint64_t b = Fetch64(s + 8);
uint64_t c = Fetch64(s + len - 8) * mul;
uint64_t d = Fetch64(s + len - 16) * k2;
return HashLen16(Rotate(a + b, 43) + Rotate(c, 30) + d,
a + Rotate(b + k2, 18) + c, mul);
}
// Return a 16-byte hash for 48 bytes. Quick and dirty.
// Callers do best to use "random-looking" values for a and b.
static std::pair<uint64_t, uint64_t> WeakHashLen32WithSeeds(uint64_t w, uint64_t x,
uint64_t y, uint64_t z,
uint64_t a, uint64_t b) {
a += w;
b = Rotate(b + a + z, 21);
uint64_t c = a;
a += x;
a += y;
b += Rotate(a, 44);
return std::make_pair(a + z, b + c);
}
// Return a 16-byte hash for s[0] ... s[31], a, and b. Quick and dirty.
static std::pair<uint64_t, uint64_t> WeakHashLen32WithSeeds(const char *s, uint64_t a,
uint64_t b) {
return WeakHashLen32WithSeeds(Fetch64(s), Fetch64(s + 8), Fetch64(s + 16),
Fetch64(s + 24), a, b);
}
// Return an 8-byte hash for 33 to 64 bytes.
static uint64_t HashLen33to64(const char *s, size_t len) {
uint64_t mul = k2 + len * 2;
uint64_t a = Fetch64(s) * k2;
uint64_t b = Fetch64(s + 8);
uint64_t c = Fetch64(s + len - 24);
uint64_t d = Fetch64(s + len - 32);
uint64_t e = Fetch64(s + 16) * k2;
uint64_t f = Fetch64(s + 24) * 9;
uint64_t g = Fetch64(s + len - 8);
uint64_t h = Fetch64(s + len - 16) * mul;
uint64_t u = Rotate(a + g, 43) + (Rotate(b, 30) + c) * 9;
uint64_t v = ((a + g) ^ d) + f + 1;
uint64_t w = absl::gbswap_64((u + v) * mul) + h;
uint64_t x = Rotate(e + f, 42) + c;
uint64_t y = (absl::gbswap_64((v + w) * mul) + g) * mul;
uint64_t z = e + f + c;
a = absl::gbswap_64((x + z) * mul + y) + b;
b = ShiftMix((z + a) * mul + d + h) * mul;
return b + x;
}
uint64_t CityHash64(const char *s, size_t len) {
if (len <= 32) {
if (len <= 16) {
return HashLen0to16(s, len);
} else {
return HashLen17to32(s, len);
}
} else if (len <= 64) {
return HashLen33to64(s, len);
}
// For strings over 64 bytes we hash the end first, and then as we
// loop we keep 56 bytes of state: v, w, x, y, and z.
uint64_t x = Fetch64(s + len - 40);
uint64_t y = Fetch64(s + len - 16) + Fetch64(s + len - 56);
uint64_t z = HashLen16(Fetch64(s + len - 48) + len, Fetch64(s + len - 24));
std::pair<uint64_t, uint64_t> v = WeakHashLen32WithSeeds(s + len - 64, len, z);
std::pair<uint64_t, uint64_t> w = WeakHashLen32WithSeeds(s + len - 32, y + k1, x);
x = x * k1 + Fetch64(s);
// Decrease len to the nearest multiple of 64, and operate on 64-byte chunks.
len = (len - 1) & ~static_cast<size_t>(63);
do {
x = Rotate(x + y + v.first + Fetch64(s + 8), 37) * k1;
y = Rotate(y + v.second + Fetch64(s + 48), 42) * k1;
x ^= w.second;
y += v.first + Fetch64(s + 40);
z = Rotate(z + w.first, 33) * k1;
v = WeakHashLen32WithSeeds(s, v.second * k1, x + w.first);
w = WeakHashLen32WithSeeds(s + 32, z + w.second, y + Fetch64(s + 16));
std::swap(z, x);
s += 64;
len -= 64;
} while (len != 0);
return HashLen16(HashLen16(v.first, w.first) + ShiftMix(y) * k1 + z,
HashLen16(v.second, w.second) + x);
}
uint64_t CityHash64WithSeed(const char *s, size_t len, uint64_t seed) {
return CityHash64WithSeeds(s, len, k2, seed);
}
uint64_t CityHash64WithSeeds(const char *s, size_t len, uint64_t seed0,
uint64_t seed1) {
return HashLen16(CityHash64(s, len) - seed0, seed1);
}
} // namespace hash_internal
ABSL_NAMESPACE_END
} // namespace absl

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// Copyright 2018 The Abseil Authors.
//
// 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
//
// https://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.
//
// https://code.google.com/p/cityhash/
//
// This file provides a few functions for hashing strings. All of them are
// high-quality functions in the sense that they pass standard tests such
// as Austin Appleby's SMHasher. They are also fast.
//
// For 64-bit x86 code, on short strings, we don't know of anything faster than
// CityHash64 that is of comparable quality. We believe our nearest competitor
// is Murmur3. For 64-bit x86 code, CityHash64 is an excellent choice for hash
// tables and most other hashing (excluding cryptography).
//
// For 32-bit x86 code, we don't know of anything faster than CityHash32 that
// is of comparable quality. We believe our nearest competitor is Murmur3A.
// (On 64-bit CPUs, it is typically faster to use the other CityHash variants.)
//
// Functions in the CityHash family are not suitable for cryptography.
//
// Please see CityHash's README file for more details on our performance
// measurements and so on.
//
// WARNING: This code has been only lightly tested on big-endian platforms!
// It is known to work well on little-endian platforms that have a small penalty
// for unaligned reads, such as current Intel and AMD moderate-to-high-end CPUs.
// It should work on all 32-bit and 64-bit platforms that allow unaligned reads;
// bug reports are welcome.
//
// By the way, for some hash functions, given strings a and b, the hash
// of a+b is easily derived from the hashes of a and b. This property
// doesn't hold for any hash functions in this file.
#ifndef ABSL_HASH_INTERNAL_CITY_H_
#define ABSL_HASH_INTERNAL_CITY_H_
#include <stdint.h>
#include <stdlib.h> // for size_t.
#include <utility>
#include "absl/base/config.h"
namespace absl {
ABSL_NAMESPACE_BEGIN
namespace hash_internal {
typedef std::pair<uint64_t, uint64_t> uint128;
inline uint64_t Uint128Low64(const uint128 &x) { return x.first; }
inline uint64_t Uint128High64(const uint128 &x) { return x.second; }
// Hash function for a byte array.
uint64_t CityHash64(const char *s, size_t len);
// Hash function for a byte array. For convenience, a 64-bit seed is also
// hashed into the result.
uint64_t CityHash64WithSeed(const char *s, size_t len, uint64_t seed);
// Hash function for a byte array. For convenience, two seeds are also
// hashed into the result.
uint64_t CityHash64WithSeeds(const char *s, size_t len, uint64_t seed0,
uint64_t seed1);
// Hash function for a byte array. Most useful in 32-bit binaries.
uint32_t CityHash32(const char *s, size_t len);
// Hash 128 input bits down to 64 bits of output.
// This is intended to be a reasonably good hash function.
inline uint64_t Hash128to64(const uint128 &x) {
// Murmur-inspired hashing.
const uint64_t kMul = 0x9ddfea08eb382d69ULL;
uint64_t a = (Uint128Low64(x) ^ Uint128High64(x)) * kMul;
a ^= (a >> 47);
uint64_t b = (Uint128High64(x) ^ a) * kMul;
b ^= (b >> 47);
b *= kMul;
return b;
}
} // namespace hash_internal
ABSL_NAMESPACE_END
} // namespace absl
#endif // ABSL_HASH_INTERNAL_CITY_H_

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// Copyright 2018 The Abseil Authors.
//
// 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
//
// https://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.
#include "absl/hash/internal/city.h"
#include <string.h>
#include <cstdio>
#include <iostream>
#include "gtest/gtest.h"
namespace absl {
ABSL_NAMESPACE_BEGIN
namespace hash_internal {
static const uint64_t k0 = 0xc3a5c85c97cb3127ULL;
static const uint64_t kSeed0 = 1234567;
static const uint64_t kSeed1 = k0;
static const int kDataSize = 1 << 20;
static const int kTestSize = 300;
static char data[kDataSize];
// Initialize data to pseudorandom values.
void setup() {
uint64_t a = 9;
uint64_t b = 777;
for (int i = 0; i < kDataSize; i++) {
a += b;
b += a;
a = (a ^ (a >> 41)) * k0;
b = (b ^ (b >> 41)) * k0 + i;
uint8_t u = b >> 37;
memcpy(data + i, &u, 1); // uint8_t -> char
}
}
#define C(x) 0x##x##ULL
static const uint64_t testdata[kTestSize][4] = {
{C(9ae16a3b2f90404f), C(75106db890237a4a), C(3feac5f636039766),
C(dc56d17a)},
{C(541150e87f415e96), C(1aef0d24b3148a1a), C(bacc300e1e82345a),
C(99929334)},
{C(f3786a4b25827c1), C(34ee1a2bf767bd1c), C(2f15ca2ebfb631f2), C(4252edb7)},
{C(ef923a7a1af78eab), C(79163b1e1e9a9b18), C(df3b2aca6e1e4a30),
C(ebc34f3c)},
{C(11df592596f41d88), C(843ec0bce9042f9c), C(cce2ea1e08b1eb30),
C(26f2b463)},
{C(831f448bdc5600b3), C(62a24be3120a6919), C(1b44098a41e010da),
C(b042c047)},
{C(3eca803e70304894), C(d80de767e4a920a), C(a51cfbb292efd53d), C(e73bb0a8)},
{C(1b5a063fb4c7f9f1), C(318dbc24af66dee9), C(10ef7b32d5c719af),
C(91dfdd75)},
{C(a0f10149a0e538d6), C(69d008c20f87419f), C(41b36376185b3e9e),
C(c87f95de)},
{C(fb8d9c70660b910b), C(a45b0cc3476bff1b), C(b28d1996144f0207),
C(3f5538ef)},
{C(236827beae282a46), C(e43970221139c946), C(4f3ac6faa837a3aa),
C(70eb1a1f)},
{C(c385e435136ecf7c), C(d9d17368ff6c4a08), C(1b31eed4e5251a67),
C(cfd63b83)},
{C(e3f6828b6017086d), C(21b4d1900554b3b0), C(bef38be1809e24f1),
C(894a52ef)},
{C(851fff285561dca0), C(4d1277d73cdf416f), C(28ccffa61010ebe2),
C(9cde6a54)},
{C(61152a63595a96d9), C(d1a3a91ef3a7ba45), C(443b6bb4a493ad0c),
C(6c4898d5)},
{C(44473e03be306c88), C(30097761f872472a), C(9fd1b669bfad82d7),
C(13e1978e)},
{C(3ead5f21d344056), C(fb6420393cfb05c3), C(407932394cbbd303), C(51b4ba8)},
{C(6abbfde37ee03b5b), C(83febf188d2cc113), C(cda7b62d94d5b8ee),
C(b6b06e40)},
{C(943e7ed63b3c080), C(1ef207e9444ef7f8), C(ef4a9f9f8c6f9b4a), C(240a2f2)},
{C(d72ce05171ef8a1a), C(c6bd6bd869203894), C(c760e6396455d23a),
C(5dcefc30)},
{C(4182832b52d63735), C(337097e123eea414), C(b5a72ca0456df910),
C(7a48b105)},
{C(d6cdae892584a2cb), C(58de0fa4eca17dcd), C(43df30b8f5f1cb00),
C(fd55007b)},
{C(5c8e90bc267c5ee4), C(e9ae044075d992d9), C(f234cbfd1f0a1e59),
C(6b95894c)},
{C(bbd7f30ac310a6f3), C(b23b570d2666685f), C(fb13fb08c9814fe7),
C(3360e827)},
{C(36a097aa49519d97), C(8204380a73c4065), C(77c2004bdd9e276a), C(45177e0b)},
{C(dc78cb032c49217), C(112464083f83e03a), C(96ae53e28170c0f5), C(7c6fffe4)},
{C(441593e0da922dfe), C(936ef46061469b32), C(204a1921197ddd87),
C(bbc78da4)},
{C(2ba3883d71cc2133), C(72f2bbb32bed1a3c), C(27e1bd96d4843251),
C(c5c25d39)},
{C(f2b6d2adf8423600), C(7514e2f016a48722), C(43045743a50396ba),
C(b6e5d06e)},
{C(38fffe7f3680d63c), C(d513325255a7a6d1), C(31ed47790f6ca62f),
C(6178504e)},
{C(b7477bf0b9ce37c6), C(63b1c580a7fd02a4), C(f6433b9f10a5dac), C(bd4c3637)},
{C(55bdb0e71e3edebd), C(c7ab562bcf0568bc), C(43166332f9ee684f),
C(6e7ac474)},
{C(782fa1b08b475e7), C(fb7138951c61b23b), C(9829105e234fb11e), C(1fb4b518)},
{C(c5dc19b876d37a80), C(15ffcff666cfd710), C(e8c30c72003103e2),
C(31d13d6d)},
{C(5e1141711d2d6706), C(b537f6dee8de6933), C(3af0a1fbbe027c54),
C(26fa72e3)},
{C(782edf6da001234f), C(f48cbd5c66c48f3), C(808754d1e64e2a32), C(6a7433bf)},
{C(d26285842ff04d44), C(8f38d71341eacca9), C(5ca436f4db7a883c),
C(4e6df758)},
{C(c6ab830865a6bae6), C(6aa8e8dd4b98815c), C(efe3846713c371e5),
C(d57f63ea)},
{C(44b3a1929232892), C(61dca0e914fc217), C(a607cc142096b964), C(52ef73b3)},
{C(4b603d7932a8de4f), C(fae64c464b8a8f45), C(8fafab75661d602a), C(3cb36c3)},
{C(4ec0b54cf1566aff), C(30d2c7269b206bf4), C(77c22e82295e1061),
C(72c39bea)},
{C(ed8b7a4b34954ff7), C(56432de31f4ee757), C(85bd3abaa572b155),
C(a65aa25c)},
{C(5d28b43694176c26), C(714cc8bc12d060ae), C(3437726273a83fe6),
C(74740539)},
{C(6a1ef3639e1d202e), C(919bc1bd145ad928), C(30f3f7e48c28a773),
C(c3ae3c26)},
{C(159f4d9e0307b111), C(3e17914a5675a0c), C(af849bd425047b51), C(f29db8a2)},
{C(cc0a840725a7e25b), C(57c69454396e193a), C(976eaf7eee0b4540),
C(1ef4cbf4)},
{C(a2b27ee22f63c3f1), C(9ebde0ce1b3976b2), C(2fe6a92a257af308),
C(a9be6c41)},
{C(d8f2f234899bcab3), C(b10b037297c3a168), C(debea2c510ceda7f), C(fa31801)},
{C(584f28543864844f), C(d7cee9fc2d46f20d), C(a38dca5657387205),
C(8331c5d8)},
{C(a94be46dd9aa41af), C(a57e5b7723d3f9bd), C(34bf845a52fd2f), C(e9876db8)},
{C(9a87bea227491d20), C(a468657e2b9c43e7), C(af9ba60db8d89ef7),
C(27b0604e)},
{C(27688c24958d1a5c), C(e3b4a1c9429cf253), C(48a95811f70d64bc),
C(dcec07f2)},
{C(5d1d37790a1873ad), C(ed9cd4bcc5fa1090), C(ce51cde05d8cd96a),
C(cff0a82a)},
{C(1f03fd18b711eea9), C(566d89b1946d381a), C(6e96e83fc92563ab),
C(fec83621)},
{C(f0316f286cf527b6), C(f84c29538de1aa5a), C(7612ed3c923d4a71), C(743d8dc)},
{C(297008bcb3e3401d), C(61a8e407f82b0c69), C(a4a35bff0524fa0e),
C(64d41d26)},
{C(43c6252411ee3be), C(b4ca1b8077777168), C(2746dc3f7da1737f), C(acd90c81)},
{C(ce38a9a54fad6599), C(6d6f4a90b9e8755e), C(c3ecc79ff105de3f),
C(7c746a4b)},
{C(270a9305fef70cf), C(600193999d884f3a), C(f4d49eae09ed8a1), C(b1047e99)},
{C(e71be7c28e84d119), C(eb6ace59932736e6), C(70c4397807ba12c5),
C(d1fd1068)},
{C(b5b58c24b53aaa19), C(d2a6ab0773dd897f), C(ef762fe01ecb5b97),
C(56486077)},
{C(44dd59bd301995cf), C(3ccabd76493ada1a), C(540db4c87d55ef23),
C(6069be80)},
{C(b4d4789eb6f2630b), C(bf6973263ce8ef0e), C(d1c75c50844b9d3), C(2078359b)},
{C(12807833c463737c), C(58e927ea3b3776b4), C(72dd20ef1c2f8ad0),
C(9ea21004)},
{C(e88419922b87176f), C(bcf32f41a7ddbf6f), C(d6ebefd8085c1a0f),
C(9c9cfe88)},
{C(105191e0ec8f7f60), C(5918dbfcca971e79), C(6b285c8a944767b9),
C(b70a6ddd)},
{C(a5b88bf7399a9f07), C(fca3ddfd96461cc4), C(ebe738fdc0282fc6),
C(dea37298)},
{C(d08c3f5747d84f50), C(4e708b27d1b6f8ac), C(70f70fd734888606),
C(8f480819)},
{C(2f72d12a40044b4b), C(889689352fec53de), C(f03e6ad87eb2f36), C(30b3b16)},
{C(aa1f61fdc5c2e11e), C(c2c56cd11277ab27), C(a1e73069fdf1f94f),
C(f31bc4e8)},
{C(9489b36fe2246244), C(3355367033be74b8), C(5f57c2277cbce516),
C(419f953b)},
{C(358d7c0476a044cd), C(e0b7b47bcbd8854f), C(ffb42ec696705519),
C(20e9e76d)},
{C(b0c48df14275265a), C(9da4448975905efa), C(d716618e414ceb6d),
C(646f0ff8)},
{C(daa70bb300956588), C(410ea6883a240c6d), C(f5c8239fb5673eb3),
C(eeb7eca8)},
{C(4ec97a20b6c4c7c2), C(5913b1cd454f29fd), C(a9629f9daf06d685), C(8112bb9)},
{C(5c3323628435a2e8), C(1bea45ce9e72a6e3), C(904f0a7027ddb52e),
C(85a6d477)},
{C(c1ef26bea260abdb), C(6ee423f2137f9280), C(df2118b946ed0b43),
C(56f76c84)},
{C(6be7381b115d653a), C(ed046190758ea511), C(de6a45ffc3ed1159),
C(9af45d55)},
{C(ae3eece1711b2105), C(14fd3f4027f81a4a), C(abb7e45177d151db),
C(d1c33760)},
{C(376c28588b8fb389), C(6b045e84d8491ed2), C(4e857effb7d4e7dc),
C(c56bbf69)},
{C(58d943503bb6748f), C(419c6c8e88ac70f6), C(586760cbf3d3d368),
C(abecfb9b)},
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{C(4739613234278a49), C(99ea5bcd340bf663), C(258640912e712b12),
C(ef7c0c18)},
{C(420e6c926bc54841), C(96dbbf6f4e7c75cd), C(d8d40fa70c3c67bb),
C(b6ad4b68)},
{C(c8601bab561bc1b7), C(72b26272a0ff869a), C(56fdfc986d6bc3c4),
C(c1e46b17)},
{C(b2d294931a0e20eb), C(284ffd9a0815bc38), C(1f8a103aac9bbe6), C(57b8df25)},
{C(7966f53c37b6c6d7), C(8e6abcfb3aa2b88f), C(7f2e5e0724e5f345),
C(e9fa36d6)},
{C(be9bb0abd03b7368), C(13bca93a3031be55), C(e864f4f52b55b472),
C(8f8daefc)},
{C(a08d128c5f1649be), C(a8166c3dbbe19aad), C(cb9f914f829ec62c), C(6e1bb7e)},
{C(7c386f0ffe0465ac), C(530419c9d843dbf3), C(7450e3a4f72b8d8c),
C(fd0076f0)},
{C(bb362094e7ef4f8), C(ff3c2a48966f9725), C(55152803acd4a7fe), C(899b17b6)},
{C(cd80dea24321eea4), C(52b4fdc8130c2b15), C(f3ea100b154bfb82),
C(e3e84e31)},
{C(d599a04125372c3a), C(313136c56a56f363), C(1e993c3677625832),
C(eef79b6b)},
{C(dbbf541e9dfda0a), C(1479fceb6db4f844), C(31ab576b59062534), C(868e3315)},
{C(c2ee3288be4fe2bf), C(c65d2f5ddf32b92), C(af6ecdf121ba5485), C(4639a426)},
{C(d86603ced1ed4730), C(f9de718aaada7709), C(db8b9755194c6535),
C(f3213646)},
{C(915263c671b28809), C(a815378e7ad762fd), C(abec6dc9b669f559),
C(17f148e9)},
{C(2b67cdd38c307a5e), C(cb1d45bb5c9fe1c), C(800baf2a02ec18ad), C(bfd94880)},
{C(2d107419073b9cd0), C(a96db0740cef8f54), C(ec41ee91b3ecdc1b),
C(bb1fa7f3)},
{C(f3e9487ec0e26dfc), C(1ab1f63224e837fa), C(119983bb5a8125d8), C(88816b1)},
{C(1160987c8fe86f7d), C(879e6db1481eb91b), C(d7dcb802bfe6885d),
C(5c2faeb3)},
{C(eab8112c560b967b), C(97f550b58e89dbae), C(846ed506d304051f),
C(51b5fc6f)},
{C(1addcf0386d35351), C(b5f436561f8f1484), C(85d38e22181c9bb1),
C(33d94752)},
{C(d445ba84bf803e09), C(1216c2497038f804), C(2293216ea2237207),
C(b0c92948)},
{C(37235a096a8be435), C(d9b73130493589c2), C(3b1024f59378d3be),
C(c7171590)},
{C(763ad6ea2fe1c99d), C(cf7af5368ac1e26b), C(4d5e451b3bb8d3d4),
C(240a67fb)},
{C(ea627fc84cd1b857), C(85e372494520071f), C(69ec61800845780b),
C(e1843cd5)},
{C(1f2ffd79f2cdc0c8), C(726a1bc31b337aaa), C(678b7f275ef96434),
C(fda1452b)},
{C(39a9e146ec4b3210), C(f63f75802a78b1ac), C(e2e22539c94741c3),
C(a2cad330)},
{C(74cba303e2dd9d6d), C(692699b83289fad1), C(dfb9aa7874678480),
C(53467e16)},
{C(4cbc2b73a43071e0), C(56c5db4c4ca4e0b7), C(1b275a162f46bd3d),
C(da14a8d0)},
{C(875638b9715d2221), C(d9ba0615c0c58740), C(616d4be2dfe825aa),
C(67333551)},
{C(fb686b2782994a8d), C(edee60693756bb48), C(e6bc3cae0ded2ef5),
C(a0ebd66e)},
{C(ab21d81a911e6723), C(4c31b07354852f59), C(835da384c9384744),
C(4b769593)},
{C(33d013cc0cd46ecf), C(3de726423aea122c), C(116af51117fe21a9),
C(6aa75624)},
{C(8ca92c7cd39fae5d), C(317e620e1bf20f1), C(4f0b33bf2194b97f), C(602a3f96)},
{C(fdde3b03f018f43e), C(38f932946c78660), C(c84084ce946851ee), C(cd183c4d)},
{C(9c8502050e9c9458), C(d6d2a1a69964beb9), C(1675766f480229b5),
C(960a4d07)},
{C(348176ca2fa2fdd2), C(3a89c514cc360c2d), C(9f90b8afb318d6d0),
C(9ae998c4)},
{C(4a3d3dfbbaea130b), C(4e221c920f61ed01), C(553fd6cd1304531f),
C(74e2179d)},
{C(b371f768cdf4edb9), C(bdef2ace6d2de0f0), C(e05b4100f7f1baec),
C(ee9bae25)},
{C(7a1d2e96934f61f), C(eb1760ae6af7d961), C(887eb0da063005df), C(b66edf10)},
{C(8be53d466d4728f2), C(86a5ac8e0d416640), C(984aa464cdb5c8bb),
C(d6209737)},
{C(829677eb03abf042), C(43cad004b6bc2c0), C(f2f224756803971a), C(b994a88)},
{C(754435bae3496fc), C(5707fc006f094dcf), C(8951c86ab19d8e40), C(a05d43c0)},
{C(fda9877ea8e3805f), C(31e868b6ffd521b7), C(b08c90681fb6a0fd),
C(c79f73a8)},
{C(2e36f523ca8f5eb5), C(8b22932f89b27513), C(331cd6ecbfadc1bb),
C(a490aff5)},
{C(21a378ef76828208), C(a5c13037fa841da2), C(506d22a53fbe9812),
C(dfad65b4)},
{C(ccdd5600054b16ca), C(f78846e84204cb7b), C(1f9faec82c24eac9), C(1d07dfb)},
{C(7854468f4e0cabd0), C(3a3f6b4f098d0692), C(ae2423ec7799d30d),
C(416df9a0)},
{C(7f88db5346d8f997), C(88eac9aacc653798), C(68a4d0295f8eefa1),
C(1f8fb9cc)},
{C(bb3fb5fb01d60fcf), C(1b7cc0847a215eb6), C(1246c994437990a1),
C(7abf48e3)},
{C(2e783e1761acd84d), C(39158042bac975a0), C(1cd21c5a8071188d),
C(dea4e3dd)},
{C(392058251cf22acc), C(944ec4475ead4620), C(b330a10b5cb94166),
C(c6064f22)},
{C(adf5c1e5d6419947), C(2a9747bc659d28aa), C(95c5b8cb1f5d62c), C(743bed9c)},
{C(6bc1db2c2bee5aba), C(e63b0ed635307398), C(7b2eca111f30dbbc),
C(fce254d5)},
{C(b00f898229efa508), C(83b7590ad7f6985c), C(2780e70a0592e41d),
C(e47ec9d1)},
{C(b56eb769ce0d9a8c), C(ce196117bfbcaf04), C(b26c3c3797d66165),
C(334a145c)},
{C(70c0637675b94150), C(259e1669305b0a15), C(46e1dd9fd387a58d),
C(adec1e3c)},
{C(74c0b8a6821faafe), C(abac39d7491370e7), C(faf0b2a48a4e6aed),
C(f6a9fbf8)},
{C(5fb5e48ac7b7fa4f), C(a96170f08f5acbc7), C(bbf5c63d4f52a1e5),
C(5398210c)},
};
void TestUnchanging(const uint64_t* expected, int offset, int len) {
EXPECT_EQ(expected[0], CityHash64(data + offset, len));
EXPECT_EQ(expected[3], CityHash32(data + offset, len));
EXPECT_EQ(expected[1], CityHash64WithSeed(data + offset, len, kSeed0));
EXPECT_EQ(expected[2],
CityHash64WithSeeds(data + offset, len, kSeed0, kSeed1));
}
TEST(CityHashTest, Unchanging) {
setup();
int i = 0;
for (; i < kTestSize - 1; i++) {
TestUnchanging(testdata[i], i * i, i);
}
TestUnchanging(testdata[i], 0, kDataSize);
}
} // namespace hash_internal
ABSL_NAMESPACE_END
} // namespace absl

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// Copyright 2018 The Abseil Authors.
//
// 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
//
// https://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.
#include "absl/hash/internal/hash.h"
namespace absl {
ABSL_NAMESPACE_BEGIN
namespace hash_internal {
uint64_t CityHashState::CombineLargeContiguousImpl32(uint64_t state,
const unsigned char* first,
size_t len) {
while (len >= PiecewiseChunkSize()) {
state =
Mix(state, absl::hash_internal::CityHash32(reinterpret_cast<const char*>(first),
PiecewiseChunkSize()));
len -= PiecewiseChunkSize();
first += PiecewiseChunkSize();
}
// Handle the remainder.
return CombineContiguousImpl(state, first, len,
std::integral_constant<int, 4>{});
}
uint64_t CityHashState::CombineLargeContiguousImpl64(uint64_t state,
const unsigned char* first,
size_t len) {
while (len >= PiecewiseChunkSize()) {
state =
Mix(state, absl::hash_internal::CityHash64(reinterpret_cast<const char*>(first),
PiecewiseChunkSize()));
len -= PiecewiseChunkSize();
first += PiecewiseChunkSize();
}
// Handle the remainder.
return CombineContiguousImpl(state, first, len,
std::integral_constant<int, 8>{});
}
ABSL_CONST_INIT const void* const CityHashState::kSeed = &kSeed;
} // namespace hash_internal
ABSL_NAMESPACE_END
} // namespace absl

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// Copyright 2018 The Abseil Authors.
//
// 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
//
// https://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.
//
// -----------------------------------------------------------------------------
// File: hash.h
// -----------------------------------------------------------------------------
//
#ifndef ABSL_HASH_INTERNAL_HASH_H_
#define ABSL_HASH_INTERNAL_HASH_H_
#include <algorithm>
#include <array>
#include <cmath>
#include <cstring>
#include <deque>
#include <forward_list>
#include <functional>
#include <iterator>
#include <limits>
#include <list>
#include <map>
#include <memory>
#include <set>
#include <string>
#include <tuple>
#include <type_traits>
#include <utility>
#include <vector>
#include "absl/base/internal/endian.h"
#include "absl/base/port.h"
#include "absl/container/fixed_array.h"
#include "absl/meta/type_traits.h"
#include "absl/numeric/int128.h"
#include "absl/strings/string_view.h"
#include "absl/types/optional.h"
#include "absl/types/variant.h"
#include "absl/utility/utility.h"
#include "absl/hash/internal/city.h"
namespace absl {
ABSL_NAMESPACE_BEGIN
namespace hash_internal {
// Internal detail: Large buffers are hashed in smaller chunks. This function
// returns the size of these chunks.
constexpr size_t PiecewiseChunkSize() { return 1024; }
// PiecewiseCombiner
//
// PiecewiseCombiner is an internal-only helper class for hashing a piecewise
// buffer of `char` or `unsigned char` as though it were contiguous. This class
// provides two methods:
//
// H add_buffer(state, data, size)
// H finalize(state)
//
// `add_buffer` can be called zero or more times, followed by a single call to
// `finalize`. This will produce the same hash expansion as concatenating each
// buffer piece into a single contiguous buffer, and passing this to
// `H::combine_contiguous`.
//
// Example usage:
// PiecewiseCombiner combiner;
// for (const auto& piece : pieces) {
// state = combiner.add_buffer(std::move(state), piece.data, piece.size);
// }
// return combiner.finalize(std::move(state));
class PiecewiseCombiner {
public:
PiecewiseCombiner() : position_(0) {}
PiecewiseCombiner(const PiecewiseCombiner&) = delete;
PiecewiseCombiner& operator=(const PiecewiseCombiner&) = delete;
// PiecewiseCombiner::add_buffer()
//
// Appends the given range of bytes to the sequence to be hashed, which may
// modify the provided hash state.
template <typename H>
H add_buffer(H state, const unsigned char* data, size_t size);
template <typename H>
H add_buffer(H state, const char* data, size_t size) {
return add_buffer(std::move(state),
reinterpret_cast<const unsigned char*>(data), size);
}
// PiecewiseCombiner::finalize()
//
// Finishes combining the hash sequence, which may may modify the provided
// hash state.
//
// Once finalize() is called, add_buffer() may no longer be called. The
// resulting hash state will be the same as if the pieces passed to
// add_buffer() were concatenated into a single flat buffer, and then provided
// to H::combine_contiguous().
template <typename H>
H finalize(H state);
private:
unsigned char buf_[PiecewiseChunkSize()];
size_t position_;
};
// HashStateBase
//
// A hash state object represents an intermediate state in the computation
// of an unspecified hash algorithm. `HashStateBase` provides a CRTP style
// base class for hash state implementations. Developers adding type support
// for `absl::Hash` should not rely on any parts of the state object other than
// the following member functions:
//
// * HashStateBase::combine()
// * HashStateBase::combine_contiguous()
//
// A derived hash state class of type `H` must provide a static member function
// with a signature similar to the following:
//
// `static H combine_contiguous(H state, const unsigned char*, size_t)`.
//
// `HashStateBase` will provide a complete implementation for a hash state
// object in terms of this method.
//
// Example:
//
// // Use CRTP to define your derived class.
// struct MyHashState : HashStateBase<MyHashState> {
// static H combine_contiguous(H state, const unsigned char*, size_t);
// using MyHashState::HashStateBase::combine;
// using MyHashState::HashStateBase::combine_contiguous;
// };
template <typename H>
class HashStateBase {
public:
// HashStateBase::combine()
//
// Combines an arbitrary number of values into a hash state, returning the
// updated state.
//
// Each of the value types `T` must be separately hashable by the Abseil
// hashing framework.
//
// NOTE:
//
// state = H::combine(std::move(state), value1, value2, value3);
//
// is guaranteed to produce the same hash expansion as:
//
// state = H::combine(std::move(state), value1);
// state = H::combine(std::move(state), value2);
// state = H::combine(std::move(state), value3);
template <typename T, typename... Ts>
static H combine(H state, const T& value, const Ts&... values);
static H combine(H state) { return state; }
// HashStateBase::combine_contiguous()
//
// Combines a contiguous array of `size` elements into a hash state, returning
// the updated state.
//
// NOTE:
//
// state = H::combine_contiguous(std::move(state), data, size);
//
// is NOT guaranteed to produce the same hash expansion as a for-loop (it may
// perform internal optimizations). If you need this guarantee, use the
// for-loop instead.
template <typename T>
static H combine_contiguous(H state, const T* data, size_t size);
using AbslInternalPiecewiseCombiner = PiecewiseCombiner;
};
// is_uniquely_represented
//
// `is_uniquely_represented<T>` is a trait class that indicates whether `T`
// is uniquely represented.
//
// A type is "uniquely represented" if two equal values of that type are
// guaranteed to have the same bytes in their underlying storage. In other
// words, if `a == b`, then `memcmp(&a, &b, sizeof(T))` is guaranteed to be
// zero. This property cannot be detected automatically, so this trait is false
// by default, but can be specialized by types that wish to assert that they are
// uniquely represented. This makes them eligible for certain optimizations.
//
// If you have any doubt whatsoever, do not specialize this template.
// The default is completely safe, and merely disables some optimizations
// that will not matter for most types. Specializing this template,
// on the other hand, can be very hazardous.
//
// To be uniquely represented, a type must not have multiple ways of
// representing the same value; for example, float and double are not
// uniquely represented, because they have distinct representations for
// +0 and -0. Furthermore, the type's byte representation must consist
// solely of user-controlled data, with no padding bits and no compiler-
// controlled data such as vptrs or sanitizer metadata. This is usually
// very difficult to guarantee, because in most cases the compiler can
// insert data and padding bits at its own discretion.
//
// If you specialize this template for a type `T`, you must do so in the file
// that defines that type (or in this file). If you define that specialization
// anywhere else, `is_uniquely_represented<T>` could have different meanings
// in different places.
//
// The Enable parameter is meaningless; it is provided as a convenience,
// to support certain SFINAE techniques when defining specializations.
template <typename T, typename Enable = void>
struct is_uniquely_represented : std::false_type {};
// is_uniquely_represented<unsigned char>
//
// unsigned char is a synonym for "byte", so it is guaranteed to be
// uniquely represented.
template <>
struct is_uniquely_represented<unsigned char> : std::true_type {};
// is_uniquely_represented for non-standard integral types
//
// Integral types other than bool should be uniquely represented on any
// platform that this will plausibly be ported to.
template <typename Integral>
struct is_uniquely_represented<
Integral, typename std::enable_if<std::is_integral<Integral>::value>::type>
: std::true_type {};
// is_uniquely_represented<bool>
//
//
template <>
struct is_uniquely_represented<bool> : std::false_type {};
// hash_bytes()
//
// Convenience function that combines `hash_state` with the byte representation
// of `value`.
template <typename H, typename T>
H hash_bytes(H hash_state, const T& value) {
const unsigned char* start = reinterpret_cast<const unsigned char*>(&value);
return H::combine_contiguous(std::move(hash_state), start, sizeof(value));
}
// -----------------------------------------------------------------------------
// AbslHashValue for Basic Types
// -----------------------------------------------------------------------------
// Note: Default `AbslHashValue` implementations live in `hash_internal`. This
// allows us to block lexical scope lookup when doing an unqualified call to
// `AbslHashValue` below. User-defined implementations of `AbslHashValue` can
// only be found via ADL.
// AbslHashValue() for hashing bool values
//
// We use SFINAE to ensure that this overload only accepts bool, not types that
// are convertible to bool.
template <typename H, typename B>
typename std::enable_if<std::is_same<B, bool>::value, H>::type AbslHashValue(
H hash_state, B value) {
return H::combine(std::move(hash_state),
static_cast<unsigned char>(value ? 1 : 0));
}
// AbslHashValue() for hashing enum values
template <typename H, typename Enum>
typename std::enable_if<std::is_enum<Enum>::value, H>::type AbslHashValue(
H hash_state, Enum e) {
// In practice, we could almost certainly just invoke hash_bytes directly,
// but it's possible that a sanitizer might one day want to
// store data in the unused bits of an enum. To avoid that risk, we
// convert to the underlying type before hashing. Hopefully this will get
// optimized away; if not, we can reopen discussion with c-toolchain-team.
return H::combine(std::move(hash_state),
static_cast<typename std::underlying_type<Enum>::type>(e));
}
// AbslHashValue() for hashing floating-point values
template <typename H, typename Float>
typename std::enable_if<std::is_same<Float, float>::value ||
std::is_same<Float, double>::value,
H>::type
AbslHashValue(H hash_state, Float value) {
return hash_internal::hash_bytes(std::move(hash_state),
value == 0 ? 0 : value);
}
// Long double has the property that it might have extra unused bytes in it.
// For example, in x86 sizeof(long double)==16 but it only really uses 80-bits
// of it. This means we can't use hash_bytes on a long double and have to
// convert it to something else first.
template <typename H, typename LongDouble>
typename std::enable_if<std::is_same<LongDouble, long double>::value, H>::type
AbslHashValue(H hash_state, LongDouble value) {
const int category = std::fpclassify(value);
switch (category) {
case FP_INFINITE:
// Add the sign bit to differentiate between +Inf and -Inf
hash_state = H::combine(std::move(hash_state), std::signbit(value));
break;
case FP_NAN:
case FP_ZERO:
default:
// Category is enough for these.
break;
case FP_NORMAL:
case FP_SUBNORMAL:
// We can't convert `value` directly to double because this would have
// undefined behavior if the value is out of range.
// std::frexp gives us a value in the range (-1, -.5] or [.5, 1) that is
// guaranteed to be in range for `double`. The truncation is
// implementation defined, but that works as long as it is deterministic.
int exp;
auto mantissa = static_cast<double>(std::frexp(value, &exp));
hash_state = H::combine(std::move(hash_state), mantissa, exp);
}
return H::combine(std::move(hash_state), category);
}
// AbslHashValue() for hashing pointers
template <typename H, typename T>
H AbslHashValue(H hash_state, T* ptr) {
auto v = reinterpret_cast<uintptr_t>(ptr);
// Due to alignment, pointers tend to have low bits as zero, and the next few
// bits follow a pattern since they are also multiples of some base value.
// Mixing the pointer twice helps prevent stuck low bits for certain alignment
// values.
return H::combine(std::move(hash_state), v, v);
}
// AbslHashValue() for hashing nullptr_t
template <typename H>
H AbslHashValue(H hash_state, std::nullptr_t) {
return H::combine(std::move(hash_state), static_cast<void*>(nullptr));
}
// -----------------------------------------------------------------------------
// AbslHashValue for Composite Types
// -----------------------------------------------------------------------------
// is_hashable()
//
// Trait class which returns true if T is hashable by the absl::Hash framework.
// Used for the AbslHashValue implementations for composite types below.
template <typename T>
struct is_hashable;
// AbslHashValue() for hashing pairs
template <typename H, typename T1, typename T2>
typename std::enable_if<is_hashable<T1>::value && is_hashable<T2>::value,
H>::type
AbslHashValue(H hash_state, const std::pair<T1, T2>& p) {
return H::combine(std::move(hash_state), p.first, p.second);
}
// hash_tuple()
//
// Helper function for hashing a tuple. The third argument should
// be an index_sequence running from 0 to tuple_size<Tuple> - 1.
template <typename H, typename Tuple, size_t... Is>
H hash_tuple(H hash_state, const Tuple& t, absl::index_sequence<Is...>) {
return H::combine(std::move(hash_state), std::get<Is>(t)...);
}
// AbslHashValue for hashing tuples
template <typename H, typename... Ts>
#if defined(_MSC_VER)
// This SFINAE gets MSVC confused under some conditions. Let's just disable it
// for now.
H
#else // _MSC_VER
typename std::enable_if<absl::conjunction<is_hashable<Ts>...>::value, H>::type
#endif // _MSC_VER
AbslHashValue(H hash_state, const std::tuple<Ts...>& t) {
return hash_internal::hash_tuple(std::move(hash_state), t,
absl::make_index_sequence<sizeof...(Ts)>());
}
// -----------------------------------------------------------------------------
// AbslHashValue for Pointers
// -----------------------------------------------------------------------------
// AbslHashValue for hashing unique_ptr
template <typename H, typename T, typename D>
H AbslHashValue(H hash_state, const std::unique_ptr<T, D>& ptr) {
return H::combine(std::move(hash_state), ptr.get());
}
// AbslHashValue for hashing shared_ptr
template <typename H, typename T>
H AbslHashValue(H hash_state, const std::shared_ptr<T>& ptr) {
return H::combine(std::move(hash_state), ptr.get());
}
// -----------------------------------------------------------------------------
// AbslHashValue for String-Like Types
// -----------------------------------------------------------------------------
// AbslHashValue for hashing strings
//
// All the string-like types supported here provide the same hash expansion for
// the same character sequence. These types are:
//
// - `absl::Cord`
// - `std::string` (and std::basic_string<char, std::char_traits<char>, A> for
// any allocator A)
// - `absl::string_view` and `std::string_view`
//
// For simplicity, we currently support only `char` strings. This support may
// be broadened, if necessary, but with some caution - this overload would
// misbehave in cases where the traits' `eq()` member isn't equivalent to `==`
// on the underlying character type.
template <typename H>
H AbslHashValue(H hash_state, absl::string_view str) {
return H::combine(
H::combine_contiguous(std::move(hash_state), str.data(), str.size()),
str.size());
}
// Support std::wstring, std::u16string and std::u32string.
template <typename Char, typename Alloc, typename H,
typename = absl::enable_if_t<std::is_same<Char, wchar_t>::value ||
std::is_same<Char, char16_t>::value ||
std::is_same<Char, char32_t>::value>>
H AbslHashValue(
H hash_state,
const std::basic_string<Char, std::char_traits<Char>, Alloc>& str) {
return H::combine(
H::combine_contiguous(std::move(hash_state), str.data(), str.size()),
str.size());
}
// -----------------------------------------------------------------------------
// AbslHashValue for Sequence Containers
// -----------------------------------------------------------------------------
// AbslHashValue for hashing std::array
template <typename H, typename T, size_t N>
typename std::enable_if<is_hashable<T>::value, H>::type AbslHashValue(
H hash_state, const std::array<T, N>& array) {
return H::combine_contiguous(std::move(hash_state), array.data(),
array.size());
}
// AbslHashValue for hashing std::deque
template <typename H, typename T, typename Allocator>
typename std::enable_if<is_hashable<T>::value, H>::type AbslHashValue(
H hash_state, const std::deque<T, Allocator>& deque) {
// TODO(gromer): investigate a more efficient implementation taking
// advantage of the chunk structure.
for (const auto& t : deque) {
hash_state = H::combine(std::move(hash_state), t);
}
return H::combine(std::move(hash_state), deque.size());
}
// AbslHashValue for hashing std::forward_list
template <typename H, typename T, typename Allocator>
typename std::enable_if<is_hashable<T>::value, H>::type AbslHashValue(
H hash_state, const std::forward_list<T, Allocator>& list) {
size_t size = 0;
for (const T& t : list) {
hash_state = H::combine(std::move(hash_state), t);
++size;
}
return H::combine(std::move(hash_state), size);
}
// AbslHashValue for hashing std::list
template <typename H, typename T, typename Allocator>
typename std::enable_if<is_hashable<T>::value, H>::type AbslHashValue(
H hash_state, const std::list<T, Allocator>& list) {
for (const auto& t : list) {
hash_state = H::combine(std::move(hash_state), t);
}
return H::combine(std::move(hash_state), list.size());
}
// AbslHashValue for hashing std::vector
//
// Do not use this for vector<bool>. It does not have a .data(), and a fallback
// for std::hash<> is most likely faster.
template <typename H, typename T, typename Allocator>
typename std::enable_if<is_hashable<T>::value && !std::is_same<T, bool>::value,
H>::type
AbslHashValue(H hash_state, const std::vector<T, Allocator>& vector) {
return H::combine(H::combine_contiguous(std::move(hash_state), vector.data(),
vector.size()),
vector.size());
}
// -----------------------------------------------------------------------------
// AbslHashValue for Ordered Associative Containers
// -----------------------------------------------------------------------------
// AbslHashValue for hashing std::map
template <typename H, typename Key, typename T, typename Compare,
typename Allocator>
typename std::enable_if<is_hashable<Key>::value && is_hashable<T>::value,
H>::type
AbslHashValue(H hash_state, const std::map<Key, T, Compare, Allocator>& map) {
for (const auto& t : map) {
hash_state = H::combine(std::move(hash_state), t);
}
return H::combine(std::move(hash_state), map.size());
}
// AbslHashValue for hashing std::multimap
template <typename H, typename Key, typename T, typename Compare,
typename Allocator>
typename std::enable_if<is_hashable<Key>::value && is_hashable<T>::value,
H>::type
AbslHashValue(H hash_state,
const std::multimap<Key, T, Compare, Allocator>& map) {
for (const auto& t : map) {
hash_state = H::combine(std::move(hash_state), t);
}
return H::combine(std::move(hash_state), map.size());
}
// AbslHashValue for hashing std::set
template <typename H, typename Key, typename Compare, typename Allocator>
typename std::enable_if<is_hashable<Key>::value, H>::type AbslHashValue(
H hash_state, const std::set<Key, Compare, Allocator>& set) {
for (const auto& t : set) {
hash_state = H::combine(std::move(hash_state), t);
}
return H::combine(std::move(hash_state), set.size());
}
// AbslHashValue for hashing std::multiset
template <typename H, typename Key, typename Compare, typename Allocator>
typename std::enable_if<is_hashable<Key>::value, H>::type AbslHashValue(
H hash_state, const std::multiset<Key, Compare, Allocator>& set) {
for (const auto& t : set) {
hash_state = H::combine(std::move(hash_state), t);
}
return H::combine(std::move(hash_state), set.size());
}
// -----------------------------------------------------------------------------
// AbslHashValue for Wrapper Types
// -----------------------------------------------------------------------------
// AbslHashValue for hashing std::reference_wrapper
template <typename H, typename T>
typename std::enable_if<is_hashable<T>::value, H>::type AbslHashValue(
H hash_state, std::reference_wrapper<T> opt) {
return H::combine(std::move(hash_state), opt.get());
}
// AbslHashValue for hashing absl::optional
template <typename H, typename T>
typename std::enable_if<is_hashable<T>::value, H>::type AbslHashValue(
H hash_state, const absl::optional<T>& opt) {
if (opt) hash_state = H::combine(std::move(hash_state), *opt);
return H::combine(std::move(hash_state), opt.has_value());
}
// VariantVisitor
template <typename H>
struct VariantVisitor {
H&& hash_state;
template <typename T>
H operator()(const T& t) const {
return H::combine(std::move(hash_state), t);
}
};
// AbslHashValue for hashing absl::variant
template <typename H, typename... T>
typename std::enable_if<conjunction<is_hashable<T>...>::value, H>::type
AbslHashValue(H hash_state, const absl::variant<T...>& v) {
if (!v.valueless_by_exception()) {
hash_state = absl::visit(VariantVisitor<H>{std::move(hash_state)}, v);
}
return H::combine(std::move(hash_state), v.index());
}
// -----------------------------------------------------------------------------
// AbslHashValue for Other Types
// -----------------------------------------------------------------------------
// AbslHashValue for hashing std::bitset is not defined, for the same reason as
// for vector<bool> (see std::vector above): It does not expose the raw bytes,
// and a fallback to std::hash<> is most likely faster.
// -----------------------------------------------------------------------------
// hash_range_or_bytes()
//
// Mixes all values in the range [data, data+size) into the hash state.
// This overload accepts only uniquely-represented types, and hashes them by
// 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;
}
#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
// HashSelect
//
// Type trait to select the appropriate hash implementation to use.
// HashSelect::type<T> will give the proper hash implementation, to be invoked
// as:
// HashSelect::type<T>::Invoke(state, value)
// Also, HashSelect::type<T>::value is a boolean equal to `true` if there is a
// valid `Invoke` function. Types that are not hashable will have a ::value of
// `false`.
struct HashSelect {
private:
struct State : HashStateBase<State> {
static State combine_contiguous(State hash_state, const unsigned char*,
size_t);
using State::HashStateBase::combine_contiguous;
};
struct UniquelyRepresentedProbe {
template <typename H, typename T>
static auto Invoke(H state, const T& value)
-> absl::enable_if_t<is_uniquely_represented<T>::value, H> {
return hash_internal::hash_bytes(std::move(state), value);
}
};
struct HashValueProbe {
template <typename H, typename T>
static auto Invoke(H state, const T& value) -> absl::enable_if_t<
std::is_same<H,
decltype(AbslHashValue(std::move(state), value))>::value,
H> {
return AbslHashValue(std::move(state), value);
}
};
struct LegacyHashProbe {
#if ABSL_HASH_INTERNAL_SUPPORT_LEGACY_HASH_
template <typename H, typename T>
static auto Invoke(H state, const T& value) -> absl::enable_if_t<
std::is_convertible<
decltype(ABSL_INTERNAL_LEGACY_HASH_NAMESPACE::hash<T>()(value)),
size_t>::value,
H> {
return hash_internal::hash_bytes(
std::move(state),
ABSL_INTERNAL_LEGACY_HASH_NAMESPACE::hash<T>{}(value));
}
#endif // ABSL_HASH_INTERNAL_SUPPORT_LEGACY_HASH_
};
struct StdHashProbe {
template <typename H, typename T>
static auto Invoke(H state, const T& value)
-> absl::enable_if_t<type_traits_internal::IsHashable<T>::value, H> {
return hash_internal::hash_bytes(std::move(state), std::hash<T>{}(value));
}
};
template <typename Hash, typename T>
struct Probe : Hash {
private:
template <typename H, typename = decltype(H::Invoke(
std::declval<State>(), std::declval<const T&>()))>
static std::true_type Test(int);
template <typename U>
static std::false_type Test(char);
public:
static constexpr bool value = decltype(Test<Hash>(0))::value;
};
public:
// Probe each implementation in order.
// disjunction provides short circuiting wrt instantiation.
template <typename T>
using Apply = absl::disjunction< //
Probe<UniquelyRepresentedProbe, T>, //
Probe<HashValueProbe, T>, //
Probe<LegacyHashProbe, T>, //
Probe<StdHashProbe, T>, //
std::false_type>;
};
template <typename T>
struct is_hashable
: std::integral_constant<bool, HashSelect::template Apply<T>::value> {};
// CityHashState
class ABSL_DLL 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*/);
// Slow dispatch path for calls to CombineContiguousImpl with a size argument
// larger than PiecewiseChunkSize(). Has the same effect as calling
// CombineContiguousImpl() repeatedly with the chunk stride size.
static uint64_t CombineLargeContiguousImpl32(uint64_t state,
const unsigned char* first,
size_t len);
static uint64_t CombineLargeContiguousImpl64(uint64_t state,
const unsigned char* first,
size_t len);
// 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) {
if (ABSL_PREDICT_FALSE(len > PiecewiseChunkSize())) {
return CombineLargeContiguousImpl32(state, first, len);
}
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) {
if (ABSL_PREDICT_FALSE(len > PiecewiseChunkSize())) {
return CombineLargeContiguousImpl64(state, first, len);
}
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::HashSelect::template Apply<T>::Invoke(
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);
}
// HashStateBase::PiecewiseCombiner::add_buffer()
template <typename H>
H PiecewiseCombiner::add_buffer(H state, const unsigned char* data,
size_t size) {
if (position_ + size < PiecewiseChunkSize()) {
// This partial chunk does not fill our existing buffer
memcpy(buf_ + position_, data, size);
position_ += size;
return state;
}
// If the buffer is partially filled we need to complete the buffer
// and hash it.
if (position_ != 0) {
const size_t bytes_needed = PiecewiseChunkSize() - position_;
memcpy(buf_ + position_, data, bytes_needed);
state = H::combine_contiguous(std::move(state), buf_, PiecewiseChunkSize());
data += bytes_needed;
size -= bytes_needed;
}
// Hash whatever chunks we can without copying
while (size >= PiecewiseChunkSize()) {
state = H::combine_contiguous(std::move(state), data, PiecewiseChunkSize());
data += PiecewiseChunkSize();
size -= PiecewiseChunkSize();
}
// Fill the buffer with the remainder
memcpy(buf_, data, size);
position_ = size;
return state;
}
// HashStateBase::PiecewiseCombiner::finalize()
template <typename H>
H PiecewiseCombiner::finalize(H state) {
// Hash the remainder left in the buffer, which may be empty
return H::combine_contiguous(std::move(state), buf_, position_);
}
} // namespace hash_internal
ABSL_NAMESPACE_END
} // namespace absl
#endif // ABSL_HASH_INTERNAL_HASH_H_

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// Copyright 2018 The Abseil Authors.
//
// 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
//
// https://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.
#include <cstdlib>
#include "absl/hash/hash.h"
// Prints the hash of argv[1].
int main(int argc, char** argv) {
if (argc < 2) return 1;
printf("%zu\n", absl::Hash<int>{}(std::atoi(argv[1]))); // NOLINT
}

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// Copyright 2018 The Abseil Authors.
//
// 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
//
// https://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.
#ifndef ABSL_HASH_INTERNAL_SPY_HASH_STATE_H_
#define ABSL_HASH_INTERNAL_SPY_HASH_STATE_H_
#include <ostream>
#include <string>
#include <vector>
#include "absl/hash/hash.h"
#include "absl/strings/match.h"
#include "absl/strings/str_format.h"
#include "absl/strings/str_join.h"
namespace absl {
ABSL_NAMESPACE_BEGIN
namespace hash_internal {
// SpyHashState is an implementation of the HashState API that simply
// accumulates all input bytes in an internal buffer. This makes it useful
// for testing AbslHashValue overloads (so long as they are templated on the
// HashState parameter), since it can report the exact hash representation
// that the AbslHashValue overload produces.
//
// Sample usage:
// EXPECT_EQ(SpyHashState::combine(SpyHashState(), foo),
// SpyHashState::combine(SpyHashState(), bar));
template <typename T>
class SpyHashStateImpl : public HashStateBase<SpyHashStateImpl<T>> {
public:
SpyHashStateImpl() : error_(std::make_shared<absl::optional<std::string>>()) {
static_assert(std::is_void<T>::value, "");
}
// Move-only
SpyHashStateImpl(const SpyHashStateImpl&) = delete;
SpyHashStateImpl& operator=(const SpyHashStateImpl&) = delete;
SpyHashStateImpl(SpyHashStateImpl&& other) noexcept {
*this = std::move(other);
}
SpyHashStateImpl& operator=(SpyHashStateImpl&& other) noexcept {
hash_representation_ = std::move(other.hash_representation_);
error_ = other.error_;
moved_from_ = other.moved_from_;
other.moved_from_ = true;
return *this;
}
template <typename U>
SpyHashStateImpl(SpyHashStateImpl<U>&& other) { // NOLINT
hash_representation_ = std::move(other.hash_representation_);
error_ = other.error_;
moved_from_ = other.moved_from_;
other.moved_from_ = true;
}
template <typename A, typename... Args>
static SpyHashStateImpl combine(SpyHashStateImpl s, const A& a,
const Args&... args) {
// Pass an instance of SpyHashStateImpl<A> when trying to combine `A`. This
// allows us to test that the user only uses this instance for combine calls
// and does not call AbslHashValue directly.
// See AbslHashValue implementation at the bottom.
s = SpyHashStateImpl<A>::HashStateBase::combine(std::move(s), a);
return SpyHashStateImpl::combine(std::move(s), args...);
}
static SpyHashStateImpl combine(SpyHashStateImpl s) {
if (direct_absl_hash_value_error_) {
*s.error_ = "AbslHashValue should not be invoked directly.";
} else if (s.moved_from_) {
*s.error_ = "Used moved-from instance of the hash state object.";
}
return s;
}
static void SetDirectAbslHashValueError() {
direct_absl_hash_value_error_ = true;
}
// Two SpyHashStateImpl objects are equal if they hold equal hash
// representations.
friend bool operator==(const SpyHashStateImpl& lhs,
const SpyHashStateImpl& rhs) {
return lhs.hash_representation_ == rhs.hash_representation_;
}
friend bool operator!=(const SpyHashStateImpl& lhs,
const SpyHashStateImpl& rhs) {
return !(lhs == rhs);
}
enum class CompareResult {
kEqual,
kASuffixB,
kBSuffixA,
kUnequal,
};
static CompareResult Compare(const SpyHashStateImpl& a,
const SpyHashStateImpl& b) {
const std::string a_flat = absl::StrJoin(a.hash_representation_, "");
const std::string b_flat = absl::StrJoin(b.hash_representation_, "");
if (a_flat == b_flat) return CompareResult::kEqual;
if (absl::EndsWith(a_flat, b_flat)) return CompareResult::kBSuffixA;
if (absl::EndsWith(b_flat, a_flat)) return CompareResult::kASuffixB;
return CompareResult::kUnequal;
}
// operator<< prints the hash representation as a hex and ASCII dump, to
// facilitate debugging.
friend std::ostream& operator<<(std::ostream& out,
const SpyHashStateImpl& hash_state) {
out << "[\n";
for (auto& s : hash_state.hash_representation_) {
size_t offset = 0;
for (char c : s) {
if (offset % 16 == 0) {
out << absl::StreamFormat("\n0x%04x: ", offset);
}
if (offset % 2 == 0) {
out << " ";
}
out << absl::StreamFormat("%02x", c);
++offset;
}
out << "\n";
}
return out << "]";
}
// The base case of the combine recursion, which writes raw bytes into the
// internal buffer.
static SpyHashStateImpl combine_contiguous(SpyHashStateImpl hash_state,
const unsigned char* begin,
size_t size) {
const size_t large_chunk_stride = PiecewiseChunkSize();
if (size > large_chunk_stride) {
// Combining a large contiguous buffer must have the same effect as
// doing it piecewise by the stride length, followed by the (possibly
// empty) remainder.
while (size >= large_chunk_stride) {
hash_state = SpyHashStateImpl::combine_contiguous(
std::move(hash_state), begin, large_chunk_stride);
begin += large_chunk_stride;
size -= large_chunk_stride;
}
}
hash_state.hash_representation_.emplace_back(
reinterpret_cast<const char*>(begin), size);
return hash_state;
}
using SpyHashStateImpl::HashStateBase::combine_contiguous;
absl::optional<std::string> error() const {
if (moved_from_) {
return "Returned a moved-from instance of the hash state object.";
}
return *error_;
}
private:
template <typename U>
friend class SpyHashStateImpl;
// This is true if SpyHashStateImpl<T> has been passed to a call of
// AbslHashValue with the wrong type. This detects that the user called
// AbslHashValue directly (because the hash state type does not match).
static bool direct_absl_hash_value_error_;
std::vector<std::string> hash_representation_;
// This is a shared_ptr because we want all instances of the particular
// SpyHashState run to share the field. This way we can set the error for
// use-after-move and all the copies will see it.
std::shared_ptr<absl::optional<std::string>> error_;
bool moved_from_ = false;
};
template <typename T>
bool SpyHashStateImpl<T>::direct_absl_hash_value_error_;
template <bool& B>
struct OdrUse {
constexpr OdrUse() {}
bool& b = B;
};
template <void (*)()>
struct RunOnStartup {
static bool run;
static constexpr OdrUse<run> kOdrUse{};
};
template <void (*f)()>
bool RunOnStartup<f>::run = (f(), true);
template <
typename T, typename U,
// Only trigger for when (T != U),
typename = absl::enable_if_t<!std::is_same<T, U>::value>,
// This statement works in two ways:
// - First, it instantiates RunOnStartup and forces the initialization of
// `run`, which set the global variable.
// - Second, it triggers a SFINAE error disabling the overload to prevent
// compile time errors. If we didn't disable the overload we would get
// ambiguous overload errors, which we don't want.
int = RunOnStartup<SpyHashStateImpl<T>::SetDirectAbslHashValueError>::run>
void AbslHashValue(SpyHashStateImpl<T>, const U&);
using SpyHashState = SpyHashStateImpl<void>;
} // namespace hash_internal
ABSL_NAMESPACE_END
} // namespace absl
#endif // ABSL_HASH_INTERNAL_SPY_HASH_STATE_H_