Abseil Common Libraries (C++) (grcp 依赖) https://abseil.io/
You can not select more than 25 topics Topics must start with a letter or number, can include dashes ('-') and can be up to 35 characters long.

446 lines
16 KiB

Export of internal Abseil changes -- f012012ef78234a6a4585321b67d7b7c92ebc266 by Laramie Leavitt <lar@google.com>: Slight restructuring of absl/random/internal randen implementation. Convert round-keys.inc into randen_round_keys.cc file. Consistently use a 128-bit pointer type for internal method parameters. This allows simpler pointer arithmetic in C++ & permits removal of some constants and casts. Remove some redundancy in comments & constexpr variables. Specifically, all references to Randen algorithm parameters use RandenTraits; duplication in RandenSlow removed. PiperOrigin-RevId: 312190313 -- dc8b42e054046741e9ed65335bfdface997c6063 by Abseil Team <absl-team@google.com>: Internal change. PiperOrigin-RevId: 312167304 -- f13d248fafaf206492c1362c3574031aea3abaf7 by Matthew Brown <matthewbr@google.com>: Cleanup StrFormat extensions a little. PiperOrigin-RevId: 312166336 -- 9d9117589667afe2332bb7ad42bc967ca7c54502 by Derek Mauro <dmauro@google.com>: Internal change PiperOrigin-RevId: 312105213 -- 9a12b9b3aa0e59b8ee6cf9408ed0029045543a9b by Abseil Team <absl-team@google.com>: Complete IGNORE_TYPE macro renaming. PiperOrigin-RevId: 311999699 -- 64756f20d61021d999bd0d4c15e9ad3857382f57 by Gennadiy Rozental <rogeeff@google.com>: Switch to fixed bytes specific default value. This fixes the Abseil Flags for big endian platforms. PiperOrigin-RevId: 311844448 -- bdbe6b5b29791dbc3816ada1828458b3010ff1e9 by Laramie Leavitt <lar@google.com>: Change many distribution tests to use pcg_engine as a deterministic source of entropy. It's reasonable to test that the BitGen itself has good entropy, however when testing the cross product of all random distributions x all the architecture variations x all submitted changes results in a large number of tests. In order to account for these failures while still using good entropy requires that our allowed sigma need to account for all of these independent tests. Our current sigma values are too restrictive, and we see a lot of failures, so we have to either relax the sigma values or convert some of the statistical tests to use deterministic values. This changelist does the latter. PiperOrigin-RevId: 311840096 GitOrigin-RevId: f012012ef78234a6a4585321b67d7b7c92ebc266 Change-Id: Ic84886f38ff30d7d72c126e9b63c9a61eb729a1a
5 years ago
// 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_CONTAINER_INTERNAL_CONTAINER_MEMORY_H_
#define ABSL_CONTAINER_INTERNAL_CONTAINER_MEMORY_H_
#ifdef ADDRESS_SANITIZER
#include <sanitizer/asan_interface.h>
#endif
#ifdef MEMORY_SANITIZER
#include <sanitizer/msan_interface.h>
#endif
#include <cassert>
#include <cstddef>
#include <memory>
#include <tuple>
#include <type_traits>
#include <utility>
#include "absl/memory/memory.h"
#include "absl/meta/type_traits.h"
#include "absl/utility/utility.h"
namespace absl {
ABSL_NAMESPACE_BEGIN
namespace container_internal {
template <size_t Alignment>
struct alignas(Alignment) AlignedType {};
// Allocates at least n bytes aligned to the specified alignment.
// Alignment must be a power of 2. It must be positive.
//
// Note that many allocators don't honor alignment requirements above certain
// threshold (usually either alignof(std::max_align_t) or alignof(void*)).
// Allocate() doesn't apply alignment corrections. If the underlying allocator
// returns insufficiently alignment pointer, that's what you are going to get.
template <size_t Alignment, class Alloc>
void* Allocate(Alloc* alloc, size_t n) {
static_assert(Alignment > 0, "");
assert(n && "n must be positive");
using M = AlignedType<Alignment>;
using A = typename absl::allocator_traits<Alloc>::template rebind_alloc<M>;
using AT = typename absl::allocator_traits<Alloc>::template rebind_traits<M>;
A mem_alloc(*alloc);
void* p = AT::allocate(mem_alloc, (n + sizeof(M) - 1) / sizeof(M));
assert(reinterpret_cast<uintptr_t>(p) % Alignment == 0 &&
"allocator does not respect alignment");
return p;
}
// The pointer must have been previously obtained by calling
// Allocate<Alignment>(alloc, n).
template <size_t Alignment, class Alloc>
void Deallocate(Alloc* alloc, void* p, size_t n) {
static_assert(Alignment > 0, "");
assert(n && "n must be positive");
using M = AlignedType<Alignment>;
using A = typename absl::allocator_traits<Alloc>::template rebind_alloc<M>;
using AT = typename absl::allocator_traits<Alloc>::template rebind_traits<M>;
A mem_alloc(*alloc);
AT::deallocate(mem_alloc, static_cast<M*>(p),
(n + sizeof(M) - 1) / sizeof(M));
}
namespace memory_internal {
// Constructs T into uninitialized storage pointed by `ptr` using the args
// specified in the tuple.
template <class Alloc, class T, class Tuple, size_t... I>
void ConstructFromTupleImpl(Alloc* alloc, T* ptr, Tuple&& t,
absl::index_sequence<I...>) {
absl::allocator_traits<Alloc>::construct(
*alloc, ptr, std::get<I>(std::forward<Tuple>(t))...);
}
template <class T, class F>
struct WithConstructedImplF {
template <class... Args>
decltype(std::declval<F>()(std::declval<T>())) operator()(
Args&&... args) const {
return std::forward<F>(f)(T(std::forward<Args>(args)...));
}
F&& f;
};
template <class T, class Tuple, size_t... Is, class F>
decltype(std::declval<F>()(std::declval<T>())) WithConstructedImpl(
Tuple&& t, absl::index_sequence<Is...>, F&& f) {
return WithConstructedImplF<T, F>{std::forward<F>(f)}(
std::get<Is>(std::forward<Tuple>(t))...);
}
template <class T, size_t... Is>
auto TupleRefImpl(T&& t, absl::index_sequence<Is...>)
-> decltype(std::forward_as_tuple(std::get<Is>(std::forward<T>(t))...)) {
return std::forward_as_tuple(std::get<Is>(std::forward<T>(t))...);
}
// Returns a tuple of references to the elements of the input tuple. T must be a
// tuple.
template <class T>
auto TupleRef(T&& t) -> decltype(
TupleRefImpl(std::forward<T>(t),
absl::make_index_sequence<
std::tuple_size<typename std::decay<T>::type>::value>())) {
return TupleRefImpl(
std::forward<T>(t),
absl::make_index_sequence<
std::tuple_size<typename std::decay<T>::type>::value>());
}
template <class F, class K, class V>
decltype(std::declval<F>()(std::declval<const K&>(), std::piecewise_construct,
std::declval<std::tuple<K>>(), std::declval<V>()))
DecomposePairImpl(F&& f, std::pair<std::tuple<K>, V> p) {
const auto& key = std::get<0>(p.first);
return std::forward<F>(f)(key, std::piecewise_construct, std::move(p.first),
std::move(p.second));
}
} // namespace memory_internal
// Constructs T into uninitialized storage pointed by `ptr` using the args
// specified in the tuple.
template <class Alloc, class T, class Tuple>
void ConstructFromTuple(Alloc* alloc, T* ptr, Tuple&& t) {
memory_internal::ConstructFromTupleImpl(
alloc, ptr, std::forward<Tuple>(t),
absl::make_index_sequence<
std::tuple_size<typename std::decay<Tuple>::type>::value>());
}
// Constructs T using the args specified in the tuple and calls F with the
// constructed value.
template <class T, class Tuple, class F>
decltype(std::declval<F>()(std::declval<T>())) WithConstructed(
Tuple&& t, F&& f) {
return memory_internal::WithConstructedImpl<T>(
std::forward<Tuple>(t),
absl::make_index_sequence<
std::tuple_size<typename std::decay<Tuple>::type>::value>(),
std::forward<F>(f));
}
// Given arguments of an std::pair's consructor, PairArgs() returns a pair of
// tuples with references to the passed arguments. The tuples contain
// constructor arguments for the first and the second elements of the pair.
//
// The following two snippets are equivalent.
//
// 1. std::pair<F, S> p(args...);
//
// 2. auto a = PairArgs(args...);
// std::pair<F, S> p(std::piecewise_construct,
// std::move(p.first), std::move(p.second));
inline std::pair<std::tuple<>, std::tuple<>> PairArgs() { return {}; }
template <class F, class S>
std::pair<std::tuple<F&&>, std::tuple<S&&>> PairArgs(F&& f, S&& s) {
return {std::piecewise_construct, std::forward_as_tuple(std::forward<F>(f)),
std::forward_as_tuple(std::forward<S>(s))};
}
template <class F, class S>
std::pair<std::tuple<const F&>, std::tuple<const S&>> PairArgs(
const std::pair<F, S>& p) {
return PairArgs(p.first, p.second);
}
template <class F, class S>
std::pair<std::tuple<F&&>, std::tuple<S&&>> PairArgs(std::pair<F, S>&& p) {
return PairArgs(std::forward<F>(p.first), std::forward<S>(p.second));
}
template <class F, class S>
auto PairArgs(std::piecewise_construct_t, F&& f, S&& s)
-> decltype(std::make_pair(memory_internal::TupleRef(std::forward<F>(f)),
memory_internal::TupleRef(std::forward<S>(s)))) {
return std::make_pair(memory_internal::TupleRef(std::forward<F>(f)),
memory_internal::TupleRef(std::forward<S>(s)));
}
// A helper function for implementing apply() in map policies.
template <class F, class... Args>
auto DecomposePair(F&& f, Args&&... args)
-> decltype(memory_internal::DecomposePairImpl(
std::forward<F>(f), PairArgs(std::forward<Args>(args)...))) {
return memory_internal::DecomposePairImpl(
std::forward<F>(f), PairArgs(std::forward<Args>(args)...));
}
// A helper function for implementing apply() in set policies.
template <class F, class Arg>
decltype(std::declval<F>()(std::declval<const Arg&>(), std::declval<Arg>()))
DecomposeValue(F&& f, Arg&& arg) {
const auto& key = arg;
return std::forward<F>(f)(key, std::forward<Arg>(arg));
}
// Helper functions for asan and msan.
inline void SanitizerPoisonMemoryRegion(const void* m, size_t s) {
#ifdef ADDRESS_SANITIZER
ASAN_POISON_MEMORY_REGION(m, s);
#endif
#ifdef MEMORY_SANITIZER
__msan_poison(m, s);
#endif
(void)m;
(void)s;
}
inline void SanitizerUnpoisonMemoryRegion(const void* m, size_t s) {
#ifdef ADDRESS_SANITIZER
ASAN_UNPOISON_MEMORY_REGION(m, s);
#endif
#ifdef MEMORY_SANITIZER
__msan_unpoison(m, s);
#endif
(void)m;
(void)s;
}
template <typename T>
inline void SanitizerPoisonObject(const T* object) {
SanitizerPoisonMemoryRegion(object, sizeof(T));
}
template <typename T>
inline void SanitizerUnpoisonObject(const T* object) {
SanitizerUnpoisonMemoryRegion(object, sizeof(T));
}
namespace memory_internal {
// If Pair is a standard-layout type, OffsetOf<Pair>::kFirst and
// OffsetOf<Pair>::kSecond are equivalent to offsetof(Pair, first) and
// offsetof(Pair, second) respectively. Otherwise they are -1.
//
// The purpose of OffsetOf is to avoid calling offsetof() on non-standard-layout
// type, which is non-portable.
template <class Pair, class = std::true_type>
struct OffsetOf {
static constexpr size_t kFirst = static_cast<size_t>(-1);
static constexpr size_t kSecond = static_cast<size_t>(-1);
};
template <class Pair>
struct OffsetOf<Pair, typename std::is_standard_layout<Pair>::type> {
static constexpr size_t kFirst = offsetof(Pair, first);
static constexpr size_t kSecond = offsetof(Pair, second);
};
template <class K, class V>
struct IsLayoutCompatible {
private:
struct Pair {
K first;
V second;
};
// Is P layout-compatible with Pair?
template <class P>
static constexpr bool LayoutCompatible() {
return std::is_standard_layout<P>() && sizeof(P) == sizeof(Pair) &&
alignof(P) == alignof(Pair) &&
memory_internal::OffsetOf<P>::kFirst ==
memory_internal::OffsetOf<Pair>::kFirst &&
memory_internal::OffsetOf<P>::kSecond ==
memory_internal::OffsetOf<Pair>::kSecond;
}
public:
// Whether pair<const K, V> and pair<K, V> are layout-compatible. If they are,
// then it is safe to store them in a union and read from either.
static constexpr bool value = std::is_standard_layout<K>() &&
std::is_standard_layout<Pair>() &&
memory_internal::OffsetOf<Pair>::kFirst == 0 &&
LayoutCompatible<std::pair<K, V>>() &&
LayoutCompatible<std::pair<const K, V>>();
};
} // namespace memory_internal
// The internal storage type for key-value containers like flat_hash_map.
//
// It is convenient for the value_type of a flat_hash_map<K, V> to be
// pair<const K, V>; the "const K" prevents accidental modification of the key
// when dealing with the reference returned from find() and similar methods.
// However, this creates other problems; we want to be able to emplace(K, V)
// efficiently with move operations, and similarly be able to move a
// pair<K, V> in insert().
//
// The solution is this union, which aliases the const and non-const versions
// of the pair. This also allows flat_hash_map<const K, V> to work, even though
// that has the same efficiency issues with move in emplace() and insert() -
// but people do it anyway.
//
// If kMutableKeys is false, only the value member can be accessed.
//
// If kMutableKeys is true, key can be accessed through all slots while value
// and mutable_value must be accessed only via INITIALIZED slots. Slots are
// created and destroyed via mutable_value so that the key can be moved later.
//
// Accessing one of the union fields while the other is active is safe as
// long as they are layout-compatible, which is guaranteed by the definition of
// kMutableKeys. For C++11, the relevant section of the standard is
// https://timsong-cpp.github.io/cppwp/n3337/class.mem#19 (9.2.19)
template <class K, class V>
union map_slot_type {
map_slot_type() {}
~map_slot_type() = delete;
using value_type = std::pair<const K, V>;
using mutable_value_type =
std::pair<absl::remove_const_t<K>, absl::remove_const_t<V>>;
value_type value;
mutable_value_type mutable_value;
absl::remove_const_t<K> key;
};
template <class K, class V>
struct map_slot_policy {
using slot_type = map_slot_type<K, V>;
using value_type = std::pair<const K, V>;
using mutable_value_type = std::pair<K, V>;
private:
static void emplace(slot_type* slot) {
// The construction of union doesn't do anything at runtime but it allows us
// to access its members without violating aliasing rules.
new (slot) slot_type;
}
// If pair<const K, V> and pair<K, V> are layout-compatible, we can accept one
// or the other via slot_type. We are also free to access the key via
// slot_type::key in this case.
using kMutableKeys = memory_internal::IsLayoutCompatible<K, V>;
public:
static value_type& element(slot_type* slot) { return slot->value; }
static const value_type& element(const slot_type* slot) {
return slot->value;
}
static const K& key(const slot_type* slot) {
return kMutableKeys::value ? slot->key : slot->value.first;
}
template <class Allocator, class... Args>
static void construct(Allocator* alloc, slot_type* slot, Args&&... args) {
emplace(slot);
if (kMutableKeys::value) {
absl::allocator_traits<Allocator>::construct(*alloc, &slot->mutable_value,
std::forward<Args>(args)...);
} else {
absl::allocator_traits<Allocator>::construct(*alloc, &slot->value,
std::forward<Args>(args)...);
}
}
// Construct this slot by moving from another slot.
template <class Allocator>
static void construct(Allocator* alloc, slot_type* slot, slot_type* other) {
emplace(slot);
if (kMutableKeys::value) {
absl::allocator_traits<Allocator>::construct(
*alloc, &slot->mutable_value, std::move(other->mutable_value));
} else {
absl::allocator_traits<Allocator>::construct(*alloc, &slot->value,
std::move(other->value));
}
}
template <class Allocator>
static void destroy(Allocator* alloc, slot_type* slot) {
if (kMutableKeys::value) {
absl::allocator_traits<Allocator>::destroy(*alloc, &slot->mutable_value);
} else {
absl::allocator_traits<Allocator>::destroy(*alloc, &slot->value);
}
}
template <class Allocator>
static void transfer(Allocator* alloc, slot_type* new_slot,
slot_type* old_slot) {
emplace(new_slot);
if (kMutableKeys::value) {
absl::allocator_traits<Allocator>::construct(
*alloc, &new_slot->mutable_value, std::move(old_slot->mutable_value));
} else {
absl::allocator_traits<Allocator>::construct(*alloc, &new_slot->value,
std::move(old_slot->value));
}
destroy(alloc, old_slot);
}
template <class Allocator>
static void swap(Allocator* alloc, slot_type* a, slot_type* b) {
if (kMutableKeys::value) {
using std::swap;
swap(a->mutable_value, b->mutable_value);
} else {
value_type tmp = std::move(a->value);
absl::allocator_traits<Allocator>::destroy(*alloc, &a->value);
absl::allocator_traits<Allocator>::construct(*alloc, &a->value,
std::move(b->value));
absl::allocator_traits<Allocator>::destroy(*alloc, &b->value);
absl::allocator_traits<Allocator>::construct(*alloc, &b->value,
std::move(tmp));
}
}
template <class Allocator>
static void move(Allocator* alloc, slot_type* src, slot_type* dest) {
if (kMutableKeys::value) {
dest->mutable_value = std::move(src->mutable_value);
} else {
absl::allocator_traits<Allocator>::destroy(*alloc, &dest->value);
absl::allocator_traits<Allocator>::construct(*alloc, &dest->value,
std::move(src->value));
}
}
template <class Allocator>
static void move(Allocator* alloc, slot_type* first, slot_type* last,
slot_type* result) {
for (slot_type *src = first, *dest = result; src != last; ++src, ++dest)
move(alloc, src, dest);
}
};
} // namespace container_internal
ABSL_NAMESPACE_END
} // namespace absl
#endif // ABSL_CONTAINER_INTERNAL_CONTAINER_MEMORY_H_