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#ifndef CHUNKED_MEMORY_POOL_INL_H_
#error "Direct inclusion of this file is not allowed, include chunked_memory_pool.h"
// For the sake of sane code completion.
#include "chunked_memory_pool.h"
#endif
#include "serialize.h"
#include <library/cpp/yt/system/exit.h>
#include <library/cpp/yt/malloc/malloc.h>
#include <util/system/align.h>
namespace NYT {
////////////////////////////////////////////////////////////////////////////////
inline void TAllocationHolder::operator delete(void* ptr) noexcept
{
::free(ptr);
}
inline TMutableRef TAllocationHolder::GetRef() const
{
return Ref_;
}
template <class TDerived>
TDerived* TAllocationHolder::Allocate(size_t size, TRefCountedTypeCookie cookie)
{
auto requestedSize = sizeof(TDerived) + size;
auto* ptr = ::malloc(requestedSize);
if (!ptr) {
AbortProcess(ToUnderlying(EProcessExitCode::OutOfMemory));
}
#ifndef _win_
auto allocatedSize = ::malloc_usable_size(ptr);
if (allocatedSize) {
size += allocatedSize - requestedSize;
}
#endif
auto* instance = static_cast<TDerived*>(ptr);
try {
new (instance) TDerived(TMutableRef(instance + 1, size), cookie);
} catch (const std::exception& ex) {
// Do not forget to free the memory.
::free(ptr);
throw;
}
return instance;
}
////////////////////////////////////////////////////////////////////////////////
inline TChunkedMemoryPool::TChunkedMemoryPool()
: TChunkedMemoryPool(
GetRefCountedTypeCookie<TDefaultChunkedMemoryPoolTag>())
{ }
template <class TTag>
inline TChunkedMemoryPool::TChunkedMemoryPool(
TTag,
size_t startChunkSize)
: TChunkedMemoryPool(
GetRefCountedTypeCookie<TTag>(),
startChunkSize)
{ }
inline char* TChunkedMemoryPool::AllocateUnaligned(size_t size)
{
// Fast path.
if (FreeZoneEnd_ >= FreeZoneBegin_ + size) {
FreeZoneEnd_ -= size;
Size_ += size;
return FreeZoneEnd_;
}
// Slow path.
return AllocateUnalignedSlow(size);
}
inline char* TChunkedMemoryPool::AllocateAligned(size_t size, int align)
{
// NB: This can lead to FreeZoneBegin_ >= FreeZoneEnd_ in which case the chunk is full.
FreeZoneBegin_ = AlignUp(FreeZoneBegin_, align);
// Fast path.
if (FreeZoneBegin_ + size <= FreeZoneEnd_) {
char* result = FreeZoneBegin_;
Size_ += size;
FreeZoneBegin_ += size;
return result;
}
// Slow path.
return AllocateAlignedSlow(size, align);
}
template <class T>
inline T* TChunkedMemoryPool::AllocateUninitialized(int n, int align)
{
return reinterpret_cast<T*>(AllocateAligned(sizeof(T) * n, align));
}
template <class T>
inline TMutableRange<T> TChunkedMemoryPool::Capture(TRange<T> src, int align)
{
auto* dst = AllocateUninitialized<T>(src.Size(), align);
::memcpy(dst, src.Begin(), sizeof(T) * src.Size());
return TMutableRange<T>(dst, src.Size());
}
inline void TChunkedMemoryPool::Free(char* from, char* to)
{
if (FreeZoneBegin_ == to) {
FreeZoneBegin_ = from;
}
if (FreeZoneEnd_ == from) {
FreeZoneEnd_ = to;
}
}
inline void TChunkedMemoryPool::Clear()
{
Size_ = 0;
if (Chunks_.empty()) {
FreeZoneBegin_ = nullptr;
FreeZoneEnd_ = nullptr;
NextChunkIndex_ = 0;
} else {
FreeZoneBegin_ = Chunks_.front()->GetRef().Begin();
FreeZoneEnd_ = Chunks_.front()->GetRef().End();
NextChunkIndex_ = 1;
}
for (const auto& block : OtherBlocks_) {
Capacity_ -= block->GetRef().Size();
}
OtherBlocks_.clear();
}
////////////////////////////////////////////////////////////////////////////////
} // namespace NYT
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