[*] Polish AuMemory

This commit is contained in:
Reece Wilson 2024-03-19 15:47:42 +00:00
parent 0b60cb8099
commit bd1283e146
32 changed files with 1099 additions and 848 deletions

View File

@ -10,6 +10,8 @@
namespace Aurora::Memory
{
struct ProxyHeap;
static const AuUInt8 kHeapSize = 128;
static const AuUInt8 kHeap2Size = 255;
struct Heap
{
@ -18,73 +20,110 @@ namespace Aurora::Memory
virtual HeapStats &GetStats() = 0;
virtual void WalkHeap(bool(*fCallback)(void *, void *), void *pSecondArg) = 0;
// Potentially slower, zero allocate
template<typename T = void *>
T ZAlloc(Types::size_t length)
T ZAlloc(Types::size_t uLength)
{
return reinterpret_cast<T>(_ZAlloc(length));
if constexpr (AuIsVoid_v<AuRemovePointer_t<T>>)
{
return reinterpret_cast<T>(_ZAlloc(uLength));
}
else
{
return reinterpret_cast<T>(_ZAlloc(uLength, alignof(AuRemovePointer_t<T>)));
}
}
template<typename T = void *>
T ZAlloc(Types::size_t length, Types::size_t align)
T ZAlloc(Types::size_t uLength, Types::size_t uAlignment)
{
return reinterpret_cast<T>(_ZAlloc(length, align));
return reinterpret_cast<T>(_ZAlloc(uLength, uAlignment));
}
template<typename T>
T *ZAlloc()
{
return reinterpret_cast<T *>(_ZAlloc(sizeof(T)));
return reinterpret_cast<T *>(_ZAlloc(sizeof(T), alignof(T)));
}
template<typename T>
T *NewArray(Types::size_t count)
T *NewArray(Types::size_t uLength)
{
return ZAlloc<T *>(count * sizeof(T));
return ZAlloc<T *>(uLength * sizeof(T), alignof(T));
}
template<typename T>
T *NewArray(Types::size_t count, Types::size_t align)
T *NewArray(Types::size_t uLength, Types::size_t uAlignment)
{
return ZAlloc<T *>(count * sizeof(T), align);
return ZAlloc<T *>(uLength * sizeof(T), uAlignment);
}
/// Fast, unsafe alloc
template<typename T = void *>
T FAlloc(Types::size_t length)
T FAlloc(Types::size_t uLength)
{
return reinterpret_cast<T>(_FAlloc(length));
if constexpr (AuIsVoid_v<AuRemovePointer_t<T>>)
{
return reinterpret_cast<T>(_FAlloc(uLength));
}
else
{
return reinterpret_cast<T>(_FAlloc(uLength, alignof(AuRemovePointer_t<T>)));
}
}
template<typename T = void *>
T FAlloc(Types::size_t length, Types::size_t align)
T FAlloc(Types::size_t uLength, Types::size_t uAlignment)
{
return reinterpret_cast<T>(_FAlloc(length, align));
return reinterpret_cast<T>(_FAlloc(uLength, uAlignment));
}
template<typename T>
T ZRealloc(T pHead, Types::size_t length)
T *FAlloc()
{
return reinterpret_cast<T>(_ZRealloc(reinterpret_cast<void *>(pHead), length));
return reinterpret_cast<T *>(_FAlloc(sizeof(T), alignof(T)));
}
// Reallocs
template<typename T>
T ZRealloc(T pHead, Types::size_t uLength)
{
if constexpr (AuIsVoid_v<AuRemovePointer_t<T>>)
{
return reinterpret_cast<T>(_ZRealloc(reinterpret_cast<void *>(pHead), uLength));
}
else
{
return reinterpret_cast<T>(_ZRealloc(reinterpret_cast<void *>(pHead), uLength, alignof(AuRemovePointer_t<T>)));
}
}
template<typename T>
T ZRealloc(T pHead, Types::size_t length, Types::size_t alloc)
T ZRealloc(T pHead, Types::size_t uLength, Types::size_t uAlignment)
{
return reinterpret_cast<T>(_ZRealloc(reinterpret_cast<void *>(pHead), length), alloc);
return reinterpret_cast<T>(_ZRealloc(reinterpret_cast<void *>(pHead), uLength, uAlignment));
}
template<typename T>
T FRealloc(T pHead, Types::size_t length)
T FRealloc(T pHead, Types::size_t uLength)
{
return reinterpret_cast<T>(_FRealloc(reinterpret_cast<void *>(pHead), length));
if constexpr (AuIsVoid_v<AuRemovePointer_t<T>>)
{
return reinterpret_cast<T>(_FRealloc(reinterpret_cast<void *>(pHead), uLength));
}
else
{
return reinterpret_cast<T>(_FRealloc(reinterpret_cast<void *>(pHead), uLength, alignof(AuRemovePointer_t<T>)));
}
}
template<typename T>
T FRealloc(T pHead, Types::size_t length, Types::size_t alloc)
T FRealloc(T pHead, Types::size_t uLength, Types::size_t uAlignment)
{
return reinterpret_cast<T>(_FRealloc(reinterpret_cast<void *>(pHead), length), alloc);
return reinterpret_cast<T>(_FRealloc(reinterpret_cast<void *>(pHead), uLength, uAlignment));
}
// Free
template<typename T>
void Free(T pHead)
{
@ -115,12 +154,12 @@ namespace Aurora::Memory
auto pVoids = (void **)(((char *)pThat) - kAlignment);
auto pHeap = (Heap *)pVoids[0];
auto uCount = (AuUInt)pVoids[1];
auto uLength = (AuUInt)pVoids[1];
if constexpr (AuIsClass_v<T> &&
!AuIsTriviallyDestructible_v<T>)
{
for (AU_ITERATE_N(i, uCount))
for (AU_ITERATE_N(i, uLength))
{
auto &refElement = pThat[i];
refElement.~T();
@ -187,10 +226,20 @@ namespace Aurora::Memory
}
*(void **)pPtr = pThat;
return AuSPtr<T>((T *)(pPtr + kAlignment), &Heap::DeleteThat<T>);
auto pTThat = (T *)(pPtr + kAlignment);
AUROXTL_COMMODITY_TRY
{
return AuSPtr<T>(pTThat, &Heap::DeleteThat<T>);
}
AUROXTL_COMMODITY_CATCH
{
Heap::DeleteThat<T>(pTThat);
return {};
}
}
// note: callers can use AuHUPOf_t<T> pUniquePointer = AuNullHeapPointer<T>()
// note: callers can use AuHUPOf_t<Z> pUniquePointer = AuNullHeapPointer<Z>()
template <class T, class Z = T, class ...Args>
AuUPtr<Z, decltype(&Heap::DeleteThat<Z>)> NewClassUnique(Args &&...args)
@ -288,7 +337,16 @@ namespace Aurora::Memory
pVoids[0] = pThat;
pVoids[1] = (void *)uElements;
return AuSPtr<T>((T *)(pPtr + kAlignment), &Heap::DeleteThatArray<T>);
auto pTThat = (T *)(pPtr + kAlignment);
AUROXTL_COMMODITY_TRY
{
return AuSPtr<T>(pTThat, &Heap::DeleteThatArray<T>);
}
AUROXTL_COMMODITY_CATCH
{
Heap::DeleteThatArray<T>(pTThat);
return {};
}
}
// note: callers can use AuHUPOf_t<T> pUniquePointer = AuNullHeapPointer<T>()
@ -372,31 +430,6 @@ namespace Aurora::Memory
}
}
template<typename T>
static AuSPtr<T> ToSmartPointer(AuSPtr<Heap> heap,
T *pHead,
bool bPinHeap = true)
{
auto handle = bPinHeap ?
heap :
AuSPtr<Heap> {};
auto pHeap = heap.get();
return AuSPtr<T>(pHead,
[handle, pHeap](T *pDeleteMe)
{
if constexpr (AuIsClass_v<T>
#if !defined(AURT_HEAP_NO_STL)
&& !std::is_trivially_destructible_v<T>
#endif
)
{
pDeleteMe->~T();
}
pHeap->Free(pDeleteMe);
});
}
template <typename T>
using HUPOf_t = AuUPtr<T, decltype(&Heap::DeleteThat<T>)>;
@ -408,9 +441,9 @@ namespace Aurora::Memory
virtual Heap *GetSelfReferenceRaw() = 0;
virtual AU_ALLOC void *_ZAlloc(Types::size_t uLength) = 0;
virtual AU_ALLOC void *_ZAlloc(Types::size_t uLength, Types::size_t align) = 0;
virtual AU_ALLOC void *_ZAlloc(Types::size_t uLength, Types::size_t uAlignment) = 0;
virtual AU_ALLOC void *_FAlloc(Types::size_t uLength) = 0;
virtual AU_ALLOC void *_FAlloc(Types::size_t uLength, Types::size_t align) = 0;
virtual AU_ALLOC void *_FAlloc(Types::size_t uLength, Types::size_t uAlignment) = 0;
virtual AU_ALLOC void *_ZRealloc(void *pBase, Types::size_t uLength, Types::size_t uAlign) = 0;
virtual AU_ALLOC void *_ZRealloc(void *pBase, Types::size_t uLength) = 0;
virtual AU_ALLOC void *_FRealloc(void *pBase, Types::size_t uLength, Types::size_t uAlign) = 0;
@ -432,8 +465,8 @@ namespace Aurora::Memory
};
/**
Returns a heap interface backed by the default allocator
*/
* Returns a heap interface backed by the default allocator
*/
AUKN_SHARED_API(DefaultDiscontiguousHeap, Heap);
inline Heap *GetDefaultDiscontiguousHeap()
@ -448,27 +481,28 @@ namespace Aurora::Memory
}
/**
Allocates uLength amount of contiguous virtual memory
* Allocates uLength amount of contiguous virtual memory
* @return a heap backed by uLength bytes of virtual memory
* @warning the SOO variant cannot guarantee release-on-last-free and will panic if uLength cannot be allocated. Use AllocHeap[Shared/Unique/New](uLength) instead.
*/
AUKN_SHARED_SOO2_NCM(AllocHeap, Heap, kHeapSize, ((AuUInt, uLength)), AuUInt uLength);
@warning Heaps are guaranteed to outlive their allocations; heaps are the one object that effectively own a single reference count on themselves.
Requesting termination before all of its' memory has been free will result, pHead at worst, a warning.
Expect to leak unless all allocs have been paired by a free.
/**
* @warning the SOO variant cannot guarantee release-on-last-free.
*/
AUKN_SHARED_SOO2_NCM(RequestHeapOfRegion, Heap, kHeapSize, ((const MemoryViewWrite &, memory)), const MemoryViewWrite &memory);
I do not expect to implement force frees simply because all our primary use cases keep track of dtors to forcefully release leaked objects.
Use RequestHeapOfRegion to be backed by caller owned memory.
/**
* Proxies an existing heap with encapsulated statistics.
* This is intended for debugging purposes when accurate heap stats of a heap-subset are desired.
* @warning this heap cannot guarantee release-on-last-free
*/
AUKN_SHARED_SOO2_NCM(HeapProxy, Heap, kHeap2Size, ((const AuSPtr<Heap> &, pHead)), const AuSPtr<Heap> &pHead);
@return a heap backed by uLength bytes of virtual memory
/**
* Proxies an existing heap with encapsulated statistics and leak detector
* This is intended for debugging purposes when accurate heap stats of a heap-subset are desired.
* @warning this heap cannot guarantee release-on-last-free
*/
AUKN_SHARED_API(AllocHeap, Heap, AuUInt uLength);
AUKN_SHARED_API(RequestHeapOfRegion, Heap, const MemoryViewWrite &memory);
// AllocHeap but use mimalloc (or the default allocator) instead
AUKN_SHARED_API(AllocHeapMimalloc, Heap, AuUInt uLength);
// Proxies an existing heap with encapsulated statistics
AUKN_SHARED_API(HeapProxy, Heap, const AuSPtr<Heap> &pHead);
// Proxies an existing heap with encapsulated statistics and leak detector
AUKN_SHARED_API(HeapProxyEx, Heap, const AuSPtr<Heap> &pHead, LeakFinderAlloc_f pfAlloc, LeakFinderFree_f pfFree);
AUKN_SHARED_SOO2_NCM(HeapProxyEx, Heap, kHeap2Size, ((const AuSPtr<Heap> &,pHead), (LeakFinderAlloc_f, pfAlloc), (LeakFinderFree_f, pfFree)), const AuSPtr<Heap> &pHead, LeakFinderAlloc_f pfAlloc, LeakFinderFree_f pfFree);
}

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@ -32,26 +32,26 @@ namespace Aurora::Memory
LeakFinderFree_f pFree);
// thread-local
AUKN_SYM void SetMemoryLowNotification(MemoryLowNotification_f pFunc);
AUKN_SYM void SetMemoryLowNotification(MemoryLowNotification_f pFunc);
AUKN_SYM void ReserveHeapMemory(AuUInt uHeapSize, bool bCommit = true);
AUKN_SYM AU_ALLOC void *_ZAlloc(Types::size_t length);
AUKN_SYM AU_ALLOC void *_ZAlloc(Types::size_t length, Types::size_t align);
AUKN_SYM AU_ALLOC void *_FAlloc(Types::size_t length);
AUKN_SYM AU_ALLOC void *_FAlloc(Types::size_t length, Types::size_t align);
AUKN_SYM AU_ALLOC void *_ZRealloc(void *buffer, Types::size_t length, Types::size_t align);
AUKN_SYM AU_ALLOC void *_ZRealloc(void *buffer, Types::size_t length);
AUKN_SYM AU_ALLOC void *_FRealloc(void *buffer, Types::size_t length, Types::size_t align);
AUKN_SYM AU_ALLOC void *_FRealloc(void *buffer, Types::size_t length);
AUKN_SYM AU_ALLOC void *_ZAlloc(Types::size_t uLength);
AUKN_SYM AU_ALLOC void *_ZAlloc(Types::size_t uLength, Types::size_t uAlignment);
AUKN_SYM AU_ALLOC void *_FAlloc(Types::size_t uLength);
AUKN_SYM AU_ALLOC void *_FAlloc(Types::size_t uLength, Types::size_t uAlignment);
AUKN_SYM AU_ALLOC void *_ZRealloc(void *buffer, Types::size_t uLength, Types::size_t uAlignment);
AUKN_SYM AU_ALLOC void *_ZRealloc(void *buffer, Types::size_t uLength);
AUKN_SYM AU_ALLOC void *_FRealloc(void *buffer, Types::size_t uLength, Types::size_t uAlignment);
AUKN_SYM AU_ALLOC void *_FRealloc(void *buffer, Types::size_t uLength);
AUKN_SYM void _Free(void *buffer);
AUKN_SYM AuUInt GetChunkSize(const void *head);
AUKN_SYM AuUInt GetPageSize();
static void *__FAlloc(Types::size_t length, Types::size_t align)
static void *__FAlloc(Types::size_t uLength, Types::size_t uAlignment)
{
return _FAlloc(length, align);
return _FAlloc(uLength, uAlignment);
}
static void __Free(void *buffer)
@ -59,89 +59,126 @@ namespace Aurora::Memory
_Free(buffer);
}
// These memory management APIs do not support class types, and will likely *never* support them
// QST already handles dynamic allocation of structs in a given heap properly (afaik)
// _new, new, et al are backed by operator overloads directed towards these functions
// -> do not double init
// TODO: ensure typeof(T) is not a pointer of a class
#if !defined(_CPPSHARP)
template<typename T>
T ZAlloc(Types::size_t length)
template<typename T = void *>
T ZAlloc(Types::size_t uLength)
{
static_assert(!AuIsClass_v<AuRemovePointer_t<T>>, "Do not use heap/kmem apis with classes");
return reinterpret_cast<T>(_ZAlloc(length));
}
template<typename T>
T ZAlloc(Types::size_t length, Types::size_t align)
{
static_assert(!AuIsClass_v<AuRemovePointer_t<T>>, "Do not use heap/kmem apis with classes");
return reinterpret_cast<T>(_ZAlloc(length, align));
}
template<typename T>
T *NewArray(Types::size_t count)
{
static_assert(!AuIsClass_v<T>, "Do not use heap/kmem apis with classes");
return reinterpret_cast<T *>(_FAlloc(count * sizeof(T)));
}
template<typename T>
T *NewArray(Types::size_t count, Types::size_t align)
{
static_assert(!AuIsClass_v<T>, "Do not use heap/kmem apis with classes");
return reinterpret_cast<T *>(_FAlloc(count * sizeof(T)), align);
}
template<typename T>
AuSPtr<T> AllocateFastArray(Types::size_t length, Types::size_t align = sizeof(T))
{
static_assert(!AuIsClass_v<AuRemovePointer_t<T>>, "Do not use heap/kmem apis with classes");
return AuSPtr<T>(reinterpret_cast<T *>(_FAlloc(length)), [](T *ptr)
static_assert((!AuIsClass_v<AuRemovePointer_t<T>> || (AuIsTriviallyConstructible_v<AuRemovePointer_t<T>> && AuIsTriviallyDestructible_v<AuRemovePointer_t<T>>)),
"Do not use heap/kmem apis with classes. Use AuNewClass[Unique]");
if constexpr (AuIsVoid_v<AuRemovePointer_t<T>>)
{
_Free(ptr);
});
return reinterpret_cast<T>(_ZAlloc(uLength));
}
else
{
return reinterpret_cast<T>(_ZAlloc(uLength, alignof(AuRemovePointer_t<T>)));
}
}
template<typename T = void *>
T ZAlloc(Types::size_t uLength, Types::size_t uAlignment)
{
static_assert((!AuIsClass_v<T> || (AuIsTriviallyConstructible_v<T> && AuIsTriviallyDestructible_v<T>)),
"Do not use heap/kmem apis with classes. Use AuNewClass[Unique] instead");
return reinterpret_cast<T>(_ZAlloc(uLength, uAlignment));
}
template<typename T = void *>
T FAlloc(Types::size_t uLength)
{
static_assert((!AuIsClass_v<AuRemovePointer_t<T>> || (AuIsTriviallyConstructible_v<AuRemovePointer_t<T>> && AuIsTriviallyDestructible_v<AuRemovePointer_t<T>>)),
"Do not use heap/kmem apis with classes. Use AuNewClass[Unique]");
if constexpr (AuIsVoid_v<AuRemovePointer_t<T>>)
{
return reinterpret_cast<T>(_FAlloc(uLength));
}
else
{
return reinterpret_cast<T>(_FAlloc(uLength, alignof(AuRemovePointer_t<T>)));
}
}
template<typename T = void *>
T FAlloc(Types::size_t uLength, Types::size_t uAlignment)
{
static_assert((!AuIsClass_v<T> || (AuIsTriviallyConstructible_v<T> && AuIsTriviallyDestructible_v<T>)),
"Do not use heap/kmem apis with classes. Use AuNewClass[Unique] instead");
return reinterpret_cast<T>(_FAlloc(uLength, uAlignment));
}
template<typename T>
T FAlloc(Types::size_t length)
T *ZAlloc()
{
static_assert(!AuIsClass_v<AuRemovePointer_t<T>>, "Do not use heap/kmem apis with classes");
return reinterpret_cast<T>(_FAlloc(length));
return ZAlloc<T *>(sizeof(T), alignof(T));
}
template<typename T>
T FAlloc(Types::size_t length, Types::size_t align)
T *FAlloc()
{
static_assert(!AuIsClass_v<AuRemovePointer_t<T>>, "Do not use heap/kmem apis with classes");
return reinterpret_cast<T>(_FAlloc(length, align));
return FAlloc<T *>(sizeof(T), alignof(T));
}
template<typename T>
T ZRealloc(T in, Types::size_t length)
T *NewArray(Types::size_t uCount)
{
return reinterpret_cast<T>(_ZRealloc(reinterpret_cast<void *>(in), length));
static_assert((!AuIsClass_v<T> || (AuIsTriviallyConstructible_v<T> && AuIsTriviallyDestructible_v<T>)),
"Do not use heap/kmem apis with classes. Use AuNewClassArray[Unique] instead");
return reinterpret_cast<T *>(_FAlloc(uCount * sizeof(T), alignof(T)));
}
template<typename T>
T ZRealloc(T in, Types::size_t length, Types::size_t alloc)
T *NewArray(Types::size_t uCount, Types::size_t uAlignment)
{
return reinterpret_cast<T>(_ZRealloc(reinterpret_cast<void *>(in), length), alloc);
static_assert((!AuIsClass_v<T> || (AuIsTriviallyConstructible_v<T> && AuIsTriviallyDestructible_v<T>)),
"Do not use heap/kmem apis with classes. Use AuNewClassArray[Unique] instead");
return reinterpret_cast<T *>(_FAlloc(uCount * sizeof(T), uAlignment));
}
template<typename T>
T FRealloc(T in, Types::size_t length)
AuSPtr<T> AllocateFastArray(Types::size_t uLength, Types::size_t uAlignment = alignof(T))
{
return reinterpret_cast<T>(_FRealloc(reinterpret_cast<void *>(in), length));
static_assert((!AuIsClass_v<T> || (AuIsTriviallyConstructible_v<T> && AuIsTriviallyDestructible_v<T>)),
"Do not use heap/kmem apis with classes. Use AuNewClassArray instead");
return AuSPtr<T>(reinterpret_cast<T *>(_FAlloc(uLength, uAlignment)), &_Free);
}
template<typename T>
T FRealloc(T in, Types::size_t length, Types::size_t alloc)
T FRealloc(T in, Types::size_t uLength)
{
return reinterpret_cast<T>(_FRealloc(reinterpret_cast<void *>(in), length), alloc);
if constexpr (AuIsVoid_v<AuRemovePointer_t<T>>)
{
return reinterpret_cast<T>(_FRealloc(reinterpret_cast<void *>(in), uLength));
}
else
{
return reinterpret_cast<T>(_FRealloc(reinterpret_cast<void *>(in), uLength, alignof(AuRemovePointer_t<T>)));
}
}
template<typename T>
T ZRealloc(T in, Types::size_t uLength)
{
if constexpr (AuIsVoid_v<AuRemovePointer_t<T>>)
{
return reinterpret_cast<T>(_ZRealloc(reinterpret_cast<void *>(in), uLength));
}
else
{
return reinterpret_cast<T>(_ZRealloc(reinterpret_cast<void *>(in), uLength, alignof(AuRemovePointer_t<T>)));
}
}
template<typename T>
T ZRealloc(T in, Types::size_t uLength, Types::size_t uAlignment)
{
return reinterpret_cast<T>(_ZRealloc(reinterpret_cast<void *>(in), uLength, uAlignment));
}
template<typename T>
T FRealloc(T in, Types::size_t uLength, Types::size_t uAlignment)
{
return reinterpret_cast<T>(_FRealloc(reinterpret_cast<void *>(in), uLength, uAlignment));
}
template<typename T>

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@ -26,6 +26,11 @@ extern "C"
}
#endif
namespace Aurora::Memory
{
AuUInt32 RoundPageUp(AuUInt32 value);
}
namespace Aurora
{
static bool gShouldResPathDoNothing {};
@ -778,4 +783,15 @@ namespace Aurora
return length.QuadPart;
}
void *SysAllocateLarge(AuUInt uLength)
{
uLength = AuMemory::RoundPageUp(uLength);
return VirtualAlloc(nullptr, uLength, MEM_COMMIT | MEM_RESERVE, PAGE_READWRITE);
}
void SysAllocateFree(void *pBuffer, AuUInt uLength)
{
VirtualFree(pBuffer, 0, MEM_RELEASE);
}
}

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@ -8,12 +8,18 @@
#include "RuntimeInternal.hpp"
#include "AuProcAddresses.UNIX.hpp"
#include <Source/Debug/ExceptionWatcher.Unix.hpp>
#include <sys/mman.h>
namespace Aurora::Process
{
void PosixForkResetLocks();
}
namespace Aurora::Memory
{
AuUInt32 RoundPageUp(AuUInt32 value);
}
namespace Aurora
{
int PosixOpen(const char *pathname, int flags, mode_t mode)
@ -159,4 +165,16 @@ namespace Aurora
{
return PosixGetLength(uOSHandle);
}
void *SysAllocateLarge(AuUInt uLength)
{
uLength = AuMemory::RoundPageUp(uLength);
return ::mmap(0, uLength, PROT_READ | PROT_WRITE, MAP_PRIVATE | MAP_ANONYMOUS, -1, 0);
}
void SysAllocateFree(void *pBuffer, AuUInt uLength)
{
uLength = AuMemory::RoundPageUp(uLength);
::munmap(pBuffer, uLength);
}
}

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@ -6,10 +6,8 @@
Author: Reece
***/
#include <RuntimeInternal.hpp>
#include "AuProcAddresses.hpp"
#if defined(AURORA_IS_MODERNNT_DERIVED)
#include "AuProcAddresses.NT.hpp"
#endif
namespace Aurora
{
@ -29,4 +27,18 @@ namespace Aurora
InitLinuxAddresses();
#endif
}
#if !defined(AURORA_HAS_SYS_ALLOC_LARGE)
void *SysAllocateLarge(AuUInt uLength)
{
return AuMemory::FAlloc<void *>(uLength, 32);
}
void SysAllocateFree(void *pBuffer, AuUInt uLength)
{
AuMemory::Free(pBuffer);
}
#endif
}

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@ -47,4 +47,14 @@ namespace Aurora
void SysWakeAllOnAddress(const void *pAddress);
AuUInt64 SysGetFileLength(AuUInt uOSHandle);
}
void *SysAllocateLarge(AuUInt uLength);
void SysAllocateFree(void *pBuffer, AuUInt uLength);
}
#if defined(AURORA_IS_MODERNNT_DERIVED) || defined(AURORA_IS_POSIX_DERIVED)
#if !defined(AURORA_HAS_SYS_ALLOC_LARGE)
#define AURORA_HAS_SYS_ALLOC_LARGE
#endif
#endif

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@ -38,7 +38,7 @@
#include "CmdLine/AuCmdLine.hpp"
#include "Grug/AuGrug.hpp"
#include "Threading/AuSleep.hpp"
#include "Memory/Cache.hpp"
#include "Memory/AuMemoryCache.hpp"
#include "Threading/Primitives/SMTYield.hpp"
#include <mimalloc.h>
#include "Process/AuProcessStartTime.hpp"

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@ -8,27 +8,29 @@
#include <Source/RuntimeInternal.hpp>
#include "Debug.hpp"
#include "ErrorStack.hpp"
#include <Source/Memory/Heap.hpp>
#include <Source/Memory/AuHeap.hpp>
#include <Source/Memory/AuBaseHeap.hpp>
namespace Aurora::Debug
{
static thread_local AuSInt tlsMemoryCrunchCounter;
static auto const kAutoReservePool = 3 * 1024 * 1024;
static auto const kDefaultReservePool = 3 * 1024 * 1024;
AuUInt8 *gReservePoolStart {};
AuUInt8 *gReservePoolEnd {};
// Extern defintions
AuUInt8 *gReservePoolStart {};
AuUInt8 *gReservePoolEnd {};
AuSPtr<AuMemory::Heap> gReserveHeap {};
void InitMemoryCrunch()
{
gReserveHeap = AuMemory::AllocHeapShared(gRuntimeConfig.debug.uDebugMemoryReserveSize ?
gRuntimeConfig.debug.uDebugMemoryReserveSize :
kAutoReservePool);
kDefaultReservePool);
SysAssert(gReserveHeap);
auto pHeap = AuStaticCast<AuMemory::BaseHeap>(gReserveHeap);
gReservePoolStart = AuReinterpretCast<AuUInt8 *>(pHeap->base_);
gReservePoolEnd = AuReinterpretCast<AuUInt8 *>(pHeap->base_) + pHeap->length_;
gReservePoolStart = AuReinterpretCast<AuUInt8 *>(pHeap->GetHeapBase());
gReservePoolEnd = AuReinterpretCast<AuUInt8 *>(gReservePoolStart) + pHeap->GetHeapLength();
}
bool IsPointerReserveRange(void *ptr)

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@ -9,7 +9,7 @@
namespace Aurora::HWInfo
{
inline AuUInt32 gPageSize;
inline AuUInt32 gPageSize { 4096 }; // harden: specify default value in case of early access
template<typename T>
AuOptional<T> QueryBsdHwStat(int id);

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@ -0,0 +1,28 @@
/***
Copyright (C) 2021-2024 J Reece Wilson (a/k/a "Reece"). All rights reserved.
File: AuBaseHeap.cpp
Date: 2021-6-12
Author: Reece
***/
#include <Source/RuntimeInternal.hpp>
#include "AuBaseHeap.hpp"
namespace Aurora::Memory
{
HeapStats &BaseHeap::GetStats()
{
UpdateStats();
return stats;
}
void *BaseHeap::GetHeapBase()
{
return this->pBase_;
}
AuUInt BaseHeap::GetHeapLength()
{
return this->uLength_;
}
}

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@ -0,0 +1,28 @@
/***
Copyright (C) 2021 J Reece Wilson (a/k/a "Reece"). All rights reserved.
File: AuBaseHeap.hpp
Date: 2021-6-12
Author: Reece
***/
#pragma once
namespace Aurora::Memory
{
struct BaseHeap : Heap
{
virtual void UpdateStats() = 0;
HeapStats &GetStats() override;
void *GetHeapBase();
AuUInt GetHeapLength();
protected:
HeapStats stats;
protected:
void *pBase_ {};
AuUInt uLength_ {};
};
}

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@ -0,0 +1,144 @@
/***
Copyright (C) 2021 J Reece Wilson (a/k/a "Reece"). All rights reserved.
File: AuDefaultHeap.cpp
Date: 2021-6-13
Author: Reece
***/
#include <Source/RuntimeInternal.hpp>
#include "AuDefaultHeap.hpp"
#include "AuHeap.hpp"
#include <Source/Debug/MemoryCrunch.hpp>
#include <mimalloc.h>
namespace Aurora::Memory
{
AuSPtr<Heap> DefaultHeap::AllocateDivision(AuUInt32 heap, AuUInt32 alignment)
{
return AllocateDivisionGlobal(this, heap, alignment);
}
void *DefaultHeap::_ZAlloc(Types::size_t length)
{
return AuMemory::_ZAlloc(length);
}
void *DefaultHeap::_ZAlloc(Types::size_t length, Types::size_t align)
{
return AuMemory::_ZAlloc(length, align);
}
Types::size_t DefaultHeap::GetChunkSize(const void *head)
{
return AuMemory::GetChunkSize(head);
}
void *DefaultHeap::_FAlloc(Types::size_t length)
{
return AuMemory::_FAlloc(length);
}
void *DefaultHeap::_FAlloc(Types::size_t length, Types::size_t align)
{
return AuMemory::_FAlloc(length, align);
}
void *DefaultHeap::_ZRealloc(void *buffer, Types::size_t length, Types::size_t align)
{
return AuMemory::_ZRealloc(buffer, length, align);
}
void *DefaultHeap::_ZRealloc(void *buffer, Types::size_t length)
{
return AuMemory::_ZRealloc(buffer, length);
}
void *DefaultHeap::_FRealloc(void *buffer, Types::size_t length, Types::size_t align)
{
return AuMemory::_FRealloc(buffer, length, align);
}
void *DefaultHeap::_FRealloc(void *buffer, Types::size_t length)
{
return AuMemory::_FRealloc(buffer, length);
}
void DefaultHeap::_Free(void *buffer)
{
return AuMemory::_Free(buffer);
}
AuSPtr<Heap> DefaultHeap::GetSelfReference()
{
return {};
}
Heap *DefaultHeap::GetSelfReferenceRaw()
{
return this;
}
struct WalkInstance
{
bool(*fCallback)(void *, void *);
void *pSecondArg;
};
static bool mi_block_visit_funHandler(const mi_heap_t *heap, const mi_heap_area_t *area, void *block, size_t block_size, void *arg)
{
auto pWalkInstance = (WalkInstance *)arg;
if (!block)
{
return true;
}
if (!area->used)
{
return true;
}
#if 0
for (AU_ITERATE_N(i, area->used))
{
if (!pWalkInstance->fCallback(((AuUInt *)block) + (i * area->block_size), pWalkInstance->pSecondArg))
{
return false;
}
}
#else
return pWalkInstance->fCallback(block, pWalkInstance->pSecondArg);
#endif
return true;
}
void DefaultHeap::WalkHeap(bool(*fCallback)(void *, void*), void *pSecondArg)
{
WalkInstance inst;
inst.fCallback = fCallback;
inst.pSecondArg = pSecondArg;
mi_heap_visit_blocks(mi_heap_get_default(), true , &mi_block_visit_funHandler, &inst);
}
void DefaultHeap::UpdateStats()
{
auto other = AuDebug::gReserveHeap->GetStats();
this->stats.bIsSharedWithOtherHeaps = true;
this->stats.uBytesLiveCounter = gBytesCounterAllocated + other.uBytesLiveCounter;
this->stats.uBytesPeakCounter = AuMax(gBytesCounterPeak, other.uBytesPeakCounter);
if (!this->stats.uBytesCapacity)
{
this->stats.uBytesCapacity = Aurora::HWInfo::GetMemStatSystem /*should be process, but process is this with extra steps.*/().value_or(AuHwInfo::RamStat { }).qwAvailable;
}
}
static DefaultHeap gDefaultAllocation;
AUKN_SYM Heap *DefaultDiscontiguousHeapNew()
{
return &gDefaultAllocation;
}
AUKN_SYM void DefaultDiscontiguousHeapRelease(Heap * heap) {}
}

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@ -0,0 +1,34 @@
/***
Copyright (C) 2021 J Reece Wilson (a/k/a "Reece"). All rights reserved.
File: AuDefaultHeap.hpp
Date: 2021-6-13
Author: Reece
***/
#pragma once
#include "AuBaseHeap.hpp"
namespace Aurora::Memory
{
struct DefaultHeap : BaseHeap
{
AuSPtr<Heap> AllocateDivision(AuUInt32 heap, AuUInt32 alignment) override;
void *_ZAlloc(Types::size_t length) override;
void *_ZAlloc(Types::size_t length, Types::size_t align) override;
Types::size_t GetChunkSize(const void *head) override;
void *_FAlloc(Types::size_t length) override;
void *_FAlloc(Types::size_t length, Types::size_t align) override;
void *_ZRealloc(void *buffer, Types::size_t length, Types::size_t align) override;
void *_ZRealloc(void *buffer, Types::size_t length) override;
void *_FRealloc(void *buffer, Types::size_t length, Types::size_t align) override;
void *_FRealloc(void *buffer, Types::size_t length) override;
void _Free(void *buffer) override;
AuSPtr<Heap> GetSelfReference() override;
Heap *GetSelfReferenceRaw() override;
void WalkHeap(bool(*fCallback)(void *, void *), void *pSecondArg) override;
void UpdateStats() override;
};
}

17
Source/Memory/AuHeap.cpp Normal file
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@ -0,0 +1,17 @@
/***
Copyright (C) 2021 J Reece Wilson (a/k/a "Reece"). All rights reserved.
File: AuHeap.cpp
Date: 2021-6-12
Author: Reece
***/
#include <Source/RuntimeInternal.hpp>
#include "AuHeap.hpp"
namespace Aurora::Memory
{
AuUInt32 RoundPageUp(AuUInt32 uLength)
{
return AuPageRoundUp(uLength, HWInfo::GetPageSize());
}
}

18
Source/Memory/AuHeap.hpp Normal file
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@ -0,0 +1,18 @@
/***
Copyright (C) 2021 J Reece Wilson (a/k/a "Reece"). All rights reserved.
File: AuHeap.hpp
Date: 2021-6-12
Author: Reece
***/
#pragma once
#include "AuMemory.hpp"
#include "AuBaseHeap.hpp"
namespace Aurora::Memory
{
AuUInt32 RoundPageUp(AuUInt32 value);
AuSPtr<Heap> AllocateDivisionGlobal(Heap *heap, AuUInt32 length, AuUInt32 alignment);
}

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@ -0,0 +1,28 @@
/***
Copyright (C) 2021-2024 J Reece Wilson (a/k/a "Reece"). All rights reserved.
File: AuHeapDeletable.cpp
File: AuHeap.cpp
Date: 2021-6-12
Author: Reece
***/
#include <Source/RuntimeInternal.hpp>
#include "AuHeapDeletable.hpp"
namespace Aurora::Memory
{
DeletableHeap::DeletableHeap(Heap *parent, void *ptr) :
pParent(pParent),
ptr2_(ptr)
{
}
DeletableHeap::~DeletableHeap()
{
if (this->ptr2_)
{
pParent->Free(this->ptr2_);
}
}
}

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@ -0,0 +1,23 @@
/***
Copyright (C) 2021-2024 J Reece Wilson (a/k/a "Reece"). All rights reserved.
File: AuHeapDeletable.hpp
File: Heap.hpp
Date: 2021-6-12
Author: Reece
***/
#pragma once
#include "AuHeapInternal.hpp"
namespace Aurora::Memory
{
struct DeletableHeap : InternalHeap
{
Heap *pParent {};
void *ptr2_ {};
DeletableHeap(Heap *pParent, void *ptr);
~DeletableHeap();
};
}

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@ -0,0 +1,349 @@
/***
Copyright (C) 2021-2024 J Reece Wilson (a/k/a "Reece"). All rights reserved.
File: AuHeapInternal.cpp
File: AuHeap.cpp
Date: 2021-6-12
Author: Reece
***/
#include <Source/RuntimeInternal.hpp>
#include "AuHeap.hpp"
#include "AuHeapInternal.hpp"
#include "AuHeapDeletable.hpp"
typedef struct FragmentHeader
{
void * next;
void * prev;
size_t size;
bool used;
} FragmentHeader;
namespace Aurora::Memory
{
InternalHeap::InternalHeap() :
heap_(nullptr),
count_(0)
{ }
InternalHeap::InternalHeap(const MemoryViewWrite &memory)
{
SysAssert(this->Init(memory.length, memory.ptr));
}
InternalHeap::InternalHeap(AuUInt uLength)
{
SysAssert(this->Init(uLength), "Couldn't initialize inline AuHeap! [OOM]");
}
InternalHeap::~InternalHeap()
{
SysAssertDbgExp(this->count_ == 0);
if (this->pBase_)
{
if (this->heap_)
{
this->heap_ = nullptr;
}
if (this->bOwnsMemory_)
{
SysAllocateFree(this->pBase_, this->uLength_);
this->pBase_ = nullptr;
}
}
}
AuUInt InternalHeap::GetHeapSize(const void *ptr)
{
return reinterpret_cast<const FragmentHeader *>(ptr)[-1].size;
}
bool InternalHeap::Init(AuUInt uLength, void *ptr)
{
SysAssert(!this->pBase_, "heap already initialized");
SysAssert(uLength, "invalid heap allocation");
if (ptr)
{
this->pBase_ = ptr;
this->uLength_ = uLength;
this->bOwnsMemory_ = false;
}
else
{
if (uLength <= 4096)
{
uLength = 4096;
}
if (!(this->pBase_ = SysAllocateLarge(uLength)))
{
return false;
}
this->bOwnsMemory_ = true;
this->uLength_ = uLength;
}
if (!(this->heap_ = o1heapInit(this->pBase_, uLength)))
{
return false;
}
return true;
}
Types::size_t InternalHeap::GetChunkSize(const void *head)
{
return InternalHeap::GetHeapSize(head);
}
AuSPtr<Heap> InternalHeap::AllocateDivision(AuUInt32 heap, AuUInt32 alignment)
{
return AllocateDivisionGlobal(this, heap, alignment);
}
AuSPtr<Heap> AllocateDivisionGlobal(Heap *heap, AuUInt32 uLength, AuUInt32 alignment)
{
auto ptr = heap->ZAlloc<void *>(uLength, alignment);
if (!ptr)
{
return {};
}
auto ret = AuMakeShared<DeletableHeap>(heap, ptr);
if (!ret)
{
heap->Free(ptr);
return {};
}
if (!ret->Init(uLength, ptr))
{
return {};
}
return ret;
}
void *InternalHeap::_FAlloc(Types::size_t uLength)
{
if (!this->heap_)
{
return nullptr;
}
auto ret = o1heapAllocate(this->heap_, uLength);
if (ret)
{
AuAtomicAdd(&this->count_, 1);
}
return ret;
}
void *InternalHeap::_FAlloc(Types::size_t uLength, Types::size_t uAlign)
{
SysAssert(uAlign <= O1HEAP_ALIGNMENT, "heap wrapping is unsupported, alignment past the supported 2^x alignment is not possible");
return this->_FAlloc(uLength);
}
void *InternalHeap::_ZAlloc(Types::size_t uLength)
{
if (!this->heap_)
{
return nullptr;
}
auto ptr = this->_FAlloc(uLength);
if (!ptr)
{
return nullptr;
}
AuMemset(ptr, 0, uLength);
return ptr;
}
void *InternalHeap::_ZAlloc(Types::size_t uLength, Types::size_t uAlign)
{
SysAssert(uAlign <= O1HEAP_ALIGNMENT, "heap wrapping is unsupported, alignment past the supported 2^x alignment is not possible");
return _ZAlloc(uLength);
}
void *InternalHeap::_ZRealloc(void *pBuffer, Types::size_t uLength)
{
auto prevLength = GetHeapSize(pBuffer);
auto alloc = this->_ZAlloc(uLength);
if (!alloc)
{
return nullptr;
}
AuMemcpy(alloc, pBuffer, AuMin(prevLength, uLength));
this->_Free(pBuffer);
return alloc;
}
void *InternalHeap::_ZRealloc(void *pBuffer, Types::size_t uLength, Types::size_t uAlign)
{
SysAssert(uAlign <= O1HEAP_ALIGNMENT, "heap wrapping is unsupported, alignment past the supported 2^x alignment is not possible");
return this->_ZRealloc(pBuffer, uLength);
}
void *InternalHeap::_FRealloc(void *pBuffer, Types::size_t uLength)
{
auto prevLength = GetHeapSize(pBuffer);
auto alloc = this->_FAlloc(uLength);
if (!alloc)
{
return nullptr;
}
AuMemcpy(alloc, pBuffer, AuMin(prevLength, uLength));
this->_Free(pBuffer);
return alloc;
}
void *InternalHeap::_FRealloc(void *pBuffer, Types::size_t uLength, Types::size_t uAlign)
{
SysAssert(uAlign <= O1HEAP_ALIGNMENT, "heap wrapping is unsupported, alignment past the supported 2^x alignment is not possible");
return this->_FRealloc(pBuffer, uLength);
}
void InternalHeap::_Free(void *pBuffer)
{
if (pBuffer == nullptr)
{
return;
}
o1heapFree(this->heap_, pBuffer);
DecrementUsers();
}
void InternalHeap::DecrementUsers()
{
if (AuAtomicSub(&this->count_, 1) == 0)
{
TryRelease();
}
}
void InternalHeap::TryRelease()
{
if (!this->bIsDangling_)
{
return;
}
if (count_ == 0)
{
delete this;
}
}
void InternalHeap::RequestTermination()
{
if (AuAtomicLoad(&this->count_))
{
SysPushErrorMemory("Heap life was less than its allocations, waiting for final free");
SysPushErrorMemory("Reporting using mayday!");
// Write a crash dump for later review, and do not panic.
// We just have a leak with no sign of corruption
Telemetry::Mayday();
this->bIsDangling_ = true;
}
else
{
delete this;
}
}
void InternalHeap::UpdateStats()
{
auto pDiag = o1heapGetDiagnostics(this->heap_);
this->stats.uBytesLiveCounter = pDiag.allocated;
this->stats.uBytesCapacity = pDiag.capacity;
this->stats.uBytesPeakCounter = pDiag.peak_allocated;
}
void InternalHeap::WalkHeap(bool(*fCallback)(void *, void *), void *pSecondArg)
{
o1heapTraverseHeap(this->heap_, fCallback, pSecondArg);
}
AuSPtr<Heap> InternalHeap::GetSelfReference()
{
try
{
return AuSharedFromThis();
}
catch (...)
{
return {};
}
}
Heap *InternalHeap::GetSelfReferenceRaw()
{
return this;
}
AUKN_SYM Heap *AllocHeapNew(AuUInt uSize)
{
auto pHeap = _new InternalHeap();
if (!pHeap)
{
return nullptr;
}
if (!pHeap->Init(uSize, nullptr))
{
delete pHeap;
return nullptr;
}
return pHeap;
}
AUKN_SYM void AllocHeapRelease(Heap *pHeap)
{
static_cast<InternalHeap *>(pHeap)->RequestTermination();
}
AUKN_SYM Heap *RequestHeapOfRegionNew(const MemoryViewWrite &memory)
{
if (!memory)
{
SysPushErrorArg();
return nullptr;
}
auto pHeap = _new InternalHeap();
if (!pHeap)
{
return nullptr;
}
if (!pHeap->Init(memory.length, memory.ptr))
{
delete pHeap;
return nullptr;
}
return pHeap;
}
AUKN_SYM void RequestHeapOfRegionRelease(Heap *pHeap)
{
static_cast<InternalHeap *>(pHeap)->RequestTermination();
}
AUROXTL_INTERFACE_SOO_SRC_EX(AURORA_SYMBOL_EXPORT, RequestHeapOfRegion, InternalHeap, (const MemoryViewWrite &, memory))
AUROXTL_INTERFACE_SOO_SRC_EX(AURORA_SYMBOL_EXPORT, AllocHeap, InternalHeap, (AuUInt, uLength))
}

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@ -0,0 +1,64 @@
/***
Copyright (C) 2021-2024 J Reece Wilson (a/k/a "Reece"). All rights reserved.
File: AuHeapInternal.hpp
File: Heap.hpp
Date: 2021-6-12
Author: Reece
***/
#pragma once
#include "AuMemory.hpp"
#include "AuBaseHeap.hpp"
#include "o1heap.hpp"
namespace Aurora::Memory
{
struct InternalHeap :
BaseHeap,
AuEnableSharedFromThis<InternalHeap>
{
virtual AuSPtr<Heap> AllocateDivision(AuUInt32 heap, AuUInt32 alignment) override;
InternalHeap();
InternalHeap(const MemoryViewWrite &memory);
InternalHeap(AuUInt uLength);
virtual ~InternalHeap();
bool Init(AuUInt uLength, void *ptr = nullptr);
static AuUInt GetHeapSize(const void *ptr);
Types::size_t GetChunkSize(const void *head) override;
void *_FAlloc(Types::size_t uLength) override;
void *_FAlloc(Types::size_t uLength, Types::size_t uAlign) override;
void *_ZAlloc(Types::size_t uLength) override;
void *_ZAlloc(Types::size_t uLength, Types::size_t uAlign) override;
void *_ZRealloc(void *pBuffer, Types::size_t uLength) override;
void *_ZRealloc(void *pBuffer, Types::size_t uLength, Types::size_t uAlign) override;
void *_FRealloc(void *pBuffer, Types::size_t uLength) override;
void *_FRealloc(void *pBuffer, Types::size_t uLength, Types::size_t uAlign) override;
void _Free(void *pBuffer) override;
AuSPtr<Heap> GetSelfReference() override;
Heap *GetSelfReferenceRaw() override;
void TryRelease();
void DecrementUsers();
void RequestTermination();
void UpdateStats() override;
void WalkHeap(bool(*fCallback)(void *, void *), void *pSecondArg) override;
private:
O1HeapInstance *heap_ {};
int count_ {};
bool bIsDangling_ {};
protected:
bool bOwnsMemory_ {};
};
}

View File

@ -1,14 +1,13 @@
/***
Copyright (C) 2024 J Reece Wilson (a/k/a "Reece"). All rights reserved.
File: HeapProxy.cpp
File: AuHeapProxy.cpp
Date: 2024-1-16
Author: Reece
***/
#include <Source/RuntimeInternal.hpp>
#include "Memory.hpp"
#include "Heap.hpp"
#include "HeapProxy.hpp"
#include "AuHeap.hpp"
#include "AuHeapProxy.hpp"
namespace Aurora::Memory
{
@ -58,9 +57,9 @@ namespace Aurora::Memory
}
}
void *ProxyHeap::_ZAlloc(Types::size_t uLength, Types::size_t align)
void *ProxyHeap::_ZAlloc(Types::size_t uLength, Types::size_t uAlign)
{
if (auto pThat = this->pHeap->ZAlloc(uLength, align))
if (auto pThat = this->pHeap->ZAlloc(uLength, uAlign))
{
auto uLengthCurrent = this->GetChunkSize(pThat);
AuAtomicAdd(&this->uBytesLifetime, uLengthCurrent);
@ -103,9 +102,9 @@ namespace Aurora::Memory
}
}
void *ProxyHeap::_FAlloc(Types::size_t uLength, Types::size_t align)
void *ProxyHeap::_FAlloc(Types::size_t uLength, Types::size_t uAlign)
{
if (auto pThat = this->pHeap->_FAlloc(uLength, align))
if (auto pThat = this->pHeap->_FAlloc(uLength, uAlign))
{
auto uLengthCurrent = this->GetChunkSize(pThat);
AuAtomicAdd(&this->uBytesLifetime, uLengthCurrent);
@ -123,13 +122,13 @@ namespace Aurora::Memory
}
}
void *ProxyHeap::_ZRealloc(void *pHead, Types::size_t uLength, Types::size_t align)
void *ProxyHeap::_ZRealloc(void *pHead, Types::size_t uLength, Types::size_t uAlign)
{
if (pHead)
{
auto uLengthCurrent = this->GetChunkSize(pHead);
if (auto pThat = this->pHeap->_ZRealloc(pHead, uLength, align))
if (auto pThat = this->pHeap->_ZRealloc(pHead, uLength, uAlign))
{
auto uLengthNext = this->GetChunkSize(pThat);
AuAtomicAdd(&this->uBytesFree, uLengthCurrent);
@ -185,13 +184,13 @@ namespace Aurora::Memory
}
}
void *ProxyHeap::_FRealloc(void *pHead, Types::size_t uLength, Types::size_t align)
void *ProxyHeap::_FRealloc(void *pHead, Types::size_t uLength, Types::size_t uAlign)
{
if (pHead)
{
auto uLengthCurrent = this->GetChunkSize(pHead);
if (auto pThat = this->pHeap->_FRealloc(pHead, uLength, align))
if (auto pThat = this->pHeap->_FRealloc(pHead, uLength, uAlign))
{
auto uLengthNext = this->GetChunkSize(pThat);
AuAtomicAdd(&this->uBytesFree, uLengthCurrent);
@ -329,4 +328,8 @@ namespace Aurora::Memory
{
AuSafeDelete<ProxyHeap *>(heap);
}
AUROXTL_INTERFACE_SOO_SRC_EX(AURORA_SYMBOL_EXPORT, HeapProxy, ProxyHeap, (const AuSPtr<Heap> &, pHead))
AUROXTL_INTERFACE_SOO_SRC_EX(AURORA_SYMBOL_EXPORT, HeapProxyEx, ProxyHeap, (const AuSPtr<Heap> &, pHead), (LeakFinderAlloc_f, pfAlloc), (LeakFinderFree_f, pfFree))
}

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@ -1,7 +1,7 @@
/***
Copyright (C) 2024 J Reece Wilson (a/k/a "Reece"). All rights reserved.
File: HeapProxy.hpp
File: AuHeapProxy.hpp
Date: 2024-1-16
Author: Reece
***/

View File

@ -1,19 +1,14 @@
/***
Copyright (C) 2021 J Reece Wilson (a/k/a "Reece"). All rights reserved.
File: Memory.cpp
File: AuMemory.cpp
Date: 2021-6-12
Author: Reece
***/
#include <Source/RuntimeInternal.hpp>
#include "Memory.hpp"
#include "AuMemory.hpp"
#include <mimalloc.h>
#include <Source/HWInfo/AuHWInfo.hpp>
#if defined(AURORA_IS_LINUX_DERIVED)
#include <sys/mman.h>
#endif
#include <Source/Debug/MemoryCrunch.hpp>
#include <Source/Debug/ErrorStack.hpp>
@ -23,10 +18,10 @@ namespace Aurora::Memory
AuUInt gBytesCounterPeak {};
thread_local AuInt64 tlsLastOutOfMemory {};
thread_local MemoryLowNotification_f tlsMemoryLowNotification;
static LeakFinderAlloc_f gLeakFinderAlloc;
static LeakFinderFree_f gLeakFinderFree;
thread_local MemoryLowNotification_f tlsMemoryLowNotification;
static LeakFinderFree_f gLeakFinderFree;
static void AddBytesToCounter(AuUInt uBytes)
{
@ -148,8 +143,7 @@ namespace Aurora::Memory
AUKN_SYM void *_ZRealloc(void *buffer, Types::size_t length, Types::size_t align)
{
SysAssertDbg(length);
void *pRet;
void *pRet = nullptr;
if (AuDebug::IsPointerReserveRange(buffer))
{
@ -159,9 +153,15 @@ namespace Aurora::Memory
{
auto oldLen = ::mi_malloc_size(buffer);
pRet = ::mi_rezalloc_aligned(buffer, length, align);
if (pRet)
if (buffer && !length)
{
::mi_free(buffer);
}
else if (!buffer && length)
{
return _ZAlloc(length, align);
}
else if ((pRet = ::mi_rezalloc_aligned(buffer, length, align)))
{
auto uNewSize = ::mi_malloc_size(pRet);
@ -178,14 +178,12 @@ namespace Aurora::Memory
gLeakFinderAlloc(pRet, uNewSize);
}
}
else if (buffer && length)
{
OnOOM(length);
}
}
if (!pRet)
if (!pRet && buffer && length)
{
OnOOM(length);
if (gRuntimeConfig.debug.bIsMemoryErrorFatal)
{
SysPanic("ZAllocEx out of memory");
@ -197,8 +195,7 @@ namespace Aurora::Memory
AUKN_SYM void *_ZRealloc(void *buffer, Types::size_t length)
{
SysAssertDbg(length);
void *pRet;
void *pRet = nullptr;
if (AuDebug::IsPointerReserveRange(buffer))
{
@ -208,9 +205,15 @@ namespace Aurora::Memory
{
auto oldLen = ::mi_malloc_size(buffer);
pRet = ::mi_rezalloc(buffer, length);
if (pRet)
if (buffer && !length)
{
::mi_free(buffer);
}
else if (!buffer && length)
{
return _ZAlloc(length);
}
else if ((pRet = ::mi_rezalloc(buffer, length)))
{
auto uNewSize = ::mi_malloc_size(pRet);
@ -227,14 +230,12 @@ namespace Aurora::Memory
gLeakFinderAlloc(pRet, uNewSize);
}
}
else if (buffer && length)
{
OnOOM(length);
}
}
if (!pRet)
if (!pRet && buffer && length)
{
OnOOM(length);
if (gRuntimeConfig.debug.bIsMemoryErrorFatal)
{
SysPanic("ZAlloc out of memory");
@ -246,8 +247,7 @@ namespace Aurora::Memory
AUKN_SYM void *_FRealloc(void *buffer, Types::size_t length, Types::size_t align)
{
SysAssertDbg(length);
void *pRet;
void *pRet = nullptr;
if (AuDebug::IsPointerReserveRange(buffer))
{
@ -257,9 +257,15 @@ namespace Aurora::Memory
{
auto oldLen = ::mi_malloc_size(buffer);
pRet = ::mi_realloc_aligned(buffer, length, align);
if (pRet)
if (buffer && !length)
{
::mi_free(buffer);
}
else if (!buffer && length)
{
return _FAlloc(length, align);
}
else if ((pRet = ::mi_realloc_aligned(buffer, length, align)))
{
auto uNewSize = ::mi_malloc_size(pRet);
@ -276,14 +282,12 @@ namespace Aurora::Memory
gLeakFinderAlloc(pRet, uNewSize);
}
}
else if (buffer && length)
{
OnOOM(length);
}
}
if (!pRet)
if (!pRet && buffer && length)
{
OnOOM(length);
if (gRuntimeConfig.debug.bIsMemoryErrorFatal)
{
SysPanic("FReallocEx out of memory");
@ -295,8 +299,7 @@ namespace Aurora::Memory
AUKN_SYM void *_FRealloc(void *buffer, Types::size_t length)
{
SysAssertDbg(length);
void *pRet;
void *pRet = nullptr;
if (AuDebug::IsPointerReserveRange(buffer))
{
@ -306,9 +309,15 @@ namespace Aurora::Memory
{
auto oldLen = ::mi_malloc_size(buffer);
pRet = ::mi_realloc(buffer, length);
if (pRet)
if (buffer && !length)
{
::mi_free(buffer);
}
else if (!buffer && length)
{
return _FAlloc(length);
}
else if ((pRet = ::mi_realloc(buffer, length)))
{
auto uNewSize = ::mi_malloc_size(pRet);
@ -325,14 +334,12 @@ namespace Aurora::Memory
gLeakFinderAlloc(pRet, uNewSize);
}
}
else if (buffer && length)
{
OnOOM(length);
}
}
if (!pRet)
if (!pRet && buffer && length)
{
OnOOM(length);
if (gRuntimeConfig.debug.bIsMemoryErrorFatal)
{
SysPanic("FRealloc out of memory");
@ -360,7 +367,6 @@ namespace Aurora::Memory
RemoveBytesFromCounter(uCount);
::mi_free(pHead);
if (gLeakFinderFree)
{
gLeakFinderFree(pHead, uCount);

View File

@ -1,12 +1,14 @@
/***
Copyright (C) 2021 J Reece Wilson (a/k/a "Reece"). All rights reserved.
File: Memory.hpp
File: AuMemory.hpp
Date: 2021-6-12
Author: Reece
***/
#pragma once
#include "AuMemory.hpp"
namespace Aurora::Memory
{
extern AuUInt gBytesCounterAllocated;

View File

@ -1,13 +1,13 @@
/***
Copyright (C) 2022 J Reece Wilson (a/k/a "Reece"). All rights reserved.
File: Cache.cpp
File: AuMemoryCache.cpp
Date: 2022-3-21
Author: Reece
***/
#include <Source/RuntimeInternal.hpp>
#include "Memory.hpp"
#include "Cache.hpp"
#include "AuMemory.hpp"
#include "AuMemoryCache.hpp"
#include <Source/HWInfo/AuHWInfo.hpp>
#define LINUX_SUPPORTS_CACHE_CTL 0

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@ -1,7 +1,7 @@
/***
Copyright (C) 2022 J Reece Wilson (a/k/a "Reece"). All rights reserved.
File: Cache.hpp
File: AuMemoryCache.hpp
Date: 2022-3-21
Author: Reece
***/

View File

@ -1,13 +1,13 @@
/***
Copyright (C) 2022 J Reece Wilson (a/k/a "Reece"). All rights reserved.
File: SwapLock.cpp
File: AuMemorySwapLock.cpp
Date: 2022-3-21
Author: Reece
***/
#include <Source/RuntimeInternal.hpp>
#include "Memory.hpp"
#include "SwapLock.hpp"
#include "AuMemory.hpp"
#include "AuMemorySwapLock.hpp"
#include <Source/HWInfo/AuHWInfo.hpp>
#if defined(AURORA_IS_LINUX_DERIVED)

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@ -1,7 +1,7 @@
/***
Copyright (C) 2022 J Reece Wilson (a/k/a "Reece"). All rights reserved.
File: SwapLock.hpp
File: AuMemorySwapLock.hpp
Date: 2022-3-21
Author: Reece
***/

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@ -1,148 +0,0 @@
/***
Copyright (C) 2021 J Reece Wilson (a/k/a "Reece"). All rights reserved.
File: DefaultHeap.cpp
Date: 2021-6-13
Author: Reece
***/
#include <Source/RuntimeInternal.hpp>
#include "Memory.hpp"
#include "DefaultHeap.hpp"
#include "Heap.hpp"
#include <Source/Debug/MemoryCrunch.hpp>
#include <mimalloc.h>
namespace Aurora::Memory
{
struct DefaultHeap : BaseHeap
{
AuSPtr<Heap> AllocateDivision(AuUInt32 heap, AuUInt32 alignment) override
{
return AllocateDivisionGlobal(this, heap, alignment);
}
void *_ZAlloc(Types::size_t length) override
{
return Aurora::Memory::_ZAlloc(length);
}
void *_ZAlloc(Types::size_t length, Types::size_t align) override
{
return Aurora::Memory::_ZAlloc(length, align);
}
Types::size_t GetChunkSize(const void *head) override
{
return Aurora::Memory::GetChunkSize(head);
}
void *_FAlloc(Types::size_t length) override
{
return Aurora::Memory::_FAlloc(length);
}
void *_FAlloc(Types::size_t length, Types::size_t align) override
{
return Aurora::Memory::_FAlloc(length, align);
}
void *_ZRealloc(void *buffer, Types::size_t length, Types::size_t align) override
{
return Aurora::Memory::_ZRealloc(buffer, length, align);
}
void *_ZRealloc(void *buffer, Types::size_t length) override
{
return Aurora::Memory::_ZRealloc(buffer, length);
}
void *_FRealloc(void *buffer, Types::size_t length, Types::size_t align) override
{
return Aurora::Memory::_FRealloc(buffer, length, align);
}
void *_FRealloc(void *buffer, Types::size_t length) override
{
return Aurora::Memory::_FRealloc(buffer, length);
}
void _Free(void *buffer) override
{
return Aurora::Memory::_Free(buffer);
}
AuSPtr<Heap> GetSelfReference() override
{
return {};
}
Heap *GetSelfReferenceRaw() override
{
return this;
}
struct WalkInstance
{
bool(*fCallback)(void *, void *);
void *pSecondArg;
};
static bool mi_block_visit_funHandler(const mi_heap_t *heap, const mi_heap_area_t *area, void *block, size_t block_size, void *arg)
{
auto pWalkInstance = (WalkInstance *)arg;
if (!block)
{
return true;
}
if (!area->used)
{
return true;
}
#if 0
for (AU_ITERATE_N(i, area->used))
{
if (!pWalkInstance->fCallback(((AuUInt *)block) + (i * area->block_size), pWalkInstance->pSecondArg))
{
return false;
}
}
#else
return pWalkInstance->fCallback(block, pWalkInstance->pSecondArg);
#endif
return true;
}
void WalkHeap(bool(*fCallback)(void *, void*), void *pSecondArg) override
{
WalkInstance inst;
inst.fCallback = fCallback;
inst.pSecondArg = pSecondArg;
mi_heap_visit_blocks(mi_heap_get_default(), true , &mi_block_visit_funHandler, &inst);
}
void UpdateStats() override
{
auto other = AuDebug::gReserveHeap->GetStats();
this->stats.bIsSharedWithOtherHeaps = true;
this->stats.uBytesLiveCounter = gBytesCounterAllocated + other.uBytesLiveCounter;
this->stats.uBytesPeakCounter = AuMax(gBytesCounterPeak, other.uBytesPeakCounter);
if (!this->stats.uBytesCapacity)
{
this->stats.uBytesCapacity = Aurora::HWInfo::GetMemStatSystem /*should be process, but process is this with extra steps.*/().value_or(AuHwInfo::RamStat { }).qwAvailable;
}
}
};
static DefaultHeap gDefaultAllocation;
AUKN_SYM Heap *DefaultDiscontiguousHeapNew()
{
return &gDefaultAllocation;
}
AUKN_SYM void DefaultDiscontiguousHeapRelease(Heap * heap) {}
}

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@ -1,12 +0,0 @@
/***
Copyright (C) 2021 J Reece Wilson (a/k/a "Reece"). All rights reserved.
File: DefaultHeap.hpp
Date: 2021-6-13
Author: Reece
***/
#pragma once
namespace Aurora::Memory
{
}

View File

@ -1,432 +0,0 @@
/***
Copyright (C) 2021 J Reece Wilson (a/k/a "Reece"). All rights reserved.
File: Heap.cpp
Date: 2021-6-12
Author: Reece
***/
#include <Source/RuntimeInternal.hpp>
#include "Memory.hpp"
#include "Heap.hpp"
#include "mimalloc.h"
#include "o1heap.hpp"
#if defined(AURORA_IS_POSIX_DERIVED)
#include <sys/mman.h>
#endif
namespace Aurora::Memory
{
static AuUInt32 RoundPageUp(AuUInt32 value)
{
return AuPageRoundUp(value, HWInfo::GetPageSize());
}
static void *HeapLargeAllocate(AuUInt length)
{
length = RoundPageUp(length);
#if defined(AURORA_IS_MODERNNT_DERIVED)
return VirtualAlloc(nullptr, length, MEM_COMMIT | MEM_RESERVE, PAGE_READWRITE);
#elif defined(AURORA_IS_POSIX_DERIVED)
return mmap(0, length, PROT_READ | PROT_WRITE, MAP_PRIVATE | MAP_ANONYMOUS, -1, 0);
#else
// ideally we should page align.
// i think mimalloc has fast paths with warnings for overly large passthrough allocations. unsure.
// 32 alignment in the fastest way mimalloc can provide us memory seems adequate
// it's very easy for mimalloc to seethe at larger allocations, but it does have slowpaths to handle them
return AuMemory::FAlloc<void *>(length, 32);
#endif
}
static void HeapLargeFree(void *buffer, AuUInt length)
{
length = RoundPageUp(length);
#if defined(AURORA_IS_MODERNNT_DERIVED)
VirtualFree(buffer, 0, MEM_RELEASE);
#elif defined(AURORA_IS_POSIX_DERIVED)
munmap(buffer, length);
#else
AuMemory::Free(buffer);
mi_collect(false);
#endif
}
struct InternalHeap : BaseHeap, AuEnableSharedFromThis<InternalHeap>
{
virtual AuSPtr<Heap> AllocateDivision(AuUInt32 heap, AuUInt32 alignment) override;
InternalHeap() : heap_(nullptr), count_(0)
{ }
virtual ~InternalHeap();
bool ownsMemory_ {};
bool Init(AuUInt length, void *ptr = nullptr);
typedef struct FragmentHeader
{
void *next;
void *prev;
size_t size;
bool used;
} FragmentHeader;
static AuUInt GetHeapSize(const void *ptr)
{
return reinterpret_cast<const FragmentHeader *>(ptr)[-1].size;
}
Types::size_t GetChunkSize(const void *head) override;
void *_FAlloc(Types::size_t length) override;
void *_FAlloc(Types::size_t length, Types::size_t align) override;
void *_ZAlloc(Types::size_t length) override;
void *_ZAlloc(Types::size_t length, Types::size_t align) override;
void *_ZRealloc(void *buffer, Types::size_t length) override;
void *_ZRealloc(void *buffer, Types::size_t length, Types::size_t align) override;
void *_FRealloc(void *buffer, Types::size_t length) override;
void *_FRealloc(void *buffer, Types::size_t length, Types::size_t align) override;
void _Free(void *buffer) override;
AuSPtr<Heap> GetSelfReference() override;
Heap *GetSelfReferenceRaw() override;
void TryRelease();
void DecrementUsers();
void RequestTermination();
void UpdateStats() override;
void WalkHeap(bool(*fCallback)(void *, void *), void *pSecondArg) override;
private:
O1HeapInstance *heap_ {};
int count_ {};
bool isDangling_ {};
};
struct DeletableHeap : InternalHeap
{
Heap *parent {};
void *ptr2_ {};
DeletableHeap(Heap *parent, void *ptr);
~DeletableHeap();
};
DeletableHeap::DeletableHeap(Heap *parent, void *ptr) : parent(parent), ptr2_(ptr)
{
}
DeletableHeap::~DeletableHeap()
{
if (this->ptr2_)
{
parent->Free(this->ptr2_);
}
}
InternalHeap::~InternalHeap()
{
SysAssertDbgExp(count_ == 0);
if (this->base_)
{
if (this->heap_)
{
this->heap_ = nullptr;
}
if (this->ownsMemory_)
{
HeapLargeFree(this->base_, this->length_);
this->base_ = nullptr;
}
}
}
bool InternalHeap::Init(AuUInt length, void *ptr)
{
SysAssert(!this->base_, "heap already initialized");
SysAssert(length, "invalid heap allocation");
if (ptr)
{
this->base_ = ptr;
this->length_ = length;
this->ownsMemory_ = false;
}
else
{
if (length <= 4096)
{
length = 4086;
}
if (!(this->base_ = HeapLargeAllocate(length)))
{
return false;
}
this->ownsMemory_ = true;
this->length_ = length;
}
if (!(this->heap_ = o1heapInit(this->base_, length)))
{
return false;
}
return true;
}
Types::size_t InternalHeap::GetChunkSize(const void *head)
{
return InternalHeap::GetHeapSize(head);
}
AuSPtr<Heap> InternalHeap::AllocateDivision(AuUInt32 heap, AuUInt32 alignment)
{
return AllocateDivisionGlobal(this, heap, alignment);
}
AuSPtr<Heap> AllocateDivisionGlobal(Heap *heap, AuUInt32 length, AuUInt32 alignment)
{
auto ptr = heap->ZAlloc<void *>(length, alignment);
if (!ptr)
{
return {};
}
auto ret = AuMakeShared<DeletableHeap>(heap, ptr);
if (!ret)
{
heap->Free(ptr);
return {};
}
if (!ret->Init(length, ptr))
{
return {};
}
return ret;
}
void *InternalHeap::_FAlloc(Types::size_t length)
{
if (!this->heap_)
{
return nullptr;
}
auto ret = o1heapAllocate(this->heap_, length);
if (ret)
{
AuAtomicAdd(&this->count_, 1);
}
return ret;
}
void *InternalHeap::_FAlloc(Types::size_t length, Types::size_t align)
{
SysAssert(align <= O1HEAP_ALIGNMENT, "heap wrapping is unsupported, alignment past the supported 2^x alignment is not possible");
return this->_FAlloc(length);
}
void *InternalHeap::_ZAlloc(Types::size_t length)
{
if (!this->heap_)
{
return nullptr;
}
auto ptr = this->_FAlloc(length);
if (!ptr)
{
return nullptr;
}
AuMemset(ptr, 0, length);
return ptr;
}
void *InternalHeap::_ZAlloc(Types::size_t length, Types::size_t align)
{
SysAssert(align <= O1HEAP_ALIGNMENT, "heap wrapping is unsupported, alignment past the supported 2^x alignment is not possible");
return _ZAlloc(length);
}
void *InternalHeap::_ZRealloc(void *buffer, Types::size_t length)
{
auto prevLength = GetHeapSize(buffer);
auto alloc = this->_ZAlloc(length);
if (!alloc)
{
return nullptr;
}
AuMemcpy(alloc, buffer, AuMin(prevLength, length));
this->_Free(buffer);
return alloc;
}
void *InternalHeap::_ZRealloc(void *buffer, Types::size_t length, Types::size_t align)
{
SysAssert(align <= O1HEAP_ALIGNMENT, "heap wrapping is unsupported, alignment past the supported 2^x alignment is not possible");
return this->_ZRealloc(buffer, length);
}
void *InternalHeap::_FRealloc(void *buffer, Types::size_t length)
{
auto prevLength = GetHeapSize(buffer);
auto alloc = this->_FAlloc(length);
if (!alloc)
{
return nullptr;
}
AuMemcpy(alloc, buffer, AuMin(prevLength, length));
this->_Free(buffer);
return alloc;
}
void *InternalHeap::_FRealloc(void *buffer, Types::size_t length, Types::size_t align)
{
SysAssert(align <= O1HEAP_ALIGNMENT, "heap wrapping is unsupported, alignment past the supported 2^x alignment is not possible");
return this->_FRealloc(buffer, length);
}
void InternalHeap::_Free(void *buffer)
{
if (buffer == nullptr)
{
return;
}
o1heapFree(this->heap_, buffer);
DecrementUsers();
}
void InternalHeap::DecrementUsers()
{
if (AuAtomicSub(&this->count_, 1) == 0)
{
TryRelease();
}
}
void InternalHeap::TryRelease()
{
if (!this->isDangling_)
{
return;
}
if (count_ == 0)
{
delete this;
}
}
void InternalHeap::RequestTermination()
{
if (AuAtomicLoad(&this->count_))
{
SysPushErrorMemory("Heap life was less than its allocations, waiting for final free");
SysPushErrorMemory("Reporting using mayday!");
// Write a crash dump for later review, and do not panic.
// We just have a leak with no sign of corruption
Telemetry::Mayday();
this->isDangling_ = true;
}
else
{
delete this;
}
}
void InternalHeap::UpdateStats()
{
auto pDiag = o1heapGetDiagnostics(this->heap_);
this->stats.uBytesLiveCounter = pDiag.allocated;
this->stats.uBytesCapacity = pDiag.capacity;
this->stats.uBytesPeakCounter = pDiag.peak_allocated;
}
void InternalHeap::WalkHeap(bool(*fCallback)(void *, void *), void *pSecondArg)
{
o1heapTraverseHeap(this->heap_, fCallback, pSecondArg);
}
AuSPtr<Heap> InternalHeap::GetSelfReference()
{
try
{
return AuSharedFromThis();
}
catch (...)
{
return {};
}
}
Heap *InternalHeap::GetSelfReferenceRaw()
{
return this;
}
AUKN_SYM Heap *AllocHeapNew(AuUInt size)
{
auto heap = _new InternalHeap();
if (!heap)
{
return nullptr;
}
if (!heap->Init(size, nullptr))
{
delete heap;
return nullptr;
}
return heap;
}
AUKN_SYM void AllocHeapRelease(Heap *heap)
{
static_cast<InternalHeap *>(heap)->RequestTermination();
}
AUKN_SYM Heap *RequestHeapOfRegionNew(const MemoryViewWrite &memory)
{
if (!memory)
{
SysPushErrorArg();
return nullptr;
}
auto heap = _new InternalHeap();
if (!heap)
{
return nullptr;
}
if (!heap->Init(memory.length, memory.ptr))
{
delete heap;
return nullptr;
}
return heap;
}
AUKN_SYM void RequestHeapOfRegionRelease(Heap *heap)
{
static_cast<InternalHeap *>(heap)->RequestTermination();
}
}

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@ -1,28 +0,0 @@
/***
Copyright (C) 2021 J Reece Wilson (a/k/a "Reece"). All rights reserved.
File: Heap.hpp
Date: 2021-6-12
Author: Reece
***/
#pragma once
namespace Aurora::Memory
{
struct BaseHeap : Heap
{
void *base_ {};
AuUInt length_ {};
HeapStats stats;
virtual void UpdateStats() = 0;
inline HeapStats &GetStats() override
{
UpdateStats();
return stats;
}
};
AuSPtr<Heap> AllocateDivisionGlobal(Heap *heap, AuUInt32 length, AuUInt32 alignment);
}

View File

@ -6,9 +6,7 @@
Author: Reece
***/
#include <Source/RuntimeInternal.hpp>
#include "Memory.hpp"
#include "SwapLock.hpp"
#include <Source/HWInfo/AuHWInfo.hpp>
#include "AuMemory.hpp"
namespace Aurora::Memory::Transition
{