--- /dev/null Thu Jan 01 00:00:00 1970 +0000
+++ b/kernel/eka/common/heap_hybrid.cpp Wed Jun 23 11:59:44 2010 +0100
@@ -0,0 +1,3319 @@
+// Copyright (c) 1994-2009 Nokia Corporation and/or its subsidiary(-ies).
+// All rights reserved.
+// This component and the accompanying materials are made available
+// under the terms of the License "Eclipse Public License v1.0"
+// which accompanies this distribution, and is available
+// at the URL "http://www.eclipse.org/legal/epl-v10.html".
+//
+// Initial Contributors:
+// Nokia Corporation - initial contribution.
+//
+// Contributors:
+//
+// Description:
+// kernel\eka\common\heap_hybrid.cpp
+//
+// Uses malloc (aka dlmalloc) written by Doug Lea version 2.8.4
+//
+
+#include "common.h"
+#ifdef __KERNEL_MODE__
+#include <kernel/kern_priv.h>
+#endif
+#include "dla.h"
+#ifndef __KERNEL_MODE__
+#include "slab.h"
+#include "page_alloc.h"
+#endif
+#include "heap_hybrid.h"
+
+// enables btrace code compiling into
+#define ENABLE_BTRACE
+
+// if non zero this causes the iSlabs to be configured only when the chunk size exceeds this level
+#define DELAYED_SLAB_THRESHOLD (64*1024) // 64KB seems about right based on trace data
+#define SLAB_CONFIG 0xabe // Use slabs of size 48, 40, 32, 24, 20, 16, 12, and 8 bytes
+
+#ifdef _DEBUG
+#define __SIMULATE_ALLOC_FAIL(s) if (CheckForSimulatedAllocFail()) {s}
+#define __ALLOC_DEBUG_HEADER(s) (s += EDebugHdrSize)
+#define __SET_DEBUG_DATA(p,n,c) (((SDebugCell*)(p))->nestingLevel = (n), ((SDebugCell*)(p))->allocCount = (c))
+#define __GET_USER_DATA_BFR(p) ((p!=0) ? (TUint8*)(p) + EDebugHdrSize : NULL)
+#define __GET_DEBUG_DATA_BFR(p) ((p!=0) ? (TUint8*)(p) - EDebugHdrSize : NULL)
+#define __ZAP_CELL(p) memset( (TUint8*)p, 0xde, (AllocLen(__GET_USER_DATA_BFR(p))+EDebugHdrSize))
+#define __DEBUG_SAVE(p) TInt dbgNestLevel = ((SDebugCell*)p)->nestingLevel
+#define __DEBUG_RESTORE(p) if (p) {((SDebugCell*)p)->nestingLevel = dbgNestLevel;}
+#define __DEBUG_HDR_SIZE EDebugHdrSize
+#define __REMOVE_DBG_HDR(n) (n*EDebugHdrSize)
+#define __GET_AVAIL_BLOCK_SIZE(s) ( (s<EDebugHdrSize) ? 0 : s-EDebugHdrSize )
+#define __UPDATE_ALLOC_COUNT(o,n,c) if (o!=n && n) {((SDebugCell*)n)->allocCount = (c);}
+#define __INIT_COUNTERS(i) iCellCount=i,iTotalAllocSize=i
+#define __INCREMENT_COUNTERS(p) iCellCount++, iTotalAllocSize += AllocLen(p)
+#define __DECREMENT_COUNTERS(p) iCellCount--, iTotalAllocSize -= AllocLen(p)
+#define __UPDATE_TOTAL_ALLOC(p,s) iTotalAllocSize += (AllocLen(__GET_USER_DATA_BFR(p)) - s)
+
+#else
+#define __SIMULATE_ALLOC_FAIL(s)
+#define __ALLOC_DEBUG_HEADER(s)
+#define __SET_DEBUG_DATA(p,n,c)
+#define __GET_USER_DATA_BFR(p) (p)
+#define __GET_DEBUG_DATA_BFR(p) (p)
+#define __ZAP_CELL(p)
+#define __DEBUG_SAVE(p)
+#define __DEBUG_RESTORE(p)
+#define __DEBUG_HDR_SIZE 0
+#define __REMOVE_DBG_HDR(n) 0
+#define __GET_AVAIL_BLOCK_SIZE(s) (s)
+#define __UPDATE_ALLOC_COUNT(o,n,c)
+#define __INIT_COUNTERS(i) iCellCount=i,iTotalAllocSize=i
+#define __INCREMENT_COUNTERS(p)
+#define __DECREMENT_COUNTERS(p)
+#define __UPDATE_TOTAL_ALLOC(p,s)
+
+#endif
+
+
+#define MEMORY_MONITORED (iFlags & EMonitorMemory)
+#define GM (&iGlobalMallocState)
+#define IS_FIXED_HEAP (iFlags & EFixedSize)
+#define __INIT_COUNTERS(i) iCellCount=i,iTotalAllocSize=i
+#define __POWER_OF_2(x) (!((x)&((x)-1)))
+
+#define __DL_BFR_CHECK(M,P) \
+ if ( MEMORY_MONITORED ) \
+ if ( !IS_ALIGNED(P) || ((TUint8*)(P)<M->iSeg.iBase) || ((TUint8*)(P)>(M->iSeg.iBase+M->iSeg.iSize))) \
+ BTraceContext12(BTrace::EHeap, BTrace::EHeapCorruption, (TUint32)this, (TUint32)P, (TUint32)0), HEAP_PANIC(ETHeapBadCellAddress); \
+ else DoCheckInuseChunk(M, MEM2CHUNK(P))
+
+#ifndef __KERNEL_MODE__
+
+#define __SLAB_BFR_CHECK(S,P,B) \
+ if ( MEMORY_MONITORED ) \
+ if ( ((TUint32)P & 0x3) || ((TUint8*)P<iMemBase) || ((TUint8*)(P)>(TUint8*)this)) \
+ BTraceContext12(BTrace::EHeap, BTrace::EHeapCorruption, (TUint32)this, (TUint32)P, (TUint32)S), HEAP_PANIC(ETHeapBadCellAddress); \
+ else DoCheckSlab(S, EPartialFullSlab, P), BuildPartialSlabBitmap(B,S,P)
+#define __PAGE_BFR_CHECK(P) \
+ if ( MEMORY_MONITORED ) \
+ if ( ((TUint32)P & ((1 << iPageSize)-1)) || ((TUint8*)P<iMemBase) || ((TUint8*)(P)>(TUint8*)this)) \
+ BTraceContext12(BTrace::EHeap, BTrace::EHeapCorruption, (TUint32)this, (TUint32)P, (TUint32)0), HEAP_PANIC(ETHeapBadCellAddress)
+
+#endif
+
+#ifdef _MSC_VER
+// This is required while we are still using VC6 to compile, so as to avoid warnings that cannot be fixed
+// without having to edit the original Doug Lea source. The 4146 warnings are due to the original code having
+// a liking for negating unsigned numbers and the 4127 warnings are due to the original code using the RTCHECK
+// macro with values that are always defined as 1. It is better to turn these warnings off than to introduce
+// diffs between the original Doug Lea implementation and our adaptation of it
+#pragma warning( disable : 4146 ) /* unary minus operator applied to unsigned type, result still unsigned */
+#pragma warning( disable : 4127 ) /* conditional expression is constant */
+#endif // _MSC_VER
+
+
+/**
+@SYMPatchable
+@publishedPartner
+@released
+
+Defines the minimum cell size of a heap.
+
+The constant can be changed at ROM build time using patchdata OBY keyword.
+
+@deprecated Patching this constant no longer has any effect.
+*/
+#ifdef __X86GCC__ // For X86GCC we dont use the proper data import attribute
+#undef IMPORT_D // since the constants are not really imported. GCC doesn't
+#define IMPORT_D // allow imports from self.
+#endif
+IMPORT_D extern const TInt KHeapMinCellSize;
+
+/**
+@SYMPatchable
+@publishedPartner
+@released
+
+This constant defines the ratio that determines the amount of hysteresis between heap growing and heap
+shrinking.
+It is a 32-bit fixed point number where the radix point is defined to be
+between bits 7 and 8 (where the LSB is bit 0) i.e. using standard notation, a Q8 or a fx24.8
+fixed point number. For example, for a ratio of 2.0, set KHeapShrinkHysRatio=0x200.
+
+The heap shrinking hysteresis value is calculated to be:
+@code
+KHeapShrinkHysRatio*(iGrowBy>>8)
+@endcode
+where iGrowBy is a page aligned value set by the argument, aGrowBy, to the RHeap constructor.
+The default hysteresis value is iGrowBy bytes i.e. KHeapShrinkHysRatio=2.0.
+
+Memory usage may be improved by reducing the heap shrinking hysteresis
+by setting 1.0 < KHeapShrinkHysRatio < 2.0. Heap shrinking hysteresis is disabled/removed
+when KHeapShrinkHysRatio <= 1.0.
+
+The constant can be changed at ROM build time using patchdata OBY keyword.
+*/
+IMPORT_D extern const TInt KHeapShrinkHysRatio;
+
+UEXPORT_C TInt RHeap::AllocLen(const TAny* aCell) const
+{
+ const MAllocator* m = this;
+ return m->AllocLen(aCell);
+}
+
+UEXPORT_C TAny* RHeap::Alloc(TInt aSize)
+{
+ const MAllocator* m = this;
+ return ((MAllocator*)m)->Alloc(aSize);
+}
+
+UEXPORT_C void RHeap::Free(TAny* aCell)
+{
+ const MAllocator* m = this;
+ ((MAllocator*)m)->Free(aCell);
+}
+
+UEXPORT_C TAny* RHeap::ReAlloc(TAny* aCell, TInt aSize, TInt aMode)
+{
+ const MAllocator* m = this;
+ return ((MAllocator*)m)->ReAlloc(aCell, aSize, aMode);
+}
+
+UEXPORT_C TInt RHeap::DebugFunction(TInt aFunc, TAny* a1, TAny* a2)
+{
+ const MAllocator* m = this;
+ return ((MAllocator*)m)->DebugFunction(aFunc, a1, a2);
+}
+
+UEXPORT_C TInt RHeap::Extension_(TUint aExtensionId, TAny*& a0, TAny* a1)
+{
+ const MAllocator* m = this;
+ return ((MAllocator*)m)->Extension_(aExtensionId, a0, a1);
+}
+
+#ifndef __KERNEL_MODE__
+
+EXPORT_C TInt RHeap::AllocSize(TInt& aTotalAllocSize) const
+{
+ const MAllocator* m = this;
+ return m->AllocSize(aTotalAllocSize);
+}
+
+EXPORT_C TInt RHeap::Available(TInt& aBiggestBlock) const
+{
+ const MAllocator* m = this;
+ return m->Available(aBiggestBlock);
+}
+
+EXPORT_C void RHeap::Reset()
+{
+ const MAllocator* m = this;
+ ((MAllocator*)m)->Reset();
+}
+
+EXPORT_C TInt RHeap::Compress()
+{
+ const MAllocator* m = this;
+ return ((MAllocator*)m)->Compress();
+}
+#endif
+
+RHybridHeap::RHybridHeap()
+ {
+ // This initialisation cannot be done in RHeap() for compatibility reasons
+ iMaxLength = iChunkHandle = iNestingLevel = 0;
+ iTop = NULL;
+ iFailType = ENone;
+ iTestData = NULL;
+ }
+
+void RHybridHeap::operator delete(TAny*, TAny*)
+/**
+Called if constructor issued by operator new(TUint aSize, TAny* aBase) throws exception.
+This is dummy as corresponding new operator does not allocate memory.
+*/
+{}
+
+
+#ifndef __KERNEL_MODE__
+void RHybridHeap::Lock() const
+ /**
+ @internalComponent
+*/
+ {((RFastLock&)iLock).Wait();}
+
+
+void RHybridHeap::Unlock() const
+ /**
+ @internalComponent
+*/
+ {((RFastLock&)iLock).Signal();}
+
+
+TInt RHybridHeap::ChunkHandle() const
+ /**
+ @internalComponent
+*/
+{
+ return iChunkHandle;
+}
+
+#else
+//
+// This method is implemented in kheap.cpp
+//
+//void RHybridHeap::Lock() const
+ /**
+ @internalComponent
+*/
+// {;}
+
+
+
+//
+// This method is implemented in kheap.cpp
+//
+//void RHybridHeap::Unlock() const
+ /**
+ @internalComponent
+*/
+// {;}
+
+
+TInt RHybridHeap::ChunkHandle() const
+ /**
+ @internalComponent
+*/
+{
+ return 0;
+}
+#endif
+
+RHybridHeap::RHybridHeap(TInt aChunkHandle, TInt aOffset, TInt aMinLength, TInt aMaxLength, TInt aGrowBy, TInt aAlign, TBool aSingleThread, TBool aDLOnly, TBool aUseAdjust)
+/**
+Constructor for a non fixed heap. Unlike the fixed heap, this heap is quite flexible in terms of its minimum and
+maximum lengths and in that it can use the hybrid allocator if all of its requirements are met.
+*/
+ : iOffset(aOffset), iChunkSize(aMinLength)
+ {
+ __ASSERT_ALWAYS(iOffset>=0, HEAP_PANIC(ETHeapNewBadOffset));
+
+ iChunkHandle = aChunkHandle;
+ iMinLength = aMinLength;
+ iMaxLength = aMaxLength;
+
+ // If the user has explicitly specified 0 as the aGrowBy value, set it to 1 so that it will be rounded up to the nearst page size
+ if (aGrowBy == 0)
+ aGrowBy = 1;
+ GET_PAGE_SIZE(iPageSize);
+ iGrowBy = _ALIGN_UP(aGrowBy, iPageSize);
+
+ Construct(aSingleThread, aDLOnly, aUseAdjust, aAlign);
+ }
+
+RHybridHeap::RHybridHeap(TInt aMaxLength, TInt aAlign, TBool aSingleThread)
+/**
+Constructor for a fixed heap. We have restrictions in that we have fixed minimum and maximum lengths and cannot grow
+and we only use DL allocator.
+*/
+ : iOffset(0), iChunkSize(aMaxLength)
+ {
+ iChunkHandle = NULL;
+ iMinLength = aMaxLength;
+ iMaxLength = aMaxLength;
+ iGrowBy = 0;
+
+ Construct(aSingleThread, ETrue, ETrue, aAlign);
+ }
+
+TAny* RHybridHeap::operator new(TUint aSize, TAny* aBase) __NO_THROW
+{
+ __ASSERT_ALWAYS(aSize>=sizeof(RHybridHeap), HEAP_PANIC(ETHeapNewBadSize));
+ RHybridHeap* h = (RHybridHeap*)aBase;
+ h->iBase = ((TUint8*)aBase) + aSize;
+ return aBase;
+}
+
+void RHybridHeap::Construct(TBool aSingleThread, TBool aDLOnly, TBool aUseAdjust, TInt aAlign)
+{
+ iAlign = aAlign ? aAlign : RHybridHeap::ECellAlignment;
+ __ASSERT_ALWAYS((TUint32)iAlign>=sizeof(TAny*) && __POWER_OF_2(iAlign), HEAP_PANIC(ETHeapNewBadAlignment));
+
+ // This initialisation cannot be done in RHeap() for compatibility reasons
+ iTop = NULL;
+ iFailType = ENone;
+ iNestingLevel = 0;
+ iTestData = NULL;
+
+ iHighWaterMark = iMinLength;
+ iAllocCount = 0;
+ iFlags = aSingleThread ? ESingleThreaded : 0;
+ iGrowBy = _ALIGN_UP(iGrowBy, iPageSize);
+
+ if ( iMinLength == iMaxLength )
+ {
+ iFlags |= EFixedSize;
+ aDLOnly = ETrue;
+ }
+#ifndef __KERNEL_MODE__
+#ifdef DELAYED_SLAB_THRESHOLD
+ iSlabInitThreshold = DELAYED_SLAB_THRESHOLD;
+#else
+ iSlabInitThreshold = 0;
+#endif // DELAYED_SLAB_THRESHOLD
+ iUseAdjust = aUseAdjust;
+ iDLOnly = aDLOnly;
+#else
+ (void)aUseAdjust;
+#endif
+ // Initialise suballocators
+ // if DL only is required then it cannot allocate slab or page memory
+ // so these sub-allocators should be disabled. Otherwise initialise with default values
+ if ( aDLOnly )
+ {
+ Init(0, 0);
+ }
+ else
+ {
+ Init(SLAB_CONFIG, 16);
+ }
+
+#ifdef ENABLE_BTRACE
+
+ TUint32 traceData[4];
+ traceData[0] = iMinLength;
+ traceData[1] = iMaxLength;
+ traceData[2] = iGrowBy;
+ traceData[3] = iAlign;
+ BTraceContextN(BTrace::ETest1, 90, (TUint32)this, 11, traceData, sizeof(traceData));
+#endif
+
+}
+
+#ifndef __KERNEL_MODE__
+TInt RHybridHeap::ConstructLock(TUint32 aMode)
+{
+ TBool duplicateLock = EFalse;
+ TInt r = KErrNone;
+ if (!(iFlags & ESingleThreaded))
+ {
+ duplicateLock = aMode & UserHeap::EChunkHeapSwitchTo;
+ r = iLock.CreateLocal(duplicateLock ? EOwnerThread : EOwnerProcess);
+ if( r != KErrNone)
+ {
+ iChunkHandle = 0;
+ return r;
+ }
+ }
+
+ if ( aMode & UserHeap::EChunkHeapSwitchTo )
+ User::SwitchHeap(this);
+
+ iHandles = &iChunkHandle;
+ if (!(iFlags & ESingleThreaded))
+ {
+ // now change the thread-relative chunk/semaphore handles into process-relative handles
+ iHandleCount = 2;
+ if(duplicateLock)
+ {
+ RHandleBase s = iLock;
+ r = iLock.Duplicate(RThread());
+ s.Close();
+ }
+ if (r==KErrNone && (aMode & UserHeap::EChunkHeapDuplicate))
+ {
+ r = ((RChunk*)&iChunkHandle)->Duplicate(RThread());
+ if (r!=KErrNone)
+ iLock.Close(), iChunkHandle=0;
+ }
+ }
+ else
+ {
+ iHandleCount = 1;
+ if (aMode & UserHeap::EChunkHeapDuplicate)
+ r = ((RChunk*)&iChunkHandle)->Duplicate(RThread(), EOwnerThread);
+ }
+
+ return r;
+}
+#endif
+
+void RHybridHeap::Init(TInt aBitmapSlab, TInt aPagePower)
+{
+ /*Moved code which does initilization */
+ iTop = (TUint8*)this + iMinLength;
+ iBase = Ceiling(iBase, ECellAlignment); // Align iBase address
+
+ __INIT_COUNTERS(0);
+ // memset(&mparams,0,sizeof(mparams));
+
+ InitDlMalloc(iTop - iBase, 0);
+
+#ifndef __KERNEL_MODE__
+ SlabInit();
+ iSlabConfigBits = aBitmapSlab;
+ if ( iChunkSize > iSlabInitThreshold )
+ {
+ iSlabInitThreshold = KMaxTInt32;
+ SlabConfig(aBitmapSlab); // Delayed slab configuration done
+ }
+ if ( aPagePower )
+ {
+ RChunk chunk;
+ chunk.SetHandle(iChunkHandle);
+ iMemBase = chunk.Base(); // Store base address for paged allocator
+ }
+
+ /*10-1K,11-2K,12-4k,13-8K,14-16K,15-32K,16-64K*/
+ PagedInit(aPagePower);
+
+#ifdef ENABLE_BTRACE
+ TUint32 traceData[3];
+ traceData[0] = aBitmapSlab;
+ traceData[1] = aPagePower;
+ traceData[2] = GM->iTrimCheck;
+ BTraceContextN(BTrace::ETest1, 90, (TUint32)this, 0, traceData, sizeof(traceData));
+#endif
+#else
+ (void)aBitmapSlab;
+ (void)aPagePower;
+#endif // __KERNEL_MODE__
+
+}
+
+
+TInt RHybridHeap::AllocLen(const TAny* aCell) const
+{
+ aCell = __GET_DEBUG_DATA_BFR(aCell);
+
+ if (PtrDiff(aCell, this) >= 0)
+ {
+ mchunkptr m = MEM2CHUNK(aCell);
+ return CHUNKSIZE(m) - OVERHEAD_FOR(m) - __DEBUG_HDR_SIZE;
+ }
+#ifndef __KERNEL_MODE__
+ if ( aCell )
+ {
+ if (LowBits(aCell, iPageSize) )
+ return SlabHeaderSize(slab::SlabFor(aCell)->iHeader) - __DEBUG_HDR_SIZE;
+
+ return PagedSize((void*)aCell) - __DEBUG_HDR_SIZE;
+ }
+#endif
+ return 0; // NULL pointer situation, should PANIC !!
+}
+
+#ifdef __KERNEL_MODE__
+TAny* RHybridHeap::Alloc(TInt aSize)
+{
+ __CHECK_THREAD_STATE;
+ __ASSERT_ALWAYS((TUint)aSize<(KMaxTInt/2),HEAP_PANIC(ETHeapBadAllocatedCellSize));
+ __SIMULATE_ALLOC_FAIL(return NULL;)
+ Lock();
+ __ALLOC_DEBUG_HEADER(aSize);
+ TAny* addr = DlMalloc(aSize);
+ if ( addr )
+ {
+// iCellCount++;
+ __SET_DEBUG_DATA(addr, iNestingLevel, ++iAllocCount);
+ addr = __GET_USER_DATA_BFR(addr);
+ __INCREMENT_COUNTERS(addr);
+ memclr(addr, AllocLen(addr));
+ }
+ Unlock();
+#ifdef ENABLE_BTRACE
+ if (iFlags & ETraceAllocs)
+ {
+ if ( addr )
+ {
+ TUint32 traceData[3];
+ traceData[0] = AllocLen(addr);
+ traceData[1] = aSize - __DEBUG_HDR_SIZE;
+ traceData[2] = 0;
+ BTraceContextN(BTrace::EHeap, BTrace::EHeapAlloc, (TUint32)this, (TUint32)addr, traceData, sizeof(traceData));
+ }
+ else
+ BTraceContext8(BTrace::EHeap, BTrace::EHeapAllocFail, (TUint32)this, (TUint32)(aSize - __DEBUG_HDR_SIZE));
+ }
+#endif
+ return addr;
+}
+#else
+
+TAny* RHybridHeap::Alloc(TInt aSize)
+{
+ __ASSERT_ALWAYS((TUint)aSize<(KMaxTInt/2),HEAP_PANIC(ETHeapBadAllocatedCellSize));
+ __SIMULATE_ALLOC_FAIL(return NULL;)
+
+ TAny* addr;
+#ifdef ENABLE_BTRACE
+ TInt aSubAllocator=0;
+#endif
+
+ Lock();
+
+ __ALLOC_DEBUG_HEADER(aSize);
+
+ if (aSize < iSlabThreshold)
+ {
+ TInt ix = iSizeMap[(aSize+3)>>2];
+ HEAP_ASSERT(ix != 0xff);
+ addr = SlabAllocate(iSlabAlloc[ix]);
+ if ( !addr )
+ { // Slab allocation has failed, try to allocate from DL
+ addr = DlMalloc(aSize);
+ }
+#ifdef ENABLE_BTRACE
+ else
+ aSubAllocator=1;
+#endif
+ }else if((aSize >> iPageThreshold)==0)
+ {
+ addr = DlMalloc(aSize);
+ }
+ else
+ {
+ addr = PagedAllocate(aSize);
+ if ( !addr )
+ { // Page allocation has failed, try to allocate from DL
+ addr = DlMalloc(aSize);
+ }
+#ifdef ENABLE_BTRACE
+ else
+ aSubAllocator=2;
+#endif
+ }
+
+ if ( addr )
+ {
+// iCellCount++;
+ __SET_DEBUG_DATA(addr, iNestingLevel, ++iAllocCount);
+ addr = __GET_USER_DATA_BFR(addr);
+ __INCREMENT_COUNTERS(addr);
+ }
+ Unlock();
+
+#ifdef ENABLE_BTRACE
+ if (iFlags & ETraceAllocs)
+ {
+ if ( addr )
+ {
+ TUint32 traceData[3];
+ traceData[0] = AllocLen(addr);
+ traceData[1] = aSize - __DEBUG_HDR_SIZE;
+ traceData[2] = aSubAllocator;
+ BTraceContextN(BTrace::EHeap, BTrace::EHeapAlloc, (TUint32)this, (TUint32)addr, traceData, sizeof(traceData));
+ }
+ else
+ BTraceContext8(BTrace::EHeap, BTrace::EHeapAllocFail, (TUint32)this, (TUint32)(aSize - __DEBUG_HDR_SIZE));
+ }
+#endif
+
+ return addr;
+}
+#endif // __KERNEL_MODE__
+
+#ifndef __KERNEL_MODE__
+TInt RHybridHeap::Compress()
+{
+ if ( IS_FIXED_HEAP )
+ return 0;
+
+ Lock();
+ TInt Reduced = SysTrim(GM, 0);
+ if (iSparePage)
+ {
+ Unmap(iSparePage, iPageSize);
+ iSparePage = 0;
+ Reduced += iPageSize;
+ }
+ Unlock();
+ return Reduced;
+}
+#endif
+
+void RHybridHeap::Free(TAny* aPtr)
+{
+ __CHECK_THREAD_STATE;
+ if ( !aPtr )
+ return;
+#ifdef ENABLE_BTRACE
+ TInt aSubAllocator=0;
+#endif
+ Lock();
+
+ aPtr = __GET_DEBUG_DATA_BFR(aPtr);
+
+#ifndef __KERNEL_MODE__
+ if (PtrDiff(aPtr, this) >= 0)
+ {
+#endif
+ __DL_BFR_CHECK(GM, aPtr);
+ __DECREMENT_COUNTERS(__GET_USER_DATA_BFR(aPtr));
+ __ZAP_CELL(aPtr);
+ DlFree( aPtr);
+#ifndef __KERNEL_MODE__
+ }
+
+ else if ( LowBits(aPtr, iPageSize) == 0 )
+ {
+#ifdef ENABLE_BTRACE
+ aSubAllocator = 2;
+#endif
+ __PAGE_BFR_CHECK(aPtr);
+ __DECREMENT_COUNTERS(__GET_USER_DATA_BFR(aPtr));
+ PagedFree(aPtr);
+ }
+ else
+ {
+#ifdef ENABLE_BTRACE
+ aSubAllocator = 1;
+#endif
+ TUint32 bm[4];
+ __SLAB_BFR_CHECK(slab::SlabFor(aPtr),aPtr,bm);
+ __DECREMENT_COUNTERS(__GET_USER_DATA_BFR(aPtr));
+ __ZAP_CELL(aPtr);
+ SlabFree(aPtr);
+ }
+#endif // __KERNEL_MODE__
+// iCellCount--;
+ Unlock();
+#ifdef ENABLE_BTRACE
+ if (iFlags & ETraceAllocs)
+ {
+ TUint32 traceData;
+ traceData = aSubAllocator;
+ BTraceContextN(BTrace::EHeap, BTrace::EHeapFree, (TUint32)this, (TUint32)__GET_USER_DATA_BFR(aPtr), &traceData, sizeof(traceData));
+ }
+#endif
+}
+
+#ifndef __KERNEL_MODE__
+void RHybridHeap::Reset()
+/**
+Frees all allocated cells on this heap.
+*/
+{
+ Lock();
+ if ( !IS_FIXED_HEAP )
+ {
+ if ( GM->iSeg.iSize > (iMinLength - sizeof(*this)) )
+ Unmap(GM->iSeg.iBase + (iMinLength - sizeof(*this)), (GM->iSeg.iSize - (iMinLength - sizeof(*this))));
+ ResetBitmap();
+ if ( !iDLOnly )
+ Init(iSlabConfigBits, iPageThreshold);
+ else
+ Init(0,0);
+ }
+ else Init(0,0);
+ Unlock();
+}
+#endif
+
+TAny* RHybridHeap::ReAllocImpl(TAny* aPtr, TInt aSize, TInt aMode)
+{
+ // First handle special case of calling reallocate with NULL aPtr
+ if (!aPtr)
+ {
+ if (( aMode & ENeverMove ) == 0 )
+ {
+ aPtr = Alloc(aSize - __DEBUG_HDR_SIZE);
+ aPtr = __GET_DEBUG_DATA_BFR(aPtr);
+ }
+ return aPtr;
+ }
+
+ TInt oldsize = AllocLen(__GET_USER_DATA_BFR(aPtr)) + __DEBUG_HDR_SIZE;
+
+ // Insist on geometric growth when reallocating memory, this reduces copying and fragmentation
+ // generated during arithmetic growth of buffer/array/vector memory
+ // Experiments have shown that 25% is a good threshold for this policy
+ if (aSize <= oldsize)
+ {
+ if (aSize >= oldsize - (oldsize>>2))
+ return aPtr; // don't change if >75% original size
+ }
+ else
+ {
+ __SIMULATE_ALLOC_FAIL(return NULL;)
+ if (aSize < oldsize + (oldsize>>2))
+ {
+ aSize = _ALIGN_UP(oldsize + (oldsize>>2), 4); // grow to at least 125% original size
+ }
+ }
+ __DEBUG_SAVE(aPtr);
+
+ TAny* newp;
+#ifdef __KERNEL_MODE__
+ Lock();
+ __DL_BFR_CHECK(GM, aPtr);
+ newp = DlRealloc(aPtr, aSize, aMode);
+ Unlock();
+ if ( newp )
+ {
+ if ( aSize > oldsize )
+ memclr(((TUint8*)newp) + oldsize, (aSize-oldsize)); // Buffer has grown in place, clear extra
+ __DEBUG_RESTORE(newp);
+ __UPDATE_ALLOC_COUNT(aPtr, newp, ++iAllocCount);
+ __UPDATE_TOTAL_ALLOC(newp, oldsize);
+ }
+#else
+ // Decide how to reallocate based on (a) the current cell location, (b) the mode requested and (c) the new size
+ if ( PtrDiff(aPtr, this) >= 0 )
+ { // current cell in Doug Lea iArena
+ if ( (aMode & ENeverMove)
+ ||
+ (!(aMode & EAllowMoveOnShrink) && (aSize < oldsize))
+ ||
+ ((aSize >= iSlabThreshold) && ((aSize >> iPageThreshold) == 0)) )
+ {
+ Lock();
+ __DL_BFR_CHECK(GM, aPtr);
+ newp = DlRealloc(aPtr, aSize, aMode); // old and new in DL allocator
+ Unlock();
+ __DEBUG_RESTORE(newp);
+ __UPDATE_ALLOC_COUNT(aPtr,newp, ++iAllocCount);
+ __UPDATE_TOTAL_ALLOC(newp, oldsize);
+ return newp;
+ }
+ }
+ else if (LowBits(aPtr, iPageSize) == 0)
+ { // current cell in paged iArena
+ if ( (aMode & ENeverMove)
+ ||
+ (!(aMode & EAllowMoveOnShrink) && (aSize < oldsize))
+ ||
+ ((aSize >> iPageThreshold) != 0) )
+ {
+ Lock();
+ __PAGE_BFR_CHECK(aPtr);
+ newp = PagedReallocate(aPtr, aSize, aMode); // old and new in paged allocator
+ Unlock();
+ __DEBUG_RESTORE(newp);
+ __UPDATE_ALLOC_COUNT(aPtr,newp, ++iAllocCount);
+ __UPDATE_TOTAL_ALLOC(newp, oldsize);
+ return newp;
+ }
+ }
+ else
+ { // current cell in slab iArena
+ TUint32 bm[4];
+ Lock();
+ __SLAB_BFR_CHECK(slab::SlabFor(aPtr), aPtr, bm);
+ Unlock();
+ if ( aSize <= oldsize)
+ return aPtr;
+ if (aMode & ENeverMove)
+ return NULL; // cannot grow in slab iArena
+ // just use alloc/copy/free...
+ }
+
+ // fallback to allocate and copy
+ // shouldn't get here if we cannot move the cell
+ // __ASSERT(mode == emobile || (mode==efixshrink && size>oldsize));
+
+ newp = Alloc(aSize - __DEBUG_HDR_SIZE);
+ newp = __GET_DEBUG_DATA_BFR(newp);
+ if (newp)
+ {
+ memcpy(newp, aPtr, oldsize<aSize ? oldsize : aSize);
+ __DEBUG_RESTORE(newp);
+ Free(__GET_USER_DATA_BFR(aPtr));
+ }
+
+#endif // __KERNEL_MODE__
+ return newp;
+}
+
+
+TAny* RHybridHeap::ReAlloc(TAny* aPtr, TInt aSize, TInt aMode )
+{
+
+ aPtr = __GET_DEBUG_DATA_BFR(aPtr);
+ __ALLOC_DEBUG_HEADER(aSize);
+
+ TAny* retval = ReAllocImpl(aPtr, aSize, aMode);
+
+ retval = __GET_USER_DATA_BFR(retval);
+
+#ifdef ENABLE_BTRACE
+ if (iFlags & ETraceAllocs)
+ {
+ if ( retval )
+ {
+ TUint32 traceData[3];
+ traceData[0] = AllocLen(retval);
+ traceData[1] = aSize - __DEBUG_HDR_SIZE;
+ traceData[2] = (TUint32)aPtr;
+ BTraceContextN(BTrace::EHeap, BTrace::EHeapReAlloc,(TUint32)this, (TUint32)retval, traceData, sizeof(traceData));
+ }
+ else
+ BTraceContext12(BTrace::EHeap, BTrace::EHeapReAllocFail, (TUint32)this, (TUint32)aPtr, (TUint32)(aSize - __DEBUG_HDR_SIZE));
+ }
+#endif
+ return retval;
+}
+
+#ifndef __KERNEL_MODE__
+TInt RHybridHeap::Available(TInt& aBiggestBlock) const
+/**
+Gets the total free space currently available on the heap and the space
+available in the largest free block.
+
+Note that this function exists mainly for compatibility reasons. In a modern
+heap implementation such as that present in Symbian it is not appropriate to
+concern oneself with details such as the amount of free memory available on a
+heap and its largeset free block, because the way that a modern heap implmentation
+works is not simple. The amount of available virtual memory != physical memory
+and there are multiple allocation strategies used internally, which makes all
+memory usage figures "fuzzy" at best.
+
+In short, if you want to see if there is enough memory available to allocate a
+block of memory, call Alloc() and if it succeeds then there is enough memory!
+Messing around with functions like this is somewhat pointless with modern heap
+allocators.
+
+@param aBiggestBlock On return, contains the space available in the largest
+ free block on the heap. Due to the internals of modern
+ heap implementations, you can probably still allocate a
+ block larger than this!
+
+@return The total free space currently available on the heap. Again, you can
+ probably still allocate more than this!
+*/
+{
+ struct HeapInfo info;
+ Lock();
+ TInt Biggest = GetInfo(&info);
+ aBiggestBlock = __GET_AVAIL_BLOCK_SIZE(Biggest);
+ Unlock();
+ return __GET_AVAIL_BLOCK_SIZE(info.iFreeBytes);
+
+}
+
+TInt RHybridHeap::AllocSize(TInt& aTotalAllocSize) const
+ /**
+ Gets the number of cells allocated on this heap, and the total space
+ allocated to them.
+
+ @param aTotalAllocSize On return, contains the total space allocated
+ to the cells.
+
+ @return The number of cells allocated on this heap.
+*/
+{
+ struct HeapInfo info;
+ Lock();
+ GetInfo(&info);
+ aTotalAllocSize = info.iAllocBytes - __REMOVE_DBG_HDR(info.iAllocN);
+ Unlock();
+ return info.iAllocN;
+}
+
+#endif
+
+TInt RHybridHeap::Extension_(TUint /* aExtensionId */, TAny*& /* a0 */, TAny* /* a1 */)
+{
+ return KErrNotSupported;
+}
+
+
+
+///////////////////////////////////////////////////////////////////////////////
+// imported from dla.cpp
+///////////////////////////////////////////////////////////////////////////////
+
+//#include <unistd.h>
+//#define DEBUG_REALLOC
+#ifdef DEBUG_REALLOC
+#include <e32debug.h>
+#endif
+
+inline void RHybridHeap::InitBins(mstate m)
+{
+ /* Establish circular links for iSmallBins */
+ bindex_t i;
+ for (i = 0; i < NSMALLBINS; ++i) {
+ sbinptr bin = SMALLBIN_AT(m,i);
+ bin->iFd = bin->iBk = bin;
+ }
+ }
+/* ---------------------------- malloc support --------------------------- */
+
+/* allocate a large request from the best fitting chunk in a treebin */
+void* RHybridHeap::TmallocLarge(mstate m, size_t nb) {
+ tchunkptr v = 0;
+ size_t rsize = -nb; /* Unsigned negation */
+ tchunkptr t;
+ bindex_t idx;
+ ComputeTreeIndex(nb, idx);
+
+ if ((t = *TREEBIN_AT(m, idx)) != 0)
+ {
+ /* Traverse tree for this bin looking for node with size == nb */
+ size_t sizebits = nb << LEFTSHIFT_FOR_TREE_INDEX(idx);
+ tchunkptr rst = 0; /* The deepest untaken right subtree */
+ for (;;)
+ {
+ tchunkptr rt;
+ size_t trem = CHUNKSIZE(t) - nb;
+ if (trem < rsize)
+ {
+ v = t;
+ if ((rsize = trem) == 0)
+ break;
+ }
+ rt = t->iChild[1];
+ t = t->iChild[(sizebits >> (SIZE_T_BITSIZE-SIZE_T_ONE)) & 1];
+ if (rt != 0 && rt != t)
+ rst = rt;
+ if (t == 0)
+ {
+ t = rst; /* set t to least subtree holding sizes > nb */
+ break;
+ }
+ sizebits <<= 1;
+ }
+ }
+ if (t == 0 && v == 0)
+ { /* set t to root of next non-empty treebin */
+ binmap_t leftbits = LEFT_BITS(IDX2BIT(idx)) & m->iTreeMap;
+ if (leftbits != 0)
+ {
+ bindex_t i;
+ binmap_t leastbit = LEAST_BIT(leftbits);
+ ComputeBit2idx(leastbit, i);
+ t = *TREEBIN_AT(m, i);
+ }
+ }
+ while (t != 0)
+ { /* Find smallest of tree or subtree */
+ size_t trem = CHUNKSIZE(t) - nb;
+ if (trem < rsize) {
+ rsize = trem;
+ v = t;
+ }
+ t = LEFTMOST_CHILD(t);
+ }
+ /* If iDv is a better fit, return 0 so malloc will use it */
+ if (v != 0 && rsize < (size_t)(m->iDvSize - nb))
+ {
+ if (RTCHECK(OK_ADDRESS(m, v)))
+ { /* split */
+ mchunkptr r = CHUNK_PLUS_OFFSET(v, nb);
+ HEAP_ASSERT(CHUNKSIZE(v) == rsize + nb);
+ if (RTCHECK(OK_NEXT(v, r)))
+ {
+ UnlinkLargeChunk(m, v);
+ if (rsize < MIN_CHUNK_SIZE)
+ SET_INUSE_AND_PINUSE(m, v, (rsize + nb));
+ else
+ {
+ SET_SIZE_AND_PINUSE_OF_INUSE_CHUNK(m, v, nb);
+ SET_SIZE_AND_PINUSE_OF_FREE_CHUNK(r, rsize);
+ InsertChunk(m, r, rsize);
+ }
+ return CHUNK2MEM(v);
+ }
+ }
+ // CORRUPTION_ERROR_ACTION(m);
+ }
+ return 0;
+ }
+
+/* allocate a small request from the best fitting chunk in a treebin */
+void* RHybridHeap::TmallocSmall(mstate m, size_t nb)
+{
+ tchunkptr t, v;
+ size_t rsize;
+ bindex_t i;
+ binmap_t leastbit = LEAST_BIT(m->iTreeMap);
+ ComputeBit2idx(leastbit, i);
+
+ v = t = *TREEBIN_AT(m, i);
+ rsize = CHUNKSIZE(t) - nb;
+
+ while ((t = LEFTMOST_CHILD(t)) != 0)
+ {
+ size_t trem = CHUNKSIZE(t) - nb;
+ if (trem < rsize)
+ {
+ rsize = trem;
+ v = t;
+ }
+ }
+
+ if (RTCHECK(OK_ADDRESS(m, v)))
+ {
+ mchunkptr r = CHUNK_PLUS_OFFSET(v, nb);
+ HEAP_ASSERT(CHUNKSIZE(v) == rsize + nb);
+ if (RTCHECK(OK_NEXT(v, r)))
+ {
+ UnlinkLargeChunk(m, v);
+ if (rsize < MIN_CHUNK_SIZE)
+ SET_INUSE_AND_PINUSE(m, v, (rsize + nb));
+ else
+ {
+ SET_SIZE_AND_PINUSE_OF_INUSE_CHUNK(m, v, nb);
+ SET_SIZE_AND_PINUSE_OF_FREE_CHUNK(r, rsize);
+ ReplaceDv(m, r, rsize);
+ }
+ return CHUNK2MEM(v);
+ }
+ }
+ // CORRUPTION_ERROR_ACTION(m);
+ // return 0;
+ }
+
+inline void RHybridHeap::InitTop(mstate m, mchunkptr p, size_t psize)
+{
+ /* Ensure alignment */
+ size_t offset = ALIGN_OFFSET(CHUNK2MEM(p));
+ p = (mchunkptr)((TUint8*)p + offset);
+ psize -= offset;
+ m->iTop = p;
+ m->iTopSize = psize;
+ p->iHead = psize | PINUSE_BIT;
+ /* set size of fake trailing chunk holding overhead space only once */
+ mchunkptr chunkPlusOff = CHUNK_PLUS_OFFSET(p, psize);
+ chunkPlusOff->iHead = TOP_FOOT_SIZE;
+ m->iTrimCheck = KHeapShrinkHysRatio*(iGrowBy>>8);
+}
+
+
+/* Unlink the first chunk from a smallbin */
+inline void RHybridHeap::UnlinkFirstSmallChunk(mstate M,mchunkptr B,mchunkptr P,bindex_t& I)
+{
+ mchunkptr F = P->iFd;
+ HEAP_ASSERT(P != B);
+ HEAP_ASSERT(P != F);
+ HEAP_ASSERT(CHUNKSIZE(P) == SMALL_INDEX2SIZE(I));
+ if (B == F)
+ CLEAR_SMALLMAP(M, I);
+ else if (RTCHECK(OK_ADDRESS(M, F)))
+ {
+ B->iFd = F;
+ F->iBk = B;
+ }
+ else
+ {
+ CORRUPTION_ERROR_ACTION(M);
+ }
+}
+/* Link a free chunk into a smallbin */
+inline void RHybridHeap::InsertSmallChunk(mstate M,mchunkptr P, size_t S)
+{
+ bindex_t I = SMALL_INDEX(S);
+ mchunkptr B = SMALLBIN_AT(M, I);
+ mchunkptr F = B;
+ HEAP_ASSERT(S >= MIN_CHUNK_SIZE);
+ if (!SMALLMAP_IS_MARKED(M, I))
+ MARK_SMALLMAP(M, I);
+ else if (RTCHECK(OK_ADDRESS(M, B->iFd)))
+ F = B->iFd;
+ else
+ {
+ CORRUPTION_ERROR_ACTION(M);
+ }
+ B->iFd = P;
+ F->iBk = P;
+ P->iFd = F;
+ P->iBk = B;
+}
+
+
+inline void RHybridHeap::InsertChunk(mstate M,mchunkptr P,size_t S)
+{
+ if (IS_SMALL(S))
+ InsertSmallChunk(M, P, S);
+ else
+ {
+ tchunkptr TP = (tchunkptr)(P); InsertLargeChunk(M, TP, S);
+ }
+}
+
+inline void RHybridHeap::UnlinkLargeChunk(mstate M,tchunkptr X)
+{
+ tchunkptr XP = X->iParent;
+ tchunkptr R;
+ if (X->iBk != X)
+ {
+ tchunkptr F = X->iFd;
+ R = X->iBk;
+ if (RTCHECK(OK_ADDRESS(M, F)))
+ {
+ F->iBk = R;
+ R->iFd = F;
+ }
+ else
+ {
+ CORRUPTION_ERROR_ACTION(M);
+ }
+ }
+ else
+ {
+ tchunkptr* RP;
+ if (((R = *(RP = &(X->iChild[1]))) != 0) ||
+ ((R = *(RP = &(X->iChild[0]))) != 0))
+ {
+ tchunkptr* CP;
+ while ((*(CP = &(R->iChild[1])) != 0) ||
+ (*(CP = &(R->iChild[0])) != 0))
+ {
+ R = *(RP = CP);
+ }
+ if (RTCHECK(OK_ADDRESS(M, RP)))
+ *RP = 0;
+ else
+ {
+ CORRUPTION_ERROR_ACTION(M);
+ }
+ }
+ }
+ if (XP != 0)
+ {
+ tbinptr* H = TREEBIN_AT(M, X->iIndex);
+ if (X == *H)
+ {
+ if ((*H = R) == 0)
+ CLEAR_TREEMAP(M, X->iIndex);
+ }
+ else if (RTCHECK(OK_ADDRESS(M, XP)))
+ {
+ if (XP->iChild[0] == X)
+ XP->iChild[0] = R;
+ else
+ XP->iChild[1] = R;
+ }
+ else
+ CORRUPTION_ERROR_ACTION(M);
+ if (R != 0)
+ {
+ if (RTCHECK(OK_ADDRESS(M, R)))
+ {
+ tchunkptr C0, C1;
+ R->iParent = XP;
+ if ((C0 = X->iChild[0]) != 0)
+ {
+ if (RTCHECK(OK_ADDRESS(M, C0)))
+ {
+ R->iChild[0] = C0;
+ C0->iParent = R;
+ }
+ else
+ CORRUPTION_ERROR_ACTION(M);
+ }
+ if ((C1 = X->iChild[1]) != 0)
+ {
+ if (RTCHECK(OK_ADDRESS(M, C1)))
+ {
+ R->iChild[1] = C1;
+ C1->iParent = R;
+ }
+ else
+ CORRUPTION_ERROR_ACTION(M);
+ }
+ }
+ else
+ CORRUPTION_ERROR_ACTION(M);
+ }
+ }
+}
+
+/* Unlink a chunk from a smallbin */
+inline void RHybridHeap::UnlinkSmallChunk(mstate M, mchunkptr P,size_t S)
+{
+ mchunkptr F = P->iFd;
+ mchunkptr B = P->iBk;
+ bindex_t I = SMALL_INDEX(S);
+ HEAP_ASSERT(P != B);
+ HEAP_ASSERT(P != F);
+ HEAP_ASSERT(CHUNKSIZE(P) == SMALL_INDEX2SIZE(I));
+ if (F == B)
+ CLEAR_SMALLMAP(M, I);
+ else if (RTCHECK((F == SMALLBIN_AT(M,I) || OK_ADDRESS(M, F)) &&
+ (B == SMALLBIN_AT(M,I) || OK_ADDRESS(M, B))))
+ {
+ F->iBk = B;
+ B->iFd = F;
+ }
+ else
+ {
+ CORRUPTION_ERROR_ACTION(M);
+ }
+}
+
+inline void RHybridHeap::UnlinkChunk(mstate M, mchunkptr P, size_t S)
+{
+ if (IS_SMALL(S))
+ UnlinkSmallChunk(M, P, S);
+ else
+ {
+ tchunkptr TP = (tchunkptr)(P); UnlinkLargeChunk(M, TP);
+ }
+}
+
+// For DL debug functions
+void RHybridHeap::DoComputeTreeIndex(size_t S, bindex_t& I)
+{
+ ComputeTreeIndex(S, I);
+}
+
+inline void RHybridHeap::ComputeTreeIndex(size_t S, bindex_t& I)
+{
+ size_t X = S >> TREEBIN_SHIFT;
+ if (X == 0)
+ I = 0;
+ else if (X > 0xFFFF)
+ I = NTREEBINS-1;
+ else
+ {
+ unsigned int Y = (unsigned int)X;
+ unsigned int N = ((Y - 0x100) >> 16) & 8;
+ unsigned int K = (((Y <<= N) - 0x1000) >> 16) & 4;
+ N += K;
+ N += K = (((Y <<= K) - 0x4000) >> 16) & 2;
+ K = 14 - N + ((Y <<= K) >> 15);
+ I = (K << 1) + ((S >> (K + (TREEBIN_SHIFT-1)) & 1));
+ }
+}
+
+/* ------------------------- Operations on trees ------------------------- */
+
+/* Insert chunk into tree */
+inline void RHybridHeap::InsertLargeChunk(mstate M,tchunkptr X,size_t S)
+{
+ tbinptr* H;
+ bindex_t I;
+ ComputeTreeIndex(S, I);
+ H = TREEBIN_AT(M, I);
+ X->iIndex = I;
+ X->iChild[0] = X->iChild[1] = 0;
+ if (!TREEMAP_IS_MARKED(M, I))
+ {
+ MARK_TREEMAP(M, I);
+ *H = X;
+ X->iParent = (tchunkptr)H;
+ X->iFd = X->iBk = X;
+ }
+ else
+ {
+ tchunkptr T = *H;
+ size_t K = S << LEFTSHIFT_FOR_TREE_INDEX(I);
+ for (;;)
+ {
+ if (CHUNKSIZE(T) != S) {
+ tchunkptr* C = &(T->iChild[(K >> (SIZE_T_BITSIZE-SIZE_T_ONE)) & 1]);
+ K <<= 1;
+ if (*C != 0)
+ T = *C;
+ else if (RTCHECK(OK_ADDRESS(M, C)))
+ {
+ *C = X;
+ X->iParent = T;
+ X->iFd = X->iBk = X;
+ break;
+ }
+ else
+ {
+ CORRUPTION_ERROR_ACTION(M);
+ break;
+ }
+ }
+ else
+ {
+ tchunkptr F = T->iFd;
+ if (RTCHECK(OK_ADDRESS(M, T) && OK_ADDRESS(M, F)))
+ {
+ T->iFd = F->iBk = X;
+ X->iFd = F;
+ X->iBk = T;
+ X->iParent = 0;
+ break;
+ }
+ else
+ {
+ CORRUPTION_ERROR_ACTION(M);
+ break;
+ }
+ }
+ }
+ }
+}
+
+/*
+Unlink steps:
+
+1. If x is a chained node, unlink it from its same-sized iFd/iBk links
+and choose its iBk node as its replacement.
+2. If x was the last node of its size, but not a leaf node, it must
+be replaced with a leaf node (not merely one with an open left or
+right), to make sure that lefts and rights of descendents
+correspond properly to bit masks. We use the rightmost descendent
+of x. We could use any other leaf, but this is easy to locate and
+tends to counteract removal of leftmosts elsewhere, and so keeps
+paths shorter than minimally guaranteed. This doesn't loop much
+because on average a node in a tree is near the bottom.
+3. If x is the base of a chain (i.e., has iParent links) relink
+x's iParent and children to x's replacement (or null if none).
+*/
+
+/* Replace iDv node, binning the old one */
+/* Used only when iDvSize known to be small */
+inline void RHybridHeap::ReplaceDv(mstate M, mchunkptr P, size_t S)
+{
+ size_t DVS = M->iDvSize;
+ if (DVS != 0)
+ {
+ mchunkptr DV = M->iDv;
+ HEAP_ASSERT(IS_SMALL(DVS));
+ InsertSmallChunk(M, DV, DVS);
+ }
+ M->iDvSize = S;
+ M->iDv = P;
+}
+
+
+inline void RHybridHeap::ComputeBit2idx(binmap_t X,bindex_t& I)
+{
+ unsigned int Y = X - 1;
+ unsigned int K = Y >> (16-4) & 16;
+ unsigned int N = K; Y >>= K;
+ N += K = Y >> (8-3) & 8; Y >>= K;
+ N += K = Y >> (4-2) & 4; Y >>= K;
+ N += K = Y >> (2-1) & 2; Y >>= K;
+ N += K = Y >> (1-0) & 1; Y >>= K;
+ I = (bindex_t)(N + Y);
+}
+
+
+
+int RHybridHeap::SysTrim(mstate m, size_t pad)
+{
+ size_t extra = 0;
+
+ if ( IS_INITIALIZED(m) )
+ {
+ pad += TOP_FOOT_SIZE; /* ensure enough room for segment overhead */
+
+ if (m->iTopSize > pad)
+ {
+ extra = Floor(m->iTopSize - pad, iPageSize);
+ if ( (m->iSeg.iSize - extra) < (iMinLength - sizeof(*this)) )
+ {
+ if ( m->iSeg.iSize > (iMinLength - sizeof(*this)) )
+ extra = Floor(m->iSeg.iSize - (iMinLength - sizeof(*this)), iPageSize); /* do not shrink heap below min length */
+ else extra = 0;
+ }
+
+ if ( extra )
+ {
+ Unmap(m->iSeg.iBase + m->iSeg.iSize - extra, extra);
+
+ m->iSeg.iSize -= extra;
+ InitTop(m, m->iTop, m->iTopSize - extra);
+ CHECK_TOP_CHUNK(m, m->iTop);
+ }
+ }
+
+ }
+
+ return extra;
+}
+
+/* Get memory from system using MORECORE */
+
+void* RHybridHeap::SysAlloc(mstate m, size_t nb)
+{
+ HEAP_ASSERT(m->iTop);
+ /* Subtract out existing available iTop space from MORECORE request. */
+// size_t asize = _ALIGN_UP(nb - m->iTopSize + TOP_FOOT_SIZE + SIZE_T_ONE, iGrowBy);
+ TInt asize = _ALIGN_UP(nb - m->iTopSize + SYS_ALLOC_PADDING, iGrowBy); // From DLA version 2.8.4
+
+ char* br = (char*)Map(m->iSeg.iBase+m->iSeg.iSize, asize);
+ if (!br)
+ return 0;
+ HEAP_ASSERT(br == (char*)m->iSeg.iBase+m->iSeg.iSize);
+
+ /* Merge with an existing segment */
+ m->iSeg.iSize += asize;
+ InitTop(m, m->iTop, m->iTopSize + asize);
+
+ if (nb < m->iTopSize)
+ { /* Allocate from new or extended iTop space */
+ size_t rsize = m->iTopSize -= nb;
+ mchunkptr p = m->iTop;
+ mchunkptr r = m->iTop = CHUNK_PLUS_OFFSET(p, nb);
+ r->iHead = rsize | PINUSE_BIT;
+ SET_SIZE_AND_PINUSE_OF_INUSE_CHUNK(m, p, nb);
+ CHECK_TOP_CHUNK(m, m->iTop);
+ CHECK_MALLOCED_CHUNK(m, CHUNK2MEM(p), nb);
+ return CHUNK2MEM(p);
+ }
+
+ return 0;
+}
+
+
+void RHybridHeap::InitDlMalloc(size_t capacity, int /*locked*/)
+{
+ memset(GM,0,sizeof(malloc_state));
+ // The maximum amount that can be allocated can be calculated as:-
+ // 2^sizeof(size_t) - sizeof(malloc_state) - TOP_FOOT_SIZE - page Size(all accordingly padded)
+ // If the capacity exceeds this, no allocation will be done.
+ GM->iSeg.iBase = iBase;
+ GM->iSeg.iSize = capacity;
+ InitBins(GM);
+ InitTop(GM, (mchunkptr)iBase, capacity - TOP_FOOT_SIZE);
+}
+
+void* RHybridHeap::DlMalloc(size_t bytes)
+{
+ /*
+ Basic algorithm:
+ If a small request (< 256 bytes minus per-chunk overhead):
+ 1. If one exists, use a remainderless chunk in associated smallbin.
+ (Remainderless means that there are too few excess bytes to
+ represent as a chunk.)
+ 2. If it is big enough, use the iDv chunk, which is normally the
+ chunk adjacent to the one used for the most recent small request.
+ 3. If one exists, split the smallest available chunk in a bin,
+ saving remainder in iDv.
+ 4. If it is big enough, use the iTop chunk.
+ 5. If available, get memory from system and use it
+ Otherwise, for a large request:
+ 1. Find the smallest available binned chunk that fits, and use it
+ if it is better fitting than iDv chunk, splitting if necessary.
+ 2. If better fitting than any binned chunk, use the iDv chunk.
+ 3. If it is big enough, use the iTop chunk.
+ 4. If request size >= mmap threshold, try to directly mmap this chunk.
+ 5. If available, get memory from system and use it
+*/
+ void* mem;
+ size_t nb;
+ if (bytes <= MAX_SMALL_REQUEST)
+ {
+ bindex_t idx;
+ binmap_t smallbits;
+ nb = (bytes < MIN_REQUEST)? MIN_CHUNK_SIZE : PAD_REQUEST(bytes);
+ idx = SMALL_INDEX(nb);
+ smallbits = GM->iSmallMap >> idx;
+
+ if ((smallbits & 0x3U) != 0)
+ { /* Remainderless fit to a smallbin. */
+ mchunkptr b, p;
+ idx += ~smallbits & 1; /* Uses next bin if idx empty */
+ b = SMALLBIN_AT(GM, idx);
+ p = b->iFd;
+ HEAP_ASSERT(CHUNKSIZE(p) == SMALL_INDEX2SIZE(idx));
+ UnlinkFirstSmallChunk(GM, b, p, idx);
+ SET_INUSE_AND_PINUSE(GM, p, SMALL_INDEX2SIZE(idx));
+ mem = CHUNK2MEM(p);
+ CHECK_MALLOCED_CHUNK(GM, mem, nb);
+ return mem;
+ }
+
+ else if (nb > GM->iDvSize)
+ {
+ if (smallbits != 0)
+ { /* Use chunk in next nonempty smallbin */
+ mchunkptr b, p, r;
+ size_t rsize;
+ bindex_t i;
+ binmap_t leftbits = (smallbits << idx) & LEFT_BITS(IDX2BIT(idx));
+ binmap_t leastbit = LEAST_BIT(leftbits);
+ ComputeBit2idx(leastbit, i);
+ b = SMALLBIN_AT(GM, i);
+ p = b->iFd;
+ HEAP_ASSERT(CHUNKSIZE(p) == SMALL_INDEX2SIZE(i));
+ UnlinkFirstSmallChunk(GM, b, p, i);
+ rsize = SMALL_INDEX2SIZE(i) - nb;
+ /* Fit here cannot be remainderless if 4byte sizes */
+ if (SIZE_T_SIZE != 4 && rsize < MIN_CHUNK_SIZE)
+ SET_INUSE_AND_PINUSE(GM, p, SMALL_INDEX2SIZE(i));
+ else
+ {
+ SET_SIZE_AND_PINUSE_OF_INUSE_CHUNK(GM, p, nb);
+ r = CHUNK_PLUS_OFFSET(p, nb);
+ SET_SIZE_AND_PINUSE_OF_FREE_CHUNK(r, rsize);
+ ReplaceDv(GM, r, rsize);
+ }
+ mem = CHUNK2MEM(p);
+ CHECK_MALLOCED_CHUNK(GM, mem, nb);
+ return mem;
+ }
+
+ else if (GM->iTreeMap != 0 && (mem = TmallocSmall(GM, nb)) != 0)
+ {
+ CHECK_MALLOCED_CHUNK(GM, mem, nb);
+ return mem;
+ }
+ }
+ }
+ else if (bytes >= MAX_REQUEST)
+ nb = MAX_SIZE_T; /* Too big to allocate. Force failure (in sys alloc) */
+ else
+ {
+ nb = PAD_REQUEST(bytes);
+ if (GM->iTreeMap != 0 && (mem = TmallocLarge(GM, nb)) != 0)
+ {
+ CHECK_MALLOCED_CHUNK(GM, mem, nb);
+ return mem;
+ }
+ }
+
+ if (nb <= GM->iDvSize)
+ {
+ size_t rsize = GM->iDvSize - nb;
+ mchunkptr p = GM->iDv;
+ if (rsize >= MIN_CHUNK_SIZE)
+ { /* split iDv */
+ mchunkptr r = GM->iDv = CHUNK_PLUS_OFFSET(p, nb);
+ GM->iDvSize = rsize;
+ SET_SIZE_AND_PINUSE_OF_FREE_CHUNK(r, rsize);
+ SET_SIZE_AND_PINUSE_OF_INUSE_CHUNK(GM, p, nb);
+ }
+ else
+ { /* exhaust iDv */
+ size_t dvs = GM->iDvSize;
+ GM->iDvSize = 0;
+ GM->iDv = 0;
+ SET_INUSE_AND_PINUSE(GM, p, dvs);
+ }
+ mem = CHUNK2MEM(p);
+ CHECK_MALLOCED_CHUNK(GM, mem, nb);
+ return mem;
+ }
+
+ else if (nb < GM->iTopSize)
+ { /* Split iTop */
+ size_t rsize = GM->iTopSize -= nb;
+ mchunkptr p = GM->iTop;
+ mchunkptr r = GM->iTop = CHUNK_PLUS_OFFSET(p, nb);
+ r->iHead = rsize | PINUSE_BIT;
+ SET_SIZE_AND_PINUSE_OF_INUSE_CHUNK(GM, p, nb);
+ mem = CHUNK2MEM(p);
+ CHECK_TOP_CHUNK(GM, GM->iTop);
+ CHECK_MALLOCED_CHUNK(GM, mem, nb);
+ return mem;
+ }
+
+ return SysAlloc(GM, nb);
+}
+
+
+void RHybridHeap::DlFree(void* mem)
+{
+ /*
+ Consolidate freed chunks with preceeding or succeeding bordering
+ free chunks, if they exist, and then place in a bin. Intermixed
+ with special cases for iTop, iDv, mmapped chunks, and usage errors.
+*/
+ mchunkptr p = MEM2CHUNK(mem);
+ CHECK_INUSE_CHUNK(GM, p);
+ if (RTCHECK(OK_ADDRESS(GM, p) && OK_CINUSE(p)))
+ {
+ size_t psize = CHUNKSIZE(p);
+ mchunkptr next = CHUNK_PLUS_OFFSET(p, psize);
+ if (!PINUSE(p))
+ {
+ size_t prevsize = p->iPrevFoot;
+ mchunkptr prev = CHUNK_MINUS_OFFSET(p, prevsize);
+ psize += prevsize;
+ p = prev;
+ if (RTCHECK(OK_ADDRESS(GM, prev)))
+ { /* consolidate backward */
+ if (p != GM->iDv)
+ {
+ UnlinkChunk(GM, p, prevsize);
+ }
+ else if ((next->iHead & INUSE_BITS) == INUSE_BITS)
+ {
+ GM->iDvSize = psize;
+ SET_FREE_WITH_PINUSE(p, psize, next);
+ return;
+ }
+ }
+ else
+ {
+ USAGE_ERROR_ACTION(GM, p);
+ return;
+ }
+ }
+
+ if (RTCHECK(OK_NEXT(p, next) && OK_PINUSE(next)))
+ {
+ if (!CINUSE(next))
+ { /* consolidate forward */
+ if (next == GM->iTop)
+ {
+ size_t tsize = GM->iTopSize += psize;
+ GM->iTop = p;
+ p->iHead = tsize | PINUSE_BIT;
+ if (p == GM->iDv)
+ {
+ GM->iDv = 0;
+ GM->iDvSize = 0;
+ }
+ if ( !IS_FIXED_HEAP && SHOULD_TRIM(GM, tsize) )
+ SysTrim(GM, 0);
+ return;
+ }
+ else if (next == GM->iDv)
+ {
+ size_t dsize = GM->iDvSize += psize;
+ GM->iDv = p;
+ SET_SIZE_AND_PINUSE_OF_FREE_CHUNK(p, dsize);
+ return;
+ }
+ else
+ {
+ size_t nsize = CHUNKSIZE(next);
+ psize += nsize;
+ UnlinkChunk(GM, next, nsize);
+ SET_SIZE_AND_PINUSE_OF_FREE_CHUNK(p, psize);
+ if (p == GM->iDv)
+ {
+ GM->iDvSize = psize;
+ return;
+ }
+ }
+ }
+ else
+ SET_FREE_WITH_PINUSE(p, psize, next);
+ InsertChunk(GM, p, psize);
+ CHECK_FREE_CHUNK(GM, p);
+ return;
+ }
+ }
+}
+
+
+void* RHybridHeap::DlRealloc(void* oldmem, size_t bytes, TInt mode)
+{
+ mchunkptr oldp = MEM2CHUNK(oldmem);
+ size_t oldsize = CHUNKSIZE(oldp);
+ mchunkptr next = CHUNK_PLUS_OFFSET(oldp, oldsize);
+ mchunkptr newp = 0;
+ void* extra = 0;
+
+ /* Try to either shrink or extend into iTop. Else malloc-copy-free */
+
+ if (RTCHECK(OK_ADDRESS(GM, oldp) && OK_CINUSE(oldp) &&
+ OK_NEXT(oldp, next) && OK_PINUSE(next)))
+ {
+ size_t nb = REQUEST2SIZE(bytes);
+ if (oldsize >= nb) { /* already big enough */
+ size_t rsize = oldsize - nb;
+ newp = oldp;
+ if (rsize >= MIN_CHUNK_SIZE)
+ {
+ mchunkptr remainder = CHUNK_PLUS_OFFSET(newp, nb);
+ SET_INUSE(GM, newp, nb);
+// SET_INUSE(GM, remainder, rsize);
+ SET_INUSE_AND_PINUSE(GM, remainder, rsize); // corrected in original DLA version V2.8.4
+ extra = CHUNK2MEM(remainder);
+ }
+ }
+ else if (next == GM->iTop && oldsize + GM->iTopSize > nb)
+ {
+ /* Expand into iTop */
+ size_t newsize = oldsize + GM->iTopSize;
+ size_t newtopsize = newsize - nb;
+ mchunkptr newtop = CHUNK_PLUS_OFFSET(oldp, nb);
+ SET_INUSE(GM, oldp, nb);
+ newtop->iHead = newtopsize |PINUSE_BIT;
+ GM->iTop = newtop;
+ GM->iTopSize = newtopsize;
+ newp = oldp;
+ }
+ }
+ else
+ {
+ USAGE_ERROR_ACTION(GM, oldmem);
+ }
+
+ if (newp != 0)
+ {
+ if (extra != 0)
+ {
+ DlFree(extra);
+ }
+ CHECK_INUSE_CHUNK(GM, newp);
+ return CHUNK2MEM(newp);
+ }
+ else
+ {
+ if ( mode & ENeverMove )
+ return 0; // cannot move
+ void* newmem = DlMalloc(bytes);
+ if (newmem != 0)
+ {
+ size_t oc = oldsize - OVERHEAD_FOR(oldp);
+ memcpy(newmem, oldmem, (oc < bytes)? oc : bytes);
+ DlFree(oldmem);
+ }
+ return newmem;
+ }
+ // return 0;
+}
+
+size_t RHybridHeap::DlInfo(struct HeapInfo* i, SWalkInfo* wi) const
+{
+ TInt max = ((GM->iTopSize-1) & ~CHUNK_ALIGN_MASK) - CHUNK_OVERHEAD;
+ if ( max < 0 )
+ max = 0;
+ else ++i->iFreeN; // iTop always free
+ i->iFreeBytes += max;
+
+ Walk(wi, GM->iTop, max, EGoodFreeCell, EDougLeaAllocator); // Introduce DL iTop buffer to the walk function
+
+ for (mchunkptr q = ALIGN_AS_CHUNK(GM->iSeg.iBase); q != GM->iTop; q = NEXT_CHUNK(q))
+ {
+ TInt sz = CHUNKSIZE(q);
+ if (!CINUSE(q))
+ {
+ if ( sz > max )
+ max = sz;
+ i->iFreeBytes += sz;
+ ++i->iFreeN;
+ Walk(wi, CHUNK2MEM(q), sz, EGoodFreeCell, EDougLeaAllocator); // Introduce DL free buffer to the walk function
+ }
+ else
+ {
+ i->iAllocBytes += sz - CHUNK_OVERHEAD;
+ ++i->iAllocN;
+ Walk(wi, CHUNK2MEM(q), (sz- CHUNK_OVERHEAD), EGoodAllocatedCell, EDougLeaAllocator); // Introduce DL allocated buffer to the walk function
+ }
+ }
+ return max; // return largest available chunk size
+}
+
+//
+// get statistics about the state of the allocator
+//
+TInt RHybridHeap::GetInfo(struct HeapInfo* i, SWalkInfo* wi) const
+{
+ memset(i,0,sizeof(HeapInfo));
+ i->iFootprint = iChunkSize;
+ i->iMaxSize = iMaxLength;
+#ifndef __KERNEL_MODE__
+ PagedInfo(i, wi);
+ SlabInfo(i, wi);
+#endif
+ return DlInfo(i,wi);
+}
+
+//
+// Methods to commit/decommit memory pages from chunk
+//
+
+
+void* RHybridHeap::Map(void* p, TInt sz)
+//
+// allocate pages in the chunk
+// if p is NULL, Find an allocate the required number of pages (which must lie in the lower half)
+// otherwise commit the pages specified
+//
+{
+ HEAP_ASSERT(sz > 0);
+
+ if ( iChunkSize + sz > iMaxLength)
+ return 0;
+
+#ifdef __KERNEL_MODE__
+
+ TInt r = ((DChunk*)iChunkHandle)->Adjust(iChunkSize + iOffset + sz);
+ if (r < 0)
+ return 0;
+
+ iChunkSize += sz;
+
+#else
+
+ RChunk chunk;
+ chunk.SetHandle(iChunkHandle);
+ if ( p )
+ {
+ TInt r;
+ if ( iUseAdjust )
+ r = chunk.Adjust(iChunkSize + sz);
+ else
+ {
+ HEAP_ASSERT(sz == Ceiling(sz, iPageSize));
+ HEAP_ASSERT(p == Floor(p, iPageSize));
+ r = chunk.Commit(iOffset + PtrDiff(p, this),sz);
+ }
+ if (r < 0)
+ return 0;
+ }
+ else
+ {
+ TInt r = chunk.Allocate(sz);
+ if (r < 0)
+ return 0;
+ if (r > iOffset)
+ {
+ // can't allow page allocations in DL zone
+ chunk.Decommit(r, sz);
+ return 0;
+ }
+ p = Offset(this, r - iOffset);
+ }
+ iChunkSize += sz;
+
+ if (iChunkSize >= iSlabInitThreshold)
+ { // set up slab system now that heap is large enough
+ SlabConfig(iSlabConfigBits);
+ iSlabInitThreshold = KMaxTInt32;
+ }
+
+#endif // __KERNEL_MODE__
+
+#ifdef ENABLE_BTRACE
+ if(iChunkSize > iHighWaterMark)
+ {
+ iHighWaterMark = Ceiling(iChunkSize,16*iPageSize);
+ TUint32 traceData[6];
+ traceData[0] = iChunkHandle;
+ traceData[1] = iMinLength;
+ traceData[2] = iMaxLength;
+ traceData[3] = sz;
+ traceData[4] = iChunkSize;
+ traceData[5] = iHighWaterMark;
+ BTraceContextN(BTrace::ETest1, 90, (TUint32)this, 33, traceData, sizeof(traceData));
+ }
+#endif
+
+ return p;
+}
+
+void RHybridHeap::Unmap(void* p, TInt sz)
+{
+ HEAP_ASSERT(sz > 0);
+
+#ifdef __KERNEL_MODE__
+
+ (void)p;
+ HEAP_ASSERT(sz == Ceiling(sz, iPageSize));
+#if defined(_DEBUG)
+ TInt r =
+#endif
+ ((DChunk*)iChunkHandle)->Adjust(iChunkSize + iOffset - sz);
+ HEAP_ASSERT(r >= 0);
+
+#else
+
+ RChunk chunk;
+ chunk.SetHandle(iChunkHandle);
+ if ( iUseAdjust )
+ {
+ HEAP_ASSERT(sz == Ceiling(sz, iPageSize));
+#if defined(_DEBUG)
+ TInt r =
+#endif
+ chunk.Adjust(iChunkSize - sz);
+ HEAP_ASSERT(r >= 0);
+ }
+ else
+ {
+ HEAP_ASSERT(sz == Ceiling(sz, iPageSize));
+ HEAP_ASSERT(p == Floor(p, iPageSize));
+#if defined(_DEBUG)
+ TInt r =
+#endif
+ chunk.Decommit(PtrDiff(p, Offset(this,-iOffset)), sz);
+ HEAP_ASSERT(r >= 0);
+ }
+#endif // __KERNEL_MODE__
+
+ iChunkSize -= sz;
+}
+
+
+#ifndef __KERNEL_MODE__
+//
+// Slab allocator code
+//
+
+//inline slab* slab::SlabFor(void* p)
+slab* slab::SlabFor( const void* p)
+{
+ return (slab*)(Floor(p, SLABSIZE));
+}
+
+//
+// Remove slab s from its tree/heap (not necessarily the root), preserving the address order
+// invariant of the heap
+//
+void RHybridHeap::TreeRemove(slab* s)
+{
+ slab** r = s->iParent;
+ slab* c1 = s->iChild1;
+ slab* c2 = s->iChild2;
+ for (;;)
+ {
+ if (!c2)
+ {
+ *r = c1;
+ if (c1)
+ c1->iParent = r;
+ return;
+ }
+ if (!c1)
+ {
+ *r = c2;
+ c2->iParent = r;
+ return;
+ }
+ if (c1 > c2)
+ {
+ slab* c3 = c1;
+ c1 = c2;
+ c2 = c3;
+ }
+ slab* newc2 = c1->iChild2;
+ *r = c1;
+ c1->iParent = r;
+ c1->iChild2 = c2;
+ c2->iParent = &c1->iChild2;
+ s = c1;
+ c1 = s->iChild1;
+ c2 = newc2;
+ r = &s->iChild1;
+ }
+}
+//
+// Insert slab s into the tree/heap rooted at r, preserving the address ordering
+// invariant of the heap
+//
+void RHybridHeap::TreeInsert(slab* s,slab** r)
+{
+ slab* n = *r;
+ for (;;)
+ {
+ if (!n)
+ { // tree empty
+ *r = s;
+ s->iParent = r;
+ s->iChild1 = s->iChild2 = 0;
+ break;
+ }
+ if (s < n)
+ { // insert between iParent and n
+ *r = s;
+ s->iParent = r;
+ s->iChild1 = n;
+ s->iChild2 = 0;
+ n->iParent = &s->iChild1;
+ break;
+ }
+ slab* c1 = n->iChild1;
+ slab* c2 = n->iChild2;
+ if ((c1 - 1) > (c2 - 1))
+ {
+ r = &n->iChild1;
+ n = c1;
+ }
+ else
+ {
+ r = &n->iChild2;
+ n = c2;
+ }
+ }
+}
+
+void* RHybridHeap::AllocNewSlab(slabset& allocator)
+//
+// Acquire and initialise a new slab, returning a cell from the slab
+// The strategy is:
+// 1. Use the lowest address free slab, if available. This is done by using the lowest slab
+// in the page at the root of the iPartialPage heap (which is address ordered). If the
+// is now fully used, remove it from the iPartialPage heap.
+// 2. Allocate a new page for iSlabs if no empty iSlabs are available
+//
+{
+ page* p = page::PageFor(iPartialPage);
+ if (!p)
+ return AllocNewPage(allocator);
+
+ unsigned h = p->iSlabs[0].iHeader;
+ unsigned pagemap = SlabHeaderPagemap(h);
+ HEAP_ASSERT(&p->iSlabs[HIBIT(pagemap)] == iPartialPage);
+
+ unsigned slabix = LOWBIT(pagemap);
+ p->iSlabs[0].iHeader = h &~ (0x100<<slabix);
+ if (!(pagemap &~ (1<<slabix)))
+ {
+ TreeRemove(iPartialPage); // last free slab in page
+ }
+
+ return InitNewSlab(allocator, &p->iSlabs[slabix]);
+}
+
+/**Defination of this functionis not there in proto code***/
+#if 0
+void RHybridHeap::partial_insert(slab* s)
+{
+ // slab has had first cell freed and needs to be linked back into iPartial tree
+ slabset& ss = iSlabAlloc[iSizeMap[s->clz]];
+
+ HEAP_ASSERT(s->used == slabfull);
+ s->used = ss.fulluse - s->clz; // full-1 loading
+ TreeInsert(s,&ss.iPartial);
+ CHECKTREE(&ss.iPartial);
+}
+/**Defination of this functionis not there in proto code***/
+#endif
+
+void* RHybridHeap::AllocNewPage(slabset& allocator)
+//
+// Acquire and initialise a new page, returning a cell from a new slab
+// The iPartialPage tree is empty (otherwise we'd have used a slab from there)
+// The iPartialPage link is put in the highest addressed slab in the page, and the
+// lowest addressed slab is used to fulfill the allocation request
+//
+{
+ page* p = iSparePage;
+ if (p)
+ iSparePage = 0;
+ else
+ {
+ p = static_cast<page*>(Map(0, iPageSize));
+ if (!p)
+ return 0;
+ }
+ HEAP_ASSERT(p == Floor(p, iPageSize));
+ // Store page allocated for slab into paged_bitmap (for RHybridHeap::Reset())
+ if (!PagedSetSize(p, iPageSize))
+ {
+ Unmap(p, iPageSize);
+ return 0;
+ }
+ p->iSlabs[0].iHeader = ((1<<3) + (1<<2) + (1<<1))<<8; // set pagemap
+ p->iSlabs[3].iParent = &iPartialPage;
+ p->iSlabs[3].iChild1 = p->iSlabs[3].iChild2 = 0;
+ iPartialPage = &p->iSlabs[3];
+ return InitNewSlab(allocator,&p->iSlabs[0]);
+}
+
+void RHybridHeap::FreePage(page* p)
+//
+// Release an unused page to the OS
+// A single page is cached for reuse to reduce thrashing
+// the OS allocator.
+//
+{
+ HEAP_ASSERT(Ceiling(p, iPageSize) == p);
+ if (!iSparePage)
+ {
+ iSparePage = p;
+ return;
+ }
+
+ // unmapped slab page must be cleared from paged_bitmap, too
+ PagedZapSize(p, iPageSize); // clear page map
+
+ Unmap(p, iPageSize);
+}
+
+void RHybridHeap::FreeSlab(slab* s)
+//
+// Release an empty slab to the slab manager
+// The strategy is:
+// 1. The page containing the slab is checked to see the state of the other iSlabs in the page by
+// inspecting the pagemap field in the iHeader of the first slab in the page.
+// 2. The pagemap is updated to indicate the new unused slab
+// 3. If this is the only unused slab in the page then the slab iHeader is used to add the page to
+// the iPartialPage tree/heap
+// 4. If all the iSlabs in the page are now unused the page is release back to the OS
+// 5. If this slab has a higher address than the one currently used to track this page in
+// the iPartialPage heap, the linkage is moved to the new unused slab
+//
+{
+ TreeRemove(s);
+ CHECKTREE(s->iParent);
+ HEAP_ASSERT(SlabHeaderUsedm4(s->iHeader) == SlabHeaderSize(s->iHeader)-4);
+
+ page* p = page::PageFor(s);
+ unsigned h = p->iSlabs[0].iHeader;
+ int slabix = s - &p->iSlabs[0];
+ unsigned pagemap = SlabHeaderPagemap(h);
+ p->iSlabs[0].iHeader = h | (0x100<<slabix);
+ if (pagemap == 0)
+ { // page was full before, use this slab as link in empty heap
+ TreeInsert(s, &iPartialPage);
+ }
+ else
+ { // Find the current empty-link slab
+ slab* sl = &p->iSlabs[HIBIT(pagemap)];
+ pagemap ^= (1<<slabix);
+ if (pagemap == 0xf)
+ { // page is now empty so recycle page to os
+ TreeRemove(sl);
+ FreePage(p);
+ return;
+ }
+ // ensure the free list link is in highest address slab in page
+ if (s > sl)
+ { // replace current link with new one. Address-order tree so position stays the same
+ slab** r = sl->iParent;
+ slab* c1 = sl->iChild1;
+ slab* c2 = sl->iChild2;
+ s->iParent = r;
+ s->iChild1 = c1;
+ s->iChild2 = c2;
+ *r = s;
+ if (c1)
+ c1->iParent = &s->iChild1;
+ if (c2)
+ c2->iParent = &s->iChild2;
+ }
+ CHECK(if (s < sl) s=sl);
+ }
+ HEAP_ASSERT(SlabHeaderPagemap(p->iSlabs[0].iHeader) != 0);
+ HEAP_ASSERT(HIBIT(SlabHeaderPagemap(p->iSlabs[0].iHeader)) == unsigned(s - &p->iSlabs[0]));
+}
+
+
+void RHybridHeap::SlabInit()
+{
+ iSlabThreshold=0;
+ iPartialPage = 0;
+ iFullSlab = 0;
+ iSparePage = 0;
+ memset(&iSizeMap[0],0xff,sizeof(iSizeMap));
+ memset(&iSlabAlloc[0],0,sizeof(iSlabAlloc));
+}
+
+void RHybridHeap::SlabConfig(unsigned slabbitmap)
+{
+ HEAP_ASSERT((slabbitmap & ~EOkBits) == 0);
+ HEAP_ASSERT(MAXSLABSIZE <= 60);
+
+ unsigned int ix = 0xff;
+ unsigned int bit = 1<<((MAXSLABSIZE>>2)-1);
+ for (int sz = MAXSLABSIZE; sz >= 0; sz -= 4, bit >>= 1)
+ {
+ if (slabbitmap & bit)
+ {
+ if (ix == 0xff)
+ iSlabThreshold=sz+1;
+ ix = (sz>>2)-1;
+ }
+ iSizeMap[sz>>2] = (TUint8) ix;
+ }
+}
+
+
+void* RHybridHeap::SlabAllocate(slabset& ss)
+//
+// Allocate a cell from the given slabset
+// Strategy:
+// 1. Take the partially full slab at the iTop of the heap (lowest address).
+// 2. If there is no such slab, allocate from a new slab
+// 3. If the slab has a non-empty freelist, pop the cell from the front of the list and update the slab
+// 4. Otherwise, if the slab is not full, return the cell at the end of the currently used region of
+// the slab, updating the slab
+// 5. Otherwise, release the slab from the iPartial tree/heap, marking it as 'floating' and go back to
+// step 1
+//
+{
+ for (;;)
+ {
+ slab *s = ss.iPartial;
+ if (!s)
+ break;
+ unsigned h = s->iHeader;
+ unsigned free = h & 0xff; // extract free cell positioning
+ if (free)
+ {
+ HEAP_ASSERT(((free<<2)-sizeof(slabhdr))%SlabHeaderSize(h) == 0);
+ void* p = Offset(s,free<<2);
+ free = *(unsigned char*)p; // get next pos in free list
+ h += (h&0x3C000)<<6; // update usedm4
+ h &= ~0xff;
+ h |= free; // update freelist
+ s->iHeader = h;
+ HEAP_ASSERT(SlabHeaderFree(h) == 0 || ((SlabHeaderFree(h)<<2)-sizeof(slabhdr))%SlabHeaderSize(h) == 0);
+ HEAP_ASSERT(SlabHeaderUsedm4(h) <= 0x3F8u);
+ HEAP_ASSERT((SlabHeaderUsedm4(h)+4)%SlabHeaderSize(h) == 0);
+ return p;
+ }
+ unsigned h2 = h + ((h&0x3C000)<<6);
+// if (h2 < 0xfc00000)
+ if (h2 < MAXUSEDM4BITS)
+ {
+ HEAP_ASSERT((SlabHeaderUsedm4(h2)+4)%SlabHeaderSize(h2) == 0);
+ s->iHeader = h2;
+ return Offset(s,(h>>18) + sizeof(unsigned) + sizeof(slabhdr));
+ }
+ h |= FLOATING_BIT; // mark the slab as full-floating
+ s->iHeader = h;
+ TreeRemove(s);
+ slab* c = iFullSlab; // add to full list
+ iFullSlab = s;
+ s->iParent = &iFullSlab;
+ s->iChild1 = c;
+ s->iChild2 = 0;
+ if (c)
+ c->iParent = &s->iChild1;
+
+ CHECKTREE(&ss.iPartial);
+ // go back and try the next slab...
+ }
+ // no iPartial iSlabs found, so allocate from a new slab
+ return AllocNewSlab(ss);
+}
+
+void RHybridHeap::SlabFree(void* p)
+//
+// Free a cell from the slab allocator
+// Strategy:
+// 1. Find the containing slab (round down to nearest 1KB boundary)
+// 2. Push the cell into the slab's freelist, and update the slab usage count
+// 3. If this is the last allocated cell, free the slab to the main slab manager
+// 4. If the slab was full-floating then insert the slab in it's respective iPartial tree
+//
+{
+ HEAP_ASSERT(LowBits(p,3)==0);
+ slab* s = slab::SlabFor(p);
+ CHECKSLAB(s,ESlabAllocator,p);
+ CHECKSLABBFR(s,p);
+
+ unsigned pos = LowBits(p, SLABSIZE);
+ unsigned h = s->iHeader;
+ HEAP_ASSERT(SlabHeaderUsedm4(h) != 0x3fC); // slab is empty already
+ HEAP_ASSERT((pos-sizeof(slabhdr))%SlabHeaderSize(h) == 0);
+ *(unsigned char*)p = (unsigned char)h;
+ h &= ~0xFF;
+ h |= (pos>>2);
+ unsigned size = h & 0x3C000;
+ if (int(h) >= 0)
+ {
+ h -= size<<6;
+ if (int(h)>=0)
+ {
+ s->iHeader = h;
+ return;
+ }
+ FreeSlab(s);
+ return;
+ }
+ h -= size<<6;
+ h &= ~FLOATING_BIT;
+ s->iHeader = h;
+ slab** full = s->iParent; // remove from full list
+ slab* c = s->iChild1;
+ *full = c;
+ if (c)
+ c->iParent = full;
+
+ slabset& ss = iSlabAlloc[iSizeMap[size>>14]];
+ TreeInsert(s,&ss.iPartial);
+ CHECKTREE(&ss.iPartial);
+}
+
+void* RHybridHeap::InitNewSlab(slabset& allocator, slab* s)
+//
+// initialise an empty slab for this allocator and return the fist cell
+// pre-condition: the slabset has no iPartial iSlabs for allocation
+//
+{
+ HEAP_ASSERT(allocator.iPartial==0);
+ TInt size = 4 + ((&allocator-&iSlabAlloc[0])<<2); // infer size from slab allocator address
+ unsigned h = s->iHeader & 0xF00; // preserve pagemap only
+ h |= (size<<12); // set size
+ h |= (size-4)<<18; // set usedminus4 to one object minus 4
+ s->iHeader = h;
+ allocator.iPartial = s;
+ s->iParent = &allocator.iPartial;
+ s->iChild1 = s->iChild2 = 0;
+ return Offset(s,sizeof(slabhdr));
+}
+
+const unsigned char slab_bitcount[16] = {0,1,1,2,1,2,2,3,1,2,2,3,2,3,3,4};
+
+const unsigned char slab_ext_frag[16] =
+{
+ 0,
+ 16 + (1008 % 4),
+ 16 + (1008 % 8),
+ 16 + (1008 % 12),
+ 16 + (1008 % 16),
+ 16 + (1008 % 20),
+ 16 + (1008 % 24),
+ 16 + (1008 % 28),
+ 16 + (1008 % 32),
+ 16 + (1008 % 36),
+ 16 + (1008 % 40),
+ 16 + (1008 % 44),
+ 16 + (1008 % 48),
+ 16 + (1008 % 52),
+ 16 + (1008 % 56),
+ 16 + (1008 % 60)
+};
+
+void RHybridHeap::TreeWalk(slab* const* root, void (*f)(slab*, struct HeapInfo*, SWalkInfo*), struct HeapInfo* i, SWalkInfo* wi)
+{
+ // iterative walk around the tree at root
+
+ slab* s = *root;
+ if (!s)
+ return;
+
+ for (;;)
+ {
+ slab* c;
+ while ((c = s->iChild1) != 0)
+ s = c; // walk down left side to end
+ for (;;)
+ {
+ f(s, i, wi);
+ c = s->iChild2;
+ if (c)
+ { // one step down right side, now try and walk down left
+ s = c;
+ break;
+ }
+ for (;;)
+ { // loop to walk up right side
+ slab** pp = s->iParent;
+ if (pp == root)
+ return;
+ s = slab::SlabFor(pp);
+ if (pp == &s->iChild1)
+ break;
+ }
+ }
+ }
+}
+
+void RHybridHeap::SlabEmptyInfo(slab* s, struct HeapInfo* i, SWalkInfo* wi)
+{
+ Walk(wi, s, SLABSIZE, EGoodFreeCell, EEmptySlab); // Introduce an empty slab to the walk function
+ int nslab = slab_bitcount[SlabHeaderPagemap(page::PageFor(s)->iSlabs[0].iHeader)];
+ i->iFreeN += nslab;
+ i->iFreeBytes += nslab << SLABSHIFT;
+}
+
+void RHybridHeap::SlabPartialInfo(slab* s, struct HeapInfo* i, SWalkInfo* wi)
+{
+ Walk(wi, s, SLABSIZE, EGoodAllocatedCell, EPartialFullSlab); // Introduce a full slab to the walk function
+ unsigned h = s->iHeader;
+ unsigned used = SlabHeaderUsedm4(h)+4;
+ unsigned size = SlabHeaderSize(h);
+ unsigned free = 1024 - slab_ext_frag[size>>2] - used;
+ i->iFreeN += (free/size);
+ i->iFreeBytes += free;
+ i->iAllocN += (used/size);
+ i->iAllocBytes += used;
+}
+
+void RHybridHeap::SlabFullInfo(slab* s, struct HeapInfo* i, SWalkInfo* wi)
+{
+ Walk(wi, s, SLABSIZE, EGoodAllocatedCell, EFullSlab); // Introduce a full slab to the walk function
+ unsigned h = s->iHeader;
+ unsigned used = SlabHeaderUsedm4(h)+4;
+ unsigned size = SlabHeaderSize(h);
+ HEAP_ASSERT(1024 - slab_ext_frag[size>>2] - used == 0);
+ i->iAllocN += (used/size);
+ i->iAllocBytes += used;
+}
+
+void RHybridHeap::SlabInfo(struct HeapInfo* i, SWalkInfo* wi) const
+{
+ if (iSparePage)
+ {
+ i->iFreeBytes += iPageSize;
+ i->iFreeN = 4;
+ Walk(wi, iSparePage, iPageSize, EGoodFreeCell, ESlabSpare); // Introduce Slab spare page to the walk function
+ }
+ TreeWalk(&iFullSlab, &SlabFullInfo, i, wi);
+ for (int ix = 0; ix < (MAXSLABSIZE>>2); ++ix)
+ TreeWalk(&iSlabAlloc[ix].iPartial, &SlabPartialInfo, i, wi);
+ TreeWalk(&iPartialPage, &SlabEmptyInfo, i, wi);
+}
+
+
+//
+// Bitmap class implementation for large page allocator
+//
+inline unsigned char* paged_bitmap::Addr() const {return iBase;}
+inline unsigned paged_bitmap::Size() const {return iNbits;}
+//
+
+void paged_bitmap::Init(unsigned char* p, unsigned size, unsigned bit)
+{
+ iBase = p;
+ iNbits=size;
+ int bytes=Ceiling(size,8)>>3;
+ memset(p,bit?0xff:0,bytes);
+}
+
+inline void paged_bitmap::Set(unsigned ix, unsigned bit)
+{
+ if (bit)
+ iBase[ix>>3] |= (1<<(ix&7));
+ else
+ iBase[ix>>3] &= ~(1<<(ix&7));
+}
+
+inline unsigned paged_bitmap::operator[](unsigned ix) const
+{
+ return 1U&(iBase[ix>>3] >> (ix&7));
+}
+
+void paged_bitmap::Setn(unsigned ix, unsigned len, unsigned bit)
+{
+ int l=len;
+ while (--l>=0)
+ Set(ix++,bit);
+}
+
+void paged_bitmap::Set(unsigned ix, unsigned len, unsigned val)
+{
+ int l=len;
+ while (--l>=0)
+ {
+ Set(ix++,val&1);
+ val>>=1;
+ }
+}
+
+unsigned paged_bitmap::Bits(unsigned ix, unsigned len) const
+{
+ int l=len;
+ unsigned val=0;
+ unsigned bit=0;
+ while (--l>=0)
+ val |= (*this)[ix++]<<bit++;
+ return val;
+}
+
+bool paged_bitmap::Is(unsigned ix, unsigned len, unsigned bit) const
+{
+ unsigned i2 = ix+len;
+ if (i2 > iNbits)
+ return false;
+ for (;;)
+ {
+ if ((*this)[ix] != bit)
+ return false;
+ if (++ix==i2)
+ return true;
+ }
+}
+
+int paged_bitmap::Find(unsigned start, unsigned bit) const
+{
+ if (start<iNbits) do
+ {
+ if ((*this)[start]==bit)
+ return start;
+ } while (++start<iNbits);
+ return -1;
+}
+
+
+//
+// Page allocator code
+//
+void RHybridHeap::PagedInit(TInt aPagePower)
+{
+ if (aPagePower > 0)
+ {
+ if (aPagePower < MINPAGEPOWER)
+ aPagePower = MINPAGEPOWER;
+ }
+ else aPagePower = 31;
+
+ iPageThreshold = aPagePower;
+ /*-------------------------------------------------------------
+ * Initialize page bitmap
+ *-------------------------------------------------------------*/
+ iPageMap.Init((unsigned char*)&iBitMapBuffer, MAXSMALLPAGEBITS, 0);
+}
+
+void* RHybridHeap::PagedAllocate(unsigned size)
+{
+ TInt nbytes = Ceiling(size, iPageSize);
+ void* p = Map(0, nbytes);
+ if (!p)
+ return 0;
+ if (!PagedSetSize(p, nbytes))
+ {
+ Unmap(p, nbytes);
+ return 0;
+ }
+ return p;
+}
+
+void* RHybridHeap::PagedReallocate(void* p, unsigned size, TInt mode)
+{
+
+ HEAP_ASSERT(Ceiling(p, iPageSize) == p);
+ unsigned nbytes = Ceiling(size, iPageSize);
+
+ unsigned osize = PagedSize(p);
+ if ( nbytes == 0 ) // Special case to handle shrinking below min page threshold
+ nbytes = Min((1 << MINPAGEPOWER), osize);
+
+ if (osize == nbytes)
+ return p;
+
+ if (nbytes < osize)
+ { // shrink in place, unmap final pages and rewrite the pagemap
+ Unmap(Offset(p, nbytes), osize-nbytes);
+ // zap old code and then write new code (will not fail)
+ PagedZapSize(p, osize);
+
+ TBool check = PagedSetSize(p, nbytes);
+ __ASSERT_ALWAYS(check, HEAP_PANIC(ETHeapBadCellAddress));
+
+ return p;
+ }
+
+ // nbytes > osize
+ // try and extend current region first
+
+ void* newp = Map(Offset(p, osize), nbytes-osize);
+ if (newp)
+ { // In place growth. Possibility that pagemap may have to grow AND then fails
+ if (!PagedSetSize(p, nbytes))
+ { // must release extra mapping
+ Unmap(Offset(p, osize), nbytes-osize);
+ return 0;
+ }
+ // if successful, the new length code will have overwritten the old one (it is at least as long)
+ return p;
+ }
+
+ // fallback to allocate/copy/free
+ if (mode & ENeverMove)
+ return 0; // not allowed to move cell
+
+ newp = PagedAllocate(nbytes);
+ if (!newp)
+ return 0;
+ memcpy(newp, p, osize);
+ PagedFree(p);
+ return newp;
+}
+
+void RHybridHeap::PagedFree(void* p)
+{
+ HEAP_ASSERT(Ceiling(p, iPageSize) == p);
+
+
+ unsigned size = PagedSize(p);
+
+ PagedZapSize(p, size); // clear page map
+ Unmap(p, size);
+}
+
+void RHybridHeap::PagedInfo(struct HeapInfo* i, SWalkInfo* wi) const
+{
+ for (int ix = 0;(ix = iPageMap.Find(ix,1)) >= 0;)
+ {
+ int npage = PagedDecode(ix);
+ // Introduce paged buffer to the walk function
+ TAny* bfr = Bitmap2addr(ix);
+ int len = npage << PAGESHIFT;
+ if ( len > iPageSize )
+ { // If buffer is not larger than one page it must be a slab page mapped into bitmap
+ i->iAllocBytes += len;
+ ++i->iAllocN;
+ Walk(wi, bfr, len, EGoodAllocatedCell, EPageAllocator);
+ }
+ ix += (npage<<1);
+ }
+}
+
+void RHybridHeap::ResetBitmap()
+/*---------------------------------------------------------
+ * Go through paged_bitmap and unmap all buffers to system
+ * This method is called from RHybridHeap::Reset() to unmap all page
+ * allocated - and slab pages which are stored in bitmap, too
+ *---------------------------------------------------------*/
+{
+ unsigned iNbits = iPageMap.Size();
+ if ( iNbits )
+ {
+ for (int ix = 0;(ix = iPageMap.Find(ix,1)) >= 0;)
+ {
+ int npage = PagedDecode(ix);
+ void* p = Bitmap2addr(ix);
+ unsigned size = PagedSize(p);
+ PagedZapSize(p, size); // clear page map
+ Unmap(p, size);
+ ix += (npage<<1);
+ }
+ if ( (TInt)iNbits > MAXSMALLPAGEBITS )
+ {
+ // unmap page reserved for enlarged bitmap
+ Unmap(iPageMap.Addr(), (iNbits >> 3) );
+ }
+ }
+}
+
+TBool RHybridHeap::CheckBitmap(void* aBfr, TInt aSize, TUint32& aDummy, TInt& aNPages)
+/*---------------------------------------------------------
+ * If aBfr = NULL
+ * Go through paged_bitmap and unmap all buffers to system
+ * and assure that by reading the first word of each page of aBfr
+ * that aBfr is still accessible
+ * else
+ * Assure that specified buffer is mapped with correct length in
+ * page map
+ *---------------------------------------------------------*/
+{
+ TBool ret;
+ if ( aBfr )
+ {
+ __ASSERT_ALWAYS((Ceiling(aBfr, iPageSize) == aBfr), HEAP_PANIC(ETHeapBadCellAddress));
+ ret = ( aSize == (TInt)PagedSize(aBfr));
+ }
+ else
+ {
+ ret = ETrue;
+ unsigned iNbits = iPageMap.Size();
+ if ( iNbits )
+ {
+ TInt npage;
+ aNPages = 0;
+ for (int ix = 0;(ix = iPageMap.Find(ix,1)) >= 0;)
+ {
+ npage = PagedDecode(ix);
+ aNPages += npage;
+ void* p = Bitmap2addr(ix);
+ __ASSERT_ALWAYS((Ceiling(p, iPageSize) == p), HEAP_PANIC(ETHeapBadCellAddress));
+ unsigned s = PagedSize(p);
+ __ASSERT_ALWAYS((Ceiling(s, iPageSize) == s), HEAP_PANIC(ETHeapBadCellAddress));
+ while ( s )
+ {
+ aDummy += *(TUint32*)((TUint8*)p + (s-iPageSize));
+ s -= iPageSize;
+ }
+ ix += (npage<<1);
+ }
+ if ( (TInt)iNbits > MAXSMALLPAGEBITS )
+ {
+ // add enlarged bitmap page(s) to total page count
+ npage = (iNbits >> 3);
+ __ASSERT_ALWAYS((Ceiling(npage, iPageSize) == npage), HEAP_PANIC(ETHeapBadCellAddress));
+ aNPages += (npage / iPageSize);
+ }
+ }
+ }
+
+ return ret;
+}
+
+
+// The paged allocations are tracked in a bitmap which has 2 bits per page
+// this allows us to store allocations as small as 4KB
+// The presence and size of an allocation is encoded as follows:
+// let N = number of pages in the allocation, then
+// 10 : N = 1 // 4KB
+// 110n : N = 2 + n // 8-12KB
+// 1110nnnn : N = nnnn // 16-60KB
+// 1111n[18] : N = n[18] // 64KB-1GB
+
+const struct etab { unsigned char offset, len, codelen, code;} encode_table[] =
+{
+ {1,2,2,0x1},
+ {2,4,3,0x3},
+ {0,8,4,0x7},
+ {0,22,4,0xf}
+};
+
+// Return code length for specified allocation Size(assumed to be aligned to pages)
+inline unsigned paged_codelen(unsigned size, unsigned pagesz)
+{
+ HEAP_ASSERT(size == Ceiling(size, pagesz));
+
+ if (size == pagesz)
+ return 2;
+ else if (size < 4*pagesz)
+ return 4;
+ else if (size < 16*pagesz)
+ return 8;
+ else
+ return 22;
+}
+
+inline const etab& paged_coding(unsigned npage)
+{
+ if (npage < 4)
+ return encode_table[npage>>1];
+ else if (npage < 16)
+ return encode_table[2];
+ else
+ return encode_table[3];
+}
+
+bool RHybridHeap::PagedEncode(unsigned pos, unsigned npage)
+{
+ const etab& e = paged_coding(npage);
+ if (pos + e.len > iPageMap.Size())
+ {
+ // need to grow the page bitmap to fit the cell length into the map
+ // if we outgrow original bitmap buffer in RHybridHeap metadata, then just get enough pages to cover the full space:
+ // * initial 68 byte bitmap mapped (68*8*4kB):2 = 1,1MB
+ // * 4KB can Map(4096*8*4kB):2 = 64MB
+ unsigned maxsize = Ceiling(iMaxLength, iPageSize);
+ unsigned mapbits = maxsize >> (PAGESHIFT-1);
+ maxsize = Ceiling(mapbits>>3, iPageSize);
+ void* newb = Map(0, maxsize);
+ if (!newb)
+ return false;
+
+ unsigned char* oldb = iPageMap.Addr();
+ iPageMap.Init((unsigned char*)newb, (maxsize<<3), 0);
+ memcpy(newb, oldb, Ceiling(MAXSMALLPAGEBITS,8)>>3);
+ }
+ // encode the allocation block size into the bitmap, starting at the bit for the start page
+ unsigned bits = e.code;
+ bits |= (npage - e.offset) << e.codelen;
+ iPageMap.Set(pos, e.len, bits);
+ return true;
+}
+
+unsigned RHybridHeap::PagedDecode(unsigned pos) const
+{
+ __ASSERT_ALWAYS(pos + 2 <= iPageMap.Size(), HEAP_PANIC(ETHeapBadCellAddress));
+
+ unsigned bits = iPageMap.Bits(pos,2);
+ __ASSERT_ALWAYS(bits & 1, HEAP_PANIC(ETHeapBadCellAddress));
+ bits >>= 1;
+ if (bits == 0)
+ return 1;
+ __ASSERT_ALWAYS(pos + 4 <= iPageMap.Size(), HEAP_PANIC(ETHeapBadCellAddress));
+ bits = iPageMap.Bits(pos+2,2);
+ if ((bits & 1) == 0)
+ return 2 + (bits>>1);
+ else if ((bits>>1) == 0)
+ {
+ __ASSERT_ALWAYS(pos + 8 <= iPageMap.Size(), HEAP_PANIC(ETHeapBadCellAddress));
+ return iPageMap.Bits(pos+4, 4);
+ }
+ else
+ {
+ __ASSERT_ALWAYS(pos + 22 <= iPageMap.Size(), HEAP_PANIC(ETHeapBadCellAddress));
+ return iPageMap.Bits(pos+4, 18);
+ }
+}
+
+inline void RHybridHeap::PagedZapSize(void* p, unsigned size)
+{iPageMap.Setn(PtrDiff(p, iMemBase) >> (PAGESHIFT-1), paged_codelen(size, iPageSize) ,0);}
+
+inline unsigned RHybridHeap::PagedSize(void* p) const
+ { return PagedDecode(PtrDiff(p, iMemBase) >> (PAGESHIFT-1)) << PAGESHIFT; }
+
+inline bool RHybridHeap::PagedSetSize(void* p, unsigned size)
+{ return PagedEncode(PtrDiff(p, iMemBase) >> (PAGESHIFT-1), size >> PAGESHIFT); }
+
+inline void* RHybridHeap::Bitmap2addr(unsigned pos) const
+ { return iMemBase + (1 << (PAGESHIFT-1))*pos; }
+
+
+//////////////////////////////////////////////////////////////////////////
+//////////////////////////////////////////////////////////////////////////
+//////////////////////////////////////////////////////////////////////////
+/**
+Constructor where minimum and maximum length of the heap can be defined.
+It defaults the chunk heap to be created to have use a new local chunk,
+to have a grow by value of KMinHeapGrowBy, to be unaligned, not to be
+single threaded and not to have any mode flags set.
+
+@param aMinLength The minimum length of the heap to be created.
+@param aMaxLength The maximum length to which the heap to be created can grow.
+ If the supplied value is less than a page size, then it
+ is discarded and the page size is used instead.
+*/
+EXPORT_C TChunkHeapCreateInfo::TChunkHeapCreateInfo(TInt aMinLength, TInt aMaxLength) :
+ iVersionNumber(EVersion0), iMinLength(aMinLength), iMaxLength(aMaxLength),
+iAlign(0), iGrowBy(1), iSingleThread(EFalse),
+iOffset(0), iPaging(EUnspecified), iMode(0), iName(NULL)
+{
+}
+
+
+/**
+Sets the chunk heap to create a new chunk with the specified name.
+
+This overriddes any previous call to TChunkHeapCreateInfo::SetNewChunkHeap() or
+TChunkHeapCreateInfo::SetExistingChunkHeap() for this TChunkHeapCreateInfo object.
+
+@param aName The name to be given to the chunk heap to be created
+If NULL, the function constructs a local chunk to host the heap.
+If not NULL, a pointer to a descriptor containing the name to be
+assigned to the global chunk hosting the heap.
+*/
+EXPORT_C void TChunkHeapCreateInfo::SetCreateChunk(const TDesC* aName)
+{
+ iName = (TDesC*)aName;
+ iChunk.SetHandle(KNullHandle);
+}
+
+
+/**
+Sets the chunk heap to be created to use the chunk specified.
+
+This overriddes any previous call to TChunkHeapCreateInfo::SetNewChunkHeap() or
+TChunkHeapCreateInfo::SetExistingChunkHeap() for this TChunkHeapCreateInfo object.
+
+@param aChunk A handle to the chunk to use for the heap.
+*/
+EXPORT_C void TChunkHeapCreateInfo::SetUseChunk(const RChunk aChunk)
+{
+ iName = NULL;
+ iChunk = aChunk;
+}
+
+EXPORT_C RHeap* UserHeap::FixedHeap(TAny* aBase, TInt aMaxLength, TInt aAlign, TBool aSingleThread)
+/**
+Creates a fixed length heap at a specified location.
+
+On successful return from this function, the heap is ready to use. This assumes that
+the memory pointed to by aBase is mapped and able to be used. You must ensure that you
+pass in a large enough value for aMaxLength. Passing in a value that is too small to
+hold the metadata for the heap (~1 KB) will result in the size being rounded up and the
+heap thereby running over the end of the memory assigned to it. But then if you were to
+pass in such as small value then you would not be able to do any allocations from the
+heap anyway. Moral of the story: Use a sensible value for aMaxLength!
+
+@param aBase A pointer to the location where the heap is to be constructed.
+@param aMaxLength The maximum length in bytes to which the heap can grow. If the
+ supplied value is too small to hold the heap's metadata, it
+ will be increased.
+@param aAlign From Symbian^4 onwards, this value is ignored but EABI 8
+ byte alignment is guaranteed for all allocations 8 bytes or
+ more in size. 4 byte allocations will be aligned to a 4
+ byte boundary. Best to pass in zero.
+@param aSingleThread EFalse if the heap is to be accessed from multiple threads.
+ This will cause internal locks to be created, guaranteeing
+ thread safety.
+
+@return A pointer to the new heap, or NULL if the heap could not be created.
+
+@panic USER 56 if aMaxLength is negative.
+*/
+{
+ __ASSERT_ALWAYS( aMaxLength>=0, ::Panic(ETHeapMaxLengthNegative));
+ if ( aMaxLength < (TInt)sizeof(RHybridHeap) )
+ aMaxLength = sizeof(RHybridHeap);
+
+ RHybridHeap* h = new(aBase) RHybridHeap(aMaxLength, aAlign, aSingleThread);
+
+ if (!aSingleThread)
+ {
+ TInt r = h->iLock.CreateLocal();
+ if (r!=KErrNone)
+ return NULL; // No need to delete the RHybridHeap instance as the new above is only a placement new
+ h->iHandles = (TInt*)&h->iLock;
+ h->iHandleCount = 1;
+ }
+ return h;
+}
+
+/**
+Creates a chunk heap of the type specified by the parameter aCreateInfo.
+
+@param aCreateInfo A reference to a TChunkHeapCreateInfo object specifying the
+type of chunk heap to create.
+
+@return A pointer to the new heap or NULL if the heap could not be created.
+
+@panic USER 41 if the heap's specified minimum length is greater than the specified maximum length.
+@panic USER 55 if the heap's specified minimum length is negative.
+@panic USER 172 if the heap's specified alignment is not a power of 2 or is less than the size of a TAny*.
+*/
+EXPORT_C RHeap* UserHeap::ChunkHeap(const TChunkHeapCreateInfo& aCreateInfo)
+{
+ // aCreateInfo must have been configured to use a new chunk or an exiting chunk.
+ __ASSERT_ALWAYS(!(aCreateInfo.iMode & (TUint32)~EChunkHeapMask), ::Panic(EHeapCreateInvalidMode));
+ RHeap* h = NULL;
+
+ if (aCreateInfo.iChunk.Handle() == KNullHandle)
+ {
+ // A new chunk is to be created for this heap.
+
+ __ASSERT_ALWAYS(aCreateInfo.iMinLength >= 0, ::Panic(ETHeapMinLengthNegative));
+ __ASSERT_ALWAYS(aCreateInfo.iMaxLength >= aCreateInfo.iMinLength, ::Panic(ETHeapCreateMaxLessThanMin));
+
+ TInt maxLength = aCreateInfo.iMaxLength;
+ TInt page_size;
+ GET_PAGE_SIZE(page_size);
+
+ if (maxLength < page_size)
+ maxLength = page_size;
+
+ TChunkCreateInfo chunkInfo;
+#if USE_HYBRID_HEAP
+ if ( aCreateInfo.iOffset )
+ chunkInfo.SetNormal(0, maxLength); // Create DL only heap
+ else
+ {
+ maxLength = 2*maxLength;
+ chunkInfo.SetDisconnected(0, 0, maxLength); // Create hybrid heap
+ }
+#else
+ chunkInfo.SetNormal(0, maxLength); // Create DL only heap
+#endif
+ chunkInfo.SetOwner((aCreateInfo.iSingleThread)? EOwnerThread : EOwnerProcess);
+ if (aCreateInfo.iName)
+ chunkInfo.SetGlobal(*aCreateInfo.iName);
+ // Set the paging attributes of the chunk.
+ if (aCreateInfo.iPaging == TChunkHeapCreateInfo::EPaged)
+ chunkInfo.SetPaging(TChunkCreateInfo::EPaged);
+ if (aCreateInfo.iPaging == TChunkHeapCreateInfo::EUnpaged)
+ chunkInfo.SetPaging(TChunkCreateInfo::EUnpaged);
+ // Create the chunk.
+ RChunk chunk;
+ if (chunk.Create(chunkInfo) != KErrNone)
+ return NULL;
+ // Create the heap using the new chunk.
+ TUint mode = aCreateInfo.iMode | EChunkHeapDuplicate; // Must duplicate the handle.
+ h = OffsetChunkHeap(chunk, aCreateInfo.iMinLength, aCreateInfo.iOffset,
+ aCreateInfo.iGrowBy, maxLength, aCreateInfo.iAlign,
+ aCreateInfo.iSingleThread, mode);
+ chunk.Close();
+ }
+ else
+ {
+ h = OffsetChunkHeap(aCreateInfo.iChunk, aCreateInfo.iMinLength, aCreateInfo.iOffset,
+ aCreateInfo.iGrowBy, aCreateInfo.iMaxLength, aCreateInfo.iAlign,
+ aCreateInfo.iSingleThread, aCreateInfo.iMode);
+ }
+ return h;
+}
+
+
+
+EXPORT_C RHeap* UserHeap::ChunkHeap(const TDesC* aName, TInt aMinLength, TInt aMaxLength, TInt aGrowBy, TInt aAlign, TBool aSingleThread)
+/**
+Creates a heap in a local or global chunk.
+
+The chunk hosting the heap can be local or global.
+
+A local chunk is one which is private to the process creating it and is not
+intended for access by other user processes. A global chunk is one which is
+visible to all processes.
+
+The hosting chunk is local, if the pointer aName is NULL, otherwise the
+hosting chunk is global and the descriptor *aName is assumed to contain
+the name to be assigned to it.
+
+Ownership of the host chunk is vested in the current process.
+
+A minimum and a maximum size for the heap can be specified. On successful
+return from this function, the size of the heap is at least aMinLength.
+If subsequent requests for allocation of memory from the heap cannot be
+satisfied by compressing the heap, the size of the heap is extended in
+increments of aGrowBy until the request can be satisfied. Attempts to extend
+the heap causes the size of the host chunk to be adjusted.
+
+Note that the size of the heap cannot be adjusted by more than aMaxLength.
+
+@param aName If NULL, the function constructs a local chunk to host
+ the heap. If not NULL, a pointer to a descriptor containing
+ the name to be assigned to the global chunk hosting the heap.
+@param aMinLength The minimum length of the heap in bytes. This will be
+ rounded up to the nearest page size by the allocator.
+@param aMaxLength The maximum length in bytes to which the heap can grow. This
+ will be rounded up to the nearest page size by the allocator.
+@param aGrowBy The number of bytes by which the heap will grow when more
+ memory is required. This will be rounded up to the nearest
+ page size by the allocator. If a value is not explicitly
+ specified, the page size is taken by default.
+@param aAlign From Symbian^4 onwards, this value is ignored but EABI 8
+ byte alignment is guaranteed for all allocations 8 bytes or
+ more in size. 4 byte allocations will be aligned to a 4
+ byte boundary. Best to pass in zero.
+@param aSingleThread EFalse if the heap is to be accessed from multiple threads.
+ This will cause internal locks to be created, guaranteeing
+ thread safety.
+
+@return A pointer to the new heap or NULL if the heap could not be created.
+
+@panic USER 41 if aMaxLength is < aMinLength.
+@panic USER 55 if aMinLength is negative.
+@panic USER 56 if aMaxLength is negative.
+*/
+ {
+ TInt page_size;
+ GET_PAGE_SIZE(page_size);
+ TInt minLength = _ALIGN_UP(aMinLength, page_size);
+ TInt maxLength = Max(aMaxLength, minLength);
+
+ TChunkHeapCreateInfo createInfo(minLength, maxLength);
+ createInfo.SetCreateChunk(aName);
+ createInfo.SetGrowBy(aGrowBy);
+ createInfo.SetAlignment(aAlign);
+ createInfo.SetSingleThread(aSingleThread);
+
+ return ChunkHeap(createInfo);
+ }
+
+EXPORT_C RHeap* UserHeap::ChunkHeap(RChunk aChunk, TInt aMinLength, TInt aGrowBy, TInt aMaxLength, TInt aAlign, TBool aSingleThread, TUint32 aMode)
+/**
+Creates a heap in an existing chunk.
+
+This function is intended to be used to create a heap in a user writable code
+chunk as created by a call to RChunk::CreateLocalCode(). This type of heap can
+be used to hold code fragments from a JIT compiler.
+
+@param aChunk The chunk that will host the heap.
+@param aMinLength The minimum length of the heap in bytes. This will be
+ rounded up to the nearest page size by the allocator.
+@param aGrowBy The number of bytes by which the heap will grow when more
+ memory is required. This will be rounded up to the nearest
+ page size by the allocator. If a value is not explicitly
+ specified, the page size is taken by default.
+@param aMaxLength The maximum length in bytes to which the heap can grow. This
+ will be rounded up to the nearest page size by the allocator.
+ If 0 is passed in, the maximum lengt of the chunk is used.
+@param aAlign From Symbian^4 onwards, this value is ignored but EABI 8
+ byte alignment is guaranteed for all allocations 8 bytes or
+ more in size. 4 byte allocations will be aligned to a 4
+ byte boundary. Best to pass in zero.
+@param aSingleThread EFalse if the heap is to be accessed from multiple threads.
+ This will cause internal locks to be created, guaranteeing
+ thread safety.
+@param aMode Flags controlling the heap creation. See RAllocator::TFlags.
+
+@return A pointer to the new heap or NULL if the heap could not be created.
+
+@see UserHeap::OffsetChunkHeap()
+*/
+ {
+ return OffsetChunkHeap(aChunk, aMinLength, 0, aGrowBy, aMaxLength, aAlign, aSingleThread, aMode);
+ }
+
+EXPORT_C RHeap* UserHeap::OffsetChunkHeap(RChunk aChunk, TInt aMinLength, TInt aOffset, TInt aGrowBy, TInt aMaxLength, TInt aAlign, TBool aSingleThread, TUint32 aMode)
+/**
+Creates a heap in an existing chunk, offset from the beginning of the chunk.
+
+This function is intended to be used to create a heap using a chunk which has
+some of its memory already used, at the start of that that chunk. The maximum
+length to which the heap can grow is the maximum size of the chunk, minus the
+data at the start of the chunk.
+
+The offset at which to create the heap is passed in as the aOffset parameter.
+Legacy heap implementations always respected the aOffset value, however more
+modern heap implementations are more sophisticated and cannot necessarily respect
+this value. Therefore, if possible, you should always use an aOffset of 0 unless
+you have a very explicit requirement for using a non zero value. Using a non zero
+value will result in a less efficient heap algorithm being used in order to respect
+the offset.
+
+Another issue to consider when using this function is the type of the chunk passed
+in. In order for the most efficient heap algorithms to be used, the chunk passed
+in should always be a disconnected chunk. Passing in a non disconnected chunk will
+again result in a less efficient heap algorithm being used.
+
+Finally, another requirement for the most efficient heap algorithms to be used is
+for the heap to be able to expand. Therefore, unless you have a specific reason to
+do so, always specify aMaxLength > aMinLength.
+
+So, if possible, use aOffset == zero, aMaxLength > aMinLength and a disconnected
+chunk for best results!
+
+@param aChunk The chunk that will host the heap.
+@param aMinLength The minimum length of the heap in bytes. This will be
+ rounded up to the nearest page size by the allocator.
+@param aOffset The offset in bytes from the start of the chunk at which to
+ create the heap. If used (and it shouldn't really be!)
+ then it will be rounded up to a multiple of 8, to respect
+ EABI 8 byte alignment requirements.
+@param aGrowBy The number of bytes by which the heap will grow when more
+ memory is required. This will be rounded up to the nearest
+ page size by the allocator. If a value is not explicitly
+ specified, the page size is taken by default.
+@param aMaxLength The maximum length in bytes to which the heap can grow. This
+ will be rounded up to the nearest page size by the allocator.
+ If 0 is passed in, the maximum length of the chunk is used.
+@param aAlign From Symbian^4 onwards, this value is ignored but EABI 8
+ byte alignment is guaranteed for all allocations 8 bytes or
+ more in size. 4 byte allocations will be aligned to a 4
+ byte boundary. Best to pass in zero.
+@param aSingleThread EFalse if the heap is to be accessed from multiple threads.
+ This will cause internal locks to be created, guaranteeing
+ thread safety.
+@param aMode Flags controlling the heap creation. See RAllocator::TFlags.
+
+@return A pointer to the new heap or NULL if the heap could not be created.
+
+@panic USER 41 if aMaxLength is < aMinLength.
+@panic USER 55 if aMinLength is negative.
+@panic USER 56 if aMaxLength is negative.
+@panic USER 168 if aOffset is negative.
+*/
+ {
+ TBool dlOnly = EFalse;
+ TInt pageSize;
+ GET_PAGE_SIZE(pageSize);
+ TInt align = RHybridHeap::ECellAlignment; // Always use EABI 8 byte alignment
+
+ __ASSERT_ALWAYS(aMinLength>=0, ::Panic(ETHeapMinLengthNegative));
+ __ASSERT_ALWAYS(aMaxLength>=0, ::Panic(ETHeapMaxLengthNegative));
+
+ if ( aMaxLength > 0 )
+ __ASSERT_ALWAYS(aMaxLength>=aMinLength, ::Panic(ETHeapCreateMaxLessThanMin));
+
+ // Stick to EABI alignment for the start offset, if any
+ aOffset = _ALIGN_UP(aOffset, align);
+
+ // Using an aOffset > 0 means that we can't use the hybrid allocator and have to revert to Doug Lea only
+ if (aOffset > 0)
+ dlOnly = ETrue;
+
+ // Ensure that the minimum length is enough to hold the RHybridHeap object itself
+ TInt minCell = _ALIGN_UP(Max((TInt)RHybridHeap::EAllocCellSize, (TInt)RHybridHeap::EFreeCellSize), align);
+ TInt hybridHeapSize = (sizeof(RHybridHeap) + minCell);
+ if (aMinLength < hybridHeapSize)
+ aMinLength = hybridHeapSize;
+
+ // Round the minimum length up to a multiple of the page size, taking into account that the
+ // offset takes up a part of the chunk's memory
+ aMinLength = _ALIGN_UP((aMinLength + aOffset), pageSize);
+
+ // If aMaxLength is 0 then use the entire chunk
+ TInt chunkSize = aChunk.MaxSize();
+ if (aMaxLength == 0)
+ {
+ aMaxLength = chunkSize;
+ }
+ // Otherwise round the maximum length up to a multiple of the page size, taking into account that
+ // the offset takes up a part of the chunk's memory. We also clip the maximum length to the chunk
+ // size, so the user may get a little less than requested if the chunk size is not large enough
+ else
+ {
+ aMaxLength = _ALIGN_UP((aMaxLength + aOffset), pageSize);
+ if (aMaxLength > chunkSize)
+ aMaxLength = chunkSize;
+ }
+
+ // If the rounded up values don't make sense then a crazy aMinLength or aOffset must have been passed
+ // in, so fail the heap creation
+ if (aMinLength > aMaxLength)
+ return NULL;
+
+ // Adding the offset into the minimum and maximum length was only necessary for ensuring a good fit of
+ // the heap into the chunk. Re-adjust them now back to non offset relative sizes
+ aMinLength -= aOffset;
+ aMaxLength -= aOffset;
+
+ // If we are still creating the hybrid allocator (call parameter
+ // aOffset is 0 and aMaxLength > aMinLength), we must reduce heap
+ // aMaxLength size to the value aMaxLength/2 and set the aOffset to point in the middle of chunk.
+ TInt offset = aOffset;
+ TInt maxLength = aMaxLength;
+ if (!dlOnly && (aMaxLength > aMinLength))
+ maxLength = offset = _ALIGN_UP(aMaxLength >> 1, pageSize);
+
+ // Try to use commit to map aMinLength physical memory for the heap, taking into account the offset. If
+ // the operation fails, suppose that the chunk is not a disconnected heap and try to map physical memory
+ // with adjust. In this case, we also can't use the hybrid allocator and have to revert to Doug Lea only
+ TBool useAdjust = EFalse;
+ TInt r = aChunk.Commit(offset, aMinLength);
+ if (r == KErrGeneral)
+ {
+ dlOnly = useAdjust = ETrue;
+ r = aChunk.Adjust(aMinLength);
+ if (r != KErrNone)
+ return NULL;
+ }
+ else if (r == KErrNone)
+ {
+ // We have a disconnected chunk reset aOffset and aMaxlength
+ aOffset = offset;
+ aMaxLength = maxLength;
+ }
+
+ else
+ return NULL;
+
+ // Parameters have been mostly verified and we know whether to use the hybrid allocator or Doug Lea only. The
+ // constructor for the hybrid heap will automatically drop back to Doug Lea if it determines that aMinLength
+ // == aMaxLength, so no need to worry about that requirement here. The user specified alignment is not used but
+ // is passed in so that it can be sanity checked in case the user is doing something totally crazy with it
+ RHybridHeap* h = new (aChunk.Base() + aOffset) RHybridHeap(aChunk.Handle(), aOffset, aMinLength, aMaxLength,
+ aGrowBy, aAlign, aSingleThread, dlOnly, useAdjust);
+
+ if (h->ConstructLock(aMode) != KErrNone)
+ return NULL;
+
+ // Return the heap address
+ return h;
+ }
+
+#define UserTestDebugMaskBit(bit) (TBool)(UserSvr::DebugMask(bit>>5) & (1<<(bit&31)))
+
+_LIT(KLitDollarHeap,"$HEAP");
+EXPORT_C TInt UserHeap::CreateThreadHeap(SStdEpocThreadCreateInfo& aInfo, RHeap*& aHeap, TInt aAlign, TBool aSingleThread)
+/**
+@internalComponent
+*/
+//
+// Create a user-side heap
+//
+{
+ TInt page_size;
+ GET_PAGE_SIZE(page_size);
+ TInt minLength = _ALIGN_UP(aInfo.iHeapInitialSize, page_size);
+ TInt maxLength = Max(aInfo.iHeapMaxSize, minLength);
+ if (UserTestDebugMaskBit(96)) // 96 == KUSERHEAPTRACE in nk_trace.h
+ aInfo.iFlags |= ETraceHeapAllocs;
+ // Create the thread's heap chunk.
+ RChunk c;
+ TChunkCreateInfo createInfo;
+
+ createInfo.SetThreadHeap(0, maxLength, KLitDollarHeap()); // Initialise with no memory committed.
+#if USE_HYBRID_HEAP
+ //
+ // Create disconnected chunk for hybrid heap with double max length value
+ //
+ maxLength = 2*maxLength;
+ createInfo.SetDisconnected(0, 0, maxLength);
+#endif
+ // Set the paging policy of the heap chunk based on the thread's paging policy.
+ TUint pagingflags = aInfo.iFlags & EThreadCreateFlagPagingMask;
+ switch (pagingflags)
+ {
+ case EThreadCreateFlagPaged:
+ createInfo.SetPaging(TChunkCreateInfo::EPaged);
+ break;
+ case EThreadCreateFlagUnpaged:
+ createInfo.SetPaging(TChunkCreateInfo::EUnpaged);
+ break;
+ case EThreadCreateFlagPagingUnspec:
+ // Leave the chunk paging policy unspecified so the process's
+ // paging policy is used.
+ break;
+ }
+
+ TInt r = c.Create(createInfo);
+ if (r!=KErrNone)
+ return r;
+
+ aHeap = ChunkHeap(c, minLength, page_size, maxLength, aAlign, aSingleThread, EChunkHeapSwitchTo|EChunkHeapDuplicate);
+ c.Close();
+
+ if ( !aHeap )
+ return KErrNoMemory;
+
+ if (aInfo.iFlags & ETraceHeapAllocs)
+ {
+ aHeap->iFlags |= RHeap::ETraceAllocs;
+ BTraceContext8(BTrace::EHeap, BTrace::EHeapCreate,(TUint32)aHeap, RHybridHeap::EAllocCellSize);
+ TInt chunkId = ((RHandleBase&)((RHybridHeap*)aHeap)->iChunkHandle).BTraceId();
+ BTraceContext8(BTrace::EHeap, BTrace::EHeapChunkCreate, (TUint32)aHeap, chunkId);
+ }
+ if (aInfo.iFlags & EMonitorHeapMemory)
+ aHeap->iFlags |= RHeap::EMonitorMemory;
+
+ return KErrNone;
+}
+
+#endif // __KERNEL_MODE__