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author | mread <qt-info@nokia.com> | 2010-09-22 12:27:15 (GMT) |
---|---|---|
committer | mread <qt-info@nokia.com> | 2010-09-30 14:48:29 (GMT) |
commit | 40b413ca994fd26404672cefa71dc36fd2626b67 (patch) | |
tree | 32f53649c4548ecce80e031e882fca1f87dd9958 /src/corelib | |
parent | 3579fd98fbaf95d7dfc4d05f34e00353a295d340 (diff) | |
download | Qt-40b413ca994fd26404672cefa71dc36fd2626b67.zip Qt-40b413ca994fd26404672cefa71dc36fd2626b67.tar.gz Qt-40b413ca994fd26404672cefa71dc36fd2626b67.tar.bz2 |
Qt apps to use the Symbian^4 fast allocator in pre-Symbian^4 platforms
The hybrid heap allocator has been copied from Symbian^4 (MCL wk36
initially) and is installed by qtmain.lib as the initial allocator
for Qt apps.
Task-number: QT-3967
Reviewed-by: Shane Kearns
Diffstat (limited to 'src/corelib')
-rw-r--r-- | src/corelib/arch/symbian/arch.pri | 10 | ||||
-rw-r--r-- | src/corelib/arch/symbian/common_p.h | 105 | ||||
-rw-r--r-- | src/corelib/arch/symbian/debugfunction.cpp | 1147 | ||||
-rw-r--r-- | src/corelib/arch/symbian/dla_p.h | 622 | ||||
-rw-r--r-- | src/corelib/arch/symbian/heap_hybrid.cpp | 3337 | ||||
-rw-r--r-- | src/corelib/arch/symbian/heap_hybrid_p.h | 391 | ||||
-rw-r--r-- | src/corelib/arch/symbian/newallocator.cpp | 2916 | ||||
-rw-r--r-- | src/corelib/arch/symbian/newallocator_p.h | 338 | ||||
-rw-r--r-- | src/corelib/arch/symbian/page_alloc_p.h | 68 | ||||
-rw-r--r-- | src/corelib/arch/symbian/qt_heapsetup_symbian.cpp | 99 | ||||
-rw-r--r-- | src/corelib/arch/symbian/qt_hybridHeap_symbian.h | 76 | ||||
-rw-r--r-- | src/corelib/arch/symbian/slab_p.h | 125 | ||||
-rw-r--r-- | src/corelib/global/qglobal.h | 2 |
13 files changed, 5621 insertions, 3615 deletions
diff --git a/src/corelib/arch/symbian/arch.pri b/src/corelib/arch/symbian/arch.pri index bab042c..8c546c0 100644 --- a/src/corelib/arch/symbian/arch.pri +++ b/src/corelib/arch/symbian/arch.pri @@ -3,8 +3,14 @@ # SOURCES += $$QT_ARCH_CPP/qatomic_symbian.cpp \ $$QT_ARCH_CPP/../armv6/qatomic_generic_armv6.cpp \ - $$QT_ARCH_CPP/newallocator.cpp + $$QT_ARCH_CPP/heap_hybrid.cpp \ + $$QT_ARCH_CPP/debugfunction.cpp \ + $$QT_ARCH_CPP/qt_heapsetup_symbian.cpp HEADERS += $$QT_ARCH_CPP/dla_p.h \ - $$QT_ARCH_CPP/newallocator_p.h + $$QT_ARCH_CPP/heap_hybrid_p.h \ + $$QT_ARCH_CPP/common_p.h \ + $$QT_ARCH_CPP/page_alloc_p.h \ + $$QT_ARCH_CPP/slab_p.h + exists($$EPOCROOT/epoc32/include/u32std.h):DEFINES += QT_SYMBIAN_HAVE_U32STD_H diff --git a/src/corelib/arch/symbian/common_p.h b/src/corelib/arch/symbian/common_p.h new file mode 100644 index 0000000..d7682ae --- /dev/null +++ b/src/corelib/arch/symbian/common_p.h @@ -0,0 +1,105 @@ +/**************************************************************************** +** +** Copyright (C) 2010 Nokia Corporation and/or its subsidiary(-ies). +** All rights reserved. +** Contact: Nokia Corporation (qt-info@nokia.com) +** +** This file is part of the QtCore module of the Qt Toolkit. +** +** $QT_BEGIN_LICENSE:LGPL$ +** No Commercial Usage +** This file contains pre-release code and may not be distributed. +** You may use this file in accordance with the terms and conditions +** contained in the Technology Preview License Agreement accompanying +** this package. +** +** GNU Lesser General Public License Usage +** Alternatively, this file may be used under the terms of the GNU Lesser +** General Public License version 2.1 as published by the Free Software +** Foundation and appearing in the file LICENSE.LGPL included in the +** packaging of this file. Please review the following information to +** ensure the GNU Lesser General Public License version 2.1 requirements +** will be met: http://www.gnu.org/licenses/old-licenses/lgpl-2.1.html. +** +** In addition, as a special exception, Nokia gives you certain additional +** rights. These rights are described in the Nokia Qt LGPL Exception +** version 1.1, included in the file LGPL_EXCEPTION.txt in this package. +** +** If you have questions regarding the use of this file, please contact +** Nokia at qt-info@nokia.com. +** +** +** +** +** +** +** +** +** $QT_END_LICENSE$ +** +****************************************************************************/ + +#ifndef __E32_COMMON_H__ +#define __E32_COMMON_H__ + +#ifdef __KERNEL_MODE__ +#include <e32cmn.h> +#include <e32panic.h> +#include "u32std.h" +#else +#include <e32std.h> +#include <e32base.h> +#include <e32math.h> +#include <e32svr.h> +#include <e32ver.h> +#include <e32hal.h> +#include <e32panic.h> +#include <u32exec.h> +#endif + +GLREF_C void Panic(TCdtPanic aPanic); +GLDEF_C void PanicBadArrayIndex(); +GLREF_C TInt __DoConvertNum(TUint, TRadix, TUint, TUint8*&); +GLREF_C TInt __DoConvertNum(Uint64, TRadix, TUint, TUint8*&); + +#ifdef __KERNEL_MODE__ +GLREF_C void KernHeapFault(TCdtPanic aPanic); +GLREF_C void KHeapCheckThreadState(); +TInt StringLength(const TUint16* aPtr); +TInt StringLength(const TUint8* aPtr); + +#define STD_CLASS Kern +#define STRING_LENGTH(s) StringLength(s) +#define STRING_LENGTH_16(s) StringLength(s) +#define PANIC_CURRENT_THREAD(c,r) Kern::PanicCurrentThread(c, r) +#define __KERNEL_CHECK_RADIX(r) __ASSERT_ALWAYS(((r)==EDecimal)||((r)==EHex),Panic(EInvalidRadix)) +#define APPEND_BUF_SIZE 10 +#define APPEND_BUF_SIZE_64 20 +#define HEAP_PANIC(r) Kern::Printf("HEAP CORRUPTED %s %d", __FILE__, __LINE__), RHeapK::Fault(r) +#define GET_PAGE_SIZE(x) x = M::PageSizeInBytes() +#define DIVISION_BY_ZERO() FAULT() + +#ifdef _DEBUG +#define __CHECK_THREAD_STATE RHeapK::CheckThreadState() +#else +#define __CHECK_THREAD_STATE +#endif + +#else + +#define STD_CLASS User +#define STRING_LENGTH(s) User::StringLength(s) +#define STRING_LENGTH_16(s) User::StringLength(s) +#define PANIC_CURRENT_THREAD(c,r) User::Panic(c, r) +#define MEM_COMPARE_16 Mem::Compare +#define __KERNEL_CHECK_RADIX(r) +#define APPEND_BUF_SIZE 32 +#define APPEND_BUF_SIZE_64 64 +#define HEAP_PANIC(r) RDebug::Printf("HEAP CORRUPTED %s %d", __FILE__, __LINE__), Panic(r) +#define GET_PAGE_SIZE(x) UserHal::PageSizeInBytes(x) +#define DIVISION_BY_ZERO() User::RaiseException(EExcIntegerDivideByZero) +#define __CHECK_THREAD_STATE + +#endif // __KERNEL_MODE__ + +#endif diff --git a/src/corelib/arch/symbian/debugfunction.cpp b/src/corelib/arch/symbian/debugfunction.cpp new file mode 100644 index 0000000..62adde0 --- /dev/null +++ b/src/corelib/arch/symbian/debugfunction.cpp @@ -0,0 +1,1147 @@ +/**************************************************************************** +** +** Copyright (C) 2010 Nokia Corporation and/or its subsidiary(-ies). +** All rights reserved. +** Contact: Nokia Corporation (qt-info@nokia.com) +** +** This file is part of the QtCore module of the Qt Toolkit. +** +** $QT_BEGIN_LICENSE:LGPL$ +** No Commercial Usage +** This file contains pre-release code and may not be distributed. +** You may use this file in accordance with the terms and conditions +** contained in the Technology Preview License Agreement accompanying +** this package. +** +** GNU Lesser General Public License Usage +** Alternatively, this file may be used under the terms of the GNU Lesser +** General Public License version 2.1 as published by the Free Software +** Foundation and appearing in the file LICENSE.LGPL included in the +** packaging of this file. Please review the following information to +** ensure the GNU Lesser General Public License version 2.1 requirements +** will be met: http://www.gnu.org/licenses/old-licenses/lgpl-2.1.html. +** +** In addition, as a special exception, Nokia gives you certain additional +** rights. These rights are described in the Nokia Qt LGPL Exception +** version 1.1, included in the file LGPL_EXCEPTION.txt in this package. +** +** If you have questions regarding the use of this file, please contact +** Nokia at qt-info@nokia.com. +** +** +** +** +** +** +** +** +** $QT_END_LICENSE$ +** +****************************************************************************/ + +#include "qt_hybridheap_symbian.h" + +#ifdef QT_USE_NEW_SYMBIAN_ALLOCATOR + +#define GM (&iGlobalMallocState) +#define __HEAP_CORRUPTED_TRACE(t,p,l) BTraceContext12(BTrace::EHeap, BTrace::EHeapCorruption, (TUint32)t, (TUint32)p, (TUint32)l); +#define __HEAP_CORRUPTED_TEST(c,x, p,l) if (!c) { if (iFlags & (EMonitorMemory+ETraceAllocs) ) __HEAP_CORRUPTED_TRACE(this,p,l) HEAP_PANIC(x); } +#define __HEAP_CORRUPTED_TEST_STATIC(c,t,x,p,l) if (!c) { if (t && (t->iFlags & (EMonitorMemory+ETraceAllocs) )) __HEAP_CORRUPTED_TRACE(t,p,l) HEAP_PANIC(x); } + +TInt RHybridHeap::DebugFunction(TInt aFunc, TAny* a1, TAny* a2) +{ + TInt r = KErrNone; + switch(aFunc) + { + + case RAllocator::ECount: + struct HeapInfo info; + Lock(); + GetInfo(&info, NULL); + *(unsigned*)a1 = info.iFreeN; + r = info.iAllocN; + Unlock(); + break; + + case RAllocator::EMarkStart: + __DEBUG_ONLY(DoMarkStart()); + break; + + case RAllocator::EMarkEnd: + __DEBUG_ONLY( r = DoMarkEnd((TInt)a1) ); + break; + + case RAllocator::ECheck: + r = DoCheckHeap((SCheckInfo*)a1); + break; + + case RAllocator::ESetFail: + __DEBUG_ONLY(DoSetAllocFail((TAllocFail)(TInt)a1, (TInt)a2)); + break; + +#ifdef SYMBIAN4_DEBUG_FUNCTIONS_SUPPORTED + case RAllocator::EGetFail: + __DEBUG_ONLY(r = iFailType); + break; +#endif // SYMBIAN4_DEBUG_FUNCTIONS_SUPPORTED + + case RAllocator::ESetBurstFail: +#if _DEBUG + { + SRAllocatorBurstFail* fail = (SRAllocatorBurstFail*) a2; + DoSetAllocFail((TAllocFail)(TInt)a1, fail->iRate, fail->iBurst); + } +#endif + break; + + case RAllocator::ECheckFailure: + // iRand will be incremented for each EFailNext, EBurstFailNext, + // EDeterministic and EBurstDeterministic failure. + r = iRand; + break; + + case RAllocator::ECopyDebugInfo: + { + TInt nestingLevel = ((SDebugCell*)a1)[-1].nestingLevel; + ((SDebugCell*)a2)[-1].nestingLevel = nestingLevel; + break; + } + +#ifdef SYMBIAN4_DEBUG_FUNCTIONS_SUPPORTED + case RAllocator::EGetSize: + { + r = iChunkSize - sizeof(RHybridHeap); + break; + } + + case RAllocator::EGetMaxLength: + { + r = iMaxLength; + break; + } + + case RAllocator::EGetBase: + { + *(TAny**)a1 = iBase; + break; + } + + case RAllocator::EAlignInteger: + { + r = _ALIGN_UP((TInt)a1, iAlign); + break; + } + + case RAllocator::EAlignAddr: + { + *(TAny**)a2 = (TAny*)_ALIGN_UP((TLinAddr)a1, iAlign); + break; + } + + case RHybridHeap::EWalk: + struct HeapInfo hinfo; + SWalkInfo winfo; + Lock(); + winfo.iFunction = (TWalkFunc)a1; + winfo.iParam = a2; + winfo.iHeap = (RHybridHeap*)this; + GetInfo(&hinfo, &winfo); + Unlock(); + break; + +#ifndef __KERNEL_MODE__ + + case RHybridHeap::EHybridHeap: + { + if ( !a1 ) + return KErrGeneral; + STestCommand* cmd = (STestCommand*)a1; + switch ( cmd->iCommand ) + { + case EGetConfig: + cmd->iConfig.iSlabBits = iSlabConfigBits; + cmd->iConfig.iDelayedSlabThreshold = iPageThreshold; + cmd->iConfig.iPagePower = iPageThreshold; + break; + + case ESetConfig: + // + // New configuration data for slab and page allocator. + // Reset heap to get data into use + // +#if USE_HYBRID_HEAP + iSlabConfigBits = cmd->iConfig.iSlabBits & 0x3fff; + iSlabInitThreshold = cmd->iConfig.iDelayedSlabThreshold; + iPageThreshold = (cmd->iConfig.iPagePower & 0x1f); + Reset(); +#endif + break; + + case EHeapMetaData: + cmd->iData = this; + break; + + case ETestData: + iTestData = cmd->iData; + break; + + default: + return KErrNotSupported; + + } + + break; + } +#endif // __KERNEL_MODE +#endif // SYMBIAN4_DEBUG_FUNCTIONS_SUPPORTED + + default: + return KErrNotSupported; + + } + return r; +} + +void RHybridHeap::Walk(SWalkInfo* aInfo, TAny* aBfr, TInt aLth, TCellType aBfrType, TAllocatorType aAllocatorType) +{ + // + // This function is always called from RHybridHeap::GetInfo. + // Actual walk function is called if SWalkInfo pointer is defined + // + // + if ( aInfo ) + { +#ifdef __KERNEL_MODE__ + (void)aAllocatorType; +#if defined(_DEBUG) + if ( aBfrType == EGoodAllocatedCell ) + aInfo->iFunction(aInfo->iParam, aBfrType, ((TUint8*)aBfr+EDebugHdrSize), (aLth-EDebugHdrSize) ); + else + aInfo->iFunction(aInfo->iParam, aBfrType, aBfr, aLth ); +#else + aInfo->iFunction(aInfo->iParam, aBfrType, aBfr, aLth ); +#endif + +#else // __KERNEL_MODE__ + + if ( aAllocatorType & (EFullSlab + EPartialFullSlab + EEmptySlab + ESlabSpare) ) + { + if ( aInfo->iHeap ) + { + TUint32 dummy; + TInt npages; + aInfo->iHeap->DoCheckSlab((slab*)aBfr, aAllocatorType); + __HEAP_CORRUPTED_TEST_STATIC(aInfo->iHeap->CheckBitmap(Floor(aBfr, PAGESIZE), PAGESIZE, dummy, npages), + aInfo->iHeap, ETHeapBadCellAddress, aBfr, aLth); + } + if ( aAllocatorType & EPartialFullSlab ) + WalkPartialFullSlab(aInfo, (slab*)aBfr, aBfrType, aLth); + else if ( aAllocatorType & EFullSlab ) + WalkFullSlab(aInfo, (slab*)aBfr, aBfrType, aLth); + } +#if defined(_DEBUG) + else if ( aBfrType == EGoodAllocatedCell ) + aInfo->iFunction(aInfo->iParam, aBfrType, ((TUint8*)aBfr+EDebugHdrSize), (aLth-EDebugHdrSize) ); + else + aInfo->iFunction(aInfo->iParam, aBfrType, aBfr, aLth ); +#else + else + aInfo->iFunction(aInfo->iParam, aBfrType, aBfr, aLth ); +#endif + +#endif // __KERNEL_MODE + } +} + +#ifndef __KERNEL_MODE__ +void RHybridHeap::WalkPartialFullSlab(SWalkInfo* aInfo, slab* aSlab, TCellType /*aBfrType*/, TInt /*aLth*/) +{ + if ( aInfo ) + { + // + // Build bitmap of free buffers in the partial full slab + // + TUint32 bitmap[4]; + __HEAP_CORRUPTED_TEST_STATIC( (aInfo->iHeap != NULL), aInfo->iHeap, ETHeapBadCellAddress, 0, aSlab); + aInfo->iHeap->BuildPartialSlabBitmap(bitmap, aSlab); + // + // Find used (allocated) buffers from iPartial full slab + // + TUint32 h = aSlab->iHeader; + TUint32 size = SlabHeaderSize(h); + TUint32 count = KMaxSlabPayload / size; // Total buffer count in slab + TUint32 i = 0; + TUint32 ix = 0; + TUint32 bit = 1; + + while ( i < count ) + { + + if ( bitmap[ix] & bit ) + { + aInfo->iFunction(aInfo->iParam, EGoodFreeCell, &aSlab->iPayload[i*size], size ); + } + else + { +#if defined(_DEBUG) + aInfo->iFunction(aInfo->iParam, EGoodAllocatedCell, (&aSlab->iPayload[i*size]+EDebugHdrSize), (size-EDebugHdrSize) ); +#else + aInfo->iFunction(aInfo->iParam, EGoodAllocatedCell, &aSlab->iPayload[i*size], size ); +#endif + } + bit <<= 1; + if ( bit == 0 ) + { + bit = 1; + ix ++; + } + + i ++; + } + } + +} + +void RHybridHeap::WalkFullSlab(SWalkInfo* aInfo, slab* aSlab, TCellType aBfrType, TInt /*aLth*/) +{ + if ( aInfo ) + { + TUint32 h = aSlab->iHeader; + TUint32 size = SlabHeaderSize(h); + TUint32 count = (SlabHeaderUsedm4(h) + 4) / size; + TUint32 i = 0; + while ( i < count ) + { +#if defined(_DEBUG) + if ( aBfrType == EGoodAllocatedCell ) + aInfo->iFunction(aInfo->iParam, aBfrType, (&aSlab->iPayload[i*size]+EDebugHdrSize), (size-EDebugHdrSize) ); + else + aInfo->iFunction(aInfo->iParam, aBfrType, &aSlab->iPayload[i*size], size ); +#else + aInfo->iFunction(aInfo->iParam, aBfrType, &aSlab->iPayload[i*size], size ); +#endif + i ++; + } + } +} + +void RHybridHeap::BuildPartialSlabBitmap(TUint32* aBitmap, slab* aSlab, TAny* aBfr) +{ + // + // Build a bitmap of free buffers in a partial full slab + // + TInt i; + TUint32 bit = 0; + TUint32 index; + TUint32 h = aSlab->iHeader; + TUint32 used = SlabHeaderUsedm4(h)+4; + TUint32 size = SlabHeaderSize(h); + TInt count = (KMaxSlabPayload / size); + TInt free_count = count - (used / size); // Total free buffer count in slab + aBitmap[0] = 0, aBitmap[1] = 0, aBitmap[2] = 0, aBitmap[3] = 0; + TUint32 offs = (h & 0xff) << 2; + + // + // Process first buffer in partial slab free buffer chain + // + while ( offs ) + { + unsigned char* p = (unsigned char*)Offset(aSlab, offs); + __HEAP_CORRUPTED_TEST( (sizeof(slabhdr) <= offs), ETHeapBadCellAddress, p, aSlab); + offs -= sizeof(slabhdr); + __HEAP_CORRUPTED_TEST( (offs % size == 0), ETHeapBadCellAddress, p, aSlab); + index = (offs / size); // Bit index in bitmap + i = 0; + while ( i < 4 ) + { + if ( index < 32 ) + { + bit = (1 << index); + break; + } + index -= 32; + i ++; + } + + __HEAP_CORRUPTED_TEST( ((aBitmap[i] & bit) == 0), ETHeapBadCellAddress, p, aSlab); // Buffer already in chain + + aBitmap[i] |= bit; + free_count --; + offs = ((unsigned)*p) << 2; // Next in free chain + } + + __HEAP_CORRUPTED_TEST( (free_count >= 0), ETHeapBadCellAddress, aBfr, aSlab); // free buffer count/size mismatch + // + // Process next rest of the free buffers which are in the + // wilderness (at end of the slab) + // + index = count - 1; + i = index / 32; + index = index % 32; + while ( free_count && (i >= 0)) + { + bit = (1 << index); + __HEAP_CORRUPTED_TEST( ((aBitmap[i] & bit) == 0), ETHeapBadCellAddress, aBfr, aSlab); // Buffer already in chain + aBitmap[i] |= bit; + if ( index ) + index --; + else + { + index = 31; + i --; + } + free_count --; + } + + if ( aBfr ) // Assure that specified buffer does NOT exist in partial slab free buffer chain + { + offs = LowBits(aBfr, SLABSIZE); + __HEAP_CORRUPTED_TEST( (sizeof(slabhdr) <= offs), ETHeapBadCellAddress, aBfr, aSlab); + offs -= sizeof(slabhdr); + __HEAP_CORRUPTED_TEST( ((offs % size) == 0), ETHeapBadCellAddress, aBfr, aSlab); + index = (offs / size); // Bit index in bitmap + i = 0; + while ( i < 4 ) + { + if ( index < 32 ) + { + bit = (1 << index); + break; + } + index -= 32; + i ++; + } + __HEAP_CORRUPTED_TEST( ((aBitmap[i] & bit) == 0), ETHeapBadCellAddress, aBfr, aSlab); // Buffer already in chain + } +} + +#endif // __KERNEL_MODE__ + +void RHybridHeap::WalkCheckCell(TAny* aPtr, TCellType aType, TAny* aCell, TInt aLen) +{ + (void)aCell; + SHeapCellInfo& info = *(SHeapCellInfo*)aPtr; + switch(aType) + { + case EGoodAllocatedCell: + { + ++info.iTotalAlloc; + info.iTotalAllocSize += aLen; +#if defined(_DEBUG) + RHybridHeap& h = *info.iHeap; + SDebugCell* DbgCell = (SDebugCell*)((TUint8*)aCell-EDebugHdrSize); + if ( DbgCell->nestingLevel == h.iNestingLevel ) + { + if (++info.iLevelAlloc==1) + info.iStranded = DbgCell; +#ifdef __KERNEL_MODE__ + if (KDebugNum(KSERVER) || KDebugNum(KTESTFAST)) + { + Kern::Printf("LEAKED KERNEL HEAP CELL @ %08x : len=%d", aCell, aLen); + TLinAddr base = ((TLinAddr)aCell)&~0x0f; + TLinAddr end = ((TLinAddr)aCell)+(TLinAddr)aLen; + while(base<end) + { + const TUint32* p = (const TUint32*)base; + Kern::Printf("%08x: %08x %08x %08x %08x", p, p[0], p[1], p[2], p[3]); + base += 16; + } + } +#endif + } +#endif + break; + } + case EGoodFreeCell: + ++info.iTotalFree; + break; + case EBadAllocatedCellSize: + HEAP_PANIC(ETHeapBadAllocatedCellSize); + case EBadAllocatedCellAddress: + HEAP_PANIC(ETHeapBadAllocatedCellAddress); + case EBadFreeCellAddress: + HEAP_PANIC(ETHeapBadFreeCellAddress); + case EBadFreeCellSize: + HEAP_PANIC(ETHeapBadFreeCellSize); + default: + HEAP_PANIC(ETHeapWalkBadCellType); + } +} + + +TInt RHybridHeap::DoCheckHeap(SCheckInfo* aInfo) +{ + (void)aInfo; + SHeapCellInfo info; + memclr(&info, sizeof(info)); + info.iHeap = this; + struct HeapInfo hinfo; + SWalkInfo winfo; + Lock(); + DoCheckMallocState(GM); // Check DL heap internal structure +#ifndef __KERNEL_MODE__ + TUint32 dummy; + TInt npages; + __HEAP_CORRUPTED_TEST(CheckBitmap(NULL, 0, dummy, npages), ETHeapBadCellAddress, this, 0); // Check page allocator buffers + DoCheckSlabTrees(); + DoCheckCommittedSize(npages, GM); +#endif + winfo.iFunction = WalkCheckCell; + winfo.iParam = &info; + winfo.iHeap = (RHybridHeap*)this; + GetInfo(&hinfo, &winfo); + Unlock(); + +#if defined(_DEBUG) + if (!aInfo) + return KErrNone; + TInt expected = aInfo->iCount; + TInt actual = aInfo->iAll ? info.iTotalAlloc : info.iLevelAlloc; + if (actual!=expected && !iTestData) + { +#ifdef __KERNEL_MODE__ + Kern::Fault("KERN-ALLOC COUNT", (expected<<16)|actual ); +#else + User::Panic(_L("ALLOC COUNT"), (expected<<16)|actual ); +#endif + } +#endif + return KErrNone; +} + +#ifdef _DEBUG +void RHybridHeap::DoMarkStart() +{ + if (iNestingLevel==0) + iAllocCount=0; + iNestingLevel++; +} + +TUint32 RHybridHeap::DoMarkEnd(TInt aExpected) +{ + if (iNestingLevel==0) + return 0; + SHeapCellInfo info; + SHeapCellInfo* p = iTestData ? (SHeapCellInfo*)iTestData : &info; + memclr(p, sizeof(info)); + p->iHeap = this; + struct HeapInfo hinfo; + SWalkInfo winfo; + Lock(); + winfo.iFunction = WalkCheckCell; + winfo.iParam = p; + winfo.iHeap = (RHybridHeap*)this; + GetInfo(&hinfo, &winfo); + Unlock(); + + if (p->iLevelAlloc != aExpected && !iTestData) + return (TUint32)(p->iStranded + 1); + if (--iNestingLevel == 0) + iAllocCount = 0; + return 0; +} + +void RHybridHeap::DoSetAllocFail(TAllocFail aType, TInt aRate) +{// Default to a burst mode of 1, as aType may be a burst type. + DoSetAllocFail(aType, aRate, 1); +} + +void ResetAllocCellLevels(TAny* aPtr, RHybridHeap::TCellType aType, TAny* aCell, TInt aLen) +{ + (void)aPtr; + (void)aLen; + + if (aType == RHybridHeap::EGoodAllocatedCell) + { + RHybridHeap::SDebugCell* DbgCell = (RHybridHeap::SDebugCell*)((TUint8*)aCell-RHeap::EDebugHdrSize); + DbgCell->nestingLevel = 0; + } +} + +// Don't change as the ETHeapBadDebugFailParameter check below and the API +// documentation rely on this being 16 for RHybridHeap. +LOCAL_D const TInt KBurstFailRateShift = 16; +LOCAL_D const TInt KBurstFailRateMask = (1 << KBurstFailRateShift) - 1; + +void RHybridHeap::DoSetAllocFail(TAllocFail aType, TInt aRate, TUint aBurst) +{ + if (aType==EReset) + { + // reset levels of all allocated cells to 0 + // this should prevent subsequent tests failing unnecessarily + iFailed = EFalse; // Reset for ECheckFailure relies on this. + struct HeapInfo hinfo; + SWalkInfo winfo; + Lock(); + winfo.iFunction = (TWalkFunc)&ResetAllocCellLevels; + winfo.iParam = NULL; + winfo.iHeap = (RHybridHeap*)this; + GetInfo(&hinfo, &winfo); + Unlock(); + // reset heap allocation mark as well + iNestingLevel=0; + iAllocCount=0; + aType=ENone; + } + + switch (aType) + { + case EBurstRandom: + case EBurstTrueRandom: + case EBurstDeterministic: + case EBurstFailNext: + // If the fail type is a burst type then iFailRate is split in 2: + // the 16 lsbs are the fail rate and the 16 msbs are the burst length. + if (TUint(aRate) > (TUint)KMaxTUint16 || aBurst > KMaxTUint16) + HEAP_PANIC(ETHeapBadDebugFailParameter); + + iFailed = EFalse; + iFailType = aType; + iFailRate = (aRate == 0) ? 1 : aRate; + iFailAllocCount = -iFailRate; + iFailRate = iFailRate | (aBurst << KBurstFailRateShift); + break; + + default: + iFailed = EFalse; + iFailType = aType; + iFailRate = (aRate == 0) ? 1 : aRate; // A rate of <1 is meaningless + iFailAllocCount = 0; + break; + } + + // Set up iRand for either: + // - random seed value, or + // - a count of the number of failures so far. + iRand = 0; +#ifndef __KERNEL_MODE__ + switch (iFailType) + { + case ETrueRandom: + case EBurstTrueRandom: + { + TTime time; + time.HomeTime(); + TInt64 seed = time.Int64(); + iRand = Math::Rand(seed); + break; + } + case ERandom: + case EBurstRandom: + { + TInt64 seed = 12345; + iRand = Math::Rand(seed); + break; + } + default: + break; + } +#endif +} + +TBool RHybridHeap::CheckForSimulatedAllocFail() +// +// Check to see if the user has requested simulated alloc failure, and if so possibly +// Return ETrue indicating a failure. +// +{ + // For burst mode failures iFailRate is shared + TUint16 rate = (TUint16)(iFailRate & KBurstFailRateMask); + TUint16 burst = (TUint16)(iFailRate >> KBurstFailRateShift); + TBool r = EFalse; + switch (iFailType) + { +#ifndef __KERNEL_MODE__ + case ERandom: + case ETrueRandom: + if (++iFailAllocCount>=iFailRate) + { + iFailAllocCount=0; + if (!iFailed) // haven't failed yet after iFailRate allocations so fail now + return(ETrue); + iFailed=EFalse; + } + else + { + if (!iFailed) + { + TInt64 seed=iRand; + iRand=Math::Rand(seed); + if (iRand%iFailRate==0) + { + iFailed=ETrue; + return(ETrue); + } + } + } + break; + + case EBurstRandom: + case EBurstTrueRandom: + if (++iFailAllocCount < 0) + { + // We haven't started failing yet so should we now? + TInt64 seed = iRand; + iRand = Math::Rand(seed); + if (iRand % rate == 0) + {// Fail now. Reset iFailAllocCount so we fail burst times + iFailAllocCount = 0; + r = ETrue; + } + } + else + { + if (iFailAllocCount < burst) + {// Keep failing for burst times + r = ETrue; + } + else + {// We've now failed burst times so start again. + iFailAllocCount = -(rate - 1); + } + } + break; +#endif + case EDeterministic: + if (++iFailAllocCount%iFailRate==0) + { + r=ETrue; + iRand++; // Keep count of how many times we have failed + } + break; + + case EBurstDeterministic: + // This will fail burst number of times, every rate attempts. + if (++iFailAllocCount >= 0) + { + if (iFailAllocCount == burst - 1) + {// This is the burst time we have failed so make it the last by + // reseting counts so we next fail after rate attempts. + iFailAllocCount = -rate; + } + r = ETrue; + iRand++; // Keep count of how many times we have failed + } + break; + + case EFailNext: + if ((++iFailAllocCount%iFailRate)==0) + { + iFailType=ENone; + r=ETrue; + iRand++; // Keep count of how many times we have failed + } + break; + + case EBurstFailNext: + if (++iFailAllocCount >= 0) + { + if (iFailAllocCount == burst - 1) + {// This is the burst time we have failed so make it the last. + iFailType = ENone; + } + r = ETrue; + iRand++; // Keep count of how many times we have failed + } + break; + + default: + break; + } + return r; +} + +#endif // DEBUG + +// +// Methods for Doug Lea allocator detailed check +// + +void RHybridHeap::DoCheckAnyChunk(mstate m, mchunkptr p) +{ + __HEAP_CORRUPTED_TEST(((IS_ALIGNED(CHUNK2MEM(p))) || (p->iHead == FENCEPOST_HEAD)), ETHeapBadCellAddress, p, 0); + (void)m; +} + +/* Check properties of iTop chunk */ +void RHybridHeap::DoCheckTopChunk(mstate m, mchunkptr p) +{ + msegmentptr sp = &m->iSeg; + size_t sz = CHUNKSIZE(p); + __HEAP_CORRUPTED_TEST((sp != 0), ETHeapBadCellAddress, p, 0); + __HEAP_CORRUPTED_TEST(((IS_ALIGNED(CHUNK2MEM(p))) || (p->iHead == FENCEPOST_HEAD)), ETHeapBadCellAddress, p,0); + __HEAP_CORRUPTED_TEST((sz == m->iTopSize), ETHeapBadCellAddress,p,0); + __HEAP_CORRUPTED_TEST((sz > 0), ETHeapBadCellAddress,p,0); + __HEAP_CORRUPTED_TEST((sz == ((sp->iBase + sp->iSize) - (TUint8*)p) - TOP_FOOT_SIZE), ETHeapBadCellAddress,p,0); + __HEAP_CORRUPTED_TEST((PINUSE(p)), ETHeapBadCellAddress,p,0); + __HEAP_CORRUPTED_TEST((!NEXT_PINUSE(p)), ETHeapBadCellAddress,p,0); +} + +/* Check properties of inuse chunks */ +void RHybridHeap::DoCheckInuseChunk(mstate m, mchunkptr p) +{ + DoCheckAnyChunk(m, p); + __HEAP_CORRUPTED_TEST((CINUSE(p)), ETHeapBadCellAddress,p,0); + __HEAP_CORRUPTED_TEST((NEXT_PINUSE(p)), ETHeapBadCellAddress,p,0); + /* If not PINUSE and not mmapped, previous chunk has OK offset */ + __HEAP_CORRUPTED_TEST((PINUSE(p) || NEXT_CHUNK(PREV_CHUNK(p)) == p), ETHeapBadCellAddress,p,0); +} + +/* Check properties of free chunks */ +void RHybridHeap::DoCheckFreeChunk(mstate m, mchunkptr p) +{ + size_t sz = p->iHead & ~(PINUSE_BIT|CINUSE_BIT); + mchunkptr next = CHUNK_PLUS_OFFSET(p, sz); + DoCheckAnyChunk(m, p); + __HEAP_CORRUPTED_TEST((!CINUSE(p)), ETHeapBadCellAddress,p,0); + __HEAP_CORRUPTED_TEST((!NEXT_PINUSE(p)), ETHeapBadCellAddress,p,0); + if (p != m->iDv && p != m->iTop) + { + if (sz >= MIN_CHUNK_SIZE) + { + __HEAP_CORRUPTED_TEST(((sz & CHUNK_ALIGN_MASK) == 0), ETHeapBadCellAddress,p,0); + __HEAP_CORRUPTED_TEST((IS_ALIGNED(CHUNK2MEM(p))), ETHeapBadCellAddress,p,0); + __HEAP_CORRUPTED_TEST((next->iPrevFoot == sz), ETHeapBadCellAddress,p,0); + __HEAP_CORRUPTED_TEST((PINUSE(p)), ETHeapBadCellAddress,p,0); + __HEAP_CORRUPTED_TEST( (next == m->iTop || CINUSE(next)), ETHeapBadCellAddress,p,0); + __HEAP_CORRUPTED_TEST((p->iFd->iBk == p), ETHeapBadCellAddress,p,0); + __HEAP_CORRUPTED_TEST((p->iBk->iFd == p), ETHeapBadCellAddress,p,0); + } + else /* markers are always of size SIZE_T_SIZE */ + __HEAP_CORRUPTED_TEST((sz == SIZE_T_SIZE), ETHeapBadCellAddress,p,0); + } +} + +/* Check properties of malloced chunks at the point they are malloced */ +void RHybridHeap::DoCheckMallocedChunk(mstate m, void* mem, size_t s) +{ + if (mem != 0) + { + mchunkptr p = MEM2CHUNK(mem); + size_t sz = p->iHead & ~(PINUSE_BIT|CINUSE_BIT); + DoCheckInuseChunk(m, p); + __HEAP_CORRUPTED_TEST(((sz & CHUNK_ALIGN_MASK) == 0), ETHeapBadCellAddress,p,0); + __HEAP_CORRUPTED_TEST((sz >= MIN_CHUNK_SIZE), ETHeapBadCellAddress,p,0); + __HEAP_CORRUPTED_TEST((sz >= s), ETHeapBadCellAddress,p,0); + /* unless mmapped, size is less than MIN_CHUNK_SIZE more than request */ + __HEAP_CORRUPTED_TEST((sz < (s + MIN_CHUNK_SIZE)), ETHeapBadCellAddress,p,0); + } +} + +/* Check a tree and its subtrees. */ +void RHybridHeap::DoCheckTree(mstate m, tchunkptr t) +{ + tchunkptr head = 0; + tchunkptr u = t; + bindex_t tindex = t->iIndex; + size_t tsize = CHUNKSIZE(t); + bindex_t idx; + DoComputeTreeIndex(tsize, idx); + __HEAP_CORRUPTED_TEST((tindex == idx), ETHeapBadCellAddress,u,0); + __HEAP_CORRUPTED_TEST((tsize >= MIN_LARGE_SIZE), ETHeapBadCellAddress,u,0); + __HEAP_CORRUPTED_TEST((tsize >= MINSIZE_FOR_TREE_INDEX(idx)), ETHeapBadCellAddress,u,0); + __HEAP_CORRUPTED_TEST(((idx == NTREEBINS-1) || (tsize < MINSIZE_FOR_TREE_INDEX((idx+1)))), ETHeapBadCellAddress,u,0); + + do + { /* traverse through chain of same-sized nodes */ + DoCheckAnyChunk(m, ((mchunkptr)u)); + __HEAP_CORRUPTED_TEST((u->iIndex == tindex), ETHeapBadCellAddress,u,0); + __HEAP_CORRUPTED_TEST((CHUNKSIZE(u) == tsize), ETHeapBadCellAddress,u,0); + __HEAP_CORRUPTED_TEST((!CINUSE(u)), ETHeapBadCellAddress,u,0); + __HEAP_CORRUPTED_TEST((!NEXT_PINUSE(u)), ETHeapBadCellAddress,u,0); + __HEAP_CORRUPTED_TEST((u->iFd->iBk == u), ETHeapBadCellAddress,u,0); + __HEAP_CORRUPTED_TEST((u->iBk->iFd == u), ETHeapBadCellAddress,u,0); + if (u->iParent == 0) + { + __HEAP_CORRUPTED_TEST((u->iChild[0] == 0), ETHeapBadCellAddress,u,0); + __HEAP_CORRUPTED_TEST((u->iChild[1] == 0), ETHeapBadCellAddress,u,0); + } + else + { + __HEAP_CORRUPTED_TEST((head == 0), ETHeapBadCellAddress,u,0); /* only one node on chain has iParent */ + head = u; + __HEAP_CORRUPTED_TEST((u->iParent != u), ETHeapBadCellAddress,u,0); + __HEAP_CORRUPTED_TEST( (u->iParent->iChild[0] == u || + u->iParent->iChild[1] == u || + *((tbinptr*)(u->iParent)) == u), ETHeapBadCellAddress,u,0); + if (u->iChild[0] != 0) + { + __HEAP_CORRUPTED_TEST((u->iChild[0]->iParent == u), ETHeapBadCellAddress,u,0); + __HEAP_CORRUPTED_TEST((u->iChild[0] != u), ETHeapBadCellAddress,u,0); + DoCheckTree(m, u->iChild[0]); + } + if (u->iChild[1] != 0) + { + __HEAP_CORRUPTED_TEST((u->iChild[1]->iParent == u), ETHeapBadCellAddress,u,0); + __HEAP_CORRUPTED_TEST((u->iChild[1] != u), ETHeapBadCellAddress,u,0); + DoCheckTree(m, u->iChild[1]); + } + if (u->iChild[0] != 0 && u->iChild[1] != 0) + { + __HEAP_CORRUPTED_TEST((CHUNKSIZE(u->iChild[0]) < CHUNKSIZE(u->iChild[1])), ETHeapBadCellAddress,u,0); + } + } + u = u->iFd; + } + while (u != t); + __HEAP_CORRUPTED_TEST((head != 0), ETHeapBadCellAddress,u,0); +} + +/* Check all the chunks in a treebin. */ +void RHybridHeap::DoCheckTreebin(mstate m, bindex_t i) +{ + tbinptr* tb = TREEBIN_AT(m, i); + tchunkptr t = *tb; + int empty = (m->iTreeMap & (1U << i)) == 0; + if (t == 0) + __HEAP_CORRUPTED_TEST((empty), ETHeapBadCellAddress,t,0); + if (!empty) + DoCheckTree(m, t); +} + +/* Check all the chunks in a smallbin. */ +void RHybridHeap::DoCheckSmallbin(mstate m, bindex_t i) +{ + sbinptr b = SMALLBIN_AT(m, i); + mchunkptr p = b->iBk; + unsigned int empty = (m->iSmallMap & (1U << i)) == 0; + if (p == b) + __HEAP_CORRUPTED_TEST((empty), ETHeapBadCellAddress,p,0); + if (!empty) + { + for (; p != b; p = p->iBk) + { + size_t size = CHUNKSIZE(p); + mchunkptr q; + /* each chunk claims to be free */ + DoCheckFreeChunk(m, p); + /* chunk belongs in bin */ + __HEAP_CORRUPTED_TEST((SMALL_INDEX(size) == i), ETHeapBadCellAddress,p,0); + __HEAP_CORRUPTED_TEST((p->iBk == b || CHUNKSIZE(p->iBk) == CHUNKSIZE(p)), ETHeapBadCellAddress,p,0); + /* chunk is followed by an inuse chunk */ + q = NEXT_CHUNK(p); + if (q->iHead != FENCEPOST_HEAD) + DoCheckInuseChunk(m, q); + } + } +} + +/* Find x in a bin. Used in other check functions. */ +TInt RHybridHeap::BinFind(mstate m, mchunkptr x) +{ + size_t size = CHUNKSIZE(x); + if (IS_SMALL(size)) + { + bindex_t sidx = SMALL_INDEX(size); + sbinptr b = SMALLBIN_AT(m, sidx); + if (SMALLMAP_IS_MARKED(m, sidx)) + { + mchunkptr p = b; + do + { + if (p == x) + return 1; + } + while ((p = p->iFd) != b); + } + } + else + { + bindex_t tidx; + DoComputeTreeIndex(size, tidx); + if (TREEMAP_IS_MARKED(m, tidx)) + { + tchunkptr t = *TREEBIN_AT(m, tidx); + size_t sizebits = size << LEFTSHIFT_FOR_TREE_INDEX(tidx); + while (t != 0 && CHUNKSIZE(t) != size) + { + t = t->iChild[(sizebits >> (SIZE_T_BITSIZE-SIZE_T_ONE)) & 1]; + sizebits <<= 1; + } + if (t != 0) + { + tchunkptr u = t; + do + { + if (u == (tchunkptr)x) + return 1; + } + while ((u = u->iFd) != t); + } + } + } + return 0; +} + +/* Traverse each chunk and check it; return total */ +size_t RHybridHeap::TraverseAndCheck(mstate m) +{ + size_t sum = 0; + msegmentptr s = &m->iSeg; + sum += m->iTopSize + TOP_FOOT_SIZE; + mchunkptr q = ALIGN_AS_CHUNK(s->iBase); + mchunkptr lastq = 0; + __HEAP_CORRUPTED_TEST((PINUSE(q)), ETHeapBadCellAddress,q,0); + while (q != m->iTop && q->iHead != FENCEPOST_HEAD) + { + sum += CHUNKSIZE(q); + if (CINUSE(q)) + { + __HEAP_CORRUPTED_TEST((!BinFind(m, q)), ETHeapBadCellAddress,q,0); + DoCheckInuseChunk(m, q); + } + else + { + __HEAP_CORRUPTED_TEST((q == m->iDv || BinFind(m, q)), ETHeapBadCellAddress,q,0); + __HEAP_CORRUPTED_TEST((lastq == 0 || CINUSE(lastq)), ETHeapBadCellAddress,q,0); /* Not 2 consecutive free */ + DoCheckFreeChunk(m, q); + } + lastq = q; + q = NEXT_CHUNK(q); + } + return sum; +} + +/* Check all properties of malloc_state. */ +void RHybridHeap::DoCheckMallocState(mstate m) +{ + bindex_t i; +// size_t total; + /* check bins */ + for (i = 0; i < NSMALLBINS; ++i) + DoCheckSmallbin(m, i); + for (i = 0; i < NTREEBINS; ++i) + DoCheckTreebin(m, i); + + if (m->iDvSize != 0) + { /* check iDv chunk */ + DoCheckAnyChunk(m, m->iDv); + __HEAP_CORRUPTED_TEST((m->iDvSize == CHUNKSIZE(m->iDv)), ETHeapBadCellAddress,m->iDv,0); + __HEAP_CORRUPTED_TEST((m->iDvSize >= MIN_CHUNK_SIZE), ETHeapBadCellAddress,m->iDv,0); + __HEAP_CORRUPTED_TEST((BinFind(m, m->iDv) == 0), ETHeapBadCellAddress,m->iDv,0); + } + + if (m->iTop != 0) + { /* check iTop chunk */ + DoCheckTopChunk(m, m->iTop); + __HEAP_CORRUPTED_TEST((m->iTopSize == CHUNKSIZE(m->iTop)), ETHeapBadCellAddress,m->iTop,0); + __HEAP_CORRUPTED_TEST((m->iTopSize > 0), ETHeapBadCellAddress,m->iTop,0); + __HEAP_CORRUPTED_TEST((BinFind(m, m->iTop) == 0), ETHeapBadCellAddress,m->iTop,0); + } + +// total = + TraverseAndCheck(m); +} + +#ifndef __KERNEL_MODE__ +// +// Methods for Slab allocator detailed check +// +void RHybridHeap::DoCheckSlabTree(slab** aS, TBool aPartialPage) +{ + slab* s = *aS; + if (!s) + return; + + TUint size = SlabHeaderSize(s->iHeader); + slab** parent = aS; + slab** child2 = &s->iChild2; + + while ( s ) + { + __HEAP_CORRUPTED_TEST((s->iParent == parent), ETHeapBadCellAddress,s,SLABSIZE); + __HEAP_CORRUPTED_TEST((!s->iChild1 || s < s->iChild1), ETHeapBadCellAddress,s,SLABSIZE); + __HEAP_CORRUPTED_TEST((!s->iChild2 || s < s->iChild2), ETHeapBadCellAddress,s,SLABSIZE); + + if ( aPartialPage ) + { + if ( s->iChild1 ) + size = SlabHeaderSize(s->iChild1->iHeader); + } + else + { + __HEAP_CORRUPTED_TEST((SlabHeaderSize(s->iHeader) == size), ETHeapBadCellAddress,s,SLABSIZE); + } + parent = &s->iChild1; + s = s->iChild1; + + } + + parent = child2; + s = *child2; + + while ( s ) + { + __HEAP_CORRUPTED_TEST((s->iParent == parent), ETHeapBadCellAddress,s,SLABSIZE); + __HEAP_CORRUPTED_TEST((!s->iChild1 || s < s->iChild1), ETHeapBadCellAddress,s,SLABSIZE); + __HEAP_CORRUPTED_TEST((!s->iChild2 || s < s->iChild2), ETHeapBadCellAddress,s,SLABSIZE); + + if ( aPartialPage ) + { + if ( s->iChild2 ) + size = SlabHeaderSize(s->iChild2->iHeader); + } + else + { + __HEAP_CORRUPTED_TEST((SlabHeaderSize(s->iHeader) == size), ETHeapBadCellAddress,s,SLABSIZE); + } + parent = &s->iChild2; + s = s->iChild2; + + } + +} + +void RHybridHeap::DoCheckSlabTrees() +{ + for (TInt i = 0; i < (MAXSLABSIZE>>2); ++i) + DoCheckSlabTree(&iSlabAlloc[i].iPartial, EFalse); + DoCheckSlabTree(&iPartialPage, ETrue); +} + +void RHybridHeap::DoCheckSlab(slab* aSlab, TAllocatorType aSlabType, TAny* aBfr) +{ + if ( (aSlabType == ESlabSpare) || (aSlabType == EEmptySlab) ) + return; + + unsigned h = aSlab->iHeader; + __HEAP_CORRUPTED_TEST((ZEROBITS(h)), ETHeapBadCellAddress,aBfr,aSlab); + unsigned used = SlabHeaderUsedm4(h)+4; + unsigned size = SlabHeaderSize(h); + __HEAP_CORRUPTED_TEST( (used < SLABSIZE),ETHeapBadCellAddress, aBfr, aSlab); + __HEAP_CORRUPTED_TEST( ((size > 3 ) && (size < MAXSLABSIZE)), ETHeapBadCellAddress,aBfr,aSlab); + unsigned count = 0; + + switch ( aSlabType ) + { + case EFullSlab: + count = (KMaxSlabPayload / size ); + __HEAP_CORRUPTED_TEST((used == count*size), ETHeapBadCellAddress,aBfr,aSlab); + __HEAP_CORRUPTED_TEST((HeaderFloating(h)), ETHeapBadCellAddress,aBfr,aSlab); + break; + + case EPartialFullSlab: + __HEAP_CORRUPTED_TEST(((used % size)==0),ETHeapBadCellAddress,aBfr,aSlab); + __HEAP_CORRUPTED_TEST(((SlabHeaderFree(h) == 0) || (((SlabHeaderFree(h)<<2)-sizeof(slabhdr)) % SlabHeaderSize(h) == 0)), + ETHeapBadCellAddress,aBfr,aSlab); + break; + + default: + break; + + } +} + +// +// Check that committed size in heap equals number of pages in bitmap +// plus size of Doug Lea region +// +void RHybridHeap::DoCheckCommittedSize(TInt aNPages, mstate aM) +{ + TInt total_committed = (aNPages * iPageSize) + aM->iSeg.iSize + (iBase - (TUint8*)this); + __HEAP_CORRUPTED_TEST((total_committed == iChunkSize), ETHeapBadCellAddress,total_committed,iChunkSize); +} + +#endif // __KERNEL_MODE__ + +#endif /* QT_USE_NEW_SYMBIAN_ALLOCATOR */ diff --git a/src/corelib/arch/symbian/dla_p.h b/src/corelib/arch/symbian/dla_p.h index 9d31499..519a4a2 100644 --- a/src/corelib/arch/symbian/dla_p.h +++ b/src/corelib/arch/symbian/dla_p.h @@ -1,10 +1,10 @@ /**************************************************************************** ** -** Copyright (C) 2009 Nokia Corporation and/or its subsidiary(-ies). +** Copyright (C) 2010 Nokia Corporation and/or its subsidiary(-ies). ** All rights reserved. ** Contact: Nokia Corporation (qt-info@nokia.com) ** -** This file is part of the Symbian application wrapper of the Qt Toolkit. +** This file is part of the QtCore module of the Qt Toolkit. ** ** $QT_BEGIN_LICENSE:LGPL$ ** No Commercial Usage @@ -38,12 +38,12 @@ ** $QT_END_LICENSE$ ** ****************************************************************************/ + #ifndef __DLA__ #define __DLA__ #define DEFAULT_TRIM_THRESHOLD ((size_t)4U * (size_t)1024U) -#define __SYMBIAN__ #define MSPACES 0 #define HAVE_MORECORE 1 #define MORECORE_CONTIGUOUS 1 @@ -54,7 +54,6 @@ #define USE_LOCKS 0 #define INSECURE 1 #define NO_MALLINFO 0 -#define HAVE_GETPAGESIZE #define LACKS_SYS_TYPES_H #ifndef LACKS_SYS_TYPES_H @@ -81,9 +80,9 @@ typedef unsigned int size_t; #endif /* ONLY_MSPACES */ #endif /* MSPACES */ -#ifndef MALLOC_ALIGNMENT - #define MALLOC_ALIGNMENT ((size_t)8U) -#endif /* MALLOC_ALIGNMENT */ +//#ifndef MALLOC_ALIGNMENT +// #define MALLOC_ALIGNMENT ((size_t)8U) +//#endif /* MALLOC_ALIGNMENT */ #ifndef FOOTERS #define FOOTERS 0 @@ -91,13 +90,10 @@ typedef unsigned int size_t; #ifndef ABORT // #define ABORT abort() - #define ABORT User::Invariant()// redefined so euser isn't dependant on oe +// #define ABORT User::Invariant()// redefined so euser isn't dependant on oe + #define ABORT HEAP_PANIC(ETHeapBadCellAddress) #endif /* ABORT */ -#ifndef ABORT_ON_ASSERT_FAILURE - #define ABORT_ON_ASSERT_FAILURE 1 -#endif /* ABORT_ON_ASSERT_FAILURE */ - #ifndef PROCEED_ON_ERROR #define PROCEED_ON_ERROR 0 #endif /* PROCEED_ON_ERROR */ @@ -163,7 +159,7 @@ typedef unsigned int size_t; #define DEFAULT_TRIM_THRESHOLD ((size_t)2U * (size_t)1024U * (size_t)1024U) #else /* MORECORE_CANNOT_TRIM */ #define DEFAULT_TRIM_THRESHOLD MAX_SIZE_T - #endif /* MORECORE_CANNOT_TRIM */ + #endif /* MORECORE_CANNOT_TRIM */ #endif /* DEFAULT_TRIM_THRESHOLD */ #ifndef DEFAULT_MMAP_THRESHOLD @@ -230,18 +226,17 @@ typedef unsigned int size_t; #else /* HAVE_USR_INCLUDE_MALLOC_H */ struct mallinfo { - MALLINFO_FIELD_TYPE arena; /* non-mmapped space allocated from system */ - MALLINFO_FIELD_TYPE ordblks; /* number of free chunks */ - MALLINFO_FIELD_TYPE smblks; /* always 0 */ - MALLINFO_FIELD_TYPE hblks; /* always 0 */ - MALLINFO_FIELD_TYPE hblkhd; /* space in mmapped regions */ - MALLINFO_FIELD_TYPE usmblks; /* maximum total allocated space */ - MALLINFO_FIELD_TYPE fsmblks; /* always 0 */ - MALLINFO_FIELD_TYPE uordblks; /* total allocated space */ - MALLINFO_FIELD_TYPE fordblks; /* total free space */ - MALLINFO_FIELD_TYPE keepcost; /* releasable (via malloc_trim) space */ - MALLINFO_FIELD_TYPE cellCount;/* Number of chunks allocated*/ - MALLINFO_FIELD_TYPE largestBlock; + MALLINFO_FIELD_TYPE iArena; /* non-mmapped space allocated from system */ + MALLINFO_FIELD_TYPE iOrdblks; /* number of free chunks */ + MALLINFO_FIELD_TYPE iSmblks; /* always 0 */ + MALLINFO_FIELD_TYPE iHblks; /* always 0 */ + MALLINFO_FIELD_TYPE iHblkhd; /* space in mmapped regions */ + MALLINFO_FIELD_TYPE iUsmblks; /* maximum total allocated space */ + MALLINFO_FIELD_TYPE iFsmblks; /* always 0 */ + MALLINFO_FIELD_TYPE iUordblks; /* total allocated space */ + MALLINFO_FIELD_TYPE iFordblks; /* total free space */ + MALLINFO_FIELD_TYPE iKeepcost; /* releasable (via malloc_trim) space */ + MALLINFO_FIELD_TYPE iCellCount;/* Number of chunks allocated*/ }; #endif /* HAVE_USR_INCLUDE_MALLOC_H */ @@ -251,7 +246,7 @@ struct mallinfo { typedef void* mspace; #endif /* MSPACES */ -#ifndef __SYMBIAN__ +#if 0 #include <stdio.h>/* for printing in malloc_stats */ @@ -260,23 +255,17 @@ struct mallinfo { #endif /* LACKS_ERRNO_H */ #if FOOTERS - #include <time.h> /* for magic initialization */ + #include <time.h> /* for iMagic initialization */ #endif /* FOOTERS */ #ifndef LACKS_STDLIB_H #include <stdlib.h> /* for abort() */ #endif /* LACKS_STDLIB_H */ -#ifdef DEBUG - #if ABORT_ON_ASSERT_FAILURE - #define assert(x) if(!(x)) ABORT - #else /* ABORT_ON_ASSERT_FAILURE */ - #include <assert.h> - #endif /* ABORT_ON_ASSERT_FAILURE */ -#else /* DEBUG */ - #define assert(x) -#endif /* DEBUG */ - +#if !defined(ASSERT) +#define ASSERT(x) __ASSERT_DEBUG(x, HEAP_PANIC(ETHeapBadCellAddress)) +#endif + #ifndef LACKS_STRING_H #include <string.h> /* for memset etc */ #endif /* LACKS_STRING_H */ @@ -302,7 +291,7 @@ struct mallinfo { extern void* sbrk(size_t); #else /* LACKS_UNISTD_H */ #if !defined(__FreeBSD__) && !defined(__OpenBSD__) && !defined(__NetBSD__) - extern void* sbrk(ptrdiff_t); + extern void* sbrk(ptrdiff_t); /*Amod sbrk is not defined in WIN32 need to check in symbian*/ #endif /* FreeBSD etc */ #endif /* LACKS_UNISTD_H */ @@ -310,45 +299,45 @@ struct mallinfo { #endif -#define assert(x) ASSERT(x) - +/*AMOD: For MALLOC_GETPAGESIZE*/ +#if 0 // replaced with GET_PAGE_SIZE() defined in heap.cpp #ifndef WIN32 - #ifndef malloc_getpagesize + #ifndef MALLOC_GETPAGESIZE #ifdef _SC_PAGESIZE /* some SVR4 systems omit an underscore */ #ifndef _SC_PAGE_SIZE #define _SC_PAGE_SIZE _SC_PAGESIZE #endif #endif #ifdef _SC_PAGE_SIZE - #define malloc_getpagesize sysconf(_SC_PAGE_SIZE) + #define MALLOC_GETPAGESIZE sysconf(_SC_PAGE_SIZE) #else #if defined(BSD) || defined(DGUX) || defined(HAVE_GETPAGESIZE) extern size_t getpagesize(); - #define malloc_getpagesize getpagesize() + #define MALLOC_GETPAGESIZE getpagesize() #else #ifdef WIN32 /* use supplied emulation of getpagesize */ - #define malloc_getpagesize getpagesize() + #define MALLOC_GETPAGESIZE getpagesize() #else #ifndef LACKS_SYS_PARAM_H #include <sys/param.h> #endif #ifdef EXEC_PAGESIZE - #define malloc_getpagesize EXEC_PAGESIZE + #define MALLOC_GETPAGESIZE EXEC_PAGESIZE #else #ifdef NBPG #ifndef CLSIZE - #define malloc_getpagesize NBPG + #define MALLOC_GETPAGESIZE NBPG #else - #define malloc_getpagesize (NBPG * CLSIZE) + #define MALLOC_GETPAGESIZE (NBPG * CLSIZE) #endif #else #ifdef NBPC - #define malloc_getpagesize NBPC + #define MALLOC_GETPAGESIZE NBPC #else #ifdef PAGESIZE - #define malloc_getpagesize PAGESIZE + #define MALLOC_GETPAGESIZE PAGESIZE #else /* just guess */ - #define malloc_getpagesize ((size_t)4096U) + #define MALLOC_GETPAGESIZE ((size_t)4096U) #endif #endif #endif @@ -358,6 +347,8 @@ struct mallinfo { #endif #endif #endif +#endif +/*AMOD: For MALLOC_GETPAGESIZE*/ /* ------------------- size_t and alignment properties -------------------- */ @@ -379,14 +370,14 @@ struct mallinfo { #define CHUNK_ALIGN_MASK (MALLOC_ALIGNMENT - SIZE_T_ONE) /* True if address a has acceptable alignment */ -//#define is_aligned(A) (((size_t)((A)) & (CHUNK_ALIGN_MASK)) == 0) -#define is_aligned(A) (((unsigned int)((A)) & (CHUNK_ALIGN_MASK)) == 0) +//#define IS_ALIGNED(A) (((size_t)((A)) & (CHUNK_ALIGN_MASK)) == 0) +#define IS_ALIGNED(A) (((unsigned int)((A)) & (CHUNK_ALIGN_MASK)) == 0) /* the number of bytes to offset an address to align it */ -#define align_offset(A)\ +#define ALIGN_OFFSET(A)\ ((((size_t)(A) & CHUNK_ALIGN_MASK) == 0)? 0 :\ ((MALLOC_ALIGNMENT - ((size_t)(A) & CHUNK_ALIGN_MASK)) & CHUNK_ALIGN_MASK)) - + /* -------------------------- MMAP preliminaries ------------------------- */ /* @@ -415,7 +406,7 @@ struct mallinfo { #if !defined(MAP_ANONYMOUS) && defined(MAP_ANON) #define MAP_ANONYMOUS MAP_ANON #endif /* MAP_ANON */ - #ifdef MAP_ANONYMOUS + #ifdef MAP_ANONYMOUS #define MMAP_FLAGS (MAP_PRIVATE|MAP_ANONYMOUS) #define CALL_MMAP(s) mmap(0, (s), MMAP_PROT, (int)MMAP_FLAGS, -1, 0) #else /* MAP_ANONYMOUS */ @@ -463,13 +454,13 @@ struct mallinfo { #if USE_LOCKS /* When locks are defined, there are up to two global locks: - * If HAVE_MORECORE, morecore_mutex protects sequences of calls to + * If HAVE_MORECORE, iMorecoreMutex protects sequences of calls to MORECORE. In many cases sys_alloc requires two calls, that should not be interleaved with calls by other threads. This does not protect against direct calls to MORECORE by other threads not using this lock, so there is still code to cope the best we can on interference. - * magic_init_mutex ensures that mparams.magic and other + * iMagicInitMutex ensures that mparams.iMagic and other unique mparams values are initialized only once. */ #ifndef WIN32 @@ -479,20 +470,20 @@ struct mallinfo { #define INITIAL_LOCK(l) pthread_mutex_init(l, NULL) #define ACQUIRE_LOCK(l) pthread_mutex_lock(l) #define RELEASE_LOCK(l) pthread_mutex_unlock(l) - + #if HAVE_MORECORE - //static MLOCK_T morecore_mutex = PTHREAD_MUTEX_INITIALIZER; + //static MLOCK_T iMorecoreMutex = PTHREAD_MUTEX_INITIALIZER; #endif /* HAVE_MORECORE */ - //static MLOCK_T magic_init_mutex = PTHREAD_MUTEX_INITIALIZER; + //static MLOCK_T iMagicInitMutex = PTHREAD_MUTEX_INITIALIZER; #else /* WIN32 */ #define MLOCK_T long #define INITIAL_LOCK(l) *(l)=0 #define ACQUIRE_LOCK(l) win32_acquire_lock(l) #define RELEASE_LOCK(l) win32_release_lock(l) #if HAVE_MORECORE - static MLOCK_T morecore_mutex; + static MLOCK_T iMorecoreMutex; #endif /* HAVE_MORECORE */ - static MLOCK_T magic_init_mutex; + static MLOCK_T iMagicInitMutex; #endif /* WIN32 */ #define USE_LOCK_BIT (2U) #else /* USE_LOCKS */ @@ -501,19 +492,19 @@ struct mallinfo { #endif /* USE_LOCKS */ #if USE_LOCKS && HAVE_MORECORE - #define ACQUIRE_MORECORE_LOCK(M) ACQUIRE_LOCK((M->morecore_mutex)/*&morecore_mutex*/); - #define RELEASE_MORECORE_LOCK(M) RELEASE_LOCK((M->morecore_mutex)/*&morecore_mutex*/); + #define ACQUIRE_MORECORE_LOCK(M) ACQUIRE_LOCK((M->iMorecoreMutex)/*&iMorecoreMutex*/); + #define RELEASE_MORECORE_LOCK(M) RELEASE_LOCK((M->iMorecoreMutex)/*&iMorecoreMutex*/); #else /* USE_LOCKS && HAVE_MORECORE */ #define ACQUIRE_MORECORE_LOCK(M) #define RELEASE_MORECORE_LOCK(M) #endif /* USE_LOCKS && HAVE_MORECORE */ #if USE_LOCKS - /*Currently not suporting this*/ - #define ACQUIRE_MAGIC_INIT_LOCK(M) ACQUIRE_LOCK(((M)->magic_init_mutex)); + /*Currently not suporting this*/ + #define ACQUIRE_MAGIC_INIT_LOCK(M) ACQUIRE_LOCK(((M)->iMagicInitMutex)); //AMOD: changed #define ACQUIRE_MAGIC_INIT_LOCK() //#define RELEASE_MAGIC_INIT_LOCK() - #define RELEASE_MAGIC_INIT_LOCK(M) RELEASE_LOCK(((M)->magic_init_mutex)); + #define RELEASE_MAGIC_INIT_LOCK(M) RELEASE_LOCK(((M)->iMagicInitMutex)); #else /* USE_LOCKS */ #define ACQUIRE_MAGIC_INIT_LOCK(M) #define RELEASE_MAGIC_INIT_LOCK(M) @@ -521,10 +512,10 @@ struct mallinfo { /*CHUNK representation*/ struct malloc_chunk { - size_t prev_foot; /* Size of previous chunk (if free). */ - size_t head; /* Size and inuse bits. */ - struct malloc_chunk* fd; /* double links -- used only if free. */ - struct malloc_chunk* bk; + size_t iPrevFoot; /* Size of previous chunk (if free). */ + size_t iHead; /* Size and inuse bits. */ + struct malloc_chunk* iFd; /* double links -- used only if free. */ + struct malloc_chunk* iBk; }; typedef struct malloc_chunk mchunk; @@ -538,11 +529,11 @@ typedef unsigned int flag_t; /* The type of various bit flag sets */ /* ------------------- Chunks sizes and alignments ----------------------- */ #define MCHUNK_SIZE (sizeof(mchunk)) -#if FOOTERS - #define CHUNK_OVERHEAD (TWO_SIZE_T_SIZES) -#else /* FOOTERS */ - #define CHUNK_OVERHEAD (SIZE_T_SIZE) -#endif /* FOOTERS */ +//#if FOOTERS +// #define CHUNK_OVERHEAD (TWO_SIZE_T_SIZES) +//#else /* FOOTERS */ +// #define CHUNK_OVERHEAD (SIZE_T_SIZE) +//#endif /* FOOTERS */ /* MMapped chunks need a second word of overhead ... */ #define MMAP_CHUNK_OVERHEAD (TWO_SIZE_T_SIZES) @@ -553,27 +544,27 @@ typedef unsigned int flag_t; /* The type of various bit flag sets */ #define MIN_CHUNK_SIZE ((MCHUNK_SIZE + CHUNK_ALIGN_MASK) & ~CHUNK_ALIGN_MASK) /* conversion from malloc headers to user pointers, and back */ -#define chunk2mem(p) ((void*)((TUint8*)(p) + TWO_SIZE_T_SIZES)) -#define mem2chunk(mem) ((mchunkptr)((TUint8*)(mem) - TWO_SIZE_T_SIZES)) +#define CHUNK2MEM(p) ((void*)((TUint8*)(p) + TWO_SIZE_T_SIZES)) +#define MEM2CHUNK(mem) ((mchunkptr)((TUint8*)(mem) - TWO_SIZE_T_SIZES)) /* chunk associated with aligned address A */ -#define align_as_chunk(A) (mchunkptr)((A) + align_offset(chunk2mem(A))) +#define ALIGN_AS_CHUNK(A) (mchunkptr)((A) + ALIGN_OFFSET(CHUNK2MEM(A))) /* Bounds on request (not chunk) sizes. */ #define MAX_REQUEST ((-MIN_CHUNK_SIZE) << 2) #define MIN_REQUEST (MIN_CHUNK_SIZE - CHUNK_OVERHEAD - SIZE_T_ONE) /* pad request bytes into a usable size */ -#define pad_request(req) (((req) + CHUNK_OVERHEAD + CHUNK_ALIGN_MASK) & ~CHUNK_ALIGN_MASK) +#define PAD_REQUEST(req) (((req) + CHUNK_OVERHEAD + CHUNK_ALIGN_MASK) & ~CHUNK_ALIGN_MASK) /* pad request, checking for minimum (but not maximum) */ -#define request2size(req) (((req) < MIN_REQUEST)? MIN_CHUNK_SIZE : pad_request(req)) +#define REQUEST2SIZE(req) (((req) < MIN_REQUEST)? MIN_CHUNK_SIZE : PAD_REQUEST(req)) -/* ------------------ Operations on head and foot fields ----------------- */ +/* ------------------ Operations on iHead and foot fields ----------------- */ /* - The head field of a chunk is or'ed with PINUSE_BIT when previous + The iHead field of a chunk is or'ed with PINUSE_BIT when previous adjacent chunk in use, and or'ed with CINUSE_BIT if this chunk is in - use. If the chunk was obtained with mmap, the prev_foot field has + use. If the chunk was obtained with mmap, the iPrevFoot field has IS_MMAPPED_BIT set, otherwise holding the offset of the base of the mmapped region to the base of the chunk. */ @@ -584,58 +575,58 @@ typedef unsigned int flag_t; /* The type of various bit flag sets */ /* Head value for fenceposts */ #define FENCEPOST_HEAD (INUSE_BITS|SIZE_T_SIZE) -/* extraction of fields from head words */ -#define cinuse(p) ((p)->head & CINUSE_BIT) -#define pinuse(p) ((p)->head & PINUSE_BIT) -#define chunksize(p) ((p)->head & ~(INUSE_BITS)) +/* extraction of fields from iHead words */ +#define CINUSE(p) ((p)->iHead & CINUSE_BIT) +#define PINUSE(p) ((p)->iHead & PINUSE_BIT) +#define CHUNKSIZE(p) ((p)->iHead & ~(INUSE_BITS)) -#define clear_pinuse(p) ((p)->head &= ~PINUSE_BIT) -#define clear_cinuse(p) ((p)->head &= ~CINUSE_BIT) +#define CLEAR_PINUSE(p) ((p)->iHead &= ~PINUSE_BIT) +#define CLEAR_CINUSE(p) ((p)->iHead &= ~CINUSE_BIT) /* Treat space at ptr +/- offset as a chunk */ -#define chunk_plus_offset(p, s) ((mchunkptr)(((TUint8*)(p)) + (s))) -#define chunk_minus_offset(p, s) ((mchunkptr)(((TUint8*)(p)) - (s))) +#define CHUNK_PLUS_OFFSET(p, s) ((mchunkptr)(((TUint8*)(p)) + (s))) +#define CHUNK_MINUS_OFFSET(p, s) ((mchunkptr)(((TUint8*)(p)) - (s))) /* Ptr to next or previous physical malloc_chunk. */ -#define next_chunk(p) ((mchunkptr)( ((TUint8*)(p)) + ((p)->head & ~INUSE_BITS))) -#define prev_chunk(p) ((mchunkptr)( ((TUint8*)(p)) - ((p)->prev_foot) )) +#define NEXT_CHUNK(p) ((mchunkptr)( ((TUint8*)(p)) + ((p)->iHead & ~INUSE_BITS))) +#define PREV_CHUNK(p) ((mchunkptr)( ((TUint8*)(p)) - ((p)->iPrevFoot) )) -/* extract next chunk's pinuse bit */ -#define next_pinuse(p) ((next_chunk(p)->head) & PINUSE_BIT) +/* extract next chunk's PINUSE bit */ +#define NEXT_PINUSE(p) ((NEXT_CHUNK(p)->iHead) & PINUSE_BIT) /* Get/set size at footer */ -#define get_foot(p, s) (((mchunkptr)((TUint8*)(p) + (s)))->prev_foot) -#define set_foot(p, s) (((mchunkptr)((TUint8*)(p) + (s)))->prev_foot = (s)) +#define GET_FOOT(p, s) (((mchunkptr)((TUint8*)(p) + (s)))->iPrevFoot) +#define SET_FOOT(p, s) (((mchunkptr)((TUint8*)(p) + (s)))->iPrevFoot = (s)) -/* Set size, pinuse bit, and foot */ -#define set_size_and_pinuse_of_free_chunk(p, s) ((p)->head = (s|PINUSE_BIT), set_foot(p, s)) +/* Set size, PINUSE bit, and foot */ +#define SET_SIZE_AND_PINUSE_OF_FREE_CHUNK(p, s) ((p)->iHead = (s|PINUSE_BIT), SET_FOOT(p, s)) -/* Set size, pinuse bit, foot, and clear next pinuse */ -#define set_free_with_pinuse(p, s, n) (clear_pinuse(n), set_size_and_pinuse_of_free_chunk(p, s)) +/* Set size, PINUSE bit, foot, and clear next PINUSE */ +#define SET_FREE_WITH_PINUSE(p, s, n) (CLEAR_PINUSE(n), SET_SIZE_AND_PINUSE_OF_FREE_CHUNK(p, s)) -#define is_mmapped(p) (!((p)->head & PINUSE_BIT) && ((p)->prev_foot & IS_MMAPPED_BIT)) +#define IS_MMAPPED(p) (!((p)->iHead & PINUSE_BIT) && ((p)->iPrevFoot & IS_MMAPPED_BIT)) /* Get the internal overhead associated with chunk p */ -#define overhead_for(p) (is_mmapped(p)? MMAP_CHUNK_OVERHEAD : CHUNK_OVERHEAD) +#define OVERHEAD_FOR(p) (IS_MMAPPED(p)? MMAP_CHUNK_OVERHEAD : CHUNK_OVERHEAD) /* Return true if malloced space is not necessarily cleared */ #if MMAP_CLEARS - #define calloc_must_clear(p) (!is_mmapped(p)) + #define CALLOC_MUST_CLEAR(p) (!IS_MMAPPED(p)) #else /* MMAP_CLEARS */ - #define calloc_must_clear(p) (1) + #define CALLOC_MUST_CLEAR(p) (1) #endif /* MMAP_CLEARS */ /* ---------------------- Overlaid data structures ----------------------- */ struct malloc_tree_chunk { /* The first four fields must be compatible with malloc_chunk */ - size_t prev_foot; - size_t head; - struct malloc_tree_chunk* fd; - struct malloc_tree_chunk* bk; - - struct malloc_tree_chunk* child[2]; - struct malloc_tree_chunk* parent; - bindex_t index; + size_t iPrevFoot; + size_t iHead; + struct malloc_tree_chunk* iFd; + struct malloc_tree_chunk* iBk; + + struct malloc_tree_chunk* iChild[2]; + struct malloc_tree_chunk* iParent; + bindex_t iIndex; }; typedef struct malloc_tree_chunk tchunk; @@ -643,25 +634,23 @@ typedef struct malloc_tree_chunk* tchunkptr; typedef struct malloc_tree_chunk* tbinptr; /* The type of bins of trees */ /* A little helper macro for trees */ -#define leftmost_child(t) ((t)->child[0] != 0? (t)->child[0] : (t)->child[1]) +#define LEFTMOST_CHILD(t) ((t)->iChild[0] != 0? (t)->iChild[0] : (t)->iChild[1]) /*Segment structur*/ -struct malloc_segment { - TUint8* base; /* base address */ - size_t size; /* allocated size */ - struct malloc_segment* next; /* ptr to next segment */ - flag_t sflags; /* mmap and extern flag */ -}; +//struct malloc_segment { +// TUint8* iBase; /* base address */ +// size_t iSize; /* allocated size */ +//}; -#define is_mmapped_segment(S) ((S)->sflags & IS_MMAPPED_BIT) -#define is_extern_segment(S) ((S)->sflags & EXTERN_BIT) +#define IS_MMAPPED_SEGMENT(S) ((S)->iSflags & IS_MMAPPED_BIT) +#define IS_EXTERN_SEGMENT(S) ((S)->iSflags & EXTERN_BIT) typedef struct malloc_segment msegment; typedef struct malloc_segment* msegmentptr; /*Malloc State data structur*/ -#define NSMALLBINS (32U) -#define NTREEBINS (32U) +//#define NSMALLBINS (32U) +//#define NTREEBINS (32U) #define SMALLBIN_SHIFT (3U) #define SMALLBIN_WIDTH (SIZE_T_ONE << SMALLBIN_SHIFT) #define TREEBIN_SHIFT (8U) @@ -669,29 +658,42 @@ typedef struct malloc_segment* msegmentptr; #define MAX_SMALL_SIZE (MIN_LARGE_SIZE - SIZE_T_ONE) #define MAX_SMALL_REQUEST (MAX_SMALL_SIZE - CHUNK_ALIGN_MASK - CHUNK_OVERHEAD) +/*struct malloc_state { + binmap_t iSmallMap; + binmap_t iTreeMap; + size_t iDvSize; + size_t iTopSize; + mchunkptr iDv; + mchunkptr iTop; + size_t iTrimCheck; + mchunkptr iSmallBins[(NSMALLBINS+1)*2]; + tbinptr iTreeBins[NTREEBINS]; + msegment iSeg; + };*/ +/* struct malloc_state { - binmap_t smallmap; - binmap_t treemap; - size_t dvsize; - size_t topsize; - TUint8* least_addr; - mchunkptr dv; - mchunkptr top; - size_t trim_check; - size_t magic; - mchunkptr smallbins[(NSMALLBINS+1)*2]; - tbinptr treebins[NTREEBINS]; - size_t footprint; - size_t max_footprint; - flag_t mflags; + binmap_t iSmallMap; + binmap_t iTreeMap; + size_t iDvSize; + size_t iTopSize; + TUint8* iLeastAddr; + mchunkptr iDv; + mchunkptr iTop; + size_t iTrimCheck; + size_t iMagic; + mchunkptr iSmallBins[(NSMALLBINS+1)*2]; + tbinptr iTreeBins[NTREEBINS]; + size_t iFootprint; + size_t iMaxFootprint; + flag_t iMflags; #if USE_LOCKS - MLOCK_T mutex; /* locate lock among fields that rarely change */ - MLOCK_T magic_init_mutex; - MLOCK_T morecore_mutex; -#endif /* USE_LOCKS */ - msegment seg; + MLOCK_T iMutex; + MLOCK_T iMagicInitMutex; + MLOCK_T iMorecoreMutex; +#endif + msegment iSeg; }; - +*/ typedef struct malloc_state* mstate; /* ------------- Global malloc_state and malloc_params ------------------- */ @@ -703,14 +705,14 @@ typedef struct malloc_state* mstate; */ struct malloc_params { - size_t magic; - size_t page_size; - size_t granularity; - size_t mmap_threshold; - size_t trim_threshold; - flag_t default_mflags; + size_t iMagic; + size_t iPageSize; + size_t iGranularity; + size_t iMmapThreshold; + size_t iTrimThreshold; + flag_t iDefaultMflags; #if USE_LOCKS - MLOCK_T magic_init_mutex; + MLOCK_T iMagicInitMutex; #endif /* USE_LOCKS */ }; @@ -718,46 +720,46 @@ struct malloc_params { /*AMOD: Need to check this as this will be the member of the class*/ //static struct malloc_state _gm_; -//#define gm (&_gm_) - -//#define is_global(M) ((M) == &_gm_) +//#define GM (&_gm_) + +//#define IS_GLOBAL(M) ((M) == &_gm_) /*AMOD: has changed*/ -#define is_global(M) ((M) == gm) -#define is_initialized(M) ((M)->top != 0) +#define IS_GLOBAL(M) ((M) == GM) +#define IS_INITIALIZED(M) ((M)->iTop != 0) /* -------------------------- system alloc setup ------------------------- */ -/* Operations on mflags */ +/* Operations on iMflags */ -#define use_lock(M) ((M)->mflags & USE_LOCK_BIT) -#define enable_lock(M) ((M)->mflags |= USE_LOCK_BIT) -#define disable_lock(M) ((M)->mflags &= ~USE_LOCK_BIT) +#define USE_LOCK(M) ((M)->iMflags & USE_LOCK_BIT) +#define ENABLE_LOCK(M) ((M)->iMflags |= USE_LOCK_BIT) +#define DISABLE_LOCK(M) ((M)->iMflags &= ~USE_LOCK_BIT) -#define use_mmap(M) ((M)->mflags & USE_MMAP_BIT) -#define enable_mmap(M) ((M)->mflags |= USE_MMAP_BIT) -#define disable_mmap(M) ((M)->mflags &= ~USE_MMAP_BIT) +#define USE_MMAP(M) ((M)->iMflags & USE_MMAP_BIT) +#define ENABLE_MMAP(M) ((M)->iMflags |= USE_MMAP_BIT) +#define DISABLE_MMAP(M) ((M)->iMflags &= ~USE_MMAP_BIT) -#define use_noncontiguous(M) ((M)->mflags & USE_NONCONTIGUOUS_BIT) -#define disable_contiguous(M) ((M)->mflags |= USE_NONCONTIGUOUS_BIT) +#define USE_NONCONTIGUOUS(M) ((M)->iMflags & USE_NONCONTIGUOUS_BIT) +#define DISABLE_CONTIGUOUS(M) ((M)->iMflags |= USE_NONCONTIGUOUS_BIT) -#define set_lock(M,L) ((M)->mflags = (L)? ((M)->mflags | USE_LOCK_BIT) : ((M)->mflags & ~USE_LOCK_BIT)) +#define SET_LOCK(M,L) ((M)->iMflags = (L)? ((M)->iMflags | USE_LOCK_BIT) : ((M)->iMflags & ~USE_LOCK_BIT)) /* page-align a size */ -#define page_align(S) (((S) + (mparams.page_size)) & ~(mparams.page_size - SIZE_T_ONE)) +#define PAGE_ALIGN(S) (((S) + (mparams.iPageSize)) & ~(mparams.iPageSize - SIZE_T_ONE)) -/* granularity-align a size */ -#define granularity_align(S) (((S) + (mparams.granularity)) & ~(mparams.granularity - SIZE_T_ONE)) +/* iGranularity-align a size */ +#define GRANULARITY_ALIGN(S) (((S) + (mparams.iGranularity)) & ~(mparams.iGranularity - SIZE_T_ONE)) -#define is_page_aligned(S) (((size_t)(S) & (mparams.page_size - SIZE_T_ONE)) == 0) -#define is_granularity_aligned(S) (((size_t)(S) & (mparams.granularity - SIZE_T_ONE)) == 0) +#define IS_PAGE_ALIGNED(S) (((size_t)(S) & (mparams.iPageSize - SIZE_T_ONE)) == 0) +#define IS_GRANULARITY_ALIGNED(S) (((size_t)(S) & (mparams.iGranularity - SIZE_T_ONE)) == 0) /* True if segment S holds address A */ -#define segment_holds(S, A) ((TUint8*)(A) >= S->base && (TUint8*)(A) < S->base + S->size) +#define SEGMENT_HOLDS(S, A) ((TUint8*)(A) >= S->iBase && (TUint8*)(A) < S->iBase + S->iSize) #ifndef MORECORE_CANNOT_TRIM - #define should_trim(M,s) ((s) > (M)->trim_check) + #define SHOULD_TRIM(M,s) ((s) > (M)->iTrimCheck) #else /* MORECORE_CANNOT_TRIM */ - #define should_trim(M,s) (0) + #define SHOULD_TRIM(M,s) (0) #endif /* MORECORE_CANNOT_TRIM */ /* @@ -765,8 +767,9 @@ struct malloc_params { that may be needed to place segment records and fenceposts when new noncontiguous segments are added. */ -#define TOP_FOOT_SIZE (align_offset(chunk2mem(0))+pad_request(sizeof(struct malloc_segment))+MIN_CHUNK_SIZE) +#define TOP_FOOT_SIZE (ALIGN_OFFSET(CHUNK2MEM(0))+PAD_REQUEST(sizeof(struct malloc_segment))+MIN_CHUNK_SIZE) +#define SYS_ALLOC_PADDING (TOP_FOOT_SIZE + MALLOC_ALIGNMENT) /* ------------------------------- Hooks -------------------------------- */ /* @@ -777,9 +780,9 @@ struct malloc_params { #if USE_LOCKS /* Ensure locks are initialized */ - #define GLOBALLY_INITIALIZE() (mparams.page_size == 0 && init_mparams()) - #define PREACTION(M) (use_lock((M))?(ACQUIRE_LOCK((M)->mutex),0):0) /*Action to take like lock before alloc*/ - #define POSTACTION(M) { if (use_lock(M)) RELEASE_LOCK((M)->mutex); } + #define GLOBALLY_INITIALIZE() (mparams.iPageSize == 0 && init_mparams()) + #define PREACTION(M) (USE_LOCK((M))?(ACQUIRE_LOCK((M)->iMutex),0):0) /*Action to take like lock before alloc*/ + #define POSTACTION(M) { if (USE_LOCK(M)) RELEASE_LOCK((M)->iMutex); } #else /* USE_LOCKS */ #ifndef PREACTION @@ -802,8 +805,8 @@ struct malloc_params { /* A count of the number of corruption errors causing resets */ int malloc_corruption_error_count; /* default corruption action */ - static void reset_on_error(mstate m); - #define CORRUPTION_ERROR_ACTION(m) reset_on_error(m) + static void ResetOnError(mstate m); + #define CORRUPTION_ERROR_ACTION(m) ResetOnError(m) #define USAGE_ERROR_ACTION(m, p) #else /* PROCEED_ON_ERROR */ #ifndef CORRUPTION_ERROR_ACTION @@ -814,108 +817,86 @@ struct malloc_params { #endif /* USAGE_ERROR_ACTION */ #endif /* PROCEED_ON_ERROR */ - /* -------------------------- Debugging setup ---------------------------- */ -#if ! DEBUG - #define check_free_chunk(M,P) - #define check_inuse_chunk(M,P) - #define check_malloced_chunk(M,P,N) - #define check_mmapped_chunk(M,P) - #define check_malloc_state(M) - #define check_top_chunk(M,P) +#ifdef _DEBUG + #define CHECK_FREE_CHUNK(M,P) DoCheckFreeChunk(M,P) + #define CHECK_INUSE_CHUNK(M,P) DoCheckInuseChunk(M,P) + #define CHECK_TOP_CHUNK(M,P) DoCheckTopChunk(M,P) + #define CHECK_MALLOCED_CHUNK(M,P,N) DoCheckMallocedChunk(M,P,N) + #define CHECK_MMAPPED_CHUNK(M,P) DoCheckMmappedChunk(M,P) + #define CHECK_MALLOC_STATE(M) DoCheckMallocState(M) #else /* DEBUG */ - #define check_free_chunk(M,P) do_check_free_chunk(M,P) - #define check_inuse_chunk(M,P) do_check_inuse_chunk(M,P) - #define check_top_chunk(M,P) do_check_top_chunk(M,P) - #define check_malloced_chunk(M,P,N) do_check_malloced_chunk(M,P,N) - #define check_mmapped_chunk(M,P) do_check_mmapped_chunk(M,P) - #define check_malloc_state(M) do_check_malloc_state(M) - static void do_check_any_chunk(mstate m, mchunkptr p); - static void do_check_top_chunk(mstate m, mchunkptr p); - static void do_check_mmapped_chunk(mstate m, mchunkptr p); - static void do_check_inuse_chunk(mstate m, mchunkptr p); - static void do_check_free_chunk(mstate m, mchunkptr p); - static void do_check_malloced_chunk(mstate m, void* mem, size_t s); - static void do_check_tree(mstate m, tchunkptr t); - static void do_check_treebin(mstate m, bindex_t i); - static void do_check_smallbin(mstate m, bindex_t i); - static void do_check_malloc_state(mstate m); - static int bin_find(mstate m, mchunkptr x); - static size_t traverse_and_check(mstate m); + #define CHECK_FREE_CHUNK(M,P) + #define CHECK_INUSE_CHUNK(M,P) + #define CHECK_MALLOCED_CHUNK(M,P,N) + #define CHECK_MMAPPED_CHUNK(M,P) + #define CHECK_MALLOC_STATE(M) + #define CHECK_TOP_CHUNK(M,P) #endif /* DEBUG */ /* ---------------------------- Indexing Bins ---------------------------- */ -#define is_small(s) (((s) >> SMALLBIN_SHIFT) < NSMALLBINS) -#define small_index(s) ((s) >> SMALLBIN_SHIFT) -#define small_index2size(i) ((i) << SMALLBIN_SHIFT) -#define MIN_SMALL_INDEX (small_index(MIN_CHUNK_SIZE)) +#define IS_SMALL(s) (((s) >> SMALLBIN_SHIFT) < NSMALLBINS) +#define SMALL_INDEX(s) ((s) >> SMALLBIN_SHIFT) +#define SMALL_INDEX2SIZE(i) ((i) << SMALLBIN_SHIFT) +#define MIN_SMALL_INDEX (SMALL_INDEX(MIN_CHUNK_SIZE)) /* addressing by index. See above about smallbin repositioning */ -#define smallbin_at(M, i) ((sbinptr)((TUint8*)&((M)->smallbins[(i)<<1]))) -#define treebin_at(M,i) (&((M)->treebins[i])) +#define SMALLBIN_AT(M, i) ((sbinptr)((TUint8*)&((M)->iSmallBins[(i)<<1]))) +#define TREEBIN_AT(M,i) (&((M)->iTreeBins[i])) /* Bit representing maximum resolved size in a treebin at i */ -#define bit_for_tree_index(i) (i == NTREEBINS-1)? (SIZE_T_BITSIZE-1) : (((i) >> 1) + TREEBIN_SHIFT - 2) +#define BIT_FOR_TREE_INDEX(i) (i == NTREEBINS-1)? (SIZE_T_BITSIZE-1) : (((i) >> 1) + TREEBIN_SHIFT - 2) /* Shift placing maximum resolved bit in a treebin at i as sign bit */ -#define leftshift_for_tree_index(i) ((i == NTREEBINS-1)? 0 : ((SIZE_T_BITSIZE-SIZE_T_ONE) - (((i) >> 1) + TREEBIN_SHIFT - 2))) +#define LEFTSHIFT_FOR_TREE_INDEX(i) ((i == NTREEBINS-1)? 0 : ((SIZE_T_BITSIZE-SIZE_T_ONE) - (((i) >> 1) + TREEBIN_SHIFT - 2))) /* The size of the smallest chunk held in bin with index i */ -#define minsize_for_tree_index(i) ((SIZE_T_ONE << (((i) >> 1) + TREEBIN_SHIFT)) | (((size_t)((i) & SIZE_T_ONE)) << (((i) >> 1) + TREEBIN_SHIFT - 1))) +#define MINSIZE_FOR_TREE_INDEX(i) ((SIZE_T_ONE << (((i) >> 1) + TREEBIN_SHIFT)) | (((size_t)((i) & SIZE_T_ONE)) << (((i) >> 1) + TREEBIN_SHIFT - 1))) /* ------------------------ Operations on bin maps ----------------------- */ /* bit corresponding to given index */ -#define idx2bit(i) ((binmap_t)(1) << (i)) +#define IDX2BIT(i) ((binmap_t)(1) << (i)) /* Mark/Clear bits with given index */ -#define mark_smallmap(M,i) ((M)->smallmap |= idx2bit(i)) -#define clear_smallmap(M,i) ((M)->smallmap &= ~idx2bit(i)) -#define smallmap_is_marked(M,i) ((M)->smallmap & idx2bit(i)) -#define mark_treemap(M,i) ((M)->treemap |= idx2bit(i)) -#define clear_treemap(M,i) ((M)->treemap &= ~idx2bit(i)) -#define treemap_is_marked(M,i) ((M)->treemap & idx2bit(i)) - -/* isolate the least set bit of a bitmap */ -#define least_bit(x) ((x) & -(x)) - -/* mask with all bits to left of least bit of x on */ -#define left_bits(x) ((x<<1) | -(x<<1)) - -/* mask with all bits to left of or equal to least bit of x on */ -#define same_or_left_bits(x) ((x) | -(x)) +#define MARK_SMALLMAP(M,i) ((M)->iSmallMap |= IDX2BIT(i)) +#define CLEAR_SMALLMAP(M,i) ((M)->iSmallMap &= ~IDX2BIT(i)) +#define SMALLMAP_IS_MARKED(M,i) ((M)->iSmallMap & IDX2BIT(i)) +#define MARK_TREEMAP(M,i) ((M)->iTreeMap |= IDX2BIT(i)) +#define CLEAR_TREEMAP(M,i) ((M)->iTreeMap &= ~IDX2BIT(i)) +#define TREEMAP_IS_MARKED(M,i) ((M)->iTreeMap & IDX2BIT(i)) /* isolate the least set bit of a bitmap */ -#define least_bit(x) ((x) & -(x)) +#define LEAST_BIT(x) ((x) & -(x)) /* mask with all bits to left of least bit of x on */ -#define left_bits(x) ((x<<1) | -(x<<1)) +#define LEFT_BITS(x) ((x<<1) | -(x<<1)) /* mask with all bits to left of or equal to least bit of x on */ -#define same_or_left_bits(x) ((x) | -(x)) +#define SAME_OR_LEFT_BITS(x) ((x) | -(x)) #if !INSECURE /* Check if address a is at least as high as any from MORECORE or MMAP */ - #define ok_address(M, a) ((TUint8*)(a) >= (M)->least_addr) + #define OK_ADDRESS(M, a) ((TUint8*)(a) >= (M)->iLeastAddr) /* Check if address of next chunk n is higher than base chunk p */ - #define ok_next(p, n) ((TUint8*)(p) < (TUint8*)(n)) - /* Check if p has its cinuse bit on */ - #define ok_cinuse(p) cinuse(p) - /* Check if p has its pinuse bit on */ - #define ok_pinuse(p) pinuse(p) + #define OK_NEXT(p, n) ((TUint8*)(p) < (TUint8*)(n)) + /* Check if p has its CINUSE bit on */ + #define OK_CINUSE(p) CINUSE(p) + /* Check if p has its PINUSE bit on */ + #define OK_PINUSE(p) PINUSE(p) #else /* !INSECURE */ - #define ok_address(M, a) (1) - #define ok_next(b, n) (1) - #define ok_cinuse(p) (1) - #define ok_pinuse(p) (1) + #define OK_ADDRESS(M, a) (1) + #define OK_NEXT(b, n) (1) + #define OK_CINUSE(p) (1) + #define OK_PINUSE(p) (1) #endif /* !INSECURE */ #if (FOOTERS && !INSECURE) - /* Check if (alleged) mstate m has expected magic field */ - #define ok_magic(M) ((M)->magic == mparams.magic) + /* Check if (alleged) mstate m has expected iMagic field */ + #define OK_MAGIC(M) ((M)->iMagic == mparams.iMagic) #else /* (FOOTERS && !INSECURE) */ - #define ok_magic(M) (1) + #define OK_MAGIC(M) (1) #endif /* (FOOTERS && !INSECURE) */ /* In gcc, use __builtin_expect to minimize impact of checks */ @@ -931,135 +912,58 @@ struct malloc_params { #endif /* !INSECURE */ /* macros to set up inuse chunks with or without footers */ #if !FOOTERS - #define mark_inuse_foot(M,p,s) - /* Set cinuse bit and pinuse bit of next chunk */ - #define set_inuse(M,p,s) ((p)->head = (((p)->head & PINUSE_BIT)|s|CINUSE_BIT),((mchunkptr)(((TUint8*)(p)) + (s)))->head |= PINUSE_BIT) - /* Set cinuse and pinuse of this chunk and pinuse of next chunk */ - #define set_inuse_and_pinuse(M,p,s) ((p)->head = (s|PINUSE_BIT|CINUSE_BIT),((mchunkptr)(((TUint8*)(p)) + (s)))->head |= PINUSE_BIT) - /* Set size, cinuse and pinuse bit of this chunk */ - #define set_size_and_pinuse_of_inuse_chunk(M, p, s) ((p)->head = (s|PINUSE_BIT|CINUSE_BIT)) + #define MARK_INUSE_FOOT(M,p,s) + /* Set CINUSE bit and PINUSE bit of next chunk */ + #define SET_INUSE(M,p,s) ((p)->iHead = (((p)->iHead & PINUSE_BIT)|s|CINUSE_BIT),((mchunkptr)(((TUint8*)(p)) + (s)))->iHead |= PINUSE_BIT) + /* Set CINUSE and PINUSE of this chunk and PINUSE of next chunk */ + #define SET_INUSE_AND_PINUSE(M,p,s) ((p)->iHead = (s|PINUSE_BIT|CINUSE_BIT),((mchunkptr)(((TUint8*)(p)) + (s)))->iHead |= PINUSE_BIT) + /* Set size, CINUSE and PINUSE bit of this chunk */ + #define SET_SIZE_AND_PINUSE_OF_INUSE_CHUNK(M, p, s) ((p)->iHead = (s|PINUSE_BIT|CINUSE_BIT)) #else /* FOOTERS */ /* Set foot of inuse chunk to be xor of mstate and seed */ - #define mark_inuse_foot(M,p,s) (((mchunkptr)((TUint8*)(p) + (s)))->prev_foot = ((size_t)(M) ^ mparams.magic)) - #define get_mstate_for(p) ((mstate)(((mchunkptr)((TUint8*)(p)+(chunksize(p))))->prev_foot ^ mparams.magic)) - #define set_inuse(M,p,s)\ - ((p)->head = (((p)->head & PINUSE_BIT)|s|CINUSE_BIT),\ - (((mchunkptr)(((TUint8*)(p)) + (s)))->head |= PINUSE_BIT), \ - mark_inuse_foot(M,p,s)) - #define set_inuse_and_pinuse(M,p,s)\ - ((p)->head = (s|PINUSE_BIT|CINUSE_BIT),\ - (((mchunkptr)(((TUint8*)(p)) + (s)))->head |= PINUSE_BIT),\ - mark_inuse_foot(M,p,s)) - #define set_size_and_pinuse_of_inuse_chunk(M, p, s)\ - ((p)->head = (s|PINUSE_BIT|CINUSE_BIT),\ - mark_inuse_foot(M, p, s)) + #define MARK_INUSE_FOOT(M,p,s) (((mchunkptr)((TUint8*)(p) + (s)))->iPrevFoot = ((size_t)(M) ^ mparams.iMagic)) + #define GET_MSTATE_FOR(p) ((mstate)(((mchunkptr)((TUint8*)(p)+(CHUNKSIZE(p))))->iPrevFoot ^ mparams.iMagic)) + #define SET_INUSE(M,p,s)\ + ((p)->iHead = (((p)->iHead & PINUSE_BIT)|s|CINUSE_BIT),\ + (((mchunkptr)(((TUint8*)(p)) + (s)))->iHead |= PINUSE_BIT), \ + MARK_INUSE_FOOT(M,p,s)) + #define SET_INUSE_AND_PINUSE(M,p,s)\ + ((p)->iHead = (s|PINUSE_BIT|CINUSE_BIT),\ + (((mchunkptr)(((TUint8*)(p)) + (s)))->iHead |= PINUSE_BIT),\ + MARK_INUSE_FOOT(M,p,s)) + #define SET_SIZE_AND_PINUSE_OF_INUSE_CHUNK(M, p, s)\ + ((p)->iHead = (s|PINUSE_BIT|CINUSE_BIT),\ + MARK_INUSE_FOOT(M, p, s)) #endif /* !FOOTERS */ #if ONLY_MSPACES -#define internal_malloc(m, b) mspace_malloc(m, b) -#define internal_free(m, mem) mspace_free(m,mem); +#define INTERNAL_MALLOC(m, b) mspace_malloc(m, b) +#define INTERNAL_FREE(m, mem) mspace_free(m,mem); #else /* ONLY_MSPACES */ #if MSPACES - #define internal_malloc(m, b) (m == gm)? dlmalloc(b) : mspace_malloc(m, b) - #define internal_free(m, mem) if (m == gm) dlfree(mem); else mspace_free(m,mem); + #define INTERNAL_MALLOC(m, b) (m == GM)? dlmalloc(b) : mspace_malloc(m, b) + #define INTERNAL_FREE(m, mem) if (m == GM) dlfree(mem); else mspace_free(m,mem); #else /* MSPACES */ - #define internal_malloc(m, b) dlmalloc(b) - #define internal_free(m, mem) dlfree(mem) + #define INTERNAL_MALLOC(m, b) dlmalloc(b) + #define INTERNAL_FREE(m, mem) dlfree(mem) #endif /* MSPACES */ #endif /* ONLY_MSPACES */ -/******CODE TO SUPORT SLAB ALLOCATOR******/ - + #ifndef NDEBUG #define CHECKING 1 #endif - +// #define HYSTERESIS 4 + #define HYSTERESIS 1 + #define HYSTERESIS_BYTES (2*PAGESIZE) + #define HYSTERESIS_GROW (HYSTERESIS*PAGESIZE) + #if CHECKING - #ifndef ASSERT - #define ASSERT(x) {if (!(x)) abort();} - #endif #define CHECK(x) x #else - #ifndef ASSERT + #undef ASSERT #define ASSERT(x) (void)0 - #endif #define CHECK(x) (void)0 #endif - - class slab; - class slabhdr; - #define maxslabsize 56 - #define pageshift 12 - #define pagesize (1<<pageshift) - #define slabshift 10 - #define slabsize (1 << slabshift) - #define cellalign 8 - const unsigned slabfull = 0; - const TInt slabsperpage = (int)(pagesize/slabsize); - #define hibit(bits) (((unsigned)bits & 0xc) ? 2 + ((unsigned)bits>>3) : ((unsigned) bits>>1)) - - #define lowbit(bits) (((unsigned) bits&3) ? 1 - ((unsigned)bits&1) : 3 - (((unsigned)bits>>2)&1)) - #define minpagepower pageshift+2 - #define cellalign 8 - class slabhdr - { - public: - unsigned header; - // made up of - // bits | 31 | 30..28 | 27..18 | 17..12 | 11..8 | 7..0 | - // +----------+--------+--------+--------+---------+----------+ - // field | floating | zero | used-4 | size | pagemap | free pos | - // - slab** parent; // reference to parent's pointer to this slab in tree - slab* child1; // 1st child in tree - slab* child2; // 2nd child in tree - }; - - inline unsigned header_floating(unsigned h) - {return (h&0x80000000);} - const unsigned maxuse = (slabsize - sizeof(slabhdr))>>2; - const unsigned firstpos = sizeof(slabhdr)>>2; - #define checktree(x) (void)0 - template <class T> inline T floor(const T addr, unsigned aln) - {return T((unsigned(addr))&~(aln-1));} - template <class T> inline T ceiling(T addr, unsigned aln) - {return T((unsigned(addr)+(aln-1))&~(aln-1));} - template <class T> inline unsigned lowbits(T addr, unsigned aln) - {return unsigned(addr)&(aln-1);} - template <class T1, class T2> inline int ptrdiff(const T1* a1, const T2* a2) - {return reinterpret_cast<const unsigned char*>(a1) - reinterpret_cast<const unsigned char*>(a2);} - template <class T> inline T offset(T addr, signed ofs) - {return T(unsigned(addr)+ofs);} - class slabset - { - public: - slab* partial; - }; - - class slab : public slabhdr - { - public: - void init(unsigned clz); - //static slab* slabfor( void* p); - static slab* slabfor(const void* p) ; - private: - unsigned char payload[slabsize-sizeof(slabhdr)]; - }; - class page - { - public: - inline static page* pagefor(slab* s); - //slab slabs; - slab slabs[slabsperpage]; - }; - - - inline page* page::pagefor(slab* s) - {return reinterpret_cast<page*>(floor(s, pagesize));} - struct pagecell - { - void* page; - unsigned size; - }; - /******CODE TO SUPORT SLAB ALLOCATOR******/ + #endif/*__DLA__*/ diff --git a/src/corelib/arch/symbian/heap_hybrid.cpp b/src/corelib/arch/symbian/heap_hybrid.cpp new file mode 100644 index 0000000..4b514b2 --- /dev/null +++ b/src/corelib/arch/symbian/heap_hybrid.cpp @@ -0,0 +1,3337 @@ +/**************************************************************************** +** +** Copyright (C) 2010 Nokia Corporation and/or its subsidiary(-ies). +** All rights reserved. +** Contact: Nokia Corporation (qt-info@nokia.com) +** +** This file is part of the QtCore module of the Qt Toolkit. +** +** $QT_BEGIN_LICENSE:LGPL$ +** No Commercial Usage +** This file contains pre-release code and may not be distributed. +** You may use this file in accordance with the terms and conditions +** contained in the Technology Preview License Agreement accompanying +** this package. +** +** GNU Lesser General Public License Usage +** Alternatively, this file may be used under the terms of the GNU Lesser +** General Public License version 2.1 as published by the Free Software +** Foundation and appearing in the file LICENSE.LGPL included in the +** packaging of this file. Please review the following information to +** ensure the GNU Lesser General Public License version 2.1 requirements +** will be met: http://www.gnu.org/licenses/old-licenses/lgpl-2.1.html. +** +** In addition, as a special exception, Nokia gives you certain additional +** rights. These rights are described in the Nokia Qt LGPL Exception +** version 1.1, included in the file LGPL_EXCEPTION.txt in this package. +** +** If you have questions regarding the use of this file, please contact +** Nokia at qt-info@nokia.com. +** +** +** +** +** +** +** +** +** $QT_END_LICENSE$ +** +****************************************************************************/ + +#include "qt_hybridheap_symbian.h" + +#ifdef QT_USE_NEW_SYMBIAN_ALLOCATOR + +// 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__ + +#endif /* QT_USE_NEW_SYMBIAN_ALLOCATOR */ diff --git a/src/corelib/arch/symbian/heap_hybrid_p.h b/src/corelib/arch/symbian/heap_hybrid_p.h new file mode 100644 index 0000000..bb6fd31 --- /dev/null +++ b/src/corelib/arch/symbian/heap_hybrid_p.h @@ -0,0 +1,391 @@ +/**************************************************************************** +** +** Copyright (C) 2010 Nokia Corporation and/or its subsidiary(-ies). +** All rights reserved. +** Contact: Nokia Corporation (qt-info@nokia.com) +** +** This file is part of the QtCore module of the Qt Toolkit. +** +** $QT_BEGIN_LICENSE:LGPL$ +** No Commercial Usage +** This file contains pre-release code and may not be distributed. +** You may use this file in accordance with the terms and conditions +** contained in the Technology Preview License Agreement accompanying +** this package. +** +** GNU Lesser General Public License Usage +** Alternatively, this file may be used under the terms of the GNU Lesser +** General Public License version 2.1 as published by the Free Software +** Foundation and appearing in the file LICENSE.LGPL included in the +** packaging of this file. Please review the following information to +** ensure the GNU Lesser General Public License version 2.1 requirements +** will be met: http://www.gnu.org/licenses/old-licenses/lgpl-2.1.html. +** +** In addition, as a special exception, Nokia gives you certain additional +** rights. These rights are described in the Nokia Qt LGPL Exception +** version 1.1, included in the file LGPL_EXCEPTION.txt in this package. +** +** If you have questions regarding the use of this file, please contact +** Nokia at qt-info@nokia.com. +** +** +** +** +** +** +** +** +** $QT_END_LICENSE$ +** +****************************************************************************/ + +#ifndef __HEAP_HYBRID_H__ +#define __HEAP_HYBRID_H__ + +#include <e32cmn.h> + +#ifdef __WINS__ +#define USE_HYBRID_HEAP 0 +#else +#define USE_HYBRID_HEAP 1 +#endif + +// This stuff is all temporary in order to prevent having to include dla.h from heap_hybrid.h, which causes +// problems due to its definition of size_t (and possibly other types). This is unfortunate but we cannot +// pollute the namespace with these types or it will cause problems with Open C and other POSIX compatibility +// efforts in Symbian + +#define NSMALLBINS (32U) +#define NTREEBINS (32U) + +#ifndef MALLOC_ALIGNMENT + #define MALLOC_ALIGNMENT ((TUint)8U) +#endif /* MALLOC_ALIGNMENT */ + +#define CHUNK_OVERHEAD (sizeof(TUint)) + +typedef unsigned int bindex_t; +typedef unsigned int binmap_t; +typedef struct malloc_chunk* mchunkptr; +typedef struct malloc_segment msegment; +typedef struct malloc_state* mstate; +typedef struct malloc_tree_chunk* tbinptr; +typedef struct malloc_tree_chunk* tchunkptr; + +struct malloc_segment { + TUint8* iBase; /* base address */ + TUint iSize; /* allocated size */ +}; + +struct malloc_state { + binmap_t iSmallMap; + binmap_t iTreeMap; + TUint iDvSize; + TUint iTopSize; + mchunkptr iDv; + mchunkptr iTop; + TUint iTrimCheck; + mchunkptr iSmallBins[(NSMALLBINS+1)*2]; + tbinptr iTreeBins[NTREEBINS]; + msegment iSeg; + }; + +class RHybridHeap : public RHeap + { + +public: +// MGR CHANGE +typedef void (*TWalkFunc)(TAny*, RHeap::TCellType, TAny*, TInt); + + + struct HeapInfo + { + unsigned iFootprint; + unsigned iMaxSize; + unsigned iAllocBytes; + unsigned iAllocN; + unsigned iFreeBytes; + unsigned iFreeN; + }; + + struct SHeapCellInfo { RHybridHeap* iHeap; TInt iTotalAlloc; TInt iTotalAllocSize; TInt iTotalFree; TInt iLevelAlloc; SDebugCell* iStranded; }; + + + /** + @internalComponent + */ + enum TAllocatorType + {ESlabAllocator, EDougLeaAllocator, EPageAllocator, EFullSlab=0x80, EPartialFullSlab=0x40, EEmptySlab=0x20, ESlabSpare=0x10, ESlabMask=0xf0}; + + + /** + @internalComponent + */ + struct SWalkInfo { + /** + Walk function address shall be called + */ + TWalkFunc iFunction; + + /** + The first parameter for callback function + */ + TAny* iParam; + /** + Pointer to RHybridHeap object + */ + RHybridHeap* iHeap; + }; + + /** + @internalComponent + */ + struct SConfig { + /** + Required slab configuration ( bit 0=4, bit 1=8 .. + bit 13 = 56) + */ + TUint32 iSlabBits; + /** + Delayed slab threshold in bytes (0 = no threshold) + */ + TInt iDelayedSlabThreshold; + /** + 2^n is smallest size allocated in paged allocator (14-31 = 16 Kb --> ) + */ + TInt iPagePower; + + }; + + /** + @internalComponent + + This structure is used by test code for configuring the allocators and obtaining information + from them in order to ensure they are behaving as required. This is internal test specific + code and is liable to be changed without warning at any time. You should under no circumstances + be using it! + */ + struct STestCommand + { + TInt iCommand; // The test related command to be executed + + union + { + SConfig iConfig; // Configuration used by test code only + TAny* iData; // Extra supporting data for the test command + }; + }; + + /** + @internalComponent + + Commands used by test code for configuring the allocators and obtaining information them them + */ + enum TTestCommand { EGetConfig, ESetConfig, EHeapMetaData, ETestData }; + + virtual TAny* Alloc(TInt aSize); + virtual void Free(TAny* aPtr); + virtual TAny* ReAlloc(TAny* aPtr, TInt aSize, TInt aMode=0); + virtual TInt AllocLen(const TAny* aCell) const; +#ifndef __KERNEL_MODE__ + virtual TInt Compress(); + virtual void Reset(); + virtual TInt AllocSize(TInt& aTotalAllocSize) const; + virtual TInt Available(TInt& aBiggestBlock) const; +#endif + virtual TInt DebugFunction(TInt aFunc, TAny* a1=NULL, TAny* a2=NULL); +protected: + virtual TInt Extension_(TUint aExtensionId, TAny*& a0, TAny* a1); + +public: + TAny* operator new(TUint aSize, TAny* aBase) __NO_THROW; + void operator delete(TAny*, TAny*); + +private: + TInt DoCountAllocFree(TInt& aFree); + TInt DoCheckHeap(SCheckInfo* aInfo); + void DoMarkStart(); + TUint32 DoMarkEnd(TInt aExpected); + void DoSetAllocFail(TAllocFail aType, TInt aRate); + TBool CheckForSimulatedAllocFail(); + void DoSetAllocFail(TAllocFail aType, TInt aRate, TUint aBurst); + + void Lock() const; + void Unlock() const; + TInt ChunkHandle() const; + + RHybridHeap(TInt aChunkHandle, TInt aOffset, TInt aMinLength, TInt aMaxLength, TInt aGrowBy, TInt aAlign, TBool aSingleThread, TBool aDlOnly, TBool aUseAdjust); + RHybridHeap(TInt aMaxLength, TInt aAlign=0, TBool aSingleThread=ETrue); + RHybridHeap(); + + void Init(TInt aBitmapSlab, TInt aPagePower); + inline void InitBins(mstate m); + inline void InitTop(mstate m, mchunkptr p, TUint psize); + void* SysAlloc(mstate m, TUint nb); + int SysTrim(mstate m, TUint pad); + void* TmallocLarge(mstate m, TUint nb); + void* TmallocSmall(mstate m, TUint nb); + /*MACROS converted functions*/ + static inline void UnlinkFirstSmallChunk(mstate M,mchunkptr B,mchunkptr P,bindex_t& I); + static inline void InsertSmallChunk(mstate M,mchunkptr P, TUint S); + static inline void InsertChunk(mstate M,mchunkptr P,TUint S); + static inline void UnlinkLargeChunk(mstate M,tchunkptr X); + static inline void UnlinkSmallChunk(mstate M, mchunkptr P,TUint S); + static inline void UnlinkChunk(mstate M, mchunkptr P, TUint S); + static inline void ComputeTreeIndex(TUint S, bindex_t& I); + static inline void InsertLargeChunk(mstate M,tchunkptr X,TUint S); + static inline void ReplaceDv(mstate M, mchunkptr P, TUint S); + static inline void ComputeBit2idx(binmap_t X,bindex_t& I); + + void DoComputeTreeIndex(TUint S, bindex_t& I); + void DoCheckAnyChunk(mstate m, mchunkptr p); + void DoCheckTopChunk(mstate m, mchunkptr p); + void DoCheckInuseChunk(mstate m, mchunkptr p); + void DoCheckFreeChunk(mstate m, mchunkptr p); + void DoCheckMallocedChunk(mstate m, void* mem, TUint s); + void DoCheckTree(mstate m, tchunkptr t); + void DoCheckTreebin(mstate m, bindex_t i); + void DoCheckSmallbin(mstate m, bindex_t i); + TInt BinFind(mstate m, mchunkptr x); + TUint TraverseAndCheck(mstate m); + void DoCheckMallocState(mstate m); + + TInt GetInfo(struct HeapInfo* i, SWalkInfo* wi=NULL) const; + void InitDlMalloc(TUint capacity, int locked); + void* DlMalloc(TUint); + void DlFree(void*); + void* DlRealloc(void*, TUint, TInt); + TUint DlInfo(struct HeapInfo* i, SWalkInfo* wi) const; + void DoCheckCommittedSize(TInt aNPages, mstate aM); + + TAny* ReAllocImpl(TAny* aPtr, TInt aSize, TInt aMode); + void Construct(TBool aSingleThread, TBool aDLOnly, TBool aUseAdjust, TInt aAlign); +#ifndef __KERNEL_MODE__ + TInt ConstructLock(TUint32 aMode); +#endif + static void Walk(SWalkInfo* aInfo, TAny* aBfr, TInt aLth, TCellType aBfrType, TAllocatorType aAlloctorType); + static void WalkCheckCell(TAny* aPtr, TCellType aType, TAny* aCell, TInt aLen); + void* Map(void* p, TInt sz); + void Unmap(void* p,TInt sz); + +private: + TInt iMinLength; + TInt iOffset; // offset of RHeap object from chunk base + TInt iGrowBy; + TInt iMinCell; + TInt iPageSize; + + // Temporarily commented out and exported from RHeap to prevent source breaks from req417-52840. + // This will be moved with another REQ after submission and subsequent fixing of bad code + //TInt iNestingLevel; + TInt iAllocCount; + // Temporarily commented out. See comment above regarding req417-52840 source breaks + //TAllocFail iFailType; + TInt iFailRate; + TBool iFailed; + TInt iFailAllocCount; + TInt iRand; + // Temporarily commented out. See comment above regarding req417-52840 source breaks + //TAny* iTestData; + + TInt iChunkSize; + TInt iHighWaterMark; + TBool iUseAdjust; + TBool iDLOnly; + + malloc_state iGlobalMallocState; + +#ifdef __KERNEL_MODE__ + + friend class RHeapK; + +#else + + friend class UserHeap; + friend class HybridHeap; + friend class TestHybridHeap; + +private: + + static void TreeRemove(slab* s); + static void TreeInsert(slab* s,slab** r); + + enum {EOkBits = (1<<(MAXSLABSIZE>>2))-1}; + + void SlabInit(); + void SlabConfig(unsigned slabbitmap); + void* SlabAllocate(slabset& allocator); + void SlabFree(void* p); + void* AllocNewSlab(slabset& allocator); + void* AllocNewPage(slabset& allocator); + void* InitNewSlab(slabset& allocator, slab* s); + void FreeSlab(slab* s); + void FreePage(page* p); + void SlabInfo(struct HeapInfo* i, SWalkInfo* wi) const; + static void SlabFullInfo(slab* s, struct HeapInfo* i, SWalkInfo* wi); + static void SlabPartialInfo(slab* s, struct HeapInfo* i, SWalkInfo* wi); + static void SlabEmptyInfo(slab* s, struct HeapInfo* i, SWalkInfo* wi); + static void TreeWalk(slab* const* root, void (*f)(slab*, struct HeapInfo*, SWalkInfo*), struct HeapInfo* i, SWalkInfo* wi); + + static void WalkPartialFullSlab(SWalkInfo* aInfo, slab* aSlab, TCellType aBfrType, TInt aLth); + static void WalkFullSlab(SWalkInfo* aInfo, slab* aSlab, TCellType aBfrType, TInt aLth); + void DoCheckSlab(slab* aSlab, TAllocatorType aSlabType, TAny* aBfr=NULL); + void DoCheckSlabTrees(); + void DoCheckSlabTree(slab** aS, TBool aPartialPage); + void BuildPartialSlabBitmap(TUint32* aBitmap, slab* aSlab, TAny* aBfr=NULL); + + static inline unsigned SlabHeaderFree(unsigned h) + {return (h&0x000000ff);} + static inline unsigned SlabHeaderPagemap(unsigned h) + {return (h&0x00000f00)>>8;} + static inline unsigned SlabHeaderSize(unsigned h) + {return (h&0x0003f000)>>12;} + static inline unsigned SlabHeaderUsedm4(unsigned h) + {return (h&0x0ffc0000)>>18;} + /***paged allocator code***/ + void PagedInit(TInt aPagePower); + void* PagedAllocate(unsigned size); + void PagedFree(void* p); + void* PagedReallocate(void* p, unsigned size, TInt mode); + + bool PagedEncode(unsigned pos, unsigned npage); + unsigned PagedDecode(unsigned pos) const; + inline unsigned PagedSize(void* p) const; + inline bool PagedSetSize(void* p, unsigned size); + inline void PagedZapSize(void* p, unsigned size); + inline void* Bitmap2addr(unsigned pos) const; + void PagedInfo(struct HeapInfo* i, SWalkInfo* wi) const; + void ResetBitmap(); + TBool CheckBitmap(void* aBfr, TInt aSize, TUint32& aDummy, TInt& aNPages); + +private: + paged_bitmap iPageMap; // bitmap representing page allocator's pages + TUint8* iMemBase; // bottom of paged/slab memory (chunk base) + TUint8 iBitMapBuffer[MAXSMALLPAGEBITS>>3]; // buffer for initial page bitmap + TInt iSlabThreshold; // allocations < than this are done by the slab allocator + TInt iPageThreshold; // 2^n is smallest cell size allocated in paged allocator + TInt iSlabInitThreshold; // slab allocator will be used after chunk reaches this size + TUint32 iSlabConfigBits; // set of bits that specify which slab sizes to use + slab* iPartialPage; // partial-use page tree + slab* iFullSlab; // full slabs list (so we can find them when walking) + page* iSparePage; // cached, to avoid kernel exec calls for unmapping/remapping + TUint8 iSizeMap[(MAXSLABSIZE>>2)+1]; // index of slabset indexes based on size class + slabset iSlabAlloc[MAXSLABSIZE>>2]; // array of pointers to slabsets + +#endif // __KERNEL_MODE__ +}; + +#define HEAP_ASSERT(x) __ASSERT_DEBUG(x, HEAP_PANIC(ETHeapBadCellAddress)) + +template <class T> inline T Floor(const T addr, unsigned aln) +{return T((unsigned(addr))&~(aln-1));} +template <class T> inline T Ceiling(T addr, unsigned aln) +{return T((unsigned(addr)+(aln-1))&~(aln-1));} +template <class T> inline unsigned LowBits(T addr, unsigned aln) +{return unsigned(addr)&(aln-1);} +template <class T1, class T2> inline int PtrDiff(const T1* a1, const T2* a2) +{return reinterpret_cast<const unsigned char*>(a1) - reinterpret_cast<const unsigned char*>(a2);} +template <class T> inline T Offset(T addr, unsigned ofs) +{return T(unsigned(addr)+ofs);} + +#endif //__HEAP_HYBRID_H__ diff --git a/src/corelib/arch/symbian/newallocator.cpp b/src/corelib/arch/symbian/newallocator.cpp deleted file mode 100644 index 7025483..0000000 --- a/src/corelib/arch/symbian/newallocator.cpp +++ /dev/null @@ -1,2916 +0,0 @@ -/**************************************************************************** -** -** Copyright (C) 2009 Nokia Corporation and/or its subsidiary(-ies). -** All rights reserved. -** Contact: Nokia Corporation (qt-info@nokia.com) -** -** This file is part of the Symbian application wrapper of the Qt Toolkit. -** -** $QT_BEGIN_LICENSE:LGPL$ -** No Commercial Usage -** This file contains pre-release code and may not be distributed. -** You may use this file in accordance with the terms and conditions -** contained in the Technology Preview License Agreement accompanying -** this package. -** -** GNU Lesser General Public License Usage -** Alternatively, this file may be used under the terms of the GNU Lesser -** General Public License version 2.1 as published by the Free Software -** Foundation and appearing in the file LICENSE.LGPL included in the -** packaging of this file. Please review the following information to -** ensure the GNU Lesser General Public License version 2.1 requirements -** will be met: http://www.gnu.org/licenses/old-licenses/lgpl-2.1.html. -** -** In addition, as a special exception, Nokia gives you certain additional -** rights. These rights are described in the Nokia Qt LGPL Exception -** version 1.1, included in the file LGPL_EXCEPTION.txt in this package. -** -** If you have questions regarding the use of this file, please contact -** Nokia at qt-info@nokia.com. -** -** -** -** -** -** -** -** -** $QT_END_LICENSE$ -** -** The memory allocator is backported from Symbian OS, and can eventually -** be removed from Qt once it is built in to all supported OS versions. -** The allocator is a composite of three allocators: -** - A page allocator, for large allocations -** - A slab allocator, for small allocations -** - Doug Lea's allocator, for medium size allocations -****************************************************************************/ -#include <qglobal.h> -#include <e32std.h> -#include <e32cmn.h> -#include <hal.h> -#include <e32panic.h> - -#ifndef QT_SYMBIAN_HAVE_U32STD_H -struct SThreadCreateInfo - { - TAny* iHandle; - TInt iType; - TThreadFunction iFunction; - TAny* iPtr; - TAny* iSupervisorStack; - TInt iSupervisorStackSize; - TAny* iUserStack; - TInt iUserStackSize; - TInt iInitialThreadPriority; - TPtrC iName; - TInt iTotalSize; // Size including any extras (must be a multiple of 8 bytes) - }; - -struct SStdEpocThreadCreateInfo : public SThreadCreateInfo - { - RAllocator* iAllocator; - TInt iHeapInitialSize; - TInt iHeapMaxSize; - TInt iPadding; // Make structure size a multiple of 8 bytes - }; -#else -#include <u32std.h> -#endif -#include <e32svr.h> - -//Named local chunks require support from the kernel, which depends on Symbian^3 -#define NO_NAMED_LOCAL_CHUNKS -//Reserving a minimum heap size is not supported, because the implementation does not know what type of -//memory to use. DLA memory grows upwards, slab and page allocators grow downwards. -//This would need kernel support to do properly. -#define NO_RESERVE_MEMORY - -//The BTRACE debug framework requires Symbian OS 9.4 or higher. -//Required header files are not included in S60 5.0 SDKs, but -//they are available for open source versions of Symbian OS. -//Note that although Symbian OS 9.3 supports BTRACE, the usage in this file -//depends on 9.4 header files. - -//This debug flag uses BTRACE to emit debug traces to identify the heaps. -//Note that it uses the ETest1 trace category which is not reserved -//#define TRACING_HEAPS -//This debug flag uses BTRACE to emit debug traces to aid with debugging -//allocs, frees & reallocs. It should be used together with the KUSERHEAPTRACE -//kernel trace flag to enable heap tracing. -//#define TRACING_ALLOCS -//This debug flag turns on tracing of the call stack for each alloc trace. -//It is dependent on TRACING_ALLOCS. -//#define TRACING_CALLSTACKS - -#if defined(TRACING_ALLOCS) || defined(TRACING_HEAPS) -#include <e32btrace.h> -#endif - -#ifndef __WINS__ -#pragma push -#pragma arm -#endif - -#ifdef QT_USE_NEW_SYMBIAN_ALLOCATOR - -#include "dla_p.h" -#include "newallocator_p.h" - -// if non zero this causes the slabs 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) - -_LIT(KDLHeapPanicCategory, "DL Heap"); -#define GET_PAGE_SIZE(x) HAL::Get(HALData::EMemoryPageSize, x) -#define __CHECK_CELL(p) -#define __POWER_OF_2(x) ((TUint32)((x)^((x)-1))>=(TUint32)(x)) -#define HEAP_PANIC(r) Panic(r) - -LOCAL_C void Panic(TCdtPanic aPanic) -// Panic the process with USER as the category. - { - User::Panic(_L("USER"),aPanic); - } - -#define STACKSIZE 32 -inline void RNewAllocator::TraceCallStack() -{ -#ifdef TRACING_CALLSTACKS - TUint32 filteredStack[STACKSIZE]; - TThreadStackInfo info; - TUint32 *sp = (TUint32*)&sp; - RThread().StackInfo(info); - Lock(); - TInt i; - for (i=0;i<STACKSIZE;i++) { - if ((TLinAddr)sp>=info.iBase) break; - while ((TLinAddr)sp < info.iBase) { - TUint32 cur = *sp++; - TUint32 range = cur & 0xF0000000; - if (range == 0x80000000 || range == 0x70000000) { - filteredStack[i] = cur; - break; - } - } - } - Unlock(); - BTraceContextBig(BTrace::EHeap, BTrace::EHeapCallStack, (TUint32)this, filteredStack, i * 4); -#endif -} - -size_t getpagesize() -{ - TInt size; - TInt err = GET_PAGE_SIZE(size); - if(err != KErrNone) - return (size_t)0x1000; - return (size_t)size; -} - -#define gm (&iGlobalMallocState) - -RNewAllocator::RNewAllocator(TInt aMaxLength, TInt aAlign, TBool aSingleThread) -// constructor for a fixed heap. Just use DL allocator - :iMinLength(aMaxLength), iMaxLength(aMaxLength), iOffset(0), iGrowBy(0), iChunkHandle(0), - iNestingLevel(0), iAllocCount(0), iFailType(ENone), iTestData(NULL), iChunkSize(aMaxLength) - { - - if ((TUint32)aAlign>=sizeof(TAny*) && __POWER_OF_2(iAlign)) - { - iAlign = aAlign; - } - else - { - iAlign = 4; - } - iPageSize = 0; - iFlags = aSingleThread ? (ESingleThreaded|EFixedSize) : EFixedSize; - - Init(0, 0, 0); - } - -RNewAllocator::RNewAllocator(TInt aChunkHandle, TInt aOffset, TInt aMinLength, TInt aMaxLength, TInt aGrowBy, - TInt aAlign, TBool aSingleThread) - : iMinLength(aMinLength), iMaxLength(aMaxLength), iOffset(aOffset), iChunkHandle(aChunkHandle), iAlign(aAlign), iNestingLevel(0), iAllocCount(0), - iFailType(ENone), iTestData(NULL), iChunkSize(aMinLength),iHighWaterMark(aMinLength) - { - iPageSize = malloc_getpagesize; - __ASSERT_ALWAYS(aOffset >=0, User::Panic(KDLHeapPanicCategory, ETHeapNewBadOffset)); - iGrowBy = _ALIGN_UP(aGrowBy, iPageSize); - iFlags = aSingleThread ? ESingleThreaded : 0; - - // Initialise - // if the heap is created with aMinLength==aMaxLength then it cannot allocate slab or page memory - // so these sub-allocators should be disabled. Otherwise initialise with default values - if (aMinLength == aMaxLength) - Init(0, 0, 0); - else - Init(0xabe, 16, iPageSize*4); // slabs {48, 40, 32, 24, 20, 16, 12, 8}, page {64KB}, trim {16KB} -#ifdef TRACING_HEAPS - RChunk chunk; - chunk.SetHandle(iChunkHandle); - TKName chunk_name; - chunk.FullName(chunk_name); - BTraceContextBig(BTrace::ETest1, 2, 22, chunk_name.Ptr(), chunk_name.Size()); - - TUint32 traceData[4]; - traceData[0] = iChunkHandle; - traceData[1] = iMinLength; - traceData[2] = iMaxLength; - traceData[3] = iAlign; - BTraceContextN(BTrace::ETest1, 1, (TUint32)this, 11, traceData, sizeof(traceData)); -#endif - - } - -TAny* RNewAllocator::operator new(TUint aSize, TAny* aBase) __NO_THROW - { - __ASSERT_ALWAYS(aSize>=sizeof(RNewAllocator), HEAP_PANIC(ETHeapNewBadSize)); - RNewAllocator* h = (RNewAllocator*)aBase; - h->iAlign = 0x80000000; // garbage value - h->iBase = ((TUint8*)aBase) + aSize; - return aBase; - } - -void RNewAllocator::Init(TInt aBitmapSlab, TInt aPagePower, size_t aTrimThreshold) - { - __ASSERT_ALWAYS((TUint32)iAlign>=sizeof(TAny*) && __POWER_OF_2(iAlign), HEAP_PANIC(ETHeapNewBadAlignment)); - - /*Moved code which does initialization */ - iTop = (TUint8*)this + iMinLength; - iAllocCount = 0; - memset(&mparams,0,sizeof(mparams)); - - Init_Dlmalloc(iTop - iBase, 0, aTrimThreshold); - - slab_init(); - slab_config_bits = aBitmapSlab; -#ifdef DELAYED_SLAB_THRESHOLD - if (iChunkSize < DELAYED_SLAB_THRESHOLD) - { - slab_init_threshold = DELAYED_SLAB_THRESHOLD; - } - else -#endif // DELAYED_SLAB_THRESHOLD - { - slab_init_threshold = KMaxTUint; - slab_config(aBitmapSlab); - } - - /*10-1K,11-2K,12-4k,13-8K,14-16K,15-32K,16-64K*/ - paged_init(aPagePower); - -#ifdef TRACING_ALLOCS - TUint32 traceData[3]; - traceData[0] = aBitmapSlab; - traceData[1] = aPagePower; - traceData[2] = aTrimThreshold; - BTraceContextN(BTrace::ETest1, BTrace::EHeapAlloc, (TUint32)this, 0, traceData, sizeof(traceData)); -#endif - - } - -RNewAllocator::SCell* RNewAllocator::GetAddress(const TAny* aCell) const -// -// As much as possible, check a cell address and backspace it -// to point at the cell header. -// - { - - TLinAddr m = TLinAddr(iAlign - 1); - __ASSERT_ALWAYS(!(TLinAddr(aCell)&m), HEAP_PANIC(ETHeapBadCellAddress)); - - SCell* pC = (SCell*)(((TUint8*)aCell)-EAllocCellSize); - __CHECK_CELL(pC); - - return pC; - } - -TInt RNewAllocator::AllocLen(const TAny* aCell) const -{ - if (ptrdiff(aCell, this) >= 0) - { - mchunkptr m = mem2chunk(aCell); - return chunksize(m) - overhead_for(m); - } - if (lowbits(aCell, pagesize) > cellalign) - return header_size(slab::slabfor(aCell)->header); - if (lowbits(aCell, pagesize) == cellalign) - return *(unsigned*)(offset(aCell,-int(cellalign)))-cellalign; - return paged_descriptor(aCell)->size; -} - -TAny* RNewAllocator::Alloc(TInt aSize) -{ - __ASSERT_ALWAYS((TUint)aSize<(KMaxTInt/2),HEAP_PANIC(ETHeapBadAllocatedCellSize)); - - TAny* addr; - -#ifdef TRACING_ALLOCS - TInt aCnt=0; -#endif - Lock(); - if (aSize < slab_threshold) - { - TInt ix = sizemap[(aSize+3)>>2]; - ASSERT(ix != 0xff); - addr = slab_allocate(slaballoc[ix]); - }else if((aSize >> page_threshold)==0) - { -#ifdef TRACING_ALLOCS - aCnt=1; -#endif - addr = dlmalloc(aSize); - } - else - { -#ifdef TRACING_ALLOCS - aCnt=2; -#endif - addr = paged_allocate(aSize); - } - - iCellCount++; - iTotalAllocSize += aSize; - Unlock(); - -#ifdef TRACING_ALLOCS - if (iFlags & ETraceAllocs) - { - TUint32 traceData[3]; - traceData[0] = AllocLen(addr); - traceData[1] = aSize; - traceData[2] = aCnt; - BTraceContextN(BTrace::EHeap, BTrace::EHeapAlloc, (TUint32)this, (TUint32)addr, traceData, sizeof(traceData)); - TraceCallStack(); - } -#endif - - return addr; -} - -TInt RNewAllocator::Compress() - { - if (iFlags & EFixedSize) - return 0; - - Lock(); - dlmalloc_trim(0); - if (spare_page) - { - unmap(spare_page,pagesize); - spare_page = 0; - } - Unlock(); - return 0; - } - -void RNewAllocator::Free(TAny* aPtr) -{ - -#ifdef TRACING_ALLOCS - TInt aCnt=0; -#endif -#ifdef ENABLE_DEBUG_TRACE - RThread me; - TBuf<100> thName; - me.FullName(thName); -#endif - //if (!aPtr) return; //return in case of NULL pointer - - Lock(); - - if (!aPtr) - ; - else if (ptrdiff(aPtr, this) >= 0) - { -#ifdef TRACING_ALLOCS - aCnt = 1; -#endif - dlfree( aPtr); - } - else if (lowbits(aPtr, pagesize) <= cellalign) - { -#ifdef TRACING_ALLOCS - aCnt = 2; -#endif - paged_free(aPtr); - } - else - { -#ifdef TRACING_ALLOCS - aCnt = 0; -#endif - slab_free(aPtr); - } - iCellCount--; - Unlock(); - -#ifdef TRACING_ALLOCS - if (iFlags & ETraceAllocs) - { - TUint32 traceData; - traceData = aCnt; - BTraceContextN(BTrace::EHeap, BTrace::EHeapFree, (TUint32)this, (TUint32)aPtr, &traceData, sizeof(traceData)); - TraceCallStack(); - } -#endif -} - - -void RNewAllocator::Reset() - { - // TODO free everything - User::Panic(_L("RNewAllocator"), 1); //this should never be called - } - -#ifdef TRACING_ALLOCS -inline void RNewAllocator::TraceReAlloc(TAny* aPtr, TInt aSize, TAny* aNewPtr, TInt aZone) -{ - if (aNewPtr && (iFlags & ETraceAllocs)) { - TUint32 traceData[3]; - traceData[0] = AllocLen(aNewPtr); - traceData[1] = aSize; - traceData[2] = (TUint32) aPtr; - BTraceContextN(BTrace::EHeap, BTrace::EHeapReAlloc, (TUint32) this, (TUint32) aNewPtr, - traceData, sizeof(traceData)); - TraceCallStack(); - //workaround for SAW not handling reallocs properly - if (aZone >= 0 && aPtr != aNewPtr) { - BTraceContextN(BTrace::EHeap, BTrace::EHeapFree, (TUint32) this, (TUint32) aPtr, - &aZone, sizeof(aZone)); - TraceCallStack(); - } - } -} -#else -//Q_UNUSED generates code that prevents the compiler optimising out the empty inline function -inline void RNewAllocator::TraceReAlloc(TAny* , TInt , TAny* , TInt ) -{} -#endif - -TAny* RNewAllocator::ReAlloc(TAny* aPtr, TInt aSize, TInt /*aMode = 0*/) - { - if(ptrdiff(aPtr,this)>=0) - { - // original cell is in DL zone - if(aSize >= slab_threshold && (aSize>>page_threshold)==0) - { - // and so is the new one - Lock(); - TAny* addr = dlrealloc(aPtr,aSize); - Unlock(); - TraceReAlloc(aPtr, aSize, addr, 0); - return addr; - } - } - else if(lowbits(aPtr,pagesize)<=cellalign) - { - // original cell is either NULL or in paged zone - if (!aPtr) - return Alloc(aSize); - if(aSize >> page_threshold) - { - // and so is the new one - Lock(); - TAny* addr = paged_reallocate(aPtr,aSize); - Unlock(); - TraceReAlloc(aPtr, aSize, addr, 2); - return addr; - } - } - else - { - // original cell is in slab znoe - if(aSize <= header_size(slab::slabfor(aPtr)->header)) { - TraceReAlloc(aPtr, aSize, aPtr, 1); - return aPtr; - } - } - TAny* newp = Alloc(aSize); - if(newp) - { - TInt oldsize = AllocLen(aPtr); - memcpy(newp,aPtr,oldsize<aSize?oldsize:aSize); - Free(aPtr); - } - return newp; - } - -TInt RNewAllocator::Available(TInt& aBiggestBlock) const -{ - //TODO: consider page and slab allocators - - //this gets free space in DL region - the C ported code doesn't respect const yet. - RNewAllocator* self = const_cast<RNewAllocator*> (this); - mallinfo info = self->dlmallinfo(); - aBiggestBlock = info.largestBlock; - return info.fordblks; -} -TInt RNewAllocator::AllocSize(TInt& aTotalAllocSize) const -{ - aTotalAllocSize = iTotalAllocSize; - return iCellCount; -} - -TInt RNewAllocator::DebugFunction(TInt aFunc, TAny* a1, TAny* /*a2*/) - { - TInt r = KErrNotSupported; - TInt* a1int = reinterpret_cast<TInt*>(a1); - switch(aFunc) { - case RAllocator::ECount: - { - struct mallinfo mi = dlmallinfo(); - *a1int = mi.fordblks; - r = mi.uordblks; - } - break; - case RAllocator::EMarkStart: - case RAllocator::EMarkEnd: - case RAllocator::ESetFail: - case RAllocator::ECheck: - r = KErrNone; - break; - } - return r; - } - -TInt RNewAllocator::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 -int RNewAllocator::init_mparams(size_t aTrimThreshold /*= DEFAULT_TRIM_THRESHOLD*/) -{ - if (mparams.page_size == 0) - { - size_t s; - mparams.mmap_threshold = DEFAULT_MMAP_THRESHOLD; - mparams.trim_threshold = aTrimThreshold; - #if MORECORE_CONTIGUOUS - mparams.default_mflags = USE_LOCK_BIT|USE_MMAP_BIT; - #else /* MORECORE_CONTIGUOUS */ - mparams.default_mflags = USE_LOCK_BIT|USE_MMAP_BIT|USE_NONCONTIGUOUS_BIT; - #endif /* MORECORE_CONTIGUOUS */ - - s = (size_t)0x58585858U; - ACQUIRE_MAGIC_INIT_LOCK(&mparams); - if (mparams.magic == 0) { - mparams.magic = s; - /* Set up lock for main malloc area */ - INITIAL_LOCK(&gm->mutex); - gm->mflags = mparams.default_mflags; - } - RELEASE_MAGIC_INIT_LOCK(&mparams); - - mparams.page_size = malloc_getpagesize; - - mparams.granularity = ((DEFAULT_GRANULARITY != 0)? - DEFAULT_GRANULARITY : mparams.page_size); - - /* Sanity-check configuration: - size_t must be unsigned and as wide as pointer type. - ints must be at least 4 bytes. - alignment must be at least 8. - Alignment, min chunk size, and page size must all be powers of 2. - */ - - if ((sizeof(size_t) != sizeof(TUint8*)) || - (MAX_SIZE_T < MIN_CHUNK_SIZE) || - (sizeof(int) < 4) || - (MALLOC_ALIGNMENT < (size_t)8U) || - ((MALLOC_ALIGNMENT & (MALLOC_ALIGNMENT-SIZE_T_ONE)) != 0) || - ((MCHUNK_SIZE & (MCHUNK_SIZE-SIZE_T_ONE)) != 0) || - ((mparams.granularity & (mparams.granularity-SIZE_T_ONE)) != 0) || - ((mparams.page_size & (mparams.page_size-SIZE_T_ONE)) != 0)) - ABORT; - } - return 0; -} - -void RNewAllocator::init_bins(mstate m) { - /* Establish circular links for smallbins */ - bindex_t i; - for (i = 0; i < NSMALLBINS; ++i) { - sbinptr bin = smallbin_at(m,i); - bin->fd = bin->bk = bin; - } -} -/* ---------------------------- malloc support --------------------------- */ - -/* allocate a large request from the best fitting chunk in a treebin */ -void* RNewAllocator::tmalloc_large(mstate m, size_t nb) { - tchunkptr v = 0; - size_t rsize = -nb; /* Unsigned negation */ - tchunkptr t; - bindex_t idx; - compute_tree_index(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->child[1]; - t = t->child[(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->treemap; - if (leftbits != 0) { - bindex_t i; - binmap_t leastbit = least_bit(leftbits); - compute_bit2idx(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 dv is a better fit, return 0 so malloc will use it */ - if (v != 0 && rsize < (size_t)(m->dvsize - nb)) { - if (RTCHECK(ok_address(m, v))) { /* split */ - mchunkptr r = chunk_plus_offset(v, nb); - assert(chunksize(v) == rsize + nb); - if (RTCHECK(ok_next(v, r))) { - unlink_large_chunk(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); - insert_chunk(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* RNewAllocator::tmalloc_small(mstate m, size_t nb) { - tchunkptr t, v; - size_t rsize; - bindex_t i; - binmap_t leastbit = least_bit(m->treemap); - compute_bit2idx(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); - assert(chunksize(v) == rsize + nb); - if (RTCHECK(ok_next(v, r))) { - unlink_large_chunk(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); - replace_dv(m, r, rsize); - } - return chunk2mem(v); - } - } - CORRUPTION_ERROR_ACTION(m); - return 0; -} - -void RNewAllocator::init_top(mstate m, mchunkptr p, size_t psize) -{ - /* Ensure alignment */ - size_t offset = align_offset(chunk2mem(p)); - p = (mchunkptr)((TUint8*)p + offset); - psize -= offset; - m->top = p; - m->topsize = psize; - p->head = psize | PINUSE_BIT; - /* set size of fake trailing chunk holding overhead space only once */ - mchunkptr chunkPlusOff = chunk_plus_offset(p, psize); - chunkPlusOff->head = TOP_FOOT_SIZE; - m->trim_check = mparams.trim_threshold; /* reset on each update */ -} - -void* RNewAllocator::internal_realloc(mstate m, void* oldmem, size_t bytes) -{ - if (bytes >= MAX_REQUEST) { - MALLOC_FAILURE_ACTION; - return 0; - } - if (!PREACTION(m)) { - 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 top. Else malloc-copy-free */ - - if (RTCHECK(ok_address(m, oldp) && ok_cinuse(oldp) && - ok_next(oldp, next) && ok_pinuse(next))) { - size_t nb = request2size(bytes); - if (is_mmapped(oldp)) - newp = mmap_resize(m, oldp, nb); - else - 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(m, newp, nb); - set_inuse(m, remainder, rsize); - extra = chunk2mem(remainder); - } - } - /*AMOD: Modified to optimized*/ - else if (next == m->top && oldsize + m->topsize > nb) - { - /* Expand into top */ - if(oldsize + m->topsize > nb) - { - size_t newsize = oldsize + m->topsize; - size_t newtopsize = newsize - nb; - mchunkptr newtop = chunk_plus_offset(oldp, nb); - set_inuse(m, oldp, nb); - newtop->head = newtopsize |PINUSE_BIT; - m->top = newtop; - m->topsize = newtopsize; - newp = oldp; - } - } - } - else { - USAGE_ERROR_ACTION(m, oldmem); - POSTACTION(m); - return 0; - } - - POSTACTION(m); - - if (newp != 0) { - if (extra != 0) { - internal_free(m, extra); - } - check_inuse_chunk(m, newp); - return chunk2mem(newp); - } - else { - void* newmem = internal_malloc(m, bytes); - if (newmem != 0) { - size_t oc = oldsize - overhead_for(oldp); - memcpy(newmem, oldmem, (oc < bytes)? oc : bytes); - internal_free(m, oldmem); - } - return newmem; - } - } - return 0; -} -/* ----------------------------- statistics ------------------------------ */ -mallinfo RNewAllocator::internal_mallinfo(mstate m) { - struct mallinfo nm = { 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0 }; - TInt chunkCnt = 0; - if (!PREACTION(m)) { - check_malloc_state(m); - if (is_initialized(m)) { - size_t nfree = SIZE_T_ONE; /* top always free */ - size_t mfree = m->topsize + TOP_FOOT_SIZE; - size_t sum = mfree; - msegmentptr s = &m->seg; - while (s != 0) { - mchunkptr q = align_as_chunk(s->base); - chunkCnt++; - while (segment_holds(s, q) && - q != m->top && q->head != FENCEPOST_HEAD) { - size_t sz = chunksize(q); - sum += sz; - if (!cinuse(q)) { - if (sz > nm.largestBlock) - nm.largestBlock = sz; - mfree += sz; - ++nfree; - } - q = next_chunk(q); - } - s = s->next; - } - nm.arena = sum; - nm.ordblks = nfree; - nm.hblkhd = m->footprint - sum; - nm.usmblks = m->max_footprint; - nm.uordblks = m->footprint - mfree; - nm.fordblks = mfree; - nm.keepcost = m->topsize; - nm.cellCount= chunkCnt;/*number of chunks allocated*/ - } - POSTACTION(m); - } - return nm; -} - -void RNewAllocator::internal_malloc_stats(mstate m) { -if (!PREACTION(m)) { - size_t fp = 0; - size_t used = 0; - check_malloc_state(m); - if (is_initialized(m)) { - msegmentptr s = &m->seg; - size_t maxfp = m->max_footprint; - fp = m->footprint; - used = fp - (m->topsize + TOP_FOOT_SIZE); - - while (s != 0) { - mchunkptr q = align_as_chunk(s->base); - while (segment_holds(s, q) && - q != m->top && q->head != FENCEPOST_HEAD) { - if (!cinuse(q)) - used -= chunksize(q); - q = next_chunk(q); - } - s = s->next; - } - } - POSTACTION(m); -} -} -/* support for mallopt */ -int RNewAllocator::change_mparam(int param_number, int value) { - size_t val = (size_t)value; - init_mparams(DEFAULT_TRIM_THRESHOLD); - switch(param_number) { - case M_TRIM_THRESHOLD: - mparams.trim_threshold = val; - return 1; - case M_GRANULARITY: - if (val >= mparams.page_size && ((val & (val-1)) == 0)) { - mparams.granularity = val; - return 1; - } - else - return 0; - case M_MMAP_THRESHOLD: - mparams.mmap_threshold = val; - return 1; - default: - return 0; - } -} -/* Get memory from system using MORECORE or MMAP */ -void* RNewAllocator::sys_alloc(mstate m, size_t nb) -{ - TUint8* tbase = CMFAIL; - size_t tsize = 0; - flag_t mmap_flag = 0; - //init_mparams();/*No need to do init_params here*/ - /* Directly map large chunks */ - if (use_mmap(m) && nb >= mparams.mmap_threshold) - { - void* mem = mmap_alloc(m, nb); - if (mem != 0) - return mem; - } - /* - Try getting memory in any of three ways (in most-preferred to - least-preferred order): - 1. A call to MORECORE that can normally contiguously extend memory. - (disabled if not MORECORE_CONTIGUOUS or not HAVE_MORECORE or - or main space is mmapped or a previous contiguous call failed) - 2. A call to MMAP new space (disabled if not HAVE_MMAP). - Note that under the default settings, if MORECORE is unable to - fulfill a request, and HAVE_MMAP is true, then mmap is - used as a noncontiguous system allocator. This is a useful backup - strategy for systems with holes in address spaces -- in this case - sbrk cannot contiguously expand the heap, but mmap may be able to - find space. - 3. A call to MORECORE that cannot usually contiguously extend memory. - (disabled if not HAVE_MORECORE) - */ - /*Trying to allocate the memory*/ - if(MORECORE_CONTIGUOUS && !use_noncontiguous(m)) - { - TUint8* br = CMFAIL; - msegmentptr ss = (m->top == 0)? 0 : segment_holding(m, (TUint8*)m->top); - size_t asize = 0; - ACQUIRE_MORECORE_LOCK(m); - if (ss == 0) - { /* First time through or recovery */ - TUint8* base = (TUint8*)CALL_MORECORE(0); - if (base != CMFAIL) - { - asize = granularity_align(nb + TOP_FOOT_SIZE + SIZE_T_ONE); - /* Adjust to end on a page boundary */ - if (!is_page_aligned(base)) - asize += (page_align((size_t)base) - (size_t)base); - /* Can't call MORECORE if size is negative when treated as signed */ - if (asize < HALF_MAX_SIZE_T &&(br = (TUint8*)(CALL_MORECORE(asize))) == base) - { - tbase = base; - tsize = asize; - } - } - } - else - { - /* Subtract out existing available top space from MORECORE request. */ - asize = granularity_align(nb - m->topsize + TOP_FOOT_SIZE + SIZE_T_ONE); - /* Use mem here only if it did continuously extend old space */ - if (asize < HALF_MAX_SIZE_T && - (br = (TUint8*)(CALL_MORECORE(asize))) == ss->base+ss->size) { - tbase = br; - tsize = asize; - } - } - if (tbase == CMFAIL) { /* Cope with partial failure */ - if (br != CMFAIL) { /* Try to use/extend the space we did get */ - if (asize < HALF_MAX_SIZE_T && - asize < nb + TOP_FOOT_SIZE + SIZE_T_ONE) { - size_t esize = granularity_align(nb + TOP_FOOT_SIZE + SIZE_T_ONE - asize); - if (esize < HALF_MAX_SIZE_T) { - TUint8* end = (TUint8*)CALL_MORECORE(esize); - if (end != CMFAIL) - asize += esize; - else { /* Can't use; try to release */ - CALL_MORECORE(-asize); - br = CMFAIL; - } - } - } - } - if (br != CMFAIL) { /* Use the space we did get */ - tbase = br; - tsize = asize; - } - else - disable_contiguous(m); /* Don't try contiguous path in the future */ - } - RELEASE_MORECORE_LOCK(m); - } - if (HAVE_MMAP && tbase == CMFAIL) { /* Try MMAP */ - size_t req = nb + TOP_FOOT_SIZE + SIZE_T_ONE; - size_t rsize = granularity_align(req); - if (rsize > nb) { /* Fail if wraps around zero */ - TUint8* mp = (TUint8*)(CALL_MMAP(rsize)); - if (mp != CMFAIL) { - tbase = mp; - tsize = rsize; - mmap_flag = IS_MMAPPED_BIT; - } - } - } - if (HAVE_MORECORE && tbase == CMFAIL) { /* Try noncontiguous MORECORE */ - size_t asize = granularity_align(nb + TOP_FOOT_SIZE + SIZE_T_ONE); - if (asize < HALF_MAX_SIZE_T) { - TUint8* br = CMFAIL; - TUint8* end = CMFAIL; - ACQUIRE_MORECORE_LOCK(m); - br = (TUint8*)(CALL_MORECORE(asize)); - end = (TUint8*)(CALL_MORECORE(0)); - RELEASE_MORECORE_LOCK(m); - if (br != CMFAIL && end != CMFAIL && br < end) { - size_t ssize = end - br; - if (ssize > nb + TOP_FOOT_SIZE) { - tbase = br; - tsize = ssize; - } - } - } - } - if (tbase != CMFAIL) { - if ((m->footprint += tsize) > m->max_footprint) - m->max_footprint = m->footprint; - if (!is_initialized(m)) { /* first-time initialization */ - m->seg.base = m->least_addr = tbase; - m->seg.size = tsize; - m->seg.sflags = mmap_flag; - m->magic = mparams.magic; - init_bins(m); - if (is_global(m)) - init_top(m, (mchunkptr)tbase, tsize - TOP_FOOT_SIZE); - else { - /* Offset top by embedded malloc_state */ - mchunkptr mn = next_chunk(mem2chunk(m)); - init_top(m, mn, (size_t)((tbase + tsize) - (TUint8*)mn) -TOP_FOOT_SIZE); - } - }else { - /* Try to merge with an existing segment */ - msegmentptr sp = &m->seg; - while (sp != 0 && tbase != sp->base + sp->size) - sp = sp->next; - if (sp != 0 && !is_extern_segment(sp) && - (sp->sflags & IS_MMAPPED_BIT) == mmap_flag && - segment_holds(sp, m->top)) - { /* append */ - sp->size += tsize; - init_top(m, m->top, m->topsize + tsize); - } - else { - if (tbase < m->least_addr) - m->least_addr = tbase; - sp = &m->seg; - while (sp != 0 && sp->base != tbase + tsize) - sp = sp->next; - if (sp != 0 && - !is_extern_segment(sp) && - (sp->sflags & IS_MMAPPED_BIT) == mmap_flag) { - TUint8* oldbase = sp->base; - sp->base = tbase; - sp->size += tsize; - return prepend_alloc(m, tbase, oldbase, nb); - } - else - add_segment(m, tbase, tsize, mmap_flag); - } - } - if (nb < m->topsize) { /* Allocate from new or extended top space */ - size_t rsize = m->topsize -= nb; - mchunkptr p = m->top; - mchunkptr r = m->top = chunk_plus_offset(p, nb); - r->head = rsize | PINUSE_BIT; - set_size_and_pinuse_of_inuse_chunk(m, p, nb); - check_top_chunk(m, m->top); - check_malloced_chunk(m, chunk2mem(p), nb); - return chunk2mem(p); - } - } - /*need to check this*/ - //errno = -1; - return 0; -} -msegmentptr RNewAllocator::segment_holding(mstate m, TUint8* addr) { - msegmentptr sp = &m->seg; - for (;;) { - if (addr >= sp->base && addr < sp->base + sp->size) - return sp; - if ((sp = sp->next) == 0) - return 0; - } -} -/* Unlink the first chunk from a smallbin */ -inline void RNewAllocator::unlink_first_small_chunk(mstate M,mchunkptr B,mchunkptr P,bindex_t& I) -{ - mchunkptr F = P->fd; - assert(P != B); - assert(P != F); - assert(chunksize(P) == small_index2size(I)); - if (B == F) - clear_smallmap(M, I); - else if (RTCHECK(ok_address(M, F))) { - B->fd = F; - F->bk = B; - } - else { - CORRUPTION_ERROR_ACTION(M); - } -} -/* Link a free chunk into a smallbin */ -inline void RNewAllocator::insert_small_chunk(mstate M,mchunkptr P, size_t S) -{ - bindex_t I = small_index(S); - mchunkptr B = smallbin_at(M, I); - mchunkptr F = B; - assert(S >= MIN_CHUNK_SIZE); - if (!smallmap_is_marked(M, I)) - mark_smallmap(M, I); - else if (RTCHECK(ok_address(M, B->fd))) - F = B->fd; - else { - CORRUPTION_ERROR_ACTION(M); - } - B->fd = P; - F->bk = P; - P->fd = F; - P->bk = B; -} - - -inline void RNewAllocator::insert_chunk(mstate M,mchunkptr P,size_t S) -{ - if (is_small(S)) - insert_small_chunk(M, P, S); - else{ - tchunkptr TP = (tchunkptr)(P); insert_large_chunk(M, TP, S); - } -} - -inline void RNewAllocator::unlink_large_chunk(mstate M,tchunkptr X) -{ - tchunkptr XP = X->parent; - tchunkptr R; - if (X->bk != X) { - tchunkptr F = X->fd; - R = X->bk; - if (RTCHECK(ok_address(M, F))) { - F->bk = R; - R->fd = F; - } - else { - CORRUPTION_ERROR_ACTION(M); - } - } - else { - tchunkptr* RP; - if (((R = *(RP = &(X->child[1]))) != 0) || - ((R = *(RP = &(X->child[0]))) != 0)) { - tchunkptr* CP; - while ((*(CP = &(R->child[1])) != 0) || - (*(CP = &(R->child[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->index); - if (X == *H) { - if ((*H = R) == 0) - clear_treemap(M, X->index); - } - else if (RTCHECK(ok_address(M, XP))) { - if (XP->child[0] == X) - XP->child[0] = R; - else - XP->child[1] = R; - } - else - CORRUPTION_ERROR_ACTION(M); - if (R != 0) { - if (RTCHECK(ok_address(M, R))) { - tchunkptr C0, C1; - R->parent = XP; - if ((C0 = X->child[0]) != 0) { - if (RTCHECK(ok_address(M, C0))) { - R->child[0] = C0; - C0->parent = R; - } - else - CORRUPTION_ERROR_ACTION(M); - } - if ((C1 = X->child[1]) != 0) { - if (RTCHECK(ok_address(M, C1))) { - R->child[1] = C1; - C1->parent = R; - } - else - CORRUPTION_ERROR_ACTION(M); - } - } - else - CORRUPTION_ERROR_ACTION(M); - } - } -} - -/* Unlink a chunk from a smallbin */ -inline void RNewAllocator::unlink_small_chunk(mstate M, mchunkptr P,size_t S) -{ - mchunkptr F = P->fd; - mchunkptr B = P->bk; - bindex_t I = small_index(S); - assert(P != B); - assert(P != F); - 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->bk = B; - B->fd = F; - } - else { - CORRUPTION_ERROR_ACTION(M); - } -} - -inline void RNewAllocator::unlink_chunk(mstate M, mchunkptr P, size_t S) -{ - if (is_small(S)) - unlink_small_chunk(M, P, S); - else - { - tchunkptr TP = (tchunkptr)(P); unlink_large_chunk(M, TP); - } -} - -inline void RNewAllocator::compute_tree_index(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 RNewAllocator::insert_large_chunk(mstate M,tchunkptr X,size_t S) -{ - tbinptr* H; - bindex_t I; - compute_tree_index(S, I); - H = treebin_at(M, I); - X->index = I; - X->child[0] = X->child[1] = 0; - if (!treemap_is_marked(M, I)) { - mark_treemap(M, I); - *H = X; - X->parent = (tchunkptr)H; - X->fd = X->bk = X; - } - else { - tchunkptr T = *H; - size_t K = S << leftshift_for_tree_index(I); - for (;;) { - if (chunksize(T) != S) { - tchunkptr* C = &(T->child[(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->parent = T; - X->fd = X->bk = X; - break; - } - else { - CORRUPTION_ERROR_ACTION(M); - break; - } - } - else { - tchunkptr F = T->fd; - if (RTCHECK(ok_address(M, T) && ok_address(M, F))) { - T->fd = F->bk = X; - X->fd = F; - X->bk = T; - X->parent = 0; - break; - } - else { - CORRUPTION_ERROR_ACTION(M); - break; - } - } - } - } -} - -/* - Unlink steps: - - 1. If x is a chained node, unlink it from its same-sized fd/bk links - and choose its bk 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 parent links) relink - x's parent and children to x's replacement (or null if none). -*/ - -/* Replace dv node, binning the old one */ -/* Used only when dvsize known to be small */ -inline void RNewAllocator::replace_dv(mstate M, mchunkptr P, size_t S) -{ - size_t DVS = M->dvsize; - if (DVS != 0) { - mchunkptr DV = M->dv; - assert(is_small(DVS)); - insert_small_chunk(M, DV, DVS); - } - M->dvsize = S; - M->dv = P; -} - -inline void RNewAllocator::compute_bit2idx(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); -} - -void RNewAllocator::add_segment(mstate m, TUint8* tbase, size_t tsize, flag_t mmapped) { - /* Determine locations and sizes of segment, fenceposts, old top */ - TUint8* old_top = (TUint8*)m->top; - msegmentptr oldsp = segment_holding(m, old_top); - TUint8* old_end = oldsp->base + oldsp->size; - size_t ssize = pad_request(sizeof(struct malloc_segment)); - TUint8* rawsp = old_end - (ssize + FOUR_SIZE_T_SIZES + CHUNK_ALIGN_MASK); - size_t offset = align_offset(chunk2mem(rawsp)); - TUint8* asp = rawsp + offset; - TUint8* csp = (asp < (old_top + MIN_CHUNK_SIZE))? old_top : asp; - mchunkptr sp = (mchunkptr)csp; - msegmentptr ss = (msegmentptr)(chunk2mem(sp)); - mchunkptr tnext = chunk_plus_offset(sp, ssize); - mchunkptr p = tnext; - int nfences = 0; - - /* reset top to new space */ - init_top(m, (mchunkptr)tbase, tsize - TOP_FOOT_SIZE); - - /* Set up segment record */ - assert(is_aligned(ss)); - set_size_and_pinuse_of_inuse_chunk(m, sp, ssize); - *ss = m->seg; /* Push current record */ - m->seg.base = tbase; - m->seg.size = tsize; - m->seg.sflags = mmapped; - m->seg.next = ss; - - /* Insert trailing fenceposts */ - for (;;) { - mchunkptr nextp = chunk_plus_offset(p, SIZE_T_SIZE); - p->head = FENCEPOST_HEAD; - ++nfences; - if ((TUint8*)(&(nextp->head)) < old_end) - p = nextp; - else - break; - } - assert(nfences >= 2); - - /* Insert the rest of old top into a bin as an ordinary free chunk */ - if (csp != old_top) { - mchunkptr q = (mchunkptr)old_top; - size_t psize = csp - old_top; - mchunkptr tn = chunk_plus_offset(q, psize); - set_free_with_pinuse(q, psize, tn); - insert_chunk(m, q, psize); - } - - check_top_chunk(m, m->top); -} - - -void* RNewAllocator::prepend_alloc(mstate m, TUint8* newbase, TUint8* oldbase, - size_t nb) { - mchunkptr p = align_as_chunk(newbase); - mchunkptr oldfirst = align_as_chunk(oldbase); - size_t psize = (TUint8*)oldfirst - (TUint8*)p; - mchunkptr q = chunk_plus_offset(p, nb); - size_t qsize = psize - nb; - set_size_and_pinuse_of_inuse_chunk(m, p, nb); - - assert((TUint8*)oldfirst > (TUint8*)q); - assert(pinuse(oldfirst)); - assert(qsize >= MIN_CHUNK_SIZE); - - /* consolidate remainder with first chunk of old base */ - if (oldfirst == m->top) { - size_t tsize = m->topsize += qsize; - m->top = q; - q->head = tsize | PINUSE_BIT; - check_top_chunk(m, q); - } - else if (oldfirst == m->dv) { - size_t dsize = m->dvsize += qsize; - m->dv = q; - set_size_and_pinuse_of_free_chunk(q, dsize); - } - else { - if (!cinuse(oldfirst)) { - size_t nsize = chunksize(oldfirst); - unlink_chunk(m, oldfirst, nsize); - oldfirst = chunk_plus_offset(oldfirst, nsize); - qsize += nsize; - } - set_free_with_pinuse(q, qsize, oldfirst); - insert_chunk(m, q, qsize); - check_free_chunk(m, q); - } - - check_malloced_chunk(m, chunk2mem(p), nb); - return chunk2mem(p); -} - -void* RNewAllocator::mmap_alloc(mstate m, size_t nb) { - size_t mmsize = granularity_align(nb + SIX_SIZE_T_SIZES + CHUNK_ALIGN_MASK); - if (mmsize > nb) { /* Check for wrap around 0 */ - TUint8* mm = (TUint8*)(DIRECT_MMAP(mmsize)); - if (mm != CMFAIL) { - size_t offset = align_offset(chunk2mem(mm)); - size_t psize = mmsize - offset - MMAP_FOOT_PAD; - mchunkptr p = (mchunkptr)(mm + offset); - p->prev_foot = offset | IS_MMAPPED_BIT; - (p)->head = (psize|CINUSE_BIT); - mark_inuse_foot(m, p, psize); - chunk_plus_offset(p, psize)->head = FENCEPOST_HEAD; - chunk_plus_offset(p, psize+SIZE_T_SIZE)->head = 0; - - if (mm < m->least_addr) - m->least_addr = mm; - if ((m->footprint += mmsize) > m->max_footprint) - m->max_footprint = m->footprint; - assert(is_aligned(chunk2mem(p))); - check_mmapped_chunk(m, p); - return chunk2mem(p); - } - } - return 0; -} - - int RNewAllocator::sys_trim(mstate m, size_t pad) - { - size_t released = 0; - if (pad < MAX_REQUEST && is_initialized(m)) { - pad += TOP_FOOT_SIZE; /* ensure enough room for segment overhead */ - - if (m->topsize > pad) { - /* Shrink top space in granularity-size units, keeping at least one */ - size_t unit = mparams.granularity; - size_t extra = ((m->topsize - pad + (unit - SIZE_T_ONE)) / unit - SIZE_T_ONE) * unit; - msegmentptr sp = segment_holding(m, (TUint8*)m->top); - - if (!is_extern_segment(sp)) { - if (is_mmapped_segment(sp)) { - if (HAVE_MMAP && - sp->size >= extra && - !has_segment_link(m, sp)) { /* can't shrink if pinned */ - size_t newsize = sp->size - extra; - /* Prefer mremap, fall back to munmap */ - if ((CALL_MREMAP(sp->base, sp->size, newsize, 0) != MFAIL) || - (CALL_MUNMAP(sp->base + newsize, extra) == 0)) { - released = extra; - } - } - } - else if (HAVE_MORECORE) { - if (extra >= HALF_MAX_SIZE_T) /* Avoid wrapping negative */ - extra = (HALF_MAX_SIZE_T) + SIZE_T_ONE - unit; - ACQUIRE_MORECORE_LOCK(m); - { - /* Make sure end of memory is where we last set it. */ - TUint8* old_br = (TUint8*)(CALL_MORECORE(0)); - if (old_br == sp->base + sp->size) { - TUint8* rel_br = (TUint8*)(CALL_MORECORE(-extra)); - TUint8* new_br = (TUint8*)(CALL_MORECORE(0)); - if (rel_br != CMFAIL && new_br < old_br) - released = old_br - new_br; - } - } - RELEASE_MORECORE_LOCK(m); - } - } - - if (released != 0) { - sp->size -= released; - m->footprint -= released; - init_top(m, m->top, m->topsize - released); - check_top_chunk(m, m->top); - } - } - - /* Unmap any unused mmapped segments */ - if (HAVE_MMAP) - released += release_unused_segments(m); - - /* On failure, disable autotrim to avoid repeated failed future calls */ - if (released == 0) - m->trim_check = MAX_SIZE_T; - } - - return (released != 0)? 1 : 0; - } - - inline int RNewAllocator::has_segment_link(mstate m, msegmentptr ss) - { - msegmentptr sp = &m->seg; - for (;;) { - if ((TUint8*)sp >= ss->base && (TUint8*)sp < ss->base + ss->size) - return 1; - if ((sp = sp->next) == 0) - return 0; - } - } - - /* Unmap and unlink any mmapped segments that don't contain used chunks */ - size_t RNewAllocator::release_unused_segments(mstate m) - { - size_t released = 0; - msegmentptr pred = &m->seg; - msegmentptr sp = pred->next; - while (sp != 0) { - TUint8* base = sp->base; - size_t size = sp->size; - msegmentptr next = sp->next; - if (is_mmapped_segment(sp) && !is_extern_segment(sp)) { - mchunkptr p = align_as_chunk(base); - size_t psize = chunksize(p); - /* Can unmap if first chunk holds entire segment and not pinned */ - if (!cinuse(p) && (TUint8*)p + psize >= base + size - TOP_FOOT_SIZE) { - tchunkptr tp = (tchunkptr)p; - assert(segment_holds(sp, (TUint8*)sp)); - if (p == m->dv) { - m->dv = 0; - m->dvsize = 0; - } - else { - unlink_large_chunk(m, tp); - } - if (CALL_MUNMAP(base, size) == 0) { - released += size; - m->footprint -= size; - /* unlink obsoleted record */ - sp = pred; - sp->next = next; - } - else { /* back out if cannot unmap */ - insert_large_chunk(m, tp, psize); - } - } - } - pred = sp; - sp = next; - }/*End of while*/ - return released; - } - /* Realloc using mmap */ - inline mchunkptr RNewAllocator::mmap_resize(mstate m, mchunkptr oldp, size_t nb) - { - size_t oldsize = chunksize(oldp); - if (is_small(nb)) /* Can't shrink mmap regions below small size */ - return 0; - /* Keep old chunk if big enough but not too big */ - if (oldsize >= nb + SIZE_T_SIZE && - (oldsize - nb) <= (mparams.granularity << 1)) - return oldp; - else { - size_t offset = oldp->prev_foot & ~IS_MMAPPED_BIT; - size_t oldmmsize = oldsize + offset + MMAP_FOOT_PAD; - size_t newmmsize = granularity_align(nb + SIX_SIZE_T_SIZES + - CHUNK_ALIGN_MASK); - TUint8* cp = (TUint8*)CALL_MREMAP((char*)oldp - offset, - oldmmsize, newmmsize, 1); - if (cp != CMFAIL) { - mchunkptr newp = (mchunkptr)(cp + offset); - size_t psize = newmmsize - offset - MMAP_FOOT_PAD; - newp->head = (psize|CINUSE_BIT); - mark_inuse_foot(m, newp, psize); - chunk_plus_offset(newp, psize)->head = FENCEPOST_HEAD; - chunk_plus_offset(newp, psize+SIZE_T_SIZE)->head = 0; - - if (cp < m->least_addr) - m->least_addr = cp; - if ((m->footprint += newmmsize - oldmmsize) > m->max_footprint) - m->max_footprint = m->footprint; - check_mmapped_chunk(m, newp); - return newp; - } - } - return 0; - } - - -void RNewAllocator::Init_Dlmalloc(size_t capacity, int locked, size_t aTrimThreshold) - { - memset(gm,0,sizeof(malloc_state)); - init_mparams(aTrimThreshold); /* Ensure pagesize etc initialized */ - // 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->seg.base = gm->least_addr = iBase; - gm->seg.size = capacity; - gm->seg.sflags = !IS_MMAPPED_BIT; - set_lock(gm, locked); - gm->magic = mparams.magic; - init_bins(gm); - init_top(gm, (mchunkptr)iBase, capacity - TOP_FOOT_SIZE); - } - -void* RNewAllocator::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 dv 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 dv. - 4. If it is big enough, use the top 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 dv chunk, splitting if necessary. - 2. If better fitting than any binned chunk, use the dv chunk. - 3. If it is big enough, use the top chunk. - 4. If request size >= mmap threshold, try to directly mmap this chunk. - 5. If available, get memory from system and use it - - The ugly goto's here ensure that postaction occurs along all paths. - */ - if (!PREACTION(gm)) { - 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->smallmap >> 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->fd; - assert(chunksize(p) == small_index2size(idx)); - unlink_first_small_chunk(gm, b, p, idx); - set_inuse_and_pinuse(gm, p, small_index2size(idx)); - mem = chunk2mem(p); - check_malloced_chunk(gm, mem, nb); - goto postaction; - } - - else if (nb > gm->dvsize) { - 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); - compute_bit2idx(leastbit, i); - b = smallbin_at(gm, i); - p = b->fd; - assert(chunksize(p) == small_index2size(i)); - unlink_first_small_chunk(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); - replace_dv(gm, r, rsize); - } - mem = chunk2mem(p); - check_malloced_chunk(gm, mem, nb); - goto postaction; - } - - else if (gm->treemap != 0 && (mem = tmalloc_small(gm, nb)) != 0) { - check_malloced_chunk(gm, mem, nb); - goto postaction; - } - } - } - 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->treemap != 0 && (mem = tmalloc_large(gm, nb)) != 0) { - check_malloced_chunk(gm, mem, nb); - goto postaction; - } - } - - if (nb <= gm->dvsize) { - size_t rsize = gm->dvsize - nb; - mchunkptr p = gm->dv; - if (rsize >= MIN_CHUNK_SIZE) { /* split dv */ - mchunkptr r = gm->dv = chunk_plus_offset(p, nb); - gm->dvsize = rsize; - set_size_and_pinuse_of_free_chunk(r, rsize); - set_size_and_pinuse_of_inuse_chunk(gm, p, nb); - } - else { /* exhaust dv */ - size_t dvs = gm->dvsize; - gm->dvsize = 0; - gm->dv = 0; - set_inuse_and_pinuse(gm, p, dvs); - } - mem = chunk2mem(p); - check_malloced_chunk(gm, mem, nb); - goto postaction; - } - - else if (nb < gm->topsize) { /* Split top */ - size_t rsize = gm->topsize -= nb; - mchunkptr p = gm->top; - mchunkptr r = gm->top = chunk_plus_offset(p, nb); - r->head = rsize | PINUSE_BIT; - set_size_and_pinuse_of_inuse_chunk(gm, p, nb); - mem = chunk2mem(p); - check_top_chunk(gm, gm->top); - check_malloced_chunk(gm, mem, nb); - goto postaction; - } - - mem = sys_alloc(gm, nb); - - postaction: - POSTACTION(gm); - return mem; - } - - return 0; -} - -void RNewAllocator::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 top, dv, mmapped chunks, and usage errors. - */ - - if (mem != 0) - { - mchunkptr p = mem2chunk(mem); -#if FOOTERS - mstate fm = get_mstate_for(p); - if (!ok_magic(fm)) - { - USAGE_ERROR_ACTION(fm, p); - return; - } -#else /* FOOTERS */ -#define fm gm -#endif /* FOOTERS */ - - if (!PREACTION(fm)) - { - check_inuse_chunk(fm, p); - if (RTCHECK(ok_address(fm, p) && ok_cinuse(p))) - { - size_t psize = chunksize(p); - iTotalAllocSize -= psize; - mchunkptr next = chunk_plus_offset(p, psize); - if (!pinuse(p)) - { - size_t prevsize = p->prev_foot; - if ((prevsize & IS_MMAPPED_BIT) != 0) - { - prevsize &= ~IS_MMAPPED_BIT; - psize += prevsize + MMAP_FOOT_PAD; - /*TInt tmp = TOP_FOOT_SIZE; - TUint8* top = (TUint8*)fm->top + fm->topsize + 40; - if((top == (TUint8*)p)&& fm->topsize > 4096) - { - fm->topsize += psize; - msegmentptr sp = segment_holding(fm, (TUint8*)fm->top); - sp->size+=psize; - if (should_trim(fm, fm->topsize)) - sys_trim(fm, 0); - goto postaction; - } - else*/ - { - if (CALL_MUNMAP((char*)p - prevsize, psize) == 0) - fm->footprint -= psize; - goto postaction; - } - } - else - { - mchunkptr prev = chunk_minus_offset(p, prevsize); - psize += prevsize; - p = prev; - if (RTCHECK(ok_address(fm, prev))) - { /* consolidate backward */ - if (p != fm->dv) - { - unlink_chunk(fm, p, prevsize); - } - else if ((next->head & INUSE_BITS) == INUSE_BITS) - { - fm->dvsize = psize; - set_free_with_pinuse(p, psize, next); - goto postaction; - } - } - else - goto erroraction; - } - } - - if (RTCHECK(ok_next(p, next) && ok_pinuse(next))) - { - if (!cinuse(next)) - { /* consolidate forward */ - if (next == fm->top) - { - size_t tsize = fm->topsize += psize; - fm->top = p; - p->head = tsize | PINUSE_BIT; - if (p == fm->dv) - { - fm->dv = 0; - fm->dvsize = 0; - } - if (should_trim(fm, tsize)) - sys_trim(fm, 0); - goto postaction; - } - else if (next == fm->dv) - { - size_t dsize = fm->dvsize += psize; - fm->dv = p; - set_size_and_pinuse_of_free_chunk(p, dsize); - goto postaction; - } - else - { - size_t nsize = chunksize(next); - psize += nsize; - unlink_chunk(fm, next, nsize); - set_size_and_pinuse_of_free_chunk(p, psize); - if (p == fm->dv) - { - fm->dvsize = psize; - goto postaction; - } - } - } - else - set_free_with_pinuse(p, psize, next); - insert_chunk(fm, p, psize); - check_free_chunk(fm, p); - goto postaction; - } - } -erroraction: - USAGE_ERROR_ACTION(fm, p); -postaction: - POSTACTION(fm); - } - } -#if !FOOTERS -#undef fm -#endif /* FOOTERS */ -} - -void* RNewAllocator::dlrealloc(void* oldmem, size_t bytes) { - if (oldmem == 0) - return dlmalloc(bytes); -#ifdef REALLOC_ZERO_BYTES_FREES - if (bytes == 0) { - dlfree(oldmem); - return 0; - } -#endif /* REALLOC_ZERO_BYTES_FREES */ - else { -#if ! FOOTERS - mstate m = gm; -#else /* FOOTERS */ - mstate m = get_mstate_for(mem2chunk(oldmem)); - if (!ok_magic(m)) { - USAGE_ERROR_ACTION(m, oldmem); - return 0; - } -#endif /* FOOTERS */ - return internal_realloc(m, oldmem, bytes); - } -} - - -int RNewAllocator::dlmalloc_trim(size_t pad) { - int result = 0; - if (!PREACTION(gm)) { - result = sys_trim(gm, pad); - POSTACTION(gm); - } - return result; -} - -size_t RNewAllocator::dlmalloc_footprint(void) { - return gm->footprint; -} - -size_t RNewAllocator::dlmalloc_max_footprint(void) { - return gm->max_footprint; -} - -#if !NO_MALLINFO -struct mallinfo RNewAllocator::dlmallinfo(void) { - return internal_mallinfo(gm); -} -#endif /* NO_MALLINFO */ - -void RNewAllocator::dlmalloc_stats() { - internal_malloc_stats(gm); -} - -int RNewAllocator::dlmallopt(int param_number, int value) { - return change_mparam(param_number, value); -} - -//inline slab* slab::slabfor(void* p) -inline slab* slab::slabfor( const void* p) - {return (slab*)(floor(p, slabsize));} - - -void RNewAllocator::tree_remove(slab* s) -{ - slab** r = s->parent; - slab* c1 = s->child1; - slab* c2 = s->child2; - for (;;) - { - if (!c2) - { - *r = c1; - if (c1) - c1->parent = r; - return; - } - if (!c1) - { - *r = c2; - c2->parent = r; - return; - } - if (c1 > c2) - { - slab* c3 = c1; - c1 = c2; - c2 = c3; - } - slab* newc2 = c1->child2; - *r = c1; - c1->parent = r; - c1->child2 = c2; - c2->parent = &c1->child2; - s = c1; - c1 = s->child1; - c2 = newc2; - r = &s->child1; - } -} -void RNewAllocator::tree_insert(slab* s,slab** r) - { - slab* n = *r; - for (;;) - { - if (!n) - { // tree empty - *r = s; - s->parent = r; - s->child1 = s->child2 = 0; - break; - } - if (s < n) - { // insert between parent and n - *r = s; - s->parent = r; - s->child1 = n; - s->child2 = 0; - n->parent = &s->child1; - break; - } - slab* c1 = n->child1; - slab* c2 = n->child2; - if (c1 < c2) - { - r = &n->child1; - n = c1; - } - else - { - r = &n->child2; - n = c2; - } - } - } -void* RNewAllocator::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 partial_page heap (which is address ordered). If the -// is now fully used, remove it from the partial_page heap. -// 2. Allocate a new page for slabs if no empty slabs are available -// -{ - page* p = page::pagefor(partial_page); - if (!p) - return allocnewpage(allocator); - - unsigned h = p->slabs[0].header; - unsigned pagemap = header_pagemap(h); - ASSERT(&p->slabs[hibit(pagemap)] == partial_page); - - unsigned slabix = lowbit(pagemap); - p->slabs[0].header = h &~ (0x100<<slabix); - if (!(pagemap &~ (1<<slabix))) - { - tree_remove(partial_page); // last free slab in page - } - return initnewslab(allocator,&p->slabs[slabix]); -} - -/**Defination of this functionis not there in proto code***/ -#if 0 -void RNewAllocator::partial_insert(slab* s) - { - // slab has had first cell freed and needs to be linked back into partial tree - slabset& ss = slaballoc[sizemap[s->clz]]; - - ASSERT(s->used == slabfull); - s->used = ss.fulluse - s->clz; // full-1 loading - tree_insert(s,&ss.partial); - checktree(ss.partial); - } -/**Defination of this functionis not there in proto code***/ -#endif - -void* RNewAllocator::allocnewpage(slabset& allocator) -// -// Acquire and initialise a new page, returning a cell from a new slab -// The partial_page tree is empty (otherwise we'd have used a slab from there) -// The partial_page 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 = spare_page; - if (p) - spare_page = 0; - else - { - p = static_cast<page*>(map(0,pagesize)); - if (!p) - return 0; - } - ASSERT(p == floor(p,pagesize)); - p->slabs[0].header = ((1<<3) + (1<<2) + (1<<1))<<8; // set pagemap - p->slabs[3].parent = &partial_page; - p->slabs[3].child1 = p->slabs[3].child2 = 0; - partial_page = &p->slabs[3]; - return initnewslab(allocator,&p->slabs[0]); -} - -void RNewAllocator::freepage(page* p) -// -// Release an unused page to the OS -// A single page is cached for reuse to reduce thrashing -// the OS allocator. -// -{ - ASSERT(ceiling(p,pagesize) == p); - if (!spare_page) - { - spare_page = p; - return; - } - unmap(p,pagesize); -} - -void RNewAllocator::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 slabs in the page by -// inspecting the pagemap field in the header 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 header is used to add the page to -// the partial_page tree/heap -// 4. If all the slabs 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 partial_page heap, the linkage is moved to the new unused slab -// -{ - tree_remove(s); - checktree(*s->parent); - ASSERT(header_usedm4(s->header) == header_size(s->header)-4); - CHECK(s->header |= 0xFF00000); // illegal value for debug purposes - page* p = page::pagefor(s); - unsigned h = p->slabs[0].header; - int slabix = s - &p->slabs[0]; - unsigned pagemap = header_pagemap(h); - p->slabs[0].header = h | (0x100<<slabix); - if (pagemap == 0) - { // page was full before, use this slab as link in empty heap - tree_insert(s, &partial_page); - } - else - { // find the current empty-link slab - slab* sl = &p->slabs[hibit(pagemap)]; - pagemap ^= (1<<slabix); - if (pagemap == 0xf) - { // page is now empty so recycle page to os - tree_remove(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->parent; - slab* c1 = sl->child1; - slab* c2 = sl->child2; - s->parent = r; - s->child1 = c1; - s->child2 = c2; - *r = s; - if (c1) - c1->parent = &s->child1; - if (c2) - c2->parent = &s->child2; - } - CHECK(if (s < sl) s=sl); - } - ASSERT(header_pagemap(p->slabs[0].header) != 0); - ASSERT(hibit(header_pagemap(p->slabs[0].header)) == unsigned(s - &p->slabs[0])); -} - -void RNewAllocator::slab_init() -{ - slab_threshold=0; - partial_page = 0; - spare_page = 0; - memset(&sizemap[0],0xff,sizeof(sizemap)); - memset(&slaballoc[0],0,sizeof(slaballoc)); -} - -void RNewAllocator::slab_config(unsigned slabbitmap) -{ - ASSERT((slabbitmap & ~okbits) == 0); - ASSERT(maxslabsize <= 60); - - unsigned char ix = 0xff; - unsigned bit = 1<<((maxslabsize>>2)-1); - for (int sz = maxslabsize; sz >= 0; sz -= 4, bit >>= 1) - { - if (slabbitmap & bit) - { - if (ix == 0xff) - slab_threshold=sz+1; - ix = (sz>>2)-1; - } - sizemap[sz>>2] = ix; - } -} - -void* RNewAllocator::slab_allocate(slabset& ss) -// -// Allocate a cell from the given slabset -// Strategy: -// 1. Take the partially full slab at the top 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 partial tree/heap, marking it as 'floating' and go back to -// step 1 -// -{ - for (;;) - { - slab *s = ss.partial; - if (!s) - break; - unsigned h = s->header; - unsigned free = h & 0xff; // extract free cell positiong - if (free) - { - ASSERT(((free<<2)-sizeof(slabhdr))%header_size(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->header = h; - ASSERT(header_free(h) == 0 || ((header_free(h)<<2)-sizeof(slabhdr))%header_size(h) == 0); - ASSERT(header_usedm4(h) <= 0x3F8u); - ASSERT((header_usedm4(h)+4)%header_size(h) == 0); - return p; - } - unsigned h2 = h + ((h&0x3C000)<<6); - if (h2 < 0xfc00000) - { - ASSERT((header_usedm4(h2)+4)%header_size(h2) == 0); - s->header = h2; - return offset(s,(h>>18) + sizeof(unsigned) + sizeof(slabhdr)); - } - h |= 0x80000000; // mark the slab as full-floating - s->header = h; - tree_remove(s); - checktree(ss.partial); - // go back and try the next slab... - } - // no partial slabs found, so allocate from a new slab - return allocnewslab(ss); -} - -void RNewAllocator::slab_free(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 partial tree -// -{ - ASSERT(lowbits(p,3)==0); - slab* s = slab::slabfor(p); - - unsigned pos = lowbits(p, slabsize); - unsigned h = s->header; - ASSERT(header_usedm4(h) != 0x3fC); // slab is empty already - ASSERT((pos-sizeof(slabhdr))%header_size(h) == 0); - *(unsigned char*)p = (unsigned char)h; - h &= ~0xFF; - h |= (pos>>2); - unsigned size = h & 0x3C000; - iTotalAllocSize -= size; - if (int(h) >= 0) - { - h -= size<<6; - if (int(h)>=0) - { - s->header = h; - return; - } - freeslab(s); - return; - } - h -= size<<6; - h &= ~0x80000000; - s->header = h; - slabset& ss = slaballoc[(size>>14)-1]; - tree_insert(s,&ss.partial); - checktree(ss.partial); -} - -void* RNewAllocator::initnewslab(slabset& allocator, slab* s) -// -// initialise an empty slab for this allocator and return the fist cell -// pre-condition: the slabset has no partial slabs for allocation -// -{ - ASSERT(allocator.partial==0); - TInt size = 4 + ((&allocator-&slaballoc[0])<<2); // infer size from slab allocator address - unsigned h = s->header & 0xF00; // preserve pagemap only - h |= (size<<12); // set size - h |= (size-4)<<18; // set usedminus4 to one object minus 4 - s->header = h; - allocator.partial = s; - s->parent = &allocator.partial; - s->child1 = s->child2 = 0; - return offset(s,sizeof(slabhdr)); -} - -TAny* RNewAllocator::SetBrk(TInt32 aDelta) -{ - if (iFlags & EFixedSize) - return MFAIL; - - if (aDelta < 0) - { - unmap(offset(iTop, aDelta), -aDelta); - } - else if (aDelta > 0) - { - if (!map(iTop, aDelta)) - return MFAIL; - } - void * p =iTop; - iTop = offset(iTop, aDelta); - return p; -} - -void* RNewAllocator::map(void* p,unsigned 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 -// -{ -ASSERT(p == floor(p, pagesize)); -ASSERT(sz == ceiling(sz, pagesize)); -ASSERT(sz > 0); - - if (iChunkSize + sz > iMaxLength) - return 0; - - RChunk chunk; - chunk.SetHandle(iChunkHandle); - if (p) - { - TInt r = chunk.Commit(iOffset + ptrdiff(p, this),sz); - if (r < 0) - return 0; - //ASSERT(p = offset(this, r - iOffset)); - } - 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; -#ifdef TRACING_HEAPS - if(iChunkSize > iHighWaterMark) - { - iHighWaterMark = ceiling(iChunkSize,16*pagesize); - - - RChunk chunk; - chunk.SetHandle(iChunkHandle); - TKName chunk_name; - chunk.FullName(chunk_name); - BTraceContextBig(BTrace::ETest1, 4, 44, chunk_name.Ptr(), chunk_name.Size()); - - TUint32 traceData[6]; - traceData[0] = iChunkHandle; - traceData[1] = iMinLength; - traceData[2] = iMaxLength; - traceData[3] = sz; - traceData[4] = iChunkSize; - traceData[5] = iHighWaterMark; - BTraceContextN(BTrace::ETest1, 3, (TUint32)this, 33, traceData, sizeof(traceData)); - } -#endif - if (iChunkSize >= slab_init_threshold) - { // set up slab system now that heap is large enough - slab_config(slab_config_bits); - slab_init_threshold = KMaxTUint; - } - return p; -} - -void* RNewAllocator::remap(void* p,unsigned oldsz,unsigned sz) -{ - if (oldsz > sz) - { // shrink - unmap(offset(p,sz), oldsz-sz); - } - else if (oldsz < sz) - { // grow, try and do this in place first - if (!map(offset(p, oldsz), sz-oldsz)) - { - // need to allocate-copy-free - void* newp = map(0, sz); - memcpy(newp, p, oldsz); - unmap(p,oldsz); - return newp; - } - } - return p; -} - -void RNewAllocator::unmap(void* p,unsigned sz) -{ - ASSERT(p == floor(p, pagesize)); - ASSERT(sz == ceiling(sz, pagesize)); - ASSERT(sz > 0); - - RChunk chunk; - chunk.SetHandle(iChunkHandle); - TInt r = chunk.Decommit(ptrdiff(p, offset(this,-iOffset)), sz); - //TInt offset = (TUint8*)p-(TUint8*)chunk.Base(); - //TInt r = chunk.Decommit(offset,sz); - - ASSERT(r >= 0); - iChunkSize -= sz; -} - -void RNewAllocator::paged_init(unsigned pagepower) - { - if (pagepower == 0) - pagepower = 31; - else if (pagepower < minpagepower) - pagepower = minpagepower; - page_threshold = pagepower; - for (int i=0;i<npagecells;++i) - { - pagelist[i].page = 0; - pagelist[i].size = 0; - } - } - -void* RNewAllocator::paged_allocate(unsigned size) -{ - unsigned nbytes = ceiling(size, pagesize); - if (nbytes < size + cellalign) - { // not enough extra space for header and alignment, try and use cell list - for (pagecell *c = pagelist,*e = c + npagecells;c < e;++c) - if (c->page == 0) - { - void* p = map(0, nbytes); - if (!p) - return 0; - c->page = p; - c->size = nbytes; - return p; - } - } - // use a cell header - nbytes = ceiling(size + cellalign, pagesize); - void* p = map(0, nbytes); - if (!p) - return 0; - *static_cast<unsigned*>(p) = nbytes; - return offset(p, cellalign); -} - -void* RNewAllocator::paged_reallocate(void* p, unsigned size) -{ - if (lowbits(p, pagesize) == 0) - { // continue using descriptor - pagecell* c = paged_descriptor(p); - unsigned nbytes = ceiling(size, pagesize); - void* newp = remap(p, c->size, nbytes); - if (!newp) - return 0; - c->page = newp; - c->size = nbytes; - return newp; - } - else - { // use a cell header - ASSERT(lowbits(p,pagesize) == cellalign); - p = offset(p,-int(cellalign)); - unsigned nbytes = ceiling(size + cellalign, pagesize); - unsigned obytes = *static_cast<unsigned*>(p); - void* newp = remap(p, obytes, nbytes); - if (!newp) - return 0; - *static_cast<unsigned*>(newp) = nbytes; - return offset(newp, cellalign); - } -} - -void RNewAllocator::paged_free(void* p) -{ - if (lowbits(p,pagesize) == 0) - { // check pagelist - pagecell* c = paged_descriptor(p); - - iTotalAllocSize -= c->size; - - unmap(p, c->size); - c->page = 0; - c->size = 0; - } - else - { // check page header - unsigned* page = static_cast<unsigned*>(offset(p,-int(cellalign))); - unsigned size = *page; - unmap(page,size); - } -} - -pagecell* RNewAllocator::paged_descriptor(const void* p) const -{ - ASSERT(lowbits(p,pagesize) == 0); - // Double casting to keep the compiler happy. Seems to think we can trying to - // change a non-const member (pagelist) in a const function - pagecell* c = (pagecell*)((void*)pagelist); - pagecell* e = c + npagecells; - for (;;) - { - ASSERT(c!=e); - if (c->page == p) - return c; - ++c; - } -} - -RNewAllocator* RNewAllocator::FixedHeap(TAny* aBase, TInt aMaxLength, TInt aAlign, TBool aSingleThread) -/** -Creates a fixed length heap at a specified location. - -On successful return from this function, aMaxLength bytes are committed by the chunk. -The heap cannot be extended. - -@param aBase A pointer to the location where the heap is to be constructed. -@param aMaxLength The length of the heap. If the supplied value is less - than KMinHeapSize, it is discarded and the value KMinHeapSize - is used instead. -@param aAlign The alignment of heap cells. -@param aSingleThread Indicates whether single threaded or not. - -@return A pointer to the new heap, or NULL if the heap could not be created. - -@panic USER 56 if aMaxLength is negative. -*/ -// -// Force construction of the fixed memory. -// - { - - __ASSERT_ALWAYS(aMaxLength>=0, ::Panic(ETHeapMaxLengthNegative)); - if (aMaxLength<KMinHeapSize) - aMaxLength=KMinHeapSize; - - RNewAllocator* h = new(aBase) RNewAllocator(aMaxLength, aAlign, aSingleThread); - - if (!aSingleThread) - { - TInt r = h->iLock.CreateLocal(); - if (r!=KErrNone) - return NULL; - h->iHandles = (TInt*)&h->iLock; - h->iHandleCount = 1; - } - return h; - } - -RNewAllocator* RNewAllocator::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. -@param aMaxLength The maximum length to which the heap can grow. - If the supplied value is less than KMinHeapSize, then it - is discarded and the value KMinHeapSize used instead. -@param aGrowBy The increments to the size of the host chunk. If a value is - not explicitly specified, the value KMinHeapGrowBy is taken - by default -@param aAlign The alignment of heap cells. -@param aSingleThread Indicates whether single threaded or not. - -@return A pointer to the new heap or NULL if the heap could not be created. - -@panic USER 41 if aMinLength is greater than the supplied value of aMaxLength. -@panic USER 55 if aMinLength is negative. -@panic USER 56 if aMaxLength is negative. -*/ -// -// Allocate a Chunk of the requested size and force construction. -// - { - - __ASSERT_ALWAYS(aMinLength>=0, ::Panic(ETHeapMinLengthNegative)); - __ASSERT_ALWAYS(aMaxLength>=aMinLength, ::Panic(ETHeapCreateMaxLessThanMin)); - if (aMaxLength<KMinHeapSize) - aMaxLength=KMinHeapSize; - RChunk c; - TInt r; - if (aName) - r = c.CreateDisconnectedGlobal(*aName, 0, 0, aMaxLength*2, aSingleThread ? EOwnerThread : EOwnerProcess); - else - r = c.CreateDisconnectedLocal(0, 0, aMaxLength*2, aSingleThread ? EOwnerThread : EOwnerProcess); - if (r!=KErrNone) - return NULL; - - RNewAllocator* h = ChunkHeap(c, aMinLength, aGrowBy, aMaxLength, aAlign, aSingleThread, UserHeap::EChunkHeapDuplicate); - c.Close(); - return h; - } - -RNewAllocator* RNewAllocator::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. - -The maximum length to which the heap can grow is the same as -the maximum size of the chunk. - -@param aChunk The chunk that will host the heap. -@param aMinLength The minimum length of the heap. -@param aGrowBy The increments to the size of the host chunk. -@param aMaxLength The maximum length to which the heap can grow. -@param aAlign The alignment of heap cells. -@param aSingleThread Indicates whether single threaded or not. -@param aMode Flags controlling the reallocation. The only bit which has any - effect on reallocation is that defined by the enumeration - ENeverMove of the enum RAllocator::TReAllocMode. - If this is set, then any successful reallocation guarantees not - to have changed the start address of the cell. - By default, this parameter is zero. - -@return A pointer to the new heap or NULL if the heap could not be created. -*/ -// -// Construct a heap in an already existing chunk -// - { - - return OffsetChunkHeap(aChunk, aMinLength, 0, aGrowBy, aMaxLength, aAlign, aSingleThread, aMode); - } - -RNewAllocator* RNewAllocator::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 where a fixed amount of -additional data must be stored at a known location. The additional data can be -placed at the base address of the chunk, allowing it to be located without -depending on the internals of the heap structure. - -The maximum length to which the heap can grow is the maximum size of the chunk, -minus the offset. - -@param aChunk The chunk that will host the heap. -@param aMinLength The minimum length of the heap. -@param aOffset The offset from the start of the chunk, to the start of the heap. -@param aGrowBy The increments to the size of the host chunk. -@param aMaxLength The maximum length to which the heap can grow. -@param aAlign The alignment of heap cells. -@param aSingleThread Indicates whether single threaded or not. -@param aMode Flags controlling the reallocation. The only bit which has any - effect on reallocation is that defined by the enumeration - ENeverMove of the enum RAllocator::TReAllocMode. - If this is set, then any successful reallocation guarantees not - to have changed the start address of the cell. - By default, this parameter is zero. - -@return A pointer to the new heap or NULL if the heap could not be created. -*/ -// -// Construct a heap in an already existing chunk -// - { - - TInt page_size = malloc_getpagesize; - if (!aAlign) - aAlign = RNewAllocator::ECellAlignment; - TInt maxLength = aChunk.MaxSize(); - TInt round_up = Max(aAlign, page_size); - TInt min_cell = _ALIGN_UP(Max((TInt)RNewAllocator::EAllocCellSize, (TInt)RNewAllocator::EFreeCellSize), aAlign); - aOffset = _ALIGN_UP(aOffset, 8); - -#ifdef NO_RESERVE_MEMORY -#ifdef TRACING_HEAPS - TKName chunk_name; - aChunk.FullName(chunk_name); - BTraceContextBig(BTrace::ETest1, 0xF, 0xFF, chunk_name.Ptr(), chunk_name.Size()); - - TUint32 traceData[4]; - traceData[0] = aChunk.Handle(); - traceData[1] = aMinLength; - traceData[2] = aMaxLength; - traceData[3] = aAlign; - BTraceContextN(BTrace::ETest1, 0xE, 0xEE, 0xEE, traceData, sizeof(traceData)); -#endif - //modifying the aMinLength because not all memory is the same in the new allocator. So it cannot reserve it properly - if( aMinLength<aMaxLength) - aMinLength = 0; -#endif - - if (aMaxLength && aMaxLength+aOffset<maxLength) - maxLength = _ALIGN_UP(aMaxLength+aOffset, round_up); - __ASSERT_ALWAYS(aMinLength>=0, ::Panic(ETHeapMinLengthNegative)); - __ASSERT_ALWAYS(maxLength>=aMinLength, ::Panic(ETHeapCreateMaxLessThanMin)); - aMinLength = _ALIGN_UP(Max(aMinLength, (TInt)sizeof(RNewAllocator) + min_cell) + aOffset, round_up); - - // the new allocator uses a disconnected chunk so must commit the initial allocation - // with Commit() instead of Adjust() - // TInt r=aChunk.Adjust(aMinLength); - //TInt r = aChunk.Commit(aOffset, aMinLength); - - aOffset = maxLength; - //TInt MORE_CORE_OFFSET = maxLength/2; - //TInt r = aChunk.Commit(MORE_CORE_OFFSET, aMinLength); - TInt r = aChunk.Commit(aOffset, aMinLength); - - if (r!=KErrNone) - return NULL; - - RNewAllocator* h = new (aChunk.Base() + aOffset) RNewAllocator(aChunk.Handle(), aOffset, aMinLength, maxLength, aGrowBy, aAlign, aSingleThread); - //RNewAllocator* h = new (aChunk.Base() + MORE_CORE_OFFSET) RNewAllocator(aChunk.Handle(), aOffset, aMinLength, maxLength, aGrowBy, aAlign, aSingleThread); - - TBool duplicateLock = EFalse; - if (!aSingleThread) - { - duplicateLock = aMode & UserHeap::EChunkHeapSwitchTo; - if(h->iLock.CreateLocal(duplicateLock ? EOwnerThread : EOwnerProcess)!=KErrNone) - { - h->iChunkHandle = 0; - return NULL; - } - } - - if (aMode & UserHeap::EChunkHeapSwitchTo) - User::SwitchHeap(h); - - h->iHandles = &h->iChunkHandle; - if (!aSingleThread) - { - // now change the thread-relative chunk/semaphore handles into process-relative handles - h->iHandleCount = 2; - if(duplicateLock) - { - RHandleBase s = h->iLock; - r = h->iLock.Duplicate(RThread()); - s.Close(); - } - if (r==KErrNone && (aMode & UserHeap::EChunkHeapDuplicate)) - { - r = ((RChunk*)&h->iChunkHandle)->Duplicate(RThread()); - if (r!=KErrNone) - h->iLock.Close(), h->iChunkHandle=0; - } - } - else - { - h->iHandleCount = 1; - if (aMode & UserHeap::EChunkHeapDuplicate) - r = ((RChunk*)&h->iChunkHandle)->Duplicate(RThread(), EOwnerThread); - } - - // return the heap address - return (r==KErrNone) ? h : NULL; - } - - -#define UserTestDebugMaskBit(bit) (TBool)(UserSvr::DebugMask(bit>>5) & (1<<(bit&31))) - -#ifndef NO_NAMED_LOCAL_CHUNKS -//this class requires Symbian^3 for ElocalNamed - -// Hack to get access to TChunkCreateInfo internals outside of the kernel -class TFakeChunkCreateInfo: public TChunkCreateInfo - { -public: - void SetThreadNewAllocator(TInt aInitialSize, TInt aMaxSize, const TDesC& aName) - { - iType = TChunkCreate::ENormal | TChunkCreate::EDisconnected | TChunkCreate::EData; - iMaxSize = aMaxSize * 2; - - iInitialBottom = 0; - iInitialTop = aInitialSize; - iAttributes = TChunkCreate::ELocalNamed; - iName = &aName; - iOwnerType = EOwnerThread; - } - }; -#endif - -#ifndef NO_NAMED_LOCAL_CHUNKS -_LIT(KLitDollarHeap,"$HEAP"); -#endif -TInt RNewAllocator::CreateThreadHeap(SStdEpocThreadCreateInfo& aInfo, RNewAllocator*& aHeap, TInt aAlign, TBool aSingleThread) -/** -@internalComponent -*/ -// -// Create a user-side heap -// - { - TInt page_size = malloc_getpagesize; - TInt minLength = _ALIGN_UP(aInfo.iHeapInitialSize, page_size); - TInt maxLength = Max(aInfo.iHeapMaxSize, minLength); -#ifdef TRACING_ALLOCS - if (UserTestDebugMaskBit(96)) // 96 == KUSERHEAPTRACE in nk_trace.h - aInfo.iFlags |= ETraceHeapAllocs; -#endif - // Create the thread's heap chunk. - RChunk c; -#ifndef NO_NAMED_LOCAL_CHUNKS - TFakeChunkCreateInfo createInfo; - createInfo.SetThreadNewAllocator(0, maxLength, KLitDollarHeap()); // Initialise with no memory committed. - TInt r = c.Create(createInfo); -#else - TInt r = c.CreateDisconnectedLocal(0, 0, maxLength * 2); -#endif - if (r!=KErrNone) - return r; - aHeap = ChunkHeap(c, minLength, page_size, maxLength, aAlign, aSingleThread, UserHeap::EChunkHeapSwitchTo|UserHeap::EChunkHeapDuplicate); - c.Close(); - if (!aHeap) - return KErrNoMemory; -#ifdef TRACING_ALLOCS - if (aInfo.iFlags & ETraceHeapAllocs) - { - aHeap->iFlags |= RAllocator::ETraceAllocs; - BTraceContext8(BTrace::EHeap, BTrace::EHeapCreate,(TUint32)aHeap, RNewAllocator::EAllocCellSize); - TInt handle = aHeap->ChunkHandle(); - TInt chunkId = ((RHandleBase&)handle).BTraceId(); - BTraceContext8(BTrace::EHeap, BTrace::EHeapChunkCreate, (TUint32)aHeap, chunkId); - } -#endif - return KErrNone; - } - -/* - * \internal - * Called from the qtmain.lib application wrapper. - * Create a new heap as requested, but use the new allocator - */ -Q_CORE_EXPORT TInt qt_symbian_SetupThreadHeap(TBool /*aNotFirst*/, SStdEpocThreadCreateInfo& aInfo) - { - TInt r = KErrNone; - if (!aInfo.iAllocator && aInfo.iHeapInitialSize>0) - { - // new heap required - RNewAllocator* pH = NULL; - r = RNewAllocator::CreateThreadHeap(aInfo, pH); - } - else if (aInfo.iAllocator) - { - // sharing a heap - RAllocator* pA = aInfo.iAllocator; - pA->Open(); - User::SwitchAllocator(pA); - } - return r; - } - -#else -/* - * \internal - * Called from the qtmain.lib application wrapper. - * Create a new heap as requested, using the default system allocator - */ -Q_CORE_EXPORT TInt qt_symbian_SetupThreadHeap(TBool aNotFirst, SStdEpocThreadCreateInfo& aInfo) -{ - return UserHeap::SetupThreadHeap(aNotFirst, aInfo); -} -#endif - -#ifndef __WINS__ -#pragma pop -#endif diff --git a/src/corelib/arch/symbian/newallocator_p.h b/src/corelib/arch/symbian/newallocator_p.h deleted file mode 100644 index fd28f2d..0000000 --- a/src/corelib/arch/symbian/newallocator_p.h +++ /dev/null @@ -1,338 +0,0 @@ -/**************************************************************************** -** -** Copyright (C) 2009 Nokia Corporation and/or its subsidiary(-ies). -** All rights reserved. -** Contact: Nokia Corporation (qt-info@nokia.com) -** -** This file is part of the Symbian application wrapper of the Qt Toolkit. -** -** $QT_BEGIN_LICENSE:LGPL$ -** No Commercial Usage -** This file contains pre-release code and may not be distributed. -** You may use this file in accordance with the terms and conditions -** contained in the Technology Preview License Agreement accompanying -** this package. -** -** GNU Lesser General Public License Usage -** Alternatively, this file may be used under the terms of the GNU Lesser -** General Public License version 2.1 as published by the Free Software -** Foundation and appearing in the file LICENSE.LGPL included in the -** packaging of this file. Please review the following information to -** ensure the GNU Lesser General Public License version 2.1 requirements -** will be met: http://www.gnu.org/licenses/old-licenses/lgpl-2.1.html. -** -** In addition, as a special exception, Nokia gives you certain additional -** rights. These rights are described in the Nokia Qt LGPL Exception -** version 1.1, included in the file LGPL_EXCEPTION.txt in this package. -** -** If you have questions regarding the use of this file, please contact -** Nokia at qt-info@nokia.com. -** -** -** -** -** -** -** -** -** $QT_END_LICENSE$ -** -** The memory allocator is backported from Symbian OS, and can eventually -** be removed from Qt once it is built in to all supported OS versions. -** The allocator is a composite of three allocators: -** - A page allocator, for large allocations -** - A slab allocator, for small allocations -** - Doug Lea's allocator, for medium size allocations -****************************************************************************/ -#ifndef NEWALLOCATOR_H -#define NEWALLOCATOR_H - -class RNewAllocator : public RAllocator - { -public: - enum{EAllocCellSize = 8}; - - virtual TAny* Alloc(TInt aSize); - virtual void Free(TAny* aPtr); - virtual TAny* ReAlloc(TAny* aPtr, TInt aSize, TInt aMode=0); - virtual TInt AllocLen(const TAny* aCell) const; - virtual TInt Compress(); - virtual void Reset(); - virtual TInt AllocSize(TInt& aTotalAllocSize) const; - virtual TInt Available(TInt& aBiggestBlock) const; - virtual TInt DebugFunction(TInt aFunc, TAny* a1=NULL, TAny* a2=NULL); -protected: - virtual TInt Extension_(TUint aExtensionId, TAny*& a0, TAny* a1); - -public: - TInt Size() const - { return iChunkSize; } - - inline TInt MaxLength() const; - inline TUint8* Base() const; - inline TInt Align(TInt a) const; - inline const TAny* Align(const TAny* a) const; - inline void Lock() const; - inline void Unlock() const; - inline TInt ChunkHandle() const; - - /** - @internalComponent - */ - struct _s_align {char c; double d;}; - - /** - The structure of a heap cell header for a heap cell on the free list. - */ - struct SCell { - /** - The length of the cell, which includes the length of - this header. - */ - TInt len; - - - /** - A pointer to the next cell in the free list. - */ - SCell* next; - }; - - /** - The default cell alignment. - */ - enum {ECellAlignment = sizeof(_s_align)-sizeof(double)}; - - /** - Size of a free cell header. - */ - enum {EFreeCellSize = sizeof(SCell)}; - - /** - @internalComponent - */ - enum TDefaultShrinkRatios {EShrinkRatio1=256, EShrinkRatioDflt=512}; - -public: - RNewAllocator(TInt aMaxLength, TInt aAlign=0, TBool aSingleThread=ETrue); - RNewAllocator(TInt aChunkHandle, TInt aOffset, TInt aMinLength, TInt aMaxLength, TInt aGrowBy, TInt aAlign=0, TBool aSingleThread=EFalse); - inline RNewAllocator(); - - TAny* operator new(TUint aSize, TAny* aBase) __NO_THROW; - inline void operator delete(TAny*, TAny*); - -protected: - SCell* GetAddress(const TAny* aCell) const; - -public: - TInt iMinLength; - TInt iMaxLength; // maximum bytes used by the allocator in total - TInt iOffset; // offset of RNewAllocator object from chunk base - TInt iGrowBy; - - TInt iChunkHandle; // handle of chunk - RFastLock iLock; - TUint8* iBase; // bottom of DL memory, i.e. this+sizeof(RNewAllocator) - TUint8* iTop; // top of DL memory (page aligned) - TInt iAlign; - TInt iMinCell; - TInt iPageSize; - SCell iFree; -protected: - TInt iNestingLevel; - TInt iAllocCount; - TAllocFail iFailType; - TInt iFailRate; - TBool iFailed; - TInt iFailAllocCount; - TInt iRand; - TAny* iTestData; -protected: - TInt iChunkSize; // currently allocated bytes in the chunk (== chunk.Size()) - malloc_state iGlobalMallocState; - malloc_params mparams; - TInt iHighWaterMark; -private: - void Init(TInt aBitmapSlab, TInt aPagePower, size_t aTrimThreshold);/*Init internal data structures*/ - inline int init_mparams(size_t aTrimThreshold /*= DEFAULT_TRIM_THRESHOLD*/); - void init_bins(mstate m); - void init_top(mstate m, mchunkptr p, size_t psize); - void* sys_alloc(mstate m, size_t nb); - msegmentptr segment_holding(mstate m, TUint8* addr); - void add_segment(mstate m, TUint8* tbase, size_t tsize, flag_t mmapped); - int sys_trim(mstate m, size_t pad); - int has_segment_link(mstate m, msegmentptr ss); - size_t release_unused_segments(mstate m); - void* mmap_alloc(mstate m, size_t nb);/*Need to check this function*/ - void* prepend_alloc(mstate m, TUint8* newbase, TUint8* oldbase, size_t nb); - void* tmalloc_large(mstate m, size_t nb); - void* tmalloc_small(mstate m, size_t nb); - /*MACROS converted functions*/ - static inline void unlink_first_small_chunk(mstate M,mchunkptr B,mchunkptr P,bindex_t& I); - static inline void insert_small_chunk(mstate M,mchunkptr P, size_t S); - static inline void insert_chunk(mstate M,mchunkptr P,size_t S); - static inline void unlink_large_chunk(mstate M,tchunkptr X); - static inline void unlink_small_chunk(mstate M, mchunkptr P,size_t S); - static inline void unlink_chunk(mstate M, mchunkptr P, size_t S); - static inline void compute_tree_index(size_t S, bindex_t& I); - static inline void insert_large_chunk(mstate M,tchunkptr X,size_t S); - static inline void replace_dv(mstate M, mchunkptr P, size_t S); - static inline void compute_bit2idx(binmap_t X,bindex_t& I); - /*MACROS converted functions*/ - TAny* SetBrk(TInt32 aDelta); - void* internal_realloc(mstate m, void* oldmem, size_t bytes); - void internal_malloc_stats(mstate m); - int change_mparam(int param_number, int value); -#if !NO_MALLINFO - mallinfo internal_mallinfo(mstate m); -#endif - void Init_Dlmalloc(size_t capacity, int locked, size_t aTrimThreshold); - void* dlmalloc(size_t); - void dlfree(void*); - void* dlrealloc(void*, size_t); - int dlmallopt(int, int); - size_t dlmalloc_footprint(void); - size_t dlmalloc_max_footprint(void); - #if !NO_MALLINFO - struct mallinfo dlmallinfo(void); - #endif - int dlmalloc_trim(size_t); - size_t dlmalloc_usable_size(void*); - void dlmalloc_stats(void); - inline mchunkptr mmap_resize(mstate m, mchunkptr oldp, size_t nb); - - /****************************Code Added For DL heap**********************/ - friend TInt qt_symbian_SetupThreadHeap(TBool aNotFirst, SStdEpocThreadCreateInfo& aInfo); -private: - unsigned short slab_threshold; - unsigned short page_threshold; // 2^n is smallest cell size allocated in paged allocator - unsigned slab_init_threshold; - unsigned slab_config_bits; - slab* partial_page;// partial-use page tree - page* spare_page; // single empty page cached - unsigned char sizemap[(maxslabsize>>2)+1]; // index of slabset based on size class -private: - static void tree_remove(slab* s); - static void tree_insert(slab* s,slab** r); -public: - enum {okbits = (1<<(maxslabsize>>2))-1}; - void slab_init(); - void slab_config(unsigned slabbitmap); - void* slab_allocate(slabset& allocator); - void slab_free(void* p); - void* allocnewslab(slabset& allocator); - void* allocnewpage(slabset& allocator); - void* initnewslab(slabset& allocator, slab* s); - void freeslab(slab* s); - void freepage(page* p); - void* map(void* p,unsigned sz); - void* remap(void* p,unsigned oldsz,unsigned sz); - void unmap(void* p,unsigned sz); - /**I think we need to move this functions to slab allocator class***/ - static inline unsigned header_free(unsigned h) - {return (h&0x000000ff);} - static inline unsigned header_pagemap(unsigned h) - {return (h&0x00000f00)>>8;} - static inline unsigned header_size(unsigned h) - {return (h&0x0003f000)>>12;} - static inline unsigned header_usedm4(unsigned h) - {return (h&0x0ffc0000)>>18;} - /***paged allocator code***/ - void paged_init(unsigned pagepower); - void* paged_allocate(unsigned size); - void paged_free(void* p); - void* paged_reallocate(void* p, unsigned size); - pagecell* paged_descriptor(const void* p) const ; -private: - // paged allocator structures - enum {npagecells=4}; - pagecell pagelist[npagecells]; // descriptors for page-aligned large allocations - inline void TraceReAlloc(TAny* aPtr, TInt aSize, TAny* aNewPtr, TInt aZone); - inline void TraceCallStack(); - // to track maximum used - //TInt iHighWaterMark; - - slabset slaballoc[maxslabsize>>2]; - -private: - static RNewAllocator* FixedHeap(TAny* aBase, TInt aMaxLength, TInt aAlign, TBool aSingleThread); - static RNewAllocator* ChunkHeap(const TDesC* aName, TInt aMinLength, TInt aMaxLength, TInt aGrowBy, TInt aAlign, TBool aSingleThread); - static RNewAllocator* ChunkHeap(RChunk aChunk, TInt aMinLength, TInt aGrowBy, TInt aMaxLength, TInt aAlign, TBool aSingleThread, TUint32 aMode); - static RNewAllocator* OffsetChunkHeap(RChunk aChunk, TInt aMinLength, TInt aOffset, TInt aGrowBy, TInt aMaxLength, TInt aAlign, TBool aSingleThread, TUint32 aMode); - static TInt CreateThreadHeap(SStdEpocThreadCreateInfo& aInfo, RNewAllocator*& aHeap, TInt aAlign = 0, TBool aSingleThread = EFalse); -}; - -inline RNewAllocator::RNewAllocator() - {} - -/** -@return The maximum length to which the heap can grow. - -@publishedAll -@released -*/ -inline TInt RNewAllocator::MaxLength() const - {return iMaxLength;} - -inline void RNewAllocator::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. -*/ - {} - - -inline TUint8* RNewAllocator::Base() const -/** -Gets a pointer to the start of the heap. - -Note that because of the small space overhead incurred by all allocated cells, -no cell will have the same address as that returned by this function. - -@return A pointer to the base of the heap. -*/ - {return iBase;} - - -inline TInt RNewAllocator::Align(TInt a) const -/** -@internalComponent -*/ - {return _ALIGN_UP(a, iAlign);} - - - - -inline const TAny* RNewAllocator::Align(const TAny* a) const -/** -@internalComponent -*/ - {return (const TAny*)_ALIGN_UP((TLinAddr)a, iAlign);} - - - -inline void RNewAllocator::Lock() const -/** -@internalComponent -*/ - {((RFastLock&)iLock).Wait();} - - - - -inline void RNewAllocator::Unlock() const -/** -@internalComponent -*/ - {((RFastLock&)iLock).Signal();} - - -inline TInt RNewAllocator::ChunkHandle() const -/** -@internalComponent -*/ - { - return iChunkHandle; - } - -#endif // NEWALLOCATOR_H diff --git a/src/corelib/arch/symbian/page_alloc_p.h b/src/corelib/arch/symbian/page_alloc_p.h new file mode 100644 index 0000000..5241d78 --- /dev/null +++ b/src/corelib/arch/symbian/page_alloc_p.h @@ -0,0 +1,68 @@ +/**************************************************************************** +** +** Copyright (C) 2010 Nokia Corporation and/or its subsidiary(-ies). +** All rights reserved. +** Contact: Nokia Corporation (qt-info@nokia.com) +** +** This file is part of the QtCore module of the Qt Toolkit. +** +** $QT_BEGIN_LICENSE:LGPL$ +** No Commercial Usage +** This file contains pre-release code and may not be distributed. +** You may use this file in accordance with the terms and conditions +** contained in the Technology Preview License Agreement accompanying +** this package. +** +** GNU Lesser General Public License Usage +** Alternatively, this file may be used under the terms of the GNU Lesser +** General Public License version 2.1 as published by the Free Software +** Foundation and appearing in the file LICENSE.LGPL included in the +** packaging of this file. Please review the following information to +** ensure the GNU Lesser General Public License version 2.1 requirements +** will be met: http://www.gnu.org/licenses/old-licenses/lgpl-2.1.html. +** +** In addition, as a special exception, Nokia gives you certain additional +** rights. These rights are described in the Nokia Qt LGPL Exception +** version 1.1, included in the file LGPL_EXCEPTION.txt in this package. +** +** If you have questions regarding the use of this file, please contact +** Nokia at qt-info@nokia.com. +** +** +** +** +** +** +** +** +** $QT_END_LICENSE$ +** +****************************************************************************/ + +#ifndef __KERNEL_MODE__ + +const int MAXSMALLPAGEBITS = 68<<3; +#define MINPAGEPOWER PAGESHIFT+2 + +struct paged_bitmap +{ + public: + inline paged_bitmap() : iBase(0), iNbits(0) {} + void Init(unsigned char* p, unsigned size, unsigned bit); +// + inline unsigned char* Addr() const; + inline unsigned Size() const; +// + inline void Set(unsigned ix, unsigned bit); + inline unsigned operator[](unsigned ix) const; + bool Is(unsigned ix, unsigned len, unsigned bit) const; + void Set(unsigned ix, unsigned len, unsigned val); + void Setn(unsigned ix, unsigned len, unsigned bit); + unsigned Bits(unsigned ix, unsigned len) const; // little endian + int Find(unsigned start, unsigned bit) const; + private: + unsigned char* iBase; + unsigned iNbits; +}; + +#endif // __KERNEL_MODE__ diff --git a/src/corelib/arch/symbian/qt_heapsetup_symbian.cpp b/src/corelib/arch/symbian/qt_heapsetup_symbian.cpp new file mode 100644 index 0000000..3d92ccd --- /dev/null +++ b/src/corelib/arch/symbian/qt_heapsetup_symbian.cpp @@ -0,0 +1,99 @@ +/**************************************************************************** +** +** Copyright (C) 2010 Nokia Corporation and/or its subsidiary(-ies). +** All rights reserved. +** Contact: Nokia Corporation (qt-info@nokia.com) +** +** This file is part of the QtCore module of the Qt Toolkit. +** +** $QT_BEGIN_LICENSE:LGPL$ +** No Commercial Usage +** This file contains pre-release code and may not be distributed. +** You may use this file in accordance with the terms and conditions +** contained in the Technology Preview License Agreement accompanying +** this package. +** +** GNU Lesser General Public License Usage +** Alternatively, this file may be used under the terms of the GNU Lesser +** General Public License version 2.1 as published by the Free Software +** Foundation and appearing in the file LICENSE.LGPL included in the +** packaging of this file. Please review the following information to +** ensure the GNU Lesser General Public License version 2.1 requirements +** will be met: http://www.gnu.org/licenses/old-licenses/lgpl-2.1.html. +** +** In addition, as a special exception, Nokia gives you certain additional +** rights. These rights are described in the Nokia Qt LGPL Exception +** version 1.1, included in the file LGPL_EXCEPTION.txt in this package. +** +** If you have questions regarding the use of this file, please contact +** Nokia at qt-info@nokia.com. +** +** +** +** +** +** +** +** +** $QT_END_LICENSE$ +** +****************************************************************************/ + +#include "qt_hybridheap_symbian.h" + +#ifdef QT_USE_NEW_SYMBIAN_ALLOCATOR + +/* + * \internal + * Called from the qtmain.lib application wrapper. + * Create a new heap as requested, but use the new allocator + */ +Q_CORE_EXPORT TInt qt_symbian_SetupThreadHeap(TBool aNotFirst, SStdEpocThreadCreateInfo& aInfo) +{ + TInt r = KErrNone; + if (!aInfo.iAllocator && aInfo.iHeapInitialSize>0) + { + // new heap required + RHeap* pH = NULL; + r = UserHeap::CreateThreadHeap(aInfo, pH); + } + else if (aInfo.iAllocator) + { + // sharing a heap + RAllocator* pA = aInfo.iAllocator; + pA->Open(); + User::SwitchAllocator(pA); + } + return r; +} + +void TChunkCreateInfo::SetThreadHeap(TInt aInitialSize, TInt aMaxSize, const TDesC& aName) +{ + iType = TChunkCreate::ENormal | TChunkCreate::EData; + iMaxSize = aMaxSize; + iInitialBottom = 0; + iInitialTop = aInitialSize; + iAttributes |= TChunkCreate::ELocalNamed; + iName = &aName; + iOwnerType = EOwnerThread; +} + +void Panic(TCdtPanic reason) +{ + _LIT(KCat, "QtHybridHeap"); + User::Panic(KCat, reason); +} + +#else /* QT_USE_NEW_SYMBIAN_ALLOCATOR */ + +/* + * \internal + * Called from the qtmain.lib application wrapper. + * Create a new heap as requested, using the default system allocator + */ +Q_CORE_EXPORT TInt qt_symbian_SetupThreadHeap(TBool aNotFirst, SStdEpocThreadCreateInfo& aInfo) +{ + return UserHeap::SetupThreadHeap(aNotFirst, aInfo); +} + +#endif /* QT_USE_NEW_SYMBIAN_ALLOCATOR */ diff --git a/src/corelib/arch/symbian/qt_hybridHeap_symbian.h b/src/corelib/arch/symbian/qt_hybridHeap_symbian.h new file mode 100644 index 0000000..872c4ec --- /dev/null +++ b/src/corelib/arch/symbian/qt_hybridHeap_symbian.h @@ -0,0 +1,76 @@ +/**************************************************************************** +** +** Copyright (C) 2010 Nokia Corporation and/or its subsidiary(-ies). +** All rights reserved. +** Contact: Nokia Corporation (qt-info@nokia.com) +** +** This file is part of the QtCore module of the Qt Toolkit. +** +** $QT_BEGIN_LICENSE:LGPL$ +** No Commercial Usage +** This file contains pre-release code and may not be distributed. +** You may use this file in accordance with the terms and conditions +** contained in the Technology Preview License Agreement accompanying +** this package. +** +** GNU Lesser General Public License Usage +** Alternatively, this file may be used under the terms of the GNU Lesser +** General Public License version 2.1 as published by the Free Software +** Foundation and appearing in the file LICENSE.LGPL included in the +** packaging of this file. Please review the following information to +** ensure the GNU Lesser General Public License version 2.1 requirements +** will be met: http://www.gnu.org/licenses/old-licenses/lgpl-2.1.html. +** +** In addition, as a special exception, Nokia gives you certain additional +** rights. These rights are described in the Nokia Qt LGPL Exception +** version 1.1, included in the file LGPL_EXCEPTION.txt in this package. +** +** If you have questions regarding the use of this file, please contact +** Nokia at qt-info@nokia.com. +** +** +** +** +** +** +** +** +** $QT_END_LICENSE$ +** +****************************************************************************/ + +#ifndef QT_HYBRIDHEAP_SYMBIAN_H +#define QT_HYBRIDHEAP_SYMBIAN_H + +#include <qglobal.h> + +#ifdef QT_USE_NEW_SYMBIAN_ALLOCATOR + +#include "common_p.h" +#ifdef __KERNEL_MODE__ +#include <kernel/kern_priv.h> +#endif +#include "dla_p.h" +#ifndef __KERNEL_MODE__ +#include "slab_p.h" +#include "page_alloc_p.h" +#endif +#include "heap_hybrid_p.h" + +// disabling Symbian import/export macros to prevent code copied from Symbian^4 from exporting symbols +#undef UIMPORT_C +#define UIMPORT_C +#undef IMPORT_C +#define IMPORT_C +#undef UEXPORT_C +#define UEXPORT_C +#undef EXPORT_C +#define EXPORT_C +#undef IMPORT_D +#define IMPORT_D + +#undef SYMBIAN4_DEBUG_FUNCTIONS_SUPPORTED + +#endif /* QT_USE_NEW_SYMBIAN_ALLOCATOR */ + +#endif /* QT_HYBRIDHEAP_SYMBIAN_H */ diff --git a/src/corelib/arch/symbian/slab_p.h b/src/corelib/arch/symbian/slab_p.h new file mode 100644 index 0000000..234a310 --- /dev/null +++ b/src/corelib/arch/symbian/slab_p.h @@ -0,0 +1,125 @@ +/**************************************************************************** +** +** Copyright (C) 2010 Nokia Corporation and/or its subsidiary(-ies). +** All rights reserved. +** Contact: Nokia Corporation (qt-info@nokia.com) +** +** This file is part of the QtCore module of the Qt Toolkit. +** +** $QT_BEGIN_LICENSE:LGPL$ +** No Commercial Usage +** This file contains pre-release code and may not be distributed. +** You may use this file in accordance with the terms and conditions +** contained in the Technology Preview License Agreement accompanying +** this package. +** +** GNU Lesser General Public License Usage +** Alternatively, this file may be used under the terms of the GNU Lesser +** General Public License version 2.1 as published by the Free Software +** Foundation and appearing in the file LICENSE.LGPL included in the +** packaging of this file. Please review the following information to +** ensure the GNU Lesser General Public License version 2.1 requirements +** will be met: http://www.gnu.org/licenses/old-licenses/lgpl-2.1.html. +** +** In addition, as a special exception, Nokia gives you certain additional +** rights. These rights are described in the Nokia Qt LGPL Exception +** version 1.1, included in the file LGPL_EXCEPTION.txt in this package. +** +** If you have questions regarding the use of this file, please contact +** Nokia at qt-info@nokia.com. +** +** +** +** +** +** +** +** +** $QT_END_LICENSE$ +** +****************************************************************************/ + +#ifndef __KERNEL_MODE__ + +class slab; +class slabhdr; +#define MAXSLABSIZE 56 +#define PAGESHIFT 12 +#define PAGESIZE (1<<PAGESHIFT) +#define SLABSHIFT 10 +#define SLABSIZE (1 << SLABSHIFT) +#define CELLALIGN 8 + + +const unsigned slabfull = 0; +const TInt slabsperpage = (int)(PAGESIZE/SLABSIZE); +#define HIBIT(bits) (((unsigned)bits & 0xc) ? 2 + ((unsigned)bits>>3) : ((unsigned) bits>>1)) + +#define LOWBIT(bits) (((unsigned) bits&3) ? 1 - ((unsigned)bits&1) : 3 - (((unsigned)bits>>2)&1)) + +#define ZEROBITS(header) (((unsigned)header & 0x70000000) ? 0 : 1) + +class slabhdr +{ + public: + unsigned iHeader; + // made up of + // bits | 31 | 30..28 | 27..18 | 17..12 | 11..8 | 7..0 | + // +----------+--------+--------+--------+---------+----------+ + // field | floating | zero | used-4 | size | pagemap | free pos | + // + slab** iParent; // reference to iParent's pointer to this slab in tree + slab* iChild1; // 1st iChild in tree + slab* iChild2; // 2nd iChild in tree +}; + +const TInt KMaxSlabPayload = SLABSIZE - sizeof(slabhdr); +#define MAXUSEDM4BITS 0x0fc00000 +#define FLOATING_BIT 0x80000000 + +inline unsigned HeaderFloating(unsigned h) +{return (h&0x80000000);} +const unsigned maxuse = (SLABSIZE - sizeof(slabhdr))>>2; +const unsigned firstpos = sizeof(slabhdr)>>2; + +#ifdef _DEBUG +#define CHECKTREE(x) DoCheckSlabTree(x,EFalse) +#define CHECKSLAB(s,t,p) DoCheckSlab(s,t,p) +#define CHECKSLABBFR(s,p) {TUint32 b[4]; BuildPartialSlabBitmap(b,s,p);} +#else +#define CHECKTREE(x) (void)0 +#define CHECKSLAB(s,t,p) (void)0 +#define CHECKSLABBFR(s,p) (void)0 +#endif + +class slabset +{ + public: + slab* iPartial; +}; + +class slab : public slabhdr +{ + public: + void Init(unsigned clz); + //static slab* SlabFor( void* p); + static slab* SlabFor(const void* p) ; + unsigned char iPayload[SLABSIZE-sizeof(slabhdr)]; +}; + +class page +{ + public: + inline static page* PageFor(slab* s); + //slab iSlabs; + slab iSlabs[slabsperpage]; +}; + + +inline page* page::PageFor(slab* s) +{ + return reinterpret_cast<page*>((unsigned(s))&~(PAGESIZE-1)); +} + + +#endif // __KERNEL_MODE__ diff --git a/src/corelib/global/qglobal.h b/src/corelib/global/qglobal.h index 9c90fbf..45ca28e 100644 --- a/src/corelib/global/qglobal.h +++ b/src/corelib/global/qglobal.h @@ -2451,9 +2451,11 @@ QT3_SUPPORT Q_CORE_EXPORT const char *qInstallPathSysconf(); #endif #endif +#ifndef SYMBIAN_GRAPHICS_WSERV_QT_EFFECTS //Enable the (backported) new allocator. When it is available in OS, //this flag should be disabled for that OS version onward #define QT_USE_NEW_SYMBIAN_ALLOCATOR +#endif //Symbian does not support data imports from a DLL #define Q_NO_DATA_RELOCATION |