diff -r 000000000000 -r bde4ae8d615e os/kernelhwsrv/kerneltest/e32test/heap/t_heap2.cpp --- /dev/null Thu Jan 01 00:00:00 1970 +0000 +++ b/os/kernelhwsrv/kerneltest/e32test/heap/t_heap2.cpp Fri Jun 15 03:10:57 2012 +0200 @@ -0,0 +1,1455 @@ +// Copyright (c) 2002-2009 Nokia Corporation and/or its subsidiary(-ies). +// All rights reserved. +// This component and the accompanying materials are made available +// under the terms of the License "Eclipse Public License v1.0" +// which accompanies this distribution, and is available +// at the URL "http://www.eclipse.org/legal/epl-v10.html". +// +// Initial Contributors: +// Nokia Corporation - initial contribution. +// +// Contributors: +// +// Description: +// e32test\heap\t_heap2.cpp +// Overview: +// Tests RHeap class, including a stress test and a "grow in place" +// ReAlloc test. +// API Information: +// RHeap +// Details: +// - Test allocation on fixed length heaps in local, disconnected chunks for +// different heap sizes and alignments. Assumes knowledge of heap +// implementation. +// - Test allocation, free, reallocation and compression on chunk heaps with +// different maximum and minimum lengths and alignments. Assumes knowledge +// of heap implementation. +// - Stress test heap implementation with a single thread that allocates, frees +// and reallocates cells, and checks the heap. +// - Stress test heap implementation with two threads that run concurrently. +// - Create a chunk heap, test growing in place by allocating a cell and +// then reallocating additional space until failure, verify that the cell +// did not move and the size was increased. +// - The heap is checked to verify that no cells remain allocated after the +// tests are complete. +// Platforms/Drives/Compatibility: +// All +// Assumptions/Requirement/Pre-requisites: +// Failures and causes: +// Base Port information: +// +// + +#include +#include +#include +#include + +// Needed for KHeapShrinkHysRatio which is now ROM 'patchdata' +#include "TestRHeapShrink.h" + +#define DECL_GET(T,x) inline T x() const {return i##x;} +#define DECL_GET2(T,x,y) inline T y() const {return i##x;} + + +#ifdef __EABI__ + IMPORT_D extern const TInt KHeapMinCellSize; +#else + const TInt KHeapMinCellSize = 0; +#endif + +RTest test(_L("T_HEAP2")); + +#define TEST_ALIGN(p,a) test((TLinAddr(p)&((a)-1))==0) + +struct STestCell + { + enum {EMagic = 0xb8aa3b29}; + + TUint32 iLength; + TUint32 iData[1]; + + void Set(TInt aLength); + void Verify(TInt aLength); + void Verify(const TAny* aInitPtr, TInt aInitLength, TInt aLength); + }; + +void STestCell::Set(TInt aLength) + { + TInt i; + TUint32 x = (TUint32)this ^ (TUint32)aLength ^ (TUint32)EMagic; + aLength -= RHeap::EAllocCellSize; + if (aLength==0) + return; + iLength = x; + aLength /= sizeof(TUint32); + for (i=0; ilen; + TUint8* pEnd = (TUint8*)pC + len; + TEST_ALIGN(aCell, iAlign); + TEST_ALIGN(len, iAlign); + test(len >= iMinCell); + test((TUint8*)pC>=iBase && pEnd<=iTop); + return len; + } + +void RTestHeap::FullCheckAllocatedCell(const TAny* aCell) const + { + ((STestCell*)aCell)->Verify(CheckAllocatedCell(aCell)); + } + +TAny* RTestHeap::TestAlloc(TInt aSize) + { + TAny* p = Alloc(aSize); + if (p) + { + TInt len = CheckAllocatedCell(p); + test((len-RHeap::EAllocCellSize)>=aSize); + ((STestCell*)p)->Set(len); + } + return p; + } + +void RTestHeap::TestFree(TAny* aPtr) + { + if (aPtr) + FullCheckAllocatedCell(aPtr); + Free(aPtr); + } + +TAny* RTestHeap::TestReAlloc(TAny* aPtr, TInt aSize, TInt aMode) + { + TInt old_len = aPtr ? CheckAllocatedCell(aPtr) : 0; + if (aPtr) + ((STestCell*)aPtr)->Verify(old_len); + TAny* p = ReAlloc(aPtr, aSize, aMode); + if (!p) + { + ((STestCell*)aPtr)->Verify(old_len); + return p; + } + TInt new_len = CheckAllocatedCell(p); + test((new_len-RHeap::EAllocCellSize)>=aSize); + if (p == aPtr) + { + ((STestCell*)p)->Verify(p, old_len, Min(old_len, new_len)); + if (new_len != old_len) + ((STestCell*)p)->Set(new_len); + return p; + } + test(!(aMode & ENeverMove)); + test((new_len > old_len) || (aMode & EAllowMoveOnShrink)); + if (old_len) + ((STestCell*)p)->Verify(aPtr, old_len, Min(old_len, new_len)); + if (new_len != old_len) + ((STestCell*)p)->Set(new_len); + return p; + } + +struct SHeapCellInfo + { + RTestHeap* iHeap; + TInt iTotalAlloc; + TInt iTotalAllocSize; + TInt iTotalFree; + TUint8* iNextCell; + }; + +void RTestHeap::WalkFullCheckCell(TAny* aPtr, TCellType aType, TAny* aCell, TInt aLen) + { + (void)aCell; + ::SHeapCellInfo& info = *(::SHeapCellInfo*)aPtr; + switch(aType) + { + case EGoodAllocatedCell: + { + test(aCell == info.iNextCell); + TInt len = ((SCell*)aCell)->len; + test(len == aLen); + info.iNextCell += len; + ++info.iTotalAlloc; + info.iTotalAllocSize += (aLen-EAllocCellSize); + STestCell* pT = (STestCell*)((TUint8*)aCell + EAllocCellSize); + pT->Verify(len); + break; + } + case EGoodFreeCell: + { + test(aCell == info.iNextCell); + TInt len = ((SCell*)aCell)->len; + test(len == aLen); + info.iNextCell += len; + ++info.iTotalFree; + break; + } + default: + test.Printf(_L("TYPE=%d ??\n"),aType); + test(0); + break; + } + } + +void RTestHeap::FullCheck() + { + ::SHeapCellInfo info; + Mem::FillZ(&info, sizeof(info)); + info.iHeap = this; + info.iNextCell = iBase; + DebugFunction(EWalk, (TAny*)&WalkFullCheckCell, &info); + test(info.iNextCell == iTop); + test(info.iTotalAlloc == iCellCount); + test(info.iTotalAllocSize == iTotalAllocSize); + } + +TInt RTestHeap::FreeCellLen(const TAny* aPtr) const + { + SCell* p = iFree.next; + SCell* q = (SCell*)((TUint8*)aPtr - EAllocCellSize); + for (; p && p!=q; p = p->next) {} + if (p == q) + return p->len - EAllocCellSize; + return -1; + } + +TInt RTestHeap::LastFreeCellLen(void) const + { + SCell* p = iFree.next; + if (p==NULL) + return -1; + for (; p->next; p=p->next){} + return p->len; + } + + +/** Checks whether a call to Compress() will actually perform a reduction + of the heap. + Relies on the free last cell on the heap being cell that has just been freed + plus any extra. + Intended for use by t_heap2.cpp - DoTest4(). + @param aFreedSize The size in bytes of the cell that was freed +*/ +TInt RTestHeap::CalcComp(TInt aFreedSize) + { + TInt largestCell=0; + largestCell = LastFreeCellLen(); + // if the largest cell is too small or it would have been compressed by the + // free operation then return 0. + if (largestCell < iPageSize || aFreedSize >= KHeapShrinkHysRatio*(iGrowBy>>8)) + { + return 0; + } + else + { + return _ALIGN_DOWN(aFreedSize,iPageSize); + } + } + +/** compress the heap if the KHeapShrinkRatio is too large for what we are + expecting in DoTest4(). +*/ +void RTestHeap::ForceCompress(TInt aFreed) + { + if (aFreed < KHeapShrinkHysRatio*(iGrowBy>>8)) + { + Compress(); + } + } +RTestHeap* RTestHeap::FixedHeap(TInt aMaxLength, TInt aAlign, TBool aSingleThread) + { + RChunk c; + TInt bottom = 0x40000; + TInt top = bottom + aMaxLength; + TInt r = c.CreateDisconnectedLocal(bottom, top, top + bottom, EOwnerThread); + if (r!=KErrNone) + return NULL; + TUint8* base = c.Base() + bottom; + RTestHeap* h = (RTestHeap*)UserHeap::FixedHeap(base, aMaxLength, aAlign, aSingleThread); + if (!aAlign) + aAlign = RHeap::ECellAlignment; + test((TUint8*)h == base); + test(h->AccessCount() == 1); + test(h->HandleCount() == (aSingleThread ? 0 : 1)); + test(h->Handles() == (aSingleThread ? NULL : (TInt*)&h->LockRef())); + test(h->Flags() == TUint32(RAllocator::EFixedSize | (aSingleThread ? RAllocator::ESingleThreaded : 0))); + test(h->CellCount() == 0); + test(h->TotalAllocSize() == 0); + test(h->MaxLength() == aMaxLength); + test(h->MinLength() == h->Top() - (TUint8*)h); + test(h->Offset() == 0); + test(h->GrowBy() == 0); + test(h->ChunkHandle() == 0); + test(h->Align() == aAlign); + TInt min_cell = _ALIGN_UP((KHeapMinCellSize + Max((TInt)RHeap::EAllocCellSize, (TInt)RHeap::EFreeCellSize)), aAlign); + TInt hdr_len = _ALIGN_UP(sizeof(RHeap) + RHeap::EAllocCellSize, aAlign) - RHeap::EAllocCellSize; + TInt user_len = _ALIGN_DOWN(aMaxLength - hdr_len, aAlign); + test(h->Base() == base + hdr_len); + test(h->MinCell() == min_cell); + test(h->Top() - h->Base() == user_len); + test(h->FreeRef().next == (RHeap::SCell*)h->Base()); + h->TakeChunkOwnership(c); + return h; + } + +void RTestHeap::TakeChunkOwnership(RChunk aChunk) + { + iChunkHandle = aChunk.Handle(); + ++iHandleCount; + iHandles = &iChunkHandle; + } + + +#define ACCESS_COUNT(h) (((RTestHeap*)h)->AccessCount()) +#define HANDLE_COUNT(h) (((RTestHeap*)h)->HandleCount()) +#define HANDLES(h) (((RTestHeap*)h)->Handles()) +#define FLAGS(h) (((RTestHeap*)h)->Flags()) +#define CELL_COUNT(h) (((RTestHeap*)h)->CellCount()) +#define TOTAL_ALLOC_SIZE(h) (((RTestHeap*)h)->TotalAllocSize()) +#define MIN_LENGTH(h) (((RTestHeap*)h)->MinLength()) +#define OFFSET(h) (((RTestHeap*)h)->Offset()) +#define GROW_BY(h) (((RTestHeap*)h)->GrowBy()) +#define CHUNK_HANDLE(h) (((RTestHeap*)h)->ChunkHandle()) +#define LOCK_REF(h) (((RTestHeap*)h)->LockRef()) +#define TOP(h) (((RTestHeap*)h)->Top()) +#define ALIGN(h) (((RTestHeap*)h)->Align()) +#define MIN_CELL(h) (((RTestHeap*)h)->MinCell()) +#define PAGE_SIZE(h) (((RTestHeap*)h)->PageSize()) +#define FREE_REF(h) (((RTestHeap*)h)->FreeRef()) + +void DoTest1(RHeap* aH) + { + RTestHeap* h = (RTestHeap*)aH; + test.Printf(_L("Test Alloc: min=%x max=%x align=%d growby=%d\n"), + h->MinLength(), h->MaxLength(), h->Align(), h->GrowBy()); + TInt l; + TAny* p = NULL; + TUint8* next = h->Base(); + TUint8* top = h->Top(); + TUint8* limit = (TUint8*)h + h->MaxLength(); + TBool fixed = h->Flags() & RAllocator::EFixedSize; + for (l=1; l<=1024; ++l) + { + TInt remain1 = top - next; + TInt xl1 = _ALIGN_UP(Max((l+RHeap::EAllocCellSize), h->MinCell()), h->Align()); + p = h->TestAlloc(l); + if ( (fixed && remain1 < xl1) || (next + xl1 > limit) ) + { + test(p == NULL); + test(top == h->Top()); + test.Printf(_L("Alloc failed at l=%d next=%08x\n"), l, next); + break; + } + test(p == next + RHeap::EAllocCellSize); + if (xl1 > remain1) + { + // no room for this cell + TInt g = h->GrowBy(); + while (xl1 > remain1) + { + top += g; + remain1 += g; + } + } + test(top == h->Top()); + if (xl1 + h->MinCell() > remain1) + { + // this cell fits but remainder is too small or nonexistent + xl1 = top - next; + next = top; + test(h->FreeRef().next == NULL); + } + else + { + // this cell fits and remainder can be reused + next += xl1; + } + test(aH->AllocLen(p) == xl1 - RHeap::EAllocCellSize); + } + h->FullCheck(); + } + +void DoTest2(RHeap* aH) + { + RTestHeap* h = (RTestHeap*)aH; + test.Printf(_L("Test Free: min=%x max=%x align=%d growby=%d\n"), + h->MinLength(), h->MaxLength(), h->Align(), h->GrowBy()); + TInt al; + TInt min = h->MinCell(); + TBool pad = EFalse; + for (al=1; al<256; (void)((pad=!pad)!=0 || (al+=al+1)) ) + { + TAny* p[32]; + TInt last_len = 0; + TAny* last = NULL; + TInt i; + test.Printf(_L("al=%d pad=%d\n"), al, pad); + TUint8* top=0; + TAny* spare=0; + TBool heapReduced = EFalse; + for (i=0; i<32; ++i) + { + // Check whether the cell created for the allocation of al would end up + // including extra bytes from the last free cell that aren't enough + // to create a new free cell. + top = h->Top(); + TInt freeLen=h->LastFreeCellLen(); + TInt actualAllocBytes = Max(_ALIGN_UP(al + RHeap::EAllocCellSize, h->Align()), min); + TInt remainingBytes = freeLen - actualAllocBytes; + if (remainingBytes < min) + { + // Force the heap to grow so that once this allocation is freed + // the free cell left will be large enough to include the al allocation + // and to create a new free cell if necessary. + actualAllocBytes = _ALIGN_UP(actualAllocBytes + min, h->Align()); + TAny* q = h->TestAlloc(actualAllocBytes); + // Check heap has grown + test(top < h->Top()); + top = h->Top(); + test(q!=NULL); + // Have grown the heap so allocate a cell as a place holder to stop + // the heap being shrunk and the actual cell we want to allocate from being the + // wrong size + spare=h->TestAlloc(8); + h->TestFree(q); + // Ensure heap wasn't shrunk after free + test(top == h->Top()); + } + top = h->Top(); + // Allocate the new + p[i] = h->TestAlloc(al); + test(p[i]!=NULL); + if (remainingBytes < min) + {// now safe to free any padding as p[i] now allocated and its size can't change + h->TestFree(spare); + } + TInt tmp1=h->AllocLen(p[i]); + TInt tmp2=Max(_ALIGN_UP(al+RHeap::EAllocCellSize,h->Align()), min)-RHeap::EAllocCellSize; + test(tmp1 == tmp2); + } + last = (TUint8*)p[31] + _ALIGN_UP(Max((al + RHeap::EAllocCellSize), min), h->Align()); + last_len = h->FreeCellLen(last); + test(last_len > 0); + if (pad) + { + test(h->TestAlloc(last_len) == last); + test(h->FreeRef().next == NULL); + } + else + last = NULL; + top = h->Top(); + for (i=0,heapReduced=EFalse; i<32; ++i) + { + h->TestFree(p[i]); + TInt fl = h->FreeCellLen(p[i]); + TInt xfl = _ALIGN_UP(Max((al + RHeap::EAllocCellSize), h->MinCell()), h->Align()) - RHeap::EAllocCellSize; + if (h->Top() < top) // heap was reduced due to small KHeapShrinkHysRatio and big KHeapMinCellSize + { + top = h->Top(); + heapReduced = ETrue; + } + + if (i < 31 || pad) + test(fl == xfl); + else + { + if (!heapReduced) + test(fl == xfl + RHeap::EAllocCellSize + last_len); + else + { + heapReduced = EFalse; + } + } + test(h->TestAlloc(al)==p[i]); + } + for (i=0,heapReduced=EFalse; i<31; ++i) + { + TInt j = i+1; + TUint8* q; + // Free to adjacent cells and check that the free cell left is the combined + // size of the 2 adjacent cells just freed + h->TestFree(p[i]); + h->TestFree(p[j]); + TInt fl = h->FreeCellLen(p[i]); + if (h->Top() < top) // heap was reduced due to small KHeapShrinkHysRatio and big KHeapMinCellSize + { + top = h->Top(); + heapReduced = ETrue; + } + TInt xfl = 2 * _ALIGN_UP(Max((al + RHeap::EAllocCellSize), h->MinCell()), h->Align()) - RHeap::EAllocCellSize; + if (j < 31 || pad) + test(fl == xfl); + else + { + if (!heapReduced) + test(fl == xfl + RHeap::EAllocCellSize + last_len); + else + { + heapReduced = EFalse; + } + } + test(h->FreeCellLen(p[j]) < 0); + test(h->TestAlloc(fl)==p[i]); + test(h->Top() == top); + h->TestFree(p[i]); + test(h->FreeCellLen(p[i]) == fl); + // test when you alloc a cell that is larger than cells just freed + // that its position is not the same as the freed cells + // will hold for all cells except top/last one + if (j < 31 && !pad && fl < last_len) + { + q = (TUint8*)h->TestAlloc(fl+1); + if (h->Top() > top) + top = h->Top(); + test(h->Top() == top); + test(q > p[i]); + h->TestFree(q); + if (h->Top() < top) // heap was reduced due to small KHeapShrinkHysRatio and big KHeapMinCellSize + { + top = h->Top(); + heapReduced = ETrue; + } + } + // check cell that is just smaller than space but not small enough + // for a new free cell to be created, is the size of whole free cell + test(h->TestAlloc(fl-min+1)==p[i]); + test(h->Top() == top); + test(h->AllocLen(p[i])==fl); + h->TestFree(p[i]); + // Check cell that is small enough for new free cell and alloc'd cell to be + // created at p[i] cell is created at p[i] + test(h->TestAlloc(fl-min)==p[i]); + test(h->Top() == top); + // check free cell is at expected position + q = (TUint8*)p[i] + fl - min + RHeap::EAllocCellSize; + test(h->FreeCellLen(q) == min - RHeap::EAllocCellSize); + // alloc 0 length cell at q, will work as new cell of min length will be created + test(h->TestAlloc(0) == q); + test(h->Top() == top); + h->TestFree(p[i]); + test(h->FreeCellLen(p[i]) == fl - min); + h->TestFree(q); + // again check free cells are combined + test(h->FreeCellLen(q) < 0); + test(h->FreeCellLen(p[i]) == fl); + // check reallocating the cells places them back to same positions + test(h->TestAlloc(al)==p[i]); + test(h->Top() == top); + test(h->TestAlloc(al)==p[j]); + test(h->Top() == top); + if (pad) + test(h->FreeRef().next == NULL); + } + for (i=0,heapReduced=EFalse; i<30; ++i) + { + TInt j = i+1; + TInt k = i+2; + TUint8* q; + // Free 3 adjacent cells and check free cell created is combined size + h->TestFree(p[i]); + h->TestFree(p[k]); + h->TestFree(p[j]); + h->FullCheck(); + if (h->Top() < top) // heap was reduced due to small KHeapShrinkHysRatio and big KHeapMinCellSize + { + top = h->Top(); + heapReduced = ETrue; + } + TInt fl = h->FreeCellLen(p[i]); + TInt xfl = 3 * _ALIGN_UP(Max((al + RHeap::EAllocCellSize), h->MinCell()), h->Align()) - RHeap::EAllocCellSize; + if (k < 31 || pad) + test(fl == xfl); + else + { + if (!heapReduced) + test(fl == xfl + RHeap::EAllocCellSize + last_len); + else + { + heapReduced = EFalse; + } + } + test(h->FreeCellLen(p[j]) < 0); + test(h->FreeCellLen(p[k]) < 0); + //ensure created free cell is allocated to new cell of free cell size + test(h->TestAlloc(fl)==p[i]); + test(h->Top() == top); + h->TestFree(p[i]); + test(h->FreeCellLen(p[i]) == fl); + if (h->Top() < top) // heap was reduced due to small KHeapShrinkHysRatio and big KHeapMinCellSize + top = h->Top(); + if (k < 31 && !pad && fl < last_len) + { + // Test new cell one larger than free cell size is allocated somewhere else + q = (TUint8*)h->TestAlloc(fl+1); + if (h->Top() > top) + top = h->Top(); + test(h->Top() == top); + test(q > p[i]); + h->TestFree(q); + if (h->Top() < top) // heap was reduced due to small KHeapShrinkHysRatio and big KHeapMinCellSize + { + top = h->Top(); + heapReduced = ETrue; + } + } + // check allocating cell just smaller than free cell size but + // too large for neew free cell to be created, is size of whole free cell + test(h->TestAlloc(fl-min+1)==p[i]); + test(h->Top() == top); + test(h->AllocLen(p[i])==fl); + h->TestFree(p[i]); + // ensure free cell is created this time as well as alloc'd cell + test(h->TestAlloc(fl-min)==p[i]); + test(h->Top() == top); + q = (TUint8*)p[i] + fl - min + RHeap::EAllocCellSize; + test(h->FreeCellLen(q) == min - RHeap::EAllocCellSize); + test(h->TestAlloc(0) == q); + test(h->Top() == top); + h->TestFree(p[i]); + test(h->FreeCellLen(p[i]) == fl - min); + h->TestFree(q); + test(h->FreeCellLen(q) < 0); + test(h->FreeCellLen(p[i]) == fl); + // realloc all cells and check heap not expanded + test(h->TestAlloc(al)==p[i]); + test(h->Top() == top); + test(h->TestAlloc(al)==p[j]); + test(h->Top() == top); + test(h->TestAlloc(al)==p[k]); + test(h->Top() == top); + // If padding than no space should left on heap + if (pad) + test(h->FreeRef().next == NULL); + } + // when padding this will free padding from top of heap + h->TestFree(last); + } + h->FullCheck(); + } + +void DoTest3(RHeap* aH) + { + RTestHeap* h = (RTestHeap*)aH; + test.Printf(_L("Test ReAlloc: min=%x max=%x align=%d growby=%d\n"), + h->MinLength(), h->MaxLength(), h->Align(), h->GrowBy()); + // allocate continuous heap cell, then free them and reallocate again + TInt al; + for (al=1; al<256; al+=al+1) + { + TAny* p0 = h->TestAlloc(al); + TInt al0 = h->AllocLen(p0); + h->TestFree(p0); + TAny* p1 = h->TestReAlloc(NULL, al, 0); + TInt al1 = h->AllocLen(p1); + test(p1 == p0); + test(al1 == al0); + h->TestFree(p1); + TAny* p2 = h->TestAlloc(1); + TAny* p3 = h->TestReAlloc(p2, al, 0); + test(p3 == p0); + TInt al3 = h->AllocLen(p3); + test(al3 == al0); + h->TestFree(p3); + TAny* p4 = h->TestAlloc(1024); + TAny* p5 = h->TestReAlloc(p4, al, 0); + test(p5 == p0); + TInt al5 = h->AllocLen(p5); + test(al5 == al0); + h->TestFree(p5); + } + TInt i; + TInt j; + for (j=0; j<30; j+=3) + { + TAny* p[30]; + TInt ala[30]; + TInt fla[30]; + h->Reset(); + for (i=0; i<30; ++i) + { + p[i] = h->TestAlloc(8*i*i); + ala[i] = h->AllocLen(p[i]); + fla[i] = 0; + } + for (i=1; i<30; i+=3) + { + h->TestFree(p[i]); + fla[i] = h->FreeCellLen(p[i]); + test(fla[i] == ala[i]); + test(h->FreeCellLen(p[i-1]) < 0); + test(h->FreeCellLen(p[i+1]) < 0); + } + h->FullCheck(); + TInt al1 = _ALIGN_UP(Max((RHeap::EAllocCellSize + 1), h->MinCell()), h->Align()); + // adjust al1 for some case when reallocated heap cell will not be shrinked because remainder will not big enough + // to form a new free cell due to a big KHeapMinCellSize value + TInt alaj = ala[j] + RHeap::EAllocCellSize; + if (al1 < alaj && alaj - al1 < h->MinCell()) + al1 = alaj; + TAny* p1 = h->TestReAlloc(p[j], 1, RHeap::ENeverMove); + test(p1 == p[j]); + test(h->AllocLen(p1) == al1 - RHeap::EAllocCellSize); + TAny* p1b = (TUint8*)p1 + al1; + test(h->FreeCellLen(p1b) == fla[j+1] + RHeap::EAllocCellSize + ala[j] - al1); + TInt l2 = ala[j] + fla[j+1] + RHeap::EAllocCellSize; // max without moving + TInt l3 = l2 - h->MinCell(); + TAny* p3 = h->TestReAlloc(p[j], l3, RHeap::ENeverMove); + test(p3 == p[j]); + TAny* p3b = (TUint8*)p3 + h->AllocLen(p3) + RHeap::EAllocCellSize; + test(h->FreeCellLen(p3b) == h->MinCell() - RHeap::EAllocCellSize); + TAny* p2 = h->TestReAlloc(p[j], l2, RHeap::ENeverMove); + test(p2 == p[j]); + test(h->AllocLen(p2) == l2); + TAny* p4 = h->TestReAlloc(p[j], l2+1, RHeap::ENeverMove); + test(p4 == NULL); + test(h->AllocLen(p2) == l2); + TAny* p5 = h->TestReAlloc(p[j], l2+1, 0); + TInt k = 0; + for (; k<30 && fla[k] <= l2; ++k) {} + if (k < 30) + test(p5 == p[k]); + else + test(p5 >= (TUint8*)p[29] + ala[29]); + test(h->FreeCellLen(p2) == ala[j] + ala[j+1] + RHeap::EAllocCellSize); + TInt ali = _ALIGN_UP(RHeap::EAllocCellSize,h->Align()); + TAny* p6b = (TUint8*)p[j+2] + ala[j+2] - ali + RHeap::EAllocCellSize; + test(h->FreeCellLen(p6b) < 0); + TAny* p6 = h->TestReAlloc(p[j+2], ala[j+2] - ali , 0); + test(p6 == p[j+2]); + if (h->AllocLen(p6) != ala[j+2]) // allocated heap cell size changed + test(h->FreeCellLen(p6b) == h->MinCell() - RHeap::EAllocCellSize); + TInt g = h->GrowBy(); + TAny* p7 = h->TestReAlloc(p5, 8*g, 0); + test(p7 >= p5); + TUint8* p8 = (TUint8*)p7 - RHeap::EAllocCellSize + al1; + TUint8* p9 = (TUint8*)_ALIGN_UP(TLinAddr(p8), h->PageSize()); + if (p9-p8 < h->MinCell()) + p9 += h->PageSize(); + TAny* p7b = h->TestReAlloc(p7, 1, 0); + test(p7b == p7); + test(h->Top() + (RHeap::EAllocCellSize & (h->Align()-1)) == p9); + + h->FullCheck(); + } + } + +// Test compression +// {1 free cell, >1 free cell} x {reduce cell, eliminate cell, reduce cell but too small} +// +void DoTest4(RHeap* aH) + { + RTestHeap* h = (RTestHeap*)aH; + test.Printf(_L("Test Compress: min=%x max=%x align=%d growby=%d\n"), + h->MinLength(), h->MaxLength(), h->Align(), h->GrowBy()); + TInt page_size; + UserHal::PageSizeInBytes(page_size); + test(page_size == h->PageSize()); + TInt g = h->GrowBy(); + TEST_ALIGN(g, page_size); + test(g >= page_size); + RChunk c; + c.SetHandle(h->ChunkHandle()); + TInt align = h->Align(); + TInt minc = h->MinCell(); + + TInt orig_size = c.Size(); + TUint8* orig_top = h->Top(); + + // size in bytes that last free cell on the top of the heap must be + // before the heap will be shrunk, size must include the no of bytes to + // store the cell data/header i.e RHeap::EAllocCellSize + TInt shrinkThres = KHeapShrinkHysRatio*(g>>8); + + TInt pass; + for (pass=0; pass<2; ++pass) + { + TUint8* p0 = (TUint8*)h->TestAlloc(4); + test(p0 == h->Base() + RHeap::EAllocCellSize); + TInt l1 = h->Top() - (TUint8*)h->FreeRef().next; + TEST_ALIGN(l1, align); + l1 -= RHeap::EAllocCellSize; + TUint8* p1; + // Grow heap by 2*iGrowBy bytes + p1 = (TUint8*)h->TestAlloc(l1 + 2*g); + test(p1 == p0 + h->AllocLen(p0) + RHeap::EAllocCellSize); + test(h->Top() - orig_top == 2*g); + test(c.Size() - orig_size == 2*g); + // May compress heap, may not + h->TestFree(p1); + h->ForceCompress(2*g); + test(h->Top() == orig_top); + test(c.Size() == orig_size); + test((TUint8*)h->FreeRef().next == p1 - RHeap::EAllocCellSize); + h->FullCheck(); + //if KHeapShrinkHysRatio is > 2.0 then heap compression will occur here + test(h->Compress() == 0); + test(h->TestAlloc(l1) == p1); + test(h->FreeRef().next == NULL); + if (pass) + h->TestFree(p0); // leave another free cell on second pass + TInt l2 = g - RHeap::EAllocCellSize; + // Will grow heap by iGrowBy bytes + TUint8* p2 = (TUint8*)h->TestAlloc(l2); + test(p2 == orig_top + RHeap::EAllocCellSize); + test(h->Top() - orig_top == g); + test(c.Size() - orig_size == g); + // may or may not compress heap + h->TestFree(p2); + if (l2+RHeap::EAllocCellSize >= shrinkThres) + { + // When KHeapShrinkRatio small enough heap will have been compressed + test(h->Top() == orig_top); + if (pass) + { + test((TUint8*)h->FreeRef().next == p0 - RHeap::EAllocCellSize); + test((TUint8*)h->FreeRef().next->next == NULL); + } + else + test((TUint8*)h->FreeRef().next == NULL); + } + else + { + test(h->Top() - orig_top == g); + if (pass) + { + test((TUint8*)h->FreeRef().next == p0 - RHeap::EAllocCellSize); + test((TUint8*)h->FreeRef().next->next == orig_top); + } + else + test((TUint8*)h->FreeRef().next == orig_top); + } + // this compress will only do anything if the KHeapShrinkRatio is large + // enough to introduce hysteresis otherwise the heap would have been compressed + // by the free operation itself + TInt tmp1,tmp2; + tmp2=h->CalcComp(g); + tmp1=h->Compress(); + test(tmp1 == tmp2); + test(h->Top() == orig_top); + test(c.Size() == orig_size); + h->FullCheck(); + // shouldn't compress heap as already compressed + test(h->Compress() == 0); + //grow heap by iGrowBy bytes + test(h->TestAlloc(l2) == p2); + //grow heap by iGrowBy bytes + TUint8* p3 = (TUint8*)h->TestAlloc(l2); + test(p3 == p2 + g); + test(h->Top() - orig_top == 2*g); + test(c.Size() - orig_size == 2*g); + // may or may not reduce heap + h->TestFree(p2); + // may or may not reduce heap + h->TestFree(p3); + h->ForceCompress(2*g); + test(h->Top() == orig_top); + test(c.Size() == orig_size); + h->FullCheck(); + if (pass) + { + test((TUint8*)h->FreeRef().next == p0 - RHeap::EAllocCellSize); + test((TUint8*)h->FreeRef().next->next == NULL); + } + else + test((TUint8*)h->FreeRef().next == NULL); + //grow heap by iGrowBy bytes + test(h->TestAlloc(l2) == p2); + //grow heap by iGrowBy*2 + page size bytes + test(h->TestAlloc(l2 + g + page_size) == p3); + test(h->Top() - orig_top == 4*g); + test(c.Size() - orig_size == 4*g); + // will compress heap if KHeapShrinkHysRatio <= KHeapShrinkRatioDflt + test(h->TestReAlloc(p3, page_size - RHeap::EAllocCellSize, 0) == p3); + h->ForceCompress(g+page_size); + test(h->Top() - orig_top == g + page_size); + test(c.Size() - orig_size == g + page_size); + h->FullCheck(); + // will compress heap if KHeapShrinkHysRatio <= KHeapShrinkRatio1 + h->TestFree(p2); + // will compress heap if KHeapShrinkHysRatio <= KHeapShrinkRatio1 && g<=page_size + // or KHeapShrinkHysRatio >= 2.0 and g==page_size + h->TestFree(p3); + // may or may not perform further compression + tmp1=h->CalcComp(g+page_size); + tmp2=h->Compress(); + test(tmp1 == tmp2); + test(h->Top() == orig_top); + test(c.Size() == orig_size); + h->FullCheck(); + test(h->TestAlloc(l2 - minc) == p2); + test(h->TestAlloc(l2 + g + page_size + minc) == p3 - minc); + test(h->Top() - orig_top == 4*g); + test(c.Size() - orig_size == 4*g); + h->TestFree(p3 - minc); + h->ForceCompress(l2 + g + page_size + minc); + test(h->Top() - orig_top == g); + test(c.Size() - orig_size == g); + h->FullCheck(); + if (pass) + { + test((TUint8*)h->FreeRef().next == p0 - RHeap::EAllocCellSize); + test((TUint8*)h->FreeRef().next->next == p3 - minc - RHeap::EAllocCellSize); + } + else + test((TUint8*)h->FreeRef().next == p3 - minc - RHeap::EAllocCellSize); + h->TestFree(p2); + if (l2+RHeap::EAllocCellSize >= shrinkThres) + { + // When KHeapShrinkRatio small enough heap will have been compressed + test(h->Top() == orig_top); + test(c.Size() - orig_size == 0); + } + else + { + test(h->Top() - orig_top == g); + test(c.Size() - orig_size == g); + } + h->FullCheck(); + if ( ((TLinAddr)orig_top & (align-1)) == 0) + { + TAny* free; + TEST_ALIGN(p2 - RHeap::EAllocCellSize, page_size); + // will have free space of g-minc + test(h->TestAlloc(l2 + minc) == p2); + test(h->Top() - orig_top == 2*g); + test(c.Size() - orig_size == 2*g); + free = pass ? h->FreeRef().next->next : h->FreeRef().next; + test(free != NULL); + test(h->TestReAlloc(p2, l2 - 4, 0) == p2); + TInt freeSp = g-minc + (l2+minc - (l2-4)); + TInt adjust = 0; + if (freeSp >= shrinkThres && freeSp-page_size >= minc) + { + // if page_size is less than growBy (g) then heap will be shrunk + // by less than a whole g. + adjust = g-((page_sizeTop() - orig_top == 2*g - adjust); + test(c.Size() - orig_size == 2*g - adjust); + free = pass ? h->FreeRef().next->next : h->FreeRef().next; + test(free != NULL); + TEST_ALIGN(TLinAddr(free)+4, page_size); + test(h->TestAlloc(l2 + g + page_size + 4) == p3 - 4); + test(h->Top() - orig_top == 4*g - adjust); + test(c.Size() - orig_size == 4*g - adjust); + h->TestFree(p3 - 4); + h->ForceCompress(l2 + g + page_size + 4); + test(h->Top() - orig_top == g + page_size); + test(c.Size() - orig_size == g + page_size); + h->FullCheck(); + h->TestFree(p2); + h->ForceCompress(l2-4); + test(h->Compress() == 0); + // check heap is grown, will have free space of g-minc + test(h->TestAlloc(l2 + minc) == p2); + test(h->Top() - orig_top == 2*g); + test(c.Size() - orig_size == 2*g); + free = pass ? h->FreeRef().next->next : h->FreeRef().next; + test(free != NULL); + // may shrink heap as will now have g+minc free bytes + test(h->TestReAlloc(p2, l2 - minc, 0) == p2); + if (g+minc >= shrinkThres) + { + test(h->Top() - orig_top == g); + test(c.Size() - orig_size == g); + } + else + { + test(h->Top() - orig_top == 2*g); + test(c.Size() - orig_size == 2*g); + } + free = pass ? h->FreeRef().next->next : h->FreeRef().next; + test(free != NULL); + TEST_ALIGN(TLinAddr(free)+minc, page_size); + test(h->TestAlloc(l2 + g + page_size + minc) == p3 - minc); + test(h->Top() - orig_top == 4*g); + test(c.Size() - orig_size == 4*g); + h->TestFree(p3 - minc); + h->ForceCompress(l2 + g + page_size + minc); + test(h->Top() - orig_top == g); + test(c.Size() - orig_size == g); + h->FullCheck(); + h->TestFree(p2); + } + + h->TestFree(p1); + if (pass == 0) + h->TestFree(p0); + h->Compress(); + } + h->FullCheck(); + } + +void Test1() + { + RHeap* h; + h = RTestHeap::FixedHeap(0x1000, 0); + test(h != NULL); + DoTest1(h); + h->Close(); + h = RTestHeap::FixedHeap(0x1000, 0, EFalse); + test(h != NULL); + DoTest1(h); + h->Close(); + h = RTestHeap::FixedHeap(0x10000, 64); + test(h != NULL); + DoTest1(h); + h->Close(); + h = RTestHeap::FixedHeap(0x100000, 4096); + test(h != NULL); + DoTest1(h); + h->Close(); + h = RTestHeap::FixedHeap(0x100000, 8192); + test(h != NULL); + DoTest1(h); + h->Close(); + h = UserHeap::ChunkHeap(&KNullDesC(), 0x1000, 0x1000, 0x1000, 4); + test(h != NULL); + DoTest1(h); + h->Close(); + h = UserHeap::ChunkHeap(&KNullDesC(), 0x1000, 0x10000, 0x1000, 4); + test(h != NULL); + DoTest1(h); + h->Close(); + h = UserHeap::ChunkHeap(&KNullDesC(), 0x1000, 0x100000, 0x1000, 4096); + test(h != NULL); + DoTest1(h); + h->Close(); + h = UserHeap::ChunkHeap(&KNullDesC(), 0x1000, 0x100000, 0x1000, 4); + test(h != NULL); + DoTest1(h); + h->Reset(); + DoTest2(h); + h->Reset(); + DoTest3(h); + h->Reset(); + DoTest4(h); + h->Close(); + h = UserHeap::ChunkHeap(&KNullDesC(), 0x1000, 0x100000, 0x1000, 8); + test(h != NULL); + DoTest1(h); + h->Reset(); + DoTest2(h); + h->Reset(); + DoTest3(h); + h->Reset(); + DoTest4(h); + h->Close(); + h = UserHeap::ChunkHeap(&KNullDesC(), 0x1000, 0x100000, 0x1000, 16); + test(h != NULL); + DoTest1(h); + h->Reset(); + DoTest2(h); + h->Reset(); + DoTest3(h); + h->Reset(); + DoTest4(h); + h->Close(); + h = UserHeap::ChunkHeap(&KNullDesC(), 0x1000, 0x100000, 0x1000, 32); + test(h != NULL); + DoTest1(h); + h->Reset(); + DoTest2(h); + h->Reset(); + DoTest3(h); + h->Reset(); + DoTest4(h); + h->Close(); + h = UserHeap::ChunkHeap(&KNullDesC(), 0x3000, 0x100000, 0x3000, 4); + test(h != NULL); + DoTest1(h); + h->Reset(); + DoTest2(h); + h->Reset(); + DoTest3(h); + h->Reset(); + DoTest4(h); + h->Close(); + } + +struct SHeapStress + { + RThread iThread; + volatile TBool iStop; + TInt iAllocs; + TInt iFailedAllocs; + TInt iFrees; + TInt iReAllocs; + TInt iFailedReAllocs; + TInt iChecks; + TUint32 iSeed; + RAllocator* iAllocator; + + TUint32 Random(); + }; + +TUint32 SHeapStress::Random() + { + iSeed *= 69069; + iSeed += 41; + return iSeed; + } + +TInt RandomLength(TUint32 aRandom) + { + TUint8 x = (TUint8)aRandom; + if (x & 0x80) + return (x & 0x7f) << 7; + return x & 0x7f; + } + +TInt HeapStress(TAny* aPtr) + { + SHeapStress& hs = *(SHeapStress*)aPtr; + RTestHeap* h = (RTestHeap*)&User::Allocator(); + TUint8* cell[256]; + TInt len[256]; + + Mem::FillZ(cell, sizeof(cell)); + Mem::FillZ(len, sizeof(len)); + + RThread::Rendezvous(KErrNone); + while (!hs.iStop) + { + // allocate all cells + TInt i; + for (i=0; i<256; ++i) + { + if (!cell[i]) + { + ++hs.iAllocs; + cell[i] = (TUint8*)h->TestAlloc(RandomLength(hs.Random())); + if (cell[i]) + len[i] = h->AllocLen(cell[i]); + else + ++hs.iFailedAllocs; + } + } + + // free some cells + TInt n = 64 + (hs.Random() & 127); + while (--n) + { + i = hs.Random() & 0xff; + if (cell[i]) + { + test(h->AllocLen(cell[i]) == len[i]); + h->TestFree(cell[i]); + cell[i] = NULL; + len[i] = 0; + ++hs.iFrees; + } + } + + // realloc some cells + n = 64 + (hs.Random() & 127); + while (--n) + { + TUint32 rn = hs.Random(); + i = (rn >> 8) & 0xff; + TInt new_len = RandomLength(rn); + if (cell[i]) + { + test(h->AllocLen(cell[i]) == len[i]); + ++hs.iReAllocs; + TUint8* p = (TUint8*)h->TestReAlloc(cell[i], new_len, rn >> 16); + if (p) + { + cell[i] = p; + len[i] = h->AllocLen(p); + } + else + ++hs.iFailedReAllocs; + } + } + + // check the heap + h->Check(); + ++hs.iChecks; + } + return 0; + } + +void CreateStressThread(SHeapStress& aInfo) + { + Mem::FillZ(&aInfo, _FOFF(SHeapStress, iSeed)); + RThread& t = aInfo.iThread; + TInt r = t.Create(KNullDesC(), &HeapStress, 0x2000, aInfo.iAllocator, &aInfo); + test(r==KErrNone); + t.SetPriority(EPriorityLess); + TRequestStatus s; + t.Rendezvous(s); + test(s == KRequestPending); + t.Resume(); + User::WaitForRequest(s); + test(s == KErrNone); + test(t.ExitType() == EExitPending); + t.SetPriority(EPriorityMuchLess); + } + +void StopStressThread(SHeapStress& aInfo) + { + RThread& t = aInfo.iThread; + TRequestStatus s; + t.Logon(s); + aInfo.iStop = ETrue; + User::WaitForRequest(s); + const TDesC& exitCat = t.ExitCategory(); + TInt exitReason = t.ExitReason(); + TInt exitType = t.ExitType(); + test.Printf(_L("Exit type %d,%d,%S\n"), exitType, exitReason, &exitCat); + test(exitType == EExitKill); + test(exitReason == KErrNone); + test(s == KErrNone); + test.Printf(_L("Total Allocs : %d\n"), aInfo.iAllocs); + test.Printf(_L("Failed Allocs : %d\n"), aInfo.iFailedAllocs); + test.Printf(_L("Total Frees : %d\n"), aInfo.iFrees); + test.Printf(_L("Total ReAllocs : %d\n"), aInfo.iReAllocs); + test.Printf(_L("Failed ReAllocs : %d\n"), aInfo.iFailedReAllocs); + test.Printf(_L("Heap checks : %d\n"), aInfo.iChecks); + } + +void DoStressTest1(RAllocator* aAllocator) + { + RTestHeap* h = (RTestHeap*)aAllocator; + test.Printf(_L("Test Stress 1: min=%x max=%x align=%d growby=%d\n"), + h->MinLength(), h->MaxLength(), h->Align(), h->GrowBy()); + SHeapStress hs; + hs.iSeed = 0xb504f334; + hs.iAllocator = aAllocator; + CreateStressThread(hs); + User::After(10*1000000); + StopStressThread(hs); + CLOSE_AND_WAIT(hs.iThread); + h->FullCheck(); + } + +void DoStressTest2(RAllocator* aAllocator) + { + RTestHeap* h = (RTestHeap*)aAllocator; + test.Printf(_L("Test Stress 2: min=%x max=%x align=%d growby=%d\n"), + h->MinLength(), h->MaxLength(), h->Align(), h->GrowBy()); + SHeapStress hs1; + SHeapStress hs2; + hs1.iSeed = 0xb504f334; + hs1.iAllocator = aAllocator; + hs2.iSeed = 0xddb3d743; + hs2.iAllocator = aAllocator; + CreateStressThread(hs1); + CreateStressThread(hs2); + User::After(20*1000000); + StopStressThread(hs1); + StopStressThread(hs2); + CLOSE_AND_WAIT(hs1.iThread); + CLOSE_AND_WAIT(hs2.iThread); + h->FullCheck(); + } + +void StressTests() + { + RHeap* h; + h = UserHeap::ChunkHeap(&KNullDesC(), 0x1000, 0x100000, 0x1000, 4); + test(h != NULL); + DoStressTest1(h); + h->Reset(); + DoStressTest2(h); + h->Close(); + h = UserHeap::ChunkHeap(&KNullDesC(), 0x1000, 0x100000, 0x1000, 8); + test(h != NULL); + DoStressTest1(h); + h->Reset(); + DoStressTest2(h); + h->Close(); + } + +TInt TestHeapGrowInPlace(TInt aMode) + { + TBool reAllocs=EFalse; + TBool heapGrew=EFalse; + + RHeap* myHeap; + + myHeap = UserHeap::ChunkHeap(NULL,0x1000,0x4000,0x1000); + + TAny *testBuffer,*testBuffer2; + // Start size chosen so that 1st realloc will use up exactly all the heap. + // Later iterations wont, and there will be a free cell at the end of the heap. + TInt currentSize = ((0x800) - sizeof(RHeap)) - RHeap::EAllocCellSize; + TInt growBy = 0x800; + TInt newSpace, space; + + testBuffer2 = myHeap->Alloc(currentSize); + + newSpace = myHeap->Size(); + do + { + space = newSpace; + testBuffer = testBuffer2; + currentSize+=growBy; + testBuffer2 = myHeap->ReAlloc(testBuffer,currentSize,aMode); + + newSpace = myHeap->Size(); + + if (testBuffer2) + { + + if (testBuffer!=testBuffer2) + reAllocs = ETrue; + + if (newSpace>space) + heapGrew = ETrue; + } + growBy-=16; + } while (testBuffer2); + currentSize-=growBy; + + myHeap->Free(testBuffer); + myHeap->Close(); + + // How did we do? + if (reAllocs) + { + test.Printf(_L("Failure - Memory was moved!\n")); + return -100; + } + if (!heapGrew) + { + test.Printf(_L("Failure - Heap Never Grew!\n")); + return -200; + } + if (currentSize<= 0x3000) + { + test.Printf(_L("Failed to grow by a reasonable amount!\n")); + return -300; + } + + return KErrNone; + } + +void ReAllocTests() + { + test.Next(_L("Testing Grow In Place")); + test(TestHeapGrowInPlace(0)==KErrNone); + test(TestHeapGrowInPlace(RHeap::ENeverMove)==KErrNone); + } + +RHeap* TestDEF078391Heap = 0; + +TInt TestDEF078391ThreadFunction(TAny*) + { + TestDEF078391Heap = UserHeap::ChunkHeap(NULL,0x1000,0x100000,KMinHeapGrowBy,0,EFalse); + return TestDEF078391Heap ? KErrNone : KErrGeneral; + } + +void TestDEF078391() + { + // Test that creating a multithreaded heap with UserHeap::ChunkHeap + // doesn't create any reference counts on the creating thread. + // This is done by creating a heap in a named thread, then exiting + // the thread and re-creating it with the same name. + // This will fail with KErrAlreadyExists if the orinal thread has + // not died because of an unclosed reference count. + test.Next(_L("Test that creating a multithreaded heap doesn't open references of creator")); + _LIT(KThreadName,"ThreadName"); + RThread t; + TInt r=t.Create(KThreadName,TestDEF078391ThreadFunction,0x1000,0x1000,0x100000,NULL); + test(r==KErrNone); + TRequestStatus status; + t.Logon(status); + t.Resume(); + User::WaitForRequest(status); + test(status==KErrNone); + test(t.ExitType()==EExitKill); + test(t.ExitReason()==KErrNone); + CLOSE_AND_WAIT(t); + test(TestDEF078391Heap!=0); + User::After(1000000); // give more opportunity for thread cleanup to happen + + // create thread a second time + r=t.Create(KThreadName,TestDEF078391ThreadFunction,0x1000,0x1000,0x100000,NULL); + test(r==KErrNone); + t.Kill(0); + CLOSE_AND_WAIT(t); + + // close the heap that got created earlier + TestDEF078391Heap->Close(); + } + +TInt E32Main() + { + test.Title(); + __KHEAP_MARK; + test.Start(_L("Testing heaps")); + TestDEF078391(); + Test1(); + StressTests(); + ReAllocTests(); + test.End(); + __KHEAP_MARKEND; + return 0; + }