Parallel-parsing "noexport" flag.
/*
* Copyright (c) 1996-2009 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:
*
*/
#include <e32std.h>
#include <e32std_private.h>
#include <e32uid.h>
#include "h_utl.h"
#include <string.h>
#include <stdlib.h>
#include "r_global.h"
#include "r_obey.h"
#include "r_rom.h"
#include "r_dir.h"
// Routines for optimising the ROM by improving the code
//
// NB. Largely untouched since ER5, so not likely to work without
// some significant effort. Doesn't know about ARMv4T or ARMv5 instructions.
TInt E32Rom::CollapseImportThunks(TRomBuilderEntry* aFile)
//
// Collapse 3-word import thunks into a single branch
//
{
TRomImageHeader *pI=aFile->iRomImageHeader;
TUint32 *pE=(TUint32*)RomToActualAddress(pI->iCodeAddress); // address of code section
TUint32 codeSize=pI->iCodeSize;
TUint32 *pC=pE+(codeSize>>2)-3;
TUint32 low=0;
TUint32 high=0;
TUint32 romLow=0;
TUint32 romHigh=0;
TBool block=EFalse;
TInt blocknum=0;
TRACE(TCOLLAPSE1,Print(ELog,"CollapseImportThunks() File %s[%08x]\n",aFile->iFileName,
pI->iHardwareVariant));
while(pC>=pE)
{
if (pC[0]==0xe59fc000 && pC[1]==0xe59cf000 && (pC[2]&0xf0000000)==0x50000000)
{
// assume this is an import thunk
if (!block)
{
high=(TUint32)(pC+3);
block=ETrue;
}
pC-=3;
}
else
{
if (block)
{
low=(TUint32)(pC+3);
block=EFalse;
TInt numImports=(high-low)/12;
TRACE(TCOLLAPSE2,Print(ELog,"?Import thunk block %08x-%08x %d %d\n",ActualToRomAddress((TAny*)low),ActualToRomAddress((TAny*)high),numImports,aFile->iImportCount));
if (numImports==aFile->iImportCount)
{
if (blocknum==0)
{
romLow=(TUint32)ActualToRomAddress((TAny*)low);
romHigh=(TUint32)ActualToRomAddress((TAny*)high);
}
blocknum++;
}
}
pC--;
}
}
if (blocknum==0)
{
Print(EWarning,"Import thunk block for %s[%08x] not found\n",aFile->iFileName,
pI->iHardwareVariant);
}
else if (blocknum==1)
{
low=(TUint32)RomToActualAddress(romLow);
high=(TUint32)RomToActualAddress(romHigh);
TRACE(TCOLLAPSE1,Print(ELog,"Import thunk block %08x-%08x\n",romLow,romHigh));
TUint32 *pX;
for (pX=(TUint32*)low; pX<(TUint32*)high; pX+=3)
{
TUint32 *pA=(TUint32*)RomToActualAddress(pX[2]);
TUint32 jumpAddr=*pA;
jumpAddr=FindFinalJumpDestination(jumpAddr);
TInt offset=(TInt)jumpAddr-(TInt)ActualToRomAddress(pX)-8;
if (offset<33554432 && offset>-33554432)
{
pX[0]=0xea000000 | ((offset&0x03ffffff)>>2);
iImportsFixedUp++;
}
}
aFile->iImportBlockStartAddress=romLow;
aFile->iImportBlockEndAddress=romHigh;
}
else
Print(EWarning,"??Import thunk block ambiguous - not changed\n");
return KErrNone;
}
TInt E32Rom::CollapseBranches()
//
// Collapse chained branches
//
{
Print(ELog, "\nCollapsing Chained Branches.\n");
TInt i;
for (i=0; i<iObey->iNumberOfPeFiles; i++)
{
TRomBuilderEntry* file=iPeFiles[i];
if (file->iOrigHdr->iImportOffset && file->iImportBlockEndAddress!=0)
{
TInt r=CollapseBranches(file);
if (r!=KErrNone)
return r;
}
}
return KErrNone;
}
inline void SetBit(TUint32* aBitmap, TInt aOffset)
{
aOffset>>=2;
aBitmap[aOffset>>5] |= (1<<(aOffset&0x1f));
}
inline TInt BitTest(TUint32* aBitmap, TInt aOffset)
{
aOffset>>=2;
return(aBitmap[aOffset>>5]&(1<<(aOffset&0x1f)));
}
TUint32 E32Rom::FindFinalJumpDestination(TUint32 ja)
{
// follow a chain of branches to final destination
TUint32 initja=ja;
TUint8* aja=(TUint8*)RomToActualAddress(ja);
FOREVER
{
if ((*(TUint32*)aja &0xff000000)==0xea000000)
{
// branch to an unconditional branch
TInt off=(*(TUint32*)aja & 0x00ffffff)<<8;
off>>=6;
if (off==-8)
{
// branch to same address
break;
}
ja+=(off+8);
aja+=(off+8);
TRACE(TCOLLAPSE2,Print(ELog,"Chain branch %08x to %08x\n",initja,ja));
}
else
break;
}
return ja;
}
TInt E32Rom::CollapseBranches(TRomBuilderEntry* aFile)
{
// Main code section is between pI->iCodeAddress and aImportThunkStart. This contains
// all the explicit code and interspersed literals.
// aImportThunkStart-aImportThunkEnd contains import thunks (already collapsed)
// aImportThunkEnd-iat contains template instantiations and virtual destructors
// iat-rdata contains import addresses - no need to touch these
// rdata-expdir contains constant data and vtables
// expdir-end contains exported addresses - no need to touch these
TUint32 impStart=aFile->iImportBlockStartAddress;
TUint32 impEnd=aFile->iImportBlockEndAddress;
TRomImageHeader *pI=aFile->iRomImageHeader;
TRACE(TCOLLAPSE1,Print(ELog,"CollapseBranches() File %s[%08x]\n",aFile->iFileName,
pI->iHardwareVariant));
TUint32 codeStart=pI->iCodeAddress;
TUint32 codeSize=pI->iCodeSize;
TUint32 codeEnd=codeStart+codeSize;
TUint32 *pC=(TUint32*)RomToActualAddress(codeStart); // address of code section
TUint32 *pE=(TUint32*)RomToActualAddress(codeEnd);
TUint32 romIat=codeStart+aFile->iHdr->iTextSize;
TUint32 romRdata=romIat+aFile->iImportCount*4;
TUint32 exportDir=pI->iExportDir;
if (exportDir==0)
exportDir=codeEnd;
TRACE(TCOLLAPSE1,Print(ELog,"iat=%08x, rdata=%08x, expdir=%08x, end=%08x\n",romIat,romRdata,exportDir,codeEnd));
TUint32 *pD=new TUint32[(codeSize+127)>>7];
if (!pD)
return KErrNoMemory;
TInt rdataSize=TInt(exportDir)-TInt(romRdata);
TUint32 *pR=new TUint32[(rdataSize+127)>>7];
if (!pR)
return KErrNoMemory;
TInt i;
for (i=0; i<TInt((codeSize+127)>>7); i++)
pD[i]=0;
for (i=0; i<TInt((rdataSize+127)>>7); i++)
pR[i]=0;
TUint32 *pX;
// go through code looking for data references
for (pX=pC; pX<pE; pX++)
{
if ((*pX&0x0f3f0000)==0x051f0000)
{
// opcode is LDRcc Rn, [PC, #d]
TInt offset=*pX & 0xfff;
if ((*pX&0x00800000)==0)
offset=-offset;
TUint32 eff=(ActualToRomAddress(pX)+8+offset)&~3;
if (eff>=codeStart && eff<codeEnd)
{
SetBit(pD,eff-codeStart);
if (eff<codeEnd-4)
SetBit(pD,eff-codeStart+4);
TUint32 data=*(TUint32*)((TUint8*)pX+(offset&~3)+8); // fetch data word
if (data>=romRdata && data<exportDir)
{
// it's an address of something in .rdata, possibly a vtable
SetBit(pR,data-romRdata);
}
}
}
}
TUint32 *importStart=(TUint32*)RomToActualAddress(impStart);
TUint32 *iatStart=(TUint32*)RomToActualAddress(romIat);
if (iObey->iCollapseMode==ECollapseImportThunksAndVtables)
goto vtablesonly;
// go through .text looking for Bcc and BLcc intstructions
for (pX=pC; pX<importStart; pX++)
{
if ((*pX&0xfe000000)==0xea000000 && BitTest(pD,TInt(pX)-TInt(pC))==0 )
{
TInt off=(*pX & 0x00ffffff)<<8;
off>>=6;
TUint32 pc=ActualToRomAddress(pX)+8;
TUint32 ja=pc+off;
TUint32 initja=ja;
if (ja<codeStart || ja>=codeEnd)
{
TRACE(TCOLLAPSE2,Print(ELog,"??Branch at %08x to %08x??\n",pc-8,ja));
goto notthismodule;
}
TRACE(TCOLLAPSE4,Print(ELog,"Branch at %08x opcode %08x ja=%08x\n",pc-8,*pX,ja));
ja=FindFinalJumpDestination(ja);
if (ja!=initja)
{
off=(TInt(ja)-TInt(pc))>>2;
if (off>-33554432 && off<33554432)
{
TUint32 oldOpc=*pX;
*pX=(*pX & 0xff000000)|(off&0x00ffffff); // fix up branch
TRACE(TCOLLAPSE2,Print(ELog,"Opcode at %08x fixed up from %08x to %08x\n",pc-8,oldOpc,*pX));
iBranchesFixedUp++;
}
}
notthismodule: ;
}
}
// go through template instantiations and virtual destructors
// looking for Bcc and BLcc intstructions to import thunks
pX=(TUint32*)RomToActualAddress(impEnd);
for (; pX<iatStart; pX++)
{
if ((*pX&0xfe000000)==0xea000000 && BitTest(pD,TInt(pX)-TInt(pC))==0 )
{
TInt off=(*pX & 0x00ffffff)<<8;
off>>=6;
TUint32 pc=ActualToRomAddress(pX)+8;
TUint32 ja=pc+off;
TUint32 initja=ja;
TRACE(TCOLLAPSE4,Print(ELog,"Branch at %08x opcode %08x ja=%08x\n",pc-8,*pX,ja));
if (ja<codeStart || ja>=codeEnd)
{
TRACE(TCOLLAPSE2,Print(ELog,"??Branch at %08x to %08x??\n",pc-8,ja));
goto notthismodule2;
}
ja=FindFinalJumpDestination(ja);
if (ja!=initja)
{
off=(TInt(ja)-TInt(pc))>>2;
if (off>-33554432 && off<33554432)
{
TUint32 oldOpc=*pX;
*pX=(*pX & 0xff000000)|(off&0x00ffffff); // fix up branch
TRACE(TCOLLAPSE2,Print(ELog,"Opcode at %08x fixed up from %08x to %08x\n",pc-8,oldOpc,*pX));
iBranchesFixedUp++;
}
}
notthismodule2: ;
}
}
vtablesonly:
// go through rdata section looking for vtables with references to import thunks
TUint32 *expStart=(TUint32*)RomToActualAddress(exportDir);
TUint32* pW=(TUint32*)RomToActualAddress(romRdata);
pX=pW;
while(pX<expStart-1)
{
// first look for reference to start of vtable
// there are always two 0 words at the start of a vtable
if (BitTest(pR,TInt(pX)-TInt(pW)) && pX[0]==0 && pX[1]==0)
{
TRACE(TCOLLAPSE3,Print(ELog,"?vtable at %08x\n",ActualToRomAddress(pX)));
// look for next reference - there are no references to
// intermediate entries of vtable
TUint32* pY;
for (pY=pX+1; pY<expStart && BitTest(pR,TInt(pY)-TInt(pW))==0; pY++);
// pY should now point to the end of the vtable
// check all entries except the first two are valid ROM addresses in this module
TRACE(TCOLLAPSE3,Print(ELog,"?vtable at %08x to %08x\n",ActualToRomAddress(pX),ActualToRomAddress(pY)));
TUint32 *pZ;
for (pZ=pX+2; pZ<pY; pZ++)
{
if (*pZ<codeStart || *pZ>=codeEnd)
break;
}
if (pZ==pY)
{
// this is a vtable
// check each address to see if it is an import thunk and if so fix it up
TRACE(TCOLLAPSE3,Print(ELog,"!vtable at %08x to %08x\n",ActualToRomAddress(pX),ActualToRomAddress(pY)));
for (pZ=pX+2; pZ<pY; pZ++)
{
TUint32 ja=*pZ;
TUint32 initja=ja;
ja=FindFinalJumpDestination(ja);
if (ja!=initja)
{
*pZ=ja;
TRACE(TCOLLAPSE2,Print(ELog,"Vtable entry at %08x fixed up from %08x to %08x\n",ActualToRomAddress(pZ),initja,ja));
iVtableEntriesFixedUp++;
}
}
pX=pY;
}
else
pX++;
}
else
pX++;
}
delete[] pR;
delete[] pD;
return KErrNone;
}