Add --asm option to elf2e32, so that GCCE builds can use --asm=gas with --dump=a and get a usable .s file (Bug 1405)
// Copyright (c) 2005-2009 Nokia Corporation and/or its subsidiary(-ies).
// All rights reserved.
// This component and the accompanying materials are made available
// under the terms of "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 "byte_pair.h"
#undef ASSERT
#define ASSERT(c) if(!(c)) \
{ \
__BREAKPOINT() \
}
const TInt MaxBlockSize = 0x1000;
TUint16 PairCount[0x10000];
TUint16 PairBuffer[MaxBlockSize*2];
TUint16 GlobalPairs[0x10000] = {0};
TUint16 GlobalTokenCounts[0x100] = {0};
TUint16 ByteCount[0x100+4];
void CountBytes(TUint8* data, TInt size)
{
memset(ByteCount,0,sizeof(ByteCount));
TUint8* dataEnd = data+size;
while(data<dataEnd)
++ByteCount[*data++];
}
inline void ByteUsed(TInt b)
{
ByteCount[b] = 0xffff;
}
// 11915620
// 11913551 return -ByteCount[b1]-ByteCount[b2];
// 11913185
#if 0
int TieBreak(int b1,int b2)
{
int i;
int x = 0;
for(i=0; i<0x100; i++)
x += PairCount[(b1<<8)+i];
int y = 0;
for(i=b2; i<0x10000; i+=0x100)
y += PairCount[i];
return -x-y;
}
#endif
int TieBreak(int b1,int b2)
{
return -ByteCount[b1]-ByteCount[b2];
}
TInt MostCommonPair(TInt& pair, TUint8* data, TInt size, TInt minFrequency, TInt marker)
{
memset(PairCount,0,sizeof(PairCount));
TUint8* dataEnd = data+size-1;
TInt pairsFound = 0;
TInt lastPair = -1;
while(data<dataEnd)
{
TInt b1 = *data++;
if(b1==marker)
{
// skip marker and following byte
lastPair = -1;
++data;
continue;
}
TInt b2 = *data;
if(b2==marker)
{
// skip marker and following byte
lastPair = -1;
data+=2;
continue;
}
TInt p = (b2<<8)|b1;
if(p==lastPair)
{
// ensure a pair of identical bytes don't get double counted
lastPair = -1;
continue;
}
lastPair = p;
++PairCount[p];
if(PairCount[p]==minFrequency)
PairBuffer[pairsFound++] = (TUint16)p;
}
TInt bestCount = -1;
TInt bestPair = -1;
TInt bestTieBreak = 0;
TInt p;
while(pairsFound--)
{
p = PairBuffer[pairsFound];
TInt f=PairCount[p];
if(f>bestCount)
{
bestCount = f;
bestPair = p;
bestTieBreak = TieBreak(p&0xff,p>>8);
}
else if(f==bestCount)
{
TInt tieBreak = TieBreak(p&0xff,p>>8);
if(tieBreak>bestTieBreak)
{
bestCount = f;
bestPair = p;
bestTieBreak = tieBreak;
}
}
}
pair = bestPair;
return bestCount;
}
TInt LeastCommonByte(TInt& byte)
{
TInt bestCount = 0xffff;
TInt bestByte = -1;
for(TInt b=0; b<0x100; b++)
{
TInt f = ByteCount[b];
if(f<bestCount)
{
bestCount = f;
bestByte = b;
}
}
byte = bestByte;
return bestCount;
}
TInt Pak(TUint8* dst, TUint8* src, TInt size)
{
TInt originalSize = size;
TUint8* dst2 = dst+size*2;
TUint8* in = src;
TUint8* out = dst;
TUint8 tokens[0x100*3];
TInt tokenCount = 0;
CountBytes(in,size);
TInt marker = -1;
TInt overhead = 1+3+LeastCommonByte(marker);
ByteUsed(marker);
TUint8* inEnd = in+size;
TUint8* outStart = out;
while(in<inEnd)
{
TInt b=*in++;
if(b==marker)
*out++ = (TUint8)b;
*out++ = (TUint8)b;
}
size = out-outStart;
TInt outToggle = 1;
in = dst;
out = dst2;
for(TInt r=256; r>0; --r)
{
TInt byte;
TInt byteCount = LeastCommonByte(byte);
TInt pair;
TInt pairCount = MostCommonPair(pair,in,size,overhead+1,marker);
TInt saving = pairCount-byteCount;
if(saving<=overhead)
break;
overhead = 3;
if(tokenCount>=32)
overhead = 2;
TUint8* d=tokens+3*tokenCount;
++tokenCount;
*d++ = (TUint8)byte;
ByteUsed(byte);
*d++ = (TUint8)pair;
ByteUsed(pair&0xff);
*d++ = (TUint8)(pair>>8);
ByteUsed(pair>>8);
++GlobalPairs[pair];
inEnd = in+size;
outStart = out;
while(in<inEnd)
{
TInt b=*in++;
if(b==marker)
{
*out++ = (TUint8)marker;
b = *in++;
}
else if(b==byte)
{
*out++ = (TUint8)marker;
--byteCount;
}
else if(b==(pair&0xff) && in<inEnd && *in==(pair>>8))
{
++in;
b = byte;
--pairCount;
}
*out++ = (TUint8)b;
}
ASSERT(!byteCount);
ASSERT(!pairCount);
size = out-outStart;
outToggle ^= 1;
if(outToggle)
{
in = dst;
out = dst2;
}
else
{
in = dst2;
out = dst;
}
}
// sort tokens with a bubble sort...
for(TInt x=0; x<tokenCount-1; x++)
for(TInt y=x+1; y<tokenCount; y++)
if(tokens[x*3]>tokens[y*3])
{
TInt z = tokens[x*3];
tokens[x*3] = tokens[y*3];
tokens[y*3] = (TUint8)z;
z = tokens[x*3+1];
tokens[x*3+1] = tokens[y*3+1];
tokens[y*3+1] = (TUint8)z;
z = tokens[x*3+2];
tokens[x*3+2] = tokens[y*3+2];
tokens[y*3+2] = (TUint8)z;
}
// check for not being able to compress...
if(size>originalSize)
{
*dst++ = 0; // store zero token count
memcpy(dst,src,originalSize); // store original data
return originalSize+1;
}
// make sure data is in second buffer (dst2)
if(in!=dst2)
memcpy(dst2,dst,size);
// store tokens...
TUint8* originalDst = dst;
*dst++ = (TUint8)tokenCount;
if(tokenCount)
{
*dst++ = (TUint8)marker;
if(tokenCount<32)
{
memcpy(dst,tokens,tokenCount*3);
dst += tokenCount*3;
}
else
{
TUint8* bitMask = dst;
memset(bitMask,0,32);
dst += 32;
TUint8* d=tokens;
do
{
TInt t=*d++;
bitMask[t>>3] |= (1<<(t&7));
*dst++ = *d++;
*dst++ = *d++;
}
while(--tokenCount);
}
}
// store data...
memcpy(dst,dst2,size);
dst += size;
// get stats...
++GlobalTokenCounts[tokenCount];
// return total size of compressed data...
return dst-originalDst;
}
TInt Unpak(TUint8* dst, TInt dstSize, TUint8* src, TInt srcSize, TUint8*& srcNext)
{
TUint8* dstStart = dst;
TUint8* dstEnd = dst+dstSize;
TUint8* srcEnd = src+srcSize;
TUint32 LUT[0x100/2];
TUint8* LUT0 = (TUint8*)LUT;
TUint8* LUT1 = LUT0+0x100;
TUint8 stack[0x100];
TUint8* stackStart = stack+sizeof(stack);
TUint8* sp = stackStart;
TUint32 marker = ~0u;
TInt numTokens;
TUint32 p1;
TUint32 p2;
TUint32* l = (TUint32*)LUT;
TUint32 b = 0x03020100;
TUint32 step = 0x04040404;
do
{
*l++ = b;
b += step;
}
while(b>step);
if(src>=srcEnd)
goto error;
numTokens = *src++;
if(numTokens)
{
if(src>=srcEnd)
goto error;
marker = *src++;
LUT0[marker] = (TUint8)~marker;
if(numTokens<32)
{
TUint8* tokenEnd = src+3*numTokens;
if(tokenEnd>srcEnd)
goto error;
do
{
TInt b = *src++;
TInt p1 = *src++;
TInt p2 = *src++;
LUT0[b] = (TUint8)p1;
LUT1[b] = (TUint8)p2;
}
while(src<tokenEnd);
}
else
{
TUint8* bitMask = src;
src += 32;
if(src>srcEnd)
goto error;
TInt b=0;
do
{
TUint8 mask = bitMask[b>>3];
if(mask&(1<<(b&7)))
{
if(src>srcEnd)
goto error;
TInt p1 = *src++;
if(src>srcEnd)
goto error;
TInt p2 = *src++;
LUT0[b] = (TUint8)p1;
LUT1[b] = (TUint8)p2;
--numTokens;
}
++b;
}
while(b<0x100);
if(numTokens)
goto error;
}
}
if(src>=srcEnd)
goto error;
b = *src++;
if(dst>=dstEnd)
goto error;
p1 = LUT0[b];
if(p1!=b)
goto not_single;
next:
if(src>=srcEnd)
goto done_s;
b = *src++;
*dst++ = (TUint8)p1;
if(dst>=dstEnd)
goto done_d;
p1 = LUT0[b];
if(p1==b)
goto next;
not_single:
if(b==marker)
goto do_marker;
do_pair:
p2 = LUT1[b];
b = p1;
p1 = LUT0[b];
if(sp<=stack)
goto error;
*--sp = (TUint8)p2;
recurse:
if(b!=p1)
goto do_pair;
if(sp==stackStart)
goto next;
b = *sp++;
if(dst>=dstEnd)
goto error;
*dst++ = (TUint8)p1;
p1 = LUT0[b];
goto recurse;
do_marker:
if(src>=srcEnd)
goto error;
p1 = *src++;
goto next;
error:
srcNext = 0;
return KErrCorrupt;
done_s:
*dst++ = (TUint8)p1;
srcNext = src;
return dst-dstStart;
done_d:
if(dst>=dstEnd)
--src;
srcNext = src;
return dst-dstStart;
}
TUint8 PakBuffer[MaxBlockSize*4];
TUint8 UnpakBuffer[MaxBlockSize];
TInt BytePairCompress(TUint8* dst, TUint8* src, TInt size)
{
ASSERT(size<=MaxBlockSize);
TInt compressedSize = Pak(PakBuffer,src,size);
TUint8* pakEnd;
TInt us = Unpak(UnpakBuffer,MaxBlockSize,PakBuffer,compressedSize,pakEnd);
ASSERT(us==size)
ASSERT(pakEnd==PakBuffer+compressedSize)
ASSERT(!memcmp(src,UnpakBuffer,size))
if(compressedSize>=size)
return KErrTooBig;
memcpy(dst,PakBuffer,compressedSize);
return compressedSize;
}