fix: make sure host attribute is set rather than blank in logs on windows by using the env var 'COMPUTERNAME' instead of 'HOSTNAME'. Thus make it less difficult to order recipes in the log by time.
// 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;
}