// Copyright (c) 1998-2009 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:
// f32\sfile\sf_inflate.h
//
//
#include "sf_deflate.h"
#include "sf_ldr.h"
// Class RInflater
//
// The inflation algorithm, complete with huffman decoding
inline CInflater::CInflater(TBitInput& aInput)
:iBits(&aInput),iEncoding(0),iOut(0)
{}
void CInflater::ConstructL()
{
iEncoding=new(ELeave) TEncoding;
InitL();
iLen=0;
iOut=new(ELeave) TUint8[KDeflateMaxDistance];
iAvail=iLimit=iOut;
}
CInflater* CInflater::NewLC(TBitInput& aInput)
{
CInflater* self=new(ELeave) CInflater(aInput);
CleanupStack::PushL(self);
self->ConstructL();
return self;
}
CInflater::~CInflater()
{
delete iEncoding;
delete [] iOut;
}
TInt CInflater::ReadL(TUint8* aBuffer,TInt aLength, TMemoryMoveFunction aMemMovefn)
{
TInt tfr=0;
for (;;)
{
TInt len=Min(aLength,iLimit-iAvail);
if (len && aBuffer)
{
aMemMovefn(aBuffer,iAvail,len);
aBuffer+=len;
}
aLength-=len;
iAvail+=len;
tfr+=len;
if (aLength==0)
return tfr;
len=InflateL();
if (len==0)
return tfr;
iAvail=iOut;
iLimit=iAvail+len;
}
}
TInt CInflater::SkipL(TInt aLength)
{
return ReadL(0,aLength,Mem::Move);
}
void CInflater::InitL()
{
// read the encoding
Huffman::InternalizeL(*iBits,iEncoding->iLitLen,KDeflationCodes);
// validate the encoding
if (!Huffman::IsValid(iEncoding->iLitLen,TEncoding::ELitLens) ||
!Huffman::IsValid(iEncoding->iDistance,TEncoding::EDistances))
LEAVE_FAILURE(KErrCorrupt);
// convert the length tables into huffman decoding trees
Huffman::Decoding(iEncoding->iLitLen,TEncoding::ELitLens,iEncoding->iLitLen);
Huffman::Decoding(iEncoding->iDistance,TEncoding::EDistances,iEncoding->iDistance,KDeflateDistCodeBase);
}
TInt CInflater::InflateL()
//
// consume all data lag in the history buffer, then decode to fill up the output buffer
// return the number of available bytes in the output buffer. This is only ever less than
// the buffer size if the end of stream marker has been read
//
{
// empty the history buffer into the output
TUint8* out=iOut;
TUint8* const end=out+KDeflateMaxDistance;
const TUint32* tree=iEncoding->iLitLen;
if (iLen<0) // EOF
return 0;
if (iLen>0)
goto useHistory;
//
while (out<end)
{
// get a huffman code
{
TInt val=iBits->HuffmanL(tree)-TEncoding::ELiterals;
if (val<0)
{
*out++=TUint8(val);
continue; // another literal/length combo
}
if (val==TEncoding::EEos-TEncoding::ELiterals)
{ // eos marker. we're done
iLen=-1;
break;
}
// get the extra bits for the code
TInt code=val&0xff;
if (code>=8)
{ // xtra bits
TInt xtra=(code>>2)-1;
code-=xtra<<2;
code<<=xtra;
code|=iBits->ReadL(xtra);
}
if (val<KDeflateDistCodeBase-TEncoding::ELiterals)
{
// length code... get the code
if(TUint(code)>TUint(KDeflateMaxLength-KDeflateMinLength))
{
CHECK_FAILURE(KErrCorrupt);
goto error;
}
iLen=code+KDeflateMinLength;
tree=iEncoding->iDistance;
continue; // read the huffman code
}
// distance code
if(TUint(code)>TUint(KDeflateMaxDistance-1))
{
CHECK_FAILURE(KErrCorrupt);
goto error;
}
iRptr=out-(code+1);
if (iRptr+KDeflateMaxDistance<end)
iRptr+=KDeflateMaxDistance;
if(!iLen)
{
CHECK_FAILURE(KErrCorrupt);
goto error;
}
}
useHistory:
{
TInt tfr=Min(end-out,iLen);
iLen-=tfr;
const TUint8* from=iRptr;
do
{
*out++=*from++;
if (from==end)
from-=KDeflateMaxDistance;
} while (--tfr!=0);
iRptr=from;
tree=iEncoding->iLitLen;
}
};
return out-iOut;
error:
LEAVE_FAILURE(KErrCorrupt);
return 0;
}