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Modified source engine (2017) developed by valve and leaked in 2020. Not for commercial purporses
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source-engine/vpklib/packedstore.cpp

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//========= Copyright Valve Corporation, All rights reserved. ============//
//
// Purpose:
//
//===========================================================================//
#include "vpklib/packedstore.h"
#include "packedstore_internal.h"
#include "tier1/utlintrusivelist.h"
#include "tier1/generichash.h"
#include "tier1/checksum_crc.h"
#include "tier1/checksum_md5.h"
#include "tier1/utldict.h"
#include "tier2/fileutils.h"
#include "tier1/utlbuffer.h"
#ifdef VPK_ENABLE_SIGNING
#include "crypto.h"
#endif
#ifdef IS_WINDOWS_PC
#include <windows.h>
#endif
// memdbgon must be the last include file in a .cpp file!!!
#include "tier0/memdbgon.h"
typedef uint16 PackFileIndex_t;
#define PACKFILEINDEX_END 0xffff
CUtlBuffer, Color: misalign fixes
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const uint16 packedfileindex_end = 0xffff;
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#pragma pack(1)
struct CFilePartDescr
{
PackFileIndex_t m_nFileNumber;
uint32 m_nFileDataOffset;
uint32 m_nFileDataSize;
};
struct CFileHeaderFixedData
{
uint32 m_nFileCRC;
uint16 m_nMetaDataSize;
CFilePartDescr m_PartDescriptors[1]; // variable length
FORCEINLINE const void *MetaData( void ) const;
FORCEINLINE const CFilePartDescr *FileData( int nPart = 0 ) const;
uint32 TotalDataSize( void ) const
{
return m_nMetaDataSize + m_PartDescriptors[0].m_nFileDataSize;
}
size_t HeaderSizeIncludingMetaData( void ) const
{
size_t nRet = sizeof( *this ) - sizeof( m_PartDescriptors ) + m_nMetaDataSize;
// see how many parts we have and count the size of their descriptors
CFilePartDescr const *pPart = m_PartDescriptors;
while( pPart->m_nFileNumber != PACKFILEINDEX_END )
{
nRet += sizeof( CFilePartDescr );
pPart++;
}
nRet += sizeof( PackFileIndex_t ); // count terminator
return nRet;
}
};
#pragma pack()
#define PACKEDFILE_DIR_HASH_SIZE 43
static int s_FileHeaderSize( char const *pName, int nNumDataParts, int nNumMetaDataBytes )
{
return 1 + strlen( pName ) + // name plus nul
sizeof( uint32 ) + // file crc
sizeof( uint16 ) + // meta data size
nNumMetaDataBytes + // metadata
nNumDataParts * sizeof( CFilePartDescr ) + // part data
sizeof( PackFileIndex_t ); // part data 0xff end marker
}
class CFileDirectoryData
{
public:
CFileDirectoryData *m_pNext;
char const *m_Name;
};
// hash chain for accelerating file lookups. We can find an extension by hash, and find the
// directories containing files with this extension by another hash
class CFileExtensionData
{
public:
CFileExtensionData *m_pNext; // next one that has the same hash
char const *m_Name; // points at extension string within the directory data
// nodes for each directory containing a file of this type
CUtlIntrusiveList<CFileDirectoryData> m_pDirectoryHashTable[PACKEDFILE_DIR_HASH_SIZE];
~CFileExtensionData( void )
{
for( int i = 0; i < ARRAYSIZE( m_pDirectoryHashTable ); i++ )
{
m_pDirectoryHashTable[i].Purge();
}
}
};
static int SkipFile( char const * &pData ) // returns highest file index
{
int nHighestChunkIndex = -1;
pData += 1 + V_strlen( pData );
pData += sizeof( uint32 );
CUtlBuffer, Color: misalign fixes
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uint16 nMetaDataSize;
Q_memcpy( &nMetaDataSize, pData, sizeof( uint16 ) );
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pData += sizeof( uint16 );
CUtlBuffer, Color: misalign fixes
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while ( Q_memcmp( pData, &packedfileindex_end, sizeof( packedfileindex_end ) ) != 0 )
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{
int nIdx = reinterpret_cast<CFilePartDescr const *>(pData)->m_nFileNumber;
if ( nIdx != VPKFILENUMBER_EMBEDDED_IN_DIR_FILE )
nHighestChunkIndex = MAX( nHighestChunkIndex, nIdx );
pData += sizeof( CFilePartDescr );
}
pData += sizeof( PackFileIndex_t );
pData += nMetaDataSize;
return nHighestChunkIndex;
}
static inline int SkipAllFilesInDir( char const * & pData )
{
int nHighestChunkIndex = -1;
pData += 1 + strlen( pData ); // skip dir name
// now, march through all the files
while( *pData ) // until we're out of files to look at
{
int nSkipIndex = SkipFile( pData );
nHighestChunkIndex = MAX( nHighestChunkIndex, nSkipIndex );
}
pData++; // skip end marker
return nHighestChunkIndex;
}
CFileHeaderFixedData *CPackedStore::FindFileEntry( char const *pDirname, char const *pBaseName, char const *pExtension, uint8 **pExtBaseOut , uint8 **pNameBaseOut )
{
if ( pExtBaseOut )
*pExtBaseOut = NULL;
if ( pNameBaseOut )
*pNameBaseOut = NULL;
int nExtensionHash = HashString( pExtension ) % PACKEDFILE_EXT_HASH_SIZE;
CFileExtensionData const *pExt = m_pExtensionData[nExtensionHash].FindNamedNodeCaseSensitive( pExtension );
if ( pExt )
{
int nDirHash = HashString( pDirname ) % PACKEDFILE_DIR_HASH_SIZE;
CFileDirectoryData const *pDir = pExt->m_pDirectoryHashTable[nDirHash].FindNamedNodeCaseSensitive( pDirname );
if ( pDir )
{
if ( pExtBaseOut )
*pExtBaseOut = (uint8 *) pDir;
// we found the right directory. now, sequential search. data is heavily packed, so
// this is a little awkward. See fileformat.txt
char const *pData = pDir->m_Name;
pData += 1 + strlen( pData ); // skip dir name
// now, march through all the files
while( *pData ) // until we're out of files to look at
{
if ( !V_strcmp( pData, pBaseName ) ) // found it?
{
if ( pNameBaseOut )
*pNameBaseOut = (uint8 *) pData;
return ( CFileHeaderFixedData * )( pData + 1 + V_strlen( pData ) ); // return header
}
// this isn't it - skip over it
SkipFile( pData );
}
}
}
return NULL;
}
const void *CFileHeaderFixedData::MetaData( void ) const
{
if ( ! m_nMetaDataSize )
return NULL;
const CFilePartDescr *ret = &( m_PartDescriptors[0] );
while( ret->m_nFileNumber != PACKFILEINDEX_END )
ret++;
return reinterpret_cast<uint8 const *>( ret ) + sizeof( PackFileIndex_t );
}
CFilePartDescr const *CFileHeaderFixedData::FileData( int nPart ) const
{
return m_PartDescriptors + nPart;
}
void CPackedStore::Init( void )
{
m_nHighestChunkFileIndex = -1;
m_bUseDirFile = false;
m_pszFileBaseName[0] = 0;
m_pszFullPathName[0] = 0;
memset( m_pExtensionData, 0, sizeof( m_pExtensionData ) );
m_nDirectoryDataSize = 0;
m_nWriteChunkSize = k_nVPKDefaultChunkSize;
m_nSizeOfSignedData = 0;
m_Signature.Purge();
m_SignaturePrivateKey.Purge();
m_SignaturePublicKey.Purge();
}
void CPackedStore::BuildHashTables( void )
{
m_nHighestChunkFileIndex = -1;
for( int i = 0; i < ARRAYSIZE( m_pExtensionData ) ; i++ )
{
m_pExtensionData[i].Purge();
}
char const *pData = reinterpret_cast< char const *>( DirectoryData() );
while( *pData )
{
// for each extension
int nExtensionHash = HashString( pData ) % PACKEDFILE_EXT_HASH_SIZE;
CFileExtensionData *pNewExt = new CFileExtensionData;
pNewExt->m_Name = pData;
m_pExtensionData[nExtensionHash].AddToHead( pNewExt );
// now, iterate over all directories associated with this extension
pData += 1 + strlen( pData );
while( *pData )
{
int nDirHash = HashString( pData ) % PACKEDFILE_DIR_HASH_SIZE;
CFileDirectoryData *pNewDir = new CFileDirectoryData;
pNewDir->m_Name = pData;
pNewExt->m_pDirectoryHashTable[nDirHash].AddToHead( pNewDir );
int nDirChunk = SkipAllFilesInDir( pData );
m_nHighestChunkFileIndex = MAX( m_nHighestChunkFileIndex, nDirChunk );
}
// step past \0
pData++;
}
}
bool CPackedStore::IsEmpty( void ) const
{
return ( m_DirectoryData.Count() <= 1 );
}
static void StripTrailingString( char *pszBuf, const char *pszStrip )
{
int lBuf = V_strlen( pszBuf );
int lStrip = V_strlen( pszStrip );
if ( lBuf < lStrip )
return;
char *pExpectedPos = pszBuf + lBuf - lStrip;
if ( V_stricmp( pExpectedPos, pszStrip ) == 0 )
*pExpectedPos = '\0';
}
CPackedStore::CPackedStore( char const *pFileBasename, char *pszFName, IBaseFileSystem *pFS, bool bOpenForWrite ):m_PackedStoreReadCache( pFS )
{
Init();
m_pFileSystem = pFS;
m_PackedStoreReadCache.m_pPackedStore = this;
m_DirectoryData.AddToTail( 0 );
if ( pFileBasename )
{
V_strcpy( m_pszFileBaseName, pFileBasename );
StripTrailingString( m_pszFileBaseName, ".vpk" );
StripTrailingString( m_pszFileBaseName, "_dir" );
sprintf( pszFName, "%s_dir.vpk", m_pszFileBaseName );
#ifdef _WIN32
Q_strlower( pszFName );
#endif
CInputFile dirFile( pszFName );
// Try to load the VPK as a standalone (probably an addon) even if the standard _dir name is not present
if ( dirFile.IsOk() )
{
m_bUseDirFile = true;
}
else
{
m_bUseDirFile = false;
sprintf( pszFName, "%s.vpk", m_pszFileBaseName );
dirFile.Open( pszFName );
}
bool bNewFileFormat = false;
if ( dirFile.IsOk() )
{
// first, check if it is the new versioned variant
VPKDirHeader_t dirHeader;
// try to read the header.
if (
( dirFile.Read( &dirHeader, sizeof( dirHeader ) ) == sizeof( dirHeader ) ) &&
( dirHeader.m_nHeaderMarker == VPK_HEADER_MARKER ) )
{
if ( dirHeader.m_nVersion == VPK_PREVIOUS_VERSION )
{
// fill in the fields of the new header.
dirHeader.m_nEmbeddedChunkSize = dirFile.Size() - dirHeader.m_nDirectorySize - sizeof( VPKDirHeaderOld_t );
dirHeader.m_nChunkHashesSize = 0;
dirHeader.m_nSelfHashesSize = 0;
dirHeader.m_nSignatureSize = 0;
// pretend we didnt read the extra header
dirFile.Seek( sizeof( VPKDirHeaderOld_t ) );
}
else if ( dirHeader.m_nVersion != VPK_CURRENT_VERSION )
{
Error( "Unknown version %d for vpk %s", dirHeader.m_nVersion, pFileBasename );
}
bNewFileFormat = true;
}
else // its an old file
{
dirFile.Seek( 0 );
// fill in a fake header, zero out garbage we read
dirHeader.m_nDirectorySize = dirFile.Size();
dirHeader.m_nEmbeddedChunkSize = 0;
dirHeader.m_nChunkHashesSize = 0;
dirHeader.m_nSelfHashesSize = 0;
dirHeader.m_nSignatureSize = 0;
}
uint32 nSizeOfHeader = dirFile.Tell();
int nSize = dirHeader.m_nDirectorySize;
m_nDirectoryDataSize = dirHeader.m_nDirectorySize;
m_DirectoryData.SetCount( nSize );
dirFile.MustRead( DirectoryData(), nSize );
// now, if we are opening for write, read the entire contents of the embedded data chunk in the dir into ram
if ( bOpenForWrite && bNewFileFormat )
{
if ( dirHeader.m_nEmbeddedChunkSize )
{
CUtlVector<uint8> readBuffer;
int nRemainingSize = dirHeader.m_nEmbeddedChunkSize;
m_EmbeddedChunkData.EnsureCapacity( dirHeader.m_nEmbeddedChunkSize );
// We'll allocate around half a meg of contiguous memory for the read. Any more and the SDK's VPK
// utility has a higher chance of choking on low-end machines.
readBuffer.SetCount( 524288 );
while ( nRemainingSize > 0 )
{
int nReadSize = MIN( nRemainingSize , 524288 );
dirFile.MustRead( readBuffer.Base(), nReadSize );
for ( int i = 0; i < nReadSize; i++ )
{
m_EmbeddedChunkData.AddToTail( readBuffer[i] );
}
nRemainingSize -= nReadSize;
}
}
}
int cbVecHashes = dirHeader.m_nChunkHashesSize;
int ctHashes = cbVecHashes/sizeof(m_vecChunkHashFraction[0]);
m_vecChunkHashFraction.EnsureCount( ctHashes );
dirFile.MustRead( m_vecChunkHashFraction.Base(), cbVecHashes );
FOR_EACH_VEC( m_vecChunkHashFraction, i )
{
int idxFound = m_vecChunkHashFraction.Find( m_vecChunkHashFraction[i] );
Assert ( idxFound == i ); idxFound;
}
// now read the self hashes
V_memset( m_DirectoryMD5.bits, 0, sizeof(m_DirectoryMD5.bits) );
V_memset( m_ChunkHashesMD5.bits, 0, sizeof(m_ChunkHashesMD5.bits) );
V_memset( m_TotalFileMD5.bits, 0, sizeof(m_TotalFileMD5.bits) );
if ( dirHeader.m_nSelfHashesSize == 3*sizeof(m_DirectoryMD5.bits) )
{
// first is an MD5 of directory data
dirFile.MustRead( m_DirectoryMD5.bits, sizeof(m_DirectoryMD5.bits) );
// next is an MD5 of
dirFile.MustRead( m_ChunkHashesMD5.bits, sizeof(m_ChunkHashesMD5.bits) );
// at this point the filesystem has calculated an MD5 of everything in the file up to this point.
// we could ask it for a snapshot of that MD5 value and then be able to compare it to m_TotalFileMD5
// but we would have to do it *before* we read it
dirFile.MustRead( m_TotalFileMD5.bits, sizeof(m_TotalFileMD5.bits) );
}
// Is there a signature?
m_nSizeOfSignedData = 0;
if ( dirHeader.m_nSignatureSize != 0 )
{
// Everything immediately proceeding it should have been signed.
m_nSizeOfSignedData = dirFile.Tell();
uint32 nExpectedSignedSize = nSizeOfHeader + dirHeader.ComputeSizeofSignedDataAfterHeader();
if ( m_nSizeOfSignedData != nExpectedSignedSize )
{
Error( "Size mismatch determining size of signed data block (%d vs %d)", m_nSizeOfSignedData, nExpectedSignedSize );
}
// Read the public key
uint32 cubPublicKey = 0;
dirFile.MustRead( &cubPublicKey, sizeof(cubPublicKey) );
m_SignaturePublicKey.SetCount( cubPublicKey );
dirFile.MustRead( m_SignaturePublicKey.Base(), cubPublicKey );
// Read the private key
uint32 cubSignature = 0;
dirFile.MustRead( &cubSignature, sizeof(cubSignature) );
m_Signature.SetCount( cubSignature );
dirFile.MustRead( m_Signature.Base(), cubSignature );
}
}
Q_MakeAbsolutePath( m_pszFullPathName, sizeof( m_pszFullPathName ), m_pszFileBaseName );
V_strcat_safe( m_pszFullPathName, ".vpk" );
//Q_strlower( m_pszFullPathName ); // NO! this screws up linux.
Q_FixSlashes( m_pszFullPathName );
}
BuildHashTables();
}
void CPackedStore::GetDataFileName( char *pchFileNameOut, int cchFileNameOut, int nFileNumber ) const
{
if ( nFileNumber == VPKFILENUMBER_EMBEDDED_IN_DIR_FILE )
{
if ( m_bUseDirFile )
{
V_snprintf( pchFileNameOut, cchFileNameOut, "%s_dir.vpk", m_pszFileBaseName );
}
else
{
V_snprintf( pchFileNameOut, cchFileNameOut, "%s.vpk", m_pszFileBaseName );
}
}
else
{
V_snprintf( pchFileNameOut, cchFileNameOut, "%s_%03d.vpk", m_pszFileBaseName, nFileNumber );
}
}
CPackedStore::~CPackedStore( void )
{
for( int i = 0; i < ARRAYSIZE( m_pExtensionData ) ; i++ )
{
m_pExtensionData[i].Purge();
}
for (int i = 0; i < ARRAYSIZE( m_FileHandles ); i++ )
{
if ( m_FileHandles[i].m_nFileNumber != -1 )
{
#ifdef IS_WINDOWS_PC
CloseHandle( m_FileHandles[i].m_hFileHandle );
#else
m_pFileSystem->Close( m_FileHandles[i].m_hFileHandle );
#endif
}
}
// Free the FindFirst cache data
m_directoryList.PurgeAndDeleteElements();
FOR_EACH_MAP( m_dirContents, i )
{
m_dirContents[i]->PurgeAndDeleteElements();
delete m_dirContents[i];
}
}
void SplitFileComponents( char const *pFileName, char *pDirOut, char *pBaseOut, char *pExtOut )
{
char pTmpDirOut[MAX_PATH];
V_ExtractFilePath( pFileName, pTmpDirOut, MAX_PATH );
// now, pTmpDirOut to pDirOut, except when we find more then one '\' in a row, only output one
char *pOutDirPtr = pDirOut;
for( char *pDirInPtr = pTmpDirOut; *pDirInPtr; pDirInPtr++ )
{
char c = *( pDirInPtr );
*( pOutDirPtr++ ) = c;
// if we copied a \, skip all subsequent slashes
while( ( c == '\\' ) && ( pDirInPtr[1] == c ) )
{
pDirInPtr++;
}
}
*( pOutDirPtr ) = 0; // null terminate
if ( !pDirOut[0] )
strcpy( pDirOut, " " ); // blank dir name
V_strcpy( pBaseOut, V_UnqualifiedFileName( pFileName ) );
char *pDot = strrchr( pBaseOut, '.' );
if ( pDot )
{
*pDot = 0;
V_strncpy( pExtOut, pDot+1, MAX_PATH );
}
else
{
pExtOut[0]=' ';
pExtOut[1]=0;
}
V_FixSlashes( pDirOut, '/' );
V_strlower( pDirOut );
// the game sometimes asks for paths like dir1/../dir2/ we will replace this with dir2/. This
// one line of perl code sucks in c++.
for(;;)
{
char *pDotDot = V_strstr( pDirOut + 1, "/../" ); // start at second char. we don't want a beginning /
if (! pDotDot )
{
break;
}
// search backwards from the /.. for the previous directory part
char *pPrevSlash = pDotDot - 1;
while( ( pPrevSlash > pDirOut ) && ( pPrevSlash[0] != '/' ) )
{
pPrevSlash--;
}
// if our path was dir0/dir1/../dir2, we are now pointing at "/dir1".
// is strmove in all compilers? that would be better than this loop
char *pStrIn = pDotDot + 3;
for(;;)
{
*pPrevSlash = *pStrIn;
if ( pStrIn[0] )
{
++pPrevSlash;
++pStrIn;
}
else
{
break;
}
}
}
char *pLastDirChar = pDirOut + strlen( pDirOut ) - 1;
if ( ( pLastDirChar[0] == '/' ) || ( pLastDirChar[0] == '\\' ) )
*pLastDirChar = 0; // kill trailing slash
V_strlower( pBaseOut );
V_strlower( pExtOut );
}
CPackedStoreFileHandle CPackedStore::OpenFile( char const *pFileName )
{
char dirName[MAX_PATH];
char baseName[MAX_PATH];
char extName[MAX_PATH];
// Fix up the filename first
char tempFileName[MAX_PATH];
V_strncpy( tempFileName, pFileName, sizeof( tempFileName ) );
V_FixSlashes( tempFileName, CORRECT_PATH_SEPARATOR );
// V_RemoveDotSlashes( tempFileName, CORRECT_PATH_SEPARATOR, true );
V_FixDoubleSlashes( tempFileName );
if ( !V_IsAbsolutePath( tempFileName ) )
{
V_strlower( tempFileName );
}
SplitFileComponents( tempFileName, dirName, baseName, extName );
CPackedStoreFileHandle ret;
CFileHeaderFixedData *pHeader = FindFileEntry( dirName, baseName, extName, NULL, &( ret.m_pDirFileNamePtr ) );
if ( pHeader )
{
ret.m_nFileNumber = pHeader->m_PartDescriptors[0].m_nFileNumber;
ret.m_nFileOffset = pHeader->m_PartDescriptors[0].m_nFileDataOffset;
ret.m_nFileSize = pHeader->m_PartDescriptors[0].m_nFileDataSize + pHeader->m_nMetaDataSize;
ret.m_nCurrentFileOffset = 0;
ret.m_pMetaData = pHeader->MetaData();
ret.m_nMetaDataSize = pHeader->m_nMetaDataSize;
ret.m_pHeaderData = pHeader;
ret.m_pOwner = this;
}
else
{
ret.m_nFileNumber = -1;
ret.m_pOwner = NULL;
}
return ret;
}
CPackedStoreFileHandle CPackedStore::GetHandleForHashingFiles()
{
CPackedStoreFileHandle ret;
ret.m_nFileNumber = 0;
ret.m_nFileOffset = 0;
ret.m_nFileSize = 0;
ret.m_nMetaDataSize = 0;
ret.m_nCurrentFileOffset = 0;
ret.m_pDirFileNamePtr = NULL;
ret.m_pHeaderData = NULL;
ret.m_pMetaData = NULL;
ret.m_pOwner = this;
return ret;
}
void CPackedStore::Write( void )
{
// !KLUDGE!
// Write the whole header into a buffer in memory.
// We do this so we can easily sign it.
CUtlBuffer bufDirFile;
VPKDirHeader_t headerOut;
headerOut.m_nDirectorySize = m_DirectoryData.Count();
headerOut.m_nEmbeddedChunkSize = m_EmbeddedChunkData.Count();
headerOut.m_nChunkHashesSize = m_vecChunkHashFraction.Count()*sizeof(m_vecChunkHashFraction[0]);
headerOut.m_nSelfHashesSize = 3*sizeof(m_DirectoryMD5.bits);
headerOut.m_nSignatureSize = 0;
// Do we plan on signing this thing and writing a signature?
m_Signature.Purge();
if ( m_SignaturePrivateKey.Count() > 0 && m_SignaturePublicKey.Count() > 0 )
{
#ifdef VPK_ENABLE_SIGNING
Fix compilation under MSVC(VS2019)
3 years ago
uint32 nExpectedSignatureSize = k_cubRSASignature;
1
5 years ago
headerOut.m_nSignatureSize = sizeof(uint32) + m_SignaturePublicKey.Count() + sizeof(uint32) + nExpectedSignatureSize;
#else
Error( "VPK signing not implemented" );
#endif
}
bufDirFile.Put( &headerOut, sizeof( headerOut ) );
bufDirFile.Put( DirectoryData(), m_DirectoryData.Count() );
if ( m_EmbeddedChunkData.Count() )
{
int nRemainingSize = m_EmbeddedChunkData.Count();
CUtlVector<uint8> writeBuffer;
writeBuffer.SetCount( 524288 );
int nChunkOffset = 0;
while ( nRemainingSize > 0 )
{
// We'll write around half a meg of contiguous memory at once. Any more and the SDK's VPK
// utility has a higher chance of choking on low-end machines.
int nWriteSize = MIN( nRemainingSize, 524288 );
for ( int i = 0; i < nWriteSize; i++ )
{
writeBuffer[i] = m_EmbeddedChunkData[nChunkOffset++];
}
bufDirFile.Put( writeBuffer.Base(), nWriteSize );
nRemainingSize -= nWriteSize;
}
}
// write the chunk hashes out
bufDirFile.Put( m_vecChunkHashFraction.Base(), m_vecChunkHashFraction.Count()*sizeof(m_vecChunkHashFraction[0]) );
// write out the MD5s of the 2 main pieces of data
bufDirFile.Put( m_DirectoryMD5.bits, sizeof( m_DirectoryMD5.bits ) );
bufDirFile.Put( m_ChunkHashesMD5.bits, sizeof( m_ChunkHashesMD5.bits ) );
// compute the final MD5 ( of everything in the file up to this point )
MD5_ProcessSingleBuffer( bufDirFile.Base(), bufDirFile.TellPut(), m_TotalFileMD5 );
bufDirFile.Put( m_TotalFileMD5.bits, sizeof( m_TotalFileMD5.bits ) );
// Should we sign all this stuff?
m_nSizeOfSignedData = 0;
#ifdef VPK_ENABLE_SIGNING
if ( headerOut.m_nSignatureSize > 0 )
{
m_nSizeOfSignedData = bufDirFile.TellPut();
uint32 nExpectedSignedSize = sizeof(headerOut) + headerOut.ComputeSizeofSignedDataAfterHeader();
if ( m_nSizeOfSignedData != nExpectedSignedSize )
{
Error( "Size mismatch determining size of signed data block (%d vs %d)", m_nSizeOfSignedData, nExpectedSignedSize );
}
// Allocate more than enough space to hold the signature
m_Signature.SetCount( nExpectedSignatureSize + 1024 );
// Calcuate the signature
uint32 cubSignature = m_Signature.Count();
if ( !CCrypto::RSASignSHA256( (const uint8 *)bufDirFile.Base(), bufDirFile.TellPut(),
(uint8 *)m_Signature.Base(), &cubSignature,
(const uint8 *)m_SignaturePrivateKey.Base(), m_SignaturePrivateKey.Count() ) )
{
Error( "VPK signing failed. Private key may be corrupt or invalid" );
}
// Confirm that the size was what we expected
if ( cubSignature != nExpectedSignatureSize )
{
Error( "VPK signing produced %d byte signature. Expected size was %d bytes", cubSignature, nExpectedSignatureSize );
}
// Shrink signature to fit
m_Signature.SetCountNonDestructively( cubSignature );
// Now re-check the signature, using the public key that we are about
// to burn into the file, to make sure there's no mismatch.
if ( !CCrypto::RSAVerifySignatureSHA256( (const uint8 *)bufDirFile.Base(), bufDirFile.TellPut(),
(const uint8 *)m_Signature.Base(), cubSignature,
(const uint8 *)m_SignaturePublicKey.Base(), m_SignaturePublicKey.Count() ) )
{
Error( "VPK signature verification failed immediately after signing. The public key might be invalid, or might not match the private key used to generate the signature." );
}
// Write public key which should be used
uint32 cubPublicKey = m_SignaturePublicKey.Count();
bufDirFile.Put( &cubPublicKey, sizeof(cubPublicKey) );
bufDirFile.Put( m_SignaturePublicKey.Base(), cubPublicKey );
// Write signature
bufDirFile.Put( &cubSignature, sizeof(cubSignature) );
bufDirFile.Put( m_Signature.Base(), cubSignature );
}
#endif
char szOutFileName[MAX_PATH];
// Delete any existing header file, either the standalone kind,
// or the _dir kind.
V_sprintf_safe( szOutFileName, "%s.vpk", m_pszFileBaseName );
if ( g_pFullFileSystem->FileExists( szOutFileName ) )
g_pFullFileSystem->RemoveFile( szOutFileName );
V_sprintf_safe( szOutFileName, "%s_dir.vpk", m_pszFileBaseName );
if ( g_pFullFileSystem->FileExists( szOutFileName ) )
g_pFullFileSystem->RemoveFile( szOutFileName );
// Force on multi-chunk mode if we have any files in a chunk
if ( m_nHighestChunkFileIndex >= 0 )
m_bUseDirFile = true;
// Fetch actual name to write
GetDataFileName( szOutFileName, sizeof(szOutFileName), VPKFILENUMBER_EMBEDDED_IN_DIR_FILE );
// Now actually write the data to disk
COutputFile dirFile( szOutFileName );
dirFile.Write( bufDirFile.Base(), bufDirFile.TellPut() );
dirFile.Close();
}
#ifdef VPK_ENABLE_SIGNING
void CPackedStore::SetKeysForSigning( int nPrivateKeySize, const void *pPrivateKeyData, int nPublicKeySize, const void *pPublicKeyData )
{
m_SignaturePrivateKey.SetSize( nPrivateKeySize );
V_memcpy( m_SignaturePrivateKey.Base(), pPrivateKeyData, nPrivateKeySize );
m_SignaturePublicKey.SetSize( nPublicKeySize );
V_memcpy( m_SignaturePublicKey.Base(), pPublicKeyData, nPublicKeySize );
// Discard any existing signature
m_Signature.Purge();
}
CPackedStore::ESignatureCheckResult CPackedStore::CheckSignature( int nSignatureSize, const void *pSignature ) const
{
if ( m_Signature.Count() == 0 )
return eSignatureCheckResult_NotSigned;
Assert( m_nSizeOfSignedData > 0 );
// Confirm correct public key, if they specified one.
if ( nSignatureSize > 0 && pSignature != NULL )
{
if ( m_SignaturePublicKey.Count() != nSignatureSize || V_memcmp( pSignature, m_SignaturePublicKey.Base(), nSignatureSize ) != 0 )
{
return eSignatureCheckResult_WrongKey;
}
}
char szFilename[ MAX_PATH ];
GetDataFileName( szFilename, sizeof( szFilename ), VPKFILENUMBER_EMBEDDED_IN_DIR_FILE );
// Read the data
CUtlBuffer bufSignedData;
if ( !g_pFullFileSystem->ReadFile( szFilename, NULL, bufSignedData, m_nSizeOfSignedData ) )
return eSignatureCheckResult_Failed;
if ( bufSignedData.TellPut() < (int)m_nSizeOfSignedData )
{
Assert( false ); // ?
return eSignatureCheckResult_Failed;
}
// Check the signature
if ( !CCrypto::RSAVerifySignatureSHA256( (const uint8 *)bufSignedData.Base(), m_nSizeOfSignedData,
(const uint8 *)m_Signature.Base(), m_Signature.Count(),
(const uint8 *)m_SignaturePublicKey.Base(), m_SignaturePublicKey.Count() ) )
{
return eSignatureCheckResult_InvalidSignature;
}
return eSignatureCheckResult_ValidSignature;
}
#endif
CPackedStoreReadCache::CPackedStoreReadCache( IBaseFileSystem *pFS ):m_treeCachedVPKRead( CachedVPKRead_t::Less )
{
m_pPackedStore = NULL;
m_cItemsInCache = 0;
m_pFileSystem = pFS;
m_cubReadFromCache = 0;
m_cReadFromCache = 0;
m_cDiscardsFromCache = 0;
m_cAddedToCache = 0;
m_cCacheMiss = 0;
m_cubCacheMiss = 0;
m_cFileErrors = 0;
m_cFileErrorsCorrected = 0;
m_cFileResultsDifferent = 0;
m_pFileTracker = NULL;
}
// check if the read request can be satisfied from the read cache we have in 1MB chunks
bool CPackedStoreReadCache::BCanSatisfyFromReadCache( uint8 *pOutData, CPackedStoreFileHandle &handle, FileHandleTracker_t &fHandle, int nDesiredPos, int nNumBytes, int &nRead )
{
nRead = 0;
int nFileFraction = nDesiredPos & k_nCacheBufferMask;
int nOffset = nDesiredPos - nFileFraction;
int cubReadChunk = nOffset + nNumBytes;
if ( cubReadChunk > k_cubCacheBufferSize )
cubReadChunk = ( k_nCacheBufferMask - nOffset ) & (k_cubCacheBufferSize-1);
else
cubReadChunk = nNumBytes;
// the request might straddle multiple chunks - we make sure we have all of the data, if we are missing any, we fail
while ( nNumBytes )
{
int nReadChunk = 0;
if ( !BCanSatisfyFromReadCacheInternal( pOutData, handle, fHandle, nDesiredPos, cubReadChunk, nReadChunk ) )
{
return false;
}
nNumBytes -= cubReadChunk;
pOutData += cubReadChunk;
nDesiredPos += cubReadChunk;
nRead += nReadChunk;
nFileFraction += k_cubCacheBufferSize;
cubReadChunk = nNumBytes;
if ( cubReadChunk > k_cubCacheBufferSize )
cubReadChunk = k_cubCacheBufferSize;
}
return true;
}
// read a single line into the cache
bool CPackedStoreReadCache::ReadCacheLine( FileHandleTracker_t &fHandle, CachedVPKRead_t &cachedVPKRead )
{
cachedVPKRead.m_cubBuffer = 0;
#ifdef IS_WINDOWS_PC
if ( cachedVPKRead.m_nFileFraction != fHandle.m_nCurOfs )
SetFilePointer ( fHandle.m_hFileHandle, cachedVPKRead.m_nFileFraction, NULL, FILE_BEGIN);
ReadFile( fHandle.m_hFileHandle, cachedVPKRead.m_pubBuffer, k_cubCacheBufferSize, (LPDWORD) &cachedVPKRead.m_cubBuffer, NULL );
SetFilePointer ( fHandle.m_hFileHandle, fHandle.m_nCurOfs, NULL, FILE_BEGIN);
#else
m_pFileSystem->Seek( fHandle.m_hFileHandle, cachedVPKRead.m_nFileFraction, FILESYSTEM_SEEK_HEAD );
cachedVPKRead.m_cubBuffer = m_pFileSystem->Read( cachedVPKRead.m_pubBuffer, k_cubCacheBufferSize, fHandle.m_hFileHandle );
m_pFileSystem->Seek( fHandle.m_hFileHandle, fHandle.m_nCurOfs, FILESYSTEM_SEEK_HEAD );
#endif
Assert( cachedVPKRead.m_hMD5RequestHandle == 0 );
if ( m_pFileTracker ) // file tracker doesn't exist in the VPK command line tool
{
cachedVPKRead.m_hMD5RequestHandle = m_pFileTracker->SubmitThreadedMD5Request( cachedVPKRead.m_pubBuffer, cachedVPKRead.m_cubBuffer, m_pPackedStore->m_PackFileID, cachedVPKRead.m_nPackFileNumber, cachedVPKRead.m_nFileFraction );
}
return cachedVPKRead.m_cubBuffer > 0;
}
// check if the MD5 matches
bool CPackedStoreReadCache::CheckMd5Result( CachedVPKRead_t &cachedVPKRead )
{
ChunkHashFraction_t chunkHashFraction;
if ( !m_pPackedStore->FindFileHashFraction( cachedVPKRead.m_nPackFileNumber, cachedVPKRead.m_nFileFraction, chunkHashFraction ) )
return true;
if ( Q_memcmp( &cachedVPKRead.m_md5Value, &chunkHashFraction.m_md5contents, sizeof( MD5Value_t ) ) != 0 )
{
char szFilename[ 512 ];
m_pPackedStore->GetDataFileName( szFilename, sizeof(szFilename), cachedVPKRead.m_nPackFileNumber );
char szCalculated[ MD5_DIGEST_LENGTH*2 + 4 ];
char szExpected[ MD5_DIGEST_LENGTH*2 + 4 ];
V_binarytohex( cachedVPKRead.m_md5Value.bits, MD5_DIGEST_LENGTH, szCalculated, sizeof(szCalculated) );
V_binarytohex( chunkHashFraction.m_md5contents.bits, MD5_DIGEST_LENGTH, szExpected, sizeof(szExpected) );
Warning(
"Corruption detected in %s\n"
"\n"
"Try verifying the integrity of your game cache.\n"
"https://support.steampowered.com/kb_article.php?ref=2037-QEUH-3335"
"\n"
"Offset %d, expected %s, got %s\n",
szFilename,
cachedVPKRead.m_nFileFraction, szExpected, szCalculated
);
// we got an error reading this chunk, record the error
m_cFileErrors++;
cachedVPKRead.m_cFailedHashes++;
// give a copy to the fail whale
//m_queueCachedVPKReadsRetry.PushItem( cachedVPKRead );
return false;
}
if ( cachedVPKRead.m_cFailedHashes > 0 )
{
m_cFileErrorsCorrected++;
}
return true;
}
int CPackedStoreReadCache::FindBufferToUse()
{
int idxLRU = 0;
int idxToRemove = m_treeCachedVPKRead.InvalidIndex();
uint32 uTimeLowest = (uint32)~0; // MAXINT
// find the oldest item, reuse its buffer
for ( int i = 0; i < m_cItemsInCache; i++ )
{
if ( m_rgLastUsedTime[i] < uTimeLowest )
{
uTimeLowest = m_rgLastUsedTime[i];
idxToRemove = m_rgCurrentCacheIndex[i];
idxLRU = i;
}
int idxCurrent = m_rgCurrentCacheIndex[i];
// while we are here check if the MD5 is done
if ( m_treeCachedVPKRead[idxCurrent].m_hMD5RequestHandle )
{
CachedVPKRead_t &cachedVPKRead = m_treeCachedVPKRead[idxCurrent];
if ( m_pFileTracker->IsMD5RequestComplete( cachedVPKRead.m_hMD5RequestHandle, &cachedVPKRead.m_md5Value ) )
{
// if it is done, check the results
cachedVPKRead.m_hMD5RequestHandle = 0;
// if we got bad data - stop looking, just use this one
if ( !CheckMd5Result( cachedVPKRead ) )
return i;
}
}
}
// if we submitted its MD5 for processing, then wait until that is done
if ( m_treeCachedVPKRead[idxToRemove].m_hMD5RequestHandle )
{
CachedVPKRead_t &cachedVPKRead = m_treeCachedVPKRead[idxToRemove];
m_pFileTracker->BlockUntilMD5RequestComplete( cachedVPKRead.m_hMD5RequestHandle, &cachedVPKRead.m_md5Value );
m_treeCachedVPKRead[idxToRemove].m_hMD5RequestHandle = 0;
// make sure it matches what it is supposed to match
CheckMd5Result( cachedVPKRead );
}
return idxLRU;
}
// manage the cache
bool CPackedStoreReadCache::BCanSatisfyFromReadCacheInternal( uint8 *pOutData, CPackedStoreFileHandle &handle, FileHandleTracker_t &fHandle, int nDesiredPos, int nNumBytes, int &nRead )
{
m_rwlock.LockForRead();
bool bLockedForWrite = false;
CachedVPKRead_t key;
key.m_nPackFileNumber = handle.m_nFileNumber;
key.m_nFileFraction = nDesiredPos & k_nCacheBufferMask;
int idxTrackedVPKFile = m_treeCachedVPKRead.Find( key );
if ( idxTrackedVPKFile == m_treeCachedVPKRead.InvalidIndex() || m_treeCachedVPKRead[idxTrackedVPKFile].m_pubBuffer == NULL )
{
m_rwlock.UnlockRead();
m_rwlock.LockForWrite();
bLockedForWrite = true;
// if we didnt find it, we had to grab the write lock, it may have been added while we waited
idxTrackedVPKFile = m_treeCachedVPKRead.Find( key );
}
if ( idxTrackedVPKFile == m_treeCachedVPKRead.InvalidIndex() )
{
idxTrackedVPKFile = m_treeCachedVPKRead.Insert( key );
}
CachedVPKRead_t &cachedVPKRead = m_treeCachedVPKRead[idxTrackedVPKFile];
// Cache hit?
if ( cachedVPKRead.m_pubBuffer == NULL )
{
// We need to have it locked for write, because we're about to muck with these structures.
if ( !bLockedForWrite )
{
Assert( bLockedForWrite );
return false;
}
Assert( cachedVPKRead.m_idxLRU < 0 );
// Can we add another line to the cache, or should we reuse an existing one?
int idxLRU = -1;
if ( m_cItemsInCache >= k_nCacheBuffersToKeep )
{
// Need to kick out the LRU.
idxLRU = FindBufferToUse();
int idxToRemove = m_rgCurrentCacheIndex[idxLRU];
Assert( m_treeCachedVPKRead[idxToRemove].m_idxLRU == idxLRU );
Assert( m_treeCachedVPKRead[idxToRemove].m_pubBuffer != NULL );
// Transfer ownership of the buffer
cachedVPKRead.m_pubBuffer = m_treeCachedVPKRead[idxToRemove].m_pubBuffer;
m_treeCachedVPKRead[idxToRemove].m_pubBuffer = NULL;
m_treeCachedVPKRead[idxToRemove].m_cubBuffer = 0;
m_treeCachedVPKRead[idxToRemove].m_idxLRU = -1;
m_cDiscardsFromCache++;
}
else
{
// We can add a new one
idxLRU = m_cItemsInCache;
m_cItemsInCache++;
Assert( cachedVPKRead.m_pubBuffer == NULL );
}
m_rgCurrentCacheIndex[idxLRU] = idxTrackedVPKFile;
cachedVPKRead.m_idxLRU = idxLRU;
if ( cachedVPKRead.m_pubBuffer == NULL )
{
cachedVPKRead.m_pubBuffer = (uint8 *)malloc( k_cubCacheBufferSize );
if ( cachedVPKRead.m_pubBuffer == NULL )
Error( "Out of memory" );
}
ReadCacheLine( fHandle, cachedVPKRead );
m_cAddedToCache++;
}
else
{
Assert( cachedVPKRead.m_idxLRU >= 0 );
Assert( m_rgCurrentCacheIndex[cachedVPKRead.m_idxLRU] == idxTrackedVPKFile );
}
// Assume no bytes will be satisfied from cache
bool bSuccess = false;
nRead = 0;
// Can we read at least one byte?
Assert( cachedVPKRead.m_nFileFraction <= nDesiredPos );
int nBufferEnd = cachedVPKRead.m_cubBuffer + cachedVPKRead.m_nFileFraction;
if ( cachedVPKRead.m_pubBuffer != NULL && nBufferEnd > nDesiredPos )
{
nRead = Min( nBufferEnd - nDesiredPos, nNumBytes );
int nOffset = nDesiredPos - cachedVPKRead.m_nFileFraction;
Assert( nOffset >= 0 );
memcpy( pOutData, (uint8 *)&cachedVPKRead.m_pubBuffer[nOffset], nRead );
m_cubReadFromCache += nRead;
m_cReadFromCache ++;
bSuccess = true;
m_rgLastUsedTime[m_treeCachedVPKRead[idxTrackedVPKFile].m_idxLRU] = Plat_MSTime();
}
if ( bLockedForWrite )
m_rwlock.UnlockWrite();
else
m_rwlock.UnlockRead();
return bSuccess;
}
void CPackedStoreReadCache::RetryBadCacheLine( CachedVPKRead_t &cachedVPKRead )
{
ChunkHashFraction_t chunkHashFraction;
m_pPackedStore->FindFileHashFraction( cachedVPKRead.m_nPackFileNumber, cachedVPKRead.m_nFileFraction, chunkHashFraction );
cachedVPKRead.m_pubBuffer = (uint8 *)malloc( k_cubCacheBufferSize );
FileHandleTracker_t &fHandle = m_pPackedStore->GetFileHandle( cachedVPKRead.m_nPackFileNumber );
fHandle.m_Mutex.Lock();
ReadCacheLine( fHandle, cachedVPKRead );
fHandle.m_Mutex.Unlock();
m_pFileTracker->BlockUntilMD5RequestComplete( cachedVPKRead.m_hMD5RequestHandle, &cachedVPKRead.m_md5Value );
cachedVPKRead.m_hMD5RequestHandle = 0;
CheckMd5Result( cachedVPKRead );
cachedVPKRead.m_pubBuffer = NULL;
}
// try reloading anything that failed its md5 check
// this is currently only for gathering information, doesnt do anything to repair the cache
void CPackedStoreReadCache::RetryAllBadCacheLines()
{
// while( m_queueCachedVPKReadsRetry.Count() )
// {
// CachedVPKRead_t cachedVPKRead;
// m_rwlock.LockForWrite();
// if ( m_queueCachedVPKReadsRetry.PopItem( &cachedVPKRead ) )
// {
// // retry anything that didnt match one time
// RetryBadCacheLine( cachedVPKRead );
// m_listCachedVPKReadsFailed.AddToTail( cachedVPKRead );
// // m_listCachedVPKReadsFailed contains all the data about failed reads - for error or OGS reporting
// }
// m_rwlock.UnlockWrite();
// }
}
void CPackedStore::GetPackFileLoadErrorSummary( CUtlString &sErrors )
{
FOR_EACH_LL( m_PackedStoreReadCache.m_listCachedVPKReadsFailed, i )
{
char szDataFileName[MAX_PATH];
CPackedStoreFileHandle fhandle = GetHandleForHashingFiles();
fhandle.m_nFileNumber = m_PackedStoreReadCache.m_listCachedVPKReadsFailed[i].m_nPackFileNumber;
fhandle.GetPackFileName( szDataFileName, sizeof(szDataFileName) );
const char *pszFileName = V_GetFileName( szDataFileName );
CUtlString sTemp;
sTemp.Format( "Pack File %s at offset %x length %x errorcount = %d \n",
pszFileName,
m_PackedStoreReadCache.m_listCachedVPKReadsFailed[i].m_nFileFraction,
m_PackedStoreReadCache.m_listCachedVPKReadsFailed[i].m_cubBuffer,
m_PackedStoreReadCache.m_listCachedVPKReadsFailed[i].m_cFailedHashes );
sErrors += sTemp ;
char hex[sizeof(MD5Value_t)*2 + 1 ];
Q_binarytohex( m_PackedStoreReadCache.m_listCachedVPKReadsFailed[i].m_md5Value.bits,
sizeof(MD5Value_t), hex, sizeof( hex ) );
ChunkHashFraction_t chunkHashFraction;
FindFileHashFraction( m_PackedStoreReadCache.m_listCachedVPKReadsFailed[i].m_nPackFileNumber, m_PackedStoreReadCache.m_listCachedVPKReadsFailed[i].m_nFileFraction, chunkHashFraction );
char hex2[sizeof(MD5Value_t)*2 + 1 ];
Q_binarytohex( chunkHashFraction.m_md5contents.bits,
sizeof(MD5Value_t), hex2, sizeof( hex2 ) );
sTemp.Format( "Last Md5 Value %s Should be %s \n", hex, hex2 );
sErrors += sTemp ;
}
}
int CPackedStore::ReadData( CPackedStoreFileHandle &handle, void *pOutData, int nNumBytes )
{
int nRet = 0;
// clamp read size to file size
nNumBytes = MIN( nNumBytes, handle.m_nFileSize - handle.m_nCurrentFileOffset );
if ( nNumBytes > 0 )
{
// first satisfy from the metadata, if we can
int nNumMetaDataBytes = MIN( nNumBytes, handle.m_nMetaDataSize - handle.m_nCurrentFileOffset );
if ( nNumMetaDataBytes > 0 )
{
memcpy( pOutData, reinterpret_cast<uint8 const *>( handle.m_pMetaData )
+ handle.m_nCurrentFileOffset, nNumMetaDataBytes );
nRet += nNumMetaDataBytes;
pOutData = reinterpret_cast<uint8 *>( pOutData ) + nNumMetaDataBytes;
handle.m_nCurrentFileOffset += nNumMetaDataBytes;
nNumBytes -= nNumMetaDataBytes;
}
// satisfy remaining bytes from file
if ( nNumBytes > 0 )
{
FileHandleTracker_t &fHandle = GetFileHandle( handle.m_nFileNumber );
int nDesiredPos = handle.m_nFileOffset + handle.m_nCurrentFileOffset - handle.m_nMetaDataSize;
int nRead;
fHandle.m_Mutex.Lock();
if ( handle.m_nFileNumber == VPKFILENUMBER_EMBEDDED_IN_DIR_FILE )
{
// for file data in the directory header, all offsets are relative to the size of the dir header.
nDesiredPos += m_nDirectoryDataSize + sizeof( VPKDirHeader_t );
}
if ( m_PackedStoreReadCache.BCanSatisfyFromReadCache( (uint8 *)pOutData, handle, fHandle, nDesiredPos, nNumBytes, nRead ) )
{
handle.m_nCurrentFileOffset += nRead;
}
else
{
#ifdef IS_WINDOWS_PC
if ( nDesiredPos != fHandle.m_nCurOfs )
SetFilePointer ( fHandle.m_hFileHandle, nDesiredPos, NULL, FILE_BEGIN);
ReadFile( fHandle.m_hFileHandle, pOutData, nNumBytes, (LPDWORD) &nRead, NULL );
#else
m_pFileSystem->Seek( fHandle.m_hFileHandle, nDesiredPos, FILESYSTEM_SEEK_HEAD );
nRead = m_pFileSystem->Read( pOutData, nNumBytes, fHandle.m_hFileHandle );
#endif
handle.m_nCurrentFileOffset += nRead;
fHandle.m_nCurOfs = nRead + nDesiredPos;
}
Assert( nRead == nNumBytes );
nRet += nRead;
fHandle.m_Mutex.Unlock();
}
}
m_PackedStoreReadCache.RetryAllBadCacheLines();
return nRet;
}
bool CPackedStore::HashEntirePackFile( CPackedStoreFileHandle &handle, int64 &nFileSize, int nFileFraction, int nFractionSize, FileHash_t &fileHash )
{
#define CRC_CHUNK_SIZE (32*1024)
unsigned char tempBuf[CRC_CHUNK_SIZE];
#ifdef COMPUTE_HASH_TIMES
CFastTimer timer;
timer.Start();
#endif
FileHandleTracker_t &fHandle = GetFileHandle( handle.m_nFileNumber );
fHandle.m_Mutex.Lock();
#ifdef IS_WINDOWS_PC
unsigned int fileSizeHigh;
unsigned int fileLength = GetFileSize( fHandle.m_hFileHandle, (LPDWORD) &fileSizeHigh );
#else
unsigned int fileLength = m_pFileSystem->Size( fHandle.m_hFileHandle );
#endif
nFileSize = fileLength;
MD5Context_t ctx;
memset(&ctx, 0, sizeof(MD5Context_t));
MD5Init(&ctx);
int nDesiredPos = nFileFraction;
#ifdef IS_WINDOWS_PC
if ( nDesiredPos != fHandle.m_nCurOfs )
SetFilePointer ( fHandle.m_hFileHandle, nDesiredPos, NULL, FILE_BEGIN);
#else
m_pFileSystem->Seek( fHandle.m_hFileHandle, nDesiredPos, FILESYSTEM_SEEK_HEAD );
#endif
int nFractionLength = ( fileLength - nFileFraction );
if ( nFractionLength > nFractionSize )
nFractionLength = nFractionSize;
int nChunks = nFractionLength / CRC_CHUNK_SIZE + 1;
unsigned int curStartByte = 0;
for ( int iChunk=0; iChunk < nChunks; iChunk++ )
{
int curEndByte = MIN( curStartByte + CRC_CHUNK_SIZE, (uint)nFractionLength );
int chunkLen = curEndByte - curStartByte;
if ( chunkLen == 0 )
break;
int nRead;
#ifdef IS_WINDOWS_PC
ReadFile( fHandle.m_hFileHandle, tempBuf, chunkLen, (LPDWORD) &nRead, NULL );
#else
nRead = m_pFileSystem->Read( tempBuf, chunkLen, fHandle.m_hFileHandle );
#endif
MD5Update(&ctx, tempBuf, nRead);
curStartByte += CRC_CHUNK_SIZE;
}
MD5Final( fileHash.m_md5contents.bits, &ctx);
fileHash.m_crcIOSequence = nFractionLength;
fileHash.m_cbFileLen = nFractionLength;
fileHash.m_eFileHashType = FileHash_t::k_EFileHashTypeEntireFile;
fileHash.m_nPackFileNumber = handle.m_nFileNumber;
fileHash.m_PackFileID = handle.m_pOwner->m_PackFileID;
// seek back to where it was
#ifdef IS_WINDOWS_PC
SetFilePointer ( fHandle.m_hFileHandle, fHandle.m_nCurOfs, NULL, FILE_BEGIN);
#else
m_pFileSystem->Seek( fHandle.m_hFileHandle, fHandle.m_nCurOfs, FILESYSTEM_SEEK_HEAD );
#endif
fHandle.m_Mutex.Unlock();
#ifdef COMPUTE_HASH_TIMES
timer.End();
int nMicroSec = timer.GetDuration().GetMicroseconds();
char rgch[256];
Q_snprintf( rgch, 256, "MD5 Pack File %d %d \n", handle.m_nFileNumber, nMicroSec );
Plat_DebugString( rgch );
#endif
return true;
}
void CPackedStore::DiscardChunkHashes( int iChunkFileIndex )
{
// Wow, this could be a LOT faster because the list is
// sorted. Probably not worth optimizing
FOR_EACH_VEC_BACK( m_vecChunkHashFraction, i )
{
if ( m_vecChunkHashFraction[i].m_nPackFileNumber == iChunkFileIndex )
m_vecChunkHashFraction.Remove( i );
}
}
void CPackedStore::HashChunkFile( int iChunkFileIndex )
{
AUTO_LOCK( m_Mutex );
static const int k_nFileFractionSize = 0x00100000; // 1 MB
// Purge any hashes we already have for this chunk.
DiscardChunkHashes( iChunkFileIndex );
CPackedStoreFileHandle VPKHandle = GetHandleForHashingFiles();
VPKHandle.m_nFileNumber = iChunkFileIndex;
int nFileFraction = 0;
while ( 1 )
{
FileHash_t filehash;
// VPKHandle.m_nFileNumber;
// nFileFraction;
int64 fileSize = 0;
// if we have never hashed this before - do it now
HashEntirePackFile( VPKHandle, fileSize, nFileFraction, k_nFileFractionSize, filehash );
ChunkHashFraction_t fileHashFraction;
fileHashFraction.m_cbChunkLen = filehash.m_cbFileLen;
fileHashFraction.m_nPackFileNumber = VPKHandle.m_nFileNumber;
fileHashFraction.m_nFileFraction = nFileFraction;
Q_memcpy( fileHashFraction.m_md5contents.bits, filehash.m_md5contents.bits, sizeof(fileHashFraction.m_md5contents) );
m_vecChunkHashFraction.Insert( fileHashFraction );
// move to next section
nFileFraction += k_nFileFractionSize;
// if we are at EOF we are done
if ( nFileFraction > fileSize )
break;
}
}
void CPackedStore::HashAllChunkFiles()
{
// Rebuild the directory hash tables. The main reason to do this is
// so that the highest chunk number is correct, in case chunks have
// been removed.
BuildHashTables();
// make brand new hashes
m_vecChunkHashFraction.Purge();
for ( int iChunkFileIndex = 0 ; iChunkFileIndex <= GetHighestChunkFileIndex() ; ++iChunkFileIndex )
HashChunkFile( iChunkFileIndex );
}
void CPackedStore::ComputeDirectoryHash( MD5Value_t &md5Directory )
{
MD5Context_t ctx;
memset(&ctx, 0, sizeof(MD5Context_t));
MD5Init(&ctx);
MD5Update(&ctx, m_DirectoryData.Base(), m_DirectoryData.Count() );
MD5Final( md5Directory.bits, &ctx);
}
void CPackedStore::ComputeChunkHash( MD5Value_t &md5ChunkHashes )
{
MD5Context_t ctx;
memset(&ctx, 0, sizeof(MD5Context_t));
MD5Init(&ctx);
MD5Update(&ctx, (uint8 *)m_vecChunkHashFraction.Base(), m_vecChunkHashFraction.Count()*sizeof(m_vecChunkHashFraction[0]) );
MD5Final( md5ChunkHashes.bits, &ctx);
}
bool CPackedStore::BTestDirectoryHash()
{
if ( !BFileContainedHashes() )
return true;
MD5Value_t md5Directory;
ComputeDirectoryHash( md5Directory );
return Q_memcmp( m_DirectoryMD5.bits, md5Directory.bits, sizeof( md5Directory.bits ) ) == 0;
}
bool CPackedStore::BTestMasterChunkHash()
{
if ( !BFileContainedHashes() )
return true;
MD5Value_t md5ChunkHashes;
ComputeChunkHash( md5ChunkHashes );
return Q_memcmp( m_ChunkHashesMD5.bits, md5ChunkHashes.bits, sizeof( md5ChunkHashes.bits ) ) == 0;
}
void CPackedStore::HashEverything()
{
HashAllChunkFiles();
HashMetadata();
}
void CPackedStore::HashMetadata()
{
ComputeDirectoryHash( m_DirectoryMD5 );
ComputeChunkHash( m_ChunkHashesMD5 );
}
bool CPackedStore::FindFileHashFraction( int nPackFileNumber, int nFileFraction, ChunkHashFraction_t &fileHashFraction )
{
ChunkHashFraction_t fileHashFractionFind;
fileHashFractionFind.m_nFileFraction = nFileFraction;
fileHashFractionFind.m_nPackFileNumber = nPackFileNumber;
int idx = m_vecChunkHashFraction.Find( fileHashFractionFind );
if ( idx == m_vecChunkHashFraction.InvalidIndex() )
{
Assert( false );
return false;
}
fileHashFraction = m_vecChunkHashFraction[idx];
return true;
}
void CPackedStore::GetPackFileName( CPackedStoreFileHandle &handle, char *pchFileNameOut, int cchFileNameOut ) const
{
GetDataFileName( pchFileNameOut, cchFileNameOut, handle.m_nFileNumber );
}
FileHandleTracker_t & CPackedStore::GetFileHandle( int nFileNumber )
{
AUTO_LOCK( m_Mutex );
int nFileHandleIdx = nFileNumber % ARRAYSIZE( m_FileHandles );
if ( m_FileHandles[nFileHandleIdx].m_nFileNumber == nFileNumber )
{
return m_FileHandles[nFileHandleIdx];
}
else if ( m_FileHandles[nFileHandleIdx].m_nFileNumber == -1 )
{
// no luck finding the handle - need a new one
char pszDataFileName[MAX_PATH];
GetDataFileName( pszDataFileName, sizeof(pszDataFileName), nFileNumber );
m_FileHandles[nFileHandleIdx].m_nCurOfs = 0;
#ifdef IS_WINDOWS_PC
m_FileHandles[nFileHandleIdx].m_hFileHandle =
CreateFile( pszDataFileName, // file to open
GENERIC_READ, // open for reading
FILE_SHARE_READ, // share for reading
NULL, // default security
OPEN_EXISTING, // existing file only
FILE_ATTRIBUTE_NORMAL, // normal file
NULL); // no attr. template
if ( m_FileHandles[nFileHandleIdx].m_hFileHandle != INVALID_HANDLE_VALUE )
{
m_FileHandles[nFileHandleIdx].m_nFileNumber = nFileNumber;
}
#else
m_FileHandles[nFileHandleIdx].m_hFileHandle = m_pFileSystem->Open( pszDataFileName, "rb" );
if ( m_FileHandles[nFileHandleIdx].m_hFileHandle != FILESYSTEM_INVALID_HANDLE )
{
m_FileHandles[nFileHandleIdx].m_nFileNumber = nFileNumber;
}
#endif
return m_FileHandles[nFileHandleIdx];
}
Error( "Exceeded limit of number of vpk files supported (%d)!\n", MAX_ARCHIVE_FILES_TO_KEEP_OPEN_AT_ONCE );
static FileHandleTracker_t invalid;
#ifdef IS_WINDOWS_PC
invalid.m_hFileHandle = INVALID_HANDLE_VALUE;
#else
invalid.m_hFileHandle = FILESYSTEM_INVALID_HANDLE;
#endif
return invalid;
}
bool CPackedStore::RemoveFileFromDirectory( const char *pszName )
{
// Remove it without building hash tables
if ( !InternalRemoveFileFromDirectory( pszName ) )
return false;
// We removed it, we need to rebuild hash tables
BuildHashTables();
return true;
}
bool CPackedStore::InternalRemoveFileFromDirectory( const char *pszName )
{
CPackedStoreFileHandle pData = OpenFile( pszName );
if ( !pData )
return false;
CFileHeaderFixedData *pHeader = pData.m_pHeaderData;
// delete the old header so we can insert a new one with updated contents
int nBytesToRemove = ( int )( V_strlen( ( char * ) pData.m_pDirFileNamePtr ) + 1 + pHeader->HeaderSizeIncludingMetaData() );
m_DirectoryData.RemoveMultiple( pData.m_pDirFileNamePtr - m_DirectoryData.Base(), nBytesToRemove );
return true;
}
void CPackedStore::AddFileToDirectory( const VPKContentFileInfo_t &info )
{
// this method is fairly complicated because it has to do inserts into the packed directory
// data Our strategy is to build out the whole ext _ dir _ file record. if none of this is
// already present, we will just insert it in the head of the file. If the extension is
// present, we'll insert the dir+file part. If the extension + dir is present, we just insert
// the file part at the right place. If everything is present, we just need to return the
// current record
// First, remove it if it's already there,
// without rebuilding the hash tables
InternalRemoveFileFromDirectory( info.m_sName );
// let's build out a header
char pszExt[MAX_PATH];
char pszBase[MAX_PATH];
char pszDir[MAX_PATH];
SplitFileComponents( info.m_sName, pszDir, pszBase, pszExt );
int nNumDataParts = 1;
int nFileDataSize = s_FileHeaderSize( pszBase, nNumDataParts, info.m_iPreloadSize );
int nTotalHeaderSize = ( int )( nFileDataSize + ( 2 + strlen( pszExt ) ) + ( 2 + strlen( pszDir ) ) );
char *pBuf = ( char * ) stackalloc( nTotalHeaderSize );
char *pOut = pBuf;
strcpy( pOut, pszExt );
pOut += strlen( pszExt );
*( pOut++ ) = 0; // null on ext name
strcpy( pOut, pszDir );
pOut += strlen( pszDir );
*( pOut++ ) = 0; // null at end of dir name
strcpy( pOut, pszBase );
pOut += strlen( pszBase );
*( pOut++ ) = 0;
uint32 nCRC = info.m_crc;
memcpy( pOut, &nCRC, sizeof( nCRC ) );
pOut += sizeof( int );
if ( info.m_iPreloadSize > 0xffff )
Error( "Preload size for '%s' is too big", info.m_sName.String() );
uint16 nMetaDataSize = (uint16)info.m_iPreloadSize;
memcpy( pOut, &nMetaDataSize, sizeof( uint16 ) );
pOut += sizeof( uint16 );
// now, build file parts.
CFilePartDescr newPart;
newPart.m_nFileDataSize = info.GetSizeInChunkFile();
newPart.m_nFileNumber = ( info.m_idxChunk < 0 ) ? VPKFILENUMBER_EMBEDDED_IN_DIR_FILE : info.m_idxChunk;
newPart.m_nFileDataOffset = info.m_iOffsetInChunk;
memcpy( pOut, &newPart, sizeof( newPart ) );
pOut += sizeof( newPart );
PackFileIndex_t endOfPartMarker = PACKFILEINDEX_END;
memcpy( pOut, &endOfPartMarker, sizeof( endOfPartMarker ) );
pOut += sizeof( PackFileIndex_t );
if ( nMetaDataSize )
{
Assert( info.m_pPreloadData );
memcpy( pOut, info.m_pPreloadData, nMetaDataSize );
pOut += nMetaDataSize;
}
*( pOut++ ) = 0; // mark no more files in dir
*( pOut++ ) = 0; // mark no more dirs in extension
Assert( pOut - pBuf == nTotalHeaderSize );
// now, we need to insert our header, figuring out how many of the fields are already there
int nExtensionHash = HashString( pszExt ) % PACKEDFILE_EXT_HASH_SIZE;
int nInsertOffset = 0;
CFileExtensionData const *pExt = m_pExtensionData[nExtensionHash].FindNamedNodeCaseSensitive( pszExt );
char *pHeaderInsertPtr = pBuf;
if ( pExt )
{
// this is not a new extension. we should not insert the extension record
nTotalHeaderSize -= 2 + strlen( pszExt ); // null + end of dir list marker
pHeaderInsertPtr += 1 + strlen( pszExt ); // don't insert the name + null
// now, look for the directory
int nDirHash = HashString( pszDir ) % PACKEDFILE_DIR_HASH_SIZE;
CFileDirectoryData const *pDir = pExt->m_pDirectoryHashTable[nDirHash].FindNamedNodeCaseSensitive( pszDir );
if ( pDir )
{
// dir and extension found. all we need to do is insert the file data itself
nTotalHeaderSize -= 2 + strlen( pszDir ); // null + end of file list marker
pHeaderInsertPtr += 1 + strlen( pszDir );
char const *pStartOfDirFileData = pDir->m_Name + 1 + strlen( pDir->m_Name );
nInsertOffset = pStartOfDirFileData - ( char const * ) ( m_DirectoryData.Base() );
}
else
{
char const *pStartOfExtFileData = pExt->m_Name + 1 + strlen( pExt->m_Name );
nInsertOffset = pStartOfExtFileData - ( char const * ) ( m_DirectoryData.Base() );
}
}
m_DirectoryData.InsertMultipleBefore( nInsertOffset, nTotalHeaderSize );
memcpy( &m_DirectoryData[nInsertOffset], pHeaderInsertPtr, nTotalHeaderSize );
BuildHashTables();
}
ePackedStoreAddResultCode CPackedStore::AddFile( char const *pFile, uint16 nMetaDataSize, const void *pFileData, uint32 nFileTotalSize, bool bMultiChunk, uint32 const *pCrcValue )
{
// Calculate CRC if they didn't provide one
uint32 nCRC;
if ( pCrcValue )
{
nCRC = *pCrcValue;
}
else
{
nCRC = CRC32_ProcessSingleBuffer( pFileData, nFileTotalSize );
}
// Check if it is already here with the same contents
CPackedStoreFileHandle pData = OpenFile( pFile );
ePackedStoreAddResultCode nRslt = EPADD_NEWFILE;
if ( pData ) // already in pack
{
CFileHeaderFixedData *pHeader = pData.m_pHeaderData;
if ( ( nFileTotalSize == pHeader->TotalDataSize() ) && ( pHeader->m_nFileCRC == nCRC ) && ( nMetaDataSize == pHeader->m_nMetaDataSize ) ) // file unchanged?
{
return EPADD_ADDSAMEFILE;
}
nRslt = EPADD_UPDATEFILE;
}
// Build up the directory info into an interface structure
VPKContentFileInfo_t dirEntry;
dirEntry.m_sName = pFile;
dirEntry.m_iTotalSize = nFileTotalSize;
dirEntry.m_iPreloadSize = Min( (uint32)nMetaDataSize, (uint32)nFileTotalSize ) ;
dirEntry.m_pPreloadData = ( dirEntry.m_iPreloadSize > 0 ) ? pFileData : NULL;
dirEntry.m_crc = nCRC;
uint32 nBytesInChunk = dirEntry.GetSizeInChunkFile();
const unsigned char *pDataStart = (const unsigned char *)pFileData + dirEntry.m_iPreloadSize;
if ( bMultiChunk && nBytesInChunk > 0 )
{
// Check if we need to start a new chunk
char szDataFileName[MAX_PATH];
if ( m_nHighestChunkFileIndex < 0 )
{
dirEntry.m_idxChunk = 0;
dirEntry.m_iOffsetInChunk = 0;
}
else
{
dirEntry.m_idxChunk = m_nHighestChunkFileIndex;
// Append to most recent chunk
GetDataFileName( szDataFileName, sizeof(szDataFileName), m_nHighestChunkFileIndex );
dirEntry.m_iOffsetInChunk = g_pFullFileSystem->Size( szDataFileName );
if ( (int)dirEntry.m_iOffsetInChunk <= 0 ) // technical wrong, but we shouldn't have 2GB chunks. (Sort of defeats the whole purpose.)
{
// Note, there is one possible failure case. if we have a file whose data
// is actually all in the preload section, but it is marked as being
// in a chunk, then we might have a zero byte "chunk." We really should
// not be assigning any files to "chunks" if they are entirely in the preload
// area.
Error( "Error querying %s for file size\n", szDataFileName );
}
// Check if we need to start a new chunk
if ( (int)dirEntry.m_iOffsetInChunk >= m_nWriteChunkSize )
{
++dirEntry.m_idxChunk;
dirEntry.m_iOffsetInChunk = 0;
}
}
m_nHighestChunkFileIndex = MAX( m_nHighestChunkFileIndex, dirEntry.m_idxChunk );
// write the actual data
GetDataFileName( szDataFileName, sizeof(szDataFileName), dirEntry.m_idxChunk );
FileHandle_t fHandle = m_pFileSystem->Open( szDataFileName, "rb+" );
if ( !fHandle && dirEntry.m_iOffsetInChunk == 0 )
fHandle = m_pFileSystem->Open( szDataFileName, "wb" );
if ( !fHandle )
Error( "Cannot open %s for writing", szDataFileName );
m_pFileSystem->Seek( fHandle, dirEntry.m_iOffsetInChunk, FILESYSTEM_SEEK_HEAD );
m_pFileSystem->Write( pDataStart, nBytesInChunk, fHandle );
m_pFileSystem->Close( fHandle );
// Force on the use of the "dir" file
m_bUseDirFile = true;
}
else
{
// append to the dir data.
dirEntry.m_idxChunk = VPKFILENUMBER_EMBEDDED_IN_DIR_FILE;
dirEntry.m_iOffsetInChunk = m_EmbeddedChunkData.Count();
m_EmbeddedChunkData.AddMultipleToTail( nBytesInChunk, pDataStart );
}
// Update the directory
AddFileToDirectory( dirEntry );
return nRslt;
}
int CPackedStore::GetFileList( CUtlStringList &outFilenames, bool bFormattedOutput, bool bSortedOutput )
{
return GetFileList( NULL, outFilenames, bFormattedOutput, bSortedOutput );
}
int CPackedStore::GetFileList( const char *pWildCard, CUtlStringList &outFilenames, bool bFormattedOutput, bool bSortedOutput )
{
// Separate the wildcard base from the extension
char szWildCardPath[MAX_PATH];
char szWildCardBase[64];
char szWildCardExt[20];
bool bNoBaseWildcard = false;
bool bNoExtWildcard = false;
szWildCardPath[0] = szWildCardExt[0] = szWildCardBase[0] = NULL;
// Parse the wildcard string into a base and extension used for string comparisons
if ( pWildCard )
{
V_ExtractFilePath( pWildCard, szWildCardPath, sizeof( szWildCardPath ) );
V_FixSlashes( szWildCardPath, '/' );
V_FileBase( pWildCard, szWildCardBase, sizeof( szWildCardBase ) );
V_ExtractFileExtension( pWildCard, szWildCardExt, sizeof( szWildCardExt ) );
// Remove '*' from the base and extension strings so that the string comparison calls will match
char *pcStar = strchr( szWildCardBase, '*' );
pcStar ? *pcStar = NULL : bNoBaseWildcard = true;
pcStar = strchr( szWildCardExt, '*' );
pcStar ? *pcStar = NULL : bNoExtWildcard = true;
}
char const *pData = reinterpret_cast< char const *>( DirectoryData() );
while( *pData )
{
// for each extension
char pszCurExtension[MAX_PATH];
if ( pData[0] != ' ' )
sprintf( pszCurExtension, ".%s", pData );
else
pszCurExtension[0] = 0;
// now, iterate over all directories associated with this extension
pData += 1 + strlen( pData );
while( *pData )
{
char pszCurDir[MAX_PATH];
if ( pData[0] != ' ' )
sprintf( pszCurDir, "%s/", pData );
else
pszCurDir[0] = 0;
pData += 1 + strlen( pData ); // skip dir name
// now, march through all the files
while( *pData ) // until we're out of files to look at
{
char pszFNameOut[MAX_PATH*2];
if ( bFormattedOutput )
{
CFileHeaderFixedData const *pHeader = reinterpret_cast< CFileHeaderFixedData const *>( pData + 1 + strlen( pData ) );
sprintf( pszFNameOut, "%s%s%s crc=0x%x metadatasz=%d", pszCurDir, pData, pszCurExtension, pHeader->m_nFileCRC, pHeader->m_nMetaDataSize );
CFilePartDescr const *pPart = &( pHeader->m_PartDescriptors[0] );
while( pPart->m_nFileNumber != PACKFILEINDEX_END )
{
sprintf( pszFNameOut + strlen( pszFNameOut )," fnumber=%d ofs=0x%x sz=%d",
pPart->m_nFileNumber, pPart->m_nFileDataOffset, pPart->m_nFileDataSize );
pPart++;
}
}
else
{
V_strncpy( pszFNameOut, pszCurDir, sizeof( pszFNameOut ) );
V_strncat( pszFNameOut, pData, sizeof( pszFNameOut ) );
V_strncat( pszFNameOut, pszCurExtension, sizeof( pszFNameOut ) );
}
SkipFile( pData );
bool matches = true;
if ( pWildCard )
{
// See if the filename matches the wildcards
char szFNameOutPath[MAX_PATH];
char szFNameOutBase[64];
char szFNameOutExt[20];
V_ExtractFilePath( pszFNameOut, szFNameOutPath, sizeof( szFNameOutPath ) );
V_FileBase( pszFNameOut, szFNameOutBase, sizeof( szFNameOutBase ) );
V_ExtractFileExtension( pszFNameOut, szFNameOutExt, sizeof( szFNameOutExt ) );
matches = !V_strnicmp( szFNameOutPath, szWildCardPath, sizeof( szWildCardPath ) );
matches = matches && ( !V_strlen( szWildCardExt ) || bNoExtWildcard ? 0 == V_strnicmp( szFNameOutExt, szWildCardExt, strlen( szWildCardExt ) ) : 0 != V_stristr(szFNameOutExt, szWildCardExt ) );
matches = matches && ( !V_strlen( szWildCardBase ) || bNoBaseWildcard ? 0 == V_strnicmp( szFNameOutBase, szWildCardBase, strlen( szWildCardBase ) ) : 0 != V_stristr(szFNameOutBase, szWildCardBase ) );
}
// Add the file to the output list
if ( matches )
{
char *pFName = new char[1 + strlen( pszFNameOut ) ];
strcpy( pFName, pszFNameOut );
outFilenames.AddToTail( pFName );
}
}
pData++; // skip end marker
}
pData++; // skip end marker
}
if ( bSortedOutput )
{
outFilenames.Sort( &CUtlStringList::SortFunc );
}
return outFilenames.Count();
}
void CPackedStore::GetFileList( const char *pWildcard, CUtlVector<VPKContentFileInfo_t> &outVecResults )
{
// !KLUDGE! Get the filenames first, and then "find" them again.
CUtlStringList vecFilenames;
GetFileList( vecFilenames, false, false );
FOR_EACH_VEC( vecFilenames, i )
{
// Locate where it is in the existing file
CPackedStoreFileHandle h = OpenFile( vecFilenames[i] );
if ( !h )
Error( "File '%s' was returned by GetFileList, but OpenFile() fails?!", vecFilenames[i] );
// Convert to output structure
VPKContentFileInfo_t &f = outVecResults[ outVecResults.AddToTail() ];
f.m_sName = vecFilenames[i];
f.m_idxChunk = ( h.m_nFileNumber == VPKFILENUMBER_EMBEDDED_IN_DIR_FILE ) ? -1 : h.m_nFileNumber;
f.m_iTotalSize = h.m_nFileSize;
f.m_iOffsetInChunk = h.m_nFileOffset;
f.m_iPreloadSize = h.m_nMetaDataSize;
f.m_crc = h.m_pHeaderData->m_nFileCRC;
f.m_pPreloadData = h.m_pHeaderData->MetaData();
}
}
int CPackedStore::GetFileAndDirLists( CUtlStringList &outDirnames, CUtlStringList &outFilenames, bool bSortedOutput )
{
return GetFileAndDirLists( NULL, outDirnames, outFilenames, bSortedOutput );
}
void CPackedStore::BuildFindFirstCache()
{
CUtlStringList allVPKFiles;
char szLastDirFound[MAX_PATH];
// Init
V_strncpy( szLastDirFound, "$$$$$$$HighlyUnlikelyPathForInitializationPurposes#######", sizeof( szLastDirFound ) );
m_dirContents.SetLessFunc( DefLessFunc( int ) );
// Get all files in the VPK
GetFileList( allVPKFiles, false, true );
// Add directories to directory list and files into map
FOR_EACH_VEC( allVPKFiles, i )
{
char szFilePath[MAX_PATH];
V_ExtractFilePath( allVPKFiles[i], szFilePath, sizeof( szFilePath ) );
Q_StripTrailingSlash( szFilePath );
// New directory
if ( V_strnicmp( szFilePath, szLastDirFound, sizeof( szLastDirFound ) ) )
{
// Mark the new one as the last one encountered
V_strncpy( szLastDirFound, szFilePath, sizeof( szFilePath ) );
// Add it
m_directoryList.CopyAndAddToTail( szFilePath );
m_dirContents.Insert( m_directoryList.Count(), new CUtlStringList() ); // Freed in destructor
}
unsigned short nIndex = m_dirContents.Find( m_directoryList.Count() );
CUtlStringList *pList = m_dirContents.Element( nIndex );
pList->CopyAndAddToTail( V_UnqualifiedFileName( allVPKFiles[i] ) );
}
}
int CPackedStore::GetFileAndDirLists( const char *pWildCard, CUtlStringList &outDirnames, CUtlStringList &outFilenames, bool bSortedOutput )
{
// If this is the first time we've called FindFirst on this CPackedStore then let's build the caches
if ( !m_directoryList.Count() )
{
BuildFindFirstCache();
#ifdef NEVER
printf("CPackedStore::GetFileAndDirLists - list of directories in VPK files\n");
FOR_EACH_VEC( m_directoryList, i )
{
printf("\t%d : %s\n", i, m_directoryList[i] );
}
#endif // NEVER
}
// printf("CPackedStore::GetFileAndDirLists - Searching for %s\n", pWildCard? pWildCard: "NULL");
if ( pWildCard )
{
CUtlDict<int,int> AddedDirectories; // Used to remove duplicate paths
char szWildCardPath[MAX_PATH];
char szWildCardBase[64];
char szWildCardExt[20];
int nLenWildcardPath = 0;
int nLenWildcardBase = 0;
int nLenWildcardExt = 0;
bool bBaseWildcard = true;
bool bExtWildcard = true;
szWildCardPath[0] = szWildCardExt[0] = szWildCardBase[0] = '\0';
//
// Parse the wildcard string into a base and extension used for string comparisons
//
V_ExtractFilePath( pWildCard, szWildCardPath, sizeof( szWildCardPath ) );
V_FixSlashes( szWildCardPath, '/' );
V_FileBase( pWildCard, szWildCardBase, sizeof( szWildCardBase ) );
V_ExtractFileExtension( pWildCard, szWildCardExt, sizeof( szWildCardExt ) );
// From the pattern, we now have the directory path up to the file pattern, the filename base, and the filename
// extension.
// Remove '*' from the base and extension strings so that the string comparison calls will match
char *pcStar = strchr( szWildCardBase, '*' );
pcStar ? *pcStar = NULL : bBaseWildcard = false;
pcStar = strchr( szWildCardExt, '*' );
pcStar ? *pcStar = NULL : bExtWildcard = false;
nLenWildcardPath = V_strlen( szWildCardPath );
nLenWildcardBase = V_strlen( szWildCardBase );
nLenWildcardExt = V_strlen( szWildCardExt );
// Generate the list of directories and files that match the wildcard
//
//
// Directories first
//
FOR_EACH_VEC( m_directoryList, i )
{
// Does this file's path match the wildcard path?
if ( ( nLenWildcardPath && ( 0 == V_strnicmp( m_directoryList[i], szWildCardPath, nLenWildcardPath ) ) )
|| ( !nLenWildcardPath && ( 0 == V_strlen( m_directoryList[i] ) ) ) )
{
// Extract the sub-directory name if there is one
char szSubDir[64];
char *szSubDirExtension = NULL; // this is anything after a '.' in szSubDir
bool bBaseMatch = false;
bool bExtMatch = false;
// Copy everything to the right of the root directory
V_strncpy( szSubDir, &m_directoryList[i][nLenWildcardPath], sizeof( szSubDir ) );
// Set the next / to NULL and we have our subdirectory
char *pSlash = strchr( szSubDir, '/' );
pSlash ? *pSlash = NULL : NULL;
szSubDirExtension = strchr( szSubDir, '.' );
if ( szSubDirExtension )
{
// Null out the . and move the szSubDirExtension to point to the extension
*szSubDirExtension = '\0';
szSubDirExtension++;
}
// If we have a base dir name, and we have a szWildCardBase to match against
if ( bBaseWildcard )
bBaseMatch = true; // The base is the wildCard ("*"), so whatever we have as the base matches
else
bBaseMatch = ( 0 == V_strnicmp( szSubDir, szWildCardBase, nLenWildcardBase ) );
// If we have an extension and we have a szWildCardExtension to mach against
if ( bExtWildcard )
bExtMatch = true; // The extension is the wildcard ("*"), so whatever we have as the extension matches
else
bExtMatch = ( NULL == szSubDirExtension && '\0' == *szWildCardExt ) || (( NULL != szSubDirExtension ) && ( 0 == V_strnicmp( szSubDirExtension, szWildCardExt, nLenWildcardExt ) ));
// If both parts match, then add it to the list of directories that match
if ( bBaseMatch && bExtMatch )
{
char szFullPathToDir[ MAX_PATH ];
V_strncpy( szFullPathToDir, szWildCardPath, nLenWildcardPath );
V_strcat_safe( szFullPathToDir, "/" );
V_strcat_safe( szFullPathToDir, szSubDir );
// Add the subdirectory to the list if it isn't already there
if ( -1 == AddedDirectories.Find( szFullPathToDir ) )
{
char *pDName = new char[1 + strlen( szFullPathToDir )];
V_strncpy( pDName, szFullPathToDir, 1 + strlen( szFullPathToDir ) );
outDirnames.AddToTail( pDName );
AddedDirectories.Insert( pDName, 0 );
}
}
}
}
//
// Files
//
FOR_EACH_VEC( m_directoryList, i )
{
// We no longer want the trailing slash
Q_StripTrailingSlash( szWildCardPath );
// Find the directory that matches the wildcard path
if ( !V_strnicmp( szWildCardPath, m_directoryList[i], sizeof( szWildCardPath ) ) )
{
CUtlStringList &filesInDirectory = *(m_dirContents.Element( i ));
// Use the cached list of files in this directory
FOR_EACH_VEC( filesInDirectory, iFile )
{
bool matches = true;
// See if the filename matches the wildcards
char szFNameOutBase[64];
char szFNameOutExt[20];
V_FileBase( filesInDirectory[iFile], szFNameOutBase, sizeof( szFNameOutBase ) );
V_ExtractFileExtension( filesInDirectory[iFile], szFNameOutExt, sizeof( szFNameOutExt ) );
// Since we have a sorted list we can optimize using the return code of the compare
int c = V_strnicmp( szWildCardBase, szFNameOutBase, nLenWildcardBase );
if ( c < 0 )
break;
if ( c > 0 )
continue;
matches = ( (nLenWildcardExt <= 0) || bBaseWildcard ? 0 == V_strnicmp( szFNameOutExt, szWildCardExt, nLenWildcardExt ) : V_stristr( szFNameOutExt, szWildCardExt ) != NULL );
// Add the file to the output list
if ( matches )
{
bool bFound = false;
FOR_EACH_VEC( outFilenames, j )
{
if ( !V_strncmp( outFilenames[j], filesInDirectory[iFile], V_strlen( filesInDirectory[iFile] ) ) )
{
bFound = true;
break;
}
}
if ( !bFound )
{
outFilenames.CopyAndAddToTail( filesInDirectory[iFile] );
}
}
}
}
}
}
else // Otherwise, simply return the base data
{
// Add all the files as well
FOR_EACH_VEC( m_directoryList, i )
{
// Add all directories
outDirnames.CopyAndAddToTail( m_directoryList[i] );
// Now add all files
CUtlStringList &filesInDirectory = *(m_dirContents.Element( i ));
FOR_EACH_VEC( filesInDirectory, j )
{
outFilenames.CopyAndAddToTail( filesInDirectory[j] );
}
}
}
// Sort the output if requested
if ( bSortedOutput )
{
outDirnames.Sort( &CUtlStringList::SortFunc );
outFilenames.Sort( &CUtlStringList::SortFunc );
}
return outDirnames.Count();
}