Team Fortress 2 Source Code as on 22/4/2020
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//========= Copyright Valve Corporation, All rights reserved. ============//
//
// Purpose:
//
//=============================================================================
#include <stdio.h>
#include <stdlib.h>
#include <string.h>
#include <ctype.h>
#include <malloc.h>
#ifdef _WIN32
#include <process.h>
#include <io.h>
#endif
#include <stddef.h>
#include <fcntl.h>
#include <sys/types.h>
#include <sys/stat.h>
#include "tier1/utlbuffer.h"
#include "tier1/strtools.h"
#include "tier2/riff.h"
#if defined( _WIN32 ) && !defined( _X360 )
#include <windows.h>
#endif
#ifdef MAKE_GAMEDATA_TOOL
#include "../public/materialsystem/shader_vcs_version.h"
#include "../public/materialsystem/imaterial.h"
#include "../public/materialsystem/hardwareverts.h"
#include "../public/vtf/vtf.h"
#else
#include "materialsystem/shader_vcs_version.h"
#include "materialsystem/imaterial.h"
#include "materialsystem/hardwareverts.h"
#endif
#include "xwvfile.h"
#include "xzp.h"
CByteswap g_xzpSwap;
extern IFileReadBinary *g_pSndIO;
// memdbgon must be the last include file in a .cpp file!!!
#include "tier0/memdbgon.h"
//-----------------------------------------------------------------------------
// Datadesc blocks for byteswapping:
//-----------------------------------------------------------------------------
BEGIN_BYTESWAP_DATADESC( xZipHeader_t )
DEFINE_FIELD( Magic, FIELD_INTEGER ),
DEFINE_FIELD( Version, FIELD_INTEGER ),
DEFINE_FIELD( PreloadDirectoryEntries, FIELD_INTEGER ),
DEFINE_FIELD( DirectoryEntries, FIELD_INTEGER ),
DEFINE_FIELD( PreloadBytes, FIELD_INTEGER ),
DEFINE_FIELD( HeaderLength, FIELD_INTEGER ),
DEFINE_FIELD( FilenameEntries, FIELD_INTEGER ),
DEFINE_FIELD( FilenameStringsOffset, FIELD_INTEGER ),
DEFINE_FIELD( FilenameStringsLength, FIELD_INTEGER ),
END_BYTESWAP_DATADESC()
BEGIN_BYTESWAP_DATADESC( xZipDirectoryEntry_t )
DEFINE_FIELD( FilenameCRC, FIELD_INTEGER ),
DEFINE_FIELD( Length, FIELD_INTEGER ),
DEFINE_FIELD( StoredOffset, FIELD_INTEGER ),
END_BYTESWAP_DATADESC()
BEGIN_BYTESWAP_DATADESC( xZipFilenameEntry_t )
DEFINE_FIELD( FilenameCRC, FIELD_INTEGER ),
DEFINE_FIELD( FilenameOffset, FIELD_INTEGER ),
DEFINE_FIELD( TimeStamp, FIELD_INTEGER ),
END_BYTESWAP_DATADESC()
BEGIN_BYTESWAP_DATADESC( xZipFooter_t )
DEFINE_FIELD( Size, FIELD_INTEGER ),
DEFINE_FIELD( Magic, FIELD_INTEGER ),
END_BYTESWAP_DATADESC()
CXZip::CXZip()
{
// Ensure that the header doesn't contain a valid magic yet.
m_Header.Magic = 0;
m_pPreloadedData = NULL;
m_nPreloadStart = 0;
m_pDirectory = NULL;
m_pPreloadDirectory = NULL;
m_nRegular2PreloadEntryMapping = NULL;
m_bByteSwapped = false;
m_pFilenames = NULL;
m_hZip = NULL;
m_pRead = NULL;
m_hUser = 0;
m_nMonitorLevel = 0;
}
CXZip::CXZip( const char* filename )
{
// Ensure that the header doesn't contain a valid magic yet.
m_Header.Magic = 0;
m_nPreloadStart = 0;
m_pPreloadedData = NULL;
m_pDirectory = NULL;
m_pPreloadDirectory = NULL;
m_nRegular2PreloadEntryMapping = NULL;
m_bByteSwapped = false;
m_pFilenames = NULL;
m_hZip = NULL;
m_pRead = NULL;
m_hUser = 0;
m_nMonitorLevel = 0;
Load( filename );
}
CXZip::CXZip( FILE* handle, int offset, int size ) // file handle and offset of the zip file
{
m_pRead = NULL;
m_hUser = 0;
m_nPreloadStart = 0;
m_pDirectory = NULL;
m_pPreloadDirectory = NULL;
m_nRegular2PreloadEntryMapping = NULL;
m_bByteSwapped = false;
m_pFilenames = NULL;
m_pPreloadedData = NULL;
m_nMonitorLevel = 0;
Load( handle, offset, size );
}
CXZip::~CXZip()
{
Unload();
}
bool CXZip::InstallAlternateIO( int (*read)( void* buffer, int offset, int length, int nDestLength, int hUser), int hUser )
{
m_pRead = read;
m_hUser = hUser;
return true;
}
// Loads an xZip file into memory:
bool CXZip::Load( const char* filename, bool bPreload )
{
FILE* hZip = fopen( filename, "rb" );
fseek(hZip,0,SEEK_END);
int nSize = ftell( hZip );
return Load( hZip, 0, nSize, bPreload );
}
bool CXZip::Load( FILE* handle, int nOffset, int nSize, bool bPreload ) // Load a pack file into this instance. Returns true on success.
{
Unload();
m_bByteSwapped = false;
m_hZip = handle;
m_nOffset = nOffset;
m_nSize = nSize;
// Hacky, clean up:
if( m_hZip && !m_pRead )
{
InstallAlternateIO( defaultRead, (int)m_hZip );
}
if( m_hZip == NULL && m_pRead == NULL )
{
return false;
}
// Read the header:
m_pRead( &m_Header, 0, -1, sizeof(m_Header), m_hUser );
// Validate the Magic number and at the same time determine if I am reading a regular or swappped xZip file:
switch( m_Swap.SourceIsNativeEndian<int>( m_Header.Magic, xZipHeader_t::MAGIC ) )
{
// Does the magic match exactly?
case 1:
m_Swap.ActivateByteSwapping( false );
m_bByteSwapped = false;
break;
// Does the magic match, but is swapped?
case 0:
m_bByteSwapped = true;
m_Swap.ActivateByteSwapping( true ); // We must be reading the opposite endianness.
m_Swap.SwapFieldsToTargetEndian<xZipHeader_t>( &m_Header );
break;
default:
assert( 0 );
// Fail gently in release:
// The magic doesn't match in any respect:
case -1:
{
printf("Invalid xZip file\n");
if( m_hZip )
{
fclose( m_hZip );
m_hZip = NULL;
}
return false;
}
}
// Validate the archive version:
if( m_Header.Version != xZipHeader_t::VERSION )
{
// Backward compatable support for version 1
Msg("Incorrect xZip version found %u - expected %u\n", m_Header.Version, xZipHeader_t::VERSION );
if( m_hZip )
{
fclose( m_hZip );
m_hZip = NULL;
}
m_Header.Magic = xZipHeader_t::FREE;
return false;
}
// Read the directory:
{
MEM_ALLOC_CREDIT();
m_pDirectory = (xZipDirectoryEntry_t*)malloc( sizeof(xZipDirectoryEntry_t) * m_Header.DirectoryEntries );
m_pRead( m_pDirectory, m_Header.HeaderLength, -1, sizeof( xZipDirectoryEntry_t ) * m_Header.DirectoryEntries, m_hUser );
// Swap the directory entries if nessecary
if( m_bByteSwapped )
{
for( unsigned nDirectoryEntry = 0; nDirectoryEntry < m_Header.DirectoryEntries; nDirectoryEntry++ )
{
m_Swap.SwapFieldsToTargetEndian<xZipDirectoryEntry_t>( &( m_pDirectory[nDirectoryEntry] ) );
}
}
m_nPreloadStart = m_Header.HeaderLength + ( sizeof( xZipDirectoryEntry_t ) * m_Header.DirectoryEntries );
}
// Preload the preload chunk if desired:
if( bPreload )
{
PreloadData();
}
return true;
}
void CXZip::Unload()
{
DiscardPreloadedData();
// Dump the directory:
if( m_pDirectory )
{
free( m_pDirectory );
m_pDirectory = NULL;
}
if( m_pFilenames )
{
free( m_pFilenames );
m_pFilenames = NULL;
}
// Invalidate the header:
m_Header.Magic = 0;
if( m_hZip )
{
fclose( m_hZip );
m_hZip = NULL;
}
}
//-----------------------------------------------------------------------------
// CXZip::PreloadData
//
// Loads the preloaded data if it isn't already.
//-----------------------------------------------------------------------------
void CXZip::PreloadData()
{
Assert( IsValid() );
// Ensure it isn't already preloaded
if( m_pPreloadedData )
return;
// If I don't have a preloaded section, ignore the request.
if( !m_Header.PreloadBytes || !m_Header.PreloadDirectoryEntries )
return;
// Allocate and read the data block in:
#ifndef _X360
MEM_ALLOC_CREDIT_( "xZip" );
m_pPreloadedData = malloc( m_Header.PreloadBytes );
// Just drop out if allocation fails;
if ( !m_pPreloadedData )
return;
m_pRead( m_pPreloadedData, m_nPreloadStart, -1, m_Header.PreloadBytes, m_hUser );
#else
int nAlignedStart = AlignValue( ( m_nPreloadStart - XBOX_HDD_SECTORSIZE ) + 1, XBOX_HDD_SECTORSIZE );
int nBytesToRead = AlignValue( ( m_nPreloadStart - nAlignedStart ) + m_Header.PreloadBytes, XBOX_HDD_SECTORSIZE );
int nBytesBuffer = AlignValue( nBytesToRead, XBOX_HDD_SECTORSIZE );
byte *pReadData = (byte *)malloc( nBytesBuffer );
// Just drop out if allocation fails;
if ( !pReadData )
return;
MEM_ALLOC_CREDIT_( "xZip" );
m_pRead( pReadData, nAlignedStart, nBytesBuffer,nBytesToRead, m_hUser );
m_pPreloadedData = pReadData + ( m_nPreloadStart - nAlignedStart );
#endif
// Set up the preload directory:
m_pPreloadDirectory = (xZipDirectoryEntry_t*)m_pPreloadedData;
// Swap the preload directory:
if ( m_bByteSwapped )
{
for ( unsigned nDirectoryEntry = 0; nDirectoryEntry < m_Header.PreloadDirectoryEntries; nDirectoryEntry++ )
{
m_Swap.SwapFieldsToTargetEndian<xZipDirectoryEntry_t>( &( m_pPreloadDirectory[nDirectoryEntry] ) );
}
}
// Set up the regular 2 preload mapping section:
m_nRegular2PreloadEntryMapping = (unsigned short*)(((unsigned char*)m_pPreloadDirectory) + ( sizeof(xZipDirectoryEntry_t) * m_Header.PreloadDirectoryEntries ));
// Swap the regular to preload mapping
if ( m_bByteSwapped )
{
m_Swap.SwapBufferToTargetEndian<short>( (short *)m_nRegular2PreloadEntryMapping, (short *)m_nRegular2PreloadEntryMapping, m_Header.DirectoryEntries );
}
}
//-----------------------------------------------------------------------------
// CXZip::DiscardPreloadedData
//
// frees the preloaded data cache if it's present.
//-----------------------------------------------------------------------------
void CXZip::DiscardPreloadedData()
{
if ( m_pPreloadedData )
{
#ifndef _X360
free( m_pPreloadedData );
#else
int nAlignedStart = AlignValue( ( m_nPreloadStart - XBOX_HDD_SECTORSIZE ) + 1, XBOX_HDD_SECTORSIZE );
byte *pReadData = (byte *)m_pPreloadedData - ( m_nPreloadStart - nAlignedStart );
free( pReadData );
#endif
m_pPreloadedData = NULL;
m_pPreloadDirectory = NULL;
m_nRegular2PreloadEntryMapping = NULL;
}
}
int CXZip::defaultRead( void* buffer, int offset, int destLength, int length, int hUser)
{
fseek( (FILE*)hUser, offset, SEEK_SET );
return fread( buffer, 1, length, (FILE*)hUser );
}
char* CXZip::GetEntryFileName( unsigned CRC, char* pDefault )
{
Assert( IsValid() );
if( IsRetail() )
{
return pDefault;
}
else
{
// Make sure I have a filename section:
if( m_Header.FilenameStringsOffset == 0 || m_Header.FilenameEntries == 0 || CRC == 0 )
{
return pDefault;
}
// If the filename chunk isn't here, load it up:
if( !m_pFilenames )
{
MEM_ALLOC_CREDIT_("xZip");
m_pFilenames = (xZipFilenameEntry_t*)malloc( m_Header.FilenameStringsLength );
m_pRead( m_pFilenames, m_Header.FilenameStringsOffset, -1, m_Header.FilenameStringsLength, m_hUser );
// TODO: Swap!
for( unsigned int i=0; i< m_Header.FilenameEntries;i++ )
{
m_Swap.SwapFieldsToTargetEndian<xZipFilenameEntry_t>(&m_pFilenames[i]);
}
}
// Find this entry in the preload directory
xZipFilenameEntry_t entry;
entry.FilenameCRC = CRC;
xZipFilenameEntry_t* found = (xZipFilenameEntry_t*)bsearch( &entry, m_pFilenames, m_Header.FilenameEntries, sizeof(xZipFilenameEntry_t), xZipFilenameEntry_t::xZipFilenameEntryCompare );
if( !found )
return pDefault;
return (((char*)m_pFilenames) + found->FilenameOffset) - m_Header.FilenameStringsOffset;
}
}
// Sanity checks that the zip file is ready and readable:
bool CXZip::IsValid()
{
if( m_Header.Magic != xZipHeader_t::MAGIC )
return false;
if( m_Header.Version > xZipHeader_t::VERSION )
return false;
if( !m_pDirectory )
return false;
return true;
}
void CXZip::WarningDir()
{
Assert( IsValid());
for( unsigned i = 0; i< m_Header.DirectoryEntries; i++ )
{
Msg( GetEntryFileName( m_pDirectory[i].FilenameCRC ) );
}
}
int CXZip::ReadIndex( int nEntryIndex, int nFileOffset, int nDestBytes, int nLength, void* pBuffer )
{
Assert( IsValid() );
if( nLength <=0 || nEntryIndex < 0 )
return 0;
// HACK HACK HACK - convert the pack file index to a local file index (ie, assuming the full file index is being passed in)
nFileOffset -= m_pDirectory[nEntryIndex].StoredOffset;
// HACK HACK HACK
// If I've got my preload section loaded, first check there:
xZipDirectoryEntry_t* pPreloadEntry = GetPreloadEntry(nEntryIndex);
if( pPreloadEntry )
{
Assert( pPreloadEntry->FilenameCRC == m_pDirectory[nEntryIndex].FilenameCRC );
if( nFileOffset + nLength <= (int)pPreloadEntry->Length )
{
if( m_nMonitorLevel >= 2 )
{
char* filename = GetEntryFileName( m_pDirectory[nEntryIndex].FilenameCRC, "(!!! unknown !!!)" );
Msg("PACK(preload) %s: length:%i offset:%i",filename,nLength, nFileOffset);
}
memcpy( pBuffer, (char*)m_pPreloadedData + pPreloadEntry->StoredOffset + nFileOffset - m_nPreloadStart, nLength );
return nLength;
}
}
// Offset int the zip to start the read:
int ZipOffset = m_pDirectory[nEntryIndex].StoredOffset + nFileOffset;
int nBytesRead = m_pRead( pBuffer, ZipOffset, nDestBytes, nLength, m_hUser);
if( m_nMonitorLevel )
{
char* filename = GetEntryFileName( m_pDirectory[nEntryIndex].FilenameCRC, "(!!! unknown !!!)" );
unsigned preload = 0;
if( m_pPreloadedData && m_nRegular2PreloadEntryMapping[nEntryIndex] != 0xFFFF )
{
// Find this entry in the preload directory
xZipDirectoryEntry_t* entry = &(m_pPreloadDirectory[m_nRegular2PreloadEntryMapping[nEntryIndex]]);
Assert(entry->FilenameCRC == m_pDirectory[nEntryIndex].FilenameCRC);
preload = entry->Length;
}
Msg("PACK %s: length:%i offset:%i (preload bytes:%i)",filename,nLength, nFileOffset, preload);
}
return nBytesRead;
}
bool CXZip::GetSimpleFileOffsetLength( const char* FileName, int& nBaseIndex, int &nFileOffset, int &nLength )
{
Assert( IsValid() );
xZipDirectoryEntry_t entry;
entry.FilenameCRC = xZipCRCFilename( FileName );
xZipDirectoryEntry_t* found = (xZipDirectoryEntry_t*)bsearch( &entry, m_pDirectory, m_Header.DirectoryEntries, sizeof(xZipDirectoryEntry_t), xZipDirectoryEntry_t::xZipDirectoryEntryFindCompare );
if( found == NULL )
return false;
nFileOffset = found[0].StoredOffset;
nLength = found[0].Length;
nBaseIndex = (((int)((char*)found - (char*)m_pDirectory))/sizeof(xZipDirectoryEntry_t));
return true;
}
bool CXZip::ExtractFile( const char* FileName )
{
return false;
}
// Compares to xZipDirectoryEntries.
//
// Sorts in the following order:
// FilenameCRC
// FileOffset
// Length
// StoredOffset
//
// The sort function may look overly complex, but it is actually useful for locating different pieces of
// the same file in a meaningful order.
//
int __cdecl xZipDirectoryEntry_t::xZipDirectoryEntrySortCompare( const void* left, const void* right )
{
xZipDirectoryEntry_t *l = (xZipDirectoryEntry_t*)left,
*r = (xZipDirectoryEntry_t*)right;
if( l->FilenameCRC < r->FilenameCRC )
{
return -1;
}
else if( l->FilenameCRC > r->FilenameCRC )
{
return 1;
}
// else l->FileOffset == r->FileOffset
if( l->Length < r->Length )
{
return -1;
}
else if( l->Length > r->Length )
{
return 1;
}
// else l->Length == r->Length
if( l->StoredOffset < r->StoredOffset )
{
return -1;
}
else if( l->StoredOffset > r->StoredOffset )
{
return 1;
}
// else everything is identical:
return 0;
}
// Find an entry with matching CRC only
int __cdecl xZipDirectoryEntry_t::xZipDirectoryEntryFindCompare( const void* left, const void* right )
{
xZipDirectoryEntry_t *l = (xZipDirectoryEntry_t*)left,
*r = (xZipDirectoryEntry_t*)right;
if( l->FilenameCRC < r->FilenameCRC )
{
return -1;
}
else if( l->FilenameCRC > r->FilenameCRC )
{
return 1;
}
return 0;
}
int __cdecl xZipFilenameEntry_t::xZipFilenameEntryCompare( const void* left, const void* right )
{
xZipFilenameEntry_t *l = (xZipFilenameEntry_t*)left,
*r = (xZipFilenameEntry_t*)right;
if( l->FilenameCRC < r->FilenameCRC )
{
return -1;
}
else if( l->FilenameCRC > r->FilenameCRC )
{
return 1;
}
return 0;
}
// CRC's an individual xZip filename:
unsigned xZipCRCFilename( const char* filename )
{
unsigned hash = 0xAAAAAAAA; // Alternating 1's and 0's
for( ; *filename ; filename++ )
{
char c = *filename;
// Fix slashes
if( c == '/' )
c = '\\';
else
c = (char)tolower(c);
hash = hash * 33 + c;
}
return hash;
}
#if defined( MAKE_GAMEDATA_TOOL )
// ------------
xZipHeader_t Header;
xZipDirectoryEntry_t *pDirectoryEntries = NULL;
xZipDirectoryEntry_t *pPreloadDirectoryEntries = NULL;
xZipFilenameEntry_t *pFilenameEntries = NULL;
char *pFilenameData = NULL;
unsigned nFilenameDataLength = 0;
unsigned InputFileBytes = 0;
char* CleanFilename( char* filename )
{
// Trim leading white space:
while( isspace(*filename) )
filename++;
// Trim trailing white space:
while( isspace( filename[strlen(filename)-1] ) )
{
filename[strlen(filename)-1] = '\0';
}
return filename;
}
bool CopyFileBytes( FILE* hDestination, FILE* hSource, unsigned nBytes )
{
char buffer[16384];
while( nBytes > 0 )
{
int nBytesRead = fread( buffer, 1, nBytes > sizeof(buffer) ? sizeof(buffer) : nBytes, hSource );
fwrite(buffer, 1, nBytesRead, hDestination );
nBytes -= nBytesRead;
}
return true;
}
bool WriteFileBytes( FILE* hDestination, CUtlBuffer &source, unsigned nBytes )
{
unsigned int nBytesWritten = fwrite(source.Base(), 1, nBytes, hDestination );
return (nBytesWritten == nBytes);
}
void PadFileBytes(FILE* hFile, int nPreloadPadding )
{
if( nPreloadPadding < 0 || nPreloadPadding >= 512)
{
puts("Invalid padding");
return;
}
char padding[512];
memset(padding,0,nPreloadPadding);
fwrite(padding,1,nPreloadPadding,hFile);
}
void AddFilename( const char* filename )
{
unsigned CRCfilename = xZipCRCFilename( filename );
// If we already have this filename don't add it again:
for( int i = 0; i < (int)Header.FilenameEntries; i++ )
{
if( pFilenameEntries[i].FilenameCRC == CRCfilename )
{
return;
}
}
Header.FilenameEntries++;
// Add the file to the file string table:
pFilenameEntries = (xZipFilenameEntry_t*)realloc( pFilenameEntries, sizeof(xZipFilenameEntry_t) * Header.FilenameEntries );
int filenameLength = (int)strlen(filename) + 1;
pFilenameEntries[Header.FilenameEntries-1].FilenameCRC = CRCfilename;
pFilenameEntries[Header.FilenameEntries-1].FilenameOffset = nFilenameDataLength;
// Grab the timestamp for the file:
struct stat buf;
if( stat( filename, &buf ) != -1 )
{
pFilenameEntries[Header.FilenameEntries - 1].TimeStamp = buf.st_mtime;
}
else
{
pFilenameEntries[Header.FilenameEntries - 1].TimeStamp = 0;
}
nFilenameDataLength += filenameLength;
pFilenameData = (char*)realloc(pFilenameData, nFilenameDataLength);
memcpy(pFilenameData + nFilenameDataLength - filenameLength, filename, filenameLength);
}
FILE* hTempFilePreload;
FILE* hTempFileData;
FILE* hOutputFile;
bool xZipAddFile( const char* filename, CUtlBuffer &fileBuff, bool bPrecacheEntireFile, bool bProcessPrecacheHeader, bool bProcessPrecacheHeaderOnly )
{
unsigned int fileSize = fileBuff.TellMaxPut();
// Track total input bytes for stats reasons
InputFileBytes += fileSize;
unsigned customPreloadSize = 0;
if( bPrecacheEntireFile )
{
customPreloadSize = fileSize;
}
else if( bProcessPrecacheHeader )
{
customPreloadSize = xZipComputeCustomPreloads( filename );
}
else if( bProcessPrecacheHeaderOnly )
{
customPreloadSize = xZipComputeCustomPreloads( filename );
fileSize = min( fileSize, customPreloadSize );
}
unsigned CRC = xZipCRCFilename( filename );
// Does this file have a split header?
if( customPreloadSize > 0 )
{
// Initialize the entry header:
xZipDirectoryEntry_t entry;
memset( &entry, 0, sizeof( entry ) );
entry.FilenameCRC = CRC;
entry.Length = customPreloadSize;
entry.StoredOffset = ftell(hTempFilePreload);
// Add the directory entry to the preload table:
Header.PreloadDirectoryEntries++;
pPreloadDirectoryEntries = (xZipDirectoryEntry_t*)realloc( pPreloadDirectoryEntries, sizeof( xZipDirectoryEntry_t ) * Header.PreloadDirectoryEntries );
memcpy( pPreloadDirectoryEntries + Header.PreloadDirectoryEntries - 1, &entry, sizeof( entry ) );
// Concatenate the data in the preload file:
fileBuff.SeekGet( CUtlBuffer::SEEK_HEAD, 0 );
WriteFileBytes( hTempFilePreload, fileBuff, entry.Length );
fileBuff.SeekGet( CUtlBuffer::SEEK_HEAD, 0 );
// Add the filename entry:
AddFilename( filename );
// Spew it:
printf("+Preload: \"%s\": Length:%u\n", filename, entry.Length );
}
// Copy the file to the regular data region:
xZipDirectoryEntry_t entry;
memset(&entry,0,sizeof(entry));
entry.FilenameCRC = CRC;
entry.Length = fileSize;
entry.StoredOffset = ftell(hTempFileData);
// Add the directory entry to the table:
Header.DirectoryEntries++;
pDirectoryEntries = (xZipDirectoryEntry_t*)realloc( pDirectoryEntries, sizeof( xZipDirectoryEntry_t ) * Header.DirectoryEntries );
memcpy( pDirectoryEntries + Header.DirectoryEntries - 1, &entry, sizeof( entry ) );
WriteFileBytes( hTempFileData, fileBuff, entry.Length );
// Align the data region to a 512 byte boundry: (has to be on last entry as well to ensure enough space to perform the final read,
// and initial alignment is taken careof by assembexzip)
int nPadding = ( XBOX_HDD_SECTORSIZE - ( ftell( hTempFileData ) % XBOX_HDD_SECTORSIZE) ) % XBOX_HDD_SECTORSIZE;
PadFileBytes( hTempFileData, nPadding );
// Add the file to the file string table:
AddFilename( filename );
// Print a summary
printf("+File: \"%s\": Length:%u Padding:%i\n", filename, entry.Length, nPadding );
return true;
}
bool xZipAddFile( const char* zipname, bool bPrecacheEntireFile, bool bProcessPrecacheHeader, bool bProcessPrecacheHeaderOnly )
{
// Clean up the filename:
char buffer[MAX_PATH];
strcpy(buffer, zipname);
// Fix slashes and convert it to lower case:
char *filename;
for( filename = buffer; *filename; filename++ )
{
if( *filename == '/' )
*filename = '\\';
else
{
*filename = (char)tolower(*filename);
}
}
// Skip leading white space:
for( filename = buffer; isspace(*filename); filename++ )
;
// Obliterate trailing white space:
for(;;)
{
int len = (int)strlen( filename );
if( len <= 0 )
{
printf("!!!! BAD FILENAME: \"%s\"\n", filename );
return false;
}
if( isspace( filename[len-1] ) )
filename[len-1]='\0';
else
break;
}
// Ensure we don't already have this file:
unsigned CRC = xZipCRCFilename( filename );
for( unsigned i=0; i < Header.DirectoryEntries; i++ )
{
if( pDirectoryEntries[i].FilenameCRC == CRC )
{
printf("!!!! NOT ADDING DUPLICATE FILENAME: \"%s\"\n", filename );
return false;
}
}
// Attempt to open the file:
FILE* hFile = fopen( filename, "rb" );
if( !hFile )
{
printf("!!!! FAILED TO OPEN FILE: \"%s\"\n", filename );
return false;
}
// Get the length of the file:
fseek(hFile,0,SEEK_END);
unsigned fileSize = ftell(hFile);
fseek(hFile,0,SEEK_SET);
CUtlBuffer fileBuff;
fileBuff.EnsureCapacity( fileSize );
fread( fileBuff.Base(), fileSize, 1, hFile );
fclose( hFile );
fileBuff.SeekPut( CUtlBuffer::SEEK_HEAD, fileSize );
return xZipAddFile( zipname, fileBuff, bPrecacheEntireFile, bProcessPrecacheHeader, bProcessPrecacheHeaderOnly );
}
int xZipBegin( const char* fileNameXzip )
{
// Create and initialize the header:
memset( &Header, 0, sizeof(Header) ); // Zero out the header:
Header.Magic = xZipHeader_t::MAGIC;
Header.Version = xZipHeader_t::VERSION;
Header.HeaderLength = sizeof(Header);
// Open the output file:
hOutputFile = fopen(fileNameXzip,"wb+");
if( !hOutputFile )
{
printf("Failed to open \"%s\" for writing.\n", fileNameXzip);
exit( EXIT_FAILURE);
}
// Create a temporary file for storing the preloaded data:
hTempFilePreload = tmpfile();
if( !hTempFilePreload )
{
printf( "Error: failed to create temporary file\n" );
return EXIT_FAILURE;
}
// Create a temporary file for storing the non preloaded data
hTempFileData = tmpfile();
if( !hTempFileData )
{
printf( "Error: failed to create temporary file\n");
return EXIT_FAILURE;
}
return EXIT_SUCCESS;
}
bool xZipEnd()
{
int nPreloadDirectorySize = sizeof(xZipDirectoryEntry_t)*Header.PreloadDirectoryEntries;
int nRegular2PreloadSize = sizeof(unsigned short) * Header.DirectoryEntries;
// Compute the size of the preloaded section:
if( Header.PreloadDirectoryEntries )
{
fseek( hTempFilePreload, 0, SEEK_END );
Header.PreloadBytes = ftell(hTempFilePreload) + nPreloadDirectorySize + nRegular2PreloadSize; // Raw# of bytes to preload
fseek( hTempFilePreload, 0, SEEK_SET );
}
else
{
Header.PreloadBytes = 0;
}
// Number of bytes preceeding the preloaded section:
int nPreloadOffset = sizeof( Header ) + ( sizeof( xZipDirectoryEntry_t ) * Header.DirectoryEntries );
// Number of bytes to pad between the end of the preload section and the start of the data section:
int nPadding = ( 512 - ( ( nPreloadOffset + Header.PreloadBytes ) % 512) ) %512; // Number of alignment bytes after the preload section
// Offset past the preload section:
int nDataOffset = nPreloadOffset + Header.PreloadBytes + nPadding;
// Write out the header: (will need to be rewritten at the end as well) - note: not even bothering to byteswap at this point
fwrite(&Header,sizeof(Header),1,hOutputFile);
// Fixup each of the directory entries to make them relative to the beginning of the file.
for( unsigned i=0; i< Header.DirectoryEntries;i++ )
{
xZipDirectoryEntry_t* pDir = &(pDirectoryEntries[i]);
// Adjust files in the regular data area:
pDir->StoredOffset = nDataOffset + pDir->StoredOffset;
}
// Sort and write the directory:
printf("Sorting and writing %i directory entries...\n",Header.DirectoryEntries);
qsort(pDirectoryEntries,Header.DirectoryEntries,sizeof(xZipDirectoryEntry_t),&xZipDirectoryEntry_t::xZipDirectoryEntrySortCompare);
// Swap the directory entries:
for( unsigned i=0; i < Header.DirectoryEntries; i++ )
{
g_xzpSwap.SwapFieldsToTargetEndian<xZipDirectoryEntry_t>(&pDirectoryEntries[i]);
}
fwrite(pDirectoryEntries,Header.DirectoryEntries*sizeof(xZipDirectoryEntry_t),1, hOutputFile);
// Swap the directory back for later use:
for( unsigned i=0; i < Header.DirectoryEntries; i++ )
{
g_xzpSwap.SwapFieldsToTargetEndian<xZipDirectoryEntry_t>(&pDirectoryEntries[i]);
}
// Copy the preload section:
if( Header.PreloadBytes > 0 )
{
printf("Generating the preload section...(%u)\n", Header.PreloadBytes);
// Fixup each of the directory entries to make them relative to the beginning of the file.
for( unsigned i=0; i< Header.PreloadDirectoryEntries;i++ )
{
xZipDirectoryEntry_t* pDir = &(pPreloadDirectoryEntries[i]);
// Shift preload data down by preload bytes (and skipping over the directory):
pDir->StoredOffset += nPreloadOffset + nPreloadDirectorySize + nRegular2PreloadSize;
}
printf("Sorting %u preload directory entries...\n",Header.PreloadDirectoryEntries);
qsort(pPreloadDirectoryEntries,Header.PreloadDirectoryEntries,sizeof(xZipDirectoryEntry_t),&xZipDirectoryEntry_t::xZipDirectoryEntrySortCompare);
printf("Building regular to preload mapping table for %u entries...\n", Header.DirectoryEntries );
unsigned short* Regular2Preload = (unsigned short*)malloc( nRegular2PreloadSize );
for( unsigned i = 0; i < Header.DirectoryEntries; i++ )
{
unsigned short j;
for( j = 0; j < Header.PreloadDirectoryEntries; j++ )
{
if( pDirectoryEntries[i].FilenameCRC == pPreloadDirectoryEntries[j].FilenameCRC )
break;
}
// If I couldn't find it mark it as non-existant:
if( j == Header.PreloadDirectoryEntries )
j = 0xFFFF;
Regular2Preload[i] = j;
}
printf("Writing preloaded directory entreis...\n" );
// Swap the preload directory entries:
for( unsigned i=0; i < Header.PreloadDirectoryEntries; i++ )
{
g_xzpSwap.SwapFieldsToTargetEndian<xZipDirectoryEntry_t>(&pPreloadDirectoryEntries[i]);
}
fwrite( pPreloadDirectoryEntries, Header.PreloadDirectoryEntries*sizeof(xZipDirectoryEntry_t),1, hOutputFile );
// Swap them back:
for( unsigned i=0; i < Header.PreloadDirectoryEntries; i++ )
{
g_xzpSwap.SwapFieldsToTargetEndian<xZipDirectoryEntry_t>(&pPreloadDirectoryEntries[i]);
}
printf("Writing regular to preload mapping (%u bytes)...\n", sizeof(unsigned short)*Header.DirectoryEntries );
// Swap regular to preload mapping:
g_xzpSwap.SwapBufferToTargetEndian<short>((short*)Regular2Preload, (short*)Regular2Preload, nRegular2PreloadSize / sizeof(short) );
fwrite( Regular2Preload, nRegular2PreloadSize,1,hOutputFile );
// Swap it back
g_xzpSwap.SwapBufferToTargetEndian<short>((short*)Regular2Preload, (short*)Regular2Preload, nRegular2PreloadSize / sizeof(short) );
printf("Copying %u Preloadable Bytes...\n", Header.PreloadBytes - nPreloadDirectorySize - nRegular2PreloadSize );
fseek(hTempFilePreload,0,SEEK_SET);
CopyFileBytes(hOutputFile, hTempFilePreload, Header.PreloadBytes - nPreloadDirectorySize - nRegular2PreloadSize );
}
// Align the data section following the preload section:
if( nPadding )
{
printf("Aligning Data Section Start by %u bytes...\n", nPadding );
PadFileBytes(hOutputFile, nPadding );
}
// Copy the data section:
fseek(hTempFileData, 0, SEEK_END );
unsigned length = ftell( hTempFileData );
fseek(hTempFileData, 0, SEEK_SET );
printf("Copying %u Bytes...\n",length);
CopyFileBytes(hOutputFile, hTempFileData, length);
// Write out the filename data if present:
if( nFilenameDataLength && Header.FilenameEntries )
{
Header.FilenameStringsOffset = ftell(hOutputFile);
Header.FilenameStringsLength = (Header.FilenameEntries*sizeof(xZipFilenameEntry_t)) + nFilenameDataLength;
// Adjust the offset in each of the filename offsets to absolute position in the file.
for( unsigned i=0;i<Header.FilenameEntries;i++ )
{
pFilenameEntries[i].FilenameOffset += ( Header.FilenameStringsOffset + (Header.DirectoryEntries*sizeof(xZipFilenameEntry_t)));
}
printf("Sorting and writing %u filename directory entries...\n",Header.FilenameEntries);
// Sort the data:
qsort(pFilenameEntries,Header.FilenameEntries,sizeof(xZipFilenameEntry_t),&xZipFilenameEntry_t::xZipFilenameEntryCompare);
// Write the data out:
for( unsigned int i = 0; i < Header.FilenameEntries; i++ )
{
g_xzpSwap.SwapFieldsToTargetEndian<xZipFilenameEntry_t>(&pFilenameEntries[i]);
}
fwrite(pFilenameEntries,1,Header.FilenameEntries*sizeof(xZipFilenameEntry_t),hOutputFile);
// Swap them back:
for( unsigned int i = 0; i < Header.FilenameEntries; i++ )
{
g_xzpSwap.SwapFieldsToTargetEndian<xZipFilenameEntry_t>(&pFilenameEntries[i]);
}
printf("Writing %u bytes of filename data...\n",nFilenameDataLength);
fwrite(pFilenameData,1,nFilenameDataLength,hOutputFile);
}
// Compute the total file size, including the size of the footer:
unsigned OutputFileBytes = ftell(hOutputFile) + sizeof(xZipFooter_t);
// Write the footer: (block used to keep possibly swapped footer from being used later)
{
xZipFooter_t footer;
footer.Magic = xZipFooter_t::MAGIC;
footer.Size = OutputFileBytes;
g_xzpSwap.SwapFieldsToTargetEndian<xZipFooter_t>( &footer ); // Swap the footer
fwrite( &footer, 1, sizeof(footer), hOutputFile );
}
// Seek back and rewrite the header (filename data changes it for example)
fseek(hOutputFile,0,SEEK_SET);
g_xzpSwap.SwapFieldsToTargetEndian<xZipHeader_t>( &Header ); // Swap it to write out:
fwrite(&Header,1,sizeof(Header),hOutputFile);
g_xzpSwap.SwapFieldsToTargetEndian<xZipHeader_t>( &Header ); // But then swap it back so we can use it in memory
// Shut down
fclose(hOutputFile);
// Print the summary
printf("\n\nSummary: Input:%u, XZip:%u, Directory Entries:%u (%u preloaded), Preloaded Bytes:%u\n\n",InputFileBytes,OutputFileBytes,Header.DirectoryEntries, Header.PreloadDirectoryEntries, Header.PreloadBytes);
// Shut down:
fclose(hTempFileData);
fclose(hTempFilePreload);
return true;
}
#define PADD_ID MAKEID('P','A','D','D')
//-----------------------------------------------------------------------------
// xZipComputeWAVPreload
//
// Returns the number of bytes from a xbox compliant WAV file that should go into
// the preload section:
//-----------------------------------------------------------------------------
unsigned xZipComputeWAVPreload( char *pFileName )
{
InFileRIFF riff( pFileName, *g_pSndIO );
if ( riff.RIFFName() != RIFF_WAVE )
{
return 0;
}
IterateRIFF walk( riff, riff.RIFFSize() );
while ( walk.ChunkAvailable() )
{
// xbox compliant wavs have a single PADD chunk
if ( walk.ChunkName() == PADD_ID )
{
// want to preload data up through PADD chunk header
// and not the actual pad bytes
return walk.ChunkFilePosition() + 2*sizeof( int );
}
walk.ChunkNext();
}
return 0;
}
//-----------------------------------------------------------------------------
// xZipComputeXWVPreload
//
// Returns the number of bytes from a XWV file that should go into the preload
// section:
//-----------------------------------------------------------------------------
unsigned xZipComputeXWVPreload( const char* filename )
{
FILE* hFile = fopen( filename, "rb" );
if ( !hFile )
{
printf( "Failed to open xwv file: %s\n", filename );
return 0;
}
// Read and validate the XWV header:
xwvHeader_t header;
memset( &header, 0, sizeof(header) );
fread( &header, 1, sizeof(header), hFile );
fclose( hFile );
if ( header.id != XWV_ID || header.headerSize != sizeof(header) )
return 0;
return header.GetPreloadSize();
}
unsigned xZipComputeXTFPreload( const char* filename )
{
#if 0 // X360TBD: Not using XTF anymore
FILE* hFile = fopen( filename, "rb" );
if ( !hFile )
{
printf("Failed to open file: %s\n", filename);
return 0;
}
XTFFileHeader_t header;
memset( &header,0, sizeof( header ) );
fread( &header,1,sizeof(header),hFile);
fclose(hFile);
if ( !strncmp( header.fileTypeString, "XTF", 4 ) )
return header.preloadDataSize;
#endif
return 0;
}
// TODO: ONLY store them in the preload section:
unsigned xZipComputeVMTPreload( const char* filename )
{
// Store VMT's entirely
if ( !strstr(filename,".vmt") )
return 0;
FILE* hFile = fopen( filename, "rb" );
if ( !hFile )
{
printf("Failed to open file: %s\n", filename);
return 0;
}
fseek( hFile, 0, SEEK_END );
unsigned offset = ftell( hFile );
fclose( hFile );
return offset;
}
// TODO: ONLY store them in the preload section:
unsigned xZipComputeVHVPreload( const char* filename )
{
// Store VMT's entirely
if ( !strstr(filename,".vhv") )
return 0;
FILE* hFile = fopen( filename, "rb" );
if ( !hFile )
{
printf("Failed to open file: %s\n", filename);
return 0;
}
fclose( hFile );
// Just load the header:
return sizeof(HardwareVerts::FileHeader_t);
}
unsigned xZipComputeXCSPreload( const char* filename )
{
if( !strstr(filename,".vcs") )
return 0;
FILE* hFile = fopen( filename, "rb" );
if ( !hFile )
{
printf("Failed to open file: %s\n", filename);
return 0;
}
XShaderHeader_t header;
fread(&header,1,sizeof(XShaderHeader_t), hFile);
fseek(hFile,0,SEEK_END);
fclose(hFile);
if (!header.IsValid())
return 0;
return header.BytesToPreload();
}
unsigned xZipComputeCustomPreloads( const char* filename )
{
// X360TBD: These all need to act on a utlbuffer
Assert( 0 );
return 0;
// strlwr(filename);
unsigned offset = xZipComputeXWVPreload( filename );
if ( offset )
return offset;
offset = xZipComputeVMTPreload( filename );
if ( offset )
return offset;
offset = xZipComputeXCSPreload( filename );
if ( offset )
return offset;
offset = xZipComputeVHVPreload( filename );
if ( offset )
return offset;
return xZipComputeXTFPreload( filename );
}
#endif // MAKE_GAMEDATA_TOOL