gtkradiant/tools/quake3/q3data/video.c
TTimo ab3a99dbbe eol style
git-svn-id: svn://svn.icculus.org/gtkradiant/GtkRadiant/branches/ZeroRadiant.ab@184 8a3a26a2-13c4-0310-b231-cf6edde360e5
2007-11-04 03:47:06 +00:00

1132 lines
26 KiB
C

#include <assert.h>
#include "q3data.h"
static int s_resample_width = 256;
static int s_resample_height = 256;
#define OUTPUT_TGAS 1
#define UNCOMPRESSED 0
#define BTC_COMPRESSION 1
static int s_compression_method = BTC_COMPRESSION;
static const char *CIN_EXTENSION = "cn2";
static const int CIN_SIGNATURE = ( 'C' << 24 ) | ( 'I' << 16 ) | ( 'N' << 8 ) | ( '2' );
static byte *s_soundtrack;
static char s_base[32];
static char s_output_base[32];
/*
===============================================================================
WAV loading
===============================================================================
*/
typedef struct
{
int rate;
int width;
int channels;
int loopstart;
int samples;
int dataofs; // chunk starts this many bytes from file start
} wavinfo_t;
byte *data_p;
byte *iff_end;
byte *last_chunk;
byte *iff_data;
int iff_chunk_len;
static int s_samplecounts[0x10000];
static wavinfo_t s_wavinfo;
short GetLittleShort(void)
{
short val = 0;
val = *data_p;
val = val + (*(data_p+1)<<8);
data_p += 2;
return val;
}
int GetLittleLong(void)
{
int val = 0;
val = *data_p;
val = val + (*(data_p+1)<<8);
val = val + (*(data_p+2)<<16);
val = val + (*(data_p+3)<<24);
data_p += 4;
return val;
}
void FindNextChunk(char *name)
{
while (1)
{
data_p=last_chunk;
if (data_p >= iff_end)
{ // didn't find the chunk
data_p = NULL;
return;
}
data_p += 4;
iff_chunk_len = GetLittleLong();
if (iff_chunk_len < 0)
{
data_p = NULL;
return;
}
// if (iff_chunk_len > 1024*1024)
// Sys_Error ("FindNextChunk: %i length is past the 1 meg sanity limit", iff_chunk_len);
data_p -= 8;
last_chunk = data_p + 8 + ( (iff_chunk_len + 1) & ~1 );
if (!strncmp(data_p, name, 4))
return;
}
}
void FindChunk(char *name)
{
last_chunk = iff_data;
FindNextChunk (name);
}
void DumpChunks(void)
{
char str[5];
str[4] = 0;
data_p=iff_data;
do
{
memcpy (str, data_p, 4);
data_p += 4;
iff_chunk_len = GetLittleLong();
printf ("0x%x : %s (%d)\n", (int)(data_p - 4), str, iff_chunk_len);
data_p += (iff_chunk_len + 1) & ~1;
} while (data_p < iff_end);
}
/*
============
GetWavinfo
============
*/
wavinfo_t GetWavinfo (char *name, byte *wav, int wavlength)
{
wavinfo_t info;
int i;
int format;
int samples;
memset (&info, 0, sizeof(info));
if (!wav)
return info;
iff_data = wav;
iff_end = wav + wavlength;
// find "RIFF" chunk
FindChunk("RIFF");
if (!(data_p && !strncmp(data_p+8, "WAVE", 4)))
{
printf("Missing RIFF/WAVE chunks\n");
return info;
}
// get "fmt " chunk
iff_data = data_p + 12;
// DumpChunks ();
FindChunk("fmt ");
if (!data_p)
{
printf("Missing fmt chunk\n");
return info;
}
data_p += 8;
format = GetLittleShort();
if (format != 1)
{
printf("Microsoft PCM format only\n");
return info;
}
info.channels = GetLittleShort();
info.rate = GetLittleLong();
data_p += 4+2;
info.width = GetLittleShort() / 8;
// get cue chunk
FindChunk("cue ");
if (data_p)
{
data_p += 32;
info.loopstart = GetLittleLong();
// Com_Printf("loopstart=%d\n", sfx->loopstart);
// if the next chunk is a LIST chunk, look for a cue length marker
FindNextChunk ("LIST");
if (data_p)
{
if (!strncmp (data_p + 28, "mark", 4))
{ // this is not a proper parse, but it works with cooledit...
data_p += 24;
i = GetLittleLong (); // samples in loop
info.samples = info.loopstart + i;
}
}
}
else
info.loopstart = -1;
// find data chunk
FindChunk("data");
if (!data_p)
{
printf("Missing data chunk\n");
return info;
}
data_p += 4;
samples = GetLittleLong ();
if (info.samples)
{
if (samples < info.samples)
Error ("Sound %s has a bad loop length", name);
}
else
info.samples = samples;
info.dataofs = data_p - wav;
return info;
}
//=====================================================================
/*
==============
LoadSoundtrack
==============
*/
void LoadSoundtrack (void)
{
char name[1024];
FILE *f;
int len;
int i, val, j;
s_soundtrack = NULL;
sprintf (name, "%svideo/%s/%s.wav", gamedir, s_base, s_base);
printf ("WAV: %s\n", name);
f = fopen (name, "rb");
if (!f)
{
printf ("no soundtrack for %s\n", s_base);
return;
}
len = Q_filelength(f);
s_soundtrack = malloc(len);
fread (s_soundtrack, 1, len, f);
fclose (f);
s_wavinfo = GetWavinfo (name, s_soundtrack, len);
// count samples for compression
memset (s_samplecounts, 0, sizeof(s_samplecounts));
j = s_wavinfo.samples/2;
for (i=0 ; i<j ; i++)
{
val = ((unsigned short *)( s_soundtrack + s_wavinfo.dataofs))[i];
s_samplecounts[val]++;
}
val = 0;
for (i=0 ; i<0x10000 ; i++)
if (s_samplecounts[i])
val++;
printf ("%i unique sample values\n", val);
}
/*
==================
WriteSound
==================
*/
void WriteSound (FILE *output, int frame)
{
int start, end;
int count;
int empty = 0;
int i;
int sample;
int width;
width = s_wavinfo.width * s_wavinfo.channels;
start = frame*s_wavinfo.rate/14;
end = (frame+1)*s_wavinfo.rate/14;
count = end - start;
for (i=0 ; i<count ; i++)
{
sample = start+i;
if (sample > s_wavinfo.samples || !s_soundtrack)
fwrite (&empty, 1, width, output);
else
fwrite (s_soundtrack + s_wavinfo.dataofs + sample*width, 1, width,output);
}
}
//==========================================================================
static float s_resampleXRatio;
static float s_resampleYRatio;
static void BoxFilterHorizontalElements( unsigned char *dst, unsigned char *src, float s0, float s1 )
{
float w;
float rSum = 0, gSum = 0, bSum = 0;
float x = s0;
float sumWeight = 0;
for ( x = s0; x < s1; x++, src += 4 )
{
if ( x == s0 )
{
w = ( int ) ( s0 + 1 ) - x;
}
else if ( x + 1 >= s1 )
{
w = s1 - ( int ) x;
}
else
{
w = 1.0f;
}
rSum += src[0] * w;
gSum += src[1] * w;
bSum += src[2] * w;
sumWeight += w;
}
rSum /= sumWeight;
gSum /= sumWeight;
bSum /= sumWeight;
dst[0] = ( unsigned char ) ( rSum + 0.5 );
dst[1] = ( unsigned char ) ( gSum + 0.5 );
dst[2] = ( unsigned char ) ( bSum + 0.5 );
}
static void BoxFilterVerticalElements( unsigned char *dst, // destination of the filter process
unsigned char *src, // source pixels
int srcStep, // stride of the source pixels
float s0, float s1 )
{
float w;
float rSum = 0, gSum = 0, bSum = 0;
float y = s0;
float sumWeight = 0;
for ( y = s0; y < ( int ) ( s1 + 1 ) ; y++, src += srcStep )
{
if ( y == s0 )
{
w = ( int ) ( s0 + 1 ) - y;
}
else if ( y + 1 >= s1 )
{
w = s1 - ( int ) y;
}
else
{
w = 1.0f;
}
rSum += src[0] * w;
gSum += src[1] * w;
bSum += src[2] * w;
sumWeight += w;
}
rSum /= sumWeight;
gSum /= sumWeight;
bSum /= sumWeight;
dst[0] = ( unsigned char ) ( rSum + 0.5 );
dst[1] = ( unsigned char ) ( gSum + 0.5 );
dst[2] = ( unsigned char ) ( bSum + 0.5 );
dst[3] = 0xff;
}
static void BoxFilterRow( unsigned char *dstStart, cblock_t *in, int dstRow, int rowWidth )
{
int i;
unsigned char *indata = ( unsigned char * ) in->data;
indata += 4 * dstRow * in->width;
for ( i = 0; i < rowWidth; i++ )
{
float c0 = i * s_resampleXRatio;
float c1 = ( i + 1 ) * s_resampleXRatio;
BoxFilterHorizontalElements( &dstStart[i*4], &indata[( ( int ) c0 ) * 4], c0, c1 );
}
}
static void BoxFilterColumn( unsigned char *dstStart, unsigned char *srcStart, int dstCol, int dstRowWidth, int dstColHeight, int srcRowWidthInPels )
{
float c0, c1;
int i;
for ( i = 0; i < dstColHeight; i++ )
{
c0 = i * s_resampleYRatio;
c1 = ( i + 1 ) * s_resampleYRatio;
BoxFilterVerticalElements( &dstStart[i*4*dstRowWidth], &srcStart[(int)c0*srcRowWidthInPels*4], srcRowWidthInPels*4, c0, c1 );
}
}
#define DROP_SAMPLE 0
#define BOX_FILTER 1
static void ResampleFrame( cblock_t *in, unsigned char *out, int method, int outWidth, int outHeight )
{
int row, column;
unsigned char *indata = ( unsigned char * ) in->data;
s_resampleXRatio = in->width / ( float ) outWidth;
s_resampleYRatio = in->height / ( float ) outHeight;
if ( method == DROP_SAMPLE )
{
for ( row = 0; row < outHeight; row++ )
{
int r = ( int ) ( row * s_resampleYRatio );
for ( column = 0; column < outWidth; column++ )
{
int c = ( int ) ( column * s_resampleXRatio );
out[(row*outWidth+column)*4+0] = indata[(r*in->width+c)*4+0];
out[(row*outWidth+column)*4+1] = indata[(r*in->width+c)*4+1];
out[(row*outWidth+column)*4+2] = indata[(r*in->width+c)*4+2];
out[(row*outWidth+column)*4+3] = 0xff;
}
}
}
else if ( method == BOX_FILTER )
{
unsigned char intermediate[1024*1024*4];
assert( in->height <= 1024 );
assert( in->width <= 1024 );
//
// filter our M x N source image into a RESAMPLE_WIDTH x N horizontally filtered image
//
for ( row = 0; row < in->height; row++ )
{
BoxFilterRow( &intermediate[row*4*outWidth], in, row, outWidth );
}
//
// filter our RESAMPLE_WIDTH x N horizontally filtered image into a RESAMPLE_WIDTH x RESAMPLE_HEIGHT filtered image
//
for ( column = 0; column < outWidth; column++ )
{
BoxFilterColumn( &out[column*4], &intermediate[column*4], column, outWidth, outHeight, s_resample_width );
}
}
}
static float BTCDistanceSquared( float a[3], float b[3] )
{
return ( b[0] - a[0] ) * ( b[0] - a[0] ) +
( b[1] - a[1] ) * ( b[1] - a[1] ) +
( b[2] - a[2] ) * ( b[2] - a[2] );
}
static void BTCFindEndpoints( float inBlock[4][4][3], unsigned int endPoints[2][2] )
{
float longestDistance = -1;
int bX, bY;
//
// find the two points farthest from each other
//
for ( bY = 0; bY < 4; bY++ )
{
for ( bX = 0; bX < 4; bX++ )
{
int cX, cY;
float d;
//
// check the rest of the current row
//
for ( cX = bX + 1; cX < 4; cX++ )
{
if ( ( d = BTCDistanceSquared( inBlock[bY][bX], inBlock[bY][cX] ) ) > longestDistance )
{
longestDistance = d;
endPoints[0][0] = bX;
endPoints[0][1] = bY;
endPoints[1][0] = cX;
endPoints[1][1] = bY;
}
}
//
// check remaining rows and columns
//
for ( cY = bY+1; cY < 4; cY++ )
{
for ( cX = 0; cX < 4; cX++ )
{
if ( ( d = BTCDistanceSquared( inBlock[bY][bX], inBlock[cY][cX] ) ) > longestDistance )
{
longestDistance = d;
endPoints[0][0] = bX;
endPoints[0][1] = bY;
endPoints[1][0] = cX;
endPoints[1][1] = cY;
}
}
}
}
}
}
static float BTCQuantizeBlock( float inBlock[4][4][3], unsigned long endPoints[2][2], int btcQuantizedBlock[4][4], float bestError )
{
int i;
int blockY, blockX;
float dR, dG, dB;
float R, G, B;
float error = 0;
float colorLine[4][3];
//
// build the color line
//
dR = inBlock[endPoints[1][1]][endPoints[1][0]][0] -
inBlock[endPoints[0][1]][endPoints[0][0]][0];
dG = inBlock[endPoints[1][1]][endPoints[1][0]][1] -
inBlock[endPoints[0][1]][endPoints[0][0]][1];
dB = inBlock[endPoints[1][1]][endPoints[1][0]][2] -
inBlock[endPoints[0][1]][endPoints[0][0]][2];
dR *= 0.33f;
dG *= 0.33f;
dB *= 0.33f;
R = inBlock[endPoints[0][1]][endPoints[0][0]][0];
G = inBlock[endPoints[0][1]][endPoints[0][0]][1];
B = inBlock[endPoints[0][1]][endPoints[0][0]][2];
for ( i = 0; i < 4; i++ )
{
colorLine[i][0] = R;
colorLine[i][1] = G;
colorLine[i][2] = B;
R += dR;
G += dG;
B += dB;
}
//
// quantize each pixel into the appropriate range
//
for ( blockY = 0; blockY < 4; blockY++ )
{
for ( blockX = 0; blockX < 4; blockX++ )
{
float distance = 10000000000;
int shortest = -1;
for ( i = 0; i < 4; i++ )
{
float d;
if ( ( d = BTCDistanceSquared( inBlock[blockY][blockX], colorLine[i] ) ) < distance )
{
distance = d;
shortest = i;
}
}
error += distance;
//
// if bestError is not -1 then that means this is a speculative quantization
//
if ( bestError != -1 )
{
if ( error > bestError )
return error;
}
btcQuantizedBlock[blockY][blockX] = shortest;
}
}
return error;
}
/*
** float BTCCompressBlock
*/
static float BTCCompressBlock( float inBlock[4][4][3], unsigned long out[2] )
{
int i;
int btcQuantizedBlock[4][4]; // values should be [0..3]
unsigned long encodedEndPoints, encodedBitmap;
unsigned int endPoints[2][2]; // endPoints[0] = color start, endPoints[1] = color end
int blockY, blockX;
float error = 0;
float bestError = 10000000000;
unsigned int bestEndPoints[2][2];
#if 0
//
// find the "ideal" end points for the color vector
//
BTCFindEndpoints( inBlock, endPoints );
error = BTCQuantizeBlock( inBlock, endPoints, btcQuantizedBlock );
memcpy( bestEndPoints, endPoints, sizeof( bestEndPoints ) );
#else
for ( blockY = 0; blockY < 4; blockY++ )
{
for ( blockX = 0; blockX < 4; blockX++ )
{
int x2, y2;
for ( y2 = 0; y2 < 4; y2++ )
{
for ( x2 = 0; x2 < 4; x2++ )
{
if ( ( x2 == blockX ) && ( y2 == blockY ) )
continue;
endPoints[0][0] = blockX;
endPoints[0][1] = blockY;
endPoints[1][0] = x2;
endPoints[1][1] = y2;
error = BTCQuantizeBlock( inBlock, endPoints, btcQuantizedBlock, -1 ); //bestError );
if ( error < bestError )
{
bestError = error;
memcpy( bestEndPoints, endPoints, sizeof( bestEndPoints ) );
}
}
}
}
}
error = BTCQuantizeBlock( inBlock, bestEndPoints, btcQuantizedBlock, -1.0f );
#endif
//
// encode the results
//
encodedBitmap = 0;
for ( blockY = 0; blockY < 4; blockY++ )
{
for ( blockX = 0; blockX < 4; blockX++ )
{
int shift = ( blockX + blockY * 4 ) * 2;
encodedBitmap |= btcQuantizedBlock[blockY][blockX] << shift;
}
}
//
// encode endpoints
//
encodedEndPoints = 0;
for ( i = 0; i < 2; i++ )
{
int iR, iG, iB;
iR = ( ( int ) inBlock[bestEndPoints[i][1]][bestEndPoints[i][0]][0] );
if ( iR > 255 )
iR = 255;
else if ( iR < 0 )
iR = 0;
iR >>= 3;
iG = ( ( int ) inBlock[bestEndPoints[i][1]][bestEndPoints[i][0]][1] );
if ( iG > 255 )
iG = 255;
else if ( iG < 0 )
iG = 0;
iG >>= 2;
iB = ( ( int ) inBlock[bestEndPoints[i][1]][bestEndPoints[i][0]][2] );
if ( iB > 255 )
iB = 255;
else if ( iB < 0 )
iB = 0;
iB >>= 3;
encodedEndPoints |= ( ( ( iR << 11 ) | ( iG << 5 ) | ( iB ) ) << ( i * 16 ) );
}
//
// store
//
out[0] = encodedBitmap;
out[1] = encodedEndPoints;
return error;
}
/*
** void BTCDecompressFrame
*/
static void BTCDecompressFrame( unsigned long *src, unsigned char *dst )
{
int x, y;
int iR, iG, iB;
int dstX, dstY;
float colorStart[3], colorEnd[3];
unsigned char colorRampABGR[4][4];
unsigned encoded;
memset( colorRampABGR, 0xff, sizeof( colorRampABGR ) );
for ( y = 0; y < s_resample_height / 4; y++ )
{
for ( x = 0; x < s_resample_width / 4; x++ )
{
unsigned colorStartPacked = src[(y*s_resample_width/4 + x)*2 + 1] & 0xffff;
unsigned colorEndPacked = src[(y*s_resample_width/4 + x)*2 + 1] >> 16;
//
// grab the end points
// 0 = color start
// 1 = color end
//
iR = ( ( colorStartPacked >> 11 ) & ( ( 1 << 5 ) - 1 ) );
iR = ( iR << 3 ) | ( iR >> 2 );
iG = ( ( colorStartPacked >> 5 ) & ( ( 1 << 6 ) - 1 ) );
iG = ( iG << 2 ) | ( iG >> 4 );
iB = ( ( colorStartPacked ) & ( ( 1 << 5 ) - 1 ) );
iB = ( iB << 3 ) | ( iB >> 2 );
colorStart[0] = iR;
colorStart[1] = iG;
colorStart[2] = iB;
colorRampABGR[0][0] = iR;
colorRampABGR[0][1] = iG;
colorRampABGR[0][2] = iB;
iR = ( ( colorEndPacked >> 11 ) & ( ( 1 << 5 ) - 1 ) );
iR = ( iR << 3 ) | ( iR >> 2 );
iG = ( ( colorEndPacked >> 5 ) & ( ( 1 << 6 ) - 1 ) );
iG = ( iG << 2 ) | ( iG >> 4 );
iB = ( colorEndPacked & ( ( 1 << 5 ) - 1 ) );
iB = ( iB << 3 ) | ( iB >> 2 );
colorEnd[0] = iR;
colorEnd[1] = iG;
colorEnd[2] = iB;
colorRampABGR[3][0] = iR;
colorRampABGR[3][1] = iG;
colorRampABGR[3][2] = iB;
//
// compute this block's color ramp
// FIXME: This needs to be reversed on big-endian machines
//
colorRampABGR[1][0] = colorStart[0] * 0.66f + colorEnd[0] * 0.33f;
colorRampABGR[1][1] = colorStart[1] * 0.66f + colorEnd[1] * 0.33f;
colorRampABGR[1][2] = colorStart[2] * 0.66f + colorEnd[2] * 0.33f;
colorRampABGR[2][0] = colorStart[0] * 0.33f + colorEnd[0] * 0.66f;
colorRampABGR[2][1] = colorStart[1] * 0.33f + colorEnd[1] * 0.66f;
colorRampABGR[2][2] = colorStart[2] * 0.33f + colorEnd[2] * 0.66f;
//
// decode the color data
// information is encoded in 2-bit pixels, with low order bits corresponding
// to upper left pixels. These 2-bit values are indexed into the block's
// computer color ramp.
//
encoded = src[(y*s_resample_width/4 + x)*2 + 0];
for ( dstY = 0; dstY < 4; dstY++ )
{
for ( dstX = 0; dstX < 4; dstX++ )
{
memcpy( &dst[(y*4+dstY)*s_resample_width*4+x*4*4+dstX*4], colorRampABGR[encoded&3], sizeof( colorRampABGR[0] ) );
encoded >>= 2;
}
}
}
}
}
/*
** BTCCompressFrame
**
** Perform a BTC compression using a 2-bit encoding at each pixel. This
** compression method is performed by decomposing the incoming image into
** a sequence of 4x4 blocks. At each block two color values are computed
** that define the endpoints of a vector in color space that represent
** the two colors "farthest apart".
*/
static float BTCCompressFrame( unsigned char *src, unsigned long *dst )
{
int x, y;
int bX, bY;
float btcBlock[4][4][3];
float error = 0;
for ( y = 0; y < s_resample_height / 4; y++ )
{
for ( x = 0; x < s_resample_width / 4; x++ )
{
//
// fill in the BTC block with raw values
//
for ( bY = 0; bY < 4; bY++ )
{
for ( bX = 0; bX < 4; bX++ )
{
btcBlock[bY][bX][0] = src[(y*4+bY)*s_resample_width*4 + (x*4+bX)*4 + 0];
btcBlock[bY][bX][1] = src[(y*4+bY)*s_resample_width*4 + (x*4+bX)*4 + 1];
btcBlock[bY][bX][2] = src[(y*4+bY)*s_resample_width*4 + (x*4+bX)*4 + 2];
}
}
error += BTCCompressBlock( btcBlock, &dst[(y*s_resample_width/4+x)*2] );
}
}
return error / ( ( s_resample_width / 4 ) * ( s_resample_height / 4 ) );
}
/*
===================
LoadFrame
===================
*/
cblock_t LoadFrame (char *base, int frame, int digits, byte **palette)
{
int ten3, ten2, ten1, ten0;
cblock_t in;
int width, height;
char name[1024];
FILE *f;
in.data = NULL;
in.count = -1;
ten3 = frame/1000;
ten2 = (frame-ten3*1000)/100;
ten1 = (frame-ten3*1000-ten2*100)/10;
ten0 = frame%10;
if (digits == 4)
sprintf (name, "%svideo/%s/%s%i%i%i%i.tga", gamedir, base, base, ten3, ten2, ten1, ten0);
else
sprintf (name, "%svideo/%s/%s%i%i%i.tga", gamedir, base, base, ten2, ten1, ten0);
f = fopen(name, "rb");
if (!f)
{
in.data = NULL;
return in;
}
fclose (f);
printf ("%s", name);
LoadTGA( name, ( unsigned char ** ) &in.data, &width, &height );
if ( palette )
*palette = 0;
// Load256Image (name, &in.data, palette, &width, &height);
in.count = width*height;
in.width = width;
in.height = height;
// FIXME: map 0 and 255!
#if 0
// rle compress
rle = RLE(in);
free (in.data);
return rle;
#endif
return in;
}
/*
===============
Cmd_Video
video <directory> <framedigits>
===============
*/
void Cmd_Video (void)
{
float sumError = 0, error = 0, maxError = 0;
char savename[1024];
char name[1024];
FILE *output;
int startframe, frame;
int width, height;
int i;
int digits;
int minutes;
float fseconds;
int remSeconds;
cblock_t in;
unsigned char *resampled;
unsigned long *compressed;
clock_t start, stop;
GetToken (qfalse);
strcpy (s_base, token);
if (g_release)
{
// sprintf (savename, "video/%s.cin", token);
// ReleaseFile (savename);
return;
}
GetToken( qfalse );
strcpy( s_output_base, token );
GetToken (qfalse);
digits = atoi(token);
GetToken( qfalse );
if ( !strcmp( token, "btc" ) )
{
s_compression_method = BTC_COMPRESSION;
printf( "Compression: BTC\n" );
}
else if ( !strcmp( token, "uc" ) )
{
s_compression_method = UNCOMPRESSED;
printf( "Compression: none\n" );
}
else
{
Error( "Uknown compression method '%s'\n", token );
}
GetToken( qfalse );
s_resample_width = atoi( token );
GetToken( qfalse );
s_resample_height = atoi( token );
resampled = malloc( sizeof( unsigned char ) * 4 * s_resample_width * s_resample_height );
compressed = malloc( sizeof( long ) * 2 * ( s_resample_width / 4 ) * ( s_resample_height / 4 ) );
printf( "Resample width: %d\n", s_resample_width );
printf( "Resample height: %d\n", s_resample_height );
// optionally skip frames
if (TokenAvailable ())
{
GetToken (qfalse);
startframe = atoi(token);
}
else
startframe=0;
sprintf (savename, "%svideo/%s.%s", writedir, s_output_base, CIN_EXTENSION );
// load the entire sound wav file if present
LoadSoundtrack ();
if (digits == 4)
sprintf (name, "%svideo/%s/%s0000.tga", gamedir, s_base, s_base);
else
sprintf (name, "%svideo/%s/%s000.tga", gamedir, s_base, s_base);
printf ("%s\n", name);
LoadTGA( name, NULL, &width, &height);
output = fopen (savename, "wb");
if (!output)
Error ("Can't open %s", savename);
// write header info
i = LittleLong( CIN_SIGNATURE );
fwrite (&i, 4, 1, output );
i = LittleLong (s_resample_width);
fwrite (&i, 4, 1, output);
i = LittleLong (s_resample_height);
fwrite (&i, 4, 1, output);
i = LittleLong (s_wavinfo.rate);
fwrite (&i, 4, 1, output);
i = LittleLong (s_wavinfo.width);
fwrite (&i, 4, 1, output);
i = LittleLong (s_wavinfo.channels);
fwrite (&i, 4, 1, output);
i = LittleLong ( s_compression_method );
fwrite (&i, 4, 1, output );
start = clock();
// perform compression on a per frame basis
for ( frame=startframe ; ; frame++)
{
printf ("%02d: ", frame);
in = LoadFrame (s_base, frame, digits, 0 );
if (!in.data)
break;
ResampleFrame( &in, ( unsigned char * ) resampled, BOX_FILTER, s_resample_width, s_resample_height );
if ( s_compression_method == UNCOMPRESSED )
{
printf( "\n" );
fwrite( resampled, 1, sizeof( unsigned char ) * s_resample_width * s_resample_height * 4, output );
#if OUTPUT_TGAS
{
int x, y;
char buffer[1000];
for ( y = 0; y < s_resample_height/2; y++ )
{
for ( x = 0; x < s_resample_width; x++ )
{
unsigned char tmp[4];
tmp[0] = resampled[(s_resample_height-1-y)*s_resample_width*4 + x*4 + 0];
tmp[1] = resampled[(s_resample_height-1-y)*s_resample_width*4 + x*4 + 1];
tmp[2] = resampled[(s_resample_height-1-y)*s_resample_width*4 + x*4 + 2];
tmp[3] = resampled[(s_resample_height-1-y)*s_resample_width*4 + x*4 + 3];
resampled[(s_resample_height-1-y)*s_resample_width*4 + x*4 + 0] = resampled[y*s_resample_width*4 + x*4 + 0];
resampled[(s_resample_height-1-y)*s_resample_width*4 + x*4 + 1] = resampled[y*s_resample_width*4 + x*4 + 1];
resampled[(s_resample_height-1-y)*s_resample_width*4 + x*4 + 2] = resampled[y*s_resample_width*4 + x*4 + 2];
resampled[(s_resample_height-1-y)*s_resample_width*4 + x*4 + 3] = resampled[y*s_resample_width*4 + x*4 + 3];
resampled[y*s_resample_width*4 + x*4 + 0] = tmp[0];
resampled[y*s_resample_width*4 + x*4 + 1] = tmp[1];
resampled[y*s_resample_width*4 + x*4 + 2] = tmp[2];
resampled[y*s_resample_width*4 + x*4 + 3] = tmp[3];
}
}
sprintf( buffer, "%svideo/%s/uc%04d.tga", gamedir, s_base, frame );
WriteTGA( buffer, resampled, s_resample_width, s_resample_height );
}
#endif
}
else if ( s_compression_method == BTC_COMPRESSION )
{
error = BTCCompressFrame( resampled, compressed );
sumError += error;
if ( error > maxError )
maxError = error;
printf( " (error = %f)\n", error );
fwrite( compressed, 1, 2 * sizeof( long ) * ( s_resample_width / 4 ) * ( s_resample_height / 4 ), output );
#if OUTPUT_TGAS
{
int x, y;
unsigned char *uncompressed;
char buffer[1000];
uncompressed = malloc( sizeof( unsigned char ) * 4 * s_resample_width * s_resample_height );
BTCDecompressFrame( compressed, uncompressed );
for ( y = 0; y < s_resample_height/2; y++ )
{
for ( x = 0; x < s_resample_width; x++ )
{
unsigned char tmp[4];
tmp[0] = uncompressed[(s_resample_height-1-y)*s_resample_width*4 + x*4 + 0];
tmp[1] = uncompressed[(s_resample_height-1-y)*s_resample_width*4 + x*4 + 1];
tmp[2] = uncompressed[(s_resample_height-1-y)*s_resample_width*4 + x*4 + 2];
tmp[3] = uncompressed[(s_resample_height-1-y)*s_resample_width*4 + x*4 + 3];
uncompressed[(s_resample_height-1-y)*s_resample_width*4 + x*4 + 0] = uncompressed[y*s_resample_width*4 + x*4 + 0];
uncompressed[(s_resample_height-1-y)*s_resample_width*4 + x*4 + 1] = uncompressed[y*s_resample_width*4 + x*4 + 1];
uncompressed[(s_resample_height-1-y)*s_resample_width*4 + x*4 + 2] = uncompressed[y*s_resample_width*4 + x*4 + 2];
uncompressed[(s_resample_height-1-y)*s_resample_width*4 + x*4 + 3] = uncompressed[y*s_resample_width*4 + x*4 + 3];
uncompressed[y*s_resample_width*4 + x*4 + 0] = tmp[0];
uncompressed[y*s_resample_width*4 + x*4 + 1] = tmp[1];
uncompressed[y*s_resample_width*4 + x*4 + 2] = tmp[2];
uncompressed[y*s_resample_width*4 + x*4 + 3] = tmp[3];
}
}
sprintf( buffer, "%svideo/%s/btc%04d.tga", gamedir, s_base, frame );
WriteTGA( buffer, uncompressed, s_resample_width, s_resample_height );
free( uncompressed );
}
#endif
}
WriteSound( output, frame );
free (in.data);
}
stop = clock();
printf ("\n");
printf ("Total size: %i\n", ftell( output ) );
printf ("Average error: %f\n", sumError / ( frame - startframe ) );
printf ("Max error: %f\n", maxError );
fseconds = ( stop - start ) / 1000.0f;
minutes = fseconds / 60;
remSeconds = fseconds - minutes * 60;
printf ("Total time: %d s (%d m %d s)\n", ( int ) fseconds, minutes, remSeconds );
printf ("Time/frame: %.2f seconds\n", fseconds / ( frame - startframe ) );
fclose (output);
if ( s_soundtrack )
{
free( s_soundtrack );
s_soundtrack = 0;
}
}