quakequest/Projects/Android/jni/dpvsimpledecode.c
2019-05-30 06:57:57 +01:00

656 lines
17 KiB
C

#include "quakedef.h"
#include "dpvsimpledecode.h"
#define HZREADERROR_OK 0
#define HZREADERROR_EOF 1
#define HZREADERROR_MALLOCFAILED 2
//#define HZREADBLOCKSIZE 16000
#define HZREADBLOCKSIZE 1048576
typedef struct hz_bitstream_read_s
{
qfile_t *file;
int endoffile;
}
hz_bitstream_read_t;
typedef struct hz_bitstream_readblock_s
{
struct hz_bitstream_readblock_s *next;
unsigned int size;
unsigned char data[HZREADBLOCKSIZE];
}
hz_bitstream_readblock_t;
typedef struct hz_bitstream_readblocks_s
{
hz_bitstream_readblock_t *blocks;
hz_bitstream_readblock_t *current;
unsigned int position;
unsigned int store;
int count;
}
hz_bitstream_readblocks_t;
static hz_bitstream_read_t *hz_bitstream_read_open(char *filename)
{
qfile_t *file;
hz_bitstream_read_t *stream;
if ((file = FS_OpenVirtualFile(filename, false)))
{
stream = (hz_bitstream_read_t *)Z_Malloc(sizeof(hz_bitstream_read_t));
memset(stream, 0, sizeof(*stream));
stream->file = file;
return stream;
}
else
return NULL;
}
static void hz_bitstream_read_close(hz_bitstream_read_t *stream)
{
if (stream)
{
FS_Close(stream->file);
Z_Free(stream);
}
}
static hz_bitstream_readblocks_t *hz_bitstream_read_blocks_new(void)
{
hz_bitstream_readblocks_t *blocks;
blocks = (hz_bitstream_readblocks_t *)Z_Malloc(sizeof(hz_bitstream_readblocks_t));
if (blocks == NULL)
return NULL;
memset(blocks, 0, sizeof(hz_bitstream_readblocks_t));
return blocks;
}
static void hz_bitstream_read_blocks_free(hz_bitstream_readblocks_t *blocks)
{
hz_bitstream_readblock_t *b, *n;
if (blocks == NULL)
return;
for (b = blocks->blocks;b;b = n)
{
n = b->next;
Z_Free(b);
}
Z_Free(blocks);
}
static void hz_bitstream_read_flushbits(hz_bitstream_readblocks_t *blocks)
{
blocks->store = 0;
blocks->count = 0;
}
static int hz_bitstream_read_blocks_read(hz_bitstream_readblocks_t *blocks, hz_bitstream_read_t *stream, unsigned int size)
{
int s;
hz_bitstream_readblock_t *b, *p;
s = size;
p = NULL;
b = blocks->blocks;
while (s > 0)
{
if (b == NULL)
{
b = (hz_bitstream_readblock_t *)Z_Malloc(sizeof(hz_bitstream_readblock_t));
if (b == NULL)
return HZREADERROR_MALLOCFAILED;
b->next = NULL;
b->size = 0;
if (p != NULL)
p->next = b;
else
blocks->blocks = b;
}
if (s > HZREADBLOCKSIZE)
b->size = HZREADBLOCKSIZE;
else
b->size = s;
s -= b->size;
if (FS_Read(stream->file, b->data, b->size) != (fs_offset_t)b->size)
{
stream->endoffile = 1;
break;
}
p = b;
b = b->next;
}
while (b)
{
b->size = 0;
b = b->next;
}
blocks->current = blocks->blocks;
blocks->position = 0;
hz_bitstream_read_flushbits(blocks);
if (stream->endoffile)
return HZREADERROR_EOF;
return HZREADERROR_OK;
}
static unsigned int hz_bitstream_read_blocks_getbyte(hz_bitstream_readblocks_t *blocks)
{
while (blocks->current != NULL && blocks->position >= blocks->current->size)
{
blocks->position = 0;
blocks->current = blocks->current->next;
}
if (blocks->current == NULL)
return 0;
return blocks->current->data[blocks->position++];
}
static int hz_bitstream_read_bit(hz_bitstream_readblocks_t *blocks)
{
if (!blocks->count)
{
blocks->count += 8;
blocks->store <<= 8;
blocks->store |= hz_bitstream_read_blocks_getbyte(blocks) & 0xFF;
}
blocks->count--;
return (blocks->store >> blocks->count) & 1;
}
static unsigned int hz_bitstream_read_bits(hz_bitstream_readblocks_t *blocks, int size)
{
unsigned int num = 0;
// we can only handle about 24 bits at a time safely
// (there might be up to 7 bits more than we need in the bit store)
if (size > 24)
{
size -= 8;
num |= hz_bitstream_read_bits(blocks, 8) << size;
}
while (blocks->count < size)
{
blocks->count += 8;
blocks->store <<= 8;
blocks->store |= hz_bitstream_read_blocks_getbyte(blocks) & 0xFF;
}
blocks->count -= size;
num |= (blocks->store >> blocks->count) & ((1 << size) - 1);
return num;
}
static unsigned int hz_bitstream_read_byte(hz_bitstream_readblocks_t *blocks)
{
return hz_bitstream_read_blocks_getbyte(blocks);
}
static unsigned int hz_bitstream_read_short(hz_bitstream_readblocks_t *blocks)
{
return (hz_bitstream_read_byte(blocks) << 8)
| (hz_bitstream_read_byte(blocks));
}
static unsigned int hz_bitstream_read_int(hz_bitstream_readblocks_t *blocks)
{
return (hz_bitstream_read_byte(blocks) << 24)
| (hz_bitstream_read_byte(blocks) << 16)
| (hz_bitstream_read_byte(blocks) << 8)
| (hz_bitstream_read_byte(blocks));
}
static void hz_bitstream_read_bytes(hz_bitstream_readblocks_t *blocks, void *outdata, unsigned int size)
{
unsigned char *out;
out = (unsigned char *)outdata;
while (size--)
*out++ = hz_bitstream_read_byte(blocks);
}
#define BLOCKSIZE 8
typedef struct dpvsimpledecodestream_s
{
hz_bitstream_read_t *bitstream;
hz_bitstream_readblocks_t *framedatablocks;
int error;
double info_framerate;
unsigned int info_frames;
unsigned int info_imagewidth;
unsigned int info_imageheight;
unsigned int info_imagebpp;
unsigned int info_imageRloss;
unsigned int info_imageRmask;
unsigned int info_imageRshift;
unsigned int info_imageGloss;
unsigned int info_imageGmask;
unsigned int info_imageGshift;
unsigned int info_imageBloss;
unsigned int info_imageBmask;
unsigned int info_imageBshift;
unsigned int info_imagesize;
double info_aspectratio;
// current video frame (needed because of delta compression)
int videoframenum;
// current video frame data (needed because of delta compression)
unsigned int *videopixels;
// channel the sound file is being played on
int sndchan;
}
dpvsimpledecodestream_t;
static int dpvsimpledecode_setpixelformat(dpvsimpledecodestream_t *s, unsigned int Rmask, unsigned int Gmask, unsigned int Bmask, unsigned int bytesperpixel)
{
int Rshift, Rbits, Gshift, Gbits, Bshift, Bbits;
if (!Rmask)
{
s->error = DPVSIMPLEDECODEERROR_INVALIDRMASK;
return s->error;
}
if (!Gmask)
{
s->error = DPVSIMPLEDECODEERROR_INVALIDGMASK;
return s->error;
}
if (!Bmask)
{
s->error = DPVSIMPLEDECODEERROR_INVALIDBMASK;
return s->error;
}
if (Rmask & Gmask || Rmask & Bmask || Gmask & Bmask)
{
s->error = DPVSIMPLEDECODEERROR_COLORMASKSOVERLAP;
return s->error;
}
switch (bytesperpixel)
{
case 2:
if ((Rmask | Gmask | Bmask) > 65536)
{
s->error = DPVSIMPLEDECODEERROR_COLORMASKSEXCEEDBPP;
return s->error;
}
break;
case 4:
break;
default:
s->error = DPVSIMPLEDECODEERROR_UNSUPPORTEDBPP;
return s->error;
}
for (Rshift = 0;!(Rmask & 1);Rshift++, Rmask >>= 1);
for (Gshift = 0;!(Gmask & 1);Gshift++, Gmask >>= 1);
for (Bshift = 0;!(Bmask & 1);Bshift++, Bmask >>= 1);
if (((Rmask + 1) & Rmask) != 0)
{
s->error = DPVSIMPLEDECODEERROR_INVALIDRMASK;
return s->error;
}
if (((Gmask + 1) & Gmask) != 0)
{
s->error = DPVSIMPLEDECODEERROR_INVALIDGMASK;
return s->error;
}
if (((Bmask + 1) & Bmask) != 0)
{
s->error = DPVSIMPLEDECODEERROR_INVALIDBMASK;
return s->error;
}
for (Rbits = 0;Rmask & 1;Rbits++, Rmask >>= 1);
for (Gbits = 0;Gmask & 1;Gbits++, Gmask >>= 1);
for (Bbits = 0;Bmask & 1;Bbits++, Bmask >>= 1);
if (Rbits > 8)
{
Rshift += (Rbits - 8);
Rbits = 8;
}
if (Gbits > 8)
{
Gshift += (Gbits - 8);
Gbits = 8;
}
if (Bbits > 8)
{
Bshift += (Bbits - 8);
Bbits = 8;
}
s->info_imagebpp = bytesperpixel;
s->info_imageRloss = 16 + (8 - Rbits);
s->info_imageGloss = 8 + (8 - Gbits);
s->info_imageBloss = 0 + (8 - Bbits);
s->info_imageRmask = (1 << Rbits) - 1;
s->info_imageGmask = (1 << Gbits) - 1;
s->info_imageBmask = (1 << Bbits) - 1;
s->info_imageRshift = Rshift;
s->info_imageGshift = Gshift;
s->info_imageBshift = Bshift;
s->info_imagesize = s->info_imagewidth * s->info_imageheight * s->info_imagebpp;
return s->error;
}
// opening and closing streams
// opens a stream
void *dpvsimpledecode_open(clvideo_t *video, char *filename, const char **errorstring)
{
dpvsimpledecodestream_t *s;
char t[8], *wavename;
if (errorstring != NULL)
*errorstring = NULL;
s = (dpvsimpledecodestream_t *)Z_Malloc(sizeof(dpvsimpledecodestream_t));
if (s != NULL)
{
s->bitstream = hz_bitstream_read_open(filename);
if (s->bitstream != NULL)
{
// check file identification
s->framedatablocks = hz_bitstream_read_blocks_new();
if (s->framedatablocks != NULL)
{
hz_bitstream_read_blocks_read(s->framedatablocks, s->bitstream, 8);
hz_bitstream_read_bytes(s->framedatablocks, t, 8);
if (!memcmp(t, "DPVideo", 8))
{
// check version number
hz_bitstream_read_blocks_read(s->framedatablocks, s->bitstream, 2);
if (hz_bitstream_read_short(s->framedatablocks) == 1)
{
hz_bitstream_read_blocks_read(s->framedatablocks, s->bitstream, 12);
s->info_imagewidth = hz_bitstream_read_short(s->framedatablocks);
s->info_imageheight = hz_bitstream_read_short(s->framedatablocks);
s->info_framerate = (double) hz_bitstream_read_int(s->framedatablocks) * (1.0 / 65536.0);
s->info_aspectratio = (double)s->info_imagewidth / (double)s->info_imageheight;
if (s->info_framerate > 0.0)
{
s->videopixels = (unsigned int *)Z_Malloc(s->info_imagewidth * s->info_imageheight * sizeof(*s->videopixels));
if (s->videopixels != NULL)
{
size_t namelen;
namelen = strlen(filename) + 10;
wavename = (char *)Z_Malloc(namelen);
if (wavename)
{
sfx_t* sfx;
FS_StripExtension(filename, wavename, namelen);
strlcat(wavename, ".wav", namelen);
sfx = S_PrecacheSound (wavename, false, false);
if (sfx != NULL)
s->sndchan = S_StartSound (-1, 0, sfx, vec3_origin, 1.0f, 0);
else
s->sndchan = -1;
Z_Free(wavename);
}
// all is well...
// set the module functions
s->videoframenum = -10000;
video->close = dpvsimpledecode_close;
video->getwidth = dpvsimpledecode_getwidth;
video->getheight = dpvsimpledecode_getheight;
video->getframerate = dpvsimpledecode_getframerate;
video->decodeframe = dpvsimpledecode_video;
video->getaspectratio = dpvsimpledecode_getaspectratio;
return s;
}
else if (errorstring != NULL)
*errorstring = "unable to allocate video image buffer";
}
else if (errorstring != NULL)
*errorstring = "error in video info chunk";
}
else if (errorstring != NULL)
*errorstring = "read error";
}
else if (errorstring != NULL)
*errorstring = "not a dpvideo file";
hz_bitstream_read_blocks_free(s->framedatablocks);
}
else if (errorstring != NULL)
*errorstring = "unable to allocate memory for reading buffer";
hz_bitstream_read_close(s->bitstream);
}
else if (errorstring != NULL)
*errorstring = "unable to open file";
Z_Free(s);
}
else if (errorstring != NULL)
*errorstring = "unable to allocate memory for stream info structure";
return NULL;
}
// closes a stream
void dpvsimpledecode_close(void *stream)
{
dpvsimpledecodestream_t *s = (dpvsimpledecodestream_t *)stream;
if (s == NULL)
return;
if (s->videopixels)
Z_Free(s->videopixels);
if (s->sndchan != -1)
S_StopChannel (s->sndchan, true, true);
if (s->framedatablocks)
hz_bitstream_read_blocks_free(s->framedatablocks);
if (s->bitstream)
hz_bitstream_read_close(s->bitstream);
Z_Free(s);
}
// utilitarian functions
// returns the current error number for the stream, and resets the error
// number to DPVSIMPLEDECODEERROR_NONE
// if the supplied string pointer variable is not NULL, it will be set to the
// error message
int dpvsimpledecode_error(void *stream, const char **errorstring)
{
dpvsimpledecodestream_t *s = (dpvsimpledecodestream_t *)stream;
int e;
e = s->error;
s->error = 0;
if (errorstring)
{
switch (e)
{
case DPVSIMPLEDECODEERROR_NONE:
*errorstring = "no error";
break;
case DPVSIMPLEDECODEERROR_EOF:
*errorstring = "end of file reached (this is not an error)";
break;
case DPVSIMPLEDECODEERROR_READERROR:
*errorstring = "read error (corrupt or incomplete file)";
break;
case DPVSIMPLEDECODEERROR_SOUNDBUFFERTOOSMALL:
*errorstring = "sound buffer is too small for decoding frame (please allocate it as large as dpvsimpledecode_getneededsoundbufferlength suggests)";
break;
case DPVSIMPLEDECODEERROR_INVALIDRMASK:
*errorstring = "invalid red bits mask";
break;
case DPVSIMPLEDECODEERROR_INVALIDGMASK:
*errorstring = "invalid green bits mask";
break;
case DPVSIMPLEDECODEERROR_INVALIDBMASK:
*errorstring = "invalid blue bits mask";
break;
case DPVSIMPLEDECODEERROR_COLORMASKSOVERLAP:
*errorstring = "color bit masks overlap";
break;
case DPVSIMPLEDECODEERROR_COLORMASKSEXCEEDBPP:
*errorstring = "color masks too big for specified bytes per pixel";
break;
case DPVSIMPLEDECODEERROR_UNSUPPORTEDBPP:
*errorstring = "unsupported bytes per pixel (must be 2 for 16bit, or 4 for 32bit)";
break;
default:
*errorstring = "unknown error";
break;
}
}
return e;
}
// returns the width of the image data
unsigned int dpvsimpledecode_getwidth(void *stream)
{
dpvsimpledecodestream_t *s = (dpvsimpledecodestream_t *)stream;
return s->info_imagewidth;
}
// returns the height of the image data
unsigned int dpvsimpledecode_getheight(void *stream)
{
dpvsimpledecodestream_t *s = (dpvsimpledecodestream_t *)stream;
return s->info_imageheight;
}
// returns the framerate of the stream
double dpvsimpledecode_getframerate(void *stream)
{
dpvsimpledecodestream_t *s = (dpvsimpledecodestream_t *)stream;
return s->info_framerate;
}
// return aspect ratio of the stream
double dpvsimpledecode_getaspectratio(void *stream)
{
dpvsimpledecodestream_t *s = (dpvsimpledecodestream_t *)stream;
return s->info_aspectratio;
}
static int dpvsimpledecode_convertpixels(dpvsimpledecodestream_t *s, void *imagedata, int imagebytesperrow)
{
unsigned int a, x, y, width, height;
unsigned int Rloss, Rmask, Rshift, Gloss, Gmask, Gshift, Bloss, Bmask, Bshift;
unsigned int *in;
width = s->info_imagewidth;
height = s->info_imageheight;
Rloss = s->info_imageRloss;
Rmask = s->info_imageRmask;
Rshift = s->info_imageRshift;
Gloss = s->info_imageGloss;
Gmask = s->info_imageGmask;
Gshift = s->info_imageGshift;
Bloss = s->info_imageBloss;
Bmask = s->info_imageBmask;
Bshift = s->info_imageBshift;
in = s->videopixels;
if (s->info_imagebpp == 4)
{
unsigned int *outrow;
for (y = 0;y < height;y++)
{
outrow = (unsigned int *)((unsigned char *)imagedata + y * imagebytesperrow);
for (x = 0;x < width;x++)
{
a = *in++;
outrow[x] = (((a >> Rloss) & Rmask) << Rshift) | (((a >> Gloss) & Gmask) << Gshift) | (((a >> Bloss) & Bmask) << Bshift);
}
}
}
else
{
unsigned short *outrow;
for (y = 0;y < height;y++)
{
outrow = (unsigned short *)((unsigned char *)imagedata + y * imagebytesperrow);
if (Rloss == 19 && Gloss == 10 && Bloss == 3 && Rshift == 11 && Gshift == 5 && Bshift == 0)
{
// optimized
for (x = 0;x < width;x++)
{
a = *in++;
outrow[x] = ((a >> 8) & 0xF800) | ((a >> 5) & 0x07E0) | ((a >> 3) & 0x001F);
}
}
else
{
for (x = 0;x < width;x++)
{
a = *in++;
outrow[x] = (((a >> Rloss) & Rmask) << Rshift) | (((a >> Gloss) & Gmask) << Gshift) | (((a >> Bloss) & Bmask) << Bshift);
}
}
}
}
return s->error;
}
static int dpvsimpledecode_decompressimage(dpvsimpledecodestream_t *s)
{
int i, a, b, colors, g, x1, y1, bw, bh, width, height, palettebits;
unsigned int palette[256], *outrow, *out;
g = BLOCKSIZE;
width = s->info_imagewidth;
height = s->info_imageheight;
for (y1 = 0;y1 < height;y1 += g)
{
outrow = s->videopixels + y1 * width;
bh = g;
if (y1 + bh > height)
bh = height - y1;
for (x1 = 0;x1 < width;x1 += g)
{
out = outrow + x1;
bw = g;
if (x1 + bw > width)
bw = width - x1;
if (hz_bitstream_read_bit(s->framedatablocks))
{
// updated block
palettebits = hz_bitstream_read_bits(s->framedatablocks, 3);
colors = 1 << palettebits;
for (i = 0;i < colors;i++)
palette[i] = hz_bitstream_read_bits(s->framedatablocks, 24);
if (palettebits)
{
for (b = 0;b < bh;b++, out += width)
for (a = 0;a < bw;a++)
out[a] = palette[hz_bitstream_read_bits(s->framedatablocks, palettebits)];
}
else
{
for (b = 0;b < bh;b++, out += width)
for (a = 0;a < bw;a++)
out[a] = palette[0];
}
}
}
}
return s->error;
}
// decodes a video frame to the supplied output pixels
int dpvsimpledecode_video(void *stream, void *imagedata, unsigned int Rmask, unsigned int Gmask, unsigned int Bmask, unsigned int bytesperpixel, int imagebytesperrow)
{
dpvsimpledecodestream_t *s = (dpvsimpledecodestream_t *)stream;
unsigned int framedatasize;
char t[4];
s->error = DPVSIMPLEDECODEERROR_NONE;
if (dpvsimpledecode_setpixelformat(s, Rmask, Gmask, Bmask, bytesperpixel))
return s->error;
hz_bitstream_read_blocks_read(s->framedatablocks, s->bitstream, 8);
hz_bitstream_read_bytes(s->framedatablocks, t, 4);
if (memcmp(t, "VID0", 4))
{
if (t[0] == 0)
return (s->error = DPVSIMPLEDECODEERROR_EOF);
else
return (s->error = DPVSIMPLEDECODEERROR_READERROR);
}
framedatasize = hz_bitstream_read_int(s->framedatablocks);
hz_bitstream_read_blocks_read(s->framedatablocks, s->bitstream, framedatasize);
if (dpvsimpledecode_decompressimage(s))
return s->error;
dpvsimpledecode_convertpixels(s, imagedata, imagebytesperrow);
return s->error;
}