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vdr/dvbspu.c

510 lines
13 KiB
C

/*
* SPU decoder for DVB devices
*
* Copyright (C) 2001.2002 Andreas Schultz <aschultz@warp10.net>
*
* This code is distributed under the terms and conditions of the
* GNU GENERAL PUBLIC LICENSE. See the file COPYING for details.
*
* parts of this file are derived from the OMS program.
*
* $Id: dvbspu.c 1.4 2003/08/15 13:04:39 kls Exp $
*/
#include <assert.h>
#include <string.h>
#include <inttypes.h>
#include <math.h>
#include "osd.h"
#include "osdbase.h"
#include "device.h"
#include "dvbspu.h"
/*
* cDvbSpubitmap:
*
* this is a bitmap of the full screen and two palettes
* the normal palette for the background and the highlight palette
*
* Inputs:
* - a SPU rle encoded image on creation, which will be decoded into
* the full screen indexed bitmap
*
* Output:
* - a minimal sized cDvbSpuBitmap a given palette, the indexed bitmap
* will be scanned to get the smallest possible resulting bitmap considering
* transparencies
*/
// #define SPUDEBUG
#ifdef SPUDEBUG
#define DEBUG(format, args...) printf (format, ## args)
#else
#define DEBUG(format, args...)
#endif
// --- cDvbSpuPalette----------------------------------
void cDvbSpuPalette::setPalette(const uint32_t * pal)
{
for (int i = 0; i < 16; i++)
palette[i] = yuv2rgb(pal[i]);
}
// --- cDvbSpuBitmap --------------------------------------------
#define setMin(a, b) if (a > b) a = b
#define setMax(a, b) if (a < b) a = b
#define spuXres 720
#define spuYres 576
#define revRect(r1, r2) { r1.x1 = r2.x2; r1.y1 = r2.y2; r1.x2 = r2.x1; r1.y2 = r2.y1; }
cDvbSpuBitmap::cDvbSpuBitmap(sDvbSpuRect size,
uint8_t * fodd, uint8_t * eodd,
uint8_t * feven, uint8_t * eeven)
{
if (size.x1 < 0 || size.y1 < 0 || size.x2 >= spuXres
|| size.y2 >= spuYres)
throw;
bmpsize = size;
revRect(minsize[0], size);
revRect(minsize[1], size);
revRect(minsize[2], size);
revRect(minsize[3], size);
if (!(bmp = new uint8_t[spuXres * spuYres * sizeof(uint8_t)]))
throw;
memset(bmp, 0, spuXres * spuYres * sizeof(uint8_t));
putFieldData(0, fodd, eodd);
putFieldData(1, feven, eeven);
}
cDvbSpuBitmap::~cDvbSpuBitmap()
{
delete[]bmp;
}
cBitmap *cDvbSpuBitmap::getBitmap(const aDvbSpuPalDescr paldescr,
const cDvbSpuPalette & pal,
sDvbSpuRect & size) const
{
int h = size.height();
int w = size.width();
if (size.y1 + h >= spuYres)
h = spuYres - size.y1 - 1;
if (size.x1 + w >= spuXres)
w = spuXres - size.x1 - 1;
if (w & 0x03)
w += 4 - (w & 0x03);
cBitmap *ret = new cBitmap(w, h, 2, true);
// set the palette
for (int i = 0; i < 4; i++) {
uint32_t color =
pal.getColor(paldescr[i].index, paldescr[i].trans);
ret->SetColor(i, (eDvbColor) color);
}
// set the content
for (int yp = 0; yp < h; yp++) {
for (int xp = 0; xp < w; xp++) {
uint8_t idx = bmp[(size.y1 + yp) * spuXres + size.x1 + xp];
ret->SetIndex(xp, yp, idx);
}
}
return ret;
}
// find the minimum non-transparent area
bool cDvbSpuBitmap::getMinSize(const aDvbSpuPalDescr paldescr,
sDvbSpuRect & size) const
{
bool ret = false;
for (int i = 0; i < 4; i++) {
if (paldescr[i].trans != 0) {
if (!ret)
size = minsize[i];
else {
setMin(size.x1, minsize[i].x1);
setMin(size.y1, minsize[i].y1);
setMax(size.x2, minsize[i].x2);
setMax(size.y2, minsize[i].y2);
}
ret = true;
}
}
if (ret)
DEBUG("MinSize: (%d, %d) x (%d, %d)\n",
size.x1, size.y1, size.x2, size.y2);
return ret;
}
void cDvbSpuBitmap::putPixel(int xp, int yp, int len, uint8_t colorid)
{
memset(bmp + spuXres * yp + xp, colorid, len);
setMin(minsize[colorid].x1, xp);
setMin(minsize[colorid].y1, yp);
setMax(minsize[colorid].x2, xp + len - 1);
setMax(minsize[colorid].y2, yp + len - 1);
}
static uint8_t getBits(uint8_t * &data, uint8_t & bitf)
{
uint8_t ret = *data;
if (bitf)
ret >>= 4;
else
data++;
bitf ^= 1;
return (ret & 0xf);
}
void cDvbSpuBitmap::putFieldData(int field, uint8_t * data, uint8_t * endp)
{
int xp = bmpsize.x1;
int yp = bmpsize.y1 + field;
uint8_t bitf = 1;
while (data < endp) {
uint16_t vlc = getBits(data, bitf);
if (vlc < 0x0004) {
vlc = (vlc << 4) | getBits(data, bitf);
if (vlc < 0x0010) {
vlc = (vlc << 4) | getBits(data, bitf);
if (vlc < 0x0040) {
vlc = (vlc << 4) | getBits(data, bitf);
}
}
}
uint8_t color = vlc & 0x03;
int len = vlc >> 2;
// if len == 0 -> end sequence - fill to end of line
len = len ? len : bmpsize.x2 - xp + 1;
putPixel(xp, yp, len, color);
xp += len;
if (xp > bmpsize.x2) {
// nextLine
if (!bitf)
data++;
bitf = 1;
xp = bmpsize.x1;
yp += 2;
if (yp > bmpsize.y2)
return;
}
}
}
// --- cDvbSpuDecoder-----------------------------
#define CMD_SPU_MENU 0x00
#define CMD_SPU_SHOW 0x01
#define CMD_SPU_HIDE 0x02
#define CMD_SPU_SET_PALETTE 0x03
#define CMD_SPU_SET_ALPHA 0x04
#define CMD_SPU_SET_SIZE 0x05
#define CMD_SPU_SET_PXD_OFFSET 0x06
#define CMD_SPU_EOF 0xff
#define spuU32(i) ((spu[i] << 8) + spu[i+1])
cDvbSpuDecoder::cDvbSpuDecoder()
{
clean = true;
scaleMode = eSpuNormal;
spu = NULL;
osd = NULL;
spubmp = NULL;
}
cDvbSpuDecoder::~cDvbSpuDecoder()
{
delete spubmp;
delete spu;
delete osd;
}
void cDvbSpuDecoder::processSPU(uint32_t pts, uint8_t * buf)
{
setTime(pts);
DEBUG("SPU pushData: pts: %d\n", pts);
delete spubmp;
spubmp = NULL;
delete[]spu;
spu = buf;
spupts = pts;
DCSQ_offset = cmdOffs();
prev_DCSQ_offset = 0;
clean = true;
}
void cDvbSpuDecoder::setScaleMode(cSpuDecoder::eScaleMode ScaleMode)
{
scaleMode = ScaleMode;
}
void cDvbSpuDecoder::setPalette(uint32_t * pal)
{
palette.setPalette(pal);
}
void cDvbSpuDecoder::setHighlight(uint16_t sx, uint16_t sy,
uint16_t ex, uint16_t ey,
uint32_t palette)
{
aDvbSpuPalDescr pld;
for (int i = 0; i < 4; i++) {
pld[i].index = 0xf & (palette >> (16 + 4 * i));
pld[i].trans = 0xf & (palette >> (4 * i));
}
bool ne = hlpsize.x1 != sx || hlpsize.y1 != sy ||
hlpsize.x2 != ex || hlpsize.y2 != ey ||
pld[0] != hlpDescr[0] || pld[1] != hlpDescr[1] ||
pld[2] != hlpDescr[2] || pld[3] != hlpDescr[3];
if (ne) {
DEBUG("setHighlight: %d,%d x %d,%d\n", sx, sy, ex, ey);
hlpsize.x1 = sx;
hlpsize.y1 = sy;
hlpsize.x2 = ex;
hlpsize.y2 = ey;
memcpy(hlpDescr, pld, sizeof(aDvbSpuPalDescr));
highlight = true;
clean = false;
}
}
void cDvbSpuDecoder::clearHighlight(void)
{
clean &= !highlight;
highlight = false;
}
int cDvbSpuDecoder::ScaleYcoord(int value)
{
if (scaleMode == eSpuLetterBox) {
int offset = cDevice::PrimaryDevice()->GetVideoSystem() == vsPAL ? 72 : 60;
return lround((value * 3.0) / 4.0) + offset;
}
else
return value;
}
int cDvbSpuDecoder::ScaleYres(int value)
{
if (scaleMode == eSpuLetterBox)
return lround((value * 3.0) / 4.0);
else
return value;
}
void cDvbSpuDecoder::DrawBmp(sDvbSpuRect & size, cBitmap * bmp)
{
osd->Create(size.x1, size.y1, size.width(), size.height(), 2, false);
osd->SetBitmap(size.x1, size.y1, *bmp);
delete bmp;
}
void cDvbSpuDecoder::Draw(void)
{
Hide();
if (!spubmp)
return;
cBitmap *fg = NULL;
cBitmap *bg = NULL;
sDvbSpuRect bgsize;
sDvbSpuRect hlsize;
hlsize.x1 = hlpsize.x1;
hlsize.y1 = ScaleYcoord(hlpsize.y1);
hlsize.x2 = hlpsize.x2;
hlsize.y2 = ScaleYcoord(hlpsize.y2);
if (highlight)
fg = spubmp->getBitmap(hlpDescr, palette, hlsize);
if (spubmp->getMinSize(palDescr, bgsize)) {
bg = spubmp->getBitmap(palDescr, palette, bgsize);
if (scaleMode == eSpuLetterBox) {
// the coordinates have to be modified for letterbox
int y1 = ScaleYres(bgsize.y1) + bgsize.height();
bgsize.y2 = y1 + bgsize.height();
bgsize.y1 = y1;
}
}
if (bg || fg) {
if (osd == NULL)
if ((osd = cOsd::OpenRaw(0, 0)) == NULL) {
dsyslog("OpenRaw failed\n");
return;
}
if (fg)
DrawBmp(hlsize, fg);
if (bg)
DrawBmp(bgsize, bg);
osd->Flush();
}
clean = true;
}
void cDvbSpuDecoder::Hide(void)
{
delete osd;
osd = NULL;
}
void cDvbSpuDecoder::Empty(void)
{
Hide();
delete spubmp;
spubmp = NULL;
delete[]spu;
spu = NULL;
clearHighlight();
clean = true;
}
int cDvbSpuDecoder::setTime(uint32_t pts)
{
if (!spu)
return 0;
if (spu && !clean)
Draw();
while (DCSQ_offset != prev_DCSQ_offset) { /* Display Control Sequences */
int i = DCSQ_offset;
state = spNONE;
uint32_t exec_time = spupts + spuU32(i) * 1024;
if ((pts != 0) && (exec_time > pts))
return 0;
DEBUG("offs = %d, rel = %d, time = %d, pts = %d, diff = %d\n",
i, spuU32(i) * 1024, exec_time, pts, exec_time - pts);
if (pts != 0) {
uint16_t feven = 0;
uint16_t fodd = 0;
i += 2;
prev_DCSQ_offset = DCSQ_offset;
DCSQ_offset = spuU32(i);
DEBUG("offs = %d, DCSQ = %d, prev_DCSQ = %d\n",
i, DCSQ_offset, prev_DCSQ_offset);
i += 2;
while (spu[i] != CMD_SPU_EOF) { // Command Sequence
switch (spu[i]) {
case CMD_SPU_SHOW: // show subpicture
DEBUG("\tshow subpicture\n");
state = spSHOW;
i++;
break;
case CMD_SPU_HIDE: // hide subpicture
DEBUG("\thide subpicture\n");
state = spHIDE;
i++;
break;
case CMD_SPU_SET_PALETTE: // CLUT
palDescr[0].index = spu[i + 2] & 0xf;
palDescr[1].index = spu[i + 2] >> 4;
palDescr[2].index = spu[i + 1] & 0xf;
palDescr[3].index = spu[i + 1] >> 4;
i += 3;
break;
case CMD_SPU_SET_ALPHA: // transparency palette
palDescr[0].trans = spu[i + 2] & 0xf;
palDescr[1].trans = spu[i + 2] >> 4;
palDescr[2].trans = spu[i + 1] & 0xf;
palDescr[3].trans = spu[i + 1] >> 4;
i += 3;
break;
case CMD_SPU_SET_SIZE: // image coordinates
size.x1 = (spu[i + 1] << 4) | (spu[i + 2] >> 4);
size.x2 = ((spu[i + 2] & 0x0f) << 8) | spu[i + 3];
size.y1 = (spu[i + 4] << 4) | (spu[i + 5] >> 4);
size.y2 = ((spu[i + 5] & 0x0f) << 8) | spu[i + 6];
DEBUG("\t(%d, %d) x (%d, %d)\n",
size.x1, size.y1, size.x2, size.y2);
i += 7;
break;
case CMD_SPU_SET_PXD_OFFSET: // image 1 / image 2 offsets
fodd = spuU32(i + 1);
feven = spuU32(i + 3);
DEBUG("\todd = %d even = %d\n", fodd, feven);
i += 5;
break;
case CMD_SPU_MENU:
DEBUG("\tspu menu\n");
state = spMENU;
i++;
break;
default:
esyslog("invalid sequence in control header (%.2x)\n",
spu[i]);
assert(0);
i++;
break;
}
}
if (fodd != 0 && feven != 0) {
delete spubmp;
spubmp = new cDvbSpuBitmap(size, spu + fodd, spu + feven,
spu + feven, spu + cmdOffs());
}
} else if (!clean)
state = spSHOW;
if (state == spSHOW || state == spMENU)
Draw();
if (state == spHIDE)
Hide();
if (pts == 0)
return 0;
}
return 1;
}