mpv/libvo/mga_common.c

338 lines
8.6 KiB
C

#include "fastmemcpy.h"
#include "../mmx_defs.h"
#include "../postproc/rgb2rgb.h"
// mga_vid drawing functions
static int mga_next_frame=0;
static mga_vid_config_t mga_vid_config;
static uint8_t *vid_data, *frames[4];
static int f = -1;
static void draw_alpha(int x0,int y0, int w,int h, unsigned char* src, unsigned char *srca, int stride){
int x,y;
uint32_t bespitch = (mga_vid_config.src_width + 31) & ~31;
switch(mga_vid_config.format){
case MGA_VID_FORMAT_YV12:
case MGA_VID_FORMAT_IYUV:
case MGA_VID_FORMAT_I420:
vo_draw_alpha_yv12(w,h,src,srca,stride,vid_data+bespitch*y0+x0,bespitch);
break;
case MGA_VID_FORMAT_YUY2:
vo_draw_alpha_yuy2(w,h,src,srca,stride,vid_data+2*(bespitch*y0+x0),2*bespitch);
break;
case MGA_VID_FORMAT_UYVY:
vo_draw_alpha_yuy2(w,h,src,srca,stride,vid_data+2*(bespitch*y0+x0)+1,2*bespitch);
break;
}
}
static int mga_set_video_eq( const vidix_video_eq_t *info)
{
uint32_t luma;
float factor = 256.0 / 2000;
luma = ((int)(info->brightness * factor) << 16) +
((int)(info->contrast * factor) & 0xFFFF);
if (ioctl(f,MGA_VID_SET_LUMA,luma)) {
perror("Error in mga_vid_config ioctl()");
printf("Could not set luma values in the kernel module!\n");
return -1;
}
return 0;
}
static int mga_get_video_eq( vidix_video_eq_t *info)
{
uint32_t luma;
float factor = 2000.0 / 256;
if (ioctl(f,MGA_VID_GET_LUMA,&luma)) {
perror("Error in mga_vid_config ioctl()");
printf("Could not get luma values from the kernel module!\n");
return -1;
}
info->brightness = (luma >> 16) * factor;
info->cap |= VEQ_CAP_BRIGHTNESS;
info->contrast = (luma & 0xFFFF) * factor;
info->cap |= VEQ_CAP_CONTRAST;
return 0;
}
//static void
//write_slice_g200(uint8_t *y,uint8_t *cr, uint8_t *cb,uint32_t slice_num)
static void
draw_slice_g200(uint8_t *image[], int stride[], int width,int height,int x,int y)
{
uint8_t *src;
uint8_t *src2;
uint8_t *dest;
uint32_t bespitch,h,w;
bespitch = (mga_vid_config.src_width + 31) & ~31;
dest = vid_data + bespitch*y + x;
mem2agpcpy_pic(dest, image[0], width, height, bespitch, stride[0]);
width/=2;height/=2;x/=2;y/=2;
dest = vid_data + bespitch*mga_vid_config.src_height + bespitch*y + 2*x;
interleaveBytes(image[1],image[2],dest,
width, height,
stride[1], stride[2], bespitch);
}
static void
draw_slice_g400(uint8_t *image[], int stride[], int w,int h,int x,int y)
{
uint8_t *src;
uint8_t *dest;
uint8_t *dest2;
uint32_t bespitch,bespitch2;
int i;
bespitch = (mga_vid_config.src_width + 31) & ~31;
bespitch2 = bespitch/2;
dest = vid_data + bespitch * y + x;
mem2agpcpy_pic(dest, image[0], w, h, bespitch, stride[0]);
w/=2;h/=2;x/=2;y/=2;
dest = vid_data + bespitch*mga_vid_config.src_height + bespitch2 * y + x;
dest2= dest + bespitch2*mga_vid_config.src_height / 2;
if(mga_vid_config.format==MGA_VID_FORMAT_YV12){
// mga_vid's YV12 assumes Y,U,V order (insteda of Y,V,U) :(
mem2agpcpy_pic(dest, image[1], w, h, bespitch2, stride[1]);
mem2agpcpy_pic(dest2,image[2], w, h, bespitch2, stride[2]);
} else {
mem2agpcpy_pic(dest, image[2], w, h, bespitch2, stride[2]);
mem2agpcpy_pic(dest2,image[1], w, h, bespitch2, stride[1]);
}
}
static uint32_t
draw_slice(uint8_t *src[], int stride[], int w,int h,int x,int y)
{
#if 0
printf("vo: %p/%d %p/%d %p/%d %dx%d/%d;%d \n",
src[0],stride[0],
src[1],stride[1],
src[2],stride[2],
w,h,x,y);
#endif
if (mga_vid_config.card_type == MGA_G200)
draw_slice_g200(src,stride,w,h,x,y);
else
draw_slice_g400(src,stride,w,h,x,y);
return 0;
}
static void
vo_mga_flip_page(void)
{
// printf("-- flip to %d --\n",mga_next_frame);
#if 1
ioctl(f,MGA_VID_FSEL,&mga_next_frame);
mga_next_frame=(mga_next_frame+1)%mga_vid_config.num_frames;
vid_data=frames[mga_next_frame];
#endif
}
static void
write_frame_yuy2(uint8_t *y)
{
int len=2*mga_vid_config.src_width;
uint32_t bespitch = (mga_vid_config.src_width + 31) & ~31;
mem2agpcpy_pic(vid_data, y, len, mga_vid_config.src_height, 2*bespitch, len);
}
static uint32_t
draw_frame(uint8_t *src[])
{
switch(mga_vid_config.format){
case MGA_VID_FORMAT_YUY2:
case MGA_VID_FORMAT_UYVY:
write_frame_yuy2(src[0]);break;
}
return 0;
}
static uint32_t
get_image(mp_image_t *mpi){
uint32_t bespitch = (mga_vid_config.src_width + 31) & ~31;
uint32_t bespitch2 = bespitch/2;
// printf("mga: get_image() called\n");
if(mpi->type==MP_IMGTYPE_STATIC && mga_vid_config.num_frames>1) return VO_FALSE; // it is not static
if(mpi->flags&MP_IMGFLAG_READABLE) return VO_FALSE; // slow video ram
if(mga_vid_config.card_type == MGA_G200 && mpi->flags&MP_IMGFLAG_PLANAR) return VO_FALSE;
// printf("width=%d vs. bespitch=%d, flags=0x%X \n",mpi->width,bespitch,mpi->flags);
if((mpi->width==bespitch) ||
(mpi->flags&(MP_IMGFLAG_ACCEPT_STRIDE|MP_IMGFLAG_ACCEPT_WIDTH))){
// we're lucky or codec accepts stride => ok, let's go!
if(mpi->flags&MP_IMGFLAG_PLANAR){
mpi->planes[0]=vid_data;
if(mpi->flags&MP_IMGFLAG_SWAPPED){
mpi->planes[1]=vid_data + bespitch*mga_vid_config.src_height;
mpi->planes[2]=mpi->planes[1] + bespitch2*mga_vid_config.src_height/2;
} else {
mpi->planes[2]=vid_data + bespitch*mga_vid_config.src_height;
mpi->planes[1]=mpi->planes[2] + bespitch2*mga_vid_config.src_height/2;
}
mpi->width=mpi->stride[0]=bespitch;
mpi->stride[1]=mpi->stride[2]=bespitch2;
} else {
mpi->planes[0]=vid_data;
mpi->width=bespitch;
mpi->stride[0]=mpi->width*(mpi->bpp/8);
}
mpi->flags|=MP_IMGFLAG_DIRECT;
// printf("mga: get_image() SUCCESS -> Direct Rendering ENABLED\n");
return VO_TRUE;
}
return VO_FALSE;
}
static uint32_t
query_format(uint32_t format)
{
switch(format){
case IMGFMT_YV12:
case IMGFMT_I420:
case IMGFMT_IYUV:
case IMGFMT_YUY2:
case IMGFMT_UYVY:
// case IMGFMT_RGB|24:
// case IMGFMT_BGR|24:
return 3 | VFCAP_OSD|VFCAP_HWSCALE_UP|VFCAP_HWSCALE_DOWN;
}
return 0;
}
static void query_vaa(vo_vaa_t *vaa)
{
memset(vaa,0,sizeof(vo_vaa_t));
vaa->get_video_eq = mga_get_video_eq;
vaa->set_video_eq = mga_set_video_eq;
}
static void mga_fullscreen()
{
uint32_t w,h;
if ( !vo_fs ) {
vo_fs=VO_TRUE;
w=vo_screenwidth; h=vo_screenheight;
aspect(&w,&h,A_ZOOM);
} else {
vo_fs=VO_FALSE;
w=vo_dwidth; h=vo_dheight;
aspect(&w,&h,A_NOZOOM);
}
mga_vid_config.dest_width = w;
mga_vid_config.dest_height= h;
if (vo_screenwidth && vo_screenheight) {
mga_vid_config.x_org=(vo_screenwidth-w)/2;
mga_vid_config.y_org=(vo_screenheight-h)/2;
} else {
mga_vid_config.x_org= 0;
mga_vid_config.y_org= 0;
}
if ( ioctl( f,MGA_VID_CONFIG,&mga_vid_config ) )
printf( "Error in mga_vid_config ioctl (wrong mga_vid.o version?)" );
}
static uint32_t control(uint32_t request, void *data, ...)
{
switch (request) {
case VOCTRL_QUERY_VAA:
query_vaa((vo_vaa_t*)data);
return VO_TRUE;
case VOCTRL_QUERY_FORMAT:
return query_format(*((uint32_t*)data));
case VOCTRL_GET_IMAGE:
return get_image(data);
case VOCTRL_FULLSCREEN:
#ifdef VO_XMGA
vo_x11_fullscreen();
#else
mga_fullscreen();
#endif
return VO_TRUE;
#if defined( VO_XMGA ) && defined( HAVE_NEW_GUI )
case VOCTRL_GUISUPPORT:
return VO_TRUE;
#endif
}
return VO_NOTIMPL;
}
static int mga_init(){
char *frame_mem;
mga_vid_config.num_frames=(vo_directrendering && !vo_doublebuffering)?1:3;
mga_vid_config.version=MGA_VID_VERSION;
if (ioctl(f,MGA_VID_CONFIG,&mga_vid_config))
{
perror("Error in mga_vid_config ioctl()");
printf("Your mga_vid driver version is incompatible with this MPlayer version!\n");
return -1;
}
ioctl(f,MGA_VID_ON,0);
printf("[mga] Using %d buffers.\n",mga_vid_config.num_frames);
frames[0] = (char*)mmap(0,mga_vid_config.frame_size*mga_vid_config.num_frames,PROT_WRITE,MAP_SHARED,f,0);
frames[1] = frames[0] + 1*mga_vid_config.frame_size;
frames[2] = frames[0] + 2*mga_vid_config.frame_size;
frames[3] = frames[0] + 3*mga_vid_config.frame_size;
mga_next_frame = 0;
vid_data = frames[mga_next_frame];
//clear the buffer
memset(frames[0],0x80,mga_vid_config.frame_size*mga_vid_config.num_frames);
return 0;
}
static int mga_uninit(){
ioctl( f,MGA_VID_OFF,0 );
munmap(frames[0],mga_vid_config.frame_size*mga_vid_config.num_frames);
close(f);
f = -1;
}
static uint32_t preinit(const char *arg)
{
char *devname=vo_subdevice?vo_subdevice:"/dev/mga_vid";
f = open(devname,O_RDWR);
if(f == -1)
{
perror("open");
printf("Couldn't open %s\n",devname);
return(-1);
}
return 0;
}