1
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mpv/video/out/vo_vdpau.c

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/*
* VDPAU video output driver
*
* Copyright (C) 2008 NVIDIA (Rajib Mahapatra <rmahapatra@nvidia.com>)
Implement vsync-aware frame timing for VDPAU Main things added are custom frame dropping for VDPAU to work around the display FPS limit, frame timing adjustment to avoid jitter when video frame times keep falling near vsyncs, and use of VDPAU's timing feature to keep one future frame queued in advance. NVIDIA's VDPAU implementation refuses to change the displayed frame more than once per vsync. This set a limit on how much video could be sped up, and caused problems for nearly all videos on low-FPS video projectors (playing 24 FPS video on a 24 FPS projector would not work reliably as MPlayer may need to slightly speed up the video for AV sync). This commit adds a framedrop mechanism that drops some frames so that no more than one is sent for display per vsync. The code tries to select the dropped frames smartly, selecting the best one to show for each vsync. Because of the timing features needed the drop functionality currently does not work if the correct-pts option is disabled. The code also adjusts frame timing slightly to avoid jitter. If you for example play 24 FPS video content on a 72 FPS display then normally a frame would be shown for 3 vsyncs, but if the frame times happen to fall near vsyncs and change between just before and just after then there could be frames alternating between 2 and 4 vsyncs. The code changes frame timing by up to one quarter vsync interval to avoid this. The above functionality depends on having reliable vsync timing information available. The display refresh rate is not directly provided by the VDPAU API. The current code uses information from the XF86VidMode extension if available; I'm not sure how common cases where that is inaccurate are. The refresh rate can be specified manually if necessary. After the changes in this commit MPlayer now always tries to keep one frame queued for future display using VDPAU's internal timing mechanism (however no more than 50 ms to the future). This should make video playback somewhat more robust against timing inaccuracies caused by system load.
2009-11-15 03:39:22 +01:00
* Copyright (C) 2009 Uoti Urpala
*
* This file is part of MPlayer.
*
* MPlayer is free software; you can redistribute it and/or modify
* it under the terms of the GNU General Public License as published by
* the Free Software Foundation; either version 2 of the License, or
* (at your option) any later version.
*
* MPlayer is distributed in the hope that it will be useful,
* but WITHOUT ANY WARRANTY; without even the implied warranty of
* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
* GNU General Public License for more details.
*
* You should have received a copy of the GNU General Public License along
* with MPlayer; if not, write to the Free Software Foundation, Inc.,
* 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA.
*/
2009-05-09 17:08:30 +02:00
/*
vdpau: split off decoder parts, use "new" libavcodec vdpau hwaccel API Move the decoder parts from vo_vdpau.c to a new file vdpau_old.c. This file is named so because because it's written against the "old" libavcodec vdpau pseudo-decoder (e.g. "h264_vdpau"). Add support for the "new" libavcodec vdpau support. This was recently added and replaces the "old" vdpau parts. (In fact, Libav is about to deprecate and remove the "old" API without deprecation grace period, so we have to support it now. Moreover, there will probably be no Libav release which supports both, so the transition is even less smooth than we could hope, and we have to support both the old and new API.) Whether the old or new API is used is checked by a configure test: if the new API is found, it is used, otherwise the old API is assumed. Some details might be handled differently. Especially display preemption is a bit problematic with the "new" libavcodec vdpau support: it wants to keep a pointer to a specific vdpau API function (which can be driver specific, because preemption might switch drivers). Also, surface IDs are now directly stored in AVFrames (and mp_images), so they can't be forced to VDP_INVALID_HANDLE on preemption. (This changes even with older libavcodec versions, because mp_image always uses the newer representation to make vo_vdpau.c simpler.) Decoder initialization in the new code tries to deal with codec profiles, while the old code always uses the highest profile per codec. Surface allocation changes. Since the decoder won't call config() in vo_vdpau.c on video size change anymore, we allow allocating surfaces of arbitrary size instead of locking it to what the VO was configured. The non-hwdec code also has slightly different allocation behavior now. Enabling the old vdpau special decoders via e.g. --vd=lavc:h264_vdpau doesn't work anymore (a warning suggesting the --hwdec option is printed instead).
2013-07-28 01:49:45 +02:00
* Actual decoding is done in video/decode/vdpau.c
*/
#include <stdio.h>
core/VO: Allow VO drivers to add/modify frames Add interfaces to allow VO drivers to add or remove frames from the video stream and to alter timestamps. Currently this functionality only works with in correct-pts mode. Use the new functionality in vo_vdpau to properly support frame-adding deinterlace modes. Frames added by the VDPAU deinterlacing code are now properly timed. Before every second frame was always shown immediately (probably next monitor refresh) after the previous one, even if you were watching things in slow motion, and framestepping didn't stop at them at all. When seeking the deinterlace algorithm is no longer fed a mix of frames from old and new positions. As a side effect of the changes a problem with resize events was also fixed. Resizing calls video_to_output_surface() to render the frame at the new resolution, but before this function also changed the list of history frames, so resizing could give an image different from the original one, and also corrupt next frames due to them seeing the wrong history. Now the function has no such side effects. There are more resize-related problems though that will be fixed in a later commit. The deint_mpi[] list of reserved frames is increased from 2 to 3 entries for reasons related to the above. Having 2 entries is enough when you initially get a new frame in draw_image() because then you'll have those two entries plus the new one for a total of 3 (the code relied on the oldest mpi implicitly staying reserved for the duration of the call even after usage count was decreased). However if you want to be able to reproduce the rendering outside draw_image(), relying on the explicitly reserved list only, then it needs to store 3 entries.
2009-09-18 15:27:55 +02:00
#include <stdlib.h>
#include <stdint.h>
#include <stdbool.h>
Implement vsync-aware frame timing for VDPAU Main things added are custom frame dropping for VDPAU to work around the display FPS limit, frame timing adjustment to avoid jitter when video frame times keep falling near vsyncs, and use of VDPAU's timing feature to keep one future frame queued in advance. NVIDIA's VDPAU implementation refuses to change the displayed frame more than once per vsync. This set a limit on how much video could be sped up, and caused problems for nearly all videos on low-FPS video projectors (playing 24 FPS video on a 24 FPS projector would not work reliably as MPlayer may need to slightly speed up the video for AV sync). This commit adds a framedrop mechanism that drops some frames so that no more than one is sent for display per vsync. The code tries to select the dropped frames smartly, selecting the best one to show for each vsync. Because of the timing features needed the drop functionality currently does not work if the correct-pts option is disabled. The code also adjusts frame timing slightly to avoid jitter. If you for example play 24 FPS video content on a 72 FPS display then normally a frame would be shown for 3 vsyncs, but if the frame times happen to fall near vsyncs and change between just before and just after then there could be frames alternating between 2 and 4 vsyncs. The code changes frame timing by up to one quarter vsync interval to avoid this. The above functionality depends on having reliable vsync timing information available. The display refresh rate is not directly provided by the VDPAU API. The current code uses information from the XF86VidMode extension if available; I'm not sure how common cases where that is inaccurate are. The refresh rate can be specified manually if necessary. After the changes in this commit MPlayer now always tries to keep one frame queued for future display using VDPAU's internal timing mechanism (however no more than 50 ms to the future). This should make video playback somewhat more robust against timing inaccuracies caused by system load.
2009-11-15 03:39:22 +01:00
#include <limits.h>
#include <assert.h>
#include <libavutil/common.h>
#include "config.h"
vdpau: split off decoder parts, use "new" libavcodec vdpau hwaccel API Move the decoder parts from vo_vdpau.c to a new file vdpau_old.c. This file is named so because because it's written against the "old" libavcodec vdpau pseudo-decoder (e.g. "h264_vdpau"). Add support for the "new" libavcodec vdpau support. This was recently added and replaces the "old" vdpau parts. (In fact, Libav is about to deprecate and remove the "old" API without deprecation grace period, so we have to support it now. Moreover, there will probably be no Libav release which supports both, so the transition is even less smooth than we could hope, and we have to support both the old and new API.) Whether the old or new API is used is checked by a configure test: if the new API is found, it is used, otherwise the old API is assumed. Some details might be handled differently. Especially display preemption is a bit problematic with the "new" libavcodec vdpau support: it wants to keep a pointer to a specific vdpau API function (which can be driver specific, because preemption might switch drivers). Also, surface IDs are now directly stored in AVFrames (and mp_images), so they can't be forced to VDP_INVALID_HANDLE on preemption. (This changes even with older libavcodec versions, because mp_image always uses the newer representation to make vo_vdpau.c simpler.) Decoder initialization in the new code tries to deal with codec profiles, while the old code always uses the highest profile per codec. Surface allocation changes. Since the decoder won't call config() in vo_vdpau.c on video size change anymore, we allow allocating surfaces of arbitrary size instead of locking it to what the VO was configured. The non-hwdec code also has slightly different allocation behavior now. Enabling the old vdpau special decoders via e.g. --vd=lavc:h264_vdpau doesn't work anymore (a warning suggesting the --hwdec option is printed instead).
2013-07-28 01:49:45 +02:00
#include "video/vdpau.h"
#include "video/vdpau_mixer.h"
#include "video/hwdec.h"
#include "common/msg.h"
#include "options/options.h"
#include "talloc.h"
#include "vo.h"
#include "x11_common.h"
#include "video/csputils.h"
#include "sub/osd.h"
#include "options/m_option.h"
#include "video/vfcap.h"
#include "video/mp_image.h"
#include "osdep/timer.h"
#include "bitmap_packer.h"
// Returns x + a, but wrapped around to the range [0, m)
// a must be within [-m, m], x within [0, m)
#define WRAP_ADD(x, a, m) ((a) < 0 \
? ((x)+(a)+(m) < (m) ? (x)+(a)+(m) : (x)+(a)) \
: ((x)+(a) < (m) ? (x)+(a) : (x)+(a)-(m)))
/* number of video and output surfaces */
#define MAX_OUTPUT_SURFACES 15
#define NUM_BUFFERED_VIDEO 5
2011-10-06 20:46:01 +02:00
/* Pixelformat used for output surfaces */
#define OUTPUT_RGBA_FORMAT VDP_RGBA_FORMAT_B8G8R8A8
/*
* Global variable declaration - VDPAU specific
*/
struct vdpctx {
struct mp_vdpau_ctx *mpvdp;
vdpau: split off decoder parts, use "new" libavcodec vdpau hwaccel API Move the decoder parts from vo_vdpau.c to a new file vdpau_old.c. This file is named so because because it's written against the "old" libavcodec vdpau pseudo-decoder (e.g. "h264_vdpau"). Add support for the "new" libavcodec vdpau support. This was recently added and replaces the "old" vdpau parts. (In fact, Libav is about to deprecate and remove the "old" API without deprecation grace period, so we have to support it now. Moreover, there will probably be no Libav release which supports both, so the transition is even less smooth than we could hope, and we have to support both the old and new API.) Whether the old or new API is used is checked by a configure test: if the new API is found, it is used, otherwise the old API is assumed. Some details might be handled differently. Especially display preemption is a bit problematic with the "new" libavcodec vdpau support: it wants to keep a pointer to a specific vdpau API function (which can be driver specific, because preemption might switch drivers). Also, surface IDs are now directly stored in AVFrames (and mp_images), so they can't be forced to VDP_INVALID_HANDLE on preemption. (This changes even with older libavcodec versions, because mp_image always uses the newer representation to make vo_vdpau.c simpler.) Decoder initialization in the new code tries to deal with codec profiles, while the old code always uses the highest profile per codec. Surface allocation changes. Since the decoder won't call config() in vo_vdpau.c on video size change anymore, we allow allocating surfaces of arbitrary size instead of locking it to what the VO was configured. The non-hwdec code also has slightly different allocation behavior now. Enabling the old vdpau special decoders via e.g. --vd=lavc:h264_vdpau doesn't work anymore (a warning suggesting the --hwdec option is printed instead).
2013-07-28 01:49:45 +02:00
struct vdp_functions *vdp;
VdpDevice vdp_device;
uint64_t preemption_counter;
vdpau: split off decoder parts, use "new" libavcodec vdpau hwaccel API Move the decoder parts from vo_vdpau.c to a new file vdpau_old.c. This file is named so because because it's written against the "old" libavcodec vdpau pseudo-decoder (e.g. "h264_vdpau"). Add support for the "new" libavcodec vdpau support. This was recently added and replaces the "old" vdpau parts. (In fact, Libav is about to deprecate and remove the "old" API without deprecation grace period, so we have to support it now. Moreover, there will probably be no Libav release which supports both, so the transition is even less smooth than we could hope, and we have to support both the old and new API.) Whether the old or new API is used is checked by a configure test: if the new API is found, it is used, otherwise the old API is assumed. Some details might be handled differently. Especially display preemption is a bit problematic with the "new" libavcodec vdpau support: it wants to keep a pointer to a specific vdpau API function (which can be driver specific, because preemption might switch drivers). Also, surface IDs are now directly stored in AVFrames (and mp_images), so they can't be forced to VDP_INVALID_HANDLE on preemption. (This changes even with older libavcodec versions, because mp_image always uses the newer representation to make vo_vdpau.c simpler.) Decoder initialization in the new code tries to deal with codec profiles, while the old code always uses the highest profile per codec. Surface allocation changes. Since the decoder won't call config() in vo_vdpau.c on video size change anymore, we allow allocating surfaces of arbitrary size instead of locking it to what the VO was configured. The non-hwdec code also has slightly different allocation behavior now. Enabling the old vdpau special decoders via e.g. --vd=lavc:h264_vdpau doesn't work anymore (a warning suggesting the --hwdec option is printed instead).
2013-07-28 01:49:45 +02:00
struct m_color colorkey;
VdpPresentationQueueTarget flip_target;
VdpPresentationQueue flip_queue;
VdpOutputSurface output_surfaces[MAX_OUTPUT_SURFACES];
VdpOutputSurface screenshot_surface;
int num_output_surfaces;
VdpOutputSurface rgb_surfaces[NUM_BUFFERED_VIDEO];
bool rgb_surfaces_used[NUM_BUFFERED_VIDEO];
VdpOutputSurface black_pixel;
struct mp_image *buffered_video[NUM_BUFFERED_VIDEO];
int buffer_pos;
// State for redrawing the screen after seek-reset
int prev_buffer_pos;
int output_surface_width, output_surface_height;
int force_yuv;
struct mp_vdpau_mixer *video_mixer;
int deint;
int pullup;
float denoise;
float sharpen;
int hqscaling;
int chroma_deint;
int flip_offset_window;
int flip_offset_fs;
bool flip;
VdpRect src_rect_vid;
VdpRect out_rect_vid;
struct mp_osd_res osd_rect;
int surface_num; // indexes output_surfaces
int query_surface_num;
Implement vsync-aware frame timing for VDPAU Main things added are custom frame dropping for VDPAU to work around the display FPS limit, frame timing adjustment to avoid jitter when video frame times keep falling near vsyncs, and use of VDPAU's timing feature to keep one future frame queued in advance. NVIDIA's VDPAU implementation refuses to change the displayed frame more than once per vsync. This set a limit on how much video could be sped up, and caused problems for nearly all videos on low-FPS video projectors (playing 24 FPS video on a 24 FPS projector would not work reliably as MPlayer may need to slightly speed up the video for AV sync). This commit adds a framedrop mechanism that drops some frames so that no more than one is sent for display per vsync. The code tries to select the dropped frames smartly, selecting the best one to show for each vsync. Because of the timing features needed the drop functionality currently does not work if the correct-pts option is disabled. The code also adjusts frame timing slightly to avoid jitter. If you for example play 24 FPS video content on a 72 FPS display then normally a frame would be shown for 3 vsyncs, but if the frame times happen to fall near vsyncs and change between just before and just after then there could be frames alternating between 2 and 4 vsyncs. The code changes frame timing by up to one quarter vsync interval to avoid this. The above functionality depends on having reliable vsync timing information available. The display refresh rate is not directly provided by the VDPAU API. The current code uses information from the XF86VidMode extension if available; I'm not sure how common cases where that is inaccurate are. The refresh rate can be specified manually if necessary. After the changes in this commit MPlayer now always tries to keep one frame queued for future display using VDPAU's internal timing mechanism (however no more than 50 ms to the future). This should make video playback somewhat more robust against timing inaccuracies caused by system load.
2009-11-15 03:39:22 +01:00
VdpTime recent_vsync_time;
float user_fps;
int composite_detect;
Implement vsync-aware frame timing for VDPAU Main things added are custom frame dropping for VDPAU to work around the display FPS limit, frame timing adjustment to avoid jitter when video frame times keep falling near vsyncs, and use of VDPAU's timing feature to keep one future frame queued in advance. NVIDIA's VDPAU implementation refuses to change the displayed frame more than once per vsync. This set a limit on how much video could be sped up, and caused problems for nearly all videos on low-FPS video projectors (playing 24 FPS video on a 24 FPS projector would not work reliably as MPlayer may need to slightly speed up the video for AV sync). This commit adds a framedrop mechanism that drops some frames so that no more than one is sent for display per vsync. The code tries to select the dropped frames smartly, selecting the best one to show for each vsync. Because of the timing features needed the drop functionality currently does not work if the correct-pts option is disabled. The code also adjusts frame timing slightly to avoid jitter. If you for example play 24 FPS video content on a 72 FPS display then normally a frame would be shown for 3 vsyncs, but if the frame times happen to fall near vsyncs and change between just before and just after then there could be frames alternating between 2 and 4 vsyncs. The code changes frame timing by up to one quarter vsync interval to avoid this. The above functionality depends on having reliable vsync timing information available. The display refresh rate is not directly provided by the VDPAU API. The current code uses information from the XF86VidMode extension if available; I'm not sure how common cases where that is inaccurate are. The refresh rate can be specified manually if necessary. After the changes in this commit MPlayer now always tries to keep one frame queued for future display using VDPAU's internal timing mechanism (however no more than 50 ms to the future). This should make video playback somewhat more robust against timing inaccuracies caused by system load.
2009-11-15 03:39:22 +01:00
unsigned int vsync_interval;
uint64_t last_queue_time;
uint64_t queue_time[MAX_OUTPUT_SURFACES];
Implement vsync-aware frame timing for VDPAU Main things added are custom frame dropping for VDPAU to work around the display FPS limit, frame timing adjustment to avoid jitter when video frame times keep falling near vsyncs, and use of VDPAU's timing feature to keep one future frame queued in advance. NVIDIA's VDPAU implementation refuses to change the displayed frame more than once per vsync. This set a limit on how much video could be sped up, and caused problems for nearly all videos on low-FPS video projectors (playing 24 FPS video on a 24 FPS projector would not work reliably as MPlayer may need to slightly speed up the video for AV sync). This commit adds a framedrop mechanism that drops some frames so that no more than one is sent for display per vsync. The code tries to select the dropped frames smartly, selecting the best one to show for each vsync. Because of the timing features needed the drop functionality currently does not work if the correct-pts option is disabled. The code also adjusts frame timing slightly to avoid jitter. If you for example play 24 FPS video content on a 72 FPS display then normally a frame would be shown for 3 vsyncs, but if the frame times happen to fall near vsyncs and change between just before and just after then there could be frames alternating between 2 and 4 vsyncs. The code changes frame timing by up to one quarter vsync interval to avoid this. The above functionality depends on having reliable vsync timing information available. The display refresh rate is not directly provided by the VDPAU API. The current code uses information from the XF86VidMode extension if available; I'm not sure how common cases where that is inaccurate are. The refresh rate can be specified manually if necessary. After the changes in this commit MPlayer now always tries to keep one frame queued for future display using VDPAU's internal timing mechanism (however no more than 50 ms to the future). This should make video playback somewhat more robust against timing inaccuracies caused by system load.
2009-11-15 03:39:22 +01:00
uint64_t last_ideal_time;
bool dropped_frame;
uint64_t dropped_time;
uint32_t vid_width, vid_height;
uint32_t image_format;
VdpChromaType vdp_chroma_type;
VdpYCbCrFormat vdp_pixel_format;
bool rgb_mode;
// OSD
struct osd_bitmap_surface {
VdpRGBAFormat format;
VdpBitmapSurface surface;
uint32_t max_width;
uint32_t max_height;
struct bitmap_packer *packer;
// List of surfaces to be rendered
struct osd_target {
VdpRect source;
VdpRect dest;
VdpColor color;
} *targets;
int targets_size;
int render_count;
int bitmap_id;
int bitmap_pos_id;
} osd_surfaces[MAX_OSD_PARTS];
// Video equalizer
video, options: implement better YUV->RGB conversion control Rewrite control of the colorspace and input/output level parameters used in YUV-RGB conversions, replacing VO-specific suboptions with new common options and adding configuration support to more cases. Add new option --colormatrix which selects the colorspace the original video is assumed to have in YUV->RGB conversions. The default behavior changes from assuming BT.601 to colorspace autoselection between BT.601 and BT.709 using a simple heuristic based on video size. Add new options --colormatrix-input-range and --colormatrix-output-range which select input YUV and output RGB range. Disable the previously existing VO-specific colorspace and level conversion suboptions in vo_gl and vo_vdpau. Remove the "yuv_colorspace" property and replace it with one named "colormatrix" and semantics matching the new option. Add new properties matching the options for level conversion. Colorspace selection is currently supported by vo_gl, vo_vdpau, vo_xv and vf_scale, and all can change it at runtime (previously only vo_vdpau and vo_xv could). vo_vdpau now uses the same conversion matrix generation as vo_gl instead of libvdpau functionality; the main functional difference is that the "contrast" equalizer control behaves somewhat differently (it scales the Y component around 1/2 instead of around 0, so that contrast 0 makes the image gray rather than black). vo_xv does not support level conversion. vf_scale supports range setting for input, but always outputs full-range RGB. The value of the slave properties is the policy setting used for conversions. This means they can be set to any value regardless of whether the current VO supports that value or whether there currently even is any video. Possibly separate properties could be added to query the conversion actually used at the moment, if any. Because the colorspace and level settings are now set with a single VF/VO control call, the return value of that is no longer used to signal whether all the settings are actually supported. Instead code should set all the details it can support, and ignore the rest. The core will use GET_YUV_COLORSPACE to check which colorspace details have been set and which not. In other words, the return value for SET_YUV_COLORSPACE only signals whether any kind of YUV colorspace conversion handling exists at all, and VOs have to take care to return the actual state with GET_YUV_COLORSPACE instead. To be changed in later commits: add missing option documentation.
2011-10-15 23:50:21 +02:00
struct mp_csp_equalizer video_eq;
};
static bool status_ok(struct vo *vo);
2011-10-06 20:46:01 +02:00
static int render_video_to_output_surface(struct vo *vo,
VdpOutputSurface output_surface,
VdpRect *output_rect,
VdpRect *video_rect)
{
struct vdpctx *vc = vo->priv;
struct vdp_functions *vdp = vc->vdp;
VdpTime dummy;
VdpStatus vdp_st;
int dp = vc->buffer_pos;
// Redraw frame from before seek reset?
if (dp < 0)
dp = vc->prev_buffer_pos;
if (dp < 0) {
// At least clear the screen if there is nothing to render
int flags = VDP_OUTPUT_SURFACE_RENDER_ROTATE_0;
vdp_st = vdp->output_surface_render_output_surface(output_surface,
NULL, vc->black_pixel,
NULL, NULL, NULL,
flags);
return -1;
}
struct mp_image *mpi = vc->buffered_video[dp];
vdp_st = vdp->presentation_queue_block_until_surface_idle(vc->flip_queue,
output_surface,
&dummy);
2013-12-21 18:05:23 +01:00
CHECK_VDP_WARNING(vo, "Error when calling "
"vdp_presentation_queue_block_until_surface_idle");
if (vc->rgb_mode) {
VdpOutputSurface surface = (uintptr_t)mpi->planes[0];
int flags = VDP_OUTPUT_SURFACE_RENDER_ROTATE_0;
vdp_st = vdp->output_surface_render_output_surface(output_surface,
NULL, vc->black_pixel,
NULL, NULL, NULL,
flags);
2013-12-21 18:05:23 +01:00
CHECK_VDP_WARNING(vo, "Error clearing screen");
vdp_st = vdp->output_surface_render_output_surface(output_surface,
output_rect,
surface,
video_rect,
NULL, NULL, flags);
2013-12-21 18:05:23 +01:00
CHECK_VDP_WARNING(vo, "Error when calling "
"vdp_output_surface_render_output_surface");
return 0;
}
struct mp_vdpau_mixer_frame *frame = mp_vdpau_mixed_frame_get(mpi);
struct mp_vdpau_mixer_opts opts = {0};
if (frame)
opts = frame->opts;
// Apply custom vo_vdpau suboptions.
opts.chroma_deint |= vc->chroma_deint;
opts.pullup |= vc->pullup;
opts.denoise = MPCLAMP(opts.denoise + vc->denoise, 0, 1);
opts.sharpen = MPCLAMP(opts.sharpen + vc->sharpen, -1, 1);
if (vc->hqscaling)
opts.hqscaling = vc->hqscaling;
mp_vdpau_mixer_render(vc->video_mixer, &opts, output_surface, output_rect,
mpi, video_rect);
return 0;
core/VO: Allow VO drivers to add/modify frames Add interfaces to allow VO drivers to add or remove frames from the video stream and to alter timestamps. Currently this functionality only works with in correct-pts mode. Use the new functionality in vo_vdpau to properly support frame-adding deinterlace modes. Frames added by the VDPAU deinterlacing code are now properly timed. Before every second frame was always shown immediately (probably next monitor refresh) after the previous one, even if you were watching things in slow motion, and framestepping didn't stop at them at all. When seeking the deinterlace algorithm is no longer fed a mix of frames from old and new positions. As a side effect of the changes a problem with resize events was also fixed. Resizing calls video_to_output_surface() to render the frame at the new resolution, but before this function also changed the list of history frames, so resizing could give an image different from the original one, and also corrupt next frames due to them seeing the wrong history. Now the function has no such side effects. There are more resize-related problems though that will be fixed in a later commit. The deint_mpi[] list of reserved frames is increased from 2 to 3 entries for reasons related to the above. Having 2 entries is enough when you initially get a new frame in draw_image() because then you'll have those two entries plus the new one for a total of 3 (the code relied on the oldest mpi implicitly staying reserved for the duration of the call even after usage count was decreased). However if you want to be able to reproduce the rendering outside draw_image(), relying on the explicitly reserved list only, then it needs to store 3 entries.
2009-09-18 15:27:55 +02:00
}
2011-10-06 20:46:01 +02:00
static int video_to_output_surface(struct vo *vo)
{
struct vdpctx *vc = vo->priv;
return render_video_to_output_surface(vo,
vc->output_surfaces[vc->surface_num],
&vc->out_rect_vid, &vc->src_rect_vid);
2011-10-06 20:46:01 +02:00
}
static int next_buffer_pos(struct vo *vo, bool eof)
core/VO: Allow VO drivers to add/modify frames Add interfaces to allow VO drivers to add or remove frames from the video stream and to alter timestamps. Currently this functionality only works with in correct-pts mode. Use the new functionality in vo_vdpau to properly support frame-adding deinterlace modes. Frames added by the VDPAU deinterlacing code are now properly timed. Before every second frame was always shown immediately (probably next monitor refresh) after the previous one, even if you were watching things in slow motion, and framestepping didn't stop at them at all. When seeking the deinterlace algorithm is no longer fed a mix of frames from old and new positions. As a side effect of the changes a problem with resize events was also fixed. Resizing calls video_to_output_surface() to render the frame at the new resolution, but before this function also changed the list of history frames, so resizing could give an image different from the original one, and also corrupt next frames due to them seeing the wrong history. Now the function has no such side effects. There are more resize-related problems though that will be fixed in a later commit. The deint_mpi[] list of reserved frames is increased from 2 to 3 entries for reasons related to the above. Having 2 entries is enough when you initially get a new frame in draw_image() because then you'll have those two entries plus the new one for a total of 3 (the code relied on the oldest mpi implicitly staying reserved for the duration of the call even after usage count was decreased). However if you want to be able to reproduce the rendering outside draw_image(), relying on the explicitly reserved list only, then it needs to store 3 entries.
2009-09-18 15:27:55 +02:00
{
struct vdpctx *vc = vo->priv;
int dqp = vc->buffer_pos;
if (dqp < 0)
dqp += 1000;
else
dqp -= 1;
if (dqp < (eof ? 0 : 1))
return -1;
return dqp;
}
static void set_next_frame_info(struct vo *vo, bool eof)
{
struct vdpctx *vc = vo->priv;
core/VO: Allow VO drivers to add/modify frames Add interfaces to allow VO drivers to add or remove frames from the video stream and to alter timestamps. Currently this functionality only works with in correct-pts mode. Use the new functionality in vo_vdpau to properly support frame-adding deinterlace modes. Frames added by the VDPAU deinterlacing code are now properly timed. Before every second frame was always shown immediately (probably next monitor refresh) after the previous one, even if you were watching things in slow motion, and framestepping didn't stop at them at all. When seeking the deinterlace algorithm is no longer fed a mix of frames from old and new positions. As a side effect of the changes a problem with resize events was also fixed. Resizing calls video_to_output_surface() to render the frame at the new resolution, but before this function also changed the list of history frames, so resizing could give an image different from the original one, and also corrupt next frames due to them seeing the wrong history. Now the function has no such side effects. There are more resize-related problems though that will be fixed in a later commit. The deint_mpi[] list of reserved frames is increased from 2 to 3 entries for reasons related to the above. Having 2 entries is enough when you initially get a new frame in draw_image() because then you'll have those two entries plus the new one for a total of 3 (the code relied on the oldest mpi implicitly staying reserved for the duration of the call even after usage count was decreased). However if you want to be able to reproduce the rendering outside draw_image(), relying on the explicitly reserved list only, then it needs to store 3 entries.
2009-09-18 15:27:55 +02:00
vo->frame_loaded = false;
int dqp = next_buffer_pos(vo, eof);
if (dqp < 0)
return;
core/VO: Allow VO drivers to add/modify frames Add interfaces to allow VO drivers to add or remove frames from the video stream and to alter timestamps. Currently this functionality only works with in correct-pts mode. Use the new functionality in vo_vdpau to properly support frame-adding deinterlace modes. Frames added by the VDPAU deinterlacing code are now properly timed. Before every second frame was always shown immediately (probably next monitor refresh) after the previous one, even if you were watching things in slow motion, and framestepping didn't stop at them at all. When seeking the deinterlace algorithm is no longer fed a mix of frames from old and new positions. As a side effect of the changes a problem with resize events was also fixed. Resizing calls video_to_output_surface() to render the frame at the new resolution, but before this function also changed the list of history frames, so resizing could give an image different from the original one, and also corrupt next frames due to them seeing the wrong history. Now the function has no such side effects. There are more resize-related problems though that will be fixed in a later commit. The deint_mpi[] list of reserved frames is increased from 2 to 3 entries for reasons related to the above. Having 2 entries is enough when you initially get a new frame in draw_image() because then you'll have those two entries plus the new one for a total of 3 (the code relied on the oldest mpi implicitly staying reserved for the duration of the call even after usage count was decreased). However if you want to be able to reproduce the rendering outside draw_image(), relying on the explicitly reserved list only, then it needs to store 3 entries.
2009-09-18 15:27:55 +02:00
vo->frame_loaded = true;
// Set pts values
struct mp_image **bv = &vc->buffered_video[0];
if (dqp == 0) { // no future frame/pts available
vo->next_pts = bv[0]->pts;
vo->next_pts2 = MP_NOPTS_VALUE;
} else {
vo->next_pts = bv[dqp]->pts;
vo->next_pts2 = bv[dqp - 1]->pts;
}
core/VO: Allow VO drivers to add/modify frames Add interfaces to allow VO drivers to add or remove frames from the video stream and to alter timestamps. Currently this functionality only works with in correct-pts mode. Use the new functionality in vo_vdpau to properly support frame-adding deinterlace modes. Frames added by the VDPAU deinterlacing code are now properly timed. Before every second frame was always shown immediately (probably next monitor refresh) after the previous one, even if you were watching things in slow motion, and framestepping didn't stop at them at all. When seeking the deinterlace algorithm is no longer fed a mix of frames from old and new positions. As a side effect of the changes a problem with resize events was also fixed. Resizing calls video_to_output_surface() to render the frame at the new resolution, but before this function also changed the list of history frames, so resizing could give an image different from the original one, and also corrupt next frames due to them seeing the wrong history. Now the function has no such side effects. There are more resize-related problems though that will be fixed in a later commit. The deint_mpi[] list of reserved frames is increased from 2 to 3 entries for reasons related to the above. Having 2 entries is enough when you initially get a new frame in draw_image() because then you'll have those two entries plus the new one for a total of 3 (the code relied on the oldest mpi implicitly staying reserved for the duration of the call even after usage count was decreased). However if you want to be able to reproduce the rendering outside draw_image(), relying on the explicitly reserved list only, then it needs to store 3 entries.
2009-09-18 15:27:55 +02:00
}
static void add_new_video_surface(struct vo *vo, struct mp_image *mpi)
{
struct vdpctx *vc = vo->priv;
struct mp_image **bv = vc->buffered_video;
mp_image_unrefp(&bv[NUM_BUFFERED_VIDEO - 1]);
for (int i = NUM_BUFFERED_VIDEO - 1; i > 0; i--)
bv[i] = bv[i - 1];
bv[0] = mpi;
vc->buffer_pos = FFMIN(vc->buffer_pos + 1, NUM_BUFFERED_VIDEO - 2);
set_next_frame_info(vo, false);
}
static void forget_frames(struct vo *vo, bool seek_reset)
core/VO: Allow VO drivers to add/modify frames Add interfaces to allow VO drivers to add or remove frames from the video stream and to alter timestamps. Currently this functionality only works with in correct-pts mode. Use the new functionality in vo_vdpau to properly support frame-adding deinterlace modes. Frames added by the VDPAU deinterlacing code are now properly timed. Before every second frame was always shown immediately (probably next monitor refresh) after the previous one, even if you were watching things in slow motion, and framestepping didn't stop at them at all. When seeking the deinterlace algorithm is no longer fed a mix of frames from old and new positions. As a side effect of the changes a problem with resize events was also fixed. Resizing calls video_to_output_surface() to render the frame at the new resolution, but before this function also changed the list of history frames, so resizing could give an image different from the original one, and also corrupt next frames due to them seeing the wrong history. Now the function has no such side effects. There are more resize-related problems though that will be fixed in a later commit. The deint_mpi[] list of reserved frames is increased from 2 to 3 entries for reasons related to the above. Having 2 entries is enough when you initially get a new frame in draw_image() because then you'll have those two entries plus the new one for a total of 3 (the code relied on the oldest mpi implicitly staying reserved for the duration of the call even after usage count was decreased). However if you want to be able to reproduce the rendering outside draw_image(), relying on the explicitly reserved list only, then it needs to store 3 entries.
2009-09-18 15:27:55 +02:00
{
struct vdpctx *vc = vo->priv;
if (seek_reset) {
if (vc->buffer_pos >= 0)
vc->prev_buffer_pos = vc->buffer_pos;
} else {
vc->prev_buffer_pos = -1001;
}
vc->buffer_pos = -1001;
Implement vsync-aware frame timing for VDPAU Main things added are custom frame dropping for VDPAU to work around the display FPS limit, frame timing adjustment to avoid jitter when video frame times keep falling near vsyncs, and use of VDPAU's timing feature to keep one future frame queued in advance. NVIDIA's VDPAU implementation refuses to change the displayed frame more than once per vsync. This set a limit on how much video could be sped up, and caused problems for nearly all videos on low-FPS video projectors (playing 24 FPS video on a 24 FPS projector would not work reliably as MPlayer may need to slightly speed up the video for AV sync). This commit adds a framedrop mechanism that drops some frames so that no more than one is sent for display per vsync. The code tries to select the dropped frames smartly, selecting the best one to show for each vsync. Because of the timing features needed the drop functionality currently does not work if the correct-pts option is disabled. The code also adjusts frame timing slightly to avoid jitter. If you for example play 24 FPS video content on a 72 FPS display then normally a frame would be shown for 3 vsyncs, but if the frame times happen to fall near vsyncs and change between just before and just after then there could be frames alternating between 2 and 4 vsyncs. The code changes frame timing by up to one quarter vsync interval to avoid this. The above functionality depends on having reliable vsync timing information available. The display refresh rate is not directly provided by the VDPAU API. The current code uses information from the XF86VidMode extension if available; I'm not sure how common cases where that is inaccurate are. The refresh rate can be specified manually if necessary. After the changes in this commit MPlayer now always tries to keep one frame queued for future display using VDPAU's internal timing mechanism (however no more than 50 ms to the future). This should make video playback somewhat more robust against timing inaccuracies caused by system load.
2009-11-15 03:39:22 +01:00
vc->dropped_frame = false;
if (vc->prev_buffer_pos < 0) {
for (int i = 0; i < NUM_BUFFERED_VIDEO; i++)
mp_image_unrefp(&vc->buffered_video[i]);
}
}
2009-05-04 02:09:50 +02:00
static void resize(struct vo *vo)
{
struct vdpctx *vc = vo->priv;
struct vdp_functions *vdp = vc->vdp;
VdpStatus vdp_st;
struct mp_rect src_rect;
struct mp_rect dst_rect;
vo_get_src_dst_rects(vo, &src_rect, &dst_rect, &vc->osd_rect);
vc->out_rect_vid.x0 = dst_rect.x0;
vc->out_rect_vid.x1 = dst_rect.x1;
vc->out_rect_vid.y0 = dst_rect.y0;
vc->out_rect_vid.y1 = dst_rect.y1;
vc->src_rect_vid.x0 = src_rect.x0;
vc->src_rect_vid.x1 = src_rect.x1;
vc->src_rect_vid.y0 = vc->flip ? src_rect.y1 : src_rect.y0;
vc->src_rect_vid.y1 = vc->flip ? src_rect.y0 : src_rect.y1;
int flip_offset_ms = vo->opts->fullscreen ?
vc->flip_offset_fs :
vc->flip_offset_window;
vo->flip_queue_offset = flip_offset_ms / 1000.;
if (vc->output_surface_width < vo->dwidth
|| vc->output_surface_height < vo->dheight) {
if (vc->output_surface_width < vo->dwidth) {
vc->output_surface_width += vc->output_surface_width >> 1;
2009-05-09 17:08:30 +02:00
vc->output_surface_width = FFMAX(vc->output_surface_width,
vo->dwidth);
}
if (vc->output_surface_height < vo->dheight) {
vc->output_surface_height += vc->output_surface_height >> 1;
2009-05-09 17:08:30 +02:00
vc->output_surface_height = FFMAX(vc->output_surface_height,
vo->dheight);
}
// Creation of output_surfaces
for (int i = 0; i < vc->num_output_surfaces; i++)
if (vc->output_surfaces[i] != VDP_INVALID_HANDLE) {
vdp_st = vdp->output_surface_destroy(vc->output_surfaces[i]);
2013-12-21 18:05:23 +01:00
CHECK_VDP_WARNING(vo, "Error when calling "
"vdp_output_surface_destroy");
}
for (int i = 0; i < vc->num_output_surfaces; i++) {
2009-05-09 17:08:30 +02:00
vdp_st = vdp->output_surface_create(vc->vdp_device,
2011-10-06 20:46:01 +02:00
OUTPUT_RGBA_FORMAT,
2009-05-09 17:08:30 +02:00
vc->output_surface_width,
vc->output_surface_height,
&vc->output_surfaces[i]);
2013-12-21 18:05:23 +01:00
CHECK_VDP_WARNING(vo, "Error when calling vdp_output_surface_create");
MP_DBG(vo, "vdpau out create: %u\n",
2009-05-09 17:08:30 +02:00
vc->output_surfaces[i]);
}
}
vo->want_redraw = true;
}
2009-05-04 02:09:50 +02:00
static int win_x11_init_vdpau_flip_queue(struct vo *vo)
{
struct vdpctx *vc = vo->priv;
struct vdp_functions *vdp = vc->vdp;
2009-05-04 02:09:50 +02:00
struct vo_x11_state *x11 = vo->x11;
VdpStatus vdp_st;
if (vc->flip_target == VDP_INVALID_HANDLE) {
vdp_st = vdp->presentation_queue_target_create_x11(vc->vdp_device,
x11->window,
&vc->flip_target);
2013-12-21 18:05:23 +01:00
CHECK_VDP_ERROR(vo, "Error when calling "
"vdp_presentation_queue_target_create_x11");
}
/* Emperically this seems to be the first call which fails when we
* try to reinit after preemption while the user is still switched
* from X to a virtual terminal (creating the vdp_device initially
* succeeds, as does creating the flip_target above). This is
* probably not guaranteed behavior, but we'll assume it as a simple
* way to reduce warnings while trying to recover from preemption.
*/
if (vc->flip_queue == VDP_INVALID_HANDLE) {
vdp_st = vdp->presentation_queue_create(vc->vdp_device, vc->flip_target,
&vc->flip_queue);
if (vc->mpvdp->is_preempted && vdp_st != VDP_STATUS_OK) {
MP_DBG(vo, "Failed to create flip queue while preempted: %s\n",
vdp->get_error_string(vdp_st));
return -1;
} else
2013-12-21 18:05:23 +01:00
CHECK_VDP_ERROR(vo, "Error when calling vdp_presentation_queue_create");
}
if (vc->colorkey.a > 0) {
VdpColor color = {
.red = vc->colorkey.r / 255.0,
.green = vc->colorkey.g / 255.0,
.blue = vc->colorkey.b / 255.0,
.alpha = 0,
};
vdp_st = vdp->presentation_queue_set_background_color(vc->flip_queue,
&color);
2013-12-21 18:05:23 +01:00
CHECK_VDP_WARNING(vo, "Error setting colorkey");
}
Implement vsync-aware frame timing for VDPAU Main things added are custom frame dropping for VDPAU to work around the display FPS limit, frame timing adjustment to avoid jitter when video frame times keep falling near vsyncs, and use of VDPAU's timing feature to keep one future frame queued in advance. NVIDIA's VDPAU implementation refuses to change the displayed frame more than once per vsync. This set a limit on how much video could be sped up, and caused problems for nearly all videos on low-FPS video projectors (playing 24 FPS video on a 24 FPS projector would not work reliably as MPlayer may need to slightly speed up the video for AV sync). This commit adds a framedrop mechanism that drops some frames so that no more than one is sent for display per vsync. The code tries to select the dropped frames smartly, selecting the best one to show for each vsync. Because of the timing features needed the drop functionality currently does not work if the correct-pts option is disabled. The code also adjusts frame timing slightly to avoid jitter. If you for example play 24 FPS video content on a 72 FPS display then normally a frame would be shown for 3 vsyncs, but if the frame times happen to fall near vsyncs and change between just before and just after then there could be frames alternating between 2 and 4 vsyncs. The code changes frame timing by up to one quarter vsync interval to avoid this. The above functionality depends on having reliable vsync timing information available. The display refresh rate is not directly provided by the VDPAU API. The current code uses information from the XF86VidMode extension if available; I'm not sure how common cases where that is inaccurate are. The refresh rate can be specified manually if necessary. After the changes in this commit MPlayer now always tries to keep one frame queued for future display using VDPAU's internal timing mechanism (however no more than 50 ms to the future). This should make video playback somewhat more robust against timing inaccuracies caused by system load.
2009-11-15 03:39:22 +01:00
vc->vsync_interval = 1;
if (vc->composite_detect && vo_x11_screen_is_composited(vo)) {
MP_INFO(vo, "Compositing window manager detected. Assuming timing info "
"is inaccurate.\n");
} else if (vc->user_fps > 0) {
Implement vsync-aware frame timing for VDPAU Main things added are custom frame dropping for VDPAU to work around the display FPS limit, frame timing adjustment to avoid jitter when video frame times keep falling near vsyncs, and use of VDPAU's timing feature to keep one future frame queued in advance. NVIDIA's VDPAU implementation refuses to change the displayed frame more than once per vsync. This set a limit on how much video could be sped up, and caused problems for nearly all videos on low-FPS video projectors (playing 24 FPS video on a 24 FPS projector would not work reliably as MPlayer may need to slightly speed up the video for AV sync). This commit adds a framedrop mechanism that drops some frames so that no more than one is sent for display per vsync. The code tries to select the dropped frames smartly, selecting the best one to show for each vsync. Because of the timing features needed the drop functionality currently does not work if the correct-pts option is disabled. The code also adjusts frame timing slightly to avoid jitter. If you for example play 24 FPS video content on a 72 FPS display then normally a frame would be shown for 3 vsyncs, but if the frame times happen to fall near vsyncs and change between just before and just after then there could be frames alternating between 2 and 4 vsyncs. The code changes frame timing by up to one quarter vsync interval to avoid this. The above functionality depends on having reliable vsync timing information available. The display refresh rate is not directly provided by the VDPAU API. The current code uses information from the XF86VidMode extension if available; I'm not sure how common cases where that is inaccurate are. The refresh rate can be specified manually if necessary. After the changes in this commit MPlayer now always tries to keep one frame queued for future display using VDPAU's internal timing mechanism (however no more than 50 ms to the future). This should make video playback somewhat more robust against timing inaccuracies caused by system load.
2009-11-15 03:39:22 +01:00
vc->vsync_interval = 1e9 / vc->user_fps;
MP_INFO(vo, "Assuming user-specified display refresh rate of %.3f Hz.\n",
vc->user_fps);
Implement vsync-aware frame timing for VDPAU Main things added are custom frame dropping for VDPAU to work around the display FPS limit, frame timing adjustment to avoid jitter when video frame times keep falling near vsyncs, and use of VDPAU's timing feature to keep one future frame queued in advance. NVIDIA's VDPAU implementation refuses to change the displayed frame more than once per vsync. This set a limit on how much video could be sped up, and caused problems for nearly all videos on low-FPS video projectors (playing 24 FPS video on a 24 FPS projector would not work reliably as MPlayer may need to slightly speed up the video for AV sync). This commit adds a framedrop mechanism that drops some frames so that no more than one is sent for display per vsync. The code tries to select the dropped frames smartly, selecting the best one to show for each vsync. Because of the timing features needed the drop functionality currently does not work if the correct-pts option is disabled. The code also adjusts frame timing slightly to avoid jitter. If you for example play 24 FPS video content on a 72 FPS display then normally a frame would be shown for 3 vsyncs, but if the frame times happen to fall near vsyncs and change between just before and just after then there could be frames alternating between 2 and 4 vsyncs. The code changes frame timing by up to one quarter vsync interval to avoid this. The above functionality depends on having reliable vsync timing information available. The display refresh rate is not directly provided by the VDPAU API. The current code uses information from the XF86VidMode extension if available; I'm not sure how common cases where that is inaccurate are. The refresh rate can be specified manually if necessary. After the changes in this commit MPlayer now always tries to keep one frame queued for future display using VDPAU's internal timing mechanism (however no more than 50 ms to the future). This should make video playback somewhat more robust against timing inaccuracies caused by system load.
2009-11-15 03:39:22 +01:00
} else if (vc->user_fps == 0) {
#if HAVE_XF86VM
double fps = vo_x11_vm_get_fps(vo);
Implement vsync-aware frame timing for VDPAU Main things added are custom frame dropping for VDPAU to work around the display FPS limit, frame timing adjustment to avoid jitter when video frame times keep falling near vsyncs, and use of VDPAU's timing feature to keep one future frame queued in advance. NVIDIA's VDPAU implementation refuses to change the displayed frame more than once per vsync. This set a limit on how much video could be sped up, and caused problems for nearly all videos on low-FPS video projectors (playing 24 FPS video on a 24 FPS projector would not work reliably as MPlayer may need to slightly speed up the video for AV sync). This commit adds a framedrop mechanism that drops some frames so that no more than one is sent for display per vsync. The code tries to select the dropped frames smartly, selecting the best one to show for each vsync. Because of the timing features needed the drop functionality currently does not work if the correct-pts option is disabled. The code also adjusts frame timing slightly to avoid jitter. If you for example play 24 FPS video content on a 72 FPS display then normally a frame would be shown for 3 vsyncs, but if the frame times happen to fall near vsyncs and change between just before and just after then there could be frames alternating between 2 and 4 vsyncs. The code changes frame timing by up to one quarter vsync interval to avoid this. The above functionality depends on having reliable vsync timing information available. The display refresh rate is not directly provided by the VDPAU API. The current code uses information from the XF86VidMode extension if available; I'm not sure how common cases where that is inaccurate are. The refresh rate can be specified manually if necessary. After the changes in this commit MPlayer now always tries to keep one frame queued for future display using VDPAU's internal timing mechanism (however no more than 50 ms to the future). This should make video playback somewhat more robust against timing inaccuracies caused by system load.
2009-11-15 03:39:22 +01:00
if (!fps)
MP_WARN(vo, "Failed to get display FPS\n");
Implement vsync-aware frame timing for VDPAU Main things added are custom frame dropping for VDPAU to work around the display FPS limit, frame timing adjustment to avoid jitter when video frame times keep falling near vsyncs, and use of VDPAU's timing feature to keep one future frame queued in advance. NVIDIA's VDPAU implementation refuses to change the displayed frame more than once per vsync. This set a limit on how much video could be sped up, and caused problems for nearly all videos on low-FPS video projectors (playing 24 FPS video on a 24 FPS projector would not work reliably as MPlayer may need to slightly speed up the video for AV sync). This commit adds a framedrop mechanism that drops some frames so that no more than one is sent for display per vsync. The code tries to select the dropped frames smartly, selecting the best one to show for each vsync. Because of the timing features needed the drop functionality currently does not work if the correct-pts option is disabled. The code also adjusts frame timing slightly to avoid jitter. If you for example play 24 FPS video content on a 72 FPS display then normally a frame would be shown for 3 vsyncs, but if the frame times happen to fall near vsyncs and change between just before and just after then there could be frames alternating between 2 and 4 vsyncs. The code changes frame timing by up to one quarter vsync interval to avoid this. The above functionality depends on having reliable vsync timing information available. The display refresh rate is not directly provided by the VDPAU API. The current code uses information from the XF86VidMode extension if available; I'm not sure how common cases where that is inaccurate are. The refresh rate can be specified manually if necessary. After the changes in this commit MPlayer now always tries to keep one frame queued for future display using VDPAU's internal timing mechanism (however no more than 50 ms to the future). This should make video playback somewhat more robust against timing inaccuracies caused by system load.
2009-11-15 03:39:22 +01:00
else {
vc->vsync_interval = 1e9 / fps;
// This is verbose, but I'm not yet sure how common wrong values are
MP_INFO(vo, "Got display refresh rate %.3f Hz.\n", fps);
MP_INFO(vo, "If that value looks wrong give the "
"-vo vdpau:fps=X suboption manually.\n");
Implement vsync-aware frame timing for VDPAU Main things added are custom frame dropping for VDPAU to work around the display FPS limit, frame timing adjustment to avoid jitter when video frame times keep falling near vsyncs, and use of VDPAU's timing feature to keep one future frame queued in advance. NVIDIA's VDPAU implementation refuses to change the displayed frame more than once per vsync. This set a limit on how much video could be sped up, and caused problems for nearly all videos on low-FPS video projectors (playing 24 FPS video on a 24 FPS projector would not work reliably as MPlayer may need to slightly speed up the video for AV sync). This commit adds a framedrop mechanism that drops some frames so that no more than one is sent for display per vsync. The code tries to select the dropped frames smartly, selecting the best one to show for each vsync. Because of the timing features needed the drop functionality currently does not work if the correct-pts option is disabled. The code also adjusts frame timing slightly to avoid jitter. If you for example play 24 FPS video content on a 72 FPS display then normally a frame would be shown for 3 vsyncs, but if the frame times happen to fall near vsyncs and change between just before and just after then there could be frames alternating between 2 and 4 vsyncs. The code changes frame timing by up to one quarter vsync interval to avoid this. The above functionality depends on having reliable vsync timing information available. The display refresh rate is not directly provided by the VDPAU API. The current code uses information from the XF86VidMode extension if available; I'm not sure how common cases where that is inaccurate are. The refresh rate can be specified manually if necessary. After the changes in this commit MPlayer now always tries to keep one frame queued for future display using VDPAU's internal timing mechanism (however no more than 50 ms to the future). This should make video playback somewhat more robust against timing inaccuracies caused by system load.
2009-11-15 03:39:22 +01:00
}
#else
MP_INFO(vo, "This binary has been compiled without XF86VidMode support.\n");
MP_INFO(vo, "Can't use vsync-aware timing without manually provided "
"-vo vdpau:fps=X suboption.\n");
Implement vsync-aware frame timing for VDPAU Main things added are custom frame dropping for VDPAU to work around the display FPS limit, frame timing adjustment to avoid jitter when video frame times keep falling near vsyncs, and use of VDPAU's timing feature to keep one future frame queued in advance. NVIDIA's VDPAU implementation refuses to change the displayed frame more than once per vsync. This set a limit on how much video could be sped up, and caused problems for nearly all videos on low-FPS video projectors (playing 24 FPS video on a 24 FPS projector would not work reliably as MPlayer may need to slightly speed up the video for AV sync). This commit adds a framedrop mechanism that drops some frames so that no more than one is sent for display per vsync. The code tries to select the dropped frames smartly, selecting the best one to show for each vsync. Because of the timing features needed the drop functionality currently does not work if the correct-pts option is disabled. The code also adjusts frame timing slightly to avoid jitter. If you for example play 24 FPS video content on a 72 FPS display then normally a frame would be shown for 3 vsyncs, but if the frame times happen to fall near vsyncs and change between just before and just after then there could be frames alternating between 2 and 4 vsyncs. The code changes frame timing by up to one quarter vsync interval to avoid this. The above functionality depends on having reliable vsync timing information available. The display refresh rate is not directly provided by the VDPAU API. The current code uses information from the XF86VidMode extension if available; I'm not sure how common cases where that is inaccurate are. The refresh rate can be specified manually if necessary. After the changes in this commit MPlayer now always tries to keep one frame queued for future display using VDPAU's internal timing mechanism (however no more than 50 ms to the future). This should make video playback somewhat more robust against timing inaccuracies caused by system load.
2009-11-15 03:39:22 +01:00
#endif
} else
MP_VERBOSE(vo, "framedrop/timing logic disabled by user.\n");
Implement vsync-aware frame timing for VDPAU Main things added are custom frame dropping for VDPAU to work around the display FPS limit, frame timing adjustment to avoid jitter when video frame times keep falling near vsyncs, and use of VDPAU's timing feature to keep one future frame queued in advance. NVIDIA's VDPAU implementation refuses to change the displayed frame more than once per vsync. This set a limit on how much video could be sped up, and caused problems for nearly all videos on low-FPS video projectors (playing 24 FPS video on a 24 FPS projector would not work reliably as MPlayer may need to slightly speed up the video for AV sync). This commit adds a framedrop mechanism that drops some frames so that no more than one is sent for display per vsync. The code tries to select the dropped frames smartly, selecting the best one to show for each vsync. Because of the timing features needed the drop functionality currently does not work if the correct-pts option is disabled. The code also adjusts frame timing slightly to avoid jitter. If you for example play 24 FPS video content on a 72 FPS display then normally a frame would be shown for 3 vsyncs, but if the frame times happen to fall near vsyncs and change between just before and just after then there could be frames alternating between 2 and 4 vsyncs. The code changes frame timing by up to one quarter vsync interval to avoid this. The above functionality depends on having reliable vsync timing information available. The display refresh rate is not directly provided by the VDPAU API. The current code uses information from the XF86VidMode extension if available; I'm not sure how common cases where that is inaccurate are. The refresh rate can be specified manually if necessary. After the changes in this commit MPlayer now always tries to keep one frame queued for future display using VDPAU's internal timing mechanism (however no more than 50 ms to the future). This should make video playback somewhat more robust against timing inaccuracies caused by system load.
2009-11-15 03:39:22 +01:00
return 0;
}
// Free everything specific to a certain video file
static void free_video_specific(struct vo *vo)
{
struct vdpctx *vc = vo->priv;
struct vdp_functions *vdp = vc->vdp;
VdpStatus vdp_st;
forget_frames(vo, false);
if (vc->screenshot_surface != VDP_INVALID_HANDLE) {
vdp_st = vdp->output_surface_destroy(vc->screenshot_surface);
2013-12-21 18:05:23 +01:00
CHECK_VDP_WARNING(vo, "Error when calling vdp_output_surface_destroy");
}
vc->screenshot_surface = VDP_INVALID_HANDLE;
for (int n = 0; n < NUM_BUFFERED_VIDEO; n++) {
assert(!vc->rgb_surfaces_used[n]);
if (vc->rgb_surfaces[n] != VDP_INVALID_HANDLE) {
vdp_st = vdp->output_surface_destroy(vc->rgb_surfaces[n]);
2013-12-21 18:05:23 +01:00
CHECK_VDP_WARNING(vo, "Error when calling vdp_output_surface_destroy");
}
vc->rgb_surfaces[n] = VDP_INVALID_HANDLE;
}
if (vc->black_pixel != VDP_INVALID_HANDLE) {
vdp_st = vdp->output_surface_destroy(vc->black_pixel);
2013-12-21 18:05:23 +01:00
CHECK_VDP_WARNING(vo, "Error when calling vdp_output_surface_destroy");
}
vc->black_pixel = VDP_INVALID_HANDLE;
}
static int get_rgb_format(int imgfmt)
{
switch (imgfmt) {
case IMGFMT_BGR32: return VDP_RGBA_FORMAT_B8G8R8A8;
default: return -1;
}
}
static int initialize_vdpau_objects(struct vo *vo)
{
struct vdpctx *vc = vo->priv;
struct vdp_functions *vdp = vc->vdp;
VdpStatus vdp_st;
vdpau: split off decoder parts, use "new" libavcodec vdpau hwaccel API Move the decoder parts from vo_vdpau.c to a new file vdpau_old.c. This file is named so because because it's written against the "old" libavcodec vdpau pseudo-decoder (e.g. "h264_vdpau"). Add support for the "new" libavcodec vdpau support. This was recently added and replaces the "old" vdpau parts. (In fact, Libav is about to deprecate and remove the "old" API without deprecation grace period, so we have to support it now. Moreover, there will probably be no Libav release which supports both, so the transition is even less smooth than we could hope, and we have to support both the old and new API.) Whether the old or new API is used is checked by a configure test: if the new API is found, it is used, otherwise the old API is assumed. Some details might be handled differently. Especially display preemption is a bit problematic with the "new" libavcodec vdpau support: it wants to keep a pointer to a specific vdpau API function (which can be driver specific, because preemption might switch drivers). Also, surface IDs are now directly stored in AVFrames (and mp_images), so they can't be forced to VDP_INVALID_HANDLE on preemption. (This changes even with older libavcodec versions, because mp_image always uses the newer representation to make vo_vdpau.c simpler.) Decoder initialization in the new code tries to deal with codec profiles, while the old code always uses the highest profile per codec. Surface allocation changes. Since the decoder won't call config() in vo_vdpau.c on video size change anymore, we allow allocating surfaces of arbitrary size instead of locking it to what the VO was configured. The non-hwdec code also has slightly different allocation behavior now. Enabling the old vdpau special decoders via e.g. --vd=lavc:h264_vdpau doesn't work anymore (a warning suggesting the --hwdec option is printed instead).
2013-07-28 01:49:45 +02:00
mp_vdpau_get_format(vc->image_format, &vc->vdp_chroma_type,
&vc->vdp_pixel_format);
vc->video_mixer->chroma_type = vc->vdp_chroma_type;
vc->video_mixer->initialized = false;
if (win_x11_init_vdpau_flip_queue(vo) < 0)
return -1;
if (vc->rgb_mode) {
int format = get_rgb_format(vc->image_format);
for (int n = 0; n < NUM_BUFFERED_VIDEO; n++) {
vdp_st = vdp->output_surface_create(vc->vdp_device,
format,
vc->vid_width, vc->vid_height,
&vc->rgb_surfaces[n]);
2013-12-21 18:05:23 +01:00
CHECK_VDP_ERROR(vo, "Allocating RGB surface");
}
vdp_st = vdp->output_surface_create(vc->vdp_device, OUTPUT_RGBA_FORMAT,
1, 1, &vc->black_pixel);
2013-12-21 18:05:23 +01:00
CHECK_VDP_ERROR(vo, "Allocating clearing surface");
const char data[4] = {0};
vdp_st = vdp->output_surface_put_bits_native(vc->black_pixel,
(const void*[]){data},
(uint32_t[]){4}, NULL);
2013-12-21 18:05:23 +01:00
CHECK_VDP_ERROR(vo, "Initializing clearing surface");
}
forget_frames(vo, false);
resize(vo);
return 0;
}
static void mark_vdpau_objects_uninitialized(struct vo *vo)
{
struct vdpctx *vc = vo->priv;
for (int i = 0; i < NUM_BUFFERED_VIDEO; i++)
vc->rgb_surfaces[i] = VDP_INVALID_HANDLE;
forget_frames(vo, false);
vc->black_pixel = VDP_INVALID_HANDLE;
vc->video_mixer->video_mixer = VDP_INVALID_HANDLE;
vc->flip_queue = VDP_INVALID_HANDLE;
vc->flip_target = VDP_INVALID_HANDLE;
for (int i = 0; i < MAX_OUTPUT_SURFACES; i++)
vc->output_surfaces[i] = VDP_INVALID_HANDLE;
vc->screenshot_surface = VDP_INVALID_HANDLE;
vc->vdp_device = VDP_INVALID_HANDLE;
for (int i = 0; i < MAX_OSD_PARTS; i++) {
struct osd_bitmap_surface *sfc = &vc->osd_surfaces[i];
talloc_free(sfc->packer);
sfc->bitmap_id = sfc->bitmap_pos_id = 0;
*sfc = (struct osd_bitmap_surface){
.surface = VDP_INVALID_HANDLE,
};
}
vc->output_surface_width = vc->output_surface_height = -1;
}
static int handle_preemption(struct vo *vo)
{
struct vdpctx *vc = vo->priv;
if (!mp_vdpau_status_ok(vc->mpvdp)) {
mark_vdpau_objects_uninitialized(vo);
return -1;
}
if (vc->preemption_counter == vc->mpvdp->preemption_counter)
return 0;
mark_vdpau_objects_uninitialized(vo);
vc->preemption_counter = vc->mpvdp->preemption_counter;
vc->vdp_device = vc->mpvdp->vdp_device;
if (initialize_vdpau_objects(vo) < 0)
return -1;
return 1;
}
vdpau: split off decoder parts, use "new" libavcodec vdpau hwaccel API Move the decoder parts from vo_vdpau.c to a new file vdpau_old.c. This file is named so because because it's written against the "old" libavcodec vdpau pseudo-decoder (e.g. "h264_vdpau"). Add support for the "new" libavcodec vdpau support. This was recently added and replaces the "old" vdpau parts. (In fact, Libav is about to deprecate and remove the "old" API without deprecation grace period, so we have to support it now. Moreover, there will probably be no Libav release which supports both, so the transition is even less smooth than we could hope, and we have to support both the old and new API.) Whether the old or new API is used is checked by a configure test: if the new API is found, it is used, otherwise the old API is assumed. Some details might be handled differently. Especially display preemption is a bit problematic with the "new" libavcodec vdpau support: it wants to keep a pointer to a specific vdpau API function (which can be driver specific, because preemption might switch drivers). Also, surface IDs are now directly stored in AVFrames (and mp_images), so they can't be forced to VDP_INVALID_HANDLE on preemption. (This changes even with older libavcodec versions, because mp_image always uses the newer representation to make vo_vdpau.c simpler.) Decoder initialization in the new code tries to deal with codec profiles, while the old code always uses the highest profile per codec. Surface allocation changes. Since the decoder won't call config() in vo_vdpau.c on video size change anymore, we allow allocating surfaces of arbitrary size instead of locking it to what the VO was configured. The non-hwdec code also has slightly different allocation behavior now. Enabling the old vdpau special decoders via e.g. --vd=lavc:h264_vdpau doesn't work anymore (a warning suggesting the --hwdec option is printed instead).
2013-07-28 01:49:45 +02:00
static bool status_ok(struct vo *vo)
{
return vo->config_ok && handle_preemption(vo) >= 0;
}
/*
* connect to X server, create and map window, initialize all
* VDPAU objects, create different surfaces etc.
*/
static int reconfig(struct vo *vo, struct mp_image_params *params, int flags)
{
struct vdpctx *vc = vo->priv;
if (handle_preemption(vo) < 0)
return -1;
vc->flip = flags & VOFLAG_FLIPPING;
vc->image_format = params->imgfmt;
vc->vid_width = params->w;
vc->vid_height = params->h;
2011-10-06 20:46:01 +02:00
vc->rgb_mode = get_rgb_format(params->imgfmt) >= 0;
free_video_specific(vo);
vo_x11_config_vo_window(vo, NULL, vo->dwidth, vo->dheight, flags, "vdpau");
if (initialize_vdpau_objects(vo) < 0)
return -1;
return 0;
}
static struct bitmap_packer *make_packer(struct vo *vo, VdpRGBAFormat format)
{
struct vdpctx *vc = vo->priv;
struct vdp_functions *vdp = vc->vdp;
2009-05-09 17:08:30 +02:00
struct bitmap_packer *packer = talloc_zero(vo, struct bitmap_packer);
uint32_t w_max = 0, h_max = 0;
VdpStatus vdp_st = vdp->
bitmap_surface_query_capabilities(vc->vdp_device, format,
&(VdpBool){0}, &w_max, &h_max);
2013-12-21 18:05:23 +01:00
CHECK_VDP_WARNING(vo, "Query to get max OSD surface size failed");
packer->w_max = w_max;
packer->h_max = h_max;
return packer;
}
static void draw_osd_part(struct vo *vo, int index)
{
struct vdpctx *vc = vo->priv;
struct vdp_functions *vdp = vc->vdp;
VdpStatus vdp_st;
struct osd_bitmap_surface *sfc = &vc->osd_surfaces[index];
VdpOutputSurface output_surface = vc->output_surfaces[vc->surface_num];
int i;
2009-05-09 17:08:30 +02:00
VdpOutputSurfaceRenderBlendState blend_state = {
.struct_version = VDP_OUTPUT_SURFACE_RENDER_BLEND_STATE_VERSION,
.blend_factor_source_color =
VDP_OUTPUT_SURFACE_RENDER_BLEND_FACTOR_SRC_ALPHA,
.blend_factor_source_alpha =
VDP_OUTPUT_SURFACE_RENDER_BLEND_FACTOR_ZERO,
2009-05-09 17:08:30 +02:00
.blend_factor_destination_color =
VDP_OUTPUT_SURFACE_RENDER_BLEND_FACTOR_ONE_MINUS_SRC_ALPHA,
.blend_factor_destination_alpha =
VDP_OUTPUT_SURFACE_RENDER_BLEND_FACTOR_ZERO,
2009-05-09 17:08:30 +02:00
.blend_equation_color = VDP_OUTPUT_SURFACE_RENDER_BLEND_EQUATION_ADD,
.blend_equation_alpha = VDP_OUTPUT_SURFACE_RENDER_BLEND_EQUATION_ADD,
};
VdpOutputSurfaceRenderBlendState blend_state_premultiplied = blend_state;
blend_state_premultiplied.blend_factor_source_color =
VDP_OUTPUT_SURFACE_RENDER_BLEND_FACTOR_ONE;
for (i = 0; i < sfc->render_count; i++) {
VdpOutputSurfaceRenderBlendState *blend = &blend_state;
if (sfc->format == VDP_RGBA_FORMAT_B8G8R8A8)
blend = &blend_state_premultiplied;
2009-05-09 17:08:30 +02:00
vdp_st = vdp->
output_surface_render_bitmap_surface(output_surface,
&sfc->targets[i].dest,
sfc->surface,
&sfc->targets[i].source,
&sfc->targets[i].color,
blend,
2009-05-09 17:08:30 +02:00
VDP_OUTPUT_SURFACE_RENDER_ROTATE_0);
2013-12-21 18:05:23 +01:00
CHECK_VDP_WARNING(vo, "OSD: Error when rendering");
}
}
static void generate_osd_part(struct vo *vo, struct sub_bitmaps *imgs)
{
struct vdpctx *vc = vo->priv;
struct vdp_functions *vdp = vc->vdp;
VdpStatus vdp_st;
struct osd_bitmap_surface *sfc = &vc->osd_surfaces[imgs->render_index];
bool need_upload = false;
if (imgs->bitmap_pos_id == sfc->bitmap_pos_id)
return; // Nothing changed and we still have the old data
sfc->render_count = 0;
if (imgs->format == SUBBITMAP_EMPTY || imgs->num_parts == 0)
return;
if (imgs->bitmap_id == sfc->bitmap_id)
goto osd_skip_upload;
need_upload = true;
VdpRGBAFormat format;
int format_size;
switch (imgs->format) {
case SUBBITMAP_LIBASS:
format = VDP_RGBA_FORMAT_A8;
format_size = 1;
break;
case SUBBITMAP_RGBA:
format = VDP_RGBA_FORMAT_B8G8R8A8;
format_size = 4;
break;
default:
abort();
};
if (sfc->format != format) {
talloc_free(sfc->packer);
sfc->packer = NULL;
};
sfc->format = format;
if (!sfc->packer)
sfc->packer = make_packer(vo, format);
sfc->packer->padding = imgs->scaled; // assume 2x2 filter on scaling
int r = packer_pack_from_subbitmaps(sfc->packer, imgs);
if (r < 0) {
MP_ERR(vo, "OSD bitmaps do not fit on a surface with the maximum "
"supported size\n");
return;
} else if (r == 1) {
if (sfc->surface != VDP_INVALID_HANDLE) {
vdp_st = vdp->bitmap_surface_destroy(sfc->surface);
2013-12-21 18:05:23 +01:00
CHECK_VDP_WARNING(vo, "Error when calling vdp_bitmap_surface_destroy");
}
MP_VERBOSE(vo, "Allocating a %dx%d surface for OSD bitmaps.\n",
sfc->packer->w, sfc->packer->h);
vdp_st = vdp->bitmap_surface_create(vc->vdp_device, format,
sfc->packer->w, sfc->packer->h,
true, &sfc->surface);
vo_vdpau: Allocate one large surface for EOSD content Create a single large bitmap surface for EOSD objects and pack all the bitmap rectangles inside that. The old code created a separate bitmap surface for every bitmap and then resized the cached surfaces when drawing later frames. The number of surfaces could be large (at least about 2000 for one sample subtitle script) so this was very inefficient. The old code also used a very simple strategy for pairing existing surfaces to new bitmaps; it could resize tiny surfaces to hold large glyphs while using existing large surfaces to hold tiny glyphs and as a result allocate arbitrarily much more total surface area than was necessary. The new code only supports using a single surface, freeing it and allocating a larger one if necessary. It would be possible to support multiple surfaces in case of hitting the maximum bitmap surface size, but I'll wait to see if that is actually needed before implementing it. NVIDIA seems to support bitmap surface sizes up to 8192x8192, so it would take either a really pathological subtitle script rendered at a high resolution or an implementation with lower limits before multiple surfaces would be necessary. The packing algorithm should successfully pack the bitmaps into a surface of size w*h as long as the total area of the bitmaps does not exceed 16/17 (w-max_bitmap_width)*(h-max_bitmap_height), so there should be no totally catastrophic failure cases. The 16/17 factor comes from approximate sorting used in the algorithm. On average performance should be better than this minimum guaranteed level.
2009-09-02 19:21:24 +02:00
if (vdp_st != VDP_STATUS_OK)
sfc->surface = VDP_INVALID_HANDLE;
2013-12-21 18:05:23 +01:00
CHECK_VDP_WARNING(vo, "OSD: error when creating surface");
}
if (imgs->scaled) {
char zeros[sfc->packer->used_width * format_size];
memset(zeros, 0, sizeof(zeros));
vdp_st = vdp->bitmap_surface_put_bits_native(sfc->surface,
&(const void *){zeros}, &(uint32_t){0},
&(VdpRect){0, 0, sfc->packer->used_width,
sfc->packer->used_height});
}
osd_skip_upload:
if (sfc->surface == VDP_INVALID_HANDLE)
vo_vdpau: Allocate one large surface for EOSD content Create a single large bitmap surface for EOSD objects and pack all the bitmap rectangles inside that. The old code created a separate bitmap surface for every bitmap and then resized the cached surfaces when drawing later frames. The number of surfaces could be large (at least about 2000 for one sample subtitle script) so this was very inefficient. The old code also used a very simple strategy for pairing existing surfaces to new bitmaps; it could resize tiny surfaces to hold large glyphs while using existing large surfaces to hold tiny glyphs and as a result allocate arbitrarily much more total surface area than was necessary. The new code only supports using a single surface, freeing it and allocating a larger one if necessary. It would be possible to support multiple surfaces in case of hitting the maximum bitmap surface size, but I'll wait to see if that is actually needed before implementing it. NVIDIA seems to support bitmap surface sizes up to 8192x8192, so it would take either a really pathological subtitle script rendered at a high resolution or an implementation with lower limits before multiple surfaces would be necessary. The packing algorithm should successfully pack the bitmaps into a surface of size w*h as long as the total area of the bitmaps does not exceed 16/17 (w-max_bitmap_width)*(h-max_bitmap_height), so there should be no totally catastrophic failure cases. The 16/17 factor comes from approximate sorting used in the algorithm. On average performance should be better than this minimum guaranteed level.
2009-09-02 19:21:24 +02:00
return;
if (sfc->packer->count > sfc->targets_size) {
talloc_free(sfc->targets);
sfc->targets_size = sfc->packer->count;
sfc->targets = talloc_size(vc, sfc->targets_size
* sizeof(*sfc->targets));
}
for (int i = 0 ;i < sfc->packer->count; i++) {
struct sub_bitmap *b = &imgs->parts[i];
struct osd_target *target = sfc->targets + sfc->render_count;
int x = sfc->packer->result[i].x;
int y = sfc->packer->result[i].y;
target->source = (VdpRect){x, y, x + b->w, y + b->h};
target->dest = (VdpRect){b->x, b->y, b->x + b->dw, b->y + b->dh};
target->color = (VdpColor){1, 1, 1, 1};
if (imgs->format == SUBBITMAP_LIBASS) {
uint32_t color = b->libass.color;
target->color.alpha = 1.0 - ((color >> 0) & 0xff) / 255.0;
target->color.blue = ((color >> 8) & 0xff) / 255.0;
target->color.green = ((color >> 16) & 0xff) / 255.0;
target->color.red = ((color >> 24) & 0xff) / 255.0;
}
if (need_upload) {
vdp_st = vdp->
bitmap_surface_put_bits_native(sfc->surface,
&(const void *){b->bitmap},
&(uint32_t){b->stride},
&target->source);
2013-12-21 18:05:23 +01:00
CHECK_VDP_WARNING(vo, "OSD: putbits failed");
}
sfc->render_count++;
}
sfc->bitmap_id = imgs->bitmap_id;
sfc->bitmap_pos_id = imgs->bitmap_pos_id;
}
static void draw_osd_cb(void *ctx, struct sub_bitmaps *imgs)
{
struct vo *vo = ctx;
generate_osd_part(vo, imgs);
draw_osd_part(vo, imgs->render_index);
}
static void draw_osd(struct vo *vo, struct osd_state *osd)
{
struct vdpctx *vc = vo->priv;
if (!status_ok(vo))
return;
static const bool formats[SUBBITMAP_COUNT] = {
[SUBBITMAP_LIBASS] = true,
[SUBBITMAP_RGBA] = true,
};
osd_draw(osd, vc->osd_rect, osd_get_vo_pts(osd), 0, formats, draw_osd_cb, vo);
}
static int update_presentation_queue_status(struct vo *vo)
{
struct vdpctx *vc = vo->priv;
struct vdp_functions *vdp = vc->vdp;
VdpStatus vdp_st;
2009-05-09 17:08:30 +02:00
while (vc->query_surface_num != vc->surface_num) {
VdpTime vtime;
VdpPresentationQueueStatus status;
VdpOutputSurface surface = vc->output_surfaces[vc->query_surface_num];
vdp_st = vdp->presentation_queue_query_surface_status(vc->flip_queue,
surface,
&status, &vtime);
2013-12-21 18:05:23 +01:00
CHECK_VDP_WARNING(vo, "Error calling "
"presentation_queue_query_surface_status");
if (mp_msg_test(vo->log, MSGL_TRACE)) {
VdpTime current;
vdp_st = vdp->presentation_queue_get_time(vc->flip_queue, &current);
CHECK_VDP_WARNING(vo, "Error when calling "
"vdp_presentation_queue_get_time");
MP_TRACE(vo, "Vdpau time: %"PRIu64"\n", (uint64_t)current);
MP_TRACE(vo, "Surface %d status: %d time: %"PRIu64"\n",
(int)surface, (int)status, (uint64_t)vtime);
}
if (status == VDP_PRESENTATION_QUEUE_STATUS_QUEUED)
break;
if (vc->vsync_interval > 1) {
uint64_t qtime = vc->queue_time[vc->query_surface_num];
int diff = ((int64_t)vtime - (int64_t)qtime) / 1e6;
MP_TRACE(vo, "Queue time difference: %d ms\n", diff);
if (vtime < qtime + vc->vsync_interval / 2)
MP_VERBOSE(vo, "Frame shown too early (%d ms)\n", diff);
if (vtime > qtime + vc->vsync_interval)
MP_VERBOSE(vo, "Frame shown late (%d ms)\n", diff);
}
vc->query_surface_num = WRAP_ADD(vc->query_surface_num, 1,
vc->num_output_surfaces);
vc->recent_vsync_time = vtime;
}
int num_queued = WRAP_ADD(vc->surface_num, -vc->query_surface_num,
vc->num_output_surfaces);
MP_DBG(vo, "Queued surface count (before add): %d\n", num_queued);
return num_queued;
Implement vsync-aware frame timing for VDPAU Main things added are custom frame dropping for VDPAU to work around the display FPS limit, frame timing adjustment to avoid jitter when video frame times keep falling near vsyncs, and use of VDPAU's timing feature to keep one future frame queued in advance. NVIDIA's VDPAU implementation refuses to change the displayed frame more than once per vsync. This set a limit on how much video could be sped up, and caused problems for nearly all videos on low-FPS video projectors (playing 24 FPS video on a 24 FPS projector would not work reliably as MPlayer may need to slightly speed up the video for AV sync). This commit adds a framedrop mechanism that drops some frames so that no more than one is sent for display per vsync. The code tries to select the dropped frames smartly, selecting the best one to show for each vsync. Because of the timing features needed the drop functionality currently does not work if the correct-pts option is disabled. The code also adjusts frame timing slightly to avoid jitter. If you for example play 24 FPS video content on a 72 FPS display then normally a frame would be shown for 3 vsyncs, but if the frame times happen to fall near vsyncs and change between just before and just after then there could be frames alternating between 2 and 4 vsyncs. The code changes frame timing by up to one quarter vsync interval to avoid this. The above functionality depends on having reliable vsync timing information available. The display refresh rate is not directly provided by the VDPAU API. The current code uses information from the XF86VidMode extension if available; I'm not sure how common cases where that is inaccurate are. The refresh rate can be specified manually if necessary. After the changes in this commit MPlayer now always tries to keep one frame queued for future display using VDPAU's internal timing mechanism (however no more than 50 ms to the future). This should make video playback somewhat more robust against timing inaccuracies caused by system load.
2009-11-15 03:39:22 +01:00
}
// Return the timestamp of the vsync that must have happened before ts.
static inline uint64_t prev_vsync(struct vdpctx *vc, uint64_t ts)
Implement vsync-aware frame timing for VDPAU Main things added are custom frame dropping for VDPAU to work around the display FPS limit, frame timing adjustment to avoid jitter when video frame times keep falling near vsyncs, and use of VDPAU's timing feature to keep one future frame queued in advance. NVIDIA's VDPAU implementation refuses to change the displayed frame more than once per vsync. This set a limit on how much video could be sped up, and caused problems for nearly all videos on low-FPS video projectors (playing 24 FPS video on a 24 FPS projector would not work reliably as MPlayer may need to slightly speed up the video for AV sync). This commit adds a framedrop mechanism that drops some frames so that no more than one is sent for display per vsync. The code tries to select the dropped frames smartly, selecting the best one to show for each vsync. Because of the timing features needed the drop functionality currently does not work if the correct-pts option is disabled. The code also adjusts frame timing slightly to avoid jitter. If you for example play 24 FPS video content on a 72 FPS display then normally a frame would be shown for 3 vsyncs, but if the frame times happen to fall near vsyncs and change between just before and just after then there could be frames alternating between 2 and 4 vsyncs. The code changes frame timing by up to one quarter vsync interval to avoid this. The above functionality depends on having reliable vsync timing information available. The display refresh rate is not directly provided by the VDPAU API. The current code uses information from the XF86VidMode extension if available; I'm not sure how common cases where that is inaccurate are. The refresh rate can be specified manually if necessary. After the changes in this commit MPlayer now always tries to keep one frame queued for future display using VDPAU's internal timing mechanism (however no more than 50 ms to the future). This should make video playback somewhat more robust against timing inaccuracies caused by system load.
2009-11-15 03:39:22 +01:00
{
int64_t diff = (int64_t)(ts - vc->recent_vsync_time);
int64_t offset = diff % vc->vsync_interval;
if (offset < 0)
offset += vc->vsync_interval;
Implement vsync-aware frame timing for VDPAU Main things added are custom frame dropping for VDPAU to work around the display FPS limit, frame timing adjustment to avoid jitter when video frame times keep falling near vsyncs, and use of VDPAU's timing feature to keep one future frame queued in advance. NVIDIA's VDPAU implementation refuses to change the displayed frame more than once per vsync. This set a limit on how much video could be sped up, and caused problems for nearly all videos on low-FPS video projectors (playing 24 FPS video on a 24 FPS projector would not work reliably as MPlayer may need to slightly speed up the video for AV sync). This commit adds a framedrop mechanism that drops some frames so that no more than one is sent for display per vsync. The code tries to select the dropped frames smartly, selecting the best one to show for each vsync. Because of the timing features needed the drop functionality currently does not work if the correct-pts option is disabled. The code also adjusts frame timing slightly to avoid jitter. If you for example play 24 FPS video content on a 72 FPS display then normally a frame would be shown for 3 vsyncs, but if the frame times happen to fall near vsyncs and change between just before and just after then there could be frames alternating between 2 and 4 vsyncs. The code changes frame timing by up to one quarter vsync interval to avoid this. The above functionality depends on having reliable vsync timing information available. The display refresh rate is not directly provided by the VDPAU API. The current code uses information from the XF86VidMode extension if available; I'm not sure how common cases where that is inaccurate are. The refresh rate can be specified manually if necessary. After the changes in this commit MPlayer now always tries to keep one frame queued for future display using VDPAU's internal timing mechanism (however no more than 50 ms to the future). This should make video playback somewhat more robust against timing inaccuracies caused by system load.
2009-11-15 03:39:22 +01:00
return ts - offset;
}
static void flip_page_timed(struct vo *vo, int64_t pts_us, int duration)
Implement vsync-aware frame timing for VDPAU Main things added are custom frame dropping for VDPAU to work around the display FPS limit, frame timing adjustment to avoid jitter when video frame times keep falling near vsyncs, and use of VDPAU's timing feature to keep one future frame queued in advance. NVIDIA's VDPAU implementation refuses to change the displayed frame more than once per vsync. This set a limit on how much video could be sped up, and caused problems for nearly all videos on low-FPS video projectors (playing 24 FPS video on a 24 FPS projector would not work reliably as MPlayer may need to slightly speed up the video for AV sync). This commit adds a framedrop mechanism that drops some frames so that no more than one is sent for display per vsync. The code tries to select the dropped frames smartly, selecting the best one to show for each vsync. Because of the timing features needed the drop functionality currently does not work if the correct-pts option is disabled. The code also adjusts frame timing slightly to avoid jitter. If you for example play 24 FPS video content on a 72 FPS display then normally a frame would be shown for 3 vsyncs, but if the frame times happen to fall near vsyncs and change between just before and just after then there could be frames alternating between 2 and 4 vsyncs. The code changes frame timing by up to one quarter vsync interval to avoid this. The above functionality depends on having reliable vsync timing information available. The display refresh rate is not directly provided by the VDPAU API. The current code uses information from the XF86VidMode extension if available; I'm not sure how common cases where that is inaccurate are. The refresh rate can be specified manually if necessary. After the changes in this commit MPlayer now always tries to keep one frame queued for future display using VDPAU's internal timing mechanism (however no more than 50 ms to the future). This should make video playback somewhat more robust against timing inaccuracies caused by system load.
2009-11-15 03:39:22 +01:00
{
struct vdpctx *vc = vo->priv;
struct vdp_functions *vdp = vc->vdp;
VdpStatus vdp_st;
uint32_t vsync_interval = vc->vsync_interval;
if (handle_preemption(vo) < 0)
return;
Implement vsync-aware frame timing for VDPAU Main things added are custom frame dropping for VDPAU to work around the display FPS limit, frame timing adjustment to avoid jitter when video frame times keep falling near vsyncs, and use of VDPAU's timing feature to keep one future frame queued in advance. NVIDIA's VDPAU implementation refuses to change the displayed frame more than once per vsync. This set a limit on how much video could be sped up, and caused problems for nearly all videos on low-FPS video projectors (playing 24 FPS video on a 24 FPS projector would not work reliably as MPlayer may need to slightly speed up the video for AV sync). This commit adds a framedrop mechanism that drops some frames so that no more than one is sent for display per vsync. The code tries to select the dropped frames smartly, selecting the best one to show for each vsync. Because of the timing features needed the drop functionality currently does not work if the correct-pts option is disabled. The code also adjusts frame timing slightly to avoid jitter. If you for example play 24 FPS video content on a 72 FPS display then normally a frame would be shown for 3 vsyncs, but if the frame times happen to fall near vsyncs and change between just before and just after then there could be frames alternating between 2 and 4 vsyncs. The code changes frame timing by up to one quarter vsync interval to avoid this. The above functionality depends on having reliable vsync timing information available. The display refresh rate is not directly provided by the VDPAU API. The current code uses information from the XF86VidMode extension if available; I'm not sure how common cases where that is inaccurate are. The refresh rate can be specified manually if necessary. After the changes in this commit MPlayer now always tries to keep one frame queued for future display using VDPAU's internal timing mechanism (however no more than 50 ms to the future). This should make video playback somewhat more robust against timing inaccuracies caused by system load.
2009-11-15 03:39:22 +01:00
if (duration > INT_MAX / 1000)
duration = -1;
else
duration *= 1000;
if (vc->vsync_interval == 1)
Implement vsync-aware frame timing for VDPAU Main things added are custom frame dropping for VDPAU to work around the display FPS limit, frame timing adjustment to avoid jitter when video frame times keep falling near vsyncs, and use of VDPAU's timing feature to keep one future frame queued in advance. NVIDIA's VDPAU implementation refuses to change the displayed frame more than once per vsync. This set a limit on how much video could be sped up, and caused problems for nearly all videos on low-FPS video projectors (playing 24 FPS video on a 24 FPS projector would not work reliably as MPlayer may need to slightly speed up the video for AV sync). This commit adds a framedrop mechanism that drops some frames so that no more than one is sent for display per vsync. The code tries to select the dropped frames smartly, selecting the best one to show for each vsync. Because of the timing features needed the drop functionality currently does not work if the correct-pts option is disabled. The code also adjusts frame timing slightly to avoid jitter. If you for example play 24 FPS video content on a 72 FPS display then normally a frame would be shown for 3 vsyncs, but if the frame times happen to fall near vsyncs and change between just before and just after then there could be frames alternating between 2 and 4 vsyncs. The code changes frame timing by up to one quarter vsync interval to avoid this. The above functionality depends on having reliable vsync timing information available. The display refresh rate is not directly provided by the VDPAU API. The current code uses information from the XF86VidMode extension if available; I'm not sure how common cases where that is inaccurate are. The refresh rate can be specified manually if necessary. After the changes in this commit MPlayer now always tries to keep one frame queued for future display using VDPAU's internal timing mechanism (however no more than 50 ms to the future). This should make video playback somewhat more robust against timing inaccuracies caused by system load.
2009-11-15 03:39:22 +01:00
duration = -1; // Make sure drop logic is disabled
vo_vdpau: simplify time management and make it more robust vo_vdpau used a somewhat complicated and fragile mechanism to convert the vdpau time to internal mpv time. This was fragile as in it couldn't deal well with Mesa's (apparently) random timestamps, which can change the base offset in multiple situations. It can happen when moving the mpv window to a different screen, and somehow it also happens when pausing the player. It seems this mechanism to synchronize the vdpau time is not actually needed. There are only 2 places where sync_vdptime() is used (i.e. returning the current vdpau time interpolated by system time). The first call is for determining the PTS used to queue a frame. This also uses convert_to_vdptime(). It's easily replaced by querying the time directly, and adding the wait time to it (rel_pts_ns in the patch). The second call is pretty odd: it updates the vdpau time a second time in the same function. From what I can see, this can matter only if update_presentation_queue_status() is very slow. I'm not sure what to make out of this, because the call merely queries the presentation queue. Just assume it isn't slow, and that we don't have to update the time. Another potential issue with this is that we call VdpPresentationQueueGetTime() every frame now, instead of every 5 seconds and interpolating the other calls via system time. More over, this is per video frame (which can be portantially dropped, and not per actually displayed frame. Assume this doesn't matter. This simplifies the code, and should make it more robust on Mesa. But note that what Mesa does is obviously insane - this is one situation where you really need a stable time source. There are still plenty of race condition windows where things can go wrong, although this commit should drastically reduce the possibility of this. In my tests, everything worked well. But I have no access to a Mesa system with vdpau, so it needs testing by others. See github issues #520, #694, #695.
2014-04-07 18:33:25 +02:00
VdpTime vdp_time = 0;
vdp_st = vdp->presentation_queue_get_time(vc->flip_queue, &vdp_time);
CHECK_VDP_WARNING(vo, "Error when calling vdp_presentation_queue_get_time");
int64_t rel_pts_ns = (pts_us - mp_time_us()) * 1000;
if (!pts_us || rel_pts_ns < 0)
rel_pts_ns = 0;
vo_vdpau: simplify time management and make it more robust vo_vdpau used a somewhat complicated and fragile mechanism to convert the vdpau time to internal mpv time. This was fragile as in it couldn't deal well with Mesa's (apparently) random timestamps, which can change the base offset in multiple situations. It can happen when moving the mpv window to a different screen, and somehow it also happens when pausing the player. It seems this mechanism to synchronize the vdpau time is not actually needed. There are only 2 places where sync_vdptime() is used (i.e. returning the current vdpau time interpolated by system time). The first call is for determining the PTS used to queue a frame. This also uses convert_to_vdptime(). It's easily replaced by querying the time directly, and adding the wait time to it (rel_pts_ns in the patch). The second call is pretty odd: it updates the vdpau time a second time in the same function. From what I can see, this can matter only if update_presentation_queue_status() is very slow. I'm not sure what to make out of this, because the call merely queries the presentation queue. Just assume it isn't slow, and that we don't have to update the time. Another potential issue with this is that we call VdpPresentationQueueGetTime() every frame now, instead of every 5 seconds and interpolating the other calls via system time. More over, this is per video frame (which can be portantially dropped, and not per actually displayed frame. Assume this doesn't matter. This simplifies the code, and should make it more robust on Mesa. But note that what Mesa does is obviously insane - this is one situation where you really need a stable time source. There are still plenty of race condition windows where things can go wrong, although this commit should drastically reduce the possibility of this. In my tests, everything worked well. But I have no access to a Mesa system with vdpau, so it needs testing by others. See github issues #520, #694, #695.
2014-04-07 18:33:25 +02:00
uint64_t now = vdp_time;
uint64_t pts = now + rel_pts_ns;
Implement vsync-aware frame timing for VDPAU Main things added are custom frame dropping for VDPAU to work around the display FPS limit, frame timing adjustment to avoid jitter when video frame times keep falling near vsyncs, and use of VDPAU's timing feature to keep one future frame queued in advance. NVIDIA's VDPAU implementation refuses to change the displayed frame more than once per vsync. This set a limit on how much video could be sped up, and caused problems for nearly all videos on low-FPS video projectors (playing 24 FPS video on a 24 FPS projector would not work reliably as MPlayer may need to slightly speed up the video for AV sync). This commit adds a framedrop mechanism that drops some frames so that no more than one is sent for display per vsync. The code tries to select the dropped frames smartly, selecting the best one to show for each vsync. Because of the timing features needed the drop functionality currently does not work if the correct-pts option is disabled. The code also adjusts frame timing slightly to avoid jitter. If you for example play 24 FPS video content on a 72 FPS display then normally a frame would be shown for 3 vsyncs, but if the frame times happen to fall near vsyncs and change between just before and just after then there could be frames alternating between 2 and 4 vsyncs. The code changes frame timing by up to one quarter vsync interval to avoid this. The above functionality depends on having reliable vsync timing information available. The display refresh rate is not directly provided by the VDPAU API. The current code uses information from the XF86VidMode extension if available; I'm not sure how common cases where that is inaccurate are. The refresh rate can be specified manually if necessary. After the changes in this commit MPlayer now always tries to keep one frame queued for future display using VDPAU's internal timing mechanism (however no more than 50 ms to the future). This should make video playback somewhat more robust against timing inaccuracies caused by system load.
2009-11-15 03:39:22 +01:00
uint64_t ideal_pts = pts;
uint64_t npts = duration >= 0 ? pts + duration : UINT64_MAX;
/* This should normally never happen.
* - The last queued frame can't have a PTS that goes more than 50ms in the
* future. This is guaranteed by the playloop, which currently actually
* roughly queues 50ms ahead, plus the flip queue offset. Just to be sure
* give some additional room by doubling the time.
* - The last vsync can never be in the future.
*/
int64_t max_pts_ahead = (vo->flip_queue_offset + 0.050) * 2 * 1e9;
if (vc->last_queue_time > now + max_pts_ahead ||
vc->recent_vsync_time > now)
{
vc->last_queue_time = 0;
vc->recent_vsync_time = 0;
MP_WARN(vo, "Inconsistent timing detected.\n");
}
#define PREV_VSYNC(ts) prev_vsync(vc, ts)
Implement vsync-aware frame timing for VDPAU Main things added are custom frame dropping for VDPAU to work around the display FPS limit, frame timing adjustment to avoid jitter when video frame times keep falling near vsyncs, and use of VDPAU's timing feature to keep one future frame queued in advance. NVIDIA's VDPAU implementation refuses to change the displayed frame more than once per vsync. This set a limit on how much video could be sped up, and caused problems for nearly all videos on low-FPS video projectors (playing 24 FPS video on a 24 FPS projector would not work reliably as MPlayer may need to slightly speed up the video for AV sync). This commit adds a framedrop mechanism that drops some frames so that no more than one is sent for display per vsync. The code tries to select the dropped frames smartly, selecting the best one to show for each vsync. Because of the timing features needed the drop functionality currently does not work if the correct-pts option is disabled. The code also adjusts frame timing slightly to avoid jitter. If you for example play 24 FPS video content on a 72 FPS display then normally a frame would be shown for 3 vsyncs, but if the frame times happen to fall near vsyncs and change between just before and just after then there could be frames alternating between 2 and 4 vsyncs. The code changes frame timing by up to one quarter vsync interval to avoid this. The above functionality depends on having reliable vsync timing information available. The display refresh rate is not directly provided by the VDPAU API. The current code uses information from the XF86VidMode extension if available; I'm not sure how common cases where that is inaccurate are. The refresh rate can be specified manually if necessary. After the changes in this commit MPlayer now always tries to keep one frame queued for future display using VDPAU's internal timing mechanism (however no more than 50 ms to the future). This should make video playback somewhat more robust against timing inaccuracies caused by system load.
2009-11-15 03:39:22 +01:00
/* We hope to be here at least one vsync before the frame should be shown.
* If we are running late then don't drop the frame unless there is
* already one queued for the next vsync; even if we _hope_ to show the
* next frame soon enough to mean this one should be dropped we might
* not make the target time in reality. Without this check we could drop
* every frame, freezing the display completely if video lags behind.
*/
if (now > PREV_VSYNC(FFMAX(pts, vc->last_queue_time + vsync_interval)))
Implement vsync-aware frame timing for VDPAU Main things added are custom frame dropping for VDPAU to work around the display FPS limit, frame timing adjustment to avoid jitter when video frame times keep falling near vsyncs, and use of VDPAU's timing feature to keep one future frame queued in advance. NVIDIA's VDPAU implementation refuses to change the displayed frame more than once per vsync. This set a limit on how much video could be sped up, and caused problems for nearly all videos on low-FPS video projectors (playing 24 FPS video on a 24 FPS projector would not work reliably as MPlayer may need to slightly speed up the video for AV sync). This commit adds a framedrop mechanism that drops some frames so that no more than one is sent for display per vsync. The code tries to select the dropped frames smartly, selecting the best one to show for each vsync. Because of the timing features needed the drop functionality currently does not work if the correct-pts option is disabled. The code also adjusts frame timing slightly to avoid jitter. If you for example play 24 FPS video content on a 72 FPS display then normally a frame would be shown for 3 vsyncs, but if the frame times happen to fall near vsyncs and change between just before and just after then there could be frames alternating between 2 and 4 vsyncs. The code changes frame timing by up to one quarter vsync interval to avoid this. The above functionality depends on having reliable vsync timing information available. The display refresh rate is not directly provided by the VDPAU API. The current code uses information from the XF86VidMode extension if available; I'm not sure how common cases where that is inaccurate are. The refresh rate can be specified manually if necessary. After the changes in this commit MPlayer now always tries to keep one frame queued for future display using VDPAU's internal timing mechanism (however no more than 50 ms to the future). This should make video playback somewhat more robust against timing inaccuracies caused by system load.
2009-11-15 03:39:22 +01:00
npts = UINT64_MAX;
/* Allow flipping a frame at a vsync if its presentation time is a
* bit after that vsync and the change makes the flip time delta
* from previous frame better match the target timestamp delta.
* This avoids instability with frame timestamps falling near vsyncs.
* For example if the frame timestamps were (with vsyncs at
* integer values) 0.01, 1.99, 4.01, 5.99, 8.01, ... then
* straightforward timing at next vsync would flip the frames at
* 1, 2, 5, 6, 9; this changes it to 1, 2, 4, 6, 8 and so on with
* regular 2-vsync intervals.
*
* Also allow moving the frame forward if it looks like we dropped
* the previous frame incorrectly (now that we know better after
* having final exact timestamp information for this frame) and
* there would unnecessarily be a vsync without a frame change.
*/
uint64_t vsync = PREV_VSYNC(pts);
if (pts < vsync + vsync_interval / 4
&& (vsync - PREV_VSYNC(vc->last_queue_time)
Implement vsync-aware frame timing for VDPAU Main things added are custom frame dropping for VDPAU to work around the display FPS limit, frame timing adjustment to avoid jitter when video frame times keep falling near vsyncs, and use of VDPAU's timing feature to keep one future frame queued in advance. NVIDIA's VDPAU implementation refuses to change the displayed frame more than once per vsync. This set a limit on how much video could be sped up, and caused problems for nearly all videos on low-FPS video projectors (playing 24 FPS video on a 24 FPS projector would not work reliably as MPlayer may need to slightly speed up the video for AV sync). This commit adds a framedrop mechanism that drops some frames so that no more than one is sent for display per vsync. The code tries to select the dropped frames smartly, selecting the best one to show for each vsync. Because of the timing features needed the drop functionality currently does not work if the correct-pts option is disabled. The code also adjusts frame timing slightly to avoid jitter. If you for example play 24 FPS video content on a 72 FPS display then normally a frame would be shown for 3 vsyncs, but if the frame times happen to fall near vsyncs and change between just before and just after then there could be frames alternating between 2 and 4 vsyncs. The code changes frame timing by up to one quarter vsync interval to avoid this. The above functionality depends on having reliable vsync timing information available. The display refresh rate is not directly provided by the VDPAU API. The current code uses information from the XF86VidMode extension if available; I'm not sure how common cases where that is inaccurate are. The refresh rate can be specified manually if necessary. After the changes in this commit MPlayer now always tries to keep one frame queued for future display using VDPAU's internal timing mechanism (however no more than 50 ms to the future). This should make video playback somewhat more robust against timing inaccuracies caused by system load.
2009-11-15 03:39:22 +01:00
> pts - vc->last_ideal_time + vsync_interval / 2
|| vc->dropped_frame && vsync > vc->dropped_time))
pts -= vsync_interval / 2;
vc->dropped_frame = true; // changed at end if false
vc->dropped_time = ideal_pts;
pts = FFMAX(pts, vc->last_queue_time + vsync_interval);
pts = FFMAX(pts, now);
if (npts < PREV_VSYNC(pts) + vsync_interval)
return;
int num_flips = update_presentation_queue_status(vo);
vsync = vc->recent_vsync_time + num_flips * vc->vsync_interval;
Implement vsync-aware frame timing for VDPAU Main things added are custom frame dropping for VDPAU to work around the display FPS limit, frame timing adjustment to avoid jitter when video frame times keep falling near vsyncs, and use of VDPAU's timing feature to keep one future frame queued in advance. NVIDIA's VDPAU implementation refuses to change the displayed frame more than once per vsync. This set a limit on how much video could be sped up, and caused problems for nearly all videos on low-FPS video projectors (playing 24 FPS video on a 24 FPS projector would not work reliably as MPlayer may need to slightly speed up the video for AV sync). This commit adds a framedrop mechanism that drops some frames so that no more than one is sent for display per vsync. The code tries to select the dropped frames smartly, selecting the best one to show for each vsync. Because of the timing features needed the drop functionality currently does not work if the correct-pts option is disabled. The code also adjusts frame timing slightly to avoid jitter. If you for example play 24 FPS video content on a 72 FPS display then normally a frame would be shown for 3 vsyncs, but if the frame times happen to fall near vsyncs and change between just before and just after then there could be frames alternating between 2 and 4 vsyncs. The code changes frame timing by up to one quarter vsync interval to avoid this. The above functionality depends on having reliable vsync timing information available. The display refresh rate is not directly provided by the VDPAU API. The current code uses information from the XF86VidMode extension if available; I'm not sure how common cases where that is inaccurate are. The refresh rate can be specified manually if necessary. After the changes in this commit MPlayer now always tries to keep one frame queued for future display using VDPAU's internal timing mechanism (however no more than 50 ms to the future). This should make video playback somewhat more robust against timing inaccuracies caused by system load.
2009-11-15 03:39:22 +01:00
pts = FFMAX(pts, now);
pts = FFMAX(pts, vsync + (vsync_interval >> 2));
Implement vsync-aware frame timing for VDPAU Main things added are custom frame dropping for VDPAU to work around the display FPS limit, frame timing adjustment to avoid jitter when video frame times keep falling near vsyncs, and use of VDPAU's timing feature to keep one future frame queued in advance. NVIDIA's VDPAU implementation refuses to change the displayed frame more than once per vsync. This set a limit on how much video could be sped up, and caused problems for nearly all videos on low-FPS video projectors (playing 24 FPS video on a 24 FPS projector would not work reliably as MPlayer may need to slightly speed up the video for AV sync). This commit adds a framedrop mechanism that drops some frames so that no more than one is sent for display per vsync. The code tries to select the dropped frames smartly, selecting the best one to show for each vsync. Because of the timing features needed the drop functionality currently does not work if the correct-pts option is disabled. The code also adjusts frame timing slightly to avoid jitter. If you for example play 24 FPS video content on a 72 FPS display then normally a frame would be shown for 3 vsyncs, but if the frame times happen to fall near vsyncs and change between just before and just after then there could be frames alternating between 2 and 4 vsyncs. The code changes frame timing by up to one quarter vsync interval to avoid this. The above functionality depends on having reliable vsync timing information available. The display refresh rate is not directly provided by the VDPAU API. The current code uses information from the XF86VidMode extension if available; I'm not sure how common cases where that is inaccurate are. The refresh rate can be specified manually if necessary. After the changes in this commit MPlayer now always tries to keep one frame queued for future display using VDPAU's internal timing mechanism (however no more than 50 ms to the future). This should make video playback somewhat more robust against timing inaccuracies caused by system load.
2009-11-15 03:39:22 +01:00
vsync = PREV_VSYNC(pts);
if (npts < vsync + vsync_interval)
return;
pts = vsync + (vsync_interval >> 2);
VdpOutputSurface frame = vc->output_surfaces[vc->surface_num];
vdp_st = vdp->presentation_queue_display(vc->flip_queue, frame,
vo->dwidth, vo->dheight, pts);
2013-12-21 18:05:23 +01:00
CHECK_VDP_WARNING(vo, "Error when calling vdp_presentation_queue_display");
vo_vdpau: simplify time management and make it more robust vo_vdpau used a somewhat complicated and fragile mechanism to convert the vdpau time to internal mpv time. This was fragile as in it couldn't deal well with Mesa's (apparently) random timestamps, which can change the base offset in multiple situations. It can happen when moving the mpv window to a different screen, and somehow it also happens when pausing the player. It seems this mechanism to synchronize the vdpau time is not actually needed. There are only 2 places where sync_vdptime() is used (i.e. returning the current vdpau time interpolated by system time). The first call is for determining the PTS used to queue a frame. This also uses convert_to_vdptime(). It's easily replaced by querying the time directly, and adding the wait time to it (rel_pts_ns in the patch). The second call is pretty odd: it updates the vdpau time a second time in the same function. From what I can see, this can matter only if update_presentation_queue_status() is very slow. I'm not sure what to make out of this, because the call merely queries the presentation queue. Just assume it isn't slow, and that we don't have to update the time. Another potential issue with this is that we call VdpPresentationQueueGetTime() every frame now, instead of every 5 seconds and interpolating the other calls via system time. More over, this is per video frame (which can be portantially dropped, and not per actually displayed frame. Assume this doesn't matter. This simplifies the code, and should make it more robust on Mesa. But note that what Mesa does is obviously insane - this is one situation where you really need a stable time source. There are still plenty of race condition windows where things can go wrong, although this commit should drastically reduce the possibility of this. In my tests, everything worked well. But I have no access to a Mesa system with vdpau, so it needs testing by others. See github issues #520, #694, #695.
2014-04-07 18:33:25 +02:00
MP_TRACE(vo, "Queue new surface %d: Vdpau time: %"PRIu64" "
"pts: %"PRIu64"\n", (int)frame, now, pts);
Implement vsync-aware frame timing for VDPAU Main things added are custom frame dropping for VDPAU to work around the display FPS limit, frame timing adjustment to avoid jitter when video frame times keep falling near vsyncs, and use of VDPAU's timing feature to keep one future frame queued in advance. NVIDIA's VDPAU implementation refuses to change the displayed frame more than once per vsync. This set a limit on how much video could be sped up, and caused problems for nearly all videos on low-FPS video projectors (playing 24 FPS video on a 24 FPS projector would not work reliably as MPlayer may need to slightly speed up the video for AV sync). This commit adds a framedrop mechanism that drops some frames so that no more than one is sent for display per vsync. The code tries to select the dropped frames smartly, selecting the best one to show for each vsync. Because of the timing features needed the drop functionality currently does not work if the correct-pts option is disabled. The code also adjusts frame timing slightly to avoid jitter. If you for example play 24 FPS video content on a 72 FPS display then normally a frame would be shown for 3 vsyncs, but if the frame times happen to fall near vsyncs and change between just before and just after then there could be frames alternating between 2 and 4 vsyncs. The code changes frame timing by up to one quarter vsync interval to avoid this. The above functionality depends on having reliable vsync timing information available. The display refresh rate is not directly provided by the VDPAU API. The current code uses information from the XF86VidMode extension if available; I'm not sure how common cases where that is inaccurate are. The refresh rate can be specified manually if necessary. After the changes in this commit MPlayer now always tries to keep one frame queued for future display using VDPAU's internal timing mechanism (however no more than 50 ms to the future). This should make video playback somewhat more robust against timing inaccuracies caused by system load.
2009-11-15 03:39:22 +01:00
vc->last_queue_time = pts;
vc->queue_time[vc->surface_num] = pts;
Implement vsync-aware frame timing for VDPAU Main things added are custom frame dropping for VDPAU to work around the display FPS limit, frame timing adjustment to avoid jitter when video frame times keep falling near vsyncs, and use of VDPAU's timing feature to keep one future frame queued in advance. NVIDIA's VDPAU implementation refuses to change the displayed frame more than once per vsync. This set a limit on how much video could be sped up, and caused problems for nearly all videos on low-FPS video projectors (playing 24 FPS video on a 24 FPS projector would not work reliably as MPlayer may need to slightly speed up the video for AV sync). This commit adds a framedrop mechanism that drops some frames so that no more than one is sent for display per vsync. The code tries to select the dropped frames smartly, selecting the best one to show for each vsync. Because of the timing features needed the drop functionality currently does not work if the correct-pts option is disabled. The code also adjusts frame timing slightly to avoid jitter. If you for example play 24 FPS video content on a 72 FPS display then normally a frame would be shown for 3 vsyncs, but if the frame times happen to fall near vsyncs and change between just before and just after then there could be frames alternating between 2 and 4 vsyncs. The code changes frame timing by up to one quarter vsync interval to avoid this. The above functionality depends on having reliable vsync timing information available. The display refresh rate is not directly provided by the VDPAU API. The current code uses information from the XF86VidMode extension if available; I'm not sure how common cases where that is inaccurate are. The refresh rate can be specified manually if necessary. After the changes in this commit MPlayer now always tries to keep one frame queued for future display using VDPAU's internal timing mechanism (however no more than 50 ms to the future). This should make video playback somewhat more robust against timing inaccuracies caused by system load.
2009-11-15 03:39:22 +01:00
vc->last_ideal_time = ideal_pts;
vc->dropped_frame = false;
vc->surface_num = WRAP_ADD(vc->surface_num, 1, vc->num_output_surfaces);
}
static void free_rgb_surface(void *ptr)
{
bool *entry = ptr;
*entry = false;
}
static struct mp_image *get_rgb_surface(struct vo *vo)
{
struct vdpctx *vc = vo->priv;
assert(vc->rgb_mode);
for (int n = 0; n < NUM_BUFFERED_VIDEO; n++) {
bool *used = &vc->rgb_surfaces_used[n];
if (!*used) {
*used = true;
struct mp_image mpi = {0};
mpi.planes[0] = (void *)(uintptr_t)vc->rgb_surfaces[n];
return mp_image_new_custom_ref(&mpi, used, free_rgb_surface);
}
}
MP_ERR(vo, "no surfaces available in get_rgb_surface\n");
return NULL;
}
static void draw_image(struct vo *vo, mp_image_t *mpi)
{
struct vdpctx *vc = vo->priv;
struct vdp_functions *vdp = vc->vdp;
core/VO: Allow VO drivers to add/modify frames Add interfaces to allow VO drivers to add or remove frames from the video stream and to alter timestamps. Currently this functionality only works with in correct-pts mode. Use the new functionality in vo_vdpau to properly support frame-adding deinterlace modes. Frames added by the VDPAU deinterlacing code are now properly timed. Before every second frame was always shown immediately (probably next monitor refresh) after the previous one, even if you were watching things in slow motion, and framestepping didn't stop at them at all. When seeking the deinterlace algorithm is no longer fed a mix of frames from old and new positions. As a side effect of the changes a problem with resize events was also fixed. Resizing calls video_to_output_surface() to render the frame at the new resolution, but before this function also changed the list of history frames, so resizing could give an image different from the original one, and also corrupt next frames due to them seeing the wrong history. Now the function has no such side effects. There are more resize-related problems though that will be fixed in a later commit. The deint_mpi[] list of reserved frames is increased from 2 to 3 entries for reasons related to the above. Having 2 entries is enough when you initially get a new frame in draw_image() because then you'll have those two entries plus the new one for a total of 3 (the code relied on the oldest mpi implicitly staying reserved for the duration of the call even after usage count was decreased). However if you want to be able to reproduce the rendering outside draw_image(), relying on the explicitly reserved list only, then it needs to store 3 entries.
2009-09-18 15:27:55 +02:00
struct mp_image *reserved_mpi = NULL;
VdpStatus vdp_st;
core/VO: Allow VO drivers to add/modify frames Add interfaces to allow VO drivers to add or remove frames from the video stream and to alter timestamps. Currently this functionality only works with in correct-pts mode. Use the new functionality in vo_vdpau to properly support frame-adding deinterlace modes. Frames added by the VDPAU deinterlacing code are now properly timed. Before every second frame was always shown immediately (probably next monitor refresh) after the previous one, even if you were watching things in slow motion, and framestepping didn't stop at them at all. When seeking the deinterlace algorithm is no longer fed a mix of frames from old and new positions. As a side effect of the changes a problem with resize events was also fixed. Resizing calls video_to_output_surface() to render the frame at the new resolution, but before this function also changed the list of history frames, so resizing could give an image different from the original one, and also corrupt next frames due to them seeing the wrong history. Now the function has no such side effects. There are more resize-related problems though that will be fixed in a later commit. The deint_mpi[] list of reserved frames is increased from 2 to 3 entries for reasons related to the above. Having 2 entries is enough when you initially get a new frame in draw_image() because then you'll have those two entries plus the new one for a total of 3 (the code relied on the oldest mpi implicitly staying reserved for the duration of the call even after usage count was decreased). However if you want to be able to reproduce the rendering outside draw_image(), relying on the explicitly reserved list only, then it needs to store 3 entries.
2009-09-18 15:27:55 +02:00
// Forget previous frames, as we can display a new one now.
vc->prev_buffer_pos = -1001;
mp_image_unrefp(&vc->buffered_video[NUM_BUFFERED_VIDEO - 1]);
if (vc->image_format == IMGFMT_VDPAU) {
vdpau: split off decoder parts, use "new" libavcodec vdpau hwaccel API Move the decoder parts from vo_vdpau.c to a new file vdpau_old.c. This file is named so because because it's written against the "old" libavcodec vdpau pseudo-decoder (e.g. "h264_vdpau"). Add support for the "new" libavcodec vdpau support. This was recently added and replaces the "old" vdpau parts. (In fact, Libav is about to deprecate and remove the "old" API without deprecation grace period, so we have to support it now. Moreover, there will probably be no Libav release which supports both, so the transition is even less smooth than we could hope, and we have to support both the old and new API.) Whether the old or new API is used is checked by a configure test: if the new API is found, it is used, otherwise the old API is assumed. Some details might be handled differently. Especially display preemption is a bit problematic with the "new" libavcodec vdpau support: it wants to keep a pointer to a specific vdpau API function (which can be driver specific, because preemption might switch drivers). Also, surface IDs are now directly stored in AVFrames (and mp_images), so they can't be forced to VDP_INVALID_HANDLE on preemption. (This changes even with older libavcodec versions, because mp_image always uses the newer representation to make vo_vdpau.c simpler.) Decoder initialization in the new code tries to deal with codec profiles, while the old code always uses the highest profile per codec. Surface allocation changes. Since the decoder won't call config() in vo_vdpau.c on video size change anymore, we allow allocating surfaces of arbitrary size instead of locking it to what the VO was configured. The non-hwdec code also has slightly different allocation behavior now. Enabling the old vdpau special decoders via e.g. --vd=lavc:h264_vdpau doesn't work anymore (a warning suggesting the --hwdec option is printed instead).
2013-07-28 01:49:45 +02:00
reserved_mpi = mp_image_new_ref(mpi);
} else if (vc->rgb_mode) {
reserved_mpi = get_rgb_surface(vo);
if (!reserved_mpi)
return;
VdpOutputSurface rgb_surface = (uintptr_t)reserved_mpi->planes[0];
if (rgb_surface != VDP_INVALID_HANDLE) {
vdp_st = vdp->output_surface_put_bits_native(rgb_surface,
&(const void *){mpi->planes[0]},
&(uint32_t){mpi->stride[0]},
NULL);
2013-12-21 18:05:23 +01:00
CHECK_VDP_WARNING(vo, "Error when calling "
"output_surface_put_bits_native");
}
} else {
reserved_mpi = mp_vdpau_get_video_surface(vc->mpvdp, vc->vdp_chroma_type,
mpi->w, mpi->h);
vdpau: split off decoder parts, use "new" libavcodec vdpau hwaccel API Move the decoder parts from vo_vdpau.c to a new file vdpau_old.c. This file is named so because because it's written against the "old" libavcodec vdpau pseudo-decoder (e.g. "h264_vdpau"). Add support for the "new" libavcodec vdpau support. This was recently added and replaces the "old" vdpau parts. (In fact, Libav is about to deprecate and remove the "old" API without deprecation grace period, so we have to support it now. Moreover, there will probably be no Libav release which supports both, so the transition is even less smooth than we could hope, and we have to support both the old and new API.) Whether the old or new API is used is checked by a configure test: if the new API is found, it is used, otherwise the old API is assumed. Some details might be handled differently. Especially display preemption is a bit problematic with the "new" libavcodec vdpau support: it wants to keep a pointer to a specific vdpau API function (which can be driver specific, because preemption might switch drivers). Also, surface IDs are now directly stored in AVFrames (and mp_images), so they can't be forced to VDP_INVALID_HANDLE on preemption. (This changes even with older libavcodec versions, because mp_image always uses the newer representation to make vo_vdpau.c simpler.) Decoder initialization in the new code tries to deal with codec profiles, while the old code always uses the highest profile per codec. Surface allocation changes. Since the decoder won't call config() in vo_vdpau.c on video size change anymore, we allow allocating surfaces of arbitrary size instead of locking it to what the VO was configured. The non-hwdec code also has slightly different allocation behavior now. Enabling the old vdpau special decoders via e.g. --vd=lavc:h264_vdpau doesn't work anymore (a warning suggesting the --hwdec option is printed instead).
2013-07-28 01:49:45 +02:00
if (!reserved_mpi)
return;
VdpVideoSurface surface = (VdpVideoSurface)(intptr_t)reserved_mpi->planes[3];
if (handle_preemption(vo) >= 0) {
const void *destdata[3] = {mpi->planes[0], mpi->planes[2],
mpi->planes[1]};
if (vc->image_format == IMGFMT_NV12)
destdata[1] = destdata[2];
vdpau: split off decoder parts, use "new" libavcodec vdpau hwaccel API Move the decoder parts from vo_vdpau.c to a new file vdpau_old.c. This file is named so because because it's written against the "old" libavcodec vdpau pseudo-decoder (e.g. "h264_vdpau"). Add support for the "new" libavcodec vdpau support. This was recently added and replaces the "old" vdpau parts. (In fact, Libav is about to deprecate and remove the "old" API without deprecation grace period, so we have to support it now. Moreover, there will probably be no Libav release which supports both, so the transition is even less smooth than we could hope, and we have to support both the old and new API.) Whether the old or new API is used is checked by a configure test: if the new API is found, it is used, otherwise the old API is assumed. Some details might be handled differently. Especially display preemption is a bit problematic with the "new" libavcodec vdpau support: it wants to keep a pointer to a specific vdpau API function (which can be driver specific, because preemption might switch drivers). Also, surface IDs are now directly stored in AVFrames (and mp_images), so they can't be forced to VDP_INVALID_HANDLE on preemption. (This changes even with older libavcodec versions, because mp_image always uses the newer representation to make vo_vdpau.c simpler.) Decoder initialization in the new code tries to deal with codec profiles, while the old code always uses the highest profile per codec. Surface allocation changes. Since the decoder won't call config() in vo_vdpau.c on video size change anymore, we allow allocating surfaces of arbitrary size instead of locking it to what the VO was configured. The non-hwdec code also has slightly different allocation behavior now. Enabling the old vdpau special decoders via e.g. --vd=lavc:h264_vdpau doesn't work anymore (a warning suggesting the --hwdec option is printed instead).
2013-07-28 01:49:45 +02:00
vdp_st = vdp->video_surface_put_bits_y_cb_cr(surface,
vc->vdp_pixel_format, destdata, mpi->stride);
2013-12-21 18:05:23 +01:00
CHECK_VDP_WARNING(vo, "Error when calling "
"vdp_video_surface_put_bits_y_cb_cr");
}
}
reserved_mpi->pts = mpi->pts;
add_new_video_surface(vo, reserved_mpi);
core/VO: Allow VO drivers to add/modify frames Add interfaces to allow VO drivers to add or remove frames from the video stream and to alter timestamps. Currently this functionality only works with in correct-pts mode. Use the new functionality in vo_vdpau to properly support frame-adding deinterlace modes. Frames added by the VDPAU deinterlacing code are now properly timed. Before every second frame was always shown immediately (probably next monitor refresh) after the previous one, even if you were watching things in slow motion, and framestepping didn't stop at them at all. When seeking the deinterlace algorithm is no longer fed a mix of frames from old and new positions. As a side effect of the changes a problem with resize events was also fixed. Resizing calls video_to_output_surface() to render the frame at the new resolution, but before this function also changed the list of history frames, so resizing could give an image different from the original one, and also corrupt next frames due to them seeing the wrong history. Now the function has no such side effects. There are more resize-related problems though that will be fixed in a later commit. The deint_mpi[] list of reserved frames is increased from 2 to 3 entries for reasons related to the above. Having 2 entries is enough when you initially get a new frame in draw_image() because then you'll have those two entries plus the new one for a total of 3 (the code relied on the oldest mpi implicitly staying reserved for the duration of the call even after usage count was decreased). However if you want to be able to reproduce the rendering outside draw_image(), relying on the explicitly reserved list only, then it needs to store 3 entries.
2009-09-18 15:27:55 +02:00
return;
}
2011-10-06 20:46:01 +02:00
// warning: the size and pixel format of surface must match that of the
// surfaces in vc->output_surfaces
2013-12-21 18:05:23 +01:00
static struct mp_image *read_output_surface(struct vo *vo,
VdpOutputSurface surface,
int width, int height)
2011-10-06 20:46:01 +02:00
{
2013-12-21 18:05:23 +01:00
struct vdpctx *vc = vo->priv;
2011-10-06 20:46:01 +02:00
VdpStatus vdp_st;
struct vdp_functions *vdp = vc->vdp;
if (!vo->params)
return NULL;
struct mp_image *image = mp_image_alloc(IMGFMT_BGR32, width, height);
image->params.colorspace = MP_CSP_RGB;
// hardcoded with conv. matrix
image->params.colorlevels = vo->params->outputlevels;
2011-10-06 20:46:01 +02:00
void *dst_planes[] = { image->planes[0] };
uint32_t dst_pitches[] = { image->stride[0] };
vdp_st = vdp->output_surface_get_bits_native(surface, NULL, dst_planes,
dst_pitches);
2013-12-21 18:05:23 +01:00
CHECK_VDP_WARNING(vo, "Error when calling vdp_output_surface_get_bits_native");
2011-10-06 20:46:01 +02:00
return image;
}
static struct mp_image *get_screenshot(struct vo *vo)
{
struct vdpctx *vc = vo->priv;
VdpStatus vdp_st;
struct vdp_functions *vdp = vc->vdp;
2011-10-06 20:46:01 +02:00
if (!vo->params)
return NULL;
if (vc->screenshot_surface == VDP_INVALID_HANDLE) {
vdp_st = vdp->output_surface_create(vc->vdp_device,
OUTPUT_RGBA_FORMAT,
vc->vid_width, vc->vid_height,
&vc->screenshot_surface);
2013-12-21 18:05:23 +01:00
CHECK_VDP_WARNING(vo, "Error when calling vdp_output_surface_create");
}
2011-10-06 20:46:01 +02:00
VdpRect in = { .x1 = vo->params->w, .y1 = vo->params->h };
VdpRect out = { .x1 = vo->params->d_w, .y1 = vo->params->d_h };
render_video_to_output_surface(vo, vc->screenshot_surface, &out, &in);
2011-10-06 20:46:01 +02:00
return read_output_surface(vo, vc->screenshot_surface, out.x1, out.y1);
2011-10-06 20:46:01 +02:00
}
static struct mp_image *get_window_screenshot(struct vo *vo)
{
struct vdpctx *vc = vo->priv;
int last_surface = WRAP_ADD(vc->surface_num, -1, vc->num_output_surfaces);
VdpOutputSurface screen = vc->output_surfaces[last_surface];
2013-12-21 18:05:23 +01:00
struct mp_image *image = read_output_surface(vo, screen,
vc->output_surface_width,
vc->output_surface_height);
mp_image_set_size(image, vo->dwidth, vo->dheight);
2011-10-06 20:46:01 +02:00
return image;
}
static int query_format(struct vo *vo, uint32_t format)
{
struct vdpctx *vc = vo->priv;
int flags = VFCAP_CSP_SUPPORTED | VFCAP_CSP_SUPPORTED_BY_HW;
if (mp_vdpau_get_format(format, NULL, NULL))
return flags;
int rgb_format = get_rgb_format(format);
if (!vc->force_yuv && rgb_format >= 0)
return flags;
return 0;
}
static void destroy_vdpau_objects(struct vo *vo)
{
struct vdpctx *vc = vo->priv;
struct vdp_functions *vdp = vc->vdp;
VdpStatus vdp_st;
free_video_specific(vo);
if (vc->flip_queue != VDP_INVALID_HANDLE) {
vdp_st = vdp->presentation_queue_destroy(vc->flip_queue);
2013-12-21 18:05:23 +01:00
CHECK_VDP_WARNING(vo, "Error when calling vdp_presentation_queue_destroy");
}
if (vc->flip_target != VDP_INVALID_HANDLE) {
vdp_st = vdp->presentation_queue_target_destroy(vc->flip_target);
2013-12-21 18:05:23 +01:00
CHECK_VDP_WARNING(vo, "Error when calling "
2009-05-09 17:08:30 +02:00
"vdp_presentation_queue_target_destroy");
}
for (int i = 0; i < vc->num_output_surfaces; i++) {
if (vc->output_surfaces[i] == VDP_INVALID_HANDLE)
continue;
vdp_st = vdp->output_surface_destroy(vc->output_surfaces[i]);
2013-12-21 18:05:23 +01:00
CHECK_VDP_WARNING(vo, "Error when calling vdp_output_surface_destroy");
}
for (int i = 0; i < MAX_OSD_PARTS; i++) {
struct osd_bitmap_surface *sfc = &vc->osd_surfaces[i];
if (sfc->surface != VDP_INVALID_HANDLE) {
vdp_st = vdp->bitmap_surface_destroy(sfc->surface);
2013-12-21 18:05:23 +01:00
CHECK_VDP_WARNING(vo, "Error when calling vdp_bitmap_surface_destroy");
}
}
mp_vdpau_destroy(vc->mpvdp);
vc->mpvdp = NULL;
}
2009-05-04 02:09:50 +02:00
static void uninit(struct vo *vo)
{
struct vdpctx *vc = vo->priv;
/* Destroy all vdpau objects */
mp_vdpau_mixer_destroy(vc->video_mixer);
destroy_vdpau_objects(vo);
2009-05-04 02:09:50 +02:00
vo_x11_uninit(vo);
}
static int preinit(struct vo *vo)
{
struct vdpctx *vc = vo->priv;
if (!vo_x11_init(vo))
return -1;
vc->mpvdp = mp_vdpau_create_device_x11(vo->log, vo->x11);
if (!vc->mpvdp) {
vo_x11_uninit(vo);
return -1;
}
vdpau: split off decoder parts, use "new" libavcodec vdpau hwaccel API Move the decoder parts from vo_vdpau.c to a new file vdpau_old.c. This file is named so because because it's written against the "old" libavcodec vdpau pseudo-decoder (e.g. "h264_vdpau"). Add support for the "new" libavcodec vdpau support. This was recently added and replaces the "old" vdpau parts. (In fact, Libav is about to deprecate and remove the "old" API without deprecation grace period, so we have to support it now. Moreover, there will probably be no Libav release which supports both, so the transition is even less smooth than we could hope, and we have to support both the old and new API.) Whether the old or new API is used is checked by a configure test: if the new API is found, it is used, otherwise the old API is assumed. Some details might be handled differently. Especially display preemption is a bit problematic with the "new" libavcodec vdpau support: it wants to keep a pointer to a specific vdpau API function (which can be driver specific, because preemption might switch drivers). Also, surface IDs are now directly stored in AVFrames (and mp_images), so they can't be forced to VDP_INVALID_HANDLE on preemption. (This changes even with older libavcodec versions, because mp_image always uses the newer representation to make vo_vdpau.c simpler.) Decoder initialization in the new code tries to deal with codec profiles, while the old code always uses the highest profile per codec. Surface allocation changes. Since the decoder won't call config() in vo_vdpau.c on video size change anymore, we allow allocating surfaces of arbitrary size instead of locking it to what the VO was configured. The non-hwdec code also has slightly different allocation behavior now. Enabling the old vdpau special decoders via e.g. --vd=lavc:h264_vdpau doesn't work anymore (a warning suggesting the --hwdec option is printed instead).
2013-07-28 01:49:45 +02:00
vc->video_mixer = mp_vdpau_mixer_create(vc->mpvdp, vo->log);
2009-05-08 20:48:01 +02:00
// Mark everything as invalid first so uninit() can tell what has been
// allocated
mark_vdpau_objects_uninitialized(vo);
2009-05-08 20:48:01 +02:00
vc->preemption_counter = vc->mpvdp->preemption_counter;
vc->vdp_device = vc->mpvdp->vdp_device;
vc->vdp = &vc->mpvdp->vdp;
video, options: implement better YUV->RGB conversion control Rewrite control of the colorspace and input/output level parameters used in YUV-RGB conversions, replacing VO-specific suboptions with new common options and adding configuration support to more cases. Add new option --colormatrix which selects the colorspace the original video is assumed to have in YUV->RGB conversions. The default behavior changes from assuming BT.601 to colorspace autoselection between BT.601 and BT.709 using a simple heuristic based on video size. Add new options --colormatrix-input-range and --colormatrix-output-range which select input YUV and output RGB range. Disable the previously existing VO-specific colorspace and level conversion suboptions in vo_gl and vo_vdpau. Remove the "yuv_colorspace" property and replace it with one named "colormatrix" and semantics matching the new option. Add new properties matching the options for level conversion. Colorspace selection is currently supported by vo_gl, vo_vdpau, vo_xv and vf_scale, and all can change it at runtime (previously only vo_vdpau and vo_xv could). vo_vdpau now uses the same conversion matrix generation as vo_gl instead of libvdpau functionality; the main functional difference is that the "contrast" equalizer control behaves somewhat differently (it scales the Y component around 1/2 instead of around 0, so that contrast 0 makes the image gray rather than black). vo_xv does not support level conversion. vf_scale supports range setting for input, but always outputs full-range RGB. The value of the slave properties is the policy setting used for conversions. This means they can be set to any value regardless of whether the current VO supports that value or whether there currently even is any video. Possibly separate properties could be added to query the conversion actually used at the moment, if any. Because the colorspace and level settings are now set with a single VF/VO control call, the return value of that is no longer used to signal whether all the settings are actually supported. Instead code should set all the details it can support, and ignore the rest. The core will use GET_YUV_COLORSPACE to check which colorspace details have been set and which not. In other words, the return value for SET_YUV_COLORSPACE only signals whether any kind of YUV colorspace conversion handling exists at all, and VOs have to take care to return the actual state with GET_YUV_COLORSPACE instead. To be changed in later commits: add missing option documentation.
2011-10-15 23:50:21 +02:00
vc->video_eq.capabilities = MP_CSP_EQ_CAPS_COLORMATRIX;
return 0;
}
static int get_equalizer(struct vo *vo, const char *name, int *value)
{
struct vdpctx *vc = vo->priv;
if (vc->rgb_mode)
return false;
return mp_csp_equalizer_get(&vc->video_mixer->video_eq, name, value) >= 0 ?
video, options: implement better YUV->RGB conversion control Rewrite control of the colorspace and input/output level parameters used in YUV-RGB conversions, replacing VO-specific suboptions with new common options and adding configuration support to more cases. Add new option --colormatrix which selects the colorspace the original video is assumed to have in YUV->RGB conversions. The default behavior changes from assuming BT.601 to colorspace autoselection between BT.601 and BT.709 using a simple heuristic based on video size. Add new options --colormatrix-input-range and --colormatrix-output-range which select input YUV and output RGB range. Disable the previously existing VO-specific colorspace and level conversion suboptions in vo_gl and vo_vdpau. Remove the "yuv_colorspace" property and replace it with one named "colormatrix" and semantics matching the new option. Add new properties matching the options for level conversion. Colorspace selection is currently supported by vo_gl, vo_vdpau, vo_xv and vf_scale, and all can change it at runtime (previously only vo_vdpau and vo_xv could). vo_vdpau now uses the same conversion matrix generation as vo_gl instead of libvdpau functionality; the main functional difference is that the "contrast" equalizer control behaves somewhat differently (it scales the Y component around 1/2 instead of around 0, so that contrast 0 makes the image gray rather than black). vo_xv does not support level conversion. vf_scale supports range setting for input, but always outputs full-range RGB. The value of the slave properties is the policy setting used for conversions. This means they can be set to any value regardless of whether the current VO supports that value or whether there currently even is any video. Possibly separate properties could be added to query the conversion actually used at the moment, if any. Because the colorspace and level settings are now set with a single VF/VO control call, the return value of that is no longer used to signal whether all the settings are actually supported. Instead code should set all the details it can support, and ignore the rest. The core will use GET_YUV_COLORSPACE to check which colorspace details have been set and which not. In other words, the return value for SET_YUV_COLORSPACE only signals whether any kind of YUV colorspace conversion handling exists at all, and VOs have to take care to return the actual state with GET_YUV_COLORSPACE instead. To be changed in later commits: add missing option documentation.
2011-10-15 23:50:21 +02:00
VO_TRUE : VO_NOTIMPL;
}
static int set_equalizer(struct vo *vo, const char *name, int value)
{
struct vdpctx *vc = vo->priv;
if (vc->rgb_mode)
return false;
if (mp_csp_equalizer_set(&vc->video_mixer->video_eq, name, value) < 0)
return VO_NOTIMPL;
vc->video_mixer->initialized = false;
return true;
}
static void checked_resize(struct vo *vo)
{
if (!status_ok(vo))
return;
resize(vo);
}
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static int control(struct vo *vo, uint32_t request, void *data)
{
struct vdpctx *vc = vo->priv;
handle_preemption(vo);
switch (request) {
case VOCTRL_PAUSE:
Implement vsync-aware frame timing for VDPAU Main things added are custom frame dropping for VDPAU to work around the display FPS limit, frame timing adjustment to avoid jitter when video frame times keep falling near vsyncs, and use of VDPAU's timing feature to keep one future frame queued in advance. NVIDIA's VDPAU implementation refuses to change the displayed frame more than once per vsync. This set a limit on how much video could be sped up, and caused problems for nearly all videos on low-FPS video projectors (playing 24 FPS video on a 24 FPS projector would not work reliably as MPlayer may need to slightly speed up the video for AV sync). This commit adds a framedrop mechanism that drops some frames so that no more than one is sent for display per vsync. The code tries to select the dropped frames smartly, selecting the best one to show for each vsync. Because of the timing features needed the drop functionality currently does not work if the correct-pts option is disabled. The code also adjusts frame timing slightly to avoid jitter. If you for example play 24 FPS video content on a 72 FPS display then normally a frame would be shown for 3 vsyncs, but if the frame times happen to fall near vsyncs and change between just before and just after then there could be frames alternating between 2 and 4 vsyncs. The code changes frame timing by up to one quarter vsync interval to avoid this. The above functionality depends on having reliable vsync timing information available. The display refresh rate is not directly provided by the VDPAU API. The current code uses information from the XF86VidMode extension if available; I'm not sure how common cases where that is inaccurate are. The refresh rate can be specified manually if necessary. After the changes in this commit MPlayer now always tries to keep one frame queued for future display using VDPAU's internal timing mechanism (however no more than 50 ms to the future). This should make video playback somewhat more robust against timing inaccuracies caused by system load.
2009-11-15 03:39:22 +01:00
if (vc->dropped_frame)
vo->want_redraw = true;
return true;
vdpau: split off decoder parts, use "new" libavcodec vdpau hwaccel API Move the decoder parts from vo_vdpau.c to a new file vdpau_old.c. This file is named so because because it's written against the "old" libavcodec vdpau pseudo-decoder (e.g. "h264_vdpau"). Add support for the "new" libavcodec vdpau support. This was recently added and replaces the "old" vdpau parts. (In fact, Libav is about to deprecate and remove the "old" API without deprecation grace period, so we have to support it now. Moreover, there will probably be no Libav release which supports both, so the transition is even less smooth than we could hope, and we have to support both the old and new API.) Whether the old or new API is used is checked by a configure test: if the new API is found, it is used, otherwise the old API is assumed. Some details might be handled differently. Especially display preemption is a bit problematic with the "new" libavcodec vdpau support: it wants to keep a pointer to a specific vdpau API function (which can be driver specific, because preemption might switch drivers). Also, surface IDs are now directly stored in AVFrames (and mp_images), so they can't be forced to VDP_INVALID_HANDLE on preemption. (This changes even with older libavcodec versions, because mp_image always uses the newer representation to make vo_vdpau.c simpler.) Decoder initialization in the new code tries to deal with codec profiles, while the old code always uses the highest profile per codec. Surface allocation changes. Since the decoder won't call config() in vo_vdpau.c on video size change anymore, we allow allocating surfaces of arbitrary size instead of locking it to what the VO was configured. The non-hwdec code also has slightly different allocation behavior now. Enabling the old vdpau special decoders via e.g. --vd=lavc:h264_vdpau doesn't work anymore (a warning suggesting the --hwdec option is printed instead).
2013-07-28 01:49:45 +02:00
case VOCTRL_GET_HWDEC_INFO: {
struct mp_hwdec_info *arg = data;
arg->vdpau_ctx = vc->mpvdp;
return true;
vdpau: split off decoder parts, use "new" libavcodec vdpau hwaccel API Move the decoder parts from vo_vdpau.c to a new file vdpau_old.c. This file is named so because because it's written against the "old" libavcodec vdpau pseudo-decoder (e.g. "h264_vdpau"). Add support for the "new" libavcodec vdpau support. This was recently added and replaces the "old" vdpau parts. (In fact, Libav is about to deprecate and remove the "old" API without deprecation grace period, so we have to support it now. Moreover, there will probably be no Libav release which supports both, so the transition is even less smooth than we could hope, and we have to support both the old and new API.) Whether the old or new API is used is checked by a configure test: if the new API is found, it is used, otherwise the old API is assumed. Some details might be handled differently. Especially display preemption is a bit problematic with the "new" libavcodec vdpau support: it wants to keep a pointer to a specific vdpau API function (which can be driver specific, because preemption might switch drivers). Also, surface IDs are now directly stored in AVFrames (and mp_images), so they can't be forced to VDP_INVALID_HANDLE on preemption. (This changes even with older libavcodec versions, because mp_image always uses the newer representation to make vo_vdpau.c simpler.) Decoder initialization in the new code tries to deal with codec profiles, while the old code always uses the highest profile per codec. Surface allocation changes. Since the decoder won't call config() in vo_vdpau.c on video size change anymore, we allow allocating surfaces of arbitrary size instead of locking it to what the VO was configured. The non-hwdec code also has slightly different allocation behavior now. Enabling the old vdpau special decoders via e.g. --vd=lavc:h264_vdpau doesn't work anymore (a warning suggesting the --hwdec option is printed instead).
2013-07-28 01:49:45 +02:00
}
case VOCTRL_GET_PANSCAN:
return VO_TRUE;
case VOCTRL_SET_PANSCAN:
checked_resize(vo);
return VO_TRUE;
case VOCTRL_SET_EQUALIZER: {
vo->want_redraw = true;
struct voctrl_set_equalizer_args *args = data;
return set_equalizer(vo, args->name, args->value);
}
case VOCTRL_GET_EQUALIZER: {
struct voctrl_get_equalizer_args *args = data;
return get_equalizer(vo, args->name, args->valueptr);
}
case VOCTRL_GET_COLORSPACE: {
struct mp_image_params *params = data;
if (vo->params && !vc->rgb_mode) {
params->colorspace = vo->params->colorspace;
params->colorlevels = vo->params->colorlevels;
params->outputlevels = vo->params->outputlevels;
}
return true;
}
case VOCTRL_NEWFRAME:
vc->buffer_pos = next_buffer_pos(vo, true);
if (status_ok(vo))
video_to_output_surface(vo);
return true;
case VOCTRL_SKIPFRAME:
vc->buffer_pos = next_buffer_pos(vo, true);
return true;
case VOCTRL_REDRAW_FRAME:
if (status_ok(vo))
video_to_output_surface(vo);
return true;
core/VO: Allow VO drivers to add/modify frames Add interfaces to allow VO drivers to add or remove frames from the video stream and to alter timestamps. Currently this functionality only works with in correct-pts mode. Use the new functionality in vo_vdpau to properly support frame-adding deinterlace modes. Frames added by the VDPAU deinterlacing code are now properly timed. Before every second frame was always shown immediately (probably next monitor refresh) after the previous one, even if you were watching things in slow motion, and framestepping didn't stop at them at all. When seeking the deinterlace algorithm is no longer fed a mix of frames from old and new positions. As a side effect of the changes a problem with resize events was also fixed. Resizing calls video_to_output_surface() to render the frame at the new resolution, but before this function also changed the list of history frames, so resizing could give an image different from the original one, and also corrupt next frames due to them seeing the wrong history. Now the function has no such side effects. There are more resize-related problems though that will be fixed in a later commit. The deint_mpi[] list of reserved frames is increased from 2 to 3 entries for reasons related to the above. Having 2 entries is enough when you initially get a new frame in draw_image() because then you'll have those two entries plus the new one for a total of 3 (the code relied on the oldest mpi implicitly staying reserved for the duration of the call even after usage count was decreased). However if you want to be able to reproduce the rendering outside draw_image(), relying on the explicitly reserved list only, then it needs to store 3 entries.
2009-09-18 15:27:55 +02:00
case VOCTRL_RESET:
forget_frames(vo, true);
core/VO: Allow VO drivers to add/modify frames Add interfaces to allow VO drivers to add or remove frames from the video stream and to alter timestamps. Currently this functionality only works with in correct-pts mode. Use the new functionality in vo_vdpau to properly support frame-adding deinterlace modes. Frames added by the VDPAU deinterlacing code are now properly timed. Before every second frame was always shown immediately (probably next monitor refresh) after the previous one, even if you were watching things in slow motion, and framestepping didn't stop at them at all. When seeking the deinterlace algorithm is no longer fed a mix of frames from old and new positions. As a side effect of the changes a problem with resize events was also fixed. Resizing calls video_to_output_surface() to render the frame at the new resolution, but before this function also changed the list of history frames, so resizing could give an image different from the original one, and also corrupt next frames due to them seeing the wrong history. Now the function has no such side effects. There are more resize-related problems though that will be fixed in a later commit. The deint_mpi[] list of reserved frames is increased from 2 to 3 entries for reasons related to the above. Having 2 entries is enough when you initially get a new frame in draw_image() because then you'll have those two entries plus the new one for a total of 3 (the code relied on the oldest mpi implicitly staying reserved for the duration of the call even after usage count was decreased). However if you want to be able to reproduce the rendering outside draw_image(), relying on the explicitly reserved list only, then it needs to store 3 entries.
2009-09-18 15:27:55 +02:00
return true;
2011-10-06 20:46:01 +02:00
case VOCTRL_SCREENSHOT: {
if (!status_ok(vo))
return false;
2011-10-06 20:46:01 +02:00
struct voctrl_screenshot_args *args = data;
if (args->full_window)
args->out_image = get_window_screenshot(vo);
else
args->out_image = get_screenshot(vo);
return true;
}
case VOCTRL_GET_PREF_DEINT:
*(int *)data = vc->deint;
return true;
}
2013-05-16 14:02:28 +02:00
int events = 0;
int r = vo_x11_control(vo, &events, request, data);
if (events & VO_EVENT_RESIZE) {
checked_resize(vo);
} else if (events & VO_EVENT_EXPOSE) {
vo->want_redraw = true;
}
return r;
}
#define OPT_BASE_STRUCT struct vdpctx
2009-05-04 02:09:50 +02:00
const struct vo_driver video_out_vdpau = {
core/VO: Allow VO drivers to add/modify frames Add interfaces to allow VO drivers to add or remove frames from the video stream and to alter timestamps. Currently this functionality only works with in correct-pts mode. Use the new functionality in vo_vdpau to properly support frame-adding deinterlace modes. Frames added by the VDPAU deinterlacing code are now properly timed. Before every second frame was always shown immediately (probably next monitor refresh) after the previous one, even if you were watching things in slow motion, and framestepping didn't stop at them at all. When seeking the deinterlace algorithm is no longer fed a mix of frames from old and new positions. As a side effect of the changes a problem with resize events was also fixed. Resizing calls video_to_output_surface() to render the frame at the new resolution, but before this function also changed the list of history frames, so resizing could give an image different from the original one, and also corrupt next frames due to them seeing the wrong history. Now the function has no such side effects. There are more resize-related problems though that will be fixed in a later commit. The deint_mpi[] list of reserved frames is increased from 2 to 3 entries for reasons related to the above. Having 2 entries is enough when you initially get a new frame in draw_image() because then you'll have those two entries plus the new one for a total of 3 (the code relied on the oldest mpi implicitly staying reserved for the duration of the call even after usage count was decreased). However if you want to be able to reproduce the rendering outside draw_image(), relying on the explicitly reserved list only, then it needs to store 3 entries.
2009-09-18 15:27:55 +02:00
.buffer_frames = true,
.description = "VDPAU with X11",
.name = "vdpau",
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.preinit = preinit,
.query_format = query_format,
.reconfig = reconfig,
2009-05-04 02:09:50 +02:00
.control = control,
.draw_image = draw_image,
.get_buffered_frame = set_next_frame_info,
2009-05-04 02:09:50 +02:00
.draw_osd = draw_osd,
Implement vsync-aware frame timing for VDPAU Main things added are custom frame dropping for VDPAU to work around the display FPS limit, frame timing adjustment to avoid jitter when video frame times keep falling near vsyncs, and use of VDPAU's timing feature to keep one future frame queued in advance. NVIDIA's VDPAU implementation refuses to change the displayed frame more than once per vsync. This set a limit on how much video could be sped up, and caused problems for nearly all videos on low-FPS video projectors (playing 24 FPS video on a 24 FPS projector would not work reliably as MPlayer may need to slightly speed up the video for AV sync). This commit adds a framedrop mechanism that drops some frames so that no more than one is sent for display per vsync. The code tries to select the dropped frames smartly, selecting the best one to show for each vsync. Because of the timing features needed the drop functionality currently does not work if the correct-pts option is disabled. The code also adjusts frame timing slightly to avoid jitter. If you for example play 24 FPS video content on a 72 FPS display then normally a frame would be shown for 3 vsyncs, but if the frame times happen to fall near vsyncs and change between just before and just after then there could be frames alternating between 2 and 4 vsyncs. The code changes frame timing by up to one quarter vsync interval to avoid this. The above functionality depends on having reliable vsync timing information available. The display refresh rate is not directly provided by the VDPAU API. The current code uses information from the XF86VidMode extension if available; I'm not sure how common cases where that is inaccurate are. The refresh rate can be specified manually if necessary. After the changes in this commit MPlayer now always tries to keep one frame queued for future display using VDPAU's internal timing mechanism (however no more than 50 ms to the future). This should make video playback somewhat more robust against timing inaccuracies caused by system load.
2009-11-15 03:39:22 +01:00
.flip_page_timed = flip_page_timed,
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.uninit = uninit,
.priv_size = sizeof(struct vdpctx),
.options = (const struct m_option []){
OPT_INTRANGE("deint", deint, 0, -4, 4),
OPT_FLAG("chroma-deint", chroma_deint, 0, OPTDEF_INT(1)),
OPT_FLAG("pullup", pullup, 0),
OPT_FLOATRANGE("denoise", denoise, 0, 0, 1),
OPT_FLOATRANGE("sharpen", sharpen, 0, -1, 1),
OPT_INTRANGE("hqscaling", hqscaling, 0, 0, 9),
OPT_FLOAT("fps", user_fps, 0),
OPT_FLAG("composite-detect", composite_detect, 0, OPTDEF_INT(1)),
OPT_INT("queuetime_windowed", flip_offset_window, 0, OPTDEF_INT(50)),
OPT_INT("queuetime_fs", flip_offset_fs, 0, OPTDEF_INT(50)),
OPT_INTRANGE("output_surfaces", num_output_surfaces, 0,
2, MAX_OUTPUT_SURFACES, OPTDEF_INT(3)),
OPT_COLOR("colorkey", colorkey, 0,
.defval = &(const struct m_color) {
.r = 2, .g = 5, .b = 7, .a = 255,
}),
OPT_FLAG("force-yuv", force_yuv, 0),
{NULL},
}
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};