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1 /*
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25 /**
26 * \file va_vpp.h
27 * \brief The video processing API
29 * This file contains the \ref api_vpp "Video processing API".
32 #ifndef VA_VPP_H
33 #define VA_VPP_H
35 #ifdef __cplusplus
36 extern "C" {
37 #endif
39 /**
40 * \defgroup api_vpp Video processing API
42 * @{
44 * The video processing API uses the same paradigm as for decoding:
45 * - Query for supported filters;
46 * - Set up a video processing pipeline;
47 * - Send video processing parameters through VA buffers.
49 * \section api_vpp_caps Query for supported filters
51 * Checking whether video processing is supported can be performed
52 * with vaQueryConfigEntrypoints() and the profile argument set to
53 * #VAProfileNone. If video processing is supported, then the list of
54 * returned entry-points will include #VAEntrypointVideoProc.
56 * \code
57 * VAEntrypoint *entrypoints;
58 * int i, num_entrypoints, supportsVideoProcessing = 0;
60 * num_entrypoints = vaMaxNumEntrypoints();
61 * entrypoints = malloc(num_entrypoints * sizeof(entrypoints[0]);
62 * vaQueryConfigEntrypoints(va_dpy, VAProfileNone,
63 * entrypoints, &num_entrypoints);
65 * for (i = 0; !supportsVideoProcessing && i < num_entrypoints; i++) {
66 * if (entrypoints[i] == VAEntrypointVideoProc)
67 * supportsVideoProcessing = 1;
68 * }
69 * \endcode
71 * Then, the vaQueryVideoProcFilters() function is used to query the
72 * list of video processing filters.
74 * \code
75 * VAProcFilterType filters[VAProcFilterCount];
76 * unsigned int num_filters = VAProcFilterCount;
78 * // num_filters shall be initialized to the length of the array
79 * vaQueryVideoProcFilters(va_dpy, vpp_ctx, &filters, &num_filters);
80 * \endcode
82 * Finally, individual filter capabilities can be checked with
83 * vaQueryVideoProcFilterCaps().
85 * \code
86 * VAProcFilterCap denoise_caps;
87 * unsigned int num_denoise_caps = 1;
88 * vaQueryVideoProcFilterCaps(va_dpy, vpp_ctx,
89 * VAProcFilterNoiseReduction,
90 * &denoise_caps, &num_denoise_caps
91 * );
93 * VAProcFilterCapDeinterlacing deinterlacing_caps[VAProcDeinterlacingCount];
94 * unsigned int num_deinterlacing_caps = VAProcDeinterlacingCount;
95 * vaQueryVideoProcFilterCaps(va_dpy, vpp_ctx,
96 * VAProcFilterDeinterlacing,
97 * &deinterlacing_caps, &num_deinterlacing_caps
98 * );
99 * \endcode
101 * \section api_vpp_setup Set up a video processing pipeline
103 * A video processing pipeline buffer is created for each source
104 * surface we want to process. However, buffers holding filter
105 * parameters can be created once and for all. Rationale is to avoid
106 * multiple creation/destruction chains of filter buffers and also
107 * because filter parameters generally won't change frame after
108 * frame. e.g. this makes it possible to implement a checkerboard of
109 * videos where the same filters are applied to each video source.
111 * The general control flow is demonstrated by the following pseudo-code:
112 * \code
113 * // Create filters
114 * VABufferID denoise_filter, deint_filter;
115 * VABufferID filter_bufs[VAProcFilterCount];
116 * unsigned int num_filter_bufs;
118 * for (i = 0; i < num_filters; i++) {
119 * switch (filters[i]) {
120 * case VAProcFilterNoiseReduction: { // Noise reduction filter
121 * VAProcFilterParameterBuffer denoise;
122 * denoise.type = VAProcFilterNoiseReduction;
123 * denoise.value = 0.5;
124 * vaCreateBuffer(va_dpy, vpp_ctx,
125 * VAProcFilterParameterBufferType, sizeof(denoise), 1,
126 * &denoise, &denoise_filter
127 * );
128 * filter_bufs[num_filter_bufs++] = denoise_filter;
129 * break;
132 * case VAProcFilterDeinterlacing: // Motion-adaptive deinterlacing
133 * for (j = 0; j < num_deinterlacing_caps; j++) {
134 * VAProcFilterCapDeinterlacing * const cap = &deinterlacing_caps[j];
135 * if (cap->type != VAProcDeinterlacingMotionAdaptive)
136 * continue;
138 * VAProcFilterParameterBufferDeinterlacing deint;
139 * deint.type = VAProcFilterDeinterlacing;
140 * deint.algorithm = VAProcDeinterlacingMotionAdaptive;
141 * vaCreateBuffer(va_dpy, vpp_ctx,
142 * VAProcFilterParameterBufferType, sizeof(deint), 1,
143 * &deint, &deint_filter
144 * );
145 * filter_bufs[num_filter_bufs++] = deint_filter;
149 * \endcode
151 * Once the video processing pipeline is set up, the caller shall check the
152 * implied capabilities and requirements with vaQueryVideoProcPipelineCaps().
153 * This function can be used to validate the number of reference frames are
154 * needed by the specified deinterlacing algorithm, the supported color
155 * primaries, etc.
156 * \code
157 * // Create filters
158 * VAProcPipelineCaps pipeline_caps;
159 * VASurfaceID *forward_references;
160 * unsigned int num_forward_references;
161 * VASurfaceID *backward_references;
162 * unsigned int num_backward_references;
163 * VAProcColorStandardType in_color_standards[VAProcColorStandardCount];
164 * VAProcColorStandardType out_color_standards[VAProcColorStandardCount];
166 * pipeline_caps.input_color_standards = NULL;
167 * pipeline_caps.num_input_color_standards = ARRAY_ELEMS(in_color_standards);
168 * pipeline_caps.output_color_standards = NULL;
169 * pipeline_caps.num_output_color_standards = ARRAY_ELEMS(out_color_standards);
170 * vaQueryVideoProcPipelineCaps(va_dpy, vpp_ctx,
171 * filter_bufs, num_filter_bufs,
172 * &pipeline_caps
173 * );
175 * num_forward_references = pipeline_caps.num_forward_references;
176 * forward_references =
177 * malloc(num__forward_references * sizeof(VASurfaceID));
178 * num_backward_references = pipeline_caps.num_backward_references;
179 * backward_references =
180 * malloc(num_backward_references * sizeof(VASurfaceID));
181 * \endcode
183 * \section api_vpp_submit Send video processing parameters through VA buffers
185 * Video processing pipeline parameters are submitted for each source
186 * surface to process. Video filter parameters can also change, per-surface.
187 * e.g. the list of reference frames used for deinterlacing.
189 * \code
190 * foreach (iteration) {
191 * vaBeginPicture(va_dpy, vpp_ctx, vpp_surface);
192 * foreach (surface) {
193 * VARectangle output_region;
194 * VABufferID pipeline_buf;
195 * VAProcPipelineParameterBuffer *pipeline_param;
197 * vaCreateBuffer(va_dpy, vpp_ctx,
198 * VAProcPipelineParameterBuffer, sizeof(*pipeline_param), 1,
199 * NULL, &pipeline_buf
200 * );
202 * // Setup output region for this surface
203 * // e.g. upper left corner for the first surface
204 * output_region.x = BORDER;
205 * output_region.y = BORDER;
206 * output_region.width =
207 * (vpp_surface_width - (Nx_surfaces + 1) * BORDER) / Nx_surfaces;
208 * output_region.height =
209 * (vpp_surface_height - (Ny_surfaces + 1) * BORDER) / Ny_surfaces;
211 * vaMapBuffer(va_dpy, pipeline_buf, &pipeline_param);
212 * pipeline_param->surface = surface;
213 * pipeline_param->surface_region = NULL;
214 * pipeline_param->output_region = &output_region;
215 * pipeline_param->output_background_color = 0;
216 * if (first surface to render)
217 * pipeline_param->output_background_color = 0xff000000; // black
218 * pipeline_param->filter_flags = VA_FILTER_SCALING_HQ;
219 * pipeline_param->filters = filter_bufs;
220 * pipeline_param->num_filters = num_filter_bufs;
221 * vaUnmapBuffer(va_dpy, pipeline_buf);
223 * // Update reference frames for deinterlacing, if necessary
224 * pipeline_param->forward_references = forward_references;
225 * pipeline_param->num_forward_references = num_forward_references_used;
226 * pipeline_param->backward_references = backward_references;
227 * pipeline_param->num_backward_references = num_bacward_references_used;
229 * // Apply filters
230 * vaRenderPicture(va_dpy, vpp_ctx, &pipeline_buf, 1);
232 * vaEndPicture(va_dpy, vpp_ctx);
234 * \endcode
237 /** \brief Video filter types. */
238 typedef enum _VAProcFilterType {
239 VAProcFilterNone = 0,
240 /** \brief Noise reduction filter. */
241 VAProcFilterNoiseReduction,
242 /** \brief Deinterlacing filter. */
243 VAProcFilterDeinterlacing,
244 /** \brief Sharpening filter. */
245 VAProcFilterSharpening,
246 /** \brief Color balance parameters. */
247 VAProcFilterColorBalance,
248 /** \brief Skin Tone Enhancement. */
249 VAProcFilterSkinToneEnhancement,
250 VAProcFilterCount
251 } VAProcFilterType;
253 /** \brief Deinterlacing types. */
254 typedef enum _VAProcDeinterlacingType {
255 VAProcDeinterlacingNone = 0,
256 /** \brief Bob deinterlacing algorithm. */
257 VAProcDeinterlacingBob,
258 /** \brief Weave deinterlacing algorithm. */
259 VAProcDeinterlacingWeave,
260 /** \brief Motion adaptive deinterlacing algorithm. */
261 VAProcDeinterlacingMotionAdaptive,
262 /** \brief Motion compensated deinterlacing algorithm. */
263 VAProcDeinterlacingMotionCompensated,
264 /** \brief Number of deinterlacing algorithms. */
265 VAProcDeinterlacingCount
266 } VAProcDeinterlacingType;
268 /** \brief Color balance types. */
269 typedef enum _VAProcColorBalanceType {
270 VAProcColorBalanceNone = 0,
271 /** \brief Hue. */
272 VAProcColorBalanceHue,
273 /** \brief Saturation. */
274 VAProcColorBalanceSaturation,
275 /** \brief Brightness. */
276 VAProcColorBalanceBrightness,
277 /** \brief Contrast. */
278 VAProcColorBalanceContrast,
279 /** \brief Automatically adjusted saturation. */
280 VAProcColorBalanceAutoSaturation,
281 /** \brief Automatically adjusted brightness. */
282 VAProcColorBalanceAutoBrightness,
283 /** \brief Automatically adjusted contrast. */
284 VAProcColorBalanceAutoContrast,
285 /** \brief Number of color balance attributes. */
286 VAProcColorBalanceCount
287 } VAProcColorBalanceType;
289 /** \brief Color standard types. */
290 typedef enum _VAProcColorStandardType {
291 VAProcColorStandardNone = 0,
292 /** \brief ITU-R BT.601. */
293 VAProcColorStandardBT601,
294 /** \brief ITU-R BT.709. */
295 VAProcColorStandardBT709,
296 /** \brief ITU-R BT.470-2 System M. */
297 VAProcColorStandardBT470M,
298 /** \brief ITU-R BT.470-2 System B, G. */
299 VAProcColorStandardBT470BG,
300 /** \brief SMPTE-170M. */
301 VAProcColorStandardSMPTE170M,
302 /** \brief SMPTE-240M. */
303 VAProcColorStandardSMPTE240M,
304 /** \brief Generic film. */
305 VAProcColorStandardGenericFilm,
306 /** \brief Number of color standards. */
307 VAProcColorStandardCount
308 } VAProcColorStandardType;
310 /** @name Video pipeline flags */
311 /**@{*/
312 /** \brief Specifies whether to apply subpictures when processing a surface. */
313 #define VA_PROC_PIPELINE_SUBPICTURES 0x00000001
315 * \brief Specifies whether to apply power or performance
316 * optimizations to a pipeline.
318 * When processing several surfaces, it may be necessary to prioritize
319 * more certain pipelines than others. This flag is only a hint to the
320 * video processor so that it can omit certain filters to save power
321 * for example. Typically, this flag could be used with video surfaces
322 * decoded from a secondary bitstream.
324 #define VA_PROC_PIPELINE_FAST 0x00000002
325 /**@}*/
327 /** @name Video filter flags */
328 /**@{*/
329 /** \brief Specifies whether the filter shall be present in the pipeline. */
330 #define VA_PROC_FILTER_MANDATORY 0x00000001
331 /**@}*/
333 /** @name Pipeline end flags */
334 /**@{*/
335 /** \brief Specifies the pipeline is the last. */
336 #define VA_PIPELINE_FLAG_END 0x00000004
337 /**@}*/
339 /** \brief Video processing pipeline capabilities. */
340 typedef struct _VAProcPipelineCaps {
341 /** \brief Pipeline flags. See VAProcPipelineParameterBuffer::pipeline_flags. */
342 unsigned int pipeline_flags;
343 /** \brief Extra filter flags. See VAProcPipelineParameterBuffer::filter_flags. */
344 unsigned int filter_flags;
345 /** \brief Number of forward reference frames that are needed. */
346 unsigned int num_forward_references;
347 /** \brief Number of backward reference frames that are needed. */
348 unsigned int num_backward_references;
349 /** \brief List of color standards supported on input. */
350 VAProcColorStandardType *input_color_standards;
351 /** \brief Number of elements in \ref input_color_standards array. */
352 unsigned int num_input_color_standards;
353 /** \brief List of color standards supported on output. */
354 VAProcColorStandardType *output_color_standards;
355 /** \brief Number of elements in \ref output_color_standards array. */
356 unsigned int num_output_color_standards;
357 } VAProcPipelineCaps;
359 /** \brief Specification of values supported by the filter. */
360 typedef struct _VAProcFilterValueRange {
361 /** \brief Minimum value supported, inclusive. */
362 float min_value;
363 /** \brief Maximum value supported, inclusive. */
364 float max_value;
365 /** \brief Default value. */
366 float default_value;
367 /** \brief Step value that alters the filter behaviour in a sensible way. */
368 float step;
369 } VAProcFilterValueRange;
372 * \brief Video processing pipeline configuration.
374 * This buffer defines a video processing pipeline. As for any buffer
375 * passed to \c vaRenderPicture(), this is a one-time usage model.
376 * However, the actual filters to be applied are provided in the
377 * \c filters field, so they can be re-used in other processing
378 * pipelines.
380 * The target surface is specified by the \c render_target argument of
381 * \c vaBeginPicture(). The general usage model is described as follows:
382 * - \c vaBeginPicture(): specify the target surface that receives the
383 * processed output;
384 * - \c vaRenderPicture(): specify a surface to be processed and composed
385 * into the \c render_target. Use as many \c vaRenderPicture() calls as
386 * necessary surfaces to compose ;
387 * - \c vaEndPicture(): tell the driver to start processing the surfaces
388 * with the requested filters.
390 * If a filter (e.g. noise reduction) needs to be applied with different
391 * values for multiple surfaces, the application needs to create as many
392 * filter parameter buffers as necessary. i.e. the filter parameters shall
393 * not change between two calls to \c vaRenderPicture().
395 * For composition usage models, the first surface to process will generally
396 * use an opaque background color, i.e. \c output_background_color set with
397 * the most significant byte set to \c 0xff. For instance, \c 0xff000000 for
398 * a black background. Then, subsequent surfaces would use a transparent
399 * background color.
401 typedef struct _VAProcPipelineParameterBuffer {
403 * \brief Source surface ID.
405 * ID of the source surface to process. If subpictures are associated
406 * with the video surfaces then they shall be rendered to the target
407 * surface, if the #VA_PROC_PIPELINE_SUBPICTURES pipeline flag is set.
409 VASurfaceID surface;
411 * \brief Region within the source surface to be processed.
413 * Pointer to a #VARectangle defining the region within the source
414 * surface to be processed. If NULL, \c surface_region implies the
415 * whole surface.
417 const VARectangle *surface_region;
419 * \brief Requested input color primaries.
421 * Color primaries are implicitly converted throughout the processing
422 * pipeline. The video processor chooses the best moment to apply
423 * this conversion. The set of supported color primaries primaries
424 * for input shall be queried with vaQueryVideoProcPipelineCaps().
426 VAProcColorStandardType surface_color_standard;
428 * \brief Region within the output surface.
430 * Pointer to a #VARectangle defining the region within the output
431 * surface that receives the processed pixels. If NULL, \c output_region
432 * implies the whole surface.
434 * Note that any pixels residing outside the specified region will
435 * be filled in with the \ref output_background_color.
437 const VARectangle *output_region;
439 * \brief Background color.
441 * Background color used to fill in pixels that reside outside of the
442 * specified \ref output_region. The color is specified in ARGB format:
443 * [31:24] alpha, [23:16] red, [15:8] green, [7:0] blue.
445 * Unless the alpha value is zero or the \ref output_region represents
446 * the whole target surface size, implementations shall not render the
447 * source surface to the target surface directly. Rather, in order to
448 * maintain the exact semantics of \ref output_background_color, the
449 * driver shall use a temporary surface and fill it in with the
450 * appropriate background color. Next, the driver will blend this
451 * temporary surface into the target surface.
453 unsigned int output_background_color;
455 * \brief Requested output color primaries.
457 VAProcColorStandardType output_color_standard;
459 * \brief Pipeline filters. See video pipeline flags.
461 * Flags to control the pipeline, like whether to apply subpictures
462 * or not, notify the driver that it can opt for power optimizations,
463 * should this be needed.
465 unsigned int pipeline_flags;
467 * \brief Extra filter flags. See vaPutSurface() flags.
469 * Filter flags are used as a fast path, wherever possible, to use
470 * vaPutSurface() flags instead of explicit filter parameter buffers.
472 * Allowed filter flags API-wise. Use vaQueryVideoProcPipelineCaps()
473 * to check for implementation details:
474 * - Bob-deinterlacing: \c VA_FRAME_PICTURE, \c VA_TOP_FIELD,
475 * \c VA_BOTTOM_FIELD. Note that any deinterlacing filter
476 * (#VAProcFilterDeinterlacing) will override those flags.
477 * - Color space conversion: \c VA_SRC_BT601, \c VA_SRC_BT709,
478 * \c VA_SRC_SMPTE_240.
479 * - Scaling: \c VA_FILTER_SCALING_DEFAULT, \c VA_FILTER_SCALING_FAST,
480 * \c VA_FILTER_SCALING_HQ, \c VA_FILTER_SCALING_NL_ANAMORPHIC.
482 unsigned int filter_flags;
484 * \brief Array of filters to apply to the surface.
486 * The list of filters shall be ordered in the same way the driver expects
487 * them. i.e. as was returned from vaQueryVideoProcFilters().
488 * Otherwise, a #VA_STATUS_ERROR_INVALID_FILTER_CHAIN is returned
489 * from vaRenderPicture() with this buffer.
491 * #VA_STATUS_ERROR_UNSUPPORTED_FILTER is returned if the list
492 * contains an unsupported filter.
494 * Note: no filter buffer is destroyed after a call to vaRenderPicture(),
495 * only this pipeline buffer will be destroyed as per the core API
496 * specification. This allows for flexibility in re-using the filter for
497 * other surfaces to be processed.
499 VABufferID *filters;
500 /** \brief Actual number of filters. */
501 unsigned int num_filters;
502 /** \brief Array of forward reference frames. */
503 VASurfaceID *forward_references;
504 /** \brief Number of forward reference frames that were supplied. */
505 unsigned int num_forward_references;
506 /** \brief Array of backward reference frames. */
507 VASurfaceID *backward_references;
508 /** \brief Number of backward reference frames that were supplied. */
509 unsigned int num_backward_references;
510 } VAProcPipelineParameterBuffer;
513 * \brief Filter parameter buffer base.
515 * This is a helper structure used by driver implementations only.
516 * Users are not supposed to allocate filter parameter buffers of this
517 * type.
519 typedef struct _VAProcFilterParameterBufferBase {
520 /** \brief Filter type. */
521 VAProcFilterType type;
522 } VAProcFilterParameterBufferBase;
525 * \brief Default filter parametrization.
527 * Unless there is a filter-specific parameter buffer,
528 * #VAProcFilterParameterBuffer is the default type to use.
530 typedef struct _VAProcFilterParameterBuffer {
531 /** \brief Filter type. */
532 VAProcFilterType type;
533 /** \brief Value. */
534 float value;
535 } VAProcFilterParameterBuffer;
537 /** @name De-interlacing flags */
538 /**@{*/
539 /**
540 * \brief Bottom field first in the input frame.
541 * if this is not set then assumes top field first.
543 #define VA_DEINTERLACING_BOTTOM_FIELD_FIRST 0x0001
544 /**
545 * \brief Bottom field used in deinterlacing.
546 * if this is not set then assumes top field is used.
548 #define VA_DEINTERLACING_BOTTOM_FIELD 0x0002
549 /**
550 * \brief A single field is stored in the input frame.
551 * if this is not set then assumes the frame contains two interleaved fields.
553 #define VA_DEINTERLACING_ONE_FIELD 0x0004
554 /**@}*/
556 /** \brief Deinterlacing filter parametrization. */
557 typedef struct _VAProcFilterParameterBufferDeinterlacing {
558 /** \brief Filter type. Shall be set to #VAProcFilterDeinterlacing. */
559 VAProcFilterType type;
560 /** \brief Deinterlacing algorithm. */
561 VAProcDeinterlacingType algorithm;
562 /** \brief Deinterlacing flags. */
563 unsigned int flags;
564 } VAProcFilterParameterBufferDeinterlacing;
567 * \brief Color balance filter parametrization.
569 * This buffer defines color balance attributes. A VA buffer can hold
570 * several color balance attributes by creating a VA buffer of desired
571 * number of elements. This can be achieved by the following pseudo-code:
573 * \code
574 * enum { kHue, kSaturation, kBrightness, kContrast };
576 * // Initial color balance parameters
577 * static const VAProcFilterParameterBufferColorBalance colorBalanceParams[4] =
579 * [kHue] =
580 * { VAProcFilterColorBalance, VAProcColorBalanceHue, 0.5 },
581 * [kSaturation] =
582 * { VAProcFilterColorBalance, VAProcColorBalanceSaturation, 0.5 },
583 * [kBrightness] =
584 * { VAProcFilterColorBalance, VAProcColorBalanceBrightness, 0.5 },
585 * [kSaturation] =
586 * { VAProcFilterColorBalance, VAProcColorBalanceSaturation, 0.5 }
587 * };
589 * // Create buffer
590 * VABufferID colorBalanceBuffer;
591 * vaCreateBuffer(va_dpy, vpp_ctx,
592 * VAProcFilterParameterBufferType, sizeof(*pColorBalanceParam), 4,
593 * colorBalanceParams,
594 * &colorBalanceBuffer
595 * );
597 * VAProcFilterParameterBufferColorBalance *pColorBalanceParam;
598 * vaMapBuffer(va_dpy, colorBalanceBuffer, &pColorBalanceParam);
600 * // Change brightness only
601 * pColorBalanceBuffer[kBrightness].value = 0.75;
603 * vaUnmapBuffer(va_dpy, colorBalanceBuffer);
604 * \endcode
606 typedef struct _VAProcFilterParameterBufferColorBalance {
607 /** \brief Filter type. Shall be set to #VAProcFilterColorBalance. */
608 VAProcFilterType type;
609 /** \brief Color balance attribute. */
610 VAProcColorBalanceType attrib;
612 * \brief Color balance value.
614 * Special case for automatically adjusted attributes. e.g.
615 * #VAProcColorBalanceAutoSaturation,
616 * #VAProcColorBalanceAutoBrightness,
617 * #VAProcColorBalanceAutoContrast.
618 * - If \ref value is \c 1.0 +/- \c FLT_EPSILON, the attribute is
619 * automatically adjusted and overrides any other attribute of
620 * the same type that would have been set explicitly;
621 * - If \ref value is \c 0.0 +/- \c FLT_EPSILON, the attribute is
622 * disabled and other attribute of the same type is used instead.
624 float value;
625 } VAProcFilterParameterBufferColorBalance;
628 * \brief Default filter cap specification (single range value).
630 * Unless there is a filter-specific cap structure, #VAProcFilterCap is the
631 * default type to use for output caps from vaQueryVideoProcFilterCaps().
633 typedef struct _VAProcFilterCap {
634 /** \brief Range of supported values for the filter. */
635 VAProcFilterValueRange range;
636 } VAProcFilterCap;
638 /** \brief Capabilities specification for the deinterlacing filter. */
639 typedef struct _VAProcFilterCapDeinterlacing {
640 /** \brief Deinterlacing algorithm. */
641 VAProcDeinterlacingType type;
642 } VAProcFilterCapDeinterlacing;
644 /** \brief Capabilities specification for the color balance filter. */
645 typedef struct _VAProcFilterCapColorBalance {
646 /** \brief Color balance operation. */
647 VAProcColorBalanceType type;
648 /** \brief Range of supported values for the specified operation. */
649 VAProcFilterValueRange range;
650 } VAProcFilterCapColorBalance;
653 * \brief Queries video processing filters.
655 * This function returns the list of video processing filters supported
656 * by the driver. The \c filters array is allocated by the user and
657 * \c num_filters shall be initialized to the number of allocated
658 * elements in that array. Upon successful return, the actual number
659 * of filters will be overwritten into \c num_filters. Otherwise,
660 * \c VA_STATUS_ERROR_MAX_NUM_EXCEEDED is returned and \c num_filters
661 * is adjusted to the number of elements that would be returned if enough
662 * space was available.
664 * The list of video processing filters supported by the driver shall
665 * be ordered in the way they can be iteratively applied. This is needed
666 * for both correctness, i.e. some filters would not mean anything if
667 * applied at the beginning of the pipeline; but also for performance
668 * since some filters can be applied in a single pass (e.g. noise
669 * reduction + deinterlacing).
671 * @param[in] dpy the VA display
672 * @param[in] context the video processing context
673 * @param[out] filters the output array of #VAProcFilterType elements
674 * @param[in,out] num_filters the number of elements allocated on input,
675 * the number of elements actually filled in on output
677 VAStatus
678 vaQueryVideoProcFilters(
679 VADisplay dpy,
680 VAContextID context,
681 VAProcFilterType *filters,
682 unsigned int *num_filters
686 * \brief Queries video filter capabilities.
688 * This function returns the list of capabilities supported by the driver
689 * for a specific video filter. The \c filter_caps array is allocated by
690 * the user and \c num_filter_caps shall be initialized to the number
691 * of allocated elements in that array. Upon successful return, the
692 * actual number of filters will be overwritten into \c num_filter_caps.
693 * Otherwise, \c VA_STATUS_ERROR_MAX_NUM_EXCEEDED is returned and
694 * \c num_filter_caps is adjusted to the number of elements that would be
695 * returned if enough space was available.
697 * @param[in] dpy the VA display
698 * @param[in] context the video processing context
699 * @param[in] type the video filter type
700 * @param[out] filter_caps the output array of #VAProcFilterCap elements
701 * @param[in,out] num_filter_caps the number of elements allocated on input,
702 * the number of elements actually filled in output
704 VAStatus
705 vaQueryVideoProcFilterCaps(
706 VADisplay dpy,
707 VAContextID context,
708 VAProcFilterType type,
709 void *filter_caps,
710 unsigned int *num_filter_caps
714 * \brief Queries video processing pipeline capabilities.
716 * This function returns the video processing pipeline capabilities. The
717 * \c filters array defines the video processing pipeline and is an array
718 * of buffers holding filter parameters.
720 * Note: the #VAProcPipelineCaps structure contains user-provided arrays.
721 * If non-NULL, the corresponding \c num_* fields shall be filled in on
722 * input with the number of elements allocated. Upon successful return,
723 * the actual number of elements will be overwritten into the \c num_*
724 * fields. Otherwise, \c VA_STATUS_ERROR_MAX_NUM_EXCEEDED is returned
725 * and \c num_* fields are adjusted to the number of elements that would
726 * be returned if enough space was available.
728 * @param[in] dpy the VA display
729 * @param[in] context the video processing context
730 * @param[in] filters the array of VA buffers defining the video
731 * processing pipeline
732 * @param[in] num_filters the number of elements in filters
733 * @param[in,out] pipeline_caps the video processing pipeline capabilities
735 VAStatus
736 vaQueryVideoProcPipelineCaps(
737 VADisplay dpy,
738 VAContextID context,
739 VABufferID *filters,
740 unsigned int num_filters,
741 VAProcPipelineCaps *pipeline_caps
744 /**@}*/
746 #ifdef __cplusplus
748 #endif
750 #endif /* VA_VPP_H */