1 /* 2 * Copyright (c) 2007-2009 Intel Corporation. All Rights Reserved. 3 * 4 * Permission is hereby granted, free of charge, to any person obtaining a 5 * copy of this software and associated documentation files (the 6 * "Software"), to deal in the Software without restriction, including 7 * without limitation the rights to use, copy, modify, merge, publish, 8 * distribute, sub license, and/or sell copies of the Software, and to 9 * permit persons to whom the Software is furnished to do so, subject to 10 * the following conditions: 11 * 12 * The above copyright notice and this permission notice (including the 13 * next paragraph) shall be included in all copies or substantial portions 14 * of the Software. 15 * 16 * THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS 17 * OR IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF 18 * MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE AND NON-INFRINGEMENT. 19 * IN NO EVENT SHALL INTEL AND/OR ITS SUPPLIERS BE LIABLE FOR 20 * ANY CLAIM, DAMAGES OR OTHER LIABILITY, WHETHER IN AN ACTION OF CONTRACT, 21 * TORT OR OTHERWISE, ARISING FROM, OUT OF OR IN CONNECTION WITH THE 22 * SOFTWARE OR THE USE OR OTHER DEALINGS IN THE SOFTWARE. 23 */ 24 /* 25 * Video Acceleration (VA) API Specification 26 * 27 * Rev. 0.30 28 * <jonathan.bian@intel.com> 29 * 30 * Revision History: 31 * rev 0.10 (12/10/2006 Jonathan Bian) - Initial draft 32 * rev 0.11 (12/15/2006 Jonathan Bian) - Fixed some errors 33 * rev 0.12 (02/05/2007 Jonathan Bian) - Added VC-1 data structures for slice level decode 34 * rev 0.13 (02/28/2007 Jonathan Bian) - Added GetDisplay() 35 * rev 0.14 (04/13/2007 Jonathan Bian) - Fixed MPEG-2 PictureParameter structure, cleaned up a few funcs. 36 * rev 0.15 (04/20/2007 Jonathan Bian) - Overhauled buffer management 37 * rev 0.16 (05/02/2007 Jonathan Bian) - Added error codes and fixed some issues with configuration 38 * rev 0.17 (05/07/2007 Jonathan Bian) - Added H.264/AVC data structures for slice level decode. 39 * rev 0.18 (05/14/2007 Jonathan Bian) - Added data structures for MPEG-4 slice level decode 40 * and MPEG-2 motion compensation. 41 * rev 0.19 (08/06/2007 Jonathan Bian) - Removed extra type for bitplane data. 42 * rev 0.20 (08/08/2007 Jonathan Bian) - Added missing fields to VC-1 PictureParameter structure. 43 * rev 0.21 (08/20/2007 Jonathan Bian) - Added image and subpicture support. 44 * rev 0.22 (08/27/2007 Jonathan Bian) - Added support for chroma-keying and global alpha. 45 * rev 0.23 (09/11/2007 Jonathan Bian) - Fixed some issues with images and subpictures. 46 * rev 0.24 (09/18/2007 Jonathan Bian) - Added display attributes. 47 * rev 0.25 (10/18/2007 Jonathan Bian) - Changed to use IDs only for some types. 48 * rev 0.26 (11/07/2007 Waldo Bastian) - Change vaCreateBuffer semantics 49 * rev 0.27 (11/19/2007 Matt Sottek) - Added DeriveImage 50 * rev 0.28 (12/06/2007 Jonathan Bian) - Added new versions of PutImage and AssociateSubpicture 51 * to enable scaling 52 * rev 0.29 (02/07/2008 Jonathan Bian) - VC1 parameter fixes, 53 * added VA_STATUS_ERROR_RESOLUTION_NOT_SUPPORTED 54 * rev 0.30 (03/01/2009 Jonathan Bian) - Added encoding support for H.264 BP and MPEG-4 SP and fixes 55 * for ISO C conformance. 56 * rev 0.31 (09/02/2009 Gwenole Beauchesne) - VC-1/H264 fields change for VDPAU and XvBA backend 57 * Application needs to relink with the new library. 58 * 59 * rev 0.31.1 (03/29/2009) - Data structure for JPEG encode 60 * rev 0.31.2 (01/13/2011 Anthony Pabon)- Added a flag to indicate Subpicture coordinates are screen 61 * screen relative rather than source video relative. 62 * rev 0.32.0 (01/13/2011 Xiang Haihao) - Add profile into VAPictureParameterBufferVC1 63 * update VAAPI to 0.32.0 64 * 65 * Acknowledgements: 66 * Some concepts borrowed from XvMC and XvImage. 67 * Waldo Bastian (Intel), Matt Sottek (Intel), Austin Yuan (Intel), and Gwenole Beauchesne (SDS) 68 * contributed to various aspects of the API. 69 */ 70 71 /** 72 * \file va.h 73 * \brief The Core API 74 * 75 * This file contains the \ref api_core "Core API". 76 */ 77 78 #ifndef _VA_H_ 79 #define _VA_H_ 80 81 #include <stdint.h> 82 #include <va/va_version.h> 83 84 #ifdef __cplusplus 85 extern "C" { 86 #endif 87 88 #ifdef __GNUC__ 89 # define __maybe_unused __attribute__((__unused__)) 90 #else 91 # define __maybe_unused 92 #endif 93 94 /** 95 * \mainpage Video Acceleration (VA) API 96 * 97 * \section intro Introduction 98 * 99 * The main motivation for VA-API (Video Acceleration API) is to 100 * enable hardware accelerated video decode and encode at various 101 * entry-points (VLD, IDCT, Motion Compensation etc.) for the 102 * prevailing coding standards today (MPEG-2, MPEG-4 ASP/H.263, MPEG-4 103 * AVC/H.264, VC-1/VMW3, and JPEG). 104 * 105 * VA-API is split into several modules: 106 * - \ref api_core 107 * - \ref api_enc_core 108 * - \ref api_enc_h264 109 * - \ref api_vpp 110 */ 111 112 /** 113 * \defgroup api_core Core API 114 * 115 * @{ 116 */ 117 118 /* 119 Overview 120 121 The VA API is intended to provide an interface between a video decode/encode/display 122 application (client) and a hardware accelerator (server), to off-load 123 video decode/encode/display operations from the host to the hardware accelerator at various 124 entry-points. 125 126 The basic operation steps are: 127 128 - Negotiate a mutually acceptable configuration with the server to lock 129 down profile, entrypoints, and other attributes that will not change on 130 a frame-by-frame basis. 131 - Create a decode context which represents a "virtualized" hardware decode 132 device 133 - Get and fill decode buffers with picture level, slice level and macroblock 134 level data (depending on entrypoints) 135 - Pass the decode buffers to the server to decode the current frame 136 137 Initialization & Configuration Management 138 139 - Find out supported profiles 140 - Find out entrypoints for a given profile 141 - Find out configuration attributes for a given profile/entrypoint pair 142 - Create a configuration for use by the decoder 143 144 */ 145 146 typedef void* VADisplay; /* window system dependent */ 147 148 typedef int VAStatus; /* Return status type from functions */ 149 /* Values for the return status */ 150 #define VA_STATUS_SUCCESS 0x00000000 151 #define VA_STATUS_ERROR_OPERATION_FAILED 0x00000001 152 #define VA_STATUS_ERROR_ALLOCATION_FAILED 0x00000002 153 #define VA_STATUS_ERROR_INVALID_DISPLAY 0x00000003 154 #define VA_STATUS_ERROR_INVALID_CONFIG 0x00000004 155 #define VA_STATUS_ERROR_INVALID_CONTEXT 0x00000005 156 #define VA_STATUS_ERROR_INVALID_SURFACE 0x00000006 157 #define VA_STATUS_ERROR_INVALID_BUFFER 0x00000007 158 #define VA_STATUS_ERROR_INVALID_IMAGE 0x00000008 159 #define VA_STATUS_ERROR_INVALID_SUBPICTURE 0x00000009 160 #define VA_STATUS_ERROR_ATTR_NOT_SUPPORTED 0x0000000a 161 #define VA_STATUS_ERROR_MAX_NUM_EXCEEDED 0x0000000b 162 #define VA_STATUS_ERROR_UNSUPPORTED_PROFILE 0x0000000c 163 #define VA_STATUS_ERROR_UNSUPPORTED_ENTRYPOINT 0x0000000d 164 #define VA_STATUS_ERROR_UNSUPPORTED_RT_FORMAT 0x0000000e 165 #define VA_STATUS_ERROR_UNSUPPORTED_BUFFERTYPE 0x0000000f 166 #define VA_STATUS_ERROR_SURFACE_BUSY 0x00000010 167 #define VA_STATUS_ERROR_FLAG_NOT_SUPPORTED 0x00000011 168 #define VA_STATUS_ERROR_INVALID_PARAMETER 0x00000012 169 #define VA_STATUS_ERROR_RESOLUTION_NOT_SUPPORTED 0x00000013 170 #define VA_STATUS_ERROR_UNIMPLEMENTED 0x00000014 171 #define VA_STATUS_ERROR_SURFACE_IN_DISPLAYING 0x00000015 172 #define VA_STATUS_ERROR_INVALID_IMAGE_FORMAT 0x00000016 173 #define VA_STATUS_ERROR_DECODING_ERROR 0x00000017 174 #define VA_STATUS_ERROR_ENCODING_ERROR 0x00000018 175 /** 176 * \brief An invalid/unsupported value was supplied. 177 * 178 * This is a catch-all error code for invalid or unsupported values. 179 * e.g. value exceeding the valid range, invalid type in the context 180 * of generic attribute values. 181 */ 182 #define VA_STATUS_ERROR_INVALID_VALUE 0x00000019 183 /** \brief An unsupported filter was supplied. */ 184 #define VA_STATUS_ERROR_UNSUPPORTED_FILTER 0x00000020 185 /** \brief An invalid filter chain was supplied. */ 186 #define VA_STATUS_ERROR_INVALID_FILTER_CHAIN 0x00000021 187 /** \brief Indicate HW busy (e.g. run multiple encoding simultaneously). */ 188 #define VA_STATUS_ERROR_HW_BUSY 0x00000022 189 /** \brief An invalid blend state was supplied. */ 190 #define VA_STATUS_ERROR_INVALID_BLEND_STATE 0x00000023 191 #define VA_STATUS_ERROR_UNKNOWN 0xFFFFFFFF 192 193 /* De-interlacing flags for vaPutSurface() */ 194 #define VA_FRAME_PICTURE 0x00000000 195 #define VA_TOP_FIELD 0x00000001 196 #define VA_BOTTOM_FIELD 0x00000002 197 198 /* 199 * Enabled the positioning/cropping/blending feature: 200 * 1, specify the video playback position in the isurface 201 * 2, specify the cropping info for video playback 202 * 3, encoded video will blend with background color 203 */ 204 #define VA_ENABLE_BLEND 0x00000004 /* video area blend with the constant color */ 205 206 /* 207 * Clears the drawable with background color. 208 * for hardware overlay based implementation this flag 209 * can be used to turn off the overlay 210 */ 211 #define VA_CLEAR_DRAWABLE 0x00000008 212 213 /* Color space conversion flags for vaPutSurface() */ 214 #define VA_SRC_COLOR_MASK 0x000000f0 215 #define VA_SRC_BT601 0x00000010 216 #define VA_SRC_BT709 0x00000020 217 #define VA_SRC_SMPTE_240 0x00000040 218 #define VA_SRC_BT2020 0x00000080 219 220 /* Scaling flags for vaPutSurface() */ 221 #define VA_FILTER_SCALING_DEFAULT 0x00000000 222 #define VA_FILTER_SCALING_FAST 0x00000100 223 #define VA_FILTER_SCALING_HQ 0x00000200 224 #define VA_FILTER_SCALING_NL_ANAMORPHIC 0x00000300 225 #define VA_FILTER_SCALING_MASK 0x00000f00 226 227 /* 228 * The upper 16 bits are reserved for VPP filter fast path usage. 229 * Flag to enable auto noise reduction. 230 */ 231 #define VA_FILTER_NOISEREDUCTION_AUTO 0x00010000 232 233 /* 234 * This is to indicate that the color-space conversion uses full range or reduced range. 235 * VA_SOURCE_RANGE_FULL(Full range): Y/Cb/Cr is in [0, 255]. It is mainly used 236 * for JPEG/JFIF formats. The combination with the BT601 flag means that 237 * JPEG/JFIF color-space conversion matrix is used. 238 * VA_SOURCE_RANGE_REDUCED(Reduced range): Y is in [16, 235] and Cb/Cr is in [16, 240]. 239 * It is mainly used for the YUV->RGB color-space conversion in SDTV/HDTV/UHDTV. 240 */ 241 #define VA_SOURCE_RANGE_MASK 0x00020000 242 #define VA_SOURCE_RANGE_FULL 0x00020000 243 #define VA_SOURCE_RANGE_REDUCED 0x00000000 244 /* 245 * Returns a short english description of error_status 246 */ 247 const char *vaErrorStr(VAStatus error_status); 248 249 typedef struct _VARectangle 250 { 251 short x; 252 short y; 253 unsigned short width; 254 unsigned short height; 255 } VARectangle; 256 257 /** \brief Generic motion vector data structure. */ 258 typedef struct _VAMotionVector { 259 /** \mv0[0]: horizontal motion vector for past reference */ 260 /** \mv0[1]: vertical motion vector for past reference */ 261 /** \mv1[0]: horizontal motion vector for future reference */ 262 /** \mv1[1]: vertical motion vector for future reference */ 263 unsigned short mv0[2]; /* past reference */ 264 unsigned short mv1[2]; /* future reference */ 265 } VAMotionVector; 266 267 /* 268 * Initialization: 269 * A display must be obtained by calling vaGetDisplay() before calling 270 * vaInitialize() and other functions. This connects the API to the 271 * native window system. 272 * For X Windows, native_dpy would be from XOpenDisplay() 273 */ 274 typedef void* VANativeDisplay; /* window system dependent */ 275 276 int vaDisplayIsValid(VADisplay dpy); 277 278 /* 279 * Initialize the library 280 */ 281 VAStatus vaInitialize ( 282 VADisplay dpy, 283 int *major_version, /* out */ 284 int *minor_version /* out */ 285 ); 286 287 /* 288 * After this call, all library internal resources will be cleaned up 289 */ 290 VAStatus vaTerminate ( 291 VADisplay dpy 292 ); 293 294 /* 295 * vaQueryVendorString returns a pointer to a zero-terminated string 296 * describing some aspects of the VA implemenation on a specific 297 * hardware accelerator. The format of the returned string is vendor 298 * specific and at the discretion of the implementer. 299 * e.g. for the Intel GMA500 implementation, an example would be: 300 * "Intel GMA500 - 2.0.0.32L.0005" 301 */ 302 const char *vaQueryVendorString ( 303 VADisplay dpy 304 ); 305 306 typedef int (*VAPrivFunc)(); 307 308 /* 309 * Return a function pointer given a function name in the library. 310 * This allows private interfaces into the library 311 */ 312 VAPrivFunc vaGetLibFunc ( 313 VADisplay dpy, 314 const char *func 315 ); 316 317 /* Currently defined profiles */ 318 typedef enum 319 { 320 /** \brief Profile ID used for video processing. */ 321 VAProfileNone = -1, 322 VAProfileMPEG2Simple = 0, 323 VAProfileMPEG2Main = 1, 324 VAProfileMPEG4Simple = 2, 325 VAProfileMPEG4AdvancedSimple = 3, 326 VAProfileMPEG4Main = 4, 327 VAProfileH264Baseline = 5, 328 VAProfileH264Main = 6, 329 VAProfileH264High = 7, 330 VAProfileVC1Simple = 8, 331 VAProfileVC1Main = 9, 332 VAProfileVC1Advanced = 10, 333 VAProfileH263Baseline = 11, 334 VAProfileJPEGBaseline = 12, 335 VAProfileH264ConstrainedBaseline = 13, 336 VAProfileVP8Version0_3 = 14, 337 VAProfileH264MultiviewHigh = 15, 338 VAProfileH264StereoHigh = 16, 339 VAProfileHEVCMain = 17, 340 VAProfileHEVCMain10 = 18, 341 VAProfileVP9Version0 = 19, 342 VAProfileAVS = 20, 343 VAProfileMax 344 } VAProfile; 345 346 /* 347 * Currently defined entrypoints 348 */ 349 typedef enum 350 { 351 VAEntrypointVLD = 1, 352 VAEntrypointIZZ = 2, 353 VAEntrypointIDCT = 3, 354 VAEntrypointMoComp = 4, 355 VAEntrypointDeblocking = 5, 356 VAEntrypointEncSlice = 6, /* slice level encode */ 357 VAEntrypointEncPicture = 7, /* pictuer encode, JPEG, etc */ 358 /* 359 * For an implementation that supports a low power/high performance variant 360 * for slice level encode, it can choose to expose the 361 * VAEntrypointEncSliceLP entrypoint. Certain encoding tools may not be 362 * available with this entrypoint (e.g. interlace, MBAFF) and the 363 * application can query the encoding configuration attributes to find 364 * out more details if this entrypoint is supported. 365 */ 366 VAEntrypointEncSliceLP = 8, 367 VAEntrypointVideoProc = 10, /**< Video pre/post-processing. */ 368 369 /** 370 * \brief Intel specific entrypoints start at 1001 371 */ 372 /** 373 * \brief VAEntrypointEncFEIIntel 374 * 375 * The purpose of FEI (Flexible Encoding Infrastructure) is to allow applications to 376 * have more controls and trade off quality for speed with their own IPs. A pre-processing 377 * function for getting some statistics and motion vectors is added 378 * and some extra controls for Encode pipeline are provided. 379 * The application can optionally call the statistics function 380 * to get motion vectors and statistics before calling encode function. 381 * The application can also optionally provide input to VME for extra 382 * encode control and get the output from VME. Application can chose to 383 * modify the VME output/PAK input during encoding, but the performance 384 * impact is significant. 385 * 386 * On top of the existing buffers for normal encode, there will be 387 * one extra input buffer (VAEncMiscParameterIntelFEIFrameControl) and 388 * three extra output buffers (VAIntelEncFEIMVBufferType, VAIntelEncFEIModeBufferType 389 * and VAIntelEncFEIDistortionBufferType) for VAEntrypointIntelEncFEI entry function. 390 * If separate PAK is set, two extra input buffers 391 * (VAIntelEncFEIMVBufferType, VAIntelEncFEIModeBufferType) are needed for PAK input. 392 * 393 **/ 394 VAEntrypointEncFEIIntel = 1001, 395 /** 396 * \brief VAEntrypointStatisticsIntel 397 * 398 * Statistics, like variances, distortions, motion vectors can be obtained 399 * via this entry point. Checking whether Statistics is supported can be 400 * performed with vaQueryConfigEntrypoints() and the profile argument 401 * set to #VAProfileNone. If Statistics entry point is supported, 402 * then the list of returned entry-points will include #VAEntrypointIntelStatistics. 403 * Supported pixel format, maximum resolution and statistics specific attributes 404 * can be obtained via normal attribute query. 405 * One input buffer (VAIntelStatsStatisticsParameterBufferType) and one or two 406 * output buffers (VAIntelStatsStatisticsBufferType and VAIntelStatsMotionVectorBufferType) 407 * are needed for this entry point. 408 * 409 **/ 410 VAEntrypointStatisticsIntel, 411 VAEntrypointMax 412 } VAEntrypoint; 413 414 /* Currently defined configuration attribute types */ 415 typedef enum 416 { 417 VAConfigAttribRTFormat = 0, 418 VAConfigAttribSpatialResidual = 1, 419 VAConfigAttribSpatialClipping = 2, 420 VAConfigAttribIntraResidual = 3, 421 VAConfigAttribEncryption = 4, 422 VAConfigAttribRateControl = 5, 423 424 /** @name Attributes for decoding */ 425 /**@{*/ 426 /** 427 * \brief Slice Decoding mode. Read/write. 428 * 429 * This attribute determines what mode the driver supports for slice 430 * decoding, through vaGetConfigAttributes(); and what mode the user 431 * will be providing to the driver, through vaCreateConfig(), if the 432 * driver supports those. If this attribute is not set by the user then 433 * it is assumed that VA_DEC_SLICE_MODE_NORMAL mode is used. 434 * 435 * See \c VA_DEC_SLICE_MODE_xxx for the list of slice decoding modes. 436 */ 437 VAConfigAttribDecSliceMode = 6, 438 /** 439 * \brief JPEG decoding attribute. Read-only. 440 * 441 * This attribute exposes a number of capabilities of the underlying 442 * JPEG implementation. The attribute value is partitioned into fields as defined in the 443 * VAConfigAttribValDecJPEG union. 444 */ 445 VAConfigAttribDecJPEG = 7, 446 447 /** @name Attributes for encoding */ 448 /**@{*/ 449 /** 450 * \brief Packed headers mode. Read/write. 451 * 452 * This attribute determines what packed headers the driver supports, 453 * through vaGetConfigAttributes(); and what packed headers the user 454 * will be providing to the driver, through vaCreateConfig(), if the 455 * driver supports those. 456 * 457 * See \c VA_ENC_PACKED_HEADER_xxx for the list of packed headers. 458 */ 459 VAConfigAttribEncPackedHeaders = 10, 460 /** 461 * \brief Interlaced mode. Read/write. 462 * 463 * This attribute determines what kind of interlaced encoding mode 464 * the driver supports. 465 * 466 * See \c VA_ENC_INTERLACED_xxx for the list of interlaced modes. 467 */ 468 VAConfigAttribEncInterlaced = 11, 469 /** 470 * \brief Maximum number of reference frames. Read-only. 471 * 472 * This attribute determines the maximum number of reference 473 * frames supported for encoding. 474 * 475 * Note: for H.264 encoding, the value represents the maximum number 476 * of reference frames for both the reference picture list 0 (bottom 477 * 16 bits) and the reference picture list 1 (top 16 bits). 478 */ 479 VAConfigAttribEncMaxRefFrames = 13, 480 /** 481 * \brief Maximum number of slices per frame. Read-only. 482 * 483 * This attribute determines the maximum number of slices the 484 * driver can support to encode a single frame. 485 */ 486 VAConfigAttribEncMaxSlices = 14, 487 /** 488 * \brief Slice structure. Read-only. 489 * 490 * This attribute determines slice structures supported by the 491 * driver for encoding. This attribute is a hint to the user so 492 * that he can choose a suitable surface size and how to arrange 493 * the encoding process of multiple slices per frame. 494 * 495 * More specifically, for H.264 encoding, this attribute 496 * determines the range of accepted values to 497 * VAEncSliceParameterBufferH264::macroblock_address and 498 * VAEncSliceParameterBufferH264::num_macroblocks. 499 * 500 * See \c VA_ENC_SLICE_STRUCTURE_xxx for the supported slice 501 * structure types. 502 */ 503 VAConfigAttribEncSliceStructure = 15, 504 /** 505 * \brief Macroblock information. Read-only. 506 * 507 * This attribute determines whether the driver supports extra 508 * encoding information per-macroblock. e.g. QP. 509 * 510 * More specifically, for H.264 encoding, if the driver returns a non-zero 511 * value for this attribute, this means the application can create 512 * additional #VAEncMacroblockParameterBufferH264 buffers referenced 513 * through VAEncSliceParameterBufferH264::macroblock_info. 514 */ 515 VAConfigAttribEncMacroblockInfo = 16, 516 /** 517 * \brief Auto reference frame management. Read-only 518 * 519 * This attribute determines whether the driver supports auto reference management 520 * 521 * If driver supports, application only needs to set scratch reference surfaces 522 * via VAPictureParameterBufferH264:ReferenceFrames. The scratch surfaces number is 523 * determined by the maximum number of RefPicList0 and RefPicList0 which can be queried from 524 * VAConfigAttribEncMaxRefFrames. Application doesn't need to set VAPictureParameterBufferH264:CurrPic 525 * and VAEncSliceParameterBufferH264:RefPicList. Driver will manage the reference frames internally 526 * and choose the best reference frames. Which scratch surface is used for reconstructed frame and which 527 * surfaces are used for reference frames will be fedback via VACodedBufferSegment 528 */ 529 VAConfigAttribEncAutoReference = 17, 530 /** 531 * \brief Maximum picture width. Read-only. 532 * 533 * This attribute determines the maximum picture width the driver supports 534 * for a given configuration. 535 */ 536 VAConfigAttribMaxPictureWidth = 18, 537 /** 538 * \brief Maximum picture height. Read-only. 539 * 540 * This attribute determines the maximum picture height the driver supports 541 * for a given configuration. 542 */ 543 VAConfigAttribMaxPictureHeight = 19, 544 /** 545 * \brief JPEG encoding attribute. Read-only. 546 * 547 * This attribute exposes a number of capabilities of the underlying 548 * JPEG implementation. The attribute value is partitioned into fields as defined in the 549 * VAConfigAttribValEncJPEG union. 550 */ 551 VAConfigAttribEncJPEG = 20, 552 /** 553 * \brief Encoding quality range attribute. Read-only. 554 * 555 * This attribute conveys whether the driver supports different quality level settings 556 * for encoding. A value less than or equal to 1 means that the encoder only has a single 557 * quality setting, and a value greater than 1 represents the number of quality levels 558 * that can be configured. e.g. a value of 2 means there are two distinct quality levels. 559 */ 560 VAConfigAttribEncQualityRange = 21, 561 /** 562 * \brief Encoding quantization attribute. Read-only. 563 * 564 * This attribute conveys whether the driver supports certain types of quantization methods 565 * for encoding (e.g. trellis). 566 */ 567 VAConfigAttribEncQuantization = 22, 568 /** 569 * \brief Encoding intra refresh attribute. Read-only. 570 * 571 * This attribute conveys whether the driver supports certain types of intra refresh methods 572 * for encoding (e.g. adaptive intra refresh or rolling intra refresh). 573 */ 574 VAConfigAttribEncIntraRefresh = 23, 575 /** 576 * \brief Encoding skip frame attribute. Read-only. 577 * 578 * This attribute conveys whether the driver supports sending skip frame parameters 579 * (VAEncMiscParameterTypeSkipFrame) to the encoder's rate control, when the user has 580 * externally skipped frames. It is a boolean value 0 - unsupported, 1 - supported. 581 */ 582 VAConfigAttribEncSkipFrame = 24, 583 /** 584 * \brief Encoding region-of-interest (ROI) attribute. Read-only. 585 * 586 * This attribute conveys whether the driver supports region-of-interest (ROI) encoding, 587 * based on user provided ROI rectangles. The attribute value returned indicates the number 588 * of regions that are supported. e.g. A value of 0 means ROI encoding is not supported. 589 * If ROI encoding is supported, the ROI information is passed to the driver using 590 * VAEncMiscParameterTypeRoi. 591 */ 592 VAConfigAttribEncRoi = 25, 593 /** 594 * \brief Encoding extended rate control attribute. Read-only. 595 * 596 * This attribute conveys whether the driver supports any extended rate control features 597 * The attribute value is partitioned into fields as defined in the 598 * VAConfigAttribValEncRateControlExt union. 599 */ 600 VAConfigAttribEncRateControlExt = 26, 601 /** 602 * \brief Intel specific attributes start at 1001 603 */ 604 /** 605 * \brief Encode function type. 606 * 607 * This attribute conveys whether the driver supports different function types for encode. 608 * It can be ENC, PAK, or ENC + PAK. Currently it is for FEI entry point only. 609 * Default is ENC + PAK. 610 */ 611 VAConfigAttribEncFunctionTypeIntel = 1001, 612 /** 613 * \brief Maximum number of MV predictors. Read-only. 614 * 615 * This attribute determines the maximum number of MV predictors the driver 616 * can support to encode a single frame. 0 means no MV predictor is supported. 617 */ 618 VAConfigAttribEncMVPredictorsIntel, 619 /** 620 * \brief Statistics attribute. Read-only. 621 * 622 * This attribute exposes a number of capabilities of the VAEntrypointStatistics entry 623 * point. The attribute value is partitioned into fields as defined in the 624 * VAConfigAttribValStatistics union. 625 */ 626 VAConfigAttribStatisticsIntel, 627 /**@}*/ 628 VAConfigAttribTypeMax 629 } VAConfigAttribType; 630 631 /* 632 * Configuration attributes 633 * If there is more than one value for an attribute, a default 634 * value will be assigned to the attribute if the client does not 635 * specify the attribute when creating a configuration 636 */ 637 typedef struct _VAConfigAttrib { 638 VAConfigAttribType type; 639 unsigned int value; /* OR'd flags (bits) for this attribute */ 640 } VAConfigAttrib; 641 642 /* attribute value for VAConfigAttribRTFormat */ 643 #define VA_RT_FORMAT_YUV420 0x00000001 644 #define VA_RT_FORMAT_YUV422 0x00000002 645 #define VA_RT_FORMAT_YUV444 0x00000004 646 #define VA_RT_FORMAT_YUV411 0x00000008 647 #define VA_RT_FORMAT_YUV400 0x00000010 648 #define VA_RT_FORMAT_RGB16 0x00010000 649 #define VA_RT_FORMAT_RGB32 0x00020000 650 /* RGBP covers RGBP and BGRP fourcc */ 651 #define VA_RT_FORMAT_RGBP 0x00100000 652 #define VA_RT_FORMAT_PROTECTED 0x80000000 653 654 /** @name Attribute values for VAConfigAttribRateControl */ 655 /**@{*/ 656 /** \brief Driver does not support any form of rate control. */ 657 #define VA_RC_NONE 0x00000001 658 /** \brief Constant bitrate. */ 659 #define VA_RC_CBR 0x00000002 660 /** \brief Variable bitrate. */ 661 #define VA_RC_VBR 0x00000004 662 /** \brief Video conference mode. */ 663 #define VA_RC_VCM 0x00000008 664 /** \brief Constant QP. */ 665 #define VA_RC_CQP 0x00000010 666 /** \brief Variable bitrate with peak rate higher than average bitrate. */ 667 #define VA_RC_VBR_CONSTRAINED 0x00000020 668 /** \brief Intelligent Constant Quality. Provided an initial ICQ_quality_factor, 669 * adjusts QP at a frame and MB level based on motion to improve subjective quality. */ 670 #define VA_RC_ICQ 0x00000040 671 /** \brief Macroblock based rate control. Per MB control is decided 672 * internally in the encoder. It may be combined with other RC modes, except CQP. */ 673 #define VA_RC_MB 0x00000080 674 675 /**@}*/ 676 677 /** @name Attribute values for VAConfigAttribDecSliceMode */ 678 /**@{*/ 679 /** \brief Driver supports normal mode for slice decoding */ 680 #define VA_DEC_SLICE_MODE_NORMAL 0x00000001 681 /** \brief Driver supports base mode for slice decoding */ 682 #define VA_DEC_SLICE_MODE_BASE 0x00000002 683 684 /** @name Attribute values for VAConfigAttribDecJPEG */ 685 /**@{*/ 686 typedef union _VAConfigAttribValDecJPEG { 687 /** \brief Set to (1 << VA_ROTATION_xxx) for supported rotation angles. */ 688 unsigned int rotation; 689 /** \brief Reserved for future use. */ 690 unsigned int reserved[3]; 691 } VAConfigAttribValDecJPEG; 692 /** \brief Driver supports subsample mode for slice decoding */ 693 #define VA_DEC_SLICE_MODE_SUBSAMPLE 0x00000004 694 695 /**@}*/ 696 697 /** @name Attribute values for VAConfigAttribEncPackedHeaders */ 698 /**@{*/ 699 /** \brief Driver does not support any packed headers mode. */ 700 #define VA_ENC_PACKED_HEADER_NONE 0x00000000 701 /** \brief Driver supports packed sequence headers. e.g. SPS for H.264. */ 702 #define VA_ENC_PACKED_HEADER_SEQUENCE 0x00000001 703 /** \brief Driver supports packed picture headers. e.g. PPS for H.264. */ 704 #define VA_ENC_PACKED_HEADER_PICTURE 0x00000002 705 /** \brief Driver supports packed slice headers. e.g. \c slice_header() for H.264. */ 706 #define VA_ENC_PACKED_HEADER_SLICE 0x00000004 707 /** \brief Driver supports misc packed headers. e.g. SEI for H.264. */ 708 #define VA_ENC_PACKED_HEADER_MISC 0x00000008 709 /** \brief Driver supports raw packed header, see VAEncPackedHeaderRawData */ 710 #define VA_ENC_PACKED_HEADER_RAW_DATA 0x0000000C 711 /**@}*/ 712 713 /** @name Attribute values for VAConfigAttribEncInterlaced */ 714 /**@{*/ 715 /** \brief Driver does not support interlaced coding. */ 716 #define VA_ENC_INTERLACED_NONE 0x00000000 717 /** \brief Driver supports interlaced frame coding. */ 718 #define VA_ENC_INTERLACED_FRAME 0x00000001 719 /** \brief Driver supports interlaced field coding. */ 720 #define VA_ENC_INTERLACED_FIELD 0x00000002 721 /** \brief Driver supports macroblock adaptive frame field coding. */ 722 #define VA_ENC_INTERLACED_MBAFF 0x00000004 723 /** \brief Driver supports picture adaptive frame field coding. */ 724 #define VA_ENC_INTERLACED_PAFF 0x00000008 725 /**@}*/ 726 727 /** @name Attribute values for VAConfigAttribEncSliceStructure */ 728 /**@{*/ 729 /** \brief Driver supports an arbitrary number of rows per slice. */ 730 #define VA_ENC_SLICE_STRUCTURE_ARBITRARY_ROWS 0x00000000 731 /** \brief Driver supports a power-of-two number of rows per slice. */ 732 #define VA_ENC_SLICE_STRUCTURE_POWER_OF_TWO_ROWS 0x00000001 733 /** \brief Driver supports an arbitrary number of rows per slice. */ 734 #define VA_ENC_SLICE_STRUCTURE_ARBITRARY_MACROBLOCKS 0x00000002 735 /** \brief Driver supports any number of rows per slice but they must be the same 736 for all slices except for the last one, which must be equal or smaller 737 to the previous slices. */ 738 #define VA_ENC_SLICE_STRUCTURE_EQUAL_ROWS 0x00000004 739 /** \brief Driver supports a maximum slice size requested by the app. 740 The size is sent in VAEncMiscParameterMaxSliceSize. */ 741 #define VA_ENC_SLICE_STRUCTURE_MAX_SLICE_SIZE 0x00000008 742 /**@}*/ 743 744 /** \brief Attribute value for VAConfigAttribEncJPEG */ 745 typedef union _VAConfigAttribValEncJPEG { 746 struct { 747 /** \brief set to 1 for arithmatic coding. */ 748 unsigned int arithmatic_coding_mode : 1; 749 /** \brief set to 1 for progressive dct. */ 750 unsigned int progressive_dct_mode : 1; 751 /** \brief set to 1 for non-interleaved. */ 752 unsigned int non_interleaved_mode : 1; 753 /** \brief set to 1 for differential. */ 754 unsigned int differential_mode : 1; 755 unsigned int max_num_components : 3; 756 unsigned int max_num_scans : 4; 757 unsigned int max_num_huffman_tables : 3; 758 unsigned int max_num_quantization_tables : 3; 759 } bits; 760 unsigned int value; 761 } VAConfigAttribValEncJPEG; 762 763 /** @name Attribute values for VAConfigAttribEncQuantization */ 764 /**@{*/ 765 /** \brief Driver does not support special types of quantization */ 766 #define VA_ENC_QUANTIZATION_NONE 0x00000000 767 /** \brief Driver supports trellis quantization */ 768 #define VA_ENC_QUANTIZATION_TRELLIS_SUPPORTED 0x00000001 769 /**@}*/ 770 771 /** @name Attribute values for VAConfigAttribEncIntraRefresh */ 772 /**@{*/ 773 /** \brief Driver does not support intra refresh */ 774 #define VA_ENC_INTRA_REFRESH_NONE 0x00000000 775 /** \brief Driver supports column based rolling intra refresh */ 776 #define VA_ENC_INTRA_REFRESH_ROLLING_COLUMN 0x00000001 777 /** \brief Driver supports row based rolling intra refresh */ 778 #define VA_ENC_INTRA_REFRESH_ROLLING_ROW 0x00000002 779 /** \brief Driver supports adaptive intra refresh */ 780 #define VA_ENC_INTRA_REFRESH_ADAPTIVE 0x00000010 781 /** \brief Driver supports cyclic intra refresh */ 782 #define VA_ENC_INTRA_REFRESH_CYCLIC 0x00000020 783 784 /**@}*/ 785 786 /** \brief Attribute value for VAConfigAttribEncRateControlExt */ 787 typedef union _VAConfigAttribValEncRateControlExt { 788 struct { 789 /** \brief The number of temporal layers with layer specific bit-rate targets 790 * that are supported. The application will send multiple 791 * VAEncMiscParameterRateControl and VAEncMiscParameterFrameRate structures 792 * for each layer, using the temporal_id field as the layer identifier. 793 * If per temporal layer rate control is not supported, 794 * num_temporal_layers_minus1 will be 0 and the temporal_id field in 795 * VAEncMiscParameterRateControl and VAEncMiscParameterFrameRate will be ignored. 796 */ 797 unsigned int num_temporal_layers_minus1 : 8; 798 unsigned int reserved : 24; 799 } bits; 800 unsigned int value; 801 } VAConfigAttribValEncRateControlExt; 802 803 /** 804 * \brief Intel specific attribute definitions 805 */ 806 /** @name Attribute values for VAConfigAttribEncFunctionTypeIntel 807 * 808 * The desired type should be passed to driver when creating the configuration. 809 * If VA_ENC_FUNCTION_ENC_PAK is set, VA_ENC_FUNCTION_ENC and VA_ENC_FUNCTION_PAK 810 * will be ignored if set also. VA_ENC_FUNCTION_ENC and VA_ENC_FUNCTION_PAK operations 811 * shall be called separately if ENC and PAK (VA_ENC_FUNCTION_ENC | VA_ENC_FUNCTION_PAK) 812 * is set for configuration. VA_ENC_FUNCTION_ENC_PAK is recommended for best performance. 813 * If only VA_ENC_FUNCTION_ENC is set, there will be no bitstream output. 814 * If VA_ENC_FUNCTION_ENC_PAK is not set and VA_ENC_FUNCTION_PAK is set, then two extra 815 * input buffers for PAK are needed: VAEncFEIMVBufferType and VAEncFEIModeBufferType. 816 **/ 817 /**@{*/ 818 /** \brief Only default is supported */ 819 #define VA_ENC_FUNCTION_DEFAULT_INTEL 0x00000000 820 /** \brief ENC only is supported */ 821 #define VA_ENC_FUNCTION_ENC_INTEL 0x00000001 822 /** \brief PAK only is supported */ 823 #define VA_ENC_FUNCTION_PAK_INTEL 0x00000002 824 /** \brief ENC_PAK is supported */ 825 #define VA_ENC_FUNCTION_ENC_PAK_INTEL 0x00000004 826 827 /**@}*/ 828 829 /** \brief Attribute value for VAConfigAttribStatisticsIntel */ 830 typedef union _VAConfigAttribValStatisticsIntel { 831 struct { 832 /** \brief Max number of past reference frames that are supported. */ 833 unsigned int max_num_past_references : 4; 834 /** \brief Max number of future reference frames that are supported. */ 835 unsigned int max_num_future_references : 4; 836 /** \brief Number of output surfaces that are supported */ 837 unsigned int num_outputs : 3; 838 /** \brief Interlaced content is supported */ 839 unsigned int interlaced : 1; 840 unsigned int reserved : 20; 841 } bits; 842 unsigned int value; 843 } VAConfigAttribValStatisticsIntel; 844 845 /* 846 * if an attribute is not applicable for a given 847 * profile/entrypoint pair, then set the value to the following 848 */ 849 #define VA_ATTRIB_NOT_SUPPORTED 0x80000000 850 851 /* Get maximum number of profiles supported by the implementation */ 852 int vaMaxNumProfiles ( 853 VADisplay dpy 854 ); 855 856 /* Get maximum number of entrypoints supported by the implementation */ 857 int vaMaxNumEntrypoints ( 858 VADisplay dpy 859 ); 860 861 /* Get maximum number of attributs supported by the implementation */ 862 int vaMaxNumConfigAttributes ( 863 VADisplay dpy 864 ); 865 866 /* 867 * Query supported profiles 868 * The caller must provide a "profile_list" array that can hold at 869 * least vaMaxNumProfile() entries. The actual number of profiles 870 * returned in "profile_list" is returned in "num_profile". 871 */ 872 VAStatus vaQueryConfigProfiles ( 873 VADisplay dpy, 874 VAProfile *profile_list, /* out */ 875 int *num_profiles /* out */ 876 ); 877 878 /* 879 * Query supported entrypoints for a given profile 880 * The caller must provide an "entrypoint_list" array that can hold at 881 * least vaMaxNumEntrypoints() entries. The actual number of entrypoints 882 * returned in "entrypoint_list" is returned in "num_entrypoints". 883 */ 884 VAStatus vaQueryConfigEntrypoints ( 885 VADisplay dpy, 886 VAProfile profile, 887 VAEntrypoint *entrypoint_list, /* out */ 888 int *num_entrypoints /* out */ 889 ); 890 891 /* 892 * Get attributes for a given profile/entrypoint pair 893 * The caller must provide an "attrib_list" with all attributes to be 894 * retrieved. Upon return, the attributes in "attrib_list" have been 895 * updated with their value. Unknown attributes or attributes that are 896 * not supported for the given profile/entrypoint pair will have their 897 * value set to VA_ATTRIB_NOT_SUPPORTED 898 */ 899 VAStatus vaGetConfigAttributes ( 900 VADisplay dpy, 901 VAProfile profile, 902 VAEntrypoint entrypoint, 903 VAConfigAttrib *attrib_list, /* in/out */ 904 int num_attribs 905 ); 906 907 /* Generic ID type, can be re-typed for specific implementation */ 908 typedef unsigned int VAGenericID; 909 910 typedef VAGenericID VAConfigID; 911 912 /* 913 * Create a configuration for the decode pipeline 914 * it passes in the attribute list that specifies the attributes it cares 915 * about, with the rest taking default values. 916 */ 917 VAStatus vaCreateConfig ( 918 VADisplay dpy, 919 VAProfile profile, 920 VAEntrypoint entrypoint, 921 VAConfigAttrib *attrib_list, 922 int num_attribs, 923 VAConfigID *config_id /* out */ 924 ); 925 926 /* 927 * Free resources associdated with a given config 928 */ 929 VAStatus vaDestroyConfig ( 930 VADisplay dpy, 931 VAConfigID config_id 932 ); 933 934 /* 935 * Query all attributes for a given configuration 936 * The profile of the configuration is returned in "profile" 937 * The entrypoint of the configuration is returned in "entrypoint" 938 * The caller must provide an "attrib_list" array that can hold at least 939 * vaMaxNumConfigAttributes() entries. The actual number of attributes 940 * returned in "attrib_list" is returned in "num_attribs" 941 */ 942 VAStatus vaQueryConfigAttributes ( 943 VADisplay dpy, 944 VAConfigID config_id, 945 VAProfile *profile, /* out */ 946 VAEntrypoint *entrypoint, /* out */ 947 VAConfigAttrib *attrib_list,/* out */ 948 int *num_attribs /* out */ 949 ); 950 951 952 /* 953 * Contexts and Surfaces 954 * 955 * Context represents a "virtual" video decode pipeline. Surfaces are render 956 * targets for a given context. The data in the surfaces are not accessible 957 * to the client and the internal data format of the surface is implementatin 958 * specific. 959 * 960 * Surfaces will be bound to a context when the context is created. Once 961 * a surface is bound to a given context, it can not be used to create 962 * another context. The association is removed when the context is destroyed 963 * 964 * Both contexts and surfaces are identified by unique IDs and its 965 * implementation specific internals are kept opaque to the clients 966 */ 967 968 typedef VAGenericID VAContextID; 969 970 typedef VAGenericID VASurfaceID; 971 972 #define VA_INVALID_ID 0xffffffff 973 #define VA_INVALID_SURFACE VA_INVALID_ID 974 975 /** \brief Generic value types. */ 976 typedef enum { 977 VAGenericValueTypeInteger = 1, /**< 32-bit signed integer. */ 978 VAGenericValueTypeFloat, /**< 32-bit floating-point value. */ 979 VAGenericValueTypePointer, /**< Generic pointer type */ 980 VAGenericValueTypeFunc /**< Pointer to function */ 981 } VAGenericValueType; 982 983 /** \brief Generic function type. */ 984 typedef void (*VAGenericFunc)(void); 985 986 /** \brief Generic value. */ 987 typedef struct _VAGenericValue { 988 /** \brief Value type. See #VAGenericValueType. */ 989 VAGenericValueType type; 990 /** \brief Value holder. */ 991 union { 992 /** \brief 32-bit signed integer. */ 993 int i; 994 /** \brief 32-bit float. */ 995 float f; 996 /** \brief Generic pointer. */ 997 void *p; 998 /** \brief Pointer to function. */ 999 VAGenericFunc fn; 1000 } value; 1001 } VAGenericValue; 1002 1003 /** @name Surface attribute flags */ 1004 /**@{*/ 1005 /** \brief Surface attribute is not supported. */ 1006 #define VA_SURFACE_ATTRIB_NOT_SUPPORTED 0x00000000 1007 /** \brief Surface attribute can be got through vaQuerySurfaceAttributes(). */ 1008 #define VA_SURFACE_ATTRIB_GETTABLE 0x00000001 1009 /** \brief Surface attribute can be set through vaCreateSurfaces(). */ 1010 #define VA_SURFACE_ATTRIB_SETTABLE 0x00000002 1011 /**@}*/ 1012 1013 /** \brief Surface attribute types. */ 1014 typedef enum { 1015 VASurfaceAttribNone = 0, 1016 /** 1017 * \brief Pixel format (fourcc). 1018 * 1019 * The value is meaningful as input to vaQuerySurfaceAttributes(). 1020 * If zero, the driver returns the optimal pixel format for the 1021 * specified config. Otherwise, if non-zero, the value represents 1022 * a pixel format (FOURCC) that is kept as is on output, if the 1023 * driver supports it. Otherwise, the driver sets the value to 1024 * zero and drops the \c VA_SURFACE_ATTRIB_SETTABLE flag. 1025 */ 1026 VASurfaceAttribPixelFormat, 1027 /** \brief Minimal width in pixels (int, read-only). */ 1028 VASurfaceAttribMinWidth, 1029 /** \brief Maximal width in pixels (int, read-only). */ 1030 VASurfaceAttribMaxWidth, 1031 /** \brief Minimal height in pixels (int, read-only). */ 1032 VASurfaceAttribMinHeight, 1033 /** \brief Maximal height in pixels (int, read-only). */ 1034 VASurfaceAttribMaxHeight, 1035 /** \brief Surface memory type expressed in bit fields (int, read/write). */ 1036 VASurfaceAttribMemoryType, 1037 /** \brief External buffer descriptor (pointer, write). */ 1038 VASurfaceAttribExternalBufferDescriptor, 1039 /** \brief Surface usage hint, gives the driver a hint of intended usage 1040 * to optimize allocation (e.g. tiling) (int, read/write). */ 1041 VASurfaceAttribUsageHint, 1042 /** \brief Number of surface attributes. */ 1043 VASurfaceAttribCount 1044 } VASurfaceAttribType; 1045 1046 /** \brief Surface attribute. */ 1047 typedef struct _VASurfaceAttrib { 1048 /** \brief Type. */ 1049 VASurfaceAttribType type; 1050 /** \brief Flags. See "Surface attribute flags". */ 1051 unsigned int flags; 1052 /** \brief Value. See "Surface attribute types" for the expected types. */ 1053 VAGenericValue value; 1054 } VASurfaceAttrib; 1055 1056 /** 1057 * @name VASurfaceAttribMemoryType values in bit fields. 1058 * Bit 0:7 are reserved for generic types, Bit 31:28 are reserved for 1059 * Linux DRM, Bit 23:20 are reserved for Android. DRM and Android specific 1060 * types are defined in DRM and Android header files. 1061 */ 1062 /**@{*/ 1063 /** \brief VA memory type (default) is supported. */ 1064 #define VA_SURFACE_ATTRIB_MEM_TYPE_VA 0x00000001 1065 /** \brief V4L2 buffer memory type is supported. */ 1066 #define VA_SURFACE_ATTRIB_MEM_TYPE_V4L2 0x00000002 1067 /** \brief User pointer memory type is supported. */ 1068 #define VA_SURFACE_ATTRIB_MEM_TYPE_USER_PTR 0x00000004 1069 /**@}*/ 1070 1071 /** 1072 * \brief VASurfaceAttribExternalBuffers structure for 1073 * the VASurfaceAttribExternalBufferDescriptor attribute. 1074 */ 1075 typedef struct _VASurfaceAttribExternalBuffers { 1076 /** \brief pixel format in fourcc. */ 1077 unsigned int pixel_format; 1078 /** \brief width in pixels. */ 1079 unsigned int width; 1080 /** \brief height in pixels. */ 1081 unsigned int height; 1082 /** \brief total size of the buffer in bytes. */ 1083 unsigned int data_size; 1084 /** \brief number of planes for planar layout */ 1085 unsigned int num_planes; 1086 /** \brief pitch for each plane in bytes */ 1087 unsigned int pitches[4]; 1088 /** \brief offset for each plane in bytes */ 1089 unsigned int offsets[4]; 1090 /** \brief buffer handles or user pointers */ 1091 unsigned long *buffers; 1092 /** \brief number of elements in the "buffers" array */ 1093 unsigned int num_buffers; 1094 /** \brief flags. See "Surface external buffer descriptor flags". */ 1095 unsigned int flags; 1096 /** \brief reserved for passing private data */ 1097 void *private_data; 1098 } VASurfaceAttribExternalBuffers; 1099 1100 /** @name VASurfaceAttribExternalBuffers flags */ 1101 /**@{*/ 1102 /** \brief Enable memory tiling */ 1103 #define VA_SURFACE_EXTBUF_DESC_ENABLE_TILING 0x00000001 1104 /** \brief Memory is cacheable */ 1105 #define VA_SURFACE_EXTBUF_DESC_CACHED 0x00000002 1106 /** \brief Memory is non-cacheable */ 1107 #define VA_SURFACE_EXTBUF_DESC_UNCACHED 0x00000004 1108 /** \brief Memory is write-combined */ 1109 #define VA_SURFACE_EXTBUF_DESC_WC 0x00000008 1110 /** \brief Memory is protected */ 1111 #define VA_SURFACE_EXTBUF_DESC_PROTECTED 0x80000000 1112 1113 /** @name VASurfaceAttribUsageHint attribute usage hint flags */ 1114 /**@{*/ 1115 /** \brief Surface usage not indicated. */ 1116 #define VA_SURFACE_ATTRIB_USAGE_HINT_GENERIC 0x00000000 1117 /** \brief Surface used by video decoder. */ 1118 #define VA_SURFACE_ATTRIB_USAGE_HINT_DECODER 0x00000001 1119 /** \brief Surface used by video encoder. */ 1120 #define VA_SURFACE_ATTRIB_USAGE_HINT_ENCODER 0x00000002 1121 /** \brief Surface read by video post-processing. */ 1122 #define VA_SURFACE_ATTRIB_USAGE_HINT_VPP_READ 0x00000004 1123 /** \brief Surface written by video post-processing. */ 1124 #define VA_SURFACE_ATTRIB_USAGE_HINT_VPP_WRITE 0x00000008 1125 /** \brief Surface used for display. */ 1126 #define VA_SURFACE_ATTRIB_USAGE_HINT_DISPLAY 0x00000010 1127 1128 /**@}*/ 1129 1130 /** 1131 * \brief Queries surface attributes for the supplied config. 1132 * 1133 * Unlike vaGetSurfaceAttributes(), this function queries for all 1134 * supported attributes for the supplied VA @config. In particular, if 1135 * the underlying hardware supports the creation of VA surfaces in 1136 * various formats, then this function will enumerate all pixel 1137 * formats that are supported. 1138 * 1139 * The \c attrib_list array is allocated by the user and \c 1140 * num_attribs shall be initialized to the number of allocated 1141 * elements in that array. Upon successful return, the actual number 1142 * of attributes will be overwritten into \c num_attribs. Otherwise, 1143 * \c VA_STATUS_ERROR_MAX_NUM_EXCEEDED is returned and \c num_attribs 1144 * is adjusted to the number of elements that would be returned if 1145 * enough space was available. 1146 * 1147 * Note: it is perfectly valid to pass NULL to the \c attrib_list 1148 * argument when vaQuerySurfaceAttributes() is used to determine the 1149 * actual number of elements that need to be allocated. 1150 * 1151 * @param[in] dpy the VA display 1152 * @param[in] config the config identifying a codec or a video 1153 * processing pipeline 1154 * @param[out] attrib_list the output array of #VASurfaceAttrib elements 1155 * @param[in,out] num_attribs the number of elements allocated on 1156 * input, the number of elements actually filled in output 1157 */ 1158 VAStatus 1159 vaQuerySurfaceAttributes( 1160 VADisplay dpy, 1161 VAConfigID config, 1162 VASurfaceAttrib *attrib_list, 1163 unsigned int *num_attribs 1164 ); 1165 1166 /** 1167 * \brief Creates an array of surfaces 1168 * 1169 * Creates an array of surfaces. The optional list of attributes shall 1170 * be constructed and validated through vaGetSurfaceAttributes() or 1171 * constructed based based on what the underlying hardware could 1172 * expose through vaQuerySurfaceAttributes(). 1173 * 1174 * @param[in] dpy the VA display 1175 * @param[in] format the desired surface format. See \c VA_RT_FORMAT_* 1176 * @param[in] width the surface width 1177 * @param[in] height the surface height 1178 * @param[out] surfaces the array of newly created surfaces 1179 * @param[in] num_surfaces the number of surfaces to create 1180 * @param[in] attrib_list the list of (optional) attributes, or \c NULL 1181 * @param[in] num_attribs the number of attributes supplied in 1182 * \c attrib_list, or zero 1183 */ 1184 VAStatus 1185 vaCreateSurfaces( 1186 VADisplay dpy, 1187 unsigned int format, 1188 unsigned int width, 1189 unsigned int height, 1190 VASurfaceID *surfaces, 1191 unsigned int num_surfaces, 1192 VASurfaceAttrib *attrib_list, 1193 unsigned int num_attribs 1194 ); 1195 1196 /* 1197 * vaDestroySurfaces - Destroy resources associated with surfaces. 1198 * Surfaces can only be destroyed after the context associated has been 1199 * destroyed. 1200 * dpy: display 1201 * surfaces: array of surfaces to destroy 1202 * num_surfaces: number of surfaces in the array to be destroyed. 1203 */ 1204 VAStatus vaDestroySurfaces ( 1205 VADisplay dpy, 1206 VASurfaceID *surfaces, 1207 int num_surfaces 1208 ); 1209 1210 #define VA_PROGRESSIVE 0x1 1211 /* 1212 * vaCreateContext - Create a context 1213 * dpy: display 1214 * config_id: configuration for the context 1215 * picture_width: coded picture width 1216 * picture_height: coded picture height 1217 * flag: any combination of the following: 1218 * VA_PROGRESSIVE (only progressive frame pictures in the sequence when set) 1219 * render_targets: render targets (surfaces) tied to the context 1220 * num_render_targets: number of render targets in the above array 1221 * context: created context id upon return 1222 */ 1223 VAStatus vaCreateContext ( 1224 VADisplay dpy, 1225 VAConfigID config_id, 1226 int picture_width, 1227 int picture_height, 1228 int flag, 1229 VASurfaceID *render_targets, 1230 int num_render_targets, 1231 VAContextID *context /* out */ 1232 ); 1233 1234 /* 1235 * vaDestroyContext - Destroy a context 1236 * dpy: display 1237 * context: context to be destroyed 1238 */ 1239 VAStatus vaDestroyContext ( 1240 VADisplay dpy, 1241 VAContextID context 1242 ); 1243 1244 /* 1245 * Buffers 1246 * Buffers are used to pass various types of data from the 1247 * client to the server. The server maintains a data store 1248 * for each buffer created, and the client idenfies a buffer 1249 * through a unique buffer id assigned by the server. 1250 */ 1251 1252 typedef VAGenericID VABufferID; 1253 1254 typedef enum 1255 { 1256 VAPictureParameterBufferType = 0, 1257 VAIQMatrixBufferType = 1, 1258 VABitPlaneBufferType = 2, 1259 VASliceGroupMapBufferType = 3, 1260 VASliceParameterBufferType = 4, 1261 VASliceDataBufferType = 5, 1262 VAMacroblockParameterBufferType = 6, 1263 VAResidualDataBufferType = 7, 1264 VADeblockingParameterBufferType = 8, 1265 VAImageBufferType = 9, 1266 VAProtectedSliceDataBufferType = 10, 1267 VAQMatrixBufferType = 11, 1268 VAHuffmanTableBufferType = 12, 1269 VAProbabilityBufferType = 13, 1270 /* Following are encode buffer types */ 1271 VAEncCodedBufferType = 21, 1272 VAEncSequenceParameterBufferType = 22, 1273 VAEncPictureParameterBufferType = 23, 1274 VAEncSliceParameterBufferType = 24, 1275 VAEncPackedHeaderParameterBufferType = 25, 1276 VAEncPackedHeaderDataBufferType = 26, 1277 VAEncMiscParameterBufferType = 27, 1278 VAEncMacroblockParameterBufferType = 28, 1279 VAEncMacroblockMapBufferType = 29, 1280 VAEncQpBufferType = 30, 1281 /* Following are video processing buffer types */ 1282 /** 1283 * \brief Video processing pipeline parameter buffer. 1284 * 1285 * This buffer describes the video processing pipeline. See 1286 * #VAProcPipelineParameterBuffer for details. 1287 */ 1288 VAProcPipelineParameterBufferType = 41, 1289 /** 1290 * \brief Video filter parameter buffer. 1291 * 1292 * This buffer describes the video filter parameters. All buffers 1293 * inherit from #VAProcFilterParameterBufferBase, thus including 1294 * a unique filter buffer type. 1295 * 1296 * The default buffer used by most filters is #VAProcFilterParameterBuffer. 1297 * Filters requiring advanced parameters include, but are not limited to, 1298 * deinterlacing (#VAProcFilterParameterBufferDeinterlacing), 1299 * color balance (#VAProcFilterParameterBufferColorBalance), etc. 1300 */ 1301 VAProcFilterParameterBufferType = 42, 1302 VAParsePictureParameterBufferType = 43, 1303 VAParseSliceHeaderGroupBufferType = 44, 1304 1305 /** 1306 * \brief Intel specific buffer types start at 1001 1307 */ 1308 VAEncFEIMVBufferTypeIntel = 1001, 1309 VAEncFEIModeBufferTypeIntel, 1310 VAEncFEIDistortionBufferTypeIntel, 1311 VAStatsStatisticsParameterBufferTypeIntel, 1312 VAStatsStatisticsBufferTypeIntel, 1313 VAStatsMotionVectorBufferTypeIntel, 1314 1315 VABufferTypeMax 1316 } VABufferType; 1317 1318 typedef enum 1319 { 1320 VAEncMiscParameterTypeFrameRate = 0, 1321 VAEncMiscParameterTypeRateControl = 1, 1322 VAEncMiscParameterTypeMaxSliceSize = 2, 1323 /** \brief Buffer type used for Adaptive intra refresh */ 1324 VAEncMiscParameterTypeAIR = 3, 1325 /** \brief Buffer type used to express a maximum frame size (in bits). */ 1326 VAEncMiscParameterTypeMaxFrameSize = 4, 1327 /** \brief Buffer type used for HRD parameters. */ 1328 VAEncMiscParameterTypeHRD = 5, 1329 VAEncMiscParameterTypeQualityLevel = 6, 1330 /** \brief Buffer type used for Rolling intra refresh */ 1331 VAEncMiscParameterTypeRIR = 7, 1332 VAEncMiscParameterTypeQuantization = 8, 1333 /** \brief Buffer type used for sending skip frame parameters to the encoder's 1334 * rate control, when the user has externally skipped frames. */ 1335 VAEncMiscParameterTypeSkipFrame = 9, 1336 /** \brief Buffer type used for region-of-interest (ROI) parameters. */ 1337 VAEncMiscParameterTypeROI = 10, 1338 /** \brief Buffer type used for Cyclic intra refresh */ 1339 VAEncMiscParameterTypeCIR = 11, 1340 /** \brief Buffer type used for temporal layer structure */ 1341 VAEncMiscParameterTypeTemporalLayerStructure = 12, 1342 1343 /* Intel specific types start at 1001 */ 1344 /* VAEntrypointEncFEIIntel */ 1345 VAEncMiscParameterTypeFEIFrameControlIntel = 1001 1346 } VAEncMiscParameterType; 1347 1348 /** \brief Packed header type. */ 1349 typedef enum { 1350 /** \brief Packed sequence header. */ 1351 VAEncPackedHeaderSequence = 1, 1352 /** \brief Packed picture header. */ 1353 VAEncPackedHeaderPicture = 2, 1354 /** \brief Packed slice header. */ 1355 VAEncPackedHeaderSlice = 3, 1356 /** 1357 * \brief Packed raw header. 1358 * 1359 * Packed raw data header can be used by the client to insert a header 1360 * into the bitstream data buffer at the point it is passed, the driver 1361 * will handle the raw packed header based on "has_emulation_bytes" field 1362 * in the packed header parameter structure. 1363 */ 1364 VAEncPackedHeaderRawData = 4, 1365 /** \brief Misc packed header. See codec-specific definitions. */ 1366 VAEncPackedHeaderMiscMask = 0x80000000, 1367 } VAEncPackedHeaderType; 1368 1369 /** \brief Packed header parameter. */ 1370 typedef struct _VAEncPackedHeaderParameterBuffer { 1371 /** Type of the packed header buffer. See #VAEncPackedHeaderType. */ 1372 unsigned int type; 1373 /** \brief Size of the #VAEncPackedHeaderDataBuffer in bits. */ 1374 unsigned int bit_length; 1375 /** \brief Flag: buffer contains start code emulation prevention bytes? */ 1376 unsigned char has_emulation_bytes; 1377 } VAEncPackedHeaderParameterBuffer; 1378 1379 /* 1380 * For application, e.g. set a new bitrate 1381 * VABufferID buf_id; 1382 * VAEncMiscParameterBuffer *misc_param; 1383 * VAEncMiscParameterRateControl *misc_rate_ctrl; 1384 * 1385 * vaCreateBuffer(dpy, context, VAEncMiscParameterBufferType, 1386 * sizeof(VAEncMiscParameterBuffer) + sizeof(VAEncMiscParameterRateControl), 1387 * 1, NULL, &buf_id); 1388 * 1389 * vaMapBuffer(dpy,buf_id,(void **)&misc_param); 1390 * misc_param->type = VAEncMiscParameterTypeRateControl; 1391 * misc_rate_ctrl= (VAEncMiscParameterRateControl *)misc_param->data; 1392 * misc_rate_ctrl->bits_per_second = 6400000; 1393 * vaUnmapBuffer(dpy, buf_id); 1394 * vaRenderPicture(dpy, context, &buf_id, 1); 1395 */ 1396 typedef struct _VAEncMiscParameterBuffer 1397 { 1398 VAEncMiscParameterType type; 1399 unsigned int data[0]; 1400 } VAEncMiscParameterBuffer; 1401 1402 /** \brief Temporal Structure*/ 1403 typedef struct _VAEncMiscParameterTemporalLayerStructure 1404 { 1405 /* The number of temporal layers */ 1406 uint32_t number_of_layers; 1407 /* this is Length of the sequence defining frame layer membership. Should be 1-32 */ 1408 uint32_t periodicity; 1409 /*This is Array indicating the layer id for each frame in a sequence of length ts_periodicity.*/ 1410 uint32_t layer_id[32]; 1411 } VAEncMiscParameterTemporalLayerStructure; 1412 1413 1414 /** \brief Rate control parameters */ 1415 typedef struct _VAEncMiscParameterRateControl 1416 { 1417 /* this is the maximum bit-rate to be constrained by the rate control implementation */ 1418 unsigned int bits_per_second; 1419 /* this is the bit-rate the rate control is targeting, as a percentage of the maximum 1420 * bit-rate for example if target_percentage is 95 then the rate control will target 1421 * a bit-rate that is 95% of the maximum bit-rate 1422 */ 1423 unsigned int target_percentage; 1424 /* windows size in milliseconds. For example if this is set to 500, 1425 * then the rate control will guarantee the target bit-rate over a 500 ms window 1426 */ 1427 unsigned int window_size; 1428 /* initial_qp: initial QP for the first I frames 1429 * min_qp/max_qp: minimal and maximum QP frames 1430 * If set them to 0, encoder chooses the best QP according to rate control 1431 */ 1432 unsigned int initial_qp; 1433 unsigned int min_qp; 1434 unsigned int max_qp; 1435 unsigned int basic_unit_size; 1436 union 1437 { 1438 struct 1439 { 1440 unsigned int reset : 1; 1441 unsigned int disable_frame_skip : 1; /* Disable frame skip in rate control mode */ 1442 unsigned int disable_bit_stuffing : 1; /* Disable bit stuffing in rate control mode */ 1443 unsigned int mb_rate_control : 4; /* Control VA_RC_MB 0: default, 1: enable, 2: disable, other: reserved*/ 1444 /* 1445 * The temporal layer that the rate control parameters are specified for. 1446 */ 1447 unsigned int temporal_id : 8; 1448 unsigned int reserved : 17; 1449 } bits; 1450 unsigned int value; 1451 } rc_flags; 1452 unsigned int ICQ_quality_factor; /* Initial ICQ quality factor: 1-51. */ 1453 } VAEncMiscParameterRateControl; 1454 1455 typedef struct _VAEncMiscParameterFrameRate 1456 { 1457 unsigned int framerate; 1458 union 1459 { 1460 struct 1461 { 1462 /* 1463 * The temporal id the framerate parameters are specified for. 1464 */ 1465 unsigned int temporal_id : 8; 1466 unsigned int reserved : 24; 1467 } bits; 1468 unsigned int value; 1469 } framerate_flags; 1470 } VAEncMiscParameterFrameRate; 1471 1472 /* 1473 * Allow a maximum slice size to be specified (in bits). 1474 * The encoder will attempt to make sure that individual slices do not exceed this size 1475 * Or to signal applicate if the slice size exceed this size, see "status" of VACodedBufferSegment 1476 */ 1477 typedef struct _VAEncMiscParameterMaxSliceSize 1478 { 1479 unsigned int max_slice_size; 1480 } VAEncMiscParameterMaxSliceSize; 1481 1482 /* 1483 * \brief Cyclic intra refresh data structure for encoding. 1484 */ 1485 typedef struct _VAEncMiscParameterCIR 1486 { 1487 /** \brief the number of consecutive macroblocks to be coded as intra */ 1488 unsigned int cir_num_mbs; 1489 } VAEncMiscParameterCIR; 1490 1491 /* 1492 * \brief Adaptive intra refresh data structure for encoding. 1493 */ 1494 typedef struct _VAEncMiscParameterAIR 1495 { 1496 /** \brief the minimum number of macroblocks to refresh in a frame */ 1497 unsigned int air_num_mbs; 1498 /** 1499 * \brief threshhold of blockmatching criterion (typically SAD) 1500 * 1501 * Macroblocks above that threshold are marked as candidates and 1502 * on subsequent frames a number of these candidates are coded as Intra 1503 * Generally the threshhold need to be set and tuned to an appropriate level 1504 * according to the feedback of coded frame. 1505 */ 1506 unsigned int air_threshold; 1507 /** \brief if set to 1 then hardware auto-tune the AIR threshold */ 1508 unsigned int air_auto; 1509 } VAEncMiscParameterAIR; 1510 1511 /* 1512 * \brief Rolling intra refresh data structure for encoding. 1513 */ 1514 typedef struct _VAEncMiscParameterRIR 1515 { 1516 union 1517 { 1518 struct 1519 /** 1520 * \brief Indicate if intra refresh is enabled in column/row. 1521 * 1522 * App should query VAConfigAttribEncIntraRefresh to confirm RIR support 1523 * by the driver before sending this structure. The following RIR restrictions 1524 * apply: 1525 * - No field encoding. 1526 * - No B frames. 1527 * - No multiple references. 1528 */ 1529 { 1530 /* \brief enable RIR in column */ 1531 unsigned int enable_rir_column : 1; 1532 /* \brief enable RIR in row */ 1533 unsigned int enable_rir_row : 1; 1534 unsigned int reserved : 30; 1535 } bits; 1536 unsigned int value; 1537 } rir_flags; 1538 /** 1539 * \brief Indicates the column or row location in MB. It is ignored if 1540 * rir_flags is 0. 1541 */ 1542 unsigned short intra_insertion_location; 1543 /** 1544 * \brief Indicates the number of columns or rows in MB. It is ignored if 1545 * rir_flags is 0. 1546 */ 1547 unsigned short intra_insert_size; 1548 /** 1549 * \brief indicates the Qp difference for inserted intra columns or rows. 1550 * App can use this to adjust intra Qp based on bitrate & max frame size. 1551 */ 1552 char qp_delta_for_inserted_intra; 1553 1554 } VAEncMiscParameterRIR; 1555 1556 typedef struct _VAEncMiscParameterHRD 1557 { 1558 /** 1559 * \brief This value indicates the amount of data that will 1560 * be buffered by the decoding application prior to beginning playback 1561 */ 1562 unsigned int initial_buffer_fullness; /* in bits */ 1563 /** 1564 * \brief This value indicates the amount of data that the 1565 * encoder should try to maintain in the decoder's buffer 1566 */ 1567 unsigned int optimal_buffer_fullness; /* in bits */ 1568 /** 1569 * \brief This value indicates the amount of data that 1570 * may be buffered by the decoding application 1571 */ 1572 unsigned int buffer_size; /* in bits */ 1573 } VAEncMiscParameterHRD; 1574 1575 /** 1576 * \brief Defines a maximum frame size (in bits). 1577 * 1578 * This misc parameter buffer defines the maximum size of a frame (in 1579 * bits). The encoder will try to make sure that each frame does not 1580 * exceed this size. Otherwise, if the frame size exceeds this size, 1581 * the \c status flag of #VACodedBufferSegment will contain 1582 * #VA_CODED_BUF_STATUS_FRAME_SIZE_OVERFLOW. 1583 */ 1584 typedef struct _VAEncMiscParameterBufferMaxFrameSize { 1585 /** \brief Type. Shall be set to #VAEncMiscParameterTypeMaxFrameSize. */ 1586 VAEncMiscParameterType type; 1587 /** \brief Maximum size of a frame (in bits). */ 1588 unsigned int max_frame_size; 1589 } VAEncMiscParameterBufferMaxFrameSize; 1590 1591 /** 1592 * \brief Encoding quality level. 1593 * 1594 * The encoding quality could be set through this structure, if the implementation 1595 * supports multiple quality levels. The quality level set through this structure is 1596 * persistent over the entire coded sequence, or until a new structure is being sent. 1597 * The quality level range can be queried through the VAConfigAttribEncQualityRange 1598 * attribute. A lower value means higher quality, and a value of 1 represents the highest 1599 * quality. The quality level setting is used as a trade-off between quality and speed/power 1600 * consumption, with higher quality corresponds to lower speed and higher power consumption. 1601 */ 1602 typedef struct _VAEncMiscParameterBufferQualityLevel { 1603 /** \brief Encoding quality level setting. */ 1604 unsigned int quality_level; 1605 } VAEncMiscParameterBufferQualityLevel; 1606 1607 /** 1608 * \brief Quantization settings for encoding. 1609 * 1610 * Some encoders support special types of quantization such as trellis, and this structure 1611 * can be used by the app to control these special types of quantization by the encoder. 1612 */ 1613 typedef struct _VAEncMiscParameterQuantization 1614 { 1615 union 1616 { 1617 /* if no flags is set then quantization is determined by the driver */ 1618 struct 1619 { 1620 /* \brief disable trellis for all frames/fields */ 1621 unsigned int disable_trellis : 1; 1622 /* \brief enable trellis for I frames/fields */ 1623 unsigned int enable_trellis_I : 1; 1624 /* \brief enable trellis for P frames/fields */ 1625 unsigned int enable_trellis_P : 1; 1626 /* \brief enable trellis for B frames/fields */ 1627 unsigned int enable_trellis_B : 1; 1628 unsigned int reserved : 28; 1629 } bits; 1630 unsigned int value; 1631 } quantization_flags; 1632 } VAEncMiscParameterQuantization; 1633 1634 /** 1635 * \brief Encoding skip frame. 1636 * 1637 * The application may choose to skip frames externally to the encoder (e.g. drop completely or 1638 * code as all skip's). For rate control purposes the encoder will need to know the size and number 1639 * of skipped frames. Skip frame(s) indicated through this structure is applicable only to the 1640 * current frame. It is allowed for the application to still send in packed headers for the driver to 1641 * pack, although no frame will be encoded (e.g. for HW to encrypt the frame). 1642 */ 1643 typedef struct _VAEncMiscParameterSkipFrame { 1644 /** \brief Indicates skip frames as below. 1645 * 0: Encode as normal, no skip. 1646 * 1: One or more frames were skipped prior to the current frame, encode the current frame as normal. 1647 * 2: The current frame is to be skipped, do not encode it but pack/encrypt the packed header contents 1648 * (all except VAEncPackedHeaderSlice) which could contain actual frame contents (e.g. pack the frame 1649 * in VAEncPackedHeaderPicture). */ 1650 unsigned char skip_frame_flag; 1651 /** \brief The number of frames skipped prior to the current frame. Valid when skip_frame_flag = 1. */ 1652 unsigned char num_skip_frames; 1653 /** \brief When skip_frame_flag = 1, the size of the skipped frames in bits. When skip_frame_flag = 2, 1654 * the size of the current skipped frame that is to be packed/encrypted in bits. */ 1655 unsigned int size_skip_frames; 1656 } VAEncMiscParameterSkipFrame; 1657 1658 /** 1659 * \brief Encoding region-of-interest (ROI). 1660 * 1661 * The encoding ROI can be set through this structure, if the implementation 1662 * supports ROI input. The ROI set through this structure is applicable only to the 1663 * current frame. The number of supported ROIs can be queried through the 1664 * VAConfigAttribEncRoi. The encoder will use the ROI information to adjust the QP 1665 * values of the MB's that fall within the ROIs. 1666 */ 1667 typedef struct _VAEncMiscParameterBufferRoi { 1668 /** \brief Number of ROIs being sent.*/ 1669 unsigned int num_roi; 1670 /** \brief Valid when VAConfigAttribRateControl != VA_RC_CQP, then the encoder's 1671 * rate control will determine actual delta QPs. Specifies the max/min allowed delta QPs.*/ 1672 char max_delta_qp; 1673 char min_delta_qp; 1674 1675 /** \brief Pointer to a VAEncROI array with num_ROI elements.*/ 1676 struct VAEncROI 1677 { 1678 /** \brief Defines the ROI boundary in pixels, the driver will map it to appropriate 1679 * codec coding units. It is relative to the frame coordinates for both frame and field cases. */ 1680 VARectangle roi_rectangle; 1681 /** \brief When VAConfigAttribRateControl == VA_RC_CQP then roi_value specifes the delta QP that 1682 * will be added on top of the frame level QP. For other rate control modes, roi_value specifies the 1683 * priority of the ROI region relative to the non-ROI region. It can positive (more important) or 1684 * negative (less important) values and is compared with non-ROI region (taken as value 0). 1685 * E.g. ROI region with roi_value -3 is less important than the non-ROI region (roi_value implied to be 0) 1686 * which is less important than ROI region with roi_value +2. For overlapping regions, the roi_value 1687 * that is first in the ROI array will have priority. */ 1688 char roi_value; 1689 } *ROI; 1690 } VAEncMiscParameterBufferROI; 1691 1692 /* 1693 * There will be cases where the bitstream buffer will not have enough room to hold 1694 * the data for the entire slice, and the following flags will be used in the slice 1695 * parameter to signal to the server for the possible cases. 1696 * If a slice parameter buffer and slice data buffer pair is sent to the server with 1697 * the slice data partially in the slice data buffer (BEGIN and MIDDLE cases below), 1698 * then a slice parameter and data buffer needs to be sent again to complete this slice. 1699 */ 1700 #define VA_SLICE_DATA_FLAG_ALL 0x00 /* whole slice is in the buffer */ 1701 #define VA_SLICE_DATA_FLAG_BEGIN 0x01 /* The beginning of the slice is in the buffer but the end if not */ 1702 #define VA_SLICE_DATA_FLAG_MIDDLE 0x02 /* Neither beginning nor end of the slice is in the buffer */ 1703 #define VA_SLICE_DATA_FLAG_END 0x04 /* end of the slice is in the buffer */ 1704 1705 /* Codec-independent Slice Parameter Buffer base */ 1706 typedef struct _VASliceParameterBufferBase 1707 { 1708 unsigned int slice_data_size; /* number of bytes in the slice data buffer for this slice */ 1709 unsigned int slice_data_offset; /* the offset to the first byte of slice data */ 1710 unsigned int slice_data_flag; /* see VA_SLICE_DATA_FLAG_XXX definitions */ 1711 } VASliceParameterBufferBase; 1712 1713 #include <va/va_dec_jpeg.h> 1714 1715 /**************************** 1716 * MPEG-2 data structures 1717 ****************************/ 1718 1719 /* MPEG-2 Picture Parameter Buffer */ 1720 /* 1721 * For each frame or field, and before any slice data, a single 1722 * picture parameter buffer must be send. 1723 */ 1724 typedef struct _VAPictureParameterBufferMPEG2 1725 { 1726 unsigned short horizontal_size; 1727 unsigned short vertical_size; 1728 VASurfaceID forward_reference_picture; 1729 VASurfaceID backward_reference_picture; 1730 /* meanings of the following fields are the same as in the standard */ 1731 int picture_coding_type; 1732 int f_code; /* pack all four fcode into this */ 1733 union { 1734 struct { 1735 unsigned int intra_dc_precision : 2; 1736 unsigned int picture_structure : 2; 1737 unsigned int top_field_first : 1; 1738 unsigned int frame_pred_frame_dct : 1; 1739 unsigned int concealment_motion_vectors : 1; 1740 unsigned int q_scale_type : 1; 1741 unsigned int intra_vlc_format : 1; 1742 unsigned int alternate_scan : 1; 1743 unsigned int repeat_first_field : 1; 1744 unsigned int progressive_frame : 1; 1745 unsigned int is_first_field : 1; /* indicate whether the current field 1746 * is the first field for field picture 1747 */ 1748 } bits; 1749 unsigned int value; 1750 } picture_coding_extension; 1751 } VAPictureParameterBufferMPEG2; 1752 1753 /* MPEG-2 Inverse Quantization Matrix Buffer */ 1754 typedef struct _VAIQMatrixBufferMPEG2 1755 { 1756 int load_intra_quantiser_matrix; 1757 int load_non_intra_quantiser_matrix; 1758 int load_chroma_intra_quantiser_matrix; 1759 int load_chroma_non_intra_quantiser_matrix; 1760 unsigned char intra_quantiser_matrix[64]; 1761 unsigned char non_intra_quantiser_matrix[64]; 1762 unsigned char chroma_intra_quantiser_matrix[64]; 1763 unsigned char chroma_non_intra_quantiser_matrix[64]; 1764 } VAIQMatrixBufferMPEG2; 1765 1766 /* MPEG-2 Slice Parameter Buffer */ 1767 typedef struct _VASliceParameterBufferMPEG2 1768 { 1769 unsigned int slice_data_size;/* number of bytes in the slice data buffer for this slice */ 1770 unsigned int slice_data_offset;/* the offset to the first byte of slice data */ 1771 unsigned int slice_data_flag; /* see VA_SLICE_DATA_FLAG_XXX defintions */ 1772 unsigned int macroblock_offset;/* the offset to the first bit of MB from the first byte of slice data */ 1773 unsigned int slice_horizontal_position; 1774 unsigned int slice_vertical_position; 1775 int quantiser_scale_code; 1776 int intra_slice_flag; 1777 } VASliceParameterBufferMPEG2; 1778 1779 /* MPEG-2 Macroblock Parameter Buffer */ 1780 typedef struct _VAMacroblockParameterBufferMPEG2 1781 { 1782 unsigned short macroblock_address; 1783 /* 1784 * macroblock_address (in raster scan order) 1785 * top-left: 0 1786 * bottom-right: picture-height-in-mb*picture-width-in-mb - 1 1787 */ 1788 unsigned char macroblock_type; /* see definition below */ 1789 union { 1790 struct { 1791 unsigned int frame_motion_type : 2; 1792 unsigned int field_motion_type : 2; 1793 unsigned int dct_type : 1; 1794 } bits; 1795 unsigned int value; 1796 } macroblock_modes; 1797 unsigned char motion_vertical_field_select; 1798 /* 1799 * motion_vertical_field_select: 1800 * see section 6.3.17.2 in the spec 1801 * only the lower 4 bits are used 1802 * bit 0: first vector forward 1803 * bit 1: first vector backward 1804 * bit 2: second vector forward 1805 * bit 3: second vector backward 1806 */ 1807 short PMV[2][2][2]; /* see Table 7-7 in the spec */ 1808 unsigned short coded_block_pattern; 1809 /* 1810 * The bitplanes for coded_block_pattern are described 1811 * in Figure 6.10-12 in the spec 1812 */ 1813 1814 /* Number of skipped macroblocks after this macroblock */ 1815 unsigned short num_skipped_macroblocks; 1816 } VAMacroblockParameterBufferMPEG2; 1817 1818 /* 1819 * OR'd flags for macroblock_type (section 6.3.17.1 in the spec) 1820 */ 1821 #define VA_MB_TYPE_MOTION_FORWARD 0x02 1822 #define VA_MB_TYPE_MOTION_BACKWARD 0x04 1823 #define VA_MB_TYPE_MOTION_PATTERN 0x08 1824 #define VA_MB_TYPE_MOTION_INTRA 0x10 1825 1826 /* 1827 * MPEG-2 Residual Data Buffer 1828 * For each macroblock, there wil be 64 shorts (16-bit) in the 1829 * residual data buffer 1830 */ 1831 1832 /**************************** 1833 * MPEG-4 Part 2 data structures 1834 ****************************/ 1835 1836 /* MPEG-4 Picture Parameter Buffer */ 1837 /* 1838 * For each frame or field, and before any slice data, a single 1839 * picture parameter buffer must be send. 1840 */ 1841 typedef struct _VAPictureParameterBufferMPEG4 1842 { 1843 unsigned short vop_width; 1844 unsigned short vop_height; 1845 VASurfaceID forward_reference_picture; 1846 VASurfaceID backward_reference_picture; 1847 union { 1848 struct { 1849 unsigned int short_video_header : 1; 1850 unsigned int chroma_format : 2; 1851 unsigned int interlaced : 1; 1852 unsigned int obmc_disable : 1; 1853 unsigned int sprite_enable : 2; 1854 unsigned int sprite_warping_accuracy : 2; 1855 unsigned int quant_type : 1; 1856 unsigned int quarter_sample : 1; 1857 unsigned int data_partitioned : 1; 1858 unsigned int reversible_vlc : 1; 1859 unsigned int resync_marker_disable : 1; 1860 } bits; 1861 unsigned int value; 1862 } vol_fields; 1863 unsigned char no_of_sprite_warping_points; 1864 short sprite_trajectory_du[3]; 1865 short sprite_trajectory_dv[3]; 1866 unsigned char quant_precision; 1867 union { 1868 struct { 1869 unsigned int vop_coding_type : 2; 1870 unsigned int backward_reference_vop_coding_type : 2; 1871 unsigned int vop_rounding_type : 1; 1872 unsigned int intra_dc_vlc_thr : 3; 1873 unsigned int top_field_first : 1; 1874 unsigned int alternate_vertical_scan_flag : 1; 1875 } bits; 1876 unsigned int value; 1877 } vop_fields; 1878 unsigned char vop_fcode_forward; 1879 unsigned char vop_fcode_backward; 1880 unsigned short vop_time_increment_resolution; 1881 /* short header related */ 1882 unsigned char num_gobs_in_vop; 1883 unsigned char num_macroblocks_in_gob; 1884 /* for direct mode prediction */ 1885 short TRB; 1886 short TRD; 1887 unsigned int Tframe; 1888 unsigned char vop_quant; 1889 } VAPictureParameterBufferMPEG4; 1890 1891 /* MPEG-4 Inverse Quantization Matrix Buffer */ 1892 typedef struct _VAIQMatrixBufferMPEG4 1893 { 1894 int load_intra_quant_mat; 1895 int load_non_intra_quant_mat; 1896 unsigned char intra_quant_mat[64]; 1897 unsigned char non_intra_quant_mat[64]; 1898 } VAIQMatrixBufferMPEG4; 1899 1900 /* MPEG-4 Slice Parameter Buffer */ 1901 typedef struct _VASliceParameterBufferMPEG4 1902 { 1903 unsigned int slice_data_size;/* number of bytes in the slice data buffer for this slice */ 1904 unsigned int slice_data_offset;/* the offset to the first byte of slice data */ 1905 unsigned int slice_data_flag; /* see VA_SLICE_DATA_FLAG_XXX defintions */ 1906 unsigned int macroblock_offset;/* the offset to the first bit of MB from the first byte of slice data */ 1907 unsigned int macroblock_number; 1908 int quant_scale; 1909 } VASliceParameterBufferMPEG4; 1910 1911 /* 1912 VC-1 data structures 1913 */ 1914 1915 typedef enum /* see 7.1.1.32 */ 1916 { 1917 VAMvMode1Mv = 0, 1918 VAMvMode1MvHalfPel = 1, 1919 VAMvMode1MvHalfPelBilinear = 2, 1920 VAMvModeMixedMv = 3, 1921 VAMvModeIntensityCompensation = 4 1922 } VAMvModeVC1; 1923 1924 /* VC-1 Picture Parameter Buffer */ 1925 /* 1926 * For each picture, and before any slice data, a picture parameter 1927 * buffer must be send. Multiple picture parameter buffers may be 1928 * sent for a single picture. In that case picture parameters will 1929 * apply to all slice data that follow it until a new picture 1930 * parameter buffer is sent. 1931 * 1932 * Notes: 1933 * pic_quantizer_type should be set to the applicable quantizer 1934 * type as defined by QUANTIZER (J.1.19) and either 1935 * PQUANTIZER (7.1.1.8) or PQINDEX (7.1.1.6) 1936 */ 1937 typedef struct _VAPictureParameterBufferVC1 1938 { 1939 VASurfaceID forward_reference_picture; 1940 VASurfaceID backward_reference_picture; 1941 /* if out-of-loop post-processing is done on the render 1942 target, then we need to keep the in-loop decoded 1943 picture as a reference picture */ 1944 VASurfaceID inloop_decoded_picture; 1945 1946 /* sequence layer for AP or meta data for SP and MP */ 1947 union { 1948 struct { 1949 unsigned int pulldown : 1; /* SEQUENCE_LAYER::PULLDOWN */ 1950 unsigned int interlace : 1; /* SEQUENCE_LAYER::INTERLACE */ 1951 unsigned int tfcntrflag : 1; /* SEQUENCE_LAYER::TFCNTRFLAG */ 1952 unsigned int finterpflag : 1; /* SEQUENCE_LAYER::FINTERPFLAG */ 1953 unsigned int psf : 1; /* SEQUENCE_LAYER::PSF */ 1954 unsigned int multires : 1; /* METADATA::MULTIRES */ 1955 unsigned int overlap : 1; /* METADATA::OVERLAP */ 1956 unsigned int syncmarker : 1; /* METADATA::SYNCMARKER */ 1957 unsigned int rangered : 1; /* METADATA::RANGERED */ 1958 unsigned int max_b_frames : 3; /* METADATA::MAXBFRAMES */ 1959 unsigned int profile : 2; /* SEQUENCE_LAYER::PROFILE or The MSB of METADATA::PROFILE */ 1960 } bits; 1961 unsigned int value; 1962 } sequence_fields; 1963 1964 unsigned short coded_width; /* ENTRY_POINT_LAYER::CODED_WIDTH */ 1965 unsigned short coded_height; /* ENTRY_POINT_LAYER::CODED_HEIGHT */ 1966 union { 1967 struct { 1968 unsigned int broken_link : 1; /* ENTRY_POINT_LAYER::BROKEN_LINK */ 1969 unsigned int closed_entry : 1; /* ENTRY_POINT_LAYER::CLOSED_ENTRY */ 1970 unsigned int panscan_flag : 1; /* ENTRY_POINT_LAYER::PANSCAN_FLAG */ 1971 unsigned int loopfilter : 1; /* ENTRY_POINT_LAYER::LOOPFILTER */ 1972 } bits; 1973 unsigned int value; 1974 } entrypoint_fields; 1975 unsigned char conditional_overlap_flag; /* ENTRY_POINT_LAYER::CONDOVER */ 1976 unsigned char fast_uvmc_flag; /* ENTRY_POINT_LAYER::FASTUVMC */ 1977 union { 1978 struct { 1979 unsigned int luma_flag : 1; /* ENTRY_POINT_LAYER::RANGE_MAPY_FLAG */ 1980 unsigned int luma : 3; /* ENTRY_POINT_LAYER::RANGE_MAPY */ 1981 unsigned int chroma_flag : 1; /* ENTRY_POINT_LAYER::RANGE_MAPUV_FLAG */ 1982 unsigned int chroma : 3; /* ENTRY_POINT_LAYER::RANGE_MAPUV */ 1983 } bits; 1984 unsigned int value; 1985 } range_mapping_fields; 1986 1987 unsigned char b_picture_fraction; /* PICTURE_LAYER::BFRACTION */ 1988 unsigned char cbp_table; /* PICTURE_LAYER::CBPTAB/ICBPTAB */ 1989 unsigned char mb_mode_table; /* PICTURE_LAYER::MBMODETAB */ 1990 unsigned char range_reduction_frame;/* PICTURE_LAYER::RANGEREDFRM */ 1991 unsigned char rounding_control; /* PICTURE_LAYER::RNDCTRL */ 1992 unsigned char post_processing; /* PICTURE_LAYER::POSTPROC */ 1993 unsigned char picture_resolution_index; /* PICTURE_LAYER::RESPIC */ 1994 unsigned char luma_scale; /* PICTURE_LAYER::LUMSCALE */ 1995 unsigned char luma_shift; /* PICTURE_LAYER::LUMSHIFT */ 1996 union { 1997 struct { 1998 unsigned int picture_type : 3; /* PICTURE_LAYER::PTYPE */ 1999 unsigned int frame_coding_mode : 3; /* PICTURE_LAYER::FCM */ 2000 unsigned int top_field_first : 1; /* PICTURE_LAYER::TFF */ 2001 unsigned int is_first_field : 1; /* set to 1 if it is the first field */ 2002 unsigned int intensity_compensation : 1; /* PICTURE_LAYER::INTCOMP */ 2003 } bits; 2004 unsigned int value; 2005 } picture_fields; 2006 union { 2007 struct { 2008 unsigned int mv_type_mb : 1; /* PICTURE::MVTYPEMB */ 2009 unsigned int direct_mb : 1; /* PICTURE::DIRECTMB */ 2010 unsigned int skip_mb : 1; /* PICTURE::SKIPMB */ 2011 unsigned int field_tx : 1; /* PICTURE::FIELDTX */ 2012 unsigned int forward_mb : 1; /* PICTURE::FORWARDMB */ 2013 unsigned int ac_pred : 1; /* PICTURE::ACPRED */ 2014 unsigned int overflags : 1; /* PICTURE::OVERFLAGS */ 2015 } flags; 2016 unsigned int value; 2017 } raw_coding; 2018 union { 2019 struct { 2020 unsigned int bp_mv_type_mb : 1; /* PICTURE::MVTYPEMB */ 2021 unsigned int bp_direct_mb : 1; /* PICTURE::DIRECTMB */ 2022 unsigned int bp_skip_mb : 1; /* PICTURE::SKIPMB */ 2023 unsigned int bp_field_tx : 1; /* PICTURE::FIELDTX */ 2024 unsigned int bp_forward_mb : 1; /* PICTURE::FORWARDMB */ 2025 unsigned int bp_ac_pred : 1; /* PICTURE::ACPRED */ 2026 unsigned int bp_overflags : 1; /* PICTURE::OVERFLAGS */ 2027 } flags; 2028 unsigned int value; 2029 } bitplane_present; /* signal what bitplane is being passed via the bitplane buffer */ 2030 union { 2031 struct { 2032 unsigned int reference_distance_flag : 1;/* PICTURE_LAYER::REFDIST_FLAG */ 2033 unsigned int reference_distance : 5;/* PICTURE_LAYER::REFDIST */ 2034 unsigned int num_reference_pictures: 1;/* PICTURE_LAYER::NUMREF */ 2035 unsigned int reference_field_pic_indicator : 1;/* PICTURE_LAYER::REFFIELD */ 2036 } bits; 2037 unsigned int value; 2038 } reference_fields; 2039 union { 2040 struct { 2041 unsigned int mv_mode : 3; /* PICTURE_LAYER::MVMODE */ 2042 unsigned int mv_mode2 : 3; /* PICTURE_LAYER::MVMODE2 */ 2043 unsigned int mv_table : 3; /* PICTURE_LAYER::MVTAB/IMVTAB */ 2044 unsigned int two_mv_block_pattern_table: 2; /* PICTURE_LAYER::2MVBPTAB */ 2045 unsigned int four_mv_switch : 1; /* PICTURE_LAYER::4MVSWITCH */ 2046 unsigned int four_mv_block_pattern_table : 2; /* PICTURE_LAYER::4MVBPTAB */ 2047 unsigned int extended_mv_flag : 1; /* ENTRY_POINT_LAYER::EXTENDED_MV */ 2048 unsigned int extended_mv_range : 2; /* PICTURE_LAYER::MVRANGE */ 2049 unsigned int extended_dmv_flag : 1; /* ENTRY_POINT_LAYER::EXTENDED_DMV */ 2050 unsigned int extended_dmv_range : 2; /* PICTURE_LAYER::DMVRANGE */ 2051 } bits; 2052 unsigned int value; 2053 } mv_fields; 2054 union { 2055 struct { 2056 unsigned int dquant : 2; /* ENTRY_POINT_LAYER::DQUANT */ 2057 unsigned int quantizer : 2; /* ENTRY_POINT_LAYER::QUANTIZER */ 2058 unsigned int half_qp : 1; /* PICTURE_LAYER::HALFQP */ 2059 unsigned int pic_quantizer_scale : 5;/* PICTURE_LAYER::PQUANT */ 2060 unsigned int pic_quantizer_type : 1;/* PICTURE_LAYER::PQUANTIZER */ 2061 unsigned int dq_frame : 1; /* VOPDQUANT::DQUANTFRM */ 2062 unsigned int dq_profile : 2; /* VOPDQUANT::DQPROFILE */ 2063 unsigned int dq_sb_edge : 2; /* VOPDQUANT::DQSBEDGE */ 2064 unsigned int dq_db_edge : 2; /* VOPDQUANT::DQDBEDGE */ 2065 unsigned int dq_binary_level : 1; /* VOPDQUANT::DQBILEVEL */ 2066 unsigned int alt_pic_quantizer : 5;/* VOPDQUANT::ALTPQUANT */ 2067 } bits; 2068 unsigned int value; 2069 } pic_quantizer_fields; 2070 union { 2071 struct { 2072 unsigned int variable_sized_transform_flag : 1;/* ENTRY_POINT_LAYER::VSTRANSFORM */ 2073 unsigned int mb_level_transform_type_flag : 1;/* PICTURE_LAYER::TTMBF */ 2074 unsigned int frame_level_transform_type : 2;/* PICTURE_LAYER::TTFRM */ 2075 unsigned int transform_ac_codingset_idx1 : 2;/* PICTURE_LAYER::TRANSACFRM */ 2076 unsigned int transform_ac_codingset_idx2 : 2;/* PICTURE_LAYER::TRANSACFRM2 */ 2077 unsigned int intra_transform_dc_table : 1;/* PICTURE_LAYER::TRANSDCTAB */ 2078 } bits; 2079 unsigned int value; 2080 } transform_fields; 2081 unsigned char luma_scale2; /* PICTURE_LAYER::LUMSCALE2 */ 2082 unsigned char luma_shift2; /* PICTURE_LAYER::LUMSHIFT2 */ 2083 } VAPictureParameterBufferVC1; 2084 2085 /* VC-1 Bitplane Buffer 2086 There will be at most three bitplanes coded in any picture header. To send 2087 the bitplane data more efficiently, each byte is divided in two nibbles, with 2088 each nibble carrying three bitplanes for one macroblock. The following table 2089 shows the bitplane data arrangement within each nibble based on the picture 2090 type. 2091 2092 Picture Type Bit3 Bit2 Bit1 Bit0 2093 I or BI OVERFLAGS ACPRED FIELDTX 2094 P MYTYPEMB SKIPMB DIRECTMB 2095 B FORWARDMB SKIPMB DIRECTMB 2096 2097 Within each byte, the lower nibble is for the first MB and the upper nibble is 2098 for the second MB. E.g. the lower nibble of the first byte in the bitplane 2099 buffer is for Macroblock #1 and the upper nibble of the first byte is for 2100 Macroblock #2 in the first row. 2101 */ 2102 2103 /* VC-1 Slice Parameter Buffer */ 2104 typedef struct _VASliceParameterBufferVC1 2105 { 2106 unsigned int slice_data_size;/* number of bytes in the slice data buffer for this slice */ 2107 unsigned int slice_data_offset;/* the offset to the first byte of slice data */ 2108 unsigned int slice_data_flag; /* see VA_SLICE_DATA_FLAG_XXX defintions */ 2109 unsigned int macroblock_offset;/* the offset to the first bit of MB from the first byte of slice data */ 2110 unsigned int slice_vertical_position; 2111 } VASliceParameterBufferVC1; 2112 2113 /* VC-1 Slice Data Buffer */ 2114 /* 2115 This is simplely a buffer containing raw bit-stream bytes 2116 */ 2117 2118 /**************************** 2119 * H.264/AVC data structures 2120 ****************************/ 2121 2122 typedef struct _VAPictureH264 2123 { 2124 VASurfaceID picture_id; 2125 /* 2126 * frame_idx is long_term_frame_idx for long term reference picture, 2127 * and frame_num for short term reference picture. 2128 */ 2129 unsigned int frame_idx; 2130 /* 2131 * see flags below. 2132 */ 2133 unsigned int flags; 2134 signed int TopFieldOrderCnt; 2135 signed int BottomFieldOrderCnt; 2136 } VAPictureH264; 2137 /* flags in VAPictureH264 could be OR of the following */ 2138 #define VA_PICTURE_H264_INVALID 0x00000001 2139 #define VA_PICTURE_H264_TOP_FIELD 0x00000002 2140 #define VA_PICTURE_H264_BOTTOM_FIELD 0x00000004 2141 #define VA_PICTURE_H264_SHORT_TERM_REFERENCE 0x00000008 2142 #define VA_PICTURE_H264_LONG_TERM_REFERENCE 0x00000010 2143 #define VA_PICTURE_H264_NON_EXISTING 0x00000020 2144 2145 /* H.264 Picture Parameter Buffer */ 2146 /* 2147 * For each picture, and before any slice data, a single 2148 * picture parameter buffer must be send. 2149 */ 2150 typedef struct _VAPictureParameterBufferH264 2151 { 2152 VAPictureH264 CurrPic; 2153 VAPictureH264 ReferenceFrames[16]; /* in DPB */ 2154 unsigned short picture_width_in_mbs_minus1; 2155 unsigned short picture_height_in_mbs_minus1; 2156 unsigned char bit_depth_luma_minus8; 2157 unsigned char bit_depth_chroma_minus8; 2158 unsigned char num_ref_frames; 2159 union { 2160 struct { 2161 unsigned int chroma_format_idc : 2; 2162 unsigned int residual_colour_transform_flag : 1; 2163 unsigned int gaps_in_frame_num_value_allowed_flag : 1; 2164 unsigned int frame_mbs_only_flag : 1; 2165 unsigned int mb_adaptive_frame_field_flag : 1; 2166 unsigned int direct_8x8_inference_flag : 1; 2167 unsigned int MinLumaBiPredSize8x8 : 1; /* see A.3.3.2 */ 2168 unsigned int log2_max_frame_num_minus4 : 4; 2169 unsigned int pic_order_cnt_type : 2; 2170 unsigned int log2_max_pic_order_cnt_lsb_minus4 : 4; 2171 unsigned int delta_pic_order_always_zero_flag : 1; 2172 } bits; 2173 unsigned int value; 2174 } seq_fields; 2175 unsigned char num_slice_groups_minus1; 2176 unsigned char slice_group_map_type; 2177 unsigned short slice_group_change_rate_minus1; 2178 signed char pic_init_qp_minus26; 2179 signed char pic_init_qs_minus26; 2180 signed char chroma_qp_index_offset; 2181 signed char second_chroma_qp_index_offset; 2182 union { 2183 struct { 2184 unsigned int entropy_coding_mode_flag : 1; 2185 unsigned int weighted_pred_flag : 1; 2186 unsigned int weighted_bipred_idc : 2; 2187 unsigned int transform_8x8_mode_flag : 1; 2188 unsigned int field_pic_flag : 1; 2189 unsigned int constrained_intra_pred_flag : 1; 2190 unsigned int pic_order_present_flag : 1; 2191 unsigned int deblocking_filter_control_present_flag : 1; 2192 unsigned int redundant_pic_cnt_present_flag : 1; 2193 unsigned int reference_pic_flag : 1; /* nal_ref_idc != 0 */ 2194 } bits; 2195 unsigned int value; 2196 } pic_fields; 2197 unsigned short frame_num; 2198 unsigned char num_ref_idx_l0_default_active_minus1; 2199 unsigned char num_ref_idx_l1_default_active_minus1; 2200 } VAPictureParameterBufferH264; 2201 2202 /* H.264 Inverse Quantization Matrix Buffer */ 2203 typedef struct _VAIQMatrixBufferH264 2204 { 2205 unsigned char ScalingList4x4[6][16]; 2206 unsigned char ScalingList8x8[2][64]; 2207 } VAIQMatrixBufferH264; 2208 2209 /* 2210 * H.264 Slice Group Map Buffer 2211 * When VAPictureParameterBufferH264::num_slice_group_minus1 is not equal to 0, 2212 * A slice group map buffer should be sent for each picture if required. The buffer 2213 * is sent only when there is a change in the mapping values. 2214 * The slice group map buffer map "map units" to slice groups as specified in 2215 * section 8.2.2 of the H.264 spec. The buffer will contain one byte for each macroblock 2216 * in raster scan order 2217 */ 2218 2219 /* 2220 * H.264 Slice Parameter Buffer for base mode decoding 2221 */ 2222 typedef struct _VASliceParameterBufferBaseH264 2223 { 2224 unsigned int slice_data_size;/* number of bytes in the slice data buffer for this slice */ 2225 /** \brief Byte offset to the NAL Header Unit for this slice. */ 2226 unsigned int slice_data_offset; 2227 unsigned int slice_data_flag; /* see VA_SLICE_DATA_FLAG_XXX defintions */ 2228 } VASliceParameterBufferH264Base; 2229 2230 /* 2231 * H.264 Slice Parameter Buffer for normal mode decoding 2232 */ 2233 typedef struct _VASliceParameterBufferH264 2234 { 2235 unsigned int slice_data_size;/* number of bytes in the slice data buffer for this slice */ 2236 /** \brief Byte offset to the NAL Header Unit for this slice. */ 2237 unsigned int slice_data_offset; 2238 unsigned int slice_data_flag; /* see VA_SLICE_DATA_FLAG_XXX defintions */ 2239 /** 2240 * \brief Bit offset from NAL Header Unit to the begining of slice_data(). 2241 * 2242 * This bit offset is relative to and includes the NAL unit byte 2243 * and represents the number of bits parsed in the slice_header() 2244 * after the removal of any emulation prevention bytes in 2245 * there. However, the slice data buffer passed to the hardware is 2246 * the original bitstream, thus including any emulation prevention 2247 * bytes. 2248 */ 2249 unsigned short slice_data_bit_offset; 2250 unsigned short first_mb_in_slice; 2251 unsigned char slice_type; 2252 unsigned char direct_spatial_mv_pred_flag; 2253 unsigned char num_ref_idx_l0_active_minus1; 2254 unsigned char num_ref_idx_l1_active_minus1; 2255 unsigned char cabac_init_idc; 2256 char slice_qp_delta; 2257 unsigned char disable_deblocking_filter_idc; 2258 char slice_alpha_c0_offset_div2; 2259 char slice_beta_offset_div2; 2260 VAPictureH264 RefPicList0[32]; /* See 8.2.4.2 */ 2261 VAPictureH264 RefPicList1[32]; /* See 8.2.4.2 */ 2262 unsigned char luma_log2_weight_denom; 2263 unsigned char chroma_log2_weight_denom; 2264 unsigned char luma_weight_l0_flag; 2265 short luma_weight_l0[32]; 2266 short luma_offset_l0[32]; 2267 unsigned char chroma_weight_l0_flag; 2268 short chroma_weight_l0[32][2]; 2269 short chroma_offset_l0[32][2]; 2270 unsigned char luma_weight_l1_flag; 2271 short luma_weight_l1[32]; 2272 short luma_offset_l1[32]; 2273 unsigned char chroma_weight_l1_flag; 2274 short chroma_weight_l1[32][2]; 2275 short chroma_offset_l1[32][2]; 2276 } VASliceParameterBufferH264; 2277 2278 /**************************** 2279 * Common encode data structures 2280 ****************************/ 2281 typedef enum 2282 { 2283 VAEncPictureTypeIntra = 0, 2284 VAEncPictureTypePredictive = 1, 2285 VAEncPictureTypeBidirectional = 2, 2286 } VAEncPictureType; 2287 2288 /* Encode Slice Parameter Buffer */ 2289 typedef struct _VAEncSliceParameterBuffer 2290 { 2291 unsigned int start_row_number; /* starting MB row number for this slice */ 2292 unsigned int slice_height; /* slice height measured in MB */ 2293 union { 2294 struct { 2295 unsigned int is_intra : 1; 2296 unsigned int disable_deblocking_filter_idc : 2; 2297 unsigned int uses_long_term_ref :1; 2298 unsigned int is_long_term_ref :1; 2299 } bits; 2300 unsigned int value; 2301 } slice_flags; 2302 } VAEncSliceParameterBuffer; 2303 2304 2305 /**************************** 2306 * H.263 specific encode data structures 2307 ****************************/ 2308 2309 typedef struct _VAEncSequenceParameterBufferH263 2310 { 2311 unsigned int intra_period; 2312 unsigned int bits_per_second; 2313 unsigned int frame_rate; 2314 unsigned int initial_qp; 2315 unsigned int min_qp; 2316 } VAEncSequenceParameterBufferH263; 2317 2318 typedef struct _VAEncPictureParameterBufferH263 2319 { 2320 VASurfaceID reference_picture; 2321 VASurfaceID reconstructed_picture; 2322 VABufferID coded_buf; 2323 unsigned short picture_width; 2324 unsigned short picture_height; 2325 VAEncPictureType picture_type; 2326 } VAEncPictureParameterBufferH263; 2327 2328 /**************************** 2329 * MPEG-4 specific encode data structures 2330 ****************************/ 2331 2332 typedef struct _VAEncSequenceParameterBufferMPEG4 2333 { 2334 unsigned char profile_and_level_indication; 2335 unsigned int intra_period; 2336 unsigned int video_object_layer_width; 2337 unsigned int video_object_layer_height; 2338 unsigned int vop_time_increment_resolution; 2339 unsigned int fixed_vop_rate; 2340 unsigned int fixed_vop_time_increment; 2341 unsigned int bits_per_second; 2342 unsigned int frame_rate; 2343 unsigned int initial_qp; 2344 unsigned int min_qp; 2345 } VAEncSequenceParameterBufferMPEG4; 2346 2347 typedef struct _VAEncPictureParameterBufferMPEG4 2348 { 2349 VASurfaceID reference_picture; 2350 VASurfaceID reconstructed_picture; 2351 VABufferID coded_buf; 2352 unsigned short picture_width; 2353 unsigned short picture_height; 2354 unsigned int modulo_time_base; /* number of 1s */ 2355 unsigned int vop_time_increment; 2356 VAEncPictureType picture_type; 2357 } VAEncPictureParameterBufferMPEG4; 2358 2359 2360 2361 /* Buffer functions */ 2362 2363 /* 2364 * Creates a buffer for "num_elements" elements of "size" bytes and 2365 * initalize with "data". 2366 * if "data" is null, then the contents of the buffer data store 2367 * are undefined. 2368 * Basically there are two ways to get buffer data to the server side. One is 2369 * to call vaCreateBuffer() with a non-null "data", which results the data being 2370 * copied to the data store on the server side. A different method that 2371 * eliminates this copy is to pass null as "data" when calling vaCreateBuffer(), 2372 * and then use vaMapBuffer() to map the data store from the server side to the 2373 * client address space for access. 2374 * Note: image buffers are created by the library, not the client. Please see 2375 * vaCreateImage on how image buffers are managed. 2376 */ 2377 VAStatus vaCreateBuffer ( 2378 VADisplay dpy, 2379 VAContextID context, 2380 VABufferType type, /* in */ 2381 unsigned int size, /* in */ 2382 unsigned int num_elements, /* in */ 2383 void *data, /* in */ 2384 VABufferID *buf_id /* out */ 2385 ); 2386 2387 /* 2388 * Convey to the server how many valid elements are in the buffer. 2389 * e.g. if multiple slice parameters are being held in a single buffer, 2390 * this will communicate to the server the number of slice parameters 2391 * that are valid in the buffer. 2392 */ 2393 VAStatus vaBufferSetNumElements ( 2394 VADisplay dpy, 2395 VABufferID buf_id, /* in */ 2396 unsigned int num_elements /* in */ 2397 ); 2398 2399 2400 /* 2401 * device independent data structure for codedbuffer 2402 */ 2403 2404 /* 2405 * FICTURE_AVE_QP(bit7-0): The average Qp value used during this frame 2406 * LARGE_SLICE(bit8):At least one slice in the current frame was large 2407 * enough for the encoder to attempt to limit its size. 2408 * SLICE_OVERFLOW(bit9): At least one slice in the current frame has 2409 * exceeded the maximum slice size specified. 2410 * BITRATE_OVERFLOW(bit10): The peak bitrate was exceeded for this frame. 2411 * BITRATE_HIGH(bit11): The frame size got within the safety margin of the maximum size (VCM only) 2412 * AIR_MB_OVER_THRESHOLD: the number of MBs adapted to Intra MB 2413 */ 2414 #define VA_CODED_BUF_STATUS_PICTURE_AVE_QP_MASK 0xff 2415 #define VA_CODED_BUF_STATUS_LARGE_SLICE_MASK 0x100 2416 #define VA_CODED_BUF_STATUS_SLICE_OVERFLOW_MASK 0x200 2417 #define VA_CODED_BUF_STATUS_BITRATE_OVERFLOW 0x400 2418 #define VA_CODED_BUF_STATUS_BITRATE_HIGH 0x800 2419 /** 2420 * \brief The frame has exceeded the maximum requested size. 2421 * 2422 * This flag indicates that the encoded frame size exceeds the value 2423 * specified through a misc parameter buffer of type 2424 * #VAEncMiscParameterTypeMaxFrameSize. 2425 */ 2426 #define VA_CODED_BUF_STATUS_FRAME_SIZE_OVERFLOW 0x1000 2427 #define VA_CODED_BUF_STATUS_AIR_MB_OVER_THRESHOLD 0xff0000 2428 2429 /** 2430 * \brief The coded buffer segment contains a single NAL unit. 2431 * 2432 * This flag indicates that the coded buffer segment contains a 2433 * single NAL unit. This flag might be useful to the user for 2434 * processing the coded buffer. 2435 */ 2436 #define VA_CODED_BUF_STATUS_SINGLE_NALU 0x10000000 2437 2438 /** 2439 * \brief The coded buffer segment contains a private data. 2440 * 2441 * This flag indicates that the coded buffer segment contains 2442 * private data. This flag can be used to exchange private data 2443 * between the client and the driver. Private data should follow 2444 * regular coded data in the coded buffer segement list. 2445 */ 2446 #define VA_CODED_BUF_STATUS_PRIVATE_DATA 0x80000000 2447 2448 /** 2449 * \brief Coded buffer segment. 2450 * 2451 * #VACodedBufferSegment is an element of a linked list describing 2452 * some information on the coded buffer. The coded buffer segment 2453 * could contain either a single NAL unit, or more than one NAL unit. 2454 * It is recommended (but not required) to return a single NAL unit 2455 * in a coded buffer segment, and the implementation should set the 2456 * VA_CODED_BUF_STATUS_SINGLE_NALU status flag if that is the case. 2457 */ 2458 typedef struct _VACodedBufferSegment { 2459 /** 2460 * \brief Size of the data buffer in this segment (in bytes). 2461 */ 2462 unsigned int size; 2463 /** \brief Bit offset into the data buffer where the video data starts. */ 2464 unsigned int bit_offset; 2465 /** \brief Status set by the driver. See \c VA_CODED_BUF_STATUS_*. */ 2466 unsigned int status; 2467 /** \brief Reserved for future use. */ 2468 unsigned int reserved; 2469 /** \brief Pointer to the start of the data buffer. */ 2470 void *buf; 2471 /** 2472 * \brief Pointer to the next #VACodedBufferSegment element, 2473 * or \c NULL if there is none. 2474 */ 2475 void *next; 2476 } VACodedBufferSegment; 2477 2478 2479 /* 2480 * H.264 Parsed Slice Header Group Info 2481 * After slice header is parsed by decode hardware, 2482 * group slice header buffer will be returned to client. 2483 * client will retrieve multiple parsed slice header infos from that buffer 2484 */ 2485 2486 /* H.264 Parsed Slice Header Info */ 2487 typedef struct _VAParseSliceHeaderGroupBuffer 2488 { 2489 unsigned int size; 2490 2491 unsigned char nal_ref_idc; 2492 unsigned char nal_unit_type; 2493 unsigned char slice_type; 2494 unsigned char redundant_pic_cnt; 2495 2496 unsigned short first_mb_in_slice; 2497 char slice_qp_delta; 2498 char slice_qs_delta; 2499 2500 unsigned char luma_log2_weight_denom; 2501 unsigned char chroma_log2_weight_denom; 2502 unsigned char cabac_init_idc; 2503 unsigned char reserved8bit; 2504 2505 unsigned short pic_order_cnt_lsb; 2506 unsigned short reserved16bit; 2507 2508 unsigned short idr_pic_id; 2509 unsigned char pic_parameter_set_id; 2510 unsigned char colour_plane_id; 2511 2512 char slice_alpha_c0_offset_div2; 2513 char slice_beta_offset_div2; 2514 unsigned char slice_group_change_cycle; 2515 unsigned char disable_deblocking_filter_idc; 2516 2517 unsigned int frame_num; 2518 int delta_pic_order_cnt_bottom; 2519 int delta_pic_order_cnt[2]; 2520 2521 unsigned char num_reorder_cmds[2]; 2522 unsigned char num_ref_active_minus1[2]; 2523 2524 unsigned int weights_present[2][2]; 2525 2526 unsigned short num_mem_man_ops; 2527 2528 union { 2529 struct { 2530 unsigned field_pic_flag : 1; 2531 unsigned bottom_field_flag : 1; 2532 unsigned num_ref_idx_active_override_flag : 1; 2533 unsigned direct_spatial_mv_pred_flag : 1; 2534 unsigned no_output_of_prior_pics_flag : 1; 2535 unsigned long_term_reference_flag : 1; 2536 unsigned idr_flag : 1; 2537 unsigned anchor_pic_flag : 1; 2538 unsigned inter_view_flag : 1; 2539 } bits; 2540 2541 unsigned short value; 2542 } flags; 2543 2544 //MVC 2545 unsigned short view_id; 2546 unsigned char priority_id; 2547 unsigned char temporal_id; 2548 } VAParseSliceHeaderGroupBuffer; 2549 2550 typedef struct _VAParsePictureParameterBuffer { 2551 VABufferID frame_buf_id; 2552 VABufferID slice_headers_buf_id; 2553 unsigned int frame_size; 2554 unsigned int slice_headers_size; 2555 union { 2556 struct { 2557 unsigned frame_mbs_only_flag : 1; 2558 unsigned pic_order_present_flag : 1; 2559 unsigned delta_pic_order_always_zero_flag : 1; 2560 unsigned redundant_pic_cnt_present_flag : 1; 2561 unsigned weighted_pred_flag : 1; 2562 unsigned entropy_coding_mode_flag : 1; 2563 unsigned deblocking_filter_control_present_flag : 1; 2564 unsigned weighted_bipred_idc : 1; 2565 } bits; 2566 unsigned int value; 2567 } flags; 2568 2569 union { 2570 struct { 2571 unsigned char nalu_header_unit_type : 5; 2572 unsigned char nalu_header_ref_idc : 2; 2573 } bits; 2574 unsigned char value; 2575 } nalu_header; 2576 2577 unsigned short expected_pic_parameter_set_id; 2578 unsigned char num_slice_groups_minus1; 2579 unsigned char slice_group_map_type; 2580 unsigned char log2_slice_group_change_cycle; 2581 unsigned char chroma_format_idc; 2582 2583 unsigned char log2_max_pic_order_cnt_lsb_minus4; 2584 unsigned char pic_order_cnt_type; 2585 unsigned char log2_max_frame_num_minus4; 2586 unsigned char idr_flag; 2587 unsigned char slice_offset; 2588 2589 /* additionally */ 2590 unsigned char residual_colour_transform_flag; 2591 unsigned char num_ref_idc_l0_active_minus1; 2592 unsigned char num_ref_idc_l1_active_minus1; 2593 } VAParsePictureParameterBuffer; 2594 2595 /* 2596 * Map data store of the buffer into the client's address space 2597 * vaCreateBuffer() needs to be called with "data" set to NULL before 2598 * calling vaMapBuffer() 2599 * 2600 * if buffer type is VAEncCodedBufferType, pbuf points to link-list of 2601 * VACodedBufferSegment, and the list is terminated if "next" is NULL 2602 */ 2603 VAStatus vaMapBuffer ( 2604 VADisplay dpy, 2605 VABufferID buf_id, /* in */ 2606 void **pbuf /* out */ 2607 ); 2608 2609 /* 2610 * After client making changes to a mapped data store, it needs to 2611 * "Unmap" it to let the server know that the data is ready to be 2612 * consumed by the server 2613 */ 2614 VAStatus vaUnmapBuffer ( 2615 VADisplay dpy, 2616 VABufferID buf_id /* in */ 2617 ); 2618 2619 /* 2620 * After this call, the buffer is deleted and this buffer_id is no longer valid 2621 * Only call this if the buffer is not going to be passed to vaRenderBuffer 2622 */ 2623 VAStatus vaDestroyBuffer ( 2624 VADisplay dpy, 2625 VABufferID buffer_id 2626 ); 2627 2628 /* 2629 Render (Decode) Pictures 2630 2631 A picture represents either a frame or a field. 2632 2633 The Begin/Render/End sequence sends the decode buffers to the server 2634 */ 2635 2636 /* 2637 * Get ready to decode a picture to a target surface 2638 */ 2639 VAStatus vaBeginPicture ( 2640 VADisplay dpy, 2641 VAContextID context, 2642 VASurfaceID render_target 2643 ); 2644 2645 /* 2646 * Send decode buffers to the server. 2647 * Buffers are automatically destroyed afterwards 2648 */ 2649 VAStatus vaRenderPicture ( 2650 VADisplay dpy, 2651 VAContextID context, 2652 VABufferID *buffers, 2653 int num_buffers 2654 ); 2655 2656 /* 2657 * Make the end of rendering for a picture. 2658 * The server should start processing all pending operations for this 2659 * surface. This call is non-blocking. The client can start another 2660 * Begin/Render/End sequence on a different render target. 2661 */ 2662 VAStatus vaEndPicture ( 2663 VADisplay dpy, 2664 VAContextID context 2665 ); 2666 2667 /* 2668 2669 Synchronization 2670 2671 */ 2672 2673 /* 2674 * This function blocks until all pending operations on the render target 2675 * have been completed. Upon return it is safe to use the render target for a 2676 * different picture. 2677 */ 2678 VAStatus vaSyncSurface ( 2679 VADisplay dpy, 2680 VASurfaceID render_target 2681 ); 2682 2683 typedef enum 2684 { 2685 VASurfaceRendering = 1, /* Rendering in progress */ 2686 VASurfaceDisplaying = 2, /* Displaying in progress (not safe to render into it) */ 2687 /* this status is useful if surface is used as the source */ 2688 /* of an overlay */ 2689 VASurfaceReady = 4, /* not being rendered or displayed */ 2690 VASurfaceSkipped = 8 /* Indicate a skipped frame during encode */ 2691 } VASurfaceStatus; 2692 2693 /* 2694 * Find out any pending ops on the render target 2695 */ 2696 VAStatus vaQuerySurfaceStatus ( 2697 VADisplay dpy, 2698 VASurfaceID render_target, 2699 VASurfaceStatus *status /* out */ 2700 ); 2701 2702 typedef enum 2703 { 2704 VADecodeSliceMissing = 0, 2705 VADecodeMBError = 1, 2706 } VADecodeErrorType; 2707 2708 /* 2709 * Client calls vaQuerySurfaceError with VA_STATUS_ERROR_DECODING_ERROR, server side returns 2710 * an array of structure VASurfaceDecodeMBErrors, and the array is terminated by setting status=-1 2711 */ 2712 typedef struct _VASurfaceDecodeMBErrors 2713 { 2714 int status; /* 1 if start_mb/end_mb with errors is returned, 2 if num_mb with errors is returned, -1 means this record is invalid */ 2715 unsigned int start_mb; /* start mb address with errors */ 2716 unsigned int end_mb; /* end mb address with errors */ 2717 VADecodeErrorType decode_error_type; 2718 unsigned int num_mb; /* number of mbs with errors */ 2719 } VASurfaceDecodeMBErrors; 2720 2721 /* 2722 * After the application gets VA_STATUS_ERROR_DECODING_ERROR after calling vaSyncSurface(), 2723 * it can call vaQuerySurfaceError to find out further details on the particular error. 2724 * VA_STATUS_ERROR_DECODING_ERROR should be passed in as "error_status", 2725 * upon the return, error_info will point to an array of _VASurfaceDecodeMBErrors structure, 2726 * which is allocated and filled by libVA with detailed information on the missing or error macroblocks. 2727 * The array is terminated if "status==-1" is detected. 2728 */ 2729 VAStatus vaQuerySurfaceError( 2730 VADisplay dpy, 2731 VASurfaceID surface, 2732 VAStatus error_status, 2733 void **error_info 2734 ); 2735 2736 /* 2737 * Images and Subpictures 2738 * VAImage is used to either get the surface data to client memory, or 2739 * to copy image data in client memory to a surface. 2740 * Both images, subpictures and surfaces follow the same 2D coordinate system where origin 2741 * is at the upper left corner with positive X to the right and positive Y down 2742 */ 2743 #define VA_FOURCC(ch0, ch1, ch2, ch3) \ 2744 ((unsigned long)(unsigned char) (ch0) | ((unsigned long)(unsigned char) (ch1) << 8) | \ 2745 ((unsigned long)(unsigned char) (ch2) << 16) | ((unsigned long)(unsigned char) (ch3) << 24 )) 2746 2747 /* 2748 * Pre-defined fourcc codes 2749 */ 2750 #define VA_FOURCC_NV12 0x3231564E 2751 #define VA_FOURCC_NV21 0x3132564E 2752 #define VA_FOURCC_AI44 0x34344149 2753 #define VA_FOURCC_RGBA 0x41424752 2754 #define VA_FOURCC_RGBX 0x58424752 2755 #define VA_FOURCC_BGRA 0x41524742 2756 #define VA_FOURCC_BGRX 0x58524742 2757 #define VA_FOURCC_ARGB 0x42475241 2758 #define VA_FOURCC_XRGB 0x42475258 2759 #define VA_FOURCC_ABGR 0x52474241 2760 #define VA_FOURCC_XBGR 0x52474258 2761 #define VA_FOURCC_UYVY 0x59565955 2762 #define VA_FOURCC_YUY2 0x32595559 2763 #define VA_FOURCC_AYUV 0x56555941 2764 #define VA_FOURCC_NV11 0x3131564e 2765 #define VA_FOURCC_YV12 0x32315659 2766 #define VA_FOURCC_P208 0x38303250 2767 #define VA_FOURCC_IYUV 0x56555949 2768 #define VA_FOURCC_YV24 0x34325659 2769 #define VA_FOURCC_YV32 0x32335659 2770 #define VA_FOURCC_Y800 0x30303859 2771 #define VA_FOURCC_IMC3 0x33434D49 2772 #define VA_FOURCC_411P 0x50313134 2773 #define VA_FOURCC_422H 0x48323234 2774 #define VA_FOURCC_422V 0x56323234 2775 #define VA_FOURCC_444P 0x50343434 2776 #define VA_FOURCC_RGBP 0x50424752 2777 #define VA_FOURCC_BGRP 0x50524742 2778 #define VA_FOURCC_411R 0x52313134 /* rotated 411P */ 2779 2780 /* byte order */ 2781 #define VA_LSB_FIRST 1 2782 #define VA_MSB_FIRST 2 2783 2784 typedef struct _VAImageFormat 2785 { 2786 unsigned int fourcc; 2787 unsigned int byte_order; /* VA_LSB_FIRST, VA_MSB_FIRST */ 2788 unsigned int bits_per_pixel; 2789 /* for RGB formats */ 2790 unsigned int depth; /* significant bits per pixel */ 2791 unsigned int red_mask; 2792 unsigned int green_mask; 2793 unsigned int blue_mask; 2794 unsigned int alpha_mask; 2795 } VAImageFormat; 2796 2797 typedef VAGenericID VAImageID; 2798 2799 typedef struct _VAImage 2800 { 2801 VAImageID image_id; /* uniquely identify this image */ 2802 VAImageFormat format; 2803 VABufferID buf; /* image data buffer */ 2804 /* 2805 * Image data will be stored in a buffer of type VAImageBufferType to facilitate 2806 * data store on the server side for optimal performance. The buffer will be 2807 * created by the CreateImage function, and proper storage allocated based on the image 2808 * size and format. This buffer is managed by the library implementation, and 2809 * accessed by the client through the buffer Map/Unmap functions. 2810 */ 2811 unsigned short width; 2812 unsigned short height; 2813 unsigned int data_size; 2814 unsigned int num_planes; /* can not be greater than 4 */ 2815 /* 2816 * An array indicating the scanline pitch in bytes for each plane. 2817 * Each plane may have a different pitch. Maximum 3 planes for planar formats 2818 */ 2819 unsigned int pitches[3]; 2820 /* 2821 * An array indicating the byte offset from the beginning of the image data 2822 * to the start of each plane. 2823 */ 2824 unsigned int offsets[3]; 2825 2826 /* The following fields are only needed for paletted formats */ 2827 int num_palette_entries; /* set to zero for non-palette images */ 2828 /* 2829 * Each component is one byte and entry_bytes indicates the number of components in 2830 * each entry (eg. 3 for YUV palette entries). set to zero for non-palette images 2831 */ 2832 int entry_bytes; 2833 /* 2834 * An array of ascii characters describing the order of the components within the bytes. 2835 * Only entry_bytes characters of the string are used. 2836 */ 2837 char component_order[4]; 2838 /* 2839 * Pitch and byte offset for the fourth plane if the image format requires 4 planes 2840 * Particular use case is JPEG with CMYK profile 2841 */ 2842 unsigned int extra_pitch; 2843 unsigned int extra_offset; 2844 } VAImage; 2845 2846 /* Get maximum number of image formats supported by the implementation */ 2847 int vaMaxNumImageFormats ( 2848 VADisplay dpy 2849 ); 2850 2851 /* 2852 * Query supported image formats 2853 * The caller must provide a "format_list" array that can hold at 2854 * least vaMaxNumImageFormats() entries. The actual number of formats 2855 * returned in "format_list" is returned in "num_formats". 2856 */ 2857 VAStatus vaQueryImageFormats ( 2858 VADisplay dpy, 2859 VAImageFormat *format_list, /* out */ 2860 int *num_formats /* out */ 2861 ); 2862 2863 /* 2864 * Create a VAImage structure 2865 * The width and height fields returned in the VAImage structure may get 2866 * enlarged for some YUV formats. Upon return from this function, 2867 * image->buf has been created and proper storage allocated by the library. 2868 * The client can access the image through the Map/Unmap calls. 2869 */ 2870 VAStatus vaCreateImage ( 2871 VADisplay dpy, 2872 VAImageFormat *format, 2873 int width, 2874 int height, 2875 VAImage *image /* out */ 2876 ); 2877 2878 /* 2879 * Should call DestroyImage before destroying the surface it is bound to 2880 */ 2881 VAStatus vaDestroyImage ( 2882 VADisplay dpy, 2883 VAImageID image 2884 ); 2885 2886 VAStatus vaSetImagePalette ( 2887 VADisplay dpy, 2888 VAImageID image, 2889 /* 2890 * pointer to an array holding the palette data. The size of the array is 2891 * num_palette_entries * entry_bytes in size. The order of the components 2892 * in the palette is described by the component_order in VAImage struct 2893 */ 2894 unsigned char *palette 2895 ); 2896 2897 /* 2898 * Retrive surface data into a VAImage 2899 * Image must be in a format supported by the implementation 2900 */ 2901 VAStatus vaGetImage ( 2902 VADisplay dpy, 2903 VASurfaceID surface, 2904 int x, /* coordinates of the upper left source pixel */ 2905 int y, 2906 unsigned int width, /* width and height of the region */ 2907 unsigned int height, 2908 VAImageID image 2909 ); 2910 2911 /* 2912 * Copy data from a VAImage to a surface 2913 * Image must be in a format supported by the implementation 2914 * Returns a VA_STATUS_ERROR_SURFACE_BUSY if the surface 2915 * shouldn't be rendered into when this is called 2916 */ 2917 VAStatus vaPutImage ( 2918 VADisplay dpy, 2919 VASurfaceID surface, 2920 VAImageID image, 2921 int src_x, 2922 int src_y, 2923 unsigned int src_width, 2924 unsigned int src_height, 2925 int dest_x, 2926 int dest_y, 2927 unsigned int dest_width, 2928 unsigned int dest_height 2929 ); 2930 2931 /* 2932 * Derive an VAImage from an existing surface. 2933 * This interface will derive a VAImage and corresponding image buffer from 2934 * an existing VA Surface. The image buffer can then be mapped/unmapped for 2935 * direct CPU access. This operation is only possible on implementations with 2936 * direct rendering capabilities and internal surface formats that can be 2937 * represented with a VAImage. When the operation is not possible this interface 2938 * will return VA_STATUS_ERROR_OPERATION_FAILED. Clients should then fall back 2939 * to using vaCreateImage + vaPutImage to accomplish the same task in an 2940 * indirect manner. 2941 * 2942 * Implementations should only return success when the resulting image buffer 2943 * would be useable with vaMap/Unmap. 2944 * 2945 * When directly accessing a surface special care must be taken to insure 2946 * proper synchronization with the graphics hardware. Clients should call 2947 * vaQuerySurfaceStatus to insure that a surface is not the target of concurrent 2948 * rendering or currently being displayed by an overlay. 2949 * 2950 * Additionally nothing about the contents of a surface should be assumed 2951 * following a vaPutSurface. Implementations are free to modify the surface for 2952 * scaling or subpicture blending within a call to vaPutImage. 2953 * 2954 * Calls to vaPutImage or vaGetImage using the same surface from which the image 2955 * has been derived will return VA_STATUS_ERROR_SURFACE_BUSY. vaPutImage or 2956 * vaGetImage with other surfaces is supported. 2957 * 2958 * An image created with vaDeriveImage should be freed with vaDestroyImage. The 2959 * image and image buffer structures will be destroyed; however, the underlying 2960 * surface will remain unchanged until freed with vaDestroySurfaces. 2961 */ 2962 VAStatus vaDeriveImage ( 2963 VADisplay dpy, 2964 VASurfaceID surface, 2965 VAImage *image /* out */ 2966 ); 2967 2968 /* 2969 * Subpictures 2970 * Subpicture is a special type of image that can be blended 2971 * with a surface during vaPutSurface(). Subpicture can be used to render 2972 * DVD sub-titles or closed captioning text etc. 2973 */ 2974 2975 typedef VAGenericID VASubpictureID; 2976 2977 /* Get maximum number of subpicture formats supported by the implementation */ 2978 int vaMaxNumSubpictureFormats ( 2979 VADisplay dpy 2980 ); 2981 2982 /* flags for subpictures */ 2983 #define VA_SUBPICTURE_CHROMA_KEYING 0x0001 2984 #define VA_SUBPICTURE_GLOBAL_ALPHA 0x0002 2985 #define VA_SUBPICTURE_DESTINATION_IS_SCREEN_COORD 0x0004 2986 /* 2987 * Query supported subpicture formats 2988 * The caller must provide a "format_list" array that can hold at 2989 * least vaMaxNumSubpictureFormats() entries. The flags arrary holds the flag 2990 * for each format to indicate additional capabilities for that format. The actual 2991 * number of formats returned in "format_list" is returned in "num_formats". 2992 * flags: returned value to indicate addtional capabilities 2993 * VA_SUBPICTURE_CHROMA_KEYING - supports chroma-keying 2994 * VA_SUBPICTURE_GLOBAL_ALPHA - supports global alpha 2995 * VA_SUBPICTURE_DESTINATION_IS_SCREEN_COORD - supports unscaled screen relative subpictures for On Screen Display 2996 */ 2997 2998 VAStatus vaQuerySubpictureFormats ( 2999 VADisplay dpy, 3000 VAImageFormat *format_list, /* out */ 3001 unsigned int *flags, /* out */ 3002 unsigned int *num_formats /* out */ 3003 ); 3004 3005 /* 3006 * Subpictures are created with an image associated. 3007 */ 3008 VAStatus vaCreateSubpicture ( 3009 VADisplay dpy, 3010 VAImageID image, 3011 VASubpictureID *subpicture /* out */ 3012 ); 3013 3014 /* 3015 * Destroy the subpicture before destroying the image it is assocated to 3016 */ 3017 VAStatus vaDestroySubpicture ( 3018 VADisplay dpy, 3019 VASubpictureID subpicture 3020 ); 3021 3022 /* 3023 * Bind an image to the subpicture. This image will now be associated with 3024 * the subpicture instead of the one at creation. 3025 */ 3026 VAStatus vaSetSubpictureImage ( 3027 VADisplay dpy, 3028 VASubpictureID subpicture, 3029 VAImageID image 3030 ); 3031 3032 /* 3033 * If chromakey is enabled, then the area where the source value falls within 3034 * the chromakey [min, max] range is transparent 3035 * The chromakey component format is the following: 3036 * For RGB: [0:7] Red [8:15] Blue [16:23] Green 3037 * For YUV: [0:7] V [8:15] U [16:23] Y 3038 * The chromakey mask can be used to mask out certain components for chromakey 3039 * comparision 3040 */ 3041 VAStatus vaSetSubpictureChromakey ( 3042 VADisplay dpy, 3043 VASubpictureID subpicture, 3044 unsigned int chromakey_min, 3045 unsigned int chromakey_max, 3046 unsigned int chromakey_mask 3047 ); 3048 3049 /* 3050 * Global alpha value is between 0 and 1. A value of 1 means fully opaque and 3051 * a value of 0 means fully transparent. If per-pixel alpha is also specified then 3052 * the overall alpha is per-pixel alpha multiplied by the global alpha 3053 */ 3054 VAStatus vaSetSubpictureGlobalAlpha ( 3055 VADisplay dpy, 3056 VASubpictureID subpicture, 3057 float global_alpha 3058 ); 3059 3060 /* 3061 * vaAssociateSubpicture associates the subpicture with target_surfaces. 3062 * It defines the region mapping between the subpicture and the target 3063 * surfaces through source and destination rectangles (with the same width and height). 3064 * Both will be displayed at the next call to vaPutSurface. Additional 3065 * associations before the call to vaPutSurface simply overrides the association. 3066 */ 3067 VAStatus vaAssociateSubpicture ( 3068 VADisplay dpy, 3069 VASubpictureID subpicture, 3070 VASurfaceID *target_surfaces, 3071 int num_surfaces, 3072 short src_x, /* upper left offset in subpicture */ 3073 short src_y, 3074 unsigned short src_width, 3075 unsigned short src_height, 3076 short dest_x, /* upper left offset in surface */ 3077 short dest_y, 3078 unsigned short dest_width, 3079 unsigned short dest_height, 3080 /* 3081 * whether to enable chroma-keying, global-alpha, or screen relative mode 3082 * see VA_SUBPICTURE_XXX values 3083 */ 3084 unsigned int flags 3085 ); 3086 3087 /* 3088 * vaDeassociateSubpicture removes the association of the subpicture with target_surfaces. 3089 */ 3090 VAStatus vaDeassociateSubpicture ( 3091 VADisplay dpy, 3092 VASubpictureID subpicture, 3093 VASurfaceID *target_surfaces, 3094 int num_surfaces 3095 ); 3096 3097 /* 3098 * Display attributes 3099 * Display attributes are used to control things such as contrast, hue, saturation, 3100 * brightness etc. in the rendering process. The application can query what 3101 * attributes are supported by the driver, and then set the appropriate attributes 3102 * before calling vaPutSurface() 3103 */ 3104 3105 /** 3106 * @name Rotation angles 3107 * 3108 * Those values could be used for VADisplayAttribRotation attribute or 3109 * VAProcPipelineParameterBuffer::rotation_state or in VAConfigAttribValDecJPEG. 3110 * The rotation operation is clockwise. 3111 */ 3112 /**@{*/ 3113 /** \brief No rotation. */ 3114 #define VA_ROTATION_NONE 0x00000000 3115 /** \brief Rotation by 90° clockwise. */ 3116 #define VA_ROTATION_90 0x00000001 3117 /** \brief Rotation by 180° clockwise. */ 3118 #define VA_ROTATION_180 0x00000002 3119 /** \brief Rotation by 270° clockwise. */ 3120 #define VA_ROTATION_270 0x00000003 3121 /**@}*/ 3122 3123 /** 3124 * @name Mirroring directions 3125 * 3126 * Those values could be used for VADisplayAttribMirror attribute or 3127 * VAProcPipelineParameterBuffer::mirror_state. 3128 3129 */ 3130 /**@{*/ 3131 /** \brief No Mirroring. */ 3132 #define VA_MIRROR_NONE 0x00000000 3133 /** \brief Horizontal Mirroring. */ 3134 #define VA_MIRROR_HORIZONTAL 0x00000001 3135 /** \brief Vertical Mirroring. */ 3136 #define VA_MIRROR_VERTICAL 0x00000002 3137 /**@}*/ 3138 3139 /* attribute value for VADisplayAttribOutOfLoopDeblock */ 3140 #define VA_OOL_DEBLOCKING_FALSE 0x00000000 3141 #define VA_OOL_DEBLOCKING_TRUE 0x00000001 3142 3143 /* Render mode */ 3144 #define VA_RENDER_MODE_UNDEFINED 0 3145 #define VA_RENDER_MODE_LOCAL_OVERLAY 1 3146 #define VA_RENDER_MODE_LOCAL_GPU 2 3147 #define VA_RENDER_MODE_EXTERNAL_OVERLAY 4 3148 #define VA_RENDER_MODE_EXTERNAL_GPU 8 3149 3150 /* Render device */ 3151 #define VA_RENDER_DEVICE_UNDEFINED 0 3152 #define VA_RENDER_DEVICE_LOCAL 1 3153 #define VA_RENDER_DEVICE_EXTERNAL 2 3154 3155 /* Currently defined display attribute types */ 3156 typedef enum 3157 { 3158 VADisplayAttribBrightness = 0, 3159 VADisplayAttribContrast = 1, 3160 VADisplayAttribHue = 2, 3161 VADisplayAttribSaturation = 3, 3162 /* client can specifiy a background color for the target window 3163 * the new feature of video conference, 3164 * the uncovered area of the surface is filled by this color 3165 * also it will blend with the decoded video color 3166 */ 3167 VADisplayAttribBackgroundColor = 4, 3168 VADisplayAttribRotation = 6, 3169 VADisplayAttribOutofLoopDeblock = 7, 3170 3171 /* 3172 * For type VADisplayAttribCSCMatrix, "value" field is a pointer to the color 3173 * conversion matrix. Each element in the matrix is float-point 3174 */ 3175 VADisplayAttribCSCMatrix = 12, 3176 /* specify the constant color used to blend with video surface 3177 * Cd = Cv*Cc*Ac + Cb *(1 - Ac) C means the constant RGB 3178 * d: the final color to overwrite into the frame buffer 3179 * v: decoded video after color conversion, 3180 * c: video color specified by VADisplayAttribBlendColor 3181 * b: background color of the drawable 3182 */ 3183 VADisplayAttribBlendColor = 13, 3184 /* 3185 * Indicate driver to skip painting color key or not. 3186 * only applicable if the render is overlay 3187 */ 3188 VADisplayAttribOverlayAutoPaintColorKey = 14, 3189 /* 3190 * customized overlay color key, the format is RGB888 3191 * [23:16] = Red, [15:08] = Green, [07:00] = Blue. 3192 */ 3193 VADisplayAttribOverlayColorKey = 15, 3194 /* 3195 * The hint for the implementation of vaPutSurface 3196 * normally, the driver could use an overlay or GPU to render the surface on the screen 3197 * this flag provides APP the flexibity to switch the render dynamically 3198 */ 3199 VADisplayAttribRenderMode = 16, 3200 /* 3201 * specify if vaPutSurface needs to render into specified monitors 3202 * one example is that one external monitor (e.g. HDMI) is enabled, 3203 * but the window manager is not aware of it, and there is no associated drawable 3204 */ 3205 VADisplayAttribRenderDevice = 17, 3206 /* 3207 * specify vaPutSurface render area if there is no drawable on the monitor 3208 */ 3209 VADisplayAttribRenderRect = 18, 3210 /* 3211 * The flag is used to indicate that the range flag of color-space conversion. 3212 * "value" field should be assigned as VA_SOURCE_RANGE_FULL or VA_SOURCE_RANGE_REDUCED 3213 * to indicate full range or reduced range 3214 */ 3215 VADisplayAttribColorRange = 19, 3216 3217 } VADisplayAttribType; 3218 3219 /* flags for VADisplayAttribute */ 3220 #define VA_DISPLAY_ATTRIB_NOT_SUPPORTED 0x0000 3221 #define VA_DISPLAY_ATTRIB_GETTABLE 0x0001 3222 #define VA_DISPLAY_ATTRIB_SETTABLE 0x0002 3223 3224 typedef struct _VADisplayAttribute 3225 { 3226 VADisplayAttribType type; 3227 int min_value; 3228 int max_value; 3229 int value; /* used by the set/get attribute functions */ 3230 /* flags can be VA_DISPLAY_ATTRIB_GETTABLE or VA_DISPLAY_ATTRIB_SETTABLE or OR'd together */ 3231 unsigned int flags; 3232 void *attrib_ptr; /* if flags contains VA_DISPLAY_ATTRIB_POINTER, then "attrib_ptr" points to a structure for this display attribute */ 3233 } VADisplayAttribute; 3234 3235 /* Get maximum number of display attributs supported by the implementation */ 3236 int vaMaxNumDisplayAttributes ( 3237 VADisplay dpy 3238 ); 3239 3240 /* 3241 * Query display attributes 3242 * The caller must provide a "attr_list" array that can hold at 3243 * least vaMaxNumDisplayAttributes() entries. The actual number of attributes 3244 * returned in "attr_list" is returned in "num_attributes". 3245 */ 3246 VAStatus vaQueryDisplayAttributes ( 3247 VADisplay dpy, 3248 VADisplayAttribute *attr_list, /* out */ 3249 int *num_attributes /* out */ 3250 ); 3251 3252 /* 3253 * Get display attributes 3254 * This function returns the current attribute values in "attr_list". 3255 * Only attributes returned with VA_DISPLAY_ATTRIB_GETTABLE set in the "flags" field 3256 * from vaQueryDisplayAttributes() can have their values retrieved. 3257 */ 3258 VAStatus vaGetDisplayAttributes ( 3259 VADisplay dpy, 3260 VADisplayAttribute *attr_list, /* in/out */ 3261 int num_attributes 3262 ); 3263 3264 /* 3265 * Set display attributes 3266 * Only attributes returned with VA_DISPLAY_ATTRIB_SETTABLE set in the "flags" field 3267 * from vaQueryDisplayAttributes() can be set. If the attribute is not settable or 3268 * the value is out of range, the function returns VA_STATUS_ERROR_ATTR_NOT_SUPPORTED 3269 */ 3270 VAStatus vaSetDisplayAttributes ( 3271 VADisplay dpy, 3272 VADisplayAttribute *attr_list, 3273 int num_attributes 3274 ); 3275 3276 /**@}*/ 3277 3278 #ifdef __cplusplus 3279 } 3280 #endif 3281 3282 #endif /* _VA_H_ */ 3283