ref: 40a0590950ea9307a1deba1f74b56218e2c6e6d2
dir: /vpx/vpx_encoder.h/
/* * Copyright (c) 2010 The WebM project authors. All Rights Reserved. * * Use of this source code is governed by a BSD-style license * that can be found in the LICENSE file in the root of the source * tree. An additional intellectual property rights grant can be found * in the file PATENTS. All contributing project authors may * be found in the AUTHORS file in the root of the source tree. */ #ifndef VPX_VPX_VPX_ENCODER_H_ #define VPX_VPX_VPX_ENCODER_H_ /*!\defgroup encoder Encoder Algorithm Interface * \ingroup codec * This abstraction allows applications using this encoder to easily support * multiple video formats with minimal code duplication. This section describes * the interface common to all encoders. * @{ */ /*!\file * \brief Describes the encoder algorithm interface to applications. * * This file describes the interface between an application and a * video encoder algorithm. * */ #ifdef __cplusplus extern "C" { #endif #include "./vpx_codec.h" /*! Temporal Scalability: Maximum length of the sequence defining frame * layer membership */ #define VPX_TS_MAX_PERIODICITY 16 /*! Temporal Scalability: Maximum number of coding layers */ #define VPX_TS_MAX_LAYERS 5 /*!\deprecated Use #VPX_TS_MAX_PERIODICITY instead. */ #define MAX_PERIODICITY VPX_TS_MAX_PERIODICITY /*! Temporal+Spatial Scalability: Maximum number of coding layers */ #define VPX_MAX_LAYERS 12 // 3 temporal + 4 spatial layers are allowed. /*!\deprecated Use #VPX_MAX_LAYERS instead. */ #define MAX_LAYERS VPX_MAX_LAYERS // 3 temporal + 4 spatial layers allowed. /*! Spatial Scalability: Maximum number of coding layers */ #define VPX_SS_MAX_LAYERS 5 /*! Spatial Scalability: Default number of coding layers */ #define VPX_SS_DEFAULT_LAYERS 1 /*!\brief Current ABI version number * * \internal * If this file is altered in any way that changes the ABI, this value * must be bumped. Examples include, but are not limited to, changing * types, removing or reassigning enums, adding/removing/rearranging * fields to structures */ #define VPX_ENCODER_ABI_VERSION \ (14 + VPX_CODEC_ABI_VERSION) /**<\hideinitializer*/ /*! \brief Encoder capabilities bitfield * * Each encoder advertises the capabilities it supports as part of its * ::vpx_codec_iface_t interface structure. Capabilities are extra * interfaces or functionality, and are not required to be supported * by an encoder. * * The available flags are specified by VPX_CODEC_CAP_* defines. */ #define VPX_CODEC_CAP_PSNR 0x10000 /**< Can issue PSNR packets */ /*! Can output one partition at a time. Each partition is returned in its * own VPX_CODEC_CX_FRAME_PKT, with the FRAME_IS_FRAGMENT flag set for * every partition but the last. In this mode all frames are always * returned partition by partition. */ #define VPX_CODEC_CAP_OUTPUT_PARTITION 0x20000 /*! \brief Initialization-time Feature Enabling * * Certain codec features must be known at initialization time, to allow * for proper memory allocation. * * The available flags are specified by VPX_CODEC_USE_* defines. */ #define VPX_CODEC_USE_PSNR 0x10000 /**< Calculate PSNR on each frame */ /*!\brief Make the encoder output one partition at a time. */ #define VPX_CODEC_USE_OUTPUT_PARTITION 0x20000 #define VPX_CODEC_USE_HIGHBITDEPTH 0x40000 /**< Use high bitdepth */ /*!\brief Generic fixed size buffer structure * * This structure is able to hold a reference to any fixed size buffer. */ typedef struct vpx_fixed_buf { void *buf; /**< Pointer to the data */ size_t sz; /**< Length of the buffer, in chars */ } vpx_fixed_buf_t; /**< alias for struct vpx_fixed_buf */ /*!\brief Time Stamp Type * * An integer, which when multiplied by the stream's time base, provides * the absolute time of a sample. */ typedef int64_t vpx_codec_pts_t; /*!\brief Compressed Frame Flags * * This type represents a bitfield containing information about a compressed * frame that may be useful to an application. The most significant 16 bits * can be used by an algorithm to provide additional detail, for example to * support frame types that are codec specific (MPEG-1 D-frames for example) */ typedef uint32_t vpx_codec_frame_flags_t; #define VPX_FRAME_IS_KEY 0x1 /**< frame is the start of a GOP */ /*!\brief frame can be dropped without affecting the stream (no future frame * depends on this one) */ #define VPX_FRAME_IS_DROPPABLE 0x2 /*!\brief frame should be decoded but will not be shown */ #define VPX_FRAME_IS_INVISIBLE 0x4 /*!\brief this is a fragment of the encoded frame */ #define VPX_FRAME_IS_FRAGMENT 0x8 /*!\brief Error Resilient flags * * These flags define which error resilient features to enable in the * encoder. The flags are specified through the * vpx_codec_enc_cfg::g_error_resilient variable. */ typedef uint32_t vpx_codec_er_flags_t; /*!\brief Improve resiliency against losses of whole frames */ #define VPX_ERROR_RESILIENT_DEFAULT 0x1 /*!\brief The frame partitions are independently decodable by the bool decoder, * meaning that partitions can be decoded even though earlier partitions have * been lost. Note that intra prediction is still done over the partition * boundary. */ #define VPX_ERROR_RESILIENT_PARTITIONS 0x2 /*!\brief Encoder output packet variants * * This enumeration lists the different kinds of data packets that can be * returned by calls to vpx_codec_get_cx_data(). Algorithms \ref MAY * extend this list to provide additional functionality. */ enum vpx_codec_cx_pkt_kind { VPX_CODEC_CX_FRAME_PKT, /**< Compressed video frame */ VPX_CODEC_STATS_PKT, /**< Two-pass statistics for this frame */ VPX_CODEC_FPMB_STATS_PKT, /**< first pass mb statistics for this frame */ VPX_CODEC_PSNR_PKT, /**< PSNR statistics for this frame */ VPX_CODEC_CUSTOM_PKT = 256 /**< Algorithm extensions */ }; /*!\brief Encoder output packet * * This structure contains the different kinds of output data the encoder * may produce while compressing a frame. */ typedef struct vpx_codec_cx_pkt { enum vpx_codec_cx_pkt_kind kind; /**< packet variant */ union { struct { void *buf; /**< compressed data buffer */ size_t sz; /**< length of compressed data */ /*!\brief time stamp to show frame (in timebase units) */ vpx_codec_pts_t pts; /*!\brief duration to show frame (in timebase units) */ unsigned long duration; vpx_codec_frame_flags_t flags; /**< flags for this frame */ /*!\brief the partition id defines the decoding order of the partitions. * Only applicable when "output partition" mode is enabled. First * partition has id 0.*/ int partition_id; /*!\brief Width and height of frames in this packet. VP8 will only use the * first one.*/ unsigned int width[VPX_SS_MAX_LAYERS]; /**< frame width */ unsigned int height[VPX_SS_MAX_LAYERS]; /**< frame height */ /*!\brief Flag to indicate if spatial layer frame in this packet is * encoded or dropped. VP8 will always be set to 1.*/ uint8_t spatial_layer_encoded[VPX_SS_MAX_LAYERS]; } frame; /**< data for compressed frame packet */ vpx_fixed_buf_t twopass_stats; /**< data for two-pass packet */ vpx_fixed_buf_t firstpass_mb_stats; /**< first pass mb packet */ struct vpx_psnr_pkt { unsigned int samples[4]; /**< Number of samples, total/y/u/v */ uint64_t sse[4]; /**< sum squared error, total/y/u/v */ double psnr[4]; /**< PSNR, total/y/u/v */ } psnr; /**< data for PSNR packet */ vpx_fixed_buf_t raw; /**< data for arbitrary packets */ /* This packet size is fixed to allow codecs to extend this * interface without having to manage storage for raw packets, * i.e., if it's smaller than 128 bytes, you can store in the * packet list directly. */ char pad[128 - sizeof(enum vpx_codec_cx_pkt_kind)]; /**< fixed sz */ } data; /**< packet data */ } vpx_codec_cx_pkt_t; /**< alias for struct vpx_codec_cx_pkt */ /*!\brief Encoder return output buffer callback * * This callback function, when registered, returns with packets when each * spatial layer is encoded. */ // putting the definitions here for now. (agrange: find if there // is a better place for this) typedef void (*vpx_codec_enc_output_cx_pkt_cb_fn_t)(vpx_codec_cx_pkt_t *pkt, void *user_data); /*!\brief Callback function pointer / user data pair storage */ typedef struct vpx_codec_enc_output_cx_cb_pair { vpx_codec_enc_output_cx_pkt_cb_fn_t output_cx_pkt; /**< Callback function */ void *user_priv; /**< Pointer to private data */ } vpx_codec_priv_output_cx_pkt_cb_pair_t; /*!\brief Rational Number * * This structure holds a fractional value. */ typedef struct vpx_rational { int num; /**< fraction numerator */ int den; /**< fraction denominator */ } vpx_rational_t; /**< alias for struct vpx_rational */ /*!\brief Multi-pass Encoding Pass */ enum vpx_enc_pass { VPX_RC_ONE_PASS, /**< Single pass mode */ VPX_RC_FIRST_PASS, /**< First pass of multi-pass mode */ VPX_RC_LAST_PASS /**< Final pass of multi-pass mode */ }; /*!\brief Rate control mode */ enum vpx_rc_mode { VPX_VBR, /**< Variable Bit Rate (VBR) mode */ VPX_CBR, /**< Constant Bit Rate (CBR) mode */ VPX_CQ, /**< Constrained Quality (CQ) mode */ VPX_Q, /**< Constant Quality (Q) mode */ }; /*!\brief Keyframe placement mode. * * This enumeration determines whether keyframes are placed automatically by * the encoder or whether this behavior is disabled. Older releases of this * SDK were implemented such that VPX_KF_FIXED meant keyframes were disabled. * This name is confusing for this behavior, so the new symbols to be used * are VPX_KF_AUTO and VPX_KF_DISABLED. */ enum vpx_kf_mode { VPX_KF_FIXED, /**< deprecated, implies VPX_KF_DISABLED */ VPX_KF_AUTO, /**< Encoder determines optimal placement automatically */ VPX_KF_DISABLED = 0 /**< Encoder does not place keyframes. */ }; /*!\brief Encoded Frame Flags * * This type indicates a bitfield to be passed to vpx_codec_encode(), defining * per-frame boolean values. By convention, bits common to all codecs will be * named VPX_EFLAG_*, and bits specific to an algorithm will be named * /algo/_eflag_*. The lower order 16 bits are reserved for common use. */ typedef long vpx_enc_frame_flags_t; #define VPX_EFLAG_FORCE_KF (1 << 0) /**< Force this frame to be a keyframe */ /*!\brief Encoder configuration structure * * This structure contains the encoder settings that have common representations * across all codecs. This doesn't imply that all codecs support all features, * however. */ typedef struct vpx_codec_enc_cfg { /* * generic settings (g) */ /*!\brief Algorithm specific "usage" value * * Algorithms may define multiple values for usage, which may convey the * intent of how the application intends to use the stream. If this value * is non-zero, consult the documentation for the codec to determine its * meaning. */ unsigned int g_usage; /*!\brief Maximum number of threads to use * * For multi-threaded implementations, use no more than this number of * threads. The codec may use fewer threads than allowed. The value * 0 is equivalent to the value 1. */ unsigned int g_threads; /*!\brief Bitstream profile to use * * Some codecs support a notion of multiple bitstream profiles. Typically * this maps to a set of features that are turned on or off. Often the * profile to use is determined by the features of the intended decoder. * Consult the documentation for the codec to determine the valid values * for this parameter, or set to zero for a sane default. */ unsigned int g_profile; /**< profile of bitstream to use */ /*!\brief Width of the frame * * This value identifies the presentation resolution of the frame, * in pixels. Note that the frames passed as input to the encoder must * have this resolution. Frames will be presented by the decoder in this * resolution, independent of any spatial resampling the encoder may do. */ unsigned int g_w; /*!\brief Height of the frame * * This value identifies the presentation resolution of the frame, * in pixels. Note that the frames passed as input to the encoder must * have this resolution. Frames will be presented by the decoder in this * resolution, independent of any spatial resampling the encoder may do. */ unsigned int g_h; /*!\brief Bit-depth of the codec * * This value identifies the bit_depth of the codec, * Only certain bit-depths are supported as identified in the * vpx_bit_depth_t enum. */ vpx_bit_depth_t g_bit_depth; /*!\brief Bit-depth of the input frames * * This value identifies the bit_depth of the input frames in bits. * Note that the frames passed as input to the encoder must have * this bit-depth. */ unsigned int g_input_bit_depth; /*!\brief Stream timebase units * * Indicates the smallest interval of time, in seconds, used by the stream. * For fixed frame rate material, or variable frame rate material where * frames are timed at a multiple of a given clock (ex: video capture), * the \ref RECOMMENDED method is to set the timebase to the reciprocal * of the frame rate (ex: 1001/30000 for 29.970 Hz NTSC). This allows the * pts to correspond to the frame number, which can be handy. For * re-encoding video from containers with absolute time timestamps, the * \ref RECOMMENDED method is to set the timebase to that of the parent * container or multimedia framework (ex: 1/1000 for ms, as in FLV). */ struct vpx_rational g_timebase; /*!\brief Enable error resilient modes. * * The error resilient bitfield indicates to the encoder which features * it should enable to take measures for streaming over lossy or noisy * links. */ vpx_codec_er_flags_t g_error_resilient; /*!\brief Multi-pass Encoding Mode * * This value should be set to the current phase for multi-pass encoding. * For single pass, set to #VPX_RC_ONE_PASS. */ enum vpx_enc_pass g_pass; /*!\brief Allow lagged encoding * * If set, this value allows the encoder to consume a number of input * frames before producing output frames. This allows the encoder to * base decisions for the current frame on future frames. This does * increase the latency of the encoding pipeline, so it is not appropriate * in all situations (ex: realtime encoding). * * Note that this is a maximum value -- the encoder may produce frames * sooner than the given limit. Set this value to 0 to disable this * feature. */ unsigned int g_lag_in_frames; /* * rate control settings (rc) */ /*!\brief Temporal resampling configuration, if supported by the codec. * * Temporal resampling allows the codec to "drop" frames as a strategy to * meet its target data rate. This can cause temporal discontinuities in * the encoded video, which may appear as stuttering during playback. This * trade-off is often acceptable, but for many applications is not. It can * be disabled in these cases. * * Note that not all codecs support this feature. All vpx VPx codecs do. * For other codecs, consult the documentation for that algorithm. * * This threshold is described as a percentage of the target data buffer. * When the data buffer falls below this percentage of fullness, a * dropped frame is indicated. Set the threshold to zero (0) to disable * this feature. */ unsigned int rc_dropframe_thresh; /*!\brief Enable/disable spatial resampling, if supported by the codec. * * Spatial resampling allows the codec to compress a lower resolution * version of the frame, which is then upscaled by the encoder to the * correct presentation resolution. This increases visual quality at * low data rates, at the expense of CPU time on the encoder/decoder. */ unsigned int rc_resize_allowed; /*!\brief Internal coded frame width. * * If spatial resampling is enabled this specifies the width of the * encoded frame. */ unsigned int rc_scaled_width; /*!\brief Internal coded frame height. * * If spatial resampling is enabled this specifies the height of the * encoded frame. */ unsigned int rc_scaled_height; /*!\brief Spatial resampling up watermark. * * This threshold is described as a percentage of the target data buffer. * When the data buffer rises above this percentage of fullness, the * encoder will step up to a higher resolution version of the frame. */ unsigned int rc_resize_up_thresh; /*!\brief Spatial resampling down watermark. * * This threshold is described as a percentage of the target data buffer. * When the data buffer falls below this percentage of fullness, the * encoder will step down to a lower resolution version of the frame. */ unsigned int rc_resize_down_thresh; /*!\brief Rate control algorithm to use. * * Indicates whether the end usage of this stream is to be streamed over * a bandwidth constrained link, indicating that Constant Bit Rate (CBR) * mode should be used, or whether it will be played back on a high * bandwidth link, as from a local disk, where higher variations in * bitrate are acceptable. */ enum vpx_rc_mode rc_end_usage; /*!\brief Two-pass stats buffer. * * A buffer containing all of the stats packets produced in the first * pass, concatenated. */ vpx_fixed_buf_t rc_twopass_stats_in; /*!\brief first pass mb stats buffer. * * A buffer containing all of the first pass mb stats packets produced * in the first pass, concatenated. */ vpx_fixed_buf_t rc_firstpass_mb_stats_in; /*!\brief Target data rate * * Target bandwidth to use for this stream, in kilobits per second. */ unsigned int rc_target_bitrate; /* * quantizer settings */ /*!\brief Minimum (Best Quality) Quantizer * * The quantizer is the most direct control over the quality of the * encoded image. The range of valid values for the quantizer is codec * specific. Consult the documentation for the codec to determine the * values to use. To determine the range programmatically, call * vpx_codec_enc_config_default() with a usage value of 0. */ unsigned int rc_min_quantizer; /*!\brief Maximum (Worst Quality) Quantizer * * The quantizer is the most direct control over the quality of the * encoded image. The range of valid values for the quantizer is codec * specific. Consult the documentation for the codec to determine the * values to use. To determine the range programmatically, call * vpx_codec_enc_config_default() with a usage value of 0. */ unsigned int rc_max_quantizer; /* * bitrate tolerance */ /*!\brief Rate control adaptation undershoot control * * VP8: Expressed as a percentage of the target bitrate, * controls the maximum allowed adaptation speed of the codec. * This factor controls the maximum amount of bits that can * be subtracted from the target bitrate in order to compensate * for prior overshoot. * VP9: Expressed as a percentage of the target bitrate, a threshold * undershoot level (current rate vs target) beyond which more agressive * corrective measures are taken. * * * Valid values in the range VP8:0-1000 VP9: 0-100. */ unsigned int rc_undershoot_pct; /*!\brief Rate control adaptation overshoot control * * VP8: Expressed as a percentage of the target bitrate, * controls the maximum allowed adaptation speed of the codec. * This factor controls the maximum amount of bits that can * be added to the target bitrate in order to compensate for * prior undershoot. * VP9: Expressed as a percentage of the target bitrate, a threshold * overshoot level (current rate vs target) beyond which more agressive * corrective measures are taken. * * Valid values in the range VP8:0-1000 VP9: 0-100. */ unsigned int rc_overshoot_pct; /* * decoder buffer model parameters */ /*!\brief Decoder Buffer Size * * This value indicates the amount of data that may be buffered by the * decoding application. Note that this value is expressed in units of * time (milliseconds). For example, a value of 5000 indicates that the * client will buffer (at least) 5000ms worth of encoded data. Use the * target bitrate (#rc_target_bitrate) to convert to bits/bytes, if * necessary. */ unsigned int rc_buf_sz; /*!\brief Decoder Buffer Initial Size * * This value indicates the amount of data that will be buffered by the * decoding application prior to beginning playback. This value is * expressed in units of time (milliseconds). Use the target bitrate * (#rc_target_bitrate) to convert to bits/bytes, if necessary. */ unsigned int rc_buf_initial_sz; /*!\brief Decoder Buffer Optimal Size * * This value indicates the amount of data that the encoder should try * to maintain in the decoder's buffer. This value is expressed in units * of time (milliseconds). Use the target bitrate (#rc_target_bitrate) * to convert to bits/bytes, if necessary. */ unsigned int rc_buf_optimal_sz; /* * 2 pass rate control parameters */ /*!\brief Two-pass mode CBR/VBR bias * * Bias, expressed on a scale of 0 to 100, for determining target size * for the current frame. The value 0 indicates the optimal CBR mode * value should be used. The value 100 indicates the optimal VBR mode * value should be used. Values in between indicate which way the * encoder should "lean." */ unsigned int rc_2pass_vbr_bias_pct; /*!\brief Two-pass mode per-GOP minimum bitrate * * This value, expressed as a percentage of the target bitrate, indicates * the minimum bitrate to be used for a single GOP (aka "section") */ unsigned int rc_2pass_vbr_minsection_pct; /*!\brief Two-pass mode per-GOP maximum bitrate * * This value, expressed as a percentage of the target bitrate, indicates * the maximum bitrate to be used for a single GOP (aka "section") */ unsigned int rc_2pass_vbr_maxsection_pct; /*!\brief Two-pass corpus vbr mode complexity control * Used only in VP9: A value representing the corpus midpoint complexity * for corpus vbr mode. This value defaults to 0 which disables corpus vbr * mode in favour of normal vbr mode. */ unsigned int rc_2pass_vbr_corpus_complexity; /* * keyframing settings (kf) */ /*!\brief Keyframe placement mode * * This value indicates whether the encoder should place keyframes at a * fixed interval, or determine the optimal placement automatically * (as governed by the #kf_min_dist and #kf_max_dist parameters) */ enum vpx_kf_mode kf_mode; /*!\brief Keyframe minimum interval * * This value, expressed as a number of frames, prevents the encoder from * placing a keyframe nearer than kf_min_dist to the previous keyframe. At * least kf_min_dist frames non-keyframes will be coded before the next * keyframe. Set kf_min_dist equal to kf_max_dist for a fixed interval. */ unsigned int kf_min_dist; /*!\brief Keyframe maximum interval * * This value, expressed as a number of frames, forces the encoder to code * a keyframe if one has not been coded in the last kf_max_dist frames. * A value of 0 implies all frames will be keyframes. Set kf_min_dist * equal to kf_max_dist for a fixed interval. */ unsigned int kf_max_dist; /* * Spatial scalability settings (ss) */ /*!\brief Number of spatial coding layers. * * This value specifies the number of spatial coding layers to be used. */ unsigned int ss_number_layers; /*!\brief Enable auto alt reference flags for each spatial layer. * * These values specify if auto alt reference frame is enabled for each * spatial layer. */ int ss_enable_auto_alt_ref[VPX_SS_MAX_LAYERS]; /*!\brief Target bitrate for each spatial layer. * * These values specify the target coding bitrate to be used for each * spatial layer. */ unsigned int ss_target_bitrate[VPX_SS_MAX_LAYERS]; /*!\brief Number of temporal coding layers. * * This value specifies the number of temporal layers to be used. */ unsigned int ts_number_layers; /*!\brief Target bitrate for each temporal layer. * * These values specify the target coding bitrate to be used for each * temporal layer. */ unsigned int ts_target_bitrate[VPX_TS_MAX_LAYERS]; /*!\brief Frame rate decimation factor for each temporal layer. * * These values specify the frame rate decimation factors to apply * to each temporal layer. */ unsigned int ts_rate_decimator[VPX_TS_MAX_LAYERS]; /*!\brief Length of the sequence defining frame temporal layer membership. * * This value specifies the length of the sequence that defines the * membership of frames to temporal layers. For example, if the * ts_periodicity = 8, then the frames are assigned to coding layers with a * repeated sequence of length 8. */ unsigned int ts_periodicity; /*!\brief Template defining the membership of frames to temporal layers. * * This array defines the membership of frames to temporal coding layers. * For a 2-layer encoding that assigns even numbered frames to one temporal * layer (0) and odd numbered frames to a second temporal layer (1) with * ts_periodicity=8, then ts_layer_id = (0,1,0,1,0,1,0,1). */ unsigned int ts_layer_id[VPX_TS_MAX_PERIODICITY]; /*!\brief Target bitrate for each spatial/temporal layer. * * These values specify the target coding bitrate to be used for each * spatial/temporal layer. * */ unsigned int layer_target_bitrate[VPX_MAX_LAYERS]; /*!\brief Temporal layering mode indicating which temporal layering scheme to * use. * * The value (refer to VP9E_TEMPORAL_LAYERING_MODE) specifies the * temporal layering mode to use. * */ int temporal_layering_mode; } vpx_codec_enc_cfg_t; /**< alias for struct vpx_codec_enc_cfg */ /*!\brief vp9 svc extra configure parameters * * This defines max/min quantizers and scale factors for each layer * */ typedef struct vpx_svc_parameters { int max_quantizers[VPX_MAX_LAYERS]; /**< Max Q for each layer */ int min_quantizers[VPX_MAX_LAYERS]; /**< Min Q for each layer */ int scaling_factor_num[VPX_MAX_LAYERS]; /**< Scaling factor-numerator */ int scaling_factor_den[VPX_MAX_LAYERS]; /**< Scaling factor-denominator */ int speed_per_layer[VPX_MAX_LAYERS]; /**< Speed setting for each sl */ int temporal_layering_mode; /**< Temporal layering mode */ } vpx_svc_extra_cfg_t; /*!\brief Initialize an encoder instance * * Initializes a encoder context using the given interface. Applications * should call the vpx_codec_enc_init convenience macro instead of this * function directly, to ensure that the ABI version number parameter * is properly initialized. * * If the library was configured with --disable-multithread, this call * is not thread safe and should be guarded with a lock if being used * in a multithreaded context. * * \param[in] ctx Pointer to this instance's context. * \param[in] iface Pointer to the algorithm interface to use. * \param[in] cfg Configuration to use, if known. May be NULL. * \param[in] flags Bitfield of VPX_CODEC_USE_* flags * \param[in] ver ABI version number. Must be set to * VPX_ENCODER_ABI_VERSION * \retval #VPX_CODEC_OK * The decoder algorithm initialized. * \retval #VPX_CODEC_MEM_ERROR * Memory allocation failed. */ vpx_codec_err_t vpx_codec_enc_init_ver(vpx_codec_ctx_t *ctx, vpx_codec_iface_t *iface, const vpx_codec_enc_cfg_t *cfg, vpx_codec_flags_t flags, int ver); /*!\brief Convenience macro for vpx_codec_enc_init_ver() * * Ensures the ABI version parameter is properly set. */ #define vpx_codec_enc_init(ctx, iface, cfg, flags) \ vpx_codec_enc_init_ver(ctx, iface, cfg, flags, VPX_ENCODER_ABI_VERSION) /*!\brief Initialize multi-encoder instance * * Initializes multi-encoder context using the given interface. * Applications should call the vpx_codec_enc_init_multi convenience macro * instead of this function directly, to ensure that the ABI version number * parameter is properly initialized. * * \param[in] ctx Pointer to this instance's context. * \param[in] iface Pointer to the algorithm interface to use. * \param[in] cfg Configuration to use, if known. May be NULL. * \param[in] num_enc Total number of encoders. * \param[in] flags Bitfield of VPX_CODEC_USE_* flags * \param[in] dsf Pointer to down-sampling factors. * \param[in] ver ABI version number. Must be set to * VPX_ENCODER_ABI_VERSION * \retval #VPX_CODEC_OK * The decoder algorithm initialized. * \retval #VPX_CODEC_MEM_ERROR * Memory allocation failed. */ vpx_codec_err_t vpx_codec_enc_init_multi_ver( vpx_codec_ctx_t *ctx, vpx_codec_iface_t *iface, vpx_codec_enc_cfg_t *cfg, int num_enc, vpx_codec_flags_t flags, vpx_rational_t *dsf, int ver); /*!\brief Convenience macro for vpx_codec_enc_init_multi_ver() * * Ensures the ABI version parameter is properly set. */ #define vpx_codec_enc_init_multi(ctx, iface, cfg, num_enc, flags, dsf) \ vpx_codec_enc_init_multi_ver(ctx, iface, cfg, num_enc, flags, dsf, \ VPX_ENCODER_ABI_VERSION) /*!\brief Get a default configuration * * Initializes a encoder configuration structure with default values. Supports * the notion of "usages" so that an algorithm may offer different default * settings depending on the user's intended goal. This function \ref SHOULD * be called by all applications to initialize the configuration structure * before specializing the configuration with application specific values. * * \param[in] iface Pointer to the algorithm interface to use. * \param[out] cfg Configuration buffer to populate. * \param[in] reserved Must set to 0 for VP8 and VP9. * * \retval #VPX_CODEC_OK * The configuration was populated. * \retval #VPX_CODEC_INCAPABLE * Interface is not an encoder interface. * \retval #VPX_CODEC_INVALID_PARAM * A parameter was NULL, or the usage value was not recognized. */ vpx_codec_err_t vpx_codec_enc_config_default(vpx_codec_iface_t *iface, vpx_codec_enc_cfg_t *cfg, unsigned int reserved); /*!\brief Set or change configuration * * Reconfigures an encoder instance according to the given configuration. * * \param[in] ctx Pointer to this instance's context * \param[in] cfg Configuration buffer to use * * \retval #VPX_CODEC_OK * The configuration was populated. * \retval #VPX_CODEC_INCAPABLE * Interface is not an encoder interface. * \retval #VPX_CODEC_INVALID_PARAM * A parameter was NULL, or the usage value was not recognized. */ vpx_codec_err_t vpx_codec_enc_config_set(vpx_codec_ctx_t *ctx, const vpx_codec_enc_cfg_t *cfg); /*!\brief Get global stream headers * * Retrieves a stream level global header packet, if supported by the codec. * * \param[in] ctx Pointer to this instance's context * * \retval NULL * Encoder does not support global header * \retval Non-NULL * Pointer to buffer containing global header packet */ vpx_fixed_buf_t *vpx_codec_get_global_headers(vpx_codec_ctx_t *ctx); /*!\brief deadline parameter analogous to VPx REALTIME mode. */ #define VPX_DL_REALTIME (1) /*!\brief deadline parameter analogous to VPx GOOD QUALITY mode. */ #define VPX_DL_GOOD_QUALITY (1000000) /*!\brief deadline parameter analogous to VPx BEST QUALITY mode. */ #define VPX_DL_BEST_QUALITY (0) /*!\brief Encode a frame * * Encodes a video frame at the given "presentation time." The presentation * time stamp (PTS) \ref MUST be strictly increasing. * * The encoder supports the notion of a soft real-time deadline. Given a * non-zero value to the deadline parameter, the encoder will make a "best * effort" guarantee to return before the given time slice expires. It is * implicit that limiting the available time to encode will degrade the * output quality. The encoder can be given an unlimited time to produce the * best possible frame by specifying a deadline of '0'. This deadline * supercedes the VPx notion of "best quality, good quality, realtime". * Applications that wish to map these former settings to the new deadline * based system can use the symbols #VPX_DL_REALTIME, #VPX_DL_GOOD_QUALITY, * and #VPX_DL_BEST_QUALITY. * * When the last frame has been passed to the encoder, this function should * continue to be called, with the img parameter set to NULL. This will * signal the end-of-stream condition to the encoder and allow it to encode * any held buffers. Encoding is complete when vpx_codec_encode() is called * and vpx_codec_get_cx_data() returns no data. * * \param[in] ctx Pointer to this instance's context * \param[in] img Image data to encode, NULL to flush. * \param[in] pts Presentation time stamp, in timebase units. * \param[in] duration Duration to show frame, in timebase units. * \param[in] flags Flags to use for encoding this frame. * \param[in] deadline Time to spend encoding, in microseconds. (0=infinite) * * \retval #VPX_CODEC_OK * The configuration was populated. * \retval #VPX_CODEC_INCAPABLE * Interface is not an encoder interface. * \retval #VPX_CODEC_INVALID_PARAM * A parameter was NULL, the image format is unsupported, etc. */ vpx_codec_err_t vpx_codec_encode(vpx_codec_ctx_t *ctx, const vpx_image_t *img, vpx_codec_pts_t pts, unsigned long duration, vpx_enc_frame_flags_t flags, unsigned long deadline); /*!\brief Set compressed data output buffer * * Sets the buffer that the codec should output the compressed data * into. This call effectively sets the buffer pointer returned in the * next VPX_CODEC_CX_FRAME_PKT packet. Subsequent packets will be * appended into this buffer. The buffer is preserved across frames, * so applications must periodically call this function after flushing * the accumulated compressed data to disk or to the network to reset * the pointer to the buffer's head. * * `pad_before` bytes will be skipped before writing the compressed * data, and `pad_after` bytes will be appended to the packet. The size * of the packet will be the sum of the size of the actual compressed * data, pad_before, and pad_after. The padding bytes will be preserved * (not overwritten). * * Note that calling this function does not guarantee that the returned * compressed data will be placed into the specified buffer. In the * event that the encoded data will not fit into the buffer provided, * the returned packet \ref MAY point to an internal buffer, as it would * if this call were never used. In this event, the output packet will * NOT have any padding, and the application must free space and copy it * to the proper place. This is of particular note in configurations * that may output multiple packets for a single encoded frame (e.g., lagged * encoding) or if the application does not reset the buffer periodically. * * Applications may restore the default behavior of the codec providing * the compressed data buffer by calling this function with a NULL * buffer. * * Applications \ref MUSTNOT call this function during iteration of * vpx_codec_get_cx_data(). * * \param[in] ctx Pointer to this instance's context * \param[in] buf Buffer to store compressed data into * \param[in] pad_before Bytes to skip before writing compressed data * \param[in] pad_after Bytes to skip after writing compressed data * * \retval #VPX_CODEC_OK * The buffer was set successfully. * \retval #VPX_CODEC_INVALID_PARAM * A parameter was NULL, the image format is unsupported, etc. */ vpx_codec_err_t vpx_codec_set_cx_data_buf(vpx_codec_ctx_t *ctx, const vpx_fixed_buf_t *buf, unsigned int pad_before, unsigned int pad_after); /*!\brief Encoded data iterator * * Iterates over a list of data packets to be passed from the encoder to the * application. The different kinds of packets available are enumerated in * #vpx_codec_cx_pkt_kind. * * #VPX_CODEC_CX_FRAME_PKT packets should be passed to the application's * muxer. Multiple compressed frames may be in the list. * #VPX_CODEC_STATS_PKT packets should be appended to a global buffer. * * The application \ref MUST silently ignore any packet kinds that it does * not recognize or support. * * The data buffers returned from this function are only guaranteed to be * valid until the application makes another call to any vpx_codec_* function. * * \param[in] ctx Pointer to this instance's context * \param[in,out] iter Iterator storage, initialized to NULL * * \return Returns a pointer to an output data packet (compressed frame data, * two-pass statistics, etc.) or NULL to signal end-of-list. * */ const vpx_codec_cx_pkt_t *vpx_codec_get_cx_data(vpx_codec_ctx_t *ctx, vpx_codec_iter_t *iter); /*!\brief Get Preview Frame * * Returns an image that can be used as a preview. Shows the image as it would * exist at the decompressor. The application \ref MUST NOT write into this * image buffer. * * \param[in] ctx Pointer to this instance's context * * \return Returns a pointer to a preview image, or NULL if no image is * available. * */ const vpx_image_t *vpx_codec_get_preview_frame(vpx_codec_ctx_t *ctx); /*!@} - end defgroup encoder*/ #ifdef __cplusplus } #endif #endif // VPX_VPX_VPX_ENCODER_H_