/* GStreamer * Copyright (C) 2015 Intel Corporation * Author: Sreerenj Balachandran * Copyright (C) 2019 Seungha Yang * * This library is free software; you can redistribute it and/or * modify it under the terms of the GNU Library General Public * License as published by the Free Software Foundation; either * version 2 of the License, or (at your option) any later version. * * This library is distributed in the hope that it will be useful, * but WITHOUT ANY WARRANTY; without even the implied warranty of * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU * Library General Public License for more details. * * You should have received a copy of the GNU Library General Public * License along with this library; if not, write to the * Free Software Foundation, Inc., 51 Franklin St, Fifth Floor, * Boston, MA 02110-1301, USA. */ /** * SECTION:gsth265decoder * @title: GstH265Decoder * @short_description: Base class to implement stateless H.265 decoders * @sources: * - gsth265picture.h */ #ifdef HAVE_CONFIG_H #include #endif #include #include "gsth265decoder.h" GST_DEBUG_CATEGORY (gst_h265_decoder_debug); #define GST_CAT_DEFAULT gst_h265_decoder_debug typedef enum { GST_H265_DECODER_FORMAT_NONE, GST_H265_DECODER_FORMAT_HVC1, GST_H265_DECODER_FORMAT_HEV1, GST_H265_DECODER_FORMAT_BYTE } GstH265DecoderFormat; typedef enum { GST_H265_DECODER_ALIGN_NONE, GST_H265_DECODER_ALIGN_NAL, GST_H265_DECODER_ALIGN_AU } GstH265DecoderAlign; struct _GstH265DecoderPrivate { gint width, height; guint8 conformance_window_flag; gint crop_rect_width; gint crop_rect_height; gint crop_rect_x; gint crop_rect_y; guint nal_length_size; /* state */ GstH265DecoderFormat in_format; GstH265DecoderAlign align; GstH265Parser *parser; GstH265Dpb *dpb; /* 0: frame or field-pair interlaced stream * 1: alternating, single field interlaced stream. * When equal to 1, picture timing SEI shall be present in every AU */ guint8 field_seq_flag; guint8 progressive_source_flag; guint8 interlaced_source_flag; /* Updated/cleared per handle_frame() by using picture timeing SEI */ GstH265SEIPicStructType cur_pic_struct; guint8 cur_source_scan_type; guint8 cur_duplicate_flag; gboolean no_output_of_prior_pics_flag; /* vps/sps/pps of the current slice */ const GstH265VPS *active_vps; const GstH265SPS *active_sps; const GstH265PPS *active_pps; guint32 SpsMaxLatencyPictures; /* Picture currently being processed/decoded */ GstH265Picture *current_picture; GstVideoCodecFrame *current_frame; /* Slice (slice header + nalu) currently being processed/decoded */ GstH265Slice current_slice; GstH265Slice prev_slice; GstH265Slice prev_independent_slice; gint32 poc; // PicOrderCntVal gint32 poc_msb; // PicOrderCntMsb gint32 poc_lsb; // pic_order_cnt_lsb (from slice_header()) gint32 prev_poc_msb; // prevPicOrderCntMsb gint32 prev_poc_lsb; // prevPicOrderCntLsb gint32 prev_tid0pic_poc_lsb; gint32 prev_tid0pic_poc_msb; gint32 PocStCurrBefore[16]; gint32 PocStCurrAfter[16]; gint32 PocStFoll[16]; gint32 PocLtCurr[16]; gint32 PocLtFoll[16]; /* PicOrderCount of the previously outputted frame */ gint last_output_poc; gboolean associated_irap_NoRaslOutputFlag; gboolean new_bitstream; gboolean prev_nal_is_eos; /* Reference picture lists, constructed for each slice */ gboolean process_ref_pic_lists; GArray *ref_pic_list_tmp; GArray *ref_pic_list0; GArray *ref_pic_list1; GArray *nalu; /* Split packetized data into actual nal chunks (for malformed stream) */ GArray *split_nalu; /* For delayed output */ guint preferred_output_delay; gboolean is_live; GstQueueArray *output_queue; gboolean input_state_changed; }; typedef struct { union { GstH265SPS sps; GstH265Slice slice; } unit; gboolean is_slice; } GstH265DecoderNalUnit; typedef struct { /* Holds ref */ GstVideoCodecFrame *frame; GstH265Picture *picture; /* Without ref */ GstH265Decoder *self; } GstH265DecoderOutputFrame; #define UPDATE_FLOW_RETURN(ret,new_ret) G_STMT_START { \ if (*(ret) == GST_FLOW_OK) \ *(ret) = new_ret; \ } G_STMT_END #define parent_class gst_h265_decoder_parent_class G_DEFINE_ABSTRACT_TYPE_WITH_CODE (GstH265Decoder, gst_h265_decoder, GST_TYPE_VIDEO_DECODER, G_ADD_PRIVATE (GstH265Decoder); GST_DEBUG_CATEGORY_INIT (gst_h265_decoder_debug, "h265decoder", 0, "H.265 Video Decoder")); static void gst_h265_decoder_finalize (GObject * object); static gboolean gst_h265_decoder_start (GstVideoDecoder * decoder); static gboolean gst_h265_decoder_stop (GstVideoDecoder * decoder); static gboolean gst_h265_decoder_set_format (GstVideoDecoder * decoder, GstVideoCodecState * state); static gboolean gst_h265_decoder_negotiate (GstVideoDecoder * decoder); static GstFlowReturn gst_h265_decoder_finish (GstVideoDecoder * decoder); static gboolean gst_h265_decoder_flush (GstVideoDecoder * decoder); static GstFlowReturn gst_h265_decoder_drain (GstVideoDecoder * decoder); static GstFlowReturn gst_h265_decoder_handle_frame (GstVideoDecoder * decoder, GstVideoCodecFrame * frame); static void gst_h265_decoder_finish_current_picture (GstH265Decoder * self, GstFlowReturn * ret); static void gst_h265_decoder_clear_ref_pic_sets (GstH265Decoder * self); static void gst_h265_decoder_clear_dpb (GstH265Decoder * self, gboolean flush); static GstFlowReturn gst_h265_decoder_drain_internal (GstH265Decoder * self); static GstFlowReturn gst_h265_decoder_start_current_picture (GstH265Decoder * self); static void gst_h265_decoder_clear_nalu (GstH265DecoderNalUnit * nalu); static void gst_h265_decoder_clear_output_frame (GstH265DecoderOutputFrame * output_frame); static void gst_h265_decoder_class_init (GstH265DecoderClass * klass) { GstVideoDecoderClass *decoder_class = GST_VIDEO_DECODER_CLASS (klass); GObjectClass *object_class = G_OBJECT_CLASS (klass); object_class->finalize = GST_DEBUG_FUNCPTR (gst_h265_decoder_finalize); decoder_class->start = GST_DEBUG_FUNCPTR (gst_h265_decoder_start); decoder_class->stop = GST_DEBUG_FUNCPTR (gst_h265_decoder_stop); decoder_class->set_format = GST_DEBUG_FUNCPTR (gst_h265_decoder_set_format); decoder_class->negotiate = GST_DEBUG_FUNCPTR (gst_h265_decoder_negotiate); decoder_class->finish = GST_DEBUG_FUNCPTR (gst_h265_decoder_finish); decoder_class->flush = GST_DEBUG_FUNCPTR (gst_h265_decoder_flush); decoder_class->drain = GST_DEBUG_FUNCPTR (gst_h265_decoder_drain); decoder_class->handle_frame = GST_DEBUG_FUNCPTR (gst_h265_decoder_handle_frame); } static void gst_h265_decoder_init (GstH265Decoder * self) { GstH265DecoderPrivate *priv; gst_video_decoder_set_packetized (GST_VIDEO_DECODER (self), TRUE); gst_video_decoder_set_needs_format (GST_VIDEO_DECODER (self), TRUE); self->priv = priv = gst_h265_decoder_get_instance_private (self); priv->last_output_poc = G_MININT32; priv->ref_pic_list_tmp = g_array_sized_new (FALSE, TRUE, sizeof (GstH265Picture *), 32); priv->ref_pic_list0 = g_array_sized_new (FALSE, TRUE, sizeof (GstH265Picture *), 32); priv->ref_pic_list1 = g_array_sized_new (FALSE, TRUE, sizeof (GstH265Picture *), 32); priv->nalu = g_array_sized_new (FALSE, TRUE, sizeof (GstH265DecoderNalUnit), 8); priv->split_nalu = g_array_new (FALSE, FALSE, sizeof (GstH265NalUnit)); g_array_set_clear_func (priv->nalu, (GDestroyNotify) gst_h265_decoder_clear_nalu); priv->output_queue = gst_queue_array_new_for_struct (sizeof (GstH265DecoderOutputFrame), 1); gst_queue_array_set_clear_func (priv->output_queue, (GDestroyNotify) gst_h265_decoder_clear_output_frame); } static void gst_h265_decoder_finalize (GObject * object) { GstH265Decoder *self = GST_H265_DECODER (object); GstH265DecoderPrivate *priv = self->priv; g_array_unref (priv->ref_pic_list_tmp); g_array_unref (priv->ref_pic_list0); g_array_unref (priv->ref_pic_list1); g_array_unref (priv->nalu); g_array_unref (priv->split_nalu); gst_queue_array_free (priv->output_queue); G_OBJECT_CLASS (parent_class)->finalize (object); } static gboolean gst_h265_decoder_start (GstVideoDecoder * decoder) { GstH265Decoder *self = GST_H265_DECODER (decoder); GstH265DecoderPrivate *priv = self->priv; priv->parser = gst_h265_parser_new (); priv->dpb = gst_h265_dpb_new (); priv->new_bitstream = TRUE; priv->prev_nal_is_eos = FALSE; return TRUE; } static gboolean gst_h265_decoder_stop (GstVideoDecoder * decoder) { GstH265Decoder *self = GST_H265_DECODER (decoder); GstH265DecoderPrivate *priv = self->priv; if (self->input_state) { gst_video_codec_state_unref (self->input_state); self->input_state = NULL; } if (priv->parser) { gst_h265_parser_free (priv->parser); priv->parser = NULL; } if (priv->dpb) { gst_h265_dpb_free (priv->dpb); priv->dpb = NULL; } gst_h265_decoder_clear_ref_pic_sets (self); return TRUE; } static void gst_h265_decoder_clear_output_frame (GstH265DecoderOutputFrame * output_frame) { if (!output_frame) return; if (output_frame->frame) { gst_video_decoder_release_frame (GST_VIDEO_DECODER (output_frame->self), output_frame->frame); output_frame->frame = NULL; } gst_clear_h265_picture (&output_frame->picture); } static gboolean gst_h265_decoder_is_crop_rect_changed (GstH265Decoder * self, GstH265SPS * sps) { GstH265DecoderPrivate *priv = self->priv; if (priv->conformance_window_flag != sps->conformance_window_flag) return TRUE; if (priv->crop_rect_width != sps->crop_rect_width) return TRUE; if (priv->crop_rect_height != sps->crop_rect_height) return TRUE; if (priv->crop_rect_x != sps->crop_rect_x) return TRUE; if (priv->crop_rect_y != sps->crop_rect_y) return TRUE; return FALSE; } static void gst_h265_decoder_drain_output_queue (GstH265Decoder * self, guint num, GstFlowReturn * ret) { GstH265DecoderPrivate *priv = self->priv; GstH265DecoderClass *klass = GST_H265_DECODER_GET_CLASS (self); g_assert (klass->output_picture); g_assert (ret != NULL); while (gst_queue_array_get_length (priv->output_queue) > num) { GstH265DecoderOutputFrame *output_frame = (GstH265DecoderOutputFrame *) gst_queue_array_pop_head_struct (priv->output_queue); GstFlowReturn flow_ret = klass->output_picture (self, output_frame->frame, output_frame->picture); UPDATE_FLOW_RETURN (ret, flow_ret); } } static void gst_h265_decoder_set_latency (GstH265Decoder * self, const GstH265SPS * sps, gint max_dpb_size) { GstH265DecoderPrivate *priv = self->priv; GstCaps *caps; GstClockTime min, max; GstStructure *structure; gint fps_d = 1, fps_n = 0; guint frames_delay; caps = gst_pad_get_current_caps (GST_VIDEO_DECODER_SRC_PAD (self)); if (!caps && self->input_state) caps = gst_caps_ref (self->input_state->caps); if (caps) { structure = gst_caps_get_structure (caps, 0); if (gst_structure_get_fraction (structure, "framerate", &fps_n, &fps_d)) { if (fps_n == 0) { /* variable framerate: see if we have a max-framerate */ gst_structure_get_fraction (structure, "max-framerate", &fps_n, &fps_d); } } gst_caps_unref (caps); } /* if no fps or variable, then 25/1 */ if (fps_n == 0) { fps_n = 25; fps_d = 1; } /* Minimum possible latency could be calculated based on C.5.2.3 * 1) # of pictures (marked as "needed for output") in DPB > sps_max_num_reorder_pics * - We will assume all pictures in DPB are marked as "needed for output" * 2) sps_max_latency_increase_plus1 != 0 and * PicLatencyCount >= SpsMaxLatencyPictures * - SpsMaxLatencyPictures is equal to * "sps_max_num_reorder_pics + sps_max_latency_increase_plus1 - 1" * and PicLatencyCount of each picture in DPB is increased by 1 per * decoding loop. Note that PicLatencyCount of the currently decoded * picture is zero. So, in case that all pictures in DPB are marked as * "needed for output", Only condition 1) will have an effect * regardless of sps_max_latency_increase_plus1. * * For example, assume sps_max_num_reorder_pics is 2 and * sps_max_latency_increase_plus1 is 1, then SpsMaxLatencyPictures is 2. * For a picture in DPB to have PicLatencyCount >= SpsMaxLatencyPictures, * there must be at least 3 pictures including current picture in DPB * (current picture's PicLatencyCount is zero). * This is already covered by the condition 1). So, this condition 2) * will have effect only when there are pictures marked as * "not needed for output" in DPB. * * Thus, we can take sps_max_num_reorder_pics as a min latency value */ frames_delay = sps->max_num_reorder_pics[sps->max_sub_layers_minus1]; /* Consider output delay wanted by subclass */ frames_delay += priv->preferred_output_delay; min = gst_util_uint64_scale_int (frames_delay * GST_SECOND, fps_d, fps_n); max = gst_util_uint64_scale_int ((max_dpb_size + priv->preferred_output_delay) * GST_SECOND, fps_d, fps_n); GST_DEBUG_OBJECT (self, "latency min %" GST_TIME_FORMAT " max %" GST_TIME_FORMAT " min-frames-delay %d", GST_TIME_ARGS (min), GST_TIME_ARGS (max), frames_delay); gst_video_decoder_set_latency (GST_VIDEO_DECODER (self), min, max); } static GstFlowReturn gst_h265_decoder_process_sps (GstH265Decoder * self, GstH265SPS * sps) { GstH265DecoderPrivate *priv = self->priv; gint max_dpb_size; gint prev_max_dpb_size; gint MaxLumaPS; const gint MaxDpbPicBuf = 6; gint PicSizeInSamplesY; guint8 field_seq_flag = 0; guint8 progressive_source_flag = 0; guint8 interlaced_source_flag = 0; GstFlowReturn ret = GST_FLOW_OK; /* A.4.1 */ MaxLumaPS = 35651584; PicSizeInSamplesY = sps->width * sps->height; if (PicSizeInSamplesY <= (MaxLumaPS >> 2)) max_dpb_size = MaxDpbPicBuf * 4; else if (PicSizeInSamplesY <= (MaxLumaPS >> 1)) max_dpb_size = MaxDpbPicBuf * 2; else if (PicSizeInSamplesY <= ((3 * MaxLumaPS) >> 2)) max_dpb_size = (MaxDpbPicBuf * 4) / 3; else max_dpb_size = MaxDpbPicBuf; max_dpb_size = MIN (max_dpb_size, 16); if (sps->vui_parameters_present_flag) field_seq_flag = sps->vui_params.field_seq_flag; progressive_source_flag = sps->profile_tier_level.progressive_source_flag; interlaced_source_flag = sps->profile_tier_level.interlaced_source_flag; prev_max_dpb_size = gst_h265_dpb_get_max_num_pics (priv->dpb); if (priv->width != sps->width || priv->height != sps->height || prev_max_dpb_size != max_dpb_size || priv->field_seq_flag != field_seq_flag || priv->progressive_source_flag != progressive_source_flag || priv->interlaced_source_flag != interlaced_source_flag || gst_h265_decoder_is_crop_rect_changed (self, sps)) { GstH265DecoderClass *klass = GST_H265_DECODER_GET_CLASS (self); GST_DEBUG_OBJECT (self, "SPS updated, resolution: %dx%d -> %dx%d, dpb size: %d -> %d, " "field_seq_flag: %d -> %d, progressive_source_flag: %d -> %d, " "interlaced_source_flag: %d -> %d", priv->width, priv->height, sps->width, sps->height, prev_max_dpb_size, max_dpb_size, priv->field_seq_flag, field_seq_flag, priv->progressive_source_flag, progressive_source_flag, priv->interlaced_source_flag, interlaced_source_flag); if (priv->no_output_of_prior_pics_flag) { gst_h265_decoder_drain_output_queue (self, 0, &ret); gst_h265_decoder_clear_dpb (self, FALSE); } else { ret = gst_h265_decoder_drain_internal (self); } if (ret != GST_FLOW_OK) return ret; if (klass->get_preferred_output_delay) { priv->preferred_output_delay = klass->get_preferred_output_delay (self, priv->is_live); } else { priv->preferred_output_delay = 0; } g_assert (klass->new_sequence); ret = klass->new_sequence (self, sps, max_dpb_size + priv->preferred_output_delay); if (ret != GST_FLOW_OK) { GST_WARNING_OBJECT (self, "subclass does not want accept new sequence"); return ret; } priv->width = sps->width; priv->height = sps->height; priv->conformance_window_flag = sps->conformance_window_flag; priv->crop_rect_width = sps->crop_rect_width; priv->crop_rect_height = sps->crop_rect_height; priv->crop_rect_x = sps->crop_rect_x; priv->crop_rect_y = sps->crop_rect_y; priv->field_seq_flag = field_seq_flag; priv->progressive_source_flag = progressive_source_flag; priv->interlaced_source_flag = interlaced_source_flag; gst_h265_dpb_set_max_num_pics (priv->dpb, max_dpb_size); gst_h265_decoder_set_latency (self, sps, max_dpb_size); GST_DEBUG_OBJECT (self, "Set DPB max size %d", max_dpb_size); } if (sps->max_latency_increase_plus1[sps->max_sub_layers_minus1]) { priv->SpsMaxLatencyPictures = sps->max_num_reorder_pics[sps->max_sub_layers_minus1] + sps->max_latency_increase_plus1[sps->max_sub_layers_minus1] - 1; } else { priv->SpsMaxLatencyPictures = 0; } return GST_FLOW_OK; } static GstH265ParserResult gst_h265_decoder_parse_sei (GstH265Decoder * self, GstH265NalUnit * nalu) { GstH265DecoderPrivate *priv = self->priv; GstH265ParserResult pres; GArray *messages = NULL; guint i; pres = gst_h265_parser_parse_sei (priv->parser, nalu, &messages); if (pres != GST_H265_PARSER_OK) { GST_WARNING_OBJECT (self, "Failed to parse SEI, result %d", pres); /* XXX: Ignore error from SEI parsing, it might be malformed bitstream, * or our fault. But shouldn't be critical */ g_clear_pointer (&messages, g_array_unref); return GST_H265_PARSER_OK; } for (i = 0; i < messages->len; i++) { GstH265SEIMessage *sei = &g_array_index (messages, GstH265SEIMessage, i); switch (sei->payloadType) { case GST_H265_SEI_PIC_TIMING: priv->cur_pic_struct = sei->payload.pic_timing.pic_struct; priv->cur_source_scan_type = sei->payload.pic_timing.source_scan_type; priv->cur_duplicate_flag = sei->payload.pic_timing.duplicate_flag; GST_TRACE_OBJECT (self, "Picture Timing SEI, pic_struct: %d, source_scan_type: %d, " "duplicate_flag: %d", priv->cur_pic_struct, priv->cur_source_scan_type, priv->cur_duplicate_flag); break; default: break; } } g_array_free (messages, TRUE); GST_LOG_OBJECT (self, "SEI parsed"); return GST_H265_PARSER_OK; } static void gst_h265_decoder_process_ref_pic_lists (GstH265Decoder * self, GstH265Picture * curr_pic, GstH265Slice * slice, GArray ** ref_pic_list0, GArray ** ref_pic_list1) { GstH265DecoderPrivate *priv = self->priv; GstH265RefPicListModification *ref_mod = &slice->header.ref_pic_list_modification; GstH265PPSSccExtensionParams *scc_ext = &slice->header.pps->pps_scc_extension_params; GArray *tmp_refs; gint num_tmp_refs, i; *ref_pic_list0 = priv->ref_pic_list0; *ref_pic_list1 = priv->ref_pic_list1; /* There is nothing to be done for I slices */ if (GST_H265_IS_I_SLICE (&slice->header)) return; /* Infinite loop prevention */ if (self->NumPocStCurrBefore == 0 && self->NumPocStCurrAfter == 0 && self->NumPocLtCurr == 0 && !scc_ext->pps_curr_pic_ref_enabled_flag) { GST_WARNING_OBJECT (self, "Expected references, got none, preventing infinite loop."); return; } /* 8.3.4 Deriving l0 */ tmp_refs = priv->ref_pic_list_tmp; /* (8-8) * Deriving l0 consists of appending in loop RefPicSetStCurrBefore, * RefPicSetStCurrAfter and RefPicSetLtCurr until NumRpsCurrTempList0 item * has been reached. */ /* NumRpsCurrTempList0 */ num_tmp_refs = MAX (slice->header.num_ref_idx_l0_active_minus1 + 1, self->NumPicTotalCurr); while (tmp_refs->len < num_tmp_refs) { for (i = 0; i < self->NumPocStCurrBefore && tmp_refs->len < num_tmp_refs; i++) g_array_append_val (tmp_refs, self->RefPicSetStCurrBefore[i]); for (i = 0; i < self->NumPocStCurrAfter && tmp_refs->len < num_tmp_refs; i++) g_array_append_val (tmp_refs, self->RefPicSetStCurrAfter[i]); for (i = 0; i < self->NumPocLtCurr && tmp_refs->len < num_tmp_refs; i++) g_array_append_val (tmp_refs, self->RefPicSetLtCurr[i]); if (scc_ext->pps_curr_pic_ref_enabled_flag) g_array_append_val (tmp_refs, curr_pic); } /* (8-9) * If needed, apply the modification based on the lookup table found in the * slice header (list_entry_l0). */ for (i = 0; i <= slice->header.num_ref_idx_l0_active_minus1; i++) { GstH265Picture **tmp = (GstH265Picture **) tmp_refs->data; if (ref_mod->ref_pic_list_modification_flag_l0) g_array_append_val (*ref_pic_list0, tmp[ref_mod->list_entry_l0[i]]); else g_array_append_val (*ref_pic_list0, tmp[i]); } if (scc_ext->pps_curr_pic_ref_enabled_flag && !ref_mod->ref_pic_list_modification_flag_l0 && num_tmp_refs > (slice->header.num_ref_idx_l0_active_minus1 + 1)) { g_array_index (*ref_pic_list0, GstH265Picture *, slice->header.num_ref_idx_l0_active_minus1) = curr_pic; } g_array_set_size (tmp_refs, 0); /* For P slices we only need l0 */ if (GST_H265_IS_P_SLICE (&slice->header)) return; /* 8.3.4 Deriving l1 */ /* (8-10) * Deriving l1 consists of appending in loop RefPicSetStCurrAfter, * RefPicSetStCurrBefore and RefPicSetLtCurr until NumRpsCurrTempList1 items * has been reached. */ /* NumRpsCurrTempList1 */ num_tmp_refs = MAX (slice->header.num_ref_idx_l1_active_minus1 + 1, self->NumPicTotalCurr); while (tmp_refs->len < num_tmp_refs) { for (i = 0; i < self->NumPocStCurrAfter && tmp_refs->len < num_tmp_refs; i++) g_array_append_val (tmp_refs, self->RefPicSetStCurrAfter[i]); for (i = 0; i < self->NumPocStCurrBefore && tmp_refs->len < num_tmp_refs; i++) g_array_append_val (tmp_refs, self->RefPicSetStCurrBefore[i]); for (i = 0; i < self->NumPocLtCurr && tmp_refs->len < num_tmp_refs; i++) g_array_append_val (tmp_refs, self->RefPicSetLtCurr[i]); if (scc_ext->pps_curr_pic_ref_enabled_flag) g_array_append_val (tmp_refs, curr_pic); } /* (8-11) * If needed, apply the modification based on the lookup table found in the * slice header (list_entry_l1). */ for (i = 0; i <= slice->header.num_ref_idx_l1_active_minus1; i++) { GstH265Picture **tmp = (GstH265Picture **) tmp_refs->data; if (ref_mod->ref_pic_list_modification_flag_l1) g_array_append_val (*ref_pic_list1, tmp[ref_mod->list_entry_l1[i]]); else g_array_append_val (*ref_pic_list1, tmp[i]); } g_array_set_size (tmp_refs, 0); } static GstFlowReturn gst_h265_decoder_decode_slice (GstH265Decoder * self) { GstH265DecoderClass *klass = GST_H265_DECODER_GET_CLASS (self); GstH265DecoderPrivate *priv = self->priv; GstH265Slice *slice = &priv->current_slice; GstH265Picture *picture = priv->current_picture; GArray *l0 = NULL; GArray *l1 = NULL; GstFlowReturn ret = GST_FLOW_OK; if (!picture) { GST_ERROR_OBJECT (self, "No current picture"); return GST_FLOW_ERROR; } g_assert (klass->decode_slice); if (priv->process_ref_pic_lists) { l0 = priv->ref_pic_list0; l1 = priv->ref_pic_list1; gst_h265_decoder_process_ref_pic_lists (self, picture, slice, &l0, &l1); } ret = klass->decode_slice (self, picture, slice, l0, l1); if (priv->process_ref_pic_lists) { g_array_set_size (l0, 0); g_array_set_size (l1, 0); } return ret; } static GstFlowReturn gst_h265_decoder_preprocess_slice (GstH265Decoder * self, GstH265Slice * slice) { GstH265DecoderPrivate *priv = self->priv; const GstH265SliceHdr *slice_hdr = &slice->header; if (priv->current_picture && slice_hdr->first_slice_segment_in_pic_flag) { GST_WARNING_OBJECT (self, "Current picture is not finished but slice header has " "first_slice_segment_in_pic_flag"); return GST_FLOW_ERROR; } return GST_FLOW_OK; } static GstFlowReturn gst_h265_decoder_process_slice (GstH265Decoder * self, GstH265Slice * slice) { GstH265DecoderPrivate *priv = self->priv; GstFlowReturn ret = GST_FLOW_OK; priv->current_slice = *slice; if (priv->current_slice.header.dependent_slice_segment_flag) { GstH265SliceHdr *slice_hdr = &priv->current_slice.header; GstH265SliceHdr *indep_slice_hdr = &priv->prev_independent_slice.header; memcpy (&slice_hdr->type, &indep_slice_hdr->type, G_STRUCT_OFFSET (GstH265SliceHdr, num_entry_point_offsets) - G_STRUCT_OFFSET (GstH265SliceHdr, type)); } else { priv->prev_independent_slice = priv->current_slice; memset (&priv->prev_independent_slice.nalu, 0, sizeof (GstH265NalUnit)); } ret = gst_h265_decoder_preprocess_slice (self, &priv->current_slice); if (ret != GST_FLOW_OK) return ret; /* The used SPS may not be the latest parsed one, make * sure we have updated it before decode the frame */ ret = gst_h265_decoder_process_sps (self, priv->current_slice.header.pps->sps); if (ret != GST_FLOW_OK) { GST_WARNING_OBJECT (self, "Failed to process sps"); return ret; } priv->active_pps = priv->current_slice.header.pps; priv->active_sps = priv->active_pps->sps; if (!priv->current_picture) { GstH265DecoderClass *klass = GST_H265_DECODER_GET_CLASS (self); GstH265Picture *picture; GstFlowReturn ret = GST_FLOW_OK; g_assert (priv->current_frame); picture = gst_h265_picture_new (); /* This allows accessing the frame from the picture. */ picture->system_frame_number = priv->current_frame->system_frame_number; priv->current_picture = picture; if (klass->new_picture) ret = klass->new_picture (self, priv->current_frame, picture); if (ret != GST_FLOW_OK) { GST_WARNING_OBJECT (self, "subclass does not want accept new picture"); priv->current_picture = NULL; gst_h265_picture_unref (picture); return ret; } ret = gst_h265_decoder_start_current_picture (self); if (ret != GST_FLOW_OK) { GST_WARNING_OBJECT (self, "start picture failed"); return ret; } /* this picture was dropped */ if (!priv->current_picture) return GST_FLOW_OK; } return gst_h265_decoder_decode_slice (self); } static GstH265ParserResult gst_h265_decoder_parse_slice (GstH265Decoder * self, GstH265NalUnit * nalu) { GstH265DecoderPrivate *priv = self->priv; GstH265ParserResult pres; GstH265Slice slice; GstH265DecoderNalUnit decoder_nalu; memset (&slice, 0, sizeof (GstH265Slice)); pres = gst_h265_parser_parse_slice_hdr (priv->parser, nalu, &slice.header); if (pres != GST_H265_PARSER_OK) return pres; /* NOTE: gst_h265_parser_parse_slice_hdr() allocates array * GstH265SliceHdr::entry_point_offset_minus1 but we don't use it * in this h265decoder baseclass at the moment */ gst_h265_slice_hdr_free (&slice.header); slice.nalu = *nalu; if (nalu->type >= GST_H265_NAL_SLICE_BLA_W_LP && nalu->type <= GST_H265_NAL_SLICE_CRA_NUT) { slice.rap_pic_flag = TRUE; } /* NoRaslOutputFlag == 1 if the current picture is * 1) an IDR picture * 2) a BLA picture * 3) a CRA picture that is the first access unit in the bitstream * 4) first picture that follows an end of sequence NAL unit in decoding order * 5) has HandleCraAsBlaFlag == 1 (set by external means, so not considering ) */ if (GST_H265_IS_NAL_TYPE_IDR (nalu->type) || GST_H265_IS_NAL_TYPE_BLA (nalu->type) || (GST_H265_IS_NAL_TYPE_CRA (nalu->type) && priv->new_bitstream) || priv->prev_nal_is_eos) { slice.no_rasl_output_flag = TRUE; } if (GST_H265_IS_NAL_TYPE_IRAP (nalu->type)) { slice.intra_pic_flag = TRUE; if (slice.no_rasl_output_flag && !priv->new_bitstream) { /* C 3.2 */ slice.clear_dpb = TRUE; if (nalu->type == GST_H265_NAL_SLICE_CRA_NUT) { slice.no_output_of_prior_pics_flag = TRUE; } else { slice.no_output_of_prior_pics_flag = slice.header.no_output_of_prior_pics_flag; } } } if (slice.no_output_of_prior_pics_flag) priv->no_output_of_prior_pics_flag = TRUE; decoder_nalu.unit.slice = slice; decoder_nalu.is_slice = TRUE; g_array_append_val (priv->nalu, decoder_nalu); return GST_H265_PARSER_OK; } static GstH265ParserResult gst_h265_decoder_parse_nalu (GstH265Decoder * self, GstH265NalUnit * nalu) { GstH265DecoderPrivate *priv = self->priv; GstH265VPS vps; GstH265SPS sps; GstH265PPS pps; GstH265ParserResult ret = GST_H265_PARSER_OK; GstH265DecoderNalUnit decoder_nalu; GST_LOG_OBJECT (self, "Parsed nal type: %d, offset %d, size %d", nalu->type, nalu->offset, nalu->size); switch (nalu->type) { case GST_H265_NAL_VPS: ret = gst_h265_parser_parse_vps (priv->parser, nalu, &vps); break; case GST_H265_NAL_SPS: ret = gst_h265_parser_parse_sps (priv->parser, nalu, &sps, TRUE); if (ret != GST_H265_PARSER_OK) break; memset (&decoder_nalu, 0, sizeof (GstH265DecoderNalUnit)); decoder_nalu.unit.sps = sps; g_array_append_val (priv->nalu, decoder_nalu); break; case GST_H265_NAL_PPS: ret = gst_h265_parser_parse_pps (priv->parser, nalu, &pps); break; case GST_H265_NAL_PREFIX_SEI: case GST_H265_NAL_SUFFIX_SEI: ret = gst_h265_decoder_parse_sei (self, nalu); break; case GST_H265_NAL_SLICE_TRAIL_N: case GST_H265_NAL_SLICE_TRAIL_R: case GST_H265_NAL_SLICE_TSA_N: case GST_H265_NAL_SLICE_TSA_R: case GST_H265_NAL_SLICE_STSA_N: case GST_H265_NAL_SLICE_STSA_R: case GST_H265_NAL_SLICE_RADL_N: case GST_H265_NAL_SLICE_RADL_R: case GST_H265_NAL_SLICE_RASL_N: case GST_H265_NAL_SLICE_RASL_R: case GST_H265_NAL_SLICE_BLA_W_LP: case GST_H265_NAL_SLICE_BLA_W_RADL: case GST_H265_NAL_SLICE_BLA_N_LP: case GST_H265_NAL_SLICE_IDR_W_RADL: case GST_H265_NAL_SLICE_IDR_N_LP: case GST_H265_NAL_SLICE_CRA_NUT: ret = gst_h265_decoder_parse_slice (self, nalu); priv->new_bitstream = FALSE; priv->prev_nal_is_eos = FALSE; break; case GST_H265_NAL_EOB: priv->new_bitstream = TRUE; break; case GST_H265_NAL_EOS: priv->prev_nal_is_eos = TRUE; break; default: break; } return ret; } static GstFlowReturn gst_h265_decoder_decode_nalu (GstH265Decoder * self, GstH265DecoderNalUnit * nalu) { if (nalu->is_slice) return gst_h265_decoder_process_slice (self, &nalu->unit.slice); return GST_FLOW_OK; } static void gst_h265_decoder_format_from_caps (GstH265Decoder * self, GstCaps * caps, GstH265DecoderFormat * format, GstH265DecoderAlign * align) { if (format) *format = GST_H265_DECODER_FORMAT_NONE; if (align) *align = GST_H265_DECODER_ALIGN_NONE; if (!gst_caps_is_fixed (caps)) { GST_WARNING_OBJECT (self, "Caps wasn't fixed"); return; } GST_DEBUG_OBJECT (self, "parsing caps: %" GST_PTR_FORMAT, caps); if (caps && gst_caps_get_size (caps) > 0) { GstStructure *s = gst_caps_get_structure (caps, 0); const gchar *str = NULL; if (format) { if ((str = gst_structure_get_string (s, "stream-format"))) { if (strcmp (str, "hvc1") == 0) *format = GST_H265_DECODER_FORMAT_HVC1; else if (strcmp (str, "hev1") == 0) *format = GST_H265_DECODER_FORMAT_HEV1; else if (strcmp (str, "byte-stream") == 0) *format = GST_H265_DECODER_FORMAT_BYTE; } } if (align) { if ((str = gst_structure_get_string (s, "alignment"))) { if (strcmp (str, "au") == 0) *align = GST_H265_DECODER_ALIGN_AU; else if (strcmp (str, "nal") == 0) *align = GST_H265_DECODER_ALIGN_NAL; } } } } static GstFlowReturn gst_h265_decoder_parse_codec_data (GstH265Decoder * self, const guint8 * data, gsize size) { GstH265DecoderPrivate *priv = self->priv; guint num_nal_arrays; guint off; guint num_nals, i, j; GstH265ParserResult pres; GstH265NalUnit nalu; GstH265VPS vps; GstH265SPS sps; GstH265PPS pps; /* parse the hvcC data */ if (size < 23) { GST_WARNING_OBJECT (self, "hvcC too small"); return GST_FLOW_ERROR; } /* wrong hvcC version */ if (data[0] != 0 && data[0] != 1) { return GST_FLOW_ERROR; } priv->nal_length_size = (data[21] & 0x03) + 1; GST_DEBUG_OBJECT (self, "nal length size %u", priv->nal_length_size); num_nal_arrays = data[22]; off = 23; for (i = 0; i < num_nal_arrays; i++) { if (off + 3 >= size) { GST_WARNING_OBJECT (self, "hvcC too small"); return GST_FLOW_ERROR; } num_nals = GST_READ_UINT16_BE (data + off + 1); off += 3; for (j = 0; j < num_nals; j++) { pres = gst_h265_parser_identify_nalu_hevc (priv->parser, data, off, size, 2, &nalu); if (pres != GST_H265_PARSER_OK) { GST_WARNING_OBJECT (self, "hvcC too small"); return GST_FLOW_ERROR; } switch (nalu.type) { case GST_H265_NAL_VPS: pres = gst_h265_parser_parse_vps (priv->parser, &nalu, &vps); if (pres != GST_H265_PARSER_OK) { GST_WARNING_OBJECT (self, "Failed to parse VPS"); return GST_FLOW_ERROR; } break; case GST_H265_NAL_SPS: pres = gst_h265_parser_parse_sps (priv->parser, &nalu, &sps, TRUE); if (pres != GST_H265_PARSER_OK) { GST_WARNING_OBJECT (self, "Failed to parse SPS"); return GST_FLOW_ERROR; } break; case GST_H265_NAL_PPS: pres = gst_h265_parser_parse_pps (priv->parser, &nalu, &pps); if (pres != GST_H265_PARSER_OK) { GST_WARNING_OBJECT (self, "Failed to parse PPS"); return GST_FLOW_ERROR; } break; default: break; } off = nalu.offset + nalu.size; } } return GST_FLOW_OK; } static gboolean gst_h265_decoder_set_format (GstVideoDecoder * decoder, GstVideoCodecState * state) { GstH265Decoder *self = GST_H265_DECODER (decoder); GstH265DecoderPrivate *priv = self->priv; GstQuery *query; GST_DEBUG_OBJECT (decoder, "Set format"); priv->input_state_changed = TRUE; if (self->input_state) gst_video_codec_state_unref (self->input_state); self->input_state = gst_video_codec_state_ref (state); priv->is_live = FALSE; query = gst_query_new_latency (); if (gst_pad_peer_query (GST_VIDEO_DECODER_SINK_PAD (self), query)) gst_query_parse_latency (query, &priv->is_live, NULL, NULL); gst_query_unref (query); if (state->caps) { GstH265DecoderFormat format; GstH265DecoderAlign align; gst_h265_decoder_format_from_caps (self, state->caps, &format, &align); if (format == GST_H265_DECODER_FORMAT_NONE) { /* codec_data implies packetized */ if (state->codec_data) { GST_WARNING_OBJECT (self, "video/x-h265 caps with codec_data but no stream-format=hev1 or hvc1"); format = GST_H265_DECODER_FORMAT_HEV1; } else { /* otherwise assume bytestream input */ GST_WARNING_OBJECT (self, "video/x-h265 caps without codec_data or stream-format"); format = GST_H265_DECODER_FORMAT_BYTE; } } if (format == GST_H265_DECODER_FORMAT_HEV1 || format == GST_H265_DECODER_FORMAT_HVC1) { if (!state->codec_data) { /* Try it with size 4 anyway */ priv->nal_length_size = 4; GST_WARNING_OBJECT (self, "packetized format without codec data, assuming nal length size is 4"); } /* AVC implies alignment=au */ if (align == GST_H265_DECODER_ALIGN_NONE) align = GST_H265_DECODER_ALIGN_AU; } if (format == GST_H265_DECODER_FORMAT_BYTE && state->codec_data) GST_WARNING_OBJECT (self, "bytestream with codec data"); priv->in_format = format; priv->align = align; } if (state->codec_data) { GstMapInfo map; gst_buffer_map (state->codec_data, &map, GST_MAP_READ); if (gst_h265_decoder_parse_codec_data (self, map.data, map.size) != GST_FLOW_OK) { /* keep going without error. * Probably inband SPS/PPS might be valid data */ GST_WARNING_OBJECT (self, "Failed to handle codec data"); } gst_buffer_unmap (state->codec_data, &map); } return TRUE; } static gboolean gst_h265_decoder_negotiate (GstVideoDecoder * decoder) { GstH265Decoder *self = GST_H265_DECODER (decoder); /* output state must be updated by subclass using new input state already */ self->priv->input_state_changed = FALSE; return GST_VIDEO_DECODER_CLASS (parent_class)->negotiate (decoder); } static gboolean gst_h265_decoder_flush (GstVideoDecoder * decoder) { GstH265Decoder *self = GST_H265_DECODER (decoder); gst_h265_decoder_clear_dpb (self, TRUE); return TRUE; } static GstFlowReturn gst_h265_decoder_drain (GstVideoDecoder * decoder) { GstH265Decoder *self = GST_H265_DECODER (decoder); /* dpb will be cleared by this method */ return gst_h265_decoder_drain_internal (self); } static GstFlowReturn gst_h265_decoder_finish (GstVideoDecoder * decoder) { return gst_h265_decoder_drain (decoder); } static gboolean gst_h265_decoder_fill_picture_from_slice (GstH265Decoder * self, const GstH265Slice * slice, GstH265Picture * picture) { GstH265DecoderPrivate *priv = self->priv; const GstH265SliceHdr *slice_hdr = &slice->header; const GstH265NalUnit *nalu = &slice->nalu; picture->RapPicFlag = slice->rap_pic_flag; picture->NoRaslOutputFlag = slice->no_rasl_output_flag; picture->IntraPicFlag = slice->intra_pic_flag; picture->NoOutputOfPriorPicsFlag = slice->no_output_of_prior_pics_flag; if (picture->IntraPicFlag) { priv->associated_irap_NoRaslOutputFlag = picture->NoRaslOutputFlag; } if (GST_H265_IS_NAL_TYPE_RASL (nalu->type) && priv->associated_irap_NoRaslOutputFlag) { picture->output_flag = FALSE; } else { picture->output_flag = slice_hdr->pic_output_flag; } return TRUE; } #define RSV_VCL_N10 10 #define RSV_VCL_N12 12 #define RSV_VCL_N14 14 static gboolean nal_is_ref (guint8 nal_type) { gboolean ret = FALSE; switch (nal_type) { case GST_H265_NAL_SLICE_TRAIL_N: case GST_H265_NAL_SLICE_TSA_N: case GST_H265_NAL_SLICE_STSA_N: case GST_H265_NAL_SLICE_RADL_N: case GST_H265_NAL_SLICE_RASL_N: case RSV_VCL_N10: case RSV_VCL_N12: case RSV_VCL_N14: ret = FALSE; break; default: ret = TRUE; break; } return ret; } static gboolean gst_h265_decoder_calculate_poc (GstH265Decoder * self, const GstH265Slice * slice, GstH265Picture * picture) { GstH265DecoderPrivate *priv = self->priv; const GstH265SliceHdr *slice_hdr = &slice->header; const GstH265NalUnit *nalu = &slice->nalu; const GstH265SPS *sps = priv->active_sps; gint32 MaxPicOrderCntLsb = 1 << (sps->log2_max_pic_order_cnt_lsb_minus4 + 4); gboolean is_irap; priv->prev_poc_lsb = priv->poc_lsb; priv->prev_poc_msb = priv->poc_msb; is_irap = GST_H265_IS_NAL_TYPE_IRAP (nalu->type); if (!(is_irap && picture->NoRaslOutputFlag)) { priv->prev_poc_lsb = priv->prev_tid0pic_poc_lsb; priv->prev_poc_msb = priv->prev_tid0pic_poc_msb; } /* Finding PicOrderCntMsb */ if (is_irap && picture->NoRaslOutputFlag) { priv->poc_msb = 0; } else { /* (8-1) */ if ((slice_hdr->pic_order_cnt_lsb < priv->prev_poc_lsb) && ((priv->prev_poc_lsb - slice_hdr->pic_order_cnt_lsb) >= (MaxPicOrderCntLsb / 2))) priv->poc_msb = priv->prev_poc_msb + MaxPicOrderCntLsb; else if ((slice_hdr->pic_order_cnt_lsb > priv->prev_poc_lsb) && ((slice_hdr->pic_order_cnt_lsb - priv->prev_poc_lsb) > (MaxPicOrderCntLsb / 2))) priv->poc_msb = priv->prev_poc_msb - MaxPicOrderCntLsb; else priv->poc_msb = priv->prev_poc_msb; } /* (8-2) */ priv->poc = picture->pic_order_cnt = priv->poc_msb + slice_hdr->pic_order_cnt_lsb; priv->poc_lsb = picture->pic_order_cnt_lsb = slice_hdr->pic_order_cnt_lsb; if (GST_H265_IS_NAL_TYPE_IDR (nalu->type)) { picture->pic_order_cnt = 0; picture->pic_order_cnt_lsb = 0; priv->poc_lsb = 0; priv->poc_msb = 0; priv->prev_poc_lsb = 0; priv->prev_poc_msb = 0; priv->prev_tid0pic_poc_lsb = 0; priv->prev_tid0pic_poc_msb = 0; } GST_LOG_OBJECT (self, "PicOrderCntVal %d, (lsb %d)", picture->pic_order_cnt, picture->pic_order_cnt_lsb); if (nalu->temporal_id_plus1 == 1 && !GST_H265_IS_NAL_TYPE_RASL (nalu->type) && !GST_H265_IS_NAL_TYPE_RADL (nalu->type) && nal_is_ref (nalu->type)) { priv->prev_tid0pic_poc_lsb = slice_hdr->pic_order_cnt_lsb; priv->prev_tid0pic_poc_msb = priv->poc_msb; } return TRUE; } static gboolean gst_h265_decoder_set_buffer_flags (GstH265Decoder * self, GstH265Picture * picture) { GstH265DecoderPrivate *priv = self->priv; switch (picture->pic_struct) { case GST_H265_SEI_PIC_STRUCT_FRAME: break; case GST_H265_SEI_PIC_STRUCT_TOP_FIELD: case GST_H265_SEI_PIC_STRUCT_TOP_PAIRED_PREVIOUS_BOTTOM: case GST_H265_SEI_PIC_STRUCT_TOP_PAIRED_NEXT_BOTTOM: if (!priv->field_seq_flag) { GST_FIXME_OBJECT (self, "top-field with field_seq_flag == 0, what does it mean?"); } else { picture->buffer_flags = GST_VIDEO_BUFFER_FLAG_TOP_FIELD; } break; case GST_H265_SEI_PIC_STRUCT_BOTTOM_FIELD: case GST_H265_SEI_PIC_STRUCT_BOTTOM_PAIRED_PREVIOUS_TOP: case GST_H265_SEI_PIC_STRUCT_BOTTOM_PAIRED_NEXT_TOP: if (!priv->field_seq_flag) { GST_FIXME_OBJECT (self, "bottom-field with field_seq_flag == 0, what does it mean?"); } else { picture->buffer_flags = GST_VIDEO_BUFFER_FLAG_BOTTOM_FIELD; } break; case GST_H265_SEI_PIC_STRUCT_TOP_BOTTOM: if (priv->field_seq_flag) { GST_FIXME_OBJECT (self, "TFF with field_seq_flag == 1, what does it mean?"); } else { picture->buffer_flags = GST_VIDEO_BUFFER_FLAG_INTERLACED | GST_VIDEO_BUFFER_FLAG_TFF; } break; case GST_H265_SEI_PIC_STRUCT_BOTTOM_TOP: if (priv->field_seq_flag) { GST_FIXME_OBJECT (self, "BFF with field_seq_flag == 1, what does it mean?"); } else { picture->buffer_flags = GST_VIDEO_BUFFER_FLAG_INTERLACED; } break; default: GST_FIXME_OBJECT (self, "Unhandled picture time SEI pic_struct %d", picture->pic_struct); break; } return TRUE; } static gboolean gst_h265_decoder_init_current_picture (GstH265Decoder * self) { GstH265DecoderPrivate *priv = self->priv; if (!gst_h265_decoder_fill_picture_from_slice (self, &priv->current_slice, priv->current_picture)) { return FALSE; } if (!gst_h265_decoder_calculate_poc (self, &priv->current_slice, priv->current_picture)) return FALSE; /* Use picture struct parsed from picture timing SEI */ priv->current_picture->pic_struct = priv->cur_pic_struct; priv->current_picture->source_scan_type = priv->cur_source_scan_type; priv->current_picture->duplicate_flag = priv->cur_duplicate_flag; gst_h265_decoder_set_buffer_flags (self, priv->current_picture); return TRUE; } static gboolean has_entry_in_rps (GstH265Picture * dpb_pic, GstH265Picture ** rps_list, guint rps_list_length) { guint i; if (!dpb_pic || !rps_list || !rps_list_length) return FALSE; for (i = 0; i < rps_list_length; i++) { if (rps_list[i] && rps_list[i]->pic_order_cnt == dpb_pic->pic_order_cnt) return TRUE; } return FALSE; } static void gst_h265_decoder_clear_ref_pic_sets (GstH265Decoder * self) { guint i; for (i = 0; i < 16; i++) { gst_h265_picture_replace (&self->RefPicSetLtCurr[i], NULL); gst_h265_picture_replace (&self->RefPicSetLtFoll[i], NULL); gst_h265_picture_replace (&self->RefPicSetStCurrBefore[i], NULL); gst_h265_picture_replace (&self->RefPicSetStCurrAfter[i], NULL); gst_h265_picture_replace (&self->RefPicSetStFoll[i], NULL); } } static void gst_h265_decoder_derive_and_mark_rps (GstH265Decoder * self, GstH265Picture * picture, gint32 * CurrDeltaPocMsbPresentFlag, gint32 * FollDeltaPocMsbPresentFlag) { GstH265DecoderPrivate *priv = self->priv; guint i; GArray *dpb_array; gst_h265_decoder_clear_ref_pic_sets (self); /* (8-6) */ for (i = 0; i < self->NumPocLtCurr; i++) { if (!CurrDeltaPocMsbPresentFlag[i]) { self->RefPicSetLtCurr[i] = gst_h265_dpb_get_ref_by_poc_lsb (priv->dpb, priv->PocLtCurr[i]); } else { self->RefPicSetLtCurr[i] = gst_h265_dpb_get_ref_by_poc (priv->dpb, priv->PocLtCurr[i]); } } for (i = 0; i < self->NumPocLtFoll; i++) { if (!FollDeltaPocMsbPresentFlag[i]) { self->RefPicSetLtFoll[i] = gst_h265_dpb_get_ref_by_poc_lsb (priv->dpb, priv->PocLtFoll[i]); } else { self->RefPicSetLtFoll[i] = gst_h265_dpb_get_ref_by_poc (priv->dpb, priv->PocLtFoll[i]); } } /* Mark all ref pics in RefPicSetLtCurr and RefPicSetLtFol as long_term_refs */ for (i = 0; i < self->NumPocLtCurr; i++) { if (self->RefPicSetLtCurr[i]) { self->RefPicSetLtCurr[i]->ref = TRUE; self->RefPicSetLtCurr[i]->long_term = TRUE; } } for (i = 0; i < self->NumPocLtFoll; i++) { if (self->RefPicSetLtFoll[i]) { self->RefPicSetLtFoll[i]->ref = TRUE; self->RefPicSetLtFoll[i]->long_term = TRUE; } } /* (8-7) */ for (i = 0; i < self->NumPocStCurrBefore; i++) { self->RefPicSetStCurrBefore[i] = gst_h265_dpb_get_short_ref_by_poc (priv->dpb, priv->PocStCurrBefore[i]); } for (i = 0; i < self->NumPocStCurrAfter; i++) { self->RefPicSetStCurrAfter[i] = gst_h265_dpb_get_short_ref_by_poc (priv->dpb, priv->PocStCurrAfter[i]); } for (i = 0; i < self->NumPocStFoll; i++) { self->RefPicSetStFoll[i] = gst_h265_dpb_get_short_ref_by_poc (priv->dpb, priv->PocStFoll[i]); } /* Mark all dpb pics not beloging to RefPicSet*[] as unused for ref */ dpb_array = gst_h265_dpb_get_pictures_all (priv->dpb); for (i = 0; i < dpb_array->len; i++) { GstH265Picture *dpb_pic = g_array_index (dpb_array, GstH265Picture *, i); if (dpb_pic && !has_entry_in_rps (dpb_pic, self->RefPicSetLtCurr, self->NumPocLtCurr) && !has_entry_in_rps (dpb_pic, self->RefPicSetLtFoll, self->NumPocLtFoll) && !has_entry_in_rps (dpb_pic, self->RefPicSetStCurrAfter, self->NumPocStCurrAfter) && !has_entry_in_rps (dpb_pic, self->RefPicSetStCurrBefore, self->NumPocStCurrBefore) && !has_entry_in_rps (dpb_pic, self->RefPicSetStFoll, self->NumPocStFoll)) { GST_LOG_OBJECT (self, "Mark Picture %p (poc %d) as non-ref", dpb_pic, dpb_pic->pic_order_cnt); dpb_pic->ref = FALSE; dpb_pic->long_term = FALSE; } } g_array_unref (dpb_array); } static gboolean gst_h265_decoder_prepare_rps (GstH265Decoder * self, const GstH265Slice * slice, GstH265Picture * picture) { GstH265DecoderPrivate *priv = self->priv; gint32 CurrDeltaPocMsbPresentFlag[16] = { 0, }; gint32 FollDeltaPocMsbPresentFlag[16] = { 0, }; const GstH265SliceHdr *slice_hdr = &slice->header; const GstH265NalUnit *nalu = &slice->nalu; const GstH265SPS *sps = priv->active_sps; guint32 MaxPicOrderCntLsb = 1 << (sps->log2_max_pic_order_cnt_lsb_minus4 + 4); gint i, j, k; /* if it is an irap pic, set all ref pics in dpb as unused for ref */ if (GST_H265_IS_NAL_TYPE_IRAP (nalu->type) && picture->NoRaslOutputFlag) { GST_DEBUG_OBJECT (self, "Mark all pictures in DPB as non-ref"); gst_h265_dpb_mark_all_non_ref (priv->dpb); } /* Reset everything for IDR */ if (GST_H265_IS_NAL_TYPE_IDR (nalu->type)) { memset (priv->PocStCurrBefore, 0, sizeof (priv->PocStCurrBefore)); memset (priv->PocStCurrAfter, 0, sizeof (priv->PocStCurrAfter)); memset (priv->PocStFoll, 0, sizeof (priv->PocStFoll)); memset (priv->PocLtCurr, 0, sizeof (priv->PocLtCurr)); memset (priv->PocLtFoll, 0, sizeof (priv->PocLtFoll)); self->NumPocStCurrBefore = self->NumPocStCurrAfter = self->NumPocStFoll = 0; self->NumPocLtCurr = self->NumPocLtFoll = 0; } else { const GstH265ShortTermRefPicSet *stRefPic = NULL; gint32 num_lt_pics, pocLt; gint32 PocLsbLt[16] = { 0, }; gint32 UsedByCurrPicLt[16] = { 0, }; gint32 DeltaPocMsbCycleLt[16] = { 0, }; gint numtotalcurr = 0; /* this is based on CurrRpsIdx described in spec */ if (!slice_hdr->short_term_ref_pic_set_sps_flag) stRefPic = &slice_hdr->short_term_ref_pic_sets; else if (sps->num_short_term_ref_pic_sets) stRefPic = &sps->short_term_ref_pic_set[slice_hdr->short_term_ref_pic_set_idx]; if (stRefPic == NULL) return FALSE; GST_LOG_OBJECT (self, "NumDeltaPocs: %d, NumNegativePics: %d, NumPositivePics %d", stRefPic->NumDeltaPocs, stRefPic->NumNegativePics, stRefPic->NumPositivePics); for (i = 0, j = 0, k = 0; i < stRefPic->NumNegativePics; i++) { if (stRefPic->UsedByCurrPicS0[i]) { priv->PocStCurrBefore[j++] = picture->pic_order_cnt + stRefPic->DeltaPocS0[i]; numtotalcurr++; } else priv->PocStFoll[k++] = picture->pic_order_cnt + stRefPic->DeltaPocS0[i]; } self->NumPocStCurrBefore = j; for (i = 0, j = 0; i < stRefPic->NumPositivePics; i++) { if (stRefPic->UsedByCurrPicS1[i]) { priv->PocStCurrAfter[j++] = picture->pic_order_cnt + stRefPic->DeltaPocS1[i]; numtotalcurr++; } else priv->PocStFoll[k++] = picture->pic_order_cnt + stRefPic->DeltaPocS1[i]; } self->NumPocStCurrAfter = j; self->NumPocStFoll = k; num_lt_pics = slice_hdr->num_long_term_sps + slice_hdr->num_long_term_pics; /* The variables PocLsbLt[i] and UsedByCurrPicLt[i] are derived as follows: */ for (i = 0; i < num_lt_pics; i++) { if (i < slice_hdr->num_long_term_sps) { PocLsbLt[i] = sps->lt_ref_pic_poc_lsb_sps[slice_hdr->lt_idx_sps[i]]; UsedByCurrPicLt[i] = sps->used_by_curr_pic_lt_sps_flag[slice_hdr->lt_idx_sps[i]]; } else { PocLsbLt[i] = slice_hdr->poc_lsb_lt[i]; UsedByCurrPicLt[i] = slice_hdr->used_by_curr_pic_lt_flag[i]; } if (UsedByCurrPicLt[i]) numtotalcurr++; } self->NumPicTotalCurr = numtotalcurr; /* The variable DeltaPocMsbCycleLt[i] is derived as follows: (7-38) */ for (i = 0; i < num_lt_pics; i++) { if (i == 0 || i == slice_hdr->num_long_term_sps) DeltaPocMsbCycleLt[i] = slice_hdr->delta_poc_msb_cycle_lt[i]; else DeltaPocMsbCycleLt[i] = slice_hdr->delta_poc_msb_cycle_lt[i] + DeltaPocMsbCycleLt[i - 1]; } /* (8-5) */ for (i = 0, j = 0, k = 0; i < num_lt_pics; i++) { pocLt = PocLsbLt[i]; if (slice_hdr->delta_poc_msb_present_flag[i]) pocLt += picture->pic_order_cnt - DeltaPocMsbCycleLt[i] * MaxPicOrderCntLsb - slice_hdr->pic_order_cnt_lsb; if (UsedByCurrPicLt[i]) { priv->PocLtCurr[j] = pocLt; CurrDeltaPocMsbPresentFlag[j++] = slice_hdr->delta_poc_msb_present_flag[i]; } else { priv->PocLtFoll[k] = pocLt; FollDeltaPocMsbPresentFlag[k++] = slice_hdr->delta_poc_msb_present_flag[i]; } } self->NumPocLtCurr = j; self->NumPocLtFoll = k; } GST_LOG_OBJECT (self, "NumPocStCurrBefore: %d", self->NumPocStCurrBefore); GST_LOG_OBJECT (self, "NumPocStCurrAfter: %d", self->NumPocStCurrAfter); GST_LOG_OBJECT (self, "NumPocStFoll: %d", self->NumPocStFoll); GST_LOG_OBJECT (self, "NumPocLtCurr: %d", self->NumPocLtCurr); GST_LOG_OBJECT (self, "NumPocLtFoll: %d", self->NumPocLtFoll); GST_LOG_OBJECT (self, "NumPicTotalCurr: %d", self->NumPicTotalCurr); /* the derivation process for the RPS and the picture marking */ gst_h265_decoder_derive_and_mark_rps (self, picture, CurrDeltaPocMsbPresentFlag, FollDeltaPocMsbPresentFlag); return TRUE; } static void gst_h265_decoder_do_output_picture (GstH265Decoder * self, GstH265Picture * picture, GstFlowReturn * ret) { GstH265DecoderPrivate *priv = self->priv; GstVideoCodecFrame *frame = NULL; GstH265DecoderOutputFrame output_frame; GstFlowReturn flow_ret = GST_FLOW_OK; g_assert (ret != NULL); GST_LOG_OBJECT (self, "Output picture %p (poc %d)", picture, picture->pic_order_cnt); if (picture->pic_order_cnt < priv->last_output_poc) { GST_WARNING_OBJECT (self, "Outputting out of order %d -> %d, likely a broken stream", priv->last_output_poc, picture->pic_order_cnt); } priv->last_output_poc = picture->pic_order_cnt; frame = gst_video_decoder_get_frame (GST_VIDEO_DECODER (self), picture->system_frame_number); if (!frame) { GST_ERROR_OBJECT (self, "No available codec frame with frame number %d", picture->system_frame_number); UPDATE_FLOW_RETURN (ret, GST_FLOW_ERROR); gst_h265_picture_unref (picture); return; } output_frame.frame = frame; output_frame.picture = picture; output_frame.self = self; gst_queue_array_push_tail_struct (priv->output_queue, &output_frame); gst_h265_decoder_drain_output_queue (self, priv->preferred_output_delay, &flow_ret); UPDATE_FLOW_RETURN (ret, flow_ret); } static void gst_h265_decoder_clear_dpb (GstH265Decoder * self, gboolean flush) { GstVideoDecoder *decoder = GST_VIDEO_DECODER (self); GstH265DecoderPrivate *priv = self->priv; GstH265Picture *picture; /* If we are not flushing now, videodecoder baseclass will hold * GstVideoCodecFrame. Release frames manually */ if (!flush) { while ((picture = gst_h265_dpb_bump (priv->dpb, TRUE)) != NULL) { GstVideoCodecFrame *frame = gst_video_decoder_get_frame (decoder, picture->system_frame_number); if (frame) gst_video_decoder_release_frame (decoder, frame); gst_h265_picture_unref (picture); } } gst_queue_array_clear (priv->output_queue); gst_h265_dpb_clear (priv->dpb); priv->last_output_poc = G_MININT32; } static GstFlowReturn gst_h265_decoder_drain_internal (GstH265Decoder * self) { GstH265DecoderPrivate *priv = self->priv; GstH265Picture *picture; GstFlowReturn ret = GST_FLOW_OK; while ((picture = gst_h265_dpb_bump (priv->dpb, TRUE)) != NULL) gst_h265_decoder_do_output_picture (self, picture, &ret); gst_h265_decoder_drain_output_queue (self, 0, &ret); gst_h265_dpb_clear (priv->dpb); priv->last_output_poc = G_MININT32; return ret; } /* C.5.2.2 */ static GstFlowReturn gst_h265_decoder_dpb_init (GstH265Decoder * self, const GstH265Slice * slice, GstH265Picture * picture) { GstH265DecoderPrivate *priv = self->priv; const GstH265SPS *sps = priv->active_sps; GstH265Picture *to_output; GstFlowReturn ret = GST_FLOW_OK; /* C 3.2 */ if (slice->clear_dpb) { if (picture->NoOutputOfPriorPicsFlag) { GST_DEBUG_OBJECT (self, "Clear dpb"); gst_h265_decoder_drain_output_queue (self, 0, &ret); gst_h265_decoder_clear_dpb (self, FALSE); } else { gst_h265_dpb_delete_unused (priv->dpb); while ((to_output = gst_h265_dpb_bump (priv->dpb, FALSE)) != NULL) gst_h265_decoder_do_output_picture (self, to_output, &ret); if (gst_h265_dpb_get_size (priv->dpb) > 0) { GST_WARNING_OBJECT (self, "IDR or BLA frame failed to clear the dpb, " "there are still %d pictures in the dpb, last output poc is %d", gst_h265_dpb_get_size (priv->dpb), priv->last_output_poc); } else { priv->last_output_poc = G_MININT32; } } } else { gst_h265_dpb_delete_unused (priv->dpb); while (gst_h265_dpb_needs_bump (priv->dpb, sps->max_num_reorder_pics[sps->max_sub_layers_minus1], priv->SpsMaxLatencyPictures, sps->max_dec_pic_buffering_minus1[sps->max_sub_layers_minus1] + 1)) { to_output = gst_h265_dpb_bump (priv->dpb, FALSE); /* Something wrong... */ if (!to_output) { GST_WARNING_OBJECT (self, "Bumping is needed but no picture to output"); break; } gst_h265_decoder_do_output_picture (self, to_output, &ret); } } return ret; } static GstFlowReturn gst_h265_decoder_start_current_picture (GstH265Decoder * self) { GstH265DecoderClass *klass; GstH265DecoderPrivate *priv = self->priv; GstFlowReturn ret = GST_FLOW_OK; g_assert (priv->current_picture != NULL); g_assert (priv->active_sps != NULL); g_assert (priv->active_pps != NULL); if (!gst_h265_decoder_init_current_picture (self)) return GST_FLOW_ERROR; /* Drop all RASL pictures having NoRaslOutputFlag is TRUE for the * associated IRAP picture */ if (GST_H265_IS_NAL_TYPE_RASL (priv->current_slice.nalu.type) && priv->associated_irap_NoRaslOutputFlag) { GST_DEBUG_OBJECT (self, "Drop current picture"); gst_h265_picture_replace (&priv->current_picture, NULL); return GST_FLOW_OK; } /* If subclass didn't update output state at this point, * marking this picture as a discont and stores current input state */ if (priv->input_state_changed) { priv->current_picture->discont_state = gst_video_codec_state_ref (self->input_state); priv->input_state_changed = FALSE; } if (!gst_h265_decoder_prepare_rps (self, &priv->current_slice, priv->current_picture)) { GST_WARNING_OBJECT (self, "Failed to prepare ref pic set"); gst_clear_h265_picture (&priv->current_picture); return GST_FLOW_ERROR; } ret = gst_h265_decoder_dpb_init (self, &priv->current_slice, priv->current_picture); if (ret != GST_FLOW_OK) { GST_WARNING_OBJECT (self, "Failed to init dpb"); return ret; } klass = GST_H265_DECODER_GET_CLASS (self); if (klass->start_picture) { ret = klass->start_picture (self, priv->current_picture, &priv->current_slice, priv->dpb); if (ret != GST_FLOW_OK) { GST_WARNING_OBJECT (self, "subclass does not want to start picture"); return ret; } } return GST_FLOW_OK; } static void gst_h265_decoder_finish_picture (GstH265Decoder * self, GstH265Picture * picture, GstFlowReturn * ret) { GstVideoDecoder *decoder = GST_VIDEO_DECODER (self); GstH265DecoderPrivate *priv = self->priv; const GstH265SPS *sps = priv->active_sps; g_assert (ret != NULL); GST_LOG_OBJECT (self, "Finishing picture %p (poc %d), entries in DPB %d", picture, picture->pic_order_cnt, gst_h265_dpb_get_size (priv->dpb)); gst_h265_dpb_delete_unused (priv->dpb); /* This picture is decode only, drop corresponding frame */ if (!picture->output_flag) { GstVideoCodecFrame *frame = gst_video_decoder_get_frame (decoder, picture->system_frame_number); gst_video_decoder_release_frame (decoder, frame); } /* gst_h265_dpb_add() will take care of pic_latency_cnt increment and * reference picture marking for this picture */ gst_h265_dpb_add (priv->dpb, picture); /* NOTE: As per C.5.2.2, bumping by sps_max_dec_pic_buffering_minus1 is * applied only for the output and removal of pictures from the DPB before * the decoding of the current picture. So pass zero here */ while (gst_h265_dpb_needs_bump (priv->dpb, sps->max_num_reorder_pics[sps->max_sub_layers_minus1], priv->SpsMaxLatencyPictures, 0)) { GstH265Picture *to_output = gst_h265_dpb_bump (priv->dpb, FALSE); /* Something wrong... */ if (!to_output) { GST_WARNING_OBJECT (self, "Bumping is needed but no picture to output"); break; } gst_h265_decoder_do_output_picture (self, to_output, ret); } } static void gst_h265_decoder_finish_current_picture (GstH265Decoder * self, GstFlowReturn * ret) { GstH265DecoderPrivate *priv = self->priv; GstH265DecoderClass *klass; GstFlowReturn flow_ret = GST_FLOW_OK; g_assert (ret != NULL); if (!priv->current_picture) return; klass = GST_H265_DECODER_GET_CLASS (self); if (klass->end_picture) { flow_ret = klass->end_picture (self, priv->current_picture); if (flow_ret != GST_FLOW_OK) { GST_WARNING_OBJECT (self, "End picture failed"); /* continue to empty dpb */ UPDATE_FLOW_RETURN (ret, flow_ret); } } /* finish picture takes ownership of the picture */ gst_h265_decoder_finish_picture (self, priv->current_picture, &flow_ret); priv->current_picture = NULL; UPDATE_FLOW_RETURN (ret, flow_ret); } static void gst_h265_decoder_reset_frame_state (GstH265Decoder * self) { GstH265DecoderPrivate *priv = self->priv; /* Clear picture struct information */ priv->cur_pic_struct = GST_H265_SEI_PIC_STRUCT_FRAME; priv->cur_source_scan_type = 2; priv->cur_duplicate_flag = 0; priv->no_output_of_prior_pics_flag = FALSE; priv->current_frame = NULL; g_array_set_size (priv->nalu, 0); } static GstFlowReturn gst_h265_decoder_handle_frame (GstVideoDecoder * decoder, GstVideoCodecFrame * frame) { GstH265Decoder *self = GST_H265_DECODER (decoder); GstH265DecoderPrivate *priv = self->priv; GstBuffer *in_buf = frame->input_buffer; GstH265NalUnit nalu; GstH265ParserResult pres; GstMapInfo map; GstFlowReturn decode_ret = GST_FLOW_OK; guint i; GST_LOG_OBJECT (self, "handle frame, PTS: %" GST_TIME_FORMAT ", DTS: %" GST_TIME_FORMAT, GST_TIME_ARGS (GST_BUFFER_PTS (in_buf)), GST_TIME_ARGS (GST_BUFFER_DTS (in_buf))); gst_h265_decoder_reset_frame_state (self); priv->current_frame = frame; if (!gst_buffer_map (in_buf, &map, GST_MAP_READ)) { GST_ELEMENT_ERROR (self, RESOURCE, READ, ("Failed to map memory for reading"), (NULL)); return GST_FLOW_ERROR; } if (priv->in_format == GST_H265_DECODER_FORMAT_HVC1 || priv->in_format == GST_H265_DECODER_FORMAT_HEV1) { guint offset = 0; gsize consumed; do { pres = gst_h265_parser_identify_and_split_nalu_hevc (priv->parser, map.data, offset, map.size, priv->nal_length_size, priv->split_nalu, &consumed); if (pres != GST_H265_PARSER_OK) break; for (i = 0; i < priv->split_nalu->len; i++) { GstH265NalUnit *nl = &g_array_index (priv->split_nalu, GstH265NalUnit, i); pres = gst_h265_decoder_parse_nalu (self, nl); if (pres != GST_H265_PARSER_OK) break; } if (pres != GST_H265_PARSER_OK) break; offset += consumed; } while (pres == GST_H265_PARSER_OK); } else { pres = gst_h265_parser_identify_nalu (priv->parser, map.data, 0, map.size, &nalu); if (pres == GST_H265_PARSER_NO_NAL_END) pres = GST_H265_PARSER_OK; while (pres == GST_H265_PARSER_OK) { pres = gst_h265_decoder_parse_nalu (self, &nalu); if (pres != GST_H265_PARSER_OK) break; pres = gst_h265_parser_identify_nalu (priv->parser, map.data, nalu.offset + nalu.size, map.size, &nalu); if (pres == GST_H265_PARSER_NO_NAL_END) pres = GST_H265_PARSER_OK; } } for (i = 0; i < priv->nalu->len && decode_ret == GST_FLOW_OK; i++) { GstH265DecoderNalUnit *decoder_nalu = &g_array_index (priv->nalu, GstH265DecoderNalUnit, i); decode_ret = gst_h265_decoder_decode_nalu (self, decoder_nalu); } gst_buffer_unmap (in_buf, &map); gst_h265_decoder_reset_frame_state (self); if (decode_ret != GST_FLOW_OK) { if (decode_ret == GST_FLOW_ERROR) { GST_VIDEO_DECODER_ERROR (self, 1, STREAM, DECODE, ("Failed to decode data"), (NULL), decode_ret); } gst_video_decoder_drop_frame (decoder, frame); gst_clear_h265_picture (&priv->current_picture); return decode_ret; } if (priv->current_picture) { gst_h265_decoder_finish_current_picture (self, &decode_ret); gst_video_codec_frame_unref (frame); } else { /* This picture was dropped */ gst_video_decoder_release_frame (decoder, frame); } if (decode_ret == GST_FLOW_ERROR) { GST_VIDEO_DECODER_ERROR (self, 1, STREAM, DECODE, ("Failed to decode data"), (NULL), decode_ret); } return decode_ret; } static void gst_h265_decoder_clear_nalu (GstH265DecoderNalUnit * nalu) { if (!nalu) return; memset (nalu, 0, sizeof (GstH265DecoderNalUnit)); } /** * gst_h265_decoder_set_process_ref_pic_lists: * @decoder: a #GstH265Decoder * @process: whether subclass is requiring reference picture modification process * * Called to en/disable reference picture modification process. * * Since: 1.20 */ void gst_h265_decoder_set_process_ref_pic_lists (GstH265Decoder * decoder, gboolean process) { decoder->priv->process_ref_pic_lists = process; } /** * gst_h265_decoder_get_picture: * @decoder: a #GstH265Decoder * @system_frame_number: a target system frame number of #GstH265Picture * * Retrive DPB and return a #GstH265Picture corresponding to * the @system_frame_number * * Returns: (transfer full) (nullable): a #GstH265Picture if successful, or %NULL otherwise * * Since: 1.20 */ GstH265Picture * gst_h265_decoder_get_picture (GstH265Decoder * decoder, guint32 system_frame_number) { return gst_h265_dpb_get_picture (decoder->priv->dpb, system_frame_number); }