/* Gstreamer * Copyright (C) <2011> Intel Corporation * Copyright (C) <2011> Collabora Ltd. * Copyright (C) <2011> Thibault Saunier * * Some bits C-c,C-v'ed and s/4/3 from h264parse and videoparsers/h264parse.c: * Copyright (C) <2010> Mark Nauwelaerts * Copyright (C) <2010> Collabora Multimedia * Copyright (C) <2010> Nokia Corporation * * (C) 2005 Michal Benes * (C) 2008 Wim Taymans * * 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:gsth264parser * @short_description: Convenience library for h264 video * bitstream parsing. * * It offers you bitstream parsing in AVC mode or not. To identify Nals in a bitstream and * parse its headers, you should call: * * * #gst_h264_parser_identify_nalu to identify the following nalu in not AVC bitstreams * * * #gst_h264_parser_identify_nalu_avc to identify the nalu in AVC bitstreams * * * * Then, depending on the #GstH264NalUnitType of the newly parsed #GstH264NalUnit, you should * call the differents functions to parse the structure: * * * From #GST_H264_NAL_SLICE to #GST_H264_NAL_SLICE_IDR: #gst_h264_parser_parse_slice_hdr * * * #GST_H264_NAL_SEI: #gst_h264_parser_parse_sei * * * #GST_H264_NAL_SPS: #gst_h264_parser_parse_sps * * * #GST_H264_NAL_PPS: #gst_h264_parser_parse_pps * * * Any other: #gst_h264_parser_parse_nal * * * * Note: You should always call gst_h264_parser_parse_nal if you don't actually need * #GstH264NalUnitType to be parsed for your personnal use, in order to guarantee that the * #GstH264NalParser is always up to date. * * For more details about the structures, look at the ITU-T H.264 and ISO/IEC 14496-10 – MPEG-4 * Part 10 specifications, you can download them from: * * * * ITU-T H.264: http://www.itu.int/rec/T-REC-H.264 * * * ISO/IEC 14496-10: http://www.iso.org/iso/iso_catalogue/catalogue_tc/catalogue_detail.htm?csnumber=56538 * * */ #ifdef HAVE_CONFIG_H # include "config.h" #endif #include "gsth264parser.h" #include #include #include GST_DEBUG_CATEGORY (h264_parser_debug); #define GST_CAT_DEFAULT h264_parser_debug static gboolean initialized = FALSE; #define INITIALIZE_DEBUG_CATEGORY \ if (!initialized) { \ GST_DEBUG_CATEGORY_INIT (h264_parser_debug, "codecparsers_h264", 0, \ "h264 parser library"); \ initialized = TRUE; \ } /**** Default scaling_lists according to Table 7-2 *****/ static const guint8 default_4x4_intra[16] = { 6, 13, 13, 20, 20, 20, 28, 28, 28, 28, 32, 32, 32, 37, 37, 42 }; static const guint8 default_4x4_inter[16] = { 10, 14, 14, 20, 20, 20, 24, 24, 24, 24, 27, 27, 27, 30, 30, 34 }; static const guint8 default_8x8_intra[64] = { 6, 10, 10, 13, 11, 13, 16, 16, 16, 16, 18, 18, 18, 18, 18, 23, 23, 23, 23, 23, 23, 25, 25, 25, 25, 25, 25, 25, 27, 27, 27, 27, 27, 27, 27, 27, 29, 29, 29, 29, 29, 29, 29, 31, 31, 31, 31, 31, 31, 33, 33, 33, 33, 33, 36, 36, 36, 36, 38, 38, 38, 40, 40, 42 }; static const guint8 default_8x8_inter[64] = { 9, 13, 13, 15, 13, 15, 17, 17, 17, 17, 19, 19, 19, 19, 19, 21, 21, 21, 21, 21, 21, 22, 22, 22, 22, 22, 22, 22, 24, 24, 24, 24, 24, 24, 24, 24, 25, 25, 25, 25, 25, 25, 25, 27, 27, 27, 27, 27, 27, 28, 28, 28, 28, 28, 30, 30, 30, 30, 32, 32, 32, 33, 33, 35 }; static const guint8 zigzag_8x8[64] = { 0, 1, 8, 16, 9, 2, 3, 10, 17, 24, 32, 25, 18, 11, 4, 5, 12, 19, 26, 33, 40, 48, 41, 34, 27, 20, 13, 6, 7, 14, 21, 28, 35, 42, 49, 56, 57, 50, 43, 36, 29, 22, 15, 23, 30, 37, 44, 51, 58, 59, 52, 45, 38, 31, 39, 46, 53, 60, 61, 54, 47, 55, 62, 63 }; static const guint8 zigzag_4x4[16] = { 0, 1, 4, 8, 5, 2, 3, 6, 9, 12, 13, 10, 7, 11, 14, 15, }; typedef struct { guint par_n, par_d; } PAR; /* Table E-1 - Meaning of sample aspect ratio indicator (1..16) */ static PAR aspect_ratios[17] = { {0, 0}, {1, 1}, {12, 11}, {10, 11}, {16, 11}, {40, 33}, {24, 11}, {20, 11}, {32, 11}, {80, 33}, {18, 11}, {15, 11}, {64, 33}, {160, 99}, {4, 3}, {3, 2}, {2, 1} }; /* Compute Ceil(Log2(v)) */ /* Derived from branchless code for integer log2(v) from: */ static guint ceil_log2 (guint32 v) { guint r, shift; v--; r = (v > 0xFFFF) << 4; v >>= r; shift = (v > 0xFF) << 3; v >>= shift; r |= shift; shift = (v > 0xF) << 2; v >>= shift; r |= shift; shift = (v > 0x3) << 1; v >>= shift; r |= shift; r |= (v >> 1); return r + 1; } /****** Nal parser ******/ typedef struct { const guint8 *data; guint size; guint n_epb; /* Number of emulation prevention bytes */ guint byte; /* Byte position */ guint bits_in_cache; /* bitpos in the cache of next bit */ guint8 first_byte; guint64 cache; /* cached bytes */ } NalReader; static void nal_reader_init (NalReader * nr, const guint8 * data, guint size) { nr->data = data; nr->size = size; nr->n_epb = 0; nr->byte = 0; nr->bits_in_cache = 0; /* fill with something other than 0 to detect emulation prevention bytes */ nr->first_byte = 0xff; nr->cache = 0xff; } static inline gboolean nal_reader_read (NalReader * nr, guint nbits) { if (G_UNLIKELY (nr->byte * 8 + (nbits - nr->bits_in_cache) > nr->size * 8)) { GST_DEBUG ("Can not read %u bits, bits in cache %u, Byte * 8 %u, size in " "bits %u", nbits, nr->bits_in_cache, nr->byte * 8, nr->size * 8); return FALSE; } while (nr->bits_in_cache < nbits) { guint8 byte; gboolean check_three_byte; check_three_byte = TRUE; next_byte: if (G_UNLIKELY (nr->byte >= nr->size)) return FALSE; byte = nr->data[nr->byte++]; /* check if the byte is a emulation_prevention_three_byte */ if (check_three_byte && byte == 0x03 && nr->first_byte == 0x00 && ((nr->cache & 0xff) == 0)) { /* next byte goes unconditionally to the cache, even if it's 0x03 */ check_three_byte = FALSE; nr->n_epb++; goto next_byte; } nr->cache = (nr->cache << 8) | nr->first_byte; nr->first_byte = byte; nr->bits_in_cache += 8; } return TRUE; } static inline gboolean nal_reader_skip (NalReader * nr, guint nbits) { if (G_UNLIKELY (!nal_reader_read (nr, nbits))) return FALSE; nr->bits_in_cache -= nbits; return TRUE; } static inline guint nal_reader_get_pos (const NalReader * nr) { return nr->byte * 8 - nr->bits_in_cache; } static inline guint nal_reader_get_remaining (const NalReader * nr) { return (nr->size - nr->byte) * 8 + nr->bits_in_cache; } static inline guint nal_reader_get_epb_count (const NalReader * nr) { return nr->n_epb; } #define GST_NAL_READER_READ_BITS(bits) \ static gboolean \ nal_reader_get_bits_uint##bits (NalReader *nr, guint##bits *val, guint nbits) \ { \ guint shift; \ \ if (!nal_reader_read (nr, nbits)) \ return FALSE; \ \ /* bring the required bits down and truncate */ \ shift = nr->bits_in_cache - nbits; \ *val = nr->first_byte >> shift; \ \ *val |= nr->cache << (8 - shift); \ /* mask out required bits */ \ if (nbits < bits) \ *val &= ((guint##bits)1 << nbits) - 1; \ \ nr->bits_in_cache = shift; \ \ return TRUE; \ } \ GST_NAL_READER_READ_BITS (8); GST_NAL_READER_READ_BITS (16); GST_NAL_READER_READ_BITS (32); #define GST_NAL_READER_PEAK_BITS(bits) \ static gboolean \ nal_reader_peek_bits_uint##bits (const NalReader *nr, guint##bits *val, guint nbits) \ { \ NalReader tmp; \ \ tmp = *nr; \ return nal_reader_get_bits_uint##bits (&tmp, val, nbits); \ } GST_NAL_READER_PEAK_BITS (8); static gboolean nal_reader_get_ue (NalReader * nr, guint32 * val) { guint i = 0; guint8 bit; guint32 value; if (G_UNLIKELY (!nal_reader_get_bits_uint8 (nr, &bit, 1))) { return FALSE; } while (bit == 0) { i++; if G_UNLIKELY ((!nal_reader_get_bits_uint8 (nr, &bit, 1))) return FALSE; } if (G_UNLIKELY (i > 32)) return FALSE; if (G_UNLIKELY (!nal_reader_get_bits_uint32 (nr, &value, i))) return FALSE; *val = (1 << i) - 1 + value; return TRUE; } static inline gboolean nal_reader_get_se (NalReader * nr, gint32 * val) { guint32 value; if (G_UNLIKELY (!nal_reader_get_ue (nr, &value))) return FALSE; if (value % 2) *val = (value / 2) + 1; else *val = -(value / 2); return TRUE; } #define CHECK_ALLOWED(val, min, max) { \ if (val < min || val > max) { \ GST_WARNING ("value not in allowed range. value: %d, range %d-%d", \ val, min, max); \ goto error; \ } \ } #define READ_UINT8(nr, val, nbits) { \ if (!nal_reader_get_bits_uint8 (nr, &val, nbits)) { \ GST_WARNING ("failed to read uint8, nbits: %d", nbits); \ goto error; \ } \ } #define READ_UINT16(nr, val, nbits) { \ if (!nal_reader_get_bits_uint16 (nr, &val, nbits)) { \ GST_WARNING ("failed to read uint16, nbits: %d", nbits); \ goto error; \ } \ } #define READ_UINT32(nr, val, nbits) { \ if (!nal_reader_get_bits_uint32 (nr, &val, nbits)) { \ GST_WARNING ("failed to read uint32, nbits: %d", nbits); \ goto error; \ } \ } #define READ_UINT64(nr, val, nbits) { \ if (!nal_reader_get_bits_uint64 (nr, &val, nbits)) { \ GST_WARNING ("failed to read uint32, nbits: %d", nbits); \ goto error; \ } \ } #define READ_UE(nr, val) { \ if (!nal_reader_get_ue (nr, &val)) { \ GST_WARNING ("failed to read UE"); \ goto error; \ } \ } #define READ_UE_ALLOWED(nr, val, min, max) { \ guint32 tmp; \ READ_UE (nr, tmp); \ CHECK_ALLOWED (tmp, min, max); \ val = tmp; \ } #define READ_SE(nr, val) { \ if (!nal_reader_get_se (nr, &val)) { \ GST_WARNING ("failed to read SE"); \ goto error; \ } \ } #define READ_SE_ALLOWED(nr, val, min, max) { \ gint32 tmp; \ READ_SE (nr, tmp); \ CHECK_ALLOWED (tmp, min, max); \ val = tmp; \ } /*********** end of nal parser ***************/ /***** Utils ****/ #define EXTENDED_SAR 255 static GstH264SPS * gst_h264_parser_get_sps (GstH264NalParser * nalparser, guint8 sps_id) { GstH264SPS *sps; sps = &nalparser->sps[sps_id]; if (sps->valid) return sps; return NULL; } static GstH264PPS * gst_h264_parser_get_pps (GstH264NalParser * nalparser, guint8 pps_id) { GstH264PPS *pps; pps = &nalparser->pps[pps_id]; if (pps->valid) return pps; return NULL; } static inline void set_nalu_datas (GstH264NalUnit * nalu) { guint8 *data = nalu->data + nalu->offset; nalu->type = (data[0] & 0x1f); nalu->ref_idc = (data[0] & 0x60) >> 5; nalu->idr_pic_flag = (nalu->type == 5 ? 1 : 0); GST_DEBUG ("Nal type %u, ref_idc %u", nalu->type, nalu->ref_idc); } static inline gint scan_for_start_codes (const guint8 * data, guint size) { GstByteReader br; gst_byte_reader_init (&br, data, size); /* NALU not empty, so we can at least expect 1 (even 2) bytes following sc */ return gst_byte_reader_masked_scan_uint32 (&br, 0xffffff00, 0x00000100, 0, size); } static gboolean gst_h264_parser_more_data (NalReader * nr) { guint remaining; remaining = nal_reader_get_remaining (nr); if (remaining == 0) return FALSE; if (remaining <= 8) { guint8 rbsp_stop_one_bit; if (!nal_reader_peek_bits_uint8 (nr, &rbsp_stop_one_bit, 1)) return FALSE; if (rbsp_stop_one_bit == 1) { guint8 zero_bits; if (remaining == 1) return FALSE; if (!nal_reader_peek_bits_uint8 (nr, &zero_bits, remaining)) return FALSE; if ((zero_bits - (1 << (remaining - 1))) == 0) return FALSE; } } return TRUE; } /****** Parsing functions *****/ static gboolean gst_h264_parse_hrd_parameters (GstH264HRDParams * hrd, NalReader * nr) { guint sched_sel_idx; GST_DEBUG ("parsing \"HRD Parameters\""); READ_UE_ALLOWED (nr, hrd->cpb_cnt_minus1, 0, 31); READ_UINT8 (nr, hrd->bit_rate_scale, 4); READ_UINT8 (nr, hrd->cpb_size_scale, 4); for (sched_sel_idx = 0; sched_sel_idx <= hrd->cpb_cnt_minus1; sched_sel_idx++) { READ_UE (nr, hrd->bit_rate_value_minus1[sched_sel_idx]); READ_UE (nr, hrd->cpb_size_value_minus1[sched_sel_idx]); READ_UINT8 (nr, hrd->cbr_flag[sched_sel_idx], 1); } READ_UINT8 (nr, hrd->initial_cpb_removal_delay_length_minus1, 5); READ_UINT8 (nr, hrd->cpb_removal_delay_length_minus1, 5); READ_UINT8 (nr, hrd->dpb_output_delay_length_minus1, 5); READ_UINT8 (nr, hrd->time_offset_length, 5); return TRUE; error: GST_WARNING ("error parsing \"HRD Parameters\""); return FALSE; } static gboolean gst_h264_parse_vui_parameters (GstH264SPS * sps, NalReader * nr) { GstH264VUIParams *vui = &sps->vui_parameters; GST_DEBUG ("parsing \"VUI Parameters\""); /* set default values for fields that might not be present in the bitstream and have valid defaults */ vui->aspect_ratio_idc = 0; vui->video_format = 5; vui->video_full_range_flag = 0; vui->colour_primaries = 2; vui->transfer_characteristics = 2; vui->matrix_coefficients = 2; vui->chroma_sample_loc_type_top_field = 0; vui->chroma_sample_loc_type_bottom_field = 0; vui->low_delay_hrd_flag = 0; vui->par_n = 0; vui->par_d = 0; READ_UINT8 (nr, vui->aspect_ratio_info_present_flag, 1); if (vui->aspect_ratio_info_present_flag) { READ_UINT8 (nr, vui->aspect_ratio_idc, 8); if (vui->aspect_ratio_idc == EXTENDED_SAR) { READ_UINT16 (nr, vui->sar_width, 16); READ_UINT16 (nr, vui->sar_height, 16); vui->par_n = vui->sar_width; vui->par_d = vui->sar_height; } else if (vui->aspect_ratio_idc <= 16) { vui->par_n = aspect_ratios[vui->aspect_ratio_idc].par_n; vui->par_d = aspect_ratios[vui->aspect_ratio_idc].par_d; } } READ_UINT8 (nr, vui->overscan_info_present_flag, 1); if (vui->overscan_info_present_flag) READ_UINT8 (nr, vui->overscan_appropriate_flag, 1); READ_UINT8 (nr, vui->video_signal_type_present_flag, 1); if (vui->video_signal_type_present_flag) { READ_UINT8 (nr, vui->video_format, 3); READ_UINT8 (nr, vui->video_full_range_flag, 1); READ_UINT8 (nr, vui->colour_description_present_flag, 1); if (vui->colour_description_present_flag) { READ_UINT8 (nr, vui->colour_primaries, 8); READ_UINT8 (nr, vui->transfer_characteristics, 8); READ_UINT8 (nr, vui->matrix_coefficients, 8); } } READ_UINT8 (nr, vui->chroma_loc_info_present_flag, 1); if (vui->chroma_loc_info_present_flag) { READ_UE_ALLOWED (nr, vui->chroma_sample_loc_type_top_field, 0, 5); READ_UE_ALLOWED (nr, vui->chroma_sample_loc_type_bottom_field, 0, 5); } READ_UINT8 (nr, vui->timing_info_present_flag, 1); if (vui->timing_info_present_flag) { READ_UINT32 (nr, vui->num_units_in_tick, 32); if (vui->num_units_in_tick == 0) GST_WARNING ("num_units_in_tick = 0 detected in stream " "(incompliant to H.264 E.2.1)."); READ_UINT32 (nr, vui->time_scale, 32); if (vui->time_scale == 0) GST_WARNING ("time_scale = 0 detected in stream " "(incompliant to H.264 E.2.1)."); READ_UINT8 (nr, vui->fixed_frame_rate_flag, 1); } READ_UINT8 (nr, vui->nal_hrd_parameters_present_flag, 1); if (vui->nal_hrd_parameters_present_flag) { if (!gst_h264_parse_hrd_parameters (&vui->nal_hrd_parameters, nr)) goto error; } READ_UINT8 (nr, vui->vcl_hrd_parameters_present_flag, 1); if (vui->vcl_hrd_parameters_present_flag) { if (!gst_h264_parse_hrd_parameters (&vui->vcl_hrd_parameters, nr)) goto error; } if (vui->nal_hrd_parameters_present_flag || vui->vcl_hrd_parameters_present_flag) READ_UINT8 (nr, vui->low_delay_hrd_flag, 1); READ_UINT8 (nr, vui->pic_struct_present_flag, 1); READ_UINT8 (nr, vui->bitstream_restriction_flag, 1); if (vui->bitstream_restriction_flag) { READ_UINT8 (nr, vui->motion_vectors_over_pic_boundaries_flag, 1); READ_UE (nr, vui->max_bytes_per_pic_denom); READ_UE_ALLOWED (nr, vui->max_bits_per_mb_denom, 0, 16); READ_UE_ALLOWED (nr, vui->log2_max_mv_length_horizontal, 0, 16); READ_UE_ALLOWED (nr, vui->log2_max_mv_length_vertical, 0, 16); READ_UE (nr, vui->num_reorder_frames); READ_UE (nr, vui->max_dec_frame_buffering); } return TRUE; error: GST_WARNING ("error parsing \"VUI Parameters\""); return FALSE; } static gboolean gst_h264_parser_parse_scaling_list (NalReader * nr, guint8 scaling_lists_4x4[6][16], guint8 scaling_lists_8x8[6][64], const guint8 fallback_4x4_inter[16], const guint8 fallback_4x4_intra[16], const guint8 fallback_8x8_inter[64], const guint8 fallback_8x8_intra[64], guint8 n_lists) { guint i; GST_DEBUG ("parsing scaling lists"); for (i = 0; i < 12; i++) { gboolean use_default = FALSE; if (i < n_lists) { guint8 scaling_list_present_flag; READ_UINT8 (nr, scaling_list_present_flag, 1); if (scaling_list_present_flag) { guint8 *scaling_list; guint size; guint j; guint8 last_scale, next_scale; if (i < 6) { scaling_list = scaling_lists_4x4[i]; size = 16; } else { scaling_list = scaling_lists_8x8[i - 6]; size = 64; } last_scale = 8; next_scale = 8; for (j = 0; j < size; j++) { if (next_scale != 0) { gint32 delta_scale; READ_SE (nr, delta_scale); next_scale = (last_scale + delta_scale) & 0xff; } if (j == 0 && next_scale == 0) { use_default = TRUE; break; } last_scale = scaling_list[j] = (next_scale == 0) ? last_scale : next_scale; } } else use_default = TRUE; } else use_default = TRUE; if (use_default) { switch (i) { case 0: memcpy (scaling_lists_4x4[0], fallback_4x4_intra, 16); break; case 1: memcpy (scaling_lists_4x4[1], scaling_lists_4x4[0], 16); break; case 2: memcpy (scaling_lists_4x4[2], scaling_lists_4x4[1], 16); break; case 3: memcpy (scaling_lists_4x4[3], fallback_4x4_inter, 16); break; case 4: memcpy (scaling_lists_4x4[4], scaling_lists_4x4[3], 16); break; case 5: memcpy (scaling_lists_4x4[5], scaling_lists_4x4[4], 16); break; case 6: memcpy (scaling_lists_8x8[0], fallback_8x8_intra, 64); break; case 7: memcpy (scaling_lists_8x8[1], fallback_8x8_inter, 64); break; case 8: memcpy (scaling_lists_8x8[2], scaling_lists_8x8[0], 64); break; case 9: memcpy (scaling_lists_8x8[3], scaling_lists_8x8[1], 64); break; case 10: memcpy (scaling_lists_8x8[4], scaling_lists_8x8[2], 64); break; case 11: memcpy (scaling_lists_8x8[5], scaling_lists_8x8[3], 64); break; default: break; } } } return TRUE; error: GST_WARNING ("error parsing scaling lists"); return FALSE; } static gboolean slice_parse_ref_pic_list_modification_1 (GstH264SliceHdr * slice, NalReader * nr, guint list) { GstH264RefPicListModification *entries; guint8 *ref_pic_list_modification_flag, *n_ref_pic_list_modification; guint32 modification_of_pic_nums_idc; guint i = 0; if (list == 0) { entries = slice->ref_pic_list_modification_l0; ref_pic_list_modification_flag = &slice->ref_pic_list_modification_flag_l0; n_ref_pic_list_modification = &slice->n_ref_pic_list_modification_l0; } else { entries = slice->ref_pic_list_modification_l1; ref_pic_list_modification_flag = &slice->ref_pic_list_modification_flag_l1; n_ref_pic_list_modification = &slice->n_ref_pic_list_modification_l1; } READ_UINT8 (nr, *ref_pic_list_modification_flag, 1); if (*ref_pic_list_modification_flag) { while (1) { READ_UE (nr, modification_of_pic_nums_idc); if (modification_of_pic_nums_idc == 3) break; if (modification_of_pic_nums_idc == 0 || modification_of_pic_nums_idc == 1) { READ_UE_ALLOWED (nr, entries[i].value.abs_diff_pic_num_minus1, 0, slice->max_pic_num - 1); } else if (modification_of_pic_nums_idc == 2) { READ_UE (nr, entries[i].value.long_term_pic_num); } entries[i++].modification_of_pic_nums_idc = modification_of_pic_nums_idc; } } *n_ref_pic_list_modification = i; return TRUE; error: GST_WARNING ("error parsing \"Reference picture list %u modification\"", list); return FALSE; } static gboolean slice_parse_ref_pic_list_modification (GstH264SliceHdr * slice, NalReader * nr) { if (!GST_H264_IS_I_SLICE (slice) && !GST_H264_IS_SI_SLICE (slice)) { if (!slice_parse_ref_pic_list_modification_1 (slice, nr, 0)) return FALSE; } if (GST_H264_IS_B_SLICE (slice)) { if (!slice_parse_ref_pic_list_modification_1 (slice, nr, 1)) return FALSE; } return TRUE; } static gboolean gst_h264_slice_parse_dec_ref_pic_marking (GstH264SliceHdr * slice, GstH264NalUnit * nalu, NalReader * nr) { GstH264DecRefPicMarking *dec_ref_pic_m; GST_DEBUG ("parsing \"Decoded reference picture marking\""); dec_ref_pic_m = &slice->dec_ref_pic_marking; if (nalu->idr_pic_flag) { READ_UINT8 (nr, dec_ref_pic_m->no_output_of_prior_pics_flag, 1); READ_UINT8 (nr, dec_ref_pic_m->long_term_reference_flag, 1); } else { READ_UINT8 (nr, dec_ref_pic_m->adaptive_ref_pic_marking_mode_flag, 1); if (dec_ref_pic_m->adaptive_ref_pic_marking_mode_flag) { guint32 mem_mgmt_ctrl_op; GstH264RefPicMarking *refpicmarking; dec_ref_pic_m->n_ref_pic_marking = 0; while (1) { refpicmarking = &dec_ref_pic_m->ref_pic_marking[dec_ref_pic_m->n_ref_pic_marking]; READ_UE (nr, mem_mgmt_ctrl_op); if (mem_mgmt_ctrl_op == 0) break; refpicmarking->memory_management_control_operation = mem_mgmt_ctrl_op; if (mem_mgmt_ctrl_op == 1 || mem_mgmt_ctrl_op == 3) READ_UE (nr, refpicmarking->difference_of_pic_nums_minus1); if (mem_mgmt_ctrl_op == 2) READ_UE (nr, refpicmarking->long_term_pic_num); if (mem_mgmt_ctrl_op == 3 || mem_mgmt_ctrl_op == 6) READ_UE (nr, refpicmarking->long_term_frame_idx); if (mem_mgmt_ctrl_op == 4) READ_UE (nr, refpicmarking->max_long_term_frame_idx_plus1); dec_ref_pic_m->n_ref_pic_marking++; } } } return TRUE; error: GST_WARNING ("error parsing \"Decoded reference picture marking\""); return FALSE; } static gboolean gst_h264_slice_parse_pred_weight_table (GstH264SliceHdr * slice, NalReader * nr, guint8 chroma_array_type) { GstH264PredWeightTable *p; gint16 default_luma_weight, default_chroma_weight; gint i; GST_DEBUG ("parsing \"Prediction weight table\""); p = &slice->pred_weight_table; READ_UE_ALLOWED (nr, p->luma_log2_weight_denom, 0, 7); /* set default values */ default_luma_weight = 1 << p->luma_log2_weight_denom; for (i = 0; i < G_N_ELEMENTS (p->luma_weight_l0); i++) p->luma_weight_l0[i] = default_luma_weight; memset (p->luma_offset_l0, 0, sizeof (p->luma_offset_l0)); if (GST_H264_IS_B_SLICE (slice)) { for (i = 0; i < G_N_ELEMENTS (p->luma_weight_l1); i++) p->luma_weight_l1[i] = default_luma_weight; memset (p->luma_offset_l1, 0, sizeof (p->luma_offset_l1)); } if (chroma_array_type != 0) { READ_UE_ALLOWED (nr, p->chroma_log2_weight_denom, 0, 7); /* set default values */ default_chroma_weight = 1 << p->chroma_log2_weight_denom; for (i = 0; i < G_N_ELEMENTS (p->chroma_weight_l0); i++) { p->chroma_weight_l0[i][0] = default_chroma_weight; p->chroma_weight_l0[i][1] = default_chroma_weight; } memset (p->chroma_offset_l0, 0, sizeof (p->chroma_offset_l0)); if (GST_H264_IS_B_SLICE (slice)) { for (i = 0; i < G_N_ELEMENTS (p->chroma_weight_l1); i++) { p->chroma_weight_l1[i][0] = default_chroma_weight; p->chroma_weight_l1[i][1] = default_chroma_weight; } memset (p->chroma_offset_l1, 0, sizeof (p->chroma_offset_l1)); } } for (i = 0; i <= slice->num_ref_idx_l0_active_minus1; i++) { guint8 luma_weight_l0_flag; READ_UINT8 (nr, luma_weight_l0_flag, 1); if (luma_weight_l0_flag) { READ_SE_ALLOWED (nr, p->luma_weight_l0[i], -128, 127); READ_SE_ALLOWED (nr, p->luma_offset_l0[i], -128, 127); } if (chroma_array_type != 0) { guint8 chroma_weight_l0_flag; gint j; READ_UINT8 (nr, chroma_weight_l0_flag, 1); if (chroma_weight_l0_flag) { for (j = 0; j < 2; j++) { READ_SE_ALLOWED (nr, p->chroma_weight_l0[i][j], -128, 127); READ_SE_ALLOWED (nr, p->chroma_offset_l0[i][j], -128, 127); } } } } if (GST_H264_IS_B_SLICE (slice)) { for (i = 0; i <= slice->num_ref_idx_l1_active_minus1; i++) { guint8 luma_weight_l1_flag; READ_UINT8 (nr, luma_weight_l1_flag, 1); if (luma_weight_l1_flag) { READ_SE_ALLOWED (nr, p->luma_weight_l1[i], -128, 127); READ_SE_ALLOWED (nr, p->luma_offset_l1[i], -128, 127); } if (chroma_array_type != 0) { guint8 chroma_weight_l1_flag; gint j; READ_UINT8 (nr, chroma_weight_l1_flag, 1); if (chroma_weight_l1_flag) { for (j = 0; j < 2; j++) { READ_SE_ALLOWED (nr, p->chroma_weight_l1[i][j], -128, 127); READ_SE_ALLOWED (nr, p->chroma_offset_l1[i][j], -128, 127); } } } } } return TRUE; error: GST_WARNING ("error parsing \"Prediction weight table\""); return FALSE; } static GstH264ParserResult gst_h264_parser_parse_buffering_period (GstH264NalParser * nalparser, GstH264BufferingPeriod * per, NalReader * nr) { GstH264SPS *sps; guint8 sps_id; GST_DEBUG ("parsing \"Buffering period\""); READ_UE_ALLOWED (nr, sps_id, 0, GST_H264_MAX_SPS_COUNT - 1); sps = gst_h264_parser_get_sps (nalparser, sps_id); if (!sps) { GST_WARNING ("couldn't find associated sequence parameter set with id: %d", sps_id); return GST_H264_PARSER_BROKEN_LINK; } per->sps = sps; if (sps->vui_parameters_present_flag) { GstH264VUIParams *vui = &sps->vui_parameters; if (vui->nal_hrd_parameters_present_flag) { GstH264HRDParams *hrd = &vui->nal_hrd_parameters; guint8 sched_sel_idx; for (sched_sel_idx = 0; sched_sel_idx <= hrd->cpb_cnt_minus1; sched_sel_idx++) { READ_UINT8 (nr, per->nal_initial_cpb_removal_delay[sched_sel_idx], 5); READ_UINT8 (nr, per->nal_initial_cpb_removal_delay_offset[sched_sel_idx], 5); } } if (vui->vcl_hrd_parameters_present_flag) { GstH264HRDParams *hrd = &vui->vcl_hrd_parameters; guint8 sched_sel_idx; for (sched_sel_idx = 0; sched_sel_idx <= hrd->cpb_cnt_minus1; sched_sel_idx++) { READ_UINT8 (nr, per->vcl_initial_cpb_removal_delay[sched_sel_idx], 5); READ_UINT8 (nr, per->vcl_initial_cpb_removal_delay_offset[sched_sel_idx], 5); } } } return GST_H264_PARSER_OK; error: GST_WARNING ("error parsing \"Buffering period\""); return GST_H264_PARSER_ERROR; } static gboolean gst_h264_parse_clock_timestamp (GstH264ClockTimestamp * tim, GstH264VUIParams * vui, NalReader * nr) { guint8 full_timestamp_flag; guint8 time_offset_length; GST_DEBUG ("parsing \"Clock timestamp\""); /* defalt values */ tim->time_offset = 0; READ_UINT8 (nr, tim->ct_type, 2); READ_UINT8 (nr, tim->nuit_field_based_flag, 1); READ_UINT8 (nr, tim->counting_type, 5); READ_UINT8 (nr, full_timestamp_flag, 1); READ_UINT8 (nr, tim->discontinuity_flag, 1); READ_UINT8 (nr, tim->cnt_dropped_flag, 1); READ_UINT8 (nr, tim->n_frames, 8); if (full_timestamp_flag) { tim->seconds_flag = TRUE; READ_UINT8 (nr, tim->seconds_value, 6); tim->minutes_flag = TRUE; READ_UINT8 (nr, tim->minutes_value, 6); tim->hours_flag = TRUE; READ_UINT8 (nr, tim->hours_value, 5); } else { READ_UINT8 (nr, tim->seconds_flag, 1); if (tim->seconds_flag) { READ_UINT8 (nr, tim->seconds_value, 6); READ_UINT8 (nr, tim->minutes_flag, 1); if (tim->minutes_flag) { READ_UINT8 (nr, tim->minutes_value, 6); READ_UINT8 (nr, tim->hours_flag, 1); if (tim->hours_flag) READ_UINT8 (nr, tim->hours_value, 5); } } } time_offset_length = 0; if (vui->nal_hrd_parameters_present_flag) time_offset_length = vui->nal_hrd_parameters.time_offset_length; else if (vui->vcl_hrd_parameters_present_flag) time_offset_length = vui->vcl_hrd_parameters.time_offset_length; if (time_offset_length > 0) READ_UINT32 (nr, tim->time_offset, time_offset_length); return TRUE; error: GST_WARNING ("error parsing \"Clock timestamp\""); return FALSE; } static GstH264ParserResult gst_h264_parser_parse_pic_timing (GstH264NalParser * nalparser, GstH264PicTiming * tim, NalReader * nr) { GST_DEBUG ("parsing \"Picture timing\""); if (!nalparser->last_sps || !nalparser->last_sps->valid) { GST_WARNING ("didn't get the associated sequence paramater set for the " "current access unit"); goto error; } /* default values */ memset (tim->clock_timestamp_flag, 0, 3); if (nalparser->last_sps->vui_parameters_present_flag) { GstH264VUIParams *vui = &nalparser->last_sps->vui_parameters; if (vui->nal_hrd_parameters_present_flag) { READ_UINT32 (nr, tim->cpb_removal_delay, vui->nal_hrd_parameters.cpb_removal_delay_length_minus1 + 1); READ_UINT32 (nr, tim->dpb_output_delay, vui->nal_hrd_parameters.dpb_output_delay_length_minus1 + 1); } else if (vui->vcl_hrd_parameters_present_flag) { READ_UINT32 (nr, tim->cpb_removal_delay, vui->vcl_hrd_parameters.cpb_removal_delay_length_minus1 + 1); READ_UINT32 (nr, tim->dpb_output_delay, vui->vcl_hrd_parameters.dpb_output_delay_length_minus1 + 1); } if (vui->pic_struct_present_flag) { const guint8 num_clock_ts_table[9] = { 1, 1, 1, 2, 2, 3, 3, 2, 3 }; guint8 num_clock_num_ts; guint i; tim->pic_struct_present_flag = TRUE; READ_UINT8 (nr, tim->pic_struct, 4); CHECK_ALLOWED ((gint8) tim->pic_struct, 0, 8); num_clock_num_ts = num_clock_ts_table[tim->pic_struct]; for (i = 0; i < num_clock_num_ts; i++) { READ_UINT8 (nr, tim->clock_timestamp_flag[i], 1); if (tim->clock_timestamp_flag[i]) { if (!gst_h264_parse_clock_timestamp (&tim->clock_timestamp[i], vui, nr)) goto error; } } } } return GST_H264_PARSER_OK; error: GST_WARNING ("error parsing \"Picture timing\""); return GST_H264_PARSER_ERROR; } /******** API *************/ /** * gst_h264_nal_parser_new: * * Creates a new #GstH264NalParser. It should be freed with * gst_h264_nal_parser_free after use. * * Returns: a new #GstH264NalParser */ GstH264NalParser * gst_h264_nal_parser_new (void) { GstH264NalParser *nalparser; nalparser = g_slice_new0 (GstH264NalParser); INITIALIZE_DEBUG_CATEGORY; return nalparser; } /** * gst_h264_nal_parser_free: * @nalparser: the #GstH264NalParser to free * * Frees @nalparser and sets it to %NULL */ void gst_h264_nal_parser_free (GstH264NalParser * nalparser) { g_slice_free (GstH264NalParser, nalparser); nalparser = NULL; } /** * gst_h264_parser_identify_nalu_unchecked: * @nalparser: a #GstH264NalParser * @data: The data to parse * @offset: the offset from which to parse @data * @size: the size of @data * @nalu: The #GstH264NalUnit where to store parsed nal headers * * Parses @data and fills @nalu from the next nalu data from @data. * * This differs from @gst_h264_parser_identify_nalu in that it doesn't * check whether the packet is complete or not. * * Note: Only use this function if you already know the provided @data * is a complete NALU, else use @gst_h264_parser_identify_nalu. * * Returns: a #GstH264ParserResult */ GstH264ParserResult gst_h264_parser_identify_nalu_unchecked (GstH264NalParser * nalparser, const guint8 * data, guint offset, gsize size, GstH264NalUnit * nalu) { gint off1; if (size < offset + 4) { GST_DEBUG ("Can't parse, buffer has too small size %" G_GSIZE_FORMAT ", offset %u", size, offset); return GST_H264_PARSER_ERROR; } off1 = scan_for_start_codes (data + offset, size - offset); if (off1 < 0) { GST_DEBUG ("No start code prefix in this buffer"); return GST_H264_PARSER_NO_NAL; } if (offset + off1 == size - 1) { GST_DEBUG ("Missing data to identify nal unit"); return GST_H264_PARSER_ERROR; } nalu->valid = TRUE; nalu->sc_offset = offset + off1; nalu->offset = offset + off1 + 3; nalu->data = (guint8 *) data; set_nalu_datas (nalu); /* sc might have 2 or 3 0-bytes */ if (nalu->sc_offset > 0 && data[nalu->sc_offset - 1] == 00 && (nalu->type == GST_H264_NAL_SPS || nalu->type == GST_H264_NAL_PPS || nalu->type == GST_H264_NAL_AU_DELIMITER)) nalu->sc_offset--; if (nalu->type == GST_H264_NAL_SEQ_END || nalu->type == GST_H264_NAL_STREAM_END) { GST_DEBUG ("end-of-seq or end-of-stream nal found"); nalu->size = 0; return GST_H264_PARSER_OK; } nalu->size = size - nalu->offset; return GST_H264_PARSER_OK; } /** * gst_h264_parser_identify_nalu: * @nalparser: a #GstH264NalParser * @data: The data to parse * @offset: the offset from which to parse @data * @size: the size of @data * @nalu: The #GstH264NalUnit where to store parsed nal headers * * Parses @data and fills @nalu from the next nalu data from @data * * Returns: a #GstH264ParserResult */ GstH264ParserResult gst_h264_parser_identify_nalu (GstH264NalParser * nalparser, const guint8 * data, guint offset, gsize size, GstH264NalUnit * nalu) { GstH264ParserResult res; gint off2; res = gst_h264_parser_identify_nalu_unchecked (nalparser, data, offset, size, nalu); if (res != GST_H264_PARSER_OK || nalu->size == 0) goto beach; off2 = scan_for_start_codes (data + nalu->offset, size - nalu->offset); if (off2 < 0) { GST_DEBUG ("Nal start %d, No end found", nalu->offset); return GST_H264_PARSER_NO_NAL_END; } if (off2 > 0 && data[nalu->offset + off2 - 1] == 00) off2--; nalu->size = off2; if (nalu->size < 2) return GST_H264_PARSER_BROKEN_DATA; GST_DEBUG ("Complete nal found. Off: %d, Size: %d", nalu->offset, nalu->size); beach: return res; } /** * gst_h264_parser_identify_nalu_avc: * @nalparser: a #GstH264NalParser * @data: The data to parse, must be the beging of the Nal unit * @offset: the offset from which to parse @data * @size: the size of @data * @nal_length_size: the size in bytes of the AVC nal length prefix. * @nalu: The #GstH264NalUnit where to store parsed nal headers * * Parses @data and sets @nalu. * * Returns: a #GstH264ParserResult */ GstH264ParserResult gst_h264_parser_identify_nalu_avc (GstH264NalParser * nalparser, const guint8 * data, guint offset, gsize size, guint8 nal_length_size, GstH264NalUnit * nalu) { GstBitReader br; if (size < offset + nal_length_size) { GST_DEBUG ("Can't parse, buffer has too small size %" G_GSIZE_FORMAT ", offset %u", size, offset); return GST_H264_PARSER_ERROR; } size = size - offset; gst_bit_reader_init (&br, data + offset, size); nalu->size = gst_bit_reader_get_bits_uint32_unchecked (&br, nal_length_size * 8); nalu->sc_offset = offset; nalu->offset = offset + nal_length_size; if (size < nalu->size + nal_length_size) { nalu->size = 0; return GST_H264_PARSER_NO_NAL_END; } nalu->data = (guint8 *) data; set_nalu_datas (nalu); if (nalu->size < 2) return GST_H264_PARSER_BROKEN_DATA; nalu->valid = TRUE; return GST_H264_PARSER_OK; } /** * gst_h264_parser_parse_nal: * @nalparser: a #GstH264NalParser * @nalu: The #GstH264NalUnit to parse * * This function should be called in the case one doesn't need to * parse a specific structure. It is necessary to do so to make * sure @nalparser is up to date. * * Returns: a #GstH264ParserResult */ GstH264ParserResult gst_h264_parser_parse_nal (GstH264NalParser * nalparser, GstH264NalUnit * nalu) { GstH264SPS sps; GstH264PPS pps; switch (nalu->type) { case GST_H264_NAL_SPS: return gst_h264_parser_parse_sps (nalparser, nalu, &sps, FALSE); break; case GST_H264_NAL_PPS: return gst_h264_parser_parse_pps (nalparser, nalu, &pps); } return GST_H264_PARSER_OK; } /** * gst_h264_parser_parse_sps: * @nalparser: a #GstH264NalParser * @nalu: The #GST_H264_NAL_SPS #GstH264NalUnit to parse * @sps: The #GstH264SPS to fill. * @parse_vui_params: Whether to parse the vui_params or not * * Parses @data, and fills the @sps structure. * * Returns: a #GstH264ParserResult */ GstH264ParserResult gst_h264_parser_parse_sps (GstH264NalParser * nalparser, GstH264NalUnit * nalu, GstH264SPS * sps, gboolean parse_vui_params) { GstH264ParserResult res = gst_h264_parse_sps (nalu, sps, parse_vui_params); if (res == GST_H264_PARSER_OK) { GST_DEBUG ("adding sequence parameter set with id: %d to array", sps->id); nalparser->sps[sps->id] = *sps; nalparser->last_sps = &nalparser->sps[sps->id]; } return res; } /** * gst_h264_parse_sps: * @nalu: The #GST_H264_NAL_SPS #GstH264NalUnit to parse * @sps: The #GstH264SPS to fill. * @parse_vui_params: Whether to parse the vui_params or not * * Parses @data, and fills the @sps structure. * * Returns: a #GstH264ParserResult */ GstH264ParserResult gst_h264_parse_sps (GstH264NalUnit * nalu, GstH264SPS * sps, gboolean parse_vui_params) { NalReader nr; gint width, height; guint subwc[] = { 1, 2, 2, 1 }; guint subhc[] = { 1, 2, 1, 1 }; GstH264VUIParams *vui = NULL; INITIALIZE_DEBUG_CATEGORY; GST_DEBUG ("parsing SPS"); nal_reader_init (&nr, nalu->data + nalu->offset + 1, nalu->size - 1); /* set default values for fields that might not be present in the bitstream and have valid defaults */ sps->chroma_format_idc = 1; sps->separate_colour_plane_flag = 0; sps->bit_depth_luma_minus8 = 0; sps->bit_depth_chroma_minus8 = 0; memset (sps->scaling_lists_4x4, 16, 96); memset (sps->scaling_lists_8x8, 16, 384); memset (&sps->vui_parameters, 0, sizeof (sps->vui_parameters)); sps->mb_adaptive_frame_field_flag = 0; sps->frame_crop_left_offset = 0; sps->frame_crop_right_offset = 0; sps->frame_crop_top_offset = 0; sps->frame_crop_bottom_offset = 0; sps->delta_pic_order_always_zero_flag = 0; READ_UINT8 (&nr, sps->profile_idc, 8); READ_UINT8 (&nr, sps->constraint_set0_flag, 1); READ_UINT8 (&nr, sps->constraint_set1_flag, 1); READ_UINT8 (&nr, sps->constraint_set2_flag, 1); READ_UINT8 (&nr, sps->constraint_set3_flag, 1); /* skip reserved_zero_4bits */ if (!nal_reader_skip (&nr, 4)) goto error; READ_UINT8 (&nr, sps->level_idc, 8); READ_UE_ALLOWED (&nr, sps->id, 0, GST_H264_MAX_SPS_COUNT - 1); if (sps->profile_idc == 100 || sps->profile_idc == 110 || sps->profile_idc == 122 || sps->profile_idc == 244 || sps->profile_idc == 44 || sps->profile_idc == 83 || sps->profile_idc == 86) { READ_UE_ALLOWED (&nr, sps->chroma_format_idc, 0, 3); if (sps->chroma_format_idc == 3) READ_UINT8 (&nr, sps->separate_colour_plane_flag, 1); READ_UE_ALLOWED (&nr, sps->bit_depth_luma_minus8, 0, 6); READ_UE_ALLOWED (&nr, sps->bit_depth_chroma_minus8, 0, 6); READ_UINT8 (&nr, sps->qpprime_y_zero_transform_bypass_flag, 1); READ_UINT8 (&nr, sps->scaling_matrix_present_flag, 1); if (sps->scaling_matrix_present_flag) { guint8 n_lists; n_lists = (sps->chroma_format_idc != 3) ? 8 : 12; if (!gst_h264_parser_parse_scaling_list (&nr, sps->scaling_lists_4x4, sps->scaling_lists_8x8, default_4x4_inter, default_4x4_intra, default_8x8_inter, default_8x8_intra, n_lists)) goto error; } } READ_UE_ALLOWED (&nr, sps->log2_max_frame_num_minus4, 0, 12); sps->max_frame_num = 1 << (sps->log2_max_frame_num_minus4 + 4); READ_UE_ALLOWED (&nr, sps->pic_order_cnt_type, 0, 2); if (sps->pic_order_cnt_type == 0) { READ_UE_ALLOWED (&nr, sps->log2_max_pic_order_cnt_lsb_minus4, 0, 12); } else if (sps->pic_order_cnt_type == 1) { guint i; READ_UINT8 (&nr, sps->delta_pic_order_always_zero_flag, 1); READ_SE (&nr, sps->offset_for_non_ref_pic); READ_SE (&nr, sps->offset_for_top_to_bottom_field); READ_UE_ALLOWED (&nr, sps->num_ref_frames_in_pic_order_cnt_cycle, 0, 255); for (i = 0; i < sps->num_ref_frames_in_pic_order_cnt_cycle; i++) READ_SE (&nr, sps->offset_for_ref_frame[i]); } READ_UE (&nr, sps->num_ref_frames); READ_UINT8 (&nr, sps->gaps_in_frame_num_value_allowed_flag, 1); READ_UE (&nr, sps->pic_width_in_mbs_minus1); READ_UE (&nr, sps->pic_height_in_map_units_minus1); READ_UINT8 (&nr, sps->frame_mbs_only_flag, 1); if (!sps->frame_mbs_only_flag) READ_UINT8 (&nr, sps->mb_adaptive_frame_field_flag, 1); READ_UINT8 (&nr, sps->direct_8x8_inference_flag, 1); READ_UINT8 (&nr, sps->frame_cropping_flag, 1); if (sps->frame_cropping_flag) { READ_UE (&nr, sps->frame_crop_left_offset); READ_UE (&nr, sps->frame_crop_right_offset); READ_UE (&nr, sps->frame_crop_top_offset); READ_UE (&nr, sps->frame_crop_bottom_offset); } READ_UINT8 (&nr, sps->vui_parameters_present_flag, 1); if (sps->vui_parameters_present_flag && parse_vui_params) { if (!gst_h264_parse_vui_parameters (sps, &nr)) goto error; vui = &sps->vui_parameters; } /* calculate ChromaArrayType */ if (sps->separate_colour_plane_flag) sps->chroma_array_type = 0; else sps->chroma_array_type = sps->chroma_format_idc; /* Calculate width and height */ width = (sps->pic_width_in_mbs_minus1 + 1); width *= 16; height = (sps->pic_height_in_map_units_minus1 + 1); height *= 16 * (2 - sps->frame_mbs_only_flag); GST_LOG ("initial width=%d, height=%d", width, height); if (width < 0 || height < 0) { GST_WARNING ("invalid width/height in SPS"); goto error; } sps->width = width; sps->height = height; if (sps->frame_cropping_flag) { const guint crop_unit_x = subwc[sps->chroma_format_idc]; const guint crop_unit_y = subhc[sps->chroma_format_idc] * (2 - sps->frame_mbs_only_flag); width -= (sps->frame_crop_left_offset + sps->frame_crop_right_offset) * crop_unit_x; height -= (sps->frame_crop_top_offset + sps->frame_crop_bottom_offset) * crop_unit_y; sps->crop_rect_width = width; sps->crop_rect_height = height; sps->crop_rect_x = sps->frame_crop_left_offset * crop_unit_x; sps->crop_rect_y = sps->frame_crop_top_offset * crop_unit_y; GST_LOG ("crop_rectangle x=%u y=%u width=%u, height=%u", sps->crop_rect_x, sps->crop_rect_y, width, height); } sps->fps_num = 0; sps->fps_den = 1; if (vui && vui->timing_info_present_flag) { /* derive framerate */ /* FIXME verify / also handle other cases */ GST_LOG ("Framerate: %u %u %u %u", parse_vui_params, vui->fixed_frame_rate_flag, sps->frame_mbs_only_flag, vui->pic_struct_present_flag); if (parse_vui_params && vui->fixed_frame_rate_flag && sps->frame_mbs_only_flag && !vui->pic_struct_present_flag) { sps->fps_num = vui->time_scale; sps->fps_den = vui->num_units_in_tick; /* picture is a frame = 2 fields */ sps->fps_den *= 2; GST_LOG ("framerate %d/%d", sps->fps_num, sps->fps_den); } } else { GST_LOG ("No VUI, unknown framerate"); } sps->valid = TRUE; return GST_H264_PARSER_OK; error: GST_WARNING ("error parsing \"Sequence parameter set\""); sps->valid = FALSE; return GST_H264_PARSER_ERROR; } /** * gst_h264_parse_pps: * @nalparser: a #GstH264NalParser * @nalu: The #GST_H264_NAL_PPS #GstH264NalUnit to parse * @pps: The #GstH264PPS to fill. * * Parses @data, and fills the @pps structure. * * Returns: a #GstH264ParserResult */ GstH264ParserResult gst_h264_parse_pps (GstH264NalParser * nalparser, GstH264NalUnit * nalu, GstH264PPS * pps) { NalReader nr; GstH264SPS *sps; gint sps_id; guint8 pic_scaling_matrix_present_flag; gint qp_bd_offset; INITIALIZE_DEBUG_CATEGORY; GST_DEBUG ("parsing PPS"); nal_reader_init (&nr, nalu->data + nalu->offset + 1, nalu->size - 1); READ_UE_ALLOWED (&nr, pps->id, 0, GST_H264_MAX_PPS_COUNT - 1); READ_UE_ALLOWED (&nr, sps_id, 0, GST_H264_MAX_SPS_COUNT - 1); sps = gst_h264_parser_get_sps (nalparser, sps_id); if (!sps) { GST_WARNING ("couldn't find associated sequence parameter set with id: %d", sps_id); return GST_H264_PARSER_BROKEN_LINK; } pps->sequence = sps; qp_bd_offset = 6 * (sps->bit_depth_luma_minus8 + sps->separate_colour_plane_flag); /* set default values for fields that might not be present in the bitstream and have valid defaults */ pps->slice_group_id = NULL; pps->transform_8x8_mode_flag = 0; memcpy (&pps->scaling_lists_4x4, &sps->scaling_lists_4x4, 96); memcpy (&pps->scaling_lists_8x8, &sps->scaling_lists_8x8, 384); READ_UINT8 (&nr, pps->entropy_coding_mode_flag, 1); READ_UINT8 (&nr, pps->pic_order_present_flag, 1); READ_UE_ALLOWED (&nr, pps->num_slice_groups_minus1, 0, 7); if (pps->num_slice_groups_minus1 > 0) { READ_UE_ALLOWED (&nr, pps->slice_group_map_type, 0, 6); if (pps->slice_group_map_type == 0) { gint i; for (i = 0; i <= pps->num_slice_groups_minus1; i++) READ_UE (&nr, pps->run_length_minus1[i]); } else if (pps->slice_group_map_type == 2) { gint i; for (i = 0; i <= pps->num_slice_groups_minus1; i++) { READ_UE (&nr, pps->top_left[i]); READ_UE (&nr, pps->bottom_right[i]); } } else if (pps->slice_group_map_type >= 3 && pps->slice_group_map_type <= 5) { READ_UINT8 (&nr, pps->slice_group_change_direction_flag, 1); READ_UE (&nr, pps->slice_group_change_rate_minus1); } else if (pps->slice_group_map_type == 6) { gint bits; gint i; READ_UE (&nr, pps->pic_size_in_map_units_minus1); bits = g_bit_storage (pps->num_slice_groups_minus1); pps->slice_group_id = g_new (guint8, pps->pic_size_in_map_units_minus1 + 1); for (i = 0; i <= pps->pic_size_in_map_units_minus1; i++) READ_UINT8 (&nr, pps->slice_group_id[i], bits); } } READ_UE_ALLOWED (&nr, pps->num_ref_idx_l0_active_minus1, 0, 31); READ_UE_ALLOWED (&nr, pps->num_ref_idx_l1_active_minus1, 0, 31); READ_UINT8 (&nr, pps->weighted_pred_flag, 1); READ_UINT8 (&nr, pps->weighted_bipred_idc, 2); READ_SE_ALLOWED (&nr, pps->pic_init_qp_minus26, -(26 + qp_bd_offset), 25); READ_SE_ALLOWED (&nr, pps->pic_init_qs_minus26, -26, 25); READ_SE_ALLOWED (&nr, pps->chroma_qp_index_offset, -12, 12); pps->second_chroma_qp_index_offset = pps->chroma_qp_index_offset; READ_UINT8 (&nr, pps->deblocking_filter_control_present_flag, 1); READ_UINT8 (&nr, pps->constrained_intra_pred_flag, 1); READ_UINT8 (&nr, pps->redundant_pic_cnt_present_flag, 1); if (!gst_h264_parser_more_data (&nr)) goto done; READ_UINT8 (&nr, pps->transform_8x8_mode_flag, 1); READ_UINT8 (&nr, pic_scaling_matrix_present_flag, 1); if (pic_scaling_matrix_present_flag) { guint8 n_lists; n_lists = 6 + ((sps->chroma_format_idc != 3) ? 2 : 6) * pps->transform_8x8_mode_flag; if (sps->scaling_matrix_present_flag) { if (!gst_h264_parser_parse_scaling_list (&nr, pps->scaling_lists_4x4, pps->scaling_lists_8x8, sps->scaling_lists_4x4[3], sps->scaling_lists_4x4[0], sps->scaling_lists_8x8[3], sps->scaling_lists_8x8[0], n_lists)) goto error; } else { if (!gst_h264_parser_parse_scaling_list (&nr, pps->scaling_lists_4x4, pps->scaling_lists_8x8, default_4x4_inter, default_4x4_intra, default_8x8_inter, default_8x8_intra, n_lists)) goto error; } } READ_SE_ALLOWED (&nr, pps->second_chroma_qp_index_offset, -12, 12); done: pps->valid = TRUE; return GST_H264_PARSER_OK; error: GST_WARNING ("error parsing \"Picture parameter set\""); pps->valid = FALSE; return GST_H264_PARSER_ERROR; } /** * gst_h264_parser_parse_pps: * @nalparser: a #GstH264NalParser * @nalu: The #GST_H264_NAL_PPS #GstH264NalUnit to parse * @pps: The #GstH264PPS to fill. * * Parses @data, and fills the @pps structure. * * Returns: a #GstH264ParserResult */ GstH264ParserResult gst_h264_parser_parse_pps (GstH264NalParser * nalparser, GstH264NalUnit * nalu, GstH264PPS * pps) { GstH264ParserResult res = gst_h264_parse_pps (nalparser, nalu, pps); if (res == GST_H264_PARSER_OK) { GST_DEBUG ("adding picture parameter set with id: %d to array", pps->id); nalparser->pps[pps->id] = *pps; nalparser->last_pps = &nalparser->pps[pps->id]; } return res; } /** * gst_h264_parser_parse_slice_hdr: * @nalparser: a #GstH264NalParser * @nalu: The #GST_H264_NAL_SLICE #GstH264NalUnit to parse * @slice: The #GstH264SliceHdr to fill. * @parse_pred_weight_table: Whether to parse the pred_weight_table or not * @parse_dec_ref_pic_marking: Whether to parse the dec_ref_pic_marking or not * * Parses @data, and fills the @slice structure. * * Returns: a #GstH264ParserResult */ GstH264ParserResult gst_h264_parser_parse_slice_hdr (GstH264NalParser * nalparser, GstH264NalUnit * nalu, GstH264SliceHdr * slice, gboolean parse_pred_weight_table, gboolean parse_dec_ref_pic_marking) { NalReader nr; gint pps_id; GstH264PPS *pps; GstH264SPS *sps; if (!nalu->size) { GST_DEBUG ("Invalid Nal Unit"); return GST_H264_PARSER_ERROR; } nal_reader_init (&nr, nalu->data + nalu->offset + 1, nalu->size - 1); READ_UE (&nr, slice->first_mb_in_slice); READ_UE (&nr, slice->type); GST_DEBUG ("parsing \"Slice header\", slice type %u", slice->type); READ_UE_ALLOWED (&nr, pps_id, 0, GST_H264_MAX_PPS_COUNT - 1); pps = gst_h264_parser_get_pps (nalparser, pps_id); if (!pps) { GST_WARNING ("couldn't find associated picture parameter set with id: %d", pps_id); return GST_H264_PARSER_BROKEN_LINK; } slice->pps = pps; sps = pps->sequence; if (!sps) { GST_WARNING ("couldn't find associated sequence parameter set with id: %d", pps->id); return GST_H264_PARSER_BROKEN_LINK; } /* set default values for fields that might not be present in the bitstream and have valid defaults */ slice->field_pic_flag = 0; slice->bottom_field_flag = 0; slice->delta_pic_order_cnt_bottom = 0; slice->delta_pic_order_cnt[0] = 0; slice->delta_pic_order_cnt[1] = 0; slice->redundant_pic_cnt = 0; slice->num_ref_idx_l0_active_minus1 = pps->num_ref_idx_l0_active_minus1; slice->num_ref_idx_l1_active_minus1 = pps->num_ref_idx_l1_active_minus1; slice->disable_deblocking_filter_idc = 0; slice->slice_alpha_c0_offset_div2 = 0; slice->slice_beta_offset_div2 = 0; if (sps->separate_colour_plane_flag) READ_UINT8 (&nr, slice->colour_plane_id, 2); READ_UINT16 (&nr, slice->frame_num, sps->log2_max_frame_num_minus4 + 4); if (!sps->frame_mbs_only_flag) { READ_UINT8 (&nr, slice->field_pic_flag, 1); if (slice->field_pic_flag) READ_UINT8 (&nr, slice->bottom_field_flag, 1); } /* calculate MaxPicNum */ if (slice->field_pic_flag) slice->max_pic_num = sps->max_frame_num; else slice->max_pic_num = 2 * sps->max_frame_num; if (nalu->type == 5) READ_UE_ALLOWED (&nr, slice->idr_pic_id, 0, G_MAXUINT16); if (sps->pic_order_cnt_type == 0) { READ_UINT16 (&nr, slice->pic_order_cnt_lsb, sps->log2_max_pic_order_cnt_lsb_minus4 + 4); if (pps->pic_order_present_flag && !slice->field_pic_flag) READ_SE (&nr, slice->delta_pic_order_cnt_bottom); } if (sps->pic_order_cnt_type == 1 && !sps->delta_pic_order_always_zero_flag) { READ_SE (&nr, slice->delta_pic_order_cnt[0]); if (pps->pic_order_present_flag && !slice->field_pic_flag) READ_SE (&nr, slice->delta_pic_order_cnt[1]); } if (pps->redundant_pic_cnt_present_flag) READ_UE_ALLOWED (&nr, slice->redundant_pic_cnt, 0, G_MAXINT8); if (GST_H264_IS_B_SLICE (slice)) READ_UINT8 (&nr, slice->direct_spatial_mv_pred_flag, 1); if (GST_H264_IS_P_SLICE (slice) || GST_H264_IS_SP_SLICE (slice) || GST_H264_IS_B_SLICE (slice)) { guint8 num_ref_idx_active_override_flag; READ_UINT8 (&nr, num_ref_idx_active_override_flag, 1); if (num_ref_idx_active_override_flag) { READ_UE_ALLOWED (&nr, slice->num_ref_idx_l0_active_minus1, 0, 31); if (GST_H264_IS_B_SLICE (slice)) READ_UE_ALLOWED (&nr, slice->num_ref_idx_l1_active_minus1, 0, 31); } } if (!slice_parse_ref_pic_list_modification (slice, &nr)) goto error; if ((pps->weighted_pred_flag && (GST_H264_IS_P_SLICE (slice) || GST_H264_IS_SP_SLICE (slice))) || (pps->weighted_bipred_idc == 1 && GST_H264_IS_B_SLICE (slice))) { if (!gst_h264_slice_parse_pred_weight_table (slice, &nr, sps->chroma_array_type)) goto error; } if (nalu->ref_idc != 0) { if (!gst_h264_slice_parse_dec_ref_pic_marking (slice, nalu, &nr)) goto error; } if (pps->entropy_coding_mode_flag && !GST_H264_IS_I_SLICE (slice) && !GST_H264_IS_SI_SLICE (slice)) READ_UE_ALLOWED (&nr, slice->cabac_init_idc, 0, 2); READ_SE_ALLOWED (&nr, slice->slice_qp_delta, -87, 77); if (GST_H264_IS_SP_SLICE (slice) || GST_H264_IS_SI_SLICE (slice)) { guint8 sp_for_switch_flag; if (GST_H264_IS_SP_SLICE (slice)) READ_UINT8 (&nr, sp_for_switch_flag, 1); READ_SE_ALLOWED (&nr, slice->slice_qs_delta, -51, 51); } if (pps->deblocking_filter_control_present_flag) { READ_UE_ALLOWED (&nr, slice->disable_deblocking_filter_idc, 0, 2); if (slice->disable_deblocking_filter_idc != 1) { READ_SE_ALLOWED (&nr, slice->slice_alpha_c0_offset_div2, -6, 6); READ_SE_ALLOWED (&nr, slice->slice_beta_offset_div2, -6, 6); } } if (pps->num_slice_groups_minus1 > 0 && pps->slice_group_map_type >= 3 && pps->slice_group_map_type <= 5) { /* Ceil(Log2(PicSizeInMapUnits / SliceGroupChangeRate + 1)) [7-33] */ guint32 PicWidthInMbs = sps->pic_width_in_mbs_minus1 + 1; guint32 PicHeightInMapUnits = sps->pic_height_in_map_units_minus1 + 1; guint32 PicSizeInMapUnits = PicWidthInMbs * PicHeightInMapUnits; guint32 SliceGroupChangeRate = pps->slice_group_change_rate_minus1 + 1; const guint n = ceil_log2 (PicSizeInMapUnits / SliceGroupChangeRate + 1); READ_UINT16 (&nr, slice->slice_group_change_cycle, n); } slice->header_size = nal_reader_get_pos (&nr); slice->n_emulation_prevention_bytes = nal_reader_get_epb_count (&nr); return GST_H264_PARSER_OK; error: GST_WARNING ("error parsing \"Slice header\""); return GST_H264_PARSER_ERROR; } /** * gst_h264_parser_parse_sei: * @nalparser: a #GstH264NalParser * @nalu: The #GST_H264_NAL_SEI #GstH264NalUnit to parse * @sei: The #GstH264SEIMessage to fill. * * Parses @data, and fills the @sei structures. * * Returns: a #GstH264ParserResult */ GstH264ParserResult gst_h264_parser_parse_sei (GstH264NalParser * nalparser, GstH264NalUnit * nalu, GstH264SEIMessage * sei) { NalReader nr; guint32 payloadSize; guint8 payload_type_byte, payload_size_byte; #ifndef GST_DISABLE_GST_DEBUG guint remaining, payload_size; #endif GstH264ParserResult res; GST_DEBUG ("parsing \"Sei message\""); nal_reader_init (&nr, nalu->data + nalu->offset + 1, nalu->size - 1); /* init */ memset (sei, 0, sizeof (*sei)); sei->payloadType = 0; do { READ_UINT8 (&nr, payload_type_byte, 8); sei->payloadType += payload_type_byte; } while (payload_type_byte == 0xff); payloadSize = 0; do { READ_UINT8 (&nr, payload_size_byte, 8); payloadSize += payload_size_byte; } while (payload_size_byte == 0xff); #ifndef GST_DISABLE_GST_DEBUG remaining = nal_reader_get_remaining (&nr) * 8; payload_size = payloadSize < remaining ? payloadSize : remaining; GST_DEBUG ("SEI message received: payloadType %u, payloadSize = %u bytes", sei->payloadType, payload_size); #endif if (sei->payloadType == GST_H264_SEI_BUF_PERIOD) { /* size not set; might depend on emulation_prevention_three_byte */ res = gst_h264_parser_parse_buffering_period (nalparser, &sei->payload.buffering_period, &nr); } else if (sei->payloadType == GST_H264_SEI_PIC_TIMING) { /* size not set; might depend on emulation_prevention_three_byte */ res = gst_h264_parser_parse_pic_timing (nalparser, &sei->payload.pic_timing, &nr); } else res = GST_H264_PARSER_OK; return res; error: GST_WARNING ("error parsing \"Sei message\""); return GST_H264_PARSER_ERROR; } /** * gst_h264_video_quant_matrix_8x8_get_zigzag_from_raster: * @out_quant: (out): The resulting quantization matrix * @quant: The source quantization matrix * * Converts quantization matrix @quant from raster scan order to * zigzag scan order and store the resulting factors into @out_quant. * * Note: it is an error to pass the same table in both @quant and * @out_quant arguments. * * Since: 1.4 */ void gst_h264_video_quant_matrix_8x8_get_zigzag_from_raster (guint8 out_quant[64], const guint8 quant[64]) { guint i; g_return_if_fail (out_quant != quant); for (i = 0; i < 64; i++) out_quant[i] = quant[zigzag_8x8[i]]; } /** * gst_h264_quant_matrix_8x8_get_raster_from_zigzag: * @out_quant: (out): The resulting quantization matrix * @quant: The source quantization matrix * * Converts quantization matrix @quant from zigzag scan order to * raster scan order and store the resulting factors into @out_quant. * * Note: it is an error to pass the same table in both @quant and * @out_quant arguments. * * Since: 1.4 */ void gst_h264_video_quant_matrix_8x8_get_raster_from_zigzag (guint8 out_quant[64], const guint8 quant[64]) { guint i; g_return_if_fail (out_quant != quant); for (i = 0; i < 64; i++) out_quant[zigzag_8x8[i]] = quant[i]; } /** * gst_h264_video_quant_matrix_4x4_get_zigzag_from_raster: * @out_quant: (out): The resulting quantization matrix * @quant: The source quantization matrix * * Converts quantization matrix @quant from raster scan order to * zigzag scan order and store the resulting factors into @out_quant. * * Note: it is an error to pass the same table in both @quant and * @out_quant arguments. * * Since: 1.4 */ void gst_h264_video_quant_matrix_4x4_get_zigzag_from_raster (guint8 out_quant[16], const guint8 quant[16]) { guint i; g_return_if_fail (out_quant != quant); for (i = 0; i < 16; i++) out_quant[i] = quant[zigzag_4x4[i]]; } /** * gst_h264_quant_matrix_4x4_get_raster_from_zigzag: * @out_quant: (out): The resulting quantization matrix * @quant: The source quantization matrix * * Converts quantization matrix @quant from zigzag scan order to * raster scan order and store the resulting factors into @out_quant. * * Note: it is an error to pass the same table in both @quant and * @out_quant arguments. * * Since: 1.4 */ void gst_h264_video_quant_matrix_4x4_get_raster_from_zigzag (guint8 out_quant[16], const guint8 quant[16]) { guint i; g_return_if_fail (out_quant != quant); for (i = 0; i < 16; i++) out_quant[zigzag_4x4[i]] = quant[i]; }