/* * This file is part of FFmpeg. * * FFmpeg is free software; you can redistribute it and/or * modify it under the terms of the GNU Lesser General Public * License as published by the Free Software Foundation; either * version 2.1 of the License, or (at your option) any later version. * * FFmpeg 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 * Lesser General Public License for more details. * * You should have received a copy of the GNU Lesser General Public * License along with FFmpeg; if not, write to the Free Software * Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA */ #include "libavutil/avassert.h" #include "libavutil/pixfmt.h" #include "cbs.h" #include "cbs_internal.h" #include "cbs_av1.h" #include "internal.h" static int cbs_av1_read_uvlc(CodedBitstreamContext *ctx, GetBitContext *gbc, const char *name, uint32_t *write_to, uint32_t range_min, uint32_t range_max) { uint32_t zeroes, bits_value, value; int position; if (ctx->trace_enable) position = get_bits_count(gbc); zeroes = 0; while (zeroes < 32) { if (get_bits_left(gbc) < 1) { av_log(ctx->log_ctx, AV_LOG_ERROR, "Invalid uvlc code at " "%s: bitstream ended.\n", name); return AVERROR_INVALIDDATA; } if (get_bits1(gbc)) break; ++zeroes; } if (zeroes >= 32) { // The spec allows at least thirty-two zero bits followed by a // one to mean 2^32-1, with no constraint on the number of // zeroes. The libaom reference decoder does not match this, // instead reading thirty-two zeroes but not the following one // to mean 2^32-1. These two interpretations are incompatible // and other implementations may follow one or the other. // Therefore we reject thirty-two zeroes because the intended // behaviour is not clear. av_log(ctx->log_ctx, AV_LOG_ERROR, "Thirty-two zero bits in " "%s uvlc code: considered invalid due to conflicting " "standard and reference decoder behaviour.\n", name); return AVERROR_INVALIDDATA; } else { if (get_bits_left(gbc) < zeroes) { av_log(ctx->log_ctx, AV_LOG_ERROR, "Invalid uvlc code at " "%s: bitstream ended.\n", name); return AVERROR_INVALIDDATA; } bits_value = get_bits_long(gbc, zeroes); value = bits_value + (UINT32_C(1) << zeroes) - 1; } if (ctx->trace_enable) { char bits[65]; int i, j, k; if (zeroes >= 32) { while (zeroes > 32) { k = FFMIN(zeroes - 32, 32); for (i = 0; i < k; i++) bits[i] = '0'; bits[i] = 0; ff_cbs_trace_syntax_element(ctx, position, name, NULL, bits, 0); zeroes -= k; position += k; } } for (i = 0; i < zeroes; i++) bits[i] = '0'; bits[i++] = '1'; if (zeroes < 32) { for (j = 0; j < zeroes; j++) bits[i++] = (bits_value >> (zeroes - j - 1) & 1) ? '1' : '0'; } bits[i] = 0; ff_cbs_trace_syntax_element(ctx, position, name, NULL, bits, value); } if (value < range_min || value > range_max) { av_log(ctx->log_ctx, AV_LOG_ERROR, "%s out of range: " "%"PRIu32", but must be in [%"PRIu32",%"PRIu32"].\n", name, value, range_min, range_max); return AVERROR_INVALIDDATA; } *write_to = value; return 0; } static int cbs_av1_write_uvlc(CodedBitstreamContext *ctx, PutBitContext *pbc, const char *name, uint32_t value, uint32_t range_min, uint32_t range_max) { uint32_t v; int position, zeroes; if (value < range_min || value > range_max) { av_log(ctx->log_ctx, AV_LOG_ERROR, "%s out of range: " "%"PRIu32", but must be in [%"PRIu32",%"PRIu32"].\n", name, value, range_min, range_max); return AVERROR_INVALIDDATA; } if (ctx->trace_enable) position = put_bits_count(pbc); if (value == 0) { zeroes = 0; put_bits(pbc, 1, 1); } else { zeroes = av_log2(value + 1); v = value - (1U << zeroes) + 1; put_bits(pbc, zeroes, 0); put_bits(pbc, 1, 1); put_bits(pbc, zeroes, v); } if (ctx->trace_enable) { char bits[65]; int i, j; i = 0; for (j = 0; j < zeroes; j++) bits[i++] = '0'; bits[i++] = '1'; for (j = 0; j < zeroes; j++) bits[i++] = (v >> (zeroes - j - 1) & 1) ? '1' : '0'; bits[i++] = 0; ff_cbs_trace_syntax_element(ctx, position, name, NULL, bits, value); } return 0; } static int cbs_av1_read_leb128(CodedBitstreamContext *ctx, GetBitContext *gbc, const char *name, uint64_t *write_to) { uint64_t value; int position, err, i; if (ctx->trace_enable) position = get_bits_count(gbc); value = 0; for (i = 0; i < 8; i++) { int subscript[2] = { 1, i }; uint32_t byte; err = ff_cbs_read_unsigned(ctx, gbc, 8, "leb128_byte[i]", subscript, &byte, 0x00, 0xff); if (err < 0) return err; value |= (uint64_t)(byte & 0x7f) << (i * 7); if (!(byte & 0x80)) break; } if (value > UINT32_MAX) return AVERROR_INVALIDDATA; if (ctx->trace_enable) ff_cbs_trace_syntax_element(ctx, position, name, NULL, "", value); *write_to = value; return 0; } static int cbs_av1_write_leb128(CodedBitstreamContext *ctx, PutBitContext *pbc, const char *name, uint64_t value) { int position, err, len, i; uint8_t byte; len = (av_log2(value) + 7) / 7; if (ctx->trace_enable) position = put_bits_count(pbc); for (i = 0; i < len; i++) { int subscript[2] = { 1, i }; byte = value >> (7 * i) & 0x7f; if (i < len - 1) byte |= 0x80; err = ff_cbs_write_unsigned(ctx, pbc, 8, "leb128_byte[i]", subscript, byte, 0x00, 0xff); if (err < 0) return err; } if (ctx->trace_enable) ff_cbs_trace_syntax_element(ctx, position, name, NULL, "", value); return 0; } static int cbs_av1_read_ns(CodedBitstreamContext *ctx, GetBitContext *gbc, uint32_t n, const char *name, const int *subscripts, uint32_t *write_to) { uint32_t w, m, v, extra_bit, value; int position; av_assert0(n > 0); if (ctx->trace_enable) position = get_bits_count(gbc); w = av_log2(n) + 1; m = (1 << w) - n; if (get_bits_left(gbc) < w) { av_log(ctx->log_ctx, AV_LOG_ERROR, "Invalid non-symmetric value at " "%s: bitstream ended.\n", name); return AVERROR_INVALIDDATA; } if (w - 1 > 0) v = get_bits(gbc, w - 1); else v = 0; if (v < m) { value = v; } else { extra_bit = get_bits1(gbc); value = (v << 1) - m + extra_bit; } if (ctx->trace_enable) { char bits[33]; int i; for (i = 0; i < w - 1; i++) bits[i] = (v >> i & 1) ? '1' : '0'; if (v >= m) bits[i++] = extra_bit ? '1' : '0'; bits[i] = 0; ff_cbs_trace_syntax_element(ctx, position, name, subscripts, bits, value); } *write_to = value; return 0; } static int cbs_av1_write_ns(CodedBitstreamContext *ctx, PutBitContext *pbc, uint32_t n, const char *name, const int *subscripts, uint32_t value) { uint32_t w, m, v, extra_bit; int position; if (value > n) { av_log(ctx->log_ctx, AV_LOG_ERROR, "%s out of range: " "%"PRIu32", but must be in [0,%"PRIu32"].\n", name, value, n); return AVERROR_INVALIDDATA; } if (ctx->trace_enable) position = put_bits_count(pbc); w = av_log2(n) + 1; m = (1 << w) - n; if (put_bits_left(pbc) < w) return AVERROR(ENOSPC); if (value < m) { v = value; put_bits(pbc, w - 1, v); } else { v = m + ((value - m) >> 1); extra_bit = (value - m) & 1; put_bits(pbc, w - 1, v); put_bits(pbc, 1, extra_bit); } if (ctx->trace_enable) { char bits[33]; int i; for (i = 0; i < w - 1; i++) bits[i] = (v >> i & 1) ? '1' : '0'; if (value >= m) bits[i++] = extra_bit ? '1' : '0'; bits[i] = 0; ff_cbs_trace_syntax_element(ctx, position, name, subscripts, bits, value); } return 0; } static int cbs_av1_read_increment(CodedBitstreamContext *ctx, GetBitContext *gbc, uint32_t range_min, uint32_t range_max, const char *name, uint32_t *write_to) { uint32_t value; int position, i; char bits[33]; av_assert0(range_min <= range_max && range_max - range_min < sizeof(bits) - 1); if (ctx->trace_enable) position = get_bits_count(gbc); for (i = 0, value = range_min; value < range_max;) { if (get_bits_left(gbc) < 1) { av_log(ctx->log_ctx, AV_LOG_ERROR, "Invalid increment value at " "%s: bitstream ended.\n", name); return AVERROR_INVALIDDATA; } if (get_bits1(gbc)) { bits[i++] = '1'; ++value; } else { bits[i++] = '0'; break; } } if (ctx->trace_enable) { bits[i] = 0; ff_cbs_trace_syntax_element(ctx, position, name, NULL, bits, value); } *write_to = value; return 0; } static int cbs_av1_write_increment(CodedBitstreamContext *ctx, PutBitContext *pbc, uint32_t range_min, uint32_t range_max, const char *name, uint32_t value) { int len; av_assert0(range_min <= range_max && range_max - range_min < 32); if (value < range_min || value > range_max) { av_log(ctx->log_ctx, AV_LOG_ERROR, "%s out of range: " "%"PRIu32", but must be in [%"PRIu32",%"PRIu32"].\n", name, value, range_min, range_max); return AVERROR_INVALIDDATA; } if (value == range_max) len = range_max - range_min; else len = value - range_min + 1; if (put_bits_left(pbc) < len) return AVERROR(ENOSPC); if (ctx->trace_enable) { char bits[33]; int i; for (i = 0; i < len; i++) { if (range_min + i == value) bits[i] = '0'; else bits[i] = '1'; } bits[i] = 0; ff_cbs_trace_syntax_element(ctx, put_bits_count(pbc), name, NULL, bits, value); } if (len > 0) put_bits(pbc, len, (1U << len) - 1 - (value != range_max)); return 0; } static int cbs_av1_read_subexp(CodedBitstreamContext *ctx, GetBitContext *gbc, uint32_t range_max, const char *name, const int *subscripts, uint32_t *write_to) { uint32_t value; int position, err; uint32_t max_len, len, range_offset, range_bits; if (ctx->trace_enable) position = get_bits_count(gbc); av_assert0(range_max > 0); max_len = av_log2(range_max - 1) - 3; err = cbs_av1_read_increment(ctx, gbc, 0, max_len, "subexp_more_bits", &len); if (err < 0) return err; if (len) { range_bits = 2 + len; range_offset = 1 << range_bits; } else { range_bits = 3; range_offset = 0; } if (len < max_len) { err = ff_cbs_read_unsigned(ctx, gbc, range_bits, "subexp_bits", NULL, &value, 0, MAX_UINT_BITS(range_bits)); if (err < 0) return err; } else { err = cbs_av1_read_ns(ctx, gbc, range_max - range_offset, "subexp_final_bits", NULL, &value); if (err < 0) return err; } value += range_offset; if (ctx->trace_enable) ff_cbs_trace_syntax_element(ctx, position, name, subscripts, "", value); *write_to = value; return err; } static int cbs_av1_write_subexp(CodedBitstreamContext *ctx, PutBitContext *pbc, uint32_t range_max, const char *name, const int *subscripts, uint32_t value) { int position, err; uint32_t max_len, len, range_offset, range_bits; if (value > range_max) { av_log(ctx->log_ctx, AV_LOG_ERROR, "%s out of range: " "%"PRIu32", but must be in [0,%"PRIu32"].\n", name, value, range_max); return AVERROR_INVALIDDATA; } if (ctx->trace_enable) position = put_bits_count(pbc); av_assert0(range_max > 0); max_len = av_log2(range_max - 1) - 3; if (value < 8) { range_bits = 3; range_offset = 0; len = 0; } else { range_bits = av_log2(value); len = range_bits - 2; if (len > max_len) { // The top bin is combined with the one below it. av_assert0(len == max_len + 1); --range_bits; len = max_len; } range_offset = 1 << range_bits; } err = cbs_av1_write_increment(ctx, pbc, 0, max_len, "subexp_more_bits", len); if (err < 0) return err; if (len < max_len) { err = ff_cbs_write_unsigned(ctx, pbc, range_bits, "subexp_bits", NULL, value - range_offset, 0, MAX_UINT_BITS(range_bits)); if (err < 0) return err; } else { err = cbs_av1_write_ns(ctx, pbc, range_max - range_offset, "subexp_final_bits", NULL, value - range_offset); if (err < 0) return err; } if (ctx->trace_enable) ff_cbs_trace_syntax_element(ctx, position, name, subscripts, "", value); return err; } static int cbs_av1_tile_log2(int blksize, int target) { int k; for (k = 0; (blksize << k) < target; k++); return k; } static int cbs_av1_get_relative_dist(const AV1RawSequenceHeader *seq, unsigned int a, unsigned int b) { unsigned int diff, m; if (!seq->enable_order_hint) return 0; diff = a - b; m = 1 << seq->order_hint_bits_minus_1; diff = (diff & (m - 1)) - (diff & m); return diff; } static size_t cbs_av1_get_payload_bytes_left(GetBitContext *gbc) { GetBitContext tmp = *gbc; size_t size = 0; for (int i = 0; get_bits_left(&tmp) >= 8; i++) { if (get_bits(&tmp, 8)) size = i; } return size; } #define HEADER(name) do { \ ff_cbs_trace_header(ctx, name); \ } while (0) #define CHECK(call) do { \ err = (call); \ if (err < 0) \ return err; \ } while (0) #define FUNC_NAME(rw, codec, name) cbs_ ## codec ## _ ## rw ## _ ## name #define FUNC_AV1(rw, name) FUNC_NAME(rw, av1, name) #define FUNC(name) FUNC_AV1(READWRITE, name) #define SUBSCRIPTS(subs, ...) (subs > 0 ? ((int[subs + 1]){ subs, __VA_ARGS__ }) : NULL) #define fb(width, name) \ xf(width, name, current->name, 0, MAX_UINT_BITS(width), 0) #define fc(width, name, range_min, range_max) \ xf(width, name, current->name, range_min, range_max, 0) #define flag(name) fb(1, name) #define su(width, name) \ xsu(width, name, current->name, 0) #define fbs(width, name, subs, ...) \ xf(width, name, current->name, 0, MAX_UINT_BITS(width), subs, __VA_ARGS__) #define fcs(width, name, range_min, range_max, subs, ...) \ xf(width, name, current->name, range_min, range_max, subs, __VA_ARGS__) #define flags(name, subs, ...) \ xf(1, name, current->name, 0, 1, subs, __VA_ARGS__) #define sus(width, name, subs, ...) \ xsu(width, name, current->name, subs, __VA_ARGS__) #define fixed(width, name, value) do { \ av_unused uint32_t fixed_value = value; \ xf(width, name, fixed_value, value, value, 0); \ } while (0) #define READ #define READWRITE read #define RWContext GetBitContext #define xf(width, name, var, range_min, range_max, subs, ...) do { \ uint32_t value; \ CHECK(ff_cbs_read_unsigned(ctx, rw, width, #name, \ SUBSCRIPTS(subs, __VA_ARGS__), \ &value, range_min, range_max)); \ var = value; \ } while (0) #define xsu(width, name, var, subs, ...) do { \ int32_t value; \ CHECK(ff_cbs_read_signed(ctx, rw, width, #name, \ SUBSCRIPTS(subs, __VA_ARGS__), &value, \ MIN_INT_BITS(width), \ MAX_INT_BITS(width))); \ var = value; \ } while (0) #define uvlc(name, range_min, range_max) do { \ uint32_t value; \ CHECK(cbs_av1_read_uvlc(ctx, rw, #name, \ &value, range_min, range_max)); \ current->name = value; \ } while (0) #define ns(max_value, name, subs, ...) do { \ uint32_t value; \ CHECK(cbs_av1_read_ns(ctx, rw, max_value, #name, \ SUBSCRIPTS(subs, __VA_ARGS__), &value)); \ current->name = value; \ } while (0) #define increment(name, min, max) do { \ uint32_t value; \ CHECK(cbs_av1_read_increment(ctx, rw, min, max, #name, &value)); \ current->name = value; \ } while (0) #define subexp(name, max, subs, ...) do { \ uint32_t value; \ CHECK(cbs_av1_read_subexp(ctx, rw, max, #name, \ SUBSCRIPTS(subs, __VA_ARGS__), &value)); \ current->name = value; \ } while (0) #define delta_q(name) do { \ uint8_t delta_coded; \ int8_t delta_q; \ xf(1, name.delta_coded, delta_coded, 0, 1, 0); \ if (delta_coded) \ xsu(1 + 6, name.delta_q, delta_q, 0); \ else \ delta_q = 0; \ current->name = delta_q; \ } while (0) #define leb128(name) do { \ uint64_t value; \ CHECK(cbs_av1_read_leb128(ctx, rw, #name, &value)); \ current->name = value; \ } while (0) #define infer(name, value) do { \ current->name = value; \ } while (0) #define byte_alignment(rw) (get_bits_count(rw) % 8) #include "cbs_av1_syntax_template.c" #undef READ #undef READWRITE #undef RWContext #undef xf #undef xsu #undef uvlc #undef ns #undef increment #undef subexp #undef delta_q #undef leb128 #undef infer #undef byte_alignment #define WRITE #define READWRITE write #define RWContext PutBitContext #define xf(width, name, var, range_min, range_max, subs, ...) do { \ CHECK(ff_cbs_write_unsigned(ctx, rw, width, #name, \ SUBSCRIPTS(subs, __VA_ARGS__), \ var, range_min, range_max)); \ } while (0) #define xsu(width, name, var, subs, ...) do { \ CHECK(ff_cbs_write_signed(ctx, rw, width, #name, \ SUBSCRIPTS(subs, __VA_ARGS__), var, \ MIN_INT_BITS(width), \ MAX_INT_BITS(width))); \ } while (0) #define uvlc(name, range_min, range_max) do { \ CHECK(cbs_av1_write_uvlc(ctx, rw, #name, current->name, \ range_min, range_max)); \ } while (0) #define ns(max_value, name, subs, ...) do { \ CHECK(cbs_av1_write_ns(ctx, rw, max_value, #name, \ SUBSCRIPTS(subs, __VA_ARGS__), \ current->name)); \ } while (0) #define increment(name, min, max) do { \ CHECK(cbs_av1_write_increment(ctx, rw, min, max, #name, \ current->name)); \ } while (0) #define subexp(name, max, subs, ...) do { \ CHECK(cbs_av1_write_subexp(ctx, rw, max, #name, \ SUBSCRIPTS(subs, __VA_ARGS__), \ current->name)); \ } while (0) #define delta_q(name) do { \ xf(1, name.delta_coded, current->name != 0, 0, 1, 0); \ if (current->name) \ xsu(1 + 6, name.delta_q, current->name, 0); \ } while (0) #define leb128(name) do { \ CHECK(cbs_av1_write_leb128(ctx, rw, #name, current->name)); \ } while (0) #define infer(name, value) do { \ if (current->name != (value)) { \ av_log(ctx->log_ctx, AV_LOG_WARNING, "Warning: " \ "%s does not match inferred value: " \ "%"PRId64", but should be %"PRId64".\n", \ #name, (int64_t)current->name, (int64_t)(value)); \ } \ } while (0) #define byte_alignment(rw) (put_bits_count(rw) % 8) #include "cbs_av1_syntax_template.c" #undef WRITE #undef READWRITE #undef RWContext #undef xf #undef xsu #undef uvlc #undef ns #undef increment #undef subexp #undef delta_q #undef leb128 #undef infer #undef byte_alignment static int cbs_av1_split_fragment(CodedBitstreamContext *ctx, CodedBitstreamFragment *frag, int header) { GetBitContext gbc; uint8_t *data; size_t size; uint64_t obu_length; int pos, err, trace; // Don't include this parsing in trace output. trace = ctx->trace_enable; ctx->trace_enable = 0; data = frag->data; size = frag->data_size; if (INT_MAX / 8 < size) { av_log(ctx->log_ctx, AV_LOG_ERROR, "Invalid fragment: " "too large (%"SIZE_SPECIFIER" bytes).\n", size); err = AVERROR_INVALIDDATA; goto fail; } while (size > 0) { AV1RawOBUHeader header; uint64_t obu_size; init_get_bits(&gbc, data, 8 * size); err = cbs_av1_read_obu_header(ctx, &gbc, &header); if (err < 0) goto fail; if (get_bits_left(&gbc) < 8) { av_log(ctx->log_ctx, AV_LOG_ERROR, "Invalid OBU: fragment " "too short (%"SIZE_SPECIFIER" bytes).\n", size); err = AVERROR_INVALIDDATA; goto fail; } if (header.obu_has_size_field) { err = cbs_av1_read_leb128(ctx, &gbc, "obu_size", &obu_size); if (err < 0) goto fail; } else obu_size = size - 1 - header.obu_extension_flag; pos = get_bits_count(&gbc); av_assert0(pos % 8 == 0 && pos / 8 <= size); obu_length = pos / 8 + obu_size; if (size < obu_length) { av_log(ctx->log_ctx, AV_LOG_ERROR, "Invalid OBU length: " "%"PRIu64", but only %"SIZE_SPECIFIER" bytes remaining in fragment.\n", obu_length, size); err = AVERROR_INVALIDDATA; goto fail; } err = ff_cbs_insert_unit_data(ctx, frag, -1, header.obu_type, data, obu_length, frag->data_ref); if (err < 0) goto fail; data += obu_length; size -= obu_length; } err = 0; fail: ctx->trace_enable = trace; return err; } static void cbs_av1_free_tile_data(AV1RawTileData *td) { av_buffer_unref(&td->data_ref); } static void cbs_av1_free_padding(AV1RawPadding *pd) { av_buffer_unref(&pd->payload_ref); } static void cbs_av1_free_metadata(AV1RawMetadata *md) { switch (md->metadata_type) { case AV1_METADATA_TYPE_ITUT_T35: av_buffer_unref(&md->metadata.itut_t35.payload_ref); break; } } static void cbs_av1_free_obu(void *unit, uint8_t *content) { AV1RawOBU *obu = (AV1RawOBU*)content; switch (obu->header.obu_type) { case AV1_OBU_TILE_GROUP: cbs_av1_free_tile_data(&obu->obu.tile_group.tile_data); break; case AV1_OBU_FRAME: cbs_av1_free_tile_data(&obu->obu.frame.tile_group.tile_data); break; case AV1_OBU_TILE_LIST: cbs_av1_free_tile_data(&obu->obu.tile_list.tile_data); break; case AV1_OBU_METADATA: cbs_av1_free_metadata(&obu->obu.metadata); break; case AV1_OBU_PADDING: cbs_av1_free_padding(&obu->obu.padding); break; } av_freep(&obu); } static int cbs_av1_ref_tile_data(CodedBitstreamContext *ctx, CodedBitstreamUnit *unit, GetBitContext *gbc, AV1RawTileData *td) { int pos; pos = get_bits_count(gbc); if (pos >= 8 * unit->data_size) { av_log(ctx->log_ctx, AV_LOG_ERROR, "Bitstream ended before " "any data in tile group (%d bits read).\n", pos); return AVERROR_INVALIDDATA; } // Must be byte-aligned at this point. av_assert0(pos % 8 == 0); td->data_ref = av_buffer_ref(unit->data_ref); if (!td->data_ref) return AVERROR(ENOMEM); td->data = unit->data + pos / 8; td->data_size = unit->data_size - pos / 8; return 0; } static int cbs_av1_read_unit(CodedBitstreamContext *ctx, CodedBitstreamUnit *unit) { CodedBitstreamAV1Context *priv = ctx->priv_data; AV1RawOBU *obu; GetBitContext gbc; int err, start_pos, end_pos; err = ff_cbs_alloc_unit_content(ctx, unit, sizeof(*obu), &cbs_av1_free_obu); if (err < 0) return err; obu = unit->content; err = init_get_bits(&gbc, unit->data, 8 * unit->data_size); if (err < 0) return err; err = cbs_av1_read_obu_header(ctx, &gbc, &obu->header); if (err < 0) return err; av_assert0(obu->header.obu_type == unit->type); if (obu->header.obu_has_size_field) { uint64_t obu_size; err = cbs_av1_read_leb128(ctx, &gbc, "obu_size", &obu_size); if (err < 0) return err; obu->obu_size = obu_size; } else { if (unit->data_size < 1 + obu->header.obu_extension_flag) { av_log(ctx->log_ctx, AV_LOG_ERROR, "Invalid OBU length: " "unit too short (%"SIZE_SPECIFIER").\n", unit->data_size); return AVERROR_INVALIDDATA; } obu->obu_size = unit->data_size - 1 - obu->header.obu_extension_flag; } start_pos = get_bits_count(&gbc); if (obu->header.obu_extension_flag) { priv->temporal_id = obu->header.temporal_id; priv->spatial_id = obu->header.spatial_id; if (obu->header.obu_type != AV1_OBU_SEQUENCE_HEADER && obu->header.obu_type != AV1_OBU_TEMPORAL_DELIMITER && priv->operating_point_idc) { int in_temporal_layer = (priv->operating_point_idc >> priv->temporal_id ) & 1; int in_spatial_layer = (priv->operating_point_idc >> (priv->spatial_id + 8)) & 1; if (!in_temporal_layer || !in_spatial_layer) { // Decoding will drop this OBU at this operating point. } } } else { priv->temporal_id = 0; priv->spatial_id = 0; } priv->ref = (AV1ReferenceFrameState *)&priv->read_ref; switch (obu->header.obu_type) { case AV1_OBU_SEQUENCE_HEADER: { err = cbs_av1_read_sequence_header_obu(ctx, &gbc, &obu->obu.sequence_header); if (err < 0) return err; av_buffer_unref(&priv->sequence_header_ref); priv->sequence_header = NULL; priv->sequence_header_ref = av_buffer_ref(unit->content_ref); if (!priv->sequence_header_ref) return AVERROR(ENOMEM); priv->sequence_header = &obu->obu.sequence_header; } break; case AV1_OBU_TEMPORAL_DELIMITER: { err = cbs_av1_read_temporal_delimiter_obu(ctx, &gbc); if (err < 0) return err; } break; case AV1_OBU_FRAME_HEADER: case AV1_OBU_REDUNDANT_FRAME_HEADER: { err = cbs_av1_read_frame_header_obu(ctx, &gbc, &obu->obu.frame_header, obu->header.obu_type == AV1_OBU_REDUNDANT_FRAME_HEADER, unit->data_ref); if (err < 0) return err; } break; case AV1_OBU_TILE_GROUP: { err = cbs_av1_read_tile_group_obu(ctx, &gbc, &obu->obu.tile_group); if (err < 0) return err; err = cbs_av1_ref_tile_data(ctx, unit, &gbc, &obu->obu.tile_group.tile_data); if (err < 0) return err; } break; case AV1_OBU_FRAME: { err = cbs_av1_read_frame_obu(ctx, &gbc, &obu->obu.frame, unit->data_ref); if (err < 0) return err; err = cbs_av1_ref_tile_data(ctx, unit, &gbc, &obu->obu.frame.tile_group.tile_data); if (err < 0) return err; } break; case AV1_OBU_TILE_LIST: { err = cbs_av1_read_tile_list_obu(ctx, &gbc, &obu->obu.tile_list); if (err < 0) return err; err = cbs_av1_ref_tile_data(ctx, unit, &gbc, &obu->obu.tile_list.tile_data); if (err < 0) return err; } break; case AV1_OBU_METADATA: { err = cbs_av1_read_metadata_obu(ctx, &gbc, &obu->obu.metadata); if (err < 0) return err; } break; case AV1_OBU_PADDING: { err = cbs_av1_read_padding_obu(ctx, &gbc, &obu->obu.padding); if (err < 0) return err; } break; default: return AVERROR(ENOSYS); } end_pos = get_bits_count(&gbc); av_assert0(end_pos <= unit->data_size * 8); if (obu->obu_size > 0 && obu->header.obu_type != AV1_OBU_TILE_GROUP && obu->header.obu_type != AV1_OBU_TILE_LIST && obu->header.obu_type != AV1_OBU_FRAME) { int nb_bits = obu->obu_size * 8 + start_pos - end_pos; if (nb_bits <= 0) return AVERROR_INVALIDDATA; err = cbs_av1_read_trailing_bits(ctx, &gbc, nb_bits); if (err < 0) return err; } return 0; } static int cbs_av1_write_obu(CodedBitstreamContext *ctx, CodedBitstreamUnit *unit, PutBitContext *pbc) { CodedBitstreamAV1Context *priv = ctx->priv_data; AV1RawOBU *obu = unit->content; PutBitContext pbc_tmp; AV1RawTileData *td; size_t header_size; int err, start_pos, end_pos, data_pos; // OBUs in the normal bitstream format must contain a size field // in every OBU (in annex B it is optional, but we don't support // writing that). obu->header.obu_has_size_field = 1; err = cbs_av1_write_obu_header(ctx, pbc, &obu->header); if (err < 0) return err; if (obu->header.obu_has_size_field) { pbc_tmp = *pbc; // Add space for the size field to fill later. put_bits32(pbc, 0); put_bits32(pbc, 0); } td = NULL; start_pos = put_bits_count(pbc); priv->ref = (AV1ReferenceFrameState *)&priv->write_ref; switch (obu->header.obu_type) { case AV1_OBU_SEQUENCE_HEADER: { err = cbs_av1_write_sequence_header_obu(ctx, pbc, &obu->obu.sequence_header); if (err < 0) return err; av_buffer_unref(&priv->sequence_header_ref); priv->sequence_header = NULL; priv->sequence_header_ref = av_buffer_ref(unit->content_ref); if (!priv->sequence_header_ref) return AVERROR(ENOMEM); priv->sequence_header = &obu->obu.sequence_header; } break; case AV1_OBU_TEMPORAL_DELIMITER: { err = cbs_av1_write_temporal_delimiter_obu(ctx, pbc); if (err < 0) return err; } break; case AV1_OBU_FRAME_HEADER: case AV1_OBU_REDUNDANT_FRAME_HEADER: { err = cbs_av1_write_frame_header_obu(ctx, pbc, &obu->obu.frame_header, obu->header.obu_type == AV1_OBU_REDUNDANT_FRAME_HEADER, NULL); if (err < 0) return err; } break; case AV1_OBU_TILE_GROUP: { err = cbs_av1_write_tile_group_obu(ctx, pbc, &obu->obu.tile_group); if (err < 0) return err; td = &obu->obu.tile_group.tile_data; } break; case AV1_OBU_FRAME: { err = cbs_av1_write_frame_obu(ctx, pbc, &obu->obu.frame, NULL); if (err < 0) return err; td = &obu->obu.frame.tile_group.tile_data; } break; case AV1_OBU_TILE_LIST: { err = cbs_av1_write_tile_list_obu(ctx, pbc, &obu->obu.tile_list); if (err < 0) return err; td = &obu->obu.tile_list.tile_data; } break; case AV1_OBU_METADATA: { err = cbs_av1_write_metadata_obu(ctx, pbc, &obu->obu.metadata); if (err < 0) return err; } break; case AV1_OBU_PADDING: { err = cbs_av1_write_padding_obu(ctx, pbc, &obu->obu.padding); if (err < 0) return err; } break; default: return AVERROR(ENOSYS); } end_pos = put_bits_count(pbc); header_size = (end_pos - start_pos + 7) / 8; if (td) { obu->obu_size = header_size + td->data_size; } else if (header_size > 0) { // Add trailing bits and recalculate. err = cbs_av1_write_trailing_bits(ctx, pbc, 8 - end_pos % 8); if (err < 0) return err; end_pos = put_bits_count(pbc); obu->obu_size = header_size = (end_pos - start_pos + 7) / 8; } else { // Empty OBU. obu->obu_size = 0; } end_pos = put_bits_count(pbc); // Must now be byte-aligned. av_assert0(end_pos % 8 == 0); flush_put_bits(pbc); start_pos /= 8; end_pos /= 8; *pbc = pbc_tmp; err = cbs_av1_write_leb128(ctx, pbc, "obu_size", obu->obu_size); if (err < 0) return err; data_pos = put_bits_count(pbc) / 8; flush_put_bits(pbc); av_assert0(data_pos <= start_pos); if (8 * obu->obu_size > put_bits_left(pbc)) return AVERROR(ENOSPC); if (obu->obu_size > 0) { memmove(pbc->buf + data_pos, pbc->buf + start_pos, header_size); skip_put_bytes(pbc, header_size); if (td) { memcpy(pbc->buf + data_pos + header_size, td->data, td->data_size); skip_put_bytes(pbc, td->data_size); } } // OBU data must be byte-aligned. av_assert0(put_bits_count(pbc) % 8 == 0); return 0; } static int cbs_av1_assemble_fragment(CodedBitstreamContext *ctx, CodedBitstreamFragment *frag) { size_t size, pos; int i; size = 0; for (i = 0; i < frag->nb_units; i++) size += frag->units[i].data_size; frag->data_ref = av_buffer_alloc(size + AV_INPUT_BUFFER_PADDING_SIZE); if (!frag->data_ref) return AVERROR(ENOMEM); frag->data = frag->data_ref->data; memset(frag->data + size, 0, AV_INPUT_BUFFER_PADDING_SIZE); pos = 0; for (i = 0; i < frag->nb_units; i++) { memcpy(frag->data + pos, frag->units[i].data, frag->units[i].data_size); pos += frag->units[i].data_size; } av_assert0(pos == size); frag->data_size = size; return 0; } static void cbs_av1_close(CodedBitstreamContext *ctx) { CodedBitstreamAV1Context *priv = ctx->priv_data; av_buffer_unref(&priv->sequence_header_ref); av_buffer_unref(&priv->frame_header_ref); } const CodedBitstreamType ff_cbs_type_av1 = { .codec_id = AV_CODEC_ID_AV1, .priv_data_size = sizeof(CodedBitstreamAV1Context), .split_fragment = &cbs_av1_split_fragment, .read_unit = &cbs_av1_read_unit, .write_unit = &cbs_av1_write_obu, .assemble_fragment = &cbs_av1_assemble_fragment, .close = &cbs_av1_close, };