/* Spa BAP LC3 codec * * Copyright © 2020 Wim Taymans * Copyright © 2022 Pauli Virtanen * Copyright © 2022 Collabora * * Permission is hereby granted, free of charge, to any person obtaining a * copy of this software and associated documentation files (the "Software"), * to deal in the Software without restriction, including without limitation * the rights to use, copy, modify, merge, publish, distribute, sublicense, * and/or sell copies of the Software, and to permit persons to whom the * Software is furnished to do so, subject to the following conditions: * * The above copyright notice and this permission notice (including the next * paragraph) shall be included in all copies or substantial portions of the * Software. * * THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR * IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY, * FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL * THE AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER * LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING * FROM, OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER * DEALINGS IN THE SOFTWARE. */ #include #include #include #include #include #include #include #include #include #include "media-codecs.h" #include "bap-codec-caps.h" #define MAX_PACS 64 struct impl { lc3_encoder_t enc[LC3_MAX_CHANNELS]; lc3_decoder_t dec[LC3_MAX_CHANNELS]; int mtu; int samplerate; int channels; int frame_dus; int framelen; int samples; unsigned int codesize; }; struct __attribute__((packed)) ltv { uint8_t len; uint8_t type; uint8_t value[]; }; struct pac_data { const uint8_t *data; size_t size; }; static int write_ltv(uint8_t *dest, uint8_t type, void* value, size_t len) { struct ltv *ltv = (struct ltv *)dest; ltv->len = len + 1; ltv->type = type; memcpy(ltv->value, value, len); return len + 2; } static int write_ltv_uint8(uint8_t *dest, uint8_t type, uint8_t value) { return write_ltv(dest, type, &value, sizeof(value)); } static int write_ltv_uint16(uint8_t *dest, uint8_t type, uint16_t value) { return write_ltv(dest, type, &value, sizeof(value)); } static int write_ltv_uint32(uint8_t *dest, uint8_t type, uint32_t value) { return write_ltv(dest, type, &value, sizeof(value)); } static int codec_fill_caps(const struct media_codec *codec, uint32_t flags, uint8_t caps[A2DP_MAX_CAPS_SIZE]) { uint8_t *data = caps; uint16_t framelen[2] = {htobs(LC3_MIN_FRAME_BYTES), htobs(LC3_MAX_FRAME_BYTES)}; data += write_ltv_uint16(data, LC3_TYPE_FREQ, htobs(LC3_FREQ_48KHZ | LC3_FREQ_24KHZ | LC3_FREQ_16KHZ | LC3_FREQ_8KHZ)); data += write_ltv_uint8(data, LC3_TYPE_DUR, LC3_DUR_ANY); data += write_ltv_uint8(data, LC3_TYPE_CHAN, LC3_CHAN_1 | LC3_CHAN_2); data += write_ltv(data, LC3_TYPE_FRAMELEN, framelen, sizeof(framelen)); data += write_ltv_uint8(data, LC3_TYPE_BLKS, 2); return data - caps; } static int parse_bluez_pacs(const uint8_t *data, size_t data_size, struct pac_data pacs[MAX_PACS]) { /* * BlueZ capabilites for the same codec may contain multiple * PACs separated by zero-length LTV (see BlueZ b907befc2d80) */ int pac = 0; pacs[pac] = (struct pac_data){ data, 0 }; while (data_size > 0) { struct ltv *ltv = (struct ltv *)data; if (ltv->len == 0) { /* delimiter */ if (pac + 1 >= MAX_PACS) break; ++pac; pacs[pac] = (struct pac_data){ data + 1, 0 }; } else if (ltv->len >= data_size) { return -EINVAL; } else { pacs[pac].size += ltv->len + 1; } data_size -= ltv->len + 1; data += ltv->len + 1; } return pac + 1; } static bool parse_capabilities(bap_lc3_t *conf, const uint8_t *data, size_t data_size) { uint16_t framelen_min = 0, framelen_max = 0; if (!data_size) return false; memset(conf, 0, sizeof(*conf)); conf->frame_duration = 0xFF; while (data_size > 0) { struct ltv *ltv = (struct ltv *)data; if (ltv->len < sizeof(struct ltv) || ltv->len >= data_size) return false; switch (ltv->type) { case LC3_TYPE_FREQ: spa_return_val_if_fail(ltv->len == 3, false); { uint16_t rate = ltv->value[0] + (ltv->value[1] << 8); if (rate & LC3_FREQ_48KHZ) conf->rate = LC3_CONFIG_FREQ_48KHZ; else if (rate & LC3_FREQ_24KHZ) conf->rate = LC3_CONFIG_FREQ_24KHZ; else if (rate & LC3_FREQ_16KHZ) conf->rate = LC3_CONFIG_FREQ_16KHZ; else if (rate & LC3_FREQ_8KHZ) conf->rate = LC3_CONFIG_FREQ_8KHZ; else return false; } break; case LC3_TYPE_DUR: spa_return_val_if_fail(ltv->len == 2, false); { uint8_t duration = ltv->value[0]; if (duration & LC3_DUR_10) conf->frame_duration = LC3_CONFIG_DURATION_10; else if (duration & LC3_DUR_7_5) conf->frame_duration = LC3_CONFIG_DURATION_7_5; else return false; } break; case LC3_TYPE_CHAN: spa_return_val_if_fail(ltv->len == 2, false); { uint8_t channels = ltv->value[0]; /* Only mono or stereo streams are currently supported, * in both case Audio location is defined as both Front Left * and Front Right, difference is done by the n_blks parameter. */ if ((channels & LC3_CHAN_2) || (channels & LC3_CHAN_1)) conf->channels = LC3_CONFIG_CHNL_FR | LC3_CONFIG_CHNL_FL; else return false; } break; case LC3_TYPE_FRAMELEN: spa_return_val_if_fail(ltv->len == 5, false); framelen_min = ltv->value[0] + (ltv->value[1] << 8); framelen_max = ltv->value[2] + (ltv->value[3] << 8); break; case LC3_TYPE_BLKS: spa_return_val_if_fail(ltv->len == 2, false); conf->n_blks = ltv->value[0]; if (!conf->n_blks) return false; break; default: return false; } data_size -= ltv->len + 1; data += ltv->len + 1; } if (framelen_min < LC3_MIN_FRAME_BYTES || framelen_max > LC3_MAX_FRAME_BYTES) return false; if (conf->frame_duration == 0xFF || !conf->rate) return false; if (!conf->channels) conf->channels = LC3_CONFIG_CHNL_FL; switch (conf->rate) { case LC3_CONFIG_FREQ_48KHZ: if (conf->frame_duration == LC3_CONFIG_DURATION_7_5) conf->framelen = 117; else conf->framelen = 120; break; case LC3_CONFIG_FREQ_24KHZ: if (conf->frame_duration == LC3_CONFIG_DURATION_7_5) conf->framelen = 45; else conf->framelen = 60; break; case LC3_CONFIG_FREQ_16KHZ: if (conf->frame_duration == LC3_CONFIG_DURATION_7_5) conf->framelen = 30; else conf->framelen = 40; break; case LC3_CONFIG_FREQ_8KHZ: if (conf->frame_duration == LC3_CONFIG_DURATION_7_5) conf->framelen = 26; else conf->framelen = 30; break; default: return false; } return true; } static bool parse_conf(bap_lc3_t *conf, const uint8_t *data, size_t data_size) { if (!data_size) return false; memset(conf, 0, sizeof(*conf)); conf->frame_duration = 0xFF; while (data_size > 0) { struct ltv *ltv = (struct ltv *)data; if (ltv->len < sizeof(struct ltv) || ltv->len >= data_size) return false; switch (ltv->type) { case LC3_TYPE_FREQ: spa_return_val_if_fail(ltv->len == 2, false); conf->rate = ltv->value[0]; break; case LC3_TYPE_DUR: spa_return_val_if_fail(ltv->len == 2, false); conf->frame_duration = ltv->value[0]; break; case LC3_TYPE_CHAN: spa_return_val_if_fail(ltv->len == 5, false); conf->channels = ltv->value[0] + (ltv->value[1] << 8) + (ltv->value[2] << 16) + (ltv->value[3] << 24); break; case LC3_TYPE_FRAMELEN: spa_return_val_if_fail(ltv->len == 3, false); conf->framelen = ltv->value[0] + (ltv->value[1] << 8); break; case LC3_TYPE_BLKS: spa_return_val_if_fail(ltv->len == 2, false); conf->n_blks = ltv->value[0]; if (!conf->n_blks) return false; break; default: return false; } data_size -= ltv->len + 1; data += ltv->len + 1; } if (conf->frame_duration == 0xFF || !conf->rate) return false; return true; } static int conf_cmp(const bap_lc3_t *conf1, int res1, const bap_lc3_t *conf2, int res2) { const bap_lc3_t *conf; int a, b; #define PREFER_EXPR(expr) \ do { \ conf = conf1; \ a = (expr); \ conf = conf2; \ b = (expr); \ if (a != b) \ return b - a; \ } while (0) #define PREFER_BOOL(expr) PREFER_EXPR((expr) ? 1 : 0) /* Prefer valid */ a = (res1 > 0 && (size_t)res1 == sizeof(bap_lc3_t)) ? 1 : 0; b = (res2 > 0 && (size_t)res2 == sizeof(bap_lc3_t)) ? 1 : 0; if (!a || !b) return b - a; PREFER_BOOL(conf->channels & LC3_CHAN_2); PREFER_BOOL(conf->rate & (LC3_CONFIG_FREQ_48KHZ | LC3_CONFIG_FREQ_24KHZ | LC3_CONFIG_FREQ_16KHZ | LC3_CONFIG_FREQ_8KHZ)); PREFER_BOOL(conf->rate & LC3_CONFIG_FREQ_48KHZ); return 0; #undef PREFER_EXPR #undef PREFER_BOOL } static int pac_cmp(const void *p1, const void *p2) { const struct pac_data *pac1 = p1; const struct pac_data *pac2 = p2; bap_lc3_t conf1, conf2; int res1, res2; res1 = parse_capabilities(&conf1, pac1->data, pac1->size) ? (int)sizeof(bap_lc3_t) : -EINVAL; res2 = parse_capabilities(&conf2, pac2->data, pac2->size) ? (int)sizeof(bap_lc3_t) : -EINVAL; return conf_cmp(&conf1, res1, &conf2, res2); } static int codec_select_config(const struct media_codec *codec, uint32_t flags, const void *caps, size_t caps_size, const struct media_codec_audio_info *info, const struct spa_dict *settings, uint8_t config[A2DP_MAX_CAPS_SIZE]) { struct pac_data pacs[MAX_PACS]; int npacs; bap_lc3_t conf; uint8_t *data = config; if (caps == NULL) return -EINVAL; /* Select best conf from those possible */ npacs = parse_bluez_pacs(caps, caps_size, pacs); if (npacs < 0) return npacs; else if (npacs == 0) return -EINVAL; qsort(pacs, npacs, sizeof(struct pac_data), pac_cmp); if (!parse_capabilities(&conf, pacs[0].data, pacs[0].size)) return -ENOTSUP; data += write_ltv_uint8(data, LC3_TYPE_FREQ, conf.rate); data += write_ltv_uint8(data, LC3_TYPE_DUR, conf.frame_duration); data += write_ltv_uint32(data, LC3_TYPE_CHAN, htobl(conf.channels)); data += write_ltv_uint16(data, LC3_TYPE_FRAMELEN, htobs(conf.framelen)); data += write_ltv_uint8(data, LC3_TYPE_BLKS, conf.n_blks); return data - config; } static int codec_caps_preference_cmp(const struct media_codec *codec, uint32_t flags, const void *caps1, size_t caps1_size, const void *caps2, size_t caps2_size, const struct media_codec_audio_info *info, const struct spa_dict *global_settings) { bap_lc3_t conf1, conf2; int res1, res2; /* Order selected configurations by preference */ res1 = codec->select_config(codec, 0, caps1, caps1_size, info, NULL, (uint8_t *)&conf1); res2 = codec->select_config(codec, 0, caps2, caps2_size, info , NULL, (uint8_t *)&conf2); return conf_cmp(&conf1, res1, &conf2, res2); } static uint8_t channels_to_positions(uint32_t channels, uint8_t n_channels, uint32_t *position) { uint8_t n_positions = 0; spa_assert(n_channels <= SPA_AUDIO_MAX_CHANNELS); /* First check if stream is configure for Mono, i.e. 1 block for both Front * Left anf Front Right, * else map LE Audio locations to PipeWire locations in the ascending order * which will be used as block order in stream. */ if ((channels & (LC3_CONFIG_CHNL_FR | LC3_CONFIG_CHNL_FL)) == (LC3_CONFIG_CHNL_FR | LC3_CONFIG_CHNL_FL) && n_channels == 1) { position[0] = SPA_AUDIO_CHANNEL_MONO; n_positions = 1; } else { #define CHANNEL_2_SPACHANNEL(channel,spa_channel) if (channels & channel) position[n_positions++] = spa_channel; CHANNEL_2_SPACHANNEL(LC3_CONFIG_CHNL_FL, SPA_AUDIO_CHANNEL_FL); CHANNEL_2_SPACHANNEL(LC3_CONFIG_CHNL_FR, SPA_AUDIO_CHANNEL_FR); CHANNEL_2_SPACHANNEL(LC3_CONFIG_CHNL_FC, SPA_AUDIO_CHANNEL_FC); CHANNEL_2_SPACHANNEL(LC3_CONFIG_CHNL_LFE, SPA_AUDIO_CHANNEL_LFE); CHANNEL_2_SPACHANNEL(LC3_CONFIG_CHNL_BL, SPA_AUDIO_CHANNEL_RL); CHANNEL_2_SPACHANNEL(LC3_CONFIG_CHNL_BR, SPA_AUDIO_CHANNEL_RR); CHANNEL_2_SPACHANNEL(LC3_CONFIG_CHNL_FLC, SPA_AUDIO_CHANNEL_FLC); CHANNEL_2_SPACHANNEL(LC3_CONFIG_CHNL_FRC, SPA_AUDIO_CHANNEL_FRC); CHANNEL_2_SPACHANNEL(LC3_CONFIG_CHNL_BC, SPA_AUDIO_CHANNEL_BC); CHANNEL_2_SPACHANNEL(LC3_CONFIG_CHNL_LFE2, SPA_AUDIO_CHANNEL_LFE2); CHANNEL_2_SPACHANNEL(LC3_CONFIG_CHNL_SL, SPA_AUDIO_CHANNEL_SL); CHANNEL_2_SPACHANNEL(LC3_CONFIG_CHNL_SR, SPA_AUDIO_CHANNEL_SR); CHANNEL_2_SPACHANNEL(LC3_CONFIG_CHNL_TFL, SPA_AUDIO_CHANNEL_TFL); CHANNEL_2_SPACHANNEL(LC3_CONFIG_CHNL_TFR, SPA_AUDIO_CHANNEL_TFR); CHANNEL_2_SPACHANNEL(LC3_CONFIG_CHNL_TFC, SPA_AUDIO_CHANNEL_TFC); CHANNEL_2_SPACHANNEL(LC3_CONFIG_CHNL_TC, SPA_AUDIO_CHANNEL_TC); CHANNEL_2_SPACHANNEL(LC3_CONFIG_CHNL_TBL, SPA_AUDIO_CHANNEL_TRL); CHANNEL_2_SPACHANNEL(LC3_CONFIG_CHNL_TBR, SPA_AUDIO_CHANNEL_TRR); CHANNEL_2_SPACHANNEL(LC3_CONFIG_CHNL_TSL, SPA_AUDIO_CHANNEL_TSL); CHANNEL_2_SPACHANNEL(LC3_CONFIG_CHNL_TSR, SPA_AUDIO_CHANNEL_TSR); CHANNEL_2_SPACHANNEL(LC3_CONFIG_CHNL_TBC, SPA_AUDIO_CHANNEL_TRC); CHANNEL_2_SPACHANNEL(LC3_CONFIG_CHNL_BFC, SPA_AUDIO_CHANNEL_BC); CHANNEL_2_SPACHANNEL(LC3_CONFIG_CHNL_BFL, SPA_AUDIO_CHANNEL_BLC); CHANNEL_2_SPACHANNEL(LC3_CONFIG_CHNL_BFR, SPA_AUDIO_CHANNEL_BRC); CHANNEL_2_SPACHANNEL(LC3_CONFIG_CHNL_FLW, SPA_AUDIO_CHANNEL_FLW); CHANNEL_2_SPACHANNEL(LC3_CONFIG_CHNL_FRW, SPA_AUDIO_CHANNEL_FRW); CHANNEL_2_SPACHANNEL(LC3_CONFIG_CHNL_LS, SPA_AUDIO_CHANNEL_LLFE); /* is it the right mapping? */ CHANNEL_2_SPACHANNEL(LC3_CONFIG_CHNL_RS, SPA_AUDIO_CHANNEL_RLFE); /* is it the right mapping? */ #undef CHANNEL_2_SPACHANNEL } return n_positions; } static int codec_enum_config(const struct media_codec *codec, uint32_t flags, const void *caps, size_t caps_size, uint32_t id, uint32_t idx, struct spa_pod_builder *b, struct spa_pod **param) { bap_lc3_t conf; struct spa_pod_frame f[2]; struct spa_pod_choice *choice; uint32_t position[SPA_AUDIO_MAX_CHANNELS]; uint32_t i = 0; uint8_t res; if (!parse_conf(&conf, caps, caps_size)) return -EINVAL; if (idx > 0) return 0; spa_pod_builder_push_object(b, &f[0], SPA_TYPE_OBJECT_Format, id); spa_pod_builder_add(b, SPA_FORMAT_mediaType, SPA_POD_Id(SPA_MEDIA_TYPE_audio), SPA_FORMAT_mediaSubtype, SPA_POD_Id(SPA_MEDIA_SUBTYPE_raw), SPA_FORMAT_AUDIO_format, SPA_POD_Id(SPA_AUDIO_FORMAT_S24_32), 0); spa_pod_builder_prop(b, SPA_FORMAT_AUDIO_rate, 0); spa_pod_builder_push_choice(b, &f[1], SPA_CHOICE_None, 0); choice = (struct spa_pod_choice*)spa_pod_builder_frame(b, &f[1]); i = 0; if (conf.rate & LC3_CONFIG_FREQ_48KHZ) { if (i++ == 0) spa_pod_builder_int(b, 48000); spa_pod_builder_int(b, 48000); } if (conf.rate & LC3_CONFIG_FREQ_24KHZ) { if (i++ == 0) spa_pod_builder_int(b, 24000); spa_pod_builder_int(b, 24000); } if (conf.rate & LC3_CONFIG_FREQ_16KHZ) { if (i++ == 0) spa_pod_builder_int(b, 16000); spa_pod_builder_int(b, 16000); } if (conf.rate & LC3_CONFIG_FREQ_8KHZ) { if (i++ == 0) spa_pod_builder_int(b, 8000); spa_pod_builder_int(b, 8000); } if (i == 0) return -EINVAL; if (i > 1) choice->body.type = SPA_CHOICE_Enum; spa_pod_builder_pop(b, &f[1]); res = channels_to_positions(conf.channels, conf.n_blks, position); if (res == 0) return -EINVAL; spa_pod_builder_add(b, SPA_FORMAT_AUDIO_channels, SPA_POD_Int(res), SPA_FORMAT_AUDIO_position, SPA_POD_Array(sizeof(uint32_t), SPA_TYPE_Id, res, position), 0); *param = spa_pod_builder_pop(b, &f[0]); return *param == NULL ? -EIO : 1; } static int codec_validate_config(const struct media_codec *codec, uint32_t flags, const void *caps, size_t caps_size, struct spa_audio_info *info) { bap_lc3_t conf; uint8_t res; if (caps == NULL) return -EINVAL; if (!parse_conf(&conf, caps, caps_size)) return -ENOTSUP; spa_zero(*info); info->media_type = SPA_MEDIA_TYPE_audio; info->media_subtype = SPA_MEDIA_SUBTYPE_raw; info->info.raw.format = SPA_AUDIO_FORMAT_S24_32; switch (conf.rate) { case LC3_CONFIG_FREQ_48KHZ: info->info.raw.rate = 48000U; break; case LC3_CONFIG_FREQ_24KHZ: info->info.raw.rate = 24000U; break; case LC3_CONFIG_FREQ_16KHZ: info->info.raw.rate = 16000U; break; case LC3_CONFIG_FREQ_8KHZ: info->info.raw.rate = 8000U; break; default: return -EINVAL; } res = channels_to_positions(conf.channels, conf.n_blks, info->info.raw.position); if (res == 0) return -EINVAL; info->info.raw.channels = res; switch (conf.frame_duration) { case LC3_CONFIG_DURATION_10: case LC3_CONFIG_DURATION_7_5: break; default: return -EINVAL; } return 0; } static int codec_get_qos(const struct media_codec *codec, const void *config, size_t config_size, const struct bap_endpoint_qos *endpoint_qos, struct bap_codec_qos *qos) { bap_lc3_t conf; spa_zero(*qos); if (!parse_conf(&conf, config, config_size)) return -EINVAL; qos->framing = false; if (endpoint_qos->phy & 0x2) qos->phy = 0x2; else if (endpoint_qos->phy & 0x1) qos->phy = 0x1; else qos->phy = 0x2; qos->retransmission = 2; /* default */ qos->sdu = conf.framelen * conf.n_blks; qos->latency = 20; /* default */ qos->delay = 40000U; qos->interval = (conf.frame_duration == LC3_CONFIG_DURATION_7_5 ? 7500 : 10000); qos->target_latency = BT_ISO_QOS_TARGET_LATENCY_BALANCED; switch (conf.rate) { case LC3_CONFIG_FREQ_8KHZ: case LC3_CONFIG_FREQ_16KHZ: case LC3_CONFIG_FREQ_24KHZ: case LC3_CONFIG_FREQ_32KHZ: qos->retransmission = 2; qos->latency = (conf.frame_duration == LC3_CONFIG_DURATION_7_5 ? 8 : 10); break; case LC3_CONFIG_FREQ_48KHZ: qos->retransmission = 5; qos->latency = (conf.frame_duration == LC3_CONFIG_DURATION_7_5 ? 15 : 20); break; } /* Clamp to ASE values */ if (endpoint_qos->latency >= 0x0005 && endpoint_qos->latency <= 0x0FA0) /* Values outside the range are RFU */ qos->latency = SPA_MAX(qos->latency, endpoint_qos->latency); if (endpoint_qos->delay_min) qos->delay = SPA_MAX(qos->delay, endpoint_qos->delay_min); if (endpoint_qos->delay_max) qos->delay = SPA_MIN(qos->delay, endpoint_qos->delay_max); return 0; } static void *codec_init(const struct media_codec *codec, uint32_t flags, void *config, size_t config_len, const struct spa_audio_info *info, void *props, size_t mtu) { bap_lc3_t conf; struct impl *this = NULL; struct spa_audio_info config_info; int res, ich; if (info->media_type != SPA_MEDIA_TYPE_audio || info->media_subtype != SPA_MEDIA_SUBTYPE_raw || info->info.raw.format != SPA_AUDIO_FORMAT_S24_32) { res = -EINVAL; goto error; } if ((this = calloc(1, sizeof(struct impl))) == NULL) goto error_errno; if ((res = codec_validate_config(codec, flags, config, config_len, &config_info)) < 0) goto error; if (!parse_conf(&conf, config, config_len)) { res = -ENOTSUP; goto error; } this->mtu = mtu; this->samplerate = config_info.info.raw.rate; this->channels = config_info.info.raw.channels; this->framelen = conf.framelen; switch (conf.frame_duration) { case LC3_CONFIG_DURATION_10: this->frame_dus = 10000; break; case LC3_CONFIG_DURATION_7_5: this->frame_dus = 7500; break; default: res = -EINVAL; goto error; } this->samples = lc3_frame_samples(this->frame_dus, this->samplerate); if (this->samples < 0) { res = -EINVAL; goto error; } this->codesize = this->samples * this->channels * sizeof(int32_t); if (!(flags & MEDIA_CODEC_FLAG_SINK)) { for (ich = 0; ich < this->channels; ich++) { this->enc[ich] = lc3_setup_encoder(this->frame_dus, this->samplerate, 0, calloc(1, lc3_encoder_size(this->frame_dus, this->samplerate))); if (this->enc[ich] == NULL) { res = -EINVAL; goto error; } } } else { for (ich = 0; ich < this->channels; ich++) { this->dec[ich] = lc3_setup_decoder(this->frame_dus, this->samplerate, 0, calloc(1, lc3_decoder_size(this->frame_dus, this->samplerate))); if (this->dec[ich] == NULL) { res = -EINVAL; goto error; } } } return this; error_errno: res = -errno; goto error; error: if (this) { for (ich = 0; ich < this->channels; ich++) { if (this->enc[ich]) free(this->enc[ich]); if (this->dec[ich]) free(this->dec[ich]); } } free(this); errno = -res; return NULL; } static void codec_deinit(void *data) { struct impl *this = data; int ich; for (ich = 0; ich < this->channels; ich++) { if (this->enc[ich]) free(this->enc[ich]); if (this->dec[ich]) free(this->dec[ich]); } free(this); } static int codec_get_block_size(void *data) { struct impl *this = data; return this->codesize; } static int codec_abr_process (void *data, size_t unsent) { return -ENOTSUP; } static int codec_start_encode (void *data, void *dst, size_t dst_size, uint16_t seqnum, uint32_t timestamp) { return 0; } static int codec_encode(void *data, const void *src, size_t src_size, void *dst, size_t dst_size, size_t *dst_out, int *need_flush) { struct impl *this = data; int frame_bytes; int ich, res; int size, processed; frame_bytes = lc3_frame_bytes(this->frame_dus, this->samplerate); processed = 0; size = 0; if (src_size < (size_t)this->codesize) goto done; if (dst_size < (size_t)frame_bytes) goto done; for (ich = 0; ich < this->channels; ich++) { uint8_t *in = (uint8_t *)src + (ich * 4); uint8_t *out = (uint8_t *)dst + ich * this->framelen; res = lc3_encode(this->enc[ich], LC3_PCM_FORMAT_S24, in, this->channels, this->framelen, out); size += this->framelen; if (SPA_UNLIKELY(res != 0)) return -EINVAL; } *dst_out = size; processed += this->codesize; done: spa_assert(size <= this->mtu); *need_flush = NEED_FLUSH_ALL; return processed; } static SPA_UNUSED int codec_start_decode (void *data, const void *src, size_t src_size, uint16_t *seqnum, uint32_t *timestamp) { return 0; } static SPA_UNUSED int codec_decode(void *data, const void *src, size_t src_size, void *dst, size_t dst_size, size_t *dst_out) { struct impl *this = data; int ich, res; int consumed; int samples; spa_return_val_if_fail((size_t)(this->framelen * this->channels) == src_size, -EINVAL); consumed = 0; samples = lc3_frame_samples(this->frame_dus, this->samplerate); if (samples == -1) return -EINVAL; if (dst_size < this->codesize) return -EINVAL; for (ich = 0; ich < this->channels; ich++) { uint8_t *in = (uint8_t *)src + ich * this->framelen; uint8_t *out = (uint8_t *)dst + (ich * 4); res = lc3_decode(this->dec[ich], in, this->framelen, LC3_PCM_FORMAT_S24, out, this->channels); if (SPA_UNLIKELY(res < 0)) return -EINVAL; consumed += this->framelen; } *dst_out = this->codesize; return consumed; } static int codec_reduce_bitpool(void *data) { return -ENOTSUP; } static int codec_increase_bitpool(void *data) { return -ENOTSUP; } const struct media_codec bap_codec_lc3 = { .id = SPA_BLUETOOTH_AUDIO_CODEC_LC3, .name = "lc3", .codec_id = BAP_CODEC_LC3, .bap = true, .description = "LC3", .fill_caps = codec_fill_caps, .select_config = codec_select_config, .enum_config = codec_enum_config, .validate_config = codec_validate_config, .get_qos = codec_get_qos, .caps_preference_cmp = codec_caps_preference_cmp, .init = codec_init, .deinit = codec_deinit, .get_block_size = codec_get_block_size, .abr_process = codec_abr_process, .start_encode = codec_start_encode, .encode = codec_encode, .start_decode = codec_start_decode, .decode = codec_decode, .reduce_bitpool = codec_reduce_bitpool, .increase_bitpool = codec_increase_bitpool }; MEDIA_CODEC_EXPORT_DEF( "lc3", &bap_codec_lc3 );