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audioconvert: add channelmix and resample

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This commit is contained in:
Wim Taymans 2022-02-24 12:10:10 +01:00
parent 399f638eb1
commit 8cb0d9fd7b
1 changed files with 192 additions and 25 deletions
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217
spa/plugins/audioconvert/audioconvert2.c
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@ -89,6 +89,7 @@ struct props {
struct volumes monitor; struct volumes monitor;
int quality; int quality;
unsigned int have_soft_volume:1; unsigned int have_soft_volume:1;
double rate;
}; };
static void props_reset(struct props *props) static void props_reset(struct props *props)
@ -101,6 +102,7 @@ static void props_reset(struct props *props)
init_volumes(&props->channel); init_volumes(&props->channel);
init_volumes(&props->soft); init_volumes(&props->soft);
init_volumes(&props->monitor); init_volumes(&props->monitor);
props->rate = 1.0;
} }
struct buffer { struct buffer {
@ -116,7 +118,6 @@ struct port {
uint32_t direction; uint32_t direction;
uint32_t id; uint32_t id;
struct spa_io_rate_match *rate_match;
struct spa_io_buffers *io; struct spa_io_buffers *io;
uint64_t info_all; uint64_t info_all;
@ -174,7 +175,10 @@ struct impl {
uint32_t max_align; uint32_t max_align;
uint32_t quantum_limit; uint32_t quantum_limit;
struct props props;
struct spa_io_position *io_position; struct spa_io_position *io_position;
struct spa_io_rate_match *io_rate_match;
uint64_t info_all; uint64_t info_all;
struct spa_node_info info; struct spa_node_info info;
@ -193,17 +197,20 @@ struct impl {
struct dir dir[2]; struct dir dir[2];
struct channelmix mix; struct channelmix mix;
struct resample resample; struct resample resample;
struct volume volume;
double rate_scale;
unsigned int started:1; unsigned int started:1;
unsigned int peaks:1; unsigned int peaks:1;
unsigned int is_passthrough:1;
struct volume volume;
struct props props;
uint32_t empty_size; uint32_t empty_size;
float *empty; float *empty;
float *scratch; float *scratch;
float *tmp; float *tmp;
float *tmp2;
float *tmp_datas[2][MAX_PORTS];
}; };
#define CHECK_PORT(this,d,p) ((p) < this->dir[d].n_ports) #define CHECK_PORT(this,d,p) ((p) < this->dir[d].n_ports)
@ -248,7 +255,7 @@ static void emit_port_info(struct impl *this, struct port *port, bool full)
if (PORT_IS_DSP(this, port->direction, port->id)) { if (PORT_IS_DSP(this, port->direction, port->id)) {
items[n_items++] = SPA_DICT_ITEM_INIT(SPA_KEY_FORMAT_DSP, "32 bit float mono audio"); items[n_items++] = SPA_DICT_ITEM_INIT(SPA_KEY_FORMAT_DSP, "32 bit float mono audio");
items[n_items++] = SPA_DICT_ITEM_INIT(SPA_KEY_AUDIO_CHANNEL, port->position); items[n_items++] = SPA_DICT_ITEM_INIT(SPA_KEY_AUDIO_CHANNEL, port->position);
if (port->direction == SPA_DIRECTION_OUTPUT) if (port->is_monitor)
items[n_items++] = SPA_DICT_ITEM_INIT(SPA_KEY_PORT_MONITOR, "true"); items[n_items++] = SPA_DICT_ITEM_INIT(SPA_KEY_PORT_MONITOR, "true");
} }
port->info.props = &SPA_DICT_INIT(items, n_items); port->info.props = &SPA_DICT_INIT(items, n_items);
@ -877,6 +884,59 @@ static uint64_t default_mask(uint32_t channels)
return mask; return mask;
} }
static void fix_volumes(struct volumes *vols, uint32_t channels)
{
float s;
uint32_t i;
if (vols->n_volumes > 0) {
s = 0.0f;
for (i = 0; i < vols->n_volumes; i++)
s += vols->volumes[i];
s /= vols->n_volumes;
} else {
s = 1.0f;
}
vols->n_volumes = channels;
for (i = 0; i < vols->n_volumes; i++)
vols->volumes[i] = s;
}
static int remap_volumes(struct impl *this, const struct spa_audio_info *info)
{
struct props *p = &this->props;
uint32_t i, j, target = info->info.raw.channels;
for (i = 0; i < p->n_channels; i++) {
for (j = i; j < target; j++) {
spa_log_debug(this->log, "%d %d: %d <-> %d", i, j,
p->channel_map[i], info->info.raw.position[j]);
if (p->channel_map[i] != info->info.raw.position[j])
continue;
if (i != j) {
SPA_SWAP(p->channel_map[i], p->channel_map[j]);
SPA_SWAP(p->channel.volumes[i], p->channel.volumes[j]);
SPA_SWAP(p->soft.volumes[i], p->soft.volumes[j]);
SPA_SWAP(p->monitor.volumes[i], p->monitor.volumes[j]);
}
break;
}
}
p->n_channels = target;
for (i = 0; i < p->n_channels; i++)
p->channel_map[i] = info->info.raw.position[i];
if (target == 0)
return 0;
if (p->channel.n_volumes != target)
fix_volumes(&p->channel, target);
if (p->soft.n_volumes != target)
fix_volumes(&p->soft, target);
if (p->monitor.n_volumes != target)
fix_volumes(&p->monitor, target);
return 1;
}
static void set_volume(struct impl *this) static void set_volume(struct impl *this)
{ {
struct volumes *vol; struct volumes *vol;
@ -938,7 +998,7 @@ static int setup_channelmix(struct impl *this)
if ((res = channelmix_init(&this->mix)) < 0) if ((res = channelmix_init(&this->mix)) < 0)
return res; return res;
//remap_volumes(this, this->direction == SPA_DIRECTION_INPUT ? src_info : dst_info); remap_volumes(this, &in->format);
set_volume(this); set_volume(this);
spa_log_debug(this->log, "%p: got channelmix features %08x:%08x flags:%08x", spa_log_debug(this->log, "%p: got channelmix features %08x:%08x flags:%08x",
@ -970,6 +1030,7 @@ static int setup_resample(struct impl *this)
this->resample.o_rate = out->format.info.raw.rate; this->resample.o_rate = out->format.info.raw.rate;
this->resample.log = this->log; this->resample.log = this->log;
this->resample.quality = this->props.quality; this->resample.quality = this->props.quality;
this->resample.cpu_flags = this->cpu_flags;
if (this->peaks) if (this->peaks)
res = resample_peaks_init(&this->resample); res = resample_peaks_init(&this->resample);
@ -1035,6 +1096,7 @@ static int setup_out_convert(struct impl *this)
static int setup_convert(struct impl *this) static int setup_convert(struct impl *this)
{ {
struct dir *in, *out; struct dir *in, *out;
uint32_t i;
in = &this->dir[SPA_DIRECTION_INPUT]; in = &this->dir[SPA_DIRECTION_INPUT];
out = &this->dir[SPA_DIRECTION_OUTPUT]; out = &this->dir[SPA_DIRECTION_OUTPUT];
@ -1047,6 +1109,12 @@ static int setup_convert(struct impl *this)
setup_resample(this); setup_resample(this);
setup_out_convert(this); setup_out_convert(this);
for (i = 0; i < MAX_PORTS; i++) {
this->tmp_datas[0][i] = SPA_PTROFF(this->tmp, this->empty_size * i, void);
this->tmp_datas[0][i] = SPA_PTR_ALIGN(this->tmp_datas[0][i], MAX_ALIGN, void);
this->tmp_datas[1][i] = SPA_PTROFF(this->tmp2, this->empty_size * i, void);
this->tmp_datas[1][i] = SPA_PTR_ALIGN(this->tmp_datas[1][i], MAX_ALIGN, void);
}
return 0; return 0;
} }
@ -1570,6 +1638,10 @@ impl_node_port_use_buffers(void *object,
spa_log_warn(this->log, "%p: memory %d on buffer %d not aligned", spa_log_warn(this->log, "%p: memory %d on buffer %d not aligned",
this, j, i); this, j, i);
} }
if (direction == SPA_DIRECTION_OUTPUT &&
!SPA_FLAG_IS_SET(d[j].flags, SPA_DATA_FLAG_DYNAMIC))
this->is_passthrough = false;
b->datas[j] = d[j].data; b->datas[j] = d[j].data;
maxsize = SPA_MAX(maxsize, d[j].maxsize); maxsize = SPA_MAX(maxsize, d[j].maxsize);
@ -1581,7 +1653,9 @@ impl_node_port_use_buffers(void *object,
this->empty = realloc(this->empty, maxsize + MAX_ALIGN); this->empty = realloc(this->empty, maxsize + MAX_ALIGN);
this->scratch = realloc(this->scratch, maxsize + MAX_ALIGN); this->scratch = realloc(this->scratch, maxsize + MAX_ALIGN);
this->tmp = realloc(this->tmp, (4 * maxsize + MAX_ALIGN) * MAX_PORTS); this->tmp = realloc(this->tmp, (4 * maxsize + MAX_ALIGN) * MAX_PORTS);
if (this->empty == NULL) this->tmp2 = realloc(this->tmp2, (4 * maxsize + MAX_ALIGN) * MAX_PORTS);
if (this->empty == NULL || this->scratch == NULL ||
this->tmp == NULL || this->tmp2 == NULL)
return -errno; return -errno;
memset(this->empty, 0, maxsize + MAX_ALIGN); memset(this->empty, 0, maxsize + MAX_ALIGN);
this->empty_size = maxsize; this->empty_size = maxsize;
@ -1613,7 +1687,7 @@ impl_node_port_set_io(void *object,
port->io = data; port->io = data;
break; break;
case SPA_IO_RateMatch: case SPA_IO_RateMatch:
port->rate_match = data; this->io_rate_match = data;
break; break;
default: default:
return -ENOENT; return -ENOENT;
@ -1678,16 +1752,57 @@ static inline int get_out_buffer(struct impl *this, struct port *port, struct bu
return 0; return 0;
} }
static void resample_update_rate_match(struct impl *this, bool passthrough, uint32_t out_size, uint32_t in_queued)
{
if (this->io_rate_match) {
uint32_t match_size;
if (passthrough) {
this->io_rate_match->delay = 0;
match_size = out_size;
} else {
if (SPA_FLAG_IS_SET(this->io_rate_match->flags, SPA_IO_RATE_MATCH_FLAG_ACTIVE))
resample_update_rate(&this->resample, this->rate_scale * this->io_rate_match->rate);
else
resample_update_rate(&this->resample, this->rate_scale);
this->io_rate_match->delay = resample_delay(&this->resample);
match_size = resample_in_len(&this->resample, out_size);
}
match_size -= SPA_MIN(match_size, in_queued);
this->io_rate_match->size = match_size;
spa_log_trace_fp(this->log, "%p: next match %u", this, match_size);
} else {
resample_update_rate(&this->resample, this->rate_scale * this->props.rate);
}
}
static inline bool resample_is_passthrough(struct impl *this)
{
return this->resample.i_rate == this->resample.o_rate && this->rate_scale == 1.0 &&
(this->io_rate_match == NULL ||
!SPA_FLAG_IS_SET(this->io_rate_match->flags, SPA_IO_RATE_MATCH_FLAG_ACTIVE));
}
static void resample_recalc_rate_match(struct impl *this)
{
bool passthrough = resample_is_passthrough(this);
uint32_t out_size = this->io_position ? this->io_position->clock.duration : 1024;
resample_update_rate_match(this, passthrough, out_size, 0);
}
static int impl_node_process(void *object) static int impl_node_process(void *object)
{ {
struct impl *this = object; struct impl *this = object;
const void *src_datas[MAX_PORTS]; const void *src_datas[MAX_PORTS], **in_datas;
void *dst_datas[MAX_PORTS], *tmp_datas[MAX_PORTS]; void *dst_datas[MAX_PORTS], **out_datas;
uint32_t i, j, n_src_datas = 0, n_dst_datas = 0, n_samples; uint32_t i, j, n_src_datas = 0, n_dst_datas = 0, n_samples;
struct port *port; struct port *port;
struct buffer *buf; struct buffer *buf;
struct spa_data *bd; struct spa_data *bd, *dst_bufs[MAX_PORTS];
int res, ready = 0; int ready = 0, tmp = 0;
bool in_passthrough, mix_passthrough, resample_passthrough, out_passthrough, end_passthrough;
uint32_t in_len, out_len;
if (SPA_LIKELY(this->io_position)) if (SPA_LIKELY(this->io_position))
n_samples = this->io_position->clock.duration; n_samples = this->io_position->clock.duration;
@ -1697,12 +1812,6 @@ static int impl_node_process(void *object)
for (i = 0; i < this->dir[SPA_DIRECTION_INPUT].n_ports; i++) { for (i = 0; i < this->dir[SPA_DIRECTION_INPUT].n_ports; i++) {
port = GET_IN_PORT(this, i); port = GET_IN_PORT(this, i);
if (port->rate_match)
port->rate_match->size = n_samples;
tmp_datas[i] = SPA_PTROFF(this->tmp, this->empty_size * i, void);
tmp_datas[i] = SPA_PTR_ALIGN(tmp_datas[i], MAX_ALIGN, void);
if (SPA_UNLIKELY(get_in_buffer(this, port, &buf) != 0)) { if (SPA_UNLIKELY(get_in_buffer(this, port, &buf) != 0)) {
src_datas[n_src_datas++] = SPA_PTR_ALIGN(this->empty, MAX_ALIGN, void); src_datas[n_src_datas++] = SPA_PTR_ALIGN(this->empty, MAX_ALIGN, void);
continue; continue;
@ -1719,16 +1828,18 @@ static int impl_node_process(void *object)
} }
ready++; ready++;
} }
if (ready == 0 && this->dir[SPA_DIRECTION_INPUT].mode == SPA_PARAM_PORT_CONFIG_MODE_convert)
resample_passthrough = resample_is_passthrough(this);
if (ready == 0) {
resample_recalc_rate_match(this);
return SPA_STATUS_NEED_DATA; return SPA_STATUS_NEED_DATA;
}
for (i = 0; i < this->dir[SPA_DIRECTION_OUTPUT].n_ports; i++) { for (i = 0; i < this->dir[SPA_DIRECTION_OUTPUT].n_ports; i++) {
port = GET_OUT_PORT(this, i); port = GET_OUT_PORT(this, i);
tmp_datas[i] = SPA_PTROFF(this->tmp, this->empty_size * i, void);
tmp_datas[i] = SPA_PTR_ALIGN(tmp_datas[i], MAX_ALIGN, void);
if (SPA_UNLIKELY(get_out_buffer(this, port, &buf) != 0)) { if (SPA_UNLIKELY(get_out_buffer(this, port, &buf) != 0)) {
dst_bufs[n_dst_datas] = NULL;
dst_datas[n_dst_datas++] = SPA_PTR_ALIGN(this->scratch, MAX_ALIGN, void); dst_datas[n_dst_datas++] = SPA_PTR_ALIGN(this->scratch, MAX_ALIGN, void);
continue; continue;
} }
@ -1736,19 +1847,71 @@ static int impl_node_process(void *object)
for (j = 0; j < buf->buf->n_datas; j++) { for (j = 0; j < buf->buf->n_datas; j++) {
bd = &buf->buf->datas[j]; bd = &buf->buf->datas[j];
dst_bufs[n_dst_datas] = bd;
dst_datas[n_dst_datas++] = bd->data; dst_datas[n_dst_datas++] = bd->data;
bd->chunk->offset = 0; bd->chunk->offset = 0;
bd->chunk->size = n_samples * port->stride; bd->chunk->size = 0;
spa_log_trace_fp(this->log, "%p: %d %d", this, bd->chunk->size, n_samples); spa_log_trace_fp(this->log, "%p: %d %d", this, bd->chunk->size, n_samples);
} }
} }
convert_process(&this->dir[SPA_DIRECTION_INPUT].conv, tmp_datas, src_datas, n_samples); in_passthrough = this->dir[SPA_DIRECTION_INPUT].conv.is_passthrough;
mix_passthrough = SPA_FLAG_IS_SET(this->mix.flags, CHANNELMIX_FLAG_IDENTITY);
out_passthrough = this->dir[SPA_DIRECTION_OUTPUT].conv.is_passthrough;
end_passthrough = mix_passthrough && resample_passthrough && out_passthrough;
convert_process(&this->dir[SPA_DIRECTION_OUTPUT].conv, dst_datas, (const void**)tmp_datas, n_samples); in_datas = (const void**)src_datas;
if (!in_passthrough || end_passthrough) {
if (end_passthrough)
out_datas = (void **)dst_datas;
else
out_datas = (void **)this->tmp_datas[(tmp++) & 1];
convert_process(&this->dir[SPA_DIRECTION_INPUT].conv, out_datas, in_datas, n_samples);
} else {
out_datas = (void **)in_datas;
}
in_datas = (const void**)out_datas;
if (!mix_passthrough) {
if (resample_passthrough && out_passthrough)
out_datas = (void **)dst_datas;
else
out_datas = (void **)this->tmp_datas[(tmp++) & 1];
channelmix_process(&this->mix, out_datas, in_datas, n_samples);
} else {
out_datas = (void **)in_datas;
}
in_datas = (const void**)out_datas;
if (!resample_passthrough) {
if (out_passthrough)
out_datas = (void **)dst_datas;
else
out_datas = (void **)this->tmp_datas[(tmp++) & 1];
in_len = n_samples;
out_len = this->quantum_limit;
resample_process(&this->resample, in_datas, &in_len, out_datas, &out_len);
} else {
out_datas = (void **)in_datas;
out_len = n_samples;
}
resample_update_rate_match(this, resample_passthrough, n_samples, 0);
n_samples = out_len;
in_datas = (const void **)out_datas;
if (!out_passthrough)
convert_process(&this->dir[SPA_DIRECTION_OUTPUT].conv, dst_datas, in_datas, n_samples);
for (i = 0; i < n_dst_datas; i++) {
port = GET_OUT_PORT(this, 0);
if (dst_bufs[i]) {
dst_bufs[i]->chunk->size = n_samples * port->stride;
spa_log_debug(this->log, "%d %d", n_samples, dst_bufs[i]->chunk->size);
}
}
return SPA_STATUS_NEED_DATA | SPA_STATUS_HAVE_DATA; return SPA_STATUS_NEED_DATA | SPA_STATUS_HAVE_DATA;
} }
@ -1802,6 +1965,8 @@ static int impl_clear(struct spa_handle *handle)
free(this->dir[SPA_DIRECTION_OUTPUT].ports[i]); free(this->dir[SPA_DIRECTION_OUTPUT].ports[i]);
free(this->empty); free(this->empty);
free(this->scratch); free(this->scratch);
free(this->tmp);
free(this->tmp2);
return 0; return 0;
} }
@ -1877,6 +2042,8 @@ impl_init(const struct spa_handle_factory *factory,
volume_init(&this->volume); volume_init(&this->volume);
props_reset(&this->props); props_reset(&this->props);
this->rate_scale = 1.0;
reconfigure_mode(this, SPA_PARAM_PORT_CONFIG_MODE_convert, SPA_DIRECTION_INPUT, false, NULL); reconfigure_mode(this, SPA_PARAM_PORT_CONFIG_MODE_convert, SPA_DIRECTION_INPUT, false, NULL);
reconfigure_mode(this, SPA_PARAM_PORT_CONFIG_MODE_convert, SPA_DIRECTION_OUTPUT, false, NULL); reconfigure_mode(this, SPA_PARAM_PORT_CONFIG_MODE_convert, SPA_DIRECTION_OUTPUT, false, NULL);