PulseAudio 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 of the License,
+ by the Free Software Foundation; either version 2.1 of the License,
or (at your option) any later version.
PulseAudio is distributed in the hope that it will be useful, but
#include <string.h>
-#if HAVE_LIBSAMPLERATE
+#ifdef HAVE_LIBSAMPLERATE
#include <samplerate.h>
#endif
-#include <liboil/liboilfuncs.h>
-#include <liboil/liboil.h>
+#ifdef HAVE_SPEEX
+#include <speex/speex_resampler.h>
+#endif
#include <pulse/xmalloc.h>
#include <pulsecore/sconv.h>
#include <pulsecore/log.h>
#include <pulsecore/macro.h>
#include <pulsecore/strbuf.h>
-
-#include "speexwrap.h"
+#include <pulsecore/remap.h>
#include "ffmpeg/avcodec.h"
pa_convert_func_t to_work_format_func;
pa_convert_func_t from_work_format_func;
- float map_table[PA_CHANNELS_MAX][PA_CHANNELS_MAX];
+ pa_remap_t remap;
pa_bool_t map_required;
void (*impl_free)(pa_resampler *r);
} src;
#endif
+#ifdef HAVE_SPEEX
struct { /* data specific to speex */
SpeexResamplerState* state;
} speex;
+#endif
struct { /* data specific to ffmpeg */
struct AVResampleContext *state;
static int copy_init(pa_resampler *r);
static int trivial_init(pa_resampler*r);
+#ifdef HAVE_SPEEX
static int speex_init(pa_resampler*r);
+#endif
static int ffmpeg_init(pa_resampler*r);
static int peaks_init(pa_resampler*r);
#ifdef HAVE_LIBSAMPLERATE
[PA_RESAMPLER_SRC_LINEAR] = NULL,
#endif
[PA_RESAMPLER_TRIVIAL] = trivial_init,
+#ifdef HAVE_SPEEX
[PA_RESAMPLER_SPEEX_FLOAT_BASE+0] = speex_init,
[PA_RESAMPLER_SPEEX_FLOAT_BASE+1] = speex_init,
[PA_RESAMPLER_SPEEX_FLOAT_BASE+2] = speex_init,
[PA_RESAMPLER_SPEEX_FIXED_BASE+8] = speex_init,
[PA_RESAMPLER_SPEEX_FIXED_BASE+9] = speex_init,
[PA_RESAMPLER_SPEEX_FIXED_BASE+10] = speex_init,
+#else
+ [PA_RESAMPLER_SPEEX_FLOAT_BASE+0] = NULL,
+ [PA_RESAMPLER_SPEEX_FLOAT_BASE+1] = NULL,
+ [PA_RESAMPLER_SPEEX_FLOAT_BASE+2] = NULL,
+ [PA_RESAMPLER_SPEEX_FLOAT_BASE+3] = NULL,
+ [PA_RESAMPLER_SPEEX_FLOAT_BASE+4] = NULL,
+ [PA_RESAMPLER_SPEEX_FLOAT_BASE+5] = NULL,
+ [PA_RESAMPLER_SPEEX_FLOAT_BASE+6] = NULL,
+ [PA_RESAMPLER_SPEEX_FLOAT_BASE+7] = NULL,
+ [PA_RESAMPLER_SPEEX_FLOAT_BASE+8] = NULL,
+ [PA_RESAMPLER_SPEEX_FLOAT_BASE+9] = NULL,
+ [PA_RESAMPLER_SPEEX_FLOAT_BASE+10] = NULL,
+ [PA_RESAMPLER_SPEEX_FIXED_BASE+0] = NULL,
+ [PA_RESAMPLER_SPEEX_FIXED_BASE+1] = NULL,
+ [PA_RESAMPLER_SPEEX_FIXED_BASE+2] = NULL,
+ [PA_RESAMPLER_SPEEX_FIXED_BASE+3] = NULL,
+ [PA_RESAMPLER_SPEEX_FIXED_BASE+4] = NULL,
+ [PA_RESAMPLER_SPEEX_FIXED_BASE+5] = NULL,
+ [PA_RESAMPLER_SPEEX_FIXED_BASE+6] = NULL,
+ [PA_RESAMPLER_SPEEX_FIXED_BASE+7] = NULL,
+ [PA_RESAMPLER_SPEEX_FIXED_BASE+8] = NULL,
+ [PA_RESAMPLER_SPEEX_FIXED_BASE+9] = NULL,
+ [PA_RESAMPLER_SPEEX_FIXED_BASE+10] = NULL,
+#endif
[PA_RESAMPLER_FFMPEG] = ffmpeg_init,
[PA_RESAMPLER_AUTO] = NULL,
[PA_RESAMPLER_COPY] = copy_init,
[PA_RESAMPLER_PEAKS] = peaks_init,
};
-static inline size_t sample_size(pa_sample_format_t f) {
- pa_sample_spec ss = {
- .format = f,
- .rate = 0,
- .channels = 1
- };
-
- return pa_sample_size(&ss);
-}
-
pa_resampler* pa_resampler_new(
pa_mempool *pool,
const pa_sample_spec *a,
method = PA_RESAMPLER_AUTO;
}
- if (method == PA_RESAMPLER_AUTO)
+ if (method == PA_RESAMPLER_AUTO) {
+#ifdef HAVE_SPEEX
method = PA_RESAMPLER_SPEEX_FLOAT_BASE + 3;
+#else
+ method = PA_RESAMPLER_FFMPEG;
+#endif
+ }
r = pa_xnew(pa_resampler, 1);
r->mempool = pool;
r->i_ss = *a;
r->o_ss = *b;
+ /* set up the remap structure */
+ r->remap.i_ss = &r->i_ss;
+ r->remap.o_ss = &r->o_ss;
+ r->remap.format = &r->work_format;
+
if (am)
r->i_cm = *am;
else if (!pa_channel_map_init_auto(&r->i_cm, r->i_ss.channels, PA_CHANNEL_MAP_DEFAULT))
if (a->format == PA_SAMPLE_S32NE || a->format == PA_SAMPLE_S32RE ||
a->format == PA_SAMPLE_FLOAT32NE || a->format == PA_SAMPLE_FLOAT32RE ||
+ a->format == PA_SAMPLE_S24NE || a->format == PA_SAMPLE_S24RE ||
+ a->format == PA_SAMPLE_S24_32NE || a->format == PA_SAMPLE_S24_32RE ||
b->format == PA_SAMPLE_S32NE || b->format == PA_SAMPLE_S32RE ||
- b->format == PA_SAMPLE_FLOAT32NE || b->format == PA_SAMPLE_FLOAT32RE)
+ b->format == PA_SAMPLE_FLOAT32NE || b->format == PA_SAMPLE_FLOAT32RE ||
+ b->format == PA_SAMPLE_S24NE || b->format == PA_SAMPLE_S24RE ||
+ b->format == PA_SAMPLE_S24_32NE || b->format == PA_SAMPLE_S24_32RE)
r->work_format = PA_SAMPLE_FLOAT32NE;
else
r->work_format = PA_SAMPLE_S16NE;
pa_log_info("Using %s as working format.", pa_sample_format_to_string(r->work_format));
- r->w_sz = sample_size(r->work_format);
+ r->w_sz = pa_sample_size_of_format(r->work_format);
if (r->i_ss.format == r->work_format)
r->to_work_format_func = NULL;
return r;
fail:
- if (r)
- pa_xfree(r);
+ pa_xfree(r);
return NULL;
}
size_t pa_resampler_request(pa_resampler *r, size_t out_length) {
pa_assert(r);
- return (((out_length / r->o_fz)*r->i_ss.rate)/r->o_ss.rate) * r->i_fz;
+ /* Let's round up here */
+
+ return (((((out_length + r->o_fz-1) / r->o_fz) * r->i_ss.rate) + r->o_ss.rate-1) / r->o_ss.rate) * r->i_fz;
}
size_t pa_resampler_result(pa_resampler *r, size_t in_length) {
pa_assert(r);
- return (((in_length / r->i_fz)*r->o_ss.rate)/r->i_ss.rate) * r->o_fz;
+ /* Let's round up here */
+
+ return (((((in_length + r->i_fz-1) / r->i_fz) * r->o_ss.rate) + r->i_ss.rate-1) / r->i_ss.rate) * r->o_fz;
}
size_t pa_resampler_max_block_size(pa_resampler *r) {
/* We deduce the "largest" sample spec we're using during the
* conversion */
- ss.channels = PA_MAX(r->i_ss.channels, r->o_ss.channels);
+ ss.channels = (uint8_t) (PA_MAX(r->i_ss.channels, r->o_ss.channels));
/* We silently assume that the format enum is ordered by size */
ss.format = PA_MAX(r->i_ss.format, r->o_ss.format);
return r->method;
}
+const pa_channel_map* pa_resampler_input_channel_map(pa_resampler *r) {
+ pa_assert(r);
+
+ return &r->i_cm;
+}
+
+const pa_sample_spec* pa_resampler_input_sample_spec(pa_resampler *r) {
+ pa_assert(r);
+
+ return &r->i_ss;
+}
+
+const pa_channel_map* pa_resampler_output_channel_map(pa_resampler *r) {
+ pa_assert(r);
+
+ return &r->o_cm;
+}
+
+const pa_sample_spec* pa_resampler_output_sample_spec(pa_resampler *r) {
+ pa_assert(r);
+
+ return &r->o_ss;
+}
+
static const char * const resample_methods[] = {
"src-sinc-best-quality",
"src-sinc-medium-quality",
return 0;
#endif
+#ifndef HAVE_SPEEX
+ if (m >= PA_RESAMPLER_SPEEX_FLOAT_BASE && m <= PA_RESAMPLER_SPEEX_FLOAT_MAX)
+ return 0;
+ if (m >= PA_RESAMPLER_SPEEX_FIXED_BASE && m <= PA_RESAMPLER_SPEEX_FIXED_MAX)
+ return 0;
+#endif
+
return 1;
}
p == PA_CHANNEL_POSITION_LFE;
}
+static pa_bool_t on_front(pa_channel_position_t p) {
+ return
+ p == PA_CHANNEL_POSITION_FRONT_LEFT ||
+ p == PA_CHANNEL_POSITION_FRONT_RIGHT ||
+ p == PA_CHANNEL_POSITION_FRONT_CENTER ||
+ p == PA_CHANNEL_POSITION_TOP_FRONT_LEFT ||
+ p == PA_CHANNEL_POSITION_TOP_FRONT_RIGHT ||
+ p == PA_CHANNEL_POSITION_TOP_FRONT_CENTER ||
+ p == PA_CHANNEL_POSITION_FRONT_LEFT_OF_CENTER ||
+ p == PA_CHANNEL_POSITION_FRONT_RIGHT_OF_CENTER;
+}
+
+static pa_bool_t on_rear(pa_channel_position_t p) {
+ return
+ p == PA_CHANNEL_POSITION_REAR_LEFT ||
+ p == PA_CHANNEL_POSITION_REAR_RIGHT ||
+ p == PA_CHANNEL_POSITION_REAR_CENTER ||
+ p == PA_CHANNEL_POSITION_TOP_REAR_LEFT ||
+ p == PA_CHANNEL_POSITION_TOP_REAR_RIGHT ||
+ p == PA_CHANNEL_POSITION_TOP_REAR_CENTER;
+}
+
+static pa_bool_t on_side(pa_channel_position_t p) {
+ return
+ p == PA_CHANNEL_POSITION_SIDE_LEFT ||
+ p == PA_CHANNEL_POSITION_SIDE_RIGHT ||
+ p == PA_CHANNEL_POSITION_TOP_CENTER;
+}
+
+enum {
+ ON_FRONT,
+ ON_REAR,
+ ON_SIDE,
+ ON_OTHER
+};
+
+static int front_rear_side(pa_channel_position_t p) {
+ if (on_front(p))
+ return ON_FRONT;
+ if (on_rear(p))
+ return ON_REAR;
+ if (on_side(p))
+ return ON_SIDE;
+ return ON_OTHER;
+}
+
static void calc_map_table(pa_resampler *r) {
unsigned oc, ic;
+ unsigned n_oc, n_ic;
pa_bool_t ic_connected[PA_CHANNELS_MAX];
pa_bool_t remix;
pa_strbuf *s;
char *t;
+ pa_remap_t *m;
pa_assert(r);
if (!(r->map_required = (r->i_ss.channels != r->o_ss.channels || (!(r->flags & PA_RESAMPLER_NO_REMAP) && !pa_channel_map_equal(&r->i_cm, &r->o_cm)))))
return;
- memset(r->map_table, 0, sizeof(r->map_table));
+ m = &r->remap;
+
+ n_oc = r->o_ss.channels;
+ n_ic = r->i_ss.channels;
+
+ memset(m->map_table_f, 0, sizeof(m->map_table_f));
+ memset(m->map_table_i, 0, sizeof(m->map_table_i));
+
memset(ic_connected, 0, sizeof(ic_connected));
remix = (r->flags & (PA_RESAMPLER_NO_REMAP|PA_RESAMPLER_NO_REMIX)) == 0;
- for (oc = 0; oc < r->o_ss.channels; oc++) {
+ for (oc = 0; oc < n_oc; oc++) {
pa_bool_t oc_connected = FALSE;
pa_channel_position_t b = r->o_cm.map[oc];
- for (ic = 0; ic < r->i_ss.channels; ic++) {
+ for (ic = 0; ic < n_ic; ic++) {
pa_channel_position_t a = r->i_cm.map[ic];
if (r->flags & PA_RESAMPLER_NO_REMAP) {
/* We shall not do any remapping. Hence, just check by index */
if (ic == oc)
- r->map_table[oc][ic] = 1.0;
+ m->map_table_f[oc][ic] = 1.0;
continue;
}
/* We shall not do any remixing. Hence, just check by name */
if (a == b)
- r->map_table[oc][ic] = 1.0;
+ m->map_table_f[oc][ic] = 1.0;
continue;
}
* volume will not match, and the two channels will be a
* linear combination of both.
*
- * This is losely based on random suggestions found on the
+ * This is loosely based on random suggestions found on the
* Internet, such as this:
* http://www.halfgaar.net/surround-sound-in-linux and the
* alsa upmix plugin.
* D:left, all D:right, all D:center channels, gain is
* 0.375. The current (as result of 1..6) factors
* should be multiplied by 0.75. (Alt. suggestion: 0.25
- * vs. 0.5)
+ * vs. 0.5) If C-front is only mixed into
+ * L-front/R-front if available, otherwise into all L/R
+ * channels. Similarly for C-rear.
*
* S: and D: shall relate to the source resp. destination channels.
*
*/
if (a == b || a == PA_CHANNEL_POSITION_MONO || b == PA_CHANNEL_POSITION_MONO) {
- r->map_table[oc][ic] = 1.0;
+ m->map_table_f[oc][ic] = 1.0;
oc_connected = TRUE;
ic_connected[ic] = TRUE;
if (!oc_connected && remix) {
/* OK, we shall remix */
+ /* Try to find matching input ports for this output port */
+
if (on_left(b)) {
unsigned n = 0;
/* We are not connected and on the left side, let's
* average all left side input channels. */
- for (ic = 0; ic < r->i_ss.channels; ic++)
+ for (ic = 0; ic < n_ic; ic++)
if (on_left(r->i_cm.map[ic]))
n++;
if (n > 0)
- for (ic = 0; ic < r->i_ss.channels; ic++)
+ for (ic = 0; ic < n_ic; ic++)
if (on_left(r->i_cm.map[ic])) {
- r->map_table[oc][ic] = 1.0 / n;
+ m->map_table_f[oc][ic] = 1.0f / (float) n;
ic_connected[ic] = TRUE;
}
/* We are not connected and on the right side, let's
* average all right side input channels. */
- for (ic = 0; ic < r->i_ss.channels; ic++)
+ for (ic = 0; ic < n_ic; ic++)
if (on_right(r->i_cm.map[ic]))
n++;
if (n > 0)
- for (ic = 0; ic < r->i_ss.channels; ic++)
+ for (ic = 0; ic < n_ic; ic++)
if (on_right(r->i_cm.map[ic])) {
- r->map_table[oc][ic] = 1.0 / n;
+ m->map_table_f[oc][ic] = 1.0f / (float) n;
ic_connected[ic] = TRUE;
}
/* We are not connected and at the center. Let's
* average all center input channels. */
- for (ic = 0; ic < r->i_ss.channels; ic++)
+ for (ic = 0; ic < n_ic; ic++)
if (on_center(r->i_cm.map[ic]))
n++;
if (n > 0) {
- for (ic = 0; ic < r->i_ss.channels; ic++)
+ for (ic = 0; ic < n_ic; ic++)
if (on_center(r->i_cm.map[ic])) {
- r->map_table[oc][ic] = 1.0 / n;
+ m->map_table_f[oc][ic] = 1.0f / (float) n;
ic_connected[ic] = TRUE;
}
} else {
n = 0;
- for (ic = 0; ic < r->i_ss.channels; ic++)
+ for (ic = 0; ic < n_ic; ic++)
if (on_left(r->i_cm.map[ic]) || on_right(r->i_cm.map[ic]))
n++;
if (n > 0)
- for (ic = 0; ic < r->i_ss.channels; ic++)
+ for (ic = 0; ic < n_ic; ic++)
if (on_left(r->i_cm.map[ic]) || on_right(r->i_cm.map[ic])) {
- r->map_table[oc][ic] = 1.0 / n;
+ m->map_table_f[oc][ic] = 1.0f / (float) n;
ic_connected[ic] = TRUE;
}
/* We are not connected and an LFE. Let's average all
* channels for LFE. */
- for (ic = 0; ic < r->i_ss.channels; ic++) {
- r->map_table[oc][ic] = 1.0 / r->i_ss.channels;
+ for (ic = 0; ic < n_ic; ic++) {
+
+ if (!(r->flags & PA_RESAMPLER_NO_LFE))
+ m->map_table_f[oc][ic] = 1.0f / (float) n_ic;
+ else
+ m->map_table_f[oc][ic] = 0;
/* Please note that a channel connected to LFE
* doesn't really count as connected. */
ic_unconnected_center = 0,
ic_unconnected_lfe = 0;
- for (ic = 0; ic < r->i_ss.channels; ic++) {
+ for (ic = 0; ic < n_ic; ic++) {
pa_channel_position_t a = r->i_cm.map[ic];
if (ic_connected[ic])
/* OK, so there are unconnected input channels on the
* left. Let's multiply all already connected channels on
* the left side by .9 and add in our averaged unconnected
- * channels multplied by .1 */
+ * channels multiplied by .1 */
- for (oc = 0; oc < r->o_ss.channels; oc++) {
+ for (oc = 0; oc < n_oc; oc++) {
if (!on_left(r->o_cm.map[oc]))
continue;
- for (ic = 0; ic < r->i_ss.channels; ic++) {
+ for (ic = 0; ic < n_ic; ic++) {
if (ic_connected[ic]) {
- r->map_table[oc][ic] *= .9;
+ m->map_table_f[oc][ic] *= .9f;
continue;
}
if (on_left(r->i_cm.map[ic]))
- r->map_table[oc][ic] = .1 / ic_unconnected_left;
+ m->map_table_f[oc][ic] = .1f / (float) ic_unconnected_left;
}
}
}
/* OK, so there are unconnected input channels on the
* right. Let's multiply all already connected channels on
* the right side by .9 and add in our averaged unconnected
- * channels multplied by .1 */
+ * channels multiplied by .1 */
- for (oc = 0; oc < r->o_ss.channels; oc++) {
+ for (oc = 0; oc < n_oc; oc++) {
if (!on_right(r->o_cm.map[oc]))
continue;
- for (ic = 0; ic < r->i_ss.channels; ic++) {
+ for (ic = 0; ic < n_ic; ic++) {
if (ic_connected[ic]) {
- r->map_table[oc][ic] *= .9;
+ m->map_table_f[oc][ic] *= .9f;
continue;
}
if (on_right(r->i_cm.map[ic]))
- r->map_table[oc][ic] = .1 / ic_unconnected_right;
+ m->map_table_f[oc][ic] = .1f / (float) ic_unconnected_right;
}
}
}
/* OK, so there are unconnected input channels on the
* center. Let's multiply all already connected channels on
* the center side by .9 and add in our averaged unconnected
- * channels multplied by .1 */
+ * channels multiplied by .1 */
- for (oc = 0; oc < r->o_ss.channels; oc++) {
+ for (oc = 0; oc < n_oc; oc++) {
if (!on_center(r->o_cm.map[oc]))
continue;
- for (ic = 0; ic < r->i_ss.channels; ic++) {
+ for (ic = 0; ic < n_ic; ic++) {
if (ic_connected[ic]) {
- r->map_table[oc][ic] *= .9;
+ m->map_table_f[oc][ic] *= .9f;
continue;
}
if (on_center(r->i_cm.map[ic])) {
- r->map_table[oc][ic] = .1 / ic_unconnected_center;
+ m->map_table_f[oc][ic] = .1f / (float) ic_unconnected_center;
mixed_in = TRUE;
}
}
}
if (!mixed_in) {
+ unsigned ncenter[PA_CHANNELS_MAX];
+ pa_bool_t found_frs[PA_CHANNELS_MAX];
+
+ memset(ncenter, 0, sizeof(ncenter));
+ memset(found_frs, 0, sizeof(found_frs));
/* Hmm, as it appears there was no center channel we
could mix our center channel in. In this case, mix
it into left and right. Using .375 and 0.75 as
factors. */
- for (oc = 0; oc < r->o_ss.channels; oc++) {
+ for (ic = 0; ic < n_ic; ic++) {
+
+ if (ic_connected[ic])
+ continue;
+
+ if (!on_center(r->i_cm.map[ic]))
+ continue;
+
+ for (oc = 0; oc < n_oc; oc++) {
+
+ if (!on_left(r->o_cm.map[oc]) && !on_right(r->o_cm.map[oc]))
+ continue;
+
+ if (front_rear_side(r->i_cm.map[ic]) == front_rear_side(r->o_cm.map[oc])) {
+ found_frs[ic] = TRUE;
+ break;
+ }
+ }
+
+ for (oc = 0; oc < n_oc; oc++) {
+
+ if (!on_left(r->o_cm.map[oc]) && !on_right(r->o_cm.map[oc]))
+ continue;
+
+ if (!found_frs[ic] || front_rear_side(r->i_cm.map[ic]) == front_rear_side(r->o_cm.map[oc]))
+ ncenter[oc]++;
+ }
+ }
+
+ for (oc = 0; oc < n_oc; oc++) {
if (!on_left(r->o_cm.map[oc]) && !on_right(r->o_cm.map[oc]))
continue;
- for (ic = 0; ic < r->i_ss.channels; ic++) {
+ if (ncenter[oc] <= 0)
+ continue;
+
+ for (ic = 0; ic < n_ic; ic++) {
if (ic_connected[ic]) {
- r->map_table[oc][ic] *= .75;
+ m->map_table_f[oc][ic] *= .75f;
continue;
}
- if (on_center(r->i_cm.map[ic]))
- r->map_table[oc][ic] = .375 / ic_unconnected_center;
+ if (!on_center(r->i_cm.map[ic]))
+ continue;
+
+ if (!found_frs[ic] || front_rear_side(r->i_cm.map[ic]) == front_rear_side(r->o_cm.map[oc]))
+ m->map_table_f[oc][ic] = .375f / (float) ncenter[oc];
}
}
}
}
- if (ic_unconnected_lfe > 0) {
+ if (ic_unconnected_lfe > 0 && !(r->flags & PA_RESAMPLER_NO_LFE)) {
/* OK, so there is an unconnected LFE channel. Let's mix
* it into all channels, with factor 0.375 */
- for (ic = 0; ic < r->i_ss.channels; ic++) {
+ for (ic = 0; ic < n_ic; ic++) {
if (!on_lfe(r->i_cm.map[ic]))
continue;
- for (oc = 0; oc < r->o_ss.channels; oc++)
- r->map_table[oc][ic] = 0.375 / ic_unconnected_lfe;
+ for (oc = 0; oc < n_oc; oc++)
+ m->map_table_f[oc][ic] = 0.375f / (float) ic_unconnected_lfe;
}
}
}
-
+ /* make an 16:16 int version of the matrix */
+ for (oc = 0; oc < n_oc; oc++)
+ for (ic = 0; ic < n_ic; ic++)
+ m->map_table_i[oc][ic] = (int32_t) (m->map_table_f[oc][ic] * 0x10000);
s = pa_strbuf_new();
pa_strbuf_printf(s, " ");
- for (ic = 0; ic < r->i_ss.channels; ic++)
+ for (ic = 0; ic < n_ic; ic++)
pa_strbuf_printf(s, " I%02u ", ic);
pa_strbuf_puts(s, "\n +");
- for (ic = 0; ic < r->i_ss.channels; ic++)
+ for (ic = 0; ic < n_ic; ic++)
pa_strbuf_printf(s, "------");
pa_strbuf_puts(s, "\n");
- for (oc = 0; oc < r->o_ss.channels; oc++) {
+ for (oc = 0; oc < n_oc; oc++) {
pa_strbuf_printf(s, "O%02u |", oc);
- for (ic = 0; ic < r->i_ss.channels; ic++)
- pa_strbuf_printf(s, " %1.3f", r->map_table[oc][ic]);
+ for (ic = 0; ic < n_ic; ic++)
+ pa_strbuf_printf(s, " %1.3f", m->map_table_f[oc][ic]);
pa_strbuf_puts(s, "\n");
}
pa_log_debug("Channel matrix:\n%s", t = pa_strbuf_tostring_free(s));
pa_xfree(t);
+
+ /* initialize the remapping function */
+ pa_init_remap(m);
}
static pa_memchunk* convert_to_work_format(pa_resampler *r, pa_memchunk *input) {
if (!r->to_work_format_func || !input->length)
return input;
- n_samples = (input->length / r->i_fz) * r->i_ss.channels;
+ n_samples = (unsigned) ((input->length / r->i_fz) * r->i_ss.channels);
r->buf1.index = 0;
r->buf1.length = r->w_sz * n_samples;
return &r->buf1;
}
-static void vectoradd_s16_with_fraction(
- int16_t *d, int dstr,
- const int16_t *s1, int sstr1,
- const int16_t *s2, int sstr2,
- int n,
- float s3, float s4) {
-
- int32_t i3, i4;
-
- i3 = (int32_t) (s3 * 0x10000);
- i4 = (int32_t) (s4 * 0x10000);
-
- for (; n > 0; n--) {
- int32_t a, b;
-
- a = *s1;
- b = *s2;
-
- a = (a * i3) / 0x10000;
- b = (b * i4) / 0x10000;
-
- *d = (int16_t) (a + b);
-
- s1 = (const int16_t*) ((const uint8_t*) s1 + sstr1);
- s2 = (const int16_t*) ((const uint8_t*) s2 + sstr2);
- d = (int16_t*) ((uint8_t*) d + dstr);
-
- }
-}
-
static pa_memchunk *remap_channels(pa_resampler *r, pa_memchunk *input) {
unsigned in_n_samples, out_n_samples, n_frames;
- int i_skip, o_skip;
- unsigned oc;
void *src, *dst;
+ pa_remap_t *remap;
pa_assert(r);
pa_assert(input);
if (!r->map_required || !input->length)
return input;
- in_n_samples = input->length / r->w_sz;
+ in_n_samples = (unsigned) (input->length / r->w_sz);
n_frames = in_n_samples / r->i_ss.channels;
out_n_samples = n_frames * r->o_ss.channels;
src = ((uint8_t*) pa_memblock_acquire(input->memblock) + input->index);
dst = pa_memblock_acquire(r->buf2.memblock);
- memset(dst, 0, r->buf2.length);
-
- o_skip = r->w_sz * r->o_ss.channels;
- i_skip = r->w_sz * r->i_ss.channels;
-
- switch (r->work_format) {
- case PA_SAMPLE_FLOAT32NE:
-
- for (oc = 0; oc < r->o_ss.channels; oc++) {
- unsigned ic;
- static const float one = 1.0;
-
- for (ic = 0; ic < r->i_ss.channels; ic++) {
-
- if (r->map_table[oc][ic] <= 0.0)
- continue;
-
- oil_vectoradd_f32(
- (float*) dst + oc, o_skip,
- (float*) dst + oc, o_skip,
- (float*) src + ic, i_skip,
- n_frames,
- &one, &r->map_table[oc][ic]);
- }
- }
-
- break;
-
- case PA_SAMPLE_S16NE:
-
- for (oc = 0; oc < r->o_ss.channels; oc++) {
- unsigned ic;
-
- for (ic = 0; ic < r->i_ss.channels; ic++) {
+ remap = &r->remap;
- if (r->map_table[oc][ic] <= 0.0)
- continue;
-
- if (r->map_table[oc][ic] >= 1.0) {
- static const int16_t one = 1;
-
- oil_vectoradd_s16(
- (int16_t*) dst + oc, o_skip,
- (int16_t*) dst + oc, o_skip,
- (int16_t*) src + ic, i_skip,
- n_frames,
- &one, &one);
-
- } else
-
- vectoradd_s16_with_fraction(
- (int16_t*) dst + oc, o_skip,
- (int16_t*) dst + oc, o_skip,
- (int16_t*) src + ic, i_skip,
- n_frames,
- 1.0, r->map_table[oc][ic]);
- }
- }
-
- break;
-
- default:
- pa_assert_not_reached();
- }
+ pa_assert(remap->do_remap);
+ remap->do_remap(remap, dst, src, n_frames);
pa_memblock_release(input->memblock);
pa_memblock_release(r->buf2.memblock);
- r->buf2.length = out_n_samples * r->w_sz;
-
return &r->buf2;
}
if (!r->impl_resample || !input->length)
return input;
- in_n_samples = input->length / r->w_sz;
- in_n_frames = in_n_samples / r->o_ss.channels;
+ in_n_samples = (unsigned) (input->length / r->w_sz);
+ in_n_frames = (unsigned) (in_n_samples / r->o_ss.channels);
out_n_frames = ((in_n_frames*r->o_ss.rate)/r->i_ss.rate)+EXTRA_FRAMES;
out_n_samples = out_n_frames * r->o_ss.channels;
if (!r->from_work_format_func || !input->length)
return input;
- n_samples = input->length / r->w_sz;
- n_frames = n_samples / r->o_ss.channels;
+ n_samples = (unsigned) (input->length / r->w_sz);
+ n_frames = n_samples / r->o_ss.channels;
r->buf4.index = 0;
r->buf4.length = r->o_fz * n_frames;
memset(&data, 0, sizeof(data));
data.data_in = (float*) ((uint8_t*) pa_memblock_acquire(input->memblock) + input->index);
- data.input_frames = in_n_frames;
+ data.input_frames = (long int) in_n_frames;
data.data_out = (float*) ((uint8_t*) pa_memblock_acquire(output->memblock) + output->index);
- data.output_frames = *out_n_frames;
+ data.output_frames = (long int) *out_n_frames;
data.src_ratio = (double) r->o_ss.rate / r->i_ss.rate;
data.end_of_input = 0;
pa_memblock_release(input->memblock);
pa_memblock_release(output->memblock);
- *out_n_frames = data.output_frames_gen;
+ *out_n_frames = (unsigned) data.output_frames_gen;
}
static void libsamplerate_update_rates(pa_resampler *r) {
}
#endif
+#ifdef HAVE_SPEEX
/*** speex based implementation ***/
static void speex_resample_float(pa_resampler *r, const pa_memchunk *input, unsigned in_n_frames, pa_memchunk *output, unsigned *out_n_frames) {
in = (float*) ((uint8_t*) pa_memblock_acquire(input->memblock) + input->index);
out = (float*) ((uint8_t*) pa_memblock_acquire(output->memblock) + output->index);
- pa_assert_se(paspfl_resampler_process_interleaved_float(r->speex.state, in, &inf, out, &outf) == 0);
+ pa_assert_se(speex_resampler_process_interleaved_float(r->speex.state, in, &inf, out, &outf) == 0);
pa_memblock_release(input->memblock);
pa_memblock_release(output->memblock);
in = (int16_t*) ((uint8_t*) pa_memblock_acquire(input->memblock) + input->index);
out = (int16_t*) ((uint8_t*) pa_memblock_acquire(output->memblock) + output->index);
- pa_assert_se(paspfx_resampler_process_interleaved_int(r->speex.state, in, &inf, out, &outf) == 0);
+ pa_assert_se(speex_resampler_process_interleaved_int(r->speex.state, in, &inf, out, &outf) == 0);
pa_memblock_release(input->memblock);
pa_memblock_release(output->memblock);
static void speex_update_rates(pa_resampler *r) {
pa_assert(r);
- if (r->method >= PA_RESAMPLER_SPEEX_FIXED_BASE && r->method <= PA_RESAMPLER_SPEEX_FIXED_MAX)
- pa_assert_se(paspfx_resampler_set_rate(r->speex.state, r->i_ss.rate, r->o_ss.rate) == 0);
- else {
- pa_assert(r->method >= PA_RESAMPLER_SPEEX_FLOAT_BASE && r->method <= PA_RESAMPLER_SPEEX_FLOAT_MAX);
- pa_assert_se(paspfl_resampler_set_rate(r->speex.state, r->i_ss.rate, r->o_ss.rate) == 0);
- }
+ pa_assert_se(speex_resampler_set_rate(r->speex.state, r->i_ss.rate, r->o_ss.rate) == 0);
}
static void speex_reset(pa_resampler *r) {
pa_assert(r);
- if (r->method >= PA_RESAMPLER_SPEEX_FIXED_BASE && r->method <= PA_RESAMPLER_SPEEX_FIXED_MAX)
- pa_assert_se(paspfx_resampler_reset_mem(r->speex.state) == 0);
- else {
- pa_assert(r->method >= PA_RESAMPLER_SPEEX_FLOAT_BASE && r->method <= PA_RESAMPLER_SPEEX_FLOAT_MAX);
- pa_assert_se(paspfl_resampler_reset_mem(r->speex.state) == 0);
- }
+ pa_assert_se(speex_resampler_reset_mem(r->speex.state) == 0);
}
static void speex_free(pa_resampler *r) {
if (!r->speex.state)
return;
- if (r->method >= PA_RESAMPLER_SPEEX_FIXED_BASE && r->method <= PA_RESAMPLER_SPEEX_FIXED_MAX)
- paspfx_resampler_destroy(r->speex.state);
- else {
- pa_assert(r->method >= PA_RESAMPLER_SPEEX_FLOAT_BASE && r->method <= PA_RESAMPLER_SPEEX_FLOAT_MAX);
- paspfl_resampler_destroy(r->speex.state);
- }
+ speex_resampler_destroy(r->speex.state);
}
static int speex_init(pa_resampler *r) {
r->impl_reset = speex_reset;
if (r->method >= PA_RESAMPLER_SPEEX_FIXED_BASE && r->method <= PA_RESAMPLER_SPEEX_FIXED_MAX) {
- q = r->method - PA_RESAMPLER_SPEEX_FIXED_BASE;
-
- pa_log_info("Choosing speex quality setting %i.", q);
-
- if (!(r->speex.state = paspfx_resampler_init(r->o_ss.channels, r->i_ss.rate, r->o_ss.rate, q, &err)))
- return -1;
+ q = r->method - PA_RESAMPLER_SPEEX_FIXED_BASE;
r->impl_resample = speex_resample_int;
+
} else {
pa_assert(r->method >= PA_RESAMPLER_SPEEX_FLOAT_BASE && r->method <= PA_RESAMPLER_SPEEX_FLOAT_MAX);
- q = r->method - PA_RESAMPLER_SPEEX_FLOAT_BASE;
-
- pa_log_info("Choosing speex quality setting %i.", q);
-
- if (!(r->speex.state = paspfl_resampler_init(r->o_ss.channels, r->i_ss.rate, r->o_ss.rate, q, &err)))
- return -1;
+ q = r->method - PA_RESAMPLER_SPEEX_FLOAT_BASE;
r->impl_resample = speex_resample_float;
}
+ pa_log_info("Choosing speex quality setting %i.", q);
+
+ if (!(r->speex.state = speex_resampler_init(r->o_ss.channels, r->i_ss.rate, r->o_ss.rate, q, &err)))
+ return -1;
+
return 0;
}
+#endif
/* Trivial implementation */
static void trivial_resample(pa_resampler *r, const pa_memchunk *input, unsigned in_n_frames, pa_memchunk *output, unsigned *out_n_frames) {
size_t fz;
- unsigned o_index;
+ unsigned i_index, o_index;
void *src, *dst;
pa_assert(r);
pa_assert(input);
pa_assert(output);
pa_assert(out_n_frames);
+ pa_assert(r->i_ss.channels == r->o_ss.channels);
fz = r->w_sz * r->o_ss.channels;
dst = (uint8_t*) pa_memblock_acquire(output->memblock) + output->index;
for (o_index = 0;; o_index++, r->trivial.o_counter++) {
- unsigned j;
-
- j = ((r->trivial.o_counter * r->i_ss.rate) / r->o_ss.rate);
- j = j > r->trivial.i_counter ? j - r->trivial.i_counter : 0;
+ i_index = (r->trivial.o_counter * r->i_ss.rate) / r->o_ss.rate;
+ i_index = i_index > r->trivial.i_counter ? i_index - r->trivial.i_counter : 0;
- if (j >= in_n_frames)
+ if (i_index >= in_n_frames)
break;
- pa_assert(o_index * fz < pa_memblock_get_length(output->memblock));
+ pa_assert_fp(o_index * fz < pa_memblock_get_length(output->memblock));
- oil_memcpy((uint8_t*) dst + fz * o_index,
- (uint8_t*) src + fz * j, fz);
+ /* Directly assign some common sample sizes, use memcpy as fallback */
+ if (r->w_sz == 2) {
+ for (unsigned c = 0; c < r->o_ss.channels; c++)
+ ((uint16_t *) dst)[o_index+c] = ((uint16_t *) src)[i_index+c];
+ } else if (r->w_sz == 4) {
+ for (unsigned c = 0; c < r->o_ss.channels; c++)
+ ((uint32_t *) dst)[o_index+c] = ((uint32_t *) src)[i_index+c];
+ } else {
+ memcpy((uint8_t *) dst + fz * o_index, (uint8_t *) src + fz * i_index, (int) fz);
+ }
}
pa_memblock_release(input->memblock);
/* Peak finder implementation */
static void peaks_resample(pa_resampler *r, const pa_memchunk *input, unsigned in_n_frames, pa_memchunk *output, unsigned *out_n_frames) {
- size_t fz;
- unsigned o_index;
+ unsigned c, o_index = 0;
+ unsigned i, i_end = 0;
void *src, *dst;
- unsigned start = 0;
pa_assert(r);
pa_assert(input);
pa_assert(output);
pa_assert(out_n_frames);
-
- fz = r->w_sz * r->o_ss.channels;
+ pa_assert(r->i_ss.rate >= r->o_ss.rate);
+ pa_assert(r->i_ss.channels == r->o_ss.channels);
+ pa_assert(r->work_format == PA_SAMPLE_S16NE || r->work_format == PA_SAMPLE_FLOAT32NE);
src = (uint8_t*) pa_memblock_acquire(input->memblock) + input->index;
dst = (uint8_t*) pa_memblock_acquire(output->memblock) + output->index;
- for (o_index = 0;; o_index++, r->peaks.o_counter++) {
- unsigned j;
+ i = (r->peaks.o_counter * r->i_ss.rate) / r->o_ss.rate;
+ i = i > r->peaks.i_counter ? i - r->peaks.i_counter : 0;
- j = ((r->peaks.o_counter * r->i_ss.rate) / r->o_ss.rate);
- j = j > r->peaks.i_counter ? j - r->peaks.i_counter : 0;
+ while (i_end < in_n_frames) {
+ i_end = ((r->peaks.o_counter+1) * r->i_ss.rate) / r->o_ss.rate;
+ i_end = i_end > r->peaks.i_counter ? i_end - r->peaks.i_counter : 0;
- if (j >= in_n_frames)
- break;
+ pa_assert_fp(o_index * r->w_sz * r->o_ss.channels < pa_memblock_get_length(output->memblock));
- pa_assert(o_index * fz < pa_memblock_get_length(output->memblock));
+ /* 1ch float is treated separately, because that is the common case */
+ if (r->o_ss.channels == 1 && r->work_format == PA_SAMPLE_FLOAT32NE) {
+ float *s = (float*) src + i;
+ float *d = (float*) dst + o_index;
- if (r->work_format == PA_SAMPLE_S16NE) {
- unsigned i, c;
- int16_t *s = (int16_t*) ((uint8_t*) src + fz * j);
- int16_t *d = (int16_t*) ((uint8_t*) dst + fz * o_index);
+ for (; i < i_end && i < in_n_frames; i++) {
+ float n = fabsf(*s++);
+
+ if (n > r->peaks.max_f[0])
+ r->peaks.max_f[0] = n;
+ }
- for (i = start; i <= j; i++)
- for (c = 0; c < r->o_ss.channels; c++, s++) {
- int16_t n;
+ if (i == i_end) {
+ *d = r->peaks.max_f[0];
+ r->peaks.max_f[0] = 0;
+ o_index++, r->peaks.o_counter++;
+ }
+ } else if (r->work_format == PA_SAMPLE_S16NE) {
+ int16_t *s = (int16_t*) src + r->i_ss.channels * i;
+ int16_t *d = (int16_t*) dst + r->o_ss.channels * o_index;
- n = *s < 0 ? -*s : *s;
+ for (; i < i_end && i < in_n_frames; i++)
+ for (c = 0; c < r->o_ss.channels; c++) {
+ int16_t n = abs(*s++);
if (n > r->peaks.max_i[c])
r->peaks.max_i[c] = n;
}
- for (c = 0; c < r->o_ss.channels; c++, d++) {
- *d = r->peaks.max_i[c];
- r->peaks.max_i[c] = 0;
+ if (i == i_end) {
+ for (c = 0; c < r->o_ss.channels; c++, d++) {
+ *d = r->peaks.max_i[c];
+ r->peaks.max_i[c] = 0;
+ }
+ o_index++, r->peaks.o_counter++;
}
} else {
- unsigned i, c;
- float *s = (float*) ((uint8_t*) src + fz * j);
- float *d = (float*) ((uint8_t*) dst + fz * o_index);
-
- pa_assert(r->work_format == PA_SAMPLE_FLOAT32NE);
+ float *s = (float*) src + r->i_ss.channels * i;
+ float *d = (float*) dst + r->o_ss.channels * o_index;
- for (i = start; i <= j; i++)
- for (c = 0; c < r->o_ss.channels; c++, s++) {
- float n = fabsf(*s);
+ for (; i < i_end && i < in_n_frames; i++)
+ for (c = 0; c < r->o_ss.channels; c++) {
+ float n = fabsf(*s++);
if (n > r->peaks.max_f[c])
r->peaks.max_f[c] = n;
}
- for (c = 0; c < r->o_ss.channels; c++, d++) {
- *d = r->peaks.max_f[c];
- r->peaks.max_f[c] = 0;
+ if (i == i_end) {
+ for (c = 0; c < r->o_ss.channels; c++, d++) {
+ *d = r->peaks.max_f[c];
+ r->peaks.max_f[c] = 0;
+ }
+ o_index++, r->peaks.o_counter++;
}
}
-
- start = j+1;
}
pa_memblock_release(input->memblock);
p = pa_memblock_acquire(b);
/* Copy the remaining data into it */
- l = r->ffmpeg.buf[c].length;
+ l = (unsigned) r->ffmpeg.buf[c].length;
if (r->ffmpeg.buf[c].memblock) {
t = (int16_t*) ((uint8_t*) pa_memblock_acquire(r->ffmpeg.buf[c].memblock) + r->ffmpeg.buf[c].index);
memcpy(p, t, l);
pa_memblock_release(input->memblock);
/* Calculate the resulting number of frames */
- in = in_n_frames + l / sizeof(int16_t);
+ in = (unsigned) in_n_frames + l / (unsigned) sizeof(int16_t);
/* Allocate buffer for the result */
w = pa_memblock_new(r->mempool, *out_n_frames * sizeof(int16_t));
q = pa_memblock_acquire(w);
/* Now, resample */
- used_frames = av_resample(r->ffmpeg.state,
- q, p,
- &consumed_frames,
- in, *out_n_frames,
- c >= (unsigned) r->o_ss.channels-1);
+ used_frames = (unsigned) av_resample(r->ffmpeg.state,
+ q, p,
+ &consumed_frames,
+ (int) in, (int) *out_n_frames,
+ c >= (unsigned) (r->o_ss.channels-1));
pa_memblock_release(b);
pa_assert(consumed_frames <= (int) in);
if (consumed_frames < (int) in) {
r->ffmpeg.buf[c].memblock = b;
- r->ffmpeg.buf[c].index = consumed_frames * sizeof(int16_t);
- r->ffmpeg.buf[c].length = (in - consumed_frames) * sizeof(int16_t);
+ r->ffmpeg.buf[c].index = (size_t) consumed_frames * sizeof(int16_t);
+ r->ffmpeg.buf[c].length = (size_t) (in - (unsigned) consumed_frames) * sizeof(int16_t);
} else
pa_memblock_unref(b);
* internally only uses these hardcoded values, so let's use them
* here for now as well until ffmpeg makes this configurable. */
- if (!(r->ffmpeg.state = av_resample_init(r->o_ss.rate, r->i_ss.rate, 16, 10, 0, 0.8)))
+ if (!(r->ffmpeg.state = av_resample_init((int) r->o_ss.rate, (int) r->i_ss.rate, 16, 10, 0, 0.8)))
return -1;
r->impl_free = ffmpeg_free;