gstreamer/gst-libs/gst/audio/audio-converter.c
Sebastian Dröge 71e819ae7d audio-converter: In passthrough, also don't copy if in and out block are the same
In and out array are usually different, they are stack allocated arrays.
However the blocks inside them still can be the same.

https://bugzilla.gnome.org/show_bug.cgi?id=775369
2016-11-30 10:43:50 +02:00

1351 lines
38 KiB
C

/* GStreamer
* Copyright (C) 2005 Wim Taymans <wim at fluendo dot com>
* (C) 2015 Wim Taymans <wim.taymans@gmail.com>
*
* audioconverter.c: Convert audio to different audio formats automatically
*
* This library is free software; you can redistribute it and/or
* modify it under the terms of the GNU Library General Public
* License as published by the Free Software Foundation; either
* version 2 of the License, or (at your option) any later version.
*
* This library is distributed in the hope that it will be useful,
* but WITHOUT ANY WARRANTY; without even the implied warranty of
* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU
* Library General Public License for more details.
*
* You should have received a copy of the GNU Library General Public
* License along with this library; if not, write to the
* Free Software Foundation, Inc., 51 Franklin St, Fifth Floor,
* Boston, MA 02110-1301, USA.
*/
#ifdef HAVE_CONFIG_H
#include "config.h"
#endif
#include <math.h>
#include <string.h>
#include "audio-converter.h"
#include "gstaudiopack.h"
/**
* SECTION:audioconverter
* @short_description: Generic audio conversion
*
* <refsect2>
* <para>
* This object is used to convert audio samples from one format to another.
* The object can perform conversion of:
* <itemizedlist>
* <listitem><para>
* audio format with optional dithering and noise shaping
* </para></listitem>
* <listitem><para>
* audio samplerate
* </para></listitem>
* <listitem><para>
* audio channels and channel layout
* </para></listitem>
* </para>
* </refsect2>
*/
#ifndef GST_DISABLE_GST_DEBUG
#define GST_CAT_DEFAULT ensure_debug_category()
static GstDebugCategory *
ensure_debug_category (void)
{
static gsize cat_gonce = 0;
if (g_once_init_enter (&cat_gonce)) {
gsize cat_done;
cat_done = (gsize) _gst_debug_category_new ("audio-converter", 0,
"audio-converter object");
g_once_init_leave (&cat_gonce, cat_done);
}
return (GstDebugCategory *) cat_gonce;
}
#else
#define ensure_debug_category() /* NOOP */
#endif /* GST_DISABLE_GST_DEBUG */
typedef struct _AudioChain AudioChain;
typedef void (*AudioConvertFunc) (gpointer dst, const gpointer src, gint count);
typedef gboolean (*AudioConvertSamplesFunc) (GstAudioConverter * convert,
GstAudioConverterFlags flags, gpointer in[], gsize in_frames,
gpointer out[], gsize out_frames);
typedef void (*AudioConvertEndianFunc) (gpointer dst, const gpointer src,
gint count);
/* int/int int/float float/int float/float
*
* unpack S32 S32 F64 F64
* convert S32->F64
* channel mix S32 F64 F64 F64
* convert F64->S32
* quantize S32 S32
* pack S32 F64 S32 F64
*
*
* interleave
* deinterleave
* resample
*/
struct _GstAudioConverter
{
GstAudioInfo in;
GstAudioInfo out;
GstStructure *config;
GstAudioConverterFlags flags;
GstAudioFormat current_format;
GstAudioLayout current_layout;
gint current_channels;
gboolean in_writable;
gpointer *in_data;
gsize in_frames;
gpointer *out_data;
gsize out_frames;
gboolean in_place; /* the conversion can be done in place; returned by gst_audio_converter_supports_inplace() */
/* unpack */
gboolean in_default;
gboolean unpack_ip;
/* convert in */
AudioConvertFunc convert_in;
/* channel mix */
gboolean mix_passthrough;
GstAudioChannelMixer *mix;
/* resample */
GstAudioResampler *resampler;
/* convert out */
AudioConvertFunc convert_out;
/* quant */
GstAudioQuantize *quant;
/* pack */
gboolean out_default;
AudioChain *chain_end; /* NULL for empty chain or points to the last element in the chain */
/* endian swap */
AudioConvertEndianFunc swap_endian;
AudioConvertSamplesFunc convert;
};
typedef gboolean (*AudioChainFunc) (AudioChain * chain, gpointer user_data);
typedef gpointer *(*AudioChainAllocFunc) (AudioChain * chain, gsize num_samples,
gpointer user_data);
struct _AudioChain
{
AudioChain *prev;
AudioChainFunc make_func;
gpointer make_func_data;
GDestroyNotify make_func_notify;
const GstAudioFormatInfo *finfo;
gint stride;
gint inc;
gint blocks;
gboolean pass_alloc;
gboolean allow_ip;
AudioChainAllocFunc alloc_func;
gpointer alloc_data;
gpointer *tmp;
gsize allocated_samples;
gpointer *samples;
gsize num_samples;
};
static AudioChain *
audio_chain_new (AudioChain * prev, GstAudioConverter * convert)
{
AudioChain *chain;
chain = g_slice_new0 (AudioChain);
chain->prev = prev;
if (convert->current_layout == GST_AUDIO_LAYOUT_NON_INTERLEAVED) {
chain->inc = 1;
chain->blocks = convert->current_channels;
} else {
chain->inc = convert->current_channels;
chain->blocks = 1;
}
chain->finfo = gst_audio_format_get_info (convert->current_format);
chain->stride = (chain->finfo->width * chain->inc) / 8;
return chain;
}
static void
audio_chain_set_make_func (AudioChain * chain,
AudioChainFunc make_func, gpointer user_data, GDestroyNotify notify)
{
chain->make_func = make_func;
chain->make_func_data = user_data;
chain->make_func_notify = notify;
}
static void
audio_chain_free (AudioChain * chain)
{
GST_LOG ("free chain %p", chain);
if (chain->make_func_notify)
chain->make_func_notify (chain->make_func_data);
g_free (chain->tmp);
g_slice_free (AudioChain, chain);
}
static gpointer *
audio_chain_alloc_samples (AudioChain * chain, gsize num_samples)
{
return chain->alloc_func (chain, num_samples, chain->alloc_data);
}
static void
audio_chain_set_samples (AudioChain * chain, gpointer * samples,
gsize num_samples)
{
GST_LOG ("set samples %p %" G_GSIZE_FORMAT, samples, num_samples);
chain->samples = samples;
chain->num_samples = num_samples;
}
static gpointer *
audio_chain_get_samples (AudioChain * chain, gsize * avail)
{
gpointer *res;
while (!chain->samples)
chain->make_func (chain, chain->make_func_data);
res = chain->samples;
*avail = chain->num_samples;
chain->samples = NULL;
return res;
}
/*
static guint
get_opt_uint (GstAudioConverter * convert, const gchar * opt, guint def)
{
guint res;
if (!gst_structure_get_uint (convert->config, opt, &res))
res = def;
return res;
}
*/
static gint
get_opt_enum (GstAudioConverter * convert, const gchar * opt, GType type,
gint def)
{
gint res;
if (!gst_structure_get_enum (convert->config, opt, type, &res))
res = def;
return res;
}
#define DEFAULT_OPT_RESAMPLER_METHOD GST_AUDIO_RESAMPLER_METHOD_BLACKMAN_NUTTALL
#define DEFAULT_OPT_DITHER_METHOD GST_AUDIO_DITHER_NONE
#define DEFAULT_OPT_NOISE_SHAPING_METHOD GST_AUDIO_NOISE_SHAPING_NONE
#define DEFAULT_OPT_QUANTIZATION 1
#define GET_OPT_RESAMPLER_METHOD(c) get_opt_enum(c, \
GST_AUDIO_CONVERTER_OPT_RESAMPLER_METHOD, GST_TYPE_AUDIO_RESAMPLER_METHOD, \
DEFAULT_OPT_RESAMPLER_METHOD)
#define GET_OPT_DITHER_METHOD(c) get_opt_enum(c, \
GST_AUDIO_CONVERTER_OPT_DITHER_METHOD, GST_TYPE_AUDIO_DITHER_METHOD, \
DEFAULT_OPT_DITHER_METHOD)
#define GET_OPT_NOISE_SHAPING_METHOD(c) get_opt_enum(c, \
GST_AUDIO_CONVERTER_OPT_NOISE_SHAPING_METHOD, GST_TYPE_AUDIO_NOISE_SHAPING_METHOD, \
DEFAULT_OPT_NOISE_SHAPING_METHOD)
#define GET_OPT_QUANTIZATION(c) get_opt_uint(c, \
GST_AUDIO_CONVERTER_OPT_QUANTIZATION, DEFAULT_OPT_QUANTIZATION)
static gboolean
copy_config (GQuark field_id, const GValue * value, gpointer user_data)
{
GstAudioConverter *convert = user_data;
gst_structure_id_set_value (convert->config, field_id, value);
return TRUE;
}
/**
* gst_audio_converter_update_config:
* @convert: a #GstAudioConverter
* @in_rate: input rate
* @out_rate: output rate
* @config: (transfer full) (allow-none): a #GstStructure or %NULL
*
* Set @in_rate, @out_rate and @config as extra configuration for @convert.
*
* @in_rate and @out_rate specify the new sample rates of input and output
* formats. A value of 0 leaves the sample rate unchanged.
*
* @config can be %NULL, in which case, the current configuration is not
* changed.
*
* If the parameters in @config can not be set exactly, this function returns
* %FALSE and will try to update as much state as possible. The new state can
* then be retrieved and refined with gst_audio_converter_get_config().
*
* Look at the #GST_AUDIO_CONVERTER_OPT_* fields to check valid configuration
* option and values.
*
* Returns: %TRUE when the new parameters could be set
*/
gboolean
gst_audio_converter_update_config (GstAudioConverter * convert,
gint in_rate, gint out_rate, GstStructure * config)
{
g_return_val_if_fail (convert != NULL, FALSE);
g_return_val_if_fail ((in_rate == 0 && out_rate == 0) ||
convert->flags & GST_AUDIO_CONVERTER_FLAG_VARIABLE_RATE, FALSE);
GST_LOG ("new rate %d -> %d", in_rate, out_rate);
if (in_rate <= 0)
in_rate = convert->in.rate;
if (out_rate <= 0)
out_rate = convert->out.rate;
convert->in.rate = in_rate;
convert->out.rate = out_rate;
if (convert->resampler)
gst_audio_resampler_update (convert->resampler, in_rate, out_rate, config);
if (config) {
gst_structure_foreach (config, copy_config, convert);
gst_structure_free (config);
}
return TRUE;
}
/**
* gst_audio_converter_get_config:
* @convert: a #GstAudioConverter
* @in_rate: result input rate
* @out_rate: result output rate
*
* Get the current configuration of @convert.
*
* Returns: a #GstStructure that remains valid for as long as @convert is valid
* or until gst_audio_converter_update_config() is called.
*/
const GstStructure *
gst_audio_converter_get_config (GstAudioConverter * convert,
gint * in_rate, gint * out_rate)
{
g_return_val_if_fail (convert != NULL, NULL);
if (in_rate)
*in_rate = convert->in.rate;
if (out_rate)
*out_rate = convert->out.rate;
return convert->config;
}
static gpointer *
get_output_samples (AudioChain * chain, gsize num_samples, gpointer user_data)
{
GstAudioConverter *convert = user_data;
GST_LOG ("output samples %p %" G_GSIZE_FORMAT, convert->out_data,
num_samples);
return convert->out_data;
}
#define MEM_ALIGN(m,a) ((gint8 *)((guintptr)((gint8 *)(m) + ((a)-1)) & ~((a)-1)))
#define ALIGN 16
static gpointer *
get_temp_samples (AudioChain * chain, gsize num_samples, gpointer user_data)
{
if (num_samples > chain->allocated_samples) {
gint i;
gint8 *s;
gsize stride = GST_ROUND_UP_N (num_samples * chain->stride, ALIGN);
/* first part contains the pointers, second part the data, add some extra bytes
* for alignement */
gsize needed = (stride + sizeof (gpointer)) * chain->blocks + ALIGN - 1;
GST_DEBUG ("alloc samples %d %" G_GSIZE_FORMAT " %" G_GSIZE_FORMAT,
chain->stride, num_samples, needed);
chain->tmp = g_realloc (chain->tmp, needed);
chain->allocated_samples = num_samples;
/* pointer to the data, make sure it's 16 bytes aligned */
s = MEM_ALIGN (&chain->tmp[chain->blocks], ALIGN);
/* set up the pointers */
for (i = 0; i < chain->blocks; i++)
chain->tmp[i] = s + i * stride;
}
GST_LOG ("temp samples %p %" G_GSIZE_FORMAT, chain->tmp, num_samples);
return chain->tmp;
}
static gboolean
do_unpack (AudioChain * chain, gpointer user_data)
{
GstAudioConverter *convert = user_data;
gsize num_samples;
gpointer *tmp;
gboolean in_writable;
in_writable = convert->in_writable;
num_samples = convert->in_frames;
if (!chain->allow_ip || !in_writable || !convert->in_default) {
gint i;
if (in_writable && chain->allow_ip) {
tmp = convert->in_data;
GST_LOG ("unpack in-place %p, %" G_GSIZE_FORMAT, tmp, num_samples);
} else {
tmp = audio_chain_alloc_samples (chain, num_samples);
GST_LOG ("unpack to tmp %p, %" G_GSIZE_FORMAT, tmp, num_samples);
}
if (convert->in_data) {
for (i = 0; i < chain->blocks; i++) {
if (convert->in_default) {
GST_LOG ("copy %p, %p, %" G_GSIZE_FORMAT, tmp[i], convert->in_data[i],
num_samples);
memcpy (tmp[i], convert->in_data[i], num_samples * chain->stride);
} else {
GST_LOG ("unpack %p, %p, %" G_GSIZE_FORMAT, tmp[i],
convert->in_data[i], num_samples);
convert->in.finfo->unpack_func (convert->in.finfo,
GST_AUDIO_PACK_FLAG_TRUNCATE_RANGE, tmp[i], convert->in_data[i],
num_samples * chain->inc);
}
}
} else {
for (i = 0; i < chain->blocks; i++) {
gst_audio_format_fill_silence (chain->finfo, tmp[i],
num_samples * chain->inc);
}
}
} else {
tmp = convert->in_data;
GST_LOG ("get in samples %p", tmp);
}
audio_chain_set_samples (chain, tmp, num_samples);
return TRUE;
}
static gboolean
do_convert_in (AudioChain * chain, gpointer user_data)
{
gsize num_samples;
GstAudioConverter *convert = user_data;
gpointer *in, *out;
gint i;
in = audio_chain_get_samples (chain->prev, &num_samples);
out = (chain->allow_ip ? in : audio_chain_alloc_samples (chain, num_samples));
GST_LOG ("convert in %p, %p, %" G_GSIZE_FORMAT, in, out, num_samples);
for (i = 0; i < chain->blocks; i++)
convert->convert_in (out[i], in[i], num_samples * chain->inc);
audio_chain_set_samples (chain, out, num_samples);
return TRUE;
}
static gboolean
do_mix (AudioChain * chain, gpointer user_data)
{
gsize num_samples;
GstAudioConverter *convert = user_data;
gpointer *in, *out;
in = audio_chain_get_samples (chain->prev, &num_samples);
out = (chain->allow_ip ? in : audio_chain_alloc_samples (chain, num_samples));
GST_LOG ("mix %p, %p, %" G_GSIZE_FORMAT, in, out, num_samples);
gst_audio_channel_mixer_samples (convert->mix, in, out, num_samples);
audio_chain_set_samples (chain, out, num_samples);
return TRUE;
}
static gboolean
do_resample (AudioChain * chain, gpointer user_data)
{
GstAudioConverter *convert = user_data;
gpointer *in, *out;
gsize in_frames, out_frames;
in = audio_chain_get_samples (chain->prev, &in_frames);
out_frames = convert->out_frames;
out = (chain->allow_ip ? in : audio_chain_alloc_samples (chain, out_frames));
GST_LOG ("resample %p %p,%" G_GSIZE_FORMAT " %" G_GSIZE_FORMAT, in,
out, in_frames, out_frames);
gst_audio_resampler_resample (convert->resampler, in, in_frames, out,
out_frames);
audio_chain_set_samples (chain, out, out_frames);
return TRUE;
}
static gboolean
do_convert_out (AudioChain * chain, gpointer user_data)
{
GstAudioConverter *convert = user_data;
gsize num_samples;
gpointer *in, *out;
gint i;
in = audio_chain_get_samples (chain->prev, &num_samples);
out = (chain->allow_ip ? in : audio_chain_alloc_samples (chain, num_samples));
GST_LOG ("convert out %p, %p %" G_GSIZE_FORMAT, in, out, num_samples);
for (i = 0; i < chain->blocks; i++)
convert->convert_out (out[i], in[i], num_samples * chain->inc);
audio_chain_set_samples (chain, out, num_samples);
return TRUE;
}
static gboolean
do_quantize (AudioChain * chain, gpointer user_data)
{
GstAudioConverter *convert = user_data;
gsize num_samples;
gpointer *in, *out;
in = audio_chain_get_samples (chain->prev, &num_samples);
out = (chain->allow_ip ? in : audio_chain_alloc_samples (chain, num_samples));
GST_LOG ("quantize %p, %p %" G_GSIZE_FORMAT, in, out, num_samples);
gst_audio_quantize_samples (convert->quant, in, out, num_samples);
audio_chain_set_samples (chain, out, num_samples);
return TRUE;
}
static gboolean
is_intermediate_format (GstAudioFormat format)
{
return (format == GST_AUDIO_FORMAT_S16 ||
format == GST_AUDIO_FORMAT_S32 ||
format == GST_AUDIO_FORMAT_F32 || format == GST_AUDIO_FORMAT_F64);
}
static AudioChain *
chain_unpack (GstAudioConverter * convert)
{
AudioChain *prev;
GstAudioInfo *in = &convert->in;
GstAudioInfo *out = &convert->out;
gboolean same_format;
same_format = in->finfo->format == out->finfo->format;
/* do not unpack if we have the same input format as the output format
* and it is a possible intermediate format */
if (same_format && is_intermediate_format (in->finfo->format)) {
convert->current_format = in->finfo->format;
} else {
convert->current_format = in->finfo->unpack_format;
}
convert->current_layout = in->layout;
convert->current_channels = in->channels;
convert->in_default = convert->current_format == in->finfo->format;
GST_INFO ("unpack format %s to %s",
gst_audio_format_to_string (in->finfo->format),
gst_audio_format_to_string (convert->current_format));
prev = audio_chain_new (NULL, convert);
prev->allow_ip = prev->finfo->width <= in->finfo->width;
prev->pass_alloc = FALSE;
audio_chain_set_make_func (prev, do_unpack, convert, NULL);
return prev;
}
static AudioChain *
chain_convert_in (GstAudioConverter * convert, AudioChain * prev)
{
gboolean in_int, out_int;
GstAudioInfo *in = &convert->in;
GstAudioInfo *out = &convert->out;
in_int = GST_AUDIO_FORMAT_INFO_IS_INTEGER (in->finfo);
out_int = GST_AUDIO_FORMAT_INFO_IS_INTEGER (out->finfo);
if (in_int && !out_int) {
GST_INFO ("convert S32 to F64");
convert->convert_in = (AudioConvertFunc) audio_orc_s32_to_double;
convert->current_format = GST_AUDIO_FORMAT_F64;
prev = audio_chain_new (prev, convert);
prev->allow_ip = FALSE;
prev->pass_alloc = FALSE;
audio_chain_set_make_func (prev, do_convert_in, convert, NULL);
}
return prev;
}
static AudioChain *
chain_mix (GstAudioConverter * convert, AudioChain * prev)
{
GstAudioChannelMixerFlags flags;
GstAudioInfo *in = &convert->in;
GstAudioInfo *out = &convert->out;
GstAudioFormat format = convert->current_format;
flags =
GST_AUDIO_INFO_IS_UNPOSITIONED (in) ?
GST_AUDIO_CHANNEL_MIXER_FLAGS_UNPOSITIONED_IN : 0;
flags |=
GST_AUDIO_INFO_IS_UNPOSITIONED (out) ?
GST_AUDIO_CHANNEL_MIXER_FLAGS_UNPOSITIONED_OUT : 0;
convert->current_channels = out->channels;
convert->mix =
gst_audio_channel_mixer_new (flags, format, in->channels, in->position,
out->channels, out->position);
convert->mix_passthrough =
gst_audio_channel_mixer_is_passthrough (convert->mix);
GST_INFO ("mix format %s, passthrough %d, in_channels %d, out_channels %d",
gst_audio_format_to_string (format), convert->mix_passthrough,
in->channels, out->channels);
if (!convert->mix_passthrough) {
prev = audio_chain_new (prev, convert);
prev->allow_ip = FALSE;
prev->pass_alloc = FALSE;
audio_chain_set_make_func (prev, do_mix, convert, NULL);
}
return prev;
}
static AudioChain *
chain_resample (GstAudioConverter * convert, AudioChain * prev)
{
GstAudioInfo *in = &convert->in;
GstAudioInfo *out = &convert->out;
GstAudioResamplerMethod method;
GstAudioResamplerFlags flags;
GstAudioFormat format = convert->current_format;
gint channels = convert->current_channels;
gboolean variable_rate;
variable_rate = convert->flags & GST_AUDIO_CONVERTER_FLAG_VARIABLE_RATE;
if (in->rate != out->rate || variable_rate) {
method = GET_OPT_RESAMPLER_METHOD (convert);
flags = 0;
if (convert->current_layout == GST_AUDIO_LAYOUT_NON_INTERLEAVED) {
flags |= GST_AUDIO_RESAMPLER_FLAG_NON_INTERLEAVED_IN;
flags |= GST_AUDIO_RESAMPLER_FLAG_NON_INTERLEAVED_OUT;
}
if (variable_rate)
flags |= GST_AUDIO_RESAMPLER_FLAG_VARIABLE_RATE;
convert->resampler =
gst_audio_resampler_new (method, flags, format, channels, in->rate,
out->rate, convert->config);
prev = audio_chain_new (prev, convert);
prev->allow_ip = FALSE;
prev->pass_alloc = FALSE;
audio_chain_set_make_func (prev, do_resample, convert, NULL);
}
return prev;
}
static AudioChain *
chain_convert_out (GstAudioConverter * convert, AudioChain * prev)
{
gboolean in_int, out_int;
GstAudioInfo *in = &convert->in;
GstAudioInfo *out = &convert->out;
in_int = GST_AUDIO_FORMAT_INFO_IS_INTEGER (in->finfo);
out_int = GST_AUDIO_FORMAT_INFO_IS_INTEGER (out->finfo);
if (!in_int && out_int) {
convert->convert_out = (AudioConvertFunc) audio_orc_double_to_s32;
convert->current_format = GST_AUDIO_FORMAT_S32;
GST_INFO ("convert F64 to S32");
prev = audio_chain_new (prev, convert);
prev->allow_ip = TRUE;
prev->pass_alloc = FALSE;
audio_chain_set_make_func (prev, do_convert_out, convert, NULL);
}
return prev;
}
static AudioChain *
chain_quantize (GstAudioConverter * convert, AudioChain * prev)
{
const GstAudioFormatInfo *cur_finfo;
GstAudioInfo *out = &convert->out;
gint in_depth, out_depth;
gboolean in_int, out_int;
GstAudioDitherMethod dither;
GstAudioNoiseShapingMethod ns;
dither = GET_OPT_DITHER_METHOD (convert);
ns = GET_OPT_NOISE_SHAPING_METHOD (convert);
cur_finfo = gst_audio_format_get_info (convert->current_format);
in_depth = GST_AUDIO_FORMAT_INFO_DEPTH (cur_finfo);
out_depth = GST_AUDIO_FORMAT_INFO_DEPTH (out->finfo);
GST_INFO ("depth in %d, out %d", in_depth, out_depth);
in_int = GST_AUDIO_FORMAT_INFO_IS_INTEGER (cur_finfo);
out_int = GST_AUDIO_FORMAT_INFO_IS_INTEGER (out->finfo);
/* Don't dither or apply noise shaping if target depth is bigger than 20 bits
* as DA converters only can do a SNR up to 20 bits in reality.
* Also don't dither or apply noise shaping if target depth is larger than
* source depth. */
if (out_depth > 20 || (in_int && out_depth >= in_depth)) {
dither = GST_AUDIO_DITHER_NONE;
ns = GST_AUDIO_NOISE_SHAPING_NONE;
GST_INFO ("using no dither and noise shaping");
} else {
GST_INFO ("using dither %d and noise shaping %d", dither, ns);
/* Use simple error feedback when output sample rate is smaller than
* 32000 as the other methods might move the noise to audible ranges */
if (ns > GST_AUDIO_NOISE_SHAPING_ERROR_FEEDBACK && out->rate < 32000)
ns = GST_AUDIO_NOISE_SHAPING_ERROR_FEEDBACK;
}
/* we still want to run the quantization step when reducing bits to get
* the rounding correct */
if (out_int && out_depth < 32
&& convert->current_format == GST_AUDIO_FORMAT_S32) {
GST_INFO ("quantize to %d bits, dither %d, ns %d", out_depth, dither, ns);
convert->quant =
gst_audio_quantize_new (dither, ns, 0, convert->current_format,
out->channels, 1U << (32 - out_depth));
prev = audio_chain_new (prev, convert);
prev->allow_ip = TRUE;
prev->pass_alloc = TRUE;
audio_chain_set_make_func (prev, do_quantize, convert, NULL);
}
return prev;
}
static AudioChain *
chain_pack (GstAudioConverter * convert, AudioChain * prev)
{
GstAudioInfo *out = &convert->out;
GstAudioFormat format = convert->current_format;
convert->current_format = out->finfo->format;
convert->out_default = format == out->finfo->format;
GST_INFO ("pack format %s to %s", gst_audio_format_to_string (format),
gst_audio_format_to_string (out->finfo->format));
return prev;
}
static void
setup_allocators (GstAudioConverter * convert)
{
AudioChain *chain;
AudioChainAllocFunc alloc_func;
gboolean allow_ip;
/* start with using dest if we can directly write into it */
if (convert->out_default) {
alloc_func = get_output_samples;
allow_ip = FALSE;
} else {
alloc_func = get_temp_samples;
allow_ip = TRUE;
}
/* now walk backwards, we try to write into the dest samples directly
* and keep track if the source needs to be writable */
for (chain = convert->chain_end; chain; chain = chain->prev) {
chain->alloc_func = alloc_func;
chain->alloc_data = convert;
chain->allow_ip = allow_ip && chain->allow_ip;
GST_LOG ("chain %p: %d %d", chain, allow_ip, chain->allow_ip);
if (!chain->pass_alloc) {
/* can't pass allocator, make new temp line allocator */
alloc_func = get_temp_samples;
allow_ip = TRUE;
}
}
}
static gboolean
converter_passthrough (GstAudioConverter * convert,
GstAudioConverterFlags flags, gpointer in[], gsize in_frames,
gpointer out[], gsize out_frames)
{
gint i;
AudioChain *chain;
gsize samples;
/* in-place passthrough -> do nothing */
if (in == out) {
g_assert (convert->in_place);
return TRUE;
}
chain = convert->chain_end;
samples = in_frames * chain->inc;
GST_LOG ("passthrough: %" G_GSIZE_FORMAT " / %" G_GSIZE_FORMAT " samples",
in_frames, samples);
if (in) {
gsize bytes;
bytes = samples * (convert->in.bpf / convert->in.channels);
for (i = 0; i < chain->blocks; i++) {
if (out[i] == in[i]) {
g_assert (convert->in_place);
continue;
}
memcpy (out[i], in[i], bytes);
}
} else {
for (i = 0; i < chain->blocks; i++)
gst_audio_format_fill_silence (convert->in.finfo, out[i], samples);
}
return TRUE;
}
/* perform LE<->BE conversion on a block of @count 16-bit samples
* dst may equal src for in-place conversion
*/
static void
converter_swap_endian_16 (gpointer dst, const gpointer src, gint count)
{
guint16 *out = dst;
const guint16 *in = src;
gint i;
for (i = 0; i < count; i++)
out[i] = GUINT16_SWAP_LE_BE (in[i]);
}
/* perform LE<->BE conversion on a block of @count 24-bit samples
* dst may equal src for in-place conversion
*
* naive algorithm, which performs better with -O3 and worse with -O2
* than the commented out optimized algorithm below
*/
static void
converter_swap_endian_24 (gpointer dst, const gpointer src, gint count)
{
guint8 *out = dst;
const guint8 *in = src;
gint i;
count *= 3;
for (i = 0; i < count; i += 3) {
guint8 x = in[i + 0];
out[i + 0] = in[i + 2];
out[i + 1] = in[i + 1];
out[i + 2] = x;
}
}
/* the below code performs better with -O2 but worse with -O3 */
#if 0
/* perform LE<->BE conversion on a block of @count 24-bit samples
* dst may equal src for in-place conversion
*
* assumes that dst and src are 32-bit aligned
*/
static void
converter_swap_endian_24 (gpointer dst, const gpointer src, gint count)
{
guint32 *out = dst;
const guint32 *in = src;
guint8 *out8;
const guint8 *in8;
gint i;
/* first convert 24-bit samples in multiples of 4 reading 3x 32-bits in one cycle
*
* input: A1 B1 C1 A2 , B2 C2 A3 B3 , C3 A4 B4 C4
* 32-bit endian swap: A2 C1 B1 A1 , B3 A3 C2 B2 , C4 B4 A4 C3
* <-- x --> <-- y --> , <-- z -->
*
* desired output: C1 B1 A1 C2 , B2 A2 C3 B3 , A3 C4 B4 A4
*/
for (i = 0; i < count / 4; i++, in += 3, out += 3) {
guint32 x, y, z;
x = GUINT32_SWAP_LE_BE (in[0]);
y = GUINT32_SWAP_LE_BE (in[1]);
z = GUINT32_SWAP_LE_BE (in[2]);
#if G_BYTE_ORDER == G_BIG_ENDIAN
out[0] = (x << 8) + ((y >> 8) & 0xff);
out[1] = (in[1] & 0xff0000ff) + ((x >> 8) & 0xff0000) + ((z << 8) & 0xff00);
out[2] = (z >> 8) + ((y << 8) & 0xff000000);
#else
out[0] = (x >> 8) + ((y << 8) & 0xff000000);
out[1] = (in[1] & 0xff0000ff) + ((x << 8) & 0xff00) + ((z >> 8) & 0xff0000);
out[2] = (z << 8) + ((y >> 8) & 0xff);
#endif
}
/* convert the remainder less efficiently */
for (out8 = (guint8 *) out, in8 = (const guint8 *) in, i = 0; i < (count & 3);
i++) {
guint8 x = in8[i + 0];
out8[i + 0] = in8[i + 2];
out8[i + 1] = in8[i + 1];
out8[i + 2] = x;
}
}
#endif
/* perform LE<->BE conversion on a block of @count 32-bit samples
* dst may equal src for in-place conversion
*/
static void
converter_swap_endian_32 (gpointer dst, const gpointer src, gint count)
{
guint32 *out = dst;
const guint32 *in = src;
gint i;
for (i = 0; i < count; i++)
out[i] = GUINT32_SWAP_LE_BE (in[i]);
}
/* perform LE<->BE conversion on a block of @count 64-bit samples
* dst may equal src for in-place conversion
*/
static void
converter_swap_endian_64 (gpointer dst, const gpointer src, gint count)
{
guint64 *out = dst;
const guint64 *in = src;
gint i;
for (i = 0; i < count; i++)
out[i] = GUINT64_SWAP_LE_BE (in[i]);
}
/* the worker function to perform endian-conversion only
* assuming finfo and foutinfo have the same depth
*/
static gboolean
converter_endian (GstAudioConverter * convert,
GstAudioConverterFlags flags, gpointer in[], gsize in_frames,
gpointer out[], gsize out_frames)
{
gint i;
AudioChain *chain;
gsize samples;
chain = convert->chain_end;
samples = in_frames * chain->inc;
GST_LOG ("convert endian: %" G_GSIZE_FORMAT " / %" G_GSIZE_FORMAT " samples",
in_frames, samples);
if (in) {
for (i = 0; i < chain->blocks; i++)
convert->swap_endian (out[i], in[i], samples);
} else {
for (i = 0; i < chain->blocks; i++)
gst_audio_format_fill_silence (convert->in.finfo, out[i], samples);
}
return TRUE;
}
static gboolean
converter_generic (GstAudioConverter * convert,
GstAudioConverterFlags flags, gpointer in[], gsize in_frames,
gpointer out[], gsize out_frames)
{
AudioChain *chain;
gpointer *tmp;
gint i;
gsize produced;
chain = convert->chain_end;
convert->in_writable = flags & GST_AUDIO_CONVERTER_FLAG_IN_WRITABLE;
convert->in_data = in;
convert->in_frames = in_frames;
convert->out_data = out;
convert->out_frames = out_frames;
/* get frames to pack */
tmp = audio_chain_get_samples (chain, &produced);
if (!convert->out_default) {
GST_LOG ("pack %p, %p %" G_GSIZE_FORMAT, tmp, out, produced);
/* and pack if needed */
for (i = 0; i < chain->blocks; i++)
convert->out.finfo->pack_func (convert->out.finfo, 0, tmp[i], out[i],
produced * chain->inc);
}
return TRUE;
}
static gboolean
converter_resample (GstAudioConverter * convert,
GstAudioConverterFlags flags, gpointer in[], gsize in_frames,
gpointer out[], gsize out_frames)
{
gst_audio_resampler_resample (convert->resampler, in, in_frames, out,
out_frames);
return TRUE;
}
#define GST_AUDIO_FORMAT_IS_ENDIAN_CONVERSION(info1, info2) \
( \
!(((info1)->flags ^ (info2)->flags) & (~GST_AUDIO_FORMAT_FLAG_UNPACK)) && \
(info1)->endianness != (info2)->endianness && \
(info1)->width == (info2)->width && \
(info1)->depth == (info2)->depth \
)
/**
* gst_audio_converter_new: (skip)
* @flags: extra #GstAudioConverterFlags
* @in_info: a source #GstAudioInfo
* @out_info: a destination #GstAudioInfo
* @config: (transfer full): a #GstStructure with configuration options
*
* Create a new #GstAudioConverter that is able to convert between @in and @out
* audio formats.
*
* @config contains extra configuration options, see #GST_VIDEO_CONVERTER_OPT_*
* parameters for details about the options and values.
*
* Returns: a #GstAudioConverter or %NULL if conversion is not possible.
*/
GstAudioConverter *
gst_audio_converter_new (GstAudioConverterFlags flags, GstAudioInfo * in_info,
GstAudioInfo * out_info, GstStructure * config)
{
GstAudioConverter *convert;
AudioChain *prev;
g_return_val_if_fail (in_info != NULL, FALSE);
g_return_val_if_fail (out_info != NULL, FALSE);
g_return_val_if_fail (in_info->layout == GST_AUDIO_LAYOUT_INTERLEAVED, FALSE);
g_return_val_if_fail (in_info->layout == out_info->layout, FALSE);
if ((GST_AUDIO_INFO_CHANNELS (in_info) != GST_AUDIO_INFO_CHANNELS (out_info))
&& (GST_AUDIO_INFO_IS_UNPOSITIONED (in_info)
|| GST_AUDIO_INFO_IS_UNPOSITIONED (out_info)))
goto unpositioned;
convert = g_slice_new0 (GstAudioConverter);
convert->flags = flags;
convert->in = *in_info;
convert->out = *out_info;
/* default config */
convert->config = gst_structure_new_empty ("GstAudioConverter");
if (config)
gst_audio_converter_update_config (convert, 0, 0, config);
GST_INFO ("unitsizes: %d -> %d", in_info->bpf, out_info->bpf);
/* step 1, unpack */
prev = chain_unpack (convert);
/* step 2, optional convert from S32 to F64 for channel mix */
prev = chain_convert_in (convert, prev);
/* step 3, channel mix */
prev = chain_mix (convert, prev);
/* step 4, resample */
prev = chain_resample (convert, prev);
/* step 5, optional convert for quantize */
prev = chain_convert_out (convert, prev);
/* step 6, optional quantize */
prev = chain_quantize (convert, prev);
/* step 7, pack */
convert->chain_end = chain_pack (convert, prev);
convert->convert = converter_generic;
convert->in_place = FALSE;
/* optimize */
if (convert->mix_passthrough) {
if (out_info->finfo->format == in_info->finfo->format) {
if (convert->resampler == NULL) {
GST_INFO
("same formats, no resampler and passthrough mixing -> passthrough");
convert->convert = converter_passthrough;
convert->in_place = TRUE;
} else {
if (is_intermediate_format (in_info->finfo->format)) {
GST_INFO ("same formats, and passthrough mixing -> only resampling");
convert->convert = converter_resample;
}
}
} else if (GST_AUDIO_FORMAT_IS_ENDIAN_CONVERSION (out_info->finfo,
in_info->finfo)) {
if (convert->resampler == NULL) {
GST_INFO ("no resampler, passthrough mixing -> only endian conversion");
convert->convert = converter_endian;
convert->in_place = TRUE;
switch (GST_AUDIO_INFO_BPS (in_info)) {
case 2:
GST_DEBUG ("initializing 16-bit endian conversion");
convert->swap_endian = converter_swap_endian_16;
break;
case 3:
GST_DEBUG ("initializing 24-bit endian conversion");
convert->swap_endian = converter_swap_endian_24;
break;
case 4:
GST_DEBUG ("initializing 32-bit endian conversion");
convert->swap_endian = converter_swap_endian_32;
break;
case 8:
GST_DEBUG ("initializing 64-bit endian conversion");
convert->swap_endian = converter_swap_endian_64;
break;
default:
GST_ERROR ("unsupported sample width for endian conversion");
g_assert_not_reached ();
}
}
}
}
setup_allocators (convert);
return convert;
/* ERRORS */
unpositioned:
{
GST_WARNING ("unpositioned channels");
return NULL;
}
}
/**
* gst_audio_converter_free:
* @convert: a #GstAudioConverter
*
* Free a previously allocated @convert instance.
*/
void
gst_audio_converter_free (GstAudioConverter * convert)
{
AudioChain *chain;
g_return_if_fail (convert != NULL);
/* walk the chain backwards and free all elements */
for (chain = convert->chain_end; chain;) {
AudioChain *prev = chain->prev;
audio_chain_free (chain);
chain = prev;
}
if (convert->quant)
gst_audio_quantize_free (convert->quant);
if (convert->mix)
gst_audio_channel_mixer_free (convert->mix);
if (convert->resampler)
gst_audio_resampler_free (convert->resampler);
gst_audio_info_init (&convert->in);
gst_audio_info_init (&convert->out);
gst_structure_free (convert->config);
g_slice_free (GstAudioConverter, convert);
}
/**
* gst_audio_converter_get_out_frames:
* @convert: a #GstAudioConverter
* @in_frames: number of input frames
*
* Calculate how many output frames can be produced when @in_frames input
* frames are given to @convert.
*
* Returns: the number of output frames
*/
gsize
gst_audio_converter_get_out_frames (GstAudioConverter * convert,
gsize in_frames)
{
if (convert->resampler)
return gst_audio_resampler_get_out_frames (convert->resampler, in_frames);
else
return in_frames;
}
/**
* gst_audio_converter_get_in_frames:
* @convert: a #GstAudioConverter
* @out_frames: number of output frames
*
* Calculate how many input frames are currently needed by @convert to produce
* @out_frames of output frames.
*
* Returns: the number of input frames
*/
gsize
gst_audio_converter_get_in_frames (GstAudioConverter * convert,
gsize out_frames)
{
if (convert->resampler)
return gst_audio_resampler_get_in_frames (convert->resampler, out_frames);
else
return out_frames;
}
/**
* gst_audio_converter_get_max_latency:
* @convert: a #GstAudioConverter
*
* Get the maximum number of input frames that the converter would
* need before producing output.
*
* Returns: the latency of @convert as expressed in the number of
* frames.
*/
gsize
gst_audio_converter_get_max_latency (GstAudioConverter * convert)
{
if (convert->resampler)
return gst_audio_resampler_get_max_latency (convert->resampler);
else
return 0;
}
/**
* gst_audio_converter_reset:
* @convert: a #GstAudioConverter
*
* Reset @convert to the state it was when it was first created, clearing
* any history it might currently have.
*/
void
gst_audio_converter_reset (GstAudioConverter * convert)
{
if (convert->resampler)
gst_audio_resampler_reset (convert->resampler);
if (convert->quant)
gst_audio_quantize_reset (convert->quant);
}
/**
* gst_audio_converter_samples:
* @convert: a #GstAudioConverter
* @flags: extra #GstAudioConverterFlags
* @in: input frames
* @in_frames: number of input frames
* @out: output frames
* @out_frames: number of output frames
*
* Perform the conversion with @in_frames in @in to @out_frames in @out
* using @convert.
*
* In case the samples are interleaved, @in and @out must point to an
* array with a single element pointing to a block of interleaved samples.
*
* If non-interleaved samples are used, @in and @out must point to an
* array with pointers to memory blocks, one for each channel.
*
* @in may be %NULL, in which case @in_frames of silence samples are processed
* by the converter.
*
* This function always produces @out_frames of output and consumes @in_frames of
* input. Use gst_audio_converter_get_out_frames() and
* gst_audio_converter_get_in_frames() to make sure @in_frames and @out_frames
* are matching and @in and @out point to enough memory.
*
* Returns: %TRUE is the conversion could be performed.
*/
gboolean
gst_audio_converter_samples (GstAudioConverter * convert,
GstAudioConverterFlags flags, gpointer in[], gsize in_frames,
gpointer out[], gsize out_frames)
{
g_return_val_if_fail (convert != NULL, FALSE);
g_return_val_if_fail (out != NULL, FALSE);
if (in_frames == 0) {
GST_LOG ("skipping empty buffer");
return TRUE;
}
return convert->convert (convert, flags, in, in_frames, out, out_frames);
}
/**
* gst_audio_converter_supports_inplace
* @convert: a #GstAudioConverter
*
* Returns whether the audio converter can perform the conversion in-place.
* The return value would be typically input to gst_base_transform_set_in_place()
*
* Returns: %TRUE when the conversion can be done in place.
*/
gboolean
gst_audio_converter_supports_inplace (GstAudioConverter * convert)
{
return convert->in_place;
}