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livetrax/libs/backends/portaudio/portaudio_io.cc
John Emmas a2b1482cad Fix a problem with ASIO buffer sizes on Windows 
PortAudio uses what it calls 'default suggested latencies' but in callback streaming mode, they can result in wildly inaccurate buffer sizing (e.g. the user requests a buffer size of 128 but PortAudio actually instructs ASIO to use a much bigger size).

What we do now is to improve PortAudio's suggested latency calculation by basing it on the actual buffer size requested by the user.
2021-03-18 16:12:28 +00:00

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/*
* Copyright (C) 2015-2016 Tim Mayberry <mojofunk@gmail.com>
* Copyright (C) 2015 Robin Gareus <robin@gareus.org>
*
* This program is free software; you can redistribute it and/or modify
* it under the terms of the GNU General Public License as published by
* the Free Software Foundation; either version 2 of the License, or
* (at your option) any later version.
*
* This program 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 General Public License for more details.
*
* You should have received a copy of the GNU General Public License along
* with this program; if not, write to the Free Software Foundation, Inc.,
* 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA.
*/
#include <stdio.h>
#include <stdlib.h>
#include <string.h>
#include <assert.h>
#include <glibmm.h>
#include "portaudio_io.h"
#ifdef WITH_ASIO
#include "pa_asio.h"
#endif
#include "pbd/compose.h"
#include "ardour/audio_backend.h"
#include "debug.h"
#define INTERLEAVED_INPUT
#define INTERLEAVED_OUTPUT
using namespace PBD;
using namespace ARDOUR;
PortAudioIO::PortAudioIO ()
: _capture_channels (0)
, _playback_channels (0)
, _stream (0)
, _input_buffer (0)
, _output_buffer (0)
, _cur_sample_rate (0)
, _cur_input_latency (0)
, _cur_output_latency (0)
, _host_api_index(-1)
{
}
PortAudioIO::~PortAudioIO ()
{
close_stream();
pa_deinitialize ();
clear_device_lists ();
free (_input_buffer); _input_buffer = NULL;
free (_output_buffer); _output_buffer = NULL;
}
std::string
PortAudioIO::control_app_name (int device_id) const
{
#ifdef WITH_ASIO
if (get_current_host_api_type() == paASIO) {
// is this used for anything, or just acts as a boolean?
return "PortaudioASIO";
}
#endif
return std::string();
}
void
PortAudioIO::launch_control_app (int device_id)
{
#ifdef WITH_ASIO
PaError err = PaAsio_ShowControlPanel (device_id, NULL);
if (err != paNoError) {
// error << ?
DEBUG_AUDIO (string_compose (
"Unable to show control panel for device with index %1\n", device_id));
}
#endif
}
void
PortAudioIO::get_default_sample_rates (std::vector<float>& rates)
{
rates.push_back(8000.0);
rates.push_back(22050.0);
rates.push_back(24000.0);
rates.push_back(44100.0);
rates.push_back(48000.0);
rates.push_back(88200.0);
rates.push_back(96000.0);
rates.push_back(176400.0);
rates.push_back(192000.0);
}
int
PortAudioIO::available_sample_rates(int device_id, std::vector<float>& sampleRates)
{
if (!pa_initialize()) return -1;
#ifdef WITH_ASIO
if (get_current_host_api_type() == paASIO) {
get_default_sample_rates(sampleRates);
return 0;
}
#endif
// TODO use separate int device_input, int device_output ?!
if (device_id == DeviceDefault) {
device_id = get_default_input_device ();
}
DEBUG_AUDIO (
string_compose ("Querying Samplerates for device %1\n", device_id));
sampleRates.clear();
const PaDeviceInfo* nfo = Pa_GetDeviceInfo(device_id);
if (nfo) {
PaStreamParameters inputParam;
PaStreamParameters outputParam;
inputParam.device = device_id;
inputParam.channelCount = nfo->maxInputChannels;
inputParam.sampleFormat = paFloat32;
inputParam.suggestedLatency = 0;
inputParam.hostApiSpecificStreamInfo = 0;
outputParam.device = device_id;
outputParam.channelCount = nfo->maxOutputChannels;
outputParam.sampleFormat = paFloat32;
outputParam.suggestedLatency = 0;
outputParam.hostApiSpecificStreamInfo = 0;
std::vector<float> rates;
get_default_sample_rates(rates);
for (std::vector<float>::const_iterator i = rates.begin(); i != rates.end();
++i) {
if (paFormatIsSupported ==
Pa_IsFormatSupported(nfo->maxInputChannels > 0 ? &inputParam : NULL,
nfo->maxOutputChannels > 0 ? &outputParam : NULL,
*i)) {
sampleRates.push_back(*i);
}
}
}
if (sampleRates.empty()) {
// fill in something..
get_default_sample_rates(sampleRates);
}
return 0;
}
#ifdef WITH_ASIO
bool
PortAudioIO::get_asio_buffer_properties (int device_id,
long& min_size_samples,
long& max_size_samples,
long& preferred_size_samples,
long& granularity)
{
// we shouldn't really need all these checks but it shouldn't hurt
const PaDeviceInfo* device_info = Pa_GetDeviceInfo(device_id);
if (!device_info) {
DEBUG_AUDIO (string_compose (
"Unable to get device info from device index %1\n", device_id));
return false;
}
if (get_current_host_api_type() != paASIO) {
DEBUG_AUDIO (string_compose (
"ERROR device_id %1 is not an ASIO device\n", device_id));
return false;
}
PaError err = PaAsio_GetAvailableBufferSizes (device_id,
&min_size_samples,
&max_size_samples,
&preferred_size_samples,
&granularity);
if (err != paNoError) {
DEBUG_AUDIO (string_compose (
"Unable to determine available buffer sizes for device %1\n", device_id));
return false;
}
return true;
}
static
bool
is_power_of_two (uint32_t v)
{
return ((v != 0) && !(v & (v - 1)));
}
bool
PortAudioIO::get_asio_buffer_sizes(int device_id,
std::vector<uint32_t>& buffer_sizes,
bool preferred_only)
{
long min_size_samples = 0;
long max_size_samples = 0;
long preferred_size_samples = 0;
long granularity = 0;
if (!get_asio_buffer_properties (device_id,
min_size_samples,
max_size_samples,
preferred_size_samples,
granularity)) {
DEBUG_AUDIO (string_compose (
"Unable to get device buffer properties from device index %1\n", device_id));
return false;
}
DEBUG_AUDIO (string_compose ("ASIO buffer properties for device %1, "
"min_size_samples: %2, max_size_samples: %3, "
"preferred_size_samples: %4, granularity: %5\n",
device_id,
min_size_samples,
max_size_samples,
preferred_size_samples,
granularity));
bool driver_returns_one_size = (min_size_samples == max_size_samples) &&
(min_size_samples == preferred_size_samples);
if (preferred_only || driver_returns_one_size) {
buffer_sizes.push_back(preferred_size_samples);
return true;
}
long buffer_size = min_size_samples;
// If min size and granularity are power of two then just use values that
// are power of 2 even if the granularity allows for more values
bool use_power_of_two =
is_power_of_two(min_size_samples) && is_power_of_two(granularity);
if (granularity <= 0 || use_power_of_two) {
// driver uses buffer sizes that are power of 2
while (buffer_size <= max_size_samples) {
buffer_sizes.push_back(buffer_size);
buffer_size *= 2;
}
} else {
if (min_size_samples == max_size_samples) {
// The devices I have tested either return the same values for
// min/max/preferred and changing buffer size is intended to only be
// done via the control dialog or they return a range where min != max
// but I guess min == max could happen if a driver only supports a single
// buffer size
buffer_sizes.push_back(min_size_samples);
return true;
}
// If min_size_samples is not power of 2 use at most 8 of the possible
// buffer sizes spread evenly between min and max
long max_values = 8;
while (((max_size_samples - min_size_samples) / granularity) > max_values) {
granularity *= 2;
}
while (buffer_size < max_size_samples) {
buffer_sizes.push_back(buffer_size);
buffer_size += granularity;
}
buffer_sizes.push_back(max_size_samples);
}
return true;
}
#endif
void
PortAudioIO::get_default_buffer_sizes(std::vector<uint32_t>& buffer_sizes)
{
buffer_sizes.push_back(64);
buffer_sizes.push_back(128);
buffer_sizes.push_back(256);
buffer_sizes.push_back(512);
buffer_sizes.push_back(1024);
buffer_sizes.push_back(2048);
buffer_sizes.push_back(4096);
}
int
PortAudioIO::available_buffer_sizes(int device_id, std::vector<uint32_t>& buffer_sizes)
{
#ifdef WITH_ASIO
if (get_current_host_api_type() == paASIO) {
if (get_asio_buffer_sizes (device_id, buffer_sizes, false)) {
return 0;
}
}
#endif
get_default_buffer_sizes (buffer_sizes);
return 0;
}
void
PortAudioIO::input_device_list(std::map<int, std::string> &devices) const
{
for (std::map<int, paDevice*>::const_iterator i = _input_devices.begin ();
i != _input_devices.end ();
++i) {
devices.insert (std::pair<int, std::string>(i->first, Glib::locale_to_utf8(i->second->name)));
}
}
void
PortAudioIO::output_device_list(std::map<int, std::string> &devices) const
{
for (std::map<int, paDevice*>::const_iterator i = _output_devices.begin ();
i != _output_devices.end ();
++i) {
devices.insert (std::pair<int, std::string>(i->first, Glib::locale_to_utf8(i->second->name)));
}
}
bool&
PortAudioIO::pa_initialized()
{
static bool s_initialized = false;
return s_initialized;
}
bool
PortAudioIO::pa_initialize()
{
if (pa_initialized()) return true;
PaError err = Pa_Initialize();
if (err != paNoError) {
return false;
}
pa_initialized() = true;
return true;
}
bool
PortAudioIO::pa_deinitialize()
{
if (!pa_initialized()) return true;
PaError err = Pa_Terminate();
if (err != paNoError) {
return false;
}
pa_initialized() = false;
return true;
}
void
PortAudioIO::host_api_list (std::vector<std::string>& api_list)
{
if (!pa_initialize()) return;
PaHostApiIndex count = Pa_GetHostApiCount();
if (count < 0) return;
for (int i = 0; i < count; ++i) {
const PaHostApiInfo* info = Pa_GetHostApiInfo (i);
if (info->name != NULL) { // possible?
api_list.push_back (info->name);
}
}
}
PaHostApiTypeId
PortAudioIO::get_current_host_api_type () const
{
const PaHostApiInfo* info = Pa_GetHostApiInfo (_host_api_index);
if (info == NULL) {
DEBUG_AUDIO(string_compose(
"Unable to determine Host API type from index %1\n", _host_api_index));
return (PaHostApiTypeId)0;
}
return info->type;
}
std::string
PortAudioIO::get_host_api_name_from_index (PaHostApiIndex index)
{
std::vector<std::string> api_list;
host_api_list(api_list);
return api_list[index];
}
bool
PortAudioIO::set_host_api (const std::string& host_api_name)
{
PaHostApiIndex new_index = get_host_api_index_from_name (host_api_name);
if (new_index < 0) {
DEBUG_AUDIO ("Portaudio: Error setting host API\n");
return false;
}
_host_api_index = new_index;
_host_api_name = host_api_name;
return true;
}
PaHostApiIndex
PortAudioIO::get_host_api_index_from_name (const std::string& name)
{
if (!pa_initialize()) return -1;
PaHostApiIndex count = Pa_GetHostApiCount();
if (count < 0) {
DEBUG_AUDIO ("Host API count < 0\n");
return -1;
}
for (int i = 0; i < count; ++i) {
const PaHostApiInfo* info = Pa_GetHostApiInfo (i);
if (info != NULL && info->name != NULL) { // possible?
if (name == info->name) {
return i;
}
}
}
DEBUG_AUDIO (string_compose ("Unable to get host API from name: %1\n", name));
return -1;
}
PaDeviceIndex
PortAudioIO::get_default_input_device () const
{
const PaHostApiInfo* info = Pa_GetHostApiInfo (_host_api_index);
if (info == NULL) return -1;
return info->defaultInputDevice;
}
PaDeviceIndex
PortAudioIO::get_default_output_device () const
{
const PaHostApiInfo* info = Pa_GetHostApiInfo (_host_api_index);
if (info == NULL) return -1;
return info->defaultOutputDevice;
}
void
PortAudioIO::clear_device_lists ()
{
for (std::map<int, paDevice*>::const_iterator i = _input_devices.begin (); i != _input_devices.end(); ++i) {
delete i->second;
}
_input_devices.clear();
for (std::map<int, paDevice*>::const_iterator i = _output_devices.begin (); i != _output_devices.end(); ++i) {
delete i->second;
}
_output_devices.clear();
}
void
PortAudioIO::add_none_devices ()
{
_input_devices.insert(std::pair<int, paDevice*>(
DeviceNone, new paDevice(AudioBackend::get_standard_device_name(AudioBackend::DeviceNone), 0, 0)));
_output_devices.insert(std::pair<int, paDevice*>(
DeviceNone, new paDevice(AudioBackend::get_standard_device_name(AudioBackend::DeviceNone), 0, 0)));
}
void
PortAudioIO::add_default_devices ()
{
const PaHostApiInfo* info = Pa_GetHostApiInfo (_host_api_index);
if (info == NULL) return;
const PaDeviceInfo* nfo_i = Pa_GetDeviceInfo(get_default_input_device());
const PaDeviceInfo* nfo_o = Pa_GetDeviceInfo(get_default_output_device());
if (nfo_i && nfo_o) {
_input_devices.insert (std::pair<int, paDevice*> (DeviceDefault,
new paDevice(AudioBackend::get_standard_device_name(AudioBackend::DeviceDefault),
nfo_i->maxInputChannels,
nfo_o->maxOutputChannels
)));
_output_devices.insert (std::pair<int, paDevice*> (DeviceDefault,
new paDevice(AudioBackend::get_standard_device_name(AudioBackend::DeviceDefault),
nfo_i->maxInputChannels,
nfo_o->maxOutputChannels
)));
}
}
void
PortAudioIO::add_devices ()
{
const PaHostApiInfo* info = Pa_GetHostApiInfo (_host_api_index);
if (info == NULL) return;
int n_devices = Pa_GetDeviceCount();
DEBUG_AUDIO (string_compose ("PortAudio found %1 devices\n", n_devices));
for (int i = 0 ; i < n_devices; ++i) {
const PaDeviceInfo* nfo = Pa_GetDeviceInfo(i);
if (!nfo) continue;
if (nfo->hostApi != _host_api_index) continue;
DEBUG_AUDIO (string_compose (" (%1) '%2' '%3' in: %4 (lat: %5 .. %6) out: %7 "
"(lat: %8 .. %9) sr:%10\n",
i,
info->name,
nfo->name,
nfo->maxInputChannels,
nfo->defaultLowInputLatency * 1e3,
nfo->defaultHighInputLatency * 1e3,
nfo->maxOutputChannels,
nfo->defaultLowOutputLatency * 1e3,
nfo->defaultHighOutputLatency * 1e3,
nfo->defaultSampleRate));
if ( nfo->maxInputChannels == 0 && nfo->maxOutputChannels == 0) {
continue;
}
if (nfo->maxInputChannels > 0) {
_input_devices.insert (std::pair<int, paDevice*> (i, new paDevice(
nfo->name,
nfo->maxInputChannels,
nfo->maxOutputChannels
)));
}
if (nfo->maxOutputChannels > 0) {
_output_devices.insert (std::pair<int, paDevice*> (i, new paDevice(
nfo->name,
nfo->maxInputChannels,
nfo->maxOutputChannels
)));
}
}
}
bool
PortAudioIO::update_devices()
{
DEBUG_AUDIO ("Update devices\n");
if (_stream != NULL) return false;
pa_deinitialize();
if (!pa_initialize()) return false;
clear_device_lists ();
// ASIO doesn't support separate input/output devices so adding None
// doesn't make sense
if (get_current_host_api_type() != paASIO) {
add_none_devices ();
}
add_devices ();
return true;
}
void
PortAudioIO::reset_stream_dependents ()
{
_capture_channels = 0;
_playback_channels = 0;
_cur_sample_rate = 0;
_cur_input_latency = 0;
_cur_output_latency = 0;
}
PaErrorCode
PortAudioIO::close_stream()
{
if (!_stream) return paNoError;
PaError err = Pa_CloseStream (_stream);
if (err != paNoError) {
return (PaErrorCode)err;
}
_stream = NULL;
reset_stream_dependents();
free (_input_buffer); _input_buffer = NULL;
free (_output_buffer); _output_buffer = NULL;
return paNoError;
}
PaErrorCode
PortAudioIO::start_stream()
{
PaError err = Pa_StartStream (_stream);
if (err != paNoError) {
DEBUG_AUDIO(string_compose("PortAudio failed to start stream %1\n",
Pa_GetErrorText(err)));
return (PaErrorCode)err;
}
return paNoError;
}
bool
PortAudioIO::set_sample_rate_and_latency_from_stream ()
{
const PaStreamInfo* nfo_s = Pa_GetStreamInfo(_stream);
if (nfo_s == NULL) {
return false;
}
_cur_sample_rate = nfo_s->sampleRate;
_cur_input_latency = nfo_s->inputLatency * _cur_sample_rate;
_cur_output_latency = nfo_s->outputLatency * _cur_sample_rate;
DEBUG_AUDIO (string_compose ("PA Sample Rate %1 SPS\n", _cur_sample_rate));
DEBUG_AUDIO (string_compose ("PA Input Latency %1ms, %2 spl\n",
1e3 * nfo_s->inputLatency,
_cur_input_latency));
DEBUG_AUDIO (string_compose ("PA Output Latency %1ms, %2 spl\n",
1e3 * nfo_s->outputLatency,
_cur_output_latency));
return true;
}
bool
PortAudioIO::allocate_buffers_for_blocking_api (uint32_t samples_per_period)
{
if (_capture_channels > 0) {
_input_buffer =
(float*)malloc(samples_per_period * _capture_channels * sizeof(float));
if (!_input_buffer) {
DEBUG_AUDIO("PortAudio failed to allocate input buffer.\n");
return false;
}
}
if (_playback_channels > 0) {
_output_buffer =
(float*)calloc(samples_per_period * _playback_channels, sizeof(float));
if (!_output_buffer) {
DEBUG_AUDIO("PortAudio failed to allocate output buffer.\n");
return false;
}
}
return true;
}
bool
PortAudioIO::get_input_stream_params(int device_input,
PaStreamParameters& inputParam) const
{
const PaDeviceInfo *nfo_in = NULL;
if (device_input == DeviceDefault) {
device_input = get_default_input_device ();
}
if (device_input == DeviceNone) {
return false;
}
nfo_in = Pa_GetDeviceInfo(device_input);
if (nfo_in == NULL) {
DEBUG_AUDIO ("PortAudio Cannot Query Input Device Info\n");
return false;
}
inputParam.device = device_input;
inputParam.channelCount = nfo_in->maxInputChannels;
#ifdef INTERLEAVED_INPUT
inputParam.sampleFormat = paFloat32;
#else
inputParam.sampleFormat = paFloat32 | paNonInterleaved;
#endif
if (!inputParam.suggestedLatency) {
inputParam.suggestedLatency = nfo_in->defaultLowInputLatency;
}
inputParam.hostApiSpecificStreamInfo = NULL;
return true;
}
bool
PortAudioIO::get_output_stream_params(int device_output,
PaStreamParameters& outputParam) const
{
const PaDeviceInfo *nfo_out = NULL;
if (device_output == DeviceDefault) {
device_output = get_default_output_device ();
}
if (device_output == DeviceNone) {
return false;
}
nfo_out = Pa_GetDeviceInfo(device_output);
if (nfo_out == NULL) {
DEBUG_AUDIO ("PortAudio Cannot Query Output Device Info\n");
return false;
}
outputParam.device = device_output;
outputParam.channelCount = nfo_out->maxOutputChannels;
#ifdef INTERLEAVED_OUTPUT
outputParam.sampleFormat = paFloat32;
#else
outputParam.sampleFormat = paFloat32 | paNonInterleaved;
#endif
if (!outputParam.suggestedLatency) {
outputParam.suggestedLatency = nfo_out->defaultLowOutputLatency;
}
outputParam.hostApiSpecificStreamInfo = NULL;
return true;
}
PaErrorCode
PortAudioIO::pre_stream_open(int device_input,
PaStreamParameters& inputParam,
int device_output,
PaStreamParameters& outputParam,
uint32_t sample_rate,
uint32_t samples_per_period)
{
if (!pa_initialize()) {
DEBUG_AUDIO ("PortAudio Initialization Failed\n");
return paNotInitialized;
}
reset_stream_dependents ();
DEBUG_AUDIO (string_compose (
"PortAudio Device IDs: i:%1 o:%2\n", device_input, device_output));
if (device_input == DeviceNone && device_output == DeviceNone) {
return paBadIODeviceCombination;
}
if ((get_current_host_api_type() == paASIO) && sample_rate) {
outputParam.suggestedLatency = inputParam.suggestedLatency = ((double)samples_per_period / (double)sample_rate);
} else {
outputParam.suggestedLatency = inputParam.suggestedLatency = 0;
}
if (get_input_stream_params(device_input, inputParam)) {
_capture_channels = inputParam.channelCount;
}
if (get_output_stream_params(device_output, outputParam)) {
_playback_channels = outputParam.channelCount;
}
if (_capture_channels == 0 && _playback_channels == 0) {
DEBUG_AUDIO("PortAudio no input or output channels.\n");
return paBadIODeviceCombination;
}
DEBUG_AUDIO (string_compose ("PortAudio Channels: in:%1 out:%2\n",
_capture_channels,
_playback_channels));
return paNoError;
}
PaErrorCode
PortAudioIO::open_callback_stream(int device_input,
int device_output,
double sample_rate,
uint32_t samples_per_period,
PaStreamCallback* callback,
void* data)
{
PaStreamParameters inputParam;
PaStreamParameters outputParam;
PaErrorCode error_code =
pre_stream_open(device_input, inputParam, device_output, outputParam, sample_rate, samples_per_period);
if (error_code != paNoError) return error_code;
PaError err = paNoError;
DEBUG_AUDIO ("Open Callback Stream\n");
err = Pa_OpenStream(&_stream,
_capture_channels > 0 ? &inputParam : NULL,
_playback_channels > 0 ? &outputParam : NULL,
sample_rate,
samples_per_period,
paDitherOff,
callback,
data);
if (err != paNoError) {
DEBUG_AUDIO(string_compose("PortAudio failed to open stream %1\n",
Pa_GetErrorText(err)));
return paInternalError;
}
if (!set_sample_rate_and_latency_from_stream()) {
DEBUG_AUDIO ("PortAudio failed to query stream information.\n");
close_stream();
return paInternalError;
}
return paNoError;
}
PaErrorCode
PortAudioIO::open_blocking_stream(int device_input,
int device_output,
double sample_rate,
uint32_t samples_per_period)
{
PaStreamParameters inputParam;
PaStreamParameters outputParam;
PaErrorCode error_code =
pre_stream_open(device_input, inputParam, device_output, outputParam, sample_rate, samples_per_period);
if (error_code != paNoError) return error_code;
PaError err = paNoError;
err = Pa_OpenStream (
&_stream,
_capture_channels > 0 ? &inputParam: NULL,
_playback_channels > 0 ? &outputParam: NULL,
sample_rate,
samples_per_period,
paDitherOff,
NULL, NULL);
if (err != paNoError) {
DEBUG_AUDIO(string_compose("PortAudio failed to open stream %1\n",
Pa_GetErrorText(err)));
return (PaErrorCode)err;
}
if (!set_sample_rate_and_latency_from_stream()) {
DEBUG_AUDIO ("PortAudio failed to query stream information.\n");
close_stream();
return paInternalError;
}
if (!allocate_buffers_for_blocking_api(samples_per_period)) {
close_stream();
return paInternalError;
}
return paNoError;
}
int
PortAudioIO::next_cycle (uint32_t n_samples)
{
bool xrun = false;
PaError err;
err = Pa_IsStreamActive (_stream);
if (err != 1) {
// 0: inactive / aborted
// < 0: error
return -1;
}
// TODO, check drift.. process part with larger capacity first.
// Pa_GetStreamReadAvailable(_stream) < Pa_GetStreamWriteAvailable(_stream)
if (_playback_channels > 0) {
err = Pa_WriteStream (_stream, _output_buffer, n_samples);
if (err) xrun = true;
}
if (_capture_channels > 0) {
err = Pa_ReadStream (_stream, _input_buffer, n_samples);
if (err) {
memset (_input_buffer, 0, sizeof(float) * n_samples * _capture_channels);
xrun = true;
}
}
return xrun ? 1 : 0;
}
std::string
PortAudioIO::get_input_channel_name (int device_id, uint32_t channel) const
{
#ifdef WITH_ASIO
const char* channel_name;
// This will return an error for non-ASIO devices so no need to check if
// the device_id corresponds to an ASIO device.
PaError err = PaAsio_GetInputChannelName (device_id, channel, &channel_name);
if (err == paNoError) {
DEBUG_AUDIO (
string_compose ("Input channel name for device %1, channel %2 is %3\n",
device_id,
channel,
channel_name));
return channel_name;
}
#endif
return std::string();
}
std::string
PortAudioIO::get_output_channel_name (int device_id, uint32_t channel) const
{
#ifdef WITH_ASIO
const char* channel_name;
PaError err = PaAsio_GetOutputChannelName (device_id, channel, &channel_name);
if (err == paNoError) {
DEBUG_AUDIO (
string_compose ("Output channel name for device %1, channel %2 is %3\n",
device_id,
channel,
channel_name));
return channel_name;
}
#endif
return std::string();
}
#ifdef INTERLEAVED_INPUT
int
PortAudioIO::get_capture_channel (uint32_t chn, float *input, uint32_t n_samples)
{
assert(chn < _capture_channels);
const uint32_t stride = _capture_channels;
float *ptr = _input_buffer + chn;
while (n_samples-- > 0) {
*input++ = *ptr;
ptr += stride;
}
return 0;
}
#else
int
PortAudioIO::get_capture_channel (uint32_t chn, float *input, uint32_t n_samples)
{
assert(chn < _capture_channels);
memcpy((void*)input, &(_input_buffer[chn * n_samples]), n_samples * sizeof(float));
return 0;
}
#endif
#ifdef INTERLEAVED_OUTPUT
int
PortAudioIO::set_playback_channel (uint32_t chn, const float *output, uint32_t n_samples)
{
assert(chn < _playback_channels);
const uint32_t stride = _playback_channels;
float *ptr = _output_buffer + chn;
while (n_samples-- > 0) {
*ptr = *output++;
ptr += stride;
}
return 0;
}
#else
int
PortAudioIO::set_playback_channel (uint32_t chn, const float *output, uint32_t n_samples)
{
assert(chn < _playback_channels);
memcpy((void*)&(_output_buffer[chn * n_samples]), (void*)output, n_samples * sizeof(float));
return 0;
}
#endif
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