path: root/gr-audio/lib/alsa/audio_alsa_source.cc

/* -*- c++ -*- */
/*
 * Copyright 2004-2011 Free Software Foundation, Inc.
 * 
 * This file is part of GNU Radio
 * 
 * GNU Radio 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 3, or (at your option)
 * any later version.
 * 
 * GNU Radio 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 GNU Radio; see the file COPYING.  If not, write to
 * the Free Software Foundation, Inc., 51 Franklin Street,
 * Boston, MA 02110-1301, USA.
 */

#ifdef HAVE_CONFIG_H
#include "config.h"
#endif

#include "gr_audio_registry.h"
#include <audio_alsa_source.h>
#include <gr_io_signature.h>
#include <gr_prefs.h>
#include <stdio.h>
#include <iostream>
#include <stdexcept>
#include <gri_alsa.h>

AUDIO_REGISTER_SOURCE(REG_PRIO_HIGH, alsa)(
    int sampling_rate, const std::string &device_name, bool ok_to_block
){
    return audio_source::sptr(new audio_alsa_source(sampling_rate, device_name, ok_to_block));
}

static bool CHATTY_DEBUG = false;

static snd_pcm_format_t acceptable_formats[] = {
  // these are in our preferred order...
  SND_PCM_FORMAT_S32,
  SND_PCM_FORMAT_S16
};

#define NELEMS(x) (sizeof(x)/sizeof(x[0]))


static std::string 
default_device_name ()
{
  return gr_prefs::singleton()->get_string("audio_alsa", "default_input_device", "hw:0,0");
}

static double
default_period_time ()
{
  return std::max(0.001, gr_prefs::singleton()->get_double("audio_alsa", "period_time", 0.010));
}

static int
default_nperiods ()
{
  return std::max(2L, gr_prefs::singleton()->get_long("audio_alsa", "nperiods", 4));
}

// ----------------------------------------------------------------

audio_alsa_source::audio_alsa_source (int sampling_rate,
				      const std::string device_name,
				      bool ok_to_block)
  : gr_sync_block ("audio_alsa_source",
		   gr_make_io_signature (0, 0, 0),
		   gr_make_io_signature (0, 0, 0)),
    d_sampling_rate (sampling_rate),
    d_device_name (device_name.empty() ? default_device_name() : device_name),
    d_pcm_handle (0),
    d_hw_params ((snd_pcm_hw_params_t *)(new char[snd_pcm_hw_params_sizeof()])),
    d_sw_params ((snd_pcm_sw_params_t *)(new char[snd_pcm_sw_params_sizeof()])),
    d_nperiods (default_nperiods()),
    d_period_time_us ((unsigned int) (default_period_time() * 1e6)),
    d_period_size (0),
    d_buffer_size_bytes (0), d_buffer (0),
    d_worker (0), d_hw_nchan (0),
    d_special_case_stereo_to_mono (false),
    d_noverruns (0), d_nsuspends (0)
{

  CHATTY_DEBUG = gr_prefs::singleton()->get_bool("audio_alsa", "verbose", false);

  int  	error;
  int	dir;

  // open the device for capture
  error = snd_pcm_open(&d_pcm_handle, d_device_name.c_str (),
		       SND_PCM_STREAM_CAPTURE, 0);
  if (error < 0){
    fprintf (stderr, "audio_alsa_source[%s]: %s\n",
	     d_device_name.c_str(), snd_strerror(error));
    throw std::runtime_error ("audio_alsa_source");
  }

  // Fill params with a full configuration space for a PCM.
  error = snd_pcm_hw_params_any(d_pcm_handle, d_hw_params);
  if (error < 0)
    bail ("broken configuration for playback", error);

  if (CHATTY_DEBUG)
    gri_alsa_dump_hw_params (d_pcm_handle, d_hw_params, stdout);

  // now that we know how many channels the h/w can handle, set output signature
  unsigned int umax_chan;
  unsigned int umin_chan;
  snd_pcm_hw_params_get_channels_min (d_hw_params, &umin_chan);
  snd_pcm_hw_params_get_channels_max (d_hw_params, &umax_chan);
  int min_chan = std::min (umin_chan, 1000U);
  int max_chan = std::min (umax_chan, 1000U);

  // As a special case, if the hw's min_chan is two, we'll accept
  // a single output and handle the demux ourselves.

  if (min_chan == 2){
    min_chan = 1;
    d_special_case_stereo_to_mono = true;
  }
  
  set_output_signature (gr_make_io_signature (min_chan, max_chan,
					      sizeof (float)));
  
  // fill in portions of the d_hw_params that we know now...

  // Specify the access methods we implement
  // For now, we only handle RW_INTERLEAVED...
  snd_pcm_access_mask_t *access_mask;
  snd_pcm_access_mask_t **access_mask_ptr = &access_mask; // FIXME: workaround for compiler warning
  snd_pcm_access_mask_alloca (access_mask_ptr);
  snd_pcm_access_mask_none (access_mask);
  snd_pcm_access_mask_set (access_mask, SND_PCM_ACCESS_RW_INTERLEAVED);
  // snd_pcm_access_mask_set (access_mask, SND_PCM_ACCESS_RW_NONINTERLEAVED);

  if ((error = snd_pcm_hw_params_set_access_mask (d_pcm_handle,
						  d_hw_params, access_mask)) < 0)
    bail ("failed to set access mask", error);


  // set sample format
  if (!gri_alsa_pick_acceptable_format (d_pcm_handle, d_hw_params,
					acceptable_formats,
					NELEMS (acceptable_formats),
					&d_format,
					"audio_alsa_source",
					CHATTY_DEBUG))
    throw std::runtime_error ("audio_alsa_source");
  

  // sampling rate
  unsigned int orig_sampling_rate = d_sampling_rate;
  if ((error = snd_pcm_hw_params_set_rate_near (d_pcm_handle, d_hw_params,
						&d_sampling_rate, 0)) < 0)
    bail ("failed to set rate near", error);
  
  if (orig_sampling_rate != d_sampling_rate){
    fprintf (stderr, "audio_alsa_source[%s]: unable to support sampling rate %d\n",
	     snd_pcm_name (d_pcm_handle), orig_sampling_rate);
    fprintf (stderr, "  card requested %d instead.\n", d_sampling_rate);
  }

  /*
   * ALSA transfers data in units of "periods".
   * We indirectly determine the underlying buffersize by specifying
   * the number of periods we want (typically 4) and the length of each
   * period in units of time (typically 1ms).
   */
  unsigned int min_nperiods, max_nperiods;
  snd_pcm_hw_params_get_periods_min (d_hw_params, &min_nperiods, &dir);
  snd_pcm_hw_params_get_periods_max (d_hw_params, &max_nperiods, &dir);
  //fprintf (stderr, "alsa_source: min_nperiods = %d, max_nperiods = %d\n",
  // min_nperiods, max_nperiods);


  unsigned int orig_nperiods = d_nperiods;
  d_nperiods = std::min (std::max (min_nperiods, d_nperiods), max_nperiods);

  // adjust period time so that total buffering remains more-or-less constant
  d_period_time_us = (d_period_time_us * orig_nperiods) / d_nperiods;

  error = snd_pcm_hw_params_set_periods (d_pcm_handle, d_hw_params,
					 d_nperiods, 0);
  if (error < 0)
    bail ("set_periods failed", error);

  dir = 0;
  error = snd_pcm_hw_params_set_period_time_near (d_pcm_handle, d_hw_params,
						  &d_period_time_us, &dir);
  if (error < 0)
    bail ("set_period_time_near failed", error);

  dir = 0;
  error = snd_pcm_hw_params_get_period_size (d_hw_params,
					     &d_period_size, &dir);
  if (error < 0)
    bail ("get_period_size failed", error);
  
  set_output_multiple (d_period_size);
}

bool
audio_alsa_source::check_topology (int ninputs, int noutputs)
{
  // noutputs is how many channels the user has connected.
  // Now we can finish up setting up the hw params...

  unsigned int nchan = noutputs;
  int err;

  // Check the state of the stream
  // Ensure that the pcm is in a state where we can still mess with the hw_params
  snd_pcm_state_t state;
  state=snd_pcm_state(d_pcm_handle);
  if ( state== SND_PCM_STATE_RUNNING)
    return true;  // If stream is running, don't change any parameters
  else if(state == SND_PCM_STATE_XRUN )
    snd_pcm_prepare ( d_pcm_handle ); // Prepare stream on underrun, and we can set parameters;

  bool special_case = nchan == 1 && d_special_case_stereo_to_mono;
  if (special_case)
    nchan = 2;

  d_hw_nchan = nchan;
  err = snd_pcm_hw_params_set_channels (d_pcm_handle, d_hw_params, d_hw_nchan);
  if (err < 0){
    output_error_msg ("set_channels failed", err);
    return false;
  }

  // set the parameters into the driver...
  err = snd_pcm_hw_params(d_pcm_handle, d_hw_params);
  if (err < 0){
    output_error_msg ("snd_pcm_hw_params failed", err);
    return false;
  }

  d_buffer_size_bytes =
    d_period_size * d_hw_nchan * snd_pcm_format_size (d_format, 1);

  d_buffer = new char [d_buffer_size_bytes];

  if (CHATTY_DEBUG)
    fprintf (stdout, "audio_alsa_source[%s]: sample resolution = %d bits\n",
	     snd_pcm_name (d_pcm_handle),
	     snd_pcm_hw_params_get_sbits (d_hw_params));

  switch (d_format){
  case SND_PCM_FORMAT_S16:
    if (special_case)
      d_worker = &audio_alsa_source::work_s16_2x1;
    else
      d_worker = &audio_alsa_source::work_s16;
    break;

  case SND_PCM_FORMAT_S32:
    if (special_case)
      d_worker = &audio_alsa_source::work_s32_2x1;
    else
      d_worker = &audio_alsa_source::work_s32;
    break;

  default:
    assert (0);
  }

  return true;
}

audio_alsa_source::~audio_alsa_source ()
{
  if (snd_pcm_state (d_pcm_handle) == SND_PCM_STATE_RUNNING)
    snd_pcm_drop (d_pcm_handle);

  snd_pcm_close(d_pcm_handle);
  delete [] ((char *) d_hw_params);
  delete [] ((char *) d_sw_params);
  delete [] d_buffer;
}

int
audio_alsa_source::work (int noutput_items,
			 gr_vector_const_void_star &input_items,
			 gr_vector_void_star &output_items)
{
  assert ((noutput_items % d_period_size) == 0);
  assert (noutput_items != 0);

  // this is a call through a pointer to a method...
  return (this->*d_worker)(noutput_items, input_items, output_items);
}

/*
 * Work function that deals with float to S16 conversion
 */
int
audio_alsa_source::work_s16 (int noutput_items,
			     gr_vector_const_void_star &input_items,
			     gr_vector_void_star &output_items)
{
  typedef gr_int16	sample_t;	// the type of samples we're creating
  static const int NBITS = 16;		// # of bits in a sample
  
  unsigned int nchan = output_items.size ();
  float **out = (float **) &output_items[0];
  sample_t *buf = (sample_t *) d_buffer;
  int bi;

  unsigned int sizeof_frame = d_hw_nchan * sizeof (sample_t);
  assert (d_buffer_size_bytes == d_period_size * sizeof_frame);

  // To minimize latency, return at most a single period's worth of samples.
  // [We could also read the first one in a blocking mode and subsequent
  //  ones in non-blocking mode, but we'll leave that for later (or never).]
  
  if (!read_buffer (buf, d_period_size, sizeof_frame))
    return -1;		// No fixing this problem.  Say we're done.

  // process one period of data
  bi = 0;
  for (unsigned int i = 0; i < d_period_size; i++){
    for (unsigned int chan = 0; chan < nchan; chan++){
      out[chan][i] = (float) buf[bi++] * (1.0 / (float) ((1L << (NBITS-1)) - 1));
    }
  }

  return d_period_size;
}

/*
 * Work function that deals with float to S16 conversion
 * and stereo to mono kludge...
 */
int
audio_alsa_source::work_s16_2x1 (int noutput_items,
				 gr_vector_const_void_star &input_items,
				 gr_vector_void_star &output_items)
{
  typedef gr_int16	sample_t;	// the type of samples we're creating
  static const int NBITS = 16;		// # of bits in a sample
  
  unsigned int nchan = output_items.size ();
  float **out = (float **) &output_items[0];
  sample_t *buf = (sample_t *) d_buffer;
  int bi;

  assert (nchan == 1);

  unsigned int sizeof_frame = d_hw_nchan * sizeof (sample_t);
  assert (d_buffer_size_bytes == d_period_size * sizeof_frame);

  // To minimize latency, return at most a single period's worth of samples.
  // [We could also read the first one in a blocking mode and subsequent
  //  ones in non-blocking mode, but we'll leave that for later (or never).]
  
  if (!read_buffer (buf, d_period_size, sizeof_frame))
    return -1;		// No fixing this problem.  Say we're done.

  // process one period of data
  bi = 0;
  for (unsigned int i = 0; i < d_period_size; i++){
    int t = (buf[bi] + buf[bi+1]) / 2;
    bi += 2;
    out[0][i] = (float) t * (1.0 / (float) ((1L << (NBITS-1)) - 1));
  }

  return d_period_size;
}

/*
 * Work function that deals with float to S32 conversion
 */
int
audio_alsa_source::work_s32 (int noutput_items,
			     gr_vector_const_void_star &input_items,
			     gr_vector_void_star &output_items)
{
  typedef gr_int32	sample_t;	// the type of samples we're creating
  static const int NBITS = 32;		// # of bits in a sample
  
  unsigned int nchan = output_items.size ();
  float **out = (float **) &output_items[0];
  sample_t *buf = (sample_t *) d_buffer;
  int bi;

  unsigned int sizeof_frame = d_hw_nchan * sizeof (sample_t);
  assert (d_buffer_size_bytes == d_period_size * sizeof_frame);

  // To minimize latency, return at most a single period's worth of samples.
  // [We could also read the first one in a blocking mode and subsequent
  //  ones in non-blocking mode, but we'll leave that for later (or never).]
  
  if (!read_buffer (buf, d_period_size, sizeof_frame))
    return -1;		// No fixing this problem.  Say we're done.

  // process one period of data
  bi = 0;
  for (unsigned int i = 0; i < d_period_size; i++){
    for (unsigned int chan = 0; chan < nchan; chan++){
      out[chan][i] = (float) buf[bi++] * (1.0 / (float) ((1L << (NBITS-1)) - 1));
    }
  }

  return d_period_size;
}

/*
 * Work function that deals with float to S32 conversion
 * and stereo to mono kludge...
 */
int
audio_alsa_source::work_s32_2x1 (int noutput_items,
				 gr_vector_const_void_star &input_items,
				 gr_vector_void_star &output_items)
{
  typedef gr_int32	sample_t;	// the type of samples we're creating
  static const int NBITS = 32;		// # of bits in a sample
  
  unsigned int nchan = output_items.size ();
  float **out = (float **) &output_items[0];
  sample_t *buf = (sample_t *) d_buffer;
  int bi;

  assert (nchan == 1);

  unsigned int sizeof_frame = d_hw_nchan * sizeof (sample_t);
  assert (d_buffer_size_bytes == d_period_size * sizeof_frame);

  // To minimize latency, return at most a single period's worth of samples.
  // [We could also read the first one in a blocking mode and subsequent
  //  ones in non-blocking mode, but we'll leave that for later (or never).]
  
  if (!read_buffer (buf, d_period_size, sizeof_frame))
    return -1;		// No fixing this problem.  Say we're done.

  // process one period of data
  bi = 0;
  for (unsigned int i = 0; i < d_period_size; i++){
    int t = (buf[bi] + buf[bi+1]) / 2;
    bi += 2;
    out[0][i] = (float) t * (1.0 / (float) ((1L << (NBITS-1)) - 1));
  }

  return d_period_size;
}

bool
audio_alsa_source::read_buffer (void *vbuffer, unsigned nframes, unsigned sizeof_frame)
{
  unsigned char *buffer = (unsigned char *) vbuffer;

  while (nframes > 0){
    int r = snd_pcm_readi (d_pcm_handle, buffer, nframes);
    if (r == -EAGAIN)
      continue;			// try again

    else if (r == -EPIPE){	// overrun
      d_noverruns++;
      fputs ("aO", stderr);
      if ((r = snd_pcm_prepare (d_pcm_handle)) < 0){
	output_error_msg ("snd_pcm_prepare failed. Can't recover from overrun", r);
	return false;
      }
      continue;			// try again
    }

    else if (r == -ESTRPIPE){	// h/w is suspended (whatever that means)
				// This is apparently related to power management
      d_nsuspends++;
      if ((r = snd_pcm_resume (d_pcm_handle)) < 0){
	output_error_msg ("failed to resume from suspend", r);
	return false;
      }
      continue;			// try again
    }

    else if (r < 0){
      output_error_msg ("snd_pcm_readi failed", r);
      return false;
    }

    nframes -= r;
    buffer += r * sizeof_frame;
  }

  return true;
}


void
audio_alsa_source::output_error_msg (const char *msg, int err)
{
  fprintf (stderr, "audio_alsa_source[%s]: %s: %s\n",
	   snd_pcm_name (d_pcm_handle), msg,  snd_strerror (err));
}

void
audio_alsa_source::bail (const char *msg, int err) throw (std::runtime_error)
{
  output_error_msg (msg, err);
  throw std::runtime_error ("audio_alsa_source");
}