/* * $Id: pa_linux_alsa.c 1822 2012-03-28 16:14:49Z dmitrykos $ * PortAudio Portable Real-Time Audio Library * Latest Version at: http://www.portaudio.com * ALSA implementation by Joshua Haberman and Arve Knudsen * * Copyright (c) 2002 Joshua Haberman * Copyright (c) 2005-2009 Arve Knudsen * Copyright (c) 2008 Kevin Kofler * Copyright (c) 2011 Dmitry Kostjuchenko * * Based on the Open Source API proposed by Ross Bencina * Copyright (c) 1999-2002 Ross Bencina, Phil Burk * * Permission is hereby granted, free of charge, to any person obtaining * a copy of this software and associated documentation files * (the "Software"), to deal in the Software without restriction, * including without limitation the rights to use, copy, modify, merge, * publish, distribute, sublicense, and/or sell copies of the Software, * and to permit persons to whom the Software is furnished to do so, * subject to the following conditions: * * The above copyright notice and this permission notice shall be * included in all copies or substantial portions of the Software. * * THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, * EXPRESS OR IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF * MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. * IN NO EVENT SHALL THE AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR * ANY CLAIM, DAMAGES OR OTHER LIABILITY, WHETHER IN AN ACTION OF * CONTRACT, TORT OR OTHERWISE, ARISING FROM, OUT OF OR IN CONNECTION * WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE SOFTWARE. */ /* * The text above constitutes the entire PortAudio license; however, * the PortAudio community also makes the following non-binding requests: * * Any person wishing to distribute modifications to the Software is * requested to send the modifications to the original developer so that * they can be incorporated into the canonical version. It is also * requested that these non-binding requests be included along with the * license above. */ /** @file @ingroup hostapi_src */ #define ALSA_PCM_NEW_HW_PARAMS_API #define ALSA_PCM_NEW_SW_PARAMS_API #include #undef ALSA_PCM_NEW_HW_PARAMS_API #undef ALSA_PCM_NEW_SW_PARAMS_API #include #include /* strlen() */ #include #include #include #include #include #include #include /* For sig_atomic_t */ #ifdef PA_ALSA_DYNAMIC #include /* For dlXXX functions */ #endif #include "portaudio.h" #include "pa_util.h" #include "pa_unix_util.h" #include "pa_allocation.h" #include "pa_hostapi.h" #include "pa_stream.h" #include "pa_cpuload.h" #include "pa_process.h" #include "pa_endianness.h" #include "pa_debugprint.h" #include "pa_linux_alsa.h" /* Add missing define (for compatibility with older ALSA versions). */ #ifndef SND_PCM_TSTAMP_ENABLE #define SND_PCM_TSTAMP_ENABLE SND_PCM_TSTAMP_MMAP #endif /* Combine version elements into a single (unsigned) integer */ #define ALSA_VERSION_INT(major, minor, subminor) ((major << 16) | (minor << 8) | subminor) /* Remove paNonInterleaved flag to get pure format value. */ #define PA_ALSA_TO_FORMAT(X) ((X) & ~(paNonInterleaved)) /* Defines Alsa function types and pointers to these functions. */ #define _PA_DEFINE_FUNC(x) typedef typeof(x) x##_ft; static x##_ft *alsa_##x = 0 /* Alloca helper. */ #define __alsa_snd_alloca(ptr,type) do { size_t __alsa_alloca_size = alsa_##type##_sizeof(); (*ptr) = (type##_t *) alloca(__alsa_alloca_size); memset(*ptr, 0, __alsa_alloca_size); } while (0) _PA_DEFINE_FUNC(snd_pcm_open); _PA_DEFINE_FUNC(snd_pcm_close); _PA_DEFINE_FUNC(snd_pcm_nonblock); _PA_DEFINE_FUNC(snd_pcm_frames_to_bytes); _PA_DEFINE_FUNC(snd_pcm_prepare); _PA_DEFINE_FUNC(snd_pcm_start); _PA_DEFINE_FUNC(snd_pcm_resume); _PA_DEFINE_FUNC(snd_pcm_wait); _PA_DEFINE_FUNC(snd_pcm_state); _PA_DEFINE_FUNC(snd_pcm_avail_update); _PA_DEFINE_FUNC(snd_pcm_areas_silence); _PA_DEFINE_FUNC(snd_pcm_mmap_begin); _PA_DEFINE_FUNC(snd_pcm_mmap_commit); _PA_DEFINE_FUNC(snd_pcm_readi); _PA_DEFINE_FUNC(snd_pcm_readn); _PA_DEFINE_FUNC(snd_pcm_writei); _PA_DEFINE_FUNC(snd_pcm_writen); _PA_DEFINE_FUNC(snd_pcm_drain); _PA_DEFINE_FUNC(snd_pcm_recover); _PA_DEFINE_FUNC(snd_pcm_drop); _PA_DEFINE_FUNC(snd_pcm_area_copy); _PA_DEFINE_FUNC(snd_pcm_poll_descriptors); _PA_DEFINE_FUNC(snd_pcm_poll_descriptors_count); _PA_DEFINE_FUNC(snd_pcm_poll_descriptors_revents); _PA_DEFINE_FUNC(snd_pcm_format_size); _PA_DEFINE_FUNC(snd_pcm_link); _PA_DEFINE_FUNC(snd_pcm_delay); _PA_DEFINE_FUNC(snd_pcm_hw_params_sizeof); _PA_DEFINE_FUNC(snd_pcm_hw_params_malloc); _PA_DEFINE_FUNC(snd_pcm_hw_params_free); _PA_DEFINE_FUNC(snd_pcm_hw_params_any); _PA_DEFINE_FUNC(snd_pcm_hw_params_set_access); _PA_DEFINE_FUNC(snd_pcm_hw_params_set_format); _PA_DEFINE_FUNC(snd_pcm_hw_params_set_channels); //_PA_DEFINE_FUNC(snd_pcm_hw_params_set_periods_near); _PA_DEFINE_FUNC(snd_pcm_hw_params_set_rate_near); //!!! _PA_DEFINE_FUNC(snd_pcm_hw_params_set_rate); _PA_DEFINE_FUNC(snd_pcm_hw_params_set_rate_resample); //_PA_DEFINE_FUNC(snd_pcm_hw_params_set_buffer_time_near); _PA_DEFINE_FUNC(snd_pcm_hw_params_set_buffer_size); _PA_DEFINE_FUNC(snd_pcm_hw_params_set_buffer_size_near); //!!! _PA_DEFINE_FUNC(snd_pcm_hw_params_set_buffer_size_min); //_PA_DEFINE_FUNC(snd_pcm_hw_params_set_period_time_near); _PA_DEFINE_FUNC(snd_pcm_hw_params_set_period_size_near); _PA_DEFINE_FUNC(snd_pcm_hw_params_set_periods_integer); _PA_DEFINE_FUNC(snd_pcm_hw_params_set_periods_min); _PA_DEFINE_FUNC(snd_pcm_hw_params_get_buffer_size); //_PA_DEFINE_FUNC(snd_pcm_hw_params_get_period_size); //_PA_DEFINE_FUNC(snd_pcm_hw_params_get_access); //_PA_DEFINE_FUNC(snd_pcm_hw_params_get_periods); //_PA_DEFINE_FUNC(snd_pcm_hw_params_get_rate); _PA_DEFINE_FUNC(snd_pcm_hw_params_get_channels_min); _PA_DEFINE_FUNC(snd_pcm_hw_params_get_channels_max); _PA_DEFINE_FUNC(snd_pcm_hw_params_test_period_size); _PA_DEFINE_FUNC(snd_pcm_hw_params_test_format); _PA_DEFINE_FUNC(snd_pcm_hw_params_test_access); _PA_DEFINE_FUNC(snd_pcm_hw_params_dump); _PA_DEFINE_FUNC(snd_pcm_hw_params); _PA_DEFINE_FUNC(snd_pcm_hw_params_get_periods_min); _PA_DEFINE_FUNC(snd_pcm_hw_params_get_periods_max); _PA_DEFINE_FUNC(snd_pcm_hw_params_set_period_size); _PA_DEFINE_FUNC(snd_pcm_hw_params_get_period_size_min); _PA_DEFINE_FUNC(snd_pcm_hw_params_get_period_size_max); _PA_DEFINE_FUNC(snd_pcm_hw_params_get_buffer_size_max); _PA_DEFINE_FUNC(snd_pcm_hw_params_get_rate_min); _PA_DEFINE_FUNC(snd_pcm_hw_params_get_rate_max); _PA_DEFINE_FUNC(snd_pcm_hw_params_get_rate_numden); #define alsa_snd_pcm_hw_params_alloca(ptr) __alsa_snd_alloca(ptr, snd_pcm_hw_params) _PA_DEFINE_FUNC(snd_pcm_sw_params_sizeof); _PA_DEFINE_FUNC(snd_pcm_sw_params_malloc); _PA_DEFINE_FUNC(snd_pcm_sw_params_current); _PA_DEFINE_FUNC(snd_pcm_sw_params_set_avail_min); _PA_DEFINE_FUNC(snd_pcm_sw_params); _PA_DEFINE_FUNC(snd_pcm_sw_params_free); _PA_DEFINE_FUNC(snd_pcm_sw_params_set_start_threshold); _PA_DEFINE_FUNC(snd_pcm_sw_params_set_stop_threshold); _PA_DEFINE_FUNC(snd_pcm_sw_params_get_boundary); _PA_DEFINE_FUNC(snd_pcm_sw_params_set_silence_threshold); _PA_DEFINE_FUNC(snd_pcm_sw_params_set_silence_size); _PA_DEFINE_FUNC(snd_pcm_sw_params_set_xfer_align); _PA_DEFINE_FUNC(snd_pcm_sw_params_set_tstamp_mode); #define alsa_snd_pcm_sw_params_alloca(ptr) __alsa_snd_alloca(ptr, snd_pcm_sw_params) _PA_DEFINE_FUNC(snd_pcm_info); _PA_DEFINE_FUNC(snd_pcm_info_sizeof); _PA_DEFINE_FUNC(snd_pcm_info_malloc); _PA_DEFINE_FUNC(snd_pcm_info_free); _PA_DEFINE_FUNC(snd_pcm_info_set_device); _PA_DEFINE_FUNC(snd_pcm_info_set_subdevice); _PA_DEFINE_FUNC(snd_pcm_info_set_stream); _PA_DEFINE_FUNC(snd_pcm_info_get_name); _PA_DEFINE_FUNC(snd_pcm_info_get_card); _PA_DEFINE_FUNC(snd_pcm_info_get_subdevices_count); _PA_DEFINE_FUNC(snd_pcm_info_get_subdevice_name); _PA_DEFINE_FUNC(snd_pcm_info_get_subdevices_avail); #define alsa_snd_pcm_info_alloca(ptr) __alsa_snd_alloca(ptr, snd_pcm_info) _PA_DEFINE_FUNC(snd_ctl_pcm_next_device); _PA_DEFINE_FUNC(snd_ctl_pcm_info); _PA_DEFINE_FUNC(snd_ctl_open); _PA_DEFINE_FUNC(snd_ctl_close); _PA_DEFINE_FUNC(snd_ctl_card_info_malloc); _PA_DEFINE_FUNC(snd_ctl_card_info_free); _PA_DEFINE_FUNC(snd_ctl_card_info); _PA_DEFINE_FUNC(snd_ctl_card_info_sizeof); _PA_DEFINE_FUNC(snd_ctl_card_info_get_name); #define alsa_snd_ctl_card_info_alloca(ptr) __alsa_snd_alloca(ptr, snd_ctl_card_info) _PA_DEFINE_FUNC(snd_config); _PA_DEFINE_FUNC(snd_config_update); _PA_DEFINE_FUNC(snd_config_search); _PA_DEFINE_FUNC(snd_config_iterator_entry); _PA_DEFINE_FUNC(snd_config_iterator_first); _PA_DEFINE_FUNC(snd_config_iterator_end); _PA_DEFINE_FUNC(snd_config_iterator_next); _PA_DEFINE_FUNC(snd_config_get_string); _PA_DEFINE_FUNC(snd_config_get_id); _PA_DEFINE_FUNC(snd_config_update_free_global); _PA_DEFINE_FUNC(snd_pcm_status); _PA_DEFINE_FUNC(snd_pcm_status_sizeof); _PA_DEFINE_FUNC(snd_pcm_status_get_tstamp); _PA_DEFINE_FUNC(snd_pcm_status_get_state); _PA_DEFINE_FUNC(snd_pcm_status_get_trigger_tstamp); _PA_DEFINE_FUNC(snd_pcm_status_get_delay); #define alsa_snd_pcm_status_alloca(ptr) __alsa_snd_alloca(ptr, snd_pcm_status) _PA_DEFINE_FUNC(snd_card_next); _PA_DEFINE_FUNC(snd_asoundlib_version); _PA_DEFINE_FUNC(snd_strerror); _PA_DEFINE_FUNC(snd_output_stdio_attach); #define alsa_snd_config_for_each(pos, next, node)\ for (pos = alsa_snd_config_iterator_first(node),\ next = alsa_snd_config_iterator_next(pos);\ pos != alsa_snd_config_iterator_end(node); pos = next, next = alsa_snd_config_iterator_next(pos)) #undef _PA_DEFINE_FUNC /* Redefine 'PA_ALSA_PATHNAME' to a different Alsa library name if desired. */ #ifndef PA_ALSA_PATHNAME #define PA_ALSA_PATHNAME "libasound.so" #endif static const char *g_AlsaLibName = PA_ALSA_PATHNAME; /* Handle to dynamically loaded library. */ static void *g_AlsaLib = NULL; #ifdef PA_ALSA_DYNAMIC #define _PA_LOCAL_IMPL(x) __pa_local_##x int _PA_LOCAL_IMPL(snd_pcm_hw_params_set_rate_near) (snd_pcm_t *pcm, snd_pcm_hw_params_t *params, unsigned int *val, int *dir) { int ret; if ((ret = alsa_snd_pcm_hw_params_set_rate(pcm, params, (*val), (*dir))) < 0) return ret; return 0; } int _PA_LOCAL_IMPL(snd_pcm_hw_params_set_buffer_size_near) (snd_pcm_t *pcm, snd_pcm_hw_params_t *params, snd_pcm_uframes_t *val) { int ret; if ((ret = alsa_snd_pcm_hw_params_set_buffer_size(pcm, params, (*val))) < 0) return ret; return 0; } int _PA_LOCAL_IMPL(snd_pcm_hw_params_set_period_size_near) (snd_pcm_t *pcm, snd_pcm_hw_params_t *params, snd_pcm_uframes_t *val, int *dir) { int ret; if ((ret = alsa_snd_pcm_hw_params_set_period_size(pcm, params, (*val), (*dir))) < 0) return ret; return 0; } int _PA_LOCAL_IMPL(snd_pcm_hw_params_get_channels_min) (const snd_pcm_hw_params_t *params, unsigned int *val) { (*val) = 1; return 0; } int _PA_LOCAL_IMPL(snd_pcm_hw_params_get_channels_max) (const snd_pcm_hw_params_t *params, unsigned int *val) { (*val) = 2; return 0; } int _PA_LOCAL_IMPL(snd_pcm_hw_params_get_periods_min) (const snd_pcm_hw_params_t *params, unsigned int *val, int *dir) { (*val) = 2; return 0; } int _PA_LOCAL_IMPL(snd_pcm_hw_params_get_periods_max) (const snd_pcm_hw_params_t *params, unsigned int *val, int *dir) { (*val) = 8; return 0; } int _PA_LOCAL_IMPL(snd_pcm_hw_params_get_period_size_min) (const snd_pcm_hw_params_t *params, snd_pcm_uframes_t *frames, int *dir) { (*frames) = 64; return 0; } int _PA_LOCAL_IMPL(snd_pcm_hw_params_get_period_size_max) (const snd_pcm_hw_params_t *params, snd_pcm_uframes_t *frames, int *dir) { (*frames) = 512; return 0; } int _PA_LOCAL_IMPL(snd_pcm_hw_params_get_buffer_size_max) (const snd_pcm_hw_params_t *params, snd_pcm_uframes_t *val) { int ret; int dir = 0; snd_pcm_uframes_t pmax = 0; unsigned int pcnt = 0; if ((ret = _PA_LOCAL_IMPL(snd_pcm_hw_params_get_period_size_max)(params, &pmax, &dir)) < 0) return ret; if ((ret = _PA_LOCAL_IMPL(snd_pcm_hw_params_get_periods_max)(params, &pcnt, &dir)) < 0) return ret; (*val) = pmax * pcnt; return 0; } int _PA_LOCAL_IMPL(snd_pcm_hw_params_get_rate_min) (const snd_pcm_hw_params_t *params, unsigned int *val, int *dir) { (*val) = 44100; return 0; } int _PA_LOCAL_IMPL(snd_pcm_hw_params_get_rate_max) (const snd_pcm_hw_params_t *params, unsigned int *val, int *dir) { (*val) = 44100; return 0; } #endif // PA_ALSA_DYNAMIC /* Trying to load Alsa library dynamically if 'PA_ALSA_DYNAMIC' is defined, othervise will link during compilation. */ static int PaAlsa_LoadLibrary() { #ifdef PA_ALSA_DYNAMIC PA_DEBUG(( "%s: loading ALSA library file - %s\n", __FUNCTION__, g_AlsaLibName )); dlerror(); g_AlsaLib = dlopen(g_AlsaLibName, (RTLD_NOW|RTLD_GLOBAL)); if (g_AlsaLib == NULL) { PA_DEBUG(( "%s: failed dlopen() ALSA library file - %s, error: %s\n", __FUNCTION__, g_AlsaLibName, dlerror() )); return 0; } PA_DEBUG(( "%s: loading ALSA API\n", __FUNCTION__ )); #define _PA_LOAD_FUNC(x) do { \ alsa_##x = dlsym(g_AlsaLib, #x); \ if (alsa_##x == NULL) { \ PA_DEBUG(( "%s: symbol [%s] not found in - %s, error: %s\n", __FUNCTION__, #x, g_AlsaLibName, dlerror() )); }\ } while(0) #else #define _PA_LOAD_FUNC(x) alsa_##x = &x #endif _PA_LOAD_FUNC(snd_pcm_open); _PA_LOAD_FUNC(snd_pcm_close); _PA_LOAD_FUNC(snd_pcm_nonblock); _PA_LOAD_FUNC(snd_pcm_frames_to_bytes); _PA_LOAD_FUNC(snd_pcm_prepare); _PA_LOAD_FUNC(snd_pcm_start); _PA_LOAD_FUNC(snd_pcm_resume); _PA_LOAD_FUNC(snd_pcm_wait); _PA_LOAD_FUNC(snd_pcm_state); _PA_LOAD_FUNC(snd_pcm_avail_update); _PA_LOAD_FUNC(snd_pcm_areas_silence); _PA_LOAD_FUNC(snd_pcm_mmap_begin); _PA_LOAD_FUNC(snd_pcm_mmap_commit); _PA_LOAD_FUNC(snd_pcm_readi); _PA_LOAD_FUNC(snd_pcm_readn); _PA_LOAD_FUNC(snd_pcm_writei); _PA_LOAD_FUNC(snd_pcm_writen); _PA_LOAD_FUNC(snd_pcm_drain); _PA_LOAD_FUNC(snd_pcm_recover); _PA_LOAD_FUNC(snd_pcm_drop); _PA_LOAD_FUNC(snd_pcm_area_copy); _PA_LOAD_FUNC(snd_pcm_poll_descriptors); _PA_LOAD_FUNC(snd_pcm_poll_descriptors_count); _PA_LOAD_FUNC(snd_pcm_poll_descriptors_revents); _PA_LOAD_FUNC(snd_pcm_format_size); _PA_LOAD_FUNC(snd_pcm_link); _PA_LOAD_FUNC(snd_pcm_delay); _PA_LOAD_FUNC(snd_pcm_hw_params_sizeof); _PA_LOAD_FUNC(snd_pcm_hw_params_malloc); _PA_LOAD_FUNC(snd_pcm_hw_params_free); _PA_LOAD_FUNC(snd_pcm_hw_params_any); _PA_LOAD_FUNC(snd_pcm_hw_params_set_access); _PA_LOAD_FUNC(snd_pcm_hw_params_set_format); _PA_LOAD_FUNC(snd_pcm_hw_params_set_channels); //_PA_LOAD_FUNC(snd_pcm_hw_params_set_periods_near); _PA_LOAD_FUNC(snd_pcm_hw_params_set_rate_near); _PA_LOAD_FUNC(snd_pcm_hw_params_set_rate); _PA_LOAD_FUNC(snd_pcm_hw_params_set_rate_resample); //_PA_LOAD_FUNC(snd_pcm_hw_params_set_buffer_time_near); _PA_LOAD_FUNC(snd_pcm_hw_params_set_buffer_size); _PA_LOAD_FUNC(snd_pcm_hw_params_set_buffer_size_near); _PA_LOAD_FUNC(snd_pcm_hw_params_set_buffer_size_min); //_PA_LOAD_FUNC(snd_pcm_hw_params_set_period_time_near); _PA_LOAD_FUNC(snd_pcm_hw_params_set_period_size_near); _PA_LOAD_FUNC(snd_pcm_hw_params_set_periods_integer); _PA_LOAD_FUNC(snd_pcm_hw_params_set_periods_min); _PA_LOAD_FUNC(snd_pcm_hw_params_get_buffer_size); //_PA_LOAD_FUNC(snd_pcm_hw_params_get_period_size); //_PA_LOAD_FUNC(snd_pcm_hw_params_get_access); //_PA_LOAD_FUNC(snd_pcm_hw_params_get_periods); //_PA_LOAD_FUNC(snd_pcm_hw_params_get_rate); _PA_LOAD_FUNC(snd_pcm_hw_params_get_channels_min); _PA_LOAD_FUNC(snd_pcm_hw_params_get_channels_max); _PA_LOAD_FUNC(snd_pcm_hw_params_test_period_size); _PA_LOAD_FUNC(snd_pcm_hw_params_test_format); _PA_LOAD_FUNC(snd_pcm_hw_params_test_access); _PA_LOAD_FUNC(snd_pcm_hw_params_dump); _PA_LOAD_FUNC(snd_pcm_hw_params); _PA_LOAD_FUNC(snd_pcm_hw_params_get_periods_min); _PA_LOAD_FUNC(snd_pcm_hw_params_get_periods_max); _PA_LOAD_FUNC(snd_pcm_hw_params_set_period_size); _PA_LOAD_FUNC(snd_pcm_hw_params_get_period_size_min); _PA_LOAD_FUNC(snd_pcm_hw_params_get_period_size_max); _PA_LOAD_FUNC(snd_pcm_hw_params_get_buffer_size_max); _PA_LOAD_FUNC(snd_pcm_hw_params_get_rate_min); _PA_LOAD_FUNC(snd_pcm_hw_params_get_rate_max); _PA_LOAD_FUNC(snd_pcm_hw_params_get_rate_numden); _PA_LOAD_FUNC(snd_pcm_sw_params_sizeof); _PA_LOAD_FUNC(snd_pcm_sw_params_malloc); _PA_LOAD_FUNC(snd_pcm_sw_params_current); _PA_LOAD_FUNC(snd_pcm_sw_params_set_avail_min); _PA_LOAD_FUNC(snd_pcm_sw_params); _PA_LOAD_FUNC(snd_pcm_sw_params_free); _PA_LOAD_FUNC(snd_pcm_sw_params_set_start_threshold); _PA_LOAD_FUNC(snd_pcm_sw_params_set_stop_threshold); _PA_LOAD_FUNC(snd_pcm_sw_params_get_boundary); _PA_LOAD_FUNC(snd_pcm_sw_params_set_silence_threshold); _PA_LOAD_FUNC(snd_pcm_sw_params_set_silence_size); _PA_LOAD_FUNC(snd_pcm_sw_params_set_xfer_align); _PA_LOAD_FUNC(snd_pcm_sw_params_set_tstamp_mode); _PA_LOAD_FUNC(snd_pcm_info); _PA_LOAD_FUNC(snd_pcm_info_sizeof); _PA_LOAD_FUNC(snd_pcm_info_malloc); _PA_LOAD_FUNC(snd_pcm_info_free); _PA_LOAD_FUNC(snd_pcm_info_set_device); _PA_LOAD_FUNC(snd_pcm_info_set_subdevice); _PA_LOAD_FUNC(snd_pcm_info_set_stream); _PA_LOAD_FUNC(snd_pcm_info_get_name); _PA_LOAD_FUNC(snd_pcm_info_get_card); _PA_LOAD_FUNC(snd_pcm_info_get_subdevices_count); _PA_LOAD_FUNC(snd_pcm_info_get_subdevice_name); _PA_LOAD_FUNC(snd_pcm_info_get_subdevices_avail); _PA_LOAD_FUNC(snd_ctl_pcm_next_device); _PA_LOAD_FUNC(snd_ctl_pcm_info); _PA_LOAD_FUNC(snd_ctl_open); _PA_LOAD_FUNC(snd_ctl_close); _PA_LOAD_FUNC(snd_ctl_card_info_malloc); _PA_LOAD_FUNC(snd_ctl_card_info_free); _PA_LOAD_FUNC(snd_ctl_card_info); _PA_LOAD_FUNC(snd_ctl_card_info_sizeof); _PA_LOAD_FUNC(snd_ctl_card_info_get_name); _PA_LOAD_FUNC(snd_config); _PA_LOAD_FUNC(snd_config_update); _PA_LOAD_FUNC(snd_config_search); _PA_LOAD_FUNC(snd_config_iterator_entry); _PA_LOAD_FUNC(snd_config_iterator_first); _PA_LOAD_FUNC(snd_config_iterator_end); _PA_LOAD_FUNC(snd_config_iterator_next); _PA_LOAD_FUNC(snd_config_get_string); _PA_LOAD_FUNC(snd_config_get_id); _PA_LOAD_FUNC(snd_config_update_free_global); _PA_LOAD_FUNC(snd_pcm_status); _PA_LOAD_FUNC(snd_pcm_status_sizeof); _PA_LOAD_FUNC(snd_pcm_status_get_tstamp); _PA_LOAD_FUNC(snd_pcm_status_get_state); _PA_LOAD_FUNC(snd_pcm_status_get_trigger_tstamp); _PA_LOAD_FUNC(snd_pcm_status_get_delay); _PA_LOAD_FUNC(snd_card_next); _PA_LOAD_FUNC(snd_asoundlib_version); _PA_LOAD_FUNC(snd_strerror); _PA_LOAD_FUNC(snd_output_stdio_attach); #undef _PA_LOAD_FUNC #ifdef PA_ALSA_DYNAMIC PA_DEBUG(( "%s: loaded ALSA API - ok\n", __FUNCTION__ )); #define _PA_VALIDATE_LOAD_REPLACEMENT(x)\ do {\ if (alsa_##x == NULL)\ {\ alsa_##x = &_PA_LOCAL_IMPL(x);\ PA_DEBUG(( "%s: replacing [%s] with local implementation\n", __FUNCTION__, #x ));\ }\ } while (0) _PA_VALIDATE_LOAD_REPLACEMENT(snd_pcm_hw_params_set_rate_near); _PA_VALIDATE_LOAD_REPLACEMENT(snd_pcm_hw_params_set_buffer_size_near); _PA_VALIDATE_LOAD_REPLACEMENT(snd_pcm_hw_params_set_period_size_near); _PA_VALIDATE_LOAD_REPLACEMENT(snd_pcm_hw_params_get_channels_min); _PA_VALIDATE_LOAD_REPLACEMENT(snd_pcm_hw_params_get_channels_max); _PA_VALIDATE_LOAD_REPLACEMENT(snd_pcm_hw_params_get_periods_min); _PA_VALIDATE_LOAD_REPLACEMENT(snd_pcm_hw_params_get_periods_max); _PA_VALIDATE_LOAD_REPLACEMENT(snd_pcm_hw_params_get_period_size_min); _PA_VALIDATE_LOAD_REPLACEMENT(snd_pcm_hw_params_get_period_size_max); _PA_VALIDATE_LOAD_REPLACEMENT(snd_pcm_hw_params_get_buffer_size_max); _PA_VALIDATE_LOAD_REPLACEMENT(snd_pcm_hw_params_get_rate_min); _PA_VALIDATE_LOAD_REPLACEMENT(snd_pcm_hw_params_get_rate_max); #undef _PA_LOCAL_IMPL #undef _PA_VALIDATE_LOAD_REPLACEMENT #endif // PA_ALSA_DYNAMIC return 1; } void PaAlsa_SetLibraryPathName( const char *pathName ) { #ifdef PA_ALSA_DYNAMIC g_AlsaLibName = pathName; #else (void)pathName; #endif } /* Close handle to Alsa library. */ static void PaAlsa_CloseLibrary() { #ifdef PA_ALSA_DYNAMIC dlclose(g_AlsaLib); g_AlsaLib = NULL; #endif } /* Check return value of ALSA function, and map it to PaError */ #define ENSURE_(expr, code) \ do { \ int __pa_unsure_error_id;\ if( UNLIKELY( (__pa_unsure_error_id = (expr)) < 0 ) ) \ { \ /* PaUtil_SetLastHostErrorInfo should only be used in the main thread */ \ if( (code) == paUnanticipatedHostError && pthread_equal( pthread_self(), paUnixMainThread) ) \ { \ PaUtil_SetLastHostErrorInfo( paALSA, __pa_unsure_error_id, alsa_snd_strerror( __pa_unsure_error_id ) ); \ } \ PaUtil_DebugPrint( "Expression '" #expr "' failed in '" __FILE__ "', line: " STRINGIZE( __LINE__ ) "\n" ); \ if( (code) == paUnanticipatedHostError ) \ PA_DEBUG(( "Host error description: %s\n", alsa_snd_strerror( __pa_unsure_error_id ) )); \ result = (code); \ goto error; \ } \ } while (0) #define ASSERT_CALL_(expr, success) \ do {\ int __pa_assert_error_id;\ __pa_assert_error_id = (expr);\ assert( success == __pa_assert_error_id );\ } while (0) static int numPeriods_ = 4; static int busyRetries_ = 100; int PaAlsa_SetNumPeriods( int numPeriods ) { numPeriods_ = numPeriods; return paNoError; } typedef enum { StreamDirection_In, StreamDirection_Out } StreamDirection; typedef struct { PaSampleFormat hostSampleFormat; unsigned long framesPerBuffer; int numUserChannels, numHostChannels; int userInterleaved, hostInterleaved; int canMmap; void *nonMmapBuffer; unsigned int nonMmapBufferSize; PaDeviceIndex device; /* Keep the device index */ int deviceIsPlug; /* Distinguish plug types from direct 'hw:' devices */ int useReventFix; /* Alsa older than 1.0.16, plug devices need a fix */ int useByteSwapConverter; /* Some devices have BE only format supported */ snd_pcm_t *pcm; snd_pcm_uframes_t bufferSize; snd_pcm_format_t nativeFormat; unsigned int nfds; int ready; /* Marked ready from poll */ void **userBuffers; snd_pcm_uframes_t offset; StreamDirection streamDir; snd_pcm_channel_area_t *channelAreas; /* Needed for channel adaption */ } PaAlsaStreamComponent; /* Implementation specific stream structure */ typedef struct PaAlsaStream { PaUtilStreamRepresentation streamRepresentation; PaUtilCpuLoadMeasurer cpuLoadMeasurer; PaUtilBufferProcessor bufferProcessor; PaUnixThread thread; unsigned long framesPerUserBuffer, maxFramesPerHostBuffer; int primeBuffers; int callbackMode; /* bool: are we running in callback mode? */ int pcmsSynced; /* Have we successfully synced pcms */ int rtSched; /* the callback thread uses these to poll the sound device(s), waiting * for data to be ready/available */ struct pollfd* pfds; int pollTimeout; /* Used in communication between threads */ volatile sig_atomic_t callback_finished; /* bool: are we in the "callback finished" state? */ volatile sig_atomic_t callbackAbort; /* Drop frames? */ volatile sig_atomic_t isActive; /* Is stream in active state? (Between StartStream and StopStream || !paContinue) */ PaUnixMutex stateMtx; /* Used to synchronize access to stream state */ int neverDropInput; PaTime underrun; PaTime overrun; PaAlsaStreamComponent capture, playback; } PaAlsaStream; /* PaAlsaHostApiRepresentation - host api datastructure specific to this implementation */ typedef struct PaAlsaHostApiRepresentation { PaUtilHostApiRepresentation baseHostApiRep; PaUtilStreamInterface callbackStreamInterface; PaUtilStreamInterface blockingStreamInterface; PaUtilAllocationGroup *allocations; PaHostApiIndex hostApiIndex; PaUint32 alsaLibVersion; /* Retrieved from the library at run-time */ } PaAlsaHostApiRepresentation; typedef struct PaAlsaDeviceInfo { PaDeviceInfo baseDeviceInfo; char *alsaName; int isPlug; int minInputChannels; int minOutputChannels; } PaAlsaDeviceInfo; /* prototypes for functions declared in this file */ static void Terminate( struct PaUtilHostApiRepresentation *hostApi ); static PaError IsFormatSupported( struct PaUtilHostApiRepresentation *hostApi, const PaStreamParameters *inputParameters, const PaStreamParameters *outputParameters, double sampleRate ); static PaError OpenStream( struct PaUtilHostApiRepresentation *hostApi, PaStream** s, const PaStreamParameters *inputParameters, const PaStreamParameters *outputParameters, double sampleRate, unsigned long framesPerBuffer, PaStreamFlags streamFlags, PaStreamCallback *callback, void *userData ); static PaError CloseStream( PaStream* stream ); static PaError StartStream( PaStream *stream ); static PaError StopStream( PaStream *stream ); static PaError AbortStream( PaStream *stream ); static PaError IsStreamStopped( PaStream *s ); static PaError IsStreamActive( PaStream *stream ); static PaTime GetStreamTime( PaStream *stream ); static double GetStreamCpuLoad( PaStream* stream ); static PaError BuildDeviceList( PaAlsaHostApiRepresentation *hostApi ); static int SetApproximateSampleRate( snd_pcm_t *pcm, snd_pcm_hw_params_t *hwParams, double sampleRate ); static int GetExactSampleRate( snd_pcm_hw_params_t *hwParams, double *sampleRate ); static PaUint32 PaAlsaVersionNum(void); /* Callback prototypes */ static void *CallbackThreadFunc( void *userData ); /* Blocking prototypes */ static signed long GetStreamReadAvailable( PaStream* s ); static signed long GetStreamWriteAvailable( PaStream* s ); static PaError ReadStream( PaStream* stream, void *buffer, unsigned long frames ); static PaError WriteStream( PaStream* stream, const void *buffer, unsigned long frames ); static const PaAlsaDeviceInfo *GetDeviceInfo( const PaUtilHostApiRepresentation *hostApi, int device ) { return (const PaAlsaDeviceInfo *)hostApi->deviceInfos[device]; } /* Replaces standard PortAudio converter with Alsa internal byte-swapping implementation */ static void CheckAndReplaceConverterForSwapping( PaAlsaStream *stream ); /** Uncommented because AlsaErrorHandler is unused for anything good yet. If AlsaErrorHandler is to be used, do not forget to register this callback in PaAlsa_Initialize, and unregister in Terminate. */ /*static void AlsaErrorHandler(const char *file, int line, const char *function, int err, const char *fmt, ...) { }*/ PaError PaAlsa_Initialize( PaUtilHostApiRepresentation **hostApi, PaHostApiIndex hostApiIndex ) { PaError result = paNoError; PaAlsaHostApiRepresentation *alsaHostApi = NULL; /* Try loading Alsa library. */ if (!PaAlsa_LoadLibrary()) return paHostApiNotFound; PA_UNLESS( alsaHostApi = (PaAlsaHostApiRepresentation*) PaUtil_AllocateMemory( sizeof(PaAlsaHostApiRepresentation) ), paInsufficientMemory ); PA_UNLESS( alsaHostApi->allocations = PaUtil_CreateAllocationGroup(), paInsufficientMemory ); alsaHostApi->hostApiIndex = hostApiIndex; alsaHostApi->alsaLibVersion = PaAlsaVersionNum(); *hostApi = (PaUtilHostApiRepresentation*)alsaHostApi; (*hostApi)->info.structVersion = 1; (*hostApi)->info.type = paALSA; (*hostApi)->info.name = "ALSA"; (*hostApi)->Terminate = Terminate; (*hostApi)->OpenStream = OpenStream; (*hostApi)->IsFormatSupported = IsFormatSupported; /** If AlsaErrorHandler is to be used, do not forget to unregister callback pointer in Terminate function. */ /*ENSURE_( snd_lib_error_set_handler(AlsaErrorHandler), paUnanticipatedHostError );*/ PA_ENSURE( BuildDeviceList( alsaHostApi ) ); PaUtil_InitializeStreamInterface( &alsaHostApi->callbackStreamInterface, CloseStream, StartStream, StopStream, AbortStream, IsStreamStopped, IsStreamActive, GetStreamTime, GetStreamCpuLoad, PaUtil_DummyRead, PaUtil_DummyWrite, PaUtil_DummyGetReadAvailable, PaUtil_DummyGetWriteAvailable ); PaUtil_InitializeStreamInterface( &alsaHostApi->blockingStreamInterface, CloseStream, StartStream, StopStream, AbortStream, IsStreamStopped, IsStreamActive, GetStreamTime, PaUtil_DummyGetCpuLoad, ReadStream, WriteStream, GetStreamReadAvailable, GetStreamWriteAvailable ); PA_ENSURE( PaUnixThreading_Initialize() ); return result; error: if( alsaHostApi ) { if( alsaHostApi->allocations ) { PaUtil_FreeAllAllocations( alsaHostApi->allocations ); PaUtil_DestroyAllocationGroup( alsaHostApi->allocations ); } PaUtil_FreeMemory( alsaHostApi ); } return result; } static void Terminate( struct PaUtilHostApiRepresentation *hostApi ) { PaAlsaHostApiRepresentation *alsaHostApi = (PaAlsaHostApiRepresentation*)hostApi; assert( hostApi ); /** See AlsaErrorHandler and PaAlsa_Initialize for details. */ /*snd_lib_error_set_handler(NULL);*/ if( alsaHostApi->allocations ) { PaUtil_FreeAllAllocations( alsaHostApi->allocations ); PaUtil_DestroyAllocationGroup( alsaHostApi->allocations ); } PaUtil_FreeMemory( alsaHostApi ); alsa_snd_config_update_free_global(); /* Close Alsa library. */ PaAlsa_CloseLibrary(); } /** Determine max channels and default latencies. * * This function provides functionality to grope an opened (might be opened for capture or playback) pcm device for * traits like max channels, suitable default latencies and default sample rate. Upon error, max channels is set to zero, * and a suitable result returned. The device is closed before returning. */ static PaError GropeDevice( snd_pcm_t* pcm, int isPlug, StreamDirection mode, int openBlocking, PaAlsaDeviceInfo* devInfo ) { PaError result = paNoError; snd_pcm_hw_params_t *hwParams; snd_pcm_uframes_t lowLatency = 512, highLatency = 2048; unsigned int minChans, maxChans; int* minChannels, * maxChannels; double * defaultLowLatency, * defaultHighLatency, * defaultSampleRate = &devInfo->baseDeviceInfo.defaultSampleRate; double defaultSr = *defaultSampleRate; assert( pcm ); PA_DEBUG(( "%s: collecting info ..\n", __FUNCTION__ )); if( StreamDirection_In == mode ) { minChannels = &devInfo->minInputChannels; maxChannels = &devInfo->baseDeviceInfo.maxInputChannels; defaultLowLatency = &devInfo->baseDeviceInfo.defaultLowInputLatency; defaultHighLatency = &devInfo->baseDeviceInfo.defaultHighInputLatency; } else { minChannels = &devInfo->minOutputChannels; maxChannels = &devInfo->baseDeviceInfo.maxOutputChannels; defaultLowLatency = &devInfo->baseDeviceInfo.defaultLowOutputLatency; defaultHighLatency = &devInfo->baseDeviceInfo.defaultHighOutputLatency; } ENSURE_( alsa_snd_pcm_nonblock( pcm, 0 ), paUnanticipatedHostError ); alsa_snd_pcm_hw_params_alloca( &hwParams ); alsa_snd_pcm_hw_params_any( pcm, hwParams ); if( defaultSr >= 0 ) { /* Could be that the device opened in one mode supports samplerates that the other mode wont have, * so try again .. */ if( SetApproximateSampleRate( pcm, hwParams, defaultSr ) < 0 ) { defaultSr = -1.; PA_DEBUG(( "%s: Original default samplerate failed, trying again ..\n", __FUNCTION__ )); } } if( defaultSr < 0. ) /* Default sample rate not set */ { unsigned int sampleRate = 44100; /* Will contain approximate rate returned by alsa-lib */ if( alsa_snd_pcm_hw_params_set_rate_near( pcm, hwParams, &sampleRate, NULL ) < 0) { result = paUnanticipatedHostError; goto error; } ENSURE_( GetExactSampleRate( hwParams, &defaultSr ), paUnanticipatedHostError ); } ENSURE_( alsa_snd_pcm_hw_params_get_channels_min( hwParams, &minChans ), paUnanticipatedHostError ); ENSURE_( alsa_snd_pcm_hw_params_get_channels_max( hwParams, &maxChans ), paUnanticipatedHostError ); assert( maxChans <= INT_MAX ); assert( maxChans > 0 ); /* Weird linking issue could cause wrong version of ALSA symbols to be called, resulting in zeroed values */ /* XXX: Limit to sensible number (ALSA plugins accept a crazy amount of channels)? */ if( isPlug && maxChans > 128 ) { maxChans = 128; PA_DEBUG(( "%s: Limiting number of plugin channels to %u\n", __FUNCTION__, maxChans )); } /* TWEAKME: * * Giving values for default min and max latency is not * straightforward. Here are our objectives: * * * for low latency, we want to give the lowest value * that will work reliably. This varies based on the * sound card, kernel, CPU, etc. I think it is better * to give sub-optimal latency than to give a number * too low and cause dropouts. My conservative * estimate at this point is to base it on 4096-sample * latency at 44.1 kHz, which gives a latency of 23ms. * * for high latency we want to give a large enough * value that dropouts are basically impossible. This * doesn't really require as much tweaking, since * providing too large a number will just cause us to * select the nearest setting that will work at stream * config time. */ ENSURE_( alsa_snd_pcm_hw_params_set_buffer_size_near( pcm, hwParams, &lowLatency ), paUnanticipatedHostError ); /* Have to reset hwParams, to set new buffer size */ ENSURE_( alsa_snd_pcm_hw_params_any( pcm, hwParams ), paUnanticipatedHostError ); ENSURE_( alsa_snd_pcm_hw_params_set_buffer_size_near( pcm, hwParams, &highLatency ), paUnanticipatedHostError ); *minChannels = (int)minChans; *maxChannels = (int)maxChans; *defaultSampleRate = defaultSr; *defaultLowLatency = (double) lowLatency / *defaultSampleRate; *defaultHighLatency = (double) highLatency / *defaultSampleRate; end: alsa_snd_pcm_close( pcm ); return result; error: goto end; } /* Initialize device info with invalid values (maxInputChannels and maxOutputChannels are set to zero since these indicate * wether input/output is available) */ static void InitializeDeviceInfo( PaDeviceInfo *deviceInfo ) { deviceInfo->structVersion = -1; deviceInfo->name = NULL; deviceInfo->hostApi = -1; deviceInfo->maxInputChannels = 0; deviceInfo->maxOutputChannels = 0; deviceInfo->defaultLowInputLatency = -1.; deviceInfo->defaultLowOutputLatency = -1.; deviceInfo->defaultHighInputLatency = -1.; deviceInfo->defaultHighOutputLatency = -1.; deviceInfo->defaultSampleRate = -1.; } /* Retrieve the version of the runtime Alsa-lib, as a single number equivalent to * SND_LIB_VERSION. Only a version string is available ("a.b.c") so this has to be converted. * Assume 'a' and 'b' are single digits only. */ static PaUint32 PaAlsaVersionNum(void) { char* verStr; PaUint32 verNum; verStr = (char*) alsa_snd_asoundlib_version(); verNum = ALSA_VERSION_INT( atoi(verStr), atoi(verStr + 2), atoi(verStr + 4) ); PA_DEBUG(( "ALSA version (build): " SND_LIB_VERSION_STR "\nALSA version (runtime): %s\n", verStr )); return verNum; } /* Helper struct */ typedef struct { char *alsaName; char *name; int isPlug; int hasPlayback; int hasCapture; } HwDevInfo; HwDevInfo predefinedNames[] = { { "center_lfe", NULL, 0, 1, 0 }, /* { "default", NULL, 0, 1, 1 }, */ { "dmix", NULL, 0, 1, 0 }, /* { "dpl", NULL, 0, 1, 0 }, */ /* { "dsnoop", NULL, 0, 0, 1 }, */ { "front", NULL, 0, 1, 0 }, { "iec958", NULL, 0, 1, 0 }, /* { "modem", NULL, 0, 1, 0 }, */ { "rear", NULL, 0, 1, 0 }, { "side", NULL, 0, 1, 0 }, /* { "spdif", NULL, 0, 0, 0 }, */ { "surround40", NULL, 0, 1, 0 }, { "surround41", NULL, 0, 1, 0 }, { "surround50", NULL, 0, 1, 0 }, { "surround51", NULL, 0, 1, 0 }, { "surround71", NULL, 0, 1, 0 }, { "AndroidPlayback_Earpiece_normal", NULL, 0, 1, 0 }, { "AndroidPlayback_Speaker_normal", NULL, 0, 1, 0 }, { "AndroidPlayback_Bluetooth_normal", NULL, 0, 1, 0 }, { "AndroidPlayback_Headset_normal", NULL, 0, 1, 0 }, { "AndroidPlayback_Speaker_Headset_normal", NULL, 0, 1, 0 }, { "AndroidPlayback_Bluetooth-A2DP_normal", NULL, 0, 1, 0 }, { "AndroidPlayback_ExtraDockSpeaker_normal", NULL, 0, 1, 0 }, { "AndroidPlayback_TvOut_normal", NULL, 0, 1, 0 }, { "AndroidRecord_Microphone", NULL, 0, 0, 1 }, { "AndroidRecord_Earpiece_normal", NULL, 0, 0, 1 }, { "AndroidRecord_Speaker_normal", NULL, 0, 0, 1 }, { "AndroidRecord_Headset_normal", NULL, 0, 0, 1 }, { "AndroidRecord_Bluetooth_normal", NULL, 0, 0, 1 }, { "AndroidRecord_Speaker_Headset_normal", NULL, 0, 0, 1 }, { NULL, NULL, 0, 1, 0 } }; static const HwDevInfo *FindDeviceName( const char *name ) { int i; for( i = 0; predefinedNames[i].alsaName; i++ ) { if( strcmp( name, predefinedNames[i].alsaName ) == 0 ) { return &predefinedNames[i]; } } return NULL; } static PaError PaAlsa_StrDup( PaAlsaHostApiRepresentation *alsaApi, char **dst, const char *src) { PaError result = paNoError; int len = strlen( src ) + 1; /* PA_DEBUG(("PaStrDup %s %d\n", src, len)); */ PA_UNLESS( *dst = (char *)PaUtil_GroupAllocateMemory( alsaApi->allocations, len ), paInsufficientMemory ); strncpy( *dst, src, len ); error: return result; } /* Disregard some standard plugins */ static int IgnorePlugin( const char *pluginId ) { static const char *ignoredPlugins[] = {"hw", "plughw", "plug", "dsnoop", "tee", "file", "null", "shm", "cards", "rate_convert", NULL}; int i = 0; while( ignoredPlugins[i] ) { if( !strcmp( pluginId, ignoredPlugins[i] ) ) { return 1; } ++i; } return 0; } /** Open PCM device. * * Wrapper around alsa_snd_pcm_open which may repeatedly retry opening a device if it is busy, for * a certain time. This is because dmix may temporarily hold on to a device after it (dmix) * has been opened and closed. * @param mode: Open mode (e.g., SND_PCM_BLOCKING). * @param waitOnBusy: Retry opening busy device for up to one second? **/ static int OpenPcm( snd_pcm_t **pcmp, const char *name, snd_pcm_stream_t stream, int mode, int waitOnBusy ) { int tries = 0, maxTries = waitOnBusy ? busyRetries_ : 0; int ret = alsa_snd_pcm_open( pcmp, name, stream, mode ); for( tries = 0; tries < maxTries && -EBUSY == ret; ++tries ) { Pa_Sleep( 10 ); ret = alsa_snd_pcm_open( pcmp, name, stream, mode ); if( -EBUSY != ret ) { PA_DEBUG(( "%s: Successfully opened initially busy device after %d tries\n", __FUNCTION__, tries )); } } if( -EBUSY == ret ) { PA_DEBUG(( "%s: Failed to open busy device '%s'\n", __FUNCTION__, name )); } else { if (ret < 0) PA_DEBUG(( "%s: Opened device '%s' ptr[%p] - result: [%d:%s]\n", __FUNCTION__, name, *pcmp, ret, alsa_snd_strerror(ret) )); } return ret; } static PaError FillInDevInfo( PaAlsaHostApiRepresentation *alsaApi, HwDevInfo* deviceName, int blocking, PaAlsaDeviceInfo* devInfo, int* devIdx ) { PaError result = 0; PaDeviceInfo *baseDeviceInfo = &devInfo->baseDeviceInfo; snd_pcm_t *pcm = NULL; PaUtilHostApiRepresentation *baseApi = &alsaApi->baseHostApiRep; PA_DEBUG(( "%s: Filling device info for: %s\n", __FUNCTION__, deviceName->name )); /* Zero fields */ InitializeDeviceInfo( baseDeviceInfo ); /* to determine device capabilities, we must open the device and query the * hardware parameter configuration space */ /* Query capture */ if( deviceName->hasCapture && OpenPcm( &pcm, deviceName->alsaName, SND_PCM_STREAM_CAPTURE, blocking, 0 ) >= 0 ) { if( GropeDevice( pcm, deviceName->isPlug, StreamDirection_In, blocking, devInfo ) != paNoError ) { /* Error */ PA_DEBUG(("%s: Failed groping %s for capture\n", __FUNCTION__, deviceName->alsaName)); goto end; } } /* Query playback */ if( deviceName->hasPlayback && OpenPcm( &pcm, deviceName->alsaName, SND_PCM_STREAM_PLAYBACK, blocking, 0 ) >= 0 ) { if( GropeDevice( pcm, deviceName->isPlug, StreamDirection_Out, blocking, devInfo ) != paNoError ) { /* Error */ PA_DEBUG(("%s: Failed groping %s for playback\n", __FUNCTION__, deviceName->alsaName)); goto end; } } baseDeviceInfo->structVersion = 2; baseDeviceInfo->hostApi = alsaApi->hostApiIndex; baseDeviceInfo->name = deviceName->name; devInfo->alsaName = deviceName->alsaName; devInfo->isPlug = deviceName->isPlug; /* A: Storing pointer to PaAlsaDeviceInfo object as pointer to PaDeviceInfo object. * Should now be safe to add device info, unless the device supports neither capture nor playback */ if( baseDeviceInfo->maxInputChannels > 0 || baseDeviceInfo->maxOutputChannels > 0 ) { /* Make device default if there isn't already one or it is the ALSA "default" device */ if( (baseApi->info.defaultInputDevice == paNoDevice || !strcmp(deviceName->alsaName, "default" )) && baseDeviceInfo->maxInputChannels > 0 ) { baseApi->info.defaultInputDevice = *devIdx; PA_DEBUG(("Default input device: %s\n", deviceName->name)); } if( (baseApi->info.defaultOutputDevice == paNoDevice || !strcmp(deviceName->alsaName, "default" )) && baseDeviceInfo->maxOutputChannels > 0 ) { baseApi->info.defaultOutputDevice = *devIdx; PA_DEBUG(("Default output device: %s\n", deviceName->name)); } PA_DEBUG(("%s: Adding device %s: %d\n", __FUNCTION__, deviceName->name, *devIdx)); baseApi->deviceInfos[*devIdx] = (PaDeviceInfo *) devInfo; (*devIdx) += 1; } else { PA_DEBUG(( "%s: Skipped device: %s, all channels == 0\n", __FUNCTION__, deviceName->name )); } end: return result; } /* Build PaDeviceInfo list, ignore devices for which we cannot determine capabilities (possibly busy, sigh) */ static PaError BuildDeviceList( PaAlsaHostApiRepresentation *alsaApi ) { PaUtilHostApiRepresentation *baseApi = &alsaApi->baseHostApiRep; PaAlsaDeviceInfo *deviceInfoArray; int cardIdx = -1, devIdx = 0; snd_ctl_card_info_t *cardInfo; PaError result = paNoError; size_t numDeviceNames = 0, maxDeviceNames = 1, i; HwDevInfo *hwDevInfos = NULL; snd_config_t *topNode = NULL; snd_pcm_info_t *pcmInfo; int res; int blocking = SND_PCM_NONBLOCK; #ifdef PA_ENABLE_DEBUG_OUTPUT PaTime startTime = PaUtil_GetTime(); #endif if( getenv( "PA_ALSA_INITIALIZE_BLOCK" ) && atoi( getenv( "PA_ALSA_INITIALIZE_BLOCK" ) ) ) blocking = 0; /* These two will be set to the first working input and output device, respectively */ baseApi->info.defaultInputDevice = paNoDevice; baseApi->info.defaultOutputDevice = paNoDevice; /* Gather info about hw devices * alsa_snd_card_next() modifies the integer passed to it to be: * the index of the first card if the parameter is -1 * the index of the next card if the parameter is the index of a card * -1 if there are no more cards * * The function itself returns 0 if it succeeded. */ cardIdx = -1; alsa_snd_ctl_card_info_alloca( &cardInfo ); alsa_snd_pcm_info_alloca( &pcmInfo ); while( alsa_snd_card_next( &cardIdx ) == 0 && cardIdx >= 0 ) { char alsaCardNameId[64] = { 0 }; char *cardName; int devIdx = -1; snd_ctl_t *ctl; /* Make card name */ snprintf( alsaCardNameId, sizeof (alsaCardNameId)-1, "hw:%d", cardIdx ); /* Try opening card */ if( alsa_snd_ctl_open( &ctl, alsaCardNameId, 0 ) < 0 ) { /* Unable to open card :( */ PA_DEBUG(( "%s: Unable to open device %s\n", __FUNCTION__, alsaCardNameId )); continue; } alsa_snd_ctl_card_info( ctl, cardInfo ); PA_ENSURE( PaAlsa_StrDup( alsaApi, &cardName, alsa_snd_ctl_card_info_get_name( cardInfo )) ); PA_DEBUG(( "%s: Open card: id[%s] name[%s]\n", __FUNCTION__, alsaCardNameId, cardName )); /* Iterate devices */ while( alsa_snd_ctl_pcm_next_device( ctl, &devIdx ) == 0 && devIdx >= 0 ) { char *alsaDeviceName, *deviceName; size_t len; int hasPlayback = 0, hasCapture = 0; int subDevIdx, subDevCount = 1; PA_DEBUG(( "%s: - idx = %d:\n", __FUNCTION__, devIdx )); /* Make this device current */ alsa_snd_pcm_info_set_device( pcmInfo, devIdx ); /* Iterate sub-devices */ for( subDevIdx = 0; subDevIdx < subDevCount; ++subDevIdx ) { char buf[64] = { 0 }; /* Make this sub-device current */ alsa_snd_pcm_info_set_subdevice( pcmInfo, subDevIdx ); /* Test for Capture capability */ alsa_snd_pcm_info_set_stream( pcmInfo, SND_PCM_STREAM_CAPTURE ); if( alsa_snd_ctl_pcm_info( ctl, pcmInfo ) >= 0 ) { hasCapture = 1; } /* Test for Playback capability */ alsa_snd_pcm_info_set_stream( pcmInfo, SND_PCM_STREAM_PLAYBACK ); if( alsa_snd_ctl_pcm_info( ctl, pcmInfo ) >= 0 ) { hasPlayback = 1; } /* If neither supported, such device is stub or failed */ if( !hasPlayback && !hasCapture ) { continue; } /* Get sub-device count */ if( subDevIdx == 0 ) { subDevCount = alsa_snd_pcm_info_get_subdevices_count( pcmInfo ); PA_DEBUG(( "%s: sub-devices: %d/%d\n", __FUNCTION__, alsa_snd_pcm_info_get_subdevices_avail( pcmInfo ), subDevCount)); } PA_DEBUG(( "%s: - sub: %d\n", __FUNCTION__, subDevIdx )); if( hasCapture ) PA_DEBUG(( "%s: - cap: CAPTURE\n", __FUNCTION__ )); if( hasPlayback ) PA_DEBUG(( "%s: - cap: PLAYBACK\n", __FUNCTION__ )); /* Make name Id */ snprintf( buf, sizeof(buf)-1, ( subDevCount > 1 ? "hw:%d,%d,%d" : "hw:%d,%d" ), cardIdx, devIdx, subDevIdx ); /* Make name */ if( subDevCount <= 1 ) { const char *snd_deviceName = alsa_snd_pcm_info_get_name( pcmInfo ); len = snprintf( NULL, 0, "%s: %s (%s)", cardName, snd_deviceName, buf ) + 1; PA_UNLESS( deviceName = (char *)PaUtil_GroupAllocateMemory( alsaApi->allocations, len ), paInsufficientMemory ); snprintf( deviceName, len, "%s: %s (%s)", cardName, snd_deviceName, buf ); } else { const char *snd_deviceName = alsa_snd_pcm_info_get_name( pcmInfo ); const char *snd_subDeviceName = alsa_snd_pcm_info_get_subdevice_name( pcmInfo ); len = snprintf( NULL, 0, "%s: %s (%s) {%s}", cardName, snd_deviceName, buf, snd_subDeviceName ) + 1; PA_UNLESS( deviceName = (char *)PaUtil_GroupAllocateMemory( alsaApi->allocations, len ), paInsufficientMemory ); snprintf( deviceName, len, "%s: %s (%s) {%s}", cardName, snd_deviceName, buf, snd_subDeviceName ); } ++numDeviceNames; if( !hwDevInfos || numDeviceNames > maxDeviceNames ) { maxDeviceNames *= 2; PA_UNLESS( hwDevInfos = (HwDevInfo *) realloc( hwDevInfos, maxDeviceNames * sizeof (HwDevInfo) ), paInsufficientMemory ); } PA_ENSURE( PaAlsa_StrDup( alsaApi, &alsaDeviceName, buf ) ); hwDevInfos[ numDeviceNames - 1 ].alsaName = alsaDeviceName; hwDevInfos[ numDeviceNames - 1 ].name = deviceName; hwDevInfos[ numDeviceNames - 1 ].isPlug = 0; hwDevInfos[ numDeviceNames - 1 ].hasPlayback = hasPlayback; hwDevInfos[ numDeviceNames - 1 ].hasCapture = hasCapture; PA_DEBUG(( "%s: Registered device: id[%s] name[%s]\n", __FUNCTION__, alsaDeviceName, deviceName )); } } alsa_snd_ctl_close( ctl ); } /* Iterate over plugin devices */ if( NULL == (*alsa_snd_config) ) { /* alsa_snd_config_update is called implicitly by some functions, if this hasn't happened snd_config will be NULL (bleh) */ ENSURE_( alsa_snd_config_update(), paUnanticipatedHostError ); PA_DEBUG(( "Updating snd_config\n" )); } assert( *alsa_snd_config ); if( (res = alsa_snd_config_search( *alsa_snd_config, "pcm", &topNode )) >= 0 ) { snd_config_iterator_t i, next; alsa_snd_config_for_each( i, next, topNode ) { const char *tpStr = "unknown", *idStr = NULL; int err = 0; char *alsaDeviceName, *deviceName; const HwDevInfo *predefined = NULL; snd_config_t *n = alsa_snd_config_iterator_entry( i ), * tp = NULL;; if( (err = alsa_snd_config_search( n, "type", &tp )) < 0 ) { if( -ENOENT != err ) { ENSURE_(err, paUnanticipatedHostError); } } else { ENSURE_( alsa_snd_config_get_string( tp, &tpStr ), paUnanticipatedHostError ); } ENSURE_( alsa_snd_config_get_id( n, &idStr ), paUnanticipatedHostError ); if( IgnorePlugin( idStr ) ) { PA_DEBUG(( "%s: Ignoring ALSA plugin device [%s] of type [%s]\n", __FUNCTION__, idStr, tpStr )); continue; } PA_DEBUG(( "%s: Found plugin [%s] of type [%s]\n", __FUNCTION__, idStr, tpStr )); PA_UNLESS( alsaDeviceName = (char*)PaUtil_GroupAllocateMemory( alsaApi->allocations, strlen(idStr) + 6 ), paInsufficientMemory ); strcpy( alsaDeviceName, idStr ); PA_UNLESS( deviceName = (char*)PaUtil_GroupAllocateMemory( alsaApi->allocations, strlen(idStr) + 1 ), paInsufficientMemory ); strcpy( deviceName, idStr ); ++numDeviceNames; if( !hwDevInfos || numDeviceNames > maxDeviceNames ) { maxDeviceNames *= 2; PA_UNLESS( hwDevInfos = (HwDevInfo *) realloc( hwDevInfos, maxDeviceNames * sizeof (HwDevInfo) ), paInsufficientMemory ); } predefined = FindDeviceName( alsaDeviceName ); hwDevInfos[numDeviceNames - 1].alsaName = alsaDeviceName; hwDevInfos[numDeviceNames - 1].name = deviceName; hwDevInfos[numDeviceNames - 1].isPlug = 1; if( predefined ) { hwDevInfos[numDeviceNames - 1].hasPlayback = predefined->hasPlayback; hwDevInfos[numDeviceNames - 1].hasCapture = predefined->hasCapture; } else { hwDevInfos[numDeviceNames - 1].hasPlayback = 1; hwDevInfos[numDeviceNames - 1].hasCapture = 1; } } } else PA_DEBUG(( "%s: Iterating over ALSA plugins failed: %s\n", __FUNCTION__, alsa_snd_strerror( res ) )); /* allocate deviceInfo memory based on the number of devices */ PA_UNLESS( baseApi->deviceInfos = (PaDeviceInfo**)PaUtil_GroupAllocateMemory( alsaApi->allocations, sizeof(PaDeviceInfo*) * (numDeviceNames) ), paInsufficientMemory ); /* allocate all device info structs in a contiguous block */ PA_UNLESS( deviceInfoArray = (PaAlsaDeviceInfo*)PaUtil_GroupAllocateMemory( alsaApi->allocations, sizeof(PaAlsaDeviceInfo) * numDeviceNames ), paInsufficientMemory ); /* Loop over list of cards, filling in info. If a device is deemed unavailable (can't get name), * it's ignored. * * Note that we do this in two stages. This is a workaround owing to the fact that the 'dmix' * plugin may cause the underlying hardware device to be busy for a short while even after it * (dmix) is closed. The 'default' plugin may also point to the dmix plugin, so the same goes * for this. */ PA_DEBUG(( "%s: Filling device info for %d devices\n", __FUNCTION__, numDeviceNames )); for( i = 0, devIdx = 0; i < numDeviceNames; ++i ) { PaAlsaDeviceInfo* devInfo = &deviceInfoArray[i]; HwDevInfo* hwInfo = &hwDevInfos[i]; if( !strcmp( hwInfo->name, "dmix" ) || !strcmp( hwInfo->name, "default" ) ) { continue; } PA_ENSURE( FillInDevInfo( alsaApi, hwInfo, blocking, devInfo, &devIdx ) ); } assert( devIdx < numDeviceNames ); /* Now inspect 'dmix' and 'default' plugins */ for( i = 0; i < numDeviceNames; ++i ) { PaAlsaDeviceInfo* devInfo = &deviceInfoArray[i]; HwDevInfo* hwInfo = &hwDevInfos[i]; if( strcmp( hwInfo->name, "dmix" ) && strcmp( hwInfo->name, "default" ) ) { continue; } PA_ENSURE( FillInDevInfo( alsaApi, hwInfo, blocking, devInfo, &devIdx ) ); } free( hwDevInfos ); baseApi->info.deviceCount = devIdx; /* Number of successfully queried devices */ #ifdef PA_ENABLE_DEBUG_OUTPUT PA_DEBUG(( "%s: Building device list took %f seconds\n", __FUNCTION__, PaUtil_GetTime() - startTime )); #endif end: return result; error: /* No particular action */ goto end; } /* Check against known device capabilities */ static PaError ValidateParameters( const PaStreamParameters *parameters, PaUtilHostApiRepresentation *hostApi, StreamDirection mode ) { PaError result = paNoError; int maxChans; const PaAlsaDeviceInfo *deviceInfo = NULL; assert( parameters ); if( parameters->device != paUseHostApiSpecificDeviceSpecification ) { assert( parameters->device < hostApi->info.deviceCount ); PA_UNLESS( parameters->hostApiSpecificStreamInfo == NULL, paBadIODeviceCombination ); deviceInfo = GetDeviceInfo( hostApi, parameters->device ); } else { const PaAlsaStreamInfo *streamInfo = parameters->hostApiSpecificStreamInfo; PA_UNLESS( parameters->device == paUseHostApiSpecificDeviceSpecification, paInvalidDevice ); PA_UNLESS( streamInfo->size == sizeof (PaAlsaStreamInfo) && streamInfo->version == 1, paIncompatibleHostApiSpecificStreamInfo ); PA_UNLESS( streamInfo->deviceString != NULL, paInvalidDevice ); /* Skip further checking */ return paNoError; } assert( deviceInfo ); assert( parameters->hostApiSpecificStreamInfo == NULL ); maxChans = (StreamDirection_In == mode ? deviceInfo->baseDeviceInfo.maxInputChannels : deviceInfo->baseDeviceInfo.maxOutputChannels); PA_UNLESS( parameters->channelCount <= maxChans, paInvalidChannelCount ); error: return result; } /* Given an open stream, what sample formats are available? */ static PaSampleFormat GetAvailableFormats( snd_pcm_t *pcm ) { PaSampleFormat available = 0; snd_pcm_hw_params_t *hwParams; alsa_snd_pcm_hw_params_alloca( &hwParams ); alsa_snd_pcm_hw_params_any( pcm, hwParams ); if( alsa_snd_pcm_hw_params_test_format( pcm, hwParams, SND_PCM_FORMAT_FLOAT ) >= 0 ) available |= paFloat32; if( alsa_snd_pcm_hw_params_test_format( pcm, hwParams, SND_PCM_FORMAT_S32 ) >= 0 ) available |= paInt32; #ifdef PA_LITTLE_ENDIAN if( alsa_snd_pcm_hw_params_test_format( pcm, hwParams, SND_PCM_FORMAT_S24_3LE ) >= 0 ) available |= paInt24; #elif defined PA_BIG_ENDIAN if( alsa_snd_pcm_hw_params_test_format( pcm, hwParams, SND_PCM_FORMAT_S24_3BE ) >= 0 ) available |= paInt24; #endif if( alsa_snd_pcm_hw_params_test_format( pcm, hwParams, SND_PCM_FORMAT_S16 ) >= 0 ) available |= paInt16; if( alsa_snd_pcm_hw_params_test_format( pcm, hwParams, SND_PCM_FORMAT_U8 ) >= 0 ) available |= paUInt8; if( alsa_snd_pcm_hw_params_test_format( pcm, hwParams, SND_PCM_FORMAT_S8 ) >= 0 ) available |= paInt8; return available; } /* Given an open stream, what sample formats are available with endianness opposite to native ? */ static PaSampleFormat GetAvailableFormatsReverse( snd_pcm_t *pcm ) { PaSampleFormat available = 0; snd_pcm_hw_params_t *hwParams; alsa_snd_pcm_hw_params_alloca( &hwParams ); alsa_snd_pcm_hw_params_any( pcm, hwParams ); #ifdef PA_LITTLE_ENDIAN if( alsa_snd_pcm_hw_params_test_format( pcm, hwParams, SND_PCM_FORMAT_S24_3BE ) >= 0 ) available |= paInt24; #elif defined PA_BIG_ENDIAN if( alsa_snd_pcm_hw_params_test_format( pcm, hwParams, SND_PCM_FORMAT_S24_3LE ) >= 0 ) available |= paInt24; #endif return available; } /* Output to console all formats supported by device */ static void LogAllAvailableFormats( snd_pcm_t *pcm ) { PaSampleFormat available = 0; snd_pcm_hw_params_t *hwParams; alsa_snd_pcm_hw_params_alloca( &hwParams ); alsa_snd_pcm_hw_params_any( pcm, hwParams ); PA_DEBUG(( " --- Supported Formats ---\n" )); if( alsa_snd_pcm_hw_params_test_format( pcm, hwParams, SND_PCM_FORMAT_S8 ) >= 0) PA_DEBUG(( "SND_PCM_FORMAT_S8\n" )); if( alsa_snd_pcm_hw_params_test_format( pcm, hwParams, SND_PCM_FORMAT_U8 ) >= 0) PA_DEBUG(( "SND_PCM_FORMAT_U8\n" )); if( alsa_snd_pcm_hw_params_test_format( pcm, hwParams, SND_PCM_FORMAT_S16_LE ) >= 0) PA_DEBUG(( "SND_PCM_FORMAT_S16_LE\n" )); if( alsa_snd_pcm_hw_params_test_format( pcm, hwParams, SND_PCM_FORMAT_S16_BE ) >= 0) PA_DEBUG(( "SND_PCM_FORMAT_S16_BE\n" )); if( alsa_snd_pcm_hw_params_test_format( pcm, hwParams, SND_PCM_FORMAT_U16_LE ) >= 0) PA_DEBUG(( "SND_PCM_FORMAT_U16_LE\n" )); if( alsa_snd_pcm_hw_params_test_format( pcm, hwParams, SND_PCM_FORMAT_U16_BE ) >= 0) PA_DEBUG(( "SND_PCM_FORMAT_U16_BE\n" )); if( alsa_snd_pcm_hw_params_test_format( pcm, hwParams, SND_PCM_FORMAT_S24_LE ) >= 0) PA_DEBUG(( "SND_PCM_FORMAT_S24_LE\n" )); if( alsa_snd_pcm_hw_params_test_format( pcm, hwParams, SND_PCM_FORMAT_S24_BE ) >= 0) PA_DEBUG(( "SND_PCM_FORMAT_S24_BE\n" )); if( alsa_snd_pcm_hw_params_test_format( pcm, hwParams, SND_PCM_FORMAT_U24_LE ) >= 0) PA_DEBUG(( "SND_PCM_FORMAT_U24_LE\n" )); if( alsa_snd_pcm_hw_params_test_format( pcm, hwParams, SND_PCM_FORMAT_U24_BE ) >= 0) PA_DEBUG(( "SND_PCM_FORMAT_U24_BE\n" )); if( alsa_snd_pcm_hw_params_test_format( pcm, hwParams, SND_PCM_FORMAT_FLOAT_LE ) >= 0) PA_DEBUG(( "SND_PCM_FORMAT_FLOAT_LE\n" )); if( alsa_snd_pcm_hw_params_test_format( pcm, hwParams, SND_PCM_FORMAT_FLOAT_BE ) >= 0) PA_DEBUG(( "SND_PCM_FORMAT_FLOAT_BE\n" )); if( alsa_snd_pcm_hw_params_test_format( pcm, hwParams, SND_PCM_FORMAT_FLOAT64_LE ) >= 0) PA_DEBUG(( "SND_PCM_FORMAT_FLOAT64_LE\n" )); if( alsa_snd_pcm_hw_params_test_format( pcm, hwParams, SND_PCM_FORMAT_FLOAT64_BE ) >= 0) PA_DEBUG(( "SND_PCM_FORMAT_FLOAT64_BE\n" )); if( alsa_snd_pcm_hw_params_test_format( pcm, hwParams, SND_PCM_FORMAT_IEC958_SUBFRAME_LE ) >= 0) PA_DEBUG(( "SND_PCM_FORMAT_IEC958_SUBFRAME_LE\n" )); if( alsa_snd_pcm_hw_params_test_format( pcm, hwParams, SND_PCM_FORMAT_IEC958_SUBFRAME_BE ) >= 0) PA_DEBUG(( "SND_PCM_FORMAT_IEC958_SUBFRAME_BE\n" )); if( alsa_snd_pcm_hw_params_test_format( pcm, hwParams, SND_PCM_FORMAT_MU_LAW ) >= 0) PA_DEBUG(( "SND_PCM_FORMAT_MU_LAW\n" )); if( alsa_snd_pcm_hw_params_test_format( pcm, hwParams, SND_PCM_FORMAT_A_LAW ) >= 0) PA_DEBUG(( "SND_PCM_FORMAT_A_LAW\n" )); if( alsa_snd_pcm_hw_params_test_format( pcm, hwParams, SND_PCM_FORMAT_IMA_ADPCM ) >= 0) PA_DEBUG(( "SND_PCM_FORMAT_IMA_ADPCM\n" )); if( alsa_snd_pcm_hw_params_test_format( pcm, hwParams, SND_PCM_FORMAT_MPEG ) >= 0) PA_DEBUG(( "SND_PCM_FORMAT_MPEG\n" )); if( alsa_snd_pcm_hw_params_test_format( pcm, hwParams, SND_PCM_FORMAT_GSM ) >= 0) PA_DEBUG(( "SND_PCM_FORMAT_GSM\n" )); if( alsa_snd_pcm_hw_params_test_format( pcm, hwParams, SND_PCM_FORMAT_SPECIAL ) >= 0) PA_DEBUG(( "SND_PCM_FORMAT_SPECIAL\n" )); if( alsa_snd_pcm_hw_params_test_format( pcm, hwParams, SND_PCM_FORMAT_S24_3LE ) >= 0) PA_DEBUG(( "SND_PCM_FORMAT_S24_3LE\n" )); if( alsa_snd_pcm_hw_params_test_format( pcm, hwParams, SND_PCM_FORMAT_S24_3BE ) >= 0) PA_DEBUG(( "SND_PCM_FORMAT_S24_3BE\n" )); if( alsa_snd_pcm_hw_params_test_format( pcm, hwParams, SND_PCM_FORMAT_U24_3LE ) >= 0) PA_DEBUG(( "SND_PCM_FORMAT_U24_3LE\n" )); if( alsa_snd_pcm_hw_params_test_format( pcm, hwParams, SND_PCM_FORMAT_U24_3BE ) >= 0) PA_DEBUG(( "SND_PCM_FORMAT_U24_3BE\n" )); if( alsa_snd_pcm_hw_params_test_format( pcm, hwParams, SND_PCM_FORMAT_S20_3LE ) >= 0) PA_DEBUG(( "SND_PCM_FORMAT_S20_3LE\n" )); if( alsa_snd_pcm_hw_params_test_format( pcm, hwParams, SND_PCM_FORMAT_S20_3BE ) >= 0) PA_DEBUG(( "SND_PCM_FORMAT_S20_3BE\n" )); if( alsa_snd_pcm_hw_params_test_format( pcm, hwParams, SND_PCM_FORMAT_U20_3LE ) >= 0) PA_DEBUG(( "SND_PCM_FORMAT_U20_3LE\n" )); if( alsa_snd_pcm_hw_params_test_format( pcm, hwParams, SND_PCM_FORMAT_U20_3BE ) >= 0) PA_DEBUG(( "SND_PCM_FORMAT_U20_3BE\n" )); if( alsa_snd_pcm_hw_params_test_format( pcm, hwParams, SND_PCM_FORMAT_S18_3LE ) >= 0) PA_DEBUG(( "SND_PCM_FORMAT_S18_3LE\n" )); if( alsa_snd_pcm_hw_params_test_format( pcm, hwParams, SND_PCM_FORMAT_S18_3BE ) >= 0) PA_DEBUG(( "SND_PCM_FORMAT_S18_3BE\n" )); if( alsa_snd_pcm_hw_params_test_format( pcm, hwParams, SND_PCM_FORMAT_U18_3LE ) >= 0) PA_DEBUG(( "SND_PCM_FORMAT_U18_3LE\n" )); if( alsa_snd_pcm_hw_params_test_format( pcm, hwParams, SND_PCM_FORMAT_U18_3BE ) >= 0) PA_DEBUG(( "SND_PCM_FORMAT_U18_3BE\n" )); if( alsa_snd_pcm_hw_params_test_format( pcm, hwParams, SND_PCM_FORMAT_S16 ) >= 0) PA_DEBUG(( "SND_PCM_FORMAT_S16\n" )); if( alsa_snd_pcm_hw_params_test_format( pcm, hwParams, SND_PCM_FORMAT_U16 ) >= 0) PA_DEBUG(( "SND_PCM_FORMAT_U16\n" )); if( alsa_snd_pcm_hw_params_test_format( pcm, hwParams, SND_PCM_FORMAT_S24 ) >= 0) PA_DEBUG(( "SND_PCM_FORMAT_S24\n" )); if( alsa_snd_pcm_hw_params_test_format( pcm, hwParams, SND_PCM_FORMAT_U24 ) >= 0) PA_DEBUG(( "SND_PCM_FORMAT_U24\n" )); if( alsa_snd_pcm_hw_params_test_format( pcm, hwParams, SND_PCM_FORMAT_S32 ) >= 0) PA_DEBUG(( "SND_PCM_FORMAT_S32\n" )); if( alsa_snd_pcm_hw_params_test_format( pcm, hwParams, SND_PCM_FORMAT_U32 ) >= 0) PA_DEBUG(( "SND_PCM_FORMAT_U32\n" )); if( alsa_snd_pcm_hw_params_test_format( pcm, hwParams, SND_PCM_FORMAT_FLOAT ) >= 0) PA_DEBUG(( "SND_PCM_FORMAT_FLOAT\n" )); if( alsa_snd_pcm_hw_params_test_format( pcm, hwParams, SND_PCM_FORMAT_FLOAT64 ) >= 0) PA_DEBUG(( "SND_PCM_FORMAT_FLOAT64\n" )); if( alsa_snd_pcm_hw_params_test_format( pcm, hwParams, SND_PCM_FORMAT_IEC958_SUBFRAME ) >= 0) PA_DEBUG(( "SND_PCM_FORMAT_IEC958_SUBFRAME\n" )); PA_DEBUG(( " -------------------------\n" )); } static snd_pcm_format_t Pa2AlsaFormat( PaSampleFormat paFormat ) { switch( PA_ALSA_TO_FORMAT(paFormat) ) { case paFloat32: return SND_PCM_FORMAT_FLOAT; case paInt16: return SND_PCM_FORMAT_S16; case paInt24: #ifdef PA_LITTLE_ENDIAN return SND_PCM_FORMAT_S24_3LE; #elif defined PA_BIG_ENDIAN return SND_PCM_FORMAT_S24_3BE; #endif case paInt32: return SND_PCM_FORMAT_S32; case paInt8: return SND_PCM_FORMAT_S8; case paUInt8: return SND_PCM_FORMAT_U8; default: return SND_PCM_FORMAT_UNKNOWN; } } static snd_pcm_format_t Pa2AlsaFormatReverse( PaSampleFormat paFormat ) { switch( PA_ALSA_TO_FORMAT(paFormat) ) { case paInt24: #ifdef PA_LITTLE_ENDIAN return SND_PCM_FORMAT_S24_3BE; #elif defined PA_BIG_ENDIAN return SND_PCM_FORMAT_S24_3LE; #endif default: return SND_PCM_FORMAT_UNKNOWN; } } /** Open an ALSA pcm handle. * * The device to be open can be specified in a custom PaAlsaStreamInfo struct, or it will be a device number. In case of a * device number, it maybe specified through an env variable (PA_ALSA_PLUGHW) that we should open the corresponding plugin * device. */ static PaError AlsaOpen( const PaUtilHostApiRepresentation *hostApi, const PaStreamParameters *params, StreamDirection streamDir, snd_pcm_t **pcm ) { PaError result = paNoError; int ret; char dnameArray[50]; const char* deviceName = dnameArray; const PaAlsaDeviceInfo *deviceInfo = NULL; PaAlsaStreamInfo *streamInfo = (PaAlsaStreamInfo *)params->hostApiSpecificStreamInfo; if( !streamInfo ) { int usePlug = 0; deviceInfo = GetDeviceInfo( hostApi, params->device ); /* If device name starts with hw: and PA_ALSA_PLUGHW is 1, we open the plughw device instead */ if( !strncmp( "hw:", deviceInfo->alsaName, 3 ) && getenv( "PA_ALSA_PLUGHW" ) ) usePlug = atoi( getenv( "PA_ALSA_PLUGHW" ) ); if( usePlug ) snprintf( dnameArray, 50, "plug%s", deviceInfo->alsaName ); else deviceName = deviceInfo->alsaName; } else deviceName = streamInfo->deviceString; PA_DEBUG(( "%s: Opening device %s\n", __FUNCTION__, deviceName )); if( (ret = OpenPcm( pcm, deviceName, streamDir == StreamDirection_In ? SND_PCM_STREAM_CAPTURE : SND_PCM_STREAM_PLAYBACK, SND_PCM_NONBLOCK, 1 )) < 0 ) { /* Not to be closed */ *pcm = NULL; ENSURE_( ret, -EBUSY == ret ? paDeviceUnavailable : paBadIODeviceCombination ); } ENSURE_( alsa_snd_pcm_nonblock( *pcm, 0 ), paUnanticipatedHostError ); end: return result; error: goto end; } static PaError TestParameters( const PaUtilHostApiRepresentation *hostApi, const PaStreamParameters *parameters, double sampleRate, StreamDirection streamDir ) { PaError result = paNoError; snd_pcm_t *pcm = NULL; PaSampleFormat availableFormats; /* We are able to adapt to a number of channels less than what the device supports */ unsigned int numHostChannels; PaSampleFormat hostFormat; snd_pcm_format_t hostNativeFormat; snd_pcm_hw_params_t *hwParams; alsa_snd_pcm_hw_params_alloca( &hwParams ); if( !parameters->hostApiSpecificStreamInfo ) { const PaAlsaDeviceInfo *devInfo = GetDeviceInfo( hostApi, parameters->device ); numHostChannels = PA_MAX( parameters->channelCount, StreamDirection_In == streamDir ? devInfo->minInputChannels : devInfo->minOutputChannels ); } else numHostChannels = parameters->channelCount; PA_ENSURE( AlsaOpen( hostApi, parameters, streamDir, &pcm ) ); alsa_snd_pcm_hw_params_any( pcm, hwParams ); if( SetApproximateSampleRate( pcm, hwParams, sampleRate ) < 0 ) { result = paInvalidSampleRate; goto error; } if( alsa_snd_pcm_hw_params_set_channels( pcm, hwParams, numHostChannels ) < 0 ) { result = paInvalidChannelCount; goto error; } /* See if we can find a best possible match */ if ( ( availableFormats = GetAvailableFormats( pcm ) ) != 0 ) { PA_ENSURE( hostFormat = PaUtil_SelectClosestAvailableFormat( PA_ALSA_TO_FORMAT(availableFormats), parameters->sampleFormat ) ); hostNativeFormat = Pa2AlsaFormat( hostFormat ); } else if ( ( availableFormats = GetAvailableFormatsReverse( pcm ) ) != 0 ) { PA_ENSURE( hostFormat = PaUtil_SelectClosestAvailableFormat( PA_ALSA_TO_FORMAT(availableFormats), parameters->sampleFormat ) ); hostNativeFormat = Pa2AlsaFormatReverse( hostFormat ); } else { result = paSampleFormatNotSupported; goto error; } ENSURE_( alsa_snd_pcm_hw_params_set_format( pcm, hwParams, hostNativeFormat ), paUnanticipatedHostError ); { /* It happens that this call fails because the device is busy */ int ret = 0; if( (ret = alsa_snd_pcm_hw_params( pcm, hwParams )) < 0) { if( -EINVAL == ret ) { /* Don't know what to return here */ result = paBadIODeviceCombination; goto error; } else if( -EBUSY == ret ) { result = paDeviceUnavailable; PA_DEBUG(( "%s: Device is busy\n", __FUNCTION__ )); } else { result = paUnanticipatedHostError; } ENSURE_( ret, result ); } } end: if( pcm ) { alsa_snd_pcm_close( pcm ); } return result; error: goto end; } static PaError IsFormatSupported( struct PaUtilHostApiRepresentation *hostApi, const PaStreamParameters *inputParameters, const PaStreamParameters *outputParameters, double sampleRate ) { int inputChannelCount = 0, outputChannelCount = 0; PaSampleFormat inputSampleFormat, outputSampleFormat; PaError result = paFormatIsSupported; if( inputParameters ) { PA_ENSURE( ValidateParameters( inputParameters, hostApi, StreamDirection_In ) ); inputChannelCount = inputParameters->channelCount; inputSampleFormat = inputParameters->sampleFormat; } if( outputParameters ) { PA_ENSURE( ValidateParameters( outputParameters, hostApi, StreamDirection_Out ) ); outputChannelCount = outputParameters->channelCount; outputSampleFormat = outputParameters->sampleFormat; } if( inputChannelCount ) { if( (result = TestParameters( hostApi, inputParameters, sampleRate, StreamDirection_In )) != paNoError ) goto error; } if ( outputChannelCount ) { if( (result = TestParameters( hostApi, outputParameters, sampleRate, StreamDirection_Out )) != paNoError ) goto error; } return paFormatIsSupported; error: return result; } static PaError PaAlsaStreamComponent_Initialize( PaAlsaStreamComponent *self, PaAlsaHostApiRepresentation *alsaApi, const PaStreamParameters *params, StreamDirection streamDir, int callbackMode ) { PaSampleFormat availableFormats; PaError result = paNoError; PaSampleFormat userSampleFormat = params->sampleFormat, hostSampleFormat = paSampleFormatNotSupported; assert( params->channelCount > 0 ); /* Make sure things have an initial value */ memset( self, 0, sizeof (PaAlsaStreamComponent) ); if( NULL == params->hostApiSpecificStreamInfo ) { const PaAlsaDeviceInfo *devInfo = GetDeviceInfo( &alsaApi->baseHostApiRep, params->device ); self->numHostChannels = PA_MAX( params->channelCount, StreamDirection_In == streamDir ? devInfo->minInputChannels : devInfo->minOutputChannels ); self->deviceIsPlug = devInfo->isPlug; } else { /* We're blissfully unaware of the minimum channelCount */ self->numHostChannels = params->channelCount; /* Check if device name does not start with hw: to determine if it is a 'plug' device */ if( strncmp( "hw:", ((PaAlsaStreamInfo *)params->hostApiSpecificStreamInfo)->deviceString, 3 ) != 0 ) self->deviceIsPlug = 1; /* An Alsa plug device, not a direct hw device */ } if( self->deviceIsPlug && alsaApi->alsaLibVersion < ALSA_VERSION_INT( 1, 0, 16 ) ) self->useReventFix = 1; /* Prior to Alsa1.0.16, plug devices may stutter without this fix */ self->device = params->device; PA_ENSURE( AlsaOpen( &alsaApi->baseHostApiRep, params, streamDir, &self->pcm ) ); self->nfds = alsa_snd_pcm_poll_descriptors_count( self->pcm ); /* Select the best host sample format */ if ( ( availableFormats = GetAvailableFormats( self->pcm ) ) != 0 ) { PA_ENSURE( hostSampleFormat = PaUtil_SelectClosestAvailableFormat( PA_ALSA_TO_FORMAT(availableFormats), userSampleFormat ) ); self->nativeFormat = Pa2AlsaFormat( hostSampleFormat ); } else if ( ( availableFormats = GetAvailableFormatsReverse( self->pcm ) ) != 0 ) { PA_ENSURE( hostSampleFormat = PaUtil_SelectClosestAvailableFormat( PA_ALSA_TO_FORMAT(availableFormats), userSampleFormat ) ); self->nativeFormat = Pa2AlsaFormatReverse( hostSampleFormat ); self->useByteSwapConverter = 1; } else { result = paSampleFormatNotSupported; goto error; } self->hostSampleFormat = hostSampleFormat; self->hostInterleaved = self->userInterleaved = !(userSampleFormat & paNonInterleaved); self->numUserChannels = params->channelCount; self->streamDir = streamDir; self->canMmap = 0; self->nonMmapBuffer = NULL; self->nonMmapBufferSize = 0; if( !callbackMode && !self->userInterleaved ) { /* Pre-allocate non-interleaved user provided buffers */ PA_UNLESS( self->userBuffers = PaUtil_AllocateMemory( sizeof (void *) * self->numUserChannels ), paInsufficientMemory ); } error: /* Log all available formats. */ if ( hostSampleFormat == paSampleFormatNotSupported ) { LogAllAvailableFormats( self->pcm ); PA_DEBUG(( "%s: Please provide the log output to PortAudio developers, your hardware does not have any sample format implemented yet.\n", __FUNCTION__ )); } return result; } static void PaAlsaStreamComponent_Terminate( PaAlsaStreamComponent *self ) { alsa_snd_pcm_close( self->pcm ); if( self->userBuffers ) PaUtil_FreeMemory( self->userBuffers ); } /* static int nearbyint_(float value) { if( value - (int)value > .5 ) return (int)ceil( value ); return (int)floor( value ); } */ /** Initiate configuration, preparing for determining a period size suitable for both capture and playback components. * */ static PaError PaAlsaStreamComponent_InitialConfigure( PaAlsaStreamComponent *self, const PaStreamParameters *params, int primeBuffers, snd_pcm_hw_params_t *hwParams, double *sampleRate ) { /* Configuration consists of setting all of ALSA's parameters. * These parameters come in two flavors: hardware parameters * and software paramters. Hardware parameters will affect * the way the device is initialized, software parameters * affect the way ALSA interacts with me, the user-level client. */ PaError result = paNoError; snd_pcm_access_t accessMode, alternateAccessMode; int dir = 0; snd_pcm_t *pcm = self->pcm; double sr = *sampleRate; unsigned int minPeriods = 2; /* self->framesPerBuffer = framesPerHostBuffer; */ /* ... fill up the configuration space with all possibile * combinations of parameters this device will accept */ ENSURE_( alsa_snd_pcm_hw_params_any( pcm, hwParams ), paUnanticipatedHostError ); ENSURE_( alsa_snd_pcm_hw_params_set_periods_integer( pcm, hwParams ), paUnanticipatedHostError ); /* I think there should be at least 2 periods (even though ALSA doesn't appear to enforce this) */ dir = 0; ENSURE_( alsa_snd_pcm_hw_params_set_periods_min( pcm, hwParams, &minPeriods, &dir ), paUnanticipatedHostError ); if( self->userInterleaved ) { accessMode = SND_PCM_ACCESS_MMAP_INTERLEAVED; alternateAccessMode = SND_PCM_ACCESS_MMAP_NONINTERLEAVED; /* test if MMAP supported */ self->canMmap = alsa_snd_pcm_hw_params_test_access( pcm, hwParams, accessMode ) >= 0 || alsa_snd_pcm_hw_params_test_access( pcm, hwParams, alternateAccessMode ) >= 0; PA_DEBUG(("%s: device MMAP SND_PCM_ACCESS_MMAP_INTERLEAVED: %s\n", __FUNCTION__, (alsa_snd_pcm_hw_params_test_access( pcm, hwParams, accessMode ) >= 0 ? "YES" : "NO"))); PA_DEBUG(("%s: device MMAP SND_PCM_ACCESS_MMAP_NONINTERLEAVED: %s\n", __FUNCTION__, (alsa_snd_pcm_hw_params_test_access( pcm, hwParams, alternateAccessMode ) >= 0 ? "YES" : "NO"))); if (!self->canMmap) { accessMode = SND_PCM_ACCESS_RW_INTERLEAVED; alternateAccessMode = SND_PCM_ACCESS_RW_NONINTERLEAVED; } } else { accessMode = SND_PCM_ACCESS_MMAP_NONINTERLEAVED; alternateAccessMode = SND_PCM_ACCESS_MMAP_INTERLEAVED; /* test if MMAP supported */ self->canMmap = alsa_snd_pcm_hw_params_test_access( pcm, hwParams, accessMode ) >= 0 || alsa_snd_pcm_hw_params_test_access( pcm, hwParams, alternateAccessMode ) >= 0; PA_DEBUG(("%s: device MMAP SND_PCM_ACCESS_MMAP_NONINTERLEAVED: %s\n", __FUNCTION__, (alsa_snd_pcm_hw_params_test_access( pcm, hwParams, accessMode ) >= 0 ? "YES" : "NO"))); PA_DEBUG(("%s: device MMAP SND_PCM_ACCESS_MMAP_INTERLEAVED: %s\n", __FUNCTION__, (alsa_snd_pcm_hw_params_test_access( pcm, hwParams, alternateAccessMode ) >= 0 ? "YES" : "NO"))); if (!self->canMmap) { accessMode = SND_PCM_ACCESS_RW_NONINTERLEAVED; alternateAccessMode = SND_PCM_ACCESS_RW_INTERLEAVED; } } PA_DEBUG(("%s: device can MMAP: %s\n", __FUNCTION__, (self->canMmap ? "YES" : "NO"))); /* If requested access mode fails, try alternate mode */ if( alsa_snd_pcm_hw_params_set_access( pcm, hwParams, accessMode ) < 0 ) { int err = 0; if( (err = alsa_snd_pcm_hw_params_set_access( pcm, hwParams, alternateAccessMode )) < 0) { result = paUnanticipatedHostError; PaUtil_SetLastHostErrorInfo( paALSA, err, alsa_snd_strerror( err ) ); goto error; } /* Flip mode */ self->hostInterleaved = !self->userInterleaved; } /* Some specific hardware (reported: Audio8 DJ) can fail with assertion during this step. */ ENSURE_( alsa_snd_pcm_hw_params_set_format( pcm, hwParams, self->nativeFormat ), paUnanticipatedHostError ); ENSURE_( SetApproximateSampleRate( pcm, hwParams, sr ), paInvalidSampleRate ); ENSURE_( GetExactSampleRate( hwParams, &sr ), paUnanticipatedHostError ); /* reject if there's no sample rate within 1% of the one requested */ if( (fabs( *sampleRate - sr ) / *sampleRate) > 0.01 ) { PA_DEBUG(("%s: Wanted %f, closest sample rate was %d\n", __FUNCTION__, sampleRate, sr )); PA_ENSURE( paInvalidSampleRate ); } ENSURE_( alsa_snd_pcm_hw_params_set_channels( pcm, hwParams, self->numHostChannels ), paInvalidChannelCount ); *sampleRate = sr; end: return result; error: /* No particular action */ goto end; } /** Finish the configuration of the component's ALSA device. * * As part of this method, the component's bufferSize attribute will be set. * @param latency: The latency for this component. */ static PaError PaAlsaStreamComponent_FinishConfigure( PaAlsaStreamComponent *self, snd_pcm_hw_params_t* hwParams, const PaStreamParameters *params, int primeBuffers, double sampleRate, PaTime* latency ) { PaError result = paNoError; snd_pcm_sw_params_t* swParams; snd_pcm_uframes_t bufSz = 0; *latency = -1.; alsa_snd_pcm_sw_params_alloca( &swParams ); bufSz = params->suggestedLatency * sampleRate; ENSURE_( alsa_snd_pcm_hw_params_set_buffer_size_near( self->pcm, hwParams, &bufSz ), paUnanticipatedHostError ); /* Set the parameters! */ { int r = alsa_snd_pcm_hw_params( self->pcm, hwParams ); #ifdef PA_ENABLE_DEBUG_OUTPUT if( r < 0 ) { snd_output_t *output = NULL; alsa_snd_output_stdio_attach( &output, stderr, 0 ); alsa_snd_pcm_hw_params_dump( hwParams, output ); } #endif ENSURE_(r, paUnanticipatedHostError ); } if (alsa_snd_pcm_hw_params_get_buffer_size != NULL) { ENSURE_( alsa_snd_pcm_hw_params_get_buffer_size( hwParams, &self->bufferSize ), paUnanticipatedHostError ); } else { self->bufferSize = bufSz; } /* Latency in seconds */ *latency = self->bufferSize / sampleRate; /* Now software parameters... */ ENSURE_( alsa_snd_pcm_sw_params_current( self->pcm, swParams ), paUnanticipatedHostError ); ENSURE_( alsa_snd_pcm_sw_params_set_start_threshold( self->pcm, swParams, self->framesPerBuffer ), paUnanticipatedHostError ); ENSURE_( alsa_snd_pcm_sw_params_set_stop_threshold( self->pcm, swParams, self->bufferSize ), paUnanticipatedHostError ); /* Silence buffer in the case of underrun */ if( !primeBuffers ) /* XXX: Make sense? */ { snd_pcm_uframes_t boundary; ENSURE_( alsa_snd_pcm_sw_params_get_boundary( swParams, &boundary ), paUnanticipatedHostError ); ENSURE_( alsa_snd_pcm_sw_params_set_silence_threshold( self->pcm, swParams, 0 ), paUnanticipatedHostError ); ENSURE_( alsa_snd_pcm_sw_params_set_silence_size( self->pcm, swParams, boundary ), paUnanticipatedHostError ); } ENSURE_( alsa_snd_pcm_sw_params_set_avail_min( self->pcm, swParams, self->framesPerBuffer ), paUnanticipatedHostError ); ENSURE_( alsa_snd_pcm_sw_params_set_xfer_align( self->pcm, swParams, 1 ), paUnanticipatedHostError ); ENSURE_( alsa_snd_pcm_sw_params_set_tstamp_mode( self->pcm, swParams, SND_PCM_TSTAMP_ENABLE ), paUnanticipatedHostError ); /* Set the parameters! */ ENSURE_( alsa_snd_pcm_sw_params( self->pcm, swParams ), paUnanticipatedHostError ); error: return result; } static PaError PaAlsaStream_Initialize( PaAlsaStream *self, PaAlsaHostApiRepresentation *alsaApi, const PaStreamParameters *inParams, const PaStreamParameters *outParams, double sampleRate, unsigned long framesPerUserBuffer, PaStreamCallback callback, PaStreamFlags streamFlags, void *userData ) { PaError result = paNoError; assert( self ); memset( self, 0, sizeof (PaAlsaStream) ); if( NULL != callback ) { PaUtil_InitializeStreamRepresentation( &self->streamRepresentation, &alsaApi->callbackStreamInterface, callback, userData ); self->callbackMode = 1; } else { PaUtil_InitializeStreamRepresentation( &self->streamRepresentation, &alsaApi->blockingStreamInterface, NULL, userData ); } self->framesPerUserBuffer = framesPerUserBuffer; self->neverDropInput = streamFlags & paNeverDropInput; /* XXX: Ignore paPrimeOutputBuffersUsingStreamCallback untill buffer priming is fully supported in pa_process.c */ /* if( outParams & streamFlags & paPrimeOutputBuffersUsingStreamCallback ) self->primeBuffers = 1; */ memset( &self->capture, 0, sizeof (PaAlsaStreamComponent) ); memset( &self->playback, 0, sizeof (PaAlsaStreamComponent) ); if( inParams ) { PA_ENSURE( PaAlsaStreamComponent_Initialize( &self->capture, alsaApi, inParams, StreamDirection_In, NULL != callback ) ); } if( outParams ) { PA_ENSURE( PaAlsaStreamComponent_Initialize( &self->playback, alsaApi, outParams, StreamDirection_Out, NULL != callback ) ); } assert( self->capture.nfds || self->playback.nfds ); PA_UNLESS( self->pfds = (struct pollfd*)PaUtil_AllocateMemory( (self->capture.nfds + self->playback.nfds) * sizeof (struct pollfd) ), paInsufficientMemory ); PaUtil_InitializeCpuLoadMeasurer( &self->cpuLoadMeasurer, sampleRate ); ASSERT_CALL_( PaUnixMutex_Initialize( &self->stateMtx ), paNoError ); error: return result; } /** Free resources associated with stream, and eventually stream itself. * * Frees allocated memory, and terminates individual StreamComponents. */ static void PaAlsaStream_Terminate( PaAlsaStream *self ) { assert( self ); if( self->capture.pcm ) { PaAlsaStreamComponent_Terminate( &self->capture ); } if( self->playback.pcm ) { PaAlsaStreamComponent_Terminate( &self->playback ); } PaUtil_FreeMemory( self->pfds ); ASSERT_CALL_( PaUnixMutex_Terminate( &self->stateMtx ), paNoError ); PaUtil_FreeMemory( self ); } /** Calculate polling timeout * * @param frames Time to wait * @return Polling timeout in milliseconds */ static int CalculatePollTimeout( const PaAlsaStream *stream, unsigned long frames ) { assert( stream->streamRepresentation.streamInfo.sampleRate > 0.0 ); /* Period in msecs, rounded up */ return (int)ceil( 1000 * frames / stream->streamRepresentation.streamInfo.sampleRate ); } /** Align value in backward direction. * * @param v: Value to align. * @param align: Alignment. */ static unsigned long PaAlsa_AlignBackward(unsigned long v, unsigned long align) { return ((v - (align ? v % align : 0))); } /** Align value in forward direction. * * @param v: Value to align. * @param align: Alignment. */ static unsigned long PaAlsa_AlignForward(unsigned long v, unsigned long align) { unsigned long remainder = (align ? (v % align) : 0); return (remainder != 0 ? v + (align - remainder) : v); } /** Get size of host buffer maintained from the number of user frames, sample rate and suggested latency. Minimum double buffering * is maintained to allow 100% CPU usage inside user callback. * * @param userFramesPerBuffer: User buffer size in number of frames. * @param suggestedLatency: User provided desired latency. * @param sampleRate: Sample rate. */ static unsigned long PaAlsa_GetFramesPerHostBuffer(unsigned long userFramesPerBuffer, PaTime suggestedLatency, double sampleRate) { unsigned long frames = userFramesPerBuffer + PA_MAX( userFramesPerBuffer, (unsigned long)(suggestedLatency * sampleRate) ); return frames; } /** Determine size per host buffer. * * During this method call, the component's framesPerBuffer attribute gets computed, and the corresponding period size * gets configured for the device. * @param accurate: If the configured period size is non-integer, this will be set to 0. */ static PaError PaAlsaStreamComponent_DetermineFramesPerBuffer( PaAlsaStreamComponent* self, const PaStreamParameters* params, unsigned long framesPerUserBuffer, double sampleRate, snd_pcm_hw_params_t* hwParams, int* accurate ) { PaError result = paNoError; unsigned long bufferSize, framesPerHostBuffer; int dir = 0; /* Calculate host buffer size */ bufferSize = PaAlsa_GetFramesPerHostBuffer(framesPerUserBuffer, params->suggestedLatency, sampleRate); /* Log */ PA_DEBUG(( "%s: user-buffer (frames) = %lu\n", __FUNCTION__, framesPerUserBuffer )); PA_DEBUG(( "%s: user-buffer (sec) = %f\n", __FUNCTION__, (double)(framesPerUserBuffer / sampleRate) )); PA_DEBUG(( "%s: suggested latency (sec) = %f\n", __FUNCTION__, params->suggestedLatency )); PA_DEBUG(( "%s: suggested host buffer (frames) = %lu\n", __FUNCTION__, bufferSize )); PA_DEBUG(( "%s: suggested host buffer (sec) = %f\n", __FUNCTION__, (double)(bufferSize / sampleRate) )); #ifdef PA_ALSA_USE_OBSOLETE_HOST_BUFFER_CALC if( framesPerUserBuffer != paFramesPerBufferUnspecified ) { /* Preferably the host buffer size should be a multiple of the user buffer size */ if( bufferSize > framesPerUserBuffer ) { snd_pcm_uframes_t remainder = bufferSize % framesPerUserBuffer; if( remainder > framesPerUserBuffer / 2. ) bufferSize += framesPerUserBuffer - remainder; else bufferSize -= remainder; assert( bufferSize % framesPerUserBuffer == 0 ); } else if( framesPerUserBuffer % bufferSize != 0 ) { /* Find a good compromise between user specified latency and buffer size */ if( bufferSize > framesPerUserBuffer * .75 ) { bufferSize = framesPerUserBuffer; } else { snd_pcm_uframes_t newSz = framesPerUserBuffer; while( newSz / 2 >= bufferSize ) { if( framesPerUserBuffer % (newSz / 2) != 0 ) { /* No use dividing any further */ break; } newSz /= 2; } bufferSize = newSz; } assert( framesPerUserBuffer % bufferSize == 0 ); } } #endif { unsigned numPeriods = numPeriods_, maxPeriods = 0, minPeriods = numPeriods_; /* It may be that the device only supports 2 periods for instance */ dir = 0; ENSURE_( alsa_snd_pcm_hw_params_get_periods_min( hwParams, &minPeriods, &dir ), paUnanticipatedHostError ); ENSURE_( alsa_snd_pcm_hw_params_get_periods_max( hwParams, &maxPeriods, &dir ), paUnanticipatedHostError ); assert( maxPeriods > 1 ); /* Clamp to min/max */ numPeriods = PA_MIN(maxPeriods, PA_MAX(minPeriods, numPeriods)); PA_DEBUG(( "%s: periods min = %lu, max = %lu, req = %lu \n", __FUNCTION__, minPeriods, maxPeriods, numPeriods )); #ifndef PA_ALSA_USE_OBSOLETE_HOST_BUFFER_CALC /* Calculate period size */ framesPerHostBuffer = (bufferSize / numPeriods); /* Align & test size */ if( framesPerUserBuffer != paFramesPerBufferUnspecified ) { /* Align to user buffer size */ framesPerHostBuffer = PaAlsa_AlignForward(framesPerHostBuffer, framesPerUserBuffer); /* Test (borrowed from older implementation) */ if( framesPerHostBuffer < framesPerUserBuffer ) { assert( framesPerUserBuffer % framesPerHostBuffer == 0 ); if( alsa_snd_pcm_hw_params_test_period_size( self->pcm, hwParams, framesPerHostBuffer, 0 ) < 0 ) { if( alsa_snd_pcm_hw_params_test_period_size( self->pcm, hwParams, framesPerHostBuffer * 2, 0 ) == 0 ) framesPerHostBuffer *= 2; else if( alsa_snd_pcm_hw_params_test_period_size( self->pcm, hwParams, framesPerHostBuffer / 2, 0 ) == 0 ) framesPerHostBuffer /= 2; } } else { assert( framesPerHostBuffer % framesPerUserBuffer == 0 ); if( alsa_snd_pcm_hw_params_test_period_size( self->pcm, hwParams, framesPerHostBuffer, 0 ) < 0 ) { if( alsa_snd_pcm_hw_params_test_period_size( self->pcm, hwParams, framesPerHostBuffer + framesPerUserBuffer, 0 ) == 0 ) framesPerHostBuffer += framesPerUserBuffer; else if( alsa_snd_pcm_hw_params_test_period_size( self->pcm, hwParams, framesPerHostBuffer - framesPerUserBuffer, 0 ) == 0 ) framesPerHostBuffer -= framesPerUserBuffer; } } } #endif #ifdef PA_ALSA_USE_OBSOLETE_HOST_BUFFER_CALC if( framesPerUserBuffer != paFramesPerBufferUnspecified ) { /* Try to get a power-of-two of the user buffer size. */ framesPerHostBuffer = framesPerUserBuffer; if( framesPerHostBuffer < bufferSize ) { while( bufferSize / framesPerHostBuffer > numPeriods ) { framesPerHostBuffer *= 2; } /* One extra period is preferrable to one less (should be more robust) */ if( bufferSize / framesPerHostBuffer < numPeriods ) { framesPerHostBuffer /= 2; } } else { while( bufferSize / framesPerHostBuffer < numPeriods ) { if( framesPerUserBuffer % (framesPerHostBuffer / 2) != 0 ) { /* Can't be divided any further */ break; } framesPerHostBuffer /= 2; } } if( framesPerHostBuffer < framesPerUserBuffer ) { assert( framesPerUserBuffer % framesPerHostBuffer == 0 ); if( alsa_snd_pcm_hw_params_test_period_size( self->pcm, hwParams, framesPerHostBuffer, 0 ) < 0 ) { if( alsa_snd_pcm_hw_params_test_period_size( self->pcm, hwParams, framesPerHostBuffer * 2, 0 ) == 0 ) framesPerHostBuffer *= 2; else if( alsa_snd_pcm_hw_params_test_period_size( self->pcm, hwParams, framesPerHostBuffer / 2, 0 ) == 0 ) framesPerHostBuffer /= 2; } } else { assert( framesPerHostBuffer % framesPerUserBuffer == 0 ); if( alsa_snd_pcm_hw_params_test_period_size( self->pcm, hwParams, framesPerHostBuffer, 0 ) < 0 ) { if( alsa_snd_pcm_hw_params_test_period_size( self->pcm, hwParams, framesPerHostBuffer + framesPerUserBuffer, 0 ) == 0 ) framesPerHostBuffer += framesPerUserBuffer; else if( alsa_snd_pcm_hw_params_test_period_size( self->pcm, hwParams, framesPerHostBuffer - framesPerUserBuffer, 0 ) == 0 ) framesPerHostBuffer -= framesPerUserBuffer; } } } else { framesPerHostBuffer = bufferSize / numPeriods; } /* non-mmap mode needs a reasonably-sized buffer or it'll stutter */ if( !self->canMmap && framesPerHostBuffer < 2048 ) framesPerHostBuffer = 2048; #endif PA_DEBUG(( "%s: suggested host buffer period = %lu \n", __FUNCTION__, framesPerHostBuffer )); } { /* Get min/max period sizes and adjust our chosen */ snd_pcm_uframes_t min = 0, max = 0, minmax_diff; ENSURE_( alsa_snd_pcm_hw_params_get_period_size_min( hwParams, &min, NULL ), paUnanticipatedHostError ); ENSURE_( alsa_snd_pcm_hw_params_get_period_size_max( hwParams, &max, NULL ), paUnanticipatedHostError ); minmax_diff = max - min; if( framesPerHostBuffer < min ) { PA_DEBUG(( "%s: The determined period size (%lu) is less than minimum (%lu)\n", __FUNCTION__, framesPerHostBuffer, min )); framesPerHostBuffer = ((minmax_diff == 2) ? min + 1 : min); } else if( framesPerHostBuffer > max ) { PA_DEBUG(( "%s: The determined period size (%lu) is greater than maximum (%lu)\n", __FUNCTION__, framesPerHostBuffer, max )); framesPerHostBuffer = ((minmax_diff == 2) ? max - 1 : max); } PA_DEBUG(( "%s: device period minimum = %lu\n", __FUNCTION__, min )); PA_DEBUG(( "%s: device period maximum = %lu\n", __FUNCTION__, max )); PA_DEBUG(( "%s: host buffer period = %lu\n", __FUNCTION__, framesPerHostBuffer )); PA_DEBUG(( "%s: host buffer period latency = %f\n", __FUNCTION__, (double)(framesPerHostBuffer / sampleRate) )); /* Try setting period size */ dir = 0; ENSURE_( alsa_snd_pcm_hw_params_set_period_size_near( self->pcm, hwParams, &framesPerHostBuffer, &dir ), paUnanticipatedHostError ); if( dir != 0 ) { PA_DEBUG(( "%s: The configured period size is non-integer.\n", __FUNCTION__, dir )); *accurate = 0; } } /* Set result */ self->framesPerBuffer = framesPerHostBuffer; error: return result; } /* We need to determine how many frames per host buffer (period) to use. Our * goals are to provide the best possible performance, but also to * honor the requested latency settings as closely as we can. Therefore this * decision is based on: * * - the period sizes that playback and/or capture support. The * host buffer size has to be one of these. * - the number of periods that playback and/or capture support. * * We want to make period_size*(num_periods-1) to be as close as possible * to latency*rate for both playback and capture. * * This method will determine suitable period sizes for capture and playback handles, and report the maximum number of * frames per host buffer. The latter is relevant, in case we should be so unfortunate that the period size differs * between capture and playback. If this should happen, the stream's hostBufferSizeMode attribute will be set to * paUtilBoundedHostBufferSize, because the best we can do is limit the size of individual host buffers to the upper * bound. The size of host buffers scheduled for processing should only matter if the user has specified a buffer size, * but when he/she does we must strive for an optimal configuration. By default we'll opt for a fixed host buffer size, * which should be fine if the period size is the same for capture and playback. In general, if there is a specified user * buffer size, this method tries it best to determine a period size which is a multiple of the user buffer size. * * The framesPerBuffer attributes of the individual capture and playback components of the stream are set to corresponding * values determined here. Since these should be reported as * * This is one of those blocks of code that will just take a lot of * refinement to be any good. * * In the full-duplex case it is possible that the routine was unable * to find a number of frames per buffer acceptable to both devices * TODO: Implement an algorithm to find the value closest to acceptance * by both devices, to minimize difference between period sizes? * * @param determinedFramesPerHostBuffer: The determined host buffer size. */ static PaError PaAlsaStream_DetermineFramesPerBuffer( PaAlsaStream* self, double sampleRate, const PaStreamParameters* inputParameters, const PaStreamParameters* outputParameters, unsigned long framesPerUserBuffer, snd_pcm_hw_params_t* hwParamsCapture, snd_pcm_hw_params_t* hwParamsPlayback, PaUtilHostBufferSizeMode* hostBufferSizeMode ) { PaError result = paNoError; unsigned long framesPerHostBuffer = 0; int dir = 0; int accurate = 1; unsigned numPeriods = numPeriods_; if( self->capture.pcm && self->playback.pcm ) { if( framesPerUserBuffer == paFramesPerBufferUnspecified ) { /* Come up with a common desired latency */ snd_pcm_uframes_t desiredBufSz, e, minPeriodSize, maxPeriodSize, optimalPeriodSize, periodSize, minCapture, minPlayback, maxCapture, maxPlayback; dir = 0; ENSURE_( alsa_snd_pcm_hw_params_get_period_size_min( hwParamsCapture, &minCapture, &dir ), paUnanticipatedHostError ); dir = 0; ENSURE_( alsa_snd_pcm_hw_params_get_period_size_min( hwParamsPlayback, &minPlayback, &dir ), paUnanticipatedHostError ); dir = 0; ENSURE_( alsa_snd_pcm_hw_params_get_period_size_max( hwParamsCapture, &maxCapture, &dir ), paUnanticipatedHostError ); dir = 0; ENSURE_( alsa_snd_pcm_hw_params_get_period_size_max( hwParamsPlayback, &maxPlayback, &dir ), paUnanticipatedHostError ); minPeriodSize = PA_MAX( minPlayback, minCapture ); maxPeriodSize = PA_MIN( maxPlayback, maxCapture ); PA_UNLESS( minPeriodSize <= maxPeriodSize, paBadIODeviceCombination ); desiredBufSz = (snd_pcm_uframes_t)(PA_MIN( outputParameters->suggestedLatency, inputParameters->suggestedLatency ) * sampleRate); /* Clamp desiredBufSz */ { snd_pcm_uframes_t maxBufferSize; snd_pcm_uframes_t maxBufferSizeCapture, maxBufferSizePlayback; ENSURE_( alsa_snd_pcm_hw_params_get_buffer_size_max( hwParamsCapture, &maxBufferSizeCapture ), paUnanticipatedHostError ); ENSURE_( alsa_snd_pcm_hw_params_get_buffer_size_max( hwParamsPlayback, &maxBufferSizePlayback ), paUnanticipatedHostError ); maxBufferSize = PA_MIN( maxBufferSizeCapture, maxBufferSizePlayback ); desiredBufSz = PA_MIN( desiredBufSz, maxBufferSize ); } /* Find the closest power of 2 */ e = ilogb( minPeriodSize ); if( minPeriodSize & (minPeriodSize - 1) ) e += 1; periodSize = (snd_pcm_uframes_t)pow( 2, e ); while( periodSize <= maxPeriodSize ) { if( alsa_snd_pcm_hw_params_test_period_size( self->playback.pcm, hwParamsPlayback, periodSize, 0 ) >= 0 && alsa_snd_pcm_hw_params_test_period_size( self->capture.pcm, hwParamsCapture, periodSize, 0 ) >= 0 ) { /* OK! */ break; } periodSize *= 2; } optimalPeriodSize = PA_MAX( desiredBufSz / numPeriods, minPeriodSize ); optimalPeriodSize = PA_MIN( optimalPeriodSize, maxPeriodSize ); /* Find the closest power of 2 */ e = ilogb( optimalPeriodSize ); if( optimalPeriodSize & (optimalPeriodSize - 1) ) e += 1; optimalPeriodSize = (snd_pcm_uframes_t)pow( 2, e ); while( optimalPeriodSize >= periodSize ) { if( alsa_snd_pcm_hw_params_test_period_size( self->capture.pcm, hwParamsCapture, optimalPeriodSize, 0 ) >= 0 && alsa_snd_pcm_hw_params_test_period_size( self->playback.pcm, hwParamsPlayback, optimalPeriodSize, 0 ) >= 0 ) { break; } optimalPeriodSize /= 2; } if( optimalPeriodSize > periodSize ) periodSize = optimalPeriodSize; if( periodSize <= maxPeriodSize ) { /* Looks good, the periodSize _should_ be acceptable by both devices */ ENSURE_( alsa_snd_pcm_hw_params_set_period_size( self->capture.pcm, hwParamsCapture, periodSize, 0 ), paUnanticipatedHostError ); ENSURE_( alsa_snd_pcm_hw_params_set_period_size( self->playback.pcm, hwParamsPlayback, periodSize, 0 ), paUnanticipatedHostError ); self->capture.framesPerBuffer = self->playback.framesPerBuffer = periodSize; framesPerHostBuffer = periodSize; } else { /* Unable to find a common period size, oh well */ optimalPeriodSize = PA_MAX( desiredBufSz / numPeriods, minPeriodSize ); optimalPeriodSize = PA_MIN( optimalPeriodSize, maxPeriodSize ); self->capture.framesPerBuffer = optimalPeriodSize; dir = 0; ENSURE_( alsa_snd_pcm_hw_params_set_period_size_near( self->capture.pcm, hwParamsCapture, &self->capture.framesPerBuffer, &dir ), paUnanticipatedHostError ); self->playback.framesPerBuffer = optimalPeriodSize; dir = 0; ENSURE_( alsa_snd_pcm_hw_params_set_period_size_near( self->playback.pcm, hwParamsPlayback, &self->playback.framesPerBuffer, &dir ), paUnanticipatedHostError ); framesPerHostBuffer = PA_MAX( self->capture.framesPerBuffer, self->playback.framesPerBuffer ); *hostBufferSizeMode = paUtilBoundedHostBufferSize; } } else { /* We choose the simple route and determine a suitable number of frames per buffer for one component of * the stream, then we hope that this will work for the other component too (it should!). */ unsigned maxPeriods = 0; PaAlsaStreamComponent* first = &self->capture, * second = &self->playback; const PaStreamParameters* firstStreamParams = inputParameters; snd_pcm_hw_params_t* firstHwParams = hwParamsCapture, * secondHwParams = hwParamsPlayback; dir = 0; ENSURE_( alsa_snd_pcm_hw_params_get_periods_max( hwParamsPlayback, &maxPeriods, &dir ), paUnanticipatedHostError ); if( maxPeriods < numPeriods ) { /* The playback component is trickier to get right, try that first */ first = &self->playback; second = &self->capture; firstStreamParams = outputParameters; firstHwParams = hwParamsPlayback; secondHwParams = hwParamsCapture; } PA_ENSURE( PaAlsaStreamComponent_DetermineFramesPerBuffer( first, firstStreamParams, framesPerUserBuffer, sampleRate, firstHwParams, &accurate ) ); second->framesPerBuffer = first->framesPerBuffer; dir = 0; ENSURE_( alsa_snd_pcm_hw_params_set_period_size_near( second->pcm, secondHwParams, &second->framesPerBuffer, &dir ), paUnanticipatedHostError ); if( self->capture.framesPerBuffer == self->playback.framesPerBuffer ) { framesPerHostBuffer = self->capture.framesPerBuffer; } else { framesPerHostBuffer = PA_MAX( self->capture.framesPerBuffer, self->playback.framesPerBuffer ); *hostBufferSizeMode = paUtilBoundedHostBufferSize; } } } else /* half-duplex is a slightly simpler case */ { if( self->capture.pcm ) { PA_ENSURE( PaAlsaStreamComponent_DetermineFramesPerBuffer( &self->capture, inputParameters, framesPerUserBuffer, sampleRate, hwParamsCapture, &accurate) ); framesPerHostBuffer = self->capture.framesPerBuffer; } else { assert( self->playback.pcm ); PA_ENSURE( PaAlsaStreamComponent_DetermineFramesPerBuffer( &self->playback, outputParameters, framesPerUserBuffer, sampleRate, hwParamsPlayback, &accurate ) ); framesPerHostBuffer = self->playback.framesPerBuffer; } } PA_UNLESS( framesPerHostBuffer != 0, paInternalError ); self->maxFramesPerHostBuffer = framesPerHostBuffer; if( !self->playback.canMmap || !accurate ) { /* Don't know the exact size per host buffer */ *hostBufferSizeMode = paUtilBoundedHostBufferSize; /* Raise upper bound */ if( !accurate ) ++self->maxFramesPerHostBuffer; } error: return result; } /** Set up ALSA stream parameters. * */ static PaError PaAlsaStream_Configure( PaAlsaStream *self, const PaStreamParameters *inParams, const PaStreamParameters* outParams, double sampleRate, unsigned long framesPerUserBuffer, double* inputLatency, double* outputLatency, PaUtilHostBufferSizeMode* hostBufferSizeMode ) { PaError result = paNoError; double realSr = sampleRate; snd_pcm_hw_params_t* hwParamsCapture, * hwParamsPlayback; alsa_snd_pcm_hw_params_alloca( &hwParamsCapture ); alsa_snd_pcm_hw_params_alloca( &hwParamsPlayback ); if( self->capture.pcm ) PA_ENSURE( PaAlsaStreamComponent_InitialConfigure( &self->capture, inParams, self->primeBuffers, hwParamsCapture, &realSr ) ); if( self->playback.pcm ) PA_ENSURE( PaAlsaStreamComponent_InitialConfigure( &self->playback, outParams, self->primeBuffers, hwParamsPlayback, &realSr ) ); PA_ENSURE( PaAlsaStream_DetermineFramesPerBuffer( self, realSr, inParams, outParams, framesPerUserBuffer, hwParamsCapture, hwParamsPlayback, hostBufferSizeMode ) ); if( self->capture.pcm ) { assert( self->capture.framesPerBuffer != 0 ); PA_ENSURE( PaAlsaStreamComponent_FinishConfigure( &self->capture, hwParamsCapture, inParams, self->primeBuffers, realSr, inputLatency ) ); PA_DEBUG(( "%s: Capture period size: %lu, latency: %f\n", __FUNCTION__, self->capture.framesPerBuffer, *inputLatency )); } if( self->playback.pcm ) { assert( self->playback.framesPerBuffer != 0 ); PA_ENSURE( PaAlsaStreamComponent_FinishConfigure( &self->playback, hwParamsPlayback, outParams, self->primeBuffers, realSr, outputLatency ) ); PA_DEBUG(( "%s: Playback period size: %lu, latency: %f\n", __FUNCTION__, self->playback.framesPerBuffer, *outputLatency )); } /* Should be exact now */ self->streamRepresentation.streamInfo.sampleRate = realSr; /* this will cause the two streams to automatically start/stop/prepare in sync. * We only need to execute these operations on one of the pair. * A: We don't want to do this on a blocking stream. */ if( self->callbackMode && self->capture.pcm && self->playback.pcm ) { int err = alsa_snd_pcm_link( self->capture.pcm, self->playback.pcm ); if( err == 0 ) self->pcmsSynced = 1; else PA_DEBUG(( "%s: Unable to sync pcms: %s\n", __FUNCTION__, alsa_snd_strerror( err ) )); } { unsigned long minFramesPerHostBuffer = PA_MIN( self->capture.pcm ? self->capture.framesPerBuffer : ULONG_MAX, self->playback.pcm ? self->playback.framesPerBuffer : ULONG_MAX ); self->pollTimeout = CalculatePollTimeout( self, minFramesPerHostBuffer ); /* Period in msecs, rounded up */ /* Time before watchdog unthrottles realtime thread == 1/4 of period time in msecs */ /* self->threading.throttledSleepTime = (unsigned long) (minFramesPerHostBuffer / sampleRate / 4 * 1000); */ } if( self->callbackMode ) { /* If the user expects a certain number of frames per callback we will either have to rely on block adaption * (framesPerHostBuffer is not an integer multiple of framesPerBuffer) or we can simply align the number * of host buffer frames with what the user specified */ if( self->framesPerUserBuffer != paFramesPerBufferUnspecified ) { /* self->alignFrames = 1; */ /* Unless the ratio between number of host and user buffer frames is an integer we will have to rely * on block adaption */ /* if( framesPerHostBuffer % framesPerBuffer != 0 || (self->capture.pcm && self->playback.pcm && self->capture.framesPerBuffer != self->playback.framesPerBuffer) ) self->useBlockAdaption = 1; else self->alignFrames = 1; */ } } error: return result; } static PaError OpenStream( struct PaUtilHostApiRepresentation *hostApi, PaStream** s, const PaStreamParameters *inputParameters, const PaStreamParameters *outputParameters, double sampleRate, unsigned long framesPerBuffer, PaStreamFlags streamFlags, PaStreamCallback* callback, void *userData ) { PaError result = paNoError; PaAlsaHostApiRepresentation *alsaHostApi = (PaAlsaHostApiRepresentation*)hostApi; PaAlsaStream *stream = NULL; PaSampleFormat hostInputSampleFormat = 0, hostOutputSampleFormat = 0; PaSampleFormat inputSampleFormat = 0, outputSampleFormat = 0; int numInputChannels = 0, numOutputChannels = 0; PaTime inputLatency, outputLatency; /* Operate with fixed host buffer size by default, since other modes will invariably lead to block adaption */ /* XXX: Use Bounded by default? Output tends to get stuttery with Fixed ... */ PaUtilHostBufferSizeMode hostBufferSizeMode = paUtilFixedHostBufferSize; if( (streamFlags & paPlatformSpecificFlags) != 0 ) return paInvalidFlag; if( inputParameters ) { PA_ENSURE( ValidateParameters( inputParameters, hostApi, StreamDirection_In ) ); numInputChannels = inputParameters->channelCount; inputSampleFormat = inputParameters->sampleFormat; } if( outputParameters ) { PA_ENSURE( ValidateParameters( outputParameters, hostApi, StreamDirection_Out ) ); numOutputChannels = outputParameters->channelCount; outputSampleFormat = outputParameters->sampleFormat; } /* XXX: Why do we support this anyway? */ if( framesPerBuffer == paFramesPerBufferUnspecified && getenv( "PA_ALSA_PERIODSIZE" ) != NULL ) { PA_DEBUG(( "%s: Getting framesPerBuffer from environment\n", __FUNCTION__ )); framesPerBuffer = atoi( getenv("PA_ALSA_PERIODSIZE") ); } PA_UNLESS( stream = (PaAlsaStream*)PaUtil_AllocateMemory( sizeof(PaAlsaStream) ), paInsufficientMemory ); PA_ENSURE( PaAlsaStream_Initialize( stream, alsaHostApi, inputParameters, outputParameters, sampleRate, framesPerBuffer, callback, streamFlags, userData ) ); PA_ENSURE( PaAlsaStream_Configure( stream, inputParameters, outputParameters, sampleRate, framesPerBuffer, &inputLatency, &outputLatency, &hostBufferSizeMode ) ); hostInputSampleFormat = stream->capture.hostSampleFormat | (!stream->capture.hostInterleaved ? paNonInterleaved : 0); hostOutputSampleFormat = stream->playback.hostSampleFormat | (!stream->playback.hostInterleaved ? paNonInterleaved : 0); PA_ENSURE( PaUtil_InitializeBufferProcessor( &stream->bufferProcessor, numInputChannels, inputSampleFormat, hostInputSampleFormat, numOutputChannels, outputSampleFormat, hostOutputSampleFormat, sampleRate, streamFlags, framesPerBuffer, stream->maxFramesPerHostBuffer, hostBufferSizeMode, callback, userData ) ); /* Some drivers may work only in Big-Endian format (example: Audio4DJ), check it and replace original converter with Alsa specific with swapping capability. */ CheckAndReplaceConverterForSwapping( stream ); /* Ok, buffer processor is initialized, now we can deduce it's latency */ if( numInputChannels > 0 ) stream->streamRepresentation.streamInfo.inputLatency = inputLatency + (PaTime)( PaUtil_GetBufferProcessorInputLatencyFrames( &stream->bufferProcessor ) / sampleRate); if( numOutputChannels > 0 ) stream->streamRepresentation.streamInfo.outputLatency = outputLatency + (PaTime)( PaUtil_GetBufferProcessorOutputLatencyFrames( &stream->bufferProcessor ) / sampleRate); PA_DEBUG(( "%s: Stream: framesPerBuffer = %lu, maxFramesPerHostBuffer = %lu, latency = i(%f)/o(%f), \n", __FUNCTION__, framesPerBuffer, stream->maxFramesPerHostBuffer, stream->streamRepresentation.streamInfo.inputLatency, stream->streamRepresentation.streamInfo.outputLatency)); *s = (PaStream*)stream; return result; error: if( stream ) { PA_DEBUG(( "%s: Stream in error, terminating\n", __FUNCTION__ )); PaAlsaStream_Terminate( stream ); } return result; } static PaError CloseStream( PaStream* s ) { PaError result = paNoError; PaAlsaStream *stream = (PaAlsaStream*)s; PaUtil_TerminateBufferProcessor( &stream->bufferProcessor ); PaUtil_TerminateStreamRepresentation( &stream->streamRepresentation ); PaAlsaStream_Terminate( stream ); return result; } static void SilenceBuffer( PaAlsaStream *stream ) { const snd_pcm_channel_area_t *areas; snd_pcm_uframes_t frames = (snd_pcm_uframes_t)alsa_snd_pcm_avail_update( stream->playback.pcm ), offset; alsa_snd_pcm_mmap_begin( stream->playback.pcm, &areas, &offset, &frames ); alsa_snd_pcm_areas_silence( areas, offset, stream->playback.numHostChannels, frames, stream->playback.nativeFormat ); alsa_snd_pcm_mmap_commit( stream->playback.pcm, offset, frames ); } /** Start/prepare pcm(s) for streaming. * * Depending on wether the stream is in callback or blocking mode, we will respectively start or simply * prepare the playback pcm. If the buffer has _not_ been primed, we will in callback mode prepare and * silence the buffer before starting playback. In blocking mode we simply prepare, as the playback will * be started automatically as the user writes to output. * * The capture pcm, however, will simply be prepared and started. */ static PaError AlsaStart( PaAlsaStream *stream, int priming ) { PaError result = paNoError; if( stream->playback.pcm ) { if( stream->callbackMode ) { if( !priming ) { /* Buffer isn't primed, so prepare and silence */ ENSURE_( alsa_snd_pcm_prepare( stream->playback.pcm ), paUnanticipatedHostError ); if( stream->playback.canMmap ) SilenceBuffer( stream ); } if( stream->playback.canMmap ) ENSURE_( alsa_snd_pcm_start( stream->playback.pcm ), paUnanticipatedHostError ); } else ENSURE_( alsa_snd_pcm_prepare( stream->playback.pcm ), paUnanticipatedHostError ); } if( stream->capture.pcm && !stream->pcmsSynced ) { ENSURE_( alsa_snd_pcm_prepare( stream->capture.pcm ), paUnanticipatedHostError ); /* For a blocking stream we want to start capture as well, since nothing will happen otherwise */ ENSURE_( alsa_snd_pcm_start( stream->capture.pcm ), paUnanticipatedHostError ); } end: return result; error: goto end; } /** Utility function for determining if pcms are in running state. * */ #if 0 static int IsRunning( PaAlsaStream *stream ) { int result = 0; PA_ENSURE( PaUnixMutex_Lock( &stream->stateMtx ) ); if( stream->capture.pcm ) { snd_pcm_state_t capture_state = alsa_snd_pcm_state( stream->capture.pcm ); if( capture_state == SND_PCM_STATE_RUNNING || capture_state == SND_PCM_STATE_XRUN || capture_state == SND_PCM_STATE_DRAINING ) { result = 1; goto end; } } if( stream->playback.pcm ) { snd_pcm_state_t playback_state = alsa_snd_pcm_state( stream->playback.pcm ); if( playback_state == SND_PCM_STATE_RUNNING || playback_state == SND_PCM_STATE_XRUN || playback_state == SND_PCM_STATE_DRAINING ) { result = 1; goto end; } } end: ASSERT_CALL_( PaUnixMutex_Unlock( &stream->stateMtx ), paNoError ); return result; error: goto error; } #endif static PaError StartStream( PaStream *s ) { PaError result = paNoError; PaAlsaStream* stream = (PaAlsaStream*)s; int streamStarted = 0; /* So we can know wether we need to take the stream down */ /* Ready the processor */ PaUtil_ResetBufferProcessor( &stream->bufferProcessor ); /* Set now, so we can test for activity further down */ stream->isActive = 1; if( stream->callbackMode ) { PA_ENSURE( PaUnixThread_New( &stream->thread, &CallbackThreadFunc, stream, 1., stream->rtSched ) ); } else { PA_ENSURE( AlsaStart( stream, 0 ) ); streamStarted = 1; } end: return result; error: if( streamStarted ) { AbortStream( stream ); } stream->isActive = 0; goto end; } /** Stop PCM handle, either softly or abruptly. */ static PaError AlsaStop( PaAlsaStream *stream, int abort ) { PaError result = paNoError; /* XXX: alsa_snd_pcm_drain tends to lock up, avoid it until we find out more */ abort = 1; /* if( stream->capture.pcm && !strcmp( Pa_GetDeviceInfo( stream->capture.device )->name, "dmix" ) ) { abort = 1; } else if( stream->playback.pcm && !strcmp( Pa_GetDeviceInfo( stream->playback.device )->name, "dmix" ) ) { abort = 1; } */ if( abort ) { if( stream->playback.pcm ) { ENSURE_( alsa_snd_pcm_drop( stream->playback.pcm ), paUnanticipatedHostError ); } if( stream->capture.pcm && !stream->pcmsSynced ) { ENSURE_( alsa_snd_pcm_drop( stream->capture.pcm ), paUnanticipatedHostError ); } PA_DEBUG(( "%s: Dropped frames\n", __FUNCTION__ )); } else { if( stream->playback.pcm ) { ENSURE_( alsa_snd_pcm_nonblock( stream->playback.pcm, 0 ), paUnanticipatedHostError ); if( alsa_snd_pcm_drain( stream->playback.pcm ) < 0 ) { PA_DEBUG(( "%s: Draining playback handle failed!\n", __FUNCTION__ )); } } if( stream->capture.pcm && !stream->pcmsSynced ) { /* We don't need to retrieve any remaining frames */ if( alsa_snd_pcm_drain( stream->capture.pcm ) < 0 ) { PA_DEBUG(( "%s: Draining capture handle failed!\n", __FUNCTION__ )); } } } end: return result; error: goto end; } /** Stop or abort stream. * * If a stream is in callback mode we will have to inspect wether the background thread has * finished, or we will have to take it out. In either case we join the thread before * returning. In blocking mode, we simply tell ALSA to stop abruptly (abort) or finish * buffers (drain) * * Stream will be considered inactive (!PaAlsaStream::isActive) after a call to this function */ static PaError RealStop( PaAlsaStream *stream, int abort ) { PaError result = paNoError; /* First deal with the callback thread, cancelling and/or joining * it if necessary */ if( stream->callbackMode ) { PaError threadRes; stream->callbackAbort = abort; if( !abort ) { PA_DEBUG(( "Stopping callback\n" )); } PA_ENSURE( PaUnixThread_Terminate( &stream->thread, !abort, &threadRes ) ); if( threadRes != paNoError ) { PA_DEBUG(( "Callback thread returned: %d\n", threadRes )); } #if 0 if( watchdogRes != paNoError ) PA_DEBUG(( "Watchdog thread returned: %d\n", watchdogRes )); #endif stream->callback_finished = 0; } else { PA_ENSURE( AlsaStop( stream, abort ) ); } stream->isActive = 0; end: return result; error: goto end; } static PaError StopStream( PaStream *s ) { return RealStop( (PaAlsaStream *) s, 0 ); } static PaError AbortStream( PaStream *s ) { return RealStop( (PaAlsaStream * ) s, 1 ); } /** The stream is considered stopped before StartStream, or AFTER a call to Abort/StopStream (callback * returning !paContinue is not considered) * */ static PaError IsStreamStopped( PaStream *s ) { PaAlsaStream *stream = (PaAlsaStream *)s; /* callback_finished indicates we need to join callback thread (ie. in Abort/StopStream) */ return !IsStreamActive( s ) && !stream->callback_finished; } static PaError IsStreamActive( PaStream *s ) { PaAlsaStream *stream = (PaAlsaStream*)s; return stream->isActive; } static PaTime GetStreamTime( PaStream *s ) { PaAlsaStream *stream = (PaAlsaStream*)s; snd_timestamp_t timestamp; snd_pcm_status_t* status; alsa_snd_pcm_status_alloca( &status ); /* TODO: what if we have both? does it really matter? */ /* TODO: if running in callback mode, this will mean * libasound routines are being called from multiple threads. * need to verify that libasound is thread-safe. */ if( stream->capture.pcm ) { alsa_snd_pcm_status( stream->capture.pcm, status ); } else if( stream->playback.pcm ) { alsa_snd_pcm_status( stream->playback.pcm, status ); } alsa_snd_pcm_status_get_tstamp( status, ×tamp ); return timestamp.tv_sec + (PaTime)timestamp.tv_usec / 1e6; } static double GetStreamCpuLoad( PaStream* s ) { PaAlsaStream *stream = (PaAlsaStream*)s; return PaUtil_GetCpuLoad( &stream->cpuLoadMeasurer ); } static int SetApproximateSampleRate( snd_pcm_t *pcm, snd_pcm_hw_params_t *hwParams, double sampleRate ) { PaError result = paNoError; unsigned long approx = (unsigned long) sampleRate; int dir = 0; double fraction = sampleRate - approx; assert( pcm && hwParams ); if( fraction > 0.0 ) { if( fraction > 0.5 ) { ++approx; dir = -1; } else dir = 1; } if( alsa_snd_pcm_hw_params_set_rate( pcm, hwParams, approx, dir ) < 0) result = paInvalidSampleRate; end: return result; error: /* Log */ { unsigned int _min = 0, _max = 0; int _dir = 0; ENSURE_( alsa_snd_pcm_hw_params_get_rate_min( hwParams, &_min, &_dir ), paUnanticipatedHostError ); ENSURE_( alsa_snd_pcm_hw_params_get_rate_max( hwParams, &_max, &_dir ), paUnanticipatedHostError ); PA_DEBUG(( "%s: SR min = %d, max = %d, req = %lu\n", __FUNCTION__, _min, _max, approx )); } goto end; } /* Return exact sample rate in param sampleRate */ static int GetExactSampleRate( snd_pcm_hw_params_t *hwParams, double *sampleRate ) { unsigned int num, den; int err; assert( hwParams ); err = alsa_snd_pcm_hw_params_get_rate_numden( hwParams, &num, &den ); *sampleRate = (double) num / den; return err; } /* Utility functions for blocking/callback interfaces */ /* Atomic restart of stream (we don't want the intermediate state visible) */ static PaError AlsaRestart( PaAlsaStream *stream ) { PaError result = paNoError; PA_ENSURE( PaUnixMutex_Lock( &stream->stateMtx ) ); PA_ENSURE( AlsaStop( stream, 0 ) ); PA_ENSURE( AlsaStart( stream, 0 ) ); PA_DEBUG(( "%s: Restarted audio\n", __FUNCTION__ )); error: PA_ENSURE( PaUnixMutex_Unlock( &stream->stateMtx ) ); return result; } /** Recover from xrun state. * */ static PaError PaAlsaStream_HandleXrun( PaAlsaStream *self ) { PaError result = paNoError; snd_pcm_status_t *st; PaTime now = PaUtil_GetTime(); snd_timestamp_t t; int restartAlsa = 0; /* do not restart Alsa by default */ alsa_snd_pcm_status_alloca( &st ); if( self->playback.pcm ) { alsa_snd_pcm_status( self->playback.pcm, st ); if( alsa_snd_pcm_status_get_state( st ) == SND_PCM_STATE_XRUN ) { alsa_snd_pcm_status_get_trigger_tstamp( st, &t ); self->underrun = now * 1000 - ((PaTime) t.tv_sec * 1000 + (PaTime) t.tv_usec / 1000); if (!self->playback.canMmap) { if (alsa_snd_pcm_recover( self->playback.pcm, -EPIPE, 0 ) < 0) { PA_DEBUG(( "%s: [playback] non-MMAP-PCM failed recovering from XRUN, will restart Alsa\n", __FUNCTION__ )); ++ restartAlsa; /* did not manage to recover */ } } else ++ restartAlsa; /* always restart MMAPed device */ } } if( self->capture.pcm ) { alsa_snd_pcm_status( self->capture.pcm, st ); if( alsa_snd_pcm_status_get_state( st ) == SND_PCM_STATE_XRUN ) { alsa_snd_pcm_status_get_trigger_tstamp( st, &t ); self->overrun = now * 1000 - ((PaTime) t.tv_sec * 1000 + (PaTime) t.tv_usec / 1000); if (!self->capture.canMmap) { if (alsa_snd_pcm_recover( self->capture.pcm, -EPIPE, 0 ) < 0) { PA_DEBUG(( "%s: [capture] non-MMAP-PCM failed recovering from XRUN, will restart Alsa\n", __FUNCTION__ )); ++ restartAlsa; /* did not manage to recover */ } } else ++ restartAlsa; /* always restart MMAPed device */ } } if( restartAlsa ) { PA_DEBUG(( "%s: restarting Alsa to recover from XRUN\n", __FUNCTION__ )); PA_ENSURE( AlsaRestart( self ) ); } end: return result; error: goto end; } /** Decide if we should continue polling for specified direction, eventually adjust the poll timeout. * */ static PaError ContinuePoll( const PaAlsaStream *stream, StreamDirection streamDir, int *pollTimeout, int *continuePoll ) { PaError result = paNoError; snd_pcm_sframes_t delay, margin; int err; const PaAlsaStreamComponent *component = NULL, *otherComponent = NULL; *continuePoll = 1; if( StreamDirection_In == streamDir ) { component = &stream->capture; otherComponent = &stream->playback; } else { component = &stream->playback; otherComponent = &stream->capture; } /* ALSA docs say that negative delay should indicate xrun, but in my experience alsa_snd_pcm_delay returns -EPIPE */ if( (err = alsa_snd_pcm_delay( otherComponent->pcm, &delay )) < 0 ) { if( err == -EPIPE ) { /* Xrun */ *continuePoll = 0; goto error; } ENSURE_( err, paUnanticipatedHostError ); } if( StreamDirection_Out == streamDir ) { /* Number of eligible frames before capture overrun */ delay = otherComponent->bufferSize - delay; } margin = delay - otherComponent->framesPerBuffer / 2; if( margin < 0 ) { PA_DEBUG(( "%s: Stopping poll for %s\n", __FUNCTION__, StreamDirection_In == streamDir ? "capture" : "playback" )); *continuePoll = 0; } else if( margin < otherComponent->framesPerBuffer ) { *pollTimeout = CalculatePollTimeout( stream, margin ); PA_DEBUG(( "%s: Trying to poll again for %s frames, pollTimeout: %d\n", __FUNCTION__, StreamDirection_In == streamDir ? "capture" : "playback", *pollTimeout )); } error: return result; } /* Callback interface */ static void OnExit( void *data ) { PaAlsaStream *stream = (PaAlsaStream *) data; assert( data ); PaUtil_ResetCpuLoadMeasurer( &stream->cpuLoadMeasurer ); stream->callback_finished = 1; /* Let the outside world know stream was stopped in callback */ PA_DEBUG(( "%s: Stopping ALSA handles\n", __FUNCTION__ )); AlsaStop( stream, stream->callbackAbort ); PA_DEBUG(( "%s: Stoppage\n", __FUNCTION__ )); /* Eventually notify user all buffers have played */ if( stream->streamRepresentation.streamFinishedCallback ) { stream->streamRepresentation.streamFinishedCallback( stream->streamRepresentation.userData ); } stream->isActive = 0; } static void CalculateTimeInfo( PaAlsaStream *stream, PaStreamCallbackTimeInfo *timeInfo ) { snd_pcm_status_t *capture_status, *playback_status; snd_timestamp_t capture_timestamp, playback_timestamp; PaTime capture_time = 0., playback_time = 0.; alsa_snd_pcm_status_alloca( &capture_status ); alsa_snd_pcm_status_alloca( &playback_status ); if( stream->capture.pcm ) { snd_pcm_sframes_t capture_delay; alsa_snd_pcm_status( stream->capture.pcm, capture_status ); alsa_snd_pcm_status_get_tstamp( capture_status, &capture_timestamp ); capture_time = capture_timestamp.tv_sec + ((PaTime)capture_timestamp.tv_usec / 1000000.0); timeInfo->currentTime = capture_time; capture_delay = alsa_snd_pcm_status_get_delay( capture_status ); timeInfo->inputBufferAdcTime = timeInfo->currentTime - (PaTime)capture_delay / stream->streamRepresentation.streamInfo.sampleRate; } if( stream->playback.pcm ) { snd_pcm_sframes_t playback_delay; alsa_snd_pcm_status( stream->playback.pcm, playback_status ); alsa_snd_pcm_status_get_tstamp( playback_status, &playback_timestamp ); playback_time = playback_timestamp.tv_sec + ((PaTime)playback_timestamp.tv_usec / 1000000.0); if( stream->capture.pcm ) /* Full duplex */ { /* Hmm, we have both a playback and a capture timestamp. * Hopefully they are the same... */ if( fabs( capture_time - playback_time ) > 0.01 ) PA_DEBUG(("Capture time and playback time differ by %f\n", fabs(capture_time-playback_time))); } else timeInfo->currentTime = playback_time; playback_delay = alsa_snd_pcm_status_get_delay( playback_status ); timeInfo->outputBufferDacTime = timeInfo->currentTime + (PaTime)playback_delay / stream->streamRepresentation.streamInfo.sampleRate; } } /** Called after buffer processing is finished. * * A number of mmapped frames is committed, it is possible that an xrun has occurred in the meantime. * * @param numFrames The number of frames that has been processed * @param xrun Return whether an xrun has occurred */ static PaError PaAlsaStreamComponent_EndProcessing( PaAlsaStreamComponent *self, unsigned long numFrames, int *xrun ) { PaError result = paNoError; int res = 0; /* @concern FullDuplex It is possible that only one direction is marked ready after polling, and processed * afterwards */ if( !self->ready ) goto end; if( !self->canMmap && StreamDirection_Out == self->streamDir ) { /* Play sound */ if( self->hostInterleaved ) res = alsa_snd_pcm_writei( self->pcm, self->nonMmapBuffer, numFrames ); else { void *bufs[self->numHostChannels]; int bufsize = alsa_snd_pcm_format_size( self->nativeFormat, self->framesPerBuffer + 1 ); unsigned char *buffer = self->nonMmapBuffer; int i; for( i = 0; i < self->numHostChannels; ++i ) { bufs[i] = buffer; buffer += bufsize; } res = alsa_snd_pcm_writen( self->pcm, bufs, numFrames ); } } if( self->canMmap ) res = alsa_snd_pcm_mmap_commit( self->pcm, self->offset, numFrames ); else { /* using realloc for optimisation free( self->nonMmapBuffer ); self->nonMmapBuffer = NULL; */ } if( res == -EPIPE || res == -ESTRPIPE ) { *xrun = 1; } else { ENSURE_( res, paUnanticipatedHostError ); } end: error: return result; } /* Extract buffer from channel area */ static unsigned char *ExtractAddress( const snd_pcm_channel_area_t *area, snd_pcm_uframes_t offset ) { return (unsigned char *) area->addr + (area->first + offset * area->step) / 8; } /** Do necessary adaption between user and host channels. * @concern ChannelAdaption Adapting between user and host channels can involve silencing unused channels and duplicating mono information if host outputs come in pairs. */ static PaError PaAlsaStreamComponent_DoChannelAdaption( PaAlsaStreamComponent *self, PaUtilBufferProcessor *bp, int numFrames ) { PaError result = paNoError; unsigned char *p; int i; int unusedChans = self->numHostChannels - self->numUserChannels; unsigned char *src, *dst; int convertMono = (self->numHostChannels % 2) == 0 && (self->numUserChannels % 2) != 0; assert( StreamDirection_Out == self->streamDir ); if( self->hostInterleaved ) { int swidth = alsa_snd_pcm_format_size( self->nativeFormat, 1 ); unsigned char *buffer = self->canMmap ? ExtractAddress( self->channelAreas, self->offset ) : self->nonMmapBuffer; /* Start after the last user channel */ p = buffer + self->numUserChannels * swidth; if( convertMono ) { /* Convert the last user channel into stereo pair */ src = buffer + (self->numUserChannels - 1) * swidth; for( i = 0; i < numFrames; ++i ) { dst = src + swidth; memcpy( dst, src, swidth ); src += self->numHostChannels * swidth; } /* Don't touch the channel we just wrote to */ p += swidth; --unusedChans; } if( unusedChans > 0 ) { /* Silence unused output channels */ for( i = 0; i < numFrames; ++i ) { memset( p, 0, swidth * unusedChans ); p += self->numHostChannels * swidth; } } } else { /* We extract the last user channel */ if( convertMono ) { ENSURE_( alsa_snd_pcm_area_copy( self->channelAreas + self->numUserChannels, self->offset, self->channelAreas + (self->numUserChannels - 1), self->offset, numFrames, self->nativeFormat ), paUnanticipatedHostError ); --unusedChans; } if( unusedChans > 0 ) { alsa_snd_pcm_areas_silence( self->channelAreas + (self->numHostChannels - unusedChans), self->offset, unusedChans, numFrames, self->nativeFormat ); } } error: return result; } static PaError PaAlsaStream_EndProcessing( PaAlsaStream *self, unsigned long numFrames, int *xrunOccurred ) { PaError result = paNoError; int xrun = 0; if( self->capture.pcm ) { PA_ENSURE( PaAlsaStreamComponent_EndProcessing( &self->capture, numFrames, &xrun ) ); } if( self->playback.pcm ) { if( self->playback.numHostChannels > self->playback.numUserChannels ) { PA_ENSURE( PaAlsaStreamComponent_DoChannelAdaption( &self->playback, &self->bufferProcessor, numFrames ) ); } PA_ENSURE( PaAlsaStreamComponent_EndProcessing( &self->playback, numFrames, &xrun ) ); } error: *xrunOccurred = xrun; return result; } /** Update the number of available frames. * */ static PaError PaAlsaStreamComponent_GetAvailableFrames( PaAlsaStreamComponent *self, unsigned long *numFrames, int *xrunOccurred ) { PaError result = paNoError; snd_pcm_sframes_t framesAvail = alsa_snd_pcm_avail_update( self->pcm ); *xrunOccurred = 0; if( -EPIPE == framesAvail ) { *xrunOccurred = 1; framesAvail = 0; } else { ENSURE_( framesAvail, paUnanticipatedHostError ); } *numFrames = framesAvail; error: return result; } /** Fill in pollfd objects. */ static PaError PaAlsaStreamComponent_BeginPolling( PaAlsaStreamComponent* self, struct pollfd* pfds ) { PaError result = paNoError; int ret = alsa_snd_pcm_poll_descriptors( self->pcm, pfds, self->nfds ); (void)ret; /* Prevent unused variable warning if asserts are turned off */ assert( ret == self->nfds ); self->ready = 0; return result; } /** Examine results from poll(). * * @param pfds pollfds to inspect * @param shouldPoll Should we continue to poll * @param xrun Has an xrun occurred */ static PaError PaAlsaStreamComponent_EndPolling( PaAlsaStreamComponent* self, struct pollfd* pfds, int* shouldPoll, int* xrun ) { PaError result = paNoError; unsigned short revents; ENSURE_( alsa_snd_pcm_poll_descriptors_revents( self->pcm, pfds, self->nfds, &revents ), paUnanticipatedHostError ); if( revents != 0 ) { if( revents & POLLERR ) { *xrun = 1; } else if( revents & POLLHUP ) { *xrun = 1; PA_DEBUG(( "%s: revents has POLLHUP, processing as XRUN\n", __FUNCTION__ )); } else self->ready = 1; *shouldPoll = 0; } else /* (A zero revent occurred) */ /* Work around an issue with Alsa older than 1.0.16 using some plugins (eg default with plug + dmix) where * POLLIN or POLLOUT are zeroed by Alsa-lib if _mmap_avail() is a few frames short of avail_min at period * boundary, possibly due to erratic dma interrupts at period boundary? Treat as a valid event. */ if( self->useReventFix ) { self->ready = 1; *shouldPoll = 0; } error: return result; } /** Return the number of available frames for this stream. * * @concern FullDuplex The minimum available for the two directions is calculated, it might be desirable to ignore * one direction however (not marked ready from poll), so this is controlled by queryCapture and queryPlayback. * * @param queryCapture Check available for capture * @param queryPlayback Check available for playback * @param available The returned number of frames * @param xrunOccurred Return whether an xrun has occurred */ static PaError PaAlsaStream_GetAvailableFrames( PaAlsaStream *self, int queryCapture, int queryPlayback, unsigned long *available, int *xrunOccurred ) { PaError result = paNoError; unsigned long captureFrames, playbackFrames; *xrunOccurred = 0; assert( queryCapture || queryPlayback ); if( queryCapture ) { assert( self->capture.pcm ); PA_ENSURE( PaAlsaStreamComponent_GetAvailableFrames( &self->capture, &captureFrames, xrunOccurred ) ); if( *xrunOccurred ) { goto end; } } if( queryPlayback ) { assert( self->playback.pcm ); PA_ENSURE( PaAlsaStreamComponent_GetAvailableFrames( &self->playback, &playbackFrames, xrunOccurred ) ); if( *xrunOccurred ) { goto end; } } if( queryCapture && queryPlayback ) { *available = PA_MIN( captureFrames, playbackFrames ); /*PA_DEBUG(("capture: %lu, playback: %lu, combined: %lu\n", captureFrames, playbackFrames, *available));*/ } else if( queryCapture ) { *available = captureFrames; } else { *available = playbackFrames; } end: error: return result; } /** Wait for and report available buffer space from ALSA. * * Unless ALSA reports a minimum of frames available for I/O, we poll the ALSA filedescriptors for more. * Both of these operations can uncover xrun conditions. * * @concern Xruns Both polling and querying available frames can report an xrun condition. * * @param framesAvail Return the number of available frames * @param xrunOccurred Return whether an xrun has occurred */ static PaError PaAlsaStream_WaitForFrames( PaAlsaStream *self, unsigned long *framesAvail, int *xrunOccurred ) { PaError result = paNoError; int pollPlayback = self->playback.pcm != NULL, pollCapture = self->capture.pcm != NULL; int pollTimeout = self->pollTimeout; int xrun = 0, timeouts = 0; int pollResults; assert( self ); assert( framesAvail ); if( !self->callbackMode ) { /* In blocking mode we will only wait if necessary */ PA_ENSURE( PaAlsaStream_GetAvailableFrames( self, self->capture.pcm != NULL, self->playback.pcm != NULL, framesAvail, &xrun ) ); if( xrun ) { goto end; } if( *framesAvail > 0 ) { /* Mark pcms ready from poll */ if( self->capture.pcm ) self->capture.ready = 1; if( self->playback.pcm ) self->playback.ready = 1; goto end; } } while( pollPlayback || pollCapture ) { int totalFds = 0; struct pollfd *capturePfds = NULL, *playbackPfds = NULL; #ifdef PTHREAD_CANCELED pthread_testcancel(); #endif if( pollCapture ) { capturePfds = self->pfds; PA_ENSURE( PaAlsaStreamComponent_BeginPolling( &self->capture, capturePfds ) ); totalFds += self->capture.nfds; } if( pollPlayback ) { playbackPfds = self->pfds + (self->capture.pcm ? self->capture.nfds : 0); PA_ENSURE( PaAlsaStreamComponent_BeginPolling( &self->playback, playbackPfds ) ); totalFds += self->playback.nfds; } pollResults = poll( self->pfds, totalFds, pollTimeout ); if( pollResults < 0 ) { /* XXX: Depend on preprocessor condition? */ if( errno == EINTR ) { /* gdb */ Pa_Sleep( 1 ); /* avoid hot loop */ continue; } /* TODO: Add macro for checking system calls */ PA_ENSURE( paInternalError ); } else if (pollResults == 0) { /* Suspended, paused or failed device can provide 0 poll results. To avoid deadloop in such situation * we simply run counter 'timeouts' which detects 0 poll result and accumulates. As soon as 2048 timouts (around 2 seconds) * are achieved we simply fail function with paTimedOut to notify waiting methods that device is not capable * of providing audio data anymore and needs some corresponding recovery action. * Note that 'timeouts' is reset to 0 if poll() managed to return non 0 results. */ /*PA_DEBUG(( "%s: poll == 0 results, timed out, %d times left\n", __FUNCTION__, 2048 - timeouts ));*/ ++ timeouts; if (timeouts > 1) /* sometimes device times out, but normally once, so we do not sleep any time */ { Pa_Sleep( 1 ); /* avoid hot loop */ } /* not else ! */ if (timeouts >= 2048) /* audio device not working, shall return error to notify waiters */ { *framesAvail = 0; /* no frames available for processing */ xrun = 1; /* try recovering device */ PA_DEBUG(( "%s: poll timed out\n", __FUNCTION__, timeouts )); goto end;/*PA_ENSURE( paTimedOut );*/ } } else if (pollResults > 0) { /* reset timouts counter */ timeouts = 0; /* check the return status of our pfds */ if( pollCapture ) { PA_ENSURE( PaAlsaStreamComponent_EndPolling( &self->capture, capturePfds, &pollCapture, &xrun ) ); } if( pollPlayback ) { PA_ENSURE( PaAlsaStreamComponent_EndPolling( &self->playback, playbackPfds, &pollPlayback, &xrun ) ); } if( xrun ) { break; } } /* @concern FullDuplex If only one of two pcms is ready we may want to compromise between the two. * If there is less than half a period's worth of samples left of frames in the other pcm's buffer we will * stop polling. */ if( self->capture.pcm && self->playback.pcm ) { if( pollCapture && !pollPlayback ) { PA_ENSURE( ContinuePoll( self, StreamDirection_In, &pollTimeout, &pollCapture ) ); } else if( pollPlayback && !pollCapture ) { PA_ENSURE( ContinuePoll( self, StreamDirection_Out, &pollTimeout, &pollPlayback ) ); } } } if( !xrun ) { /* Get the number of available frames for the pcms that are marked ready. * @concern FullDuplex If only one direction is marked ready (from poll), the number of frames available for * the other direction is returned. Output is normally preferred over capture however, so capture frames may be * discarded to avoid overrun unless paNeverDropInput is specified. */ int captureReady = self->capture.pcm ? self->capture.ready : 0, playbackReady = self->playback.pcm ? self->playback.ready : 0; PA_ENSURE( PaAlsaStream_GetAvailableFrames( self, captureReady, playbackReady, framesAvail, &xrun ) ); if( self->capture.pcm && self->playback.pcm ) { if( !self->playback.ready && !self->neverDropInput ) { /* Drop input, a period's worth */ assert( self->capture.ready ); PaAlsaStreamComponent_EndProcessing( &self->capture, PA_MIN( self->capture.framesPerBuffer, *framesAvail ), &xrun ); *framesAvail = 0; self->capture.ready = 0; } } else if( self->capture.pcm ) assert( self->capture.ready ); else assert( self->playback.ready ); } end: error: if( xrun ) { /* Recover from the xrun state */ PA_ENSURE( PaAlsaStream_HandleXrun( self ) ); *framesAvail = 0; } else { if( 0 != *framesAvail ) { /* If we're reporting frames eligible for processing, one of the handles better be ready */ PA_UNLESS( self->capture.ready || self->playback.ready, paInternalError ); } } *xrunOccurred = xrun; return result; } /** Register per-channel ALSA buffer information with buffer processor. * * Mmapped buffer space is acquired from ALSA, and registered with the buffer processor. Differences between the * number of host and user channels is taken into account. * * @param numFrames On entrance the number of requested frames, on exit the number of contiguously accessible frames. */ static PaError PaAlsaStreamComponent_RegisterChannels( PaAlsaStreamComponent* self, PaUtilBufferProcessor* bp, unsigned long* numFrames, int* xrun ) { PaError result = paNoError; const snd_pcm_channel_area_t *areas, *area; void (*setChannel)(PaUtilBufferProcessor *, unsigned int, void *, unsigned int) = StreamDirection_In == self->streamDir ? PaUtil_SetInputChannel : PaUtil_SetOutputChannel; unsigned char *buffer, *p; int i; unsigned long framesAvail; /* This _must_ be called before mmap_begin */ PA_ENSURE( PaAlsaStreamComponent_GetAvailableFrames( self, &framesAvail, xrun ) ); if( *xrun ) { *numFrames = 0; goto end; } if( self->canMmap ) { ENSURE_( alsa_snd_pcm_mmap_begin( self->pcm, &areas, &self->offset, numFrames ), paUnanticipatedHostError ); /* @concern ChannelAdaption Buffer address is recorded so we can do some channel adaption later */ self->channelAreas = (snd_pcm_channel_area_t *)areas; } else { unsigned int bufferSize = self->numHostChannels * alsa_snd_pcm_format_size( self->nativeFormat, *numFrames ); if (bufferSize > self->nonMmapBufferSize) { self->nonMmapBuffer = realloc(self->nonMmapBuffer, (self->nonMmapBufferSize = bufferSize)); if (!self->nonMmapBuffer) { result = paInsufficientMemory; goto error; } } } if( self->hostInterleaved ) { int swidth = alsa_snd_pcm_format_size( self->nativeFormat, 1 ); p = buffer = self->canMmap ? ExtractAddress( areas, self->offset ) : self->nonMmapBuffer; for( i = 0; i < self->numUserChannels; ++i ) { /* We're setting the channels up to userChannels, but the stride will be hostChannels samples */ setChannel( bp, i, p, self->numHostChannels ); p += swidth; } } else { if( self->canMmap ) { for( i = 0; i < self->numUserChannels; ++i ) { area = areas + i; buffer = ExtractAddress( area, self->offset ); setChannel( bp, i, buffer, 1 ); } } else { unsigned int buf_per_ch_size = self->nonMmapBufferSize / self->numHostChannels; buffer = self->nonMmapBuffer; for( i = 0; i < self->numUserChannels; ++i ) { setChannel( bp, i, buffer, 1 ); buffer += buf_per_ch_size; } } } if( !self->canMmap && StreamDirection_In == self->streamDir ) { /* Read sound */ int res; if( self->hostInterleaved ) res = alsa_snd_pcm_readi( self->pcm, self->nonMmapBuffer, *numFrames ); else { void *bufs[self->numHostChannels]; unsigned int buf_per_ch_size = self->nonMmapBufferSize / self->numHostChannels; unsigned char *buffer = self->nonMmapBuffer; int i; for( i = 0; i < self->numHostChannels; ++i ) { bufs[i] = buffer; buffer += buf_per_ch_size; } res = alsa_snd_pcm_readn( self->pcm, bufs, *numFrames ); } if( res == -EPIPE || res == -ESTRPIPE ) { *xrun = 1; *numFrames = 0; } } end: error: return result; } /** Initiate buffer processing. * * ALSA buffers are registered with the PA buffer processor and the buffer size (in frames) set. * * @concern FullDuplex If both directions are being processed, the minimum amount of frames for the two directions is * calculated. * * @param numFrames On entrance the number of available frames, on exit the number of received frames * @param xrunOccurred Return whether an xrun has occurred */ static PaError PaAlsaStream_SetUpBuffers( PaAlsaStream* self, unsigned long* numFrames, int* xrunOccurred ) { PaError result = paNoError; unsigned long captureFrames = ULONG_MAX, playbackFrames = ULONG_MAX, commonFrames = 0; int xrun = 0; if( *xrunOccurred ) { *numFrames = 0; return result; } /* If we got here at least one of the pcm's should be marked ready */ PA_UNLESS( self->capture.ready || self->playback.ready, paInternalError ); /* Extract per-channel ALSA buffer pointers and register them with the buffer processor. * It is possible that a direction is not marked ready however, because it is out of sync with the other. */ if( self->capture.pcm && self->capture.ready ) { captureFrames = *numFrames; PA_ENSURE( PaAlsaStreamComponent_RegisterChannels( &self->capture, &self->bufferProcessor, &captureFrames, &xrun ) ); } if( self->playback.pcm && self->playback.ready ) { playbackFrames = *numFrames; PA_ENSURE( PaAlsaStreamComponent_RegisterChannels( &self->playback, &self->bufferProcessor, &playbackFrames, &xrun ) ); } if( xrun ) { /* Nothing more to do */ assert( 0 == commonFrames ); goto end; } commonFrames = PA_MIN( captureFrames, playbackFrames ); /* assert( commonFrames <= *numFrames ); */ if( commonFrames > *numFrames ) { /* Hmmm ... how come there are more frames available than we requested!? Blah. */ PA_DEBUG(( "%s: Common available frames are reported to be more than number requested: %lu, %lu, callbackMode: %d\n", __FUNCTION__, commonFrames, *numFrames, self->callbackMode )); if( self->capture.pcm ) { PA_DEBUG(( "%s: captureFrames: %lu, capture.ready: %d\n", __FUNCTION__, captureFrames, self->capture.ready )); } if( self->playback.pcm ) { PA_DEBUG(( "%s: playbackFrames: %lu, playback.ready: %d\n", __FUNCTION__, playbackFrames, self->playback.ready )); } commonFrames = 0; goto end; } /* Inform PortAudio of the number of frames we got. * @concern FullDuplex We might be experiencing underflow in either end; if its an input underflow, we go on * with output. If its output underflow however, depending on the paNeverDropInput flag, we may want to simply * discard the excess input or call the callback with paOutputOverflow flagged. */ if( self->capture.pcm ) { if( self->capture.ready ) { PaUtil_SetInputFrameCount( &self->bufferProcessor, commonFrames ); } else { /* We have input underflow */ PaUtil_SetNoInput( &self->bufferProcessor ); } } if( self->playback.pcm ) { if( self->playback.ready ) { PaUtil_SetOutputFrameCount( &self->bufferProcessor, commonFrames ); } else { /* We have output underflow, but keeping input data (paNeverDropInput) */ assert( self->neverDropInput ); assert( self->capture.pcm != NULL ); PA_DEBUG(( "%s: Setting output buffers to NULL\n", __FUNCTION__ )); PaUtil_SetNoOutput( &self->bufferProcessor ); } } end: *numFrames = commonFrames; error: if( xrun ) { PA_ENSURE( PaAlsaStream_HandleXrun( self ) ); *numFrames = 0; } *xrunOccurred = xrun; return result; } /** Callback thread's function. * * Roughly, the workflow can be described in the following way: The number of available frames that can be processed * directly is obtained from ALSA, we then request as much directly accessible memory as possible within this amount * from ALSA. The buffer memory is registered with the PA buffer processor and processing is carried out with * PaUtil_EndBufferProcessing. Finally, the number of processed frames is reported to ALSA. The processing can * happen in several iterations untill we have consumed the known number of available frames (or an xrun is detected). */ static void *CallbackThreadFunc( void *userData ) { PaError result = paNoError; PaAlsaStream *stream = (PaAlsaStream*) userData; PaStreamCallbackTimeInfo timeInfo = {0, 0, 0}; snd_pcm_sframes_t startThreshold = 0; int callbackResult = paContinue; PaStreamCallbackFlags cbFlags = 0; /* We might want to keep state across iterations */ int streamStarted = 0; assert( stream ); /* Execute OnExit when exiting */ pthread_cleanup_push( &OnExit, stream ); /* Not implemented */ assert( !stream->primeBuffers ); /* @concern StreamStart If the output is being primed the output pcm needs to be prepared, otherwise the * stream is started immediately. The latter involves signaling the waiting main thread. */ if( stream->primeBuffers ) { snd_pcm_sframes_t avail; if( stream->playback.pcm ) ENSURE_( alsa_snd_pcm_prepare( stream->playback.pcm ), paUnanticipatedHostError ); if( stream->capture.pcm && !stream->pcmsSynced ) ENSURE_( alsa_snd_pcm_prepare( stream->capture.pcm ), paUnanticipatedHostError ); /* We can't be certain that the whole ring buffer is available for priming, but there should be * at least one period */ avail = alsa_snd_pcm_avail_update( stream->playback.pcm ); startThreshold = avail - (avail % stream->playback.framesPerBuffer); assert( startThreshold >= stream->playback.framesPerBuffer ); } else { PA_ENSURE( PaUnixThread_PrepareNotify( &stream->thread ) ); /* Buffer will be zeroed */ PA_ENSURE( AlsaStart( stream, 0 ) ); PA_ENSURE( PaUnixThread_NotifyParent( &stream->thread ) ); streamStarted = 1; } while( 1 ) { unsigned long framesAvail, framesGot; int xrun = 0; #ifdef PTHREAD_CANCELED pthread_testcancel(); #endif /* @concern StreamStop if the main thread has requested a stop and the stream has not been effectively * stopped we signal this condition by modifying callbackResult (we'll want to flush buffered output). */ if( PaUnixThread_StopRequested( &stream->thread ) && paContinue == callbackResult ) { PA_DEBUG(( "Setting callbackResult to paComplete\n" )); callbackResult = paComplete; } if( paContinue != callbackResult ) { stream->callbackAbort = (paAbort == callbackResult); if( stream->callbackAbort || /** @concern BlockAdaption: Go on if adaption buffers are empty */ PaUtil_IsBufferProcessorOutputEmpty( &stream->bufferProcessor ) ) { goto end; } PA_DEBUG(( "%s: Flushing buffer processor\n", __FUNCTION__ )); /* There is still buffered output that needs to be processed */ } /* Wait for data to become available, this comes down to polling the ALSA file descriptors untill we have * a number of available frames. */ PA_ENSURE( PaAlsaStream_WaitForFrames( stream, &framesAvail, &xrun ) ); if( xrun ) { assert( 0 == framesAvail ); continue; /* XXX: Report xruns to the user? A situation is conceivable where the callback is never invoked due * to constant xruns, it might be desirable to notify the user of this. */ } /* Consume buffer space. Once we have a number of frames available for consumption we must retrieve the * mmapped buffers from ALSA, this is contiguously accessible memory however, so we may receive smaller * portions at a time than is available as a whole. Therefore we should be prepared to process several * chunks successively. The buffers are passed to the PA buffer processor. */ while( framesAvail > 0 ) { xrun = 0; #ifdef PTHREAD_CANCELED pthread_testcancel(); #endif /** @concern Xruns Under/overflows are to be reported to the callback */ if( stream->underrun > 0.0 ) { cbFlags |= paOutputUnderflow; stream->underrun = 0.0; } if( stream->overrun > 0.0 ) { cbFlags |= paInputOverflow; stream->overrun = 0.0; } if( stream->capture.pcm && stream->playback.pcm ) { /** @concern FullDuplex It's possible that only one direction is being processed to avoid an * under- or overflow, this should be reported correspondingly */ if( !stream->capture.ready ) { cbFlags |= paInputUnderflow; PA_DEBUG(( "%s: Input underflow\n", __FUNCTION__ )); } else if( !stream->playback.ready ) { cbFlags |= paOutputOverflow; PA_DEBUG(( "%s: Output overflow\n", __FUNCTION__ )); } } #if 0 CallbackUpdate( &stream->threading ); #endif CalculateTimeInfo( stream, &timeInfo ); PaUtil_BeginBufferProcessing( &stream->bufferProcessor, &timeInfo, cbFlags ); cbFlags = 0; /* CPU load measurement should include processing activivity external to the stream callback */ PaUtil_BeginCpuLoadMeasurement( &stream->cpuLoadMeasurer ); framesGot = framesAvail; if( paUtilFixedHostBufferSize == stream->bufferProcessor.hostBufferSizeMode ) { /* We've committed to a fixed host buffer size, stick to that */ framesGot = framesGot >= stream->maxFramesPerHostBuffer ? stream->maxFramesPerHostBuffer : 0; } else { /* We've committed to an upper bound on the size of host buffers */ assert( paUtilBoundedHostBufferSize == stream->bufferProcessor.hostBufferSizeMode ); framesGot = PA_MIN( framesGot, stream->maxFramesPerHostBuffer ); } PA_ENSURE( PaAlsaStream_SetUpBuffers( stream, &framesGot, &xrun ) ); /* Check the host buffer size against the buffer processor configuration */ framesAvail -= framesGot; if( framesGot > 0 ) { assert( !xrun ); PaUtil_EndBufferProcessing( &stream->bufferProcessor, &callbackResult ); PA_ENSURE( PaAlsaStream_EndProcessing( stream, framesGot, &xrun ) ); } PaUtil_EndCpuLoadMeasurement( &stream->cpuLoadMeasurer, framesGot ); if( 0 == framesGot ) { /* Go back to polling for more frames */ break; } if( paContinue != callbackResult ) break; } } end: ; /* Hack to fix "label at end of compound statement" error caused by pthread_cleanup_pop(1) macro. */ /* Match pthread_cleanup_push */ pthread_cleanup_pop( 1 ); PA_DEBUG(( "%s: Thread %d exiting\n ", __FUNCTION__, pthread_self() )); PaUnixThreading_EXIT( result ); error: PA_DEBUG(( "%s: Thread %d is canceled due to error %d\n ", __FUNCTION__, pthread_self(), result )); goto end; } /* Blocking interface */ static PaError ReadStream( PaStream* s, void *buffer, unsigned long frames ) { PaError result = paNoError; PaAlsaStream *stream = (PaAlsaStream*)s; unsigned long framesGot, framesAvail; void *userBuffer; snd_pcm_t *save = stream->playback.pcm; assert( stream ); PA_UNLESS( stream->capture.pcm, paCanNotReadFromAnOutputOnlyStream ); /* Disregard playback */ stream->playback.pcm = NULL; if( stream->overrun > 0. ) { result = paInputOverflowed; stream->overrun = 0.0; } if( stream->capture.userInterleaved ) { userBuffer = buffer; } else { /* Copy channels into local array */ userBuffer = stream->capture.userBuffers; memcpy( userBuffer, buffer, sizeof (void *) * stream->capture.numUserChannels ); } /* Start stream if in prepared state */ if( alsa_snd_pcm_state( stream->capture.pcm ) == SND_PCM_STATE_PREPARED ) { ENSURE_( alsa_snd_pcm_start( stream->capture.pcm ), paUnanticipatedHostError ); } while( frames > 0 ) { int xrun = 0; PA_ENSURE( PaAlsaStream_WaitForFrames( stream, &framesAvail, &xrun ) ); framesGot = PA_MIN( framesAvail, frames ); PA_ENSURE( PaAlsaStream_SetUpBuffers( stream, &framesGot, &xrun ) ); if( framesGot > 0 ) { framesGot = PaUtil_CopyInput( &stream->bufferProcessor, &userBuffer, framesGot ); PA_ENSURE( PaAlsaStream_EndProcessing( stream, framesGot, &xrun ) ); frames -= framesGot; } } end: stream->playback.pcm = save; return result; error: goto end; } static PaError WriteStream( PaStream* s, const void *buffer, unsigned long frames ) { PaError result = paNoError; signed long err; PaAlsaStream *stream = (PaAlsaStream*)s; snd_pcm_uframes_t framesGot, framesAvail; const void *userBuffer; snd_pcm_t *save = stream->capture.pcm; assert( stream ); PA_UNLESS( stream->playback.pcm, paCanNotWriteToAnInputOnlyStream ); /* Disregard capture */ stream->capture.pcm = NULL; if( stream->underrun > 0. ) { result = paOutputUnderflowed; stream->underrun = 0.0; } if( stream->playback.userInterleaved ) userBuffer = buffer; else /* Copy channels into local array */ { userBuffer = stream->playback.userBuffers; memcpy( (void *)userBuffer, buffer, sizeof (void *) * stream->playback.numUserChannels ); } while( frames > 0 ) { int xrun = 0; snd_pcm_uframes_t hwAvail; PA_ENSURE( PaAlsaStream_WaitForFrames( stream, &framesAvail, &xrun ) ); framesGot = PA_MIN( framesAvail, frames ); PA_ENSURE( PaAlsaStream_SetUpBuffers( stream, &framesGot, &xrun ) ); if( framesGot > 0 ) { framesGot = PaUtil_CopyOutput( &stream->bufferProcessor, &userBuffer, framesGot ); PA_ENSURE( PaAlsaStream_EndProcessing( stream, framesGot, &xrun ) ); frames -= framesGot; } /* Start stream after one period of samples worth */ /* Frames residing in buffer */ PA_ENSURE( err = GetStreamWriteAvailable( stream ) ); framesAvail = err; hwAvail = stream->playback.bufferSize - framesAvail; if( alsa_snd_pcm_state( stream->playback.pcm ) == SND_PCM_STATE_PREPARED && hwAvail >= stream->playback.framesPerBuffer ) { ENSURE_( alsa_snd_pcm_start( stream->playback.pcm ), paUnanticipatedHostError ); } } end: stream->capture.pcm = save; return result; error: goto end; } /* Return frames available for reading. In the event of an overflow, the capture pcm will be restarted */ static signed long GetStreamReadAvailable( PaStream* s ) { PaError result = paNoError; PaAlsaStream *stream = (PaAlsaStream*)s; unsigned long avail; int xrun; PA_ENSURE( PaAlsaStreamComponent_GetAvailableFrames( &stream->capture, &avail, &xrun ) ); if( xrun ) { PA_ENSURE( PaAlsaStream_HandleXrun( stream ) ); PA_ENSURE( PaAlsaStreamComponent_GetAvailableFrames( &stream->capture, &avail, &xrun ) ); if( xrun ) PA_ENSURE( paInputOverflowed ); } return (signed long)avail; error: return result; } static signed long GetStreamWriteAvailable( PaStream* s ) { PaError result = paNoError; PaAlsaStream *stream = (PaAlsaStream*)s; unsigned long avail; int xrun; PA_ENSURE( PaAlsaStreamComponent_GetAvailableFrames( &stream->playback, &avail, &xrun ) ); if( xrun ) { snd_pcm_sframes_t savail; PA_ENSURE( PaAlsaStream_HandleXrun( stream ) ); savail = alsa_snd_pcm_avail_update( stream->playback.pcm ); /* savail should not contain -EPIPE now, since PaAlsaStream_HandleXrun will only prepare the pcm */ ENSURE_( savail, paUnanticipatedHostError ); avail = (unsigned long) savail; } return (signed long)avail; error: return result; } /* Extensions */ void PaAlsa_InitializeStreamInfo( PaAlsaStreamInfo *info ) { info->size = sizeof (PaAlsaStreamInfo); info->hostApiType = paALSA; info->version = 1; info->deviceString = NULL; } void PaAlsa_EnableRealtimeScheduling( PaStream *s, int enable ) { PaAlsaStream *stream = (PaAlsaStream *) s; stream->rtSched = enable; } #if 0 void PaAlsa_EnableWatchdog( PaStream *s, int enable ) { PaAlsaStream *stream = (PaAlsaStream *) s; stream->thread.useWatchdog = enable; } #endif static PaError GetAlsaStreamPointer( PaStream* s, PaAlsaStream** stream ) { PaError result = paNoError; PaUtilHostApiRepresentation* hostApi; PaAlsaHostApiRepresentation* alsaHostApi; PA_ENSURE( PaUtil_ValidateStreamPointer( s ) ); PA_ENSURE( PaUtil_GetHostApiRepresentation( &hostApi, paALSA ) ); alsaHostApi = (PaAlsaHostApiRepresentation*)hostApi; PA_UNLESS( PA_STREAM_REP( s )->streamInterface == &alsaHostApi->callbackStreamInterface || PA_STREAM_REP( s )->streamInterface == &alsaHostApi->blockingStreamInterface, paIncompatibleStreamHostApi ); *stream = (PaAlsaStream*)s; error: return paNoError; } PaError PaAlsa_GetStreamInputCard(PaStream* s, int* card) { PaAlsaStream *stream; PaError result = paNoError; snd_pcm_info_t* pcmInfo; PA_ENSURE( GetAlsaStreamPointer( s, &stream ) ); /* XXX: More descriptive error? */ PA_UNLESS( stream->capture.pcm, paDeviceUnavailable ); alsa_snd_pcm_info_alloca( &pcmInfo ); PA_ENSURE( alsa_snd_pcm_info( stream->capture.pcm, pcmInfo ) ); *card = alsa_snd_pcm_info_get_card( pcmInfo ); error: return result; } PaError PaAlsa_GetStreamOutputCard(PaStream* s, int* card) { PaAlsaStream *stream; PaError result = paNoError; snd_pcm_info_t* pcmInfo; PA_ENSURE( GetAlsaStreamPointer( s, &stream ) ); /* XXX: More descriptive error? */ PA_UNLESS( stream->playback.pcm, paDeviceUnavailable ); alsa_snd_pcm_info_alloca( &pcmInfo ); PA_ENSURE( alsa_snd_pcm_info( stream->playback.pcm, pcmInfo ) ); *card = alsa_snd_pcm_info_get_card( pcmInfo ); error: return result; } PaError PaAlsa_SetRetriesBusy( int retries ) { busyRetries_ = retries; return paNoError; } /* -------------------------------------------------------------------------- */ /* -------------------------------------------------------------------------- */ /* -------------------------------------------------------------------------- */ /* CONVERTERS (Swapping SRC/DST) */ /* -------------------------------------------------------------------------- */ #define PA_CLIP_( val, min, max )\ { val = ((val) < (min)) ? (min) : (((val) > (max)) ? (max) : (val)); } static const double const_1_div_2147483648_ = 1.0 / 2147483648.0; /* 32 bit multiplier */ /* -------------------------------------------------------------------------- */ static void Copy_24_To_24_Swap( void *destinationBuffer, signed int destinationStride, void *sourceBuffer, signed int sourceStride, unsigned int count, struct PaUtilTriangularDitherGenerator *ditherGenerator ) { unsigned char *src = (unsigned char*)sourceBuffer; unsigned char *dest = (unsigned char*)destinationBuffer; (void) ditherGenerator; /* unused parameter */ while( count-- ) { dest[2] = src[0]; dest[1] = src[1]; dest[0] = src[2]; src += sourceStride * 3; dest += destinationStride * 3; } } /* -------------------------------------------------------------------------- */ static void UInt8_To_Int24_Swap( void *destinationBuffer, signed int destinationStride, void *sourceBuffer, signed int sourceStride, unsigned int count, struct PaUtilTriangularDitherGenerator *ditherGenerator ) { unsigned char *src = (unsigned char*)sourceBuffer; unsigned char *dest = (unsigned char*)destinationBuffer; (void) ditherGenerator; /* unused parameters */ while( count-- ) { #if defined(PA_LITTLE_ENDIAN) dest[2] = 0; dest[1] = 0; dest[0] = (unsigned char)(*src - 128); #elif defined(PA_BIG_ENDIAN) dest[2] = (unsigned char)(*src - 128); dest[1] = 0; dest[0] = 0; #endif src += sourceStride; dest += destinationStride * 3; } } /* -------------------------------------------------------------------------- */ static void Int8_To_Int24_Swap( void *destinationBuffer, signed int destinationStride, void *sourceBuffer, signed int sourceStride, unsigned int count, struct PaUtilTriangularDitherGenerator *ditherGenerator ) { signed char *src = (signed char*)sourceBuffer; unsigned char *dest = (unsigned char*)destinationBuffer; (void)ditherGenerator; /* unused parameter */ while( count-- ) { #if defined(PA_LITTLE_ENDIAN) dest[2] = 0; dest[1] = 0; dest[0] = (*src); #elif defined(PA_BIG_ENDIAN) dest[2] = (*src); dest[1] = 0; dest[0] = 0; #endif src += sourceStride; dest += destinationStride * 3; } } /* -------------------------------------------------------------------------- */ static void Int16_To_Int24_Swap( void *destinationBuffer, signed int destinationStride, void *sourceBuffer, signed int sourceStride, unsigned int count, struct PaUtilTriangularDitherGenerator *ditherGenerator ) { PaInt16 *src = (PaInt16*) sourceBuffer; unsigned char *dest = (unsigned char*)destinationBuffer; PaInt16 temp; (void) ditherGenerator; /* unused parameter */ while( count-- ) { temp = *src; #if defined(PA_LITTLE_ENDIAN) dest[2] = 0; dest[1] = (unsigned char)(temp); dest[0] = (unsigned char)(temp >> 8); #elif defined(PA_BIG_ENDIAN) dest[2] = (unsigned char)(temp >> 8); dest[1] = (unsigned char)(temp); dest[0] = 0; #endif src += sourceStride; dest += destinationStride * 3; } } /* -------------------------------------------------------------------------- */ static void Int32_To_Int24_Swap( void *destinationBuffer, signed int destinationStride, void *sourceBuffer, signed int sourceStride, unsigned int count, struct PaUtilTriangularDitherGenerator *ditherGenerator ) { PaInt32 *src = (PaInt32*)sourceBuffer; unsigned char *dest = (unsigned char*)destinationBuffer; (void) ditherGenerator; /* unused parameter */ while( count-- ) { /* REVIEW */ #if defined(PA_LITTLE_ENDIAN) dest[2] = (unsigned char)(*src >> 8); dest[1] = (unsigned char)(*src >> 16); dest[0] = (unsigned char)(*src >> 24); #elif defined(PA_BIG_ENDIAN) dest[2] = (unsigned char)(*src >> 24); dest[1] = (unsigned char)(*src >> 16); dest[0] = (unsigned char)(*src >> 8); #endif src += sourceStride; dest += destinationStride * 3; } } /* -------------------------------------------------------------------------- */ static void Float32_To_Int24_Swap( void *destinationBuffer, signed int destinationStride, void *sourceBuffer, signed int sourceStride, unsigned int count, struct PaUtilTriangularDitherGenerator *ditherGenerator ) { float *src = (float*)sourceBuffer; unsigned char *dest = (unsigned char*)destinationBuffer; PaInt32 temp; (void) ditherGenerator; /* unused parameter */ while( count-- ) { /* convert to 32 bit and drop the low 8 bits */ double scaled = (double)(*src) * 2147483647.0; temp = (PaInt32) scaled; #if defined(PA_LITTLE_ENDIAN) dest[2] = (unsigned char)(temp >> 8); dest[1] = (unsigned char)(temp >> 16); dest[0] = (unsigned char)(temp >> 24); #elif defined(PA_BIG_ENDIAN) dest[2] = (unsigned char)(temp >> 24); dest[1] = (unsigned char)(temp >> 16); dest[0] = (unsigned char)(temp >> 8); #endif src += sourceStride; dest += destinationStride * 3; } } /* -------------------------------------------------------------------------- */ static void Float32_To_Int24_Dither_Swap( void *destinationBuffer, signed int destinationStride, void *sourceBuffer, signed int sourceStride, unsigned int count, struct PaUtilTriangularDitherGenerator *ditherGenerator ) { float *src = (float*)sourceBuffer; unsigned char *dest = (unsigned char*)destinationBuffer; PaInt32 temp; while( count-- ) { /* convert to 32 bit and drop the low 8 bits */ double dither = PaUtil_GenerateFloatTriangularDither( ditherGenerator ); /* use smaller scaler to prevent overflow when we add the dither */ double dithered = ((double)*src * (2147483646.0)) + dither; temp = (PaInt32) dithered; #if defined(PA_LITTLE_ENDIAN) dest[2] = (unsigned char)(temp >> 8); dest[1] = (unsigned char)(temp >> 16); dest[0] = (unsigned char)(temp >> 24); #elif defined(PA_BIG_ENDIAN) dest[2] = (unsigned char)(temp >> 24); dest[1] = (unsigned char)(temp >> 16); dest[0] = (unsigned char)(temp >> 8); #endif src += sourceStride; dest += destinationStride * 3; } } /* -------------------------------------------------------------------------- */ static void Float32_To_Int24_Clip_Swap( void *destinationBuffer, signed int destinationStride, void *sourceBuffer, signed int sourceStride, unsigned int count, struct PaUtilTriangularDitherGenerator *ditherGenerator ) { float *src = (float*)sourceBuffer; unsigned char *dest = (unsigned char*)destinationBuffer; PaInt32 temp; (void) ditherGenerator; /* unused parameter */ while( count-- ) { /* convert to 32 bit and drop the low 8 bits */ double scaled = *src * 0x7FFFFFFF; PA_CLIP_( scaled, -2147483648., 2147483647. ); temp = (PaInt32) scaled; #if defined(PA_LITTLE_ENDIAN) dest[2] = (unsigned char)(temp >> 8); dest[1] = (unsigned char)(temp >> 16); dest[0] = (unsigned char)(temp >> 24); #elif defined(PA_BIG_ENDIAN) dest[2] = (unsigned char)(temp >> 24); dest[1] = (unsigned char)(temp >> 16); dest[0] = (unsigned char)(temp >> 8); #endif src += sourceStride; dest += destinationStride * 3; } } /* -------------------------------------------------------------------------- */ static void Float32_To_Int24_DitherClip_Swap( void *destinationBuffer, signed int destinationStride, void *sourceBuffer, signed int sourceStride, unsigned int count, struct PaUtilTriangularDitherGenerator *ditherGenerator ) { float *src = (float*)sourceBuffer; unsigned char *dest = (unsigned char*)destinationBuffer; PaInt32 temp; while( count-- ) { /* convert to 32 bit and drop the low 8 bits */ double dither = PaUtil_GenerateFloatTriangularDither( ditherGenerator ); /* use smaller scaler to prevent overflow when we add the dither */ double dithered = ((double)*src * (2147483646.0)) + dither; PA_CLIP_( dithered, -2147483648., 2147483647. ); temp = (PaInt32) dithered; #if defined(PA_LITTLE_ENDIAN) dest[2] = (unsigned char)(temp >> 8); dest[1] = (unsigned char)(temp >> 16); dest[0] = (unsigned char)(temp >> 24); #elif defined(PA_BIG_ENDIAN) dest[2] = (unsigned char)(temp >> 24); dest[1] = (unsigned char)(temp >> 16); dest[0] = (unsigned char)(temp >> 8); #endif src += sourceStride; dest += destinationStride * 3; } } /* -------------------------------------------------------------------------- */ static void Int24_To_Float32_Swap( void *destinationBuffer, signed int destinationStride, void *sourceBuffer, signed int sourceStride, unsigned int count, struct PaUtilTriangularDitherGenerator *ditherGenerator ) { unsigned char *src = (unsigned char*)sourceBuffer; float *dest = (float*)destinationBuffer; PaInt32 temp; (void) ditherGenerator; /* unused parameter */ while( count-- ) { #if defined(PA_LITTLE_ENDIAN) temp = (((PaInt32)src[2]) << 8); temp = temp | (((PaInt32)src[1]) << 16); temp = temp | (((PaInt32)src[0]) << 24); #elif defined(PA_BIG_ENDIAN) temp = (((PaInt32)src[2]) << 24); temp = temp | (((PaInt32)src[1]) << 16); temp = temp | (((PaInt32)src[0]) << 8); #endif *dest = (float) ((double)temp * const_1_div_2147483648_); src += sourceStride * 3; dest += destinationStride; } } /* -------------------------------------------------------------------------- */ static void Int24_To_Int32_Swap( void *destinationBuffer, signed int destinationStride, void *sourceBuffer, signed int sourceStride, unsigned int count, struct PaUtilTriangularDitherGenerator *ditherGenerator ) { unsigned char *src = (unsigned char*)sourceBuffer; PaInt32 *dest = (PaInt32*) destinationBuffer; PaInt32 temp; (void) ditherGenerator; /* unused parameter */ while( count-- ) { #if defined(PA_LITTLE_ENDIAN) temp = (((PaInt32)src[2]) << 8); temp = temp | (((PaInt32)src[1]) << 16); temp = temp | (((PaInt32)src[0]) << 24); #elif defined(PA_BIG_ENDIAN) temp = (((PaInt32)src[2]) << 24); temp = temp | (((PaInt32)src[1]) << 16); temp = temp | (((PaInt32)src[0]) << 8); #endif *dest = temp; src += sourceStride * 3; dest += destinationStride; } } /* -------------------------------------------------------------------------- */ static void Int24_To_Int16_Swap( void *destinationBuffer, signed int destinationStride, void *sourceBuffer, signed int sourceStride, unsigned int count, struct PaUtilTriangularDitherGenerator *ditherGenerator ) { unsigned char *src = (unsigned char*)sourceBuffer; PaInt16 *dest = (PaInt16*)destinationBuffer; PaInt16 temp; (void) ditherGenerator; /* unused parameter */ while( count-- ) { #if defined(PA_LITTLE_ENDIAN) /* src[2] is discarded */ temp = (((PaInt16)src[1])); temp = temp | (PaInt16)(((PaInt16)src[0]) << 8); #elif defined(PA_BIG_ENDIAN) /* src[0] is discarded */ temp = (PaInt16)(((PaInt16)src[2]) << 8); temp = temp | (((PaInt16)src[1])); #endif *dest = temp; src += sourceStride * 3; dest += destinationStride; } } /* -------------------------------------------------------------------------- */ static void Int24_To_Int16_Dither_Swap( void *destinationBuffer, signed int destinationStride, void *sourceBuffer, signed int sourceStride, unsigned int count, struct PaUtilTriangularDitherGenerator *ditherGenerator ) { unsigned char *src = (unsigned char*)sourceBuffer; PaInt16 *dest = (PaInt16*)destinationBuffer; PaInt32 temp, dither; while( count-- ) { #if defined(PA_LITTLE_ENDIAN) temp = (((PaInt32)src[2]) << 8); temp = temp | (((PaInt32)src[1]) << 16); temp = temp | (((PaInt32)src[0]) << 24); #elif defined(PA_BIG_ENDIAN) temp = (((PaInt32)src[2]) << 24); temp = temp | (((PaInt32)src[1]) << 16); temp = temp | (((PaInt32)src[0]) << 8); #endif /* REVIEW */ dither = PaUtil_Generate16BitTriangularDither( ditherGenerator ); *dest = (PaInt16) (((temp >> 1) + dither) >> 15); src += sourceStride * 3; dest += destinationStride; } } /* -------------------------------------------------------------------------- */ static void Int24_To_Int8_Swap( void *destinationBuffer, signed int destinationStride, void *sourceBuffer, signed int sourceStride, unsigned int count, struct PaUtilTriangularDitherGenerator *ditherGenerator ) { unsigned char *src = (unsigned char*)sourceBuffer; signed char *dest = (signed char*)destinationBuffer; (void) ditherGenerator; /* unused parameter */ while( count-- ) { #if defined(PA_LITTLE_ENDIAN) /* src[0] is discarded */ /* src[1] is discarded */ *dest = src[0]; #elif defined(PA_BIG_ENDIAN) /* src[2] is discarded */ /* src[1] is discarded */ *dest = src[2]; #endif src += sourceStride * 3; dest += destinationStride; } } /* -------------------------------------------------------------------------- */ static void Int24_To_Int8_Dither_Swap( void *destinationBuffer, signed int destinationStride, void *sourceBuffer, signed int sourceStride, unsigned int count, struct PaUtilTriangularDitherGenerator *ditherGenerator ) { unsigned char *src = (unsigned char*)sourceBuffer; signed char *dest = (signed char*)destinationBuffer; PaInt32 temp, dither; while( count-- ) { #if defined(PA_LITTLE_ENDIAN) temp = (((PaInt32)src[2]) << 8); temp = temp | (((PaInt32)src[1]) << 16); temp = temp | (((PaInt32)src[0]) << 24); #elif defined(PA_BIG_ENDIAN) temp = (((PaInt32)src[2]) << 24); temp = temp | (((PaInt32)src[1]) << 16); temp = temp | (((PaInt32)src[0]) << 8); #endif /* REVIEW */ dither = PaUtil_Generate16BitTriangularDither( ditherGenerator ); *dest = (signed char) (((temp >> 1) + dither) >> 23); src += sourceStride * 3; dest += destinationStride; } } /* -------------------------------------------------------------------------- */ static void Int24_To_UInt8_Swap( void *destinationBuffer, signed int destinationStride, void *sourceBuffer, signed int sourceStride, unsigned int count, struct PaUtilTriangularDitherGenerator *ditherGenerator ) { unsigned char *src = (unsigned char*)sourceBuffer; unsigned char *dest = (unsigned char*)destinationBuffer; (void) ditherGenerator; /* unused parameter */ while( count-- ) { #if defined(PA_LITTLE_ENDIAN) /* src[0] is discarded */ /* src[1] is discarded */ *dest = (unsigned char)(src[0] + 128); #elif defined(PA_BIG_ENDIAN) *dest = (unsigned char)(src[2] + 128); /* src[1] is discarded */ /* src[2] is discarded */ #endif src += sourceStride * 3; dest += destinationStride; } } /* -------------------------------------------------------------------------- */ static void X_To_X_Stub( void *destinationBuffer, signed int destinationStride, void *sourceBuffer, signed int sourceStride, unsigned int count, struct PaUtilTriangularDitherGenerator *ditherGenerator ) { (void) destinationBuffer; /* unused parameters */ (void) destinationStride; /* unused parameters */ (void) sourceBuffer; /* unused parameters */ (void) sourceStride; /* unused parameters */ (void) count; /* unused parameters */ (void) ditherGenerator; /* unused parameters */ /* IMPLEMENT ME */ assert(0 && "input/output format needs additional swapping converter"); } /* -------------------------------------------------------------------------- */ static PaUtilConverterTable paAlsaSwapConverters = { X_To_X_Stub, /* PaUtilConverter *Float32_To_Int32; */ X_To_X_Stub, /* PaUtilConverter *Float32_To_Int32_Dither; */ X_To_X_Stub, /* PaUtilConverter *Float32_To_Int32_Clip; */ X_To_X_Stub, /* PaUtilConverter *Float32_To_Int32_DitherClip; */ Float32_To_Int24_Swap, /* PaUtilConverter *Float32_To_Int24; */ Float32_To_Int24_Dither_Swap, /* PaUtilConverter *Float32_To_Int24_Dither; */ Float32_To_Int24_Clip_Swap, /* PaUtilConverter *Float32_To_Int24_Clip; */ Float32_To_Int24_DitherClip_Swap, /* PaUtilConverter *Float32_To_Int24_DitherClip; */ X_To_X_Stub, /* PaUtilConverter *Float32_To_Int16; */ X_To_X_Stub, /* PaUtilConverter *Float32_To_Int16_Dither; */ X_To_X_Stub, /* PaUtilConverter *Float32_To_Int16_Clip; */ X_To_X_Stub, /* PaUtilConverter *Float32_To_Int16_DitherClip; */ X_To_X_Stub, /* PaUtilConverter *Float32_To_Int8; */ X_To_X_Stub, /* PaUtilConverter *Float32_To_Int8_Dither; */ X_To_X_Stub, /* PaUtilConverter *Float32_To_Int8_Clip; */ X_To_X_Stub, /* PaUtilConverter *Float32_To_Int8_DitherClip; */ X_To_X_Stub, /* PaUtilConverter *Float32_To_UInt8; */ X_To_X_Stub, /* PaUtilConverter *Float32_To_UInt8_Dither; */ X_To_X_Stub, /* PaUtilConverter *Float32_To_UInt8_Clip; */ X_To_X_Stub, /* PaUtilConverter *Float32_To_UInt8_DitherClip; */ X_To_X_Stub, /* PaUtilConverter *Int32_To_Float32; */ Int32_To_Int24_Swap, /* PaUtilConverter *Int32_To_Int24; */ X_To_X_Stub,/*TO-DO*//* PaUtilConverter *Int32_To_Int24_Dither; */ X_To_X_Stub, /* PaUtilConverter *Int32_To_Int16; */ X_To_X_Stub, /* PaUtilConverter *Int32_To_Int16_Dither; */ X_To_X_Stub, /* PaUtilConverter *Int32_To_Int8; */ X_To_X_Stub, /* PaUtilConverter *Int32_To_Int8_Dither; */ X_To_X_Stub, /* PaUtilConverter *Int32_To_UInt8; */ X_To_X_Stub, /* PaUtilConverter *Int32_To_UInt8_Dither; */ Int24_To_Float32_Swap, /* PaUtilConverter *Int24_To_Float32; */ Int24_To_Int32_Swap, /* PaUtilConverter *Int24_To_Int32; */ Int24_To_Int16_Swap, /* PaUtilConverter *Int24_To_Int16; */ Int24_To_Int16_Dither_Swap, /* PaUtilConverter *Int24_To_Int16_Dither; */ Int24_To_Int8_Swap, /* PaUtilConverter *Int24_To_Int8; */ Int24_To_Int8_Dither_Swap, /* PaUtilConverter *Int24_To_Int8_Dither; */ Int24_To_UInt8_Swap, /* PaUtilConverter *Int24_To_UInt8; */ X_To_X_Stub, /* PaUtilConverter *Int24_To_UInt8_Dither; */ X_To_X_Stub, /* PaUtilConverter *Int16_To_Float32; */ X_To_X_Stub, /* PaUtilConverter *Int16_To_Int32; */ Int16_To_Int24_Swap, /* PaUtilConverter *Int16_To_Int24; */ X_To_X_Stub, /* PaUtilConverter *Int16_To_Int8; */ X_To_X_Stub, /* PaUtilConverter *Int16_To_Int8_Dither; */ X_To_X_Stub, /* PaUtilConverter *Int16_To_UInt8; */ X_To_X_Stub, /* PaUtilConverter *Int16_To_UInt8_Dither; */ X_To_X_Stub, /* PaUtilConverter *Int8_To_Float32; */ X_To_X_Stub, /* PaUtilConverter *Int8_To_Int32; */ Int8_To_Int24_Swap, /* PaUtilConverter *Int8_To_Int24 */ X_To_X_Stub, /* PaUtilConverter *Int8_To_Int16; */ X_To_X_Stub, /* PaUtilConverter *Int8_To_UInt8; */ X_To_X_Stub, /* PaUtilConverter *UInt8_To_Float32; */ X_To_X_Stub, /* PaUtilConverter *UInt8_To_Int32; */ UInt8_To_Int24_Swap, /* PaUtilConverter *UInt8_To_Int24; */ X_To_X_Stub, /* PaUtilConverter *UInt8_To_Int16; */ X_To_X_Stub, /* PaUtilConverter *UInt8_To_Int8; */ X_To_X_Stub, /* PaUtilConverter *Copy_8_To_8; */ X_To_X_Stub, /* PaUtilConverter *Copy_16_To_16; */ Copy_24_To_24_Swap, /* PaUtilConverter *Copy_24_To_24; */ X_To_X_Stub /* PaUtilConverter *Copy_32_To_32; */ }; void CheckAndReplaceConverterForSwapping( PaAlsaStream *stream ) { PaUtilConverter **cv_org = (PaUtilConverter **)&paConverters, **cv_swp = (PaUtilConverter **)&paAlsaSwapConverters; int i, i_max = sizeof(PaUtilConverterTable)/sizeof(PaUtilConverter *); if( stream->capture.useByteSwapConverter ) { for( i = 0; i < i_max; ++i ) { if( cv_org[i] == stream->bufferProcessor.inputConverter ) { stream->bufferProcessor.inputConverter = cv_swp[i]; break; } } } if( stream->playback.useByteSwapConverter ) { for( i = 0; i < i_max; ++i ) { if( cv_org[i] == stream->bufferProcessor.outputConverter ) { stream->bufferProcessor.outputConverter = cv_swp[i]; break; } } } }