#define __STDC_FORMAT_MACROS #include "cubeb/cubeb.h" #include #include #include #include #include #include #include #ifdef _WIN32 #include // Used by CoInitialize() #endif #ifndef M_PI #define M_PI 3.14159263 #endif // Default values if none specified #define DEFAULT_RATE 44100 #define DEFAULT_OUTPUT_CHANNELS 2 #define DEFAULT_INPUT_CHANNELS 1 static const char* state_to_string(cubeb_state state) { switch (state) { case CUBEB_STATE_STARTED: return "CUBEB_STATE_STARTED"; case CUBEB_STATE_STOPPED: return "CUBEB_STATE_STOPPED"; case CUBEB_STATE_DRAINED: return "CUBEB_STATE_DRAINED"; case CUBEB_STATE_ERROR: return "CUBEB_STATE_ERROR"; default: return "Undefined state"; } } void print_log(const char* msg, ...) { va_list args; va_start(args, msg); vprintf(msg, args); va_end(args); } class cubeb_client final { public: cubeb_client() {} ~cubeb_client() {} bool init(char const * backend_name = nullptr); bool init_stream(); bool start_stream(); bool stop_stream(); bool destroy_stream() const; bool destroy(); bool activate_log(cubeb_log_level log_level) const; void set_latency_testing(bool on); void set_latency_frames(uint32_t latency_frames); uint64_t get_stream_position() const; uint32_t get_stream_output_latency() const; uint32_t get_stream_input_latency() const; uint32_t get_max_channel_count() const; long user_data_cb(cubeb_stream* stm, void* user, const void* input_buffer, void* output_buffer, long nframes); void user_state_cb(cubeb_stream* stm, void* user, cubeb_state state); bool register_device_collection_changed(cubeb_device_type devtype) const; bool unregister_device_collection_changed(cubeb_device_type devtype) const; cubeb_stream_params output_params = {}; cubeb_stream_params input_params = {}; void force_drain() { _force_drain = true; } private: bool has_input() { return input_params.rate != 0; } bool has_output() { return output_params.rate != 0; } cubeb* context = nullptr; cubeb_stream* stream = nullptr; cubeb_devid output_device = nullptr; cubeb_devid input_device = nullptr; /* Accessed only from client and audio thread. */ std::atomic _rate = {0}; std::atomic _channels = {0}; std::atomic _latency_testing = {false}; std::atomic _latency_frames = {0}; // if !0, override. Else, use min. std::atomic _force_drain = {false}; /* Accessed only from audio thread. */ uint32_t _total_frames = 0; }; bool cubeb_client::init(char const * backend_name) { int rv = cubeb_init(&context, "Cubeb Test Application", backend_name); if (rv != CUBEB_OK) { fprintf(stderr, "Could not init cubeb\n"); return false; } fprintf(stderr, "Init cubeb backend: %s\n", cubeb_get_backend_id(context)); return true; } static long user_data_cb_s(cubeb_stream* stm, void* user, const void* input_buffer, void* output_buffer, long nframes) { assert(user); return static_cast(user)->user_data_cb(stm, user, input_buffer, output_buffer, nframes); } static void user_state_cb_s(cubeb_stream* stm, void* user, cubeb_state state) { assert(user); return static_cast(user)->user_state_cb(stm, user, state); } void input_device_changed_callback_s(cubeb* context, void* user) { fprintf(stderr, "input_device_changed_callback_s\n"); } void output_device_changed_callback_s(cubeb* context, void* user) { fprintf(stderr, "output_device_changed_callback_s\n"); } void io_device_changed_callback_s(cubeb* context, void* user) { fprintf(stderr, "io_device_changed_callback\n"); } bool cubeb_client::init_stream() { assert(has_input() || has_output()); _rate = has_output() ? output_params.rate : input_params.rate; _channels = has_output() ? output_params.channels : input_params.channels; cubeb_stream_params params; params.rate = _rate; params.channels = 2; params.format = CUBEB_SAMPLE_FLOAT32NE; uint32_t latency = 0; int rv = cubeb_get_min_latency(context, ¶ms, &latency); if (rv != CUBEB_OK) { fprintf(stderr, "Could not get min latency."); return false; } if (_latency_frames) { latency = _latency_frames.load(); printf("Opening a stream with a forced latency of %d frames\n", latency); } rv = cubeb_stream_init(context, &stream, "Stream", input_device, has_input() ? &input_params : nullptr, output_device, has_output() ? &output_params : nullptr, latency, user_data_cb_s, user_state_cb_s, this); if (rv != CUBEB_OK) { fprintf(stderr, "Could not open the stream\n"); return false; } return true; } bool cubeb_client::start_stream() { _force_drain = false; int rv = cubeb_stream_start(stream); if (rv != CUBEB_OK) { fprintf(stderr, "Could not start the stream\n"); return false; } return true; } bool cubeb_client::stop_stream() { _force_drain = false; int rv = cubeb_stream_stop(stream); if (rv != CUBEB_OK) { fprintf(stderr, "Could not stop the stream\n"); return false; } return true; } uint64_t cubeb_client::get_stream_position() const { uint64_t pos = 0; int rv = cubeb_stream_get_position(stream, &pos); if (rv != CUBEB_OK) { fprintf(stderr, "Could not get the position of the stream\n"); return 0; } return pos; } uint32_t cubeb_client::get_stream_output_latency() const { uint32_t latency = 0; int rv = cubeb_stream_get_latency(stream, &latency); if (rv != CUBEB_OK) { fprintf(stderr, "Could not get the latency of the stream\n"); return 0; } return latency; } uint32_t cubeb_client::get_stream_input_latency() const { uint32_t latency = 0; int rv = cubeb_stream_get_input_latency(stream, &latency); if (rv != CUBEB_OK) { fprintf(stderr, "Could not get the latency of the input stream\n"); return 0; } return latency; } uint32_t cubeb_client::get_max_channel_count() const { uint32_t channels = 0; int rv = cubeb_get_max_channel_count(context, &channels); if (rv != CUBEB_OK) { fprintf(stderr, "Could not get max channel count\n"); return 0; } return channels; } bool cubeb_client::destroy_stream() const { cubeb_stream_destroy(stream); return true; } bool cubeb_client::destroy() { cubeb_destroy(context); return true; } bool cubeb_client::activate_log(cubeb_log_level log_level) const { cubeb_log_callback log_callback = nullptr; if (log_level != CUBEB_LOG_DISABLED) { log_callback = print_log; } if (cubeb_set_log_callback(log_level, log_callback) != CUBEB_OK) { fprintf(stderr, "Set log callback failed\n"); return false; } return true; } void cubeb_client::set_latency_testing(bool on) { _latency_testing = on; } void cubeb_client::set_latency_frames(uint32_t latency_frames) { _latency_frames = latency_frames; } static void fill_with_sine_tone(float* buf, uint32_t num_of_frames, uint32_t num_of_channels, uint32_t frame_rate, uint32_t position) { for (uint32_t i = 0; i < num_of_frames; ++i) { for (uint32_t c = 0; c < num_of_channels; ++c) { buf[i * num_of_channels + c] = 0.2 * sin(2 * M_PI * (i + position) * 350 / frame_rate); buf[i * num_of_channels + c] += 0.2 * sin(2 * M_PI * (i + position) * 440 / frame_rate); } } } long cubeb_client::user_data_cb(cubeb_stream* stm, void* user, const void* input_buffer, void* output_buffer, long nframes) { if (input_buffer && output_buffer) { const float* in = static_cast(input_buffer); float* out = static_cast(output_buffer); if (_latency_testing) { for (int32_t i = 0; i < nframes; i++) { // Impulses every second, mixed with the input signal fed back at half // gain, to measure the input-to-output latency via feedback. uint32_t clock = ((_total_frames + i) % _rate); if (!clock) { for (uint32_t j = 0; j < _channels; j++) { out[i * _channels + j] = 1.0 + in[i] * 0.5; } } else { for (uint32_t j = 0; j < _channels; j++) { out[i * _channels + j] = 0.0 + in[i] * 0.5; } } } } else { for (int32_t i = 0; i < nframes; i++) { for (uint32_t j = 0; j < _channels; j++) { out[i * _channels + j] = in[i]; } } } } else if (output_buffer && !input_buffer) { fill_with_sine_tone(static_cast(output_buffer), nframes, _channels, _rate, _total_frames); } _total_frames += nframes; if (_force_drain) { return nframes - 1; } return nframes; } void cubeb_client::user_state_cb(cubeb_stream* stm, void* user, cubeb_state state) { fprintf(stderr, "state is %s\n", state_to_string(state)); } bool cubeb_client::register_device_collection_changed( cubeb_device_type devtype) const { cubeb_device_collection_changed_callback callback = nullptr; if (devtype == static_cast(CUBEB_DEVICE_TYPE_INPUT | CUBEB_DEVICE_TYPE_OUTPUT)) { callback = io_device_changed_callback_s; } else if (devtype & CUBEB_DEVICE_TYPE_OUTPUT) { callback = output_device_changed_callback_s; } else if (devtype & CUBEB_DEVICE_TYPE_INPUT) { callback = input_device_changed_callback_s; } int r = cubeb_register_device_collection_changed( context, devtype, callback, nullptr); if (r != CUBEB_OK) { return false; } return true; } bool cubeb_client::unregister_device_collection_changed( cubeb_device_type devtype) const { int r = cubeb_register_device_collection_changed( context, devtype, nullptr, nullptr); if (r != CUBEB_OK) { return false; } return true; } enum play_mode { RECORD, PLAYBACK, DUPLEX, LATENCY_TESTING, COLLECTION_CHANGE, }; struct operation_data { play_mode pm; uint32_t rate; cubeb_device_type collection_device_type; }; void print_help() { const char * msg = "0: change log level to disabled\n" "1: change log level to normal\n" "2: change log level to verbose\n" "c: get max number of channels\n" "p: start a initialized stream\n" "s: stop a started stream\n" "d: destroy stream\n" "e: force stream to drain\n" "f: get stream position (client thread)\n" "i: change device type to input\n" "o: change device type to output\n" "a: change device type to input and output\n" "k: change device type to unknown\n" "r: register device collection changed callback for the current device type\n" "u: unregister device collection changed callback for the current device type\n" "q: quit\n" "h: print this message\n"; fprintf(stderr, "%s\n", msg); } bool choose_action(cubeb_client& cl, operation_data * op, int c) { // Consume "enter" and "space" while (c == 10 || c == 32) { c = getchar(); } if (c == EOF) { c = 'q'; } if (c == 'q') { if (op->pm == PLAYBACK || op->pm == RECORD || op->pm == DUPLEX || op->pm == LATENCY_TESTING) { bool res = cl.stop_stream(); if (!res) { fprintf(stderr, "stop_stream failed\n"); } res = cl.destroy_stream(); if (!res) { fprintf(stderr, "destroy_stream failed\n"); } } else if (op->pm == COLLECTION_CHANGE) { bool res = cl.unregister_device_collection_changed(op->collection_device_type); if (!res) { fprintf(stderr, "unregister_device_collection_changed failed\n"); } } return false; // exit the loop } else if (c == 'h') { print_help(); } else if (c == '0') { cl.activate_log(CUBEB_LOG_DISABLED); fprintf(stderr, "Log level changed to DISABLED\n"); } else if (c == '1') { cl.activate_log(CUBEB_LOG_DISABLED); cl.activate_log(CUBEB_LOG_NORMAL); fprintf(stderr, "Log level changed to NORMAL\n"); } else if (c == '2') { cl.activate_log(CUBEB_LOG_DISABLED); cl.activate_log(CUBEB_LOG_VERBOSE); fprintf(stderr, "Log level changed to VERBOSE\n"); } else if (c == 'p') { bool res = cl.start_stream(); if (res) { fprintf(stderr, "start_stream succeed\n"); } else { fprintf(stderr, "start_stream failed\n"); } } else if (c == 's') { bool res = cl.stop_stream(); if (res) { fprintf(stderr, "stop_stream succeed\n"); } else { fprintf(stderr, "stop_stream failed\n"); } } else if (c == 'd') { bool res = cl.destroy_stream(); if (res) { fprintf(stderr, "destroy_stream succeed\n"); } else { fprintf(stderr, "destroy_stream failed\n"); } } else if (c == 'e') { cl.force_drain(); } else if (c == 'c') { uint32_t channel_count = cl.get_max_channel_count(); fprintf(stderr, "max channel count (default output device): %u\n", channel_count); } else if (c == 'f') { uint64_t pos = cl.get_stream_position(); uint32_t latency; fprintf(stderr, "stream position %" PRIu64 ".", pos); if(op->pm == PLAYBACK || op->pm == DUPLEX) { latency = cl.get_stream_output_latency(); fprintf(stderr, " (output latency %" PRIu32 ")", latency); } if(op->pm == RECORD || op->pm == DUPLEX) { latency = cl.get_stream_input_latency(); fprintf(stderr, " (input latency %" PRIu32 ")", latency); } fprintf(stderr, "\n"); } else if (c == 'i') { op->collection_device_type = CUBEB_DEVICE_TYPE_INPUT; fprintf(stderr, "collection device type changed to INPUT\n"); } else if (c == 'o') { op->collection_device_type = CUBEB_DEVICE_TYPE_OUTPUT; fprintf(stderr, "collection device type changed to OUTPUT\n"); } else if (c == 'a') { op->collection_device_type = static_cast(CUBEB_DEVICE_TYPE_INPUT | CUBEB_DEVICE_TYPE_OUTPUT); fprintf(stderr, "collection device type changed to INPUT | OUTPUT\n"); } else if (c == 'k') { op->collection_device_type = CUBEB_DEVICE_TYPE_UNKNOWN; fprintf(stderr, "collection device type changed to UNKNOWN\n"); } else if (c == 'r') { bool res = cl.register_device_collection_changed(op->collection_device_type); if (res) { fprintf(stderr, "register_device_collection_changed succeed\n"); } else { fprintf(stderr, "register_device_collection_changed failed\n"); } } else if (c == 'u') { bool res = cl.unregister_device_collection_changed(op->collection_device_type); if (res) { fprintf(stderr, "unregister_device_collection_changed succeed\n"); } else { fprintf(stderr, "unregister_device_collection_changed failed\n"); } } else { fprintf(stderr, "Error: '%c' is not a valid entry\n", c); } return true; // Loop up } int main(int argc, char* argv[]) { #ifdef _WIN32 CoInitialize(nullptr); #endif operation_data op; op.pm = PLAYBACK; if (argc > 1) { if ('r' == argv[1][0]) { op.pm = RECORD; } else if ('p' == argv[1][0]) { op.pm = PLAYBACK; } else if ('d' == argv[1][0]) { op.pm = DUPLEX; } else if ('l' == argv[1][0]) { op.pm = LATENCY_TESTING; } else if ('c' == argv[1][0]) { op.pm = COLLECTION_CHANGE; } } op.rate = DEFAULT_RATE; uint32_t latency_override = 0; if (op.pm == LATENCY_TESTING && argc > 2) { latency_override = strtoul(argv[2], NULL, 10); printf("LATENCY_TESTING %d\n", latency_override); } else if (argc > 2) { op.rate = strtoul(argv[2], NULL, 0); } bool res = false; cubeb_client cl; cl.activate_log(CUBEB_LOG_DISABLED); fprintf(stderr, "Log level is DISABLED\n"); cl.init(/* default backend */); op.collection_device_type = CUBEB_DEVICE_TYPE_UNKNOWN; fprintf(stderr, "collection device type is UNKNOWN\n"); if (op.pm == COLLECTION_CHANGE) { op.collection_device_type = CUBEB_DEVICE_TYPE_OUTPUT; fprintf(stderr, "collection device type changed to OUTPUT\n"); res = cl.register_device_collection_changed(op.collection_device_type); if (res) { fprintf(stderr, "register_device_collection_changed succeed\n"); } else { fprintf(stderr, "register_device_collection_changed failed\n"); } } else { if (op.pm == PLAYBACK || op.pm == DUPLEX || op.pm == LATENCY_TESTING) { cl.output_params = {CUBEB_SAMPLE_FLOAT32NE, op.rate, DEFAULT_OUTPUT_CHANNELS, CUBEB_LAYOUT_STEREO, CUBEB_STREAM_PREF_NONE}; } if (op.pm == RECORD || op.pm == DUPLEX || op.pm == LATENCY_TESTING) { cl.input_params = {CUBEB_SAMPLE_FLOAT32NE, op.rate, DEFAULT_INPUT_CHANNELS, CUBEB_LAYOUT_UNDEFINED, CUBEB_STREAM_PREF_NONE}; } if (op.pm == LATENCY_TESTING) { cl.set_latency_testing(true); if (latency_override) { cl.set_latency_frames(latency_override); } } res = cl.init_stream(); if (!res) { fprintf(stderr, "stream_init failed\n"); return -1; } fprintf(stderr, "stream_init succeed\n"); res = cl.start_stream(); if (res) { fprintf(stderr, "stream_start succeed\n"); } else { fprintf(stderr, "stream_init failed\n"); } } // User input do { fprintf(stderr, "press `q` to abort or `h` for help\n"); } while (choose_action(cl, &op, getchar())); cl.destroy(); return 0; }