libsoundio/test/unit_tests.c

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#undef NDEBUG
#include "soundio_private.h"
#include "os.h"
#include "util.h"
#include "atomics.h"
#include <stdio.h>
#include <string.h>
#include <assert.h>
#include <limits.h>
static inline void ok_or_panic(int err) {
if (err)
soundio_panic("%s", soundio_strerror(err));
}
static void test_os_get_time(void) {
ok_or_panic(soundio_os_init());
double prev_time = soundio_os_get_time();
for (int i = 0; i < 1000; i += 1) {
double time = soundio_os_get_time();
assert(time >= prev_time);
prev_time = time;
}
}
static void write_callback(struct SoundIoOutStream *device, int frame_count_min, int frame_count_max) { }
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static void error_callback(struct SoundIoOutStream *device, int err) { }
static void test_create_outstream(void) {
struct SoundIo *soundio = soundio_create();
assert(soundio);
ok_or_panic(soundio_connect(soundio));
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soundio_flush_events(soundio);
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int default_out_device_index = soundio_default_output_device_index(soundio);
assert(default_out_device_index >= 0);
struct SoundIoDevice *device = soundio_get_output_device(soundio, default_out_device_index);
assert(device);
struct SoundIoOutStream *outstream = soundio_outstream_create(device);
outstream->format = SoundIoFormatFloat32NE;
outstream->sample_rate = 48000;
outstream->layout = device->layouts[0];
outstream->software_latency = 0.1;
outstream->write_callback = write_callback;
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outstream->error_callback = error_callback;
ok_or_panic(soundio_outstream_open(outstream));
soundio_outstream_destroy(outstream);
soundio_device_unref(device);
soundio_destroy(soundio);
soundio = NULL;
soundio_destroy(soundio);
}
static void test_ring_buffer_basic(void) {
struct SoundIo *soundio = soundio_create();
assert(soundio);
struct SoundIoRingBuffer *rb = soundio_ring_buffer_create(soundio, 10);
assert(rb);
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int page_size = soundio_os_page_size();
assert(soundio_ring_buffer_capacity(rb) == page_size);
char *write_ptr = soundio_ring_buffer_write_ptr(rb);
int amt = sprintf(write_ptr, "hello") + 1;
soundio_ring_buffer_advance_write_ptr(rb, amt);
assert(soundio_ring_buffer_fill_count(rb) == amt);
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assert(soundio_ring_buffer_free_count(rb) == page_size - amt);
char *read_ptr = soundio_ring_buffer_read_ptr(rb);
assert(strcmp(read_ptr, "hello") == 0);
soundio_ring_buffer_advance_read_ptr(rb, amt);
assert(soundio_ring_buffer_fill_count(rb) == 0);
assert(soundio_ring_buffer_free_count(rb) == soundio_ring_buffer_capacity(rb));
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soundio_ring_buffer_advance_write_ptr(rb, page_size - 2);
soundio_ring_buffer_advance_read_ptr(rb, page_size - 2);
amt = sprintf(soundio_ring_buffer_write_ptr(rb), "writing past the end") + 1;
soundio_ring_buffer_advance_write_ptr(rb, amt);
assert(soundio_ring_buffer_fill_count(rb) == amt);
assert(strcmp(soundio_ring_buffer_read_ptr(rb), "writing past the end") == 0);
soundio_ring_buffer_advance_read_ptr(rb, amt);
assert(soundio_ring_buffer_fill_count(rb) == 0);
assert(soundio_ring_buffer_free_count(rb) == soundio_ring_buffer_capacity(rb));
soundio_ring_buffer_destroy(rb);
soundio_destroy(soundio);
}
static struct SoundIoRingBuffer *rb = NULL;
static const int rb_size = 3528;
static long expected_write_head;
static long expected_read_head;
static struct SoundIoAtomicBool rb_done;
static struct SoundIoAtomicInt rb_write_it;
static struct SoundIoAtomicInt rb_read_it;
// just for testing purposes; does not need to be high quality random
static double random_double(void) {
return ((double)rand() / (double)RAND_MAX);
}
static void reader_thread_run(void *arg) {
while (!SOUNDIO_ATOMIC_LOAD(rb_done)) {
SOUNDIO_ATOMIC_FETCH_ADD(rb_read_it, 1);
int fill_count = soundio_ring_buffer_fill_count(rb);
assert(fill_count >= 0);
assert(fill_count <= rb_size);
int amount_to_read = soundio_int_min(random_double() * 2.0 * fill_count, fill_count);
soundio_ring_buffer_advance_read_ptr(rb, amount_to_read);
expected_read_head += amount_to_read;
}
}
static void writer_thread_run(void *arg) {
while (!SOUNDIO_ATOMIC_LOAD(rb_done)) {
SOUNDIO_ATOMIC_FETCH_ADD(rb_write_it, 1);
int fill_count = soundio_ring_buffer_fill_count(rb);
assert(fill_count >= 0);
assert(fill_count <= rb_size);
int free_count = rb_size - fill_count;
assert(free_count >= 0);
assert(free_count <= rb_size);
int value = soundio_int_min(random_double() * 2.0 * free_count, free_count);
soundio_ring_buffer_advance_write_ptr(rb, value);
expected_write_head += value;
}
}
static void test_ring_buffer_threaded(void) {
struct SoundIo *soundio = soundio_create();
assert(soundio);
rb = soundio_ring_buffer_create(soundio, rb_size);
expected_write_head = 0;
expected_read_head = 0;
SOUNDIO_ATOMIC_STORE(rb_read_it, 0);
SOUNDIO_ATOMIC_STORE(rb_write_it, 0);
SOUNDIO_ATOMIC_STORE(rb_done, false);
struct SoundIoOsThread *reader_thread;
ok_or_panic(soundio_os_thread_create(reader_thread_run, NULL, NULL, &reader_thread));
struct SoundIoOsThread *writer_thread;
ok_or_panic(soundio_os_thread_create(writer_thread_run, NULL, NULL, &writer_thread));
while (SOUNDIO_ATOMIC_LOAD(rb_read_it) < 100000 || SOUNDIO_ATOMIC_LOAD(rb_write_it) < 100000) {}
SOUNDIO_ATOMIC_STORE(rb_done, true);
soundio_os_thread_destroy(reader_thread);
soundio_os_thread_destroy(writer_thread);
int fill_count = soundio_ring_buffer_fill_count(rb);
int expected_fill_count = expected_write_head - expected_read_head;
assert(fill_count == expected_fill_count);
soundio_destroy(soundio);
}
static void test_mirrored_memory(void) {
struct SoundIoOsMirroredMemory mem;
ok_or_panic(soundio_os_init());
static const int requested_bytes = 1024;
ok_or_panic(soundio_os_init_mirrored_memory(&mem, requested_bytes));
const int size_bytes = mem.capacity;
for (int i = 0; i < size_bytes; i += 1) {
mem.address[i] = rand() % CHAR_MAX;
}
for (int i = 0; i < size_bytes; i += 1) {
assert(mem.address[i] == mem.address[size_bytes+i]);
}
soundio_os_deinit_mirrored_memory(&mem);
}
static void test_nearest_sample_rate(void) {
struct SoundIoDevice device;
struct SoundIoSampleRateRange sample_rates[2] = {
{
44100,
48000
},
{
96000,
96000,
},
};
device.sample_rate_count = 2;
device.sample_rates = sample_rates;
assert(soundio_device_nearest_sample_rate(&device, 100) == 44100);
assert(soundio_device_nearest_sample_rate(&device, 44099) == 44100);
assert(soundio_device_nearest_sample_rate(&device, 44100) == 44100);
assert(soundio_device_nearest_sample_rate(&device, 45000) == 45000);
assert(soundio_device_nearest_sample_rate(&device, 48000) == 48000);
assert(soundio_device_nearest_sample_rate(&device, 48001) == 96000);
assert(soundio_device_nearest_sample_rate(&device, 90000) == 96000);
assert(soundio_device_nearest_sample_rate(&device, 96001) == 96000);
assert(soundio_device_nearest_sample_rate(&device, 9999999) == 96000);
}
struct Test {
const char *name;
void (*fn)(void);
};
static struct Test tests[] = {
{"os_get_time", test_os_get_time},
{"create output stream", test_create_outstream},
{"mirrored memory", test_mirrored_memory},
{"soundio_device_nearest_sample_rate", test_nearest_sample_rate},
{"ring buffer basic", test_ring_buffer_basic},
{"ring buffer threaded", test_ring_buffer_threaded},
{NULL, NULL},
};
static void exec_test(struct Test *test) {
fprintf(stderr, "testing %s...", test->name);
test->fn();
fprintf(stderr, "OK\n");
}
int main(int argc, char *argv[]) {
const char *match = NULL;
if (argc == 2)
match = argv[1];
struct Test *test = &tests[0];
while (test->name) {
if (!match || strstr(test->name, match))
exec_test(test);
test += 1;
}
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return 0;
}