Apq
/
obs-studio
mirror of https://github.com/obsproject/obs-studio.git


			
				
					
						
						
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							#include <stdint.h>
#include <inttypes.h>
#include <math.h>

#include <obs-module.h>
#include <media-io/audio-math.h>

/* -------------------------------------------------------- */

#define do_log(level, format, ...) \
	blog(level, "[compressor: '%s'] " format, \
			obs_source_get_name(cd->context), ##__VA_ARGS__)

#define warn(format, ...)  do_log(LOG_WARNING, format, ##__VA_ARGS__)
#define info(format, ...)  do_log(LOG_INFO,    format, ##__VA_ARGS__)

#ifdef _DEBUG
#define debug(format, ...) do_log(LOG_DEBUG,   format, ##__VA_ARGS__)
#else
#define debug(format, ...)
#endif

/* -------------------------------------------------------- */

#define S_RATIO                         "ratio"
#define S_THRESHOLD                     "threshold"
#define S_ATTACK_TIME                   "attack_time"
#define S_RELEASE_TIME                  "release_time"
#define S_OUTPUT_GAIN                   "output_gain"

#define MT_ obs_module_text
#define TEXT_RATIO                      MT_("Compressor.Ratio")
#define TEXT_THRESHOLD                  MT_("Compressor.Threshold")
#define TEXT_ATTACK_TIME                MT_("Compressor.AttackTime")
#define TEXT_RELEASE_TIME               MT_("Compressor.ReleaseTime")
#define TEXT_OUTPUT_GAIN                MT_("Compressor.OutputGain")

#define MIN_RATIO                       1.0f
#define MAX_RATIO                       32.0f
#define MIN_THRESHOLD_DB                -60.0f
#define MAX_THRESHOLD_DB                0.0f
#define MIN_OUTPUT_GAIN_DB              -32.0f
#define MAX_OUTPUT_GAIN_DB              32.0f
#define MIN_ATK_RLS_MS                  1
#define MAX_ATK_RLS_MS                  300
#define DEFAULT_AUDIO_BUF_MS            10

#define MS_IN_S                         1000
#define MS_IN_S_F                       ((float)MS_IN_S)

/* -------------------------------------------------------- */

struct compressor_data {
	obs_source_t *context;
	float *envelope_buf;
	size_t envelope_buf_len;

	float ratio;
	float threshold;
	float attack_gain;
	float release_gain;
	float output_gain;

	size_t num_channels;
	float envelope;
	float slope;
};

/* -------------------------------------------------------- */

static inline void resize_env_buffer(struct compressor_data *cd, size_t len)
{
	cd->envelope_buf_len = len;
	cd->envelope_buf = brealloc(cd->envelope_buf, len * sizeof(float));
}

static inline float gain_coefficient(uint32_t sample_rate, float time)
{
	return (float)exp(-1.0f / (sample_rate * time));
}

static const char *compressor_name(void *unused)
{
	UNUSED_PARAMETER(unused);
	return obs_module_text("Compressor");
}

static void compressor_update(void *data, obs_data_t *s)
{
	struct compressor_data *cd = data;

	const uint32_t sample_rate =
		audio_output_get_sample_rate(obs_get_audio());
	const size_t num_channels =
		audio_output_get_channels(obs_get_audio());
	const float attack_time_ms =
		(float)obs_data_get_int(s, S_ATTACK_TIME);
	const float release_time_ms =
		(float)obs_data_get_int(s, S_RELEASE_TIME);
	const float output_gain_db =
		(float)obs_data_get_double(s, S_OUTPUT_GAIN);

	if (cd->envelope_buf_len <= 0) {
		resize_env_buffer(cd,
				sample_rate * DEFAULT_AUDIO_BUF_MS / MS_IN_S);
	}

	cd->ratio = (float)obs_data_get_double(s, S_RATIO);
	cd->threshold = (float)obs_data_get_double(s, S_THRESHOLD);
	cd->attack_gain = gain_coefficient(sample_rate,
			attack_time_ms / MS_IN_S_F);
	cd->release_gain = gain_coefficient(sample_rate,
			release_time_ms / MS_IN_S_F);
	cd->output_gain = db_to_mul(output_gain_db);
	cd->num_channels = num_channels;
	cd->slope = 1.0f - (1.0f / cd->ratio);
}

static void *compressor_create(obs_data_t *settings, obs_source_t *filter)
{
	struct compressor_data *cd = bzalloc(sizeof(struct compressor_data));
	cd->context = filter;
	compressor_update(cd, settings);
	return cd;
}

static void compressor_destroy(void *data)
{
	struct compressor_data *cd = data;
	bfree(cd->envelope_buf);
	bfree(cd);
}

static inline void analyze_envelope(struct compressor_data *cd,
	const float **samples, const uint32_t num_samples)
{
	if (cd->envelope_buf_len < num_samples) {
		resize_env_buffer(cd, num_samples);
	}

	memset(cd->envelope_buf, 0, num_samples * sizeof(cd->envelope_buf[0]));
	for (size_t chan = 0; chan < cd->num_channels; ++chan) {
		if (samples[chan]) {
			float env = cd->envelope;
			for (uint32_t i = 0; i < num_samples; ++i) {
				const float env_in = fabsf(samples[chan][i]);
				if (env < env_in) {
					env = env_in + cd->attack_gain *
						(env - env_in);
				} else {
					env = env_in + cd->release_gain *
						(env - env_in);
				}
				cd->envelope_buf[i] = fmaxf(
						cd->envelope_buf[i], env);
			}
		}
	}
	cd->envelope = cd->envelope_buf[num_samples - 1];
}

static inline void process_compression(const struct compressor_data *cd,
	float **samples, uint32_t num_samples)
{
	for (size_t i = 0; i < num_samples; ++i) {
		const float env_db = mul_to_db(cd->envelope_buf[i]);
		float gain = cd->slope * (cd->threshold - env_db);
		gain = db_to_mul(fminf(0, gain));

		for (size_t c = 0; c < cd->num_channels; ++c) {
			if (samples[c]) {
				samples[c][i] *= gain * cd->output_gain;
			}
		}
	}
}

static struct obs_audio_data *compressor_filter_audio(void *data,
	struct obs_audio_data *audio)
{
	struct compressor_data *cd = data;
	const uint32_t num_samples = audio->frames;
	float **samples = (float**)audio->data;

	analyze_envelope(cd, samples, num_samples);
	process_compression(cd, samples, num_samples);

	return audio;
}

static void compressor_defaults(obs_data_t *s)
{
	obs_data_set_default_double(s, S_RATIO, 10.0f);
	obs_data_set_default_double(s, S_THRESHOLD, -18.0f);
	obs_data_set_default_int(s, S_ATTACK_TIME, 6);
	obs_data_set_default_int(s, S_RELEASE_TIME, 60);
	obs_data_set_default_double(s, S_OUTPUT_GAIN, 0.0f);
}

static obs_properties_t *compressor_properties(void *data)
{
	obs_properties_t *props = obs_properties_create();

	obs_properties_add_float_slider(props, S_RATIO,
		TEXT_RATIO, MIN_RATIO, MAX_RATIO, 0.5f);
	obs_properties_add_float_slider(props, S_THRESHOLD,
		TEXT_THRESHOLD, MIN_THRESHOLD_DB, MAX_THRESHOLD_DB, 0.1f);
	obs_properties_add_int_slider(props, S_ATTACK_TIME,
		TEXT_ATTACK_TIME, MIN_ATK_RLS_MS, MAX_ATK_RLS_MS, 1);
	obs_properties_add_int_slider(props, S_RELEASE_TIME,
		TEXT_RELEASE_TIME, MIN_ATK_RLS_MS, MAX_ATK_RLS_MS, 1);
	obs_properties_add_float_slider(props, S_OUTPUT_GAIN,
		TEXT_OUTPUT_GAIN, MIN_OUTPUT_GAIN_DB, MAX_OUTPUT_GAIN_DB, 0.1f);

	UNUSED_PARAMETER(data);
	return props;
}

struct obs_source_info compressor_filter = {
	.id = "compressor_filter",
	.type = OBS_SOURCE_TYPE_FILTER,
	.output_flags = OBS_SOURCE_AUDIO,
	.get_name = compressor_name,
	.create = compressor_create,
	.destroy = compressor_destroy,
	.update = compressor_update,
	.filter_audio = compressor_filter_audio,
	.get_defaults = compressor_defaults,
	.get_properties = compressor_properties,
};