cog/Visualization/ThirdParty/deadbeef/analyzer.c

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/*
DeaDBeeF -- the music player
Copyright (C) 2009-2021 Alexey Yakovenko and other contributors
This software is provided 'as-is', without any express or implied
warranty. In no event will the authors be held liable for any damages
arising from the use of this software.
Permission is granted to anyone to use this software for any purpose,
including commercial applications, and to alter it and redistribute it
freely, subject to the following restrictions:
1. The origin of this software must not be misrepresented; you must not
claim that you wrote the original software. If you use this software
in a product, an acknowledgment in the product documentation would be
appreciated but is not required.
2. Altered source versions must be plainly marked as such, and must not be
misrepresented as being the original software.
3. This notice may not be removed or altered from any source distribution.
*/
#include "analyzer.h"
#include <math.h>
#include <stdint.h>
#include <stdio.h>
#include <stdlib.h>
#include <string.h>
#define OCTAVES 11
#define STEPS 24
#define ROOT24 1.0293022366 // pow(2, 1.0 / STEPS)
#define C0 16.3515978313 // 440 * pow(ROOT24, -114);
#pragma mark - Forward declarations
static float
_get_bar_height(ddb_analyzer_t *analyzer, float normalized_height, int view_height);
static void
_generate_frequency_labels(ddb_analyzer_t *analyzer);
static void
_generate_frequency_bars(ddb_analyzer_t *analyzer);
static void
_generate_octave_note_bars(ddb_analyzer_t *analyzer);
static void
_tempered_scale_bands_precalc(ddb_analyzer_t *analyzer);
static float _bin_for_freq_floor(ddb_analyzer_t *analyzer, float freq);
static float _bin_for_freq_round(ddb_analyzer_t *analyzer, float freq);
static float _freq_for_bin(ddb_analyzer_t *analyzer, int bin);
static float
_interpolate_bin_with_ratio(float *fft_data, int bin, float ratio, int fft_size);
#pragma mark - Public
ddb_analyzer_t *
ddb_analyzer_alloc(void) {
return calloc(1, sizeof(ddb_analyzer_t));
}
ddb_analyzer_t *
ddb_analyzer_init(ddb_analyzer_t *analyzer) {
analyzer->mode = DDB_ANALYZER_MODE_FREQUENCIES;
analyzer->min_freq = 50;
analyzer->max_freq = 22000;
analyzer->view_width = 1000;
analyzer->peak_hold = 10;
analyzer->peak_speed_scale = 1000.f;
analyzer->db_lower_bound = -80;
analyzer->octave_bars_step = 1;
analyzer->freq_is_log = 1;
analyzer->bar_gap_denominator = 3;
return analyzer;
}
void ddb_analyzer_dealloc(ddb_analyzer_t *analyzer) {
free(analyzer->tempered_scale_bands);
free(analyzer->fft_data);
memset(analyzer, 0, sizeof(ddb_analyzer_t));
}
void ddb_analyzer_free(ddb_analyzer_t *analyzer) {
free(analyzer);
}
void ddb_analyzer_process(ddb_analyzer_t *analyzer, int samplerate, int channels, const float *fft_data, int fft_size) {
int need_regenerate = 0;
if(channels > 2) {
channels = 2;
}
if(!analyzer->max_of_stereo_data) {
channels = 1;
}
if(analyzer->mode_did_change || channels != analyzer->channels || fft_size != analyzer->fft_size || samplerate != analyzer->samplerate) {
analyzer->channels = channels;
analyzer->fft_size = fft_size;
analyzer->samplerate = samplerate;
free(analyzer->fft_data);
analyzer->fft_data = malloc(fft_size * channels * sizeof(float));
need_regenerate = 1;
analyzer->mode_did_change = 0;
}
memcpy(analyzer->fft_data, fft_data, fft_size * channels * sizeof(float));
if(need_regenerate) {
switch(analyzer->mode) {
case DDB_ANALYZER_MODE_FREQUENCIES:
_generate_frequency_bars(analyzer);
break;
case DDB_ANALYZER_MODE_OCTAVE_NOTE_BANDS:
_generate_octave_note_bars(analyzer);
break;
}
_generate_frequency_labels(analyzer);
}
}
/// Update bars and peaks for the next frame
void ddb_analyzer_tick(ddb_analyzer_t *analyzer) {
if(analyzer->mode_did_change) {
return; // avoid ticks until the next data update
}
// frequency lines
for(int ch = 0; ch < analyzer->channels; ch++) {
float *fft_data = analyzer->fft_data + ch * analyzer->fft_size;
ddb_analyzer_bar_t *bar = analyzer->bars;
for(int i = 0; i < analyzer->bar_count; i++, bar++) {
float norm_h = _interpolate_bin_with_ratio(fft_data, bar->bin, bar->ratio, analyzer->fft_size);
// if the bar spans more than one bin, find the max value
for(int b = bar->bin + 1; b <= bar->last_bin; b++) {
float val = analyzer->fft_data[b];
if(val > norm_h) {
norm_h = val;
}
}
float bound = -analyzer->db_lower_bound;
float height = (20 * log10(norm_h) + bound) / bound;
if(ch == 0) {
bar->height = height;
} else if(height > bar->height) {
bar->height = height;
}
}
}
// peaks
ddb_analyzer_bar_t *bar = analyzer->bars;
for(int i = 0; i < analyzer->bar_count; i++, bar++) {
if(bar->peak < bar->height) {
bar->peak = bar->height;
bar->peak_speed = analyzer->peak_hold;
}
if(bar->peak_speed-- < 0) {
bar->peak += bar->peak_speed / analyzer->peak_speed_scale;
if(bar->peak < bar->height) {
bar->peak = bar->height;
}
}
}
}
void ddb_analyzer_get_draw_data(ddb_analyzer_t *analyzer, int view_width, int view_height, ddb_analyzer_draw_data_t *draw_data) {
if(draw_data->bar_count != analyzer->bar_count) {
free(draw_data->bars);
draw_data->bars = calloc(analyzer->bar_count, sizeof(ddb_analyzer_draw_bar_t));
draw_data->bar_count = analyzer->bar_count;
}
if(analyzer->mode == DDB_ANALYZER_MODE_FREQUENCIES) {
draw_data->bar_width = 1;
} else if(analyzer->mode == DDB_ANALYZER_MODE_OCTAVE_NOTE_BANDS) {
if(analyzer->fractional_bars) {
float width = (float)view_width / analyzer->bar_count;
float gap = analyzer->bar_gap_denominator > 0 ? width / analyzer->bar_gap_denominator : 0;
draw_data->bar_width = width - gap;
} else {
int width = view_width / analyzer->bar_count;
int gap = analyzer->bar_gap_denominator > 0 ? width / analyzer->bar_gap_denominator : 0;
if(gap < 1) {
gap = 1;
}
if(width <= 1) {
width = 1;
gap = 0;
}
draw_data->bar_width = width - gap;
}
}
ddb_analyzer_bar_t *bar = analyzer->bars;
ddb_analyzer_draw_bar_t *draw_bar = draw_data->bars;
for(int i = 0; i < analyzer->bar_count; i++, bar++, draw_bar++) {
float height = bar->height;
draw_bar->bar_height = _get_bar_height(analyzer, height, view_height);
draw_bar->xpos = bar->xpos * view_width;
draw_bar->peak_ypos = _get_bar_height(analyzer, bar->peak, view_height);
}
memcpy(draw_data->label_freq_texts, analyzer->label_freq_texts, sizeof(analyzer->label_freq_texts));
for(int i = 0; i < analyzer->label_freq_count; i++) {
draw_data->label_freq_positions[i] = analyzer->label_freq_positions[i] * view_width;
}
draw_data->label_freq_count = analyzer->label_freq_count;
}
void ddb_analyzer_draw_data_dealloc(ddb_analyzer_draw_data_t *draw_data) {
free(draw_data->bars);
memset(draw_data, 0, sizeof(ddb_analyzer_draw_data_t));
}
#pragma mark - Private
static float
_get_bar_height(ddb_analyzer_t *analyzer, float normalized_height, int view_height) {
float height = normalized_height;
if(height < 0) {
height = 0;
} else if(height > 1) {
height = 1;
}
height *= view_height;
return height;
}
static void
_generate_frequency_labels(ddb_analyzer_t *analyzer) {
float min_freq_log = log10(analyzer->min_freq);
float max_freq_log = log10(analyzer->max_freq);
float view_width = analyzer->view_width;
float width_log = view_width / (max_freq_log - min_freq_log);
// calculate the distance between any 2 neighbour labels
float freq = 64000;
float freq2 = 32000;
float pos = width_log * (log10(freq) - min_freq_log) / view_width;
float pos2 = width_log * (log10(freq2) - min_freq_log) / view_width;
float dist = pos - pos2;
// generate position and text for each label
int index = 0;
while(freq > 30 && index < DDB_ANALYZER_MAX_LABEL_FREQS) {
analyzer->label_freq_positions[index] = pos;
if(freq < 1000) {
snprintf(analyzer->label_freq_texts[index], sizeof(analyzer->label_freq_texts[index]), "%d", (int)round(freq));
} else {
snprintf(analyzer->label_freq_texts[index], sizeof(analyzer->label_freq_texts[index]), "%dk", ((int)freq) / 1000);
}
pos -= dist;
freq /= 2;
index += 1;
}
analyzer->label_freq_count = index;
}
static void
_generate_frequency_bars(ddb_analyzer_t *analyzer) {
float min_freq = analyzer->min_freq;
float min_freq_log;
float view_width = analyzer->view_width;
float width;
if(analyzer->freq_is_log) {
min_freq_log = log10(analyzer->min_freq);
float max_freq_log = log10(analyzer->max_freq);
width = view_width / (max_freq_log - min_freq_log);
} else {
min_freq = analyzer->min_freq;
width = view_width / (analyzer->max_freq - min_freq);
}
float minIndex = _bin_for_freq_floor(analyzer, analyzer->min_freq);
float maxIndex = _bin_for_freq_round(analyzer, analyzer->max_freq);
int prev = -1;
analyzer->bar_count = 0;
if(analyzer->bar_count_max != analyzer->view_width) {
free(analyzer->bars);
analyzer->bars = calloc(analyzer->view_width, sizeof(ddb_analyzer_bar_t));
analyzer->bar_count_max = analyzer->view_width;
}
for(int i = minIndex; i <= maxIndex; i++) {
float freq = _freq_for_bin(analyzer, i);
// FIXME: only int position!
int pos;
if(analyzer->freq_is_log)
pos = width * (log10(freq) - min_freq_log);
else
pos = width * (freq - min_freq);
if(pos > prev && pos >= 0) {
// start accumulating frequencies for the new band
ddb_analyzer_bar_t *bar = analyzer->bars + analyzer->bar_count;
bar->xpos = pos / view_width; // normalized position
bar->bin = i;
bar->ratio = 0;
analyzer->bar_count += 1;
prev = pos;
}
}
}
static void
_generate_octave_note_bars(ddb_analyzer_t *analyzer) {
analyzer->bar_count = 0;
_tempered_scale_bands_precalc(analyzer);
if(analyzer->bar_count_max != OCTAVES * STEPS) {
free(analyzer->bars);
analyzer->bars = calloc(OCTAVES * STEPS, sizeof(ddb_analyzer_bar_t));
analyzer->bar_count_max = OCTAVES * STEPS;
}
int minBand = -1;
/*int maxBand = -1;*/
ddb_analyzer_bar_t *prev_bar = NULL;
for(int i = 0; i < OCTAVES * STEPS; i += analyzer->octave_bars_step) {
ddb_analyzer_band_t *band = &analyzer->tempered_scale_bands[i];
if(band->freq < analyzer->min_freq || band->freq > analyzer->max_freq) {
continue;
}
if(minBand == -1) {
minBand = i;
}
/*maxBand = i;*/
ddb_analyzer_bar_t *bar = analyzer->bars + analyzer->bar_count;
int bin = _bin_for_freq_floor(analyzer, band->freq);
bar->bin = bin;
bar->last_bin = 0;
bar->ratio = 0;
// interpolation ratio of next bin of previous bar to the first bin of this bar
if(prev_bar && bin - 1 > prev_bar->bin) {
prev_bar->last_bin = bin - 1;
}
analyzer->bar_count += 1;
// get interpolation ratio to the next bin
int bin2 = bin + 1;
if(bin2 < analyzer->fft_size) {
float p = log10(band->freq);
float p1 = log10(_freq_for_bin(analyzer, bin));
float p2 = log10(_freq_for_bin(analyzer, bin2));
float d = p2 - p1;
bar->ratio = (p - p1) / d;
}
prev_bar = bar;
}
for(int i = 0; i < analyzer->bar_count; i++) {
analyzer->bars[i].xpos = (float)i / analyzer->bar_count;
}
}
static float _bin_for_freq_floor(ddb_analyzer_t *analyzer, float freq) {
float max = analyzer->fft_size - 1;
float bin = floor(freq * analyzer->fft_size / analyzer->samplerate);
return bin < max ? bin : max;
}
static float _bin_for_freq_round(ddb_analyzer_t *analyzer, float freq) {
float max = analyzer->fft_size - 1;
float bin = round(freq * analyzer->fft_size / analyzer->samplerate);
return bin < max ? bin : max;
}
static float _freq_for_bin(ddb_analyzer_t *analyzer, int bin) {
return (int64_t)bin * analyzer->samplerate / analyzer->fft_size;
}
// Precalculate data for tempered scale
static void
_tempered_scale_bands_precalc(ddb_analyzer_t *analyzer) {
if(analyzer->tempered_scale_bands != NULL) {
return;
}
analyzer->tempered_scale_bands = calloc(OCTAVES * STEPS, sizeof(ddb_analyzer_band_t));
for(int i = 0; i < OCTAVES * STEPS; i++) {
float f = C0 * pow(ROOT24, i);
float bin = _bin_for_freq_floor(analyzer, f);
float binf = _freq_for_bin(analyzer, bin);
float fn = _freq_for_bin(analyzer, bin + 1);
float ratio = (f - binf) / (fn - binf);
analyzer->tempered_scale_bands[i].bin = bin;
analyzer->tempered_scale_bands[i].freq = f;
analyzer->tempered_scale_bands[i].ratio = ratio;
}
}
static float
_interpolate_bin_with_ratio(float *fft_data, int bin, float ratio, int fft_size) {
return bin < fft_size ? (bin + 1 < fft_size ? (fft_data[bin] + (fft_data[bin + 1] - fft_data[bin]) * ratio) : fft_data[bin]) : 0.0;
}