Funkin/source/funkin/audio/waveform/WaveformDataParser.hx
2024-03-13 18:47:15 -07:00

146 lines
4.8 KiB
Haxe

package funkin.audio.waveform;
import funkin.util.TimerUtil;
class WaveformDataParser
{
static final INT16_MAX:Int = 32767;
static final INT16_MIN:Int = -32768;
static final INT8_MAX:Int = 127;
static final INT8_MIN:Int = -128;
public static function interpretFlxSound(sound:flixel.sound.FlxSound):Null<WaveformData>
{
if (sound == null) return null;
// Method 1. This only works if the sound has been played before.
@:privateAccess
var soundBuffer:Null<lime.media.AudioBuffer> = sound?._channel?.__source?.buffer;
if (soundBuffer == null)
{
// Method 2. This works if the sound has not been played before.
@:privateAccess
soundBuffer = sound?._sound?.__buffer;
if (soundBuffer == null)
{
trace('[WAVEFORM] Failed to interpret FlxSound: ${sound}');
return null;
}
else
{
// trace('[WAVEFORM] Method 2 worked.');
}
}
else
{
// trace('[WAVEFORM] Method 1 worked.');
}
return interpretAudioBuffer(soundBuffer);
}
public static function interpretAudioBuffer(soundBuffer:lime.media.AudioBuffer):Null<WaveformData>
{
var sampleRate = soundBuffer.sampleRate;
var channels = soundBuffer.channels;
var bitsPerSample = soundBuffer.bitsPerSample;
var samplesPerPoint:Int = 256; // I don't think we need to configure this.
var pointsPerSecond:Float = sampleRate / samplesPerPoint; // 172 samples per second for most songs is plenty precise while still being performant..
// TODO: Make this work better on HTML5.
var soundData:lime.utils.Int16Array = cast soundBuffer.data;
var soundDataRawLength:Int = soundData.length;
var soundDataSampleCount:Int = Std.int(Math.ceil(soundDataRawLength / channels / (bitsPerSample == 16 ? 2 : 1)));
var outputPointCount:Int = Std.int(Math.ceil(soundDataSampleCount / samplesPerPoint));
// trace('Interpreting audio buffer:');
// trace(' sampleRate: ${sampleRate}');
// trace(' channels: ${channels}');
// trace(' bitsPerSample: ${bitsPerSample}');
// trace(' samplesPerPoint: ${samplesPerPoint}');
// trace(' pointsPerSecond: ${pointsPerSecond}');
// trace(' soundDataRawLength: ${soundDataRawLength}');
// trace(' soundDataSampleCount: ${soundDataSampleCount}');
// trace(' soundDataRawLength/4: ${soundDataRawLength / 4}');
// trace(' outputPointCount: ${outputPointCount}');
var minSampleValue:Int = bitsPerSample == 16 ? INT16_MIN : INT8_MIN;
var maxSampleValue:Int = bitsPerSample == 16 ? INT16_MAX : INT8_MAX;
var outputData:Array<Int> = [];
var perfStart:Float = TimerUtil.start();
for (pointIndex in 0...outputPointCount)
{
// minChannel1, maxChannel1, minChannel2, maxChannel2, ...
var values:Array<Int> = [];
for (i in 0...channels)
{
values.push(bitsPerSample == 16 ? INT16_MAX : INT8_MAX);
values.push(bitsPerSample == 16 ? INT16_MIN : INT8_MIN);
}
var rangeStart = pointIndex * samplesPerPoint;
var rangeEnd = rangeStart + samplesPerPoint;
if (rangeEnd > soundDataSampleCount) rangeEnd = soundDataSampleCount;
for (sampleIndex in rangeStart...rangeEnd)
{
for (channelIndex in 0...channels)
{
var sampleIndex:Int = sampleIndex * channels + channelIndex;
var sampleValue = soundData[sampleIndex];
if (sampleValue < values[channelIndex * 2]) values[(channelIndex * 2)] = sampleValue;
if (sampleValue > values[channelIndex * 2 + 1]) values[(channelIndex * 2) + 1] = sampleValue;
}
}
// We now have the min and max values for the range.
for (value in values)
outputData.push(value);
}
var outputDataLength:Int = Std.int(outputData.length / channels / 2);
var result = new WaveformData(null, channels, sampleRate, samplesPerPoint, bitsPerSample, outputPointCount, outputData);
trace('[WAVEFORM] Interpreted audio buffer in ${TimerUtil.seconds(perfStart)}.');
return result;
}
public static function parseWaveformData(path:String):Null<WaveformData>
{
var rawJson:String = openfl.Assets.getText(path).trim();
return parseWaveformDataString(rawJson, path);
}
public static function parseWaveformDataString(contents:String, ?fileName:String):Null<WaveformData>
{
var parser = new json2object.JsonParser<WaveformData>();
parser.ignoreUnknownVariables = false;
trace('[WAVEFORM] Parsing waveform data: ${contents}');
parser.fromJson(contents, fileName);
if (parser.errors.length > 0)
{
printErrors(parser.errors, fileName);
return null;
}
return parser.value;
}
static function printErrors(errors:Array<json2object.Error>, id:String = ''):Void
{
trace('[WAVEFORM] Failed to parse waveform data: ${id}');
for (error in errors)
funkin.data.DataError.printError(error);
}
}