Haha-Yes/node_modules/node-opus/test/old/app.js


"use strict";

var opus = require('../../');
var fs = require('fs');

//
// Generate a sin tone.
//
var freq = 123;
var time = 5;
var rate = 48000;

// Allocate a buffer for the tone. We use 16-bit samples.
var samples = rate*time;
var length = samples*2;
var b = Buffer.alloc(length);

// Generate the tone.
for( var i = 0; i < rate*time; i++ ) {
	var value = Math.round( Math.sin( 2*Math.PI*i*freq/rate ) * Math.pow( 2, 14 ) );
	b.writeInt16LE( value, i*2 );
}

//
// Create the encoder.
//

// Use 20ms frames.
var frame_size = rate * 0.02;
var encoder = new opus.OpusEncoder( rate );

// Open the output streams.
var output = fs.createWriteStream( 'out.opus' );
var input_raw = fs.createWriteStream( 'in.pcm' );
var output_raw = fs.createWriteStream( 'out.pcm' );

var read = 0;
while( b.length > 0 ) {
    var size = Math.min( b.length, frame_size );
    
    // If the input buffer is smaller than the frame_size, copy it into a new 0-padded buffer.
	if( size < frame_size ) {
		var temp = Buffer.alloc( frame_size );
        temp.fill(0);
        b.copy( temp );
        b = temp;
	}

    // We encode frame_size 16-bit samples. This requires a frame_size*2 buffer of bytes.
	var bufferSize = frame_size * 2;
	var toEncode = b.slice(0, bufferSize);
    console.log( frame_size );

    // Encode and decode.
	var encoded = encoder.encode( toEncode );
	var decoded = encoder.decode( encoded );

    // Write the results in the output files.
    input_raw.write( toEncode );
    output.write( encoded );
	output_raw.write( decoded );

    // Move the buffer forward by the buffer size.
    b = b.slice( bufferSize );
}

output.end();
input_raw.end();
output_raw.end();

console.log( 'Wrote following files.' );
console.log( 'in.pcm   : Input PCM signal' );
console.log( 'out.opus : OPUS encoded input signal' );
console.log( 'out.pcm  : Decoded PCM signal' );
commando 2018-09-09 21:20:36 +02:00
			`"use strict";`

			`var opus = require('../../');`
			`var fs = require('fs');`

			`//`
			`// Generate a sin tone.`
			`//`
			`var freq = 123;`
			`var time = 5;`
			`var rate = 48000;`

			`// Allocate a buffer for the tone. We use 16-bit samples.`
			`var samples = rate*time;`
			`var length = samples*2;`
			`var b = Buffer.alloc(length);`

			`// Generate the tone.`
			`for( var i = 0; i < rate*time; i++ ) {`
			`var value = Math.round( Math.sin( 2Math.PIifreq/rate ) Math.pow( 2, 14 ) );`
			`b.writeInt16LE( value, i*2 );`
			`}`

			`//`
			`// Create the encoder.`
			`//`

			`// Use 20ms frames.`
			`var frame_size = rate * 0.02;`
			`var encoder = new opus.OpusEncoder( rate );`

			`// Open the output streams.`
			`var output = fs.createWriteStream( 'out.opus' );`
			`var input_raw = fs.createWriteStream( 'in.pcm' );`
			`var output_raw = fs.createWriteStream( 'out.pcm' );`

			`var read = 0;`
			`while( b.length > 0 ) {`
			`var size = Math.min( b.length, frame_size );`

			`// If the input buffer is smaller than the frame_size, copy it into a new 0-padded buffer.`
			`if( size < frame_size ) {`
			`var temp = Buffer.alloc( frame_size );`
			`temp.fill(0);`
			`b.copy( temp );`
			`b = temp;`
			`}`

			`// We encode frame_size 16-bit samples. This requires a frame_size*2 buffer of bytes.`
			`var bufferSize = frame_size * 2;`
			`var toEncode = b.slice(0, bufferSize);`
			`console.log( frame_size );`

			`// Encode and decode.`
			`var encoded = encoder.encode( toEncode );`
			`var decoded = encoder.decode( encoded );`

			`// Write the results in the output files.`
			`input_raw.write( toEncode );`
			`output.write( encoded );`
			`output_raw.write( decoded );`

			`// Move the buffer forward by the buffer size.`
			`b = b.slice( bufferSize );`
			`}`

			`output.end();`
			`input_raw.end();`
			`output_raw.end();`

			`console.log( 'Wrote following files.' );`
			`console.log( 'in.pcm : Input PCM signal' );`
			`console.log( 'out.opus : OPUS encoded input signal' );`
			`console.log( 'out.pcm : Decoded PCM signal' );`