LayoutTests/webaudio/resources/fft.js - WebKit - Git at Google

 // FFT routines.  Obtained from
 // https://github.com/rtoy/js-hacks/blob/master/fft/fft-r2-nn.js.
 //
 // Create an FFT object of order |order|.  This will
 // compute forward and inverse FFTs of length 2^|order|.
 function FFT(order) {
   if (order <= 1) {
     throw new this.FFTException(order);
   }

   this.order = order;
   this.N = 1 << order;
   this.halfN = 1 << (order - 1);

   // Internal variables needed for computing each stage of the FFT.
   this.pairsInGroup = 0;
   this.numberOfGroups = 0;
   this.distance = 0;
   this.notSwitchInput = 0;

   // Work arrays
   this.aReal = new Float32Array(this.N);
   this.aImag = new Float32Array(this.N);
   this.debug = 0;

   // Twiddle tables for the FFT.
   this.twiddleCos = new Float32Array(this.N);
   this.twiddleSin = new Float32Array(this.N);

   let omega = -2 * Math.PI / this.N;
   for (let k = 0; k < this.N; ++k) {
     this.twiddleCos[k] = Math.fround(Math.cos(omega * k));
     this.twiddleSin[k] = Math.fround(Math.sin(omega * k));
   }
 }

 FFT.prototype.FFTException =
     function(order) {
   this.value = order;
   this.message = 'Order must be greater than 1: ';
   this.toString = function() {
     return this.message + this.value;
   };
 }

     // Core routine that does one stage of the FFT, implementing all of
     // the butterflies for that stage.
     FFT.prototype.FFTRadix2Core =
         function(aReal, aImag, bReal, bImag) {
   let index = 0;
   for (let k = 0; k < this.numberOfGroups; ++k) {
     let jfirst = 2 * k * this.pairsInGroup;
     let jlast = jfirst + this.pairsInGroup - 1;
     let jtwiddle = k * this.pairsInGroup;
     let wr = this.twiddleCos[jtwiddle];
     let wi = this.twiddleSin[jtwiddle];

     for (let j = jfirst; j <= jlast; ++j) {
       // temp = w * a[j + distance]
       let idx = j + this.distance;
       let tr = wr * aReal[idx] - wi * aImag[idx];
       let ti = wr * aImag[idx] + wi * aReal[idx];

       bReal[index] = aReal[j] + tr;
       bImag[index] = aImag[j] + ti;
       bReal[index + this.halfN] = aReal[j] - tr;
       bImag[index + this.halfN] = aImag[j] - ti;
       ++index;
     }
   }
 }

         // Forward out-of-place complex FFT.
         //
         // Computes the forward FFT, b,  of a complex vector x:
         //
         //   b[k] = sum(x[n] * W^(k*n), n, 0, N - 1), k = 0, 1,..., N-1
         //
         // where
         //   N = length of x, which must be a power of 2 and
         //   W = exp(-2*i*pi/N)
         //
         //   x = |xr| + i*|xi|
         //   b = |bReal| + i*|bImag|
         FFT.prototype.fft =
             function(xr, xi, bReal, bImag) {
   this.pairsInGroup = this.halfN;
   this.numberOfGroups = 1;
   this.distance = this.halfN;
   this.notSwitchInput = true;

   // Arrange it so that the last iteration puts the desired output
   // in bReal/bImag.
   if (this.order & 1 == 1) {
     this.FFTRadix2Core(xr, xi, bReal, bImag);
     this.notSwitchInput = !this.notSwitchInput;
   } else {
     this.FFTRadix2Core(xr, xi, this.aReal, this.aImag);
   }

   this.pairsInGroup >>= 1;
   this.numberOfGroups <<= 1;
   this.distance >>= 1;

   while (this.numberOfGroups < this.N) {
     if (this.notSwitchInput) {
       this.FFTRadix2Core(this.aReal, this.aImag, bReal, bImag);
     } else {
       this.FFTRadix2Core(bReal, bImag, this.aReal, this.aImag);
     }

     this.notSwitchInput = !this.notSwitchInput;
     this.pairsInGroup >>= 1;
     this.numberOfGroups <<= 1;
     this.distance >>= 1;
   }
 }

             // Core routine that does one stage of the FFT, implementing all of
             // the butterflies for that stage.  This is identical to
             // FFTRadix2Core, except the twiddle factor, w, is the conjugate.
             FFT.prototype.iFFTRadix2Core =
                 function(aReal, aImag, bReal, bImag) {
   let index = 0;
   for (let k = 0; k < this.numberOfGroups; ++k) {
     let jfirst = 2 * k * this.pairsInGroup;
     let jlast = jfirst + this.pairsInGroup - 1;
     let jtwiddle = k * this.pairsInGroup;
     let wr = this.twiddleCos[jtwiddle];
     let wi = -this.twiddleSin[jtwiddle];

     for (let j = jfirst; j <= jlast; ++j) {
       // temp = w * a[j + distance]
       let idx = j + this.distance;
       let tr = wr * aReal[idx] - wi * aImag[idx];
       let ti = wr * aImag[idx] + wi * aReal[idx];

       bReal[index] = aReal[j] + tr;
       bImag[index] = aImag[j] + ti;
       bReal[index + this.halfN] = aReal[j] - tr;
       bImag[index + this.halfN] = aImag[j] - ti;
       ++index;
     }
   }
 }

                 // Inverse out-of-place complex FFT.
                 //
                 // Computes the inverse FFT, b,  of a complex vector x:
                 //
                 //   b[k] = sum(x[n] * W^(-k*n), n, 0, N - 1), k = 0, 1,..., N-1
                 //
                 // where
                 //   N = length of x, which must be a power of 2 and
                 //   W = exp(-2*i*pi/N)
                 //
                 //   x = |xr| + i*|xi|
                 //   b = |bReal| + i*|bImag|
                 //
                 // Note that ifft(fft(x)) = N * x.  To get x, call ifftScale to
                 // scale the output of the ifft appropriately.
                 FFT.prototype.ifft =
                     function(xr, xi, bReal, bImag) {
   this.pairsInGroup = this.halfN;
   this.numberOfGroups = 1;
   this.distance = this.halfN;
   this.notSwitchInput = true;

   // Arrange it so that the last iteration puts the desired output
   // in bReal/bImag.
   if (this.order & 1 == 1) {
     this.iFFTRadix2Core(xr, xi, bReal, bImag);
     this.notSwitchInput = !this.notSwitchInput;
   } else {
     this.iFFTRadix2Core(xr, xi, this.aReal, this.aImag);
   }

   this.pairsInGroup >>= 1;
   this.numberOfGroups <<= 1;
   this.distance >>= 1;

   while (this.numberOfGroups < this.N) {
     if (this.notSwitchInput) {
       this.iFFTRadix2Core(this.aReal, this.aImag, bReal, bImag);
     } else {
       this.iFFTRadix2Core(bReal, bImag, this.aReal, this.aImag);
     }

     this.notSwitchInput = !this.notSwitchInput;
     this.pairsInGroup >>= 1;
     this.numberOfGroups <<= 1;
     this.distance >>= 1;
   }
 }

                     //
                     // Scales the IFFT by 1/N, done in place.
                     FFT.prototype.ifftScale =
                         function(xr, xi) {
   let factor = 1 / this.N;
   for (let k = 0; k < this.N; ++k) {
     xr[k] *= factor;
     xi[k] *= factor;
   }
 }

                         // First stage for the RFFT.  Basically the same as
                         // FFTRadix2Core, but we assume aImag is 0, and adjust
                         // the code accordingly.
                         FFT.prototype.RFFTRadix2CoreStage1 =
                             function(aReal, bReal, bImag) {
   let index = 0;
   for (let k = 0; k < this.numberOfGroups; ++k) {
     let jfirst = 2 * k * this.pairsInGroup;
     let jlast = jfirst + this.pairsInGroup - 1;
     let jtwiddle = k * this.pairsInGroup;
     let wr = this.twiddleCos[jtwiddle];
     let wi = this.twiddleSin[jtwiddle];

     for (let j = jfirst; j <= jlast; ++j) {
       // temp = w * a[j + distance]
       let idx = j + this.distance;
       let tr = wr * aReal[idx];
       let ti = wi * aReal[idx];

       bReal[index] = aReal[j] + tr;
       bImag[index] = ti;
       bReal[index + this.halfN] = aReal[j] - tr;
       bImag[index + this.halfN] = -ti;
       ++index;
     }
   }
 }

                             // Forward Real FFT.  Like fft, but the signal is
                             // assumed to be real, so the imaginary part is not
                             // supplied.  The output, however, is still the same
                             // and is returned in two arrays.  (This could be
                             // optimized to use less storage, both internally
                             // and for the output, but we don't do that.)
                             FFT.prototype.rfft = function(xr, bReal, bImag) {
   this.pairsInGroup = this.halfN;
   this.numberOfGroups = 1;
   this.distance = this.halfN;
   this.notSwitchInput = true;

   // Arrange it so that the last iteration puts the desired output
   // in bReal/bImag.
   if (this.order & 1 == 1) {
     this.RFFTRadix2CoreStage1(xr, bReal, bImag);
     this.notSwitchInput = !this.notSwitchInput;
   } else {
     this.RFFTRadix2CoreStage1(xr, this.aReal, this.aImag);
   }

   this.pairsInGroup >>= 1;
   this.numberOfGroups <<= 1;
   this.distance >>= 1;

   while (this.numberOfGroups < this.N) {
     if (this.notSwitchInput) {
       this.FFTRadix2Core(this.aReal, this.aImag, bReal, bImag);
     } else {
       this.FFTRadix2Core(bReal, bImag, this.aReal, this.aImag);
     }

     this.notSwitchInput = !this.notSwitchInput;
     this.pairsInGroup >>= 1;
     this.numberOfGroups <<= 1;
     this.distance >>= 1;
   }
 }
	// FFT routines. Obtained from
	// https://github.com/rtoy/js-hacks/blob/master/fft/fft-r2-nn.js.
	//
	// Create an FFT object of order \|order\|. This will
	// compute forward and inverse FFTs of length 2^\|order\|.
	function FFT(order) {
	if (order <= 1) {
	throw new this.FFTException(order);
	}

	this.order = order;
	this.N = 1 << order;
	this.halfN = 1 << (order - 1);

	// Internal variables needed for computing each stage of the FFT.
	this.pairsInGroup = 0;
	this.numberOfGroups = 0;
	this.distance = 0;
	this.notSwitchInput = 0;

	// Work arrays
	this.aReal = new Float32Array(this.N);
	this.aImag = new Float32Array(this.N);
	this.debug = 0;

	// Twiddle tables for the FFT.
	this.twiddleCos = new Float32Array(this.N);
	this.twiddleSin = new Float32Array(this.N);

	let omega = -2 * Math.PI / this.N;
	for (let k = 0; k < this.N; ++k) {
	this.twiddleCos[k] = Math.fround(Math.cos(omega * k));
	this.twiddleSin[k] = Math.fround(Math.sin(omega * k));
	}
	}

	FFT.prototype.FFTException =
	function(order) {
	this.value = order;
	this.message = 'Order must be greater than 1: ';
	this.toString = function() {
	return this.message + this.value;
	};
	}

	// Core routine that does one stage of the FFT, implementing all of
	// the butterflies for that stage.
	FFT.prototype.FFTRadix2Core =
	function(aReal, aImag, bReal, bImag) {
	let index = 0;
	for (let k = 0; k < this.numberOfGroups; ++k) {
	let jfirst = 2 * k * this.pairsInGroup;
	let jlast = jfirst + this.pairsInGroup - 1;
	let jtwiddle = k * this.pairsInGroup;
	let wr = this.twiddleCos[jtwiddle];
	let wi = this.twiddleSin[jtwiddle];

	for (let j = jfirst; j <= jlast; ++j) {
	// temp = w * a[j + distance]
	let idx = j + this.distance;
	let tr = wr * aReal[idx] - wi * aImag[idx];
	let ti = wr * aImag[idx] + wi * aReal[idx];

	bReal[index] = aReal[j] + tr;
	bImag[index] = aImag[j] + ti;
	bReal[index + this.halfN] = aReal[j] - tr;
	bImag[index + this.halfN] = aImag[j] - ti;
	++index;
	}
	}
	}

	// Forward out-of-place complex FFT.
	//
	// Computes the forward FFT, b, of a complex vector x:
	//
	// b[k] = sum(x[n] * W^(k*n), n, 0, N - 1), k = 0, 1,..., N-1
	//
	// where
	// N = length of x, which must be a power of 2 and
	// W = exp(-2ipi/N)
	//
	// x = \|xr\| + i*\|xi\|
	// b = \|bReal\| + i*\|bImag\|
	FFT.prototype.fft =
	function(xr, xi, bReal, bImag) {
	this.pairsInGroup = this.halfN;
	this.numberOfGroups = 1;
	this.distance = this.halfN;
	this.notSwitchInput = true;

	// Arrange it so that the last iteration puts the desired output
	// in bReal/bImag.
	if (this.order & 1 == 1) {
	this.FFTRadix2Core(xr, xi, bReal, bImag);
	this.notSwitchInput = !this.notSwitchInput;
	} else {
	this.FFTRadix2Core(xr, xi, this.aReal, this.aImag);
	}

	this.pairsInGroup >>= 1;
	this.numberOfGroups <<= 1;
	this.distance >>= 1;

	while (this.numberOfGroups < this.N) {
	if (this.notSwitchInput) {
	this.FFTRadix2Core(this.aReal, this.aImag, bReal, bImag);
	} else {
	this.FFTRadix2Core(bReal, bImag, this.aReal, this.aImag);
	}

	this.notSwitchInput = !this.notSwitchInput;
	this.pairsInGroup >>= 1;
	this.numberOfGroups <<= 1;
	this.distance >>= 1;
	}
	}

	// Core routine that does one stage of the FFT, implementing all of
	// the butterflies for that stage. This is identical to
	// FFTRadix2Core, except the twiddle factor, w, is the conjugate.
	FFT.prototype.iFFTRadix2Core =
	function(aReal, aImag, bReal, bImag) {
	let index = 0;
	for (let k = 0; k < this.numberOfGroups; ++k) {
	let jfirst = 2 * k * this.pairsInGroup;
	let jlast = jfirst + this.pairsInGroup - 1;
	let jtwiddle = k * this.pairsInGroup;
	let wr = this.twiddleCos[jtwiddle];
	let wi = -this.twiddleSin[jtwiddle];

	for (let j = jfirst; j <= jlast; ++j) {
	// temp = w * a[j + distance]
	let idx = j + this.distance;
	let tr = wr * aReal[idx] - wi * aImag[idx];
	let ti = wr * aImag[idx] + wi * aReal[idx];

	bReal[index] = aReal[j] + tr;
	bImag[index] = aImag[j] + ti;
	bReal[index + this.halfN] = aReal[j] - tr;
	bImag[index + this.halfN] = aImag[j] - ti;
	++index;
	}
	}
	}

	// Inverse out-of-place complex FFT.
	//
	// Computes the inverse FFT, b, of a complex vector x:
	//
	// b[k] = sum(x[n] * W^(-k*n), n, 0, N - 1), k = 0, 1,..., N-1
	//
	// where
	// N = length of x, which must be a power of 2 and
	// W = exp(-2ipi/N)
	//
	// x = \|xr\| + i*\|xi\|
	// b = \|bReal\| + i*\|bImag\|
	//
	// Note that ifft(fft(x)) = N * x. To get x, call ifftScale to
	// scale the output of the ifft appropriately.
	FFT.prototype.ifft =
	function(xr, xi, bReal, bImag) {
	this.pairsInGroup = this.halfN;
	this.numberOfGroups = 1;
	this.distance = this.halfN;
	this.notSwitchInput = true;

	// Arrange it so that the last iteration puts the desired output
	// in bReal/bImag.
	if (this.order & 1 == 1) {
	this.iFFTRadix2Core(xr, xi, bReal, bImag);
	this.notSwitchInput = !this.notSwitchInput;
	} else {
	this.iFFTRadix2Core(xr, xi, this.aReal, this.aImag);
	}

	this.pairsInGroup >>= 1;
	this.numberOfGroups <<= 1;
	this.distance >>= 1;

	while (this.numberOfGroups < this.N) {
	if (this.notSwitchInput) {
	this.iFFTRadix2Core(this.aReal, this.aImag, bReal, bImag);
	} else {
	this.iFFTRadix2Core(bReal, bImag, this.aReal, this.aImag);
	}

	this.notSwitchInput = !this.notSwitchInput;
	this.pairsInGroup >>= 1;
	this.numberOfGroups <<= 1;
	this.distance >>= 1;
	}
	}

	//
	// Scales the IFFT by 1/N, done in place.
	FFT.prototype.ifftScale =
	function(xr, xi) {
	let factor = 1 / this.N;
	for (let k = 0; k < this.N; ++k) {
	xr[k] *= factor;
	xi[k] *= factor;
	}
	}

	// First stage for the RFFT. Basically the same as
	// FFTRadix2Core, but we assume aImag is 0, and adjust
	// the code accordingly.
	FFT.prototype.RFFTRadix2CoreStage1 =
	function(aReal, bReal, bImag) {
	let index = 0;
	for (let k = 0; k < this.numberOfGroups; ++k) {
	let jfirst = 2 * k * this.pairsInGroup;
	let jlast = jfirst + this.pairsInGroup - 1;
	let jtwiddle = k * this.pairsInGroup;
	let wr = this.twiddleCos[jtwiddle];
	let wi = this.twiddleSin[jtwiddle];

	for (let j = jfirst; j <= jlast; ++j) {
	// temp = w * a[j + distance]
	let idx = j + this.distance;
	let tr = wr * aReal[idx];
	let ti = wi * aReal[idx];

	bReal[index] = aReal[j] + tr;
	bImag[index] = ti;
	bReal[index + this.halfN] = aReal[j] - tr;
	bImag[index + this.halfN] = -ti;
	++index;
	}
	}
	}

	// Forward Real FFT. Like fft, but the signal is
	// assumed to be real, so the imaginary part is not
	// supplied. The output, however, is still the same
	// and is returned in two arrays. (This could be
	// optimized to use less storage, both internally
	// and for the output, but we don't do that.)
	FFT.prototype.rfft = function(xr, bReal, bImag) {
	this.pairsInGroup = this.halfN;
	this.numberOfGroups = 1;
	this.distance = this.halfN;
	this.notSwitchInput = true;

	// Arrange it so that the last iteration puts the desired output
	// in bReal/bImag.
	if (this.order & 1 == 1) {
	this.RFFTRadix2CoreStage1(xr, bReal, bImag);
	this.notSwitchInput = !this.notSwitchInput;
	} else {
	this.RFFTRadix2CoreStage1(xr, this.aReal, this.aImag);
	}

	this.pairsInGroup >>= 1;
	this.numberOfGroups <<= 1;
	this.distance >>= 1;

	while (this.numberOfGroups < this.N) {
	if (this.notSwitchInput) {
	this.FFTRadix2Core(this.aReal, this.aImag, bReal, bImag);
	} else {
	this.FFTRadix2Core(bReal, bImag, this.aReal, this.aImag);
	}

	this.notSwitchInput = !this.notSwitchInput;
	this.pairsInGroup >>= 1;
	this.numberOfGroups <<= 1;
	this.distance >>= 1;
	}
	}