common_audio/signal_processing/spl_sqrt.c - src - Git at Google

 /*
  *  Copyright (c) 2011 The WebRTC project authors. All Rights Reserved.
  *
  *  Use of this source code is governed by a BSD-style license
  *  that can be found in the LICENSE file in the root of the source
  *  tree. An additional intellectual property rights grant can be found
  *  in the file PATENTS.  All contributing project authors may
  *  be found in the AUTHORS file in the root of the source tree.
  */


 /*
  * This file contains the function WebRtcSpl_Sqrt().
  * The description header can be found in signal_processing_library.h
  *
  */

 #include "rtc_base/checks.h"
 #include "common_audio/signal_processing/include/signal_processing_library.h"

 int32_t WebRtcSpl_SqrtLocal(int32_t in);

 int32_t WebRtcSpl_SqrtLocal(int32_t in)
 {

     int16_t x_half, t16;
     int32_t A, B, x2;

     /* The following block performs:
      y=in/2
      x=y-2^30
      x_half=x/2^31
      t = 1 + (x_half) - 0.5*((x_half)^2) + 0.5*((x_half)^3) - 0.625*((x_half)^4)
          + 0.875*((x_half)^5)
      */

     B = in / 2;

     B = B - ((int32_t)0x40000000); // B = in/2 - 1/2
     x_half = (int16_t)(B >> 16);  // x_half = x/2 = (in-1)/2
     B = B + ((int32_t)0x40000000); // B = 1 + x/2
     B = B + ((int32_t)0x40000000); // Add 0.5 twice (since 1.0 does not exist in Q31)

     x2 = ((int32_t)x_half) * ((int32_t)x_half) * 2; // A = (x/2)^2
     A = -x2; // A = -(x/2)^2
     B = B + (A >> 1); // B = 1 + x/2 - 0.5*(x/2)^2

     A >>= 16;
     A = A * A * 2; // A = (x/2)^4
     t16 = (int16_t)(A >> 16);
     B += -20480 * t16 * 2;  // B = B - 0.625*A
     // After this, B = 1 + x/2 - 0.5*(x/2)^2 - 0.625*(x/2)^4

     A = x_half * t16 * 2;  // A = (x/2)^5
     t16 = (int16_t)(A >> 16);
     B += 28672 * t16 * 2;  // B = B + 0.875*A
     // After this, B = 1 + x/2 - 0.5*(x/2)^2 - 0.625*(x/2)^4 + 0.875*(x/2)^5

     t16 = (int16_t)(x2 >> 16);
     A = x_half * t16 * 2;  // A = x/2^3

     B = B + (A >> 1); // B = B + 0.5*A
     // After this, B = 1 + x/2 - 0.5*(x/2)^2 + 0.5*(x/2)^3 - 0.625*(x/2)^4 + 0.875*(x/2)^5

     B = B + ((int32_t)32768); // Round off bit

     return B;
 }

 int32_t WebRtcSpl_Sqrt(int32_t value)
 {
     /*
      Algorithm:

      Six term Taylor Series is used here to compute the square root of a number
      y^0.5 = (1+x)^0.5 where x = y-1
      = 1+(x/2)-0.5*((x/2)^2+0.5*((x/2)^3-0.625*((x/2)^4+0.875*((x/2)^5)
      0.5 <= x < 1

      Example of how the algorithm works, with ut=sqrt(in), and
      with in=73632 and ut=271 (even shift value case):

      in=73632
      y= in/131072
      x=y-1
      t = 1 + (x/2) - 0.5*((x/2)^2) + 0.5*((x/2)^3) - 0.625*((x/2)^4) + 0.875*((x/2)^5)
      ut=t*(1/sqrt(2))*512

      or:

      in=73632
      in2=73632*2^14
      y= in2/2^31
      x=y-1
      t = 1 + (x/2) - 0.5*((x/2)^2) + 0.5*((x/2)^3) - 0.625*((x/2)^4) + 0.875*((x/2)^5)
      ut=t*(1/sqrt(2))
      ut2=ut*2^9

      which gives:

      in  = 73632
      in2 = 1206386688
      y   = 0.56176757812500
      x   = -0.43823242187500
      t   = 0.74973506527313
      ut  = 0.53014274874797
      ut2 = 2.714330873589594e+002

      or:

      in=73632
      in2=73632*2^14
      y=in2/2
      x=y-2^30
      x_half=x/2^31
      t = 1 + (x_half) - 0.5*((x_half)^2) + 0.5*((x_half)^3) - 0.625*((x_half)^4)
          + 0.875*((x_half)^5)
      ut=t*(1/sqrt(2))
      ut2=ut*2^9

      which gives:

      in  = 73632
      in2 = 1206386688
      y   = 603193344
      x   = -470548480
      x_half =  -0.21911621093750
      t   = 0.74973506527313
      ut  = 0.53014274874797
      ut2 = 2.714330873589594e+002

      */

     int16_t x_norm, nshift, t16, sh;
     int32_t A;

     int16_t k_sqrt_2 = 23170; // 1/sqrt2 (==5a82)

     A = value;

     // The convention in this function is to calculate sqrt(abs(A)). Negate the
     // input if it is negative.
     if (A < 0) {
         if (A == WEBRTC_SPL_WORD32_MIN) {
             // This number cannot be held in an int32_t after negating.
             // Map it to the maximum positive value.
             A = WEBRTC_SPL_WORD32_MAX;
         } else {
             A = -A;
         }
     } else if (A == 0) {
         return 0;  // sqrt(0) = 0
     }

     sh = WebRtcSpl_NormW32(A); // # shifts to normalize A
     A = WEBRTC_SPL_LSHIFT_W32(A, sh); // Normalize A
     if (A < (WEBRTC_SPL_WORD32_MAX - 32767))
     {
         A = A + ((int32_t)32768); // Round off bit
     } else
     {
         A = WEBRTC_SPL_WORD32_MAX;
     }

     x_norm = (int16_t)(A >> 16);  // x_norm = AH

     nshift = (sh / 2);
     RTC_DCHECK_GE(nshift, 0);

     A = (int32_t)WEBRTC_SPL_LSHIFT_W32((int32_t)x_norm, 16);
     A = WEBRTC_SPL_ABS_W32(A); // A = abs(x_norm<<16)
     A = WebRtcSpl_SqrtLocal(A); // A = sqrt(A)

     if (2 * nshift == sh) {
         // Even shift value case

         t16 = (int16_t)(A >> 16);  // t16 = AH

         A = k_sqrt_2 * t16 * 2;  // A = 1/sqrt(2)*t16
         A = A + ((int32_t)32768); // Round off
         A = A & ((int32_t)0x7fff0000); // Round off

         A >>= 15;  // A = A>>16

     } else
     {
         A >>= 16;  // A = A>>16
     }

     A = A & ((int32_t)0x0000ffff);
     A >>= nshift;  // De-normalize the result.

     return A;
 }
	/*
	* Copyright (c) 2011 The WebRTC project authors. All Rights Reserved.
	*
	* Use of this source code is governed by a BSD-style license
	* that can be found in the LICENSE file in the root of the source
	* tree. An additional intellectual property rights grant can be found
	* in the file PATENTS. All contributing project authors may
	* be found in the AUTHORS file in the root of the source tree.
	*/


	/*
	* This file contains the function WebRtcSpl_Sqrt().
	* The description header can be found in signal_processing_library.h
	*
	*/

	#include "rtc_base/checks.h"
	#include "common_audio/signal_processing/include/signal_processing_library.h"

	int32_t WebRtcSpl_SqrtLocal(int32_t in);

	int32_t WebRtcSpl_SqrtLocal(int32_t in)
	{

	int16_t x_half, t16;
	int32_t A, B, x2;

	/* The following block performs:
	y=in/2
	x=y-2^30
	x_half=x/2^31
	t = 1 + (x_half) - 0.5((x_half)^2) + 0.5((x_half)^3) - 0.625*((x_half)^4)
	+ 0.875*((x_half)^5)
	*/

	B = in / 2;

	B = B - ((int32_t)0x40000000); // B = in/2 - 1/2
	x_half = (int16_t)(B >> 16); // x_half = x/2 = (in-1)/2
	B = B + ((int32_t)0x40000000); // B = 1 + x/2
	B = B + ((int32_t)0x40000000); // Add 0.5 twice (since 1.0 does not exist in Q31)

	x2 = ((int32_t)x_half) * ((int32_t)x_half) * 2; // A = (x/2)^2
	A = -x2; // A = -(x/2)^2
	B = B + (A >> 1); // B = 1 + x/2 - 0.5*(x/2)^2

	A >>= 16;
	A = A * A * 2; // A = (x/2)^4
	t16 = (int16_t)(A >> 16);
	B += -20480 * t16 * 2; // B = B - 0.625*A
	// After this, B = 1 + x/2 - 0.5(x/2)^2 - 0.625(x/2)^4

	A = x_half * t16 * 2; // A = (x/2)^5
	t16 = (int16_t)(A >> 16);
	B += 28672 * t16 * 2; // B = B + 0.875*A
	// After this, B = 1 + x/2 - 0.5(x/2)^2 - 0.625(x/2)^4 + 0.875*(x/2)^5

	t16 = (int16_t)(x2 >> 16);
	A = x_half * t16 * 2; // A = x/2^3

	B = B + (A >> 1); // B = B + 0.5*A
	// After this, B = 1 + x/2 - 0.5(x/2)^2 + 0.5(x/2)^3 - 0.625(x/2)^4 + 0.875(x/2)^5

	B = B + ((int32_t)32768); // Round off bit

	return B;
	}

	int32_t WebRtcSpl_Sqrt(int32_t value)
	{
	/*
	Algorithm:

	Six term Taylor Series is used here to compute the square root of a number
	y^0.5 = (1+x)^0.5 where x = y-1
	= 1+(x/2)-0.5((x/2)^2+0.5((x/2)^3-0.625((x/2)^4+0.875((x/2)^5)
	0.5 <= x < 1

	Example of how the algorithm works, with ut=sqrt(in), and
	with in=73632 and ut=271 (even shift value case):

	in=73632
	y= in/131072
	x=y-1
	t = 1 + (x/2) - 0.5((x/2)^2) + 0.5((x/2)^3) - 0.625((x/2)^4) + 0.875((x/2)^5)
	ut=t(1/sqrt(2))512

	or:

	in=73632
	in2=73632*2^14
	y= in2/2^31
	x=y-1
	t = 1 + (x/2) - 0.5((x/2)^2) + 0.5((x/2)^3) - 0.625((x/2)^4) + 0.875((x/2)^5)
	ut=t*(1/sqrt(2))
	ut2=ut*2^9

	which gives:

	in = 73632
	in2 = 1206386688
	y = 0.56176757812500
	x = -0.43823242187500
	t = 0.74973506527313
	ut = 0.53014274874797
	ut2 = 2.714330873589594e+002

	or:

	in=73632
	in2=73632*2^14
	y=in2/2
	x=y-2^30
	x_half=x/2^31
	t = 1 + (x_half) - 0.5((x_half)^2) + 0.5((x_half)^3) - 0.625*((x_half)^4)
	+ 0.875*((x_half)^5)
	ut=t*(1/sqrt(2))
	ut2=ut*2^9

	which gives:

	in = 73632
	in2 = 1206386688
	y = 603193344
	x = -470548480
	x_half = -0.21911621093750
	t = 0.74973506527313
	ut = 0.53014274874797
	ut2 = 2.714330873589594e+002

	*/

	int16_t x_norm, nshift, t16, sh;
	int32_t A;

	int16_t k_sqrt_2 = 23170; // 1/sqrt2 (==5a82)

	A = value;

	// The convention in this function is to calculate sqrt(abs(A)). Negate the
	// input if it is negative.
	if (A < 0) {
	if (A == WEBRTC_SPL_WORD32_MIN) {
	// This number cannot be held in an int32_t after negating.
	// Map it to the maximum positive value.
	A = WEBRTC_SPL_WORD32_MAX;
	} else {
	A = -A;
	}
	} else if (A == 0) {
	return 0; // sqrt(0) = 0
	}

	sh = WebRtcSpl_NormW32(A); // # shifts to normalize A
	A = WEBRTC_SPL_LSHIFT_W32(A, sh); // Normalize A
	if (A < (WEBRTC_SPL_WORD32_MAX - 32767))
	{
	A = A + ((int32_t)32768); // Round off bit
	} else
	{
	A = WEBRTC_SPL_WORD32_MAX;
	}

	x_norm = (int16_t)(A >> 16); // x_norm = AH

	nshift = (sh / 2);
	RTC_DCHECK_GE(nshift, 0);

	A = (int32_t)WEBRTC_SPL_LSHIFT_W32((int32_t)x_norm, 16);
	A = WEBRTC_SPL_ABS_W32(A); // A = abs(x_norm<<16)
	A = WebRtcSpl_SqrtLocal(A); // A = sqrt(A)

	if (2 * nshift == sh) {
	// Even shift value case

	t16 = (int16_t)(A >> 16); // t16 = AH

	A = k_sqrt_2 * t16 * 2; // A = 1/sqrt(2)*t16
	A = A + ((int32_t)32768); // Round off
	A = A & ((int32_t)0x7fff0000); // Round off

	A >>= 15; // A = A>>16

	} else
	{
	A >>= 16; // A = A>>16
	}

	A = A & ((int32_t)0x0000ffff);
	A >>= nshift; // De-normalize the result.

	return A;
	}