webrtc/modules/audio_processing/aec/aec_rdft.c - platform/external/webrtc - Git at Google

 /*
  * http://www.kurims.kyoto-u.ac.jp/~ooura/fft.html
  * Copyright Takuya OOURA, 1996-2001
  *
  * You may use, copy, modify and distribute this code for any purpose (include
  * commercial use) and without fee. Please refer to this package when you modify
  * this code.
  *
  * Changes by the WebRTC authors:
  *    - Trivial type modifications.
  *    - Minimal code subset to do rdft of length 128.
  *    - Optimizations because of known length.
  *
  *  All changes are covered by the WebRTC license and IP grant:
  *  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.
  */

 #include "webrtc/modules/audio_processing/aec/aec_rdft.h"

 #include <math.h>

 #include "webrtc/system_wrappers/interface/cpu_features_wrapper.h"
 #include "webrtc/typedefs.h"

 // constants shared by all paths (C, SSE2).
 float rdft_w[64];
 // constants used by the C path.
 float rdft_wk3ri_first[32];
 float rdft_wk3ri_second[32];
 // constants used by SSE2 but initialized in C path.
 ALIGN16_BEG float ALIGN16_END rdft_wk1r[32];
 ALIGN16_BEG float ALIGN16_END rdft_wk2r[32];
 ALIGN16_BEG float ALIGN16_END rdft_wk3r[32];
 ALIGN16_BEG float ALIGN16_END rdft_wk1i[32];
 ALIGN16_BEG float ALIGN16_END rdft_wk2i[32];
 ALIGN16_BEG float ALIGN16_END rdft_wk3i[32];
 ALIGN16_BEG float ALIGN16_END cftmdl_wk1r[4];

 static int ip[16];

 static void bitrv2_32(int* ip, float* a) {
   const int n = 32;
   int j, j1, k, k1, m, m2;
   float xr, xi, yr, yi;

   ip[0] = 0;
   {
     int l = n;
     m = 1;
     while ((m << 3) < l) {
       l >>= 1;
       for (j = 0; j < m; j++) {
         ip[m + j] = ip[j] + l;
       }
       m <<= 1;
     }
   }
   m2 = 2 * m;
   for (k = 0; k < m; k++) {
     for (j = 0; j < k; j++) {
       j1 = 2 * j + ip[k];
       k1 = 2 * k + ip[j];
       xr = a[j1];
       xi = a[j1 + 1];
       yr = a[k1];
       yi = a[k1 + 1];
       a[j1] = yr;
       a[j1 + 1] = yi;
       a[k1] = xr;
       a[k1 + 1] = xi;
       j1 += m2;
       k1 += 2 * m2;
       xr = a[j1];
       xi = a[j1 + 1];
       yr = a[k1];
       yi = a[k1 + 1];
       a[j1] = yr;
       a[j1 + 1] = yi;
       a[k1] = xr;
       a[k1 + 1] = xi;
       j1 += m2;
       k1 -= m2;
       xr = a[j1];
       xi = a[j1 + 1];
       yr = a[k1];
       yi = a[k1 + 1];
       a[j1] = yr;
       a[j1 + 1] = yi;
       a[k1] = xr;
       a[k1 + 1] = xi;
       j1 += m2;
       k1 += 2 * m2;
       xr = a[j1];
       xi = a[j1 + 1];
       yr = a[k1];
       yi = a[k1 + 1];
       a[j1] = yr;
       a[j1 + 1] = yi;
       a[k1] = xr;
       a[k1 + 1] = xi;
     }
     j1 = 2 * k + m2 + ip[k];
     k1 = j1 + m2;
     xr = a[j1];
     xi = a[j1 + 1];
     yr = a[k1];
     yi = a[k1 + 1];
     a[j1] = yr;
     a[j1 + 1] = yi;
     a[k1] = xr;
     a[k1 + 1] = xi;
   }
 }

 static void bitrv2_128_C(float* a) {
   /*
       Following things have been attempted but are no faster:
       (a) Storing the swap indexes in a LUT (index calculations are done
           for 'free' while waiting on memory/L1).
       (b) Consolidate the load/store of two consecutive floats by a 64 bit
           integer (execution is memory/L1 bound).
       (c) Do a mix of floats and 64 bit integer to maximize register
           utilization (execution is memory/L1 bound).
       (d) Replacing ip[i] by ((k<<31)>>25) + ((k >> 1)<<5).
       (e) Hard-coding of the offsets to completely eliminates index
           calculations.
   */

   unsigned int j, j1, k, k1;
   float xr, xi, yr, yi;

   static const int ip[4] = {0, 64, 32, 96};
   for (k = 0; k < 4; k++) {
     for (j = 0; j < k; j++) {
       j1 = 2 * j + ip[k];
       k1 = 2 * k + ip[j];
       xr = a[j1 + 0];
       xi = a[j1 + 1];
       yr = a[k1 + 0];
       yi = a[k1 + 1];
       a[j1 + 0] = yr;
       a[j1 + 1] = yi;
       a[k1 + 0] = xr;
       a[k1 + 1] = xi;
       j1 += 8;
       k1 += 16;
       xr = a[j1 + 0];
       xi = a[j1 + 1];
       yr = a[k1 + 0];
       yi = a[k1 + 1];
       a[j1 + 0] = yr;
       a[j1 + 1] = yi;
       a[k1 + 0] = xr;
       a[k1 + 1] = xi;
       j1 += 8;
       k1 -= 8;
       xr = a[j1 + 0];
       xi = a[j1 + 1];
       yr = a[k1 + 0];
       yi = a[k1 + 1];
       a[j1 + 0] = yr;
       a[j1 + 1] = yi;
       a[k1 + 0] = xr;
       a[k1 + 1] = xi;
       j1 += 8;
       k1 += 16;
       xr = a[j1 + 0];
       xi = a[j1 + 1];
       yr = a[k1 + 0];
       yi = a[k1 + 1];
       a[j1 + 0] = yr;
       a[j1 + 1] = yi;
       a[k1 + 0] = xr;
       a[k1 + 1] = xi;
     }
     j1 = 2 * k + 8 + ip[k];
     k1 = j1 + 8;
     xr = a[j1 + 0];
     xi = a[j1 + 1];
     yr = a[k1 + 0];
     yi = a[k1 + 1];
     a[j1 + 0] = yr;
     a[j1 + 1] = yi;
     a[k1 + 0] = xr;
     a[k1 + 1] = xi;
   }
 }

 static void makewt_32(void) {
   const int nw = 32;
   int j, nwh;
   float delta, x, y;

   ip[0] = nw;
   ip[1] = 1;
   nwh = nw >> 1;
   delta = atanf(1.0f) / nwh;
   rdft_w[0] = 1;
   rdft_w[1] = 0;
   rdft_w[nwh] = cosf(delta * nwh);
   rdft_w[nwh + 1] = rdft_w[nwh];
   for (j = 2; j < nwh; j += 2) {
     x = cosf(delta * j);
     y = sinf(delta * j);
     rdft_w[j] = x;
     rdft_w[j + 1] = y;
     rdft_w[nw - j] = y;
     rdft_w[nw - j + 1] = x;
   }
   bitrv2_32(ip + 2, rdft_w);

   // pre-calculate constants used by cft1st_128 and cftmdl_128...
   cftmdl_wk1r[0] = rdft_w[2];
   cftmdl_wk1r[1] = rdft_w[2];
   cftmdl_wk1r[2] = rdft_w[2];
   cftmdl_wk1r[3] = -rdft_w[2];
   {
     int k1;

     for (k1 = 0, j = 0; j < 128; j += 16, k1 += 2) {
       const int k2 = 2 * k1;
       const float wk2r = rdft_w[k1 + 0];
       const float wk2i = rdft_w[k1 + 1];
       float wk1r, wk1i;
       // ... scalar version.
       wk1r = rdft_w[k2 + 0];
       wk1i = rdft_w[k2 + 1];
       rdft_wk3ri_first[k1 + 0] = wk1r - 2 * wk2i * wk1i;
       rdft_wk3ri_first[k1 + 1] = 2 * wk2i * wk1r - wk1i;
       wk1r = rdft_w[k2 + 2];
       wk1i = rdft_w[k2 + 3];
       rdft_wk3ri_second[k1 + 0] = wk1r - 2 * wk2r * wk1i;
       rdft_wk3ri_second[k1 + 1] = 2 * wk2r * wk1r - wk1i;
       // ... vector version.
       rdft_wk1r[k2 + 0] = rdft_w[k2 + 0];
       rdft_wk1r[k2 + 1] = rdft_w[k2 + 0];
       rdft_wk1r[k2 + 2] = rdft_w[k2 + 2];
       rdft_wk1r[k2 + 3] = rdft_w[k2 + 2];
       rdft_wk2r[k2 + 0] = rdft_w[k1 + 0];
       rdft_wk2r[k2 + 1] = rdft_w[k1 + 0];
       rdft_wk2r[k2 + 2] = -rdft_w[k1 + 1];
       rdft_wk2r[k2 + 3] = -rdft_w[k1 + 1];
       rdft_wk3r[k2 + 0] = rdft_wk3ri_first[k1 + 0];
       rdft_wk3r[k2 + 1] = rdft_wk3ri_first[k1 + 0];
       rdft_wk3r[k2 + 2] = rdft_wk3ri_second[k1 + 0];
       rdft_wk3r[k2 + 3] = rdft_wk3ri_second[k1 + 0];
       rdft_wk1i[k2 + 0] = -rdft_w[k2 + 1];
       rdft_wk1i[k2 + 1] = rdft_w[k2 + 1];
       rdft_wk1i[k2 + 2] = -rdft_w[k2 + 3];
       rdft_wk1i[k2 + 3] = rdft_w[k2 + 3];
       rdft_wk2i[k2 + 0] = -rdft_w[k1 + 1];
       rdft_wk2i[k2 + 1] = rdft_w[k1 + 1];
       rdft_wk2i[k2 + 2] = -rdft_w[k1 + 0];
       rdft_wk2i[k2 + 3] = rdft_w[k1 + 0];
       rdft_wk3i[k2 + 0] = -rdft_wk3ri_first[k1 + 1];
       rdft_wk3i[k2 + 1] = rdft_wk3ri_first[k1 + 1];
       rdft_wk3i[k2 + 2] = -rdft_wk3ri_second[k1 + 1];
       rdft_wk3i[k2 + 3] = rdft_wk3ri_second[k1 + 1];
     }
   }
 }

 static void makect_32(void) {
   float* c = rdft_w + 32;
   const int nc = 32;
   int j, nch;
   float delta;

   ip[1] = nc;
   nch = nc >> 1;
   delta = atanf(1.0f) / nch;
   c[0] = cosf(delta * nch);
   c[nch] = 0.5f * c[0];
   for (j = 1; j < nch; j++) {
     c[j] = 0.5f * cosf(delta * j);
     c[nc - j] = 0.5f * sinf(delta * j);
   }
 }

 static void cft1st_128_C(float* a) {
   const int n = 128;
   int j, k1, k2;
   float wk1r, wk1i, wk2r, wk2i, wk3r, wk3i;
   float x0r, x0i, x1r, x1i, x2r, x2i, x3r, x3i;

   // The processing of the first set of elements was simplified in C to avoid
   // some operations (multiplication by zero or one, addition of two elements
   // multiplied by the same weight, ...).
   x0r = a[0] + a[2];
   x0i = a[1] + a[3];
   x1r = a[0] - a[2];
   x1i = a[1] - a[3];
   x2r = a[4] + a[6];
   x2i = a[5] + a[7];
   x3r = a[4] - a[6];
   x3i = a[5] - a[7];
   a[0] = x0r + x2r;
   a[1] = x0i + x2i;
   a[4] = x0r - x2r;
   a[5] = x0i - x2i;
   a[2] = x1r - x3i;
   a[3] = x1i + x3r;
   a[6] = x1r + x3i;
   a[7] = x1i - x3r;
   wk1r = rdft_w[2];
   x0r = a[8] + a[10];
   x0i = a[9] + a[11];
   x1r = a[8] - a[10];
   x1i = a[9] - a[11];
   x2r = a[12] + a[14];
   x2i = a[13] + a[15];
   x3r = a[12] - a[14];
   x3i = a[13] - a[15];
   a[8] = x0r + x2r;
   a[9] = x0i + x2i;
   a[12] = x2i - x0i;
   a[13] = x0r - x2r;
   x0r = x1r - x3i;
   x0i = x1i + x3r;
   a[10] = wk1r * (x0r - x0i);
   a[11] = wk1r * (x0r + x0i);
   x0r = x3i + x1r;
   x0i = x3r - x1i;
   a[14] = wk1r * (x0i - x0r);
   a[15] = wk1r * (x0i + x0r);
   k1 = 0;
   for (j = 16; j < n; j += 16) {
     k1 += 2;
     k2 = 2 * k1;
     wk2r = rdft_w[k1 + 0];
     wk2i = rdft_w[k1 + 1];
     wk1r = rdft_w[k2 + 0];
     wk1i = rdft_w[k2 + 1];
     wk3r = rdft_wk3ri_first[k1 + 0];
     wk3i = rdft_wk3ri_first[k1 + 1];
     x0r = a[j + 0] + a[j + 2];
     x0i = a[j + 1] + a[j + 3];
     x1r = a[j + 0] - a[j + 2];
     x1i = a[j + 1] - a[j + 3];
     x2r = a[j + 4] + a[j + 6];
     x2i = a[j + 5] + a[j + 7];
     x3r = a[j + 4] - a[j + 6];
     x3i = a[j + 5] - a[j + 7];
     a[j + 0] = x0r + x2r;
     a[j + 1] = x0i + x2i;
     x0r -= x2r;
     x0i -= x2i;
     a[j + 4] = wk2r * x0r - wk2i * x0i;
     a[j + 5] = wk2r * x0i + wk2i * x0r;
     x0r = x1r - x3i;
     x0i = x1i + x3r;
     a[j + 2] = wk1r * x0r - wk1i * x0i;
     a[j + 3] = wk1r * x0i + wk1i * x0r;
     x0r = x1r + x3i;
     x0i = x1i - x3r;
     a[j + 6] = wk3r * x0r - wk3i * x0i;
     a[j + 7] = wk3r * x0i + wk3i * x0r;
     wk1r = rdft_w[k2 + 2];
     wk1i = rdft_w[k2 + 3];
     wk3r = rdft_wk3ri_second[k1 + 0];
     wk3i = rdft_wk3ri_second[k1 + 1];
     x0r = a[j + 8] + a[j + 10];
     x0i = a[j + 9] + a[j + 11];
     x1r = a[j + 8] - a[j + 10];
     x1i = a[j + 9] - a[j + 11];
     x2r = a[j + 12] + a[j + 14];
     x2i = a[j + 13] + a[j + 15];
     x3r = a[j + 12] - a[j + 14];
     x3i = a[j + 13] - a[j + 15];
     a[j + 8] = x0r + x2r;
     a[j + 9] = x0i + x2i;
     x0r -= x2r;
     x0i -= x2i;
     a[j + 12] = -wk2i * x0r - wk2r * x0i;
     a[j + 13] = -wk2i * x0i + wk2r * x0r;
     x0r = x1r - x3i;
     x0i = x1i + x3r;
     a[j + 10] = wk1r * x0r - wk1i * x0i;
     a[j + 11] = wk1r * x0i + wk1i * x0r;
     x0r = x1r + x3i;
     x0i = x1i - x3r;
     a[j + 14] = wk3r * x0r - wk3i * x0i;
     a[j + 15] = wk3r * x0i + wk3i * x0r;
   }
 }

 static void cftmdl_128_C(float* a) {
   const int l = 8;
   const int n = 128;
   const int m = 32;
   int j0, j1, j2, j3, k, k1, k2, m2;
   float wk1r, wk1i, wk2r, wk2i, wk3r, wk3i;
   float x0r, x0i, x1r, x1i, x2r, x2i, x3r, x3i;

   for (j0 = 0; j0 < l; j0 += 2) {
     j1 = j0 + 8;
     j2 = j0 + 16;
     j3 = j0 + 24;
     x0r = a[j0 + 0] + a[j1 + 0];
     x0i = a[j0 + 1] + a[j1 + 1];
     x1r = a[j0 + 0] - a[j1 + 0];
     x1i = a[j0 + 1] - a[j1 + 1];
     x2r = a[j2 + 0] + a[j3 + 0];
     x2i = a[j2 + 1] + a[j3 + 1];
     x3r = a[j2 + 0] - a[j3 + 0];
     x3i = a[j2 + 1] - a[j3 + 1];
     a[j0 + 0] = x0r + x2r;
     a[j0 + 1] = x0i + x2i;
     a[j2 + 0] = x0r - x2r;
     a[j2 + 1] = x0i - x2i;
     a[j1 + 0] = x1r - x3i;
     a[j1 + 1] = x1i + x3r;
     a[j3 + 0] = x1r + x3i;
     a[j3 + 1] = x1i - x3r;
   }
   wk1r = rdft_w[2];
   for (j0 = m; j0 < l + m; j0 += 2) {
     j1 = j0 + 8;
     j2 = j0 + 16;
     j3 = j0 + 24;
     x0r = a[j0 + 0] + a[j1 + 0];
     x0i = a[j0 + 1] + a[j1 + 1];
     x1r = a[j0 + 0] - a[j1 + 0];
     x1i = a[j0 + 1] - a[j1 + 1];
     x2r = a[j2 + 0] + a[j3 + 0];
     x2i = a[j2 + 1] + a[j3 + 1];
     x3r = a[j2 + 0] - a[j3 + 0];
     x3i = a[j2 + 1] - a[j3 + 1];
     a[j0 + 0] = x0r + x2r;
     a[j0 + 1] = x0i + x2i;
     a[j2 + 0] = x2i - x0i;
     a[j2 + 1] = x0r - x2r;
     x0r = x1r - x3i;
     x0i = x1i + x3r;
     a[j1 + 0] = wk1r * (x0r - x0i);
     a[j1 + 1] = wk1r * (x0r + x0i);
     x0r = x3i + x1r;
     x0i = x3r - x1i;
     a[j3 + 0] = wk1r * (x0i - x0r);
     a[j3 + 1] = wk1r * (x0i + x0r);
   }
   k1 = 0;
   m2 = 2 * m;
   for (k = m2; k < n; k += m2) {
     k1 += 2;
     k2 = 2 * k1;
     wk2r = rdft_w[k1 + 0];
     wk2i = rdft_w[k1 + 1];
     wk1r = rdft_w[k2 + 0];
     wk1i = rdft_w[k2 + 1];
     wk3r = rdft_wk3ri_first[k1 + 0];
     wk3i = rdft_wk3ri_first[k1 + 1];
     for (j0 = k; j0 < l + k; j0 += 2) {
       j1 = j0 + 8;
       j2 = j0 + 16;
       j3 = j0 + 24;
       x0r = a[j0 + 0] + a[j1 + 0];
       x0i = a[j0 + 1] + a[j1 + 1];
       x1r = a[j0 + 0] - a[j1 + 0];
       x1i = a[j0 + 1] - a[j1 + 1];
       x2r = a[j2 + 0] + a[j3 + 0];
       x2i = a[j2 + 1] + a[j3 + 1];
       x3r = a[j2 + 0] - a[j3 + 0];
       x3i = a[j2 + 1] - a[j3 + 1];
       a[j0 + 0] = x0r + x2r;
       a[j0 + 1] = x0i + x2i;
       x0r -= x2r;
       x0i -= x2i;
       a[j2 + 0] = wk2r * x0r - wk2i * x0i;
       a[j2 + 1] = wk2r * x0i + wk2i * x0r;
       x0r = x1r - x3i;
       x0i = x1i + x3r;
       a[j1 + 0] = wk1r * x0r - wk1i * x0i;
       a[j1 + 1] = wk1r * x0i + wk1i * x0r;
       x0r = x1r + x3i;
       x0i = x1i - x3r;
       a[j3 + 0] = wk3r * x0r - wk3i * x0i;
       a[j3 + 1] = wk3r * x0i + wk3i * x0r;
     }
     wk1r = rdft_w[k2 + 2];
     wk1i = rdft_w[k2 + 3];
     wk3r = rdft_wk3ri_second[k1 + 0];
     wk3i = rdft_wk3ri_second[k1 + 1];
     for (j0 = k + m; j0 < l + (k + m); j0 += 2) {
       j1 = j0 + 8;
       j2 = j0 + 16;
       j3 = j0 + 24;
       x0r = a[j0 + 0] + a[j1 + 0];
       x0i = a[j0 + 1] + a[j1 + 1];
       x1r = a[j0 + 0] - a[j1 + 0];
       x1i = a[j0 + 1] - a[j1 + 1];
       x2r = a[j2 + 0] + a[j3 + 0];
       x2i = a[j2 + 1] + a[j3 + 1];
       x3r = a[j2 + 0] - a[j3 + 0];
       x3i = a[j2 + 1] - a[j3 + 1];
       a[j0 + 0] = x0r + x2r;
       a[j0 + 1] = x0i + x2i;
       x0r -= x2r;
       x0i -= x2i;
       a[j2 + 0] = -wk2i * x0r - wk2r * x0i;
       a[j2 + 1] = -wk2i * x0i + wk2r * x0r;
       x0r = x1r - x3i;
       x0i = x1i + x3r;
       a[j1 + 0] = wk1r * x0r - wk1i * x0i;
       a[j1 + 1] = wk1r * x0i + wk1i * x0r;
       x0r = x1r + x3i;
       x0i = x1i - x3r;
       a[j3 + 0] = wk3r * x0r - wk3i * x0i;
       a[j3 + 1] = wk3r * x0i + wk3i * x0r;
     }
   }
 }

 static void cftfsub_128_C(float* a) {
   int j, j1, j2, j3, l;
   float x0r, x0i, x1r, x1i, x2r, x2i, x3r, x3i;

   cft1st_128(a);
   cftmdl_128(a);
   l = 32;
   for (j = 0; j < l; j += 2) {
     j1 = j + l;
     j2 = j1 + l;
     j3 = j2 + l;
     x0r = a[j] + a[j1];
     x0i = a[j + 1] + a[j1 + 1];
     x1r = a[j] - a[j1];
     x1i = a[j + 1] - a[j1 + 1];
     x2r = a[j2] + a[j3];
     x2i = a[j2 + 1] + a[j3 + 1];
     x3r = a[j2] - a[j3];
     x3i = a[j2 + 1] - a[j3 + 1];
     a[j] = x0r + x2r;
     a[j + 1] = x0i + x2i;
     a[j2] = x0r - x2r;
     a[j2 + 1] = x0i - x2i;
     a[j1] = x1r - x3i;
     a[j1 + 1] = x1i + x3r;
     a[j3] = x1r + x3i;
     a[j3 + 1] = x1i - x3r;
   }
 }

 static void cftbsub_128_C(float* a) {
   int j, j1, j2, j3, l;
   float x0r, x0i, x1r, x1i, x2r, x2i, x3r, x3i;

   cft1st_128(a);
   cftmdl_128(a);
   l = 32;

   for (j = 0; j < l; j += 2) {
     j1 = j + l;
     j2 = j1 + l;
     j3 = j2 + l;
     x0r = a[j] + a[j1];
     x0i = -a[j + 1] - a[j1 + 1];
     x1r = a[j] - a[j1];
     x1i = -a[j + 1] + a[j1 + 1];
     x2r = a[j2] + a[j3];
     x2i = a[j2 + 1] + a[j3 + 1];
     x3r = a[j2] - a[j3];
     x3i = a[j2 + 1] - a[j3 + 1];
     a[j] = x0r + x2r;
     a[j + 1] = x0i - x2i;
     a[j2] = x0r - x2r;
     a[j2 + 1] = x0i + x2i;
     a[j1] = x1r - x3i;
     a[j1 + 1] = x1i - x3r;
     a[j3] = x1r + x3i;
     a[j3 + 1] = x1i + x3r;
   }
 }

 static void rftfsub_128_C(float* a) {
   const float* c = rdft_w + 32;
   int j1, j2, k1, k2;
   float wkr, wki, xr, xi, yr, yi;

   for (j1 = 1, j2 = 2; j2 < 64; j1 += 1, j2 += 2) {
     k2 = 128 - j2;
     k1 = 32 - j1;
     wkr = 0.5f - c[k1];
     wki = c[j1];
     xr = a[j2 + 0] - a[k2 + 0];
     xi = a[j2 + 1] + a[k2 + 1];
     yr = wkr * xr - wki * xi;
     yi = wkr * xi + wki * xr;
     a[j2 + 0] -= yr;
     a[j2 + 1] -= yi;
     a[k2 + 0] += yr;
     a[k2 + 1] -= yi;
   }
 }

 static void rftbsub_128_C(float* a) {
   const float* c = rdft_w + 32;
   int j1, j2, k1, k2;
   float wkr, wki, xr, xi, yr, yi;

   a[1] = -a[1];
   for (j1 = 1, j2 = 2; j2 < 64; j1 += 1, j2 += 2) {
     k2 = 128 - j2;
     k1 = 32 - j1;
     wkr = 0.5f - c[k1];
     wki = c[j1];
     xr = a[j2 + 0] - a[k2 + 0];
     xi = a[j2 + 1] + a[k2 + 1];
     yr = wkr * xr + wki * xi;
     yi = wkr * xi - wki * xr;
     a[j2 + 0] = a[j2 + 0] - yr;
     a[j2 + 1] = yi - a[j2 + 1];
     a[k2 + 0] = yr + a[k2 + 0];
     a[k2 + 1] = yi - a[k2 + 1];
   }
   a[65] = -a[65];
 }

 void aec_rdft_forward_128(float* a) {
   float xi;
   bitrv2_128(a);
   cftfsub_128(a);
   rftfsub_128(a);
   xi = a[0] - a[1];
   a[0] += a[1];
   a[1] = xi;
 }

 void aec_rdft_inverse_128(float* a) {
   a[1] = 0.5f * (a[0] - a[1]);
   a[0] -= a[1];
   rftbsub_128(a);
   bitrv2_128(a);
   cftbsub_128(a);
 }

 // code path selection
 rft_sub_128_t cft1st_128;
 rft_sub_128_t cftmdl_128;
 rft_sub_128_t rftfsub_128;
 rft_sub_128_t rftbsub_128;
 rft_sub_128_t cftfsub_128;
 rft_sub_128_t cftbsub_128;
 rft_sub_128_t bitrv2_128;

 void aec_rdft_init(void) {
   cft1st_128 = cft1st_128_C;
   cftmdl_128 = cftmdl_128_C;
   rftfsub_128 = rftfsub_128_C;
   rftbsub_128 = rftbsub_128_C;
   cftfsub_128 = cftfsub_128_C;
   cftbsub_128 = cftbsub_128_C;
   bitrv2_128 = bitrv2_128_C;
 #if defined(WEBRTC_ARCH_X86_FAMILY)
   if (WebRtc_GetCPUInfo(kSSE2)) {
     aec_rdft_init_sse2();
   }
 #endif
 #if defined(MIPS_FPU_LE)
   aec_rdft_init_mips();
 #endif
 #if defined(WEBRTC_DETECT_ARM_NEON) || defined(WEBRTC_ARCH_ARM_NEON)
   aec_rdft_init_neon();
 #endif
   // init library constants.
   makewt_32();
   makect_32();
 }
	/*
	* http://www.kurims.kyoto-u.ac.jp/~ooura/fft.html
	* Copyright Takuya OOURA, 1996-2001
	*
	* You may use, copy, modify and distribute this code for any purpose (include
	* commercial use) and without fee. Please refer to this package when you modify
	* this code.
	*
	* Changes by the WebRTC authors:
	* - Trivial type modifications.
	* - Minimal code subset to do rdft of length 128.
	* - Optimizations because of known length.
	*
	* All changes are covered by the WebRTC license and IP grant:
	* 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.
	*/

	#include "webrtc/modules/audio_processing/aec/aec_rdft.h"

	#include <math.h>

	#include "webrtc/system_wrappers/interface/cpu_features_wrapper.h"
	#include "webrtc/typedefs.h"

	// constants shared by all paths (C, SSE2).
	float rdft_w[64];
	// constants used by the C path.
	float rdft_wk3ri_first[32];
	float rdft_wk3ri_second[32];
	// constants used by SSE2 but initialized in C path.
	ALIGN16_BEG float ALIGN16_END rdft_wk1r[32];
	ALIGN16_BEG float ALIGN16_END rdft_wk2r[32];
	ALIGN16_BEG float ALIGN16_END rdft_wk3r[32];
	ALIGN16_BEG float ALIGN16_END rdft_wk1i[32];
	ALIGN16_BEG float ALIGN16_END rdft_wk2i[32];
	ALIGN16_BEG float ALIGN16_END rdft_wk3i[32];
	ALIGN16_BEG float ALIGN16_END cftmdl_wk1r[4];

	static int ip[16];

	static void bitrv2_32(int* ip, float* a) {
	const int n = 32;
	int j, j1, k, k1, m, m2;
	float xr, xi, yr, yi;

	ip[0] = 0;
	{
	int l = n;
	m = 1;
	while ((m << 3) < l) {
	l >>= 1;
	for (j = 0; j < m; j++) {
	ip[m + j] = ip[j] + l;
	}
	m <<= 1;
	}
	}
	m2 = 2 * m;
	for (k = 0; k < m; k++) {
	for (j = 0; j < k; j++) {
	j1 = 2 * j + ip[k];
	k1 = 2 * k + ip[j];
	xr = a[j1];
	xi = a[j1 + 1];
	yr = a[k1];
	yi = a[k1 + 1];
	a[j1] = yr;
	a[j1 + 1] = yi;
	a[k1] = xr;
	a[k1 + 1] = xi;
	j1 += m2;
	k1 += 2 * m2;
	xr = a[j1];
	xi = a[j1 + 1];
	yr = a[k1];
	yi = a[k1 + 1];
	a[j1] = yr;
	a[j1 + 1] = yi;
	a[k1] = xr;
	a[k1 + 1] = xi;
	j1 += m2;
	k1 -= m2;
	xr = a[j1];
	xi = a[j1 + 1];
	yr = a[k1];
	yi = a[k1 + 1];
	a[j1] = yr;
	a[j1 + 1] = yi;
	a[k1] = xr;
	a[k1 + 1] = xi;
	j1 += m2;
	k1 += 2 * m2;
	xr = a[j1];
	xi = a[j1 + 1];
	yr = a[k1];
	yi = a[k1 + 1];
	a[j1] = yr;
	a[j1 + 1] = yi;
	a[k1] = xr;
	a[k1 + 1] = xi;
	}
	j1 = 2 * k + m2 + ip[k];
	k1 = j1 + m2;
	xr = a[j1];
	xi = a[j1 + 1];
	yr = a[k1];
	yi = a[k1 + 1];
	a[j1] = yr;
	a[j1 + 1] = yi;
	a[k1] = xr;
	a[k1 + 1] = xi;
	}
	}

	static void bitrv2_128_C(float* a) {
	/*
	Following things have been attempted but are no faster:
	(a) Storing the swap indexes in a LUT (index calculations are done
	for 'free' while waiting on memory/L1).
	(b) Consolidate the load/store of two consecutive floats by a 64 bit
	integer (execution is memory/L1 bound).
	(c) Do a mix of floats and 64 bit integer to maximize register
	utilization (execution is memory/L1 bound).
	(d) Replacing ip[i] by ((k<<31)>>25) + ((k >> 1)<<5).
	(e) Hard-coding of the offsets to completely eliminates index
	calculations.
	*/

	unsigned int j, j1, k, k1;
	float xr, xi, yr, yi;

	static const int ip[4] = {0, 64, 32, 96};
	for (k = 0; k < 4; k++) {
	for (j = 0; j < k; j++) {
	j1 = 2 * j + ip[k];
	k1 = 2 * k + ip[j];
	xr = a[j1 + 0];
	xi = a[j1 + 1];
	yr = a[k1 + 0];
	yi = a[k1 + 1];
	a[j1 + 0] = yr;
	a[j1 + 1] = yi;
	a[k1 + 0] = xr;
	a[k1 + 1] = xi;
	j1 += 8;
	k1 += 16;
	xr = a[j1 + 0];
	xi = a[j1 + 1];
	yr = a[k1 + 0];
	yi = a[k1 + 1];
	a[j1 + 0] = yr;
	a[j1 + 1] = yi;
	a[k1 + 0] = xr;
	a[k1 + 1] = xi;
	j1 += 8;
	k1 -= 8;
	xr = a[j1 + 0];
	xi = a[j1 + 1];
	yr = a[k1 + 0];
	yi = a[k1 + 1];
	a[j1 + 0] = yr;
	a[j1 + 1] = yi;
	a[k1 + 0] = xr;
	a[k1 + 1] = xi;
	j1 += 8;
	k1 += 16;
	xr = a[j1 + 0];
	xi = a[j1 + 1];
	yr = a[k1 + 0];
	yi = a[k1 + 1];
	a[j1 + 0] = yr;
	a[j1 + 1] = yi;
	a[k1 + 0] = xr;
	a[k1 + 1] = xi;
	}
	j1 = 2 * k + 8 + ip[k];
	k1 = j1 + 8;
	xr = a[j1 + 0];
	xi = a[j1 + 1];
	yr = a[k1 + 0];
	yi = a[k1 + 1];
	a[j1 + 0] = yr;
	a[j1 + 1] = yi;
	a[k1 + 0] = xr;
	a[k1 + 1] = xi;
	}
	}

	static void makewt_32(void) {
	const int nw = 32;
	int j, nwh;
	float delta, x, y;

	ip[0] = nw;
	ip[1] = 1;
	nwh = nw >> 1;
	delta = atanf(1.0f) / nwh;
	rdft_w[0] = 1;
	rdft_w[1] = 0;
	rdft_w[nwh] = cosf(delta * nwh);
	rdft_w[nwh + 1] = rdft_w[nwh];
	for (j = 2; j < nwh; j += 2) {
	x = cosf(delta * j);
	y = sinf(delta * j);
	rdft_w[j] = x;
	rdft_w[j + 1] = y;
	rdft_w[nw - j] = y;
	rdft_w[nw - j + 1] = x;
	}
	bitrv2_32(ip + 2, rdft_w);

	// pre-calculate constants used by cft1st_128 and cftmdl_128...
	cftmdl_wk1r[0] = rdft_w[2];
	cftmdl_wk1r[1] = rdft_w[2];
	cftmdl_wk1r[2] = rdft_w[2];
	cftmdl_wk1r[3] = -rdft_w[2];
	{
	int k1;

	for (k1 = 0, j = 0; j < 128; j += 16, k1 += 2) {
	const int k2 = 2 * k1;
	const float wk2r = rdft_w[k1 + 0];
	const float wk2i = rdft_w[k1 + 1];
	float wk1r, wk1i;
	// ... scalar version.
	wk1r = rdft_w[k2 + 0];
	wk1i = rdft_w[k2 + 1];
	rdft_wk3ri_first[k1 + 0] = wk1r - 2 * wk2i * wk1i;
	rdft_wk3ri_first[k1 + 1] = 2 * wk2i * wk1r - wk1i;
	wk1r = rdft_w[k2 + 2];
	wk1i = rdft_w[k2 + 3];
	rdft_wk3ri_second[k1 + 0] = wk1r - 2 * wk2r * wk1i;
	rdft_wk3ri_second[k1 + 1] = 2 * wk2r * wk1r - wk1i;
	// ... vector version.
	rdft_wk1r[k2 + 0] = rdft_w[k2 + 0];
	rdft_wk1r[k2 + 1] = rdft_w[k2 + 0];
	rdft_wk1r[k2 + 2] = rdft_w[k2 + 2];
	rdft_wk1r[k2 + 3] = rdft_w[k2 + 2];
	rdft_wk2r[k2 + 0] = rdft_w[k1 + 0];
	rdft_wk2r[k2 + 1] = rdft_w[k1 + 0];
	rdft_wk2r[k2 + 2] = -rdft_w[k1 + 1];
	rdft_wk2r[k2 + 3] = -rdft_w[k1 + 1];
	rdft_wk3r[k2 + 0] = rdft_wk3ri_first[k1 + 0];
	rdft_wk3r[k2 + 1] = rdft_wk3ri_first[k1 + 0];
	rdft_wk3r[k2 + 2] = rdft_wk3ri_second[k1 + 0];
	rdft_wk3r[k2 + 3] = rdft_wk3ri_second[k1 + 0];
	rdft_wk1i[k2 + 0] = -rdft_w[k2 + 1];
	rdft_wk1i[k2 + 1] = rdft_w[k2 + 1];
	rdft_wk1i[k2 + 2] = -rdft_w[k2 + 3];
	rdft_wk1i[k2 + 3] = rdft_w[k2 + 3];
	rdft_wk2i[k2 + 0] = -rdft_w[k1 + 1];
	rdft_wk2i[k2 + 1] = rdft_w[k1 + 1];
	rdft_wk2i[k2 + 2] = -rdft_w[k1 + 0];
	rdft_wk2i[k2 + 3] = rdft_w[k1 + 0];
	rdft_wk3i[k2 + 0] = -rdft_wk3ri_first[k1 + 1];
	rdft_wk3i[k2 + 1] = rdft_wk3ri_first[k1 + 1];
	rdft_wk3i[k2 + 2] = -rdft_wk3ri_second[k1 + 1];
	rdft_wk3i[k2 + 3] = rdft_wk3ri_second[k1 + 1];
	}
	}
	}

	static void makect_32(void) {
	float* c = rdft_w + 32;
	const int nc = 32;
	int j, nch;
	float delta;

	ip[1] = nc;
	nch = nc >> 1;
	delta = atanf(1.0f) / nch;
	c[0] = cosf(delta * nch);
	c[nch] = 0.5f * c[0];
	for (j = 1; j < nch; j++) {
	c[j] = 0.5f * cosf(delta * j);
	c[nc - j] = 0.5f * sinf(delta * j);
	}
	}

	static void cft1st_128_C(float* a) {
	const int n = 128;
	int j, k1, k2;
	float wk1r, wk1i, wk2r, wk2i, wk3r, wk3i;
	float x0r, x0i, x1r, x1i, x2r, x2i, x3r, x3i;

	// The processing of the first set of elements was simplified in C to avoid
	// some operations (multiplication by zero or one, addition of two elements
	// multiplied by the same weight, ...).
	x0r = a[0] + a[2];
	x0i = a[1] + a[3];
	x1r = a[0] - a[2];
	x1i = a[1] - a[3];
	x2r = a[4] + a[6];
	x2i = a[5] + a[7];
	x3r = a[4] - a[6];
	x3i = a[5] - a[7];
	a[0] = x0r + x2r;
	a[1] = x0i + x2i;
	a[4] = x0r - x2r;
	a[5] = x0i - x2i;
	a[2] = x1r - x3i;
	a[3] = x1i + x3r;
	a[6] = x1r + x3i;
	a[7] = x1i - x3r;
	wk1r = rdft_w[2];
	x0r = a[8] + a[10];
	x0i = a[9] + a[11];
	x1r = a[8] - a[10];
	x1i = a[9] - a[11];
	x2r = a[12] + a[14];
	x2i = a[13] + a[15];
	x3r = a[12] - a[14];
	x3i = a[13] - a[15];
	a[8] = x0r + x2r;
	a[9] = x0i + x2i;
	a[12] = x2i - x0i;
	a[13] = x0r - x2r;
	x0r = x1r - x3i;
	x0i = x1i + x3r;
	a[10] = wk1r * (x0r - x0i);
	a[11] = wk1r * (x0r + x0i);
	x0r = x3i + x1r;
	x0i = x3r - x1i;
	a[14] = wk1r * (x0i - x0r);
	a[15] = wk1r * (x0i + x0r);
	k1 = 0;
	for (j = 16; j < n; j += 16) {
	k1 += 2;
	k2 = 2 * k1;
	wk2r = rdft_w[k1 + 0];
	wk2i = rdft_w[k1 + 1];
	wk1r = rdft_w[k2 + 0];
	wk1i = rdft_w[k2 + 1];
	wk3r = rdft_wk3ri_first[k1 + 0];
	wk3i = rdft_wk3ri_first[k1 + 1];
	x0r = a[j + 0] + a[j + 2];
	x0i = a[j + 1] + a[j + 3];
	x1r = a[j + 0] - a[j + 2];
	x1i = a[j + 1] - a[j + 3];
	x2r = a[j + 4] + a[j + 6];
	x2i = a[j + 5] + a[j + 7];
	x3r = a[j + 4] - a[j + 6];
	x3i = a[j + 5] - a[j + 7];
	a[j + 0] = x0r + x2r;
	a[j + 1] = x0i + x2i;
	x0r -= x2r;
	x0i -= x2i;
	a[j + 4] = wk2r * x0r - wk2i * x0i;
	a[j + 5] = wk2r * x0i + wk2i * x0r;
	x0r = x1r - x3i;
	x0i = x1i + x3r;
	a[j + 2] = wk1r * x0r - wk1i * x0i;
	a[j + 3] = wk1r * x0i + wk1i * x0r;
	x0r = x1r + x3i;
	x0i = x1i - x3r;
	a[j + 6] = wk3r * x0r - wk3i * x0i;
	a[j + 7] = wk3r * x0i + wk3i * x0r;
	wk1r = rdft_w[k2 + 2];
	wk1i = rdft_w[k2 + 3];
	wk3r = rdft_wk3ri_second[k1 + 0];
	wk3i = rdft_wk3ri_second[k1 + 1];
	x0r = a[j + 8] + a[j + 10];
	x0i = a[j + 9] + a[j + 11];
	x1r = a[j + 8] - a[j + 10];
	x1i = a[j + 9] - a[j + 11];
	x2r = a[j + 12] + a[j + 14];
	x2i = a[j + 13] + a[j + 15];
	x3r = a[j + 12] - a[j + 14];
	x3i = a[j + 13] - a[j + 15];
	a[j + 8] = x0r + x2r;
	a[j + 9] = x0i + x2i;
	x0r -= x2r;
	x0i -= x2i;
	a[j + 12] = -wk2i * x0r - wk2r * x0i;
	a[j + 13] = -wk2i * x0i + wk2r * x0r;
	x0r = x1r - x3i;
	x0i = x1i + x3r;
	a[j + 10] = wk1r * x0r - wk1i * x0i;
	a[j + 11] = wk1r * x0i + wk1i * x0r;
	x0r = x1r + x3i;
	x0i = x1i - x3r;
	a[j + 14] = wk3r * x0r - wk3i * x0i;
	a[j + 15] = wk3r * x0i + wk3i * x0r;
	}
	}

	static void cftmdl_128_C(float* a) {
	const int l = 8;
	const int n = 128;
	const int m = 32;
	int j0, j1, j2, j3, k, k1, k2, m2;
	float wk1r, wk1i, wk2r, wk2i, wk3r, wk3i;
	float x0r, x0i, x1r, x1i, x2r, x2i, x3r, x3i;

	for (j0 = 0; j0 < l; j0 += 2) {
	j1 = j0 + 8;
	j2 = j0 + 16;
	j3 = j0 + 24;
	x0r = a[j0 + 0] + a[j1 + 0];
	x0i = a[j0 + 1] + a[j1 + 1];
	x1r = a[j0 + 0] - a[j1 + 0];
	x1i = a[j0 + 1] - a[j1 + 1];
	x2r = a[j2 + 0] + a[j3 + 0];
	x2i = a[j2 + 1] + a[j3 + 1];
	x3r = a[j2 + 0] - a[j3 + 0];
	x3i = a[j2 + 1] - a[j3 + 1];
	a[j0 + 0] = x0r + x2r;
	a[j0 + 1] = x0i + x2i;
	a[j2 + 0] = x0r - x2r;
	a[j2 + 1] = x0i - x2i;
	a[j1 + 0] = x1r - x3i;
	a[j1 + 1] = x1i + x3r;
	a[j3 + 0] = x1r + x3i;
	a[j3 + 1] = x1i - x3r;
	}
	wk1r = rdft_w[2];
	for (j0 = m; j0 < l + m; j0 += 2) {
	j1 = j0 + 8;
	j2 = j0 + 16;
	j3 = j0 + 24;
	x0r = a[j0 + 0] + a[j1 + 0];
	x0i = a[j0 + 1] + a[j1 + 1];
	x1r = a[j0 + 0] - a[j1 + 0];
	x1i = a[j0 + 1] - a[j1 + 1];
	x2r = a[j2 + 0] + a[j3 + 0];
	x2i = a[j2 + 1] + a[j3 + 1];
	x3r = a[j2 + 0] - a[j3 + 0];
	x3i = a[j2 + 1] - a[j3 + 1];
	a[j0 + 0] = x0r + x2r;
	a[j0 + 1] = x0i + x2i;
	a[j2 + 0] = x2i - x0i;
	a[j2 + 1] = x0r - x2r;
	x0r = x1r - x3i;
	x0i = x1i + x3r;
	a[j1 + 0] = wk1r * (x0r - x0i);
	a[j1 + 1] = wk1r * (x0r + x0i);
	x0r = x3i + x1r;
	x0i = x3r - x1i;
	a[j3 + 0] = wk1r * (x0i - x0r);
	a[j3 + 1] = wk1r * (x0i + x0r);
	}
	k1 = 0;
	m2 = 2 * m;
	for (k = m2; k < n; k += m2) {
	k1 += 2;
	k2 = 2 * k1;
	wk2r = rdft_w[k1 + 0];
	wk2i = rdft_w[k1 + 1];
	wk1r = rdft_w[k2 + 0];
	wk1i = rdft_w[k2 + 1];
	wk3r = rdft_wk3ri_first[k1 + 0];
	wk3i = rdft_wk3ri_first[k1 + 1];
	for (j0 = k; j0 < l + k; j0 += 2) {
	j1 = j0 + 8;
	j2 = j0 + 16;
	j3 = j0 + 24;
	x0r = a[j0 + 0] + a[j1 + 0];
	x0i = a[j0 + 1] + a[j1 + 1];
	x1r = a[j0 + 0] - a[j1 + 0];
	x1i = a[j0 + 1] - a[j1 + 1];
	x2r = a[j2 + 0] + a[j3 + 0];
	x2i = a[j2 + 1] + a[j3 + 1];
	x3r = a[j2 + 0] - a[j3 + 0];
	x3i = a[j2 + 1] - a[j3 + 1];
	a[j0 + 0] = x0r + x2r;
	a[j0 + 1] = x0i + x2i;
	x0r -= x2r;
	x0i -= x2i;
	a[j2 + 0] = wk2r * x0r - wk2i * x0i;
	a[j2 + 1] = wk2r * x0i + wk2i * x0r;
	x0r = x1r - x3i;
	x0i = x1i + x3r;
	a[j1 + 0] = wk1r * x0r - wk1i * x0i;
	a[j1 + 1] = wk1r * x0i + wk1i * x0r;
	x0r = x1r + x3i;
	x0i = x1i - x3r;
	a[j3 + 0] = wk3r * x0r - wk3i * x0i;
	a[j3 + 1] = wk3r * x0i + wk3i * x0r;
	}
	wk1r = rdft_w[k2 + 2];
	wk1i = rdft_w[k2 + 3];
	wk3r = rdft_wk3ri_second[k1 + 0];
	wk3i = rdft_wk3ri_second[k1 + 1];
	for (j0 = k + m; j0 < l + (k + m); j0 += 2) {
	j1 = j0 + 8;
	j2 = j0 + 16;
	j3 = j0 + 24;
	x0r = a[j0 + 0] + a[j1 + 0];
	x0i = a[j0 + 1] + a[j1 + 1];
	x1r = a[j0 + 0] - a[j1 + 0];
	x1i = a[j0 + 1] - a[j1 + 1];
	x2r = a[j2 + 0] + a[j3 + 0];
	x2i = a[j2 + 1] + a[j3 + 1];
	x3r = a[j2 + 0] - a[j3 + 0];
	x3i = a[j2 + 1] - a[j3 + 1];
	a[j0 + 0] = x0r + x2r;
	a[j0 + 1] = x0i + x2i;
	x0r -= x2r;
	x0i -= x2i;
	a[j2 + 0] = -wk2i * x0r - wk2r * x0i;
	a[j2 + 1] = -wk2i * x0i + wk2r * x0r;
	x0r = x1r - x3i;
	x0i = x1i + x3r;
	a[j1 + 0] = wk1r * x0r - wk1i * x0i;
	a[j1 + 1] = wk1r * x0i + wk1i * x0r;
	x0r = x1r + x3i;
	x0i = x1i - x3r;
	a[j3 + 0] = wk3r * x0r - wk3i * x0i;
	a[j3 + 1] = wk3r * x0i + wk3i * x0r;
	}
	}
	}

	static void cftfsub_128_C(float* a) {
	int j, j1, j2, j3, l;
	float x0r, x0i, x1r, x1i, x2r, x2i, x3r, x3i;

	cft1st_128(a);
	cftmdl_128(a);
	l = 32;
	for (j = 0; j < l; j += 2) {
	j1 = j + l;
	j2 = j1 + l;
	j3 = j2 + l;
	x0r = a[j] + a[j1];
	x0i = a[j + 1] + a[j1 + 1];
	x1r = a[j] - a[j1];
	x1i = a[j + 1] - a[j1 + 1];
	x2r = a[j2] + a[j3];
	x2i = a[j2 + 1] + a[j3 + 1];
	x3r = a[j2] - a[j3];
	x3i = a[j2 + 1] - a[j3 + 1];
	a[j] = x0r + x2r;
	a[j + 1] = x0i + x2i;
	a[j2] = x0r - x2r;
	a[j2 + 1] = x0i - x2i;
	a[j1] = x1r - x3i;
	a[j1 + 1] = x1i + x3r;
	a[j3] = x1r + x3i;
	a[j3 + 1] = x1i - x3r;
	}
	}

	static void cftbsub_128_C(float* a) {
	int j, j1, j2, j3, l;
	float x0r, x0i, x1r, x1i, x2r, x2i, x3r, x3i;

	cft1st_128(a);
	cftmdl_128(a);
	l = 32;

	for (j = 0; j < l; j += 2) {
	j1 = j + l;
	j2 = j1 + l;
	j3 = j2 + l;
	x0r = a[j] + a[j1];
	x0i = -a[j + 1] - a[j1 + 1];
	x1r = a[j] - a[j1];
	x1i = -a[j + 1] + a[j1 + 1];
	x2r = a[j2] + a[j3];
	x2i = a[j2 + 1] + a[j3 + 1];
	x3r = a[j2] - a[j3];
	x3i = a[j2 + 1] - a[j3 + 1];
	a[j] = x0r + x2r;
	a[j + 1] = x0i - x2i;
	a[j2] = x0r - x2r;
	a[j2 + 1] = x0i + x2i;
	a[j1] = x1r - x3i;
	a[j1 + 1] = x1i - x3r;
	a[j3] = x1r + x3i;
	a[j3 + 1] = x1i + x3r;
	}
	}

	static void rftfsub_128_C(float* a) {
	const float* c = rdft_w + 32;
	int j1, j2, k1, k2;
	float wkr, wki, xr, xi, yr, yi;

	for (j1 = 1, j2 = 2; j2 < 64; j1 += 1, j2 += 2) {
	k2 = 128 - j2;
	k1 = 32 - j1;
	wkr = 0.5f - c[k1];
	wki = c[j1];
	xr = a[j2 + 0] - a[k2 + 0];
	xi = a[j2 + 1] + a[k2 + 1];
	yr = wkr * xr - wki * xi;
	yi = wkr * xi + wki * xr;
	a[j2 + 0] -= yr;
	a[j2 + 1] -= yi;
	a[k2 + 0] += yr;
	a[k2 + 1] -= yi;
	}
	}

	static void rftbsub_128_C(float* a) {
	const float* c = rdft_w + 32;
	int j1, j2, k1, k2;
	float wkr, wki, xr, xi, yr, yi;

	a[1] = -a[1];
	for (j1 = 1, j2 = 2; j2 < 64; j1 += 1, j2 += 2) {
	k2 = 128 - j2;
	k1 = 32 - j1;
	wkr = 0.5f - c[k1];
	wki = c[j1];
	xr = a[j2 + 0] - a[k2 + 0];
	xi = a[j2 + 1] + a[k2 + 1];
	yr = wkr * xr + wki * xi;
	yi = wkr * xi - wki * xr;
	a[j2 + 0] = a[j2 + 0] - yr;
	a[j2 + 1] = yi - a[j2 + 1];
	a[k2 + 0] = yr + a[k2 + 0];
	a[k2 + 1] = yi - a[k2 + 1];
	}
	a[65] = -a[65];
	}

	void aec_rdft_forward_128(float* a) {
	float xi;
	bitrv2_128(a);
	cftfsub_128(a);
	rftfsub_128(a);
	xi = a[0] - a[1];
	a[0] += a[1];
	a[1] = xi;
	}

	void aec_rdft_inverse_128(float* a) {
	a[1] = 0.5f * (a[0] - a[1]);
	a[0] -= a[1];
	rftbsub_128(a);
	bitrv2_128(a);
	cftbsub_128(a);
	}

	// code path selection
	rft_sub_128_t cft1st_128;
	rft_sub_128_t cftmdl_128;
	rft_sub_128_t rftfsub_128;
	rft_sub_128_t rftbsub_128;
	rft_sub_128_t cftfsub_128;
	rft_sub_128_t cftbsub_128;
	rft_sub_128_t bitrv2_128;

	void aec_rdft_init(void) {
	cft1st_128 = cft1st_128_C;
	cftmdl_128 = cftmdl_128_C;
	rftfsub_128 = rftfsub_128_C;
	rftbsub_128 = rftbsub_128_C;
	cftfsub_128 = cftfsub_128_C;
	cftbsub_128 = cftbsub_128_C;
	bitrv2_128 = bitrv2_128_C;
	#if defined(WEBRTC_ARCH_X86_FAMILY)
	if (WebRtc_GetCPUInfo(kSSE2)) {
	aec_rdft_init_sse2();
	}
	#endif
	#if defined(MIPS_FPU_LE)
	aec_rdft_init_mips();
	#endif
	#if defined(WEBRTC_DETECT_ARM_NEON) \|\| defined(WEBRTC_ARCH_ARM_NEON)
	aec_rdft_init_neon();
	#endif
	// init library constants.
	makewt_32();
	makect_32();
	}