common_audio/third_party/ooura/fft_size_128/ooura_fft_neon.cc - src - Git at Google

 /*
  *  Copyright (c) 2014 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.
  */

 /*
  * The rdft AEC algorithm, neon version of speed-critical functions.
  *
  * Based on the sse2 version.
  */

 #include <arm_neon.h>

 #include "common_audio/third_party/ooura/fft_size_128/ooura_fft.h"
 #include "common_audio/third_party/ooura/fft_size_128/ooura_fft_tables_common.h"
 #include "common_audio/third_party/ooura/fft_size_128/ooura_fft_tables_neon_sse2.h"

 namespace webrtc {

 #if defined(WEBRTC_HAS_NEON)
 void cft1st_128_neon(float* a) {
   const float32x4_t vec_swap_sign = vld1q_f32((float32_t*)k_swap_sign);
   int j, k2;

   for (k2 = 0, j = 0; j < 128; j += 16, k2 += 4) {
     float32x4_t a00v = vld1q_f32(&a[j + 0]);
     float32x4_t a04v = vld1q_f32(&a[j + 4]);
     float32x4_t a08v = vld1q_f32(&a[j + 8]);
     float32x4_t a12v = vld1q_f32(&a[j + 12]);
     float32x4_t a01v = vcombine_f32(vget_low_f32(a00v), vget_low_f32(a08v));
     float32x4_t a23v = vcombine_f32(vget_high_f32(a00v), vget_high_f32(a08v));
     float32x4_t a45v = vcombine_f32(vget_low_f32(a04v), vget_low_f32(a12v));
     float32x4_t a67v = vcombine_f32(vget_high_f32(a04v), vget_high_f32(a12v));
     const float32x4_t wk1rv = vld1q_f32(&rdft_wk1r[k2]);
     const float32x4_t wk1iv = vld1q_f32(&rdft_wk1i[k2]);
     const float32x4_t wk2rv = vld1q_f32(&rdft_wk2r[k2]);
     const float32x4_t wk2iv = vld1q_f32(&rdft_wk2i[k2]);
     const float32x4_t wk3rv = vld1q_f32(&rdft_wk3r[k2]);
     const float32x4_t wk3iv = vld1q_f32(&rdft_wk3i[k2]);
     float32x4_t x0v = vaddq_f32(a01v, a23v);
     const float32x4_t x1v = vsubq_f32(a01v, a23v);
     const float32x4_t x2v = vaddq_f32(a45v, a67v);
     const float32x4_t x3v = vsubq_f32(a45v, a67v);
     const float32x4_t x3w = vrev64q_f32(x3v);
     float32x4_t x0w;
     a01v = vaddq_f32(x0v, x2v);
     x0v = vsubq_f32(x0v, x2v);
     x0w = vrev64q_f32(x0v);
     a45v = vmulq_f32(wk2rv, x0v);
     a45v = vmlaq_f32(a45v, wk2iv, x0w);
     x0v = vmlaq_f32(x1v, x3w, vec_swap_sign);
     x0w = vrev64q_f32(x0v);
     a23v = vmulq_f32(wk1rv, x0v);
     a23v = vmlaq_f32(a23v, wk1iv, x0w);
     x0v = vmlsq_f32(x1v, x3w, vec_swap_sign);
     x0w = vrev64q_f32(x0v);
     a67v = vmulq_f32(wk3rv, x0v);
     a67v = vmlaq_f32(a67v, wk3iv, x0w);
     a00v = vcombine_f32(vget_low_f32(a01v), vget_low_f32(a23v));
     a04v = vcombine_f32(vget_low_f32(a45v), vget_low_f32(a67v));
     a08v = vcombine_f32(vget_high_f32(a01v), vget_high_f32(a23v));
     a12v = vcombine_f32(vget_high_f32(a45v), vget_high_f32(a67v));
     vst1q_f32(&a[j + 0], a00v);
     vst1q_f32(&a[j + 4], a04v);
     vst1q_f32(&a[j + 8], a08v);
     vst1q_f32(&a[j + 12], a12v);
   }
 }

 void cftmdl_128_neon(float* a) {
   int j;
   const int l = 8;
   const float32x4_t vec_swap_sign = vld1q_f32((float32_t*)k_swap_sign);
   float32x4_t wk1rv = vld1q_f32(cftmdl_wk1r);

   for (j = 0; j < l; j += 2) {
     const float32x2_t a_00 = vld1_f32(&a[j + 0]);
     const float32x2_t a_08 = vld1_f32(&a[j + 8]);
     const float32x2_t a_32 = vld1_f32(&a[j + 32]);
     const float32x2_t a_40 = vld1_f32(&a[j + 40]);
     const float32x4_t a_00_32 = vcombine_f32(a_00, a_32);
     const float32x4_t a_08_40 = vcombine_f32(a_08, a_40);
     const float32x4_t x0r0_0i0_0r1_x0i1 = vaddq_f32(a_00_32, a_08_40);
     const float32x4_t x1r0_1i0_1r1_x1i1 = vsubq_f32(a_00_32, a_08_40);
     const float32x2_t a_16 = vld1_f32(&a[j + 16]);
     const float32x2_t a_24 = vld1_f32(&a[j + 24]);
     const float32x2_t a_48 = vld1_f32(&a[j + 48]);
     const float32x2_t a_56 = vld1_f32(&a[j + 56]);
     const float32x4_t a_16_48 = vcombine_f32(a_16, a_48);
     const float32x4_t a_24_56 = vcombine_f32(a_24, a_56);
     const float32x4_t x2r0_2i0_2r1_x2i1 = vaddq_f32(a_16_48, a_24_56);
     const float32x4_t x3r0_3i0_3r1_x3i1 = vsubq_f32(a_16_48, a_24_56);
     const float32x4_t xx0 = vaddq_f32(x0r0_0i0_0r1_x0i1, x2r0_2i0_2r1_x2i1);
     const float32x4_t xx1 = vsubq_f32(x0r0_0i0_0r1_x0i1, x2r0_2i0_2r1_x2i1);
     const float32x4_t x3i0_3r0_3i1_x3r1 = vrev64q_f32(x3r0_3i0_3r1_x3i1);
     const float32x4_t x1_x3_add =
         vmlaq_f32(x1r0_1i0_1r1_x1i1, vec_swap_sign, x3i0_3r0_3i1_x3r1);
     const float32x4_t x1_x3_sub =
         vmlsq_f32(x1r0_1i0_1r1_x1i1, vec_swap_sign, x3i0_3r0_3i1_x3r1);
     const float32x2_t yy0_a = vdup_lane_f32(vget_high_f32(x1_x3_add), 0);
     const float32x2_t yy0_s = vdup_lane_f32(vget_high_f32(x1_x3_sub), 0);
     const float32x4_t yy0_as = vcombine_f32(yy0_a, yy0_s);
     const float32x2_t yy1_a = vdup_lane_f32(vget_high_f32(x1_x3_add), 1);
     const float32x2_t yy1_s = vdup_lane_f32(vget_high_f32(x1_x3_sub), 1);
     const float32x4_t yy1_as = vcombine_f32(yy1_a, yy1_s);
     const float32x4_t yy0 = vmlaq_f32(yy0_as, vec_swap_sign, yy1_as);
     const float32x4_t yy4 = vmulq_f32(wk1rv, yy0);
     const float32x4_t xx1_rev = vrev64q_f32(xx1);
     const float32x4_t yy4_rev = vrev64q_f32(yy4);

     vst1_f32(&a[j + 0], vget_low_f32(xx0));
     vst1_f32(&a[j + 32], vget_high_f32(xx0));
     vst1_f32(&a[j + 16], vget_low_f32(xx1));
     vst1_f32(&a[j + 48], vget_high_f32(xx1_rev));

     a[j + 48] = -a[j + 48];

     vst1_f32(&a[j + 8], vget_low_f32(x1_x3_add));
     vst1_f32(&a[j + 24], vget_low_f32(x1_x3_sub));
     vst1_f32(&a[j + 40], vget_low_f32(yy4));
     vst1_f32(&a[j + 56], vget_high_f32(yy4_rev));
   }

   {
     const int k = 64;
     const int k1 = 2;
     const int k2 = 2 * k1;
     const float32x4_t wk2rv = vld1q_f32(&rdft_wk2r[k2 + 0]);
     const float32x4_t wk2iv = vld1q_f32(&rdft_wk2i[k2 + 0]);
     const float32x4_t wk1iv = vld1q_f32(&rdft_wk1i[k2 + 0]);
     const float32x4_t wk3rv = vld1q_f32(&rdft_wk3r[k2 + 0]);
     const float32x4_t wk3iv = vld1q_f32(&rdft_wk3i[k2 + 0]);
     wk1rv = vld1q_f32(&rdft_wk1r[k2 + 0]);
     for (j = k; j < l + k; j += 2) {
       const float32x2_t a_00 = vld1_f32(&a[j + 0]);
       const float32x2_t a_08 = vld1_f32(&a[j + 8]);
       const float32x2_t a_32 = vld1_f32(&a[j + 32]);
       const float32x2_t a_40 = vld1_f32(&a[j + 40]);
       const float32x4_t a_00_32 = vcombine_f32(a_00, a_32);
       const float32x4_t a_08_40 = vcombine_f32(a_08, a_40);
       const float32x4_t x0r0_0i0_0r1_x0i1 = vaddq_f32(a_00_32, a_08_40);
       const float32x4_t x1r0_1i0_1r1_x1i1 = vsubq_f32(a_00_32, a_08_40);
       const float32x2_t a_16 = vld1_f32(&a[j + 16]);
       const float32x2_t a_24 = vld1_f32(&a[j + 24]);
       const float32x2_t a_48 = vld1_f32(&a[j + 48]);
       const float32x2_t a_56 = vld1_f32(&a[j + 56]);
       const float32x4_t a_16_48 = vcombine_f32(a_16, a_48);
       const float32x4_t a_24_56 = vcombine_f32(a_24, a_56);
       const float32x4_t x2r0_2i0_2r1_x2i1 = vaddq_f32(a_16_48, a_24_56);
       const float32x4_t x3r0_3i0_3r1_x3i1 = vsubq_f32(a_16_48, a_24_56);
       const float32x4_t xx = vaddq_f32(x0r0_0i0_0r1_x0i1, x2r0_2i0_2r1_x2i1);
       const float32x4_t xx1 = vsubq_f32(x0r0_0i0_0r1_x0i1, x2r0_2i0_2r1_x2i1);
       const float32x4_t x3i0_3r0_3i1_x3r1 = vrev64q_f32(x3r0_3i0_3r1_x3i1);
       const float32x4_t x1_x3_add =
           vmlaq_f32(x1r0_1i0_1r1_x1i1, vec_swap_sign, x3i0_3r0_3i1_x3r1);
       const float32x4_t x1_x3_sub =
           vmlsq_f32(x1r0_1i0_1r1_x1i1, vec_swap_sign, x3i0_3r0_3i1_x3r1);
       float32x4_t xx4 = vmulq_f32(wk2rv, xx1);
       float32x4_t xx12 = vmulq_f32(wk1rv, x1_x3_add);
       float32x4_t xx22 = vmulq_f32(wk3rv, x1_x3_sub);
       xx4 = vmlaq_f32(xx4, wk2iv, vrev64q_f32(xx1));
       xx12 = vmlaq_f32(xx12, wk1iv, vrev64q_f32(x1_x3_add));
       xx22 = vmlaq_f32(xx22, wk3iv, vrev64q_f32(x1_x3_sub));

       vst1_f32(&a[j + 0], vget_low_f32(xx));
       vst1_f32(&a[j + 32], vget_high_f32(xx));
       vst1_f32(&a[j + 16], vget_low_f32(xx4));
       vst1_f32(&a[j + 48], vget_high_f32(xx4));
       vst1_f32(&a[j + 8], vget_low_f32(xx12));
       vst1_f32(&a[j + 40], vget_high_f32(xx12));
       vst1_f32(&a[j + 24], vget_low_f32(xx22));
       vst1_f32(&a[j + 56], vget_high_f32(xx22));
     }
   }
 }

 __inline static float32x4_t reverse_order_f32x4(float32x4_t in) {
   // A B C D -> C D A B
   const float32x4_t rev = vcombine_f32(vget_high_f32(in), vget_low_f32(in));
   // C D A B -> D C B A
   return vrev64q_f32(rev);
 }

 void rftfsub_128_neon(float* a) {
   const float* c = rdft_w + 32;
   int j1, j2;
   const float32x4_t mm_half = vdupq_n_f32(0.5f);

   // Vectorized code (four at once).
   // Note: commented number are indexes for the first iteration of the loop.
   for (j1 = 1, j2 = 2; j2 + 7 < 64; j1 += 4, j2 += 8) {
     // Load 'wk'.
     const float32x4_t c_j1 = vld1q_f32(&c[j1]);          //  1,  2,  3,  4,
     const float32x4_t c_k1 = vld1q_f32(&c[29 - j1]);     // 28, 29, 30, 31,
     const float32x4_t wkrt = vsubq_f32(mm_half, c_k1);   // 28, 29, 30, 31,
     const float32x4_t wkr_ = reverse_order_f32x4(wkrt);  // 31, 30, 29, 28,
     const float32x4_t wki_ = c_j1;                       //  1,  2,  3,  4,
     // Load and shuffle 'a'.
     //   2,   4,   6,   8,   3,   5,   7,   9
     float32x4x2_t a_j2_p = vld2q_f32(&a[0 + j2]);
     // 120, 122, 124, 126, 121, 123, 125, 127,
     const float32x4x2_t k2_0_4 = vld2q_f32(&a[122 - j2]);
     // 126, 124, 122, 120
     const float32x4_t a_k2_p0 = reverse_order_f32x4(k2_0_4.val[0]);
     // 127, 125, 123, 121
     const float32x4_t a_k2_p1 = reverse_order_f32x4(k2_0_4.val[1]);
     // Calculate 'x'.
     const float32x4_t xr_ = vsubq_f32(a_j2_p.val[0], a_k2_p0);
     // 2-126, 4-124, 6-122, 8-120,
     const float32x4_t xi_ = vaddq_f32(a_j2_p.val[1], a_k2_p1);
     // 3-127, 5-125, 7-123, 9-121,
     // Calculate product into 'y'.
     //    yr = wkr * xr - wki * xi;
     //    yi = wkr * xi + wki * xr;
     const float32x4_t a_ = vmulq_f32(wkr_, xr_);
     const float32x4_t b_ = vmulq_f32(wki_, xi_);
     const float32x4_t c_ = vmulq_f32(wkr_, xi_);
     const float32x4_t d_ = vmulq_f32(wki_, xr_);
     const float32x4_t yr_ = vsubq_f32(a_, b_);  // 2-126, 4-124, 6-122, 8-120,
     const float32x4_t yi_ = vaddq_f32(c_, d_);  // 3-127, 5-125, 7-123, 9-121,
                                                 // Update 'a'.
                                                 //    a[j2 + 0] -= yr;
                                                 //    a[j2 + 1] -= yi;
                                                 //    a[k2 + 0] += yr;
                                                 //    a[k2 + 1] -= yi;
     // 126, 124, 122, 120,
     const float32x4_t a_k2_p0n = vaddq_f32(a_k2_p0, yr_);
     // 127, 125, 123, 121,
     const float32x4_t a_k2_p1n = vsubq_f32(a_k2_p1, yi_);
     // Shuffle in right order and store.
     const float32x4_t a_k2_p0nr = vrev64q_f32(a_k2_p0n);
     const float32x4_t a_k2_p1nr = vrev64q_f32(a_k2_p1n);
     // 124, 125, 126, 127, 120, 121, 122, 123
     const float32x4x2_t a_k2_n = vzipq_f32(a_k2_p0nr, a_k2_p1nr);
     //   2,   4,   6,   8,
     a_j2_p.val[0] = vsubq_f32(a_j2_p.val[0], yr_);
     //   3,   5,   7,   9,
     a_j2_p.val[1] = vsubq_f32(a_j2_p.val[1], yi_);
     //   2,   3,   4,   5,   6,   7,   8,   9,
     vst2q_f32(&a[0 + j2], a_j2_p);

     vst1q_f32(&a[122 - j2], a_k2_n.val[1]);
     vst1q_f32(&a[126 - j2], a_k2_n.val[0]);
   }

   // Scalar code for the remaining items.
   for (; j2 < 64; j1 += 1, j2 += 2) {
     const int k2 = 128 - j2;
     const int k1 = 32 - j1;
     const float wkr = 0.5f - c[k1];
     const float wki = c[j1];
     const float xr = a[j2 + 0] - a[k2 + 0];
     const float xi = a[j2 + 1] + a[k2 + 1];
     const float yr = wkr * xr - wki * xi;
     const float yi = wkr * xi + wki * xr;
     a[j2 + 0] -= yr;
     a[j2 + 1] -= yi;
     a[k2 + 0] += yr;
     a[k2 + 1] -= yi;
   }
 }

 void rftbsub_128_neon(float* a) {
   const float* c = rdft_w + 32;
   int j1, j2;
   const float32x4_t mm_half = vdupq_n_f32(0.5f);

   a[1] = -a[1];
   // Vectorized code (four at once).
   //    Note: commented number are indexes for the first iteration of the loop.
   for (j1 = 1, j2 = 2; j2 + 7 < 64; j1 += 4, j2 += 8) {
     // Load 'wk'.
     const float32x4_t c_j1 = vld1q_f32(&c[j1]);          //  1,  2,  3,  4,
     const float32x4_t c_k1 = vld1q_f32(&c[29 - j1]);     // 28, 29, 30, 31,
     const float32x4_t wkrt = vsubq_f32(mm_half, c_k1);   // 28, 29, 30, 31,
     const float32x4_t wkr_ = reverse_order_f32x4(wkrt);  // 31, 30, 29, 28,
     const float32x4_t wki_ = c_j1;                       //  1,  2,  3,  4,
     // Load and shuffle 'a'.
     //   2,   4,   6,   8,   3,   5,   7,   9
     float32x4x2_t a_j2_p = vld2q_f32(&a[0 + j2]);
     // 120, 122, 124, 126, 121, 123, 125, 127,
     const float32x4x2_t k2_0_4 = vld2q_f32(&a[122 - j2]);
     // 126, 124, 122, 120
     const float32x4_t a_k2_p0 = reverse_order_f32x4(k2_0_4.val[0]);
     // 127, 125, 123, 121
     const float32x4_t a_k2_p1 = reverse_order_f32x4(k2_0_4.val[1]);
     // Calculate 'x'.
     const float32x4_t xr_ = vsubq_f32(a_j2_p.val[0], a_k2_p0);
     // 2-126, 4-124, 6-122, 8-120,
     const float32x4_t xi_ = vaddq_f32(a_j2_p.val[1], a_k2_p1);
     // 3-127, 5-125, 7-123, 9-121,
     // Calculate product into 'y'.
     //    yr = wkr * xr - wki * xi;
     //    yi = wkr * xi + wki * xr;
     const float32x4_t a_ = vmulq_f32(wkr_, xr_);
     const float32x4_t b_ = vmulq_f32(wki_, xi_);
     const float32x4_t c_ = vmulq_f32(wkr_, xi_);
     const float32x4_t d_ = vmulq_f32(wki_, xr_);
     const float32x4_t yr_ = vaddq_f32(a_, b_);  // 2-126, 4-124, 6-122, 8-120,
     const float32x4_t yi_ = vsubq_f32(c_, d_);  // 3-127, 5-125, 7-123, 9-121,
                                                 // Update 'a'.
                                                 //    a[j2 + 0] -= yr;
                                                 //    a[j2 + 1] -= yi;
                                                 //    a[k2 + 0] += yr;
                                                 //    a[k2 + 1] -= yi;
     // 126, 124, 122, 120,
     const float32x4_t a_k2_p0n = vaddq_f32(a_k2_p0, yr_);
     // 127, 125, 123, 121,
     const float32x4_t a_k2_p1n = vsubq_f32(yi_, a_k2_p1);
     // Shuffle in right order and store.
     //   2,   3,   4,   5,   6,   7,   8,   9,
     const float32x4_t a_k2_p0nr = vrev64q_f32(a_k2_p0n);
     const float32x4_t a_k2_p1nr = vrev64q_f32(a_k2_p1n);
     // 124, 125, 126, 127, 120, 121, 122, 123
     const float32x4x2_t a_k2_n = vzipq_f32(a_k2_p0nr, a_k2_p1nr);
     //   2,   4,   6,   8,
     a_j2_p.val[0] = vsubq_f32(a_j2_p.val[0], yr_);
     //   3,   5,   7,   9,
     a_j2_p.val[1] = vsubq_f32(yi_, a_j2_p.val[1]);
     //   2,   3,   4,   5,   6,   7,   8,   9,
     vst2q_f32(&a[0 + j2], a_j2_p);

     vst1q_f32(&a[122 - j2], a_k2_n.val[1]);
     vst1q_f32(&a[126 - j2], a_k2_n.val[0]);
   }

   // Scalar code for the remaining items.
   for (; j2 < 64; j1 += 1, j2 += 2) {
     const int k2 = 128 - j2;
     const int k1 = 32 - j1;
     const float wkr = 0.5f - c[k1];
     const float wki = c[j1];
     const float xr = a[j2 + 0] - a[k2 + 0];
     const float xi = a[j2 + 1] + a[k2 + 1];
     const float yr = wkr * xr + wki * xi;
     const float 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];
 }
 #endif

 }  // namespace webrtc
	/*
	* Copyright (c) 2014 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.
	*/

	/*
	* The rdft AEC algorithm, neon version of speed-critical functions.
	*
	* Based on the sse2 version.
	*/

	#include <arm_neon.h>

	#include "common_audio/third_party/ooura/fft_size_128/ooura_fft.h"
	#include "common_audio/third_party/ooura/fft_size_128/ooura_fft_tables_common.h"
	#include "common_audio/third_party/ooura/fft_size_128/ooura_fft_tables_neon_sse2.h"

	namespace webrtc {

	#if defined(WEBRTC_HAS_NEON)
	void cft1st_128_neon(float* a) {
	const float32x4_t vec_swap_sign = vld1q_f32((float32_t*)k_swap_sign);
	int j, k2;

	for (k2 = 0, j = 0; j < 128; j += 16, k2 += 4) {
	float32x4_t a00v = vld1q_f32(&a[j + 0]);
	float32x4_t a04v = vld1q_f32(&a[j + 4]);
	float32x4_t a08v = vld1q_f32(&a[j + 8]);
	float32x4_t a12v = vld1q_f32(&a[j + 12]);
	float32x4_t a01v = vcombine_f32(vget_low_f32(a00v), vget_low_f32(a08v));
	float32x4_t a23v = vcombine_f32(vget_high_f32(a00v), vget_high_f32(a08v));
	float32x4_t a45v = vcombine_f32(vget_low_f32(a04v), vget_low_f32(a12v));
	float32x4_t a67v = vcombine_f32(vget_high_f32(a04v), vget_high_f32(a12v));
	const float32x4_t wk1rv = vld1q_f32(&rdft_wk1r[k2]);
	const float32x4_t wk1iv = vld1q_f32(&rdft_wk1i[k2]);
	const float32x4_t wk2rv = vld1q_f32(&rdft_wk2r[k2]);
	const float32x4_t wk2iv = vld1q_f32(&rdft_wk2i[k2]);
	const float32x4_t wk3rv = vld1q_f32(&rdft_wk3r[k2]);
	const float32x4_t wk3iv = vld1q_f32(&rdft_wk3i[k2]);
	float32x4_t x0v = vaddq_f32(a01v, a23v);
	const float32x4_t x1v = vsubq_f32(a01v, a23v);
	const float32x4_t x2v = vaddq_f32(a45v, a67v);
	const float32x4_t x3v = vsubq_f32(a45v, a67v);
	const float32x4_t x3w = vrev64q_f32(x3v);
	float32x4_t x0w;
	a01v = vaddq_f32(x0v, x2v);
	x0v = vsubq_f32(x0v, x2v);
	x0w = vrev64q_f32(x0v);
	a45v = vmulq_f32(wk2rv, x0v);
	a45v = vmlaq_f32(a45v, wk2iv, x0w);
	x0v = vmlaq_f32(x1v, x3w, vec_swap_sign);
	x0w = vrev64q_f32(x0v);
	a23v = vmulq_f32(wk1rv, x0v);
	a23v = vmlaq_f32(a23v, wk1iv, x0w);
	x0v = vmlsq_f32(x1v, x3w, vec_swap_sign);
	x0w = vrev64q_f32(x0v);
	a67v = vmulq_f32(wk3rv, x0v);
	a67v = vmlaq_f32(a67v, wk3iv, x0w);
	a00v = vcombine_f32(vget_low_f32(a01v), vget_low_f32(a23v));
	a04v = vcombine_f32(vget_low_f32(a45v), vget_low_f32(a67v));
	a08v = vcombine_f32(vget_high_f32(a01v), vget_high_f32(a23v));
	a12v = vcombine_f32(vget_high_f32(a45v), vget_high_f32(a67v));
	vst1q_f32(&a[j + 0], a00v);
	vst1q_f32(&a[j + 4], a04v);
	vst1q_f32(&a[j + 8], a08v);
	vst1q_f32(&a[j + 12], a12v);
	}
	}

	void cftmdl_128_neon(float* a) {
	int j;
	const int l = 8;
	const float32x4_t vec_swap_sign = vld1q_f32((float32_t*)k_swap_sign);
	float32x4_t wk1rv = vld1q_f32(cftmdl_wk1r);

	for (j = 0; j < l; j += 2) {
	const float32x2_t a_00 = vld1_f32(&a[j + 0]);
	const float32x2_t a_08 = vld1_f32(&a[j + 8]);
	const float32x2_t a_32 = vld1_f32(&a[j + 32]);
	const float32x2_t a_40 = vld1_f32(&a[j + 40]);
	const float32x4_t a_00_32 = vcombine_f32(a_00, a_32);
	const float32x4_t a_08_40 = vcombine_f32(a_08, a_40);
	const float32x4_t x0r0_0i0_0r1_x0i1 = vaddq_f32(a_00_32, a_08_40);
	const float32x4_t x1r0_1i0_1r1_x1i1 = vsubq_f32(a_00_32, a_08_40);
	const float32x2_t a_16 = vld1_f32(&a[j + 16]);
	const float32x2_t a_24 = vld1_f32(&a[j + 24]);
	const float32x2_t a_48 = vld1_f32(&a[j + 48]);
	const float32x2_t a_56 = vld1_f32(&a[j + 56]);
	const float32x4_t a_16_48 = vcombine_f32(a_16, a_48);
	const float32x4_t a_24_56 = vcombine_f32(a_24, a_56);
	const float32x4_t x2r0_2i0_2r1_x2i1 = vaddq_f32(a_16_48, a_24_56);
	const float32x4_t x3r0_3i0_3r1_x3i1 = vsubq_f32(a_16_48, a_24_56);
	const float32x4_t xx0 = vaddq_f32(x0r0_0i0_0r1_x0i1, x2r0_2i0_2r1_x2i1);
	const float32x4_t xx1 = vsubq_f32(x0r0_0i0_0r1_x0i1, x2r0_2i0_2r1_x2i1);
	const float32x4_t x3i0_3r0_3i1_x3r1 = vrev64q_f32(x3r0_3i0_3r1_x3i1);
	const float32x4_t x1_x3_add =
	vmlaq_f32(x1r0_1i0_1r1_x1i1, vec_swap_sign, x3i0_3r0_3i1_x3r1);
	const float32x4_t x1_x3_sub =
	vmlsq_f32(x1r0_1i0_1r1_x1i1, vec_swap_sign, x3i0_3r0_3i1_x3r1);
	const float32x2_t yy0_a = vdup_lane_f32(vget_high_f32(x1_x3_add), 0);
	const float32x2_t yy0_s = vdup_lane_f32(vget_high_f32(x1_x3_sub), 0);
	const float32x4_t yy0_as = vcombine_f32(yy0_a, yy0_s);
	const float32x2_t yy1_a = vdup_lane_f32(vget_high_f32(x1_x3_add), 1);
	const float32x2_t yy1_s = vdup_lane_f32(vget_high_f32(x1_x3_sub), 1);
	const float32x4_t yy1_as = vcombine_f32(yy1_a, yy1_s);
	const float32x4_t yy0 = vmlaq_f32(yy0_as, vec_swap_sign, yy1_as);
	const float32x4_t yy4 = vmulq_f32(wk1rv, yy0);
	const float32x4_t xx1_rev = vrev64q_f32(xx1);
	const float32x4_t yy4_rev = vrev64q_f32(yy4);

	vst1_f32(&a[j + 0], vget_low_f32(xx0));
	vst1_f32(&a[j + 32], vget_high_f32(xx0));
	vst1_f32(&a[j + 16], vget_low_f32(xx1));
	vst1_f32(&a[j + 48], vget_high_f32(xx1_rev));

	a[j + 48] = -a[j + 48];

	vst1_f32(&a[j + 8], vget_low_f32(x1_x3_add));
	vst1_f32(&a[j + 24], vget_low_f32(x1_x3_sub));
	vst1_f32(&a[j + 40], vget_low_f32(yy4));
	vst1_f32(&a[j + 56], vget_high_f32(yy4_rev));
	}

	{
	const int k = 64;
	const int k1 = 2;
	const int k2 = 2 * k1;
	const float32x4_t wk2rv = vld1q_f32(&rdft_wk2r[k2 + 0]);
	const float32x4_t wk2iv = vld1q_f32(&rdft_wk2i[k2 + 0]);
	const float32x4_t wk1iv = vld1q_f32(&rdft_wk1i[k2 + 0]);
	const float32x4_t wk3rv = vld1q_f32(&rdft_wk3r[k2 + 0]);
	const float32x4_t wk3iv = vld1q_f32(&rdft_wk3i[k2 + 0]);
	wk1rv = vld1q_f32(&rdft_wk1r[k2 + 0]);
	for (j = k; j < l + k; j += 2) {
	const float32x2_t a_00 = vld1_f32(&a[j + 0]);
	const float32x2_t a_08 = vld1_f32(&a[j + 8]);
	const float32x2_t a_32 = vld1_f32(&a[j + 32]);
	const float32x2_t a_40 = vld1_f32(&a[j + 40]);
	const float32x4_t a_00_32 = vcombine_f32(a_00, a_32);
	const float32x4_t a_08_40 = vcombine_f32(a_08, a_40);
	const float32x4_t x0r0_0i0_0r1_x0i1 = vaddq_f32(a_00_32, a_08_40);
	const float32x4_t x1r0_1i0_1r1_x1i1 = vsubq_f32(a_00_32, a_08_40);
	const float32x2_t a_16 = vld1_f32(&a[j + 16]);
	const float32x2_t a_24 = vld1_f32(&a[j + 24]);
	const float32x2_t a_48 = vld1_f32(&a[j + 48]);
	const float32x2_t a_56 = vld1_f32(&a[j + 56]);
	const float32x4_t a_16_48 = vcombine_f32(a_16, a_48);
	const float32x4_t a_24_56 = vcombine_f32(a_24, a_56);
	const float32x4_t x2r0_2i0_2r1_x2i1 = vaddq_f32(a_16_48, a_24_56);
	const float32x4_t x3r0_3i0_3r1_x3i1 = vsubq_f32(a_16_48, a_24_56);
	const float32x4_t xx = vaddq_f32(x0r0_0i0_0r1_x0i1, x2r0_2i0_2r1_x2i1);
	const float32x4_t xx1 = vsubq_f32(x0r0_0i0_0r1_x0i1, x2r0_2i0_2r1_x2i1);
	const float32x4_t x3i0_3r0_3i1_x3r1 = vrev64q_f32(x3r0_3i0_3r1_x3i1);
	const float32x4_t x1_x3_add =
	vmlaq_f32(x1r0_1i0_1r1_x1i1, vec_swap_sign, x3i0_3r0_3i1_x3r1);
	const float32x4_t x1_x3_sub =
	vmlsq_f32(x1r0_1i0_1r1_x1i1, vec_swap_sign, x3i0_3r0_3i1_x3r1);
	float32x4_t xx4 = vmulq_f32(wk2rv, xx1);
	float32x4_t xx12 = vmulq_f32(wk1rv, x1_x3_add);
	float32x4_t xx22 = vmulq_f32(wk3rv, x1_x3_sub);
	xx4 = vmlaq_f32(xx4, wk2iv, vrev64q_f32(xx1));
	xx12 = vmlaq_f32(xx12, wk1iv, vrev64q_f32(x1_x3_add));
	xx22 = vmlaq_f32(xx22, wk3iv, vrev64q_f32(x1_x3_sub));

	vst1_f32(&a[j + 0], vget_low_f32(xx));
	vst1_f32(&a[j + 32], vget_high_f32(xx));
	vst1_f32(&a[j + 16], vget_low_f32(xx4));
	vst1_f32(&a[j + 48], vget_high_f32(xx4));
	vst1_f32(&a[j + 8], vget_low_f32(xx12));
	vst1_f32(&a[j + 40], vget_high_f32(xx12));
	vst1_f32(&a[j + 24], vget_low_f32(xx22));
	vst1_f32(&a[j + 56], vget_high_f32(xx22));
	}
	}
	}

	__inline static float32x4_t reverse_order_f32x4(float32x4_t in) {
	// A B C D -> C D A B
	const float32x4_t rev = vcombine_f32(vget_high_f32(in), vget_low_f32(in));
	// C D A B -> D C B A
	return vrev64q_f32(rev);
	}

	void rftfsub_128_neon(float* a) {
	const float* c = rdft_w + 32;
	int j1, j2;
	const float32x4_t mm_half = vdupq_n_f32(0.5f);

	// Vectorized code (four at once).
	// Note: commented number are indexes for the first iteration of the loop.
	for (j1 = 1, j2 = 2; j2 + 7 < 64; j1 += 4, j2 += 8) {
	// Load 'wk'.
	const float32x4_t c_j1 = vld1q_f32(&c[j1]); // 1, 2, 3, 4,
	const float32x4_t c_k1 = vld1q_f32(&c[29 - j1]); // 28, 29, 30, 31,
	const float32x4_t wkrt = vsubq_f32(mm_half, c_k1); // 28, 29, 30, 31,
	const float32x4_t wkr_ = reverse_order_f32x4(wkrt); // 31, 30, 29, 28,
	const float32x4_t wki_ = c_j1; // 1, 2, 3, 4,
	// Load and shuffle 'a'.
	// 2, 4, 6, 8, 3, 5, 7, 9
	float32x4x2_t a_j2_p = vld2q_f32(&a[0 + j2]);
	// 120, 122, 124, 126, 121, 123, 125, 127,
	const float32x4x2_t k2_0_4 = vld2q_f32(&a[122 - j2]);
	// 126, 124, 122, 120
	const float32x4_t a_k2_p0 = reverse_order_f32x4(k2_0_4.val[0]);
	// 127, 125, 123, 121
	const float32x4_t a_k2_p1 = reverse_order_f32x4(k2_0_4.val[1]);
	// Calculate 'x'.
	const float32x4_t xr_ = vsubq_f32(a_j2_p.val[0], a_k2_p0);
	// 2-126, 4-124, 6-122, 8-120,
	const float32x4_t xi_ = vaddq_f32(a_j2_p.val[1], a_k2_p1);
	// 3-127, 5-125, 7-123, 9-121,
	// Calculate product into 'y'.
	// yr = wkr * xr - wki * xi;
	// yi = wkr * xi + wki * xr;
	const float32x4_t a_ = vmulq_f32(wkr_, xr_);
	const float32x4_t b_ = vmulq_f32(wki_, xi_);
	const float32x4_t c_ = vmulq_f32(wkr_, xi_);
	const float32x4_t d_ = vmulq_f32(wki_, xr_);
	const float32x4_t yr_ = vsubq_f32(a_, b_); // 2-126, 4-124, 6-122, 8-120,
	const float32x4_t yi_ = vaddq_f32(c_, d_); // 3-127, 5-125, 7-123, 9-121,
	// Update 'a'.
	// a[j2 + 0] -= yr;
	// a[j2 + 1] -= yi;
	// a[k2 + 0] += yr;
	// a[k2 + 1] -= yi;
	// 126, 124, 122, 120,
	const float32x4_t a_k2_p0n = vaddq_f32(a_k2_p0, yr_);
	// 127, 125, 123, 121,
	const float32x4_t a_k2_p1n = vsubq_f32(a_k2_p1, yi_);
	// Shuffle in right order and store.
	const float32x4_t a_k2_p0nr = vrev64q_f32(a_k2_p0n);
	const float32x4_t a_k2_p1nr = vrev64q_f32(a_k2_p1n);
	// 124, 125, 126, 127, 120, 121, 122, 123
	const float32x4x2_t a_k2_n = vzipq_f32(a_k2_p0nr, a_k2_p1nr);
	// 2, 4, 6, 8,
	a_j2_p.val[0] = vsubq_f32(a_j2_p.val[0], yr_);
	// 3, 5, 7, 9,
	a_j2_p.val[1] = vsubq_f32(a_j2_p.val[1], yi_);
	// 2, 3, 4, 5, 6, 7, 8, 9,
	vst2q_f32(&a[0 + j2], a_j2_p);

	vst1q_f32(&a[122 - j2], a_k2_n.val[1]);
	vst1q_f32(&a[126 - j2], a_k2_n.val[0]);
	}

	// Scalar code for the remaining items.
	for (; j2 < 64; j1 += 1, j2 += 2) {
	const int k2 = 128 - j2;
	const int k1 = 32 - j1;
	const float wkr = 0.5f - c[k1];
	const float wki = c[j1];
	const float xr = a[j2 + 0] - a[k2 + 0];
	const float xi = a[j2 + 1] + a[k2 + 1];
	const float yr = wkr * xr - wki * xi;
	const float yi = wkr * xi + wki * xr;
	a[j2 + 0] -= yr;
	a[j2 + 1] -= yi;
	a[k2 + 0] += yr;
	a[k2 + 1] -= yi;
	}
	}

	void rftbsub_128_neon(float* a) {
	const float* c = rdft_w + 32;
	int j1, j2;
	const float32x4_t mm_half = vdupq_n_f32(0.5f);

	a[1] = -a[1];
	// Vectorized code (four at once).
	// Note: commented number are indexes for the first iteration of the loop.
	for (j1 = 1, j2 = 2; j2 + 7 < 64; j1 += 4, j2 += 8) {
	// Load 'wk'.
	const float32x4_t c_j1 = vld1q_f32(&c[j1]); // 1, 2, 3, 4,
	const float32x4_t c_k1 = vld1q_f32(&c[29 - j1]); // 28, 29, 30, 31,
	const float32x4_t wkrt = vsubq_f32(mm_half, c_k1); // 28, 29, 30, 31,
	const float32x4_t wkr_ = reverse_order_f32x4(wkrt); // 31, 30, 29, 28,
	const float32x4_t wki_ = c_j1; // 1, 2, 3, 4,
	// Load and shuffle 'a'.
	// 2, 4, 6, 8, 3, 5, 7, 9
	float32x4x2_t a_j2_p = vld2q_f32(&a[0 + j2]);
	// 120, 122, 124, 126, 121, 123, 125, 127,
	const float32x4x2_t k2_0_4 = vld2q_f32(&a[122 - j2]);
	// 126, 124, 122, 120
	const float32x4_t a_k2_p0 = reverse_order_f32x4(k2_0_4.val[0]);
	// 127, 125, 123, 121
	const float32x4_t a_k2_p1 = reverse_order_f32x4(k2_0_4.val[1]);
	// Calculate 'x'.
	const float32x4_t xr_ = vsubq_f32(a_j2_p.val[0], a_k2_p0);
	// 2-126, 4-124, 6-122, 8-120,
	const float32x4_t xi_ = vaddq_f32(a_j2_p.val[1], a_k2_p1);
	// 3-127, 5-125, 7-123, 9-121,
	// Calculate product into 'y'.
	// yr = wkr * xr - wki * xi;
	// yi = wkr * xi + wki * xr;
	const float32x4_t a_ = vmulq_f32(wkr_, xr_);
	const float32x4_t b_ = vmulq_f32(wki_, xi_);
	const float32x4_t c_ = vmulq_f32(wkr_, xi_);
	const float32x4_t d_ = vmulq_f32(wki_, xr_);
	const float32x4_t yr_ = vaddq_f32(a_, b_); // 2-126, 4-124, 6-122, 8-120,
	const float32x4_t yi_ = vsubq_f32(c_, d_); // 3-127, 5-125, 7-123, 9-121,
	// Update 'a'.
	// a[j2 + 0] -= yr;
	// a[j2 + 1] -= yi;
	// a[k2 + 0] += yr;
	// a[k2 + 1] -= yi;
	// 126, 124, 122, 120,
	const float32x4_t a_k2_p0n = vaddq_f32(a_k2_p0, yr_);
	// 127, 125, 123, 121,
	const float32x4_t a_k2_p1n = vsubq_f32(yi_, a_k2_p1);
	// Shuffle in right order and store.
	// 2, 3, 4, 5, 6, 7, 8, 9,
	const float32x4_t a_k2_p0nr = vrev64q_f32(a_k2_p0n);
	const float32x4_t a_k2_p1nr = vrev64q_f32(a_k2_p1n);
	// 124, 125, 126, 127, 120, 121, 122, 123
	const float32x4x2_t a_k2_n = vzipq_f32(a_k2_p0nr, a_k2_p1nr);
	// 2, 4, 6, 8,
	a_j2_p.val[0] = vsubq_f32(a_j2_p.val[0], yr_);
	// 3, 5, 7, 9,
	a_j2_p.val[1] = vsubq_f32(yi_, a_j2_p.val[1]);
	// 2, 3, 4, 5, 6, 7, 8, 9,
	vst2q_f32(&a[0 + j2], a_j2_p);

	vst1q_f32(&a[122 - j2], a_k2_n.val[1]);
	vst1q_f32(&a[126 - j2], a_k2_n.val[0]);
	}

	// Scalar code for the remaining items.
	for (; j2 < 64; j1 += 1, j2 += 2) {
	const int k2 = 128 - j2;
	const int k1 = 32 - j1;
	const float wkr = 0.5f - c[k1];
	const float wki = c[j1];
	const float xr = a[j2 + 0] - a[k2 + 0];
	const float xi = a[j2 + 1] + a[k2 + 1];
	const float yr = wkr * xr + wki * xi;
	const float 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];
	}
	#endif

	} // namespace webrtc