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cobalt / cobalt / cc19caab3101a025a2ae4db11601ed3496c7d730 / . / third_party / libvpx / vpx_dsp / arm / fdct32x32_neon.c
blob: e9cd34904b60d60f5c2ab0cd507ad40e0b118815 [file] [log] [blame]
/*
* Copyright (c) 2017 The WebM 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.
*/
#include <arm_neon.h>
#include "./vpx_config.h"
#include "./vpx_dsp_rtcd.h"
#include "vpx_dsp/txfm_common.h"
#include "vpx_dsp/arm/mem_neon.h"
#include "vpx_dsp/arm/transpose_neon.h"
// Most gcc 4.9 distributions outside of Android do not generate correct code
// for this function.
#if !defined(__clang__) && !defined(__ANDROID__) && defined(__GNUC__) && \
__GNUC__ == 4 && __GNUC_MINOR__ <= 9
void vpx_fdct32x32_neon(const int16_t *input, tran_low_t *output, int stride) {
vpx_fdct32x32_c(input, output, stride);
}
void vpx_fdct32x32_rd_neon(const int16_t *input, tran_low_t *output,
int stride) {
vpx_fdct32x32_rd_c(input, output, stride);
}
#else
#define LOAD_INCREMENT(src, stride, dest, index) \
do { \
dest[index] = vld1q_s16(src); \
src += stride; \
} while (0)
#define ADD_S16(src, index0, index1, dest, index3) \
do { \
dest[index3] = vaddq_s16(src[index0], src[index1]); \
} while (0)
#define ADD_SHIFT_S16(src, index0, index1) \
do { \
src[index1] = vshlq_n_s16(vsubq_s16(src[index0], src[index1]), 2); \
} while (0)
// Load, cross, and multiply by 4. Load the first 8 and last 8, then the
// middle
// 16. Doing sets of 16 at a time. Maybe sets of 8 would be better?
static INLINE void load(const int16_t *a, int stride, int16x8_t *b) {
const int16_t *a_end = a + 24 * stride;
int16x8_t c[8];
LOAD_INCREMENT(a, stride, b, 0);
LOAD_INCREMENT(a, stride, b, 1);
LOAD_INCREMENT(a, stride, b, 2);
LOAD_INCREMENT(a, stride, b, 3);
LOAD_INCREMENT(a, stride, b, 4);
LOAD_INCREMENT(a, stride, b, 5);
LOAD_INCREMENT(a, stride, b, 6);
LOAD_INCREMENT(a, stride, b, 7);
LOAD_INCREMENT(a_end, stride, b, 24);
LOAD_INCREMENT(a_end, stride, b, 25);
LOAD_INCREMENT(a_end, stride, b, 26);
LOAD_INCREMENT(a_end, stride, b, 27);
LOAD_INCREMENT(a_end, stride, b, 28);
LOAD_INCREMENT(a_end, stride, b, 29);
LOAD_INCREMENT(a_end, stride, b, 30);
LOAD_INCREMENT(a_end, stride, b, 31);
ADD_S16(b, 0, 31, c, 0);
ADD_S16(b, 1, 30, c, 1);
ADD_S16(b, 2, 29, c, 2);
ADD_S16(b, 3, 28, c, 3);
ADD_S16(b, 4, 27, c, 4);
ADD_S16(b, 5, 26, c, 5);
ADD_S16(b, 6, 25, c, 6);
ADD_S16(b, 7, 24, c, 7);
ADD_SHIFT_S16(b, 7, 24);
ADD_SHIFT_S16(b, 6, 25);
ADD_SHIFT_S16(b, 5, 26);
ADD_SHIFT_S16(b, 4, 27);
ADD_SHIFT_S16(b, 3, 28);
ADD_SHIFT_S16(b, 2, 29);
ADD_SHIFT_S16(b, 1, 30);
ADD_SHIFT_S16(b, 0, 31);
b[0] = vshlq_n_s16(c[0], 2);
b[1] = vshlq_n_s16(c[1], 2);
b[2] = vshlq_n_s16(c[2], 2);
b[3] = vshlq_n_s16(c[3], 2);
b[4] = vshlq_n_s16(c[4], 2);
b[5] = vshlq_n_s16(c[5], 2);
b[6] = vshlq_n_s16(c[6], 2);
b[7] = vshlq_n_s16(c[7], 2);
LOAD_INCREMENT(a, stride, b, 8);
LOAD_INCREMENT(a, stride, b, 9);
LOAD_INCREMENT(a, stride, b, 10);
LOAD_INCREMENT(a, stride, b, 11);
LOAD_INCREMENT(a, stride, b, 12);
LOAD_INCREMENT(a, stride, b, 13);
LOAD_INCREMENT(a, stride, b, 14);
LOAD_INCREMENT(a, stride, b, 15);
LOAD_INCREMENT(a, stride, b, 16);
LOAD_INCREMENT(a, stride, b, 17);
LOAD_INCREMENT(a, stride, b, 18);
LOAD_INCREMENT(a, stride, b, 19);
LOAD_INCREMENT(a, stride, b, 20);
LOAD_INCREMENT(a, stride, b, 21);
LOAD_INCREMENT(a, stride, b, 22);
LOAD_INCREMENT(a, stride, b, 23);
ADD_S16(b, 8, 23, c, 0);
ADD_S16(b, 9, 22, c, 1);
ADD_S16(b, 10, 21, c, 2);
ADD_S16(b, 11, 20, c, 3);
ADD_S16(b, 12, 19, c, 4);
ADD_S16(b, 13, 18, c, 5);
ADD_S16(b, 14, 17, c, 6);
ADD_S16(b, 15, 16, c, 7);
ADD_SHIFT_S16(b, 15, 16);
ADD_SHIFT_S16(b, 14, 17);
ADD_SHIFT_S16(b, 13, 18);
ADD_SHIFT_S16(b, 12, 19);
ADD_SHIFT_S16(b, 11, 20);
ADD_SHIFT_S16(b, 10, 21);
ADD_SHIFT_S16(b, 9, 22);
ADD_SHIFT_S16(b, 8, 23);
b[8] = vshlq_n_s16(c[0], 2);
b[9] = vshlq_n_s16(c[1], 2);
b[10] = vshlq_n_s16(c[2], 2);
b[11] = vshlq_n_s16(c[3], 2);
b[12] = vshlq_n_s16(c[4], 2);
b[13] = vshlq_n_s16(c[5], 2);
b[14] = vshlq_n_s16(c[6], 2);
b[15] = vshlq_n_s16(c[7], 2);
}
#undef LOAD_INCREMENT
#undef ADD_S16
#undef ADD_SHIFT_S16
#define STORE_S16(src, index, dest) \
do { \
store_s16q_to_tran_low(dest, src[index]); \
dest += 8; \
} while (0);
// Store 32 16x8 values, assuming stride == 32.
// Slight twist: store horizontally in blocks of 8.
static INLINE void store(tran_low_t *a, const int16x8_t *b) {
STORE_S16(b, 0, a);
STORE_S16(b, 8, a);
STORE_S16(b, 16, a);
STORE_S16(b, 24, a);
STORE_S16(b, 1, a);
STORE_S16(b, 9, a);
STORE_S16(b, 17, a);
STORE_S16(b, 25, a);
STORE_S16(b, 2, a);
STORE_S16(b, 10, a);
STORE_S16(b, 18, a);
STORE_S16(b, 26, a);
STORE_S16(b, 3, a);
STORE_S16(b, 11, a);
STORE_S16(b, 19, a);
STORE_S16(b, 27, a);
STORE_S16(b, 4, a);
STORE_S16(b, 12, a);
STORE_S16(b, 20, a);
STORE_S16(b, 28, a);
STORE_S16(b, 5, a);
STORE_S16(b, 13, a);
STORE_S16(b, 21, a);
STORE_S16(b, 29, a);
STORE_S16(b, 6, a);
STORE_S16(b, 14, a);
STORE_S16(b, 22, a);
STORE_S16(b, 30, a);
STORE_S16(b, 7, a);
STORE_S16(b, 15, a);
STORE_S16(b, 23, a);
STORE_S16(b, 31, a);
}
#undef STORE_S16
// fdct_round_shift((a +/- b) * c)
static INLINE void butterfly_one_coeff(const int16x8_t a, const int16x8_t b,
const tran_high_t constant,
int16x8_t *add, int16x8_t *sub) {
const int32x4_t a0 = vmull_n_s16(vget_low_s16(a), constant);
const int32x4_t a1 = vmull_n_s16(vget_high_s16(a), constant);
const int32x4_t sum0 = vmlal_n_s16(a0, vget_low_s16(b), constant);
const int32x4_t sum1 = vmlal_n_s16(a1, vget_high_s16(b), constant);
const int32x4_t diff0 = vmlsl_n_s16(a0, vget_low_s16(b), constant);
const int32x4_t diff1 = vmlsl_n_s16(a1, vget_high_s16(b), constant);
const int16x4_t rounded0 = vqrshrn_n_s32(sum0, DCT_CONST_BITS);
const int16x4_t rounded1 = vqrshrn_n_s32(sum1, DCT_CONST_BITS);
const int16x4_t rounded2 = vqrshrn_n_s32(diff0, DCT_CONST_BITS);
const int16x4_t rounded3 = vqrshrn_n_s32(diff1, DCT_CONST_BITS);
*add = vcombine_s16(rounded0, rounded1);
*sub = vcombine_s16(rounded2, rounded3);
}
// fdct_round_shift(a * c0 +/- b * c1)
static INLINE void butterfly_two_coeff(const int16x8_t a, const int16x8_t b,
const tran_coef_t constant0,
const tran_coef_t constant1,
int16x8_t *add, int16x8_t *sub) {
const int32x4_t a0 = vmull_n_s16(vget_low_s16(a), constant0);
const int32x4_t a1 = vmull_n_s16(vget_high_s16(a), constant0);
const int32x4_t a2 = vmull_n_s16(vget_low_s16(a), constant1);
const int32x4_t a3 = vmull_n_s16(vget_high_s16(a), constant1);
const int32x4_t sum0 = vmlal_n_s16(a2, vget_low_s16(b), constant0);
const int32x4_t sum1 = vmlal_n_s16(a3, vget_high_s16(b), constant0);
const int32x4_t diff0 = vmlsl_n_s16(a0, vget_low_s16(b), constant1);
const int32x4_t diff1 = vmlsl_n_s16(a1, vget_high_s16(b), constant1);
const int16x4_t rounded0 = vqrshrn_n_s32(sum0, DCT_CONST_BITS);
const int16x4_t rounded1 = vqrshrn_n_s32(sum1, DCT_CONST_BITS);
const int16x4_t rounded2 = vqrshrn_n_s32(diff0, DCT_CONST_BITS);
const int16x4_t rounded3 = vqrshrn_n_s32(diff1, DCT_CONST_BITS);
*add = vcombine_s16(rounded0, rounded1);
*sub = vcombine_s16(rounded2, rounded3);
}
// Add 2 if positive, 1 if negative, and shift by 2.
// In practice, subtract the sign bit, then shift with rounding.
static INLINE int16x8_t sub_round_shift(const int16x8_t a) {
const uint16x8_t a_u16 = vreinterpretq_u16_s16(a);
const uint16x8_t a_sign_u16 = vshrq_n_u16(a_u16, 15);
const int16x8_t a_sign_s16 = vreinterpretq_s16_u16(a_sign_u16);
return vrshrq_n_s16(vsubq_s16(a, a_sign_s16), 2);
}
static void dct_body_first_pass(const int16x8_t *in, int16x8_t *out) {
int16x8_t a[32];
int16x8_t b[32];
// Stage 1: Done as part of the load.
// Stage 2.
// Mini cross. X the first 16 values and the middle 8 of the second half.
a[0] = vaddq_s16(in[0], in[15]);
a[1] = vaddq_s16(in[1], in[14]);
a[2] = vaddq_s16(in[2], in[13]);
a[3] = vaddq_s16(in[3], in[12]);
a[4] = vaddq_s16(in[4], in[11]);
a[5] = vaddq_s16(in[5], in[10]);
a[6] = vaddq_s16(in[6], in[9]);
a[7] = vaddq_s16(in[7], in[8]);
a[8] = vsubq_s16(in[7], in[8]);
a[9] = vsubq_s16(in[6], in[9]);
a[10] = vsubq_s16(in[5], in[10]);
a[11] = vsubq_s16(in[4], in[11]);
a[12] = vsubq_s16(in[3], in[12]);
a[13] = vsubq_s16(in[2], in[13]);
a[14] = vsubq_s16(in[1], in[14]);
a[15] = vsubq_s16(in[0], in[15]);
a[16] = in[16];
a[17] = in[17];
a[18] = in[18];
a[19] = in[19];
butterfly_one_coeff(in[27], in[20], cospi_16_64, &a[27], &a[20]);
butterfly_one_coeff(in[26], in[21], cospi_16_64, &a[26], &a[21]);
butterfly_one_coeff(in[25], in[22], cospi_16_64, &a[25], &a[22]);
butterfly_one_coeff(in[24], in[23], cospi_16_64, &a[24], &a[23]);
a[28] = in[28];
a[29] = in[29];
a[30] = in[30];
a[31] = in[31];
// Stage 3.
b[0] = vaddq_s16(a[0], a[7]);
b[1] = vaddq_s16(a[1], a[6]);
b[2] = vaddq_s16(a[2], a[5]);
b[3] = vaddq_s16(a[3], a[4]);
b[4] = vsubq_s16(a[3], a[4]);
b[5] = vsubq_s16(a[2], a[5]);
b[6] = vsubq_s16(a[1], a[6]);
b[7] = vsubq_s16(a[0], a[7]);
b[8] = a[8];
b[9] = a[9];
butterfly_one_coeff(a[13], a[10], cospi_16_64, &b[13], &b[10]);
butterfly_one_coeff(a[12], a[11], cospi_16_64, &b[12], &b[11]);
b[14] = a[14];
b[15] = a[15];
b[16] = vaddq_s16(in[16], a[23]);
b[17] = vaddq_s16(in[17], a[22]);
b[18] = vaddq_s16(in[18], a[21]);
b[19] = vaddq_s16(in[19], a[20]);
b[20] = vsubq_s16(in[19], a[20]);
b[21] = vsubq_s16(in[18], a[21]);
b[22] = vsubq_s16(in[17], a[22]);
b[23] = vsubq_s16(in[16], a[23]);
b[24] = vsubq_s16(in[31], a[24]);
b[25] = vsubq_s16(in[30], a[25]);
b[26] = vsubq_s16(in[29], a[26]);
b[27] = vsubq_s16(in[28], a[27]);
b[28] = vaddq_s16(in[28], a[27]);
b[29] = vaddq_s16(in[29], a[26]);
b[30] = vaddq_s16(in[30], a[25]);
b[31] = vaddq_s16(in[31], a[24]);
// Stage 4.
a[0] = vaddq_s16(b[0], b[3]);
a[1] = vaddq_s16(b[1], b[2]);
a[2] = vsubq_s16(b[1], b[2]);
a[3] = vsubq_s16(b[0], b[3]);
a[4] = b[4];
butterfly_one_coeff(b[6], b[5], cospi_16_64, &a[6], &a[5]);
a[7] = b[7];
a[8] = vaddq_s16(b[8], b[11]);
a[9] = vaddq_s16(b[9], b[10]);
a[10] = vsubq_s16(b[9], b[10]);
a[11] = vsubq_s16(b[8], b[11]);
a[12] = vsubq_s16(b[15], b[12]);
a[13] = vsubq_s16(b[14], b[13]);
a[14] = vaddq_s16(b[14], b[13]);
a[15] = vaddq_s16(b[15], b[12]);
a[16] = b[16];
a[17] = b[17];
butterfly_two_coeff(b[29], b[18], cospi_24_64, cospi_8_64, &a[29], &a[18]);
butterfly_two_coeff(b[28], b[19], cospi_24_64, cospi_8_64, &a[28], &a[19]);
butterfly_two_coeff(b[27], b[20], -cospi_8_64, cospi_24_64, &a[27], &a[20]);
butterfly_two_coeff(b[26], b[21], -cospi_8_64, cospi_24_64, &a[26], &a[21]);
a[22] = b[22];
a[23] = b[23];
a[24] = b[24];
a[25] = b[25];
a[30] = b[30];
a[31] = b[31];
// Stage 5.
butterfly_one_coeff(a[0], a[1], cospi_16_64, &b[0], &b[1]);
butterfly_two_coeff(a[3], a[2], cospi_24_64, cospi_8_64, &b[2], &b[3]);
b[4] = vaddq_s16(a[4], a[5]);
b[5] = vsubq_s16(a[4], a[5]);
b[6] = vsubq_s16(a[7], a[6]);
b[7] = vaddq_s16(a[7], a[6]);
b[8] = a[8];
butterfly_two_coeff(a[14], a[9], cospi_24_64, cospi_8_64, &b[14], &b[9]);
butterfly_two_coeff(a[13], a[10], -cospi_8_64, cospi_24_64, &b[13], &b[10]);
b[11] = a[11];
b[12] = a[12];
b[15] = a[15];
b[16] = vaddq_s16(a[19], a[16]);
b[17] = vaddq_s16(a[18], a[17]);
b[18] = vsubq_s16(a[17], a[18]);
b[19] = vsubq_s16(a[16], a[19]);
b[20] = vsubq_s16(a[23], a[20]);
b[21] = vsubq_s16(a[22], a[21]);
b[22] = vaddq_s16(a[21], a[22]);
b[23] = vaddq_s16(a[20], a[23]);
b[24] = vaddq_s16(a[27], a[24]);
b[25] = vaddq_s16(a[26], a[25]);
b[26] = vsubq_s16(a[25], a[26]);
b[27] = vsubq_s16(a[24], a[27]);
b[28] = vsubq_s16(a[31], a[28]);
b[29] = vsubq_s16(a[30], a[29]);
b[30] = vaddq_s16(a[29], a[30]);
b[31] = vaddq_s16(a[28], a[31]);
// Stage 6.
a[0] = b[0];
a[1] = b[1];
a[2] = b[2];
a[3] = b[3];
butterfly_two_coeff(b[7], b[4], cospi_28_64, cospi_4_64, &a[4], &a[7]);
butterfly_two_coeff(b[6], b[5], cospi_12_64, cospi_20_64, &a[5], &a[6]);
a[8] = vaddq_s16(b[8], b[9]);
a[9] = vsubq_s16(b[8], b[9]);
a[10] = vsubq_s16(b[11], b[10]);
a[11] = vaddq_s16(b[11], b[10]);
a[12] = vaddq_s16(b[12], b[13]);
a[13] = vsubq_s16(b[12], b[13]);
a[14] = vsubq_s16(b[15], b[14]);
a[15] = vaddq_s16(b[15], b[14]);
a[16] = b[16];
a[19] = b[19];
a[20] = b[20];
a[23] = b[23];
a[24] = b[24];
a[27] = b[27];
a[28] = b[28];
a[31] = b[31];
butterfly_two_coeff(b[30], b[17], cospi_28_64, cospi_4_64, &a[30], &a[17]);
butterfly_two_coeff(b[29], b[18], -cospi_4_64, cospi_28_64, &a[29], &a[18]);
butterfly_two_coeff(b[26], b[21], cospi_12_64, cospi_20_64, &a[26], &a[21]);
butterfly_two_coeff(b[25], b[22], -cospi_20_64, cospi_12_64, &a[25], &a[22]);
// Stage 7.
b[0] = a[0];
b[1] = a[1];
b[2] = a[2];
b[3] = a[3];
b[4] = a[4];
b[5] = a[5];
b[6] = a[6];
b[7] = a[7];
butterfly_two_coeff(a[15], a[8], cospi_30_64, cospi_2_64, &b[8], &b[15]);
butterfly_two_coeff(a[14], a[9], cospi_14_64, cospi_18_64, &b[9], &b[14]);
butterfly_two_coeff(a[13], a[10], cospi_22_64, cospi_10_64, &b[10], &b[13]);
butterfly_two_coeff(a[12], a[11], cospi_6_64, cospi_26_64, &b[11], &b[12]);
b[16] = vaddq_s16(a[16], a[17]);
b[17] = vsubq_s16(a[16], a[17]);
b[18] = vsubq_s16(a[19], a[18]);
b[19] = vaddq_s16(a[19], a[18]);
b[20] = vaddq_s16(a[20], a[21]);
b[21] = vsubq_s16(a[20], a[21]);
b[22] = vsubq_s16(a[23], a[22]);
b[23] = vaddq_s16(a[23], a[22]);
b[24] = vaddq_s16(a[24], a[25]);
b[25] = vsubq_s16(a[24], a[25]);
b[26] = vsubq_s16(a[27], a[26]);
b[27] = vaddq_s16(a[27], a[26]);
b[28] = vaddq_s16(a[28], a[29]);
b[29] = vsubq_s16(a[28], a[29]);
b[30] = vsubq_s16(a[31], a[30]);
b[31] = vaddq_s16(a[31], a[30]);
// Final stage.
// Also compute partial rounding shift:
// output[j * 32 + i] = (temp_out[j] + 1 + (temp_out[j] > 0)) >> 2;
out[0] = sub_round_shift(b[0]);
out[16] = sub_round_shift(b[1]);
out[8] = sub_round_shift(b[2]);
out[24] = sub_round_shift(b[3]);
out[4] = sub_round_shift(b[4]);
out[20] = sub_round_shift(b[5]);
out[12] = sub_round_shift(b[6]);
out[28] = sub_round_shift(b[7]);
out[2] = sub_round_shift(b[8]);
out[18] = sub_round_shift(b[9]);
out[10] = sub_round_shift(b[10]);
out[26] = sub_round_shift(b[11]);
out[6] = sub_round_shift(b[12]);
out[22] = sub_round_shift(b[13]);
out[14] = sub_round_shift(b[14]);
out[30] = sub_round_shift(b[15]);
butterfly_two_coeff(b[31], b[16], cospi_31_64, cospi_1_64, &a[1], &a[31]);
out[1] = sub_round_shift(a[1]);
out[31] = sub_round_shift(a[31]);
butterfly_two_coeff(b[30], b[17], cospi_15_64, cospi_17_64, &a[17], &a[15]);
out[17] = sub_round_shift(a[17]);
out[15] = sub_round_shift(a[15]);
butterfly_two_coeff(b[29], b[18], cospi_23_64, cospi_9_64, &a[9], &a[23]);
out[9] = sub_round_shift(a[9]);
out[23] = sub_round_shift(a[23]);
butterfly_two_coeff(b[28], b[19], cospi_7_64, cospi_25_64, &a[25], &a[7]);
out[25] = sub_round_shift(a[25]);
out[7] = sub_round_shift(a[7]);
butterfly_two_coeff(b[27], b[20], cospi_27_64, cospi_5_64, &a[5], &a[27]);
out[5] = sub_round_shift(a[5]);
out[27] = sub_round_shift(a[27]);
butterfly_two_coeff(b[26], b[21], cospi_11_64, cospi_21_64, &a[21], &a[11]);
out[21] = sub_round_shift(a[21]);
out[11] = sub_round_shift(a[11]);
butterfly_two_coeff(b[25], b[22], cospi_19_64, cospi_13_64, &a[13], &a[19]);
out[13] = sub_round_shift(a[13]);
out[19] = sub_round_shift(a[19]);
butterfly_two_coeff(b[24], b[23], cospi_3_64, cospi_29_64, &a[29], &a[3]);
out[29] = sub_round_shift(a[29]);
out[3] = sub_round_shift(a[3]);
}
#define PASS_THROUGH(src, dst, element) \
do { \
dst##_lo[element] = src##_lo[element]; \
dst##_hi[element] = src##_hi[element]; \
} while (0)
#define ADD_S16_S32(a, left_index, right_index, b, b_index) \
do { \
b##_lo[b_index] = \
vaddl_s16(vget_low_s16(a[left_index]), vget_low_s16(a[right_index])); \
b##_hi[b_index] = vaddl_s16(vget_high_s16(a[left_index]), \
vget_high_s16(a[right_index])); \
} while (0)
#define SUB_S16_S32(a, left_index, right_index, b, b_index) \
do { \
b##_lo[b_index] = \
vsubl_s16(vget_low_s16(a[left_index]), vget_low_s16(a[right_index])); \
b##_hi[b_index] = vsubl_s16(vget_high_s16(a[left_index]), \
vget_high_s16(a[right_index])); \
} while (0)
#define ADDW_S16_S32(a, a_index, b, b_index, c, c_index) \
do { \
c##_lo[c_index] = vaddw_s16(a##_lo[a_index], vget_low_s16(b[b_index])); \
c##_hi[c_index] = vaddw_s16(a##_hi[a_index], vget_high_s16(b[b_index])); \
} while (0)
#define SUBW_S16_S32(a, a_index, b, b_index, temp, temp_index, c, c_index) \
do { \
temp##_lo[temp_index] = vmovl_s16(vget_low_s16(a[a_index])); \
temp##_hi[temp_index] = vmovl_s16(vget_high_s16(a[a_index])); \
c##_lo[c_index] = vsubq_s32(temp##_lo[temp_index], b##_lo[b_index]); \
c##_hi[c_index] = vsubq_s32(temp##_hi[temp_index], b##_hi[b_index]); \
} while (0)
#define ADD_S32(a, left_index, right_index, b, b_index) \
do { \
b##_lo[b_index] = vaddq_s32(a##_lo[left_index], a##_lo[right_index]); \
b##_hi[b_index] = vaddq_s32(a##_hi[left_index], a##_hi[right_index]); \
} while (0)
#define SUB_S32(a, left_index, right_index, b, b_index) \
do { \
b##_lo[b_index] = vsubq_s32(a##_lo[left_index], a##_lo[right_index]); \
b##_hi[b_index] = vsubq_s32(a##_hi[left_index], a##_hi[right_index]); \
} while (0)
// Like butterfly_one_coeff, but don't narrow results.
static INLINE void butterfly_one_coeff_s16_s32(
const int16x8_t a, const int16x8_t b, const tran_high_t constant,
int32x4_t *add_lo, int32x4_t *add_hi, int32x4_t *sub_lo,
int32x4_t *sub_hi) {
const int32x4_t a0 = vmull_n_s16(vget_low_s16(a), constant);
const int32x4_t a1 = vmull_n_s16(vget_high_s16(a), constant);
const int32x4_t sum0 = vmlal_n_s16(a0, vget_low_s16(b), constant);
const int32x4_t sum1 = vmlal_n_s16(a1, vget_high_s16(b), constant);
const int32x4_t diff0 = vmlsl_n_s16(a0, vget_low_s16(b), constant);
const int32x4_t diff1 = vmlsl_n_s16(a1, vget_high_s16(b), constant);
*add_lo = vrshrq_n_s32(sum0, DCT_CONST_BITS);
*add_hi = vrshrq_n_s32(sum1, DCT_CONST_BITS);
*sub_lo = vrshrq_n_s32(diff0, DCT_CONST_BITS);
*sub_hi = vrshrq_n_s32(diff1, DCT_CONST_BITS);
}
#define BUTTERFLY_ONE_S16_S32(a, left_index, right_index, constant, b, \
add_index, sub_index) \
do { \
butterfly_one_coeff_s16_s32(a[left_index], a[right_index], constant, \
&b##_lo[add_index], &b##_hi[add_index], \
&b##_lo[sub_index], &b##_hi[sub_index]); \
} while (0)
// Like butterfly_one_coeff, but with s32.
static INLINE void butterfly_one_coeff_s32(
const int32x4_t a_lo, const int32x4_t a_hi, const int32x4_t b_lo,
const int32x4_t b_hi, const int32_t constant, int32x4_t *add_lo,
int32x4_t *add_hi, int32x4_t *sub_lo, int32x4_t *sub_hi) {
const int32x4_t a_lo_0 = vmulq_n_s32(a_lo, constant);
const int32x4_t a_hi_0 = vmulq_n_s32(a_hi, constant);
const int32x4_t sum0 = vmlaq_n_s32(a_lo_0, b_lo, constant);
const int32x4_t sum1 = vmlaq_n_s32(a_hi_0, b_hi, constant);
const int32x4_t diff0 = vmlsq_n_s32(a_lo_0, b_lo, constant);
const int32x4_t diff1 = vmlsq_n_s32(a_hi_0, b_hi, constant);
*add_lo = vrshrq_n_s32(sum0, DCT_CONST_BITS);
*add_hi = vrshrq_n_s32(sum1, DCT_CONST_BITS);
*sub_lo = vrshrq_n_s32(diff0, DCT_CONST_BITS);
*sub_hi = vrshrq_n_s32(diff1, DCT_CONST_BITS);
}
#define BUTTERFLY_ONE_S32(a, left_index, right_index, constant, b, add_index, \
sub_index) \
do { \
butterfly_one_coeff_s32(a##_lo[left_index], a##_hi[left_index], \
a##_lo[right_index], a##_hi[right_index], \
constant, &b##_lo[add_index], &b##_hi[add_index], \
&b##_lo[sub_index], &b##_hi[sub_index]); \
} while (0)
// Like butterfly_two_coeff, but with s32.
static INLINE void butterfly_two_coeff_s32(
const int32x4_t a_lo, const int32x4_t a_hi, const int32x4_t b_lo,
const int32x4_t b_hi, const int32_t constant0, const int32_t constant1,
int32x4_t *add_lo, int32x4_t *add_hi, int32x4_t *sub_lo,
int32x4_t *sub_hi) {
const int32x4_t a0 = vmulq_n_s32(a_lo, constant0);
const int32x4_t a1 = vmulq_n_s32(a_hi, constant0);
const int32x4_t a2 = vmulq_n_s32(a_lo, constant1);
const int32x4_t a3 = vmulq_n_s32(a_hi, constant1);
const int32x4_t sum0 = vmlaq_n_s32(a2, b_lo, constant0);
const int32x4_t sum1 = vmlaq_n_s32(a3, b_hi, constant0);
const int32x4_t diff0 = vmlsq_n_s32(a0, b_lo, constant1);
const int32x4_t diff1 = vmlsq_n_s32(a1, b_hi, constant1);
*add_lo = vrshrq_n_s32(sum0, DCT_CONST_BITS);
*add_hi = vrshrq_n_s32(sum1, DCT_CONST_BITS);
*sub_lo = vrshrq_n_s32(diff0, DCT_CONST_BITS);
*sub_hi = vrshrq_n_s32(diff1, DCT_CONST_BITS);
}
#define BUTTERFLY_TWO_S32(a, left_index, right_index, left_constant, \
right_constant, b, add_index, sub_index) \
do { \
butterfly_two_coeff_s32(a##_lo[left_index], a##_hi[left_index], \
a##_lo[right_index], a##_hi[right_index], \
left_constant, right_constant, &b##_lo[add_index], \
&b##_hi[add_index], &b##_lo[sub_index], \
&b##_hi[sub_index]); \
} while (0)
// Add 1 if positive, 2 if negative, and shift by 2.
// In practice, add 1, then add the sign bit, then shift without rounding.
static INLINE int16x8_t add_round_shift_s32(const int32x4_t a_lo,
const int32x4_t a_hi) {
const int32x4_t one = vdupq_n_s32(1);
const uint32x4_t a_lo_u32 = vreinterpretq_u32_s32(a_lo);
const uint32x4_t a_lo_sign_u32 = vshrq_n_u32(a_lo_u32, 31);
const int32x4_t a_lo_sign_s32 = vreinterpretq_s32_u32(a_lo_sign_u32);
const int16x4_t b_lo =
vshrn_n_s32(vqaddq_s32(vqaddq_s32(a_lo, a_lo_sign_s32), one), 2);
const uint32x4_t a_hi_u32 = vreinterpretq_u32_s32(a_hi);
const uint32x4_t a_hi_sign_u32 = vshrq_n_u32(a_hi_u32, 31);
const int32x4_t a_hi_sign_s32 = vreinterpretq_s32_u32(a_hi_sign_u32);
const int16x4_t b_hi =
vshrn_n_s32(vqaddq_s32(vqaddq_s32(a_hi, a_hi_sign_s32), one), 2);
return vcombine_s16(b_lo, b_hi);
}
static void dct_body_second_pass(const int16x8_t *in, int16x8_t *out) {
int16x8_t a[32];
int16x8_t b[32];
int32x4_t c_lo[32];
int32x4_t c_hi[32];
int32x4_t d_lo[32];
int32x4_t d_hi[32];
// Stage 1. Done as part of the load for the first pass.
a[0] = vaddq_s16(in[0], in[31]);
a[1] = vaddq_s16(in[1], in[30]);
a[2] = vaddq_s16(in[2], in[29]);
a[3] = vaddq_s16(in[3], in[28]);
a[4] = vaddq_s16(in[4], in[27]);
a[5] = vaddq_s16(in[5], in[26]);
a[6] = vaddq_s16(in[6], in[25]);
a[7] = vaddq_s16(in[7], in[24]);
a[8] = vaddq_s16(in[8], in[23]);
a[9] = vaddq_s16(in[9], in[22]);
a[10] = vaddq_s16(in[10], in[21]);
a[11] = vaddq_s16(in[11], in[20]);
a[12] = vaddq_s16(in[12], in[19]);
a[13] = vaddq_s16(in[13], in[18]);
a[14] = vaddq_s16(in[14], in[17]);
a[15] = vaddq_s16(in[15], in[16]);
a[16] = vsubq_s16(in[15], in[16]);
a[17] = vsubq_s16(in[14], in[17]);
a[18] = vsubq_s16(in[13], in[18]);
a[19] = vsubq_s16(in[12], in[19]);
a[20] = vsubq_s16(in[11], in[20]);
a[21] = vsubq_s16(in[10], in[21]);
a[22] = vsubq_s16(in[9], in[22]);
a[23] = vsubq_s16(in[8], in[23]);
a[24] = vsubq_s16(in[7], in[24]);
a[25] = vsubq_s16(in[6], in[25]);
a[26] = vsubq_s16(in[5], in[26]);
a[27] = vsubq_s16(in[4], in[27]);
a[28] = vsubq_s16(in[3], in[28]);
a[29] = vsubq_s16(in[2], in[29]);
a[30] = vsubq_s16(in[1], in[30]);
a[31] = vsubq_s16(in[0], in[31]);
// Stage 2.
b[0] = vaddq_s16(a[0], a[15]);
b[1] = vaddq_s16(a[1], a[14]);
b[2] = vaddq_s16(a[2], a[13]);
b[3] = vaddq_s16(a[3], a[12]);
b[4] = vaddq_s16(a[4], a[11]);
b[5] = vaddq_s16(a[5], a[10]);
b[6] = vaddq_s16(a[6], a[9]);
b[7] = vaddq_s16(a[7], a[8]);
b[8] = vsubq_s16(a[7], a[8]);
b[9] = vsubq_s16(a[6], a[9]);
b[10] = vsubq_s16(a[5], a[10]);
b[11] = vsubq_s16(a[4], a[11]);
b[12] = vsubq_s16(a[3], a[12]);
b[13] = vsubq_s16(a[2], a[13]);
b[14] = vsubq_s16(a[1], a[14]);
b[15] = vsubq_s16(a[0], a[15]);
b[16] = a[16];
b[17] = a[17];
b[18] = a[18];
b[19] = a[19];
butterfly_one_coeff(a[27], a[20], cospi_16_64, &b[27], &b[20]);
butterfly_one_coeff(a[26], a[21], cospi_16_64, &b[26], &b[21]);
butterfly_one_coeff(a[25], a[22], cospi_16_64, &b[25], &b[22]);
butterfly_one_coeff(a[24], a[23], cospi_16_64, &b[24], &b[23]);
b[28] = a[28];
b[29] = a[29];
b[30] = a[30];
b[31] = a[31];
// Stage 3. With extreme values for input this calculation rolls over int16_t.
// The sources for b[0] get added multiple times and, through testing, have
// been shown to overflow starting here.
ADD_S16_S32(b, 0, 7, c, 0);
ADD_S16_S32(b, 1, 6, c, 1);
ADD_S16_S32(b, 2, 5, c, 2);
ADD_S16_S32(b, 3, 4, c, 3);
SUB_S16_S32(b, 3, 4, c, 4);
SUB_S16_S32(b, 2, 5, c, 5);
SUB_S16_S32(b, 1, 6, c, 6);
SUB_S16_S32(b, 0, 7, c, 7);
a[8] = b[8];
a[9] = b[9];
BUTTERFLY_ONE_S16_S32(b, 13, 10, cospi_16_64, c, 13, 10);
BUTTERFLY_ONE_S16_S32(b, 12, 11, cospi_16_64, c, 12, 11);
a[14] = b[14];
a[15] = b[15];
ADD_S16_S32(b, 16, 23, c, 16);
ADD_S16_S32(b, 17, 22, c, 17);
ADD_S16_S32(b, 18, 21, c, 18);
ADD_S16_S32(b, 19, 20, c, 19);
SUB_S16_S32(b, 19, 20, c, 20);
SUB_S16_S32(b, 18, 21, c, 21);
SUB_S16_S32(b, 17, 22, c, 22);
SUB_S16_S32(b, 16, 23, c, 23);
SUB_S16_S32(b, 31, 24, c, 24);
SUB_S16_S32(b, 30, 25, c, 25);
SUB_S16_S32(b, 29, 26, c, 26);
SUB_S16_S32(b, 28, 27, c, 27);
ADD_S16_S32(b, 28, 27, c, 28);
ADD_S16_S32(b, 29, 26, c, 29);
ADD_S16_S32(b, 30, 25, c, 30);
ADD_S16_S32(b, 31, 24, c, 31);
// Stage 4.
ADD_S32(c, 0, 3, d, 0);
ADD_S32(c, 1, 2, d, 1);
SUB_S32(c, 1, 2, d, 2);
SUB_S32(c, 0, 3, d, 3);
PASS_THROUGH(c, d, 4);
BUTTERFLY_ONE_S32(c, 6, 5, cospi_16_64, d, 6, 5);
PASS_THROUGH(c, d, 7);
ADDW_S16_S32(c, 11, a, 8, d, 8);
ADDW_S16_S32(c, 10, a, 9, d, 9);
SUBW_S16_S32(a, 9, c, 10, c, 9, d, 10);
SUBW_S16_S32(a, 8, c, 11, c, 8, d, 11);
SUBW_S16_S32(a, 15, c, 12, c, 15, d, 12);
SUBW_S16_S32(a, 14, c, 13, c, 14, d, 13);
ADDW_S16_S32(c, 13, b, 14, d, 14);
ADDW_S16_S32(c, 12, b, 15, d, 15);
PASS_THROUGH(c, d, 16);
PASS_THROUGH(c, d, 17);
BUTTERFLY_TWO_S32(c, 29, 18, cospi_24_64, cospi_8_64, d, 29, 18);
BUTTERFLY_TWO_S32(c, 28, 19, cospi_24_64, cospi_8_64, d, 28, 19);
BUTTERFLY_TWO_S32(c, 27, 20, -cospi_8_64, cospi_24_64, d, 27, 20);
BUTTERFLY_TWO_S32(c, 26, 21, -cospi_8_64, cospi_24_64, d, 26, 21);
PASS_THROUGH(c, d, 22);
PASS_THROUGH(c, d, 23);
PASS_THROUGH(c, d, 24);
PASS_THROUGH(c, d, 25);
PASS_THROUGH(c, d, 30);
PASS_THROUGH(c, d, 31);
// Stage 5.
BUTTERFLY_ONE_S32(d, 0, 1, cospi_16_64, c, 0, 1);
BUTTERFLY_TWO_S32(d, 3, 2, cospi_24_64, cospi_8_64, c, 2, 3);
ADD_S32(d, 4, 5, c, 4);
SUB_S32(d, 4, 5, c, 5);
SUB_S32(d, 7, 6, c, 6);
ADD_S32(d, 7, 6, c, 7);
PASS_THROUGH(d, c, 8);
BUTTERFLY_TWO_S32(d, 14, 9, cospi_24_64, cospi_8_64, c, 14, 9);
BUTTERFLY_TWO_S32(d, 13, 10, -cospi_8_64, cospi_24_64, c, 13, 10);
PASS_THROUGH(d, c, 11);
PASS_THROUGH(d, c, 12);
PASS_THROUGH(d, c, 15);
ADD_S32(d, 16, 19, c, 16);
ADD_S32(d, 17, 18, c, 17);
SUB_S32(d, 17, 18, c, 18);
SUB_S32(d, 16, 19, c, 19);
SUB_S32(d, 23, 20, c, 20);
SUB_S32(d, 22, 21, c, 21);
ADD_S32(d, 22, 21, c, 22);
ADD_S32(d, 23, 20, c, 23);
ADD_S32(d, 24, 27, c, 24);
ADD_S32(d, 25, 26, c, 25);
SUB_S32(d, 25, 26, c, 26);
SUB_S32(d, 24, 27, c, 27);
SUB_S32(d, 31, 28, c, 28);
SUB_S32(d, 30, 29, c, 29);
ADD_S32(d, 30, 29, c, 30);
ADD_S32(d, 31, 28, c, 31);
// Stage 6.
PASS_THROUGH(c, d, 0);
PASS_THROUGH(c, d, 1);
PASS_THROUGH(c, d, 2);
PASS_THROUGH(c, d, 3);
BUTTERFLY_TWO_S32(c, 7, 4, cospi_28_64, cospi_4_64, d, 4, 7);
BUTTERFLY_TWO_S32(c, 6, 5, cospi_12_64, cospi_20_64, d, 5, 6);
ADD_S32(c, 8, 9, d, 8);
SUB_S32(c, 8, 9, d, 9);
SUB_S32(c, 11, 10, d, 10);
ADD_S32(c, 11, 10, d, 11);
ADD_S32(c, 12, 13, d, 12);
SUB_S32(c, 12, 13, d, 13);
SUB_S32(c, 15, 14, d, 14);
ADD_S32(c, 15, 14, d, 15);
PASS_THROUGH(c, d, 16);
PASS_THROUGH(c, d, 19);
PASS_THROUGH(c, d, 20);
PASS_THROUGH(c, d, 23);
PASS_THROUGH(c, d, 24);
PASS_THROUGH(c, d, 27);
PASS_THROUGH(c, d, 28);
PASS_THROUGH(c, d, 31);
BUTTERFLY_TWO_S32(c, 30, 17, cospi_28_64, cospi_4_64, d, 30, 17);
BUTTERFLY_TWO_S32(c, 29, 18, -cospi_4_64, cospi_28_64, d, 29, 18);
BUTTERFLY_TWO_S32(c, 26, 21, cospi_12_64, cospi_20_64, d, 26, 21);
BUTTERFLY_TWO_S32(c, 25, 22, -cospi_20_64, cospi_12_64, d, 25, 22);
// Stage 7.
PASS_THROUGH(d, c, 0);
PASS_THROUGH(d, c, 1);
PASS_THROUGH(d, c, 2);
PASS_THROUGH(d, c, 3);
PASS_THROUGH(d, c, 4);
PASS_THROUGH(d, c, 5);
PASS_THROUGH(d, c, 6);
PASS_THROUGH(d, c, 7);
BUTTERFLY_TWO_S32(d, 15, 8, cospi_30_64, cospi_2_64, c, 8, 15);
BUTTERFLY_TWO_S32(d, 14, 9, cospi_14_64, cospi_18_64, c, 9, 14);
BUTTERFLY_TWO_S32(d, 13, 10, cospi_22_64, cospi_10_64, c, 10, 13);
BUTTERFLY_TWO_S32(d, 12, 11, cospi_6_64, cospi_26_64, c, 11, 12);
ADD_S32(d, 16, 17, c, 16);
SUB_S32(d, 16, 17, c, 17);
SUB_S32(d, 19, 18, c, 18);
ADD_S32(d, 19, 18, c, 19);
ADD_S32(d, 20, 21, c, 20);
SUB_S32(d, 20, 21, c, 21);
SUB_S32(d, 23, 22, c, 22);
ADD_S32(d, 23, 22, c, 23);
ADD_S32(d, 24, 25, c, 24);
SUB_S32(d, 24, 25, c, 25);
SUB_S32(d, 27, 26, c, 26);
ADD_S32(d, 27, 26, c, 27);
ADD_S32(d, 28, 29, c, 28);
SUB_S32(d, 28, 29, c, 29);
SUB_S32(d, 31, 30, c, 30);
ADD_S32(d, 31, 30, c, 31);
// Final stage.
// Roll rounding into this function so we can pass back int16x8.
out[0] = add_round_shift_s32(c_lo[0], c_hi[0]);
out[16] = add_round_shift_s32(c_lo[1], c_hi[1]);
out[8] = add_round_shift_s32(c_lo[2], c_hi[2]);
out[24] = add_round_shift_s32(c_lo[3], c_hi[3]);
out[4] = add_round_shift_s32(c_lo[4], c_hi[4]);
out[20] = add_round_shift_s32(c_lo[5], c_hi[5]);
out[12] = add_round_shift_s32(c_lo[6], c_hi[6]);
out[28] = add_round_shift_s32(c_lo[7], c_hi[7]);
out[2] = add_round_shift_s32(c_lo[8], c_hi[8]);
out[18] = add_round_shift_s32(c_lo[9], c_hi[9]);
out[10] = add_round_shift_s32(c_lo[10], c_hi[10]);
out[26] = add_round_shift_s32(c_lo[11], c_hi[11]);
out[6] = add_round_shift_s32(c_lo[12], c_hi[12]);
out[22] = add_round_shift_s32(c_lo[13], c_hi[13]);
out[14] = add_round_shift_s32(c_lo[14], c_hi[14]);
out[30] = add_round_shift_s32(c_lo[15], c_hi[15]);
BUTTERFLY_TWO_S32(c, 31, 16, cospi_31_64, cospi_1_64, d, 1, 31);
out[1] = add_round_shift_s32(d_lo[1], d_hi[1]);
out[31] = add_round_shift_s32(d_lo[31], d_hi[31]);
BUTTERFLY_TWO_S32(c, 30, 17, cospi_15_64, cospi_17_64, d, 17, 15);
out[17] = add_round_shift_s32(d_lo[17], d_hi[17]);
out[15] = add_round_shift_s32(d_lo[15], d_hi[15]);
BUTTERFLY_TWO_S32(c, 29, 18, cospi_23_64, cospi_9_64, d, 9, 23);
out[9] = add_round_shift_s32(d_lo[9], d_hi[9]);
out[23] = add_round_shift_s32(d_lo[23], d_hi[23]);
BUTTERFLY_TWO_S32(c, 28, 19, cospi_7_64, cospi_25_64, d, 25, 7);
out[25] = add_round_shift_s32(d_lo[25], d_hi[25]);
out[7] = add_round_shift_s32(d_lo[7], d_hi[7]);
BUTTERFLY_TWO_S32(c, 27, 20, cospi_27_64, cospi_5_64, d, 5, 27);
out[5] = add_round_shift_s32(d_lo[5], d_hi[5]);
out[27] = add_round_shift_s32(d_lo[27], d_hi[27]);
BUTTERFLY_TWO_S32(c, 26, 21, cospi_11_64, cospi_21_64, d, 21, 11);
out[21] = add_round_shift_s32(d_lo[21], d_hi[21]);
out[11] = add_round_shift_s32(d_lo[11], d_hi[11]);
BUTTERFLY_TWO_S32(c, 25, 22, cospi_19_64, cospi_13_64, d, 13, 19);
out[13] = add_round_shift_s32(d_lo[13], d_hi[13]);
out[19] = add_round_shift_s32(d_lo[19], d_hi[19]);
BUTTERFLY_TWO_S32(c, 24, 23, cospi_3_64, cospi_29_64, d, 29, 3);
out[29] = add_round_shift_s32(d_lo[29], d_hi[29]);
out[3] = add_round_shift_s32(d_lo[3], d_hi[3]);
}
// Add 1 if positive, 2 if negative, and shift by 2.
// In practice, add 1, then add the sign bit, then shift without rounding.
static INLINE int16x8_t add_round_shift_s16(const int16x8_t a) {
const int16x8_t one = vdupq_n_s16(1);
const uint16x8_t a_u16 = vreinterpretq_u16_s16(a);
const uint16x8_t a_sign_u16 = vshrq_n_u16(a_u16, 15);
const int16x8_t a_sign_s16 = vreinterpretq_s16_u16(a_sign_u16);
return vshrq_n_s16(vaddq_s16(vaddq_s16(a, a_sign_s16), one), 2);
}
static void dct_body_second_pass_rd(const int16x8_t *in, int16x8_t *out) {
int16x8_t a[32];
int16x8_t b[32];
// Stage 1. Done as part of the load for the first pass.
a[0] = vaddq_s16(in[0], in[31]);
a[1] = vaddq_s16(in[1], in[30]);
a[2] = vaddq_s16(in[2], in[29]);
a[3] = vaddq_s16(in[3], in[28]);
a[4] = vaddq_s16(in[4], in[27]);
a[5] = vaddq_s16(in[5], in[26]);
a[6] = vaddq_s16(in[6], in[25]);
a[7] = vaddq_s16(in[7], in[24]);
a[8] = vaddq_s16(in[8], in[23]);
a[9] = vaddq_s16(in[9], in[22]);
a[10] = vaddq_s16(in[10], in[21]);
a[11] = vaddq_s16(in[11], in[20]);
a[12] = vaddq_s16(in[12], in[19]);
a[13] = vaddq_s16(in[13], in[18]);
a[14] = vaddq_s16(in[14], in[17]);
a[15] = vaddq_s16(in[15], in[16]);
a[16] = vsubq_s16(in[15], in[16]);
a[17] = vsubq_s16(in[14], in[17]);
a[18] = vsubq_s16(in[13], in[18]);
a[19] = vsubq_s16(in[12], in[19]);
a[20] = vsubq_s16(in[11], in[20]);
a[21] = vsubq_s16(in[10], in[21]);
a[22] = vsubq_s16(in[9], in[22]);
a[23] = vsubq_s16(in[8], in[23]);
a[24] = vsubq_s16(in[7], in[24]);
a[25] = vsubq_s16(in[6], in[25]);
a[26] = vsubq_s16(in[5], in[26]);
a[27] = vsubq_s16(in[4], in[27]);
a[28] = vsubq_s16(in[3], in[28]);
a[29] = vsubq_s16(in[2], in[29]);
a[30] = vsubq_s16(in[1], in[30]);
a[31] = vsubq_s16(in[0], in[31]);
// Stage 2.
// For the "rd" version, all the values are rounded down after stage 2 to keep
// the values in 16 bits.
b[0] = add_round_shift_s16(vaddq_s16(a[0], a[15]));
b[1] = add_round_shift_s16(vaddq_s16(a[1], a[14]));
b[2] = add_round_shift_s16(vaddq_s16(a[2], a[13]));
b[3] = add_round_shift_s16(vaddq_s16(a[3], a[12]));
b[4] = add_round_shift_s16(vaddq_s16(a[4], a[11]));
b[5] = add_round_shift_s16(vaddq_s16(a[5], a[10]));
b[6] = add_round_shift_s16(vaddq_s16(a[6], a[9]));
b[7] = add_round_shift_s16(vaddq_s16(a[7], a[8]));
b[8] = add_round_shift_s16(vsubq_s16(a[7], a[8]));
b[9] = add_round_shift_s16(vsubq_s16(a[6], a[9]));
b[10] = add_round_shift_s16(vsubq_s16(a[5], a[10]));
b[11] = add_round_shift_s16(vsubq_s16(a[4], a[11]));
b[12] = add_round_shift_s16(vsubq_s16(a[3], a[12]));
b[13] = add_round_shift_s16(vsubq_s16(a[2], a[13]));
b[14] = add_round_shift_s16(vsubq_s16(a[1], a[14]));
b[15] = add_round_shift_s16(vsubq_s16(a[0], a[15]));
b[16] = add_round_shift_s16(a[16]);
b[17] = add_round_shift_s16(a[17]);
b[18] = add_round_shift_s16(a[18]);
b[19] = add_round_shift_s16(a[19]);
butterfly_one_coeff(a[27], a[20], cospi_16_64, &b[27], &b[20]);
butterfly_one_coeff(a[26], a[21], cospi_16_64, &b[26], &b[21]);
butterfly_one_coeff(a[25], a[22], cospi_16_64, &b[25], &b[22]);
butterfly_one_coeff(a[24], a[23], cospi_16_64, &b[24], &b[23]);
b[20] = add_round_shift_s16(b[20]);
b[21] = add_round_shift_s16(b[21]);
b[22] = add_round_shift_s16(b[22]);
b[23] = add_round_shift_s16(b[23]);
b[24] = add_round_shift_s16(b[24]);
b[25] = add_round_shift_s16(b[25]);
b[26] = add_round_shift_s16(b[26]);
b[27] = add_round_shift_s16(b[27]);
b[28] = add_round_shift_s16(a[28]);
b[29] = add_round_shift_s16(a[29]);
b[30] = add_round_shift_s16(a[30]);
b[31] = add_round_shift_s16(a[31]);
// Stage 3.
a[0] = vaddq_s16(b[0], b[7]);
a[1] = vaddq_s16(b[1], b[6]);
a[2] = vaddq_s16(b[2], b[5]);
a[3] = vaddq_s16(b[3], b[4]);
a[4] = vsubq_s16(b[3], b[4]);
a[5] = vsubq_s16(b[2], b[5]);
a[6] = vsubq_s16(b[1], b[6]);
a[7] = vsubq_s16(b[0], b[7]);
a[8] = b[8];
a[9] = b[9];
butterfly_one_coeff(b[13], b[10], cospi_16_64, &a[13], &a[10]);
butterfly_one_coeff(b[12], b[11], cospi_16_64, &a[12], &a[11]);
a[14] = b[14];
a[15] = b[15];
a[16] = vaddq_s16(b[16], b[23]);
a[17] = vaddq_s16(b[17], b[22]);
a[18] = vaddq_s16(b[18], b[21]);
a[19] = vaddq_s16(b[19], b[20]);
a[20] = vsubq_s16(b[19], b[20]);
a[21] = vsubq_s16(b[18], b[21]);
a[22] = vsubq_s16(b[17], b[22]);
a[23] = vsubq_s16(b[16], b[23]);
a[24] = vsubq_s16(b[31], b[24]);
a[25] = vsubq_s16(b[30], b[25]);
a[26] = vsubq_s16(b[29], b[26]);
a[27] = vsubq_s16(b[28], b[27]);
a[28] = vaddq_s16(b[28], b[27]);
a[29] = vaddq_s16(b[29], b[26]);
a[30] = vaddq_s16(b[30], b[25]);
a[31] = vaddq_s16(b[31], b[24]);
// Stage 4.
b[0] = vaddq_s16(a[0], a[3]);
b[1] = vaddq_s16(a[1], a[2]);
b[2] = vsubq_s16(a[1], a[2]);
b[3] = vsubq_s16(a[0], a[3]);
b[4] = a[4];
butterfly_one_coeff(a[6], a[5], cospi_16_64, &b[6], &b[5]);
b[7] = a[7];
b[8] = vaddq_s16(a[8], a[11]);
b[9] = vaddq_s16(a[9], a[10]);
b[10] = vsubq_s16(a[9], a[10]);
b[11] = vsubq_s16(a[8], a[11]);
b[12] = vsubq_s16(a[15], a[12]);
b[13] = vsubq_s16(a[14], a[13]);
b[14] = vaddq_s16(a[14], a[13]);
b[15] = vaddq_s16(a[15], a[12]);
b[16] = a[16];
b[17] = a[17];
butterfly_two_coeff(a[29], a[18], cospi_24_64, cospi_8_64, &b[29], &b[18]);
butterfly_two_coeff(a[28], a[19], cospi_24_64, cospi_8_64, &b[28], &b[19]);
butterfly_two_coeff(a[27], a[20], -cospi_8_64, cospi_24_64, &b[27], &b[20]);
butterfly_two_coeff(a[26], a[21], -cospi_8_64, cospi_24_64, &b[26], &b[21]);
b[22] = a[22];
b[23] = a[23];
b[24] = a[24];
b[25] = a[25];
b[30] = a[30];
b[31] = a[31];
// Stage 5.
butterfly_one_coeff(b[0], b[1], cospi_16_64, &a[0], &a[1]);
butterfly_two_coeff(b[3], b[2], cospi_24_64, cospi_8_64, &a[2], &a[3]);
a[4] = vaddq_s16(b[4], b[5]);
a[5] = vsubq_s16(b[4], b[5]);
a[6] = vsubq_s16(b[7], b[6]);
a[7] = vaddq_s16(b[7], b[6]);
a[8] = b[8];
butterfly_two_coeff(b[14], b[9], cospi_24_64, cospi_8_64, &a[14], &a[9]);
butterfly_two_coeff(b[13], b[10], -cospi_8_64, cospi_24_64, &a[13], &a[10]);
a[11] = b[11];
a[12] = b[12];
a[15] = b[15];
a[16] = vaddq_s16(b[19], b[16]);
a[17] = vaddq_s16(b[18], b[17]);
a[18] = vsubq_s16(b[17], b[18]);
a[19] = vsubq_s16(b[16], b[19]);
a[20] = vsubq_s16(b[23], b[20]);
a[21] = vsubq_s16(b[22], b[21]);
a[22] = vaddq_s16(b[21], b[22]);
a[23] = vaddq_s16(b[20], b[23]);
a[24] = vaddq_s16(b[27], b[24]);
a[25] = vaddq_s16(b[26], b[25]);
a[26] = vsubq_s16(b[25], b[26]);
a[27] = vsubq_s16(b[24], b[27]);
a[28] = vsubq_s16(b[31], b[28]);
a[29] = vsubq_s16(b[30], b[29]);
a[30] = vaddq_s16(b[29], b[30]);
a[31] = vaddq_s16(b[28], b[31]);
// Stage 6.
b[0] = a[0];
b[1] = a[1];
b[2] = a[2];
b[3] = a[3];
butterfly_two_coeff(a[7], a[4], cospi_28_64, cospi_4_64, &b[4], &b[7]);
butterfly_two_coeff(a[6], a[5], cospi_12_64, cospi_20_64, &b[5], &b[6]);
b[8] = vaddq_s16(a[8], a[9]);
b[9] = vsubq_s16(a[8], a[9]);
b[10] = vsubq_s16(a[11], a[10]);
b[11] = vaddq_s16(a[11], a[10]);
b[12] = vaddq_s16(a[12], a[13]);
b[13] = vsubq_s16(a[12], a[13]);
b[14] = vsubq_s16(a[15], a[14]);
b[15] = vaddq_s16(a[15], a[14]);
b[16] = a[16];
b[19] = a[19];
b[20] = a[20];
b[23] = a[23];
b[24] = a[24];
b[27] = a[27];
b[28] = a[28];
b[31] = a[31];
butterfly_two_coeff(a[30], a[17], cospi_28_64, cospi_4_64, &b[30], &b[17]);
butterfly_two_coeff(a[29], a[18], -cospi_4_64, cospi_28_64, &b[29], &b[18]);
butterfly_two_coeff(a[26], a[21], cospi_12_64, cospi_20_64, &b[26], &b[21]);
butterfly_two_coeff(a[25], a[22], -cospi_20_64, cospi_12_64, &b[25], &b[22]);
// Stage 7.
a[0] = b[0];
a[1] = b[1];
a[2] = b[2];
a[3] = b[3];
a[4] = b[4];
a[5] = b[5];
a[6] = b[6];
a[7] = b[7];
butterfly_two_coeff(b[15], b[8], cospi_30_64, cospi_2_64, &a[8], &a[15]);
butterfly_two_coeff(b[14], b[9], cospi_14_64, cospi_18_64, &a[9], &a[14]);
butterfly_two_coeff(b[13], b[10], cospi_22_64, cospi_10_64, &a[10], &a[13]);
butterfly_two_coeff(b[12], b[11], cospi_6_64, cospi_26_64, &a[11], &a[12]);
a[16] = vaddq_s16(b[16], b[17]);
a[17] = vsubq_s16(b[16], b[17]);
a[18] = vsubq_s16(b[19], b[18]);
a[19] = vaddq_s16(b[19], b[18]);
a[20] = vaddq_s16(b[20], b[21]);
a[21] = vsubq_s16(b[20], b[21]);
a[22] = vsubq_s16(b[23], b[22]);
a[23] = vaddq_s16(b[23], b[22]);
a[24] = vaddq_s16(b[24], b[25]);
a[25] = vsubq_s16(b[24], b[25]);
a[26] = vsubq_s16(b[27], b[26]);
a[27] = vaddq_s16(b[27], b[26]);
a[28] = vaddq_s16(b[28], b[29]);
a[29] = vsubq_s16(b[28], b[29]);
a[30] = vsubq_s16(b[31], b[30]);
a[31] = vaddq_s16(b[31], b[30]);
// Final stage.
out[0] = a[0];
out[16] = a[1];
out[8] = a[2];
out[24] = a[3];
out[4] = a[4];
out[20] = a[5];
out[12] = a[6];
out[28] = a[7];
out[2] = a[8];
out[18] = a[9];
out[10] = a[10];
out[26] = a[11];
out[6] = a[12];
out[22] = a[13];
out[14] = a[14];
out[30] = a[15];
butterfly_two_coeff(a[31], a[16], cospi_31_64, cospi_1_64, &out[1], &out[31]);
butterfly_two_coeff(a[30], a[17], cospi_15_64, cospi_17_64, &out[17],
&out[15]);
butterfly_two_coeff(a[29], a[18], cospi_23_64, cospi_9_64, &out[9], &out[23]);
butterfly_two_coeff(a[28], a[19], cospi_7_64, cospi_25_64, &out[25], &out[7]);
butterfly_two_coeff(a[27], a[20], cospi_27_64, cospi_5_64, &out[5], &out[27]);
butterfly_two_coeff(a[26], a[21], cospi_11_64, cospi_21_64, &out[21],
&out[11]);
butterfly_two_coeff(a[25], a[22], cospi_19_64, cospi_13_64, &out[13],
&out[19]);
butterfly_two_coeff(a[24], a[23], cospi_3_64, cospi_29_64, &out[29], &out[3]);
}
#undef PASS_THROUGH
#undef ADD_S16_S32
#undef SUB_S16_S32
#undef ADDW_S16_S32
#undef SUBW_S16_S32
#undef ADD_S32
#undef SUB_S32
#undef BUTTERFLY_ONE_S16_S32
#undef BUTTERFLY_ONE_S32
#undef BUTTERFLY_TWO_S32
// Transpose 8x8 to a new location. Don't use transpose_neon.h because those
// are all in-place.
// TODO(johannkoenig): share with other fdcts.
static INLINE void transpose_8x8(const int16x8_t *a, int16x8_t *b) {
// Swap 16 bit elements.
const int16x8x2_t c0 = vtrnq_s16(a[0], a[1]);
const int16x8x2_t c1 = vtrnq_s16(a[2], a[3]);
const int16x8x2_t c2 = vtrnq_s16(a[4], a[5]);
const int16x8x2_t c3 = vtrnq_s16(a[6], a[7]);
// Swap 32 bit elements.
const int32x4x2_t d0 = vtrnq_s32(vreinterpretq_s32_s16(c0.val[0]),
vreinterpretq_s32_s16(c1.val[0]));
const int32x4x2_t d1 = vtrnq_s32(vreinterpretq_s32_s16(c0.val[1]),
vreinterpretq_s32_s16(c1.val[1]));
const int32x4x2_t d2 = vtrnq_s32(vreinterpretq_s32_s16(c2.val[0]),
vreinterpretq_s32_s16(c3.val[0]));
const int32x4x2_t d3 = vtrnq_s32(vreinterpretq_s32_s16(c2.val[1]),
vreinterpretq_s32_s16(c3.val[1]));
// Swap 64 bit elements
const int16x8x2_t e0 = vpx_vtrnq_s64_to_s16(d0.val[0], d2.val[0]);
const int16x8x2_t e1 = vpx_vtrnq_s64_to_s16(d1.val[0], d3.val[0]);
const int16x8x2_t e2 = vpx_vtrnq_s64_to_s16(d0.val[1], d2.val[1]);
const int16x8x2_t e3 = vpx_vtrnq_s64_to_s16(d1.val[1], d3.val[1]);
b[0] = e0.val[0];
b[1] = e1.val[0];
b[2] = e2.val[0];
b[3] = e3.val[0];
b[4] = e0.val[1];
b[5] = e1.val[1];
b[6] = e2.val[1];
b[7] = e3.val[1];
}
void vpx_fdct32x32_neon(const int16_t *input, tran_low_t *output, int stride) {
int16x8_t temp0[32];
int16x8_t temp1[32];
int16x8_t temp2[32];
int16x8_t temp3[32];
int16x8_t temp4[32];
int16x8_t temp5[32];
// Process in 8x32 columns.
load(input, stride, temp0);
dct_body_first_pass(temp0, temp1);
load(input + 8, stride, temp0);
dct_body_first_pass(temp0, temp2);
load(input + 16, stride, temp0);
dct_body_first_pass(temp0, temp3);
load(input + 24, stride, temp0);
dct_body_first_pass(temp0, temp4);
// Generate the top row by munging the first set of 8 from each one together.
transpose_8x8(&temp1[0], &temp0[0]);
transpose_8x8(&temp2[0], &temp0[8]);
transpose_8x8(&temp3[0], &temp0[16]);
transpose_8x8(&temp4[0], &temp0[24]);
dct_body_second_pass(temp0, temp5);
transpose_s16_8x8(&temp5[0], &temp5[1], &temp5[2], &temp5[3], &temp5[4],
&temp5[5], &temp5[6], &temp5[7]);
transpose_s16_8x8(&temp5[8], &temp5[9], &temp5[10], &temp5[11], &temp5[12],
&temp5[13], &temp5[14], &temp5[15]);
transpose_s16_8x8(&temp5[16], &temp5[17], &temp5[18], &temp5[19], &temp5[20],
&temp5[21], &temp5[22], &temp5[23]);
transpose_s16_8x8(&temp5[24], &temp5[25], &temp5[26], &temp5[27], &temp5[28],
&temp5[29], &temp5[30], &temp5[31]);
store(output, temp5);
// Second row of 8x32.
transpose_8x8(&temp1[8], &temp0[0]);
transpose_8x8(&temp2[8], &temp0[8]);
transpose_8x8(&temp3[8], &temp0[16]);
transpose_8x8(&temp4[8], &temp0[24]);
dct_body_second_pass(temp0, temp5);
transpose_s16_8x8(&temp5[0], &temp5[1], &temp5[2], &temp5[3], &temp5[4],
&temp5[5], &temp5[6], &temp5[7]);
transpose_s16_8x8(&temp5[8], &temp5[9], &temp5[10], &temp5[11], &temp5[12],
&temp5[13], &temp5[14], &temp5[15]);
transpose_s16_8x8(&temp5[16], &temp5[17], &temp5[18], &temp5[19], &temp5[20],
&temp5[21], &temp5[22], &temp5[23]);
transpose_s16_8x8(&temp5[24], &temp5[25], &temp5[26], &temp5[27], &temp5[28],
&temp5[29], &temp5[30], &temp5[31]);
store(output + 8 * 32, temp5);
// Third row of 8x32
transpose_8x8(&temp1[16], &temp0[0]);
transpose_8x8(&temp2[16], &temp0[8]);
transpose_8x8(&temp3[16], &temp0[16]);
transpose_8x8(&temp4[16], &temp0[24]);
dct_body_second_pass(temp0, temp5);
transpose_s16_8x8(&temp5[0], &temp5[1], &temp5[2], &temp5[3], &temp5[4],
&temp5[5], &temp5[6], &temp5[7]);
transpose_s16_8x8(&temp5[8], &temp5[9], &temp5[10], &temp5[11], &temp5[12],
&temp5[13], &temp5[14], &temp5[15]);
transpose_s16_8x8(&temp5[16], &temp5[17], &temp5[18], &temp5[19], &temp5[20],
&temp5[21], &temp5[22], &temp5[23]);
transpose_s16_8x8(&temp5[24], &temp5[25], &temp5[26], &temp5[27], &temp5[28],
&temp5[29], &temp5[30], &temp5[31]);
store(output + 16 * 32, temp5);
// Final row of 8x32.
transpose_8x8(&temp1[24], &temp0[0]);
transpose_8x8(&temp2[24], &temp0[8]);
transpose_8x8(&temp3[24], &temp0[16]);
transpose_8x8(&temp4[24], &temp0[24]);
dct_body_second_pass(temp0, temp5);
transpose_s16_8x8(&temp5[0], &temp5[1], &temp5[2], &temp5[3], &temp5[4],
&temp5[5], &temp5[6], &temp5[7]);
transpose_s16_8x8(&temp5[8], &temp5[9], &temp5[10], &temp5[11], &temp5[12],
&temp5[13], &temp5[14], &temp5[15]);
transpose_s16_8x8(&temp5[16], &temp5[17], &temp5[18], &temp5[19], &temp5[20],
&temp5[21], &temp5[22], &temp5[23]);
transpose_s16_8x8(&temp5[24], &temp5[25], &temp5[26], &temp5[27], &temp5[28],
&temp5[29], &temp5[30], &temp5[31]);
store(output + 24 * 32, temp5);
}
void vpx_fdct32x32_rd_neon(const int16_t *input, tran_low_t *output,
int stride) {
int16x8_t temp0[32];
int16x8_t temp1[32];
int16x8_t temp2[32];
int16x8_t temp3[32];
int16x8_t temp4[32];
int16x8_t temp5[32];
// Process in 8x32 columns.
load(input, stride, temp0);
dct_body_first_pass(temp0, temp1);
load(input + 8, stride, temp0);
dct_body_first_pass(temp0, temp2);
load(input + 16, stride, temp0);
dct_body_first_pass(temp0, temp3);
load(input + 24, stride, temp0);
dct_body_first_pass(temp0, temp4);
// Generate the top row by munging the first set of 8 from each one together.
transpose_8x8(&temp1[0], &temp0[0]);
transpose_8x8(&temp2[0], &temp0[8]);
transpose_8x8(&temp3[0], &temp0[16]);
transpose_8x8(&temp4[0], &temp0[24]);
dct_body_second_pass_rd(temp0, temp5);
transpose_s16_8x8(&temp5[0], &temp5[1], &temp5[2], &temp5[3], &temp5[4],
&temp5[5], &temp5[6], &temp5[7]);
transpose_s16_8x8(&temp5[8], &temp5[9], &temp5[10], &temp5[11], &temp5[12],
&temp5[13], &temp5[14], &temp5[15]);
transpose_s16_8x8(&temp5[16], &temp5[17], &temp5[18], &temp5[19], &temp5[20],
&temp5[21], &temp5[22], &temp5[23]);
transpose_s16_8x8(&temp5[24], &temp5[25], &temp5[26], &temp5[27], &temp5[28],
&temp5[29], &temp5[30], &temp5[31]);
store(output, temp5);
// Second row of 8x32.
transpose_8x8(&temp1[8], &temp0[0]);
transpose_8x8(&temp2[8], &temp0[8]);
transpose_8x8(&temp3[8], &temp0[16]);
transpose_8x8(&temp4[8], &temp0[24]);
dct_body_second_pass_rd(temp0, temp5);
transpose_s16_8x8(&temp5[0], &temp5[1], &temp5[2], &temp5[3], &temp5[4],
&temp5[5], &temp5[6], &temp5[7]);
transpose_s16_8x8(&temp5[8], &temp5[9], &temp5[10], &temp5[11], &temp5[12],
&temp5[13], &temp5[14], &temp5[15]);
transpose_s16_8x8(&temp5[16], &temp5[17], &temp5[18], &temp5[19], &temp5[20],
&temp5[21], &temp5[22], &temp5[23]);
transpose_s16_8x8(&temp5[24], &temp5[25], &temp5[26], &temp5[27], &temp5[28],
&temp5[29], &temp5[30], &temp5[31]);
store(output + 8 * 32, temp5);
// Third row of 8x32
transpose_8x8(&temp1[16], &temp0[0]);
transpose_8x8(&temp2[16], &temp0[8]);
transpose_8x8(&temp3[16], &temp0[16]);
transpose_8x8(&temp4[16], &temp0[24]);
dct_body_second_pass_rd(temp0, temp5);
transpose_s16_8x8(&temp5[0], &temp5[1], &temp5[2], &temp5[3], &temp5[4],
&temp5[5], &temp5[6], &temp5[7]);
transpose_s16_8x8(&temp5[8], &temp5[9], &temp5[10], &temp5[11], &temp5[12],
&temp5[13], &temp5[14], &temp5[15]);
transpose_s16_8x8(&temp5[16], &temp5[17], &temp5[18], &temp5[19], &temp5[20],
&temp5[21], &temp5[22], &temp5[23]);
transpose_s16_8x8(&temp5[24], &temp5[25], &temp5[26], &temp5[27], &temp5[28],
&temp5[29], &temp5[30], &temp5[31]);
store(output + 16 * 32, temp5);
// Final row of 8x32.
transpose_8x8(&temp1[24], &temp0[0]);
transpose_8x8(&temp2[24], &temp0[8]);
transpose_8x8(&temp3[24], &temp0[16]);
transpose_8x8(&temp4[24], &temp0[24]);
dct_body_second_pass_rd(temp0, temp5);
transpose_s16_8x8(&temp5[0], &temp5[1], &temp5[2], &temp5[3], &temp5[4],
&temp5[5], &temp5[6], &temp5[7]);
transpose_s16_8x8(&temp5[8], &temp5[9], &temp5[10], &temp5[11], &temp5[12],
&temp5[13], &temp5[14], &temp5[15]);
transpose_s16_8x8(&temp5[16], &temp5[17], &temp5[18], &temp5[19], &temp5[20],
&temp5[21], &temp5[22], &temp5[23]);
transpose_s16_8x8(&temp5[24], &temp5[25], &temp5[26], &temp5[27], &temp5[28],
&temp5[29], &temp5[30], &temp5[31]);
store(output + 24 * 32, temp5);
}
#endif // !defined(__clang__) && !defined(__ANDROID__) && defined(__GNUC__) &&
// __GNUC__ == 4 && __GNUC_MINOR__ <= 9