64653fa133
The unnecessary upcast to (int) will be cleaned later. BUG=webm:1450 Change-Id: Ia234575206d5a74540526924b06ed3939322d063
388 lines
15 KiB
C
388 lines
15 KiB
C
/*
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* Copyright (c) 2017 The WebM project authors. All Rights Reserved.
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*
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* Use of this source code is governed by a BSD-style license
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* that can be found in the LICENSE file in the root of the source
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* tree. An additional intellectual property rights grant can be found
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* in the file PATENTS. All contributing project authors may
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* be found in the AUTHORS file in the root of the source tree.
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*/
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#include <arm_neon.h>
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#include "./vpx_config.h"
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#include "./vpx_dsp_rtcd.h"
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#include "vpx_dsp/txfm_common.h"
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#include "vpx_dsp/arm/mem_neon.h"
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#include "vpx_dsp/arm/transpose_neon.h"
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// Some builds of gcc 4.9.2 and .3 have trouble with some of the inline
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// functions.
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#if !defined(__clang__) && !defined(__ANDROID__) && defined(__GNUC__) && \
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__GNUC__ == 4 && __GNUC_MINOR__ == 9 && __GNUC_PATCHLEVEL__ < 4
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void vpx_fdct16x16_neon(const int16_t *input, tran_low_t *output, int stride) {
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vpx_fdct16x16_c(input, output, stride);
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}
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#else
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static INLINE void load(const int16_t *a, int stride, int16x8_t *b /*[16]*/) {
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b[0] = vld1q_s16(a);
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a += stride;
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b[1] = vld1q_s16(a);
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a += stride;
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b[2] = vld1q_s16(a);
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a += stride;
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b[3] = vld1q_s16(a);
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a += stride;
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b[4] = vld1q_s16(a);
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a += stride;
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b[5] = vld1q_s16(a);
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a += stride;
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b[6] = vld1q_s16(a);
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a += stride;
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b[7] = vld1q_s16(a);
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a += stride;
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b[8] = vld1q_s16(a);
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a += stride;
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b[9] = vld1q_s16(a);
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a += stride;
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b[10] = vld1q_s16(a);
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a += stride;
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b[11] = vld1q_s16(a);
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a += stride;
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b[12] = vld1q_s16(a);
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a += stride;
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b[13] = vld1q_s16(a);
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a += stride;
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b[14] = vld1q_s16(a);
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a += stride;
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b[15] = vld1q_s16(a);
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}
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// Store 8 16x8 values, assuming stride == 16.
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static INLINE void store(tran_low_t *a, const int16x8_t *b /*[8]*/) {
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store_s16q_to_tran_low(a, b[0]);
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a += 16;
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store_s16q_to_tran_low(a, b[1]);
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a += 16;
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store_s16q_to_tran_low(a, b[2]);
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a += 16;
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store_s16q_to_tran_low(a, b[3]);
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a += 16;
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store_s16q_to_tran_low(a, b[4]);
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a += 16;
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store_s16q_to_tran_low(a, b[5]);
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a += 16;
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store_s16q_to_tran_low(a, b[6]);
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a += 16;
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store_s16q_to_tran_low(a, b[7]);
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}
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// Load step of each pass. Add and subtract clear across the input, requiring
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// all 16 values to be loaded. For the first pass it also multiplies by 4.
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// To maybe reduce register usage this could be combined with the load() step to
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// get the first 4 and last 4 values, cross those, then load the middle 8 values
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// and cross them.
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static INLINE void cross_input(const int16x8_t *a /*[16]*/,
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int16x8_t *b /*[16]*/, const int pass) {
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if (pass == 0) {
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b[0] = vshlq_n_s16(vaddq_s16(a[0], a[15]), 2);
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b[1] = vshlq_n_s16(vaddq_s16(a[1], a[14]), 2);
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b[2] = vshlq_n_s16(vaddq_s16(a[2], a[13]), 2);
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b[3] = vshlq_n_s16(vaddq_s16(a[3], a[12]), 2);
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b[4] = vshlq_n_s16(vaddq_s16(a[4], a[11]), 2);
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b[5] = vshlq_n_s16(vaddq_s16(a[5], a[10]), 2);
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b[6] = vshlq_n_s16(vaddq_s16(a[6], a[9]), 2);
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b[7] = vshlq_n_s16(vaddq_s16(a[7], a[8]), 2);
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b[8] = vshlq_n_s16(vsubq_s16(a[7], a[8]), 2);
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b[9] = vshlq_n_s16(vsubq_s16(a[6], a[9]), 2);
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b[10] = vshlq_n_s16(vsubq_s16(a[5], a[10]), 2);
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b[11] = vshlq_n_s16(vsubq_s16(a[4], a[11]), 2);
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b[12] = vshlq_n_s16(vsubq_s16(a[3], a[12]), 2);
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b[13] = vshlq_n_s16(vsubq_s16(a[2], a[13]), 2);
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b[14] = vshlq_n_s16(vsubq_s16(a[1], a[14]), 2);
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b[15] = vshlq_n_s16(vsubq_s16(a[0], a[15]), 2);
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} else {
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b[0] = vaddq_s16(a[0], a[15]);
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b[1] = vaddq_s16(a[1], a[14]);
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b[2] = vaddq_s16(a[2], a[13]);
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b[3] = vaddq_s16(a[3], a[12]);
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b[4] = vaddq_s16(a[4], a[11]);
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b[5] = vaddq_s16(a[5], a[10]);
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b[6] = vaddq_s16(a[6], a[9]);
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b[7] = vaddq_s16(a[7], a[8]);
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b[8] = vsubq_s16(a[7], a[8]);
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b[9] = vsubq_s16(a[6], a[9]);
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b[10] = vsubq_s16(a[5], a[10]);
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b[11] = vsubq_s16(a[4], a[11]);
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b[12] = vsubq_s16(a[3], a[12]);
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b[13] = vsubq_s16(a[2], a[13]);
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b[14] = vsubq_s16(a[1], a[14]);
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b[15] = vsubq_s16(a[0], a[15]);
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}
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}
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// Quarter round at the beginning of the second pass. Can't use vrshr (rounding)
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// because this only adds 1, not 1 << 2.
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static INLINE void partial_round_shift(int16x8_t *a /*[16]*/) {
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const int16x8_t one = vdupq_n_s16(1);
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a[0] = vshrq_n_s16(vaddq_s16(a[0], one), 2);
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a[1] = vshrq_n_s16(vaddq_s16(a[1], one), 2);
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a[2] = vshrq_n_s16(vaddq_s16(a[2], one), 2);
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a[3] = vshrq_n_s16(vaddq_s16(a[3], one), 2);
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a[4] = vshrq_n_s16(vaddq_s16(a[4], one), 2);
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a[5] = vshrq_n_s16(vaddq_s16(a[5], one), 2);
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a[6] = vshrq_n_s16(vaddq_s16(a[6], one), 2);
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a[7] = vshrq_n_s16(vaddq_s16(a[7], one), 2);
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a[8] = vshrq_n_s16(vaddq_s16(a[8], one), 2);
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a[9] = vshrq_n_s16(vaddq_s16(a[9], one), 2);
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a[10] = vshrq_n_s16(vaddq_s16(a[10], one), 2);
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a[11] = vshrq_n_s16(vaddq_s16(a[11], one), 2);
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a[12] = vshrq_n_s16(vaddq_s16(a[12], one), 2);
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a[13] = vshrq_n_s16(vaddq_s16(a[13], one), 2);
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a[14] = vshrq_n_s16(vaddq_s16(a[14], one), 2);
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a[15] = vshrq_n_s16(vaddq_s16(a[15], one), 2);
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}
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// fdct_round_shift((a +/- b) * c)
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static INLINE void butterfly_one_coeff(const int16x8_t a, const int16x8_t b,
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const tran_high_t c, int16x8_t *add,
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int16x8_t *sub) {
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const int32x4_t a0 = vmull_n_s16(vget_low_s16(a), c);
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const int32x4_t a1 = vmull_n_s16(vget_high_s16(a), c);
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const int32x4_t sum0 = vmlal_n_s16(a0, vget_low_s16(b), c);
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const int32x4_t sum1 = vmlal_n_s16(a1, vget_high_s16(b), c);
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const int32x4_t diff0 = vmlsl_n_s16(a0, vget_low_s16(b), c);
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const int32x4_t diff1 = vmlsl_n_s16(a1, vget_high_s16(b), c);
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const int16x4_t rounded0 = vqrshrn_n_s32(sum0, 14);
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const int16x4_t rounded1 = vqrshrn_n_s32(sum1, 14);
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const int16x4_t rounded2 = vqrshrn_n_s32(diff0, 14);
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const int16x4_t rounded3 = vqrshrn_n_s32(diff1, 14);
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*add = vcombine_s16(rounded0, rounded1);
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*sub = vcombine_s16(rounded2, rounded3);
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}
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// fdct_round_shift(a * c0 +/- b * c1)
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static INLINE void butterfly_two_coeff(const int16x8_t a, const int16x8_t b,
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const tran_coef_t c0,
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const tran_coef_t c1, int16x8_t *add,
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int16x8_t *sub) {
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const int32x4_t a0 = vmull_n_s16(vget_low_s16(a), c0);
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const int32x4_t a1 = vmull_n_s16(vget_high_s16(a), c0);
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const int32x4_t a2 = vmull_n_s16(vget_low_s16(a), c1);
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const int32x4_t a3 = vmull_n_s16(vget_high_s16(a), c1);
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const int32x4_t sum0 = vmlal_n_s16(a2, vget_low_s16(b), c0);
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const int32x4_t sum1 = vmlal_n_s16(a3, vget_high_s16(b), c0);
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const int32x4_t diff0 = vmlsl_n_s16(a0, vget_low_s16(b), c1);
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const int32x4_t diff1 = vmlsl_n_s16(a1, vget_high_s16(b), c1);
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const int16x4_t rounded0 = vqrshrn_n_s32(sum0, 14);
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const int16x4_t rounded1 = vqrshrn_n_s32(sum1, 14);
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const int16x4_t rounded2 = vqrshrn_n_s32(diff0, 14);
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const int16x4_t rounded3 = vqrshrn_n_s32(diff1, 14);
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*add = vcombine_s16(rounded0, rounded1);
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*sub = vcombine_s16(rounded2, rounded3);
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}
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// Transpose 8x8 to a new location. Don't use transpose_neon.h because those
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// are all in-place.
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static INLINE void transpose_8x8(const int16x8_t *a /*[8]*/,
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int16x8_t *b /*[8]*/) {
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// Swap 16 bit elements.
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const int16x8x2_t c0 = vtrnq_s16(a[0], a[1]);
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const int16x8x2_t c1 = vtrnq_s16(a[2], a[3]);
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const int16x8x2_t c2 = vtrnq_s16(a[4], a[5]);
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const int16x8x2_t c3 = vtrnq_s16(a[6], a[7]);
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// Swap 32 bit elements.
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const int32x4x2_t d0 = vtrnq_s32(vreinterpretq_s32_s16(c0.val[0]),
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vreinterpretq_s32_s16(c1.val[0]));
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const int32x4x2_t d1 = vtrnq_s32(vreinterpretq_s32_s16(c0.val[1]),
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vreinterpretq_s32_s16(c1.val[1]));
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const int32x4x2_t d2 = vtrnq_s32(vreinterpretq_s32_s16(c2.val[0]),
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vreinterpretq_s32_s16(c3.val[0]));
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const int32x4x2_t d3 = vtrnq_s32(vreinterpretq_s32_s16(c2.val[1]),
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vreinterpretq_s32_s16(c3.val[1]));
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// Swap 64 bit elements
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const int16x8x2_t e0 = vpx_vtrnq_s64_to_s16(d0.val[0], d2.val[0]);
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const int16x8x2_t e1 = vpx_vtrnq_s64_to_s16(d1.val[0], d3.val[0]);
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const int16x8x2_t e2 = vpx_vtrnq_s64_to_s16(d0.val[1], d2.val[1]);
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const int16x8x2_t e3 = vpx_vtrnq_s64_to_s16(d1.val[1], d3.val[1]);
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b[0] = e0.val[0];
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b[1] = e1.val[0];
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b[2] = e2.val[0];
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b[3] = e3.val[0];
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b[4] = e0.val[1];
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b[5] = e1.val[1];
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b[6] = e2.val[1];
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b[7] = e3.val[1];
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}
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// Main body of fdct16x16.
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static void dct_body(const int16x8_t *in /*[16]*/, int16x8_t *out /*[16]*/) {
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int16x8_t s[8];
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int16x8_t x[4];
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int16x8_t step[8];
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// stage 1
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// From fwd_txfm.c: Work on the first eight values; fdct8(input,
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// even_results);"
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s[0] = vaddq_s16(in[0], in[7]);
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s[1] = vaddq_s16(in[1], in[6]);
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s[2] = vaddq_s16(in[2], in[5]);
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s[3] = vaddq_s16(in[3], in[4]);
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s[4] = vsubq_s16(in[3], in[4]);
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s[5] = vsubq_s16(in[2], in[5]);
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s[6] = vsubq_s16(in[1], in[6]);
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s[7] = vsubq_s16(in[0], in[7]);
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// fdct4(step, step);
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x[0] = vaddq_s16(s[0], s[3]);
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x[1] = vaddq_s16(s[1], s[2]);
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x[2] = vsubq_s16(s[1], s[2]);
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x[3] = vsubq_s16(s[0], s[3]);
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// out[0] = fdct_round_shift((x0 + x1) * cospi_16_64)
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// out[8] = fdct_round_shift((x0 - x1) * cospi_16_64)
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butterfly_one_coeff(x[0], x[1], cospi_16_64, &out[0], &out[8]);
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// out[4] = fdct_round_shift(x3 * cospi_8_64 + x2 * cospi_24_64);
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// out[12] = fdct_round_shift(x3 * cospi_24_64 - x2 * cospi_8_64);
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butterfly_two_coeff(x[3], x[2], cospi_24_64, cospi_8_64, &out[4], &out[12]);
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// Stage 2
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// Re-using source s5/s6
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// s5 = fdct_round_shift((s6 - s5) * cospi_16_64)
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// s6 = fdct_round_shift((s6 + s5) * cospi_16_64)
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butterfly_one_coeff(s[6], s[5], cospi_16_64, &s[6], &s[5]);
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// Stage 3
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x[0] = vaddq_s16(s[4], s[5]);
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x[1] = vsubq_s16(s[4], s[5]);
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x[2] = vsubq_s16(s[7], s[6]);
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x[3] = vaddq_s16(s[7], s[6]);
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// Stage 4
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// out[2] = fdct_round_shift(x0 * cospi_28_64 + x3 * cospi_4_64)
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// out[14] = fdct_round_shift(x3 * cospi_28_64 + x0 * -cospi_4_64)
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butterfly_two_coeff(x[3], x[0], cospi_28_64, cospi_4_64, &out[2], &out[14]);
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// out[6] = fdct_round_shift(x1 * cospi_12_64 + x2 * cospi_20_64)
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// out[10] = fdct_round_shift(x2 * cospi_12_64 + x1 * -cospi_20_64)
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butterfly_two_coeff(x[2], x[1], cospi_12_64, cospi_20_64, &out[10], &out[6]);
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// step 2
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// From fwd_txfm.c: Work on the next eight values; step1 -> odd_results"
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// That file distinguished between "in_high" and "step1" but the only
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// difference is that "in_high" is the first 8 values and "step 1" is the
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// second. Here, since they are all in one array, "step1" values are += 8.
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// step2[2] = fdct_round_shift((step1[5] - step1[2]) * cospi_16_64)
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// step2[3] = fdct_round_shift((step1[4] - step1[3]) * cospi_16_64)
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// step2[4] = fdct_round_shift((step1[4] + step1[3]) * cospi_16_64)
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// step2[5] = fdct_round_shift((step1[5] + step1[2]) * cospi_16_64)
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butterfly_one_coeff(in[13], in[10], cospi_16_64, &s[5], &s[2]);
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butterfly_one_coeff(in[12], in[11], cospi_16_64, &s[4], &s[3]);
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// step 3
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s[0] = vaddq_s16(in[8], s[3]);
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s[1] = vaddq_s16(in[9], s[2]);
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x[0] = vsubq_s16(in[9], s[2]);
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x[1] = vsubq_s16(in[8], s[3]);
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x[2] = vsubq_s16(in[15], s[4]);
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x[3] = vsubq_s16(in[14], s[5]);
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s[6] = vaddq_s16(in[14], s[5]);
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s[7] = vaddq_s16(in[15], s[4]);
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// step 4
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// step2[1] = fdct_round_shift(step3[1] *-cospi_8_64 + step3[6] * cospi_24_64)
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// step2[6] = fdct_round_shift(step3[1] * cospi_24_64 + step3[6] * cospi_8_64)
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butterfly_two_coeff(s[6], s[1], cospi_24_64, cospi_8_64, &s[6], &s[1]);
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// step2[2] = fdct_round_shift(step3[2] * cospi_24_64 + step3[5] * cospi_8_64)
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// step2[5] = fdct_round_shift(step3[2] * cospi_8_64 - step3[5] * cospi_24_64)
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butterfly_two_coeff(x[0], x[3], cospi_8_64, cospi_24_64, &s[2], &s[5]);
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// step 5
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step[0] = vaddq_s16(s[0], s[1]);
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step[1] = vsubq_s16(s[0], s[1]);
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step[2] = vaddq_s16(x[1], s[2]);
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step[3] = vsubq_s16(x[1], s[2]);
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step[4] = vsubq_s16(x[2], s[5]);
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step[5] = vaddq_s16(x[2], s[5]);
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step[6] = vsubq_s16(s[7], s[6]);
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step[7] = vaddq_s16(s[7], s[6]);
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// step 6
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// out[1] = fdct_round_shift(step1[0] * cospi_30_64 + step1[7] * cospi_2_64)
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// out[9] = fdct_round_shift(step1[1] * cospi_14_64 + step1[6] * cospi_18_64)
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// out[5] = fdct_round_shift(step1[2] * cospi_22_64 + step1[5] * cospi_10_64)
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// out[13] = fdct_round_shift(step1[3] * cospi_6_64 + step1[4] * cospi_26_64)
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// out[3] = fdct_round_shift(step1[3] * -cospi_26_64 + step1[4] * cospi_6_64)
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// out[11] = fdct_round_shift(step1[2] * -cospi_10_64 + step1[5] *
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// cospi_22_64)
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// out[7] = fdct_round_shift(step1[1] * -cospi_18_64 + step1[6] * cospi_14_64)
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// out[15] = fdct_round_shift(step1[0] * -cospi_2_64 + step1[7] * cospi_30_64)
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butterfly_two_coeff(step[6], step[1], cospi_14_64, cospi_18_64, &out[9],
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&out[7]);
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butterfly_two_coeff(step[7], step[0], cospi_30_64, cospi_2_64, &out[1],
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&out[15]);
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butterfly_two_coeff(step[4], step[3], cospi_6_64, cospi_26_64, &out[13],
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&out[3]);
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butterfly_two_coeff(step[5], step[2], cospi_22_64, cospi_10_64, &out[5],
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&out[11]);
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}
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void vpx_fdct16x16_neon(const int16_t *input, tran_low_t *output, int stride) {
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int16x8_t temp0[16];
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int16x8_t temp1[16];
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int16x8_t temp2[16];
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int16x8_t temp3[16];
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|
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// Left half.
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load(input, stride, temp0);
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cross_input(temp0, temp1, 0);
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dct_body(temp1, temp0);
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|
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// Right half.
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load(input + 8, stride, temp1);
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cross_input(temp1, temp2, 0);
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dct_body(temp2, temp1);
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|
|
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// Transpose top left and top right quarters into one contiguous location to
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// process to the top half.
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transpose_8x8(&temp0[0], &temp2[0]);
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transpose_8x8(&temp1[0], &temp2[8]);
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partial_round_shift(temp2);
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cross_input(temp2, temp3, 1);
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|
dct_body(temp3, temp2);
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transpose_s16_8x8(&temp2[0], &temp2[1], &temp2[2], &temp2[3], &temp2[4],
|
|
&temp2[5], &temp2[6], &temp2[7]);
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|
transpose_s16_8x8(&temp2[8], &temp2[9], &temp2[10], &temp2[11], &temp2[12],
|
|
&temp2[13], &temp2[14], &temp2[15]);
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|
store(output, temp2);
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|
store(output + 8, temp2 + 8);
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|
output += 8 * 16;
|
|
|
|
// Transpose bottom left and bottom right quarters into one contiguous
|
|
// location to process to the bottom half.
|
|
transpose_8x8(&temp0[8], &temp1[0]);
|
|
transpose_s16_8x8(&temp1[8], &temp1[9], &temp1[10], &temp1[11], &temp1[12],
|
|
&temp1[13], &temp1[14], &temp1[15]);
|
|
partial_round_shift(temp1);
|
|
cross_input(temp1, temp0, 1);
|
|
dct_body(temp0, temp1);
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|
transpose_s16_8x8(&temp1[0], &temp1[1], &temp1[2], &temp1[3], &temp1[4],
|
|
&temp1[5], &temp1[6], &temp1[7]);
|
|
transpose_s16_8x8(&temp1[8], &temp1[9], &temp1[10], &temp1[11], &temp1[12],
|
|
&temp1[13], &temp1[14], &temp1[15]);
|
|
store(output, temp1);
|
|
store(output + 8, temp1 + 8);
|
|
}
|
|
#endif // !defined(__clang__) && !defined(__ANDROID__) && defined(__GNUC__) &&
|
|
// __GNUC__ == 4 && __GNUC_MINOR__ == 9 && __GNUC_PATCHLEVEL__ < 4
|