ref: ccb06a9fb15b9c10099cef28ff1240eb9ffa9390
dir: /vpx_dsp/arm/highbd_idct32x32_1024_add_neon.c/
/* * 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/arm/idct_neon.h" #include "vpx_dsp/arm/transpose_neon.h" #include "vpx_dsp/txfm_common.h" static INLINE void load_from_transformed(const int32_t *const trans_buf, const int first, const int second, int32x4x2_t *const q0, int32x4x2_t *const q1) { q0->val[0] = vld1q_s32(trans_buf + first * 8); q0->val[1] = vld1q_s32(trans_buf + first * 8 + 4); q1->val[0] = vld1q_s32(trans_buf + second * 8); q1->val[1] = vld1q_s32(trans_buf + second * 8 + 4); } static INLINE void load_from_output(const int32_t *const out, const int first, const int second, int32x4x2_t *const q0, int32x4x2_t *const q1) { q0->val[0] = vld1q_s32(out + first * 32); q0->val[1] = vld1q_s32(out + first * 32 + 4); q1->val[0] = vld1q_s32(out + second * 32); q1->val[1] = vld1q_s32(out + second * 32 + 4); } static INLINE void store_in_output(int32_t *const out, const int first, const int second, const int32x4x2_t q0, const int32x4x2_t q1) { vst1q_s32(out + first * 32, q0.val[0]); vst1q_s32(out + first * 32 + 4, q0.val[1]); vst1q_s32(out + second * 32, q1.val[0]); vst1q_s32(out + second * 32 + 4, q1.val[1]); } static INLINE void highbd_store_combine_results( uint16_t *p1, uint16_t *p2, const int stride, const int32x4x2_t q0, const int32x4x2_t q1, const int32x4x2_t q2, const int32x4x2_t q3, const int16x8_t max) { int16x8_t o[4]; uint16x8_t d[4]; d[0] = vld1q_u16(p1); p1 += stride; d[1] = vld1q_u16(p1); d[3] = vld1q_u16(p2); p2 -= stride; d[2] = vld1q_u16(p2); o[0] = vcombine_s16(vrshrn_n_s32(q0.val[0], 6), vrshrn_n_s32(q0.val[1], 6)); o[1] = vcombine_s16(vrshrn_n_s32(q1.val[0], 6), vrshrn_n_s32(q1.val[1], 6)); o[2] = vcombine_s16(vrshrn_n_s32(q2.val[0], 6), vrshrn_n_s32(q2.val[1], 6)); o[3] = vcombine_s16(vrshrn_n_s32(q3.val[0], 6), vrshrn_n_s32(q3.val[1], 6)); o[0] = vqaddq_s16(o[0], vreinterpretq_s16_u16(d[0])); o[1] = vqaddq_s16(o[1], vreinterpretq_s16_u16(d[1])); o[2] = vqaddq_s16(o[2], vreinterpretq_s16_u16(d[2])); o[3] = vqaddq_s16(o[3], vreinterpretq_s16_u16(d[3])); o[0] = vminq_s16(o[0], max); o[1] = vminq_s16(o[1], max); o[2] = vminq_s16(o[2], max); o[3] = vminq_s16(o[3], max); d[0] = vqshluq_n_s16(o[0], 0); d[1] = vqshluq_n_s16(o[1], 0); d[2] = vqshluq_n_s16(o[2], 0); d[3] = vqshluq_n_s16(o[3], 0); vst1q_u16(p1, d[1]); p1 -= stride; vst1q_u16(p1, d[0]); vst1q_u16(p2, d[2]); p2 += stride; vst1q_u16(p2, d[3]); } static INLINE void do_butterfly(const int32x4x2_t qIn0, const int32x4x2_t qIn1, const int32_t first_const, const int32_t second_const, int32x4x2_t *const qOut0, int32x4x2_t *const qOut1) { int64x2x2_t q[4]; int32x2_t d[6]; // Note: using v{mul, mla, mls}l_n_s32 here slows down 35% with gcc 4.9. d[4] = vdup_n_s32(first_const); d[5] = vdup_n_s32(second_const); q[0].val[0] = vmull_s32(vget_low_s32(qIn0.val[0]), d[4]); q[0].val[1] = vmull_s32(vget_high_s32(qIn0.val[0]), d[4]); q[1].val[0] = vmull_s32(vget_low_s32(qIn0.val[1]), d[4]); q[1].val[1] = vmull_s32(vget_high_s32(qIn0.val[1]), d[4]); q[0].val[0] = vmlsl_s32(q[0].val[0], vget_low_s32(qIn1.val[0]), d[5]); q[0].val[1] = vmlsl_s32(q[0].val[1], vget_high_s32(qIn1.val[0]), d[5]); q[1].val[0] = vmlsl_s32(q[1].val[0], vget_low_s32(qIn1.val[1]), d[5]); q[1].val[1] = vmlsl_s32(q[1].val[1], vget_high_s32(qIn1.val[1]), d[5]); q[2].val[0] = vmull_s32(vget_low_s32(qIn0.val[0]), d[5]); q[2].val[1] = vmull_s32(vget_high_s32(qIn0.val[0]), d[5]); q[3].val[0] = vmull_s32(vget_low_s32(qIn0.val[1]), d[5]); q[3].val[1] = vmull_s32(vget_high_s32(qIn0.val[1]), d[5]); q[2].val[0] = vmlal_s32(q[2].val[0], vget_low_s32(qIn1.val[0]), d[4]); q[2].val[1] = vmlal_s32(q[2].val[1], vget_high_s32(qIn1.val[0]), d[4]); q[3].val[0] = vmlal_s32(q[3].val[0], vget_low_s32(qIn1.val[1]), d[4]); q[3].val[1] = vmlal_s32(q[3].val[1], vget_high_s32(qIn1.val[1]), d[4]); qOut0->val[0] = vcombine_s32(vrshrn_n_s64(q[0].val[0], DCT_CONST_BITS), vrshrn_n_s64(q[0].val[1], DCT_CONST_BITS)); qOut0->val[1] = vcombine_s32(vrshrn_n_s64(q[1].val[0], DCT_CONST_BITS), vrshrn_n_s64(q[1].val[1], DCT_CONST_BITS)); qOut1->val[0] = vcombine_s32(vrshrn_n_s64(q[2].val[0], DCT_CONST_BITS), vrshrn_n_s64(q[2].val[1], DCT_CONST_BITS)); qOut1->val[1] = vcombine_s32(vrshrn_n_s64(q[3].val[0], DCT_CONST_BITS), vrshrn_n_s64(q[3].val[1], DCT_CONST_BITS)); } static INLINE void load_s32x4q_dual(const int32_t *in, int32x4x2_t *const s) { s[0].val[0] = vld1q_s32(in); s[0].val[1] = vld1q_s32(in + 4); in += 32; s[1].val[0] = vld1q_s32(in); s[1].val[1] = vld1q_s32(in + 4); in += 32; s[2].val[0] = vld1q_s32(in); s[2].val[1] = vld1q_s32(in + 4); in += 32; s[3].val[0] = vld1q_s32(in); s[3].val[1] = vld1q_s32(in + 4); in += 32; s[4].val[0] = vld1q_s32(in); s[4].val[1] = vld1q_s32(in + 4); in += 32; s[5].val[0] = vld1q_s32(in); s[5].val[1] = vld1q_s32(in + 4); in += 32; s[6].val[0] = vld1q_s32(in); s[6].val[1] = vld1q_s32(in + 4); in += 32; s[7].val[0] = vld1q_s32(in); s[7].val[1] = vld1q_s32(in + 4); } static INLINE void transpose_and_store_s32_8x8(int32x4x2_t *const a, int32_t **out) { transpose_s32_8x8(&a[0], &a[1], &a[2], &a[3], &a[4], &a[5], &a[6], &a[7]); vst1q_s32(*out, a[0].val[0]); *out += 4; vst1q_s32(*out, a[0].val[1]); *out += 4; vst1q_s32(*out, a[1].val[0]); *out += 4; vst1q_s32(*out, a[1].val[1]); *out += 4; vst1q_s32(*out, a[2].val[0]); *out += 4; vst1q_s32(*out, a[2].val[1]); *out += 4; vst1q_s32(*out, a[3].val[0]); *out += 4; vst1q_s32(*out, a[3].val[1]); *out += 4; vst1q_s32(*out, a[4].val[0]); *out += 4; vst1q_s32(*out, a[4].val[1]); *out += 4; vst1q_s32(*out, a[5].val[0]); *out += 4; vst1q_s32(*out, a[5].val[1]); *out += 4; vst1q_s32(*out, a[6].val[0]); *out += 4; vst1q_s32(*out, a[6].val[1]); *out += 4; vst1q_s32(*out, a[7].val[0]); *out += 4; vst1q_s32(*out, a[7].val[1]); *out += 4; } static INLINE void idct32_transpose_pair(const int32_t *input, int32_t *t_buf) { int i; int32x4x2_t s[8]; for (i = 0; i < 4; i++, input += 8) { load_s32x4q_dual(input, s); transpose_and_store_s32_8x8(s, &t_buf); } } static INLINE void idct32_bands_end_1st_pass(int32_t *const out, int32x4x2_t *const q) { store_in_output(out, 16, 17, q[6], q[7]); store_in_output(out, 14, 15, q[8], q[9]); load_from_output(out, 30, 31, &q[0], &q[1]); q[4] = highbd_idct_add_dual(q[2], q[1]); q[5] = highbd_idct_add_dual(q[3], q[0]); q[6] = highbd_idct_sub_dual(q[3], q[0]); q[7] = highbd_idct_sub_dual(q[2], q[1]); store_in_output(out, 30, 31, q[6], q[7]); store_in_output(out, 0, 1, q[4], q[5]); load_from_output(out, 12, 13, &q[0], &q[1]); q[2] = highbd_idct_add_dual(q[10], q[1]); q[3] = highbd_idct_add_dual(q[11], q[0]); q[4] = highbd_idct_sub_dual(q[11], q[0]); q[5] = highbd_idct_sub_dual(q[10], q[1]); load_from_output(out, 18, 19, &q[0], &q[1]); q[8] = highbd_idct_add_dual(q[4], q[1]); q[9] = highbd_idct_add_dual(q[5], q[0]); q[6] = highbd_idct_sub_dual(q[5], q[0]); q[7] = highbd_idct_sub_dual(q[4], q[1]); store_in_output(out, 18, 19, q[6], q[7]); store_in_output(out, 12, 13, q[8], q[9]); load_from_output(out, 28, 29, &q[0], &q[1]); q[4] = highbd_idct_add_dual(q[2], q[1]); q[5] = highbd_idct_add_dual(q[3], q[0]); q[6] = highbd_idct_sub_dual(q[3], q[0]); q[7] = highbd_idct_sub_dual(q[2], q[1]); store_in_output(out, 28, 29, q[6], q[7]); store_in_output(out, 2, 3, q[4], q[5]); load_from_output(out, 10, 11, &q[0], &q[1]); q[2] = highbd_idct_add_dual(q[12], q[1]); q[3] = highbd_idct_add_dual(q[13], q[0]); q[4] = highbd_idct_sub_dual(q[13], q[0]); q[5] = highbd_idct_sub_dual(q[12], q[1]); load_from_output(out, 20, 21, &q[0], &q[1]); q[8] = highbd_idct_add_dual(q[4], q[1]); q[9] = highbd_idct_add_dual(q[5], q[0]); q[6] = highbd_idct_sub_dual(q[5], q[0]); q[7] = highbd_idct_sub_dual(q[4], q[1]); store_in_output(out, 20, 21, q[6], q[7]); store_in_output(out, 10, 11, q[8], q[9]); load_from_output(out, 26, 27, &q[0], &q[1]); q[4] = highbd_idct_add_dual(q[2], q[1]); q[5] = highbd_idct_add_dual(q[3], q[0]); q[6] = highbd_idct_sub_dual(q[3], q[0]); q[7] = highbd_idct_sub_dual(q[2], q[1]); store_in_output(out, 26, 27, q[6], q[7]); store_in_output(out, 4, 5, q[4], q[5]); load_from_output(out, 8, 9, &q[0], &q[1]); q[2] = highbd_idct_add_dual(q[14], q[1]); q[3] = highbd_idct_add_dual(q[15], q[0]); q[4] = highbd_idct_sub_dual(q[15], q[0]); q[5] = highbd_idct_sub_dual(q[14], q[1]); load_from_output(out, 22, 23, &q[0], &q[1]); q[8] = highbd_idct_add_dual(q[4], q[1]); q[9] = highbd_idct_add_dual(q[5], q[0]); q[6] = highbd_idct_sub_dual(q[5], q[0]); q[7] = highbd_idct_sub_dual(q[4], q[1]); store_in_output(out, 22, 23, q[6], q[7]); store_in_output(out, 8, 9, q[8], q[9]); load_from_output(out, 24, 25, &q[0], &q[1]); q[4] = highbd_idct_add_dual(q[2], q[1]); q[5] = highbd_idct_add_dual(q[3], q[0]); q[6] = highbd_idct_sub_dual(q[3], q[0]); q[7] = highbd_idct_sub_dual(q[2], q[1]); store_in_output(out, 24, 25, q[6], q[7]); store_in_output(out, 6, 7, q[4], q[5]); } static INLINE void idct32_bands_end_2nd_pass(const int32_t *const out, uint16_t *const dest, const int stride, const int16x8_t max, int32x4x2_t *const q) { uint16_t *dest0 = dest + 0 * stride; uint16_t *dest1 = dest + 31 * stride; uint16_t *dest2 = dest + 16 * stride; uint16_t *dest3 = dest + 15 * stride; const int str2 = stride << 1; highbd_store_combine_results(dest2, dest3, stride, q[6], q[7], q[8], q[9], max); dest2 += str2; dest3 -= str2; load_from_output(out, 30, 31, &q[0], &q[1]); q[4] = highbd_idct_add_dual(q[2], q[1]); q[5] = highbd_idct_add_dual(q[3], q[0]); q[6] = highbd_idct_sub_dual(q[3], q[0]); q[7] = highbd_idct_sub_dual(q[2], q[1]); highbd_store_combine_results(dest0, dest1, stride, q[4], q[5], q[6], q[7], max); dest0 += str2; dest1 -= str2; load_from_output(out, 12, 13, &q[0], &q[1]); q[2] = highbd_idct_add_dual(q[10], q[1]); q[3] = highbd_idct_add_dual(q[11], q[0]); q[4] = highbd_idct_sub_dual(q[11], q[0]); q[5] = highbd_idct_sub_dual(q[10], q[1]); load_from_output(out, 18, 19, &q[0], &q[1]); q[8] = highbd_idct_add_dual(q[4], q[1]); q[9] = highbd_idct_add_dual(q[5], q[0]); q[6] = highbd_idct_sub_dual(q[5], q[0]); q[7] = highbd_idct_sub_dual(q[4], q[1]); highbd_store_combine_results(dest2, dest3, stride, q[6], q[7], q[8], q[9], max); dest2 += str2; dest3 -= str2; load_from_output(out, 28, 29, &q[0], &q[1]); q[4] = highbd_idct_add_dual(q[2], q[1]); q[5] = highbd_idct_add_dual(q[3], q[0]); q[6] = highbd_idct_sub_dual(q[3], q[0]); q[7] = highbd_idct_sub_dual(q[2], q[1]); highbd_store_combine_results(dest0, dest1, stride, q[4], q[5], q[6], q[7], max); dest0 += str2; dest1 -= str2; load_from_output(out, 10, 11, &q[0], &q[1]); q[2] = highbd_idct_add_dual(q[12], q[1]); q[3] = highbd_idct_add_dual(q[13], q[0]); q[4] = highbd_idct_sub_dual(q[13], q[0]); q[5] = highbd_idct_sub_dual(q[12], q[1]); load_from_output(out, 20, 21, &q[0], &q[1]); q[8] = highbd_idct_add_dual(q[4], q[1]); q[9] = highbd_idct_add_dual(q[5], q[0]); q[6] = highbd_idct_sub_dual(q[5], q[0]); q[7] = highbd_idct_sub_dual(q[4], q[1]); highbd_store_combine_results(dest2, dest3, stride, q[6], q[7], q[8], q[9], max); dest2 += str2; dest3 -= str2; load_from_output(out, 26, 27, &q[0], &q[1]); q[4] = highbd_idct_add_dual(q[2], q[1]); q[5] = highbd_idct_add_dual(q[3], q[0]); q[6] = highbd_idct_sub_dual(q[3], q[0]); q[7] = highbd_idct_sub_dual(q[2], q[1]); highbd_store_combine_results(dest0, dest1, stride, q[4], q[5], q[6], q[7], max); dest0 += str2; dest1 -= str2; load_from_output(out, 8, 9, &q[0], &q[1]); q[2] = highbd_idct_add_dual(q[14], q[1]); q[3] = highbd_idct_add_dual(q[15], q[0]); q[4] = highbd_idct_sub_dual(q[15], q[0]); q[5] = highbd_idct_sub_dual(q[14], q[1]); load_from_output(out, 22, 23, &q[0], &q[1]); q[8] = highbd_idct_add_dual(q[4], q[1]); q[9] = highbd_idct_add_dual(q[5], q[0]); q[6] = highbd_idct_sub_dual(q[5], q[0]); q[7] = highbd_idct_sub_dual(q[4], q[1]); highbd_store_combine_results(dest2, dest3, stride, q[6], q[7], q[8], q[9], max); load_from_output(out, 24, 25, &q[0], &q[1]); q[4] = highbd_idct_add_dual(q[2], q[1]); q[5] = highbd_idct_add_dual(q[3], q[0]); q[6] = highbd_idct_sub_dual(q[3], q[0]); q[7] = highbd_idct_sub_dual(q[2], q[1]); highbd_store_combine_results(dest0, dest1, stride, q[4], q[5], q[6], q[7], max); } static INLINE void vpx_highbd_idct32_32_neon(const tran_low_t *input, uint16_t *dst, const int stride, const int bd) { int i, idct32_pass_loop; int32_t trans_buf[32 * 8]; int32_t pass1[32 * 32]; int32_t pass2[32 * 32]; int32_t *out; int32x4x2_t q[16]; for (idct32_pass_loop = 0, out = pass1; idct32_pass_loop < 2; idct32_pass_loop++, input = pass1, out = pass2) { for (i = 0; i < 4; i++, out += 8) { // idct32_bands_loop idct32_transpose_pair(input, trans_buf); input += 32 * 8; // ----------------------------------------- // BLOCK A: 16-19,28-31 // ----------------------------------------- // generate 16,17,30,31 // part of stage 1 load_from_transformed(trans_buf, 1, 31, &q[14], &q[13]); do_butterfly(q[14], q[13], cospi_31_64, cospi_1_64, &q[0], &q[2]); load_from_transformed(trans_buf, 17, 15, &q[14], &q[13]); do_butterfly(q[14], q[13], cospi_15_64, cospi_17_64, &q[1], &q[3]); // part of stage 2 q[4] = highbd_idct_add_dual(q[0], q[1]); q[13] = highbd_idct_sub_dual(q[0], q[1]); q[6] = highbd_idct_add_dual(q[2], q[3]); q[14] = highbd_idct_sub_dual(q[2], q[3]); // part of stage 3 do_butterfly(q[14], q[13], cospi_28_64, cospi_4_64, &q[5], &q[7]); // generate 18,19,28,29 // part of stage 1 load_from_transformed(trans_buf, 9, 23, &q[14], &q[13]); do_butterfly(q[14], q[13], cospi_23_64, cospi_9_64, &q[0], &q[2]); load_from_transformed(trans_buf, 25, 7, &q[14], &q[13]); do_butterfly(q[14], q[13], cospi_7_64, cospi_25_64, &q[1], &q[3]); // part of stage 2 q[13] = highbd_idct_sub_dual(q[3], q[2]); q[3] = highbd_idct_add_dual(q[3], q[2]); q[14] = highbd_idct_sub_dual(q[1], q[0]); q[2] = highbd_idct_add_dual(q[1], q[0]); // part of stage 3 do_butterfly(q[14], q[13], -cospi_4_64, -cospi_28_64, &q[1], &q[0]); // part of stage 4 q[8] = highbd_idct_add_dual(q[4], q[2]); q[9] = highbd_idct_add_dual(q[5], q[0]); q[10] = highbd_idct_add_dual(q[7], q[1]); q[15] = highbd_idct_add_dual(q[6], q[3]); q[13] = highbd_idct_sub_dual(q[5], q[0]); q[14] = highbd_idct_sub_dual(q[7], q[1]); store_in_output(out, 16, 31, q[8], q[15]); store_in_output(out, 17, 30, q[9], q[10]); // part of stage 5 do_butterfly(q[14], q[13], cospi_24_64, cospi_8_64, &q[0], &q[1]); store_in_output(out, 29, 18, q[1], q[0]); // part of stage 4 q[13] = highbd_idct_sub_dual(q[4], q[2]); q[14] = highbd_idct_sub_dual(q[6], q[3]); // part of stage 5 do_butterfly(q[14], q[13], cospi_24_64, cospi_8_64, &q[4], &q[6]); store_in_output(out, 19, 28, q[4], q[6]); // ----------------------------------------- // BLOCK B: 20-23,24-27 // ----------------------------------------- // generate 20,21,26,27 // part of stage 1 load_from_transformed(trans_buf, 5, 27, &q[14], &q[13]); do_butterfly(q[14], q[13], cospi_27_64, cospi_5_64, &q[0], &q[2]); load_from_transformed(trans_buf, 21, 11, &q[14], &q[13]); do_butterfly(q[14], q[13], cospi_11_64, cospi_21_64, &q[1], &q[3]); // part of stage 2 q[13] = highbd_idct_sub_dual(q[0], q[1]); q[0] = highbd_idct_add_dual(q[0], q[1]); q[14] = highbd_idct_sub_dual(q[2], q[3]); q[2] = highbd_idct_add_dual(q[2], q[3]); // part of stage 3 do_butterfly(q[14], q[13], cospi_12_64, cospi_20_64, &q[1], &q[3]); // generate 22,23,24,25 // part of stage 1 load_from_transformed(trans_buf, 13, 19, &q[14], &q[13]); do_butterfly(q[14], q[13], cospi_19_64, cospi_13_64, &q[5], &q[7]); load_from_transformed(trans_buf, 29, 3, &q[14], &q[13]); do_butterfly(q[14], q[13], cospi_3_64, cospi_29_64, &q[4], &q[6]); // part of stage 2 q[14] = highbd_idct_sub_dual(q[4], q[5]); q[5] = highbd_idct_add_dual(q[4], q[5]); q[13] = highbd_idct_sub_dual(q[6], q[7]); q[6] = highbd_idct_add_dual(q[6], q[7]); // part of stage 3 do_butterfly(q[14], q[13], -cospi_20_64, -cospi_12_64, &q[4], &q[7]); // part of stage 4 q[10] = highbd_idct_add_dual(q[7], q[1]); q[11] = highbd_idct_add_dual(q[5], q[0]); q[12] = highbd_idct_add_dual(q[6], q[2]); q[15] = highbd_idct_add_dual(q[4], q[3]); // part of stage 6 load_from_output(out, 16, 17, &q[14], &q[13]); q[8] = highbd_idct_add_dual(q[14], q[11]); q[9] = highbd_idct_add_dual(q[13], q[10]); q[13] = highbd_idct_sub_dual(q[13], q[10]); q[11] = highbd_idct_sub_dual(q[14], q[11]); store_in_output(out, 17, 16, q[9], q[8]); load_from_output(out, 30, 31, &q[14], &q[9]); q[8] = highbd_idct_sub_dual(q[9], q[12]); q[10] = highbd_idct_add_dual(q[14], q[15]); q[14] = highbd_idct_sub_dual(q[14], q[15]); q[12] = highbd_idct_add_dual(q[9], q[12]); store_in_output(out, 30, 31, q[10], q[12]); // part of stage 7 do_butterfly(q[14], q[13], cospi_16_64, cospi_16_64, &q[13], &q[14]); store_in_output(out, 25, 22, q[14], q[13]); do_butterfly(q[8], q[11], cospi_16_64, cospi_16_64, &q[13], &q[14]); store_in_output(out, 24, 23, q[14], q[13]); // part of stage 4 q[14] = highbd_idct_sub_dual(q[5], q[0]); q[13] = highbd_idct_sub_dual(q[6], q[2]); do_butterfly(q[14], q[13], -cospi_8_64, -cospi_24_64, &q[5], &q[6]); q[14] = highbd_idct_sub_dual(q[7], q[1]); q[13] = highbd_idct_sub_dual(q[4], q[3]); do_butterfly(q[14], q[13], -cospi_8_64, -cospi_24_64, &q[0], &q[1]); // part of stage 6 load_from_output(out, 18, 19, &q[14], &q[13]); q[8] = highbd_idct_add_dual(q[14], q[1]); q[9] = highbd_idct_add_dual(q[13], q[6]); q[13] = highbd_idct_sub_dual(q[13], q[6]); q[1] = highbd_idct_sub_dual(q[14], q[1]); store_in_output(out, 18, 19, q[8], q[9]); load_from_output(out, 28, 29, &q[8], &q[9]); q[14] = highbd_idct_sub_dual(q[8], q[5]); q[10] = highbd_idct_add_dual(q[8], q[5]); q[11] = highbd_idct_add_dual(q[9], q[0]); q[0] = highbd_idct_sub_dual(q[9], q[0]); store_in_output(out, 28, 29, q[10], q[11]); // part of stage 7 do_butterfly(q[14], q[13], cospi_16_64, cospi_16_64, &q[13], &q[14]); store_in_output(out, 20, 27, q[13], q[14]); do_butterfly(q[0], q[1], cospi_16_64, cospi_16_64, &q[1], &q[0]); store_in_output(out, 21, 26, q[1], q[0]); // ----------------------------------------- // BLOCK C: 8-10,11-15 // ----------------------------------------- // generate 8,9,14,15 // part of stage 2 load_from_transformed(trans_buf, 2, 30, &q[14], &q[13]); do_butterfly(q[14], q[13], cospi_30_64, cospi_2_64, &q[0], &q[2]); load_from_transformed(trans_buf, 18, 14, &q[14], &q[13]); do_butterfly(q[14], q[13], cospi_14_64, cospi_18_64, &q[1], &q[3]); // part of stage 3 q[13] = highbd_idct_sub_dual(q[0], q[1]); q[0] = highbd_idct_add_dual(q[0], q[1]); q[14] = highbd_idct_sub_dual(q[2], q[3]); q[2] = highbd_idct_add_dual(q[2], q[3]); // part of stage 4 do_butterfly(q[14], q[13], cospi_24_64, cospi_8_64, &q[1], &q[3]); // generate 10,11,12,13 // part of stage 2 load_from_transformed(trans_buf, 10, 22, &q[14], &q[13]); do_butterfly(q[14], q[13], cospi_22_64, cospi_10_64, &q[5], &q[7]); load_from_transformed(trans_buf, 26, 6, &q[14], &q[13]); do_butterfly(q[14], q[13], cospi_6_64, cospi_26_64, &q[4], &q[6]); // part of stage 3 q[14] = highbd_idct_sub_dual(q[4], q[5]); q[5] = highbd_idct_add_dual(q[4], q[5]); q[13] = highbd_idct_sub_dual(q[6], q[7]); q[6] = highbd_idct_add_dual(q[6], q[7]); // part of stage 4 do_butterfly(q[14], q[13], -cospi_8_64, -cospi_24_64, &q[4], &q[7]); // part of stage 5 q[8] = highbd_idct_add_dual(q[0], q[5]); q[9] = highbd_idct_add_dual(q[1], q[7]); q[13] = highbd_idct_sub_dual(q[1], q[7]); q[14] = highbd_idct_sub_dual(q[3], q[4]); q[10] = highbd_idct_add_dual(q[3], q[4]); q[15] = highbd_idct_add_dual(q[2], q[6]); store_in_output(out, 8, 15, q[8], q[15]); store_in_output(out, 9, 14, q[9], q[10]); // part of stage 6 do_butterfly(q[14], q[13], cospi_16_64, cospi_16_64, &q[1], &q[3]); store_in_output(out, 13, 10, q[3], q[1]); q[13] = highbd_idct_sub_dual(q[0], q[5]); q[14] = highbd_idct_sub_dual(q[2], q[6]); do_butterfly(q[14], q[13], cospi_16_64, cospi_16_64, &q[1], &q[3]); store_in_output(out, 11, 12, q[1], q[3]); // ----------------------------------------- // BLOCK D: 0-3,4-7 // ----------------------------------------- // generate 4,5,6,7 // part of stage 3 load_from_transformed(trans_buf, 4, 28, &q[14], &q[13]); do_butterfly(q[14], q[13], cospi_28_64, cospi_4_64, &q[0], &q[2]); load_from_transformed(trans_buf, 20, 12, &q[14], &q[13]); do_butterfly(q[14], q[13], cospi_12_64, cospi_20_64, &q[1], &q[3]); // part of stage 4 q[13] = highbd_idct_sub_dual(q[0], q[1]); q[0] = highbd_idct_add_dual(q[0], q[1]); q[14] = highbd_idct_sub_dual(q[2], q[3]); q[2] = highbd_idct_add_dual(q[2], q[3]); // part of stage 5 do_butterfly(q[14], q[13], cospi_16_64, cospi_16_64, &q[1], &q[3]); // generate 0,1,2,3 // part of stage 4 load_from_transformed(trans_buf, 0, 16, &q[14], &q[13]); do_butterfly(q[14], q[13], cospi_16_64, cospi_16_64, &q[5], &q[7]); load_from_transformed(trans_buf, 8, 24, &q[14], &q[13]); do_butterfly(q[14], q[13], cospi_24_64, cospi_8_64, &q[14], &q[6]); // part of stage 5 q[4] = highbd_idct_add_dual(q[7], q[6]); q[7] = highbd_idct_sub_dual(q[7], q[6]); q[6] = highbd_idct_sub_dual(q[5], q[14]); q[5] = highbd_idct_add_dual(q[5], q[14]); // part of stage 6 q[8] = highbd_idct_add_dual(q[4], q[2]); q[9] = highbd_idct_add_dual(q[5], q[3]); q[10] = highbd_idct_add_dual(q[6], q[1]); q[11] = highbd_idct_add_dual(q[7], q[0]); q[12] = highbd_idct_sub_dual(q[7], q[0]); q[13] = highbd_idct_sub_dual(q[6], q[1]); q[14] = highbd_idct_sub_dual(q[5], q[3]); q[15] = highbd_idct_sub_dual(q[4], q[2]); // part of stage 7 load_from_output(out, 14, 15, &q[0], &q[1]); q[2] = highbd_idct_add_dual(q[8], q[1]); q[3] = highbd_idct_add_dual(q[9], q[0]); q[4] = highbd_idct_sub_dual(q[9], q[0]); q[5] = highbd_idct_sub_dual(q[8], q[1]); load_from_output(out, 16, 17, &q[0], &q[1]); q[8] = highbd_idct_add_dual(q[4], q[1]); q[9] = highbd_idct_add_dual(q[5], q[0]); q[6] = highbd_idct_sub_dual(q[5], q[0]); q[7] = highbd_idct_sub_dual(q[4], q[1]); if (idct32_pass_loop == 0) { idct32_bands_end_1st_pass(out, q); } else { const int16x8_t max = vdupq_n_s16((1 << bd) - 1); idct32_bands_end_2nd_pass(out, dst, stride, max, q); dst += 8; } } } } void vpx_highbd_idct32x32_1024_add_neon(const tran_low_t *input, uint16_t *dest, int stride, int bd) { if (bd == 8) { vpx_idct32_32_neon(input, CAST_TO_BYTEPTR(dest), stride, 1); } else { vpx_highbd_idct32_32_neon(input, dest, stride, bd); } }