/* * Copyright (c) 2020, Alliance for Open Media. All rights reserved. * * This source code is subject to the terms of the BSD 2 Clause License and * the Alliance for Open Media Patent License 1.0. If the BSD 2 Clause License * was not distributed with this source code in the LICENSE file, you canzip * obtain it at www.aomedia.org/license/software. If the Alliance for Open * Media Patent License 1.0 was not distributed with this source code in the * PATENTS file, you can obtain it at www.aomedia.org/license/patent. */ #include #include #include "av1/common/av1_inv_txfm1d_cfg.h" #include "av1/common/idct.h" #include "config/aom_config.h" #include "config/av1_rtcd.h" #if AOM_ARCH_AARCH64 #define TRANSPOSE_4X4(x0, x1, x2, x3, y0, y1, y2, y3) \ do { \ int32x4x2_t swap_low = vtrnq_s32(x0, x1); \ int32x4x2_t swap_high = vtrnq_s32(x2, x3); \ y0 = vreinterpretq_s32_s64( \ vzip1q_s64(vreinterpretq_s64_s32(swap_low.val[0]), \ vreinterpretq_s64_s32(swap_high.val[0]))); \ y1 = vreinterpretq_s32_s64( \ vzip1q_s64(vreinterpretq_s64_s32(swap_low.val[1]), \ vreinterpretq_s64_s32(swap_high.val[1]))); \ y2 = vreinterpretq_s32_s64( \ vzip2q_s64(vreinterpretq_s64_s32(swap_low.val[0]), \ vreinterpretq_s64_s32(swap_high.val[0]))); \ y3 = vreinterpretq_s32_s64( \ vzip2q_s64(vreinterpretq_s64_s32(swap_low.val[1]), \ vreinterpretq_s64_s32(swap_high.val[1]))); \ } while (0) #else #define TRANSPOSE_4X4(x0, x1, x2, x3, y0, y1, y2, y3) \ do { \ int32x4x2_t swap_low = vtrnq_s32(x0, x1); \ int32x4x2_t swap_high = vtrnq_s32(x2, x3); \ y0 = vextq_s32(vextq_s32(swap_low.val[0], swap_low.val[0], 2), \ swap_high.val[0], 2); \ y1 = vextq_s32(vextq_s32(swap_low.val[1], swap_low.val[1], 2), \ swap_high.val[1], 2); \ y2 = vextq_s32(swap_low.val[0], \ vextq_s32(swap_high.val[0], swap_high.val[0], 2), 2); \ y3 = vextq_s32(swap_low.val[1], \ vextq_s32(swap_high.val[1], swap_high.val[1], 2), 2); \ } while (0) #endif // AOM_ARCH_AARCH64 static inline void transpose_4x4(const int32x4_t *in, int32x4_t *out) { TRANSPOSE_4X4(in[0], in[1], in[2], in[3], out[0], out[1], out[2], out[3]); } static inline void transpose_8x8(const int32x4_t *in, int32x4_t *out) { TRANSPOSE_4X4(in[0], in[2], in[4], in[6], out[0], out[2], out[4], out[6]); TRANSPOSE_4X4(in[1], in[3], in[5], in[7], out[8], out[10], out[12], out[14]); TRANSPOSE_4X4(in[8], in[10], in[12], in[14], out[1], out[3], out[5], out[7]); TRANSPOSE_4X4(in[9], in[11], in[13], in[15], out[9], out[11], out[13], out[15]); } static inline void round_shift_array_32_neon(int32x4_t *input, int32x4_t *output, const int size, const int bit) { const int32x4_t v_bit = vdupq_n_s32(-bit); for (int i = 0; i < size; i++) { output[i] = vrshlq_s32(input[i], v_bit); } } static inline void round_shift_rect_array_32_neon(int32x4_t *input, int32x4_t *output, const int size) { for (int i = 0; i < size; i++) { const int32x4_t r0 = vmulq_n_s32(input[i], NewInvSqrt2); output[i] = vrshrq_n_s32(r0, NewSqrt2Bits); } } static inline int32x4_t half_btf_neon_r(const int32_t *n0, const int32x4_t *w0, const int32_t *n1, const int32x4_t *w1, const int32x4_t *v_bit, const int32x4_t *rnding) { int32x4_t x; x = vmlaq_n_s32(*rnding, *w0, *n0); x = vmlaq_n_s32(x, *w1, *n1); x = vshlq_s32(x, *v_bit); return x; } static inline int32x4_t half_btf_neon_mode11_r( const int32_t *n0, const int32x4_t *w0, const int32_t *n1, const int32x4_t *w1, const int32x4_t *v_bit, const int32x4_t *rnding) { int32x4_t x; x = vmlaq_n_s32(*rnding, *w0, -*n0); x = vmlaq_n_s32(x, *w1, -*n1); x = vshlq_s32(x, *v_bit); return x; } static inline int32x4_t half_btf_neon_mode01_r( const int32_t *n0, const int32x4_t *w0, const int32_t *n1, const int32x4_t *w1, const int32x4_t *v_bit, const int32x4_t *rnding) { int32x4_t x; x = vmlaq_n_s32(*rnding, *w0, *n0); x = vmlsq_n_s32(x, *w1, *n1); x = vshlq_s32(x, *v_bit); return x; } static inline int32x4_t half_btf_neon_mode10_r( const int32_t *n0, const int32x4_t *w0, const int32_t *n1, const int32x4_t *w1, const int32x4_t *v_bit, const int32x4_t *rnding) { int32x4_t x; x = vmlaq_n_s32(*rnding, *w1, *n1); x = vmlsq_n_s32(x, *w0, *n0); x = vshlq_s32(x, *v_bit); return x; } static inline int32x4_t half_btf_0_neon_r(const int32_t *n0, const int32x4_t *w0, const int32x4_t *v_bit, const int32x4_t *rnding) { int32x4_t x; x = vmlaq_n_s32(*rnding, *w0, *n0); x = vshlq_s32(x, *v_bit); return x; } static inline int32x4_t half_btf_0_m_neon_r(const int32_t *n0, const int32x4_t *w0, const int32x4_t *v_bit, const int32x4_t *rnding) { int32x4_t x; x = vmlaq_n_s32(*rnding, *w0, -*n0); x = vshlq_s32(x, *v_bit); return x; } static inline void flip_buf_neon(int32x4_t *in, int32x4_t *out, int size) { for (int i = 0; i < size; ++i) { out[size - i - 1] = in[i]; } } typedef void (*fwd_transform_1d_neon)(int32x4_t *in, int32x4_t *out, int bit, const int num_cols); typedef void (*transform_1d_neon)(int32x4_t *in, int32x4_t *out, int32_t bit, int32_t do_cols, int32_t bd, int32_t out_shift); static inline uint16x8_t highbd_clamp_u16(uint16x8_t *u, const uint16x8_t *min, const uint16x8_t *max) { int16x8_t clamped; clamped = vminq_s16(vreinterpretq_s16_u16(*u), vreinterpretq_s16_u16(*max)); clamped = vmaxq_s16(clamped, vreinterpretq_s16_u16(*min)); return vreinterpretq_u16_s16(clamped); } static inline void round_shift_4x4(int32x4_t *in, int shift) { if (shift != 0) { const int32x4_t v_shift = vdupq_n_s32(-shift); in[0] = vrshlq_s32(in[0], v_shift); in[1] = vrshlq_s32(in[1], v_shift); in[2] = vrshlq_s32(in[2], v_shift); in[3] = vrshlq_s32(in[3], v_shift); } } static void round_shift_8x8(int32x4_t *in, int shift) { assert(shift != 0); const int32x4_t v_shift = vdupq_n_s32(-shift); in[0] = vrshlq_s32(in[0], v_shift); in[1] = vrshlq_s32(in[1], v_shift); in[2] = vrshlq_s32(in[2], v_shift); in[3] = vrshlq_s32(in[3], v_shift); in[4] = vrshlq_s32(in[4], v_shift); in[5] = vrshlq_s32(in[5], v_shift); in[6] = vrshlq_s32(in[6], v_shift); in[7] = vrshlq_s32(in[7], v_shift); in[8] = vrshlq_s32(in[8], v_shift); in[9] = vrshlq_s32(in[9], v_shift); in[10] = vrshlq_s32(in[10], v_shift); in[11] = vrshlq_s32(in[11], v_shift); in[12] = vrshlq_s32(in[12], v_shift); in[13] = vrshlq_s32(in[13], v_shift); in[14] = vrshlq_s32(in[14], v_shift); in[15] = vrshlq_s32(in[15], v_shift); } static void highbd_clamp_s32_neon(int32x4_t *in, int32x4_t *out, const int32x4_t *clamp_lo, const int32x4_t *clamp_hi, int size) { int32x4_t a0, a1; for (int i = 0; i < size; i += 4) { a0 = vmaxq_s32(in[i], *clamp_lo); out[i] = vminq_s32(a0, *clamp_hi); a1 = vmaxq_s32(in[i + 1], *clamp_lo); out[i + 1] = vminq_s32(a1, *clamp_hi); a0 = vmaxq_s32(in[i + 2], *clamp_lo); out[i + 2] = vminq_s32(a0, *clamp_hi); a1 = vmaxq_s32(in[i + 3], *clamp_lo); out[i + 3] = vminq_s32(a1, *clamp_hi); } } static inline uint16x8_t highbd_get_recon_8x8_neon(const uint16x8_t pred, int32x4_t res0, int32x4_t res1, const int bd) { const uint16x8_t v_zero = vdupq_n_u16(0); int32x4_t min_clip_val = vreinterpretq_s32_u16(v_zero); int32x4_t max_clip_val = vdupq_n_s32((1 << bd) - 1); uint16x8x2_t x; x.val[0] = vreinterpretq_u16_s32( vaddw_s16(res0, vreinterpret_s16_u16(vget_low_u16(pred)))); x.val[1] = vreinterpretq_u16_s32( vaddw_s16(res1, vreinterpret_s16_u16(vget_high_u16(pred)))); x.val[0] = vreinterpretq_u16_s32( vmaxq_s32(vreinterpretq_s32_u16(x.val[0]), min_clip_val)); x.val[0] = vreinterpretq_u16_s32( vminq_s32(vreinterpretq_s32_u16(x.val[0]), max_clip_val)); x.val[1] = vreinterpretq_u16_s32( vmaxq_s32(vreinterpretq_s32_u16(x.val[1]), min_clip_val)); x.val[1] = vreinterpretq_u16_s32( vminq_s32(vreinterpretq_s32_u16(x.val[1]), max_clip_val)); uint16x8_t res = vcombine_u16(vqmovn_u32(vreinterpretq_u32_u16(x.val[0])), vqmovn_u32(vreinterpretq_u32_u16(x.val[1]))); return res; } static inline uint16x4_t highbd_get_recon_4xn_neon(uint16x4_t pred, int32x4_t res0, const int bd) { uint16x4_t x0_ = vreinterpret_u16_s16( vmovn_s32(vaddw_s16(res0, vreinterpret_s16_u16(pred)))); uint16x8_t x0 = vcombine_u16(x0_, x0_); const uint16x8_t vmin = vdupq_n_u16(0); const uint16x8_t vmax = vdupq_n_u16((1 << bd) - 1); x0 = highbd_clamp_u16(&x0, &vmin, &vmax); return vget_low_u16(x0); } static inline void highbd_write_buffer_4xn_neon(int32x4_t *in, uint16_t *output, int stride, int flipud, int height, const int bd) { int j = flipud ? (height - 1) : 0; const int step = flipud ? -1 : 1; for (int i = 0; i < height; ++i, j += step) { uint16x4_t v = vld1_u16(output + i * stride); uint16x4_t u = highbd_get_recon_4xn_neon(v, in[j], bd); vst1_u16(output + i * stride, u); } } static inline void highbd_write_buffer_8xn_neon(int32x4_t *in, uint16_t *output, int stride, int flipud, int height, const int bd) { int j = flipud ? (height - 1) : 0; const int step = flipud ? -1 : 1; for (int i = 0; i < height; ++i, j += step) { uint16x8_t v = vld1q_u16(output + i * stride); uint16x8_t u = highbd_get_recon_8x8_neon(v, in[j], in[j + height], bd); vst1q_u16(output + i * stride, u); } } static inline void load_buffer_32bit_input(const int32_t *in, int stride, int32x4_t *out, int out_size) { for (int i = 0; i < out_size; ++i) { out[i] = vld1q_s32(in + i * stride); } } static inline void load_buffer_4x4(const int32_t *coeff, int32x4_t *in) { in[0] = vld1q_s32(coeff + 0); in[1] = vld1q_s32(coeff + 4); in[2] = vld1q_s32(coeff + 8); in[3] = vld1q_s32(coeff + 12); } static void addsub_neon(const int32x4_t in0, const int32x4_t in1, int32x4_t *out0, int32x4_t *out1, const int32x4_t *clamp_lo, const int32x4_t *clamp_hi) { int32x4_t a0 = vaddq_s32(in0, in1); int32x4_t a1 = vsubq_s32(in0, in1); a0 = vmaxq_s32(a0, *clamp_lo); a0 = vminq_s32(a0, *clamp_hi); a1 = vmaxq_s32(a1, *clamp_lo); a1 = vminq_s32(a1, *clamp_hi); *out0 = a0; *out1 = a1; } static void shift_and_clamp_neon(int32x4_t *in0, int32x4_t *in1, const int32x4_t *clamp_lo, const int32x4_t *clamp_hi, const int32x4_t *v_shift) { int32x4_t in0_w_offset = vrshlq_s32(*in0, *v_shift); int32x4_t in1_w_offset = vrshlq_s32(*in1, *v_shift); in0_w_offset = vmaxq_s32(in0_w_offset, *clamp_lo); in0_w_offset = vminq_s32(in0_w_offset, *clamp_hi); in1_w_offset = vmaxq_s32(in1_w_offset, *clamp_lo); in1_w_offset = vminq_s32(in1_w_offset, *clamp_hi); *in0 = in0_w_offset; *in1 = in1_w_offset; } static inline void idct32_stage4_neon(int32x4_t *bf1, const int32_t *cospi, const int32x4_t *v_bit, const int32x4_t *rnding) { int32x4_t temp1, temp2; temp1 = half_btf_neon_mode10_r(&cospi[8], &bf1[17], &cospi[56], &bf1[30], v_bit, rnding); bf1[30] = half_btf_neon_r(&cospi[56], &bf1[17], &cospi[8], &bf1[30], v_bit, rnding); bf1[17] = temp1; temp2 = half_btf_neon_mode11_r(&cospi[56], &bf1[18], &cospi[8], &bf1[29], v_bit, rnding); bf1[29] = half_btf_neon_mode10_r(&cospi[8], &bf1[18], &cospi[56], &bf1[29], v_bit, rnding); bf1[18] = temp2; temp1 = half_btf_neon_mode10_r(&cospi[40], &bf1[21], &cospi[24], &bf1[26], v_bit, rnding); bf1[26] = half_btf_neon_r(&cospi[24], &bf1[21], &cospi[40], &bf1[26], v_bit, rnding); bf1[21] = temp1; temp2 = half_btf_neon_mode11_r(&cospi[24], &bf1[22], &cospi[40], &bf1[25], v_bit, rnding); bf1[25] = half_btf_neon_mode10_r(&cospi[40], &bf1[22], &cospi[24], &bf1[25], v_bit, rnding); bf1[22] = temp2; } static inline void idct32_stage5_neon(int32x4_t *bf1, const int32_t *cospi, const int32x4_t *clamp_lo, const int32x4_t *clamp_hi, const int32x4_t *v_bit, const int32x4_t *rnding) { int32x4_t temp1, temp2; temp1 = half_btf_neon_mode10_r(&cospi[16], &bf1[9], &cospi[48], &bf1[14], v_bit, rnding); bf1[14] = half_btf_neon_r(&cospi[48], &bf1[9], &cospi[16], &bf1[14], v_bit, rnding); bf1[9] = temp1; temp2 = half_btf_neon_mode11_r(&cospi[48], &bf1[10], &cospi[16], &bf1[13], v_bit, rnding); bf1[13] = half_btf_neon_mode10_r(&cospi[16], &bf1[10], &cospi[48], &bf1[13], v_bit, rnding); bf1[10] = temp2; addsub_neon(bf1[16], bf1[19], bf1 + 16, bf1 + 19, clamp_lo, clamp_hi); addsub_neon(bf1[17], bf1[18], bf1 + 17, bf1 + 18, clamp_lo, clamp_hi); addsub_neon(bf1[23], bf1[20], bf1 + 23, bf1 + 20, clamp_lo, clamp_hi); addsub_neon(bf1[22], bf1[21], bf1 + 22, bf1 + 21, clamp_lo, clamp_hi); addsub_neon(bf1[24], bf1[27], bf1 + 24, bf1 + 27, clamp_lo, clamp_hi); addsub_neon(bf1[25], bf1[26], bf1 + 25, bf1 + 26, clamp_lo, clamp_hi); addsub_neon(bf1[31], bf1[28], bf1 + 31, bf1 + 28, clamp_lo, clamp_hi); addsub_neon(bf1[30], bf1[29], bf1 + 30, bf1 + 29, clamp_lo, clamp_hi); } static inline void idct32_stage6_neon(int32x4_t *bf1, const int32_t *cospi, const int32x4_t *clamp_lo, const int32x4_t *clamp_hi, const int32x4_t *v_bit, const int32x4_t *rnding) { int32x4_t temp1, temp2; temp1 = half_btf_neon_mode10_r(&cospi[32], &bf1[5], &cospi[32], &bf1[6], v_bit, rnding); bf1[6] = half_btf_neon_r(&cospi[32], &bf1[5], &cospi[32], &bf1[6], v_bit, rnding); bf1[5] = temp1; addsub_neon(bf1[8], bf1[11], bf1 + 8, bf1 + 11, clamp_lo, clamp_hi); addsub_neon(bf1[9], bf1[10], bf1 + 9, bf1 + 10, clamp_lo, clamp_hi); addsub_neon(bf1[15], bf1[12], bf1 + 15, bf1 + 12, clamp_lo, clamp_hi); addsub_neon(bf1[14], bf1[13], bf1 + 14, bf1 + 13, clamp_lo, clamp_hi); temp1 = half_btf_neon_mode10_r(&cospi[16], &bf1[18], &cospi[48], &bf1[29], v_bit, rnding); bf1[29] = half_btf_neon_r(&cospi[48], &bf1[18], &cospi[16], &bf1[29], v_bit, rnding); bf1[18] = temp1; temp2 = half_btf_neon_mode10_r(&cospi[16], &bf1[19], &cospi[48], &bf1[28], v_bit, rnding); bf1[28] = half_btf_neon_r(&cospi[48], &bf1[19], &cospi[16], &bf1[28], v_bit, rnding); bf1[19] = temp2; temp1 = half_btf_neon_mode11_r(&cospi[48], &bf1[20], &cospi[16], &bf1[27], v_bit, rnding); bf1[27] = half_btf_neon_mode10_r(&cospi[16], &bf1[20], &cospi[48], &bf1[27], v_bit, rnding); bf1[20] = temp1; temp2 = half_btf_neon_mode11_r(&cospi[48], &bf1[21], &cospi[16], &bf1[26], v_bit, rnding); bf1[26] = half_btf_neon_mode10_r(&cospi[16], &bf1[21], &cospi[48], &bf1[26], v_bit, rnding); bf1[21] = temp2; } static inline void idct32_stage7_neon(int32x4_t *bf1, const int32_t *cospi, const int32x4_t *clamp_lo, const int32x4_t *clamp_hi, const int32x4_t *v_bit, const int32x4_t *rnding) { int32x4_t temp1, temp2; addsub_neon(bf1[0], bf1[7], bf1 + 0, bf1 + 7, clamp_lo, clamp_hi); addsub_neon(bf1[1], bf1[6], bf1 + 1, bf1 + 6, clamp_lo, clamp_hi); addsub_neon(bf1[2], bf1[5], bf1 + 2, bf1 + 5, clamp_lo, clamp_hi); addsub_neon(bf1[3], bf1[4], bf1 + 3, bf1 + 4, clamp_lo, clamp_hi); temp1 = half_btf_neon_mode10_r(&cospi[32], &bf1[10], &cospi[32], &bf1[13], v_bit, rnding); bf1[13] = half_btf_neon_r(&cospi[32], &bf1[10], &cospi[32], &bf1[13], v_bit, rnding); bf1[10] = temp1; temp2 = half_btf_neon_mode10_r(&cospi[32], &bf1[11], &cospi[32], &bf1[12], v_bit, rnding); bf1[12] = half_btf_neon_r(&cospi[32], &bf1[11], &cospi[32], &bf1[12], v_bit, rnding); bf1[11] = temp2; addsub_neon(bf1[16], bf1[23], bf1 + 16, bf1 + 23, clamp_lo, clamp_hi); addsub_neon(bf1[17], bf1[22], bf1 + 17, bf1 + 22, clamp_lo, clamp_hi); addsub_neon(bf1[18], bf1[21], bf1 + 18, bf1 + 21, clamp_lo, clamp_hi); addsub_neon(bf1[19], bf1[20], bf1 + 19, bf1 + 20, clamp_lo, clamp_hi); addsub_neon(bf1[31], bf1[24], bf1 + 31, bf1 + 24, clamp_lo, clamp_hi); addsub_neon(bf1[30], bf1[25], bf1 + 30, bf1 + 25, clamp_lo, clamp_hi); addsub_neon(bf1[29], bf1[26], bf1 + 29, bf1 + 26, clamp_lo, clamp_hi); addsub_neon(bf1[28], bf1[27], bf1 + 28, bf1 + 27, clamp_lo, clamp_hi); } static inline void idct32_stage8_neon(int32x4_t *bf1, const int32_t *cospi, const int32x4_t *clamp_lo, const int32x4_t *clamp_hi, const int32x4_t *v_bit, const int32x4_t *rnding) { int32x4_t temp1, temp2; addsub_neon(bf1[0], bf1[15], bf1 + 0, bf1 + 15, clamp_lo, clamp_hi); addsub_neon(bf1[1], bf1[14], bf1 + 1, bf1 + 14, clamp_lo, clamp_hi); addsub_neon(bf1[2], bf1[13], bf1 + 2, bf1 + 13, clamp_lo, clamp_hi); addsub_neon(bf1[3], bf1[12], bf1 + 3, bf1 + 12, clamp_lo, clamp_hi); addsub_neon(bf1[4], bf1[11], bf1 + 4, bf1 + 11, clamp_lo, clamp_hi); addsub_neon(bf1[5], bf1[10], bf1 + 5, bf1 + 10, clamp_lo, clamp_hi); addsub_neon(bf1[6], bf1[9], bf1 + 6, bf1 + 9, clamp_lo, clamp_hi); addsub_neon(bf1[7], bf1[8], bf1 + 7, bf1 + 8, clamp_lo, clamp_hi); temp1 = half_btf_neon_mode10_r(&cospi[32], &bf1[20], &cospi[32], &bf1[27], v_bit, rnding); bf1[27] = half_btf_neon_r(&cospi[32], &bf1[20], &cospi[32], &bf1[27], v_bit, rnding); bf1[20] = temp1; temp2 = half_btf_neon_mode10_r(&cospi[32], &bf1[21], &cospi[32], &bf1[26], v_bit, rnding); bf1[26] = half_btf_neon_r(&cospi[32], &bf1[21], &cospi[32], &bf1[26], v_bit, rnding); bf1[21] = temp2; temp1 = half_btf_neon_mode10_r(&cospi[32], &bf1[22], &cospi[32], &bf1[25], v_bit, rnding); bf1[25] = half_btf_neon_r(&cospi[32], &bf1[22], &cospi[32], &bf1[25], v_bit, rnding); bf1[22] = temp1; temp2 = half_btf_neon_mode10_r(&cospi[32], &bf1[23], &cospi[32], &bf1[24], v_bit, rnding); bf1[24] = half_btf_neon_r(&cospi[32], &bf1[23], &cospi[32], &bf1[24], v_bit, rnding); bf1[23] = temp2; } static inline void idct32_stage9_neon(int32x4_t *bf1, int32x4_t *out, const int do_cols, const int bd, const int out_shift, const int32x4_t *clamp_lo, const int32x4_t *clamp_hi) { addsub_neon(bf1[0], bf1[31], out + 0, out + 31, clamp_lo, clamp_hi); addsub_neon(bf1[1], bf1[30], out + 1, out + 30, clamp_lo, clamp_hi); addsub_neon(bf1[2], bf1[29], out + 2, out + 29, clamp_lo, clamp_hi); addsub_neon(bf1[3], bf1[28], out + 3, out + 28, clamp_lo, clamp_hi); addsub_neon(bf1[4], bf1[27], out + 4, out + 27, clamp_lo, clamp_hi); addsub_neon(bf1[5], bf1[26], out + 5, out + 26, clamp_lo, clamp_hi); addsub_neon(bf1[6], bf1[25], out + 6, out + 25, clamp_lo, clamp_hi); addsub_neon(bf1[7], bf1[24], out + 7, out + 24, clamp_lo, clamp_hi); addsub_neon(bf1[8], bf1[23], out + 8, out + 23, clamp_lo, clamp_hi); addsub_neon(bf1[9], bf1[22], out + 9, out + 22, clamp_lo, clamp_hi); addsub_neon(bf1[10], bf1[21], out + 10, out + 21, clamp_lo, clamp_hi); addsub_neon(bf1[11], bf1[20], out + 11, out + 20, clamp_lo, clamp_hi); addsub_neon(bf1[12], bf1[19], out + 12, out + 19, clamp_lo, clamp_hi); addsub_neon(bf1[13], bf1[18], out + 13, out + 18, clamp_lo, clamp_hi); addsub_neon(bf1[14], bf1[17], out + 14, out + 17, clamp_lo, clamp_hi); addsub_neon(bf1[15], bf1[16], out + 15, out + 16, clamp_lo, clamp_hi); if (!do_cols) { const int log_range_out = AOMMAX(16, bd + 6); const int32x4_t clamp_lo_out = vdupq_n_s32(-(1 << (log_range_out - 1))); const int32x4_t clamp_hi_out = vdupq_n_s32((1 << (log_range_out - 1)) - 1); for (int i = 0; i < 32; i += 8) { round_shift_4x4(out + i, out_shift); round_shift_4x4(out + i + 4, out_shift); } highbd_clamp_s32_neon(out, out, &clamp_lo_out, &clamp_hi_out, 32); } } static void neg_shift_neon(const int32x4_t *in0, const int32x4_t *in1, int32x4_t *out0, int32x4_t *out1, const int32x4_t *clamp_lo, const int32x4_t *clamp_hi, const int32x4_t *v_shift, int32x4_t *offset) { int32x4_t a0 = vaddq_s32(*offset, *in0); int32x4_t a1 = vsubq_s32(*offset, *in1); a0 = vshlq_s32(a0, *v_shift); a1 = vshlq_s32(a1, *v_shift); a0 = vmaxq_s32(a0, *clamp_lo); a0 = vminq_s32(a0, *clamp_hi); a1 = vmaxq_s32(a1, *clamp_lo); a1 = vminq_s32(a1, *clamp_hi); *out0 = a0; *out1 = a1; } static void idct4x4_neon(int32x4_t *in, int32x4_t *out, int bit, int do_cols, int bd, int out_shift) { const int32_t *cospi = cospi_arr(bit); int log_range = AOMMAX(16, bd + (do_cols ? 6 : 8)); int32x4_t clamp_lo = vdupq_n_s32(-(1 << (log_range - 1))); int32x4_t clamp_hi = vdupq_n_s32((1 << (log_range - 1)) - 1); int32x4_t rnding = vdupq_n_s32(1 << (bit - 1)); int32x4_t u0, u1, u2, u3; int32x4_t v0, v1, v2, v3, x, y; // Stage 0-1-2 u0 = in[0]; u1 = in[1]; u2 = in[2]; u3 = in[3]; const int32x4_t v_bit = vdupq_n_s32(-bit); x = vmlaq_n_s32(rnding, u0, cospi[32]); y = vmulq_n_s32(u2, cospi[32]); v0 = vaddq_s32(x, y); v0 = vshlq_s32(v0, v_bit); v1 = vsubq_s32(x, y); v1 = vshlq_s32(v1, v_bit); x = vmlaq_n_s32(rnding, u1, cospi[48]); v2 = vmlsq_n_s32(x, u3, cospi[16]); v2 = vshlq_s32(v2, v_bit); x = vmlaq_n_s32(rnding, u1, cospi[16]); v3 = vmlaq_n_s32(x, u3, cospi[48]); v3 = vshlq_s32(v3, v_bit); // Stage 3 addsub_neon(v0, v3, out + 0, out + 3, &clamp_lo, &clamp_hi); addsub_neon(v1, v2, out + 1, out + 2, &clamp_lo, &clamp_hi); if (!do_cols) { log_range = AOMMAX(16, bd + 6); clamp_lo = vdupq_n_s32(-(1 << (log_range - 1))); clamp_hi = vdupq_n_s32((1 << (log_range - 1)) - 1); const int32x4_t v_shift = vdupq_n_s32(-out_shift); shift_and_clamp_neon(out + 0, out + 3, &clamp_lo, &clamp_hi, &v_shift); shift_and_clamp_neon(out + 1, out + 2, &clamp_lo, &clamp_hi, &v_shift); } } static void iadst4x4_neon(int32x4_t *in, int32x4_t *out, int bit, int do_cols, int bd, int out_shift) { const int32_t *sinpi = sinpi_arr(bit); const int32x4_t zero = vdupq_n_s32(0); int64x2_t rnding = vdupq_n_s64(1ll << (bit + 4 - 1)); const int32x2_t mul = vdup_n_s32(1 << 4); int32x4_t t; int32x4_t s0, s1, s2, s3, s4, s5, s6, s7; int32x4_t x0, x1, x2, x3; int32x4_t u0, u1, u2, u3; x0 = in[0]; x1 = in[1]; x2 = in[2]; x3 = in[3]; s0 = vmulq_n_s32(x0, sinpi[1]); s1 = vmulq_n_s32(x0, sinpi[2]); s2 = vmulq_n_s32(x1, sinpi[3]); s3 = vmulq_n_s32(x2, sinpi[4]); s4 = vmulq_n_s32(x2, sinpi[1]); s5 = vmulq_n_s32(x3, sinpi[2]); s6 = vmulq_n_s32(x3, sinpi[4]); t = vsubq_s32(x0, x2); s7 = vaddq_s32(t, x3); t = vaddq_s32(s0, s3); s0 = vaddq_s32(t, s5); t = vsubq_s32(s1, s4); s1 = vsubq_s32(t, s6); s3 = s2; s2 = vmulq_n_s32(s7, sinpi[3]); u0 = vaddq_s32(s0, s3); u1 = vaddq_s32(s1, s3); u2 = s2; t = vaddq_s32(s0, s1); u3 = vsubq_s32(t, s3); // u0 int32x4x2_t u0x; u0x.val[0] = vreinterpretq_s32_s64( vmull_s32(vmovn_s64(vreinterpretq_s64_s32(u0)), mul)); u0x.val[0] = vreinterpretq_s32_s64( vaddq_s64(vreinterpretq_s64_s32(u0x.val[0]), rnding)); u0 = vextq_s32(u0, zero, 1); u0x.val[1] = vreinterpretq_s32_s64( vmull_s32(vmovn_s64(vreinterpretq_s64_s32(u0)), mul)); u0x.val[1] = vreinterpretq_s32_s64( vaddq_s64(vreinterpretq_s64_s32(u0x.val[1]), rnding)); u0x.val[0] = vreinterpretq_s32_s16(vextq_s16( vreinterpretq_s16_s32(u0x.val[0]), vreinterpretq_s16_s32(zero), 1)); u0x.val[1] = vreinterpretq_s32_s16(vextq_s16( vreinterpretq_s16_s32(u0x.val[1]), vreinterpretq_s16_s32(zero), 1)); u0x = vzipq_s32(u0x.val[0], u0x.val[1]); #if AOM_ARCH_AARCH64 u0 = vreinterpretq_s32_s64(vzip1q_s64(vreinterpretq_s64_s32(u0x.val[0]), vreinterpretq_s64_s32(u0x.val[1]))); #else u0 = vcombine_s32(vget_low_s32(u0x.val[0]), vget_low_s32(u0x.val[1])); #endif // AOM_ARCH_AARCH64 // u1 int32x4x2_t u1x; u1x.val[0] = vreinterpretq_s32_s64( vmull_s32(vmovn_s64(vreinterpretq_s64_s32(u1)), mul)); u1x.val[0] = vreinterpretq_s32_s64( vaddq_s64(vreinterpretq_s64_s32(u1x.val[0]), rnding)); u1 = vextq_s32(u1, zero, 1); u1x.val[1] = vreinterpretq_s32_s64( vmull_s32(vmovn_s64(vreinterpretq_s64_s32(u1)), mul)); u1x.val[1] = vreinterpretq_s32_s64( vaddq_s64(vreinterpretq_s64_s32(u1x.val[1]), rnding)); u1x.val[0] = vreinterpretq_s32_s16(vextq_s16( vreinterpretq_s16_s32(u1x.val[0]), vreinterpretq_s16_s32(zero), 1)); u1x.val[1] = vreinterpretq_s32_s16(vextq_s16( vreinterpretq_s16_s32(u1x.val[1]), vreinterpretq_s16_s32(zero), 1)); u1x = vzipq_s32(u1x.val[0], u1x.val[1]); #if AOM_ARCH_AARCH64 u1 = vreinterpretq_s32_s64(vzip1q_s64(vreinterpretq_s64_s32(u1x.val[0]), vreinterpretq_s64_s32(u1x.val[1]))); #else u1 = vcombine_s32(vget_low_s32(u1x.val[0]), vget_low_s32(u1x.val[1])); #endif // AOM_ARCH_AARCH64 // u2 int32x4x2_t u2x; u2x.val[0] = vreinterpretq_s32_s64( vmull_s32(vmovn_s64(vreinterpretq_s64_s32(u2)), mul)); u2x.val[0] = vreinterpretq_s32_s64( vaddq_s64(vreinterpretq_s64_s32(u2x.val[0]), rnding)); u2 = vextq_s32(u2, zero, 1); u2x.val[1] = vreinterpretq_s32_s64( vmull_s32(vmovn_s64(vreinterpretq_s64_s32(u2)), mul)); u2x.val[1] = vreinterpretq_s32_s64( vaddq_s64(vreinterpretq_s64_s32(u2x.val[1]), rnding)); u2x.val[0] = vreinterpretq_s32_s16(vextq_s16( vreinterpretq_s16_s32(u2x.val[0]), vreinterpretq_s16_s32(zero), 1)); u2x.val[1] = vreinterpretq_s32_s16(vextq_s16( vreinterpretq_s16_s32(u2x.val[1]), vreinterpretq_s16_s32(zero), 1)); u2x = vzipq_s32(u2x.val[0], u2x.val[1]); #if AOM_ARCH_AARCH64 u2 = vreinterpretq_s32_s64(vzip1q_s64(vreinterpretq_s64_s32(u2x.val[0]), vreinterpretq_s64_s32(u2x.val[1]))); #else u2 = vcombine_s32(vget_low_s32(u2x.val[0]), vget_low_s32(u2x.val[1])); #endif // AOM_ARCH_AARCH64 // u3 int32x4x2_t u3x; u3x.val[0] = vreinterpretq_s32_s64( vmull_s32(vmovn_s64(vreinterpretq_s64_s32(u3)), mul)); u3x.val[0] = vreinterpretq_s32_s64( vaddq_s64(vreinterpretq_s64_s32(u3x.val[0]), rnding)); u3 = vextq_s32(u3, zero, 1); u3x.val[1] = vreinterpretq_s32_s64( vmull_s32(vmovn_s64(vreinterpretq_s64_s32(u3)), mul)); u3x.val[1] = vreinterpretq_s32_s64( vaddq_s64(vreinterpretq_s64_s32(u3x.val[1]), rnding)); u3x.val[0] = vreinterpretq_s32_s16(vextq_s16( vreinterpretq_s16_s32(u3x.val[0]), vreinterpretq_s16_s32(zero), 1)); u3x.val[1] = vreinterpretq_s32_s16(vextq_s16( vreinterpretq_s16_s32(u3x.val[1]), vreinterpretq_s16_s32(zero), 1)); u3x = vzipq_s32(u3x.val[0], u3x.val[1]); #if AOM_ARCH_AARCH64 u3 = vreinterpretq_s32_s64(vzip1q_s64(vreinterpretq_s64_s32(u3x.val[0]), vreinterpretq_s64_s32(u3x.val[1]))); #else u3 = vcombine_s32(vget_low_s32(u3x.val[0]), vget_low_s32(u3x.val[1])); #endif // AOM_ARCH_AARCH64 out[0] = u0; out[1] = u1; out[2] = u2; out[3] = u3; if (!do_cols) { const int log_range = AOMMAX(16, bd + 6); const int32x4_t clamp_lo = vdupq_n_s32(-(1 << (log_range - 1))); const int32x4_t clamp_hi = vdupq_n_s32((1 << (log_range - 1)) - 1); round_shift_4x4(out, out_shift); highbd_clamp_s32_neon(out, out, &clamp_lo, &clamp_hi, 4); } } static void write_buffer_4x4(int32x4_t *in, uint16_t *output, int stride, int fliplr, int flipud, int shift, int bd) { uint32x4_t u0, u1, u2, u3; uint16x4_t v0, v1, v2, v3; round_shift_4x4(in, shift); v0 = vld1_u16(output + 0 * stride); v1 = vld1_u16(output + 1 * stride); v2 = vld1_u16(output + 2 * stride); v3 = vld1_u16(output + 3 * stride); if (fliplr) { u0 = vrev64q_u32(vreinterpretq_u32_s32(in[0])); in[0] = vreinterpretq_s32_u32(vextq_u32(u0, u0, 2)); u0 = vrev64q_u32(vreinterpretq_u32_s32(in[1])); in[1] = vreinterpretq_s32_u32(vextq_u32(u0, u0, 2)); u0 = vrev64q_u32(vreinterpretq_u32_s32(in[2])); in[2] = vreinterpretq_s32_u32(vextq_u32(u0, u0, 2)); u0 = vrev64q_u32(vreinterpretq_u32_s32(in[3])); in[3] = vreinterpretq_s32_u32(vextq_u32(u0, u0, 2)); } if (flipud) { u0 = vaddw_u16(vreinterpretq_u32_s32(in[3]), v0); u1 = vaddw_u16(vreinterpretq_u32_s32(in[2]), v1); u2 = vaddw_u16(vreinterpretq_u32_s32(in[1]), v2); u3 = vaddw_u16(vreinterpretq_u32_s32(in[0]), v3); } else { u0 = vaddw_u16(vreinterpretq_u32_s32(in[0]), v0); u1 = vaddw_u16(vreinterpretq_u32_s32(in[1]), v1); u2 = vaddw_u16(vreinterpretq_u32_s32(in[2]), v2); u3 = vaddw_u16(vreinterpretq_u32_s32(in[3]), v3); } uint16x8_t u4 = vcombine_u16(vqmovn_u32(u0), vqmovn_u32(u1)); uint16x8_t u5 = vcombine_u16(vqmovn_u32(u2), vqmovn_u32(u3)); const uint16x8_t vmin = vdupq_n_u16(0); const uint16x8_t vmax = vdupq_n_u16((1 << bd) - 1); u4 = highbd_clamp_u16(&u4, &vmin, &vmax); u5 = highbd_clamp_u16(&u5, &vmin, &vmax); vst1_u16(output + 0 * stride, vget_low_u16(u4)); vst1_u16(output + 1 * stride, vget_high_u16(u4)); vst1_u16(output + 2 * stride, vget_low_u16(u5)); vst1_u16(output + 3 * stride, vget_high_u16(u5)); } static void iidentity4_neon(int32x4_t *in, int32x4_t *out, int bit, int do_cols, int bd, int out_shift) { (void)bit; int32x4_t zero = vdupq_n_s32(0); int32x2_t fact = vdup_n_s32(NewSqrt2); int32x4x2_t a0; const int64x2_t rnding = vdupq_n_s64(1 << (NewSqrt2Bits - 1)); for (int i = 0; i < 4; i++) { a0.val[0] = vreinterpretq_s32_s64( vmlal_s32(rnding, vmovn_s64(vreinterpretq_s64_s32(in[i])), fact)); a0.val[0] = vreinterpretq_s32_s64( vshrq_n_s64(vreinterpretq_s64_s32(a0.val[0]), NewSqrt2Bits)); a0.val[1] = vextq_s32(in[i], zero, 1); a0.val[1] = vreinterpretq_s32_s64( vmlal_s32(rnding, vmovn_s64(vreinterpretq_s64_s32(a0.val[1])), fact)); a0.val[1] = vreinterpretq_s32_s64( vshrq_n_s64(vreinterpretq_s64_s32(a0.val[1]), NewSqrt2Bits)); a0 = vzipq_s32(a0.val[0], a0.val[1]); #if AOM_ARCH_AARCH64 out[i] = vreinterpretq_s32_s64(vzip1q_s64( vreinterpretq_s64_s32(a0.val[0]), vreinterpretq_s64_s32(a0.val[1]))); #else out[i] = vextq_s32(vextq_s32(a0.val[0], a0.val[0], 2), a0.val[1], 2); #endif } if (!do_cols) { const int log_range = AOMMAX(16, bd + 6); const int32x4_t clamp_lo = vdupq_n_s32(-(1 << (log_range - 1))); const int32x4_t clamp_hi = vdupq_n_s32((1 << (log_range - 1)) - 1); round_shift_4x4(out, out_shift); highbd_clamp_s32_neon(out, out, &clamp_lo, &clamp_hi, 4); } } void av1_inv_txfm2d_add_4x4_neon(const int32_t *input, uint16_t *output, int stride, TX_TYPE tx_type, int bd) { int32x4_t in[4]; const int8_t *shift = av1_inv_txfm_shift_ls[TX_4X4]; switch (tx_type) { case DCT_DCT: load_buffer_4x4(input, in); idct4x4_neon(in, in, INV_COS_BIT, 0, bd, 0); transpose_4x4(in, in); idct4x4_neon(in, in, INV_COS_BIT, 1, bd, 0); write_buffer_4x4(in, output, stride, 0, 0, -shift[1], bd); break; case ADST_DCT: load_buffer_4x4(input, in); idct4x4_neon(in, in, INV_COS_BIT, 0, bd, 0); transpose_4x4(in, in); iadst4x4_neon(in, in, INV_COS_BIT, 1, bd, 0); write_buffer_4x4(in, output, stride, 0, 0, -shift[1], bd); break; case DCT_ADST: load_buffer_4x4(input, in); iadst4x4_neon(in, in, INV_COS_BIT, 0, bd, 0); transpose_4x4(in, in); idct4x4_neon(in, in, INV_COS_BIT, 1, bd, 0); write_buffer_4x4(in, output, stride, 0, 0, -shift[1], bd); break; case ADST_ADST: load_buffer_4x4(input, in); iadst4x4_neon(in, in, INV_COS_BIT, 0, bd, 0); transpose_4x4(in, in); iadst4x4_neon(in, in, INV_COS_BIT, 1, bd, 0); write_buffer_4x4(in, output, stride, 0, 0, -shift[1], bd); break; case FLIPADST_DCT: load_buffer_4x4(input, in); idct4x4_neon(in, in, INV_COS_BIT, 0, bd, 0); transpose_4x4(in, in); iadst4x4_neon(in, in, INV_COS_BIT, 1, bd, 0); write_buffer_4x4(in, output, stride, 0, 1, -shift[1], bd); break; case DCT_FLIPADST: load_buffer_4x4(input, in); iadst4x4_neon(in, in, INV_COS_BIT, 0, bd, 0); transpose_4x4(in, in); idct4x4_neon(in, in, INV_COS_BIT, 1, bd, 0); write_buffer_4x4(in, output, stride, 1, 0, -shift[1], bd); break; case FLIPADST_FLIPADST: load_buffer_4x4(input, in); iadst4x4_neon(in, in, INV_COS_BIT, 0, bd, 0); transpose_4x4(in, in); iadst4x4_neon(in, in, INV_COS_BIT, 1, bd, 0); write_buffer_4x4(in, output, stride, 1, 1, -shift[1], bd); break; case ADST_FLIPADST: load_buffer_4x4(input, in); iadst4x4_neon(in, in, INV_COS_BIT, 0, bd, 0); transpose_4x4(in, in); iadst4x4_neon(in, in, INV_COS_BIT, 1, bd, 0); write_buffer_4x4(in, output, stride, 1, 0, -shift[1], bd); break; case FLIPADST_ADST: load_buffer_4x4(input, in); iadst4x4_neon(in, in, INV_COS_BIT, 0, bd, 0); transpose_4x4(in, in); iadst4x4_neon(in, in, INV_COS_BIT, 1, bd, 0); write_buffer_4x4(in, output, stride, 0, 1, -shift[1], bd); break; case IDTX: load_buffer_4x4(input, in); iidentity4_neon(in, in, INV_COS_BIT, 0, bd, 0); transpose_4x4(in, in); iidentity4_neon(in, in, INV_COS_BIT, 1, bd, 0); write_buffer_4x4(in, output, stride, 0, 0, -shift[1], bd); break; case V_DCT: load_buffer_4x4(input, in); iidentity4_neon(in, in, INV_COS_BIT, 0, bd, 0); transpose_4x4(in, in); idct4x4_neon(in, in, INV_COS_BIT, 1, bd, 0); write_buffer_4x4(in, output, stride, 0, 0, -shift[1], bd); break; case H_DCT: load_buffer_4x4(input, in); idct4x4_neon(in, in, INV_COS_BIT, 0, bd, 0); transpose_4x4(in, in); iidentity4_neon(in, in, INV_COS_BIT, 1, bd, 0); write_buffer_4x4(in, output, stride, 0, 0, -shift[1], bd); break; case V_ADST: load_buffer_4x4(input, in); iidentity4_neon(in, in, INV_COS_BIT, 0, bd, 0); transpose_4x4(in, in); iadst4x4_neon(in, in, INV_COS_BIT, 1, bd, 0); write_buffer_4x4(in, output, stride, 0, 0, -shift[1], bd); break; case H_ADST: load_buffer_4x4(input, in); iadst4x4_neon(in, in, INV_COS_BIT, 0, bd, 0); transpose_4x4(in, in); iidentity4_neon(in, in, INV_COS_BIT, 1, bd, 0); write_buffer_4x4(in, output, stride, 0, 0, -shift[1], bd); break; case V_FLIPADST: load_buffer_4x4(input, in); iidentity4_neon(in, in, INV_COS_BIT, 0, bd, 0); transpose_4x4(in, in); iadst4x4_neon(in, in, INV_COS_BIT, 1, bd, 0); write_buffer_4x4(in, output, stride, 0, 1, -shift[1], bd); break; case H_FLIPADST: load_buffer_4x4(input, in); iadst4x4_neon(in, in, INV_COS_BIT, 0, bd, 0); transpose_4x4(in, in); iidentity4_neon(in, in, INV_COS_BIT, 1, bd, 0); write_buffer_4x4(in, output, stride, 1, 0, -shift[1], bd); break; default: assert(0); } } // 8x8 static void load_buffer_8x8(const int32_t *coeff, int32x4_t *in) { in[0] = vld1q_s32(coeff + 0); in[1] = vld1q_s32(coeff + 4); in[2] = vld1q_s32(coeff + 8); in[3] = vld1q_s32(coeff + 12); in[4] = vld1q_s32(coeff + 16); in[5] = vld1q_s32(coeff + 20); in[6] = vld1q_s32(coeff + 24); in[7] = vld1q_s32(coeff + 28); in[8] = vld1q_s32(coeff + 32); in[9] = vld1q_s32(coeff + 36); in[10] = vld1q_s32(coeff + 40); in[11] = vld1q_s32(coeff + 44); in[12] = vld1q_s32(coeff + 48); in[13] = vld1q_s32(coeff + 52); in[14] = vld1q_s32(coeff + 56); in[15] = vld1q_s32(coeff + 60); } static void idct8x8_neon(int32x4_t *in, int32x4_t *out, int bit, int do_cols, int bd, int out_shift) { const int32_t *cospi = cospi_arr(bit); const int log_range = AOMMAX(16, bd + (do_cols ? 6 : 8)); const int32x4_t clamp_lo = vdupq_n_s32(-(1 << (log_range - 1))); const int32x4_t clamp_hi = vdupq_n_s32((1 << (log_range - 1)) - 1); int32x4_t u0, u1, u2, u3, u4, u5, u6, u7; int32x4_t v0, v1, v2, v3, v4, v5, v6, v7; int32x4_t x, y; int col; const int32x4_t rnding = vdupq_n_s32(1 << (bit - 1)); const int32x4_t v_bit = vdupq_n_s32(-bit); // Note: // Even column: 0, 2, ..., 14 // Odd column: 1, 3, ..., 15 // one even column plus one odd column constructs one row (8 coeffs) // total we have 8 rows (8x8). for (col = 0; col < 2; ++col) { // stage 0 // stage 1 // stage 2 u0 = in[0 * 2 + col]; u1 = in[4 * 2 + col]; u2 = in[2 * 2 + col]; u3 = in[6 * 2 + col]; x = vmulq_n_s32(in[1 * 2 + col], cospi[56]); u4 = vmlaq_n_s32(x, in[7 * 2 + col], -cospi[8]); u4 = vaddq_s32(u4, rnding); u4 = vshlq_s32(u4, v_bit); x = vmulq_n_s32(in[1 * 2 + col], cospi[8]); u7 = vmlaq_n_s32(x, in[7 * 2 + col], cospi[56]); u7 = vaddq_s32(u7, rnding); u7 = vshlq_s32(u7, v_bit); x = vmulq_n_s32(in[5 * 2 + col], cospi[24]); u5 = vmlaq_n_s32(x, in[3 * 2 + col], -cospi[40]); u5 = vaddq_s32(u5, rnding); u5 = vshlq_s32(u5, v_bit); x = vmulq_n_s32(in[5 * 2 + col], cospi[40]); u6 = vmlaq_n_s32(x, in[3 * 2 + col], cospi[24]); u6 = vaddq_s32(u6, rnding); u6 = vshlq_s32(u6, v_bit); // stage 3 x = vmulq_n_s32(u0, cospi[32]); y = vmulq_n_s32(u1, cospi[32]); v0 = vaddq_s32(x, y); v0 = vaddq_s32(v0, rnding); v0 = vshlq_s32(v0, v_bit); v1 = vsubq_s32(x, y); v1 = vaddq_s32(v1, rnding); v1 = vshlq_s32(v1, v_bit); x = vmulq_n_s32(u2, cospi[48]); v2 = vmlaq_n_s32(x, u3, -cospi[16]); v2 = vaddq_s32(v2, rnding); v2 = vshlq_s32(v2, v_bit); x = vmulq_n_s32(u2, cospi[16]); v3 = vmlaq_n_s32(x, u3, cospi[48]); v3 = vaddq_s32(v3, rnding); v3 = vshlq_s32(v3, v_bit); addsub_neon(u4, u5, &v4, &v5, &clamp_lo, &clamp_hi); addsub_neon(u7, u6, &v7, &v6, &clamp_lo, &clamp_hi); // stage 4 addsub_neon(v0, v3, &u0, &u3, &clamp_lo, &clamp_hi); addsub_neon(v1, v2, &u1, &u2, &clamp_lo, &clamp_hi); u4 = v4; u7 = v7; x = vmulq_n_s32(v5, cospi[32]); y = vmulq_n_s32(v6, cospi[32]); u6 = vaddq_s32(y, x); u6 = vaddq_s32(u6, rnding); u6 = vshlq_s32(u6, v_bit); u5 = vsubq_s32(y, x); u5 = vaddq_s32(u5, rnding); u5 = vshlq_s32(u5, v_bit); // stage 5 addsub_neon(u0, u7, out + 0 * 2 + col, out + 7 * 2 + col, &clamp_lo, &clamp_hi); addsub_neon(u1, u6, out + 1 * 2 + col, out + 6 * 2 + col, &clamp_lo, &clamp_hi); addsub_neon(u2, u5, out + 2 * 2 + col, out + 5 * 2 + col, &clamp_lo, &clamp_hi); addsub_neon(u3, u4, out + 3 * 2 + col, out + 4 * 2 + col, &clamp_lo, &clamp_hi); } if (!do_cols) { const int log_range_out = AOMMAX(16, bd + 6); const int32x4_t clamp_lo_out = vdupq_n_s32(-(1 << (log_range_out - 1))); const int32x4_t clamp_hi_out = vdupq_n_s32((1 << (log_range_out - 1)) - 1); round_shift_8x8(out, out_shift); highbd_clamp_s32_neon(out, out, &clamp_lo_out, &clamp_hi_out, 16); } } static void iadst8x8_neon(int32x4_t *in, int32x4_t *out, int bit, int do_cols, int bd, int out_shift) { const int32_t *cospi = cospi_arr(bit); const int32x4_t kZero = vdupq_n_s32(0); const int log_range = AOMMAX(16, bd + (do_cols ? 6 : 8)); const int32x4_t clamp_lo = vdupq_n_s32(-(1 << (log_range - 1))); const int32x4_t clamp_hi = vdupq_n_s32((1 << (log_range - 1)) - 1); int32x4_t u[8], v[8], x; const int32x4_t v_bit = vdupq_n_s32(-bit); const int32x4_t rnding = vdupq_n_s32(1 << (bit - 1)); // stage 0-1-2 // (1) u[0] = vmlaq_n_s32(rnding, in[14], cospi[4]); u[0] = vmlaq_n_s32(u[0], in[0], cospi[60]); u[0] = vshlq_s32(u[0], v_bit); u[1] = vmlaq_n_s32(rnding, in[14], cospi[60]); u[1] = vmlsq_n_s32(u[1], in[0], cospi[4]); u[1] = vshlq_s32(u[1], v_bit); // (2) u[2] = vmlaq_n_s32(rnding, in[10], cospi[20]); u[2] = vmlaq_n_s32(u[2], in[4], cospi[44]); u[2] = vshlq_s32(u[2], v_bit); u[3] = vmlaq_n_s32(rnding, in[10], cospi[44]); u[3] = vmlsq_n_s32(u[3], in[4], cospi[20]); u[3] = vshlq_s32(u[3], v_bit); // (3) u[4] = vmlaq_n_s32(rnding, in[6], cospi[36]); u[4] = vmlaq_n_s32(u[4], in[8], cospi[28]); u[4] = vshlq_s32(u[4], v_bit); u[5] = vmlaq_n_s32(rnding, in[6], cospi[28]); u[5] = vmlsq_n_s32(u[5], in[8], cospi[36]); u[5] = vshlq_s32(u[5], v_bit); // (4) u[6] = vmlaq_n_s32(rnding, in[2], cospi[52]); u[6] = vmlaq_n_s32(u[6], in[12], cospi[12]); u[6] = vshlq_s32(u[6], v_bit); u[7] = vmlaq_n_s32(rnding, in[2], cospi[12]); u[7] = vmlsq_n_s32(u[7], in[12], cospi[52]); u[7] = vshlq_s32(u[7], v_bit); // stage 3 addsub_neon(u[0], u[4], &v[0], &v[4], &clamp_lo, &clamp_hi); addsub_neon(u[1], u[5], &v[1], &v[5], &clamp_lo, &clamp_hi); addsub_neon(u[2], u[6], &v[2], &v[6], &clamp_lo, &clamp_hi); addsub_neon(u[3], u[7], &v[3], &v[7], &clamp_lo, &clamp_hi); // stage 4 u[0] = v[0]; u[1] = v[1]; u[2] = v[2]; u[3] = v[3]; u[4] = vmlaq_n_s32(rnding, v[4], cospi[16]); u[4] = vmlaq_n_s32(u[4], v[5], cospi[48]); u[4] = vshlq_s32(u[4], v_bit); u[5] = vmlaq_n_s32(rnding, v[4], cospi[48]); u[5] = vmlsq_n_s32(u[5], v[5], cospi[16]); u[5] = vshlq_s32(u[5], v_bit); u[6] = vmlaq_n_s32(rnding, v[7], cospi[16]); u[6] = vmlsq_n_s32(u[6], v[6], cospi[48]); u[6] = vshlq_s32(u[6], v_bit); u[7] = vmlaq_n_s32(rnding, v[7], cospi[48]); u[7] = vmlaq_n_s32(u[7], v[6], cospi[16]); u[7] = vshlq_s32(u[7], v_bit); // stage 5 addsub_neon(u[0], u[2], &v[0], &v[2], &clamp_lo, &clamp_hi); addsub_neon(u[1], u[3], &v[1], &v[3], &clamp_lo, &clamp_hi); addsub_neon(u[4], u[6], &v[4], &v[6], &clamp_lo, &clamp_hi); addsub_neon(u[5], u[7], &v[5], &v[7], &clamp_lo, &clamp_hi); // stage 6 u[0] = v[0]; u[1] = v[1]; u[4] = v[4]; u[5] = v[5]; v[0] = vmlaq_n_s32(rnding, v[2], cospi[32]); x = vmulq_n_s32(v[3], cospi[32]); u[2] = vaddq_s32(v[0], x); u[2] = vshlq_s32(u[2], v_bit); u[3] = vsubq_s32(v[0], x); u[3] = vshlq_s32(u[3], v_bit); v[0] = vmlaq_n_s32(rnding, v[6], cospi[32]); x = vmulq_n_s32(v[7], cospi[32]); u[6] = vaddq_s32(v[0], x); u[6] = vshlq_s32(u[6], v_bit); u[7] = vsubq_s32(v[0], x); u[7] = vshlq_s32(u[7], v_bit); // stage 7 if (do_cols) { out[0] = u[0]; out[2] = vsubq_s32(kZero, u[4]); out[4] = u[6]; out[6] = vsubq_s32(kZero, u[2]); out[8] = u[3]; out[10] = vsubq_s32(kZero, u[7]); out[12] = u[5]; out[14] = vsubq_s32(kZero, u[1]); } else { const int log_range_out = AOMMAX(16, bd + 6); const int32x4_t clamp_lo_out = vdupq_n_s32(-(1 << (log_range_out - 1))); const int32x4_t clamp_hi_out = vdupq_n_s32((1 << (log_range_out - 1)) - 1); const int32x4_t v_shift = vdupq_n_s32(-out_shift); int32x4_t offset = vdupq_n_s32((1 << out_shift) >> 1); neg_shift_neon(&u[0], &u[4], out + 0, out + 2, &clamp_lo_out, &clamp_hi_out, &v_shift, &offset); neg_shift_neon(&u[6], &u[2], out + 4, out + 6, &clamp_lo_out, &clamp_hi_out, &v_shift, &offset); neg_shift_neon(&u[3], &u[7], out + 8, out + 10, &clamp_lo_out, &clamp_hi_out, &v_shift, &offset); neg_shift_neon(&u[5], &u[1], out + 12, out + 14, &clamp_lo_out, &clamp_hi_out, &v_shift, &offset); } // Odd 8 points: 1, 3, ..., 15 // stage 0 // stage 1 // stage 2 // (1) u[0] = vmlaq_n_s32(rnding, in[15], cospi[4]); u[0] = vmlaq_n_s32(u[0], in[1], cospi[60]); u[0] = vshlq_s32(u[0], v_bit); u[1] = vmlaq_n_s32(rnding, in[15], cospi[60]); u[1] = vmlsq_n_s32(u[1], in[1], cospi[4]); u[1] = vshlq_s32(u[1], v_bit); // (2) u[2] = vmlaq_n_s32(rnding, in[11], cospi[20]); u[2] = vmlaq_n_s32(u[2], in[5], cospi[44]); u[2] = vshlq_s32(u[2], v_bit); u[3] = vmlaq_n_s32(rnding, in[11], cospi[44]); u[3] = vmlsq_n_s32(u[3], in[5], cospi[20]); u[3] = vshlq_s32(u[3], v_bit); // (3) u[4] = vmlaq_n_s32(rnding, in[7], cospi[36]); u[4] = vmlaq_n_s32(u[4], in[9], cospi[28]); u[4] = vshlq_s32(u[4], v_bit); u[5] = vmlaq_n_s32(rnding, in[7], cospi[28]); u[5] = vmlsq_n_s32(u[5], in[9], cospi[36]); u[5] = vshlq_s32(u[5], v_bit); // (4) u[6] = vmlaq_n_s32(rnding, in[3], cospi[52]); u[6] = vmlaq_n_s32(u[6], in[13], cospi[12]); u[6] = vshlq_s32(u[6], v_bit); u[7] = vmlaq_n_s32(rnding, in[3], cospi[12]); u[7] = vmlsq_n_s32(u[7], in[13], cospi[52]); u[7] = vshlq_s32(u[7], v_bit); // stage 3 addsub_neon(u[0], u[4], &v[0], &v[4], &clamp_lo, &clamp_hi); addsub_neon(u[1], u[5], &v[1], &v[5], &clamp_lo, &clamp_hi); addsub_neon(u[2], u[6], &v[2], &v[6], &clamp_lo, &clamp_hi); addsub_neon(u[3], u[7], &v[3], &v[7], &clamp_lo, &clamp_hi); // stage 4 u[0] = v[0]; u[1] = v[1]; u[2] = v[2]; u[3] = v[3]; u[4] = vmlaq_n_s32(rnding, v[4], cospi[16]); u[4] = vmlaq_n_s32(u[4], v[5], cospi[48]); u[4] = vshlq_s32(u[4], v_bit); u[5] = vmlaq_n_s32(rnding, v[4], cospi[48]); u[5] = vmlsq_n_s32(u[5], v[5], cospi[16]); u[5] = vshlq_s32(u[5], v_bit); u[6] = vmlaq_n_s32(rnding, v[7], cospi[16]); u[6] = vmlsq_n_s32(u[6], v[6], cospi[48]); u[6] = vshlq_s32(u[6], v_bit); u[7] = vmlaq_n_s32(rnding, v[6], cospi[16]); u[7] = vmlaq_n_s32(u[7], v[7], cospi[48]); u[7] = vshlq_s32(u[7], v_bit); // stage 5 addsub_neon(u[0], u[2], &v[0], &v[2], &clamp_lo, &clamp_hi); addsub_neon(u[1], u[3], &v[1], &v[3], &clamp_lo, &clamp_hi); addsub_neon(u[4], u[6], &v[4], &v[6], &clamp_lo, &clamp_hi); addsub_neon(u[5], u[7], &v[5], &v[7], &clamp_lo, &clamp_hi); // stage 6 u[0] = v[0]; u[1] = v[1]; u[4] = v[4]; u[5] = v[5]; v[0] = vmlaq_n_s32(rnding, v[2], cospi[32]); x = vmulq_n_s32(v[3], cospi[32]); u[2] = vaddq_s32(v[0], x); u[2] = vshlq_s32(u[2], v_bit); u[3] = vsubq_s32(v[0], x); u[3] = vshlq_s32(u[3], v_bit); v[0] = vmlaq_n_s32(rnding, v[6], cospi[32]); x = vmulq_n_s32(v[7], cospi[32]); u[6] = vaddq_s32(v[0], x); u[6] = vshlq_s32(u[6], v_bit); u[7] = vsubq_s32(v[0], x); u[7] = vshlq_s32(u[7], v_bit); // stage 7 if (do_cols) { out[1] = u[0]; out[3] = vsubq_s32(kZero, u[4]); out[5] = u[6]; out[7] = vsubq_s32(kZero, u[2]); out[9] = u[3]; out[11] = vsubq_s32(kZero, u[7]); out[13] = u[5]; out[15] = vsubq_s32(kZero, u[1]); } else { const int log_range_out = AOMMAX(16, bd + 6); const int32x4_t clamp_lo_out = vdupq_n_s32(-(1 << (log_range_out - 1))); const int32x4_t clamp_hi_out = vdupq_n_s32((1 << (log_range_out - 1)) - 1); const int32x4_t v_shift = vdupq_n_s32(-out_shift); int32x4_t offset = vdupq_n_s32((1 << out_shift) >> 1); neg_shift_neon(&u[0], &u[4], out + 1, out + 3, &clamp_lo_out, &clamp_hi_out, &v_shift, &offset); neg_shift_neon(&u[6], &u[2], out + 5, out + 7, &clamp_lo_out, &clamp_hi_out, &v_shift, &offset); neg_shift_neon(&u[3], &u[7], out + 9, out + 11, &clamp_lo_out, &clamp_hi_out, &v_shift, &offset); neg_shift_neon(&u[5], &u[1], out + 13, out + 15, &clamp_lo_out, &clamp_hi_out, &v_shift, &offset); } } static void iidentity8_neon(int32x4_t *in, int32x4_t *out, int bit, int do_cols, int bd, int out_shift) { (void)bit; out[0] = vaddq_s32(in[0], in[0]); out[1] = vaddq_s32(in[1], in[1]); out[2] = vaddq_s32(in[2], in[2]); out[3] = vaddq_s32(in[3], in[3]); out[4] = vaddq_s32(in[4], in[4]); out[5] = vaddq_s32(in[5], in[5]); out[6] = vaddq_s32(in[6], in[6]); out[7] = vaddq_s32(in[7], in[7]); if (!do_cols) { const int log_range = AOMMAX(16, bd + 6); const int32x4_t clamp_lo = vdupq_n_s32(-(1 << (log_range - 1))); const int32x4_t clamp_hi = vdupq_n_s32((1 << (log_range - 1)) - 1); round_shift_4x4(out, out_shift); round_shift_4x4(out + 4, out_shift); highbd_clamp_s32_neon(out, out, &clamp_lo, &clamp_hi, 8); } } static uint16x8_t get_recon_8x8(const uint16x8_t pred, int32x4_t res_lo, int32x4_t res_hi, int fliplr, int bd) { uint16x8x2_t x; if (fliplr) { res_lo = vrev64q_s32(res_lo); res_lo = vextq_s32(res_lo, res_lo, 2); res_hi = vrev64q_s32(res_hi); res_hi = vextq_s32(res_hi, res_hi, 2); x.val[0] = vreinterpretq_u16_s32( vaddw_s16(res_hi, vreinterpret_s16_u16(vget_low_u16(pred)))); x.val[1] = vreinterpretq_u16_s32( vaddw_s16(res_lo, vreinterpret_s16_u16(vget_high_u16(pred)))); } else { x.val[0] = vreinterpretq_u16_s32( vaddw_s16(res_lo, vreinterpret_s16_u16(vget_low_u16(pred)))); x.val[1] = vreinterpretq_u16_s32( vaddw_s16(res_hi, vreinterpret_s16_u16(vget_high_u16(pred)))); } uint16x8_t x2 = vcombine_u16(vqmovn_u32(vreinterpretq_u32_u16(x.val[0])), vqmovn_u32(vreinterpretq_u32_u16(x.val[1]))); const uint16x8_t vmin = vdupq_n_u16(0); const uint16x8_t vmax = vdupq_n_u16((1 << bd) - 1); return highbd_clamp_u16(&x2, &vmin, &vmax); } static void write_buffer_8x8(int32x4_t *in, uint16_t *output, int stride, int fliplr, int flipud, int shift, int bd) { uint16x8_t u0, u1, u2, u3, u4, u5, u6, u7; uint16x8_t v0, v1, v2, v3, v4, v5, v6, v7; round_shift_8x8(in, shift); v0 = vld1q_u16(output + 0 * stride); v1 = vld1q_u16(output + 1 * stride); v2 = vld1q_u16(output + 2 * stride); v3 = vld1q_u16(output + 3 * stride); v4 = vld1q_u16(output + 4 * stride); v5 = vld1q_u16(output + 5 * stride); v6 = vld1q_u16(output + 6 * stride); v7 = vld1q_u16(output + 7 * stride); if (flipud) { u0 = get_recon_8x8(v0, in[14], in[15], fliplr, bd); u1 = get_recon_8x8(v1, in[12], in[13], fliplr, bd); u2 = get_recon_8x8(v2, in[10], in[11], fliplr, bd); u3 = get_recon_8x8(v3, in[8], in[9], fliplr, bd); u4 = get_recon_8x8(v4, in[6], in[7], fliplr, bd); u5 = get_recon_8x8(v5, in[4], in[5], fliplr, bd); u6 = get_recon_8x8(v6, in[2], in[3], fliplr, bd); u7 = get_recon_8x8(v7, in[0], in[1], fliplr, bd); } else { u0 = get_recon_8x8(v0, in[0], in[1], fliplr, bd); u1 = get_recon_8x8(v1, in[2], in[3], fliplr, bd); u2 = get_recon_8x8(v2, in[4], in[5], fliplr, bd); u3 = get_recon_8x8(v3, in[6], in[7], fliplr, bd); u4 = get_recon_8x8(v4, in[8], in[9], fliplr, bd); u5 = get_recon_8x8(v5, in[10], in[11], fliplr, bd); u6 = get_recon_8x8(v6, in[12], in[13], fliplr, bd); u7 = get_recon_8x8(v7, in[14], in[15], fliplr, bd); } vst1q_u16(output + 0 * stride, u0); vst1q_u16(output + 1 * stride, u1); vst1q_u16(output + 2 * stride, u2); vst1q_u16(output + 3 * stride, u3); vst1q_u16(output + 4 * stride, u4); vst1q_u16(output + 5 * stride, u5); vst1q_u16(output + 6 * stride, u6); vst1q_u16(output + 7 * stride, u7); } void av1_inv_txfm2d_add_8x8_neon(const int32_t *input, uint16_t *output, int stride, TX_TYPE tx_type, int bd) { int32x4_t in[16], out[16]; const int8_t *shift = av1_inv_txfm_shift_ls[TX_8X8]; switch (tx_type) { case DCT_DCT: load_buffer_8x8(input, in); idct8x8_neon(in, out, INV_COS_BIT, 0, bd, -shift[0]); transpose_8x8(out, in); idct8x8_neon(in, out, INV_COS_BIT, 1, bd, 0); write_buffer_8x8(out, output, stride, 0, 0, -shift[1], bd); break; case DCT_ADST: load_buffer_8x8(input, in); iadst8x8_neon(in, out, INV_COS_BIT, 0, bd, -shift[0]); transpose_8x8(out, in); idct8x8_neon(in, out, INV_COS_BIT, 1, bd, 0); write_buffer_8x8(out, output, stride, 0, 0, -shift[1], bd); break; case ADST_DCT: load_buffer_8x8(input, in); idct8x8_neon(in, out, INV_COS_BIT, 0, bd, -shift[0]); transpose_8x8(out, in); iadst8x8_neon(in, out, INV_COS_BIT, 1, bd, 0); write_buffer_8x8(out, output, stride, 0, 0, -shift[1], bd); break; case ADST_ADST: load_buffer_8x8(input, in); iadst8x8_neon(in, out, INV_COS_BIT, 0, bd, -shift[0]); transpose_8x8(out, in); iadst8x8_neon(in, out, INV_COS_BIT, 1, bd, 0); write_buffer_8x8(out, output, stride, 0, 0, -shift[1], bd); break; case FLIPADST_DCT: load_buffer_8x8(input, in); idct8x8_neon(in, out, INV_COS_BIT, 0, bd, -shift[0]); transpose_8x8(out, in); iadst8x8_neon(in, out, INV_COS_BIT, 1, bd, 0); write_buffer_8x8(out, output, stride, 0, 1, -shift[1], bd); break; case DCT_FLIPADST: load_buffer_8x8(input, in); iadst8x8_neon(in, out, INV_COS_BIT, 0, bd, -shift[0]); transpose_8x8(out, in); idct8x8_neon(in, out, INV_COS_BIT, 1, bd, 0); write_buffer_8x8(out, output, stride, 1, 0, -shift[1], bd); break; case ADST_FLIPADST: load_buffer_8x8(input, in); iadst8x8_neon(in, out, INV_COS_BIT, 0, bd, -shift[0]); transpose_8x8(out, in); iadst8x8_neon(in, out, INV_COS_BIT, 1, bd, 0); write_buffer_8x8(out, output, stride, 1, 0, -shift[1], bd); break; case FLIPADST_FLIPADST: load_buffer_8x8(input, in); iadst8x8_neon(in, out, INV_COS_BIT, 0, bd, -shift[0]); transpose_8x8(out, in); iadst8x8_neon(in, out, INV_COS_BIT, 1, bd, 0); write_buffer_8x8(out, output, stride, 1, 1, -shift[1], bd); break; case FLIPADST_ADST: load_buffer_8x8(input, in); iadst8x8_neon(in, out, INV_COS_BIT, 0, bd, -shift[0]); transpose_8x8(out, in); iadst8x8_neon(in, out, INV_COS_BIT, 1, bd, 0); write_buffer_8x8(out, output, stride, 0, 1, -shift[1], bd); break; default: assert(0); } } static void idct8x8_low1_neon(int32x4_t *in, int32x4_t *out, int bit, int do_cols, int bd, int out_shift) { const int32_t *cospi = cospi_arr(bit); const int log_range = AOMMAX(16, bd + (do_cols ? 6 : 8)); int32x4_t clamp_lo = vdupq_n_s32(-(1 << (log_range - 1))); int32x4_t clamp_hi = vdupq_n_s32((1 << (log_range - 1)) - 1); int32x4_t x; const int32x4_t v_bit = vdupq_n_s32(-bit); const int32x4_t rnding = vdupq_n_s32(1 << (bit - 1)); // stage 0-1-2-3 x = vmulq_n_s32(in[0], cospi[32]); x = vaddq_s32(vshlq_s32(x, v_bit), rnding); // stage 4-5 if (!do_cols) { const int log_range_out = AOMMAX(16, bd + 6); clamp_lo = vdupq_n_s32(-(1 << (log_range_out - 1))); clamp_hi = vdupq_n_s32((1 << (log_range_out - 1)) - 1); int32x4_t offset = vdupq_n_s32((1 << out_shift) >> 1); x = vaddq_s32(x, offset); x = vshlq_s32(x, vdupq_n_s32(-out_shift)); } x = vmaxq_s32(x, clamp_lo); x = vminq_s32(x, clamp_hi); out[0] = x; out[1] = x; out[2] = x; out[3] = x; out[4] = x; out[5] = x; out[6] = x; out[7] = x; } static void idct8x8_new_neon(int32x4_t *in, int32x4_t *out, int bit, int do_cols, int bd, int out_shift) { const int32_t *cospi = cospi_arr(bit); const int log_range = AOMMAX(16, bd + (do_cols ? 6 : 8)); const int32x4_t clamp_lo = vdupq_n_s32(-(1 << (log_range - 1))); const int32x4_t clamp_hi = vdupq_n_s32((1 << (log_range - 1)) - 1); int32x4_t u0, u1, u2, u3, u4, u5, u6, u7; int32x4_t v0, v1, v2, v3, v4, v5, v6, v7; int32x4_t x, y; const int32x4_t v_bit = vdupq_n_s32(-bit); const int32x4_t rnding = vdupq_n_s32(1 << (bit - 1)); // stage 0 // stage 1 // stage 2 u0 = in[0]; u1 = in[4]; u2 = in[2]; u3 = in[6]; x = vmlaq_n_s32(rnding, in[1], cospi[56]); u4 = vmlaq_n_s32(x, in[7], -cospi[8]); u4 = vshlq_s32(u4, v_bit); x = vmlaq_n_s32(rnding, in[1], cospi[8]); u7 = vmlaq_n_s32(x, in[7], cospi[56]); u7 = vshlq_s32(u7, v_bit); x = vmlaq_n_s32(rnding, in[5], cospi[24]); u5 = vmlaq_n_s32(x, in[3], -cospi[40]); u5 = vshlq_s32(u5, v_bit); x = vmlaq_n_s32(rnding, in[5], cospi[40]); u6 = vmlaq_n_s32(x, in[3], cospi[24]); u6 = vshlq_s32(u6, v_bit); // stage 3 x = vmlaq_n_s32(rnding, u0, cospi[32]); y = vmulq_n_s32(u1, cospi[32]); v0 = vaddq_s32(x, y); v0 = vshlq_s32(v0, v_bit); v1 = vsubq_s32(x, y); v1 = vshlq_s32(v1, v_bit); x = vmlaq_n_s32(rnding, u2, cospi[48]); v2 = vmlaq_n_s32(x, u3, -cospi[16]); v2 = vshlq_s32(v2, v_bit); x = vmlaq_n_s32(rnding, u2, cospi[16]); v3 = vmlaq_n_s32(x, u3, cospi[48]); v3 = vshlq_s32(v3, v_bit); addsub_neon(u4, u5, &v4, &v5, &clamp_lo, &clamp_hi); addsub_neon(u7, u6, &v7, &v6, &clamp_lo, &clamp_hi); // stage 4 addsub_neon(v0, v3, &u0, &u3, &clamp_lo, &clamp_hi); addsub_neon(v1, v2, &u1, &u2, &clamp_lo, &clamp_hi); u4 = v4; u7 = v7; x = vmulq_n_s32(v5, cospi[32]); y = vmlaq_n_s32(rnding, v6, cospi[32]); u6 = vaddq_s32(y, x); u6 = vshlq_s32(u6, v_bit); u5 = vsubq_s32(y, x); u5 = vshlq_s32(u5, v_bit); // stage 5 addsub_neon(u0, u7, out + 0, out + 7, &clamp_lo, &clamp_hi); addsub_neon(u1, u6, out + 1, out + 6, &clamp_lo, &clamp_hi); addsub_neon(u2, u5, out + 2, out + 5, &clamp_lo, &clamp_hi); addsub_neon(u3, u4, out + 3, out + 4, &clamp_lo, &clamp_hi); if (!do_cols) { const int log_range_out = AOMMAX(16, bd + 6); const int32x4_t clamp_lo_out = vdupq_n_s32(-(1 << (log_range_out - 1))); const int32x4_t clamp_hi_out = vdupq_n_s32((1 << (log_range_out - 1)) - 1); round_shift_4x4(out, out_shift); round_shift_4x4(out + 4, out_shift); highbd_clamp_s32_neon(out, out, &clamp_lo_out, &clamp_hi_out, 8); } } static void iadst8x8_low1_neon(int32x4_t *in, int32x4_t *out, int bit, int do_cols, int bd, int out_shift) { const int32_t *cospi = cospi_arr(bit); int32x4_t u[8], x; const int32x4_t v_bit = vdupq_n_s32(-bit); const int32x4_t rnding = vdupq_n_s32(1 << (bit - 1)); // stage 0-2 u[0] = vmlaq_n_s32(rnding, in[0], cospi[60]); u[0] = vshlq_s32(u[0], v_bit); u[1] = vmlaq_n_s32(rnding, in[0], cospi[4]); u[1] = vshlq_s32(vnegq_s32(u[1]), v_bit); // stage 3-4 int32x4_t temp1, temp2; temp1 = vmlaq_n_s32(rnding, u[0], cospi[16]); temp1 = vmlaq_n_s32(temp1, u[1], cospi[48]); temp1 = vshlq_s32(temp1, v_bit); u[4] = temp1; temp2 = vmlaq_n_s32(rnding, u[0], cospi[48]); u[5] = vmlsq_n_s32(temp2, u[1], cospi[16]); u[5] = vshlq_s32(u[5], v_bit); // stage 5-6 temp1 = vmlaq_n_s32(rnding, u[0], cospi[32]); x = vmulq_n_s32(u[1], cospi[32]); u[2] = vaddq_s32(temp1, x); u[2] = vshlq_s32(u[2], v_bit); u[3] = vsubq_s32(temp1, x); u[3] = vshlq_s32(u[3], v_bit); temp1 = vmlaq_n_s32(rnding, u[4], cospi[32]); x = vmulq_n_s32(u[5], cospi[32]); u[6] = vaddq_s32(temp1, x); u[6] = vshlq_s32(u[6], v_bit); u[7] = vsubq_s32(temp1, x); u[7] = vshlq_s32(u[7], v_bit); // stage 7 if (do_cols) { out[0] = u[0]; out[1] = vnegq_s32(u[4]); out[2] = u[6]; out[3] = vnegq_s32(u[2]); out[4] = u[3]; out[5] = vnegq_s32(u[7]); out[6] = u[5]; out[7] = vnegq_s32(u[1]); } else { const int log_range_out = AOMMAX(16, bd + 6); const int32x4_t clamp_lo_out = vdupq_n_s32(-(1 << (log_range_out - 1))); const int32x4_t clamp_hi_out = vdupq_n_s32((1 << (log_range_out - 1)) - 1); const int32x4_t v_shift = vdupq_n_s32(-out_shift); int32x4_t offset = vdupq_n_s32((1 << out_shift) >> 1); neg_shift_neon(&u[0], &u[4], out + 0, out + 1, &clamp_lo_out, &clamp_hi_out, &v_shift, &offset); neg_shift_neon(&u[6], &u[2], out + 2, out + 3, &clamp_lo_out, &clamp_hi_out, &v_shift, &offset); neg_shift_neon(&u[3], &u[7], out + 4, out + 5, &clamp_lo_out, &clamp_hi_out, &v_shift, &offset); neg_shift_neon(&u[5], &u[1], out + 6, out + 7, &clamp_lo_out, &clamp_hi_out, &v_shift, &offset); } } static void iadst8x8_new_neon(int32x4_t *in, int32x4_t *out, int bit, int do_cols, int bd, int out_shift) { const int32_t *cospi = cospi_arr(bit); // const int32x4_t rnding = vdupq_n_s32(1 << (bit - 1)); const int log_range = AOMMAX(16, bd + (do_cols ? 6 : 8)); const int32x4_t clamp_lo = vdupq_n_s32(-(1 << (log_range - 1))); const int32x4_t clamp_hi = vdupq_n_s32((1 << (log_range - 1)) - 1); int32x4_t u[8], v[8], x; const int32x4_t v_bit = vdupq_n_s32(-bit); const int32x4_t rnding = vdupq_n_s32(1 << (bit - 1)); // stage 0-2 u[0] = vmlaq_n_s32(rnding, in[7], cospi[4]); u[0] = vmlaq_n_s32(u[0], in[0], cospi[60]); u[0] = vshlq_s32(u[0], v_bit); u[1] = vmlaq_n_s32(rnding, in[7], cospi[60]); u[1] = vmlsq_n_s32(u[1], in[0], cospi[4]); u[1] = vshlq_s32(u[1], v_bit); // (2) u[2] = vmlaq_n_s32(rnding, in[5], cospi[20]); u[2] = vmlaq_n_s32(u[2], in[2], cospi[44]); u[2] = vshlq_s32(u[2], v_bit); u[3] = vmlaq_n_s32(rnding, in[5], cospi[44]); u[3] = vmlsq_n_s32(u[3], in[2], cospi[20]); u[3] = vshlq_s32(u[3], v_bit); // (3) u[4] = vmlaq_n_s32(rnding, in[3], cospi[36]); u[4] = vmlaq_n_s32(u[4], in[4], cospi[28]); u[4] = vshlq_s32(u[4], v_bit); u[5] = vmlaq_n_s32(rnding, in[3], cospi[28]); u[5] = vmlsq_n_s32(u[5], in[4], cospi[36]); u[5] = vshlq_s32(u[5], v_bit); // (4) u[6] = vmulq_n_s32(in[1], cospi[52]); u[6] = vmlaq_n_s32(u[6], in[6], cospi[12]); u[6] = vaddq_s32(u[6], rnding); u[6] = vshlq_s32(u[6], v_bit); u[7] = vmulq_n_s32(in[1], cospi[12]); u[7] = vmlsq_n_s32(u[7], in[6], cospi[52]); u[7] = vaddq_s32(u[7], rnding); u[7] = vshlq_s32(u[7], v_bit); // stage 3 addsub_neon(u[0], u[4], &v[0], &v[4], &clamp_lo, &clamp_hi); addsub_neon(u[1], u[5], &v[1], &v[5], &clamp_lo, &clamp_hi); addsub_neon(u[2], u[6], &v[2], &v[6], &clamp_lo, &clamp_hi); addsub_neon(u[3], u[7], &v[3], &v[7], &clamp_lo, &clamp_hi); // stage 4 u[0] = v[0]; u[1] = v[1]; u[2] = v[2]; u[3] = v[3]; u[4] = vmlaq_n_s32(rnding, v[4], cospi[16]); u[4] = vmlaq_n_s32(u[4], v[5], cospi[48]); u[4] = vshlq_s32(u[4], v_bit); u[5] = vmlaq_n_s32(rnding, v[4], cospi[48]); u[5] = vmlsq_n_s32(u[5], v[5], cospi[16]); u[5] = vshlq_s32(u[5], v_bit); u[6] = vmlsq_n_s32(rnding, v[6], cospi[48]); u[6] = vmlaq_n_s32(u[6], v[7], cospi[16]); u[6] = vshlq_s32(u[6], v_bit); u[7] = vmlaq_n_s32(rnding, v[6], cospi[16]); u[7] = vmlaq_n_s32(u[7], v[7], cospi[48]); u[7] = vshlq_s32(u[7], v_bit); // stage 5 addsub_neon(u[0], u[2], &v[0], &v[2], &clamp_lo, &clamp_hi); addsub_neon(u[1], u[3], &v[1], &v[3], &clamp_lo, &clamp_hi); addsub_neon(u[4], u[6], &v[4], &v[6], &clamp_lo, &clamp_hi); addsub_neon(u[5], u[7], &v[5], &v[7], &clamp_lo, &clamp_hi); // stage 6 u[0] = v[0]; u[1] = v[1]; u[4] = v[4]; u[5] = v[5]; v[0] = vmlaq_n_s32(rnding, v[2], cospi[32]); x = vmulq_n_s32(v[3], cospi[32]); u[2] = vaddq_s32(v[0], x); u[2] = vshlq_s32(u[2], v_bit); u[3] = vsubq_s32(v[0], x); u[3] = vshlq_s32(u[3], v_bit); v[0] = vmlaq_n_s32(rnding, v[6], cospi[32]); x = vmulq_n_s32(v[7], cospi[32]); u[6] = vaddq_s32(v[0], x); u[6] = vshlq_s32(u[6], v_bit); u[7] = vsubq_s32(v[0], x); u[7] = vshlq_s32(u[7], v_bit); // stage 7 if (do_cols) { out[0] = u[0]; out[1] = vnegq_s32(u[4]); out[2] = u[6]; out[3] = vnegq_s32(u[2]); out[4] = u[3]; out[5] = vnegq_s32(u[7]); out[6] = u[5]; out[7] = vnegq_s32(u[1]); } else { const int log_range_out = AOMMAX(16, bd + 6); const int32x4_t clamp_lo_out = vdupq_n_s32(-(1 << (log_range_out - 1))); const int32x4_t clamp_hi_out = vdupq_n_s32((1 << (log_range_out - 1)) - 1); const int32x4_t v_shift = vdupq_n_s32(-out_shift); int32x4_t offset = vdupq_n_s32((1 << out_shift) >> 1); neg_shift_neon(&u[0], &u[4], out + 0, out + 1, &clamp_lo_out, &clamp_hi_out, &v_shift, &offset); neg_shift_neon(&u[6], &u[2], out + 2, out + 3, &clamp_lo_out, &clamp_hi_out, &v_shift, &offset); neg_shift_neon(&u[3], &u[7], out + 4, out + 5, &clamp_lo_out, &clamp_hi_out, &v_shift, &offset); neg_shift_neon(&u[5], &u[1], out + 6, out + 7, &clamp_lo_out, &clamp_hi_out, &v_shift, &offset); } } static void idct16x16_low1_neon(int32x4_t *in, int32x4_t *out, int bit, int do_cols, int bd, int out_shift) { const int32_t *cospi = cospi_arr(bit); int log_range = AOMMAX(16, bd + (do_cols ? 6 : 8)); int32x4_t clamp_lo = vdupq_n_s32(-(1 << (log_range - 1))); int32x4_t clamp_hi = vdupq_n_s32((1 << (log_range - 1)) - 1); const int32x4_t v_bit = vdupq_n_s32(-bit); const int32x4_t rnding = vdupq_n_s32(1 << (bit - 1)); // stage 0-4 in[0] = vmlaq_n_s32(rnding, in[0], cospi[32]); in[0] = vshlq_s32(in[0], v_bit); // stage 5-7 if (!do_cols) { log_range = AOMMAX(16, bd + 6); clamp_lo = vdupq_n_s32(-(1 << (log_range - 1))); clamp_hi = vdupq_n_s32((1 << (log_range - 1)) - 1); if (out_shift != 0) { int32x4_t offset = vdupq_n_s32((1 << out_shift) >> 1); in[0] = vaddq_s32(in[0], offset); in[0] = vshlq_s32(in[0], vdupq_n_s32(-out_shift)); } } in[0] = vmaxq_s32(in[0], clamp_lo); in[0] = vminq_s32(in[0], clamp_hi); out[0] = in[0]; out[1] = in[0]; out[2] = in[0]; out[3] = in[0]; out[4] = in[0]; out[5] = in[0]; out[6] = in[0]; out[7] = in[0]; out[8] = in[0]; out[9] = in[0]; out[10] = in[0]; out[11] = in[0]; out[12] = in[0]; out[13] = in[0]; out[14] = in[0]; out[15] = in[0]; } static void idct16x16_low8_neon(int32x4_t *in, int32x4_t *out, int bit, int do_cols, int bd, int out_shift) { const int32_t *cospi = cospi_arr(bit); const int log_range = AOMMAX(16, bd + (do_cols ? 6 : 8)); const int32x4_t clamp_lo = vdupq_n_s32(-(1 << (log_range - 1))); const int32x4_t clamp_hi = vdupq_n_s32((1 << (log_range - 1)) - 1); const int32x4_t v_bit = vdupq_n_s32(-bit); const int32x4_t rnding = vdupq_n_s32(1 << (bit - 1)); int32x4_t u[16], x, y; // stage 0-1 u[0] = in[0]; u[2] = in[4]; u[4] = in[2]; u[6] = in[6]; u[8] = in[1]; u[10] = in[5]; u[12] = in[3]; u[14] = in[7]; // stage 2 u[15] = half_btf_0_neon_r(&cospi[4], &u[8], &v_bit, &rnding); u[8] = half_btf_0_neon_r(&cospi[60], &u[8], &v_bit, &rnding); u[9] = half_btf_0_m_neon_r(&cospi[36], &u[14], &v_bit, &rnding); u[14] = half_btf_0_neon_r(&cospi[28], &u[14], &v_bit, &rnding); u[13] = half_btf_0_neon_r(&cospi[20], &u[10], &v_bit, &rnding); u[10] = half_btf_0_neon_r(&cospi[44], &u[10], &v_bit, &rnding); u[11] = half_btf_0_m_neon_r(&cospi[52], &u[12], &v_bit, &rnding); u[12] = half_btf_0_neon_r(&cospi[12], &u[12], &v_bit, &rnding); // stage 3 u[7] = half_btf_0_neon_r(&cospi[8], &u[4], &v_bit, &rnding); u[4] = half_btf_0_neon_r(&cospi[56], &u[4], &v_bit, &rnding); u[5] = half_btf_0_m_neon_r(&cospi[40], &u[6], &v_bit, &rnding); u[6] = half_btf_0_neon_r(&cospi[24], &u[6], &v_bit, &rnding); addsub_neon(u[8], u[9], &u[8], &u[9], &clamp_lo, &clamp_hi); addsub_neon(u[11], u[10], &u[11], &u[10], &clamp_lo, &clamp_hi); addsub_neon(u[12], u[13], &u[12], &u[13], &clamp_lo, &clamp_hi); addsub_neon(u[15], u[14], &u[15], &u[14], &clamp_lo, &clamp_hi); // stage 4 x = vmlaq_n_s32(rnding, u[0], cospi[32]); u[0] = vshlq_s32(x, v_bit); u[1] = u[0]; u[3] = half_btf_0_neon_r(&cospi[16], &u[2], &v_bit, &rnding); u[2] = half_btf_0_neon_r(&cospi[48], &u[2], &v_bit, &rnding); addsub_neon(u[4], u[5], &u[4], &u[5], &clamp_lo, &clamp_hi); addsub_neon(u[7], u[6], &u[7], &u[6], &clamp_lo, &clamp_hi); x = half_btf_neon_mode10_r(&cospi[16], &u[9], &cospi[48], &u[14], &v_bit, &rnding); u[14] = half_btf_neon_r(&cospi[48], &u[9], &cospi[16], &u[14], &v_bit, &rnding); u[9] = x; y = half_btf_neon_mode11_r(&cospi[48], &u[10], &cospi[16], &u[13], &v_bit, &rnding); u[13] = half_btf_neon_mode10_r(&cospi[16], &u[10], &cospi[48], &u[13], &v_bit, &rnding); u[10] = y; // stage 5 addsub_neon(u[0], u[3], &u[0], &u[3], &clamp_lo, &clamp_hi); addsub_neon(u[1], u[2], &u[1], &u[2], &clamp_lo, &clamp_hi); x = vmulq_n_s32(u[5], cospi[32]); y = vmlaq_n_s32(rnding, u[6], cospi[32]); u[5] = vsubq_s32(y, x); u[5] = vshlq_s32(u[5], v_bit); u[6] = vaddq_s32(y, x); u[6] = vshlq_s32(u[6], v_bit); addsub_neon(u[8], u[11], &u[8], &u[11], &clamp_lo, &clamp_hi); addsub_neon(u[9], u[10], &u[9], &u[10], &clamp_lo, &clamp_hi); addsub_neon(u[15], u[12], &u[15], &u[12], &clamp_lo, &clamp_hi); addsub_neon(u[14], u[13], &u[14], &u[13], &clamp_lo, &clamp_hi); // stage 6 addsub_neon(u[0], u[7], &u[0], &u[7], &clamp_lo, &clamp_hi); addsub_neon(u[1], u[6], &u[1], &u[6], &clamp_lo, &clamp_hi); addsub_neon(u[2], u[5], &u[2], &u[5], &clamp_lo, &clamp_hi); addsub_neon(u[3], u[4], &u[3], &u[4], &clamp_lo, &clamp_hi); x = vmulq_n_s32(u[10], cospi[32]); y = vmlaq_n_s32(rnding, u[13], cospi[32]); u[10] = vsubq_s32(y, x); u[10] = vshlq_s32(u[10], v_bit); u[13] = vaddq_s32(x, y); u[13] = vshlq_s32(u[13], v_bit); x = vmulq_n_s32(u[11], cospi[32]); y = vmlaq_n_s32(rnding, u[12], cospi[32]); u[11] = vsubq_s32(y, x); u[11] = vshlq_s32(u[11], v_bit); u[12] = vaddq_s32(x, y); u[12] = vshlq_s32(u[12], v_bit); // stage 7 addsub_neon(u[0], u[15], out + 0, out + 15, &clamp_lo, &clamp_hi); addsub_neon(u[1], u[14], out + 1, out + 14, &clamp_lo, &clamp_hi); addsub_neon(u[2], u[13], out + 2, out + 13, &clamp_lo, &clamp_hi); addsub_neon(u[3], u[12], out + 3, out + 12, &clamp_lo, &clamp_hi); addsub_neon(u[4], u[11], out + 4, out + 11, &clamp_lo, &clamp_hi); addsub_neon(u[5], u[10], out + 5, out + 10, &clamp_lo, &clamp_hi); addsub_neon(u[6], u[9], out + 6, out + 9, &clamp_lo, &clamp_hi); addsub_neon(u[7], u[8], out + 7, out + 8, &clamp_lo, &clamp_hi); if (!do_cols) { const int log_range_out = AOMMAX(16, bd + 6); const int32x4_t clamp_lo_out = vdupq_n_s32(-(1 << (log_range_out - 1))); const int32x4_t clamp_hi_out = vdupq_n_s32((1 << (log_range_out - 1)) - 1); round_shift_8x8(out, out_shift); highbd_clamp_s32_neon(out, out, &clamp_lo_out, &clamp_hi_out, 16); } } static void iadst16x16_low1_neon(int32x4_t *in, int32x4_t *out, int bit, int do_cols, int bd, int out_shift) { const int32_t *cospi = cospi_arr(bit); int32x4_t v[16], x, y, temp1, temp2; const int32x4_t v_bit = vdupq_n_s32(-bit); const int32x4_t rnding = vdupq_n_s32(1 << (bit - 1)); // stage 0 // stage 1 // stage 2 v[0] = vmlaq_n_s32(rnding, in[0], cospi[62]); v[0] = vshlq_s32(v[0], v_bit); v[1] = vmlsq_n_s32(rnding, in[0], cospi[2]); v[1] = vshlq_s32(v[1], v_bit); // stage 3 v[8] = v[0]; v[9] = v[1]; // stage 4 temp1 = vmlaq_n_s32(rnding, v[8], cospi[8]); temp1 = vmlaq_n_s32(temp1, v[9], cospi[56]); temp1 = vshlq_s32(temp1, v_bit); temp2 = vmlaq_n_s32(rnding, v[8], cospi[56]); temp2 = vmlsq_n_s32(temp2, v[9], cospi[8]); temp2 = vshlq_s32(temp2, v_bit); v[8] = temp1; v[9] = temp2; // stage 5 v[4] = v[0]; v[5] = v[1]; v[12] = v[8]; v[13] = v[9]; // stage 6 temp1 = vmlaq_n_s32(rnding, v[4], cospi[16]); temp1 = vmlaq_n_s32(temp1, v[5], cospi[48]); temp1 = vshlq_s32(temp1, v_bit); temp2 = vmlaq_n_s32(rnding, v[4], cospi[48]); temp2 = vmlsq_n_s32(temp2, v[5], cospi[16]); temp2 = vshlq_s32(temp2, v_bit); v[4] = temp1; v[5] = temp2; temp1 = vmlaq_n_s32(rnding, v[12], cospi[16]); temp1 = vmlaq_n_s32(temp1, v[13], cospi[48]); temp1 = vshlq_s32(temp1, v_bit); temp2 = vmlaq_n_s32(rnding, v[12], cospi[48]); temp2 = vmlsq_n_s32(temp2, v[13], cospi[16]); temp2 = vshlq_s32(temp2, v_bit); v[12] = temp1; v[13] = temp2; // stage 7 v[2] = v[0]; v[3] = v[1]; v[6] = v[4]; v[7] = v[5]; v[10] = v[8]; v[11] = v[9]; v[14] = v[12]; v[15] = v[13]; // stage 8 y = vmlaq_n_s32(rnding, v[2], cospi[32]); x = vmulq_n_s32(v[3], cospi[32]); v[2] = vaddq_s32(y, x); v[2] = vshlq_s32(v[2], v_bit); v[3] = vsubq_s32(y, x); v[3] = vshlq_s32(v[3], v_bit); y = vmlaq_n_s32(rnding, v[6], cospi[32]); x = vmulq_n_s32(v[7], cospi[32]); v[6] = vaddq_s32(y, x); v[6] = vshlq_s32(v[6], v_bit); v[7] = vsubq_s32(y, x); v[7] = vshlq_s32(v[7], v_bit); y = vmlaq_n_s32(rnding, v[10], cospi[32]); x = vmulq_n_s32(v[11], cospi[32]); v[10] = vaddq_s32(y, x); v[10] = vshlq_s32(v[10], v_bit); v[11] = vsubq_s32(y, x); v[11] = vshlq_s32(v[11], v_bit); y = vmlaq_n_s32(rnding, v[14], cospi[32]); x = vmulq_n_s32(v[15], cospi[32]); v[14] = vaddq_s32(y, x); v[14] = vshlq_s32(v[14], v_bit); v[15] = vsubq_s32(y, x); v[15] = vshlq_s32(v[15], v_bit); // stage 9 if (do_cols) { out[0] = v[0]; out[1] = vnegq_s32(v[8]); out[2] = v[12]; out[3] = vnegq_s32(v[4]); out[4] = v[6]; out[5] = vnegq_s32(v[14]); out[6] = v[10]; out[7] = vnegq_s32(v[2]); out[8] = v[3]; out[9] = vnegq_s32(v[11]); out[10] = v[15]; out[11] = vnegq_s32(v[7]); out[12] = v[5]; out[13] = vnegq_s32(v[13]); out[14] = v[9]; out[15] = vnegq_s32(v[1]); } else { const int log_range_out = AOMMAX(16, bd + 6); const int32x4_t clamp_lo_out = vdupq_n_s32(-(1 << (log_range_out - 1))); const int32x4_t clamp_hi_out = vdupq_n_s32((1 << (log_range_out - 1)) - 1); const int32x4_t v_shift = vdupq_n_s32(-out_shift); int32x4_t offset = vdupq_n_s32((1 << out_shift) >> 1); neg_shift_neon(&v[0], &v[8], out + 0, out + 1, &clamp_lo_out, &clamp_hi_out, &v_shift, &offset); neg_shift_neon(&v[12], &v[4], out + 2, out + 3, &clamp_lo_out, &clamp_hi_out, &v_shift, &offset); neg_shift_neon(&v[6], &v[14], out + 4, out + 5, &clamp_lo_out, &clamp_hi_out, &v_shift, &offset); neg_shift_neon(&v[10], &v[2], out + 6, out + 7, &clamp_lo_out, &clamp_hi_out, &v_shift, &offset); neg_shift_neon(&v[3], &v[11], out + 8, out + 9, &clamp_lo_out, &clamp_hi_out, &v_shift, &offset); neg_shift_neon(&v[15], &v[7], out + 10, out + 11, &clamp_lo_out, &clamp_hi_out, &v_shift, &offset); neg_shift_neon(&v[5], &v[13], out + 12, out + 13, &clamp_lo_out, &clamp_hi_out, &v_shift, &offset); neg_shift_neon(&v[9], &v[1], out + 14, out + 15, &clamp_lo_out, &clamp_hi_out, &v_shift, &offset); } } static void iadst16x16_low8_neon(int32x4_t *in, int32x4_t *out, int bit, int do_cols, int bd, int out_shift) { const int32_t *cospi = cospi_arr(bit); const int log_range = AOMMAX(16, bd + (do_cols ? 6 : 8)); const int32x4_t clamp_lo = vdupq_n_s32(-(1 << (log_range - 1))); const int32x4_t clamp_hi = vdupq_n_s32((1 << (log_range - 1)) - 1); int32x4_t zero = vdupq_n_s32(0); int32x4_t u[16], x, y; const int32x4_t v_bit = vdupq_n_s32(-bit); const int32x4_t rnding = vdupq_n_s32(1 << (bit - 1)); // stage 0-2 u[0] = vmlaq_n_s32(rnding, in[0], cospi[62]); u[0] = vshlq_s32(u[0], v_bit); u[1] = vmlsq_n_s32(rnding, in[0], cospi[2]); u[1] = vshlq_s32(u[1], v_bit); u[2] = vmlaq_n_s32(rnding, in[2], cospi[54]); u[2] = vshlq_s32(u[2], v_bit); u[3] = vmlsq_n_s32(rnding, in[2], cospi[10]); u[3] = vshlq_s32(u[3], v_bit); u[4] = vmlaq_n_s32(rnding, in[4], cospi[46]); u[4] = vshlq_s32(u[4], v_bit); u[5] = vmlsq_n_s32(rnding, in[4], cospi[18]); u[5] = vshlq_s32(u[5], v_bit); u[6] = vmlaq_n_s32(rnding, in[6], cospi[38]); u[6] = vshlq_s32(u[6], v_bit); u[7] = vmlsq_n_s32(rnding, in[6], cospi[26]); u[7] = vshlq_s32(u[7], v_bit); u[8] = vmlaq_n_s32(rnding, in[7], cospi[34]); u[8] = vshlq_s32(u[8], v_bit); u[9] = vmlaq_n_s32(rnding, in[7], cospi[30]); u[9] = vshlq_s32(u[9], v_bit); u[10] = vmlaq_n_s32(rnding, in[5], cospi[42]); u[10] = vshlq_s32(u[10], v_bit); u[11] = vmlaq_n_s32(rnding, in[5], cospi[22]); u[11] = vshlq_s32(u[11], v_bit); u[12] = vmlaq_n_s32(rnding, in[3], cospi[50]); u[12] = vshlq_s32(u[12], v_bit); u[13] = vmlaq_n_s32(rnding, in[3], cospi[14]); u[13] = vshlq_s32(u[13], v_bit); u[14] = vmlaq_n_s32(rnding, in[1], cospi[58]); u[14] = vshlq_s32(u[14], v_bit); u[15] = vmlaq_n_s32(rnding, in[1], cospi[6]); u[15] = vshlq_s32(u[15], v_bit); // stage 3 addsub_neon(u[0], u[8], &u[0], &u[8], &clamp_lo, &clamp_hi); addsub_neon(u[1], u[9], &u[1], &u[9], &clamp_lo, &clamp_hi); addsub_neon(u[2], u[10], &u[2], &u[10], &clamp_lo, &clamp_hi); addsub_neon(u[3], u[11], &u[3], &u[11], &clamp_lo, &clamp_hi); addsub_neon(u[4], u[12], &u[4], &u[12], &clamp_lo, &clamp_hi); addsub_neon(u[5], u[13], &u[5], &u[13], &clamp_lo, &clamp_hi); addsub_neon(u[6], u[14], &u[6], &u[14], &clamp_lo, &clamp_hi); addsub_neon(u[7], u[15], &u[7], &u[15], &clamp_lo, &clamp_hi); // stage 4 y = vmlaq_n_s32(rnding, u[8], cospi[56]); u[8] = vmlaq_n_s32(rnding, u[8], cospi[8]); u[8] = vmlaq_n_s32(u[8], u[9], cospi[56]); u[8] = vshlq_s32(u[8], v_bit); u[9] = vmlsq_n_s32(y, u[9], cospi[8]); u[9] = vshlq_s32(u[9], v_bit); y = vmlaq_n_s32(rnding, u[10], cospi[24]); u[10] = vmlaq_n_s32(rnding, u[10], cospi[40]); u[10] = vmlaq_n_s32(u[10], u[11], cospi[24]); u[10] = vshlq_s32(u[10], v_bit); u[11] = vmlsq_n_s32(y, u[11], cospi[40]); u[11] = vshlq_s32(u[11], v_bit); y = vmlaq_n_s32(rnding, u[12], cospi[8]); u[12] = vmlsq_n_s32(rnding, u[12], cospi[56]); u[12] = vmlaq_n_s32(u[12], u[13], cospi[8]); u[12] = vshlq_s32(u[12], v_bit); u[13] = vmlaq_n_s32(y, u[13], cospi[56]); u[13] = vshlq_s32(u[13], v_bit); y = vmlaq_n_s32(rnding, u[14], cospi[40]); u[14] = vmlsq_n_s32(rnding, u[14], cospi[24]); u[14] = vmlaq_n_s32(u[14], u[15], cospi[40]); u[14] = vshlq_s32(u[14], v_bit); u[15] = vmlaq_n_s32(y, u[15], cospi[24]); u[15] = vshlq_s32(u[15], v_bit); // stage 5 addsub_neon(u[0], u[4], &u[0], &u[4], &clamp_lo, &clamp_hi); addsub_neon(u[1], u[5], &u[1], &u[5], &clamp_lo, &clamp_hi); addsub_neon(u[2], u[6], &u[2], &u[6], &clamp_lo, &clamp_hi); addsub_neon(u[3], u[7], &u[3], &u[7], &clamp_lo, &clamp_hi); addsub_neon(u[8], u[12], &u[8], &u[12], &clamp_lo, &clamp_hi); addsub_neon(u[9], u[13], &u[9], &u[13], &clamp_lo, &clamp_hi); addsub_neon(u[10], u[14], &u[10], &u[14], &clamp_lo, &clamp_hi); addsub_neon(u[11], u[15], &u[11], &u[15], &clamp_lo, &clamp_hi); // stage 6 y = vmlaq_n_s32(rnding, u[4], cospi[48]); u[4] = vmlaq_n_s32(rnding, u[4], cospi[16]); u[4] = vmlaq_n_s32(u[4], u[5], cospi[48]); u[4] = vshlq_s32(u[4], v_bit); u[5] = vmlsq_n_s32(y, u[5], cospi[16]); u[5] = vshlq_s32(u[5], v_bit); y = vmlaq_n_s32(rnding, u[6], cospi[16]); u[6] = vmlsq_n_s32(rnding, u[6], cospi[48]); u[6] = vmlaq_n_s32(u[6], u[7], cospi[16]); u[6] = vshlq_s32(u[6], v_bit); u[7] = vmlaq_n_s32(y, u[7], cospi[48]); u[7] = vshlq_s32(u[7], v_bit); y = vmlaq_n_s32(rnding, u[12], cospi[48]); u[12] = vmulq_n_s32(u[12], cospi[16]); u[12] = vmlaq_n_s32(u[12], u[13], cospi[48]); u[12] = vshlq_s32(u[12], v_bit); u[13] = vmlsq_n_s32(y, u[13], cospi[16]); u[13] = vshlq_s32(u[13], v_bit); y = vmlaq_n_s32(rnding, u[14], cospi[16]); u[14] = vmlsq_n_s32(rnding, u[14], cospi[48]); u[14] = vmlaq_n_s32(u[14], u[15], cospi[16]); u[14] = vshlq_s32(u[14], v_bit); u[15] = vmlaq_n_s32(y, u[15], cospi[48]); u[15] = vshlq_s32(u[15], v_bit); // stage 7 addsub_neon(u[0], u[2], &u[0], &u[2], &clamp_lo, &clamp_hi); addsub_neon(u[1], u[3], &u[1], &u[3], &clamp_lo, &clamp_hi); addsub_neon(u[4], u[6], &u[4], &u[6], &clamp_lo, &clamp_hi); addsub_neon(u[5], u[7], &u[5], &u[7], &clamp_lo, &clamp_hi); addsub_neon(u[8], u[10], &u[8], &u[10], &clamp_lo, &clamp_hi); addsub_neon(u[9], u[11], &u[9], &u[11], &clamp_lo, &clamp_hi); addsub_neon(u[12], u[14], &u[12], &u[14], &clamp_lo, &clamp_hi); addsub_neon(u[13], u[15], &u[13], &u[15], &clamp_lo, &clamp_hi); // stage 8 y = vmlaq_n_s32(rnding, u[2], cospi[32]); x = vmulq_n_s32(u[3], cospi[32]); u[2] = vaddq_s32(y, x); u[2] = vshlq_s32(u[2], v_bit); u[3] = vsubq_s32(y, x); u[3] = vshlq_s32(u[3], v_bit); y = vmlaq_n_s32(rnding, u[6], cospi[32]); x = vmulq_n_s32(u[7], cospi[32]); u[6] = vaddq_s32(y, x); u[6] = vshlq_s32(u[6], v_bit); u[7] = vsubq_s32(y, x); u[7] = vshlq_s32(u[7], v_bit); y = vmlaq_n_s32(rnding, u[10], cospi[32]); x = vmulq_n_s32(u[11], cospi[32]); u[10] = vaddq_s32(y, x); u[10] = vshlq_s32(u[10], v_bit); u[11] = vsubq_s32(y, x); u[11] = vshlq_s32(u[11], v_bit); y = vmlaq_n_s32(rnding, u[14], cospi[32]); x = vmulq_n_s32(u[15], cospi[32]); u[14] = vaddq_s32(y, x); u[14] = vshlq_s32(u[14], v_bit); u[15] = vsubq_s32(y, x); u[15] = vshlq_s32(u[15], v_bit); // stage 9 if (do_cols) { out[0] = u[0]; out[1] = vsubq_s32(zero, u[8]); out[2] = u[12]; out[3] = vsubq_s32(zero, u[4]); out[4] = u[6]; out[5] = vsubq_s32(zero, u[14]); out[6] = u[10]; out[7] = vsubq_s32(zero, u[2]); out[8] = u[3]; out[9] = vsubq_s32(zero, u[11]); out[10] = u[15]; out[11] = vsubq_s32(zero, u[7]); out[12] = u[5]; out[13] = vsubq_s32(zero, u[13]); out[14] = u[9]; out[15] = vsubq_s32(zero, u[1]); } else { const int log_range_out = AOMMAX(16, bd + 6); const int32x4_t clamp_lo_out = vdupq_n_s32(-(1 << (log_range_out - 1))); const int32x4_t clamp_hi_out = vdupq_n_s32((1 << (log_range_out - 1)) - 1); const int32x4_t v_shift = vdupq_n_s32(-out_shift); int32x4_t offset = vdupq_n_s32((1 << out_shift) >> 1); neg_shift_neon(&u[0], &u[8], out + 0, out + 1, &clamp_lo_out, &clamp_hi_out, &v_shift, &offset); neg_shift_neon(&u[12], &u[4], out + 2, out + 3, &clamp_lo_out, &clamp_hi_out, &v_shift, &offset); neg_shift_neon(&u[6], &u[14], out + 4, out + 5, &clamp_lo_out, &clamp_hi_out, &v_shift, &offset); neg_shift_neon(&u[10], &u[2], out + 6, out + 7, &clamp_lo_out, &clamp_hi_out, &v_shift, &offset); neg_shift_neon(&u[3], &u[11], out + 8, out + 9, &clamp_lo_out, &clamp_hi_out, &v_shift, &offset); neg_shift_neon(&u[15], &u[7], out + 10, out + 11, &clamp_lo_out, &clamp_hi_out, &v_shift, &offset); neg_shift_neon(&u[5], &u[13], out + 12, out + 13, &clamp_lo_out, &clamp_hi_out, &v_shift, &offset); neg_shift_neon(&u[9], &u[1], out + 14, out + 15, &clamp_lo_out, &clamp_hi_out, &v_shift, &offset); } } static void idct16x16_neon(int32x4_t *in, int32x4_t *out, int bit, int do_cols, int bd, int out_shift) { const int32_t *cospi = cospi_arr(bit); const int log_range = AOMMAX(16, bd + (do_cols ? 6 : 8)); const int32x4_t clamp_lo = vdupq_n_s32(-(1 << (log_range - 1))); const int32x4_t clamp_hi = vdupq_n_s32((1 << (log_range - 1)) - 1); int32x4_t u[16], v[16], x, y; const int32x4_t v_bit = vdupq_n_s32(-bit); const int32x4_t rnding = vdupq_n_s32(1 << (bit - 1)); { // stage 0-1 u[0] = in[0]; u[1] = in[8]; u[2] = in[4]; u[3] = in[12]; u[4] = in[2]; u[5] = in[10]; u[6] = in[6]; u[7] = in[14]; u[8] = in[1]; u[9] = in[9]; u[10] = in[5]; u[11] = in[13]; u[12] = in[3]; u[13] = in[11]; u[14] = in[7]; u[15] = in[15]; // stage 2 v[0] = u[0]; v[1] = u[1]; v[2] = u[2]; v[3] = u[3]; v[4] = u[4]; v[5] = u[5]; v[6] = u[6]; v[7] = u[7]; v[8] = half_btf_neon_mode01_r(&cospi[60], &u[8], &cospi[4], &u[15], &v_bit, &rnding); v[9] = half_btf_neon_mode01_r(&cospi[28], &u[9], &cospi[36], &u[14], &v_bit, &rnding); v[10] = half_btf_neon_mode01_r(&cospi[44], &u[10], &cospi[20], &u[13], &v_bit, &rnding); v[11] = half_btf_neon_mode01_r(&cospi[12], &u[11], &cospi[52], &u[12], &v_bit, &rnding); v[12] = half_btf_neon_r(&cospi[52], &u[11], &cospi[12], &u[12], &v_bit, &rnding); v[13] = half_btf_neon_r(&cospi[20], &u[10], &cospi[44], &u[13], &v_bit, &rnding); v[14] = half_btf_neon_r(&cospi[36], &u[9], &cospi[28], &u[14], &v_bit, &rnding); v[15] = half_btf_neon_r(&cospi[4], &u[8], &cospi[60], &u[15], &v_bit, &rnding); // stage 3 u[0] = v[0]; u[1] = v[1]; u[2] = v[2]; u[3] = v[3]; u[4] = half_btf_neon_mode01_r(&cospi[56], &v[4], &cospi[8], &v[7], &v_bit, &rnding); u[5] = half_btf_neon_mode01_r(&cospi[24], &v[5], &cospi[40], &v[6], &v_bit, &rnding); u[6] = half_btf_neon_r(&cospi[40], &v[5], &cospi[24], &v[6], &v_bit, &rnding); u[7] = half_btf_neon_r(&cospi[8], &v[4], &cospi[56], &v[7], &v_bit, &rnding); addsub_neon(v[8], v[9], &u[8], &u[9], &clamp_lo, &clamp_hi); addsub_neon(v[11], v[10], &u[11], &u[10], &clamp_lo, &clamp_hi); addsub_neon(v[12], v[13], &u[12], &u[13], &clamp_lo, &clamp_hi); addsub_neon(v[15], v[14], &u[15], &u[14], &clamp_lo, &clamp_hi); // stage 4 x = vmlaq_n_s32(rnding, u[0], cospi[32]); y = vmulq_n_s32(u[1], cospi[32]); v[0] = vaddq_s32(x, y); v[0] = vshlq_s32(v[0], v_bit); v[1] = vsubq_s32(x, y); v[1] = vshlq_s32(v[1], v_bit); v[2] = half_btf_neon_mode01_r(&cospi[48], &u[2], &cospi[16], &u[3], &v_bit, &rnding); v[3] = half_btf_neon_r(&cospi[16], &u[2], &cospi[48], &u[3], &v_bit, &rnding); addsub_neon(u[4], u[5], &v[4], &v[5], &clamp_lo, &clamp_hi); addsub_neon(u[7], u[6], &v[7], &v[6], &clamp_lo, &clamp_hi); v[8] = u[8]; v[9] = half_btf_neon_mode10_r(&cospi[16], &u[9], &cospi[48], &u[14], &v_bit, &rnding); v[10] = half_btf_neon_mode11_r(&cospi[48], &u[10], &cospi[16], &u[13], &v_bit, &rnding); v[11] = u[11]; v[12] = u[12]; v[13] = half_btf_neon_mode10_r(&cospi[16], &u[10], &cospi[48], &u[13], &v_bit, &rnding); v[14] = half_btf_neon_r(&cospi[48], &u[9], &cospi[16], &u[14], &v_bit, &rnding); v[15] = u[15]; // stage 5 addsub_neon(v[0], v[3], &u[0], &u[3], &clamp_lo, &clamp_hi); addsub_neon(v[1], v[2], &u[1], &u[2], &clamp_lo, &clamp_hi); u[4] = v[4]; x = vmulq_n_s32(v[5], cospi[32]); y = vmlaq_n_s32(rnding, v[6], cospi[32]); u[5] = vsubq_s32(y, x); u[5] = vshlq_s32(u[5], v_bit); u[6] = vaddq_s32(y, x); u[6] = vshlq_s32(u[6], v_bit); u[7] = v[7]; addsub_neon(v[8], v[11], &u[8], &u[11], &clamp_lo, &clamp_hi); addsub_neon(v[9], v[10], &u[9], &u[10], &clamp_lo, &clamp_hi); addsub_neon(v[15], v[12], &u[15], &u[12], &clamp_lo, &clamp_hi); addsub_neon(v[14], v[13], &u[14], &u[13], &clamp_lo, &clamp_hi); // stage 6 addsub_neon(u[0], u[7], &v[0], &v[7], &clamp_lo, &clamp_hi); addsub_neon(u[1], u[6], &v[1], &v[6], &clamp_lo, &clamp_hi); addsub_neon(u[2], u[5], &v[2], &v[5], &clamp_lo, &clamp_hi); addsub_neon(u[3], u[4], &v[3], &v[4], &clamp_lo, &clamp_hi); v[8] = u[8]; v[9] = u[9]; x = vmulq_n_s32(u[10], cospi[32]); y = vmlaq_n_s32(rnding, u[13], cospi[32]); v[10] = vsubq_s32(y, x); v[10] = vshlq_s32(v[10], v_bit); v[13] = vaddq_s32(x, y); v[13] = vshlq_s32(v[13], v_bit); x = vmulq_n_s32(u[11], cospi[32]); y = vmlaq_n_s32(rnding, u[12], cospi[32]); v[11] = vsubq_s32(y, x); v[11] = vshlq_s32(v[11], v_bit); v[12] = vaddq_s32(x, y); v[12] = vshlq_s32(v[12], v_bit); v[14] = u[14]; v[15] = u[15]; // stage 7 addsub_neon(v[0], v[15], out + 0, out + 15, &clamp_lo, &clamp_hi); addsub_neon(v[1], v[14], out + 1, out + 14, &clamp_lo, &clamp_hi); addsub_neon(v[2], v[13], out + 2, out + 13, &clamp_lo, &clamp_hi); addsub_neon(v[3], v[12], out + 3, out + 12, &clamp_lo, &clamp_hi); addsub_neon(v[4], v[11], out + 4, out + 11, &clamp_lo, &clamp_hi); addsub_neon(v[5], v[10], out + 5, out + 10, &clamp_lo, &clamp_hi); addsub_neon(v[6], v[9], out + 6, out + 9, &clamp_lo, &clamp_hi); addsub_neon(v[7], v[8], out + 7, out + 8, &clamp_lo, &clamp_hi); if (!do_cols) { const int log_range_out = AOMMAX(16, bd + 6); const int32x4_t clamp_lo_out = vdupq_n_s32(-(1 << (log_range_out - 1))); const int32x4_t clamp_hi_out = vdupq_n_s32((1 << (log_range_out - 1)) - 1); round_shift_8x8(out, out_shift); highbd_clamp_s32_neon(out, out, &clamp_lo_out, &clamp_hi_out, 16); } } } static void iadst16x16_neon(int32x4_t *in, int32x4_t *out, int bit, int do_cols, int bd, int out_shift) { const int32_t *cospi = cospi_arr(bit); const int log_range = AOMMAX(16, bd + (do_cols ? 6 : 8)); const int32x4_t clamp_lo = vdupq_n_s32(-(1 << (log_range - 1))); const int32x4_t clamp_hi = vdupq_n_s32((1 << (log_range - 1)) - 1); const int32x4_t zero = vdupq_n_s32(0); const int32x4_t v_bit = vdupq_n_s32(-bit); const int32x4_t rnding = vdupq_n_s32(1 << (bit - 1)); int32x4_t u[16], v[16], x, y; // Calculate the column 0, 1, 2, 3 // stage 0 // stage 1 // stage 2 v[0] = vmlaq_n_s32(rnding, in[15], cospi[2]); v[0] = vmlaq_n_s32(v[0], in[0], cospi[62]); v[0] = vshlq_s32(v[0], v_bit); v[1] = vmlaq_n_s32(rnding, in[15], cospi[62]); v[1] = vmlsq_n_s32(v[1], in[0], cospi[2]); v[1] = vshlq_s32(v[1], v_bit); v[2] = vmlaq_n_s32(rnding, in[13], cospi[10]); v[2] = vmlaq_n_s32(v[2], in[2], cospi[54]); v[2] = vshlq_s32(v[2], v_bit); v[3] = vmlaq_n_s32(rnding, in[13], cospi[54]); v[3] = vmlsq_n_s32(v[3], in[2], cospi[10]); v[3] = vshlq_s32(v[3], v_bit); v[4] = vmlaq_n_s32(rnding, in[11], cospi[18]); v[4] = vmlaq_n_s32(v[4], in[4], cospi[46]); v[4] = vshlq_s32(v[4], v_bit); v[5] = vmlaq_n_s32(rnding, in[11], cospi[46]); v[5] = vmlsq_n_s32(v[5], in[4], cospi[18]); v[5] = vshlq_s32(v[5], v_bit); v[6] = vmlaq_n_s32(rnding, in[9], cospi[26]); v[6] = vmlaq_n_s32(v[6], in[6], cospi[38]); v[6] = vshlq_s32(v[6], v_bit); v[7] = vmlaq_n_s32(rnding, in[9], cospi[38]); v[7] = vmlsq_n_s32(v[7], in[6], cospi[26]); v[7] = vshlq_s32(v[7], v_bit); v[8] = vmlaq_n_s32(rnding, in[7], cospi[34]); v[8] = vmlaq_n_s32(v[8], in[8], cospi[30]); v[8] = vshlq_s32(v[8], v_bit); v[9] = vmlaq_n_s32(rnding, in[7], cospi[30]); v[9] = vmlsq_n_s32(v[9], in[8], cospi[34]); v[9] = vshlq_s32(v[9], v_bit); v[10] = vmlaq_n_s32(rnding, in[5], cospi[42]); v[10] = vmlaq_n_s32(v[10], in[10], cospi[22]); v[10] = vshlq_s32(v[10], v_bit); v[11] = vmlaq_n_s32(rnding, in[5], cospi[22]); v[11] = vmlsq_n_s32(v[11], in[10], cospi[42]); v[11] = vshlq_s32(v[11], v_bit); v[12] = vmlaq_n_s32(rnding, in[3], cospi[50]); v[12] = vmlaq_n_s32(v[12], in[12], cospi[14]); v[12] = vshlq_s32(v[12], v_bit); v[13] = vmlaq_n_s32(rnding, in[3], cospi[14]); v[13] = vmlsq_n_s32(v[13], in[12], cospi[50]); v[13] = vshlq_s32(v[13], v_bit); v[14] = vmlaq_n_s32(rnding, in[1], cospi[58]); v[14] = vmlaq_n_s32(v[14], in[14], cospi[6]); v[14] = vshlq_s32(v[14], v_bit); v[15] = vmlaq_n_s32(rnding, in[1], cospi[6]); v[15] = vmlsq_n_s32(v[15], in[14], cospi[58]); v[15] = vshlq_s32(v[15], v_bit); // stage 3 addsub_neon(v[0], v[8], &u[0], &u[8], &clamp_lo, &clamp_hi); addsub_neon(v[1], v[9], &u[1], &u[9], &clamp_lo, &clamp_hi); addsub_neon(v[2], v[10], &u[2], &u[10], &clamp_lo, &clamp_hi); addsub_neon(v[3], v[11], &u[3], &u[11], &clamp_lo, &clamp_hi); addsub_neon(v[4], v[12], &u[4], &u[12], &clamp_lo, &clamp_hi); addsub_neon(v[5], v[13], &u[5], &u[13], &clamp_lo, &clamp_hi); addsub_neon(v[6], v[14], &u[6], &u[14], &clamp_lo, &clamp_hi); addsub_neon(v[7], v[15], &u[7], &u[15], &clamp_lo, &clamp_hi); // stage 4 v[0] = u[0]; v[1] = u[1]; v[2] = u[2]; v[3] = u[3]; v[4] = u[4]; v[5] = u[5]; v[6] = u[6]; v[7] = u[7]; v[8] = vmlaq_n_s32(rnding, u[8], cospi[8]); v[8] = vmlaq_n_s32(v[8], u[9], cospi[56]); v[8] = vshlq_s32(v[8], v_bit); v[9] = vmlaq_n_s32(rnding, u[8], cospi[56]); v[9] = vmlsq_n_s32(v[9], u[9], cospi[8]); v[9] = vshlq_s32(v[9], v_bit); v[10] = vmlaq_n_s32(rnding, u[10], cospi[40]); v[10] = vmlaq_n_s32(v[10], u[11], cospi[24]); v[10] = vshlq_s32(v[10], v_bit); v[11] = vmlaq_n_s32(rnding, u[10], cospi[24]); v[11] = vmlsq_n_s32(v[11], u[11], cospi[40]); v[11] = vshlq_s32(v[11], v_bit); v[12] = vmlaq_n_s32(rnding, u[12], -cospi[56]); v[12] = vmlaq_n_s32(v[12], u[13], cospi[8]); v[12] = vshlq_s32(v[12], v_bit); v[13] = vmlaq_n_s32(rnding, u[12], cospi[8]); v[13] = vmlsq_n_s32(v[13], u[13], -cospi[56]); v[13] = vshlq_s32(v[13], v_bit); v[14] = vmlaq_n_s32(rnding, u[14], -cospi[24]); v[14] = vmlaq_n_s32(v[14], u[15], cospi[40]); v[14] = vshlq_s32(v[14], v_bit); v[15] = vmlaq_n_s32(rnding, u[14], cospi[40]); v[15] = vmlsq_n_s32(v[15], u[15], -cospi[24]); v[15] = vshlq_s32(v[15], v_bit); // stage 5 addsub_neon(v[0], v[4], &u[0], &u[4], &clamp_lo, &clamp_hi); addsub_neon(v[1], v[5], &u[1], &u[5], &clamp_lo, &clamp_hi); addsub_neon(v[2], v[6], &u[2], &u[6], &clamp_lo, &clamp_hi); addsub_neon(v[3], v[7], &u[3], &u[7], &clamp_lo, &clamp_hi); addsub_neon(v[8], v[12], &u[8], &u[12], &clamp_lo, &clamp_hi); addsub_neon(v[9], v[13], &u[9], &u[13], &clamp_lo, &clamp_hi); addsub_neon(v[10], v[14], &u[10], &u[14], &clamp_lo, &clamp_hi); addsub_neon(v[11], v[15], &u[11], &u[15], &clamp_lo, &clamp_hi); // stage 6 v[0] = u[0]; v[1] = u[1]; v[2] = u[2]; v[3] = u[3]; v[4] = vmlaq_n_s32(rnding, u[4], cospi[16]); v[4] = vmlaq_n_s32(v[4], u[5], cospi[48]); v[4] = vshlq_s32(v[4], v_bit); v[5] = vmlaq_n_s32(rnding, u[4], cospi[48]); v[5] = vmlsq_n_s32(v[5], u[5], cospi[16]); v[5] = vshlq_s32(v[5], v_bit); v[6] = vmlaq_n_s32(rnding, u[6], -cospi[48]); v[6] = vmlaq_n_s32(v[6], u[7], cospi[16]); v[6] = vshlq_s32(v[6], v_bit); v[7] = vmlaq_n_s32(rnding, u[6], cospi[16]); v[7] = vmlsq_n_s32(v[7], u[7], -cospi[48]); v[7] = vshlq_s32(v[7], v_bit); v[8] = u[8]; v[9] = u[9]; v[10] = u[10]; v[11] = u[11]; v[12] = vmlaq_n_s32(rnding, u[12], cospi[16]); v[12] = vmlaq_n_s32(v[12], u[13], cospi[48]); v[12] = vshlq_s32(v[12], v_bit); v[13] = vmlaq_n_s32(rnding, u[12], cospi[48]); v[13] = vmlsq_n_s32(v[13], u[13], cospi[16]); v[13] = vshlq_s32(v[13], v_bit); v[14] = vmlaq_n_s32(rnding, u[14], -cospi[48]); v[14] = vmlaq_n_s32(v[14], u[15], cospi[16]); v[14] = vshlq_s32(v[14], v_bit); v[15] = vmlaq_n_s32(rnding, u[14], cospi[16]); v[15] = vmlsq_n_s32(v[15], u[15], -cospi[48]); v[15] = vshlq_s32(v[15], v_bit); // stage 7 addsub_neon(v[0], v[2], &u[0], &u[2], &clamp_lo, &clamp_hi); addsub_neon(v[1], v[3], &u[1], &u[3], &clamp_lo, &clamp_hi); addsub_neon(v[4], v[6], &u[4], &u[6], &clamp_lo, &clamp_hi); addsub_neon(v[5], v[7], &u[5], &u[7], &clamp_lo, &clamp_hi); addsub_neon(v[8], v[10], &u[8], &u[10], &clamp_lo, &clamp_hi); addsub_neon(v[9], v[11], &u[9], &u[11], &clamp_lo, &clamp_hi); addsub_neon(v[12], v[14], &u[12], &u[14], &clamp_lo, &clamp_hi); addsub_neon(v[13], v[15], &u[13], &u[15], &clamp_lo, &clamp_hi); // stage 8 v[0] = u[0]; v[1] = u[1]; y = vmlaq_n_s32(rnding, u[2], cospi[32]); x = vmulq_n_s32(u[3], cospi[32]); v[2] = vaddq_s32(y, x); v[2] = vshlq_s32(v[2], v_bit); v[3] = vsubq_s32(y, x); v[3] = vshlq_s32(v[3], v_bit); v[4] = u[4]; v[5] = u[5]; y = vmlaq_n_s32(rnding, u[6], cospi[32]); x = vmulq_n_s32(u[7], cospi[32]); v[6] = vaddq_s32(y, x); v[6] = vshlq_s32(v[6], v_bit); v[7] = vsubq_s32(y, x); v[7] = vshlq_s32(v[7], v_bit); v[8] = u[8]; v[9] = u[9]; y = vmlaq_n_s32(rnding, u[10], cospi[32]); x = vmulq_n_s32(u[11], cospi[32]); v[10] = vaddq_s32(y, x); v[10] = vshlq_s32(v[10], v_bit); v[11] = vsubq_s32(y, x); v[11] = vshlq_s32(v[11], v_bit); v[12] = u[12]; v[13] = u[13]; y = vmlaq_n_s32(rnding, u[14], cospi[32]); x = vmulq_n_s32(u[15], cospi[32]); v[14] = vaddq_s32(y, x); v[14] = vshlq_s32(v[14], v_bit); v[15] = vsubq_s32(y, x); v[15] = vshlq_s32(v[15], v_bit); // stage 9 if (do_cols) { out[0] = v[0]; out[1] = vsubq_s32(zero, v[8]); out[2] = v[12]; out[3] = vsubq_s32(zero, v[4]); out[4] = v[6]; out[5] = vsubq_s32(zero, v[14]); out[6] = v[10]; out[7] = vsubq_s32(zero, v[2]); out[8] = v[3]; out[9] = vsubq_s32(zero, v[11]); out[10] = v[15]; out[11] = vsubq_s32(zero, v[7]); out[12] = v[5]; out[13] = vsubq_s32(zero, v[13]); out[14] = v[9]; out[15] = vsubq_s32(zero, v[1]); } else { const int log_range_out = AOMMAX(16, bd + 6); const int32x4_t clamp_lo_out = vdupq_n_s32(-(1 << (log_range_out - 1))); const int32x4_t clamp_hi_out = vdupq_n_s32((1 << (log_range_out - 1)) - 1); const int32x4_t v_shift = vdupq_n_s32(-out_shift); int32x4_t offset = vdupq_n_s32((1 << out_shift) >> 1); neg_shift_neon(&v[0], &v[8], out + 0, out + 1, &clamp_lo_out, &clamp_hi_out, &v_shift, &offset); neg_shift_neon(&v[12], &v[4], out + 2, out + 3, &clamp_lo_out, &clamp_hi_out, &v_shift, &offset); neg_shift_neon(&v[6], &v[14], out + 4, out + 5, &clamp_lo_out, &clamp_hi_out, &v_shift, &offset); neg_shift_neon(&v[10], &v[2], out + 6, out + 7, &clamp_lo_out, &clamp_hi_out, &v_shift, &offset); neg_shift_neon(&v[3], &v[11], out + 8, out + 9, &clamp_lo_out, &clamp_hi_out, &v_shift, &offset); neg_shift_neon(&v[15], &v[7], out + 10, out + 11, &clamp_lo_out, &clamp_hi_out, &v_shift, &offset); neg_shift_neon(&v[5], &v[13], out + 12, out + 13, &clamp_lo_out, &clamp_hi_out, &v_shift, &offset); neg_shift_neon(&v[9], &v[1], out + 14, out + 15, &clamp_lo_out, &clamp_hi_out, &v_shift, &offset); } } static void iidentity16_neon(int32x4_t *in, int32x4_t *out, int bit, int do_cols, int bd, int out_shift) { (void)bit; int32x2_t fact = vdup_n_s32(2 * NewSqrt2); int32x4x2_t a0; int32x4_t zero = vdupq_n_s32(0); const int64x2_t rnding = vdupq_n_s64(1 << (NewSqrt2Bits - 1)); for (int i = 0; i < 16; i++) { a0.val[0] = vreinterpretq_s32_s64( vmlal_s32(rnding, vmovn_s64(vreinterpretq_s64_s32(in[i])), fact)); a0.val[0] = vreinterpretq_s32_s64( vshrq_n_s64(vreinterpretq_s64_s32(a0.val[0]), NewSqrt2Bits)); a0.val[1] = vextq_s32(in[i], zero, 1); a0.val[1] = vreinterpretq_s32_s64( vmlal_s32(rnding, vmovn_s64(vreinterpretq_s64_s32(a0.val[1])), fact)); a0.val[1] = vreinterpretq_s32_s64( vshrq_n_s64(vreinterpretq_s64_s32(a0.val[1]), NewSqrt2Bits)); a0 = vzipq_s32(a0.val[0], a0.val[1]); #if AOM_ARCH_AARCH64 out[i] = vreinterpretq_s32_s64(vzip1q_s64( vreinterpretq_s64_s32(a0.val[0]), vreinterpretq_s64_s32(a0.val[1]))); #else out[i] = vextq_s32(vextq_s32(a0.val[0], a0.val[0], 2), a0.val[1], 2); #endif } if (!do_cols) { const int log_range = AOMMAX(16, bd + 6); const int32x4_t clamp_lo = vdupq_n_s32(-(1 << (log_range - 1))); const int32x4_t clamp_hi = vdupq_n_s32((1 << (log_range - 1)) - 1); round_shift_8x8(out, out_shift); highbd_clamp_s32_neon(out, out, &clamp_lo, &clamp_hi, 16); } } static inline void idct64_stage8_neon(int32x4_t *u, const int32_t *cospi, const int32x4_t *clamp_lo, const int32x4_t *clamp_hi, const int32x4_t *v_bit, const int32x4_t *rnding) { int i; int32x4_t temp1, temp2, temp3, temp4; temp1 = half_btf_neon_mode10_r(&cospi[32], &u[10], &cospi[32], &u[13], v_bit, rnding); u[13] = half_btf_neon_r(&cospi[32], &u[10], &cospi[32], &u[13], v_bit, rnding); u[10] = temp1; temp2 = half_btf_neon_mode10_r(&cospi[32], &u[11], &cospi[32], &u[12], v_bit, rnding); u[12] = half_btf_neon_r(&cospi[32], &u[11], &cospi[32], &u[12], v_bit, rnding); u[11] = temp2; for (i = 16; i < 20; ++i) { addsub_neon(u[i], u[i ^ 7], &u[i], &u[i ^ 7], clamp_lo, clamp_hi); addsub_neon(u[i ^ 15], u[i ^ 8], &u[i ^ 15], &u[i ^ 8], clamp_lo, clamp_hi); } temp1 = half_btf_neon_mode10_r(&cospi[16], &u[36], &cospi[48], &u[59], v_bit, rnding); temp2 = half_btf_neon_mode10_r(&cospi[16], &u[37], &cospi[48], &u[58], v_bit, rnding); temp3 = half_btf_neon_mode10_r(&cospi[16], &u[38], &cospi[48], &u[57], v_bit, rnding); temp4 = half_btf_neon_mode10_r(&cospi[16], &u[39], &cospi[48], &u[56], v_bit, rnding); u[56] = half_btf_neon_r(&cospi[48], &u[39], &cospi[16], &u[56], v_bit, rnding); u[57] = half_btf_neon_r(&cospi[48], &u[38], &cospi[16], &u[57], v_bit, rnding); u[58] = half_btf_neon_r(&cospi[48], &u[37], &cospi[16], &u[58], v_bit, rnding); u[59] = half_btf_neon_r(&cospi[48], &u[36], &cospi[16], &u[59], v_bit, rnding); u[36] = temp1; u[37] = temp2; u[38] = temp3; u[39] = temp4; temp1 = half_btf_neon_mode11_r(&cospi[48], &u[40], &cospi[16], &u[55], v_bit, rnding); temp2 = half_btf_neon_mode11_r(&cospi[48], &u[41], &cospi[16], &u[54], v_bit, rnding); temp3 = half_btf_neon_mode11_r(&cospi[48], &u[42], &cospi[16], &u[53], v_bit, rnding); temp4 = half_btf_neon_mode11_r(&cospi[48], &u[43], &cospi[16], &u[52], v_bit, rnding); u[52] = half_btf_neon_mode10_r(&cospi[16], &u[43], &cospi[48], &u[52], v_bit, rnding); u[53] = half_btf_neon_mode10_r(&cospi[16], &u[42], &cospi[48], &u[53], v_bit, rnding); u[54] = half_btf_neon_mode10_r(&cospi[16], &u[41], &cospi[48], &u[54], v_bit, rnding); u[55] = half_btf_neon_mode10_r(&cospi[16], &u[40], &cospi[48], &u[55], v_bit, rnding); u[40] = temp1; u[41] = temp2; u[42] = temp3; u[43] = temp4; } static inline void idct64_stage9_neon(int32x4_t *u, const int32_t *cospi, const int32x4_t *clamp_lo, const int32x4_t *clamp_hi, const int32x4_t *v_bit, const int32x4_t *rnding) { int i; int32x4_t temp1, temp2, temp3, temp4; for (i = 0; i < 8; ++i) { addsub_neon(u[i], u[15 - i], &u[i], &u[15 - i], clamp_lo, clamp_hi); } temp1 = half_btf_neon_mode10_r(&cospi[32], &u[20], &cospi[32], &u[27], v_bit, rnding); temp2 = half_btf_neon_mode10_r(&cospi[32], &u[21], &cospi[32], &u[26], v_bit, rnding); temp3 = half_btf_neon_mode10_r(&cospi[32], &u[22], &cospi[32], &u[25], v_bit, rnding); temp4 = half_btf_neon_mode10_r(&cospi[32], &u[23], &cospi[32], &u[24], v_bit, rnding); u[24] = half_btf_neon_r(&cospi[32], &u[23], &cospi[32], &u[24], v_bit, rnding); u[25] = half_btf_neon_r(&cospi[32], &u[22], &cospi[32], &u[25], v_bit, rnding); u[26] = half_btf_neon_r(&cospi[32], &u[21], &cospi[32], &u[26], v_bit, rnding); u[27] = half_btf_neon_r(&cospi[32], &u[20], &cospi[32], &u[27], v_bit, rnding); u[20] = temp1; u[21] = temp2; u[22] = temp3; u[23] = temp4; for (i = 32; i < 40; i++) { addsub_neon(u[i], u[i ^ 15], &u[i], &u[i ^ 15], clamp_lo, clamp_hi); } for (i = 48; i < 56; i++) { addsub_neon(u[i ^ 15], u[i], &u[i ^ 15], &u[i], clamp_lo, clamp_hi); } } static inline void idct64_stage10_neon(int32x4_t *u, const int32_t *cospi, const int32x4_t *clamp_lo, const int32x4_t *clamp_hi, const int32x4_t *v_bit, const int32x4_t *rnding) { int32x4_t temp1, temp2, temp3, temp4; for (int i = 0; i < 16; i++) { addsub_neon(u[i], u[31 - i], &u[i], &u[31 - i], clamp_lo, clamp_hi); } temp1 = half_btf_neon_mode10_r(&cospi[32], &u[40], &cospi[32], &u[55], v_bit, rnding); temp2 = half_btf_neon_mode10_r(&cospi[32], &u[41], &cospi[32], &u[54], v_bit, rnding); temp3 = half_btf_neon_mode10_r(&cospi[32], &u[42], &cospi[32], &u[53], v_bit, rnding); temp4 = half_btf_neon_mode10_r(&cospi[32], &u[43], &cospi[32], &u[52], v_bit, rnding); u[52] = half_btf_neon_r(&cospi[32], &u[43], &cospi[32], &u[52], v_bit, rnding); u[53] = half_btf_neon_r(&cospi[32], &u[42], &cospi[32], &u[53], v_bit, rnding); u[54] = half_btf_neon_r(&cospi[32], &u[41], &cospi[32], &u[54], v_bit, rnding); u[55] = half_btf_neon_r(&cospi[32], &u[40], &cospi[32], &u[55], v_bit, rnding); u[40] = temp1; u[41] = temp2; u[42] = temp3; u[43] = temp4; temp1 = half_btf_neon_mode10_r(&cospi[32], &u[44], &cospi[32], &u[51], v_bit, rnding); temp2 = half_btf_neon_mode10_r(&cospi[32], &u[45], &cospi[32], &u[50], v_bit, rnding); temp3 = half_btf_neon_mode10_r(&cospi[32], &u[46], &cospi[32], &u[49], v_bit, rnding); temp4 = half_btf_neon_mode10_r(&cospi[32], &u[47], &cospi[32], &u[48], v_bit, rnding); u[48] = half_btf_neon_r(&cospi[32], &u[47], &cospi[32], &u[48], v_bit, rnding); u[49] = half_btf_neon_r(&cospi[32], &u[46], &cospi[32], &u[49], v_bit, rnding); u[50] = half_btf_neon_r(&cospi[32], &u[45], &cospi[32], &u[50], v_bit, rnding); u[51] = half_btf_neon_r(&cospi[32], &u[44], &cospi[32], &u[51], v_bit, rnding); u[44] = temp1; u[45] = temp2; u[46] = temp3; u[47] = temp4; } static inline void idct64_stage11_neon(int32x4_t *u, int32x4_t *out, int do_cols, int bd, int out_shift, const int32x4_t *clamp_lo, const int32x4_t *clamp_hi) { for (int i = 0; i < 32; i++) { addsub_neon(u[i], u[63 - i], out + i, out + 63 - i, clamp_lo, clamp_hi); } if (!do_cols) { const int log_range_out = AOMMAX(16, bd + 6); const int32x4_t clamp_lo_out = vdupq_n_s32(-(1 << (log_range_out - 1))); const int32x4_t clamp_hi_out = vdupq_n_s32((1 << (log_range_out - 1)) - 1); for (int i = 0; i < 64; i += 4) { round_shift_4x4(out + i, out_shift); highbd_clamp_s32_neon(out + i, out + i, &clamp_lo_out, &clamp_hi_out, 4); } } } static void idct64x64_low1_neon(int32x4_t *in, int32x4_t *out, int bit, int do_cols, int bd, int out_shift) { const int32_t *cospi = cospi_arr(bit); const int log_range = AOMMAX(16, bd + (do_cols ? 6 : 8)); int32x4_t clamp_lo = vdupq_n_s32(-(1 << (log_range - 1))); int32x4_t clamp_hi = vdupq_n_s32((1 << (log_range - 1)) - 1); const int32x4_t v_bit = vdupq_n_s32(-bit); const int32x4_t rnding = vdupq_n_s32(1 << (bit - 1)); { int32x4_t x; // stage 1 // stage 2 // stage 3 // stage 4 // stage 5 // stage 6 x = half_btf_0_neon_r(&cospi[32], &in[0], &v_bit, &rnding); // stage 8 // stage 9 // stage 10 // stage 11 if (!do_cols) { const int log_range_out = AOMMAX(16, bd + 6); clamp_lo = vdupq_n_s32(-(1 << (log_range_out - 1))); clamp_hi = vdupq_n_s32((1 << (log_range_out - 1)) - 1); if (out_shift != 0) { int32x4_t offset = vdupq_n_s32((1 << out_shift) >> 1); x = vaddq_s32(x, offset); x = vshlq_s32(x, vdupq_n_s32(-out_shift)); } } x = vmaxq_s32(x, clamp_lo); x = vminq_s32(x, clamp_hi); out[0] = x; out[1] = x; out[2] = x; out[3] = x; out[4] = x; out[5] = x; out[6] = x; out[7] = x; out[8] = x; out[9] = x; out[10] = x; out[11] = x; out[12] = x; out[13] = x; out[14] = x; out[15] = x; out[16] = x; out[17] = x; out[18] = x; out[19] = x; out[20] = x; out[21] = x; out[22] = x; out[23] = x; out[24] = x; out[25] = x; out[26] = x; out[27] = x; out[28] = x; out[29] = x; out[30] = x; out[31] = x; out[32] = x; out[33] = x; out[34] = x; out[35] = x; out[36] = x; out[37] = x; out[38] = x; out[39] = x; out[40] = x; out[41] = x; out[42] = x; out[43] = x; out[44] = x; out[45] = x; out[46] = x; out[47] = x; out[48] = x; out[49] = x; out[50] = x; out[51] = x; out[52] = x; out[53] = x; out[54] = x; out[55] = x; out[56] = x; out[57] = x; out[58] = x; out[59] = x; out[60] = x; out[61] = x; out[62] = x; out[63] = x; } } static void idct64x64_low8_neon(int32x4_t *in, int32x4_t *out, int bit, int do_cols, int bd, int out_shift) { int i, j; const int32_t *cospi = cospi_arr(bit); const int log_range = AOMMAX(16, bd + (do_cols ? 6 : 8)); const int32x4_t clamp_lo = vdupq_n_s32(-(1 << (log_range - 1))); const int32x4_t clamp_hi = vdupq_n_s32((1 << (log_range - 1)) - 1); const int32x4_t v_bit = vdupq_n_s32(-bit); const int32x4_t rnding = vdupq_n_s32(1 << (bit - 1)); { int32x4_t u[64]; // stage 1 u[0] = in[0]; u[8] = in[4]; u[16] = in[2]; u[24] = in[6]; u[32] = in[1]; u[40] = in[5]; u[48] = in[3]; u[56] = in[7]; // stage 2 u[63] = half_btf_0_neon_r(&cospi[1], &u[32], &v_bit, &rnding); u[32] = half_btf_0_neon_r(&cospi[63], &u[32], &v_bit, &rnding); u[39] = half_btf_0_m_neon_r(&cospi[57], &u[56], &v_bit, &rnding); u[56] = half_btf_0_neon_r(&cospi[7], &u[56], &v_bit, &rnding); u[55] = half_btf_0_neon_r(&cospi[5], &u[40], &v_bit, &rnding); u[40] = half_btf_0_neon_r(&cospi[59], &u[40], &v_bit, &rnding); u[47] = half_btf_0_m_neon_r(&cospi[61], &u[48], &v_bit, &rnding); u[48] = half_btf_0_neon_r(&cospi[3], &u[48], &v_bit, &rnding); // stage 3 u[31] = half_btf_0_neon_r(&cospi[2], &u[16], &v_bit, &rnding); u[16] = half_btf_0_neon_r(&cospi[62], &u[16], &v_bit, &rnding); u[23] = half_btf_0_m_neon_r(&cospi[58], &u[24], &v_bit, &rnding); u[24] = half_btf_0_neon_r(&cospi[6], &u[24], &v_bit, &rnding); u[33] = u[32]; u[38] = u[39]; u[41] = u[40]; u[46] = u[47]; u[49] = u[48]; u[54] = u[55]; u[57] = u[56]; u[62] = u[63]; // stage 4 int32x4_t temp1, temp2; u[15] = half_btf_0_neon_r(&cospi[4], &u[8], &v_bit, &rnding); u[8] = half_btf_0_neon_r(&cospi[60], &u[8], &v_bit, &rnding); u[17] = u[16]; u[22] = u[23]; u[25] = u[24]; u[30] = u[31]; temp1 = half_btf_neon_mode10_r(&cospi[4], &u[33], &cospi[60], &u[62], &v_bit, &rnding); u[62] = half_btf_neon_r(&cospi[60], &u[33], &cospi[4], &u[62], &v_bit, &rnding); u[33] = temp1; temp2 = half_btf_neon_mode10_r(&cospi[36], &u[38], &cospi[28], &u[57], &v_bit, &rnding); u[38] = half_btf_neon_mode11_r(&cospi[28], &u[38], &cospi[36], &u[57], &v_bit, &rnding); u[57] = temp2; temp1 = half_btf_neon_mode10_r(&cospi[20], &u[41], &cospi[44], &u[54], &v_bit, &rnding); u[54] = half_btf_neon_r(&cospi[44], &u[41], &cospi[20], &u[54], &v_bit, &rnding); u[41] = temp1; temp2 = half_btf_neon_mode11_r(&cospi[12], &u[46], &cospi[52], &u[49], &v_bit, &rnding); u[49] = half_btf_neon_mode10_r(&cospi[52], &u[46], &cospi[12], &u[49], &v_bit, &rnding); u[46] = temp2; // stage 5 u[9] = u[8]; u[14] = u[15]; temp1 = half_btf_neon_mode10_r(&cospi[8], &u[17], &cospi[56], &u[30], &v_bit, &rnding); u[30] = half_btf_neon_r(&cospi[56], &u[17], &cospi[8], &u[30], &v_bit, &rnding); u[17] = temp1; temp2 = half_btf_neon_mode11_r(&cospi[24], &u[22], &cospi[40], &u[25], &v_bit, &rnding); u[25] = half_btf_neon_mode10_r(&cospi[40], &u[22], &cospi[24], &u[25], &v_bit, &rnding); u[22] = temp2; u[35] = u[32]; u[34] = u[33]; u[36] = u[39]; u[37] = u[38]; u[43] = u[40]; u[42] = u[41]; u[44] = u[47]; u[45] = u[46]; u[51] = u[48]; u[50] = u[49]; u[52] = u[55]; u[53] = u[54]; u[59] = u[56]; u[58] = u[57]; u[60] = u[63]; u[61] = u[62]; // stage 6 temp1 = half_btf_0_neon_r(&cospi[32], &u[0], &v_bit, &rnding); u[1] = half_btf_0_neon_r(&cospi[32], &u[0], &v_bit, &rnding); u[0] = temp1; temp2 = half_btf_neon_mode10_r(&cospi[16], &u[9], &cospi[48], &u[14], &v_bit, &rnding); u[14] = half_btf_neon_r(&cospi[48], &u[9], &cospi[16], &u[14], &v_bit, &rnding); u[9] = temp2; u[19] = u[16]; u[18] = u[17]; u[20] = u[23]; u[21] = u[22]; u[27] = u[24]; u[26] = u[25]; u[28] = u[31]; u[29] = u[30]; temp1 = half_btf_neon_mode10_r(&cospi[8], &u[34], &cospi[56], &u[61], &v_bit, &rnding); u[61] = half_btf_neon_r(&cospi[56], &u[34], &cospi[8], &u[61], &v_bit, &rnding); u[34] = temp1; temp2 = half_btf_neon_mode10_r(&cospi[8], &u[35], &cospi[56], &u[60], &v_bit, &rnding); u[60] = half_btf_neon_r(&cospi[56], &u[35], &cospi[8], &u[60], &v_bit, &rnding); u[35] = temp2; temp1 = half_btf_neon_mode11_r(&cospi[56], &u[36], &cospi[8], &u[59], &v_bit, &rnding); u[59] = half_btf_neon_mode10_r(&cospi[8], &u[36], &cospi[56], &u[59], &v_bit, &rnding); u[36] = temp1; temp2 = half_btf_neon_mode11_r(&cospi[56], &u[37], &cospi[8], &u[58], &v_bit, &rnding); u[58] = half_btf_neon_mode10_r(&cospi[8], &u[37], &cospi[56], &u[58], &v_bit, &rnding); u[37] = temp2; temp1 = half_btf_neon_mode10_r(&cospi[40], &u[42], &cospi[24], &u[53], &v_bit, &rnding); u[53] = half_btf_neon_r(&cospi[24], &u[42], &cospi[40], &u[53], &v_bit, &rnding); u[42] = temp1; temp2 = half_btf_neon_mode10_r(&cospi[40], &u[43], &cospi[24], &u[52], &v_bit, &rnding); u[52] = half_btf_neon_r(&cospi[24], &u[43], &cospi[40], &u[52], &v_bit, &rnding); u[43] = temp2; temp1 = half_btf_neon_mode11_r(&cospi[24], &u[44], &cospi[40], &u[51], &v_bit, &rnding); u[51] = half_btf_neon_mode10_r(&cospi[40], &u[44], &cospi[24], &u[51], &v_bit, &rnding); u[44] = temp1; temp2 = half_btf_neon_mode11_r(&cospi[24], &u[45], &cospi[40], &u[50], &v_bit, &rnding); u[50] = half_btf_neon_mode10_r(&cospi[40], &u[45], &cospi[24], &u[50], &v_bit, &rnding); u[45] = temp2; // stage 7 u[3] = u[0]; u[2] = u[1]; u[11] = u[8]; u[10] = u[9]; u[12] = u[15]; u[13] = u[14]; temp1 = half_btf_neon_mode10_r(&cospi[16], &u[18], &cospi[48], &u[29], &v_bit, &rnding); u[29] = half_btf_neon_r(&cospi[48], &u[18], &cospi[16], &u[29], &v_bit, &rnding); u[18] = temp1; temp2 = half_btf_neon_mode10_r(&cospi[16], &u[19], &cospi[48], &u[28], &v_bit, &rnding); u[28] = half_btf_neon_r(&cospi[48], &u[19], &cospi[16], &u[28], &v_bit, &rnding); u[19] = temp2; temp1 = half_btf_neon_mode11_r(&cospi[48], &u[20], &cospi[16], &u[27], &v_bit, &rnding); u[27] = half_btf_neon_mode10_r(&cospi[16], &u[20], &cospi[48], &u[27], &v_bit, &rnding); u[20] = temp1; temp2 = half_btf_neon_mode11_r(&cospi[48], &u[21], &cospi[16], &u[26], &v_bit, &rnding); u[26] = half_btf_neon_mode10_r(&cospi[16], &u[21], &cospi[48], &u[26], &v_bit, &rnding); u[21] = temp2; for (i = 32; i < 64; i += 16) { for (j = i; j < i + 4; j++) { addsub_neon(u[j], u[j ^ 7], &u[j], &u[j ^ 7], &clamp_lo, &clamp_hi); addsub_neon(u[j ^ 15], u[j ^ 8], &u[j ^ 15], &u[j ^ 8], &clamp_lo, &clamp_hi); } } // stage 8 u[7] = u[0]; u[6] = u[1]; u[5] = u[2]; u[4] = u[3]; u[9] = u[9]; idct64_stage8_neon(u, cospi, &clamp_lo, &clamp_hi, &v_bit, &rnding); // stage 9 idct64_stage9_neon(u, cospi, &clamp_lo, &clamp_hi, &v_bit, &rnding); // stage 10 idct64_stage10_neon(u, cospi, &clamp_lo, &clamp_hi, &v_bit, &rnding); // stage 11 idct64_stage11_neon(u, out, do_cols, bd, out_shift, &clamp_lo, &clamp_hi); } } static void idct64x64_low16_neon(int32x4_t *in, int32x4_t *out, int bit, int do_cols, int bd, int out_shift) { int i, j; const int32_t *cospi = cospi_arr(bit); const int log_range = AOMMAX(16, bd + (do_cols ? 6 : 8)); const int32x4_t clamp_lo = vdupq_n_s32(-(1 << (log_range - 1))); const int32x4_t clamp_hi = vdupq_n_s32((1 << (log_range - 1)) - 1); const int32x4_t v_bit = vdupq_n_s32(-bit); const int32x4_t rnding = vdupq_n_s32(1 << (bit - 1)); { int32x4_t u[64]; int32x4_t tmp1, tmp2, tmp3, tmp4; // stage 1 u[0] = in[0]; u[32] = in[1]; u[36] = in[9]; u[40] = in[5]; u[44] = in[13]; u[48] = in[3]; u[52] = in[11]; u[56] = in[7]; u[60] = in[15]; u[16] = in[2]; u[20] = in[10]; u[24] = in[6]; u[28] = in[14]; u[4] = in[8]; u[8] = in[4]; u[12] = in[12]; // stage 2 u[63] = half_btf_0_neon_r(&cospi[1], &u[32], &v_bit, &rnding); u[32] = half_btf_0_neon_r(&cospi[63], &u[32], &v_bit, &rnding); u[35] = half_btf_0_m_neon_r(&cospi[49], &u[60], &v_bit, &rnding); u[60] = half_btf_0_neon_r(&cospi[15], &u[60], &v_bit, &rnding); u[59] = half_btf_0_neon_r(&cospi[9], &u[36], &v_bit, &rnding); u[36] = half_btf_0_neon_r(&cospi[55], &u[36], &v_bit, &rnding); u[39] = half_btf_0_m_neon_r(&cospi[57], &u[56], &v_bit, &rnding); u[56] = half_btf_0_neon_r(&cospi[7], &u[56], &v_bit, &rnding); u[55] = half_btf_0_neon_r(&cospi[5], &u[40], &v_bit, &rnding); u[40] = half_btf_0_neon_r(&cospi[59], &u[40], &v_bit, &rnding); u[43] = half_btf_0_m_neon_r(&cospi[53], &u[52], &v_bit, &rnding); u[52] = half_btf_0_neon_r(&cospi[11], &u[52], &v_bit, &rnding); u[47] = half_btf_0_m_neon_r(&cospi[61], &u[48], &v_bit, &rnding); u[48] = half_btf_0_neon_r(&cospi[3], &u[48], &v_bit, &rnding); u[51] = half_btf_0_neon_r(&cospi[13], &u[44], &v_bit, &rnding); u[44] = half_btf_0_neon_r(&cospi[51], &u[44], &v_bit, &rnding); // stage 3 u[31] = half_btf_0_neon_r(&cospi[2], &u[16], &v_bit, &rnding); u[16] = half_btf_0_neon_r(&cospi[62], &u[16], &v_bit, &rnding); u[19] = half_btf_0_m_neon_r(&cospi[50], &u[28], &v_bit, &rnding); u[28] = half_btf_0_neon_r(&cospi[14], &u[28], &v_bit, &rnding); u[27] = half_btf_0_neon_r(&cospi[10], &u[20], &v_bit, &rnding); u[20] = half_btf_0_neon_r(&cospi[54], &u[20], &v_bit, &rnding); u[23] = half_btf_0_m_neon_r(&cospi[58], &u[24], &v_bit, &rnding); u[24] = half_btf_0_neon_r(&cospi[6], &u[24], &v_bit, &rnding); u[33] = u[32]; u[34] = u[35]; u[37] = u[36]; u[38] = u[39]; u[41] = u[40]; u[42] = u[43]; u[45] = u[44]; u[46] = u[47]; u[49] = u[48]; u[50] = u[51]; u[53] = u[52]; u[54] = u[55]; u[57] = u[56]; u[58] = u[59]; u[61] = u[60]; u[62] = u[63]; // stage 4 u[15] = half_btf_0_neon_r(&cospi[4], &u[8], &v_bit, &rnding); u[8] = half_btf_0_neon_r(&cospi[60], &u[8], &v_bit, &rnding); u[11] = half_btf_0_m_neon_r(&cospi[52], &u[12], &v_bit, &rnding); u[12] = half_btf_0_neon_r(&cospi[12], &u[12], &v_bit, &rnding); u[17] = u[16]; u[18] = u[19]; u[21] = u[20]; u[22] = u[23]; u[25] = u[24]; u[26] = u[27]; u[29] = u[28]; u[30] = u[31]; tmp1 = half_btf_neon_mode10_r(&cospi[4], &u[33], &cospi[60], &u[62], &v_bit, &rnding); tmp2 = half_btf_neon_mode11_r(&cospi[60], &u[34], &cospi[4], &u[61], &v_bit, &rnding); tmp3 = half_btf_neon_mode10_r(&cospi[36], &u[37], &cospi[28], &u[58], &v_bit, &rnding); tmp4 = half_btf_neon_mode11_r(&cospi[28], &u[38], &cospi[36], &u[57], &v_bit, &rnding); u[57] = half_btf_neon_mode10_r(&cospi[36], &u[38], &cospi[28], &u[57], &v_bit, &rnding); u[58] = half_btf_neon_r(&cospi[28], &u[37], &cospi[36], &u[58], &v_bit, &rnding); u[61] = half_btf_neon_mode10_r(&cospi[4], &u[34], &cospi[60], &u[61], &v_bit, &rnding); u[62] = half_btf_neon_r(&cospi[60], &u[33], &cospi[4], &u[62], &v_bit, &rnding); u[33] = tmp1; u[34] = tmp2; u[37] = tmp3; u[38] = tmp4; tmp1 = half_btf_neon_mode10_r(&cospi[20], &u[41], &cospi[44], &u[54], &v_bit, &rnding); tmp2 = half_btf_neon_mode11_r(&cospi[44], &u[42], &cospi[20], &u[53], &v_bit, &rnding); tmp3 = half_btf_neon_r(&cospi[52], &u[45], &cospi[12], &u[50], &v_bit, &rnding); tmp4 = half_btf_neon_mode11_r(&cospi[12], &u[46], &cospi[52], &u[49], &v_bit, &rnding); u[49] = half_btf_neon_mode10_r(&cospi[52], &u[46], &cospi[12], &u[49], &v_bit, &rnding); u[50] = half_btf_neon_r(&cospi[12], &u[45], &cospi[52], &u[50], &v_bit, &rnding); u[53] = half_btf_neon_mode10_r(&cospi[20], &u[42], &cospi[44], &u[53], &v_bit, &rnding); u[54] = half_btf_neon_r(&cospi[44], &u[41], &cospi[20], &u[54], &v_bit, &rnding); u[41] = tmp1; u[42] = tmp2; u[45] = tmp3; u[46] = tmp4; // stage 5 u[7] = half_btf_0_neon_r(&cospi[8], &u[4], &v_bit, &rnding); u[4] = half_btf_0_neon_r(&cospi[56], &u[4], &v_bit, &rnding); u[9] = u[8]; u[10] = u[11]; u[13] = u[12]; u[14] = u[15]; tmp1 = half_btf_neon_mode10_r(&cospi[8], &u[17], &cospi[56], &u[30], &v_bit, &rnding); tmp2 = half_btf_neon_mode11_r(&cospi[56], &u[18], &cospi[8], &u[29], &v_bit, &rnding); tmp3 = half_btf_neon_mode10_r(&cospi[40], &u[21], &cospi[24], &u[26], &v_bit, &rnding); tmp4 = half_btf_neon_mode11_r(&cospi[24], &u[22], &cospi[40], &u[25], &v_bit, &rnding); u[25] = half_btf_neon_mode10_r(&cospi[40], &u[22], &cospi[24], &u[25], &v_bit, &rnding); u[26] = half_btf_neon_r(&cospi[24], &u[21], &cospi[40], &u[26], &v_bit, &rnding); u[29] = half_btf_neon_mode10_r(&cospi[8], &u[18], &cospi[56], &u[29], &v_bit, &rnding); u[30] = half_btf_neon_r(&cospi[56], &u[17], &cospi[8], &u[30], &v_bit, &rnding); u[17] = tmp1; u[18] = tmp2; u[21] = tmp3; u[22] = tmp4; for (i = 32; i < 64; i += 8) { addsub_neon(u[i + 0], u[i + 3], &u[i + 0], &u[i + 3], &clamp_lo, &clamp_hi); addsub_neon(u[i + 1], u[i + 2], &u[i + 1], &u[i + 2], &clamp_lo, &clamp_hi); addsub_neon(u[i + 7], u[i + 4], &u[i + 7], &u[i + 4], &clamp_lo, &clamp_hi); addsub_neon(u[i + 6], u[i + 5], &u[i + 6], &u[i + 5], &clamp_lo, &clamp_hi); } // stage 6 tmp1 = half_btf_0_neon_r(&cospi[32], &u[0], &v_bit, &rnding); u[1] = half_btf_0_neon_r(&cospi[32], &u[0], &v_bit, &rnding); u[0] = tmp1; u[5] = u[4]; u[6] = u[7]; tmp1 = half_btf_neon_mode10_r(&cospi[16], &u[9], &cospi[48], &u[14], &v_bit, &rnding); u[14] = half_btf_neon_r(&cospi[48], &u[9], &cospi[16], &u[14], &v_bit, &rnding); u[9] = tmp1; tmp2 = half_btf_neon_mode01_r(&cospi[48], &u[10], &cospi[16], &u[13], &v_bit, &rnding); u[13] = half_btf_neon_mode10_r(&cospi[16], &u[10], &cospi[48], &u[13], &v_bit, &rnding); u[10] = tmp2; for (i = 16; i < 32; i += 8) { addsub_neon(u[i + 0], u[i + 3], &u[i + 0], &u[i + 3], &clamp_lo, &clamp_hi); addsub_neon(u[i + 1], u[i + 2], &u[i + 1], &u[i + 2], &clamp_lo, &clamp_hi); addsub_neon(u[i + 7], u[i + 4], &u[i + 7], &u[i + 4], &clamp_lo, &clamp_hi); addsub_neon(u[i + 6], u[i + 5], &u[i + 6], &u[i + 5], &clamp_lo, &clamp_hi); } tmp1 = half_btf_neon_mode10_r(&cospi[8], &u[34], &cospi[56], &u[61], &v_bit, &rnding); tmp2 = half_btf_neon_mode10_r(&cospi[8], &u[35], &cospi[56], &u[60], &v_bit, &rnding); tmp3 = half_btf_neon_mode11_r(&cospi[56], &u[36], &cospi[8], &u[59], &v_bit, &rnding); tmp4 = half_btf_neon_mode11_r(&cospi[56], &u[37], &cospi[8], &u[58], &v_bit, &rnding); u[58] = half_btf_neon_mode10_r(&cospi[8], &u[37], &cospi[56], &u[58], &v_bit, &rnding); u[59] = half_btf_neon_mode10_r(&cospi[8], &u[36], &cospi[56], &u[59], &v_bit, &rnding); u[60] = half_btf_neon_r(&cospi[56], &u[35], &cospi[8], &u[60], &v_bit, &rnding); u[61] = half_btf_neon_r(&cospi[56], &u[34], &cospi[8], &u[61], &v_bit, &rnding); u[34] = tmp1; u[35] = tmp2; u[36] = tmp3; u[37] = tmp4; tmp1 = half_btf_neon_mode10_r(&cospi[40], &u[42], &cospi[24], &u[53], &v_bit, &rnding); tmp2 = half_btf_neon_mode10_r(&cospi[40], &u[43], &cospi[24], &u[52], &v_bit, &rnding); tmp3 = half_btf_neon_mode11_r(&cospi[24], &u[44], &cospi[40], &u[51], &v_bit, &rnding); tmp4 = half_btf_neon_mode11_r(&cospi[24], &u[45], &cospi[40], &u[50], &v_bit, &rnding); u[50] = half_btf_neon_mode10_r(&cospi[40], &u[45], &cospi[24], &u[50], &v_bit, &rnding); u[51] = half_btf_neon_mode10_r(&cospi[40], &u[44], &cospi[24], &u[51], &v_bit, &rnding); u[52] = half_btf_neon_r(&cospi[24], &u[43], &cospi[40], &u[52], &v_bit, &rnding); u[53] = half_btf_neon_r(&cospi[24], &u[42], &cospi[40], &u[53], &v_bit, &rnding); u[42] = tmp1; u[43] = tmp2; u[44] = tmp3; u[45] = tmp4; // stage 7 u[3] = u[0]; u[2] = u[1]; tmp1 = half_btf_neon_mode10_r(&cospi[32], &u[5], &cospi[32], &u[6], &v_bit, &rnding); u[6] = half_btf_neon_r(&cospi[32], &u[5], &cospi[32], &u[6], &v_bit, &rnding); u[5] = tmp1; addsub_neon(u[8], u[11], &u[8], &u[11], &clamp_lo, &clamp_hi); addsub_neon(u[9], u[10], &u[9], &u[10], &clamp_lo, &clamp_hi); addsub_neon(u[15], u[12], &u[15], &u[12], &clamp_lo, &clamp_hi); addsub_neon(u[14], u[13], &u[14], &u[13], &clamp_lo, &clamp_hi); tmp1 = half_btf_neon_mode10_r(&cospi[16], &u[18], &cospi[48], &u[29], &v_bit, &rnding); tmp2 = half_btf_neon_mode10_r(&cospi[16], &u[19], &cospi[48], &u[28], &v_bit, &rnding); tmp3 = half_btf_neon_mode11_r(&cospi[48], &u[20], &cospi[16], &u[27], &v_bit, &rnding); tmp4 = half_btf_neon_mode11_r(&cospi[48], &u[21], &cospi[16], &u[26], &v_bit, &rnding); u[26] = half_btf_neon_mode10_r(&cospi[16], &u[21], &cospi[48], &u[26], &v_bit, &rnding); u[27] = half_btf_neon_mode10_r(&cospi[16], &u[20], &cospi[48], &u[27], &v_bit, &rnding); u[28] = half_btf_neon_r(&cospi[48], &u[19], &cospi[16], &u[28], &v_bit, &rnding); u[29] = half_btf_neon_r(&cospi[48], &u[18], &cospi[16], &u[29], &v_bit, &rnding); u[18] = tmp1; u[19] = tmp2; u[20] = tmp3; u[21] = tmp4; for (i = 32; i < 64; i += 16) { for (j = i; j < i + 4; j++) { addsub_neon(u[j], u[j ^ 7], &u[j], &u[j ^ 7], &clamp_lo, &clamp_hi); addsub_neon(u[j ^ 15], u[j ^ 8], &u[j ^ 15], &u[j ^ 8], &clamp_lo, &clamp_hi); } } // stage 8 for (i = 0; i < 4; ++i) { addsub_neon(u[i], u[7 - i], &u[i], &u[7 - i], &clamp_lo, &clamp_hi); } idct64_stage8_neon(u, cospi, &clamp_lo, &clamp_hi, &v_bit, &rnding); // stage 9 idct64_stage9_neon(u, cospi, &clamp_lo, &clamp_hi, &v_bit, &rnding); // stage 10 idct64_stage10_neon(u, cospi, &clamp_lo, &clamp_hi, &v_bit, &rnding); // stage 11 idct64_stage11_neon(u, out, do_cols, bd, out_shift, &clamp_lo, &clamp_hi); } } static void idct64x64_neon(int32x4_t *in, int32x4_t *out, int bit, int do_cols, int bd, int out_shift) { int i, j; const int32_t *cospi = cospi_arr(bit); const int32x4_t v_bit = vdupq_n_s32(-bit); const int32x4_t rnding = vdupq_n_s32(1 << (bit - 1)); const int log_range = AOMMAX(16, bd + (do_cols ? 6 : 8)); const int32x4_t clamp_lo = vdupq_n_s32(-(1 << (log_range - 1))); const int32x4_t clamp_hi = vdupq_n_s32((1 << (log_range - 1)) - 1); { int32x4_t u[64], v[64]; // stage 1 u[32] = in[1]; u[34] = in[17]; u[36] = in[9]; u[38] = in[25]; u[40] = in[5]; u[42] = in[21]; u[44] = in[13]; u[46] = in[29]; u[48] = in[3]; u[50] = in[19]; u[52] = in[11]; u[54] = in[27]; u[56] = in[7]; u[58] = in[23]; u[60] = in[15]; u[62] = in[31]; v[16] = in[2]; v[18] = in[18]; v[20] = in[10]; v[22] = in[26]; v[24] = in[6]; v[26] = in[22]; v[28] = in[14]; v[30] = in[30]; u[8] = in[4]; u[10] = in[20]; u[12] = in[12]; u[14] = in[28]; v[4] = in[8]; v[6] = in[24]; u[0] = in[0]; u[2] = in[16]; // stage 2 v[32] = half_btf_0_neon_r(&cospi[63], &u[32], &v_bit, &rnding); v[33] = half_btf_0_m_neon_r(&cospi[33], &u[62], &v_bit, &rnding); v[34] = half_btf_0_neon_r(&cospi[47], &u[34], &v_bit, &rnding); v[35] = half_btf_0_m_neon_r(&cospi[49], &u[60], &v_bit, &rnding); v[36] = half_btf_0_neon_r(&cospi[55], &u[36], &v_bit, &rnding); v[37] = half_btf_0_m_neon_r(&cospi[41], &u[58], &v_bit, &rnding); v[38] = half_btf_0_neon_r(&cospi[39], &u[38], &v_bit, &rnding); v[39] = half_btf_0_m_neon_r(&cospi[57], &u[56], &v_bit, &rnding); v[40] = half_btf_0_neon_r(&cospi[59], &u[40], &v_bit, &rnding); v[41] = half_btf_0_m_neon_r(&cospi[37], &u[54], &v_bit, &rnding); v[42] = half_btf_0_neon_r(&cospi[43], &u[42], &v_bit, &rnding); v[43] = half_btf_0_m_neon_r(&cospi[53], &u[52], &v_bit, &rnding); v[44] = half_btf_0_neon_r(&cospi[51], &u[44], &v_bit, &rnding); v[45] = half_btf_0_m_neon_r(&cospi[45], &u[50], &v_bit, &rnding); v[46] = half_btf_0_neon_r(&cospi[35], &u[46], &v_bit, &rnding); v[47] = half_btf_0_m_neon_r(&cospi[61], &u[48], &v_bit, &rnding); v[48] = half_btf_0_neon_r(&cospi[3], &u[48], &v_bit, &rnding); v[49] = half_btf_0_neon_r(&cospi[29], &u[46], &v_bit, &rnding); v[50] = half_btf_0_neon_r(&cospi[19], &u[50], &v_bit, &rnding); v[51] = half_btf_0_neon_r(&cospi[13], &u[44], &v_bit, &rnding); v[52] = half_btf_0_neon_r(&cospi[11], &u[52], &v_bit, &rnding); v[53] = half_btf_0_neon_r(&cospi[21], &u[42], &v_bit, &rnding); v[54] = half_btf_0_neon_r(&cospi[27], &u[54], &v_bit, &rnding); v[55] = half_btf_0_neon_r(&cospi[5], &u[40], &v_bit, &rnding); v[56] = half_btf_0_neon_r(&cospi[7], &u[56], &v_bit, &rnding); v[57] = half_btf_0_neon_r(&cospi[25], &u[38], &v_bit, &rnding); v[58] = half_btf_0_neon_r(&cospi[23], &u[58], &v_bit, &rnding); v[59] = half_btf_0_neon_r(&cospi[9], &u[36], &v_bit, &rnding); v[60] = half_btf_0_neon_r(&cospi[15], &u[60], &v_bit, &rnding); v[61] = half_btf_0_neon_r(&cospi[17], &u[34], &v_bit, &rnding); v[62] = half_btf_0_neon_r(&cospi[31], &u[62], &v_bit, &rnding); v[63] = half_btf_0_neon_r(&cospi[1], &u[32], &v_bit, &rnding); // stage 3 u[16] = half_btf_0_neon_r(&cospi[62], &v[16], &v_bit, &rnding); u[17] = half_btf_0_m_neon_r(&cospi[34], &v[30], &v_bit, &rnding); u[18] = half_btf_0_neon_r(&cospi[46], &v[18], &v_bit, &rnding); u[19] = half_btf_0_m_neon_r(&cospi[50], &v[28], &v_bit, &rnding); u[20] = half_btf_0_neon_r(&cospi[54], &v[20], &v_bit, &rnding); u[21] = half_btf_0_m_neon_r(&cospi[42], &v[26], &v_bit, &rnding); u[22] = half_btf_0_neon_r(&cospi[38], &v[22], &v_bit, &rnding); u[23] = half_btf_0_m_neon_r(&cospi[58], &v[24], &v_bit, &rnding); u[24] = half_btf_0_neon_r(&cospi[6], &v[24], &v_bit, &rnding); u[25] = half_btf_0_neon_r(&cospi[26], &v[22], &v_bit, &rnding); u[26] = half_btf_0_neon_r(&cospi[22], &v[26], &v_bit, &rnding); u[27] = half_btf_0_neon_r(&cospi[10], &v[20], &v_bit, &rnding); u[28] = half_btf_0_neon_r(&cospi[14], &v[28], &v_bit, &rnding); u[29] = half_btf_0_neon_r(&cospi[18], &v[18], &v_bit, &rnding); u[30] = half_btf_0_neon_r(&cospi[30], &v[30], &v_bit, &rnding); u[31] = half_btf_0_neon_r(&cospi[2], &v[16], &v_bit, &rnding); for (i = 32; i < 64; i += 4) { addsub_neon(v[i + 0], v[i + 1], &u[i + 0], &u[i + 1], &clamp_lo, &clamp_hi); addsub_neon(v[i + 3], v[i + 2], &u[i + 3], &u[i + 2], &clamp_lo, &clamp_hi); } // stage 4 v[8] = half_btf_0_neon_r(&cospi[60], &u[8], &v_bit, &rnding); v[9] = half_btf_0_m_neon_r(&cospi[36], &u[14], &v_bit, &rnding); v[10] = half_btf_0_neon_r(&cospi[44], &u[10], &v_bit, &rnding); v[11] = half_btf_0_m_neon_r(&cospi[52], &u[12], &v_bit, &rnding); v[12] = half_btf_0_neon_r(&cospi[12], &u[12], &v_bit, &rnding); v[13] = half_btf_0_neon_r(&cospi[20], &u[10], &v_bit, &rnding); v[14] = half_btf_0_neon_r(&cospi[28], &u[14], &v_bit, &rnding); v[15] = half_btf_0_neon_r(&cospi[4], &u[8], &v_bit, &rnding); for (i = 16; i < 32; i += 4) { addsub_neon(u[i + 0], u[i + 1], &v[i + 0], &v[i + 1], &clamp_lo, &clamp_hi); addsub_neon(u[i + 3], u[i + 2], &v[i + 3], &v[i + 2], &clamp_lo, &clamp_hi); } for (i = 32; i < 64; i += 4) { v[i + 0] = u[i + 0]; v[i + 3] = u[i + 3]; } v[33] = half_btf_neon_mode10_r(&cospi[4], &u[33], &cospi[60], &u[62], &v_bit, &rnding); v[34] = half_btf_neon_mode11_r(&cospi[60], &u[34], &cospi[4], &u[61], &v_bit, &rnding); v[37] = half_btf_neon_mode10_r(&cospi[36], &u[37], &cospi[28], &u[58], &v_bit, &rnding); v[38] = half_btf_neon_mode11_r(&cospi[28], &u[38], &cospi[36], &u[57], &v_bit, &rnding); v[41] = half_btf_neon_mode10_r(&cospi[20], &u[41], &cospi[44], &u[54], &v_bit, &rnding); v[42] = half_btf_neon_mode11_r(&cospi[44], &u[42], &cospi[20], &u[53], &v_bit, &rnding); v[45] = half_btf_neon_mode10_r(&cospi[52], &u[45], &cospi[12], &u[50], &v_bit, &rnding); v[46] = half_btf_neon_mode11_r(&cospi[12], &u[46], &cospi[52], &u[49], &v_bit, &rnding); v[49] = half_btf_neon_mode10_r(&cospi[52], &u[46], &cospi[12], &u[49], &v_bit, &rnding); v[50] = half_btf_neon_r(&cospi[12], &u[45], &cospi[52], &u[50], &v_bit, &rnding); v[53] = half_btf_neon_mode10_r(&cospi[20], &u[42], &cospi[44], &u[53], &v_bit, &rnding); v[54] = half_btf_neon_r(&cospi[44], &u[41], &cospi[20], &u[54], &v_bit, &rnding); v[57] = half_btf_neon_mode10_r(&cospi[36], &u[38], &cospi[28], &u[57], &v_bit, &rnding); v[58] = half_btf_neon_r(&cospi[28], &u[37], &cospi[36], &u[58], &v_bit, &rnding); v[61] = half_btf_neon_mode10_r(&cospi[4], &u[34], &cospi[60], &u[61], &v_bit, &rnding); v[62] = half_btf_neon_r(&cospi[60], &u[33], &cospi[4], &u[62], &v_bit, &rnding); // stage 5 u[4] = half_btf_0_neon_r(&cospi[56], &v[4], &v_bit, &rnding); u[5] = half_btf_0_m_neon_r(&cospi[40], &v[6], &v_bit, &rnding); u[6] = half_btf_0_neon_r(&cospi[24], &v[6], &v_bit, &rnding); u[7] = half_btf_0_neon_r(&cospi[8], &v[4], &v_bit, &rnding); for (i = 8; i < 16; i += 4) { addsub_neon(v[i + 0], v[i + 1], &u[i + 0], &u[i + 1], &clamp_lo, &clamp_hi); addsub_neon(v[i + 3], v[i + 2], &u[i + 3], &u[i + 2], &clamp_lo, &clamp_hi); } for (i = 16; i < 32; i += 4) { u[i + 0] = v[i + 0]; u[i + 3] = v[i + 3]; } u[17] = half_btf_neon_mode10_r(&cospi[8], &v[17], &cospi[56], &v[30], &v_bit, &rnding); u[18] = half_btf_neon_mode11_r(&cospi[56], &v[18], &cospi[8], &v[29], &v_bit, &rnding); u[21] = half_btf_neon_mode10_r(&cospi[40], &v[21], &cospi[24], &v[26], &v_bit, &rnding); u[22] = half_btf_neon_mode11_r(&cospi[24], &v[22], &cospi[40], &v[25], &v_bit, &rnding); u[25] = half_btf_neon_mode10_r(&cospi[40], &v[22], &cospi[24], &v[25], &v_bit, &rnding); u[26] = half_btf_neon_r(&cospi[24], &v[21], &cospi[40], &v[26], &v_bit, &rnding); u[29] = half_btf_neon_mode10_r(&cospi[8], &v[18], &cospi[56], &v[29], &v_bit, &rnding); u[30] = half_btf_neon_r(&cospi[56], &v[17], &cospi[8], &v[30], &v_bit, &rnding); for (i = 32; i < 64; i += 8) { addsub_neon(v[i + 0], v[i + 3], &u[i + 0], &u[i + 3], &clamp_lo, &clamp_hi); addsub_neon(v[i + 1], v[i + 2], &u[i + 1], &u[i + 2], &clamp_lo, &clamp_hi); addsub_neon(v[i + 7], v[i + 4], &u[i + 7], &u[i + 4], &clamp_lo, &clamp_hi); addsub_neon(v[i + 6], v[i + 5], &u[i + 6], &u[i + 5], &clamp_lo, &clamp_hi); } // stage 6 v[0] = half_btf_0_neon_r(&cospi[32], &u[0], &v_bit, &rnding); v[1] = half_btf_0_neon_r(&cospi[32], &u[0], &v_bit, &rnding); v[2] = half_btf_0_neon_r(&cospi[48], &u[2], &v_bit, &rnding); v[3] = half_btf_0_neon_r(&cospi[16], &u[2], &v_bit, &rnding); addsub_neon(u[4], u[5], &v[4], &v[5], &clamp_lo, &clamp_hi); addsub_neon(u[7], u[6], &v[7], &v[6], &clamp_lo, &clamp_hi); for (i = 8; i < 16; i += 4) { v[i + 0] = u[i + 0]; v[i + 3] = u[i + 3]; } v[9] = half_btf_neon_mode10_r(&cospi[16], &u[9], &cospi[48], &u[14], &v_bit, &rnding); v[10] = half_btf_neon_mode11_r(&cospi[48], &u[10], &cospi[16], &u[13], &v_bit, &rnding); v[13] = half_btf_neon_mode10_r(&cospi[16], &u[10], &cospi[48], &u[13], &v_bit, &rnding); v[14] = half_btf_neon_r(&cospi[48], &u[9], &cospi[16], &u[14], &v_bit, &rnding); for (i = 16; i < 32; i += 8) { addsub_neon(u[i + 0], u[i + 3], &v[i + 0], &v[i + 3], &clamp_lo, &clamp_hi); addsub_neon(u[i + 1], u[i + 2], &v[i + 1], &v[i + 2], &clamp_lo, &clamp_hi); addsub_neon(u[i + 7], u[i + 4], &v[i + 7], &v[i + 4], &clamp_lo, &clamp_hi); addsub_neon(u[i + 6], u[i + 5], &v[i + 6], &v[i + 5], &clamp_lo, &clamp_hi); } for (i = 32; i < 64; i += 8) { v[i + 0] = u[i + 0]; v[i + 1] = u[i + 1]; v[i + 6] = u[i + 6]; v[i + 7] = u[i + 7]; } v[34] = half_btf_neon_mode10_r(&cospi[8], &u[34], &cospi[56], &u[61], &v_bit, &rnding); v[35] = half_btf_neon_mode10_r(&cospi[8], &u[35], &cospi[56], &u[60], &v_bit, &rnding); v[36] = half_btf_neon_mode11_r(&cospi[56], &u[36], &cospi[8], &u[59], &v_bit, &rnding); v[37] = half_btf_neon_mode11_r(&cospi[56], &u[37], &cospi[8], &u[58], &v_bit, &rnding); v[42] = half_btf_neon_mode10_r(&cospi[40], &u[42], &cospi[24], &u[53], &v_bit, &rnding); v[43] = half_btf_neon_mode10_r(&cospi[40], &u[43], &cospi[24], &u[52], &v_bit, &rnding); v[44] = half_btf_neon_mode11_r(&cospi[24], &u[44], &cospi[40], &u[51], &v_bit, &rnding); v[45] = half_btf_neon_mode11_r(&cospi[24], &u[45], &cospi[40], &u[50], &v_bit, &rnding); v[50] = half_btf_neon_mode10_r(&cospi[40], &u[45], &cospi[24], &u[50], &v_bit, &rnding); v[51] = half_btf_neon_mode10_r(&cospi[40], &u[44], &cospi[24], &u[51], &v_bit, &rnding); v[52] = half_btf_neon_r(&cospi[24], &u[43], &cospi[40], &u[52], &v_bit, &rnding); v[53] = half_btf_neon_r(&cospi[24], &u[42], &cospi[40], &u[53], &v_bit, &rnding); v[58] = half_btf_neon_mode10_r(&cospi[8], &u[37], &cospi[56], &u[58], &v_bit, &rnding); v[59] = half_btf_neon_mode10_r(&cospi[8], &u[36], &cospi[56], &u[59], &v_bit, &rnding); v[60] = half_btf_neon_r(&cospi[56], &u[35], &cospi[8], &u[60], &v_bit, &rnding); v[61] = half_btf_neon_r(&cospi[56], &u[34], &cospi[8], &u[61], &v_bit, &rnding); // stage 7 addsub_neon(v[0], v[3], &u[0], &u[3], &clamp_lo, &clamp_hi); addsub_neon(v[1], v[2], &u[1], &u[2], &clamp_lo, &clamp_hi); u[4] = v[4]; u[7] = v[7]; u[5] = half_btf_neon_mode10_r(&cospi[32], &v[5], &cospi[32], &v[6], &v_bit, &rnding); u[6] = half_btf_neon_r(&cospi[32], &v[5], &cospi[32], &v[6], &v_bit, &rnding); addsub_neon(v[8], v[11], &u[8], &u[11], &clamp_lo, &clamp_hi); addsub_neon(v[9], v[10], &u[9], &u[10], &clamp_lo, &clamp_hi); addsub_neon(v[15], v[12], &u[15], &u[12], &clamp_lo, &clamp_hi); addsub_neon(v[14], v[13], &u[14], &u[13], &clamp_lo, &clamp_hi); for (i = 16; i < 32; i += 8) { u[i + 0] = v[i + 0]; u[i + 1] = v[i + 1]; u[i + 6] = v[i + 6]; u[i + 7] = v[i + 7]; } u[18] = half_btf_neon_mode10_r(&cospi[16], &v[18], &cospi[48], &v[29], &v_bit, &rnding); u[19] = half_btf_neon_mode10_r(&cospi[16], &v[19], &cospi[48], &v[28], &v_bit, &rnding); u[20] = half_btf_neon_mode11_r(&cospi[48], &v[20], &cospi[16], &v[27], &v_bit, &rnding); u[21] = half_btf_neon_mode11_r(&cospi[48], &v[21], &cospi[16], &v[26], &v_bit, &rnding); u[26] = half_btf_neon_mode10_r(&cospi[16], &v[21], &cospi[48], &v[26], &v_bit, &rnding); u[27] = half_btf_neon_mode10_r(&cospi[16], &v[20], &cospi[48], &v[27], &v_bit, &rnding); u[28] = half_btf_neon_r(&cospi[48], &v[19], &cospi[16], &v[28], &v_bit, &rnding); u[29] = half_btf_neon_r(&cospi[48], &v[18], &cospi[16], &v[29], &v_bit, &rnding); for (i = 32; i < 64; i += 16) { for (j = i; j < i + 4; j++) { addsub_neon(v[j], v[j ^ 7], &u[j], &u[j ^ 7], &clamp_lo, &clamp_hi); addsub_neon(v[j ^ 15], v[j ^ 8], &u[j ^ 15], &u[j ^ 8], &clamp_lo, &clamp_hi); } } // stage 8 for (i = 0; i < 4; ++i) { addsub_neon(u[i], u[7 - i], &v[i], &v[7 - i], &clamp_lo, &clamp_hi); } v[8] = u[8]; v[9] = u[9]; v[14] = u[14]; v[15] = u[15]; v[10] = half_btf_neon_mode10_r(&cospi[32], &u[10], &cospi[32], &u[13], &v_bit, &rnding); v[11] = half_btf_neon_mode10_r(&cospi[32], &u[11], &cospi[32], &u[12], &v_bit, &rnding); v[12] = half_btf_neon_r(&cospi[32], &u[11], &cospi[32], &u[12], &v_bit, &rnding); v[13] = half_btf_neon_r(&cospi[32], &u[10], &cospi[32], &u[13], &v_bit, &rnding); for (i = 16; i < 20; ++i) { addsub_neon(u[i], u[i ^ 7], &v[i], &v[i ^ 7], &clamp_lo, &clamp_hi); addsub_neon(u[i ^ 15], u[i ^ 8], &v[i ^ 15], &v[i ^ 8], &clamp_lo, &clamp_hi); } for (i = 32; i < 36; ++i) { v[i] = u[i]; v[i + 12] = u[i + 12]; v[i + 16] = u[i + 16]; v[i + 28] = u[i + 28]; } v[36] = half_btf_neon_mode10_r(&cospi[16], &u[36], &cospi[48], &u[59], &v_bit, &rnding); v[37] = half_btf_neon_mode10_r(&cospi[16], &u[37], &cospi[48], &u[58], &v_bit, &rnding); v[38] = half_btf_neon_mode10_r(&cospi[16], &u[38], &cospi[48], &u[57], &v_bit, &rnding); v[39] = half_btf_neon_mode10_r(&cospi[16], &u[39], &cospi[48], &u[56], &v_bit, &rnding); v[40] = half_btf_neon_mode11_r(&cospi[48], &u[40], &cospi[16], &u[55], &v_bit, &rnding); v[41] = half_btf_neon_mode11_r(&cospi[48], &u[41], &cospi[16], &u[54], &v_bit, &rnding); v[42] = half_btf_neon_mode11_r(&cospi[48], &u[42], &cospi[16], &u[53], &v_bit, &rnding); v[43] = half_btf_neon_mode11_r(&cospi[48], &u[43], &cospi[16], &u[52], &v_bit, &rnding); v[52] = half_btf_neon_mode10_r(&cospi[16], &u[43], &cospi[48], &u[52], &v_bit, &rnding); v[53] = half_btf_neon_mode10_r(&cospi[16], &u[42], &cospi[48], &u[53], &v_bit, &rnding); v[54] = half_btf_neon_mode10_r(&cospi[16], &u[41], &cospi[48], &u[54], &v_bit, &rnding); v[55] = half_btf_neon_mode10_r(&cospi[16], &u[40], &cospi[48], &u[55], &v_bit, &rnding); v[56] = half_btf_neon_r(&cospi[48], &u[39], &cospi[16], &u[56], &v_bit, &rnding); v[57] = half_btf_neon_r(&cospi[48], &u[38], &cospi[16], &u[57], &v_bit, &rnding); v[58] = half_btf_neon_r(&cospi[48], &u[37], &cospi[16], &u[58], &v_bit, &rnding); v[59] = half_btf_neon_r(&cospi[48], &u[36], &cospi[16], &u[59], &v_bit, &rnding); // stage 9 for (i = 0; i < 8; ++i) { addsub_neon(v[i], v[15 - i], &u[i], &u[15 - i], &clamp_lo, &clamp_hi); } for (i = 16; i < 20; ++i) { u[i] = v[i]; u[i + 12] = v[i + 12]; } u[20] = half_btf_neon_mode10_r(&cospi[32], &v[20], &cospi[32], &v[27], &v_bit, &rnding); u[21] = half_btf_neon_mode10_r(&cospi[32], &v[21], &cospi[32], &v[26], &v_bit, &rnding); u[22] = half_btf_neon_mode10_r(&cospi[32], &v[22], &cospi[32], &v[25], &v_bit, &rnding); u[23] = half_btf_neon_mode10_r(&cospi[32], &v[23], &cospi[32], &v[24], &v_bit, &rnding); u[24] = half_btf_neon_r(&cospi[32], &v[23], &cospi[32], &v[24], &v_bit, &rnding); u[25] = half_btf_neon_r(&cospi[32], &v[22], &cospi[32], &v[25], &v_bit, &rnding); u[26] = half_btf_neon_r(&cospi[32], &v[21], &cospi[32], &v[26], &v_bit, &rnding); u[27] = half_btf_neon_r(&cospi[32], &v[20], &cospi[32], &v[27], &v_bit, &rnding); for (i = 32; i < 40; i++) { addsub_neon(v[i], v[i ^ 15], &u[i], &u[i ^ 15], &clamp_lo, &clamp_hi); } for (i = 48; i < 56; i++) { addsub_neon(v[i ^ 15], v[i], &u[i ^ 15], &u[i], &clamp_lo, &clamp_hi); } // stage 10 for (i = 0; i < 16; i++) { addsub_neon(u[i], u[31 - i], &v[i], &v[31 - i], &clamp_lo, &clamp_hi); } for (i = 32; i < 40; i++) v[i] = u[i]; v[40] = half_btf_neon_mode10_r(&cospi[32], &u[40], &cospi[32], &u[55], &v_bit, &rnding); v[41] = half_btf_neon_mode10_r(&cospi[32], &u[41], &cospi[32], &u[54], &v_bit, &rnding); v[42] = half_btf_neon_mode10_r(&cospi[32], &u[42], &cospi[32], &u[53], &v_bit, &rnding); v[43] = half_btf_neon_mode10_r(&cospi[32], &u[43], &cospi[32], &u[52], &v_bit, &rnding); v[44] = half_btf_neon_mode10_r(&cospi[32], &u[44], &cospi[32], &u[51], &v_bit, &rnding); v[45] = half_btf_neon_mode10_r(&cospi[32], &u[45], &cospi[32], &u[50], &v_bit, &rnding); v[46] = half_btf_neon_mode10_r(&cospi[32], &u[46], &cospi[32], &u[49], &v_bit, &rnding); v[47] = half_btf_neon_mode10_r(&cospi[32], &u[47], &cospi[32], &u[48], &v_bit, &rnding); v[48] = half_btf_neon_r(&cospi[32], &u[47], &cospi[32], &u[48], &v_bit, &rnding); v[49] = half_btf_neon_r(&cospi[32], &u[46], &cospi[32], &u[49], &v_bit, &rnding); v[50] = half_btf_neon_r(&cospi[32], &u[45], &cospi[32], &u[50], &v_bit, &rnding); v[51] = half_btf_neon_r(&cospi[32], &u[44], &cospi[32], &u[51], &v_bit, &rnding); v[52] = half_btf_neon_r(&cospi[32], &u[43], &cospi[32], &u[52], &v_bit, &rnding); v[53] = half_btf_neon_r(&cospi[32], &u[42], &cospi[32], &u[53], &v_bit, &rnding); v[54] = half_btf_neon_r(&cospi[32], &u[41], &cospi[32], &u[54], &v_bit, &rnding); v[55] = half_btf_neon_r(&cospi[32], &u[40], &cospi[32], &u[55], &v_bit, &rnding); for (i = 56; i < 64; i++) v[i] = u[i]; // stage 11 for (i = 0; i < 32; i++) { addsub_neon(v[i], v[63 - i], &out[(i)], &out[(63 - i)], &clamp_lo, &clamp_hi); } if (!do_cols) { const int log_range_out = AOMMAX(16, bd + 6); const int32x4_t clamp_lo_out = vdupq_n_s32(-(1 << (log_range_out - 1))); const int32x4_t clamp_hi_out = vdupq_n_s32((1 << (log_range_out - 1)) - 1); for (i = 0; i < 64; i += 4) { round_shift_4x4(out + i, out_shift); highbd_clamp_s32_neon(out + i, out + i, &clamp_lo_out, &clamp_hi_out, 4); } } } } static void idct32x32_low1_neon(int32x4_t *in, int32x4_t *out, int bit, int do_cols, int bd, int out_shift) { const int32_t *cospi = cospi_arr(bit); const int log_range = AOMMAX(16, bd + (do_cols ? 6 : 8)); int32x4_t clamp_lo = vdupq_n_s32(-(1 << (log_range - 1))); int32x4_t clamp_hi = vdupq_n_s32((1 << (log_range - 1)) - 1); int32x4_t bf1; const int32x4_t v_bit = vdupq_n_s32(-bit); const int32x4_t rnding = vdupq_n_s32(1 << (bit - 1)); // stage 0-1 bf1 = in[0]; // stage 2-5 bf1 = half_btf_0_neon_r(&cospi[32], &bf1, &v_bit, &rnding); // stage 6-9 if (do_cols) { bf1 = vmaxq_s32(bf1, clamp_lo); bf1 = vminq_s32(bf1, clamp_hi); } else { const int log_range_out = AOMMAX(16, bd + 6); clamp_lo = vdupq_n_s32(-(1 << (log_range_out - 1))); clamp_hi = vdupq_n_s32((1 << (log_range_out - 1)) - 1); if (out_shift != 0) { bf1 = vrshlq_s32(bf1, vdupq_n_s32(-out_shift)); } } bf1 = vmaxq_s32(bf1, clamp_lo); bf1 = vminq_s32(bf1, clamp_hi); for (int i = 0; i < 32; i++) out[i] = bf1; } static void idct32x32_low8_neon(int32x4_t *in, int32x4_t *out, int bit, int do_cols, int bd, int out_shift) { const int32_t *cospi = cospi_arr(bit); const int log_range = AOMMAX(16, bd + (do_cols ? 6 : 8)); const int32x4_t clamp_lo = vdupq_n_s32(-(1 << (log_range - 1))); const int32x4_t clamp_hi = vdupq_n_s32((1 << (log_range - 1)) - 1); int32x4_t bf1[32]; const int32x4_t v_bit = vdupq_n_s32(-bit); const int32x4_t rnding = vdupq_n_s32(1 << (bit - 1)); // stage 0-1 bf1[0] = in[0]; bf1[4] = in[4]; bf1[8] = in[2]; bf1[12] = in[6]; bf1[16] = in[1]; bf1[20] = in[5]; bf1[24] = in[3]; bf1[28] = in[7]; // stage 2 bf1[31] = half_btf_0_neon_r(&cospi[2], &bf1[16], &v_bit, &rnding); bf1[16] = half_btf_0_neon_r(&cospi[62], &bf1[16], &v_bit, &rnding); bf1[19] = half_btf_0_m_neon_r(&cospi[50], &bf1[28], &v_bit, &rnding); bf1[28] = half_btf_0_neon_r(&cospi[14], &bf1[28], &v_bit, &rnding); bf1[27] = half_btf_0_neon_r(&cospi[10], &bf1[20], &v_bit, &rnding); bf1[20] = half_btf_0_neon_r(&cospi[54], &bf1[20], &v_bit, &rnding); bf1[23] = half_btf_0_m_neon_r(&cospi[58], &bf1[24], &v_bit, &rnding); bf1[24] = half_btf_0_neon_r(&cospi[6], &bf1[24], &v_bit, &rnding); // stage 3 bf1[15] = half_btf_0_neon_r(&cospi[4], &bf1[8], &v_bit, &rnding); bf1[8] = half_btf_0_neon_r(&cospi[60], &bf1[8], &v_bit, &rnding); bf1[11] = half_btf_0_m_neon_r(&cospi[52], &bf1[12], &v_bit, &rnding); bf1[12] = half_btf_0_neon_r(&cospi[12], &bf1[12], &v_bit, &rnding); bf1[17] = bf1[16]; bf1[18] = bf1[19]; bf1[21] = bf1[20]; bf1[22] = bf1[23]; bf1[25] = bf1[24]; bf1[26] = bf1[27]; bf1[29] = bf1[28]; bf1[30] = bf1[31]; // stage 4 : bf1[7] = half_btf_0_neon_r(&cospi[8], &bf1[4], &v_bit, &rnding); bf1[4] = half_btf_0_neon_r(&cospi[56], &bf1[4], &v_bit, &rnding); bf1[9] = bf1[8]; bf1[10] = bf1[11]; bf1[13] = bf1[12]; bf1[14] = bf1[15]; idct32_stage4_neon(bf1, cospi, &v_bit, &rnding); // stage 5 bf1[0] = half_btf_0_neon_r(&cospi[32], &bf1[0], &v_bit, &rnding); bf1[1] = bf1[0]; bf1[5] = bf1[4]; bf1[6] = bf1[7]; idct32_stage5_neon(bf1, cospi, &clamp_lo, &clamp_hi, &v_bit, &rnding); // stage 6 bf1[3] = bf1[0]; bf1[2] = bf1[1]; idct32_stage6_neon(bf1, cospi, &clamp_lo, &clamp_hi, &v_bit, &rnding); // stage 7 idct32_stage7_neon(bf1, cospi, &clamp_lo, &clamp_hi, &v_bit, &rnding); // stage 8 idct32_stage8_neon(bf1, cospi, &clamp_lo, &clamp_hi, &v_bit, &rnding); // stage 9 idct32_stage9_neon(bf1, out, do_cols, bd, out_shift, &clamp_lo, &clamp_hi); } static void idct32x32_low16_neon(int32x4_t *in, int32x4_t *out, int bit, int do_cols, int bd, int out_shift) { const int32_t *cospi = cospi_arr(bit); const int log_range = AOMMAX(16, bd + (do_cols ? 6 : 8)); const int32x4_t clamp_lo = vdupq_n_s32(-(1 << (log_range - 1))); const int32x4_t clamp_hi = vdupq_n_s32((1 << (log_range - 1)) - 1); int32x4_t bf1[32]; const int32x4_t v_bit = vdupq_n_s32(-bit); const int32x4_t rnding = vdupq_n_s32(1 << (bit - 1)); // stage 0-1 bf1[0] = in[0]; bf1[2] = in[8]; bf1[4] = in[4]; bf1[6] = in[12]; bf1[8] = in[2]; bf1[10] = in[10]; bf1[12] = in[6]; bf1[14] = in[14]; bf1[16] = in[1]; bf1[18] = in[9]; bf1[20] = in[5]; bf1[22] = in[13]; bf1[24] = in[3]; bf1[26] = in[11]; bf1[28] = in[7]; bf1[30] = in[15]; // stage 2 bf1[31] = half_btf_0_neon_r(&cospi[2], &bf1[16], &v_bit, &rnding); bf1[16] = half_btf_0_neon_r(&cospi[62], &bf1[16], &v_bit, &rnding); bf1[17] = half_btf_0_m_neon_r(&cospi[34], &bf1[30], &v_bit, &rnding); bf1[30] = half_btf_0_neon_r(&cospi[30], &bf1[30], &v_bit, &rnding); bf1[29] = half_btf_0_neon_r(&cospi[18], &bf1[18], &v_bit, &rnding); bf1[18] = half_btf_0_neon_r(&cospi[46], &bf1[18], &v_bit, &rnding); bf1[19] = half_btf_0_m_neon_r(&cospi[50], &bf1[28], &v_bit, &rnding); bf1[28] = half_btf_0_neon_r(&cospi[14], &bf1[28], &v_bit, &rnding); bf1[27] = half_btf_0_neon_r(&cospi[10], &bf1[20], &v_bit, &rnding); bf1[20] = half_btf_0_neon_r(&cospi[54], &bf1[20], &v_bit, &rnding); bf1[21] = half_btf_0_m_neon_r(&cospi[42], &bf1[26], &v_bit, &rnding); bf1[26] = half_btf_0_neon_r(&cospi[22], &bf1[26], &v_bit, &rnding); bf1[25] = half_btf_0_neon_r(&cospi[26], &bf1[22], &v_bit, &rnding); bf1[22] = half_btf_0_neon_r(&cospi[38], &bf1[22], &v_bit, &rnding); bf1[23] = half_btf_0_m_neon_r(&cospi[58], &bf1[24], &v_bit, &rnding); bf1[24] = half_btf_0_neon_r(&cospi[6], &bf1[24], &v_bit, &rnding); // stage 3 bf1[15] = half_btf_0_neon_r(&cospi[4], &bf1[8], &v_bit, &rnding); bf1[8] = half_btf_0_neon_r(&cospi[60], &bf1[8], &v_bit, &rnding); bf1[9] = half_btf_0_m_neon_r(&cospi[36], &bf1[14], &v_bit, &rnding); bf1[14] = half_btf_0_neon_r(&cospi[28], &bf1[14], &v_bit, &rnding); bf1[13] = half_btf_0_neon_r(&cospi[20], &bf1[10], &v_bit, &rnding); bf1[10] = half_btf_0_neon_r(&cospi[44], &bf1[10], &v_bit, &rnding); bf1[11] = half_btf_0_m_neon_r(&cospi[52], &bf1[12], &v_bit, &rnding); bf1[12] = half_btf_0_neon_r(&cospi[12], &bf1[12], &v_bit, &rnding); addsub_neon(bf1[16], bf1[17], bf1 + 16, bf1 + 17, &clamp_lo, &clamp_hi); addsub_neon(bf1[19], bf1[18], bf1 + 19, bf1 + 18, &clamp_lo, &clamp_hi); addsub_neon(bf1[20], bf1[21], bf1 + 20, bf1 + 21, &clamp_lo, &clamp_hi); addsub_neon(bf1[23], bf1[22], bf1 + 23, bf1 + 22, &clamp_lo, &clamp_hi); addsub_neon(bf1[24], bf1[25], bf1 + 24, bf1 + 25, &clamp_lo, &clamp_hi); addsub_neon(bf1[27], bf1[26], bf1 + 27, bf1 + 26, &clamp_lo, &clamp_hi); addsub_neon(bf1[28], bf1[29], bf1 + 28, bf1 + 29, &clamp_lo, &clamp_hi); addsub_neon(bf1[31], bf1[30], bf1 + 31, bf1 + 30, &clamp_lo, &clamp_hi); // stage 4 bf1[7] = half_btf_0_neon_r(&cospi[8], &bf1[4], &v_bit, &rnding); bf1[4] = half_btf_0_neon_r(&cospi[56], &bf1[4], &v_bit, &rnding); bf1[5] = half_btf_0_m_neon_r(&cospi[40], &bf1[6], &v_bit, &rnding); bf1[6] = half_btf_0_neon_r(&cospi[24], &bf1[6], &v_bit, &rnding); addsub_neon(bf1[8], bf1[9], bf1 + 8, bf1 + 9, &clamp_lo, &clamp_hi); addsub_neon(bf1[11], bf1[10], bf1 + 11, bf1 + 10, &clamp_lo, &clamp_hi); addsub_neon(bf1[12], bf1[13], bf1 + 12, bf1 + 13, &clamp_lo, &clamp_hi); addsub_neon(bf1[15], bf1[14], bf1 + 15, bf1 + 14, &clamp_lo, &clamp_hi); idct32_stage4_neon(bf1, cospi, &v_bit, &rnding); // stage 5 bf1[0] = half_btf_0_neon_r(&cospi[32], &bf1[0], &v_bit, &rnding); bf1[1] = bf1[0]; bf1[3] = half_btf_0_neon_r(&cospi[16], &bf1[2], &v_bit, &rnding); bf1[2] = half_btf_0_neon_r(&cospi[48], &bf1[2], &v_bit, &rnding); addsub_neon(bf1[4], bf1[5], bf1 + 4, bf1 + 5, &clamp_lo, &clamp_hi); addsub_neon(bf1[7], bf1[6], bf1 + 7, bf1 + 6, &clamp_lo, &clamp_hi); idct32_stage5_neon(bf1, cospi, &clamp_lo, &clamp_hi, &v_bit, &rnding); // stage 6 addsub_neon(bf1[0], bf1[3], bf1 + 0, bf1 + 3, &clamp_lo, &clamp_hi); addsub_neon(bf1[1], bf1[2], bf1 + 1, bf1 + 2, &clamp_lo, &clamp_hi); idct32_stage6_neon(bf1, cospi, &clamp_lo, &clamp_hi, &v_bit, &rnding); // stage 7 idct32_stage7_neon(bf1, cospi, &clamp_lo, &clamp_hi, &v_bit, &rnding); // stage 8 idct32_stage8_neon(bf1, cospi, &clamp_lo, &clamp_hi, &v_bit, &rnding); // stage 9 idct32_stage9_neon(bf1, out, do_cols, bd, out_shift, &clamp_lo, &clamp_hi); } static void idct32x32_neon(int32x4_t *in, int32x4_t *out, int bit, int do_cols, int bd, int out_shift) { const int32_t *cospi = cospi_arr(bit); const int log_range = AOMMAX(16, bd + (do_cols ? 6 : 8)); const int32x4_t clamp_lo = vdupq_n_s32(-(1 << (log_range - 1))); const int32x4_t clamp_hi = vdupq_n_s32((1 << (log_range - 1)) - 1); int32x4_t bf1[32], bf0[32]; const int32x4_t v_bit = vdupq_n_s32(-bit); const int32x4_t rnding = vdupq_n_s32(1 << (bit - 1)); // stage 0 // stage 1 bf1[0] = in[0]; bf1[1] = in[16]; bf1[2] = in[8]; bf1[3] = in[24]; bf1[4] = in[4]; bf1[5] = in[20]; bf1[6] = in[12]; bf1[7] = in[28]; bf1[8] = in[2]; bf1[9] = in[18]; bf1[10] = in[10]; bf1[11] = in[26]; bf1[12] = in[6]; bf1[13] = in[22]; bf1[14] = in[14]; bf1[15] = in[30]; bf1[16] = in[1]; bf1[17] = in[17]; bf1[18] = in[9]; bf1[19] = in[25]; bf1[20] = in[5]; bf1[21] = in[21]; bf1[22] = in[13]; bf1[23] = in[29]; bf1[24] = in[3]; bf1[25] = in[19]; bf1[26] = in[11]; bf1[27] = in[27]; bf1[28] = in[7]; bf1[29] = in[23]; bf1[30] = in[15]; bf1[31] = in[31]; // stage 2 for (int i = 0; i < 16; i++) bf0[i] = bf1[i]; bf0[16] = half_btf_neon_mode01_r(&cospi[62], &bf1[16], &cospi[2], &bf1[31], &v_bit, &rnding); bf0[17] = half_btf_neon_mode01_r(&cospi[30], &bf1[17], &cospi[34], &bf1[30], &v_bit, &rnding); bf0[18] = half_btf_neon_mode01_r(&cospi[46], &bf1[18], &cospi[18], &bf1[29], &v_bit, &rnding); bf0[19] = half_btf_neon_mode01_r(&cospi[14], &bf1[19], &cospi[50], &bf1[28], &v_bit, &rnding); bf0[20] = half_btf_neon_mode01_r(&cospi[54], &bf1[20], &cospi[10], &bf1[27], &v_bit, &rnding); bf0[21] = half_btf_neon_mode01_r(&cospi[22], &bf1[21], &cospi[42], &bf1[26], &v_bit, &rnding); bf0[22] = half_btf_neon_mode01_r(&cospi[38], &bf1[22], &cospi[26], &bf1[25], &v_bit, &rnding); bf0[23] = half_btf_neon_mode01_r(&cospi[6], &bf1[23], &cospi[58], &bf1[24], &v_bit, &rnding); bf0[24] = half_btf_neon_r(&cospi[58], &bf1[23], &cospi[6], &bf1[24], &v_bit, &rnding); bf0[25] = half_btf_neon_r(&cospi[26], &bf1[22], &cospi[38], &bf1[25], &v_bit, &rnding); bf0[26] = half_btf_neon_r(&cospi[42], &bf1[21], &cospi[22], &bf1[26], &v_bit, &rnding); bf0[27] = half_btf_neon_r(&cospi[10], &bf1[20], &cospi[54], &bf1[27], &v_bit, &rnding); bf0[28] = half_btf_neon_r(&cospi[50], &bf1[19], &cospi[14], &bf1[28], &v_bit, &rnding); bf0[29] = half_btf_neon_r(&cospi[18], &bf1[18], &cospi[46], &bf1[29], &v_bit, &rnding); bf0[30] = half_btf_neon_r(&cospi[34], &bf1[17], &cospi[30], &bf1[30], &v_bit, &rnding); bf0[31] = half_btf_neon_r(&cospi[2], &bf1[16], &cospi[62], &bf1[31], &v_bit, &rnding); // stage 3 for (int i = 0; i < 8; i++) bf1[i] = bf0[i]; bf1[8] = half_btf_neon_mode01_r(&cospi[60], &bf0[8], &cospi[4], &bf0[15], &v_bit, &rnding); bf1[9] = half_btf_neon_mode01_r(&cospi[28], &bf0[9], &cospi[36], &bf0[14], &v_bit, &rnding); bf1[10] = half_btf_neon_mode01_r(&cospi[44], &bf0[10], &cospi[20], &bf0[13], &v_bit, &rnding); bf1[11] = half_btf_neon_mode01_r(&cospi[12], &bf0[11], &cospi[52], &bf0[12], &v_bit, &rnding); bf1[12] = half_btf_neon_r(&cospi[52], &bf0[11], &cospi[12], &bf0[12], &v_bit, &rnding); bf1[13] = half_btf_neon_r(&cospi[20], &bf0[10], &cospi[44], &bf0[13], &v_bit, &rnding); bf1[14] = half_btf_neon_r(&cospi[36], &bf0[9], &cospi[28], &bf0[14], &v_bit, &rnding); bf1[15] = half_btf_neon_r(&cospi[4], &bf0[8], &cospi[60], &bf0[15], &v_bit, &rnding); addsub_neon(bf0[16], bf0[17], bf1 + 16, bf1 + 17, &clamp_lo, &clamp_hi); addsub_neon(bf0[19], bf0[18], bf1 + 19, bf1 + 18, &clamp_lo, &clamp_hi); addsub_neon(bf0[20], bf0[21], bf1 + 20, bf1 + 21, &clamp_lo, &clamp_hi); addsub_neon(bf0[23], bf0[22], bf1 + 23, bf1 + 22, &clamp_lo, &clamp_hi); addsub_neon(bf0[24], bf0[25], bf1 + 24, bf1 + 25, &clamp_lo, &clamp_hi); addsub_neon(bf0[27], bf0[26], bf1 + 27, bf1 + 26, &clamp_lo, &clamp_hi); addsub_neon(bf0[28], bf0[29], bf1 + 28, bf1 + 29, &clamp_lo, &clamp_hi); addsub_neon(bf0[31], bf0[30], bf1 + 31, bf1 + 30, &clamp_lo, &clamp_hi); // stage 4 bf0[0] = bf1[0]; bf0[1] = bf1[1]; bf0[2] = bf1[2]; bf0[3] = bf1[3]; bf0[4] = half_btf_neon_mode01_r(&cospi[56], &bf1[4], &cospi[8], &bf1[7], &v_bit, &rnding); bf0[5] = half_btf_neon_mode01_r(&cospi[24], &bf1[5], &cospi[40], &bf1[6], &v_bit, &rnding); bf0[6] = half_btf_neon_r(&cospi[40], &bf1[5], &cospi[24], &bf1[6], &v_bit, &rnding); bf0[7] = half_btf_neon_r(&cospi[8], &bf1[4], &cospi[56], &bf1[7], &v_bit, &rnding); addsub_neon(bf1[8], bf1[9], bf0 + 8, bf0 + 9, &clamp_lo, &clamp_hi); addsub_neon(bf1[11], bf1[10], bf0 + 11, bf0 + 10, &clamp_lo, &clamp_hi); addsub_neon(bf1[12], bf1[13], bf0 + 12, bf0 + 13, &clamp_lo, &clamp_hi); addsub_neon(bf1[15], bf1[14], bf0 + 15, bf0 + 14, &clamp_lo, &clamp_hi); bf0[16] = bf1[16]; bf0[17] = half_btf_neon_mode10_r(&cospi[8], &bf1[17], &cospi[56], &bf1[30], &v_bit, &rnding); bf0[18] = half_btf_neon_mode11_r(&cospi[56], &bf1[18], &cospi[8], &bf1[29], &v_bit, &rnding); bf0[19] = bf1[19]; bf0[20] = bf1[20]; bf0[21] = half_btf_neon_mode10_r(&cospi[40], &bf1[21], &cospi[24], &bf1[26], &v_bit, &rnding); bf0[22] = half_btf_neon_mode11_r(&cospi[24], &bf1[22], &cospi[40], &bf1[25], &v_bit, &rnding); bf0[23] = bf1[23]; bf0[24] = bf1[24]; bf0[25] = half_btf_neon_mode10_r(&cospi[40], &bf1[22], &cospi[24], &bf1[25], &v_bit, &rnding); bf0[26] = half_btf_neon_r(&cospi[24], &bf1[21], &cospi[40], &bf1[26], &v_bit, &rnding); bf0[27] = bf1[27]; bf0[28] = bf1[28]; bf0[29] = half_btf_neon_mode10_r(&cospi[8], &bf1[18], &cospi[56], &bf1[29], &v_bit, &rnding); bf0[30] = half_btf_neon_r(&cospi[56], &bf1[17], &cospi[8], &bf1[30], &v_bit, &rnding); bf0[31] = bf1[31]; // stage 5 bf1[0] = half_btf_neon_r(&cospi[32], &bf0[0], &cospi[32], &bf0[1], &v_bit, &rnding); bf1[1] = half_btf_neon_mode01_r(&cospi[32], &bf0[0], &cospi[32], &bf0[1], &v_bit, &rnding); bf1[2] = half_btf_neon_mode01_r(&cospi[48], &bf0[2], &cospi[16], &bf0[3], &v_bit, &rnding); bf1[3] = half_btf_neon_r(&cospi[16], &bf0[2], &cospi[48], &bf0[3], &v_bit, &rnding); addsub_neon(bf0[4], bf0[5], bf1 + 4, bf1 + 5, &clamp_lo, &clamp_hi); addsub_neon(bf0[7], bf0[6], bf1 + 7, bf1 + 6, &clamp_lo, &clamp_hi); bf1[8] = bf0[8]; bf1[9] = half_btf_neon_mode10_r(&cospi[16], &bf0[9], &cospi[48], &bf0[14], &v_bit, &rnding); bf1[10] = half_btf_neon_mode11_r(&cospi[48], &bf0[10], &cospi[16], &bf0[13], &v_bit, &rnding); bf1[11] = bf0[11]; bf1[12] = bf0[12]; bf1[13] = half_btf_neon_mode10_r(&cospi[16], &bf0[10], &cospi[48], &bf0[13], &v_bit, &rnding); bf1[14] = half_btf_neon_r(&cospi[48], &bf0[9], &cospi[16], &bf0[14], &v_bit, &rnding); bf1[15] = bf0[15]; addsub_neon(bf0[16], bf0[19], bf1 + 16, bf1 + 19, &clamp_lo, &clamp_hi); addsub_neon(bf0[17], bf0[18], bf1 + 17, bf1 + 18, &clamp_lo, &clamp_hi); addsub_neon(bf0[23], bf0[20], bf1 + 23, bf1 + 20, &clamp_lo, &clamp_hi); addsub_neon(bf0[22], bf0[21], bf1 + 22, bf1 + 21, &clamp_lo, &clamp_hi); addsub_neon(bf0[24], bf0[27], bf1 + 24, bf1 + 27, &clamp_lo, &clamp_hi); addsub_neon(bf0[25], bf0[26], bf1 + 25, bf1 + 26, &clamp_lo, &clamp_hi); addsub_neon(bf0[31], bf0[28], bf1 + 31, bf1 + 28, &clamp_lo, &clamp_hi); addsub_neon(bf0[30], bf0[29], bf1 + 30, bf1 + 29, &clamp_lo, &clamp_hi); // stage 6 addsub_neon(bf1[0], bf1[3], bf0 + 0, bf0 + 3, &clamp_lo, &clamp_hi); addsub_neon(bf1[1], bf1[2], bf0 + 1, bf0 + 2, &clamp_lo, &clamp_hi); bf0[4] = bf1[4]; bf0[5] = half_btf_neon_mode10_r(&cospi[32], &bf1[5], &cospi[32], &bf1[6], &v_bit, &rnding); bf0[6] = half_btf_neon_r(&cospi[32], &bf1[5], &cospi[32], &bf1[6], &v_bit, &rnding); bf0[7] = bf1[7]; addsub_neon(bf1[8], bf1[11], bf0 + 8, bf0 + 11, &clamp_lo, &clamp_hi); addsub_neon(bf1[9], bf1[10], bf0 + 9, bf0 + 10, &clamp_lo, &clamp_hi); addsub_neon(bf1[15], bf1[12], bf0 + 15, bf0 + 12, &clamp_lo, &clamp_hi); addsub_neon(bf1[14], bf1[13], bf0 + 14, bf0 + 13, &clamp_lo, &clamp_hi); bf0[16] = bf1[16]; bf0[17] = bf1[17]; bf0[18] = half_btf_neon_mode10_r(&cospi[16], &bf1[18], &cospi[48], &bf1[29], &v_bit, &rnding); bf0[19] = half_btf_neon_mode10_r(&cospi[16], &bf1[19], &cospi[48], &bf1[28], &v_bit, &rnding); bf0[20] = half_btf_neon_mode11_r(&cospi[48], &bf1[20], &cospi[16], &bf1[27], &v_bit, &rnding); bf0[21] = half_btf_neon_mode11_r(&cospi[48], &bf1[21], &cospi[16], &bf1[26], &v_bit, &rnding); bf0[22] = bf1[22]; bf0[23] = bf1[23]; bf0[24] = bf1[24]; bf0[25] = bf1[25]; bf0[26] = half_btf_neon_mode10_r(&cospi[16], &bf1[21], &cospi[48], &bf1[26], &v_bit, &rnding); bf0[27] = half_btf_neon_mode10_r(&cospi[16], &bf1[20], &cospi[48], &bf1[27], &v_bit, &rnding); bf0[28] = half_btf_neon_r(&cospi[48], &bf1[19], &cospi[16], &bf1[28], &v_bit, &rnding); bf0[29] = half_btf_neon_r(&cospi[48], &bf1[18], &cospi[16], &bf1[29], &v_bit, &rnding); bf0[30] = bf1[30]; bf0[31] = bf1[31]; // stage 7 addsub_neon(bf0[0], bf0[7], bf1 + 0, bf1 + 7, &clamp_lo, &clamp_hi); addsub_neon(bf0[1], bf0[6], bf1 + 1, bf1 + 6, &clamp_lo, &clamp_hi); addsub_neon(bf0[2], bf0[5], bf1 + 2, bf1 + 5, &clamp_lo, &clamp_hi); addsub_neon(bf0[3], bf0[4], bf1 + 3, bf1 + 4, &clamp_lo, &clamp_hi); bf1[8] = bf0[8]; bf1[9] = bf0[9]; bf1[10] = half_btf_neon_mode10_r(&cospi[32], &bf0[10], &cospi[32], &bf0[13], &v_bit, &rnding); bf1[11] = half_btf_neon_mode10_r(&cospi[32], &bf0[11], &cospi[32], &bf0[12], &v_bit, &rnding); bf1[12] = half_btf_neon_r(&cospi[32], &bf0[11], &cospi[32], &bf0[12], &v_bit, &rnding); bf1[13] = half_btf_neon_r(&cospi[32], &bf0[10], &cospi[32], &bf0[13], &v_bit, &rnding); bf1[14] = bf0[14]; bf1[15] = bf0[15]; addsub_neon(bf0[16], bf0[23], bf1 + 16, bf1 + 23, &clamp_lo, &clamp_hi); addsub_neon(bf0[17], bf0[22], bf1 + 17, bf1 + 22, &clamp_lo, &clamp_hi); addsub_neon(bf0[18], bf0[21], bf1 + 18, bf1 + 21, &clamp_lo, &clamp_hi); addsub_neon(bf0[19], bf0[20], bf1 + 19, bf1 + 20, &clamp_lo, &clamp_hi); addsub_neon(bf0[31], bf0[24], bf1 + 31, bf1 + 24, &clamp_lo, &clamp_hi); addsub_neon(bf0[30], bf0[25], bf1 + 30, bf1 + 25, &clamp_lo, &clamp_hi); addsub_neon(bf0[29], bf0[26], bf1 + 29, bf1 + 26, &clamp_lo, &clamp_hi); addsub_neon(bf0[28], bf0[27], bf1 + 28, bf1 + 27, &clamp_lo, &clamp_hi); // stage 8 addsub_neon(bf1[0], bf1[15], bf0 + 0, bf0 + 15, &clamp_lo, &clamp_hi); addsub_neon(bf1[1], bf1[14], bf0 + 1, bf0 + 14, &clamp_lo, &clamp_hi); addsub_neon(bf1[2], bf1[13], bf0 + 2, bf0 + 13, &clamp_lo, &clamp_hi); addsub_neon(bf1[3], bf1[12], bf0 + 3, bf0 + 12, &clamp_lo, &clamp_hi); addsub_neon(bf1[4], bf1[11], bf0 + 4, bf0 + 11, &clamp_lo, &clamp_hi); addsub_neon(bf1[5], bf1[10], bf0 + 5, bf0 + 10, &clamp_lo, &clamp_hi); addsub_neon(bf1[6], bf1[9], bf0 + 6, bf0 + 9, &clamp_lo, &clamp_hi); addsub_neon(bf1[7], bf1[8], bf0 + 7, bf0 + 8, &clamp_lo, &clamp_hi); bf0[16] = bf1[16]; bf0[17] = bf1[17]; bf0[18] = bf1[18]; bf0[19] = bf1[19]; bf0[20] = half_btf_neon_mode10_r(&cospi[32], &bf1[20], &cospi[32], &bf1[27], &v_bit, &rnding); bf0[21] = half_btf_neon_mode10_r(&cospi[32], &bf1[21], &cospi[32], &bf1[26], &v_bit, &rnding); bf0[22] = half_btf_neon_mode10_r(&cospi[32], &bf1[22], &cospi[32], &bf1[25], &v_bit, &rnding); bf0[23] = half_btf_neon_mode10_r(&cospi[32], &bf1[23], &cospi[32], &bf1[24], &v_bit, &rnding); bf0[24] = half_btf_neon_r(&cospi[32], &bf1[23], &cospi[32], &bf1[24], &v_bit, &rnding); bf0[25] = half_btf_neon_r(&cospi[32], &bf1[22], &cospi[32], &bf1[25], &v_bit, &rnding); bf0[26] = half_btf_neon_r(&cospi[32], &bf1[21], &cospi[32], &bf1[26], &v_bit, &rnding); bf0[27] = half_btf_neon_r(&cospi[32], &bf1[20], &cospi[32], &bf1[27], &v_bit, &rnding); bf0[28] = bf1[28]; bf0[29] = bf1[29]; bf0[30] = bf1[30]; bf0[31] = bf1[31]; // stage 9 addsub_neon(bf0[0], bf0[31], out + 0, out + 31, &clamp_lo, &clamp_hi); addsub_neon(bf0[1], bf0[30], out + 1, out + 30, &clamp_lo, &clamp_hi); addsub_neon(bf0[2], bf0[29], out + 2, out + 29, &clamp_lo, &clamp_hi); addsub_neon(bf0[3], bf0[28], out + 3, out + 28, &clamp_lo, &clamp_hi); addsub_neon(bf0[4], bf0[27], out + 4, out + 27, &clamp_lo, &clamp_hi); addsub_neon(bf0[5], bf0[26], out + 5, out + 26, &clamp_lo, &clamp_hi); addsub_neon(bf0[6], bf0[25], out + 6, out + 25, &clamp_lo, &clamp_hi); addsub_neon(bf0[7], bf0[24], out + 7, out + 24, &clamp_lo, &clamp_hi); addsub_neon(bf0[8], bf0[23], out + 8, out + 23, &clamp_lo, &clamp_hi); addsub_neon(bf0[9], bf0[22], out + 9, out + 22, &clamp_lo, &clamp_hi); addsub_neon(bf0[10], bf0[21], out + 10, out + 21, &clamp_lo, &clamp_hi); addsub_neon(bf0[11], bf0[20], out + 11, out + 20, &clamp_lo, &clamp_hi); addsub_neon(bf0[12], bf0[19], out + 12, out + 19, &clamp_lo, &clamp_hi); addsub_neon(bf0[13], bf0[18], out + 13, out + 18, &clamp_lo, &clamp_hi); addsub_neon(bf0[14], bf0[17], out + 14, out + 17, &clamp_lo, &clamp_hi); addsub_neon(bf0[15], bf0[16], out + 15, out + 16, &clamp_lo, &clamp_hi); if (!do_cols) { const int log_range_out = AOMMAX(16, bd + 6); const int32x4_t clamp_lo_out = vdupq_n_s32(-(1 << (log_range_out - 1))); const int32x4_t clamp_hi_out = vdupq_n_s32((1 << (log_range_out - 1)) - 1); round_shift_8x8(out, out_shift); round_shift_8x8(out + 16, out_shift); highbd_clamp_s32_neon(out, out, &clamp_lo_out, &clamp_hi_out, 32); } } static void iidentity32_neon(int32x4_t *in, int32x4_t *out, int bit, int do_cols, int bd, int out_shift) { (void)bit; for (int i = 0; i < 32; i += 16) { out[i] = vshlq_n_s32(in[i], 2); out[i + 1] = vshlq_n_s32(in[i + 1], 2); out[i + 2] = vshlq_n_s32(in[i + 2], 2); out[i + 3] = vshlq_n_s32(in[i + 3], 2); out[i + 4] = vshlq_n_s32(in[i + 4], 2); out[i + 5] = vshlq_n_s32(in[i + 5], 2); out[i + 6] = vshlq_n_s32(in[i + 6], 2); out[i + 7] = vshlq_n_s32(in[i + 7], 2); out[i + 8] = vshlq_n_s32(in[i + 8], 2); out[i + 9] = vshlq_n_s32(in[i + 9], 2); out[i + 10] = vshlq_n_s32(in[i + 10], 2); out[i + 11] = vshlq_n_s32(in[i + 11], 2); out[i + 12] = vshlq_n_s32(in[i + 12], 2); out[i + 13] = vshlq_n_s32(in[i + 13], 2); out[i + 14] = vshlq_n_s32(in[i + 14], 2); out[i + 15] = vshlq_n_s32(in[i + 15], 2); } if (!do_cols) { const int log_range_out = AOMMAX(16, bd + 6); const int32x4_t clamp_lo_out = vdupq_n_s32(-(1 << (log_range_out - 1))); const int32x4_t clamp_hi_out = vdupq_n_s32((1 << (log_range_out - 1)) - 1); round_shift_8x8(out, out_shift); round_shift_8x8(out + 16, out_shift); highbd_clamp_s32_neon(out, out, &clamp_lo_out, &clamp_hi_out, 32); } } // 1D itx types typedef enum ATTRIBUTE_PACKED { IDCT_1D, IADST_1D, IFLIPADST_1D = IADST_1D, IIDENTITY_1D, ITX_TYPES_1D, } ITX_TYPE_1D; static const ITX_TYPE_1D vitx_1d_tab[TX_TYPES] = { IDCT_1D, IADST_1D, IDCT_1D, IADST_1D, IFLIPADST_1D, IDCT_1D, IFLIPADST_1D, IADST_1D, IFLIPADST_1D, IIDENTITY_1D, IDCT_1D, IIDENTITY_1D, IADST_1D, IIDENTITY_1D, IFLIPADST_1D, IIDENTITY_1D, }; static const ITX_TYPE_1D hitx_1d_tab[TX_TYPES] = { IDCT_1D, IDCT_1D, IADST_1D, IADST_1D, IDCT_1D, IFLIPADST_1D, IFLIPADST_1D, IFLIPADST_1D, IADST_1D, IIDENTITY_1D, IIDENTITY_1D, IDCT_1D, IIDENTITY_1D, IADST_1D, IIDENTITY_1D, IFLIPADST_1D, }; static const transform_1d_neon highbd_txfm_all_1d_zeros_w8_arr[TX_SIZES][ITX_TYPES_1D][4] = { { { idct4x4_neon, NULL, NULL, NULL }, { iadst4x4_neon, NULL, NULL, NULL }, { iidentity4_neon, iidentity4_neon, iidentity4_neon, NULL }, }, { { idct8x8_low1_neon, idct8x8_new_neon, NULL, NULL }, { iadst8x8_low1_neon, iadst8x8_new_neon, NULL, NULL }, { iidentity8_neon, iidentity8_neon, NULL, NULL } }, { { idct16x16_low1_neon, idct16x16_low8_neon, idct16x16_neon, NULL }, { iadst16x16_low1_neon, iadst16x16_low8_neon, iadst16x16_neon, NULL }, { iidentity16_neon, NULL, iidentity16_neon, NULL }, }, { { idct32x32_low1_neon, idct32x32_low8_neon, idct32x32_low16_neon, idct32x32_neon }, { NULL, NULL, NULL, NULL }, { iidentity32_neon, NULL, NULL, NULL } }, { { idct64x64_low1_neon, idct64x64_low8_neon, idct64x64_low16_neon, idct64x64_neon }, { NULL, NULL, NULL, NULL }, { NULL, NULL, NULL, NULL } } }; void av1_inv_txfm2d_add_4x8_neon(const tran_low_t *input, uint16_t *output, int stride, TX_TYPE tx_type, const int bd) { TX_SIZE tx_size = TX_4X8; int32x4_t buf1[32] = { vdupq_n_s32(0) }; const int8_t *shift = av1_inv_txfm_shift_ls[tx_size]; const int txw_idx = get_txw_idx(tx_size); const int txh_idx = get_txh_idx(tx_size); const int txfm_size_col = tx_size_wide[tx_size]; const int txfm_size_row = tx_size_high[tx_size]; const transform_1d_neon row_txfm = highbd_txfm_all_1d_zeros_w8_arr[txw_idx][hitx_1d_tab[tx_type]][0]; const transform_1d_neon col_txfm = highbd_txfm_all_1d_zeros_w8_arr[txh_idx][vitx_1d_tab[tx_type]][1]; const int input_stride = AOMMIN(32, txfm_size_row); assert(col_txfm != NULL); assert(row_txfm != NULL); int ud_flip, lr_flip; get_flip_cfg(tx_type, &ud_flip, &lr_flip); // 1st stage: column transform int32x4_t buf0[8]; load_buffer_32bit_input(input, input_stride, buf0, txfm_size_col); load_buffer_32bit_input(input + 4, input_stride, buf0 + 4, txfm_size_col); round_shift_rect_array_32_neon(buf0, buf0, txfm_size_row); row_txfm(buf0, buf0, INV_COS_BIT, 0, bd, -shift[0]); row_txfm(buf0 + 4, buf0 + 4, INV_COS_BIT, 0, bd, -shift[0]); if (lr_flip) { TRANSPOSE_4X4(buf0[3], buf0[2], buf0[1], buf0[0], buf1[0], buf1[1], buf1[2], buf1[3]); TRANSPOSE_4X4(buf0[7], buf0[6], buf0[5], buf0[4], buf1[4], buf1[5], buf1[6], buf1[7]); } else { TRANSPOSE_4X4(buf0[0], buf0[1], buf0[2], buf0[3], buf1[0], buf1[1], buf1[2], buf1[3]); TRANSPOSE_4X4(buf0[4], buf0[5], buf0[6], buf0[7], buf1[4], buf1[5], buf1[6], buf1[7]); } // 2nd stage: column transform col_txfm(buf1, buf1, INV_COS_BIT, 1, bd, 0); round_shift_array_32_neon(buf1, buf1, txfm_size_row, -shift[1]); // write to buffer highbd_write_buffer_4xn_neon(buf1, output, stride, ud_flip, txfm_size_row, bd); } void av1_inv_txfm2d_add_8x4_neon(const int32_t *input, uint16_t *output, int stride, TX_TYPE tx_type, const int bd) { TX_SIZE tx_size = TX_8X4; int32x4_t buf1[8]; const int8_t *shift = av1_inv_txfm_shift_ls[tx_size]; const int txw_idx = get_txw_idx(tx_size); const int txh_idx = get_txh_idx(tx_size); const int txfm_size_col = tx_size_wide[tx_size]; const int txfm_size_row = tx_size_high[tx_size]; const transform_1d_neon row_txfm = highbd_txfm_all_1d_zeros_w8_arr[txw_idx][hitx_1d_tab[tx_type]][1]; const transform_1d_neon col_txfm = highbd_txfm_all_1d_zeros_w8_arr[txh_idx][vitx_1d_tab[tx_type]][0]; assert(col_txfm != NULL); assert(row_txfm != NULL); int ud_flip, lr_flip; get_flip_cfg(tx_type, &ud_flip, &lr_flip); // 1st stage: column transform int32x4_t buf0[8]; const int32_t *input_row = input; load_buffer_32bit_input(input_row, 4, buf0, txfm_size_col); round_shift_rect_array_32_neon(buf0, buf0, txfm_size_col); row_txfm(buf0, buf0, INV_COS_BIT, 0, bd, -shift[0]); int32x4_t *buf1_ptr; if (lr_flip) { flip_buf_neon(buf0, buf1, txfm_size_col); buf1_ptr = buf1; } else { buf1_ptr = buf0; } // 2nd stage: column transform for (int i = 0; i < 2; i++) { int32x4_t *buf1_cur = buf1_ptr + i * txfm_size_row; transpose_4x4(buf1_cur, buf1_cur); col_txfm(buf1_cur, buf1_cur, INV_COS_BIT, 1, bd, 0); } round_shift_array_32_neon(buf1_ptr, buf1_ptr, txfm_size_col, -shift[1]); // write to buffer highbd_write_buffer_8xn_neon(buf1_ptr, output, stride, ud_flip, txfm_size_row, bd); } void av1_inv_txfm2d_add_4x16_neon(const int32_t *input, uint16_t *output, int stride, TX_TYPE tx_type, const int bd) { TX_SIZE tx_size = TX_4X16; int32x4_t buf1[16]; const int8_t *shift = av1_inv_txfm_shift_ls[tx_size]; const int txw_idx = get_txw_idx(tx_size); const int txh_idx = get_txh_idx(tx_size); const int txfm_size_col = tx_size_wide[tx_size]; const int txfm_size_row = tx_size_high[tx_size]; const int buf_size_h_div8 = txfm_size_row >> 2; const transform_1d_neon row_txfm = highbd_txfm_all_1d_zeros_w8_arr[txw_idx][hitx_1d_tab[tx_type]][0]; const transform_1d_neon col_txfm = highbd_txfm_all_1d_zeros_w8_arr[txh_idx][vitx_1d_tab[tx_type]][2]; const int input_stride = AOMMIN(32, txfm_size_row); assert(col_txfm != NULL); assert(row_txfm != NULL); int ud_flip, lr_flip; get_flip_cfg(tx_type, &ud_flip, &lr_flip); // 1st stage: column transform int32x4_t buf0[16]; for (int i = 0; i < (txfm_size_row >> 2); i++) { const int32_t *input_row = input + i * 4; int32x4_t *buf0_cur = buf0 + i * 4; load_buffer_32bit_input(input_row, input_stride, buf0_cur, txfm_size_col); row_txfm(buf0 + (i << 2), buf0 + (i << 2), INV_COS_BIT, 0, bd, -shift[0]); } if (lr_flip) { for (int j = 0; j < buf_size_h_div8; ++j) { TRANSPOSE_4X4(buf0[4 * j + 3], buf0[4 * j + 2], buf0[4 * j + 1], buf0[4 * j], buf1[4 * j], buf1[4 * j + 1], buf1[4 * j + 2], buf1[4 * j + 3]); } } else { for (int j = 0; j < buf_size_h_div8; ++j) { TRANSPOSE_4X4(buf0[4 * j], buf0[4 * j + 1], buf0[4 * j + 2], buf0[4 * j + 3], buf1[4 * j], buf1[4 * j + 1], buf1[4 * j + 2], buf1[4 * j + 3]); } } // 2nd stage: column transform col_txfm(buf1, buf1, INV_COS_BIT, 1, bd, 0); round_shift_array_32_neon(buf1, buf1, txfm_size_row, -shift[1]); // write to buffer highbd_write_buffer_4xn_neon(buf1, output, stride, ud_flip, txfm_size_row, bd); } void av1_inv_txfm2d_add_16x4_neon(const int32_t *input, uint16_t *output, int stride, TX_TYPE tx_type, const int bd) { TX_SIZE tx_size = TX_16X4; int32x4_t buf1[16]; const int8_t *shift = av1_inv_txfm_shift_ls[tx_size]; const int txw_idx = get_txw_idx(tx_size); const int txh_idx = get_txh_idx(tx_size); const int txfm_size_col = tx_size_wide[tx_size]; const int txfm_size_row = tx_size_high[tx_size]; const int buf_size_w_div8 = txfm_size_col >> 2; const transform_1d_neon row_txfm = highbd_txfm_all_1d_zeros_w8_arr[txw_idx][hitx_1d_tab[tx_type]][2]; const transform_1d_neon col_txfm = highbd_txfm_all_1d_zeros_w8_arr[txh_idx][vitx_1d_tab[tx_type]][0]; assert(col_txfm != NULL); assert(row_txfm != NULL); int ud_flip, lr_flip; get_flip_cfg(tx_type, &ud_flip, &lr_flip); // 1st stage: column transform int32x4_t buf0[16]; const int32_t *input_row = input; load_buffer_32bit_input(input_row, 4, buf0, txfm_size_col); row_txfm(buf0, buf0, INV_COS_BIT, 0, bd, -shift[0]); int32x4_t *buf1_ptr; if (lr_flip) { flip_buf_neon(buf0, buf1, txfm_size_col); buf1_ptr = buf1; } else { buf1_ptr = buf0; } // 2nd stage: column transform for (int i = 0; i < buf_size_w_div8; i++) { int32x4_t *buf1_cur = buf1_ptr + i * txfm_size_row; transpose_4x4(buf1_cur, buf1_cur); col_txfm(buf1_cur, buf1_cur, INV_COS_BIT, 1, bd, 0); } round_shift_array_32_neon(buf1_ptr, buf1_ptr, txfm_size_col, -shift[1]); // write to buffer for (int i = 0; i < (txfm_size_col >> 3); i++) { highbd_write_buffer_8xn_neon(buf1_ptr + i * txfm_size_row * 2, output + 8 * i, stride, ud_flip, txfm_size_row, bd); } } static const int lowbd_txfm_all_1d_zeros_idx[32] = { 0, 1, 1, 1, 1, 1, 1, 1, 2, 2, 2, 2, 2, 2, 2, 2, 3, 3, 3, 3, 3, 3, 3, 3, 3, 3, 3, 3, 3, 3, 3, 3, }; // Transform block width in log2 for eob (size of 64 map to 32) static const int tx_size_wide_log2_eob[TX_SIZES_ALL] = { 2, 3, 4, 5, 5, 2, 3, 3, 4, 4, 5, 5, 5, 2, 4, 3, 5, 4, 5, }; DECLARE_ALIGNED(16, static const int16_t, av1_eob_to_eobxy_8x8_default[8]) = { 0x0707, 0x0707, 0x0707, 0x0707, 0x0707, 0x0707, 0x0707, 0x0707, }; DECLARE_ALIGNED(16, static const int16_t, av1_eob_to_eobxy_16x16_default[16]) = { 0x0707, 0x0707, 0x0f0f, 0x0f0f, 0x0f0f, 0x0f0f, 0x0f0f, 0x0f0f, 0x0f0f, 0x0f0f, 0x0f0f, 0x0f0f, 0x0f0f, 0x0f0f, 0x0f0f, 0x0f0f, }; DECLARE_ALIGNED(16, static const int16_t, av1_eob_to_eobxy_32x32_default[32]) = { 0x0707, 0x0f0f, 0x0f0f, 0x0f0f, 0x1f1f, 0x1f1f, 0x1f1f, 0x1f1f, 0x1f1f, 0x1f1f, 0x1f1f, 0x1f1f, 0x1f1f, 0x1f1f, 0x1f1f, 0x1f1f, 0x1f1f, 0x1f1f, 0x1f1f, 0x1f1f, 0x1f1f, 0x1f1f, 0x1f1f, 0x1f1f, 0x1f1f, 0x1f1f, 0x1f1f, 0x1f1f, 0x1f1f, 0x1f1f, 0x1f1f, 0x1f1f, }; DECLARE_ALIGNED(16, static const int16_t, av1_eob_to_eobxy_8x16_default[16]) = { 0x0707, 0x0707, 0x0707, 0x0707, 0x0707, 0x0f07, 0x0f07, 0x0f07, 0x0f07, 0x0f07, 0x0f07, 0x0f07, 0x0f07, 0x0f07, 0x0f07, 0x0f07, }; DECLARE_ALIGNED(16, static const int16_t, av1_eob_to_eobxy_16x8_default[8]) = { 0x0707, 0x0707, 0x070f, 0x070f, 0x070f, 0x070f, 0x070f, 0x070f, }; DECLARE_ALIGNED(16, static const int16_t, av1_eob_to_eobxy_16x32_default[32]) = { 0x0707, 0x0707, 0x0f0f, 0x0f0f, 0x0f0f, 0x0f0f, 0x0f0f, 0x0f0f, 0x0f0f, 0x1f0f, 0x1f0f, 0x1f0f, 0x1f0f, 0x1f0f, 0x1f0f, 0x1f0f, 0x1f0f, 0x1f0f, 0x1f0f, 0x1f0f, 0x1f0f, 0x1f0f, 0x1f0f, 0x1f0f, 0x1f0f, 0x1f0f, 0x1f0f, 0x1f0f, 0x1f0f, 0x1f0f, 0x1f0f, 0x1f0f, }; DECLARE_ALIGNED(16, static const int16_t, av1_eob_to_eobxy_32x16_default[16]) = { 0x0707, 0x0f0f, 0x0f0f, 0x0f0f, 0x0f1f, 0x0f1f, 0x0f1f, 0x0f1f, 0x0f1f, 0x0f1f, 0x0f1f, 0x0f1f, 0x0f1f, 0x0f1f, 0x0f1f, 0x0f1f, }; DECLARE_ALIGNED(16, static const int16_t, av1_eob_to_eobxy_8x32_default[32]) = { 0x0707, 0x0707, 0x0707, 0x0707, 0x0707, 0x0f07, 0x0f07, 0x0f07, 0x0f07, 0x0f07, 0x0f07, 0x0f07, 0x0f07, 0x1f07, 0x1f07, 0x1f07, 0x1f07, 0x1f07, 0x1f07, 0x1f07, 0x1f07, 0x1f07, 0x1f07, 0x1f07, 0x1f07, 0x1f07, 0x1f07, 0x1f07, 0x1f07, 0x1f07, 0x1f07, 0x1f07, }; DECLARE_ALIGNED(16, static const int16_t, av1_eob_to_eobxy_32x8_default[8]) = { 0x0707, 0x070f, 0x070f, 0x071f, 0x071f, 0x071f, 0x071f, 0x071f, }; DECLARE_ALIGNED(16, static const int16_t *, av1_eob_to_eobxy_default[TX_SIZES_ALL]) = { NULL, av1_eob_to_eobxy_8x8_default, av1_eob_to_eobxy_16x16_default, av1_eob_to_eobxy_32x32_default, av1_eob_to_eobxy_32x32_default, NULL, NULL, av1_eob_to_eobxy_8x16_default, av1_eob_to_eobxy_16x8_default, av1_eob_to_eobxy_16x32_default, av1_eob_to_eobxy_32x16_default, av1_eob_to_eobxy_32x32_default, av1_eob_to_eobxy_32x32_default, NULL, NULL, av1_eob_to_eobxy_8x32_default, av1_eob_to_eobxy_32x8_default, av1_eob_to_eobxy_16x32_default, av1_eob_to_eobxy_32x16_default, }; static inline void highbd_get_eobx_eoby_scan_default(int *eobx, int *eoby, TX_SIZE tx_size, int eob) { if (eob == 1) { *eobx = 0; *eoby = 0; return; } const int tx_w_log2 = tx_size_wide_log2_eob[tx_size]; const int eob_row = (eob - 1) >> tx_w_log2; const int eobxy = av1_eob_to_eobxy_default[tx_size][eob_row]; *eobx = eobxy & 0xFF; *eoby = eobxy >> 8; } static inline void get_eobx_eoby_scan_default(int *eobx, int *eoby, TX_SIZE tx_size) { if (tx_size == 2) { *eoby = 15, *eobx = 15; } else if (tx_size == 3) { *eoby = 31, *eobx = 31; } else if (tx_size == 4) { *eoby = 31, *eobx = 31; } else if (tx_size == 7) { *eoby = 15, *eobx = 7; } else if (tx_size == 8) { *eoby = 7, *eobx = 15; } else if (tx_size == 9) { *eoby = 31, *eobx = 15; } else if (tx_size == 10) { *eoby = 15, *eobx = 31; } else if (tx_size == 11) { *eoby = 31, *eobx = 31; } else if (tx_size == 12) { *eoby = 31, *eobx = 31; } else if (tx_size == 15) { *eoby = 31, *eobx = 7; } else if (tx_size == 16) { *eoby = 7, *eobx = 31; } else if (tx_size == 17) { *eoby = 31, *eobx = 15; } else if (tx_size == 18) { *eoby = 15, *eobx = 31; } else { *eoby = 0, *eobx = 0; } } static inline void get_eobx_eoby_scan_v_identity(int *eobx, int *eoby, TX_SIZE tx_size) { const int txfm_size_row = tx_size_high[tx_size]; *eoby = AOMMIN(32, txfm_size_row) - 1; *eobx = 0; } static inline void get_eobx_eoby_scan_h_identity(int *eobx, int *eoby, TX_SIZE tx_size) { const int txfm_size_col = tx_size_wide[tx_size]; *eobx = AOMMIN(32, txfm_size_col) - 1; *eoby = 0; } static void inv_txfm2d_add_h_identity_neon(const int32_t *input, uint16_t *output, int stride, TX_TYPE tx_type, TX_SIZE tx_size, const int bd) { int32x4_t buf1[64]; int eobx, eoby; get_eobx_eoby_scan_v_identity(&eobx, &eoby, tx_size); const int8_t *shift = av1_inv_txfm_shift_ls[tx_size]; const int txw_idx = get_txw_idx(tx_size); const int txh_idx = get_txh_idx(tx_size); const int txfm_size_col = tx_size_wide[tx_size]; const int txfm_size_row = tx_size_high[tx_size]; const int buf_size_w = AOMMIN(32, txfm_size_col); const int buf_size_w_div4 = buf_size_w >> 2; const int buf_size_h_div8 = (eoby + 8) >> 3; const int row_max = AOMMIN(32, txfm_size_row); const int input_stride = row_max; const int rect_type = get_rect_tx_log_ratio(txfm_size_col, txfm_size_row); const int fun_idx = lowbd_txfm_all_1d_zeros_idx[eoby]; const transform_1d_neon row_txfm = highbd_txfm_all_1d_zeros_w8_arr[txw_idx][hitx_1d_tab[tx_type]][0]; assert(row_txfm != NULL); const transform_1d_neon col_txfm = highbd_txfm_all_1d_zeros_w8_arr[txh_idx][vitx_1d_tab[tx_type]][fun_idx]; assert(col_txfm != NULL); int ud_flip, lr_flip; get_flip_cfg(tx_type, &ud_flip, &lr_flip); for (int i = 0; i < (buf_size_h_div8 << 1); ++i) { int32x4_t buf0[16]; load_buffer_32bit_input(input + i * 4, input_stride, buf0, buf_size_w); if (rect_type == 1 || rect_type == -1) { round_shift_rect_array_32_neon(buf0, buf0, buf_size_w); } row_txfm(buf0, buf0, INV_COS_BIT, 0, bd, -shift[0]); int32x4_t *_buf1 = buf1 + i * 4; for (int j = 0; j < buf_size_w_div4; ++j) { int32x4_t *buf0_cur = buf0 + j * 4; TRANSPOSE_4X4(buf0_cur[0], buf0_cur[1], buf0_cur[2], buf0_cur[3], buf0_cur[0], buf0_cur[1], buf0_cur[2], buf0_cur[3]); _buf1[j * txfm_size_row + 0] = buf0_cur[0]; _buf1[j * txfm_size_row + 1] = buf0_cur[1]; _buf1[j * txfm_size_row + 2] = buf0_cur[2]; _buf1[j * txfm_size_row + 3] = buf0_cur[3]; } } for (int i = 0; i < buf_size_w_div4; i++) { col_txfm(buf1 + i * txfm_size_row, buf1 + i * txfm_size_row, INV_COS_BIT, 1, bd, 0); round_shift_array_32_neon(buf1 + i * txfm_size_row, buf1 + i * txfm_size_row, txfm_size_row, -shift[1]); } // write to buffer for (int i = 0; i < (txfm_size_col >> 3); i++) { highbd_write_buffer_8xn_neon(buf1 + i * txfm_size_row * 2, output + 8 * i, stride, ud_flip, txfm_size_row, bd); } } static void inv_txfm2d_add_v_identity_neon(const int32_t *input, uint16_t *output, int stride, TX_TYPE tx_type, TX_SIZE tx_size, const int bd) { int32x4_t buf1[64]; int eobx, eoby; get_eobx_eoby_scan_h_identity(&eobx, &eoby, tx_size); const int8_t *shift = av1_inv_txfm_shift_ls[tx_size]; const int txw_idx = get_txw_idx(tx_size); const int txh_idx = get_txh_idx(tx_size); const int txfm_size_col = tx_size_wide[tx_size]; const int txfm_size_row = tx_size_high[tx_size]; const int buf_size_w_div4 = AOMMIN(32, txfm_size_col) >> 2; const int row_max = AOMMIN(32, txfm_size_row); const int input_stride = row_max; const int buf_size_nonzero_w_div8 = (eobx + 8) >> 3; const int buf_size_nonzero_w = buf_size_nonzero_w_div8 << 3; const int rect_type = get_rect_tx_log_ratio(txfm_size_col, txfm_size_row); const int fun_idx = lowbd_txfm_all_1d_zeros_idx[eobx]; const transform_1d_neon row_txfm = highbd_txfm_all_1d_zeros_w8_arr[txw_idx][hitx_1d_tab[tx_type]][fun_idx]; assert(row_txfm != NULL); const transform_1d_neon col_txfm = highbd_txfm_all_1d_zeros_w8_arr[txh_idx][vitx_1d_tab[tx_type]][0]; assert(col_txfm != NULL); int ud_flip, lr_flip; get_flip_cfg(tx_type, &ud_flip, &lr_flip); for (int i = 0; i < (row_max >> 2); ++i) { int32x4_t buf0[16]; load_buffer_32bit_input(input + i * 4, input_stride, buf0, buf_size_nonzero_w); if (rect_type == 1 || rect_type == -1) { round_shift_rect_array_32_neon(buf0, buf0, buf_size_nonzero_w); } row_txfm(buf0, buf0, INV_COS_BIT, 0, bd, -shift[0]); int32x4_t *_buf1 = buf1 + i * 4; if (lr_flip) { for (int j = 0; j < buf_size_w_div4; ++j) { TRANSPOSE_4X4(buf0[4 * j + 3], buf0[4 * j + 2], buf0[4 * j + 1], buf0[4 * j], _buf1[txfm_size_row * (buf_size_w_div4 - 1 - j) + 0], _buf1[txfm_size_row * (buf_size_w_div4 - 1 - j) + 1], _buf1[txfm_size_row * (buf_size_w_div4 - 1 - j) + 2], _buf1[txfm_size_row * (buf_size_w_div4 - 1 - j) + 3]); } } else { for (int j = 0; j < buf_size_w_div4; ++j) { TRANSPOSE_4X4( buf0[j * 4 + 0], buf0[j * 4 + 1], buf0[j * 4 + 2], buf0[j * 4 + 3], _buf1[j * txfm_size_row + 0], _buf1[j * txfm_size_row + 1], _buf1[j * txfm_size_row + 2], _buf1[j * txfm_size_row + 3]); } } } for (int i = 0; i < buf_size_w_div4; i++) { col_txfm(buf1 + i * txfm_size_row, buf1 + i * txfm_size_row, INV_COS_BIT, 1, bd, 0); round_shift_array_32_neon(buf1 + i * txfm_size_row, buf1 + i * txfm_size_row, txfm_size_row, -shift[1]); } // write to buffer { for (int i = 0; i < (txfm_size_col >> 3); i++) { highbd_write_buffer_8xn_neon(buf1 + i * txfm_size_row * 2, output + 8 * i, stride, ud_flip, txfm_size_row, bd); } } } static void inv_txfm2d_add_idtx_neon(const int32_t *input, uint16_t *output, int stride, TX_TYPE tx_type, TX_SIZE tx_size, const int bd) { int32x4_t buf1[64 * 4]; const int8_t *shift = av1_inv_txfm_shift_ls[tx_size]; const int txw_idx = get_txw_idx(tx_size); const int txh_idx = get_txh_idx(tx_size); const int txfm_size_col = tx_size_wide[tx_size]; const int txfm_size_row = tx_size_high[tx_size]; const int row_max = AOMMIN(32, txfm_size_row); const int input_stride = row_max; const int buf_size_w = AOMMIN(32, txfm_size_col); const int buf_size_w_div4 = buf_size_w >> 2; const int rect_type = get_rect_tx_log_ratio(txfm_size_col, txfm_size_row); const transform_1d_neon row_txfm = highbd_txfm_all_1d_zeros_w8_arr[txw_idx][hitx_1d_tab[tx_type]][0]; assert(row_txfm != NULL); const transform_1d_neon col_txfm = highbd_txfm_all_1d_zeros_w8_arr[txh_idx][vitx_1d_tab[tx_type]][0]; assert(col_txfm != NULL); for (int i = 0; i < (row_max >> 2); ++i) { int32x4_t buf0[32]; load_buffer_32bit_input(input + i * 4, input_stride, buf0, buf_size_w); if (rect_type == 1 || rect_type == -1) { round_shift_rect_array_32_neon(buf0, buf0, buf_size_w); } row_txfm(buf0, buf0, INV_COS_BIT, 0, bd, -shift[0]); int32x4_t *_buf1 = buf1 + i * 4; for (int j = 0; j < buf_size_w_div4; ++j) { int32x4_t *buf0_cur = buf0 + j * 4; TRANSPOSE_4X4(buf0_cur[0], buf0_cur[1], buf0_cur[2], buf0_cur[3], buf0_cur[0], buf0_cur[1], buf0_cur[2], buf0_cur[3]); _buf1[j * txfm_size_row + 0] = buf0_cur[0]; _buf1[j * txfm_size_row + 1] = buf0_cur[1]; _buf1[j * txfm_size_row + 2] = buf0_cur[2]; _buf1[j * txfm_size_row + 3] = buf0_cur[3]; } } for (int i = 0; i < buf_size_w_div4; i++) { col_txfm(buf1 + i * txfm_size_row, buf1 + i * txfm_size_row, INV_COS_BIT, 1, bd, 0); round_shift_array_32_neon(buf1 + i * txfm_size_row, buf1 + i * txfm_size_row, txfm_size_row, -shift[1]); } // write to buffer { for (int i = 0; i < (txfm_size_col >> 3); i++) { highbd_write_buffer_8xn_neon(buf1 + i * txfm_size_row * 2, output + 8 * i, stride, 0, txfm_size_row, bd); } } } static void inv_txfm2d_add_no_identity_neon(const int32_t *input, uint16_t *output, int stride, TX_TYPE tx_type, TX_SIZE tx_size, const int bd) { int32x4_t buf1[64 * 16]; int eobx, eoby; get_eobx_eoby_scan_default(&eobx, &eoby, tx_size); const int8_t *shift = av1_inv_txfm_shift_ls[tx_size]; const int txw_idx = get_txw_idx(tx_size); const int txh_idx = get_txh_idx(tx_size); const int txfm_size_col = tx_size_wide[tx_size]; const int txfm_size_row = tx_size_high[tx_size]; const int buf_size_w_div4 = txfm_size_col >> 2; const int buf_size_nonzero_w = (eobx + 8) >> 3 << 3; const int buf_size_nonzero_h_div8 = (eoby + 8) >> 3; const int input_stride = AOMMIN(32, txfm_size_row); const int rect_type = get_rect_tx_log_ratio(txfm_size_col, txfm_size_row); const int fun_idx_x = lowbd_txfm_all_1d_zeros_idx[eobx]; const int fun_idx_y = lowbd_txfm_all_1d_zeros_idx[eoby]; const transform_1d_neon row_txfm = highbd_txfm_all_1d_zeros_w8_arr[txw_idx][hitx_1d_tab[tx_type]][fun_idx_x]; const transform_1d_neon col_txfm = highbd_txfm_all_1d_zeros_w8_arr[txh_idx][vitx_1d_tab[tx_type]][fun_idx_y]; assert(col_txfm != NULL); assert(row_txfm != NULL); int ud_flip, lr_flip; get_flip_cfg(tx_type, &ud_flip, &lr_flip); // 1st stage: column transform for (int i = 0; i < buf_size_nonzero_h_div8 << 1; i++) { int32x4_t buf0[64]; load_buffer_32bit_input(input + i * 4, input_stride, buf0, buf_size_nonzero_w); if (rect_type == 1 || rect_type == -1) { round_shift_rect_array_32_neon(buf0, buf0, buf_size_nonzero_w); } row_txfm(buf0, buf0, INV_COS_BIT, 0, bd, -shift[0]); int32x4_t *_buf1 = &buf1[i * 4]; if (lr_flip) { for (int j = 0; j < buf_size_w_div4; ++j) { TRANSPOSE_4X4(buf0[4 * j + 3], buf0[4 * j + 2], buf0[4 * j + 1], buf0[4 * j], _buf1[txfm_size_row * (buf_size_w_div4 - 1 - j) + 0], _buf1[txfm_size_row * (buf_size_w_div4 - 1 - j) + 1], _buf1[txfm_size_row * (buf_size_w_div4 - 1 - j) + 2], _buf1[txfm_size_row * (buf_size_w_div4 - 1 - j) + 3]); } } else { for (int j = 0; j < buf_size_w_div4; ++j) { TRANSPOSE_4X4( buf0[j * 4 + 0], buf0[j * 4 + 1], buf0[j * 4 + 2], buf0[j * 4 + 3], _buf1[j * txfm_size_row + 0], _buf1[j * txfm_size_row + 1], _buf1[j * txfm_size_row + 2], _buf1[j * txfm_size_row + 3]); } } } // 2nd stage: column transform for (int i = 0; i < buf_size_w_div4; i++) { col_txfm(buf1 + i * txfm_size_row, buf1 + i * txfm_size_row, INV_COS_BIT, 1, bd, 0); round_shift_array_32_neon(buf1 + i * txfm_size_row, buf1 + i * txfm_size_row, txfm_size_row, -shift[1]); } // write to buffer { for (int i = 0; i < (txfm_size_col >> 3); i++) { highbd_write_buffer_8xn_neon(buf1 + i * txfm_size_row * 2, output + 8 * i, stride, ud_flip, txfm_size_row, bd); } } } static void highbd_inv_txfm2d_add_no_identity_neon(const int32_t *input, uint16_t *output, int stride, TX_TYPE tx_type, TX_SIZE tx_size, int eob, const int bd) { int32x4_t buf1[64 * 16]; int eobx, eoby; highbd_get_eobx_eoby_scan_default(&eobx, &eoby, tx_size, eob); const int8_t *shift = av1_inv_txfm_shift_ls[tx_size]; const int txw_idx = get_txw_idx(tx_size); const int txh_idx = get_txh_idx(tx_size); const int txfm_size_col = tx_size_wide[tx_size]; const int txfm_size_row = tx_size_high[tx_size]; const int buf_size_w_div8 = txfm_size_col >> 2; const int buf_size_nonzero_w_div8 = (eobx + 8) >> 3; const int buf_size_nonzero_h_div8 = (eoby + 8) >> 3; const int input_stride = AOMMIN(32, txfm_size_col); const int rect_type = get_rect_tx_log_ratio(txfm_size_col, txfm_size_row); const int fun_idx_x = lowbd_txfm_all_1d_zeros_idx[eobx]; const int fun_idx_y = lowbd_txfm_all_1d_zeros_idx[eoby]; const transform_1d_neon row_txfm = highbd_txfm_all_1d_zeros_w8_arr[txw_idx][hitx_1d_tab[tx_type]][fun_idx_x]; const transform_1d_neon col_txfm = highbd_txfm_all_1d_zeros_w8_arr[txh_idx][vitx_1d_tab[tx_type]][fun_idx_y]; assert(col_txfm != NULL); assert(row_txfm != NULL); int ud_flip, lr_flip; get_flip_cfg(tx_type, &ud_flip, &lr_flip); // 1st stage: column transform for (int i = 0; i < buf_size_nonzero_h_div8 << 1; i++) { int32x4_t buf0[64]; const int32_t *input_row = input + i * input_stride * 4; for (int j = 0; j < buf_size_nonzero_w_div8 << 1; ++j) { int32x4_t *buf0_cur = &buf0[j * 4]; load_buffer_32bit_input(input_row + j * 4, input_stride, buf0_cur, 4); TRANSPOSE_4X4(buf0_cur[0], buf0_cur[1], buf0_cur[2], buf0_cur[3], buf0_cur[0], buf0_cur[1], buf0_cur[2], buf0_cur[3]); } if (rect_type == 1 || rect_type == -1) { round_shift_rect_array_32_neon(buf0, buf0, buf_size_nonzero_w_div8 << 3); } row_txfm(buf0, buf0, INV_COS_BIT, 0, bd, -shift[0]); int32x4_t *_buf1 = &buf1[i * 4]; if (lr_flip) { for (int j = 0; j < buf_size_w_div8; ++j) { TRANSPOSE_4X4(buf0[4 * j + 3], buf0[4 * j + 2], buf0[4 * j + 1], buf0[4 * j], _buf1[txfm_size_row * (buf_size_w_div8 - 1 - j) + 0], _buf1[txfm_size_row * (buf_size_w_div8 - 1 - j) + 1], _buf1[txfm_size_row * (buf_size_w_div8 - 1 - j) + 2], _buf1[txfm_size_row * (buf_size_w_div8 - 1 - j) + 3]); } } else { for (int j = 0; j < buf_size_w_div8; ++j) { TRANSPOSE_4X4( buf0[j * 4 + 0], buf0[j * 4 + 1], buf0[j * 4 + 2], buf0[j * 4 + 3], _buf1[j * txfm_size_row + 0], _buf1[j * txfm_size_row + 1], _buf1[j * txfm_size_row + 2], _buf1[j * txfm_size_row + 3]); } } } // 2nd stage: column transform for (int i = 0; i < buf_size_w_div8; i++) { col_txfm(buf1 + i * txfm_size_row, buf1 + i * txfm_size_row, INV_COS_BIT, 1, bd, 0); round_shift_array_32_neon(buf1 + i * txfm_size_row, buf1 + i * txfm_size_row, txfm_size_row, -shift[1]); } // write to buffer { for (int i = 0; i < (txfm_size_col >> 3); i++) { highbd_write_buffer_8xn_neon(buf1 + i * txfm_size_row * 2, output + 8 * i, stride, ud_flip, txfm_size_row, bd); } } } static void highbd_inv_txfm2d_add_universe_neon(const int32_t *input, uint8_t *output, int stride, TX_TYPE tx_type, TX_SIZE tx_size, int eob, const int bd) { switch (tx_type) { case DCT_DCT: case ADST_DCT: case DCT_ADST: case ADST_ADST: case FLIPADST_DCT: case DCT_FLIPADST: case FLIPADST_FLIPADST: case ADST_FLIPADST: case FLIPADST_ADST: highbd_inv_txfm2d_add_no_identity_neon(input, CONVERT_TO_SHORTPTR(output), stride, tx_type, tx_size, eob, bd); break; case V_DCT: case V_ADST: case V_FLIPADST: inv_txfm2d_add_h_identity_neon(input, CONVERT_TO_SHORTPTR(output), stride, tx_type, tx_size, bd); break; case H_DCT: case H_ADST: case H_FLIPADST: inv_txfm2d_add_v_identity_neon(input, CONVERT_TO_SHORTPTR(output), stride, tx_type, tx_size, bd); break; case IDTX: inv_txfm2d_add_idtx_neon(input, CONVERT_TO_SHORTPTR(output), stride, tx_type, tx_size, bd); break; default: assert(0); break; } } static void inv_txfm2d_add_universe_neon(const int32_t *input, uint8_t *output, int stride, TX_TYPE tx_type, TX_SIZE tx_size, const int bd) { switch (tx_type) { case DCT_DCT: case ADST_DCT: case DCT_ADST: case ADST_ADST: case FLIPADST_DCT: case DCT_FLIPADST: case FLIPADST_FLIPADST: case ADST_FLIPADST: case FLIPADST_ADST: inv_txfm2d_add_no_identity_neon(input, CONVERT_TO_SHORTPTR(output), stride, tx_type, tx_size, bd); break; case V_DCT: case V_ADST: case V_FLIPADST: inv_txfm2d_add_h_identity_neon(input, CONVERT_TO_SHORTPTR(output), stride, tx_type, tx_size, bd); break; case H_DCT: case H_ADST: case H_FLIPADST: inv_txfm2d_add_v_identity_neon(input, CONVERT_TO_SHORTPTR(output), stride, tx_type, tx_size, bd); break; case IDTX: inv_txfm2d_add_idtx_neon(input, CONVERT_TO_SHORTPTR(output), stride, tx_type, tx_size, bd); break; default: assert(0); break; } } static void highbd_inv_txfm_add_8x8_neon(const tran_low_t *input, uint8_t *dest, int stride, const TxfmParam *txfm_param) { int bd = txfm_param->bd; const TX_TYPE tx_type = txfm_param->tx_type; const int32_t *src = cast_to_int32(input); switch (tx_type) { case IDTX: case H_DCT: case H_ADST: case H_FLIPADST: case V_DCT: case V_ADST: case V_FLIPADST: highbd_inv_txfm2d_add_universe_neon(input, dest, stride, tx_type, txfm_param->tx_size, txfm_param->eob, bd); break; default: av1_inv_txfm2d_add_8x8_neon(src, CONVERT_TO_SHORTPTR(dest), stride, tx_type, bd); break; } } static void highbd_inv_txfm_add_4x4_neon(const tran_low_t *input, uint8_t *dest, int stride, const TxfmParam *txfm_param) { assert(av1_ext_tx_used[txfm_param->tx_set_type][txfm_param->tx_type]); int eob = txfm_param->eob; int bd = txfm_param->bd; int lossless = txfm_param->lossless; const int32_t *src = cast_to_int32(input); const TX_TYPE tx_type = txfm_param->tx_type; if (lossless) { assert(tx_type == DCT_DCT); av1_highbd_iwht4x4_add(input, dest, stride, eob, bd); return; } av1_inv_txfm2d_add_4x4_neon(src, CONVERT_TO_SHORTPTR(dest), stride, tx_type, bd); } void av1_inv_txfm2d_add_8x16_neon(const tran_low_t *input, uint16_t *dest, int stride, TX_TYPE tx_type, const int bd) { inv_txfm2d_add_universe_neon(input, (uint8_t *)dest, stride, tx_type, TX_8X16, bd); } void av1_inv_txfm2d_add_16x8_neon(const tran_low_t *input, uint16_t *dest, int stride, TX_TYPE tx_type, const int bd) { inv_txfm2d_add_universe_neon(input, (uint8_t *)dest, stride, tx_type, TX_16X8, bd); } void av1_inv_txfm2d_add_16x32_neon(const tran_low_t *input, uint16_t *dest, int stride, TX_TYPE tx_type, const int bd) { inv_txfm2d_add_universe_neon(input, (uint8_t *)dest, stride, tx_type, TX_16X32, bd); } void av1_inv_txfm2d_add_32x16_neon(const tran_low_t *input, uint16_t *dest, int stride, TX_TYPE tx_type, const int bd) { inv_txfm2d_add_universe_neon(input, (uint8_t *)dest, stride, tx_type, TX_32X16, bd); } void av1_inv_txfm2d_add_32x32_neon(const tran_low_t *input, uint16_t *dest, int stride, TX_TYPE tx_type, const int bd) { inv_txfm2d_add_universe_neon(input, (uint8_t *)dest, stride, tx_type, TX_32X32, bd); } void av1_inv_txfm2d_add_64x64_neon(const tran_low_t *input, uint16_t *dest, int stride, TX_TYPE tx_type, const int bd) { inv_txfm2d_add_universe_neon(input, (uint8_t *)dest, stride, tx_type, TX_64X64, bd); } void av1_inv_txfm2d_add_32x64_neon(const tran_low_t *input, uint16_t *dest, int stride, TX_TYPE tx_type, const int bd) { inv_txfm2d_add_universe_neon(input, (uint8_t *)dest, stride, tx_type, TX_32X64, bd); } void av1_inv_txfm2d_add_64x32_neon(const tran_low_t *input, uint16_t *dest, int stride, TX_TYPE tx_type, const int bd) { inv_txfm2d_add_universe_neon(input, (uint8_t *)dest, stride, tx_type, TX_64X32, bd); } void av1_inv_txfm2d_add_64x16_neon(const tran_low_t *input, uint16_t *dest, int stride, TX_TYPE tx_type, const int bd) { inv_txfm2d_add_universe_neon(input, (uint8_t *)dest, stride, tx_type, TX_64X16, bd); } void av1_inv_txfm2d_add_16x64_neon(const tran_low_t *input, uint16_t *dest, int stride, TX_TYPE tx_type, const int bd) { inv_txfm2d_add_universe_neon(input, (uint8_t *)dest, stride, tx_type, TX_16X64, bd); } static void av1_inv_txfm2d_add_16x16_neon(const tran_low_t *input, uint16_t *dest, int stride, TX_TYPE tx_type, const int bd) { inv_txfm2d_add_universe_neon(input, (uint8_t *)dest, stride, tx_type, TX_16X16, bd); } void av1_inv_txfm2d_add_32x8_neon(const tran_low_t *input, uint16_t *dest, int stride, TX_TYPE tx_type, const int bd) { inv_txfm2d_add_universe_neon(input, (uint8_t *)dest, stride, tx_type, TX_32X8, bd); } void av1_inv_txfm2d_add_8x32_neon(const tran_low_t *input, uint16_t *dest, int stride, TX_TYPE tx_type, const int bd) { inv_txfm2d_add_universe_neon(input, (uint8_t *)dest, stride, tx_type, TX_8X32, bd); } void av1_highbd_inv_txfm_add_neon(const tran_low_t *input, uint8_t *dest, int stride, const TxfmParam *txfm_param) { const TX_SIZE tx_size = txfm_param->tx_size; TX_TYPE tx_type = txfm_param->tx_type; int bd = txfm_param->bd; switch (tx_size) { case TX_8X8: highbd_inv_txfm_add_8x8_neon(input, dest, stride, txfm_param); break; case TX_4X8: av1_inv_txfm2d_add_4x8_neon(input, CONVERT_TO_SHORTPTR(dest), stride, txfm_param->tx_type, txfm_param->bd); break; case TX_8X4: av1_inv_txfm2d_add_8x4_neon(input, CONVERT_TO_SHORTPTR(dest), stride, txfm_param->tx_type, txfm_param->bd); break; case TX_4X4: highbd_inv_txfm_add_4x4_neon(input, dest, stride, txfm_param); break; case TX_16X4: av1_inv_txfm2d_add_16x4_neon(input, CONVERT_TO_SHORTPTR(dest), stride, txfm_param->tx_type, txfm_param->bd); break; case TX_4X16: av1_inv_txfm2d_add_4x16_neon(input, CONVERT_TO_SHORTPTR(dest), stride, txfm_param->tx_type, txfm_param->bd); break; case TX_8X16: av1_inv_txfm2d_add_8x16_neon(input, (uint16_t *)dest, stride, tx_type, bd); break; case TX_16X8: av1_inv_txfm2d_add_16x8_neon(input, (uint16_t *)dest, stride, tx_type, bd); break; case TX_16X32: av1_inv_txfm2d_add_16x32_neon(input, (uint16_t *)dest, stride, tx_type, bd); break; case TX_32X16: av1_inv_txfm2d_add_32x16_neon(input, (uint16_t *)dest, stride, tx_type, bd); break; case TX_16X16: av1_inv_txfm2d_add_16x16_neon(input, (uint16_t *)dest, stride, tx_type, bd); break; case TX_32X32: av1_inv_txfm2d_add_32x32_neon(input, (uint16_t *)dest, stride, tx_type, bd); break; case TX_64X64: av1_inv_txfm2d_add_64x64_neon(input, (uint16_t *)dest, stride, tx_type, bd); break; case TX_32X64: av1_inv_txfm2d_add_32x64_neon(input, (uint16_t *)dest, stride, tx_type, bd); break; case TX_64X32: av1_inv_txfm2d_add_64x32_neon(input, (uint16_t *)dest, stride, tx_type, bd); break; case TX_16X64: av1_inv_txfm2d_add_16x64_neon(input, (uint16_t *)dest, stride, tx_type, bd); break; case TX_64X16: av1_inv_txfm2d_add_64x16_neon(input, (uint16_t *)dest, stride, tx_type, bd); break; case TX_32X8: av1_inv_txfm2d_add_32x8_neon(input, (uint16_t *)dest, stride, tx_type, bd); break; case TX_8X32: av1_inv_txfm2d_add_8x32_neon(input, (uint16_t *)dest, stride, tx_type, bd); break; } }