/* * 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 can * 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 "aom_dsp/arm/mem_neon.h" #include "aom_dsp/arm/transpose_neon.h" #include "aom_dsp/txfm_common.h" #include "aom_ports/mem.h" #include "av1/common/av1_txfm.h" #include "av1/encoder/av1_fwd_txfm1d_cfg.h" #include "config/aom_config.h" #include "config/av1_rtcd.h" #include "shift_neon.h" #include "txfm_neon.h" #define TXFM_COS_BIT_MAX 13 // A note on butterfly helper naming: // // butterfly_[input_ty]_[acc_ty]_[input_num]_[weight_num]_[weight_neg]_neon // e.g. butterfly_s32_s32_x4_0231_neon // | | | ^ Weights are applied as indices 0, 2, 3, 1 // | | | (see more detail below) // | | ^ (int32)x4 input/output parameters // | ^ 32-bit accumulators internally // ^ 32-bit input/output parameters // // Weights are stored as 4-tuples in Q2.13 format as (w0, 1-w0, -w0, w0-1) to // avoid needing separate negation instructions. This is represented in the // helper naming by referring to the lane index in the loaded tuple that each // multiply is performed with: // // in0 in1 // /---------- // out0 | w0 w1 ==> out0 = in0 * w0 + in1 * w1 // out1 | w2 w3 ==> out1 = in0 * w2 + in1 * w3 // // So for indices 0331 from the earlier example, we end up with: // // in0 in1 // /------------------ // out0 | (lane 0) (lane 2) ==> out0 = in0 * w0 + in1 * -w0 // out1 | (lane 3) (lane 1) ==> out1 = in0 * (w0-1) + in1 * (1-w0) static AOM_FORCE_INLINE void butterfly_s32_s32_x4_0112_neon( const int16x4_t w0101_s16, const int32x4_t in0, const int32x4_t in1, int32x4_t *out0, int32x4_t *out1) { int32x4_t w0101 = vmovl_s16(w0101_s16); int32x4_t o0 = vmulq_lane_s32(in0, vget_low_s32(w0101), 0); o0 = vmlaq_lane_s32(o0, in1, vget_low_s32(w0101), 1); int32x4_t o1 = vmulq_lane_s32(in0, vget_low_s32(w0101), 1); o1 = vmlaq_lane_s32(o1, in1, vget_high_s32(w0101), 0); *out0 = vrshrq_n_s32(o0, TXFM_COS_BIT_MAX); *out1 = vrshrq_n_s32(o1, TXFM_COS_BIT_MAX); } static AOM_FORCE_INLINE void butterfly_s32_s32_x4_0332_neon( const int16x4_t w0101_s16, const int32x4_t in0, const int32x4_t in1, int32x4_t *out0, int32x4_t *out1) { int32x4_t w0101 = vmovl_s16(w0101_s16); int32x4_t o0 = vmulq_lane_s32(in0, vget_low_s32(w0101), 0); o0 = vmlaq_lane_s32(o0, in1, vget_high_s32(w0101), 1); int32x4_t o1 = vmulq_lane_s32(in0, vget_high_s32(w0101), 1); o1 = vmlaq_lane_s32(o1, in1, vget_high_s32(w0101), 0); *out0 = vrshrq_n_s32(o0, TXFM_COS_BIT_MAX); *out1 = vrshrq_n_s32(o1, TXFM_COS_BIT_MAX); } static AOM_FORCE_INLINE void butterfly_s32_s32_x4_1003_neon( const int16x4_t w0101_s16, const int32x4_t in0, const int32x4_t in1, int32x4_t *out0, int32x4_t *out1) { int32x4_t w0101 = vmovl_s16(w0101_s16); int32x4_t o0 = vmulq_lane_s32(in0, vget_low_s32(w0101), 1); o0 = vmlaq_lane_s32(o0, in1, vget_low_s32(w0101), 0); int32x4_t o1 = vmulq_lane_s32(in0, vget_low_s32(w0101), 0); o1 = vmlaq_lane_s32(o1, in1, vget_high_s32(w0101), 1); *out0 = vrshrq_n_s32(o0, TXFM_COS_BIT_MAX); *out1 = vrshrq_n_s32(o1, TXFM_COS_BIT_MAX); } static AOM_FORCE_INLINE void butterfly_s32_s32_x4_1223_neon( const int16x4_t w0101_s16, const int32x4_t in0, const int32x4_t in1, int32x4_t *out0, int32x4_t *out1) { int32x4_t w0101 = vmovl_s16(w0101_s16); int32x4_t o0 = vmulq_lane_s32(in0, vget_low_s32(w0101), 1); o0 = vmlaq_lane_s32(o0, in1, vget_high_s32(w0101), 0); int32x4_t o1 = vmulq_lane_s32(in0, vget_high_s32(w0101), 0); o1 = vmlaq_lane_s32(o1, in1, vget_high_s32(w0101), 1); *out0 = vrshrq_n_s32(o0, TXFM_COS_BIT_MAX); *out1 = vrshrq_n_s32(o1, TXFM_COS_BIT_MAX); } #define butterfly_s16_s32_x4_neon(wvec, lane0, lane1, lane2, lane3, in0, in1, \ out0, out1) \ do { \ int32x4_t u0 = vmull_lane_s16(in0, wvec, lane0); \ u0 = vmlal_lane_s16(u0, in1, wvec, lane1); \ int32x4_t v0 = vmull_lane_s16(in0, wvec, lane2); \ v0 = vmlal_lane_s16(v0, in1, wvec, lane3); \ *out0 = vqrshrn_n_s32(u0, TXFM_COS_BIT_MAX); \ *out1 = vqrshrn_n_s32(v0, TXFM_COS_BIT_MAX); \ } while (0) static AOM_FORCE_INLINE void butterfly_s16_s32_x4_0112_neon( const int16x4_t w0101, const int16x4_t in0, const int16x4_t in1, int16x4_t *out0, int16x4_t *out1) { butterfly_s16_s32_x4_neon(w0101, 0, 1, 1, 2, in0, in1, out0, out1); } static AOM_FORCE_INLINE void butterfly_s16_s32_x4_0332_neon( const int16x4_t w0101, const int16x4_t in0, const int16x4_t in1, int16x4_t *out0, int16x4_t *out1) { butterfly_s16_s32_x4_neon(w0101, 0, 3, 3, 2, in0, in1, out0, out1); } static AOM_FORCE_INLINE void butterfly_s16_s32_x4_1003_neon( const int16x4_t w0101, const int16x4_t in0, const int16x4_t in1, int16x4_t *out0, int16x4_t *out1) { butterfly_s16_s32_x4_neon(w0101, 1, 0, 0, 3, in0, in1, out0, out1); } static AOM_FORCE_INLINE void butterfly_s16_s32_x4_1223_neon( const int16x4_t w0101, const int16x4_t in0, const int16x4_t in1, int16x4_t *out0, int16x4_t *out1) { butterfly_s16_s32_x4_neon(w0101, 1, 2, 2, 3, in0, in1, out0, out1); } #define butterfly_s16_s32_x8_neon(wvec, lane0, lane1, lane2, lane3, in0, in1, \ out0, out1) \ do { \ int32x4_t u0 = vmull_lane_s16(vget_low_s16(in0), wvec, lane0); \ u0 = vmlal_lane_s16(u0, vget_low_s16(in1), wvec, lane1); \ int32x4_t u1 = vmull_lane_s16(vget_high_s16(in0), wvec, lane0); \ u1 = vmlal_lane_s16(u1, vget_high_s16(in1), wvec, lane1); \ int32x4_t v0 = vmull_lane_s16(vget_low_s16(in0), wvec, lane2); \ v0 = vmlal_lane_s16(v0, vget_low_s16(in1), wvec, lane3); \ int32x4_t v1 = vmull_lane_s16(vget_high_s16(in0), wvec, lane2); \ v1 = vmlal_lane_s16(v1, vget_high_s16(in1), wvec, lane3); \ const int16x4_t c0 = vrshrn_n_s32(u0, TXFM_COS_BIT_MAX); \ const int16x4_t c1 = vrshrn_n_s32(u1, TXFM_COS_BIT_MAX); \ const int16x4_t d0 = vrshrn_n_s32(v0, TXFM_COS_BIT_MAX); \ const int16x4_t d1 = vrshrn_n_s32(v1, TXFM_COS_BIT_MAX); \ *out0 = vcombine_s16(c0, c1); \ *out1 = vcombine_s16(d0, d1); \ } while (0) static AOM_FORCE_INLINE void butterfly_s16_s32_x8_0112_neon( const int16x4_t w0101, const int16x8_t in0, const int16x8_t in1, int16x8_t *out0, int16x8_t *out1) { butterfly_s16_s32_x8_neon(w0101, 0, 1, 1, 2, in0, in1, out0, out1); } static AOM_FORCE_INLINE void butterfly_s16_s32_x8_0332_neon( const int16x4_t w0101, const int16x8_t in0, const int16x8_t in1, int16x8_t *out0, int16x8_t *out1) { butterfly_s16_s32_x8_neon(w0101, 0, 3, 3, 2, in0, in1, out0, out1); } static AOM_FORCE_INLINE void butterfly_s16_s32_x8_1003_neon( const int16x4_t w0101, const int16x8_t in0, const int16x8_t in1, int16x8_t *out0, int16x8_t *out1) { butterfly_s16_s32_x8_neon(w0101, 1, 0, 0, 3, in0, in1, out0, out1); } static AOM_FORCE_INLINE void butterfly_s16_s32_x8_1223_neon( const int16x4_t w0101, const int16x8_t in0, const int16x8_t in1, int16x8_t *out0, int16x8_t *out1) { butterfly_s16_s32_x8_neon(w0101, 1, 2, 2, 3, in0, in1, out0, out1); } static AOM_FORCE_INLINE void flip_buf_4_neon(int16x4_t *in, int16x4_t *out, int size) { for (int i = 0; i < size; ++i) { out[size - i - 1] = in[i]; } } static AOM_FORCE_INLINE void flip_buf_8_neon(int16x8_t *in, int16x8_t *out, int size) { for (int i = 0; i < size; ++i) { out[size - i - 1] = in[i]; } } static AOM_FORCE_INLINE void store_buffer_interleaved_s32_x8( int32_t *const out, const int32x4_t *const in1, const int32x4_t *const in2, const int stride, const int out_size) { for (int i = 0; i < out_size; ++i) { vst1q_s32(out + stride * i, in1[i]); vst1q_s32(out + stride * i + 4, in2[i]); } } static AOM_FORCE_INLINE void load_buffer_s16_x4(const int16_t *in, const int stride, int16x4_t *const out, const int out_size) { for (int i = 0; i < out_size; ++i) { out[i] = vld1_s16(in); in += stride; } } static AOM_FORCE_INLINE void load_buffer_s16_x8(const int16_t *in, int stride, int16x8_t *out, int out_size) { for (int i = 0; i < out_size; ++i) { out[i] = vld1q_s16(in + i * stride); } } static AOM_FORCE_INLINE void store_buffer_s16_x4(const int16x4_t *const in, int32_t *const out, const int stride, const int out_size) { for (int i = 0; i < out_size; ++i) { vst1q_s32(out + i * stride, vmovl_s16(in[i])); } } static AOM_FORCE_INLINE void store_buffer_s16_x8(const int16x8_t *const in, int32_t *const out, const int stride, const int out_size) { for (int i = 0; i < out_size; ++i) { vst1q_s32(out + i * stride + 0, vmovl_s16(vget_low_s16(in[i]))); vst1q_s32(out + i * stride + 4, vmovl_s16(vget_high_s16(in[i]))); } } // A note on naming: // round_shift_[sqrt2]_s16_s32_4x1_neon(...) // | | | ^ 1 => a single vector // | | | n => an array of vectors // | | | ^ input/output vector element count // | | ^ output type // | ^ input type // ^ multiplicand and shift identifier static AOM_FORCE_INLINE int16x4_t round_shift_sqrt2_s16_s16_4x1_neon(int16x4_t a) { return vqrshrn_n_s32(vmull_n_s16(a, NewSqrt2), NewSqrt2Bits); } static AOM_FORCE_INLINE int16x8_t round_shift_sqrt2_s16_s16_8x1_neon(int16x8_t a) { return vcombine_s16(round_shift_sqrt2_s16_s16_4x1_neon(vget_low_s16(a)), round_shift_sqrt2_s16_s16_4x1_neon(vget_high_s16(a))); } static AOM_FORCE_INLINE int16x4_t round_shift_2sqrt2_s16_s16_4x1_neon(int16x4_t a) { return vqrshrn_n_s32(vmull_n_s16(a, 2 * NewSqrt2), NewSqrt2Bits); } static AOM_FORCE_INLINE int16x8_t round_shift_2sqrt2_s16_s16_8x1_neon(int16x8_t a) { return vcombine_s16(round_shift_2sqrt2_s16_s16_4x1_neon(vget_low_s16(a)), round_shift_2sqrt2_s16_s16_4x1_neon(vget_high_s16(a))); } static AOM_FORCE_INLINE int32x4_t round_shift_sqrt2_s16_s32_4x1_neon(int16x4_t a) { return vrshrq_n_s32(vmull_n_s16(a, NewSqrt2), NewSqrt2Bits); } static AOM_FORCE_INLINE int32x4_t round_shift_sqrt2_s32_s32_4x1_neon(int32x4_t a) { return vrshrq_n_s32(vmulq_n_s32(a, NewSqrt2), NewSqrt2Bits); } #define ROUND_SHIFT_SQRT_LOOP_HELPER(name, type0, type1, fn) \ static AOM_FORCE_INLINE void name(const type0 *in, type1 *out, int size) { \ for (int i = 0; i < size; ++i) { \ out[i] = fn(in[i]); \ } \ } ROUND_SHIFT_SQRT_LOOP_HELPER(round_shift_sqrt2_s32_s32_4xn_neon, int32x4_t, int32x4_t, round_shift_sqrt2_s32_s32_4x1_neon) ROUND_SHIFT_SQRT_LOOP_HELPER(round_shift_sqrt2_s16_s16_4xn_neon, int16x4_t, int16x4_t, round_shift_sqrt2_s16_s16_4x1_neon) ROUND_SHIFT_SQRT_LOOP_HELPER(round_shift_sqrt2_s16_s16_8xn_neon, int16x8_t, int16x8_t, round_shift_sqrt2_s16_s16_8x1_neon) ROUND_SHIFT_SQRT_LOOP_HELPER(round_shift_2sqrt2_s16_s16_4xn_neon, int16x4_t, int16x4_t, round_shift_2sqrt2_s16_s16_4x1_neon) ROUND_SHIFT_SQRT_LOOP_HELPER(round_shift_2sqrt2_s16_s16_8xn_neon, int16x8_t, int16x8_t, round_shift_2sqrt2_s16_s16_8x1_neon) static AOM_FORCE_INLINE void store_rect_buffer_s16_x4(const int16x4_t *const in, int32_t *const out, const int stride, const int out_size) { for (int i = 0; i < out_size; ++i) { vst1q_s32(out + i * stride, round_shift_sqrt2_s16_s32_4x1_neon(in[i])); } } static AOM_FORCE_INLINE void store_rect_buffer_s16_x8(const int16x8_t *const in, int32_t *const out, const int stride, const int out_size) { for (int i = 0; i < out_size; ++i) { vst1q_s32(out + i * stride + 0, round_shift_sqrt2_s16_s32_4x1_neon(vget_low_s16(in[i]))); vst1q_s32(out + i * stride + 4, round_shift_sqrt2_s16_s32_4x1_neon(vget_high_s16(in[i]))); } } static AOM_FORCE_INLINE void fadst4x4_neon(const int16x4_t *input, int16x4_t *output, int cos_bit) { int32x4_t u[6], v[6]; const int16x4_t sinpi = vld1_s16(sinpi_arr_q13(cos_bit)); const int16x4_t u01 = vqadd_s16(input[0], input[1]); v[5] = vmull_lane_s16(input[2], sinpi, 2); v[0] = vmull_lane_s16(input[1], sinpi, 1); v[0] = vmlal_lane_s16(v[0], input[0], sinpi, 0); v[1] = vmlal_lane_s16(v[5], input[3], sinpi, 3); v[2] = vmull_lane_s16(u01, sinpi, 2); v[3] = vmull_lane_s16(input[0], sinpi, 3); v[3] = vmlsl_lane_s16(v[3], input[1], sinpi, 0); v[4] = vmlsl_lane_s16(v[5], input[3], sinpi, 1); u[0] = vaddq_s32(v[0], v[1]); u[1] = vmlsl_lane_s16(v[2], input[3], sinpi, 2); u[2] = vsubq_s32(v[3], v[4]); u[3] = vsubq_s32(u[2], u[0]); u[3] = vmlaq_n_s32(u[3], v[5], 3); output[0] = vrshrn_n_s32(u[0], TXFM_COS_BIT_MAX); output[1] = vrshrn_n_s32(u[1], TXFM_COS_BIT_MAX); output[2] = vrshrn_n_s32(u[2], TXFM_COS_BIT_MAX); output[3] = vrshrn_n_s32(u[3], TXFM_COS_BIT_MAX); } static AOM_FORCE_INLINE void fadst4x8_neon(const int16x4_t *input, int16x4_t *output, int cos_bit) { const int16_t *cospi = cospi_arr_q13(cos_bit); const int16x8_t cospi32_16 = vld1q_s16(&cospi[4 * 0]); const int16x8_t cospi4_12 = vld1q_s16(&cospi[4 * 4]); const int16x8_t cospi20_28 = vld1q_s16(&cospi[4 * 6]); const int16x4_t cospi32 = vget_low_s16(cospi32_16); const int16x4_t cospi16 = vget_high_s16(cospi32_16); const int16x4_t cospi4 = vget_low_s16(cospi4_12); const int16x4_t cospi12 = vget_high_s16(cospi4_12); const int16x4_t cospi20 = vget_low_s16(cospi20_28); const int16x4_t cospi28 = vget_high_s16(cospi20_28); // stage 1-2 int16x4_t x2[8]; butterfly_s16_s32_x4_0332_neon(cospi32, input[4], input[3], &x2[2], &x2[3]); butterfly_s16_s32_x4_0112_neon(cospi32, input[2], input[5], &x2[7], &x2[6]); // stage 3 int16x4_t x3[8]; x3[0] = vqadd_s16(input[0], x2[2]); x3[1] = vqsub_s16(x2[3], input[7]); x3[2] = vqsub_s16(input[0], x2[2]); x3[3] = vqadd_s16(input[7], x2[3]); x3[4] = vqsub_s16(x2[6], input[1]); x3[5] = vqadd_s16(input[6], x2[7]); x3[6] = vqadd_s16(input[1], x2[6]); x3[7] = vqsub_s16(input[6], x2[7]); // stage 4 int16x4_t x4[8]; butterfly_s16_s32_x4_0112_neon(cospi16, x3[4], x3[5], &x4[4], &x4[5]); butterfly_s16_s32_x4_0112_neon(cospi16, x3[7], x3[6], &x4[6], &x4[7]); // stage 5 int16x4_t x5[8]; x5[0] = vqadd_s16(x3[0], x4[4]); x5[1] = vqadd_s16(x3[1], x4[5]); x5[2] = vqadd_s16(x3[2], x4[6]); x5[3] = vqsub_s16(x4[7], x3[3]); x5[4] = vqsub_s16(x3[0], x4[4]); x5[5] = vqsub_s16(x3[1], x4[5]); x5[6] = vqsub_s16(x3[2], x4[6]); x5[7] = vqadd_s16(x3[3], x4[7]); // stage 6-7 butterfly_s16_s32_x4_0112_neon(cospi4, x5[0], x5[1], &output[7], &output[0]); butterfly_s16_s32_x4_0112_neon(cospi20, x5[2], x5[3], &output[5], &output[2]); butterfly_s16_s32_x4_1003_neon(cospi28, x5[4], x5[5], &output[3], &output[4]); butterfly_s16_s32_x4_0112_neon(cospi12, x5[6], x5[7], &output[6], &output[1]); } static AOM_FORCE_INLINE void fadst8x4_neon(const int16x8_t *input, int16x8_t *output, int cos_bit) { int32x4_t u_lo[4], u_hi[4]; const int16x4_t sinpi = vld1_s16(sinpi_arr_q13(cos_bit)); const int16x8_t u01 = vqaddq_s16(input[0], input[1]); u_lo[0] = vmull_lane_s16(vget_low_s16(input[1]), sinpi, 1); u_hi[0] = vmull_lane_s16(vget_high_s16(input[1]), sinpi, 1); u_lo[0] = vmlal_lane_s16(u_lo[0], vget_low_s16(input[0]), sinpi, 0); u_hi[0] = vmlal_lane_s16(u_hi[0], vget_high_s16(input[0]), sinpi, 0); u_lo[0] = vmlal_lane_s16(u_lo[0], vget_low_s16(input[3]), sinpi, 3); u_hi[0] = vmlal_lane_s16(u_hi[0], vget_high_s16(input[3]), sinpi, 3); u_lo[0] = vmlal_lane_s16(u_lo[0], vget_low_s16(input[2]), sinpi, 2); u_hi[0] = vmlal_lane_s16(u_hi[0], vget_high_s16(input[2]), sinpi, 2); u_lo[1] = vmull_lane_s16(vget_low_s16(u01), sinpi, 2); u_hi[1] = vmull_lane_s16(vget_high_s16(u01), sinpi, 2); u_lo[2] = vmull_lane_s16(vget_low_s16(input[0]), sinpi, 3); u_hi[2] = vmull_lane_s16(vget_high_s16(input[0]), sinpi, 3); u_lo[2] = vmlsl_lane_s16(u_lo[2], vget_low_s16(input[1]), sinpi, 0); u_hi[2] = vmlsl_lane_s16(u_hi[2], vget_high_s16(input[1]), sinpi, 0); u_lo[2] = vmlal_lane_s16(u_lo[2], vget_low_s16(input[3]), sinpi, 1); u_hi[2] = vmlal_lane_s16(u_hi[2], vget_high_s16(input[3]), sinpi, 1); u_lo[2] = vmlsl_lane_s16(u_lo[2], vget_low_s16(input[2]), sinpi, 2); u_hi[2] = vmlsl_lane_s16(u_hi[2], vget_high_s16(input[2]), sinpi, 2); u_lo[1] = vmlsl_lane_s16(u_lo[1], vget_low_s16(input[3]), sinpi, 2); u_hi[1] = vmlsl_lane_s16(u_hi[1], vget_high_s16(input[3]), sinpi, 2); u_lo[3] = vsubq_s32(u_lo[2], u_lo[0]); u_hi[3] = vsubq_s32(u_hi[2], u_hi[0]); const int16x4_t sinpix3 = vmul_n_s16(sinpi, 3); u_lo[3] = vmlal_lane_s16(u_lo[3], vget_low_s16(input[2]), sinpix3, 2); u_hi[3] = vmlal_lane_s16(u_hi[3], vget_high_s16(input[2]), sinpix3, 2); output[0] = vcombine_s16(vrshrn_n_s32(u_lo[0], TXFM_COS_BIT_MAX), vrshrn_n_s32(u_hi[0], TXFM_COS_BIT_MAX)); output[1] = vcombine_s16(vrshrn_n_s32(u_lo[1], TXFM_COS_BIT_MAX), vrshrn_n_s32(u_hi[1], TXFM_COS_BIT_MAX)); output[2] = vcombine_s16(vrshrn_n_s32(u_lo[2], TXFM_COS_BIT_MAX), vrshrn_n_s32(u_hi[2], TXFM_COS_BIT_MAX)); output[3] = vcombine_s16(vrshrn_n_s32(u_lo[3], TXFM_COS_BIT_MAX), vrshrn_n_s32(u_hi[3], TXFM_COS_BIT_MAX)); } static AOM_FORCE_INLINE void fdct4x4_neon(const int16x4_t *input, int16x4_t *output, int cos_bit) { const int16_t *cospi = cospi_arr_q13(cos_bit); const int16x4_t cospi16 = vld1_s16(&cospi[4 * 1]); int16x4_t in12a = vadd_s16(input[1], input[2]); int16x4_t in12s = vsub_s16(input[1], input[2]); int16x4_t in03a = vadd_s16(input[0], input[3]); int16x4_t in03s = vsub_s16(input[0], input[3]); int32x4_t u0ad1 = vmull_n_s16(in12a, cospi[4 * 0]); int32x4_t u0ad2 = vmull_n_s16(in03a, cospi[4 * 0]); int32x4_t u[4]; u[0] = vaddq_s32(u0ad1, u0ad2); u[1] = vsubq_s32(u0ad2, u0ad1); u[2] = vmull_lane_s16(in12s, cospi16, 1); u[2] = vmlal_lane_s16(u[2], in03s, cospi16, 0); u[3] = vmull_lane_s16(in03s, cospi16, 1); u[3] = vmlsl_lane_s16(u[3], in12s, cospi16, 0); output[0] = vrshrn_n_s32(u[0], TXFM_COS_BIT_MAX); output[1] = vrshrn_n_s32(u[2], TXFM_COS_BIT_MAX); output[2] = vrshrn_n_s32(u[1], TXFM_COS_BIT_MAX); output[3] = vrshrn_n_s32(u[3], TXFM_COS_BIT_MAX); } // Butterfly pre-processing: // e.g. n=4: // out[0] = in[0] + in[3] // out[1] = in[1] + in[2] // out[2] = in[1] - in[2] // out[3] = in[0] - in[3] static AOM_FORCE_INLINE void butterfly_dct_pre_s16_x4(const int16x4_t *input, int16x4_t *output, int n) { for (int i = 0; i < n / 2; ++i) { output[i] = vqadd_s16(input[i], input[n - i - 1]); } for (int i = 0; i < n / 2; ++i) { output[n / 2 + i] = vqsub_s16(input[n / 2 - i - 1], input[n / 2 + i]); } } static AOM_FORCE_INLINE void butterfly_dct_pre_s16_x8(const int16x8_t *input, int16x8_t *output, int n) { for (int i = 0; i < n / 2; ++i) { output[i] = vqaddq_s16(input[i], input[n - i - 1]); } for (int i = 0; i < n / 2; ++i) { output[n / 2 + i] = vqsubq_s16(input[n / 2 - i - 1], input[n / 2 + i]); } } static AOM_FORCE_INLINE void butterfly_dct_pre_s32_x4(const int32x4_t *input, int32x4_t *output, int n) { for (int i = 0; i < n / 2; ++i) { output[i] = vqaddq_s32(input[i], input[n - i - 1]); } for (int i = 0; i < n / 2; ++i) { output[n / 2 + i] = vqsubq_s32(input[n / 2 - i - 1], input[n / 2 + i]); } } // Butterfly post-processing: // e.g. n=8: // out[0] = in0[0] + in1[3]; // out[1] = in0[1] + in1[2]; // out[2] = in0[1] - in1[2]; // out[3] = in0[0] - in1[3]; // out[4] = in0[7] - in1[4]; // out[5] = in0[6] - in1[5]; // out[6] = in0[6] + in1[5]; // out[7] = in0[7] + in1[4]; static AOM_FORCE_INLINE void butterfly_dct_post_s16_x4(const int16x4_t *in0, const int16x4_t *in1, int16x4_t *output, int n) { for (int i = 0; i < n / 4; ++i) { output[i] = vqadd_s16(in0[i], in1[n / 2 - i - 1]); } for (int i = 0; i < n / 4; ++i) { output[n / 4 + i] = vqsub_s16(in0[n / 4 - i - 1], in1[n / 4 + i]); } for (int i = 0; i < n / 4; ++i) { output[n / 2 + i] = vqsub_s16(in0[n - i - 1], in1[n / 2 + i]); } for (int i = 0; i < n / 4; ++i) { output[(3 * n) / 4 + i] = vqadd_s16(in0[(3 * n) / 4 + i], in1[(3 * n) / 4 - i - 1]); } } static AOM_FORCE_INLINE void butterfly_dct_post_s16_x8(const int16x8_t *in0, const int16x8_t *in1, int16x8_t *output, int n) { for (int i = 0; i < n / 4; ++i) { output[i] = vqaddq_s16(in0[i], in1[n / 2 - i - 1]); } for (int i = 0; i < n / 4; ++i) { output[n / 4 + i] = vqsubq_s16(in0[n / 4 - i - 1], in1[n / 4 + i]); } for (int i = 0; i < n / 4; ++i) { output[n / 2 + i] = vqsubq_s16(in0[n - i - 1], in1[n / 2 + i]); } for (int i = 0; i < n / 4; ++i) { output[(3 * n) / 4 + i] = vqaddq_s16(in0[(3 * n) / 4 + i], in1[(3 * n) / 4 - i - 1]); } } static AOM_FORCE_INLINE void butterfly_dct_post_s32_x4(const int32x4_t *in0, const int32x4_t *in1, int32x4_t *output, int n) { for (int i = 0; i < n / 4; ++i) { output[i] = vqaddq_s32(in0[i], in1[n / 2 - i - 1]); } for (int i = 0; i < n / 4; ++i) { output[n / 4 + i] = vqsubq_s32(in0[n / 4 - i - 1], in1[n / 4 + i]); } for (int i = 0; i < n / 4; ++i) { output[n / 2 + i] = vqsubq_s32(in0[n - i - 1], in1[n / 2 + i]); } for (int i = 0; i < n / 4; ++i) { output[(3 * n) / 4 + i] = vqaddq_s32(in0[(3 * n) / 4 + i], in1[(3 * n) / 4 - i - 1]); } } static AOM_FORCE_INLINE void fdct8x4_neon(const int16x8_t *input, int16x8_t *output, int cos_bit) { const int16_t *cospi = cospi_arr_q13(cos_bit); const int16x8_t cospi32_16 = vld1q_s16(&cospi[4 * 0]); const int16x4_t cospi32 = vget_low_s16(cospi32_16); const int16x4_t cospi16 = vget_high_s16(cospi32_16); // stage 1 int16x8_t x1[4]; butterfly_dct_pre_s16_x8(input, x1, 4); // stage 2 int16x8_t x2[4]; butterfly_s16_s32_x8_0112_neon(cospi32, x1[0], x1[1], &x2[0], &x2[1]); butterfly_s16_s32_x8_0112_neon(cospi16, x1[3], x1[2], &x2[2], &x2[3]); // stage 3 output[0] = x2[0]; output[1] = x2[2]; output[2] = x2[1]; output[3] = x2[3]; } static AOM_FORCE_INLINE void fdct4x8_neon(const int16x4_t *input, int16x4_t *output, int cos_bit) { const int16_t *cospi = cospi_arr_q13(cos_bit); const int16x8_t cospi32_16 = vld1q_s16(&cospi[4 * 0]); const int16x8_t cospi8_24 = vld1q_s16(&cospi[4 * 2]); const int16x4_t cospi32 = vget_low_s16(cospi32_16); const int16x4_t cospi16 = vget_high_s16(cospi32_16); const int16x4_t cospi8 = vget_low_s16(cospi8_24); const int16x4_t cospi24 = vget_high_s16(cospi8_24); // stage 1 int16x4_t x1[8]; butterfly_dct_pre_s16_x4(input, x1, 8); // stage 2 int16x4_t x2[8]; butterfly_dct_pre_s16_x4(x1, x2, 4); butterfly_s16_s32_x4_0112_neon(cospi32, x1[6], x1[5], &x2[6], &x2[5]); // stage 3 int16x4_t x3[8]; butterfly_s16_s32_x4_0112_neon(cospi32, x2[0], x2[1], &output[0], &output[4]); butterfly_s16_s32_x4_0112_neon(cospi16, x2[3], x2[2], &output[2], &output[6]); butterfly_dct_post_s16_x4(x1 + 4, x2 + 4, x3 + 4, 4); // stage 4-5 butterfly_s16_s32_x4_0112_neon(cospi8, x3[7], x3[4], &output[1], &output[7]); butterfly_s16_s32_x4_1003_neon(cospi24, x3[6], x3[5], &output[5], &output[3]); } static AOM_FORCE_INLINE void fdct8x8_neon(const int16x8_t *input, int16x8_t *output, int cos_bit) { const int16_t *cospi = cospi_arr_q13(cos_bit); const int16x8_t cospi32_16 = vld1q_s16(&cospi[4 * 0]); const int16x8_t cospi8_24 = vld1q_s16(&cospi[4 * 2]); const int16x4_t cospi32 = vget_low_s16(cospi32_16); const int16x4_t cospi16 = vget_high_s16(cospi32_16); const int16x4_t cospi8 = vget_low_s16(cospi8_24); const int16x4_t cospi24 = vget_high_s16(cospi8_24); // stage 1 int16x8_t x1[8]; butterfly_dct_pre_s16_x8(input, x1, 8); // stage 2 int16x8_t x2[8]; butterfly_dct_pre_s16_x8(x1, x2, 4); butterfly_s16_s32_x8_0112_neon(cospi32, x1[6], x1[5], &x2[6], &x2[5]); // stage 3 int16x8_t x3[8]; butterfly_s16_s32_x8_0112_neon(cospi32, x2[0], x2[1], &output[0], &output[4]); butterfly_s16_s32_x8_0112_neon(cospi16, x2[3], x2[2], &output[2], &output[6]); butterfly_dct_post_s16_x8(x1 + 4, x2 + 4, x3 + 4, 4); // stage 4-5 butterfly_s16_s32_x8_0112_neon(cospi8, x3[7], x3[4], &output[1], &output[7]); butterfly_s16_s32_x8_1003_neon(cospi24, x3[6], x3[5], &output[5], &output[3]); } static AOM_FORCE_INLINE void fdct4x16_neon(const int16x4_t *input, int16x4_t *output, int cos_bit) { const int16_t *cospi = cospi_arr_q13(cos_bit); const int16x8_t cospi32_16 = vld1q_s16(&cospi[4 * 0]); const int16x8_t cospi8_24 = vld1q_s16(&cospi[4 * 2]); const int16x8_t cospi4_12 = vld1q_s16(&cospi[4 * 4]); const int16x8_t cospi20_28 = vld1q_s16(&cospi[4 * 6]); const int16x4_t cospi32 = vget_low_s16(cospi32_16); const int16x4_t cospi16 = vget_high_s16(cospi32_16); const int16x4_t cospi8 = vget_low_s16(cospi8_24); const int16x4_t cospi24 = vget_high_s16(cospi8_24); const int16x4_t cospi4 = vget_low_s16(cospi4_12); const int16x4_t cospi12 = vget_high_s16(cospi4_12); const int16x4_t cospi20 = vget_low_s16(cospi20_28); const int16x4_t cospi28 = vget_high_s16(cospi20_28); // stage 1 int16x4_t x1[16]; butterfly_dct_pre_s16_x4(input, x1, 16); // stage 2 int16x4_t x2[16]; butterfly_dct_pre_s16_x4(x1, x2, 8); butterfly_s16_s32_x4_0112_neon(cospi32, x1[13], x1[10], &x2[13], &x2[10]); butterfly_s16_s32_x4_0112_neon(cospi32, x1[12], x1[11], &x2[12], &x2[11]); // stage 3 int16x4_t x3[16]; butterfly_dct_pre_s16_x4(x2, x3, 4); butterfly_s16_s32_x4_0112_neon(cospi32, x2[6], x2[5], &x3[6], &x3[5]); butterfly_dct_post_s16_x4(x1 + 8, x2 + 8, x3 + 8, 8); // stage 4 int16x4_t x4[16]; butterfly_s16_s32_x4_0112_neon(cospi32, x3[0], x3[1], &output[0], &output[8]); butterfly_s16_s32_x4_0112_neon(cospi16, x3[3], x3[2], &output[4], &output[12]); butterfly_dct_post_s16_x4(x2 + 4, x3 + 4, x4 + 4, 4); butterfly_s16_s32_x4_0112_neon(cospi16, x3[14], x3[9], &x4[14], &x4[9]); butterfly_s16_s32_x4_1223_neon(cospi16, x3[13], x3[10], &x4[13], &x4[10]); // stage 5 int16x4_t x5[16]; butterfly_s16_s32_x4_0112_neon(cospi8, x4[7], x4[4], &output[2], &output[14]); butterfly_s16_s32_x4_1003_neon(cospi24, x4[6], x4[5], &output[10], &output[6]); butterfly_dct_post_s16_x4(x3 + 8, x4 + 8, x5 + 8, 4); butterfly_dct_post_s16_x4(x3 + 12, x4 + 12, x5 + 12, 4); // stage 6-7 butterfly_s16_s32_x4_0112_neon(cospi4, x5[15], x5[8], &output[1], &output[15]); butterfly_s16_s32_x4_1003_neon(cospi28, x5[14], x5[9], &output[9], &output[7]); butterfly_s16_s32_x4_0112_neon(cospi20, x5[13], x5[10], &output[5], &output[11]); butterfly_s16_s32_x4_1003_neon(cospi12, x5[12], x5[11], &output[13], &output[3]); } static AOM_FORCE_INLINE void fdct8x16_neon(const int16x8_t *input, int16x8_t *output, int cos_bit) { const int16_t *cospi = cospi_arr_q13(cos_bit); const int16x8_t cospi32_16 = vld1q_s16(&cospi[4 * 0]); const int16x8_t cospi8_24 = vld1q_s16(&cospi[4 * 2]); const int16x8_t cospi4_12 = vld1q_s16(&cospi[4 * 4]); const int16x8_t cospi20_28 = vld1q_s16(&cospi[4 * 6]); const int16x4_t cospi32 = vget_low_s16(cospi32_16); const int16x4_t cospi16 = vget_high_s16(cospi32_16); const int16x4_t cospi8 = vget_low_s16(cospi8_24); const int16x4_t cospi24 = vget_high_s16(cospi8_24); const int16x4_t cospi4 = vget_low_s16(cospi4_12); const int16x4_t cospi12 = vget_high_s16(cospi4_12); const int16x4_t cospi20 = vget_low_s16(cospi20_28); const int16x4_t cospi28 = vget_high_s16(cospi20_28); // stage 1 int16x8_t x1[16]; butterfly_dct_pre_s16_x8(input, x1, 16); // stage 2 int16x8_t x2[16]; butterfly_dct_pre_s16_x8(x1, x2, 8); butterfly_s16_s32_x8_0112_neon(cospi32, x1[13], x1[10], &x2[13], &x2[10]); butterfly_s16_s32_x8_0112_neon(cospi32, x1[12], x1[11], &x2[12], &x2[11]); // stage 3 int16x8_t x3[16]; butterfly_dct_pre_s16_x8(x2, x3, 4); butterfly_s16_s32_x8_0112_neon(cospi32, x2[6], x2[5], &x3[6], &x3[5]); butterfly_dct_post_s16_x8(x1 + 8, x2 + 8, x3 + 8, 8); // stage 4 int16x8_t x4[16]; butterfly_s16_s32_x8_0112_neon(cospi32, x3[0], x3[1], &output[0], &output[8]); butterfly_s16_s32_x8_0112_neon(cospi16, x3[3], x3[2], &output[4], &output[12]); butterfly_dct_post_s16_x8(x2 + 4, x3 + 4, x4 + 4, 4); butterfly_s16_s32_x8_0112_neon(cospi16, x3[14], x3[9], &x4[14], &x4[9]); butterfly_s16_s32_x8_1223_neon(cospi16, x3[13], x3[10], &x4[13], &x4[10]); // stage 5 int16x8_t x5[16]; butterfly_s16_s32_x8_0112_neon(cospi8, x4[7], x4[4], &output[2], &output[14]); butterfly_s16_s32_x8_1003_neon(cospi24, x4[6], x4[5], &output[10], &output[6]); butterfly_dct_post_s16_x8(x3 + 8, x4 + 8, x5 + 8, 4); butterfly_dct_post_s16_x8(x3 + 12, x4 + 12, x5 + 12, 4); // stage 6-7 butterfly_s16_s32_x8_0112_neon(cospi4, x5[15], x5[8], &output[1], &output[15]); butterfly_s16_s32_x8_1003_neon(cospi28, x5[14], x5[9], &output[9], &output[7]); butterfly_s16_s32_x8_0112_neon(cospi20, x5[13], x5[10], &output[5], &output[11]); butterfly_s16_s32_x8_1003_neon(cospi12, x5[12], x5[11], &output[13], &output[3]); } static AOM_FORCE_INLINE void fdct8x32_neon(const int16x8_t *input, int16x8_t *output, int cos_bit) { const int16_t *cospi = cospi_arr_q13(cos_bit); const int16x8_t cospi32_16 = vld1q_s16(&cospi[4 * 0]); const int16x8_t cospi8_24 = vld1q_s16(&cospi[4 * 2]); const int16x8_t cospi4_12 = vld1q_s16(&cospi[4 * 4]); const int16x8_t cospi20_28 = vld1q_s16(&cospi[4 * 6]); const int16x8_t cospi2_6 = vld1q_s16(&cospi[4 * 8]); const int16x8_t cospi10_14 = vld1q_s16(&cospi[4 * 10]); const int16x8_t cospi18_22 = vld1q_s16(&cospi[4 * 12]); const int16x8_t cospi26_30 = vld1q_s16(&cospi[4 * 14]); const int16x4_t cospi32 = vget_low_s16(cospi32_16); const int16x4_t cospi16 = vget_high_s16(cospi32_16); const int16x4_t cospi8 = vget_low_s16(cospi8_24); const int16x4_t cospi24 = vget_high_s16(cospi8_24); const int16x4_t cospi4 = vget_low_s16(cospi4_12); const int16x4_t cospi12 = vget_high_s16(cospi4_12); const int16x4_t cospi20 = vget_low_s16(cospi20_28); const int16x4_t cospi28 = vget_high_s16(cospi20_28); const int16x4_t cospi2 = vget_low_s16(cospi2_6); const int16x4_t cospi6 = vget_high_s16(cospi2_6); const int16x4_t cospi10 = vget_low_s16(cospi10_14); const int16x4_t cospi14 = vget_high_s16(cospi10_14); const int16x4_t cospi18 = vget_low_s16(cospi18_22); const int16x4_t cospi22 = vget_high_s16(cospi18_22); const int16x4_t cospi26 = vget_low_s16(cospi26_30); const int16x4_t cospi30 = vget_high_s16(cospi26_30); // stage 1 int16x8_t x1[32]; butterfly_dct_pre_s16_x8(input, x1, 32); // stage 2 int16x8_t x2[32]; butterfly_dct_pre_s16_x8(x1, x2, 16); butterfly_s16_s32_x8_0112_neon(cospi32, x1[27], x1[20], &x2[27], &x2[20]); butterfly_s16_s32_x8_0112_neon(cospi32, x1[26], x1[21], &x2[26], &x2[21]); butterfly_s16_s32_x8_0112_neon(cospi32, x1[25], x1[22], &x2[25], &x2[22]); butterfly_s16_s32_x8_0112_neon(cospi32, x1[24], x1[23], &x2[24], &x2[23]); // stage 3 int16x8_t x3[32]; butterfly_dct_pre_s16_x8(x2, x3, 8); butterfly_s16_s32_x8_0112_neon(cospi32, x2[13], x2[10], &x3[13], &x3[10]); butterfly_s16_s32_x8_0112_neon(cospi32, x2[12], x2[11], &x3[12], &x3[11]); butterfly_dct_post_s16_x8(x1 + 16, x2 + 16, x3 + 16, 16); // stage 4 int16x8_t x4[32]; butterfly_dct_pre_s16_x8(x3, x4, 4); butterfly_s16_s32_x8_0112_neon(cospi32, x3[6], x3[5], &x4[6], &x4[5]); butterfly_dct_post_s16_x8(x2 + 8, x3 + 8, x4 + 8, 8); butterfly_s16_s32_x8_0112_neon(cospi16, x3[29], x3[18], &x4[29], &x4[18]); butterfly_s16_s32_x8_0112_neon(cospi16, x3[28], x3[19], &x4[28], &x4[19]); butterfly_s16_s32_x8_1223_neon(cospi16, x3[27], x3[20], &x4[27], &x4[20]); butterfly_s16_s32_x8_1223_neon(cospi16, x3[26], x3[21], &x4[26], &x4[21]); // stage 5 int16x8_t x5[32]; butterfly_s16_s32_x8_0112_neon(cospi32, x4[0], x4[1], &output[0], &output[16]); butterfly_s16_s32_x8_0112_neon(cospi16, x4[3], x4[2], &output[8], &output[24]); butterfly_dct_post_s16_x8(x3 + 4, x4 + 4, x5 + 4, 4); butterfly_s16_s32_x8_0112_neon(cospi16, x4[14], x4[9], &x5[14], &x5[9]); butterfly_s16_s32_x8_1223_neon(cospi16, x4[13], x4[10], &x5[13], &x5[10]); butterfly_dct_post_s16_x8(x3 + 16, x4 + 16, x5 + 16, 8); butterfly_dct_post_s16_x8(x3 + 24, x4 + 24, x5 + 24, 8); // stage 6 int16x8_t x6[32]; butterfly_s16_s32_x8_0112_neon(cospi8, x5[7], x5[4], &output[4], &output[28]); butterfly_s16_s32_x8_1003_neon(cospi24, x5[6], x5[5], &output[20], &output[12]); butterfly_dct_post_s16_x8(x4 + 8, x5 + 8, x6 + 8, 4); butterfly_dct_post_s16_x8(x4 + 12, x5 + 12, x6 + 12, 4); butterfly_s16_s32_x8_0112_neon(cospi8, x5[30], x5[17], &x6[30], &x6[17]); butterfly_s16_s32_x8_1223_neon(cospi8, x5[29], x5[18], &x6[29], &x6[18]); butterfly_s16_s32_x8_1003_neon(cospi24, x5[26], x5[21], &x6[26], &x6[21]); butterfly_s16_s32_x8_0332_neon(cospi24, x5[25], x5[22], &x6[25], &x6[22]); // stage 7 int16x8_t x7[32]; butterfly_s16_s32_x8_0112_neon(cospi4, x6[15], x6[8], &output[2], &output[30]); butterfly_s16_s32_x8_1003_neon(cospi28, x6[14], x6[9], &output[18], &output[14]); butterfly_s16_s32_x8_0112_neon(cospi20, x6[13], x6[10], &output[10], &output[22]); butterfly_s16_s32_x8_1003_neon(cospi12, x6[12], x6[11], &output[26], &output[6]); butterfly_dct_post_s16_x8(x5 + 16, x6 + 16, x7 + 16, 4); butterfly_dct_post_s16_x8(x5 + 20, x6 + 20, x7 + 20, 4); butterfly_dct_post_s16_x8(x5 + 24, x6 + 24, x7 + 24, 4); butterfly_dct_post_s16_x8(x5 + 28, x6 + 28, x7 + 28, 4); butterfly_s16_s32_x8_0112_neon(cospi2, x7[31], x7[16], &output[1], &output[31]); butterfly_s16_s32_x8_1003_neon(cospi30, x7[30], x7[17], &output[17], &output[15]); butterfly_s16_s32_x8_0112_neon(cospi18, x7[29], x7[18], &output[9], &output[23]); butterfly_s16_s32_x8_1003_neon(cospi14, x7[28], x7[19], &output[25], &output[7]); butterfly_s16_s32_x8_0112_neon(cospi10, x7[27], x7[20], &output[5], &output[27]); butterfly_s16_s32_x8_1003_neon(cospi22, x7[26], x7[21], &output[21], &output[11]); butterfly_s16_s32_x8_0112_neon(cospi26, x7[25], x7[22], &output[13], &output[19]); butterfly_s16_s32_x8_1003_neon(cospi6, x7[24], x7[23], &output[29], &output[3]); } static AOM_FORCE_INLINE void fdct8x64_neon(const int16x8_t *input, int16x8_t *output, int cos_bit) { const int16_t *cospi = cospi_arr_q13(cos_bit); const int16x8_t cospi32_16 = vld1q_s16(&cospi[4 * 0]); const int16x8_t cospi8_24 = vld1q_s16(&cospi[4 * 2]); const int16x8_t cospi4_12 = vld1q_s16(&cospi[4 * 4]); const int16x8_t cospi20_28 = vld1q_s16(&cospi[4 * 6]); const int16x8_t cospi2_6 = vld1q_s16(&cospi[4 * 8]); const int16x8_t cospi10_14 = vld1q_s16(&cospi[4 * 10]); const int16x8_t cospi18_22 = vld1q_s16(&cospi[4 * 12]); const int16x8_t cospi26_30 = vld1q_s16(&cospi[4 * 14]); const int16x8_t cospi1_3 = vld1q_s16(&cospi[4 * 16]); const int16x8_t cospi5_7 = vld1q_s16(&cospi[4 * 18]); const int16x8_t cospi9_11 = vld1q_s16(&cospi[4 * 20]); const int16x8_t cospi13_15 = vld1q_s16(&cospi[4 * 22]); const int16x8_t cospi17_19 = vld1q_s16(&cospi[4 * 24]); const int16x8_t cospi21_23 = vld1q_s16(&cospi[4 * 26]); const int16x8_t cospi25_27 = vld1q_s16(&cospi[4 * 28]); const int16x8_t cospi29_31 = vld1q_s16(&cospi[4 * 30]); const int16x4_t cospi32 = vget_low_s16(cospi32_16); const int16x4_t cospi16 = vget_high_s16(cospi32_16); const int16x4_t cospi8 = vget_low_s16(cospi8_24); const int16x4_t cospi24 = vget_high_s16(cospi8_24); const int16x4_t cospi4 = vget_low_s16(cospi4_12); const int16x4_t cospi12 = vget_high_s16(cospi4_12); const int16x4_t cospi20 = vget_low_s16(cospi20_28); const int16x4_t cospi28 = vget_high_s16(cospi20_28); const int16x4_t cospi2 = vget_low_s16(cospi2_6); const int16x4_t cospi6 = vget_high_s16(cospi2_6); const int16x4_t cospi10 = vget_low_s16(cospi10_14); const int16x4_t cospi14 = vget_high_s16(cospi10_14); const int16x4_t cospi18 = vget_low_s16(cospi18_22); const int16x4_t cospi22 = vget_high_s16(cospi18_22); const int16x4_t cospi26 = vget_low_s16(cospi26_30); const int16x4_t cospi30 = vget_high_s16(cospi26_30); const int16x4_t cospi1 = vget_low_s16(cospi1_3); const int16x4_t cospi3 = vget_high_s16(cospi1_3); const int16x4_t cospi5 = vget_low_s16(cospi5_7); const int16x4_t cospi7 = vget_high_s16(cospi5_7); const int16x4_t cospi9 = vget_low_s16(cospi9_11); const int16x4_t cospi11 = vget_high_s16(cospi9_11); const int16x4_t cospi13 = vget_low_s16(cospi13_15); const int16x4_t cospi15 = vget_high_s16(cospi13_15); const int16x4_t cospi17 = vget_low_s16(cospi17_19); const int16x4_t cospi19 = vget_high_s16(cospi17_19); const int16x4_t cospi21 = vget_low_s16(cospi21_23); const int16x4_t cospi23 = vget_high_s16(cospi21_23); const int16x4_t cospi25 = vget_low_s16(cospi25_27); const int16x4_t cospi27 = vget_high_s16(cospi25_27); const int16x4_t cospi29 = vget_low_s16(cospi29_31); const int16x4_t cospi31 = vget_high_s16(cospi29_31); // stage 1 int16x8_t x1[64]; butterfly_dct_pre_s16_x8(input, x1, 64); // stage 2 int16x8_t x2[64]; butterfly_dct_pre_s16_x8(x1, x2, 32); butterfly_s16_s32_x8_0112_neon(cospi32, x1[55], x1[40], &x2[55], &x2[40]); butterfly_s16_s32_x8_0112_neon(cospi32, x1[54], x1[41], &x2[54], &x2[41]); butterfly_s16_s32_x8_0112_neon(cospi32, x1[53], x1[42], &x2[53], &x2[42]); butterfly_s16_s32_x8_0112_neon(cospi32, x1[52], x1[43], &x2[52], &x2[43]); butterfly_s16_s32_x8_0112_neon(cospi32, x1[51], x1[44], &x2[51], &x2[44]); butterfly_s16_s32_x8_0112_neon(cospi32, x1[50], x1[45], &x2[50], &x2[45]); butterfly_s16_s32_x8_0112_neon(cospi32, x1[49], x1[46], &x2[49], &x2[46]); butterfly_s16_s32_x8_0112_neon(cospi32, x1[48], x1[47], &x2[48], &x2[47]); // stage 3 int16x8_t x3[64]; butterfly_dct_pre_s16_x8(x2, x3, 16); x3[16] = x2[16]; x3[17] = x2[17]; x3[18] = x2[18]; x3[19] = x2[19]; butterfly_s16_s32_x8_0112_neon(cospi32, x2[27], x2[20], &x3[27], &x3[20]); butterfly_s16_s32_x8_0112_neon(cospi32, x2[26], x2[21], &x3[26], &x3[21]); butterfly_s16_s32_x8_0112_neon(cospi32, x2[25], x2[22], &x3[25], &x3[22]); butterfly_s16_s32_x8_0112_neon(cospi32, x2[24], x2[23], &x3[24], &x3[23]); x3[28] = x2[28]; x3[29] = x2[29]; x3[30] = x2[30]; x3[31] = x2[31]; butterfly_dct_post_s16_x8(x1 + 32, x2 + 32, x3 + 32, 32); // stage 4 int16x8_t x4[64]; butterfly_dct_pre_s16_x8(x3, x4, 8); butterfly_s16_s32_x8_0112_neon(cospi32, x3[13], x3[10], &x4[13], &x4[10]); butterfly_s16_s32_x8_0112_neon(cospi32, x3[12], x3[11], &x4[12], &x4[11]); butterfly_dct_post_s16_x8(x3 + 16, x3 + 16, x4 + 16, 16); butterfly_s16_s32_x8_0112_neon(cospi16, x3[59], x3[36], &x4[59], &x4[36]); butterfly_s16_s32_x8_0112_neon(cospi16, x3[58], x3[37], &x4[58], &x4[37]); butterfly_s16_s32_x8_0112_neon(cospi16, x3[57], x3[38], &x4[57], &x4[38]); butterfly_s16_s32_x8_0112_neon(cospi16, x3[56], x3[39], &x4[56], &x4[39]); butterfly_s16_s32_x8_1223_neon(cospi16, x3[55], x3[40], &x4[55], &x4[40]); butterfly_s16_s32_x8_1223_neon(cospi16, x3[54], x3[41], &x4[54], &x4[41]); butterfly_s16_s32_x8_1223_neon(cospi16, x3[53], x3[42], &x4[53], &x4[42]); butterfly_s16_s32_x8_1223_neon(cospi16, x3[52], x3[43], &x4[52], &x4[43]); // stage 5 int16x8_t x5[64]; butterfly_dct_pre_s16_x8(x4, x5, 4); butterfly_s16_s32_x8_0112_neon(cospi32, x4[6], x4[5], &x5[6], &x5[5]); butterfly_dct_post_s16_x8(x3 + 8, x4 + 8, x5 + 8, 8); butterfly_s16_s32_x8_0112_neon(cospi16, x4[29], x4[18], &x5[29], &x5[18]); butterfly_s16_s32_x8_0112_neon(cospi16, x4[28], x4[19], &x5[28], &x5[19]); butterfly_s16_s32_x8_1223_neon(cospi16, x4[27], x4[20], &x5[27], &x5[20]); butterfly_s16_s32_x8_1223_neon(cospi16, x4[26], x4[21], &x5[26], &x5[21]); butterfly_dct_post_s16_x8(x3 + 32, x4 + 32, x5 + 32, 16); butterfly_dct_post_s16_x8(x3 + 48, x4 + 48, x5 + 48, 16); // stage 6 int16x8_t x6[64]; butterfly_s16_s32_x8_0112_neon(cospi32, x5[1], x5[0], &x6[0], &x6[1]); butterfly_s16_s32_x8_0112_neon(cospi16, x5[3], x5[2], &x6[2], &x6[3]); butterfly_dct_post_s16_x8(x4 + 4, x5 + 4, x6 + 4, 4); butterfly_s16_s32_x8_0112_neon(cospi16, x5[14], x5[9], &x6[14], &x6[9]); butterfly_s16_s32_x8_1223_neon(cospi16, x5[13], x5[10], &x6[13], &x6[10]); butterfly_dct_post_s16_x8(x4 + 16, x5 + 16, x6 + 16, 8); butterfly_dct_post_s16_x8(x4 + 24, x5 + 24, x6 + 24, 8); butterfly_s16_s32_x8_0112_neon(cospi8, x5[61], x5[34], &x6[61], &x6[34]); butterfly_s16_s32_x8_0112_neon(cospi8, x5[60], x5[35], &x6[60], &x6[35]); butterfly_s16_s32_x8_1223_neon(cospi8, x5[59], x5[36], &x6[59], &x6[36]); butterfly_s16_s32_x8_1223_neon(cospi8, x5[58], x5[37], &x6[58], &x6[37]); butterfly_s16_s32_x8_1003_neon(cospi24, x5[53], x5[42], &x6[53], &x6[42]); butterfly_s16_s32_x8_1003_neon(cospi24, x5[52], x5[43], &x6[52], &x6[43]); butterfly_s16_s32_x8_0332_neon(cospi24, x5[51], x5[44], &x6[51], &x6[44]); butterfly_s16_s32_x8_0332_neon(cospi24, x5[50], x5[45], &x6[50], &x6[45]); // stage 7 int16x8_t x7[64]; butterfly_s16_s32_x8_0112_neon(cospi8, x6[7], x6[4], &x7[4], &x7[7]); butterfly_s16_s32_x8_1003_neon(cospi24, x6[6], x6[5], &x7[5], &x7[6]); butterfly_dct_post_s16_x8(x5 + 8, x6 + 8, x7 + 8, 4); butterfly_dct_post_s16_x8(x5 + 12, x6 + 12, x7 + 12, 4); butterfly_s16_s32_x8_0112_neon(cospi8, x6[30], x6[17], &x7[30], &x7[17]); butterfly_s16_s32_x8_1223_neon(cospi8, x6[29], x6[18], &x7[29], &x7[18]); butterfly_s16_s32_x8_1003_neon(cospi24, x6[26], x6[21], &x7[26], &x7[21]); butterfly_s16_s32_x8_0332_neon(cospi24, x6[25], x6[22], &x7[25], &x7[22]); butterfly_dct_post_s16_x8(x5 + 32, x6 + 32, x7 + 32, 8); butterfly_dct_post_s16_x8(x5 + 40, x6 + 40, x7 + 40, 8); butterfly_dct_post_s16_x8(x5 + 48, x6 + 48, x7 + 48, 8); butterfly_dct_post_s16_x8(x5 + 56, x6 + 56, x7 + 56, 8); // stage 8 int16x8_t x8[64]; butterfly_s16_s32_x8_0112_neon(cospi4, x7[15], x7[8], &x8[8], &x8[15]); butterfly_s16_s32_x8_1003_neon(cospi28, x7[14], x7[9], &x8[9], &x8[14]); butterfly_s16_s32_x8_0112_neon(cospi20, x7[13], x7[10], &x8[10], &x8[13]); butterfly_s16_s32_x8_1003_neon(cospi12, x7[12], x7[11], &x8[11], &x8[12]); butterfly_dct_post_s16_x8(x6 + 16, x7 + 16, x8 + 16, 4); butterfly_dct_post_s16_x8(x6 + 20, x7 + 20, x8 + 20, 4); butterfly_dct_post_s16_x8(x6 + 24, x7 + 24, x8 + 24, 4); butterfly_dct_post_s16_x8(x6 + 28, x7 + 28, x8 + 28, 4); butterfly_s16_s32_x8_0112_neon(cospi4, x7[62], x7[33], &x8[62], &x8[33]); butterfly_s16_s32_x8_1223_neon(cospi4, x7[61], x7[34], &x8[61], &x8[34]); butterfly_s16_s32_x8_1003_neon(cospi28, x7[58], x7[37], &x8[58], &x8[37]); butterfly_s16_s32_x8_0332_neon(cospi28, x7[57], x7[38], &x8[57], &x8[38]); butterfly_s16_s32_x8_0112_neon(cospi20, x7[54], x7[41], &x8[54], &x8[41]); butterfly_s16_s32_x8_1223_neon(cospi20, x7[53], x7[42], &x8[53], &x8[42]); butterfly_s16_s32_x8_1003_neon(cospi12, x7[50], x7[45], &x8[50], &x8[45]); butterfly_s16_s32_x8_0332_neon(cospi12, x7[49], x7[46], &x8[49], &x8[46]); // stage 9 int16x8_t x9[64]; butterfly_s16_s32_x8_0112_neon(cospi2, x8[31], x8[16], &x9[16], &x9[31]); butterfly_s16_s32_x8_1003_neon(cospi30, x8[30], x8[17], &x9[17], &x9[30]); butterfly_s16_s32_x8_0112_neon(cospi18, x8[29], x8[18], &x9[18], &x9[29]); butterfly_s16_s32_x8_1003_neon(cospi14, x8[28], x8[19], &x9[19], &x9[28]); butterfly_s16_s32_x8_0112_neon(cospi10, x8[27], x8[20], &x9[20], &x9[27]); butterfly_s16_s32_x8_1003_neon(cospi22, x8[26], x8[21], &x9[21], &x9[26]); butterfly_s16_s32_x8_0112_neon(cospi26, x8[25], x8[22], &x9[22], &x9[25]); butterfly_s16_s32_x8_1003_neon(cospi6, x8[24], x8[23], &x9[23], &x9[24]); butterfly_dct_post_s16_x8(x7 + 32, x8 + 32, x9 + 32, 4); butterfly_dct_post_s16_x8(x7 + 36, x8 + 36, x9 + 36, 4); butterfly_dct_post_s16_x8(x7 + 40, x8 + 40, x9 + 40, 4); butterfly_dct_post_s16_x8(x7 + 44, x8 + 44, x9 + 44, 4); butterfly_dct_post_s16_x8(x7 + 48, x8 + 48, x9 + 48, 4); butterfly_dct_post_s16_x8(x7 + 52, x8 + 52, x9 + 52, 4); butterfly_dct_post_s16_x8(x7 + 56, x8 + 56, x9 + 56, 4); butterfly_dct_post_s16_x8(x7 + 60, x8 + 60, x9 + 60, 4); // stage 10 butterfly_s16_s32_x8_0112_neon(cospi1, x9[63], x9[32], &output[1], &output[63]); butterfly_s16_s32_x8_1003_neon(cospi31, x9[62], x9[33], &output[33], &output[31]); butterfly_s16_s32_x8_0112_neon(cospi17, x9[61], x9[34], &output[17], &output[47]); butterfly_s16_s32_x8_1003_neon(cospi15, x9[60], x9[35], &output[49], &output[15]); butterfly_s16_s32_x8_0112_neon(cospi9, x9[59], x9[36], &output[9], &output[55]); butterfly_s16_s32_x8_1003_neon(cospi23, x9[58], x9[37], &output[41], &output[23]); butterfly_s16_s32_x8_0112_neon(cospi25, x9[57], x9[38], &output[25], &output[39]); butterfly_s16_s32_x8_1003_neon(cospi7, x9[56], x9[39], &output[57], &output[7]); butterfly_s16_s32_x8_0112_neon(cospi5, x9[55], x9[40], &output[5], &output[59]); butterfly_s16_s32_x8_1003_neon(cospi27, x9[54], x9[41], &output[37], &output[27]); butterfly_s16_s32_x8_0112_neon(cospi21, x9[53], x9[42], &output[21], &output[43]); butterfly_s16_s32_x8_1003_neon(cospi11, x9[52], x9[43], &output[53], &output[11]); butterfly_s16_s32_x8_0112_neon(cospi13, x9[51], x9[44], &output[13], &output[51]); butterfly_s16_s32_x8_1003_neon(cospi19, x9[50], x9[45], &output[45], &output[19]); butterfly_s16_s32_x8_0112_neon(cospi29, x9[49], x9[46], &output[29], &output[35]); butterfly_s16_s32_x8_1003_neon(cospi3, x9[48], x9[47], &output[61], &output[3]); // stage 11 output[0] = x6[0]; output[2] = x9[16]; output[4] = x8[8]; output[6] = x9[24]; output[8] = x7[4]; output[10] = x9[20]; output[12] = x8[12]; output[14] = x9[28]; output[16] = x6[2]; output[18] = x9[18]; output[20] = x8[10]; output[22] = x9[26]; output[24] = x7[6]; output[26] = x9[22]; output[28] = x8[14]; output[30] = x9[30]; output[32] = x6[1]; output[34] = x9[17]; output[36] = x8[9]; output[38] = x9[25]; output[40] = x7[5]; output[42] = x9[21]; output[44] = x8[13]; output[46] = x9[29]; output[48] = x6[3]; output[52] = x8[11]; output[54] = x9[27]; output[56] = x7[7]; output[58] = x9[23]; output[60] = x8[15]; output[62] = x9[31]; } static AOM_FORCE_INLINE void fadst8x8_neon(const int16x8_t *input, int16x8_t *output, int cos_bit) { const int16_t *cospi = cospi_arr_q13(cos_bit); const int16x8_t cospi32_16 = vld1q_s16(&cospi[4 * 0]); const int16x8_t cospi4_12 = vld1q_s16(&cospi[4 * 4]); const int16x8_t cospi20_28 = vld1q_s16(&cospi[4 * 6]); const int16x4_t cospi32 = vget_low_s16(cospi32_16); const int16x4_t cospi16 = vget_high_s16(cospi32_16); const int16x4_t cospi4 = vget_low_s16(cospi4_12); const int16x4_t cospi12 = vget_high_s16(cospi4_12); const int16x4_t cospi20 = vget_low_s16(cospi20_28); const int16x4_t cospi28 = vget_high_s16(cospi20_28); // stage 2 int16x8_t x2[8]; butterfly_s16_s32_x8_0332_neon(cospi32, input[4], input[3], &x2[2], &x2[3]); butterfly_s16_s32_x8_0112_neon(cospi32, input[2], input[5], &x2[7], &x2[6]); // stage 3 int16x8_t x3[8]; x3[0] = vqaddq_s16(input[0], x2[2]); x3[1] = vqsubq_s16(x2[3], input[7]); x3[2] = vqsubq_s16(input[0], x2[2]); x3[3] = vqaddq_s16(input[7], x2[3]); x3[4] = vqsubq_s16(x2[6], input[1]); x3[5] = vqaddq_s16(input[6], x2[7]); x3[6] = vqaddq_s16(input[1], x2[6]); x3[7] = vqsubq_s16(input[6], x2[7]); // stage 4 butterfly_s16_s32_x8_0112_neon(cospi16, x3[4], x3[5], &x3[4], &x3[5]); butterfly_s16_s32_x8_0112_neon(cospi16, x3[7], x3[6], &x3[6], &x3[7]); // stage 5 int16x8_t x5[8]; x5[0] = vqaddq_s16(x3[0], x3[4]); x5[1] = vqaddq_s16(x3[1], x3[5]); x5[2] = vqaddq_s16(x3[2], x3[6]); x5[3] = vqsubq_s16(x3[7], x3[3]); x5[4] = vqsubq_s16(x3[0], x3[4]); x5[5] = vqsubq_s16(x3[1], x3[5]); x5[6] = vqsubq_s16(x3[2], x3[6]); x5[7] = vqaddq_s16(x3[3], x3[7]); // stage 6 butterfly_s16_s32_x8_0112_neon(cospi4, x5[0], x5[1], &output[7], &output[0]); butterfly_s16_s32_x8_0112_neon(cospi20, x5[2], x5[3], &output[5], &output[2]); butterfly_s16_s32_x8_1003_neon(cospi28, x5[4], x5[5], &output[3], &output[4]); butterfly_s16_s32_x8_0112_neon(cospi12, x5[6], x5[7], &output[6], &output[1]); } static AOM_FORCE_INLINE void fadst4x16_neon(const int16x4_t *input, int16x4_t *output, int cos_bit) { const int16_t *cospi = cospi_arr_q13(cos_bit); const int16x8_t cospi32_16 = vld1q_s16(&cospi[4 * 0]); const int16x8_t cospi8_24 = vld1q_s16(&cospi[4 * 2]); const int16x8_t cospi2_6 = vld1q_s16(&cospi[4 * 8]); const int16x8_t cospi10_14 = vld1q_s16(&cospi[4 * 10]); const int16x8_t cospi18_22 = vld1q_s16(&cospi[4 * 12]); const int16x8_t cospi26_30 = vld1q_s16(&cospi[4 * 14]); const int16x4_t cospi32 = vget_low_s16(cospi32_16); const int16x4_t cospi16 = vget_high_s16(cospi32_16); const int16x4_t cospi8 = vget_low_s16(cospi8_24); const int16x4_t cospi24 = vget_high_s16(cospi8_24); const int16x4_t cospi2 = vget_low_s16(cospi2_6); const int16x4_t cospi6 = vget_high_s16(cospi2_6); const int16x4_t cospi10 = vget_low_s16(cospi10_14); const int16x4_t cospi14 = vget_high_s16(cospi10_14); const int16x4_t cospi18 = vget_low_s16(cospi18_22); const int16x4_t cospi22 = vget_high_s16(cospi18_22); const int16x4_t cospi26 = vget_low_s16(cospi26_30); const int16x4_t cospi30 = vget_high_s16(cospi26_30); // stage 2 int16x4_t x2[8]; butterfly_s16_s32_x4_0332_neon(cospi32, input[8], input[7], &x2[0], &x2[1]); butterfly_s16_s32_x4_0112_neon(cospi32, input[4], input[11], &x2[3], &x2[2]); butterfly_s16_s32_x4_0112_neon(cospi32, input[6], input[9], &x2[5], &x2[4]); butterfly_s16_s32_x4_0332_neon(cospi32, input[10], input[5], &x2[6], &x2[7]); // stage 3 int16x4_t x3[16]; x3[0] = vqadd_s16(input[0], x2[0]); x3[1] = vqsub_s16(x2[1], input[15]); x3[2] = vqsub_s16(input[0], x2[0]); x3[3] = vqadd_s16(input[15], x2[1]); x3[4] = vqsub_s16(x2[2], input[3]); x3[5] = vqadd_s16(input[12], x2[3]); x3[6] = vqadd_s16(input[3], x2[2]); x3[7] = vqsub_s16(input[12], x2[3]); x3[8] = vqsub_s16(x2[4], input[1]); x3[9] = vqadd_s16(input[14], x2[5]); x3[10] = vqadd_s16(input[1], x2[4]); x3[11] = vqsub_s16(input[14], x2[5]); x3[12] = vqadd_s16(input[2], x2[6]); x3[13] = vqsub_s16(x2[7], input[13]); x3[14] = vqsub_s16(input[2], x2[6]); x3[15] = vqadd_s16(input[13], x2[7]); // stage 4 butterfly_s16_s32_x4_0112_neon(cospi16, x3[4], x3[5], &x3[4], &x3[5]); butterfly_s16_s32_x4_0112_neon(cospi16, x3[7], x3[6], &x3[6], &x3[7]); butterfly_s16_s32_x4_0112_neon(cospi16, x3[12], x3[13], &x3[12], &x3[13]); butterfly_s16_s32_x4_0332_neon(cospi16, x3[14], x3[15], &x3[15], &x3[14]); // stage 5 int16x4_t x5[16]; x5[0] = vqadd_s16(x3[0], x3[4]); x5[1] = vqadd_s16(x3[1], x3[5]); x5[2] = vqadd_s16(x3[2], x3[6]); x5[3] = vqsub_s16(x3[7], x3[3]); x5[4] = vqsub_s16(x3[0], x3[4]); x5[5] = vqsub_s16(x3[1], x3[5]); x5[6] = vqsub_s16(x3[2], x3[6]); x5[7] = vqadd_s16(x3[3], x3[7]); x5[8] = vqadd_s16(x3[8], x3[12]); x5[9] = vqadd_s16(x3[9], x3[13]); x5[10] = vqsub_s16(x3[14], x3[10]); x5[11] = vqadd_s16(x3[11], x3[15]); x5[12] = vqsub_s16(x3[8], x3[12]); x5[13] = vqsub_s16(x3[9], x3[13]); x5[14] = vqadd_s16(x3[10], x3[14]); x5[15] = vqsub_s16(x3[11], x3[15]); // stage 6 butterfly_s16_s32_x4_0112_neon(cospi8, x5[8], x5[9], &x5[8], &x5[9]); butterfly_s16_s32_x4_1003_neon(cospi24, x5[10], x5[11], &x5[10], &x5[11]); butterfly_s16_s32_x4_1003_neon(cospi8, x5[13], x5[12], &x5[13], &x5[12]); butterfly_s16_s32_x4_1003_neon(cospi24, x5[15], x5[14], &x5[14], &x5[15]); // stage 7 int16x4_t x7[16]; x7[0] = vqadd_s16(x5[0], x5[8]); x7[1] = vqadd_s16(x5[1], x5[9]); x7[2] = vqadd_s16(x5[2], x5[10]); x7[3] = vqadd_s16(x5[3], x5[11]); x7[4] = vqadd_s16(x5[4], x5[12]); x7[5] = vqadd_s16(x5[5], x5[13]); x7[6] = vqadd_s16(x5[6], x5[14]); x7[7] = vqsub_s16(x5[15], x5[7]); x7[8] = vqsub_s16(x5[0], x5[8]); x7[9] = vqsub_s16(x5[1], x5[9]); x7[10] = vqsub_s16(x5[2], x5[10]); x7[11] = vqsub_s16(x5[3], x5[11]); x7[12] = vqsub_s16(x5[4], x5[12]); x7[13] = vqsub_s16(x5[5], x5[13]); x7[14] = vqsub_s16(x5[6], x5[14]); x7[15] = vqadd_s16(x5[7], x5[15]); // stage 8 butterfly_s16_s32_x4_0112_neon(cospi2, x7[0], x7[1], &output[15], &output[0]); butterfly_s16_s32_x4_0112_neon(cospi10, x7[2], x7[3], &output[13], &output[2]); butterfly_s16_s32_x4_0112_neon(cospi18, x7[4], x7[5], &output[11], &output[4]); butterfly_s16_s32_x4_0112_neon(cospi26, x7[6], x7[7], &output[9], &output[6]); butterfly_s16_s32_x4_1003_neon(cospi30, x7[8], x7[9], &output[7], &output[8]); butterfly_s16_s32_x4_1003_neon(cospi22, x7[10], x7[11], &output[5], &output[10]); butterfly_s16_s32_x4_1003_neon(cospi14, x7[12], x7[13], &output[3], &output[12]); butterfly_s16_s32_x4_0112_neon(cospi6, x7[14], x7[15], &output[14], &output[1]); } static AOM_FORCE_INLINE void fadst8x16_neon(const int16x8_t *input, int16x8_t *output, int cos_bit) { const int16_t *cospi = cospi_arr_q13(cos_bit); const int16x8_t cospi32_16 = vld1q_s16(&cospi[4 * 0]); const int16x8_t cospi8_24 = vld1q_s16(&cospi[4 * 2]); const int16x8_t cospi2_6 = vld1q_s16(&cospi[4 * 8]); const int16x8_t cospi10_14 = vld1q_s16(&cospi[4 * 10]); const int16x8_t cospi18_22 = vld1q_s16(&cospi[4 * 12]); const int16x8_t cospi26_30 = vld1q_s16(&cospi[4 * 14]); const int16x4_t cospi32 = vget_low_s16(cospi32_16); const int16x4_t cospi16 = vget_high_s16(cospi32_16); const int16x4_t cospi8 = vget_low_s16(cospi8_24); const int16x4_t cospi24 = vget_high_s16(cospi8_24); const int16x4_t cospi2 = vget_low_s16(cospi2_6); const int16x4_t cospi6 = vget_high_s16(cospi2_6); const int16x4_t cospi10 = vget_low_s16(cospi10_14); const int16x4_t cospi14 = vget_high_s16(cospi10_14); const int16x4_t cospi18 = vget_low_s16(cospi18_22); const int16x4_t cospi22 = vget_high_s16(cospi18_22); const int16x4_t cospi26 = vget_low_s16(cospi26_30); const int16x4_t cospi30 = vget_high_s16(cospi26_30); // stage 2 int16x8_t x2[8]; butterfly_s16_s32_x8_0332_neon(cospi32, input[8], input[7], &x2[0], &x2[1]); butterfly_s16_s32_x8_0112_neon(cospi32, input[4], input[11], &x2[3], &x2[2]); butterfly_s16_s32_x8_0112_neon(cospi32, input[6], input[9], &x2[5], &x2[4]); butterfly_s16_s32_x8_0332_neon(cospi32, input[10], input[5], &x2[6], &x2[7]); // stage 3 int16x8_t x3[16]; x3[0] = vqaddq_s16(input[0], x2[0]); x3[1] = vqsubq_s16(x2[1], input[15]); x3[2] = vqsubq_s16(input[0], x2[0]); x3[3] = vqaddq_s16(input[15], x2[1]); x3[4] = vqsubq_s16(x2[2], input[3]); x3[5] = vqaddq_s16(input[12], x2[3]); x3[6] = vqaddq_s16(input[3], x2[2]); x3[7] = vqsubq_s16(input[12], x2[3]); x3[8] = vqsubq_s16(x2[4], input[1]); x3[9] = vqaddq_s16(input[14], x2[5]); x3[10] = vqaddq_s16(input[1], x2[4]); x3[11] = vqsubq_s16(input[14], x2[5]); x3[12] = vqaddq_s16(input[2], x2[6]); x3[13] = vqsubq_s16(x2[7], input[13]); x3[14] = vqsubq_s16(input[2], x2[6]); x3[15] = vqaddq_s16(input[13], x2[7]); // stage 4 butterfly_s16_s32_x8_0112_neon(cospi16, x3[4], x3[5], &x3[4], &x3[5]); butterfly_s16_s32_x8_0112_neon(cospi16, x3[7], x3[6], &x3[6], &x3[7]); butterfly_s16_s32_x8_0112_neon(cospi16, x3[12], x3[13], &x3[12], &x3[13]); butterfly_s16_s32_x8_0332_neon(cospi16, x3[14], x3[15], &x3[15], &x3[14]); // stage 5 int16x8_t x5[16]; x5[0] = vqaddq_s16(x3[0], x3[4]); x5[1] = vqaddq_s16(x3[1], x3[5]); x5[2] = vqaddq_s16(x3[2], x3[6]); x5[3] = vqsubq_s16(x3[7], x3[3]); x5[4] = vqsubq_s16(x3[0], x3[4]); x5[5] = vqsubq_s16(x3[1], x3[5]); x5[6] = vqsubq_s16(x3[2], x3[6]); x5[7] = vqaddq_s16(x3[3], x3[7]); x5[8] = vqaddq_s16(x3[8], x3[12]); x5[9] = vqaddq_s16(x3[9], x3[13]); x5[10] = vqsubq_s16(x3[14], x3[10]); x5[11] = vqaddq_s16(x3[11], x3[15]); x5[12] = vqsubq_s16(x3[8], x3[12]); x5[13] = vqsubq_s16(x3[9], x3[13]); x5[14] = vqaddq_s16(x3[10], x3[14]); x5[15] = vqsubq_s16(x3[11], x3[15]); // stage 6 butterfly_s16_s32_x8_0112_neon(cospi8, x5[8], x5[9], &x5[8], &x5[9]); butterfly_s16_s32_x8_1003_neon(cospi24, x5[10], x5[11], &x5[10], &x5[11]); butterfly_s16_s32_x8_1003_neon(cospi8, x5[13], x5[12], &x5[13], &x5[12]); butterfly_s16_s32_x8_1003_neon(cospi24, x5[15], x5[14], &x5[14], &x5[15]); // stage 7 int16x8_t x7[16]; x7[0] = vqaddq_s16(x5[0], x5[8]); x7[1] = vqaddq_s16(x5[1], x5[9]); x7[2] = vqaddq_s16(x5[2], x5[10]); x7[3] = vqaddq_s16(x5[3], x5[11]); x7[4] = vqaddq_s16(x5[4], x5[12]); x7[5] = vqaddq_s16(x5[5], x5[13]); x7[6] = vqaddq_s16(x5[6], x5[14]); x7[7] = vqsubq_s16(x5[15], x5[7]); x7[8] = vqsubq_s16(x5[0], x5[8]); x7[9] = vqsubq_s16(x5[1], x5[9]); x7[10] = vqsubq_s16(x5[2], x5[10]); x7[11] = vqsubq_s16(x5[3], x5[11]); x7[12] = vqsubq_s16(x5[4], x5[12]); x7[13] = vqsubq_s16(x5[5], x5[13]); x7[14] = vqsubq_s16(x5[6], x5[14]); x7[15] = vqaddq_s16(x5[7], x5[15]); // stage 8 butterfly_s16_s32_x8_0112_neon(cospi2, x7[0], x7[1], &output[15], &output[0]); butterfly_s16_s32_x8_0112_neon(cospi10, x7[2], x7[3], &output[13], &output[2]); butterfly_s16_s32_x8_0112_neon(cospi18, x7[4], x7[5], &output[11], &output[4]); butterfly_s16_s32_x8_0112_neon(cospi26, x7[6], x7[7], &output[9], &output[6]); butterfly_s16_s32_x8_1003_neon(cospi30, x7[8], x7[9], &output[7], &output[8]); butterfly_s16_s32_x8_1003_neon(cospi22, x7[10], x7[11], &output[5], &output[10]); butterfly_s16_s32_x8_1003_neon(cospi14, x7[12], x7[13], &output[3], &output[12]); butterfly_s16_s32_x8_0112_neon(cospi6, x7[14], x7[15], &output[14], &output[1]); } static AOM_FORCE_INLINE void fidentity4x4_neon(const int16x4_t *const input, int16x4_t *const output, const int cos_bit) { (void)cos_bit; round_shift_sqrt2_s16_s16_4xn_neon(input, output, 4); } static AOM_FORCE_INLINE void fidentity8x4_neon(const int16x8_t *const input, int16x8_t *const output, const int cos_bit) { (void)cos_bit; round_shift_sqrt2_s16_s16_8xn_neon(input, output, 4); } static AOM_FORCE_INLINE void fidentity4x8_neon(const int16x4_t *input, int16x4_t *output, int cos_bit) { (void)cos_bit; shift_left_1_s16_x4(input, output, 8); } static AOM_FORCE_INLINE void fidentity8x8_neon(const int16x8_t *input, int16x8_t *output, int cos_bit) { (void)cos_bit; shift_left_1_s16_x8(input, output, 8); } static AOM_FORCE_INLINE void fidentity4x16_neon(const int16x4_t *input, int16x4_t *output, int cos_bit) { (void)cos_bit; round_shift_2sqrt2_s16_s16_4xn_neon(input, output, 16); } static AOM_FORCE_INLINE void fidentity8x16_neon(const int16x8_t *input, int16x8_t *output, int cos_bit) { (void)cos_bit; round_shift_2sqrt2_s16_s16_8xn_neon(input, output, 16); } static AOM_FORCE_INLINE void fidentity8x32_neon(const int16x8_t *input, int16x8_t *output, int cos_bit) { (void)cos_bit; shift_left_2_s16_x8(input, output, 32); } #define TRANSFORM_COL(name, tw, n) \ static void name##_col_neon(const int16_t *input, int16x##tw##_t *output, \ int stride, int cos_bit) { \ int16x##tw##_t buf0[n]; \ load_buffer_s16_x##tw(input, stride, buf0, n); \ shift_left_2_s16_x##tw(buf0, buf0, n); \ name##_neon(buf0, output, cos_bit); \ } TRANSFORM_COL(fadst4x4, 4, 4) TRANSFORM_COL(fadst4x8, 4, 8) TRANSFORM_COL(fadst4x16, 4, 16) TRANSFORM_COL(fadst8x4, 8, 4) TRANSFORM_COL(fadst8x8, 8, 8) TRANSFORM_COL(fadst8x16, 8, 16) TRANSFORM_COL(fdct4x4, 4, 4) TRANSFORM_COL(fdct4x8, 4, 8) TRANSFORM_COL(fdct4x16, 4, 16) TRANSFORM_COL(fdct8x4, 8, 4) TRANSFORM_COL(fdct8x8, 8, 8) TRANSFORM_COL(fdct8x16, 8, 16) TRANSFORM_COL(fdct8x32, 8, 32) TRANSFORM_COL(fidentity4x4, 4, 4) TRANSFORM_COL(fidentity4x8, 4, 8) TRANSFORM_COL(fidentity4x16, 4, 16) TRANSFORM_COL(fidentity8x4, 8, 4) TRANSFORM_COL(fidentity8x8, 8, 8) TRANSFORM_COL(fidentity8x16, 8, 16) TRANSFORM_COL(fidentity8x32, 8, 32) #define TRANSFORM_ROW(name, tw, n) \ static void name##_row_neon(const int16x##tw##_t *input, int32_t *output, \ int stride, int cos_bit) { \ int16x##tw##_t buf0[n]; \ name##_neon(input, buf0, cos_bit); \ store_buffer_s16_x##tw(buf0, output, stride, n); \ } #define TRANSFORM_ROW_RECT(name, tw, n) \ static void name##_row_rect_neon(const int16x##tw##_t *input, \ int32_t *output, int stride, int cos_bit) { \ int16x##tw##_t buf0[n]; \ name##_neon(input, buf0, cos_bit); \ store_rect_buffer_s16_x##tw(buf0, output, stride, n); \ } TRANSFORM_ROW(fadst4x4, 4, 4) TRANSFORM_ROW(fadst4x16, 4, 16) TRANSFORM_ROW(fadst8x4, 8, 4) TRANSFORM_ROW(fadst8x8, 8, 8) TRANSFORM_ROW(fadst8x16, 8, 16) TRANSFORM_ROW(fdct4x4, 4, 4) TRANSFORM_ROW(fdct4x16, 4, 16) TRANSFORM_ROW(fdct8x4, 8, 4) TRANSFORM_ROW(fdct8x8, 8, 8) TRANSFORM_ROW(fdct8x16, 8, 16) TRANSFORM_ROW(fdct8x32, 8, 32) TRANSFORM_ROW(fidentity4x4, 4, 4) TRANSFORM_ROW(fidentity4x16, 4, 16) TRANSFORM_ROW(fidentity8x4, 8, 4) TRANSFORM_ROW(fidentity8x8, 8, 8) TRANSFORM_ROW(fidentity8x16, 8, 16) TRANSFORM_ROW(fidentity8x32, 8, 32) TRANSFORM_ROW_RECT(fadst4x8, 4, 8) TRANSFORM_ROW_RECT(fadst8x4, 8, 4) TRANSFORM_ROW_RECT(fadst8x8, 8, 8) TRANSFORM_ROW_RECT(fadst8x16, 8, 16) TRANSFORM_ROW_RECT(fdct4x8, 4, 8) TRANSFORM_ROW_RECT(fdct8x4, 8, 4) TRANSFORM_ROW_RECT(fdct8x8, 8, 8) TRANSFORM_ROW_RECT(fdct8x16, 8, 16) TRANSFORM_ROW_RECT(fdct8x32, 8, 32) TRANSFORM_ROW_RECT(fidentity4x8, 4, 8) TRANSFORM_ROW_RECT(fidentity8x4, 8, 4) TRANSFORM_ROW_RECT(fidentity8x8, 8, 8) TRANSFORM_ROW_RECT(fidentity8x16, 8, 16) TRANSFORM_ROW_RECT(fidentity8x32, 8, 32) typedef void (*transform_1d_lbd_4_neon)(const int16x4_t *input, int16x4_t *output, int cos_bit); typedef void (*transform_1d_lbd_8_neon)(const int16x8_t *input, int16x8_t *output, int cos_bit); typedef void (*col_transform_1d_lbd_4_neon)(const int16_t *input, int16x4_t *output, int stride, int cos_bit); typedef void (*col_transform_1d_lbd_8_neon)(const int16_t *input, int16x8_t *output, int stride, int cos_bit); typedef void (*row_transform_1d_lbd_4_neon)(const int16x4_t *input, int32_t *output, int stride, int cos_bit); typedef void (*row_transform_1d_lbd_8_neon)(const int16x8_t *input, int32_t *output, int stride, int cos_bit); static const col_transform_1d_lbd_4_neon col_txfm4x8_arr[TX_TYPES] = { fdct4x8_col_neon, // DCT_DCT fadst4x8_col_neon, // ADST_DCT fdct4x8_col_neon, // DCT_ADST fadst4x8_col_neon, // ADST_ADST fadst4x8_col_neon, // FLIPADST_DCT fdct4x8_col_neon, // DCT_FLIPADST fadst4x8_col_neon, // FLIPADST_FLIPADST fadst4x8_col_neon, // ADST_FLIPADST fadst4x8_col_neon, // FLIPADST_ADST fidentity4x8_col_neon, // IDTX fdct4x8_col_neon, // V_DCT fidentity4x8_col_neon, // H_DCT fadst4x8_col_neon, // V_ADST fidentity4x8_col_neon, // H_ADST fadst4x8_col_neon, // V_FLIPADST fidentity4x8_col_neon // H_FLIPADST }; static const row_transform_1d_lbd_8_neon row_txfm8x4_arr[TX_TYPES] = { fdct8x4_row_neon, // DCT_DCT fdct8x4_row_neon, // ADST_DCT fadst8x4_row_neon, // DCT_ADST fadst8x4_row_neon, // ADST_ADST fdct8x4_row_neon, // FLIPADST_DCT fadst8x4_row_neon, // DCT_FLIPADST fadst8x4_row_neon, // FLIPADST_FLIPADST fadst8x4_row_neon, // ADST_FLIPADST fadst8x4_row_neon, // FLIPADST_ADST fidentity8x4_row_neon, // IDTX fidentity8x4_row_neon, // V_DCT fdct8x4_row_neon, // H_DCT fidentity8x4_row_neon, // V_ADST fadst8x4_row_neon, // H_ADST fidentity8x4_row_neon, // V_FLIPADST fadst8x4_row_neon // H_FLIPADST }; static const row_transform_1d_lbd_8_neon row_rect_txfm8x4_arr[TX_TYPES] = { fdct8x4_row_rect_neon, // DCT_DCT fdct8x4_row_rect_neon, // ADST_DCT fadst8x4_row_rect_neon, // DCT_ADST fadst8x4_row_rect_neon, // ADST_ADST fdct8x4_row_rect_neon, // FLIPADST_DCT fadst8x4_row_rect_neon, // DCT_FLIPADST fadst8x4_row_rect_neon, // FLIPADST_FLIPADST fadst8x4_row_rect_neon, // ADST_FLIPADST fadst8x4_row_rect_neon, // FLIPADST_ADST fidentity8x4_row_rect_neon, // IDTX fidentity8x4_row_rect_neon, // V_DCT fdct8x4_row_rect_neon, // H_DCT fidentity8x4_row_rect_neon, // V_ADST fadst8x4_row_rect_neon, // H_ADST fidentity8x4_row_rect_neon, // V_FLIPADST fadst8x4_row_rect_neon // H_FLIPADST }; static const col_transform_1d_lbd_8_neon col_txfm8x4_arr[TX_TYPES] = { fdct8x4_col_neon, // DCT_DCT fadst8x4_col_neon, // ADST_DCT fdct8x4_col_neon, // DCT_ADST fadst8x4_col_neon, // ADST_ADST fadst8x4_col_neon, // FLIPADST_DCT fdct8x4_col_neon, // DCT_FLIPADST fadst8x4_col_neon, // FLIPADST_FLIPADST fadst8x4_col_neon, // ADST_FLIPADST fadst8x4_col_neon, // FLIPADST_ADST fidentity8x4_col_neon, // IDTX fdct8x4_col_neon, // V_DCT fidentity8x4_col_neon, // H_DCT fadst8x4_col_neon, // V_ADST fidentity8x4_col_neon, // H_ADST fadst8x4_col_neon, // V_FLIPADST fidentity8x4_col_neon // H_FLIPADST }; static const row_transform_1d_lbd_4_neon row_rect_txfm4x8_arr[TX_TYPES] = { fdct4x8_row_rect_neon, // DCT_DCT fdct4x8_row_rect_neon, // ADST_DCT fadst4x8_row_rect_neon, // DCT_ADST fadst4x8_row_rect_neon, // ADST_ADST fdct4x8_row_rect_neon, // FLIPADST_DCT fadst4x8_row_rect_neon, // DCT_FLIPADST fadst4x8_row_rect_neon, // FLIPADST_FLIPADST fadst4x8_row_rect_neon, // ADST_FLIPADST fadst4x8_row_rect_neon, // FLIPADST_ADST fidentity4x8_row_rect_neon, // IDTX fidentity4x8_row_rect_neon, // V_DCT fdct4x8_row_rect_neon, // H_DCT fidentity4x8_row_rect_neon, // V_ADST fadst4x8_row_rect_neon, // H_ADST fidentity4x8_row_rect_neon, // V_FLIPADST fadst4x8_row_rect_neon // H_FLIPADST }; static const col_transform_1d_lbd_8_neon col_txfm8x8_arr[TX_TYPES] = { fdct8x8_col_neon, // DCT_DCT fadst8x8_col_neon, // ADST_DCT fdct8x8_col_neon, // DCT_ADST fadst8x8_col_neon, // ADST_ADST fadst8x8_col_neon, // FLIPADST_DCT fdct8x8_col_neon, // DCT_FLIPADST fadst8x8_col_neon, // FLIPADST_FLIPADST fadst8x8_col_neon, // ADST_FLIPADST fadst8x8_col_neon, // FLIPADST_ADST fidentity8x8_col_neon, // IDTX fdct8x8_col_neon, // V_DCT fidentity8x8_col_neon, // H_DCT fadst8x8_col_neon, // V_ADST fidentity8x8_col_neon, // H_ADST fadst8x8_col_neon, // V_FLIPADST fidentity8x8_col_neon, // H_FLIPADST }; static const row_transform_1d_lbd_8_neon row_txfm8x8_arr[TX_TYPES] = { fdct8x8_row_neon, // DCT_DCT fdct8x8_row_neon, // ADST_DCT fadst8x8_row_neon, // DCT_ADST fadst8x8_row_neon, // ADST_ADST fdct8x8_row_neon, // FLIPADST_DCT fadst8x8_row_neon, // DCT_FLIPADST fadst8x8_row_neon, // FLIPADST_FLIPADST fadst8x8_row_neon, // ADST_FLIPADST fadst8x8_row_neon, // FLIPADST_ADST fidentity8x8_row_neon, // IDTX fidentity8x8_row_neon, // V_DCT fdct8x8_row_neon, // H_DCT fidentity8x8_row_neon, // V_ADST fadst8x8_row_neon, // H_ADST fidentity8x8_row_neon, // V_FLIPADST fadst8x8_row_neon // H_FLIPADST }; static const row_transform_1d_lbd_8_neon row_rect_txfm8x8_arr[TX_TYPES] = { fdct8x8_row_rect_neon, // DCT_DCT fdct8x8_row_rect_neon, // ADST_DCT fadst8x8_row_rect_neon, // DCT_ADST fadst8x8_row_rect_neon, // ADST_ADST fdct8x8_row_rect_neon, // FLIPADST_DCT fadst8x8_row_rect_neon, // DCT_FLIPADST fadst8x8_row_rect_neon, // FLIPADST_FLIPADST fadst8x8_row_rect_neon, // ADST_FLIPADST fadst8x8_row_rect_neon, // FLIPADST_ADST fidentity8x8_row_rect_neon, // IDTX fidentity8x8_row_rect_neon, // V_DCT fdct8x8_row_rect_neon, // H_DCT fidentity8x8_row_rect_neon, // V_ADST fadst8x8_row_rect_neon, // H_ADST fidentity8x8_row_rect_neon, // V_FLIPADST fadst8x8_row_rect_neon // H_FLIPADST }; static const col_transform_1d_lbd_4_neon col_txfm4x16_arr[TX_TYPES] = { fdct4x16_col_neon, // DCT_DCT fadst4x16_col_neon, // ADST_DCT fdct4x16_col_neon, // DCT_ADST fadst4x16_col_neon, // ADST_ADST fadst4x16_col_neon, // FLIPADST_DCT fdct4x16_col_neon, // DCT_FLIPADST fadst4x16_col_neon, // FLIPADST_FLIPADST fadst4x16_col_neon, // ADST_FLIPADST fadst4x16_col_neon, // FLIPADST_ADST fidentity4x16_col_neon, // IDTX fdct4x16_col_neon, // V_DCT fidentity4x16_col_neon, // H_DCT fadst4x16_col_neon, // V_ADST fidentity4x16_col_neon, // H_ADST fadst4x16_col_neon, // V_FLIPADST fidentity4x16_col_neon // H_FLIPADST }; static const row_transform_1d_lbd_4_neon row_txfm4x16_arr[TX_TYPES] = { fdct4x16_row_neon, // DCT_DCT fdct4x16_row_neon, // ADST_DCT fadst4x16_row_neon, // DCT_ADST fadst4x16_row_neon, // ADST_ADST fdct4x16_row_neon, // FLIPADST_DCT fadst4x16_row_neon, // DCT_FLIPADST fadst4x16_row_neon, // FLIPADST_FLIPADST fadst4x16_row_neon, // ADST_FLIPADST fadst4x16_row_neon, // FLIPADST_ADST fidentity4x16_row_neon, // IDTX fidentity4x16_row_neon, // V_DCT fdct4x16_row_neon, // H_DCT fidentity4x16_row_neon, // V_ADST fadst4x16_row_neon, // H_ADST fidentity4x16_row_neon, // V_FLIPADST fadst4x16_row_neon // H_FLIPADST }; static const col_transform_1d_lbd_8_neon col_txfm8x16_arr[TX_TYPES] = { fdct8x16_col_neon, // DCT_DCT fadst8x16_col_neon, // ADST_DCT fdct8x16_col_neon, // DCT_ADST fadst8x16_col_neon, // ADST_ADST fadst8x16_col_neon, // FLIPADST_DCT fdct8x16_col_neon, // DCT_FLIPADST fadst8x16_col_neon, // FLIPADST_FLIPADST fadst8x16_col_neon, // ADST_FLIPADST fadst8x16_col_neon, // FLIPADST_ADST fidentity8x16_col_neon, // IDTX fdct8x16_col_neon, // V_DCT fidentity8x16_col_neon, // H_DCT fadst8x16_col_neon, // V_ADST fidentity8x16_col_neon, // H_ADST fadst8x16_col_neon, // V_FLIPADST fidentity8x16_col_neon // H_FLIPADST }; static const row_transform_1d_lbd_8_neon row_txfm8x16_arr[TX_TYPES] = { fdct8x16_row_neon, // DCT_DCT fdct8x16_row_neon, // ADST_DCT fadst8x16_row_neon, // DCT_ADST fadst8x16_row_neon, // ADST_ADST fdct8x16_row_neon, // FLIPADST_DCT fadst8x16_row_neon, // DCT_FLIPADST fadst8x16_row_neon, // FLIPADST_FLIPADST fadst8x16_row_neon, // ADST_FLIPADST fadst8x16_row_neon, // FLIPADST_ADST fidentity8x16_row_neon, // IDTX fidentity8x16_row_neon, // V_DCT fdct8x16_row_neon, // H_DCT fidentity8x16_row_neon, // V_ADST fadst8x16_row_neon, // H_ADST fidentity8x16_row_neon, // V_FLIPADST fadst8x16_row_neon // H_FLIPADST }; static const row_transform_1d_lbd_8_neon row_rect_txfm8x16_arr[TX_TYPES] = { fdct8x16_row_rect_neon, // DCT_DCT fdct8x16_row_rect_neon, // ADST_DCT fadst8x16_row_rect_neon, // DCT_ADST fadst8x16_row_rect_neon, // ADST_ADST fdct8x16_row_rect_neon, // FLIPADST_DCT fadst8x16_row_rect_neon, // DCT_FLIPADST fadst8x16_row_rect_neon, // FLIPADST_FLIPADST fadst8x16_row_rect_neon, // ADST_FLIPADST fadst8x16_row_rect_neon, // FLIPADST_ADST fidentity8x16_row_rect_neon, // IDTX fidentity8x16_row_rect_neon, // V_DCT fdct8x16_row_rect_neon, // H_DCT fidentity8x16_row_rect_neon, // V_ADST fadst8x16_row_rect_neon, // H_ADST fidentity8x16_row_rect_neon, // V_FLIPADST fadst8x16_row_rect_neon // H_FLIPADST }; static const row_transform_1d_lbd_8_neon row_txfm8x32_arr[TX_TYPES] = { fdct8x32_row_neon, // DCT_DCT NULL, // ADST_DCT NULL, // DCT_ADST NULL, // ADST_ADST NULL, // FLIPADST_DCT NULL, // DCT_FLIPADST NULL, // FLIPADST_FLIPADST NULL, // ADST_FLIPADST NULL, // FLIPADST_ADST fidentity8x32_row_neon, // IDTX fidentity8x32_row_neon, // V_DCT fdct8x32_row_neon, // H_DCT NULL, // V_ADST NULL, // H_ADST NULL, // V_FLIPADST NULL // H_FLIPADST }; static const row_transform_1d_lbd_8_neon row_rect_txfm8x32_arr[TX_TYPES] = { fdct8x32_row_rect_neon, // DCT_DCT NULL, // ADST_DCT NULL, // DCT_ADST NULL, // ADST_ADST NULL, // FLIPADST_DCT NULL, // DCT_FLIPADST NULL, // FLIPADST_FLIPADST NULL, // ADST_FLIPADST NULL, // FLIPADST_ADST fidentity8x32_row_rect_neon, // IDTX fidentity8x32_row_rect_neon, // V_DCT fdct8x32_row_rect_neon, // H_DCT NULL, // V_ADST NULL, // H_ADST NULL, // V_FLIPADST NULL // H_FLIPADST }; static const col_transform_1d_lbd_8_neon col_txfm8x32_arr[TX_TYPES] = { fdct8x32_col_neon, // DCT_DCT NULL, // ADST_DCT NULL, // DCT_ADST NULL, // ADST_ADST NULL, // FLIPADST_DCT NULL, // DCT_FLIPADST NULL, // FLIPADST_FLIPADST NULL, // ADST_FLIPADST NULL, // FLIPADST_ADST fidentity8x32_col_neon, // IDTX fdct8x32_col_neon, // V_DCT fidentity8x32_col_neon, // H_DCT NULL, // V_ADST NULL, // H_ADST NULL, // V_FLIPADST NULL // H_FLIPADST }; static void lowbd_fwd_txfm2d_4x4_neon(const int16_t *input, int32_t *output, int stride, TX_TYPE tx_type, int bd) { (void)bd; int ud_flip, lr_flip; get_flip_cfg(tx_type, &ud_flip, &lr_flip); ud_adjust_input_and_stride(ud_flip, &input, &stride, 4); int16x4_t buf0[4], buf1[4]; switch (tx_type) { case DCT_DCT: fdct4x4_col_neon(input, buf0, stride, 13); transpose_arrays_s16_4x4(buf0, buf1); fdct4x4_row_neon(buf1, output, 4, 13); break; case ADST_DCT: fadst4x4_col_neon(input, buf0, stride, 13); transpose_arrays_s16_4x4(buf0, buf1); fdct4x4_row_neon(buf1, output, 4, 13); break; case DCT_ADST: fdct4x4_col_neon(input, buf0, stride, 13); transpose_arrays_s16_4x4(buf0, buf1); fadst4x4_row_neon(buf1, output, 4, 13); break; case ADST_ADST: fadst4x4_col_neon(input, buf0, stride, 13); transpose_arrays_s16_4x4(buf0, buf1); fadst4x4_row_neon(buf1, output, 4, 13); break; case FLIPADST_DCT: fadst4x4_col_neon(input, buf0, stride, 13); transpose_arrays_s16_4x4(buf0, buf1); fdct4x4_row_neon(buf1, output, 4, 13); break; case DCT_FLIPADST: fdct4x4_col_neon(input, buf0, stride, 13); transpose_arrays_s16_4x4(buf0, buf1); flip_buf_4_neon(buf1, buf0, 4); fadst4x4_row_neon(buf0, output, 4, 13); break; case FLIPADST_FLIPADST: fadst4x4_col_neon(input, buf0, stride, 13); transpose_arrays_s16_4x4(buf0, buf1); flip_buf_4_neon(buf1, buf0, 4); fadst4x4_row_neon(buf0, output, 4, 13); break; case ADST_FLIPADST: fadst4x4_col_neon(input, buf0, stride, 13); transpose_arrays_s16_4x4(buf0, buf1); flip_buf_4_neon(buf1, buf0, 4); fadst4x4_row_neon(buf0, output, 4, 13); break; case FLIPADST_ADST: fadst4x4_col_neon(input, buf0, stride, 13); transpose_arrays_s16_4x4(buf0, buf1); fadst4x4_row_neon(buf1, output, 4, 13); break; case IDTX: fidentity4x4_col_neon(input, buf0, stride, 13); transpose_arrays_s16_4x4(buf0, buf1); fidentity4x4_row_neon(buf1, output, 4, 13); break; case V_DCT: fdct4x4_col_neon(input, buf0, stride, 13); transpose_arrays_s16_4x4(buf0, buf1); fidentity4x4_row_neon(buf1, output, 4, 13); break; case H_DCT: fidentity4x4_col_neon(input, buf0, stride, 13); transpose_arrays_s16_4x4(buf0, buf1); fdct4x4_row_neon(buf1, output, 4, 13); break; case V_ADST: fadst4x4_col_neon(input, buf0, stride, 13); transpose_arrays_s16_4x4(buf0, buf1); fidentity4x4_row_neon(buf1, output, 4, 13); break; case H_ADST: fidentity4x4_col_neon(input, buf0, stride, 13); transpose_arrays_s16_4x4(buf0, buf1); fadst4x4_row_neon(buf1, output, 4, 13); break; case V_FLIPADST: fadst4x4_col_neon(input, buf0, stride, 13); transpose_arrays_s16_4x4(buf0, buf1); fidentity4x4_row_neon(buf1, output, 4, 13); break; case H_FLIPADST: fidentity4x4_col_neon(input, buf0, stride, 13); transpose_arrays_s16_4x4(buf0, buf1); flip_buf_4_neon(buf1, buf0, 4); fadst4x4_row_neon(buf0, output, 4, 13); break; } } static void lowbd_fwd_txfm2d_4x8_neon(const int16_t *input, int32_t *output, int stride, TX_TYPE tx_type, int bd) { (void)bd; int16x4_t buf0[8]; int16x8_t buf1[8]; const col_transform_1d_lbd_4_neon col_txfm = col_txfm4x8_arr[tx_type]; const row_transform_1d_lbd_8_neon row_txfm = row_rect_txfm8x4_arr[tx_type]; int ud_flip, lr_flip; get_flip_cfg(tx_type, &ud_flip, &lr_flip); ud_adjust_input_and_stride(ud_flip, &input, &stride, 8); col_txfm(input, buf0, stride, 13); shift_right_1_round_s16_x4(buf0, buf0, 8); transpose_arrays_s16_4x8(buf0, buf1); if (lr_flip) { int16x8_t buf2[8]; flip_buf_8_neon(buf1, buf2, 4); row_txfm(buf2, output, 8, 13); } else { row_txfm(buf1, output, 8, 13); } } static void lowbd_fwd_txfm2d_4x16_neon(const int16_t *input, int32_t *output, int stride, TX_TYPE tx_type, int bd) { (void)bd; int16x4_t buf0[16]; int16x8_t buf1[16]; const col_transform_1d_lbd_4_neon col_txfm = col_txfm4x16_arr[tx_type]; const row_transform_1d_lbd_8_neon row_txfm = row_txfm8x4_arr[tx_type]; int ud_flip, lr_flip; get_flip_cfg(tx_type, &ud_flip, &lr_flip); ud_adjust_input_and_stride(ud_flip, &input, &stride, 16); col_txfm(input, buf0, stride, 13); shift_right_1_round_s16_x4(buf0, buf0, 16); transpose_arrays_s16_4x8(buf0, buf1); transpose_arrays_s16_4x8(buf0 + 8, buf1 + 8); for (int i = 0; i < 2; i++) { if (lr_flip) { int16x8_t buf2[16]; flip_buf_8_neon(buf1 + 8 * i, buf2, 4); row_txfm(buf2, output + 8 * i, 16, 12); } else { int16x8_t *buf = buf1 + 8 * i; row_txfm(buf, output + 8 * i, 16, 12); } } } static void lowbd_fwd_txfm2d_8x4_neon(const int16_t *input, int32_t *output, int stride, TX_TYPE tx_type, int bd) { (void)bd; int16x8_t buf0[8]; int16x4_t buf1[8]; const col_transform_1d_lbd_8_neon col_txfm = col_txfm8x4_arr[tx_type]; const row_transform_1d_lbd_4_neon row_txfm = row_rect_txfm4x8_arr[tx_type]; int ud_flip, lr_flip; get_flip_cfg(tx_type, &ud_flip, &lr_flip); ud_adjust_input_and_stride(ud_flip, &input, &stride, 4); col_txfm(input, buf0, stride, 13); shift_right_1_round_s16_x8(buf0, buf0, 4); transpose_arrays_s16_8x4(buf0, buf1); if (lr_flip) { int16x4_t buf2[8]; flip_buf_4_neon(buf1, buf2, 8); row_txfm(buf2, output, 4, 13); } else { row_txfm(buf1, output, 4, 13); } } static void lowbd_fwd_txfm2d_8x8_neon(const int16_t *input, int32_t *output, int stride, TX_TYPE tx_type, int bd) { (void)bd; int ud_flip, lr_flip; get_flip_cfg(tx_type, &ud_flip, &lr_flip); ud_adjust_input_and_stride(ud_flip, &input, &stride, 8); int16x8_t buf0[8], buf1[8]; switch (tx_type) { case DCT_DCT: fdct8x8_col_neon(input, buf0, stride, 13); shift_right_1_round_s16_x8(buf0, buf0, 8); transpose_arrays_s16_8x8(buf0, buf1); fdct8x8_row_neon(buf1, output, 8, 13); break; case ADST_DCT: fadst8x8_col_neon(input, buf0, stride, 13); shift_right_1_round_s16_x8(buf0, buf0, 8); transpose_arrays_s16_8x8(buf0, buf1); fdct8x8_row_neon(buf1, output, 8, 13); break; case DCT_ADST: fdct8x8_col_neon(input, buf0, stride, 13); shift_right_1_round_s16_x8(buf0, buf0, 8); transpose_arrays_s16_8x8(buf0, buf1); fadst8x8_row_neon(buf1, output, 8, 13); break; case ADST_ADST: fadst8x8_col_neon(input, buf0, stride, 13); shift_right_1_round_s16_x8(buf0, buf0, 8); transpose_arrays_s16_8x8(buf0, buf1); fadst8x8_row_neon(buf1, output, 8, 13); break; case FLIPADST_DCT: fadst8x8_col_neon(input, buf0, stride, 13); shift_right_1_round_s16_x8(buf0, buf0, 8); transpose_arrays_s16_8x8(buf0, buf1); fdct8x8_row_neon(buf1, output, 8, 13); break; case DCT_FLIPADST: fdct8x8_col_neon(input, buf0, stride, 13); shift_right_1_round_s16_x8(buf0, buf0, 8); transpose_arrays_s16_8x8(buf0, buf1); flip_buf_8_neon(buf1, buf0, 8); fadst8x8_row_neon(buf0, output, 8, 13); break; case FLIPADST_FLIPADST: fadst8x8_col_neon(input, buf0, stride, 13); shift_right_1_round_s16_x8(buf0, buf0, 8); transpose_arrays_s16_8x8(buf0, buf1); flip_buf_8_neon(buf1, buf0, 8); fadst8x8_row_neon(buf0, output, 8, 13); break; case ADST_FLIPADST: fadst8x8_col_neon(input, buf0, stride, 13); shift_right_1_round_s16_x8(buf0, buf0, 8); transpose_arrays_s16_8x8(buf0, buf1); flip_buf_8_neon(buf1, buf0, 8); fadst8x8_row_neon(buf0, output, 8, 13); break; case FLIPADST_ADST: fadst8x8_col_neon(input, buf0, stride, 13); shift_right_1_round_s16_x8(buf0, buf0, 8); transpose_arrays_s16_8x8(buf0, buf1); fadst8x8_row_neon(buf1, output, 8, 13); break; case IDTX: fidentity8x8_col_neon(input, buf0, stride, 13); shift_right_1_round_s16_x8(buf0, buf0, 8); transpose_arrays_s16_8x8(buf0, buf1); fidentity8x8_row_neon(buf1, output, 8, 13); break; case V_DCT: fdct8x8_col_neon(input, buf0, stride, 13); shift_right_1_round_s16_x8(buf0, buf0, 8); transpose_arrays_s16_8x8(buf0, buf1); fidentity8x8_row_neon(buf1, output, 8, 13); break; case H_DCT: fidentity8x8_col_neon(input, buf0, stride, 13); shift_right_1_round_s16_x8(buf0, buf0, 8); transpose_arrays_s16_8x8(buf0, buf1); fdct8x8_row_neon(buf1, output, 8, 13); break; case V_ADST: fadst8x8_col_neon(input, buf0, stride, 13); shift_right_1_round_s16_x8(buf0, buf0, 8); transpose_arrays_s16_8x8(buf0, buf1); fidentity8x8_row_neon(buf1, output, 8, 13); break; case H_ADST: fidentity8x8_col_neon(input, buf0, stride, 13); shift_right_1_round_s16_x8(buf0, buf0, 8); transpose_arrays_s16_8x8(buf0, buf1); fadst8x8_row_neon(buf1, output, 8, 13); break; case V_FLIPADST: fadst8x8_col_neon(input, buf0, stride, 13); shift_right_1_round_s16_x8(buf0, buf0, 8); transpose_arrays_s16_8x8(buf0, buf1); fidentity8x8_row_neon(buf1, output, 8, 13); break; case H_FLIPADST: fidentity8x8_col_neon(input, buf0, stride, 13); shift_right_1_round_s16_x8(buf0, buf0, 8); transpose_arrays_s16_8x8(buf0, buf1); flip_buf_8_neon(buf1, buf0, 8); fadst8x8_row_neon(buf0, output, 8, 13); break; } } static void lowbd_fwd_txfm2d_8x16_neon(const int16_t *input, int32_t *output, int stride, TX_TYPE tx_type, int bd) { (void)bd; int16x8_t buf0[16], buf1[16]; const col_transform_1d_lbd_8_neon col_txfm = col_txfm8x16_arr[tx_type]; const row_transform_1d_lbd_8_neon row_txfm = row_rect_txfm8x8_arr[tx_type]; int ud_flip, lr_flip; get_flip_cfg(tx_type, &ud_flip, &lr_flip); ud_adjust_input_and_stride(ud_flip, &input, &stride, 16); col_txfm(input, buf0, stride, 13); shift_right_2_round_s16_x8(buf0, buf0, 16); transpose_arrays_s16_8x8(buf0, buf1); transpose_arrays_s16_8x8(buf0 + 8, buf1 + 8); for (int i = 0; i < 2; i++) { if (lr_flip) { flip_buf_8_neon(buf1 + 8 * i, buf0, 8); row_txfm(buf0, output + 8 * i, 16, 13); } else { int16x8_t *buf = buf1 + 8 * i; row_txfm(buf, output + 8 * i, 16, 13); } } } static void lowbd_fwd_txfm2d_8x32_neon(const int16_t *input, int32_t *output, int stride, TX_TYPE tx_type, int bd) { (void)bd; int16x8_t buf0[32], buf1[32]; const col_transform_1d_lbd_8_neon col_txfm = col_txfm8x32_arr[tx_type]; const row_transform_1d_lbd_8_neon row_txfm = row_txfm8x8_arr[tx_type]; int ud_flip, lr_flip; get_flip_cfg(tx_type, &ud_flip, &lr_flip); ud_adjust_input_and_stride(ud_flip, &input, &stride, 32); col_txfm(input, buf0, stride, 12); shift_right_2_round_s16_x8(buf0, buf0, 32); transpose_arrays_s16_8x8(buf0, buf1); transpose_arrays_s16_8x8(buf0 + 8, buf1 + 8); transpose_arrays_s16_8x8(buf0 + 16, buf1 + 16); transpose_arrays_s16_8x8(buf0 + 24, buf1 + 24); for (int i = 0; i < 4; i++) { if (lr_flip) { flip_buf_8_neon(buf1 + 8 * i, buf0, 8); row_txfm(buf0, output + 8 * i, 32, 12); } else { int16x8_t *buf = buf1 + 8 * i; row_txfm(buf, output + 8 * i, 32, 12); } } } static void lowbd_fwd_txfm2d_16x4_neon(const int16_t *input, int32_t *output, int stride, TX_TYPE tx_type, int bd) { (void)bd; int16x8_t buf0[16]; int16x4_t buf1[16]; int16x4_t buf2[16]; const col_transform_1d_lbd_8_neon col_txfm = col_txfm8x4_arr[tx_type]; const row_transform_1d_lbd_4_neon row_txfm = row_txfm4x16_arr[tx_type]; int ud_flip, lr_flip; get_flip_cfg(tx_type, &ud_flip, &lr_flip); ud_adjust_input_and_stride(ud_flip, &input, &stride, 4); for (int i = 0; i < 2; i++) { col_txfm(input + 8 * i, buf0, stride, 13); shift_right_1_round_s16_x8(buf0, buf0, 4); transpose_arrays_s16_8x4(buf0, buf1 + 8 * i); } if (lr_flip) { flip_buf_4_neon(buf1, buf2, 16); row_txfm(buf2, output, 4, 13); } else { row_txfm(buf1, output, 4, 13); } } static void lowbd_fwd_txfm2d_16x8_neon(const int16_t *input, int32_t *output, int stride, TX_TYPE tx_type, int bd) { (void)bd; int16x8_t buf0[16], buf1[16]; const col_transform_1d_lbd_8_neon col_txfm = col_txfm8x8_arr[tx_type]; const row_transform_1d_lbd_8_neon row_txfm = row_rect_txfm8x16_arr[tx_type]; int ud_flip, lr_flip; get_flip_cfg(tx_type, &ud_flip, &lr_flip); ud_adjust_input_and_stride(ud_flip, &input, &stride, 8); for (int i = 0; i < 2; i++) { col_txfm(input + 8 * i, buf0, stride, 13); shift_right_2_round_s16_x8(buf0, buf0, 8); transpose_arrays_s16_8x8(buf0, buf1 + 8 * i); } if (lr_flip) { flip_buf_8_neon(buf1, buf0, 16); row_txfm(buf0, output, 8, 13); } else { row_txfm(buf1, output, 8, 13); } } static void lowbd_fwd_txfm2d_16x16_neon(const int16_t *input, int32_t *output, int stride, TX_TYPE tx_type, int bd) { (void)bd; int16x8_t buf0[16], buf1[32]; const col_transform_1d_lbd_8_neon col_txfm = col_txfm8x16_arr[tx_type]; const row_transform_1d_lbd_8_neon row_txfm = row_txfm8x16_arr[tx_type]; int ud_flip, lr_flip; get_flip_cfg(tx_type, &ud_flip, &lr_flip); ud_adjust_input_and_stride(ud_flip, &input, &stride, 16); for (int i = 0; i < 2; i++) { col_txfm(input + 8 * i, buf0, stride, 13); shift_right_2_round_s16_x8(buf0, buf0, 16); transpose_arrays_s16_8x8(buf0, buf1 + 0 * 16 + 8 * i); transpose_arrays_s16_8x8(buf0 + 8, buf1 + 1 * 16 + 8 * i); } for (int i = 0; i < 2; i++) { if (lr_flip) { flip_buf_8_neon(buf1 + 16 * i, buf0, 16); row_txfm(buf0, output + 8 * i, 16, 12); } else { int16x8_t *buf = buf1 + 16 * i; row_txfm(buf, output + 8 * i, 16, 12); } } } static void lowbd_fwd_txfm2d_16x32_neon(const int16_t *input, int32_t *output, int stride, TX_TYPE tx_type, int bd) { (void)bd; int16x8_t buf0[32], buf1[64]; const col_transform_1d_lbd_8_neon col_txfm = col_txfm8x32_arr[tx_type]; const row_transform_1d_lbd_8_neon row_txfm = row_rect_txfm8x16_arr[tx_type]; if (col_txfm == NULL || row_txfm == NULL) { av1_fwd_txfm2d_16x32_c(input, output, stride, tx_type, bd); return; } int ud_flip, lr_flip; get_flip_cfg(tx_type, &ud_flip, &lr_flip); ud_adjust_input_and_stride(ud_flip, &input, &stride, 32); for (int i = 0; i < 2; i++) { col_txfm(input + 8 * i, buf0, stride, 12); shift_right_4_round_s16_x8(buf0, buf0, 32); transpose_arrays_s16_8x8(buf0 + 0 * 8, buf1 + 0 * 16 + 8 * i); transpose_arrays_s16_8x8(buf0 + 1 * 8, buf1 + 1 * 16 + 8 * i); transpose_arrays_s16_8x8(buf0 + 2 * 8, buf1 + 2 * 16 + 8 * i); transpose_arrays_s16_8x8(buf0 + 3 * 8, buf1 + 3 * 16 + 8 * i); } for (int i = 0; i < 4; i++) { if (lr_flip) { flip_buf_8_neon(buf1 + 16 * i, buf0, 16); row_txfm(buf0, output + 8 * i, 32, 13); } else { int16x8_t *buf = buf1 + 16 * i; row_txfm(buf, output + 8 * i, 32, 13); } } } static void lowbd_fwd_txfm2d_32x8_neon(const int16_t *input, int32_t *output, int stride, TX_TYPE tx_type, int bd) { (void)bd; int16x8_t buf0[32], buf1[32]; const col_transform_1d_lbd_8_neon col_txfm = col_txfm8x8_arr[tx_type]; const row_transform_1d_lbd_8_neon row_txfm = row_txfm8x32_arr[tx_type]; if (col_txfm == NULL || row_txfm == NULL) { av1_fwd_txfm2d_32x16_c(input, output, stride, tx_type, bd); return; } int ud_flip, lr_flip; get_flip_cfg(tx_type, &ud_flip, &lr_flip); ud_adjust_input_and_stride(ud_flip, &input, &stride, 8); for (int i = 0; i < 4; i++) { col_txfm(input + 8 * i, buf0, stride, 13); shift_right_2_round_s16_x8(buf0, buf0, 8); transpose_arrays_s16_8x8(buf0, buf1 + 0 * 32 + 8 * i); } if (lr_flip) { flip_buf_8_neon(buf1, buf0, 32); row_txfm(buf0, output, 8, 12); } else { row_txfm(buf1, output, 8, 12); } } static void lowbd_fwd_txfm2d_32x16_neon(const int16_t *input, int32_t *output, int stride, TX_TYPE tx_type, int bd) { (void)bd; int16x8_t buf0[32], buf1[64]; const col_transform_1d_lbd_8_neon col_txfm = col_txfm8x16_arr[tx_type]; const row_transform_1d_lbd_8_neon row_txfm = row_rect_txfm8x32_arr[tx_type]; if (col_txfm == NULL || row_txfm == NULL) { av1_fwd_txfm2d_32x16_c(input, output, stride, tx_type, bd); return; } int ud_flip, lr_flip; get_flip_cfg(tx_type, &ud_flip, &lr_flip); ud_adjust_input_and_stride(ud_flip, &input, &stride, 16); for (int i = 0; i < 4; i++) { col_txfm(input + 8 * i, buf0, stride, 13); shift_right_4_round_s16_x8(buf0, buf0, 16); transpose_arrays_s16_8x8(buf0, buf1 + 0 * 32 + 8 * i); transpose_arrays_s16_8x8(buf0 + 8, buf1 + 1 * 32 + 8 * i); } for (int i = 0; i < 2; i++) { if (lr_flip) { flip_buf_8_neon(buf1 + 32 * i, buf0, 32); row_txfm(buf0, output + 8 * i, 16, 13); } else { int16x8_t *buf = buf1 + 32 * i; row_txfm(buf, output + 8 * i, 16, 13); } } } static void lowbd_fwd_txfm2d_32x32_neon(const int16_t *input, int32_t *output, int stride, TX_TYPE tx_type, int bd) { (void)bd; int16x8_t buf0[32], buf1[128]; const col_transform_1d_lbd_8_neon col_txfm = col_txfm8x32_arr[tx_type]; const row_transform_1d_lbd_8_neon row_txfm = row_txfm8x32_arr[tx_type]; if (col_txfm == NULL || row_txfm == NULL) { av1_fwd_txfm2d_32x32_c(input, output, stride, tx_type, bd); return; } int ud_flip, lr_flip; get_flip_cfg(tx_type, &ud_flip, &lr_flip); ud_adjust_input_and_stride(ud_flip, &input, &stride, 32); for (int i = 0; i < 4; i++) { col_txfm(input + 8 * i, buf0, stride, 12); shift_right_4_round_s16_x8(buf0, buf0, 32); transpose_arrays_s16_8x8(buf0 + 0 * 8, buf1 + 0 * 32 + 8 * i); transpose_arrays_s16_8x8(buf0 + 1 * 8, buf1 + 1 * 32 + 8 * i); transpose_arrays_s16_8x8(buf0 + 2 * 8, buf1 + 2 * 32 + 8 * i); transpose_arrays_s16_8x8(buf0 + 3 * 8, buf1 + 3 * 32 + 8 * i); } for (int i = 0; i < 4; i++) { if (lr_flip) { flip_buf_8_neon(buf1 + 32 * i, buf0, 32); row_txfm(buf0, output + 8 * i, 32, 12); } else { int16x8_t *buf = buf1 + 32 * i; row_txfm(buf, output + 8 * i, 32, 12); } } } static void lowbd_fwd_txfm2d_64x16_neon(const int16_t *input, int32_t *output, int stride, TX_TYPE tx_type, int bd) { (void)bd; (void)tx_type; assert(tx_type == DCT_DCT); int16x8_t buf0[64], buf1[128]; const transform_1d_lbd_8_neon col_txfm = fdct8x16_neon; const transform_1d_lbd_8_neon row_txfm = fdct8x64_neon; for (int i = 0; i < 8; i++) { load_buffer_s16_x8(input + 8 * i, stride, buf0, 16); shift_left_2_s16_x8(buf0, buf0, 16); col_txfm(buf0, buf0, 13); shift_right_4_round_s16_x8(buf0, buf0, 16); for (int j = 0; j < 2; ++j) { transpose_arrays_s16_8x8(buf0 + j * 8, buf1 + j * 64 + 8 * i); } } for (int i = 0; i < 2; i++) { int16x8_t *buf = buf1 + 64 * i; row_txfm(buf, buf, 12); store_buffer_s16_x8(buf, output + 8 * i, 16, 32); } // Zero out the bottom 16x32 area. memset(output + 16 * 32, 0, 16 * 32 * sizeof(*output)); } static void lowbd_fwd_txfm2d_16x64_neon(const int16_t *input, int32_t *output, int stride, TX_TYPE tx_type, int bd) { (void)bd; (void)tx_type; assert(tx_type == DCT_DCT); int16x8_t buf0[64], buf1[128]; const transform_1d_lbd_8_neon col_txfm = fdct8x64_neon; const transform_1d_lbd_8_neon row_txfm = fdct8x16_neon; for (int i = 0; i < 2; i++) { load_buffer_s16_x8(input + 8 * i, stride, buf0, 64); col_txfm(buf0, buf0, 13); shift_right_2_round_s16_x8(buf0, buf0, 64); for (int j = 0; j < 8; ++j) { transpose_arrays_s16_8x8(buf0 + j * 8, buf1 + j * 16 + 8 * i); } } for (int i = 0; i < 4; i++) { int16x8_t *buf = buf1 + 16 * i; row_txfm(buf, buf, 12); store_buffer_s16_x8(buf, output + 8 * i, 32, 16); } } static void fdct32_neon(const int32x4_t *input, int32x4_t *output, int cos_bit) { const int16_t *cospi = cospi_arr_q13(cos_bit); const int16x8_t cospi32_16 = vld1q_s16(&cospi[4 * 0]); const int16x8_t cospi8_24 = vld1q_s16(&cospi[4 * 2]); const int16x8_t cospi4_12 = vld1q_s16(&cospi[4 * 4]); const int16x8_t cospi20_28 = vld1q_s16(&cospi[4 * 6]); const int16x8_t cospi2_6 = vld1q_s16(&cospi[4 * 8]); const int16x8_t cospi10_14 = vld1q_s16(&cospi[4 * 10]); const int16x8_t cospi18_22 = vld1q_s16(&cospi[4 * 12]); const int16x8_t cospi26_30 = vld1q_s16(&cospi[4 * 14]); const int16x4_t cospi32 = vget_low_s16(cospi32_16); const int16x4_t cospi16 = vget_high_s16(cospi32_16); const int16x4_t cospi8 = vget_low_s16(cospi8_24); const int16x4_t cospi24 = vget_high_s16(cospi8_24); const int16x4_t cospi4 = vget_low_s16(cospi4_12); const int16x4_t cospi12 = vget_high_s16(cospi4_12); const int16x4_t cospi20 = vget_low_s16(cospi20_28); const int16x4_t cospi28 = vget_high_s16(cospi20_28); const int16x4_t cospi2 = vget_low_s16(cospi2_6); const int16x4_t cospi6 = vget_high_s16(cospi2_6); const int16x4_t cospi10 = vget_low_s16(cospi10_14); const int16x4_t cospi14 = vget_high_s16(cospi10_14); const int16x4_t cospi18 = vget_low_s16(cospi18_22); const int16x4_t cospi22 = vget_high_s16(cospi18_22); const int16x4_t cospi26 = vget_low_s16(cospi26_30); const int16x4_t cospi30 = vget_high_s16(cospi26_30); int32x4_t buf0[32]; int32x4_t buf1[32]; // stage 1 butterfly_dct_pre_s32_x4(input, buf1, 32); // stage 2 butterfly_dct_pre_s32_x4(buf1, buf0, 16); buf0[16] = buf1[16]; buf0[17] = buf1[17]; buf0[18] = buf1[18]; buf0[19] = buf1[19]; butterfly_s32_s32_x4_0112_neon(cospi32, buf1[27], buf1[20], &buf0[27], &buf0[20]); butterfly_s32_s32_x4_0112_neon(cospi32, buf1[26], buf1[21], &buf0[26], &buf0[21]); butterfly_s32_s32_x4_0112_neon(cospi32, buf1[25], buf1[22], &buf0[25], &buf0[22]); butterfly_s32_s32_x4_0112_neon(cospi32, buf1[24], buf1[23], &buf0[24], &buf0[23]); buf0[28] = buf1[28]; buf0[29] = buf1[29]; buf0[30] = buf1[30]; buf0[31] = buf1[31]; // stage 3 butterfly_dct_pre_s32_x4(buf0, buf1, 8); buf1[8] = buf0[8]; buf1[9] = buf0[9]; butterfly_s32_s32_x4_0112_neon(cospi32, buf0[13], buf0[10], &buf1[13], &buf1[10]); butterfly_s32_s32_x4_0112_neon(cospi32, buf0[12], buf0[11], &buf1[12], &buf1[11]); buf1[14] = buf0[14]; buf1[15] = buf0[15]; butterfly_dct_post_s32_x4(buf0 + 16, buf0 + 16, buf1 + 16, 16); // stage 4 butterfly_dct_pre_s32_x4(buf1, buf0, 4); buf0[4] = buf1[4]; butterfly_s32_s32_x4_0112_neon(cospi32, buf1[6], buf1[5], &buf0[6], &buf0[5]); buf0[7] = buf1[7]; butterfly_dct_post_s32_x4(buf1 + 8, buf1 + 8, buf0 + 8, 8); buf0[16] = buf1[16]; buf0[17] = buf1[17]; butterfly_s32_s32_x4_0112_neon(cospi16, buf1[29], buf1[18], &buf0[29], &buf0[18]); butterfly_s32_s32_x4_0112_neon(cospi16, buf1[28], buf1[19], &buf0[28], &buf0[19]); butterfly_s32_s32_x4_1223_neon(cospi16, buf1[27], buf1[20], &buf0[27], &buf0[20]); butterfly_s32_s32_x4_1223_neon(cospi16, buf1[26], buf1[21], &buf0[26], &buf0[21]); buf0[22] = buf1[22]; buf0[23] = buf1[23]; buf0[24] = buf1[24]; buf0[25] = buf1[25]; buf0[30] = buf1[30]; buf0[31] = buf1[31]; // stage 5 butterfly_s32_s32_x4_0112_neon(cospi32, buf0[0], buf0[1], &buf1[0], &buf1[1]); butterfly_s32_s32_x4_0112_neon(cospi16, buf0[3], buf0[2], &buf1[2], &buf1[3]); butterfly_dct_post_s32_x4(buf0 + 4, buf0 + 4, buf1 + 4, 4); buf1[8] = buf0[8]; butterfly_s32_s32_x4_0112_neon(cospi16, buf0[14], buf0[9], &buf1[14], &buf1[9]); butterfly_s32_s32_x4_1223_neon(cospi16, buf0[13], buf0[10], &buf1[13], &buf1[10]); buf1[11] = buf0[11]; buf1[12] = buf0[12]; buf1[15] = buf0[15]; butterfly_dct_post_s32_x4(buf0 + 16, buf0 + 16, buf1 + 16, 8); butterfly_dct_post_s32_x4(buf0 + 24, buf0 + 24, buf1 + 24, 8); // stage 6 buf0[0] = buf1[0]; buf0[1] = buf1[1]; buf0[2] = buf1[2]; buf0[3] = buf1[3]; butterfly_s32_s32_x4_0112_neon(cospi8, buf1[7], buf1[4], &buf0[4], &buf0[7]); butterfly_s32_s32_x4_1003_neon(cospi24, buf1[6], buf1[5], &buf0[5], &buf0[6]); butterfly_dct_post_s32_x4(buf1 + 8, buf1 + 8, buf0 + 8, 4); butterfly_dct_post_s32_x4(buf1 + 12, buf1 + 12, buf0 + 12, 4); buf0[16] = buf1[16]; butterfly_s32_s32_x4_0112_neon(cospi8, buf1[30], buf1[17], &buf0[30], &buf0[17]); butterfly_s32_s32_x4_1223_neon(cospi8, buf1[29], buf1[18], &buf0[29], &buf0[18]); buf0[19] = buf1[19]; buf0[20] = buf1[20]; butterfly_s32_s32_x4_1003_neon(cospi24, buf1[26], buf1[21], &buf0[26], &buf0[21]); butterfly_s32_s32_x4_0332_neon(cospi24, buf1[25], buf1[22], &buf0[25], &buf0[22]); buf0[23] = buf1[23]; buf0[24] = buf1[24]; buf0[27] = buf1[27]; buf0[28] = buf1[28]; buf0[31] = buf1[31]; // stage 7 buf1[0] = buf0[0]; buf1[1] = buf0[1]; buf1[2] = buf0[2]; buf1[3] = buf0[3]; buf1[4] = buf0[4]; buf1[5] = buf0[5]; buf1[6] = buf0[6]; buf1[7] = buf0[7]; butterfly_s32_s32_x4_0112_neon(cospi4, buf0[15], buf0[8], &buf1[8], &buf1[15]); butterfly_s32_s32_x4_1003_neon(cospi28, buf0[14], buf0[9], &buf1[9], &buf1[14]); butterfly_s32_s32_x4_0112_neon(cospi20, buf0[13], buf0[10], &buf1[10], &buf1[13]); butterfly_s32_s32_x4_1003_neon(cospi12, buf0[12], buf0[11], &buf1[11], &buf1[12]); butterfly_dct_post_s32_x4(buf0 + 16, buf0 + 16, buf1 + 16, 4); butterfly_dct_post_s32_x4(buf0 + 20, buf0 + 20, buf1 + 20, 4); butterfly_dct_post_s32_x4(buf0 + 24, buf0 + 24, buf1 + 24, 4); butterfly_dct_post_s32_x4(buf0 + 28, buf0 + 28, buf1 + 28, 4); // stage 8 buf0[0] = buf1[0]; buf0[1] = buf1[1]; buf0[2] = buf1[2]; buf0[3] = buf1[3]; buf0[4] = buf1[4]; buf0[5] = buf1[5]; buf0[6] = buf1[6]; buf0[7] = buf1[7]; buf0[8] = buf1[8]; buf0[9] = buf1[9]; buf0[10] = buf1[10]; buf0[11] = buf1[11]; buf0[12] = buf1[12]; buf0[13] = buf1[13]; buf0[14] = buf1[14]; buf0[15] = buf1[15]; butterfly_s32_s32_x4_0112_neon(cospi2, buf1[31], buf1[16], &buf0[16], &buf0[31]); butterfly_s32_s32_x4_1003_neon(cospi30, buf1[30], buf1[17], &buf0[17], &buf0[30]); butterfly_s32_s32_x4_0112_neon(cospi18, buf1[29], buf1[18], &buf0[18], &buf0[29]); butterfly_s32_s32_x4_1003_neon(cospi14, buf1[28], buf1[19], &buf0[19], &buf0[28]); butterfly_s32_s32_x4_0112_neon(cospi10, buf1[27], buf1[20], &buf0[20], &buf0[27]); butterfly_s32_s32_x4_1003_neon(cospi22, buf1[26], buf1[21], &buf0[21], &buf0[26]); butterfly_s32_s32_x4_0112_neon(cospi26, buf1[25], buf1[22], &buf0[22], &buf0[25]); butterfly_s32_s32_x4_1003_neon(cospi6, buf1[24], buf1[23], &buf0[23], &buf0[24]); // stage 9 output[0] = buf0[0]; output[1] = buf0[16]; output[2] = buf0[8]; output[3] = buf0[24]; output[4] = buf0[4]; output[5] = buf0[20]; output[6] = buf0[12]; output[7] = buf0[28]; output[8] = buf0[2]; output[9] = buf0[18]; output[10] = buf0[10]; output[11] = buf0[26]; output[12] = buf0[6]; output[13] = buf0[22]; output[14] = buf0[14]; output[15] = buf0[30]; output[16] = buf0[1]; output[17] = buf0[17]; output[18] = buf0[9]; output[19] = buf0[25]; output[20] = buf0[5]; output[21] = buf0[21]; output[22] = buf0[13]; output[23] = buf0[29]; output[24] = buf0[3]; output[25] = buf0[19]; output[26] = buf0[11]; output[27] = buf0[27]; output[28] = buf0[7]; output[29] = buf0[23]; output[30] = buf0[15]; output[31] = buf0[31]; } static void fdct64_neon(const int32x4_t *input, int32x4_t *output, int cos_bit) { const int16_t *cospi = cospi_arr_q13(cos_bit); const int16x8_t cospi32_16 = vld1q_s16(&cospi[4 * 0]); const int16x8_t cospi8_24 = vld1q_s16(&cospi[4 * 2]); const int16x8_t cospi4_12 = vld1q_s16(&cospi[4 * 4]); const int16x8_t cospi20_28 = vld1q_s16(&cospi[4 * 6]); const int16x8_t cospi2_6 = vld1q_s16(&cospi[4 * 8]); const int16x8_t cospi10_14 = vld1q_s16(&cospi[4 * 10]); const int16x8_t cospi18_22 = vld1q_s16(&cospi[4 * 12]); const int16x8_t cospi26_30 = vld1q_s16(&cospi[4 * 14]); const int16x8_t cospi1_3 = vld1q_s16(&cospi[4 * 16]); const int16x8_t cospi5_7 = vld1q_s16(&cospi[4 * 18]); const int16x8_t cospi9_11 = vld1q_s16(&cospi[4 * 20]); const int16x8_t cospi13_15 = vld1q_s16(&cospi[4 * 22]); const int16x8_t cospi17_19 = vld1q_s16(&cospi[4 * 24]); const int16x8_t cospi21_23 = vld1q_s16(&cospi[4 * 26]); const int16x8_t cospi25_27 = vld1q_s16(&cospi[4 * 28]); const int16x8_t cospi29_31 = vld1q_s16(&cospi[4 * 30]); const int16x4_t cospi32 = vget_low_s16(cospi32_16); const int16x4_t cospi16 = vget_high_s16(cospi32_16); const int16x4_t cospi8 = vget_low_s16(cospi8_24); const int16x4_t cospi24 = vget_high_s16(cospi8_24); const int16x4_t cospi4 = vget_low_s16(cospi4_12); const int16x4_t cospi12 = vget_high_s16(cospi4_12); const int16x4_t cospi20 = vget_low_s16(cospi20_28); const int16x4_t cospi28 = vget_high_s16(cospi20_28); const int16x4_t cospi2 = vget_low_s16(cospi2_6); const int16x4_t cospi6 = vget_high_s16(cospi2_6); const int16x4_t cospi10 = vget_low_s16(cospi10_14); const int16x4_t cospi14 = vget_high_s16(cospi10_14); const int16x4_t cospi18 = vget_low_s16(cospi18_22); const int16x4_t cospi22 = vget_high_s16(cospi18_22); const int16x4_t cospi26 = vget_low_s16(cospi26_30); const int16x4_t cospi30 = vget_high_s16(cospi26_30); const int16x4_t cospi1 = vget_low_s16(cospi1_3); const int16x4_t cospi3 = vget_high_s16(cospi1_3); const int16x4_t cospi5 = vget_low_s16(cospi5_7); const int16x4_t cospi7 = vget_high_s16(cospi5_7); const int16x4_t cospi9 = vget_low_s16(cospi9_11); const int16x4_t cospi11 = vget_high_s16(cospi9_11); const int16x4_t cospi13 = vget_low_s16(cospi13_15); const int16x4_t cospi15 = vget_high_s16(cospi13_15); const int16x4_t cospi17 = vget_low_s16(cospi17_19); const int16x4_t cospi19 = vget_high_s16(cospi17_19); const int16x4_t cospi21 = vget_low_s16(cospi21_23); const int16x4_t cospi23 = vget_high_s16(cospi21_23); const int16x4_t cospi25 = vget_low_s16(cospi25_27); const int16x4_t cospi27 = vget_high_s16(cospi25_27); const int16x4_t cospi29 = vget_low_s16(cospi29_31); const int16x4_t cospi31 = vget_high_s16(cospi29_31); // stage 1 int32x4_t x1[64]; butterfly_dct_pre_s32_x4(input, x1, 64); // stage 2 int32x4_t x2[64]; butterfly_dct_pre_s32_x4(x1, x2, 32); butterfly_s32_s32_x4_0112_neon(cospi32, x1[55], x1[40], &x2[55], &x2[40]); butterfly_s32_s32_x4_0112_neon(cospi32, x1[54], x1[41], &x2[54], &x2[41]); butterfly_s32_s32_x4_0112_neon(cospi32, x1[53], x1[42], &x2[53], &x2[42]); butterfly_s32_s32_x4_0112_neon(cospi32, x1[52], x1[43], &x2[52], &x2[43]); butterfly_s32_s32_x4_0112_neon(cospi32, x1[51], x1[44], &x2[51], &x2[44]); butterfly_s32_s32_x4_0112_neon(cospi32, x1[50], x1[45], &x2[50], &x2[45]); butterfly_s32_s32_x4_0112_neon(cospi32, x1[49], x1[46], &x2[49], &x2[46]); butterfly_s32_s32_x4_0112_neon(cospi32, x1[48], x1[47], &x2[48], &x2[47]); // stage 3 int32x4_t x3[64]; butterfly_dct_pre_s32_x4(x2, x3, 16); butterfly_s32_s32_x4_0112_neon(cospi32, x2[27], x2[20], &x3[27], &x3[20]); butterfly_s32_s32_x4_0112_neon(cospi32, x2[26], x2[21], &x3[26], &x3[21]); butterfly_s32_s32_x4_0112_neon(cospi32, x2[25], x2[22], &x3[25], &x3[22]); butterfly_s32_s32_x4_0112_neon(cospi32, x2[24], x2[23], &x3[24], &x3[23]); butterfly_dct_post_s32_x4(x1 + 32, x2 + 32, x3 + 32, 32); // stage 4 int32x4_t x4[64]; butterfly_dct_pre_s32_x4(x3, x4, 8); butterfly_s32_s32_x4_0112_neon(cospi32, x3[13], x3[10], &x4[13], &x4[10]); butterfly_s32_s32_x4_0112_neon(cospi32, x3[12], x3[11], &x4[12], &x4[11]); butterfly_dct_post_s32_x4(x2 + 16, x3 + 16, x4 + 16, 16); butterfly_s32_s32_x4_0112_neon(cospi16, x3[59], x3[36], &x4[59], &x4[36]); butterfly_s32_s32_x4_0112_neon(cospi16, x3[58], x3[37], &x4[58], &x4[37]); butterfly_s32_s32_x4_0112_neon(cospi16, x3[57], x3[38], &x4[57], &x4[38]); butterfly_s32_s32_x4_0112_neon(cospi16, x3[56], x3[39], &x4[56], &x4[39]); butterfly_s32_s32_x4_1223_neon(cospi16, x3[55], x3[40], &x4[55], &x4[40]); butterfly_s32_s32_x4_1223_neon(cospi16, x3[54], x3[41], &x4[54], &x4[41]); butterfly_s32_s32_x4_1223_neon(cospi16, x3[53], x3[42], &x4[53], &x4[42]); butterfly_s32_s32_x4_1223_neon(cospi16, x3[52], x3[43], &x4[52], &x4[43]); // stage 5 int32x4_t x5[64]; butterfly_dct_pre_s32_x4(x4, x5, 4); butterfly_s32_s32_x4_0112_neon(cospi32, x4[6], x4[5], &x5[6], &x5[5]); butterfly_dct_post_s32_x4(x3 + 8, x4 + 8, x5 + 8, 8); butterfly_s32_s32_x4_0112_neon(cospi16, x4[29], x4[18], &x5[29], &x5[18]); butterfly_s32_s32_x4_0112_neon(cospi16, x4[28], x4[19], &x5[28], &x5[19]); butterfly_s32_s32_x4_1223_neon(cospi16, x4[27], x4[20], &x5[27], &x5[20]); butterfly_s32_s32_x4_1223_neon(cospi16, x4[26], x4[21], &x5[26], &x5[21]); butterfly_dct_post_s32_x4(x3 + 32, x4 + 32, x5 + 32, 16); butterfly_dct_post_s32_x4(x3 + 48, x4 + 48, x5 + 48, 16); // stage 6 int32x4_t x6[64]; butterfly_s32_s32_x4_0112_neon(cospi32, x5[0], x5[1], &x6[0], &x6[1]); butterfly_s32_s32_x4_0112_neon(cospi16, x5[3], x5[2], &x6[2], &x6[3]); butterfly_dct_post_s32_x4(x4 + 4, x5 + 4, x6 + 4, 4); butterfly_s32_s32_x4_0112_neon(cospi16, x5[14], x5[9], &x6[14], &x6[9]); butterfly_s32_s32_x4_1223_neon(cospi16, x5[13], x5[10], &x6[13], &x6[10]); butterfly_dct_post_s32_x4(x4 + 16, x5 + 16, x6 + 16, 8); butterfly_dct_post_s32_x4(x4 + 24, x5 + 24, x6 + 24, 8); butterfly_s32_s32_x4_0112_neon(cospi8, x5[61], x5[34], &x6[61], &x6[34]); butterfly_s32_s32_x4_0112_neon(cospi8, x5[60], x5[35], &x6[60], &x6[35]); butterfly_s32_s32_x4_1223_neon(cospi8, x5[59], x5[36], &x6[59], &x6[36]); butterfly_s32_s32_x4_1223_neon(cospi8, x5[58], x5[37], &x6[58], &x6[37]); butterfly_s32_s32_x4_1003_neon(cospi24, x5[53], x5[42], &x6[53], &x6[42]); butterfly_s32_s32_x4_1003_neon(cospi24, x5[52], x5[43], &x6[52], &x6[43]); butterfly_s32_s32_x4_0332_neon(cospi24, x5[51], x5[44], &x6[51], &x6[44]); butterfly_s32_s32_x4_0332_neon(cospi24, x5[50], x5[45], &x6[50], &x6[45]); // stage 7 int32x4_t x7[64]; butterfly_s32_s32_x4_0112_neon(cospi8, x6[7], x6[4], &x7[4], &x7[7]); butterfly_s32_s32_x4_1003_neon(cospi24, x6[6], x6[5], &x7[5], &x7[6]); butterfly_dct_post_s32_x4(x5 + 8, x6 + 8, x7 + 8, 4); butterfly_dct_post_s32_x4(x5 + 12, x6 + 12, x7 + 12, 4); butterfly_s32_s32_x4_0112_neon(cospi8, x6[30], x6[17], &x7[30], &x7[17]); butterfly_s32_s32_x4_1223_neon(cospi8, x6[29], x6[18], &x7[29], &x7[18]); butterfly_s32_s32_x4_1003_neon(cospi24, x6[26], x6[21], &x7[26], &x7[21]); butterfly_s32_s32_x4_0332_neon(cospi24, x6[25], x6[22], &x7[25], &x7[22]); butterfly_dct_post_s32_x4(x5 + 32, x6 + 32, x7 + 32, 8); butterfly_dct_post_s32_x4(x5 + 40, x6 + 40, x7 + 40, 8); butterfly_dct_post_s32_x4(x5 + 48, x6 + 48, x7 + 48, 8); butterfly_dct_post_s32_x4(x5 + 56, x6 + 56, x7 + 56, 8); // stage 8 int32x4_t x8[64]; butterfly_s32_s32_x4_0112_neon(cospi4, x7[15], x7[8], &x8[8], &x8[15]); butterfly_s32_s32_x4_1003_neon(cospi28, x7[14], x7[9], &x8[9], &x8[14]); butterfly_s32_s32_x4_0112_neon(cospi20, x7[13], x7[10], &x8[10], &x8[13]); butterfly_s32_s32_x4_1003_neon(cospi12, x7[12], x7[11], &x8[11], &x8[12]); butterfly_dct_post_s32_x4(x6 + 16, x7 + 16, x8 + 16, 4); butterfly_dct_post_s32_x4(x6 + 20, x7 + 20, x8 + 20, 4); butterfly_dct_post_s32_x4(x6 + 24, x7 + 24, x8 + 24, 4); butterfly_dct_post_s32_x4(x6 + 28, x7 + 28, x8 + 28, 4); butterfly_s32_s32_x4_0112_neon(cospi4, x7[62], x7[33], &x8[62], &x8[33]); butterfly_s32_s32_x4_1223_neon(cospi4, x7[61], x7[34], &x8[61], &x8[34]); butterfly_s32_s32_x4_1003_neon(cospi28, x7[58], x7[37], &x8[58], &x8[37]); butterfly_s32_s32_x4_0332_neon(cospi28, x7[57], x7[38], &x8[57], &x8[38]); butterfly_s32_s32_x4_0112_neon(cospi20, x7[54], x7[41], &x8[54], &x8[41]); butterfly_s32_s32_x4_1223_neon(cospi20, x7[53], x7[42], &x8[53], &x8[42]); butterfly_s32_s32_x4_1003_neon(cospi12, x7[50], x7[45], &x8[50], &x8[45]); butterfly_s32_s32_x4_0332_neon(cospi12, x7[49], x7[46], &x8[49], &x8[46]); // stage 9 int32x4_t x9[64]; butterfly_s32_s32_x4_0112_neon(cospi2, x8[31], x8[16], &x9[16], &x9[31]); butterfly_s32_s32_x4_1003_neon(cospi30, x8[30], x8[17], &x9[17], &x9[30]); butterfly_s32_s32_x4_0112_neon(cospi18, x8[29], x8[18], &x9[18], &x9[29]); butterfly_s32_s32_x4_1003_neon(cospi14, x8[28], x8[19], &x9[19], &x9[28]); butterfly_s32_s32_x4_0112_neon(cospi10, x8[27], x8[20], &x9[20], &x9[27]); butterfly_s32_s32_x4_1003_neon(cospi22, x8[26], x8[21], &x9[21], &x9[26]); butterfly_s32_s32_x4_0112_neon(cospi26, x8[25], x8[22], &x9[22], &x9[25]); butterfly_s32_s32_x4_1003_neon(cospi6, x8[24], x8[23], &x9[23], &x9[24]); butterfly_dct_post_s32_x4(x7 + 32, x8 + 32, x9 + 32, 4); butterfly_dct_post_s32_x4(x7 + 36, x8 + 36, x9 + 36, 4); butterfly_dct_post_s32_x4(x7 + 40, x8 + 40, x9 + 40, 4); butterfly_dct_post_s32_x4(x7 + 44, x8 + 44, x9 + 44, 4); butterfly_dct_post_s32_x4(x7 + 48, x8 + 48, x9 + 48, 4); butterfly_dct_post_s32_x4(x7 + 52, x8 + 52, x9 + 52, 4); butterfly_dct_post_s32_x4(x7 + 56, x8 + 56, x9 + 56, 4); butterfly_dct_post_s32_x4(x7 + 60, x8 + 60, x9 + 60, 4); // stage 10 int32x4_t x10[64]; butterfly_s32_s32_x4_0112_neon(cospi1, x9[63], x9[32], &x10[32], &x10[63]); butterfly_s32_s32_x4_1003_neon(cospi31, x9[62], x9[33], &x10[33], &x10[62]); butterfly_s32_s32_x4_0112_neon(cospi17, x9[61], x9[34], &x10[34], &x10[61]); butterfly_s32_s32_x4_1003_neon(cospi15, x9[60], x9[35], &x10[35], &x10[60]); butterfly_s32_s32_x4_0112_neon(cospi9, x9[59], x9[36], &x10[36], &x10[59]); butterfly_s32_s32_x4_1003_neon(cospi23, x9[58], x9[37], &x10[37], &x10[58]); butterfly_s32_s32_x4_0112_neon(cospi25, x9[57], x9[38], &x10[38], &x10[57]); butterfly_s32_s32_x4_1003_neon(cospi7, x9[56], x9[39], &x10[39], &x10[56]); butterfly_s32_s32_x4_0112_neon(cospi5, x9[55], x9[40], &x10[40], &x10[55]); butterfly_s32_s32_x4_1003_neon(cospi27, x9[54], x9[41], &x10[41], &x10[54]); butterfly_s32_s32_x4_0112_neon(cospi21, x9[53], x9[42], &x10[42], &x10[53]); butterfly_s32_s32_x4_1003_neon(cospi11, x9[52], x9[43], &x10[43], &x10[52]); butterfly_s32_s32_x4_0112_neon(cospi13, x9[51], x9[44], &x10[44], &x10[51]); butterfly_s32_s32_x4_1003_neon(cospi19, x9[50], x9[45], &x10[45], &x10[50]); butterfly_s32_s32_x4_0112_neon(cospi29, x9[49], x9[46], &x10[46], &x10[49]); butterfly_s32_s32_x4_1003_neon(cospi3, x9[48], x9[47], &x10[47], &x10[48]); // stage 11, only store into the low 32 output indices. output[0] = x6[0]; output[1] = x10[32]; output[2] = x9[16]; output[3] = x10[48]; output[4] = x8[8]; output[5] = x10[40]; output[6] = x9[24]; output[7] = x10[56]; output[8] = x7[4]; output[9] = x10[36]; output[10] = x9[20]; output[11] = x10[52]; output[12] = x8[12]; output[13] = x10[44]; output[14] = x9[28]; output[15] = x10[60]; output[16] = x6[2]; output[17] = x10[34]; output[18] = x9[18]; output[19] = x10[50]; output[20] = x8[10]; output[21] = x10[42]; output[22] = x9[26]; output[23] = x10[58]; output[24] = x7[6]; output[25] = x10[38]; output[26] = x9[22]; output[27] = x10[54]; output[28] = x8[14]; output[29] = x10[46]; output[30] = x9[30]; output[31] = x10[62]; } static void lowbd_fwd_txfm2d_64x64_neon(const int16_t *input, int32_t *output, int stride, TX_TYPE tx_type, int bd) { (void)bd; (void)tx_type; assert(tx_type == DCT_DCT); int16x8_t buf0[64], buf1[512]; const transform_1d_lbd_8_neon col_txfm = fdct8x64_neon; for (int i = 0; i < 8; i++) { load_buffer_s16_x8(input + 8 * i, stride, buf0, 64); col_txfm(buf0, buf0, 13); shift_right_2_round_s16_x8(buf0, buf0, 64); for (int j = 0; j < 4; ++j) { transpose_arrays_s16_8x8(buf0 + j * 8, buf1 + j * 64 + 8 * i); } } for (int i = 0; i < 4; i++) { int32x4_t bufA[64]; int32x4_t bufB[64]; int16x8_t *buf = buf1 + 64 * i; for (int j = 0; j < 64; ++j) { bufA[j] = vmovl_s16(vget_low_s16(buf[j])); bufB[j] = vmovl_s16(vget_high_s16(buf[j])); } fdct64_neon(bufA, bufA, 10); fdct64_neon(bufB, bufB, 10); shift_right_2_round_s32_x4(bufA, bufA, 32); shift_right_2_round_s32_x4(bufB, bufB, 32); store_buffer_interleaved_s32_x8(output + i * 8, bufA, bufB, 32, 32); } } static void lowbd_fwd_txfm2d_64x32_neon(const int16_t *input, int32_t *output, int stride, TX_TYPE tx_type, int bd) { (void)bd; int16x8_t buf0[64], buf1[256]; const col_transform_1d_lbd_8_neon col_txfm = col_txfm8x32_arr[tx_type]; for (int i = 0; i < 8; i++) { col_txfm(input + 8 * i, buf0, stride, 12); shift_right_4_round_s16_x8(buf0, buf0, 32); for (int j = 0; j < 4; ++j) { transpose_arrays_s16_8x8(buf0 + j * 8, buf1 + j * 64 + 8 * i); } } assert(tx_type == DCT_DCT); for (int i = 0; i < 4; i++) { int32x4_t bufA[64]; int32x4_t bufB[64]; int16x8_t *buf = buf1 + 64 * i; for (int j = 0; j < 64; ++j) { bufA[j] = vmovl_s16(vget_low_s16(buf[j])); bufB[j] = vmovl_s16(vget_high_s16(buf[j])); } fdct64_neon(bufA, bufA, 11); fdct64_neon(bufB, bufB, 11); shift_right_2_round_s32_x4(bufA, bufA, 32); shift_right_2_round_s32_x4(bufB, bufB, 32); round_shift_sqrt2_s32_s32_4xn_neon(bufA, bufA, 32); round_shift_sqrt2_s32_s32_4xn_neon(bufB, bufB, 32); store_buffer_interleaved_s32_x8(output + i * 8, bufA, bufB, 32, 32); } } static void lowbd_fwd_txfm2d_32x64_neon(const int16_t *input, int32_t *output, int stride, TX_TYPE tx_type, int bd) { (void)bd; (void)tx_type; assert(tx_type == DCT_DCT); int16x8_t buf0[64], buf1[256]; const transform_1d_lbd_8_neon col_txfm = fdct8x64_neon; for (int i = 0; i < 4; i++) { load_buffer_s16_x8(input + 8 * i, stride, buf0, 64); col_txfm(buf0, buf0, 13); shift_right_2_round_s16_x8(buf0, buf0, 64); for (int j = 0; j < 4; ++j) { transpose_arrays_s16_8x8(buf0 + j * 8, buf1 + j * 32 + 8 * i); } } for (int i = 0; i < 4; i++) { int32x4_t bufA[32]; int32x4_t bufB[32]; int16x8_t *buf = buf1 + 32 * i; for (int j = 0; j < 32; ++j) { bufA[j] = vmovl_s16(vget_low_s16(buf[j])); bufB[j] = vmovl_s16(vget_high_s16(buf[j])); } fdct32_neon(bufA, bufA, 11); fdct32_neon(bufB, bufB, 11); shift_right_2_round_s32_x4(bufA, bufA, 32); shift_right_2_round_s32_x4(bufB, bufB, 32); round_shift_sqrt2_s32_s32_4xn_neon(bufA, bufA, 32); round_shift_sqrt2_s32_s32_4xn_neon(bufB, bufB, 32); store_buffer_interleaved_s32_x8(output + i * 8, bufA, bufB, 32, 32); } } static FwdTxfm2dFunc lowbd_fwd_txfm_func_ls[TX_SIZES_ALL] = { lowbd_fwd_txfm2d_4x4_neon, // 4x4 transform lowbd_fwd_txfm2d_8x8_neon, // 8x8 transform lowbd_fwd_txfm2d_16x16_neon, // 16x16 transform lowbd_fwd_txfm2d_32x32_neon, // 32x32 transform lowbd_fwd_txfm2d_64x64_neon, // 64x64 transform lowbd_fwd_txfm2d_4x8_neon, // 4x8 transform lowbd_fwd_txfm2d_8x4_neon, // 8x4 transform lowbd_fwd_txfm2d_8x16_neon, // 8x16 transform lowbd_fwd_txfm2d_16x8_neon, // 16x8 transform lowbd_fwd_txfm2d_16x32_neon, // 16x32 transform lowbd_fwd_txfm2d_32x16_neon, // 32x16 transform lowbd_fwd_txfm2d_32x64_neon, // 32x64 transform lowbd_fwd_txfm2d_64x32_neon, // 64x32 transform lowbd_fwd_txfm2d_4x16_neon, // 4x16 transform lowbd_fwd_txfm2d_16x4_neon, // 16x4 transform lowbd_fwd_txfm2d_8x32_neon, // 8x32 transform lowbd_fwd_txfm2d_32x8_neon, // 32x8 transform lowbd_fwd_txfm2d_16x64_neon, // 16x64 transform lowbd_fwd_txfm2d_64x16_neon, // 64x16 transform }; void av1_lowbd_fwd_txfm_neon(const int16_t *src_diff, tran_low_t *coeff, int diff_stride, TxfmParam *txfm_param) { FwdTxfm2dFunc fwd_txfm2d_func = lowbd_fwd_txfm_func_ls[txfm_param->tx_size]; if (txfm_param->lossless && txfm_param->tx_size == TX_4X4) { av1_lowbd_fwd_txfm_c(src_diff, coeff, diff_stride, txfm_param); } else { fwd_txfm2d_func(src_diff, coeff, diff_stride, txfm_param->tx_type, txfm_param->bd); } }