303 lines
8.0 KiB
C
303 lines
8.0 KiB
C
/*
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FreeRDP: A Remote Desktop Protocol Implementation
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RemoteFX Codec Library - NEON Optimizations
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Copyright 2011 Martin Fleisz <mfleisz@thinstuff.com>
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Licensed under the Apache License, Version 2.0 (the "License");
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you may not use this file except in compliance with the License.
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You may obtain a copy of the License at
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http://www.apache.org/licenses/LICENSE-2.0
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Unless required by applicable law or agreed to in writing, software
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distributed under the License is distributed on an "AS IS" BASIS,
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WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
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See the License for the specific language governing permissions and
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limitations under the License.
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*/
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#ifdef HAVE_CONFIG_H
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#include "config.h"
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#endif
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#if defined(__ARM_NEON__)
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#include <stdio.h>
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#include <stdlib.h>
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#include <string.h>
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#include <arm_neon.h>
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#include "rfx_types.h"
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#include "rfx_neon.h"
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#if ANDROID
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#include "cpu-features.h"
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#endif
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/* rfx_decode_YCbCr_to_RGB_NEON code now resides in the primitives library. */
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static __inline void __attribute__((__gnu_inline__, __always_inline__, __artificial__))
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rfx_quantization_decode_block_NEON(INT16 * buffer, const int buffer_size, const UINT32 factor)
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{
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if (factor <= 6)
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return;
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int16x8_t quantFactors = vdupq_n_s16(factor - 6);
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int16x8_t* buf = (int16x8_t*)buffer;
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int16x8_t* buf_end = (int16x8_t*)(buffer + buffer_size);
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do
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{
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int16x8_t val = vld1q_s16((INT16*)buf);
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val = vshlq_s16(val, quantFactors);
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vst1q_s16((INT16*)buf, val);
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buf++;
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}
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while(buf < buf_end);
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}
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void
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rfx_quantization_decode_NEON(INT16 * buffer, const UINT32 * quantization_values)
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{
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rfx_quantization_decode_block_NEON(buffer, 1024, quantization_values[8]); /* HL1 */
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rfx_quantization_decode_block_NEON(buffer + 1024, 1024, quantization_values[7]); /* LH1 */
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rfx_quantization_decode_block_NEON(buffer + 2048, 1024, quantization_values[9]); /* HH1 */
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rfx_quantization_decode_block_NEON(buffer + 3072, 256, quantization_values[5]); /* HL2 */
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rfx_quantization_decode_block_NEON(buffer + 3328, 256, quantization_values[4]); /* LH2 */
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rfx_quantization_decode_block_NEON(buffer + 3584, 256, quantization_values[6]); /* HH2 */
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rfx_quantization_decode_block_NEON(buffer + 3840, 64, quantization_values[2]); /* HL3 */
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rfx_quantization_decode_block_NEON(buffer + 3904, 64, quantization_values[1]); /* LH3 */
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rfx_quantization_decode_block_NEON(buffer + 3968, 64, quantization_values[3]); /* HH3 */
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rfx_quantization_decode_block_NEON(buffer + 4032, 64, quantization_values[0]); /* LL3 */
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}
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static __inline void __attribute__((__gnu_inline__, __always_inline__, __artificial__))
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rfx_dwt_2d_decode_block_horiz_NEON(INT16 * l, INT16 * h, INT16 * dst, int subband_width)
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{
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int y, n;
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INT16 * l_ptr = l;
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INT16 * h_ptr = h;
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INT16 * dst_ptr = dst;
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for (y = 0; y < subband_width; y++)
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{
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/* Even coefficients */
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for (n = 0; n < subband_width; n+=8)
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{
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// dst[2n] = l[n] - ((h[n-1] + h[n] + 1) >> 1);
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int16x8_t l_n = vld1q_s16(l_ptr);
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int16x8_t h_n = vld1q_s16(h_ptr);
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int16x8_t h_n_m = vld1q_s16(h_ptr - 1);
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if (n == 0)
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{
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int16_t first = vgetq_lane_s16(h_n_m, 1);
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h_n_m = vsetq_lane_s16(first, h_n_m, 0);
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}
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int16x8_t tmp_n = vaddq_s16(h_n, h_n_m);
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tmp_n = vaddq_s16(tmp_n, vdupq_n_s16(1));
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tmp_n = vshrq_n_s16(tmp_n, 1);
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int16x8_t dst_n = vsubq_s16(l_n, tmp_n);
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vst1q_s16(l_ptr, dst_n);
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l_ptr+=8;
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h_ptr+=8;
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}
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l_ptr -= subband_width;
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h_ptr -= subband_width;
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/* Odd coefficients */
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for (n = 0; n < subband_width; n+=8)
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{
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// dst[2n + 1] = (h[n] << 1) + ((dst[2n] + dst[2n + 2]) >> 1);
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int16x8_t h_n = vld1q_s16(h_ptr);
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h_n = vshlq_n_s16(h_n, 1);
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int16x8x2_t dst_n;
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dst_n.val[0] = vld1q_s16(l_ptr);
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int16x8_t dst_n_p = vld1q_s16(l_ptr + 1);
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if (n == subband_width - 8)
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{
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int16_t last = vgetq_lane_s16(dst_n_p, 6);
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dst_n_p = vsetq_lane_s16(last, dst_n_p, 7);
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}
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dst_n.val[1] = vaddq_s16(dst_n_p, dst_n.val[0]);
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dst_n.val[1] = vshrq_n_s16(dst_n.val[1], 1);
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dst_n.val[1] = vaddq_s16(dst_n.val[1], h_n);
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vst2q_s16(dst_ptr, dst_n);
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l_ptr+=8;
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h_ptr+=8;
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dst_ptr+=16;
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}
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}
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}
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static __inline void __attribute__((__gnu_inline__, __always_inline__, __artificial__))
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rfx_dwt_2d_decode_block_vert_NEON(INT16 * l, INT16 * h, INT16 * dst, int subband_width)
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{
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int x, n;
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INT16 * l_ptr = l;
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INT16 * h_ptr = h;
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INT16 * dst_ptr = dst;
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int total_width = subband_width + subband_width;
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/* Even coefficients */
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for (n = 0; n < subband_width; n++)
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{
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for (x = 0; x < total_width; x+=8)
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{
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// dst[2n] = l[n] - ((h[n-1] + h[n] + 1) >> 1);
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int16x8_t l_n = vld1q_s16(l_ptr);
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int16x8_t h_n = vld1q_s16(h_ptr);
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int16x8_t tmp_n = vaddq_s16(h_n, vdupq_n_s16(1));;
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if (n == 0)
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tmp_n = vaddq_s16(tmp_n, h_n);
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else
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{
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int16x8_t h_n_m = vld1q_s16((h_ptr - total_width));
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tmp_n = vaddq_s16(tmp_n, h_n_m);
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}
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tmp_n = vshrq_n_s16(tmp_n, 1);
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int16x8_t dst_n = vsubq_s16(l_n, tmp_n);
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vst1q_s16(dst_ptr, dst_n);
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l_ptr+=8;
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h_ptr+=8;
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dst_ptr+=8;
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}
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dst_ptr+=total_width;
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}
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h_ptr = h;
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dst_ptr = dst + total_width;
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/* Odd coefficients */
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for (n = 0; n < subband_width; n++)
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{
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for (x = 0; x < total_width; x+=8)
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{
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// dst[2n + 1] = (h[n] << 1) + ((dst[2n] + dst[2n + 2]) >> 1);
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int16x8_t h_n = vld1q_s16(h_ptr);
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int16x8_t dst_n_m = vld1q_s16(dst_ptr - total_width);
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h_n = vshlq_n_s16(h_n, 1);
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int16x8_t tmp_n = dst_n_m;
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if (n == subband_width - 1)
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tmp_n = vaddq_s16(tmp_n, dst_n_m);
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else
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{
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int16x8_t dst_n_p = vld1q_s16((dst_ptr + total_width));
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tmp_n = vaddq_s16(tmp_n, dst_n_p);
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}
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tmp_n = vshrq_n_s16(tmp_n, 1);
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int16x8_t dst_n = vaddq_s16(tmp_n, h_n);
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vst1q_s16(dst_ptr, dst_n);
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h_ptr+=8;
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dst_ptr+=8;
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}
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dst_ptr+=total_width;
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}
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}
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static __inline void __attribute__((__gnu_inline__, __always_inline__, __artificial__))
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rfx_dwt_2d_decode_block_NEON(INT16 * buffer, INT16 * idwt, int subband_width)
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{
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INT16 * hl, * lh, * hh, * ll;
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INT16 * l_dst, * h_dst;
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/* Inverse DWT in horizontal direction, results in 2 sub-bands in L, H order in tmp buffer idwt. */
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/* The 4 sub-bands are stored in HL(0), LH(1), HH(2), LL(3) order. */
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/* The lower part L uses LL(3) and HL(0). */
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/* The higher part H uses LH(1) and HH(2). */
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ll = buffer + subband_width * subband_width * 3;
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hl = buffer;
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l_dst = idwt;
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rfx_dwt_2d_decode_block_horiz_NEON(ll, hl, l_dst, subband_width);
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lh = buffer + subband_width * subband_width;
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hh = buffer + subband_width * subband_width * 2;
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h_dst = idwt + subband_width * subband_width * 2;
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rfx_dwt_2d_decode_block_horiz_NEON(lh, hh, h_dst, subband_width);
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/* Inverse DWT in vertical direction, results are stored in original buffer. */
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rfx_dwt_2d_decode_block_vert_NEON(l_dst, h_dst, buffer, subband_width);
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}
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void rfx_dwt_2d_decode_NEON(INT16 * buffer, INT16 * dwt_buffer)
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{
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rfx_dwt_2d_decode_block_NEON(buffer + 3840, dwt_buffer, 8);
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rfx_dwt_2d_decode_block_NEON(buffer + 3072, dwt_buffer, 16);
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rfx_dwt_2d_decode_block_NEON(buffer, dwt_buffer, 32);
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}
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int isNeonSupported()
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{
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#if ANDROID
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if (android_getCpuFamily() != ANDROID_CPU_FAMILY_ARM)
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{
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DEBUG_RFX("NEON optimization disabled - No ARM CPU found");
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return 0;
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}
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UINT64 features = android_getCpuFeatures();
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if ((features & ANDROID_CPU_ARM_FEATURE_ARMv7))
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{
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if (features & ANDROID_CPU_ARM_FEATURE_NEON)
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{
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DEBUG_RFX("NEON optimization enabled!");
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return FALSE;
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}
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DEBUG_RFX("NEON optimization disabled - CPU not NEON capable");
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}
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else
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{
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DEBUG_RFX("NEON optimization disabled - No ARMv7 CPU found");
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}
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return FALSE;
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#else
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return TRUE;
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#endif
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}
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void rfx_init_neon(RFX_CONTEXT * context)
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{
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if (isNeonSupported())
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{
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DEBUG_RFX("Using NEON optimizations");
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IF_PROFILER(context->priv->prof_rfx_ycbcr_to_rgb->name = "rfx_decode_YCbCr_to_RGB_NEON");
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IF_PROFILER(context->priv->prof_rfx_quantization_decode->name = "rfx_quantization_decode_NEON");
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IF_PROFILER(context->priv->prof_rfx_dwt_2d_decode->name = "rfx_dwt_2d_decode_NEON");
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context->quantization_decode = rfx_quantization_decode_NEON;
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context->dwt_2d_decode = rfx_dwt_2d_decode_NEON;
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}
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}
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#endif // __ARM_NEON__
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