// Copyright 2017 Google Inc. All Rights Reserved. // // Use of this source code is governed by a BSD-style license // that can be found in the COPYING file in the root of the source // tree. An additional intellectual property rights grant can be found // in the file PATENTS. All contributing project authors may // be found in the AUTHORS file in the root of the source tree. // ----------------------------------------------------------------------------- // // NEON variant of alpha filters // // Author: Skal (pascal.massimino@gmail.com) #include "./dsp.h" #if defined(WEBP_USE_NEON) #include #include "./neon.h" //------------------------------------------------------------------------------ // Helpful macros. # define SANITY_CHECK(in, out) \ assert(in != NULL); \ assert(out != NULL); \ assert(width > 0); \ assert(height > 0); \ assert(stride >= width); \ assert(row >= 0 && num_rows > 0 && row + num_rows <= height); \ (void)height; // Silence unused warning. // load eight u8 and widen to s16 #define U8_TO_S16(A) vreinterpretq_s16_u16(vmovl_u8(A)) #define LOAD_U8_TO_S16(A) U8_TO_S16(vld1_u8(A)) // shift left or right by N byte, inserting zeros #define SHIFT_RIGHT_N_Q(A, N) vextq_u8((A), zero, (N)) #define SHIFT_LEFT_N_Q(A, N) vextq_u8(zero, (A), (16 - (N)) % 16) // rotate left by N bytes #define ROTATE_LEFT_N(A, N) vext_u8((A), (A), (N)) // rotate right by N bytes #define ROTATE_RIGHT_N(A, N) vext_u8((A), (A), (8 - (N)) % 8) static void PredictLine_NEON(const uint8_t* src, const uint8_t* pred, uint8_t* dst, int length) { int i; assert(length >= 0); for (i = 0; i + 16 <= length; i += 16) { const uint8x16_t A = vld1q_u8(&src[i]); const uint8x16_t B = vld1q_u8(&pred[i]); const uint8x16_t C = vsubq_u8(A, B); vst1q_u8(&dst[i], C); } for (; i < length; ++i) dst[i] = src[i] - pred[i]; } // Special case for left-based prediction (when preds==dst-1 or preds==src-1). static void PredictLineLeft_NEON(const uint8_t* src, uint8_t* dst, int length) { PredictLine_NEON(src, src - 1, dst, length); } //------------------------------------------------------------------------------ // Horizontal filter. static WEBP_INLINE void DoHorizontalFilter_NEON(const uint8_t* in, int width, int height, int stride, int row, int num_rows, uint8_t* out) { const size_t start_offset = row * stride; const int last_row = row + num_rows; SANITY_CHECK(in, out); in += start_offset; out += start_offset; if (row == 0) { // Leftmost pixel is the same as input for topmost scanline. out[0] = in[0]; PredictLineLeft_NEON(in + 1, out + 1, width - 1); row = 1; in += stride; out += stride; } // Filter line-by-line. while (row < last_row) { // Leftmost pixel is predicted from above. out[0] = in[0] - in[-stride]; PredictLineLeft_NEON(in + 1, out + 1, width - 1); ++row; in += stride; out += stride; } } static void HorizontalFilter_NEON(const uint8_t* data, int width, int height, int stride, uint8_t* filtered_data) { DoHorizontalFilter_NEON(data, width, height, stride, 0, height, filtered_data); } //------------------------------------------------------------------------------ // Vertical filter. static WEBP_INLINE void DoVerticalFilter_NEON(const uint8_t* in, int width, int height, int stride, int row, int num_rows, uint8_t* out) { const size_t start_offset = row * stride; const int last_row = row + num_rows; SANITY_CHECK(in, out); in += start_offset; out += start_offset; if (row == 0) { // Very first top-left pixel is copied. out[0] = in[0]; // Rest of top scan-line is left-predicted. PredictLineLeft_NEON(in + 1, out + 1, width - 1); row = 1; in += stride; out += stride; } // Filter line-by-line. while (row < last_row) { PredictLine_NEON(in, in - stride, out, width); ++row; in += stride; out += stride; } } static void VerticalFilter_NEON(const uint8_t* data, int width, int height, int stride, uint8_t* filtered_data) { DoVerticalFilter_NEON(data, width, height, stride, 0, height, filtered_data); } //------------------------------------------------------------------------------ // Gradient filter. static WEBP_INLINE int GradientPredictor_C(uint8_t a, uint8_t b, uint8_t c) { const int g = a + b - c; return ((g & ~0xff) == 0) ? g : (g < 0) ? 0 : 255; // clip to 8bit } static void GradientPredictDirect_NEON(const uint8_t* const row, const uint8_t* const top, uint8_t* const out, int length) { int i; for (i = 0; i + 8 <= length; i += 8) { const uint8x8_t A = vld1_u8(&row[i - 1]); const uint8x8_t B = vld1_u8(&top[i + 0]); const int16x8_t C = vreinterpretq_s16_u16(vaddl_u8(A, B)); const int16x8_t D = LOAD_U8_TO_S16(&top[i - 1]); const uint8x8_t E = vqmovun_s16(vsubq_s16(C, D)); const uint8x8_t F = vld1_u8(&row[i + 0]); vst1_u8(&out[i], vsub_u8(F, E)); } for (; i < length; ++i) { out[i] = row[i] - GradientPredictor_C(row[i - 1], top[i], top[i - 1]); } } static WEBP_INLINE void DoGradientFilter_NEON(const uint8_t* in, int width, int height, int stride, int row, int num_rows, uint8_t* out) { const size_t start_offset = row * stride; const int last_row = row + num_rows; SANITY_CHECK(in, out); in += start_offset; out += start_offset; // left prediction for top scan-line if (row == 0) { out[0] = in[0]; PredictLineLeft_NEON(in + 1, out + 1, width - 1); row = 1; in += stride; out += stride; } // Filter line-by-line. while (row < last_row) { out[0] = in[0] - in[-stride]; GradientPredictDirect_NEON(in + 1, in + 1 - stride, out + 1, width - 1); ++row; in += stride; out += stride; } } static void GradientFilter_NEON(const uint8_t* data, int width, int height, int stride, uint8_t* filtered_data) { DoGradientFilter_NEON(data, width, height, stride, 0, height, filtered_data); } #undef SANITY_CHECK //------------------------------------------------------------------------------ // Inverse transforms static void HorizontalUnfilter_NEON(const uint8_t* prev, const uint8_t* in, uint8_t* out, int width) { int i; const uint8x16_t zero = vdupq_n_u8(0); uint8x16_t last; out[0] = in[0] + (prev == NULL ? 0 : prev[0]); if (width <= 1) return; last = vsetq_lane_u8(out[0], zero, 0); for (i = 1; i + 16 <= width; i += 16) { const uint8x16_t A0 = vld1q_u8(&in[i]); const uint8x16_t A1 = vaddq_u8(A0, last); const uint8x16_t A2 = SHIFT_LEFT_N_Q(A1, 1); const uint8x16_t A3 = vaddq_u8(A1, A2); const uint8x16_t A4 = SHIFT_LEFT_N_Q(A3, 2); const uint8x16_t A5 = vaddq_u8(A3, A4); const uint8x16_t A6 = SHIFT_LEFT_N_Q(A5, 4); const uint8x16_t A7 = vaddq_u8(A5, A6); const uint8x16_t A8 = SHIFT_LEFT_N_Q(A7, 8); const uint8x16_t A9 = vaddq_u8(A7, A8); vst1q_u8(&out[i], A9); last = SHIFT_RIGHT_N_Q(A9, 15); } for (; i < width; ++i) out[i] = in[i] + out[i - 1]; } static void VerticalUnfilter_NEON(const uint8_t* prev, const uint8_t* in, uint8_t* out, int width) { if (prev == NULL) { HorizontalUnfilter_NEON(NULL, in, out, width); } else { int i; assert(width >= 0); for (i = 0; i + 16 <= width; i += 16) { const uint8x16_t A = vld1q_u8(&in[i]); const uint8x16_t B = vld1q_u8(&prev[i]); const uint8x16_t C = vaddq_u8(A, B); vst1q_u8(&out[i], C); } for (; i < width; ++i) out[i] = in[i] + prev[i]; } } // GradientUnfilter_NEON is correct but slower than the C-version, // at least on ARM64. For armv7, it's a wash. // So best is to disable it for now, but keep the idea around... // #define USE_GRADIENT_UNFILTER #if defined(USE_GRADIENT_UNFILTER) #define GRAD_PROCESS_LANE(L) do { \ const uint8x8_t tmp1 = ROTATE_RIGHT_N(pred, 1); /* rotate predictor in */ \ const int16x8_t tmp2 = vaddq_s16(BC, U8_TO_S16(tmp1)); \ const uint8x8_t delta = vqmovun_s16(tmp2); \ pred = vadd_u8(D, delta); \ out = vext_u8(out, ROTATE_LEFT_N(pred, (L)), 1); \ } while (0) static void GradientPredictInverse_NEON(const uint8_t* const in, const uint8_t* const top, uint8_t* const row, int length) { if (length > 0) { int i; uint8x8_t pred = vdup_n_u8(row[-1]); // left sample uint8x8_t out = vdup_n_u8(0); for (i = 0; i + 8 <= length; i += 8) { const int16x8_t B = LOAD_U8_TO_S16(&top[i + 0]); const int16x8_t C = LOAD_U8_TO_S16(&top[i - 1]); const int16x8_t BC = vsubq_s16(B, C); // unclipped gradient basis B - C const uint8x8_t D = vld1_u8(&in[i]); // base input GRAD_PROCESS_LANE(0); GRAD_PROCESS_LANE(1); GRAD_PROCESS_LANE(2); GRAD_PROCESS_LANE(3); GRAD_PROCESS_LANE(4); GRAD_PROCESS_LANE(5); GRAD_PROCESS_LANE(6); GRAD_PROCESS_LANE(7); vst1_u8(&row[i], out); } for (; i < length; ++i) { row[i] = in[i] + GradientPredictor_C(row[i - 1], top[i], top[i - 1]); } } } #undef GRAD_PROCESS_LANE static void GradientUnfilter_NEON(const uint8_t* prev, const uint8_t* in, uint8_t* out, int width) { if (prev == NULL) { HorizontalUnfilter_NEON(NULL, in, out, width); } else { out[0] = in[0] + prev[0]; // predict from above GradientPredictInverse_NEON(in + 1, prev + 1, out + 1, width - 1); } } #endif // USE_GRADIENT_UNFILTER //------------------------------------------------------------------------------ // Entry point extern void VP8FiltersInitNEON(void); WEBP_TSAN_IGNORE_FUNCTION void VP8FiltersInitNEON(void) { WebPUnfilters[WEBP_FILTER_HORIZONTAL] = HorizontalUnfilter_NEON; WebPUnfilters[WEBP_FILTER_VERTICAL] = VerticalUnfilter_NEON; #if defined(USE_GRADIENT_UNFILTER) WebPUnfilters[WEBP_FILTER_GRADIENT] = GradientUnfilter_NEON; #endif WebPFilters[WEBP_FILTER_HORIZONTAL] = HorizontalFilter_NEON; WebPFilters[WEBP_FILTER_VERTICAL] = VerticalFilter_NEON; WebPFilters[WEBP_FILTER_GRADIENT] = GradientFilter_NEON; } #else // !WEBP_USE_NEON WEBP_DSP_INIT_STUB(VP8FiltersInitNEON) #endif // WEBP_USE_NEON