/* * Copyright (c) 2016, 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 "./av1_rtcd.h" #include "aom_ports/bitops.h" #include "aom_ports/mem.h" // sign(a-b) * min(abs(a-b), max(0, threshold - (abs(a-b) >> adjdamp))) SIMD_INLINE v128 constrain16(v128 a, v128 b, unsigned int threshold, unsigned int adjdamp) { v128 diff = v128_sub_16(a, b); const v128 sign = v128_shr_n_s16(diff, 15); diff = v128_abs_s16(diff); const v128 s = v128_ssub_u16(v128_dup_16(threshold), v128_shr_u16(diff, adjdamp)); return v128_xor(v128_add_16(sign, v128_min_s16(diff, s)), sign); } // sign(a - b) * min(abs(a - b), max(0, strength - (abs(a - b) >> adjdamp))) SIMD_INLINE v128 constrain(v256 a, v256 b, unsigned int strength, unsigned int adjdamp) { const v256 diff16 = v256_sub_16(a, b); v128 diff = v128_pack_s16_s8(v256_high_v128(diff16), v256_low_v128(diff16)); const v128 sign = v128_cmplt_s8(diff, v128_zero()); diff = v128_abs_s8(diff); return v128_xor( v128_add_8(sign, v128_min_u8(diff, v128_ssub_u8(v128_dup_8(strength), v128_shr_u8(diff, adjdamp)))), sign); } // delta = 1/16 * constrain(a, x, s, d) + 3/16 * constrain(b, x, s, d) + // 1/16 * constrain(c, x, s, d) + 3/16 * constrain(d, x, s, d) + // 3/16 * constrain(e, x, s, d) + 1/16 * constrain(f, x, s, d) + // 3/16 * constrain(g, x, s, d) + 1/16 * constrain(h, x, s, d) SIMD_INLINE v128 calc_delta(v256 x, v256 a, v256 b, v256 c, v256 d, v256 e, v256 f, v256 g, v256 h, unsigned int s, unsigned int dmp) { const v128 bdeg = v128_add_8(v128_add_8(constrain(b, x, s, dmp), constrain(d, x, s, dmp)), v128_add_8(constrain(e, x, s, dmp), constrain(g, x, s, dmp))); const v128 delta = v128_add_8( v128_add_8(v128_add_8(constrain(a, x, s, dmp), constrain(c, x, s, dmp)), v128_add_8(constrain(f, x, s, dmp), constrain(h, x, s, dmp))), v128_add_8(v128_add_8(bdeg, bdeg), bdeg)); return v128_add_8( v128_pack_s16_u8(v256_high_v128(x), v256_low_v128(x)), v128_shr_s8( v128_add_8(v128_dup_8(8), v128_add_8(delta, v128_cmplt_s8(delta, v128_zero()))), 4)); } // delta = 1/8 * constrain(a, x, s, d) + 3/8 * constrain(b, x, s, d) + // 3/8 * constrain(c, x, s, d) + 1/8 * constrain(d, x, s, d) + SIMD_INLINE v128 calc_hdelta(v256 x, v256 a, v256 b, v256 c, v256 d, unsigned int s, unsigned int dmp) { const v128 bc = v128_add_8(constrain(b, x, s, dmp), constrain(c, x, s, dmp)); const v128 delta = v128_add_8(v128_add_8(constrain(a, x, s, dmp), constrain(d, x, s, dmp)), v128_add_8(v128_add_8(bc, bc), bc)); return v128_add_8( v128_pack_s16_u8(v256_high_v128(x), v256_low_v128(x)), v128_shr_s8( v128_add_8(v128_dup_8(4), v128_add_8(delta, v128_cmplt_s8(delta, v128_zero()))), 3)); } // Process blocks of width 8, two lines at a time, 8 bit. static void SIMD_FUNC(clpf_block8)(uint8_t *dst, const uint16_t *src, int dstride, int sstride, int sizey, unsigned int strength, unsigned int adjdamp) { int y; for (y = 0; y < sizey; y += 2) { const v128 l1 = v128_load_aligned(src); const v128 l2 = v128_load_aligned(src + sstride); const v128 l3 = v128_load_aligned(src - sstride); const v128 l4 = v128_load_aligned(src + 2 * sstride); const v256 a = v256_from_v128(v128_load_aligned(src - 2 * sstride), l3); const v256 b = v256_from_v128(l3, l1); const v256 g = v256_from_v128(l2, l4); const v256 h = v256_from_v128(l4, v128_load_aligned(src + 3 * sstride)); const v256 c = v256_from_v128(v128_load_unaligned(src - 2), v128_load_unaligned(src - 2 + sstride)); const v256 d = v256_from_v128(v128_load_unaligned(src - 1), v128_load_unaligned(src - 1 + sstride)); const v256 e = v256_from_v128(v128_load_unaligned(src + 1), v128_load_unaligned(src + 1 + sstride)); const v256 f = v256_from_v128(v128_load_unaligned(src + 2), v128_load_unaligned(src + 2 + sstride)); const v128 o = calc_delta(v256_from_v128(l1, l2), a, b, c, d, e, f, g, h, strength, adjdamp); v64_store_aligned(dst, v128_high_v64(o)); v64_store_aligned(dst + dstride, v128_low_v64(o)); src += sstride * 2; dst += dstride * 2; } } // Process blocks of width 4, four lines at a time, 8 bit. static void SIMD_FUNC(clpf_block4)(uint8_t *dst, const uint16_t *src, int dstride, int sstride, int sizey, unsigned int strength, unsigned int adjdamp) { int y; for (y = 0; y < sizey; y += 4) { const v64 l0 = v64_load_aligned(src - 2 * sstride); const v64 l1 = v64_load_aligned(src - sstride); const v64 l2 = v64_load_aligned(src); const v64 l3 = v64_load_aligned(src + sstride); const v64 l4 = v64_load_aligned(src + 2 * sstride); const v64 l5 = v64_load_aligned(src + 3 * sstride); const v64 l6 = v64_load_aligned(src + 4 * sstride); const v64 l7 = v64_load_aligned(src + 5 * sstride); const v128 o = calc_delta(v256_from_v64(l2, l3, l4, l5), v256_from_v64(l0, l1, l2, l3), v256_from_v64(l1, l2, l3, l4), v256_from_v64(v64_load_unaligned(src - 2), v64_load_unaligned(src + sstride - 2), v64_load_unaligned(src + 2 * sstride - 2), v64_load_unaligned(src + 3 * sstride - 2)), v256_from_v64(v64_load_unaligned(src - 1), v64_load_unaligned(src + sstride - 1), v64_load_unaligned(src + 2 * sstride - 1), v64_load_unaligned(src + 3 * sstride - 1)), v256_from_v64(v64_load_unaligned(src + 1), v64_load_unaligned(src + sstride + 1), v64_load_unaligned(src + 2 * sstride + 1), v64_load_unaligned(src + 3 * sstride + 1)), v256_from_v64(v64_load_unaligned(src + 2), v64_load_unaligned(src + sstride + 2), v64_load_unaligned(src + 2 * sstride + 2), v64_load_unaligned(src + 3 * sstride + 2)), v256_from_v64(l3, l4, l5, l6), v256_from_v64(l4, l5, l6, l7), strength, adjdamp); u32_store_aligned(dst, v128_low_u32(v128_shr_n_byte(o, 12))); u32_store_aligned(dst + dstride, v128_low_u32(v128_shr_n_byte(o, 8))); u32_store_aligned(dst + 2 * dstride, v128_low_u32(v128_shr_n_byte(o, 4))); u32_store_aligned(dst + 3 * dstride, v128_low_u32(o)); dst += 4 * dstride; src += 4 * sstride; } } static void SIMD_FUNC(clpf_hblock8)(uint8_t *dst, const uint16_t *src, int dstride, int sstride, int sizey, unsigned int strength, unsigned int adjdamp) { int y; for (y = 0; y < sizey; y += 2) { const v256 x = v256_from_v128(v128_load_aligned(src), v128_load_aligned(src + sstride)); const v256 a = v256_from_v128(v128_load_unaligned(src - 2), v128_load_unaligned(src - 2 + sstride)); const v256 b = v256_from_v128(v128_load_unaligned(src - 1), v128_load_unaligned(src - 1 + sstride)); const v256 c = v256_from_v128(v128_load_unaligned(src + 1), v128_load_unaligned(src + 1 + sstride)); const v256 d = v256_from_v128(v128_load_unaligned(src + 2), v128_load_unaligned(src + 2 + sstride)); const v128 o = calc_hdelta(x, a, b, c, d, strength, adjdamp); v64_store_aligned(dst, v128_high_v64(o)); v64_store_aligned(dst + dstride, v128_low_v64(o)); src += sstride * 2; dst += dstride * 2; } } // Process blocks of width 4, four lines at a time, 8 bit. static void SIMD_FUNC(clpf_hblock4)(uint8_t *dst, const uint16_t *src, int dstride, int sstride, int sizey, unsigned int strength, unsigned int adjdamp) { int y; for (y = 0; y < sizey; y += 4) { const v256 a = v256_from_v64(v64_load_unaligned(src - 2), v64_load_unaligned(src + sstride - 2), v64_load_unaligned(src + 2 * sstride - 2), v64_load_unaligned(src + 3 * sstride - 2)); const v256 b = v256_from_v64(v64_load_unaligned(src - 1), v64_load_unaligned(src + sstride - 1), v64_load_unaligned(src + 2 * sstride - 1), v64_load_unaligned(src + 3 * sstride - 1)); const v256 c = v256_from_v64(v64_load_unaligned(src + 1), v64_load_unaligned(src + sstride + 1), v64_load_unaligned(src + 2 * sstride + 1), v64_load_unaligned(src + 3 * sstride + 1)); const v256 d = v256_from_v64(v64_load_unaligned(src + 2), v64_load_unaligned(src + sstride + 2), v64_load_unaligned(src + 2 * sstride + 2), v64_load_unaligned(src + 3 * sstride + 2)); const v128 o = calc_hdelta( v256_from_v64(v64_load_aligned(src), v64_load_aligned(src + sstride), v64_load_aligned(src + 2 * sstride), v64_load_aligned(src + 3 * sstride)), a, b, c, d, strength, adjdamp); u32_store_aligned(dst, v128_low_u32(v128_shr_n_byte(o, 12))); u32_store_aligned(dst + dstride, v128_low_u32(v128_shr_n_byte(o, 8))); u32_store_aligned(dst + 2 * dstride, v128_low_u32(v128_shr_n_byte(o, 4))); u32_store_aligned(dst + 3 * dstride, v128_low_u32(o)); dst += 4 * dstride; src += 4 * sstride; } } void SIMD_FUNC(aom_clpf_block)(uint8_t *dst, const uint16_t *src, int dstride, int sstride, int sizex, int sizey, unsigned int strength, unsigned int dmp) { if ((sizex != 4 && sizex != 8) || ((sizey & 3) && sizex == 4)) { // Fallback to C for odd sizes: // * block widths not 4 or 8 // * block heights not a multiple of 4 if the block width is 4 aom_clpf_block_c(dst, src, dstride, sstride, sizex, sizey, strength, dmp); } else { (sizex == 4 ? SIMD_FUNC(clpf_block4) : SIMD_FUNC(clpf_block8))( dst, src, dstride, sstride, sizey, strength, dmp - get_msb(strength)); } } void SIMD_FUNC(aom_clpf_hblock)(uint8_t *dst, const uint16_t *src, int dstride, int sstride, int sizex, int sizey, unsigned int strength, unsigned int dmp) { if ((sizex != 4 && sizex != 8) || ((sizey & 3) && sizex == 4)) { // Fallback to C for odd sizes: // * block widths not 4 or 8 // * block heights not a multiple of 4 if the block width is 4 aom_clpf_hblock_c(dst, src, dstride, sstride, sizex, sizey, strength, dmp); } else { (sizex == 4 ? SIMD_FUNC(clpf_hblock4) : SIMD_FUNC(clpf_hblock8))( dst, src, dstride, sstride, sizey, strength, dmp - get_msb(strength)); } } // delta = 1/16 * constrain(a, x, s, d) + 3/16 * constrain(b, x, s, d) + // 1/16 * constrain(c, x, s, d) + 3/16 * constrain(d, x, s, d) + // 3/16 * constrain(e, x, s, d) + 1/16 * constrain(f, x, s, d) + // 3/16 * constrain(g, x, s, d) + 1/16 * constrain(h, x, s, d) SIMD_INLINE v128 calc_delta_hbd(v128 x, v128 a, v128 b, v128 c, v128 d, v128 e, v128 f, v128 g, v128 h, unsigned int s, unsigned int dmp) { const v128 bdeg = v128_add_16( v128_add_16(constrain16(b, x, s, dmp), constrain16(d, x, s, dmp)), v128_add_16(constrain16(e, x, s, dmp), constrain16(g, x, s, dmp))); const v128 delta = v128_add_16( v128_add_16( v128_add_16(constrain16(a, x, s, dmp), constrain16(c, x, s, dmp)), v128_add_16(constrain16(f, x, s, dmp), constrain16(h, x, s, dmp))), v128_add_16(v128_add_16(bdeg, bdeg), bdeg)); return v128_add_16( x, v128_shr_s16( v128_add_16(v128_dup_16(8), v128_add_16(delta, v128_cmplt_s16(delta, v128_zero()))), 4)); } static void calc_delta_hbd4(v128 o, v128 a, v128 b, v128 c, v128 d, v128 e, v128 f, v128 g, v128 h, uint16_t *dst, unsigned int s, unsigned int dmp, int dstride) { o = calc_delta_hbd(o, a, b, c, d, e, f, g, h, s, dmp); v64_store_aligned(dst, v128_high_v64(o)); v64_store_aligned(dst + dstride, v128_low_v64(o)); } static void calc_delta_hbd8(v128 o, v128 a, v128 b, v128 c, v128 d, v128 e, v128 f, v128 g, v128 h, uint16_t *dst, unsigned int s, unsigned int adjdamp) { v128_store_aligned(dst, calc_delta_hbd(o, a, b, c, d, e, f, g, h, s, adjdamp)); } // delta = 1/16 * constrain(a, x, s, dmp) + 3/16 * constrain(b, x, s, dmp) + // 3/16 * constrain(c, x, s, dmp) + 1/16 * constrain(d, x, s, dmp) SIMD_INLINE v128 calc_hdelta_hbd(v128 x, v128 a, v128 b, v128 c, v128 d, unsigned int s, unsigned int dmp) { const v128 bc = v128_add_16(constrain16(b, x, s, dmp), constrain16(c, x, s, dmp)); const v128 delta = v128_add_16( v128_add_16(constrain16(a, x, s, dmp), constrain16(d, x, s, dmp)), v128_add_16(v128_add_16(bc, bc), bc)); return v128_add_16( x, v128_shr_s16( v128_add_16(v128_dup_16(4), v128_add_16(delta, v128_cmplt_s16(delta, v128_zero()))), 3)); } static void calc_hdelta_hbd4(v128 o, v128 a, v128 b, v128 c, v128 d, uint16_t *dst, unsigned int s, unsigned int adjdamp, int dstride) { o = calc_hdelta_hbd(o, a, b, c, d, s, adjdamp); v64_store_aligned(dst, v128_high_v64(o)); v64_store_aligned(dst + dstride, v128_low_v64(o)); } static void calc_hdelta_hbd8(v128 o, v128 a, v128 b, v128 c, v128 d, uint16_t *dst, unsigned int s, unsigned int adjdamp) { v128_store_aligned(dst, calc_hdelta_hbd(o, a, b, c, d, s, adjdamp)); } // Process blocks of width 4, two lines at time. static void SIMD_FUNC(clpf_block_hbd4)(uint16_t *dst, const uint16_t *src, int dstride, int sstride, int sizey, unsigned int strength, unsigned int adjdamp) { int y; for (y = 0; y < sizey; y += 2) { const v64 l1 = v64_load_aligned(src); const v64 l2 = v64_load_aligned(src + sstride); const v64 l3 = v64_load_aligned(src - sstride); const v64 l4 = v64_load_aligned(src + 2 * sstride); const v128 a = v128_from_v64(v64_load_aligned(src - 2 * sstride), l3); const v128 b = v128_from_v64(l3, l1); const v128 g = v128_from_v64(l2, l4); const v128 h = v128_from_v64(l4, v64_load_aligned(src + 3 * sstride)); const v128 c = v128_from_v64(v64_load_unaligned(src - 2), v64_load_unaligned(src - 2 + sstride)); const v128 d = v128_from_v64(v64_load_unaligned(src - 1), v64_load_unaligned(src - 1 + sstride)); const v128 e = v128_from_v64(v64_load_unaligned(src + 1), v64_load_unaligned(src + 1 + sstride)); const v128 f = v128_from_v64(v64_load_unaligned(src + 2), v64_load_unaligned(src + 2 + sstride)); calc_delta_hbd4(v128_from_v64(l1, l2), a, b, c, d, e, f, g, h, dst, strength, adjdamp, dstride); src += sstride * 2; dst += dstride * 2; } } // The most simple case. Start here if you need to understand the functions. static void SIMD_FUNC(clpf_block_hbd)(uint16_t *dst, const uint16_t *src, int dstride, int sstride, int sizey, unsigned int strength, unsigned int adjdamp) { int y; for (y = 0; y < sizey; y++) { const v128 o = v128_load_aligned(src); const v128 a = v128_load_aligned(src - 2 * sstride); const v128 b = v128_load_aligned(src - 1 * sstride); const v128 g = v128_load_aligned(src + sstride); const v128 h = v128_load_aligned(src + 2 * sstride); const v128 c = v128_load_unaligned(src - 2); const v128 d = v128_load_unaligned(src - 1); const v128 e = v128_load_unaligned(src + 1); const v128 f = v128_load_unaligned(src + 2); calc_delta_hbd8(o, a, b, c, d, e, f, g, h, dst, strength, adjdamp); src += sstride; dst += dstride; } } // Process blocks of width 4, horizontal filter, two lines at time. static void SIMD_FUNC(clpf_hblock_hbd4)(uint16_t *dst, const uint16_t *src, int dstride, int sstride, int sizey, unsigned int strength, unsigned int adjdamp) { int y; for (y = 0; y < sizey; y += 2) { const v128 a = v128_from_v64(v64_load_unaligned(src - 2), v64_load_unaligned(src - 2 + sstride)); const v128 b = v128_from_v64(v64_load_unaligned(src - 1), v64_load_unaligned(src - 1 + sstride)); const v128 c = v128_from_v64(v64_load_unaligned(src + 1), v64_load_unaligned(src + 1 + sstride)); const v128 d = v128_from_v64(v64_load_unaligned(src + 2), v64_load_unaligned(src + 2 + sstride)); calc_hdelta_hbd4(v128_from_v64(v64_load_unaligned(src), v64_load_unaligned(src + sstride)), a, b, c, d, dst, strength, adjdamp, dstride); src += sstride * 2; dst += dstride * 2; } } // Process blocks of width 8, horizontal filter, two lines at time. static void SIMD_FUNC(clpf_hblock_hbd)(uint16_t *dst, const uint16_t *src, int dstride, int sstride, int sizey, unsigned int strength, unsigned int adjdamp) { int y; for (y = 0; y < sizey; y++) { const v128 o = v128_load_aligned(src); const v128 a = v128_load_unaligned(src - 2); const v128 b = v128_load_unaligned(src - 1); const v128 c = v128_load_unaligned(src + 1); const v128 d = v128_load_unaligned(src + 2); calc_hdelta_hbd8(o, a, b, c, d, dst, strength, adjdamp); src += sstride; dst += dstride; } } void SIMD_FUNC(aom_clpf_block_hbd)(uint16_t *dst, const uint16_t *src, int dstride, int sstride, int sizex, int sizey, unsigned int strength, unsigned int dmp) { if ((sizex != 4 && sizex != 8) || ((sizey & 1) && sizex == 4)) { // Fallback to C for odd sizes: // * block width not 4 or 8 // * block heights not a multiple of 2 if the block width is 4 aom_clpf_block_hbd_c(dst, src, dstride, sstride, sizex, sizey, strength, dmp); } else { (sizex == 4 ? SIMD_FUNC(clpf_block_hbd4) : SIMD_FUNC(clpf_block_hbd))( dst, src, dstride, sstride, sizey, strength, dmp - get_msb(strength)); } } void SIMD_FUNC(aom_clpf_hblock_hbd)(uint16_t *dst, const uint16_t *src, int dstride, int sstride, int sizex, int sizey, unsigned int strength, unsigned int dmp) { if ((sizex != 4 && sizex != 8) || ((sizey & 1) && sizex == 4)) { // Fallback to C for odd sizes: // * block width not 4 or 8 // * block heights not a multiple of 2 if the block width is 4 aom_clpf_hblock_hbd_c(dst, src, dstride, sstride, sizex, sizey, strength, dmp); } else { (sizex == 4 ? SIMD_FUNC(clpf_hblock_hbd4) : SIMD_FUNC(clpf_hblock_hbd))( dst, src, dstride, sstride, sizey, strength, dmp - get_msb(strength)); } }