forked from mirror/libbpg
414 lines
20 KiB
C++
414 lines
20 KiB
C++
/*****************************************************************************
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* Copyright (C) 2013 x265 project
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*
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* Authors: Steve Borho <steve@borho.org>
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* Mandar Gurav <mandar@multicorewareinc.com>
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* Deepthi Devaki Akkoorath <deepthidevaki@multicorewareinc.com>
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* Mahesh Pittala <mahesh@multicorewareinc.com>
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* Rajesh Paulraj <rajesh@multicorewareinc.com>
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* Praveen Kumar Tiwari <praveen@multicorewareinc.com>
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* Min Chen <chenm003@163.com>
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*
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* This program is free software; you can redistribute it and/or modify
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* it under the terms of the GNU General Public License as published by
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* the Free Software Foundation; either version 2 of the License, or
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* (at your option) any later version.
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*
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* This program is distributed in the hope that it will be useful,
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* but WITHOUT ANY WARRANTY; without even the implied warranty of
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* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
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* GNU General Public License for more details.
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*
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* You should have received a copy of the GNU General Public License
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* along with this program; if not, write to the Free Software
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* Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02111, USA.
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*
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* This program is also available under a commercial proprietary license.
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* For more information, contact us at license @ x265.com.
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*****************************************************************************/
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#ifndef X265_PRIMITIVES_H
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#define X265_PRIMITIVES_H
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#include "common.h"
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#include "cpu.h"
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namespace X265_NS {
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// x265 private namespace
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enum LumaPU
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{
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// Square (the first 5 PUs match the block sizes)
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LUMA_4x4, LUMA_8x8, LUMA_16x16, LUMA_32x32, LUMA_64x64,
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// Rectangular
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LUMA_8x4, LUMA_4x8,
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LUMA_16x8, LUMA_8x16,
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LUMA_32x16, LUMA_16x32,
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LUMA_64x32, LUMA_32x64,
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// Asymmetrical (0.75, 0.25)
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LUMA_16x12, LUMA_12x16, LUMA_16x4, LUMA_4x16,
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LUMA_32x24, LUMA_24x32, LUMA_32x8, LUMA_8x32,
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LUMA_64x48, LUMA_48x64, LUMA_64x16, LUMA_16x64,
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NUM_PU_SIZES
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};
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enum LumaCU // can be indexed using log2n(width)-2
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{
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BLOCK_4x4,
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BLOCK_8x8,
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BLOCK_16x16,
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BLOCK_32x32,
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BLOCK_64x64,
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NUM_CU_SIZES
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};
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enum { NUM_TR_SIZE = 4 }; // TU are 4x4, 8x8, 16x16, and 32x32
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/* Chroma partition sizes. These enums are only a convenience for indexing into
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* the chroma primitive arrays when instantiating macros or templates. The
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* chroma function tables should always be indexed by a LumaPU enum when used. */
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enum ChromaPU420
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{
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CHROMA_420_2x2, CHROMA_420_4x4, CHROMA_420_8x8, CHROMA_420_16x16, CHROMA_420_32x32,
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CHROMA_420_4x2, CHROMA_420_2x4,
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CHROMA_420_8x4, CHROMA_420_4x8,
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CHROMA_420_16x8, CHROMA_420_8x16,
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CHROMA_420_32x16, CHROMA_420_16x32,
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CHROMA_420_8x6, CHROMA_420_6x8, CHROMA_420_8x2, CHROMA_420_2x8,
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CHROMA_420_16x12, CHROMA_420_12x16, CHROMA_420_16x4, CHROMA_420_4x16,
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CHROMA_420_32x24, CHROMA_420_24x32, CHROMA_420_32x8, CHROMA_420_8x32,
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};
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enum ChromaCU420
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{
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BLOCK_420_2x2,
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BLOCK_420_4x4,
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BLOCK_420_8x8,
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BLOCK_420_16x16,
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BLOCK_420_32x32
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};
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enum ChromaPU422
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{
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CHROMA_422_2x4, CHROMA_422_4x8, CHROMA_422_8x16, CHROMA_422_16x32, CHROMA_422_32x64,
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CHROMA_422_4x4, CHROMA_422_2x8,
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CHROMA_422_8x8, CHROMA_422_4x16,
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CHROMA_422_16x16, CHROMA_422_8x32,
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CHROMA_422_32x32, CHROMA_422_16x64,
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CHROMA_422_8x12, CHROMA_422_6x16, CHROMA_422_8x4, CHROMA_422_2x16,
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CHROMA_422_16x24, CHROMA_422_12x32, CHROMA_422_16x8, CHROMA_422_4x32,
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CHROMA_422_32x48, CHROMA_422_24x64, CHROMA_422_32x16, CHROMA_422_8x64,
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};
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enum ChromaCU422
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{
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BLOCK_422_2x4,
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BLOCK_422_4x8,
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BLOCK_422_8x16,
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BLOCK_422_16x32,
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BLOCK_422_32x64
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};
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typedef int (*pixelcmp_t)(const pixel* fenc, intptr_t fencstride, const pixel* fref, intptr_t frefstride); // fenc is aligned
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typedef int (*pixelcmp_ss_t)(const int16_t* fenc, intptr_t fencstride, const int16_t* fref, intptr_t frefstride);
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typedef sse_ret_t (*pixel_sse_t)(const pixel* fenc, intptr_t fencstride, const pixel* fref, intptr_t frefstride); // fenc is aligned
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typedef sse_ret_t (*pixel_sse_ss_t)(const int16_t* fenc, intptr_t fencstride, const int16_t* fref, intptr_t frefstride);
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typedef int (*pixel_ssd_s_t)(const int16_t* fenc, intptr_t fencstride);
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typedef void (*pixelcmp_x4_t)(const pixel* fenc, const pixel* fref0, const pixel* fref1, const pixel* fref2, const pixel* fref3, intptr_t frefstride, int32_t* res);
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typedef void (*pixelcmp_x3_t)(const pixel* fenc, const pixel* fref0, const pixel* fref1, const pixel* fref2, intptr_t frefstride, int32_t* res);
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typedef void (*blockfill_s_t)(int16_t* dst, intptr_t dstride, int16_t val);
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typedef void (*intra_pred_t)(pixel* dst, intptr_t dstStride, const pixel *srcPix, int dirMode, int bFilter);
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typedef void (*intra_allangs_t)(pixel *dst, pixel *refPix, pixel *filtPix, int bLuma);
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typedef void (*intra_filter_t)(const pixel* references, pixel* filtered);
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typedef void (*cpy2Dto1D_shl_t)(int16_t* dst, const int16_t* src, intptr_t srcStride, int shift);
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typedef void (*cpy2Dto1D_shr_t)(int16_t* dst, const int16_t* src, intptr_t srcStride, int shift);
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typedef void (*cpy1Dto2D_shl_t)(int16_t* dst, const int16_t* src, intptr_t dstStride, int shift);
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typedef void (*cpy1Dto2D_shr_t)(int16_t* dst, const int16_t* src, intptr_t dstStride, int shift);
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typedef uint32_t (*copy_cnt_t)(int16_t* coeff, const int16_t* residual, intptr_t resiStride);
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typedef void (*dct_t)(const int16_t* src, int16_t* dst, intptr_t srcStride);
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typedef void (*idct_t)(const int16_t* src, int16_t* dst, intptr_t dstStride);
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typedef void (*denoiseDct_t)(int16_t* dctCoef, uint32_t* resSum, const uint16_t* offset, int numCoeff);
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typedef void (*calcresidual_t)(const pixel* fenc, const pixel* pred, int16_t* residual, intptr_t stride);
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typedef void (*transpose_t)(pixel* dst, const pixel* src, intptr_t stride);
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typedef uint32_t (*quant_t)(const int16_t* coef, const int32_t* quantCoeff, int32_t* deltaU, int16_t* qCoef, int qBits, int add, int numCoeff);
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typedef uint32_t (*nquant_t)(const int16_t* coef, const int32_t* quantCoeff, int16_t* qCoef, int qBits, int add, int numCoeff);
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typedef void (*dequant_scaling_t)(const int16_t* src, const int32_t* dequantCoef, int16_t* dst, int num, int mcqp_miper, int shift);
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typedef void (*dequant_normal_t)(const int16_t* quantCoef, int16_t* coef, int num, int scale, int shift);
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typedef int(*count_nonzero_t)(const int16_t* quantCoeff);
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typedef void (*weightp_pp_t)(const pixel* src, pixel* dst, intptr_t stride, int width, int height, int w0, int round, int shift, int offset);
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typedef void (*weightp_sp_t)(const int16_t* src, pixel* dst, intptr_t srcStride, intptr_t dstStride, int width, int height, int w0, int round, int shift, int offset);
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typedef void (*scale1D_t)(pixel* dst, const pixel* src);
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typedef void (*scale2D_t)(pixel* dst, const pixel* src, intptr_t stride);
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typedef void (*downscale_t)(const pixel* src0, pixel* dstf, pixel* dsth, pixel* dstv, pixel* dstc,
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intptr_t src_stride, intptr_t dst_stride, int width, int height);
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typedef void (*extendCURowBorder_t)(pixel* txt, intptr_t stride, int width, int height, int marginX);
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typedef void (*ssim_4x4x2_core_t)(const pixel* pix1, intptr_t stride1, const pixel* pix2, intptr_t stride2, int sums[2][4]);
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typedef float (*ssim_end4_t)(int sum0[5][4], int sum1[5][4], int width);
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typedef uint64_t (*var_t)(const pixel* pix, intptr_t stride);
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typedef void (*plane_copy_deinterleave_t)(pixel* dstu, intptr_t dstuStride, pixel* dstv, intptr_t dstvStride, const pixel* src, intptr_t srcStride, int w, int h);
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typedef void (*filter_pp_t) (const pixel* src, intptr_t srcStride, pixel* dst, intptr_t dstStride, int coeffIdx);
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typedef void (*filter_hps_t) (const pixel* src, intptr_t srcStride, int16_t* dst, intptr_t dstStride, int coeffIdx, int isRowExt);
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typedef void (*filter_ps_t) (const pixel* src, intptr_t srcStride, int16_t* dst, intptr_t dstStride, int coeffIdx);
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typedef void (*filter_sp_t) (const int16_t* src, intptr_t srcStride, pixel* dst, intptr_t dstStride, int coeffIdx);
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typedef void (*filter_ss_t) (const int16_t* src, intptr_t srcStride, int16_t* dst, intptr_t dstStride, int coeffIdx);
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typedef void (*filter_hv_pp_t) (const pixel* src, intptr_t srcStride, pixel* dst, intptr_t dstStride, int idxX, int idxY);
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typedef void (*filter_p2s_t)(const pixel* src, intptr_t srcStride, int16_t* dst, intptr_t dstStride);
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typedef void (*copy_pp_t)(pixel* dst, intptr_t dstStride, const pixel* src, intptr_t srcStride); // dst is aligned
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typedef void (*copy_sp_t)(pixel* dst, intptr_t dstStride, const int16_t* src, intptr_t srcStride);
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typedef void (*copy_ps_t)(int16_t* dst, intptr_t dstStride, const pixel* src, intptr_t srcStride);
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typedef void (*copy_ss_t)(int16_t* dst, intptr_t dstStride, const int16_t* src, intptr_t srcStride);
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typedef void (*pixel_sub_ps_t)(int16_t* dst, intptr_t dstride, const pixel* src0, const pixel* src1, intptr_t sstride0, intptr_t sstride1);
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typedef void (*pixel_add_ps_t)(pixel* a, intptr_t dstride, const pixel* b0, const int16_t* b1, intptr_t sstride0, intptr_t sstride1);
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typedef void (*pixelavg_pp_t)(pixel* dst, intptr_t dstride, const pixel* src0, intptr_t sstride0, const pixel* src1, intptr_t sstride1, int weight);
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typedef void (*addAvg_t)(const int16_t* src0, const int16_t* src1, pixel* dst, intptr_t src0Stride, intptr_t src1Stride, intptr_t dstStride);
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typedef void (*saoCuOrgE0_t)(pixel* rec, int8_t* offsetEo, int width, int8_t* signLeft, intptr_t stride);
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typedef void (*saoCuOrgE1_t)(pixel* rec, int8_t* upBuff1, int8_t* offsetEo, intptr_t stride, int width);
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typedef void (*saoCuOrgE2_t)(pixel* rec, int8_t* pBufft, int8_t* pBuff1, int8_t* offsetEo, int lcuWidth, intptr_t stride);
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typedef void (*saoCuOrgE3_t)(pixel* rec, int8_t* upBuff1, int8_t* m_offsetEo, intptr_t stride, int startX, int endX);
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typedef void (*saoCuOrgB0_t)(pixel* rec, const int8_t* offsetBo, int ctuWidth, int ctuHeight, intptr_t stride);
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typedef void (*saoCuStatsBO_t)(const pixel *fenc, const pixel *rec, intptr_t stride, int endX, int endY, int32_t *stats, int32_t *count);
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typedef void (*saoCuStatsE0_t)(const pixel *fenc, const pixel *rec, intptr_t stride, int endX, int endY, int32_t *stats, int32_t *count);
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typedef void (*saoCuStatsE1_t)(const pixel *fenc, const pixel *rec, intptr_t stride, int8_t *upBuff1, int endX, int endY, int32_t *stats, int32_t *count);
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typedef void (*saoCuStatsE2_t)(const pixel *fenc, const pixel *rec, intptr_t stride, int8_t *upBuff1, int8_t *upBuff, int endX, int endY, int32_t *stats, int32_t *count);
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typedef void (*saoCuStatsE3_t)(const pixel *fenc, const pixel *rec, intptr_t stride, int8_t *upBuff1, int endX, int endY, int32_t *stats, int32_t *count);
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typedef void (*sign_t)(int8_t *dst, const pixel *src1, const pixel *src2, const int endX);
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typedef void (*planecopy_cp_t) (const uint8_t* src, intptr_t srcStride, pixel* dst, intptr_t dstStride, int width, int height, int shift);
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typedef void (*planecopy_sp_t) (const uint16_t* src, intptr_t srcStride, pixel* dst, intptr_t dstStride, int width, int height, int shift, uint16_t mask);
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typedef pixel (*planeClipAndMax_t)(pixel *src, intptr_t stride, int width, int height, uint64_t *outsum, const pixel minPix, const pixel maxPix);
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typedef void (*cutree_propagate_cost) (int* dst, const uint16_t* propagateIn, const int32_t* intraCosts, const uint16_t* interCosts, const int32_t* invQscales, const double* fpsFactor, int len);
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typedef int (*scanPosLast_t)(const uint16_t *scan, const coeff_t *coeff, uint16_t *coeffSign, uint16_t *coeffFlag, uint8_t *coeffNum, int numSig, const uint16_t* scanCG4x4, const int trSize);
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typedef uint32_t (*findPosFirstLast_t)(const int16_t *dstCoeff, const intptr_t trSize, const uint16_t scanTbl[16]);
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typedef uint32_t (*costCoeffNxN_t)(const uint16_t *scan, const coeff_t *coeff, intptr_t trSize, uint16_t *absCoeff, const uint8_t *tabSigCtx, uint32_t scanFlagMask, uint8_t *baseCtx, int offset, int scanPosSigOff, int subPosBase);
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typedef uint32_t (*costCoeffRemain_t)(uint16_t *absCoeff, int numNonZero, int idx);
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typedef uint32_t (*costC1C2Flag_t)(uint16_t *absCoeff, intptr_t numC1Flag, uint8_t *baseCtxMod, intptr_t ctxOffset);
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/* Function pointers to optimized encoder primitives. Each pointer can reference
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* either an assembly routine, a SIMD intrinsic primitive, or a C function */
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struct EncoderPrimitives
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{
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/* These primitives can be used for any sized prediction unit (from 4x4 to
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* 64x64, square, rectangular - 50/50 or asymmetrical - 25/75) and are
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* generally restricted to motion estimation and motion compensation (inter
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* prediction. Note that the 4x4 PU can only be used for intra, which is
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* really a 4x4 TU, so at most copy_pp and satd will use 4x4. This array is
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* indexed by LumaPU values, which can be retrieved by partitionFromSizes() */
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struct PU
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{
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pixelcmp_t sad; // Sum of Absolute Differences
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pixelcmp_x3_t sad_x3; // Sum of Absolute Differences, 3 mv offsets at once
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pixelcmp_x4_t sad_x4; // Sum of Absolute Differences, 4 mv offsets at once
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pixelcmp_t satd; // Sum of Absolute Transformed Differences (4x4 Hadamard)
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filter_pp_t luma_hpp; // 8-tap luma motion compensation interpolation filters
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filter_hps_t luma_hps;
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filter_pp_t luma_vpp;
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filter_ps_t luma_vps;
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filter_sp_t luma_vsp;
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filter_ss_t luma_vss;
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filter_hv_pp_t luma_hvpp; // combines hps + vsp
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pixelavg_pp_t pixelavg_pp; // quick bidir using pixels (borrowed from x264)
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addAvg_t addAvg; // bidir motion compensation, uses 16bit values
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copy_pp_t copy_pp;
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filter_p2s_t convert_p2s;
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}
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pu[NUM_PU_SIZES];
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/* These primitives can be used for square TU blocks (4x4 to 32x32) or
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* possibly square CU blocks (8x8 to 64x64). Some primitives are used for
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* both CU and TU so we merge them into one array that is indexed uniformly.
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* This keeps the index logic uniform and simple and improves cache
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* coherency. CU only primitives will leave 4x4 pointers NULL while TU only
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* primitives will leave 64x64 pointers NULL. Indexed by LumaCU */
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struct CU
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{
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dct_t dct;
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idct_t idct;
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calcresidual_t calcresidual;
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pixel_sub_ps_t sub_ps;
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pixel_add_ps_t add_ps;
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blockfill_s_t blockfill_s; // block fill, for DC transforms
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copy_cnt_t copy_cnt; // copy coeff while counting non-zero
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count_nonzero_t count_nonzero;
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cpy2Dto1D_shl_t cpy2Dto1D_shl;
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cpy2Dto1D_shr_t cpy2Dto1D_shr;
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cpy1Dto2D_shl_t cpy1Dto2D_shl;
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cpy1Dto2D_shr_t cpy1Dto2D_shr;
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copy_sp_t copy_sp;
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copy_ps_t copy_ps;
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copy_ss_t copy_ss;
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copy_pp_t copy_pp; // alias to pu[].copy_pp
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var_t var; // block internal variance
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pixel_sse_t sse_pp; // Sum of Square Error (pixel, pixel) fenc alignment not assumed
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pixel_sse_ss_t sse_ss; // Sum of Square Error (short, short) fenc alignment not assumed
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pixelcmp_t psy_cost_pp; // difference in AC energy between two pixel blocks
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pixelcmp_ss_t psy_cost_ss; // difference in AC energy between two signed residual blocks
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pixel_ssd_s_t ssd_s; // Sum of Square Error (residual coeff to self)
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pixelcmp_t sa8d; // Sum of Transformed Differences (8x8 Hadamard), uses satd for 4x4 intra TU
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transpose_t transpose; // transpose pixel block; for use with intra all-angs
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intra_allangs_t intra_pred_allangs;
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intra_filter_t intra_filter;
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intra_pred_t intra_pred[NUM_INTRA_MODE];
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}
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cu[NUM_CU_SIZES];
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/* These remaining primitives work on either fixed block sizes or take
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* block dimensions as arguments and thus do not belong in either the PU or
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* the CU arrays */
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dct_t dst4x4;
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idct_t idst4x4;
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quant_t quant;
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nquant_t nquant;
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dequant_scaling_t dequant_scaling;
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dequant_normal_t dequant_normal;
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denoiseDct_t denoiseDct;
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scale1D_t scale1D_128to64;
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scale2D_t scale2D_64to32;
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ssim_4x4x2_core_t ssim_4x4x2_core;
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ssim_end4_t ssim_end_4;
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sign_t sign;
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saoCuOrgE0_t saoCuOrgE0;
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/* To avoid the overhead in avx2 optimization in handling width=16, SAO_E0_1 is split
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* into two parts: saoCuOrgE1, saoCuOrgE1_2Rows */
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saoCuOrgE1_t saoCuOrgE1, saoCuOrgE1_2Rows;
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// saoCuOrgE2[0] is used for width<=16 and saoCuOrgE2[1] is used for width > 16.
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saoCuOrgE2_t saoCuOrgE2[2];
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/* In avx2 optimization, two rows cannot be handled simultaneously since it requires
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* a pixel from the previous row. So, saoCuOrgE3[0] is used for width<=16 and
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* saoCuOrgE3[1] is used for width > 16. */
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saoCuOrgE3_t saoCuOrgE3[2];
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|
saoCuOrgB0_t saoCuOrgB0;
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|
|
|
saoCuStatsBO_t saoCuStatsBO;
|
|
saoCuStatsE0_t saoCuStatsE0;
|
|
saoCuStatsE1_t saoCuStatsE1;
|
|
saoCuStatsE2_t saoCuStatsE2;
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|
saoCuStatsE3_t saoCuStatsE3;
|
|
|
|
downscale_t frameInitLowres;
|
|
cutree_propagate_cost propagateCost;
|
|
|
|
extendCURowBorder_t extendRowBorder;
|
|
planecopy_cp_t planecopy_cp;
|
|
planecopy_sp_t planecopy_sp;
|
|
planecopy_sp_t planecopy_sp_shl;
|
|
planeClipAndMax_t planeClipAndMax;
|
|
|
|
weightp_sp_t weight_sp;
|
|
weightp_pp_t weight_pp;
|
|
|
|
|
|
scanPosLast_t scanPosLast;
|
|
findPosFirstLast_t findPosFirstLast;
|
|
|
|
costCoeffNxN_t costCoeffNxN;
|
|
costCoeffRemain_t costCoeffRemain;
|
|
costC1C2Flag_t costC1C2Flag;
|
|
|
|
|
|
/* There is one set of chroma primitives per color space. An encoder will
|
|
* have just a single color space and thus it will only ever use one entry
|
|
* in this array. However we always fill all entries in the array in case
|
|
* multiple encoders with different color spaces share the primitive table
|
|
* in a single process. Note that 4:2:0 PU and CU are 1/2 width and 1/2
|
|
* height of their luma counterparts. 4:2:2 PU and CU are 1/2 width and full
|
|
* height, while 4:4:4 directly uses the luma block sizes and shares luma
|
|
* primitives for all cases except for the interpolation filters. 4:4:4
|
|
* interpolation filters have luma partition sizes but are only 4-tap. */
|
|
struct Chroma
|
|
{
|
|
/* Chroma prediction unit primitives. Indexed by LumaPU */
|
|
struct PUChroma
|
|
{
|
|
pixelcmp_t satd; // if chroma PU is not multiple of 4x4, will be NULL
|
|
filter_pp_t filter_vpp;
|
|
filter_ps_t filter_vps;
|
|
filter_sp_t filter_vsp;
|
|
filter_ss_t filter_vss;
|
|
filter_pp_t filter_hpp;
|
|
filter_hps_t filter_hps;
|
|
addAvg_t addAvg;
|
|
copy_pp_t copy_pp;
|
|
filter_p2s_t p2s;
|
|
|
|
}
|
|
pu[NUM_PU_SIZES];
|
|
|
|
/* Chroma transform and coding unit primitives. Indexed by LumaCU */
|
|
struct CUChroma
|
|
{
|
|
pixelcmp_t sa8d; // if chroma CU is not multiple of 8x8, will use satd
|
|
pixel_sse_t sse_pp;
|
|
pixel_sub_ps_t sub_ps;
|
|
pixel_add_ps_t add_ps;
|
|
|
|
copy_ps_t copy_ps;
|
|
copy_sp_t copy_sp;
|
|
copy_ss_t copy_ss;
|
|
copy_pp_t copy_pp;
|
|
}
|
|
cu[NUM_CU_SIZES];
|
|
|
|
}
|
|
chroma[X265_CSP_COUNT];
|
|
};
|
|
|
|
/* This copy of the table is what gets used by the encoder */
|
|
extern EncoderPrimitives primitives;
|
|
|
|
/* Returns a LumaPU enum for the given size, always expected to return a valid enum */
|
|
inline int partitionFromSizes(int width, int height)
|
|
{
|
|
X265_CHECK(((width | height) & ~(4 | 8 | 16 | 32 | 64)) == 0, "Invalid block width/height\n");
|
|
extern const uint8_t lumaPartitionMapTable[];
|
|
int w = (width >> 2) - 1;
|
|
int h = (height >> 2) - 1;
|
|
int part = (int)lumaPartitionMapTable[(w << 4) + h];
|
|
X265_CHECK(part != 255, "Invalid block width %d height %d\n", width, height);
|
|
return part;
|
|
}
|
|
|
|
inline int partitionFromLog2Size(int log2Size)
|
|
{
|
|
X265_CHECK(2 <= log2Size && log2Size <= 6, "Invalid block size\n");
|
|
return log2Size - 2;
|
|
}
|
|
|
|
void setupCPrimitives(EncoderPrimitives &p);
|
|
void setupInstrinsicPrimitives(EncoderPrimitives &p, int cpuMask);
|
|
void setupAssemblyPrimitives(EncoderPrimitives &p, int cpuMask);
|
|
void setupAliasPrimitives(EncoderPrimitives &p);
|
|
}
|
|
|
|
#if !EXPORT_C_API
|
|
extern const int PFX(max_bit_depth);
|
|
extern const char* PFX(version_str);
|
|
extern const char* PFX(build_info_str);
|
|
#endif
|
|
|
|
#endif // ifndef X265_PRIMITIVES_H
|