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Quelle encode_streaming.cc Sprache: C |
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// Copyright (c) the JPEG XL Project Authors. All rights reserved. // // Use of this source code is governed by a BSD-style // license that can be found in the LICENSE file. #include "lib/jpegli/encode_streaming.h" #include <cmath> #include "lib/jpegli/bit_writer.h" #include "lib/jpegli/bitstream.h" #include "lib/jpegli/entropy_coding.h" #include "lib/jpegli/error.h" #include "lib/jpegli/memory_manager.h" #include "lib/jxl/base/bits.h" #undef HWY_TARGET_INCLUDE #define HWY_TARGET_INCLUDE "lib/jpegli/encode_streaming.cc" #include <hwy/foreach_target.h> #include <hwy/highway.h> #include "lib/jpegli/dct-inl.h" #include "lib/jpegli/entropy_coding-inl.h" HWY_BEFORE_NAMESPACE(); namespace jpegli { namespace HWY_NAMESPACE { static const int kStreamingModeCoefficients = 0; static const int kStreamingModeTokens = 1; static const int kStreamingModeBits = 2; namespace { void ZigZagShuffle(int32_t* JXL_RESTRICT block) { // TODO(szabadka) SIMDify this. int32_t tmp[DCTSIZE2]; tmp[0] = block[0]; tmp[1] = block[1]; tmp[2] = block[8]; tmp[3] = block[16]; tmp[4] = block[9]; tmp[5] = block[2]; tmp[6] = block[3]; tmp[7] = block[10]; tmp[8] = block[17]; tmp[9] = block[24]; tmp[10] = block[32]; tmp[11] = block[25]; tmp[12] = block[18]; tmp[13] = block[11]; tmp[14] = block[4]; tmp[15] = block[5]; tmp[16] = block[12]; tmp[17] = block[19]; tmp[18] = block[26]; tmp[19] = block[33]; tmp[20] = block[40]; tmp[21] = block[48]; tmp[22] = block[41]; tmp[23] = block[34]; tmp[24] = block[27]; tmp[25] = block[20]; tmp[26] = block[13]; tmp[27] = block[6]; tmp[28] = block[7]; tmp[29] = block[14]; tmp[30] = block[21]; tmp[31] = block[28]; tmp[32] = block[35]; tmp[33] = block[42]; tmp[34] = block[49]; tmp[35] = block[56]; tmp[36] = block[57]; tmp[37] = block[50]; tmp[38] = block[43]; tmp[39] = block[36]; tmp[40] = block[29]; tmp[41] = block[22]; tmp[42] = block[15]; tmp[43] = block[23]; tmp[44] = block[30]; tmp[45] = block[37]; tmp[46] = block[44]; tmp[47] = block[51]; tmp[48] = block[58]; tmp[49] = block[59]; tmp[50] = block[52]; tmp[51] = block[45]; tmp[52] = block[38]; tmp[53] = block[31]; tmp[54] = block[39]; tmp[55] = block[46]; tmp[56] = block[53]; tmp[57] = block[60]; tmp[58] = block[61]; tmp[59] = block[54]; tmp[60] = block[47]; tmp[61] = block[55]; tmp[62] = block[62]; tmp[63] = block[63]; memcpy(block, tmp, DCTSIZE2 * sizeof(tmp[0])); } } // namespace template <int kMode> void ProcessiMCURow(j_compress_ptr cinfo) { jpeg_comp_master* m = cinfo->master; JpegBitWriter* bw = &m->bw; int xsize_mcus = DivCeil(cinfo->image_width, 8 * cinfo->max_h_samp_factor); int ysize_mcus = DivCeil(cinfo->image_height, 8 * cinfo->max_v_samp_factor); int mcu_y = m->next_iMCU_row; int32_t* block = m->block_tmp; int32_t* symbols = m->block_tmp + DCTSIZE2; int32_t* nonzero_idx = m->block_tmp + 3 * DCTSIZE2; coeff_t* JXL_RESTRICT last_dc_coeff = m->last_dc_coeff; bool adaptive_quant = m->use_adaptive_quantization && m->psnr_target == 0; JBLOCKARRAY blocks[kMaxComponents]; if (kMode == kStreamingModeCoefficients) { for (int c = 0; c < cinfo->num_components; ++c) { jpeg_component_info* comp = &cinfo->comp_info[c]; int by0 = mcu_y * comp->v_samp_factor; int block_rows_left = comp->height_in_blocks - by0; int max_block_rows = std::min(comp->v_samp_factor, block_rows_left); blocks[c] = (*cinfo->mem->access_virt_barray)( reinterpret_cast<j_common_ptr>(cinfo), m->coeff_buffers[c], by0, max_block_rows, true); } } if (kMode == kStreamingModeTokens) { TokenArray* ta = &m->token_arrays[m->cur_token_array]; int max_tokens_per_mcu_row = MaxNumTokensPerMCURow(cinfo); if (ta->num_tokens + max_tokens_per_mcu_row > m->num_tokens) { if (ta->tokens) { m->total_num_tokens += ta->num_tokens; ++m->cur_token_array; ta = &m->token_arrays[m->cur_token_array]; } m->num_tokens = EstimateNumTokens(cinfo, mcu_y, ysize_mcus, m->total_num_tokens, max_tokens_per_mcu_row); ta->tokens = Allocate<Token>(cinfo, m->num_tokens, JPOOL_IMAGE); m->next_token = ta->tokens; } } const float* imcu_start[kMaxComponents]; for (int c = 0; c < cinfo->num_components; ++c) { jpeg_component_info* comp = &cinfo->comp_info[c]; imcu_start[c] = m->raw_data[c]->Row(mcu_y * comp->v_samp_factor * DCTSIZE); } const float* qf = nullptr; if (adaptive_quant) { qf = m->quant_field.Row(0); } HuffmanCodeTable* dc_code = nullptr; HuffmanCodeTable* ac_code = nullptr; const size_t qf_stride = m->quant_field.stride(); for (int mcu_x = 0; mcu_x < xsize_mcus; ++mcu_x) { for (int c = 0; c < cinfo->num_components; ++c) { jpeg_component_info* comp = &cinfo->comp_info[c]; if (kMode == kStreamingModeBits) { dc_code = &m->coding_tables[m->context_map[c]]; ac_code = &m->coding_tables[m->context_map[c + 4]]; } float* JXL_RESTRICT qmc = m->quant_mul[c]; const size_t stride = m->raw_data[c]->stride(); const int h_factor = m->h_factor[c]; const float* zero_bias_offset = m->zero_bias_offset[c]; const float* zero_bias_mul = m->zero_bias_mul[c]; float aq_strength = 0.0f; for (int iy = 0; iy < comp->v_samp_factor; ++iy) { for (int ix = 0; ix < comp->h_samp_factor; ++ix) { size_t by = mcu_y * comp->v_samp_factor + iy; size_t bx = mcu_x * comp->h_samp_factor + ix; if (bx >= comp->width_in_blocks || by >= comp->height_in_blocks) { if (kMode == kStreamingModeTokens) { *m->next_token++ = Token(c, 0, 0); *m->next_token++ = Token(c + 4, 0, 0); } else if (kMode == kStreamingModeBits) { WriteBits(bw, dc_code->depth[0], dc_code->code[0]); WriteBits(bw, ac_code->depth[0], ac_code->code[0]); } continue; } if (adaptive_quant) { aq_strength = qf[iy * qf_stride + bx * h_factor]; } const float* pixels = imcu_start[c] + (iy * stride + bx) * DCTSIZE; ComputeCoefficientBlock(pixels, stride, qmc, last_dc_coeff[c], aq_strength, zero_bias_offset, zero_bias_mul, m->dct_buffer, block); if (kMode == kStreamingModeCoefficients) { JCOEF* cblock = &blocks[c][iy][bx][0]; for (int k = 0; k < DCTSIZE2; ++k) { cblock[k] = block[kJPEGNaturalOrder[k]]; } } block[0] -= last_dc_coeff[c]; last_dc_coeff[c] += block[0]; if (kMode == kStreamingModeTokens) { ComputeTokensForBlock<int32_t, false>(block, 0, c, c + 4, &m->next_token); } else if (kMode == kStreamingModeBits) { ZigZagShuffle(block); const int num_nonzeros = CompactBlock(block, nonzero_idx); const bool emit_eob = nonzero_idx[num_nonzeros - 1] < 1008; ComputeSymbols(num_nonzeros, nonzero_idx, block, symbols); WriteBlock(symbols, block, num_nonzeros, emit_eob, dc_code, ac_code, bw); } } } } } if (kMode == kStreamingModeTokens) { TokenArray* ta = &m->token_arrays[m->cur_token_array]; ta->num_tokens = m->next_token - ta->tokens; ScanTokenInfo* sti = &m->scan_token_info[0]; sti->num_tokens = m->total_num_tokens + ta->num_tokens; sti->restarts[0] = sti->num_tokens; } } void ComputeCoefficientsForiMCURow(j_compress_ptr cinfo) { ProcessiMCURow<kStreamingModeCoefficients>(cinfo); } void ComputeTokensForiMCURow(j_compress_ptr cinfo) { ProcessiMCURow<kStreamingModeTokens>(cinfo); } void WriteiMCURow(j_compress_ptr cinfo) { ProcessiMCURow<kStreamingModeBits>(cinfo); } // NOLINTNEXTLINE(google-readability-namespace-comments) } // namespace HWY_NAMESPACE } // namespace jpegli HWY_AFTER_NAMESPACE(); #if HWY_ONCE namespace jpegli { HWY_EXPORT(ComputeCoefficientsForiMCURow); HWY_EXPORT(ComputeTokensForiMCURow); HWY_EXPORT(WriteiMCURow); void ComputeCoefficientsForiMCURow(j_compress_ptr cinfo) { HWY_DYNAMIC_DISPATCH(ComputeCoefficientsForiMCURow)(cinfo); } void ComputeTokensForiMCURow(j_compress_ptr cinfo) { HWY_DYNAMIC_DISPATCH(ComputeTokensForiMCURow)(cinfo); } void WriteiMCURow(j_compress_ptr cinfo) { HWY_DYNAMIC_DISPATCH(WriteiMCURow)(cinfo); } } // namespace jpegli #endif // HWY_ONCE
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2026-04-04