// 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.h" #include #include #include #include "lib/jpegli/adaptive_quantization.h" #include "lib/jpegli/bit_writer.h" #include "lib/jpegli/bitstream.h" #include "lib/jpegli/color_transform.h" #include "lib/jpegli/dct.h" #include "lib/jpegli/downsample.h" #include "lib/jpegli/encode_internal.h" #include "lib/jpegli/entropy_coding.h" #include "lib/jpegli/error.h" #include "lib/jpegli/huffman.h" #include "lib/jpegli/input.h" #include "lib/jpegli/memory_manager.h" #include "lib/jpegli/quant.h" namespace jpegli { constexpr size_t kMaxBytesInMarker = 65533; void CheckState(j_compress_ptr cinfo, int state) { if (cinfo->global_state != state) { JPEGLI_ERROR("Unexpected global state %d [expected %d]", cinfo->global_state, state); } } void CheckState(j_compress_ptr cinfo, int state1, int state2) { if (cinfo->global_state != state1 && cinfo->global_state != state2) { JPEGLI_ERROR("Unexpected global state %d [expected %d or %d]", cinfo->global_state, state1, state2); } } // Initialize cinfo fields that are not dependent on input image. This is shared // between jpegli_CreateCompress() and jpegli_set_defaults() void InitializeCompressParams(j_compress_ptr cinfo) { cinfo->data_precision = 8; cinfo->num_scans = 0; cinfo->scan_info = nullptr; cinfo->raw_data_in = FALSE; cinfo->arith_code = FALSE; cinfo->optimize_coding = FALSE; cinfo->CCIR601_sampling = FALSE; cinfo->smoothing_factor = 0; cinfo->dct_method = JDCT_FLOAT; cinfo->restart_interval = 0; cinfo->restart_in_rows = 0; cinfo->write_JFIF_header = FALSE; cinfo->JFIF_major_version = 1; cinfo->JFIF_minor_version = 1; cinfo->density_unit = 0; cinfo->X_density = 1; cinfo->Y_density = 1; #if JPEG_LIB_VERSION >= 70 cinfo->scale_num = 1; cinfo->scale_denom = 1; cinfo->do_fancy_downsampling = FALSE; cinfo->min_DCT_h_scaled_size = DCTSIZE; cinfo->min_DCT_v_scaled_size = DCTSIZE; #endif } float LinearQualityToDistance(int scale_factor) { scale_factor = std::min(5000, std::max(0, scale_factor)); int quality = scale_factor < 100 ? 100 - scale_factor / 2 : 5000 / scale_factor; return jpegli_quality_to_distance(quality); } template void SetSentTableFlag(T** table_ptrs, size_t num, boolean val) { for (size_t i = 0; i < num; ++i) { if (table_ptrs[i]) table_ptrs[i]->sent_table = val; } } struct ProgressiveScan { int Ss, Se, Ah, Al; bool interleaved; }; void SetDefaultScanScript(j_compress_ptr cinfo) { int level = cinfo->master->progressive_level; std::vector progressive_mode; bool interleave_dc = (cinfo->max_h_samp_factor == 1 && cinfo->max_v_samp_factor == 1); if (level == 0) { progressive_mode.push_back({0, 63, 0, 0, true}); } else if (level == 1) { progressive_mode.push_back({0, 0, 0, 0, interleave_dc}); progressive_mode.push_back({1, 63, 0, 1, false}); progressive_mode.push_back({1, 63, 1, 0, false}); } else { progressive_mode.push_back({0, 0, 0, 0, interleave_dc}); progressive_mode.push_back({1, 2, 0, 0, false}); progressive_mode.push_back({3, 63, 0, 2, false}); progressive_mode.push_back({3, 63, 2, 1, false}); progressive_mode.push_back({3, 63, 1, 0, false}); } cinfo->script_space_size = 0; for (const auto& scan : progressive_mode) { int comps = scan.interleaved ? MAX_COMPS_IN_SCAN : 1; cinfo->script_space_size += DivCeil(cinfo->num_components, comps); } cinfo->script_space = Allocate(cinfo, cinfo->script_space_size); jpeg_scan_info* next_scan = cinfo->script_space; for (const auto& scan : progressive_mode) { int comps = scan.interleaved ? MAX_COMPS_IN_SCAN : 1; for (int c = 0; c < cinfo->num_components; c += comps) { next_scan->Ss = scan.Ss; next_scan->Se = scan.Se; next_scan->Ah = scan.Ah; next_scan->Al = scan.Al; next_scan->comps_in_scan = std::min(comps, cinfo->num_components - c); for (int j = 0; j < next_scan->comps_in_scan; ++j) { next_scan->component_index[j] = c + j; } ++next_scan; } } JXL_ASSERT(next_scan - cinfo->script_space == cinfo->script_space_size); cinfo->scan_info = cinfo->script_space; cinfo->num_scans = cinfo->script_space_size; } void ValidateScanScript(j_compress_ptr cinfo) { // Mask of coefficient bits defined by the scan script, for each component // and coefficient index. uint16_t comp_mask[kMaxComponents][DCTSIZE2] = {}; static constexpr int kMaxRefinementBit = 10; for (int i = 0; i < cinfo->num_scans; ++i) { const jpeg_scan_info& si = cinfo->scan_info[i]; if (si.comps_in_scan < 1 || si.comps_in_scan > MAX_COMPS_IN_SCAN) { JPEGLI_ERROR("Invalid number of components in scan %d", si.comps_in_scan); } int last_ci = -1; for (int j = 0; j < si.comps_in_scan; ++j) { int ci = si.component_index[j]; if (ci < 0 || ci >= cinfo->num_components) { JPEGLI_ERROR("Invalid component index %d in scan", ci); } else if (ci == last_ci) { JPEGLI_ERROR("Duplicate component index %d in scan", ci); } else if (ci < last_ci) { JPEGLI_ERROR("Out of order component index %d in scan", ci); } last_ci = ci; } if (si.Ss < 0 || si.Se < si.Ss || si.Se >= DCTSIZE2) { JPEGLI_ERROR("Invalid spectral range %d .. %d in scan", si.Ss, si.Se); } if (si.Ah < 0 || si.Al < 0 || si.Al > kMaxRefinementBit) { JPEGLI_ERROR("Invalid refinement bits %d/%d", si.Ah, si.Al); } if (!cinfo->progressive_mode) { if (si.Ss != 0 || si.Se != DCTSIZE2 - 1 || si.Ah != 0 || si.Al != 0) { JPEGLI_ERROR("Invalid scan for sequential mode"); } } else { if (si.Ss == 0 && si.Se != 0) { JPEGLI_ERROR("DC and AC together in progressive scan"); } } if (si.Ss != 0 && si.comps_in_scan != 1) { JPEGLI_ERROR("Interleaved AC only scan."); } for (int j = 0; j < si.comps_in_scan; ++j) { int ci = si.component_index[j]; if (si.Ss != 0 && comp_mask[ci][0] == 0) { JPEGLI_ERROR("AC before DC in component %d of scan", ci); } for (int k = si.Ss; k <= si.Se; ++k) { if (comp_mask[ci][k] == 0) { if (si.Ah != 0) { JPEGLI_ERROR("Invalid first scan refinement bit"); } comp_mask[ci][k] = ((0xffff << si.Al) & 0xffff); } else { if (comp_mask[ci][k] != ((0xffff << si.Ah) & 0xffff) || si.Al != si.Ah - 1) { JPEGLI_ERROR("Invalid refinement bit progression."); } comp_mask[ci][k] |= 1 << si.Al; } } } if (si.comps_in_scan > 1) { size_t mcu_size = 0; for (int j = 0; j < si.comps_in_scan; ++j) { int ci = si.component_index[j]; jpeg_component_info* comp = &cinfo->comp_info[ci]; mcu_size += comp->h_samp_factor * comp->v_samp_factor; } if (mcu_size > C_MAX_BLOCKS_IN_MCU) { JPEGLI_ERROR("MCU size too big"); } } } for (int c = 0; c < cinfo->num_components; ++c) { for (int k = 0; k < DCTSIZE2; ++k) { if (comp_mask[c][k] != 0xffff) { JPEGLI_ERROR("Incomplete scan of component %d and frequency %d", c, k); } } } } void ProcessCompressionParams(j_compress_ptr cinfo) { if (cinfo->dest == nullptr) { JPEGLI_ERROR("Missing destination."); } if (cinfo->image_width < 1 || cinfo->image_height < 1 || cinfo->input_components < 1) { JPEGLI_ERROR("Empty input image."); } if (cinfo->image_width > static_cast(JPEG_MAX_DIMENSION) || cinfo->image_height > static_cast(JPEG_MAX_DIMENSION) || cinfo->input_components > static_cast(kMaxComponents)) { JPEGLI_ERROR("Input image too big."); } if (cinfo->num_components < 1 || cinfo->num_components > static_cast(kMaxComponents)) { JPEGLI_ERROR("Invalid number of components."); } if (cinfo->data_precision != kJpegPrecision) { JPEGLI_ERROR("Invalid data precision"); } if (cinfo->arith_code) { JPEGLI_ERROR("Arithmetic coding is not implemented."); } if (cinfo->CCIR601_sampling) { JPEGLI_ERROR("CCIR601 sampling is not implemented."); } if (cinfo->restart_interval > 65535u) { JPEGLI_ERROR("Restart interval too big"); } if (cinfo->smoothing_factor < 0 || cinfo->smoothing_factor > 100) { JPEGLI_ERROR("Invalid smoothing factor %d", cinfo->smoothing_factor); } jpeg_comp_master* m = cinfo->master; cinfo->max_h_samp_factor = cinfo->max_v_samp_factor = 1; for (int c = 0; c < cinfo->num_components; ++c) { jpeg_component_info* comp = &cinfo->comp_info[c]; if (comp->component_index != c) { JPEGLI_ERROR("Invalid component index"); } for (int j = 0; j < c; ++j) { if (cinfo->comp_info[j].component_id == comp->component_id) { JPEGLI_ERROR("Duplicate component id %d", comp->component_id); } } if (comp->h_samp_factor <= 0 || comp->v_samp_factor <= 0 || comp->h_samp_factor > MAX_SAMP_FACTOR || comp->v_samp_factor > MAX_SAMP_FACTOR) { JPEGLI_ERROR("Invalid sampling factor %d x %d", comp->h_samp_factor, comp->v_samp_factor); } cinfo->max_h_samp_factor = std::max(comp->h_samp_factor, cinfo->max_h_samp_factor); cinfo->max_v_samp_factor = std::max(comp->v_samp_factor, cinfo->max_v_samp_factor); } if (cinfo->num_components == 1 && (cinfo->max_h_samp_factor != 1 || cinfo->max_v_samp_factor != 1)) { JPEGLI_ERROR("Sampling is not supported for simgle component image."); } size_t iMCU_width = DCTSIZE * cinfo->max_h_samp_factor; size_t iMCU_height = DCTSIZE * cinfo->max_v_samp_factor; size_t total_iMCU_cols = DivCeil(cinfo->image_width, iMCU_width); cinfo->total_iMCU_rows = DivCeil(cinfo->image_height, iMCU_height); m->xsize_blocks = total_iMCU_cols * cinfo->max_h_samp_factor; m->ysize_blocks = cinfo->total_iMCU_rows * cinfo->max_v_samp_factor; size_t blocks_per_iMCU = 0; for (int c = 0; c < cinfo->num_components; ++c) { jpeg_component_info* comp = &cinfo->comp_info[c]; if (cinfo->max_h_samp_factor % comp->h_samp_factor != 0 || cinfo->max_v_samp_factor % comp->v_samp_factor != 0) { JPEGLI_ERROR("Non-integral sampling ratios are not supported."); } m->h_factor[c] = cinfo->max_h_samp_factor / comp->h_samp_factor; m->v_factor[c] = cinfo->max_v_samp_factor / comp->v_samp_factor; comp->downsampled_width = DivCeil(cinfo->image_width, m->h_factor[c]); comp->downsampled_height = DivCeil(cinfo->image_height, m->v_factor[c]); comp->width_in_blocks = DivCeil(comp->downsampled_width, DCTSIZE); comp->height_in_blocks = DivCeil(comp->downsampled_height, DCTSIZE); blocks_per_iMCU += comp->h_samp_factor * comp->v_samp_factor; } m->blocks_per_iMCU_row = total_iMCU_cols * blocks_per_iMCU; // Disable adaptive quantization for subsampled luma channel. int y_channel = cinfo->jpeg_color_space == JCS_RGB ? 1 : 0; jpeg_component_info* y_comp = &cinfo->comp_info[y_channel]; if (y_comp->h_samp_factor != cinfo->max_h_samp_factor || y_comp->v_samp_factor != cinfo->max_v_samp_factor) { m->use_adaptive_quantization = false; } if (cinfo->scan_info == nullptr) { SetDefaultScanScript(cinfo); } cinfo->progressive_mode = cinfo->scan_info->Ss != 0 || cinfo->scan_info->Se != DCTSIZE2 - 1; ValidateScanScript(cinfo); } void ResetForImage(j_compress_ptr cinfo) { (*cinfo->err->reset_error_mgr)(reinterpret_cast(cinfo)); (*cinfo->dest->init_destination)(cinfo); jpeg_comp_master* m = cinfo->master; m->next_iMCU_row = 0; m->last_restart_interval = 0; m->last_dht_index = 0; m->num_huffman_codes = 0; if (cinfo->num_scans > 0) { m->scan_coding_info = Allocate(cinfo, cinfo->num_scans, JPOOL_IMAGE_ALIGNED); } } bool IsStreamingSupported(j_compress_ptr cinfo) { if (cinfo->global_state == kEncWriteCoeffs) { return false; } // TODO(szabadka) Remove this restriction. if (cinfo->restart_interval > 0 || cinfo->restart_in_rows > 0) { return false; } if (cinfo->optimize_coding || cinfo->num_scans > 1) { return false; } return true; } bool IsSinglePassOptimizerSupported(j_compress_ptr cinfo) { return cinfo->num_scans == 1 && cinfo->optimize_coding && cinfo->restart_interval == 0 && cinfo->restart_in_rows == 0; } void AllocateBuffers(j_compress_ptr cinfo) { jpeg_comp_master* m = cinfo->master; size_t iMCU_width = DCTSIZE * cinfo->max_h_samp_factor; size_t iMCU_height = DCTSIZE * cinfo->max_v_samp_factor; size_t total_iMCU_cols = DivCeil(cinfo->image_width, iMCU_width); size_t xsize_full = total_iMCU_cols * iMCU_width; size_t ysize_full = 3 * iMCU_height; if (!cinfo->raw_data_in) { int num_all_components = std::max(cinfo->input_components, cinfo->num_components); for (int c = 0; c < num_all_components; ++c) { m->input_buffer[c].Allocate(cinfo, ysize_full, xsize_full); } } for (int c = 0; c < cinfo->num_components; ++c) { jpeg_component_info* comp = &cinfo->comp_info[c]; size_t xsize = total_iMCU_cols * comp->h_samp_factor * DCTSIZE; size_t ysize = 3 * comp->v_samp_factor * DCTSIZE; if (cinfo->raw_data_in) { m->input_buffer[c].Allocate(cinfo, ysize, xsize); } m->smooth_input[c] = &m->input_buffer[c]; if (!cinfo->raw_data_in && cinfo->smoothing_factor) { m->smooth_input[c] = Allocate>(cinfo, 1, JPOOL_IMAGE); m->smooth_input[c]->Allocate(cinfo, ysize_full, xsize_full); } m->raw_data[c] = m->smooth_input[c]; if (!cinfo->raw_data_in && (m->h_factor[c] > 1 || m->v_factor[c] > 1)) { m->raw_data[c] = Allocate>(cinfo, 1, JPOOL_IMAGE); m->raw_data[c]->Allocate(cinfo, ysize, xsize); } m->quant_mul[c] = Allocate(cinfo, DCTSIZE2, JPOOL_IMAGE_ALIGNED); } m->dct_buffer = Allocate(cinfo, 2 * DCTSIZE2, JPOOL_IMAGE_ALIGNED); m->block_tmp = Allocate(cinfo, DCTSIZE2 * 4, JPOOL_IMAGE_ALIGNED); if (!IsStreamingSupported(cinfo)) { m->coeff_buffers = Allocate(cinfo, cinfo->num_components, JPOOL_IMAGE); for (int c = 0; c < cinfo->num_components; ++c) { jpeg_component_info* comp = &cinfo->comp_info[c]; const size_t xsize_blocks = comp->width_in_blocks; const size_t ysize_blocks = comp->height_in_blocks; m->coeff_buffers[c] = (*cinfo->mem->request_virt_barray)( reinterpret_cast(cinfo), JPOOL_IMAGE, /*pre_zero=*/false, xsize_blocks, ysize_blocks, comp->v_samp_factor); } } if (m->use_adaptive_quantization) { int y_channel = cinfo->jpeg_color_space == JCS_RGB ? 1 : 0; jpeg_component_info* y_comp = &cinfo->comp_info[y_channel]; const size_t xsize_blocks = y_comp->width_in_blocks; const size_t vecsize = VectorSize(); const size_t xsize_padded = DivCeil(2 * xsize_blocks, vecsize) * vecsize; m->diff_buffer = Allocate(cinfo, xsize_blocks * DCTSIZE + 8, JPOOL_IMAGE_ALIGNED); m->fuzzy_erosion_tmp.Allocate(cinfo, 2, xsize_padded); m->pre_erosion.Allocate(cinfo, 6 * cinfo->max_v_samp_factor, xsize_padded); m->quant_field.Allocate(cinfo, cinfo->max_v_samp_factor, xsize_blocks); for (int c = 0; c < cinfo->num_components; ++c) { m->zero_bias_offset[c] = Allocate(cinfo, DCTSIZE2, JPOOL_IMAGE_ALIGNED); m->zero_bias_mul[c] = Allocate(cinfo, DCTSIZE2, JPOOL_IMAGE_ALIGNED); } } } void ReadInputRow(j_compress_ptr cinfo, const uint8_t* scanline, float* row[kMaxComponents]) { jpeg_comp_master* m = cinfo->master; int num_all_components = std::max(cinfo->input_components, cinfo->num_components); for (int c = 0; c < num_all_components; ++c) { row[c] = m->input_buffer[c].Row(m->next_input_row); } ++m->next_input_row; if (scanline == nullptr) { for (int c = 0; c < cinfo->input_components; ++c) { memset(row[c], 0, cinfo->image_width * sizeof(row[c][0])); } return; } (*m->input_method)(scanline, cinfo->image_width, row); } void PadInputBuffer(j_compress_ptr cinfo, float* row[kMaxComponents]) { jpeg_comp_master* m = cinfo->master; const size_t len0 = cinfo->image_width; const size_t len1 = m->xsize_blocks * DCTSIZE; for (int c = 0; c < cinfo->num_components; ++c) { // Pad row to a multiple of the iMCU width, plus create a border of 1 // repeated pixel for adaptive quant field calculation. float last_val = row[c][len0 - 1]; for (size_t x = len0; x <= len1; ++x) { row[c][x] = last_val; } row[c][-1] = row[c][0]; } if (m->next_input_row == cinfo->image_height) { size_t num_rows = m->ysize_blocks * DCTSIZE - cinfo->image_height; for (size_t i = 0; i < num_rows; ++i) { for (int c = 0; c < cinfo->num_components; ++c) { float* dest = m->input_buffer[c].Row(m->next_input_row) - 1; memcpy(dest, row[c] - 1, (len1 + 2) * sizeof(dest[0])); } ++m->next_input_row; } } } void ProcessiMCURow(j_compress_ptr cinfo) { JXL_ASSERT(cinfo->master->next_iMCU_row < cinfo->total_iMCU_rows); if (!cinfo->raw_data_in) { ApplyInputSmoothing(cinfo); DownsampleInputBuffer(cinfo); } ComputeAdaptiveQuantField(cinfo); if (IsStreamingSupported(cinfo)) { WriteiMCURow(cinfo); } else { ComputeDCTCoefficients(cinfo); } ++cinfo->master->next_iMCU_row; } void ProcessiMCURows(j_compress_ptr cinfo) { jpeg_comp_master* m = cinfo->master; size_t iMCU_height = DCTSIZE * cinfo->max_v_samp_factor; // To have context rows both above and below the current iMCU row, we delay // processing the first iMCU row and process two iMCU rows after we receive // the last input row. if (m->next_input_row % iMCU_height == 0 && m->next_input_row > iMCU_height) { ProcessiMCURow(cinfo); } if (m->next_input_row >= cinfo->image_height) { ProcessiMCURow(cinfo); } } void InitProgressMonitor(j_compress_ptr cinfo) { if (cinfo->progress == nullptr) { return; } if (IsStreamingSupported(cinfo)) { // We have only one input pass. cinfo->progress->total_passes = 1; } else if (IsSinglePassOptimizerSupported(cinfo)) { // We have one input pass and an encode pass for each scan. cinfo->progress->total_passes = 1 + cinfo->num_scans; } else { // We have one input pass, a histogram pass for each scan, and an encode // pass for each scan. cinfo->progress->total_passes = 1 + 2 * cinfo->num_scans; } } void ProgressMonitorInputPass(j_compress_ptr cinfo) { if (cinfo->progress == nullptr) { return; } cinfo->progress->completed_passes = 0; cinfo->progress->pass_counter = cinfo->next_scanline; cinfo->progress->pass_limit = cinfo->image_height; (*cinfo->progress->progress_monitor)(reinterpret_cast(cinfo)); } void WriteFileHeader(j_compress_ptr cinfo) { WriteOutput(cinfo, {0xFF, 0xD8}); // SOI if (cinfo->write_JFIF_header) { EncodeAPP0(cinfo); } if (cinfo->write_Adobe_marker) { EncodeAPP14(cinfo); } } void WriteScanHeader(j_compress_ptr cinfo, size_t scan_idx) { jpeg_comp_master* m = cinfo->master; cinfo->restart_interval = RestartIntervalForScan(cinfo, scan_idx); if (cinfo->restart_interval != m->last_restart_interval) { EncodeDRI(cinfo); m->last_restart_interval = cinfo->restart_interval; } size_t num_dht = cinfo->master->scan_coding_info[scan_idx].num_huffman_codes; if (num_dht > 0) { bool pre_shifted = IsStreamingSupported(cinfo); EncodeDHT(cinfo, m->huffman_codes + m->last_dht_index, num_dht, pre_shifted); m->last_dht_index += num_dht; } EncodeSOS(cinfo, scan_idx); } void WriteHeaderMarkers(j_compress_ptr cinfo) { bool is_baseline = true; CopyHuffmanCodes(cinfo, &is_baseline); EncodeDQT(cinfo, /*write_all_tables=*/false, &is_baseline); EncodeSOF(cinfo, is_baseline); WriteScanHeader(cinfo, 0); memset(cinfo->master->last_dc_coeff, 0, sizeof(cinfo->master->last_dc_coeff)); } void EncodeScans(j_compress_ptr cinfo) { if (IsSinglePassOptimizerSupported(cinfo)) { EncodeSingleScan(cinfo); return; } bool is_baseline = false; if (cinfo->optimize_coding || cinfo->progressive_mode) { OptimizeHuffmanCodes(cinfo, &is_baseline); } else { CopyHuffmanCodes(cinfo, &is_baseline); } EncodeDQT(cinfo, /*write_all_tables=*/false, &is_baseline); EncodeSOF(cinfo, is_baseline); for (int i = 0; i < cinfo->num_scans; ++i) { WriteScanHeader(cinfo, i); if (!EncodeScan(cinfo, i)) { JPEGLI_ERROR("Failed to encode scan."); } } } } // namespace jpegli void jpegli_CreateCompress(j_compress_ptr cinfo, int version, size_t structsize) { cinfo->mem = nullptr; if (structsize != sizeof(*cinfo)) { JPEGLI_ERROR("jpegli_compress_struct has wrong size."); } jpegli::InitMemoryManager(reinterpret_cast(cinfo)); cinfo->progress = nullptr; cinfo->is_decompressor = FALSE; cinfo->global_state = jpegli::kEncStart; cinfo->dest = nullptr; cinfo->image_width = 0; cinfo->image_height = 0; cinfo->input_components = 0; cinfo->in_color_space = JCS_UNKNOWN; cinfo->input_gamma = 1.0f; cinfo->num_components = 0; cinfo->jpeg_color_space = JCS_UNKNOWN; cinfo->comp_info = nullptr; for (int i = 0; i < NUM_QUANT_TBLS; ++i) { cinfo->quant_tbl_ptrs[i] = nullptr; } for (int i = 0; i < NUM_HUFF_TBLS; ++i) { cinfo->dc_huff_tbl_ptrs[i] = nullptr; cinfo->ac_huff_tbl_ptrs[i] = nullptr; } memset(cinfo->arith_dc_L, 0, sizeof(cinfo->arith_dc_L)); memset(cinfo->arith_dc_U, 0, sizeof(cinfo->arith_dc_U)); memset(cinfo->arith_ac_K, 0, sizeof(cinfo->arith_ac_K)); cinfo->write_Adobe_marker = false; jpegli::InitializeCompressParams(cinfo); cinfo->master = jpegli::Allocate(cinfo, 1); cinfo->master->force_baseline = true; cinfo->master->xyb_mode = false; cinfo->master->cicp_transfer_function = 2; // unknown transfer function code cinfo->master->use_std_tables = false; cinfo->master->use_adaptive_quantization = true; cinfo->master->progressive_level = jpegli::kDefaultProgressiveLevel; cinfo->master->data_type = JPEGLI_TYPE_UINT8; cinfo->master->endianness = JPEGLI_NATIVE_ENDIAN; cinfo->master->coeff_buffers = nullptr; } void jpegli_set_xyb_mode(j_compress_ptr cinfo) { CheckState(cinfo, jpegli::kEncStart); cinfo->master->xyb_mode = true; } void jpegli_set_cicp_transfer_function(j_compress_ptr cinfo, int code) { CheckState(cinfo, jpegli::kEncStart); cinfo->master->cicp_transfer_function = code; } void jpegli_set_defaults(j_compress_ptr cinfo) { CheckState(cinfo, jpegli::kEncStart); jpegli::InitializeCompressParams(cinfo); jpegli_default_colorspace(cinfo); jpegli_set_quality(cinfo, 90, TRUE); jpegli_set_progressive_level(cinfo, jpegli::kDefaultProgressiveLevel); jpegli::AddStandardHuffmanTables(reinterpret_cast(cinfo), /*is_dc=*/false); jpegli::AddStandardHuffmanTables(reinterpret_cast(cinfo), /*is_dc=*/true); } void jpegli_default_colorspace(j_compress_ptr cinfo) { CheckState(cinfo, jpegli::kEncStart); switch (cinfo->in_color_space) { case JCS_GRAYSCALE: jpegli_set_colorspace(cinfo, JCS_GRAYSCALE); break; case JCS_RGB: { if (cinfo->master->xyb_mode) { jpegli_set_colorspace(cinfo, JCS_RGB); } else { jpegli_set_colorspace(cinfo, JCS_YCbCr); } break; } case JCS_YCbCr: jpegli_set_colorspace(cinfo, JCS_YCbCr); break; case JCS_CMYK: jpegli_set_colorspace(cinfo, JCS_CMYK); break; case JCS_YCCK: jpegli_set_colorspace(cinfo, JCS_YCCK); break; case JCS_UNKNOWN: jpegli_set_colorspace(cinfo, JCS_UNKNOWN); break; default: JPEGLI_ERROR("Unsupported input colorspace %d", cinfo->in_color_space); } } void jpegli_set_colorspace(j_compress_ptr cinfo, J_COLOR_SPACE colorspace) { CheckState(cinfo, jpegli::kEncStart); cinfo->jpeg_color_space = colorspace; switch (colorspace) { case JCS_GRAYSCALE: cinfo->num_components = 1; break; case JCS_RGB: case JCS_YCbCr: cinfo->num_components = 3; break; case JCS_CMYK: case JCS_YCCK: cinfo->num_components = 4; break; case JCS_UNKNOWN: cinfo->num_components = std::min(jpegli::kMaxComponents, cinfo->input_components); break; default: JPEGLI_ERROR("Unsupported jpeg colorspace %d", colorspace); } // Adobe marker is only needed to distinguish CMYK and YCCK JPEGs. cinfo->write_Adobe_marker = (cinfo->jpeg_color_space == JCS_YCCK); if (cinfo->comp_info == nullptr) { cinfo->comp_info = jpegli::Allocate(cinfo, MAX_COMPONENTS); } memset(cinfo->comp_info, 0, jpegli::kMaxComponents * sizeof(jpeg_component_info)); for (int c = 0; c < cinfo->num_components; ++c) { jpeg_component_info* comp = &cinfo->comp_info[c]; comp->component_index = c; comp->component_id = c + 1; comp->h_samp_factor = 1; comp->v_samp_factor = 1; comp->quant_tbl_no = 0; comp->dc_tbl_no = 0; comp->ac_tbl_no = 0; } if (colorspace == JCS_RGB) { cinfo->comp_info[0].component_id = 'R'; cinfo->comp_info[1].component_id = 'G'; cinfo->comp_info[2].component_id = 'B'; if (cinfo->master->xyb_mode) { // Subsample blue channel. cinfo->comp_info[0].h_samp_factor = cinfo->comp_info[0].v_samp_factor = 2; cinfo->comp_info[1].h_samp_factor = cinfo->comp_info[1].v_samp_factor = 2; cinfo->comp_info[2].h_samp_factor = cinfo->comp_info[2].v_samp_factor = 1; // Use separate quantization tables for each component cinfo->comp_info[1].quant_tbl_no = 1; cinfo->comp_info[2].quant_tbl_no = 2; } } else if (colorspace == JCS_CMYK) { cinfo->comp_info[0].component_id = 'C'; cinfo->comp_info[1].component_id = 'M'; cinfo->comp_info[2].component_id = 'Y'; cinfo->comp_info[3].component_id = 'K'; } else if (colorspace == JCS_YCbCr || colorspace == JCS_YCCK) { // Use separate quantization and Huffman tables for luma and chroma cinfo->comp_info[1].quant_tbl_no = 1; cinfo->comp_info[2].quant_tbl_no = 1; cinfo->comp_info[1].dc_tbl_no = cinfo->comp_info[1].ac_tbl_no = 1; cinfo->comp_info[2].dc_tbl_no = cinfo->comp_info[2].ac_tbl_no = 1; } } void jpegli_set_distance(j_compress_ptr cinfo, float distance, boolean force_baseline) { CheckState(cinfo, jpegli::kEncStart); cinfo->master->force_baseline = force_baseline; float distances[NUM_QUANT_TBLS] = {distance, distance, distance}; jpegli::SetQuantMatrices(cinfo, distances, /*add_two_chroma_tables=*/true); } float jpegli_quality_to_distance(int quality) { return (quality >= 100 ? 0.01f : quality >= 30 ? 0.1f + (100 - quality) * 0.09f : 53.0f / 3000.0f * quality * quality - 23.0f / 20.0f * quality + 25.0f); } void jpegli_set_quality(j_compress_ptr cinfo, int quality, boolean force_baseline) { CheckState(cinfo, jpegli::kEncStart); cinfo->master->force_baseline = force_baseline; float distance = jpegli_quality_to_distance(quality); float distances[NUM_QUANT_TBLS] = {distance, distance, distance}; jpegli::SetQuantMatrices(cinfo, distances, /*add_two_chroma_tables=*/false); } void jpegli_set_linear_quality(j_compress_ptr cinfo, int scale_factor, boolean force_baseline) { CheckState(cinfo, jpegli::kEncStart); cinfo->master->force_baseline = force_baseline; float distance = jpegli::LinearQualityToDistance(scale_factor); float distances[NUM_QUANT_TBLS] = {distance, distance, distance}; jpegli::SetQuantMatrices(cinfo, distances, /*add_two_chroma_tables=*/false); } #if JPEG_LIB_VERSION >= 70 void jpegli_default_qtables(j_compress_ptr cinfo, boolean force_baseline) { CheckState(cinfo, jpegli::kEncStart); cinfo->master->force_baseline = force_baseline; float distances[NUM_QUANT_TBLS]; for (int i = 0; i < NUM_QUANT_TBLS; ++i) { distances[i] = jpegli::LinearQualityToDistance(cinfo->q_scale_factor[i]); } jpegli::SetQuantMatrices(cinfo, distances, /*add_two_chroma_tables=*/false); } #endif int jpegli_quality_scaling(int quality) { quality = std::min(100, std::max(1, quality)); return quality < 50 ? 5000 / quality : 200 - 2 * quality; } void jpegli_use_standard_quant_tables(j_compress_ptr cinfo) { CheckState(cinfo, jpegli::kEncStart); cinfo->master->use_std_tables = true; } void jpegli_add_quant_table(j_compress_ptr cinfo, int which_tbl, const unsigned int* basic_table, int scale_factor, boolean force_baseline) { CheckState(cinfo, jpegli::kEncStart); if (which_tbl < 0 || which_tbl > NUM_QUANT_TBLS) { JPEGLI_ERROR("Invalid quant table index %d", which_tbl); } if (cinfo->quant_tbl_ptrs[which_tbl] == nullptr) { cinfo->quant_tbl_ptrs[which_tbl] = jpegli_alloc_quant_table(reinterpret_cast(cinfo)); } int max_qval = force_baseline ? 255 : 32767U; JQUANT_TBL* quant_table = cinfo->quant_tbl_ptrs[which_tbl]; for (int k = 0; k < DCTSIZE2; ++k) { int qval = (basic_table[k] * scale_factor + 50) / 100; qval = std::max(1, std::min(qval, max_qval)); quant_table->quantval[k] = qval; } quant_table->sent_table = FALSE; } void jpegli_enable_adaptive_quantization(j_compress_ptr cinfo, boolean value) { CheckState(cinfo, jpegli::kEncStart); cinfo->master->use_adaptive_quantization = value; } void jpegli_simple_progression(j_compress_ptr cinfo) { CheckState(cinfo, jpegli::kEncStart); jpegli_set_progressive_level(cinfo, 2); } void jpegli_set_progressive_level(j_compress_ptr cinfo, int level) { CheckState(cinfo, jpegli::kEncStart); if (level < 0) { JPEGLI_ERROR("Invalid progressive level %d", level); } cinfo->master->progressive_level = level; } void jpegli_set_input_format(j_compress_ptr cinfo, JpegliDataType data_type, JpegliEndianness endianness) { CheckState(cinfo, jpegli::kEncStart); switch (data_type) { case JPEGLI_TYPE_UINT8: case JPEGLI_TYPE_UINT16: case JPEGLI_TYPE_FLOAT: cinfo->master->data_type = data_type; break; default: JPEGLI_ERROR("Unsupported data type %d", data_type); } switch (endianness) { case JPEGLI_NATIVE_ENDIAN: case JPEGLI_LITTLE_ENDIAN: case JPEGLI_BIG_ENDIAN: cinfo->master->endianness = endianness; break; default: JPEGLI_ERROR("Unsupported endianness %d", endianness); } } #if JPEG_LIB_VERSION >= 70 void jpegli_calc_jpeg_dimensions(j_compress_ptr cinfo) { // Since input scaling is not supported, we just copy the image dimensions. cinfo->jpeg_width = cinfo->image_width; cinfo->jpeg_height = cinfo->image_height; } #endif void jpegli_copy_critical_parameters(j_decompress_ptr srcinfo, j_compress_ptr dstinfo) { CheckState(dstinfo, jpegli::kEncStart); // Image parameters. dstinfo->image_width = srcinfo->image_width; dstinfo->image_height = srcinfo->image_height; dstinfo->input_components = srcinfo->num_components; dstinfo->in_color_space = srcinfo->jpeg_color_space; dstinfo->input_gamma = srcinfo->output_gamma; // Compression parameters. jpegli_set_defaults(dstinfo); jpegli_set_colorspace(dstinfo, srcinfo->jpeg_color_space); if (dstinfo->num_components != srcinfo->num_components) { const auto& cinfo = dstinfo; return JPEGLI_ERROR("Mismatch between src colorspace and components"); } dstinfo->data_precision = srcinfo->data_precision; dstinfo->CCIR601_sampling = srcinfo->CCIR601_sampling; dstinfo->JFIF_major_version = srcinfo->JFIF_major_version; dstinfo->JFIF_minor_version = srcinfo->JFIF_minor_version; dstinfo->density_unit = srcinfo->density_unit; dstinfo->X_density = srcinfo->X_density; dstinfo->Y_density = srcinfo->Y_density; for (int c = 0; c < dstinfo->num_components; ++c) { jpeg_component_info* srccomp = &srcinfo->comp_info[c]; jpeg_component_info* dstcomp = &dstinfo->comp_info[c]; dstcomp->component_id = srccomp->component_id; dstcomp->h_samp_factor = srccomp->h_samp_factor; dstcomp->v_samp_factor = srccomp->v_samp_factor; dstcomp->quant_tbl_no = srccomp->quant_tbl_no; } for (int i = 0; i < NUM_QUANT_TBLS; ++i) { if (!srcinfo->quant_tbl_ptrs[i]) continue; if (dstinfo->quant_tbl_ptrs[i] == nullptr) { dstinfo->quant_tbl_ptrs[i] = jpegli::Allocate(dstinfo, 1); } memcpy(dstinfo->quant_tbl_ptrs[i], srcinfo->quant_tbl_ptrs[i], sizeof(JQUANT_TBL)); dstinfo->quant_tbl_ptrs[i]->sent_table = FALSE; } } void jpegli_suppress_tables(j_compress_ptr cinfo, boolean suppress) { jpegli::SetSentTableFlag(cinfo->quant_tbl_ptrs, NUM_QUANT_TBLS, suppress); jpegli::SetSentTableFlag(cinfo->dc_huff_tbl_ptrs, NUM_HUFF_TBLS, suppress); jpegli::SetSentTableFlag(cinfo->ac_huff_tbl_ptrs, NUM_HUFF_TBLS, suppress); } void jpegli_start_compress(j_compress_ptr cinfo, boolean write_all_tables) { CheckState(cinfo, jpegli::kEncStart); jpegli::ProcessCompressionParams(cinfo); jpegli::InitProgressMonitor(cinfo); jpegli::AllocateBuffers(cinfo); jpegli::ChooseInputMethod(cinfo); if (!cinfo->raw_data_in) { jpegli::ChooseColorTransform(cinfo); jpegli::ChooseDownsampleMethods(cinfo); } jpegli::InitQuantizer(cinfo); if (write_all_tables) { jpegli_suppress_tables(cinfo, FALSE); } (*cinfo->mem->realize_virt_arrays)(reinterpret_cast(cinfo)); jpegli::ResetForImage(cinfo); jpegli::WriteFileHeader(cinfo); jpegli::JpegBitWriterInit(cinfo); cinfo->next_scanline = 0; cinfo->master->next_input_row = 0; cinfo->global_state = jpegli::kEncHeader; } void jpegli_write_coefficients(j_compress_ptr cinfo, jvirt_barray_ptr* coef_arrays) { CheckState(cinfo, jpegli::kEncStart); jpegli::ProcessCompressionParams(cinfo); jpegli::InitProgressMonitor(cinfo); (*cinfo->mem->realize_virt_arrays)(reinterpret_cast(cinfo)); cinfo->master->coeff_buffers = coef_arrays; jpegli_suppress_tables(cinfo, FALSE); jpegli::ResetForImage(cinfo); jpegli::WriteFileHeader(cinfo); jpegli::JpegBitWriterInit(cinfo); cinfo->next_scanline = cinfo->image_height; cinfo->master->next_input_row = cinfo->image_height; cinfo->global_state = jpegli::kEncWriteCoeffs; } void jpegli_write_tables(j_compress_ptr cinfo) { CheckState(cinfo, jpegli::kEncStart); if (cinfo->dest == nullptr) { JPEGLI_ERROR("Missing destination."); } jpegli::ResetForImage(cinfo); bool is_baseline = true; jpeg_comp_master* m = cinfo->master; jpegli::WriteOutput(cinfo, {0xFF, 0xD8}); // SOI jpegli::EncodeDQT(cinfo, /*write_all_tables=*/true, &is_baseline); jpegli::CopyHuffmanCodes(cinfo, &is_baseline); jpegli::EncodeDHT(cinfo, m->huffman_codes, m->num_huffman_codes); jpegli::WriteOutput(cinfo, {0xFF, 0xD9}); // EOI (*cinfo->dest->term_destination)(cinfo); jpegli_suppress_tables(cinfo, TRUE); } void jpegli_write_m_header(j_compress_ptr cinfo, int marker, unsigned int datalen) { CheckState(cinfo, jpegli::kEncHeader, jpegli::kEncWriteCoeffs); if (datalen > jpegli::kMaxBytesInMarker) { JPEGLI_ERROR("Invalid marker length %u", datalen); } if (marker != 0xfe && (marker < 0xe0 || marker > 0xef)) { JPEGLI_ERROR( "jpegli_write_m_header: Only APP and COM markers are supported."); } std::vector marker_data(4 + datalen); marker_data[0] = 0xff; marker_data[1] = marker; marker_data[2] = (datalen + 2) >> 8; marker_data[3] = (datalen + 2) & 0xff; jpegli::WriteOutput(cinfo, &marker_data[0], 4); } void jpegli_write_m_byte(j_compress_ptr cinfo, int val) { uint8_t data = val; jpegli::WriteOutput(cinfo, &data, 1); } void jpegli_write_marker(j_compress_ptr cinfo, int marker, const JOCTET* dataptr, unsigned int datalen) { jpegli_write_m_header(cinfo, marker, datalen); jpegli::WriteOutput(cinfo, dataptr, datalen); } void jpegli_write_icc_profile(j_compress_ptr cinfo, const JOCTET* icc_data_ptr, unsigned int icc_data_len) { constexpr size_t kMaxIccBytesInMarker = jpegli::kMaxBytesInMarker - sizeof jpegli::kICCSignature - 2; const int num_markers = static_cast(jpegli::DivCeil(icc_data_len, kMaxIccBytesInMarker)); size_t begin = 0; for (int current_marker = 0; current_marker < num_markers; ++current_marker) { const size_t length = std::min(kMaxIccBytesInMarker, icc_data_len - begin); jpegli_write_m_header( cinfo, jpegli::kICCMarker, static_cast(length + sizeof jpegli::kICCSignature + 2)); for (const unsigned char c : jpegli::kICCSignature) { jpegli_write_m_byte(cinfo, c); } jpegli_write_m_byte(cinfo, current_marker + 1); jpegli_write_m_byte(cinfo, num_markers); for (size_t i = 0; i < length; ++i) { jpegli_write_m_byte(cinfo, icc_data_ptr[begin]); ++begin; } } } JDIMENSION jpegli_write_scanlines(j_compress_ptr cinfo, JSAMPARRAY scanlines, JDIMENSION num_lines) { CheckState(cinfo, jpegli::kEncHeader, jpegli::kEncReadImage); if (cinfo->raw_data_in) { JPEGLI_ERROR("jpegli_write_raw_data() must be called for raw data mode."); } jpegli::ProgressMonitorInputPass(cinfo); if (cinfo->global_state == jpegli::kEncHeader && jpegli::IsStreamingSupported(cinfo)) { jpegli::WriteHeaderMarkers(cinfo); } cinfo->global_state = jpegli::kEncReadImage; jpeg_comp_master* m = cinfo->master; if (num_lines + cinfo->next_scanline > cinfo->image_height) { num_lines = cinfo->image_height - cinfo->next_scanline; } JDIMENSION prev_scanline = cinfo->next_scanline; size_t input_lag = (std::min(cinfo->image_height, m->next_input_row) - cinfo->next_scanline); if (input_lag > num_lines) { JPEGLI_ERROR("Need at least %u lines to continue", input_lag); } if (input_lag > 0) { if (!jpegli::EmptyBitWriterBuffer(&m->bw)) { return 0; } cinfo->next_scanline += input_lag; } float* rows[jpegli::kMaxComponents]; for (size_t i = input_lag; i < num_lines; ++i) { jpegli::ReadInputRow(cinfo, scanlines[i], rows); (*m->color_transform)(rows, cinfo->image_width); jpegli::PadInputBuffer(cinfo, rows); jpegli::ProcessiMCURows(cinfo); if (!jpegli::EmptyBitWriterBuffer(&m->bw)) { break; } ++cinfo->next_scanline; } return cinfo->next_scanline - prev_scanline; } JDIMENSION jpegli_write_raw_data(j_compress_ptr cinfo, JSAMPIMAGE data, JDIMENSION num_lines) { CheckState(cinfo, jpegli::kEncHeader, jpegli::kEncReadImage); if (!cinfo->raw_data_in) { JPEGLI_ERROR("jpegli_write_raw_data(): raw data mode was not set"); } jpegli::ProgressMonitorInputPass(cinfo); if (cinfo->global_state == jpegli::kEncHeader && jpegli::IsStreamingSupported(cinfo)) { jpegli::WriteHeaderMarkers(cinfo); } cinfo->global_state = jpegli::kEncReadImage; jpeg_comp_master* m = cinfo->master; if (cinfo->next_scanline >= cinfo->image_height) { return 0; } size_t iMCU_height = DCTSIZE * cinfo->max_v_samp_factor; if (num_lines < iMCU_height) { JPEGLI_ERROR("Missing input lines, minimum is %u", iMCU_height); } if (cinfo->next_scanline < m->next_input_row) { JXL_ASSERT(m->next_input_row - cinfo->next_scanline == iMCU_height); if (!jpegli::EmptyBitWriterBuffer(&m->bw)) { return 0; } cinfo->next_scanline = m->next_input_row; return iMCU_height; } size_t iMCU_y = m->next_input_row / iMCU_height; float* rows[jpegli::kMaxComponents]; for (int c = 0; c < cinfo->num_components; ++c) { JSAMPARRAY plane = data[c]; jpeg_component_info* comp = &cinfo->comp_info[c]; size_t xsize = comp->width_in_blocks * DCTSIZE; size_t ysize = comp->v_samp_factor * DCTSIZE; size_t y0 = iMCU_y * ysize; auto& buffer = m->input_buffer[c]; for (size_t i = 0; i < ysize; ++i) { rows[0] = buffer.Row(y0 + i); if (plane[i] == nullptr) { memset(rows[0], 0, xsize * sizeof(rows[0][0])); } else { (*m->input_method)(plane[i], xsize, rows); } // We need a border of 1 repeated pixel for adaptive quant field. buffer.PadRow(y0 + i, xsize, /*border=*/1); } } m->next_input_row += iMCU_height; jpegli::ProcessiMCURows(cinfo); if (!jpegli::EmptyBitWriterBuffer(&m->bw)) { return 0; } cinfo->next_scanline += iMCU_height; return iMCU_height; } void jpegli_finish_compress(j_compress_ptr cinfo) { CheckState(cinfo, jpegli::kEncReadImage, jpegli::kEncWriteCoeffs); jpeg_comp_master* m = cinfo->master; if (cinfo->next_scanline < cinfo->image_height) { JPEGLI_ERROR("Incomplete image, expected %d rows, got %d", cinfo->image_height, cinfo->next_scanline); } if (jpegli::IsStreamingSupported(cinfo)) { jpegli::JumpToByteBoundary(&m->bw); if (!jpegli::EmptyBitWriterBuffer(&m->bw)) { JPEGLI_ERROR("Output suspension is not supported in finish_compress"); } if (!m->bw.healthy) { JPEGLI_ERROR("Failed to encode scan."); } } else { jpegli::EncodeScans(cinfo); } jpegli::WriteOutput(cinfo, {0xFF, 0xD9}); // EOI (*cinfo->dest->term_destination)(cinfo); // Release memory and reset global state. jpegli_abort_compress(cinfo); } void jpegli_abort_compress(j_compress_ptr cinfo) { jpegli_abort(reinterpret_cast(cinfo)); } void jpegli_destroy_compress(j_compress_ptr cinfo) { jpegli_destroy(reinterpret_cast(cinfo)); }