// 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 "tools/cjxl.h" #include #include #include #include #include #include #include #include "lib/extras/codec.h" #include "lib/extras/time.h" #include "lib/jxl/aux_out.h" #include "lib/jxl/base/cache_aligned.h" #include "lib/jxl/base/compiler_specific.h" #include "lib/jxl/base/data_parallel.h" #include "lib/jxl/base/file_io.h" #include "lib/jxl/base/padded_bytes.h" #include "lib/jxl/base/printf_macros.h" #include "lib/jxl/base/profiler.h" #include "lib/jxl/base/status.h" #include "lib/jxl/base/thread_pool_internal.h" #include "lib/jxl/codec_in_out.h" #include "lib/jxl/common.h" #include "lib/jxl/enc_cache.h" #include "lib/jxl/enc_color_management.h" #include "lib/jxl/enc_file.h" #include "lib/jxl/enc_params.h" #include "lib/jxl/frame_header.h" #include "lib/jxl/image.h" #include "lib/jxl/image_bundle.h" #include "lib/jxl/jpeg/enc_jpeg_data.h" #include "lib/jxl/modular/encoding/encoding.h" #include "tools/args.h" #include "tools/box/box.h" #include "tools/speed_stats.h" namespace jpegxl { namespace tools { namespace { static inline bool ParseSpeedTier(const char* arg, jxl::SpeedTier* out) { return jxl::ParseSpeedTier(arg, out); } static inline bool ParseColorTransform(const char* arg, jxl::ColorTransform* out) { size_t value = 0; bool ret = ParseUnsigned(arg, &value); if (ret && value > 2) ret = false; if (ret) *out = jxl::ColorTransform(value); return ret; } static inline bool ParseIntensityTarget(const char* arg, float* out) { return ParseFloat(arg, out) && *out > 0; } static inline bool ParsePhotonNoiseParameter(const char* arg, float* out) { return strncmp(arg, "ISO", 3) == 0 && ParseFloat(arg + 3, out) && *out > 0; } // Proposes a distance to try for a given bpp target. This could depend // on the entropy in the image, too, but let's start with something. static double ApproximateDistanceForBPP(double bpp) { return 1.704 * pow(bpp, -0.804); } jxl::Status LoadSaliencyMap(const std::string& filename_heatmap, jxl::ThreadPool* pool, jxl::ImageF* out_map) { jxl::CodecInOut io_heatmap; if (!SetFromFile(filename_heatmap, jxl::extras::ColorHints(), &io_heatmap, pool)) { return JXL_FAILURE("Could not load heatmap."); } *out_map = std::move(io_heatmap.Main().color()->Plane(0)); return true; } void SetParametersForSizeOrBitrate(jxl::ThreadPoolInternal* pool, const size_t pixels, CompressArgs* args) { CompressArgs s = *args; // Args for search. // If fixed size, convert to bitrate. if (s.params.target_size > 0) { s.params.target_bitrate = s.params.target_size * 8.0 / pixels; s.params.target_size = 0; } const double target_size = s.params.target_bitrate * (1 / 8.) * pixels; double dist = ApproximateDistanceForBPP(s.params.target_bitrate); s.params.target_bitrate = 0; double best_dist = 1.0; double best_loss = 1e99; jxl::CodecInOut io; double decode_mps = 0; if (!LoadAll(*args, pool, &io, &decode_mps)) { s.params.butteraugli_distance = static_cast(dist); printf("couldn't load image\n"); return; } for (int i = 0; i < 7; ++i) { s.params.butteraugli_distance = static_cast(dist); jxl::PaddedBytes candidate; bool ok = CompressJxl(io, decode_mps, pool, s, &candidate, /*print_stats=*/false); if (!ok) { printf( "Compression error occurred during the search for best size. " "Trying with butteraugli distance %.15g\n", best_dist); break; } printf("Butteraugli distance %.3f yields %6" PRIuS " bytes, %.3f bpp.\n", dist, candidate.size(), candidate.size() * 8.0 / pixels); const double ratio = static_cast(candidate.size()) / target_size; const double loss = std::max(ratio, 1.0 / std::max(ratio, 1e-30)); if (best_loss > loss) { best_dist = dist; best_loss = loss; } dist *= ratio; if (dist < 0.01) { dist = 0.01; } if (dist >= 16.0) { dist = 16.0; } } args->params.butteraugli_distance = static_cast(best_dist); args->params.target_bitrate = 0; args->params.target_size = 0; } const char* ModeFromArgs(const CompressArgs& args) { if (args.jpeg_transcode) return "JPEG"; if (args.params.modular_mode) return "Modular"; return "VarDCT"; } std::string QualityFromArgs(const CompressArgs& args) { char buf[100]; if (args.jpeg_transcode) { snprintf(buf, sizeof(buf), "lossless transcode"); } else if (args.params.IsLossless()) { snprintf(buf, sizeof(buf), "lossless"); } else { snprintf(buf, sizeof(buf), "d%.3f", args.params.butteraugli_distance); } return buf; } void PrintMode(jxl::ThreadPoolInternal* pool, const jxl::CodecInOut& io, const double decode_mps, const CompressArgs& args) { const char* mode = ModeFromArgs(args); const char* speed = SpeedTierName(args.params.speed_tier); const std::string quality = QualityFromArgs(args); fprintf(stderr, "Read %" PRIuS "x%" PRIuS " image, %.1f MP/s\n" "Encoding [%s%s, %s, %s", io.xsize(), io.ysize(), decode_mps, (args.use_container ? "Container | " : ""), mode, quality.c_str(), speed); if (args.use_container) { if (args.jpeg_transcode && args.store_jpeg_metadata) fprintf(stderr, " | JPEG reconstruction data"); if (!io.blobs.exif.empty()) fprintf(stderr, " | %" PRIuS "-byte Exif", io.blobs.exif.size()); if (!io.blobs.xmp.empty()) fprintf(stderr, " | %" PRIuS "-byte XMP", io.blobs.xmp.size()); if (!io.blobs.jumbf.empty()) fprintf(stderr, " | %" PRIuS "-byte JUMBF", io.blobs.jumbf.size()); } fprintf(stderr, "], %" PRIuS " threads.\n", pool->NumWorkerThreads()); } } // namespace void CompressArgs::AddCommandLineOptions(CommandLineParser* cmdline) { // Positional arguments. cmdline->AddPositionalOption("INPUT", /* required = */ true, "the input can be " #if JPEGXL_ENABLE_APNG "PNG, APNG, " #endif #if JPEGXL_ENABLE_GIF "GIF, " #endif #if JPEGXL_ENABLE_JPEG "JPEG, " #else "JPEG (lossless recompression only), " #endif #if JPEGXL_ENABLE_EXR "EXR, " #endif "PPM, PFM, or PGX", &file_in); cmdline->AddPositionalOption( "OUTPUT", /* required = */ true, "the compressed JXL output file (can be omitted for benchmarking)", &file_out); // Flags. // TODO(lode): also add options to add exif/xmp/other metadata in the // container. // TODO(lode): decide on good name for this flag: box, container, bmff, ... cmdline->AddOptionFlag( '\0', "container", "Always encode using container format (default: only if needed)", &use_container, &SetBooleanTrue, 1); cmdline->AddOptionFlag('\0', "strip", "Do not encode using container format (strips " "Exif/XMP/JPEG bitstream reconstruction data)", &no_container, &SetBooleanTrue, 2); cmdline->AddOptionFlag('\0', "strip_jpeg_metadata", "Do not encode JPEG bitstream reconstruction data", &store_jpeg_metadata, &SetBooleanFalse, 2); // Target distance/size/bpp opt_distance_id = cmdline->AddOptionValue( 'd', "distance", "maxError", ("Max. butteraugli distance, lower = higher quality. Range: 0 .. 25.\n" " 0.0 = mathematically lossless. Default for already-lossy input " "(JPEG/GIF).\n" " 1.0 = visually lossless. Default for other input.\n" " Recommended range: 0.5 .. 3.0."), ¶ms.butteraugli_distance, &ParseFloat); opt_target_size_id = cmdline->AddOptionValue( '\0', "target_size", "N", ("Aim at file size of N bytes.\n" " Compresses to 1 % of the target size in ideal conditions.\n" " Runs the same algorithm as --target_bpp"), ¶ms.target_size, &ParseUnsigned, 1); opt_target_bpp_id = cmdline->AddOptionValue( '\0', "target_bpp", "BPP", ("Aim at file size that has N bits per pixel.\n" " Compresses to 1 % of the target BPP in ideal conditions."), ¶ms.target_bitrate, &ParseFloat, 1); // High-level options opt_quality_id = cmdline->AddOptionValue( 'q', "quality", "QUALITY", "Quality setting (is remapped to --distance). Range: -inf .. 100.\n" " 100 = mathematically lossless. Default for already-lossy input " "(JPEG/GIF).\n Positive quality values roughly match libjpeg quality.", &quality, &ParseFloat); cmdline->AddOptionValue( 'e', "effort", "EFFORT", "Encoder effort setting. Range: 1 .. 9.\n" " Default: 7. Higher number is more effort (slower).", ¶ms.speed_tier, &ParseSpeedTier); cmdline->AddOptionValue('\0', "brotli_effort", "B_EFFORT", "Brotli effort setting. Range: 0 .. 11.\n" " Default: -1 (based on EFFORT). Higher number is " "more effort (slower).", ¶ms.brotli_effort, &ParseSigned, -1); cmdline->AddOptionValue( 's', "speed", "ANIMAL", "Deprecated synonym for --effort. Valid values are:\n" " lightning (1), thunder, falcon, cheetah, hare, wombat, squirrel, " "kitten, tortoise (9)\n" " Default: squirrel. Values are in order from faster to slower.\n", ¶ms.speed_tier, &ParseSpeedTier, 2); cmdline->AddOptionValue('\0', "faster_decoding", "AMOUNT", "Favour higher decoding speed. 0 = default, higher " "values give higher speed at the expense of quality", ¶ms.decoding_speed_tier, &ParseUnsigned, 2); cmdline->AddOptionFlag('p', "progressive", "Enable progressive/responsive decoding.", &progressive, &SetBooleanTrue); cmdline->AddOptionFlag('\0', "premultiply", "Force premultiplied (associated) alpha.", &force_premultiplied, &SetBooleanTrue, 1); cmdline->AddOptionValue('\0', "keep_invisible", "0|1", "force disable/enable preserving color of invisible " "pixels (default: 1 if lossless, 0 if lossy).", ¶ms.keep_invisible, &ParseOverride, 1); cmdline->AddOptionFlag('\0', "centerfirst", "Put center groups first in the compressed file.", ¶ms.centerfirst, &SetBooleanTrue, 1); cmdline->AddOptionValue('\0', "center_x", "0..XSIZE", "Put center groups first in the compressed file.", ¶ms.center_x, &ParseUnsigned, 1); cmdline->AddOptionValue('\0', "center_y", "0..YSIZE", "Put center groups first in the compressed file.", ¶ms.center_y, &ParseUnsigned, 1); // Flags. cmdline->AddOptionFlag('\0', "progressive_ac", "Use the progressive mode for AC.", ¶ms.progressive_mode, &SetBooleanTrue, 1); cmdline->AddOptionFlag('\0', "qprogressive_ac", "Use the progressive mode for AC.", ¶ms.qprogressive_mode, &SetBooleanTrue, 1); cmdline->AddOptionValue('\0', "progressive_dc", "num_dc_frames", "Use progressive mode for DC.", ¶ms.progressive_dc, &ParseSigned, 1); cmdline->AddOptionFlag('m', "modular", "Use the modular mode (lossy / lossless).", ¶ms.modular_mode, &SetBooleanTrue, 1); cmdline->AddOptionFlag('\0', "use_new_heuristics", "use new and not yet ready encoder heuristics", ¶ms.use_new_heuristics, &SetBooleanTrue, 2); // JPEG modes: parallel Brunsli, pixels to JPEG, or JPEG to Brunsli cmdline->AddOptionFlag('j', "jpeg_transcode", "Do lossy transcode of input JPEG file (decode to " "pixels instead of doing lossless transcode).", &jpeg_transcode, &SetBooleanFalse, 1); cmdline->AddOptionFlag('\0', "jpeg_transcode_disable_cfl", "Disable CFL for lossless JPEG recompression", ¶ms.force_cfl_jpeg_recompression, &SetBooleanFalse, 2); cmdline->AddOptionValue('\0', "num_threads", "N", "number of worker threads (zero = none).", &num_threads, &ParseUnsigned, 1); cmdline->AddOptionValue('\0', "num_reps", "N", "how many times to compress.", &num_reps, &ParseUnsigned, 1); cmdline->AddOptionValue('\0', "noise", "0|1", "force disable/enable noise generation.", ¶ms.noise, &ParseOverride, 1); cmdline->AddOptionValue( '\0', "photon_noise", "ISO3200", "Set the noise to approximately what it would be at a given nominal " "exposure on a 35mm camera. For formats other than 35mm, or when the " "whole sensor was not used, you can multiply the ISO value by the " "equivalence ratio squared, for example by 2.25 for an APS-C camera.", ¶ms.photon_noise_iso, &ParsePhotonNoiseParameter, 1); cmdline->AddOptionValue('\0', "dots", "0|1", "force disable/enable dots generation.", ¶ms.dots, &ParseOverride, 1); cmdline->AddOptionValue('\0', "patches", "0|1", "force disable/enable patches generation.", ¶ms.patches, &ParseOverride, 1); cmdline->AddOptionValue( '\0', "resampling", "-1|1|2|4|8", "Subsample all color channels by this factor, or use -1 to choose the " "resampling factor based on distance.", ¶ms.resampling, &ParseSigned, 0); cmdline->AddOptionValue( '\0', "ec_resampling", "1|2|4|8", "Subsample all extra channels by this factor. If this value is smaller " "than the resampling of color channels, it will be increased to match.", ¶ms.ec_resampling, &ParseSigned, 2); cmdline->AddOptionFlag('\0', "already_downsampled", "Do not downsample the given input before encoding, " "but still signal that the decoder should upsample.", ¶ms.already_downsampled, &SetBooleanTrue, 2); cmdline->AddOptionValue( '\0', "epf", "-1..3", "Edge preserving filter level (-1 = choose based on quality, default)", ¶ms.epf, &ParseSigned, 1); cmdline->AddOptionValue('\0', "gaborish", "0|1", "force disable/enable gaborish.", ¶ms.gaborish, &ParseOverride, 1); opt_intensity_target_id = cmdline->AddOptionValue( '\0', "intensity_target", "N", ("Intensity target of monitor in nits, higher\n" " results in higher quality image. Must be strictly positive.\n" " Default is 255 for standard images, 4000 for input images known to\n" " to have PQ or HLG transfer function."), &intensity_target, &ParseIntensityTarget, 1); cmdline->AddOptionValue('\0', "saliency_num_progressive_steps", "N", nullptr, ¶ms.saliency_num_progressive_steps, &ParseUnsigned, 2); cmdline->AddOptionValue('\0', "saliency_map_filename", "STRING", nullptr, &saliency_map_filename, &ParseString, 2); cmdline->AddOptionValue('\0', "saliency_threshold", "0..1", nullptr, ¶ms.saliency_threshold, &ParseFloat, 2); cmdline->AddOptionValue( 'x', "dec-hints", "key=value", "color_space indicates the ColorEncoding, see Description();\n" "icc_pathname refers to a binary file containing an ICC profile.", &color_hints, &ParseAndAppendKeyValue, 1); cmdline->AddOptionValue( '\0', "override_bitdepth", "0=use from image, 1-32=override", "If nonzero, store the given bit depth in the JPEG XL file metadata" " (1-32), instead of using the bit depth from the original input" " image.", &override_bitdepth, &ParseUnsigned, 2); opt_color_id = cmdline->AddOptionValue( 'c', "colortransform", "0..2", "0=XYB, 1=None, 2=YCbCr", ¶ms.color_transform, &ParseColorTransform, 2); // modular mode options cmdline->AddOptionValue( 'I', "iterations", "F", "[modular encoding] fraction of pixels used to learn MA trees " "(default=0.5, try 0 for no MA and fast decode)", ¶ms.options.nb_repeats, &ParseFloat, 2); cmdline->AddOptionValue( 'C', "colorspace", "K", ("[modular encoding] color transform: -1=default, 0=RGB (none), " "1-41=RCT (6=YCoCg, default: try several, depending on speed)"), ¶ms.colorspace, &ParseSigned, 1); opt_m_group_size_id = cmdline->AddOptionValue( 'g', "group-size", "K", ("[modular encoding] set group size to 128 << K " "(default: 1 or 2)"), ¶ms.modular_group_size_shift, &ParseUnsigned, 1); cmdline->AddOptionValue( 'P', "predictor", "K", "[modular encoding] predictor(s) to use: 0=zero, " "1=left, 2=top, 3=avg0, 4=select, 5=gradient, 6=weighted, " "7=topright, 8=topleft, 9=leftleft, 10=avg1, 11=avg2, 12=avg3, " "13=toptop predictive average " "14=mix 5 and 6, 15=mix everything. Default 14, at slowest speed " "default 15", ¶ms.options.predictor, &ParsePredictor, 1); cmdline->AddOptionValue( 'E', "extra-properties", "K", "[modular encoding] number of extra MA tree properties to use", ¶ms.options.max_properties, &ParseSigned, 2); cmdline->AddOptionValue('\0', "palette", "K", "[modular encoding] use a palette if image has at " "most K colors (default: 1024)", ¶ms.palette_colors, &ParseSigned, 1); cmdline->AddOptionFlag( '\0', "lossy-palette", "[modular encoding] quantize to a palette that has fewer entries than " "would be necessary for perfect preservation; for the time being, it is " "recommended to set --palette=0 with this option to use the default " "palette only", ¶ms.lossy_palette, &SetBooleanTrue, 1); cmdline->AddOptionValue( 'X', "pre-compact", "PERCENT", ("[modular encoding] compact channels (globally) if ratio " "used/range is below this (default: 80%)"), ¶ms.channel_colors_pre_transform_percent, &ParseFloat, 2); cmdline->AddOptionValue( 'Y', "post-compact", "PERCENT", ("[modular encoding] compact channels (per-group) if ratio " "used/range is below this (default: 80%)"), ¶ms.channel_colors_percent, &ParseFloat, 2); cmdline->AddOptionValue('R', "responsive", "K", "[modular encoding] do Squeeze transform, 0=false, " "1=true (default: true if lossy, false if lossless)", ¶ms.responsive, &ParseSigned, 1); cmdline->AddOptionFlag('V', "version", "Print version number and exit", &version, &SetBooleanTrue, 1); cmdline->AddOptionFlag('\0', "quiet", "Be more silent", &quiet, &SetBooleanTrue, 1); cmdline->AddOptionValue('\0', "print_profile", "0|1", "Print timing information before exiting", &print_profile, &ParseOverride, 1); cmdline->AddOptionFlag( 'v', "verbose", "Verbose output; can be repeated, also applies to help (!).", ¶ms.verbose, &SetBooleanTrue); } jxl::Status CompressArgs::ValidateArgs(const CommandLineParser& cmdline) { params.file_in = file_in; params.file_out = file_out; if (file_in == nullptr) { fprintf(stderr, "Missing INPUT filename.\n"); return false; } bool got_distance = cmdline.GetOption(opt_distance_id)->matched(); bool got_target_size = cmdline.GetOption(opt_target_size_id)->matched(); bool got_target_bpp = cmdline.GetOption(opt_target_bpp_id)->matched(); bool got_quality = cmdline.GetOption(opt_quality_id)->matched(); bool got_intensity_target = cmdline.GetOption(opt_intensity_target_id)->matched(); if (got_quality) { default_settings = false; if (quality < 100) jpeg_transcode = false; if (quality < 7 || quality == 100 || params.modular_mode) { if (jpeg_transcode == false) params.modular_mode = true; } // Quality settings roughly match libjpeg qualities. if (quality >= 100) { params.butteraugli_distance = 0; } else if (quality >= 30) { params.butteraugli_distance = 0.1 + (100 - quality) * 0.09; } else { params.butteraugli_distance = 6.4 + pow(2.5, (30 - quality) / 5.0f) / 6.25f; } } if (params.resampling > 1 && !params.already_downsampled) jpeg_transcode = false; if (progressive) { params.qprogressive_mode = true; params.responsive = 1; default_settings = false; } if (got_target_size || got_target_bpp || got_intensity_target) { default_settings = false; } if (params.progressive_dc < -1 || params.progressive_dc > 2) { fprintf(stderr, "Invalid/out of range progressive_dc (%d), try -1 to 2.\n", params.progressive_dc); return false; } if (got_distance) { constexpr float butteraugli_min_dist = 0.1f; constexpr float butteraugli_max_dist = 25.0f; if (!(0 <= params.butteraugli_distance && params.butteraugli_distance <= butteraugli_max_dist)) { fprintf(stderr, "Invalid/out of range distance, try 0 to %g.\n", butteraugli_max_dist); return false; } if (params.butteraugli_distance > 0) jpeg_transcode = false; if (params.butteraugli_distance == 0) { // Use modular for lossless. if (jpeg_transcode == false) params.modular_mode = true; } else if (params.butteraugli_distance < butteraugli_min_dist) { params.butteraugli_distance = butteraugli_min_dist; } default_settings = false; } if (got_target_bpp || got_target_size) { jpeg_transcode = false; } if (params.brotli_effort > 11) { fprintf(stderr, "Invalid --brotli_effort value\n"); return false; } if (got_target_bpp + got_target_size + got_distance + got_quality > 1) { fprintf(stderr, "You can specify only one of '--distance', '-q', " "'--target_bpp' and '--target_size'. They are all different ways" " to specify the image quality. When in doubt, use --distance." " It gives the most visually consistent results.\n"); return false; } if (!saliency_map_filename.empty()) { if (!params.progressive_mode) { saliency_map_filename.clear(); fprintf(stderr, "Warning: Specifying --saliency_map_filename only makes sense " "for --progressive_ac mode.\n"); } } if (!params.file_in) { fprintf(stderr, "Missing input filename.\n"); return false; } if (!cmdline.GetOption(opt_color_id)->matched()) { // default to RGB for lossless modular if (params.modular_mode) { if (params.butteraugli_distance > 0.f) { params.color_transform = jxl::ColorTransform::kXYB; } else { params.color_transform = jxl::ColorTransform::kNone; } } } if (override_bitdepth > 32) { fprintf(stderr, "override_bitdepth must be <= 32\n"); return false; } if (params.epf > 3) { fprintf(stderr, "--epf must be in the 0..3 range\n"); return false; } return true; } jxl::Status CompressArgs::ValidateArgsAfterLoad( const CommandLineParser& cmdline, const jxl::CodecInOut& io) { if (!ValidateArgs(cmdline)) return false; bool got_m_group_size = cmdline.GetOption(opt_m_group_size_id)->matched(); if (params.modular_mode && !got_m_group_size) { // Default modular group size: set to 512 if 256 would be silly const size_t kThinImageThr = 256 + 64; const size_t kSmallImageThr = 256 + 128; if (io.xsize() < kThinImageThr || io.ysize() < kThinImageThr || (io.xsize() < kSmallImageThr && io.ysize() < kSmallImageThr)) { params.modular_group_size_shift = 2; } } if (!io.blobs.exif.empty() || !io.blobs.xmp.empty() || !io.blobs.jumbf.empty() || !io.blobs.iptc.empty() || (jpeg_transcode && store_jpeg_metadata)) { use_container = true; } if (no_container) use_container = false; if (jpeg_transcode && params.modular_mode) { fprintf(stderr, "Error: cannot do lossless JPEG transcode in modular mode.\n"); return false; } if (jpeg_transcode) { if (params.progressive_mode || params.qprogressive_mode || params.progressive_dc > 0) { fprintf(stderr, "Error: progressive lossless JPEG transcode is not yet " "implemented.\n"); return false; } } return true; } jxl::Status LoadAll(CompressArgs& args, jxl::ThreadPoolInternal* pool, jxl::CodecInOut* io, double* decode_mps) { const double t0 = jxl::Now(); jxl::PaddedBytes encoded; JXL_RETURN_IF_ERROR(jxl::ReadFile(args.params.file_in, &encoded)); jxl::extras::Codec input_codec; bool ok; if (args.jpeg_transcode && encoded.size() >= 2 && encoded[0] == 0xFF && encoded[1] == 0xD8) { input_codec = jxl::extras::Codec::kJPG; ok = jxl::jpeg::DecodeImageJPG(jxl::Span(encoded), io); } else { ok = jxl::SetFromBytes(jxl::Span(encoded), args.color_hints, io, nullptr, &input_codec); } if (!ok) { fprintf(stderr, "Failed to read image %s.\n", args.params.file_in); return false; } if (args.intensity_target != 0) { io->metadata.m.SetIntensityTarget(args.intensity_target); } if (input_codec != jxl::extras::Codec::kJPG) args.jpeg_transcode = false; if (args.jpeg_transcode) args.params.butteraugli_distance = 0; if (input_codec == jxl::extras::Codec::kGIF && args.default_settings) { args.params.modular_mode = true; args.params.butteraugli_distance = 0; } if (args.override_bitdepth != 0) { if (args.override_bitdepth == 32) { io->metadata.m.SetFloat32Samples(); } else { io->metadata.m.SetUintSamples(args.override_bitdepth); } } if (args.force_premultiplied) { io->PremultiplyAlpha(); } jxl::ImageF saliency_map; if (!args.saliency_map_filename.empty()) { if (!LoadSaliencyMap(args.saliency_map_filename, pool, &saliency_map)) { fprintf(stderr, "Failed to read saliency map %s.\n", args.saliency_map_filename.c_str()); return false; } args.params.saliency_map = &saliency_map; } const double t1 = jxl::Now(); const size_t pixels = io->xsize() * io->ysize(); *decode_mps = pixels * io->frames.size() * 1E-6 / (t1 - t0); return true; } jxl::Status CompressJxl(jxl::CodecInOut& io, double decode_mps, jxl::ThreadPoolInternal* pool, CompressArgs& args, jxl::PaddedBytes* compressed, bool print_stats) { JXL_CHECK(pool); const size_t pixels = io.xsize() * io.ysize(); if (args.params.target_size > 0 || args.params.target_bitrate > 0) { // Slow iterative search for parameters that reach target bpp / size. SetParametersForSizeOrBitrate(pool, pixels, &args); } if (print_stats) PrintMode(pool, io, decode_mps, args); // Final/actual compression run (possibly repeated for benchmarking). jxl::AuxOut aux_out; if (args.inspector_image3f) { aux_out.SetInspectorImage3F(args.inspector_image3f); } SpeedStats stats; jxl::PassesEncoderState passes_encoder_state; if (args.params.use_new_heuristics) { passes_encoder_state.heuristics = jxl::make_unique(); } for (size_t i = 0; i < args.num_reps; ++i) { const double t0 = jxl::Now(); jxl::Status ok = false; if (io.Main().IsJPEG()) { // TODO(lode): automate this in the encoder. The encoder must in the // beginning choose to either do all in xyb, or all in non-xyb, write // that in the xyb_encoded header flag, and persistently keep that state // to check if every frame uses an allowed color transform. args.params.color_transform = io.Main().color_transform; } ok = EncodeFile(args.params, &io, &passes_encoder_state, compressed, jxl::GetJxlCms(), &aux_out, pool); if (!ok) { fprintf(stderr, "Failed to compress to %s.\n", ModeFromArgs(args)); return false; } const double t1 = jxl::Now(); stats.NotifyElapsed(t1 - t0); stats.SetImageSize(io.xsize(), io.ysize()); } if (print_stats) { const double bpp = static_cast(compressed->size() * jxl::kBitsPerByte) / pixels; fprintf(stderr, "Compressed to %" PRIuS " bytes (%.3f bpp%s).\n", compressed->size(), bpp / io.frames.size(), io.frames.size() == 1 ? "" : "/frame"); JXL_CHECK(stats.Print(args.num_threads)); if (args.params.verbose) { aux_out.Print(1); } } return true; } } // namespace tools } // namespace jpegxl