// 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 #include #include #include #include #include #include "lib/extras/codec.h" #include "lib/extras/dec/jxl.h" #include "lib/extras/metrics.h" #include "lib/jxl/base/compiler_specific.h" #include "lib/jxl/base/data_parallel.h" #include "lib/jxl/base/override.h" #include "lib/jxl/base/span.h" #include "lib/jxl/codec_in_out.h" #include "lib/jxl/color_encoding_internal.h" #include "lib/jxl/enc_aux_out.h" #include "lib/jxl/enc_butteraugli_comparator.h" #include "lib/jxl/enc_cache.h" #include "lib/jxl/enc_fields.h" #include "lib/jxl/enc_params.h" #include "lib/jxl/enc_toc.h" #include "lib/jxl/image.h" #include "lib/jxl/image_bundle.h" #include "lib/jxl/image_ops.h" #include "lib/jxl/image_test_utils.h" #include "lib/jxl/modular/encoding/enc_encoding.h" #include "lib/jxl/modular/encoding/encoding.h" #include "lib/jxl/modular/encoding/ma_common.h" #include "lib/jxl/padded_bytes.h" #include "lib/jxl/test_utils.h" #include "lib/jxl/testing.h" namespace jxl { namespace { using test::ReadTestData; using test::Roundtrip; void TestLosslessGroups(size_t group_size_shift) { const std::vector orig = ReadTestData("jxl/flower/flower.png"); CompressParams cparams; cparams.SetLossless(); cparams.modular_group_size_shift = group_size_shift; CodecInOut io_out; CodecInOut io; ASSERT_TRUE(SetFromBytes(Bytes(orig), &io)); io.ShrinkTo(io.xsize() / 4, io.ysize() / 4); size_t compressed_size; JXL_EXPECT_OK(Roundtrip(&io, cparams, {}, &io_out, _, &compressed_size)); EXPECT_LE(compressed_size, 280000u); JXL_EXPECT_OK(SamePixels(*io.Main().color(), *io_out.Main().color(), _)); } TEST(ModularTest, RoundtripLosslessGroups128) { TestLosslessGroups(0); } TEST(ModularTest, JXL_TSAN_SLOW_TEST(RoundtripLosslessGroups512)) { TestLosslessGroups(2); } TEST(ModularTest, JXL_TSAN_SLOW_TEST(RoundtripLosslessGroups1024)) { TestLosslessGroups(3); } TEST(ModularTest, RoundtripLosslessCustomWP_PermuteRCT) { const std::vector orig = ReadTestData("external/wesaturate/500px/u76c0g_bliznaca_srgb8.png"); CompressParams cparams; cparams.SetLossless(); // 9 = permute to GBR, to test the special case of permutation-only cparams.colorspace = 9; // slowest speed so different WP modes are tried cparams.speed_tier = SpeedTier::kTortoise; cparams.options.predictor = {Predictor::Weighted}; CodecInOut io_out; CodecInOut io; ASSERT_TRUE(SetFromBytes(Bytes(orig), &io)); io.ShrinkTo(100, 100); size_t compressed_size; JXL_EXPECT_OK(Roundtrip(&io, cparams, {}, &io_out, _, &compressed_size)); EXPECT_LE(compressed_size, 10169u); JXL_EXPECT_OK(SamePixels(*io.Main().color(), *io_out.Main().color(), _)); } TEST(ModularTest, RoundtripLossyDeltaPalette) { const std::vector orig = ReadTestData("external/wesaturate/500px/u76c0g_bliznaca_srgb8.png"); CompressParams cparams; cparams.modular_mode = true; cparams.color_transform = jxl::ColorTransform::kNone; cparams.lossy_palette = true; cparams.palette_colors = 0; CodecInOut io_out; CodecInOut io; ASSERT_TRUE(SetFromBytes(Bytes(orig), &io)); io.ShrinkTo(300, 100); size_t compressed_size; JXL_EXPECT_OK(Roundtrip(&io, cparams, {}, &io_out, _, &compressed_size)); EXPECT_LE(compressed_size, 6800u); EXPECT_THAT(ButteraugliDistance(io.frames, io_out.frames, ButteraugliParams(), *JxlGetDefaultCms(), /*distmap=*/nullptr), IsSlightlyBelow(1.5)); } TEST(ModularTest, RoundtripLossyDeltaPaletteWP) { const std::vector orig = ReadTestData("external/wesaturate/500px/u76c0g_bliznaca_srgb8.png"); CompressParams cparams; cparams.SetLossless(); cparams.lossy_palette = true; cparams.palette_colors = 0; cparams.options.predictor = jxl::Predictor::Weighted; CodecInOut io_out; CodecInOut io; ASSERT_TRUE(SetFromBytes(Bytes(orig), &io)); io.ShrinkTo(300, 100); size_t compressed_size; JXL_EXPECT_OK(Roundtrip(&io, cparams, {}, &io_out, _, &compressed_size)); EXPECT_LE(compressed_size, 7000u); EXPECT_THAT(ButteraugliDistance(io.frames, io_out.frames, ButteraugliParams(), *JxlGetDefaultCms(), /*distmap=*/nullptr), IsSlightlyBelow(10.1)); } TEST(ModularTest, RoundtripLossy) { const std::vector orig = ReadTestData("external/wesaturate/500px/u76c0g_bliznaca_srgb8.png"); CompressParams cparams; cparams.modular_mode = true; cparams.butteraugli_distance = 2.f; cparams.SetCms(*JxlGetDefaultCms()); CodecInOut io_out; CodecInOut io; ASSERT_TRUE(SetFromBytes(Bytes(orig), &io)); size_t compressed_size; JXL_EXPECT_OK(Roundtrip(&io, cparams, {}, &io_out, _, &compressed_size)); EXPECT_LE(compressed_size, 30000u); EXPECT_THAT(ButteraugliDistance(io.frames, io_out.frames, ButteraugliParams(), *JxlGetDefaultCms(), /*distmap=*/nullptr), IsSlightlyBelow(2.3)); } TEST(ModularTest, RoundtripLossy16) { const std::vector orig = ReadTestData("external/raw.pixls/DJI-FC6310-16bit_709_v4_krita.png"); CompressParams cparams; cparams.modular_mode = true; cparams.butteraugli_distance = 2.f; CodecInOut io_out; CodecInOut io; ASSERT_TRUE(SetFromBytes(Bytes(orig), &io)); JXL_CHECK(!io.metadata.m.have_preview); JXL_CHECK(io.frames.size() == 1); JXL_CHECK( io.frames[0].TransformTo(ColorEncoding::SRGB(), *JxlGetDefaultCms())); io.metadata.m.color_encoding = ColorEncoding::SRGB(); size_t compressed_size; JXL_EXPECT_OK(Roundtrip(&io, cparams, {}, &io_out, _, &compressed_size)); EXPECT_LE(compressed_size, 300u); EXPECT_THAT(ButteraugliDistance(io.frames, io_out.frames, ButteraugliParams(), *JxlGetDefaultCms(), /*distmap=*/nullptr), IsSlightlyBelow(1.6)); } TEST(ModularTest, RoundtripExtraProperties) { constexpr size_t kSize = 250; Image image(kSize, kSize, /*bitdepth=*/8, 3); ModularOptions options; options.max_properties = 4; options.predictor = Predictor::Zero; Rng rng(0); for (size_t y = 0; y < kSize; y++) { for (size_t x = 0; x < kSize; x++) { image.channel[0].plane.Row(y)[x] = image.channel[2].plane.Row(y)[x] = rng.UniformU(0, 9); } } ZeroFillImage(&image.channel[1].plane); BitWriter writer; ASSERT_TRUE(ModularGenericCompress(image, options, &writer)); writer.ZeroPadToByte(); Image decoded(kSize, kSize, /*bitdepth=*/8, image.channel.size()); for (size_t i = 0; i < image.channel.size(); i++) { const Channel& ch = image.channel[i]; decoded.channel[i] = Channel(ch.w, ch.h, ch.hshift, ch.vshift); } Status status = true; { BitReader reader(writer.GetSpan()); BitReaderScopedCloser closer(&reader, &status); ASSERT_TRUE(ModularGenericDecompress(&reader, decoded, /*header=*/nullptr, /*group_id=*/0, &options)); } ASSERT_TRUE(status); ASSERT_EQ(image.channel.size(), decoded.channel.size()); for (size_t c = 0; c < image.channel.size(); c++) { for (size_t y = 0; y < image.channel[c].plane.ysize(); y++) { for (size_t x = 0; x < image.channel[c].plane.xsize(); x++) { EXPECT_EQ(image.channel[c].plane.Row(y)[x], decoded.channel[c].plane.Row(y)[x]) << "c = " << c << ", x = " << x << ", y = " << y; } } } } TEST(ModularTest, RoundtripLosslessCustomSqueeze) { const std::vector orig = ReadTestData("external/wesaturate/500px/tmshre_riaphotographs_srgb8.png"); CodecInOut io; ASSERT_TRUE(SetFromBytes(Bytes(orig), &io)); CompressParams cparams; cparams.modular_mode = true; cparams.color_transform = jxl::ColorTransform::kNone; cparams.butteraugli_distance = 0.f; cparams.options.predictor = {Predictor::Zero}; cparams.speed_tier = SpeedTier::kThunder; cparams.responsive = 1; // Custom squeeze params, atm just for testing SqueezeParams p; p.horizontal = true; p.in_place = false; p.begin_c = 0; p.num_c = 3; cparams.squeezes.push_back(p); p.begin_c = 1; p.in_place = true; p.horizontal = false; cparams.squeezes.push_back(p); CodecInOut io2; size_t compressed_size; JXL_EXPECT_OK(Roundtrip(&io, cparams, {}, &io2, _, &compressed_size)); EXPECT_LE(compressed_size, 265000u); JXL_EXPECT_OK(SamePixels(*io.Main().color(), *io2.Main().color(), _)); } struct RoundtripLosslessConfig { int bitdepth; int responsive; }; class ModularTestParam : public ::testing::TestWithParam {}; std::vector GenerateLosslessTests() { std::vector all; for (int responsive = 0; responsive <= 1; responsive++) { for (int bitdepth = 1; bitdepth < 32; bitdepth++) { if (responsive && bitdepth > 30) continue; all.push_back({bitdepth, responsive}); } } return all; } std::string LosslessTestDescription( const testing::TestParamInfo& info) { std::stringstream name; name << info.param.bitdepth << "bit"; if (info.param.responsive) name << "Squeeze"; return name.str(); } JXL_GTEST_INSTANTIATE_TEST_SUITE_P(RoundtripLossless, ModularTestParam, testing::ValuesIn(GenerateLosslessTests()), LosslessTestDescription); TEST_P(ModularTestParam, RoundtripLossless) { RoundtripLosslessConfig config = GetParam(); int bitdepth = config.bitdepth; int responsive = config.responsive; ThreadPool* pool = nullptr; Rng generator(123); const std::vector orig = ReadTestData("external/wesaturate/500px/u76c0g_bliznaca_srgb8.png"); CodecInOut io1; ASSERT_TRUE(SetFromBytes(Bytes(orig), &io1, pool)); // vary the dimensions a bit, in case of bugs related to // even vs odd width or height. size_t xsize = 423 + bitdepth; size_t ysize = 467 + bitdepth; CodecInOut io; io.SetSize(xsize, ysize); io.metadata.m.color_encoding = jxl::ColorEncoding::SRGB(false); io.metadata.m.SetUintSamples(bitdepth); double factor = ((1lu << bitdepth) - 1lu); double ifactor = 1.0 / factor; Image3F noise_added(xsize, ysize); for (size_t c = 0; c < 3; c++) { for (size_t y = 0; y < ysize; y++) { const float* in = io1.Main().color()->PlaneRow(c, y); float* out = noise_added.PlaneRow(c, y); for (size_t x = 0; x < xsize; x++) { // make the least significant bits random float f = in[x] + generator.UniformF(0.0f, 1.f / 255.f); if (f > 1.f) f = 1.f; // quantize to the bitdepth we're testing unsigned int u = f * factor + 0.5; out[x] = u * ifactor; } } } io.SetFromImage(std::move(noise_added), jxl::ColorEncoding::SRGB(false)); CompressParams cparams; cparams.modular_mode = true; cparams.color_transform = jxl::ColorTransform::kNone; cparams.butteraugli_distance = 0.f; cparams.options.predictor = {Predictor::Zero}; cparams.speed_tier = SpeedTier::kThunder; cparams.responsive = responsive; CodecInOut io2; size_t compressed_size; JXL_EXPECT_OK(Roundtrip(&io, cparams, {}, &io2, _, &compressed_size)); EXPECT_LE(compressed_size, bitdepth * xsize * ysize / 3); EXPECT_LE(0, ComputeDistance2(io.Main(), io2.Main(), *JxlGetDefaultCms())); size_t different = 0; for (size_t c = 0; c < 3; c++) { for (size_t y = 0; y < ysize; y++) { const float* in = io.Main().color()->PlaneRow(c, y); const float* out = io2.Main().color()->PlaneRow(c, y); for (size_t x = 0; x < xsize; x++) { uint32_t uin = in[x] * factor + 0.5; uint32_t uout = out[x] * factor + 0.5; // check that the integer values are identical if (uin != uout) different++; } } } EXPECT_EQ(different, 0); } TEST(ModularTest, RoundtripLosslessCustomFloat) { CodecInOut io; size_t xsize = 100, ysize = 300; io.SetSize(xsize, ysize); io.metadata.m.bit_depth.bits_per_sample = 18; io.metadata.m.bit_depth.exponent_bits_per_sample = 6; io.metadata.m.bit_depth.floating_point_sample = true; io.metadata.m.modular_16_bit_buffer_sufficient = false; ColorEncoding color_encoding; color_encoding.Tf().SetTransferFunction(TransferFunction::kLinear); color_encoding.SetColorSpace(ColorSpace::kRGB); Image3F testimage(xsize, ysize); float factor = 1.f / (1 << 14); for (size_t c = 0; c < 3; c++) { for (size_t y = 0; y < ysize; y++) { float* const JXL_RESTRICT row = testimage.PlaneRow(c, y); for (size_t x = 0; x < xsize; x++) { row[x] = factor * (x ^ y); } } } io.SetFromImage(std::move(testimage), color_encoding); io.metadata.m.color_encoding = color_encoding; io.metadata.m.SetIntensityTarget(255); CompressParams cparams; cparams.modular_mode = true; cparams.color_transform = jxl::ColorTransform::kNone; cparams.butteraugli_distance = 0.f; cparams.options.predictor = {Predictor::Zero}; cparams.speed_tier = SpeedTier::kThunder; cparams.decoding_speed_tier = 2; CodecInOut io2; size_t compressed_size; JXL_EXPECT_OK(Roundtrip(&io, cparams, {}, &io2, _, &compressed_size)); EXPECT_LE(compressed_size, 23000u); JXL_EXPECT_OK(SamePixels(*io.Main().color(), *io2.Main().color(), _)); } void WriteHeaders(BitWriter* writer, size_t xsize, size_t ysize) { BitWriter::Allotment allotment(writer, 16); writer->Write(8, 0xFF); writer->Write(8, kCodestreamMarker); allotment.ReclaimAndCharge(writer, 0, nullptr); CodecMetadata metadata; EXPECT_TRUE(metadata.size.Set(xsize, ysize)); EXPECT_TRUE(WriteSizeHeader(metadata.size, writer, 0, nullptr)); metadata.m.color_encoding = ColorEncoding::LinearSRGB(/*is_gray=*/true); metadata.m.xyb_encoded = false; metadata.m.SetUintSamples(31); EXPECT_TRUE(WriteImageMetadata(metadata.m, writer, 0, nullptr)); metadata.transform_data.nonserialized_xyb_encoded = metadata.m.xyb_encoded; EXPECT_TRUE(Bundle::Write(metadata.transform_data, writer, 0, nullptr)); writer->ZeroPadToByte(); FrameHeader frame_header(&metadata); frame_header.encoding = FrameEncoding::kModular; frame_header.loop_filter.gab = false; frame_header.loop_filter.epf_iters = 0; EXPECT_TRUE(WriteFrameHeader(frame_header, writer, nullptr)); } // Tree with single node, zero predictor, offset is 1 and multiplier is 1, // entropy code is prefix tree with alphabet size 256 and all bits lengths 8. void WriteHistograms(BitWriter* writer) { writer->Write(1, 1); // default DC quant writer->Write(1, 1); // has_tree // tree histograms writer->Write(1, 0); // LZ77 disabled writer->Write(3, 1); // simple context map writer->Write(1, 1); // prefix code writer->Write(7, 0x63); // UnintConfig(3, 2, 1) writer->Write(12, 0xfef); // alphabet_size = 256 writer->Write(32, 0x10003); // all bit lengths 8 // tree tokens writer->Write(8, 0); // tree leaf writer->Write(8, 0); // zero predictor writer->Write(8, 64); // offset = UnpackSigned(ReverseBits(64)) = 1 writer->Write(16, 0); // multiplier = 1 // histograms writer->Write(1, 0); // LZ77 disabled writer->Write(1, 1); // prefix code writer->Write(7, 0x63); // UnintConfig(3, 2, 1) writer->Write(12, 0xfef); // alphabet_size = 256 writer->Write(32, 0x10003); // all bit lengths 8 } TEST(ModularTest, PredictorIntegerOverflow) { const size_t xsize = 1; const size_t ysize = 1; BitWriter writer; WriteHeaders(&writer, xsize, ysize); std::vector group_codes(1); { BitWriter* bw = &group_codes[0]; BitWriter::Allotment allotment(bw, 1 << 20); WriteHistograms(bw); GroupHeader header; header.use_global_tree = true; EXPECT_TRUE(Bundle::Write(header, bw, 0, nullptr)); // After UnpackSigned this becomes (1 << 31) - 1, the largest pixel_type, // and after adding the offset we get -(1 << 31). bw->Write(8, 119); bw->Write(28, 0xfffffff); bw->ZeroPadToByte(); allotment.ReclaimAndCharge(bw, 0, nullptr); } EXPECT_TRUE(WriteGroupOffsets(group_codes, nullptr, &writer, nullptr)); writer.AppendByteAligned(group_codes); PaddedBytes compressed = std::move(writer).TakeBytes(); extras::PackedPixelFile ppf; extras::JXLDecompressParams params; params.accepted_formats.push_back({1, JXL_TYPE_FLOAT, JXL_NATIVE_ENDIAN, 0}); EXPECT_TRUE(DecodeImageJXL(compressed.data(), compressed.size(), params, nullptr, &ppf)); ASSERT_EQ(1, ppf.frames.size()); const auto& img = ppf.frames[0].color; const auto pixels = reinterpret_cast(img.pixels()); EXPECT_EQ(-1.0f, pixels[0]); } TEST(ModularTest, UnsqueezeIntegerOverflow) { // Image width is 9 so we can test both the SIMD and non-vector code paths. const size_t xsize = 9; const size_t ysize = 2; BitWriter writer; WriteHeaders(&writer, xsize, ysize); std::vector group_codes(1); { BitWriter* bw = &group_codes[0]; BitWriter::Allotment allotment(bw, 1 << 20); WriteHistograms(bw); GroupHeader header; header.use_global_tree = true; header.transforms.emplace_back(); header.transforms[0].id = TransformId::kSqueeze; SqueezeParams params; params.horizontal = false; params.in_place = true; params.begin_c = 0; params.num_c = 1; header.transforms[0].squeezes.emplace_back(params); EXPECT_TRUE(Bundle::Write(header, bw, 0, nullptr)); for (size_t i = 0; i < xsize * ysize; ++i) { // After UnpackSigned and adding offset, this becomes (1 << 31) - 1, both // in the image and in the residual channels, and unsqueeze makes them // ~(3 << 30) and (1 << 30) (in pixel_type_w) and the first wraps around // to about -(1 << 30). bw->Write(8, 119); bw->Write(28, 0xffffffe); } bw->ZeroPadToByte(); allotment.ReclaimAndCharge(bw, 0, nullptr); } EXPECT_TRUE(WriteGroupOffsets(group_codes, nullptr, &writer, nullptr)); writer.AppendByteAligned(group_codes); PaddedBytes compressed = std::move(writer).TakeBytes(); extras::PackedPixelFile ppf; extras::JXLDecompressParams params; params.accepted_formats.push_back({1, JXL_TYPE_FLOAT, JXL_NATIVE_ENDIAN, 0}); EXPECT_TRUE(DecodeImageJXL(compressed.data(), compressed.size(), params, nullptr, &ppf)); ASSERT_EQ(1, ppf.frames.size()); const auto& img = ppf.frames[0].color; const auto pixels = reinterpret_cast(img.pixels()); for (size_t x = 0; x < xsize; ++x) { EXPECT_NEAR(-0.5f, pixels[x], 1e-10); EXPECT_NEAR(0.5f, pixels[xsize + x], 1e-10); } } } // namespace } // namespace jxl