// 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 "lib/jxl/base/random.h" #include "lib/jxl/dec_bit_reader.h" #include "lib/jxl/modular/encoding/encoding.h" #include "lib/jxl/modular/transform/transform.h" namespace jxl { namespace { void FillChannel(Channel& ch, Rng& rng) { auto p = &ch.plane; const size_t w = ch.w; const size_t h = ch.h; for (size_t y = 0; y < h; ++y) { pixel_type* row = p->Row(y); for (size_t x = 0; x < w; ++x) { row[x] = rng.UniformU(0, 0x80000000); } } } template void AssertEq(T a, T b) { if (a != b) __builtin_trap(); } } // namespace int TestOneInput(const uint8_t* data, size_t size) { static Status nevermind = true; BitReader reader(Span(data, size)); BitReaderScopedCloser reader_closer(&reader, &nevermind); Rng rng(reader.ReadFixedBits<56>()); // One of {0, 1, _2_, 3}; "2" will be filtered out soon. size_t nb_chans = static_cast(reader.ReadFixedBits<8>()) & 0x3; size_t nb_extra = static_cast(reader.ReadFixedBits<8>()) & 0x7; // 1..32 size_t bit_depth = (static_cast(reader.ReadFixedBits<8>()) & 0x1F) + 1; // {0, 1, 2, 3} size_t log_upsampling = (static_cast(reader.ReadFixedBits<8>()) & 0x3); size_t upsampling = 1 << log_upsampling; size_t w_orig = static_cast(reader.ReadFixedBits<16>()); size_t h_orig = static_cast(reader.ReadFixedBits<16>()); size_t w = DivCeil(w_orig, upsampling); size_t h = DivCeil(h_orig, upsampling); if ((nb_chans == 2) || ((nb_chans + nb_extra) == 0) || (w * h == 0) || ((w_orig * h_orig * (nb_chans + nb_extra)) > (1 << 23))) { return 0; } std::vector hshift; std::vector vshift; std::vector ec_upsampling; for (size_t c = 0; c < nb_chans; c++) { hshift.push_back(static_cast(reader.ReadFixedBits<8>()) & 1); vshift.push_back(static_cast(reader.ReadFixedBits<8>()) & 1); } for (size_t ec = 0; ec < nb_extra; ec++) { size_t log_ec_upsampling = (static_cast(reader.ReadFixedBits<8>()) & 0x3); log_ec_upsampling = std::max(log_ec_upsampling, log_upsampling); ec_upsampling.push_back(1 << log_ec_upsampling); } Image image(w, h, bit_depth, nb_chans + nb_extra); for (size_t c = 0; c < nb_chans; c++) { Channel& ch = image.channel[c]; ch.hshift = hshift[c]; ch.vshift = vshift[c]; ch.shrink(DivCeil(w, 1 << hshift[c]), DivCeil(h, 1 << vshift[c])); } for (size_t ec = 0; ec < nb_extra; ec++) { Channel& ch = image.channel[ec + nb_chans]; size_t ch_up = ec_upsampling[ec]; int up_level = CeilLog2Nonzero(ch_up) - CeilLog2Nonzero(upsampling); ch.shrink(DivCeil(w_orig, ch_up), DivCeil(h_orig, ch_up)); ch.hshift = ch.vshift = up_level; } GroupHeader header; if (!Bundle::Read(&reader, &header)) return 0; weighted::Header w_header; if (!Bundle::Read(&reader, &w_header)) return 0; // TODO(eustas): give it a try? if (!reader.AllReadsWithinBounds()) return 0; image.transform = header.transforms; for (Transform& transform : image.transform) { if (!transform.MetaApply(image)) return 0; } if (image.error) return 0; ModularOptions options; if (!ValidateChannelDimensions(image, options)) return 0; for (size_t i = 0; i < image.channel.size(); ++i) { FillChannel(image.channel[i], rng); } image.undo_transforms(w_header); AssertEq(image.error, false); AssertEq(image.nb_meta_channels, 0); AssertEq(image.channel.size(), nb_chans + nb_extra); for (size_t c = 0; c < nb_chans; c++) { const Channel& ch = image.channel[c]; AssertEq(ch.hshift, hshift[c]); AssertEq(ch.vshift, vshift[c]); AssertEq(ch.w, DivCeil(w, 1 << hshift[c])); AssertEq(ch.h, DivCeil(h, 1 << vshift[c])); } for (size_t ec = 0; ec < nb_extra; ec++) { const Channel& ch = image.channel[ec + nb_chans]; size_t ch_up = ec_upsampling[ec]; int up_level = CeilLog2Nonzero(ch_up) - CeilLog2Nonzero(upsampling); AssertEq(ch.w, DivCeil(w_orig, ch_up)); AssertEq(ch.h, DivCeil(h_orig, ch_up)); AssertEq(ch.hshift, up_level); AssertEq(ch.vshift, up_level); } return 0; } } // namespace jxl extern "C" int LLVMFuzzerTestOneInput(const uint8_t* data, size_t size) { return jxl::TestOneInput(data, size); }