#include #include #include #include #include #include #include #include #include #include #include #include class DiscardContents: public QPDFObjectHandle::ParserCallbacks { public: ~DiscardContents() override = default; void handleObject(QPDFObjectHandle) override { } void handleEOF() override { } }; class FuzzHelper { public: FuzzHelper(unsigned char const* data, size_t size); void run(); private: std::shared_ptr getQpdf(); std::shared_ptr getWriter(std::shared_ptr); void doWrite(std::shared_ptr w); void testWrite(); void doChecks(); Buffer input_buffer; Pl_Discard discard; }; FuzzHelper::FuzzHelper(unsigned char const* data, size_t size) : // We do not modify data, so it is safe to remove the const for Buffer input_buffer(const_cast(data), size) { } std::shared_ptr FuzzHelper::getQpdf() { auto is = std::shared_ptr(new BufferInputSource("fuzz input", &this->input_buffer)); auto qpdf = QPDF::create(); qpdf->setMaxWarnings(200); qpdf->processInputSource(is); return qpdf; } std::shared_ptr FuzzHelper::getWriter(std::shared_ptr qpdf) { auto w = std::make_shared(*qpdf); w->setOutputPipeline(&this->discard); w->setDecodeLevel(qpdf_dl_all); return w; } void FuzzHelper::doWrite(std::shared_ptr w) { try { w->write(); } catch (QPDFExc const& e) { std::cerr << e.what() << std::endl; } catch (std::runtime_error const& e) { std::cerr << e.what() << std::endl; } } void FuzzHelper::testWrite() { // Write in various ways to exercise QPDFWriter std::shared_ptr q; std::shared_ptr w; q = getQpdf(); w = getWriter(q); w->setDeterministicID(true); w->setQDFMode(true); doWrite(w); q = getQpdf(); w = getWriter(q); w->setStaticID(true); w->setLinearization(true); w->setR6EncryptionParameters("u", "o", true, true, true, true, true, true, qpdf_r3p_full, true); doWrite(w); } void FuzzHelper::doChecks() { // Limit the memory used to decompress JPEG files during fuzzing. Excessive memory use during // fuzzing is due to corrupt JPEG data which sometimes cannot be detected before // jpeg_start_decompress is called. During normal use of qpdf very large JPEGs can occasionally // occur legitimately and therefore must be allowed during normal operations. Pl_DCT::setMemoryLimit(100'000'000); Pl_DCT::setScanLimit(50); Pl_PNGFilter::setMemoryLimit(1'000'000); Pl_TIFFPredictor::setMemoryLimit(1'000'000); Pl_Flate::setMemoryLimit(1'000'000); // Do not decompress corrupt data. This may cause extended runtime within jpeglib without // exercising additional code paths in qpdf, and potentially causing counterproductive timeouts. Pl_DCT::setThrowOnCorruptData(true); // Get as much coverage as possible in parts of the library that // might benefit from fuzzing. std::cerr << "\ninfo: starting testWrite\n"; testWrite(); } void FuzzHelper::run() { // The goal here is that you should be able to throw anything at // libqpdf and it will respond without any memory errors and never // do anything worse than throwing a QPDFExc or // std::runtime_error. Throwing any other kind of exception, // segfaulting, or having a memory error (when built with // appropriate sanitizers) will all cause abnormal exit. try { doChecks(); } catch (QPDFExc const& e) { std::cerr << "QPDFExc: " << e.what() << std::endl; } catch (std::runtime_error const& e) { std::cerr << "runtime_error: " << e.what() << std::endl; } } extern "C" int LLVMFuzzerTestOneInput(unsigned char const* data, size_t size) { #ifndef _WIN32 // Used by jpeg library to work around false positives in memory // sanitizer. setenv("JSIMD_FORCENONE", "1", 1); #endif FuzzHelper f(data, size); f.run(); return 0; }