courgette/encoded_program_fuzz_unittest.cc - chromium/src - Git at Google

 // Copyright (c) 2011 The Chromium Authors. All rights reserved.
 // Use of this source code is governed by a BSD-style license that can be
 // found in the LICENSE file.

 // Fuzz testing for EncodedProgram serialized format and assembly.
 //
 // We would like some assurance that if an EncodedProgram is malformed we will
 // not crash.  The EncodedProgram could be malformed either due to malicious
 // attack to due to an error in patch generation.
 //
 // We try a lot of arbitrary modifications to the serialized form and make sure
 // that the outcome is not a crash.
 #include "courgette/encoded_program.h"

 #include <stddef.h>

 #include <memory>

 #include "base/test/test_suite.h"
 #include "courgette/assembly_program.h"
 #include "courgette/base_test_unittest.h"
 #include "courgette/courgette.h"
 #include "courgette/program_detector.h"
 #include "courgette/streams.h"

 class DecodeFuzzTest : public BaseTest {
  public:
   void FuzzExe(const char *) const;

  private:
   void FuzzByte(const std::string& buffer, const std::string& output,
                 size_t index) const;
   void FuzzBits(const std::string& buffer, const std::string& output,
                 size_t index, int bits_to_flip) const;

   // Returns true if could assemble, false if rejected.
   bool TryAssemble(const std::string& buffer, std::string* output) const;
 };

 // Loads an executable and does fuzz testing in the serialized format.
 void DecodeFuzzTest::FuzzExe(const char* file_name) const {
   std::string file1 = FileContents(file_name);

   const void* original_buffer = file1.c_str();
   size_t original_length = file1.length();

   std::unique_ptr<courgette::AssemblyProgram> program;
   const courgette::Status parse_status =
       courgette::ParseDetectedExecutable(original_buffer, original_length,
                                          &program);
   EXPECT_EQ(courgette::C_OK, parse_status);

   std::unique_ptr<courgette::EncodedProgram> encoded;
   const courgette::Status encode_status = Encode(*program, &encoded);
   EXPECT_EQ(courgette::C_OK, encode_status);

   program.reset();

   courgette::SinkStreamSet sinks;
   const courgette::Status write_status =
       WriteEncodedProgram(encoded.get(), &sinks);
   EXPECT_EQ(courgette::C_OK, write_status);

   encoded.reset();

   courgette::SinkStream sink;
   bool can_collect = sinks.CopyTo(&sink);
   EXPECT_TRUE(can_collect);

   size_t length = sink.Length();

   std::string base_buffer(reinterpret_cast<const char*>(sink.Buffer()), length);
   std::string base_output;
   bool ok = TryAssemble(base_buffer, &base_output);
   EXPECT_TRUE(ok);

   // Now we have a good serialized EncodedProgram in |base_buffer|. Time to
   // fuzz.

   // More intense fuzzing on the first part because it contains more control
   // information like substeam lengths.
   size_t position = 0;
   for ( ;  position < 100 && position < length;  position += 1) {
     FuzzByte(base_buffer, base_output, position);
   }
   // We would love to fuzz every position, but it takes too long.
   for ( ;  position < length;  position += 900) {
     FuzzByte(base_buffer, base_output, position);
   }
 }

 // FuzzByte tries to break the EncodedProgram deserializer and assembler.  It
 // takes a good serialization of and EncodedProgram, flips some bits, and checks
 // that the behaviour is reasonable.  It has testing checks for unreasonable
 // behaviours.
 void DecodeFuzzTest::FuzzByte(const std::string& base_buffer,
                               const std::string& base_output,
                               size_t index) const {
   printf("Fuzzing position %d\n", static_cast<int>(index));

   // The following 10 values are a compromize between run time and coverage of
   // the 255 'wrong' values at this byte position.

   // 0xFF flips all the bits.
   FuzzBits(base_buffer, base_output, index, 0xFF);
   // 0x7F flips the most bits without changing Varint32 framing.
   FuzzBits(base_buffer, base_output, index, 0x7F);
   // These all flip one bit.
   FuzzBits(base_buffer, base_output, index, 0x80);
   FuzzBits(base_buffer, base_output, index, 0x40);
   FuzzBits(base_buffer, base_output, index, 0x20);
   FuzzBits(base_buffer, base_output, index, 0x10);
   FuzzBits(base_buffer, base_output, index, 0x08);
   FuzzBits(base_buffer, base_output, index, 0x04);
   FuzzBits(base_buffer, base_output, index, 0x02);
   FuzzBits(base_buffer, base_output, index, 0x01);
 }

 // FuzzBits tries to break the EncodedProgram deserializer and assembler.  It
 // takes a good serialization of and EncodedProgram, flips some bits, and checks
 // that the behaviour is reasonable.
 //
 // There are EXPECT calls to check for unreasonable behaviour.  These are
 // somewhat arbitrary in that the parameters cannot easily be derived from first
 // principles.  They may need updating as the serialized format evolves.
 void DecodeFuzzTest::FuzzBits(const std::string& base_buffer,
                               const std::string& base_output,
                               size_t index, int bits_to_flip) const {
   std::string modified_buffer = base_buffer;
   std::string modified_output;
   modified_buffer[index] ^= bits_to_flip;

   bool ok = TryAssemble(modified_buffer, &modified_output);

   if (ok) {
     // We normally expect TryAssemble to fail.  But sometimes it succeeds.
     // What could have happened?  We changed one byte in the serialized form:
     //
     //  * If we changed one of the copied bytes, we would see a single byte
     //    change in the output.
     //  * If we changed an address table element, all the references to that
     //    address would be different.
     //  * If we changed a copy count, we would run out of data in some stream,
     //    or leave data remaining, so should not be here.
     //  * If we changed an origin address, it could affect all relocations based
     //    off that address.  If no relocations were based off the address then
     //    there will be no changes.
     //  * If we changed an origin address, it could cause some abs32 relocs to
     //    shift from one page to the next, changing the number and layout of
     //    blocks in the base relocation table.

     // Generated length could vary slightly due to base relocation table layout.
     // In the worst case the number of base relocation blocks doubles, approx
     // 12/4096 or 0.3% size of file.
     size_t base_length = base_output.length();
     size_t modified_length = modified_output.length();
     ptrdiff_t diff = base_length - modified_length;
     if (diff < -200 || diff > 200) {
       EXPECT_EQ(base_length, modified_length);
     }

     size_t changed_byte_count = 0;
     for (size_t i = 0;  i < base_length && i < modified_length; ++i) {
       changed_byte_count += (base_output[i] != modified_output[i]);
     }

     if (index > 60) {                     // Beyond the origin addresses ...
       EXPECT_NE(0U, changed_byte_count);   //   ... we expect some difference.
     }
     // Currently all changes are smaller than this number:
     EXPECT_GE(45000U, changed_byte_count);
   }
 }

 bool DecodeFuzzTest::TryAssemble(const std::string& buffer,
                                  std::string* output) const {
   std::unique_ptr<courgette::EncodedProgram> encoded;
   bool result = false;

   courgette::SourceStreamSet sources;
   bool can_get_source_streams = sources.Init(buffer.c_str(), buffer.length());
   if (can_get_source_streams) {
     const courgette::Status read_status =
         ReadEncodedProgram(&sources, &encoded);
     if (read_status == courgette::C_OK) {
       courgette::SinkStream assembled;
       const courgette::Status assemble_status =
           Assemble(encoded.get(), &assembled);

       if (assemble_status == courgette::C_OK) {
         const void* assembled_buffer = assembled.Buffer();
         size_t assembled_length = assembled.Length();

         output->clear();
         output->assign(reinterpret_cast<const char*>(assembled_buffer),
                        assembled_length);
         result = true;
       }
     }
   }

   return result;
 }

 TEST_F(DecodeFuzzTest, All) {
   FuzzExe("setup1.exe");
   FuzzExe("elf-32-1.exe");
 }

 int main(int argc, char** argv) {
   return base::TestSuite(argc, argv).Run();
 }
	// Copyright (c) 2011 The Chromium Authors. All rights reserved.
	// Use of this source code is governed by a BSD-style license that can be
	// found in the LICENSE file.

	// Fuzz testing for EncodedProgram serialized format and assembly.
	//
	// We would like some assurance that if an EncodedProgram is malformed we will
	// not crash. The EncodedProgram could be malformed either due to malicious
	// attack to due to an error in patch generation.
	//
	// We try a lot of arbitrary modifications to the serialized form and make sure
	// that the outcome is not a crash.
	#include "courgette/encoded_program.h"

	#include <stddef.h>

	#include <memory>

	#include "base/test/test_suite.h"
	#include "courgette/assembly_program.h"
	#include "courgette/base_test_unittest.h"
	#include "courgette/courgette.h"
	#include "courgette/program_detector.h"
	#include "courgette/streams.h"

	class DecodeFuzzTest : public BaseTest {
	public:
	void FuzzExe(const char *) const;

	private:
	void FuzzByte(const std::string& buffer, const std::string& output,
	size_t index) const;
	void FuzzBits(const std::string& buffer, const std::string& output,
	size_t index, int bits_to_flip) const;

	// Returns true if could assemble, false if rejected.
	bool TryAssemble(const std::string& buffer, std::string* output) const;
	};

	// Loads an executable and does fuzz testing in the serialized format.
	void DecodeFuzzTest::FuzzExe(const char* file_name) const {
	std::string file1 = FileContents(file_name);

	const void* original_buffer = file1.c_str();
	size_t original_length = file1.length();

	std::unique_ptr<courgette::AssemblyProgram> program;
	const courgette::Status parse_status =
	courgette::ParseDetectedExecutable(original_buffer, original_length,
	&program);
	EXPECT_EQ(courgette::C_OK, parse_status);

	std::unique_ptr<courgette::EncodedProgram> encoded;
	const courgette::Status encode_status = Encode(*program, &encoded);
	EXPECT_EQ(courgette::C_OK, encode_status);

	program.reset();

	courgette::SinkStreamSet sinks;
	const courgette::Status write_status =
	WriteEncodedProgram(encoded.get(), &sinks);
	EXPECT_EQ(courgette::C_OK, write_status);

	encoded.reset();

	courgette::SinkStream sink;
	bool can_collect = sinks.CopyTo(&sink);
	EXPECT_TRUE(can_collect);

	size_t length = sink.Length();

	std::string base_buffer(reinterpret_cast<const char*>(sink.Buffer()), length);
	std::string base_output;
	bool ok = TryAssemble(base_buffer, &base_output);
	EXPECT_TRUE(ok);

	// Now we have a good serialized EncodedProgram in \|base_buffer\|. Time to
	// fuzz.

	// More intense fuzzing on the first part because it contains more control
	// information like substeam lengths.
	size_t position = 0;
	for ( ; position < 100 && position < length; position += 1) {
	FuzzByte(base_buffer, base_output, position);
	}
	// We would love to fuzz every position, but it takes too long.
	for ( ; position < length; position += 900) {
	FuzzByte(base_buffer, base_output, position);
	}
	}

	// FuzzByte tries to break the EncodedProgram deserializer and assembler. It
	// takes a good serialization of and EncodedProgram, flips some bits, and checks
	// that the behaviour is reasonable. It has testing checks for unreasonable
	// behaviours.
	void DecodeFuzzTest::FuzzByte(const std::string& base_buffer,
	const std::string& base_output,
	size_t index) const {
	printf("Fuzzing position %d\n", static_cast<int>(index));

	// The following 10 values are a compromize between run time and coverage of
	// the 255 'wrong' values at this byte position.

	// 0xFF flips all the bits.
	FuzzBits(base_buffer, base_output, index, 0xFF);
	// 0x7F flips the most bits without changing Varint32 framing.
	FuzzBits(base_buffer, base_output, index, 0x7F);
	// These all flip one bit.
	FuzzBits(base_buffer, base_output, index, 0x80);
	FuzzBits(base_buffer, base_output, index, 0x40);
	FuzzBits(base_buffer, base_output, index, 0x20);
	FuzzBits(base_buffer, base_output, index, 0x10);
	FuzzBits(base_buffer, base_output, index, 0x08);
	FuzzBits(base_buffer, base_output, index, 0x04);
	FuzzBits(base_buffer, base_output, index, 0x02);
	FuzzBits(base_buffer, base_output, index, 0x01);
	}

	// FuzzBits tries to break the EncodedProgram deserializer and assembler. It
	// takes a good serialization of and EncodedProgram, flips some bits, and checks
	// that the behaviour is reasonable.
	//
	// There are EXPECT calls to check for unreasonable behaviour. These are
	// somewhat arbitrary in that the parameters cannot easily be derived from first
	// principles. They may need updating as the serialized format evolves.
	void DecodeFuzzTest::FuzzBits(const std::string& base_buffer,
	const std::string& base_output,
	size_t index, int bits_to_flip) const {
	std::string modified_buffer = base_buffer;
	std::string modified_output;
	modified_buffer[index] ^= bits_to_flip;

	bool ok = TryAssemble(modified_buffer, &modified_output);

	if (ok) {
	// We normally expect TryAssemble to fail. But sometimes it succeeds.
	// What could have happened? We changed one byte in the serialized form:
	//
	// * If we changed one of the copied bytes, we would see a single byte
	// change in the output.
	// * If we changed an address table element, all the references to that
	// address would be different.
	// * If we changed a copy count, we would run out of data in some stream,
	// or leave data remaining, so should not be here.
	// * If we changed an origin address, it could affect all relocations based
	// off that address. If no relocations were based off the address then
	// there will be no changes.
	// * If we changed an origin address, it could cause some abs32 relocs to
	// shift from one page to the next, changing the number and layout of
	// blocks in the base relocation table.

	// Generated length could vary slightly due to base relocation table layout.
	// In the worst case the number of base relocation blocks doubles, approx
	// 12/4096 or 0.3% size of file.
	size_t base_length = base_output.length();
	size_t modified_length = modified_output.length();
	ptrdiff_t diff = base_length - modified_length;
	if (diff < -200 \|\| diff > 200) {
	EXPECT_EQ(base_length, modified_length);
	}

	size_t changed_byte_count = 0;
	for (size_t i = 0; i < base_length && i < modified_length; ++i) {
	changed_byte_count += (base_output[i] != modified_output[i]);
	}

	if (index > 60) { // Beyond the origin addresses ...
	EXPECT_NE(0U, changed_byte_count); // ... we expect some difference.
	}
	// Currently all changes are smaller than this number:
	EXPECT_GE(45000U, changed_byte_count);
	}
	}

	bool DecodeFuzzTest::TryAssemble(const std::string& buffer,
	std::string* output) const {
	std::unique_ptr<courgette::EncodedProgram> encoded;
	bool result = false;

	courgette::SourceStreamSet sources;
	bool can_get_source_streams = sources.Init(buffer.c_str(), buffer.length());
	if (can_get_source_streams) {
	const courgette::Status read_status =
	ReadEncodedProgram(&sources, &encoded);
	if (read_status == courgette::C_OK) {
	courgette::SinkStream assembled;
	const courgette::Status assemble_status =
	Assemble(encoded.get(), &assembled);

	if (assemble_status == courgette::C_OK) {
	const void* assembled_buffer = assembled.Buffer();
	size_t assembled_length = assembled.Length();

	output->clear();
	output->assign(reinterpret_cast<const char*>(assembled_buffer),
	assembled_length);
	result = true;
	}
	}
	}

	return result;
	}

	TEST_F(DecodeFuzzTest, All) {
	FuzzExe("setup1.exe");
	FuzzExe("elf-32-1.exe");
	}

	int main(int argc, char** argv) {
	return base::TestSuite(argc, argv).Run();
	}