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nest-open-source / nest-cam / v350 / breakpad / refs/heads/main / . / src / common / mac / macho_reader_unittest.cc
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// Copyright (c) 2010 Google Inc.
// All rights reserved.
//
// Redistribution and use in source and binary forms, with or without
// modification, are permitted provided that the following conditions are
// met:
//
// * Redistributions of source code must retain the above copyright
// notice, this list of conditions and the following disclaimer.
// * Redistributions in binary form must reproduce the above
// copyright notice, this list of conditions and the following disclaimer
// in the documentation and/or other materials provided with the
// distribution.
// * Neither the name of Google Inc. nor the names of its
// contributors may be used to endorse or promote products derived from
// this software without specific prior written permission.
//
// THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS
// "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT
// LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR
// A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT
// OWNER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL,
// SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT
// LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE,
// DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY
// THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
// (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE
// OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
// Original author: Jim Blandy <jimb@mozilla.com> <jimb@red-bean.com>
// macho_reader_unittest.cc: Unit tests for google_breakpad::Mach_O::FatReader
// and google_breakpad::Mach_O::Reader.
#include <map>
#include <string>
#include <vector>
#include "breakpad_googletest_includes.h"
#include "common/mac/macho_reader.h"
#include "common/test_assembler.h"
namespace mach_o = google_breakpad::mach_o;
namespace test_assembler = google_breakpad::test_assembler;
using mach_o::FatReader;
using mach_o::FileFlags;
using mach_o::FileType;
using mach_o::LoadCommandType;
using mach_o::Reader;
using mach_o::Section;
using mach_o::SectionMap;
using mach_o::Segment;
using test_assembler::Endianness;
using test_assembler::Label;
using test_assembler::kBigEndian;
using test_assembler::kLittleEndian;
using test_assembler::kUnsetEndian;
using google_breakpad::ByteBuffer;
using std::map;
using std::string;
using std::vector;
using testing::AllOf;
using testing::DoAll;
using testing::Field;
using testing::InSequence;
using testing::Matcher;
using testing::Return;
using testing::SaveArg;
using testing::Test;
using testing::_;
// Mock classes for the reader's various reporters and handlers.
class MockFatReaderReporter: public FatReader::Reporter {
public:
MockFatReaderReporter(const string& filename)
: FatReader::Reporter(filename) { }
MOCK_METHOD0(BadHeader, void());
MOCK_METHOD0(MisplacedObjectFile, void());
MOCK_METHOD0(TooShort, void());
};
class MockReaderReporter: public Reader::Reporter {
public:
MockReaderReporter(const string& filename) : Reader::Reporter(filename) { }
MOCK_METHOD0(BadHeader, void());
MOCK_METHOD4(CPUTypeMismatch, void(cpu_type_t cpu_type,
cpu_subtype_t cpu_subtype,
cpu_type_t expected_cpu_type,
cpu_subtype_t expected_cpu_subtype));
MOCK_METHOD0(HeaderTruncated, void());
MOCK_METHOD0(LoadCommandRegionTruncated, void());
MOCK_METHOD3(LoadCommandsOverrun, void(size_t claimed, size_t i,
LoadCommandType type));
MOCK_METHOD2(LoadCommandTooShort, void(size_t i, LoadCommandType type));
MOCK_METHOD1(SectionsMissing, void(const string& name));
MOCK_METHOD1(MisplacedSegmentData, void(const string& name));
MOCK_METHOD2(MisplacedSectionData, void(const string& section,
const string& segment));
MOCK_METHOD0(MisplacedSymbolTable, void());
MOCK_METHOD1(UnsupportedCPUType, void(cpu_type_t cpu_type));
};
class MockLoadCommandHandler: public Reader::LoadCommandHandler {
public:
MOCK_METHOD2(UnknownCommand, bool(LoadCommandType, const ByteBuffer&));
MOCK_METHOD1(SegmentCommand, bool(const Segment&));
MOCK_METHOD2(SymtabCommand, bool(const ByteBuffer&, const ByteBuffer&));
};
class MockSectionHandler: public Reader::SectionHandler {
public:
MOCK_METHOD1(HandleSection, bool(const Section& section));
};
// Tests for mach_o::FatReader.
// Since the effect of these functions is to write to stderr, the
// results of these tests must be inspected by hand.
TEST(FatReaderReporter, BadHeader) {
FatReader::Reporter reporter("filename");
reporter.BadHeader();
}
TEST(FatReaderReporter, MisplacedObjectFile) {
FatReader::Reporter reporter("filename");
reporter.MisplacedObjectFile();
}
TEST(FatReaderReporter, TooShort) {
FatReader::Reporter reporter("filename");
reporter.TooShort();
}
TEST(MachOReaderReporter, BadHeader) {
Reader::Reporter reporter("filename");
reporter.BadHeader();
}
TEST(MachOReaderReporter, CPUTypeMismatch) {
Reader::Reporter reporter("filename");
reporter.CPUTypeMismatch(CPU_TYPE_I386, CPU_SUBTYPE_X86_ALL,
CPU_TYPE_POWERPC, CPU_SUBTYPE_POWERPC_ALL);
}
TEST(MachOReaderReporter, HeaderTruncated) {
Reader::Reporter reporter("filename");
reporter.HeaderTruncated();
}
TEST(MachOReaderReporter, LoadCommandRegionTruncated) {
Reader::Reporter reporter("filename");
reporter.LoadCommandRegionTruncated();
}
TEST(MachOReaderReporter, LoadCommandsOverrun) {
Reader::Reporter reporter("filename");
reporter.LoadCommandsOverrun(10, 9, LC_DYSYMTAB);
reporter.LoadCommandsOverrun(10, 9, 0);
}
TEST(MachOReaderReporter, LoadCommandTooShort) {
Reader::Reporter reporter("filename");
reporter.LoadCommandTooShort(11, LC_SYMTAB);
}
TEST(MachOReaderReporter, SectionsMissing) {
Reader::Reporter reporter("filename");
reporter.SectionsMissing("segment name");
}
TEST(MachOReaderReporter, MisplacedSegmentData) {
Reader::Reporter reporter("filename");
reporter.MisplacedSegmentData("segment name");
}
TEST(MachOReaderReporter, MisplacedSectionData) {
Reader::Reporter reporter("filename");
reporter.MisplacedSectionData("section name", "segment name");
}
TEST(MachOReaderReporter, MisplacedSymbolTable) {
Reader::Reporter reporter("filename");
reporter.MisplacedSymbolTable();
}
TEST(MachOReaderReporter, UnsupportedCPUType) {
Reader::Reporter reporter("filename");
reporter.UnsupportedCPUType(CPU_TYPE_HPPA);
}
struct FatReaderFixture {
FatReaderFixture()
: fat(kBigEndian),
reporter("reporter filename"),
reader(&reporter), object_files() {
EXPECT_CALL(reporter, BadHeader()).Times(0);
EXPECT_CALL(reporter, TooShort()).Times(0);
// here, start, and Mark are file offsets in 'fat'.
fat.start() = 0;
}
// Append a 'fat_arch' entry to 'fat', with the given field values.
void AppendFatArch(cpu_type_t type, cpu_subtype_t subtype,
Label offset, Label size, uint32_t align) {
fat
.B32(type)
.B32(subtype)
.B32(offset)
.B32(size)
.B32(align);
}
// Append |n| dummy 'fat_arch' entries to 'fat'. The cpu type and
// subtype have unrealistic values.
void AppendDummyArchEntries(int n) {
for (int i = 0; i < n; i++)
AppendFatArch(0xb68ad617, 0x715a0840, 0, 0, 1);
}
void ReadFat(bool expect_parse_success = true) {
ASSERT_TRUE(fat.GetContents(&contents));
fat_bytes = reinterpret_cast<const uint8_t*>(contents.data());
if (expect_parse_success) {
EXPECT_TRUE(reader.Read(fat_bytes, contents.size()));
size_t fat_files_count;
const SuperFatArch* fat_files = reader.object_files(&fat_files_count);
object_files.resize(fat_files_count);
for (size_t i = 0; i < fat_files_count; ++i) {
EXPECT_TRUE(fat_files[i].ConvertToFatArch(&object_files[i]));
}
}
else
EXPECT_FALSE(reader.Read(fat_bytes, contents.size()));
}
test_assembler::Section fat;
MockFatReaderReporter reporter;
FatReader reader;
string contents;
const uint8_t* fat_bytes;
vector<struct fat_arch> object_files;
};
class FatReaderTest: public FatReaderFixture, public Test { };
TEST_F(FatReaderTest, BadMagic) {
EXPECT_CALL(reporter, BadHeader()).Times(1);
fat
.B32(0xcafed00d) // magic number (incorrect)
.B32(10); // number of architectures
AppendDummyArchEntries(10);
ReadFat(false);
}
TEST_F(FatReaderTest, HeaderTooShort) {
EXPECT_CALL(reporter, TooShort()).Times(1);
fat
.B32(0xcafebabe); // magic number
ReadFat(false);
}
TEST_F(FatReaderTest, ObjectListTooShort) {
EXPECT_CALL(reporter, TooShort()).Times(1);
fat
.B32(0xcafebabe) // magic number
.B32(10); // number of architectures
AppendDummyArchEntries(9); // nine dummy architecture entries...
fat // and a tenth, missing a byte at the end
.B32(0x3d46c8fc) // cpu type
.B32(0x8a7bfb01) // cpu subtype
.B32(0) // offset
.B32(0) // size
.Append(3, '*'); // one byte short of a four-byte alignment
ReadFat(false);
}
TEST_F(FatReaderTest, DataTooShort) {
EXPECT_CALL(reporter, MisplacedObjectFile()).Times(1);
Label arch_data;
fat
.B32(0xcafebabe) // magic number
.B32(1); // number of architectures
AppendFatArch(0xb4d4a366, 0x4ba4f525, arch_data, 40, 0);
fat
.Mark(&arch_data) // file data begins here
.Append(30, '*'); // only 30 bytes, not 40 as header claims
ReadFat(false);
}
TEST_F(FatReaderTest, NoObjectFiles) {
fat
.B32(0xcafebabe) // magic number
.B32(0); // number of architectures
ReadFat();
EXPECT_EQ(0U, object_files.size());
}
TEST_F(FatReaderTest, OneObjectFile) {
Label obj1_offset;
fat
.B32(0xcafebabe) // magic number
.B32(1); // number of architectures
// First object file list entry
AppendFatArch(0x5e3a6e91, 0x52ccd852, obj1_offset, 0x42, 0x355b15b2);
// First object file data
fat
.Mark(&obj1_offset)
.Append(0x42, '*'); // dummy contents
ReadFat();
ASSERT_EQ(1U, object_files.size());
EXPECT_EQ(0x5e3a6e91, object_files[0].cputype);
EXPECT_EQ(0x52ccd852, object_files[0].cpusubtype);
EXPECT_EQ(obj1_offset.Value(), object_files[0].offset);
EXPECT_EQ(0x42U, object_files[0].size);
EXPECT_EQ(0x355b15b2U, object_files[0].align);
}
TEST_F(FatReaderTest, ThreeObjectFiles) {
Label obj1, obj2, obj3;
fat
.B32(0xcafebabe) // magic number
.B32(3); // number of architectures
// Three object file list entries.
AppendFatArch(0x0cb92c30, 0x6a159a71, obj1, 0xfb4, 0x2615dbe8);
AppendFatArch(0x0f3f1cbb, 0x6c55e90f, obj2, 0xc31, 0x83af6ffd);
AppendFatArch(0x3717276d, 0x10ecdc84, obj3, 0x4b3, 0x035267d7);
fat
// First object file data
.Mark(&obj1)
.Append(0xfb4, '*') // dummy contents
// Second object file data
.Mark(&obj2)
.Append(0xc31, '%') // dummy contents
// Third object file data
.Mark(&obj3)
.Append(0x4b3, '^'); // dummy contents
ReadFat();
ASSERT_EQ(3U, object_files.size());
// First object file.
EXPECT_EQ(0x0cb92c30, object_files[0].cputype);
EXPECT_EQ(0x6a159a71, object_files[0].cpusubtype);
EXPECT_EQ(obj1.Value(), object_files[0].offset);
EXPECT_EQ(0xfb4U, object_files[0].size);
EXPECT_EQ(0x2615dbe8U, object_files[0].align);
// Second object file.
EXPECT_EQ(0x0f3f1cbb, object_files[1].cputype);
EXPECT_EQ(0x6c55e90f, object_files[1].cpusubtype);
EXPECT_EQ(obj2.Value(), object_files[1].offset);
EXPECT_EQ(0xc31U, object_files[1].size);
EXPECT_EQ(0x83af6ffdU, object_files[1].align);
// Third object file.
EXPECT_EQ(0x3717276d, object_files[2].cputype);
EXPECT_EQ(0x10ecdc84, object_files[2].cpusubtype);
EXPECT_EQ(obj3.Value(), object_files[2].offset);
EXPECT_EQ(0x4b3U, object_files[2].size);
EXPECT_EQ(0x035267d7U, object_files[2].align);
}
TEST_F(FatReaderTest, BigEndianMachO32) {
fat.set_endianness(kBigEndian);
fat
.D32(0xfeedface) // Mach-O file magic number
.D32(0x1a9d0518) // cpu type
.D32(0x1b779357) // cpu subtype
.D32(0x009df67e) // file type
.D32(0) // no load commands
.D32(0) // the load commands occupy no bytes
.D32(0x21987a99); // flags
ReadFat();
// FatReader should treat a Mach-O file as if it were a fat binary file
// containing one object file --- the whole thing.
ASSERT_EQ(1U, object_files.size());
EXPECT_EQ(0x1a9d0518, object_files[0].cputype);
EXPECT_EQ(0x1b779357, object_files[0].cpusubtype);
EXPECT_EQ(0U, object_files[0].offset);
EXPECT_EQ(contents.size(), object_files[0].size);
}
TEST_F(FatReaderTest, BigEndianMachO64) {
fat.set_endianness(kBigEndian);
fat
.D32(0xfeedfacf) // Mach-O 64-bit file magic number
.D32(0x5aff8487) // cpu type
.D32(0x4c6a57f7) // cpu subtype
.D32(0x4392d2c8) // file type
.D32(0) // no load commands
.D32(0) // the load commands occupy no bytes
.D32(0x1b033eea); // flags
ReadFat();
// FatReader should treat a Mach-O file as if it were a fat binary file
// containing one object file --- the whole thing.
ASSERT_EQ(1U, object_files.size());
EXPECT_EQ(0x5aff8487, object_files[0].cputype);
EXPECT_EQ(0x4c6a57f7, object_files[0].cpusubtype);
EXPECT_EQ(0U, object_files[0].offset);
EXPECT_EQ(contents.size(), object_files[0].size);
}
TEST_F(FatReaderTest, LittleEndianMachO32) {
fat.set_endianness(kLittleEndian);
fat
.D32(0xfeedface) // Mach-O file magic number
.D32(0x1a9d0518) // cpu type
.D32(0x1b779357) // cpu subtype
.D32(0x009df67e) // file type
.D32(0) // no load commands
.D32(0) // the load commands occupy no bytes
.D32(0x21987a99); // flags
ReadFat();
// FatReader should treat a Mach-O file as if it were a fat binary file
// containing one object file --- the whole thing.
ASSERT_EQ(1U, object_files.size());
EXPECT_EQ(0x1a9d0518, object_files[0].cputype);
EXPECT_EQ(0x1b779357, object_files[0].cpusubtype);
EXPECT_EQ(0U, object_files[0].offset);
EXPECT_EQ(contents.size(), object_files[0].size);
}
TEST_F(FatReaderTest, LittleEndianMachO64) {
fat.set_endianness(kLittleEndian);
fat
.D32(0xfeedfacf) // Mach-O 64-bit file magic number
.D32(0x5aff8487) // cpu type
.D32(0x4c6a57f7) // cpu subtype
.D32(0x4392d2c8) // file type
.D32(0) // no load commands
.D32(0) // the load commands occupy no bytes
.D32(0x1b033eea); // flags
ReadFat();
// FatReader should treat a Mach-O file as if it were a fat binary file
// containing one object file --- the whole thing.
ASSERT_EQ(1U, object_files.size());
EXPECT_EQ(0x5aff8487, object_files[0].cputype);
EXPECT_EQ(0x4c6a57f7, object_files[0].cpusubtype);
EXPECT_EQ(0U, object_files[0].offset);
EXPECT_EQ(contents.size(), object_files[0].size);
}
TEST_F(FatReaderTest, IncompleteMach) {
fat.set_endianness(kLittleEndian);
fat
.D32(0xfeedfacf) // Mach-O 64-bit file magic number
.D32(0x5aff8487); // cpu type
// Truncated!
EXPECT_CALL(reporter, TooShort()).WillOnce(Return());
ReadFat(false);
}
// General mach_o::Reader tests.
// Dynamically scoped configuration data.
class WithConfiguration {
public:
// Establish the given parameters as the default for SizedSections
// created within the dynamic scope of this instance.
WithConfiguration(Endianness endianness, size_t word_size)
: endianness_(endianness), word_size_(word_size), saved_(current_) {
current_ = this;
}
~WithConfiguration() { current_ = saved_; }
static Endianness endianness() {
assert(current_);
return current_->endianness_;
}
static size_t word_size() {
assert(current_);
return current_->word_size_;
}
private:
// The innermost WithConfiguration in whose dynamic scope we are
// currently executing.
static WithConfiguration* current_;
// The innermost WithConfiguration whose dynamic scope encloses this
// WithConfiguration.
Endianness endianness_;
size_t word_size_;
WithConfiguration* saved_;
};
WithConfiguration* WithConfiguration::current_ = NULL;
// A test_assembler::Section with a size that we can cite. The start(),
// Here() and Mark() member functions of a SizedSection always represent
// offsets within the overall file.
class SizedSection: public test_assembler::Section {
public:
// Construct a section of the given endianness and word size.
explicit SizedSection(Endianness endianness, size_t word_size)
: test_assembler::Section(endianness), word_size_(word_size) {
assert(word_size_ == 32 || word_size_ == 64);
}
SizedSection()
: test_assembler::Section(WithConfiguration::endianness()),
word_size_(WithConfiguration::word_size()) {
assert(word_size_ == 32 || word_size_ == 64);
}
// Access/set this section's word size.
size_t word_size() const { return word_size_; }
void set_word_size(size_t word_size) {
assert(word_size_ == 32 || word_size_ == 64);
word_size_ = word_size;
}
// Return a label representing the size this section will have when it
// is Placed in some containing section.
Label final_size() const { return final_size_; }
// Append SECTION to the end of this section, and call its Finish member.
// Return a reference to this section.
SizedSection& Place(SizedSection* section) {
assert(section->endianness() == endianness());
section->Finish();
section->start() = Here();
test_assembler::Section::Append(*section);
return *this;
}
protected:
// Mark this section's contents as complete. For plain SizedSections, we
// set SECTION's start to its position in this section, and its final_size
// label to its current size. Derived classes can extend this as needed
// for their additional semantics.
virtual void Finish() {
final_size_ = Size();
}
// The word size for this data: either 32 or 64.
size_t word_size_;
private:
// This section's final size, set when we are placed in some other
// SizedSection.
Label final_size_;
};
// A SizedSection that is loaded into memory at a particular address.
class LoadedSection: public SizedSection {
public:
explicit LoadedSection(Label address = Label()) : address_(address) { }
// Return a label representing this section's address.
Label address() const { return address_; }
// Placing a loaded section within a loaded section sets the relationship
// between their addresses.
LoadedSection& Place(LoadedSection* section) {
section->address() = address() + Size();
SizedSection::Place(section);
return *this;
}
protected:
// The address at which this section's contents will be loaded.
Label address_;
};
// A SizedSection representing a segment load command.
class SegmentLoadCommand: public SizedSection {
public:
SegmentLoadCommand() : section_count_(0) { }
// Append a segment load command header with the given characteristics.
// The load command will refer to CONTENTS, which must be Placed in the
// file separately, at the desired position. Return a reference to this
// section.
SegmentLoadCommand& Header(const string& name, const LoadedSection& contents,
uint32_t maxprot, uint32_t initprot,
uint32_t flags) {
assert(contents.word_size() == word_size());
D32(word_size() == 32 ? LC_SEGMENT : LC_SEGMENT_64);
D32(final_size());
AppendCString(name, 16);
Append(endianness(), word_size() / 8, contents.address());
Append(endianness(), word_size() / 8, vmsize_);
Append(endianness(), word_size() / 8, contents.start());
Append(endianness(), word_size() / 8, contents.final_size());
D32(maxprot);
D32(initprot);
D32(final_section_count_);
D32(flags);
content_final_size_ = contents.final_size();
return *this;
}
// Return a label representing the size of this segment when loaded into
// memory. If this label is still undefined by the time we place this
// segment, it defaults to the final size of the segment's in-file
// contents. Return a reference to this load command.
Label& vmsize() { return vmsize_; }
// Add a section entry with the given characteristics to this segment
// load command. Return a reference to this. The section entry will refer
// to CONTENTS, which must be Placed in the segment's contents
// separately, at the desired position.
SegmentLoadCommand& AppendSectionEntry(const string& section_name,
const string& segment_name,
uint32_t alignment, uint32_t flags,
const LoadedSection& contents) {
AppendCString(section_name, 16);
AppendCString(segment_name, 16);
Append(endianness(), word_size() / 8, contents.address());
Append(endianness(), word_size() / 8, contents.final_size());
D32(contents.start());
D32(alignment);
D32(0); // relocations start
D32(0); // relocations size
D32(flags);
D32(0x93656b95); // reserved1
D32(0xc35a2473); // reserved2
if (word_size() == 64)
D32(0x70284b95); // reserved3
section_count_++;
return *this;
}
protected:
void Finish() {
final_section_count_ = section_count_;
if (!vmsize_.IsKnownConstant())
vmsize_ = content_final_size_;
SizedSection::Finish();
}
private:
// The number of sections that have been added to this segment so far.
size_t section_count_;
// A label representing the final number of sections this segment will hold.
Label final_section_count_;
// The size of the contents for this segment present in the file.
Label content_final_size_;
// A label representing the size of this segment when loaded; this can be
// larger than the size of its file contents, the difference being
// zero-filled. If not set explicitly by calling set_vmsize, this is set
// equal to the size of the contents.
Label vmsize_;
};
// A SizedSection holding a list of Mach-O load commands.
class LoadCommands: public SizedSection {
public:
LoadCommands() : command_count_(0) { }
// Return a label representing the final load command count.
Label final_command_count() const { return final_command_count_; }
// Increment the command count; return a reference to this section.
LoadCommands& CountCommand() {
command_count_++;
return *this;
}
// Place COMMAND, containing a load command, at the end of this section.
// Return a reference to this section.
LoadCommands& Place(SizedSection* section) {
SizedSection::Place(section);
CountCommand();
return *this;
}
protected:
// Mark this load command list as complete.
void Finish() {
SizedSection::Finish();
final_command_count_ = command_count_;
}
private:
// The number of load commands we have added to this file so far.
size_t command_count_;
// A label representing the final command count.
Label final_command_count_;
};
// A SizedSection holding the contents of a Mach-O file. Within a
// MachOFile, the start, Here, and Mark members refer to file offsets.
class MachOFile: public SizedSection {
public:
MachOFile() {
start() = 0;
}
// Create a Mach-O file header using the given characteristics and load
// command list. This Places COMMANDS immediately after the header.
// Return a reference to this section.
MachOFile& Header(LoadCommands* commands,
cpu_type_t cpu_type = CPU_TYPE_X86,
cpu_subtype_t cpu_subtype = CPU_SUBTYPE_I386_ALL,
FileType file_type = MH_EXECUTE,
uint32_t file_flags = (MH_TWOLEVEL |
MH_DYLDLINK |
MH_NOUNDEFS)) {
D32(word_size() == 32 ? 0xfeedface : 0xfeedfacf); // magic number
D32(cpu_type); // cpu type
D32(cpu_subtype); // cpu subtype
D32(file_type); // file type
D32(commands->final_command_count()); // number of load commands
D32(commands->final_size()); // their size in bytes
D32(file_flags); // flags
if (word_size() == 64)
D32(0x55638b90); // reserved
Place(commands);
return *this;
}
};
struct ReaderFixture {
ReaderFixture()
: reporter("reporter filename"),
reader(&reporter) {
EXPECT_CALL(reporter, BadHeader()).Times(0);
EXPECT_CALL(reporter, CPUTypeMismatch(_, _, _, _)).Times(0);
EXPECT_CALL(reporter, HeaderTruncated()).Times(0);
EXPECT_CALL(reporter, LoadCommandRegionTruncated()).Times(0);
EXPECT_CALL(reporter, LoadCommandsOverrun(_, _, _)).Times(0);
EXPECT_CALL(reporter, LoadCommandTooShort(_, _)).Times(0);
EXPECT_CALL(reporter, SectionsMissing(_)).Times(0);
EXPECT_CALL(reporter, MisplacedSegmentData(_)).Times(0);
EXPECT_CALL(reporter, MisplacedSectionData(_, _)).Times(0);
EXPECT_CALL(reporter, MisplacedSymbolTable()).Times(0);
EXPECT_CALL(reporter, UnsupportedCPUType(_)).Times(0);
EXPECT_CALL(load_command_handler, UnknownCommand(_, _)).Times(0);
EXPECT_CALL(load_command_handler, SegmentCommand(_)).Times(0);
}
void ReadFile(MachOFile* file,
bool expect_parse_success,
cpu_type_t expected_cpu_type,
cpu_subtype_t expected_cpu_subtype) {
ASSERT_TRUE(file->GetContents(&file_contents));
file_bytes = reinterpret_cast<const uint8_t*>(file_contents.data());
if (expect_parse_success) {
EXPECT_TRUE(reader.Read(file_bytes,
file_contents.size(),
expected_cpu_type,
expected_cpu_subtype));
} else {
EXPECT_FALSE(reader.Read(file_bytes,
file_contents.size(),
expected_cpu_type,
expected_cpu_subtype));
}
}
string file_contents;
const uint8_t* file_bytes;
MockReaderReporter reporter;
Reader reader;
MockLoadCommandHandler load_command_handler;
MockSectionHandler section_handler;
};
class ReaderTest: public ReaderFixture, public Test { };
TEST_F(ReaderTest, BadMagic) {
WithConfiguration config(kLittleEndian, 32);
const cpu_type_t kCPUType = 0x46b760df;
const cpu_subtype_t kCPUSubType = 0x76a0e7f7;
MachOFile file;
file
.D32(0x67bdebe1) // Not a proper magic number.
.D32(kCPUType) // cpu type
.D32(kCPUSubType) // cpu subtype
.D32(0x149fc717) // file type
.D32(0) // no load commands
.D32(0) // they occupy no bytes
.D32(0x80e71d64) // flags
.D32(0); // reserved
EXPECT_CALL(reporter, BadHeader()).WillOnce(Return());
ReadFile(&file, false, CPU_TYPE_ANY, kCPUSubType);
}
TEST_F(ReaderTest, MismatchedMagic) {
WithConfiguration config(kLittleEndian, 32);
const cpu_type_t kCPUType = CPU_TYPE_I386;
const cpu_subtype_t kCPUSubType = CPU_SUBTYPE_X86_ALL;
MachOFile file;
file
.D32(MH_CIGAM) // Right magic, but winds up wrong
// due to bitswapping
.D32(kCPUType) // cpu type
.D32(kCPUSubType) // cpu subtype
.D32(0x149fc717) // file type
.D32(0) // no load commands
.D32(0) // they occupy no bytes
.D32(0x80e71d64) // flags
.D32(0); // reserved
EXPECT_CALL(reporter, BadHeader()).WillOnce(Return());
ReadFile(&file, false, kCPUType, kCPUSubType);
}
TEST_F(ReaderTest, ShortMagic) {
WithConfiguration config(kBigEndian, 32);
MachOFile file;
file
.D16(0xfeed); // magic number
// truncated!
EXPECT_CALL(reporter, HeaderTruncated()).WillOnce(Return());
ReadFile(&file, false, CPU_TYPE_ANY, 0);
}
TEST_F(ReaderTest, ShortHeader) {
WithConfiguration config(kBigEndian, 32);
const cpu_type_t kCPUType = CPU_TYPE_ANY;
const cpu_subtype_t kCPUSubType = 0x76a0e7f7;
MachOFile file;
file
.D32(0xfeedface) // magic number
.D32(kCPUType) // cpu type
.D32(kCPUSubType) // cpu subtype
.D32(0x149fc717) // file type
.D32(0) // no load commands
.D32(0); // they occupy no bytes
EXPECT_CALL(reporter, HeaderTruncated()).WillOnce(Return());
ReadFile(&file, false, CPU_TYPE_ANY, kCPUSubType);
}
TEST_F(ReaderTest, MismatchedCPU) {
WithConfiguration config(kBigEndian, 32);
const cpu_type_t kCPUType = CPU_TYPE_I386;
const cpu_subtype_t kCPUSubType = CPU_SUBTYPE_X86_ALL;
MachOFile file;
file
.D32(MH_MAGIC) // Right magic for PPC (once bitswapped)
.D32(kCPUType) // cpu type
.D32(kCPUSubType) // cpu subtype
.D32(0x149fc717) // file type
.D32(0) // no load commands
.D32(0) // they occupy no bytes
.D32(0x80e71d64) // flags
.D32(0); // reserved
EXPECT_CALL(reporter,
CPUTypeMismatch(CPU_TYPE_I386, CPU_SUBTYPE_X86_ALL,
CPU_TYPE_POWERPC, CPU_SUBTYPE_POWERPC_ALL))
.WillOnce(Return());
ReadFile(&file, false, CPU_TYPE_POWERPC, CPU_SUBTYPE_POWERPC_ALL);
}
TEST_F(ReaderTest, LittleEndian32Bit) {
WithConfiguration config(kLittleEndian, 32);
const cpu_type_t kCPUType = 0x46b760df;
const cpu_subtype_t kCPUSubType = 0x76a0e7f7;
MachOFile file;
file
.D32(0xfeedface) // magic number
.D32(kCPUType) // cpu type
.D32(kCPUSubType) // cpu subtype
.D32(0x149fc717) // file type
.D32(0) // no load commands
.D32(0) // they occupy no bytes
.D32(0x80e71d64) // flags
.D32(0); // reserved
ReadFile(&file, true, CPU_TYPE_ANY, kCPUSubType);
EXPECT_FALSE(reader.bits_64());
EXPECT_FALSE(reader.big_endian());
EXPECT_EQ(kCPUType, reader.cpu_type());
EXPECT_EQ(kCPUSubType, reader.cpu_subtype());
EXPECT_EQ(FileType(0x149fc717), reader.file_type());
EXPECT_EQ(FileFlags(0x80e71d64), reader.flags());
}
TEST_F(ReaderTest, LittleEndian64Bit) {
WithConfiguration config(kLittleEndian, 64);
const cpu_type_t kCPUType = 0x46b760df;
const cpu_subtype_t kCPUSubType = 0x76a0e7f7;
MachOFile file;
file
.D32(0xfeedfacf) // magic number
.D32(kCPUType) // cpu type
.D32(kCPUSubType) // cpu subtype
.D32(0x149fc717) // file type
.D32(0) // no load commands
.D32(0) // they occupy no bytes
.D32(0x80e71d64) // flags
.D32(0); // reserved
ReadFile(&file, true, CPU_TYPE_ANY, kCPUSubType);
EXPECT_TRUE(reader.bits_64());
EXPECT_FALSE(reader.big_endian());
EXPECT_EQ(kCPUType, reader.cpu_type());
EXPECT_EQ(kCPUSubType, reader.cpu_subtype());
EXPECT_EQ(FileType(0x149fc717), reader.file_type());
EXPECT_EQ(FileFlags(0x80e71d64), reader.flags());
}
TEST_F(ReaderTest, BigEndian32Bit) {
WithConfiguration config(kBigEndian, 32);
const cpu_type_t kCPUType = 0x46b760df;
const cpu_subtype_t kCPUSubType = 0x76a0e7f7;
MachOFile file;
file
.D32(0xfeedface) // magic number
.D32(kCPUType) // cpu type
.D32(kCPUSubType) // cpu subtype
.D32(0x149fc717) // file type
.D32(0) // no load commands
.D32(0) // they occupy no bytes
.D32(0x80e71d64) // flags
.D32(0); // reserved
ReadFile(&file, true, CPU_TYPE_ANY, kCPUSubType);
EXPECT_FALSE(reader.bits_64());
EXPECT_TRUE(reader.big_endian());
EXPECT_EQ(kCPUType, reader.cpu_type());
EXPECT_EQ(kCPUSubType, reader.cpu_subtype());
EXPECT_EQ(FileType(0x149fc717), reader.file_type());
EXPECT_EQ(FileFlags(0x80e71d64), reader.flags());
}
TEST_F(ReaderTest, BigEndian64Bit) {
WithConfiguration config(kBigEndian, 64);
const cpu_type_t kCPUType = 0x46b760df;
const cpu_subtype_t kCPUSubType = 0x76a0e7f7;
MachOFile file;
file
.D32(0xfeedfacf) // magic number
.D32(kCPUType) // cpu type
.D32(kCPUSubType) // cpu subtype
.D32(0x149fc717) // file type
.D32(0) // no load commands
.D32(0) // they occupy no bytes
.D32(0x80e71d64) // flags
.D32(0); // reserved
ReadFile(&file, true, CPU_TYPE_ANY, kCPUSubType);
EXPECT_TRUE(reader.bits_64());
EXPECT_TRUE(reader.big_endian());
EXPECT_EQ(kCPUType, reader.cpu_type());
EXPECT_EQ(kCPUSubType, reader.cpu_subtype());
EXPECT_EQ(FileType(0x149fc717), reader.file_type());
EXPECT_EQ(FileFlags(0x80e71d64), reader.flags());
}
// Load command tests.
class LoadCommand: public ReaderFixture, public Test { };
TEST_F(LoadCommand, RegionTruncated) {
WithConfiguration config(kBigEndian, 64);
const cpu_type_t kCPUType = 0x46b760df;
const cpu_subtype_t kCPUSubType = 0x76a0e7f7;
MachOFile file;
file
.D32(0xfeedfacf) // magic number
.D32(kCPUType) // cpu type
.D32(kCPUSubType) // cpu subtype
.D32(0x149fc717) // file type
.D32(1) // one load command
.D32(40) // occupying 40 bytes
.D32(0x80e71d64) // flags
.D32(0) // reserved
.Append(20, 0); // load command region, not as long as
// Mach-O header promised
EXPECT_CALL(reporter, LoadCommandRegionTruncated()).WillOnce(Return());
ReadFile(&file, false, CPU_TYPE_ANY, kCPUSubType);
}
TEST_F(LoadCommand, None) {
WithConfiguration config(kLittleEndian, 32);
LoadCommands load_commands;
MachOFile file;
file.Header(&load_commands);
ReadFile(&file, true, CPU_TYPE_X86, CPU_SUBTYPE_I386_ALL);
EXPECT_FALSE(reader.bits_64());
EXPECT_FALSE(reader.big_endian());
EXPECT_EQ(CPU_TYPE_X86, reader.cpu_type());
EXPECT_EQ(CPU_SUBTYPE_I386_ALL, reader.cpu_subtype());
EXPECT_EQ(static_cast<uint32_t>(MH_EXECUTE), reader.file_type());
EXPECT_EQ(FileFlags(MH_TWOLEVEL |
MH_DYLDLINK |
MH_NOUNDEFS),
FileFlags(reader.flags()));
EXPECT_TRUE(reader.WalkLoadCommands(&load_command_handler));
}
TEST_F(LoadCommand, Unknown) {
WithConfiguration config(kBigEndian, 32);
LoadCommands load_commands;
load_commands
.CountCommand()
.D32(0x33293d4a) // unknown load command
.D32(40) // total size in bytes
.Append(32, '*'); // dummy data
MachOFile file;
file.Header(&load_commands);
ReadFile(&file, true, CPU_TYPE_ANY, 0);
EXPECT_FALSE(reader.bits_64());
EXPECT_TRUE(reader.big_endian());
EXPECT_EQ(CPU_TYPE_X86, reader.cpu_type());
EXPECT_EQ(CPU_SUBTYPE_I386_ALL, reader.cpu_subtype());
EXPECT_EQ(static_cast<uint32_t>(MH_EXECUTE), reader.file_type());
EXPECT_EQ(FileFlags(MH_TWOLEVEL |
MH_DYLDLINK |
MH_NOUNDEFS),
reader.flags());
ByteBuffer expected;
expected.start = file_bytes + load_commands.start().Value();
expected.end = expected.start + load_commands.final_size().Value();
EXPECT_CALL(load_command_handler, UnknownCommand(0x33293d4a,
expected))
.WillOnce(Return(true));
EXPECT_TRUE(reader.WalkLoadCommands(&load_command_handler));
}
TEST_F(LoadCommand, TypeIncomplete) {
WithConfiguration config(kLittleEndian, 32);
LoadCommands load_commands;
load_commands
.CountCommand()
.Append(3, 0); // load command type, incomplete
MachOFile file;
file.Header(&load_commands);
ReadFile(&file, true, CPU_TYPE_ANY, 0);
EXPECT_CALL(reporter, LoadCommandsOverrun(1, 0, 0))
.WillOnce(Return());
EXPECT_FALSE(reader.WalkLoadCommands(&load_command_handler));
}
TEST_F(LoadCommand, LengthIncomplete) {
WithConfiguration config(kBigEndian, 64);
LoadCommands load_commands;
load_commands
.CountCommand()
.D32(LC_SEGMENT); // load command
// no length
MachOFile file;
file.Header(&load_commands);
ReadFile(&file, true, CPU_TYPE_ANY, 0);
EXPECT_CALL(reporter, LoadCommandsOverrun(1, 0, LC_SEGMENT))
.WillOnce(Return());
EXPECT_FALSE(reader.WalkLoadCommands(&load_command_handler));
}
TEST_F(LoadCommand, ContentIncomplete) {
WithConfiguration config(kLittleEndian, 64);
LoadCommands load_commands;
load_commands
.CountCommand()
.D32(LC_SEGMENT) // load command
.D32(40) // total size in bytes
.Append(28, '*'); // not enough dummy data
MachOFile file;
file.Header(&load_commands);
ReadFile(&file, true, CPU_TYPE_ANY, 0);
EXPECT_CALL(reporter, LoadCommandsOverrun(1, 0, LC_SEGMENT))
.WillOnce(Return());
EXPECT_FALSE(reader.WalkLoadCommands(&load_command_handler));
}
TEST_F(LoadCommand, SegmentBE32) {
WithConfiguration config(kBigEndian, 32);
LoadedSection segment;
segment.address() = 0x1891139c;
segment.Append(42, '*'); // segment contents
SegmentLoadCommand segment_command;
segment_command
.Header("froon", segment, 0x94d6dd22, 0x8bdbc319, 0x990a16dd);
segment_command.vmsize() = 0xcb76584fU;
LoadCommands load_commands;
load_commands.Place(&segment_command);
MachOFile file;
file
.Header(&load_commands)
.Place(&segment);
ReadFile(&file, true, CPU_TYPE_ANY, 0);
Segment actual_segment;
EXPECT_CALL(load_command_handler, SegmentCommand(_))
.WillOnce(DoAll(SaveArg<0>(&actual_segment),
Return(true)));
EXPECT_TRUE(reader.WalkLoadCommands(&load_command_handler));
EXPECT_FALSE(actual_segment.bits_64);
EXPECT_EQ("froon", actual_segment.name);
EXPECT_EQ(0x1891139cU, actual_segment.vmaddr);
EXPECT_EQ(0xcb76584fU, actual_segment.vmsize);
EXPECT_EQ(0x94d6dd22U, actual_segment.maxprot);
EXPECT_EQ(0x8bdbc319U, actual_segment.initprot);
EXPECT_EQ(0x990a16ddU, actual_segment.flags);
EXPECT_EQ(0U, actual_segment.nsects);
EXPECT_EQ(0U, actual_segment.section_list.Size());
EXPECT_EQ(segment.final_size().Value(), actual_segment.contents.Size());
}
TEST_F(LoadCommand, SegmentLE32) {
WithConfiguration config(kLittleEndian, 32);
LoadedSection segment;
segment.address() = 0x4b877866;
segment.Append(42, '*'); // segment contents
SegmentLoadCommand segment_command;
segment_command
.Header("sixteenprecisely", segment,
0x350759ed, 0x6cf5a62e, 0x990a16dd);
segment_command.vmsize() = 0xcb76584fU;
LoadCommands load_commands;
load_commands.Place(&segment_command);
MachOFile file;
file
.Header(&load_commands)
.Place(&segment);
ReadFile(&file, true, CPU_TYPE_ANY, 0);
Segment actual_segment;
EXPECT_CALL(load_command_handler, SegmentCommand(_))
.WillOnce(DoAll(SaveArg<0>(&actual_segment),
Return(true)));
EXPECT_TRUE(reader.WalkLoadCommands(&load_command_handler));
EXPECT_FALSE(actual_segment.bits_64);
EXPECT_EQ("sixteenprecisely", actual_segment.name);
EXPECT_EQ(0x4b877866U, actual_segment.vmaddr);
EXPECT_EQ(0xcb76584fU, actual_segment.vmsize);
EXPECT_EQ(0x350759edU, actual_segment.maxprot);
EXPECT_EQ(0x6cf5a62eU, actual_segment.initprot);
EXPECT_EQ(0x990a16ddU, actual_segment.flags);
EXPECT_EQ(0U, actual_segment.nsects);
EXPECT_EQ(0U, actual_segment.section_list.Size());
EXPECT_EQ(segment.final_size().Value(), actual_segment.contents.Size());
}
TEST_F(LoadCommand, SegmentBE64) {
WithConfiguration config(kBigEndian, 64);
LoadedSection segment;
segment.address() = 0x79f484f77009e511ULL;
segment.Append(42, '*'); // segment contents
SegmentLoadCommand segment_command;
segment_command
.Header("froon", segment, 0x42b45da5, 0x8bdbc319, 0xb2335220);
segment_command.vmsize() = 0x8d92397ce6248abaULL;
LoadCommands load_commands;
load_commands.Place(&segment_command);
MachOFile file;
file
.Header(&load_commands)
.Place(&segment);
ReadFile(&file, true, CPU_TYPE_ANY, 0);
Segment actual_segment;
EXPECT_CALL(load_command_handler, SegmentCommand(_))
.WillOnce(DoAll(SaveArg<0>(&actual_segment),
Return(true)));
EXPECT_TRUE(reader.WalkLoadCommands(&load_command_handler));
EXPECT_EQ(true, actual_segment.bits_64);
EXPECT_EQ("froon", actual_segment.name);
EXPECT_EQ(0x79f484f77009e511ULL, actual_segment.vmaddr);
EXPECT_EQ(0x8d92397ce6248abaULL, actual_segment.vmsize);
EXPECT_EQ(0x42b45da5U, actual_segment.maxprot);
EXPECT_EQ(0x8bdbc319U, actual_segment.initprot);
EXPECT_EQ(0xb2335220U, actual_segment.flags);
EXPECT_EQ(0U, actual_segment.nsects);
EXPECT_EQ(0U, actual_segment.section_list.Size());
EXPECT_EQ(segment.final_size().Value(), actual_segment.contents.Size());
}
TEST_F(LoadCommand, SegmentLE64) {
WithConfiguration config(kLittleEndian, 64);
LoadedSection segment;
segment.address() = 0x50c0501dc5922d35ULL;
segment.Append(42, '*'); // segment contents
SegmentLoadCommand segment_command;
segment_command
.Header("sixteenprecisely", segment,
0x917c339d, 0xdbc446fa, 0xb650b563);
segment_command.vmsize() = 0x84ae73e7c75469bfULL;
LoadCommands load_commands;
load_commands.Place(&segment_command);
MachOFile file;
file
.Header(&load_commands)
.Place(&segment);
ReadFile(&file, true, CPU_TYPE_ANY, 0);
Segment actual_segment;
EXPECT_CALL(load_command_handler, SegmentCommand(_))
.WillOnce(DoAll(SaveArg<0>(&actual_segment),
Return(true)));
EXPECT_TRUE(reader.WalkLoadCommands(&load_command_handler));
EXPECT_EQ(true, actual_segment.bits_64);
EXPECT_EQ("sixteenprecisely", actual_segment.name);
EXPECT_EQ(0x50c0501dc5922d35ULL, actual_segment.vmaddr);
EXPECT_EQ(0x84ae73e7c75469bfULL, actual_segment.vmsize);
EXPECT_EQ(0x917c339dU, actual_segment.maxprot);
EXPECT_EQ(0xdbc446faU, actual_segment.initprot);
EXPECT_EQ(0xb650b563U, actual_segment.flags);
EXPECT_EQ(0U, actual_segment.nsects);
EXPECT_EQ(0U, actual_segment.section_list.Size());
EXPECT_EQ(segment.final_size().Value(), actual_segment.contents.Size());
}
TEST_F(LoadCommand, SegmentCommandTruncated) {
WithConfiguration config(kBigEndian, 32);
LoadedSection segment_contents;
segment_contents.Append(20, '*'); // lah di dah
SizedSection command;
command
.D32(LC_SEGMENT) // command type
.D32(command.final_size()) // command size
.AppendCString("too-short", 16) // segment name
.D32(0x9c759211) // vmaddr
.D32(segment_contents.final_size()) // vmsize
.D32(segment_contents.start()) // file offset
.D32(segment_contents.final_size()) // file size
.D32(0x56f28446) // max protection
.D32(0xe7910dcb) // initial protection
.D32(0) // no sections
.Append(3, 0); // flags (one byte short!)
LoadCommands load_commands;
load_commands.Place(&command);
MachOFile file;
file
.Header(&load_commands)
.Place(&segment_contents);
ReadFile(&file, true, CPU_TYPE_ANY, 0);
EXPECT_CALL(reporter, LoadCommandTooShort(0, LC_SEGMENT))
.WillOnce(Return());
EXPECT_FALSE(reader.WalkLoadCommands(&load_command_handler));
}
TEST_F(LoadCommand, SegmentBadContentOffset) {
WithConfiguration config(kLittleEndian, 32);
// Instead of letting a Place call set the segment's file offset and size,
// set them ourselves, to check that the parser catches invalid offsets
// instead of handing us bogus pointers.
LoadedSection segment;
segment.address() = 0x4db5489c;
segment.start() = 0x7e189e76; // beyond end of file
segment.final_size() = 0x98b9c3ab;
SegmentLoadCommand segment_command;
segment_command
.Header("notmerelyfifteen", segment, 0xcbab25ee, 0x359a20db, 0x68a3933f);
LoadCommands load_commands;
load_commands.Place(&segment_command);
MachOFile file;
file.Header(&load_commands);
ReadFile(&file, true, CPU_TYPE_ANY, 0);
EXPECT_CALL(reporter, MisplacedSegmentData("notmerelyfifteen"))
.WillOnce(Return());
EXPECT_FALSE(reader.WalkLoadCommands(&load_command_handler));
}
TEST_F(LoadCommand, ThreeLoadCommands) {
WithConfiguration config(kBigEndian, 32);
LoadedSection seg1, seg2, seg3;
SegmentLoadCommand cmd1, cmd2, cmd3;
seg1.Append(128, '@');
seg1.address() = 0xa7f61ef6;
cmd1.Header("head", seg1, 0x88bf1cc7, 0x889a26a4, 0xe9b80d87);
// Include some dummy data at the end of the load command. Since we
// didn't claim to have any sections, the reader should ignore this. But
// making sure the commands have different lengths ensures that we're
// using the right command's length to advance the LoadCommandIterator.
cmd1.Append(128, '!');
seg2.Append(42, '*');
seg2.address() = 0xc70fc909;
cmd2.Header("thorax", seg2, 0xde7327f4, 0xfdaf771d, 0x65e74b30);
// More dummy data at the end of the load command.
cmd2.Append(32, '^');
seg3.Append(42, '%');
seg3.address() = 0x46b3ab05;
cmd3.Header("abdomen", seg3, 0x7098b70d, 0x8d8d7728, 0x5131419b);
// More dummy data at the end of the load command.
cmd3.Append(64, '&');
LoadCommands load_commands;
load_commands.Place(&cmd1).Place(&cmd2).Place(&cmd3);
MachOFile file;
file.Header(&load_commands).Place(&seg1).Place(&seg2).Place(&seg3);
ReadFile(&file, true, CPU_TYPE_ANY, 0);
{
InSequence s;
EXPECT_CALL(load_command_handler,
SegmentCommand(Field(&Segment::name, "head")))
.WillOnce(Return(true));
EXPECT_CALL(load_command_handler,
SegmentCommand(Field(&Segment::name, "thorax")))
.WillOnce(Return(true));
EXPECT_CALL(load_command_handler,
SegmentCommand(Field(&Segment::name, "abdomen")))
.WillOnce(Return(true));
}
EXPECT_TRUE(reader.WalkLoadCommands(&load_command_handler));
}
static inline Matcher<const Section&> MatchSection(
Matcher<bool> bits_64,
Matcher<const string&> section_name,
Matcher<const string&> segment_name,
Matcher<uint64_t> address,
Matcher<uint32_t> alignment,
Matcher<uint32_t> flags,
Matcher<const ByteBuffer&> contents) {
return AllOf(AllOf(Field(&Section::bits_64, bits_64),
Field(&Section::section_name, section_name),
Field(&Section::segment_name, segment_name),
Field(&Section::address, address)),
AllOf(Field(&Section::align, alignment),
Field(&Section::flags, flags),
Field(&Section::contents, contents)));
}
static inline Matcher<const Section&> MatchSection(
Matcher<bool> bits_64,
Matcher<const string&> section_name,
Matcher<const string&> segment_name,
Matcher<uint64_t> address) {
return AllOf(Field(&Section::bits_64, bits_64),
Field(&Section::section_name, section_name),
Field(&Section::segment_name, segment_name),
Field(&Section::address, address));
}
TEST_F(LoadCommand, OneSegmentTwoSections) {
WithConfiguration config(kBigEndian, 64);
// Create some sections with some data.
LoadedSection section1, section2;
section1.Append("buddha's hand");
section2.Append("kumquat");
// Create a segment to hold them.
LoadedSection segment;
segment.address() = 0xe1d0eeec;
segment.Place(&section2).Place(&section1);
SegmentLoadCommand segment_command;
segment_command
.Header("head", segment, 0x92c9568c, 0xa89f2627, 0x4dc7a1e2)
.AppendSectionEntry("mandarin", "kishu", 12, 0x8cd4604bU, section1)
.AppendSectionEntry("bergamot", "cara cara", 12, 0x98746efaU, section2);
LoadCommands commands;
commands.Place(&segment_command);
MachOFile file;
file.Header(&commands).Place(&segment);
ReadFile(&file, true, CPU_TYPE_ANY, 0);
Segment actual_segment;
EXPECT_CALL(load_command_handler, SegmentCommand(_))
.WillOnce(DoAll(SaveArg<0>(&actual_segment),
Return(true)));
EXPECT_TRUE(reader.WalkLoadCommands(&load_command_handler));
{
InSequence s;
ByteBuffer contents1;
contents1.start = file_bytes + section1.start().Value();
contents1.end = contents1.start + section1.final_size().Value();
EXPECT_EQ("buddha's hand",
string(reinterpret_cast<const char*>(contents1.start),
contents1.Size()));
EXPECT_CALL(section_handler,
HandleSection(MatchSection(true, "mandarin", "kishu",
section1.address().Value(), 12,
0x8cd4604bU, contents1)))
.WillOnce(Return(true));
ByteBuffer contents2;
contents2.start = file_bytes + section2.start().Value();
contents2.end = contents2.start + section2.final_size().Value();
EXPECT_EQ("kumquat",
string(reinterpret_cast<const char*>(contents2.start),
contents2.Size()));
EXPECT_CALL(section_handler,
HandleSection(MatchSection(true, "bergamot", "cara cara",
section2.address().Value(), 12,
0x98746efaU, contents2)))
.WillOnce(Return(true));
}
EXPECT_TRUE(reader.WalkSegmentSections(actual_segment, &section_handler));
}
TEST_F(LoadCommand, MisplacedSectionBefore) {
WithConfiguration config(kLittleEndian, 64);
// The segment.
LoadedSection segment;
segment.address() = 0x696d83cc;
segment.Append(10, '0');
// The contents of the following sections don't matter, because
// we're not really going to Place them in segment; we're just going
// to set all their labels by hand to get the (impossible)
// configurations we want.
// A section whose starting offset is before that of its section.
LoadedSection before;
before.Append(10, '1');
before.start() = segment.start() - 1;
before.address() = segment.address() - 1;
before.final_size() = before.Size();
SegmentLoadCommand command;
command
.Header("segment", segment, 0x173baa29, 0x8407275d, 0xed8f7057)
.AppendSectionEntry("before", "segment", 0, 0x686c6921, before);
LoadCommands commands;
commands.Place(&command);
MachOFile file;
file.Header(&commands).Place(&segment);
ReadFile(&file, true, CPU_TYPE_ANY, 0);
Segment actual_segment;
EXPECT_TRUE(reader.FindSegment("segment", &actual_segment));
EXPECT_CALL(reporter, MisplacedSectionData("before", "segment"))
.WillOnce(Return());
EXPECT_FALSE(reader.WalkSegmentSections(actual_segment, &section_handler));
}
TEST_F(LoadCommand, MisplacedSectionAfter) {
WithConfiguration config(kLittleEndian, 64);
// The segment.
LoadedSection segment;
segment.address() = 0x696d83cc;
segment.Append(10, '0');
// The contents of the following sections don't matter, because
// we're not really going to Place them in segment; we're just going
// to set all their labels by hand to get the (impossible)
// configurations we want.
// A section whose starting offset is after the end of its section.
LoadedSection after;
after.Append(10, '2');
after.start() = segment.start() + 11;
after.address() = segment.address() + 11;
after.final_size() = after.Size();
SegmentLoadCommand command;
command
.Header("segment", segment, 0x173baa29, 0x8407275d, 0xed8f7057)
.AppendSectionEntry("after", "segment", 0, 0x2ee50124, after);
LoadCommands commands;
commands.Place(&command);
MachOFile file;
file.Header(&commands).Place(&segment);
ReadFile(&file, true, CPU_TYPE_ANY, 0);
Segment actual_segment;
EXPECT_TRUE(reader.FindSegment("segment", &actual_segment));
EXPECT_CALL(reporter, MisplacedSectionData("after", "segment"))
.WillOnce(Return());
EXPECT_FALSE(reader.WalkSegmentSections(actual_segment, &section_handler));
}
TEST_F(LoadCommand, MisplacedSectionTooBig) {
WithConfiguration config(kLittleEndian, 64);
// The segment.
LoadedSection segment;
segment.address() = 0x696d83cc;
segment.Append(10, '0');
// The contents of the following sections don't matter, because
// we're not really going to Place them in segment; we're just going
// to set all their labels by hand to get the (impossible)
// configurations we want.
// A section that extends beyond the end of its section.
LoadedSection too_big;
too_big.Append(10, '3');
too_big.start() = segment.start() + 1;
too_big.address() = segment.address() + 1;
too_big.final_size() = too_big.Size();
SegmentLoadCommand command;
command
.Header("segment", segment, 0x173baa29, 0x8407275d, 0xed8f7057)
.AppendSectionEntry("too big", "segment", 0, 0x8b53ae5c, too_big);
LoadCommands commands;
commands.Place(&command);
MachOFile file;
file.Header(&commands).Place(&segment);
ReadFile(&file, true, CPU_TYPE_ANY, 0);
Segment actual_segment;
EXPECT_TRUE(reader.FindSegment("segment", &actual_segment));
EXPECT_CALL(reporter, MisplacedSectionData("too big", "segment"))
.WillOnce(Return());
EXPECT_FALSE(reader.WalkSegmentSections(actual_segment, &section_handler));
}
// The segments in a .dSYM bundle's Mach-O file have their file offset
// and size set to zero, but the sections don't. The reader shouldn't
// report an error in this case.
TEST_F(LoadCommand, ZappedSegment) {
WithConfiguration config(kBigEndian, 32);
// The segment.
LoadedSection segment;
segment.address() = 0x696d83cc;
segment.start() = 0;
segment.final_size() = 0;
// The section.
LoadedSection section;
section.address() = segment.address();
section.start() = 0;
section.final_size() = 1000; // extends beyond its segment
SegmentLoadCommand command;
command
.Header("zapped", segment, 0x0861a5cb, 0x68ccff67, 0x0b66255c)
.AppendSectionEntry("twitching", "zapped", 0, 0x93b3bd42, section);
LoadCommands commands;
commands.Place(&command);
MachOFile file;
file.Header(&commands);
ReadFile(&file, true, CPU_TYPE_ANY, 0);
Segment actual_segment;
EXPECT_TRUE(reader.FindSegment("zapped", &actual_segment));
ByteBuffer zapped_extent(NULL, 0);
EXPECT_CALL(section_handler,
HandleSection(MatchSection(false, "twitching", "zapped",
0x696d83cc, 0, 0x93b3bd42,
zapped_extent)))
.WillOnce(Return(true));
EXPECT_TRUE(reader.WalkSegmentSections(actual_segment, &section_handler));
}
TEST_F(LoadCommand, MapSegmentSections) {
WithConfiguration config(kLittleEndian, 32);
// Create some sections with some data.
LoadedSection section1, section2, section3, section4;
section1.Append("buddha's hand");
section2.start() = 0; // Section 2 is an S_ZEROFILL section.
section2.final_size() = 0;
section3.Append("shasta gold");
section4.Append("satsuma");
// Create two segments to hold them.
LoadedSection segment1, segment2;
segment1.address() = 0x13e6c8a9;
segment1.Place(&section3).Place(&section1);
segment2.set_word_size(64);
segment2.address() = 0x04d462e2;
segment2.Place(&section4);
section2.address() = segment2.address() + segment2.Size();
SegmentLoadCommand segment_command1, segment_command2;
segment_command1
.Header("head", segment1, 0x67d955a6, 0x7a61c13e, 0xe3e50c64)
.AppendSectionEntry("mandarin", "head", 12, 0x5bb565d7, section1)
.AppendSectionEntry("bergamot", "head", 12, 0x8620de73, section3);
segment_command2.set_word_size(64);
segment_command2
.Header("thorax", segment2, 0x7aab2419, 0xe908007f, 0x17961d33)
.AppendSectionEntry("sixteenprecisely", "thorax",
12, S_ZEROFILL, section2)
.AppendSectionEntry("cara cara", "thorax", 12, 0xb6c5dd8a, section4);
LoadCommands commands;
commands.Place(&segment_command1).Place(&segment_command2);
MachOFile file;
file.Header(&commands).Place(&segment1).Place(&segment2);
ReadFile(&file, true, CPU_TYPE_ANY, 0);
Segment segment;
SectionMap section_map;
EXPECT_FALSE(reader.FindSegment("smoot", &segment));
ASSERT_TRUE(reader.FindSegment("thorax", &segment));
ASSERT_TRUE(reader.MapSegmentSections(segment, &section_map));
EXPECT_FALSE(section_map.find("sixteenpreciselyandthensome")
!= section_map.end());
EXPECT_FALSE(section_map.find("mandarin") != section_map.end());
ASSERT_TRUE(section_map.find("cara cara") != section_map.end());
EXPECT_THAT(section_map["cara cara"],
MatchSection(true, "cara cara", "thorax", 0x04d462e2));
ASSERT_TRUE(section_map.find("sixteenprecisely")
!= section_map.end());
ByteBuffer sixteenprecisely_contents(NULL, 0);
EXPECT_THAT(section_map["sixteenprecisely"],
MatchSection(true, "sixteenprecisely", "thorax",
0x04d462e2 + 7, 12, S_ZEROFILL,
sixteenprecisely_contents));
ASSERT_TRUE(reader.FindSegment("head", &segment));
ASSERT_TRUE(reader.MapSegmentSections(segment, &section_map));
ASSERT_TRUE(section_map.find("mandarin") != section_map.end());
EXPECT_THAT(section_map["mandarin"],
MatchSection(false, "mandarin", "head", 0x13e6c8a9 + 11));
ASSERT_TRUE(section_map.find("bergamot") != section_map.end());
EXPECT_THAT(section_map["bergamot"],
MatchSection(false, "bergamot", "head", 0x13e6c8a9));
}
TEST_F(LoadCommand, FindSegment) {
WithConfiguration config(kBigEndian, 32);
LoadedSection segment1, segment2, segment3;
segment1.address() = 0xb8ae5752;
segment1.Append("Some contents!");
segment2.address() = 0xd6b0ce83;
segment2.Append("Different stuff.");
segment3.address() = 0x7374fd2a;
segment3.Append("Further materials.");
SegmentLoadCommand cmd1, cmd2, cmd3;
cmd1.Header("first", segment1, 0xfadb6932, 0x175bf529, 0x0de790ad);
cmd2.Header("second", segment2, 0xeef716e0, 0xe103a9d7, 0x7d38a8ef);
cmd3.Header("third", segment3, 0xe172b39e, 0x86012f07, 0x080ac94d);
LoadCommands commands;
commands.Place(&cmd1).Place(&cmd2).Place(&cmd3);
MachOFile file;
file.Header(&commands).Place(&segment1).Place(&segment2).Place(&segment3);
ReadFile(&file, true, CPU_TYPE_ANY, 0);
Segment actual_segment;
EXPECT_FALSE(reader.FindSegment("murphy", &actual_segment));
EXPECT_TRUE(reader.FindSegment("second", &actual_segment));
EXPECT_EQ(0xd6b0ce83, actual_segment.vmaddr);
}
// Symtab tests.
// A StringAssembler is a class for generating .stabstr sections to present
// as input to the STABS parser.
class StringAssembler: public SizedSection {
public:
// Add the string S to this StringAssembler, and return the string's
// offset within this compilation unit's strings.
size_t Add(const string& s) {
size_t offset = Size();
AppendCString(s);
return offset;
}
};
// A SymbolAssembler is a class for generating .stab sections to present as
// test input for the STABS parser.
class SymbolAssembler: public SizedSection {
public:
// Create a SymbolAssembler that uses StringAssembler for its strings.
explicit SymbolAssembler(StringAssembler* string_assembler)
: string_assembler_(string_assembler),
entry_count_(0) { }
// Append a STAB entry to the end of this section with the given
// characteristics. NAME is the offset of this entry's name string within
// its compilation unit's portion of the .stabstr section; this can be a
// value generated by a StringAssembler. Return a reference to this
// SymbolAssembler.
SymbolAssembler& Symbol(uint8_t type, uint8_t other, Label descriptor,
Label value, Label name) {
D32(name);
D8(type);
D8(other);
D16(descriptor);
Append(endianness(), word_size_ / 8, value);
entry_count_++;
return *this;
}
// As above, but automatically add NAME to our StringAssembler.
SymbolAssembler& Symbol(uint8_t type, uint8_t other, Label descriptor,
Label value, const string& name) {
return Symbol(type, other, descriptor, value, string_assembler_->Add(name));
}
private:
// The strings for our STABS entries.
StringAssembler* string_assembler_;
// The number of entries in this compilation unit so far.
size_t entry_count_;
};
class Symtab: public ReaderFixture, public Test { };
TEST_F(Symtab, Symtab32) {
WithConfiguration config(kLittleEndian, 32);
StringAssembler strings;
SymbolAssembler symbols(&strings);
symbols
.Symbol(0x52, 0x7c, 0x3470, 0x9bb02e7c, "hrududu")
.Symbol(0x50, 0x90, 0x7520, 0x1122525d, "Frith");
SizedSection symtab_command;
symtab_command
.D32(LC_SYMTAB) // command
.D32(symtab_command.final_size()) // size
.D32(symbols.start()) // file offset of symbols
.D32(2) // symbol count
.D32(strings.start()) // file offset of strings
.D32(strings.final_size()); // strings size
LoadCommands load_commands;
load_commands.Place(&symtab_command);
MachOFile file;
file.Header(&load_commands).Place(&symbols).Place(&strings);
ReadFile(&file, true, CPU_TYPE_ANY, 0);
ByteBuffer symbols_found, strings_found;
EXPECT_CALL(load_command_handler, SymtabCommand(_, _))
.WillOnce(DoAll(SaveArg<0>(&symbols_found),
SaveArg<1>(&strings_found),
Return(true)));
EXPECT_TRUE(reader.WalkLoadCommands(&load_command_handler));
EXPECT_EQ(24U, symbols_found.Size());
EXPECT_EQ(14U, strings_found.Size());
}
TEST_F(Symtab, Symtab64) {
WithConfiguration config(kBigEndian, 64);
StringAssembler strings;
SymbolAssembler symbols(&strings);
symbols
.Symbol(0xa7, 0xaf, 0x03af, 0x42f3072c74335181ULL, "foo")
.Symbol(0xb0, 0x9a, 0x2aa7, 0x2e2d349b3d5744a0ULL, "bar");
SizedSection symtab_command;
symtab_command
.D32(LC_SYMTAB) // command
.D32(symtab_command.final_size()) // size
.D32(symbols.start()) // file offset of symbols
.D32(2) // symbol count
.D32(strings.start()) // file offset of strings
.D32(strings.final_size()); // strings size
LoadCommands load_commands;
load_commands.Place(&symtab_command);
MachOFile file;
file.Header(&load_commands).Place(&symbols).Place(&strings);
ReadFile(&file, true, CPU_TYPE_ANY, 0);
ByteBuffer symbols_found, strings_found;
EXPECT_CALL(load_command_handler, SymtabCommand(_, _))
.WillOnce(DoAll(SaveArg<0>(&symbols_found),
SaveArg<1>(&strings_found),
Return(true)));
EXPECT_TRUE(reader.WalkLoadCommands(&load_command_handler));
EXPECT_EQ(32U, symbols_found.Size());
EXPECT_EQ(8U, strings_found.Size());
}
TEST_F(Symtab, SymtabMisplacedSymbols) {
WithConfiguration config(kBigEndian, 32);
StringAssembler strings;
SymbolAssembler symbols(&strings);
symbols
.Symbol(0xa7, 0xaf, 0x03af, 0x42f3072c74335181ULL, "foo")
.Symbol(0xb0, 0x9a, 0x2aa7, 0x2e2d349b3d5744a0ULL, "bar");
SizedSection symtab_command;
symtab_command
.D32(LC_SYMTAB) // command
.D32(symtab_command.final_size()) // size
.D32(symbols.start()) // file offset of symbols
.D32(3) // symbol count (too many)
.D32(strings.start()) // file offset of strings
.D32(strings.final_size()); // strings size
LoadCommands load_commands;
load_commands.Place(&symtab_command);
MachOFile file;
// Put symbols at end, so the excessive length will be noticed.
file.Header(&load_commands).Place(&strings).Place(&symbols);
ReadFile(&file, true, CPU_TYPE_ANY, 0);
EXPECT_CALL(reporter, MisplacedSymbolTable()).Times(1);
EXPECT_FALSE(reader.WalkLoadCommands(&load_command_handler));
}
TEST_F(Symtab, SymtabMisplacedStrings) {
WithConfiguration config(kLittleEndian, 32);
StringAssembler strings;
SymbolAssembler symbols(&strings);
symbols
.Symbol(0xa7, 0xaf, 0x03af, 0x42f3072c74335181ULL, "foo")
.Symbol(0xb0, 0x9a, 0x2aa7, 0x2e2d349b3d5744a0ULL, "bar");
SizedSection symtab_command;
symtab_command
.D32(LC_SYMTAB) // command
.D32(symtab_command.final_size()) // size
.D32(symbols.start()) // file offset of symbols
.D32(2) // symbol count
.D32(strings.start()) // file offset of strings
.D32(strings.final_size() + 1); // strings size (too long)
LoadCommands load_commands;
load_commands.Place(&symtab_command);
MachOFile file;
// Put strings at end, so the excessive length will be noticed.
file.Header(&load_commands).Place(&symbols).Place(&strings);
ReadFile(&file, true, CPU_TYPE_ANY, 0);
EXPECT_CALL(reporter, MisplacedSymbolTable()).Times(1);
EXPECT_FALSE(reader.WalkLoadCommands(&load_command_handler));
}