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crashpad/util/win/process_info_test.cc
Mark Mentovai 4b450c8137 test: Use (actual, [un]expected) in gtest {ASSERT,EXPECT}_{EQ,NE} 
gtest used to require (expected, actual) ordering for arguments to
EXPECT_EQ and ASSERT_EQ, and in failed test assertions would identify
each side as “expected” or “actual.” Tests in Crashpad adhered to this
traditional ordering. After a gtest change in February 2016, it is now
agnostic with respect to the order of these arguments.

This change mechanically updates all uses of these macros to (actual,
expected) by reversing them. This provides consistency with our use of
the logging CHECK_EQ and DCHECK_EQ macros, and makes for better
readability by ordinary native speakers. The rough (but working!)
conversion tool is
https://chromium-review.googlesource.com/c/466727/1/rewrite_expectassert_eq.py,
and “git cl format” cleaned up its output.

EXPECT_NE and ASSERT_NE never had a preferred ordering. gtest never made
a judgment that one side or the other needed to provide an “unexpected”
value. Consequently, some code used (unexpected, actual) while other
code used (actual, unexpected). For consistency with the new EXPECT_EQ
and ASSERT_EQ usage, as well as consistency with CHECK_NE and DCHECK_NE,
this change also updates these use sites to (actual, unexpected) where
one side can be called “unexpected” as, for example, std::string::npos
can be. Unfortunately, this portion was a manual conversion.

References:

https://github.com/google/googletest/blob/master/googletest/docs/Primer.md#binary-comparison
77d6b17338
https://github.com/google/googletest/pull/713

Change-Id: I978fef7c94183b8b1ef63f12f5ab4d6693626be3
Reviewed-on: https://chromium-review.googlesource.com/466727
Reviewed-by: Scott Graham <scottmg@chromium.org>
2017-04-04 12:34:24 +00:00

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// Copyright 2015 The Crashpad Authors. All rights reserved.
//
// Licensed under the Apache License, Version 2.0 (the "License");
// you may not use this file except in compliance with the License.
// You may obtain a copy of the License at
//
// http://www.apache.org/licenses/LICENSE-2.0
//
// Unless required by applicable law or agreed to in writing, software
// distributed under the License is distributed on an "AS IS" BASIS,
// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
// See the License for the specific language governing permissions and
// limitations under the License.
#include "util/win/process_info.h"
#include <dbghelp.h>
#include <intrin.h>
#include <wchar.h>
#include <memory>
#include "base/files/file_path.h"
#include "base/strings/stringprintf.h"
#include "base/strings/utf_string_conversions.h"
#include "build/build_config.h"
#include "gtest/gtest.h"
#include "test/errors.h"
#include "test/scoped_temp_dir.h"
#include "test/test_paths.h"
#include "test/win/child_launcher.h"
#include "util/file/file_io.h"
#include "util/misc/random_string.h"
#include "util/misc/uuid.h"
#include "util/win/command_line.h"
#include "util/win/get_function.h"
#include "util/win/handle.h"
#include "util/win/scoped_handle.h"
namespace crashpad {
namespace test {
namespace {
const wchar_t kNtdllName[] = L"\\ntdll.dll";
bool IsProcessWow64(HANDLE process_handle) {
static const auto is_wow64_process =
GET_FUNCTION(L"kernel32.dll", ::IsWow64Process);
if (!is_wow64_process)
return false;
BOOL is_wow64;
if (!is_wow64_process(process_handle, &is_wow64)) {
PLOG(ERROR) << "IsWow64Process";
return false;
}
return !!is_wow64;
}
void VerifyAddressInInCodePage(const ProcessInfo& process_info,
WinVMAddress code_address) {
// Make sure the child code address is an code page address with the right
// information.
const ProcessInfo::MemoryBasicInformation64Vector& memory_info =
process_info.MemoryInfo();
bool found_region = false;
for (const auto& mi : memory_info) {
if (mi.BaseAddress <= code_address &&
mi.BaseAddress + mi.RegionSize > code_address) {
EXPECT_EQ(mi.State, MEM_COMMIT);
EXPECT_EQ(mi.Protect, PAGE_EXECUTE_READ);
EXPECT_EQ(mi.Type, MEM_IMAGE);
EXPECT_FALSE(found_region);
found_region = true;
}
}
EXPECT_TRUE(found_region);
}
TEST(ProcessInfo, Self) {
ProcessInfo process_info;
ASSERT_TRUE(process_info.Initialize(GetCurrentProcess()));
EXPECT_EQ(process_info.ProcessID(), GetCurrentProcessId());
EXPECT_GT(process_info.ParentProcessID(), 0u);
#if defined(ARCH_CPU_64_BITS)
EXPECT_TRUE(process_info.Is64Bit());
EXPECT_FALSE(process_info.IsWow64());
#else
EXPECT_FALSE(process_info.Is64Bit());
if (IsProcessWow64(GetCurrentProcess()))
EXPECT_TRUE(process_info.IsWow64());
else
EXPECT_FALSE(process_info.IsWow64());
#endif
std::wstring command_line;
EXPECT_TRUE(process_info.CommandLine(&command_line));
EXPECT_EQ(command_line, std::wstring(GetCommandLine()));
std::vector<ProcessInfo::Module> modules;
EXPECT_TRUE(process_info.Modules(&modules));
ASSERT_GE(modules.size(), 2u);
const wchar_t kSelfName[] = L"\\crashpad_util_test.exe";
ASSERT_GE(modules[0].name.size(), wcslen(kSelfName));
EXPECT_EQ(modules[0].name.substr(modules[0].name.size() - wcslen(kSelfName)),
kSelfName);
ASSERT_GE(modules[1].name.size(), wcslen(kNtdllName));
EXPECT_EQ(modules[1].name.substr(modules[1].name.size() - wcslen(kNtdllName)),
kNtdllName);
EXPECT_EQ(modules[0].dll_base,
reinterpret_cast<uintptr_t>(GetModuleHandle(nullptr)));
EXPECT_EQ(modules[1].dll_base,
reinterpret_cast<uintptr_t>(GetModuleHandle(L"ntdll.dll")));
EXPECT_GT(modules[0].size, 0);
EXPECT_GT(modules[1].size, 0);
EXPECT_EQ(modules[0].timestamp,
GetTimestampForLoadedLibrary(GetModuleHandle(nullptr)));
// System modules are forced to particular stamps and the file header values
// don't match the on-disk times. Just make sure we got some data here.
EXPECT_GT(modules[1].timestamp, 0);
// Find something we know is a code address and confirm expected memory
// information settings.
VerifyAddressInInCodePage(process_info,
reinterpret_cast<WinVMAddress>(_ReturnAddress()));
}
void TestOtherProcess(const base::string16& directory_modification) {
ProcessInfo process_info;
UUID done_uuid;
done_uuid.InitializeWithNew();
ScopedKernelHANDLE done(
CreateEvent(nullptr, true, false, done_uuid.ToString16().c_str()));
ASSERT_TRUE(done.get()) << ErrorMessage("CreateEvent");
base::FilePath test_executable = TestPaths::Executable();
std::wstring child_test_executable =
test_executable.DirName()
.Append(directory_modification)
.Append(test_executable.BaseName().RemoveFinalExtension().value() +
L"_process_info_test_child.exe")
.value();
std::wstring args;
AppendCommandLineArgument(done_uuid.ToString16(), &args);
ChildLauncher child(child_test_executable, args);
child.Start();
// The child sends us a code address we can look up in the memory map.
WinVMAddress code_address;
CheckedReadFileExactly(
child.stdout_read_handle(), &code_address, sizeof(code_address));
ASSERT_TRUE(process_info.Initialize(child.process_handle()));
// Tell the test it's OK to shut down now that we've read our data.
EXPECT_TRUE(SetEvent(done.get())) << ErrorMessage("SetEvent");
EXPECT_EQ(child.WaitForExit(), 0);
std::vector<ProcessInfo::Module> modules;
EXPECT_TRUE(process_info.Modules(&modules));
ASSERT_GE(modules.size(), 3u);
std::wstring child_name = L"\\crashpad_util_test_process_info_test_child.exe";
ASSERT_GE(modules[0].name.size(), child_name.size());
EXPECT_EQ(modules[0].name.substr(modules[0].name.size() - child_name.size()),
child_name);
ASSERT_GE(modules[1].name.size(), wcslen(kNtdllName));
EXPECT_EQ(modules[1].name.substr(modules[1].name.size() - wcslen(kNtdllName)),
kNtdllName);
// lz32.dll is an uncommonly-used-but-always-available module that the test
// binary manually loads.
const wchar_t kLz32dllName[] = L"\\lz32.dll";
ASSERT_GE(modules.back().name.size(), wcslen(kLz32dllName));
EXPECT_EQ(modules.back().name.substr(modules.back().name.size() -
wcslen(kLz32dllName)),
kLz32dllName);
VerifyAddressInInCodePage(process_info, code_address);
}
TEST(ProcessInfo, OtherProcess) {
TestOtherProcess(FILE_PATH_LITERAL("."));
}
#if defined(ARCH_CPU_64_BITS)
TEST(ProcessInfo, OtherProcessWOW64) {
#ifndef NDEBUG
TestOtherProcess(FILE_PATH_LITERAL("..\\..\\out\\Debug"));
#else
TestOtherProcess(FILE_PATH_LITERAL("..\\..\\out\\Release"));
#endif
}
#endif // ARCH_CPU_64_BITS
TEST(ProcessInfo, AccessibleRangesNone) {
ProcessInfo::MemoryBasicInformation64Vector memory_info;
MEMORY_BASIC_INFORMATION64 mbi = {0};
mbi.BaseAddress = 0;
mbi.RegionSize = 10;
mbi.State = MEM_FREE;
memory_info.push_back(mbi);
std::vector<CheckedRange<WinVMAddress, WinVMSize>> result =
GetReadableRangesOfMemoryMap(CheckedRange<WinVMAddress, WinVMSize>(2, 4),
memory_info);
EXPECT_TRUE(result.empty());
}
TEST(ProcessInfo, AccessibleRangesOneInside) {
ProcessInfo::MemoryBasicInformation64Vector memory_info;
MEMORY_BASIC_INFORMATION64 mbi = {0};
mbi.BaseAddress = 0;
mbi.RegionSize = 10;
mbi.State = MEM_COMMIT;
memory_info.push_back(mbi);
std::vector<CheckedRange<WinVMAddress, WinVMSize>> result =
GetReadableRangesOfMemoryMap(CheckedRange<WinVMAddress, WinVMSize>(2, 4),
memory_info);
ASSERT_EQ(result.size(), 1u);
EXPECT_EQ(result[0].base(), 2);
EXPECT_EQ(result[0].size(), 4);
}
TEST(ProcessInfo, AccessibleRangesOneTruncatedSize) {
ProcessInfo::MemoryBasicInformation64Vector memory_info;
MEMORY_BASIC_INFORMATION64 mbi = {0};
mbi.BaseAddress = 0;
mbi.RegionSize = 10;
mbi.State = MEM_COMMIT;
memory_info.push_back(mbi);
mbi.BaseAddress = 10;
mbi.RegionSize = 20;
mbi.State = MEM_FREE;
memory_info.push_back(mbi);
std::vector<CheckedRange<WinVMAddress, WinVMSize>> result =
GetReadableRangesOfMemoryMap(CheckedRange<WinVMAddress, WinVMSize>(5, 10),
memory_info);
ASSERT_EQ(result.size(), 1u);
EXPECT_EQ(result[0].base(), 5);
EXPECT_EQ(result[0].size(), 5);
}
TEST(ProcessInfo, AccessibleRangesOneMovedStart) {
ProcessInfo::MemoryBasicInformation64Vector memory_info;
MEMORY_BASIC_INFORMATION64 mbi = {0};
mbi.BaseAddress = 0;
mbi.RegionSize = 10;
mbi.State = MEM_FREE;
memory_info.push_back(mbi);
mbi.BaseAddress = 10;
mbi.RegionSize = 20;
mbi.State = MEM_COMMIT;
memory_info.push_back(mbi);
std::vector<CheckedRange<WinVMAddress, WinVMSize>> result =
GetReadableRangesOfMemoryMap(CheckedRange<WinVMAddress, WinVMSize>(5, 10),
memory_info);
ASSERT_EQ(result.size(), 1u);
EXPECT_EQ(result[0].base(), 10);
EXPECT_EQ(result[0].size(), 5);
}
TEST(ProcessInfo, ReserveIsInaccessible) {
ProcessInfo::MemoryBasicInformation64Vector memory_info;
MEMORY_BASIC_INFORMATION64 mbi = {0};
mbi.BaseAddress = 0;
mbi.RegionSize = 10;
mbi.State = MEM_RESERVE;
memory_info.push_back(mbi);
mbi.BaseAddress = 10;
mbi.RegionSize = 20;
mbi.State = MEM_COMMIT;
memory_info.push_back(mbi);
std::vector<CheckedRange<WinVMAddress, WinVMSize>> result =
GetReadableRangesOfMemoryMap(CheckedRange<WinVMAddress, WinVMSize>(5, 10),
memory_info);
ASSERT_EQ(result.size(), 1u);
EXPECT_EQ(result[0].base(), 10);
EXPECT_EQ(result[0].size(), 5);
}
TEST(ProcessInfo, PageGuardIsInaccessible) {
ProcessInfo::MemoryBasicInformation64Vector memory_info;
MEMORY_BASIC_INFORMATION64 mbi = {0};
mbi.BaseAddress = 0;
mbi.RegionSize = 10;
mbi.State = MEM_COMMIT;
mbi.Protect = PAGE_GUARD;
memory_info.push_back(mbi);
mbi.BaseAddress = 10;
mbi.RegionSize = 20;
mbi.State = MEM_COMMIT;
mbi.Protect = 0;
memory_info.push_back(mbi);
std::vector<CheckedRange<WinVMAddress, WinVMSize>> result =
GetReadableRangesOfMemoryMap(CheckedRange<WinVMAddress, WinVMSize>(5, 10),
memory_info);
ASSERT_EQ(result.size(), 1u);
EXPECT_EQ(result[0].base(), 10);
EXPECT_EQ(result[0].size(), 5);
}
TEST(ProcessInfo, PageNoAccessIsInaccessible) {
ProcessInfo::MemoryBasicInformation64Vector memory_info;
MEMORY_BASIC_INFORMATION64 mbi = {0};
mbi.BaseAddress = 0;
mbi.RegionSize = 10;
mbi.State = MEM_COMMIT;
mbi.Protect = PAGE_NOACCESS;
memory_info.push_back(mbi);
mbi.BaseAddress = 10;
mbi.RegionSize = 20;
mbi.State = MEM_COMMIT;
mbi.Protect = 0;
memory_info.push_back(mbi);
std::vector<CheckedRange<WinVMAddress, WinVMSize>> result =
GetReadableRangesOfMemoryMap(CheckedRange<WinVMAddress, WinVMSize>(5, 10),
memory_info);
ASSERT_EQ(result.size(), 1u);
EXPECT_EQ(result[0].base(), 10);
EXPECT_EQ(result[0].size(), 5);
}
TEST(ProcessInfo, AccessibleRangesCoalesced) {
ProcessInfo::MemoryBasicInformation64Vector memory_info;
MEMORY_BASIC_INFORMATION64 mbi = {0};
mbi.BaseAddress = 0;
mbi.RegionSize = 10;
mbi.State = MEM_FREE;
memory_info.push_back(mbi);
mbi.BaseAddress = 10;
mbi.RegionSize = 2;
mbi.State = MEM_COMMIT;
memory_info.push_back(mbi);
mbi.BaseAddress = 12;
mbi.RegionSize = 5;
mbi.State = MEM_COMMIT;
memory_info.push_back(mbi);
std::vector<CheckedRange<WinVMAddress, WinVMSize>> result =
GetReadableRangesOfMemoryMap(CheckedRange<WinVMAddress, WinVMSize>(11, 4),
memory_info);
ASSERT_EQ(result.size(), 1u);
EXPECT_EQ(result[0].base(), 11);
EXPECT_EQ(result[0].size(), 4);
}
TEST(ProcessInfo, AccessibleRangesMiddleUnavailable) {
ProcessInfo::MemoryBasicInformation64Vector memory_info;
MEMORY_BASIC_INFORMATION64 mbi = {0};
mbi.BaseAddress = 0;
mbi.RegionSize = 10;
mbi.State = MEM_COMMIT;
memory_info.push_back(mbi);
mbi.BaseAddress = 10;
mbi.RegionSize = 5;
mbi.State = MEM_FREE;
memory_info.push_back(mbi);
mbi.BaseAddress = 15;
mbi.RegionSize = 100;
mbi.State = MEM_COMMIT;
memory_info.push_back(mbi);
std::vector<CheckedRange<WinVMAddress, WinVMSize>> result =
GetReadableRangesOfMemoryMap(CheckedRange<WinVMAddress, WinVMSize>(5, 45),
memory_info);
ASSERT_EQ(result.size(), 2u);
EXPECT_EQ(result[0].base(), 5);
EXPECT_EQ(result[0].size(), 5);
EXPECT_EQ(result[1].base(), 15);
EXPECT_EQ(result[1].size(), 35);
}
TEST(ProcessInfo, RequestedBeforeMap) {
ProcessInfo::MemoryBasicInformation64Vector memory_info;
MEMORY_BASIC_INFORMATION64 mbi = {0};
mbi.BaseAddress = 10;
mbi.RegionSize = 10;
mbi.State = MEM_COMMIT;
memory_info.push_back(mbi);
std::vector<CheckedRange<WinVMAddress, WinVMSize>> result =
GetReadableRangesOfMemoryMap(CheckedRange<WinVMAddress, WinVMSize>(5, 10),
memory_info);
ASSERT_EQ(result.size(), 1u);
EXPECT_EQ(result[0].base(), 10);
EXPECT_EQ(result[0].size(), 5);
}
TEST(ProcessInfo, RequestedAfterMap) {
ProcessInfo::MemoryBasicInformation64Vector memory_info;
MEMORY_BASIC_INFORMATION64 mbi = {0};
mbi.BaseAddress = 10;
mbi.RegionSize = 10;
mbi.State = MEM_COMMIT;
memory_info.push_back(mbi);
std::vector<CheckedRange<WinVMAddress, WinVMSize>> result =
GetReadableRangesOfMemoryMap(
CheckedRange<WinVMAddress, WinVMSize>(15, 100), memory_info);
ASSERT_EQ(result.size(), 1u);
EXPECT_EQ(result[0].base(), 15);
EXPECT_EQ(result[0].size(), 5);
}
TEST(ProcessInfo, ReadableRanges) {
SYSTEM_INFO system_info;
GetSystemInfo(&system_info);
const size_t kBlockSize = system_info.dwPageSize;
// Allocate 6 pages, and then commit the second, fourth, and fifth, and mark
// two as committed, but PAGE_NOACCESS, so we have a setup like this:
// 0 1 2 3 4 5
// +-----------------------------------------------+
// | ????? | | xxxxx | | | ????? |
// +-----------------------------------------------+
void* reserve_region =
VirtualAlloc(nullptr, kBlockSize * 6, MEM_RESERVE, PAGE_READWRITE);
ASSERT_TRUE(reserve_region);
uintptr_t reserved_as_int = reinterpret_cast<uintptr_t>(reserve_region);
void* readable1 =
VirtualAlloc(reinterpret_cast<void*>(reserved_as_int + kBlockSize),
kBlockSize,
MEM_COMMIT,
PAGE_READWRITE);
ASSERT_TRUE(readable1);
void* readable2 =
VirtualAlloc(reinterpret_cast<void*>(reserved_as_int + (kBlockSize * 3)),
kBlockSize * 2,
MEM_COMMIT,
PAGE_READWRITE);
ASSERT_TRUE(readable2);
void* no_access =
VirtualAlloc(reinterpret_cast<void*>(reserved_as_int + (kBlockSize * 2)),
kBlockSize,
MEM_COMMIT,
PAGE_NOACCESS);
ASSERT_TRUE(no_access);
HANDLE current_process = GetCurrentProcess();
ProcessInfo info;
info.Initialize(current_process);
auto ranges = info.GetReadableRanges(
CheckedRange<WinVMAddress, WinVMSize>(reserved_as_int, kBlockSize * 6));
ASSERT_EQ(ranges.size(), 2u);
EXPECT_EQ(ranges[0].base(), reserved_as_int + kBlockSize);
EXPECT_EQ(ranges[0].size(), kBlockSize);
EXPECT_EQ(ranges[1].base(), reserved_as_int + (kBlockSize * 3));
EXPECT_EQ(ranges[1].size(), kBlockSize * 2);
// Also make sure what we think we can read corresponds with what we can
// actually read.
std::unique_ptr<unsigned char[]> into(new unsigned char[kBlockSize * 6]);
SIZE_T bytes_read;
EXPECT_TRUE(ReadProcessMemory(
current_process, readable1, into.get(), kBlockSize, &bytes_read));
EXPECT_EQ(bytes_read, kBlockSize);
EXPECT_TRUE(ReadProcessMemory(
current_process, readable2, into.get(), kBlockSize * 2, &bytes_read));
EXPECT_EQ(bytes_read, kBlockSize * 2);
EXPECT_FALSE(ReadProcessMemory(
current_process, no_access, into.get(), kBlockSize, &bytes_read));
EXPECT_FALSE(ReadProcessMemory(
current_process, reserve_region, into.get(), kBlockSize, &bytes_read));
EXPECT_FALSE(ReadProcessMemory(current_process,
reserve_region,
into.get(),
kBlockSize * 6,
&bytes_read));
}
struct ScopedRegistryKeyCloseTraits {
static HKEY InvalidValue() {
return nullptr;
}
static void Free(HKEY key) {
RegCloseKey(key);
}
};
using ScopedRegistryKey =
base::ScopedGeneric<HKEY, ScopedRegistryKeyCloseTraits>;
TEST(ProcessInfo, Handles) {
ScopedTempDir temp_dir;
ScopedFileHandle file(LoggingOpenFileForWrite(
temp_dir.path().Append(FILE_PATH_LITERAL("test_file")),
FileWriteMode::kTruncateOrCreate,
FilePermissions::kWorldReadable));
ASSERT_TRUE(file.is_valid());
SECURITY_ATTRIBUTES security_attributes = {0};
security_attributes.nLength = sizeof(security_attributes);
security_attributes.bInheritHandle = true;
ScopedFileHandle inherited_file(CreateFile(
temp_dir.path().Append(FILE_PATH_LITERAL("inheritable")).value().c_str(),
GENERIC_WRITE,
0,
&security_attributes,
CREATE_NEW,
FILE_ATTRIBUTE_NORMAL,
nullptr));
ASSERT_TRUE(inherited_file.is_valid());
HKEY key;
ASSERT_EQ(RegOpenKeyEx(
HKEY_CURRENT_USER, L"SOFTWARE\\Microsoft", 0, KEY_READ, &key),
ERROR_SUCCESS);
ScopedRegistryKey scoped_key(key);
ASSERT_TRUE(scoped_key.is_valid());
std::wstring mapping_name =
base::UTF8ToUTF16(base::StringPrintf("Local\\test_mapping_%d_%s",
GetCurrentProcessId(),
RandomString().c_str()));
ScopedKernelHANDLE mapping(CreateFileMapping(INVALID_HANDLE_VALUE,
nullptr,
PAGE_READWRITE,
0,
1024,
mapping_name.c_str()));
ASSERT_TRUE(mapping.is_valid()) << ErrorMessage("CreateFileMapping");
ProcessInfo info;
info.Initialize(GetCurrentProcess());
bool found_file_handle = false;
bool found_inherited_file_handle = false;
bool found_key_handle = false;
bool found_mapping_handle = false;
for (auto handle : info.Handles()) {
if (handle.handle == HandleToInt(file.get())) {
EXPECT_FALSE(found_file_handle);
found_file_handle = true;
EXPECT_EQ(handle.type_name, L"File");
EXPECT_EQ(handle.handle_count, 1);
EXPECT_NE(handle.pointer_count, 0u);
EXPECT_EQ(handle.granted_access & STANDARD_RIGHTS_ALL,
STANDARD_RIGHTS_READ | STANDARD_RIGHTS_WRITE | SYNCHRONIZE);
EXPECT_EQ(handle.attributes, 0);
}
if (handle.handle == HandleToInt(inherited_file.get())) {
EXPECT_FALSE(found_inherited_file_handle);
found_inherited_file_handle = true;
EXPECT_EQ(handle.type_name, L"File");
EXPECT_EQ(handle.handle_count, 1);
EXPECT_NE(handle.pointer_count, 0u);
EXPECT_EQ(handle.granted_access & STANDARD_RIGHTS_ALL,
STANDARD_RIGHTS_READ | STANDARD_RIGHTS_WRITE | SYNCHRONIZE);
// OBJ_INHERIT from ntdef.h, but including that conflicts with other
// headers.
const int kObjInherit = 0x2;
EXPECT_EQ(handle.attributes, kObjInherit);
}
if (handle.handle == HandleToInt(scoped_key.get())) {
EXPECT_FALSE(found_key_handle);
found_key_handle = true;
EXPECT_EQ(handle.type_name, L"Key");
EXPECT_EQ(handle.handle_count, 1);
EXPECT_NE(handle.pointer_count, 0u);
EXPECT_EQ(handle.granted_access & STANDARD_RIGHTS_ALL,
STANDARD_RIGHTS_READ);
EXPECT_EQ(handle.attributes, 0);
}
if (handle.handle == HandleToInt(mapping.get())) {
EXPECT_FALSE(found_mapping_handle);
found_mapping_handle = true;
EXPECT_EQ(handle.type_name, L"Section");
EXPECT_EQ(handle.handle_count, 1);
EXPECT_NE(handle.pointer_count, 0u);
EXPECT_EQ(handle.granted_access & STANDARD_RIGHTS_ALL,
DELETE | READ_CONTROL | WRITE_DAC | WRITE_OWNER |
STANDARD_RIGHTS_READ | STANDARD_RIGHTS_WRITE);
EXPECT_EQ(handle.attributes, 0);
}
}
EXPECT_TRUE(found_file_handle);
EXPECT_TRUE(found_inherited_file_handle);
EXPECT_TRUE(found_key_handle);
EXPECT_TRUE(found_mapping_handle);
}
TEST(ProcessInfo, OutOfRangeCheck) {
const size_t kAllocationSize = 12345;
std::unique_ptr<char[]> safe_memory(new char[kAllocationSize]);
ProcessInfo info;
info.Initialize(GetCurrentProcess());
EXPECT_TRUE(
info.LoggingRangeIsFullyReadable(CheckedRange<WinVMAddress, WinVMSize>(
reinterpret_cast<WinVMAddress>(safe_memory.get()), kAllocationSize)));
EXPECT_FALSE(info.LoggingRangeIsFullyReadable(
CheckedRange<WinVMAddress, WinVMSize>(0, 1024)));
}
} // namespace
} // namespace test
} // namespace crashpad
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