sandbox/win/src/win_utils.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.

 #include "sandbox/win/src/win_utils.h"

 #include <psapi.h>
 #include <stddef.h>
 #include <stdint.h>

 #include <map>
 #include <memory>
 #include <vector>

 #include "base/numerics/safe_math.h"
 #include "base/stl_util.h"
 #include "base/strings/string16.h"
 #include "base/strings/string_util.h"
 #include "base/win/pe_image.h"
 #include "sandbox/win/src/internal_types.h"
 #include "sandbox/win/src/nt_internals.h"
 #include "sandbox/win/src/sandbox_nt_util.h"

 namespace {

 const size_t kDriveLetterLen = 3;

 constexpr wchar_t kNTDotPrefix[] = L"\\\\.\\";
 const size_t kNTDotPrefixLen = base::size(kNTDotPrefix) - 1;

 // Holds the information about a known registry key.
 struct KnownReservedKey {
   const wchar_t* name;
   HKEY key;
 };

 // Contains all the known registry key by name and by handle.
 const KnownReservedKey kKnownKey[] = {
     {L"HKEY_CLASSES_ROOT", HKEY_CLASSES_ROOT},
     {L"HKEY_CURRENT_USER", HKEY_CURRENT_USER},
     {L"HKEY_LOCAL_MACHINE", HKEY_LOCAL_MACHINE},
     {L"HKEY_USERS", HKEY_USERS},
     {L"HKEY_PERFORMANCE_DATA", HKEY_PERFORMANCE_DATA},
     {L"HKEY_PERFORMANCE_TEXT", HKEY_PERFORMANCE_TEXT},
     {L"HKEY_PERFORMANCE_NLSTEXT", HKEY_PERFORMANCE_NLSTEXT},
     {L"HKEY_CURRENT_CONFIG", HKEY_CURRENT_CONFIG},
     {L"HKEY_DYN_DATA", HKEY_DYN_DATA}};

 // These functions perform case independent path comparisons.
 bool EqualPath(const base::string16& first, const base::string16& second) {
   return _wcsicmp(first.c_str(), second.c_str()) == 0;
 }

 bool EqualPath(const base::string16& first,
                size_t first_offset,
                const base::string16& second,
                size_t second_offset) {
   return _wcsicmp(first.c_str() + first_offset,
                   second.c_str() + second_offset) == 0;
 }

 bool EqualPath(const base::string16& first,
                const wchar_t* second,
                size_t second_len) {
   return _wcsnicmp(first.c_str(), second, second_len) == 0;
 }

 bool EqualPath(const base::string16& first,
                size_t first_offset,
                const wchar_t* second,
                size_t second_len) {
   return _wcsnicmp(first.c_str() + first_offset, second, second_len) == 0;
 }

 // Returns true if |path| starts with "\??\" and returns a path without that
 // component.
 bool IsNTPath(const base::string16& path, base::string16* trimmed_path) {
   if ((path.size() < sandbox::kNTPrefixLen) ||
       !EqualPath(path, sandbox::kNTPrefix, sandbox::kNTPrefixLen)) {
     *trimmed_path = path;
     return false;
   }

   *trimmed_path = path.substr(sandbox::kNTPrefixLen);
   return true;
 }

 // Returns true if |path| starts with "\Device\" and returns a path without that
 // component.
 bool IsDevicePath(const base::string16& path, base::string16* trimmed_path) {
   if ((path.size() < sandbox::kNTDevicePrefixLen) ||
       (!EqualPath(path, sandbox::kNTDevicePrefix,
                   sandbox::kNTDevicePrefixLen))) {
     *trimmed_path = path;
     return false;
   }

   *trimmed_path = path.substr(sandbox::kNTDevicePrefixLen);
   return true;
 }

 // Returns the offset to the path seperator following
 // "\Device\HarddiskVolumeX" in |path|.
 size_t PassHarddiskVolume(const base::string16& path) {
   static constexpr wchar_t pattern[] = L"\\Device\\HarddiskVolume";
   const size_t patternLen = base::size(pattern) - 1;

   // First, check for |pattern|.
   if ((path.size() < patternLen) || (!EqualPath(path, pattern, patternLen)))
     return base::string16::npos;

   // Find the next path separator, after the pattern match.
   return path.find_first_of(L'\\', patternLen - 1);
 }

 // Returns true if |path| starts with "\Device\HarddiskVolumeX\" and returns a
 // path without that component.  |removed| will hold the prefix removed.
 bool IsDeviceHarddiskPath(const base::string16& path,
                           base::string16* trimmed_path,
                           base::string16* removed) {
   size_t offset = PassHarddiskVolume(path);
   if (offset == base::string16::npos)
     return false;

   // Remove up to and including the path separator.
   *removed = path.substr(0, offset + 1);
   // Remaining path starts after the path separator.
   *trimmed_path = path.substr(offset + 1);
   return true;
 }

 bool StartsWithDriveLetter(const base::string16& path) {
   if (path.size() < kDriveLetterLen)
     return false;

   if (path[1] != L':' || path[2] != L'\\')
     return false;

   return base::IsAsciiAlpha(path[0]);
 }

 // Removes "\\\\.\\" from the path.
 void RemoveImpliedDevice(base::string16* path) {
   if (EqualPath(*path, kNTDotPrefix, kNTDotPrefixLen))
     *path = path->substr(kNTDotPrefixLen);
 }

 }  // namespace

 namespace sandbox {

 // Returns true if the provided path points to a pipe.
 bool IsPipe(const base::string16& path) {
   size_t start = 0;
   if (EqualPath(path, sandbox::kNTPrefix, sandbox::kNTPrefixLen))
     start = sandbox::kNTPrefixLen;

   const wchar_t kPipe[] = L"pipe\\";
   if (path.size() < start + base::size(kPipe) - 1)
     return false;

   return EqualPath(path, start, kPipe, base::size(kPipe) - 1);
 }

 HKEY GetReservedKeyFromName(const base::string16& name) {
   for (size_t i = 0; i < base::size(kKnownKey); ++i) {
     if (name == kKnownKey[i].name)
       return kKnownKey[i].key;
   }

   return nullptr;
 }

 bool ResolveRegistryName(base::string16 name, base::string16* resolved_name) {
   for (size_t i = 0; i < base::size(kKnownKey); ++i) {
     if (name.find(kKnownKey[i].name) == 0) {
       HKEY key;
       DWORD disposition;
       if (ERROR_SUCCESS != ::RegCreateKeyEx(kKnownKey[i].key, L"", 0, nullptr,
                                             0, MAXIMUM_ALLOWED, nullptr, &key,
                                             &disposition))
         return false;

       bool result = GetPathFromHandle(key, resolved_name);
       ::RegCloseKey(key);

       if (!result)
         return false;

       *resolved_name += name.substr(wcslen(kKnownKey[i].name));
       return true;
     }
   }

   return false;
 }

 // |full_path| can have any of the following forms:
 //    \??\c:\some\foo\bar
 //    \Device\HarddiskVolume0\some\foo\bar
 //    \??\HarddiskVolume0\some\foo\bar
 DWORD IsReparsePoint(const base::string16& full_path) {
   // Check if it's a pipe. We can't query the attributes of a pipe.
   if (IsPipe(full_path))
     return ERROR_NOT_A_REPARSE_POINT;

   base::string16 path;
   bool nt_path = IsNTPath(full_path, &path);
   bool has_drive = StartsWithDriveLetter(path);
   bool is_device_path = IsDevicePath(path, &path);

   if (!has_drive && !is_device_path && !nt_path)
     return ERROR_INVALID_NAME;

   bool added_implied_device = false;
   if (!has_drive) {
     path = base::string16(kNTDotPrefix) + path;
     added_implied_device = true;
   }

   base::string16::size_type last_pos = base::string16::npos;
   bool passed_once = false;

   do {
     path = path.substr(0, last_pos);

     DWORD attributes = ::GetFileAttributes(path.c_str());
     if (INVALID_FILE_ATTRIBUTES == attributes) {
       DWORD error = ::GetLastError();
       if (error != ERROR_FILE_NOT_FOUND && error != ERROR_PATH_NOT_FOUND &&
           error != ERROR_INVALID_NAME) {
         // Unexpected error.
         if (passed_once && added_implied_device &&
             (path.rfind(L'\\') == kNTDotPrefixLen - 1)) {
           break;
         }
         NOTREACHED_NT();
         return error;
       }
     } else if (FILE_ATTRIBUTE_REPARSE_POINT & attributes) {
       // This is a reparse point.
       return ERROR_SUCCESS;
     }

     passed_once = true;
     last_pos = path.rfind(L'\\');
   } while (last_pos > 2);  // Skip root dir.

   return ERROR_NOT_A_REPARSE_POINT;
 }

 // We get a |full_path| of the forms accepted by IsReparsePoint(), and the name
 // we'll get from |handle| will be \device\harddiskvolume1\some\foo\bar.
 bool SameObject(HANDLE handle, const wchar_t* full_path) {
   // Check if it's a pipe.
   if (IsPipe(full_path))
     return true;

   base::string16 actual_path;
   if (!GetPathFromHandle(handle, &actual_path))
     return false;

   base::string16 path(full_path);
   DCHECK_NT(!path.empty());

   // This may end with a backslash.
   const wchar_t kBackslash = '\\';
   if (path.back() == kBackslash)
     path = path.substr(0, path.length() - 1);

   // Perfect match (case-insesitive check).
   if (EqualPath(actual_path, path))
     return true;

   bool nt_path = IsNTPath(path, &path);
   bool has_drive = StartsWithDriveLetter(path);

   if (!has_drive && nt_path) {
     base::string16 simple_actual_path;
     if (!IsDevicePath(actual_path, &simple_actual_path))
       return false;

     // Perfect match (case-insesitive check).
     return (EqualPath(simple_actual_path, path));
   }

   if (!has_drive)
     return false;

   // We only need 3 chars, but let's alloc a buffer for four.
   wchar_t drive[4] = {0};
   wchar_t vol_name[MAX_PATH];
   memcpy(drive, &path[0], 2 * sizeof(*drive));

   // We'll get a double null terminated string.
   DWORD vol_length = ::QueryDosDeviceW(drive, vol_name, MAX_PATH);
   if (vol_length < 2 || vol_length == MAX_PATH)
     return false;

   // Ignore the nulls at the end.
   vol_length = static_cast<DWORD>(wcslen(vol_name));

   // The two paths should be the same length.
   if (vol_length + path.size() - 2 != actual_path.size())
     return false;

   // Check up to the drive letter.
   if (!EqualPath(actual_path, vol_name, vol_length))
     return false;

   // Check the path after the drive letter.
   if (!EqualPath(actual_path, vol_length, path, 2))
     return false;

   return true;
 }

 // Just make a best effort here.  There are lots of corner cases that we're
 // not expecting - and will fail to make long.
 bool ConvertToLongPath(base::string16* native_path,
                        const base::string16* drive_letter) {
   if (IsPipe(*native_path))
     return true;

   bool is_device_harddisk_path = false;
   bool is_nt_path = false;
   bool added_implied_device = false;
   base::string16 temp_path;
   base::string16 to_restore;

   // Process a few prefix types.
   if (IsNTPath(*native_path, &temp_path)) {
     // "\??\"
     if (!StartsWithDriveLetter(temp_path)) {
       // Prepend with "\\.\".
       temp_path = base::string16(kNTDotPrefix) + temp_path;
       added_implied_device = true;
     }
     is_nt_path = true;
   } else if (IsDeviceHarddiskPath(*native_path, &temp_path, &to_restore)) {
     // "\Device\HarddiskVolumeX\" - hacky attempt making ::GetLongPathName
     // work for native device paths.  Remove "\Device\HarddiskVolumeX\" and
     // replace with drive letter.

     // Nothing we can do if we don't have a drive letter.  Leave |native_path|
     // as is.
     if (!drive_letter || drive_letter->empty())
       return false;
     temp_path = *drive_letter + temp_path;
     is_device_harddisk_path = true;
   } else if (IsDevicePath(*native_path, &temp_path)) {
     // "\Device\" - there's nothing we can do to convert to long here.
     return false;
   }

   DWORD size = MAX_PATH;
   std::unique_ptr<wchar_t[]> long_path_buf(new wchar_t[size]);

   DWORD return_value =
       ::GetLongPathName(temp_path.c_str(), long_path_buf.get(), size);
   while (return_value >= size) {
     size *= 2;
     long_path_buf.reset(new wchar_t[size]);
     return_value =
         ::GetLongPathName(temp_path.c_str(), long_path_buf.get(), size);
   }

   DWORD last_error = ::GetLastError();
   if (0 == return_value && (ERROR_FILE_NOT_FOUND == last_error ||
                             ERROR_PATH_NOT_FOUND == last_error ||
                             ERROR_INVALID_NAME == last_error)) {
     // The file does not exist, but maybe a sub path needs to be expanded.
     base::string16::size_type last_slash = temp_path.rfind(L'\\');
     if (base::string16::npos == last_slash)
       return false;

     base::string16 begin = temp_path.substr(0, last_slash);
     base::string16 end = temp_path.substr(last_slash);
     if (!ConvertToLongPath(&begin))
       return false;

     // Ok, it worked. Let's reset the return value.
     temp_path = begin + end;
     return_value = 1;
   } else if (0 != return_value) {
     temp_path = long_path_buf.get();
   }

   // If successful, re-apply original namespace prefix before returning.
   if (return_value != 0) {
     if (added_implied_device)
       RemoveImpliedDevice(&temp_path);

     if (is_nt_path) {
       *native_path = kNTPrefix;
       *native_path += temp_path;
     } else if (is_device_harddisk_path) {
       // Remove the added drive letter.
       temp_path = temp_path.substr(kDriveLetterLen);
       *native_path = to_restore;
       *native_path += temp_path;
     } else {
       *native_path = temp_path;
     }

     return true;
   }

   return false;
 }

 bool GetPathFromHandle(HANDLE handle, base::string16* path) {
   NtQueryObjectFunction NtQueryObject = nullptr;
   ResolveNTFunctionPtr("NtQueryObject", &NtQueryObject);

   OBJECT_NAME_INFORMATION initial_buffer;
   OBJECT_NAME_INFORMATION* name = &initial_buffer;
   ULONG size = sizeof(initial_buffer);
   // Query the name information a first time to get the size of the name.
   // Windows XP requires that the size of the buffer passed in here be != 0.
   NTSTATUS status =
       NtQueryObject(handle, ObjectNameInformation, name, size, &size);

   std::unique_ptr<BYTE[]> name_ptr;
   if (size) {
     name_ptr.reset(new BYTE[size]);
     name = reinterpret_cast<OBJECT_NAME_INFORMATION*>(name_ptr.get());

     // Query the name information a second time to get the name of the
     // object referenced by the handle.
     status = NtQueryObject(handle, ObjectNameInformation, name, size, &size);
   }

   if (STATUS_SUCCESS != status)
     return false;

   path->assign(name->ObjectName.Buffer,
                name->ObjectName.Length / sizeof(name->ObjectName.Buffer[0]));
   return true;
 }

 bool GetNtPathFromWin32Path(const base::string16& path,
                             base::string16* nt_path) {
   HANDLE file = ::CreateFileW(
       path.c_str(), 0, FILE_SHARE_READ | FILE_SHARE_WRITE | FILE_SHARE_DELETE,
       nullptr, OPEN_EXISTING, FILE_FLAG_BACKUP_SEMANTICS, nullptr);
   if (file == INVALID_HANDLE_VALUE)
     return false;
   bool rv = GetPathFromHandle(file, nt_path);
   ::CloseHandle(file);
   return rv;
 }

 bool WriteProtectedChildMemory(HANDLE child_process,
                                void* address,
                                const void* buffer,
                                size_t length) {
   // First, remove the protections.
   DWORD old_protection;
   if (!::VirtualProtectEx(child_process, address, length, PAGE_WRITECOPY,
                           &old_protection))
     return false;

   SIZE_T written;
   bool ok =
       ::WriteProcessMemory(child_process, address, buffer, length, &written) &&
       (length == written);

   // Always attempt to restore the original protection.
   if (!::VirtualProtectEx(child_process, address, length, old_protection,
                           &old_protection))
     return false;

   return ok;
 }

 DWORD GetLastErrorFromNtStatus(NTSTATUS status) {
   RtlNtStatusToDosErrorFunction NtStatusToDosError = nullptr;
   ResolveNTFunctionPtr("RtlNtStatusToDosError", &NtStatusToDosError);
   return NtStatusToDosError(status);
 }

 // This function uses the undocumented PEB ImageBaseAddress field to extract
 // the base address of the new process.
 void* GetProcessBaseAddress(HANDLE process) {
   NtQueryInformationProcessFunction query_information_process = nullptr;
   ResolveNTFunctionPtr("NtQueryInformationProcess", &query_information_process);
   if (!query_information_process)
     return nullptr;
   PROCESS_BASIC_INFORMATION process_basic_info = {};
   NTSTATUS status = query_information_process(
       process, ProcessBasicInformation, &process_basic_info,
       sizeof(process_basic_info), nullptr);
   if (STATUS_SUCCESS != status)
     return nullptr;

   PEB peb = {};
   SIZE_T bytes_read = 0;
   if (!::ReadProcessMemory(process, process_basic_info.PebBaseAddress, &peb,
                            sizeof(peb), &bytes_read) ||
       (sizeof(peb) != bytes_read)) {
     return nullptr;
   }

   void* base_address = peb.ImageBaseAddress;
   char magic[2] = {};
   if (!::ReadProcessMemory(process, base_address, magic, sizeof(magic),
                            &bytes_read) ||
       (sizeof(magic) != bytes_read)) {
     return nullptr;
   }

   if (magic[0] != 'M' || magic[1] != 'Z')
     return nullptr;

   return base_address;
 }

 }  // namespace sandbox

 void ResolveNTFunctionPtr(const char* name, void* ptr) {
   static volatile HMODULE ntdll = nullptr;

   if (!ntdll) {
     HMODULE ntdll_local = ::GetModuleHandle(sandbox::kNtdllName);
     // Use PEImage to sanity-check that we have a valid ntdll handle.
     base::win::PEImage ntdll_peimage(ntdll_local);
     CHECK_NT(ntdll_peimage.VerifyMagic());
     // Race-safe way to set static ntdll.
     ::InterlockedCompareExchangePointer(
         reinterpret_cast<PVOID volatile*>(&ntdll), ntdll_local, nullptr);
   }

   CHECK_NT(ntdll);
   FARPROC* function_ptr = reinterpret_cast<FARPROC*>(ptr);
   *function_ptr = ::GetProcAddress(ntdll, name);
   CHECK_NT(*function_ptr);
 }
	// 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.

	#include "sandbox/win/src/win_utils.h"

	#include <psapi.h>
	#include <stddef.h>
	#include <stdint.h>

	#include <map>
	#include <memory>
	#include <vector>

	#include "base/numerics/safe_math.h"
	#include "base/stl_util.h"
	#include "base/strings/string16.h"
	#include "base/strings/string_util.h"
	#include "base/win/pe_image.h"
	#include "sandbox/win/src/internal_types.h"
	#include "sandbox/win/src/nt_internals.h"
	#include "sandbox/win/src/sandbox_nt_util.h"

	namespace {

	const size_t kDriveLetterLen = 3;

	constexpr wchar_t kNTDotPrefix[] = L"\\\\.\\";
	const size_t kNTDotPrefixLen = base::size(kNTDotPrefix) - 1;

	// Holds the information about a known registry key.
	struct KnownReservedKey {
	const wchar_t* name;
	HKEY key;
	};

	// Contains all the known registry key by name and by handle.
	const KnownReservedKey kKnownKey[] = {
	{L"HKEY_CLASSES_ROOT", HKEY_CLASSES_ROOT},
	{L"HKEY_CURRENT_USER", HKEY_CURRENT_USER},
	{L"HKEY_LOCAL_MACHINE", HKEY_LOCAL_MACHINE},
	{L"HKEY_USERS", HKEY_USERS},
	{L"HKEY_PERFORMANCE_DATA", HKEY_PERFORMANCE_DATA},
	{L"HKEY_PERFORMANCE_TEXT", HKEY_PERFORMANCE_TEXT},
	{L"HKEY_PERFORMANCE_NLSTEXT", HKEY_PERFORMANCE_NLSTEXT},
	{L"HKEY_CURRENT_CONFIG", HKEY_CURRENT_CONFIG},
	{L"HKEY_DYN_DATA", HKEY_DYN_DATA}};

	// These functions perform case independent path comparisons.
	bool EqualPath(const base::string16& first, const base::string16& second) {
	return _wcsicmp(first.c_str(), second.c_str()) == 0;
	}

	bool EqualPath(const base::string16& first,
	size_t first_offset,
	const base::string16& second,
	size_t second_offset) {
	return _wcsicmp(first.c_str() + first_offset,
	second.c_str() + second_offset) == 0;
	}

	bool EqualPath(const base::string16& first,
	const wchar_t* second,
	size_t second_len) {
	return _wcsnicmp(first.c_str(), second, second_len) == 0;
	}

	bool EqualPath(const base::string16& first,
	size_t first_offset,
	const wchar_t* second,
	size_t second_len) {
	return _wcsnicmp(first.c_str() + first_offset, second, second_len) == 0;
	}

	// Returns true if \|path\| starts with "\??\" and returns a path without that
	// component.
	bool IsNTPath(const base::string16& path, base::string16* trimmed_path) {
	if ((path.size() < sandbox::kNTPrefixLen) \|\|
	!EqualPath(path, sandbox::kNTPrefix, sandbox::kNTPrefixLen)) {
	*trimmed_path = path;
	return false;
	}

	*trimmed_path = path.substr(sandbox::kNTPrefixLen);
	return true;
	}

	// Returns true if \|path\| starts with "\Device\" and returns a path without that
	// component.
	bool IsDevicePath(const base::string16& path, base::string16* trimmed_path) {
	if ((path.size() < sandbox::kNTDevicePrefixLen) \|\|
	(!EqualPath(path, sandbox::kNTDevicePrefix,
	sandbox::kNTDevicePrefixLen))) {
	*trimmed_path = path;
	return false;
	}

	*trimmed_path = path.substr(sandbox::kNTDevicePrefixLen);
	return true;
	}

	// Returns the offset to the path seperator following
	// "\Device\HarddiskVolumeX" in \|path\|.
	size_t PassHarddiskVolume(const base::string16& path) {
	static constexpr wchar_t pattern[] = L"\\Device\\HarddiskVolume";
	const size_t patternLen = base::size(pattern) - 1;

	// First, check for \|pattern\|.
	if ((path.size() < patternLen) \|\| (!EqualPath(path, pattern, patternLen)))
	return base::string16::npos;

	// Find the next path separator, after the pattern match.
	return path.find_first_of(L'\\', patternLen - 1);
	}

	// Returns true if \|path\| starts with "\Device\HarddiskVolumeX\" and returns a
	// path without that component. \|removed\| will hold the prefix removed.
	bool IsDeviceHarddiskPath(const base::string16& path,
	base::string16* trimmed_path,
	base::string16* removed) {
	size_t offset = PassHarddiskVolume(path);
	if (offset == base::string16::npos)
	return false;

	// Remove up to and including the path separator.
	*removed = path.substr(0, offset + 1);
	// Remaining path starts after the path separator.
	*trimmed_path = path.substr(offset + 1);
	return true;
	}

	bool StartsWithDriveLetter(const base::string16& path) {
	if (path.size() < kDriveLetterLen)
	return false;

	if (path[1] != L':' \|\| path[2] != L'\\')
	return false;

	return base::IsAsciiAlpha(path[0]);
	}

	// Removes "\\\\.\\" from the path.
	void RemoveImpliedDevice(base::string16* path) {
	if (EqualPath(*path, kNTDotPrefix, kNTDotPrefixLen))
	*path = path->substr(kNTDotPrefixLen);
	}

	} // namespace

	namespace sandbox {

	// Returns true if the provided path points to a pipe.
	bool IsPipe(const base::string16& path) {
	size_t start = 0;
	if (EqualPath(path, sandbox::kNTPrefix, sandbox::kNTPrefixLen))
	start = sandbox::kNTPrefixLen;

	const wchar_t kPipe[] = L"pipe\\";
	if (path.size() < start + base::size(kPipe) - 1)
	return false;

	return EqualPath(path, start, kPipe, base::size(kPipe) - 1);
	}

	HKEY GetReservedKeyFromName(const base::string16& name) {
	for (size_t i = 0; i < base::size(kKnownKey); ++i) {
	if (name == kKnownKey[i].name)
	return kKnownKey[i].key;
	}

	return nullptr;
	}

	bool ResolveRegistryName(base::string16 name, base::string16* resolved_name) {
	for (size_t i = 0; i < base::size(kKnownKey); ++i) {
	if (name.find(kKnownKey[i].name) == 0) {
	HKEY key;
	DWORD disposition;
	if (ERROR_SUCCESS != ::RegCreateKeyEx(kKnownKey[i].key, L"", 0, nullptr,
	0, MAXIMUM_ALLOWED, nullptr, &key,
	&disposition))
	return false;

	bool result = GetPathFromHandle(key, resolved_name);
	::RegCloseKey(key);

	if (!result)
	return false;

	*resolved_name += name.substr(wcslen(kKnownKey[i].name));
	return true;
	}
	}

	return false;
	}

	// \|full_path\| can have any of the following forms:
	// \??\c:\some\foo\bar
	// \Device\HarddiskVolume0\some\foo\bar
	// \??\HarddiskVolume0\some\foo\bar
	DWORD IsReparsePoint(const base::string16& full_path) {
	// Check if it's a pipe. We can't query the attributes of a pipe.
	if (IsPipe(full_path))
	return ERROR_NOT_A_REPARSE_POINT;

	base::string16 path;
	bool nt_path = IsNTPath(full_path, &path);
	bool has_drive = StartsWithDriveLetter(path);
	bool is_device_path = IsDevicePath(path, &path);

	if (!has_drive && !is_device_path && !nt_path)
	return ERROR_INVALID_NAME;

	bool added_implied_device = false;
	if (!has_drive) {
	path = base::string16(kNTDotPrefix) + path;
	added_implied_device = true;
	}

	base::string16::size_type last_pos = base::string16::npos;
	bool passed_once = false;

	do {
	path = path.substr(0, last_pos);

	DWORD attributes = ::GetFileAttributes(path.c_str());
	if (INVALID_FILE_ATTRIBUTES == attributes) {
	DWORD error = ::GetLastError();
	if (error != ERROR_FILE_NOT_FOUND && error != ERROR_PATH_NOT_FOUND &&
	error != ERROR_INVALID_NAME) {
	// Unexpected error.
	if (passed_once && added_implied_device &&
	(path.rfind(L'\\') == kNTDotPrefixLen - 1)) {
	break;
	}
	NOTREACHED_NT();
	return error;
	}
	} else if (FILE_ATTRIBUTE_REPARSE_POINT & attributes) {
	// This is a reparse point.
	return ERROR_SUCCESS;
	}

	passed_once = true;
	last_pos = path.rfind(L'\\');
	} while (last_pos > 2); // Skip root dir.

	return ERROR_NOT_A_REPARSE_POINT;
	}

	// We get a \|full_path\| of the forms accepted by IsReparsePoint(), and the name
	// we'll get from \|handle\| will be \device\harddiskvolume1\some\foo\bar.
	bool SameObject(HANDLE handle, const wchar_t* full_path) {
	// Check if it's a pipe.
	if (IsPipe(full_path))
	return true;

	base::string16 actual_path;
	if (!GetPathFromHandle(handle, &actual_path))
	return false;

	base::string16 path(full_path);
	DCHECK_NT(!path.empty());

	// This may end with a backslash.
	const wchar_t kBackslash = '\\';
	if (path.back() == kBackslash)
	path = path.substr(0, path.length() - 1);

	// Perfect match (case-insesitive check).
	if (EqualPath(actual_path, path))
	return true;

	bool nt_path = IsNTPath(path, &path);
	bool has_drive = StartsWithDriveLetter(path);

	if (!has_drive && nt_path) {
	base::string16 simple_actual_path;
	if (!IsDevicePath(actual_path, &simple_actual_path))
	return false;

	// Perfect match (case-insesitive check).
	return (EqualPath(simple_actual_path, path));
	}

	if (!has_drive)
	return false;

	// We only need 3 chars, but let's alloc a buffer for four.
	wchar_t drive[4] = {0};
	wchar_t vol_name[MAX_PATH];
	memcpy(drive, &path[0], 2 * sizeof(*drive));

	// We'll get a double null terminated string.
	DWORD vol_length = ::QueryDosDeviceW(drive, vol_name, MAX_PATH);
	if (vol_length < 2 \|\| vol_length == MAX_PATH)
	return false;

	// Ignore the nulls at the end.
	vol_length = static_cast<DWORD>(wcslen(vol_name));

	// The two paths should be the same length.
	if (vol_length + path.size() - 2 != actual_path.size())
	return false;

	// Check up to the drive letter.
	if (!EqualPath(actual_path, vol_name, vol_length))
	return false;

	// Check the path after the drive letter.
	if (!EqualPath(actual_path, vol_length, path, 2))
	return false;

	return true;
	}

	// Just make a best effort here. There are lots of corner cases that we're
	// not expecting - and will fail to make long.
	bool ConvertToLongPath(base::string16* native_path,
	const base::string16* drive_letter) {
	if (IsPipe(*native_path))
	return true;

	bool is_device_harddisk_path = false;
	bool is_nt_path = false;
	bool added_implied_device = false;
	base::string16 temp_path;
	base::string16 to_restore;

	// Process a few prefix types.
	if (IsNTPath(*native_path, &temp_path)) {
	// "\??\"
	if (!StartsWithDriveLetter(temp_path)) {
	// Prepend with "\\.\".
	temp_path = base::string16(kNTDotPrefix) + temp_path;
	added_implied_device = true;
	}
	is_nt_path = true;
	} else if (IsDeviceHarddiskPath(*native_path, &temp_path, &to_restore)) {
	// "\Device\HarddiskVolumeX\" - hacky attempt making ::GetLongPathName
	// work for native device paths. Remove "\Device\HarddiskVolumeX\" and
	// replace with drive letter.

	// Nothing we can do if we don't have a drive letter. Leave \|native_path\|
	// as is.
	if (!drive_letter \|\| drive_letter->empty())
	return false;
	temp_path = *drive_letter + temp_path;
	is_device_harddisk_path = true;
	} else if (IsDevicePath(*native_path, &temp_path)) {
	// "\Device\" - there's nothing we can do to convert to long here.
	return false;
	}

	DWORD size = MAX_PATH;
	std::unique_ptr<wchar_t[]> long_path_buf(new wchar_t[size]);

	DWORD return_value =
	::GetLongPathName(temp_path.c_str(), long_path_buf.get(), size);
	while (return_value >= size) {
	size *= 2;
	long_path_buf.reset(new wchar_t[size]);
	return_value =
	::GetLongPathName(temp_path.c_str(), long_path_buf.get(), size);
	}

	DWORD last_error = ::GetLastError();
	if (0 == return_value && (ERROR_FILE_NOT_FOUND == last_error \|\|
	ERROR_PATH_NOT_FOUND == last_error \|\|
	ERROR_INVALID_NAME == last_error)) {
	// The file does not exist, but maybe a sub path needs to be expanded.
	base::string16::size_type last_slash = temp_path.rfind(L'\\');
	if (base::string16::npos == last_slash)
	return false;

	base::string16 begin = temp_path.substr(0, last_slash);
	base::string16 end = temp_path.substr(last_slash);
	if (!ConvertToLongPath(&begin))
	return false;

	// Ok, it worked. Let's reset the return value.
	temp_path = begin + end;
	return_value = 1;
	} else if (0 != return_value) {
	temp_path = long_path_buf.get();
	}

	// If successful, re-apply original namespace prefix before returning.
	if (return_value != 0) {
	if (added_implied_device)
	RemoveImpliedDevice(&temp_path);

	if (is_nt_path) {
	*native_path = kNTPrefix;
	*native_path += temp_path;
	} else if (is_device_harddisk_path) {
	// Remove the added drive letter.
	temp_path = temp_path.substr(kDriveLetterLen);
	*native_path = to_restore;
	*native_path += temp_path;
	} else {
	*native_path = temp_path;
	}

	return true;
	}

	return false;
	}

	bool GetPathFromHandle(HANDLE handle, base::string16* path) {
	NtQueryObjectFunction NtQueryObject = nullptr;
	ResolveNTFunctionPtr("NtQueryObject", &NtQueryObject);

	OBJECT_NAME_INFORMATION initial_buffer;
	OBJECT_NAME_INFORMATION* name = &initial_buffer;
	ULONG size = sizeof(initial_buffer);
	// Query the name information a first time to get the size of the name.
	// Windows XP requires that the size of the buffer passed in here be != 0.
	NTSTATUS status =
	NtQueryObject(handle, ObjectNameInformation, name, size, &size);

	std::unique_ptr<BYTE[]> name_ptr;
	if (size) {
	name_ptr.reset(new BYTE[size]);
	name = reinterpret_cast<OBJECT_NAME_INFORMATION*>(name_ptr.get());

	// Query the name information a second time to get the name of the
	// object referenced by the handle.
	status = NtQueryObject(handle, ObjectNameInformation, name, size, &size);
	}

	if (STATUS_SUCCESS != status)
	return false;

	path->assign(name->ObjectName.Buffer,
	name->ObjectName.Length / sizeof(name->ObjectName.Buffer[0]));
	return true;
	}

	bool GetNtPathFromWin32Path(const base::string16& path,
	base::string16* nt_path) {
	HANDLE file = ::CreateFileW(
	path.c_str(), 0, FILE_SHARE_READ \| FILE_SHARE_WRITE \| FILE_SHARE_DELETE,
	nullptr, OPEN_EXISTING, FILE_FLAG_BACKUP_SEMANTICS, nullptr);
	if (file == INVALID_HANDLE_VALUE)
	return false;
	bool rv = GetPathFromHandle(file, nt_path);
	::CloseHandle(file);
	return rv;
	}

	bool WriteProtectedChildMemory(HANDLE child_process,
	void* address,
	const void* buffer,
	size_t length) {
	// First, remove the protections.
	DWORD old_protection;
	if (!::VirtualProtectEx(child_process, address, length, PAGE_WRITECOPY,
	&old_protection))
	return false;

	SIZE_T written;
	bool ok =
	::WriteProcessMemory(child_process, address, buffer, length, &written) &&
	(length == written);

	// Always attempt to restore the original protection.
	if (!::VirtualProtectEx(child_process, address, length, old_protection,
	&old_protection))
	return false;

	return ok;
	}

	DWORD GetLastErrorFromNtStatus(NTSTATUS status) {
	RtlNtStatusToDosErrorFunction NtStatusToDosError = nullptr;
	ResolveNTFunctionPtr("RtlNtStatusToDosError", &NtStatusToDosError);
	return NtStatusToDosError(status);
	}

	// This function uses the undocumented PEB ImageBaseAddress field to extract
	// the base address of the new process.
	void* GetProcessBaseAddress(HANDLE process) {
	NtQueryInformationProcessFunction query_information_process = nullptr;
	ResolveNTFunctionPtr("NtQueryInformationProcess", &query_information_process);
	if (!query_information_process)
	return nullptr;
	PROCESS_BASIC_INFORMATION process_basic_info = {};
	NTSTATUS status = query_information_process(
	process, ProcessBasicInformation, &process_basic_info,
	sizeof(process_basic_info), nullptr);
	if (STATUS_SUCCESS != status)
	return nullptr;

	PEB peb = {};
	SIZE_T bytes_read = 0;
	if (!::ReadProcessMemory(process, process_basic_info.PebBaseAddress, &peb,
	sizeof(peb), &bytes_read) \|\|
	(sizeof(peb) != bytes_read)) {
	return nullptr;
	}

	void* base_address = peb.ImageBaseAddress;
	char magic[2] = {};
	if (!::ReadProcessMemory(process, base_address, magic, sizeof(magic),
	&bytes_read) \|\|
	(sizeof(magic) != bytes_read)) {
	return nullptr;
	}

	if (magic[0] != 'M' \|\| magic[1] != 'Z')
	return nullptr;

	return base_address;
	}

	} // namespace sandbox

	void ResolveNTFunctionPtr(const char* name, void* ptr) {
	static volatile HMODULE ntdll = nullptr;

	if (!ntdll) {
	HMODULE ntdll_local = ::GetModuleHandle(sandbox::kNtdllName);
	// Use PEImage to sanity-check that we have a valid ntdll handle.
	base::win::PEImage ntdll_peimage(ntdll_local);
	CHECK_NT(ntdll_peimage.VerifyMagic());
	// Race-safe way to set static ntdll.
	::InterlockedCompareExchangePointer(
	reinterpret_cast<PVOID volatile*>(&ntdll), ntdll_local, nullptr);
	}

	CHECK_NT(ntdll);
	FARPROC* function_ptr = reinterpret_cast<FARPROC*>(ptr);
	*function_ptr = ::GetProcAddress(ntdll, name);
	CHECK_NT(*function_ptr);
	}