components/storage_monitor/volume_mount_watcher_win.cc - chromium/src - Git at Google

 // Copyright 2014 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 "components/storage_monitor/volume_mount_watcher_win.h"

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

 #include <dbt.h>
 #include <fileapi.h>
 #include <shlobj.h>
 #include <winioctl.h>

 #include <algorithm>

 #include "base/bind.h"
 #include "base/bind_helpers.h"
 #include "base/stl_util.h"
 #include "base/strings/string_number_conversions.h"
 #include "base/strings/string_util.h"
 #include "base/strings/stringprintf.h"
 #include "base/strings/utf_string_conversions.h"
 #include "base/system/sys_info.h"
 #include "base/task/post_task.h"
 #include "base/task_runner_util.h"
 #include "base/time/time.h"
 #include "base/win/scoped_handle.h"
 #include "components/storage_monitor/media_storage_util.h"
 #include "components/storage_monitor/storage_info.h"
 #include "content/public/browser/browser_task_traits.h"
 #include "content/public/browser/browser_thread.h"

 using content::BrowserThread;

 namespace storage_monitor {

 namespace {

 const DWORD kMaxPathBufLen = MAX_PATH + 1;

 enum DeviceType {
   FLOPPY,
   REMOVABLE,
   FIXED,
 };

 // We are trying to figure out whether the drive is a fixed volume,
 // a removable storage, or a floppy. A "floppy" here means "a volume we
 // want to basically ignore because it won't fit media and will spin
 // if we touch it to get volume metadata." GetDriveType returns DRIVE_REMOVABLE
 // on either floppy or removable volumes. The DRIVE_CDROM type is handled
 // as a floppy, as are DRIVE_UNKNOWN and DRIVE_NO_ROOT_DIR, as there are
 // reports that some floppy drives don't report as DRIVE_REMOVABLE.
 DeviceType GetDeviceType(const base::string16& mount_point) {
   UINT drive_type = GetDriveType(mount_point.c_str());
   if (drive_type == DRIVE_FIXED || drive_type == DRIVE_REMOTE ||
       drive_type == DRIVE_RAMDISK) {
     return FIXED;
   }
   if (drive_type != DRIVE_REMOVABLE)
     return FLOPPY;

   // Check device strings of the form "X:" and "\\.\X:"
   // For floppy drives, these will return strings like "/Device/Floppy0"
   base::string16 device = mount_point;
   if (base::EndsWith(mount_point, L"\\", base::CompareCase::INSENSITIVE_ASCII))
     device = mount_point.substr(0, mount_point.length() - 1);
   base::string16 device_path;
   base::string16 device_path_slash;
   DWORD dos_device = QueryDosDevice(
       device.c_str(), base::WriteInto(&device_path, kMaxPathBufLen),
       kMaxPathBufLen);
   base::string16 device_slash = base::string16(L"\\\\.\\");
   device_slash += device;
   DWORD dos_device_slash = QueryDosDevice(
       device_slash.c_str(), base::WriteInto(&device_path_slash, kMaxPathBufLen),
       kMaxPathBufLen);
   if (dos_device == 0 && dos_device_slash == 0)
     return FLOPPY;
   if (device_path.find(L"Floppy") != base::string16::npos ||
       device_path_slash.find(L"Floppy") != base::string16::npos) {
     return FLOPPY;
   }

   return REMOVABLE;
 }

 // Returns 0 if the devicetype is not volume.
 uint32_t GetVolumeBitMaskFromBroadcastHeader(LPARAM data) {
   DEV_BROADCAST_VOLUME* dev_broadcast_volume =
       reinterpret_cast<DEV_BROADCAST_VOLUME*>(data);
   if (dev_broadcast_volume->dbcv_devicetype == DBT_DEVTYP_VOLUME)
     return dev_broadcast_volume->dbcv_unitmask;
   return 0;
 }

 // Returns true if |data| represents a logical volume structure.
 bool IsLogicalVolumeStructure(LPARAM data) {
   DEV_BROADCAST_HDR* broadcast_hdr =
       reinterpret_cast<DEV_BROADCAST_HDR*>(data);
   return broadcast_hdr && broadcast_hdr->dbch_devicetype == DBT_DEVTYP_VOLUME;
 }

 // Gets the total volume of the |mount_point| in bytes.
 uint64_t GetVolumeSize(const base::FilePath& mount_point) {
   int64_t size = base::SysInfo::AmountOfTotalDiskSpace(mount_point);
   return std::max(size, static_cast<int64_t>(0));
 }

 // Gets mass storage device information given a |device_path|. On success,
 // returns true and fills in |info|.
 // The following msdn blog entry is helpful for understanding disk volumes
 // and how they are treated in Windows:
 // http://blogs.msdn.com/b/adioltean/archive/2005/04/16/408947.aspx.
 bool GetDeviceDetails(const base::FilePath& device_path, StorageInfo* info) {
   DCHECK(info);

   base::string16 mount_point;
   if (!GetVolumePathName(device_path.value().c_str(),
                          base::WriteInto(&mount_point, kMaxPathBufLen),
                          kMaxPathBufLen)) {
     return false;
   }
   mount_point.resize(wcslen(mount_point.c_str()));

   // Note: experimentally this code does not spin a floppy drive. It
   // returns a GUID associated with the device, not the volume.
   base::string16 guid;
   if (!GetVolumeNameForVolumeMountPoint(mount_point.c_str(),
                                         base::WriteInto(&guid, kMaxPathBufLen),
                                         kMaxPathBufLen)) {
     return false;
   }
   // In case it has two GUID's (see above mentioned blog), do it again.
   if (!GetVolumeNameForVolumeMountPoint(guid.c_str(),
                                         base::WriteInto(&guid, kMaxPathBufLen),
                                         kMaxPathBufLen)) {
     return false;
   }

   // If we're adding a floppy drive, return without querying any more
   // drive metadata -- it will cause the floppy drive to seek.
   // Note: treats FLOPPY as FIXED_MASS_STORAGE. This is intentional.
   DeviceType device_type = GetDeviceType(mount_point);
   if (device_type == FLOPPY) {
     info->set_device_id(StorageInfo::MakeDeviceId(
         StorageInfo::FIXED_MASS_STORAGE, base::UTF16ToUTF8(guid)));
     return true;
   }

   base::FilePath mount_path(mount_point);
   StorageInfo::Type type = StorageInfo::FIXED_MASS_STORAGE;
   if (device_type == REMOVABLE) {
     type = StorageInfo::REMOVABLE_MASS_STORAGE_NO_DCIM;
     if (MediaStorageUtil::HasDcim(mount_path))
       type = StorageInfo::REMOVABLE_MASS_STORAGE_WITH_DCIM;
   }

   // NOTE: experimentally, this function returns false if there is no volume
   // name set.
   base::string16 volume_label;
   GetVolumeInformationW(device_path.value().c_str(),
                         base::WriteInto(&volume_label, kMaxPathBufLen),
                         kMaxPathBufLen, nullptr, nullptr, nullptr, nullptr, 0);

   uint64_t total_size_in_bytes = GetVolumeSize(mount_path);
   std::string device_id =
       StorageInfo::MakeDeviceId(type, base::UTF16ToUTF8(guid));

   // TODO(gbillock): if volume_label.empty(), get the vendor/model information
   // for the volume.
   *info = StorageInfo(device_id, mount_point, volume_label, base::string16(),
                       base::string16(), total_size_in_bytes);
   return true;
 }

 // Returns a vector of all the removable mass storage devices that are
 // connected.
 std::vector<base::FilePath> GetAttachedDevices() {
   std::vector<base::FilePath> result;
   base::string16 volume_name;
   HANDLE find_handle = FindFirstVolume(
       base::WriteInto(&volume_name, kMaxPathBufLen), kMaxPathBufLen);
   if (find_handle == INVALID_HANDLE_VALUE)
     return result;

   while (true) {
     base::string16 volume_path;
     DWORD return_count;
     if (GetVolumePathNamesForVolumeName(
             volume_name.c_str(), base::WriteInto(&volume_path, kMaxPathBufLen),
             kMaxPathBufLen, &return_count)) {
       result.push_back(base::FilePath(volume_path));
     }
     if (!FindNextVolume(find_handle,
                         base::WriteInto(&volume_name, kMaxPathBufLen),
                         kMaxPathBufLen)) {
       if (GetLastError() != ERROR_NO_MORE_FILES)
         DPLOG(ERROR);
       break;
     }
   }

   FindVolumeClose(find_handle);
   return result;
 }

 // Eject a removable volume at the specified |device| path. This works by
 // 1) locking the volume,
 // 2) unmounting the volume,
 // 3) ejecting the volume.
 // If the lock fails, it will re-schedule itself.
 // See http://support.microsoft.com/kb/165721
 void EjectDeviceInThreadPool(
     const base::FilePath& device,
     base::Callback<void(StorageMonitor::EjectStatus)> callback,
     scoped_refptr<base::SequencedTaskRunner> task_runner,
     int iteration) {
   base::FilePath::StringType volume_name;
   base::FilePath::CharType drive_letter = device.value()[0];
   // Don't try to eject if the path isn't a simple one -- we're not
   // sure how to do that yet. Need to figure out how to eject volumes mounted
   // at not-just-drive-letter paths.
   if (drive_letter < L'A' || drive_letter > L'Z' ||
       device != device.DirName()) {
     base::PostTaskWithTraits(
         FROM_HERE, {BrowserThread::UI},
         base::BindOnce(callback, StorageMonitor::EJECT_FAILURE));
     return;
   }
   base::SStringPrintf(&volume_name, L"\\\\.\\%lc:", drive_letter);

   base::win::ScopedHandle volume_handle(CreateFile(
       volume_name.c_str(), GENERIC_READ, FILE_SHARE_READ | FILE_SHARE_WRITE,
       nullptr, OPEN_EXISTING, 0, nullptr));

   if (!volume_handle.IsValid()) {
     base::PostTaskWithTraits(
         FROM_HERE, {BrowserThread::UI},
         base::BindOnce(callback, StorageMonitor::EJECT_FAILURE));
     return;
   }

   DWORD bytes_returned = 0;  // Unused, but necessary for ioctl's.

   // Lock the drive to be ejected (so that other processes can't open
   // files on it). If this fails, it means some other process has files
   // open on the device. Note that the lock is released when the volume
   // handle is closed, and this is done by the ScopedHandle above.
   BOOL locked = DeviceIoControl(volume_handle.Get(), FSCTL_LOCK_VOLUME, nullptr,
                                 0, nullptr, 0, &bytes_returned, nullptr);
   if (!locked) {
     const int kNumLockRetries = 1;
     const base::TimeDelta kLockRetryInterval =
         base::TimeDelta::FromMilliseconds(500);
     if (iteration < kNumLockRetries) {
       // Try again -- the lock may have been a transient one. This happens on
       // things like AV disk lock for some reason, or another process
       // transient disk lock.
       task_runner->PostDelayedTask(
           FROM_HERE,
           base::BindOnce(&EjectDeviceInThreadPool, device, callback,
                          task_runner, iteration + 1),
           kLockRetryInterval);
       return;
     }

     base::PostTaskWithTraits(
         FROM_HERE, {BrowserThread::UI},
         base::BindOnce(callback, StorageMonitor::EJECT_IN_USE));
     return;
   }

   // Unmount the device from the filesystem -- this will remove it from
   // the file picker, drive enumerations, etc.
   BOOL dismounted =
       DeviceIoControl(volume_handle.Get(), FSCTL_DISMOUNT_VOLUME, nullptr, 0,
                       nullptr, 0, &bytes_returned, nullptr);

   // Reached if we acquired a lock, but could not dismount. This might
   // occur if another process unmounted without locking. Call this OK,
   // since the volume is now unreachable.
   if (!dismounted) {
     DeviceIoControl(volume_handle.Get(), FSCTL_UNLOCK_VOLUME, nullptr, 0,
                     nullptr, 0, &bytes_returned, nullptr);
     base::PostTaskWithTraits(
         FROM_HERE, {BrowserThread::UI},
         base::BindOnce(callback, StorageMonitor::EJECT_OK));
     return;
   }

   PREVENT_MEDIA_REMOVAL pmr_buffer;
   pmr_buffer.PreventMediaRemoval = FALSE;
   // Mark the device as safe to remove.
   if (!DeviceIoControl(volume_handle.Get(), IOCTL_STORAGE_MEDIA_REMOVAL,
                        &pmr_buffer, sizeof(PREVENT_MEDIA_REMOVAL), nullptr, 0,
                        &bytes_returned, nullptr)) {
     base::PostTaskWithTraits(
         FROM_HERE, {BrowserThread::UI},
         base::BindOnce(callback, StorageMonitor::EJECT_FAILURE));
     return;
   }

   // Physically eject or soft-eject the device.
   if (!DeviceIoControl(volume_handle.Get(), IOCTL_STORAGE_EJECT_MEDIA, nullptr,
                        0, nullptr, 0, &bytes_returned, nullptr)) {
     base::PostTaskWithTraits(
         FROM_HERE, {BrowserThread::UI},
         base::BindOnce(callback, StorageMonitor::EJECT_FAILURE));
     return;
   }

   base::PostTaskWithTraits(FROM_HERE, {BrowserThread::UI},
                            base::BindOnce(callback, StorageMonitor::EJECT_OK));
 }

 }  // namespace

 VolumeMountWatcherWin::VolumeMountWatcherWin()
     : device_info_task_runner_(base::CreateSequencedTaskRunnerWithTraits(
           {base::MayBlock(), base::TaskPriority::BEST_EFFORT,
            base::TaskShutdownBehavior::CONTINUE_ON_SHUTDOWN})),
       notifications_(nullptr),
       weak_factory_(this) {}

 // static
 base::FilePath VolumeMountWatcherWin::DriveNumberToFilePath(int drive_number) {
   if (drive_number < 0 || drive_number > 25)
     return base::FilePath();
   base::string16 path(L"_:\\");
   path[0] = static_cast<base::char16>('A' + drive_number);
   return base::FilePath(path);
 }

 // In order to get all the weak pointers created on the UI thread, and doing
 // synchronous Windows calls in the worker pool, this kicks off a chain of
 // events which will
 // a) Enumerate attached devices
 // b) Create weak pointers for which to send completion signals from
 // c) Retrieve metadata on the volumes and then
 // d) Notify that metadata to listeners.
 void VolumeMountWatcherWin::Init() {
   DCHECK_CURRENTLY_ON(BrowserThread::UI);

   // When VolumeMountWatcherWin is created, the message pumps are not running
   // so a posted task from the constructor would never run. Therefore, do all
   // the initializations here.
   base::PostTaskAndReplyWithResult(
       device_info_task_runner_.get(), FROM_HERE, GetAttachedDevicesCallback(),
       base::Bind(&VolumeMountWatcherWin::AddDevicesOnUIThread,
                  weak_factory_.GetWeakPtr()));
 }

 void VolumeMountWatcherWin::AddDevicesOnUIThread(
     std::vector<base::FilePath> removable_devices) {
   DCHECK_CURRENTLY_ON(BrowserThread::UI);

   for (size_t i = 0; i < removable_devices.size(); i++) {
     if (base::ContainsKey(pending_device_checks_, removable_devices[i]))
       continue;
     pending_device_checks_.insert(removable_devices[i]);
     device_info_task_runner_->PostTask(
         FROM_HERE,
         base::BindOnce(&VolumeMountWatcherWin::RetrieveInfoForDeviceAndAdd,
                        removable_devices[i], GetDeviceDetailsCallback(),
                        weak_factory_.GetWeakPtr()));
   }
 }

 // static
 void VolumeMountWatcherWin::RetrieveInfoForDeviceAndAdd(
     const base::FilePath& device_path,
     const GetDeviceDetailsCallbackType& get_device_details_callback,
     base::WeakPtr<VolumeMountWatcherWin> volume_watcher) {
   StorageInfo info;
   if (!get_device_details_callback.Run(device_path, &info)) {
     base::PostTaskWithTraits(
         FROM_HERE, {BrowserThread::UI},
         base::BindOnce(&VolumeMountWatcherWin::DeviceCheckComplete,
                        volume_watcher, device_path));
     return;
   }

   base::PostTaskWithTraits(
       FROM_HERE, {BrowserThread::UI},
       base::BindOnce(&VolumeMountWatcherWin::HandleDeviceAttachEventOnUIThread,
                      volume_watcher, device_path, info));
 }

 void VolumeMountWatcherWin::DeviceCheckComplete(
     const base::FilePath& device_path) {
   DCHECK_CURRENTLY_ON(BrowserThread::UI);
   pending_device_checks_.erase(device_path);

   if (pending_device_checks_.empty()) {
     if (notifications_)
       notifications_->MarkInitialized();
   }
 }

 VolumeMountWatcherWin::GetAttachedDevicesCallbackType
     VolumeMountWatcherWin::GetAttachedDevicesCallback() const {
   return base::Bind(&GetAttachedDevices);
 }

 VolumeMountWatcherWin::GetDeviceDetailsCallbackType
     VolumeMountWatcherWin::GetDeviceDetailsCallback() const {
   return base::Bind(&GetDeviceDetails);
 }

 bool VolumeMountWatcherWin::GetDeviceInfo(const base::FilePath& device_path,
                                           StorageInfo* info) const {
   DCHECK_CURRENTLY_ON(BrowserThread::UI);
   DCHECK(info);
   base::FilePath path(device_path);
   MountPointDeviceMetadataMap::const_iterator iter =
       device_metadata_.find(path);
   while (iter == device_metadata_.end() && path.DirName() != path) {
     path = path.DirName();
     iter = device_metadata_.find(path);
   }

   if (iter == device_metadata_.end())
     return false;

   *info = iter->second;
   return true;
 }

 void VolumeMountWatcherWin::OnWindowMessage(UINT event_type, LPARAM data) {
   DCHECK_CURRENTLY_ON(BrowserThread::UI);
   switch (event_type) {
     case DBT_DEVICEARRIVAL: {
       if (IsLogicalVolumeStructure(data)) {
         DWORD unitmask = GetVolumeBitMaskFromBroadcastHeader(data);
         std::vector<base::FilePath> paths;
         for (int i = 0; unitmask; ++i, unitmask >>= 1) {
           if (!(unitmask & 0x01))
             continue;
           paths.push_back(DriveNumberToFilePath(i));
         }
         AddDevicesOnUIThread(paths);
       }
       break;
     }
     case DBT_DEVICEREMOVECOMPLETE: {
       if (IsLogicalVolumeStructure(data)) {
         DWORD unitmask = GetVolumeBitMaskFromBroadcastHeader(data);
         for (int i = 0; unitmask; ++i, unitmask >>= 1) {
           if (!(unitmask & 0x01))
             continue;
           HandleDeviceDetachEventOnUIThread(DriveNumberToFilePath(i).value());
         }
       }
       break;
     }
   }
 }

 void VolumeMountWatcherWin::OnMediaChange(WPARAM wparam, LPARAM lparam) {
   if (lparam == SHCNE_MEDIAINSERTED || lparam == SHCNE_MEDIAREMOVED) {
     struct _ITEMIDLIST* pidl = *reinterpret_cast<struct _ITEMIDLIST**>(
         wparam);
     wchar_t sPath[MAX_PATH];
     if (!SHGetPathFromIDList(pidl, sPath)) {
       DVLOG(1) << "MediaInserted: SHGetPathFromIDList failed";
       return;
     }
     switch (lparam) {
       case SHCNE_MEDIAINSERTED: {
         std::vector<base::FilePath> paths;
         paths.push_back(base::FilePath(sPath));
         AddDevicesOnUIThread(paths);
         break;
       }
       case SHCNE_MEDIAREMOVED: {
         HandleDeviceDetachEventOnUIThread(sPath);
         break;
       }
     }
   }
 }

 void VolumeMountWatcherWin::SetNotifications(
     StorageMonitor::Receiver* notifications) {
   notifications_ = notifications;
 }

 VolumeMountWatcherWin::~VolumeMountWatcherWin() {
   weak_factory_.InvalidateWeakPtrs();
 }

 void VolumeMountWatcherWin::HandleDeviceAttachEventOnUIThread(
     const base::FilePath& device_path,
     const StorageInfo& info) {
   DCHECK_CURRENTLY_ON(BrowserThread::UI);

   device_metadata_[device_path] = info;

   if (notifications_)
     notifications_->ProcessAttach(info);

   DeviceCheckComplete(device_path);
 }

 void VolumeMountWatcherWin::HandleDeviceDetachEventOnUIThread(
     const base::string16& device_location) {
   DCHECK_CURRENTLY_ON(BrowserThread::UI);

   MountPointDeviceMetadataMap::const_iterator device_info =
       device_metadata_.find(base::FilePath(device_location));
   // If the device isn't type removable (like a CD), it won't be there.
   if (device_info == device_metadata_.end())
     return;

   if (notifications_)
     notifications_->ProcessDetach(device_info->second.device_id());
   device_metadata_.erase(device_info);
 }

 void VolumeMountWatcherWin::EjectDevice(
     const std::string& device_id,
     base::Callback<void(StorageMonitor::EjectStatus)> callback) {
   DCHECK_CURRENTLY_ON(BrowserThread::UI);
   base::FilePath device = MediaStorageUtil::FindDevicePathById(device_id);
   if (device.empty()) {
     callback.Run(StorageMonitor::EJECT_FAILURE);
     return;
   }
   if (device_metadata_.erase(device) == 0) {
     callback.Run(StorageMonitor::EJECT_FAILURE);
     return;
   }

   device_info_task_runner_->PostTask(
       FROM_HERE, base::BindOnce(&EjectDeviceInThreadPool, device, callback,
                                 device_info_task_runner_, 0));
 }

 }  // namespace storage_monitor
	// Copyright 2014 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 "components/storage_monitor/volume_mount_watcher_win.h"

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

	#include <dbt.h>
	#include <fileapi.h>
	#include <shlobj.h>
	#include <winioctl.h>

	#include <algorithm>

	#include "base/bind.h"
	#include "base/bind_helpers.h"
	#include "base/stl_util.h"
	#include "base/strings/string_number_conversions.h"
	#include "base/strings/string_util.h"
	#include "base/strings/stringprintf.h"
	#include "base/strings/utf_string_conversions.h"
	#include "base/system/sys_info.h"
	#include "base/task/post_task.h"
	#include "base/task_runner_util.h"
	#include "base/time/time.h"
	#include "base/win/scoped_handle.h"
	#include "components/storage_monitor/media_storage_util.h"
	#include "components/storage_monitor/storage_info.h"
	#include "content/public/browser/browser_task_traits.h"
	#include "content/public/browser/browser_thread.h"

	using content::BrowserThread;

	namespace storage_monitor {

	namespace {

	const DWORD kMaxPathBufLen = MAX_PATH + 1;

	enum DeviceType {
	FLOPPY,
	REMOVABLE,
	FIXED,
	};

	// We are trying to figure out whether the drive is a fixed volume,
	// a removable storage, or a floppy. A "floppy" here means "a volume we
	// want to basically ignore because it won't fit media and will spin
	// if we touch it to get volume metadata." GetDriveType returns DRIVE_REMOVABLE
	// on either floppy or removable volumes. The DRIVE_CDROM type is handled
	// as a floppy, as are DRIVE_UNKNOWN and DRIVE_NO_ROOT_DIR, as there are
	// reports that some floppy drives don't report as DRIVE_REMOVABLE.
	DeviceType GetDeviceType(const base::string16& mount_point) {
	UINT drive_type = GetDriveType(mount_point.c_str());
	if (drive_type == DRIVE_FIXED \|\| drive_type == DRIVE_REMOTE \|\|
	drive_type == DRIVE_RAMDISK) {
	return FIXED;
	}
	if (drive_type != DRIVE_REMOVABLE)
	return FLOPPY;

	// Check device strings of the form "X:" and "\\.\X:"
	// For floppy drives, these will return strings like "/Device/Floppy0"
	base::string16 device = mount_point;
	if (base::EndsWith(mount_point, L"\\", base::CompareCase::INSENSITIVE_ASCII))
	device = mount_point.substr(0, mount_point.length() - 1);
	base::string16 device_path;
	base::string16 device_path_slash;
	DWORD dos_device = QueryDosDevice(
	device.c_str(), base::WriteInto(&device_path, kMaxPathBufLen),
	kMaxPathBufLen);
	base::string16 device_slash = base::string16(L"\\\\.\\");
	device_slash += device;
	DWORD dos_device_slash = QueryDosDevice(
	device_slash.c_str(), base::WriteInto(&device_path_slash, kMaxPathBufLen),
	kMaxPathBufLen);
	if (dos_device == 0 && dos_device_slash == 0)
	return FLOPPY;
	if (device_path.find(L"Floppy") != base::string16::npos \|\|
	device_path_slash.find(L"Floppy") != base::string16::npos) {
	return FLOPPY;
	}

	return REMOVABLE;
	}

	// Returns 0 if the devicetype is not volume.
	uint32_t GetVolumeBitMaskFromBroadcastHeader(LPARAM data) {
	DEV_BROADCAST_VOLUME* dev_broadcast_volume =
	reinterpret_cast<DEV_BROADCAST_VOLUME*>(data);
	if (dev_broadcast_volume->dbcv_devicetype == DBT_DEVTYP_VOLUME)
	return dev_broadcast_volume->dbcv_unitmask;
	return 0;
	}

	// Returns true if \|data\| represents a logical volume structure.
	bool IsLogicalVolumeStructure(LPARAM data) {
	DEV_BROADCAST_HDR* broadcast_hdr =
	reinterpret_cast<DEV_BROADCAST_HDR*>(data);
	return broadcast_hdr && broadcast_hdr->dbch_devicetype == DBT_DEVTYP_VOLUME;
	}

	// Gets the total volume of the \|mount_point\| in bytes.
	uint64_t GetVolumeSize(const base::FilePath& mount_point) {
	int64_t size = base::SysInfo::AmountOfTotalDiskSpace(mount_point);
	return std::max(size, static_cast<int64_t>(0));
	}

	// Gets mass storage device information given a \|device_path\|. On success,
	// returns true and fills in \|info\|.
	// The following msdn blog entry is helpful for understanding disk volumes
	// and how they are treated in Windows:
	// http://blogs.msdn.com/b/adioltean/archive/2005/04/16/408947.aspx.
	bool GetDeviceDetails(const base::FilePath& device_path, StorageInfo* info) {
	DCHECK(info);

	base::string16 mount_point;
	if (!GetVolumePathName(device_path.value().c_str(),
	base::WriteInto(&mount_point, kMaxPathBufLen),
	kMaxPathBufLen)) {
	return false;
	}
	mount_point.resize(wcslen(mount_point.c_str()));

	// Note: experimentally this code does not spin a floppy drive. It
	// returns a GUID associated with the device, not the volume.
	base::string16 guid;
	if (!GetVolumeNameForVolumeMountPoint(mount_point.c_str(),
	base::WriteInto(&guid, kMaxPathBufLen),
	kMaxPathBufLen)) {
	return false;
	}
	// In case it has two GUID's (see above mentioned blog), do it again.
	if (!GetVolumeNameForVolumeMountPoint(guid.c_str(),
	base::WriteInto(&guid, kMaxPathBufLen),
	kMaxPathBufLen)) {
	return false;
	}

	// If we're adding a floppy drive, return without querying any more
	// drive metadata -- it will cause the floppy drive to seek.
	// Note: treats FLOPPY as FIXED_MASS_STORAGE. This is intentional.
	DeviceType device_type = GetDeviceType(mount_point);
	if (device_type == FLOPPY) {
	info->set_device_id(StorageInfo::MakeDeviceId(
	StorageInfo::FIXED_MASS_STORAGE, base::UTF16ToUTF8(guid)));
	return true;
	}

	base::FilePath mount_path(mount_point);
	StorageInfo::Type type = StorageInfo::FIXED_MASS_STORAGE;
	if (device_type == REMOVABLE) {
	type = StorageInfo::REMOVABLE_MASS_STORAGE_NO_DCIM;
	if (MediaStorageUtil::HasDcim(mount_path))
	type = StorageInfo::REMOVABLE_MASS_STORAGE_WITH_DCIM;
	}

	// NOTE: experimentally, this function returns false if there is no volume
	// name set.
	base::string16 volume_label;
	GetVolumeInformationW(device_path.value().c_str(),
	base::WriteInto(&volume_label, kMaxPathBufLen),
	kMaxPathBufLen, nullptr, nullptr, nullptr, nullptr, 0);

	uint64_t total_size_in_bytes = GetVolumeSize(mount_path);
	std::string device_id =
	StorageInfo::MakeDeviceId(type, base::UTF16ToUTF8(guid));

	// TODO(gbillock): if volume_label.empty(), get the vendor/model information
	// for the volume.
	*info = StorageInfo(device_id, mount_point, volume_label, base::string16(),
	base::string16(), total_size_in_bytes);
	return true;
	}

	// Returns a vector of all the removable mass storage devices that are
	// connected.
	std::vector<base::FilePath> GetAttachedDevices() {
	std::vector<base::FilePath> result;
	base::string16 volume_name;
	HANDLE find_handle = FindFirstVolume(
	base::WriteInto(&volume_name, kMaxPathBufLen), kMaxPathBufLen);
	if (find_handle == INVALID_HANDLE_VALUE)
	return result;

	while (true) {
	base::string16 volume_path;
	DWORD return_count;
	if (GetVolumePathNamesForVolumeName(
	volume_name.c_str(), base::WriteInto(&volume_path, kMaxPathBufLen),
	kMaxPathBufLen, &return_count)) {
	result.push_back(base::FilePath(volume_path));
	}
	if (!FindNextVolume(find_handle,
	base::WriteInto(&volume_name, kMaxPathBufLen),
	kMaxPathBufLen)) {
	if (GetLastError() != ERROR_NO_MORE_FILES)
	DPLOG(ERROR);
	break;
	}
	}

	FindVolumeClose(find_handle);
	return result;
	}

	// Eject a removable volume at the specified \|device\| path. This works by
	// 1) locking the volume,
	// 2) unmounting the volume,
	// 3) ejecting the volume.
	// If the lock fails, it will re-schedule itself.
	// See http://support.microsoft.com/kb/165721
	void EjectDeviceInThreadPool(
	const base::FilePath& device,
	base::Callback<void(StorageMonitor::EjectStatus)> callback,
	scoped_refptr<base::SequencedTaskRunner> task_runner,
	int iteration) {
	base::FilePath::StringType volume_name;
	base::FilePath::CharType drive_letter = device.value()[0];
	// Don't try to eject if the path isn't a simple one -- we're not
	// sure how to do that yet. Need to figure out how to eject volumes mounted
	// at not-just-drive-letter paths.
	if (drive_letter < L'A' \|\| drive_letter > L'Z' \|\|
	device != device.DirName()) {
	base::PostTaskWithTraits(
	FROM_HERE, {BrowserThread::UI},
	base::BindOnce(callback, StorageMonitor::EJECT_FAILURE));
	return;
	}
	base::SStringPrintf(&volume_name, L"\\\\.\\%lc:", drive_letter);

	base::win::ScopedHandle volume_handle(CreateFile(
	volume_name.c_str(), GENERIC_READ, FILE_SHARE_READ \| FILE_SHARE_WRITE,
	nullptr, OPEN_EXISTING, 0, nullptr));

	if (!volume_handle.IsValid()) {
	base::PostTaskWithTraits(
	FROM_HERE, {BrowserThread::UI},
	base::BindOnce(callback, StorageMonitor::EJECT_FAILURE));
	return;
	}

	DWORD bytes_returned = 0; // Unused, but necessary for ioctl's.

	// Lock the drive to be ejected (so that other processes can't open
	// files on it). If this fails, it means some other process has files
	// open on the device. Note that the lock is released when the volume
	// handle is closed, and this is done by the ScopedHandle above.
	BOOL locked = DeviceIoControl(volume_handle.Get(), FSCTL_LOCK_VOLUME, nullptr,
	0, nullptr, 0, &bytes_returned, nullptr);
	if (!locked) {
	const int kNumLockRetries = 1;
	const base::TimeDelta kLockRetryInterval =
	base::TimeDelta::FromMilliseconds(500);
	if (iteration < kNumLockRetries) {
	// Try again -- the lock may have been a transient one. This happens on
	// things like AV disk lock for some reason, or another process
	// transient disk lock.
	task_runner->PostDelayedTask(
	FROM_HERE,
	base::BindOnce(&EjectDeviceInThreadPool, device, callback,
	task_runner, iteration + 1),
	kLockRetryInterval);
	return;
	}

	base::PostTaskWithTraits(
	FROM_HERE, {BrowserThread::UI},
	base::BindOnce(callback, StorageMonitor::EJECT_IN_USE));
	return;
	}

	// Unmount the device from the filesystem -- this will remove it from
	// the file picker, drive enumerations, etc.
	BOOL dismounted =
	DeviceIoControl(volume_handle.Get(), FSCTL_DISMOUNT_VOLUME, nullptr, 0,
	nullptr, 0, &bytes_returned, nullptr);

	// Reached if we acquired a lock, but could not dismount. This might
	// occur if another process unmounted without locking. Call this OK,
	// since the volume is now unreachable.
	if (!dismounted) {
	DeviceIoControl(volume_handle.Get(), FSCTL_UNLOCK_VOLUME, nullptr, 0,
	nullptr, 0, &bytes_returned, nullptr);
	base::PostTaskWithTraits(
	FROM_HERE, {BrowserThread::UI},
	base::BindOnce(callback, StorageMonitor::EJECT_OK));
	return;
	}

	PREVENT_MEDIA_REMOVAL pmr_buffer;
	pmr_buffer.PreventMediaRemoval = FALSE;
	// Mark the device as safe to remove.
	if (!DeviceIoControl(volume_handle.Get(), IOCTL_STORAGE_MEDIA_REMOVAL,
	&pmr_buffer, sizeof(PREVENT_MEDIA_REMOVAL), nullptr, 0,
	&bytes_returned, nullptr)) {
	base::PostTaskWithTraits(
	FROM_HERE, {BrowserThread::UI},
	base::BindOnce(callback, StorageMonitor::EJECT_FAILURE));
	return;
	}

	// Physically eject or soft-eject the device.
	if (!DeviceIoControl(volume_handle.Get(), IOCTL_STORAGE_EJECT_MEDIA, nullptr,
	0, nullptr, 0, &bytes_returned, nullptr)) {
	base::PostTaskWithTraits(
	FROM_HERE, {BrowserThread::UI},
	base::BindOnce(callback, StorageMonitor::EJECT_FAILURE));
	return;
	}

	base::PostTaskWithTraits(FROM_HERE, {BrowserThread::UI},
	base::BindOnce(callback, StorageMonitor::EJECT_OK));
	}

	} // namespace

	VolumeMountWatcherWin::VolumeMountWatcherWin()
	: device_info_task_runner_(base::CreateSequencedTaskRunnerWithTraits(
	{base::MayBlock(), base::TaskPriority::BEST_EFFORT,
	base::TaskShutdownBehavior::CONTINUE_ON_SHUTDOWN})),
	notifications_(nullptr),
	weak_factory_(this) {}

	// static
	base::FilePath VolumeMountWatcherWin::DriveNumberToFilePath(int drive_number) {
	if (drive_number < 0 \|\| drive_number > 25)
	return base::FilePath();
	base::string16 path(L"_:\\");
	path[0] = static_cast<base::char16>('A' + drive_number);
	return base::FilePath(path);
	}

	// In order to get all the weak pointers created on the UI thread, and doing
	// synchronous Windows calls in the worker pool, this kicks off a chain of
	// events which will
	// a) Enumerate attached devices
	// b) Create weak pointers for which to send completion signals from
	// c) Retrieve metadata on the volumes and then
	// d) Notify that metadata to listeners.
	void VolumeMountWatcherWin::Init() {
	DCHECK_CURRENTLY_ON(BrowserThread::UI);

	// When VolumeMountWatcherWin is created, the message pumps are not running
	// so a posted task from the constructor would never run. Therefore, do all
	// the initializations here.
	base::PostTaskAndReplyWithResult(
	device_info_task_runner_.get(), FROM_HERE, GetAttachedDevicesCallback(),
	base::Bind(&VolumeMountWatcherWin::AddDevicesOnUIThread,
	weak_factory_.GetWeakPtr()));
	}

	void VolumeMountWatcherWin::AddDevicesOnUIThread(
	std::vector<base::FilePath> removable_devices) {
	DCHECK_CURRENTLY_ON(BrowserThread::UI);

	for (size_t i = 0; i < removable_devices.size(); i++) {
	if (base::ContainsKey(pending_device_checks_, removable_devices[i]))
	continue;
	pending_device_checks_.insert(removable_devices[i]);
	device_info_task_runner_->PostTask(
	FROM_HERE,
	base::BindOnce(&VolumeMountWatcherWin::RetrieveInfoForDeviceAndAdd,
	removable_devices[i], GetDeviceDetailsCallback(),
	weak_factory_.GetWeakPtr()));
	}
	}

	// static
	void VolumeMountWatcherWin::RetrieveInfoForDeviceAndAdd(
	const base::FilePath& device_path,
	const GetDeviceDetailsCallbackType& get_device_details_callback,
	base::WeakPtr<VolumeMountWatcherWin> volume_watcher) {
	StorageInfo info;
	if (!get_device_details_callback.Run(device_path, &info)) {
	base::PostTaskWithTraits(
	FROM_HERE, {BrowserThread::UI},
	base::BindOnce(&VolumeMountWatcherWin::DeviceCheckComplete,
	volume_watcher, device_path));
	return;
	}

	base::PostTaskWithTraits(
	FROM_HERE, {BrowserThread::UI},
	base::BindOnce(&VolumeMountWatcherWin::HandleDeviceAttachEventOnUIThread,
	volume_watcher, device_path, info));
	}

	void VolumeMountWatcherWin::DeviceCheckComplete(
	const base::FilePath& device_path) {
	DCHECK_CURRENTLY_ON(BrowserThread::UI);
	pending_device_checks_.erase(device_path);

	if (pending_device_checks_.empty()) {
	if (notifications_)
	notifications_->MarkInitialized();
	}
	}

	VolumeMountWatcherWin::GetAttachedDevicesCallbackType
	VolumeMountWatcherWin::GetAttachedDevicesCallback() const {
	return base::Bind(&GetAttachedDevices);
	}

	VolumeMountWatcherWin::GetDeviceDetailsCallbackType
	VolumeMountWatcherWin::GetDeviceDetailsCallback() const {
	return base::Bind(&GetDeviceDetails);
	}

	bool VolumeMountWatcherWin::GetDeviceInfo(const base::FilePath& device_path,
	StorageInfo* info) const {
	DCHECK_CURRENTLY_ON(BrowserThread::UI);
	DCHECK(info);
	base::FilePath path(device_path);
	MountPointDeviceMetadataMap::const_iterator iter =
	device_metadata_.find(path);
	while (iter == device_metadata_.end() && path.DirName() != path) {
	path = path.DirName();
	iter = device_metadata_.find(path);
	}

	if (iter == device_metadata_.end())
	return false;

	*info = iter->second;
	return true;
	}

	void VolumeMountWatcherWin::OnWindowMessage(UINT event_type, LPARAM data) {
	DCHECK_CURRENTLY_ON(BrowserThread::UI);
	switch (event_type) {
	case DBT_DEVICEARRIVAL: {
	if (IsLogicalVolumeStructure(data)) {
	DWORD unitmask = GetVolumeBitMaskFromBroadcastHeader(data);
	std::vector<base::FilePath> paths;
	for (int i = 0; unitmask; ++i, unitmask >>= 1) {
	if (!(unitmask & 0x01))
	continue;
	paths.push_back(DriveNumberToFilePath(i));
	}
	AddDevicesOnUIThread(paths);
	}
	break;
	}
	case DBT_DEVICEREMOVECOMPLETE: {
	if (IsLogicalVolumeStructure(data)) {
	DWORD unitmask = GetVolumeBitMaskFromBroadcastHeader(data);
	for (int i = 0; unitmask; ++i, unitmask >>= 1) {
	if (!(unitmask & 0x01))
	continue;
	HandleDeviceDetachEventOnUIThread(DriveNumberToFilePath(i).value());
	}
	}
	break;
	}
	}
	}

	void VolumeMountWatcherWin::OnMediaChange(WPARAM wparam, LPARAM lparam) {
	if (lparam == SHCNE_MEDIAINSERTED \|\| lparam == SHCNE_MEDIAREMOVED) {
	struct _ITEMIDLIST* pidl = reinterpret_cast<struct _ITEMIDLIST*>(
	wparam);
	wchar_t sPath[MAX_PATH];
	if (!SHGetPathFromIDList(pidl, sPath)) {
	DVLOG(1) << "MediaInserted: SHGetPathFromIDList failed";
	return;
	}
	switch (lparam) {
	case SHCNE_MEDIAINSERTED: {
	std::vector<base::FilePath> paths;
	paths.push_back(base::FilePath(sPath));
	AddDevicesOnUIThread(paths);
	break;
	}
	case SHCNE_MEDIAREMOVED: {
	HandleDeviceDetachEventOnUIThread(sPath);
	break;
	}
	}
	}
	}

	void VolumeMountWatcherWin::SetNotifications(
	StorageMonitor::Receiver* notifications) {
	notifications_ = notifications;
	}

	VolumeMountWatcherWin::~VolumeMountWatcherWin() {
	weak_factory_.InvalidateWeakPtrs();
	}

	void VolumeMountWatcherWin::HandleDeviceAttachEventOnUIThread(
	const base::FilePath& device_path,
	const StorageInfo& info) {
	DCHECK_CURRENTLY_ON(BrowserThread::UI);

	device_metadata_[device_path] = info;

	if (notifications_)
	notifications_->ProcessAttach(info);

	DeviceCheckComplete(device_path);
	}

	void VolumeMountWatcherWin::HandleDeviceDetachEventOnUIThread(
	const base::string16& device_location) {
	DCHECK_CURRENTLY_ON(BrowserThread::UI);

	MountPointDeviceMetadataMap::const_iterator device_info =
	device_metadata_.find(base::FilePath(device_location));
	// If the device isn't type removable (like a CD), it won't be there.
	if (device_info == device_metadata_.end())
	return;

	if (notifications_)
	notifications_->ProcessDetach(device_info->second.device_id());
	device_metadata_.erase(device_info);
	}

	void VolumeMountWatcherWin::EjectDevice(
	const std::string& device_id,
	base::Callback<void(StorageMonitor::EjectStatus)> callback) {
	DCHECK_CURRENTLY_ON(BrowserThread::UI);
	base::FilePath device = MediaStorageUtil::FindDevicePathById(device_id);
	if (device.empty()) {
	callback.Run(StorageMonitor::EJECT_FAILURE);
	return;
	}
	if (device_metadata_.erase(device) == 0) {
	callback.Run(StorageMonitor::EJECT_FAILURE);
	return;
	}

	device_info_task_runner_->PostTask(
	FROM_HERE, base::BindOnce(&EjectDeviceInThreadPool, device, callback,
	device_info_task_runner_, 0));
	}

	} // namespace storage_monitor