/* -*- Mode: C++; tab-width: 8; indent-tabs-mode: nil; c-basic-offset: 2 -*- */ /* vim: set ts=8 sts=2 et sw=2 tw=80: */ /* This Source Code Form is subject to the terms of the Mozilla Public * License, v. 2.0. If a copy of the MPL was not distributed with this * file, You can obtain one at http://mozilla.org/MPL/2.0/. */ #include "mozilla/ArrayUtils.h" #include "mozilla/DebugOnly.h" #include "mozilla/TextUtils.h" #include "mozilla/UniquePtrExtensions.h" #include "mozilla/Utf8.h" #include "nsCOMPtr.h" #include "nsMemory.h" #include "GeckoProfiler.h" #include "nsLocalFile.h" #include "nsLocalFileCommon.h" #include "nsIDirectoryEnumerator.h" #include "nsNativeCharsetUtils.h" #include "nsSimpleEnumerator.h" #include "prio.h" #include "private/pprio.h" // To get PR_ImportFile #include "nsHashKeys.h" #include "nsString.h" #include "nsReadableUtils.h" #include #include #include #include #include "shellapi.h" #include "shlguid.h" #include #include #include #include #include "prproces.h" #include "prlink.h" #include "mozilla/FilePreferences.h" #include "mozilla/Mutex.h" #include "SpecialSystemDirectory.h" #include "nsTraceRefcnt.h" #include "nsXPCOMCIDInternal.h" #include "nsThreadUtils.h" #include "nsXULAppAPI.h" #include "nsIWindowMediator.h" #include "mozIDOMWindow.h" #include "nsPIDOMWindow.h" #include "nsIWidget.h" #include "mozilla/ShellHeaderOnlyUtils.h" #include "mozilla/WidgetUtils.h" #include "WinUtils.h" using namespace mozilla; using mozilla::FilePreferences::kDevicePathSpecifier; using mozilla::FilePreferences::kPathSeparator; #define CHECK_mWorkingPath() \ do { \ if (mWorkingPath.IsEmpty()) return NS_ERROR_NOT_INITIALIZED; \ } while (0) // CopyFileEx only supports unbuffered I/O in Windows Vista and above #ifndef COPY_FILE_NO_BUFFERING # define COPY_FILE_NO_BUFFERING 0x00001000 #endif #ifndef FILE_ATTRIBUTE_NOT_CONTENT_INDEXED # define FILE_ATTRIBUTE_NOT_CONTENT_INDEXED 0x00002000 #endif #ifndef DRIVE_REMOTE # define DRIVE_REMOTE 4 #endif namespace { nsresult NewLocalFile(const nsAString& aPath, bool aUseDOSDevicePathSyntax, nsIFile** aResult) { RefPtr file = new nsLocalFile(); file->SetUseDOSDevicePathSyntax(aUseDOSDevicePathSyntax); if (!aPath.IsEmpty()) { nsresult rv = file->InitWithPath(aPath); if (NS_FAILED(rv)) { return rv; } } file.forget(aResult); return NS_OK; } } // anonymous namespace static HWND GetMostRecentNavigatorHWND() { nsresult rv; nsCOMPtr winMediator( do_GetService(NS_WINDOWMEDIATOR_CONTRACTID, &rv)); if (NS_FAILED(rv)) { return nullptr; } nsCOMPtr navWin; rv = winMediator->GetMostRecentWindow(u"navigator:browser", getter_AddRefs(navWin)); if (NS_FAILED(rv) || !navWin) { return nullptr; } nsPIDOMWindowOuter* win = nsPIDOMWindowOuter::From(navWin); nsCOMPtr widget = widget::WidgetUtils::DOMWindowToWidget(win); if (!widget) { return nullptr; } return reinterpret_cast(widget->GetNativeData(NS_NATIVE_WINDOW)); } nsresult nsLocalFile::RevealFile(const nsString& aResolvedPath) { MOZ_ASSERT(!NS_IsMainThread(), "Don't run on the main thread"); DWORD attributes = GetFileAttributesW(aResolvedPath.get()); if (INVALID_FILE_ATTRIBUTES == attributes) { return NS_ERROR_FILE_INVALID_PATH; } HRESULT hr; if (attributes & FILE_ATTRIBUTE_DIRECTORY) { // We have a directory so we should open the directory itself. LPITEMIDLIST dir = ILCreateFromPathW(aResolvedPath.get()); if (!dir) { return NS_ERROR_FAILURE; } LPCITEMIDLIST selection[] = {dir}; UINT count = ArrayLength(selection); // Perform the open of the directory. hr = SHOpenFolderAndSelectItems(dir, count, selection, 0); CoTaskMemFree(dir); } else { int32_t len = aResolvedPath.Length(); // We don't currently handle UNC long paths of the form \\?\ anywhere so // this should be fine. if (len > MAX_PATH) { return NS_ERROR_FILE_INVALID_PATH; } WCHAR parentDirectoryPath[MAX_PATH + 1] = {0}; wcsncpy(parentDirectoryPath, aResolvedPath.get(), MAX_PATH); PathRemoveFileSpecW(parentDirectoryPath); // We have a file so we should open the parent directory. LPITEMIDLIST dir = ILCreateFromPathW(parentDirectoryPath); if (!dir) { return NS_ERROR_FAILURE; } // Set the item in the directory to select to the file we want to reveal. LPITEMIDLIST item = ILCreateFromPathW(aResolvedPath.get()); if (!item) { CoTaskMemFree(dir); return NS_ERROR_FAILURE; } LPCITEMIDLIST selection[] = {item}; UINT count = ArrayLength(selection); // Perform the selection of the file. hr = SHOpenFolderAndSelectItems(dir, count, selection, 0); CoTaskMemFree(dir); CoTaskMemFree(item); } return SUCCEEDED(hr) ? NS_OK : NS_ERROR_FAILURE; } class nsDriveEnumerator : public nsSimpleEnumerator, public nsIDirectoryEnumerator { public: explicit nsDriveEnumerator(bool aUseDOSDevicePathSyntax); NS_DECL_ISUPPORTS_INHERITED NS_DECL_NSISIMPLEENUMERATOR NS_FORWARD_NSISIMPLEENUMERATORBASE(nsSimpleEnumerator::) nsresult Init(); const nsID& DefaultInterface() override { return NS_GET_IID(nsIFile); } NS_IMETHOD GetNextFile(nsIFile** aResult) override { bool hasMore = false; nsresult rv = HasMoreElements(&hasMore); if (NS_FAILED(rv) || !hasMore) { return rv; } nsCOMPtr next; rv = GetNext(getter_AddRefs(next)); NS_ENSURE_SUCCESS(rv, rv); nsCOMPtr result = do_QueryInterface(next); result.forget(aResult); return NS_OK; } NS_IMETHOD Close() override { return NS_OK; } private: virtual ~nsDriveEnumerator(); /* mDrives stores the null-separated drive names. * Init sets them. * HasMoreElements checks mStartOfCurrentDrive. * GetNext advances mStartOfCurrentDrive. */ nsString mDrives; nsAString::const_iterator mStartOfCurrentDrive; nsAString::const_iterator mEndOfDrivesString; const bool mUseDOSDevicePathSyntax; }; //----------------------------------------------------------------------------- // static helper functions //----------------------------------------------------------------------------- /** * While not comprehensive, this will map many common Windows error codes to a * corresponding nsresult. If an unmapped error is encountered, the hex error * code will be logged to stderr. Error codes, names, and descriptions can be * found at the following MSDN page: * https://docs.microsoft.com/en-us/windows/win32/debug/system-error-codes */ static nsresult ConvertWinError(DWORD aWinErr) { nsresult rv; switch (aWinErr) { case ERROR_FILE_NOT_FOUND: case ERROR_PATH_NOT_FOUND: case ERROR_INVALID_DRIVE: case ERROR_NOT_READY: rv = NS_ERROR_FILE_NOT_FOUND; break; case ERROR_ACCESS_DENIED: case ERROR_NOT_SAME_DEVICE: rv = NS_ERROR_FILE_ACCESS_DENIED; break; case ERROR_SHARING_VIOLATION: // CreateFile without sharing flags case ERROR_LOCK_VIOLATION: // LockFile, LockFileEx rv = NS_ERROR_FILE_IS_LOCKED; break; case ERROR_NOT_ENOUGH_MEMORY: case ERROR_INVALID_BLOCK: case ERROR_INVALID_HANDLE: case ERROR_ARENA_TRASHED: rv = NS_ERROR_OUT_OF_MEMORY; break; case ERROR_DIR_NOT_EMPTY: case ERROR_CURRENT_DIRECTORY: rv = NS_ERROR_FILE_DIR_NOT_EMPTY; break; case ERROR_WRITE_PROTECT: rv = NS_ERROR_FILE_READ_ONLY; break; case ERROR_HANDLE_DISK_FULL: rv = NS_ERROR_FILE_TOO_BIG; break; case ERROR_FILE_EXISTS: case ERROR_ALREADY_EXISTS: case ERROR_CANNOT_MAKE: rv = NS_ERROR_FILE_ALREADY_EXISTS; break; case ERROR_FILENAME_EXCED_RANGE: rv = NS_ERROR_FILE_NAME_TOO_LONG; break; case ERROR_DIRECTORY: rv = NS_ERROR_FILE_NOT_DIRECTORY; break; case 0: rv = NS_OK; break; default: printf_stderr( "ConvertWinError received an unrecognized WinError: 0x%" PRIx32 "\n", static_cast(aWinErr)); MOZ_ASSERT((aWinErr & 0xFFFF) == aWinErr); rv = NS_ERROR_GENERATE_FAILURE(NS_ERROR_MODULE_WIN32, aWinErr & 0xFFFF); break; } return rv; } // as suggested in the MSDN documentation on SetFilePointer static __int64 MyFileSeek64(HANDLE aHandle, __int64 aDistance, DWORD aMoveMethod) { LARGE_INTEGER li; li.QuadPart = aDistance; li.LowPart = SetFilePointer(aHandle, li.LowPart, &li.HighPart, aMoveMethod); if (li.LowPart == INVALID_SET_FILE_POINTER && GetLastError() != NO_ERROR) { li.QuadPart = -1; } return li.QuadPart; } // Check whether a path is a volume root. Expects paths to be \-terminated. static bool IsRootPath(const nsAString& aPath) { // Easy cases first: if (aPath.Last() != L'\\') { return false; } if (StringEndsWith(aPath, u":\\"_ns)) { return true; } nsAString::const_iterator begin, end; aPath.BeginReading(begin); aPath.EndReading(end); // We know we've got a trailing slash, skip that: end--; // Find the next last slash: if (RFindInReadable(u"\\"_ns, begin, end)) { // Reset iterator: aPath.EndReading(end); end--; auto lastSegment = Substring(++begin, end); if (lastSegment.IsEmpty()) { return false; } // Check if we end with e.g. "c$", a drive letter in UNC or network shares if (lastSegment.Last() == L'$' && lastSegment.Length() == 2 && IsAsciiAlpha(lastSegment.First())) { return true; } // Volume GUID paths: if (StringBeginsWith(lastSegment, u"Volume{"_ns) && lastSegment.Last() == L'}') { return true; } } return false; } static auto kSpecialNTFSFilesInRoot = { u"$MFT"_ns, u"$MFTMirr"_ns, u"$LogFile"_ns, u"$Volume"_ns, u"$AttrDef"_ns, u"$Bitmap"_ns, u"$Boot"_ns, u"$BadClus"_ns, u"$Secure"_ns, u"$UpCase"_ns, u"$Extend"_ns}; static bool IsSpecialNTFSPath(const nsAString& aFilePath) { nsAString::const_iterator begin, end; aFilePath.BeginReading(begin); aFilePath.EndReading(end); auto iter = begin; // Early exit if there's no '$' (common case) if (!FindCharInReadable(L'$', iter, end)) { return false; } iter = begin; // Any use of ':$' is illegal in filenames anyway; while we support some // ADS stuff (ie ":Zone.Identifier"), none of them use the ':$' syntax: if (FindInReadable(u":$"_ns, iter, end)) { return true; } auto normalized = mozilla::MakeUniqueFallible(MAX_PATH); if (!normalized) { return true; } auto flatPath = PromiseFlatString(aFilePath); auto fullPathRV = GetFullPathNameW(flatPath.get(), MAX_PATH - 1, normalized.get(), nullptr); if (fullPathRV == 0 || fullPathRV > MAX_PATH - 1) { return false; } nsString normalizedPath(normalized.get()); normalizedPath.BeginReading(begin); normalizedPath.EndReading(end); iter = begin; auto kDelimiters = u"\\:"_ns; while (iter != end && FindCharInReadable(L'$', iter, end)) { for (auto str : kSpecialNTFSFilesInRoot) { if (StringBeginsWith(Substring(iter, end), str, nsCaseInsensitiveStringComparator)) { // If we're enclosed by separators or the beginning/end of the string, // this is one of the special files. Check if we're on a volume root. auto iterCopy = iter; iterCopy.advance(str.Length()); // We check for both \ and : here because the filename could be // followd by a colon and a stream name/type, which shouldn't affect // our check: if (iterCopy == end || kDelimiters.Contains(*iterCopy)) { iterCopy = iter; // At the start of this path component, we don't need to care about // colons: we would have caught those in the check for `:$` above. if (iterCopy == begin || *(--iterCopy) == L'\\') { return IsRootPath(Substring(begin, iter)); } } } } iter++; } return false; } //----------------------------------------------------------------------------- // We need the following three definitions to make |OpenFile| convert a file // handle to an NSPR file descriptor correctly when |O_APPEND| flag is // specified. It is defined in a private header of NSPR (primpl.h) we can't // include. As a temporary workaround until we decide how to extend // |PR_ImportFile|, we define it here. Currently, |_PR_HAVE_PEEK_BUFFER| // and |PR_STRICT_ADDR_LEN| are not defined for the 'w95'-dependent portion // of NSPR so that fields of |PRFilePrivate| #ifdef'd by them are not copied. // Similarly, |_MDFileDesc| is taken from nsprpub/pr/include/md/_win95.h. // In an unlikely case we switch to 'NT'-dependent NSPR AND this temporary // workaround last beyond the switch, |PRFilePrivate| and |_MDFileDesc| // need to be changed to match the definitions for WinNT. //----------------------------------------------------------------------------- typedef enum { _PR_TRI_TRUE = 1, _PR_TRI_FALSE = 0, _PR_TRI_UNKNOWN = -1 } _PRTriStateBool; struct _MDFileDesc { PROsfd osfd; }; struct PRFilePrivate { int32_t state; bool nonblocking; _PRTriStateBool inheritable; PRFileDesc* next; int lockCount; /* 0: not locked * -1: a native lockfile call is in progress * > 0: # times the file is locked */ bool appendMode; _MDFileDesc md; }; //----------------------------------------------------------------------------- // Six static methods defined below (OpenFile, FileTimeToPRTime, GetFileInfo, // OpenDir, CloseDir, ReadDir) should go away once the corresponding // UTF-16 APIs are implemented on all the supported platforms (or at least // Windows 9x/ME) in NSPR. Currently, they're only implemented on // Windows NT4 or later. (bug 330665) //----------------------------------------------------------------------------- // copied from nsprpub/pr/src/{io/prfile.c | md/windows/w95io.c} : // PR_Open and _PR_MD_OPEN nsresult OpenFile(const nsString& aName, int aOsflags, int aMode, bool aShareDelete, PRFileDesc** aFd) { int32_t access = 0; int32_t shareMode = FILE_SHARE_READ | FILE_SHARE_WRITE; int32_t disposition = 0; int32_t attributes = 0; if (aShareDelete) { shareMode |= FILE_SHARE_DELETE; } if (aOsflags & PR_SYNC) { attributes = FILE_FLAG_WRITE_THROUGH; } if (aOsflags & PR_RDONLY || aOsflags & PR_RDWR) { access |= GENERIC_READ; } if (aOsflags & PR_WRONLY || aOsflags & PR_RDWR) { access |= GENERIC_WRITE; } if (aOsflags & PR_CREATE_FILE && aOsflags & PR_EXCL) { disposition = CREATE_NEW; } else if (aOsflags & PR_CREATE_FILE) { if (aOsflags & PR_TRUNCATE) { disposition = CREATE_ALWAYS; } else { disposition = OPEN_ALWAYS; } } else { if (aOsflags & PR_TRUNCATE) { disposition = TRUNCATE_EXISTING; } else { disposition = OPEN_EXISTING; } } if (aOsflags & nsIFile::DELETE_ON_CLOSE) { attributes |= FILE_FLAG_DELETE_ON_CLOSE; } if (aOsflags & nsIFile::OS_READAHEAD) { attributes |= FILE_FLAG_SEQUENTIAL_SCAN; } // If no write permissions are requested, and if we are possibly creating // the file, then set the new file as read only. // The flag has no effect if we happen to open the file. if (!(aMode & (PR_IWUSR | PR_IWGRP | PR_IWOTH)) && disposition != OPEN_EXISTING) { attributes |= FILE_ATTRIBUTE_READONLY; } HANDLE file = ::CreateFileW(aName.get(), access, shareMode, nullptr, disposition, attributes, nullptr); if (file == INVALID_HANDLE_VALUE) { *aFd = nullptr; return ConvertWinError(GetLastError()); } *aFd = PR_ImportFile((PROsfd)file); if (*aFd) { // On Windows, _PR_HAVE_O_APPEND is not defined so that we have to // add it manually. (see |PR_Open| in nsprpub/pr/src/io/prfile.c) (*aFd)->secret->appendMode = (PR_APPEND & aOsflags) ? true : false; return NS_OK; } nsresult rv = NS_ErrorAccordingToNSPR(); CloseHandle(file); return rv; } // copied from nsprpub/pr/src/{io/prfile.c | md/windows/w95io.c} : // PR_FileTimeToPRTime and _PR_FileTimeToPRTime static void FileTimeToPRTime(const FILETIME* aFiletime, PRTime* aPrtm) { #ifdef __GNUC__ const PRTime _pr_filetime_offset = 116444736000000000LL; #else const PRTime _pr_filetime_offset = 116444736000000000i64; #endif MOZ_ASSERT(sizeof(FILETIME) == sizeof(PRTime)); ::CopyMemory(aPrtm, aFiletime, sizeof(PRTime)); #ifdef __GNUC__ *aPrtm = (*aPrtm - _pr_filetime_offset) / 10LL; #else *aPrtm = (*aPrtm - _pr_filetime_offset) / 10i64; #endif } // copied from nsprpub/pr/src/{io/prfile.c | md/windows/w95io.c} with some // changes : PR_GetFileInfo64, _PR_MD_GETFILEINFO64 static nsresult GetFileInfo(const nsString& aName, PRFileInfo64* aInfo) { if (aName.IsEmpty()) { return NS_ERROR_INVALID_ARG; } // Checking u"?*" for the file path excluding the kDevicePathSpecifier. // ToDo: Check if checking "?" for the file path is still needed. const int32_t offset = StringBeginsWith(aName, kDevicePathSpecifier) ? kDevicePathSpecifier.Length() : 0; if (aName.FindCharInSet(u"?*", offset) != kNotFound) { return NS_ERROR_INVALID_ARG; } WIN32_FILE_ATTRIBUTE_DATA fileData; if (!::GetFileAttributesExW(aName.get(), GetFileExInfoStandard, &fileData)) { return ConvertWinError(GetLastError()); } if (fileData.dwFileAttributes & FILE_ATTRIBUTE_REPARSE_POINT) { aInfo->type = PR_FILE_OTHER; } else if (fileData.dwFileAttributes & FILE_ATTRIBUTE_DIRECTORY) { aInfo->type = PR_FILE_DIRECTORY; } else { aInfo->type = PR_FILE_FILE; } aInfo->size = fileData.nFileSizeHigh; aInfo->size = (aInfo->size << 32) + fileData.nFileSizeLow; FileTimeToPRTime(&fileData.ftLastWriteTime, &aInfo->modifyTime); if (0 == fileData.ftCreationTime.dwLowDateTime && 0 == fileData.ftCreationTime.dwHighDateTime) { aInfo->creationTime = aInfo->modifyTime; } else { FileTimeToPRTime(&fileData.ftCreationTime, &aInfo->creationTime); } return NS_OK; } struct nsDir { HANDLE handle; WIN32_FIND_DATAW data; bool firstEntry; }; static nsresult OpenDir(const nsString& aName, nsDir** aDir) { if (NS_WARN_IF(!aDir)) { return NS_ERROR_INVALID_ARG; } *aDir = nullptr; nsDir* d = new nsDir(); nsAutoString filename(aName); // If |aName| ends in a slash or backslash, do not append another backslash. if (filename.Last() == L'/' || filename.Last() == L'\\') { filename.Append('*'); } else { filename.AppendLiteral("\\*"); } filename.ReplaceChar(L'/', L'\\'); // FindFirstFileW Will have a last error of ERROR_DIRECTORY if // \* is passed in. If \* is passed in then // ERROR_PATH_NOT_FOUND will be the last error. d->handle = ::FindFirstFileW(filename.get(), &(d->data)); if (d->handle == INVALID_HANDLE_VALUE) { delete d; return ConvertWinError(GetLastError()); } d->firstEntry = true; *aDir = d; return NS_OK; } static nsresult ReadDir(nsDir* aDir, PRDirFlags aFlags, nsString& aName) { aName.Truncate(); if (NS_WARN_IF(!aDir)) { return NS_ERROR_INVALID_ARG; } while (1) { BOOL rv; if (aDir->firstEntry) { aDir->firstEntry = false; rv = 1; } else { rv = ::FindNextFileW(aDir->handle, &(aDir->data)); } if (rv == 0) { break; } const wchar_t* fileName; fileName = (aDir)->data.cFileName; if ((aFlags & PR_SKIP_DOT) && (fileName[0] == L'.') && (fileName[1] == L'\0')) { continue; } if ((aFlags & PR_SKIP_DOT_DOT) && (fileName[0] == L'.') && (fileName[1] == L'.') && (fileName[2] == L'\0')) { continue; } DWORD attrib = aDir->data.dwFileAttributes; if ((aFlags & PR_SKIP_HIDDEN) && (attrib & FILE_ATTRIBUTE_HIDDEN)) { continue; } aName = fileName; return NS_OK; } DWORD err = GetLastError(); return err == ERROR_NO_MORE_FILES ? NS_OK : ConvertWinError(err); } static nsresult CloseDir(nsDir*& aDir) { if (NS_WARN_IF(!aDir)) { return NS_ERROR_INVALID_ARG; } BOOL isOk = FindClose(aDir->handle); delete aDir; aDir = nullptr; return isOk ? NS_OK : ConvertWinError(GetLastError()); } //----------------------------------------------------------------------------- // nsDirEnumerator //----------------------------------------------------------------------------- class nsDirEnumerator final : public nsSimpleEnumerator, public nsIDirectoryEnumerator { private: ~nsDirEnumerator() { Close(); } public: NS_DECL_ISUPPORTS_INHERITED NS_FORWARD_NSISIMPLEENUMERATORBASE(nsSimpleEnumerator::) nsDirEnumerator() : mDir(nullptr) {} const nsID& DefaultInterface() override { return NS_GET_IID(nsIFile); } nsresult Init(nsIFile* aParent) { nsAutoString filepath; aParent->GetTarget(filepath); if (filepath.IsEmpty()) { aParent->GetPath(filepath); } if (filepath.IsEmpty()) { return NS_ERROR_UNEXPECTED; } // IsDirectory is not needed here because OpenDir will return // NS_ERROR_FILE_NOT_DIRECTORY if the passed in path is a file. nsresult rv = OpenDir(filepath, &mDir); if (NS_FAILED(rv)) { return rv; } mParent = aParent; return NS_OK; } NS_IMETHOD HasMoreElements(bool* aResult) override { nsresult rv; if (!mNext && mDir) { nsString name; rv = ReadDir(mDir, PR_SKIP_BOTH, name); if (NS_FAILED(rv)) { return rv; } if (name.IsEmpty()) { // end of dir entries rv = CloseDir(mDir); if (NS_FAILED(rv)) { return rv; } *aResult = false; return NS_OK; } nsCOMPtr file; rv = mParent->Clone(getter_AddRefs(file)); if (NS_FAILED(rv)) { return rv; } rv = file->Append(name); if (NS_FAILED(rv)) { return rv; } mNext = file.forget(); } *aResult = mNext != nullptr; if (!*aResult) { Close(); } return NS_OK; } NS_IMETHOD GetNext(nsISupports** aResult) override { nsresult rv; bool hasMore; rv = HasMoreElements(&hasMore); if (NS_FAILED(rv)) { return rv; } if (!hasMore) { return NS_ERROR_FAILURE; } mNext.forget(aResult); return NS_OK; } NS_IMETHOD GetNextFile(nsIFile** aResult) override { *aResult = nullptr; bool hasMore = false; nsresult rv = HasMoreElements(&hasMore); if (NS_FAILED(rv) || !hasMore) { return rv; } mNext.forget(aResult); return NS_OK; } NS_IMETHOD Close() override { if (mDir) { nsresult rv = CloseDir(mDir); NS_ASSERTION(NS_SUCCEEDED(rv), "close failed"); if (NS_FAILED(rv)) { return NS_ERROR_FAILURE; } } return NS_OK; } protected: nsDir* mDir; nsCOMPtr mParent; nsCOMPtr mNext; }; NS_IMPL_ISUPPORTS_INHERITED(nsDirEnumerator, nsSimpleEnumerator, nsIDirectoryEnumerator) //----------------------------------------------------------------------------- // nsLocalFile //----------------------------------------------------------------------------- nsLocalFile::nsLocalFile() : mDirty(true), mResolveDirty(true), mUseDOSDevicePathSyntax(false) {} nsLocalFile::nsLocalFile(const nsAString& aFilePath) : mUseDOSDevicePathSyntax(false) { InitWithPath(aFilePath); } nsresult nsLocalFile::nsLocalFileConstructor(nsISupports* aOuter, const nsIID& aIID, void** aInstancePtr) { if (NS_WARN_IF(!aInstancePtr)) { return NS_ERROR_INVALID_ARG; } if (NS_WARN_IF(aOuter)) { return NS_ERROR_NO_AGGREGATION; } nsLocalFile* inst = new nsLocalFile(); nsresult rv = inst->QueryInterface(aIID, aInstancePtr); if (NS_FAILED(rv)) { delete inst; return rv; } return NS_OK; } //----------------------------------------------------------------------------- // nsLocalFile::nsISupports //----------------------------------------------------------------------------- NS_IMPL_ISUPPORTS(nsLocalFile, nsIFile, nsILocalFileWin) //----------------------------------------------------------------------------- // nsLocalFile //----------------------------------------------------------------------------- nsLocalFile::nsLocalFile(const nsLocalFile& aOther) : mDirty(true), mResolveDirty(true), mUseDOSDevicePathSyntax(aOther.mUseDOSDevicePathSyntax), mWorkingPath(aOther.mWorkingPath) {} nsresult nsLocalFile::ResolveSymlink() { std::wstring workingPath(mWorkingPath.Data()); if (!widget::WinUtils::ResolveJunctionPointsAndSymLinks(workingPath)) { return NS_ERROR_FAILURE; } mResolvedPath.Assign(workingPath.c_str(), workingPath.length()); return NS_OK; } // Resolve any shortcuts and stat the resolved path. After a successful return // the path is guaranteed valid and the members of mFileInfo64 can be used. nsresult nsLocalFile::ResolveAndStat() { // if we aren't dirty then we are already done if (!mDirty) { return NS_OK; } AUTO_PROFILER_LABEL("nsLocalFile::ResolveAndStat", OTHER); // we can't resolve/stat anything that isn't a valid NSPR addressable path if (mWorkingPath.IsEmpty()) { return NS_ERROR_FILE_INVALID_PATH; } // this is usually correct mResolvedPath.Assign(mWorkingPath); // Make sure root paths have a trailing slash. nsAutoString nsprPath(mWorkingPath); if (mWorkingPath.Length() == 2 && mWorkingPath.CharAt(1) == u':') { nsprPath.Append('\\'); } // first we will see if the working path exists. If it doesn't then // there is nothing more that can be done nsresult rv = GetFileInfo(nsprPath, &mFileInfo64); if (NS_FAILED(rv)) { return rv; } if (mFileInfo64.type != PR_FILE_OTHER) { mResolveDirty = false; mDirty = false; return NS_OK; } // OTHER from GetFileInfo currently means a symlink rv = ResolveSymlink(); // Even if it fails we need to have the resolved path equal to working path // for those functions that always use the resolved path. if (NS_FAILED(rv)) { mResolvedPath.Assign(mWorkingPath); return rv; } mResolveDirty = false; // get the details of the resolved path rv = GetFileInfo(mResolvedPath, &mFileInfo64); if (NS_FAILED(rv)) { return rv; } mDirty = false; return NS_OK; } /** * Fills the mResolvedPath member variable with the file or symlink target * if follow symlinks is on. This is a copy of the Resolve parts from * ResolveAndStat. ResolveAndStat is much slower though because of the stat. * * @return NS_OK on success. */ nsresult nsLocalFile::Resolve() { // if we aren't dirty then we are already done if (!mResolveDirty) { return NS_OK; } // we can't resolve/stat anything that isn't a valid NSPR addressable path if (mWorkingPath.IsEmpty()) { return NS_ERROR_FILE_INVALID_PATH; } // this is usually correct mResolvedPath.Assign(mWorkingPath); // TODO: Implement symlink support mResolveDirty = false; return NS_OK; } //----------------------------------------------------------------------------- // nsLocalFile::nsIFile //----------------------------------------------------------------------------- NS_IMETHODIMP nsLocalFile::Clone(nsIFile** aFile) { // Just copy-construct ourselves RefPtr file = new nsLocalFile(*this); file.forget(aFile); return NS_OK; } NS_IMETHODIMP nsLocalFile::InitWithFile(nsIFile* aFile) { if (NS_WARN_IF(!aFile)) { return NS_ERROR_INVALID_ARG; } nsAutoString path; aFile->GetPath(path); if (path.IsEmpty()) { return NS_ERROR_INVALID_ARG; } return InitWithPath(path); } NS_IMETHODIMP nsLocalFile::InitWithPath(const nsAString& aFilePath) { MakeDirty(); nsAString::const_iterator begin, end; aFilePath.BeginReading(begin); aFilePath.EndReading(end); // input string must not be empty if (begin == end) { return NS_ERROR_FAILURE; } char16_t firstChar = *begin; char16_t secondChar = *(++begin); // just do a sanity check. if it has any forward slashes, it is not a Native // path on windows. Also, it must have a colon at after the first char. if (FindCharInReadable(L'/', begin, end)) { return NS_ERROR_FILE_UNRECOGNIZED_PATH; } if (FilePreferences::IsBlockedUNCPath(aFilePath)) { return NS_ERROR_FILE_ACCESS_DENIED; } if (secondChar != L':' && (secondChar != L'\\' || firstChar != L'\\')) { return NS_ERROR_FILE_UNRECOGNIZED_PATH; } if (secondChar == L':') { // Make sure we have a valid drive, later code assumes the drive letter // is a single char a-z or A-Z. if (PathGetDriveNumberW(aFilePath.Data()) == -1) { return NS_ERROR_FILE_UNRECOGNIZED_PATH; } } if (IsSpecialNTFSPath(aFilePath)) { return NS_ERROR_FILE_UNRECOGNIZED_PATH; } mWorkingPath = aFilePath; // kill any trailing '\' if (mWorkingPath.Last() == L'\\') { mWorkingPath.Truncate(mWorkingPath.Length() - 1); } // Bug 1626514: make sure that we don't end up with multiple prefixes. // Prepend the "\\?\" prefix if the useDOSDevicePathSyntax is set and the path // starts with a disk designator and backslash. if (mUseDOSDevicePathSyntax && FilePreferences::StartsWithDiskDesignatorAndBackslash(mWorkingPath)) { mWorkingPath = kDevicePathSpecifier + mWorkingPath; } return NS_OK; } // Strip a handler command string of its quotes and parameters. static void CleanupHandlerPath(nsString& aPath) { // Example command strings passed into this routine: // 1) C:\Program Files\Company\some.exe -foo -bar // 2) C:\Program Files\Company\some.dll // 3) C:\Windows\some.dll,-foo -bar // 4) C:\Windows\some.cpl,-foo -bar int32_t lastCommaPos = aPath.RFindChar(','); if (lastCommaPos != kNotFound) aPath.Truncate(lastCommaPos); aPath.Append(' '); // case insensitive int32_t index = aPath.Find(".exe ", true); if (index == kNotFound) index = aPath.Find(".dll ", true); if (index == kNotFound) index = aPath.Find(".cpl ", true); if (index != kNotFound) aPath.Truncate(index + 4); aPath.Trim(" ", true, true); } // Strip the windows host process bootstrap executable rundll32.exe // from a handler's command string if it exists. static void StripRundll32(nsString& aCommandString) { // Example rundll formats: // C:\Windows\System32\rundll32.exe "path to dll" // rundll32.exe "path to dll" // C:\Windows\System32\rundll32.exe "path to dll", var var // rundll32.exe "path to dll", var var constexpr auto rundllSegment = u"rundll32.exe "_ns; constexpr auto rundllSegmentShort = u"rundll32 "_ns; // case insensitive int32_t strLen = rundllSegment.Length(); int32_t index = aCommandString.Find(rundllSegment, true); if (index == kNotFound) { strLen = rundllSegmentShort.Length(); index = aCommandString.Find(rundllSegmentShort, true); } if (index != kNotFound) { uint32_t rundllSegmentLength = index + strLen; aCommandString.Cut(0, rundllSegmentLength); } } // Returns the fully qualified path to an application handler based on // a parameterized command string. Note this routine should not be used // to launch the associated application as it strips parameters and // rundll.exe from the string. Designed for retrieving display information // on a particular handler. /* static */ bool nsLocalFile::CleanupCmdHandlerPath(nsAString& aCommandHandler) { nsAutoString handlerCommand(aCommandHandler); // Straight command path: // // %SystemRoot%\system32\NOTEPAD.EXE var // "C:\Program Files\iTunes\iTunes.exe" var var // C:\Program Files\iTunes\iTunes.exe var var // // Example rundll handlers: // // rundll32.exe "%ProgramFiles%\Win...ery\PhotoViewer.dll", var var // rundll32.exe "%ProgramFiles%\Windows Photo Gallery\PhotoViewer.dll" // C:\Windows\System32\rundll32.exe "path to dll", var var // %SystemRoot%\System32\rundll32.exe "%ProgramFiles%\Win...ery\Photo // Viewer.dll", var var // Expand environment variables so we have full path strings. uint32_t bufLength = ::ExpandEnvironmentStringsW(handlerCommand.get(), nullptr, 0); if (bufLength == 0) // Error return false; auto destination = mozilla::MakeUniqueFallible(bufLength); if (!destination) return false; if (!::ExpandEnvironmentStringsW(handlerCommand.get(), destination.get(), bufLength)) return false; handlerCommand.Assign(destination.get()); // Remove quotes around paths handlerCommand.StripChars("\""); // Strip windows host process bootstrap so we can get to the actual // handler. StripRundll32(handlerCommand); // Trim any command parameters so that we have a native path we can // initialize a local file with. CleanupHandlerPath(handlerCommand); aCommandHandler.Assign(handlerCommand); return true; } NS_IMETHODIMP nsLocalFile::InitWithCommandLine(const nsAString& aCommandLine) { nsAutoString commandLine(aCommandLine); if (!CleanupCmdHandlerPath(commandLine)) { return NS_ERROR_FILE_UNRECOGNIZED_PATH; } return InitWithPath(commandLine); } NS_IMETHODIMP nsLocalFile::OpenNSPRFileDesc(int32_t aFlags, int32_t aMode, PRFileDesc** aResult) { nsresult rv = OpenNSPRFileDescMaybeShareDelete(aFlags, aMode, false, aResult); if (NS_FAILED(rv)) { return rv; } return NS_OK; } NS_IMETHODIMP nsLocalFile::OpenANSIFileDesc(const char* aMode, FILE** aResult) { *aResult = _wfopen(mWorkingPath.get(), NS_ConvertASCIItoUTF16(aMode).get()); if (*aResult) { return NS_OK; } return NS_ERROR_FAILURE; } static nsresult do_create(nsIFile* aFile, const nsString& aPath, uint32_t aAttributes) { PRFileDesc* file; nsresult rv = OpenFile(aPath, PR_RDONLY | PR_CREATE_FILE | PR_APPEND | PR_EXCL, aAttributes, false, &file); if (file) { PR_Close(file); } if (rv == NS_ERROR_FILE_ACCESS_DENIED) { // need to return already-exists for directories (bug 452217) bool isdir; if (NS_SUCCEEDED(aFile->IsDirectory(&isdir)) && isdir) { rv = NS_ERROR_FILE_ALREADY_EXISTS; } } return rv; } static nsresult do_mkdir(nsIFile*, const nsString& aPath, uint32_t) { if (!::CreateDirectoryW(aPath.get(), nullptr)) { return ConvertWinError(GetLastError()); } return NS_OK; } NS_IMETHODIMP nsLocalFile::Create(uint32_t aType, uint32_t aAttributes) { if (aType != NORMAL_FILE_TYPE && aType != DIRECTORY_TYPE) { return NS_ERROR_FILE_UNKNOWN_TYPE; } auto* createFunc = (aType == NORMAL_FILE_TYPE ? do_create : do_mkdir); nsresult rv = createFunc(this, mWorkingPath, aAttributes); if (NS_SUCCEEDED(rv) || NS_ERROR_FILE_ALREADY_EXISTS == rv) { return rv; } // create directories to target // // A given local file can be either one of these forms: // // - normal: X:\some\path\on\this\drive // ^--- start here // // - UNC path: \\machine\volume\some\path\on\this\drive // ^--- start here // // Skip the first 'X:\' for the first form, and skip the first full // '\\machine\volume\' segment for the second form. wchar_t* path = char16ptr_t(mWorkingPath.BeginWriting()); if (path[0] == L'\\' && path[1] == L'\\') { // dealing with a UNC path here; skip past '\\machine\' path = wcschr(path + 2, L'\\'); if (!path) { return NS_ERROR_FILE_INVALID_PATH; } ++path; } // search for first slash after the drive (or volume) name wchar_t* slash = wcschr(path, L'\\'); nsresult directoryCreateError = NS_OK; if (slash) { // skip the first '\\' ++slash; slash = wcschr(slash, L'\\'); while (slash) { *slash = L'\0'; if (!::CreateDirectoryW(mWorkingPath.get(), nullptr)) { rv = ConvertWinError(GetLastError()); if (NS_ERROR_FILE_NOT_FOUND == rv && NS_ERROR_FILE_ACCESS_DENIED == directoryCreateError) { // If a previous CreateDirectory failed due to access, return that. return NS_ERROR_FILE_ACCESS_DENIED; } // perhaps the base path already exists, or perhaps we don't have // permissions to create the directory. NOTE: access denied could // occur on a parent directory even though it exists. else if (rv != NS_ERROR_FILE_ALREADY_EXISTS && rv != NS_ERROR_FILE_ACCESS_DENIED) { return rv; } directoryCreateError = rv; } *slash = L'\\'; ++slash; slash = wcschr(slash, L'\\'); } } // If our last CreateDirectory failed due to access, return that. if (NS_ERROR_FILE_ACCESS_DENIED == directoryCreateError) { return directoryCreateError; } return createFunc(this, mWorkingPath, aAttributes); } NS_IMETHODIMP nsLocalFile::Append(const nsAString& aNode) { // append this path, multiple components are not permitted return AppendInternal(PromiseFlatString(aNode), false); } NS_IMETHODIMP nsLocalFile::AppendRelativePath(const nsAString& aNode) { // append this path, multiple components are permitted return AppendInternal(PromiseFlatString(aNode), true); } nsresult nsLocalFile::AppendInternal(const nsString& aNode, bool aMultipleComponents) { if (aNode.IsEmpty()) { return NS_OK; } // check the relative path for validity if (aNode.First() == L'\\' || // can't start with an '\' aNode.Contains(L'/') || // can't contain / aNode.EqualsASCII("..")) { // can't be .. return NS_ERROR_FILE_UNRECOGNIZED_PATH; } if (aMultipleComponents) { // can't contain .. as a path component. Ensure that the valid components // "foo..foo", "..foo", and "foo.." are not falsely detected, // but the invalid paths "..\", "foo\..", "foo\..\foo", // "..\foo", etc are. constexpr auto doubleDot = u"\\.."_ns; nsAString::const_iterator start, end, offset; aNode.BeginReading(start); aNode.EndReading(end); offset = end; while (FindInReadable(doubleDot, start, offset)) { if (offset == end || *offset == L'\\') { return NS_ERROR_FILE_UNRECOGNIZED_PATH; } start = offset; offset = end; } // catches the remaining cases of prefixes if (StringBeginsWith(aNode, u"..\\"_ns)) { return NS_ERROR_FILE_UNRECOGNIZED_PATH; } } // single components can't contain '\' else if (aNode.Contains(L'\\')) { return NS_ERROR_FILE_UNRECOGNIZED_PATH; } MakeDirty(); mWorkingPath.Append('\\'); mWorkingPath.Append(aNode); if (IsSpecialNTFSPath(mWorkingPath)) { // Revert changes to mWorkingPath: mWorkingPath.SetLength(mWorkingPath.Length() - aNode.Length() - 1); return NS_ERROR_FILE_UNRECOGNIZED_PATH; } return NS_OK; } nsresult nsLocalFile::OpenNSPRFileDescMaybeShareDelete(int32_t aFlags, int32_t aMode, bool aShareDelete, PRFileDesc** aResult) { return OpenFile(mWorkingPath, aFlags, aMode, aShareDelete, aResult); } #define TOUPPER(u) (((u) >= L'a' && (u) <= L'z') ? (u) - (L'a' - L'A') : (u)) NS_IMETHODIMP nsLocalFile::Normalize() { // XXX See bug 187957 comment 18 for possible problems with this // implementation. if (mWorkingPath.IsEmpty()) { return NS_OK; } nsAutoString path(mWorkingPath); // find the index of the root backslash for the path. Everything before // this is considered fully normalized and cannot be ascended beyond // using ".." For a local drive this is the first slash (e.g. "c:\"). // For a UNC path it is the slash following the share name // (e.g. "\\server\share\"). int32_t rootIdx = 2; // default to local drive if (path.First() == L'\\') { // if a share then calculate the rootIdx rootIdx = path.FindChar(L'\\', 2); // skip \\ in front of the server if (rootIdx == kNotFound) { return NS_OK; // already normalized } rootIdx = path.FindChar(L'\\', rootIdx + 1); if (rootIdx == kNotFound) { return NS_OK; // already normalized } } else if (path.CharAt(rootIdx) != L'\\') { // The path has been specified relative to the current working directory // for that drive. To normalize it, the current working directory for // that drive needs to be inserted before the supplied relative path // which will provide an absolute path (and the rootIdx will still be 2). WCHAR cwd[MAX_PATH]; WCHAR* pcwd = cwd; int drive = TOUPPER(path.First()) - 'A' + 1; /* We need to worry about IPH, for details read bug 419326. * _getdrives - http://msdn2.microsoft.com/en-us/library/xdhk0xd2.aspx * uses a bitmask, bit 0 is 'a:' * _chdrive - http://msdn2.microsoft.com/en-us/library/0d1409hb.aspx * _getdcwd - http://msdn2.microsoft.com/en-us/library/7t2zk3s4.aspx * take an int, 1 is 'a:'. * * Because of this, we need to do some math. Subtract 1 to convert from * _chdrive/_getdcwd format to _getdrives drive numbering. * Shift left x bits to convert from integer indexing to bitfield indexing. * And of course, we need to find out if the drive is in the bitmask. * * If we're really unlucky, we can still lose, but only if the user * manages to eject the drive between our call to _getdrives() and * our *calls* to _wgetdcwd. */ if (!((1 << (drive - 1)) & _getdrives())) { return NS_ERROR_FILE_INVALID_PATH; } if (!_wgetdcwd(drive, pcwd, MAX_PATH)) { pcwd = _wgetdcwd(drive, 0, 0); } if (!pcwd) { return NS_ERROR_OUT_OF_MEMORY; } nsAutoString currentDir(pcwd); if (pcwd != cwd) { free(pcwd); } if (currentDir.Last() == '\\') { path.Replace(0, 2, currentDir); } else { path.Replace(0, 2, currentDir + u"\\"_ns); } } MOZ_ASSERT(0 < rootIdx && rootIdx < (int32_t)path.Length(), "rootIdx is invalid"); MOZ_ASSERT(path.CharAt(rootIdx) == '\\', "rootIdx is invalid"); // if there is nothing following the root path then it is already normalized if (rootIdx + 1 == (int32_t)path.Length()) { return NS_OK; } // assign the root const char16_t* pathBuffer = path.get(); // simplify access to the buffer mWorkingPath.SetCapacity(path.Length()); // it won't ever grow longer mWorkingPath.Assign(pathBuffer, rootIdx); // Normalize the path components. The actions taken are: // // "\\" condense to single backslash // "." remove from path // ".." up a directory // "..." remove from path (any number of dots > 2) // // The last form is something that Windows 95 and 98 supported and // is a shortcut for changing up multiple directories. Windows XP // and ilk ignore it in a path, as is done here. int32_t len, begin, end = rootIdx; while (end < (int32_t)path.Length()) { // find the current segment (text between the backslashes) to // be examined, this will set the following variables: // begin == index of first char in segment // end == index 1 char after last char in segment // len == length of segment begin = end + 1; end = path.FindChar('\\', begin); if (end == kNotFound) { end = path.Length(); } len = end - begin; // ignore double backslashes if (len == 0) { continue; } // len != 0, and interesting paths always begin with a dot if (pathBuffer[begin] == '.') { // ignore single dots if (len == 1) { continue; } // handle multiple dots if (len >= 2 && pathBuffer[begin + 1] == L'.') { // back up a path component on double dot if (len == 2) { int32_t prev = mWorkingPath.RFindChar('\\'); if (prev >= rootIdx) { mWorkingPath.Truncate(prev); } continue; } // length is > 2 and the first two characters are dots. // if the rest of the string is dots, then ignore it. int idx = len - 1; for (; idx >= 2; --idx) { if (pathBuffer[begin + idx] != L'.') { break; } } // this is true if the loop above didn't break // and all characters in this segment are dots. if (idx < 2) { continue; } } } // add the current component to the path, including the preceding backslash mWorkingPath.Append(pathBuffer + begin - 1, len + 1); } // kill trailing dots and spaces. int32_t filePathLen = mWorkingPath.Length() - 1; while (filePathLen > 0 && (mWorkingPath[filePathLen] == L' ' || mWorkingPath[filePathLen] == L'.')) { mWorkingPath.Truncate(filePathLen--); } MakeDirty(); return NS_OK; } NS_IMETHODIMP nsLocalFile::GetLeafName(nsAString& aLeafName) { aLeafName.Truncate(); if (mWorkingPath.IsEmpty()) { return NS_ERROR_FILE_UNRECOGNIZED_PATH; } int32_t offset = mWorkingPath.RFindChar(L'\\'); // if the working path is just a node without any lashes. if (offset == kNotFound) { aLeafName = mWorkingPath; } else { aLeafName = Substring(mWorkingPath, offset + 1); } return NS_OK; } NS_IMETHODIMP nsLocalFile::SetLeafName(const nsAString& aLeafName) { MakeDirty(); if (mWorkingPath.IsEmpty()) { return NS_ERROR_FILE_UNRECOGNIZED_PATH; } // cannot use nsCString::RFindChar() due to 0x5c problem int32_t offset = mWorkingPath.RFindChar(L'\\'); nsString newDir; if (offset) { newDir = Substring(mWorkingPath, 0, offset + 1) + aLeafName; } else { newDir = mWorkingPath + aLeafName; } if (IsSpecialNTFSPath(newDir)) { return NS_ERROR_FILE_UNRECOGNIZED_PATH; } mWorkingPath.Assign(newDir); return NS_OK; } NS_IMETHODIMP nsLocalFile::GetPath(nsAString& aResult) { MOZ_ASSERT_IF( mUseDOSDevicePathSyntax, !FilePreferences::StartsWithDiskDesignatorAndBackslash(mWorkingPath)); aResult = mWorkingPath; return NS_OK; } NS_IMETHODIMP nsLocalFile::GetCanonicalPath(nsAString& aResult) { EnsureShortPath(); aResult.Assign(mShortWorkingPath); return NS_OK; } typedef struct { WORD wLanguage; WORD wCodePage; } LANGANDCODEPAGE; NS_IMETHODIMP nsLocalFile::GetVersionInfoField(const char* aField, nsAString& aResult) { nsresult rv = NS_ERROR_FAILURE; const WCHAR* path = mWorkingPath.get(); DWORD dummy; DWORD size = ::GetFileVersionInfoSizeW(path, &dummy); if (!size) { return rv; } void* ver = moz_xcalloc(size, 1); if (::GetFileVersionInfoW(path, 0, size, ver)) { LANGANDCODEPAGE* translate = nullptr; UINT pageCount; BOOL queryResult = ::VerQueryValueW(ver, L"\\VarFileInfo\\Translation", (void**)&translate, &pageCount); if (queryResult && translate) { for (int32_t i = 0; i < 2; ++i) { wchar_t subBlock[MAX_PATH]; _snwprintf(subBlock, MAX_PATH, L"\\StringFileInfo\\%04x%04x\\%s", (i == 0 ? translate[0].wLanguage : ::GetUserDefaultLangID()), translate[0].wCodePage, NS_ConvertASCIItoUTF16(nsDependentCString(aField)).get()); subBlock[MAX_PATH - 1] = 0; LPVOID value = nullptr; UINT size; queryResult = ::VerQueryValueW(ver, subBlock, &value, &size); if (queryResult && value) { aResult.Assign(static_cast(value)); if (!aResult.IsEmpty()) { rv = NS_OK; break; } } } } } free(ver); return rv; } NS_IMETHODIMP nsLocalFile::OpenNSPRFileDescShareDelete(int32_t aFlags, int32_t aMode, PRFileDesc** aResult) { nsresult rv = OpenNSPRFileDescMaybeShareDelete(aFlags, aMode, true, aResult); if (NS_FAILED(rv)) { return rv; } return NS_OK; } /** * Determines if the drive type for the specified file is rmeote or local. * * @param path The path of the file to check * @param remote Out parameter, on function success holds true if the specified * file path is remote, or false if the file path is local. * @return true on success. The return value implies absolutely nothing about * wether the file is local or remote. */ static bool IsRemoteFilePath(LPCWSTR aPath, bool& aRemote) { // Obtain the parent directory path and make sure it ends with // a trailing backslash. WCHAR dirPath[MAX_PATH + 1] = {0}; wcsncpy(dirPath, aPath, MAX_PATH); if (!PathRemoveFileSpecW(dirPath)) { return false; } size_t len = wcslen(dirPath); // In case the dirPath holds exaclty MAX_PATH and remains unchanged, we // recheck the required length here since we need to terminate it with // a backslash. if (len >= MAX_PATH) { return false; } dirPath[len] = L'\\'; dirPath[len + 1] = L'\0'; UINT driveType = GetDriveTypeW(dirPath); aRemote = driveType == DRIVE_REMOTE; return true; } nsresult nsLocalFile::CopySingleFile(nsIFile* aSourceFile, nsIFile* aDestParent, const nsAString& aNewName, uint32_t aOptions) { nsresult rv = NS_OK; nsAutoString filePath; bool move = aOptions & (Move | Rename); // get the path that we are going to copy to. // Since windows does not know how to auto // resolve shortcuts, we must work with the // target. nsAutoString destPath; rv = aDestParent->GetTarget(destPath); if (NS_FAILED(rv)) { return rv; } destPath.Append('\\'); if (aNewName.IsEmpty()) { nsAutoString aFileName; aSourceFile->GetLeafName(aFileName); destPath.Append(aFileName); } else { destPath.Append(aNewName); } if (aOptions & FollowSymlinks) { rv = aSourceFile->GetTarget(filePath); if (filePath.IsEmpty()) { rv = aSourceFile->GetPath(filePath); } } else { rv = aSourceFile->GetPath(filePath); } if (NS_FAILED(rv)) { return rv; } #ifdef DEBUG nsCOMPtr srcWinFile = do_QueryInterface(aSourceFile); MOZ_ASSERT(srcWinFile); bool srcUseDOSDevicePathSyntax; srcWinFile->GetUseDOSDevicePathSyntax(&srcUseDOSDevicePathSyntax); nsCOMPtr destWinFile = do_QueryInterface(aDestParent); MOZ_ASSERT(destWinFile); bool destUseDOSDevicePathSyntax; destWinFile->GetUseDOSDevicePathSyntax(&destUseDOSDevicePathSyntax); MOZ_ASSERT(srcUseDOSDevicePathSyntax == destUseDOSDevicePathSyntax, "Copy or Move files with different values for " "useDOSDevicePathSyntax would fail"); #endif if (FilePreferences::IsBlockedUNCPath(destPath)) { return NS_ERROR_FILE_ACCESS_DENIED; } int copyOK = 0; if (move) { copyOK = ::MoveFileExW(filePath.get(), destPath.get(), MOVEFILE_REPLACE_EXISTING); } // If we either failed to move the file, or this is a copy, try copying: if (!copyOK && (!move || GetLastError() == ERROR_NOT_SAME_DEVICE)) { // Failed renames here should just return access denied. if (move && (aOptions & Rename)) { return NS_ERROR_FILE_ACCESS_DENIED; } // Pass the flag COPY_FILE_NO_BUFFERING to CopyFileEx as we may be copying // to a SMBV2 remote drive. Without this parameter subsequent append mode // file writes can cause the resultant file to become corrupt. We only need // to do this if the major version of Windows is > 5(Only Windows Vista and // above can support SMBV2). With a 7200RPM hard drive: Copying a 1KB file // with COPY_FILE_NO_BUFFERING takes about 30-60ms. Copying a 1KB file // without COPY_FILE_NO_BUFFERING takes < 1ms. So we only use // COPY_FILE_NO_BUFFERING when we have a remote drive. DWORD dwCopyFlags = COPY_FILE_ALLOW_DECRYPTED_DESTINATION; bool path1Remote, path2Remote; if (!IsRemoteFilePath(filePath.get(), path1Remote) || !IsRemoteFilePath(destPath.get(), path2Remote) || path1Remote || path2Remote) { dwCopyFlags |= COPY_FILE_NO_BUFFERING; } copyOK = ::CopyFileExW(filePath.get(), destPath.get(), nullptr, nullptr, nullptr, dwCopyFlags); if (move && copyOK) { DeleteFileW(filePath.get()); } } if (!copyOK) { // CopyFileEx and MoveFileEx return zero at failure. rv = ConvertWinError(GetLastError()); } else if (move && !(aOptions & SkipNtfsAclReset)) { // Set security permissions to inherit from parent. // Note: propagates to all children: slow for big file trees PACL pOldDACL = nullptr; PSECURITY_DESCRIPTOR pSD = nullptr; ::GetNamedSecurityInfoW((LPWSTR)destPath.get(), SE_FILE_OBJECT, DACL_SECURITY_INFORMATION, nullptr, nullptr, &pOldDACL, nullptr, &pSD); if (pOldDACL) ::SetNamedSecurityInfoW( (LPWSTR)destPath.get(), SE_FILE_OBJECT, DACL_SECURITY_INFORMATION | UNPROTECTED_DACL_SECURITY_INFORMATION, nullptr, nullptr, pOldDACL, nullptr); if (pSD) { LocalFree((HLOCAL)pSD); } } return rv; } nsresult nsLocalFile::CopyMove(nsIFile* aParentDir, const nsAString& aNewName, uint32_t aOptions) { bool move = aOptions & (Move | Rename); bool followSymlinks = aOptions & FollowSymlinks; // If we're not provided with a new parent, we're copying or moving to // another file in the same directory and can safely skip checking if the // destination directory exists: bool targetInSameDirectory = !aParentDir; nsCOMPtr newParentDir = aParentDir; // check to see if this exists, otherwise return an error. // we will check this by resolving. If the user wants us // to follow links, then we are talking about the target, // hence we can use the |FollowSymlinks| option. nsresult rv = ResolveAndStat(); if (NS_FAILED(rv)) { return rv; } if (!newParentDir) { // no parent was specified. We must rename. if (aNewName.IsEmpty()) { return NS_ERROR_INVALID_ARG; } rv = GetParent(getter_AddRefs(newParentDir)); if (NS_FAILED(rv)) { return rv; } } if (!newParentDir) { return NS_ERROR_FILE_DESTINATION_NOT_DIR; } if (!targetInSameDirectory) { // make sure it exists and is a directory. Create it if not there. bool exists = false; rv = newParentDir->Exists(&exists); if (NS_FAILED(rv)) { return rv; } if (!exists) { rv = newParentDir->Create(DIRECTORY_TYPE, 0644); // TODO, what permissions should we use if (NS_FAILED(rv)) { return rv; } } else { bool isDir = false; rv = newParentDir->IsDirectory(&isDir); if (NS_FAILED(rv)) { return rv; } if (!isDir) { if (followSymlinks) { bool isLink = false; rv = newParentDir->IsSymlink(&isLink); if (NS_FAILED(rv)) { return rv; } if (isLink) { nsAutoString target; rv = newParentDir->GetTarget(target); if (NS_FAILED(rv)) { return rv; } nsCOMPtr realDest = new nsLocalFile(); rv = realDest->InitWithPath(target); if (NS_FAILED(rv)) { return rv; } return CopyMove(realDest, aNewName, aOptions); } } else { return NS_ERROR_FILE_DESTINATION_NOT_DIR; } } } } // Try different ways to move/copy files/directories bool done = false; bool isDir = false; rv = IsDirectory(&isDir); if (NS_FAILED(rv)) { return rv; } bool isSymlink = false; rv = IsSymlink(&isSymlink); if (NS_FAILED(rv)) { return rv; } // Try to move the file or directory, or try to copy a single file (or // non-followed symlink) if (move || !isDir || (isSymlink && !followSymlinks)) { // Copy/Move single file, or move a directory if (!aParentDir) { aOptions |= SkipNtfsAclReset; } rv = CopySingleFile(this, newParentDir, aNewName, aOptions); done = NS_SUCCEEDED(rv); // If we are moving a directory and that fails, fallback on directory // enumeration. See bug 231300 for details. if (!done && !(move && isDir)) { return rv; } } // Not able to copy or move directly, so enumerate it if (!done) { // create a new target destination in the new parentDir; nsCOMPtr target; rv = newParentDir->Clone(getter_AddRefs(target)); if (NS_FAILED(rv)) { return rv; } nsAutoString allocatedNewName; if (aNewName.IsEmpty()) { bool isLink = false; rv = IsSymlink(&isLink); if (NS_FAILED(rv)) { return rv; } if (isLink) { nsAutoString temp; rv = GetTarget(temp); if (NS_FAILED(rv)) { return rv; } int32_t offset = temp.RFindChar(L'\\'); if (offset == kNotFound) { allocatedNewName = temp; } else { allocatedNewName = Substring(temp, offset + 1); } } else { GetLeafName(allocatedNewName); // this should be the leaf name of the } } else { allocatedNewName = aNewName; } rv = target->Append(allocatedNewName); if (NS_FAILED(rv)) { return rv; } allocatedNewName.Truncate(); bool exists = false; // check if the destination directory already exists rv = target->Exists(&exists); if (NS_FAILED(rv)) { return rv; } if (!exists) { // if the destination directory cannot be created, return an error rv = target->Create(DIRECTORY_TYPE, 0644); // TODO, what permissions should we use if (NS_FAILED(rv)) { return rv; } } else { // check if the destination directory is writable and empty bool isWritable = false; rv = target->IsWritable(&isWritable); if (NS_FAILED(rv)) { return rv; } if (!isWritable) { return NS_ERROR_FILE_ACCESS_DENIED; } nsCOMPtr targetIterator; rv = target->GetDirectoryEntries(getter_AddRefs(targetIterator)); if (NS_FAILED(rv)) { return rv; } bool more; targetIterator->HasMoreElements(&more); // return error if target directory is not empty if (more) { return NS_ERROR_FILE_DIR_NOT_EMPTY; } } RefPtr dirEnum = new nsDirEnumerator(); rv = dirEnum->Init(this); if (NS_FAILED(rv)) { NS_WARNING("dirEnum initialization failed"); return rv; } nsCOMPtr file; while (NS_SUCCEEDED(dirEnum->GetNextFile(getter_AddRefs(file))) && file) { bool isDir = false; rv = file->IsDirectory(&isDir); if (NS_FAILED(rv)) { return rv; } bool isLink = false; rv = file->IsSymlink(&isLink); if (NS_FAILED(rv)) { return rv; } if (move) { if (followSymlinks) { return NS_ERROR_FAILURE; } rv = file->MoveTo(target, u""_ns); if (NS_FAILED(rv)) { return rv; } } else { if (followSymlinks) { rv = file->CopyToFollowingLinks(target, u""_ns); } else { rv = file->CopyTo(target, u""_ns); } if (NS_FAILED(rv)) { return rv; } } } // we've finished moving all the children of this directory // in the new directory. so now delete the directory // note, we don't need to do a recursive delete. // MoveTo() is recursive. At this point, // we've already moved the children of the current folder // to the new location. nothing should be left in the folder. if (move) { rv = Remove(false /* recursive */); if (NS_FAILED(rv)) { return rv; } } } // If we moved, we want to adjust this. if (move) { MakeDirty(); nsAutoString newParentPath; newParentDir->GetPath(newParentPath); if (newParentPath.IsEmpty()) { return NS_ERROR_FAILURE; } if (aNewName.IsEmpty()) { nsAutoString aFileName; GetLeafName(aFileName); InitWithPath(newParentPath); Append(aFileName); } else { InitWithPath(newParentPath); Append(aNewName); } } return NS_OK; } NS_IMETHODIMP nsLocalFile::CopyTo(nsIFile* aNewParentDir, const nsAString& aNewName) { return CopyMove(aNewParentDir, aNewName, 0); } NS_IMETHODIMP nsLocalFile::CopyToFollowingLinks(nsIFile* aNewParentDir, const nsAString& aNewName) { return CopyMove(aNewParentDir, aNewName, FollowSymlinks); } NS_IMETHODIMP nsLocalFile::MoveTo(nsIFile* aNewParentDir, const nsAString& aNewName) { return CopyMove(aNewParentDir, aNewName, Move); } NS_IMETHODIMP nsLocalFile::MoveToFollowingLinks(nsIFile* aNewParentDir, const nsAString& aNewName) { return CopyMove(aNewParentDir, aNewName, Move | FollowSymlinks); } NS_IMETHODIMP nsLocalFile::RenameTo(nsIFile* aNewParentDir, const nsAString& aNewName) { // If we're not provided with a new parent, we're renaming inside one and // the same directory and can safely skip checking if the destination // directory exists: bool targetInSameDirectory = !aNewParentDir; nsCOMPtr targetParentDir = aNewParentDir; // check to see if this exists, otherwise return an error. // we will check this by resolving. If the user wants us // to follow links, then we are talking about the target, // hence we can use the |followSymlinks| parameter. nsresult rv = ResolveAndStat(); if (NS_FAILED(rv)) { return rv; } if (!targetParentDir) { // no parent was specified. We must rename. if (aNewName.IsEmpty()) { return NS_ERROR_INVALID_ARG; } rv = GetParent(getter_AddRefs(targetParentDir)); if (NS_FAILED(rv)) { return rv; } } if (!targetParentDir) { return NS_ERROR_FILE_DESTINATION_NOT_DIR; } if (!targetInSameDirectory) { // make sure it exists and is a directory. Create it if not there. bool exists = false; rv = targetParentDir->Exists(&exists); if (NS_FAILED(rv)) { return rv; } if (!exists) { rv = targetParentDir->Create(DIRECTORY_TYPE, 0644); if (NS_FAILED(rv)) { return rv; } } else { bool isDir = false; rv = targetParentDir->IsDirectory(&isDir); if (NS_FAILED(rv)) { return rv; } if (!isDir) { return NS_ERROR_FILE_DESTINATION_NOT_DIR; } } } uint32_t options = Rename; if (!aNewParentDir) { options |= SkipNtfsAclReset; } // Move single file, or move a directory return CopySingleFile(this, targetParentDir, aNewName, options); } NS_IMETHODIMP nsLocalFile::RenameToNative(nsIFile* aNewParentDir, const nsACString& aNewName) { nsAutoString tmp; nsresult rv = NS_CopyNativeToUnicode(aNewName, tmp); if (NS_SUCCEEDED(rv)) { return RenameTo(aNewParentDir, tmp); } return rv; } NS_IMETHODIMP nsLocalFile::Load(PRLibrary** aResult) { // Check we are correctly initialized. CHECK_mWorkingPath(); if (NS_WARN_IF(!aResult)) { return NS_ERROR_INVALID_ARG; } #ifdef NS_BUILD_REFCNT_LOGGING nsTraceRefcnt::SetActivityIsLegal(false); #endif PRLibSpec libSpec; libSpec.value.pathname_u = mWorkingPath.get(); libSpec.type = PR_LibSpec_PathnameU; *aResult = PR_LoadLibraryWithFlags(libSpec, 0); #ifdef NS_BUILD_REFCNT_LOGGING nsTraceRefcnt::SetActivityIsLegal(true); #endif if (*aResult) { return NS_OK; } return NS_ERROR_NULL_POINTER; } NS_IMETHODIMP nsLocalFile::Remove(bool aRecursive) { // NOTE: // // if the working path points to a shortcut, then we will only // delete the shortcut itself. even if the shortcut points to // a directory, we will not recurse into that directory or // delete that directory itself. likewise, if the shortcut // points to a normal file, we will not delete the real file. // this is done to be consistent with the other platforms that // behave this way. we do this even if the followLinks attribute // is set to true. this helps protect against misuse that could // lead to security bugs (e.g., bug 210588). // // Since shortcut files are no longer permitted to be used as unix-like // symlinks interspersed in the path (e.g. "c:/file.lnk/foo/bar.txt") // this processing is a lot simpler. Even if the shortcut file is // pointing to a directory, only the mWorkingPath value is used and so // only the shortcut file will be deleted. // Check we are correctly initialized. CHECK_mWorkingPath(); nsresult rv = NS_OK; bool isLink = false; rv = IsSymlink(&isLink); if (NS_FAILED(rv)) { return rv; } // only check to see if we have a directory if it isn't a link bool isDir = false; if (!isLink) { rv = IsDirectory(&isDir); if (NS_FAILED(rv)) { return rv; } } if (isDir) { if (aRecursive) { RefPtr dirEnum = new nsDirEnumerator(); rv = dirEnum->Init(this); if (NS_FAILED(rv)) { return rv; } bool more = false; while (NS_SUCCEEDED(dirEnum->HasMoreElements(&more)) && more) { nsCOMPtr item; dirEnum->GetNext(getter_AddRefs(item)); nsCOMPtr file = do_QueryInterface(item); if (file) { file->Remove(aRecursive); } } } if (RemoveDirectoryW(mWorkingPath.get()) == 0) { return ConvertWinError(GetLastError()); } } else { if (DeleteFileW(mWorkingPath.get()) == 0) { return ConvertWinError(GetLastError()); } } MakeDirty(); return rv; } NS_IMETHODIMP nsLocalFile::GetLastModifiedTime(PRTime* aLastModifiedTime) { // Check we are correctly initialized. CHECK_mWorkingPath(); if (NS_WARN_IF(!aLastModifiedTime)) { return NS_ERROR_INVALID_ARG; } // get the modified time of the target as determined by mFollowSymlinks // If true, then this will be for the target of the shortcut file, // otherwise it will be for the shortcut file itself (i.e. the same // results as GetLastModifiedTimeOfLink) nsresult rv = ResolveAndStat(); if (NS_FAILED(rv)) { return rv; } // microseconds -> milliseconds *aLastModifiedTime = mFileInfo64.modifyTime / PR_USEC_PER_MSEC; return NS_OK; } NS_IMETHODIMP nsLocalFile::GetLastModifiedTimeOfLink(PRTime* aLastModifiedTime) { // Check we are correctly initialized. CHECK_mWorkingPath(); if (NS_WARN_IF(!aLastModifiedTime)) { return NS_ERROR_INVALID_ARG; } // The caller is assumed to have already called IsSymlink // and to have found that this file is a link. PRFileInfo64 info; nsresult rv = GetFileInfo(mWorkingPath, &info); if (NS_FAILED(rv)) { return rv; } // microseconds -> milliseconds *aLastModifiedTime = info.modifyTime / PR_USEC_PER_MSEC; return NS_OK; } NS_IMETHODIMP nsLocalFile::SetLastModifiedTime(PRTime aLastModifiedTime) { // Check we are correctly initialized. CHECK_mWorkingPath(); nsresult rv = SetModDate(aLastModifiedTime, mWorkingPath.get()); if (NS_SUCCEEDED(rv)) { MakeDirty(); } return rv; } NS_IMETHODIMP nsLocalFile::SetLastModifiedTimeOfLink(PRTime aLastModifiedTime) { return SetLastModifiedTime(aLastModifiedTime); } NS_IMETHODIMP nsLocalFile::GetCreationTime(PRTime* aCreationTime) { CHECK_mWorkingPath(); if (NS_WARN_IF(!aCreationTime)) { return NS_ERROR_INVALID_ARG; } nsresult rv = ResolveAndStat(); NS_ENSURE_SUCCESS(rv, rv); *aCreationTime = mFileInfo64.creationTime / PR_USEC_PER_MSEC; return NS_OK; } NS_IMETHODIMP nsLocalFile::GetCreationTimeOfLink(PRTime* aCreationTime) { CHECK_mWorkingPath(); if (NS_WARN_IF(!aCreationTime)) { return NS_ERROR_INVALID_ARG; } PRFileInfo64 info; nsresult rv = GetFileInfo(mWorkingPath, &info); NS_ENSURE_SUCCESS(rv, rv); *aCreationTime = info.creationTime / PR_USEC_PER_MSEC; return NS_OK; } nsresult nsLocalFile::SetModDate(PRTime aLastModifiedTime, const wchar_t* aFilePath) { // The FILE_FLAG_BACKUP_SEMANTICS is required in order to change the // modification time for directories. HANDLE file = ::CreateFileW(aFilePath, // pointer to name of the file GENERIC_WRITE, // access (write) mode 0, // share mode nullptr, // pointer to security attributes OPEN_EXISTING, // how to create FILE_FLAG_BACKUP_SEMANTICS, // file attributes nullptr); if (file == INVALID_HANDLE_VALUE) { return ConvertWinError(GetLastError()); } FILETIME ft; SYSTEMTIME st; PRExplodedTime pret; // PR_ExplodeTime expects usecs... PR_ExplodeTime(aLastModifiedTime * PR_USEC_PER_MSEC, PR_GMTParameters, &pret); st.wYear = pret.tm_year; st.wMonth = pret.tm_month + 1; // Convert start offset -- Win32: Jan=1; NSPR: Jan=0 st.wDayOfWeek = pret.tm_wday; st.wDay = pret.tm_mday; st.wHour = pret.tm_hour; st.wMinute = pret.tm_min; st.wSecond = pret.tm_sec; st.wMilliseconds = pret.tm_usec / 1000; nsresult rv = NS_OK; // if at least one of these fails... if (!(SystemTimeToFileTime(&st, &ft) != 0 && SetFileTime(file, nullptr, &ft, &ft) != 0)) { rv = ConvertWinError(GetLastError()); } CloseHandle(file); return rv; } NS_IMETHODIMP nsLocalFile::GetPermissions(uint32_t* aPermissions) { if (NS_WARN_IF(!aPermissions)) { return NS_ERROR_INVALID_ARG; } // get the permissions of the target as determined by mFollowSymlinks // If true, then this will be for the target of the shortcut file, // otherwise it will be for the shortcut file itself (i.e. the same // results as GetPermissionsOfLink) nsresult rv = ResolveAndStat(); if (NS_FAILED(rv)) { return rv; } bool isWritable = false; rv = IsWritable(&isWritable); if (NS_FAILED(rv)) { return rv; } bool isExecutable = false; rv = IsExecutable(&isExecutable); if (NS_FAILED(rv)) { return rv; } *aPermissions = PR_IRUSR | PR_IRGRP | PR_IROTH; // all read if (isWritable) { *aPermissions |= PR_IWUSR | PR_IWGRP | PR_IWOTH; // all write } if (isExecutable) { *aPermissions |= PR_IXUSR | PR_IXGRP | PR_IXOTH; // all execute } return NS_OK; } NS_IMETHODIMP nsLocalFile::GetPermissionsOfLink(uint32_t* aPermissions) { // Check we are correctly initialized. CHECK_mWorkingPath(); if (NS_WARN_IF(!aPermissions)) { return NS_ERROR_INVALID_ARG; } // The caller is assumed to have already called IsSymlink // and to have found that this file is a link. It is not // possible for a link file to be executable. DWORD word = ::GetFileAttributesW(mWorkingPath.get()); if (word == INVALID_FILE_ATTRIBUTES) { return NS_ERROR_FILE_INVALID_PATH; } bool isWritable = !(word & FILE_ATTRIBUTE_READONLY); *aPermissions = PR_IRUSR | PR_IRGRP | PR_IROTH; // all read if (isWritable) { *aPermissions |= PR_IWUSR | PR_IWGRP | PR_IWOTH; // all write } return NS_OK; } NS_IMETHODIMP nsLocalFile::SetPermissions(uint32_t aPermissions) { // Check we are correctly initialized. CHECK_mWorkingPath(); // set the permissions of the target as determined by mFollowSymlinks // If true, then this will be for the target of the shortcut file, // otherwise it will be for the shortcut file itself (i.e. the same // results as SetPermissionsOfLink) nsresult rv = Resolve(); if (NS_FAILED(rv)) { return rv; } // windows only knows about the following permissions int mode = 0; if (aPermissions & (PR_IRUSR | PR_IRGRP | PR_IROTH)) { // any read mode |= _S_IREAD; } if (aPermissions & (PR_IWUSR | PR_IWGRP | PR_IWOTH)) { // any write mode |= _S_IWRITE; } if (_wchmod(mResolvedPath.get(), mode) == -1) { return NS_ERROR_FAILURE; } return NS_OK; } NS_IMETHODIMP nsLocalFile::SetPermissionsOfLink(uint32_t aPermissions) { // The caller is assumed to have already called IsSymlink // and to have found that this file is a link. // windows only knows about the following permissions int mode = 0; if (aPermissions & (PR_IRUSR | PR_IRGRP | PR_IROTH)) { // any read mode |= _S_IREAD; } if (aPermissions & (PR_IWUSR | PR_IWGRP | PR_IWOTH)) { // any write mode |= _S_IWRITE; } if (_wchmod(mWorkingPath.get(), mode) == -1) { return NS_ERROR_FAILURE; } return NS_OK; } NS_IMETHODIMP nsLocalFile::GetFileSize(int64_t* aFileSize) { if (NS_WARN_IF(!aFileSize)) { return NS_ERROR_INVALID_ARG; } nsresult rv = ResolveAndStat(); if (NS_FAILED(rv)) { return rv; } *aFileSize = mFileInfo64.size; return NS_OK; } NS_IMETHODIMP nsLocalFile::GetFileSizeOfLink(int64_t* aFileSize) { // Check we are correctly initialized. CHECK_mWorkingPath(); if (NS_WARN_IF(!aFileSize)) { return NS_ERROR_INVALID_ARG; } // The caller is assumed to have already called IsSymlink // and to have found that this file is a link. PRFileInfo64 info; if (NS_FAILED(GetFileInfo(mWorkingPath, &info))) { return NS_ERROR_FILE_INVALID_PATH; } *aFileSize = info.size; return NS_OK; } NS_IMETHODIMP nsLocalFile::SetFileSize(int64_t aFileSize) { // Check we are correctly initialized. CHECK_mWorkingPath(); HANDLE hFile = ::CreateFileW(mWorkingPath.get(), // pointer to name of the file GENERIC_WRITE, // access (write) mode FILE_SHARE_READ, // share mode nullptr, // pointer to security attributes OPEN_EXISTING, // how to create FILE_ATTRIBUTE_NORMAL, // file attributes nullptr); if (hFile == INVALID_HANDLE_VALUE) { return ConvertWinError(GetLastError()); } // seek the file pointer to the new, desired end of file // and then truncate the file at that position nsresult rv = NS_ERROR_FAILURE; aFileSize = MyFileSeek64(hFile, aFileSize, FILE_BEGIN); if (aFileSize != -1 && SetEndOfFile(hFile)) { MakeDirty(); rv = NS_OK; } CloseHandle(hFile); return rv; } NS_IMETHODIMP nsLocalFile::GetDiskSpaceAvailable(int64_t* aDiskSpaceAvailable) { // Check we are correctly initialized. CHECK_mWorkingPath(); if (NS_WARN_IF(!aDiskSpaceAvailable)) { return NS_ERROR_INVALID_ARG; } ResolveAndStat(); if (mFileInfo64.type == PR_FILE_FILE) { // Since GetDiskFreeSpaceExW works only on directories, use the parent. nsCOMPtr parent; if (NS_SUCCEEDED(GetParent(getter_AddRefs(parent))) && parent) { return parent->GetDiskSpaceAvailable(aDiskSpaceAvailable); } } ULARGE_INTEGER liFreeBytesAvailableToCaller, liTotalNumberOfBytes; if (::GetDiskFreeSpaceExW(mResolvedPath.get(), &liFreeBytesAvailableToCaller, &liTotalNumberOfBytes, nullptr)) { *aDiskSpaceAvailable = liFreeBytesAvailableToCaller.QuadPart; return NS_OK; } *aDiskSpaceAvailable = 0; return NS_OK; } NS_IMETHODIMP nsLocalFile::GetParent(nsIFile** aParent) { // Check we are correctly initialized. CHECK_mWorkingPath(); if (NS_WARN_IF(!aParent)) { return NS_ERROR_INVALID_ARG; } // A two-character path must be a drive such as C:, so it has no parent if (mWorkingPath.Length() == 2) { *aParent = nullptr; return NS_OK; } int32_t offset = mWorkingPath.RFindChar(char16_t('\\')); // adding this offset check that was removed in bug 241708 fixes mail // directories that aren't relative to/underneath the profile dir. // e.g., on a different drive. Before you remove them, please make // sure local mail directories that aren't underneath the profile dir work. if (offset == kNotFound) { return NS_ERROR_FILE_UNRECOGNIZED_PATH; } // A path of the form \\NAME is a top-level path and has no parent if (offset == 1 && mWorkingPath[0] == L'\\') { *aParent = nullptr; return NS_OK; } nsAutoString parentPath(mWorkingPath); if (offset > 0) { parentPath.Truncate(offset); } else { parentPath.AssignLiteral("\\\\."); } nsCOMPtr localFile; nsresult rv = NewLocalFile(parentPath, mUseDOSDevicePathSyntax, getter_AddRefs(localFile)); if (NS_FAILED(rv)) { return rv; } localFile.forget(aParent); return NS_OK; } NS_IMETHODIMP nsLocalFile::Exists(bool* aResult) { // Check we are correctly initialized. CHECK_mWorkingPath(); if (NS_WARN_IF(!aResult)) { return NS_ERROR_INVALID_ARG; } *aResult = false; MakeDirty(); nsresult rv = ResolveAndStat(); *aResult = NS_SUCCEEDED(rv) || rv == NS_ERROR_FILE_IS_LOCKED; return NS_OK; } NS_IMETHODIMP nsLocalFile::IsWritable(bool* aIsWritable) { // Check we are correctly initialized. CHECK_mWorkingPath(); // The read-only attribute on a FAT directory only means that it can't // be deleted. It is still possible to modify the contents of the directory. nsresult rv = IsDirectory(aIsWritable); if (rv == NS_ERROR_FILE_ACCESS_DENIED) { *aIsWritable = true; return NS_OK; } else if (rv == NS_ERROR_FILE_IS_LOCKED) { // If the file is normally allowed write access // we should still return that the file is writable. } else if (NS_FAILED(rv)) { return rv; } if (*aIsWritable) { return NS_OK; } // writable if the file doesn't have the readonly attribute rv = HasFileAttribute(FILE_ATTRIBUTE_READONLY, aIsWritable); if (rv == NS_ERROR_FILE_ACCESS_DENIED) { *aIsWritable = false; return NS_OK; } else if (rv == NS_ERROR_FILE_IS_LOCKED) { // If the file is normally allowed write access // we should still return that the file is writable. } else if (NS_FAILED(rv)) { return rv; } *aIsWritable = !*aIsWritable; // If the read only attribute is not set, check to make sure // we can open the file with write access. if (*aIsWritable) { PRFileDesc* file; rv = OpenFile(mResolvedPath, PR_WRONLY, 0, false, &file); if (NS_SUCCEEDED(rv)) { PR_Close(file); } else if (rv == NS_ERROR_FILE_ACCESS_DENIED) { *aIsWritable = false; } else if (rv == NS_ERROR_FILE_IS_LOCKED) { // If it is locked and read only we would have // gotten access denied *aIsWritable = true; } else { return rv; } } return NS_OK; } NS_IMETHODIMP nsLocalFile::IsReadable(bool* aResult) { // Check we are correctly initialized. CHECK_mWorkingPath(); if (NS_WARN_IF(!aResult)) { return NS_ERROR_INVALID_ARG; } *aResult = false; nsresult rv = ResolveAndStat(); if (NS_FAILED(rv)) { return rv; } *aResult = true; return NS_OK; } nsresult nsLocalFile::LookupExtensionIn(const char* const* aExtensionsArray, size_t aArrayLength, bool* aResult) { // Check we are correctly initialized. CHECK_mWorkingPath(); if (NS_WARN_IF(!aResult)) { return NS_ERROR_INVALID_ARG; } *aResult = false; nsresult rv; // only files can be executables bool isFile; rv = IsFile(&isFile); if (NS_FAILED(rv)) { return rv; } if (!isFile) { return NS_OK; } // TODO: shouldn't we be checking mFollowSymlinks here? bool symLink = false; rv = IsSymlink(&symLink); if (NS_FAILED(rv)) { return rv; } nsAutoString path; if (symLink) { GetTarget(path); } else { GetPath(path); } // kill trailing dots and spaces. int32_t filePathLen = path.Length() - 1; while (filePathLen > 0 && (path[filePathLen] == L' ' || path[filePathLen] == L'.')) { path.Truncate(filePathLen--); } // Get extension. int32_t dotIdx = path.RFindChar(char16_t('.')); if (dotIdx != kNotFound) { // Convert extension to lower case. char16_t* p = path.BeginWriting(); for (p += dotIdx + 1; *p; ++p) { *p += (*p >= L'A' && *p <= L'Z') ? 'a' - 'A' : 0; } nsDependentSubstring ext = Substring(path, dotIdx); for (size_t i = 0; i < aArrayLength; ++i) { if (ext.EqualsASCII(aExtensionsArray[i])) { // Found a match. Set result and quit. *aResult = true; break; } } } return NS_OK; } NS_IMETHODIMP nsLocalFile::IsExecutable(bool* aResult) { return LookupExtensionIn(sExecutableExts, ArrayLength(sExecutableExts), aResult); } NS_IMETHODIMP nsLocalFile::IsDirectory(bool* aResult) { return HasFileAttribute(FILE_ATTRIBUTE_DIRECTORY, aResult); } NS_IMETHODIMP nsLocalFile::IsFile(bool* aResult) { nsresult rv = HasFileAttribute(FILE_ATTRIBUTE_DIRECTORY, aResult); if (NS_SUCCEEDED(rv)) { *aResult = !*aResult; } return rv; } NS_IMETHODIMP nsLocalFile::IsHidden(bool* aResult) { return HasFileAttribute(FILE_ATTRIBUTE_HIDDEN, aResult); } nsresult nsLocalFile::HasFileAttribute(DWORD aFileAttrib, bool* aResult) { if (NS_WARN_IF(!aResult)) { return NS_ERROR_INVALID_ARG; } nsresult rv = Resolve(); if (NS_FAILED(rv)) { return rv; } DWORD attributes = GetFileAttributesW(mResolvedPath.get()); if (INVALID_FILE_ATTRIBUTES == attributes) { return ConvertWinError(GetLastError()); } *aResult = ((attributes & aFileAttrib) != 0); return NS_OK; } NS_IMETHODIMP nsLocalFile::IsSymlink(bool* aResult) { // Check we are correctly initialized. CHECK_mWorkingPath(); if (NS_WARN_IF(!aResult)) { return NS_ERROR_INVALID_ARG; } // TODO: Implement symlink support *aResult = false; return NS_OK; } NS_IMETHODIMP nsLocalFile::IsSpecial(bool* aResult) { return HasFileAttribute(FILE_ATTRIBUTE_SYSTEM, aResult); } NS_IMETHODIMP nsLocalFile::Equals(nsIFile* aInFile, bool* aResult) { if (NS_WARN_IF(!aInFile)) { return NS_ERROR_INVALID_ARG; } if (NS_WARN_IF(!aResult)) { return NS_ERROR_INVALID_ARG; } EnsureShortPath(); nsCOMPtr lf(do_QueryInterface(aInFile)); if (!lf) { *aResult = false; return NS_OK; } nsAutoString inFilePath; lf->GetCanonicalPath(inFilePath); bool inUseDOSDevicePathSyntax; lf->GetUseDOSDevicePathSyntax(&inUseDOSDevicePathSyntax); // Remove the prefix for both inFilePath and mShortWorkingPath if the // useDOSDevicePathSyntax from them are not the same. // This is added because of Omnijar. It compare files from different moduals // with itself nsAutoString shortWorkingPath; if (inUseDOSDevicePathSyntax == mUseDOSDevicePathSyntax) { shortWorkingPath = mShortWorkingPath; } else if (inUseDOSDevicePathSyntax && StringBeginsWith(inFilePath, kDevicePathSpecifier)) { MOZ_ASSERT(!StringBeginsWith(mShortWorkingPath, kDevicePathSpecifier)); shortWorkingPath = mShortWorkingPath; inFilePath = Substring(inFilePath, kDevicePathSpecifier.Length()); } else if (mUseDOSDevicePathSyntax && StringBeginsWith(mShortWorkingPath, kDevicePathSpecifier)) { MOZ_ASSERT(!StringBeginsWith(inFilePath, kDevicePathSpecifier)); shortWorkingPath = Substring(mShortWorkingPath, kDevicePathSpecifier.Length()); } // Ok : Win9x *aResult = _wcsicmp(shortWorkingPath.get(), inFilePath.get()) == 0; return NS_OK; } NS_IMETHODIMP nsLocalFile::Contains(nsIFile* aInFile, bool* aResult) { // Check we are correctly initialized. CHECK_mWorkingPath(); *aResult = false; nsAutoString myFilePath; if (NS_FAILED(GetTarget(myFilePath))) { GetPath(myFilePath); } uint32_t myFilePathLen = myFilePath.Length(); nsAutoString inFilePath; if (NS_FAILED(aInFile->GetTarget(inFilePath))) { aInFile->GetPath(inFilePath); } // make sure that the |aInFile|'s path has a trailing separator. if (inFilePath.Length() >= myFilePathLen && inFilePath[myFilePathLen] == L'\\') { if (_wcsnicmp(myFilePath.get(), inFilePath.get(), myFilePathLen) == 0) { *aResult = true; } } return NS_OK; } NS_IMETHODIMP nsLocalFile::GetTarget(nsAString& aResult) { aResult.Truncate(); Resolve(); MOZ_ASSERT_IF( mUseDOSDevicePathSyntax, !FilePreferences::StartsWithDiskDesignatorAndBackslash(mResolvedPath)); aResult = mResolvedPath; return NS_OK; } NS_IMETHODIMP nsLocalFile::GetDirectoryEntriesImpl(nsIDirectoryEnumerator** aEntries) { nsresult rv; *aEntries = nullptr; if (mWorkingPath.EqualsLiteral("\\\\.")) { RefPtr drives = new nsDriveEnumerator(mUseDOSDevicePathSyntax); rv = drives->Init(); if (NS_FAILED(rv)) { return rv; } drives.forget(aEntries); return NS_OK; } RefPtr dirEnum = new nsDirEnumerator(); rv = dirEnum->Init(this); if (NS_FAILED(rv)) { return rv; } dirEnum.forget(aEntries); return NS_OK; } NS_IMETHODIMP nsLocalFile::GetPersistentDescriptor(nsACString& aPersistentDescriptor) { CopyUTF16toUTF8(mWorkingPath, aPersistentDescriptor); return NS_OK; } NS_IMETHODIMP nsLocalFile::SetPersistentDescriptor(const nsACString& aPersistentDescriptor) { if (IsUtf8(aPersistentDescriptor)) { return InitWithPath(NS_ConvertUTF8toUTF16(aPersistentDescriptor)); } else { return InitWithNativePath(aPersistentDescriptor); } } NS_IMETHODIMP nsLocalFile::GetFileAttributesWin(uint32_t* aAttribs) { *aAttribs = 0; DWORD dwAttrs = GetFileAttributesW(mWorkingPath.get()); if (dwAttrs == INVALID_FILE_ATTRIBUTES) { return NS_ERROR_FILE_INVALID_PATH; } if (!(dwAttrs & FILE_ATTRIBUTE_NOT_CONTENT_INDEXED)) { *aAttribs |= WFA_SEARCH_INDEXED; } return NS_OK; } NS_IMETHODIMP nsLocalFile::SetFileAttributesWin(uint32_t aAttribs) { DWORD dwAttrs = GetFileAttributesW(mWorkingPath.get()); if (dwAttrs == INVALID_FILE_ATTRIBUTES) { return NS_ERROR_FILE_INVALID_PATH; } if (aAttribs & WFA_SEARCH_INDEXED) { dwAttrs &= ~FILE_ATTRIBUTE_NOT_CONTENT_INDEXED; } else { dwAttrs |= FILE_ATTRIBUTE_NOT_CONTENT_INDEXED; } if (aAttribs & WFA_READONLY) { dwAttrs |= FILE_ATTRIBUTE_READONLY; } else if ((aAttribs & WFA_READWRITE) && (dwAttrs & FILE_ATTRIBUTE_READONLY)) { dwAttrs &= ~FILE_ATTRIBUTE_READONLY; } if (SetFileAttributesW(mWorkingPath.get(), dwAttrs) == 0) { return NS_ERROR_FAILURE; } return NS_OK; } NS_IMETHODIMP nsLocalFile::GetUseDOSDevicePathSyntax(bool* aUseDOSDevicePathSyntax) { MOZ_ASSERT(aUseDOSDevicePathSyntax); *aUseDOSDevicePathSyntax = mUseDOSDevicePathSyntax; return NS_OK; } NS_IMETHODIMP nsLocalFile::SetUseDOSDevicePathSyntax(bool aUseDOSDevicePathSyntax) { if (mUseDOSDevicePathSyntax == aUseDOSDevicePathSyntax) { return NS_OK; } if (mUseDOSDevicePathSyntax) { if (StringBeginsWith(mWorkingPath, kDevicePathSpecifier)) { MakeDirty(); // Remove the prefix mWorkingPath = Substring(mWorkingPath, kDevicePathSpecifier.Length()); } } else { if (FilePreferences::StartsWithDiskDesignatorAndBackslash(mWorkingPath)) { MakeDirty(); // Prepend the prefix mWorkingPath = kDevicePathSpecifier + mWorkingPath; } } mUseDOSDevicePathSyntax = aUseDOSDevicePathSyntax; return NS_OK; } NS_IMETHODIMP nsLocalFile::Reveal() { // This API should be main thread only MOZ_ASSERT(NS_IsMainThread()); // make sure mResolvedPath is set nsresult rv = Resolve(); if (NS_FAILED(rv) && rv != NS_ERROR_FILE_NOT_FOUND) { return rv; } nsCOMPtr task = NS_NewRunnableFunction("nsLocalFile::Reveal", [path = mResolvedPath]() { MOZ_ASSERT(!NS_IsMainThread(), "Don't run on the main thread"); bool doCoUninitialize = SUCCEEDED(CoInitializeEx( nullptr, COINIT_APARTMENTTHREADED | COINIT_DISABLE_OLE1DDE)); RevealFile(path); if (doCoUninitialize) { CoUninitialize(); } }); return NS_DispatchBackgroundTask(task, nsIEventTarget::DISPATCH_EVENT_MAY_BLOCK); } NS_IMETHODIMP nsLocalFile::Launch() { // This API should be main thread only MOZ_ASSERT(NS_IsMainThread()); // use the app registry name to launch a shell execute.... _bstr_t execPath(mWorkingPath.get()); _variant_t args; // Pass VT_ERROR/DISP_E_PARAMNOTFOUND to omit an optional RPC parameter // to execute a file with the default verb. _variant_t verbDefault(DISP_E_PARAMNOTFOUND, VT_ERROR); _variant_t showCmd(SW_SHOWNORMAL); // Use the directory of the file we're launching as the working // directory. That way if we have a self extracting EXE it won't // suggest to extract to the install directory. wchar_t* workingDirectoryPtr = nullptr; WCHAR workingDirectory[MAX_PATH + 1] = {L'\0'}; wcsncpy(workingDirectory, mWorkingPath.get(), MAX_PATH); if (PathRemoveFileSpecW(workingDirectory)) { workingDirectoryPtr = workingDirectory; } else { NS_WARNING("Could not set working directory for launched file."); } // We have two methods to launch a file: ShellExecuteExW and // ShellExecuteByExplorer. ShellExecuteExW starts a new process as a child // of the current process, while ShellExecuteByExplorer starts a new process // as a child of explorer.exe. // // We prefer launching a process via ShellExecuteByExplorer because // applications may not support the mitigation policies inherited from our // process. For example, Skype for Business does not start correctly with // the PreferSystem32Images policy which is one of the policies we use. // // If ShellExecuteByExplorer fails for some reason e.g. a system without // running explorer.exe or VDI environment like Citrix, we fall back to // ShellExecuteExW which still works in those special environments. // // There is an exception where we go straight to ShellExecuteExW without // trying ShellExecuteByExplorer. When the extension of a downloaded file is // "exe", we prefer security rather than compatibility. // // When a user launches a downloaded executable, the directory containing // the downloaded file may contain a malicious DLL with a common name, which // may have been downloaded before. If the downloaded executable is launched // without the PreferSystem32Images policy, the process can be tricked into // loading the malicious DLL in the same directory if its name is in the // executable's dependent modules. Therefore, we always launch ".exe" // executables via ShellExecuteExW so they inherit our process's mitigation // policies including PreferSystem32Images. // // If the extension is not "exe", then we assume that we are launching an // installed application, and therefore the security risk described above // is lessened, as a malicious DLL is less likely to be installed in the // application's directory. In that case, we attempt to preserve // compatibility and try ShellExecuteByExplorer first. static const char* const onlyExeExt[] = {".exe"}; bool isExecutable; nsresult rv = LookupExtensionIn(onlyExeExt, ArrayLength(onlyExeExt), &isExecutable); if (NS_FAILED(rv)) { isExecutable = false; } // If the file is an executable, go straight to ShellExecuteExW. // Otherwise try ShellExecuteByExplorer first, and if it fails, // run ShellExecuteExW. if (!isExecutable) { mozilla::LauncherVoidResult shellExecuteOk = mozilla::ShellExecuteByExplorer(execPath, args, verbDefault, workingDirectoryPtr, showCmd); if (shellExecuteOk.isOk()) { return NS_OK; } } SHELLEXECUTEINFOW seinfo = {sizeof(SHELLEXECUTEINFOW)}; seinfo.fMask = SEE_MASK_ASYNCOK; seinfo.hwnd = GetMostRecentNavigatorHWND(); seinfo.lpVerb = nullptr; seinfo.lpFile = mWorkingPath.get(); seinfo.lpParameters = nullptr; seinfo.lpDirectory = workingDirectoryPtr; seinfo.nShow = SW_SHOWNORMAL; if (!ShellExecuteExW(&seinfo)) { return NS_ERROR_FILE_EXECUTION_FAILED; } return NS_OK; } nsresult NS_NewLocalFile(const nsAString& aPath, bool aFollowLinks, nsIFile** aResult) { RefPtr file = new nsLocalFile(); if (!aPath.IsEmpty()) { nsresult rv = file->InitWithPath(aPath); if (NS_FAILED(rv)) { return rv; } } file.forget(aResult); return NS_OK; } //----------------------------------------------------------------------------- // Native (lossy) interface //----------------------------------------------------------------------------- NS_IMETHODIMP nsLocalFile::InitWithNativePath(const nsACString& aFilePath) { nsAutoString tmp; nsresult rv = NS_CopyNativeToUnicode(aFilePath, tmp); if (NS_SUCCEEDED(rv)) { return InitWithPath(tmp); } return rv; } NS_IMETHODIMP nsLocalFile::AppendNative(const nsACString& aNode) { nsAutoString tmp; nsresult rv = NS_CopyNativeToUnicode(aNode, tmp); if (NS_SUCCEEDED(rv)) { return Append(tmp); } return rv; } NS_IMETHODIMP nsLocalFile::AppendRelativeNativePath(const nsACString& aNode) { nsAutoString tmp; nsresult rv = NS_CopyNativeToUnicode(aNode, tmp); if (NS_SUCCEEDED(rv)) { return AppendRelativePath(tmp); } return rv; } NS_IMETHODIMP nsLocalFile::GetNativeLeafName(nsACString& aLeafName) { // NS_WARNING("This API is lossy. Use GetLeafName !"); nsAutoString tmp; nsresult rv = GetLeafName(tmp); if (NS_SUCCEEDED(rv)) { rv = NS_CopyUnicodeToNative(tmp, aLeafName); } return rv; } NS_IMETHODIMP nsLocalFile::SetNativeLeafName(const nsACString& aLeafName) { nsAutoString tmp; nsresult rv = NS_CopyNativeToUnicode(aLeafName, tmp); if (NS_SUCCEEDED(rv)) { return SetLeafName(tmp); } return rv; } nsString nsLocalFile::NativePath() { return mWorkingPath; } nsCString nsIFile::HumanReadablePath() { nsString path; DebugOnly rv = GetPath(path); MOZ_ASSERT(NS_SUCCEEDED(rv)); return NS_ConvertUTF16toUTF8(path); } NS_IMETHODIMP nsLocalFile::GetNativeCanonicalPath(nsACString& aResult) { NS_WARNING("This method is lossy. Use GetCanonicalPath !"); EnsureShortPath(); NS_CopyUnicodeToNative(mShortWorkingPath, aResult); return NS_OK; } NS_IMETHODIMP nsLocalFile::CopyToNative(nsIFile* aNewParentDir, const nsACString& aNewName) { // Check we are correctly initialized. CHECK_mWorkingPath(); if (aNewName.IsEmpty()) { return CopyTo(aNewParentDir, u""_ns); } nsAutoString tmp; nsresult rv = NS_CopyNativeToUnicode(aNewName, tmp); if (NS_SUCCEEDED(rv)) { return CopyTo(aNewParentDir, tmp); } return rv; } NS_IMETHODIMP nsLocalFile::CopyToFollowingLinksNative(nsIFile* aNewParentDir, const nsACString& aNewName) { if (aNewName.IsEmpty()) { return CopyToFollowingLinks(aNewParentDir, u""_ns); } nsAutoString tmp; nsresult rv = NS_CopyNativeToUnicode(aNewName, tmp); if (NS_SUCCEEDED(rv)) { return CopyToFollowingLinks(aNewParentDir, tmp); } return rv; } NS_IMETHODIMP nsLocalFile::MoveToNative(nsIFile* aNewParentDir, const nsACString& aNewName) { // Check we are correctly initialized. CHECK_mWorkingPath(); if (aNewName.IsEmpty()) { return MoveTo(aNewParentDir, u""_ns); } nsAutoString tmp; nsresult rv = NS_CopyNativeToUnicode(aNewName, tmp); if (NS_SUCCEEDED(rv)) { return MoveTo(aNewParentDir, tmp); } return rv; } NS_IMETHODIMP nsLocalFile::MoveToFollowingLinksNative(nsIFile* aNewParentDir, const nsACString& aNewName) { // Check we are correctly initialized. CHECK_mWorkingPath(); if (aNewName.IsEmpty()) { return MoveToFollowingLinks(aNewParentDir, u""_ns); } nsAutoString tmp; nsresult rv = NS_CopyNativeToUnicode(aNewName, tmp); if (NS_SUCCEEDED(rv)) { return MoveToFollowingLinks(aNewParentDir, tmp); } return rv; } NS_IMETHODIMP nsLocalFile::GetNativeTarget(nsACString& aResult) { // Check we are correctly initialized. CHECK_mWorkingPath(); NS_WARNING("This API is lossy. Use GetTarget !"); nsAutoString tmp; nsresult rv = GetTarget(tmp); if (NS_SUCCEEDED(rv)) { rv = NS_CopyUnicodeToNative(tmp, aResult); } return rv; } nsresult NS_NewNativeLocalFile(const nsACString& aPath, bool aFollowLinks, nsIFile** aResult) { nsAutoString buf; nsresult rv = NS_CopyNativeToUnicode(aPath, buf); if (NS_FAILED(rv)) { *aResult = nullptr; return rv; } return NS_NewLocalFile(buf, aFollowLinks, aResult); } void nsLocalFile::EnsureShortPath() { if (!mShortWorkingPath.IsEmpty()) { return; } WCHAR shortPath[MAX_PATH + 1]; DWORD lengthNeeded = ::GetShortPathNameW(mWorkingPath.get(), shortPath, ArrayLength(shortPath)); // If an error occurred then lengthNeeded is set to 0 or the length of the // needed buffer including null termination. If it succeeds the number of // wide characters not including null termination is returned. if (lengthNeeded != 0 && lengthNeeded < ArrayLength(shortPath)) { mShortWorkingPath.Assign(shortPath); } else { mShortWorkingPath.Assign(mWorkingPath); } } NS_IMPL_ISUPPORTS_INHERITED(nsDriveEnumerator, nsSimpleEnumerator, nsIDirectoryEnumerator) nsDriveEnumerator::nsDriveEnumerator(bool aUseDOSDevicePathSyntax) : mUseDOSDevicePathSyntax(aUseDOSDevicePathSyntax) {} nsDriveEnumerator::~nsDriveEnumerator() {} nsresult nsDriveEnumerator::Init() { /* If the length passed to GetLogicalDriveStrings is smaller * than the length of the string it would return, it returns * the length required for the string. */ DWORD length = GetLogicalDriveStringsW(0, 0); /* The string is null terminated */ if (!mDrives.SetLength(length + 1, fallible)) { return NS_ERROR_OUT_OF_MEMORY; } if (!GetLogicalDriveStringsW(length, mDrives.get())) { return NS_ERROR_FAILURE; } mDrives.BeginReading(mStartOfCurrentDrive); mDrives.EndReading(mEndOfDrivesString); return NS_OK; } NS_IMETHODIMP nsDriveEnumerator::HasMoreElements(bool* aHasMore) { *aHasMore = *mStartOfCurrentDrive != L'\0'; return NS_OK; } NS_IMETHODIMP nsDriveEnumerator::GetNext(nsISupports** aNext) { /* GetLogicalDrives stored in mDrives is a concatenation * of null terminated strings, followed by a null terminator. * mStartOfCurrentDrive is an iterator pointing at the first * character of the current drive. */ if (*mStartOfCurrentDrive == L'\0') { *aNext = nullptr; return NS_ERROR_FAILURE; } nsAString::const_iterator driveEnd = mStartOfCurrentDrive; FindCharInReadable(L'\0', driveEnd, mEndOfDrivesString); nsString drive(Substring(mStartOfCurrentDrive, driveEnd)); mStartOfCurrentDrive = ++driveEnd; nsIFile* file; nsresult rv = NewLocalFile(drive, mUseDOSDevicePathSyntax, &file); *aNext = file; return rv; }