// Copyright (c) 2012 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 "base/file_util.h" #if defined(OS_WIN) #include #endif #include #include #include "base/file_path.h" #include "base/logging.h" #include "base/stringprintf.h" #include "base/string_piece.h" #include "base/string_util.h" #include "base/utf_string_conversions.h" namespace { const FilePath::CharType kExtensionSeparator = FILE_PATH_LITERAL('.'); // The maximum number of 'uniquified' files we will try to create. // This is used when the filename we're trying to download is already in use, // so we create a new unique filename by appending " (nnn)" before the // extension, where 1 <= nnn <= kMaxUniqueFiles. // Also used by code that cleans up said files. static const int kMaxUniqueFiles = 100; } // namespace namespace file_util { bool g_bug108724_debug = false; bool EndsWithSeparator(const FilePath& path) { FilePath::StringType value = path.value(); if (value.empty()) return false; return FilePath::IsSeparator(value[value.size() - 1]); } bool EnsureEndsWithSeparator(FilePath* path) { if (!DirectoryExists(*path)) return false; if (EndsWithSeparator(*path)) return true; FilePath::StringType& path_str = const_cast(path->value()); path_str.append(&FilePath::kSeparators[0], 1); return true; } void InsertBeforeExtension(FilePath* path, const FilePath::StringType& suffix) { FilePath::StringType& value = const_cast(path->value()); const FilePath::StringType::size_type last_dot = value.rfind(kExtensionSeparator); const FilePath::StringType::size_type last_separator = value.find_last_of(FilePath::StringType(FilePath::kSeparators)); if (last_dot == FilePath::StringType::npos || (last_separator != std::wstring::npos && last_dot < last_separator)) { // The path looks something like "C:\pics.old\jojo" or "C:\pics\jojo". // We should just append the suffix to the entire path. value.append(suffix); return; } value.insert(last_dot, suffix); } bool ContentsEqual(const FilePath& filename1, const FilePath& filename2) { // We open the file in binary format even if they are text files because // we are just comparing that bytes are exactly same in both files and not // doing anything smart with text formatting. std::ifstream file1(filename1.value().c_str(), std::ios::in | std::ios::binary); std::ifstream file2(filename2.value().c_str(), std::ios::in | std::ios::binary); // Even if both files aren't openable (and thus, in some sense, "equal"), // any unusable file yields a result of "false". if (!file1.is_open() || !file2.is_open()) return false; const int BUFFER_SIZE = 2056; char buffer1[BUFFER_SIZE], buffer2[BUFFER_SIZE]; do { file1.read(buffer1, BUFFER_SIZE); file2.read(buffer2, BUFFER_SIZE); if ((file1.eof() != file2.eof()) || (file1.gcount() != file2.gcount()) || (memcmp(buffer1, buffer2, file1.gcount()))) { file1.close(); file2.close(); return false; } } while (!file1.eof() || !file2.eof()); file1.close(); file2.close(); return true; } bool TextContentsEqual(const FilePath& filename1, const FilePath& filename2) { std::ifstream file1(filename1.value().c_str(), std::ios::in); std::ifstream file2(filename2.value().c_str(), std::ios::in); // Even if both files aren't openable (and thus, in some sense, "equal"), // any unusable file yields a result of "false". if (!file1.is_open() || !file2.is_open()) return false; do { std::string line1, line2; getline(file1, line1); getline(file2, line2); // Check for mismatched EOF states, or any error state. if ((file1.eof() != file2.eof()) || file1.bad() || file2.bad()) { return false; } // Trim all '\r' and '\n' characters from the end of the line. std::string::size_type end1 = line1.find_last_not_of("\r\n"); if (end1 == std::string::npos) line1.clear(); else if (end1 + 1 < line1.length()) line1.erase(end1 + 1); std::string::size_type end2 = line2.find_last_not_of("\r\n"); if (end2 == std::string::npos) line2.clear(); else if (end2 + 1 < line2.length()) line2.erase(end2 + 1); if (line1 != line2) return false; } while (!file1.eof() || !file2.eof()); return true; } bool ReadFileToString(const FilePath& path, std::string* contents) { if (path.ReferencesParent()) return false; FILE* file = OpenFile(path, "rb"); if (!file) { return false; } char buf[1 << 16]; size_t len; while ((len = fread(buf, 1, sizeof(buf), file)) > 0) { if (contents) contents->append(buf, len); } CloseFile(file); return true; } bool IsDirectoryEmpty(const FilePath& dir_path) { FileEnumerator files(dir_path, false, FileEnumerator::FILES | FileEnumerator::DIRECTORIES); if (files.Next().value().empty()) return true; return false; } FILE* CreateAndOpenTemporaryFile(FilePath* path) { FilePath directory; if (!GetTempDir(&directory)) return NULL; return CreateAndOpenTemporaryFileInDir(directory, path); } bool GetFileSize(const FilePath& file_path, int64* file_size) { base::PlatformFileInfo info; if (!GetFileInfo(file_path, &info)) return false; *file_size = info.size; return true; } bool IsDot(const FilePath& path) { return FILE_PATH_LITERAL(".") == path.BaseName().value(); } bool IsDotDot(const FilePath& path) { return FILE_PATH_LITERAL("..") == path.BaseName().value(); } bool TouchFile(const FilePath& path, const base::Time& last_accessed, const base::Time& last_modified) { int flags = base::PLATFORM_FILE_OPEN | base::PLATFORM_FILE_WRITE_ATTRIBUTES; #if defined(OS_WIN) // On Windows, FILE_FLAG_BACKUP_SEMANTICS is needed to open a directory. if (DirectoryExists(path)) flags |= base::PLATFORM_FILE_BACKUP_SEMANTICS; #endif // OS_WIN const base::PlatformFile file = base::CreatePlatformFile(path, flags, NULL, NULL); if (file != base::kInvalidPlatformFileValue) { bool result = base::TouchPlatformFile(file, last_accessed, last_modified); base::ClosePlatformFile(file); return result; } return false; } bool SetLastModifiedTime(const FilePath& path, const base::Time& last_modified) { return TouchFile(path, last_modified, last_modified); } bool CloseFile(FILE* file) { if (file == NULL) return true; return fclose(file) == 0; } bool TruncateFile(FILE* file) { if (file == NULL) return false; long current_offset = ftell(file); if (current_offset == -1) return false; #if defined(OS_WIN) int fd = _fileno(file); if (_chsize(fd, current_offset) != 0) return false; #else int fd = fileno(file); if (ftruncate(fd, current_offset) != 0) return false; #endif return true; } int GetUniquePathNumber( const FilePath& path, const FilePath::StringType& suffix) { bool have_suffix = !suffix.empty(); if (!PathExists(path) && (!have_suffix || !PathExists(FilePath(path.value() + suffix)))) { return 0; } FilePath new_path; for (int count = 1; count <= kMaxUniqueFiles; ++count) { new_path = path.InsertBeforeExtensionASCII(StringPrintf(" (%d)", count)); if (!PathExists(new_path) && (!have_suffix || !PathExists(FilePath(new_path.value() + suffix)))) { return count; } } return -1; } bool ContainsPath(const FilePath &parent, const FilePath& child) { FilePath abs_parent = FilePath(parent); FilePath abs_child = FilePath(child); if (!file_util::AbsolutePath(&abs_parent) || !file_util::AbsolutePath(&abs_child)) return false; #if defined(OS_WIN) // file_util::AbsolutePath() does not flatten case on Windows, so we must do // a case-insensitive compare. if (!StartsWith(abs_child.value(), abs_parent.value(), false)) #else if (!StartsWithASCII(abs_child.value(), abs_parent.value(), true)) #endif return false; // file_util::AbsolutePath() normalizes '/' to '\' on Windows, so we only need // to check kSeparators[0]. if (abs_child.value().length() <= abs_parent.value().length() || abs_child.value()[abs_parent.value().length()] != FilePath::kSeparators[0]) return false; return true; } int64 ComputeDirectorySize(const FilePath& root_path) { int64 running_size = 0; FileEnumerator file_iter(root_path, true, FileEnumerator::FILES); for (FilePath current = file_iter.Next(); !current.empty(); current = file_iter.Next()) { FileEnumerator::FindInfo info; file_iter.GetFindInfo(&info); #if defined(OS_WIN) LARGE_INTEGER li = { info.nFileSizeLow, info.nFileSizeHigh }; running_size += li.QuadPart; #else running_size += info.stat.st_size; #endif } return running_size; } int64 ComputeFilesSize(const FilePath& directory, const FilePath::StringType& pattern) { int64 running_size = 0; FileEnumerator file_iter(directory, false, FileEnumerator::FILES, pattern); for (FilePath current = file_iter.Next(); !current.empty(); current = file_iter.Next()) { FileEnumerator::FindInfo info; file_iter.GetFindInfo(&info); #if defined(OS_WIN) LARGE_INTEGER li = { info.nFileSizeLow, info.nFileSizeHigh }; running_size += li.QuadPart; #else running_size += info.stat.st_size; #endif } return running_size; } /////////////////////////////////////////////// // MemoryMappedFile MemoryMappedFile::~MemoryMappedFile() { CloseHandles(); } bool MemoryMappedFile::Initialize(const FilePath& file_name) { if (IsValid()) return false; if (!MapFileToMemory(file_name)) { CloseHandles(); return false; } return true; } bool MemoryMappedFile::Initialize(base::PlatformFile file) { if (IsValid()) return false; file_ = file; if (!MapFileToMemoryInternal()) { CloseHandles(); return false; } return true; } bool MemoryMappedFile::IsValid() const { return data_ != NULL; } bool MemoryMappedFile::MapFileToMemory(const FilePath& file_name) { file_ = base::CreatePlatformFile( file_name, base::PLATFORM_FILE_OPEN | base::PLATFORM_FILE_READ, NULL, NULL); if (file_ == base::kInvalidPlatformFileValue) { DLOG(ERROR) << "Couldn't open " << file_name.value(); return false; } return MapFileToMemoryInternal(); } /////////////////////////////////////////////// // FileEnumerator // // Note: the main logic is in file_util_.cc bool FileEnumerator::ShouldSkip(const FilePath& path) { FilePath::StringType basename = path.BaseName().value(); return IsDot(path) || (IsDotDot(path) && !(INCLUDE_DOT_DOT & file_type_)); } } // namespace