//! Files, and methods and fields to access their metadata. use std::fs; use std::io::Error as IOError; use std::io::Result as IOResult; use std::os::unix::fs::{MetadataExt, PermissionsExt, FileTypeExt}; use std::path::{Path, PathBuf}; use fs::dir::Dir; use fs::fields as f; #[allow(trivial_numeric_casts)] mod modes { use libc; pub type Mode = u32; // The `libc::mode_t` type’s actual type varies, but the value returned // from `metadata.permissions().mode()` is always `u32`. pub const USER_READ: Mode = libc::S_IRUSR as Mode; pub const USER_WRITE: Mode = libc::S_IWUSR as Mode; pub const USER_EXECUTE: Mode = libc::S_IXUSR as Mode; pub const GROUP_READ: Mode = libc::S_IRGRP as Mode; pub const GROUP_WRITE: Mode = libc::S_IWGRP as Mode; pub const GROUP_EXECUTE: Mode = libc::S_IXGRP as Mode; pub const OTHER_READ: Mode = libc::S_IROTH as Mode; pub const OTHER_WRITE: Mode = libc::S_IWOTH as Mode; pub const OTHER_EXECUTE: Mode = libc::S_IXOTH as Mode; } /// A **File** is a wrapper around one of Rust's Path objects, along with /// associated data about the file. /// /// Each file is definitely going to have its filename displayed at least /// once, have its file extension extracted at least once, and have its metadata /// information queried at least once, so it makes sense to do all this at the /// start and hold on to all the information. pub struct File<'dir> { /// The filename portion of this file's path, including the extension. /// /// This is used to compare against certain filenames (such as checking if /// it’s “Makefile” or something) and to highlight only the filename in /// colour when displaying the path. pub name: String, /// The file’s name’s extension, if present, extracted from the name. /// /// This is queried many times over, so it’s worth caching it. pub ext: Option, /// The path that begat this file. /// /// Even though the file's name is extracted, the path needs to be kept /// around, as certain operations involve looking up the file's absolute /// location (such as the Git status, or searching for compiled files). pub path: PathBuf, /// A cached `metadata` call for this file. /// /// This too is queried multiple times, and is *not* cached by the OS, as /// it could easily change between invocations - but exa is so short-lived /// it's better to just cache it. pub metadata: fs::Metadata, /// A reference to the directory that contains this file, if present. /// /// Filenames that get passed in on the command-line directly will have no /// parent directory reference - although they technically have one on the /// filesystem, we'll never need to look at it, so it'll be `None`. /// However, *directories* that get passed in will produce files that /// contain a reference to it, which is used in certain operations (such /// as looking up a file's Git status). pub dir: Option<&'dir Dir>, } impl<'dir> File<'dir> { /// Create a new `File` object from the given `Path`, inside the given /// `Dir`, if appropriate. /// /// This uses `symlink_metadata` instead of `metadata`, which doesn't /// follow symbolic links. pub fn from_path(path: &Path, parent: Option<&'dir Dir>) -> IOResult> { fs::symlink_metadata(path).map(|metadata| File::with_metadata(metadata, path, parent)) } /// Create a new File object from the given metadata result, and other data. pub fn with_metadata(metadata: fs::Metadata, path: &Path, parent: Option<&'dir Dir>) -> File<'dir> { let filename = match path.components().next_back() { Some(comp) => comp.as_os_str().to_string_lossy().to_string(), None => String::new(), }; File { path: path.to_path_buf(), dir: parent, metadata: metadata, ext: ext(path), name: filename, } } /// Whether this file is a directory on the filesystem. pub fn is_directory(&self) -> bool { self.metadata.is_dir() } /// If this file is a directory on the filesystem, then clone its /// `PathBuf` for use in one of our own `Dir` objects, and read a list of /// its contents. /// /// Returns an IO error upon failure, but this shouldn't be used to check /// if a `File` is a directory or not! For that, just use `is_directory()`. pub fn to_dir(&self, scan_for_git: bool) -> IOResult { Dir::read_dir(&*self.path, scan_for_git) } /// Whether this file is a regular file on the filesystem - that is, not a /// directory, a link, or anything else treated specially. pub fn is_file(&self) -> bool { self.metadata.is_file() } /// Whether this file is both a regular file *and* executable for the /// current user. Executable files have different semantics than /// executable directories, and so should be highlighted differently. pub fn is_executable_file(&self) -> bool { let bit = modes::USER_EXECUTE; self.is_file() && (self.metadata.permissions().mode() & bit) == bit } /// Whether this file is a symlink on the filesystem. pub fn is_link(&self) -> bool { self.metadata.file_type().is_symlink() } /// Whether this file is a named pipe on the filesystem. pub fn is_pipe(&self) -> bool { self.metadata.file_type().is_fifo() } /// Whether this file is a char device on the filesystem. pub fn is_char_device(&self) -> bool { self.metadata.file_type().is_char_device() } /// Whether this file is a block device on the filesystem. pub fn is_block_device(&self) -> bool { self.metadata.file_type().is_block_device() } /// Whether this file is a socket on the filesystem. pub fn is_socket(&self) -> bool { self.metadata.file_type().is_socket() } /// Whether this file is a dotfile, based on its name. In Unix, file names /// beginning with a dot represent system or configuration files, and /// should be hidden by default. pub fn is_dotfile(&self) -> bool { self.name.starts_with('.') } /// Assuming the current file is a symlink, follows the link and /// returns a File object from the path the link points to. /// /// If statting the file fails (usually because the file on the /// other end doesn't exist), returns the path to the file /// that should be there. pub fn link_target(&self) -> FileTarget<'dir> { let path = match fs::read_link(&self.path) { Ok(path) => path, Err(e) => return FileTarget::Err(e), }; let (metadata, ext) = { let target_path_ = match self.dir { Some(dir) if dir.path != Path::new(".") => Some(dir.join(&*path)), _ => None }; let target_path = target_path_.as_ref().unwrap_or(&path); // Use plain `metadata` instead of `symlink_metadata` - we *want* to follow links. (fs::metadata(&target_path), ext(target_path)) }; let filename = match path.components().next_back() { Some(comp) => comp.as_os_str().to_string_lossy().to_string(), None => String::new(), }; if let Ok(metadata) = metadata { FileTarget::Ok(File { path: path, dir: self.dir, metadata: metadata, ext: ext, name: filename, }) } else { FileTarget::Broken(path) } } /// This file's number of hard links. /// /// It also reports whether this is both a regular file, and a file with /// multiple links. This is important, because a file with multiple links /// is uncommon, while you can come across directories and other types /// with multiple links much more often. Thus, it should get highlighted /// more attentively. pub fn links(&self) -> f::Links { let count = self.metadata.nlink(); f::Links { count: count, multiple: self.is_file() && count > 1, } } /// This file's inode. pub fn inode(&self) -> f::Inode { f::Inode(self.metadata.ino()) } /// This file's number of filesystem blocks. /// /// (Not the size of each block, which we don't actually report on) pub fn blocks(&self) -> f::Blocks { if self.is_file() || self.is_link() { f::Blocks::Some(self.metadata.blocks()) } else { f::Blocks::None } } /// The ID of the user that own this file. pub fn user(&self) -> f::User { f::User(self.metadata.uid()) } /// The ID of the group that owns this file. pub fn group(&self) -> f::Group { f::Group(self.metadata.gid()) } /// This file's size, if it's a regular file. /// /// For directories, no size is given. Although they do have a size on /// some filesystems, I've never looked at one of those numbers and gained /// any information from it. So it's going to be hidden instead. pub fn size(&self) -> f::Size { if self.is_directory() { f::Size::None } else { f::Size::Some(self.metadata.len()) } } pub fn modified_time(&self) -> f::Time { f::Time(self.metadata.mtime()) } pub fn created_time(&self) -> f::Time { f::Time(self.metadata.ctime()) } pub fn accessed_time(&self) -> f::Time { f::Time(self.metadata.mtime()) } /// This file's 'type'. /// /// This is used in the leftmost column of the permissions column. /// Although the file type can usually be guessed from the colour of the /// file, `ls` puts this character there, so people will expect it. pub fn type_char(&self) -> f::Type { if self.is_file() { f::Type::File } else if self.is_directory() { f::Type::Directory } else if self.is_pipe() { f::Type::Pipe } else if self.is_link() { f::Type::Link } else if self.is_char_device() { f::Type::CharDevice } else if self.is_block_device() { f::Type::BlockDevice } else if self.is_socket() { f::Type::Socket } else { f::Type::Special } } /// This file's permissions, with flags for each bit. /// /// The extended-attribute '@' character that you see in here is in fact /// added in later, to avoid querying the extended attributes more than /// once. (Yes, it's a little hacky.) pub fn permissions(&self) -> f::Permissions { let bits = self.metadata.permissions().mode(); let has_bit = |bit| { bits & bit == bit }; f::Permissions { user_read: has_bit(modes::USER_READ), user_write: has_bit(modes::USER_WRITE), user_execute: has_bit(modes::USER_EXECUTE), group_read: has_bit(modes::GROUP_READ), group_write: has_bit(modes::GROUP_WRITE), group_execute: has_bit(modes::GROUP_EXECUTE), other_read: has_bit(modes::OTHER_READ), other_write: has_bit(modes::OTHER_WRITE), other_execute: has_bit(modes::OTHER_EXECUTE), } } /// Whether this file's extension is any of the strings that get passed in. /// /// This will always return `false` if the file has no extension. pub fn extension_is_one_of(&self, choices: &[&str]) -> bool { match self.ext { Some(ref ext) => choices.contains(&&ext[..]), None => false, } } /// Whether this file's name, including extension, is any of the strings /// that get passed in. pub fn name_is_one_of(&self, choices: &[&str]) -> bool { choices.contains(&&self.name[..]) } /// This file's Git status as two flags: one for staged changes, and the /// other for unstaged changes. /// /// This requires looking at the `git` field of this file's parent /// directory, so will not work if this file has just been passed in on /// the command line. pub fn git_status(&self) -> f::Git { use std::env::current_dir; match self.dir { None => f::Git { staged: f::GitStatus::NotModified, unstaged: f::GitStatus::NotModified }, Some(d) => { let cwd = match current_dir() { Err(_) => Path::new(".").join(&self.path), Ok(dir) => dir.join(&self.path), }; d.git_status(&cwd, self.is_directory()) }, } } } impl<'a> AsRef> for File<'a> { fn as_ref(&self) -> &File<'a> { self } } /// Extract an extension from a file path, if one is present, in lowercase. /// /// The extension is the series of characters after the last dot. This /// deliberately counts dotfiles, so the ".git" folder has the extension "git". /// /// ASCII lowercasing is used because these extensions are only compared /// against a pre-compiled list of extensions which are known to only exist /// within ASCII, so it's alright. fn ext(path: &Path) -> Option { use std::ascii::AsciiExt; let name = match path.file_name() { Some(f) => f.to_string_lossy().to_string(), None => return None, }; name.rfind('.').map(|p| name[p+1..].to_ascii_lowercase()) } /// The result of following a symlink. pub enum FileTarget<'dir> { /// The symlink pointed at a file that exists. Ok(File<'dir>), /// The symlink pointed at a file that does not exist. Holds the path /// where the file would be, if it existed. Broken(PathBuf), /// There was an IO error when following the link. This can happen if the /// file isn’t a link to begin with, but also if, say, we don’t have /// permission to follow it. Err(IOError), } impl<'dir> FileTarget<'dir> { /// Whether this link doesn’t lead to a file, for whatever reason. This /// gets used to determine how to highlight the link in grid views. pub fn is_broken(&self) -> bool { match *self { FileTarget::Ok(_) => false, FileTarget::Broken(_) | FileTarget::Err(_) => true, } } } #[cfg(test)] mod test { use super::ext; use std::path::Path; #[test] fn extension() { assert_eq!(Some("dat".to_string()), ext(Path::new("fester.dat"))) } #[test] fn dotfile() { assert_eq!(Some("vimrc".to_string()), ext(Path::new(".vimrc"))) } #[test] fn no_extension() { assert_eq!(None, ext(Path::new("jarlsberg"))) } }