rust/src/libstd/rt/io/stdio.rs

// Copyright 2013 The Rust Project Developers. See the COPYRIGHT
// file at the top-level directory of this distribution and at
// http://rust-lang.org/COPYRIGHT.
//
// Licensed under the Apache License, Version 2.0 <LICENSE-APACHE or
// http://www.apache.org/licenses/LICENSE-2.0> or the MIT license
// <LICENSE-MIT or http://opensource.org/licenses/MIT>, at your
// option. This file may not be copied, modified, or distributed
// except according to those terms.

/*!

This modules provides bindings to the local event loop's TTY interface, using it
to have synchronous, but non-blocking versions of stdio. These handles can be
inspected for information about terminal dimensions or related information
about the stream or terminal that it is attached to.

# Example

```rust
use std::rt::io;

let mut out = io::stdout();
out.write(bytes!("Hello, world!"));
```

*/

use fmt;
use libc;
use option::{Option, Some, None};
use result::{Ok, Err};
use rt::io::buffered::LineBufferedWriter;
use rt::rtio::{IoFactory, RtioTTY, RtioFileStream, with_local_io,
               CloseAsynchronously};
use super::{Reader, Writer, io_error, IoError, OtherIoError};

// And so begins the tale of acquiring a uv handle to a stdio stream on all
// platforms in all situations. Our story begins by splitting the world into two
// categories, windows and unix. Then one day the creators of unix said let
// there be redirection! And henceforth there was redirection away from the
// console for standard I/O streams.
//
// After this day, the world split into four factions:
//
// 1. Unix with stdout on a terminal.
// 2. Unix with stdout redirected.
// 3. Windows with stdout on a terminal.
// 4. Windows with stdout redirected.
//
// Many years passed, and then one day the nation of libuv decided to unify this
// world. After months of toiling, uv created three ideas: TTY, Pipe, File.
// These three ideas propagated throughout the lands and the four great factions
// decided to settle among them.
//
// The groups of 1, 2, and 3 all worked very hard towards the idea of TTY. Upon
// doing so, they even enhanced themselves further then their Pipe/File
// brethren, becoming the dominant powers.
//
// The group of 4, however, decided to work independently. They abandoned the
// common TTY belief throughout, and even abandoned the fledgling Pipe belief.
// The members of the 4th faction decided to only align themselves with File.
//
// tl;dr; TTY works on everything but when windows stdout is redirected, in that
//        case pipe also doesn't work, but magically file does!
enum StdSource {
    TTY(~RtioTTY),
    File(~RtioFileStream),
}

#[fixed_stack_segment] #[inline(never)]
fn src<T>(fd: libc::c_int, readable: bool, f: &fn(StdSource) -> T) -> T {
    do with_local_io |io| {
        let fd = unsafe { libc::dup(fd) };
        match io.tty_open(fd, readable) {
            Ok(tty) => Some(f(TTY(tty))),
            Err(_) => {
                // It's not really that desirable if these handles are closed
                // synchronously, and because they're squirreled away in a task
                // structure the destructors will be run when the task is
                // attempted to get destroyed. This means that if we run a
                // synchronous destructor we'll attempt to do some scheduling
                // operations which will just result in sadness.
                Some(f(File(io.fs_from_raw_fd(fd, CloseAsynchronously))))
            }
        }
    }.unwrap()
}

/// Creates a new non-blocking handle to the stdin of the current process.
///
/// See `stdout()` for notes about this function.
#[fixed_stack_segment] #[inline(never)]
pub fn stdin() -> StdReader {
    do src(libc::STDIN_FILENO, true) |src| { StdReader { inner: src } }
}

/// Creates a new non-blocking handle to the stdout of the current process.
///
/// Note that this is a fairly expensive operation in that at least one memory
/// allocation is performed. Additionally, this must be called from a runtime
/// task context because the stream returned will be a non-blocking object using
/// the local scheduler to perform the I/O.
pub fn stdout() -> StdWriter {
    do src(libc::STDOUT_FILENO, false) |src| { StdWriter { inner: src } }
}

/// Creates a new non-blocking handle to the stderr of the current process.
///
/// See `stdout()` for notes about this function.
pub fn stderr() -> StdWriter {
    do src(libc::STDERR_FILENO, false) |src| { StdWriter { inner: src } }
}

// Helper to access the local task's stdout handle
//
// Note that this is not a safe function to expose because you can create an
// aliased pointer very easily:
//
//  do with_task_stdout |io1| {
//      do with_task_stdout |io2| {
//          // io1 aliases io2
//      }
//  }
fn with_task_stdout(f: &fn(&mut Writer)) {
    use rt::local::Local;
    use rt::task::Task;

    unsafe {
        // Logging may require scheduling operations, so we can't remove the
        // task from TLS right now, hence the unsafe borrow. Sad.
        let task: *mut Task = Local::unsafe_borrow();

        match (*task).stdout_handle {
            Some(ref mut handle) => f(*handle),
            None => {
                let handle = stdout();
                let mut handle = ~LineBufferedWriter::new(handle) as ~Writer;
                f(handle);
                (*task).stdout_handle = Some(handle);
            }
        }
    }
}

/// Flushes the local task's stdout handle.
///
/// By default, this stream is a line-buffering stream, so flushing may be
/// necessary to ensure that all output is printed to the screen (if there are
/// no newlines printed).
///
/// Note that logging macros do not use this stream. Using the logging macros
/// will emit output to stderr, and while they are line buffered the log
/// messages are always terminated in a newline (no need to flush).
pub fn flush() {
    do with_task_stdout |io| {
        io.flush();
    }
}

/// Prints a string to the stdout of the current process. No newline is emitted
/// after the string is printed.
pub fn print(s: &str) {
    do with_task_stdout |io| {
        io.write(s.as_bytes());
    }
}

/// Prints a string as a line. to the stdout of the current process. A literal
/// `\n` character is printed to the console after the string.
pub fn println(s: &str) {
    do with_task_stdout |io| {
        io.write(s.as_bytes());
        io.write(['\n' as u8]);
    }
}

/// Similar to `print`, but takes a `fmt::Arguments` structure to be compatible
/// with the `format_args!` macro.
pub fn print_args(fmt: &fmt::Arguments) {
    do with_task_stdout |io| {
        fmt::write(io, fmt);
    }
}

/// Similar to `println`, but takes a `fmt::Arguments` structure to be
/// compatible with the `format_args!` macro.
pub fn println_args(fmt: &fmt::Arguments) {
    do with_task_stdout |io| {
        fmt::writeln(io, fmt);
    }
}

/// Representation of a reader of a standard input stream
pub struct StdReader {
    priv inner: StdSource
}

impl Reader for StdReader {
    fn read(&mut self, buf: &mut [u8]) -> Option<uint> {
        let ret = match self.inner {
            TTY(ref mut tty) => tty.read(buf),
            File(ref mut file) => file.read(buf).map(|i| i as uint),
        };
        match ret {
            Ok(amt) => Some(amt as uint),
            Err(e) => {
                io_error::cond.raise(e);
                None
            }
        }
    }

    fn eof(&mut self) -> bool { false }
}

/// Representation of a writer to a standard output stream
pub struct StdWriter {
    priv inner: StdSource
}

impl StdWriter {
    /// Gets the size of this output window, if possible. This is typically used
    /// when the writer is attached to something like a terminal, this is used
    /// to fetch the dimensions of the terminal.
    ///
    /// If successful, returns Some((width, height)).
    ///
    /// # Failure
    ///
    /// This function will raise on the `io_error` condition if an error
    /// happens.
    pub fn winsize(&mut self) -> Option<(int, int)> {
        match self.inner {
            TTY(ref mut tty) => {
                match tty.get_winsize() {
                    Ok(p) => Some(p),
                    Err(e) => {
                        io_error::cond.raise(e);
                        None
                    }
                }
            }
            File(*) => {
                io_error::cond.raise(IoError {
                    kind: OtherIoError,
                    desc: "stream is not a tty",
                    detail: None,
                });
                None
            }
        }
    }

    /// Controls whether this output stream is a "raw stream" or simply a normal
    /// stream.
    ///
    /// # Failure
    ///
    /// This function will raise on the `io_error` condition if an error
    /// happens.
    pub fn set_raw(&mut self, raw: bool) {
        match self.inner {
            TTY(ref mut tty) => {
                match tty.set_raw(raw) {
                    Ok(()) => {},
                    Err(e) => io_error::cond.raise(e),
                }
            }
            File(*) => {
                io_error::cond.raise(IoError {
                    kind: OtherIoError,
                    desc: "stream is not a tty",
                    detail: None,
                });
            }
        }
    }

    /// Returns whether this tream is attached to a TTY instance or not.
    ///
    /// This is similar to libc's isatty() function
    pub fn isatty(&self) -> bool {
        match self.inner {
            TTY(ref tty) => tty.isatty(),
            File(*) => false,
        }
    }
}

impl Writer for StdWriter {
    fn write(&mut self, buf: &[u8]) {
        let ret = match self.inner {
            TTY(ref mut tty) => tty.write(buf),
            File(ref mut file) => file.write(buf),
        };
        match ret {
            Ok(()) => {}
            Err(e) => io_error::cond.raise(e)
        }
    }
}

#[cfg(test)]
mod tests {
    use super::*;

    #[test]
    fn smoke() {
        // Just make sure we can acquire handles
        stdin();
        stdout();
        stderr();
    }
}