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rust/src/libstd/rt/io/stdio.rs
Alex Crichton 7755ffd013 Remove #[fixed_stack_segment] and #[rust_stack] 
These two attributes are no longer useful now that Rust has decided to leave
segmented stacks behind. It is assumed that the rust task's stack is always
large enough to make an FFI call (due to the stack being very large).

There's always the case of stack overflow, however, to consider. This does not
change the behavior of stack overflow in Rust. This is still normally triggered
by the __morestack function and aborts the whole process.

C stack overflow will continue to corrupt the stack, however (as it did before
this commit as well). The future improvement of a guard page at the end of every
rust stack is still unimplemented and is intended to be the mechanism through
which we attempt to detect C stack overflow.

Closes #8822
Closes #10155
2013-11-11 10:40:34 -08:00

322 lines
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Rust
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// 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,
standard_error, EndOfFile};
// 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),
}
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.
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 {
// When reading a piped stdin, libuv will return 0-length reads when
// stdin reaches EOF. For pretty much all other streams it will
// return an actual EOF error, but apparently for stdin it's a
// little different. Hence, here we convert a 0 length read to an
// end-of-file indicator so the caller knows to stop reading.
Ok(0) => {
io_error::cond.raise(standard_error(EndOfFile));
None
}
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 stream is attached to a TTY instance or not.
pub fn isatty(&self) -> bool {
match self.inner {
TTY(*) => true,
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();
}
}
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