The `print!` and `println!` macros are now the preferred method of printing, and so there is no reason to export the `stdio` functions in the prelude. The functions have also been replaced by their macro counterparts in the tutorial and other documentation so that newcomers don't get confused about what they should be using.
18 KiB
% The Rust Tasks and Communication Guide
Introduction
Rust provides safe concurrency through a combination of lightweight, memory-isolated tasks and message passing. This guide will describe the concurrency model in Rust, how it relates to the Rust type system, and introduce the fundamental library abstractions for constructing concurrent programs.
Rust tasks are not the same as traditional threads: rather,
they are considered green threads, lightweight units of execution that the Rust
runtime schedules cooperatively onto a small number of operating system threads.
On a multi-core system Rust tasks will be scheduled in parallel by default.
Because tasks are significantly
cheaper to create than traditional threads, Rust can create hundreds of
thousands of concurrent tasks on a typical 32-bit system.
In general, all Rust code executes inside a task, including the main
function.
In order to make efficient use of memory Rust tasks have dynamically sized stacks. A task begins its life with a small amount of stack space (currently in the low thousands of bytes, depending on platform), and acquires more stack as needed. Unlike in languages such as C, a Rust task cannot accidentally write to memory beyond the end of the stack, causing crashes or worse.
Tasks provide failure isolation and recovery. When a fatal error occurs in Rust
code as a result of an explicit call to fail!()
, an assertion failure, or
another invalid operation, the runtime system destroys the entire
task. Unlike in languages such as Java and C++, there is no way to catch
an
exception. Instead, tasks may monitor each other for failure.
Tasks use Rust's type system to provide strong memory safety guarantees. In particular, the type system guarantees that tasks cannot share mutable state with each other. Tasks communicate with each other by transferring owned data through the global exchange heap.
A note about the libraries
While Rust's type system provides the building blocks needed for safe and efficient tasks, all of the task functionality itself is implemented in the standard and extra libraries, which are still under development and do not always present a consistent or complete interface.
For your reference, these are the standard modules involved in Rust concurrency at this writing:
std::task
- All code relating to tasks and task scheduling,std::comm
- The message passing interface,extra::comm
- Additional messaging types based onstd::comm
,extra::sync
- More exotic synchronization tools, including locks,extra::arc
- The Arc (atomically reference counted) type, for safely sharing immutable data,extra::future
- A type representing values that may be computed concurrently and retrieved at a later time.
Basics
The programming interface for creating and managing tasks lives
in the task
module of the std
library, and is thus available to all
Rust code by default. At its simplest, creating a task is a matter of
calling the spawn
function with a closure argument. spawn
executes the
closure in the new task.
# use std::task::spawn;
// Print something profound in a different task using a named function
fn print_message() { println!("I am running in a different task!"); }
spawn(print_message);
// Print something more profound in a different task using a lambda expression
spawn(proc() println!("I am also running in a different task!") );
// The canonical way to spawn is using `do` notation
do spawn {
println!("I too am running in a different task!");
}
In Rust, there is nothing special about creating tasks: a task is not a concept that appears in the language semantics. Instead, Rust's type system provides all the tools necessary to implement safe concurrency: particularly, owned types. The language leaves the implementation details to the standard library.
The spawn
function has a very simple type signature: fn spawn(f: proc())
. Because it accepts only owned closures, and owned closures
contain only owned data, spawn
can safely move the entire closure
and all its associated state into an entirely different task for
execution. Like any closure, the function passed to spawn
may capture
an environment that it carries across tasks.
# use std::task::spawn;
# fn generate_task_number() -> int { 0 }
// Generate some state locally
let child_task_number = generate_task_number();
do spawn {
// Capture it in the remote task
println!("I am child number {}", child_task_number);
}
Communication
Now that we have spawned a new task, it would be nice if we could communicate with it. Recall that Rust does not have shared mutable state, so one task may not manipulate variables owned by another task. Instead we use pipes.
A pipe is simply a pair of endpoints: one for sending messages and another for receiving messages. Pipes are low-level communication building-blocks and so come in a variety of forms, each one appropriate for a different use case. In what follows, we cover the most commonly used varieties.
The simplest way to create a pipe is to use Chan::new
function to create a (Port, Chan)
pair. In Rust parlance, a channel
is a sending endpoint of a pipe, and a port is the receiving
endpoint. Consider the following example of calculating two results
concurrently:
# use std::task::spawn;
let (port, chan): (Port<int>, Chan<int>) = Chan::new();
do spawn || {
let result = some_expensive_computation();
chan.send(result);
}
some_other_expensive_computation();
let result = port.recv();
# fn some_expensive_computation() -> int { 42 }
# fn some_other_expensive_computation() {}
Let's examine this example in detail. First, the let
statement creates a
stream for sending and receiving integers (the left-hand side of the let
,
(chan, port)
, is an example of a destructuring let: the pattern separates
a tuple into its component parts).
let (port, chan): (Port<int>, Chan<int>) = Chan::new();
The child task will use the channel to send data to the parent task, which will wait to receive the data on the port. The next statement spawns the child task.
# use std::task::spawn;
# fn some_expensive_computation() -> int { 42 }
# let (port, chan) = Chan::new();
do spawn || {
let result = some_expensive_computation();
chan.send(result);
}
Notice that the creation of the task closure transfers chan
to the child
task implicitly: the closure captures chan
in its environment. Both Chan
and Port
are sendable types and may be captured into tasks or otherwise
transferred between them. In the example, the child task runs an expensive
computation, then sends the result over the captured channel.
Finally, the parent continues with some other expensive computation, then waits for the child's result to arrive on the port:
# fn some_other_expensive_computation() {}
# let (port, chan) = Chan::<int>::new();
# chan.send(0);
some_other_expensive_computation();
let result = port.recv();
The Port
and Chan
pair created by Chan::new
enables efficient
communication between a single sender and a single receiver, but multiple
senders cannot use a single Chan
, and multiple receivers cannot use a single
Port
. What if our example needed to compute multiple results across a number
of tasks? The following program is ill-typed:
# use std::task::{spawn};
# fn some_expensive_computation() -> int { 42 }
let (port, chan) = Chan::new();
do spawn {
chan.send(some_expensive_computation());
}
// ERROR! The previous spawn statement already owns the channel,
// so the compiler will not allow it to be captured again
do spawn {
chan.send(some_expensive_computation());
}
Instead we can use a SharedChan
, a type that allows a single
Chan
to be shared by multiple senders.
# use std::task::spawn;
let (port, chan) = SharedChan::new();
for init_val in range(0u, 3) {
// Create a new channel handle to distribute to the child task
let child_chan = chan.clone();
do spawn {
child_chan.send(some_expensive_computation(init_val));
}
}
let result = port.recv() + port.recv() + port.recv();
# fn some_expensive_computation(_i: uint) -> int { 42 }
Here we transfer ownership of the channel into a new SharedChan
value. Like
Chan
, SharedChan
is a non-copyable, owned type (sometimes also referred to
as an affine or linear type). Unlike with Chan
, though, the programmer
may duplicate a SharedChan
, with the clone()
method. A cloned
SharedChan
produces a new handle to the same channel, allowing multiple
tasks to send data to a single port. Between spawn
, Chan
and
SharedChan
, we have enough tools to implement many useful concurrency
patterns.
Note that the above SharedChan
example is somewhat contrived since
you could also simply use three Chan
pairs, but it serves to
illustrate the point. For reference, written with multiple streams, it
might look like the example below.
# use std::task::spawn;
# use std::vec;
// Create a vector of ports, one for each child task
let ports = vec::from_fn(3, |init_val| {
let (port, chan) = Chan::new();
do spawn {
chan.send(some_expensive_computation(init_val));
}
port
});
// Wait on each port, accumulating the results
let result = ports.iter().fold(0, |accum, port| accum + port.recv() );
# fn some_expensive_computation(_i: uint) -> int { 42 }
Backgrounding computations: Futures
With extra::future
, rust has a mechanism for requesting a computation and getting the result
later.
The basic example below illustrates this.
# fn make_a_sandwich() {};
fn fib(n: u64) -> u64 {
// lengthy computation returning an uint
12586269025
}
let mut delayed_fib = extra::future::Future::spawn(proc() fib(50));
make_a_sandwich();
println!("fib(50) = {:?}", delayed_fib.get())
The call to future::spawn
returns immediately a future
object regardless of how long it
takes to run fib(50)
. You can then make yourself a sandwich while the computation of fib
is
running. The result of the execution of the method is obtained by calling get
on the future.
This call will block until the value is available (i.e. the computation is complete). Note that
the future needs to be mutable so that it can save the result for next time get
is called.
Here is another example showing how futures allow you to background computations. The workload will be distributed on the available cores.
# use std::vec;
fn partial_sum(start: uint) -> f64 {
let mut local_sum = 0f64;
for num in range(start*100000, (start+1)*100000) {
local_sum += (num as f64 + 1.0).pow(&-2.0);
}
local_sum
}
fn main() {
let mut futures = vec::from_fn(1000, |ind| do extra::future::Future::spawn { partial_sum(ind) });
let mut final_res = 0f64;
for ft in futures.mut_iter() {
final_res += ft.get();
}
println!("π^2/6 is not far from : {}", final_res);
}
Sharing immutable data without copy: Arc
To share immutable data between tasks, a first approach would be to only use pipes as we have seen previously. A copy of the data to share would then be made for each task. In some cases, this would add up to a significant amount of wasted memory and would require copying the same data more than necessary.
To tackle this issue, one can use an Atomically Reference Counted wrapper (Arc
) as implemented in
the extra
library of Rust. With an Arc, the data will no longer be copied for each task. The Arc
acts as a reference to the shared data and only this reference is shared and cloned.
Here is a small example showing how to use Arcs. We wish to run concurrently several computations on a single large vector of floats. Each task needs the full vector to perform its duty.
# use std::vec;
# use std::rand;
use extra::arc::Arc;
fn pnorm(nums: &~[f64], p: uint) -> f64 {
nums.iter().fold(0.0, |a,b| a+(*b).pow(&(p as f64)) ).pow(&(1.0 / (p as f64)))
}
fn main() {
let numbers = vec::from_fn(1000000, |_| rand::random::<f64>());
println!("Inf-norm = {}", *numbers.iter().max().unwrap());
let numbers_arc = Arc::new(numbers);
for num in range(1u, 10) {
let (port, chan) = Chan::new();
chan.send(numbers_arc.clone());
do spawn {
let local_arc : Arc<~[f64]> = port.recv();
let task_numbers = local_arc.get();
println!("{}-norm = {}", num, pnorm(task_numbers, num));
}
}
}
The function pnorm
performs a simple computation on the vector (it computes the sum of its items
at the power given as argument and takes the inverse power of this value). The Arc on the vector is
created by the line
# use extra::arc::Arc;
# use std::vec;
# use std::rand;
# let numbers = vec::from_fn(1000000, |_| rand::random::<f64>());
let numbers_arc=Arc::new(numbers);
and a clone of it is sent to each task
# use extra::arc::Arc;
# use std::vec;
# use std::rand;
# let numbers=vec::from_fn(1000000, |_| rand::random::<f64>());
# let numbers_arc = Arc::new(numbers);
# let (port, chan) = Chan::new();
chan.send(numbers_arc.clone());
copying only the wrapper and not its contents.
Each task recovers the underlying data by
# use extra::arc::Arc;
# use std::vec;
# use std::rand;
# let numbers=vec::from_fn(1000000, |_| rand::random::<f64>());
# let numbers_arc=Arc::new(numbers);
# let (port, chan) = Chan::new();
# chan.send(numbers_arc.clone());
# let local_arc : Arc<~[f64]> = port.recv();
let task_numbers = local_arc.get();
and can use it as if it were local.
The arc
module also implements Arcs around mutable data that are not covered here.
Handling task failure
Rust has a built-in mechanism for raising exceptions. The fail!()
macro
(which can also be written with an error string as an argument: fail!( ~reason)
) and the assert!
construct (which effectively calls fail!()
if a boolean expression is false) are both ways to raise exceptions. When a
task raises an exception the task unwinds its stack---running destructors and
freeing memory along the way---and then exits. Unlike exceptions in C++,
exceptions in Rust are unrecoverable within a single task: once a task fails,
there is no way to "catch" the exception.
While it isn't possible for a task to recover from failure, tasks may notify
each other of failure. The simplest way of handling task failure is with the
try
function, which is similar to spawn
, but immediately blocks waiting
for the child task to finish. try
returns a value of type Result<T, ()>
. Result
is an enum
type with two variants: Ok
and Err
. In this
case, because the type arguments to Result
are int
and ()
, callers can
pattern-match on a result to check whether it's an Ok
result with an int
field (representing a successful result) or an Err
result (representing
termination with an error).
# use std::task;
# fn some_condition() -> bool { false }
# fn calculate_result() -> int { 0 }
let result: Result<int, ()> = do task::try {
if some_condition() {
calculate_result()
} else {
fail!("oops!");
}
};
assert!(result.is_err());
Unlike spawn
, the function spawned using try
may return a value,
which try
will dutifully propagate back to the caller in a Result
enum. If the child task terminates successfully, try
will
return an Ok
result; if the child task fails, try
will return
an Error
result.
Note: A failed task does not currently produce a useful error value (
try
always returnsErr(())
). In the future, it may be possible for tasks to intercept the value passed tofail!()
.
TODO: Need discussion of future_result
in order to make failure
modes useful.
But not all failures are created equal. In some cases you might need to abort the entire program (perhaps you're writing an assert which, if it trips, indicates an unrecoverable logic error); in other cases you might want to contain the failure at a certain boundary (perhaps a small piece of input from the outside world, which you happen to be processing in parallel, is malformed and its processing task can't proceed).
Creating a task with a bi-directional communication path
A very common thing to do is to spawn a child task where the parent
and child both need to exchange messages with each other. The
function extra::comm::DuplexStream()
supports this pattern. We'll
look briefly at how to use it.
To see how DuplexStream()
works, we will create a child task
that repeatedly receives a uint
message, converts it to a string, and sends
the string in response. The child terminates when it receives 0
.
Here is the function that implements the child task:
# use extra::comm::DuplexStream;
# use std::uint;
fn stringifier(channel: &DuplexStream<~str, uint>) {
let mut value: uint;
loop {
value = channel.recv();
channel.send(uint::to_str(value));
if value == 0 { break; }
}
}
The implementation of DuplexStream
supports both sending and
receiving. The stringifier
function takes a DuplexStream
that can
send strings (the first type parameter) and receive uint
messages
(the second type parameter). The body itself simply loops, reading
from the channel and then sending its response back. The actual
response itself is simply the stringified version of the received value,
uint::to_str(value)
.
Here is the code for the parent task:
# use std::task::spawn;
# use std::uint;
# use extra::comm::DuplexStream;
# fn stringifier(channel: &DuplexStream<~str, uint>) {
# let mut value: uint;
# loop {
# value = channel.recv();
# channel.send(uint::to_str(value));
# if value == 0u { break; }
# }
# }
# fn main() {
let (from_child, to_child) = DuplexStream::new();
do spawn {
stringifier(&to_child);
};
from_child.send(22);
assert!(from_child.recv() == ~"22");
from_child.send(23);
from_child.send(0);
assert!(from_child.recv() == ~"23");
assert!(from_child.recv() == ~"0");
# }
The parent task first calls DuplexStream
to create a pair of bidirectional
endpoints. It then uses task::spawn
to create the child task, which captures
one end of the communication channel. As a result, both parent and child can
send and receive data to and from the other.