1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 29 30 31 32 33 34 35 36 37 38 39 40 41 42 43 44 45 46 47 48 49 50 51 52 53 54 55 56 57 58 59 60 61 62 63 64 65 66 67 68 69 70 71 72 73 74 75 76 77 78 79 80 81 82 83 84 85 86 87 88 89 90 91 92 93 94 95 96 97 98 99 100 101 102 103 104 105 106 107 108 109 110 111 112 113 114 115 116 117 118 119 120 121 122 123 124 125 126 127 128 129
#![cfg(feature = "with-deprecated")]
#![allow(deprecated)]
#![deprecated(since = "0.1.4",
note = "replaced with `BiLock` in many cases, otherwise slated \
for removal due to confusion")]
use std::prelude::v1::*;
use std::sync::Arc;
use std::cell::UnsafeCell;
use task_impl;
// One critical piece of this module's contents are the `TaskRc<A>` handles.
// The purpose of this is to conceptually be able to store data in a task,
// allowing it to be accessed within multiple futures at once. For example if
// you have some concurrent futures working, they may all want mutable access to
// some data. We already know that when the futures are being poll'd that we're
// entirely synchronized (aka `&mut Task`), so you shouldn't require an
// `Arc<Mutex<T>>` to share as the synchronization isn't necessary!
//
// So the idea here is that you insert data into a task via `Task::insert`, and
// a handle to that data is then returned to you. That handle can later get
// presented to the task itself to actually retrieve the underlying data. The
// invariant is that the data can only ever be accessed with the task present,
// and the lifetime of the actual data returned is connected to the lifetime of
// the task itself.
//
// Conceptually I at least like to think of this as "dynamically adding more
// struct fields to a `Task`". Each call to insert creates a new "name" for the
// struct field, a `TaskRc<A>`, and then you can access the fields of a struct
// with the struct itself (`Task`) as well as the name of the field
// (`TaskRc<A>`). If that analogy doesn't make sense then oh well, it at least
// helped me!
//
// So anyway, we do some interesting trickery here to actually get it to work.
// Each `TaskRc<A>` handle stores `Arc<UnsafeCell<A>>`. So it turns out, we're
// not even adding data to the `Task`! Each `TaskRc<A>` contains a reference
// to this `Arc`, and `TaskRc` handles can be cloned which just bumps the
// reference count on the `Arc` itself.
//
// As before, though, you can present the `Arc` to a `Task` and if they
// originated from the same place you're allowed safe access to the internals.
// We allow but shared and mutable access without the `Sync` bound on the data,
// crucially noting that a `Task` itself is not `Sync`.
//
// So hopefully I've convinced you of this point that the `get` and `get_mut`
// methods below are indeed safe. The data is always valid as it's stored in an
// `Arc`, and access is only allowed with the proof of the associated `Task`.
// One thing you might be asking yourself though is what exactly is this "proof
// of a task"? Right now it's a `usize` corresponding to the `Task`'s
// `TaskHandle` arc allocation.
//
// Wait a minute, isn't that the ABA problem! That is, we create a task A, add
// some data to it, destroy task A, do some work, create a task B, and then ask
// to get the data from task B. In this case though the point of the
// `task_inner` "proof" field is simply that there's some non-`Sync` token
// proving that you can get access to the data. So while weird, this case should
// still be safe, as the data's not stored in the task itself.
/// A reference to a piece of data that's accessible only within a specific
/// `Task`.
///
/// This data is `Send` even when `A` is not `Sync`, because the data stored
/// within is accessed in a single-threaded way. The thread accessing it may
/// change over time, if the task migrates, so `A` must be `Send`.
#[derive(Debug)]
pub struct TaskRc<A> {
task: task_impl::Task,
ptr: Arc<UnsafeCell<A>>,
}
// for safety here, see docs at the top of this module
unsafe impl<A: Send> Send for TaskRc<A> {}
unsafe impl<A: Sync> Sync for TaskRc<A> {}
impl<A> TaskRc<A> {
/// Inserts a new piece of task-local data into this task, returning a
/// reference to it.
///
/// Ownership of the data will be transferred to the task, and the data will
/// be destroyed when the task itself is destroyed. The returned value can
/// be passed to the `with` method to get a reference back to the original
/// data.
///
/// Note that the returned handle is cloneable and copyable and can be sent
/// to other futures which will be associated with the same task. All
/// futures will then have access to this data when passed the reference
/// back.
///
/// # Panics
///
/// This function will panic if a task is not currently running.
pub fn new(a: A) -> TaskRc<A> {
TaskRc {
task: task_impl::park(),
ptr: Arc::new(UnsafeCell::new(a)),
}
}
/// Operate with a reference to the underlying data.
///
/// This method should be passed a handle previously returned by
/// `Task::insert`. That handle, when passed back into this method, will
/// retrieve a reference to the original data.
///
/// # Panics
///
/// This method will panic if a task is not currently running or if `self`
/// does not belong to the task that is currently running. That is, if
/// another task generated the `data` handle passed in, this method will
/// panic.
pub fn with<F, R>(&self, f: F) -> R
where F: FnOnce(&A) -> R
{
if !self.task.is_current() {
panic!("TaskRc being accessed on task it does not belong to");
}
f(unsafe { &*self.ptr.get() })
}
}
impl<A> Clone for TaskRc<A> {
fn clone(&self) -> TaskRc<A> {
TaskRc {
task: self.task.clone(),
ptr: self.ptr.clone(),
}
}
}