I read a lot of posts about using __weak self
inside dispatch_async
, and now I am a litle bit confused.
if I have :
self.myQueue = dispatch_queue_create("com.biview.core_data", NULL);
dispatch_async(self.myQueue, ^(void){
if (!self.var1) {
self.var1 = ...;
}
dispatch_async(dispatch_get_main_queue(), ^(void) {
if ([self.var2 superview]) {
[self.var2 removeFromSuperview];
}
[self.Label setText:text];
});
});
do I need to use __weak self
. Because I read that in some cases dispatch_async
not need a __weak self
.
See last comment here
Assuming, self is an object pointer to a UIViewController
.
Things to consider:
A UIViewController
is a "UIKit" object. UIKit objects shall not be sent methods on non-main threads, that is - those methods must execute on the main thread only!
A block that has been enqueued in a queue - whether this was synchronously or asynchronously - will eventually be executed -- no matter what! Well, unless the program terminates before this can happen.
Captured retainable strong pointers will be retained when the block will be copied (for example, when dispatched asynchronously), and again released when the block will be destroyed (after it finished).
Captured retainable weak pointers will NOT be retained and not released.
In your scenario, where you capture self in the block which is dispatched on the main queue, you don't need to worry that bad things happen.
Since self will be captured in the block which is dispatched asynchronously, self will be implicitly retained, and released again when the block has been finished.
That means, the life-time of self will be extended up until after the block finishes. Notice that your second block is dispatched on the main thread, and it's guaranteed that self is still alive when that block gets executed.
This "extended life" above, might be a desired feature of your program.
If you explicitly don't want to extend the life-time of the UIViewController
object, and instead want the block - when it finally executes - check whether this UIViewController
object does still exist at all, you can use a __weak pointer of self. Note that the block gets eventually executed, no matter whether the UIViewController
is still alive or has been deallocated in the mean time.
You might want the block doing "nothing" if the UIViewController
has been deallocated before the block will get executed:
MyController* __weak weakSelf = self;
dispatch_async(queue, ^{
MyController* strongSelf = weakSelf;
if (strongSelf) {
...
}
else {
// self has been deallocated in the meantime.
}
});
See also: Transitioning to ARC Release Notes
UIKit
objects shall not be sent methods on non-main threads!One other subtle error may occur due to the fact that UIKit
objects shall execute methods only on the main thread.
This can be violated, if a block captures a UIKit
object which is dispatched asynchronously, and executes on a non-main thread. It then may happen that the block holds the last strong reference to that UIKit
object. Now, when the block gets eventually executed, the block will be destroyed and the UIKit
object will be released. Since this is the last strong reference to the UIKit
object, it will be deallocated. However, this happens on the thread where the block has been executed - and this is not the main thread! Now, bad things can (and will usually) happen, since the dealloc
method is still a method sent to a UIKit
object.
You can avoid this error, by dispatching a block capturing a strong pointer to that UIKit object, and send it a dummy method:
UIViewController* strongUIKitPointer = ...
dispatch_async(non_main_queue, ^{
... // do something
dispatch(dispatch_get_main_queue(), ^{
[strongUIKitPointer self]; // note: self is a method, too - doing nothing
});
});
In your scenario though, the last strong reference could be only in the block which executes on the main thread. So, you are safe from this subtle error. ;)
In your setup, you never have a retain cycle. A retain cycle occurs if a retainable object A strongly references another retainable object B, and object B strongly references A. Note that a "Block" is also a retainable object.
A contrived example with a cyclic reference:
typedef void(^my_completion_block_t)(NSArray* result);
@interface UsersViewController : UIViewController
@property (nonatomic, copy) my_completion_block_t completion;
@property (nonatomic) NSArray* users;
@end
Here, we have a property completion whose value type is a Block. That is, we get an ivar with name _completion
whose type is a Block.
A client may set a completion handler which should be called when a certain operation has finished. Suppose, the operation fetches a list of Users from a remote server. The plan is to set the property users once the operation finished:
The careless approach would accidentally introduce a cyclic reference:
Somewhere in "UsersViewController.m"
self.completion = ^(NSArray* users){
self.users = users;
}
[self fetchUsers]; // start asynchronous task
Here, self holds a strong reference to the ivar _completion
, which is a block. And the block itself captures self, which causes to retain self when the block gets copied when it is dispatched. This is a classic reference cycle.
In order to avoid that cyclic reference, we have a few alternatives:
Using a __weak
qualified pointer of self
UsersViewController* __weak weakSelf = self;
self.completion = ^(NSArray* users) {
UsersViewController* strongSelf = weakSelf;
if (strongSelf) {
strongSelf.users = users;
}
else {
// the view controller does not exist anymore
}
}
[usersViewController fetchUsers];
Using a __block
qualified pointer of self and eventually setting it nil
in the block when it finishes:
UsersViewController* __block blockSelf = self;
self.completion = ^(NSArray* users) {
blockSelf.users = users;
blockSelf = nil;
}
[usersViewController fetchUsers];
See also: Transitioning to ARC Release Notes
An example of this so-called strong-weak dance in swift:
func doSomeThingAsynchronously() {
DispatchQueue.global().async {
// Do task in default queue
DispatchQueue.main.async { [weak self] in
// Do task in main queue
guard let self = self else { return }
self.updateView()
}
}
}
func doSomeThingAsynchronously() {
DispatchQueue.global().async {
// Do task in default queue
DispatchQueue.main.async { [weak self] in
// Do task in main queue
guard let strongSelf = self else { return }
strongSelf.updateView()
}
}
}
func doSomeThingAsynchronously() {
dispatch_async(dispatch_get_global_queue(DISPATCH_QUEUE_PRIORITY_DEFAULT, 0)) { () -> () in
// Do task in default queue
dispatch_async(dispatch_get_main_queue(), { [weak self] () -> () in
guard let strongSelf = self else { return }
// Do task in main queue
strongSelf.updateView()
})
}
}
Popular open source project Alamofire
uses this approach.
Extend object lifetime using the [weak self] and guard let strongSelf = self else { return } idiom.
For more info check out swift-style-guide
If you love us? You can donate to us via Paypal or buy me a coffee so we can maintain and grow! Thank you!
Donate Us With