But that really leaves me wondering: How can a weak reference possibly
be useful? If you can't count on it referencing an object, and its not
needed for things like breaking cycles, then why use one?
I have an admittedly dogmatic opinion that weak references should actually be the default way to persistently store a reference to an object with strong references requiring a more explicit syntax, like so:
// Stores a weak reference to bar. 'Foo' does not
// own bar.
private Bar bar;
// Stores a strong reference to 'Baz'. 'Foo' does
// own Baz.
private strong Baz baz;
... meanwhile the reverse for locals inside a function/method:
// Stores a strong reference to 'Bar'. It will
// not be destroyed until it goes out of scope.
Bar bar = ...;
// Stores a weak reference to 'Baz'. It can be
// destroyed before the weak reference goes out
// of scope.
weak Baz baz_weak = ...;
// Acquire a strong reference to 'Baz'.
Baz baz = baz_weak;
// If 'baz' has not been destroyed,
// do something with it.
To understand why I have this firm opinion and why weak references are useful, I'll just share a personal story at my experience in a former company that embraced GC across the board.
This was for a 3D product that dealt with hefty things like meshes and textures, some of which could individually span over a gigabyte in memory. The software revolved around a scene graph and a plugin architecture where any plugin could access the scene graph and elements inside, like textures or meshes or lights or cameras.
Now what happened was that the team and our third party developers were not so familiar with weak references and so we had people storing object references to things in the scene graph left and right. Camera plugins would store a list of strong object references to exclude from camera view. The renderer would store a list of objects to use in rendering like a list of light references. Lights would act similarly to cameras and have exclusion/inclusion lists. Shader plugins would store references to textures they use. The list goes on and on.
I was actually the one that had to do a presentation on the importance of weak references for our team one year into development after we discovered so many leaks, even though I was not the one to push the design decision to use GC (I was actually against this). I also had to implement support for weak references into our proprietary garbage collector after the presentation because our garbage collector (written by someone else) did not even support weak references originally.
And sure enough, we ended up with a software where, when a user wanted to remove an object from the scene like a mesh or texture, instead of freeing that memory, the application just continued to use the memory because something, somewhere throughout the large codebase, was still holding a reference to those scene objects and not letting them go when the user explicitly requested it. Even after clearing the scene, the software could take 3 gigabytes of memory and even more the longer you use it. And this was all because the codebase, including third party developers, failed to use weak references when appropriate.
As a result when the user requested to remove a mesh from a scene, perhaps 9/10 places where references to a given mesh were stored would properly release the reference, setting it to a null reference or removing the reference from a list to allow the garbage collector to collect it. However, there would often be a tenth place that forgot to handle such an event, keeping the mesh in memory until that thing itself was also removed from the scene (and sometimes such things lived outside of the scene and were stored in the application root). And that cascaded sometimes to the point where the software would just consume more and more memory the longer you used it to the point where handler plugins (which stick around even after clearing a scene) would extend the lifetime of the entire scene itself by storing a an injected reference to the scene root for DI, at which point the memory wouldn't be freed even after clearing the entire scene, requiring users to periodically restart the software every hour or two just to get it back to a sane amount of memory usage.
These were not easy bugs to discover. All we could see is that the application was using more and more memory the longer you ran it. It wasn't something we could easily reproduce in short-lived unit or integration tests. And sometimes after hours of exhaustive investigation, we'd discover that it wasn't even our own code that caused these memory leaks. It was inside a third party plugin that users used often where the plugin just ended up storing a reference to something like a mesh or texture that it didn't release in response to a scene removal event.
And that tendency to leak more and more memory tends to be there in software written in garbage-collected languages where the programmers aren't careful to use weak references when appropriate. Weak references should be used ideally in all cases where an object does not own another. There should be far more cases where that makes sense than strong references. It doesn't make sense for every object that references everything to share ownership in everything. For most software, the most sensible design is for one thing in the system to own another, like "scene graphs own scene objects", not "cameras also own meshes because they refer to them in the camera exclusion list".
Now GC is very scary in a large-scale, performance-critical software where such logical leaks can cause the application to take hundreds of gigabytes more memory than it should over a long period of time while slowing down to a crawl the longer you run it, starting off fast and then just getting slower and slower until you restart it.
When you're trying to investigate the source of all these leaks, you could be looking at 20 million lines of code including more outside of your control, written by plugin developers, and any one of those lines could be silently extending the lifetime of an object far longer than appropriate by merely storing an object reference to it and failing to release it in response to the appropriate event(s). Worse, all of this flies under the radar of QA and automated testing.
That's a nightmarish scenario in such a context and the only reasonable way I see to avoid such a scenario is to have a coding standard that relies heavily on weak references if you're using GC or just avoid using GC in the first place.
Now I have never had the most positive opinion about garbage collection admittedly, and it's because in my field at least, it isn't necessarily more desirable to have a logical resource leak that flies under the radar of testing over, say, a dangling pointer crash which can easily detected and reproduced and most likely corrected by the developer before he even commits his code if there's a sound testing and CI procedure.
In my particular case, the most desirable kind of bugs if we're choosing among evils are the ones most easy to discover and reproduce, and GC-type resource leaks are not easy to discover and not easy to reproduce in any sense that helps you discover the source of that leak.
However, my opinion about GC turns a lot more favorable among teams and codebases that make heavy use of weak references and only use strong references where it makes actual sense from a high-level design standpoint to extend the lifetime of an object.
After all, all we have to do to create a logical leak with GC is this:
// This makes 'Foo' instances cause 'bar' to leak, preventing
// it from being destroyed until the 'Foo' instances are also
// destroyed unless the 'Foo' instances set this to a null
// reference at the right time (ex: when the user requests
// to remove whatever Bar is from the software).
private Bar bar;
... but weak references don't risk this problem. When you're looking at millions of LOC like the above on one hand and epic memory leaks on the other, it's quite a nightmare scenario when you have to then investigate which analogical
Foo failed to set the analogical
Bar to a null reference at the appropriate time because this is the part that's so scary: the code works just fine as long as you ignore gigabytes of memory leaking. Nothing triggers any kind of error/exception, assertion failure, etc. Nothing crashes. All the unit and integration pass without complaint. It all just works except that it's leaking gigabytes of memory causing user complaints left and right while the whole team is scratching their heads about what parts of the codebase are leaky and what aren't while QA tries to do damage control by pragmatically suggesting that users save their work and restart the software every half hour as though that's supposed to be some kind of solution.
Weak References Help a Lot
So please make use of weak references whenever appropriate, and by appropriate, I mean when it doesn't make sense for an object to share ownership in another.
They're useful because you can still detect when an object has been destroyed without extending its lifetime. Strong references are useful when you genuinely need to extend the lifetime of an object, such as inside a short-lived thread so that the object isn't destroyed before the thread is finished processing it, or inside an object that genuinely makes sense to own another.
Using my scene graph example, a camera exclusion list does not need to own scene objects already owned by the scene graph. Logically that makes no sense if it did. If we're at the drawing board, no one should think, "yes, cameras should also own scene objects in addition to the scene graph itself."
It only needs those references to be able to easily refer back to those elements. When it does, it can acquire strong references to them from the weak references it stored prior to processing them and also check to see if they've been removed by the user prior to doing so as opposed to extending their lifetime possibly indefinitely to the point where the memory is leaked until the camera itself is also removed.
If the camera wants to use a convenient lazy kind of implementation that doesn't have to bother with scene removal events, then weak references at least allow it to do that without leaking epic amounts of memory all over the place. The weak references still allow it to discover, in hindsight, when objects have been removed from the scene and maybe remove the destroyed weak references from the list then without bothering with scene removal events. The ideal solution to me is to use both weak references and also handle scene removal events, but at the very least the camera exclusion list should be using weak references, not strong references.
The Usefulness of Weak References in a Team Environment
And that gets to the heart of the usefulness of weak references to me. They are never absolutely required if every developer on your team thoroughly removes/nulls out object references at appropriate times in response to the appropriate events. But in large teams at least, the bugs that can occur which are not prevented outright by the engineering standards will often end up occurring, and sometimes at staggering rates. And there weak references are a fantastic defense against the tendency for applications revolving around GC to have logical leaks the longer you run them. They're a defensive mechanism in my eyes to help translate bugs that would manifest themselves in the form of hard-to-detect memory leaks into easy-to-detect uses of an invalid reference to an object already destroyed.
They might not seem so useful in the same sense that an assembly programmer might not find much use for type safety. After all, he can do everything he needs with just raw bits and bytes and the appropriate assembly instructions. However, type safety helps to detect human errors more easily by making the human developers more explicitly express what they want to do and constraining what they're allowed to do with a particular type. I see weak references in a similar sense. They help detect human errors that would have otherwise lead to resource leaks if weak references weren't used. It is deliberately imposing constraints on yourself like, "Okay, this is weak reference to an object so it cannot possibly extend its lifetime and cause a logical leak" which is inconvenient, but so is type safety to an assembly programmer. It can still help prevent some very nasty bugs.
They're a language safety feature if you ask me and like any safety feature, it's not absolutely required and you generally won't appreciate it until you encounter a team tripping over the same things over and over because such a safety feature was lacking or not adequately used. For solo developers, safety is often one of the easiest things to ignore since if you're competent and careful, you genuinely might not personally need it. But multiply the risk of bugs by an entire team of people with mixed skills, and safety features can become things you desperately find are needed while people start analogically slipping on a wet floor left and right that you carefully avoid daily, causing dead bodies to pile up around you. I have found instead with large teams that if you don't have a coding standard that is simple to follow but lays down safe engineering practices with an iron fist that, within just a month, you could have accumulated over a hundred thousands lines of extremely buggy code with obscure, hard-to-detect bugs like the GC logical leaks mentioned above. The amount of broken code that can accumulate in just a month absent a standard to prevent the common bugs is quite staggering.
Anyway, I'm admittedly a bit dogmatic about this subject but the opinion was formed over a boatload of epic memory leaks, for which the only answer I saw short of just saying to developers, "Be more careful! You guys are leaking memory like crazy!" was to get them to use weak references more often, at which point any carelessness would not translate into epic amounts of memory leaked. It actually got to the point where we discovered so many leaky places in hindsight that flew under the radar of testing that I deliberately broke backwards source compatibility (though not binary compatibility) in our SDK. We used to have a convention like this:
typedef Strong<Mesh> MeshRef;
typedef Weak<Mesh> MeshWeakRef;
... this was a proprietary GC implemented in C++ running in a separate thread. I changed it to this:
typedef Weak<Mesh> MeshRef;
typedef Strong<Mesh> MeshStrongRef;
... and that simple change in syntax and naming convention helped enormously to prevent more leaks except we did it a couple years too late, making it damage control more than anything else.