In object-oriented computer programming, a Null Object is an object with no referenced value or with defined neutral ("null") behavior. The Null Object design pattern describes the uses of such objects and their behavior (or lack thereof). It was first published in the Pattern Languages of Program Design book series.
== Motivation ==
In most object-oriented languages, such as Java or C#, references may be null. These references need to be checked to ensure they are not null before invoking any methods, because methods typically cannot be invoked on null references.
The Objective-C language takes...
I don't take issue with the possibility of having what is effectively an std::optional<> for a return value--that makes sense. Or with always returning a collection from a function with a collection return type, and just making it null if nothing was found
@jaggedSpire I have at least 3 of such things in my pi program. A null logger is something that's planned for an upcoming refactor of the logging mechanism.
My stupid pi program has gone for 8 years without a proper logging interface. And now it's starting to catch up to me.
but returning a minimal implementation of an interface as a fallback value for a function to avoid checking for null in client code seems like it kicks the can down the road and forces the client to check the interface to see how to check for the null object
@jaggedSpire It depends on whether the object is an "essential" part of the functionality of the program.
Logging isn't. So it's perfect for null-objecting.
My Pi program has a similar thing for checkpointing computations. If you give it the null checkpointing object, it simply won't make any checkpoints and you won't be able to resume the computation after restarting the program. But it works since checkpointing isn't essential to the functionality of the task.
@LucDanton no, because the interface is being filled by the thing it's passed. Passing it in implies that the caller knows the argument is valid--the code is allowed to do some simple sanity checks in the interest of failing fast and with comprehensible errors but it's not required just the pokite thing to do
I understand the minimal functionality getting passed as an argument thing
@VermillionAzure but the featureless class makes it so you have to figure out the proper way of checking for <no object found> instead of just using the dead simple and always deducable if (ret == null)
when clients shouldn't give a damn, and it's an irrelevant detail, sure
@jaggedSpire if it’s any help, what makes a neutral object (substituting for the 'null' terminology for a sec) is with respect to something else: an algorithm, an operation or operations. a null stream is so with respect to logging code, which is an altogether not so helpful thing to say of course. so if you want to conceive of a neutral person data type, you’d probably need to figure with respect to what
e.g. passing a do-nothing function [](event_t event) {} can be neutral with respect to passing a callback that reacts to events. but [] { throw some_error {}; } can be neutral when it comes to registering an exception handler
if the callee doesn't know that it's a null object, then they can't take shortcuts based on that information that may yield faster or more reliable implementations
That is, you're describing something completely different, and then saying you don't like that different thing, which has nothing to do with what others are saying.
kinda seems to me like instead of logging to a logger, just return that information that you would have logged and let the caller decide if it needs to go in a log or not
in the scheme I have just outlined, there are no null checks.
you simply return the data you want to log and then it can go all the way up the call stack if it has to until somebody knows whether or not they want to log it
It doesn't have to be about side-effects. Take another example from my pi program. The task parallelizer. The interface consists of a function: virtual void run_in_parallel(task A, task B). Most of the implementations actually run both A and B at the same time either using explicit threads, or a pool, or something else. But there's a "null parallelizer" that is 2 lines - A.run(); B.run(); It satisfies the contract of running the tasks, and it works correctly.
you can certainly do such a thing using the technique I have outlined above, where you simply return task A and task B, and then the caller can parallelize them or not as they need
Somewhat besides the point of null object idiom, but in this case, the idea is to separate the task decomposition from the parallelization. The code doesn't (and shouldn't) care how the tasks are run. All it does it provide the tasks that can be run in parallel. Then the parallelizer object handles it.
@Puppy I think we're talking past each other. The point here is that rather than doing if (parallelizer == nullptr){A.run(); B.run();} everywhere, you just blindly call parallelizer->run_in_parallel(A, B) and insert the null-parallelizer object if you want to disable the parallelism.
@Mysticial The caller doesn't need to pass in a parallelizer at all. Therefore there's nothing that needs to be null or not null. The caller can simply directly do whatever they need.
@Mysticial No, the caller simply directly calls the parallelizer they want to use with the returned values as the arguments. In this case the parallelizer does not need to be an interface at all but just some function that takes tasks and runs them.
Yeah, putting aside the overhead of maintaining the DAG, the code needs to be written that way. And you lose the entire structure of nested scope lifetimes.
I'm merely saying that the null object pattern is completely extraneous if you don't inject totally random side effects into your functions in the first place
@Lalaland I can't speak for the performance since I've never tried doing the DAG approach. But from a practical perspective, the recursive fork-join approach is much better with respect to the algorithms that I'm implementing and for resource management.
Granted, I haven't tried really hard to find ways to make it work. Mainly because I saw no benefit of going that route. Then you have to manage a shared data structure (the DAG) itself. So I left it at that.
Yeah, unfortunately, that won't work for my use cases.
Because, the work units are data-dependent. And even if they weren't, trying to build one for an entire computation will probably result in a DAG with the # of nodes on the order of billions to trillions depending on the size of the computation. So you'd need to do it on the fly. And not build too far ahead that you're putting a strain on resources.
Right, but if you spawn 16 tasks for a machine with 16 logical cores, and it turns out one of those tasks takes 10x longer than the rest, you're still screwed.
Or if they're all the same, but then a background task comes in and hogs a core thereby starving one of the tasks. (this is called, "jitter") And it's one of the most annoying problems I dealt with in the early days of my Pi program.
Even if I designed the algorithm to divide the tasks up in to perfectly equal parts, "jitter" fucks everything up.
In routines where you have repeatedly need to spawn a bunch of tasks then wait for them to all finish, then spawn again, the "joining-time" is really sensitive to jitter and load imbalance.
Since at the tail of the DAG, you don't have any work-units left to run while you wait out the stragglers.
This isn't specific to a full async DAG approach to parallel programming, it's any sort of parallelism - including the fork-join and task-based models.
I found that best approach in these cases is to dynamically size the tasks such that they decrease in size towards the end.
What does round robin have to do with it? I think what saves you is that you have a lot of tasks (and fine granularity?) That way the imbalanced elements only happen at the end?
Or do you mean you do the scheduling "on the fly"?
@Mikhail If you have say 8 equally sized tasks running on 8 cores and a 9th background task kicks in, the OS will round-robin the time on the 9 tasks such that they all get roughly equal time. So the 8 tasks all get roughly the same CPU time and still all finish at roughly the same time. (though in practice, it's less ideal than this)
What if you just keep a pool of work units and as you expand the DAG, you assign new nodes to free work units? Then when a DAG node finishes, add that work unit back to the pool
And because a work unit can only be assigned once it's put into the pool again, race conditions won't be much of an issue.
@Mysticial Yeah, an alternative solution is to have 8 workers and 1024938234 elements of work that get distributed to each worker, and only push work to a non-saturated queue.
I used to see massive thread migration problem on Linux 3.14 (the one with the NT logo), but pinning them helped... Idk, the Linux scheduler is a constant battle.
@Aaron3468 No, but rather the # of tasks that can be run at the same time grows and shrinks. And to be efficient, you need to handle the cases where the tag reduces to one node, then expands again.
for (10000 items){
do something
}
// synchronize
for (10000 items){
do something
}
@Aaron3468 Correct. This is fundamental to all parallelism scheme, but it's easier to manage on some than others.
In the "pure" DAG approach - even if you know the cost of each node, you're still left with presenting the scheduler with an NP-complete problem to solve.
Yeah, kind of wasteful to spin down all the work just because you have to synchronize. A better solution is finding a way to synchronize each thread into a predictable, well defined state and make sure all the threads hit that state.
That way they just need to say "Yep, I'm done, I'll take the next task while you wait for the others"
Hmm, but how do you keep them from trampling memory the straggling threads still need? Sounds like you'd need to keep a few different memory frames for different stages. At some point, those frames might all be used up and you'll need a way to get all the threads to catch up before moving forward.
@Aaron3468 The resource management is one of the reasons why I've stayed away from the purely asynchronous approaches. (not to mention the difficulty of debugging)
It works fine if you do a purely functional approach where everything is passed in and returned by value or reference counted. But don't forget that now you've shifted the burden to a memory allocator that needs to take malloc() and free()s from a gazzilion threads at random times.
@Aaron3468 Depends on a lot of stuff. Usually, it's best to design it in a way where that doesn't happen.
In most cases, going purely functional is the best option anyway. It's easy to write, and from my experience, you only lose a factor of maybe 2x to implicit resource management by the memory allocator and other things.
As well as more memory consumption to fragmentation and other implementation specifics.
I've designed y-cruncher itself so that it doesn't touch the memory allocators at all (or very minimally). Mostly by using recursive static memory partitioning. But it's very difficult to get it right. My GitHub has purely function implementations of the same constants (so they allocate and free memory) - and while they use the same internals, the performance difference can be more than 2x.
Honestly it sounds like parallelism is a bit of black magic and hope. Sure, there's some good general rules, but it doesn't sound like there's any perfect solution yet
Well blog posts were good to understand lock-free queues, but I've never found a motivation to use those in my work. What really helped me was drawing stuff on paper.
Fuck, I keep running into GPU memory fragmentation leading to spurious crashes with Thrust...