I am coming from the other direction: started using
pthreads in my application, which I recently replaced with C++11's
std::thread. Now, I am playing with higher-level constructs like the pseudo-boost threadpool, and even more abstract, Intel's Threading Building Blocks. I would consider GCD to be at or even higher than TBB.
A few comments:
- imho, pthread is not more complex than GCD: at its basic core, pthread actually contains very few commands (just a handful: using just the ones mentioned in the OP will give you 95%+ of the functionality that you ever need). Like any lower-level library, it's how you put them together and how you use it which gives you its power. Don't forget that the ultimately, libraries like GCD and TBB will call a threading library like
- sometimes, it's not what you use, but how you use it, which determines success vs failure. As proponents of the library, TBB or GCD will tell you about all the benefits of using their libraries, but until you try them out in a real application context, all of it is of theoretical benefit. For example, when I read about how easy it was to use a finely-grained parallel_for, I immediately used it in a task for which I thought could benefit from parallelism. Naturally, I, too, was drawn by the fact that TBB would handle all the details about optimal loading balancing and thread allocation. The result? TBB took five times longer than the single-threaded version! But I do not blame TBB: in retrospect, this is obviously a case of a misuse of the parallel_for: when I read the fine-print, I discovered the overhead involved in using parallel_for and posited that in my case, the costs of context-switching and added function calls outweighed the benefits of using multiple threads. So you must profile your case to see which one will run faster. You may have to reorganize your algorithm to use less threading overhead.
- why does this happen? How can pthread or no threads be faster than a GCD or a TBB? When a designer designs GCD or TBB, he must make assumptions about the environment in which tasks will run. In fact, the library must be general enough that it can handle strange, unforseen use-cases by the developer. These general implementations will not come for free. On the plus-side, a library will query the hardware and the current running environment to do a better job of load-balancing. Will it work to your benefit? The only way to know is to try it out.
- is there any benefit to learning lower-level libraries like
std::thread when higher-level libraries are available? The answer is a resounding YES. The advantage of using higher-level libraries is, abstraction from the implementation details. The disadvantage of using higher-level libraries is also abstraction from the implementation details. When using
pthreads, I am supremely aware of shared state and lifetimes of objects, because if I let my guard down, especially in a medium to large size project, I can very easily get race conditions or memory faults. Do these problems go away when I use a higher-level library? Not really. It seems like I don't need to think about them, but in fact, if I get sloppy with those details, the library implementation will also crash. So you will find that if you understand the lower-level constructs, all those libraries actually make sense, because at some point, you will be thinking about implementing them yourself, if you use the lower-level calls. Of course, at that point, it's usually better to use a time-tested and debugged library call.
So, let's break down the possible implementations:
- TBB/GCD library calls: greatest benefit is for beginners of threading. They have lower barriers to entry compared to learning lower level libraries. However, they also ignore/hide some of the traps of using multi-threading. Dynamic load balancing will make your application more portable without additional coding on your part.
std::thread calls: there are actually very few calls to learn, but to use them correctly takes attention to detail and deep awareness of how your application works. If you can understand threads at this level, the APIs of higher-level libraries will certainly make more sense.
- single-threaded algorithm: let us not forget the benefits of a simple single-threaded segment. For most applications, a single-thread is easier to understand and much less error-prone than multi-threading. In fact, in many cases, it may be the appropriate design choice. The fact of the matter is, a real application goes through various multi-threading phases and single-threading phases: there may be no need to be multi-threaded all the time.
Which one is fastest? The surprising truth is, it could be any of the three of the above. To get speed benefits of multi-threading, you may need to drastically reorganize your algorithms. Whether or not the benefits outweigh the costs is highly case-dependent.
Oh, and the OP asked about cases where a thread_pool is not appropriate. Easy case: if you have a tight loop that does not require many cycles per loop to compute, using thread_pool may cost more than the benefits without serious reworking. Also be aware of the overhead of function calls like lambda through thread pools vs the use of a single tight loop.
For most applications, multi-threading is a kind of optimization, so do it at the right time and in the right places.