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The std::unique_ptr template has two parameters: the type of the pointee, and the type of the deleter. This second parameter has a default value, so you usually just write something like std::unique_ptr<int>.

The std::shared_ptr template has only one parameter though: the type of the pointee. But you can use a custom deleter with this one too, even though the deleter type is not in the class template. The usual implementation uses type erasure techniques to do this.

Is there a reason the same idea was not used for std::unique_ptr?

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@jons34 Thanks for fixing the links! –  R. Martinho Fernandes Oct 26 '12 at 18:58

2 Answers 2

up vote 27 down vote accepted

Part of the reason is that shared_ptr needs an explicit control block anyway for the ref count and sticking a deleter in isn't that big a deal on top. unique_ptr however doesn't require any additional overhead, and adding it would be unpopular- it's supposed to be a zero-overhead class. unique_ptr is supposed to be static.

You can always add your own type erasure on top if you want that behaviour- for example, you can have unique_ptr<T, std::function<void(T*)>>, something that I have done in the past.

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+1. Type erasure isn't a "good thing", it's more like a necessary evil. If you can get away with a simpler solution, then you should. unique_ptr is a much simpler and lighter-weight smart pointer than shared_ptr. –  Kerrek SB Jul 26 '11 at 12:29
    
@DeadMG: I don't get the "unique_ptr is supposed to be static" part. What does that mean -- specifically, the usage of "static"? –  Jon May 28 at 12:44
    
@Jon: It means that it should not resolve the functionality used dynamically- the compiler should statically resolve all calls involved. This enables it to compete against your momma's best home-rolled C code w.r.t. performance in all respects. –  Puppy May 28 at 13:26
    
@DeadMG: So, "static" in this context is a weaker version of "zero-overhead" (which I read as "static and also no bigger mem footprint"). That clears it up, thanks. –  Jon May 28 at 13:36

Another reason, in addition to the one pointed out by DeadMG, would be that it's possible to write

std::unique_ptr<int[]> a(new int[100]);

and ~unique_ptr will call the correct version of delete (via default_delete<_Tp[]>) thanks to specializing for both T and T[].

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I don't see how that changes much. You could specialise for T[] without the deleter parameter. –  R. Martinho Fernandes Jul 26 '11 at 13:25
    
Yes, it would be possible, but less elegant and less flexible, as it would be hardcoded inside unique_ptr, not the deleter. Note that you could plug in a foo_delete which could do something completely different, too. Having a deleter that manually runs the destructor and then marks objects for later reclamation by a GC would be a fun thing, for example. The smart pointer wouldn't need to know at all. –  Damon Jul 26 '11 at 14:56
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Just as shared_ptr doesn't need to know. You could do the same type erasure tricks when specializing for T[], no? –  R. Martinho Fernandes Jul 26 '11 at 15:04
    
Not sure... maybe, maybe not. The same line of code using shared_ptr fails to compile, which shows that shared_ptr apparently doesn't specialize. Assuming that the standard library writers don't randomly include/exclude key functionality which is easy to incorporate on a how-do-you-feel-today base, it seems that there must be a considerable, non-obvious hindrance somewhere. –  Damon Jul 26 '11 at 15:38
    
@Damon: T[] specialization is not at all key functionality. I don't even know why it's in unique_ptr. We already have std::vector<T> for this purpose. –  Puppy Jun 6 '12 at 19:06

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