Will it be possible to specialize std::optional for user-defined types? If not, is it too late to propose this to the standard?

My use case for this is an integer-like class that represents a value within a range. For instance, you could have an integer that lies somewhere in the range [0, 10]. Many of my applications are sensitive to even a single byte of overhead, so I would be unable to use a non-specialized std::optional due to the extra bool. However, a specialization for std::optional would be trivial for an integer that has a range smaller than its underlying type. We could simply store the value 11 in my example. This should provide no space or time overhead over a non-optional value.

Am I allowed to create this specialization in namespace std?

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    In that case, define your own optional class. It is not that hard to do. – Nawaz Sep 29 '13 at 17:45
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    But it would be much nicer for the users of my class to just be able to type std::optional<whatever type they want>, rather than having to remember that my type is special and should be stored in its own optional class for maximum efficiency. – David Stone Sep 29 '13 at 18:06
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    If your type's usage is heavily dependent on it having a specified size, degree of efficiency or other such constraints, then it is special and it should be handled by its own/related facilities. C++ offers, by design, very little guarantees about specific requirements for data types beyond what you have with eg.: uint32_fast_t within its standard utilities. – Luis Machuca Sep 29 '13 at 21:12
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    I disagree. The whole point of using C++ over C is that it gives you better abstractions with zero cost. The semantics of an overloaded optional would be identical. The code to use it would be identical. Why should I make my users use a separate class when there are no technical (other than the restriction in the standard on putting things in namespace std) reasons that they have to do so? – David Stone Oct 1 '13 at 0:17
  • It would be as if C++ made you use a special fast_multiply function if you wanted performance from multiplication that you use for short, but the regular old operator * was there just to trip you up in case you accidentally use it. And when my users are trying to use a "generic integer type" in template code that could be my class or it could be a built-in integer, should they be expected to write a the_optional_I_mean_to_use alias template to pick the correct one, even though there is no reason they would ever want the default version? – David Stone Oct 1 '13 at 0:19
up vote 9 down vote accepted

The general rule in [namespace.std]/1 applies:

A program may add a template specialization for any standard library template to namespace std only if the declaration depends on a user-defined type and the specialization meets the standard library requirements for the original template and is not explicitly prohibited.

So I would say it's allowed.

N.B. optional will not be part of the C++14 standard, it will be included in a separate Technical Specification on library fundamentals, so there is time to change the rule if my interpretation is wrong.

If you are after a library that efficiently packs the value and the "no-value" flag into one memory location, I recommend looking at compact_optional. It does exactly this.

It does not specialize boost::optional or std::experimental::optional but it can wrap them inside, giving you a uniform interface, with optimizations where possible and a fallback to 'classical' optional where needed.

I've asked about the same thing, regarding specializing optional<bool> and optional<tribool> among other examples, to only use one byte. While the "legality" of doing such things was not under discussion, I do think that one should not, in theory, be allowed to specialize optional<T> in contrast to eg.: hash (which is explicitly allowed).

I don't have the logs with me but part of the rationale is that the interface treats access to the data as access to a pointer or reference, meaning that if you use a different data structure in the internals, some of the invariants of access might change; not to mention providing the interface with access to the data might require something like reinterpret_cast<(some_reference_type)>. Using a uint8_t to store a optional-bool, for example, would impose several extra requirements on the interface of optional<bool> that are different to the ones of optional<T>. What should the return type of operator* be, for example?

Basically, I'm guessing the idea is to avoid the whole vector<bool> fiasco again.

In your example, it might not be too bad, as the access type is still your_integer_type& (or pointer). But in that case, simply designing your integer type to allow for a "zombie" or "undetermined" value instead of relying on optional<> to do the job for you, with its extra overhead and requirements, might be the safest choice.

  • I understand why the standard committee would be hesitant to define their own specializations, but it seems that allowing it would be beneficial when it can be done without changing the interface. In the tribool case, the storage requirements are to ultimately contain uint8_least_t. You would then have one more value possible (0, 1, 2, and 3), but the value of "3" would only be settable when stored in an optional. Then users of the non-optional class know that it is a real instance without worrying about zombie states and users of optional wouldn't know that you made this optimization. – David Stone Oct 1 '13 at 0:31
  • @DavidStone I started checking out doing this, and my leanings are to agree with this answer. The problem is not the specialization or the namespace...it's the sematnics. Trying to make a std::optional<T> without a T somewhere inside your specialization is going to be a problem. – HostileFork Nov 19 '14 at 20:15
  • Adding to my last paragraph I think I saw at some points in the C++ STD Proposals forum a proposal for a "degenerate enumeration type", basically a type interface for an integral type with a singular value marked out as "zombie" or "undetermined". That was about two months ago but might be worth to check it out. – Luis Machuca Nov 22 '14 at 0:50
  • @HostileFork: In my case, the specialized std::optional<T> would contain a T in it. In general, this could be done by way of a private constructor that sets up this special state (that is only used by optional) and declaring std::optional<T> a friend of your T. – David Stone Nov 22 '14 at 22:23
  • @DavidStone Interestingly enough...after answering I did the same thing, here's an unfinished blog article about it. Instead of private construction I made writeOptional and a testOptional friend methods. It's definitely a bit dodgy, though. I'll finish that entry at some point, hopefully, but I want to get the code more finalized. – HostileFork Nov 23 '14 at 1:25

I don't see how allowing or not allowing some particular bit pattern to represent the unengaged state falls under anything the standard covers.

If you were trying to convince a library vendor to do this, it would require an implementation, exhaustive tests to show you haven't inadvertently blown any of the requirements of optional (or accidentally invoked undefined behavior) and extensive benchmarking to show this makes a notable difference in real world (and not just contrived) situations.

Of course, you can do whatever you want to your own code.

  • My concern would be that I could not specialize templates in namespace std unless explicitly stated in the standard. It turns out that I got it backward, and that I can specialize any template unless prohibited (as long as I am doing so for a user-defined type). – David Stone Oct 2 '13 at 23:29

Make it easy to opt-in to space savings

I have decided that this is a useful thing to do, but a full specialization is a little more work than necessary (for instance, getting operator= correct).

I have posted on the Boost mailing list a way to simplify the task of specializing, especially when you only want to specialize some instantiations of a class template.


My current interface involves a special tag type used to 'unlock' access to particular functions. I have creatively named this type optional_tag. Only optional can construct an optional_tag. For a type to opt-in to a space-efficient representation, it needs the following member functions:

  • T(optional_tag) constructs an uninitialized value
  • initialize(optional_tag, Args && ...) constructs an object when there may be one in existence already
  • uninitialize(optional_tag) destroys the contained object
  • is_initialized(optional_tag) checks whether the object is currently in an initialized state

By always requiring the optional_tag parameter, we do not limit any function signatures. This is why, for instance, we cannot use operator bool() as the test, because the type may want that operator for other reasons.

An advantage of this over some other possible methods of implementing it is that you can make it work with any type that can naturally support such a state. It does not add any requirements such as having a move constructor.

You can see a full code implementation of the idea at


and for a class using the specialization:


(lines 220 through 242)

An alternative approach

This is in contrast to my previous implementation, which required users to specialize a class template. You can see the old version here:




The problem with this approach is that it is simply more work for the user. Rather than adding four member functions, the user must go into a new namespace and specialize a template.

In practice, all specializations would have an in_place_t constructor that forwards all arguments to the underlying type. The optional_tag approach, on the other hand, can just use the underlying type's constructors directly.

In the specialize optional_storage approach, the user also has the responsibility of adding proper reference-qualified overloads of a value function. In the optional_tag approach, we already have the value so we do not have to pull it out.

optional_storage also required standardizing as part of the interface of optional two helper classes, only one of which the user is supposed to specialize (and sometimes delegate their specialization to the other).

The difference between this and compact_optional

compact_optional is a way of saying "Treat this special sentinel value as the type being not present, almost like a NaN". It requires the user to know that the type they are working with has some special sentinel. An easily specializable optional is a way of saying "My type does not need extra space to store the not present state, but that state is not a normal value." It does not require anyone to know about the optimization to take advantage of it; everyone who uses the type gets it for free.

The future

My goal is to get this first into boost::optional, and then part of the std::optional proposal. Until then, you can always use bounded::optional, although it has a few other (intentional) interface differences.

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