Recently I've gotten suggestions to use span<T>'s in my code, or have seen some answers here on the site which use span's - supposedly some kind of container. But - I can't find anything like that in the C++ standard library.

So what is this mysterious span<T>, and why (or when) is it a good idea to use it if it's non-standard?

  • std::span was proposed in 2017. It applies to C++17 or C++20. Also see P0122R5, span: bounds-safe views for sequences of objects. Do you really want to target that language? It will be years before compilers catch up. – jww Jan 24 at 0:29
  • @jww: span's are quite usable with C++11... as gsl::span rather than std::span. See also my answer below. – einpoklum Jan 24 at 6:39
up vote 170 down vote accepted

What is it?

A span<T> is:

  • A very lightweight abstraction of a contiguous sequence of values of type T somewhere in memory.
  • Basically a struct { T * const ptr; size_t length; } with a bunch of convenience methods.
  • A non-owning type (i.e. a "reference-type" rather than a "value type"): It never allocates nor deallocates anything and does not keep smart pointers alive.

It was formerly known as an array_view and even earlier as array_ref.

When should I use it?

First, when not to use it:

  • Don't use it in code that could just take any pair of start & end iterators, like std::sort, std::find_if, std::copy and all of those super-generic templated functions.
  • Don't use it if you have a standard library container (or a Boost container etc.) which you know is the right fit for your code. It's not intended to supplant any of them.

Now for when to actually use it:

Use span<T> (respectively, span<const T>) instead of a free-standing T* (respectively const T*) for which you have the length value. So, replace functions like:

  void read_into(int* buffer, size_t buffer_size);

with:

  void read_into(span<int> buffer);

Why should I use it? Why is it a good thing?

Oh, spans are awesome! Using a span...

  • means that you can work with that pointer+length / start+end pointer combination like you would with a fancy, pimped-out standard library container, e.g.:

    • for (auto& x : my_span) { /* do stuff */ }
    • std::find_if(my_span.begin(), my_span.end(), some_predicate);

    ... but with absolutely none of the overhead most container classes incur.

  • lets the compiler do more work for you sometimes. For example, this:

    int buffer[BUFFER_SIZE];
    read_into(buffer, BUFFER_SIZE);
    

    becomes this:

    int buffer[BUFFER_SIZE];
    read_into(buffer);
    

    ... which will do what you would want it to do. See also Guideline P.5.

  • is the reasonable alternative to pass const vector<T>& to functions when you expect your data to be contiguous in memory. No more getting scolded by high-and-mighty C++ gurus.

  • facilitates static analysis, so the compiler might be able to help you catch silly bugs.

  • allows for debug-compilation instrumentation for runtime bounds-checking (i.e. span's methods will have some bounds-checking code within #ifndef NDEBUG ... #endif)
  • indicates that your code (that's using the span) doesn't own the pointer.

There's even more motivation for using spans, which you could find in the C++ core guidelines - but you catch the drift.

Why is it not in the standard library (as of C++17)?

It is in the standard library - but only as of C++20. The reason is that it's still pretty new in its current form, conceived in conjunction with the C++ core guidelines project, which has only been taking shape since 2015. (Although as commenters point out, it has earlier history.)

So how do I use it if it's not in the standard library yet?

It's part of the Core Guidelines's Support Library (GSL). Implementations:

  • Microsoft / Neil Macintosh's GSL contains a standalone implementation: gsl/span
  • GSL-Lite is a single-file implementation of the whole GSL (it's not that big, don't worry), including span<T>.

Note that you can use it with earlier versions of the language standard - C++11 and C++14, not just C++17.


Further reading: You can find all the details and design considerations in the final official proposal before C++17, P0122R7: span: bounds-safe views for sequences of objects by Neal Macintosh and Stephan J. Lavavej. It's a bit long though. Also, in C++20, the span comparison semantics changed (following this short paper by Tony van Eeerd).

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    Wouldn't read_into(int* from, int* to) be way more in line with the usual (iterator based) approach of the standard library? – Daniel Jour Aug 17 '17 at 10:44
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    It would make more sense to standardize a general range (supporting iterator+sentinel and iterator+length, maybe even iterator+sentinel+length) and make span a simple typedef. Because, you know, that's more generic. – Deduplicator Aug 17 '17 at 12:47
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    @Deduplicator: Ranges are coming to C++, but the current proposal (by Eric Niebler) requires support for Concepts. So not before C++20. – einpoklum Aug 17 '17 at 12:52
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    Can you explain how span can know the size of an array while it is constructed just by the array pointer alone ? Is it due to span can read the bytes next to the pointer to get the size info (I guess these bytes are also allocated by new or malloc, so they can correctly delete it later)? I can not find any article about this, and hint is appreciated. Thanks. – Hải Phạm Lê Aug 22 '17 at 13:20
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    @HảiPhạmLê: Arrays don't immediately decay into pointers. try doing std::cout << sizeof(buffer) << '\n' and you'll see you get 100 sizeof(int)'s. – einpoklum Aug 23 '17 at 7:59

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