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So I understand using var in C# makes sense because you have anonymous types that are compiler derived. C++ doesn't seem to have this feature (unless I'm wrong), so what is the point of having an auto keyword?

(It is kinda cool that unlike C#, auto does work for member/global variables, which is cool I guess, but doesn't seem enough to justify its existence).

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I wouldn't describe var using "anonymous types that are compiler derived" so much as eliminating redundant/painful* type declarations for the developer. *see LINQ EDIT: Oh wait, yeah, you can use it for the anonymous types. Disregard me. :) –  Chris Sinclair Jul 17 '13 at 1:43
That's really the only time you have to use var though. You only need to use var in a LINQ expression when the result is anonymous. –  sircodesalot Jul 17 '13 at 1:44
C++ lambdas are of anonymous types, much like C# lambdas. In that context, auto and std::function serve the same purpose as var and Func respectively. –  Jon Purdy Jul 17 '13 at 1:51
C++ lambdas are of anonymous types, much like C# lambdas. That's a good point. I ran across that not too long ago. –  sircodesalot Jul 17 '13 at 1:54
GCC and Clang have quite a bit better C++11 support than MSVC. –  chris Jul 17 '13 at 2:07

6 Answers 6

up vote 30 down vote accepted

auto has a lot of uses when it comes down to both generic programming and to save the programmer some typing.

For example, consider this. Would you rather type out:

std::unique_ptr<name::long_type::goes_here> g = 


auto g = std::make_unique<name::long_type::goes_here>(1,2,3,4)

Yes, they're both long but we know the return type and specifying it again is a bit cumbersome to type. This also goes for iterators:

for(auto i = vec.begin(); ...)


for(std::vector<type>::iterator i = vev.begin(); ...)

Its use in generic programming is also to figure out the return type of a function or if you're doing some generic algorithms where you don't know the type.

For example, consider a very basic example.

template<typename T, typename U>
auto add(T t, U u) -> decltype(t + u) {
    return t + u;

This allows the compiler to figure out the type of the add operation rather than us trying to figure it out ourselves. Note that in C++14 you can omit the trailing return type. Its uses in generic programming don't stop there either. If we wanted to work with any type of container as a wrapper function for algorithms we could use auto to help us with it. For example:

template<class Cont>
void my_sort(Cont&& cont) {
    using std::begin;
    auto first = begin(std::forward<Cont>(cont));
    // work with the iterators here

In the future (C++14), auto can be used to make polymorphic lambdas as well such as:

[](auto a) { return a + 4; }

Which can be useful as well.

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Rapptz, extracted the code to code blocks to make the differences more obvious. Hope you don't mind. Here's a +1 to compensate you if you do :-) Just kidding, the +1 is because it's a good answer. –  paxdiablo Jul 17 '13 at 1:50
@paxdiablo Thanks! I wanted to do that too :) –  Rapptz Jul 17 '13 at 1:51
@sircodesalot C++14 is a "minor" release. Not as big as C++11 but brings in some very nice things to play like polymorphic lambdas, optional, omitting the trailing return type for functions and other interesting stuff. –  Rapptz Jul 17 '13 at 2:03
@sircodesalot: "I just started downloading visual studio 2013 preview. That's insane." How is that "insane"? It's a yearly release schedule. Firefox will have eight releases in a year, with Chrome having about that many as well. If anything, VS's release schedule is slow, compared to Clang (2 per year) and GCC. –  Nicol Bolas Jul 17 '13 at 2:19
@NicolBolas: difference beeing, that VS is quite expensive… –  MFH Jul 17 '13 at 6:33

There are a number of uses for auto in C++

  1. Anonymous function objects, aka closures, aka lambda instances. auto is the only way to store them. Types can also be generated derived off those types, and types on their backs, ad infinitum.

  2. C++ can have quite complex types, such as the type of a non mutating iterator into an unordered map that uses a custom allocator and hashing function. typedef can mitigate this, but the type of a m.begin() having a particular name is not that informative: foo_iterator it = is as meaningful as auto foo_iterator =, and the auto one does not require boilerplate elsewhere.

  3. Return type deduction uses the auto keyword, which is required to do some template functions work without huge amounts of traits boilerplate. Eliminating boilerplate is a common theme: C++s robust type system means that types can carry lots of information, and encoding it at every use can be counterproductive.

  4. In some ducktype template code, the work to deduce the type of a variable is roughly the same as the work to code the variables value, and nearly identical in structure, some times literally: decltype(long expression) x = long expression;. auto eliminates that duplication.

  5. Finally in C++1y, type deduction lambdas use auto to say that an argument is a deduced one. Sort of a light weight template. Talk to extend this to non lambdas is also in skunkworks.

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+1! You organised your thoughts better than I did. –  Rapptz Jul 17 '13 at 2:09

HEre's a real life example where I could not, not use auto

I was trying to do a switch type statement in C++ where the return type is implementation specific and could not be declared easily. So using an 'auto' is probably the right way to resolve the type look up for the map declaration.

auto foo = boost::bind(&VegaFactory::load_commodity_one_leg,this,conn,_1);
std::map<std::string,decltype(foo)> methods;

auto f = methods.find(bar);
// Call f here
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This can use std::function instead of auto, so it's not quite impossible to not use auto... –  rubenvb Oct 2 '13 at 14:02

C++ does have "anonymous" types - types you cannot refer to by name because the name is not available to you. This was the case even before C++11 and lambdas. Consider the following code:

class foo {
    class bar { 
        void baz() { }
    static bar func() { return bar(); }

foo::func().baz(); // OK, only the name "bar" is private
??? a = foo::func(); // Umm...
auto b = foo::func(); b.baz(); // Hooray!

Even if not actually declared in a private scope, it is often useful for a library to leave some types unspecified in its API - especially when heavily utilizing expression templates or other template metaprogramming where the type names can be arbitrarily long with all the nested template arguments. Even the standard itself does this - for instance, the result type of std::bind is not defined by the specification.

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Oh, I see what you're getting at. Interesting. –  sircodesalot Jul 17 '13 at 14:00

syntactic sugar

I rather say

auto i = mapping.begin();


std::map<int, int>::iterator i = mapping.begin();
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It is well worth reading Herb Sutter's article Almost Always Auto for some great examples of why it's worth using auto over explicit types. The main advantages are the reduction in typing, and gives additional safety if the underlying types change. One of my favourite examples though is about how it reduces duplication. If you allocate on the stack then you'd use:

MyClass c(param);

However, if you want to create on the heap you need:

MyClass* c=new MyClass(param);

So you've had to duplicate the MyClass, but the RHS already forces the variable to be a MyClass pointer, so you can just use this instead:

auto c=new MyClass(param);

If you want to declare it as a unique_ptr then previously you would need:

unique_ptr<MyClass> c=make_unique<MyClass>(param);

which can be abbreviated to:

auto c=make_unique<MyClass>(param);
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