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I was reading cpp-next where this min template is presented as an example of how verbose C++ code can be compared to python code

template <class T, class U>
auto min(T x, U y)->decltype(x < y ? x : y)
{ return x < y ? x : y; }

At first this looks innocent but Daveed Vandevoorde made this remark

The min template that uses decltype in its return type specification doesn’t work: It returns a reference (because the argument is an lvalue) that ends up referring to a local variable in most common uses.

I figured it may not be clear to everyone how the problem manifests. Can you please give a detailed explanation and possible fixes?

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I am waiting for you to post the answer now, pleaseee.. :) – Alok Save Nov 19 '11 at 15:53
I'm a bit curious in regards to what happens if T and U are different types? Will that even work? – ronag Nov 19 '11 at 16:05
@ronag: If they are somehow convertible to a common "base". :) float and int should both be convertible to float, which will be the type of the expression. – Xeo Nov 19 '11 at 16:07
So in the end, for those of us who don't really get the details (the code in e.g. @Potatoswatter is too complex for me), what are we supposed to write? a min function with only one template parameter (i.e. with no trick to compute the return type)? – rafak Nov 20 '11 at 13:50
For C++03, the promote template can be used to compute the return type :) – Johannes Schaub - litb Nov 21 '11 at 22:35

The problem is that the arguments aren't taken as references. This invokes slicing, in the case of polymorphic types, and then a reference return to local variable. The solution is to take the arguments as rvalue references, invoking perfect forwarding, and then simply deduce and return the return type. When this is done, returning a reference is just fine, as the value still exists.

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+1 for correct idea - I suppose the first sentence doesn't lack the absence of a negation – sehe Nov 19 '11 at 17:47
I disagree. The problem is returning by reference, because then you can do: float& f = std::min(3.0f, 1); which is incorrect. – Matthieu M. Nov 19 '11 at 18:30
+1 Tried and failed to do this for C++11: – Howard Hinnant Nov 19 '11 at 20:26
@Matthieu: No, you can't, because the result of ?: when both it's parameters are rvalues is an rvalue. – Puppy Nov 19 '11 at 21:37
@DaveAbrahams: But not trying to return a reference is wrong. You should be able to do things like std::min(a, b) = 5; if a and b are both int, for example. – Puppy Nov 21 '11 at 9:54

rev 3: KonradRudolph

template <class T, class U>
auto min(T x, U y) -> typename std::remove_reference<decltype(x < y ? x : y)>::type
    return x < y ? x : y; 

rev 2: KennyTM

template <class T, class U>
auto min(T x, U y)->decltype(x < y ? std::declval<T>() : std::declval<U>())
    return x < y ? x : y; 

rev 1: T and U must be default constructible

template <class T, class U>
auto min(T x, U y)->decltype(x < y ? T() : U())
    return x < y ? x : y; 


int main()
   int x; int y;
   static_assert(std::is_same<decltype(min(x, y)), int>::value, "");
   return 0;


I'm a bit surprised but it actually compiles with remove_reference.

share|improve this answer
No, T and U will be int. – Xeo Nov 19 '11 at 16:00
Xeo: Yes you are right. I pretty much contradicted myself with the cause and fix. I've changed my answer. – ronag Nov 19 '11 at 16:03
This of course requires T and U to be default-constructible. Can’t we use a call to some id function to get a temporary from either x or y to force use of a non-reference? … Or just remove_reference – Konrad Rudolph Nov 19 '11 at 17:05
@KonradRudolph: std::declval<T>(). – kennytm Nov 19 '11 at 17:13
@KennyTM But that returns an rvalue reference, hence we’ve got the same problem as before, don’t we? – Konrad Rudolph Nov 19 '11 at 17:17

The arguments are passed by value (T and U deduced as int), but the type of ?: expression is deduced as a reference in this case since they are local lvalues inside the function. Specifics will be in @Johannes' answer that should come in a few minutes. :D

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i'm just confused :( i don't know about the tricky rules behind all this. – Johannes Schaub - litb Nov 19 '11 at 16:05
@Johannes: Sure. And I'm sure everyone will believe you don't know. ;) – Xeo Nov 19 '11 at 16:06
why deduced as reference? next code say no void f2(int x, long y) {cout << is_reference<decltype(x < y ? x : y)>::value << endl;} – Yola Dec 15 '11 at 17:41
@yola, that's because int and long are quite different types. No single reference type can link to both. But if x and y were of the same integral types, then it would be a reference. – Aaron McDaid Dec 21 '11 at 1:57

What's all the fuss, and why isn't anyone trying the obvious solution, which is perfect forwarding?

template <class T, class U>
typename std::enable_if< ! std::is_integral< T >() || ! std::is_integral< U >(),
                         typename std::common_type< T, U >::type >::type
min(T &&x, U &&y)
    { return x < y ? std::forward< T >( x ) : std::forward< U >( y ); }

template <class T, class U>
decltype( typename std::enable_if< std::is_integral< T >() && std::is_integral< U >(),
                         decltype( typename std::common_type< T, U >
         ::type{ U( -1 ) } ) >::type{ T( -1 ) } )
min(T &&x, U &&y)
    { return x < y ? std::forward< T >( x ) : std::forward< U >( y ); }

Now it works just as if you put the expression in the calling function, which is exactly what the user expects (and simply the best thing overall).

Edit: Now it prohibits dangerous unsigned vs. signed operations, per Howard's paper, by requiring that the conversion from each operand type to the result type be non-narrowing if both operands are of integral type. However, GCC won't compile this, complaining "sorry, unimplemented: mangling constructor." This seems to occur if uniform initialization is used in any way in the function signature.

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@DeadMG has already given this solution, although he was missing code :) – Johannes Schaub - litb Nov 20 '11 at 1:03
@JohannesSchaub-litb updated to add one of Howard's features as well. – Potatoswatter Nov 21 '11 at 15:21

Returning by reference might sometimes be a feature, not a bug. We'll return to this later. First a recap of the basics:

int x; int y;
x    // this is an lvalue
y    // lvalue also
x+y  // not an lvalue - you couldn't do (x+y) = 3
x<y?x:y // lvalue - you can do (x<y?x:y) = 0

The last line shows that a ?: can often be an lvalue. i.e. You can do (x<y?x:y)=0 to set the smallest variable to 0 and leave the other one alone. Of course, you can't do (1<3?6:8)=0 as you can't do 6=0 or 8=0. So it's just an rvalue in that case.

Inside min, x and y are the names of the function parameters and hence are lvalues. decltype(x<y?:x:y) is int&. (I found this other cpp-Next article useful also.)

So why might this be a problem? Well, if the return type of min is a reference, then it will return a reference to one of x or y, the function parameters. The question now is, were x and y references themselves?

Consider this use case:

int m = 5; int n = 10;
min(m,n) = 0; // do you want this to work?

We have a decision to make. Maybe we want min to return references, if the arguments to min were references. I guess it's somewhat a matter of taste. If you rigorous want to return only non-references, this is easy to enforce with std::remove_reference around the decltype(x<y?x:y). But that's boring. Let's allow ourselves to (sometimes) return references; it might be more efficient and useful in many cases.

If you use the original example definition of min, along with non-reference types for x or y, then min will return a reference to the local values among its parameters. This is bad as the references will be invalid and the behaviour undefined. For example, this would be bad:

int p = min(5,8); // reading from a now-invalid reference.

So, we have to go through a variety of use-cases and decide what behaviour we want:

// Desired behaviour
int m = 5;
int n = 10;
min(3,7); // return by value. i.e. return an int
min(m,n); // return an int& which maps to either m or n
min(3,n); // return by value
min(foo(), bar()) // what makes sense here?

Can we all agree on what behaviour we would want from such a min? And then, how do we implement it?

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I won't be online for the next few hours. Feel free to edit extensively. – Aaron McDaid Dec 21 '11 at 2:36

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