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I don't understand why the array decays to a pointer in a template function.

If you look at the following code: When the parameter is forced to be a reference (function f1) it does not decay. In the other function f it decays. Why is the type of T in function f not const char (buff&)[3] but rather const char* (if I understand it correctly)?

#include <iostream>

template <class T>
void f(T buff) {
    std::cout << "f:buff size:" << sizeof(buff) << std::endl;       //prints 4
}

template <class T>
void f1(T& buff) {
    std::cout << "f:buff size:" << sizeof(buff) << std::endl;       //prints 3
}

int main(int argc, char *argv[]) {
    const char buff[3] = {0,0,0};
    std::cout << "buff size:" << sizeof(buff) << std::endl;         //prints 3
    f(buff);
    f1(buff);
    return 0;
}
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6 Answers

up vote 5 down vote accepted

Because arrays can not be passed by value as a function parameter.
When you pass them by value they decay into a pointer.

In this function:

template <class T>
void f(T buff) {

T can not be char (&buff)[3] as this is a reference. The compiler would have tried char (buff)[3] to pass by value but that is not allowed. So to make it work arrays decay to pointers.

Your second function works because here the array is passed by reference:

template <class T>
void f1(T& buff) {

// Here T& => char (&buff)[3]
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I believe the reason they cannot be passed by value is related to the lack of copy/assignment. (Though why that's all missing is beyond me) –  Mooing Duck Oct 17 '11 at 18:33
    
@MooingDuck: In C++ the reason is that the particular behavior was inherited from C. In C the reason would be different, of course... –  David Rodríguez - dribeas Oct 17 '11 at 18:37
1  
@MooingDuck : And of course that's one of the things that makes std::array<> immediately superior to raw C-arrays. –  ildjarn Oct 17 '11 at 18:43
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To quote from spec, it says

(14.8.2.1/2) If P is not a reference type: — If A is an array type, the pointer type produced by the array-to-pointer standard conversion (4.2) is used in place of A for type deduction; otherwise

So, in your case, It is clear that,

template <class T>
void f1(T& buff) {
    std::cout << "f:buff size:" << sizeof(buff) << std::endl;       //prints 3
}

doesn't decay into pointer.

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It is because arrays cannot be passed by value to a function. So in order to make it work, the array decays into a pointer which then gets passed to the function by value.

In other words, passing an array by value is akin to initializing an array with another array, but in C++ an array cannot be initialized with another array:

char buff[]3] = {0,0,0};
char x[3] = buff; //error 

So if an array appears on the right hand side of =, the left hand side has to be either pointer or reference type:

char *y = buff; //ok - pointer
char (&z)[3] = buff; //ok - reference

Demo : http://www.ideone.com/BlfSv

It is exactly for the same reason auto is inferred differently in each case below (note that auto comes with C++11):

auto a = buff; //a is a pointer - a is same as y (above)
std::cout << sizeof(a) << std::endl; //sizeof(a) == sizeof(char*)

auto & b = buff; //b is a reference to the array - b is same as z (above)
std::cout << sizeof(b) << std::endl; //sizeof(b) == sizeof(char[3])

Output:

4 //size of the pointer
3 //size of the array of 3 chars

Demo : http://www.ideone.com/aXcF5

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Because functions can't have arrays as arguments. They can have array references though.

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The reason basically boils down to type deduction when matching the different overloads. When you call f the compiler deduces the type to be const char[3] which then decays into const char* because that's what arrays do. This is done in the same exact way that in f(1) the compiler deduces T to be int and not int&.

In the case of f1 because the argument is taken by reference, then the compiler again deduces T to be const char[3], but it takes a reference to it.

Nothing really surprising, but rather consistent if it were not for the decay of arrays to pointers when used as function arguments...

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In f1(), Size 4 is size of pointer which is 4 bytes. because in this function you have a pointer to the array.

In f1(), you have that array by reference(or another name), and it is real array size.

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