Templates
Function
templates
Function templates are special functions that can operate
with generic types. This allows us to create a function template whose
functionality can be adapted to more than one type or class without repeating
the entire code for each type.
In C++ this can be achieved using template parameters. A template parameter is a special kind of parameter that can be used to pass a type as argument: just like regular function parameters can be used to pass values to a function, template parameters allow to pass also types to a function. These function templates can use these parameters as if they were any other regular type.
The format for declaring function templates with type parameters is:
template <class identifier> function_declaration;
template <typename identifier> function_declaration;
The only difference between both prototypes is the use of either the keyword class or the keyword typename. Its use is indistinct, since both expressions have exactly the same meaning and behave exactly the same way.
For example, to create a template function that returns the greater one of two objects we could use:
In C++ this can be achieved using template parameters. A template parameter is a special kind of parameter that can be used to pass a type as argument: just like regular function parameters can be used to pass values to a function, template parameters allow to pass also types to a function. These function templates can use these parameters as if they were any other regular type.
The format for declaring function templates with type parameters is:
template <class identifier> function_declaration;
template <typename identifier> function_declaration;
The only difference between both prototypes is the use of either the keyword class or the keyword typename. Its use is indistinct, since both expressions have exactly the same meaning and behave exactly the same way.
For example, to create a template function that returns the greater one of two objects we could use:
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template <class myType>
myType GetMax (myType a, myType b)
{
return (a>b?a:b);
}
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Here we have created a template function with myType as its template parameter. This template parameter represents a type that has not yet been specified, but that can be used in the template function as if it were a regular type. As you can see, the function template GetMax returns the greater of two parameters of this still-undefined type.
To use this function template we use the following format for the function call:
function_name <type> (parameters);
For example, to call GetMax to compare two integer values of type int we can write:
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int
x,y;
GetMax <int>
(x,y);
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When the compiler encounters this call to a template function, it uses the template to automatically generate a function replacing each appearance of myType by the type passed as the actual template parameter (int in this case) and then calls it. This process is automatically performed by the compiler and is invisible to the programmer.
Here is the entire example:
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// function template
#include <iostream>
using namespace std;
template <class T>
T GetMax (T a, T b) {
T result;
result = (a>b)? a : b;
return (result);
}
int
main () {
int i=5, j=6, k;
long l=10, m=5, n;
k=GetMax<int>(i,j);
n=GetMax<long>(l,m);
cout << k << endl;
cout << n << endl;
return 0;
}
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In this case, we have used T as the template parameter name instead of myType because it is shorter and in fact is a very common template parameter name. But you can use any identifier you like.
In the example above we used the function template GetMax() twice. The first time with arguments of type int and the second one with arguments of type long. The compiler has instantiated and then called each time the appropriate version of the function.
As you can see, the type T is used within the GetMax() template function even to declare new objects of that type:
T result;
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Therefore, result will be an object of the same type as the parameters a and b when the function template is instantiated with a specific type.
In this specific case where the generic type T is used as a parameter for GetMax the compiler can find out automatically which data type has to instantiate without having to explicitly specify it within angle brackets (like we have done before specifying <int> and <long>). So we could have written instead:
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int
i,j;
GetMax (i,j);
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Since both i and j are of type int, and the compiler can automatically find out that the template parameter can only be int. This implicit method produces exactly the same result:
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// function template II
#include <iostream>
using namespace std;
template <class T>
T GetMax (T a, T b) {
return (a>b?a:b);
}
int
main () {
int i=5, j=6, k;
long l=10, m=5, n;
k=GetMax(i,j);
n=GetMax(l,m);
cout << k << endl;
cout << n << endl;
return 0;
}
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Notice how in this case, we called our function template GetMax() without explicitly specifying the type between angle-brackets <>. The compiler automatically determines what type is needed on each call.
Because our template function includes only one template parameter (class T) and the function template itself accepts two parameters, both of this T type, we cannot call our function template with two objects of different types as arguments:
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int
i;
long
l;
k = GetMax (i,l);
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This would not be correct, since our GetMax function template expects two arguments of the same type, and in this call to it we use objects of two different types.
We can also define function templates that accept more than one type parameter, simply by specifying more template parameters between the angle brackets. For example:
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template <class T, class
U>
T GetMin (T a, U b) {
return (a<b?a:b);
}
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In this case, our function template GetMin() accepts two parameters of different types and returns an object of the same type as the first parameter (T) that is passed. For example, after that declaration we could call GetMin() with:
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int
i,j;
long
l;
i = GetMin<int,long>
(j,l);
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or simply:
i = GetMin (j,l);
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even though j and l have different types, since the compiler can determine the appropriate instantiation anyway.
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