# return multiply argument from function [closed]

i know that there exist similar question here but i saw this algorithm during these days and surprised how it is implemented.consider following function

``````int divide(int numerator, int denominator, int &remainder) {
remainder = numerator % denominator;
return numerator / denominator;
}
``````

it is function implemented by references not by values itself and here is final code

``````int main() {
int num = 14;
int den = 4;
int rem;
int result = divide(num, den, rem);
cout << result << "*" << den << "+" << rem << "=" << num << endl;
``````

} result will be written in comment form

``````// 3*4+2=12
``````

just my question is while function returns one value from divide function scope,how it can determine second or reminder term?please help me.it is token from MIT official site .thanks a lot

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## closed as not a real question by Armen Tsirunyan, cdeszaq, Andrey, Jon, GravitonSep 15 '11 at 6:05

It's difficult to tell what is being asked here. This question is ambiguous, vague, incomplete, overly broad, or rhetorical and cannot be reasonably answered in its current form. For help clarifying this question so that it can be reopened, visit the help center.If this question can be reworded to fit the rules in the help center, please edit the question.

I don't understand what you're asking –  Armen Tsirunyan Sep 14 '11 at 13:56
You already know the answer. Pass by reference. –  vivek Sep 14 '11 at 13:56
As a full English sentence, your question translates to “How does the the divide() function determine the remainder parameter?” I don’t think you’re looking for the answer to that question, which is simply “It uses the variable named ‘remainder’, which is identified as the second formal parameter to the function.” You will need to re-phrase your question to get a meaningful answer. –  danorton Sep 14 '11 at 14:02
ok i have understood everything thanks a lot –  dato datuashvili Sep 14 '11 at 14:03

The value inside of the variable `rem` will be the remainder value after the function has completed. This is because the `divide()` function accepted the `remainder` argument as a reference-type, meaning that when the reference-variable is accessed inside the `divide()` function body, it is actually accessing the original variable location in memory. Thus when you set the value of the reference variable `remainder` in the function body, it affects the value at the original memory address of the `rem` variable, and once you have returned from the `divide()` function, the changes to the original `rem` variable persist even after the function has returned, since that address has had its value changed.

So by passing arguments by reference, you can change multiple values outside the function's scope, effectively doing the same thing as returning multiple variables.

This is because references are basically implicit pointers ... so when you are accessing or changing the value of a reference variable, it is changing or accessing the value at the original memory address that the reference was bound to. The "implicit" nature of the reference as a pointer is the fact that references are "bound" at creation to a memory address, and therefore cannot be NULL, and are automatically dereferenced for you by the compiler, thus omitting the need for the manual dereferencing of normal pointers. Thus you could never create a "naked" reference like:

``````int& int_reference;
``````

That would throw a compiler error. Instead references always must be "bound" to an actual memory address (i.e., an actual variable in memory) like so:

``````int actual_variable;
int& int_reference = actual_variable;
``````

Now `int_reference` is "bound" to `actual_variable`, and whenever you change the value of `int_reference`, you are changing the value at the memory location represented by `actual_variable`. So if you did

``````int_reference = 5;
``````

then `actual_variable` will also have a value of 5.

The "binding" operation for references can also happen when you pass a value to a function that has that data-type as a reference. For instance:

``````void func(int& a)
{
a = 5;
}

int main()
{
int b = 2;
func(b);

std::cout << b; //a value of "5" will be printed

return 0;
}
``````

The function `func()` will change the value at the memory address represented by `b` since we took a reference to `b` when calling `func()`. This act of passing `b` as a reference to `func()` is called "pass-by-reference". Therefore you can effectively "return" multiple values back to the caller function by passing in multiple variables as references to a function. The side-effects of calling the function will change the values that you had passed-in by reference, which is akin to if you could have actually returned multiple values from the function itself (but it's a lot more efficient).

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as you have already said, the rem variable is passed by reference

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yes it is correct ,just i did not understand because function does not return it –  dato datuashvili Sep 14 '11 at 13:59

The third parameter of the function is a reference meaning that it is an alias for the argument that is passed in.

When the caller passes the variable (an lvalue) called `rem`, the function aliases this variable with its own parameter `remainder`. All changes to `remainder` are actually changes to `rem`. So in a sense the function fills in variables from the caller's scope.

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The remainder passed to your function is a non-const reference, so the value can be altered inside the function, and it will be visible outside the function, when it returns.

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If you want to return more than one value from function you can use Boost Tuple Library for this.

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I dislike output parameters. So here is a solution that iterally returns all the values.
You can use boost::tie and return pairs (or tupples) from your function.

``````#include <iostream>
#include <utility>
#include "boost/tuple/tuple.hpp"

std::pair<int,int> divide(int numerator, int denominator)
{
int remainder = numerator % denominator;
int result    = numerator / denominator;

return make_pair(remainder, result);
}

int main()
{
int res;
int rem;

boost::tie(rem,res) = divide(10,3);
std::cout << rem << ": " << res << "\n";
}
``````
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