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I was talking with a coworker about this yesterday and it got me thinking about .Net's pass by reference.

// C#
class Foo {}

static void Test(ref Foo foo) { ... };
static void Main()
    Foo f;
    Test(ref foo);

Has to be implemented with a double indirection because we're changing the value of the pointer. Because all reference types are references (pointers)

// C#
static void Test(Foo foo) { ... }
static void Test(ref Foo foo) { ... };

equates to something like

// C++
void Test(Foo *foo);
void Test(Foo **foo);

But if this is a VALUE type, we don't actually need the double indirection. So I'm curious if

// C#
static void Test(ref int bar) { ... }


// C++
void Test(int *bar);
// or
void Test(int **bar);

1/29/10 Update: Reading all the answers, I realize that I was not exactly clear enough in what I wanted and I was misleading by throwing in C++ to what was going on. What I was primarily interested in was how it was implemented in the CLR and what the JIT would do to produce assembly for it. Thanks for all the answers, I found them all to be correct from a perspective but I chose the one that was closest to the question I thought I had asked.

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See Jon Skeets article on parameter passing yoda.arachsys.com/csharp/parameters.html –  Binary Worrier Jan 28 '10 at 16:40
"But if this is a reference type, we don't actually need the double indirection." - that may or may not be true depending on what is desired. There are times when a ref parameter to a reference type is useful. –  Michael Burr Jan 28 '10 at 16:42
@Michael: Yeah, when want to update the reference and not the object itself. –  Eduardo León Jan 28 '10 at 16:58
You meant to say "if this is a value type we don't actually need the double indirection", right? –  Eric Lippert Jan 28 '10 at 23:49
Sorry for the confusion all, Eric you're absolutely right I meant VALUE instead of REFERENCE. A very unfortunate mistype. –  Peter Oehlert Jan 29 '10 at 21:18

7 Answers 7

up vote 5 down vote accepted

In C#, when you have a method

void M(ref int f) { }

and you call it

int x = 123;
M(ref int x):

how does this work?

Logically, this means "x and f refer to the same storage location".

The way we actually implement that in the CLR is f is of type "managed reference to variable that can contain an integer". We pass the managed address of local variable x to M.

The analog of that in C++ would be a method that takes an &int -- a reference to a variable that can contain an int.

Is that clear?

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The right way to think of ref is an alias for a storage location. Thus, when you say

int x;
Foo(ref x);

and Foo is declared as

void Foo(ref int y)

you are to think of x and y as aliases for the same location in the method call above.

So, void Foo(ref int y) in C# is analogous with void Foo(int &y) in C++.

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I understand this perspective as the appropriate context to consider the CLR in the abstract divorced from an actual implementation. Perhaps I mislead people when I asked about what happened in C++. I'm more interested in what the JIT will produce in assembly. Even in C++, references (&y in your sample) are implemented with pointers. I was only using C++ because I mistakenly believed it was sufficiently expressive and low-level and many people would be familiar with it. –  Peter Oehlert Jan 29 '10 at 21:30

A reference is not a pointer.

Foo foo = new Foo();

This declares a "memory cell" which holds a reference to an instance of Foo. Then it initializes a new instance of Foo and stores the reference in the memory cell.

Bar(Foo x) { x = new Foo(); }

This declares method with a Foo parameter, which is essentially a local variable (like foo) which happens to be assigned automatically when the method is invoked with an argument.

The statement in the method creates a new instance of Foo and stores the reference to the instance in memory cell x. Memory cell foo remains unchanged.


This invokes Bar by copying the value stored in memory cell foo to memory cell x -- call by value.

Exactly the same happens if you write int instead of Foo, except that the value stored in the memory cells is not a reference but the actual value.

Qux(ref Foo y) { y = new Foo(); }

This declares a method with a Foo& parameter, which is essentially a local variable that contains the address of a memory cell which holds a reference to an object of type Foo.

Qux(ref x);

This invokes Qux by setting y to the address of memory cell x -- call by reference.

The statement in Qux creates a new instance of Foo and stores the reference to the object in the memory cell which is located at address y (which is the address of foo). So foo is assigned the reference to the new instance and changes.

Exactly the same happens when Foo is an int, except that the value stored in the memory cell passed by reference is not a reference to an object but the actual value.

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A reference is & not * you are confusing it with a pointer. So this would mean that it will be passed as:

void Test(Foo &bar);
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Which, at the ABI level, is the same thing: pass the address of bar. –  ChrisV Jan 28 '10 at 16:43
It would however exclude the thoughts of double pointers. –  Filip Ekberg Jan 28 '10 at 16:43

I'm pretty sure a value type like int would use only a single level of indirection.

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  1. MyClass --> MyClass* (or, actually, shared_ptr<MyClass>)
  2. ref --> &


void doSomething(int myInt);
void doSomethingElse(ref int myIntRef);
void doSomething(Foo foo);
void doSomethingElse(ref Foo fooRef);


void doSomething(int myInt);
void doSomethingElse(int& myInt);
void doSomething(Foo* fooPtr);
void doSomething(Foo*& fooPtrRef);
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You may want to check how it is implemented in C++/CLI. I found good explanation in a book: Expert C++/CLI: NET for Visual C++ programmers, page 83.

Foo^ is defined as "managed pointer to Foo", equivalent to UnmanagedFoo*.

int% and Foo^% are "managed references" and they are equivalent to int& and UnmanagedFoo*&.

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