Why are ints and doubles immutable? What is the purpose of returning a new object each time you want to change the value?

The reason I ask is because I'm making a class: BoundedInt, which has a value and an upper and lower bound. So I was wondering: should I make this type immutable too? (Or should it be a struct?)

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    You open huge cans of worms with these questions. My recommendation is to think twice about trying to push your data validation into the data itself. The validation makes more sense at a higher level of abstraction than the underlying datatypes. For example, you may need to have one piece of data range bound by the value of another piece of data. – Merlyn Morgan-Graham Oct 20 '10 at 20:14
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    @Merlyn: What about data with implicit boundaries, like a length [0, ∞), an angle [0, 360), or the result of a dice roll [1,6]? I certainly don't want to be -180cm tall. – Seth Oct 20 '10 at 21:22
  • @Seth: These are special cases that do not define our architecture. Whether a value of 361 or -1 is invalid depends entirely on what they are interpreted as, not on the values in and of themselves. – Steven Sudit Oct 20 '10 at 21:57
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    @Seth: A default constraint bound to a type can be useful (e.g., a 6-sided die), but you'll very often want to customize that constraint. Units are a related concern. A better approach is to use a constraint solving/mapping system, or a contract-based-programming framework (e.g. spec#). – Merlyn Morgan-Graham Oct 20 '10 at 22:03
  • you need to listen Uncle Bob's discussion on DotNetRocks about 'future of OOP' – lawphotog Apr 15 '16 at 14:58


What is the purpose of returning a new object each time you want to change the value?

I think you might be mistaken about how value types work. This isn't some costly operation like you may be imagining; it's simply the overwriting of data (as opposed to, e.g., dynamic allocation of new memory).

Secondly: here's a very simple example of why numbers are immutable:

Console.WriteLine(5); // What should happen here?

Granted, that is a contrived example. So let's consider a couple more involved ideas.

Mutable reference type

First, there's this one: what if Integer were a mutable reference type?

class Integer
    public int Value;

Then we could have code like this:

class Something
    public Integer Integer { get; set; }


Integer x = new Integer { Value = 10 };

Something t1 = new Something();
t1.Integer = x;

Something t2 = new Something();
t2.Integer = t1.Integer;

t1.Integer.Value += 1;

Console.WriteLine(t2.Integer.Value); // Would output 11

This seems to defy intuition: that the line t2.Integer = t1.Integer would simply copy a value (actually, it does; but that "value" is in fact a reference) and thus that t2.Integer would remain independent of t1.Integer.

Mutable value type

This could be approached another way, of course, keeping Integer as a value type but maintaining its mutability:

struct Integer
    public int Value;

    // just for kicks
    public static implicit operator Integer(int value)
        return new Integer { Value = value };

But now let's say we do this:

Integer x = 10;

Something t = new Something();
t.Integer = x;

t.Integer.Value += 1; // This actually won't compile; but if it did,
                      // it would be modifying a copy of t.Integer, leaving
                      // the actual value at t.Integer unchanged.

Console.WriteLine(t.Integer.Value); // would still output 10

Basically, immutability of values is something that is highly intuitive. The opposite is highly unintuitive.

I guess that is subjective, though, in all fairness ;)

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    Nice improvements in your last edit. If I could upvote a second time (in what is called Chicago style), I would. – Steven Sudit Oct 20 '10 at 21:59
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    It occurs to me that Java has an int primitive that is not an object as well as an Integer primitive wrapper class. This means that your contrived examples aren't really all that contrived. :-) – Steven Sudit Oct 20 '10 at 22:04
  • Consider a real struct type like "Rectangle". Which is clearer: "someRect.Width *= 2;" or "someRect = someRect.withNewWidth(someRect.Width*2);" It's too bad .net provides such feeble support for mutable value-type properties, but often times mutable value-type semantics are much cleaner than anything else. – supercat Oct 20 '11 at 22:03
  • @supercat: I'm kind of halfway on this one. I certainly agree that mutable value types are not bad per se. I find uses for them quite often, in fact. The unfortunate fact, however, is that they can be tricky even for smart developers. Take your example: someRect.Width *= 2; does indeed seem nice and clear; but then make that a property and suddenly the code doesn't work: someObject.Rectangle.Width *= 2; Of course, the latter won't compile; but unfortunately this would (assuming the method existed): someObject.Rectangle.Scale(2); As with all things, there are arguments on both sides. – Dan Tao Oct 20 '11 at 23:47
  • @Dan Tao: I consider .net to have a few weaknesses in its handling of value types: (1) no "const ref" parameters, nor a means of distinguishing which struct methods modify "this"; (2) no support for any type of property other than a read accessor, a write accessor, or a (read-accessor/write-accessor) pair. I think all of the "problems" with mutable structs boil down to those two things. Given #1, btw, I would agree that with Eric Lippert that structs should almost never mutate "this" within their methods. – supercat Oct 21 '11 at 14:58

Integer variables are mutable. However, integer literals are constants, hence immutable.

int i = 0;

// Mutation coming!
i += 3;

// The following line will not compile.
3 += 7;

It's possible to make an integer field immutable, using readonly. Likewise, an integer property could be get-only.

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    Thank you for the downvote. Now I would appreciate it if you offered an explanation so that I can learn from my mistake. – Steven Sudit Oct 20 '10 at 21:02
  • @Robert: Didn't say it was. :-) – Steven Sudit Oct 20 '10 at 21:04
  • It would be great if someone were to point out the error. Otherwise, I might spend the rest of my life imagining that there's no error here. – Steven Sudit Oct 20 '10 at 21:23
  • Given the silence and the upvotes, I suspect that the original downvote may have been in error. If that is not the case, I am open to correction. – Steven Sudit Oct 20 '10 at 22:05
  • The argument isn't "is 3 immutable"... it's "is an integer immutable". Huge difference. i += 3 is the same thing as i = i + 3... it's still immutable. "an immutable object is an object whose state cannot be modified after it is created." You aren't editing i IN PLACE. You are editing it and returning it back into a "new" i. Just like "hello " + "world!" means NOTHING without an s = ... on the left side. – WernerCD Oct 20 '10 at 23:59

As a mutable object, you have to lock an int variable before you change it (in any multi-threaded code that writes to your int from separate threads).

Why? Let's say you were incrementing an int, like this:


Under the hood, this is a 32-bit number. Theoretically, on a 32 bit computer you could add 1 to it, and this operation might be atomic; that is, it would be accomplished in one step, because it would be accomplished in a CPU register. Unfortunately, it's not; there is more going on than this.

What if another thread mutated this number while it was in the middle of being incremented? Your number would get corrupted.

However, if you make a thread-safe copy of your object before you increment it, operate on your thread-safe copy, and return a new object when your increment is complete, you guarantee that your increment is thread safe; it cannot be affected by any operations on the original object that take place on other threads, because you're no longer working with the original object. In effect, you have made your object immutable.

This is the basic principle behind functional programming; by making objects immutable, and returning new objects from functions, you get thread safety for free.

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  • I'm not sure this follows. In fact, the code you show is not thread-safe. You would need to use Interlocked.Increment to assure that. – Steven Sudit Oct 20 '10 at 20:36
  • I should also mention that it's impossible to lock an int, since it's not a reference type. – Steven Sudit Oct 20 '10 at 20:53
  • Thanks for changing your answer, but I'm sorry to have to say that it's still not correct. The int variable is mutable, as shown by the fact that you can increment it. And the increment operation, as mentioned, is not atomic. Even though it would normally be implemented as an INC opcode, that's not atomic with a LOCK prefix. It may be a single opcode, but translates to a fetch and a store, which means another core could win a race by storing in between those two steps. – Steven Sudit Oct 20 '10 at 20:56
  • @Steven: I never actually say in my answer that int is immutable, nor do I say that the increment is atomic, but only that it might be atomic if it were done in one step. The increment is probably not the best example, since it is multi-step anyway (it returns a value, then increments). My point is that you can return a new object and get thread safety, provided you can guarantee that the original object won't mutate during your operation. You can make that guarantee by creating a thread-safe copy of your original object, prior to performing your operation. – Robert Harvey Oct 20 '10 at 21:00
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    Robert, I just want to apologize if I came across as insufficiently clear or excessively picky. My motivation is to make your answer as good as it can be, not to be critical for its own sake. – Steven Sudit Oct 20 '10 at 22:13

It makes sense to have BoundedInt as a mutable type because it represents a variable that at any point in time has a specific value and that value can be changed but only within a certain range.

However integers themselves aren't variables so they should not be mutable.

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Anything with value semantics should be immutable in C#.

Mutable classes can't have value semantics because you can't override the assignment operator.

MyClass o1=new MyClass();
MyClass o2=o1;
//o2 got mutated too
//=> no value but reference semantics

Mutable structs are ugly because you can easily call a mutating method on a temporary variable. In particular properties return temporary variables.

MyStruct S1;
MyStruct S2{get;set;}

S1.Mutate(); //Changes S1
S2.Mutate();//Doesn't change S2

That's why I don't like that most Vector libraries use mutating methods like Normalize in their Vector struct.

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I'm working on an academic project with Neural Networks. These networks do heavy computation with doubles. I run it on amazon cloud for days on 32 core servers. When profiling the application, the top performance problem is allocation of double!! It would be fair to have a dedicated namespace with mutable types. "unsafe" keywords can be enforced for additional precaution.

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