It's awkward to talk about immutability of
ints, because the idea of mutating something that isn't a container doesn't make sense to most of us. So let's talk about strings.
Here's a string, in Python:
s = "abc"
Strings are containers in the sense that they contain some number of individual characters: here
c. If I want to change the second character to a
d, I might try:
s = 'd'
Which will fail with a
TypeError. We say strings are immutable in Python because there is no operation that will alter an existing string. Certainly there are plenty of operations that will perform some operation and create a new string, but existing strings are set in stone.
There are a couple advantages here. One is that it allows interning: sometimes when a string needs allocating (and at the discretion of the interpreter), CPython will notice that an identical string has already been allocated and just reuse the same
str object. This is easiest when strings are immutable—otherwise, you'd have to do something about problems like this:
s = "abc"
t = "abc" # this reuses the same memory, as an optimization
s = "x" # oops! now t has changed, too!
Interning is particularly useful in Python and similar languages that support runtime reflection: it has to know the name of every function and method at runtime, and a great many methods have builtin names like
__init__ (the name of the constructor method), so reusing the same string object for all those identical names saves a good deal of wasted space.
The other advantage is in semantics: you can safely pass strings to arbitrary functions without worrying that they'll be changed in-place behind your back. Functional programmers appreciate this kind of thing.
The disadvantage, of course, is that doing a lot of work with very large strings requires reallocating and rebuilding those large strings many times over, instead of making small edits in-place.
ints. This is NOT an example of immutability:
x = 3
x = 4
This doesn't involve the actual objects at all; it only assigns a new value to the variable
x = [1, 2, 3]
y = x
x[:] = [4, 5, 6]
print y # [4, 5, 6]
x[:] = syntax is "slice notation" for replacing the entire contents of a list. Here,
y are two names for the same list. So when you replace the contents of
x, you also see the same effect in
y, because... they both name the same list. (This is different from reference variables in other languages: you can assign a new value to either
y without affecting the other.)
Consider this with numbers. If you could do some hypothetical operation like the above on plain numbers, this would happen:
x = 3
y = x
x[:] = 4
print y # hypothetically, 4
But you can't do that. You can't change the number an existing
int represents. So we call them immutable.
int is easy in Smalltalk:
3 become: 4
This would change the 3 to a 4, overwriting the memory that previously contained a 3. If
ints are interned (as they can be in Python), this could even mean that everywhere
3 appears in your source code, it acts like the number 4.
In C, these distinctions aren't as meaningful, because variables are fixed blocks of memory rather than the transient labels of Python. So when you do this:
int x = 3;
x = 4;
It's hard to say definitively whether this is "mutating" an int. It does overwrite existing memory, but that's also just how C variable assignment works.
Anyway! Mutability is just about whether you're altering an existing object or replacing it with a new one. In Python and Java, you can't alter existing strings, and you can't "alter" numbers, so we call them immutable. You're free to change the contents of lists and arrays in-place without creating new ones, so they're mutable.