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In most cases, languages will not allow manipulations of references to primitives. Eg.:

var a = 0;
var b = a; // value is copied
b++; // b now represents a new value as this is really b = b + 1; so a != b

While manipulation of non-primitives will cause a (sometimes destructive) state manipulation which is reflected in all variables(using JS):

var a = [];
var b = a; // b is now a reference to the value stored in a.
a.push(1); // b[0] is now 1 -- b and a are pointing to the same thing.

This makes perfect sense. I can completely understand why things like String.replace will return a value instead of performing a state manipulation.

I was wondering, though, if there aren't any languages which allow primitives to have state manipulations. Eg.:

var a = 0;
var b = a; // b references a
b++; // b and a are now = 1.

I am aware of the pointer in the more low level languages, and that almost does what I'm talking about, but I get the feeling that it is only re-assigning the value and not actually updating a reference.

I also know about PHP references but since PHP does not allow things like this:

$str = "abcd";
$st[0] = "q"; // this causes an error.

Also, when concatenating a number of Strings in PHP, a cycle of $str .= 'var' is purported to create new strings each iteration.

Perhaps I'm crazy for even wondering this, but with the increase in prevalence of object models as backgrounds for variables, it seems that this might actually exist (it seems insanely complicated in some ways, especially if you allowed for an int object being manipulated, but it seems like such a syntax would be a good source of learning).

share|improve this question
Anecdotally, Python really got on my nerves because of unexpected (to me) structure sharing -- but I've been trying to repress the details so you'll have to look for yourself. – LHMathies Jun 15 '11 at 16:46
@LHMathies Actually, it was the study of Python that made me think about this. The fact that int represents a chached object makes that language work, but what if int were just like everything else? – cwallenpoole Jun 15 '11 at 17:06
int (and string, and tuple, etc.) is like everything else in this regard. Python always uses references to everything, regardless of the type. It just so happens that some objects are immutable. You can (with some effort and ugliness) write essentially immutable classes yourself, and several classes implemented at the same level of abstraction (and just as essential) are mutable. Really, Python isn't the language to use as an example for different treatment of "primitives" and "non-primitives". – delnan Jun 15 '11 at 20:12
(+1) for mentioning "pointer", many people forget that references have a hidden pointer. – umlcat Jun 15 '11 at 22:02
up vote 4 down vote accepted

Contrary to what you seem to assume, this is neither a new idea nor obscure. Lower-level languages don't bother to enforce immutablity of any type (after all, ++i wouldn't exist or be wasteful otherwise - and the hardware doesn't have constant registers either, right?), but they also will prefer value types (i.e. a = b copies the value, not silently gives out a reference to the same value), so you have to get your hands dirty and tell it to refer to the same value twice, e.g. by using pointers. In C:

int x = 0;
int *p = &x;
*p = 1;
/* x == 1 */

Similarily, C++ has equally-powerful pointers and also references, which for these purposes work like pointers that are implicitly dereferenced (and can't be changed to point to anything else, and can't be NULL):

int x = 0;
int &y = x;
y = 1;
// x == 1

In either case, it simply didn't occur to anyone to make the primitive types immutable (why should they? Von Neumann machines are all about changing state, after all), pointers lose much of their value if you can't change the value pointed to, and disallowing pointers to certain mutable types would be a pointless and severe restriction.

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Fascinating. The detriment of spending all of my time in VHLL is that these things seem so... non-obvious. Thank you for your answer – cwallenpoole Jun 15 '11 at 20:39
Once this seems obvious to you, you should poke around in Haskell (or ML) to get an idea why this type of manipulation actually can make life much more complicated. C and friends try to abstract how the machine works, while functional languages try to abstract how computation happens. Knowing both ways will make you better at either. – John F. Miller Jun 18 '11 at 5:41
You know, taking a little extra time to think about this, I can't believe how obvious it really is. I'll definitely look into Haskell, I've been meaning to, just haven't gotten around to it. – cwallenpoole Jun 22 '11 at 14:29
Historically, FORTRAN compilers would not include floating-point constants directly in code, but rather have code contain an index (probably 16-bit) to a 32-bit value stored in a table. Given that FORTRAN functions always used pass-by-reference semantics, one passing e.g. the constant 3.0 to a method which added 1.0 to it could cause some arbitrary subset of the constant 3.0 values in the code to be replaced with 4.0. – supercat Jun 2 '14 at 20:09

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