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What is an "opaque value" in C++?

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Some more context? –  DevSolar Oct 4 '10 at 9:53
Check this link might help you - calumgrant.net/opaque/index.html –  Sachin Shanbhag Oct 4 '10 at 9:55
why is this question tagged as language-agnostic? –  JPCF Oct 4 '10 at 17:11
@JPCF: Because opaque objects are common across many languages. –  Loki Astari Oct 4 '10 at 18:05
It just means you can't see what is inside (hence opaque). –  Loki Astari Oct 4 '10 at 18:07

5 Answers 5

up vote 18 down vote accepted

I assume (since your question did not give enough context to be sure) that you are referring to something like Opaque Pointers.

An example for an Opaque Pointer is FILE (from the C library):

#include <stdio.h>

int main()
    FILE * fh = fopen( "foo", "r" );
    if ( fh != NULL )
        fprintf( fh, "Hello" );
        fclose( fh );
    return 0;

You get a FILE pointer from fopen(), and use it as a parameter for other functions, but you never bother with what it actually points to.

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That it's actually a pointer isn't important; opaque pointers are just opaque values that happen to be pointers. –  Roger Pate Oct 4 '10 at 13:44
Actually, opaque has little to do with whether you bother with what it points to, that's a user choice. A true opaque pointer reveals no details. If you look inside stdio.h and the structure is defined, then FILE is not opaque. –  paxdiablo Aug 23 '13 at 22:51
@paxdiablo: Linguistics. No operation ever requires to actually access the value of a FILE, you just pass it around. If you couldn't figure out its contents in headers you could still reverse-engineer it, but you don't have to, because its structure is of no importance. The library implementer could change its internals without any further notice, and it shouldn't make a difference. (Unless, of course, you did hack into its internal structure.) Don't confuse ease of access with accessibility. C++ private data members aren't "invisible" either... –  DevSolar Aug 25 '13 at 5:36
@SriHarshaChilakapati: You could confirm with the actual language standard. Don't put too much trust in lecturers; they've been known to be wrong from time to time. ;-) –  DevSolar Dec 1 '13 at 7:01
@paxdiablo: I severely disagree with your point that an opaque pointer / value like FILE needs to be obfuscated in the first place, and think it's misleading and unnecessarily complicating the issue. That's the point: I don't feel your edits add to the answer. Feel free to add an answer of your own. –  DevSolar Mar 10 '14 at 6:58

"Opaque" is defined, in English, as "not able to be seen through; not transparent". In Computer Science, this means a value which reveals no details other then the type of the value itself.

People often use the C type FILE as the classic example but often this is not opaque - the details are revealed in stdio.h for anyone to see and they simply rely on the user of the type to not fiddle with the internals. That's fine as long as people stick to the rules, only passing such values to functions like fread() and fclose() but the problem with revealing information is that people sometimes (foolishly) begin to rely on it.

For example, glibc publishes its FILE structure (as struct _IO_FILE) in libio.h so that type is not technically opaque.

Note that part of the definition at the front: "not able" rather than "not willing". Opacity requires the information to be hidden rather than just enacting a "gentleman's agreement" not to use it.

Opaque pointers, done correctly, should reveal no information other than the type name itself and you can implement that in C relatively easily. Consider the following header file prog2.h for obtaining and releasing xyzzy objects:

struct xyzzy;
struct xyzzy *xyzzyOpen (void);
void xyzzyClose (struct xyzzy *fh);

This is all that clients of the code see, an incomplete type struct xyzzy and some functions to allocate and release objects of that type (they don't get to see prog2.c detailed below). Note that pointers to an incomplete type are fine but you cannot instantiate an object of that type since you don't know its internals. So the code:

struct xyzzy myvar;

would cause an error along the lines of:

prog1.c: In function ‘main’:
prog1.c:3:15: error: storage size of 'myvar' isn't known

Now you can quite happily use those functions from a program prog1.c without knowing the internals of the structure:

#include "prog2.h"
int main (void) {
    //struct xyzzy myvar;             // will error
    struct xyzzy *num1 = xyzzyOpen();
    struct xyzzy *num2 = xyzzyOpen();
    struct xyzzy *num3 = xyzzyOpen();
    xyzzyClose (num1);
    xyzzyClose (num3);                // these two intentionally
    xyzzyClose (num2);                //   reversed.
    return 0;

And the implementation of the calls, prog2.c, actually controls and knows the internals, so can use them quite freely:

#include <stdio.h>
#include <stdlib.h>
#include "prog2.h"

struct xyzzy { int payload; };
static int payloadVal = 42;

struct xyzzy *xyzzyOpen (void) {
    struct xyzzy *plugh = malloc (sizeof (struct xyzzy));
    plugh->payload = payloadVal++;
    printf ("xyzzyOpen payload = %d\n", plugh->payload);
    return plugh;

void xyzzyClose (struct xyzzy *plugh) {
    printf ("xyzzyClose payload = %d\n", plugh->payload);
    free (plugh);

The printf calls are there simply to show that it can use the internals, and you'd probably want to add checking of the return value from malloc in production-ready code but that's not relevant to the purpose of this example.

When you compile prog1.c and prog2.c into a single executable and run it, the output is:

xyzzyOpen payload = 42
xyzzyOpen payload = 43
xyzzyOpen payload = 44
xyzzyClose payload = 42
xyzzyClose payload = 44
xyzzyClose payload = 43

as you would expect from the main function.

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Upvoted it despite our disagreement, because when put in its own, it does highlight an interesting angle on the subject. Me disagreeing with its necessity doesn't mean I cannot upvote a good presentation of its merits. ;-) No hard feelings, and have a good time. –  DevSolar Mar 10 '14 at 8:17
@DevSolar, if we all agreed, I'd be bored witless :-) Cheers. –  paxdiablo Mar 10 '14 at 8:21
Interesting pointification: If I have access to the source of prog2.c, I would be able to access the internals of the struct. Is the struct still "opaque" by your definition, then? Or does true opacity require a closed-source programming model? (Just pulling your leg there, trying to point to my definition of "opacity" looking at the documentation, not the header source. ;-) ) –  DevSolar Mar 10 '14 at 8:28
S'Okay, @Dev, as an Aussie, I have an acerbic sense of humour myself. You're right that "hidden" is a matter of degree since, even without the source for prog2.c, you could examine the assembly code to figure it out. In fact, the only way to truly hide it is to not release it, which rather damages its usefulness. And a fully defined FILE within stdio.h could be considered opaque to people who have no clue how to find the header :-) –  paxdiablo Mar 10 '14 at 8:35
This is the right answer. DevSolar's is simply wrong ... FILE is NOT opaque, its internals are visible to the user just like any other struct, and people have been known to take advantage of that (and later get burned when the implementation changed or the code was ported to another implementation). The notion that one could copy the struct definition from the source and then cast the opaque pointer, while technically true, is just an obstinate refusal to admit to the correct answer. –  Jim Balter Jul 20 '14 at 2:31

That's similar to opaque pointer - a value that doesn't store data your code could interpret or provide access to data, but only identifies some other data. A typical example is a Win32 handle like HBITMAP bitmap handle - you can only pass it to relevant functions, but you can't do anything to the underlying bitmap directly.

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@MatteoItalia sharptooth SAID that HBITMAP is an opaque pointer; there's no claim here that it holds the bitmap itself. –  Jim Balter Jul 20 '14 at 2:37
@JimBalter: either I misread, or it was edited after my comment, or I intended something different altogether. Honestly, after four years I cannot remember. I'll delete my comment anyway since it's no longer relevant (if it ever was). –  Matteo Italia Jul 20 '14 at 12:08

FILE* is a good example of an opaque value. You don't use it directly; it's a single "blob" which you can't interpret or manipulate. Instead, you use a set of functions (fopen, fwrite, fprintf, etc.) which know how to manipulate it.

Being opaque in this way is common to many situations (and in many APIs) where you have a "magical" handle: a black box.

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from Wikipedia

In computer science, an opaque data type is a data type that is incompletely defined in an interface, so that its values can only be manipulated by calling subroutines that have access to the missing information. The concrete representation of the type is hidden from its users

Typical examples of opaque data types include handles for resources provided by an operating system to application software.

Some languages, such as C, allow the declaration of opaque records (structs), whose size and fields are hidden from the client. The only thing that the client can do with an object of such a type is to take its memory address, to produce an opaque pointer.

If the information provided by the interface is sufficient to determine the type's size, then clients can declare variables, fields, and arrays of that type, assign their values, and possibly compare them for equality. This is usually the case for opaque pointers.

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