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Here's a question I got in an exam today:

In C, suppose the pointers are strictly typed (ie, a pointer to an int cannot be used to point to a char). Does this reduce its expressive power? If no, why and how would you compensate for this limitation? If yes, how? And what more constructs would you have to add to "equalize" the loss of expressive power of C?

Some additional details:

  • By reduced expressive power, I think it means this: you will not be able to create certain programs that you could earlier.
  • Strictly typed pointers means you cannot do something like: int x = 5; int *p = &x; char *temp = (char*)p;
  • This includes (void*) conversions

I've included my answer below as well.

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The question is not clear. In C language all pointer types are strictly typed already, and has always been since the first C89/90. You cannot initialize/assign an int * pointer to point to a char object (unless you force this operation through an explicit type cast). The only pointer type in C that can be made to point to other data types without an explicit cast is void *. The only reason you can sometimes do it without a cast in practical code is that some C compilers by default follow very loose enforcement policies. –  AnT Mar 26 '11 at 14:36
So, what is the question about? Outlawing explicit casts? The person asking the question was simply unaware of the fact that C is already strictly typed (in the above sense)? Or something else? What exactly is meant by "strictly typed"? –  AnT Mar 26 '11 at 14:37
Fixed the question. Strictly typed in the sense that a char pointer can only point to a character. Even explicit type casts cannot make it point to int* or double*. –  Utkarsh Sinha Mar 26 '11 at 15:59
Great, but (referring to the updated question) note that things like int *p = 5 are already illegal in C. They have been illegal since C89/90. You need a cast (as in int *p = (int *) 5) for that to become legal C. If your C compiler allows int *p = 5, it means that your C compiler has overly relaxed error checking. This happens pretty often (for compatibility with legacy pre-standard code), but nevertheless int *p = 5 is not allowed in standard C already. –  AnT Mar 26 '11 at 19:36
@Andrey hmm. Changed it. –  Utkarsh Sinha Mar 27 '11 at 1:37

8 Answers 8

up vote 5 down vote accepted

Does that also mean no more void*? If so, then yes: C's expressiveness would be limited, as malloc would be impossible to implement. You'd need to add a new, typed, free store allocation mechanism in the spirit of C++ new.

(Or, no: C would still be Turing-complete. But I don't think that's what's meant here.)

Actually, C isn't even Turing-complete; see comments below.

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A note on the Turing-completeness of C: a Turing machine is a finite-state controller with an infinite tape. Strictly, only with such a tape and an interface with read, write, step left and step right instructions, C is Turing-complete. malloc doesn't make the difference, because no number of calls to it can allocate an infinite amount of memory (sizeof(void *) is a constant). –  larsmans Mar 26 '11 at 14:27
A single C implementation is not Turing-complete, but a family of C implementations where you recompile the program in a new implementation with increased type sizes and rerun it whenever the program runs out of memory is Turing-complete. This is due to Representation of Types. –  R.. Mar 26 '11 at 16:24
Note that "runs out of memory" has a formal meaning in the language due to the fact that an array of sizeof(void *) unsigned chars can hold at most (UCHAR_MAX+1)^sizeof(void *) possible pointer values. –  R.. Mar 26 '11 at 16:26
@R..: yes, so the C language is in a certain sense Turing-complete, but every implementation is finite-state unless you add an interface to infinite memory. –  larsmans Mar 26 '11 at 16:29
The language is not even Turing complete; it specifies an implementation that defines bounds that prevent it from being Turing-complete. You need an infinite family of C implementations with progressively larger pointer types to be Turing-complete. –  R.. Mar 26 '11 at 16:47

It might actually increase C's expressiveness. C is one of the few languages for which any given implementation is specified not to be turing complete. The Representation of Types in the standard specifies all types as being represented as an overlaid array of char, meaning all types and the total data available to the program (the space of all possible pointers, all possible filenames, and all possible file offsets, etc.) is finitely bounded, and therefore the computation model of C is a finite state machine.

If you removed the requirement that pointers be represented as char [sizeof (pointer type)] then the formally-specified language could in principle deal with an infinite amount of data, and it would be Turing-complete.

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C is not turing complete?! By your argument, every language in the world isn't! Can you point me to some article/book that deals with this? –  Utkarsh Sinha Mar 26 '11 at 16:16
Downvoter, care to explain? –  R.. Mar 26 '11 at 16:28
See my comments on larsmans' answer. –  R.. Mar 26 '11 at 16:33
@Utkarsh: you can verify this for yourself. void* has a constant size in any C implementation, so there's a maximum to the amount of memory a C program can address; every data object and every function has an address that can be converted to void*. (This matches the fact that practical computers are finite-state machines. It is not necessarily true for other languages.) –  larsmans Mar 26 '11 at 16:33
Indeed. You could imagine a machine with a "two-dimensional tape" that could, at each "memory location" in one dimension, hold a unbounded pointer/reference value. Most languages could be implemented on such a machine to be Turing-complete. However, due to the specification of the Representation of Types in the C standard, this is not possible for C. The number of possible pointers is bound by the fact that they are represented as an array of bytes (char). The same applies to file names and file offsets, the only other ways of addressing data in C. –  R.. Mar 26 '11 at 16:45

Well its a very subjective question. Couple that with the fact I've no idea what "expressive power" is ;)

Still not being able to cast between pointer types is a big limitation in my head. It seems that when using Java mapping a char array (Coming from something like a network socket for example) to a class is incredibly annoying. The ability to just cast it and re-interpret the memory is incredibly useful and allows for significant optimisations in processing random blocks of memory.

How would you get round these limitations? Perhaps implement a "cast" function or perhaps just a templated memcpy function that can re-interpret the memory would be a huge bonus for optimisation and, for people like me, productivity. It might even be a plan to allow some sort of class "id" to be included in the byte stream so that you know that it can be re-interpreted as a specific class.

The downside to having this power is that it allows you to interpret data in completely the wrong way. This can cause very nasty bugs.

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I do not think it reduces its expressive power - you still are able to write a Turing machine interpreter, meaning it's Turing complete. See for example this code golf thread.

If you mean expressive power in terms of user convenience, then it definitely limits C a lot because the memory allocation mechanism (malloc & co.) would have to be changed.

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Turing completeness is not only a useless measurement for how useful a language really is, OP propably means something different by "expressiveness". –  delnan Mar 26 '11 at 14:07
@delnan: True, but it's difficult to say what exactly he means. And Turing completeness is closest to the common meaning of expressive power. –  Karel Petranek Mar 26 '11 at 14:13
Edited the question, I added what I interpreted as expressive power. –  Utkarsh Sinha Mar 26 '11 at 16:16

This question is similar to asking what useful/valid uses of pointer casts are. Here are a few:

Without pointer casts, you must have several versions of memcpy, memmove, malloc as these all require pointer conversions to be implemented and used. In the case of malloc, allocating memory for user-defined structs becomes impossible.

In a slightly different category, you cannot implement a polymorphic qsort (the one provided by the standard library sorts an array of void* and can effectively be used to sort arrays of various kinds of pointers).

As to what kind of feature would allow to regain expressive power, a type system that recognizes polymorphism so that you do not have to encode it with unsafe pointer casts would be a great step. Languages of the ML family have had this kind of type system for a long time, and if you are familiar with Java's generics, they follow the same line of thinking.

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In C, suppose the pointers are strictly typed (ie, a pointer to an int cannot be used to point to a char).

Advocating strict pointer typing in C completely loses the plot, which is that it's just a portable shorthand for assembly language. You're supposed to be able to shoot yourself in the foot and a good developer will be smart enough not to.

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True, but that's what the question was. –  Utkarsh Sinha Mar 26 '11 at 16:11

I thought of a way to get around the limitation of not being able to typecast between various types. You could use a union:

union alltypepointers  
    char* c,  
    short* s,
    int* i,  
    float* f,
    double* d,

All pointers are the same size, so if you change one, you can read it as any other type. You could do arithmetic on these pointers too:

int variable = 0x2345;
alltypepointers p;
p.i = &variable;
char *temp = p.c;
int newint=*p.i;

So, you can still do everything you could do earlier => there's no decrease in expressive power.

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C does not specify that the representation of different pointer types is the same. This code has UB. Nor does it specify that you can access data via the wrong pointer type, except char types. –  R.. Mar 26 '11 at 16:17
@R. UB? Till now I assumed a pointer was just a 32/64bit number. Should be the same, regardless of the type. –  Utkarsh Sinha Mar 26 '11 at 16:21
As an example, many historical machines could only address words, not bytes. Therefore, char and void pointers were larger, and included an additional byte offset within the word that the generated code would use to extract the desired byte. –  R.. Mar 26 '11 at 16:36
More recently, x86-16 could have different-sized pointers for functions than for data. –  dan04 Mar 26 '11 at 16:45
@Utkarsh: that's a possibility, but the difference between pointers and addresses is also apparent on typical systems where char* and int* have the same representation. Adding 1 to the memory address of an int would yield the next byte in the int, but adding 1 to an int* yields a pointer to the next int (e.g. in an array), so it really adds sizeof(int) to the memory address stored in the pointer. –  larsmans Mar 27 '11 at 12:26
(someType *)((void *)somePtr)

that contruction allow you to convert any pointer to (someType *).

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Presumably this would be disallowed too, otherwise the question is somewhat trivial. –  Pascal Cuoq Mar 26 '11 at 13:58
-1: That's not what the question is about. The OP asks what would happen if this were disallowed. –  Karel Petranek Mar 26 '11 at 13:58
disallowed convertation from (anotherType *) to (someType *), but convertation (anyType *) to (void *) and (void *) to (anyType *) is guaranteed by standart –  Mark.Ablov Mar 26 '11 at 14:00
You are right. But the OP asks what would happen if any casts weren't possible in C, regardless of what the current standard says. –  Karel Petranek Mar 26 '11 at 14:05

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