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This is what I found during my learning period:

#include<iostream>
using namespace std;
int dis(char a[1])
{
    int length = strlen(a);
    char c = a[2];
    return length;
}
int main()
{
    char b[4] = "abc";
    int c = dis(b);
    cout << c;
    return 0;
}  

So in the variable int dis(char a[1]) , the [1] seems to do nothing and doesn't work at
all, because I can use a[2]. Just like int a[] or char *a. I know the array name is a pointer and how to convey an array, so my puzzle is not about this part.

What I want to know is why compilers allow this behavior (int a[1]). Or does it have other meanings that I don't know about?

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5  
That's because you can't actually pass arrays to functions. –  Ed S. Mar 27 at 3:03
33  
I think the question here was why C allows you to declare a parameter to be of array type when it is just going to behave exactly like a pointer anyway. –  Brian Mar 27 at 3:05
8  
@Brian: I'm not sure if this is an argument for or against the behavior, but it also applies if the argument type is a typedef with array type. So the "decay to pointer" in argument types isn't just syntactic sugar replacing [] with *, it's really going through the type system. This has real-world consequences for some standard types like va_list that may be defined with array or non-array type. –  R.. Mar 27 at 3:10
4  
@songyuanyao You can accomplish something not entirely dissimilar in C (and C++) using a pointer: int dis(char (*a)[1]). Then, you pass a pointer to an array: dis(&b). If you're willing to use C features that don't exist in C++, you can also say things like void foo(int data[static 256]) and int bar(double matrix[*][*]), but that's a whole other can of worms. –  Stuart Olsen Mar 27 at 8:17
1  
@StuartOlsen The point isn't which standard defined what. The point is why whoever defined it defined it that way. –  immibis Mar 27 at 10:06

8 Answers 8

up vote 116 down vote accepted

It is a quirk of the syntax for passing arrays to functions.

Actually it is not possible to pass an array in C. If you write syntax that looks like it should pass the array, what actually happens is that a pointer to the first element of the array is passed instead.

Since the pointer does not include any length information, the contents of your [] in the function formal parameter list are actually ignored.

The decision to allow this syntax was made in the 1970s and has caused much confusion ever since...

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14  
As a non-C programmer, I find this answer very accessible. +1 –  asteri Mar 27 at 13:39
12  
+1 for "The decision to allow this syntax was made in the 1970s and has caused much confusion ever since..." –  NoSenseEtAl Mar 27 at 15:56
5  
this is true but it is also possible to pass an array of just that size using void foo(int (*somearray)[20]) syntax. in this case 20 is enforced on the caller sites. –  v.oddou Mar 28 at 3:11
7  
-1 As a C programmer, I find this answer incorrect. [] are not ignored in multidimensional arrays as shown in pat's answer. So including array syntax was necessary. In addition, nothing stops compiler from issuing warnings even on single dimensional arrays. –  user694733 Mar 28 at 8:20
4  
By "the contents of your []", I am talking specifically about the code in the Question. This syntax quirk was not necessary at all, the same thing can be achieved by using pointer syntax, i.e. if a pointer is passed then require the parameter to be a pointer declarator. E.g. in pat's example, void foo(int (*args)[20]); Also, strictly speaking C does not have multi-dimensional arrays; but it has arrays whose elements can be other arrays. This doesn't change anything. –  Matt McNabb Mar 28 at 12:18

The length of the first dimension is ignored, but the length of additional dimensions are necessary to allow the compiler to compute offsets correctly. In the following example, the foo function is passed a pointer to a two-dimensional array.

#include <stdio.h>

void foo(int args[10][20])
{
    printf("%zd\n", sizeof(args[0]));
}

int main(int argc, char **argv)
{
    int a[2][20];
    foo(a);
    return 0;
}

The size of the first dimension [10] is ignored; the compiler will not prevent you from indexing off the end (notice that the formal wants 10 elements, but the actual provides only 2). However, the size of the second dimension [20] is used to determine the stride of each row, and here, the formal must match the actual. Again, the compiler will not prevent you from indexing off the end of the second dimension either.

The byte offset from the base of the array to an element args[row][col] is determined by:

sizeof(int)*(col + 20*row)

Note that if col >= 20, then you will actually index into a subsequent row (or off the end of the entire array).

sizeof(args[0]), returns 80 on my machine where sizeof(int) == 4. However, if I attempt to take sizeof(args), I get the following compiler warning:

foo.c:5:27: warning: sizeof on array function parameter will return size of 'int (*)[20]' instead of 'int [10][20]' [-Wsizeof-array-argument]
    printf("%zd\n", sizeof(args));
                          ^
foo.c:3:14: note: declared here
void foo(int args[10][20])
             ^
1 warning generated.

Here, the compiler is warning that it is only going to give the size of the pointer into which the array has decayed instead of the size of the array itself.

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Very useful - consistency with this is also plausible as the reason for the quirk in the 1-d case. –  jwg Mar 27 at 10:35
1  
It is the same idea as the 1-D case. What looks like a 2-D array in C and C++ is actually a 1-D array, each element of which is another 1-D array. In this case we have an array with 10 elements, each element of which is "array of 20 ints". As described in my post, what actually gets passed to the function is the pointer to the first element of args. In this case, the first element of args is an "array of 20 ints". Pointers include type information; what gets passed is "pointer to an array of 20 ints". –  Matt McNabb Mar 27 at 21:40
7  
Yup, that's what the int (*)[20] type is; "pointer to an array of 20 ints". –  pat Mar 27 at 21:54

The problem and how to overcome it in C++

The problem has been explained extensively by pat and Matt. The compiler is basically ignoring the first dimension of the array's size effectively ignoring the size of the passed argument.

In C++, on the other hand, you can easily overcome this limitation in two ways:

  • using references
  • using std::array (since C++11)

References

If your function is only trying to read or modify an existing array (not copying it) you can easily use references.

For example, let's assume you want to have a function that resets an array of ten ints setting every element to 0. You can easily do that by using the following function signature:

void reset(int (&array)[10]) { ... }

Not only this will work just fine, but it will also enforce the dimension of the array.

You can also make use of templates to make the above code generic:

template<class Type, std::size_t N>
void reset(Type (&array)[N]) { ... }

And finally you can take advantage of const correctness. Let's consider a function that prints an array of 10 elements:

void show(const int (&array)[10]) { ... }

By applying the const qualifier we are preventing possible modifications.


The standard library class for arrays

If you consider the above syntax both ugly and unnecessary, as I do, we can throw it in the can and use std::array instead (since C++11).

Here's the refactored code:

void reset(std::array<int, 10>& array) { ... }
void show(std::array<int, 10> const& array) { ... }

Isn't it wonderful? Not to mention that the generic code trick I've taught you earlier, still works:

template<class Type, std::size_t N>
void reset(std::array<Type, N>& array) { ... }

template<class Type, std::size_t N>
void show(const std::array<Type, N>& array) { ... }

Not only that, but you get copy and move semantic for free. :)

void copy(std::array<Type, N> array) {
    // a copy of the original passed array 
    // is made and can be dealt with indipendently
    // from the original
}

So, what are you waiting for? Go use std::array.

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2  
@kietz, I'm sorry your suggested edit got rejected, but we automatically assume C++11 is being used, unless specified otherwise. –  Jefffrey Mar 27 at 20:30
    
this is true, but we are also supposed to specify if any solution is C++11 only, based on the link you gave. –  trlkly Mar 28 at 2:26
    
@trlkly, I agree. I've edited the answer accordingly. Thanks for pointing it out. –  Jefffrey Mar 28 at 15:22

It's a fun feature of C that allows you to effectively shoot yourself in the foot if you're so inclined.

I think the reason is that C is just a step above assembly language. Size checking and similar safety features have been removed to allow for peak performance, which isn't a bad thing if the programmer is being very diligent.

Also, assigning a size to the function argument has the advantage that when the function is used by another programmer, there's a chance they'll notice a size restriction. Just using a pointer doesn't convey that information to the next programmer.

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1  
Yes. C is designed to trust the programmer over the compiler. If you are so blatantly indexing of the end of an array, you must be doing something special and intentional. –  John Mar 28 at 2:54
6  
I cut my teeth in programming on C 14 years ago. Of all my professor said, the one phrase that has stuck with me more than all others, "C was written by programmers, for programmers." The language is extremely powerful. (Prepare for cliche) As uncle Ben taught us, "With great power, comes great responsibility." –  Andrew Falanga Mar 28 at 16:26

First, C never checks array bounds. Doesn't matter if they are local, global, static, parameters, whatever. Checking array bounds means more processing, and C is supposed to be very efficient, so array bounds checking is done by the programmer when needed.

Second, there is a trick that makes it possible to pass-by-value an array to a function. It is also possible to return-by-value an array from a function. You just need to create a new data type using struct. For example:

typedef struct {
  int a[10];
} myarray_t;

myarray_t my_function(myarray_t foo) {

  myarray_t bar;

  ...

  return bar;

}

You have to access the elements like this: foo.a[1]. The extra ".a" might look weird, but this trick adds great functionality to the C language.

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6  
You're confusing runtime bounds checking with compile-time type checking. –  Ben Voigt Mar 27 at 4:15
    
@Ben Voigt: I'm only talking about bounds checking, as is the original question. –  user34814 Mar 27 at 4:24
2  
@user34814 compile-time bounds checking is within the scope of type checking. Several high-level languages offer this feature. –  Leushenko Mar 28 at 1:40

To tell the compiler that myArray points to an array of at least 10 ints:

void bar(int myArray[static 10])

A good compiler should give you a warning if you access myArray [10]. Without the "static" keyword, the 10 would mean nothing at all.

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1  
Why should a compiler warn if you access the 11th element and the array contains at least 10 elements? –  nwellnhof Mar 27 at 11:52
    
Presumably this is because the compiler can only enforce that you have at least 10 elements. If you try to access the 11th element, it cannot be sure that it exists (even though it may). –  Dylan Watson Mar 27 at 14:21
2  
I don't think that's a correct reading of the standard. [static] allows the compiler to warn if you call bar with an int[5]. It doesn't dictate what you may access within bar. The onus is entirely on the caller side. –  tab Mar 27 at 18:18
3  
error: expected primary-expression before 'static' never seen this syntax. this is unlikely to be standard C or C++. –  v.oddou Mar 28 at 3:09
3  
@v.oddou, it's specified in C99, in 6.7.5.2 and 6.7.5.3. –  Samuel Edwin Ward Mar 28 at 14:48

This is a well-known "feature" of C, passed over to C++ because C++ is supposed to correctly compile C code.

Problem arises from several aspects:

  1. An array name is supposed to be completely equivalent to a pointer.
  2. C is supposed to be fast, originally developerd to be a kind of "high-level Assembler" (especially designed to write the first "portable Operating System": Unix), so it is not supposed to insert "hidden" code; runtime range checking is thus "forbidden".
  3. Machine code generrated to access a static array or a dynamic one (either in the stack or allocated) is actually different.
  4. Since the called function cannot know the "kind" of array passed as argument everything is supposed to be a pointer and treated as such.

You could say arrays are not really supported in C (this is not really true, as I was saying before, but it is a good approximation); an array is really treated as a pointer to a block of data and accessed using pointer arithmetic. Since C does NOT have any form of RTTI You have to declare the size of the array element in the function prototype (to support pointer arithmetic). This is even "more true" for multidimensional arrays.

Anyway all above is not really true anymore :p

Most modern C/C++ compilers do support bounds checking, but standards require it to be off by default (for backward compatibility). Reasonably recent versions of gcc, for example, do compile-time range checking with "-O3 -Wall -Wextra" and full run-time bounds checking with "-fbounds-checking".

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Maybe C++ was supposed to compile C code 20 years ago, but it certainly is not, and hasn't for a long time (C++98? C99 at least, which has not been "fixed" by any newer C++ standard). –  hyde Apr 2 at 4:13
    
@hyde That sounds a bit too harsh to me. To quote Stroustrup "With minor exceptions, C is a subset of C++." (The C++ PL 4th ed., sec. 1.2.1). While both C++ and C evolve further, and features from the latest C version exist which are not in the latest C++ version, overall I think that Stroustrup quote is still valid. –  mvw Apr 2 at 13:10
    
@mvw Most C code written in this millenium, which is not intentionally kept C++ compatible by avoiding incompatible features, will use the C99 designated initializers syntax (struct MyStruct s = { .field1 = 1, .field2 = 2 };) for initializing structs, because it is just so much clearer way to initialize a struct. As a result, most current C code will be rejected by standard C++ compilers, because most C code will be initializing structs. –  hyde Apr 2 at 13:29
    
@mvw It could perhaps be said, that C++ is supposed to be compatible with C so, that it is possible to write code which will compile with both C and C++ compilers, if certain compromises are made. But that requires using a subset of both C and C++, not just subset of C++. –  hyde Apr 2 at 13:32
    
@hyde You would be surprised how much of C code is C++ compilable. A few years years ago the whole Linux kernel was C++ compilable (I do not know if it still holds true). I routinely compile C code in C++ compiler to get a superior warning checking, only "production" is compiled in C mode to squeeze the most optimization. –  ZioByte Apr 10 at 13:39

C will not only transform a parameter of type int[5] into *int; given the declaration typedef int intArray5[5];, it will transform a parameter of type intArray5 to *int as well. There are some situations where this behavior, although odd, is useful (especially with things like the va_list defined in stdargs.h, which some implementations define as an array). It would be illogical to allow as a parameter a type defined as int[5] (ignoring the dimension) but not allow int[5] to be specified directly.

I find C's handling of parameters of array type to be absurd, but it's a consequence of efforts to take an ad-hoc language, large parts of which weren't particularly well-defined or thought-out, and try to come up with behavioral specifications that are consistent with what existing implementations did for existing programs. Many of the quirks of C make sense when viewed in that light, particularly if one considers that when many of them were invented, large parts of the language we know today didn't exist yet. From what I understand, in the predecessor to C, called BCPL, compilers didn't really keep track of variable types very well. A declaration int arr[5]; was equivalent to int anonymousAllocation[5],*arr = anonymousAllocation;; once the allocation was set aside. the compiler neither knew nor cared whether arr was a pointer or an array. When accessed as either arr[x] or *arr, it would be regarded as a pointer regardless of how it was declared.

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