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I'm just starting an assignment for uni and it's raised a question for me.

I don't understand how to return a string from a function without having a memory leak.

char* trim(char* line)  {
    int start = 0;
 int end = strlen(line) - 1;

 /* find the start position of the string */
 while(isspace(line[start]) != 0)  {
 //printf("start is %d\n", start);

 /* find the position end of the string */
 while(isspace(line[end]) != 0)  {
 //printf("end is %d\n", end);

 /* calculate string length and add 1 for the sentinel */
 int len = end - start + 2;

 /* initialise char array to len and read in characters */
 int i;
 char* trimmed = calloc(sizeof(char), len);

 for(i = 0; i < (len - 1); i++)  {
     trimmed[i] = line[start + i];
 trimmed[len - 1] = '\0';

    return trimmed;

as you can see I am returning a pointer to char which is an array. I found that if I tried to make the 'trimmed' array by something like:

char trimmed[len];

then the compiler would throw up a message saying that a constant was expected on this line. I assume this meant that for some reason you can't use variables as the array length when initialising an array, although something tells me that can't be right.

So instead I made my array by allocating some memory to a char pointer.

I understand that this function is probably waaaaay sub-optimal for what it is trying to do, but what I really want to know is:

  1. Can you normally initialise an array using a variable to declare the length like:

    char trimmed[len];

  2. If I had an array that was of that type (char trimmed[]) would it have the same return type as a pointer to char (ie char*).

  3. If I make my array by allocating some memory and allocating it to a char pointer, how do I free this memory. It seems to me that once I have returned this array, I can't access it to free it as it is a local variable.

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"I assume this meant that for some reason you can't use variables as the array length when initialising an array, although something tells me that can't be right." No, that is correct, array sizes must be compile time constants. –  detly Mar 26 '10 at 17:04
+1 for following up on a topic even after you knew it was "good enough for [your] assignment" –  Pops Mar 26 '10 at 17:06
This doesn't answer your question specifically, but another option for this case would be to trim the string in-place. This is possible since a trimming operation will never increase the length of the string. Obviously, the code that uses your method will need to be modified to handle this change. –  Jeffrey L Whitledge Mar 26 '10 at 17:13
As Neil points out in his answer, detly's comment is wrong for modern C. The C99 standard allows variables in array declarations. So it is valid code. A lot of compilers default to C89 mode, though, just in case you want your code to compile on a DEC VAX or whatever. That's probably why you were getting an error. –  Chuck Mar 26 '10 at 17:18
I think that Jeffrey's answer is the most elegant. It would result in having all of the original memory allocated for the string held by the string object, but it seems that it's unlikely in normal usage for there to be a lot of white space, i.e. not a lot of waste. –  Aaron H. Mar 26 '10 at 17:39
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7 Answers

up vote 15 down vote accepted

To address (3) - You can free the newly allocated string from your calling code, once you are finished with it:

char* tmp = trim(myline);

if (tmp != NULL) {
    free( tmp );

But this places a burden on the caller to remember to free the memory. So instead you might consider passing an allocated buffer and a buffer size to trim(), for example:

void trim(char* line, char *trimmed_buf, int trimmed_buf_len){ ... }

Neil did an excellent job addressing your other questions. Basically an array declaration char trimmed[len]; will declare a local variable on the stack, so while it is syntactically correct to return a char * to this memory, the memory location that it points to will no longer be valid.

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This is the best answer, since it allows the caller to use an array allocated on the stack or on any heap of their choice, instead of forcing a particular memory management model. The main thing is to pass in both the starting pointer and length, so that there are no overwrites. –  Steven Sudit Mar 26 '10 at 17:07
Although common, there is no point in checking for NULL before calling free. The free function already does this NULL test internally and adding the test one more time adds no value (on the contrary I think it provides negative value by being noise). –  hlovdal Mar 26 '10 at 17:18
+1, thanks for the tip! I just included it in case he tries to do something with the pointer before calling free, in which case a NULL check would be a good idea. –  Justin Ethier Mar 26 '10 at 17:25
Thanks Justin and to everyone who've posted, it's helped a lot. I see now that I can still access the calloced memory outside of the function. That's what I wasn't getting. I thought I'd lost contact with it for ever. But what is returned is a pointer to the address of that memory so I can just use this to follow it back and free it. Cool. –  Joe Mar 26 '10 at 17:28
NULL checks after memory allocation are needed, but I strongly suggest reversing the test to if (tmp == NULL) {...} instead in order to no test the normal case, but test the exceptions (see stackoverflow.com/questions/114342/…) –  hlovdal Mar 26 '10 at 17:33
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To answer your specific questions, the syntax:

char trimmed[len];

where len is a variable, is only allowed in C99, not in C89 or in C++. The return type would indeed be a char *, but returning the local variable trimmed would result in undefined behaviour, so don't do it. And if you allocate an array dynamically in a function via calloc and return it, it is up to the caller of the function to free it, using the pointer that the function returns.

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Sanity! Thank you! +1 –  Tim Post Mar 26 '10 at 17:12
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Regarding dynamic sizing an array declaration like char trimmed[len]; the newest version of the C standard (ISO/IEC 9899:1999) allows this, but for this function it would not help at all. The trimmed variable has its scope within the trim function and it is allocated on the stack. So if you put return trimmed; in your code you return a pointer to a variable on the stack, and the portion of the stack where this variable lives will be released at the point where the function returns, so that will not work out so well...

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Have the caller pass in a pointer to a memory area (an a maximum length) to the function. That way the caller will be responsible for allocating (and deallocating) the memory, and the function will only provide output constrained to the buffer passed into the function.

Sure the person using the function could still mess things up (by specifying a length that doesn't have anything to do with actual buffer size, but then you can correctly argue it's the caller's fault, not this functions fault.

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Aside from C++ solutions like using std::string, you could always allocate an array of a set size, and pass the size in as a parameter, and the array as a parameter by reference or as a pointer?

This way the data is allocated in the same scope and there is no memory leakage.

Then again you can always free the memory after calling. It means that the code responsible for creating it and the code responsible for destroying the data are not the same, which can be a precursor to mistakes and errors.

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Allocation and deletion outside the function:

Allocate it from stack with char trimmed[SIZE] and pass it to the function or from heap with calloc and pass it to the function.

Allocation inside the function and deletion outside:

You allocate it inside the function with calloc, but the the caller must free it using free.

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Hm, well, answers to your questions:

  1. yes, the array would be allocated on the stack, not the heap and would be freed when the function returns.
  2. yes, char[] is mostly equivalent to char*. It is best to keep those separate, as there is a semantic difference.
  3. Using any pointer to the memory, you can use free. In your case, you would free the return the function. That is considered pretty bad form and bug-prone. You usually want the allocat'er to be the free()er. You could, perhaps, pass in a buffer for the new space, or the caller of the function could agree to have the char * line contents written on top of the existing contents. This works as trim() would always only remove stuff. I think the passed in buffer would work more often and is a good thing to get into the habit of.

As for your function, consider using memcpy() or its cousins to copy bytes into and out of a char buffer.

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