Take the 2-minute tour ×
Stack Overflow is a question and answer site for professional and enthusiast programmers. It's 100% free.

If i'm writing a program in C that i suspect might take a lot of memory, can i use the malloc function. Does malloc know how much memory my program wants? I know it returns a value of the memory it found but how does it know if its enough?


int * buffer;
buffer = (int*)malloc(sizeof(int)*70);

    fprintf(stderr, "malloc error!");
share|improve this question

migrated from programmers.stackexchange.com Feb 7 '12 at 14:12

This question came from our site for professional programmers interested in conceptual questions about software development.

How does the question title and the contents match? Do you have a particular problem with malloc in your program? What is it? Or are you asking a principal question on how malloc works in general? Then better read a book google for it there are plenty of ressources out there. –  Jens Gustedt Feb 7 '12 at 15:12
In C, never typecast the result of malloc. Read this. –  Lundin Feb 7 '12 at 15:25

7 Answers 7

Does malloc know how much memory my program wants?

You specify the amount of memory as malloc parameter, so that it knows how much memory to allocate

In your example it will allocate sizeof(int)*70 bytes (on 32bit Windows 4*70=280 bytes, for example)

I know it returns a value of the memory it found but how does it know if its enough?

It looks at your parameter and checks if OS has enough memory for you, if memory is not enough it returns NULL.

share|improve this answer
(Note that the OS can outright lie - overcommit. There's nothing you can do (portably) inside the app about that though.) –  Mat Feb 7 '12 at 14:19
@Mat may you give an example, where OS can outright lie? Do you want to say that I may receive memory even if there is no enough or may not receive it when it is enough? –  Tim Feb 7 '12 at 14:23
If the OS is set with a loose "overcommit" mode, you can request more than the available memory (including swap), and the OS will let you do so (i.e. malloc will return a valid pointer) - but your process (or something else) will get killed if it actually uses more memory than is really available. This is OS-specific. Tunable with /proc/sys/vm/overcommit_memory on Linux for example. –  Mat Feb 7 '12 at 14:32

Yes, if there isn't enough memory, malloc returns NULL.

share|improve this answer

The parameter you give to malloc is the number of bytes you want for this particular piece of memory.

If you want a char array to store 4 chars, you have to do

char *tab;
tab = malloc(sizeof(*tab) * 4);

This will take the size of *tab which is a char, times 4, and allocate this space in memory.
You have to know yourself how much is enough for your program to work.

share|improve this answer
Or if you for some crazy reason want the code to be readable, you could just write malloc(sizeof(char)*4); –  Lundin Feb 7 '12 at 15:30
Or if for some reason you want to be sure never to put the wrong type in sizeof, even if you change it, you can keep sizeof(*tab) ? A sizeof inside a malloc does not need to have the type hardcoded to be readable... Here you clearly read "I want tab to point to an array of 4", who cares if it's char or struct bmp_header during malloc ? –  Eregrith Feb 7 '12 at 15:33
Technically, accessing the contents of an uninitialized pointer is undefined behavior, but you probably get away with it on most compilers because sizeof() is evaluated at compile time. Strictly speaking, you allow the compiler to make your program go haywire with that line. Also, how often do you find yourself writing code for any kind of variable without actually knowing what type that variable actually is...? –  Lundin Feb 8 '12 at 8:23
You are not dereferencing here because, yes, sizeof() is evaluated at compile time and not just on "most" compilers. You are not doing this because you don't know the type, you are doing this because it is more readable, and if you change the type of tab, you won't have to peer through lines of code to change it everywhere and try not to forget anything. Because your compiler won't tell you if you do tab = malloc(sizeof(char*) * 4); when tab is in fact a int*. –  Eregrith Feb 8 '12 at 8:51
The last C11 draft standard is free of charge, and likely identical to the real standard in 99.99% of the cases. –  Lundin Feb 8 '12 at 10:33

malloc takes a parameter that defines the amount of memory required - and in your example it is enough memory to hold an array of 70 integers.

If it is unable to do so, it returns null.

share|improve this answer

You always have to tell malloc how much memory you require. It never knows by itself.

share|improve this answer

No, malloc does not know how much memory your program wants, you're the one who should know that, and you're telling malloc how much memory you need for that particular buffer.

However, this buffer is not the total memory allocated to your program, only the memory allocated to this particular variable. If there isn't enough memory in your system, malloc will return null.

Bottom line, there's no way for you to tell the operating system that your program will need a lot of memory, you need to allocate the memory for each buffer you need and then check whether it returned NULL to see whether there's enough memory in the system.

share|improve this answer

As others have said, you have to tell malloc how much memory you want. Note that if you don't allocate enough memory initially, you can use realloc to request more memory.

Here's an example. Suppose you want to store a line of text (delimited by a newline) from an input stream, but you don't know how long the line is, so you don't know ahead of time how much memory to allocate. You can read the input stream piecemeal into a smaller fixed-size buffer, and append that to a dynamic buffer that you can resize as necessary:

#include <string.h>
#include <stdlib.h>
#include <stdio.h>

 * Reads a line of text (delimited by a newline character) from an 
 * input stream into a dynamic buffer. 
char *getNextLine(FILE *stream, size_t *lineSize)
  char inbuf[SIZE];  // fixed-size input buffer
  char *line = NULL; // points to our dynamic buffer
  char *newline = NULL;
  char *(*append)(char *, const char *) = strcpy;

  *lineSize = 0;

   * Read from the input stream until we see a newline character
   * or the read fails (EOF or error).
  while (!newline && fgets(inbuf, sizeof inbuf, stream))
     * Resize the buffer to accomodate the string in the input buffer
     * (allocates the buffer the first time through).
    char *tmp = realloc(line, *lineSize + strlen(inbuf) + 1);
    if (tmp)
       * Check for a newline in the input buffer
      newline = strchr(inbuf, '\n');

       * If present, overwrite the newline with a 0 (nul terminator
       * character).  If you want to keep the newline in the target
       * buffer, skip this step.
      if (newline)
        *newline = 0;

       * Assign the temporary variable back to line and update the 
       * output buffer size.
      line = tmp;
      *lineSize += strlen(inbuf) + 1;

       * Write the contents of the input buffer to the target buffer.
       * First time through the loop we'll use strcpy (called through
       * the append function pointer); on each successive iteration
       * we'll use strcat to append the contents of the input buffer
       * to the target buffer.
      append(line, inbuf);
      append = strcat;
       * The realloc function failed; at this point, we'll just return
       * what we have.
      printf("Unable to extend buffer\n");

  if (!newline && !feof(stream))
    printf("Error on read!\n");

  return line;

This code uses realloc instead of malloc for the initial allocation (calling realloc with NULL as the first argument is the same as calling malloc).

Note that we assign the result of realloc to a temporary variable. If realloc fails (there isn't enough memory to satisfy the request) it will return NULL; if we assigned this to line we'd lose our pointer to any memory we've already allocated, causing a memory leak.

There's a little trickery with the append function pointer. The first time through the loop we want to copy our input buffer to the target buffer, so we set append to point to strcpy. After that, we want to append what's in the input buffer to the contents of the target buffer, so we set append to point to strcat.

Note that it's up to the caller to free the dynamic buffer when it's done with it.

share|improve this answer

Your Answer


By posting your answer, you agree to the privacy policy and terms of service.

Not the answer you're looking for? Browse other questions tagged or ask your own question.