Take the 2-minute tour ×
Stack Overflow is a question and answer site for professional and enthusiast programmers. It's 100% free, no registration required.

What is the advantage of zeroing out memory (i.e. calloc() over malloc())? Won't you change the value to something else anyways?

share|improve this question
add comment

7 Answers

up vote 7 down vote accepted

There are two camps: one says that initializing variables when they are declared helps find bugs. The people in this camp make sure everything they declare is initialized. They initialize pointers to NULL, ints to 0, etc. The idea is that everything is determinate, and when they see a NULL-pointer in a debugger, they immediately know it wasn't set properly. It can also help your program crash during testing because of NULL-pointer dereferencing rather than mysteriously crashing in production runs.

The other camp says that initializing variables at declaration makes things harder to debug, because now a compiler can't warn you about variables "used without being set".

Without telling you my personal preference1: if you belong to the first camp, you would want to calloc() instead of malloc(). If you belong to the second camp (which apparently you do) then you prefer malloc() over calloc().

Now there are two exceptions:

  • If you belong to the "initialize everything" camp, you don't calloc() but malloc() because you are initializing floating-point numbers or pointers, and you know that all bits zero doesn't necessarily mean 0 for them. Or, you don't want the extra overhead.
  • If you belong to the "set when you need to" camp, you may want to calloc() when you are allocating some data and want it to be all zeroes. For example, if you want to calculate the row-wise sum of an n by m dynamically allocated int data.

1 You can see my answers to many of the questions here on SO to see which camp I belong to :-).

share|improve this answer
    
I'd like you to name a computer made this side of 1970 that doesn't use zeros for NULL pointers or zeroed out floating point values. Not to mention, the last few years I've programmed Windows and Linux, a simple malloc does zero the memory. I believe it's supposed to be a security feature. –  Arthur Kalliokoski Feb 13 '10 at 2:46
2  
All the IEEE floating point formats define the special case of "all bits zero" represents true zero. –  wallyk Feb 13 '10 at 2:52
    
It's more a question of what is guaranteed by the standard. If I really want NULL pointers, I will set them to NULL in a loop. –  Alok Singhal Feb 13 '10 at 2:56
    
@akillio: that's almost a philosophical question, though: do you program to the standard, or do you program to the implementations you know about? Personally, I try to program to the standard if I'm writing supposedly-portable code: it's easier than learning about every computer made this side of 1970. I have in the past been genuinely surprised by compilers doing something I thought "never happens". One example which springs to mind is an ARM ABI with middle-endian data types, ffs. Obviously 0 was still bitwise 0, so not the example you asked for. –  Steve Jessop Feb 13 '10 at 2:56
1  
@Michael Burr: well, one day our compiler team started running around like headless chickens, because one of the ARM calling conventions they had to deal with had the bytes within each word of a double in little-endian order, but the most significant of the two words first. uint64_t didn't do the same, it was regular LE. There's a mention of it here: khronos.org/registry/kode/extensions/KHR/float64.html. It applies to ARM cores with the old FPA floating-point unit: wiki.debian.org/ArmEabiPort –  Steve Jessop Feb 13 '10 at 12:00
show 9 more comments
  1. By knowing what value is already there, a programmer can take some shortcuts and make certain optimizations. Most frequently, callocing a structure with pointers: they are initialized to NULL.
  2. What if the programmer forgot to initialize something in the allocation? Instead of random stuff, zero is a great default value.

In a realtime process control system I worked on long ago, we settled on having the power-on logic initialize all of RAM to 0xCC, the 8086's interrupt 3 instruction. This would cause the processor to enter the monitor (a primitive debugger) if it somehow executed uninitialized memory. (Unhelpfully, the 8086 merrily executes memory containing zeros since they are add [bx+si],al instructions. Even 32-bit mode causes them to be add [ax],al instructions.)

I don't recall if we ever found a runaway program, but the values corresponding to 0xCC in various values: 52,428 (unsigned 16 bit), -19,660 (signed 16 bits), -107374176 (32-bit float), and -9.25596313493e+61 (64-bit float) popped up in a lot of unexpected places. Also, some code expecting characters to be 7 bit ASCII—that is, a bug—alerted us to its presence when it tried to process 0xCC.

share|improve this answer
    
calloc to make pointers set to NULL is useless because it's not guaranteed by the standard that all-bits-zero == NULL. Similarly for floating-points. –  Alok Singhal Feb 13 '10 at 2:53
1  
That hasn't been true since the late 1970s. All important architectures use (void *) 0 as NULL, and the IEEE floating point formats all use "all bits zero" as true zero. –  wallyk Feb 13 '10 at 3:06
1  
(void *)0 is not necessarily all-bits-zero. The compiler must do the translation of (void *)0 to the appropriate "null pointer constant". Similarly, when you write p = 0; and p is a pointer, the compiler must set p to a bit-pattern that's equal to the null pointer constant, which may not be all bits zero. –  Alok Singhal Feb 13 '10 at 3:09
1  
Similarly integer types (other than unsigned char and the C99 fixed-size types (u)intN_t), are permitted to have padding bits, setting which to 0 can be a trap representation (for a far-fetched example if there's an inverse-parity bit, then all-bits-zero is a parity violation). Unlikely, downright evil, but if you live by the standard then you can die by the standard... –  Steve Jessop Feb 13 '10 at 3:13
    
Anyone have real world examples of architectures that don't use all bits zero as null? –  Kevin Gale Feb 13 '10 at 3:20
show 8 more comments

Assume you want to write a counting sort implementation, or depth first search a graph and keep track of visited vertices. You'll update your memory as the algorithm runs (rather than assigning a value just once). You need to initialize it to zero at the beginning. If you didn't have calloc, you'd have to manually go through it and initialize it to zero at the beginning of your algorithm. calloc can potentially do this more efficiently for you.

share|improve this answer
    
Upvoting because the rest of the answers only mention the bug-finding or short-cutting advantages (which are great info, too). They don't mention (what is probably) the original intended purpose of calloc. Sometimes you have an algorithm that allocates memory, and requires that data to be initialized to zero. Simple as that. Just because you'll eventually store a different value doesn't mean that zero isn't the correct initial value. –  Merlyn Morgan-Graham Feb 13 '10 at 2:54
    
@Merlyn: for some value of "the rest of the answers" :-) –  Alok Singhal Feb 13 '10 at 3:01
1  
Oh, sorry. I didn't realize you were still talking! ;) –  Merlyn Morgan-Graham Feb 13 '10 at 3:15
    
LOL. I am not dead yet. :-) –  Alok Singhal Feb 13 '10 at 3:40
add comment

It's good to know that whatever you're allocating is initialized to zero. Many bugs have come about from code that uses uninitialized memory. Plus, some default values in structs / classes might be fine as zero so you don't need to change all values after the malloc.

For instance, allocate a struct that has some pointers in it w/ malloc. NULL checks aren't always going to work unless they are set to NULL. If you calloc, you don't have to do the extra initialization steps for pointer values.

share|improve this answer
    
As I said in another comment: calloc to make pointers set to NULL is useless because it's not guaranteed by the standard that all-bits-zero == NULL. –  Alok Singhal Feb 13 '10 at 2:55
add comment

In addition to the benefits of initializing variables calloc also helps track down bugs.

If you accidently use a bit of the allocated memory without properly initializing it the application will always fail the same way. For example with a access violation from a null pointer. With malloc the memory has random values and this can cause the program to fail in random ways.

Random failures are very hard to track down and calloc helps avoid those.

share|improve this answer
add comment

First of all you cannot calloc pointers, at least not if you want to follow standard C.

Second, bugs just becoming masked when you clobber the member with all zeros. It is much better practice to have a debug version of malloc that initialises the memory to something that will always crash, such as 0xCDCDCDCD.

Then when you see an Access voilation you know the problem straight away. It is also beneficial to have debug free function that will whip thje memory with a different pattern so those who touch the memory after it is freed get an unexpected surprise.

Working on an embedded system, callocing just to "be sure" is usually not an option. You typically allocate and populate in one go so calloc just mens you are double touching memory.

share|improve this answer
add comment

No one has touched on the aspect of performance so I guess I'll have to. If you need to write a very fast program malloc with a "just in case" integrated memset is not a good way to go. It doesn't matter how fast the memset is, it will always be too slow. Sometimes you must initialize a vector or an array so the real issue is having control of your clock cycles (i e not wasting them). I heard a quote once "you should never give up performance accidentally" which means that from a performance standpoint you must always know why you have chosen to implement code in one way or another (what the pros and cons are and how they are weighed against each other in the specific case).

If you have a buffer that will be filled with a string it might be "nice to have" to initialize it before the string is filled in but most will agree it's a complete waste of clock cycles. If you're writing a new str* function you might want to - for debugging purposes - fill the buffer with a value that typically shouldn't appear but this will have been removed come distribution time.

As others have mentioned the compiler will warn if an uninitialized variable is being accessed so as I see it the bottom line is that there really is no excuse for initializing "just in case."

share|improve this answer
add comment

Your Answer

 
discard

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.