# What does double ampersand do in this program?

I am learning how to create processes by using fork, and I am confused in the following. This is the code:

``````int main() {
int ret = fork();
// printf("%d\n", ret);
ret = ret && fork(); /* Here is where I am confused*/
// print("ret: %d\n", ret);
if(ret == 0) {
fork();
}
printf("Hello world\n");
return 1;
}
``````

So, what is the use of double ampersand exactly doing? I ran the program with a "printf" to know what was exactly the values, but it became more confusing because the output in the first "printf" is 0 and the second "printf" is "1". So I am not quite sure what is double ampersand doing.

I appreciate the help!

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It is a boolean operator... en.wikipedia.org/wiki/Boolean_algebra#Basic_operations Also, it is very... interesting, why there is a `return 1` at the end. This is nonsense. –  Gandaro Feb 15 '12 at 18:49
What you need is a tutorial covering the basics of C. –  dandan78 Feb 15 '12 at 18:49
sloppy code is indeed confusing –  Nick Dandoulakis Feb 15 '12 at 18:57
So, the point of this question was not if this is sloppy code or not, or basics of C!. The point of I was trying to understand how many "Hello world"'s will this program output! And because it printed less "Hello world"'s than I thought it should. I did not know what was happening in that line exactly. I am wondering if you guys know how many "Hello world"'s this program is printing without running the code. –  Oscarin Feb 15 '12 at 19:40
@dandan78 ...... read my comment –  Oscarin Feb 15 '12 at 20:06
show 11 more comments

It is called the logical AND operator. This will evaluate the logical ANDing result of the two operands. The property of this operator is:

First the left hand side operand is evaluated, if it is TRUE (non zero), then the right hand side operand is evaluated. If it is also true then the whole expression is true, or false otherwise. On the other hand, if the left hand side operand is FALSE, then the right hand side operand is not evaluated at all. This can be done because, as one of the operands is false, whatever be the other operand, the expression becomes false. This is known as short circuiting

In your code, if the left hand if `ret` is true, then only the right hand side portion is evaluated, which eventually calls the `fork ()` system call. The return value of the call is ANDed with the current value of `ret`, and reassigned to `ret`.

Basically it works like

``````if (ret == TRUE)
{
retval = fork ();
ret = ret && retval;
}
``````

On success, the PID of the child process is returned in the parent, and 0 is returned in the child. On failure, -1 is returned in the parent, no child process is created, and errno is set appropriately.

Consider the fork tree below. Each tree "node" shows the sequence of executed statement in each individual statement. One work in one line.

``````    (p1)
+--+ret = fork ();
|   printf 1 shows pid
|   && allows         fork (), ret = 1 = pid1 && pid2
|   printf 2 shows 1    +
|   `if' not entered    |
|   show hello          |
|                       |    (p3)
|                       +--+ ret = 0 = ret && fork () (this is 0 here)
+-----+                      printf 2 shows 0
|                      `if' is entered
|                      fork ()
|                      show hello
|                            +
|                            |
+                            |
(p2)                          |
level 1                        +-------+
print 0 in 1st printf                  |
&& DOES NOT allow fork ()            (p5)
print 0 in 2st printf             show hello
`if' entered
fork () +-----------+
show hello          |
|
+
(p4)
show hello
``````

Here what goes in each process.

p1 executes `fork ()` once, and has a pid (non-zero) in ret. prints the pid short circuit allows to execute fork (). As this is the parent, it returns another pid, which is anded with the previous child pid, which evaluates to 1. Therefore `ret` now contains 1, which is printed in the second printf. as `ret` is 1, `if` is not executes. Hello is printed.

p2 Child of p1, so ret has 0. prints 0 in the first printf. Short circuit does not allow `fork ()` call. `if` body is entered, and `fork ()` is called, which makes (p4). Now (p2) proceeds to print Hello.

p3 Child of p1, so `fork ()` return is 0, which is ANDed with ret, and makes it 0 after the assignment. This is spawned after the first printf, so only the second printf shows 0. `if` is entered, `fork ()` is executed, which makes (p5). Now p4 proceeds to print Hello.

p4 starts from `if` body, gets out and prints Hello

p5 starts from `if` body, gets out and prints Hello

Above I have tried to express the process spawn tree, and the sequence of works in each process is expressed in each line of the process "node" on the tree. The edges denote spawn, and the edge start at the corresponding fork.

-
Thanks! This clarifies a lot!! –  Oscarin Feb 15 '12 at 20:13
Note what are printed at each level. –  phoxis Feb 15 '12 at 20:19

In C, the double ampersand `&&` is a short-circuit logical AND operation. If you have something like `a && b`, then this will evaluate as follows: it will return true if both `a` and `b` are true, but if `a` is false then `b` will never be executed.

As an added example:

``````int a = 0;
if (a && myfunc(b)) {
do_something();
}
``````

In this example, short-circuit evaluation guarantees that myfunc(b) is never called. This is because a evaluates to false. This feature permits two useful programming constructs. Firstly, if the first sub-expression checks whether an expensive computation is needed and the check evaluates to false, one can eliminate expensive computation in the second argument. Secondly, it permits a construct where the first expression guarantees a condition without which the second expression may cause a run-time error.

So your code only calls `fork()` if `ret` is true. `ret` is then assigned either 0 (`ret` is 0) or 1 (both `ret` and `fork()` are true).

-
Thanks, I appreciate the help! Now it makes sense. It was kind of a dumb question, but I did not see the answer after you showed me. Again, thanks! –  Oscarin Feb 15 '12 at 19:35

It's a logical AND, meaning if `ret` is true (non-zero), AND the result of `fork()` is true (non-zero) assign true to `ret`, else assign false (zero) to `ret`.

Since this operator is short-cirucuited, `fork()` will be called only if `ret` is true.

-
Then explain why "the output in the first printf is 0 and the second printf is 1" –  BlackBear Feb 15 '12 at 18:52
@BlackBear - I will in an hour, have to catch a ride/ –  Binyamin Sharet Feb 15 '12 at 18:53
Probably important to note that what it's really trying to do is cause prevent the child from forking again since "Upon successful completion, fork() shall return 0 to the child process and shall return the process ID of the child process to the parent process." –  BeRecursive Feb 15 '12 at 18:54
@BlackBear: The ordering of the printf of parent and child cannot be predicted. Without synchronization it may interleave. You can check my answer for the process tree, it might help. –  phoxis Feb 15 '12 at 20:11

I think what's wrong is a misunderstanding of how fork() works. If you're on UNIX, you need to do "man fork", because according to the one I read:

DESCRIPTION fork() creates a new process by duplicating the calling process. The new process, referred to as the child, is an exact duplicate of the calling process, referred to as the parent,

and..

RETURN VALUE On success, the PID of the child process is returned in the parent, and 0 is returned in the child. On failure, -1 is returned in the parent, no child process is created, and errno is set appropriately.

I suspect what might be happening is you might be seeing output from multiple forked processes that is only succeeding in confusing you. What is the exact full output of your program?

This is unlikely to be a short circuit problem because even if the second one fails, at least the first fork should have succeeded, and thus you should get a pid from at least one of the first printfs if that fork succeeded.

-

It's a lazy logical `AND` function. Search for the truth table for `AND` if you need more info on that. It's lazy because if ret is false, `fork()` will not be evaluated since anything ANDed with `false` is always `false`.

-

It's a short-circuit logical AND. If `ret` is 0, then it will execute the `fork()`. If not, it won't. I can walk through the code for you.

``````//we fork a child process
int ret = fork();

//ret is 0 if we are in the child process, -1 if fork failed
//otherwise ret is the process id of the child process

//because of this, the fork below executes only within the child process
ret = ret && fork(); /* Here is where I am confused*/

//at this point, if we did fork a process (in the child), then ret is 0 in the child
//then we fork again
if(ret == 0) {
fork();
}
``````

So we have our first process, process 1 executing this code. Let's assume all forks are successful (but you should make sure to check this... I think it should be handled within the existing code but it isn't that obvious).

• Process 1 forks, creating a child process with process ID 2.
• ret is now 2 in process 1 and 0 in process 2.
• In process 1, since ret is non-zero, no fork happens.
• In process 2, ret is 0, so we fork a child process with process ID 3.
• Now ret in process 1, 2, and 3 are 2, 3, and 0, respectively.
• Now process 3 will fork a new child.
-

The first fork, ret - fork(), will result in 3 possible outcomes:

• > 0 => parent gets pid of child
• = 0 => child process
• < 0 => error with fork

The second fork, ret = ret && fork(), will execute the fork() only if ret is nonzero. This can happen in the parent good case and the parent error case. The result of this statement can be:

• == 0 => ret was nonzero and fork() is zero.
• != 0 => ret was nonzero and fork() was nonzero.

The third fork, if (ret == 0) { fork() }, will only execute if ret is zero.

So what does all of this mean? The second fork seems suspect in that the return value from the first fork could be nonzero in the case of a parent success or failure! I don't know if this was the intended result, but it seems dubious.

The third fork would happen if the first fork return was in the child, the second fork doesn't get executed, but the third does. The third fork can also get executed if the first fork is in the parent context and the second fork is in the child context.

Someone check this logic as I could never write this kind of code.

-

In C language, the act of the `&&` operator is so:

1. Calculate the first argument. if it's zero, don't calculate the second argument, and the result is 0.
2. If the first argument isn't zero, calculate the second argument. if it's zero, the answer is 0. else, it's 1.

The function `fork` return 0 to the child process, and another number (the child's pid) to the father, so after your first `fork`, in the father process `ret>0`, and in the child process, `ret==0`. If you uncomment the first `printf`, you will get 0 and another number.

Then, you run your line. In the child, `ret` is 0, so the calculating of the `&&` is stopped before of the fork, and `ret` remains 0. In the father, `ret>0`, so it runs `fork()`, and create another child. In the father process, `fork` return positive number, so `ret` will be 1, and in the second child, `fork` return 0, so `ret` will be 0. So, if you uncomment only the second `printf`, you will get `0`,`0`,`1` (Maybe in different order).

Then, you do `if (ret==0) fork();`, so the both children (whose `ret` is 0) create new process each. Now, you have totally 5 processes, so the line `Hello world\n` will be printed 5 times.

(It's pretty dangerous to use output functions while messing with `fork` - you have 5 processes that write to the same file without any locking, so you can get results like `HHHHHeeeeellllllllllooooo wwwwwooooorrrrrlllllddddd\n\n\n\n\n`)

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Yes. That is what I realize after it. Thanks for the explanations. And don't worry with that. The point of this program is to know how many processes this program has. And I thought it should have more than five, and when I tried to debug it I realized that what I was thinking in that line was wrong. That is why I was asking was going on in that particular line. Again thank for you explanation. –  Oscarin Feb 15 '12 at 19:56