# Difference between K&R and ANSI function outputs

I ran the following code, and found some strange output.

``````
int
mean_ansi (int num1, int num2)
{
printf ("In %s\n", __FUNCTION__);
printf ("num1,num2 is %d,%d\n", num1, num2);
return (num1 + num2) / 2;
}

int
mean_K_and_R (num1, num2)
int num1, num2;
{
printf ("In %s\n", __FUNCTION__);
printf ("num1,num2 is %d,%d\n", num1, num2);
return (num1 + num2) / 2;
}

int
main ()
{
int i = 6;
double f = 1.0;

printf ("In %s\n", __FUNCTION__);
printf ("[f,i] = [%f,%d]\n", f, i);

/* deliberate mistakes */
mean_ansi (f, i);
mean_K_and_R (f, i);

return 0;
}
```
```

Output:

In main

[f,i] = [1.000000,6]

In mean_ansi

num1,num2 is 1,6

In mean_K_and_R

num1,num2 is 0,1072693248

Can anyone explain this behavior.

I saw the assembly but could not make out much.

Is there a difference in the way function arguments are pushed on the stack in both these syntaxes?

-
Good question (and good reason to definitively bury K&R declarations) –  Alexandre C. Dec 4 '11 at 13:06

Dan Olson had the right idea, and Slartibartfast explained where the values com from:

The definition of `mean_K_and_R()` is treated as if it were defined like this

``````int mean_K_and_R();
``````

ie the function takes any arguments and doesn't do any conversion aside from the default argument promotion.

If the cdecl calling convention is used, this means `mean_K_and_R(f, i)` will first push `i` to the stack, then the higher bits of `f` and then the lower bits of `f`.

But the function thinks it took two integer arguments, meaning `num1` will now refer to the lower bits of `f` and `num2` to the higher bits of `f`.

-
This is probably aggravated by the fact that the arguments are used with printf, which does no type checking. What would happen when they're used in the expression return (num1 + num2) / 2? The function thinks they're ints, will it try to promote from double to int? –  Dan Olson Feb 26 '09 at 11:56
@Dan: this has nothing to do with `printf()`: the compiler has already 'lost' the type information, ie there won't be any conversion done even in arithmetic expressions; the bit pattern of the double is interpreted as two integers because of it's particular position in the stack –  Christoph Feb 26 '09 at 15:41
@Dan: if you know C++, think something along the lines of `reinterpret_cast<int [2]>(f)` where the resulting array holds `num1` and `num2` –  Christoph Feb 26 '09 at 15:42

I did some digging and found a thread indicating that K&R style function declarations don't create a prototype, so without a separate prototype the compiler is free to treat the arguments incorrectly if it desires.

I'm not sure how true this is, you could probably verify it by inserting a prototype quickly and seeing if the functions generate the same values.

In any case K&R style declarations are very outdated, as I'm sure you know, and should probably be avoided. If anything your problem is an example of that.

-

My guess is that in the first case, there wan an implicit conversion of `double` to `int`. In a second one, 64 bits representing 1.0 were interpreted as two integers. Number 1072693248 is represented binnary as

``````00111111111100000000000000000000
``````

but if you take a look at this page, you'll see that this is actually an upper half of double representation of number 1. The first 0 is sign, 01111111111 is exponent and rest of zeros are an upper bits of fraction. Only thing I don't get is where the 1 for fraction went? Having said all this I would expect the output to be 1,1072693248.

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the firt bit of the fractional part is always 1 (as long as the values are not subnormal), ie there's no need to store it –  Christoph Feb 23 '09 at 11:19