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As far as I know the output should be like 3.14,3.14,3.14 and 256,256,256 right? But this produces a different output. Can anyone please guide me through this and tell me why this happens?

     float a = 3.14;
     int b = 256;
     char *p, *p1;
     p = (char *) &a;
     p1 = (char *) &b;
     printf("\nValue of *p=%f",*p);
     printf("\nValue of a=%f",a);
     printf("\nValue of *p=%f",*p);
     printf("\nValue of *p1=%d",*p1);
     printf("\nValue of b=%d",b);
     printf("\nValue of *p1=%d",*p1);

    Value of *p=0.000000
    Value of a=3.140000
    Value of *p=3.140001

    Value of *p1=0
    Value of b=256
    Value of *p1=0
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4 Answers 4

up vote 2 down vote accepted

I got slightly different answers that you did (http://ideone.com/RG4uq) which is not really suprising given that the behavior of variadic functions with mixed floating point and integral types is undefined.

Here's what is happening. Assuming memory starts at address 0x50000000, 32-bit machine, little endian

50000000  c3  f5  48  40   (a)
50000004  00  01  00  00   (b)
50000008  00  00  00  50   (p)
5000000c  04  00  00  50   (p1)

Type of a is float, type of b is int, type of p is char*, type of p1 is char*.

For integers, you see

  • print p1 as an int ==> *p1 is the byte at address 50000004, which is 0, so 0 is printed.
  • print b as an int ==> well obviously b is 256 because it is an int.
  • print p1 as an int ==> *p1 is the byte at address 50000004, which is 0, so 0 is printed (as before).

On a little endian machine, you can even try printing p1[1] as an integer and you will see 1 (interesting, eh? See http://ideone.com/daS6d).

For floats, things are different. On many processors, say the x86-64, parameters are passed in registers. You are calling printf three times. Each time the thing that will be printed comes from xmm0 (assuming the x86-64). But notice when you first try to print *p which is a char, nothing is passed in xmm0 (*p is passed in %edi) so whatever junk you had in there gets printed (could be 0, or 0.0234892374 or whatever). But next you pass a real float in xmm0 and print 3.14. But when you come around for the third printf, again you don't pass anything (because *p is a char) and so what is left in xmm0? That's right 3.14. It could have been something else, perhaps, but most likely it hasn't changed. :)

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The expression *p has type char. The format specifier %f requires an argument of type float. Passing an argument of the wrong type to a variadic function like printf invokes undefined behavior.

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+1 for this answer plus the corrections in the comments to dasblinkenlight's answer. :) –  Ray Toal Aug 20 '12 at 4:27
These are the outputs I get when I use %c instead of %f for printing the p and p1 bro:codepad.org/fTvUrW83(Symbol Output) ideone.com/KNdsr(Blank Output). –  glnarayanan Aug 20 '12 at 7:27
@glnarayanan In your question you weren't really clear about why you found your output surprising. I assumed it was because the line printf("\nValue of *p=%f",*p); produced different outputs the two times you executed it. In your new program this is no longer the case, so I don't see the problem. –  sepp2k Aug 20 '12 at 8:52
@glnarayanan Oh I see that you edited the question to be more specific since I've first read it. No, the output you expected would not be the correct result. There are no circumstances under which dereferencing a char pointer would ever give you a floating point value. For one thing a char is only a single byte and floating point values consist of multiple bytes. –  sepp2k Aug 20 '12 at 9:09

It is not behaving as expected because float* and char* are of different sizes. Converting them may sacrifice your expression accuracy!

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It is unlikely that float* and char* are different sizes although float and char almost certainly are. –  Robert Gamble Aug 20 '12 at 2:09

The short answer is that you are invoking undefined behavior when you pass a char type to printf using a format specifier of %f and as such you should't expect anything in particular.

The long answer is implementation dependent but what follows is my observation of what is likely occurring on your platform. When you ask printf to print a double value (as with the %f format specifier), it reads the next sizeof(double) bytes from the stack and interprets it as a floating point value and prints it. In the first printf call, the first time a new stack frame is generated, the data on the stack after the bits that form the char you actually passed equate to a zero floating point value. In the second call to printf, a new stack frame is generated, probably overwriting the same space that the first call did. In this case, a full double value is present and it is printed as expected. The stack frame is "destroyed" when the function returns. As a matter of efficiency, the stack frame is not typically zeroed out when a function returns and the contents remain. In your third call to printf, you again pass a single byte whereas you ask printf to interpret sizeof(double) bytes as a floating point value. The stack frame from the previous call to printf now contains the value of the double passed from the prior call, with one of those bytes overwritten with the byte from the new argument which results in the value printed.

If I change your second printf call to:

printf("\nValue of a=%f", 1.234);

the third call to printf prints (on my system):

Value of *p=1.234000

which seems to validate the logic presented above.

In summary, you are asking printf to read more data from the stack than you actually passed to the function and as such you the results are undefined. In your case, the data read is remnants of previous calls which explains the result you get on your specific platform. (As Ray points out, the actual way the argument is passed could vary as this is implementation dependent. Some systems will pass the value in a register but the point remains the same.)

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Passing a char using %d is perfectly fine. char gets promoted to int anyway. It's just %f that's the problem. –  sepp2k Aug 20 '12 at 2:09
@sepp2k, I think it depends actually. If char is unsigned and char and int are the same size then the argument actually gets promoted to unsigned int which makes the call undefined. –  Robert Gamble Aug 20 '12 at 2:20

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