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.

Here is a program

#include <stdio.h>
{ unsigned char i=0x80;

The output it is giving is 256. I am not clear with what does

unsigned char i=0x80; <-- i is not int it is char so what will it store?

I know bitshift and hexadecimal things. How is the value of i being stored and how does it gets changed to 256?


Why did overflow not occurred when the bit shift operation happened?

share|improve this question
Google "hexidecimal" and "bitshift operators." –  Chris Lutz Jun 18 '11 at 18:54
shame on people who down vote it,discouraging some one who is trying to understand. –  Registered User Jun 18 '11 at 18:55
I know bitshift and hexadecimal but I am not able to understand what will unsigned char i store as it is not an int –  Registered User Jun 18 '11 at 18:55
You are correct that 256 "overflows" an unsigned character (on x86 at least) -- the "magic" is you are not passing a "unsigned char" value ;-) Compare with printf(..., (unsigned char)(128 << 1)) –  user166390 Jun 18 '11 at 19:00
@Registered - When you do i << 1 that operation is performed on an int, which also matches the "%d" in the format string. –  Bo Persson Jun 18 '11 at 19:21

5 Answers 5

up vote 17 down vote accepted

In C, a char is an integer type used to store character data, typically 1 byte.

The value stored in i is 0x80 a hexidecimal constant that is equal to 128.

An arithmetic operation on two integer types (such as i << 1) will promote to the wider type, in this case to int, since 1 is an int constant. In any case, integer function arguments are promoted to int.

Then you send the result to printf, with a %d format specifier, which mean "print an integer".

share|improve this answer
PS a char isn't, always, 8 bits wide. Be careful... –  Alex Jun 19 '11 at 7:24

I think that K&R have the best answer to this question:

2.7 Type Conversions When an operator has operands of different types, they are converted to a common type according to a small number of rules. In general, the only automatic conversions are those that convert a narrower'' operand into awider'' one without losing information, such as converting an integer into floating point in an expression like f + i. Expressions that don't make sense, like using a float as a subscript, are disallowed. Expressions that might lose information, like assigning a longer integer type to a shorter, or a floating-point type to an integer, may draw a warning, but they are not illegal. A char is just a small integer, so chars may be freely used in arithmetic expressions.

So i<<1 converts i to int before it is shifted. Ken Vanerlinde has it right.

share|improve this answer
pst, sverre, and netrom all have it right as well. –  grok12 Jun 18 '11 at 20:49

0x80 is hexadecimal for 128. The operation x << 1 means to left shift by one which effectively multiplies the number by two and thus the result is 256.

share|improve this answer
@netrom all that I understand but the variable i is not integer it is a char so that is what I am not getting. –  Registered User Jun 18 '11 at 18:56
Also, since printf is variadic, the result is cast to an unsigned int rather than back down to unsigned char which would truncate the value. –  Chris Lutz Jun 18 '11 at 18:57
The one thing missing in this answer is that the x is coerced to an int before the bitshift, so the result is also an integer, not an unsigned char. I think this is the biggest confusion presented in the question –  Ken Wayne VanderLinde Jun 18 '11 at 19:03
@Reg: As Ken said, x is coerced from unsigned char to unsigned int right before the left shift. That is why no overflow occurred. –  Morten Kristensen Jun 18 '11 at 19:24
@reg you need to get rid of the misconception that the computer stores values in decimal or hexadecimal. It doesn't. It uses binary. These binary values can be represented as decimal or hex or character but to the computer they are just integer values stored as binary. –  David Heffernan Jun 18 '11 at 19:41

i=0x80 stores the hex value 0x80 in i. 0x80 == 128.

When printing out the value in the printf() format statement, the value passed to the printf() statement is i<<1.

The << operator is the unary bitwise shift left operator, which moves the bits in i to the left one position.

128 in binary is `10000000', shifting that to the right one bit gives '100000000' or 256.

share|improve this answer
Based on some previous comments, it appears there is some confusion in what is actually stored in an unsigned character value. An unsigned character is simply an unsigned integral value of 8 bits. You may be familiar with this holding ASCII characters (like 'a', or 'V'), but these are still stored as 8-bit integral values. –  Chad Jun 18 '11 at 19:00
@Chad ok you mean to say in this case 0x80 is treated as a hexadecimal number and then converted to int i.e. 128 why does it not store the character whose ASCII value is 128 –  Registered User Jun 18 '11 at 19:00
I have an upvote, but it would be nice if this discussed the type of evaluating unsigned_char << 1 to round it out. –  user166390 Jun 18 '11 at 19:01
Err, 128 in binary is 10000000, shifting by 1 overflows the bounds of unsigned char on most platforms but due to printf being variadic it isn't cast back down. –  Chris Lutz Jun 18 '11 at 19:02
The character whose ASCII value is 128 () is always stored as 0x80, in fact they are equivalent. Try a simple program that checks if '€' == 0x80 –  Chad Jun 18 '11 at 19:09

i << 1 isn't being stored in i. Thus, there's no question of overflow and 256 is the output.

The following code will give 0 as the output.

#include <stdio.h>
    unsigned char i=0x80;
    i = i<<1;
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.