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If the binary representation of 2^31-1 is 01111111 11111111 11111111 11111111, what happens to that binary number when typecast to short? This is assuming an int is 4 bytes, and a short is 2 bytes.

I wrote a test program, and the output is -1 when typecast to short. Is this correct? Does this mean that typecast to short just chopped off the 16 most-significant bits, leaving 11111111 11111111 (signed 2's complement)?


#include <stdio.h>
#include <stdlib.h>

void main()
        int x = sizeof(int);
        int y = sizeof(short);
        printf("%d, %d",x,y);

        int a = 2147483647;
        short b = (short)a;

        printf("\nad: %d",(int)a);
        printf("\nax: %x",(int)a);
        printf("\nau: %u",(int)a);

        printf("\nbd: %d",(int)b);
        printf("\nbx: %x",(int)b);
        printf("\nbu: %u",(int)b);


4, 2
ad: 2147483647
ax: 7fffffff
au: 2147483647
bd: -1
bx: ffffffff
bu: 4294967295
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Nit: It's just called "casting". "Typecasting" is when you see the same actor in the same type of role in TV or films. –  luser droog Sep 7 '13 at 8:44
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2 Answers 2

up vote 5 down vote accepted

When you assign an int to a short, if the value cannot be represented in the range of short( [-2^15, 2^15 - 1], in 2's complement), the result is implementation-defined. Signed and unsigned integers

When a value with integer type is converted to another integer type other than _Bool, if the value can be represented by the new type, it is unchanged. Otherwise, if the new type is unsigned... Otherwise, the new type is signed and the value cannot be represented in it; either the result is implementation-defined or an implementation-defined signal is raised.

As to "implementation-defined", it means that the behavior depends on the compiler, architecture, etc. Concretely, one possible result, as you may already see, is that high bits are simply discarded. This results in 11111111 11111111 in this case.

The other possible result, is that it's "rounded" down to the maximize value in the range. That is 01111111 11111111 in this case. But I can't memorize which implementation act like this.

But either way, don't rely on that.

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Will you please clarify what you mean by "implementation defined" –  user2756257 Sep 7 '13 at 8:38
@JonSmith It means that an implementation (compiler, architecture, ...) can decide what it does. –  user529758 Sep 7 '13 at 8:42
@JonSmith he basically means that each implementation will be different in many terms which will define the answer to this question. Different in terms like endianess or representation of int and short –  Ashish Yadav Sep 7 '13 at 8:44
Thanks all, much appreciated. –  user2756257 Sep 7 '13 at 8:44
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Any integer in C or any other language is stored in form of some bytes (4 bytes in C, if you use 32-bit C compiler, usually size of int depends on Compiler), when you typecast it to short and read from memory or assign to any variable, only lower 2 bytes are read or assigned since short directs the compiler to read the value as a short int.

In your case the integer is 01111111 11111111 11111111 11111111 in binary, therefore, when typecasting to short it is read as 11111111 11111111 (lower 2 bytes) which is binary representation in 16 bits for -1 (of course if its signed short, which is by default).

What I mean to say is, Suppose you have an int a = 0x7fffffff stored at address say 1234, then the memory representation of a will be:

 Memory Address:  1237     1236     1235     1234  
 Value:         01111111 11111111 11111111 11111111

When you read it as short, Only the lower 2 bytes (Addresses 1235 and 1234) are read.
Now reading them as short (or signed short) means you want the MSB of the number to be treated by compiler as Sign Bit. Since Sign bit = 1 means it is a negative number, and if you know the 2's Complement Number Format (which is used by C compiler to represent integers) then the number 11111111 11111111 in binary is equal to -1 in decimal.

Also when you use %u or printing the short int value, then it is treated as unsigned, the MSB contributes (this time) to the magnitude, not a sign bit.

One more thing I would like to add: Typecasting from short to int.
Whenever you typecast a short to int as you did in:

short b = (short)a;
printf("\nbu: %u",(int)b);

the sign bit is filled in all the extra higher bits, therefore 11111111 11111111 becomes 11111111 11111111 11111111 11111111 which is 4294967295 in unsigned decimal.

If you try typecasting 01111111 11111111 instead of 11111111 11111111 then it would have been promoted as 00000000 00000000 01111111 11111111 since sign bit is 0.

Hope you understood my explanation.

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@JonSmith Apparently, yes, in your particular case. –  user529758 Sep 7 '13 at 8:43
@H2CO3 : Thanks for pointing that out!! I have worked on 16-bit compiler, even then I did that mistake, my bad!! Now I have corrected it. –  Don't You Worry Child Sep 7 '13 at 8:56
I see, thank you! –  user529758 Sep 7 '13 at 8:57
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