Take the 2-minute tour ×
Stack Overflow is a question and answer site for professional and enthusiast programmers. It's 100% free.

I understand typecasting...but only in retrospect. My process to figure out what requires typecasting in expressions is usually retroactive because I can't predict when it will be required because I don't know how the compiler steps through them. A somewhat trite example:

int8_t x = -50;
uint16_t y = 50;
int32_t z = x * y;

On my 8-bit processor (Freescale HCS08) sets z to 63036 (2^16 - 50^2). I can see how that would be one possible answer (out of maybe 4 others), but I would not have guessed it would be the one.

A better way to ask might be: when types interact with operators (+-*/), what happens?

share|improve this question
The best is to actually get the C draft/standard and read. That way you get it first hand, instead of third hand by other people (who for the sake of explanation almost invariably need to skip details and such). –  Johannes Schaub - litb Sep 17 '10 at 17:06
Your example is incorrect - either you haven't actually tested this or your compiler is broken - you should get -2500 as expected. –  Paul R Sep 17 '10 at 17:22
@Paul R: It's what I get with my HCS08 compiler; does it not conform to the standards or does it just not match yours? –  Nick T Sep 17 '10 at 17:26
It depends on what size int has. Assuming int is 32 bits, then both x and y are converted to int, the multiplication is carried out signed, and -2500 is written into z. –  Johannes Schaub - litb Sep 17 '10 at 17:38
@Jonathan: It doesn't matter whether it fits. int is 16 bits, so the multiplication x*y is carried out in unsigned int (with x first converted to the value 65486). The result is 63036, which finally is converted to a signed 32bit value for assignment to z. The usual arithmetic conversions are a nightmare... –  Steve Jessop Sep 17 '10 at 18:11

7 Answers 7

up vote 2 down vote accepted

The folks here that say that values are always converted to the larger type are wrong. We cannot talk about anything if we don't know your platform (I see you have provided some information now). Some examples

int = 32bits, uint16_t = unsigned short, int8_t = signed char

This results in value -2500 because both operands are converted to int, and the operation is carried out signed and the signed result is written to an int32_t.

int = 16bits, uint16_t = unsigned int, int8_t = signed char

This results in value 63036 because the int8_t operand is first converted to unsinged int, resulting in 65536-50. It is then multiplied with it, resulting in 3 274 300 % 65536 (unsigned is modulo arithmetic) which is 63036. That result is then written to int32_t.

Notice that the minimum int bit-size is 16 bits. So on your 8-bit platform, this second scenario is what likely happens.

I'm not going to try and explain the rules here because it doesn't make sense to me to repeat what is written in the Standard / Draft (which is freely available) in great detail and which is usually easily understandable.

share|improve this answer

The compiler is suppsed upcast to the largest type in the expression and then place the result into the size of the location. If you were to look at the assembler output of the above, you could see exactly how the types are being read in native format from memory. Upcastings from a smaller to a larger size is safe and won't generate warnings. It's when you go from a larger type into a smaller type that precision may be lost and the compiler is supposed to warn or error.

There are cases where you want the information to be lost though. Say you are working with a sin/cos lookup table that is 256 entries long. It's very convienent and common (at least in embedded land) to use a u8 value to access the table so that the index is wrapped naturally to the table size while preseving the circular nature of sin/cos. Then a typecast back into a u8 is required, but is exactly what you want.

share|improve this answer
isn't 50 times -50 a negative number? –  Aaron Anodide Sep 17 '10 at 17:10
Maybe, depends if the place it is stored is signed or not. In this case the expression will assign into a signed value variable so it will be fine, though some compilers will warn about sign/unsigned math. The bits are the same signed or unsigned either way. –  Michael Dorgan Sep 17 '10 at 17:13
This is such a simplification I referred to in my comment. What do you think unsigned short s = 1; int i = s * -1; is? And what unsigned int s = 1; long long i = s * -1L; (both on a 32 bit system)? It's not catched by "the compiler is supposed to upcast to the largest type in the expression.". –  Johannes Schaub - litb Sep 17 '10 at 17:25
long long I've found is hacked badly in most compilers I work with. Still, I would expect both answers to be -1. Why would they be anything else? –  Michael Dorgan Sep 17 '10 at 17:38
@Michael: for the second one, if int and long are the same size (as they would be on a typical 32bit system or an LLP64 system), then -1L will be converted to unsigned, and the result is UINT_MAX, not -1. If long and long long are the same size (as they would be on an LP64 system), then the result is -1. –  Steve Jessop Sep 17 '10 at 18:34

You will need type casting when you are down casting.

upcasting is auto and is safe, that is why the compiler never issues a warning/error. But when you are downcasting you are actually placing a value which has higher precision than the type of variable you are storing it in that is why the compiler wants you to be sure and you need to explicitly down cast.

share|improve this answer

If you want a complete answer, look at other people's suggestions. Read the C standard regarding implicit type conversion. And write test cases for your code...

It is interesting that you say this, because this code:

#include "stdio.h"
#include "stdint.h"

int main(int argc, char* argv[])
  int8_t x = -50;
  uint16_t y = 50;
  int32_t z = x * y;
  printf("%i\n", z);
  return 0;

Is giving me the answer -2500.

See: http://codepad.org/JbSR3x4s

This happens for me, both on Codepad.org, and Visual Studio 2010

share|improve this answer
This is on an embedded processor (HCS08). What it shows me over the serial terminal (63036), and in the memory with the debugger (00 00 F6 3C) agree, so I don't know if my compiler is "broken" (with respect to the standards) as Paul suggests, or just different. –  Nick T Sep 17 '10 at 17:33
@Nick: your compiler is not "broken" unless you want to go so far as considering all compilers with 16-bit int "broken". :-) –  R.. Sep 18 '10 at 1:26

When the compiler does implicit casting, it follows a standard set of arithmetic conversions. These are documented in the C standard in section 6.3. If you happen to own the K&R book, there is a good summary in appendix section A6.5.

share|improve this answer
"arithmetic conversions"--the term I was looking for it appears. C99 web.archive.org/web/20050207010641/http://dev.unicals.com/… seems to zero in on what goes on. –  Nick T Sep 17 '10 at 18:09

What happens to you, here, is integer promotion. Basically before computation takes place all types that are of a rank smaller than int are promoted to signed or unsigned, here to unsigned since one of your types is an unsigned type. The computation is than performed with that width and signedness and the result is finally assigned.

On your architecture unsigned is probably 16 bit wide, which corresponds to the value that you see. Then for the assignment the computed value fits in the target type which is even wider, so the value remains the same.

share|improve this answer

To explain what happens in your example, you've got a signed 8-bit type multiplied by an unsigned 16-bit type, and so the smaller signed type is promoted to the larger unsigned type. Once this value is created, it's assigned to the 32-bit type.

If you're just working with signed or unsigned integer types, it's pretty simple. The system can always convert a smaller integer type to a larger without loss of precision, so it will convert the smaller value to the larger type in an operation. In mixed floating-point and integer calculations, it will convert the integer to the floating-point type, perhaps losing some precision.

It appears you're being confused by mixing signed and unsigned types. The system will convert to the larger type. If that larger type is signed, and can hold all the values of the unsigned type in the operation, then the operation is done as signed, otherwise as unsigned. In general, the system prefers to interpret mixed mode as unsigned.

This can be the cause of confusion (it confused you, for example), and is why I'm not entirely fond of unsigned types and arithmetic in C. I'd advise sticking to signed types when practical, and not trying to control the type size as closely as you're doing.

share|improve this answer
I'd advise the other way around: never use signed types unless you know what you're doing and really need to. Unsigned has much cleaner and more predictable behavior. –  R.. Sep 18 '10 at 1:25
@R..: I disagree with you. The only real difference is in case of overflow, and while that's a difference in the Standard it doesn't usually show up in modern general-purpose computers. Signed arithmetic has a behavior that most programmers find more intuitive. –  David Thornley Sep 20 '10 at 14:02
Actually, gcc makes use of the fact that signed overflow is undefined when optimizing, so it does make a difference in modern general-purpose computers. –  R.. Sep 20 '10 at 14:05

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.