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My friend says he read it on some page on SO that they are different,but how could the two be possibly different?

Case 1

 int i=999;
 char c=i;

Case 2

 char c=999;

In first case,we are initializing the integer i to 999,then initializing c with i,which is in fact 999.In the second case, we initialize c directly with 999.The truncation and loss of information aside, how on earth are these two cases different?

EDIT

Here's the link that I was talking of

why no overflow warning when converting int to char

One member commenting there says --It's not the same thing. The first is an assignment, the second is an initialization

So isn't it a lot more than only a question of optimization by the compiler?

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if you are using clang, you can use the emit llvm option with -s... the llvm is more readable that platform dependent asm... if I had my computer out I would do a couple of tests, but in any case the more interesting thing than the code will be how the platform you are on handles the overflow of your 8 bit value... –  Grady Player May 11 '13 at 17:57
    
Check the edit please that I have added. –  Rüppell's Vulture May 11 '13 at 18:00
    
If you have a question about the answer there, you should ask it there, not open another question. –  Jim Balter May 11 '13 at 18:02
    
@JimBalter I'll keep that in mind Mr.Balter.But I really felt that the nature of both questions are different.I want to know something other than what the OP there asked. –  Rüppell's Vulture May 11 '13 at 18:04
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@KeithThompson them I'm voting to close as duplicate on the grounds that it's answered under "why does one produce a warning but not the other"? –  djechlin May 11 '13 at 18:33
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5 Answers

up vote 7 down vote accepted

They have the same semantics.

The constant 999 is of type int.

int i=999;
char c=i;

i created as an object of type int and initialized with the int value 999, with the obvious semantics.

c is created as an object of type char, and initialized with the value of i, which happens to be 999. That value is implicitly converted from int to char.

The signedness of plain char is implementation-defined.

If plain char is an unsigned type, the result of the conversion is well defined. The value is reduced modulo CHAR_MAX+1. For a typical implementation with 8-bit bytes (CHAR_BIT==8), CHAR_MAX+1 will be 256, and the value stored will be 999 % 256, or 231.

If plain char is a signed type, and 999 exceeds CHAR_MAX, the conversion yields an implementation-defined result (or, starting with C99, raises an implementation-defined signal, but I know of no implementations that do that). Typically, for a 2's-complement system with CHAR_BIT==8, the result will be -25.

char c=999;

c is created as an object of type char. Its initial value is the int value 999 converted to char -- by exactly the same rules I described above.

If CHAR_MAX >= 999 (which can happen only if CHAR_BIT, the number of bits in a byte, is at least 10), then the conversion is trivial. There are C implementations for DSPs (digital signal processors) with CHAR_BIT set to, for example, 32. It's not something you're likely to run across on most systems.

You may be more likely to get a warning in the second case, since it's converting a constant expression; in the first case, the compiler might not keep track of the expected value of i. But a sufficiently clever compiler could warn about both, and a sufficiently naive (but still fully conforming) compiler could warn about neither.

As I said above, the result of converting a value to a signed type, when the source value doesn't fit in the target type, is implementation-defined. I suppose it's conceivable that an implementation could define different rules for constant and non-constant expressions. That would be a perverse choice, though; I'm not sure even the DS9K does that.

As for the referenced comment "The first is an assignment, the second is an initialization", that's incorrect. Both are initializations; there is no assignment in either code snippet. There is a difference in that one is an initialization with a constant value, and the other is not. Which implies, incidentally, that the second snippet could appear at file scope, outside any function, while the first could not.

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Any optimizing compiler will just make the int i = 999 local variable disappear and assign the truncated value directly to c in both cases. (Assuming that you are not using i anywhere else)

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Can you elaborate a little more please. –  Rüppell's Vulture May 11 '13 at 17:52
    
Just to elaborate a little on what @Jack said, he means that the compiler will most likely just destroy your i value. Meaning the variable will never exist after compilation and thus c=999 will be the only thing that exists meaning case 2. However, if you are using the i variable else where in your code down the line then the compiler will keep i and c like your case 1 and continue down the path. –  Nomad101 May 11 '13 at 17:54
    
Check the edit please that I have added. –  Rüppell's Vulture May 11 '13 at 18:00
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It depends on your compiler and optimization settings. Take a look at the actual assembly listing to see how different they are. For GCC and reasonable optimizations, the two blocks of code are probably equivalent.

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Some more elaboration please.OP is not very smart. –  Rüppell's Vulture May 11 '13 at 17:52
    
@Rüppell'sVulture Run it using gcc -S and compare listings. –  DarkCthulhu May 11 '13 at 17:57
    
Look at the edit please. –  Rüppell's Vulture May 11 '13 at 17:58
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Bad answer. The question isn't about the generated code, it's about the semantics, which are defined by the language standard. –  Jim Balter May 11 '13 at 17:59
    
In the original question all he really asked is "how on earth are these two cases different?" so you shouldn't be so sure about that, Jim Balter. –  David Grayson May 11 '13 at 18:13
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Aside from the fact that the first also defines an object iof type int, the semantics are identical.

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So what the user pmg from that link said is wrong?Since he seems a reputed user I had to confirm stackoverflow.com/questions/10503434/… –  Rüppell's Vulture May 11 '13 at 18:05
    
Yes, pmg was mistaken. –  Keith Thompson May 11 '13 at 18:21
    
@JimBalter: Given char c = 999;, a compiler is not required to determine that there's an overflow or to warn about it. It could generate code that evaluates the expression 999 in type int and converts it to char at execution time. That's exactly what happens in the semantics of the abstract machine. Doing the conversion at compile time is an optional optimization. –  Keith Thompson May 11 '13 at 18:22
    
"So what the user pmg from that link said is wrong?" -- Well, obviously his comment was wrong, since they are obviously both initializations. That's a different matter from whether they are different though; obviously, they are different enough that the compiler used issued a warning for one but not the other. –  Jim Balter May 11 '13 at 18:31
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i,which is in fact 999

No, i is a variable. Semantically, it doesn't have a value at the point of the initialization of c ... the value won't be known until runtime (even though we can clearly see what it will be, and so can an optimizing compiler). But in case 2 you're assigning 999 to a char, which doesn't fit, so the compiler issues a warning.

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YESSSS!!That's the word,Overflow.Can you kindly elaborate Mr.Balter..a little more details for easy understanding. –  Rüppell's Vulture May 11 '13 at 18:07
    
I'm just saying that 999 can't fit into an 8 bit char so the compiler warns about it. An int (i) may or may not fit, depending on its value at runtime, so the compiler doesn't warn about it (despite the fact that we can all see that the value will always be 999). –  Jim Balter May 11 '13 at 18:16
    
Thanks,that made it a lot clearer. –  Rüppell's Vulture May 11 '13 at 18:17
    
Strictly speaking, there is no "compile-time overflow" in either case. Logically, the initialization happens at run time. The compiler may be able to do more compile-time analysis in one case than in the other, but it's not required to do so. A sufficiently simple-minded compiler needn't warn about char c = 999;. –  Keith Thompson May 11 '13 at 18:19
    
It's entirely possible that a compiler will issue a warning for one but not the other, but a sufficiently clever compiler can warn about both, and a sufficiently naive (but still conforming) compiler can warn about neither. –  Keith Thompson May 11 '13 at 18:24
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