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Yes I know you shouldn't use C style casts in C++, but in some cases I really think it's a lot more readable if you do, compare these two for example:

d = ((double)i * 23.54) / (d + (double)j);

d = (static_cast<double>(i) * 23.54) / (d + static_cast<double>(j));

Which one is more readable?

Now on to my main question. Obviously I prefer the upper one, but there is one way to make it even more readable in my opinion:

d = (double(i) * 23.54) / (d + double(j));

My question here is, will this be less efficient? Will the compiler create more doubles in this case than if they were casted with the other methods, or is it clever enough not to? Is this more or less bad than typical C-style casts?

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While in C++ use C++ casts and refrain from using C style casts on C++ objects. Not a duplicate but bit related… – DumbCoder Dec 9 '10 at 15:12
+1 nice question, I think I have never used double(i), and I admit it's quite readable. – Stephane Rolland Dec 9 '10 at 15:13
static_cast<...> is a lot easier to search for. – DanDan Dec 9 '10 at 15:15
You do not need any casts above if i and j are int and d is double. – wilx Dec 9 '10 at 15:33
Ah right, I understand. But let's say it's needed just for the sake of argument or readability. Bad example on my part. – DaedalusAlpha Dec 9 '10 at 15:36
up vote 4 down vote accepted

The compiler will "create" exactly the same number of doubles. There is no practical difference between casting to and constructing primitive numeric types.

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While I highly appreciate the other answers and the info I've gotten in this thread, this is the only answer that actually answered my specific question, so I'll mark it as the answer ;) – DaedalusAlpha Dec 9 '10 at 16:01

They're all unreadable. You should write:

d = (i * 23.54) / (d + j);
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@DaedalusAlpha: actually, it doesn't matter. C++ will do the conversion for you and use the most appropriate type. One big advantage of this solution is that if you suddenly updated d to be of type float or long double, then the compiler will still perform the most appropriate conversion while your explicit conversions will need to be changed manually... and some will likely be forgotten. – Matthieu M. Dec 9 '10 at 15:39
@DaedalusAlpha: I've added an answer for the cases where picking the conversion is desirable (to gain precision for example), in short I highly recommend boost::numeric_cast, because it checks for overflow / underflow and thus prevents the nasty undefined behavior. – Matthieu M. Dec 9 '10 at 15:49
@DaedalusAlpha: and it's using casts "just to be safe" that tends to get people into trouble with C-casts: since they're powerful enough to perform conversions that aren't safe, you may inadvertently create an expression that will silently go from "over-verbose but correct" to "terribly, tragically wrong" when a type is changed elsewhere... – Shog9 Dec 9 '10 at 15:58
@j_random_hacker: Your example is bad and outright buggy. If RAND_MAX is INT_MAX, then RAND_MAX+1 already overflowed before you cast to double. Replacing 1 with 1.0 would fix the bug and remove the useless cast. – R.. Dec 9 '10 at 16:16
@DaedalusAlpha: Floating point types always trump integer types. (That's actually implied by my comment if you read it carefully.) All binary arithmetic and relational (<, == etc.) operators operate the same way, converting "up" small-typed arguments. The result type of arithmetic operators is the common type of the operands after any conversions done on them. Operands of % and the bitwise operators have to be integral. – j_random_hacker Dec 9 '10 at 17:30

I have already commented on R's answer about letting the compiler pick out the cast, in this particular case.

There are however cases in which you DO want an explicit conversion:

  • you want to prevent overflow or increase precision
  • you want to check the validity of the conversion

The Boost Numeric Conversion provides a highly suitable cast here, much better than static_cast: boost::numeric_cast

  • no overhead when no check is required (ie casting from a small to a large integer)
  • runtime check of the value when required (ie casting from large to small or signed to unsigned)

It's more readable than static_cast, since the very nature of the numbers is highlighted, and much safer since it prevents undefined behavior (and portability issues) to kick in.

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@j_random_hacker: thanks for the example :) – Matthieu M. Dec 9 '10 at 16:15
Your version, even if you fix the bug, still has bias. Potentially very bad bias, depending on the value of n. – R.. Dec 9 '10 at 16:18
@Matthieu: Read my comment to the other place he posted that example. It's wrong. – R.. Dec 9 '10 at 16:18
@Matthieu: Tragically that snippet contained the exact overflow bug I was trying to avoid... Here it is again, corrected: – j_random_hacker Dec 9 '10 at 16:24
Example: to get an int in the range 0 - (n-1), use (int) ((rand() / ((double) RAND_MAX + 1) * n). The (double) is critical to avoiding integer overflow on many systems where RAND_MAX is the largest representable integer. (Why not just rand() % n? It's biased.) – j_random_hacker Dec 9 '10 at 16:25

The reason why cast functions in C++ are long an unwieldy is by design 1) in order to show the user that he's probably doing something wrong 2) in cases when they are necessary, attract attention to that piece of code, that it might be doing something dangerous or unconventional.

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IMHO, the static_cast one is more readable, because it provides to the reader information about the nature of the cast.

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I suggest you compile to assembly (if your compiler supports such an option). For example, Gnu C++ option -S will output the assembly so you can see for yourself.

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