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I've seen some code where they don't use primitive types int, float, double etc. directly. They usually typedef it and use it or use things like uint_8 etc. Is it really necessary even these days? Or is C/C++ standardized enough that it is preferable to use int, float etc directly. |
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If you want a 32-bit type, use |
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Most code I read, and write, uses the fixed-size typedefs only when the size is an important assumption in the code. For example if you're parsing a binary protocol that has two 32-bit fields, you should use a typedef guaranteed to be 32-bit, if only as documentation. I'd only use int16 or int64 when the size must be that, say for a binary protocol or to avoid overflow or keep a struct small. Otherwise just use int. If you're just doing "int i" to use i in a for loop, then I would not write "int32" for that. I would never expect any "typical" (meaning "not weird embedded firmware") C/C++ code to see a 16-bit "int," and the vast majority of C/C++ code out there would implode if faced with 16-bit ints. So if you start to care about "int" being 16 bit, either you're writing code that cares about weird embedded firmware stuff, or you're sort of a language pedant. Just assume "int" is the best int for the platform at hand and don't type extra noise in your code. |
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C and C++ purposefully don't define the exact size of an int. This is because of a number of reasons, but that's not important in considering this problem. Since int isn't set to a standard size, those who want a standard size must do a bit of work to guarantee a certain number of bits. The code that defines uint_8 does that work, and without it (or a technique like it) you wouldn't have a means of defining an unsigned 8 bit number. |
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Because the types like The secret code is really quite straight-forward. Here, you have uint_8, which is interpreted
In other words, this is an unsigned integer with 8 bits (minimum) or what we used to call, in the mists of C history, an "unsigned char". |
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C and C++ don't restrict the exact size of the numeric types, the standards only specify a minimum range of values that has to be represented. This means that The reason for this is that often a particular architecture will have a size for which arithmetic works faster than other sizes. Allowing the implementor to use this size for This isn't going to go away any time soon. Even once servers and desktops are all fully transitioned to 64-bit platforms, mobile and embedded platforms may well be operating with a different integer size. Apart from anything else, you don't know what architectures might be released in the future. If you want your code to be portable, you have to use a fixed-size typedef anywhere that the type size is important to you. |
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The sizes of types in C are not particularly well standardized. 64-bit integers are one example: a 64-bit integer could be |
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The width of primitive types often depends on the system, not just the C++ standard or compiler. If you want true consistency across platforms when you're doing scientific computing, for example, you should use the specific |
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