In general, the thing you're missing is that the C way often isn't faster. It just looks more like a hack, and people often think hacks are faster.
Never use raw pointers, use smart pointers instead - OK, they're really useful, everyone knows that, I know that, I use the all the time and I know how much better they're that raw pointers, but sometimes it's completely safe to use raw pointers.. Why not?
Let's turn the question on its head. Sometimes it's safe to use raw pointers. Is that alone a reason to use them? Is there anything about raw pointers that is actually superior to smart pointers? It depends. Some smart pointer types are slower than raw pointers. Others aren't. What is the performance rationale for using a raw pointer over a
std::unique_ptr or a
boost::scoped_ptr? Neither of them have any overhead, they just provide safer semantics.
This isn't to say that you should never use raw pointers. Just that you shouldn't do it just because you think you need performance, or just because "it seems safe". Do it when you need to represent something that smart pointers can't. As a rule of thumb, use pointers to point to things, and smart pointers to take ownership of things. But it's a rule of thumb, not a universal rule. Use whichever fits the task at hand. But don't blindly assume that raw pointers will be faster. And when you use smart pointers, be sure you are familiar with them all. Too many people just use
shared_ptr for everything, and that is just awful, both in terms of performance and the very vague shared ownership semantics you end up applying to everything.
Don't use bitwise operations - too C-style? WTH? Why not, when you're sure what you're doing? For example - don't do bitwise exchange of variables ( a ^= b; b ^= a; a ^= b; ) - use standard 3-step exchange. Don't use left-shift for multiplying by two. Etc, etc.. (OK, that's not C++ style vs. C-style, but still "not good practice" )
That one is correct. And the reason is "it's faster". Bitwise exchange is problematic in many ways:
- it is slower on a modern CPU
- it is more subtle and easier to get wrong
- it works with a very limited set of types
And when multiplying by two, multiply by two. The compiler knows about this trick, and will apply it if it is faster. And once again, shifting has many of the same problems. It may, in this case, be faster (which is why the compiler will do it for you), but it is still easier to get wrong, and it works with a limited set of types. In paticular, it might compile fine with types that you think it is safe to do this trick with... And then blow up in practice. In particular, bit shifting on negative values is a minefield. Let the compiler navigate it for you.
Incidentally, this has nothing to do with "C style". The exact same advice applies in C. In C, a regular swap is still faster than the bitwise hack, and bitshifting instead of a multiply will still be done by the compiler if it is valid and if it is faster.
But as a programmer, you should use bitwise operations for one thing only: to do bitwise manipulation of integers. You've already got a multiplication operator, so use that when you want to multiply. And you've also got a
std::swap function. Use that if you want to swap two values. One of the most important tricks when optimizing is, perhaps surprisingly, to write readable, meaningful code. That allows your compiler to understand the code and optimize it.
std::swap can be specialized to do the most efficient exchange for the particular type it's used on. And the compiler knows several ways to implement multiplication, and will pick the fastest one depending on circumstance... If you tell it to. If you tell it to bit shift instead, you're just misleading it. Tell it to multiply, and it will give you the fastest multiply it has.
And finally, the most expensive - "Don't use enum-s to return codes, it's too C-style, use exceptions for different errors" ?
Depends on who you ask. Most C++ programmers I know of find room for both. But keep in mind that one unfortunate thing about return codes is that they're easily ignored. If that is unacceptable, then perhaps you should prefer an exception in this case. Another point is that RAII works better together with exceptions, and a C++ programmer should definitely use RAII wherever possible. Unfortunately, because constructors can't return error codes, exceptions are often the only way to indicate errors.
but still.. What about performance?
What about it? Any decent C programmer would be happy to tell you not to optimize prematurely.
Your CPU can execute perhaps 8 billion instructions per second. If you make two calls to a
std::stringstream in that second, is that going to make a measurable dent in the budget?
You can't predict performance. You can't make up a coding guideline that will result in fast code. Even if you never throw a single exception, and never ever use
stringstream, your code still won't automatically be fast. If you try to optimize while you write the code, then you're going to spend 90% of the effort optimizing the 90% of the code that is hardly ever executed. In order to get a measurable improvement, you need to focus on the 10% of the code that make up 95% of the execution time. Trying to make everything fast just results in a lot of wasted time with little to show for it, and a much uglier code base.