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I don't know how to type this in to google, so I'm asking this here.

In programming, do operators take different amounts of time or CPU usage? For example would:

x = y + z

take less amount of time/CPU than:

x = y * z


I know it is not noticeable, if at all. Just a curious question.

Also, if you could include as many operators as possible such as +=, -=, *=, and /= along with all normal operators.

Thank you!

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The performance of operators can vary a lot depending on datatypes etc. Perhaps you could go googling about binary arithmetic, floating point calculations etc. – appclay Mar 15 '12 at 3:44

3 Answers 3

up vote 3 down vote accepted

There is no master list for all languages, data types, CPUs, and so on, because there is just too much variability.

In some languages, operators are just syntactic sugar for full dynamically-determined type-dispatched function calls, so "a + b" could wind up being a complicated function call that takes minutes, while "a * b" might be a simple function call that takes milliseconds—or vice versa.

In languages that have fixed, compile-time types (including C++ as well as C even though C++ has overloading), you can determine at compile-time what's going to get invoked, which helps pin things down a lot, but still does not give you a final answer. (See also Dan D and Alex's answers.)

"Augmenting operators" (+= and so on) are usually just shorthand for assignment-after-expanded-operation. The actual operation takes the same amount of time. In languages with dynamic type dispatch, sometimes you cut off some auxiliary (non-operator) work as well since the augmenting operation need only look up the type of the variable once. With static (compile-time) typing, as long as the compiler is reasonably smart, simple a += b type operations never save anything over a = a + b at runtime, they are just easier to read. More complicated cases, like p->q->r->s += t, can actually save time since (in tricky cases) the p->q->r->s evaluation has to be done repeatedly if it's written out repeatedly.

As for the underlying CPU operations, there are some rules of thumb, but you have to haul out the appropriate CPU manuals to see which ones apply:

  • For integers, addition, subtraction, and logical operations like and/or/xor are never any slower than any other operation
  • For integers, multiplication is "harder" than addition, i.e., may be slower than addition etc, but may still be very fast as long as there is sufficient CPU-power dedicated to it; and division may be slower than multiplication, or may still be fast
  • For floating point operations, addition and subtraction are "harder" than multiplication and division, so they may be slower (or not, again it depends on how much transistor real estate there is dedicated to the FPU)
  • If there is no FPU, floating point is likely slower than integer
  • If there is a barrel or funnel shifter, shifts are always fast, but if not, shifts may take longer depending on "how far" the shift goes (e.g., x >> 4 may be slower than x >> 1)
  • In modern CPUs, the instruction scheduling @Alex mentioned above may or may not depend on the order of instructions, e.g., it may help to intersperse FPU instructions among integer-unit instructions (or it may not)
  • Cache effects (including placement of branches near particular points in cache lines as well as multi-level cache misses, and also TLB misses) can completely swamp the effects of careful instruction scheduling on some CPUs

These kinds of things make writing modern compiler-optimizers pretty tricky. :-)

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Yes, at the lowest levels sometimes a * b costs more than a + b and sometimes it's the other way. It really depends on the hardware used and the language used.

See for yourself, run a few tests timing the operations repeated a few thousand times.

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Thanks, but is there somewhere that i can look to find a list of operators and time usage? If not, then i would do what you said and run multiple tests XD. – Steven Rogers Mar 15 '12 at 4:14

You need to check the CPU manual and see what logic and arithmetic instructions there are and how many cycles they take to execute.

If there's no instruction for integer division or multiplication, your programming language will have to construct these operations using more primitive ones (e.g. shifts and addition/subtraction). The same applies for simple operations on long integers such as addition, subtraction, comparison, shifts, and, or, xor, bitwise inversion. If there're no instructions that do these with long integers, they have to be constructed using shorter ones, which means that operator performance will depend on the sizes of involved types.

Some CPUs do not have instructions for floating-point arithmetic, which means that all floating point operations need to be constructed using instructions operating on integers and as such they will be comparatively slower than similar operations on integers.

Another thing to consider would be whether or not the instructions in question can be paired with others in the CPU (if pairing (parallel execution) is possible at all). If they can't pair, they will slow down pairable instructions nearby. Some CPUs have multiple ALUs for simple instructions that can be executed concurrently. Besides simple pairing, some complex instructions may use more stages of the CPU's pipeline or use them differently from simple instructions, which can delay execution of those other simple instructions.

The ultimate answer depends on your CPU and programming language/compiler/interpreter.

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