# Order of Conditions in `if ... else if ... else ...` in C++

I'm trying to figure out how to write the most optimal `if ... else if ... else ...` statement in `C++`.

Suppose that we have 3 possible conditions based on some `n` variable value: `n = 0`, `0 < n < 100`, and `n = 100`. Let's assume that `n = 0` will occur in `1%` cases, `0 < n < 100``90%`, and `n = 100``9%`. Note that `if ... else if ... else ...` will be executed many times and the value of `n` will be different each time.

My first assumption was to put conditions in the descending order (the most frequent – first, the least frequent – last) like below. However, the first condition will have 3 boolean expressions. And since the first condition will be always executed (in `100%` cases) and it consists of 3 boolean expressions (`>`, `<`, and `&&`), those 3 expressions will be executed in `100%` cases. (Maybe there will be some optimization made by a compiler, and it will somehow be reduced to 2 expressions.) The second condition will be executed in `10%` cases and the third condition – in `1%` cases.

So, given that there will be a `1 000` iterations, there will be `3 100` boolean expressions evaluated (`3 000 + 100`).

``````if ((n > 0) && (n < 100)) {  // 3 boolean expressions will be executed in 100% cases.
...
} else if (n == 100) {  // 1 additional boolean expression – in 10% cases.
...
} else {  // n = 0  // No additional boolean expressions – in 1% cases.
...
}
``````

If to change the order of conditions (so that to eliminate the condition with 3 boolean expressions), there will be `1 910` boolean expressions evaluated (`1 000 + 910`).

``````if (n == 100) {  // 1 boolean expression will be executed in 100% cases.
...
} else if (n == 0) {  // 1 additional boolean expression – in 91% cases.
...
} else {  // 0 < n < 100  // No additional boolean expressions – in 90% cases.
...
}
``````

Do I understand it right? If no, how to properly optimize the code with `if ... else if ... else ...` for speed?

Update: Based on the comments, did a test. The first variant gives less lines of the compiled code than the second one. Don't know Assembly language, so I'm not sure whether less lines is better in this case.

• Please share the performance benchmarks showing the difference between the various orderings. Commented Jun 15 at 6:55
• First of all, when doing benchmarks remember to always build with optimizations enabled. Secondly, compare the generated code with each other, which is easy to do on e.g. the compiler explorer. Commented Jun 15 at 6:58
• Usually last `else` clause executes faster because don't need extra jump instruction. So `if (n == 100) ... else if (n == 0) ... else ... ;` But of course, need to be benchmarked. Commented Jun 15 at 7:14
• Because of short-circuiting operations (part of the standard, i.e. compiler agnostic), the numbers you give are wrong. Moreover, the number of cycles lost in that is going to be very small compared to whatever is going on inside the `{ ... }`, good luck benchmarking that. For the same reason, it does not look, to me, that whatever you hope to learn with this can be applied as a general rule. A more realistic `if (someFunctionWithSideEffect(n) == 0) ...` will be dominated by what happens in the function, not by how you order the `if`s.
– Atmo
Commented Jun 15 at 7:24
• Write the code in the most logical, understandable way. If there's a performance issue once you've written your code and profiling shows that the order of the statements matters, then you can try optimising it Commented Jun 15 at 7:55

One of your counts is off. You say:

``````if ((n > 0) && (n < 100)) {  // 3 boolean expressions will be executed in 100% cases.
``````

But (1) `&&` is not a Boolean expression, but an implicit `if` because it short-circuits the expression, and (2) due to the short-circuiting the second half `n < 100` will be executed only 99% of the cases. Only `n > 0` will be examined in 100% of the cases.

Apart from that, you are focusing too much on how frequently conditions are evaluated. This is a secondary concern, because first and foremost do note that it is unavoidable to check two conditionals before the most frequent branch can be entered.

With this in mind, you can now begin to ask if it is possible to avoid checking one of the two conditions with higher probability. The conditions are `n > 0` (false in 1% of cases) and `n < 100` (false in 10% of cases). Now, if you check `n > 0` first, then you can avoid checking the other in 1% of the cases, but when you check `n < 100` first, then you can avoid the other check in 10% of the cases. So, that is what you should do:

``````if (n == 100) {  // get 10% of the cases out of the way
...
} else if (n == 0) {  // unavoidable second check after first check failed
...
} else {  // most frequent case needs both checks
...
}
``````

(This assumes that [0 ... 100] are the only values that `n` can take.)

• Thank you for additional explanations! Your answer does make sense. Commented Jun 15 at 7:42
• However, most CPUs have an essentially free test for zero or not zero which may tip the balance in favour of having that test first. Only profiling the actual code can tell you which version is fastest (and it is only worth doing this as a last resort). Be aware that modern compilers are smart and if they can implement the if statement as conditional moves (with no branch penalty) then they will do so. Coding to make that easier for the compiler to see is sometimes necessary in code that has to be fast. Commented Jun 15 at 20:24