In computer science, loop inversion is a compiler optimization and loop transformation in which a while loop is replaced by an if block containing a do..while loop. When used correctly, it may improve performance due to instruction pipelining.
Example in C
int i, a[100];
i = 0;
while (i < 100) {
a[i] = 0;
i++;
}
is equivalent to:
int i, a[100];
i = 0;
if (i < 100) {
do {
a[i] = 0;
i++;
} while (i < 100);
}
Despite the seemingly greater complexity of the second example, it may actually run faster on modern CPUs because they use an instruction pipeline. By nature, any jump in the code causes a pipeline stall, which is a detriment to performance.
Additionally, loop inversion allows safe loop-invariant code motion.
Example in three-address code
i := 0 L1: if i >= 100 goto L2 a[i] := 0 i := i + 1 goto L1 L2:
If i had been initialized at 100, the instructions executed at runtime would have been:
if i >= 100
goto L2
Let us assume that i had been initialized to some value less than 100. Now let us look at the instructions executed at the moment after i has been incremented to 99 in the loop:
goto L1
if i < 100
a[i] := 0
i := i + 1
goto L1
if i >= 100
goto L2
<<at L2>>
Now, let's look at the optimized version:
i := 0 if i >= 100 goto L2 L1: a[i] := 0 i := i + 1 if i < 100 goto L1 L2:
Again, let's look at the instructions executed if i is initialized to 100:
if i >= 100
goto L2
We didn't waste any cycles compared to the original version. Now consider the case where i has been incremented to 99:
if i < 100
goto L1
a[i] := 0
i := i + 1
if i < 100
<<at L2>>
As you can see, two gotos (and thus, two pipeline stalls) have been eliminated in the execution.