Surprisingly, this turns out to be important even when quicksort is not confronted with wildly unbalanced partitions, and even when introsort is actually being used.
The problem arises (in C++) when the values in the container being sorted are really big. By this, I don't mean that they point to really big objects, but that they are themselves really big. In that case, some (possibly many) compilers will make the recursive stack frame quite big, too, because it needs at least one temporary value in order to do a swap. Swap is called inside of partition, which is not itself recursive, so you would think that the quicksort recursive driver would not require the monster stack-frame; unfortunately, partition usually ends up being inlined because it's nice and short, and not called from anywhere else.
Normally the difference between 20 and 40 stack frames is negligible, but if the values weigh in at, say, 8kb, then the difference between 20 and 40 stack frames could mean the difference between working and stack overflow, if stacks have been reduced in size to allow for many threads.
If you use the "always recurse into the smaller partition" algorithm, the stack cannot every exceed log2 N frames, where N is the number of elements in the vector. Furthermore, N cannot exceed the amount of memory available divided by the size of an element. So on a 32-bit machine, the there could only be 219 8kb elements in a vector, and the quicksort call depth could not exceed 19.
In short, writing quicksort correctly makes its stack usage predictable (as long as you can predict the size of a stack frame). Not bothering with the optimization (to save a single comparison!) can easily cause the stack depth to double even in non-pathological cases, and in pathological cases it can get a lot worse.