Array Predicates
This clever idea of Bob Bernecky's [1] provides a performance improvement for certain expressions by marking certain arrays with special properties. For example, the property of being a Permutation Vector [2] is invariant (is still a Permutation Vector, albeit a different one) under various APL primitives such as rotate/reversal (L⌽PV and ⌽PV) and grade up/down (⍋PV and ⍒PV).
Bernecky has defined several array predicate properties, one of which has been implemented in NARS so far.
Permutation Vectors
In this case, index generator (⍳S) produces a Permutation Vector, as do the grade primitives (⍋V and ⍒V), as well as deal (L?R) when the left and right arguments are the same — the results of these primitives are marked internally as Permutation Vectors. Subsequent use of such arrays maintains that property when operated on by rotate/reversal (L⌽PV and ⌽PV) and grade up/down. Moreover, the two grade (⍋PV and ⍒PV) and the index of (PV⍳R) and membership (L∊PV) primitives use a much faster (linear) algorithm than they would normally, given that the appropriate argument is a Permutation Vector.
In summary,
Set The bit: ⍳S, ⍋V, ⍒V, and R?R.
Pass on the bit: ⍋V, ⍒V, L⌽PV, and ⌽PV.
Read and take advantage of the bit: ⍋V, ⍒V, PV⍳R, and L∊PV.