Ambivalent function
In APL syntax, a function is ambivalent, or variadic, if it can be called with either monadic or dyadic valence. While every non-niladic function can be written with one or two arguments, some functions give a SYNTAX ERROR when called with two arguments (these functions are called monadic) or with only one (these are called dyadic). Ambivalent functions do not give a SYNTAX ERROR immediately in either case.
Being ambivalent, or not, is an inherent property of a function. This contrasts with the terms "monadic" and "dyadic" which may refer either to the function's inherent properties as described above or to the context in which it is used. When an ambivalent function is invoked it has either one argument or two: we would say for example it is an ambivalent function called monadically.
Tradfns
In some APLs, for example APL*PLUS, tradfns that declare a left argument in the function header are always ambivalent, and the code needs to check whether a left argument was supplied by the left argument name's name class; 0 ≠ ⎕NC 'leftArg'
. Other APLs, for example Dyalog APL, will not allow calling such a function monadically, unless the header has curly braces around the left argument name to indicate that it is optional; result ← {leftArg} FnName rightArg
. Then too, they need to query the name class, or, unique for Dyalog APL, use a specialised Called Monadically I-beam, 900⌶⍬
.[1]
Dfns
Dfns are always ambivalent, even if they reference ⍺
. (This is in contrast with dops which have a fixed operator valence determined by the presence of an unquoted ⍵⍵
in their code.) Like tradfns, the dfn can check the name class (0 ≠ ⎕NC '⍺'
).
However, most APLs that support dfns also allow a statement of the structure ⍺ ← defaultValue
which skipped if the function was called dyadically.[2] This syntax also allows assigning a function, or even an operator, to ⍺
, thus streamlining many ambivalent definitions. For example, we can create a Nth root function which defaults to being the square root when used monadically:
Root←{ ⍺←2 ⍵ * ÷⍺ }
We can also define the Over operator with ⍺
defaulting to be an operator that skips its operand:
Over←{ ⍺←{⍵ ⋄ ⍺⍺} (⍵⍵ ⍺) ⍺⍺ (⍵⍵ ⍵) }
References
- ↑ Dyalog APL Language Reference Guide > The I-Beam Operator > Called Monadically
- ↑ Dyalog APL Programming Reference Guide > Defined Functions & Operators > Direct Functions & Operators > Default Left Argument