Tacit programming: Difference between revisions

Tacit programming, also called point-free style, refers to usage of tacit functions that are defined in terms of implicit arguments. This is in contrast to the explicit use of arguments in dfns (<syntaxhighlight inline lang=apl>⍺ ⍵</source>) and tradfns (which have named arguments). Some APL dialects allow to combine functions into trains following a small set of rules. This allows creating complex derived functions without specifying any arguments explicitly.

Dialects which implement trains include Dyalog APL, dzaima/APL, ngn/apl and NARS2000.

Primitives

All primitive functions are tacit. Some APLs allow primitive functions to be named. <syntaxhighlight lang=apl>

     plus ← +
     times ← ×
     6 times 3 plus 5

48 </source>

Derived functions

Functions derived from a monadic operator and an operand, or from a dyadic operator and two operands are tacit functions: <syntaxhighlight lang=apl>

     Sum ← +/
     Sum ⍳10

55

     Dot ← +.×
     3 1 4 dot 2 7 1

17 </source>

Derived operators

A dyadic operator with its right operand forms a tacit monadic operator: <syntaxhighlight lang=apl>

     1(+⍣2)10

12

     Twice ← ⍣2
     1 +Twice 10

12 </source>

Trains

A train is a series of functions in isolation. An isolated function is either surrounded by parentheses or named.

These rules are used for 3-trains:

<syntaxhighlight lang=apl> (f g h) ⍵</source>	${\displaystyle \Leftrightarrow }$	<syntaxhighlight lang=apl>( f ⍵) g ( h ⍵)</source>
<syntaxhighlight lang=apl>⍺ (f g h) ⍵</source>	${\displaystyle \Leftrightarrow }$	<syntaxhighlight lang=apl>(⍺ f ⍵) g (⍺ h ⍵)</source>

The left tine of a fork can be an array:

<syntaxhighlight lang=apl> (A g h) ⍵</source>	${\displaystyle \Leftrightarrow }$	<syntaxhighlight lang=apl>A g ( h ⍵)</source>
<syntaxhighlight lang=apl>⍺ (A g h) ⍵</source>	${\displaystyle \Leftrightarrow }$	<syntaxhighlight lang=apl>A g (⍺ h ⍵)</source>

In APL (but not J), these rules are used for 2-trains:

<syntaxhighlight lang=apl> (g h) ⍵</source>	${\displaystyle \Leftrightarrow }$	<syntaxhighlight lang=apl>g ( h ⍵)</source>
<syntaxhighlight lang=apl>⍺ (g h) ⍵</source>	${\displaystyle \Leftrightarrow }$	<syntaxhighlight lang=apl>g (⍺ h ⍵)</source>

Any train can be expressed in terms of function composition — except dyadic forks. Some common patterns are:

<syntaxhighlight lang=apl>(f g h) ⍵</source>	${\displaystyle \Leftrightarrow }$	<syntaxhighlight lang=apl>g⍨∘f⍨∘h⍨ ⍵</source>
<syntaxhighlight lang=apl>(f g f) ⍵</source>	${\displaystyle \Leftrightarrow }$	<syntaxhighlight lang=apl>g⍥f⍨ ⍵</source>
<syntaxhighlight lang=apl>(⊢ g f) ⍵</source>	${\displaystyle \Leftrightarrow }$	<syntaxhighlight lang=apl>g∘f⍨ ⍵</source>

Debugging

In Dyalog APL, analysis of trains is assisted by a user command <syntaxhighlight lang=apl inline>]Boxing on</source>. This is achieved by executing the command <syntaxhighlight lang=apl inline>]Boxing on</source> and then entering a train without any parameters. A structure of the train will be displayed.

For example, the "accursed train" from the section below can be analysed like this: <syntaxhighlight lang=apl>

     ]Boxing on

Was OFF

     ((+.×⍨⊢~∘.×⍨)1↓⍳)     ⍝ the train to be analysed

┌───────────────────────────────┬───────┐ │┌───────────┬─────────────────┐│┌─┬─┬─┐│ ││┌───────┬─┐│┌─┬─┬───────────┐│││1│↓│⍳││ │││┌─┬─┬─┐│⍨│││⊢│~│┌───────┬─┐│││└─┴─┴─┘│ ││││+│.│×││ │││ │ ││┌─┬─┬─┐│⍨││││ │ │││└─┴─┴─┘│ │││ │ │││∘│.│×││ ││││ │ ││└───────┴─┘││ │ ││└─┴─┴─┘│ ││││ │ ││ ││ │ │└───────┴─┘│││ │ ││ │└─┴─┴───────────┘││ │ │└───────────┴─────────────────┘│ │ └───────────────────────────────┴───────┘ </source>

Alternatively, a train can be represented in form of a tree: <syntaxhighlight lang=apl>

     ]Boxing on -trains=tree

Was ON -trains=box

     ((+.×⍨⊢~∘.×⍨)1↓⍳)     ⍝ the train to be analysed
    ┌───┴───┐  
  ┌─┴─┐   ┌─┼─┐
  ⍨ ┌─┼─┐ 1 ↓ ⍳
┌─┘ ⊢ ~ ⍨      
.     ┌─┘      

┌┴┐ . + × ┌┴┐

     ∘ ×       

</source> Or fully parenthesised: <syntaxhighlight lang=apl>

     ]Boxing on -trains=parens

Was OFF -trains=box

     ((+.×⍨⊢~∘.×⍨)1↓⍳)     ⍝ the train to be analysed

(((+.×)⍨)(⊢~((∘.×)⍨)))(1↓⍳) </source>

Conversion to dfns

It can help understanding to convert a tacit function to a dfn. For many tacit functions, it is not immediately clear if the intention of the function is to be used monadically or dyadically, or even both. Such knowledge can be conveyed by comments, but sometimes it is possible to spot patterns that are exclusively monadic or dyadic: A function with a bound argument (for example <syntaxhighlight lang=apl inline>+∘1</source>) can indicate a monadic function, and in some contexts, <syntaxhighlight lang=apl inline>=</source>, which can only be used dyadically, would indicate a dyadic function. The website tacit.help provides automated translation of most tacit functions, into both monadic and dyadic, fully parenthesised dfns.

Examples

One of the major benefits of tacit programming is the ability to convey a short, well-defined idea as an isolated expression. This aids both human readability (semantic density) and the computer's ability to interpret code, potentially executing special code for particular idioms.

Plus and minus

<syntaxhighlight lang=apl>

     (+,-) 2     ⍝ ±2

2 ¯2

     5 (+,-) 2   ⍝ 5±2

7 3 </source>

Arithmetic mean

<syntaxhighlight lang=apl>

     (+⌿÷≢) ⍳10       ⍝ Mean of the first ten integers

5.5

     (+⌿÷≢) 5 4⍴⍳4    ⍝ Mean of columns in a matrix

1 2 3 4 </source>

Fractions

We can convert decimal numbers to fractions. For example, we can convert ${\displaystyle 2.625}$ to the improper fraction ${\displaystyle {\tfrac {21}{8}}}$ with <syntaxhighlight lang=apl>

     (1∧⊢,÷)2.625

21 8 </source> Alternatively, we can convert it to the mixed fraction ${\displaystyle 2{\tfrac {5}{8}}}$ with a mixed fraction: <syntaxhighlight lang=apl>

     (1∧0 1∘⊤,÷)2.625

2 5 8 </source>

Is it a palindrome?

<syntaxhighlight lang=apl>

     (⌽≡⊢)'racecar'

1

     (⌽≡⊢)'racecat'

0 </source>

Split delimited text

<syntaxhighlight lang=apl>

     ','(≠⊆⊢)'comma,delimited,text'

┌─────┬─────────┬────┐ │comma│delimited│text│ └─────┴─────────┴────┘

     ' '(≠⊆⊢)'space delimited text'

┌─────┬─────────┬────┐ │space│delimited│text│ └─────┴─────────┴────┘ </source>

Component of a vector in the direction of another vector

Sometimes a train can make an expression nicely resemble its equivalent definition in traditional mathematical notation. As an example, here is a program to compute the component of a vector ${\displaystyle {\textbf {a}}}$ in the direction of another vector ${\displaystyle {\textbf {b}}}$:

${\displaystyle {\textbf {a}}_{\textbf {b}}=({\textbf {a}}\cdot {\hat {\textbf {b}}}){\hat {\textbf {b}}}}$

<syntaxhighlight lang=apl>

     Root ← *∘÷⍨              ⍝ Nth root
     Norm ← 2 Root +.×⍨       ⍝ Magnitude (norm) of numeric vector in Euclidean space
     Unit ← ⊢÷Norm            ⍝ Unit vector in direction of vector ⍵
     InDirOf ← (⊢×+.×)∘Unit   ⍝ Component of vector ⍺ in direction of vector ⍵
     3 5 2 InDirOf 0 0 1      ⍝ Trivial example

0 0 2 </source> For a more parallel comparison of the notations, see the comparison with traditional mathematics.

The Number of the Beast

The following expression for computing the number of the Beast (and of I.P. Sharp's APL-based email system, 666 BOX) nicely illustrates how to read a train. <syntaxhighlight lang=apl>

     ((+.×⍨⊢~∘.×⍨)1↓⍳)17 ⍝ Accursed train

666 </source> First, <syntaxhighlight lang=apl inline>((+.×⍨⊢~∘.×)1↓⍳)</source> is supplied with only one argument <syntaxhighlight lang=apl inline>17</source> and is thus interpreted monadically.

Second, <syntaxhighlight lang=apl inline>(+.×⍨⊢~∘.×⍨)1↓⍳</source> is a 4-train: reading right-to-left, the last 3 components are interpreted as the fork <syntaxhighlight lang=apl inline>1↓⍳</source> and the 4-train is interpreted as the atop <syntaxhighlight lang=apl inline>(+.×⍨⊢~∘.×⍨)(1↓⍳)</source>. Similarly, <syntaxhighlight lang=apl inline>(+.×⍨⊢~∘.×⍨)</source> is also a 4-train and interpreted as the atop <syntaxhighlight lang=apl inline>+.×⍨(⊢~∘.×⍨)</source>.

Thus the accursed train is interpreted as <syntaxhighlight lang=apl inline>((+.×⍨(⊢~∘.×⍨))(1↓⍳))17</source>. Having read the train, we now evaluate it monadically. <syntaxhighlight lang=apl>

     ((+.×⍨(⊢~∘.×⍨))(1↓⍳))17 ⍝ Accursed train as an atop over a fork atop a fork
     +.×⍨(⊢~∘.×⍨)1↓⍳17       ⍝ Atop evalution
     +.×⍨(⊢1↓⍳17)~∘.×⍨1↓⍳17  ⍝ Fork evalution
     +.×⍨(1↓⍳17)~∘.×⍨1↓⍳17   ⍝ ⊢ evaluation
     +.×⍨2 3 5 7 11 13 17    ⍝ numbers 2 through 17 without those appearing in their multiplication table are primes

666 ⍝ the sum of the squares of the primes up to 17 </source> Note that <syntaxhighlight lang=apl inline>((⊢⍨∘.×⍨)1↓⍳)</source> is a train computing primes up to the given input.

A more satisfying variation of the accursed train is the following. <syntaxhighlight lang=apl>

     (⍎⊢,⍕∘≢)'((+.×⍨⊢~∘.×⍨)1↓⍳)'                    ⍝ Accursed train 2.0
     ⍎(⊢,⍕∘≢)'((+.×⍨⊢~∘.×⍨)1↓⍳)'                    ⍝ 4-train intepreted as an atop
     ⍎(⊢'((+.×⍨⊢~∘.×⍨)1↓⍳)'),⍕∘≢'((+.×⍨⊢~∘.×⍨)1↓⍳)' ⍝ fork evaluation
     ⍎'((+.×⍨⊢~∘.×⍨)1↓⍳)','17'                      ⍝ ⊢ evaluation and ⍕∘≢ evaluation
     ⍎'((+.×⍨⊢~∘.×⍨)1↓⍳)17'                         ⍝ , evaluation

666 ⍝ ⍎ executes original Accursed train </source>

External links

Tutorials

References