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'''Frame agreement''' is a [[conformability]] rule designed for [[leading axis theory]] and used by [[J]]. It states that a [[dyadic]] [[function]] can be applied between two [[array]]s only if one of their [[frame]]s, with frame length based on the function's dyadic [[function rank]], is a [[prefix]] of the other. The leading shape of the result is that of the [[argument]] with longer frame.
'''Frame agreement''' is a [[conformability]] rule which describes the conditions that must be satisfied by the [[frame]]s of [[arguments]] to [[dyadic]] [[function]]s with rank (either [[Rank operator|derived]] and/or, when supported, [[function rank|native]]). The [[frame]]s must either be identical, or one must be [[empty]], or, more generally, when supported, one frame must be a [[prefix]] of the other.


== Description ==
== Empty frame agreement ==
A dyadic function <syntaxhighlight lang=apl inline>f</syntaxhighlight> with left and right ranks <syntaxhighlight lang=apl inline>l</syntaxhighlight> and <syntaxhighlight lang=apl inline>r</syntaxhighlight>, respectively, splits its left argument <syntaxhighlight lang=apl inline>x</syntaxhighlight> into <syntaxhighlight lang=apl inline>l</syntaxhighlight>-cells, and splits its right argument <syntaxhighlight lang=apl inline>y</syntaxhighlight> into <syntaxhighlight lang=apl inline>r</syntaxhighlight>-cells. Each argument's shape is thus split into a frame and a cell shape. Given that one frame must be a prefix of the other, the shorter frame is called the common frame (denoted here as <syntaxhighlight lang=apl inline>cf</syntaxhighlight>), which may be [https://aplwiki.com/wiki/Zilde empty]. With respect to frame agreement, the generic term "cells" denotes the <syntaxhighlight lang=apl inline>l</syntaxhighlight>-cells (for the left argument) or the <syntaxhighlight lang=apl inline>r</syntaxhighlight>-cells (for the right argument). If the frames are identical, each cell of <syntaxhighlight lang=apl inline>x</syntaxhighlight> is paired with the corresponding cell of <syntaxhighlight lang=apl inline>y</syntaxhighlight> in a 1-to-1 pairing. If the frame lengths differ, each cell of the shorter-framed argument is paired with each among the corresponding group of cells of the longer-framed argument. This 1-to-n pairing can be viewed as extending the shorter frame to match the longer frame. The collective results of the individual applications of <syntaxhighlight lang=apl inline>f</syntaxhighlight> are framed by the longer frame.
In [[SHARP APL]] and [[Dyalog]], frames agree only if they [[match]], or if one frame is empty. The latter case corresponds to pairing one argument in its entirety with each of the [[cells]] of the other argument.
=== Examples ===
<syntaxhighlight lang=apl>
      x←⍳2
      y←2 3 2⍴⍳12
      x{⍺⍵}⍤99 2⊢y      ⍝ 1-to-n pairing; ⍤99 corresponds to empty frame
┌───┬─────┐
│1 2│1 2  │
│  │3 4  │
│  │5 6  │
├───┼─────┤
│1 2│ 7  8│
│  │ 9 10│
│  │11 12│
└───┴─────┘
      x{⍺⍵}⍤0 2⊢y      ⍝ 1-to-1 pairing; frames match; (,2) ≡ (,2)
┌─┬─────┐
│1│1 2  │
│ │3 4  │
│ │5 6  │
├─┼─────┤
│2│ 7  8│
│ │ 9 10│
│ │11 12│
└─┴─────┘
</syntaxhighlight>
{{Works in|[[Dyalog APL]]}}


== Examples ==
== Frame prefix agreement ==
In [[A+]], [[BQN]], and [[J]], frames agree if one is a prefix of the other. In J, because every function has associated [[function rank|ranks]], frame agreement generalizes [[leading axis agreement]].
 
=== Description ===
A dyadic function with left and right ranks l and r splits its left argument into l-cells, and splits its right argument into r-cells. Each argument's [[shape]] is thus split into a frame and a cell shape. Given that one frame must be a prefix of the other, the shorter frame is called the common frame, which may be empty. Here, the generic term "cells" will denote the l-cells (for the left argument) or r-cells (for the right argument). If the frames are identical, the cells are paired 1-to-1 between the arguments. If the frame lengths differ, each cell of the shorter-framed argument is paired with each among the corresponding group of cells of the longer-framed argument. This 1-to-n pairing can be viewed as extending the shorter frame to match the longer frame. The collective results of the individual applications of the function are framed by the longer frame.
 
=== Examples ===


<syntaxhighlight lang=j>
<syntaxhighlight lang=j>
Line 20: Line 52:
{{Works in|[[J]]}}
{{Works in|[[J]]}}


The table below shows the pairing of cells from the above example. Here the notation <syntaxhighlight lang=apl inline>[shape]</syntaxhighlight> denotes the cell shape, and <syntaxhighlight lang=apl inline>|</syntaxhighlight> denotes the division between the common frame and the remaining trailing axes.
The table below shows the pairing of cells from the above example. Here, the notation <syntaxhighlight lang=apl inline>[cell shape]</syntaxhighlight> denotes the cell shape, and <syntaxhighlight lang=apl inline>|</syntaxhighlight> denotes the division between the common frame and the remaining trailing axes.


{|class=wikitable
{|class=wikitable
Line 39: Line 71:
|}
|}


Based on the ranks <syntaxhighlight lang=apl inline>l r</syntaxhighlight> of the function <syntaxhighlight lang=apl inline>+⍤0 1</syntaxhighlight>, <syntaxhighlight lang=apl inline>x</syntaxhighlight>'s frame is <syntaxhighlight lang=apl inline>,2</syntaxhighlight> and its [[cell]] shape is [https://aplwiki.com/wiki/Zilde empty] ; y's frame is <syntaxhighlight lang=apl inline>2 3</syntaxhighlight> and its cell [[shape]] is <syntaxhighlight lang=apl inline>,2</syntaxhighlight>. The shorter of the frames, and thus the common frame, is <syntaxhighlight lang=apl inline>,2</syntaxhighlight>. Thus, relative to the common frame, each atom of <syntaxhighlight lang=apl inline>x</syntaxhighlight> is paired with the corresponding 3 rows of <syntaxhighlight lang=apl inline>y</syntaxhighlight>.
Based on the ranks <syntaxhighlight lang=apl inline>0 1</syntaxhighlight> of the given function, <syntaxhighlight lang=apl inline>x</syntaxhighlight>'s frame is <syntaxhighlight lang=apl inline>,2</syntaxhighlight> and its cell shape is empty; y's frame is <syntaxhighlight lang=apl inline>2 3</syntaxhighlight> and its cell shape is <syntaxhighlight lang=apl inline>,2</syntaxhighlight>. The shorter of the frames, and thus the common frame, is <syntaxhighlight lang=apl inline>,2</syntaxhighlight>. Relative to the common frame, each atom of <syntaxhighlight lang=apl inline>x</syntaxhighlight> is paired with the corresponding 3 vectors of <syntaxhighlight lang=apl inline>y</syntaxhighlight>.
 


The expanded example below uses APL to model frame agreement.
The expanded example below uses APL to model frame prefix agreement.


<syntaxhighlight lang=apl>
<syntaxhighlight lang=apl>
      ⎕IO←0                      ⍝ for comparison with J example
       x←⍳2
       x←⍳2
       y←2 3 2⍴⍳12
       y←2 3 2⍴⍳12
Line 52: Line 84:
│2│2 3│
│2│2 3│
└─┴───┘
└─┴───┘
       ⊢cf←lf{⍺<⍥≢⍵:⍺ ⋄ ⍵}rf      ⍝ common (shorter) frame
       ⊢cf←lf{⍺<⍥≢⍵:⍺ ⋄ ⍵}rf      ⍝ common (i.e. shorter) frame
2
2
       x{⍺⍵}⍤(-≢cf)⊢y            ⍝ 1st step: the (-≢cf)-cells are paired 1-to-1 between x and y
       x{⍺⍵}⍤(-≢cf)⊢y            ⍝ 1st step: the (-≢cf)-cells are paired 1-to-1 between x and y
Line 92: Line 124:
{{Works in|[[Dyalog APL]]}}
{{Works in|[[Dyalog APL]]}}


=== Model ===
In dialects that do not feature frame prefix agreement, it can nevertheless be utilised by the introduction of an explicit operator:
<syntaxhighlight lang=apl>
      _FA_←{
          assert←{0≡⍵:'error: no common frame prefix' ⎕SIGNAL 4 ⋄ ⍵}
          r←1↓⌽3⍴⌽⍵⍵ ⋄ ar←≢¨p←⍴¨⍺⍵      ⍝ dyadic ranks, array ranks, shapes
          c←r{⍺>0:⍺⌊⍵ ⋄ 0⌈⍺+⍵}¨ar      ⍝ cell ranks
          fl fr←(-c)↓¨p                ⍝ left and right frames                     
          s←fl{⍺<⍥≢⍵:⍺ ⋄ ⍵}fr          ⍝ shorter frame
          k←{⍬≡⍵:99 ⋄ -≢⍵}s            ⍝ relative rank
          assert ⍺∧⍥(s≡(≢s)↑⍴)⍵:        ⍝ do frames agree?
          ⍺ ⍺⍺⍤c⍤k⊢⍵
      }
      x+_FA_ 0 1⊢y
0  1
2  3
4  5
7  8
9 10
11 12
</syntaxhighlight>
{{Works in|[[Dyalog APL]]}}
[[Category:Leading axis theory]][[Category:Function characteristics]][[Category:Conformability]]{{APL features}}
[[Category:Leading axis theory]][[Category:Function characteristics]][[Category:Conformability]]{{APL features}}

Latest revision as of 14:23, 26 August 2023

Frame agreement is a conformability rule which describes the conditions that must be satisfied by the frames of arguments to dyadic functions with rank (either derived and/or, when supported, native). The frames must either be identical, or one must be empty, or, more generally, when supported, one frame must be a prefix of the other.

Empty frame agreement

In SHARP APL and Dyalog, frames agree only if they match, or if one frame is empty. The latter case corresponds to pairing one argument in its entirety with each of the cells of the other argument.

Examples

      x←⍳2
      y←2 3 2⍴⍳12
      x{⍺⍵}⍤99 2⊢y      ⍝ 1-to-n pairing; ⍤99 corresponds to empty frame
┌───┬─────┐
│1 2│1 2  │
│   │3 4  │
│   │5 6  │
├───┼─────┤
│1 2│ 7  8│
│   │ 9 10│
│   │11 12│
└───┴─────┘
      x{⍺⍵}⍤0 2⊢y       ⍝ 1-to-1 pairing; frames match; (,2) ≡ (,2)
┌─┬─────┐
│1│1 2  │
│ │3 4  │
│ │5 6  │
├─┼─────┤
│2│ 7  8│
│ │ 9 10│
│ │11 12│
└─┴─────┘
Works in: Dyalog APL

Frame prefix agreement

In A+, BQN, and J, frames agree if one is a prefix of the other. In J, because every function has associated ranks, frame agreement generalizes leading axis agreement.

Description

A dyadic function with left and right ranks l and r splits its left argument into l-cells, and splits its right argument into r-cells. Each argument's shape is thus split into a frame and a cell shape. Given that one frame must be a prefix of the other, the shorter frame is called the common frame, which may be empty. Here, the generic term "cells" will denote the l-cells (for the left argument) or r-cells (for the right argument). If the frames are identical, the cells are paired 1-to-1 between the arguments. If the frame lengths differ, each cell of the shorter-framed argument is paired with each among the corresponding group of cells of the longer-framed argument. This 1-to-n pairing can be viewed as extending the shorter frame to match the longer frame. The collective results of the individual applications of the function are framed by the longer frame.

Examples

   x=: i.2
   y=: i.2 3 2
   x+"0 1 y
 0  1
 2  3
 4  5

 7  8
 9 10
11 12
Works in: J

The table below shows the pairing of cells from the above example. Here, the notation [cell shape] denotes the cell shape, and | denotes the division between the common frame and the remaining trailing axes.

Argument Step 1: Frames / Cells Step 2: Common frame—cells paired
x 2 [] 2|[]
y 2 3 [2] 2|3 [2]

The same example, but without considering cell shape:

Argument Step 1: Frame / Cells Step 2: Common frame
x 2 C 2|C
y 2 3 C 2|3 C

Based on the ranks 0 1 of the given function, x's frame is ,2 and its cell shape is empty; y's frame is 2 3 and its cell shape is ,2. The shorter of the frames, and thus the common frame, is ,2. Relative to the common frame, each atom of x is paired with the corresponding 3 vectors of y.

The expanded example below uses APL to model frame prefix agreement.

      ⎕IO←0                      ⍝ for comparison with J example
      x←⍳2
      y←2 3 2⍴⍳12
      l r←0 1                    ⍝ the left and right ranks of the function +⍤0 1
      ⊢lf rf←(-l r)↓¨x,⍥(⊂∘⍴)y   ⍝ frames
┌─┬───┐
│2│2 3│
└─┴───┘
      ⊢cf←lf{⍺<⍥≢⍵:⍺ ⋄ ⍵}rf      ⍝ common (i.e. shorter) frame
2
      x{⍺⍵}⍤(-≢cf)⊢y             ⍝ 1st step: the (-≢cf)-cells are paired 1-to-1 between x and y
┌─┬─────┐
│0│0 1  │
│ │2 3  │
│ │4 5  │
├─┼─────┤
│1│ 6  7│
│ │ 8  9│
│ │10 11│
└─┴─────┘
      x{⍺⍵}⍤l r⍤(-≢cf)⊢y         ⍝ 2nd step: the (-≢cf)-cells in each pairing are split into l- and r-cells, and these are paired 1-to-n (or 1-to-1 if the frames are identical)
┌─┬─────┐
│0│0 1  │
├─┼─────┤
│0│2 3  │
├─┼─────┤
│0│4 5  │
└─┴─────┘
┌─┬─────┐
│1│6 7  │
├─┼─────┤
│1│8 9  │
├─┼─────┤
│1│10 11│
└─┴─────┘
      x+⍤0 1⊢y                   ⍝ n-to-m pairing; invalid in APL
RANK ERROR
      x+⍤l r⍤(-≢cf)⊢y            ⍝ matches the result of J's frame agreement
 0  1
 2  3
 4  5

 7  8
 9 10
11 12
Works in: Dyalog APL

Model

In dialects that do not feature frame prefix agreement, it can nevertheless be utilised by the introduction of an explicit operator:

      _FA_←{
           assert←{0≡⍵:'error: no common frame prefix' ⎕SIGNAL 4 ⋄ ⍵}
           r←1↓⌽3⍴⌽⍵⍵ ⋄ ar←≢¨p←⍴¨⍺⍵      ⍝ dyadic ranks, array ranks, shapes
           c←r{⍺>0:⍺⌊⍵ ⋄ 0⌈⍺+⍵}¨ar       ⍝ cell ranks
           fl fr←(-c)↓¨p                 ⍝ left and right frames                       
           s←fl{⍺<⍥≢⍵:⍺ ⋄ ⍵}fr           ⍝ shorter frame
           k←{⍬≡⍵:99 ⋄ -≢⍵}s             ⍝ relative rank
           assert ⍺∧⍥(s≡(≢s)↑⍴)⍵:        ⍝ do frames agree?
           ⍺ ⍺⍺⍤c⍤k⊢⍵
      }
      x+_FA_ 0 1⊢y
 0  1
 2  3
 4  5

 7  8
 9 10
11 12
Works in: Dyalog APL
APL features [edit]
Built-ins Primitives (functions, operators) ∙ Quad name
Array model ShapeRankDepthBoundIndex (Indexing) ∙ AxisRavelRavel orderElementScalarVectorMatrixSimple scalarSimple arrayNested arrayCellMajor cellSubarrayEmpty arrayPrototype
Data types Number (Boolean, Complex number) ∙ Character (String) ∙ BoxNamespaceFunction array
Concepts and paradigms Conformability (Scalar extension, Leading axis agreement) ∙ Scalar function (Pervasion) ∙ Identity elementComplex floorArray ordering (Total) ∙ Tacit programming (Function composition, Close composition) ∙ GlyphLeading axis theoryMajor cell searchFirst-class function
Errors LIMIT ERRORRANK ERRORSYNTAX ERRORDOMAIN ERRORLENGTH ERRORINDEX ERRORVALUE ERROREVOLUTION ERROR