Consistent Extensions in NARS2000: Difference between revisions
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* [[Indexing|Unified index reference, assignment, and modify assignment]] (<apll>R[L]</apll>, <apll>R[L]←A</apll>, and <apll>R[L]<i>f</i>←A</apll>): these three forms all allow both Reach and Scatter indexing — that is, if <apll>L⊃R</apll> is valid, it is equivalent to <apll>⊃R[⊂L]</apll>, and if <apll>L⌷R</apll> is valid, it is equivalent to <apll>R[⊃∘.,/L]</apll> — Reach and Scatter indexing may appear together within a single instance of <apll>R[L]</apll>, <apll>R[L]←A</apll>, and <apll>R[L]<i>f</i>←A</apll>. | * [[Indexing|Unified index reference, assignment, and modify assignment]] (<apll>R[L]</apll>, <apll>R[L]←A</apll>, and <apll>R[L]<i>f</i>←A</apll>): these three forms all allow both Reach and Scatter indexing — that is, if <apll>L⊃R</apll> is valid, it is equivalent to <apll>⊃R[⊂L]</apll>, and if <apll>L⌷R</apll> is valid, it is equivalent to <apll>R[⊃∘.,/L]</apll> — Reach and Scatter indexing may appear together within a single instance of <apll>R[L]</apll>, <apll>R[L]←A</apll>, and <apll>R[L]<i>f</i>←A</apll>. | ||
* [[Rank|Dyadic operator dieresis-jot]] (<apll><i>f</i>⍤[X] Y</apll>) (rank) is used to apply a function to (monadic) or between (dyadic) cells of the argument(s). | * [[Rank|Dyadic operator dieresis-jot]] (<apll><i>f</i>⍤[X] Y</apll>) (rank) is used to apply a function to (monadic) or between (dyadic) cells of the argument(s). | ||
* [[ | * [[Compose|Dyadic operator jot]] (<apll><i>f</i>∘<i>g</i></apll>) (compose) is used to join two functions or a function and a variable to produce a derived function (e.g., <apll>,∘⍋∘⍋∘,</apll>) which is applied as a single function. For example, the function <apll>*∘2</apll> when applied monadically, squares its argument. | ||
* [[Null|Monadic operator null]] (<apll><i>f</i>⊙</apll>): To aid in resolving ambiguities with slash/slope as function/operator, use this operator. It passes through all functions as functions, and forces the symbols slash/slope to be functions rather than operators. For example, use <apll>(/⊙)/3 4</apll> instead of <apll>(/)/3 4</apll>. | * [[Null|Monadic operator null]] (<apll><i>f</i>⊙</apll>): To aid in resolving ambiguities with slash/slope as function/operator, use this operator. It passes through all functions as functions, and forces the symbols slash/slope to be functions rather than operators. For example, use <apll>(/⊙)/3 4</apll> instead of <apll>(/)/3 4</apll>. | ||
* [[Partitioned_Enclose|Partitioned Enclose]] (<apll>L⊂[X] R</apll>): Partition <apll>R</apll> along the <apll>X</apll> axis according to <apll>L</apll>. | * [[Partitioned_Enclose|Partitioned Enclose]] (<apll>L⊂[X] R</apll>): Partition <apll>R</apll> along the <apll>X</apll> axis according to <apll>L</apll>. | ||
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* [[Tally]]: monadic right caret (<apll>>R</apll>) which is equivalent to <apll>⍬⍴(⍴R),1</apll>. | * [[Tally]]: monadic right caret (<apll>>R</apll>) which is equivalent to <apll>⍬⍴(⍴R),1</apll>. | ||
* [[Indices]]: monadic iota underbar (<apll>⍸R</apll>) which is equivalent to <apll>R/⍳>R</apll>. | * [[Indices]]: monadic iota underbar (<apll>⍸R</apll>) which is equivalent to <apll>R/⍳>R</apll>. | ||
* [[Type]]: Primitive monadic function down tack (<apll>⊤R</apll>) (Type). | |||
* [[Composition]]: Primitive dyadic operator dieresis circle (<apll>L f⍥g R</apll>) (Composition). | |||
<!-- * Selective assignment, e.g. <apll>(1 1⍉M)←0</apll>. --> | <!-- * Selective assignment, e.g. <apll>(1 1⍉M)←0</apll>. --> | ||
* New System Variables | * New System Variables |
Revision as of 16:32, 3 February 2011
The following features are considered consistent extensions to the Extended APL Standard in that they replace error-producing behavior with non-error-producing behavior. Note that Extended APL Standard wants you to know that the use of a consistent extension prevents a program from conforming with the Standard.
Language Features
- Sink: monadic left arrow (←R) suppresses the display of R.
- Unified index reference, assignment, and modify assignment (R[L], R[L]←A, and R[L]f←A): these three forms all allow both Reach and Scatter indexing — that is, if L⊃R is valid, it is equivalent to ⊃R[⊂L], and if L⌷R is valid, it is equivalent to R[⊃∘.,/L] — Reach and Scatter indexing may appear together within a single instance of R[L], R[L]←A, and R[L]f←A.
- Dyadic operator dieresis-jot (f⍤[X] Y) (rank) is used to apply a function to (monadic) or between (dyadic) cells of the argument(s).
- Dyadic operator jot (f∘g) (compose) is used to join two functions or a function and a variable to produce a derived function (e.g., ,∘⍋∘⍋∘,) which is applied as a single function. For example, the function *∘2 when applied monadically, squares its argument.
- Monadic operator null (f⊙): To aid in resolving ambiguities with slash/slope as function/operator, use this operator. It passes through all functions as functions, and forces the symbols slash/slope to be functions rather than operators. For example, use (/⊙)/3 4 instead of (/)/3 4.
- Partitioned Enclose (L⊂[X] R): Partition R along the X axis according to L.
- Monadic iota (⍳R) extended to negative indices. For example, in origin-0, ⍳¯3 returns ¯3 ¯2 ¯1.
- Monadic iota (⍳R) extended to length > 1 vector right arguments returns an array of indices whose shape is that of the right argument (via an internal magic function).
- Dyadic iota (L⍳R) extended to rank > 1 left arguments returns an array of vector indices to the left argument (via an internal magic function).
- Index reference, assignment, modify assignment, squad, transpose, pick, and the axis operator (R[L], R[L]←A, R[L]f←A, L⌷R, L⍉R, L⊃R, and f[L]) are each extended to negative values in L. That is, if the largest allowed value is N, then the allowable range for the values in L is 1 ¯1[1]-N to N, inclusive. For example, A, A[⍳⍴A], and A[⍳-⍴A] are all identical for any array A in either origin, as are A, (⍳⍴⍴A)⍉A, and (⍳-⍴⍴A)⍉A.
- Monadic and dyadic domino (⌹R and L⌹R) — matrix inverse/divide extended to use Moore-Penrose pseudo-inverse algorithm via Singular Value Decomposition.
- Prototypes for all primitive functions and operators.
- Jot may be used as either operand to a user-defined operator in which case the name associated with the jot inside the operator is undefined, that is, ⎕NC on the name returns 0.
- Generalized Identity Functions for reduction and inner product.
- Out of range numeric assignments to ⎕PP and ⎕PW are set to the value in the allowable range nearest the ceiling of the given number. For example, if ⎕PP is set to 23.7, that value is rounded down to 17, the largest value that system variable may assume.
- Assigning a simple empty vector to a scalar system variable (⎕CT, ⎕IO, ⎕PP, ⎕PW, or ⎕RL) assigns the system default value to the variable.
- Find: dyadic epsilon underbar (L⍷R) using the Knuth-Morris-Pratt string searching algorithm.
- Reshape (L⍴R) is extended to allow a non-empty Reshape of an empty in which case the right argument fill element is used, e.g., 2 3⍴⍬.
- Mismatch: dyadic not equal underbar (L≢R) which is equivalent to ~L≡R.
- Tally: monadic right caret (>R) which is equivalent to ⍬⍴(⍴R),1.
- Indices: monadic iota underbar (⍸R) which is equivalent to R/⍳>R.
- Type: Primitive monadic function down tack (⊤R) (Type).
- Composition: Primitive dyadic operator dieresis circle (L f⍥g R) (Composition).
- New System Variables
- ⎕FC (Format Control)
- ⎕IC (Indeterminate Control)
- New or Changed System Functions
- ⎕A (Uppercase English Alphabet) — returns the 26-character uppercase English alphabet.
- ⎕AT (Object Attributes) — returns various attributes (Valence, Fix Time, Execution Properties, and Size) of an object
- ⎕AV (Atomic Vector) — has all UCS-2 Unicode characters (65,536 in length)
- L ⎕CR R (Canonical Representation) — L=1 (nested vector of character vectors) and L=2 (character matrix)
- ⎕DM (Diagnostic Message)
- ⎕DR R and L ⎕DR R (Data Representation)
- L ⎕EA R (Execute Alternate)
- ⎕EC R (Execute Controlled)
- ⎕EM (Event Message)
- ⎕ERROR R (Signal Error)
- ⎕ES R and L ⎕ES R (Event Simulate)
- ⎕ET (Event Type)
- ⎕FMT R (Format arrays within Boxes)
- L ⎕FMT R (Format arrays using Format Phrases)
- ⎕MF R (Monitor Function)
- ⎕NC R (Name Class) — returns 21 through 24 for System labels, (Unused), Magic functions, and Magic operators.
- ⎕NL R (Name List) — R=21 through 24 lists System labels, (Unused), Magic functions, and Magic operators.
- ⎕SYSID (System Identification)
- ⎕SYSVER (System Version)
- ⎕TC and other related ⎕TCxxx (Terminal Control)
- L ⎕TF R (Transfer Form) — 1=|L (Type 1 Transfer Form) and 2=|L (Type 2 Transfer Form); L<0 interprets R and the result as Unicode characters; L>0 interprets them as APL2 characters
- ⎕UCS R (Unicode Character Set)
- ⎕VR R (Visual Representation)
- ⎕WA (Workspace Available)
- New Datatypes
- 2-byte Characters (Unicode, that is, UCS-2)
- 64-bit Integers
- APAs (Arithmetic Progression Arrays) (e.g., 2 3 4⍴⍳24 and 1E12⍴1)
- ± Infinity (e.g., ∞ for infinity and ¯∞ for negative infinity) — considerable development work needs to be done to this feature to handle the many special cases
Miscellaneous Syntax
- Strand Assignment: A sequence of names enclosed in parentheses can be assigned to. For example, (A B)←1 2 is the same as A←1 followed by B←2.
- Modify Assignment: An arbitrary (primitive or user-defined) dyadic function may appear immediately to the left of an assignment arrow. For example, Af←1 is the same as A←Af 1, and A[L]f←1 is the same as A[L]←A[L]f 1.
- Modify Strand Assignment: An arbitrary (primitive or user-defined) dyadic function may appear immediately to the left of the assignment arrow used in Strand Assignment (e.g. (A B)f←1 2 is the same as A←Af 1 followed by B←Bf 2).
- Function/operator assignment: A primitive function, operator, or derived function may be assigned to any available name (e.g., F←⍋, or F←¨, or F←∘, or F←+.×).
- Axis operator with primitive scalar dyadic functions: The axis operator indicates how the coordinates of the lower rank argument map to the coordinates of the higher rank argument. For example, (1 2+[1] 2 3⍴R is equivalent to (⍉3 2⍴1 2)+2 3⍴R.
- Axis operator with primitive scalar dyadic functions: The order of the values in the axis operator brackets is significant. For example, (2 3⍴L)+[1 2] 2 3 4⍴R and (⍉2 3⍴L)+[2 1] 2 3 4⍴R are identical.
- Axis operator with the dyadic derived function from the Each operator: As with primitive scalar dyadic functions, the axis operator indicates how the coordinates of the lower rank argument map to the coordinates of the higher rank argument. For example, (2 3⍴L)⍴¨[1 2] 2 3 4⍴R is equivalent to (3 1 2⍉4⌿1 2 3⍴L)⍴¨2 3 4⍴R.
- Axis operator to Ravel: The order of the values in the axis operator brackets is significant, and may transpose coordinates in the right argument before mapping the values to the result. For example, ,[2 1] R and ,[1 2] R are both valid and have the same shape and values but, in general, the values are in a different order.
- Axis operator with user-defined functions/operators: A user-defined function/operator may be sensitive to the axis operator in the same way various primitive functions and operators are. For example, FOO[2 3] R is valid if the function header is defined as ∇ Z←FOO[X] R.
- Axis operator values may be negative: That is, if the largest allowed value is N, then the allowable range for axis operator values is 1 ¯1[1]-N to N, inclusive.
- Strand left and right arguments and result to user-defined functions/operators along with optional left argument may be specified: For example, a strand right argument may be specified as ∇ Z←FOO (R1 R2 R3 R4) or, more fully, with a non-displayable result and strands used in all of the result, left, and right arguments with an optional left argument may be specified as ∇ (Z1 Z2)←{L1 L2 L3} (LO OP2[X] RO) (R1 R2 R3 R4).
- Note that braces are required to surround the left argument of an ambivalent function as in ∇ Z←{L} FOO R.
- The result of a user-defined function/operator may be marked as non-displayable by enclosing it in braces, as in ∇ {Z}←FOO R. If the result part of the header consists of multiple names, either ∇ {Z1 Z2}←FOO R or ∇ ({Z1 Z2})←FOO R or ∇ {(Z1 Z2)}←FOO R may be used to mark the result as non-displayable.
- Control structures on one line or split across multiple lines (e.g., :for I :in ⍳N ⋄ ... ⋄ :endfor).
- Point Notation (Base, Euler, and Pi) are extensions to the familiar Decimal and Exponential Point Notation for entering numeric constants. For example, the numeric constant 16bffff is a shorthand for entering 16⊥15 15 15 15.
- Trains: e.g., avg←(+/ ÷ ⍴) applies the functions to its argument(s) in a particular way (in this case, to compute the average of a numeric vector).
- System Labels: ⎕PRO and ⎕ID in user-defined functions/operators.
System commands
Session Manager
- Function editor: this feature may be invoked by typing ∇ by itself, or ∇ followed by a name, or )EDIT by itself, or )EDIT followed by a name, or by double-right-clicking on a function name in the session manager or function editor windows
- Multiple workspaces may be open at the same time and switched between via Tabs
- Workspaces are saved as plain text ASCII files
- All variable names are two-byte characters (Unicode, that is, UCS-2)
- Array rank and dimension limit of 64 bits
- Multilevel Undo in function editing
- Undo buffer saved with function for reuse on next edit