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The shape of an array is a [[vector]] of lengths of the array along each [[axis]]. The Shape function <code class="apl">⍴</code> is a [[monadic function]] which returns the shape of its argument array. The [[dyadic function]] [[Reshape]] (<code class="apl">⍴</code>) produces an array of the shape specified by its left argument. | The shape of an array is a [[vector]] of lengths of the array along each [[axis]]. The Shape function <code class="apl">⍴</code> is a [[monadic function]] which returns the shape of its argument array. The [[dyadic function]] [[Reshape]] (<code class="apl">⍴</code>) produces an array of the shape specified by its left argument. | ||
An array's shape may be any vector of nonnegative integers with length less than or equal to the [[maximum rank]]. The length of an array's shape is the array's [[rank]], and the product of the shape is its [[bound]]. If the shape is [[Empty array]] then the array is a [[scalar]]. | An array's shape may be any vector of nonnegative integers with length less than or equal to the [[maximum rank]]. The length of an array's shape is the array's [[rank]], and the product of the shape is its [[bound]]. If the shape is [[Empty array|empty]] then the array is a [[scalar]]. | ||
An array's shape, along with the [[index origin]], determine the possible values which can be used as an [[index]] into the array. A complete index is a vector of integers with the same length as the shape. When the index origin is subtracted from the index each element must be at least 0 and less than the corresponding element of the shape. In languages with [[negative indexing]] it may be greater than or equal to the negative of the shape rather than 0. | An array's shape, along with the [[index origin]], determine the possible values which can be used as an [[index]] into the array. A complete index is a vector of integers with the same length as the shape. When the index origin is subtracted from the index each element must be at least 0 and less than the corresponding element of the shape. In languages with [[negative indexing]] it may be greater than or equal to the negative of the shape rather than 0. | ||
Revision as of 10:55, 18 October 2019
The shape of an array is a vector of lengths of the array along each axis. The Shape function ⍴ is a monadic function which returns the shape of its argument array. The dyadic function Reshape (⍴) produces an array of the shape specified by its left argument.
An array's shape may be any vector of nonnegative integers with length less than or equal to the maximum rank. The length of an array's shape is the array's rank, and the product of the shape is its bound. If the shape is empty then the array is a scalar.
An array's shape, along with the index origin, determine the possible values which can be used as an index into the array. A complete index is a vector of integers with the same length as the shape. When the index origin is subtracted from the index each element must be at least 0 and less than the corresponding element of the shape. In languages with negative indexing it may be greater than or equal to the negative of the shape rather than 0.
Examples
(⍬≡⍴)¨1 'A' ⍝ The shape of a scalar is the empty numeric vector ⍬
1 1
⍴'ABCDE' ⍝ The shape of a vector is a length-1 vector
5
⍴'ABC'∘.,1 2 3 4 ⍝ The shape of the matrix result of an outer product
3 4
⍴'ABC'∘.,1 2 3 4∘.×0J1 1J2 ⍝ Two consecutive outer products result in a cuboid
3 4 2