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slice
Return a read-only view of an input
ndarray.
Installation
npm install @stdlib/ndarray-sliceUsage
var slice = require( '@stdlib/ndarray-slice' );slice( x, ...s[, options] )
Returns a read-only view of an input ndarray.
var Slice = require( '@stdlib/slice-ctor' );
var MultiSlice = require( '@stdlib/slice-multi' );
var ndarray = require( '@stdlib/ndarray-ctor' );
var ndarray2array = require( '@stdlib/ndarray-to-array' );
var buffer = [ 1.0, 2.0, 3.0, 4.0, 5.0, 6.0 ];
var shape = [ 3, 2 ];
var strides = [ 2, 1 ];
var offset = 0;
var x = ndarray( 'generic', buffer, shape, strides, offset, 'row-major' );
// returns <ndarray>
var sh = x.shape;
// returns [ 3, 2 ]
var arr = ndarray2array( x );
// returns [ [ 1.0, 2.0 ], [ 3.0, 4.0 ], [ 5.0, 6.0 ] ]
var s0 = new Slice( null, null, -2 );
var s1 = new Slice( null, null, -1 );
var s = new MultiSlice( s0, s1 );
// returns <MultiSlice>
var y = slice( x, s );
// returns <ndarray>
sh = y.shape;
// returns [ 2, 2 ]
arr = ndarray2array( y );
// returns [ [ 6.0, 5.0 ], [ 2.0, 1.0 ] ]The function accepts the following arguments:
-
x: input
ndarray. -
s: a
MultiSliceinstance, an array of slice arguments, or slice arguments as separate arguments. - options: function options.
The function supports three (mutually exclusive) means for providing slice arguments:
- providing a single
MultiSliceinstance. - providing a single array of slice arguments.
- providing slice arguments as separate arguments.
The following example demonstrates each invocation style returning equivalent results.
var Slice = require( '@stdlib/slice-ctor' );
var MultiSlice = require( '@stdlib/slice-multi' );
var ndarray = require( '@stdlib/ndarray-ctor' );
var ndarray2array = require( '@stdlib/ndarray-to-array' );
var buffer = [ 1.0, 2.0, 3.0, 4.0, 5.0, 6.0 ];
var shape = [ 3, 2 ];
var strides = [ 2, 1 ];
var offset = 0;
var x = ndarray( 'generic', buffer, shape, strides, offset, 'row-major' );
// returns <ndarray>
var sh = x.shape;
// returns [ 3, 2 ]
var arr = ndarray2array( x );
// returns [ [ 1.0, 2.0 ], [ 3.0, 4.0 ], [ 5.0, 6.0 ] ]
// 1. Using a MultiSlice:
var s0 = new Slice( 1, null, 1 );
var s1 = new Slice( null, null, 1 );
var s = new MultiSlice( s0, s1 );
// returns <MultiSlice>
var y = slice( x, s );
// returns <ndarray>
sh = y.shape;
// returns [ 2, 2 ]
arr = ndarray2array( y );
// returns [ [ 3.0, 4.0 ], [ 5.0, 6.0 ] ]
// 2. Using an array of slice arguments:
y = slice( x, [ s0, s1 ] );
// returns <ndarray>
sh = y.shape;
// returns [ 2, 2 ]
arr = ndarray2array( y );
// returns [ [ 3.0, 4.0 ], [ 5.0, 6.0 ] ]
// 3. Providing separate arguments:
y = slice( x, s0, s1 );
// returns <ndarray>
sh = y.shape;
// returns [ 2, 2 ]
arr = ndarray2array( y );
// returns [ [ 3.0, 4.0 ], [ 5.0, 6.0 ] ]The function supports the following options:
- strict: boolean indicating whether to enforce strict bounds checking.
By default, the function throws an error when provided a slice which exceeds array bounds. To return an empty array when a slice exceeds array bounds, set the strict option to false.
var Slice = require( '@stdlib/slice-ctor' );
var MultiSlice = require( '@stdlib/slice-multi' );
var ndarray = require( '@stdlib/ndarray-ctor' );
var ndarray2array = require( '@stdlib/ndarray-to-array' );
var buffer = [ 1.0, 2.0, 3.0, 4.0, 5.0, 6.0 ];
var shape = [ 3, 2 ];
var strides = [ 2, 1 ];
var offset = 0;
var x = ndarray( 'generic', buffer, shape, strides, offset, 'row-major' );
// returns <ndarray>
var sh = x.shape;
// returns [ 3, 2 ]
var arr = ndarray2array( x );
// returns [ [ 1.0, 2.0 ], [ 3.0, 4.0 ], [ 5.0, 6.0 ] ]
var s0 = new Slice( 1, null, 1 );
var s1 = new Slice( 10, 20, 1 );
var s = new MultiSlice( s0, s1 );
// returns <MultiSlice>
var y = slice( x, s, {
'strict': false
});
// returns <ndarray>
sh = y.shape;
// returns [ 2, 0 ]
arr = ndarray2array( y );
// returns []Notes
- A slice argument must be either a
Slice, an integer,null, orundefined. - The number of slice dimensions must match the number of array dimensions. Hence, if
xis a zero-dimensionalndarray, then, ifsis aMultiSlice,sshould be empty, and, ifsis an array,sshould not contain any slice arguments. Similarly, ifxis a one-dimensionalndarray, then, ifsis aMultiSlice,sshould have one slice dimension, and, ifsis an array,sshould contain a single slice argument. And so on and so forth.
Examples
var S = require( '@stdlib/slice-ctor' );
var E = require( '@stdlib/slice-multi' );
var array = require( '@stdlib/ndarray-array' );
var ndarray2array = require( '@stdlib/ndarray-to-array' );
var zeroTo = require( '@stdlib/array-base-zero-to' );
var slice = require( '@stdlib/ndarray-slice' );
// Alias `null` to allow for more compact indexing expressions:
var _ = null;
// Create a linear ndarray buffer:
var buf = zeroTo( 27 );
// Create an ndarray:
var x = array( buf, {
'shape': [ 3, 3, 3 ]
});
// Get each matrix...
var s1 = E( 0, _, _ );
var y1 = slice( x, s1 );
// returns <ndarray>
var a1 = ndarray2array( y1 );
// returns [ [ 0, 1, 2 ], [ 3, 4, 5 ], [ 6, 7, 8 ] ]
var s2 = E( 1, _, _ );
var y2 = slice( x, s2 );
// returns <ndarray>
var a2 = ndarray2array( y2 );
// returns [ [ 9, 10, 11 ], [ 12, 13, 14 ], [ 15, 16, 17 ] ]
var s3 = E( 2, _, _ );
var y3 = slice( x, s3 );
// returns <ndarray>
var a3 = ndarray2array( y3 );
// returns [ [ 18, 19, 20 ], [ 21, 22, 23 ], [ 24, 25, 26 ] ]
// Reverse all elements:
var s = S( _, _, -1 );
var s4 = E( s, s, s );
var y4 = slice( x, s4 );
// returns <ndarray>
var a4 = ndarray2array( y4 );
// returns [...]
// Get the second rows from each matrix:
var s5 = E( _, 1, _ );
var y5 = slice( x, s5 );
// returns <ndarray>
var a5 = ndarray2array( y5 );
// returns [ [ 3, 4, 5 ], [ 12, 13, 14 ], [ 21, 22, 23 ] ]
// Get the second columns from each matrix:
var s6 = E( _, _, 1 );
var y6 = slice( x, s6 );
// returns <ndarray>
var a6 = ndarray2array( y6 );
// returns [ [ 1, 4, 7 ], [ 10, 13, 16 ], [ 19, 22, 25 ] ]
// Use an alternative invocation style:
var y7 = slice( x, _, _, 1 );
// returns <ndarray>
var a7 = ndarray2array( y7 );
// returns [ [ 1, 4, 7 ], [ 10, 13, 16 ], [ 19, 22, 25 ] ]
// Use an alternative invocation style:
var y8 = slice( x, [ _, _, 1 ] );
// returns <ndarray>
var a8 = ndarray2array( y8 );
// returns [ [ 1, 4, 7 ], [ 10, 13, 16 ], [ 19, 22, 25 ] ]See Also
-
@stdlib/ndarray-array: multidimensional arrays. -
@stdlib/ndarray-at: return an ndarray element. -
@stdlib/ndarray-ctor: multidimensional array constructor. -
@stdlib/ndarray-slice-assign: assign element values from a broadcasted input ndarray to corresponding elements in an output ndarray view. -
@stdlib/ndarray-slice-dimension: return a read-only view of an input ndarray when sliced along a specified dimension.
Notice
This package is part of stdlib, a standard library for JavaScript and Node.js, with an emphasis on numerical and scientific computing. The library provides a collection of robust, high performance libraries for mathematics, statistics, streams, utilities, and more.
For more information on the project, filing bug reports and feature requests, and guidance on how to develop stdlib, see the main project repository.
Community
License
See LICENSE.
Copyright
Copyright © 2016-2024. The Stdlib Authors.