Type Definition ndarray::ArrayViewMut[][src]

pub type ArrayViewMut<'a, A, D> = ArrayBase<ViewRepr<&'a mut A>, D>;
Expand description

A read-write array view.

An array view represents an array or a part of it, created from an iterator, subview or slice of an array.

The ArrayViewMut<'a, A, D> is parameterized by 'a for the scope of the borrow, A for the element type and D for the dimensionality.

Array views have all the methods of an array (see ArrayBase).

See also ArrayView.

Implementations

Methods for read-write array views.

Create a read-write array view borrowing its data from a slice.

Checks whether dim and strides are compatible with the slice’s length, returning an Err if not compatible.

use ndarray::ArrayViewMut;
use ndarray::arr3;
use ndarray::ShapeBuilder;

let mut s = [0, 1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12];
let mut a = ArrayViewMut::from_shape((2, 3, 2).strides((1, 4, 2)),
                                     &mut s).unwrap();

a[[0, 0, 0]] = 1;
assert!(
    a == arr3(&[[[1, 2],
                 [4, 6],
                 [8, 10]],
                [[1, 3],
                 [5, 7],
                 [9, 11]]])
);
assert!(a.strides() == &[1, 4, 2]);

Create an ArrayViewMut<A, D> from shape information and a raw pointer to the elements.

Safety

The caller is responsible for ensuring all of the following:

  • The elements seen by moving ptr according to the shape and strides must live at least as long as 'a and must not be aliased for the duration of 'a.

  • ptr must be non-null and aligned, and it must be safe to .offset() ptr by zero.

  • It must be safe to .offset() the pointer repeatedly along all axes and calculate the counts for the .offset() calls without overflow, even if the array is empty or the elements are zero-sized.

    In other words,

    • All possible pointers generated by moving along all axes must be in bounds or one byte past the end of a single allocation with element type A. The only exceptions are if the array is empty or the element type is zero-sized. In these cases, ptr may be dangling, but it must still be safe to .offset() the pointer along the axes.

    • The offset in units of bytes between the least address and greatest address by moving along all axes must not exceed isize::MAX. This constraint prevents the computed offset, in bytes, from overflowing isize regardless of the starting point due to past offsets.

    • The offset in units of A between the least address and greatest address by moving along all axes must not exceed isize::MAX. This constraint prevents overflow when calculating the count parameter to .offset() regardless of the starting point due to past offsets.

  • The product of non-zero axis lengths must not exceed isize::MAX.

Convert the view into an ArrayViewMut<'b, A, D> where 'b is a lifetime outlived by 'a'.

Methods specific to ArrayViewMut0.

See also all methods for ArrayViewMut and ArrayBase

Consume the mutable view and return a mutable reference to the single element in the array.

The lifetime of the returned reference matches the lifetime of the data the array view was pointing to.

use ndarray::{arr0, Array0};

let mut array: Array0<f64> = arr0(5.);
let view = array.view_mut();
let mut scalar = view.into_scalar();
*scalar = 7.;
assert_eq!(scalar, &7.);
assert_eq!(array[()], 7.);

Methods for read-write array views.

Return the array’s data as a slice, if it is contiguous and in standard order. Return None otherwise.

Methods for read-write array views.

Split the array view along axis and return one mutable view strictly before the split and one mutable view after the split.

Panics if axis or index is out of bounds.

Split the view into multiple disjoint slices.

This is similar to .multi_slice_mut(), but .multi_slice_move() consumes self and produces views with lifetimes matching that of self.

See Slicing for full documentation. See also SliceInfo and D::SliceArg.

Panics if any of the following occur:

  • if any of the views would intersect (i.e. if any element would appear in multiple slices)
  • if an index is out of bounds or step size is zero
  • if D is IxDyn and info does not match the number of array axes

Trait Implementations

Implementation of ArrayViewMut::from(&mut A) where A is an array.

Create a read-write array view of the array.

Implementation of ArrayViewMut::from(&mut S) where S is a slice or slicable.

Create a one-dimensional read-write array view of the data in slice.

Panics if the slice length is greater than isize::MAX.

Convert a mutable array view to a mutable reference of a element.

This method is like IndexMut::index_mut but with a longer lifetime (matching the array view); which we can only do for the array view and not in the Index trait.

See also the get_mut method which works for all arrays and array views.

Panics if index is out of bounds.

Convert a mutable array view to a mutable reference of a element, with checked access.

See also the get_mut method which works for all arrays and array views.

Convert a mutable array view to a mutable reference of a element without boundary check.

See also the uget_mut method which works for all arrays and array views.

Note: only unchecked for non-debug builds of ndarray.

The type of the reference to the element that is produced, including its lifetime. Read more

The type of the elements being iterated over.

Which kind of iterator are we turning this into?

Creates an iterator from a value. Read more

The element produced per iteration.

Dimension type

[src]

fn __private__(&self) -> PrivateMarker

This trait is private to implement; this method exists to make it impossible to implement outside the crate. Read more