# Interfaces

A lot of the power and extensibility in Julia comes from a collection of informal interfaces. By extending a few specific methods to work for a custom type, objects of that type not only receive those functionalities, but they are also able to be used in other methods that are written to generically build upon those behaviors.

## Iteration

Required methods | Brief description | |
---|---|---|

`iterate(iter)` | Returns either a tuple of the first item and initial state or `nothing` if empty | |

`iterate(iter, state)` | Returns either a tuple of the next item and next state or `nothing` if no items remain | |

Important optional methods | Default definition | Brief description |

`Base.IteratorSize(IterType)` | `Base.HasLength()` | One of `Base.HasLength()` , `Base.HasShape{N}()` , `Base.IsInfinite()` , or `Base.SizeUnknown()` as appropriate |

`Base.IteratorEltype(IterType)` | `Base.HasEltype()` | Either `Base.EltypeUnknown()` or `Base.HasEltype()` as appropriate |

`eltype(IterType)` | `Any` | The type of the first entry of the tuple returned by `iterate()` |

`length(iter)` | (undefined) | The number of items, if known |

`size(iter, [dim])` | (undefined) | The number of items in each dimension, if known |

`Base.isdone(iter[, state])` | `missing` | Fast-path hint for iterator completion. Should be defined for stateful iterators, or else `isempty(iter)` may call `iterate(iter[, state])` and mutate the iterator. |

Value returned by `IteratorSize(IterType)` | Required Methods |
---|---|

`Base.HasLength()` | `length(iter)` |

`Base.HasShape{N}()` | `length(iter)` and `size(iter, [dim])` |

`Base.IsInfinite()` | (none) |

`Base.SizeUnknown()` | (none) |

Value returned by `IteratorEltype(IterType)` | Required Methods |
---|---|

`Base.HasEltype()` | `eltype(IterType)` |

`Base.EltypeUnknown()` | (none) |

Sequential iteration is implemented by the `iterate`

function. Instead of mutating objects as they are iterated over, Julia iterators may keep track of the iteration state externally from the object. The return value from iterate is always either a tuple of a value and a state, or `nothing`

if no elements remain. The state object will be passed back to the iterate function on the next iteration and is generally considered an implementation detail private to the iterable object.

Any object that defines this function is iterable and can be used in the many functions that rely upon iteration. It can also be used directly in a `for`

loop since the syntax:

```
for item in iter # or "for item = iter"
# body
end
```

is translated into:

```
next = iterate(iter)
while next !== nothing
(item, state) = next
# body
next = iterate(iter, state)
end
```

A simple example is an iterable sequence of square numbers with a defined length:

```
julia> struct Squares
count::Int
end
julia> Base.iterate(S::Squares, state=1) = state > S.count ? nothing : (state*state, state+1)
```

With only `iterate`

definition, the `Squares`

type is already pretty powerful. We can iterate over all the elements:

```
julia> for item in Squares(7)
println(item)
end
1
4
9
16
25
36
49
```

We can use many of the builtin methods that work with iterables, like `in`

or `sum`

:

```
julia> 25 in Squares(10)
true
julia> sum(Squares(100))
338350
```

There are a few more methods we can extend to give Julia more information about this iterable collection. We know that the elements in a `Squares`

sequence will always be `Int`

. By extending the `eltype`

method, we can give that information to Julia and help it make more specialized code in the more complicated methods. We also know the number of elements in our sequence, so we can extend `length`

, too:

```
julia> Base.eltype(::Type{Squares}) = Int # Note that this is defined for the type
julia> Base.length(S::Squares) = S.count
```

Now, when we ask Julia to `collect`

all the elements into an array it can preallocate a `Vector{Int}`

of the right size instead of naively `push!`

ing each element into a `Vector{Any}`

:

```
julia> collect(Squares(4))
4-element Vector{Int64}:
1
4
9
16
```

While we can rely upon generic implementations, we can also extend specific methods where we know there is a simpler algorithm. For example, there's a formula to compute the sum of squares, so we can override the generic iterative version with a more performant solution:

```
julia> Base.sum(S::Squares) = (n = S.count; return n*(n+1)*(2n+1)÷6)
julia> sum(Squares(1803))
1955361914
```

This is a very common pattern throughout Julia Base: a small set of required methods define an informal interface that enable many fancier behaviors. In some cases, types will want to additionally specialize those extra behaviors when they know a more efficient algorithm can be used in their specific case.

It is also often useful to allow iteration over a collection in *reverse order* by iterating over `Iterators.reverse(iterator)`

. To actually support reverse-order iteration, however, an iterator type `T`

needs to implement `iterate`

for `Iterators.Reverse{T}`

. (Given `r::Iterators.Reverse{T}`

, the underling iterator of type `T`

is `r.itr`

.) In our `Squares`

example, we would implement `Iterators.Reverse{Squares}`

methods:

```
julia> Base.iterate(rS::Iterators.Reverse{Squares}, state=rS.itr.count) = state < 1 ? nothing : (state*state, state-1)
julia> collect(Iterators.reverse(Squares(4)))
4-element Vector{Int64}:
16
9
4
1
```

## Indexing

Methods to implement | Brief description |
---|---|

`getindex(X, i)` | `X[i]` , indexed element access |

`setindex!(X, v, i)` | `X[i] = v` , indexed assignment |

`firstindex(X)` | The first index, used in `X[begin]` |

`lastindex(X)` | The last index, used in `X[end]` |

For the `Squares`

iterable above, we can easily compute the `i`

th element of the sequence by squaring it. We can expose this as an indexing expression `S[i]`

. To opt into this behavior, `Squares`

simply needs to define `getindex`

:

```
julia> function Base.getindex(S::Squares, i::Int)
1 <= i <= S.count || throw(BoundsError(S, i))
return i*i
end
julia> Squares(100)[23]
529
```

Additionally, to support the syntax `S[begin]`

and `S[end]`

, we must define `firstindex`

and `lastindex`

to specify the first and last valid indices, respectively:

```
julia> Base.firstindex(S::Squares) = 1
julia> Base.lastindex(S::Squares) = length(S)
julia> Squares(23)[end]
529
```

For multi-dimensional `begin`

/`end`

indexing as in `a[3, begin, 7]`

, for example, you should define `firstindex(a, dim)`

and `lastindex(a, dim)`

(which default to calling `first`

and `last`

on `axes(a, dim)`

, respectively).

Note, though, that the above *only* defines `getindex`

with one integer index. Indexing with anything other than an `Int`

will throw a `MethodError`

saying that there was no matching method. In order to support indexing with ranges or vectors of `Int`

s, separate methods must be written:

```
julia> Base.getindex(S::Squares, i::Number) = S[convert(Int, i)]
julia> Base.getindex(S::Squares, I) = [S[i] for i in I]
julia> Squares(10)[[3,4.,5]]
3-element Vector{Int64}:
9
16
25
```

While this is starting to support more of the indexing operations supported by some of the builtin types, there's still quite a number of behaviors missing. This `Squares`

sequence is starting to look more and more like a vector as we've added behaviors to it. Instead of defining all these behaviors ourselves, we can officially define it as a subtype of an `AbstractArray`

.

## Abstract Arrays

Methods to implement | Brief description | |
---|---|---|

`size(A)` | Returns a tuple containing the dimensions of `A` | |

`getindex(A, i::Int)` | (if `IndexLinear` ) Linear scalar indexing | |

`getindex(A, I::Vararg{Int, N})` | (if `IndexCartesian` , where `N = ndims(A)` ) N-dimensional scalar indexing | |

Optional methods | Default definition | Brief description |

`IndexStyle(::Type)` | `IndexCartesian()` | Returns either `IndexLinear()` or `IndexCartesian()` . See the description below. |

`setindex!(A, v, i::Int)` | (if `IndexLinear` ) Scalar indexed assignment | |

`setindex!(A, v, I::Vararg{Int, N})` | (if `IndexCartesian` , where `N = ndims(A)` ) N-dimensional scalar indexed assignment | |

`getindex(A, I...)` | defined in terms of scalar `getindex` | Multidimensional and nonscalar indexing |

`setindex!(A, X, I...)` | defined in terms of scalar `setindex!` | Multidimensional and nonscalar indexed assignment |

`iterate` | defined in terms of scalar `getindex` | Iteration |

`length(A)` | `prod(size(A))` | Number of elements |

`similar(A)` | `similar(A, eltype(A), size(A))` | Return a mutable array with the same shape and element type |

`similar(A, ::Type{S})` | `similar(A, S, size(A))` | Return a mutable array with the same shape and the specified element type |

`similar(A, dims::Dims)` | `similar(A, eltype(A), dims)` | Return a mutable array with the same element type and size dims |

`similar(A, ::Type{S}, dims::Dims)` | `Array{S}(undef, dims)` | Return a mutable array with the specified element type and size |

Non-traditional indices | Default definition | Brief description |

`axes(A)` | `map(OneTo, size(A))` | Return a tuple of `AbstractUnitRange{<:Integer}` of valid indices. The axes should be their own axes, that is `axes.(axes(A),1) == axes(A)` should be satisfied. |

`similar(A, ::Type{S}, inds)` | `similar(A, S, Base.to_shape(inds))` | Return a mutable array with the specified indices `inds` (see below) |

`similar(T::Union{Type,Function}, inds)` | `T(Base.to_shape(inds))` | Return an array similar to `T` with the specified indices `inds` (see below) |

If a type is defined as a subtype of `AbstractArray`

, it inherits a very large set of rich behaviors including iteration and multidimensional indexing built on top of single-element access. See the arrays manual page and the Julia Base section for more supported methods.

A key part in defining an `AbstractArray`

subtype is `IndexStyle`

. Since indexing is such an important part of an array and often occurs in hot loops, it's important to make both indexing and indexed assignment as efficient as possible. Array data structures are typically defined in one of two ways: either it most efficiently accesses its elements using just one index (linear indexing) or it intrinsically accesses the elements with indices specified for every dimension. These two modalities are identified by Julia as `IndexLinear()`

and `IndexCartesian()`

. Converting a linear index to multiple indexing subscripts is typically very expensive, so this provides a traits-based mechanism to enable efficient generic code for all array types.

This distinction determines which scalar indexing methods the type must define. `IndexLinear()`

arrays are simple: just define `getindex(A::ArrayType, i::Int)`

. When the array is subsequently indexed with a multidimensional set of indices, the fallback `getindex(A::AbstractArray, I...)`

efficiently converts the indices into one linear index and then calls the above method. `IndexCartesian()`

arrays, on the other hand, require methods to be defined for each supported dimensionality with `ndims(A)`

`Int`

indices. For example, `SparseMatrixCSC`

from the `SparseArrays`

standard library module, only supports two dimensions, so it just defines `getindex(A::SparseMatrixCSC, i::Int, j::Int)`

. The same holds for `setindex!`

.

Returning to the sequence of squares from above, we could instead define it as a subtype of an `AbstractArray{Int, 1}`

:

```
julia> struct SquaresVector <: AbstractArray{Int, 1}
count::Int
end
julia> Base.size(S::SquaresVector) = (S.count,)
julia> Base.IndexStyle(::Type{<:SquaresVector}) = IndexLinear()
julia> Base.getindex(S::SquaresVector, i::Int) = i*i
```

Note that it's very important to specify the two parameters of the `AbstractArray`

; the first defines the `eltype`

, and the second defines the `ndims`

. That supertype and those three methods are all it takes for `SquaresVector`

to be an iterable, indexable, and completely functional array:

```
julia> s = SquaresVector(4)
4-element SquaresVector:
1
4
9
16
julia> s[s .> 8]
2-element Vector{Int64}:
9
16
julia> s + s
4-element Vector{Int64}:
2
8
18
32
julia> sin.(s)
4-element Vector{Float64}:
0.8414709848078965
-0.7568024953079282
0.4121184852417566
-0.2879033166650653
```

As a more complicated example, let's define our own toy N-dimensional sparse-like array type built on top of `Dict`

:

```
julia> struct SparseArray{T,N} <: AbstractArray{T,N}
data::Dict{NTuple{N,Int}, T}
dims::NTuple{N,Int}
end
julia> SparseArray(::Type{T}, dims::Int...) where {T} = SparseArray(T, dims);
julia> SparseArray(::Type{T}, dims::NTuple{N,Int}) where {T,N} = SparseArray{T,N}(Dict{NTuple{N,Int}, T}(), dims);
julia> Base.size(A::SparseArray) = A.dims
julia> Base.similar(A::SparseArray, ::Type{T}, dims::Dims) where {T} = SparseArray(T, dims)
julia> Base.getindex(A::SparseArray{T,N}, I::Vararg{Int,N}) where {T,N} = get(A.data, I, zero(T))
julia> Base.setindex!(A::SparseArray{T,N}, v, I::Vararg{Int,N}) where {T,N} = (A.data[I] = v)
```

Notice that this is an `IndexCartesian`

array, so we must manually define `getindex`

and `setindex!`

at the dimensionality of the array. Unlike the `SquaresVector`

, we are able to define `setindex!`

, and so we can mutate the array:

```
julia> A = SparseArray(Float64, 3, 3)
3×3 SparseArray{Float64, 2}:
0.0 0.0 0.0
0.0 0.0 0.0
0.0 0.0 0.0
julia> fill!(A, 2)
3×3 SparseArray{Float64, 2}:
2.0 2.0 2.0
2.0 2.0 2.0
2.0 2.0 2.0
julia> A[:] = 1:length(A); A
3×3 SparseArray{Float64, 2}:
1.0 4.0 7.0
2.0 5.0 8.0
3.0 6.0 9.0
```

The result of indexing an `AbstractArray`

can itself be an array (for instance when indexing by an `AbstractRange`

). The `AbstractArray`

fallback methods use `similar`

to allocate an `Array`

of the appropriate size and element type, which is filled in using the basic indexing method described above. However, when implementing an array wrapper you often want the result to be wrapped as well:

```
julia> A[1:2,:]
2×3 SparseArray{Float64, 2}:
1.0 4.0 7.0
2.0 5.0 8.0
```

In this example it is accomplished by defining `Base.similar(A::SparseArray, ::Type{T}, dims::Dims) where T`

to create the appropriate wrapped array. (Note that while `similar`

supports 1- and 2-argument forms, in most case you only need to specialize the 3-argument form.) For this to work it's important that `SparseArray`

is mutable (supports `setindex!`

). Defining `similar`

, `getindex`

and `setindex!`

for `SparseArray`

also makes it possible to `copy`

the array:

```
julia> copy(A)
3×3 SparseArray{Float64, 2}:
1.0 4.0 7.0
2.0 5.0 8.0
3.0 6.0 9.0
```

In addition to all the iterable and indexable methods from above, these types can also interact with each other and use most of the methods defined in Julia Base for `AbstractArrays`

:

```
julia> A[SquaresVector(3)]
3-element SparseArray{Float64, 1}:
1.0
4.0
9.0
julia> sum(A)
45.0
```

If you are defining an array type that allows non-traditional indexing (indices that start at something other than 1), you should specialize `axes`

. You should also specialize `similar`

so that the `dims`

argument (ordinarily a `Dims`

size-tuple) can accept `AbstractUnitRange`

objects, perhaps range-types `Ind`

of your own design. For more information, see Arrays with custom indices.

## Strided Arrays

Methods to implement | Brief description | |
---|---|---|

`strides(A)` | Return the distance in memory (in number of elements) between adjacent elements in each dimension as a tuple. If `A` is an `AbstractArray{T,0}` , this should return an empty tuple. | |

`Base.unsafe_convert(::Type{Ptr{T}}, A)` | Return the native address of an array. | |

`Base.elsize(::Type{<:A})` | Return the stride between consecutive elements in the array. | |

Optional methods | Default definition | Brief description |

`stride(A, i::Int)` | `strides(A)[i]` | Return the distance in memory (in number of elements) between adjacent elements in dimension k. |

A strided array is a subtype of `AbstractArray`

whose entries are stored in memory with fixed strides. Provided the element type of the array is compatible with BLAS, a strided array can utilize BLAS and LAPACK routines for more efficient linear algebra routines. A typical example of a user-defined strided array is one that wraps a standard `Array`

with additional structure.

Warning: do not implement these methods if the underlying storage is not actually strided, as it may lead to incorrect results or segmentation faults.

Here are some examples to demonstrate which type of arrays are strided and which are not:

```
1:5 # not strided (there is no storage associated with this array.)
Vector(1:5) # is strided with strides (1,)
A = [1 5; 2 6; 3 7; 4 8] # is strided with strides (1,4)
V = view(A, 1:2, :) # is strided with strides (1,4)
V = view(A, 1:2:3, 1:2) # is strided with strides (2,4)
V = view(A, [1,2,4], :) # is not strided, as the spacing between rows is not fixed.
```

## Customizing broadcasting

Methods to implement | Brief description |
---|---|

`Base.BroadcastStyle(::Type{SrcType}) = SrcStyle()` | Broadcasting behavior of `SrcType` |

`Base.similar(bc::Broadcasted{DestStyle}, ::Type{ElType})` | Allocation of output container |

Optional methods | |

`Base.BroadcastStyle(::Style1, ::Style2) = Style12()` | Precedence rules for mixing styles |

`Base.axes(x)` | Declaration of the indices of `x` , as per `axes(x)` . |

`Base.broadcastable(x)` | Convert `x` to an object that has `axes` and supports indexing |

Bypassing default machinery | |

`Base.copy(bc::Broadcasted{DestStyle})` | Custom implementation of `broadcast` |

`Base.copyto!(dest, bc::Broadcasted{DestStyle})` | Custom implementation of `broadcast!` , specializing on `DestStyle` |

`Base.copyto!(dest::DestType, bc::Broadcasted{Nothing})` | Custom implementation of `broadcast!` , specializing on `DestType` |

`Base.Broadcast.broadcasted(f, args...)` | Override the default lazy behavior within a fused expression |

`Base.Broadcast.instantiate(bc::Broadcasted{DestStyle})` | Override the computation of the lazy broadcast's axes |

Broadcasting is triggered by an explicit call to `broadcast`

or `broadcast!`

, or implicitly by "dot" operations like `A .+ b`

or `f.(x, y)`

. Any object that has `axes`

and supports indexing can participate as an argument in broadcasting, and by default the result is stored in an `Array`

. This basic framework is extensible in three major ways:

- Ensuring that all arguments support broadcast
- Selecting an appropriate output array for the given set of arguments
- Selecting an efficient implementation for the given set of arguments

Not all types support `axes`

and indexing, but many are convenient to allow in broadcast. The `Base.broadcastable`

function is called on each argument to broadcast, allowing it to return something different that supports `axes`

and indexing. By default, this is the identity function for all `AbstractArray`

s and `Number`

s — they already support `axes`

and indexing.

If a type is intended to act like a "0-dimensional scalar" (a single object) rather than as a container for broadcasting, then the following method should be defined:

`Base.broadcastable(o::MyType) = Ref(o)`

that returns the argument wrapped in a 0-dimensional `Ref`

container. For example, such a wrapper method is defined for types themselves, functions, special singletons like `missing`

and `nothing`

, and dates.

Custom array-like types can specialize `Base.broadcastable`

to define their shape, but they should follow the convention that `collect(Base.broadcastable(x)) == collect(x)`

. A notable exception is `AbstractString`

; strings are special-cased to behave as scalars for the purposes of broadcast even though they are iterable collections of their characters (see Strings for more).

The next two steps (selecting the output array and implementation) are dependent upon determining a single answer for a given set of arguments. Broadcast must take all the varied types of its arguments and collapse them down to just one output array and one implementation. Broadcast calls this single answer a "style". Every broadcastable object each has its own preferred style, and a promotion-like system is used to combine these styles into a single answer — the "destination style".

### Broadcast Styles

`Base.BroadcastStyle`

is the abstract type from which all broadcast styles are derived. When used as a function it has two possible forms, unary (single-argument) and binary. The unary variant states that you intend to implement specific broadcasting behavior and/or output type, and do not wish to rely on the default fallback `Broadcast.DefaultArrayStyle`

.

To override these defaults, you can define a custom `BroadcastStyle`

for your object:

```
struct MyStyle <: Broadcast.BroadcastStyle end
Base.BroadcastStyle(::Type{<:MyType}) = MyStyle()
```

In some cases it might be convenient not to have to define `MyStyle`

, in which case you can leverage one of the general broadcast wrappers:

`Base.BroadcastStyle(::Type{<:MyType}) = Broadcast.Style{MyType}()`

can be used for arbitrary types.`Base.BroadcastStyle(::Type{<:MyType}) = Broadcast.ArrayStyle{MyType}()`

is preferred if`MyType`

is an`AbstractArray`

.- For
`AbstractArrays`

that only support a certain dimensionality, create a subtype of`Broadcast.AbstractArrayStyle{N}`

(see below).

When your broadcast operation involves several arguments, individual argument styles get combined to determine a single `DestStyle`

that controls the type of the output container. For more details, see below.

### Selecting an appropriate output array

The broadcast style is computed for every broadcasting operation to allow for dispatch and specialization. The actual allocation of the result array is handled by `similar`

, using the Broadcasted object as its first argument.

`Base.similar(bc::Broadcasted{DestStyle}, ::Type{ElType})`

The fallback definition is

```
similar(bc::Broadcasted{DefaultArrayStyle{N}}, ::Type{ElType}) where {N,ElType} =
similar(Array{ElType}, axes(bc))
```

However, if needed you can specialize on any or all of these arguments. The final argument `bc`

is a lazy representation of a (potentially fused) broadcast operation, a `Broadcasted`

object. For these purposes, the most important fields of the wrapper are `f`

and `args`

, describing the function and argument list, respectively. Note that the argument list can — and often does — include other nested `Broadcasted`

wrappers.

For a complete example, let's say you have created a type, `ArrayAndChar`

, that stores an array and a single character:

```
struct ArrayAndChar{T,N} <: AbstractArray{T,N}
data::Array{T,N}
char::Char
end
Base.size(A::ArrayAndChar) = size(A.data)
Base.getindex(A::ArrayAndChar{T,N}, inds::Vararg{Int,N}) where {T,N} = A.data[inds...]
Base.setindex!(A::ArrayAndChar{T,N}, val, inds::Vararg{Int,N}) where {T,N} = A.data[inds...] = val
Base.showarg(io::IO, A::ArrayAndChar, toplevel) = print(io, typeof(A), " with char '", A.char, "'")
```

You might want broadcasting to preserve the `char`

"metadata". First we define

`Base.BroadcastStyle(::Type{<:ArrayAndChar}) = Broadcast.ArrayStyle{ArrayAndChar}()`

This means we must also define a corresponding `similar`

method:

```
function Base.similar(bc::Broadcast.Broadcasted{Broadcast.ArrayStyle{ArrayAndChar}}, ::Type{ElType}) where ElType
# Scan the inputs for the ArrayAndChar:
A = find_aac(bc)
# Use the char field of A to create the output
ArrayAndChar(similar(Array{ElType}, axes(bc)), A.char)
end
"`A = find_aac(As)` returns the first ArrayAndChar among the arguments."
find_aac(bc::Base.Broadcast.Broadcasted) = find_aac(bc.args)
find_aac(args::Tuple) = find_aac(find_aac(args[1]), Base.tail(args))
find_aac(x) = x
find_aac(::Tuple{}) = nothing
find_aac(a::ArrayAndChar, rest) = a
find_aac(::Any, rest) = find_aac(rest)
```

From these definitions, one obtains the following behavior:

```
julia> a = ArrayAndChar([1 2; 3 4], 'x')
2×2 ArrayAndChar{Int64, 2} with char 'x':
1 2
3 4
julia> a .+ 1
2×2 ArrayAndChar{Int64, 2} with char 'x':
2 3
4 5
julia> a .+ [5,10]
2×2 ArrayAndChar{Int64, 2} with char 'x':
6 7
13 14
```

### Extending broadcast with custom implementations

In general, a broadcast operation is represented by a lazy `Broadcasted`

container that holds onto the function to be applied alongside its arguments. Those arguments may themselves be more nested `Broadcasted`

containers, forming a large expression tree to be evaluated. A nested tree of `Broadcasted`

containers is directly constructed by the implicit dot syntax; `5 .+ 2.*x`

is transiently represented by `Broadcasted(+, 5, Broadcasted(*, 2, x))`

, for example. This is invisible to users as it is immediately realized through a call to `copy`

, but it is this container that provides the basis for broadcast's extensibility for authors of custom types. The built-in broadcast machinery will then determine the result type and size based upon the arguments, allocate it, and then finally copy the realization of the `Broadcasted`

object into it with a default `copyto!(::AbstractArray, ::Broadcasted)`

method. The built-in fallback `broadcast`

and `broadcast!`

methods similarly construct a transient `Broadcasted`

representation of the operation so they can follow the same codepath. This allows custom array implementations to provide their own `copyto!`

specialization to customize and optimize broadcasting. This is again determined by the computed broadcast style. This is such an important part of the operation that it is stored as the first type parameter of the `Broadcasted`

type, allowing for dispatch and specialization.

For some types, the machinery to "fuse" operations across nested levels of broadcasting is not available or could be done more efficiently incrementally. In such cases, you may need or want to evaluate `x .* (x .+ 1)`

as if it had been written `broadcast(*, x, broadcast(+, x, 1))`

, where the inner operation is evaluated before tackling the outer operation. This sort of eager operation is directly supported by a bit of indirection; instead of directly constructing `Broadcasted`

objects, Julia lowers the fused expression `x .* (x .+ 1)`

to `Broadcast.broadcasted(*, x, Broadcast.broadcasted(+, x, 1))`

. Now, by default, `broadcasted`

just calls the `Broadcasted`

constructor to create the lazy representation of the fused expression tree, but you can choose to override it for a particular combination of function and arguments.

As an example, the builtin `AbstractRange`

objects use this machinery to optimize pieces of broadcasted expressions that can be eagerly evaluated purely in terms of the start, step, and length (or stop) instead of computing every single element. Just like all the other machinery, `broadcasted`

also computes and exposes the combined broadcast style of its arguments, so instead of specializing on `broadcasted(f, args...)`

, you can specialize on `broadcasted(::DestStyle, f, args...)`

for any combination of style, function, and arguments.

For example, the following definition supports the negation of ranges:

`broadcasted(::DefaultArrayStyle{1}, ::typeof(-), r::OrdinalRange) = range(-first(r), step=-step(r), length=length(r))`

### Extending in-place broadcasting

In-place broadcasting can be supported by defining the appropriate `copyto!(dest, bc::Broadcasted)`

method. Because you might want to specialize either on `dest`

or the specific subtype of `bc`

, to avoid ambiguities between packages we recommend the following convention.

If you wish to specialize on a particular style `DestStyle`

, define a method for

`copyto!(dest, bc::Broadcasted{DestStyle})`

Optionally, with this form you can also specialize on the type of `dest`

.

If instead you want to specialize on the destination type `DestType`

without specializing on `DestStyle`

, then you should define a method with the following signature:

`copyto!(dest::DestType, bc::Broadcasted{Nothing})`

This leverages a fallback implementation of `copyto!`

that converts the wrapper into a `Broadcasted{Nothing}`

. Consequently, specializing on `DestType`

has lower precedence than methods that specialize on `DestStyle`

.

Similarly, you can completely override out-of-place broadcasting with a `copy(::Broadcasted)`

method.

#### Working with `Broadcasted`

objects

In order to implement such a `copy`

or `copyto!`

, method, of course, you must work with the `Broadcasted`

wrapper to compute each element. There are two main ways of doing so:

`Broadcast.flatten`

recomputes the potentially nested operation into a single function and flat list of arguments. You are responsible for implementing the broadcasting shape rules yourself, but this may be helpful in limited situations.- Iterating over the
`CartesianIndices`

of the`axes(::Broadcasted)`

and using indexing with the resulting`CartesianIndex`

object to compute the result.

### Writing binary broadcasting rules

The precedence rules are defined by binary `BroadcastStyle`

calls:

`Base.BroadcastStyle(::Style1, ::Style2) = Style12()`

where `Style12`

is the `BroadcastStyle`

you want to choose for outputs involving arguments of `Style1`

and `Style2`

. For example,

`Base.BroadcastStyle(::Broadcast.Style{Tuple}, ::Broadcast.AbstractArrayStyle{0}) = Broadcast.Style{Tuple}()`

indicates that `Tuple`

"wins" over zero-dimensional arrays (the output container will be a tuple). It is worth noting that you do not need to (and should not) define both argument orders of this call; defining one is sufficient no matter what order the user supplies the arguments in.

For `AbstractArray`

types, defining a `BroadcastStyle`

supersedes the fallback choice, `Broadcast.DefaultArrayStyle`

. `DefaultArrayStyle`

and the abstract supertype, `AbstractArrayStyle`

, store the dimensionality as a type parameter to support specialized array types that have fixed dimensionality requirements.

`DefaultArrayStyle`

"loses" to any other `AbstractArrayStyle`

that has been defined because of the following methods:

```
BroadcastStyle(a::AbstractArrayStyle{Any}, ::DefaultArrayStyle) = a
BroadcastStyle(a::AbstractArrayStyle{N}, ::DefaultArrayStyle{N}) where N = a
BroadcastStyle(a::AbstractArrayStyle{M}, ::DefaultArrayStyle{N}) where {M,N} =
typeof(a)(Val(max(M, N)))
```

You do not need to write binary `BroadcastStyle`

rules unless you want to establish precedence for two or more non-`DefaultArrayStyle`

types.

If your array type does have fixed dimensionality requirements, then you should subtype `AbstractArrayStyle`

. For example, the sparse array code has the following definitions:

```
struct SparseVecStyle <: Broadcast.AbstractArrayStyle{1} end
struct SparseMatStyle <: Broadcast.AbstractArrayStyle{2} end
Base.BroadcastStyle(::Type{<:SparseVector}) = SparseVecStyle()
Base.BroadcastStyle(::Type{<:SparseMatrixCSC}) = SparseMatStyle()
```

Whenever you subtype `AbstractArrayStyle`

, you also need to define rules for combining dimensionalities, by creating a constructor for your style that takes a `Val(N)`

argument. For example:

```
SparseVecStyle(::Val{0}) = SparseVecStyle()
SparseVecStyle(::Val{1}) = SparseVecStyle()
SparseVecStyle(::Val{2}) = SparseMatStyle()
SparseVecStyle(::Val{N}) where N = Broadcast.DefaultArrayStyle{N}()
```

These rules indicate that the combination of a `SparseVecStyle`

with 0- or 1-dimensional arrays yields another `SparseVecStyle`

, that its combination with a 2-dimensional array yields a `SparseMatStyle`

, and anything of higher dimensionality falls back to the dense arbitrary-dimensional framework. These rules allow broadcasting to keep the sparse representation for operations that result in one or two dimensional outputs, but produce an `Array`

for any other dimensionality.

## Instance Properties

Methods to implement | Default definition | Brief description |
---|---|---|

`propertynames(x::ObjType, private::Bool=false)` | `fieldnames(typeof(x))` | Return a tuple of the properties (`x.property` ) of an object `x` . If `private=true` , also return property names intended to be kept as private |

`getproperty(x::ObjType, s::Symbol)` | `getfield(x, s)` | Return property `s` of `x` . `x.s` calls `getproperty(x, :s)` . |

`setproperty!(x::ObjType, s::Symbol, v)` | `setfield!(x, s, v)` | Set property `s` of `x` to `v` . `x.s = v` calls `setproperty!(x, :s, v)` . Should return `v` . |

Sometimes, it is desirable to change how the end-user interacts with the fields of an object. Instead of granting direct access to type fields, an extra layer of abstraction between the user and the code can be provided by overloading `object.field`

. Properties are what the user *sees of* the object, fields what the object *actually is*.

By default, properties and fields are the same. However, this behavior can be changed. For example, take this representation of a point in a plane in polar coordinates:

```
julia> mutable struct Point
r::Float64
ϕ::Float64
end
julia> p = Point(7.0, pi/4)
Point(7.0, 0.7853981633974483)
```

As described in the table above dot access `p.r`

is the same as `getproperty(p, :r)`

which is by default the same as `getfield(p, :r)`

:

```
julia> propertynames(p)
(:r, :ϕ)
julia> getproperty(p, :r), getproperty(p, :ϕ)
(7.0, 0.7853981633974483)
julia> p.r, p.ϕ
(7.0, 0.7853981633974483)
julia> getfield(p, :r), getproperty(p, :ϕ)
(7.0, 0.7853981633974483)
```

However, we may want users to be unaware that `Point`

stores the coordinates as `r`

and `ϕ`

(fields), and instead interact with `x`

and `y`

(properties). The methods in the first column can be defined to add new functionality:

```
julia> Base.propertynames(::Point, private::Bool=false) = private ? (:x, :y, :r, :ϕ) : (:x, :y)
julia> function Base.getproperty(p::Point, s::Symbol)
if s === :x
return getfield(p, :r) * cos(getfield(p, :ϕ))
elseif s === :y
return getfield(p, :r) * sin(getfield(p, :ϕ))
else
# This allows accessing fields with p.r and p.ϕ
return getfield(p, s)
end
end
julia> function Base.setproperty!(p::Point, s::Symbol, f)
if s === :x
y = p.y
setfield!(p, :r, sqrt(f^2 + y^2))
setfield!(p, :ϕ, atan(y, f))
return f
elseif s === :y
x = p.x
setfield!(p, :r, sqrt(x^2 + f^2))
setfield!(p, :ϕ, atan(f, x))
return f
else
# This allow modifying fields with p.r and p.ϕ
return setfield!(p, s, f)
end
end
```

It is important that `getfield`

and `setfield`

are used inside `getproperty`

and `setproperty!`

instead of the dot syntax, since the dot syntax would make the functions recursive which can lead to type inference issues. We can now try out the new functionality:

```
julia> propertynames(p)
(:x, :y)
julia> p.x
4.949747468305833
julia> p.y = 4.0
4.0
julia> p.r
6.363961030678928
```

Finally, it is worth noting that adding instance properties like this is quite rarely done in Julia and should in general only be done if there is a good reason for doing so.