# This file is a part of Julia. License is MIT: https://julialang.org/license ## reductions ## ###### Generic (map)reduce functions ###### if Int === Int32 const SmallSigned = Union{Int8,Int16} const SmallUnsigned = Union{UInt8,UInt16} else const SmallSigned = Union{Int8,Int16,Int32} const SmallUnsigned = Union{UInt8,UInt16,UInt32} end # Certain reductions like sum and prod may wish to promote the items being reduced over to # an appropriate size. Note we need x + zero(x) because some types like Bool have their sum # lie in a larger type. promote_sys_size(T::Type) = T promote_sys_size(::Type{<:SmallSigned}) = Int promote_sys_size(::Type{<:SmallUnsigned}) = UInt promote_sys_size_add(x) = convert(promote_sys_size(typeof(x + zero(x))), x) promote_sys_size_mul(x) = convert(promote_sys_size(typeof(x * one(x))), x) const _PromoteSysSizeFunction = Union{typeof(promote_sys_size_add), typeof(promote_sys_size_mul)} ## foldl && mapfoldl @noinline function mapfoldl_impl(f, op, v0, itr, i...) # Unroll the while loop once; if v0 is known, the call to op may # be evaluated at compile time y = iterate(itr, i...) y === nothing && return v0 v = op(v0, f(y[1])) while true y = iterate(itr, y[2]) y === nothing && break v = op(v, f(y[1])) end return v end """ mapfoldl(f, op, v0, itr) Like [`mapreduce`](@ref), but with guaranteed left associativity, as in [`foldl`](@ref). `v0` will be used exactly once. """ mapfoldl(f, op, v0, itr) = mapfoldl_impl(f, op, v0, itr) """ mapfoldl(f, op, itr) Like `mapfoldl(f, op, v0, itr)`, but using the first element of `itr` to generate `v0`. Specifically, `mapfoldl(f, op, itr)` produces the same result as `mapfoldl(f, op, f(first(itr)), drop(itr, 1))`. In general, this cannot be used with empty collections (see [`reduce(op, itr)`](@ref)). """ function mapfoldl(f, op, itr) y = iterate(itr) if y === nothing return Base.mapreduce_empty_iter(f, op, itr, iteratoreltype(itr)) end (x, i) = y v0 = f(x) mapfoldl_impl(f, op, v0, itr, i) end """ foldl(op, v0, itr) Like [`reduce`](@ref), but with guaranteed left associativity. `v0` will be used exactly once. ```jldoctest julia> foldl(=>, 0, 1:4) (((0=>1)=>2)=>3) => 4 ``` """ foldl(op, v0, itr) = mapfoldl(identity, op, v0, itr) """ foldl(op, itr) Like `foldl(op, v0, itr)`, but using the first element of `itr` as `v0`. In general, this cannot be used with empty collections (see [`reduce(op, itr)`](@ref)). ```jldoctest julia> foldl(=>, 1:4) ((1=>2)=>3) => 4 ``` """ foldl(op, itr) = mapfoldl(identity, op, itr) ## foldr & mapfoldr function mapfoldr_impl(f, op, v0, itr, i::Integer) # Unroll the while loop once; if v0 is known, the call to op may # be evaluated at compile time if isempty(itr) || i == 0 return v0 else x = itr[i] v = op(f(x), v0) while i > 1 x = itr[i -= 1] v = op(f(x), v) end return v end end """ mapfoldr(f, op, v0, itr) Like [`mapreduce`](@ref), but with guaranteed right associativity, as in [`foldr`](@ref). `v0` will be used exactly once. """ mapfoldr(f, op, v0, itr) = mapfoldr_impl(f, op, v0, itr, endof(itr)) """ mapfoldr(f, op, itr) Like `mapfoldr(f, op, v0, itr)`, but using the first element of `itr` to generate `v0`. Specifically, `mapfoldr(f, op, itr)` produces the same result as `mapfoldr(f, op, f(last(itr)), take(itr, length(itr)-1))`. In general, this cannot be used with empty collections (see [`reduce(op, itr)`](@ref)). """ function mapfoldr(f, op, itr) i = endof(itr) if isempty(itr) return Base.mapreduce_empty_iter(f, op, itr, iteratoreltype(itr)) end return mapfoldr_impl(f, op, f(itr[i]), itr, i-1) end """ foldr(op, v0, itr) Like [`reduce`](@ref), but with guaranteed right associativity. `v0` will be used exactly once. ```jldoctest julia> foldr(=>, 0, 1:4) 1 => (2=>(3=>(4=>0))) ``` """ foldr(op, v0, itr) = mapfoldr(identity, op, v0, itr) """ foldr(op, itr) Like `foldr(op, v0, itr)`, but using the last element of `itr` as `v0`. In general, this cannot be used with empty collections (see [`reduce(op, itr)`](@ref)). ```jldoctest julia> foldr(=>, 1:4) 1 => (2=>(3=>4)) ``` """ foldr(op, itr) = mapfoldr(identity, op, itr) ## reduce & mapreduce # `mapreduce_impl()` is called by `mapreduce()` (via `_mapreduce()`, when `A` # supports linear indexing) and does actual calculations (for `A[ifirst:ilast]` subset). # For efficiency, no parameter validity checks are done, it's the caller's responsibility. # `ifirst:ilast` range is assumed to be a valid non-empty subset of `A` indices. # This is a generic implementation of `mapreduce_impl()`, # certain `op` (e.g. `min` and `max`) may have their own specialized versions. @noinline function mapreduce_impl(f, op, A::AbstractArray, ifirst::Integer, ilast::Integer, blksize::Int) if ifirst == ilast @inbounds a1 = A[ifirst] return f(a1) elseif ifirst + blksize > ilast # sequential portion @inbounds a1 = A[ifirst] @inbounds a2 = A[ifirst+1] v = op(f(a1), f(a2)) @simd for i = ifirst + 2 : ilast @inbounds ai = A[i] v = op(v, f(ai)) end return v else # pairwise portion imid = (ifirst + ilast) >> 1 v1 = mapreduce_impl(f, op, A, ifirst, imid, blksize) v2 = mapreduce_impl(f, op, A, imid+1, ilast, blksize) return op(v1, v2) end end mapreduce_impl(f, op, A::AbstractArray, ifirst::Integer, ilast::Integer) = mapreduce_impl(f, op, A, ifirst, ilast, pairwise_blocksize(f, op)) """ mapreduce(f, op, itr) Like `mapreduce(f, op, v0, itr)`. In general, this cannot be used with empty collections (see `reduce(op, itr)`). """ mapreduce(f, op, itr) = mapfoldl(f, op, itr) """ mapreduce(f, op, v0, itr) Apply function `f` to each element in `itr`, and then reduce the result using the binary function `op`. `v0` must be a neutral element for `op` that will be returned for empty collections. It is unspecified whether `v0` is used for non-empty collections. [`mapreduce`](@ref) is functionally equivalent to calling `reduce(op, v0, map(f, itr))`, but will in general execute faster since no intermediate collection needs to be created. See documentation for [`reduce`](@ref) and [`map`](@ref). ```jldoctest julia> mapreduce(x->x^2, +, [1:3;]) # == 1 + 4 + 9 14 ``` The associativity of the reduction is implementation-dependent. Additionally, some implementations may reuse the return value of `f` for elements that appear multiple times in `itr`. Use [`mapfoldl`](@ref) or [`mapfoldr`](@ref) instead for guaranteed left or right associativity and invocation of `f` for every value. """ mapreduce(f, op, v0, itr) = mapfoldl(f, op, v0, itr) # Note: sum_seq usually uses four or more accumulators after partial # unrolling, so each accumulator gets at most 256 numbers pairwise_blocksize(f, op) = 1024 # This combination appears to show a benefit from a larger block size pairwise_blocksize(::typeof(abs2), ::typeof(+)) = 4096 # handling empty arrays _empty_reduce_error() = throw(ArgumentError("reducing over an empty collection is not allowed")) reduce_empty(op, T) = _empty_reduce_error() reduce_empty(::typeof(+), T) = zero(T) reduce_empty(::typeof(*), T) = one(T) reduce_empty(::typeof(&), ::Type{Bool}) = true reduce_empty(::typeof(|), ::Type{Bool}) = false mapreduce_empty(f, op, T) = _empty_reduce_error() mapreduce_empty(::typeof(identity), op, T) = reduce_empty(op, T) mapreduce_empty(f::_PromoteSysSizeFunction, op, T) = f(mapreduce_empty(identity, op, T)) mapreduce_empty(::typeof(abs), ::typeof(+), T) = abs(zero(T)) mapreduce_empty(::typeof(abs2), ::typeof(+), T) = abs2(zero(T)) mapreduce_empty(::typeof(abs), ::Union{typeof(scalarmax), typeof(max)}, T) = abs(zero(T)) mapreduce_empty(::typeof(abs2), ::Union{typeof(scalarmax), typeof(max)}, T) = abs2(zero(T)) # Allow mapreduce_empty to “see through” promote_sys_size let ComposedFunction = typename(typeof(identity ∘ identity)).wrapper global mapreduce_empty(f::ComposedFunction{<:_PromoteSysSizeFunction}, op, T) = f.f(mapreduce_empty(f.g, op, T)) end mapreduce_empty_iter(f, op, itr, ::HasEltype) = mapreduce_empty(f, op, eltype(itr)) mapreduce_empty_iter(f, op::typeof(&), itr, ::EltypeUnknown) = true mapreduce_empty_iter(f, op::typeof(|), itr, ::EltypeUnknown) = false mapreduce_empty_iter(f, op, itr, ::EltypeUnknown) = _empty_reduce_error() _mapreduce(f, op, A::AbstractArray) = _mapreduce(f, op, IndexStyle(A), A) function _mapreduce(f, op, ::IndexLinear, A::AbstractArray{T}) where T inds = linearindices(A) n = length(inds) if n == 0 return mapreduce_empty(f, op, T) elseif n == 1 @inbounds a1 = A[inds[1]] return f(a1) elseif n < 16 # process short array here, avoid mapreduce_impl() compilation @inbounds i = inds[1] @inbounds a1 = A[i] @inbounds a2 = A[i+=1] s = op(f(a1), f(a2)) while i < last(inds) @inbounds Ai = A[i+=1] s = op(s, f(Ai)) end return s else return mapreduce_impl(f, op, A, first(inds), last(inds)) end end _mapreduce(f, op, ::IndexCartesian, A::AbstractArray) = mapfoldl(f, op, A) mapreduce(f, op, A::AbstractArray) = _mapreduce(f, op, IndexStyle(A), A) mapreduce(f, op, a::Number) = f(a) """ reduce(op, v0, itr) Reduce the given collection `itr` with the given binary operator `op`. `v0` must be a neutral element for `op` that will be returned for empty collections. It is unspecified whether `v0` is used for non-empty collections. Reductions for certain commonly-used operators may have special implementations, and should be used instead: `maximum(itr)`, `minimum(itr)`, `sum(itr)`, `prod(itr)`, `any(itr)`, `all(itr)`. The associativity of the reduction is implementation dependent. This means that you can't use non-associative operations like `-` because it is undefined whether `reduce(-,[1,2,3])` should be evaluated as `(1-2)-3` or `1-(2-3)`. Use [`foldl`](@ref) or [`foldr`](@ref) instead for guaranteed left or right associativity. Some operations accumulate error. Parallelism will be easier if the reduction can be executed in groups. Future versions of Julia might change the algorithm. Note that the elements are not reordered if you use an ordered collection. # Examples ```jldoctest julia> reduce(*, 1, [2; 3; 4]) 24 ``` """ reduce(op, v0, itr) = mapreduce(identity, op, v0, itr) """ reduce(op, itr) Like `reduce(op, v0, itr)`. This cannot be used with empty collections, except for some special cases (e.g. when `op` is one of `+`, `*`, `max`, `min`, `&`, `|`) when Julia can determine the neutral element of `op`. ```jldoctest julia> reduce(*, [2; 3; 4]) 24 ``` """ reduce(op, itr) = mapreduce(identity, op, itr) reduce(op, a::Number) = a ###### Specific reduction functions ###### ## sum """ sum(f, itr) Sum the results of calling function `f` on each element of `itr`. The return type is `Int` for signed integers of less than system word size, and `UInt` for unsigned integers of less than system word size. For all other arguments, a common return type is found to which all arguments are promoted. ```jldoctest julia> sum(abs2, [2; 3; 4]) 29 ``` Note the important difference between `sum(A)` and `reduce(+, A)` for arrays with small integer eltype: ```jldoctest julia> sum(Int8[100, 28]) 128 julia> reduce(+, Int8[100, 28]) -128 ``` In the former case, the integers are widened to system word size and therefore the result is 128. In the latter case, no such widening happens and integer overflow results in -128. """ sum(f::Callable, a) = mapreduce(promote_sys_size_add ∘ f, +, a) """ sum(itr) Returns the sum of all elements in a collection. The return type is `Int` for signed integers of less than system word size, and `UInt` for unsigned integers of less than system word size. For all other arguments, a common return type is found to which all arguments are promoted. ```jldoctest julia> sum(1:20) 210 ``` """ sum(a) = mapreduce(promote_sys_size_add, +, a) sum(a::AbstractArray{Bool}) = count(a) ## prod """ prod(f, itr) Returns the product of `f` applied to each element of `itr`. The return type is `Int` for signed integers of less than system word size, and `UInt` for unsigned integers of less than system word size. For all other arguments, a common return type is found to which all arguments are promoted. ```jldoctest julia> prod(abs2, [2; 3; 4]) 576 ``` """ prod(f::Callable, a) = mapreduce(promote_sys_size_mul ∘ f, *, a) """ prod(itr) Returns the product of all elements of a collection. The return type is `Int` for signed integers of less than system word size, and `UInt` for unsigned integers of less than system word size. For all other arguments, a common return type is found to which all arguments are promoted. ```jldoctest julia> prod(1:20) 2432902008176640000 ``` """ prod(a) = mapreduce(promote_sys_size_mul, *, a) ## maximum & minimum function mapreduce_impl(f, op::Union{typeof(scalarmax), typeof(scalarmin), typeof(max), typeof(min)}, A::AbstractArray, first::Int, last::Int) # locate the first non NaN number @inbounds a1 = A[first] v = f(a1) i = first + 1 while (v == v) && (i <= last) @inbounds ai = A[i] v = op(v, f(ai)) i += 1 end v end maximum(f::Callable, a) = mapreduce(f, scalarmax, a) minimum(f::Callable, a) = mapreduce(f, scalarmin, a) """ maximum(itr) Returns the largest element in a collection. ```jldoctest julia> maximum(-20.5:10) 9.5 julia> maximum([1,2,3]) 3 ``` """ maximum(a) = mapreduce(identity, scalarmax, a) """ minimum(itr) Returns the smallest element in a collection. ```jldoctest julia> minimum(-20.5:10) -20.5 julia> minimum([1,2,3]) 1 ``` """ minimum(a) = mapreduce(identity, scalarmin, a) ## extrema extrema(r::AbstractRange) = (minimum(r), maximum(r)) extrema(x::Real) = (x, x) """ extrema(itr) -> Tuple Compute both the minimum and maximum element in a single pass, and return them as a 2-tuple. ```jldoctest julia> extrema(2:10) (2, 10) julia> extrema([9,pi,4.5]) (3.141592653589793, 9.0) ``` """ function extrema(itr) y = iterate(itr) y === nothing && throw(ArgumentError("collection must be non-empty")) (v, s) = y vmin = vmax = v while true y = iterate(itr, s) y === nothing && break (x, s) = y vmax = max(x, vmax) vmin = min(x, vmin) end return (vmin, vmax) end ## all & any """ any(itr) -> Bool Test whether any elements of a boolean collection are `true`, returning `true` as soon as the first `true` value in `itr` is encountered (short-circuiting). ```jldoctest julia> a = [true,false,false,true] 4-element Array{Bool,1}: true false false true julia> any(a) true julia> any((println(i); v) for (i, v) in enumerate(a)) 1 true ``` """ any(itr) = any(identity, itr) """ all(itr) -> Bool Test whether all elements of a boolean collection are `true`, returning `false` as soon as the first `false` value in `itr` is encountered (short-circuiting). ```jldoctest julia> a = [true,false,false,true] 4-element Array{Bool,1}: true false false true julia> all(a) false julia> all((println(i); v) for (i, v) in enumerate(a)) 1 2 false ``` """ all(itr) = all(identity, itr) """ any(p, itr) -> Bool Determine whether predicate `p` returns `true` for any elements of `itr`, returning `true` as soon as the first item in `itr` for which `p` returns `true` is encountered (short-circuiting). If the input contains [`missing`](@ref) values, return `missing` if all non-missing values are `false` (or equivalently, if the input contains no `true` value). ```jldoctest julia> any(i->(4<=i<=6), [3,5,7]) true julia> any(i -> (println(i); i > 3), 1:10) 1 2 3 4 true ``` """ function any(f, itr) anymissing = false for x in itr v = f(x) if ismissing(v) anymissing = true elseif v return true end end return anymissing ? missing : false end """ all(p, itr) -> Bool Determine whether predicate `p` returns `true` for all elements of `itr`, returning `false` as soon as the first item in `itr` for which `p` returns `false` is encountered (short-circuiting). If the input contains [`missing`](@ref) values, return `missing` if all non-missing values are `true` (or equivalently, if the input contains no `false` value). ```jldoctest julia> all(i->(4<=i<=6), [4,5,6]) true julia> all(i -> (println(i); i < 3), 1:10) 1 2 3 false ``` """ function all(f, itr) anymissing = false for x in itr v = f(x) if ismissing(v) anymissing = true # this syntax allows throwing a TypeError for non-Bool, for consistency with any elseif v continue else return false end end return anymissing ? missing : true end ## in & contains """ in(item, collection) -> Bool ∈(item,collection) -> Bool ∋(collection,item) -> Bool ∉(item,collection) -> Bool ∌(collection,item) -> Bool Determine whether an item is in the given collection, in the sense that it is `==` to one of the values generated by iterating over the collection. Some collections need a slightly different definition; for example, [`Set`](@ref)s check whether the item [`isequal`](@ref) to one of the elements. [`Dict`](@ref)s look for `(key,value)` pairs, and the key is compared using [`isequal`](@ref). To test for the presence of a key in a dictionary, use [`haskey`](@ref) or `k in keys(dict)`. ```jldoctest julia> a = 1:3:20 1:3:19 julia> 4 in a true julia> 5 in a false ``` """ in(x, itr) = any(y -> y == x, itr) const ∈ = in ∉(x, itr)=!∈(x, itr) ∋(itr, x)= ∈(x, itr) ∌(itr, x)=!∋(itr, x) ## count """ count(p, itr) -> Integer count(itr) -> Integer Count the number of elements in `itr` for which predicate `p` returns `true`. If `p` is omitted, counts the number of `true` elements in `itr` (which should be a collection of boolean values). ```jldoctest julia> count(i->(4<=i<=6), [2,3,4,5,6]) 3 julia> count([true, false, true, true]) 3 ``` """ function count(pred, itr) n = 0 for x in itr n += pred(x)::Bool end return n end function count(pred, a::AbstractArray) n = 0 for i in eachindex(a) @inbounds n += pred(a[i])::Bool end return n end count(itr) = count(identity, itr)