# This file is a part of Julia. License is MIT: https://julialang.org/license # Document NTuple here where we have everything needed for the doc system """ NTuple{N, T} A compact way of representing the type for a tuple of length `N` where all elements are of type `T`. ```jldoctest julia> isa((1, 2, 3, 4, 5, 6), NTuple{6, Int}) true ``` """ NTuple ## indexing ## length(t::Tuple) = nfields(t) endof(t::Tuple) = length(t) size(t::Tuple, d) = d==1 ? length(t) : throw(ArgumentError("invalid tuple dimension $d")) getindex(t::Tuple, i::Int) = getfield(t, i) getindex(t::Tuple, i::Real) = getfield(t, convert(Int, i)) getindex(t::Tuple, r::AbstractArray{<:Any,1}) = ([t[ri] for ri in r]...) getindex(t::Tuple, b::AbstractArray{Bool,1}) = length(b) == length(t) ? getindex(t,find(b)) : throw(BoundsError(t, b)) # returns new tuple; N.B.: becomes no-op if i is out-of-bounds setindex(x::Tuple, v, i::Integer) = _setindex((), x, v, i::Integer) function _setindex(y::Tuple, r::Tuple, v, i::Integer) @_inline_meta _setindex((y..., ifelse(length(y) + 1 == i, v, first(r))), tail(r), v, i) end _setindex(y::Tuple, r::Tuple{}, v, i::Integer) = y ## iterating ## start(t::Tuple) = 1 done(t::Tuple, i::Int) = (length(t) < i) next(t::Tuple, i::Int) = (t[i], i+1) eachindex(t::Tuple) = 1:length(t) function eachindex(t::Tuple, t2::Tuple...) @_inline_meta 1:_maxlength(t, t2...) end _maxlength(t::Tuple) = length(t) function _maxlength(t::Tuple, t2::Tuple, t3::Tuple...) @_inline_meta max(length(t), _maxlength(t2, t3...)) end # this allows partial evaluation of bounded sequences of next() calls on tuples, # while reducing to plain next() for arbitrary iterables. indexed_next(t::Tuple, i::Int, state) = (t[i], i+1) indexed_next(a::Array, i::Int, state) = (a[i], i+1) indexed_next(I, i, state) = done(I,state) ? throw(BoundsError()) : next(I, state) # Use dispatch to avoid a branch in first first(::Tuple{}) = throw(ArgumentError("tuple must be non-empty")) first(t::Tuple) = t[1] # eltype eltype(::Type{Tuple{}}) = Bottom eltype(::Type{<:Tuple{Vararg{E}}}) where {E} = E function eltype(t::Type{<:Tuple}) @_pure_meta t isa Union && return typejoin(eltype(t.a), eltype(t.b)) t´ = unwrap_unionall(t) r = Union{} for ti in t´.parameters r = typejoin(r, rewrap_unionall(unwrapva(ti), t)) end return r end # version of tail that doesn't throw on empty tuples (used in array indexing) safe_tail(t::Tuple) = tail(t) safe_tail(t::Tuple{}) = () # front (the converse of tail: it skips the last entry) function front(t::Tuple) @_inline_meta _front((), t...) end front(::Tuple{}) = throw(ArgumentError("Cannot call front on an empty tuple")) _front(out, v) = out function _front(out, v, t...) @_inline_meta _front((out..., v), t...) end ## mapping ## """ ntuple(f::Function, n::Integer) Create a tuple of length `n`, computing each element as `f(i)`, where `i` is the index of the element. ```jldoctest julia> ntuple(i -> 2*i, 4) (2, 4, 6, 8) ``` """ function ntuple(f::F, n::Integer) where F t = n <= 0 ? () : n == 1 ? (f(1),) : n == 2 ? (f(1), f(2)) : n == 3 ? (f(1), f(2), f(3)) : n == 4 ? (f(1), f(2), f(3), f(4)) : n == 5 ? (f(1), f(2), f(3), f(4), f(5)) : n == 6 ? (f(1), f(2), f(3), f(4), f(5), f(6)) : n == 7 ? (f(1), f(2), f(3), f(4), f(5), f(6), f(7)) : n == 8 ? (f(1), f(2), f(3), f(4), f(5), f(6), f(7), f(8)) : n == 9 ? (f(1), f(2), f(3), f(4), f(5), f(6), f(7), f(8), f(9)) : n == 10 ? (f(1), f(2), f(3), f(4), f(5), f(6), f(7), f(8), f(9), f(10)) : _ntuple(f, n) return t end _ntuple(f, n) = (@_noinline_meta; ([f(i) for i = 1:n]...)) # inferrable ntuple ntuple(f, ::Type{Val{0}}) = (@_inline_meta; ()) ntuple(f, ::Type{Val{1}}) = (@_inline_meta; (f(1),)) ntuple(f, ::Type{Val{2}}) = (@_inline_meta; (f(1), f(2))) ntuple(f, ::Type{Val{3}}) = (@_inline_meta; (f(1), f(2), f(3))) ntuple(f, ::Type{Val{4}}) = (@_inline_meta; (f(1), f(2), f(3), f(4))) ntuple(f, ::Type{Val{5}}) = (@_inline_meta; (f(1), f(2), f(3), f(4), f(5))) ntuple(f, ::Type{Val{6}}) = (@_inline_meta; (f(1), f(2), f(3), f(4), f(5), f(6))) ntuple(f, ::Type{Val{7}}) = (@_inline_meta; (f(1), f(2), f(3), f(4), f(5), f(6), f(7))) ntuple(f, ::Type{Val{8}}) = (@_inline_meta; (f(1), f(2), f(3), f(4), f(5), f(6), f(7), f(8))) ntuple(f, ::Type{Val{9}}) = (@_inline_meta; (f(1), f(2), f(3), f(4), f(5), f(6), f(7), f(8), f(9))) ntuple(f, ::Type{Val{10}}) = (@_inline_meta; (f(1), f(2), f(3), f(4), f(5), f(6), f(7), f(8), f(9), f(10))) ntuple(f, ::Type{Val{11}}) = (@_inline_meta; (f(1), f(2), f(3), f(4), f(5), f(6), f(7), f(8), f(9), f(10), f(11))) ntuple(f, ::Type{Val{12}}) = (@_inline_meta; (f(1), f(2), f(3), f(4), f(5), f(6), f(7), f(8), f(9), f(10), f(11), f(12))) ntuple(f, ::Type{Val{13}}) = (@_inline_meta; (f(1), f(2), f(3), f(4), f(5), f(6), f(7), f(8), f(9), f(10), f(11), f(12), f(13))) ntuple(f, ::Type{Val{14}}) = (@_inline_meta; (f(1), f(2), f(3), f(4), f(5), f(6), f(7), f(8), f(9), f(10), f(11), f(12), f(13), f(14))) ntuple(f, ::Type{Val{15}}) = (@_inline_meta; (f(1), f(2), f(3), f(4), f(5), f(6), f(7), f(8), f(9), f(10), f(11), f(12), f(13), f(14), f(15))) function ntuple(f::F, ::Type{Val{N}}) where {F,N} Core.typeassert(N, Int) (N >= 0) || throw(ArgumentError(string("tuple length should be ≥0, got ", N))) _ntuple((), f, Val{N}) end # Build up the output until it has length N _ntuple(out::NTuple{N,Any}, f::F, ::Type{Val{N}}) where {F,N} = out function _ntuple(out::NTuple{M,Any}, f::F, ::Type{Val{N}}) where {F,N,M} @_inline_meta _ntuple((out..., f(M+1)), f, Val{N}) end # 1 argument function map(f, t::Tuple{}) = () map(f, t::Tuple{Any,}) = (f(t[1]),) map(f, t::Tuple{Any, Any}) = (f(t[1]), f(t[2])) map(f, t::Tuple{Any, Any, Any}) = (f(t[1]), f(t[2]), f(t[3])) map(f, t::Tuple) = (@_inline_meta; (f(t[1]), map(f,tail(t))...)) # stop inlining after some number of arguments to avoid code blowup const Any16{N} = Tuple{Any,Any,Any,Any,Any,Any,Any,Any, Any,Any,Any,Any,Any,Any,Any,Any,Vararg{Any,N}} const All16{T,N} = Tuple{T,T,T,T,T,T,T,T, T,T,T,T,T,T,T,T,Vararg{T,N}} function map(f, t::Any16) n = length(t) A = Array{Any,1}(n) for i=1:n A[i] = f(t[i]) end (A...) end # 2 argument function map(f, t::Tuple{}, s::Tuple{}) = () map(f, t::Tuple{Any,}, s::Tuple{Any,}) = (f(t[1],s[1]),) map(f, t::Tuple{Any,Any}, s::Tuple{Any,Any}) = (f(t[1],s[1]), f(t[2],s[2])) function map(f, t::Tuple, s::Tuple) @_inline_meta (f(t[1],s[1]), map(f, tail(t), tail(s))...) end function map(f, t::Any16, s::Any16) n = length(t) A = Array{Any,1}(n) for i = 1:n A[i] = f(t[i], s[i]) end (A...) end # n argument function heads(ts::Tuple...) = map(t -> t[1], ts) tails(ts::Tuple...) = map(tail, ts) map(f, ::Tuple{}...) = () function map(f, t1::Tuple, t2::Tuple, ts::Tuple...) @_inline_meta (f(heads(t1, t2, ts...)...), map(f, tails(t1, t2, ts...)...)...) end function map(f, t1::Any16, t2::Any16, ts::Any16...) n = length(t1) A = Array{Any,1}(n) for i = 1:n A[i] = f(t1[i], t2[i], map(t -> t[i], ts)...) end (A...) end # type-stable padding fill_to_length(t::Tuple, val, ::Type{Val{N}}) where {N} = _ftl((), val, Val{N}, t...) _ftl(out::NTuple{N,Any}, val, ::Type{Val{N}}) where {N} = out function _ftl(out::NTuple{N,Any}, val, ::Type{Val{N}}, t...) where N @_inline_meta throw(ArgumentError("input tuple of length $(N+length(t)), requested $N")) end function _ftl(out, val, ::Type{Val{N}}, t1, t...) where N @_inline_meta _ftl((out..., t1), val, Val{N}, t...) end function _ftl(out, val, ::Type{Val{N}}) where N @_inline_meta _ftl((out..., val), val, Val{N}) end # constructing from an iterator # only define these in Base, to avoid overwriting the constructors if isdefined(Main, :Base) (::Type{T})(x::Tuple) where {T<:Tuple} = convert(T, x) # still use `convert` for tuples # resolve ambiguity between preceding and following methods All16{E,N}(x::Tuple) where {E,N} = convert(All16{E,N}, x) function (T::All16{E,N})(itr) where {E,N} len = N+16 elts = collect(E, Iterators.take(itr,len)) if length(elts) != len _totuple_err(T) end (elts...,) end (::Type{T})(itr) where {T<:Tuple} = _totuple(T, itr, start(itr)) _totuple(::Type{Tuple{}}, itr, s) = () function _totuple_err(T::ANY) @_noinline_meta throw(ArgumentError("too few elements for tuple type $T")) end function _totuple(T, itr, s) @_inline_meta done(itr, s) && _totuple_err(T) v, s = next(itr, s) (convert(tuple_type_head(T), v), _totuple(tuple_type_tail(T), itr, s)...) end _totuple(::Type{Tuple{Vararg{E}}}, itr, s) where {E} = (collect(E, Iterators.rest(itr,s))...,) _totuple(::Type{Tuple}, itr, s) = (collect(Iterators.rest(itr,s))...,) end ## comparison ## function isequal(t1::Tuple, t2::Tuple) if length(t1) != length(t2) return false end for i = 1:length(t1) if !isequal(t1[i], t2[i]) return false end end return true end function ==(t1::Tuple, t2::Tuple) if length(t1) != length(t2) return false end for i = 1:length(t1) if !(t1[i] == t2[i]) return false end end return true end const tuplehash_seed = UInt === UInt64 ? 0x77cfa1eef01bca90 : 0xf01bca90 hash( ::Tuple{}, h::UInt) = h + tuplehash_seed hash(x::Tuple{Any,}, h::UInt) = hash(x[1], hash((), h)) hash(x::Tuple{Any,Any}, h::UInt) = hash(x[1], hash(x[2], hash((), h))) hash(x::Tuple, h::UInt) = hash(x[1], hash(x[2], hash(tail(tail(x)), h))) function isless(t1::Tuple, t2::Tuple) n1, n2 = length(t1), length(t2) for i = 1:min(n1, n2) a, b = t1[i], t2[i] if !isequal(a, b) return isless(a, b) end end return n1 < n2 end ## functions ## isempty(x::Tuple{}) = true isempty(x::Tuple) = false revargs() = () revargs(x, r...) = (revargs(r...)..., x) reverse(t::Tuple) = revargs(t...) ## specialized reduction ## # TODO: these definitions cannot yet be combined, since +(x...) # where x might be any tuple matches too many methods. sum(x::Tuple{Any, Vararg{Any}}) = +(x...) # NOTE: should remove, but often used on array sizes prod(x::Tuple{}) = 1 prod(x::Tuple{Any, Vararg{Any}}) = *(x...) all(x::Tuple{}) = true all(x::Tuple{Bool}) = x[1] all(x::Tuple{Bool, Bool}) = x[1]&x[2] all(x::Tuple{Bool, Bool, Bool}) = x[1]&x[2]&x[3] # use generic reductions for the rest any(x::Tuple{}) = false any(x::Tuple{Bool}) = x[1] any(x::Tuple{Bool, Bool}) = x[1]|x[2] any(x::Tuple{Bool, Bool, Bool}) = x[1]|x[2]|x[3]