# This file is a part of Julia. License is MIT: https://julialang.org/license using Base.Iterators using Random using Base: IdentityUnitRange using Dates: Date, Day @test Base.IteratorSize(Any) isa Base.SizeUnknown # zip and filter iterators # issue #4718 @test collect(Iterators.filter(x->x[1], zip([true, false, true, false],"abcd"))) == [(true,'a'),(true,'c')] # issue #45085 @test_throws ArgumentError Iterators.reverse(zip("abc", "abcd")) @test_throws ArgumentError Iterators.reverse(zip("abc", Iterators.cycle("ab"))) let z = zip(1:2) @test size(z) == (2,) @test collect(z) == [(1,), (2,)] # Issue #13979 @test eltype(z) == Tuple{Int} end for z in (zip(1:2, 3:4), zip(1:2, 3:5)) @test collect(z) == [(1,3), (2,4)] @test eltype(z) == Tuple{Int,Int} @test size(z) == (2,) @test axes(z) == (Base.OneTo(2),) @test length(z) == 2 end let z = zip(1:2, Iterators.countfrom(3)) @test collect(z) == [(1,3), (2,4)] @test eltype(z) == Tuple{Int,Int} @test_throws MethodError size(z) # by convention, the zip of a finite and # an infinite iterator has only `length` @test_throws MethodError axes(z) @test length(z) == 2 end let z = zip([i*j for i in 1:3, j in -1:2:1], 1:6) @test collect(z) == [(-1, 1) (-2, 2) (-3, 3) (1, 4) (2, 5) (3, 6) ] @test eltype(z) == Tuple{Int,Int} @test_throws DimensionMismatch size(z) @test_throws DimensionMismatch axes(z) @test length(z) == 6 end let z = zip([i*j for i in 1:3, j in -1:2:1], [i*j for i in 1:3, j in -1:2:1]) @test collect(z) == [(-1, -1) (1, 1) (-2, -2) (2, 2) (-3, -3) (3, 3)] @test eltype(z) == Tuple{Int,Int} @test size(z) == (3, 2) @test axes(z) == (Base.OneTo(3), Base.OneTo(2)) @test length(z) == 6 end let z = zip(1:2, 3:4, 5:6) @test size(z) == (2,) @test collect(z) == [(1,3,5), (2,4,6)] @test eltype(z) == Tuple{Int,Int,Int} end @test eltype(Iterators.filter(isodd, 1:5)) == Int # typed `collect` @test collect(Float64, Iterators.filter(isodd, [1,2,3,4]))[1] === 1.0 # check direct EachLine constructor let b = IOBuffer("foo\n") @test collect(Base.EachLine(b)) == ["foo"] seek(b, 0) @test collect(Base.EachLine(b, keep=true)) == ["foo\n"] seek(b, 0) @test collect(Base.EachLine(b, ondone=()->0)) == ["foo"] seek(b, 0) @test collect(Base.EachLine(b, keep=true, ondone=()->0)) == ["foo\n"] end # enumerate (issue #6284) let b = IOBuffer("1\n2\n3\n"), a = [] for (i,x) in enumerate(eachline(b)) push!(a, (i,x)) end @test a == [(1,"1"),(2,"2"),(3,"3")] end # zip eachline (issue #7369) let zeb = IOBuffer("1\n2\n3\n4\n5\n"), letters = ['a', 'b', 'c', 'd', 'e'], res = [] for (number, letter) in zip(eachline(zeb), letters) push!(res, (parse(Int,strip(number)), letter)) end @test res == [(1, 'a'), (2, 'b'), (3, 'c'), (4, 'd'), (5, 'e')] end @test length(zip(cycle(1:3), 1:7)) == 7 @test length(zip(cycle(1:3), 1:7, cycle(1:3))) == 7 @test length(zip(1:3,product(1:7,cycle(1:3)))) == 3 @test length(zip(1:3,product(1:7,cycle(1:3)),8)) == 1 @test_throws ArgumentError length(zip()) # length of zip of empty tuple # map # ---- @testset "Iterators.map" begin @test collect(Iterators.map(string, 1:3)::Base.Generator) == map(string, 1:3) @test collect(Iterators.map(tuple, 1:3, 4:6)::Base.Generator) == map(tuple, 1:3, 4:6) end # rest # ---- let s = "hello" _, st = iterate(s) c = collect(rest(s, st)) @test c == ['e','l','l','o'] @test c isa Vector{Char} @test rest(s, st) == rest(rest(s,4),st) end @test_throws MethodError collect(rest(countfrom(1), 5)) # countfrom # --------- let i = 0, k = 1, l = 0 for j = countfrom(0, 2) @test j == i*2 i += 1 i <= 10 || break end for j = countfrom() @test j == k k += 1 k <= 10 || break end # test that `start` promotes to `typeof(start+step)` for j = countfrom(Int[0, 0], Float64[1.0, 2.0]) @test j isa Vector{Float64} @test j == l*[1, 2] l += 1 l <= 10 || break end # test with `start` and `step` having different types @test collect(take(countfrom(Date(2020,12,25), Day(1)), 12)) == range(Date(2020,12,25), step=Day(1), length=12) end # take # ---- let t = take(0:2:8, 10), i = 0 @test length(collect(t)) == 5 == length(t) for j = t @test j == i*2 i += 1 end @test i == 5 end let i = 0 for j = take(0:2:100, 10) @test j == i*2 i += 1 end @test i == 10 end @test isempty(take(0:2:8, 0)) @test_throws ArgumentError take(0:2:8, -1) @test length(take(1:3,typemax(Int))) == 3 @test length(take(countfrom(1),3)) == 3 @test length(take(1:6,3)) == 3 # drop # ---- let i = 0 for j = drop(0:2:10, 2) @test j == (i+2)*2 i += 1 end @test i == 4 end @test isempty(drop(0:2:10, 100)) @test isempty(collect(drop(0:2:10, 100))) @test_throws ArgumentError drop(0:2:8, -1) @test length(drop(1:3,typemax(Int))) == 0 @test length(drop(UInt(1):2, 3)) == 0 @test length(drop(StepRangeLen(1, 1, UInt(2)), 3)) == 0 @test Base.IteratorSize(drop(countfrom(1),3)) == Base.IsInfinite() @test_throws MethodError length(drop(countfrom(1), 3)) @test Base.IteratorSize(Iterators.drop(Iterators.filter(i -> i>0, 1:10), 2)) == Base.SizeUnknown() let x = Iterators.drop(Iterators.Stateful("abc"), 2) @test !Base.isdone(x, nothing) iterate(x) @test Base.isdone(x, nothing) end # double take # and take/drop canonicalization # ----------- for xs in Any["abc", [1, 2, 3]] @test take(take(xs, 2), 3) === take(xs, 2) @test take(take(xs, 4), 2) === take(xs, 2) @test drop(drop(xs, 1), 1) === drop(xs, 2) @test take(drop(xs, 1), 1) === drop(take(xs, 2), 1) @test take(drop(xs, 3), 0) === drop(take(xs, 2), 3) @test isempty(drop(drop(xs, 2), 2)) @test drop(take(drop(xs, 1), 2), 1) === take(drop(xs, 2), 1) @test take(drop(take(xs, 3), 1), 1) === take(drop(xs, 1), 1) end # takewhile # -------- @testset begin @test collect(takewhile(<(4),1:10)) == [1,2,3] @test collect(takewhile(<(4),Iterators.countfrom(1))) == [1,2,3] @test collect(takewhile(<(4),5:10)) == [] @test collect(takewhile(Returns(true),5:10)) == 5:10 @test collect(takewhile(isodd,[1,1,2,3])) == [1,1] @test collect(takewhile(<(2), takewhile(<(3), [1,1,2,3]))) == [1,1] @test Base.IteratorEltype(typeof(takewhile(<(4),Iterators.map(identity, 1:10)))) isa Base.EltypeUnknown end # dropwhile # -------- @testset begin @test collect(dropwhile(<(4), 1:10)) == 4:10 @test collect(dropwhile(<(4), 1:10)) isa Vector{Int} @test isempty(dropwhile(<(4), [])) @test collect(dropwhile(Returns(false),1:3)) == 1:3 @test isempty(dropwhile(Returns(true), 1:3)) @test collect(dropwhile(isodd,[1,1,2,3])) == [2,3] @test collect(dropwhile(iseven,dropwhile(isodd,[1,1,2,3]))) == [3] @test Base.IteratorEltype(typeof(dropwhile(<(4),Iterators.map(identity, 1:10)))) isa Base.EltypeUnknown end # cycle # ----- let i = 0 for j = cycle(0:3) @test j == i % 4 i += 1 i <= 10 || break end @test Base.isdone(cycle(0:3)) === Base.isdone(0:3) === missing @test !Base.isdone(cycle(0:3), 1) end # repeated # -------- let i = 0 for j = repeated(1, 10) @test j == 1 i += 1 end @test i == 10 end let i = 0 for j = repeated(1) @test j == 1 i += 1 i <= 10 || break end end @test eltype(repeated(0)) == Int @test eltype(repeated(0, 5)) == Int @test Base.IteratorSize(repeated(0)) == Base.IsInfinite() @test Base.IteratorSize(repeated(0, 5)) == Base.HasLength() @test Base.IteratorEltype(repeated(0)) == Base.HasEltype() @test Base.IteratorEltype(repeated(0, 5)) == Base.HasEltype() @test Base.IteratorSize(zip(repeated(0), repeated(0))) == Base.IsInfinite() # product # ------- # empty? for itr in [product(1:0), product(1:2, 1:0), product(1:0, 1:2), product(1:0, 1:1, 1:2), product(1:1, 1:0, 1:2), product(1:1, 1:2 ,1:0)] @test isempty(itr) @test isempty(collect(itr)) end # collect a product - first iterators runs faster @test collect(product(1:2)) == [(i,) for i=1:2] @test collect(product(1:2, 3:4)) == [(i, j) for i=1:2, j=3:4] @test collect(product(1:2, 3:4, 5:6)) == [(i, j, k) for i=1:2, j=3:4, k=5:6] # iteration order let expected = [(1,3,5), (2,3,5), (1,4,5), (2,4,5), (1,3,6), (2,3,6), (1,4,6), (2,4,6)] actual = product(1:2, 3:4, 5:6) for (exp, act) in zip(expected, actual) @test exp == act end end # collect multidimensional array let (a, b) = (1:3, [4 6; 5 7]) p = product(a, b) @test size(p) == (3, 2, 2) @test length(p) == 12 @test ndims(p) == 3 @test eltype(p) == NTuple{2, Int} cp = collect(p) for i = 1:3 @test cp[i, :, :] == [(i, 4) (i, 6); (i, 5) (i, 7)] end end # collect stateful iterator let itr itr = Iterators.Stateful(Iterators.map(identity, 1:5)) @test collect(itr) == 1:5 @test collect(itr) == Int[] # Stateful do not preserve shape itr = (i+1 for i in Base.Stateful([1, 2, 3])) @test collect(itr) == [2, 3, 4] @test collect(itr) == Int[] # Stateful do not preserve shape itr = (i-1 for i in Base.Stateful(zeros(Int, 0, 0))) @test collect(itr) == Int[] # Stateful do not preserve shape itr = Iterators.Stateful(Iterators.Stateful(1:1)) @test collect(itr) == [1] end # with 1D inputs let a = 1:2, b = 1.0:10.0, c = Int32(1):Int32(0) # length @test length(product()) == 1 @test length(product(a)) == 2 @test length(product(a, b)) == 20 @test length(product(a, b, c)) == 0 # size @test size(product()) == tuple() @test size(product(a)) == (2,) @test size(product(a, b)) == (2, 10) @test size(product(a, b, c)) == (2, 10, 0) # eltype @test eltype(product()) == Tuple{} @test eltype(product(a)) == Tuple{Int} @test eltype(product(a, b)) == Tuple{Int, Float64} @test eltype(product(a, b, c)) == Tuple{Int, Float64, Int32} # ndims @test ndims(product()) == 0 @test ndims(product(a)) == 1 @test ndims(product(a, b)) == 2 @test ndims(product(a, b, c)) == 3 end # with multidimensional inputs let a = randn(4, 4), b = randn(3, 3, 3), c = randn(2, 2, 2, 2) args = Any[(a,), (a, a), (a, b), (a, a, a), (a, b, c)] sizes = Any[(4, 4), (4, 4, 4, 4), (4, 4, 3, 3, 3), (4, 4, 4, 4, 4, 4), (4, 4, 3, 3, 3, 2, 2, 2, 2)] for (method, fun) in zip([size, ndims, length], [x->x, length, prod]) for i in 1:length(args) @test method(product(args[i]...)) == method(collect(product(args[i]...))) == fun(sizes[i]) end end end # more tests on product with iterators of various type let iters = (1:2, rand(2, 2, 2), take(1:4, 2), product(1:2, 1:3), product(rand(2, 2), rand(1, 1, 1)), repeated([1, -1], 2) # 28497 ) for method in [size, length, ndims, eltype] for i = 1:length(iters) args = (iters[i],) @test method(product(args...)) == method(collect(product(args...))) for j = 1:length(iters) args = iters[i], iters[j] @test method(product(args...)) == method(collect(product(args...))) for k = 1:length(iters) args = iters[i], iters[j], iters[k] @test method(product(args...)) == method(collect(product(args...))) end end end end end # product of finite length and infinite length iterators let a = 1:2, b = countfrom(1), ab = product(a, b), ba = product(b, a), abexp = [(1, 1), (2, 1), (1, 2), (2, 2), (1, 3), (2, 3)], baexp = [(1, 1), (2, 1), (3, 1), (4, 1), (5, 1), (6, 1)] for (expected, actual) in zip([abexp, baexp], [ab, ba]) for (i, el) in enumerate(actual) @test el == expected[i] i == length(expected) && break end @test_throws ArgumentError length(actual) @test_throws ArgumentError size(actual) @test_throws ArgumentError ndims(actual) end # size infinite or unknown raises an error for itr in Any[countfrom(1), Iterators.filter(Returns(0), 1:10)] @test_throws ArgumentError length(product(itr)) @test_throws ArgumentError size(product(itr)) @test_throws ArgumentError ndims(product(itr)) end @test_throws OverflowError length(product(1:typemax(Int), 1:typemax(Int))) end # IteratorSize trait business let f1 = Iterators.filter(i->i>0, 1:10) @test Base.IteratorSize(product(f1)) == Base.SizeUnknown() @test Base.IteratorSize(product(1:2, f1)) == Base.SizeUnknown() @test Base.IteratorSize(product(f1, 1:2)) == Base.SizeUnknown() @test Base.IteratorSize(product(f1, f1)) == Base.SizeUnknown() @test Base.IteratorSize(product(f1, countfrom(1))) == Base.IsInfinite() @test Base.IteratorSize(product(countfrom(1), f1)) == Base.IsInfinite() end @test Base.IteratorSize(product(1:2, countfrom(1))) == Base.IsInfinite() @test Base.IteratorSize(product(countfrom(2), countfrom(1))) == Base.IsInfinite() @test Base.IteratorSize(product(countfrom(1), 1:2)) == Base.IsInfinite() @test Base.IteratorSize(product(1:2)) == Base.HasShape{1}() @test Base.IteratorSize(product(1:2, 1:2)) == Base.HasShape{2}() @test Base.IteratorSize(product(take(1:2, 1), take(1:2, 1))) == Base.HasShape{2}() @test Base.IteratorSize(product(take(1:2, 2))) == Base.HasShape{1}() @test Base.IteratorSize(product([1 2; 3 4])) == Base.HasShape{2}() @test Base.IteratorSize(product((1,2,3,4), (5, 6, 7, 8))) == Base.HasShape{2}() # product of ::HasLength and ::HasLength @test Base.IteratorSize(product(1:2, 3:5, 5:6)) == Base.HasShape{3}() # product of 3 iterators @test Base.IteratorSize(product([1 2; 3 4], 1:4)) == Base.HasShape{3}() # product of ::HasShape{2} with ::HasShape{1} @test Base.IteratorSize(product([1 2; 3 4], (1,2))) == Base.HasShape{3}() # product of ::HasShape{2} with ::HasLength # IteratorEltype trait business let f1 = Iterators.filter(i->i>0, 1:10) @test Base.IteratorEltype(product(f1)) == Base.HasEltype() # FIXME? eltype(f1) is Any @test Base.IteratorEltype(product(1:2, f1)) == Base.HasEltype() # FIXME? eltype(f1) is Any @test Base.IteratorEltype(product(f1, 1:2)) == Base.HasEltype() # FIXME? eltype(f1) is Any @test Base.IteratorEltype(product(f1, f1)) == Base.HasEltype() # FIXME? eltype(f1) is Any @test Base.IteratorEltype(product(f1, countfrom(1))) == Base.HasEltype() # FIXME? eltype(f1) is Any @test Base.IteratorEltype(product(countfrom(1), f1)) == Base.HasEltype() # FIXME? eltype(f1) is Any end @test Base.IteratorEltype(product(1:2, countfrom(1))) == Base.HasEltype() @test Base.IteratorEltype(product(countfrom(1), 1:2)) == Base.HasEltype() @test Base.IteratorEltype(product(1:2)) == Base.HasEltype() @test Base.IteratorEltype(product(1:2, 1:2)) == Base.HasEltype() @test Base.IteratorEltype(product(take(1:2, 1), take(1:2, 1))) == Base.HasEltype() @test Base.IteratorEltype(product(take(1:2, 2))) == Base.HasEltype() @test Base.IteratorEltype(product([1 2; 3 4])) == Base.HasEltype() @test Base.IteratorEltype(product()) == Base.HasEltype() @test collect(product(1:2,3:4)) == [(1,3) (1,4); (2,3) (2,4)] @test isempty(collect(product(1:0,1:2))) @test length(product(1:2,1:10,4:6)) == 60 @test Base.IteratorSize(product(1:2, countfrom(1))) == Base.IsInfinite() @test Base.iterate(product()) == ((), true) @test Base.iterate(product(), 1) == nothing # intersection @test intersect(product(1:3, 4:6), product(2:4, 3:5)) == Iterators.ProductIterator((2:3, 4:5)) @test intersect(product(1:3, [4 5 ; 6 7]), product(2:4, [7 6 ; 5 4])).iterators == (2:3, [4, 6, 5, 7]) # flatten # ------- @test collect(flatten(Any[1:2, 4:5])) == Any[1,2,4,5] @test collect(flatten(Any[flatten(Any[1:2, 6:5]), flatten(Any[10:7, 10:9])])) == Any[1,2] @test collect(flatten(Any[flatten(Any[1:2, 4:5]), flatten(Any[6:7, 8:9])])) == Any[1,2,4,5,6,7,8,9] @test collect(flatten(Any[flatten(Any[1:2, 6:5]), flatten(Any[6:7, 8:9])])) == Any[1,2,6,7,8,9] @test collect(flatten(Any[2:1])) == Any[] @test eltype(flatten(UnitRange{Int8}[1:2, 3:4])) == Int8 @test length(flatten(zip(1:3, 4:6))) == 6 @test length(flatten(1:6)) == 6 @test collect(flatten(Any[])) == Any[] @test collect(flatten(())) == Union{}[] @test_throws ArgumentError length(flatten(NTuple[(1,), ()])) # #16680 @test_throws ArgumentError length(flatten([[1], [1]])) @testset "IteratorSize trait for flatten" begin @test Base.IteratorSize(Base.Flatten((i for i=1:2) for j=1:1)) == Base.SizeUnknown() @test Base.IteratorSize(Base.Flatten((1,2))) == Base.HasLength() @test Base.IteratorSize(Base.Flatten(1:2:4)) == Base.HasLength() end @test Base.IteratorEltype(Base.Flatten((i for i=1:2) for j=1:1)) == Base.EltypeUnknown() # see #29112, #29464, #29548 @test Base.return_types(Base.IteratorEltype, Tuple{Array}) == [Base.HasEltype] # flatmap # ------- @test flatmap(1:3) do j flatmap(1:3) do k j!=k ? ((j,k),) : () end end |> collect == [(j,k) for j in 1:3 for k in 1:3 if j!=k] # Test inspired by the monad associativity law fmf(x) = x<0 ? () : (x^2,) fmg(x) = x<1 ? () : (x/2,) fmdata = -2:0.75:2 fmv1 = flatmap(tuple.(fmdata)) do h flatmap(h) do x gx = fmg(x) flatmap(gx) do x fmf(x) end end end fmv2 = flatmap(tuple.(fmdata)) do h gh = flatmap(h) do x fmg(x) end flatmap(gh) do x fmf(x) end end @test all(fmv1 .== fmv2) # partition(c, n) let v = collect(partition([1,2,3,4,5], 1)) @test all(i->v[i][1] == i, v) end let v1 = collect(partition([1,2,3,4,5], 2)), v2 = collect(partition(flatten([[1,2],[3,4],5]), 2)) # collecting partition with SizeUnknown @test v1[1] == v2[1] == [1,2] @test v1[2] == v2[2] == [3,4] @test v1[3] == v2[3] == [5] end let v = collect(partition([1,2,3,4,5], 2)) @test v[1] == [1,2] @test v[2] == [3,4] @test v[3] == [5] end let v = collect(partition(enumerate([1,2,3,4,5]), 3)) @test v[1] == [(1,1),(2,2),(3,3)] @test v[2] == [(4,4),(5,5)] end for n in [5,6] @test collect(partition([1,2,3,4,5], n))[1] == [1,2,3,4,5] @test collect(partition(enumerate([1,2,3,4,5]), n))[1] == [(1,1),(2,2),(3,3),(4,4),(5,5)] end function iterate_length(iter) n=0 for i in iter n += 1 end return n end function simd_iterate_length(iter) n=0 @simd for i in iter n += 1 end return n end function simd_trip_count(iter) return sum(Base.SimdLoop.simd_inner_length(iter, i) for i in Base.SimdLoop.simd_outer_range(iter)) end function iterate_elements(iter) vals = Vector{eltype(iter)}(undef, length(iter)) i = 1 for v in iter @inbounds vals[i] = v i += 1 end return vals end function simd_iterate_elements(iter) vals = Vector{eltype(iter)}(undef, length(iter)) i = 1 @simd for v in iter @inbounds vals[i] = v i += 1 end return vals end function index_elements(iter) vals = Vector{eltype(iter)}(undef, length(iter)) i = 1 for j in eachindex(iter) @inbounds vals[i] = iter[j] i += 1 end return vals end @testset "CartesianPartition optimizations" for dims in ((1,), (64,), (101,), (1,1), (8,8), (11, 13), (1,1,1), (8, 4, 2), (11, 13, 17)), part in (1, 7, 8, 11, 63, 64, 65, 142, 143, 144) for fun in (i -> 1:i, i -> 1:2:2i, i -> Base.IdentityUnitRange(-i:i)) iter = CartesianIndices(map(fun, dims)) P = partition(iter, part) for I in P @test length(I) == iterate_length(I) == simd_iterate_length(I) == simd_trip_count(I) @test collect(I) == iterate_elements(I) == simd_iterate_elements(I) == index_elements(I) end @test all(Base.splat(==), zip(Iterators.flatten(map(collect, P)), iter)) end end @testset "empty/invalid partitions" begin @test_throws ArgumentError partition(1:10, 0) @test_throws ArgumentError partition(1:10, -1) @test_throws ArgumentError partition(1:0, 0) @test_throws ArgumentError partition(1:0, -1) @test isempty(partition(1:0, 1)) @test isempty(partition(CartesianIndices((0,1)), 1)) end @testset "exact partition eltypes" for a in (Base.OneTo(24), 1:24, 1:1:24, LinRange(1,10,24), .1:.1:2.4, Vector(1:24), CartesianIndices((4, 6)), Dict((1:24) .=> (1:24))) P = partition(a, 2) @test eltype(P) === typeof(first(P)) @test Iterators.IteratorEltype(P) == Iterators.HasEltype() if a isa AbstractArray P = partition(vec(a), 2) @test eltype(P) === typeof(first(P)) P = partition(reshape(a, 6, 4), 2) @test eltype(P) === typeof(first(P)) P = partition(reshape(a, 2, 3, 4), 2) @test eltype(P) === typeof(first(P)) end end @test join(map(x->string(x...), partition("Hello World!", 5)), "|") == "Hello| Worl|d!" let s = "Monkey 🙈🙊🙊" tf = (n)->join(map(x->string(x...), partition(s,n)), "|") @test tf(10) == s @test tf(9) == "Monkey 🙈🙊|🙊" @test tf(8) == "Monkey 🙈|🙊🙊" @test tf(7) == "Monkey |🙈🙊🙊" @test tf(6) == "Monkey| 🙈🙊🙊" @test tf(5) == "Monke|y 🙈🙊🙊" @test tf(4) == "Monk|ey 🙈|🙊🙊" @test tf(3) == "Mon|key| 🙈🙊|🙊" @test tf(2) == "Mo|nk|ey| 🙈|🙊🙊" @test tf(1) == "M|o|n|k|e|y| |🙈|🙊|🙊" end @test Base.IteratorEltype(partition([1,2,3,4], 2)) == Base.HasEltype() @test Base.IteratorEltype(partition((2x for x in 1:3), 2)) == Base.EltypeUnknown() # take and friends with arbitrary integers (#19214) for T in (UInt8, UInt16, UInt32, UInt64, UInt128, Int8, Int16, Int128, BigInt) @test length(take(1:6, T(3))) == 3 @test length(drop(1:6, T(3))) == 3 @test length(repeated(1, T(5))) == 5 @test collect(partition(1:5, T(5)))[1] == 1:5 end @testset "collect finite iterators issue #12009" begin @test eltype(collect(enumerate(Iterators.Filter(x -> x>0, randn(10))))) == Tuple{Int, Float64} end @testset "product iterator infinite loop" begin @test collect(product(1:1, (1, "2"))) == [(1, 1) (1, "2")] end @testset "filter empty iterable #16704" begin arr = filter(Returns(true), 1:0) @test length(arr) == 0 @test eltype(arr) == Int end @testset "Pairs type" begin for A in ([4.0 5.0 6.0], [], (4.0, 5.0, 6.0), (a=4.0, b=5.0, c=6.0), (), NamedTuple(), (a=1.1, b=2.0), ) d = pairs(A) @test d === pairs(d) @test isempty(d) == isempty(A) @test length(d) == length(A) @test keys(d) == keys(A) @test values(d) == A @test Base.IteratorSize(d) == Base.IteratorSize(A) @test Base.IteratorEltype(d) == Base.HasEltype() @test Base.IteratorSize(pairs([1 2;3 4])) isa Base.HasShape{2} @test isempty(d) || haskey(d, first(keys(d))) @test collect(v for (k, v) in d) == collect(A) if A isa NamedTuple K = Symbol V = isempty(d) ? Union{} : Float64 @test isempty(d) || haskey(d, :a) @test !haskey(d, :abc) @test !haskey(d, 1) @test get(A, :key) do; 99; end == 99 elseif A isa Tuple K = Int V = isempty(d) ? Union{} : Float64 else K = A isa AbstractVector ? Int : CartesianIndex{2} V = isempty(d) ? Any : Float64 @test get(A, 4, "not found") === "not found" if !isempty(A) @test get(A, 2, "not found") === 5.0 @test getindex(d, 3) === 6.0 @test setindex!(d, 9, 3) === d @test A[3] === 9.0 end end @test keytype(d) == K @test valtype(d) == V @test eltype(d) == Pair{K, V} end let io = IOBuffer() Base.showarg(io, pairs([1,2,3]), true) @test String(take!(io)) == "pairs(::Vector{$Int})" Base.showarg(io, pairs((a=1, b=2)), true) @test String(take!(io)) == "pairs(::NamedTuple)" Base.showarg(io, pairs(IndexLinear(), zeros(3,3)), true) @test String(take!(io)) == "pairs(IndexLinear(), ::Matrix{Float64})" Base.showarg(io, pairs(IndexCartesian(), zeros(3)), true) @test String(take!(io)) == "pairs(IndexCartesian(), ::Vector{Float64})" end end @testset "reverse iterators" begin squash(x::Number) = x squash(A) = reshape(A, length(A)) Z = Array{Int,0}(undef); Z[] = 17 # zero-dimensional test case for itr in (2:10, "∀ϵ>0", 1:0, "", (2,3,5,7,11), [2,3,5,7,11], rand(5,6), Z, 3, true, 'x', 4=>5, eachindex("∀ϵ>0"), view(Z), view(rand(5,6),2:4,2:6), (x^2 for x in 1:10), Iterators.Filter(isodd, 1:10), flatten((1:10, 50:60)), enumerate("foo"), pairs(50:60), zip(1:10,21:30,51:60), product(1:3, 10:12), repeated(3.14159, 5), (a=2, b=3, c=5, d=7, e=11)) arr = reverse(squash(collect(itr))) itr = Iterators.reverse(itr) @test squash(collect(itr)) == arr if !isempty(arr) @test first(itr) == first(arr) @test last(itr) == last(arr) end end @test collect(take(Iterators.reverse(cycle(1:3)), 7)) == collect(take(cycle(3:-1:1), 7)) let r = repeated(3.14159) @test Iterators.reverse(r) === r @test last(r) === 3.14159 end for t in [(1,), (2, 3, 5, 7, 11), (a=1,), (a=2, b=3, c=5, d=7, e=11)] @test Iterators.reverse(Iterators.reverse(t)) === t @test first(Iterators.reverse(t)) === last(t) @test last(Iterators.reverse(t)) === first(t) @test collect(Iterators.reverse(t)) == reverse(collect(t)) end end @testset "Iterators.Stateful" begin let a = @inferred(Iterators.Stateful("abcdef")) @test !isempty(a) @test popfirst!(a) == 'a' @test collect(Iterators.take(a, 3)) == ['b','c','d'] @test collect(a) == ['e', 'f'] @test_throws EOFError popfirst!(a) # trying to pop from an empty stateful iterator. end let a = @inferred(Iterators.Stateful([1, 1, 1, 2, 3, 4])) for x in a; x == 1 || break; end @test peek(a) == 3 @test sum(a) == 7 end @test eltype(Iterators.Stateful("a")) == Char # Interaction of zip/Stateful let a = Iterators.Stateful("a"), b = "" @test isempty(collect(zip(a,b))) @test !isempty(a) @test isempty(collect(zip(b,a))) @test !isempty(a) end let a = Iterators.Stateful("a"), b = "", c = Iterators.Stateful("c") @test isempty(collect(zip(a,b,c))) @test !isempty(a) @test !isempty(c) @test isempty(collect(zip(a,c,b))) @test !isempty(a) @test !isempty(c) @test isempty(collect(zip(b,a,c))) @test !isempty(a) @test !isempty(c) @test isempty(collect(zip(b,c,a))) @test !isempty(a) @test !isempty(c) @test isempty(collect(zip(c,a,b))) @test !isempty(a) @test !isempty(c) @test isempty(collect(zip(c,b,a))) @test !isempty(a) @test !isempty(c) end let a = Iterators.Stateful("aa"), b = "b", c = Iterators.Stateful("cc") @test length(collect(zip(a,b,c))) == 1 @test !isempty(a) @test !isempty(c) end let a = Iterators.Stateful("aa"), b = "b", c = Iterators.Stateful("cc") @test length(collect(zip(a,c,b))) == 1 @test !isempty(a) @test !isempty(c) end let a = Iterators.Stateful("aa"), b = "b", c = Iterators.Stateful("cc") @test length(collect(zip(b,a,c))) == 1 @test !isempty(a) @test !isempty(c) end let a = Iterators.Stateful("aa"), b = "b", c = Iterators.Stateful("cc") @test length(collect(zip(b,c,a))) == 1 @test !isempty(a) @test !isempty(c) end let a = Iterators.Stateful("aa"), b = "b", c = Iterators.Stateful("cc") @test length(collect(zip(c,a,b))) == 1 @test !isempty(a) @test !isempty(c) end let a = Iterators.Stateful("aa"), b = "b", c = Iterators.Stateful("cc") @test length(collect(zip(c,b,a))) == 1 @test !isempty(a) @test !isempty(c) end let z = zip(Iterators.Stateful("ab"), Iterators.Stateful("b"), Iterators.Stateful("c")) v, s = iterate(z) @test Base.isdone(z, s) end # Stateful wrapping mutable iterators of known length (#43245) @test length(Iterators.Stateful(Iterators.Stateful(1:5))) == 5 end @testset "pair for Svec" begin ps = pairs(Core.svec(:a, :b)) @test ps isa Iterators.Pairs @test collect(ps) == [1 => :a, 2 => :b] end @testset "inference for large zip #26765" begin x = zip(1:2, ["a", "b"], (1.0, 2.0), Base.OneTo(2), Iterators.repeated("a"), 1.0:0.2:2.0, (1 for i in 1:2), Iterators.Stateful(["a", "b", "c"]), (1.0 for i in 1:2, j in 1:3)) @test @inferred(length(x)) == 2 z = Iterators.filter(x -> x[1] >= 1, x) @test @inferred(eltype(z)) <: Tuple{Int,String,Float64,Int,String,Float64,Any,String,Any} @test @inferred(first(z)) == (1, "a", 1.0, 1, "a", 1.0, 1, "a", 1.0) @test @inferred(first(Iterators.drop(z, 1))) == (2, "b", 2.0, 2, "a", 1.2, 1, "c", 1.0) end @testset "Stateful fix #30643" begin @test Base.IteratorSize(1:10) isa Base.HasShape a = Iterators.Stateful(1:10) @test Base.IteratorSize(a) isa Base.HasLength @test length(a) == 10 @test length(collect(a)) == 10 @test length(a) == 0 b = Iterators.Stateful(Iterators.take(1:10,3)) @test Base.IteratorSize(b) isa Base.HasLength @test length(b) == 3 @test length(collect(b)) == 3 @test length(b) == 0 c = Iterators.Stateful(Iterators.countfrom(1)) @test Base.IteratorSize(c) isa Base.IsInfinite @test length(Iterators.take(c,3)) == 3 @test length(collect(Iterators.take(c,3))) == 3 d = Iterators.Stateful(Iterators.filter(isodd,1:10)) @test Base.IteratorSize(d) isa Base.SizeUnknown @test length(collect(Iterators.take(d,3))) == 3 @test length(collect(d)) == 2 @test length(collect(d)) == 0 end @testset "only" begin @test only([3]) === 3 @test_throws ArgumentError only([]) @test_throws ArgumentError only([3, 2]) @test only(fill(42)) === 42 # zero dimensional array containing a single value. @test @inferred(only((3,))) === 3 @test_throws ArgumentError only(()) @test_throws ArgumentError only((3, 2)) @test only(Dict(1=>3)) === (1=>3) @test_throws ArgumentError only(Dict{Int,Int}()) @test_throws ArgumentError only(Dict(1=>3, 2=>2)) @test only(Set([3])) === 3 @test_throws ArgumentError only(Set(Int[])) @test_throws ArgumentError only(Set([3,2])) @test @inferred(only((;a=1))) === 1 @test_throws ArgumentError only(NamedTuple()) @test_throws ArgumentError only((a=3, b=2.0)) @test @inferred(only(1)) === 1 @test @inferred(only('a')) === 'a' @test @inferred(only(Ref([1, 2]))) == [1, 2] @test_throws ArgumentError only(Pair(10, 20)) @test only(1 for ii in 1:1) === 1 @test only(1 for ii in 1:10 if ii < 2) === 1 @test_throws ArgumentError only(1 for ii in 1:10) @test_throws ArgumentError only(1 for ii in 1:10 if ii > 2) @test_throws ArgumentError only(1 for ii in 1:10 if ii > 200) end @testset "flatten empty tuple" begin @test isempty(collect(Iterators.flatten(()))) end @testset "Iterators.accumulate" begin @test collect(Iterators.accumulate(+, [])) == [] @test collect(Iterators.accumulate(+, [1])) == [1] @test collect(Iterators.accumulate(+, [1,2])) == [1,3] @test collect(Iterators.accumulate(+, [1,2,3])) == [1,3,6] @test collect(Iterators.accumulate(=>, [:a,:b,:c])) == [:a, :a => :b, (:a => :b) => :c] @test collect(Iterators.accumulate(+, (x for x in [true])))::Vector{Int} == [1] @test collect(Iterators.accumulate(+, (x for x in [true, true, false])))::Vector{Int} == [1, 2, 2] @test collect(Iterators.accumulate(+, (x for x in [true]), init=10.0))::Vector{Float64} == [11.0] @test length(Iterators.accumulate(+, [10,20,30])) == 3 @test size(Iterators.accumulate(max, rand(2,3))) == (2,3) @test Base.IteratorSize(Iterators.accumulate(max, rand(2,3))) === Base.IteratorSize(rand(2,3)) @test Base.IteratorEltype(Iterators.accumulate(*, ())) isa Base.EltypeUnknown end @testset "Base.accumulate" begin @test cumsum(x^2 for x in 1:3) == [1, 5, 14] @test cumprod(x + 1 for x in 1:3) == [2, 6, 24] @test accumulate(+, (x^2 for x in 1:3); init=100) == [101, 105, 114] end @testset "Iterators.tail_if_any" begin @test Iterators.tail_if_any(()) == () @test Iterators.tail_if_any((1, 2)) == (2,) @test Iterators.tail_if_any((1,)) == () end @testset "IteratorSize trait for zip" begin @test Base.IteratorSize(zip()) == Base.IsInfinite() # for zip of empty tuple @test Base.IteratorSize(zip((1,2,3), repeated(0))) == Base.HasLength() # for zip of ::HasLength and ::IsInfinite @test Base.IteratorSize(zip( 1:5, repeated(0) )) == Base.HasLength() # for zip of ::HasShape and ::IsInfinite @test Base.IteratorSize(zip(repeated(0), (1,2,3))) == Base.HasLength() # for zip of ::IsInfinite and ::HasLength @test Base.IteratorSize(zip(repeated(0), 1:5 )) == Base.HasLength() # for zip of ::IsInfinite and ::HasShape @test Base.IteratorSize(zip((1,2,3), 1:5) ) == Base.HasLength() # for zip of ::HasLength and ::HasShape @test Base.IteratorSize(zip(1:5, (1,2,3)) ) == Base.HasLength() # for zip of ::HasShape and ::HasLength end @testset "proper partition for non-1-indexed vector" begin @test partition(IdentityUnitRange(11:19), 5) |> collect == [11:15,16:19] # IdentityUnitRange end @testset "Iterators.peel" begin @test Iterators.peel([]) == nothing @test Iterators.peel(1:10)[1] == 1 @test Iterators.peel(1:10)[2] |> collect == 2:10 @test Iterators.peel(x^2 for x in 2:4)[1] == 4 @test Iterators.peel(x^2 for x in 2:4)[2] |> collect == [9, 16] end @testset "last for iterators" begin @test last(Iterators.map(identity, 1:3)) == 3 @test last(Iterators.filter(iseven, (Iterators.map(identity, 1:3)))) == 2 end @testset "isempty and isdone for Generators" begin itr = eachline(IOBuffer("foo\n")) gen = (x for x in itr) @test !isempty(gen) @test !Base.isdone(gen) @test collect(gen) == ["foo"] end @testset "empty product iterators" begin v = nothing for (z,) in zip(Iterators.product()) v = z end @test v == () end @testset "collect partition substring" begin @test collect(Iterators.partition(lstrip("01111", '0'), 2)) == ["11", "11"] end @testset "no single-argument map methods" begin maps = (tuple, Returns(nothing), (() -> nothing)) mappers = (Iterators.map, map, foreach) for f ∈ maps, m ∈ mappers @test !applicable(m, f) @test !hasmethod(m, Tuple{typeof(f)}) end end @testset "Iterators docstrings" begin @test isempty(Docs.undocumented_names(Iterators)) end