Revision 4954af9c5ee5bb1b5b9172ddbcbac03ca6e151ea authored by Keno Fischer on 01 September 2023, 19:52:14 UTC, committed by GitHub on 01 September 2023, 19:52:14 UTC
The change in #50429 moves around some dispatch boundaries and pushes the allocations in the offsetarrays `maximum!` test over the limit. The implementation of that code is massively type unstable. Somewhat, ironically, the whole original point of that test was to test that the implementation was not type-unstable (#28941), so actually opt our OffsetArrays implementation into the interface that's supposed to guarantee that. If this PR is fine here, I'll submit the same upstream to avoid diverging the implementations too much. Co-authored-by: Jameson Nash <vtjnash@gmail.com>
1 parent a173010
float16.jl
# This file is a part of Julia. License is MIT: https://julialang.org/license
using Test
f = Float16(2.)
g = Float16(1.)
@testset "comparisons" begin
@test f >= g
@test f > g
@test g < f
@test g <= g
@test all([g g] .< [f f])
@test all([g g] .<= [f f])
@test all([f f] .> [g g])
@test all([f f] .>= [g g])
@test isless(g, f)
@test !isless(f, g)
@test Float16(2.5) == Float16(2.5)
@test Float16(2.5) != Float16(2.6)
@test isequal(Float16(0.0), Float16(0.0))
@test !isequal(Float16(-0.0), Float16(0.0))
@test !isequal(Float16(0.0), Float16(-0.0))
for T = Base.BitInteger_types
@test -Inf16 < typemin(T)
@test -Inf16 <= typemin(T)
@test typemin(T) > -Inf16
@test typemin(T) >= -Inf16
@test typemin(T) != -Inf16
@test Inf16 > typemax(T)
@test Inf16 >= typemax(T)
@test typemax(T) < Inf16
@test typemax(T) <= Inf16
@test typemax(T) != Inf16
end
end
@testset "convert" begin
@test convert(Bool,Float16(0.0)) == false
@test convert(Bool,Float16(1.0)) == true
@test_throws InexactError convert(Bool,Float16(0.1))
@test convert(Int128,Float16(-2.0)) == Int128(-2)
@test convert(UInt128,Float16(2.0)) == UInt128(2)
# convert(::Type{Int128}, x::Float16)
@test convert(Int128, Float16(1.0)) === Int128(1.0)
@test convert(Int128, Float16(-1.0)) === Int128(-1.0)
@test_throws InexactError convert(Int128, Float16(3.5))
# convert(::Type{UInt128}, x::Float16)
@test convert(UInt128, Float16(1.0)) === UInt128(1.0)
@test_throws InexactError convert(UInt128, Float16(3.5))
@test_throws InexactError convert(UInt128, Float16(-1))
@test convert(Int128,Float16(-1.0)) == Int128(-1)
@test convert(UInt128,Float16(5.0)) == UInt128(5)
end
@testset "round, trunc, float, ceil" begin
@test round(Int,Float16(0.5f0)) == round(Int,0.5f0)
@test trunc(Int,Float16(0.9f0)) === trunc(Int,0.9f0) === 0
@test floor(Int,Float16(0.9f0)) === floor(Int,0.9f0) === 0
@test trunc(Int,Float16(1)) === 1
@test floor(Int,Float16(1)) === 1
@test ceil(Int,Float16(0.1f0)) === ceil(Int,0.1f0) === 1
@test ceil(Int,Float16(0)) === ceil(Int,0) === 0
@test round(Float16(0.1f0)) == round(0.1f0) == 0
@test round(Float16(0.9f0)) == round(0.9f0) == 1
@test trunc(Float16(0.9f0)) == trunc(0.9f0) == 0
@test floor(Float16(0.9f0)) == floor(0.9f0) == 0
@test trunc(Float16(1)) === Float16(1)
@test floor(Float16(1)) === Float16(1)
@test ceil(Float16(0.1)) == ceil(0.1)
@test ceil(Float16(0.9)) == ceil(0.9)
@test unsafe_trunc(UInt8, Float16(3)) === 0x03
@test unsafe_trunc(Int16, Float16(3)) === Int16(3)
@test unsafe_trunc(UInt128, Float16(3)) === UInt128(3)
@test unsafe_trunc(Int128, Float16(3)) === Int128(3)
@test unsafe_trunc(Int16, NaN16) === Int16(0) #18771
end
@testset "fma and muladd" begin
@test fma(Float16(0.1),Float16(0.9),Float16(0.5)) ≈ fma(0.1,0.9,0.5)
@test muladd(Float16(0.1),Float16(0.9),Float16(0.5)) ≈ muladd(0.1,0.9,0.5)
end
@testset "unary ops" begin
@test -f === Float16(-2.)
@test Float16(0.5f0)^2 ≈ Float16(0.5f0^2)
@test sin(f) ≈ sin(2f0)
@test log10(Float16(100)) == Float16(2.0)
@test sin(ComplexF16(f)) ≈ sin(complex(2f0))
# no domain error is thrown for negative values
@test cbrt(Float16(-1.0)) == -1.0
# test zero and Inf
@test cbrt(Float16(0.0)) == Float16(0.0)
@test cbrt(Inf16) == Inf16
end
@testset "binary ops" begin
@test f+g === Float16(3f0)
@test f-g === Float16(1f0)
@test f*g === Float16(2f0)
@test f/g === Float16(2f0)
@test f^g === Float16(2f0)
@test f^1 === Float16(2f0)
@test f^-g === Float16(0.5f0)
@test f + 2 === Float16(4f0)
@test f - 2 === Float16(0f0)
@test f*2 === Float16(4f0)
@test f/2 === Float16(1f0)
@test f + 2. === 4.
@test f - 2. === 0.
@test f*2. === 4.
@test f/2. === 1.
end
@testset "NaN16 and Inf16" begin
@test isnan(NaN16)
@test isnan(-NaN16)
@test !isnan(Inf16)
@test !isnan(-Inf16)
@test !isnan(Float16(2.6))
@test NaN16 != NaN16
@test isequal(NaN16, NaN16)
@test repr(NaN16) == "NaN16"
@test sprint(show, NaN16, context=:compact => true) == "NaN"
@test isinf(Inf16)
@test isinf(-Inf16)
@test !isinf(NaN16)
@test !isinf(-NaN16)
@test !isinf(Float16(2.6))
@test Inf16 == Inf16
@test Inf16 != -Inf16
@test -Inf16 < Inf16
@test isequal(Inf16, Inf16)
@test repr(Inf16) == "Inf16"
@test sprint(show, Inf16, context=:compact => true) == "Inf"
@test isnan(reinterpret(Float16,0x7c01))
@test !isinf(reinterpret(Float16,0x7c01))
@test nextfloat(Inf16) === Inf16
@test prevfloat(-Inf16) === -Inf16
end
@test repr(Float16(44099)) == "Float16(4.41e4)"
@testset "signed zeros" begin
for z1 in (Float16(0.0), Float16(-0.0)), z2 in (Float16(0.0), Float16(-0.0))
@test z1 == z2
@test isequal(z1, z1)
@test z1 === z1
for elty in (Float32, Float64)
z3 = convert(elty, z2)
@test z1==z3
end
end
end
@testset "rounding in conversions" begin
for f32 in [.3325f0, -.3325f0]
f16 = Float16(f32)
# need to round away from 0. make sure we picked closest number.
@test abs(f32 - f16) < abs(f32 - nextfloat(f16))
@test abs(f32 - f16) < abs(f32 - prevfloat(f16))
end
# halfway between and last bit is 1
ff = reinterpret(Float32, 0b00111110101010100011000000000000)
@test Float32(Float16(ff)) === reinterpret(Float32, 0b00111110101010100100000000000000)
# halfway between and last bit is 0
ff = reinterpret(Float32, 0b00111110101010100001000000000000)
@test Float32(Float16(ff)) === reinterpret(Float32, 0b00111110101010100000000000000000)
for x = (typemin(Int64), typemin(Int128)), R = (RoundUp, RoundToZero)
@test Float16(x, R) == nextfloat(-Inf16)
end
end
# issue #5948
@test string(reinterpret(Float16, 0x7bff)) == "6.55e4"
# #9939 (and #9897)
@test rationalize(Float16(0.1)) == 1//10
# issue #17148
@test rem(Float16(1.2), Float16(one(1.2))) == 0.20019531f0
# issue #32441
const f16eps2 = Float32(eps(Float16(0.0)))/2
const minsubf16 = nextfloat(Float16(0.0))
const minsubf16_32 = Float32(minsubf16)
@test Float16(f16eps2) == Float16(0.0)
@test Float16(nextfloat(f16eps2)) == minsubf16
@test Float16(prevfloat(minsubf16_32)) == minsubf16
# Ties to even, in this case up
@test Float16(minsubf16_32 + f16eps2) == nextfloat(minsubf16)
@test Float16(prevfloat(minsubf16_32 + f16eps2)) == minsubf16
# issues #33076
@test Float16(1f5) == Inf16
@testset "conversion to Float16 from" begin
for T in (Float32, Float64, BigFloat)
@testset "conversion from $T" begin
for i in 1:2^16
f = reinterpret(Float16, UInt16(i-1))
isfinite(f) || continue
if f < 0
epsdown = T(eps(f))/2
epsup = issubnormal(f) ? epsdown : T(eps(nextfloat(f)))/2
else
epsup = T(eps(f))/2
epsdown = issubnormal(f) ? epsup : T(eps(prevfloat(f)))/2
end
@test isequal(f*(-1)^(f === Float16(0)), Float16(nextfloat(T(f) - epsdown)))
@test isequal(f*(-1)^(f === -Float16(0)), Float16(prevfloat(T(f) + epsup)))
@test isequal(prevfloat(f), Float16(prevfloat(T(f) - epsdown)))
@test isequal(nextfloat(f), Float16(nextfloat(T(f) + epsup)))
end
end
end
end
Computing file changes ...
