https://github.com/JuliaLang/julia
Tip revision: f6034b8e3b70d346991f0907c086aa5884af8d07 authored by Tim Holy on 04 February 2019, 15:27:22 UTC
Introduce testset in test/offsetarray.jl
Introduce testset in test/offsetarray.jl
Tip revision: f6034b8
promotion.jl
# This file is a part of Julia. License is MIT: https://julialang.org/license
## type join (closest common ancestor, or least upper bound) ##
"""
typejoin(T, S)
Return the closest common ancestor of `T` and `S`, i.e. the narrowest type from which
they both inherit.
"""
typejoin() = (@_pure_meta; Bottom)
typejoin(@nospecialize(t)) = (@_pure_meta; t)
typejoin(@nospecialize(t), ts...) = (@_pure_meta; typejoin(t, typejoin(ts...)))
function typejoin(@nospecialize(a), @nospecialize(b))
@_pure_meta
if isa(a, TypeVar)
return typejoin(a.ub, b)
elseif isa(b, TypeVar)
return typejoin(a, b.ub)
elseif a <: b
return b
elseif b <: a
return a
elseif isa(a, UnionAll)
return UnionAll(a.var, typejoin(a.body, b))
elseif isa(b, UnionAll)
return UnionAll(b.var, typejoin(a, b.body))
elseif isa(a, Union)
return typejoin(typejoin(a.a, a.b), b)
elseif isa(b, Union)
return typejoin(a, typejoin(b.a, b.b))
elseif a <: Tuple
if !(b <: Tuple)
return Any
end
ap, bp = a.parameters, b.parameters
lar = length(ap)::Int
lbr = length(bp)::Int
if lar == 0
return Tuple{Vararg{tailjoin(bp, 1)}}
end
if lbr == 0
return Tuple{Vararg{tailjoin(ap, 1)}}
end
laf, afixed = full_va_len(ap)
lbf, bfixed = full_va_len(bp)
if laf < lbf
if isvarargtype(ap[lar]) && !afixed
c = Vector{Any}(undef, laf)
c[laf] = Vararg{typejoin(unwrapva(ap[lar]), tailjoin(bp, laf))}
n = laf-1
else
c = Vector{Any}(undef, laf+1)
c[laf+1] = Vararg{tailjoin(bp, laf+1)}
n = laf
end
elseif lbf < laf
if isvarargtype(bp[lbr]) && !bfixed
c = Vector{Any}(undef, lbf)
c[lbf] = Vararg{typejoin(unwrapva(bp[lbr]), tailjoin(ap, lbf))}
n = lbf-1
else
c = Vector{Any}(undef, lbf+1)
c[lbf+1] = Vararg{tailjoin(ap, lbf+1)}
n = lbf
end
else
c = Vector{Any}(undef, laf)
n = laf
end
for i = 1:n
ai = ap[min(i,lar)]; bi = bp[min(i,lbr)]
ci = typejoin(unwrapva(ai), unwrapva(bi))
c[i] = i == length(c) && (isvarargtype(ai) || isvarargtype(bi)) ? Vararg{ci} : ci
end
return Tuple{c...}
elseif b <: Tuple
return Any
end
while b !== Any
if a <: b.name.wrapper
while a.name !== b.name
a = supertype(a)
end
if a.name === Type.body.name
ap = a.parameters[1]
bp = b.parameters[1]
if ((isa(ap,TypeVar) && ap.lb === Bottom && ap.ub === Any) ||
(isa(bp,TypeVar) && bp.lb === Bottom && bp.ub === Any))
# handle special Type{T} supertype
return Type
end
end
aprimary = a.name.wrapper
# join on parameters
n = length(a.parameters)
if n == 0
return aprimary
end
vars = []
for i = 1:n
ai, bi = a.parameters[i], b.parameters[i]
if ai === bi || (isa(ai,Type) && isa(bi,Type) && ai <: bi && bi <: ai)
aprimary = aprimary{ai}
else
pushfirst!(vars, aprimary.var)
aprimary = aprimary.body
end
end
for v in vars
aprimary = UnionAll(v, aprimary)
end
return aprimary
end
b = supertype(b)
end
return Any
end
"""
promote_typejoin(T, S)
Compute a type that contains both `T` and `S`, which could be
either a parent of both types, or a `Union` if appropriate.
Falls back to [`typejoin`](@ref).
"""
promote_typejoin(@nospecialize(a), @nospecialize(b)) = _promote_typejoin(a, b)::Type
_promote_typejoin(@nospecialize(a), @nospecialize(b)) = typejoin(a, b)
_promote_typejoin(::Type{Nothing}, ::Type{T}) where {T} =
isconcretetype(T) || T === Union{} ? Union{T, Nothing} : Any
_promote_typejoin(::Type{T}, ::Type{Nothing}) where {T} =
isconcretetype(T) || T === Union{} ? Union{T, Nothing} : Any
_promote_typejoin(::Type{Missing}, ::Type{T}) where {T} =
isconcretetype(T) || T === Union{} ? Union{T, Missing} : Any
_promote_typejoin(::Type{T}, ::Type{Missing}) where {T} =
isconcretetype(T) || T === Union{} ? Union{T, Missing} : Any
_promote_typejoin(::Type{Nothing}, ::Type{Missing}) = Union{Nothing, Missing}
_promote_typejoin(::Type{Missing}, ::Type{Nothing}) = Union{Nothing, Missing}
_promote_typejoin(::Type{Nothing}, ::Type{Nothing}) = Nothing
_promote_typejoin(::Type{Missing}, ::Type{Missing}) = Missing
# Returns length, isfixed
function full_va_len(p)
isempty(p) && return 0, true
last = p[end]
if isvarargtype(last)
N = unwrap_unionall(last).parameters[2]
if isa(N, Integer)
return (length(p) + N - 1)::Int, true
end
return length(p)::Int, false
end
return length(p)::Int, true
end
# reduce typejoin over A[i:end]
function tailjoin(A, i)
if i > length(A)
return unwrapva(A[end])
end
t = Bottom
for j = i:length(A)
t = typejoin(t, unwrapva(A[j]))
end
return t
end
## promotion mechanism ##
"""
promote_type(type1, type2)
Promotion refers to converting values of mixed types to a single common type.
`promote_type` represents the default promotion behavior in Julia when
operators (usually mathematical) are given arguments of differing types.
`promote_type` generally tries to return a type which can at least approximate
most values of either input type without excessively widening. Some loss is
tolerated; for example, `promote_type(Int64, Float64)` returns
[`Float64`](@ref) even though strictly, not all [`Int64`](@ref) values can be
represented exactly as `Float64` values.
```jldoctest
julia> promote_type(Int64, Float64)
Float64
julia> promote_type(Int32, Int64)
Int64
julia> promote_type(Float32, BigInt)
BigFloat
julia> promote_type(Int16, Float16)
Float16
julia> promote_type(Int64, Float16)
Float16
julia> promote_type(Int8, UInt16)
UInt16
```
"""
function promote_type end
promote_type() = Bottom
promote_type(T) = T
promote_type(T, S, U, V...) = (@_inline_meta; promote_type(T, promote_type(S, U, V...)))
promote_type(::Type{Bottom}, ::Type{Bottom}) = Bottom
promote_type(::Type{T}, ::Type{T}) where {T} = T
promote_type(::Type{T}, ::Type{Bottom}) where {T} = T
promote_type(::Type{Bottom}, ::Type{T}) where {T} = T
function promote_type(::Type{T}, ::Type{S}) where {T,S}
@_inline_meta
# Try promote_rule in both orders. Typically only one is defined,
# and there is a fallback returning Bottom below, so the common case is
# promote_type(T, S) =>
# promote_result(T, S, result, Bottom) =>
# typejoin(result, Bottom) => result
promote_result(T, S, promote_rule(T,S), promote_rule(S,T))
end
"""
promote_rule(type1, type2)
Specifies what type should be used by [`promote`](@ref) when given values of types `type1` and
`type2`. This function should not be called directly, but should have definitions added to
it for new types as appropriate.
"""
function promote_rule end
promote_rule(::Type{<:Any}, ::Type{<:Any}) = Bottom
# To fix ambiguities
promote_rule(::Type{Any}, ::Type{<:Any}) = Any
promote_rule(::Type{<:Any}, ::Type{Any}) = Any
promote_rule(::Type{Any}, ::Type{Any}) = Any
promote_result(::Type{<:Any},::Type{<:Any},::Type{T},::Type{S}) where {T,S} = (@_inline_meta; promote_type(T,S))
# If no promote_rule is defined, both directions give Bottom. In that
# case use typejoin on the original types instead.
promote_result(::Type{T},::Type{S},::Type{Bottom},::Type{Bottom}) where {T,S} = (@_inline_meta; typejoin(T, S))
"""
promote(xs...)
Convert all arguments to a common type, and return them all (as a tuple).
If no arguments can be converted, an error is raised.
# Examples
```jldoctest
julia> promote(Int8(1), Float16(4.5), Float32(4.1))
(1.0f0, 4.5f0, 4.1f0)
```
"""
function promote end
function _promote(x::T, y::S) where {T,S}
@_inline_meta
R = promote_type(T, S)
return (convert(R, x), convert(R, y))
end
promote_typeof(x) = typeof(x)
promote_typeof(x, xs...) = (@_inline_meta; promote_type(typeof(x), promote_typeof(xs...)))
function _promote(x, y, z)
@_inline_meta
R = promote_typeof(x, y, z)
return (convert(R, x), convert(R, y), convert(R, z))
end
function _promote(x, y, zs...)
@_inline_meta
R = promote_typeof(x, y, zs...)
return (convert(R, x), convert(R, y), convert(Tuple{Vararg{R}}, zs)...)
end
# TODO: promote(x::T, ys::T...) where {T} here to catch all circularities?
## promotions in arithmetic, etc. ##
promote() = ()
promote(x) = (x,)
function promote(x, y)
@_inline_meta
px, py = _promote(x, y)
not_sametype((x,y), (px,py))
px, py
end
function promote(x, y, z)
@_inline_meta
px, py, pz = _promote(x, y, z)
not_sametype((x,y,z), (px,py,pz))
px, py, pz
end
function promote(x, y, z, a...)
p = _promote(x, y, z, a...)
not_sametype((x, y, z, a...), p)
p
end
promote(x::T, y::T, zs::T...) where {T} = (x, y, zs...)
not_sametype(x::T, y::T) where {T} = sametype_error(x)
not_sametype(x, y) = nothing
function sametype_error(input)
@_noinline_meta
error("promotion of types ",
join(map(x->string(typeof(x)), input), ", ", " and "),
" failed to change any arguments")
end
+(x::Number, y::Number) = +(promote(x,y)...)
*(x::Number, y::Number) = *(promote(x,y)...)
-(x::Number, y::Number) = -(promote(x,y)...)
/(x::Number, y::Number) = /(promote(x,y)...)
"""
^(x, y)
Exponentiation operator. If `x` is a matrix, computes matrix exponentiation.
If `y` is an `Int` literal (e.g. `2` in `x^2` or `-3` in `x^-3`), the Julia code
`x^y` is transformed by the compiler to `Base.literal_pow(^, x, Val(y))`, to
enable compile-time specialization on the value of the exponent.
(As a default fallback we have `Base.literal_pow(^, x, Val(y)) = ^(x,y)`,
where usually `^ == Base.^` unless `^` has been defined in the calling
namespace.)
```jldoctest
julia> 3^5
243
julia> A = [1 2; 3 4]
2×2 Array{Int64,2}:
1 2
3 4
julia> A^3
2×2 Array{Int64,2}:
37 54
81 118
```
"""
^(x::Number, y::Number) = ^(promote(x,y)...)
fma(x::Number, y::Number, z::Number) = fma(promote(x,y,z)...)
muladd(x::Number, y::Number, z::Number) = muladd(promote(x,y,z)...)
==(x::Number, y::Number) = (==)(promote(x,y)...)
<( x::Real, y::Real) = (< )(promote(x,y)...)
<=(x::Real, y::Real) = (<=)(promote(x,y)...)
div(x::Real, y::Real) = div(promote(x,y)...)
fld(x::Real, y::Real) = fld(promote(x,y)...)
cld(x::Real, y::Real) = cld(promote(x,y)...)
rem(x::Real, y::Real) = rem(promote(x,y)...)
mod(x::Real, y::Real) = mod(promote(x,y)...)
mod1(x::Real, y::Real) = mod1(promote(x,y)...)
fld1(x::Real, y::Real) = fld1(promote(x,y)...)
max(x::Real, y::Real) = max(promote(x,y)...)
min(x::Real, y::Real) = min(promote(x,y)...)
minmax(x::Real, y::Real) = minmax(promote(x, y)...)
if isdefined(Core, :Compiler)
const _return_type = Core.Compiler.return_type
else
_return_type(@nospecialize(f), @nospecialize(t)) = Any
end
"""
promote_op(f, argtypes...)
Guess what an appropriate container eltype would be for storing results of
`f(::argtypes...)`. The guess is in part based on type inference, so can change any time.
!!! warning
Due to its fragility, use of `promote_op` should be avoided. It is preferable to base
the container eltype on the type of the actual elements. Only in the absence of any
elements (for an empty result container), it may be unavoidable to call `promote_op`.
"""
promote_op(f, S::Type...) = _return_type(f, Tuple{S...})
## catch-alls to prevent infinite recursion when definitions are missing ##
no_op_err(name, T) = error(name," not defined for ",T)
(+)(x::T, y::T) where {T<:Number} = no_op_err("+", T)
(*)(x::T, y::T) where {T<:Number} = no_op_err("*", T)
(-)(x::T, y::T) where {T<:Number} = no_op_err("-", T)
(/)(x::T, y::T) where {T<:Number} = no_op_err("/", T)
(^)(x::T, y::T) where {T<:Number} = no_op_err("^", T)
fma(x::T, y::T, z::T) where {T<:Number} = no_op_err("fma", T)
fma(x::Integer, y::Integer, z::Integer) = x*y+z
muladd(x::T, y::T, z::T) where {T<:Number} = x*y+z
(&)(x::T, y::T) where {T<:Integer} = no_op_err("&", T)
(|)(x::T, y::T) where {T<:Integer} = no_op_err("|", T)
xor(x::T, y::T) where {T<:Integer} = no_op_err("xor", T)
(==)(x::T, y::T) where {T<:Number} = x === y
(< )(x::T, y::T) where {T<:Real} = no_op_err("<" , T)
(<=)(x::T, y::T) where {T<:Real} = no_op_err("<=", T)
rem(x::T, y::T) where {T<:Real} = no_op_err("rem", T)
mod(x::T, y::T) where {T<:Real} = no_op_err("mod", T)
min(x::Real) = x
max(x::Real) = x
minmax(x::Real) = (x, x)
max(x::T, y::T) where {T<:Real} = ifelse(y < x, x, y)
min(x::T, y::T) where {T<:Real} = ifelse(y < x, y, x)
minmax(x::T, y::T) where {T<:Real} = y < x ? (y, x) : (x, y)
flipsign(x::T, y::T) where {T<:Signed} = no_op_err("flipsign", T)