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hashing2.jl
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# This file is a part of Julia. License is MIT: https://julialang.org/license
## efficient value-based hashing of integers ##
function hash_integer(n::Integer, h::UInt)
h ⊻= hash_uint((n % UInt) ⊻ h)
n = abs(n)
n >>>= sizeof(UInt) << 3
while n != 0
h ⊻= hash_uint((n % UInt) ⊻ h)
n >>>= sizeof(UInt) << 3
end
return h
end
function hash_integer(n::BigInt, h::UInt)
s = n.size
s == 0 && return hash_integer(0, h)
p = convert(Ptr{UInt}, n.d)
b = unsafe_load(p)
h ⊻= hash_uint(ifelse(s < 0, -b, b) ⊻ h)
for k = 2:abs(s)
h ⊻= hash_uint(unsafe_load(p, k) ⊻ h)
end
return h
end
## generic hashing for rational values ##
function hash(x::Real, h::UInt)
# decompose x as num*2^pow/den
num, pow, den = decompose(x)
# handle special values
num == 0 && den == 0 && return hash(NaN, h)
num == 0 && return hash(ifelse(den > 0, 0.0, -0.0), h)
den == 0 && return hash(ifelse(num > 0, Inf, -Inf), h)
# normalize decomposition
if den < 0
num = -num
den = -den
end
z = trailing_zeros(num)
if z != 0
num >>= z
pow += z
end
z = trailing_zeros(den)
if z != 0
den >>= z
pow -= z
end
# handle values representable as Int64, UInt64, Float64
if den == 1
left = ndigits0z(num,2) + pow
right = trailing_zeros(num) + pow
if -1074 <= right
if 0 <= right && left <= 64
left <= 63 && return hash(Int64(num) << Int(pow), h)
signbit(num) == signbit(den) && return hash(UInt64(num) << Int(pow), h)
end # typemin(Int64) handled by Float64 case
left <= 1024 && left - right <= 53 && return hash(ldexp(Float64(num),pow), h)
end
end
# handle generic rational values
h = hash_integer(den, h)
h = hash_integer(pow, h)
h = hash_integer(num, h)
return h
end
#=
`decompose(x)`: non-canonical decomposition of rational values as `num*2^pow/den`.
The decompose function is the point where rational-valued numeric types that support
hashing hook into the hashing protocol. `decompose(x)` should return three integer
values `num, pow, den`, such that the value of `x` is mathematically equal to
num*2^pow/den
The decomposition need not be canonical in the sense that it just needs to be *some*
way to express `x` in this form, not any particular way – with the restriction that
`num` and `den` may not share any odd common factors. They may, however, have powers
of two in common – the generic hashing code will normalize those as necessary.
Special values:
- `x` is zero: `num` should be zero and `den` should have the same sign as `x`
- `x` is infinite: `den` should be zero and `num` should have the same sign as `x`
- `x` is not a number: `num` and `den` should both be zero
=#
decompose(x::Integer) = x, 0, 1
decompose(x::Rational) = numerator(x), 0, denominator(x)
function decompose(x::Float16)::NTuple{3,Int}
isnan(x) && return 0, 0, 0
isinf(x) && return ifelse(x < 0, -1, 1), 0, 0
n = reinterpret(UInt16, x)
s = (n & 0x03ff) % Int16
e = (n & 0x7c00 >> 10) % Int
s |= Int16(e != 0) << 10
d = ifelse(signbit(x), -1, 1)
s, e - 25 + (e == 0), d
end
function decompose(x::Float32)::NTuple{3,Int}
isnan(x) && return 0, 0, 0
isinf(x) && return ifelse(x < 0, -1, 1), 0, 0
n = reinterpret(UInt32, x)
s = (n & 0x007fffff) % Int32
e = (n & 0x7f800000 >> 23) % Int
s |= Int32(e != 0) << 23
d = ifelse(signbit(x), -1, 1)
s, e - 150 + (e == 0), d
end
function decompose(x::Float64)::Tuple{Int64, Int, Int}
isnan(x) && return 0, 0, 0
isinf(x) && return ifelse(x < 0, -1, 1), 0, 0
n = reinterpret(UInt64, x)
s = (n & 0x000fffffffffffff) % Int64
e = (n & 0x7ff0000000000000 >> 52) % Int
s |= Int64(e != 0) << 52
d = ifelse(signbit(x), -1, 1)
s, e - 1075 + (e == 0), d
end
function decompose(x::BigFloat)::Tuple{BigInt, Int, Int}
isnan(x) && return 0, 0, 0
isinf(x) && return x.sign, 0, 0
x == 0 && return 0, 0, x.sign
s = BigInt()
s.size = cld(x.prec, 8*sizeof(GMP.Limb)) # limbs
b = s.size * sizeof(GMP.Limb) # bytes
ccall((:__gmpz_realloc2, :libgmp), Cvoid, (Ref{BigInt}, Culong), s, 8b) # bits
ccall(:memcpy, Ptr{Cvoid}, (Ptr{Cvoid}, Ptr{Cvoid}, Csize_t), s.d, x.d, b) # bytes
s, x.exp - 8b, x.sign
end
## streamlined hashing for smallish rational types ##
function hash(x::Rational{<:BitInteger64}, h::UInt)
num, den = Base.numerator(x), Base.denominator(x)
den == 1 && return hash(num, h)
den == 0 && return hash(ifelse(num > 0, Inf, -Inf), h)
if isodd(den)
pow = trailing_zeros(num)
num >>= pow
else
pow = trailing_zeros(den)
den >>= pow
pow = -pow
if den == 1 && abs(num) < 9007199254740992
return hash(ldexp(Float64(num),pow),h)
end
end
h = hash_integer(den, h)
h = hash_integer(pow, h)
h = hash_integer(num, h)
return h
end
## hashing Float16s ##
hash(x::Float16, h::UInt) = hash(Float64(x), h)
## hashing strings ##
const memhash = UInt === UInt64 ? :memhash_seed : :memhash32_seed
const memhash_seed = UInt === UInt64 ? 0x71e729fd56419c81 : 0x56419c81
function hash(s::Union{String,SubString{String}}, h::UInt)
h += memhash_seed
# note: use pointer(s) here (see #6058).
ccall(memhash, UInt, (Ptr{UInt8}, Csize_t, UInt32), pointer(s), sizeof(s), h % UInt32) + h
end
hash(s::AbstractString, h::UInt) = hash(String(s), h)