https://github.com/JuliaLang/julia
Tip revision: a8be1cc253f334cf2266b8feda9ccbb73b2d1c79 authored by Gabriel Baraldi on 01 April 2024, 20:44:59 UTC
Change test so the output isn't hidden
Change test so the output isn't hidden
Tip revision: a8be1cc
mpfr.jl
# This file is a part of Julia. License is MIT: https://julialang.org/license
module MPFR
export
BigFloat,
setprecision
import
.Base: *, +, -, /, <, <=, ==, >, >=, ^, ceil, cmp, convert, copysign, div,
inv, exp, exp2, exponent, factorial, floor, fma, muladd, hypot, isinteger,
isfinite, isinf, isnan, ldexp, log, log2, log10, max, min, mod, modf,
nextfloat, prevfloat, promote_rule, rem, rem2pi, round, show, float,
sum, sqrt, string, print, trunc, precision, _precision, exp10, expm1, log1p,
eps, signbit, sign, sin, cos, sincos, tan, sec, csc, cot, acos, asin, atan,
cosh, sinh, tanh, sech, csch, coth, acosh, asinh, atanh, lerpi,
cbrt, typemax, typemin, unsafe_trunc, floatmin, floatmax, rounding,
setrounding, maxintfloat, widen, significand, frexp, tryparse, iszero,
isone, big, _string_n, decompose, minmax, _precision_with_base_2,
sinpi, cospi, sincospi, tanpi, sind, cosd, tand, asind, acosd, atand,
uinttype, exponent_max, exponent_min, ieee754_representation, significand_mask,
RawBigIntRoundingIncrementHelper, truncated, RawBigInt
using .Base.Libc
import ..Rounding:
rounding_raw, setrounding_raw, rounds_to_nearest, rounds_away_from_zero,
tie_breaker_is_to_even, correct_rounding_requires_increment
import ..GMP: ClongMax, CulongMax, CdoubleMax, Limb, libgmp
import ..FastMath.sincos_fast
if Sys.iswindows()
const libmpfr = "libmpfr-6.dll"
elseif Sys.isapple()
const libmpfr = "@rpath/libmpfr.6.dylib"
else
const libmpfr = "libmpfr.so.6"
end
version() = VersionNumber(unsafe_string(ccall((:mpfr_get_version,libmpfr), Ptr{Cchar}, ())))
patches() = split(unsafe_string(ccall((:mpfr_get_patches,libmpfr), Ptr{Cchar}, ())),' ')
function __init__()
try
# set exponent to full range by default
set_emin!(get_emin_min())
set_emax!(get_emax_max())
catch ex
Base.showerror_nostdio(ex, "WARNING: Error during initialization of module MPFR")
end
nothing
end
"""
MPFR.MPFRRoundingMode
Matches the `mpfr_rnd_t` enum provided by MPFR, see
https://www.mpfr.org/mpfr-current/mpfr.html#Rounding-Modes
This is for internal use, and ensures that `ROUNDING_MODE[]` is type-stable.
"""
@enum MPFRRoundingMode begin
MPFRRoundNearest
MPFRRoundToZero
MPFRRoundUp
MPFRRoundDown
MPFRRoundFromZero
MPFRRoundFaithful
end
convert(::Type{MPFRRoundingMode}, ::RoundingMode{:Nearest}) = MPFRRoundNearest
convert(::Type{MPFRRoundingMode}, ::RoundingMode{:ToZero}) = MPFRRoundToZero
convert(::Type{MPFRRoundingMode}, ::RoundingMode{:Up}) = MPFRRoundUp
convert(::Type{MPFRRoundingMode}, ::RoundingMode{:Down}) = MPFRRoundDown
convert(::Type{MPFRRoundingMode}, ::RoundingMode{:FromZero}) = MPFRRoundFromZero
function convert(::Type{RoundingMode}, r::MPFRRoundingMode)
if r == MPFRRoundNearest
return RoundNearest
elseif r == MPFRRoundToZero
return RoundToZero
elseif r == MPFRRoundUp
return RoundUp
elseif r == MPFRRoundDown
return RoundDown
elseif r == MPFRRoundFromZero
return RoundFromZero
else
throw(ArgumentError("invalid MPFR rounding mode code: $r"))
end
end
rounds_to_nearest(m::MPFRRoundingMode) = m == MPFRRoundNearest
function rounds_away_from_zero(m::MPFRRoundingMode, sign_bit::Bool)
if m == MPFRRoundToZero
false
elseif m == MPFRRoundUp
!sign_bit
elseif m == MPFRRoundDown
sign_bit
else
# Assuming `m == MPFRRoundFromZero`
true
end
end
tie_breaker_is_to_even(::MPFRRoundingMode) = true
const ROUNDING_MODE = Ref{MPFRRoundingMode}(MPFRRoundNearest)
const CURRENT_ROUNDING_MODE = Base.ScopedValue{MPFRRoundingMode}()
const DEFAULT_PRECISION = Ref{Clong}(256)
const CURRENT_PRECISION = Base.ScopedValue{Clong}()
# Basic type and initialization definitions
# Warning: the constants are MPFR implementation details from
# `src/mpfr-impl.h`, search for `MPFR_EXP_ZERO`.
const mpfr_special_exponent_zero = typemin(Clong) + true
const mpfr_special_exponent_nan = mpfr_special_exponent_zero + true
const mpfr_special_exponent_inf = mpfr_special_exponent_nan + true
"""
BigFloat <: AbstractFloat
Arbitrary precision floating point number type.
"""
mutable struct BigFloat <: AbstractFloat
prec::Clong
sign::Cint
exp::Clong
d::Ptr{Limb}
# _d::Buffer{Limb} # Julia gc handle for memory @ d
_d::String # Julia gc handle for memory @ d (optimized)
# Not recommended for general use:
# used internally by, e.g. deepcopy
global function _BigFloat(prec::Clong, sign::Cint, exp::Clong, d::String)
# ccall-based version, inlined below
#z = new(zero(Clong), zero(Cint), zero(Clong), C_NULL, d)
#ccall((:mpfr_custom_init,libmpfr), Cvoid, (Ptr{Limb}, Clong), d, prec) # currently seems to be a no-op in mpfr
#NAN_KIND = Cint(0)
#ccall((:mpfr_custom_init_set,libmpfr), Cvoid, (Ref{BigFloat}, Cint, Clong, Ptr{Limb}), z, NAN_KIND, prec, d)
#return z
return new(prec, sign, exp, pointer(d), d)
end
function BigFloat(; precision::Integer=_precision_with_base_2(BigFloat))
precision < 1 && throw(DomainError(precision, "`precision` cannot be less than 1."))
nb = ccall((:mpfr_custom_get_size,libmpfr), Csize_t, (Clong,), precision)
nb = (nb + Core.sizeof(Limb) - 1) ÷ Core.sizeof(Limb) # align to number of Limb allocations required for this
#d = Vector{Limb}(undef, nb)
d = _string_n(nb * Core.sizeof(Limb))
EXP_NAN = mpfr_special_exponent_nan
return _BigFloat(Clong(precision), one(Cint), EXP_NAN, d) # +NAN
end
end
# The rounding mode here shouldn't matter.
significand_limb_count(x::BigFloat) = div(sizeof(x._d), sizeof(Limb), RoundToZero)
rounding_raw(::Type{BigFloat}) = something(Base.ScopedValues.get(CURRENT_ROUNDING_MODE), ROUNDING_MODE[])
setrounding_raw(::Type{BigFloat}, r::MPFRRoundingMode) = ROUNDING_MODE[]=r
function setrounding_raw(f::Function, ::Type{BigFloat}, r::MPFRRoundingMode)
Base.@with(CURRENT_ROUNDING_MODE => r, f())
end
rounding(::Type{BigFloat}) = convert(RoundingMode, rounding_raw(BigFloat))
setrounding(::Type{BigFloat}, r::RoundingMode) = setrounding_raw(BigFloat, convert(MPFRRoundingMode, r))
setrounding(f::Function, ::Type{BigFloat}, r::RoundingMode) =
setrounding_raw(f, BigFloat, convert(MPFRRoundingMode, r))
# overload the definition of unsafe_convert to ensure that `x.d` is assigned
# it may have been dropped in the event that the BigFloat was serialized
Base.unsafe_convert(::Type{Ref{BigFloat}}, x::Ptr{BigFloat}) = x
@inline function Base.unsafe_convert(::Type{Ref{BigFloat}}, x::Ref{BigFloat})
x = x[]
if x.d == C_NULL
x.d = pointer(x._d)
end
return convert(Ptr{BigFloat}, Base.pointer_from_objref(x))
end
"""
BigFloat(x::Union{Real, AbstractString} [, rounding::RoundingMode=rounding(BigFloat)]; [precision::Integer=precision(BigFloat)])
Create an arbitrary precision floating point number from `x`, with precision
`precision`. The `rounding` argument specifies the direction in which the result should be
rounded if the conversion cannot be done exactly. If not provided, these are set by the current global values.
`BigFloat(x::Real)` is the same as `convert(BigFloat,x)`, except if `x` itself is already
`BigFloat`, in which case it will return a value with the precision set to the current
global precision; `convert` will always return `x`.
`BigFloat(x::AbstractString)` is identical to [`parse`](@ref). This is provided for
convenience since decimal literals are converted to `Float64` when parsed, so
`BigFloat(2.1)` may not yield what you expect.
See also:
- [`@big_str`](@ref)
- [`rounding`](@ref) and [`setrounding`](@ref)
- [`precision`](@ref) and [`setprecision`](@ref)
!!! compat "Julia 1.1"
`precision` as a keyword argument requires at least Julia 1.1.
In Julia 1.0 `precision` is the second positional argument (`BigFloat(x, precision)`).
# Examples
```jldoctest
julia> BigFloat(2.1) # 2.1 here is a Float64
2.100000000000000088817841970012523233890533447265625
julia> BigFloat("2.1") # the closest BigFloat to 2.1
2.099999999999999999999999999999999999999999999999999999999999999999999999999986
julia> BigFloat("2.1", RoundUp)
2.100000000000000000000000000000000000000000000000000000000000000000000000000021
julia> BigFloat("2.1", RoundUp, precision=128)
2.100000000000000000000000000000000000007
```
"""
BigFloat(x, r::RoundingMode)
widen(::Type{Float64}) = BigFloat
widen(::Type{BigFloat}) = BigFloat
function BigFloat(x::BigFloat, r::MPFRRoundingMode=rounding_raw(BigFloat); precision::Integer=_precision_with_base_2(BigFloat))
if precision == _precision_with_base_2(x)
return x
else
z = BigFloat(;precision=precision)
ccall((:mpfr_set, libmpfr), Int32, (Ref{BigFloat}, Ref{BigFloat}, MPFRRoundingMode),
z, x, r)
return z
end
end
function _duplicate(x::BigFloat)
z = BigFloat(;precision=_precision_with_base_2(x))
ccall((:mpfr_set, libmpfr), Int32, (Ref{BigFloat}, Ref{BigFloat}, Int32), z, x, 0)
return z
end
# convert to BigFloat
for (fJ, fC) in ((:si,:Clong), (:ui,:Culong))
@eval begin
function BigFloat(x::($fC), r::MPFRRoundingMode=rounding_raw(BigFloat); precision::Integer=_precision_with_base_2(BigFloat))
z = BigFloat(;precision=precision)
ccall(($(string(:mpfr_set_,fJ)), libmpfr), Int32, (Ref{BigFloat}, $fC, MPFRRoundingMode), z, x, r)
return z
end
end
end
function BigFloat(x::Float64, r::MPFRRoundingMode=rounding_raw(BigFloat); precision::Integer=_precision_with_base_2(BigFloat))
z = BigFloat(;precision)
# punt on the hard case where we might have to deal with rounding
# we could use this path in all cases, but mpfr_set_d has a lot of overhead.
if precision <= Base.significand_bits(Float64)
ccall((:mpfr_set_d, libmpfr), Int32, (Ref{BigFloat}, Float64, MPFRRoundingMode), z, x, r)
if isnan(x) && signbit(x) != signbit(z)
z.sign = -z.sign
end
return z
end
z.sign = 1-2*signbit(x)
if iszero(x) || !isfinite(x)
if isinf(x)
z.exp = mpfr_special_exponent_inf
elseif isnan(x)
z.exp = mpfr_special_exponent_nan
else
z.exp = mpfr_special_exponent_zero
end
return z
end
z.exp = 1 + exponent(x)
# BigFloat doesn't have an implicit bit
val = reinterpret(UInt64, significand(x))<<11 | typemin(Int64)
nlimbs = (precision + 8*Core.sizeof(Limb) - 1) ÷ (8*Core.sizeof(Limb))
# Limb is a CLong which is a UInt32 on windows (thank M$) which makes this more complicated and slower.
if Limb === UInt64
for i in 1:nlimbs-1
unsafe_store!(z.d, 0x0, i)
end
unsafe_store!(z.d, val, nlimbs)
else
for i in 1:nlimbs-2
unsafe_store!(z.d, 0x0, i)
end
unsafe_store!(z.d, val % UInt32, nlimbs-1)
unsafe_store!(z.d, (val >> 32) % UInt32, nlimbs)
end
z
end
function BigFloat(x::BigInt, r::MPFRRoundingMode=rounding_raw(BigFloat); precision::Integer=_precision_with_base_2(BigFloat))
z = BigFloat(;precision=precision)
ccall((:mpfr_set_z, libmpfr), Int32, (Ref{BigFloat}, Ref{BigInt}, MPFRRoundingMode), z, x, r)
return z
end
BigFloat(x::Integer; precision::Integer=_precision_with_base_2(BigFloat)) =
BigFloat(BigInt(x)::BigInt, rounding_raw(BigFloat); precision=precision)
BigFloat(x::Integer, r::MPFRRoundingMode; precision::Integer=_precision_with_base_2(BigFloat)) =
BigFloat(BigInt(x)::BigInt, r; precision=precision)
BigFloat(x::Union{Bool,Int8,Int16,Int32}, r::MPFRRoundingMode=rounding_raw(BigFloat); precision::Integer=_precision_with_base_2(BigFloat)) =
BigFloat(convert(Clong, x), r; precision=precision)
BigFloat(x::Union{UInt8,UInt16,UInt32}, r::MPFRRoundingMode=rounding_raw(BigFloat); precision::Integer=_precision_with_base_2(BigFloat)) =
BigFloat(convert(Culong, x), r; precision=precision)
BigFloat(x::Union{Float16,Float32}, r::MPFRRoundingMode=rounding_raw(BigFloat); precision::Integer=_precision_with_base_2(BigFloat)) =
BigFloat(Float64(x), r; precision=precision)
function BigFloat(x::Rational, r::MPFRRoundingMode=rounding_raw(BigFloat); precision::Integer=_precision_with_base_2(BigFloat))
setprecision(BigFloat, precision) do
setrounding_raw(BigFloat, r) do
BigFloat(numerator(x))::BigFloat / BigFloat(denominator(x))::BigFloat
end
end
end
function tryparse(::Type{BigFloat}, s::AbstractString; base::Integer=0, precision::Integer=_precision_with_base_2(BigFloat), rounding::MPFRRoundingMode=rounding_raw(BigFloat))
!isempty(s) && isspace(s[end]) && return tryparse(BigFloat, rstrip(s), base = base)
z = BigFloat(precision=precision)
err = ccall((:mpfr_set_str, libmpfr), Int32, (Ref{BigFloat}, Cstring, Int32, MPFRRoundingMode), z, s, base, rounding)
err == 0 ? z : nothing
end
BigFloat(x::AbstractString, r::MPFRRoundingMode=rounding_raw(BigFloat); precision::Integer=_precision_with_base_2(BigFloat)) =
parse(BigFloat, x; precision=precision, rounding=r)
Rational(x::BigFloat) = convert(Rational{BigInt}, x)
AbstractFloat(x::BigInt) = BigFloat(x)
float(::Type{BigInt}) = BigFloat
BigFloat(x::Real, r::RoundingMode; precision::Integer=_precision_with_base_2(BigFloat)) =
BigFloat(x, convert(MPFRRoundingMode, r); precision=precision)::BigFloat
BigFloat(x::AbstractString, r::RoundingMode; precision::Integer=_precision_with_base_2(BigFloat)) =
BigFloat(x, convert(MPFRRoundingMode, r); precision=precision)
## BigFloat -> Integer
_unchecked_cast(T, x::BigFloat, r::RoundingMode) = _unchecked_cast(T, x, convert(MPFRRoundingMode, r))
function _unchecked_cast(::Type{Int64}, x::BigFloat, r::MPFRRoundingMode)
ccall((:__gmpfr_mpfr_get_sj,libmpfr), Cintmax_t, (Ref{BigFloat}, MPFRRoundingMode), x, r)
end
function _unchecked_cast(::Type{UInt64}, x::BigFloat, r::MPFRRoundingMode)
ccall((:__gmpfr_mpfr_get_uj,libmpfr), Cuintmax_t, (Ref{BigFloat}, MPFRRoundingMode), x, r)
end
function _unchecked_cast(::Type{BigInt}, x::BigFloat, r::MPFRRoundingMode)
z = BigInt()
ccall((:mpfr_get_z, libmpfr), Int32, (Ref{BigInt}, Ref{BigFloat}, MPFRRoundingMode), z, x, r)
return z
end
function _unchecked_cast(::Type{T}, x::BigFloat, r::MPFRRoundingMode) where T<:Union{Signed, Unsigned}
CT = T <: Signed ? Int64 : UInt64
typemax(T) < typemax(CT) ? _unchecked_cast(CT, x, r) : _unchecked_cast(BigInt, x, r)
end
function round(::Type{T}, x::BigFloat, r::Union{RoundingMode, MPFRRoundingMode}) where T<:Union{Signed, Unsigned}
clear_flags()
res = _unchecked_cast(T, x, r)
if had_range_exception() || !(typemin(T) <= res <= typemax(T))
throw(InexactError(:round, T, x))
end
return unsafe_trunc(T, res)
end
function round(::Type{BigInt}, x::BigFloat, r::Union{RoundingMode, MPFRRoundingMode})
clear_flags()
res = _unchecked_cast(BigInt, x, r)
had_range_exception() && throw(InexactError(:round, BigInt, x))
return res
end
round(::Type{T}, x::BigFloat, r::RoundingMode) where T<:Union{Signed, Unsigned} =
invoke(round, Tuple{Type{<:Union{Signed, Unsigned}}, BigFloat, Union{RoundingMode, MPFRRoundingMode}}, T, x, r)
round(::Type{BigInt}, x::BigFloat, r::RoundingMode) =
invoke(round, Tuple{Type{BigInt}, BigFloat, Union{RoundingMode, MPFRRoundingMode}}, BigInt, x, r)
unsafe_trunc(::Type{T}, x::BigFloat) where {T<:Integer} = unsafe_trunc(T, _unchecked_cast(T, x, RoundToZero))
unsafe_trunc(::Type{BigInt}, x::BigFloat) = _unchecked_cast(BigInt, x, RoundToZero)
round(::Type{T}, x::BigFloat) where T<:Integer = round(T, x, rounding_raw(BigFloat))
# these two methods are split to increase their precedence in disambiguation:
round(::Type{Integer}, x::BigFloat, r::RoundingMode) = round(BigInt, x, r)
round(::Type{Integer}, x::BigFloat, r::MPFRRoundingMode) = round(BigInt, x, r)
function Bool(x::BigFloat)
iszero(x) && return false
isone(x) && return true
throw(InexactError(:Bool, Bool, x))
end
function BigInt(x::BigFloat)
isinteger(x) || throw(InexactError(:BigInt, BigInt, x))
trunc(BigInt, x)
end
function (::Type{T})(x::BigFloat) where T<:Integer
isinteger(x) || throw(InexactError(nameof(T), T, x))
trunc(T,x)
end
function to_ieee754(::Type{T}, x::BigFloat, rm) where {T<:AbstractFloat}
sb = signbit(x)
is_zero = iszero(x)
is_inf = isinf(x)
is_nan = isnan(x)
is_regular = !is_zero & !is_inf & !is_nan
ieee_exp = Int(x.exp) - 1
ieee_precision = precision(T)
ieee_exp_max = exponent_max(T)
ieee_exp_min = exponent_min(T)
exp_diff = ieee_exp - ieee_exp_min
is_normal = 0 ≤ exp_diff
(rm_is_to_zero, rm_is_from_zero) = if rounds_to_nearest(rm)
(false, false)
else
let from = rounds_away_from_zero(rm, sb)
(!from, from)
end
end::NTuple{2,Bool}
exp_is_huge_p = ieee_exp_max < ieee_exp
exp_is_huge_n = signbit(exp_diff + ieee_precision)
rounds_to_inf = is_regular & exp_is_huge_p & !rm_is_to_zero
rounds_to_zero = is_regular & exp_is_huge_n & !rm_is_from_zero
U = uinttype(T)
ret_u = if is_regular & !rounds_to_inf & !rounds_to_zero
if !exp_is_huge_p
# significand
v = RawBigInt{Limb}(x._d, significand_limb_count(x))
len = max(ieee_precision + min(exp_diff, 0), 0)::Int
signif = truncated(U, v, len) & significand_mask(T)
# round up if necessary
rh = RawBigIntRoundingIncrementHelper(v, len)
incr = correct_rounding_requires_increment(rh, rm, sb)
# exponent
exp_field = max(exp_diff, 0) + is_normal
ieee754_representation(T, sb, exp_field, signif) + incr
else
ieee754_representation(T, sb, Val(:omega))
end
else
if is_zero | rounds_to_zero
ieee754_representation(T, sb, Val(:zero))
elseif is_inf | rounds_to_inf
ieee754_representation(T, sb, Val(:inf))
else
ieee754_representation(T, sb, Val(:nan))
end
end::U
reinterpret(T, ret_u)
end
Float16(x::BigFloat, r::MPFRRoundingMode=rounding_raw(BigFloat)) = to_ieee754(Float16, x, r)
Float32(x::BigFloat, r::MPFRRoundingMode=rounding_raw(BigFloat)) = to_ieee754(Float32, x, r)
Float64(x::BigFloat, r::MPFRRoundingMode=rounding_raw(BigFloat)) = to_ieee754(Float64, x, r)
Float16(x::BigFloat, r::RoundingMode) = to_ieee754(Float16, x, r)
Float32(x::BigFloat, r::RoundingMode) = to_ieee754(Float32, x, r)
Float64(x::BigFloat, r::RoundingMode) = to_ieee754(Float64, x, r)
promote_rule(::Type{BigFloat}, ::Type{<:Real}) = BigFloat
promote_rule(::Type{BigInt}, ::Type{<:AbstractFloat}) = BigFloat
promote_rule(::Type{BigFloat}, ::Type{<:AbstractFloat}) = BigFloat
big(::Type{<:AbstractFloat}) = BigFloat
big(x::AbstractFloat) = convert(BigFloat, x)
function Rational{BigInt}(x::AbstractFloat)
isnan(x) && return zero(BigInt) // zero(BigInt)
isinf(x) && return copysign(one(BigInt),x) // zero(BigInt)
iszero(x) && return zero(BigInt) // one(BigInt)
s = max(precision(x) - exponent(x), 0)
BigInt(ldexp(x,s)) // (BigInt(1) << s)
end
# Basic arithmetic without promotion
for (fJ, fC) in ((:+,:add), (:*,:mul))
@eval begin
# BigFloat
function ($fJ)(x::BigFloat, y::BigFloat)
z = BigFloat()
ccall(($(string(:mpfr_,fC)),libmpfr), Int32, (Ref{BigFloat}, Ref{BigFloat}, Ref{BigFloat}, MPFRRoundingMode), z, x, y, rounding_raw(BigFloat))
return z
end
# Unsigned Integer
function ($fJ)(x::BigFloat, c::CulongMax)
z = BigFloat()
ccall(($(string(:mpfr_,fC,:_ui)), libmpfr), Int32, (Ref{BigFloat}, Ref{BigFloat}, Culong, MPFRRoundingMode), z, x, c, rounding_raw(BigFloat))
return z
end
($fJ)(c::CulongMax, x::BigFloat) = ($fJ)(x,c)
# Signed Integer
function ($fJ)(x::BigFloat, c::ClongMax)
z = BigFloat()
ccall(($(string(:mpfr_,fC,:_si)), libmpfr), Int32, (Ref{BigFloat}, Ref{BigFloat}, Clong, MPFRRoundingMode), z, x, c, rounding_raw(BigFloat))
return z
end
($fJ)(c::ClongMax, x::BigFloat) = ($fJ)(x,c)
# Float32/Float64
function ($fJ)(x::BigFloat, c::CdoubleMax)
z = BigFloat()
ccall(($(string(:mpfr_,fC,:_d)), libmpfr), Int32, (Ref{BigFloat}, Ref{BigFloat}, Cdouble, MPFRRoundingMode), z, x, c, rounding_raw(BigFloat))
return z
end
($fJ)(c::CdoubleMax, x::BigFloat) = ($fJ)(x,c)
# BigInt
function ($fJ)(x::BigFloat, c::BigInt)
z = BigFloat()
ccall(($(string(:mpfr_,fC,:_z)), libmpfr), Int32, (Ref{BigFloat}, Ref{BigFloat}, Ref{BigInt}, MPFRRoundingMode), z, x, c, rounding_raw(BigFloat))
return z
end
($fJ)(c::BigInt, x::BigFloat) = ($fJ)(x,c)
end
end
for (fJ, fC) in ((:-,:sub), (:/,:div))
@eval begin
# BigFloat
function ($fJ)(x::BigFloat, y::BigFloat)
z = BigFloat()
ccall(($(string(:mpfr_,fC)),libmpfr), Int32, (Ref{BigFloat}, Ref{BigFloat}, Ref{BigFloat}, MPFRRoundingMode), z, x, y, rounding_raw(BigFloat))
return z
end
# Unsigned Int
function ($fJ)(x::BigFloat, c::CulongMax)
z = BigFloat()
ccall(($(string(:mpfr_,fC,:_ui)), libmpfr), Int32, (Ref{BigFloat}, Ref{BigFloat}, Culong, MPFRRoundingMode), z, x, c, rounding_raw(BigFloat))
return z
end
function ($fJ)(c::CulongMax, x::BigFloat)
z = BigFloat()
ccall(($(string(:mpfr_,:ui_,fC)), libmpfr), Int32, (Ref{BigFloat}, Culong, Ref{BigFloat}, MPFRRoundingMode), z, c, x, rounding_raw(BigFloat))
return z
end
# Signed Integer
function ($fJ)(x::BigFloat, c::ClongMax)
z = BigFloat()
ccall(($(string(:mpfr_,fC,:_si)), libmpfr), Int32, (Ref{BigFloat}, Ref{BigFloat}, Clong, MPFRRoundingMode), z, x, c, rounding_raw(BigFloat))
return z
end
function ($fJ)(c::ClongMax, x::BigFloat)
z = BigFloat()
ccall(($(string(:mpfr_,:si_,fC)), libmpfr), Int32, (Ref{BigFloat}, Clong, Ref{BigFloat}, MPFRRoundingMode), z, c, x, rounding_raw(BigFloat))
return z
end
# Float32/Float64
function ($fJ)(x::BigFloat, c::CdoubleMax)
z = BigFloat()
ccall(($(string(:mpfr_,fC,:_d)), libmpfr), Int32, (Ref{BigFloat}, Ref{BigFloat}, Cdouble, MPFRRoundingMode), z, x, c, rounding_raw(BigFloat))
return z
end
function ($fJ)(c::CdoubleMax, x::BigFloat)
z = BigFloat()
ccall(($(string(:mpfr_,:d_,fC)), libmpfr), Int32, (Ref{BigFloat}, Cdouble, Ref{BigFloat}, MPFRRoundingMode), z, c, x, rounding_raw(BigFloat))
return z
end
# BigInt
function ($fJ)(x::BigFloat, c::BigInt)
z = BigFloat()
ccall(($(string(:mpfr_,fC,:_z)), libmpfr), Int32, (Ref{BigFloat}, Ref{BigFloat}, Ref{BigInt}, MPFRRoundingMode), z, x, c, rounding_raw(BigFloat))
return z
end
# no :mpfr_z_div function
end
end
function -(c::BigInt, x::BigFloat)
z = BigFloat()
ccall((:mpfr_z_sub, libmpfr), Int32, (Ref{BigFloat}, Ref{BigInt}, Ref{BigFloat}, MPFRRoundingMode), z, c, x, rounding_raw(BigFloat))
return z
end
inv(x::BigFloat) = one(Clong) / x # faster than fallback one(x)/x
function fma(x::BigFloat, y::BigFloat, z::BigFloat)
r = BigFloat()
ccall(("mpfr_fma",libmpfr), Int32, (Ref{BigFloat}, Ref{BigFloat}, Ref{BigFloat}, Ref{BigFloat}, MPFRRoundingMode), r, x, y, z, rounding_raw(BigFloat))
return r
end
muladd(x::BigFloat, y::BigFloat, z::BigFloat) = fma(x, y, z)
# div
# BigFloat
function div(x::BigFloat, y::BigFloat)
z = BigFloat()
ccall((:mpfr_div,libmpfr), Int32, (Ref{BigFloat}, Ref{BigFloat}, Ref{BigFloat}, MPFRRoundingMode), z, x, y, RoundToZero)
ccall((:mpfr_trunc, libmpfr), Int32, (Ref{BigFloat}, Ref{BigFloat}), z, z)
return z
end
# Unsigned Int
function div(x::BigFloat, c::CulongMax)
z = BigFloat()
ccall((:mpfr_div_ui, libmpfr), Int32, (Ref{BigFloat}, Ref{BigFloat}, Culong, MPFRRoundingMode), z, x, c, RoundToZero)
ccall((:mpfr_trunc, libmpfr), Int32, (Ref{BigFloat}, Ref{BigFloat}), z, z)
return z
end
function div(c::CulongMax, x::BigFloat)
z = BigFloat()
ccall((:mpfr_ui_div, libmpfr), Int32, (Ref{BigFloat}, Culong, Ref{BigFloat}, MPFRRoundingMode), z, c, x, RoundToZero)
ccall((:mpfr_trunc, libmpfr), Int32, (Ref{BigFloat}, Ref{BigFloat}), z, z)
return z
end
# Signed Integer
function div(x::BigFloat, c::ClongMax)
z = BigFloat()
ccall((:mpfr_div_si, libmpfr), Int32, (Ref{BigFloat}, Ref{BigFloat}, Clong, MPFRRoundingMode), z, x, c, RoundToZero)
ccall((:mpfr_trunc, libmpfr), Int32, (Ref{BigFloat}, Ref{BigFloat}), z, z)
return z
end
function div(c::ClongMax, x::BigFloat)
z = BigFloat()
ccall((:mpfr_si_div, libmpfr), Int32, (Ref{BigFloat}, Clong, Ref{BigFloat}, MPFRRoundingMode), z, c, x, RoundToZero)
ccall((:mpfr_trunc, libmpfr), Int32, (Ref{BigFloat}, Ref{BigFloat}), z, z)
return z
end
# Float32/Float64
function div(x::BigFloat, c::CdoubleMax)
z = BigFloat()
ccall((:mpfr_div_d, libmpfr), Int32, (Ref{BigFloat}, Ref{BigFloat}, Cdouble, MPFRRoundingMode), z, x, c, RoundToZero)
ccall((:mpfr_trunc, libmpfr), Int32, (Ref{BigFloat}, Ref{BigFloat}), z, z)
return z
end
function div(c::CdoubleMax, x::BigFloat)
z = BigFloat()
ccall((:mpfr_d_div, libmpfr), Int32, (Ref{BigFloat}, Cdouble, Ref{BigFloat}, MPFRRoundingMode), z, c, x, RoundToZero)
ccall((:mpfr_trunc, libmpfr), Int32, (Ref{BigFloat}, Ref{BigFloat}), z, z)
return z
end
# BigInt
function div(x::BigFloat, c::BigInt)
z = BigFloat()
ccall((:mpfr_div_z, libmpfr), Int32, (Ref{BigFloat}, Ref{BigFloat}, Ref{BigInt}, MPFRRoundingMode), z, x, c, RoundToZero)
ccall((:mpfr_trunc, libmpfr), Int32, (Ref{BigFloat}, Ref{BigFloat}), z, z)
return z
end
# More efficient commutative operations
for (fJ, fC, fI) in ((:+, :add, 0), (:*, :mul, 1))
@eval begin
function ($fJ)(a::BigFloat, b::BigFloat, c::BigFloat)
z = BigFloat()
ccall(($(string(:mpfr_,fC)), libmpfr), Int32, (Ref{BigFloat}, Ref{BigFloat}, Ref{BigFloat}, MPFRRoundingMode), z, a, b, rounding_raw(BigFloat))
ccall(($(string(:mpfr_,fC)), libmpfr), Int32, (Ref{BigFloat}, Ref{BigFloat}, Ref{BigFloat}, MPFRRoundingMode), z, z, c, rounding_raw(BigFloat))
return z
end
function ($fJ)(a::BigFloat, b::BigFloat, c::BigFloat, d::BigFloat)
z = BigFloat()
ccall(($(string(:mpfr_,fC)), libmpfr), Int32, (Ref{BigFloat}, Ref{BigFloat}, Ref{BigFloat}, MPFRRoundingMode), z, a, b, rounding_raw(BigFloat))
ccall(($(string(:mpfr_,fC)), libmpfr), Int32, (Ref{BigFloat}, Ref{BigFloat}, Ref{BigFloat}, MPFRRoundingMode), z, z, c, rounding_raw(BigFloat))
ccall(($(string(:mpfr_,fC)), libmpfr), Int32, (Ref{BigFloat}, Ref{BigFloat}, Ref{BigFloat}, MPFRRoundingMode), z, z, d, rounding_raw(BigFloat))
return z
end
function ($fJ)(a::BigFloat, b::BigFloat, c::BigFloat, d::BigFloat, e::BigFloat)
z = BigFloat()
ccall(($(string(:mpfr_,fC)), libmpfr), Int32, (Ref{BigFloat}, Ref{BigFloat}, Ref{BigFloat}, MPFRRoundingMode), z, a, b, rounding_raw(BigFloat))
ccall(($(string(:mpfr_,fC)), libmpfr), Int32, (Ref{BigFloat}, Ref{BigFloat}, Ref{BigFloat}, MPFRRoundingMode), z, z, c, rounding_raw(BigFloat))
ccall(($(string(:mpfr_,fC)), libmpfr), Int32, (Ref{BigFloat}, Ref{BigFloat}, Ref{BigFloat}, MPFRRoundingMode), z, z, d, rounding_raw(BigFloat))
ccall(($(string(:mpfr_,fC)), libmpfr), Int32, (Ref{BigFloat}, Ref{BigFloat}, Ref{BigFloat}, MPFRRoundingMode), z, z, e, rounding_raw(BigFloat))
return z
end
end
end
function -(x::BigFloat)
z = BigFloat()
ccall((:mpfr_neg, libmpfr), Int32, (Ref{BigFloat}, Ref{BigFloat}, MPFRRoundingMode), z, x, rounding_raw(BigFloat))
return z
end
function sqrt(x::BigFloat)
isnan(x) && return x
z = BigFloat()
ccall((:mpfr_sqrt, libmpfr), Int32, (Ref{BigFloat}, Ref{BigFloat}, MPFRRoundingMode), z, x, rounding_raw(BigFloat))
isnan(z) && throw(DomainError(x, "NaN result for non-NaN input."))
return z
end
sqrt(x::BigInt) = sqrt(BigFloat(x))
function ^(x::BigFloat, y::BigFloat)
z = BigFloat()
ccall((:mpfr_pow, libmpfr), Int32, (Ref{BigFloat}, Ref{BigFloat}, Ref{BigFloat}, MPFRRoundingMode), z, x, y, rounding_raw(BigFloat))
return z
end
function ^(x::BigFloat, y::CulongMax)
z = BigFloat()
ccall((:mpfr_pow_ui, libmpfr), Int32, (Ref{BigFloat}, Ref{BigFloat}, Culong, MPFRRoundingMode), z, x, y, rounding_raw(BigFloat))
return z
end
function ^(x::BigFloat, y::ClongMax)
z = BigFloat()
ccall((:mpfr_pow_si, libmpfr), Int32, (Ref{BigFloat}, Ref{BigFloat}, Clong, MPFRRoundingMode), z, x, y, rounding_raw(BigFloat))
return z
end
function ^(x::BigFloat, y::BigInt)
z = BigFloat()
ccall((:mpfr_pow_z, libmpfr), Int32, (Ref{BigFloat}, Ref{BigFloat}, Ref{BigInt}, MPFRRoundingMode), z, x, y, rounding_raw(BigFloat))
return z
end
^(x::BigFloat, y::Integer) = typemin(Clong) <= y <= typemax(Clong) ? x^Clong(y) : x^BigInt(y)
^(x::BigFloat, y::Unsigned) = typemin(Culong) <= y <= typemax(Culong) ? x^Culong(y) : x^BigInt(y)
for f in (:exp, :exp2, :exp10, :expm1, :cosh, :sinh, :tanh, :sech, :csch, :coth, :cbrt)
@eval function $f(x::BigFloat)
z = BigFloat()
ccall(($(string(:mpfr_,f)), libmpfr), Int32, (Ref{BigFloat}, Ref{BigFloat}, MPFRRoundingMode), z, x, rounding_raw(BigFloat))
return z
end
end
function sincos_fast(v::BigFloat)
s = BigFloat()
c = BigFloat()
ccall((:mpfr_sin_cos, libmpfr), Int32, (Ref{BigFloat}, Ref{BigFloat}, Ref{BigFloat}, MPFRRoundingMode), s, c, v, rounding_raw(BigFloat))
return (s, c)
end
sincos(v::BigFloat) = sincos_fast(v)
# return log(2)
function big_ln2()
c = BigFloat()
ccall((:mpfr_const_log2, libmpfr), Cint, (Ref{BigFloat}, MPFRRoundingMode), c, MPFR.rounding_raw(BigFloat))
return c
end
function ldexp(x::BigFloat, n::Clong)
z = BigFloat()
ccall((:mpfr_mul_2si, libmpfr), Int32, (Ref{BigFloat}, Ref{BigFloat}, Clong, MPFRRoundingMode), z, x, n, rounding_raw(BigFloat))
return z
end
function ldexp(x::BigFloat, n::Culong)
z = BigFloat()
ccall((:mpfr_mul_2ui, libmpfr), Int32, (Ref{BigFloat}, Ref{BigFloat}, Culong, MPFRRoundingMode), z, x, n, rounding_raw(BigFloat))
return z
end
ldexp(x::BigFloat, n::ClongMax) = ldexp(x, convert(Clong, n))
ldexp(x::BigFloat, n::CulongMax) = ldexp(x, convert(Culong, n))
ldexp(x::BigFloat, n::Integer) = x * exp2(BigFloat(n))
function factorial(x::BigFloat)
if x < 0 || !isinteger(x)
throw(DomainError(x, "Must be a non-negative integer."))
end
ui = convert(Culong, x)
z = BigFloat()
ccall((:mpfr_fac_ui, libmpfr), Int32, (Ref{BigFloat}, Culong, MPFRRoundingMode), z, ui, rounding_raw(BigFloat))
return z
end
function hypot(x::BigFloat, y::BigFloat)
z = BigFloat()
ccall((:mpfr_hypot, libmpfr), Int32, (Ref{BigFloat}, Ref{BigFloat}, Ref{BigFloat}, MPFRRoundingMode), z, x, y, rounding_raw(BigFloat))
return z
end
for f in (:log, :log2, :log10)
@eval function $f(x::BigFloat)
if x < 0
throw(DomainError(x, string($f, " was called with a negative real argument but ",
"will only return a complex result if called ",
"with a complex argument. Try ", $f, "(complex(x)).")))
end
z = BigFloat()
ccall(($(string(:mpfr_,f)), libmpfr), Int32, (Ref{BigFloat}, Ref{BigFloat}, MPFRRoundingMode), z, x, rounding_raw(BigFloat))
return z
end
end
function log1p(x::BigFloat)
if x < -1
throw(DomainError(x, string("log1p was called with a real argument < -1 but ",
"will only return a complex result if called ",
"with a complex argument. Try log1p(complex(x)).")))
end
z = BigFloat()
ccall((:mpfr_log1p, libmpfr), Int32, (Ref{BigFloat}, Ref{BigFloat}, MPFRRoundingMode), z, x, rounding_raw(BigFloat))
return z
end
# For `min`/`max`, general fallback for `AbstractFloat` is good enough.
# Only implement `minmax` and `_extrema_rf` to avoid repeated calls.
function minmax(x::BigFloat, y::BigFloat)
isnan(x) && return x, x
isnan(y) && return y, y
Base.Math._isless(x, y) ? (x, y) : (y, x)
end
function Base._extrema_rf(x::NTuple{2,BigFloat}, y::NTuple{2,BigFloat})
(x1, x2), (y1, y2) = x, y
isnan(x1) && return x
isnan(y1) && return y
z1 = Base.Math._isless(x1, y1) ? x1 : y1
z2 = Base.Math._isless(x2, y2) ? y2 : x2
z1, z2
end
function modf(x::BigFloat)
zint = BigFloat()
zfloat = BigFloat()
ccall((:mpfr_modf, libmpfr), Int32, (Ref{BigFloat}, Ref{BigFloat}, Ref{BigFloat}, MPFRRoundingMode), zint, zfloat, x, rounding_raw(BigFloat))
return (zfloat, zint)
end
function rem(x::BigFloat, y::BigFloat)
z = BigFloat()
ccall((:mpfr_fmod, libmpfr), Int32, (Ref{BigFloat}, Ref{BigFloat}, Ref{BigFloat}, MPFRRoundingMode), z, x, y, rounding_raw(BigFloat))
return z
end
function rem(x::BigFloat, y::BigFloat, ::RoundingMode{:Nearest})
z = BigFloat()
ccall((:mpfr_remainder, libmpfr), Int32, (Ref{BigFloat}, Ref{BigFloat}, Ref{BigFloat}, MPFRRoundingMode), z, x, y, rounding_raw(BigFloat))
return z
end
# TODO: use a higher-precision BigFloat(pi) here?
rem2pi(x::BigFloat, r::RoundingMode) = rem(x, 2*BigFloat(pi), r)
function sum(arr::AbstractArray{BigFloat})
z = BigFloat(0)
for i in arr
ccall((:mpfr_add, libmpfr), Int32,
(Ref{BigFloat}, Ref{BigFloat}, Ref{BigFloat}, MPFRRoundingMode), z, z, i, rounding_raw(BigFloat))
end
return z
end
# Functions for which NaN results are converted to DomainError, following Base
for f in (:sin, :cos, :tan, :sec, :csc, :acos, :asin, :atan, :acosh, :asinh, :atanh, :sinpi, :cospi, :tanpi)
@eval begin
function ($f)(x::BigFloat)
isnan(x) && return x
z = BigFloat()
ccall(($(string(:mpfr_,f)), libmpfr), Int32, (Ref{BigFloat}, Ref{BigFloat}, MPFRRoundingMode), z, x, rounding_raw(BigFloat))
isnan(z) && throw(DomainError(x, "NaN result for non-NaN input."))
return z
end
end
end
sincospi(x::BigFloat) = (sinpi(x), cospi(x))
function atan(y::BigFloat, x::BigFloat)
z = BigFloat()
ccall((:mpfr_atan2, libmpfr), Int32, (Ref{BigFloat}, Ref{BigFloat}, Ref{BigFloat}, MPFRRoundingMode), z, y, x, rounding_raw(BigFloat))
return z
end
# degree functions
for f in (:sin, :cos, :tan)
@eval begin
function ($(Symbol(f,:d)))(x::BigFloat)
isnan(x) && return x
z = BigFloat()
ccall(($(string(:mpfr_,f,:u)), :libmpfr), Int32, (Ref{BigFloat}, Ref{BigFloat}, Culong, MPFRRoundingMode), z, x, 360, rounding_raw(BigFloat))
isnan(z) && throw(DomainError(x, "NaN result for non-NaN input."))
return z
end
function ($(Symbol(:a,f,:d)))(x::BigFloat)
isnan(x) && return x
z = BigFloat()
ccall(($(string(:mpfr_a,f,:u)), :libmpfr), Int32, (Ref{BigFloat}, Ref{BigFloat}, Culong, MPFRRoundingMode), z, x, 360, rounding_raw(BigFloat))
isnan(z) && throw(DomainError(x, "NaN result for non-NaN input."))
return z
end
end
end
function atand(y::BigFloat, x::BigFloat)
z = BigFloat()
ccall((:mpfr_atan2u, :libmpfr), Int32, (Ref{BigFloat}, Ref{BigFloat}, Ref{BigFloat}, Culong, MPFRRoundingMode), z, y, x, 360, rounding_raw(BigFloat))
return z
end
# Utility functions
==(x::BigFloat, y::BigFloat) = ccall((:mpfr_equal_p, libmpfr), Int32, (Ref{BigFloat}, Ref{BigFloat}), x, y) != 0
<=(x::BigFloat, y::BigFloat) = ccall((:mpfr_lessequal_p, libmpfr), Int32, (Ref{BigFloat}, Ref{BigFloat}), x, y) != 0
>=(x::BigFloat, y::BigFloat) = ccall((:mpfr_greaterequal_p, libmpfr), Int32, (Ref{BigFloat}, Ref{BigFloat}), x, y) != 0
<(x::BigFloat, y::BigFloat) = ccall((:mpfr_less_p, libmpfr), Int32, (Ref{BigFloat}, Ref{BigFloat}), x, y) != 0
>(x::BigFloat, y::BigFloat) = ccall((:mpfr_greater_p, libmpfr), Int32, (Ref{BigFloat}, Ref{BigFloat}), x, y) != 0
function cmp(x::BigFloat, y::BigInt)
isnan(x) && return 1
ccall((:mpfr_cmp_z, libmpfr), Int32, (Ref{BigFloat}, Ref{BigInt}), x, y)
end
function cmp(x::BigFloat, y::ClongMax)
isnan(x) && return 1
ccall((:mpfr_cmp_si, libmpfr), Int32, (Ref{BigFloat}, Clong), x, y)
end
function cmp(x::BigFloat, y::CulongMax)
isnan(x) && return 1
ccall((:mpfr_cmp_ui, libmpfr), Int32, (Ref{BigFloat}, Culong), x, y)
end
cmp(x::BigFloat, y::Integer) = cmp(x,big(y))
cmp(x::Integer, y::BigFloat) = -cmp(y,x)
function cmp(x::BigFloat, y::CdoubleMax)
isnan(x) && return isnan(y) ? 0 : 1
isnan(y) && return -1
ccall((:mpfr_cmp_d, libmpfr), Int32, (Ref{BigFloat}, Cdouble), x, y)
end
cmp(x::CdoubleMax, y::BigFloat) = -cmp(y,x)
==(x::BigFloat, y::Integer) = !isnan(x) && cmp(x,y) == 0
==(x::Integer, y::BigFloat) = y == x
==(x::BigFloat, y::CdoubleMax) = !isnan(x) && !isnan(y) && cmp(x,y) == 0
==(x::CdoubleMax, y::BigFloat) = y == x
<(x::BigFloat, y::Integer) = !isnan(x) && cmp(x,y) < 0
<(x::Integer, y::BigFloat) = !isnan(y) && cmp(y,x) > 0
<(x::BigFloat, y::CdoubleMax) = !isnan(x) && !isnan(y) && cmp(x,y) < 0
<(x::CdoubleMax, y::BigFloat) = !isnan(x) && !isnan(y) && cmp(y,x) > 0
<=(x::BigFloat, y::Integer) = !isnan(x) && cmp(x,y) <= 0
<=(x::Integer, y::BigFloat) = !isnan(y) && cmp(y,x) >= 0
<=(x::BigFloat, y::CdoubleMax) = !isnan(x) && !isnan(y) && cmp(x,y) <= 0
<=(x::CdoubleMax, y::BigFloat) = !isnan(x) && !isnan(y) && cmp(y,x) >= 0
# Note: this inlines the implementation of `mpfr_signbit` to avoid a
# `ccall`.
signbit(x::BigFloat) = signbit(x.sign)
function sign(x::BigFloat)
c = cmp(x, 0)
(c == 0 || isnan(x)) && return x
return c < 0 ? -one(x) : one(x)
end
function _precision_with_base_2(x::BigFloat) # precision of an object of type BigFloat
return ccall((:mpfr_get_prec, libmpfr), Clong, (Ref{BigFloat},), x)
end
precision(x::BigFloat; base::Integer=2) = _precision(x, base)
_convert_precision_from_base(precision::Integer, base::Integer) =
base == 2 ? precision : ceil(Int, precision * log2(base))
_precision_with_base_2(::Type{BigFloat}) =
Int(something(Base.ScopedValues.get(CURRENT_PRECISION), DEFAULT_PRECISION[])) # default precision of the type BigFloat itself
"""
setprecision([T=BigFloat,] precision::Int; base=2)
Set the precision (in bits, by default) to be used for `T` arithmetic.
If `base` is specified, then the precision is the minimum required to give
at least `precision` digits in the given `base`.
!!! warning
This function is not thread-safe. It will affect code running on all threads, but
its behavior is undefined if called concurrently with computations that use the
setting.
!!! compat "Julia 1.8"
The `base` keyword requires at least Julia 1.8.
"""
function setprecision(::Type{BigFloat}, precision::Integer; base::Integer=2)
base > 1 || throw(DomainError(base, "`base` cannot be less than 2."))
precision > 0 || throw(DomainError(precision, "`precision` cannot be less than 1."))
DEFAULT_PRECISION[] = _convert_precision_from_base(precision, base)
return precision
end
setprecision(precision::Integer; base::Integer=2) = setprecision(BigFloat, precision; base)
maxintfloat(x::BigFloat) = BigFloat(2)^precision(x)
maxintfloat(::Type{BigFloat}) = BigFloat(2)^precision(BigFloat)
function copysign(x::BigFloat, y::BigFloat)
z = BigFloat()
ccall((:mpfr_copysign, libmpfr), Int32, (Ref{BigFloat}, Ref{BigFloat}, Ref{BigFloat}, MPFRRoundingMode), z, x, y, rounding_raw(BigFloat))
return z
end
function exponent(x::BigFloat)
if iszero(x) || !isfinite(x)
throw(DomainError(x, "`x` must be non-zero and finite."))
end
# The '- 1' is to make it work as Base.exponent
return ccall((:mpfr_get_exp, libmpfr), Clong, (Ref{BigFloat},), x) - 1
end
function frexp(x::BigFloat)
z = BigFloat()
c = Ref{Clong}()
ccall((:mpfr_frexp, libmpfr), Int32, (Ptr{Clong}, Ref{BigFloat}, Ref{BigFloat}, MPFRRoundingMode), c, z, x, rounding_raw(BigFloat))
return (z, c[])
end
function significand(x::BigFloat)
z = BigFloat()
c = Ref{Clong}()
ccall((:mpfr_frexp, libmpfr), Int32, (Ptr{Clong}, Ref{BigFloat}, Ref{BigFloat}, MPFRRoundingMode), c, z, x, rounding_raw(BigFloat))
# Double the significand to make it work as Base.significand
ccall((:mpfr_mul_si, libmpfr), Int32, (Ref{BigFloat}, Ref{BigFloat}, Clong, MPFRRoundingMode), z, z, 2, rounding_raw(BigFloat))
return z
end
function isinteger(x::BigFloat)
return ccall((:mpfr_integer_p, libmpfr), Int32, (Ref{BigFloat},), x) != 0
end
for (f,R) in ((:roundeven, :Nearest),
(:ceil, :Up),
(:floor, :Down),
(:trunc, :ToZero),
(:round, :NearestTiesAway))
@eval begin
function round(x::BigFloat, ::RoundingMode{$(QuoteNode(R))})
z = BigFloat()
ccall(($(string(:mpfr_,f)), libmpfr), Int32, (Ref{BigFloat}, Ref{BigFloat}), z, x)
return z
end
end
end
function isinf(x::BigFloat)
return x.exp == mpfr_special_exponent_inf
end
function isnan(x::BigFloat)
return x.exp == mpfr_special_exponent_nan
end
isfinite(x::BigFloat) = !isinf(x) && !isnan(x)
iszero(x::BigFloat) = x.exp == mpfr_special_exponent_zero
isone(x::BigFloat) = x == Clong(1)
@eval typemax(::Type{BigFloat}) = $(BigFloat(Inf))
@eval typemin(::Type{BigFloat}) = $(BigFloat(-Inf))
function nextfloat!(x::BigFloat, n::Integer=1)
signbit(n) && return prevfloat!(x, abs(n))
for i = 1:n
ccall((:mpfr_nextabove, libmpfr), Int32, (Ref{BigFloat},), x)
end
return x
end
function prevfloat!(x::BigFloat, n::Integer=1)
signbit(n) && return nextfloat!(x, abs(n))
for i = 1:n
ccall((:mpfr_nextbelow, libmpfr), Int32, (Ref{BigFloat},), x)
end
return x
end
nextfloat(x::BigFloat, n::Integer=1) = n == 0 ? x : nextfloat!(_duplicate(x), n)
prevfloat(x::BigFloat, n::Integer=1) = n == 0 ? x : prevfloat!(_duplicate(x), n)
eps(::Type{BigFloat}) = nextfloat(BigFloat(1)) - BigFloat(1)
floatmin(::Type{BigFloat}) = nextfloat(zero(BigFloat))
floatmax(::Type{BigFloat}) = prevfloat(BigFloat(Inf))
"""
setprecision(f::Function, [T=BigFloat,] precision::Integer; base=2)
Change the `T` arithmetic precision (in the given `base`) for the duration of `f`.
It is logically equivalent to:
old = precision(BigFloat)
setprecision(BigFloat, precision)
f()
setprecision(BigFloat, old)
Often used as `setprecision(T, precision) do ... end`
Note: `nextfloat()`, `prevfloat()` do not use the precision mentioned by
`setprecision`.
!!! compat "Julia 1.8"
The `base` keyword requires at least Julia 1.8.
"""
function setprecision(f::Function, ::Type{BigFloat}, prec::Integer; base::Integer=2)
Base.@with(CURRENT_PRECISION => _convert_precision_from_base(prec, base), f())
end
setprecision(f::Function, prec::Integer; base::Integer=2) = setprecision(f, BigFloat, prec; base)
function string_mpfr(x::BigFloat, fmt::String)
pc = Ref{Ptr{UInt8}}()
n = ccall((:mpfr_asprintf,libmpfr), Cint,
(Ptr{Ptr{UInt8}}, Ptr{UInt8}, Ref{BigFloat}...),
pc, fmt, x)
p = pc[]
# convert comma decimal separator to dot
for i = 1:n
if unsafe_load(p, i) == UInt8(',')
unsafe_store!(p, '.', i)
break
end
end
str = unsafe_string(p)
ccall((:mpfr_free_str, libmpfr), Cvoid, (Ptr{UInt8},), p)
return str
end
function _prettify_bigfloat(s::String)::String
mantissa, exponent = eachsplit(s, 'e')
if !occursin('.', mantissa)
mantissa = string(mantissa, '.')
end
mantissa = rstrip(mantissa, '0')
if endswith(mantissa, '.')
mantissa = string(mantissa, '0')
end
expo = parse(Int, exponent)
if -5 < expo < 6
expo == 0 && return mantissa
int, frac = eachsplit(mantissa, '.')
if expo > 0
expo < length(frac) ?
string(int, frac[1:expo], '.', frac[expo+1:end]) :
string(int, frac, '0'^(expo-length(frac)), '.', '0')
else
neg = startswith(int, '-')
neg == true && (int = lstrip(int, '-'))
@assert length(int) == 1
string(neg ? '-' : "", '0', '.', '0'^(-expo-1), int, frac == "0" ? "" : frac)
end
else
string(mantissa, 'e', exponent)
end
end
function _string(x::BigFloat, fmt::String)::String
isfinite(x) || return string(Float64(x))
_prettify_bigfloat(string_mpfr(x, fmt))
end
_string(x::BigFloat) = _string(x, "%Re")
_string(x::BigFloat, k::Integer) = _string(x, "%.$(k)Re")
string(b::BigFloat) = _string(b)
print(io::IO, b::BigFloat) = print(io, string(b))
function show(io::IO, b::BigFloat)
if get(io, :compact, false)::Bool
print(io, _string(b, 5))
else
print(io, _string(b))
end
end
# get/set exponent min/max
get_emax() = ccall((:mpfr_get_emax, libmpfr), Clong, ())
get_emax_min() = ccall((:mpfr_get_emax_min, libmpfr), Clong, ())
get_emax_max() = ccall((:mpfr_get_emax_max, libmpfr), Clong, ())
get_emin() = ccall((:mpfr_get_emin, libmpfr), Clong, ())
get_emin_min() = ccall((:mpfr_get_emin_min, libmpfr), Clong, ())
get_emin_max() = ccall((:mpfr_get_emin_max, libmpfr), Clong, ())
check_exponent_err(ret) = ret == 0 || throw(ArgumentError("Invalid MPFR exponent range"))
set_emax!(x) = check_exponent_err(ccall((:mpfr_set_emax, libmpfr), Cint, (Clong,), x))
set_emin!(x) = check_exponent_err(ccall((:mpfr_set_emin, libmpfr), Cint, (Clong,), x))
function Base.deepcopy_internal(x::BigFloat, stackdict::IdDict)
get!(stackdict, x) do
# d = copy(x._d)
d = x._d
d′ = GC.@preserve d unsafe_string(pointer(d), sizeof(d)) # creates a definitely-new String
y = _BigFloat(x.prec, x.sign, x.exp, d′)
#ccall((:mpfr_custom_move,libmpfr), Cvoid, (Ref{BigFloat}, Ptr{Limb}), y, d) # unnecessary
return y
end
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(Limb)) # limbs
b = s.size * sizeof(Limb) # bytes
ccall((:__gmpz_realloc2, libgmp), Cvoid, (Ref{BigInt}, Culong), s, 8b) # bits
memcpy(s.d, x.d, b)
s, x.exp - 8b, x.sign
end
function lerpi(j::Integer, d::Integer, a::BigFloat, b::BigFloat)
t = BigFloat(j)/d
fma(t, b, fma(-t, a, a))
end
# flags
clear_flags() = ccall((:mpfr_clear_flags, libmpfr), Cvoid, ())
had_underflow() = ccall((:mpfr_underflow_p, libmpfr), Cint, ()) != 0
had_overflow() = ccall((:mpfr_underflow_p, libmpfr), Cint, ()) != 0
had_nan() = ccall((:mpfr_nanflag_p, libmpfr), Cint, ()) != 0
had_inexact_exception() = ccall((:mpfr_inexflag_p, libmpfr), Cint, ()) != 0
had_range_exception() = ccall((:mpfr_erangeflag_p, libmpfr), Cint, ()) != 0
end #module
