# 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, exp, exp2, exponent, factorial, floor, fma, hypot, isinteger, isfinite, isinf, isnan, ldexp, log, log2, log10, max, min, mod, modf, nextfloat, prevfloat, promote_rule, rem, rem2pi, round, show, sum, sqrt, string, print, trunc, precision, exp10, expm1, gamma, lgamma, log1p, eps, signbit, sin, cos, tan, sec, csc, cot, acos, asin, atan, cosh, sinh, tanh, sech, csch, coth, acosh, asinh, atanh, atan2, cbrt, typemax, typemin, unsafe_trunc, realmin, realmax, rounding, setrounding, maxintfloat, widen, significand, frexp, tryparse, iszero import Base.Rounding: rounding_raw, setrounding_raw import Base.GMP: ClongMax, CulongMax, CdoubleMax, Limb import Base.Math.lgamma_r 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 end const ROUNDING_MODE = Ref{Cint}(0) const DEFAULT_PRECISION = [256] # Basic type and initialization definitions """ BigFloat <: AbstractFloat Arbitrary precision floating point number type. """ mutable struct BigFloat <: AbstractFloat prec::Clong sign::Cint exp::Clong d::Ptr{Limb} function BigFloat() prec = precision(BigFloat) z = new(zero(Clong), zero(Cint), zero(Clong), C_NULL) ccall((:mpfr_init2,:libmpfr), Void, (Ptr{BigFloat}, Clong), &z, prec) finalizer(z, cglobal((:mpfr_clear, :libmpfr))) return z end # Not recommended for general use: function BigFloat(prec::Clong, sign::Cint, exp::Clong, d::Ptr{Void}) new(prec, sign, exp, d) end end """ BigFloat(x) Create an arbitrary precision floating point number. `x` may be an [`Integer`](@ref), a [`Float64`](@ref) or a [`BigInt`](@ref). The usual mathematical operators are defined for this type, and results are promoted to a [`BigFloat`](@ref). Note that because decimal literals are converted to floating point numbers when parsed, `BigFloat(2.1)` may not yield what you expect. You may instead prefer to initialize constants from strings via [`parse`](@ref), or using the `big` string literal. ```jldoctest julia> BigFloat(2.1) 2.100000000000000088817841970012523233890533447265625000000000000000000000000000 julia> big"2.1" 2.099999999999999999999999999999999999999999999999999999999999999999999999999986 ``` """ BigFloat(x) widen(::Type{Float64}) = BigFloat widen(::Type{BigFloat}) = BigFloat convert(::Type{BigFloat}, x::BigFloat) = x # convert to BigFloat for (fJ, fC) in ((:si,:Clong), (:ui,:Culong), (:d,:Float64)) @eval begin function convert(::Type{BigFloat}, x::($fC)) z = BigFloat() ccall(($(string(:mpfr_set_,fJ)), :libmpfr), Int32, (Ptr{BigFloat}, ($fC), Int32), &z, x, ROUNDING_MODE[]) return z end end end function convert(::Type{BigFloat}, x::BigInt) z = BigFloat() ccall((:mpfr_set_z, :libmpfr), Int32, (Ptr{BigFloat}, Ptr{BigInt}, Int32), &z, &x, ROUNDING_MODE[]) return z end convert(::Type{BigFloat}, x::Integer) = BigFloat(BigInt(x)) convert(::Type{BigFloat}, x::Union{Bool,Int8,Int16,Int32}) = BigFloat(convert(Clong,x)) convert(::Type{BigFloat}, x::Union{UInt8,UInt16,UInt32}) = BigFloat(convert(Culong,x)) convert(::Type{BigFloat}, x::Union{Float16,Float32}) = BigFloat(Float64(x)) convert(::Type{BigFloat}, x::Rational) = BigFloat(numerator(x)) / BigFloat(denominator(x)) function tryparse(::Type{BigFloat}, s::AbstractString, base::Int=0) z = BigFloat() err = ccall((:mpfr_set_str, :libmpfr), Int32, (Ptr{BigFloat}, Cstring, Int32, Int32), &z, s, base, ROUNDING_MODE[]) err == 0 ? Nullable(z) : Nullable{BigFloat}() end convert(::Type{Rational}, x::BigFloat) = convert(Rational{BigInt}, x) convert(::Type{AbstractFloat}, x::BigInt) = BigFloat(x) # generic constructor with arbitrary precision: """ BigFloat(x, prec::Int) Create a representation of `x` as a [`BigFloat`](@ref) with precision `prec`. """ function BigFloat(x, prec::Int) setprecision(BigFloat, prec) do BigFloat(x) end end """ BigFloat(x, prec::Int, rounding::RoundingMode) Create a representation of `x` as a [`BigFloat`](@ref) with precision `prec` and rounding mode `rounding`. """ function BigFloat(x, prec::Int, rounding::RoundingMode) setrounding(BigFloat, rounding) do BigFloat(x, prec) end end """ BigFloat(x, rounding::RoundingMode) Create a representation of `x` as a [`BigFloat`](@ref) with the current global precision and rounding mode `rounding`. """ function BigFloat(x::Union{Integer, AbstractFloat, String}, rounding::RoundingMode) BigFloat(x, precision(BigFloat), rounding) end """ BigFloat(x::String) Create a representation of the string `x` as a [`BigFloat`](@ref). """ BigFloat(x::String) = parse(BigFloat, x) ## BigFloat -> Integer function unsafe_cast(::Type{Int64}, x::BigFloat, ri::Cint) ccall((:__gmpfr_mpfr_get_sj,:libmpfr), Cintmax_t, (Ptr{BigFloat}, Cint), &x, ri) end function unsafe_cast(::Type{UInt64}, x::BigFloat, ri::Cint) ccall((:__gmpfr_mpfr_get_uj,:libmpfr), Cuintmax_t, (Ptr{BigFloat}, Cint), &x, ri) end function unsafe_cast(::Type{T}, x::BigFloat, ri::Cint) where T<:Signed unsafe_cast(Int64, x, ri) % T end function unsafe_cast(::Type{T}, x::BigFloat, ri::Cint) where T<:Unsigned unsafe_cast(UInt64, x, ri) % T end function unsafe_cast(::Type{BigInt}, x::BigFloat, ri::Cint) # actually safe, just keep naming consistent z = BigInt() ccall((:mpfr_get_z, :libmpfr), Int32, (Ptr{BigInt}, Ptr{BigFloat}, Int32), &z, &x, ri) z end unsafe_cast(::Type{Int128}, x::BigFloat, ri::Cint) = Int128(unsafe_cast(BigInt,x,ri)) unsafe_cast(::Type{UInt128}, x::BigFloat, ri::Cint) = UInt128(unsafe_cast(BigInt,x,ri)) unsafe_cast(::Type{T}, x::BigFloat, r::RoundingMode) where {T<:Integer} = unsafe_cast(T,x,to_mpfr(r)) unsafe_trunc(::Type{T}, x::BigFloat) where {T<:Integer} = unsafe_cast(T,x,RoundToZero) function trunc{T<:Union{Signed,Unsigned}}(::Type{T}, x::BigFloat) (typemin(T) <= x <= typemax(T)) || throw(InexactError()) unsafe_cast(T,x,RoundToZero) end function floor(::Type{T}, x::BigFloat) where T<:Union{Signed,Unsigned} (typemin(T) <= x <= typemax(T)) || throw(InexactError()) unsafe_cast(T,x,RoundDown) end function ceil(::Type{T}, x::BigFloat) where T<:Union{Signed,Unsigned} (typemin(T) <= x <= typemax(T)) || throw(InexactError()) unsafe_cast(T,x,RoundUp) end function round(::Type{T}, x::BigFloat) where T<:Union{Signed,Unsigned} (typemin(T) <= x <= typemax(T)) || throw(InexactError()) unsafe_cast(T,x,ROUNDING_MODE[]) end trunc(::Type{BigInt}, x::BigFloat) = unsafe_cast(BigInt, x, RoundToZero) floor(::Type{BigInt}, x::BigFloat) = unsafe_cast(BigInt, x, RoundDown) ceil(::Type{BigInt}, x::BigFloat) = unsafe_cast(BigInt, x, RoundUp) round(::Type{BigInt}, x::BigFloat) = unsafe_cast(BigInt, x, ROUNDING_MODE[]) # convert/round/trunc/floor/ceil(Integer, x) should return a BigInt trunc(::Type{Integer}, x::BigFloat) = trunc(BigInt, x) floor(::Type{Integer}, x::BigFloat) = floor(BigInt, x) ceil(::Type{Integer}, x::BigFloat) = ceil(BigInt, x) round(::Type{Integer}, x::BigFloat) = round(BigInt, x) convert(::Type{Bool}, x::BigFloat) = x==0 ? false : x==1 ? true : throw(InexactError()) function convert(::Type{BigInt},x::BigFloat) isinteger(x) || throw(InexactError()) trunc(BigInt,x) end function convert(::Type{Integer}, x::BigFloat) isinteger(x) || throw(InexactError()) trunc(Integer,x) end function convert(::Type{T},x::BigFloat) where T<:Integer isinteger(x) || throw(InexactError()) trunc(T,x) end ## BigFloat -> AbstractFloat convert(::Type{Float64}, x::BigFloat) = ccall((:mpfr_get_d,:libmpfr), Float64, (Ptr{BigFloat}, Int32), &x, ROUNDING_MODE[]) convert(::Type{Float32}, x::BigFloat) = ccall((:mpfr_get_flt,:libmpfr), Float32, (Ptr{BigFloat}, Int32), &x, ROUNDING_MODE[]) # TODO: avoid double rounding convert(::Type{Float16}, x::BigFloat) = convert(Float16, convert(Float32, x)) Float64(x::BigFloat, r::RoundingMode) = ccall((:mpfr_get_d,:libmpfr), Float64, (Ptr{BigFloat}, Int32), &x, to_mpfr(r)) Float32(x::BigFloat, r::RoundingMode) = ccall((:mpfr_get_flt,:libmpfr), Float32, (Ptr{BigFloat}, Int32), &x, to_mpfr(r)) # TODO: avoid double rounding Float16(x::BigFloat, r::RoundingMode) = convert(Float16, Float32(x, r)) promote_rule(::Type{BigFloat}, ::Type{<:Real}) = BigFloat promote_rule(::Type{BigInt}, ::Type{<:AbstractFloat}) = BigFloat promote_rule(::Type{BigFloat}, ::Type{<:AbstractFloat}) = BigFloat function convert(::Type{Rational{BigInt}}, x::AbstractFloat) if isnan(x); return zero(BigInt)//zero(BigInt); end if isinf(x); return copysign(one(BigInt),x)//zero(BigInt); end if x == 0; return zero(BigInt) // one(BigInt); end 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(($(string(:mpfr_,fC)),:libmpfr), Int32, (Ptr{BigFloat}, Ptr{BigFloat}, Ptr{BigFloat}, Int32), &z, &x, &y, ROUNDING_MODE[]) return z end # Unsigned Integer function ($fJ)(x::BigFloat, c::CulongMax) z = BigFloat() ccall(($(string(:mpfr_,fC,:_ui)), :libmpfr), Int32, (Ptr{BigFloat}, Ptr{BigFloat}, Culong, Int32), &z, &x, c, ROUNDING_MODE[]) return z end ($fJ)(c::CulongMax, x::BigFloat) = ($fJ)(x,c) # Signed Integer function ($fJ)(x::BigFloat, c::ClongMax) z = BigFloat() ccall(($(string(:mpfr_,fC,:_si)), :libmpfr), Int32, (Ptr{BigFloat}, Ptr{BigFloat}, Clong, Int32), &z, &x, c, ROUNDING_MODE[]) return z end ($fJ)(c::ClongMax, x::BigFloat) = ($fJ)(x,c) # Float32/Float64 function ($fJ)(x::BigFloat, c::CdoubleMax) z = BigFloat() ccall(($(string(:mpfr_,fC,:_d)), :libmpfr), Int32, (Ptr{BigFloat}, Ptr{BigFloat}, Cdouble, Int32), &z, &x, c, ROUNDING_MODE[]) return z end ($fJ)(c::CdoubleMax, x::BigFloat) = ($fJ)(x,c) # BigInt function ($fJ)(x::BigFloat, c::BigInt) z = BigFloat() ccall(($(string(:mpfr_,fC,:_z)), :libmpfr), Int32, (Ptr{BigFloat}, Ptr{BigFloat}, Ptr{BigInt}, Int32), &z, &x, &c, ROUNDING_MODE[]) return z end ($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(($(string(:mpfr_,fC)),:libmpfr), Int32, (Ptr{BigFloat}, Ptr{BigFloat}, Ptr{BigFloat}, Int32), &z, &x, &y, ROUNDING_MODE[]) return z end # Unsigned Int function ($fJ)(x::BigFloat, c::CulongMax) z = BigFloat() ccall(($(string(:mpfr_,fC,:_ui)), :libmpfr), Int32, (Ptr{BigFloat}, Ptr{BigFloat}, Culong, Int32), &z, &x, c, ROUNDING_MODE[]) return z end function ($fJ)(c::CulongMax, x::BigFloat) z = BigFloat() ccall(($(string(:mpfr_,:ui_,fC)), :libmpfr), Int32, (Ptr{BigFloat}, Culong, Ptr{BigFloat}, Int32), &z, c, &x, ROUNDING_MODE[]) return z end # Signed Integer function ($fJ)(x::BigFloat, c::ClongMax) z = BigFloat() ccall(($(string(:mpfr_,fC,:_si)), :libmpfr), Int32, (Ptr{BigFloat}, Ptr{BigFloat}, Clong, Int32), &z, &x, c, ROUNDING_MODE[]) return z end function ($fJ)(c::ClongMax, x::BigFloat) z = BigFloat() ccall(($(string(:mpfr_,:si_,fC)), :libmpfr), Int32, (Ptr{BigFloat}, Clong, Ptr{BigFloat}, Int32), &z, c, &x, ROUNDING_MODE[]) return z end # Float32/Float64 function ($fJ)(x::BigFloat, c::CdoubleMax) z = BigFloat() ccall(($(string(:mpfr_,fC,:_d)), :libmpfr), Int32, (Ptr{BigFloat}, Ptr{BigFloat}, Cdouble, Int32), &z, &x, c, ROUNDING_MODE[]) return z end function ($fJ)(c::CdoubleMax, x::BigFloat) z = BigFloat() ccall(($(string(:mpfr_,:d_,fC)), :libmpfr), Int32, (Ptr{BigFloat}, Cdouble, Ptr{BigFloat}, Int32), &z, c, &x, ROUNDING_MODE[]) return z end # BigInt function ($fJ)(x::BigFloat, c::BigInt) z = BigFloat() ccall(($(string(:mpfr_,fC,:_z)), :libmpfr), Int32, (Ptr{BigFloat}, Ptr{BigFloat}, Ptr{BigInt}, Int32), &z, &x, &c, ROUNDING_MODE[]) return z end # no :mpfr_z_div function end end function -(c::BigInt, x::BigFloat) z = BigFloat() ccall((:mpfr_z_sub, :libmpfr), Int32, (Ptr{BigFloat}, Ptr{BigInt}, Ptr{BigFloat}, Int32), &z, &c, &x, ROUNDING_MODE[]) return z end function fma(x::BigFloat, y::BigFloat, z::BigFloat) r = BigFloat() ccall(("mpfr_fma",:libmpfr), Int32, (Ptr{BigFloat}, Ptr{BigFloat}, Ptr{BigFloat}, Ptr{BigFloat}, Int32), &r, &x, &y, &z, ROUNDING_MODE[]) return r end # div # BigFloat function div(x::BigFloat, y::BigFloat) z = BigFloat() ccall((:mpfr_div,:libmpfr), Int32, (Ptr{BigFloat}, Ptr{BigFloat}, Ptr{BigFloat}, Int32), &z, &x, &y, to_mpfr(RoundToZero)) ccall((:mpfr_trunc, :libmpfr), Int32, (Ptr{BigFloat}, Ptr{BigFloat}), &z, &z) return z end # Unsigned Int function div(x::BigFloat, c::CulongMax) z = BigFloat() ccall((:mpfr_div_ui, :libmpfr), Int32, (Ptr{BigFloat}, Ptr{BigFloat}, Culong, Int32), &z, &x, c, to_mpfr(RoundToZero)) ccall((:mpfr_trunc, :libmpfr), Int32, (Ptr{BigFloat}, Ptr{BigFloat}), &z, &z) return z end function div(c::CulongMax, x::BigFloat) z = BigFloat() ccall((:mpfr_ui_div, :libmpfr), Int32, (Ptr{BigFloat}, Culong, Ptr{BigFloat}, Int32), &z, c, &x, to_mpfr(RoundToZero)) ccall((:mpfr_trunc, :libmpfr), Int32, (Ptr{BigFloat}, Ptr{BigFloat}), &z, &z) return z end # Signed Integer function div(x::BigFloat, c::ClongMax) z = BigFloat() ccall((:mpfr_div_si, :libmpfr), Int32, (Ptr{BigFloat}, Ptr{BigFloat}, Clong, Int32), &z, &x, c, to_mpfr(RoundToZero)) ccall((:mpfr_trunc, :libmpfr), Int32, (Ptr{BigFloat}, Ptr{BigFloat}), &z, &z) return z end function div(c::ClongMax, x::BigFloat) z = BigFloat() ccall((:mpfr_si_div, :libmpfr), Int32, (Ptr{BigFloat}, Clong, Ptr{BigFloat}, Int32), &z, c, &x, to_mpfr(RoundToZero)) ccall((:mpfr_trunc, :libmpfr), Int32, (Ptr{BigFloat}, Ptr{BigFloat}), &z, &z) return z end # Float32/Float64 function div(x::BigFloat, c::CdoubleMax) z = BigFloat() ccall((:mpfr_div_d, :libmpfr), Int32, (Ptr{BigFloat}, Ptr{BigFloat}, Cdouble, Int32), &z, &x, c, to_mpfr(RoundToZero)) ccall((:mpfr_trunc, :libmpfr), Int32, (Ptr{BigFloat}, Ptr{BigFloat}), &z, &z) return z end function div(c::CdoubleMax, x::BigFloat) z = BigFloat() ccall((:mpfr_d_div, :libmpfr), Int32, (Ptr{BigFloat}, Cdouble, Ptr{BigFloat}, Int32), &z, c, &x, to_mpfr(RoundToZero)) ccall((:mpfr_trunc, :libmpfr), Int32, (Ptr{BigFloat}, Ptr{BigFloat}), &z, &z) return z end # BigInt function div(x::BigFloat, c::BigInt) z = BigFloat() ccall((:mpfr_div_z, :libmpfr), Int32, (Ptr{BigFloat}, Ptr{BigFloat}, Ptr{BigInt}, Int32), &z, &x, &c, to_mpfr(RoundToZero)) ccall((:mpfr_trunc, :libmpfr), Int32, (Ptr{BigFloat}, Ptr{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(($(string(:mpfr_,fC)), :libmpfr), Int32, (Ptr{BigFloat}, Ptr{BigFloat}, Ptr{BigFloat}, Int32), &z, &a, &b, ROUNDING_MODE[]) ccall(($(string(:mpfr_,fC)), :libmpfr), Int32, (Ptr{BigFloat}, Ptr{BigFloat}, Ptr{BigFloat}, Int32), &z, &z, &c, ROUNDING_MODE[]) return z end function ($fJ)(a::BigFloat, b::BigFloat, c::BigFloat, d::BigFloat) z = BigFloat() ccall(($(string(:mpfr_,fC)), :libmpfr), Int32, (Ptr{BigFloat}, Ptr{BigFloat}, Ptr{BigFloat}, Int32), &z, &a, &b, ROUNDING_MODE[]) ccall(($(string(:mpfr_,fC)), :libmpfr), Int32, (Ptr{BigFloat}, Ptr{BigFloat}, Ptr{BigFloat}, Int32), &z, &z, &c, ROUNDING_MODE[]) ccall(($(string(:mpfr_,fC)), :libmpfr), Int32, (Ptr{BigFloat}, Ptr{BigFloat}, Ptr{BigFloat}, Int32), &z, &z, &d, ROUNDING_MODE[]) return z end function ($fJ)(a::BigFloat, b::BigFloat, c::BigFloat, d::BigFloat, e::BigFloat) z = BigFloat() ccall(($(string(:mpfr_,fC)), :libmpfr), Int32, (Ptr{BigFloat}, Ptr{BigFloat}, Ptr{BigFloat}, Int32), &z, &a, &b, ROUNDING_MODE[]) ccall(($(string(:mpfr_,fC)), :libmpfr), Int32, (Ptr{BigFloat}, Ptr{BigFloat}, Ptr{BigFloat}, Int32), &z, &z, &c, ROUNDING_MODE[]) ccall(($(string(:mpfr_,fC)), :libmpfr), Int32, (Ptr{BigFloat}, Ptr{BigFloat}, Ptr{BigFloat}, Int32), &z, &z, &d, ROUNDING_MODE[]) ccall(($(string(:mpfr_,fC)), :libmpfr), Int32, (Ptr{BigFloat}, Ptr{BigFloat}, Ptr{BigFloat}, Int32), &z, &z, &e, ROUNDING_MODE[]) return z end end end function -(x::BigFloat) z = BigFloat() ccall((:mpfr_neg, :libmpfr), Int32, (Ptr{BigFloat}, Ptr{BigFloat}, Int32), &z, &x, ROUNDING_MODE[]) return z end function sqrt(x::BigFloat) isnan(x) && return x z = BigFloat() ccall((:mpfr_sqrt, :libmpfr), Int32, (Ptr{BigFloat}, Ptr{BigFloat}, Int32), &z, &x, ROUNDING_MODE[]) if isnan(z) throw(DomainError()) end return z end sqrt(x::BigInt) = sqrt(BigFloat(x)) function ^(x::BigFloat, y::BigFloat) z = BigFloat() ccall((:mpfr_pow, :libmpfr), Int32, (Ptr{BigFloat}, Ptr{BigFloat}, Ptr{BigFloat}, Int32), &z, &x, &y, ROUNDING_MODE[]) return z end function ^(x::BigFloat, y::CulongMax) z = BigFloat() ccall((:mpfr_pow_ui, :libmpfr), Int32, (Ptr{BigFloat}, Ptr{BigFloat}, Culong, Int32), &z, &x, y, ROUNDING_MODE[]) return z end function ^(x::BigFloat, y::ClongMax) z = BigFloat() ccall((:mpfr_pow_si, :libmpfr), Int32, (Ptr{BigFloat}, Ptr{BigFloat}, Clong, Int32), &z, &x, y, ROUNDING_MODE[]) return z end function ^(x::BigFloat, y::BigInt) z = BigFloat() ccall((:mpfr_pow_z, :libmpfr), Int32, (Ptr{BigFloat}, Ptr{BigFloat}, Ptr{BigInt}, Int32), &z, &x, &y, ROUNDING_MODE[]) 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, (Ptr{BigFloat}, Ptr{BigFloat}, Int32), &z, &x, ROUNDING_MODE[]) return z end end # return log(2) function big_ln2() c = BigFloat() ccall((:mpfr_const_log2, :libmpfr), Cint, (Ptr{BigFloat}, Int32), &c, MPFR.ROUNDING_MODE[]) return c end function ldexp(x::BigFloat, n::Clong) z = BigFloat() ccall((:mpfr_mul_2si, :libmpfr), Int32, (Ptr{BigFloat}, Ptr{BigFloat}, Clong, Int32), &z, &x, n, ROUNDING_MODE[]) return z end function ldexp(x::BigFloat, n::Culong) z = BigFloat() ccall((:mpfr_mul_2ui, :libmpfr), Int32, (Ptr{BigFloat}, Ptr{BigFloat}, Culong, Int32), &z, &x, n, ROUNDING_MODE[]) 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()) end ui = convert(Culong, x) z = BigFloat() ccall((:mpfr_fac_ui, :libmpfr), Int32, (Ptr{BigFloat}, Culong, Int32), &z, ui, ROUNDING_MODE[]) return z end function hypot(x::BigFloat, y::BigFloat) z = BigFloat() ccall((:mpfr_hypot, :libmpfr), Int32, (Ptr{BigFloat}, Ptr{BigFloat}, Ptr{BigFloat}, Int32), &z, &x, &y, ROUNDING_MODE[]) return z end for f in (:log, :log2, :log10) @eval function $f(x::BigFloat) if x < 0 throw(DomainError()) end z = BigFloat() ccall(($(string(:mpfr_,f)), :libmpfr), Int32, (Ptr{BigFloat}, Ptr{BigFloat}, Int32), &z, &x, ROUNDING_MODE[]) return z end end function log1p(x::BigFloat) if x < -1 throw(DomainError()) end z = BigFloat() ccall((:mpfr_log1p, :libmpfr), Int32, (Ptr{BigFloat}, Ptr{BigFloat}, Int32), &z, &x, ROUNDING_MODE[]) return z end function max(x::BigFloat, y::BigFloat) isnan(x) && return x isnan(y) && return y z = BigFloat() ccall((:mpfr_max, :libmpfr), Int32, (Ptr{BigFloat}, Ptr{BigFloat}, Ptr{BigFloat}, Int32), &z, &x, &y, ROUNDING_MODE[]) return z end function min(x::BigFloat, y::BigFloat) isnan(x) && return x isnan(y) && return y z = BigFloat() ccall((:mpfr_min, :libmpfr), Int32, (Ptr{BigFloat}, Ptr{BigFloat}, Ptr{BigFloat}, Int32), &z, &x, &y, ROUNDING_MODE[]) return z end function modf(x::BigFloat) if isinf(x) return (BigFloat(NaN), x) end zint = BigFloat() zfloat = BigFloat() ccall((:mpfr_modf, :libmpfr), Int32, (Ptr{BigFloat}, Ptr{BigFloat}, Ptr{BigFloat}, Int32), &zint, &zfloat, &x, ROUNDING_MODE[]) return (zfloat, zint) end function rem(x::BigFloat, y::BigFloat) z = BigFloat() ccall((:mpfr_fmod, :libmpfr), Int32, (Ptr{BigFloat}, Ptr{BigFloat}, Ptr{BigFloat}, Int32), &z, &x, &y, ROUNDING_MODE[]) return z end function rem(x::BigFloat, y::BigFloat, ::RoundingMode{:Nearest}) z = BigFloat() ccall((:mpfr_remainder, :libmpfr), Int32, (Ptr{BigFloat}, Ptr{BigFloat}, Ptr{BigFloat}, Int32), &z, &x, &y, ROUNDING_MODE[]) 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, (Ptr{BigFloat}, Ptr{BigFloat}, Ptr{BigFloat}, Cint), &z, &z, &i, 0) 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, :gamma) @eval begin function ($f)(x::BigFloat) if isnan(x) return x end z = BigFloat() ccall(($(string(:mpfr_,f)), :libmpfr), Int32, (Ptr{BigFloat}, Ptr{BigFloat}, Int32), &z, &x, ROUNDING_MODE[]) if isnan(z) throw(DomainError()) end return z end end end # log of absolute value of gamma function const lgamma_signp = Ref{Cint}() function lgamma(x::BigFloat) z = BigFloat() ccall((:mpfr_lgamma,:libmpfr), Cint, (Ptr{BigFloat}, Ptr{Cint}, Ptr{BigFloat}, Int32), &z, lgamma_signp, &x, ROUNDING_MODE[]) return z end lgamma_r(x::BigFloat) = (lgamma(x), lgamma_signp[]) function atan2(y::BigFloat, x::BigFloat) z = BigFloat() ccall((:mpfr_atan2, :libmpfr), Int32, (Ptr{BigFloat}, Ptr{BigFloat}, Ptr{BigFloat}, Int32), &z, &y, &x, ROUNDING_MODE[]) return z end # Utility functions ==(x::BigFloat, y::BigFloat) = ccall((:mpfr_equal_p, :libmpfr), Int32, (Ptr{BigFloat}, Ptr{BigFloat}), &x, &y) != 0 <=(x::BigFloat, y::BigFloat) = ccall((:mpfr_lessequal_p, :libmpfr), Int32, (Ptr{BigFloat}, Ptr{BigFloat}), &x, &y) != 0 >=(x::BigFloat, y::BigFloat) = ccall((:mpfr_greaterequal_p, :libmpfr), Int32, (Ptr{BigFloat}, Ptr{BigFloat}), &x, &y) != 0 <(x::BigFloat, y::BigFloat) = ccall((:mpfr_less_p, :libmpfr), Int32, (Ptr{BigFloat}, Ptr{BigFloat}), &x, &y) != 0 >(x::BigFloat, y::BigFloat) = ccall((:mpfr_greater_p, :libmpfr), Int32, (Ptr{BigFloat}, Ptr{BigFloat}), &x, &y) != 0 function cmp(x::BigFloat, y::BigInt) isnan(x) && throw(DomainError()) ccall((:mpfr_cmp_z, :libmpfr), Int32, (Ptr{BigFloat}, Ptr{BigInt}), &x, &y) end function cmp(x::BigFloat, y::ClongMax) isnan(x) && throw(DomainError()) ccall((:mpfr_cmp_si, :libmpfr), Int32, (Ptr{BigFloat}, Clong), &x, y) end function cmp(x::BigFloat, y::CulongMax) isnan(x) && throw(DomainError()) ccall((:mpfr_cmp_ui, :libmpfr), Int32, (Ptr{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) || isnan(y)) && throw(DomainError()) ccall((:mpfr_cmp_d, :libmpfr), Int32, (Ptr{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 signbit(x::BigFloat) = ccall((:mpfr_signbit, :libmpfr), Int32, (Ptr{BigFloat},), &x) != 0 function precision(x::BigFloat) # precision of an object of type BigFloat return ccall((:mpfr_get_prec, :libmpfr), Clong, (Ptr{BigFloat},), &x) end """ precision(BigFloat) Get the precision (in bits) currently used for [`BigFloat`](@ref) arithmetic. """ precision(::Type{BigFloat}) = DEFAULT_PRECISION[end] # precision of the type BigFloat itself """ setprecision([T=BigFloat,] precision::Int) Set the precision (in bits) to be used for `T` arithmetic. """ function setprecision(::Type{BigFloat}, precision::Int) if precision < 2 throw(DomainError()) end DEFAULT_PRECISION[end] = precision end setprecision(precision::Int) = setprecision(BigFloat, precision) maxintfloat(x::BigFloat) = BigFloat(2)^precision(x) maxintfloat(::Type{BigFloat}) = BigFloat(2)^precision(BigFloat) to_mpfr(::RoundingMode{:Nearest}) = Cint(0) to_mpfr(::RoundingMode{:ToZero}) = Cint(1) to_mpfr(::RoundingMode{:Up}) = Cint(2) to_mpfr(::RoundingMode{:Down}) = Cint(3) to_mpfr(::RoundingMode{:FromZero}) = Cint(4) function from_mpfr(c::Integer) if c == 0 return RoundNearest elseif c == 1 return RoundToZero elseif c == 2 return RoundUp elseif c == 3 return RoundDown elseif c == 4 return RoundFromZero else throw(ArgumentError("invalid MPFR rounding mode code: $c")) end RoundingMode(c) end rounding_raw(::Type{BigFloat}) = ROUNDING_MODE[] setrounding_raw(::Type{BigFloat},i::Integer) = ROUNDING_MODE[] = i rounding(::Type{BigFloat}) = from_mpfr(rounding_raw(BigFloat)) setrounding(::Type{BigFloat},r::RoundingMode) = setrounding_raw(BigFloat,to_mpfr(r)) function copysign(x::BigFloat, y::BigFloat) z = BigFloat() ccall((:mpfr_copysign, :libmpfr), Int32, (Ptr{BigFloat}, Ptr{BigFloat}, Ptr{BigFloat}, Int32), &z, &x, &y, ROUNDING_MODE[]) return z end function exponent(x::BigFloat) if x == 0 || !isfinite(x) throw(DomainError()) end # The '- 1' is to make it work as Base.exponent return ccall((:mpfr_get_exp, :libmpfr), Clong, (Ptr{BigFloat},), &x) - 1 end function frexp(x::BigFloat) z = BigFloat() c = Ref{Clong}() ccall((:mpfr_frexp, :libmpfr), Int32, (Ptr{Clong}, Ptr{BigFloat}, Ptr{BigFloat}, Cint), c, &z, &x, ROUNDING_MODE[]) return (z, c[]) end function significand(x::BigFloat) z = BigFloat() c = Ref{Clong}() ccall((:mpfr_frexp, :libmpfr), Int32, (Ptr{Clong}, Ptr{BigFloat}, Ptr{BigFloat}, Cint), c, &z, &x, ROUNDING_MODE[]) # Double the significand to make it work as Base.significand ccall((:mpfr_mul_si, :libmpfr), Int32, (Ptr{BigFloat}, Ptr{BigFloat}, Clong, Int32), &z, &z, 2, ROUNDING_MODE[]) return z end function isinteger(x::BigFloat) return ccall((:mpfr_integer_p, :libmpfr), Int32, (Ptr{BigFloat},), &x) != 0 end for f in (:ceil, :floor, :trunc) @eval begin function ($f)(x::BigFloat) z = BigFloat() ccall(($(string(:mpfr_,f)), :libmpfr), Int32, (Ptr{BigFloat}, Ptr{BigFloat}), &z, &x) return z end end end function round(x::BigFloat) z = BigFloat() ccall((:mpfr_rint, :libmpfr), Int32, (Ptr{BigFloat}, Ptr{BigFloat}, Cint), &z, &x, ROUNDING_MODE[]) return z end function round(x::BigFloat,::RoundingMode{:NearestTiesAway}) z = BigFloat() ccall((:mpfr_round, :libmpfr), Int32, (Ptr{BigFloat}, Ptr{BigFloat}), &z, &x) return z end function isinf(x::BigFloat) return ccall((:mpfr_inf_p, :libmpfr), Int32, (Ptr{BigFloat},), &x) != 0 end function isnan(x::BigFloat) return ccall((:mpfr_nan_p, :libmpfr), Int32, (Ptr{BigFloat},), &x) != 0 end isfinite(x::BigFloat) = !isinf(x) && !isnan(x) iszero(x::BigFloat) = x == Clong(0) @eval typemax(::Type{BigFloat}) = $(BigFloat( Inf)) @eval typemin(::Type{BigFloat}) = $(BigFloat(-Inf)) function nextfloat(x::BigFloat) z = BigFloat() ccall((:mpfr_set, :libmpfr), Int32, (Ptr{BigFloat}, Ptr{BigFloat}, Int32), &z, &x, ROUNDING_MODE[]) ccall((:mpfr_nextabove, :libmpfr), Int32, (Ptr{BigFloat},), &z) != 0 return z end function prevfloat(x::BigFloat) z = BigFloat() ccall((:mpfr_set, :libmpfr), Int32, (Ptr{BigFloat}, Ptr{BigFloat}, Int32), &z, &x, ROUNDING_MODE[]) ccall((:mpfr_nextbelow, :libmpfr), Int32, (Ptr{BigFloat},), &z) != 0 return z end eps(::Type{BigFloat}) = nextfloat(BigFloat(1)) - BigFloat(1) realmin(::Type{BigFloat}) = nextfloat(zero(BigFloat)) realmax(::Type{BigFloat}) = prevfloat(BigFloat(Inf)) """ setprecision(f::Function, [T=BigFloat,] precision::Integer) Change the `T` arithmetic precision (in bits) 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` """ function setprecision(f::Function, ::Type{T}, prec::Integer) where T old_prec = precision(T) setprecision(T, prec) try return f() finally setprecision(T, old_prec) end end setprecision(f::Function, precision::Integer) = setprecision(f, BigFloat, precision) function string(x::BigFloat) if isnan(x) || isinf(x) return string("BigFloat(", Float64(x), ", ", precision(x), ")") end # In general, the number of decimal places needed to read back the number exactly # is, excluding the most significant, ceil(log(10, 2^precision(x))) k = ceil(Int32, precision(x) * 0.3010299956639812) lng = k + Int32(8) # Add space for the sign, the most significand digit, the dot and the exponent buf = Base.StringVector(lng + 1) # format strings are guaranteed to contain no NUL, so we don't use Cstring lng = ccall((:mpfr_snprintf,:libmpfr), Int32, (Ptr{UInt8}, Culong, Ptr{UInt8}, Ptr{BigFloat}...), buf, lng + 1, "%.Re", &x) if lng < k + 5 # print at least k decimal places lng = ccall((:mpfr_sprintf,:libmpfr), Int32, (Ptr{UInt8}, Ptr{UInt8}, Ptr{BigFloat}...), buf, "%.$(k)Re", &x) elseif lng > k + 8 buf = Base.StringVector(lng + 1) lng = ccall((:mpfr_snprintf,:libmpfr), Int32, (Ptr{UInt8}, Culong, Ptr{UInt8}, Ptr{BigFloat}...), buf, lng + 1, "%.Re", &x) end n = (1 <= x < 10 || -10 < x <= -1 || x == 0) ? lng - 4 : lng return String(resize!(buf,n)) end print(io::IO, b::BigFloat) = print(io, string(b)) show(io::IO, b::BigFloat) = print(io, string(b)) # 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, ()) set_emax!(x) = ccall((:mpfr_set_emax, :libmpfr), Void, (Clong,), x) set_emin!(x) = ccall((:mpfr_set_emin, :libmpfr), Void, (Clong,), x) function Base.deepcopy_internal(x::BigFloat, stackdict::ObjectIdDict) if haskey(stackdict, x) return stackdict[x] end N = precision(x) y = BigFloat(zero(Clong), zero(Cint), zero(Clong), C_NULL) ccall((:mpfr_init2,:libmpfr), Void, (Ptr{BigFloat}, Clong), &y, N) finalizer(y, cglobal((:mpfr_clear, :libmpfr))) ccall((:mpfr_set, :libmpfr), Int32, (Ptr{BigFloat}, Ptr{BigFloat}, Int32), &y, &x, ROUNDING_MODE[]) stackdict[x] = y return y end function Base.lerpi(j::Integer, d::Integer, a::BigFloat, b::BigFloat) t = BigFloat(j)/d fma(t, b, fma(-t, a, a)) end end #module