base/gmp.jl

module GMP

export BigInt

import Base: *, +, -, /, <, <<, >>, >>>, <=, ==, >, >=, ^, (~), (&), (|), ($),
             binomial, cmp, convert, div, divrem, factorial, fld, gcd, gcdx, lcm, mod,
             ndigits, promote_rule, rem, show, isqrt, string, isprime, powermod,
             widemul, sum, trailing_zeros, trailing_ones, count_ones, base, parseint,
             serialize, deserialize, bin, oct, dec, hex, isequal, invmod,
             prevpow2, nextpow2, ndigits0z, widen

if Clong == Int32
    typealias ClongMax Union(Int8, Int16, Int32)
    typealias CulongMax Union(Uint8, Uint16, Uint32)
else
    typealias ClongMax Union(Int8, Int16, Int32, Int64)
    typealias CulongMax Union(Uint8, Uint16, Uint32, Uint64)
end

type BigInt <: Integer
    alloc::Cint
    size::Cint
    d::Ptr{Culong}
    function BigInt()
        b = new(zero(Cint), zero(Cint), C_NULL)
        ccall((:__gmpz_init,:libgmp), Void, (Ptr{BigInt},), &b)
        finalizer(b, _gmp_clear_func)
        return b
    end
end

_gmp_clear_func = C_NULL
_mpfr_clear_func = C_NULL

function __init__()
    global _gmp_clear_func = cglobal((:__gmpz_clear, :libgmp))
    global _mpfr_clear_func = cglobal((:mpfr_clear, :libmpfr))
    ccall((:__gmp_set_memory_functions, :libgmp), Void,
          (Ptr{Void},Ptr{Void},Ptr{Void}),
          cglobal(:jl_gc_counted_malloc),
          cglobal(:jl_gc_counted_realloc_with_old_size),
          cglobal(:jl_gc_counted_free))
end

widen(::Type{Int128})  = BigInt
widen(::Type{Uint128}) = BigInt
widen(::Type{BigInt})  = BigInt

BigInt(x::BigInt) = x
BigInt(s::String) = parseint(BigInt,s)

function Base.parseint_nocheck(::Type{BigInt}, s::String, base::Int)
    s = bytestring(s)
    sgn, base, i = Base.parseint_preamble(true,s,base)
    z = BigInt()
    err = ccall((:__gmpz_set_str, :libgmp),
               Int32, (Ptr{BigInt}, Ptr{Uint8}, Int32),
               &z, convert(Ptr{Uint8},SubString(s,i)), base)
    err == 0 || error("invalid big integer: $(repr(s))")
    return sgn < 0 ? -z : z
end

function BigInt(x::Union(Clong,Int32))
    z = BigInt()
    ccall((:__gmpz_set_si, :libgmp), Void, (Ptr{BigInt}, Clong), &z, x)
    return z
end
function BigInt(x::Union(Culong,Uint32))
    z = BigInt()
    ccall((:__gmpz_set_ui, :libgmp), Void, (Ptr{BigInt}, Culong), &z, x)
    return z
end

BigInt(x::Bool) = BigInt(uint(x))

function BigInt(x::Float64)
    !isinteger(x) && throw(InexactError())
    z = BigInt()
    ccall((:__gmpz_set_d, :libgmp), Void, (Ptr{BigInt}, Cdouble), &z, x)
    return z
end

BigInt(x::Union(Float16,Float32)) = BigInt(float64(x))

function BigInt(x::Integer)
    if x < 0
        if typemin(Clong) <= x
            return BigInt(convert(Clong,x))
        end
        b = BigInt(0)
        shift = 0
        while x < -1
            b += BigInt(~uint32(x&0xffffffff))<<shift
            x >>= 32
            shift += 32
        end
        return -b-1
    else
        if x <= typemax(Culong)
            return BigInt(convert(Culong,x))
        end
        b = BigInt(0)
        shift = 0
        while x > 0
            b += BigInt(uint32(x&0xffffffff))<<shift
            x >>>= 32
            shift += 32
        end
        return b
    end
end

convert(::Type{BigInt}, x::Integer) = BigInt(x)
convert(::Type{BigInt}, x::FloatingPoint) = BigInt(x)

function convert(::Type{Int64}, x::BigInt)
    lo = int64(convert(Culong, x & typemax(Uint32)))
    hi = int64(convert(Clong, x >> 32))
    hi << 32 | lo
end
convert(::Type{Int32}, n::BigInt) = int32(convert(Clong, n))
convert(::Type{Int16}, n::BigInt) = int16(convert(Clong, n))
convert(::Type{Int8}, n::BigInt) = int8(convert(Clong, n))

function convert(::Type{Clong}, n::BigInt)
    fits = ccall((:__gmpz_fits_slong_p, :libgmp), Int32, (Ptr{BigInt},), &n) != 0
    if fits
        ccall((:__gmpz_get_si, :libgmp), Clong, (Ptr{BigInt},), &n)
    else
        throw(InexactError())
    end
end

function convert(::Type{Uint64}, x::BigInt)
    lo = uint64(convert(Culong, x & typemax(Uint32)))
    hi = uint64(convert(Culong, x >> 32))
    hi << 32 | lo
end
convert(::Type{Uint32}, x::BigInt) = uint32(convert(Culong, x))
convert(::Type{Uint16}, x::BigInt) = uint16(convert(Culong, x))
convert(::Type{Uint8}, x::BigInt) = uint8(convert(Culong, x))

function convert(::Type{Culong}, n::BigInt)
    fits = ccall((:__gmpz_fits_ulong_p, :libgmp), Int32, (Ptr{BigInt},), &n) != 0
    if fits
        ccall((:__gmpz_get_ui, :libgmp), Culong, (Ptr{BigInt},), &n)
    else
        throw(InexactError())
    end
end

if sizeof(Int32) == sizeof(Clong)
    function convert(::Type{Uint128}, x::BigInt)
        uint128(uint(x>>>96))<<96 +
        uint128(uint((x>>>64) & typemax(Uint32)))<<64 +
        uint128(uint((x>>>32) & typemax(Uint32)))<<32 +
        uint128(uint(x & typemax(Uint32)))
    end
end
if sizeof(Int64) == sizeof(Clong)
    function convert(::Type{Uint128}, x::BigInt)
        uint128(uint(x>>>64))<<64 +
        uint128(uint(x & typemax(Uint64)))
    end
end
convert(::Type{Int128}, x::BigInt) = copysign(int128(uint128(abs(x))),x)

function convert(::Type{Float64}, n::BigInt)
    # TODO: this should round to nearest but instead rounds to zero
    ccall((:__gmpz_get_d, :libgmp), Float64, (Ptr{BigInt},), &n)
end
convert(::Type{Float32}, n::BigInt) = float32(float64(n))
convert(::Type{Float16}, n::BigInt) = float16(float64(n))

promote_rule{T<:Integer}(::Type{BigInt}, ::Type{T}) = BigInt

# serialization

function serialize(s, n::BigInt)
    Base.serialize_type(s, BigInt)
    serialize(s, base(62,n))
end

deserialize(s, ::Type{BigInt}) = Base.parseint_nocheck(BigInt, deserialize(s), 62)

# Binary ops
for (fJ, fC) in ((:+, :add), (:-,:sub), (:*, :mul),
                 (:fld, :fdiv_q), (:div, :tdiv_q), (:mod, :fdiv_r), (:rem, :tdiv_r),
                 (:gcd, :gcd), (:lcm, :lcm),
                 (:&, :and), (:|, :ior), (:$, :xor))
    @eval begin
        function ($fJ)(x::BigInt, y::BigInt)
            z = BigInt()
            ccall(($(string(:__gmpz_,fC)), :libgmp), Void, (Ptr{BigInt}, Ptr{BigInt}, Ptr{BigInt}), &z, &x, &y)
            return z
        end
    end
end

function invmod(x::BigInt, y::BigInt)
    z = BigInt()
    y = abs(y)
    if y == 1
        return big(0)
    end
    if (y==0 || ccall((:__gmpz_invert, :libgmp), Cint, (Ptr{BigInt}, Ptr{BigInt}, Ptr{BigInt}), &z, &x, &y) == 0)
        error("no inverse exists")
    end
    return z
end

# More efficient commutative operations
for (fJ, fC) in ((:+, :add), (:*, :mul), (:&, :and), (:|, :ior), (:$, :xor))
    @eval begin
        function ($fJ)(a::BigInt, b::BigInt, c::BigInt)
            z = BigInt()
            ccall(($(string(:__gmpz_,fC)), :libgmp), Void, (Ptr{BigInt}, Ptr{BigInt}, Ptr{BigInt}), &z, &a, &b)
            ccall(($(string(:__gmpz_,fC)), :libgmp), Void, (Ptr{BigInt}, Ptr{BigInt}, Ptr{BigInt}), &z, &z, &c)
            return z
        end
        function ($fJ)(a::BigInt, b::BigInt, c::BigInt, d::BigInt)
            z = BigInt()
            ccall(($(string(:__gmpz_,fC)), :libgmp), Void, (Ptr{BigInt}, Ptr{BigInt}, Ptr{BigInt}), &z, &a, &b)
            ccall(($(string(:__gmpz_,fC)), :libgmp), Void, (Ptr{BigInt}, Ptr{BigInt}, Ptr{BigInt}), &z, &z, &c)
            ccall(($(string(:__gmpz_,fC)), :libgmp), Void, (Ptr{BigInt}, Ptr{BigInt}, Ptr{BigInt}), &z, &z, &d)
            return z
        end
        function ($fJ)(a::BigInt, b::BigInt, c::BigInt, d::BigInt, e::BigInt)
            z = BigInt()
            ccall(($(string(:__gmpz_,fC)), :libgmp), Void, (Ptr{BigInt}, Ptr{BigInt}, Ptr{BigInt}), &z, &a, &b)
            ccall(($(string(:__gmpz_,fC)), :libgmp), Void, (Ptr{BigInt}, Ptr{BigInt}, Ptr{BigInt}), &z, &z, &c)
            ccall(($(string(:__gmpz_,fC)), :libgmp), Void, (Ptr{BigInt}, Ptr{BigInt}, Ptr{BigInt}), &z, &z, &d)
            ccall(($(string(:__gmpz_,fC)), :libgmp), Void, (Ptr{BigInt}, Ptr{BigInt}, Ptr{BigInt}), &z, &z, &e)
            return z
        end
    end
end

# Basic arithmetic without promotion
function +(x::BigInt, c::Culong)
    z = BigInt()
    ccall((:__gmpz_add_ui, :libgmp), Void, (Ptr{BigInt}, Ptr{BigInt}, Culong), &z, &x, c)
    return z
end
+(c::Culong, x::BigInt) = x + c
+(c::CulongMax, x::BigInt) = x + convert(Culong, c)
+(x::BigInt, c::CulongMax) = x + convert(Culong, c)
+(x::BigInt, c::ClongMax) = c < 0 ? -(x, convert(Culong, -c)) : x + convert(Culong, c)
+(c::ClongMax, x::BigInt) = c < 0 ? -(x, convert(Culong, -c)) : x + convert(Culong, c)

function -(x::BigInt, c::Culong)
    z = BigInt()
    ccall((:__gmpz_sub_ui, :libgmp), Void, (Ptr{BigInt}, Ptr{BigInt}, Culong), &z, &x, c)
    return z
end
function -(c::Culong, x::BigInt)
    z = BigInt()
    ccall((:__gmpz_ui_sub, :libgmp), Void, (Ptr{BigInt}, Culong, Ptr{BigInt}), &z, c, &x)
    return z
end
-(x::BigInt, c::CulongMax) = -(x, convert(Culong, c))
-(c::CulongMax, x::BigInt) = -(convert(Culong, c), x)
-(x::BigInt, c::ClongMax) = c < 0 ? +(x, convert(Culong, -c)) : -(x, convert(Culong, c))
-(c::ClongMax, x::BigInt) = c < 0 ? -(x + convert(Culong, -c)) : -(convert(Culong, c), x)

function *(x::BigInt, c::Culong)
    z = BigInt()
    ccall((:__gmpz_mul_ui, :libgmp), Void, (Ptr{BigInt}, Ptr{BigInt}, Culong), &z, &x, c)
    return z
end
*(c::Culong, x::BigInt) = x * c
*(c::CulongMax, x::BigInt) = x * convert(Culong, c)
*(x::BigInt, c::CulongMax) = x * convert(Culong, c)
function *(x::BigInt, c::Clong)
    z = BigInt()
    ccall((:__gmpz_mul_si, :libgmp), Void, (Ptr{BigInt}, Ptr{BigInt}, Clong), &z, &x, c)
    return z
end
*(c::Clong, x::BigInt) = x * c
*(x::BigInt, c::ClongMax) = x * convert(Clong, c)
*(c::ClongMax, x::BigInt) = x * convert(Clong, c)

# unary ops
for (fJ, fC) in ((:-, :neg), (:~, :com))
    @eval begin
        function ($fJ)(x::BigInt)
            z = BigInt()
            ccall(($(string(:__gmpz_,fC)), :libgmp), Void, (Ptr{BigInt}, Ptr{BigInt}), &z, &x)
            return z
        end
    end
end

function <<(x::BigInt, c::Int32)
    c < 0 && throw(DomainError())
    c == 0 && return x
    z = BigInt()
    ccall((:__gmpz_mul_2exp, :libgmp), Void, (Ptr{BigInt}, Ptr{BigInt}, Culong), &z, &x, c)
    return z
end

function >>(x::BigInt, c::Int32)
    c < 0 && throw(DomainError())
    c == 0 && return x
    z = BigInt()
    ccall((:__gmpz_fdiv_q_2exp, :libgmp), Void, (Ptr{BigInt}, Ptr{BigInt}, Culong), &z, &x, c)
    return z
end

>>>(x::BigInt, c::Int32) = x >> c

trailing_zeros(x::BigInt) = int(ccall((:__gmpz_scan1, :libgmp), Culong, (Ptr{BigInt}, Culong), &x, 0))
trailing_ones(x::BigInt) = int(ccall((:__gmpz_scan0, :libgmp), Culong, (Ptr{BigInt}, Culong), &x, 0))

count_ones(x::BigInt) = int(ccall((:__gmpz_popcount, :libgmp), Culong, (Ptr{BigInt},), &x))

function divrem(x::BigInt, y::BigInt)
    z1 = BigInt()
    z2 = BigInt()
    ccall((:__gmpz_tdiv_qr, :libgmp), Void, (Ptr{BigInt}, Ptr{BigInt}, Ptr{BigInt}, Ptr{BigInt}), &z1, &z2, &x, &y)
    z1, z2
end

function cmp(x::BigInt, y::BigInt)
    ccall((:__gmpz_cmp, :libgmp), Int32, (Ptr{BigInt}, Ptr{BigInt}), &x, &y)
end

function isqrt(x::BigInt)
    z = BigInt()
    ccall((:__gmpz_sqrt, :libgmp), Void, (Ptr{BigInt}, Ptr{BigInt}), &z, &x)
    return z
end

function ^(x::BigInt, y::Uint)
    z = BigInt()
    ccall((:__gmpz_pow_ui, :libgmp), Void, (Ptr{BigInt}, Ptr{BigInt}, Culong), &z, &x, y)
    return z
end

function bigint_pow(x::BigInt, y::Integer)
    if y<0; throw(DomainError()); end
    if x== 1; return x; end
    if x==-1; return isodd(y) ? x : -x; end
    if y>typemax(Uint); throw(DomainError()); end
    return x^uint(y)
end

^(x::BigInt , y::BigInt ) = bigint_pow(x, y)
^(x::BigInt , y::Bool   ) = y ? x : one(x)
^(x::BigInt , y::Integer) = bigint_pow(x, y)
^(x::Integer, y::BigInt ) = bigint_pow(BigInt(x), y)

function powermod(x::BigInt, p::BigInt, m::BigInt)
    p < 0 && throw(DomainError())
    r = BigInt()
    ccall((:__gmpz_powm, :libgmp), Void,
          (Ptr{BigInt}, Ptr{BigInt}, Ptr{BigInt}, Ptr{BigInt}),
          &r, &x, &p, &m)
    return m < 0 && r > 0 ? r + m : r # choose sign conistent with mod(x^p, m)
end
powermod(x::BigInt, p::Integer, m::BigInt) = powermod(x, BigInt(p), m)
powermod(x::BigInt, p::Integer, m::Integer) = powermod(x, BigInt(p), BigInt(m))

function gcdx(a::BigInt, b::BigInt)
    if b == 0 # shortcut this to ensure consistent results with gcdx(a,b)
        return a < 0 ? (-a,-one(BigInt),zero(BigInt)) : (a,one(BigInt),zero(BigInt))
    end
    g = BigInt()
    s = BigInt()
    t = BigInt()
    ccall((:__gmpz_gcdext, :libgmp), Void,
        (Ptr{BigInt}, Ptr{BigInt}, Ptr{BigInt}, Ptr{BigInt}, Ptr{BigInt}),
        &g, &s, &t, &a, &b)
    if t == 0
        # work around a difference in some versions of GMP
        if a == b
            return g, t, s
        elseif abs(a)==abs(b)
            return g, t, -s
        end
    end
    g, s, t
end

function sum(arr::AbstractArray{BigInt})
    n = BigInt(0)
    for i in arr
        ccall((:__gmpz_add, :libgmp), Void,
            (Ptr{BigInt}, Ptr{BigInt}, Ptr{BigInt}),
            &n, &n, &i)
    end
    return n
end

function factorial(x::BigInt)
    x.size < 0 && return BigInt(0)
    z = BigInt()
    ccall((:__gmpz_fac_ui, :libgmp), Void, (Ptr{BigInt}, Culong), &z, x)
    return z
end

function binomial(n::BigInt, k::Uint)
    z = BigInt()
    ccall((:__gmpz_bin_ui, :libgmp), Void, (Ptr{BigInt}, Ptr{BigInt}, Culong), &z, &n, k)
    return z
end
binomial(n::BigInt, k::Integer) = k < 0 ? throw(DomainError()) : binomial(n, uint(k))

==(x::BigInt, y::BigInt) = cmp(x,y) == 0
<=(x::BigInt, y::BigInt) = cmp(x,y) <= 0
>=(x::BigInt, y::BigInt) = cmp(x,y) >= 0
<(x::BigInt, y::BigInt) = cmp(x,y) < 0
>(x::BigInt, y::BigInt) = cmp(x,y) > 0

string(x::BigInt) = dec(x)
show(io::IO, x::BigInt) = print(io, string(x))

bin(n::BigInt) = base( 2, n)
oct(n::BigInt) = base( 8, n)
dec(n::BigInt) = base(10, n)
hex(n::BigInt) = base(16, n)

function base(b::Integer, n::BigInt)
    2 <= b <= 62 || error("invalid base: $b")
    p = ccall((:__gmpz_get_str,:libgmp), Ptr{Uint8}, (Ptr{Uint8}, Cint, Ptr{BigInt}), C_NULL, b, &n)
    len = int(ccall(:strlen, Csize_t, (Ptr{Uint8},), p))
    ASCIIString(pointer_to_array(p,len,true))
end

function ndigits0z(x::BigInt, b::Integer=10)
    # mpz_sizeinbase might return an answer 1 too big
    n = int(ccall((:__gmpz_sizeinbase,:libgmp), Culong, (Ptr{BigInt}, Int32), &x, b))
    abs(x) < big(b)^(n-1) ? n-1 : n
end
ndigits(x::BigInt, b::Integer=10) = x.size == 0 ? 1 : ndigits0z(x,b)

isprime(x::BigInt, reps=25) = ccall((:__gmpz_probab_prime_p,:libgmp), Cint, (Ptr{BigInt}, Cint), &x, reps) > 0

widemul(x::Int128, y::Uint128)  = BigInt(x)*BigInt(y)
widemul(x::Uint128, y::Int128)  = BigInt(x)*BigInt(y)

prevpow2(x::BigInt) = x.size < 0 ? -prevpow2(-x) : (x <= 2 ? x : one(BigInt) << (ndigits(x, 2)-1))
nextpow2(x::BigInt) = x.size < 0 ? -nextpow2(-x) : (x <= 2 ? x : one(BigInt) << ndigits(x-1, 2))

end # module