// Copyright 2009 The Go Authors. All rights reserved.
// Use of this source code is governed by a BSD-style
// license that can be found in the LICENSE file.
// This file provides Go implementations of elementary multi-precision
// arithmetic operations on word vectors. These have the suffix _g.
// These are needed for platforms without assembly implementations of these routines.
// This file also contains elementary operations that can be implemented
// sufficiently efficiently in Go.
package big
import "math/bits"
// A Word represents a single digit of a multi-precision unsigned integer.
type Word uint
const (
_S = _W / 8 // word size in bytes
_W = bits.UintSize // word size in bits
_B = 1 << _W // digit base
_M = _B - 1 // digit mask
)
// Many of the loops in this file are of the form
// for i := 0; i < len(z) && i < len(x) && i < len(y); i++
// i < len(z) is the real condition.
// However, checking i < len(x) && i < len(y) as well is faster than
// having the compiler do a bounds check in the body of the loop;
// remarkably it is even faster than hoisting the bounds check
// out of the loop, by doing something like
// _, _ = x[len(z)-1], y[len(z)-1]
// There are other ways to hoist the bounds check out of the loop,
// but the compiler's BCE isn't powerful enough for them (yet?).
// See the discussion in CL 164966.
// ----------------------------------------------------------------------------
// Elementary operations on words
//
// These operations are used by the vector operations below.
// z1<<_W + z0 = x*y
func mulWW_g(x, y Word) (z1, z0 Word) {
hi, lo := bits.Mul(uint(x), uint(y))
return Word(hi), Word(lo)
}
// z1<<_W + z0 = x*y + c
func mulAddWWW_g(x, y, c Word) (z1, z0 Word) {
hi, lo := bits.Mul(uint(x), uint(y))
var cc uint
lo, cc = bits.Add(lo, uint(c), 0)
return Word(hi + cc), Word(lo)
}
// nlz returns the number of leading zeros in x.
// Wraps bits.LeadingZeros call for convenience.
func nlz(x Word) uint {
return uint(bits.LeadingZeros(uint(x)))
}
// q = (u1<<_W + u0 - r)/v
func divWW_g(u1, u0, v Word) (q, r Word) {
qq, rr := bits.Div(uint(u1), uint(u0), uint(v))
return Word(qq), Word(rr)
}
// The resulting carry c is either 0 or 1.
func addVV_g(z, x, y []Word) (c Word) {
// The comment near the top of this file discusses this for loop condition.
for i := 0; i < len(z) && i < len(x) && i < len(y); i++ {
zi, cc := bits.Add(uint(x[i]), uint(y[i]), uint(c))
z[i] = Word(zi)
c = Word(cc)
}
return
}
// The resulting carry c is either 0 or 1.
func subVV_g(z, x, y []Word) (c Word) {
// The comment near the top of this file discusses this for loop condition.
for i := 0; i < len(z) && i < len(x) && i < len(y); i++ {
zi, cc := bits.Sub(uint(x[i]), uint(y[i]), uint(c))
z[i] = Word(zi)
c = Word(cc)
}
return
}
// The resulting carry c is either 0 or 1.
func addVW_g(z, x []Word, y Word) (c Word) {
c = y
// The comment near the top of this file discusses this for loop condition.
for i := 0; i < len(z) && i < len(x); i++ {
zi, cc := bits.Add(uint(x[i]), uint(c), 0)
z[i] = Word(zi)
c = Word(cc)
}
return
}
// addVWlarge is addVW, but intended for large z.
// The only difference is that we check on every iteration
// whether we are done with carries,
// and if so, switch to a much faster copy instead.
// This is only a good idea for large z,
// because the overhead of the check and the function call
// outweigh the benefits when z is small.
func addVWlarge(z, x []Word, y Word) (c Word) {
c = y
// The comment near the top of this file discusses this for loop condition.
for i := 0; i < len(z) && i < len(x); i++ {
if c == 0 {
copy(z[i:], x[i:])
return
}
zi, cc := bits.Add(uint(x[i]), uint(c), 0)
z[i] = Word(zi)
c = Word(cc)
}
return
}
func subVW_g(z, x []Word, y Word) (c Word) {
c = y
// The comment near the top of this file discusses this for loop condition.
for i := 0; i < len(z) && i < len(x); i++ {
zi, cc := bits.Sub(uint(x[i]), uint(c), 0)
z[i] = Word(zi)
c = Word(cc)
}
return
}
// subVWlarge is to subVW as addVWlarge is to addVW.
func subVWlarge(z, x []Word, y Word) (c Word) {
c = y
// The comment near the top of this file discusses this for loop condition.
for i := 0; i < len(z) && i < len(x); i++ {
if c == 0 {
copy(z[i:], x[i:])
return
}
zi, cc := bits.Sub(uint(x[i]), uint(c), 0)
z[i] = Word(zi)
c = Word(cc)
}
return
}
func shlVU_g(z, x []Word, s uint) (c Word) {
if s == 0 {
copy(z, x)
return
}
if len(z) == 0 {
return
}
s &= _W - 1 // hint to the compiler that shifts by s don't need guard code
ŝ := _W - s
ŝ &= _W - 1 // ditto
c = x[len(z)-1] >> ŝ
for i := len(z) - 1; i > 0; i-- {
z[i] = x[i]<<s | x[i-1]>>ŝ
}
z[0] = x[0] << s
return
}
func shrVU_g(z, x []Word, s uint) (c Word) {
if s == 0 {
copy(z, x)
return
}
if len(z) == 0 {
return
}
s &= _W - 1 // hint to the compiler that shifts by s don't need guard code
ŝ := _W - s
ŝ &= _W - 1 // ditto
c = x[0] << ŝ
for i := 0; i < len(z)-1; i++ {
z[i] = x[i]>>s | x[i+1]<<ŝ
}
z[len(z)-1] = x[len(z)-1] >> s
return
}
func mulAddVWW_g(z, x []Word, y, r Word) (c Word) {
c = r
// The comment near the top of this file discusses this for loop condition.
for i := 0; i < len(z) && i < len(x); i++ {
c, z[i] = mulAddWWW_g(x[i], y, c)
}
return
}
func addMulVVW_g(z, x []Word, y Word) (c Word) {
// The comment near the top of this file discusses this for loop condition.
for i := 0; i < len(z) && i < len(x); i++ {
z1, z0 := mulAddWWW_g(x[i], y, z[i])
lo, cc := bits.Add(uint(z0), uint(c), 0)
c, z[i] = Word(cc), Word(lo)
c += z1
}
return
}
func divWVW_g(z []Word, xn Word, x []Word, y Word) (r Word) {
r = xn
for i := len(z) - 1; i >= 0; i-- {
z[i], r = divWW_g(r, x[i], y)
}
return
}
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