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146 lines
3.8 KiB
Go
146 lines
3.8 KiB
Go
package inf
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import (
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"math/big"
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)
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// Rounder represents a method for rounding the (possibly infinite decimal)
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// result of a division to a finite Dec. It is used by Dec.Round() and
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// Dec.Quo().
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//
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// See the Example for results of using each Rounder with some sample values.
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//
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type Rounder rounder
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// See http://speleotrove.com/decimal/damodel.html#refround for more detailed
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// definitions of these rounding modes.
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var (
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RoundDown Rounder // towards 0
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RoundUp Rounder // away from 0
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RoundFloor Rounder // towards -infinity
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RoundCeil Rounder // towards +infinity
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RoundHalfDown Rounder // to nearest; towards 0 if same distance
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RoundHalfUp Rounder // to nearest; away from 0 if same distance
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RoundHalfEven Rounder // to nearest; even last digit if same distance
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)
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// RoundExact is to be used in the case when rounding is not necessary.
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// When used with Quo or Round, it returns the result verbatim when it can be
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// expressed exactly with the given precision, and it returns nil otherwise.
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// QuoExact is a shorthand for using Quo with RoundExact.
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var RoundExact Rounder
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type rounder interface {
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// When UseRemainder() returns true, the Round() method is passed the
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// remainder of the division, expressed as the numerator and denominator of
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// a rational.
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UseRemainder() bool
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// Round sets the rounded value of a quotient to z, and returns z.
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// quo is rounded down (truncated towards zero) to the scale obtained from
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// the Scaler in Quo().
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//
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// When the remainder is not used, remNum and remDen are nil.
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// When used, the remainder is normalized between -1 and 1; that is:
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//
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// -|remDen| < remNum < |remDen|
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//
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// remDen has the same sign as y, and remNum is zero or has the same sign
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// as x.
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Round(z, quo *Dec, remNum, remDen *big.Int) *Dec
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}
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type rndr struct {
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useRem bool
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round func(z, quo *Dec, remNum, remDen *big.Int) *Dec
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}
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func (r rndr) UseRemainder() bool {
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return r.useRem
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}
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func (r rndr) Round(z, quo *Dec, remNum, remDen *big.Int) *Dec {
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return r.round(z, quo, remNum, remDen)
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}
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var intSign = []*big.Int{big.NewInt(-1), big.NewInt(0), big.NewInt(1)}
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func roundHalf(f func(c int, odd uint) (roundUp bool)) func(z, q *Dec, rA, rB *big.Int) *Dec {
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return func(z, q *Dec, rA, rB *big.Int) *Dec {
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z.Set(q)
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brA, brB := rA.BitLen(), rB.BitLen()
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if brA < brB-1 {
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// brA < brB-1 => |rA| < |rB/2|
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return z
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}
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roundUp := false
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srA, srB := rA.Sign(), rB.Sign()
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s := srA * srB
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if brA == brB-1 {
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rA2 := new(big.Int).Lsh(rA, 1)
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if s < 0 {
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rA2.Neg(rA2)
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}
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roundUp = f(rA2.Cmp(rB)*srB, z.UnscaledBig().Bit(0))
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} else {
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// brA > brB-1 => |rA| > |rB/2|
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roundUp = true
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}
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if roundUp {
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z.UnscaledBig().Add(z.UnscaledBig(), intSign[s+1])
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}
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return z
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}
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}
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func init() {
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RoundExact = rndr{true,
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func(z, q *Dec, rA, rB *big.Int) *Dec {
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if rA.Sign() != 0 {
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return nil
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}
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return z.Set(q)
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}}
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RoundDown = rndr{false,
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func(z, q *Dec, rA, rB *big.Int) *Dec {
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return z.Set(q)
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}}
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RoundUp = rndr{true,
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func(z, q *Dec, rA, rB *big.Int) *Dec {
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z.Set(q)
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if rA.Sign() != 0 {
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z.UnscaledBig().Add(z.UnscaledBig(), intSign[rA.Sign()*rB.Sign()+1])
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}
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return z
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}}
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RoundFloor = rndr{true,
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func(z, q *Dec, rA, rB *big.Int) *Dec {
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z.Set(q)
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if rA.Sign()*rB.Sign() < 0 {
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z.UnscaledBig().Add(z.UnscaledBig(), intSign[0])
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}
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return z
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}}
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RoundCeil = rndr{true,
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func(z, q *Dec, rA, rB *big.Int) *Dec {
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z.Set(q)
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if rA.Sign()*rB.Sign() > 0 {
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z.UnscaledBig().Add(z.UnscaledBig(), intSign[2])
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}
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return z
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}}
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RoundHalfDown = rndr{true, roundHalf(
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func(c int, odd uint) bool {
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return c > 0
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})}
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RoundHalfUp = rndr{true, roundHalf(
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func(c int, odd uint) bool {
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return c >= 0
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})}
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RoundHalfEven = rndr{true, roundHalf(
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func(c int, odd uint) bool {
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return c > 0 || c == 0 && odd == 1
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})}
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}
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