vendor/k8s.io/apimachinery/pkg/api/resource/math.go - cloudstack-kubernetes-provider - Git at Google

 /*
 Copyright 2014 The Kubernetes Authors.

 Licensed under the Apache License, Version 2.0 (the "License");
 you may not use this file except in compliance with the License.
 You may obtain a copy of the License at

     http://www.apache.org/licenses/LICENSE-2.0

 Unless required by applicable law or agreed to in writing, software
 distributed under the License is distributed on an "AS IS" BASIS,
 WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
 See the License for the specific language governing permissions and
 limitations under the License.
 */

 package resource

 import (
 	"math/big"

 	inf "gopkg.in/inf.v0"
 )

 const (
 	// maxInt64Factors is the highest value that will be checked when removing factors of 10 from an int64.
 	// It is also the maximum decimal digits that can be represented with an int64.
 	maxInt64Factors = 18
 )

 var (
 	// Commonly needed big.Int values-- treat as read only!
 	bigTen      = big.NewInt(10)
 	bigZero     = big.NewInt(0)
 	bigOne      = big.NewInt(1)
 	bigThousand = big.NewInt(1000)
 	big1024     = big.NewInt(1024)

 	// Commonly needed inf.Dec values-- treat as read only!
 	decZero      = inf.NewDec(0, 0)
 	decOne       = inf.NewDec(1, 0)
 	decMinusOne  = inf.NewDec(-1, 0)
 	decThousand  = inf.NewDec(1000, 0)
 	dec1024      = inf.NewDec(1024, 0)
 	decMinus1024 = inf.NewDec(-1024, 0)

 	// Largest (in magnitude) number allowed.
 	maxAllowed = infDecAmount{inf.NewDec((1<<63)-1, 0)} // == max int64

 	// The maximum value we can represent milli-units for.
 	// Compare with the return value of Quantity.Value() to
 	// see if it's safe to use Quantity.MilliValue().
 	MaxMilliValue = int64(((1 << 63) - 1) / 1000)
 )

 const mostNegative = -(mostPositive + 1)
 const mostPositive = 1<<63 - 1

 // int64Add returns a+b, or false if that would overflow int64.
 func int64Add(a, b int64) (int64, bool) {
 	c := a + b
 	switch {
 	case a > 0 && b > 0:
 		if c < 0 {
 			return 0, false
 		}
 	case a < 0 && b < 0:
 		if c > 0 {
 			return 0, false
 		}
 		if a == mostNegative && b == mostNegative {
 			return 0, false
 		}
 	}
 	return c, true
 }

 // int64Multiply returns a*b, or false if that would overflow or underflow int64.
 func int64Multiply(a, b int64) (int64, bool) {
 	if a == 0 || b == 0 || a == 1 || b == 1 {
 		return a * b, true
 	}
 	if a == mostNegative || b == mostNegative {
 		return 0, false
 	}
 	c := a * b
 	return c, c/b == a
 }

 // int64MultiplyScale returns a*b, assuming b is greater than one, or false if that would overflow or underflow int64.
 // Use when b is known to be greater than one.
 func int64MultiplyScale(a int64, b int64) (int64, bool) {
 	if a == 0 || a == 1 {
 		return a * b, true
 	}
 	if a == mostNegative && b != 1 {
 		return 0, false
 	}
 	c := a * b
 	return c, c/b == a
 }

 // int64MultiplyScale10 multiplies a by 10, or returns false if that would overflow. This method is faster than
 // int64Multiply(a, 10) because the compiler can optimize constant factor multiplication.
 func int64MultiplyScale10(a int64) (int64, bool) {
 	if a == 0 || a == 1 {
 		return a * 10, true
 	}
 	if a == mostNegative {
 		return 0, false
 	}
 	c := a * 10
 	return c, c/10 == a
 }

 // int64MultiplyScale100 multiplies a by 100, or returns false if that would overflow. This method is faster than
 // int64Multiply(a, 100) because the compiler can optimize constant factor multiplication.
 func int64MultiplyScale100(a int64) (int64, bool) {
 	if a == 0 || a == 1 {
 		return a * 100, true
 	}
 	if a == mostNegative {
 		return 0, false
 	}
 	c := a * 100
 	return c, c/100 == a
 }

 // int64MultiplyScale1000 multiplies a by 1000, or returns false if that would overflow. This method is faster than
 // int64Multiply(a, 1000) because the compiler can optimize constant factor multiplication.
 func int64MultiplyScale1000(a int64) (int64, bool) {
 	if a == 0 || a == 1 {
 		return a * 1000, true
 	}
 	if a == mostNegative {
 		return 0, false
 	}
 	c := a * 1000
 	return c, c/1000 == a
 }

 // positiveScaleInt64 multiplies base by 10^scale, returning false if the
 // value overflows. Passing a negative scale is undefined.
 func positiveScaleInt64(base int64, scale Scale) (int64, bool) {
 	switch scale {
 	case 0:
 		return base, true
 	case 1:
 		return int64MultiplyScale10(base)
 	case 2:
 		return int64MultiplyScale100(base)
 	case 3:
 		return int64MultiplyScale1000(base)
 	case 6:
 		return int64MultiplyScale(base, 1000000)
 	case 9:
 		return int64MultiplyScale(base, 1000000000)
 	default:
 		value := base
 		var ok bool
 		for i := Scale(0); i < scale; i++ {
 			if value, ok = int64MultiplyScale(value, 10); !ok {
 				return 0, false
 			}
 		}
 		return value, true
 	}
 }

 // negativeScaleInt64 reduces base by the provided scale, rounding up, until the
 // value is zero or the scale is reached. Passing a negative scale is undefined.
 // The value returned, if not exact, is rounded away from zero.
 func negativeScaleInt64(base int64, scale Scale) (result int64, exact bool) {
 	if scale == 0 {
 		return base, true
 	}

 	value := base
 	var fraction bool
 	for i := Scale(0); i < scale; i++ {
 		if !fraction && value%10 != 0 {
 			fraction = true
 		}
 		value = value / 10
 		if value == 0 {
 			if fraction {
 				if base > 0 {
 					return 1, false
 				}
 				return -1, false
 			}
 			return 0, true
 		}
 	}
 	if fraction {
 		if base > 0 {
 			value++
 		} else {
 			value--
 		}
 	}
 	return value, !fraction
 }

 func pow10Int64(b int64) int64 {
 	switch b {
 	case 0:
 		return 1
 	case 1:
 		return 10
 	case 2:
 		return 100
 	case 3:
 		return 1000
 	case 4:
 		return 10000
 	case 5:
 		return 100000
 	case 6:
 		return 1000000
 	case 7:
 		return 10000000
 	case 8:
 		return 100000000
 	case 9:
 		return 1000000000
 	case 10:
 		return 10000000000
 	case 11:
 		return 100000000000
 	case 12:
 		return 1000000000000
 	case 13:
 		return 10000000000000
 	case 14:
 		return 100000000000000
 	case 15:
 		return 1000000000000000
 	case 16:
 		return 10000000000000000
 	case 17:
 		return 100000000000000000
 	case 18:
 		return 1000000000000000000
 	default:
 		return 0
 	}
 }

 // negativeScaleInt64 returns the result of dividing base by scale * 10 and the remainder, or
 // false if no such division is possible. Dividing by negative scales is undefined.
 func divideByScaleInt64(base int64, scale Scale) (result, remainder int64, exact bool) {
 	if scale == 0 {
 		return base, 0, true
 	}
 	// the max scale representable in base 10 in an int64 is 18 decimal places
 	if scale >= 18 {
 		return 0, base, false
 	}
 	divisor := pow10Int64(int64(scale))
 	return base / divisor, base % divisor, true
 }

 // removeInt64Factors divides in a loop; the return values have the property that
 // value == result * base ^ scale
 func removeInt64Factors(value int64, base int64) (result int64, times int32) {
 	times = 0
 	result = value
 	negative := result < 0
 	if negative {
 		result = -result
 	}
 	switch base {
 	// allow the compiler to optimize the common cases
 	case 10:
 		for result >= 10 && result%10 == 0 {
 			times++
 			result = result / 10
 		}
 	// allow the compiler to optimize the common cases
 	case 1024:
 		for result >= 1024 && result%1024 == 0 {
 			times++
 			result = result / 1024
 		}
 	default:
 		for result >= base && result%base == 0 {
 			times++
 			result = result / base
 		}
 	}
 	if negative {
 		result = -result
 	}
 	return result, times
 }

 // removeBigIntFactors divides in a loop; the return values have the property that
 // d == result * factor ^ times
 // d may be modified in place.
 // If d == 0, then the return values will be (0, 0)
 func removeBigIntFactors(d, factor *big.Int) (result *big.Int, times int32) {
 	q := big.NewInt(0)
 	m := big.NewInt(0)
 	for d.Cmp(bigZero) != 0 {
 		q.DivMod(d, factor, m)
 		if m.Cmp(bigZero) != 0 {
 			break
 		}
 		times++
 		d, q = q, d
 	}
 	return d, times
 }
	/*
	Copyright 2014 The Kubernetes Authors.

	Licensed under the Apache License, Version 2.0 (the "License");
	you may not use this file except in compliance with the License.
	You may obtain a copy of the License at

	http://www.apache.org/licenses/LICENSE-2.0

	Unless required by applicable law or agreed to in writing, software
	distributed under the License is distributed on an "AS IS" BASIS,
	WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
	See the License for the specific language governing permissions and
	limitations under the License.
	*/

	package resource

	import (
	"math/big"

	inf "gopkg.in/inf.v0"
	)

	const (
	// maxInt64Factors is the highest value that will be checked when removing factors of 10 from an int64.
	// It is also the maximum decimal digits that can be represented with an int64.
	maxInt64Factors = 18
	)

	var (
	// Commonly needed big.Int values-- treat as read only!
	bigTen = big.NewInt(10)
	bigZero = big.NewInt(0)
	bigOne = big.NewInt(1)
	bigThousand = big.NewInt(1000)
	big1024 = big.NewInt(1024)

	// Commonly needed inf.Dec values-- treat as read only!
	decZero = inf.NewDec(0, 0)
	decOne = inf.NewDec(1, 0)
	decMinusOne = inf.NewDec(-1, 0)
	decThousand = inf.NewDec(1000, 0)
	dec1024 = inf.NewDec(1024, 0)
	decMinus1024 = inf.NewDec(-1024, 0)

	// Largest (in magnitude) number allowed.
	maxAllowed = infDecAmount{inf.NewDec((1<<63)-1, 0)} // == max int64

	// The maximum value we can represent milli-units for.
	// Compare with the return value of Quantity.Value() to
	// see if it's safe to use Quantity.MilliValue().
	MaxMilliValue = int64(((1 << 63) - 1) / 1000)
	)

	const mostNegative = -(mostPositive + 1)
	const mostPositive = 1<<63 - 1

	// int64Add returns a+b, or false if that would overflow int64.
	func int64Add(a, b int64) (int64, bool) {
	c := a + b
	switch {
	case a > 0 && b > 0:
	if c < 0 {
	return 0, false
	}
	case a < 0 && b < 0:
	if c > 0 {
	return 0, false
	}
	if a == mostNegative && b == mostNegative {
	return 0, false
	}
	}
	return c, true
	}

	// int64Multiply returns a*b, or false if that would overflow or underflow int64.
	func int64Multiply(a, b int64) (int64, bool) {
	if a == 0 \|\| b == 0 \|\| a == 1 \|\| b == 1 {
	return a * b, true
	}
	if a == mostNegative \|\| b == mostNegative {
	return 0, false
	}
	c := a * b
	return c, c/b == a
	}

	// int64MultiplyScale returns a*b, assuming b is greater than one, or false if that would overflow or underflow int64.
	// Use when b is known to be greater than one.
	func int64MultiplyScale(a int64, b int64) (int64, bool) {
	if a == 0 \|\| a == 1 {
	return a * b, true
	}
	if a == mostNegative && b != 1 {
	return 0, false
	}
	c := a * b
	return c, c/b == a
	}

	// int64MultiplyScale10 multiplies a by 10, or returns false if that would overflow. This method is faster than
	// int64Multiply(a, 10) because the compiler can optimize constant factor multiplication.
	func int64MultiplyScale10(a int64) (int64, bool) {
	if a == 0 \|\| a == 1 {
	return a * 10, true
	}
	if a == mostNegative {
	return 0, false
	}
	c := a * 10
	return c, c/10 == a
	}

	// int64MultiplyScale100 multiplies a by 100, or returns false if that would overflow. This method is faster than
	// int64Multiply(a, 100) because the compiler can optimize constant factor multiplication.
	func int64MultiplyScale100(a int64) (int64, bool) {
	if a == 0 \|\| a == 1 {
	return a * 100, true
	}
	if a == mostNegative {
	return 0, false
	}
	c := a * 100
	return c, c/100 == a
	}

	// int64MultiplyScale1000 multiplies a by 1000, or returns false if that would overflow. This method is faster than
	// int64Multiply(a, 1000) because the compiler can optimize constant factor multiplication.
	func int64MultiplyScale1000(a int64) (int64, bool) {
	if a == 0 \|\| a == 1 {
	return a * 1000, true
	}
	if a == mostNegative {
	return 0, false
	}
	c := a * 1000
	return c, c/1000 == a
	}

	// positiveScaleInt64 multiplies base by 10^scale, returning false if the
	// value overflows. Passing a negative scale is undefined.
	func positiveScaleInt64(base int64, scale Scale) (int64, bool) {
	switch scale {
	case 0:
	return base, true
	case 1:
	return int64MultiplyScale10(base)
	case 2:
	return int64MultiplyScale100(base)
	case 3:
	return int64MultiplyScale1000(base)
	case 6:
	return int64MultiplyScale(base, 1000000)
	case 9:
	return int64MultiplyScale(base, 1000000000)
	default:
	value := base
	var ok bool
	for i := Scale(0); i < scale; i++ {
	if value, ok = int64MultiplyScale(value, 10); !ok {
	return 0, false
	}
	}
	return value, true
	}
	}

	// negativeScaleInt64 reduces base by the provided scale, rounding up, until the
	// value is zero or the scale is reached. Passing a negative scale is undefined.
	// The value returned, if not exact, is rounded away from zero.
	func negativeScaleInt64(base int64, scale Scale) (result int64, exact bool) {
	if scale == 0 {
	return base, true
	}

	value := base
	var fraction bool
	for i := Scale(0); i < scale; i++ {
	if !fraction && value%10 != 0 {
	fraction = true
	}
	value = value / 10
	if value == 0 {
	if fraction {
	if base > 0 {
	return 1, false
	}
	return -1, false
	}
	return 0, true
	}
	}
	if fraction {
	if base > 0 {
	value++
	} else {
	value--
	}
	}
	return value, !fraction
	}

	func pow10Int64(b int64) int64 {
	switch b {
	case 0:
	return 1
	case 1:
	return 10
	case 2:
	return 100
	case 3:
	return 1000
	case 4:
	return 10000
	case 5:
	return 100000
	case 6:
	return 1000000
	case 7:
	return 10000000
	case 8:
	return 100000000
	case 9:
	return 1000000000
	case 10:
	return 10000000000
	case 11:
	return 100000000000
	case 12:
	return 1000000000000
	case 13:
	return 10000000000000
	case 14:
	return 100000000000000
	case 15:
	return 1000000000000000
	case 16:
	return 10000000000000000
	case 17:
	return 100000000000000000
	case 18:
	return 1000000000000000000
	default:
	return 0
	}
	}

	// negativeScaleInt64 returns the result of dividing base by scale * 10 and the remainder, or
	// false if no such division is possible. Dividing by negative scales is undefined.
	func divideByScaleInt64(base int64, scale Scale) (result, remainder int64, exact bool) {
	if scale == 0 {
	return base, 0, true
	}
	// the max scale representable in base 10 in an int64 is 18 decimal places
	if scale >= 18 {
	return 0, base, false
	}
	divisor := pow10Int64(int64(scale))
	return base / divisor, base % divisor, true
	}

	// removeInt64Factors divides in a loop; the return values have the property that
	// value == result * base ^ scale
	func removeInt64Factors(value int64, base int64) (result int64, times int32) {
	times = 0
	result = value
	negative := result < 0
	if negative {
	result = -result
	}
	switch base {
	// allow the compiler to optimize the common cases
	case 10:
	for result >= 10 && result%10 == 0 {
	times++
	result = result / 10
	}
	// allow the compiler to optimize the common cases
	case 1024:
	for result >= 1024 && result%1024 == 0 {
	times++
	result = result / 1024
	}
	default:
	for result >= base && result%base == 0 {
	times++
	result = result / base
	}
	}
	if negative {
	result = -result
	}
	return result, times
	}

	// removeBigIntFactors divides in a loop; the return values have the property that
	// d == result * factor ^ times
	// d may be modified in place.
	// If d == 0, then the return values will be (0, 0)
	func removeBigIntFactors(d, factor big.Int) (result big.Int, times int32) {
	q := big.NewInt(0)
	m := big.NewInt(0)
	for d.Cmp(bigZero) != 0 {
	q.DivMod(d, factor, m)
	if m.Cmp(bigZero) != 0 {
	break
	}
	times++
	d, q = q, d
	}
	return d, times
	}