k3s/vendor/go.starlark.net/starlark/int.go

// Copyright 2017 The Bazel Authors. All rights reserved.
// Use of this source code is governed by a BSD-style
// license that can be found in the LICENSE file.

package starlark

import (
	"fmt"
	"math"
	"math/big"
	"strconv"

	"go.starlark.net/syntax"
)

// Int is the type of a Starlark int.
type Int struct {
	// We use only the signed 32 bit range of small to ensure
	// that small+small and small*small do not overflow.

	small int64    // minint32 <= small <= maxint32
	big   *big.Int // big != nil <=> value is not representable as int32
}

// newBig allocates a new big.Int.
func newBig(x int64) *big.Int {
	if 0 <= x && int64(big.Word(x)) == x {
		// x is guaranteed to fit into a single big.Word.
		// Most starlark ints are small,
		// but math/big assumes that since you've chosen to use math/big,
		// your big.Ints will probably grow, so it over-allocates.
		// Avoid that over-allocation by manually constructing a single-word slice.
		// See https://golang.org/cl/150999, which will hopefully land in Go 1.13.
		return new(big.Int).SetBits([]big.Word{big.Word(x)})
	}
	return big.NewInt(x)
}

// MakeInt returns a Starlark int for the specified signed integer.
func MakeInt(x int) Int { return MakeInt64(int64(x)) }

// MakeInt64 returns a Starlark int for the specified int64.
func MakeInt64(x int64) Int {
	if math.MinInt32 <= x && x <= math.MaxInt32 {
		return Int{small: x}
	}
	return Int{big: newBig(x)}
}

// MakeUint returns a Starlark int for the specified unsigned integer.
func MakeUint(x uint) Int { return MakeUint64(uint64(x)) }

// MakeUint64 returns a Starlark int for the specified uint64.
func MakeUint64(x uint64) Int {
	if x <= math.MaxInt32 {
		return Int{small: int64(x)}
	}
	if uint64(big.Word(x)) == x {
		// See comment in newBig for an explanation of this optimization.
		return Int{big: new(big.Int).SetBits([]big.Word{big.Word(x)})}
	}
	return Int{big: new(big.Int).SetUint64(x)}
}

// MakeBigInt returns a Starlark int for the specified big.Int.
// The caller must not subsequently modify x.
func MakeBigInt(x *big.Int) Int {
	if n := x.BitLen(); n < 32 || n == 32 && x.Int64() == math.MinInt32 {
		return Int{small: x.Int64()}
	}
	return Int{big: x}
}

var (
	zero, one = Int{small: 0}, Int{small: 1}
	oneBig    = newBig(1)

	_ HasUnary = Int{}
)

// Unary implements the operations +int, -int, and ~int.
func (i Int) Unary(op syntax.Token) (Value, error) {
	switch op {
	case syntax.MINUS:
		return zero.Sub(i), nil
	case syntax.PLUS:
		return i, nil
	case syntax.TILDE:
		return i.Not(), nil
	}
	return nil, nil
}

// Int64 returns the value as an int64.
// If it is not exactly representable the result is undefined and ok is false.
func (i Int) Int64() (_ int64, ok bool) {
	if i.big != nil {
		x, acc := bigintToInt64(i.big)
		if acc != big.Exact {
			return // inexact
		}
		return x, true
	}
	return i.small, true
}

// BigInt returns the value as a big.Int.
// The returned variable must not be modified by the client.
func (i Int) BigInt() *big.Int {
	if i.big != nil {
		return i.big
	}
	return newBig(i.small)
}

// Uint64 returns the value as a uint64.
// If it is not exactly representable the result is undefined and ok is false.
func (i Int) Uint64() (_ uint64, ok bool) {
	if i.big != nil {
		x, acc := bigintToUint64(i.big)
		if acc != big.Exact {
			return // inexact
		}
		return x, true
	}
	if i.small < 0 {
		return // inexact
	}
	return uint64(i.small), true
}

// The math/big API should provide this function.
func bigintToInt64(i *big.Int) (int64, big.Accuracy) {
	sign := i.Sign()
	if sign > 0 {
		if i.Cmp(maxint64) > 0 {
			return math.MaxInt64, big.Below
		}
	} else if sign < 0 {
		if i.Cmp(minint64) < 0 {
			return math.MinInt64, big.Above
		}
	}
	return i.Int64(), big.Exact
}

// The math/big API should provide this function.
func bigintToUint64(i *big.Int) (uint64, big.Accuracy) {
	sign := i.Sign()
	if sign > 0 {
		if i.BitLen() > 64 {
			return math.MaxUint64, big.Below
		}
	} else if sign < 0 {
		return 0, big.Above
	}
	return i.Uint64(), big.Exact
}

var (
	minint64 = new(big.Int).SetInt64(math.MinInt64)
	maxint64 = new(big.Int).SetInt64(math.MaxInt64)
)

func (i Int) Format(s fmt.State, ch rune) {
	if i.big != nil {
		i.big.Format(s, ch)
		return
	}
	newBig(i.small).Format(s, ch)
}
func (i Int) String() string {
	if i.big != nil {
		return i.big.Text(10)
	}
	return strconv.FormatInt(i.small, 10)
}
func (i Int) Type() string { return "int" }
func (i Int) Freeze()      {} // immutable
func (i Int) Truth() Bool  { return i.Sign() != 0 }
func (i Int) Hash() (uint32, error) {
	var lo big.Word
	if i.big != nil {
		lo = i.big.Bits()[0]
	} else {
		lo = big.Word(i.small)
	}
	return 12582917 * uint32(lo+3), nil
}
func (x Int) CompareSameType(op syntax.Token, v Value, depth int) (bool, error) {
	y := v.(Int)
	if x.big != nil || y.big != nil {
		return threeway(op, x.BigInt().Cmp(y.BigInt())), nil
	}
	return threeway(op, signum64(x.small-y.small)), nil
}

// Float returns the float value nearest i.
func (i Int) Float() Float {
	if i.big != nil {
		f, _ := new(big.Float).SetInt(i.big).Float64()
		return Float(f)
	}
	return Float(i.small)
}

func (x Int) Sign() int {
	if x.big != nil {
		return x.big.Sign()
	}
	return signum64(x.small)
}

func (x Int) Add(y Int) Int {
	if x.big != nil || y.big != nil {
		return MakeBigInt(new(big.Int).Add(x.BigInt(), y.BigInt()))
	}
	return MakeInt64(x.small + y.small)
}
func (x Int) Sub(y Int) Int {
	if x.big != nil || y.big != nil {
		return MakeBigInt(new(big.Int).Sub(x.BigInt(), y.BigInt()))
	}
	return MakeInt64(x.small - y.small)
}
func (x Int) Mul(y Int) Int {
	if x.big != nil || y.big != nil {
		return MakeBigInt(new(big.Int).Mul(x.BigInt(), y.BigInt()))
	}
	return MakeInt64(x.small * y.small)
}
func (x Int) Or(y Int) Int {
	if x.big != nil || y.big != nil {
		return Int{big: new(big.Int).Or(x.BigInt(), y.BigInt())}
	}
	return Int{small: x.small | y.small}
}
func (x Int) And(y Int) Int {
	if x.big != nil || y.big != nil {
		return MakeBigInt(new(big.Int).And(x.BigInt(), y.BigInt()))
	}
	return Int{small: x.small & y.small}
}
func (x Int) Xor(y Int) Int {
	if x.big != nil || y.big != nil {
		return MakeBigInt(new(big.Int).Xor(x.BigInt(), y.BigInt()))
	}
	return Int{small: x.small ^ y.small}
}
func (x Int) Not() Int {
	if x.big != nil {
		return MakeBigInt(new(big.Int).Not(x.big))
	}
	return Int{small: ^x.small}
}
func (x Int) Lsh(y uint) Int { return MakeBigInt(new(big.Int).Lsh(x.BigInt(), y)) }
func (x Int) Rsh(y uint) Int { return MakeBigInt(new(big.Int).Rsh(x.BigInt(), y)) }

// Precondition: y is nonzero.
func (x Int) Div(y Int) Int {
	// http://python-history.blogspot.com/2010/08/why-pythons-integer-division-floors.html
	if x.big != nil || y.big != nil {
		xb, yb := x.BigInt(), y.BigInt()

		var quo, rem big.Int
		quo.QuoRem(xb, yb, &rem)
		if (xb.Sign() < 0) != (yb.Sign() < 0) && rem.Sign() != 0 {
			quo.Sub(&quo, oneBig)
		}
		return MakeBigInt(&quo)
	}
	quo := x.small / y.small
	rem := x.small % y.small
	if (x.small < 0) != (y.small < 0) && rem != 0 {
		quo -= 1
	}
	return MakeInt64(quo)
}

// Precondition: y is nonzero.
func (x Int) Mod(y Int) Int {
	if x.big != nil || y.big != nil {
		xb, yb := x.BigInt(), y.BigInt()

		var quo, rem big.Int
		quo.QuoRem(xb, yb, &rem)
		if (xb.Sign() < 0) != (yb.Sign() < 0) && rem.Sign() != 0 {
			rem.Add(&rem, yb)
		}
		return MakeBigInt(&rem)
	}
	rem := x.small % y.small
	if (x.small < 0) != (y.small < 0) && rem != 0 {
		rem += y.small
	}
	return Int{small: rem}
}

func (i Int) rational() *big.Rat {
	if i.big != nil {
		return new(big.Rat).SetInt(i.big)
	}
	return new(big.Rat).SetInt64(i.small)
}

// AsInt32 returns the value of x if is representable as an int32.
func AsInt32(x Value) (int, error) {
	i, ok := x.(Int)
	if !ok {
		return 0, fmt.Errorf("got %s, want int", x.Type())
	}
	if i.big != nil {
		return 0, fmt.Errorf("%s out of range", i)
	}
	return int(i.small), nil
}

// NumberToInt converts a number x to an integer value.
// An int is returned unchanged, a float is truncated towards zero.
// NumberToInt reports an error for all other values.
func NumberToInt(x Value) (Int, error) {
	switch x := x.(type) {
	case Int:
		return x, nil
	case Float:
		f := float64(x)
		if math.IsInf(f, 0) {
			return zero, fmt.Errorf("cannot convert float infinity to integer")
		} else if math.IsNaN(f) {
			return zero, fmt.Errorf("cannot convert float NaN to integer")
		}
		return finiteFloatToInt(x), nil

	}
	return zero, fmt.Errorf("cannot convert %s to int", x.Type())
}

// finiteFloatToInt converts f to an Int, truncating towards zero.
// f must be finite.
func finiteFloatToInt(f Float) Int {
	if math.MinInt64 <= f && f <= math.MaxInt64 {
		// small values
		return MakeInt64(int64(f))
	}
	rat := f.rational()
	if rat == nil {
		panic(f) // non-finite
	}
	return MakeBigInt(new(big.Int).Div(rat.Num(), rat.Denom()))
}
Update Kubernetes to v1.21.0 * Update Kubernetes to v1.21.0 * Update to golang v1.16.2 * Update dependent modules to track with upstream * Switch to upstream flannel * Track changes to upstream cloud-controller-manager and FeatureGates Signed-off-by: Brad Davidson <brad.davidson@rancher.com> 2021-03-18 22:40:29 +00:00			`// Copyright 2017 The Bazel Authors. All rights reserved.`
			`// Use of this source code is governed by a BSD-style`
			`// license that can be found in the LICENSE file.`

			`package starlark`

			`import (`
			`"fmt"`
			`"math"`
			`"math/big"`
			`"strconv"`

			`"go.starlark.net/syntax"`
			`)`

			`// Int is the type of a Starlark int.`
			`type Int struct {`
			`// We use only the signed 32 bit range of small to ensure`
			`// that small+small and small*small do not overflow.`

			`small int64 // minint32 <= small <= maxint32`
			`big *big.Int // big != nil <=> value is not representable as int32`
			`}`

			`// newBig allocates a new big.Int.`
			`func newBig(x int64) *big.Int {`
			`if 0 <= x && int64(big.Word(x)) == x {`
			`// x is guaranteed to fit into a single big.Word.`
			`// Most starlark ints are small,`
			`// but math/big assumes that since you've chosen to use math/big,`
			`// your big.Ints will probably grow, so it over-allocates.`
			`// Avoid that over-allocation by manually constructing a single-word slice.`
			`// See https://golang.org/cl/150999, which will hopefully land in Go 1.13.`
			`return new(big.Int).SetBits([]big.Word{big.Word(x)})`
			`}`
			`return big.NewInt(x)`
			`}`

			`// MakeInt returns a Starlark int for the specified signed integer.`
			`func MakeInt(x int) Int { return MakeInt64(int64(x)) }`

			`// MakeInt64 returns a Starlark int for the specified int64.`
			`func MakeInt64(x int64) Int {`
			`if math.MinInt32 <= x && x <= math.MaxInt32 {`
			`return Int{small: x}`
			`}`
			`return Int{big: newBig(x)}`
			`}`

			`// MakeUint returns a Starlark int for the specified unsigned integer.`
			`func MakeUint(x uint) Int { return MakeUint64(uint64(x)) }`

			`// MakeUint64 returns a Starlark int for the specified uint64.`
			`func MakeUint64(x uint64) Int {`
			`if x <= math.MaxInt32 {`
			`return Int{small: int64(x)}`
			`}`
			`if uint64(big.Word(x)) == x {`
			`// See comment in newBig for an explanation of this optimization.`
			`return Int{big: new(big.Int).SetBits([]big.Word{big.Word(x)})}`
			`}`
			`return Int{big: new(big.Int).SetUint64(x)}`
			`}`

			`// MakeBigInt returns a Starlark int for the specified big.Int.`
			`// The caller must not subsequently modify x.`
			`func MakeBigInt(x *big.Int) Int {`
			`if n := x.BitLen(); n < 32 \|\| n == 32 && x.Int64() == math.MinInt32 {`
			`return Int{small: x.Int64()}`
			`}`
			`return Int{big: x}`
			`}`

			`var (`
			`zero, one = Int{small: 0}, Int{small: 1}`
			`oneBig = newBig(1)`

			`_ HasUnary = Int{}`
			`)`

			`// Unary implements the operations +int, -int, and ~int.`
			`func (i Int) Unary(op syntax.Token) (Value, error) {`
			`switch op {`
			`case syntax.MINUS:`
			`return zero.Sub(i), nil`
			`case syntax.PLUS:`
			`return i, nil`
			`case syntax.TILDE:`
			`return i.Not(), nil`
			`}`
			`return nil, nil`
			`}`

			`// Int64 returns the value as an int64.`
			`// If it is not exactly representable the result is undefined and ok is false.`
			`func (i Int) Int64() (_ int64, ok bool) {`
			`if i.big != nil {`
			`x, acc := bigintToInt64(i.big)`
			`if acc != big.Exact {`
			`return // inexact`
			`}`
			`return x, true`
			`}`
			`return i.small, true`
			`}`

			`// BigInt returns the value as a big.Int.`
			`// The returned variable must not be modified by the client.`
			`func (i Int) BigInt() *big.Int {`
			`if i.big != nil {`
			`return i.big`
			`}`
			`return newBig(i.small)`
			`}`

			`// Uint64 returns the value as a uint64.`
			`// If it is not exactly representable the result is undefined and ok is false.`
			`func (i Int) Uint64() (_ uint64, ok bool) {`
			`if i.big != nil {`
			`x, acc := bigintToUint64(i.big)`
			`if acc != big.Exact {`
			`return // inexact`
			`}`
			`return x, true`
			`}`
			`if i.small < 0 {`
			`return // inexact`
			`}`
			`return uint64(i.small), true`
			`}`

			`// The math/big API should provide this function.`
			`func bigintToInt64(i *big.Int) (int64, big.Accuracy) {`
			`sign := i.Sign()`
			`if sign > 0 {`
			`if i.Cmp(maxint64) > 0 {`
			`return math.MaxInt64, big.Below`
			`}`
			`} else if sign < 0 {`
			`if i.Cmp(minint64) < 0 {`
			`return math.MinInt64, big.Above`
			`}`
			`}`
			`return i.Int64(), big.Exact`
			`}`

			`// The math/big API should provide this function.`
			`func bigintToUint64(i *big.Int) (uint64, big.Accuracy) {`
			`sign := i.Sign()`
			`if sign > 0 {`
			`if i.BitLen() > 64 {`
			`return math.MaxUint64, big.Below`
			`}`
			`} else if sign < 0 {`
			`return 0, big.Above`
			`}`
			`return i.Uint64(), big.Exact`
			`}`

			`var (`
			`minint64 = new(big.Int).SetInt64(math.MinInt64)`
			`maxint64 = new(big.Int).SetInt64(math.MaxInt64)`
			`)`

			`func (i Int) Format(s fmt.State, ch rune) {`
			`if i.big != nil {`
			`i.big.Format(s, ch)`
			`return`
			`}`
			`newBig(i.small).Format(s, ch)`
			`}`
			`func (i Int) String() string {`
			`if i.big != nil {`
			`return i.big.Text(10)`
			`}`
			`return strconv.FormatInt(i.small, 10)`
			`}`
			`func (i Int) Type() string { return "int" }`
			`func (i Int) Freeze() {} // immutable`
			`func (i Int) Truth() Bool { return i.Sign() != 0 }`
			`func (i Int) Hash() (uint32, error) {`
			`var lo big.Word`
			`if i.big != nil {`
			`lo = i.big.Bits()[0]`
			`} else {`
			`lo = big.Word(i.small)`
			`}`
			`return 12582917 * uint32(lo+3), nil`
			`}`
			`func (x Int) CompareSameType(op syntax.Token, v Value, depth int) (bool, error) {`
			`y := v.(Int)`
			`if x.big != nil \|\| y.big != nil {`
			`return threeway(op, x.BigInt().Cmp(y.BigInt())), nil`
			`}`
			`return threeway(op, signum64(x.small-y.small)), nil`
			`}`

			`// Float returns the float value nearest i.`
			`func (i Int) Float() Float {`
			`if i.big != nil {`
			`f, _ := new(big.Float).SetInt(i.big).Float64()`
			`return Float(f)`
			`}`
			`return Float(i.small)`
			`}`

			`func (x Int) Sign() int {`
			`if x.big != nil {`
			`return x.big.Sign()`
			`}`
			`return signum64(x.small)`
			`}`

			`func (x Int) Add(y Int) Int {`
			`if x.big != nil \|\| y.big != nil {`
			`return MakeBigInt(new(big.Int).Add(x.BigInt(), y.BigInt()))`
			`}`
			`return MakeInt64(x.small + y.small)`
			`}`
			`func (x Int) Sub(y Int) Int {`
			`if x.big != nil \|\| y.big != nil {`
			`return MakeBigInt(new(big.Int).Sub(x.BigInt(), y.BigInt()))`
			`}`
			`return MakeInt64(x.small - y.small)`
			`}`
			`func (x Int) Mul(y Int) Int {`
			`if x.big != nil \|\| y.big != nil {`
			`return MakeBigInt(new(big.Int).Mul(x.BigInt(), y.BigInt()))`
			`}`
			`return MakeInt64(x.small * y.small)`
			`}`
			`func (x Int) Or(y Int) Int {`
			`if x.big != nil \|\| y.big != nil {`
			`return Int{big: new(big.Int).Or(x.BigInt(), y.BigInt())}`
			`}`
			`return Int{small: x.small \| y.small}`
			`}`
			`func (x Int) And(y Int) Int {`
			`if x.big != nil \|\| y.big != nil {`
			`return MakeBigInt(new(big.Int).And(x.BigInt(), y.BigInt()))`
			`}`
			`return Int{small: x.small & y.small}`
			`}`
			`func (x Int) Xor(y Int) Int {`
			`if x.big != nil \|\| y.big != nil {`
			`return MakeBigInt(new(big.Int).Xor(x.BigInt(), y.BigInt()))`
			`}`
			`return Int{small: x.small ^ y.small}`
			`}`
			`func (x Int) Not() Int {`
			`if x.big != nil {`
			`return MakeBigInt(new(big.Int).Not(x.big))`
			`}`
			`return Int{small: ^x.small}`
			`}`
			`func (x Int) Lsh(y uint) Int { return MakeBigInt(new(big.Int).Lsh(x.BigInt(), y)) }`
			`func (x Int) Rsh(y uint) Int { return MakeBigInt(new(big.Int).Rsh(x.BigInt(), y)) }`

			`// Precondition: y is nonzero.`
			`func (x Int) Div(y Int) Int {`
			`// http://python-history.blogspot.com/2010/08/why-pythons-integer-division-floors.html`
			`if x.big != nil \|\| y.big != nil {`
			`xb, yb := x.BigInt(), y.BigInt()`

			`var quo, rem big.Int`
			`quo.QuoRem(xb, yb, &rem)`
			`if (xb.Sign() < 0) != (yb.Sign() < 0) && rem.Sign() != 0 {`
			`quo.Sub(&quo, oneBig)`
			`}`
			`return MakeBigInt(&quo)`
			`}`
			`quo := x.small / y.small`
			`rem := x.small % y.small`
			`if (x.small < 0) != (y.small < 0) && rem != 0 {`
			`quo -= 1`
			`}`
			`return MakeInt64(quo)`
			`}`

			`// Precondition: y is nonzero.`
			`func (x Int) Mod(y Int) Int {`
			`if x.big != nil \|\| y.big != nil {`
			`xb, yb := x.BigInt(), y.BigInt()`

			`var quo, rem big.Int`
			`quo.QuoRem(xb, yb, &rem)`
			`if (xb.Sign() < 0) != (yb.Sign() < 0) && rem.Sign() != 0 {`
			`rem.Add(&rem, yb)`
			`}`
			`return MakeBigInt(&rem)`
			`}`
			`rem := x.small % y.small`
			`if (x.small < 0) != (y.small < 0) && rem != 0 {`
			`rem += y.small`
			`}`
			`return Int{small: rem}`
			`}`

			`func (i Int) rational() *big.Rat {`
			`if i.big != nil {`
			`return new(big.Rat).SetInt(i.big)`
			`}`
			`return new(big.Rat).SetInt64(i.small)`
			`}`

			`// AsInt32 returns the value of x if is representable as an int32.`
			`func AsInt32(x Value) (int, error) {`
			`i, ok := x.(Int)`
			`if !ok {`
			`return 0, fmt.Errorf("got %s, want int", x.Type())`
			`}`
			`if i.big != nil {`
			`return 0, fmt.Errorf("%s out of range", i)`
			`}`
			`return int(i.small), nil`
			`}`

			`// NumberToInt converts a number x to an integer value.`
			`// An int is returned unchanged, a float is truncated towards zero.`
			`// NumberToInt reports an error for all other values.`
			`func NumberToInt(x Value) (Int, error) {`
			`switch x := x.(type) {`
			`case Int:`
			`return x, nil`
			`case Float:`
			`f := float64(x)`
			`if math.IsInf(f, 0) {`
			`return zero, fmt.Errorf("cannot convert float infinity to integer")`
			`} else if math.IsNaN(f) {`
			`return zero, fmt.Errorf("cannot convert float NaN to integer")`
			`}`
			`return finiteFloatToInt(x), nil`

			`}`
			`return zero, fmt.Errorf("cannot convert %s to int", x.Type())`
			`}`

			`// finiteFloatToInt converts f to an Int, truncating towards zero.`
			`// f must be finite.`
			`func finiteFloatToInt(f Float) Int {`
			`if math.MinInt64 <= f && f <= math.MaxInt64 {`
			`// small values`
			`return MakeInt64(int64(f))`
			`}`
			`rat := f.rational()`
			`if rat == nil {`
			`panic(f) // non-finite`
			`}`
			`return MakeBigInt(new(big.Int).Div(rat.Num(), rat.Denom()))`
			`}`