terraformDummyRepo2/vendor/github.com/cloudflare/circl/math/wnaf.go

// Package math provides some utility functions for big integers.
package math

import "math/big"

// SignedDigit obtains the signed-digit recoding of n and returns a list L of
// digits such that n = sum( L[i]*2^(i*(w-1)) ), and each L[i] is an odd number
// in the set {±1, ±3, ..., ±2^(w-1)-1}. The third parameter ensures that the
// output has ceil(l/(w-1)) digits.
//
// Restrictions:
//   - n is odd and n > 0.
//   - 1 < w < 32.
//   - l >= bit length of n.
//
// References:
//   - Alg.6 in "Exponent Recoding and Regular Exponentiation Algorithms"
//     by Joye-Tunstall. http://doi.org/10.1007/978-3-642-02384-2_21
//   - Alg.6 in "Selecting Elliptic Curves for Cryptography: An Efficiency and
//     Security Analysis" by Bos et al. http://doi.org/10.1007/s13389-015-0097-y
func SignedDigit(n *big.Int, w, l uint) []int32 {
	if n.Sign() <= 0 || n.Bit(0) == 0 {
		panic("n must be non-zero, odd, and positive")
	}
	if w <= 1 || w >= 32 {
		panic("Verify that 1 < w < 32")
	}
	if uint(n.BitLen()) > l {
		panic("n is too big to fit in l digits")
	}
	lenN := (l + (w - 1) - 1) / (w - 1) // ceil(l/(w-1))
	L := make([]int32, lenN+1)
	var k, v big.Int
	k.Set(n)

	var i uint
	for i = 0; i < lenN; i++ {
		words := k.Bits()
		value := int32(words[0] & ((1 << w) - 1))
		value -= int32(1) << (w - 1)
		L[i] = value
		v.SetInt64(int64(value))
		k.Sub(&k, &v)
		k.Rsh(&k, w-1)
	}
	L[i] = int32(k.Int64())
	return L
}

// OmegaNAF obtains the window-w Non-Adjacent Form of a positive number n and
// 1 < w < 32. The returned slice L holds n = sum( L[i]*2^i ).
//
// Reference:
//   - Alg.9 "Efficient arithmetic on Koblitz curves" by Solinas.
//     http://doi.org/10.1023/A:1008306223194
func OmegaNAF(n *big.Int, w uint) (L []int32) {
	if n.Sign() < 0 {
		panic("n must be positive")
	}
	if w <= 1 || w >= 32 {
		panic("Verify that 1 < w < 32")
	}

	L = make([]int32, n.BitLen()+1)
	var k, v big.Int
	k.Set(n)

	i := 0
	for ; k.Sign() > 0; i++ {
		value := int32(0)
		if k.Bit(0) == 1 {
			words := k.Bits()
			value = int32(words[0] & ((1 << w) - 1))
			if value >= (int32(1) << (w - 1)) {
				value -= int32(1) << w
			}
			v.SetInt64(int64(value))
			k.Sub(&k, &v)
		}
		L[i] = value
		k.Rsh(&k, 1)
	}
	return L[:i]
}
Bump github.com/hashicorp/terraform-plugin-sdk/v2 from 2.26.1 to 2.27.0 Bumps [github.com/hashicorp/terraform-plugin-sdk/v2](https://github.com/hashicorp/terraform-plugin-sdk) from 2.26.1 to 2.27.0. - [Release notes](https://github.com/hashicorp/terraform-plugin-sdk/releases) - [Changelog](https://github.com/hashicorp/terraform-plugin-sdk/blob/main/CHANGELOG.md) - [Commits](https://github.com/hashicorp/terraform-plugin-sdk/compare/v2.26.1...v2.27.0) --- updated-dependencies: - dependency-name: github.com/hashicorp/terraform-plugin-sdk/v2 dependency-type: direct:production update-type: version-update:semver-minor ... Signed-off-by: dependabot[bot] <support@github.com> 2023-07-03 20:21:30 +00:00			`// Package math provides some utility functions for big integers.`
			`package math`

			`import "math/big"`

			`// SignedDigit obtains the signed-digit recoding of n and returns a list L of`
			`// digits such that n = sum( L[i]2^(i(w-1)) ), and each L[i] is an odd number`
			`// in the set {±1, ±3, ..., ±2^(w-1)-1}. The third parameter ensures that the`
			`// output has ceil(l/(w-1)) digits.`
			`//`
			`// Restrictions:`
			`// - n is odd and n > 0.`
			`// - 1 < w < 32.`
			`// - l >= bit length of n.`
			`//`
			`// References:`
			`// - Alg.6 in "Exponent Recoding and Regular Exponentiation Algorithms"`
			`// by Joye-Tunstall. http://doi.org/10.1007/978-3-642-02384-2_21`
			`// - Alg.6 in "Selecting Elliptic Curves for Cryptography: An Efficiency and`
			`// Security Analysis" by Bos et al. http://doi.org/10.1007/s13389-015-0097-y`
			`func SignedDigit(n *big.Int, w, l uint) []int32 {`
			`if n.Sign() <= 0 \|\| n.Bit(0) == 0 {`
			`panic("n must be non-zero, odd, and positive")`
			`}`
			`if w <= 1 \|\| w >= 32 {`
			`panic("Verify that 1 < w < 32")`
			`}`
			`if uint(n.BitLen()) > l {`
			`panic("n is too big to fit in l digits")`
			`}`
			`lenN := (l + (w - 1) - 1) / (w - 1) // ceil(l/(w-1))`
			`L := make([]int32, lenN+1)`
			`var k, v big.Int`
			`k.Set(n)`

			`var i uint`
			`for i = 0; i < lenN; i++ {`
			`words := k.Bits()`
			`value := int32(words[0] & ((1 << w) - 1))`
			`value -= int32(1) << (w - 1)`
			`L[i] = value`
			`v.SetInt64(int64(value))`
			`k.Sub(&k, &v)`
			`k.Rsh(&k, w-1)`
			`}`
			`L[i] = int32(k.Int64())`
			`return L`
			`}`

			`// OmegaNAF obtains the window-w Non-Adjacent Form of a positive number n and`
			`// 1 < w < 32. The returned slice L holds n = sum( L[i]*2^i ).`
			`//`
			`// Reference:`
			`// - Alg.9 "Efficient arithmetic on Koblitz curves" by Solinas.`
			`// http://doi.org/10.1023/A:1008306223194`
			`func OmegaNAF(n *big.Int, w uint) (L []int32) {`
			`if n.Sign() < 0 {`
			`panic("n must be positive")`
			`}`
			`if w <= 1 \|\| w >= 32 {`
			`panic("Verify that 1 < w < 32")`
			`}`

			`L = make([]int32, n.BitLen()+1)`
			`var k, v big.Int`
			`k.Set(n)`

			`i := 0`
			`for ; k.Sign() > 0; i++ {`
			`value := int32(0)`
			`if k.Bit(0) == 1 {`
			`words := k.Bits()`
			`value = int32(words[0] & ((1 << w) - 1))`
			`if value >= (int32(1) << (w - 1)) {`
			`value -= int32(1) << w`
			`}`
			`v.SetInt64(int64(value))`
			`k.Sub(&k, &v)`
			`}`
			`L[i] = value`
			`k.Rsh(&k, 1)`
			`}`
			`return L[:i]`
			`}`