mirror of
https://github.com/henrydcase/nobs.git
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228 lines
6.9 KiB
Go
228 lines
6.9 KiB
Go
package sidh
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import (
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"errors"
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. "github.com/henrydcase/nobs/dh/sidh/internal/isogeny"
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"io"
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)
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// I keep it bool in order to be able to apply logical NOT
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type KeyVariant uint
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// Id's correspond to bitlength of the prime field characteristic
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// Currently FP_751 is the only one supported by this implementation
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const (
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FP_503 uint8 = iota
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FP_751
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FP_964
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maxPrimeFieldId
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)
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const (
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// First 2 bits identify SIDH variant third bit indicates
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// wether key is a SIKE variant (set) or SIDH (not set)
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// 001 - SIDH: corresponds to 2-torsion group
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KeyVariant_SIDH_A KeyVariant = 1 << 0
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// 010 - SIDH: corresponds to 3-torsion group
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KeyVariant_SIDH_B = 1 << 1
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// 110 - SIKE
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KeyVariant_SIKE = 1<<2 | KeyVariant_SIDH_B
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)
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// Base type for public and private key. Used mainly to carry domain
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// parameters.
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type key struct {
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// Domain parameters of the algorithm to be used with a key
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params *SidhParams
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// Flag indicates wether corresponds to 2-, 3-torsion group or SIKE
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keyVariant KeyVariant
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}
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// Defines operations on public key
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type PublicKey struct {
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key
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affine_xP Fp2Element
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affine_xQ Fp2Element
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affine_xQmP Fp2Element
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}
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// Defines operations on private key
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type PrivateKey struct {
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key
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// Secret key
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Scalar []byte
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// Used only by KEM
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S []byte
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}
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// Accessor to the domain parameters
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func (key *key) Params() *SidhParams {
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return key.params
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}
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// Accessor to key variant
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func (key *key) Variant() KeyVariant {
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return key.keyVariant
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}
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// NewPrivateKey initializes private key.
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// Usage of this function guarantees that the object is correctly initialized.
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func NewPrivateKey(id uint8, v KeyVariant) *PrivateKey {
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prv := &PrivateKey{key: key{params: Params(id), keyVariant: v}}
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if (v & KeyVariant_SIDH_A) == KeyVariant_SIDH_A {
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prv.Scalar = make([]byte, prv.params.A.SecretByteLen)
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} else {
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prv.Scalar = make([]byte, prv.params.B.SecretByteLen)
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}
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if v == KeyVariant_SIKE {
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prv.S = make([]byte, prv.params.MsgLen)
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}
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return prv
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}
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// NewPublicKey initializes public key.
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// Usage of this function guarantees that the object is correctly initialized.
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func NewPublicKey(id uint8, v KeyVariant) *PublicKey {
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return &PublicKey{key: key{params: Params(id), keyVariant: v}}
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}
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// Import clears content of the public key currently stored in the structure
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// and imports key stored in the byte string. Returns error in case byte string
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// size is wrong. Doesn't perform any validation.
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func (pub *PublicKey) Import(input []byte) error {
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if len(input) != pub.Size() {
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return errors.New("sidh: input to short")
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}
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op := CurveOperations{Params: pub.params}
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ssSz := pub.params.SharedSecretSize
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op.Fp2FromBytes(&pub.affine_xP, input[0:ssSz])
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op.Fp2FromBytes(&pub.affine_xQ, input[ssSz:2*ssSz])
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op.Fp2FromBytes(&pub.affine_xQmP, input[2*ssSz:3*ssSz])
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return nil
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}
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// Exports currently stored key. In case structure hasn't been filled with key data
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// returned byte string is filled with zeros.
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func (pub *PublicKey) Export() []byte {
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output := make([]byte, pub.params.PublicKeySize)
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op := CurveOperations{Params: pub.params}
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ssSz := pub.params.SharedSecretSize
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op.Fp2ToBytes(output[0:ssSz], &pub.affine_xP)
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op.Fp2ToBytes(output[ssSz:2*ssSz], &pub.affine_xQ)
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op.Fp2ToBytes(output[2*ssSz:3*ssSz], &pub.affine_xQmP)
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return output
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}
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// Size returns size of the public key in bytes
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func (pub *PublicKey) Size() int {
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return pub.params.PublicKeySize
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}
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// Exports currently stored key. In case structure hasn't been filled with key data
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// returned byte string is filled with zeros.
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func (prv *PrivateKey) Export() []byte {
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ret := make([]byte, len(prv.Scalar)+len(prv.S))
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copy(ret, prv.S)
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copy(ret[len(prv.S):], prv.Scalar)
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return ret
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}
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// Size returns size of the private key in bytes
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func (prv *PrivateKey) Size() int {
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tmp := len(prv.Scalar)
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if prv.Variant() == KeyVariant_SIKE {
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tmp += int(prv.params.MsgLen)
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}
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return tmp
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}
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// Import clears content of the private key currently stored in the structure
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// and imports key from octet string. In case of SIKE, the random value 'S'
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// must be prepended to the value of actual private key (see SIKE spec for details).
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// Function doesn't import public key value to PrivateKey object.
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func (prv *PrivateKey) Import(input []byte) error {
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if len(input) != prv.Size() {
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return errors.New("sidh: input to short")
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}
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copy(prv.S, input[:len(prv.S)])
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copy(prv.Scalar, input[len(prv.S):])
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return nil
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}
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// Generates random private key for SIDH or SIKE. Generated value is
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// formed as little-endian integer from key-space <2^(e2-1)..2^e2 - 1>
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// for KeyVariant_A or <2^(s-1)..2^s - 1>, where s = ceil(log_2(3^e3)),
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// for KeyVariant_B.
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//
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// Returns error in case user provided RNG fails.
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func (prv *PrivateKey) Generate(rand io.Reader) error {
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var err error
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var dp *DomainParams
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if (prv.keyVariant & KeyVariant_SIDH_A) == KeyVariant_SIDH_A {
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dp = &prv.params.A
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} else {
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dp = &prv.params.B
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}
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//err = prv.generatePrivateKey(rand)
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if prv.keyVariant == KeyVariant_SIKE && err == nil {
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_, err = io.ReadFull(rand, prv.S)
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}
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// Private key generation takes advantage of the fact that keyspace for secret
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// key is (0, 2^x - 1), for some possitivite value of 'x' (see SIKE, 1.3.8).
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// It means that all bytes in the secret key, but the last one, can take any
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// value between <0x00,0xFF>. Similarily for the last byte, but generation
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// needs to chop off some bits, to make sure generated value is an element of
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// a key-space.
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_, err = io.ReadFull(rand, prv.Scalar)
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if err != nil {
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return err
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}
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prv.Scalar[len(prv.Scalar)-1] &= (1 << (dp.SecretBitLen % 8)) - 1
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// Make sure scalar is SecretBitLen long. SIKE spec says that key
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// space starts from 0, but I'm not confortable with having low
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// value scalars used for private keys. It is still secrure as per
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// table 5.1 in [SIKE].
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prv.Scalar[len(prv.Scalar)-1] |= 1 << ((dp.SecretBitLen % 8) - 1)
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return err
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}
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// Generates public key.
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//
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// Constant time.
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func (prv *PrivateKey) GeneratePublicKey() *PublicKey {
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if (prv.keyVariant & KeyVariant_SIDH_A) == KeyVariant_SIDH_A {
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return publicKeyGenA(prv)
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}
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return publicKeyGenB(prv)
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}
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// Computes a shared secret which is a j-invariant. Function requires that pub has
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// different KeyVariant than prv. Length of returned output is 2*ceil(log_2 P)/8),
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// where P is a prime defining finite field.
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//
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// It's important to notice that each keypair must not be used more than once
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// to calculate shared secret.
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//
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// Function may return error. This happens only in case provided input is invalid.
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// Constant time for properly initialized private and public key.
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func DeriveSecret(prv *PrivateKey, pub *PublicKey) ([]byte, error) {
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if (pub == nil) || (prv == nil) {
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return nil, errors.New("sidh: invalid arguments")
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}
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if (pub.keyVariant == prv.keyVariant) || (pub.params.Id != prv.params.Id) {
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return nil, errors.New("sidh: public and private are incompatbile")
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}
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if (prv.keyVariant & KeyVariant_SIDH_A) == KeyVariant_SIDH_A {
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return deriveSecretA(prv, pub), nil
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} else {
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return deriveSecretB(prv, pub), nil
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}
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}
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