2014-08-08 22:43:50 +02:00
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package snacl
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import (
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"crypto/rand"
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"crypto/subtle"
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"encoding/binary"
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"errors"
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"io"
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2014-12-11 16:08:34 +01:00
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"golang.org/x/crypto/nacl/secretbox"
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"golang.org/x/crypto/scrypt"
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2014-08-08 22:43:50 +02:00
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2015-01-16 16:11:25 +01:00
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"github.com/btcsuite/fastsha256"
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2014-08-08 22:43:50 +02:00
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)
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var (
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prng = rand.Reader
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)
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var (
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ErrInvalidPassword = errors.New("invalid password")
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ErrMalformed = errors.New("malformed data")
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ErrDecryptFailed = errors.New("unable to decrypt")
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)
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// Zero out a byte slice.
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func zero(b []byte) {
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for i := range b {
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b[i] ^= b[i]
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}
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}
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const (
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2014-06-13 19:14:44 +02:00
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// Expose secretbox's Overhead const here for convenience.
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Overhead = secretbox.Overhead
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2014-08-08 22:43:50 +02:00
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KeySize = 32
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NonceSize = 24
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DefaultN = 16384 // 2^14
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DefaultR = 8
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DefaultP = 1
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)
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// CryptoKey represents a secret key which can be used to encrypt and decrypt
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// data.
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type CryptoKey [KeySize]byte
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// Encrypt encrypts the passed data.
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func (ck *CryptoKey) Encrypt(in []byte) ([]byte, error) {
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var nonce [NonceSize]byte
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_, err := io.ReadFull(prng, nonce[:])
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if err != nil {
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return nil, err
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}
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blob := secretbox.Seal(nil, in, &nonce, (*[KeySize]byte)(ck))
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return append(nonce[:], blob...), nil
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}
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// Decrypt decrypts the passed data. The must be the output of the Encrypt
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// function.
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func (ck *CryptoKey) Decrypt(in []byte) ([]byte, error) {
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if len(in) < NonceSize {
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return nil, ErrMalformed
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}
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var nonce [NonceSize]byte
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copy(nonce[:], in[:NonceSize])
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blob := in[NonceSize:]
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opened, ok := secretbox.Open(nil, blob, &nonce, (*[KeySize]byte)(ck))
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if !ok {
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return nil, ErrDecryptFailed
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}
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return opened, nil
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}
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// Zero clears the key by manually zeroing all memory. This is for security
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// conscience application which wish to zero the memory after they've used it
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// rather than waiting until it's reclaimed by the garbage collector. The
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// key is no longer usable after this call.
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func (ck *CryptoKey) Zero() {
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zero(ck[:])
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}
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// GenerateCryptoKey generates a new crypotgraphically random key.
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func GenerateCryptoKey() (*CryptoKey, error) {
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var key CryptoKey
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_, err := io.ReadFull(prng, key[:])
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if err != nil {
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return nil, err
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}
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return &key, nil
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}
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// Parameters are not secret and can be stored in plain text.
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type Parameters struct {
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Salt [KeySize]byte
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Digest [fastsha256.Size]byte
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N int
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R int
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P int
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}
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// SecretKey houses a crypto key and the parameters needed to derive it from a
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// passphrase. It should only be used in memory.
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type SecretKey struct {
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Key *CryptoKey
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Parameters Parameters
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}
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// deriveKey fills out the Key field.
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func (sk *SecretKey) deriveKey(password *[]byte) error {
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key, err := scrypt.Key(*password, sk.Parameters.Salt[:],
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sk.Parameters.N,
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sk.Parameters.R,
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sk.Parameters.P,
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len(sk.Key))
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if err != nil {
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return err
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}
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copy(sk.Key[:], key)
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zero(key)
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return nil
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}
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// Marshal returns the Parameters field marshalled into a format suitable for
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// storage. This result of this can be stored in clear text.
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func (sk *SecretKey) Marshal() []byte {
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params := &sk.Parameters
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// The marshalled format for the the params is as follows:
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// <salt><digest><N><R><P>
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//
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// KeySize + fastsha256.Size + N (8 bytes) + R (8 bytes) + P (8 bytes)
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marshalled := make([]byte, KeySize+fastsha256.Size+24)
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b := marshalled
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copy(b[:KeySize], params.Salt[:])
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b = b[KeySize:]
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copy(b[:fastsha256.Size], params.Digest[:])
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b = b[fastsha256.Size:]
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binary.LittleEndian.PutUint64(b[:8], uint64(params.N))
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b = b[8:]
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binary.LittleEndian.PutUint64(b[:8], uint64(params.R))
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b = b[8:]
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binary.LittleEndian.PutUint64(b[:8], uint64(params.P))
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return marshalled
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}
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// Unmarshal unmarshalls the parameters needed to derive the secret key from a
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// passphrase into sk.
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func (sk *SecretKey) Unmarshal(marshalled []byte) error {
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if sk.Key == nil {
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sk.Key = (*CryptoKey)(&[KeySize]byte{})
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}
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// The marshalled format for the the params is as follows:
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// <salt><digest><N><R><P>
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//
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// KeySize + fastsha256.Size + N (8 bytes) + R (8 bytes) + P (8 bytes)
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if len(marshalled) != KeySize+fastsha256.Size+24 {
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return ErrMalformed
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}
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params := &sk.Parameters
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copy(params.Salt[:], marshalled[:KeySize])
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marshalled = marshalled[KeySize:]
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copy(params.Digest[:], marshalled[:fastsha256.Size])
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marshalled = marshalled[fastsha256.Size:]
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params.N = int(binary.LittleEndian.Uint64(marshalled[:8]))
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marshalled = marshalled[8:]
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params.R = int(binary.LittleEndian.Uint64(marshalled[:8]))
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marshalled = marshalled[8:]
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params.P = int(binary.LittleEndian.Uint64(marshalled[:8]))
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return nil
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}
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// Zero zeroes the underlying secret key while leaving the parameters intact.
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// This effectively makes the key unusable until it is derived again via the
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// DeriveKey function.
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func (sk *SecretKey) Zero() {
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sk.Key.Zero()
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}
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// DeriveKey derives the underlying secret key and ensures it matches the
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// expected digest. This should only be called after previously calling the
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// Zero function or on an initial Unmarshal.
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func (sk *SecretKey) DeriveKey(password *[]byte) error {
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if err := sk.deriveKey(password); err != nil {
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return err
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}
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// verify password
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digest := fastsha256.Sum256(sk.Key[:])
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if subtle.ConstantTimeCompare(digest[:], sk.Parameters.Digest[:]) != 1 {
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return ErrInvalidPassword
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}
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return nil
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}
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// Encrypt encrypts in bytes and returns a JSON blob.
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func (sk *SecretKey) Encrypt(in []byte) ([]byte, error) {
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return sk.Key.Encrypt(in)
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}
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// Decrypt takes in a JSON blob and returns it's decrypted form.
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func (sk *SecretKey) Decrypt(in []byte) ([]byte, error) {
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return sk.Key.Decrypt(in)
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}
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// NewSecretKey returns a SecretKey structure based on the passed parameters.
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func NewSecretKey(password *[]byte, N, r, p int) (*SecretKey, error) {
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sk := SecretKey{
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Key: (*CryptoKey)(&[KeySize]byte{}),
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}
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// setup parameters
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sk.Parameters.N = N
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sk.Parameters.R = r
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sk.Parameters.P = p
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_, err := io.ReadFull(prng, sk.Parameters.Salt[:])
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if err != nil {
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return nil, err
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}
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// derive key
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err = sk.deriveKey(password)
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if err != nil {
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return nil, err
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}
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// store digest
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sk.Parameters.Digest = fastsha256.Sum256(sk.Key[:])
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return &sk, nil
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}
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