391 lines
13 KiB
Go
391 lines
13 KiB
Go
/*
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SSHSecure - a program to harden OpenSSH from defaults
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Copyright (C) 2020 Brent Saner
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This program is free software: you can redistribute it and/or modify
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it under the terms of the GNU General Public License as published by
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the Free Software Foundation, either version 3 of the License, or
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(at your option) any later version.
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This program is distributed in the hope that it will be useful,
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but WITHOUT ANY WARRANTY; without even the implied warranty of
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MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
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GNU General Public License for more details.
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You should have received a copy of the GNU General Public License
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along with this program. If not, see <https://www.gnu.org/licenses/>.
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*/
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package sshkeys
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import (
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`bytes`
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"crypto/rand"
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"errors"
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"fmt"
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)
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func (k *EncryptedSSHKeyV1) validate() error {
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if k.Passphrase == nil {
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return errors.New("cannot use encrypted key with empty passphrase")
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}
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var validCipher bool
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var validKDF bool
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var validKT bool
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for _, v := range allowed_ciphers {
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if v == k.CipherName {
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validCipher = true
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break
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}
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}
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for _, v := range allowed_kdfnames {
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if v == k.KDFName {
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validKDF = true
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break
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}
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}
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for _, v := range allowed_keytypes {
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if v == k.DefKeyType {
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validKT = true
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}
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}
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if !validCipher || !validKDF || !validKT {
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return errors.New("invalid CipherName, KDFName, or DefKeyType specified")
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}
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return nil
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}
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func (k *EncryptedSSHKeyV1) Generate(force bool) error {
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if k.DefKeyType == "" {
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k.DefKeyType = defKeyType
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}
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if k.KDFName == "" {
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k.KDFName = defKDF
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}
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if k.CipherName == "" {
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k.CipherName = defCipher
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}
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if err := k.validate(); err != nil {
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return err
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}
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if len(k.Keys) > 0 && !force {
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return nil // Already generated.
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}
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if k.KDFOpts.Salt == nil {
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k.KDFOpts.Salt = make([]byte, defSaltLen)
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if _, err := rand.Read(k.KDFOpts.Salt); err != nil {
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return err
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}
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}
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if k.KDFOpts.Rounds == 0 {
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k.KDFOpts.Rounds = defRounds
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}
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if k.DefKeyType == KeyEd25519 {
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k.KeySize = keyEd25519
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}
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// Currently, OpenSSH has an option for multiple private keys. However, it is hardcoded to 1.
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// If multiple key support is added in the future, will need to re-tool how I do this, perhaps, in the future. TODO.
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pk := SSHPrivKey{
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Comment: fmt.Sprintf("Autogenerated via SSHSecure (%v)", projUrl),
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}
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pk.Checksum = make([]byte, 4)
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if _, err := rand.Read(pk.Checksum); err != nil {
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return err
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}
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switch k.DefKeyType {
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case KeyRsa:
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if err := pk.generateRsa(); err != nil {
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return err
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}
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case KeyEd25519:
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if err := pk.generateEd25519(); err != nil {
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return err
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}
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default:
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return errors.New("unknown key type; could not generate private/public keypair")
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}
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k.Keys = append(k.Keys, pk)
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// We also need an encrypter/decrypter since this is an encrypted key.
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if err := k.setCrypt(); err != nil {
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return err
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}
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// And then we need to build the key buffer.
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if err := k.buildKeybuf(); err != nil {
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return err
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}
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return nil
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}
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func (k *SSHKeyV1) validate() error {
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var validKT bool
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for _, v := range allowed_keytypes {
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if v == k.DefKeyType {
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validKT = true
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}
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}
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if !validKT {
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return errors.New("invalid DefKeyType specified")
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}
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return nil
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}
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func (k *SSHKeyV1) Generate(force bool) error {
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if len(k.Keys) > 0 && !force {
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return nil // Already generated.
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}
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if k.DefKeyType == KeyEd25519 {
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k.KeySize = keyEd25519
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}
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k.CipherName = CipherNull
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k.KDFName = KdfNull
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// Currently, OpenSSH has an option for multiple private keys. However, it is hardcoded to 1.
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// If multiple key support is added in the future, will need to re-tool how I do this, perhaps, in the future. TODO.
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pk := SSHPrivKey{
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Comment: fmt.Sprintf("Autogenerated via SSHSecure (%v)", projUrl),
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}
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pk.Checksum = make([]byte, 4)
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if _, err := rand.Read(pk.Checksum); err != nil {
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return err
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}
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switch k.DefKeyType {
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case KeyRsa:
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if err := pk.generateRsa(); err != nil {
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return err
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}
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case KeyEd25519:
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if err := pk.generateEd25519(); err != nil {
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return err
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}
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default:
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return errors.New("unknown key type; could not generate private/public keypair")
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}
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k.Keys = append(k.Keys, pk)
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if err := k.buildKeybuf(); err != nil {
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return err
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}
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return nil
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}
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// buildKeybuf is where an EncryptedSSHKeyV1 key buffer is actually assembled.
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// Entries are commented with their annotated reference.
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// (see ref/(encrypted|plain)/(public|private).(rsa|ed25519) and ref/format.(ed25519|rsa) for details)
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func (k *EncryptedSSHKeyV1) buildKeybuf() error {
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// TODO: error handling for each <buf>.Write()?
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// Before anything, we want a clean buffer. Just in case.
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k.Buffer.Reset()
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// Add the common header.
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if err := k.addHeader(); err != nil {
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return err
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}
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// Add the keypairs.
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// Since this is encrypted, the private key blobs are encrypted.
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// OpenSSH keys currently only support 1 keypair but support more *in theory*. This *seems* to be how they plan on doing it.
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// But boy, is it a pain. So much wasted RAM and CPU cycles. They should use terminating byte sequences IMHO but whatever.
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for _, i := range k.Keys { // 4.0.0 and 4.0.1
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switch k.CipherName {
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case CipherAes256Ctr:
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i.BlockSize = k.Crypt.Cipher.BlockSize()
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}
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kbPtr, err := i.keyBlob(&k.Crypt, true)
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if err != nil {
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return err
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}
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k.Buffer.Write(*kbPtr)
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}
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return nil
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}
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// buildKeybuf is where an SSHKeyV1 key buffer is actually assembled.
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// Entries are commented with their annotated reference.
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// (see ref/(encrypted|plain)/(public|private).(rsa|ed25519) and ref/format.(ed25519|rsa) for details)
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func (k *SSHKeyV1) buildKeybuf() error {
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// TODO: error handling for each <buf>.Write()?
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// Before anything, we want a clean buffer. Just in case.
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k.Buffer.Reset()
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// Add the common header.
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if err := k.addHeader(); err != nil {
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return err
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}
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// Add the keypairs.
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// OpenSSH keys currently only support 1 keypair but support more *in theory*. This *seems* to be how they plan on doing it.
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// But boy, is it a pain. So much wasted RAM and CPU cycles. They should use terminating byte sequences IMHO but whatever.
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for _, i := range k.Keys { // 4.0.0 and 4.0.1
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i.BlockSize = 8
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kbPtr, err := i.keyBlob(nil, false)
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if err != nil {
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return err
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}
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k.Buffer.Write(*kbPtr)
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}
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return nil
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}
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func (k *SSHKeyV1) addHeader() error {
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// TODO: error handling for each <buf>.Write()?
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// First we need to do some prep for the plaintext header.
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var kdfOptsBytes []byte
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kdfOptsBytes = k.getKdfOptBytes() // 3.0.0
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cipherBytes := []byte(k.CipherName) // 1.0
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kdf := []byte(k.KDFName) // 2.0.0
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// This is just cast to an array for visual readability.
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commonHeader := [][]byte{
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[]byte(KeyV1Magic + "\x00"), // 0
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getBytelenByteArr(cipherBytes), // 1.0
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cipherBytes, // 1.0.0
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getBytelenByteArr(kdf), // 2.0
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kdf, // 2.0.0
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getBytelenByteArr(kdfOptsBytes), // 3.0
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kdfOptsBytes, // 3.0.0
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getByteInt(len(k.Keys)), // 4.0
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}
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for _, v := range commonHeader {
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if _, err := k.Buffer.Write(v); err != nil {
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return err
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}
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}
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return nil
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}
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func (k *EncryptedSSHKeyV1) getKdfOptBytes() []byte {
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var kdfOptsBytes []byte // 3.0.0
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// This is *probably* more efficient than using a buffer just for these bytes.
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kdfOptsBytes = append(kdfOptsBytes, byte(len(k.KDFOpts.Salt))) // 3.0.0.0
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kdfOptsBytes = append(kdfOptsBytes, k.KDFOpts.Salt...) // 3.0.0.0.0
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kdfOptsBytes = append(kdfOptsBytes, byte(k.KDFOpts.Rounds)) // 3.0.0.1
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return kdfOptsBytes
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}
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func (k *SSHKeyV1) getKdfOptBytes() []byte {
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var kdfOptsBytes []byte // 3.0.0
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// No-op; unencrypted keys' KDFOpts are encapsulated by a single null byte (which the caller implements).
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return kdfOptsBytes
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}
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func (pk *SSHPrivKey) keyBlob(c *SSHCrypt, encrypt bool) (*[]byte, error) {
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// TODO: error handling for each <buf>.Write()?
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var keypairBytes bytes.Buffer // (4.0's children)
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var pubkeyBytes bytes.Buffer // 4.0.0 children (4.0.0 itself is handled before writing to keypairBytes)
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var privkeyBytes bytes.Buffer // 4.0.1 (and children)
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pubkeyName := []byte(pk.PublicKey.KeyType) // (4.0.0.0.0, cast to var because I'm lazy)
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pubkeyBytes.Write(getBytelenByteArr(pubkeyName)) // 4.0.0.0
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pubkeyBytes.Write(pubkeyName) // 4.0.0.0.0
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// TODO: Optimize?
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/*
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THE PUBLIC KEY
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This is unencrypted, even if it's an encrypted key.
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*/
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switch pk.PublicKey.KeyType {
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case KeyEd25519:
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pubkeyBytes.Write(getBytelenByteArr(pk.PublicKey.Key.([]byte))) // 4.0.0.1
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pubkeyBytes.Write(pk.PublicKey.Key.([]byte)) // 4.0.0.1.0
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case KeyRsa:
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// How messy.
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var en bytes.Buffer // 4.0.0.1 and 4.0.0.2
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// TODO: does e need getByteInt()?
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e := pk.PublicKey.Key.E.Bytes() // 4.0.0.1.0
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// TODO: does n need nullbyte prefix?
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n := pk.PublicKey.Key.N.Bytes() // 4.0.0.2.0
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en.Write(getBytelenByteArr(e)) // 4.0.0.1
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en.Write(e) // 4.0.0.1.0
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en.Write(getBytelenByteArr(n)) // 4.0.0.2
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en.Write(n) // 4.0.0.2.0
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pubkeyBytes.Write(getBytelenByteArr(en.Bytes())) // 4.0.0
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if _, err := en.WriteTo(&pubkeyBytes); err != nil { // (4.0.0 children)
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return nil, err
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}
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}
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/*
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THE PRIVATE KEY
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This is encrypted if it's an encrypted key, otherwise it's just plain readable bytes.
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*/
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// First we need two checksums.
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for i := 1; i <= 2; i++ {
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privkeyBytes.Write(pk.Checksum) // 4.0.1.0 and 4.0.1.1
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}
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// And then add the public keys. Yes, the public keys are included in the private keys.
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privkeyBytes.Write(getBytelenByteArr(pubkeyName)) // 4.0.1.2.0
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privkeyBytes.Write(pubkeyName) // 4.0.1.2.0.0
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switch pk.PublicKey.KeyType {
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case KeyEd25519:
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// This is easy.
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privkeyBytes.Write(pubkeyBytes.Bytes()) // 4.0.1.2.1
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if _, err := pubkeyBytes.WriteTo(&privkeyBytes); err != nil { // 4.0.1.2.1.0
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return nil, err
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}
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case KeyRsa:
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// This is not. We more or less have to do the same thing as the public key, BUT with e and n flipped. Gorram it.
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var ne bytes.Buffer // (4.0.1.2 children)
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// TODO: does n need nullbyte prefix?
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n := pk.PublicKey.Key.N.Bytes() // 4.0.1.2.1.0
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// TODO: does e need getByteInt()?
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e := pk.PublicKey.Key.E.Bytes() // 4.0.1.2.2.0
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ne.Write(getBytelenByteArr(n)) // 4.0.1.2.1
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ne.Write(n) // 4.0.1.2.1.0
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ne.Write(getBytelenByteArr(e)) // 4.0.1.2.2
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ne.Write(e) // 4.0.1.2.2.0
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if _, err := ne.WriteTo(&privkeyBytes); err != nil { // (4.0.1.2 children)
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return nil, err
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}
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}
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// And then we add the *actual* private keys.
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switch pk.PublicKey.KeyType {
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case KeyEd25519:
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privkeyBytes.Write(getBytelenByteArr(pk.KeyAlt)) // 4.0.1.3
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privkeyBytes.Write(pk.KeyAlt) // 4.0.1.3.0
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case KeyRsa:
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var dcpq bytes.Buffer // 4.0.1.3 to 4.0.1.6
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d := pk.Key.D.Bytes() // 4.0.1.3.0
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crt := pk.Key.Precomputed.Qinv.Bytes() // 4.0.1.4.0
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// TODO: does p need nullbyte prefix?
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p := pk.Key.Primes[0].Bytes() // 4.0.1.5.0
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// TODO: does q need nullbyte prefix?
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q := pk.Key.Primes[1].Bytes() // 4.0.1.6.0
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dcpq.Write(getBytelenByteArr(d)) // 4.0.1.3
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dcpq.Write(d) // 4.0.1.3.0
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dcpq.Write(getBytelenByteArr(crt)) // 4.0.1.4
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dcpq.Write(crt) // 4.0.1.4.0
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dcpq.Write(getBytelenByteArr(p)) // 4.0.1.5
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dcpq.Write(p) // 4.0.1.5.0
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dcpq.Write(getBytelenByteArr(q)) // 4.0.1.6
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dcpq.Write(q) // 4.0.1.6.0
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if _, err := dcpq.WriteTo(&privkeyBytes); err != nil { // 4.0.1.3 to 4.0.1.6
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return nil, err
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}
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}
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// Add the comment.
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privkeyBytes.Write(getBytelenByteArr([]byte(pk.Comment))) // 4.0.1.4 (ED25519), 4.0.1.7 (RSA)
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privkeyBytes.Write([]byte(pk.Comment)) // 4.0.1.4.0 (ED25519), 4.0.1.7.0 (RSA)
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// Add padding
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pad := 0
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n := 0
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for len(privkeyBytes.Bytes()) % pk.BlockSize != 0 { // 4.0.1.5 (ED25519), 4.0.1.8 (RSA)
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n++
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pad = n & pk.BlockSize
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privkeyBytes.Write(getSingleByteInt(pad))
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}
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// Check if the private key should be encrypted or not.
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if encrypt {
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// We encrypt here to a "new" buffer.
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// We actually just clear the buffer and then write the new encrypted data to it, and then clear the intermediate byte slice.
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if c == nil || c.Stream == nil {
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return nil, errors.New("if encrypting, you must specify a populated SSHCrypt in c")
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}
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var encBytes []byte
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c.Stream.XORKeyStream(encBytes, privkeyBytes.Bytes())
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privkeyBytes.Reset()
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privkeyBytes.Write(encBytes)
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encBytes = []byte{}
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}
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// Get the respective lengths and add child buffers to buffer.
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keypairBytes.Write(getByteInt(len(pubkeyBytes.Bytes()))) // 4.0.0
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if _, err := pubkeyBytes.WriteTo(&keypairBytes); err != nil { // (4.0.0 children)
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return nil, err
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}
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keypairBytes.Write(getByteInt(len(privkeyBytes.Bytes()))) // 4.0.1
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if _, err := privkeyBytes.WriteTo(&keypairBytes); err != nil { // (4.0.1 children)
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return nil, err
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}
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// Done!
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kpSlice := keypairBytes.Bytes()
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return &kpSlice, nil
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} |