234 lines
6.2 KiB
Go
234 lines
6.2 KiB
Go
// Copyright 2012 The Go Authors. All rights reserved.
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// Use of this source code is governed by a BSD-style
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// license that can be found in the LICENSE file.
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package x509
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// RFC 1423 describes the encryption of PEM blocks. The algorithm used to
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// generate a key from the password was derived by looking at the OpenSSL
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// implementation.
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import (
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"crypto/aes"
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"crypto/cipher"
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"crypto/des"
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"crypto/md5"
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"encoding/hex"
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"encoding/pem"
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"errors"
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"io"
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"strings"
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)
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type PEMCipher int
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// Possible values for the EncryptPEMBlock encryption algorithm.
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const (
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_ PEMCipher = iota
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PEMCipherDES
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PEMCipher3DES
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PEMCipherAES128
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PEMCipherAES192
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PEMCipherAES256
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)
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// rfc1423Algo holds a method for enciphering a PEM block.
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type rfc1423Algo struct {
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cipher PEMCipher
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name string
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cipherFunc func(key []byte) (cipher.Block, error)
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keySize int
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blockSize int
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}
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// rfc1423Algos holds a slice of the possible ways to encrypt a PEM
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// block. The ivSize numbers were taken from the OpenSSL source.
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var rfc1423Algos = []rfc1423Algo{{
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cipher: PEMCipherDES,
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name: "DES-CBC",
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cipherFunc: des.NewCipher,
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keySize: 8,
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blockSize: des.BlockSize,
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}, {
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cipher: PEMCipher3DES,
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name: "DES-EDE3-CBC",
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cipherFunc: des.NewTripleDESCipher,
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keySize: 24,
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blockSize: des.BlockSize,
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}, {
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cipher: PEMCipherAES128,
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name: "AES-128-CBC",
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cipherFunc: aes.NewCipher,
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keySize: 16,
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blockSize: aes.BlockSize,
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}, {
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cipher: PEMCipherAES192,
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name: "AES-192-CBC",
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cipherFunc: aes.NewCipher,
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keySize: 24,
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blockSize: aes.BlockSize,
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}, {
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cipher: PEMCipherAES256,
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name: "AES-256-CBC",
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cipherFunc: aes.NewCipher,
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keySize: 32,
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blockSize: aes.BlockSize,
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},
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}
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// deriveKey uses a key derivation function to stretch the password into a key
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// with the number of bits our cipher requires. This algorithm was derived from
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// the OpenSSL source.
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func (c rfc1423Algo) deriveKey(password, salt []byte) []byte {
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hash := md5.New()
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out := make([]byte, c.keySize)
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var digest []byte
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for i := 0; i < len(out); i += len(digest) {
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hash.Reset()
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hash.Write(digest)
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hash.Write(password)
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hash.Write(salt)
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digest = hash.Sum(digest[:0])
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copy(out[i:], digest)
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}
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return out
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}
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// IsEncryptedPEMBlock returns if the PEM block is password encrypted.
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func IsEncryptedPEMBlock(b *pem.Block) bool {
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_, ok := b.Headers["DEK-Info"]
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return ok
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}
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// IncorrectPasswordError is returned when an incorrect password is detected.
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var IncorrectPasswordError = errors.New("x509: decryption password incorrect")
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// DecryptPEMBlock takes a password encrypted PEM block and the password used to
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// encrypt it and returns a slice of decrypted DER encoded bytes. It inspects
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// the DEK-Info header to determine the algorithm used for decryption. If no
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// DEK-Info header is present, an error is returned. If an incorrect password
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// is detected an IncorrectPasswordError is returned.
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func DecryptPEMBlock(b *pem.Block, password []byte) ([]byte, error) {
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dek, ok := b.Headers["DEK-Info"]
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if !ok {
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return nil, errors.New("x509: no DEK-Info header in block")
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}
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idx := strings.Index(dek, ",")
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if idx == -1 {
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return nil, errors.New("x509: malformed DEK-Info header")
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}
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mode, hexIV := dek[:idx], dek[idx+1:]
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ciph := cipherByName(mode)
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if ciph == nil {
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return nil, errors.New("x509: unknown encryption mode")
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}
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iv, err := hex.DecodeString(hexIV)
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if err != nil {
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return nil, err
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}
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if len(iv) != ciph.blockSize {
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return nil, errors.New("x509: incorrect IV size")
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}
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// Based on the OpenSSL implementation. The salt is the first 8 bytes
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// of the initialization vector.
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key := ciph.deriveKey(password, iv[:8])
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block, err := ciph.cipherFunc(key)
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if err != nil {
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return nil, err
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}
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data := make([]byte, len(b.Bytes))
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dec := cipher.NewCBCDecrypter(block, iv)
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dec.CryptBlocks(data, b.Bytes)
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// Blocks are padded using a scheme where the last n bytes of padding are all
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// equal to n. It can pad from 1 to blocksize bytes inclusive. See RFC 1423.
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// For example:
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// [x y z 2 2]
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// [x y 7 7 7 7 7 7 7]
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// If we detect a bad padding, we assume it is an invalid password.
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dlen := len(data)
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if dlen == 0 || dlen%ciph.blockSize != 0 {
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return nil, errors.New("x509: invalid padding")
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}
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last := int(data[dlen-1])
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if dlen < last {
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return nil, IncorrectPasswordError
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}
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if last == 0 || last > ciph.blockSize {
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return nil, IncorrectPasswordError
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}
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for _, val := range data[dlen-last:] {
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if int(val) != last {
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return nil, IncorrectPasswordError
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}
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}
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return data[:dlen-last], nil
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}
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// EncryptPEMBlock returns a PEM block of the specified type holding the
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// given DER-encoded data encrypted with the specified algorithm and
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// password.
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func EncryptPEMBlock(rand io.Reader, blockType string, data, password []byte, alg PEMCipher) (*pem.Block, error) {
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ciph := cipherByKey(alg)
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if ciph == nil {
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return nil, errors.New("x509: unknown encryption mode")
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}
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iv := make([]byte, ciph.blockSize)
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if _, err := io.ReadFull(rand, iv); err != nil {
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return nil, errors.New("x509: cannot generate IV: " + err.Error())
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}
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// The salt is the first 8 bytes of the initialization vector,
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// matching the key derivation in DecryptPEMBlock.
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key := ciph.deriveKey(password, iv[:8])
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block, err := ciph.cipherFunc(key)
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if err != nil {
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return nil, err
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}
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enc := cipher.NewCBCEncrypter(block, iv)
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pad := ciph.blockSize - len(data)%ciph.blockSize
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encrypted := make([]byte, len(data), len(data)+pad)
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// We could save this copy by encrypting all the whole blocks in
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// the data separately, but it doesn't seem worth the additional
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// code.
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copy(encrypted, data)
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// See RFC 1423, section 1.1
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for i := 0; i < pad; i++ {
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encrypted = append(encrypted, byte(pad))
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}
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enc.CryptBlocks(encrypted, encrypted)
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return &pem.Block{
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Type: blockType,
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Headers: map[string]string{
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"Proc-Type": "4,ENCRYPTED",
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"DEK-Info": ciph.name + "," + hex.EncodeToString(iv),
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},
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Bytes: encrypted,
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}, nil
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}
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func cipherByName(name string) *rfc1423Algo {
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for i := range rfc1423Algos {
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alg := &rfc1423Algos[i]
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if alg.name == name {
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return alg
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}
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}
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return nil
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}
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func cipherByKey(key PEMCipher) *rfc1423Algo {
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for i := range rfc1423Algos {
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alg := &rfc1423Algos[i]
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if alg.cipher == key {
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return alg
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}
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}
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return nil
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}
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