// Copyright 2012 The Go Authors. All rights reserved. // Use of this source code is governed by a BSD-style // license that can be found in the LICENSE file. package cipher_test import ( "crypto/aes" "crypto/cipher" "crypto/rand" "encoding/hex" "fmt" "io" "os" ) func ExampleNewGCM_encrypt() { // The key argument should be the AES key, either 16 or 32 bytes // to select AES-128 or AES-256. key := []byte("AES256Key-32Characters1234567890") plaintext := []byte("exampleplaintext") block, err := aes.NewCipher(key) if err != nil { panic(err.Error()) } // Never use more than 2^32 random nonces with a given key because of the risk of a repeat. nonce := make([]byte, 12) if _, err := io.ReadFull(rand.Reader, nonce); err != nil { panic(err.Error()) } aesgcm, err := cipher.NewGCM(block) if err != nil { panic(err.Error()) } ciphertext := aesgcm.Seal(nil, nonce, plaintext, nil) fmt.Printf("%x\n", ciphertext) } func ExampleNewGCM_decrypt() { // The key argument should be the AES key, either 16 or 32 bytes // to select AES-128 or AES-256. key := []byte("AES256Key-32Characters1234567890") ciphertext, _ := hex.DecodeString("1019aa66cd7c024f9efd0038899dae1973ee69427f5a6579eba292ffe1b5a260") nonce, _ := hex.DecodeString("37b8e8a308c354048d245f6d") block, err := aes.NewCipher(key) if err != nil { panic(err.Error()) } aesgcm, err := cipher.NewGCM(block) if err != nil { panic(err.Error()) } plaintext, err := aesgcm.Open(nil, nonce, ciphertext, nil) if err != nil { panic(err.Error()) } fmt.Printf("%s\n", plaintext) // Output: exampleplaintext } func ExampleNewCBCDecrypter() { key := []byte("example key 1234") ciphertext, _ := hex.DecodeString("f363f3ccdcb12bb883abf484ba77d9cd7d32b5baecb3d4b1b3e0e4beffdb3ded") block, err := aes.NewCipher(key) if err != nil { panic(err) } // The IV needs to be unique, but not secure. Therefore it's common to // include it at the beginning of the ciphertext. if len(ciphertext) < aes.BlockSize { panic("ciphertext too short") } iv := ciphertext[:aes.BlockSize] ciphertext = ciphertext[aes.BlockSize:] // CBC mode always works in whole blocks. if len(ciphertext)%aes.BlockSize != 0 { panic("ciphertext is not a multiple of the block size") } mode := cipher.NewCBCDecrypter(block, iv) // CryptBlocks can work in-place if the two arguments are the same. mode.CryptBlocks(ciphertext, ciphertext) // If the original plaintext lengths are not a multiple of the block // size, padding would have to be added when encrypting, which would be // removed at this point. For an example, see // https://tools.ietf.org/html/rfc5246#section-6.2.3.2. However, it's // critical to note that ciphertexts must be authenticated (i.e. by // using crypto/hmac) before being decrypted in order to avoid creating // a padding oracle. fmt.Printf("%s\n", ciphertext) // Output: exampleplaintext } func ExampleNewCBCEncrypter() { key := []byte("example key 1234") plaintext := []byte("exampleplaintext") // CBC mode works on blocks so plaintexts may need to be padded to the // next whole block. For an example of such padding, see // https://tools.ietf.org/html/rfc5246#section-6.2.3.2. Here we'll // assume that the plaintext is already of the correct length. if len(plaintext)%aes.BlockSize != 0 { panic("plaintext is not a multiple of the block size") } block, err := aes.NewCipher(key) if err != nil { panic(err) } // The IV needs to be unique, but not secure. Therefore it's common to // include it at the beginning of the ciphertext. ciphertext := make([]byte, aes.BlockSize+len(plaintext)) iv := ciphertext[:aes.BlockSize] if _, err := io.ReadFull(rand.Reader, iv); err != nil { panic(err) } mode := cipher.NewCBCEncrypter(block, iv) mode.CryptBlocks(ciphertext[aes.BlockSize:], plaintext) // It's important to remember that ciphertexts must be authenticated // (i.e. by using crypto/hmac) as well as being encrypted in order to // be secure. fmt.Printf("%x\n", ciphertext) } func ExampleNewCFBDecrypter() { key := []byte("example key 1234") ciphertext, _ := hex.DecodeString("22277966616d9bc47177bd02603d08c9a67d5380d0fe8cf3b44438dff7b9") block, err := aes.NewCipher(key) if err != nil { panic(err) } // The IV needs to be unique, but not secure. Therefore it's common to // include it at the beginning of the ciphertext. if len(ciphertext) < aes.BlockSize { panic("ciphertext too short") } iv := ciphertext[:aes.BlockSize] ciphertext = ciphertext[aes.BlockSize:] stream := cipher.NewCFBDecrypter(block, iv) // XORKeyStream can work in-place if the two arguments are the same. stream.XORKeyStream(ciphertext, ciphertext) fmt.Printf("%s", ciphertext) // Output: some plaintext } func ExampleNewCFBEncrypter() { key := []byte("example key 1234") plaintext := []byte("some plaintext") block, err := aes.NewCipher(key) if err != nil { panic(err) } // The IV needs to be unique, but not secure. Therefore it's common to // include it at the beginning of the ciphertext. ciphertext := make([]byte, aes.BlockSize+len(plaintext)) iv := ciphertext[:aes.BlockSize] if _, err := io.ReadFull(rand.Reader, iv); err != nil { panic(err) } stream := cipher.NewCFBEncrypter(block, iv) stream.XORKeyStream(ciphertext[aes.BlockSize:], plaintext) // It's important to remember that ciphertexts must be authenticated // (i.e. by using crypto/hmac) as well as being encrypted in order to // be secure. } func ExampleNewCTR() { key := []byte("example key 1234") plaintext := []byte("some plaintext") block, err := aes.NewCipher(key) if err != nil { panic(err) } // The IV needs to be unique, but not secure. Therefore it's common to // include it at the beginning of the ciphertext. ciphertext := make([]byte, aes.BlockSize+len(plaintext)) iv := ciphertext[:aes.BlockSize] if _, err := io.ReadFull(rand.Reader, iv); err != nil { panic(err) } stream := cipher.NewCTR(block, iv) stream.XORKeyStream(ciphertext[aes.BlockSize:], plaintext) // It's important to remember that ciphertexts must be authenticated // (i.e. by using crypto/hmac) as well as being encrypted in order to // be secure. // CTR mode is the same for both encryption and decryption, so we can // also decrypt that ciphertext with NewCTR. plaintext2 := make([]byte, len(plaintext)) stream = cipher.NewCTR(block, iv) stream.XORKeyStream(plaintext2, ciphertext[aes.BlockSize:]) fmt.Printf("%s\n", plaintext2) // Output: some plaintext } func ExampleNewOFB() { key := []byte("example key 1234") plaintext := []byte("some plaintext") block, err := aes.NewCipher(key) if err != nil { panic(err) } // The IV needs to be unique, but not secure. Therefore it's common to // include it at the beginning of the ciphertext. ciphertext := make([]byte, aes.BlockSize+len(plaintext)) iv := ciphertext[:aes.BlockSize] if _, err := io.ReadFull(rand.Reader, iv); err != nil { panic(err) } stream := cipher.NewOFB(block, iv) stream.XORKeyStream(ciphertext[aes.BlockSize:], plaintext) // It's important to remember that ciphertexts must be authenticated // (i.e. by using crypto/hmac) as well as being encrypted in order to // be secure. // OFB mode is the same for both encryption and decryption, so we can // also decrypt that ciphertext with NewOFB. plaintext2 := make([]byte, len(plaintext)) stream = cipher.NewOFB(block, iv) stream.XORKeyStream(plaintext2, ciphertext[aes.BlockSize:]) fmt.Printf("%s\n", plaintext2) // Output: some plaintext } func ExampleStreamReader() { key := []byte("example key 1234") inFile, err := os.Open("encrypted-file") if err != nil { panic(err) } defer inFile.Close() block, err := aes.NewCipher(key) if err != nil { panic(err) } // If the key is unique for each ciphertext, then it's ok to use a zero // IV. var iv [aes.BlockSize]byte stream := cipher.NewOFB(block, iv[:]) outFile, err := os.OpenFile("decrypted-file", os.O_WRONLY|os.O_CREATE|os.O_TRUNC, 0600) if err != nil { panic(err) } defer outFile.Close() reader := &cipher.StreamReader{S: stream, R: inFile} // Copy the input file to the output file, decrypting as we go. if _, err := io.Copy(outFile, reader); err != nil { panic(err) } // Note that this example is simplistic in that it omits any // authentication of the encrypted data. If you were actually to use // StreamReader in this manner, an attacker could flip arbitrary bits in // the output. } func ExampleStreamWriter() { key := []byte("example key 1234") inFile, err := os.Open("plaintext-file") if err != nil { panic(err) } defer inFile.Close() block, err := aes.NewCipher(key) if err != nil { panic(err) } // If the key is unique for each ciphertext, then it's ok to use a zero // IV. var iv [aes.BlockSize]byte stream := cipher.NewOFB(block, iv[:]) outFile, err := os.OpenFile("encrypted-file", os.O_WRONLY|os.O_CREATE|os.O_TRUNC, 0600) if err != nil { panic(err) } defer outFile.Close() writer := &cipher.StreamWriter{S: stream, W: outFile} // Copy the input file to the output file, encrypting as we go. if _, err := io.Copy(writer, inFile); err != nil { panic(err) } // Note that this example is simplistic in that it omits any // authentication of the encrypted data. If you were actually to use // StreamReader in this manner, an attacker could flip arbitrary bits in // the decrypted result. }