mirror of
https://github.com/1f349/twofactor.git
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72a472700b
The counter needs to be represented in bigendian format. Unfortunately with commit #00045cb I made the unfortunate choice to swap the endiannes from big-endian to little-endian. This broke the functionality for certain counters. - [x] Added Go vendoring - [x] Bumped version of golang in travis yml file - [x] Removed conversion files and instead used import of convert sec51 external library
512 lines
16 KiB
Go
512 lines
16 KiB
Go
package cryptoengine
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import (
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"bytes"
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"crypto/rand"
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"crypto/sha256"
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"errors"
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"fmt"
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"golang.org/x/crypto/nacl/box"
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"golang.org/x/crypto/nacl/secretbox"
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"log"
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"math"
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"net/url"
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"regexp"
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"strconv"
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"strings"
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"sync"
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)
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const (
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nonceSize = 24 // this is the nonce size, required by NaCl
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keySize = 32 // this is the nonce size, required by NaCl
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rotateSaltAfterDays = 7 // this is the amount of days the salt is valid - if it crosses this amount a new salt is generated
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tcpVersion = 0 // this is the current TCP version
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)
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var (
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KeySizeError = errors.New(fmt.Sprintf("The provisioned key size is less than: %d\n", keySize))
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KeyNotValidError = errors.New("The provisioned public key is not valid")
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SaltGenerationError = errors.New("Could not generate random salt")
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KeyGenerationError = errors.New("Could not generate random key")
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MessageDecryptionError = errors.New("Could not verify the message. Message has been tempered with!")
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MessageParsingError = errors.New("Could not parse the Message from bytes")
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messageEmpty = errors.New("Can not encrypt an empty message")
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whiteSpaceRegEx = regexp.MustCompile("\\s")
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emptyKey = make([]byte, keySize)
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// salt for derivating keys
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saltSuffixFormat = "%s_salt.key" // this is the salt file,for instance: sec51_salt.key
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// secret key for symmetric encryption
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secretSuffixFormat = "%s_secret.key" // this is the secret key crypto file, for instance: sec51_secret.key
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// asymmetric keys
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publicKeySuffixFormat = "%s_public.key" // this is the public key crypto file,for instance: sec51_public.key
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privateSuffixFormat = "%s_private.key" // this is the private key crypto file,for instance: sec51_priovate.key
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// nonce secret key
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nonceSuffixFormat = "%s_nonce.key" // this is the secret key crypto file used for generating nonces,for instance: sec51_nonce.key
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)
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// This is the basic object which needs to be instanciated for encrypting messages
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// either via public key cryptography or private key cryptography
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// The object has the methods necessary to execute all the needed functions to encrypt and decrypt a message, both with symmetric and asymmetric
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// crypto
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type CryptoEngine struct {
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context string // this is the context used for the key derivation function and for namespacing the key files
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publicKey [keySize]byte // cached asymmetric public key
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privateKey [keySize]byte // cached asymmetric private key
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secretKey [keySize]byte // secret key used for symmetric encryption
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salt [keySize]byte // salt for deriving the random nonces
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nonceKey [keySize]byte // this key is used for deriving the random nonces. It's different from the privateKey
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mutex sync.Mutex // this mutex is used ti make sure that in case the engine is used by multiple thread the pre-shared key is correctly generated
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preSharedKeysMap map[string][keySize]byte // this map holds the combination hash of peer public key as the map key and the preshared key as value used to encrypt
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counter uint64 // this is the counter which is appended to the HKDF at each call
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counterMutex sync.Mutex // this is the counter mutex for a safe incrementation (TODO: look into atomic)
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}
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// This function initialize all the necessary information to carry out a secure communication
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// either via public key cryptography or secret key cryptography.
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// The peculiarity is that the user of this package needs to take care of only one parameter, the communicationIdentifier.
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// It defines a unique set of keys between the application and the communicationIdentifier unique end point.
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// IMPORTANT: The parameter communicationIdentifier defines several assumptions the code use:
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// - it names the secret key files with the comuncationIdentifier prefix. This means that if you want to have different secret keys
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// with different end points, you can differrentiate the key by having different unique communicationIdentifier.
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// It, also, loads the already created keys back in memory based on the communicationIdentifier
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// - it does the same with the asymmetric keys
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// The communicationIdentifier parameter is URL unescape, trimmed, set to lower case and all the white spaces are replaced with an underscore.
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// The publicKey parameter can be nil. In that case the CryptoEngine assumes it has been instanciated for symmetric crypto usage.
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func InitCryptoEngine(communicationIdentifier string) (*CryptoEngine, error) {
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// define an error object
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var err error
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// create a new crypto engine object
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ce := new(CryptoEngine)
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// sanitize the communicationIdentifier
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ce.context = sanitizeIdentifier(communicationIdentifier)
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// load or generate the salt
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salt, err := loadSalt(ce.context)
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if err != nil {
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return nil, err
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}
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ce.salt = salt
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// load or generate the corresponding public/private key pair
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ce.publicKey, ce.privateKey, err = loadKeyPairs(ce.context)
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if err != nil {
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return nil, err
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}
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// load or generate the secret key
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secretKey, err := loadSecretKey(ce.context)
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if err != nil {
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return nil, err
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}
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ce.secretKey = secretKey
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// load the nonce key
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nonceKey, err := loadNonceKey(ce.context)
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if err != nil {
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return nil, err
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}
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ce.nonceKey = nonceKey
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// init the map
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ce.preSharedKeysMap = make(map[string][keySize]byte)
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// finally return the CryptoEngine instance
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return ce, nil
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}
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// this function reads nonceSize random data
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func generateSalt() ([keySize]byte, error) {
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var data32 [keySize]byte
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data := make([]byte, keySize)
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_, err := rand.Read(data)
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if err != nil {
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return data32, err
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}
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total := copy(data32[:], data)
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if total != keySize {
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return data32, SaltGenerationError
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}
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return data32, nil
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}
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// this function reads keySize random data
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func generateSecretKey() ([keySize]byte, error) {
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var data32 [keySize]byte
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data := make([]byte, keySize)
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_, err := rand.Read(data)
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if err != nil {
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return data32, err
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}
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total := copy(data32[:], data[:keySize])
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if total != keySize {
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return data32, KeyGenerationError
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}
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return data32, nil
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}
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// load the salt random bytes from the id_salt.key
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// if the file does not exist, create a new one
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// if the file is older than N days (default 2) generate a new one and overwrite the old
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// TODO: rotate the salt file
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func loadSalt(id string) ([keySize]byte, error) {
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var salt [keySize]byte
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saltFile := fmt.Sprintf(saltSuffixFormat, id)
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if keyFileExists(saltFile) {
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return readKey(saltFile, keysFolderPrefixFormat)
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}
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// generate the random salt
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salt, err := generateSalt()
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if err != nil {
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return salt, err
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}
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// write the salt to the file with its prefix
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if err := writeKey(saltFile, keysFolderPrefixFormat, salt[:]); err != nil {
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return salt, err
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}
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// return the salt and no error
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return salt, nil
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}
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// load the key random bytes from the id_secret.key
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// if the file does not exist, create a new one
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func loadSecretKey(id string) ([keySize]byte, error) {
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var key [keySize]byte
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keyFile := fmt.Sprintf(secretSuffixFormat, id)
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if keyFileExists(keyFile) {
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return readKey(keyFile, keysFolderPrefixFormat)
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}
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// generate the random salt
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key, err := generateSecretKey()
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if err != nil {
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return key, err
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}
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// write the salt to the file with its prefix
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if err := writeKey(keyFile, keysFolderPrefixFormat, key[:]); err != nil {
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return key, err
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}
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// return the salt and no error
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return key, nil
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}
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// load the nonce key random bytes from the id_nonce.key
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// if the file does not exist, create a new one
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func loadNonceKey(id string) ([keySize]byte, error) {
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var nonceKey [keySize]byte
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nonceFile := fmt.Sprintf(nonceSuffixFormat, id)
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if keyFileExists(nonceFile) {
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return readKey(nonceFile, keysFolderPrefixFormat)
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}
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// generate the random salt
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nonceKey, err := generateSecretKey()
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if err != nil {
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return nonceKey, err
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}
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// write the salt to the file with its prefix
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if err := writeKey(nonceFile, keysFolderPrefixFormat, nonceKey[:]); err != nil {
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return nonceKey, err
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}
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// return the salt and no error
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return nonceKey, nil
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}
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// load the key pair, public and private keys, the id_public.key, id_private.key
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// if the files do not exist, create them
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// Returns the publicKey, privateKey, error
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func loadKeyPairs(id string) ([keySize]byte, [keySize]byte, error) {
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var private [keySize]byte
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var public [keySize]byte
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var err error
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// try to load the private key
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privateFile := fmt.Sprintf(privateSuffixFormat, id)
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if keyFileExists(privateFile) {
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if private, err = readKey(privateFile, keysFolderPrefixFormat); err != nil {
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return public, private, err
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}
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}
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// try to load the public key and if it succeed, then return both the keys
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publicFile := fmt.Sprintf(publicKeySuffixFormat, id)
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if keyFileExists(publicFile) {
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if public, err = readKey(publicFile, keysFolderPrefixFormat); err != nil {
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return public, private, err
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}
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// if we reached here, it means that both the private and the public key
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// existed and loaded successfully
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return public, private, err
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}
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// if we reached here then, we need to cerate the key pair
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tempPublic, tempPrivate, err := box.GenerateKey(rand.Reader)
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// check for errors first, otherwise continue and store the keys to files
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if err != nil {
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return public, private, err
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}
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// dereference the pointers
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public = *tempPublic
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private = *tempPrivate
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// write the public key first
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if err := writeKey(publicFile, keysFolderPrefixFormat, public[:]); err != nil {
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return public, private, err
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}
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// write the private
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if err := writeKey(privateFile, keysFolderPrefixFormat, private[:]); err != nil {
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// delete the public key, otherwise we remain in an unwanted state
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// the delete can fail as well, therefore we print an error
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if err := deleteFile(publicFile); err != nil {
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log.Printf("[SEVERE] - The private key for asymmetric encryption, %s, failed to be persisted. \nWhile trying to cleanup also the public key previosuly stored, %s, the operation failed as well.\nWe are now in an unrecoverable state.Please delete both files manually: %s - %s", privateFile, publicFile, privateFile, publicFile)
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return public, private, err
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}
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return public, private, err
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}
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// return the data
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return public, private, err
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}
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// Sanitizes the input of the communicationIdentifier
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// The input is URL unescape, trimmed, set to lower case and all the white spaces are replaced with an underscore.
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// TODO: evaluate the QueryUnescape error
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func sanitizeIdentifier(id string) string {
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// unescape in case it;s URL encoded
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unescaped, _ := url.QueryUnescape(id)
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// trim white spaces
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trimmed := strings.TrimSpace(unescaped)
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// make lower case
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lowered := strings.ToLower(trimmed)
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// replace the white spaces with _
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cleaned := whiteSpaceRegEx.ReplaceAllLiteralString(lowered, "_")
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return cleaned
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}
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func (engine *CryptoEngine) fetchAndIncrement() string {
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engine.counterMutex.Lock()
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defer engine.counterMutex.Unlock()
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// first read the current value
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// reset the counter
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if engine.counter == math.MaxUint64 {
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engine.counter = 0
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}
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// convert the counter to string
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counterString := strconv.FormatUint(engine.counter, 10)
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// increment the counter
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engine.counter += 1
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return counterString
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}
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// Gives access to the public key
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func (engine *CryptoEngine) PublicKey() []byte {
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return engine.publicKey[:]
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}
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// This method accepts a message , then encrypts its Version+Type+Text using a symmetric key
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func (engine *CryptoEngine) NewEncryptedMessage(msg message) (EncryptedMessage, error) {
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m := EncryptedMessage{}
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// derive nonce
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nonce, err := deriveNonce(engine.nonceKey, engine.salt, engine.context, engine.fetchAndIncrement())
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if err != nil {
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return m, err
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}
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m.nonce = nonce
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encryptedData := secretbox.Seal(nil, msg.toBytes(), &m.nonce, &engine.secretKey)
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// assign the encrypted data to the message
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m.data = encryptedData
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// calculate the overall size of the message
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m.length = uint64(len(m.data) + len(m.nonce) + 8)
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return m, nil
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}
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// This method accepts the message as byte slice and the public key of the receiver of the messae,
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// then encrypts it using the asymmetric key public key.
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// If the public key is not privisioned and does not have the required length of 32 bytes it raises an exception.
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func (engine *CryptoEngine) NewEncryptedMessageWithPubKey(msg message, verificationEngine VerificationEngine) (EncryptedMessage, error) {
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encryptedMessage := EncryptedMessage{}
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// get the peer public key
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peerPublicKey := verificationEngine.PublicKey()
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// check the size of the peerPublicKey
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if len(peerPublicKey) != keySize {
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return encryptedMessage, KeyNotValidError
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}
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// check the peerPublicKey is not empty (all zeros)
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if bytes.Compare(peerPublicKey[:], emptyKey) == 0 {
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return encryptedMessage, KeyNotValidError
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}
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// derive nonce
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nonce, err := deriveNonce(engine.nonceKey, engine.salt, engine.context, engine.fetchAndIncrement())
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if err != nil {
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return encryptedMessage, err
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}
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// set the nonce to the encrypted message
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encryptedMessage.nonce = nonce
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// calculate the hash of the peer public key
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sha224String := fmt.Sprintf("%x", sha256.Sum224(peerPublicKey[:]))
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// lock the mutex
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engine.mutex.Lock()
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// check if the pre sgared key is already present in the map
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if preSharedKey, ok := engine.preSharedKeysMap[sha224String]; ok { // means the key is there
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// unlock the mutex
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engine.mutex.Unlock()
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// encrypt with the pre-computed key
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encryptedData := box.SealAfterPrecomputation(nil, msg.toBytes(), &nonce, &preSharedKey)
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// assign the encrypted data to the message
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encryptedMessage.data = encryptedData
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} else { // means the key is not there
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// generate the key
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// init the buffer
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preSharedKey = [keySize]byte{}
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// precompute the share key
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box.Precompute(&preSharedKey, &peerPublicKey, &engine.privateKey)
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// assign it to the map
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engine.preSharedKeysMap[sha224String] = preSharedKey
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// unlock the mutex once the map has the sharedKey set
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engine.mutex.Unlock()
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// encrypt with the pre-computed key
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encryptedData := box.SealAfterPrecomputation(nil, msg.toBytes(), &nonce, &preSharedKey)
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// assign the encrypted data to the message
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encryptedMessage.data = encryptedData
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}
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// calculate the size of the message
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encryptedMessage.length = uint64(len(encryptedMessage.data) + len(encryptedMessage.nonce) + 8)
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return encryptedMessage, nil
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}
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// This method is used to decrypt messages where symmetrci encryption is used
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func (engine *CryptoEngine) Decrypt(encryptedBytes []byte) (*message, error) {
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var err error
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msg := new(message)
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// convert the bytes to an encrypted message
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encryptedMessage, err := encryptedMessageFromBytes(encryptedBytes)
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if err != nil {
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return nil, err
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}
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decryptedMessageBytes, valid := secretbox.Open(nil, encryptedMessage.data, &encryptedMessage.nonce, &engine.secretKey)
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// if the verification failed
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if !valid {
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return nil, MessageDecryptionError
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}
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// means we successfully managed to decrypt
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msg, err = messageFromBytes(decryptedMessageBytes)
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return msg, nil
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}
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// This method is used to decrypt messages where symmetrci encryption is used
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func (engine *CryptoEngine) DecryptWithPublicKey(encryptedBytes []byte, verificationEngine VerificationEngine) (*message, error) {
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var err error
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// get the peer public key
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peerPublicKey := verificationEngine.PublicKey()
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// convert the bytes to an encrypted message
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encryptedMessage, err := encryptedMessageFromBytes(encryptedBytes)
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if err != nil {
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return nil, err
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}
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// Make sure the key has a valid size
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if len(peerPublicKey) < keySize {
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return nil, KeyNotValidError
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}
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// calculate the hash of the peer public key
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sha224String := fmt.Sprintf("%x", sha256.Sum224(peerPublicKey[:]))
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// lock the mutex
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engine.mutex.Lock()
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// check if the pre sgared key is already present in the map
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if preSharedKey, ok := engine.preSharedKeysMap[sha224String]; ok { // means the key is there
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// unlock the mutex
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engine.mutex.Unlock()
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messageBytes, err := decryptWithPreShared(preSharedKey, encryptedMessage)
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if err != nil {
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return nil, err
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}
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return messageFromBytes(messageBytes)
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} else {
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// otherwise decrypt with the standard box open function
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messageBytes, valid := box.Open(nil, encryptedMessage.data, &encryptedMessage.nonce, &peerPublicKey, &engine.privateKey)
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if !valid {
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return nil, MessageDecryptionError
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}
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return messageFromBytes(messageBytes)
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}
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}
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func decryptWithPreShared(preSharedKey [keySize]byte, m EncryptedMessage) ([]byte, error) {
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if decryptedMessage, valid := box.OpenAfterPrecomputation(nil, m.data, &m.nonce, &preSharedKey); !valid {
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return nil, MessageDecryptionError
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} else {
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return decryptedMessage, nil
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}
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}
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