OpenXE/www/lib/class.xtea.php

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2021-05-21 08:49:41 +02:00
<?php
/* PHP Implementation of XTEA (www.php-einfach.de)
*
* XTEA was designed in 1997 by David Wheeler and Roger Needham
* of the Cambridge Computer Laboratory.
* It is not subject to any patents.
*
* It is a 64-bit Feistel cipher, consisting of 64 rounds.
* XTA has a key length of 128 bits.
*
*
* ***********************
* Diese Implementierung darf frei verwendet werden, der Autor uebernimmt keine
* Haftung fuer die Richtigkeit, Fehlerfreiheit oder die Funktionsfaehigkeit dieses Scripts.
* Benutzung auf eigene Gefahr.
*
* Ueber einen Link auf www.php-einfach.de wuerden wir uns freuen.
*
* ************************
* Usage:
* <?php
* include("xtea.class.php");
*
* $xtea = new XTEA("secret Key");
* $cipher = $xtea->Encrypt("Hello World"); //Encrypts 'Hello World'
* $plain = $xtea->Decrypt($cipher); //Decrypts the cipher text
*
* echo $plain;
* ?>
*/
class XTEA {
//Private
var $key;
// CBC or ECB Mode
// normaly, CBC Mode would be the right choice
var $cbc = 1;
function __construct($key) {
$this->key_setup($key);
}
//Verschluesseln
function encrypt($text) {
$n = strlen($text);
if($n%8 != 0) $lng = ($n+(8-($n%8)));
else $lng = 0;
$text = str_pad($text, $lng, ' ');
$text = $this->_str2long($text);
print("key 0: ".$this->key[0]."\n");
print("key 1: ".$this->key[1]."\n");
print("key 2: ".$this->key[2]."\n");
print("key 3: ".$this->key[3]."\n");
//Initialization vector: IV
if($this->cbc == 1) {
$cipher[0][0] = time();
$cipher[0][1] = (double)microtime()*1000000;
}
$a = 1;
for($i = 0; $i<count($text); $i+=2) {
if($this->cbc == 1) {
//$text mit letztem Geheimtext XOR Verknuepfen
//$text is XORed with the previous ciphertext
$text[$i] ^= $cipher[$a-1][0];
$text[$i+1] ^= $cipher[$a-1][1];
}
$cipher[] = $this->block_encrypt($text[$i],$text[$i+1]);
$a++;
}
$output = "";
for($i = 0; $i<count($cipher); $i++) {
$output .= $this->_long2str($cipher[$i][0]);
$output .= $this->_long2str($cipher[$i][1]);
}
return base64_encode($output);
}
//Entschluesseln
function decrypt($text) {
$plain = array();
$cipher = $this->_str2long(base64_decode($text, True));
if($this->cbc == 1)
$i = 2; //Message start at second block
else
$i = 0; //Message start at first block
for($i; $i<count($cipher); $i+=2) {
$return = $this->block_decrypt($cipher[$i],$cipher[$i+1]);
//Xor Verknuepfung von $return und Geheimtext aus von den letzten beiden Bloecken
//XORed $return with the previous ciphertext
if($this->cbc == 1)
$plain[] = array($return[0]^$cipher[$i-2],$return[1]^$cipher[$i-1]);
else //EBC Mode
$plain[] = $return;
}
$output = "";
for($i = 0; $i<count($plain); $i++) {
$output .= $this->_long2str($plain[$i][0]);
$output .= $this->_long2str($plain[$i][1]);
}
return $output;
}
//Bereitet den Key zum ver/entschluesseln vor
function key_setup($key) {
if(is_array($key))
$this->key = $key;
else if(isset($key) && !empty($key))
$this->key = $this->_str2long(str_pad($key, 16, $key));
else
$this->key = array(0,0,0,0);
}
//Performs a benchmark
function benchmark($length=1000) {
//1000 Byte String
$string = str_pad("", $length, "text");
//Key-Setup
$start1 = time() + (double)microtime();
$xtea = new XTEA("key");
$end1 = time() + (double)microtime();
//Encryption
$start2 = time() + (double)microtime();
$xtea->Encrypt($string);
$end2 = time() + (double)microtime();
echo "Encrypting ".$length." bytes: ".round($end2-$start2,2)." seconds (".round($length/($end2-$start2),2)." bytes/second)<br>";
}
//verify the correct implementation of the blowfish algorithm
function check_implementation() {
$xtea = new XTEA("");
$vectors = array(
array(array(0x00000000,0x00000000,0x00000000,0x00000000), array(0x41414141,0x41414141), array(0xed23375a,0x821a8c2d)),
array(array(0x00010203,0x04050607,0x08090a0b,0x0c0d0e0f), array(0x41424344,0x45464748), array(0x497df3d0,0x72612cb5)),
);
//Correct implementation?
$correct = true;
//Test vectors, see http://www.schneier.com/code/vectors.txt
foreach($vectors AS $vector) {
$key = $vector[0];
$plain = $vector[1];
$cipher = $vector[2];
$xtea->key_setup($key);
$return = $xtea->block_encrypt($vector[1][0],$vector[1][1]);
if((int)$return[0] != (int)$cipher[0] || (int)$return[1] != (int)$cipher[1])
$correct = false;
}
return $correct;
}
/***********************************
Some internal functions
***********************************/
function block_encrypt($y, $z) {
$sum=0;
$delta=0x9e3779b9;
/* start cycle */
for ($i=0; $i<32; $i++)
{
$y = $this->_add($y,
$this->_add($z << 4 ^ $this->_rshift($z, 5), $z) ^
$this-> _add($sum, $this->key[$sum & 3]));
$sum = $this->_add($sum, $delta);
$z = $this->_add($z,
$this->_add($y << 4 ^ $this->_rshift($y, 5), $y) ^
$this->_add($sum, $this->key[$this->_rshift($sum, 11) & 3]));
}
/* end cycle */
$v[0]=$y;
$v[1]=$z;
return array($y,$z);
}
function block_decrypt($y, $z) {
$delta=0x9e3779b9;
$sum=0xC6EF3720;
$n=32;
/* start cycle */
for ($i=0; $i<32; $i++)
{
$z = $this->_add($z,
-($this->_add($y << 4 ^ $this->_rshift($y, 5), $y) ^
$this->_add($sum, $this->key[$this->_rshift($sum, 11) & 3])));
$sum = $this->_add($sum, -$delta);
$y = $this->_add($y,
-($this->_add($z << 4 ^ $this->_rshift($z, 5), $z) ^
$this->_add($sum, $this->key[$sum & 3])));
}
/* end cycle */
return array($y,$z);
}
function _rshift($integer, $n) {
// convert to 32 bits
if (0xffffffff < $integer || -0xffffffff > $integer) {
$integer = fmod($integer, 0xffffffff + 1);
}
// convert to unsigned integer
if (0x7fffffff < $integer) {
$integer -= 0xffffffff + 1.0;
} elseif (-0x80000000 > $integer) {
$integer += 0xffffffff + 1.0;
}
// do right shift
if (0 > $integer) {
$integer &= 0x7fffffff; // remove sign bit before shift
$integer >>= $n; // right shift
$integer |= 1 << (31 - $n); // set shifted sign bit
} else {
$integer >>= $n; // use normal right shift
}
return $integer;
}
function _add($i1, $i2) {
$result = 0.0;
foreach (func_get_args() as $value) {
// remove sign if necessary
if (0.0 > $value) {
$value -= 1.0 + 0xffffffff;
}
$result += $value;
}
// convert to 32 bits
if (0xffffffff < $result || -0xffffffff > $result) {
$result = fmod($result, 0xffffffff + 1);
}
// convert to signed integer
if (0x7fffffff < $result) {
$result -= 0xffffffff + 1.0;
} elseif (-0x80000000 > $result) {
$result += 0xffffffff + 1.0;
}
return $result;
}
//Einen Text in Longzahlen umwandeln
//Covert a string into longinteger
function _str2long($data) {
$n = strlen($data);
$tmp = unpack('N*', $data);
$data_long = array();
$j = 0;
foreach ($tmp as $value) $data_long[$j++] = $value;
return $data_long;
}
//Longzahlen in Text umwandeln
//Convert a longinteger into a string
function _long2str($l){
return pack('N', $l);
}
}
?>