/* * Copyright (c) 2007, 2012, Oracle and/or its affiliates. All rights reserved. * DO NOT ALTER OR REMOVE COPYRIGHT NOTICES OR THIS FILE HEADER. * * This code is free software; you can redistribute it and/or modify it * under the terms of the GNU General Public License version 2 only, as * published by the Free Software Foundation. * * This code is distributed in the hope that it will be useful, but WITHOUT * ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or * FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License * version 2 for more details (a copy is included in the LICENSE file that * accompanied this code). * * You should have received a copy of the GNU General Public License version * 2 along with this work; if not, write to the Free Software Foundation, * Inc., 51 Franklin St, Fifth Floor, Boston, MA 02110-1301 USA. * * Please contact Oracle, 500 Oracle Parkway, Redwood Shores, CA 94065 USA * or visit www.oracle.com if you need additional information or have any * questions. */ // Checkstyle: stop package org.graalvm.compiler.jtt.hotpath; import java.util.Random; import org.junit.Test; import org.graalvm.compiler.jtt.JTTTest; public class HP_idea extends JTTTest { public boolean test() { buildTestData(); Do(); return verify(); } // Declare class data. Byte buffer plain1 holds the original // data for encryption, crypt1 holds the encrypted data, and // plain2 holds the decrypted data, which should match plain1 // byte for byte. int array_rows; byte[] plain1; // Buffer for plaintext data. byte[] crypt1; // Buffer for encrypted data. byte[] plain2; // Buffer for decrypted data. short[] userkey; // Key for encryption/decryption. int[] Z; // Encryption subkey (userkey derived). int[] DK; // Decryption subkey (userkey derived). void Do() { cipher_idea(plain1, crypt1, Z); // Encrypt plain1. cipher_idea(crypt1, plain2, DK); // Decrypt. } /* * buildTestData * * Builds the data used for the test -- each time the test is run. */ void buildTestData() { // Create three byte arrays that will be used (and reused) for // encryption/decryption operations. plain1 = new byte[array_rows]; crypt1 = new byte[array_rows]; plain2 = new byte[array_rows]; Random rndnum = new Random(136506717L); // Create random number generator. // Allocate three arrays to hold keys: userkey is the 128-bit key. // Z is the set of 16-bit encryption subkeys derived from userkey, // while DK is the set of 16-bit decryption subkeys also derived // from userkey. NOTE: The 16-bit values are stored here in // 32-bit int arrays so that the values may be used in calculations // as if they are unsigned. Each 64-bit block of plaintext goes // through eight processing rounds involving six of the subkeys // then a final output transform with four of the keys; (8 * 6) // + 4 = 52 subkeys. userkey = new short[8]; // User key has 8 16-bit shorts. Z = new int[52]; // Encryption subkey (user key derived). DK = new int[52]; // Decryption subkey (user key derived). // Generate user key randomly; eight 16-bit values in an array. for (int i = 0; i < 8; i++) { // Again, the random number function returns int. Converting // to a short type preserves the bit pattern in the lower 16 // bits of the int and discards the rest. userkey[i] = (short) rndnum.nextInt(); } // Compute encryption and decryption subkeys. calcEncryptKey(); calcDecryptKey(); // Fill plain1 with "text." for (int i = 0; i < array_rows; i++) { plain1[i] = (byte) i; // Converting to a byte // type preserves the bit pattern in the lower 8 bits of the // int and discards the rest. } } /* * calcEncryptKey * * Builds the 52 16-bit encryption subkeys Z[] from the user key and stores in 32-bit int array. * The routing corrects an error in the source code in the Schnier book. Basically, the sense of * the 7- and 9-bit shifts are reversed. It still works reversed, but would encrypted code would * not decrypt with someone else's IDEA code. */ private void calcEncryptKey() { int j; // Utility variable. for (int i = 0; i < 52; i++) { // Zero out the 52-int Z array. Z[i] = 0; } for (int i = 0; i < 8; i++) // First 8 subkeys are userkey itself. { Z[i] = userkey[i] & 0xffff; // Convert "unsigned" // short to int. } // Each set of 8 subkeys thereafter is derived from left rotating // the whole 128-bit key 25 bits to left (once between each set of // eight keys and then before the last four). Instead of actually // rotating the whole key, this routine just grabs the 16 bits // that are 25 bits to the right of the corresponding subkey // eight positions below the current subkey. That 16-bit extent // straddles two array members, so bits are shifted left in one // member and right (with zero fill) in the other. For the last // two subkeys in any group of eight, those 16 bits start to // wrap around to the first two members of the previous eight. for (int i = 8; i < 52; i++) { j = i % 8; if (j < 6) { Z[i] = ((Z[i - 7] >>> 9) | (Z[i - 6] << 7)) // Shift and combine. & 0xFFFF; // Just 16 bits. continue; // Next iteration. } if (j == 6) // Wrap to beginning for second chunk. { Z[i] = ((Z[i - 7] >>> 9) | (Z[i - 14] << 7)) & 0xFFFF; continue; } // j == 7 so wrap to beginning for both chunks. Z[i] = ((Z[i - 15] >>> 9) | (Z[i - 14] << 7)) & 0xFFFF; } } /* * calcDecryptKey * * Builds the 52 16-bit encryption subkeys DK[] from the encryption- subkeys Z[]. DK[] is a * 32-bit int array holding 16-bit values as unsigned. */ private void calcDecryptKey() { int j, k; // Index counters. int t1, t2, t3; // Temps to hold decrypt subkeys. t1 = inv(Z[0]); // Multiplicative inverse (mod x10001). t2 = -Z[1] & 0xffff; // Additive inverse, 2nd encrypt subkey. t3 = -Z[2] & 0xffff; // Additive inverse, 3rd encrypt subkey. DK[51] = inv(Z[3]); // Multiplicative inverse (mod x10001). DK[50] = t3; DK[49] = t2; DK[48] = t1; j = 47; // Indices into temp and encrypt arrays. k = 4; for (int i = 0; i < 7; i++) { t1 = Z[k++]; DK[j--] = Z[k++]; DK[j--] = t1; t1 = inv(Z[k++]); t2 = -Z[k++] & 0xffff; t3 = -Z[k++] & 0xffff; DK[j--] = inv(Z[k++]); DK[j--] = t2; DK[j--] = t3; DK[j--] = t1; } t1 = Z[k++]; DK[j--] = Z[k++]; DK[j--] = t1; t1 = inv(Z[k++]); t2 = -Z[k++] & 0xffff; t3 = -Z[k++] & 0xffff; DK[j--] = inv(Z[k++]); DK[j--] = t3; DK[j--] = t2; DK[j--] = t1; } /* * cipher_idea * * IDEA encryption/decryption algorithm. It processes plaintext in 64-bit blocks, one at a time, * breaking the block into four 16-bit unsigned subblocks. It goes through eight rounds of * processing using 6 new subkeys each time, plus four for last step. The source text is in * array text1, the destination text goes into array text2 The routine represents 16-bit * subblocks and subkeys as type int so that they can be treated more easily as unsigned. * Multiplication modulo 0x10001 interprets a zero sub-block as 0x10000; it must to fit in 16 * bits. */ @SuppressWarnings("static-method") private void cipher_idea(byte[] text1, byte[] text2, int[] key) { int i1 = 0; // Index into first text array. int i2 = 0; // Index into second text array. int ik; // Index into key array. int x1, x2, x3, x4, t1, t2; // Four "16-bit" blocks, two temps. int r; // Eight rounds of processing. for (int i = 0; i < text1.length; i += 8) { ik = 0; // Restart key index. r = 8; // Eight rounds of processing. // Load eight plain1 bytes as four 16-bit "unsigned" integers. // Masking with 0xff prevents sign extension with cast to int. x1 = text1[i1++] & 0xff; // Build 16-bit x1 from 2 bytes, x1 |= (text1[i1++] & 0xff) << 8; // assuming low-order byte first. x2 = text1[i1++] & 0xff; x2 |= (text1[i1++] & 0xff) << 8; x3 = text1[i1++] & 0xff; x3 |= (text1[i1++] & 0xff) << 8; x4 = text1[i1++] & 0xff; x4 |= (text1[i1++] & 0xff) << 8; do { // 1) Multiply (modulo 0x10001), 1st text sub-block // with 1st key sub-block. x1 = (int) ((long) x1 * key[ik++] % 0x10001L & 0xffff); // 2) Add (modulo 0x10000), 2nd text sub-block // with 2nd key sub-block. x2 = x2 + key[ik++] & 0xffff; // 3) Add (modulo 0x10000), 3rd text sub-block // with 3rd key sub-block. x3 = x3 + key[ik++] & 0xffff; // 4) Multiply (modulo 0x10001), 4th text sub-block // with 4th key sub-block. x4 = (int) ((long) x4 * key[ik++] % 0x10001L & 0xffff); // 5) XOR results from steps 1 and 3. t2 = x1 ^ x3; // 6) XOR results from steps 2 and 4. // Included in step 8. // 7) Multiply (modulo 0x10001), result of step 5 // with 5th key sub-block. t2 = (int) ((long) t2 * key[ik++] % 0x10001L & 0xffff); // 8) Add (modulo 0x10000), results of steps 6 and 7. t1 = t2 + (x2 ^ x4) & 0xffff; // 9) Multiply (modulo 0x10001), result of step 8 // with 6th key sub-block. t1 = (int) ((long) t1 * key[ik++] % 0x10001L & 0xffff); // 10) Add (modulo 0x10000), results of steps 7 and 9. t2 = t1 + t2 & 0xffff; // 11) XOR results from steps 1 and 9. x1 ^= t1; // 14) XOR results from steps 4 and 10. (Out of order). x4 ^= t2; // 13) XOR results from steps 2 and 10. (Out of order). t2 ^= x2; // 12) XOR results from steps 3 and 9. (Out of order). x2 = x3 ^ t1; x3 = t2; // Results of x2 and x3 now swapped. } while (--r != 0); // Repeats seven more rounds. // Final output transform (4 steps). // 1) Multiply (modulo 0x10001), 1st text-block // with 1st key sub-block. x1 = (int) ((long) x1 * key[ik++] % 0x10001L & 0xffff); // 2) Add (modulo 0x10000), 2nd text sub-block // with 2nd key sub-block. It says x3, but that is to undo swap // of subblocks 2 and 3 in 8th processing round. x3 = x3 + key[ik++] & 0xffff; // 3) Add (modulo 0x10000), 3rd text sub-block // with 3rd key sub-block. It says x2, but that is to undo swap // of subblocks 2 and 3 in 8th processing round. x2 = x2 + key[ik++] & 0xffff; // 4) Multiply (modulo 0x10001), 4th text-block // with 4th key sub-block. x4 = (int) ((long) x4 * key[ik++] % 0x10001L & 0xffff); // Repackage from 16-bit sub-blocks to 8-bit byte array text2. text2[i2++] = (byte) x1; text2[i2++] = (byte) (x1 >>> 8); text2[i2++] = (byte) x3; // x3 and x2 are switched text2[i2++] = (byte) (x3 >>> 8); // only in name. text2[i2++] = (byte) x2; text2[i2++] = (byte) (x2 >>> 8); text2[i2++] = (byte) x4; text2[i2++] = (byte) (x4 >>> 8); } // End for loop. } // End routine. /* * mul * * Performs multiplication, modulo (2**16)+1. This code is structured on the assumption that * untaken branches are cheaper than taken branches, and that the compiler doesn't schedule * branches. Java: Must work with 32-bit int and one 64-bit long to keep 16-bit values and their * products "unsigned." The routine assumes that both a and b could fit in 16 bits even though * they come in as 32-bit ints. Lots of "& 0xFFFF" masks here to keep things 16-bit. Also, * because the routine stores mod (2**16)+1 results in a 2**16 space, the result is truncated to * zero whenever the result would zero, be 2**16. And if one of the multiplicands is 0, the * result is not zero, but (2**16) + 1 minus the other multiplicand (sort of an additive inverse * mod 0x10001). * * NOTE: The java conversion of this routine works correctly, but is half the speed of using * Java's modulus division function (%) on the multiplication with a 16-bit masking of the * result--running in the Symantec Caje IDE. So it's not called for now; the test uses Java % * instead. */ /* * private int mul(int a, int b) throws ArithmeticException { long p; // Large enough to catch * 16-bit multiply // without hitting sign bit. if (a != 0) { if (b != 0) { p = (long) a * b; b * = (int) p & 0xFFFF; // Lower 16 bits. a = (int) p >>> 16; // Upper 16 bits. * * return (b - a + (b < a ? 1 : 0) & 0xFFFF); } else return ((1 - a) & 0xFFFF); // If b = 0, * then same as // 0x10001 - a. } else // If a = 0, then return return((1 - b) & 0xFFFF); // * same as 0x10001 - b. } */ /* * inv * * Compute multiplicative inverse of x, modulo (2**16)+1 using extended Euclid's GCD (greatest * common divisor) algorithm. It is unrolled twice to avoid swapping the meaning of the * registers. And some subtracts are changed to adds. Java: Though it uses signed 32-bit ints, * the interpretation of the bits within is strictly unsigned 16-bit. */ public int inv(int x) { int x2 = x; int t0, t1; int q, y; if (x2 <= 1) { return (x2); // 0 and 1 are self-inverse. } t1 = 0x10001 / x2; // (2**16+1)/x; x is >= 2, so fits 16 bits. y = 0x10001 % x2; if (y == 1) { return ((1 - t1) & 0xFFFF); } t0 = 1; do { q = x2 / y; x2 = x2 % y; t0 += q * t1; if (x2 == 1) { return (t0); } q = y / x2; y = y % x2; t1 += q * t0; } while (y != 1); return ((1 - t1) & 0xFFFF); } boolean verify() { boolean error; for (int i = 0; i < array_rows; i++) { error = (plain1[i] != plain2[i]); if (error) { return false; } } return true; } /* * freeTestData * * Nulls arrays and forces garbage collection to free up memory. */ void freeTestData() { plain1 = null; crypt1 = null; plain2 = null; userkey = null; Z = null; DK = null; } public HP_idea() { array_rows = 3000; } @Test public void run0() throws Throwable { runTest("test"); } @Test public void runInv() { runTest("inv", 724); } }