mirror of
https://github.com/rn10950/RetroZilla.git
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30d33aa8e8
9934c8faef29, 3c3b381c4865, 5a67f6beee9a, 1b1eb6d77728, a8b668fd72f7, bug962760, bug743700, bug857304, bug972653, bug972450, bug971358, bug903885, bug977073, bug976111, bug949939, bug947653, bug947572, bug903885, bug979106, bug966596, bug979004, bug979752, bug980848, bug938369, bug981170, bug668130, bug974693, bug975056, bug979132, bug370717, bug979070, bug985070, bug900067, bug977673, bug519255, bug989558, bug557299, bug987263, bug369802, a751a5146718, bug992343, bug952572, bug979703, bug994883, bug994869, bug993489, bug984608, bug977869, bug667371, bug672828, bug793347, bug977869
384 lines
10 KiB
C
384 lines
10 KiB
C
/*
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* aeskeywrap.c - implement AES Key Wrap algorithm from RFC 3394
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*
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* This Source Code Form is subject to the terms of the Mozilla Public
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* License, v. 2.0. If a copy of the MPL was not distributed with this
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* file, You can obtain one at http://mozilla.org/MPL/2.0/. */
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#ifdef FREEBL_NO_DEPEND
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#include "stubs.h"
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#endif
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#include "prcpucfg.h"
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#if defined(IS_LITTLE_ENDIAN) || defined(SHA_NO_LONG_LONG)
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#define BIG_ENDIAN_WITH_64_BIT_REGISTERS 0
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#else
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#define BIG_ENDIAN_WITH_64_BIT_REGISTERS 1
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#endif
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#include "prtypes.h" /* for PRUintXX */
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#include "secport.h" /* for PORT_XXX */
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#include "secerr.h"
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#include "blapi.h" /* for AES_ functions */
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#include "rijndael.h"
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struct AESKeyWrapContextStr {
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unsigned char iv[AES_KEY_WRAP_IV_BYTES];
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AESContext aescx;
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};
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/******************************************/
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/*
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** AES key wrap algorithm, RFC 3394
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*/
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AESKeyWrapContext *
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AESKeyWrap_AllocateContext(void)
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{
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AESKeyWrapContext * cx = PORT_New(AESKeyWrapContext);
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return cx;
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}
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SECStatus
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AESKeyWrap_InitContext(AESKeyWrapContext *cx,
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const unsigned char *key,
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unsigned int keylen,
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const unsigned char *iv,
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int x1,
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unsigned int encrypt,
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unsigned int x2)
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{
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SECStatus rv = SECFailure;
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if (!cx) {
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PORT_SetError(SEC_ERROR_INVALID_ARGS);
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return SECFailure;
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}
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if (iv) {
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memcpy(cx->iv, iv, sizeof cx->iv);
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} else {
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memset(cx->iv, 0xA6, sizeof cx->iv);
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}
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rv = AES_InitContext(&cx->aescx, key, keylen, NULL, NSS_AES, encrypt,
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AES_BLOCK_SIZE);
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return rv;
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}
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/*
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** Create a new AES context suitable for AES encryption/decryption.
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** "key" raw key data
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** "keylen" the number of bytes of key data (16, 24, or 32)
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*/
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extern AESKeyWrapContext *
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AESKeyWrap_CreateContext(const unsigned char *key, const unsigned char *iv,
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int encrypt, unsigned int keylen)
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{
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SECStatus rv;
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AESKeyWrapContext * cx = AESKeyWrap_AllocateContext();
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if (!cx)
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return NULL; /* error is already set */
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rv = AESKeyWrap_InitContext(cx, key, keylen, iv, 0, encrypt, 0);
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if (rv != SECSuccess) {
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PORT_Free(cx);
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cx = NULL; /* error should already be set */
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}
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return cx;
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}
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/*
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** Destroy a AES KeyWrap context.
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** "cx" the context
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** "freeit" if PR_TRUE then free the object as well as its sub-objects
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*/
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extern void
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AESKeyWrap_DestroyContext(AESKeyWrapContext *cx, PRBool freeit)
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{
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if (cx) {
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AES_DestroyContext(&cx->aescx, PR_FALSE);
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/* memset(cx, 0, sizeof *cx); */
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if (freeit)
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PORT_Free(cx);
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}
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}
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#if !BIG_ENDIAN_WITH_64_BIT_REGISTERS
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/* The AES Key Wrap algorithm has 64-bit values that are ALWAYS big-endian
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** (Most significant byte first) in memory. The only ALU operations done
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** on them are increment, decrement, and XOR. So, on little-endian CPUs,
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** and on CPUs that lack 64-bit registers, these big-endian 64-bit operations
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** are simulated in the following code. This is thought to be faster and
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** simpler than trying to convert the data to little-endian and back.
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*/
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/* A and T point to two 64-bit values stored most signficant byte first
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** (big endian). This function increments the 64-bit value T, and then
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** XORs it with A, changing A.
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*/
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static void
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increment_and_xor(unsigned char *A, unsigned char *T)
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{
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if (!++T[7])
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if (!++T[6])
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if (!++T[5])
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if (!++T[4])
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if (!++T[3])
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if (!++T[2])
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if (!++T[1])
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++T[0];
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A[0] ^= T[0];
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A[1] ^= T[1];
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A[2] ^= T[2];
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A[3] ^= T[3];
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A[4] ^= T[4];
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A[5] ^= T[5];
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A[6] ^= T[6];
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A[7] ^= T[7];
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}
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/* A and T point to two 64-bit values stored most signficant byte first
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** (big endian). This function XORs T with A, giving a new A, then
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** decrements the 64-bit value T.
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*/
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static void
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xor_and_decrement(unsigned char *A, unsigned char *T)
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{
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A[0] ^= T[0];
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A[1] ^= T[1];
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A[2] ^= T[2];
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A[3] ^= T[3];
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A[4] ^= T[4];
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A[5] ^= T[5];
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A[6] ^= T[6];
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A[7] ^= T[7];
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if (!T[7]--)
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if (!T[6]--)
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if (!T[5]--)
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if (!T[4]--)
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if (!T[3]--)
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if (!T[2]--)
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if (!T[1]--)
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T[0]--;
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}
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/* Given an unsigned long t (in host byte order), store this value as a
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** 64-bit big-endian value (MSB first) in *pt.
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*/
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static void
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set_t(unsigned char *pt, unsigned long t)
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{
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pt[7] = (unsigned char)t; t >>= 8;
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pt[6] = (unsigned char)t; t >>= 8;
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pt[5] = (unsigned char)t; t >>= 8;
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pt[4] = (unsigned char)t; t >>= 8;
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pt[3] = (unsigned char)t; t >>= 8;
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pt[2] = (unsigned char)t; t >>= 8;
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pt[1] = (unsigned char)t; t >>= 8;
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pt[0] = (unsigned char)t;
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}
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#endif
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/*
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** Perform AES key wrap.
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** "cx" the context
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** "output" the output buffer to store the encrypted data.
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** "outputLen" how much data is stored in "output". Set by the routine
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** after some data is stored in output.
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** "maxOutputLen" the maximum amount of data that can ever be
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** stored in "output"
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** "input" the input data
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** "inputLen" the amount of input data
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*/
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extern SECStatus
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AESKeyWrap_Encrypt(AESKeyWrapContext *cx, unsigned char *output,
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unsigned int *pOutputLen, unsigned int maxOutputLen,
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const unsigned char *input, unsigned int inputLen)
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{
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PRUint64 * R = NULL;
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unsigned int nBlocks;
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unsigned int i, j;
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unsigned int aesLen = AES_BLOCK_SIZE;
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unsigned int outLen = inputLen + AES_KEY_WRAP_BLOCK_SIZE;
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SECStatus s = SECFailure;
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/* These PRUint64s are ALWAYS big endian, regardless of CPU orientation. */
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PRUint64 t;
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PRUint64 B[2];
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#define A B[0]
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/* Check args */
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if (!inputLen || 0 != inputLen % AES_KEY_WRAP_BLOCK_SIZE) {
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PORT_SetError(SEC_ERROR_INPUT_LEN);
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return s;
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}
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#ifdef maybe
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if (!output && pOutputLen) { /* caller is asking for output size */
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*pOutputLen = outLen;
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return SECSuccess;
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}
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#endif
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if (maxOutputLen < outLen) {
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PORT_SetError(SEC_ERROR_OUTPUT_LEN);
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return s;
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}
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if (cx == NULL || output == NULL || input == NULL) {
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PORT_SetError(SEC_ERROR_INVALID_ARGS);
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return s;
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}
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nBlocks = inputLen / AES_KEY_WRAP_BLOCK_SIZE;
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R = PORT_NewArray(PRUint64, nBlocks + 1);
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if (!R)
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return s; /* error is already set. */
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/*
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** 1) Initialize variables.
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*/
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memcpy(&A, cx->iv, AES_KEY_WRAP_IV_BYTES);
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memcpy(&R[1], input, inputLen);
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#if BIG_ENDIAN_WITH_64_BIT_REGISTERS
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t = 0;
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#else
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memset(&t, 0, sizeof t);
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#endif
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/*
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** 2) Calculate intermediate values.
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*/
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for (j = 0; j < 6; ++j) {
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for (i = 1; i <= nBlocks; ++i) {
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B[1] = R[i];
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s = AES_Encrypt(&cx->aescx, (unsigned char *)B, &aesLen,
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sizeof B, (unsigned char *)B, sizeof B);
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if (s != SECSuccess)
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break;
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R[i] = B[1];
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/* here, increment t and XOR A with t (in big endian order); */
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#if BIG_ENDIAN_WITH_64_BIT_REGISTERS
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A ^= ++t;
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#else
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increment_and_xor((unsigned char *)&A, (unsigned char *)&t);
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#endif
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}
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}
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/*
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** 3) Output the results.
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*/
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if (s == SECSuccess) {
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R[0] = A;
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memcpy(output, &R[0], outLen);
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if (pOutputLen)
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*pOutputLen = outLen;
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} else if (pOutputLen) {
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*pOutputLen = 0;
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}
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PORT_ZFree(R, outLen);
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return s;
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}
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#undef A
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/*
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** Perform AES key unwrap.
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** "cx" the context
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** "output" the output buffer to store the decrypted data.
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** "outputLen" how much data is stored in "output". Set by the routine
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** after some data is stored in output.
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** "maxOutputLen" the maximum amount of data that can ever be
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** stored in "output"
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** "input" the input data
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** "inputLen" the amount of input data
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*/
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extern SECStatus
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AESKeyWrap_Decrypt(AESKeyWrapContext *cx, unsigned char *output,
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unsigned int *pOutputLen, unsigned int maxOutputLen,
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const unsigned char *input, unsigned int inputLen)
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{
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PRUint64 * R = NULL;
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unsigned int nBlocks;
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unsigned int i, j;
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unsigned int aesLen = AES_BLOCK_SIZE;
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unsigned int outLen;
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SECStatus s = SECFailure;
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/* These PRUint64s are ALWAYS big endian, regardless of CPU orientation. */
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PRUint64 t;
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PRUint64 B[2];
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#define A B[0]
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/* Check args */
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if (inputLen < 3 * AES_KEY_WRAP_BLOCK_SIZE ||
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0 != inputLen % AES_KEY_WRAP_BLOCK_SIZE) {
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PORT_SetError(SEC_ERROR_INPUT_LEN);
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return s;
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}
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outLen = inputLen - AES_KEY_WRAP_BLOCK_SIZE;
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#ifdef maybe
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if (!output && pOutputLen) { /* caller is asking for output size */
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*pOutputLen = outLen;
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return SECSuccess;
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}
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#endif
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if (maxOutputLen < outLen) {
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PORT_SetError(SEC_ERROR_OUTPUT_LEN);
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return s;
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}
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if (cx == NULL || output == NULL || input == NULL) {
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PORT_SetError(SEC_ERROR_INVALID_ARGS);
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return s;
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}
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nBlocks = inputLen / AES_KEY_WRAP_BLOCK_SIZE;
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R = PORT_NewArray(PRUint64, nBlocks);
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if (!R)
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return s; /* error is already set. */
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nBlocks--;
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/*
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** 1) Initialize variables.
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*/
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memcpy(&R[0], input, inputLen);
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A = R[0];
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#if BIG_ENDIAN_WITH_64_BIT_REGISTERS
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t = 6UL * nBlocks;
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#else
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set_t((unsigned char *)&t, 6UL * nBlocks);
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#endif
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/*
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** 2) Calculate intermediate values.
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*/
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for (j = 0; j < 6; ++j) {
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for (i = nBlocks; i; --i) {
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/* here, XOR A with t (in big endian order) and decrement t; */
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#if BIG_ENDIAN_WITH_64_BIT_REGISTERS
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A ^= t--;
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#else
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xor_and_decrement((unsigned char *)&A, (unsigned char *)&t);
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#endif
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B[1] = R[i];
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s = AES_Decrypt(&cx->aescx, (unsigned char *)B, &aesLen,
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sizeof B, (unsigned char *)B, sizeof B);
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if (s != SECSuccess)
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break;
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R[i] = B[1];
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}
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}
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/*
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** 3) Output the results.
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*/
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if (s == SECSuccess) {
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int bad = memcmp(&A, cx->iv, AES_KEY_WRAP_IV_BYTES);
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if (!bad) {
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memcpy(output, &R[1], outLen);
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if (pOutputLen)
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*pOutputLen = outLen;
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} else {
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s = SECFailure;
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PORT_SetError(SEC_ERROR_BAD_DATA);
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if (pOutputLen)
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*pOutputLen = 0;
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}
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} else if (pOutputLen) {
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*pOutputLen = 0;
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}
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PORT_ZFree(R, inputLen);
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return s;
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}
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#undef A
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