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/*
* aeskeywrap.c - implement AES Key Wrap algorithm from RFC 3394
*
* This Source Code Form is subject to the terms of the Mozilla Public
* License, v. 2.0. If a copy of the MPL was not distributed with this
* file, You can obtain one at http://mozilla.org/MPL/2.0/. */
#ifdef FREEBL_NO_DEPEND
#include "stubs.h"
#endif
#include "prcpucfg.h"
#if defined(IS_LITTLE_ENDIAN) || defined(SHA_NO_LONG_LONG)
#define BIG_ENDIAN_WITH_64_BIT_REGISTERS 0
#else
#define BIG_ENDIAN_WITH_64_BIT_REGISTERS 1
#endif
#include "prtypes.h" /* for PRUintXX */
#include "secport.h" /* for PORT_XXX */
#include "secerr.h"
#include "blapi.h" /* for AES_ functions */
#include "rijndael.h"
struct AESKeyWrapContextStr {
AESContext aescx;
unsigned char iv[AES_KEY_WRAP_IV_BYTES];
void *mem; /* Pointer to beginning of allocated memory. */
};
/******************************************/
/*
** AES key wrap algorithm, RFC 3394
*/
AESKeyWrapContext *
AESKeyWrap_AllocateContext(void)
{
/* aligned_alloc is C11 so we have to do it the old way. */
AESKeyWrapContext *ctx = PORT_ZAlloc(sizeof(AESKeyWrapContext) + 15);
if (ctx == NULL) {
PORT_SetError(SEC_ERROR_NO_MEMORY);
return NULL;
}
ctx->mem = ctx;
return (AESKeyWrapContext *)(((uintptr_t)ctx + 15) & ~(uintptr_t)0x0F);
}
SECStatus
AESKeyWrap_InitContext(AESKeyWrapContext *cx,
const unsigned char *key,
unsigned int keylen,
const unsigned char *iv,
int x1,
unsigned int encrypt,
unsigned int x2)
{
SECStatus rv = SECFailure;
if (!cx) {
PORT_SetError(SEC_ERROR_INVALID_ARGS);
return SECFailure;
}
if (iv) {
memcpy(cx->iv, iv, sizeof cx->iv);
} else {
memset(cx->iv, 0xA6, sizeof cx->iv);
}
rv = AES_InitContext(&cx->aescx, key, keylen, NULL, NSS_AES, encrypt,
AES_BLOCK_SIZE);
return rv;
}
/*
** Create a new AES context suitable for AES encryption/decryption.
** "key" raw key data
** "keylen" the number of bytes of key data (16, 24, or 32)
*/
extern AESKeyWrapContext *
AESKeyWrap_CreateContext(const unsigned char *key, const unsigned char *iv,
int encrypt, unsigned int keylen)
{
SECStatus rv;
AESKeyWrapContext *cx = AESKeyWrap_AllocateContext();
if (!cx)
return NULL; /* error is already set */
rv = AESKeyWrap_InitContext(cx, key, keylen, iv, 0, encrypt, 0);
if (rv != SECSuccess) {
PORT_Free(cx->mem);
cx = NULL; /* error should already be set */
}
return cx;
}
/*
** Destroy a AES KeyWrap context.
** "cx" the context
** "freeit" if PR_TRUE then free the object as well as its sub-objects
*/
extern void
AESKeyWrap_DestroyContext(AESKeyWrapContext *cx, PRBool freeit)
{
if (cx) {
AES_DestroyContext(&cx->aescx, PR_FALSE);
/* memset(cx, 0, sizeof *cx); */
if (freeit) {
PORT_Free(cx->mem);
}
}
}
#if !BIG_ENDIAN_WITH_64_BIT_REGISTERS
/* The AES Key Wrap algorithm has 64-bit values that are ALWAYS big-endian
** (Most significant byte first) in memory. The only ALU operations done
** on them are increment, decrement, and XOR. So, on little-endian CPUs,
** and on CPUs that lack 64-bit registers, these big-endian 64-bit operations
** are simulated in the following code. This is thought to be faster and
** simpler than trying to convert the data to little-endian and back.
*/
/* A and T point to two 64-bit values stored most signficant byte first
** (big endian). This function increments the 64-bit value T, and then
** XORs it with A, changing A.
*/
static void
increment_and_xor(unsigned char *A, unsigned char *T)
{
if (!++T[7])
if (!++T[6])
if (!++T[5])
if (!++T[4])
if (!++T[3])
if (!++T[2])
if (!++T[1])
++T[0];
A[0] ^= T[0];
A[1] ^= T[1];
A[2] ^= T[2];
A[3] ^= T[3];
A[4] ^= T[4];
A[5] ^= T[5];
A[6] ^= T[6];
A[7] ^= T[7];
}
/* A and T point to two 64-bit values stored most signficant byte first
** (big endian). This function XORs T with A, giving a new A, then
** decrements the 64-bit value T.
*/
static void
xor_and_decrement(PRUint64 *A, PRUint64 *T)
{
unsigned char *TP = (unsigned char *)T;
const PRUint64 mask = 0xFF;
*A = ((*A & mask << 56) ^ (*T & mask << 56)) |
((*A & mask << 48) ^ (*T & mask << 48)) |
((*A & mask << 40) ^ (*T & mask << 40)) |
((*A & mask << 32) ^ (*T & mask << 32)) |
((*A & mask << 24) ^ (*T & mask << 23)) |
((*A & mask << 16) ^ (*T & mask << 16)) |
((*A & mask << 8) ^ (*T & mask << 8)) |
((*A & mask) ^ (*T & mask));
if (!TP[7]--)
if (!TP[6]--)
if (!TP[5]--)
if (!TP[4]--)
if (!TP[3]--)
if (!TP[2]--)
if (!TP[1]--)
TP[0]--;
}
/* Given an unsigned long t (in host byte order), store this value as a
** 64-bit big-endian value (MSB first) in *pt.
*/
static void
set_t(unsigned char *pt, unsigned long t)
{
pt[7] = (unsigned char)t;
t >>= 8;
pt[6] = (unsigned char)t;
t >>= 8;
pt[5] = (unsigned char)t;
t >>= 8;
pt[4] = (unsigned char)t;
t >>= 8;
pt[3] = (unsigned char)t;
t >>= 8;
pt[2] = (unsigned char)t;
t >>= 8;
pt[1] = (unsigned char)t;
t >>= 8;
pt[0] = (unsigned char)t;
}
#endif
/*
** Perform AES key wrap.
** "cx" the context
** "output" the output buffer to store the encrypted data.
** "outputLen" how much data is stored in "output". Set by the routine
** after some data is stored in output.
** "maxOutputLen" the maximum amount of data that can ever be
** stored in "output"
** "input" the input data
** "inputLen" the amount of input data
*/
extern SECStatus
AESKeyWrap_Encrypt(AESKeyWrapContext *cx, unsigned char *output,
unsigned int *pOutputLen, unsigned int maxOutputLen,
const unsigned char *input, unsigned int inputLen)
{
PRUint64 *R = NULL;
unsigned int nBlocks;
unsigned int i, j;
unsigned int aesLen = AES_BLOCK_SIZE;
unsigned int outLen = inputLen + AES_KEY_WRAP_BLOCK_SIZE;
SECStatus s = SECFailure;
/* These PRUint64s are ALWAYS big endian, regardless of CPU orientation. */
PRUint64 t;
PRUint64 B[2];
#define A B[0]
/* Check args */
if (inputLen < 2 * AES_KEY_WRAP_BLOCK_SIZE ||
0 != inputLen % AES_KEY_WRAP_BLOCK_SIZE) {
PORT_SetError(SEC_ERROR_INPUT_LEN);
return s;
}
#ifdef maybe
if (!output && pOutputLen) { /* caller is asking for output size */
*pOutputLen = outLen;
return SECSuccess;
}
#endif
if (maxOutputLen < outLen) {
PORT_SetError(SEC_ERROR_OUTPUT_LEN);
return s;
}
if (cx == NULL || output == NULL || input == NULL) {
PORT_SetError(SEC_ERROR_INVALID_ARGS);
return s;
}
nBlocks = inputLen / AES_KEY_WRAP_BLOCK_SIZE;
R = PORT_NewArray(PRUint64, nBlocks + 1);
if (!R)
return s; /* error is already set. */
/*
** 1) Initialize variables.
*/
memcpy(&A, cx->iv, AES_KEY_WRAP_IV_BYTES);
memcpy(&R[1], input, inputLen);
#if BIG_ENDIAN_WITH_64_BIT_REGISTERS
t = 0;
#else
memset(&t, 0, sizeof t);
#endif
/*
** 2) Calculate intermediate values.
*/
for (j = 0; j < 6; ++j) {
for (i = 1; i <= nBlocks; ++i) {
B[1] = R[i];
s = AES_Encrypt(&cx->aescx, (unsigned char *)B, &aesLen,
sizeof B, (unsigned char *)B, sizeof B);
if (s != SECSuccess)
break;
R[i] = B[1];
/* here, increment t and XOR A with t (in big endian order); */
#if BIG_ENDIAN_WITH_64_BIT_REGISTERS
A ^= ++t;
#else
increment_and_xor((unsigned char *)&A, (unsigned char *)&t);
#endif
}
}
/*
** 3) Output the results.
*/
if (s == SECSuccess) {
R[0] = A;
memcpy(output, &R[0], outLen);
if (pOutputLen)
*pOutputLen = outLen;
} else if (pOutputLen) {
*pOutputLen = 0;
}
PORT_ZFree(R, outLen);
return s;
}
#undef A
/*
** Perform AES key unwrap.
** "cx" the context
** "output" the output buffer to store the decrypted data.
** "outputLen" how much data is stored in "output". Set by the routine
** after some data is stored in output.
** "maxOutputLen" the maximum amount of data that can ever be
** stored in "output"
** "input" the input data
** "inputLen" the amount of input data
*/
extern SECStatus
AESKeyWrap_Decrypt(AESKeyWrapContext *cx, unsigned char *output,
unsigned int *pOutputLen, unsigned int maxOutputLen,
const unsigned char *input, unsigned int inputLen)
{
PRUint64 *R = NULL;
unsigned int nBlocks;
unsigned int i, j;
unsigned int aesLen = AES_BLOCK_SIZE;
unsigned int outLen;
SECStatus s = SECFailure;
/* These PRUint64s are ALWAYS big endian, regardless of CPU orientation. */
PRUint64 t;
PRUint64 B[2];
/* Check args */
if (inputLen < 3 * AES_KEY_WRAP_BLOCK_SIZE ||
0 != inputLen % AES_KEY_WRAP_BLOCK_SIZE) {
PORT_SetError(SEC_ERROR_INPUT_LEN);
return s;
}
outLen = inputLen - AES_KEY_WRAP_BLOCK_SIZE;
#ifdef maybe
if (!output && pOutputLen) { /* caller is asking for output size */
*pOutputLen = outLen;
return SECSuccess;
}
#endif
if (maxOutputLen < outLen) {
PORT_SetError(SEC_ERROR_OUTPUT_LEN);
return s;
}
if (cx == NULL || output == NULL || input == NULL) {
PORT_SetError(SEC_ERROR_INVALID_ARGS);
return s;
}
nBlocks = inputLen / AES_KEY_WRAP_BLOCK_SIZE;
R = PORT_NewArray(PRUint64, nBlocks);
if (!R)
return s; /* error is already set. */
nBlocks--;
/*
** 1) Initialize variables.
*/
memcpy(&R[0], input, inputLen);
B[0] = R[0];
#if BIG_ENDIAN_WITH_64_BIT_REGISTERS
t = 6UL * nBlocks;
#else
set_t((unsigned char *)&t, 6UL * nBlocks);
#endif
/*
** 2) Calculate intermediate values.
*/
for (j = 0; j < 6; ++j) {
for (i = nBlocks; i; --i) {
/* here, XOR A with t (in big endian order) and decrement t; */
#if BIG_ENDIAN_WITH_64_BIT_REGISTERS
B[0] ^= t--;
#else
xor_and_decrement(&B[0], &t);
#endif
B[1] = R[i];
s = AES_Decrypt(&cx->aescx, (unsigned char *)B, &aesLen,
sizeof B, (unsigned char *)B, sizeof B);
if (s != SECSuccess)
break;
R[i] = B[1];
}
}
/*
** 3) Output the results.
*/
if (s == SECSuccess) {
int bad = memcmp(&B[0], cx->iv, AES_KEY_WRAP_IV_BYTES);
if (!bad) {
memcpy(output, &R[1], outLen);
if (pOutputLen)
*pOutputLen = outLen;
} else {
s = SECFailure;
PORT_SetError(SEC_ERROR_BAD_DATA);
if (pOutputLen)
*pOutputLen = 0;
}
} else if (pOutputLen) {
*pOutputLen = 0;
}
PORT_ZFree(R, inputLen);
return s;
}
#undef A
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