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10fa254539
Contrary to initial testing we cannot rely on these kernels to invalidate the per-cpu FPU state and restore the FPU registers. Nor can we guarantee that the kernel won't modify the FPU state which we saved in the task struck. Therefore, the kfpu_begin() and kfpu_end() functions have been updated to save and restore the FPU state using our own dedicated per-cpu FPU state variables. This has the additional advantage of allowing us to use the FPU again in user threads. So we remove the code which was added to use task queues to ensure some functions ran in kernel threads. Reviewed-by: Fabian Grünbichler <f.gruenbichler@proxmox.com> Reviewed-by: Tony Hutter <hutter2@llnl.gov> Signed-off-by: Brian Behlendorf <behlendorf1@llnl.gov> Issue #9346 Closes #9403
444 lines
11 KiB
C
444 lines
11 KiB
C
/*
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* CDDL HEADER START
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*
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* The contents of this file are subject to the terms of the
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* Common Development and Distribution License (the "License").
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* You may not use this file except in compliance with the License.
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*
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* You can obtain a copy of the license at usr/src/OPENSOLARIS.LICENSE
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* or http://www.opensolaris.org/os/licensing.
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* See the License for the specific language governing permissions
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* and limitations under the License.
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*
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* When distributing Covered Code, include this CDDL HEADER in each
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* file and include the License file at usr/src/OPENSOLARIS.LICENSE.
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* If applicable, add the following below this CDDL HEADER, with the
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* fields enclosed by brackets "[]" replaced with your own identifying
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* information: Portions Copyright [yyyy] [name of copyright owner]
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*
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* CDDL HEADER END
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*/
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/*
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* Copyright (c) 2003, 2010, Oracle and/or its affiliates. All rights reserved.
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*/
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#include <sys/zfs_context.h>
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#include <sys/crypto/icp.h>
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#include <sys/crypto/spi.h>
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#include <sys/simd.h>
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#include <modes/modes.h>
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#include <aes/aes_impl.h>
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/*
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* Initialize AES encryption and decryption key schedules.
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*
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* Parameters:
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* cipherKey User key
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* keyBits AES key size (128, 192, or 256 bits)
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* keysched AES key schedule to be initialized, of type aes_key_t.
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* Allocated by aes_alloc_keysched().
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*/
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void
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aes_init_keysched(const uint8_t *cipherKey, uint_t keyBits, void *keysched)
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{
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const aes_impl_ops_t *ops = aes_impl_get_ops();
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aes_key_t *newbie = keysched;
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uint_t keysize, i, j;
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union {
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uint64_t ka64[4];
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uint32_t ka32[8];
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} keyarr;
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switch (keyBits) {
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case 128:
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newbie->nr = 10;
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break;
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case 192:
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newbie->nr = 12;
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break;
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case 256:
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newbie->nr = 14;
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break;
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default:
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/* should never get here */
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return;
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}
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keysize = CRYPTO_BITS2BYTES(keyBits);
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/*
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* Generic C implementation requires byteswap for little endian
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* machines, various accelerated implementations for various
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* architectures may not.
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*/
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if (!ops->needs_byteswap) {
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/* no byteswap needed */
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if (IS_P2ALIGNED(cipherKey, sizeof (uint64_t))) {
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for (i = 0, j = 0; j < keysize; i++, j += 8) {
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/* LINTED: pointer alignment */
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keyarr.ka64[i] = *((uint64_t *)&cipherKey[j]);
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}
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} else {
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bcopy(cipherKey, keyarr.ka32, keysize);
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}
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} else {
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/* byte swap */
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for (i = 0, j = 0; j < keysize; i++, j += 4) {
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keyarr.ka32[i] =
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htonl(*(uint32_t *)(void *)&cipherKey[j]);
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}
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}
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ops->generate(newbie, keyarr.ka32, keyBits);
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newbie->ops = ops;
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/*
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* Note: if there are systems that need the AES_64BIT_KS type in the
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* future, move setting key schedule type to individual implementations
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*/
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newbie->type = AES_32BIT_KS;
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}
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/*
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* Encrypt one block using AES.
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* Align if needed and (for x86 32-bit only) byte-swap.
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*
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* Parameters:
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* ks Key schedule, of type aes_key_t
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* pt Input block (plain text)
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* ct Output block (crypto text). Can overlap with pt
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*/
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int
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aes_encrypt_block(const void *ks, const uint8_t *pt, uint8_t *ct)
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{
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aes_key_t *ksch = (aes_key_t *)ks;
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const aes_impl_ops_t *ops = ksch->ops;
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if (IS_P2ALIGNED2(pt, ct, sizeof (uint32_t)) && !ops->needs_byteswap) {
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/* LINTED: pointer alignment */
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ops->encrypt(&ksch->encr_ks.ks32[0], ksch->nr,
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/* LINTED: pointer alignment */
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(uint32_t *)pt, (uint32_t *)ct);
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} else {
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uint32_t buffer[AES_BLOCK_LEN / sizeof (uint32_t)];
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/* Copy input block into buffer */
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if (ops->needs_byteswap) {
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buffer[0] = htonl(*(uint32_t *)(void *)&pt[0]);
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buffer[1] = htonl(*(uint32_t *)(void *)&pt[4]);
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buffer[2] = htonl(*(uint32_t *)(void *)&pt[8]);
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buffer[3] = htonl(*(uint32_t *)(void *)&pt[12]);
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} else
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bcopy(pt, &buffer, AES_BLOCK_LEN);
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ops->encrypt(&ksch->encr_ks.ks32[0], ksch->nr, buffer, buffer);
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/* Copy result from buffer to output block */
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if (ops->needs_byteswap) {
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*(uint32_t *)(void *)&ct[0] = htonl(buffer[0]);
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*(uint32_t *)(void *)&ct[4] = htonl(buffer[1]);
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*(uint32_t *)(void *)&ct[8] = htonl(buffer[2]);
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*(uint32_t *)(void *)&ct[12] = htonl(buffer[3]);
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} else
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bcopy(&buffer, ct, AES_BLOCK_LEN);
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}
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return (CRYPTO_SUCCESS);
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}
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/*
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* Decrypt one block using AES.
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* Align and byte-swap if needed.
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*
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* Parameters:
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* ks Key schedule, of type aes_key_t
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* ct Input block (crypto text)
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* pt Output block (plain text). Can overlap with pt
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*/
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int
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aes_decrypt_block(const void *ks, const uint8_t *ct, uint8_t *pt)
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{
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aes_key_t *ksch = (aes_key_t *)ks;
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const aes_impl_ops_t *ops = ksch->ops;
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if (IS_P2ALIGNED2(ct, pt, sizeof (uint32_t)) && !ops->needs_byteswap) {
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/* LINTED: pointer alignment */
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ops->decrypt(&ksch->decr_ks.ks32[0], ksch->nr,
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/* LINTED: pointer alignment */
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(uint32_t *)ct, (uint32_t *)pt);
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} else {
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uint32_t buffer[AES_BLOCK_LEN / sizeof (uint32_t)];
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/* Copy input block into buffer */
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if (ops->needs_byteswap) {
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buffer[0] = htonl(*(uint32_t *)(void *)&ct[0]);
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buffer[1] = htonl(*(uint32_t *)(void *)&ct[4]);
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buffer[2] = htonl(*(uint32_t *)(void *)&ct[8]);
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buffer[3] = htonl(*(uint32_t *)(void *)&ct[12]);
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} else
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bcopy(ct, &buffer, AES_BLOCK_LEN);
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ops->decrypt(&ksch->decr_ks.ks32[0], ksch->nr, buffer, buffer);
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/* Copy result from buffer to output block */
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if (ops->needs_byteswap) {
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*(uint32_t *)(void *)&pt[0] = htonl(buffer[0]);
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*(uint32_t *)(void *)&pt[4] = htonl(buffer[1]);
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*(uint32_t *)(void *)&pt[8] = htonl(buffer[2]);
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*(uint32_t *)(void *)&pt[12] = htonl(buffer[3]);
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} else
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bcopy(&buffer, pt, AES_BLOCK_LEN);
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}
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return (CRYPTO_SUCCESS);
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}
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/*
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* Allocate key schedule for AES.
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*
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* Return the pointer and set size to the number of bytes allocated.
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* Memory allocated must be freed by the caller when done.
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*
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* Parameters:
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* size Size of key schedule allocated, in bytes
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* kmflag Flag passed to kmem_alloc(9F); ignored in userland.
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*/
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/* ARGSUSED */
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void *
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aes_alloc_keysched(size_t *size, int kmflag)
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{
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aes_key_t *keysched;
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keysched = (aes_key_t *)kmem_alloc(sizeof (aes_key_t), kmflag);
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if (keysched != NULL) {
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*size = sizeof (aes_key_t);
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return (keysched);
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}
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return (NULL);
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}
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/* AES implementation that contains the fastest methods */
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static aes_impl_ops_t aes_fastest_impl = {
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.name = "fastest"
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};
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/* All compiled in implementations */
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const aes_impl_ops_t *aes_all_impl[] = {
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&aes_generic_impl,
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#if defined(__x86_64)
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&aes_x86_64_impl,
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#endif
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#if defined(__x86_64) && defined(HAVE_AES)
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&aes_aesni_impl,
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#endif
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};
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/* Indicate that benchmark has been completed */
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static boolean_t aes_impl_initialized = B_FALSE;
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/* Select aes implementation */
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#define IMPL_FASTEST (UINT32_MAX)
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#define IMPL_CYCLE (UINT32_MAX-1)
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#define AES_IMPL_READ(i) (*(volatile uint32_t *) &(i))
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static uint32_t icp_aes_impl = IMPL_FASTEST;
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static uint32_t user_sel_impl = IMPL_FASTEST;
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/* Hold all supported implementations */
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static size_t aes_supp_impl_cnt = 0;
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static aes_impl_ops_t *aes_supp_impl[ARRAY_SIZE(aes_all_impl)];
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/*
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* Returns the AES operations for encrypt/decrypt/key setup. When a
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* SIMD implementation is not allowed in the current context, then
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* fallback to the fastest generic implementation.
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*/
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const aes_impl_ops_t *
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aes_impl_get_ops(void)
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{
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if (!kfpu_allowed())
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return (&aes_generic_impl);
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const aes_impl_ops_t *ops = NULL;
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const uint32_t impl = AES_IMPL_READ(icp_aes_impl);
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switch (impl) {
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case IMPL_FASTEST:
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ASSERT(aes_impl_initialized);
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ops = &aes_fastest_impl;
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break;
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case IMPL_CYCLE:
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/* Cycle through supported implementations */
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ASSERT(aes_impl_initialized);
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ASSERT3U(aes_supp_impl_cnt, >, 0);
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static size_t cycle_impl_idx = 0;
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size_t idx = (++cycle_impl_idx) % aes_supp_impl_cnt;
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ops = aes_supp_impl[idx];
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break;
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default:
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ASSERT3U(impl, <, aes_supp_impl_cnt);
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ASSERT3U(aes_supp_impl_cnt, >, 0);
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if (impl < ARRAY_SIZE(aes_all_impl))
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ops = aes_supp_impl[impl];
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break;
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}
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ASSERT3P(ops, !=, NULL);
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return (ops);
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}
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/*
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* Initialize all supported implementations.
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*/
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void
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aes_impl_init(void)
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{
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aes_impl_ops_t *curr_impl;
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int i, c;
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/* Move supported implementations into aes_supp_impls */
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for (i = 0, c = 0; i < ARRAY_SIZE(aes_all_impl); i++) {
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curr_impl = (aes_impl_ops_t *)aes_all_impl[i];
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if (curr_impl->is_supported())
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aes_supp_impl[c++] = (aes_impl_ops_t *)curr_impl;
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}
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aes_supp_impl_cnt = c;
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/*
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* Set the fastest implementation given the assumption that the
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* hardware accelerated version is the fastest.
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*/
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#if defined(__x86_64)
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#if defined(HAVE_AES)
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if (aes_aesni_impl.is_supported()) {
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memcpy(&aes_fastest_impl, &aes_aesni_impl,
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sizeof (aes_fastest_impl));
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} else
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#endif
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{
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memcpy(&aes_fastest_impl, &aes_x86_64_impl,
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sizeof (aes_fastest_impl));
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}
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#else
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memcpy(&aes_fastest_impl, &aes_generic_impl,
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sizeof (aes_fastest_impl));
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#endif
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strcpy(aes_fastest_impl.name, "fastest");
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/* Finish initialization */
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atomic_swap_32(&icp_aes_impl, user_sel_impl);
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aes_impl_initialized = B_TRUE;
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}
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static const struct {
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char *name;
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uint32_t sel;
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} aes_impl_opts[] = {
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{ "cycle", IMPL_CYCLE },
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{ "fastest", IMPL_FASTEST },
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};
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/*
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* Function sets desired aes implementation.
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*
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* If we are called before init(), user preference will be saved in
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* user_sel_impl, and applied in later init() call. This occurs when module
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* parameter is specified on module load. Otherwise, directly update
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* icp_aes_impl.
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*
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* @val Name of aes implementation to use
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* @param Unused.
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*/
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int
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aes_impl_set(const char *val)
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{
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int err = -EINVAL;
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char req_name[AES_IMPL_NAME_MAX];
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uint32_t impl = AES_IMPL_READ(user_sel_impl);
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size_t i;
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/* sanitize input */
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i = strnlen(val, AES_IMPL_NAME_MAX);
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if (i == 0 || i >= AES_IMPL_NAME_MAX)
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return (err);
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strlcpy(req_name, val, AES_IMPL_NAME_MAX);
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while (i > 0 && isspace(req_name[i-1]))
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i--;
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req_name[i] = '\0';
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/* Check mandatory options */
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for (i = 0; i < ARRAY_SIZE(aes_impl_opts); i++) {
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if (strcmp(req_name, aes_impl_opts[i].name) == 0) {
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impl = aes_impl_opts[i].sel;
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err = 0;
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break;
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}
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}
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/* check all supported impl if init() was already called */
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if (err != 0 && aes_impl_initialized) {
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/* check all supported implementations */
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for (i = 0; i < aes_supp_impl_cnt; i++) {
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if (strcmp(req_name, aes_supp_impl[i]->name) == 0) {
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impl = i;
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err = 0;
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break;
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}
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}
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}
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if (err == 0) {
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if (aes_impl_initialized)
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atomic_swap_32(&icp_aes_impl, impl);
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else
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atomic_swap_32(&user_sel_impl, impl);
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}
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return (err);
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}
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#if defined(_KERNEL)
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static int
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icp_aes_impl_set(const char *val, zfs_kernel_param_t *kp)
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{
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return (aes_impl_set(val));
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}
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static int
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icp_aes_impl_get(char *buffer, zfs_kernel_param_t *kp)
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{
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int i, cnt = 0;
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char *fmt;
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const uint32_t impl = AES_IMPL_READ(icp_aes_impl);
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ASSERT(aes_impl_initialized);
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/* list mandatory options */
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for (i = 0; i < ARRAY_SIZE(aes_impl_opts); i++) {
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fmt = (impl == aes_impl_opts[i].sel) ? "[%s] " : "%s ";
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cnt += sprintf(buffer + cnt, fmt, aes_impl_opts[i].name);
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}
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/* list all supported implementations */
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for (i = 0; i < aes_supp_impl_cnt; i++) {
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fmt = (i == impl) ? "[%s] " : "%s ";
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cnt += sprintf(buffer + cnt, fmt, aes_supp_impl[i]->name);
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}
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return (cnt);
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}
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module_param_call(icp_aes_impl, icp_aes_impl_set, icp_aes_impl_get,
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NULL, 0644);
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MODULE_PARM_DESC(icp_aes_impl, "Select aes implementation.");
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#endif
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