mirror of
https://github.com/AuxXxilium/linux_dsm_epyc7002.git
synced 2024-12-27 20:05:14 +07:00
58a6535f1a
Fix few sparse warnings of type: - sparse: incorrect type in argument - sparse: incorrect type in initializer Signed-off-by: Stanimir Varbanov <svarbanov@mm-sol.com> Signed-off-by: Herbert Xu <herbert@gondor.apana.org.au>
439 lines
12 KiB
C
439 lines
12 KiB
C
/*
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* Copyright (c) 2012-2014, The Linux Foundation. All rights reserved.
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*
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* This program is free software; you can redistribute it and/or modify
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* it under the terms of the GNU General Public License version 2 and
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* only version 2 as published by the Free Software Foundation.
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*
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* This program is distributed in the hope that it will be useful,
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* but WITHOUT ANY WARRANTY; without even the implied warranty of
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* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
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* GNU General Public License for more details.
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*/
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#include <linux/err.h>
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#include <linux/interrupt.h>
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#include <linux/types.h>
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#include <crypto/scatterwalk.h>
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#include <crypto/sha.h>
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#include "cipher.h"
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#include "common.h"
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#include "core.h"
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#include "regs-v5.h"
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#include "sha.h"
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#define QCE_SECTOR_SIZE 512
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static inline u32 qce_read(struct qce_device *qce, u32 offset)
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{
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return readl(qce->base + offset);
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}
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static inline void qce_write(struct qce_device *qce, u32 offset, u32 val)
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{
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writel(val, qce->base + offset);
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}
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static inline void qce_write_array(struct qce_device *qce, u32 offset,
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const u32 *val, unsigned int len)
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{
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int i;
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for (i = 0; i < len; i++)
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qce_write(qce, offset + i * sizeof(u32), val[i]);
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}
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static inline void
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qce_clear_array(struct qce_device *qce, u32 offset, unsigned int len)
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{
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int i;
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for (i = 0; i < len; i++)
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qce_write(qce, offset + i * sizeof(u32), 0);
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}
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static u32 qce_encr_cfg(unsigned long flags, u32 aes_key_size)
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{
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u32 cfg = 0;
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if (IS_AES(flags)) {
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if (aes_key_size == AES_KEYSIZE_128)
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cfg |= ENCR_KEY_SZ_AES128 << ENCR_KEY_SZ_SHIFT;
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else if (aes_key_size == AES_KEYSIZE_256)
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cfg |= ENCR_KEY_SZ_AES256 << ENCR_KEY_SZ_SHIFT;
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}
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if (IS_AES(flags))
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cfg |= ENCR_ALG_AES << ENCR_ALG_SHIFT;
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else if (IS_DES(flags) || IS_3DES(flags))
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cfg |= ENCR_ALG_DES << ENCR_ALG_SHIFT;
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if (IS_DES(flags))
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cfg |= ENCR_KEY_SZ_DES << ENCR_KEY_SZ_SHIFT;
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if (IS_3DES(flags))
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cfg |= ENCR_KEY_SZ_3DES << ENCR_KEY_SZ_SHIFT;
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switch (flags & QCE_MODE_MASK) {
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case QCE_MODE_ECB:
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cfg |= ENCR_MODE_ECB << ENCR_MODE_SHIFT;
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break;
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case QCE_MODE_CBC:
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cfg |= ENCR_MODE_CBC << ENCR_MODE_SHIFT;
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break;
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case QCE_MODE_CTR:
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cfg |= ENCR_MODE_CTR << ENCR_MODE_SHIFT;
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break;
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case QCE_MODE_XTS:
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cfg |= ENCR_MODE_XTS << ENCR_MODE_SHIFT;
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break;
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case QCE_MODE_CCM:
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cfg |= ENCR_MODE_CCM << ENCR_MODE_SHIFT;
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cfg |= LAST_CCM_XFR << LAST_CCM_SHIFT;
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break;
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default:
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return ~0;
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}
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return cfg;
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}
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static u32 qce_auth_cfg(unsigned long flags, u32 key_size)
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{
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u32 cfg = 0;
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if (IS_AES(flags) && (IS_CCM(flags) || IS_CMAC(flags)))
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cfg |= AUTH_ALG_AES << AUTH_ALG_SHIFT;
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else
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cfg |= AUTH_ALG_SHA << AUTH_ALG_SHIFT;
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if (IS_CCM(flags) || IS_CMAC(flags)) {
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if (key_size == AES_KEYSIZE_128)
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cfg |= AUTH_KEY_SZ_AES128 << AUTH_KEY_SIZE_SHIFT;
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else if (key_size == AES_KEYSIZE_256)
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cfg |= AUTH_KEY_SZ_AES256 << AUTH_KEY_SIZE_SHIFT;
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}
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if (IS_SHA1(flags) || IS_SHA1_HMAC(flags))
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cfg |= AUTH_SIZE_SHA1 << AUTH_SIZE_SHIFT;
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else if (IS_SHA256(flags) || IS_SHA256_HMAC(flags))
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cfg |= AUTH_SIZE_SHA256 << AUTH_SIZE_SHIFT;
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else if (IS_CMAC(flags))
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cfg |= AUTH_SIZE_ENUM_16_BYTES << AUTH_SIZE_SHIFT;
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if (IS_SHA1(flags) || IS_SHA256(flags))
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cfg |= AUTH_MODE_HASH << AUTH_MODE_SHIFT;
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else if (IS_SHA1_HMAC(flags) || IS_SHA256_HMAC(flags) ||
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IS_CBC(flags) || IS_CTR(flags))
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cfg |= AUTH_MODE_HMAC << AUTH_MODE_SHIFT;
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else if (IS_AES(flags) && IS_CCM(flags))
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cfg |= AUTH_MODE_CCM << AUTH_MODE_SHIFT;
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else if (IS_AES(flags) && IS_CMAC(flags))
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cfg |= AUTH_MODE_CMAC << AUTH_MODE_SHIFT;
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if (IS_SHA(flags) || IS_SHA_HMAC(flags))
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cfg |= AUTH_POS_BEFORE << AUTH_POS_SHIFT;
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if (IS_CCM(flags))
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cfg |= QCE_MAX_NONCE_WORDS << AUTH_NONCE_NUM_WORDS_SHIFT;
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if (IS_CBC(flags) || IS_CTR(flags) || IS_CCM(flags) ||
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IS_CMAC(flags))
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cfg |= BIT(AUTH_LAST_SHIFT) | BIT(AUTH_FIRST_SHIFT);
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return cfg;
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}
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static u32 qce_config_reg(struct qce_device *qce, int little)
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{
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u32 beats = (qce->burst_size >> 3) - 1;
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u32 pipe_pair = qce->pipe_pair_id;
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u32 config;
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config = (beats << REQ_SIZE_SHIFT) & REQ_SIZE_MASK;
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config |= BIT(MASK_DOUT_INTR_SHIFT) | BIT(MASK_DIN_INTR_SHIFT) |
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BIT(MASK_OP_DONE_INTR_SHIFT) | BIT(MASK_ERR_INTR_SHIFT);
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config |= (pipe_pair << PIPE_SET_SELECT_SHIFT) & PIPE_SET_SELECT_MASK;
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config &= ~HIGH_SPD_EN_N_SHIFT;
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if (little)
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config |= BIT(LITTLE_ENDIAN_MODE_SHIFT);
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return config;
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}
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void qce_cpu_to_be32p_array(__be32 *dst, const u8 *src, unsigned int len)
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{
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__be32 *d = dst;
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const u8 *s = src;
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unsigned int n;
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n = len / sizeof(u32);
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for (; n > 0; n--) {
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*d = cpu_to_be32p((const __u32 *) s);
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s += sizeof(__u32);
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d++;
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}
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}
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static void qce_xts_swapiv(__be32 *dst, const u8 *src, unsigned int ivsize)
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{
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u8 swap[QCE_AES_IV_LENGTH];
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u32 i, j;
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if (ivsize > QCE_AES_IV_LENGTH)
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return;
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memset(swap, 0, QCE_AES_IV_LENGTH);
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for (i = (QCE_AES_IV_LENGTH - ivsize), j = ivsize - 1;
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i < QCE_AES_IV_LENGTH; i++, j--)
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swap[i] = src[j];
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qce_cpu_to_be32p_array(dst, swap, QCE_AES_IV_LENGTH);
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}
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static void qce_xtskey(struct qce_device *qce, const u8 *enckey,
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unsigned int enckeylen, unsigned int cryptlen)
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{
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u32 xtskey[QCE_MAX_CIPHER_KEY_SIZE / sizeof(u32)] = {0};
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unsigned int xtsklen = enckeylen / (2 * sizeof(u32));
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unsigned int xtsdusize;
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qce_cpu_to_be32p_array((__be32 *)xtskey, enckey + enckeylen / 2,
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enckeylen / 2);
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qce_write_array(qce, REG_ENCR_XTS_KEY0, xtskey, xtsklen);
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/* xts du size 512B */
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xtsdusize = min_t(u32, QCE_SECTOR_SIZE, cryptlen);
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qce_write(qce, REG_ENCR_XTS_DU_SIZE, xtsdusize);
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}
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static void qce_setup_config(struct qce_device *qce)
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{
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u32 config;
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/* get big endianness */
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config = qce_config_reg(qce, 0);
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/* clear status */
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qce_write(qce, REG_STATUS, 0);
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qce_write(qce, REG_CONFIG, config);
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}
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static inline void qce_crypto_go(struct qce_device *qce)
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{
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qce_write(qce, REG_GOPROC, BIT(GO_SHIFT) | BIT(RESULTS_DUMP_SHIFT));
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}
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static int qce_setup_regs_ahash(struct crypto_async_request *async_req,
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u32 totallen, u32 offset)
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{
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struct ahash_request *req = ahash_request_cast(async_req);
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struct crypto_ahash *ahash = __crypto_ahash_cast(async_req->tfm);
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struct qce_sha_reqctx *rctx = ahash_request_ctx(req);
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struct qce_alg_template *tmpl = to_ahash_tmpl(async_req->tfm);
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struct qce_device *qce = tmpl->qce;
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unsigned int digestsize = crypto_ahash_digestsize(ahash);
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unsigned int blocksize = crypto_tfm_alg_blocksize(async_req->tfm);
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__be32 auth[SHA256_DIGEST_SIZE / sizeof(__be32)] = {0};
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__be32 mackey[QCE_SHA_HMAC_KEY_SIZE / sizeof(__be32)] = {0};
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u32 auth_cfg = 0, config;
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unsigned int iv_words;
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/* if not the last, the size has to be on the block boundary */
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if (!rctx->last_blk && req->nbytes % blocksize)
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return -EINVAL;
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qce_setup_config(qce);
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if (IS_CMAC(rctx->flags)) {
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qce_write(qce, REG_AUTH_SEG_CFG, 0);
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qce_write(qce, REG_ENCR_SEG_CFG, 0);
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qce_write(qce, REG_ENCR_SEG_SIZE, 0);
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qce_clear_array(qce, REG_AUTH_IV0, 16);
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qce_clear_array(qce, REG_AUTH_KEY0, 16);
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qce_clear_array(qce, REG_AUTH_BYTECNT0, 4);
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auth_cfg = qce_auth_cfg(rctx->flags, rctx->authklen);
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}
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if (IS_SHA_HMAC(rctx->flags) || IS_CMAC(rctx->flags)) {
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u32 authkey_words = rctx->authklen / sizeof(u32);
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qce_cpu_to_be32p_array(mackey, rctx->authkey, rctx->authklen);
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qce_write_array(qce, REG_AUTH_KEY0, (u32 *)mackey,
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authkey_words);
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}
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if (IS_CMAC(rctx->flags))
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goto go_proc;
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if (rctx->first_blk)
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memcpy(auth, rctx->digest, digestsize);
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else
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qce_cpu_to_be32p_array(auth, rctx->digest, digestsize);
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iv_words = (IS_SHA1(rctx->flags) || IS_SHA1_HMAC(rctx->flags)) ? 5 : 8;
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qce_write_array(qce, REG_AUTH_IV0, (u32 *)auth, iv_words);
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if (rctx->first_blk)
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qce_clear_array(qce, REG_AUTH_BYTECNT0, 4);
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else
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qce_write_array(qce, REG_AUTH_BYTECNT0,
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(u32 *)rctx->byte_count, 2);
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auth_cfg = qce_auth_cfg(rctx->flags, 0);
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if (rctx->last_blk)
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auth_cfg |= BIT(AUTH_LAST_SHIFT);
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else
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auth_cfg &= ~BIT(AUTH_LAST_SHIFT);
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if (rctx->first_blk)
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auth_cfg |= BIT(AUTH_FIRST_SHIFT);
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else
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auth_cfg &= ~BIT(AUTH_FIRST_SHIFT);
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go_proc:
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qce_write(qce, REG_AUTH_SEG_CFG, auth_cfg);
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qce_write(qce, REG_AUTH_SEG_SIZE, req->nbytes);
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qce_write(qce, REG_AUTH_SEG_START, 0);
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qce_write(qce, REG_ENCR_SEG_CFG, 0);
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qce_write(qce, REG_SEG_SIZE, req->nbytes);
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/* get little endianness */
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config = qce_config_reg(qce, 1);
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qce_write(qce, REG_CONFIG, config);
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qce_crypto_go(qce);
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return 0;
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}
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static int qce_setup_regs_ablkcipher(struct crypto_async_request *async_req,
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u32 totallen, u32 offset)
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{
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struct ablkcipher_request *req = ablkcipher_request_cast(async_req);
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struct qce_cipher_reqctx *rctx = ablkcipher_request_ctx(req);
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struct qce_cipher_ctx *ctx = crypto_tfm_ctx(async_req->tfm);
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struct qce_alg_template *tmpl = to_cipher_tmpl(async_req->tfm);
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struct qce_device *qce = tmpl->qce;
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__be32 enckey[QCE_MAX_CIPHER_KEY_SIZE / sizeof(__be32)] = {0};
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__be32 enciv[QCE_MAX_IV_SIZE / sizeof(__be32)] = {0};
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unsigned int enckey_words, enciv_words;
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unsigned int keylen;
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u32 encr_cfg = 0, auth_cfg = 0, config;
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unsigned int ivsize = rctx->ivsize;
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unsigned long flags = rctx->flags;
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qce_setup_config(qce);
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if (IS_XTS(flags))
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keylen = ctx->enc_keylen / 2;
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else
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keylen = ctx->enc_keylen;
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qce_cpu_to_be32p_array(enckey, ctx->enc_key, keylen);
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enckey_words = keylen / sizeof(u32);
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qce_write(qce, REG_AUTH_SEG_CFG, auth_cfg);
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encr_cfg = qce_encr_cfg(flags, keylen);
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if (IS_DES(flags)) {
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enciv_words = 2;
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enckey_words = 2;
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} else if (IS_3DES(flags)) {
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enciv_words = 2;
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enckey_words = 6;
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} else if (IS_AES(flags)) {
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if (IS_XTS(flags))
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qce_xtskey(qce, ctx->enc_key, ctx->enc_keylen,
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rctx->cryptlen);
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enciv_words = 4;
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} else {
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return -EINVAL;
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}
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qce_write_array(qce, REG_ENCR_KEY0, (u32 *)enckey, enckey_words);
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if (!IS_ECB(flags)) {
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if (IS_XTS(flags))
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qce_xts_swapiv(enciv, rctx->iv, ivsize);
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else
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qce_cpu_to_be32p_array(enciv, rctx->iv, ivsize);
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qce_write_array(qce, REG_CNTR0_IV0, (u32 *)enciv, enciv_words);
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}
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if (IS_ENCRYPT(flags))
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encr_cfg |= BIT(ENCODE_SHIFT);
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qce_write(qce, REG_ENCR_SEG_CFG, encr_cfg);
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qce_write(qce, REG_ENCR_SEG_SIZE, rctx->cryptlen);
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qce_write(qce, REG_ENCR_SEG_START, offset & 0xffff);
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if (IS_CTR(flags)) {
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qce_write(qce, REG_CNTR_MASK, ~0);
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qce_write(qce, REG_CNTR_MASK0, ~0);
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qce_write(qce, REG_CNTR_MASK1, ~0);
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qce_write(qce, REG_CNTR_MASK2, ~0);
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}
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qce_write(qce, REG_SEG_SIZE, totallen);
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/* get little endianness */
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config = qce_config_reg(qce, 1);
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qce_write(qce, REG_CONFIG, config);
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qce_crypto_go(qce);
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return 0;
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}
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int qce_start(struct crypto_async_request *async_req, u32 type, u32 totallen,
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u32 offset)
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{
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switch (type) {
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case CRYPTO_ALG_TYPE_ABLKCIPHER:
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return qce_setup_regs_ablkcipher(async_req, totallen, offset);
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case CRYPTO_ALG_TYPE_AHASH:
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return qce_setup_regs_ahash(async_req, totallen, offset);
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default:
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return -EINVAL;
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}
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}
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#define STATUS_ERRORS \
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(BIT(SW_ERR_SHIFT) | BIT(AXI_ERR_SHIFT) | BIT(HSD_ERR_SHIFT))
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int qce_check_status(struct qce_device *qce, u32 *status)
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{
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int ret = 0;
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*status = qce_read(qce, REG_STATUS);
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/*
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* Don't use result dump status. The operation may not be complete.
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* Instead, use the status we just read from device. In case, we need to
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* use result_status from result dump the result_status needs to be byte
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* swapped, since we set the device to little endian.
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*/
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if (*status & STATUS_ERRORS || !(*status & BIT(OPERATION_DONE_SHIFT)))
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ret = -ENXIO;
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return ret;
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}
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void qce_get_version(struct qce_device *qce, u32 *major, u32 *minor, u32 *step)
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{
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u32 val;
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val = qce_read(qce, REG_VERSION);
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*major = (val & CORE_MAJOR_REV_MASK) >> CORE_MAJOR_REV_SHIFT;
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*minor = (val & CORE_MINOR_REV_MASK) >> CORE_MINOR_REV_SHIFT;
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*step = (val & CORE_STEP_REV_MASK) >> CORE_STEP_REV_SHIFT;
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}
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