1
// SPDX-License-Identifier: GPL-2.0-only
2
/*
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 *   Driver for ARTPEC-6 crypto block using the kernel asynchronous crypto api.
4
 *
5
 *    Copyright (C) 2014-2017  Axis Communications AB
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 */
7
#define pr_fmt(fmt)     KBUILD_MODNAME ": " fmt
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#include <linux/bitfield.h>
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#include <linux/crypto.h>
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#include <linux/debugfs.h>
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#include <linux/delay.h>
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#include <linux/dma-mapping.h>
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#include <linux/fault-inject.h>
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#include <linux/init.h>
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#include <linux/interrupt.h>
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#include <linux/kernel.h>
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#include <linux/list.h>
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#include <linux/module.h>
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#include <linux/of.h>
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#include <linux/platform_device.h>
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#include <linux/scatterlist.h>
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#include <linux/slab.h>
24

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#include <crypto/aes.h>
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#include <crypto/gcm.h>
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#include <crypto/internal/aead.h>
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#include <crypto/internal/hash.h>
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#include <crypto/internal/skcipher.h>
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#include <crypto/scatterwalk.h>
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#include <crypto/sha1.h>
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#include <crypto/sha2.h>
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#include <crypto/xts.h>
34

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/* Max length of a line in all cache levels for Artpec SoCs. */
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#define ARTPEC_CACHE_LINE_MAX	32
37

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#define PDMA_OUT_CFG		0x0000
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#define PDMA_OUT_BUF_CFG	0x0004
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#define PDMA_OUT_CMD		0x0008
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#define PDMA_OUT_DESCRQ_PUSH	0x0010
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#define PDMA_OUT_DESCRQ_STAT	0x0014
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#define A6_PDMA_IN_CFG		0x0028
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#define A6_PDMA_IN_BUF_CFG	0x002c
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#define A6_PDMA_IN_CMD		0x0030
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#define A6_PDMA_IN_STATQ_PUSH	0x0038
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#define A6_PDMA_IN_DESCRQ_PUSH	0x0044
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#define A6_PDMA_IN_DESCRQ_STAT	0x0048
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#define A6_PDMA_INTR_MASK	0x0068
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#define A6_PDMA_ACK_INTR	0x006c
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#define A6_PDMA_MASKED_INTR	0x0074
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#define A7_PDMA_IN_CFG		0x002c
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#define A7_PDMA_IN_BUF_CFG	0x0030
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#define A7_PDMA_IN_CMD		0x0034
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#define A7_PDMA_IN_STATQ_PUSH	0x003c
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#define A7_PDMA_IN_DESCRQ_PUSH	0x0048
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#define A7_PDMA_IN_DESCRQ_STAT	0x004C
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#define A7_PDMA_INTR_MASK	0x006c
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#define A7_PDMA_ACK_INTR	0x0070
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#define A7_PDMA_MASKED_INTR	0x0078
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#define PDMA_OUT_CFG_EN				BIT(0)
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66
#define PDMA_OUT_BUF_CFG_DATA_BUF_SIZE		GENMASK(4, 0)
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#define PDMA_OUT_BUF_CFG_DESCR_BUF_SIZE		GENMASK(9, 5)
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#define PDMA_OUT_CMD_START			BIT(0)
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#define A6_PDMA_OUT_CMD_STOP			BIT(3)
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#define A7_PDMA_OUT_CMD_STOP			BIT(2)
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#define PDMA_OUT_DESCRQ_PUSH_LEN		GENMASK(5, 0)
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#define PDMA_OUT_DESCRQ_PUSH_ADDR		GENMASK(31, 6)
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#define PDMA_OUT_DESCRQ_STAT_LEVEL		GENMASK(3, 0)
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#define PDMA_OUT_DESCRQ_STAT_SIZE		GENMASK(7, 4)
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#define PDMA_IN_CFG_EN				BIT(0)
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81
#define PDMA_IN_BUF_CFG_DATA_BUF_SIZE		GENMASK(4, 0)
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#define PDMA_IN_BUF_CFG_DESCR_BUF_SIZE		GENMASK(9, 5)
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#define PDMA_IN_BUF_CFG_STAT_BUF_SIZE		GENMASK(14, 10)
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#define PDMA_IN_CMD_START			BIT(0)
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#define A6_PDMA_IN_CMD_FLUSH_STAT		BIT(2)
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#define A6_PDMA_IN_CMD_STOP			BIT(3)
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#define A7_PDMA_IN_CMD_FLUSH_STAT		BIT(1)
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#define A7_PDMA_IN_CMD_STOP			BIT(2)
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#define PDMA_IN_STATQ_PUSH_LEN			GENMASK(5, 0)
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#define PDMA_IN_STATQ_PUSH_ADDR			GENMASK(31, 6)
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94
#define PDMA_IN_DESCRQ_PUSH_LEN			GENMASK(5, 0)
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#define PDMA_IN_DESCRQ_PUSH_ADDR		GENMASK(31, 6)
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97
#define PDMA_IN_DESCRQ_STAT_LEVEL		GENMASK(3, 0)
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#define PDMA_IN_DESCRQ_STAT_SIZE		GENMASK(7, 4)
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#define A6_PDMA_INTR_MASK_IN_DATA		BIT(2)
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#define A6_PDMA_INTR_MASK_IN_EOP		BIT(3)
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#define A6_PDMA_INTR_MASK_IN_EOP_FLUSH		BIT(4)
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#define A7_PDMA_INTR_MASK_IN_DATA		BIT(3)
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#define A7_PDMA_INTR_MASK_IN_EOP		BIT(4)
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#define A7_PDMA_INTR_MASK_IN_EOP_FLUSH		BIT(5)
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#define A6_CRY_MD_OPER		GENMASK(19, 16)
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#define A6_CRY_MD_HASH_SEL_CTX	GENMASK(21, 20)
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#define A6_CRY_MD_HASH_HMAC_FIN	BIT(23)
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#define A6_CRY_MD_CIPHER_LEN	GENMASK(21, 20)
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#define A6_CRY_MD_CIPHER_DECR	BIT(22)
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#define A6_CRY_MD_CIPHER_TWEAK	BIT(23)
116
#define A6_CRY_MD_CIPHER_DSEQ	BIT(24)
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118
#define A7_CRY_MD_OPER		GENMASK(11, 8)
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120
#define A7_CRY_MD_HASH_SEL_CTX	GENMASK(13, 12)
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#define A7_CRY_MD_HASH_HMAC_FIN	BIT(15)
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123
#define A7_CRY_MD_CIPHER_LEN	GENMASK(13, 12)
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#define A7_CRY_MD_CIPHER_DECR	BIT(14)
125
#define A7_CRY_MD_CIPHER_TWEAK	BIT(15)
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#define A7_CRY_MD_CIPHER_DSEQ	BIT(16)
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128
/* DMA metadata constants */
129
#define regk_crypto_aes_cbc     0x00000002
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#define regk_crypto_aes_ctr     0x00000003
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#define regk_crypto_aes_ecb     0x00000001
132
#define regk_crypto_aes_gcm     0x00000004
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#define regk_crypto_aes_xts     0x00000005
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#define regk_crypto_cache       0x00000002
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#define a6_regk_crypto_dlkey    0x0000000a
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#define a7_regk_crypto_dlkey    0x0000000e
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#define regk_crypto_ext         0x00000001
138
#define regk_crypto_hmac_sha1   0x00000007
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#define regk_crypto_hmac_sha256 0x00000009
140
#define regk_crypto_init        0x00000000
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#define regk_crypto_key_128     0x00000000
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#define regk_crypto_key_192     0x00000001
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#define regk_crypto_key_256     0x00000002
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#define regk_crypto_null        0x00000000
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#define regk_crypto_sha1        0x00000006
146
#define regk_crypto_sha256      0x00000008
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148
/* DMA descriptor structures */
149
struct pdma_descr_ctrl  {
150
	unsigned char short_descr : 1;
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	unsigned char pad1        : 1;
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	unsigned char eop         : 1;
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	unsigned char intr        : 1;
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	unsigned char short_len   : 3;
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	unsigned char pad2        : 1;
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} __packed;
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158
struct pdma_data_descr {
159
	unsigned int len : 24;
160
	unsigned int buf : 32;
161
} __packed;
162

163
struct pdma_short_descr {
164
	unsigned char data[7];
165
} __packed;
166

167
struct pdma_descr {
168
	struct pdma_descr_ctrl ctrl;
169
	union {
170
		struct pdma_data_descr   data;
171
		struct pdma_short_descr  shrt;
172
	};
173
};
174

175
struct pdma_stat_descr {
176
	unsigned char pad1        : 1;
177
	unsigned char pad2        : 1;
178
	unsigned char eop         : 1;
179
	unsigned char pad3        : 5;
180
	unsigned int  len         : 24;
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};
182

183
/* Each descriptor array can hold max 64 entries */
184
#define PDMA_DESCR_COUNT	64
185

186
#define MODULE_NAME   "Artpec-6 CA"
187

188
/* Hash modes (including HMAC variants) */
189
#define ARTPEC6_CRYPTO_HASH_SHA1	1
190
#define ARTPEC6_CRYPTO_HASH_SHA256	2
191

192
/* Crypto modes */
193
#define ARTPEC6_CRYPTO_CIPHER_AES_ECB	1
194
#define ARTPEC6_CRYPTO_CIPHER_AES_CBC	2
195
#define ARTPEC6_CRYPTO_CIPHER_AES_CTR	3
196
#define ARTPEC6_CRYPTO_CIPHER_AES_XTS	5
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198
/* The PDMA is a DMA-engine tightly coupled with a ciphering engine.
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 * It operates on a descriptor array with up to 64 descriptor entries.
200
 * The arrays must be 64 byte aligned in memory.
201
 *
202
 * The ciphering unit has no registers and is completely controlled by
203
 * a 4-byte metadata that is inserted at the beginning of each dma packet.
204
 *
205
 * A dma packet is a sequence of descriptors terminated by setting the .eop
206
 * field in the final descriptor of the packet.
207
 *
208
 * Multiple packets are used for providing context data, key data and
209
 * the plain/ciphertext.
210
 *
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 *   PDMA Descriptors (Array)
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 *  +------+------+------+~~+-------+------+----
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 *  |  0   |  1   |  2   |~~| 11 EOP|  12  |  ....
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 *  +--+---+--+---+----+-+~~+-------+----+-+----
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 *     |      |        |       |         |
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 *     |      |        |       |         |
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 *   __|__  +-------++-------++-------+ +----+
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 *  | MD  | |Payload||Payload||Payload| | MD |
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 *  +-----+ +-------++-------++-------+ +----+
220
 */
221

222
struct artpec6_crypto_bounce_buffer {
223
	struct list_head list;
224
	size_t length;
225
	struct scatterlist *sg;
226
	size_t offset;
227
	/* buf is aligned to ARTPEC_CACHE_LINE_MAX and
228
	 * holds up to ARTPEC_CACHE_LINE_MAX bytes data.
229
	 */
230
	void *buf;
231
};
232

233
struct artpec6_crypto_dma_map {
234
	dma_addr_t dma_addr;
235
	size_t size;
236
	enum dma_data_direction dir;
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};
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239
struct artpec6_crypto_dma_descriptors {
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	struct pdma_descr out[PDMA_DESCR_COUNT] __aligned(64);
241
	struct pdma_descr in[PDMA_DESCR_COUNT] __aligned(64);
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	u32 stat[PDMA_DESCR_COUNT] __aligned(64);
243
	struct list_head bounce_buffers;
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	/* Enough maps for all out/in buffers, and all three descr. arrays */
245
	struct artpec6_crypto_dma_map maps[PDMA_DESCR_COUNT * 2 + 2];
246
	dma_addr_t out_dma_addr;
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	dma_addr_t in_dma_addr;
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	dma_addr_t stat_dma_addr;
249
	size_t out_cnt;
250
	size_t in_cnt;
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	size_t map_count;
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};
253

254
enum artpec6_crypto_variant {
255
	ARTPEC6_CRYPTO,
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	ARTPEC7_CRYPTO,
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};
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259
struct artpec6_crypto {
260
	void __iomem *base;
261
	spinlock_t queue_lock;
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	struct list_head queue; /* waiting for pdma fifo space */
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	struct list_head pending; /* submitted to pdma fifo */
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	struct tasklet_struct task;
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	struct kmem_cache *dma_cache;
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	int pending_count;
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	struct timer_list timer;
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	enum artpec6_crypto_variant variant;
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	void *pad_buffer; /* cache-aligned block padding buffer */
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	void *zero_buffer;
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};
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273
enum artpec6_crypto_hash_flags {
274
	HASH_FLAG_INIT_CTX = 2,
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	HASH_FLAG_UPDATE = 4,
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	HASH_FLAG_FINALIZE = 8,
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	HASH_FLAG_HMAC = 16,
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	HASH_FLAG_UPDATE_KEY = 32,
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};
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281
struct artpec6_crypto_req_common {
282
	struct list_head list;
283
	struct list_head complete_in_progress;
284
	struct artpec6_crypto_dma_descriptors *dma;
285
	struct crypto_async_request *req;
286
	void (*complete)(struct crypto_async_request *req);
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	gfp_t gfp_flags;
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};
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290
struct artpec6_hash_request_context {
291
	char partial_buffer[SHA256_BLOCK_SIZE];
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	char partial_buffer_out[SHA256_BLOCK_SIZE];
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	char key_buffer[SHA256_BLOCK_SIZE];
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	char pad_buffer[SHA256_BLOCK_SIZE + 32];
295
	unsigned char digeststate[SHA256_DIGEST_SIZE];
296
	size_t partial_bytes;
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	u64 digcnt;
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	u32 key_md;
299
	u32 hash_md;
300
	enum artpec6_crypto_hash_flags hash_flags;
301
	struct artpec6_crypto_req_common common;
302
};
303

304
struct artpec6_hash_export_state {
305
	char partial_buffer[SHA256_BLOCK_SIZE];
306
	unsigned char digeststate[SHA256_DIGEST_SIZE];
307
	size_t partial_bytes;
308
	u64 digcnt;
309
	int oper;
310
	unsigned int hash_flags;
311
};
312

313
struct artpec6_hashalg_context {
314
	char hmac_key[SHA256_BLOCK_SIZE];
315
	size_t hmac_key_length;
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	struct crypto_shash *child_hash;
317
};
318

319
struct artpec6_crypto_request_context {
320
	u32 cipher_md;
321
	bool decrypt;
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	struct artpec6_crypto_req_common common;
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};
324

325
struct artpec6_cryptotfm_context {
326
	unsigned char aes_key[2*AES_MAX_KEY_SIZE];
327
	size_t key_length;
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	u32 key_md;
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	int crypto_type;
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	struct crypto_sync_skcipher *fallback;
331
};
332

333
struct artpec6_crypto_aead_hw_ctx {
334
	__be64	aad_length_bits;
335
	__be64  text_length_bits;
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	__u8	J0[AES_BLOCK_SIZE];
337
};
338

339
struct artpec6_crypto_aead_req_ctx {
340
	struct artpec6_crypto_aead_hw_ctx hw_ctx;
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	u32 cipher_md;
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	bool decrypt;
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	struct artpec6_crypto_req_common common;
344
	__u8 decryption_tag[AES_BLOCK_SIZE] ____cacheline_aligned;
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};
346

347
/* The crypto framework makes it hard to avoid this global. */
348
static struct device *artpec6_crypto_dev;
349

350
#ifdef CONFIG_FAULT_INJECTION
351
static DECLARE_FAULT_ATTR(artpec6_crypto_fail_status_read);
352
static DECLARE_FAULT_ATTR(artpec6_crypto_fail_dma_array_full);
353
#endif
354

355
enum {
356
	ARTPEC6_CRYPTO_PREPARE_HASH_NO_START,
357
	ARTPEC6_CRYPTO_PREPARE_HASH_START,
358
};
359

360
static int artpec6_crypto_prepare_aead(struct aead_request *areq);
361
static int artpec6_crypto_prepare_crypto(struct skcipher_request *areq);
362
static int artpec6_crypto_prepare_hash(struct ahash_request *areq);
363

364
static void
365
artpec6_crypto_complete_crypto(struct crypto_async_request *req);
366
static void
367
artpec6_crypto_complete_cbc_encrypt(struct crypto_async_request *req);
368
static void
369
artpec6_crypto_complete_cbc_decrypt(struct crypto_async_request *req);
370
static void
371
artpec6_crypto_complete_aead(struct crypto_async_request *req);
372
static void
373
artpec6_crypto_complete_hash(struct crypto_async_request *req);
374

375
static int
376
artpec6_crypto_common_destroy(struct artpec6_crypto_req_common *common);
377

378
static void
379
artpec6_crypto_start_dma(struct artpec6_crypto_req_common *common);
380

381
struct artpec6_crypto_walk {
382
	struct scatterlist *sg;
383
	size_t offset;
384
};
385

386
static void artpec6_crypto_walk_init(struct artpec6_crypto_walk *awalk,
387
				     struct scatterlist *sg)
388
{
389
	awalk->sg = sg;
390
	awalk->offset = 0;
391
}
392

393
static size_t artpec6_crypto_walk_advance(struct artpec6_crypto_walk *awalk,
394
					  size_t nbytes)
395
{
396
	while (nbytes && awalk->sg) {
397
		size_t piece;
398

399
		WARN_ON(awalk->offset > awalk->sg->length);
400

401
		piece = min(nbytes, (size_t)awalk->sg->length - awalk->offset);
402
		nbytes -= piece;
403
		awalk->offset += piece;
404
		if (awalk->offset == awalk->sg->length) {
405
			awalk->sg = sg_next(awalk->sg);
406
			awalk->offset = 0;
407
		}
408

409
	}
410

411
	return nbytes;
412
}
413

414
static size_t
415
artpec6_crypto_walk_chunklen(const struct artpec6_crypto_walk *awalk)
416
{
417
	WARN_ON(awalk->sg->length == awalk->offset);
418

419
	return awalk->sg->length - awalk->offset;
420
}
421

422
static dma_addr_t
423
artpec6_crypto_walk_chunk_phys(const struct artpec6_crypto_walk *awalk)
424
{
425
	return sg_phys(awalk->sg) + awalk->offset;
426
}
427

428
static void
429
artpec6_crypto_copy_bounce_buffers(struct artpec6_crypto_req_common *common)
430
{
431
	struct artpec6_crypto_dma_descriptors *dma = common->dma;
432
	struct artpec6_crypto_bounce_buffer *b;
433
	struct artpec6_crypto_bounce_buffer *next;
434

435
	list_for_each_entry_safe(b, next, &dma->bounce_buffers, list) {
436
		pr_debug("bounce entry %p: %zu bytes @ %zu from %p\n",
437
			 b, b->length, b->offset, b->buf);
438
		sg_pcopy_from_buffer(b->sg,
439
				   1,
440
				   b->buf,
441
				   b->length,
442
				   b->offset);
443

444
		list_del(&b->list);
445
		kfree(b);
446
	}
447
}
448

449
static inline bool artpec6_crypto_busy(void)
450
{
451
	struct artpec6_crypto *ac = dev_get_drvdata(artpec6_crypto_dev);
452
	int fifo_count = ac->pending_count;
453

454
	return fifo_count > 6;
455
}
456

457
static int artpec6_crypto_submit(struct artpec6_crypto_req_common *req)
458
{
459
	struct artpec6_crypto *ac = dev_get_drvdata(artpec6_crypto_dev);
460
	int ret = -EBUSY;
461

462
	spin_lock_bh(&ac->queue_lock);
463

464
	if (!artpec6_crypto_busy()) {
465
		list_add_tail(&req->list, &ac->pending);
466
		artpec6_crypto_start_dma(req);
467
		ret = -EINPROGRESS;
468
	} else if (req->req->flags & CRYPTO_TFM_REQ_MAY_BACKLOG) {
469
		list_add_tail(&req->list, &ac->queue);
470
	} else {
471
		artpec6_crypto_common_destroy(req);
472
	}
473

474
	spin_unlock_bh(&ac->queue_lock);
475

476
	return ret;
477
}
478

479
static void artpec6_crypto_start_dma(struct artpec6_crypto_req_common *common)
480
{
481
	struct artpec6_crypto *ac = dev_get_drvdata(artpec6_crypto_dev);
482
	enum artpec6_crypto_variant variant = ac->variant;
483
	void __iomem *base = ac->base;
484
	struct artpec6_crypto_dma_descriptors *dma = common->dma;
485
	u32 ind, statd, outd;
486

487
	/* Make descriptor content visible to the DMA before starting it. */
488
	wmb();
489

490
	ind = FIELD_PREP(PDMA_IN_DESCRQ_PUSH_LEN, dma->in_cnt - 1) |
491
	      FIELD_PREP(PDMA_IN_DESCRQ_PUSH_ADDR, dma->in_dma_addr >> 6);
492

493
	statd = FIELD_PREP(PDMA_IN_STATQ_PUSH_LEN, dma->in_cnt - 1) |
494
		FIELD_PREP(PDMA_IN_STATQ_PUSH_ADDR, dma->stat_dma_addr >> 6);
495

496
	outd = FIELD_PREP(PDMA_OUT_DESCRQ_PUSH_LEN, dma->out_cnt - 1) |
497
	       FIELD_PREP(PDMA_OUT_DESCRQ_PUSH_ADDR, dma->out_dma_addr >> 6);
498

499
	if (variant == ARTPEC6_CRYPTO) {
500
		writel_relaxed(ind, base + A6_PDMA_IN_DESCRQ_PUSH);
501
		writel_relaxed(statd, base + A6_PDMA_IN_STATQ_PUSH);
502
		writel_relaxed(PDMA_IN_CMD_START, base + A6_PDMA_IN_CMD);
503
	} else {
504
		writel_relaxed(ind, base + A7_PDMA_IN_DESCRQ_PUSH);
505
		writel_relaxed(statd, base + A7_PDMA_IN_STATQ_PUSH);
506
		writel_relaxed(PDMA_IN_CMD_START, base + A7_PDMA_IN_CMD);
507
	}
508

509
	writel_relaxed(outd, base + PDMA_OUT_DESCRQ_PUSH);
510
	writel_relaxed(PDMA_OUT_CMD_START, base + PDMA_OUT_CMD);
511

512
	ac->pending_count++;
513
}
514

515
static void
516
artpec6_crypto_init_dma_operation(struct artpec6_crypto_req_common *common)
517
{
518
	struct artpec6_crypto_dma_descriptors *dma = common->dma;
519

520
	dma->out_cnt = 0;
521
	dma->in_cnt = 0;
522
	dma->map_count = 0;
523
	INIT_LIST_HEAD(&dma->bounce_buffers);
524
}
525

526
static bool fault_inject_dma_descr(void)
527
{
528
#ifdef CONFIG_FAULT_INJECTION
529
	return should_fail(&artpec6_crypto_fail_dma_array_full, 1);
530
#else
531
	return false;
532
#endif
533
}
534

535
/** artpec6_crypto_setup_out_descr_phys - Setup an out channel with a
536
 *                                        physical address
537
 *
538
 * @addr: The physical address of the data buffer
539
 * @len:  The length of the data buffer
540
 * @eop:  True if this is the last buffer in the packet
541
 *
542
 * @return 0 on success or -ENOSPC if there are no more descriptors available
543
 */
544
static int
545
artpec6_crypto_setup_out_descr_phys(struct artpec6_crypto_req_common *common,
546
				    dma_addr_t addr, size_t len, bool eop)
547
{
548
	struct artpec6_crypto_dma_descriptors *dma = common->dma;
549
	struct pdma_descr *d;
550

551
	if (dma->out_cnt >= PDMA_DESCR_COUNT ||
552
	    fault_inject_dma_descr()) {
553
		pr_err("No free OUT DMA descriptors available!\n");
554
		return -ENOSPC;
555
	}
556

557
	d = &dma->out[dma->out_cnt++];
558
	memset(d, 0, sizeof(*d));
559

560
	d->ctrl.short_descr = 0;
561
	d->ctrl.eop = eop;
562
	d->data.len = len;
563
	d->data.buf = addr;
564
	return 0;
565
}
566

567
/** artpec6_crypto_setup_out_descr_short - Setup a short out descriptor
568
 *
569
 * @dst: The virtual address of the data
570
 * @len: The length of the data, must be between 1 to 7 bytes
571
 * @eop: True if this is the last buffer in the packet
572
 *
573
 * @return 0 on success
574
 *	-ENOSPC if no more descriptors are available
575
 *	-EINVAL if the data length exceeds 7 bytes
576
 */
577
static int
578
artpec6_crypto_setup_out_descr_short(struct artpec6_crypto_req_common *common,
579
				     void *dst, unsigned int len, bool eop)
580
{
581
	struct artpec6_crypto_dma_descriptors *dma = common->dma;
582
	struct pdma_descr *d;
583

584
	if (dma->out_cnt >= PDMA_DESCR_COUNT ||
585
	    fault_inject_dma_descr()) {
586
		pr_err("No free OUT DMA descriptors available!\n");
587
		return -ENOSPC;
588
	} else if (len > 7 || len < 1) {
589
		return -EINVAL;
590
	}
591
	d = &dma->out[dma->out_cnt++];
592
	memset(d, 0, sizeof(*d));
593

594
	d->ctrl.short_descr = 1;
595
	d->ctrl.short_len = len;
596
	d->ctrl.eop = eop;
597
	memcpy(d->shrt.data, dst, len);
598
	return 0;
599
}
600

601
static int artpec6_crypto_dma_map_page(struct artpec6_crypto_req_common *common,
602
				      struct page *page, size_t offset,
603
				      size_t size,
604
				      enum dma_data_direction dir,
605
				      dma_addr_t *dma_addr_out)
606
{
607
	struct artpec6_crypto_dma_descriptors *dma = common->dma;
608
	struct device *dev = artpec6_crypto_dev;
609
	struct artpec6_crypto_dma_map *map;
610
	dma_addr_t dma_addr;
611

612
	*dma_addr_out = 0;
613

614
	if (dma->map_count >= ARRAY_SIZE(dma->maps))
615
		return -ENOMEM;
616

617
	dma_addr = dma_map_page(dev, page, offset, size, dir);
618
	if (dma_mapping_error(dev, dma_addr))
619
		return -ENOMEM;
620

621
	map = &dma->maps[dma->map_count++];
622
	map->size = size;
623
	map->dma_addr = dma_addr;
624
	map->dir = dir;
625

626
	*dma_addr_out = dma_addr;
627

628
	return 0;
629
}
630

631
static int
632
artpec6_crypto_dma_map_single(struct artpec6_crypto_req_common *common,
633
			      void *ptr, size_t size,
634
			      enum dma_data_direction dir,
635
			      dma_addr_t *dma_addr_out)
636
{
637
	struct page *page = virt_to_page(ptr);
638
	size_t offset = (uintptr_t)ptr & ~PAGE_MASK;
639

640
	return artpec6_crypto_dma_map_page(common, page, offset, size, dir,
641
					  dma_addr_out);
642
}
643

644
static int
645
artpec6_crypto_dma_map_descs(struct artpec6_crypto_req_common *common)
646
{
647
	struct artpec6_crypto_dma_descriptors *dma = common->dma;
648
	int ret;
649

650
	ret = artpec6_crypto_dma_map_single(common, dma->in,
651
				sizeof(dma->in[0]) * dma->in_cnt,
652
				DMA_TO_DEVICE, &dma->in_dma_addr);
653
	if (ret)
654
		return ret;
655

656
	ret = artpec6_crypto_dma_map_single(common, dma->out,
657
				sizeof(dma->out[0]) * dma->out_cnt,
658
				DMA_TO_DEVICE, &dma->out_dma_addr);
659
	if (ret)
660
		return ret;
661

662
	/* We only read one stat descriptor */
663
	dma->stat[dma->in_cnt - 1] = 0;
664

665
	/*
666
	 * DMA_BIDIRECTIONAL since we need our zeroing of the stat descriptor
667
	 * to be written.
668
	 */
669
	return artpec6_crypto_dma_map_single(common,
670
				dma->stat,
671
				sizeof(dma->stat[0]) * dma->in_cnt,
672
				DMA_BIDIRECTIONAL,
673
				&dma->stat_dma_addr);
674
}
675

676
static void
677
artpec6_crypto_dma_unmap_all(struct artpec6_crypto_req_common *common)
678
{
679
	struct artpec6_crypto_dma_descriptors *dma = common->dma;
680
	struct device *dev = artpec6_crypto_dev;
681
	int i;
682

683
	for (i = 0; i < dma->map_count; i++) {
684
		struct artpec6_crypto_dma_map *map = &dma->maps[i];
685

686
		dma_unmap_page(dev, map->dma_addr, map->size, map->dir);
687
	}
688

689
	dma->map_count = 0;
690
}
691

692
/** artpec6_crypto_setup_out_descr - Setup an out descriptor
693
 *
694
 * @dst: The virtual address of the data
695
 * @len: The length of the data
696
 * @eop: True if this is the last buffer in the packet
697
 * @use_short: If this is true and the data length is 7 bytes or less then
698
 *	a short descriptor will be used
699
 *
700
 * @return 0 on success
701
 *	Any errors from artpec6_crypto_setup_out_descr_short() or
702
 *	setup_out_descr_phys()
703
 */
704
static int
705
artpec6_crypto_setup_out_descr(struct artpec6_crypto_req_common *common,
706
			       void *dst, unsigned int len, bool eop,
707
			       bool use_short)
708
{
709
	if (use_short && len < 7) {
710
		return artpec6_crypto_setup_out_descr_short(common, dst, len,
711
							    eop);
712
	} else {
713
		int ret;
714
		dma_addr_t dma_addr;
715

716
		ret = artpec6_crypto_dma_map_single(common, dst, len,
717
						   DMA_TO_DEVICE,
718
						   &dma_addr);
719
		if (ret)
720
			return ret;
721

722
		return artpec6_crypto_setup_out_descr_phys(common, dma_addr,
723
							   len, eop);
724
	}
725
}
726

727
/** artpec6_crypto_setup_in_descr_phys - Setup an in channel with a
728
 *                                       physical address
729
 *
730
 * @addr: The physical address of the data buffer
731
 * @len:  The length of the data buffer
732
 * @intr: True if an interrupt should be fired after HW processing of this
733
 *	  descriptor
734
 *
735
 */
736
static int
737
artpec6_crypto_setup_in_descr_phys(struct artpec6_crypto_req_common *common,
738
			       dma_addr_t addr, unsigned int len, bool intr)
739
{
740
	struct artpec6_crypto_dma_descriptors *dma = common->dma;
741
	struct pdma_descr *d;
742

743
	if (dma->in_cnt >= PDMA_DESCR_COUNT ||
744
	    fault_inject_dma_descr()) {
745
		pr_err("No free IN DMA descriptors available!\n");
746
		return -ENOSPC;
747
	}
748
	d = &dma->in[dma->in_cnt++];
749
	memset(d, 0, sizeof(*d));
750

751
	d->ctrl.intr = intr;
752
	d->data.len = len;
753
	d->data.buf = addr;
754
	return 0;
755
}
756

757
/** artpec6_crypto_setup_in_descr - Setup an in channel descriptor
758
 *
759
 * @buffer: The virtual address to of the data buffer
760
 * @len:    The length of the data buffer
761
 * @last:   If this is the last data buffer in the request (i.e. an interrupt
762
 *	    is needed
763
 *
764
 * Short descriptors are not used for the in channel
765
 */
766
static int
767
artpec6_crypto_setup_in_descr(struct artpec6_crypto_req_common *common,
768
			  void *buffer, unsigned int len, bool last)
769
{
770
	dma_addr_t dma_addr;
771
	int ret;
772

773
	ret = artpec6_crypto_dma_map_single(common, buffer, len,
774
					   DMA_FROM_DEVICE, &dma_addr);
775
	if (ret)
776
		return ret;
777

778
	return artpec6_crypto_setup_in_descr_phys(common, dma_addr, len, last);
779
}
780

781
static struct artpec6_crypto_bounce_buffer *
782
artpec6_crypto_alloc_bounce(gfp_t flags)
783
{
784
	void *base;
785
	size_t alloc_size = sizeof(struct artpec6_crypto_bounce_buffer) +
786
			    2 * ARTPEC_CACHE_LINE_MAX;
787
	struct artpec6_crypto_bounce_buffer *bbuf = kzalloc(alloc_size, flags);
788

789
	if (!bbuf)
790
		return NULL;
791

792
	base = bbuf + 1;
793
	bbuf->buf = PTR_ALIGN(base, ARTPEC_CACHE_LINE_MAX);
794
	return bbuf;
795
}
796

797
static int setup_bounce_buffer_in(struct artpec6_crypto_req_common *common,
798
				  struct artpec6_crypto_walk *walk, size_t size)
799
{
800
	struct artpec6_crypto_bounce_buffer *bbuf;
801
	int ret;
802

803
	bbuf = artpec6_crypto_alloc_bounce(common->gfp_flags);
804
	if (!bbuf)
805
		return -ENOMEM;
806

807
	bbuf->length = size;
808
	bbuf->sg = walk->sg;
809
	bbuf->offset = walk->offset;
810

811
	ret =  artpec6_crypto_setup_in_descr(common, bbuf->buf, size, false);
812
	if (ret) {
813
		kfree(bbuf);
814
		return ret;
815
	}
816

817
	pr_debug("BOUNCE %zu offset %zu\n", size, walk->offset);
818
	list_add_tail(&bbuf->list, &common->dma->bounce_buffers);
819
	return 0;
820
}
821

822
static int
823
artpec6_crypto_setup_sg_descrs_in(struct artpec6_crypto_req_common *common,
824
				  struct artpec6_crypto_walk *walk,
825
				  size_t count)
826
{
827
	size_t chunk;
828
	int ret;
829
	dma_addr_t addr;
830

831
	while (walk->sg && count) {
832
		chunk = min(count, artpec6_crypto_walk_chunklen(walk));
833
		addr = artpec6_crypto_walk_chunk_phys(walk);
834

835
		/* When destination buffers are not aligned to the cache line
836
		 * size we need bounce buffers. The DMA-API requires that the
837
		 * entire line is owned by the DMA buffer and this holds also
838
		 * for the case when coherent DMA is used.
839
		 */
840
		if (!IS_ALIGNED(addr, ARTPEC_CACHE_LINE_MAX)) {
841
			chunk = min_t(dma_addr_t, chunk,
842
				      ALIGN(addr, ARTPEC_CACHE_LINE_MAX) -
843
				      addr);
844

845
			pr_debug("CHUNK-b %pad:%zu\n", &addr, chunk);
846
			ret = setup_bounce_buffer_in(common, walk, chunk);
847
		} else if (chunk < ARTPEC_CACHE_LINE_MAX) {
848
			pr_debug("CHUNK-b %pad:%zu\n", &addr, chunk);
849
			ret = setup_bounce_buffer_in(common, walk, chunk);
850
		} else {
851
			dma_addr_t dma_addr;
852

853
			chunk = chunk & ~(ARTPEC_CACHE_LINE_MAX-1);
854

855
			pr_debug("CHUNK %pad:%zu\n", &addr, chunk);
856

857
			ret = artpec6_crypto_dma_map_page(common,
858
							 sg_page(walk->sg),
859
							 walk->sg->offset +
860
							 walk->offset,
861
							 chunk,
862
							 DMA_FROM_DEVICE,
863
							 &dma_addr);
864
			if (ret)
865
				return ret;
866

867
			ret = artpec6_crypto_setup_in_descr_phys(common,
868
								 dma_addr,
869
								 chunk, false);
870
		}
871

872
		if (ret)
873
			return ret;
874

875
		count = count - chunk;
876
		artpec6_crypto_walk_advance(walk, chunk);
877
	}
878

879
	if (count)
880
		pr_err("EOL unexpected %zu bytes left\n", count);
881

882
	return count ? -EINVAL : 0;
883
}
884

885
static int
886
artpec6_crypto_setup_sg_descrs_out(struct artpec6_crypto_req_common *common,
887
				   struct artpec6_crypto_walk *walk,
888
				   size_t count)
889
{
890
	size_t chunk;
891
	int ret;
892
	dma_addr_t addr;
893

894
	while (walk->sg && count) {
895
		chunk = min(count, artpec6_crypto_walk_chunklen(walk));
896
		addr = artpec6_crypto_walk_chunk_phys(walk);
897

898
		pr_debug("OUT-CHUNK %pad:%zu\n", &addr, chunk);
899

900
		if (addr & 3) {
901
			char buf[3];
902

903
			chunk = min_t(size_t, chunk, (4-(addr&3)));
904

905
			sg_pcopy_to_buffer(walk->sg, 1, buf, chunk,
906
					   walk->offset);
907

908
			ret = artpec6_crypto_setup_out_descr_short(common, buf,
909
								   chunk,
910
								   false);
911
		} else {
912
			dma_addr_t dma_addr;
913

914
			ret = artpec6_crypto_dma_map_page(common,
915
							 sg_page(walk->sg),
916
							 walk->sg->offset +
917
							 walk->offset,
918
							 chunk,
919
							 DMA_TO_DEVICE,
920
							 &dma_addr);
921
			if (ret)
922
				return ret;
923

924
			ret = artpec6_crypto_setup_out_descr_phys(common,
925
								 dma_addr,
926
								 chunk, false);
927
		}
928

929
		if (ret)
930
			return ret;
931

932
		count = count - chunk;
933
		artpec6_crypto_walk_advance(walk, chunk);
934
	}
935

936
	if (count)
937
		pr_err("EOL unexpected %zu bytes left\n", count);
938

939
	return count ? -EINVAL : 0;
940
}
941

942

943
/** artpec6_crypto_terminate_out_descrs - Set the EOP on the last out descriptor
944
 *
945
 * If the out descriptor list is non-empty, then the eop flag on the
946
 * last used out descriptor will be set.
947
 *
948
 * @return  0 on success
949
 *	-EINVAL if the out descriptor is empty or has overflown
950
 */
951
static int
952
artpec6_crypto_terminate_out_descrs(struct artpec6_crypto_req_common *common)
953
{
954
	struct artpec6_crypto_dma_descriptors *dma = common->dma;
955
	struct pdma_descr *d;
956

957
	if (!dma->out_cnt || dma->out_cnt > PDMA_DESCR_COUNT) {
958
		pr_err("%s: OUT descriptor list is %s\n",
959
			MODULE_NAME, dma->out_cnt ? "empty" : "full");
960
		return -EINVAL;
961

962
	}
963

964
	d = &dma->out[dma->out_cnt-1];
965
	d->ctrl.eop = 1;
966

967
	return 0;
968
}
969

970
/** artpec6_crypto_terminate_in_descrs - Set the interrupt flag on the last
971
 *                                       in descriptor
972
 *
973
 * See artpec6_crypto_terminate_out_descrs() for return values
974
 */
975
static int
976
artpec6_crypto_terminate_in_descrs(struct artpec6_crypto_req_common *common)
977
{
978
	struct artpec6_crypto_dma_descriptors *dma = common->dma;
979
	struct pdma_descr *d;
980

981
	if (!dma->in_cnt || dma->in_cnt > PDMA_DESCR_COUNT) {
982
		pr_err("%s: IN descriptor list is %s\n",
983
			MODULE_NAME, dma->in_cnt ? "empty" : "full");
984
		return -EINVAL;
985
	}
986

987
	d = &dma->in[dma->in_cnt-1];
988
	d->ctrl.intr = 1;
989
	return 0;
990
}
991

992
/** create_hash_pad - Create a Secure Hash conformant pad
993
 *
994
 * @dst:      The destination buffer to write the pad. Must be at least 64 bytes
995
 * @dgstlen:  The total length of the hash digest in bytes
996
 * @bitcount: The total length of the digest in bits
997
 *
998
 * @return The total number of padding bytes written to @dst
999
 */
1000
static size_t
1001
create_hash_pad(int oper, unsigned char *dst, u64 dgstlen, u64 bitcount)
1002
{
1003
	unsigned int mod, target, diff, pad_bytes, size_bytes;
1004
	__be64 bits = __cpu_to_be64(bitcount);
1005

1006
	switch (oper) {
1007
	case regk_crypto_sha1:
1008
	case regk_crypto_sha256:
1009
	case regk_crypto_hmac_sha1:
1010
	case regk_crypto_hmac_sha256:
1011
		target = 448 / 8;
1012
		mod = 512 / 8;
1013
		size_bytes = 8;
1014
		break;
1015
	default:
1016
		target = 896 / 8;
1017
		mod = 1024 / 8;
1018
		size_bytes = 16;
1019
		break;
1020
	}
1021

1022
	target -= 1;
1023
	diff = dgstlen & (mod - 1);
1024
	pad_bytes = diff > target ? target + mod - diff : target - diff;
1025

1026
	memset(dst + 1, 0, pad_bytes);
1027
	dst[0] = 0x80;
1028

1029
	if (size_bytes == 16) {
1030
		memset(dst + 1 + pad_bytes, 0, 8);
1031
		memcpy(dst + 1 + pad_bytes + 8, &bits, 8);
1032
	} else {
1033
		memcpy(dst + 1 + pad_bytes, &bits, 8);
1034
	}
1035

1036
	return pad_bytes + size_bytes + 1;
1037
}
1038

1039
static int artpec6_crypto_common_init(struct artpec6_crypto_req_common *common,
1040
		struct crypto_async_request *parent,
1041
		void (*complete)(struct crypto_async_request *req),
1042
		struct scatterlist *dstsg, unsigned int nbytes)
1043
{
1044
	gfp_t flags;
1045
	struct artpec6_crypto *ac = dev_get_drvdata(artpec6_crypto_dev);
1046

1047
	flags = (parent->flags & CRYPTO_TFM_REQ_MAY_SLEEP) ?
1048
		 GFP_KERNEL : GFP_ATOMIC;
1049

1050
	common->gfp_flags = flags;
1051
	common->dma = kmem_cache_alloc(ac->dma_cache, flags);
1052
	if (!common->dma)
1053
		return -ENOMEM;
1054

1055
	common->req = parent;
1056
	common->complete = complete;
1057
	return 0;
1058
}
1059

1060
static void
1061
artpec6_crypto_bounce_destroy(struct artpec6_crypto_dma_descriptors *dma)
1062
{
1063
	struct artpec6_crypto_bounce_buffer *b;
1064
	struct artpec6_crypto_bounce_buffer *next;
1065

1066
	list_for_each_entry_safe(b, next, &dma->bounce_buffers, list) {
1067
		kfree(b);
1068
	}
1069
}
1070

1071
static int
1072
artpec6_crypto_common_destroy(struct artpec6_crypto_req_common *common)
1073
{
1074
	struct artpec6_crypto *ac = dev_get_drvdata(artpec6_crypto_dev);
1075

1076
	artpec6_crypto_dma_unmap_all(common);
1077
	artpec6_crypto_bounce_destroy(common->dma);
1078
	kmem_cache_free(ac->dma_cache, common->dma);
1079
	common->dma = NULL;
1080
	return 0;
1081
}
1082

1083
/*
1084
 * Ciphering functions.
1085
 */
1086
static int artpec6_crypto_encrypt(struct skcipher_request *req)
1087
{
1088
	struct crypto_skcipher *cipher = crypto_skcipher_reqtfm(req);
1089
	struct artpec6_cryptotfm_context *ctx = crypto_skcipher_ctx(cipher);
1090
	struct artpec6_crypto_request_context *req_ctx = NULL;
1091
	void (*complete)(struct crypto_async_request *req);
1092
	int ret;
1093

1094
	req_ctx = skcipher_request_ctx(req);
1095

1096
	switch (ctx->crypto_type) {
1097
	case ARTPEC6_CRYPTO_CIPHER_AES_CBC:
1098
	case ARTPEC6_CRYPTO_CIPHER_AES_ECB:
1099
	case ARTPEC6_CRYPTO_CIPHER_AES_XTS:
1100
		req_ctx->decrypt = 0;
1101
		break;
1102
	default:
1103
		break;
1104
	}
1105

1106
	switch (ctx->crypto_type) {
1107
	case ARTPEC6_CRYPTO_CIPHER_AES_CBC:
1108
		complete = artpec6_crypto_complete_cbc_encrypt;
1109
		break;
1110
	default:
1111
		complete = artpec6_crypto_complete_crypto;
1112
		break;
1113
	}
1114

1115
	ret = artpec6_crypto_common_init(&req_ctx->common,
1116
				  &req->base,
1117
				  complete,
1118
				  req->dst, req->cryptlen);
1119
	if (ret)
1120
		return ret;
1121

1122
	ret = artpec6_crypto_prepare_crypto(req);
1123
	if (ret) {
1124
		artpec6_crypto_common_destroy(&req_ctx->common);
1125
		return ret;
1126
	}
1127

1128
	return artpec6_crypto_submit(&req_ctx->common);
1129
}
1130

1131
static int artpec6_crypto_decrypt(struct skcipher_request *req)
1132
{
1133
	int ret;
1134
	struct crypto_skcipher *cipher = crypto_skcipher_reqtfm(req);
1135
	struct artpec6_cryptotfm_context *ctx = crypto_skcipher_ctx(cipher);
1136
	struct artpec6_crypto_request_context *req_ctx = NULL;
1137
	void (*complete)(struct crypto_async_request *req);
1138

1139
	req_ctx = skcipher_request_ctx(req);
1140

1141
	switch (ctx->crypto_type) {
1142
	case ARTPEC6_CRYPTO_CIPHER_AES_CBC:
1143
	case ARTPEC6_CRYPTO_CIPHER_AES_ECB:
1144
	case ARTPEC6_CRYPTO_CIPHER_AES_XTS:
1145
		req_ctx->decrypt = 1;
1146
		break;
1147
	default:
1148
		break;
1149
	}
1150

1151

1152
	switch (ctx->crypto_type) {
1153
	case ARTPEC6_CRYPTO_CIPHER_AES_CBC:
1154
		complete = artpec6_crypto_complete_cbc_decrypt;
1155
		break;
1156
	default:
1157
		complete = artpec6_crypto_complete_crypto;
1158
		break;
1159
	}
1160

1161
	ret = artpec6_crypto_common_init(&req_ctx->common, &req->base,
1162
				  complete,
1163
				  req->dst, req->cryptlen);
1164
	if (ret)
1165
		return ret;
1166

1167
	ret = artpec6_crypto_prepare_crypto(req);
1168
	if (ret) {
1169
		artpec6_crypto_common_destroy(&req_ctx->common);
1170
		return ret;
1171
	}
1172

1173
	return artpec6_crypto_submit(&req_ctx->common);
1174
}
1175

1176
static int
1177
artpec6_crypto_ctr_crypt(struct skcipher_request *req, bool encrypt)
1178
{
1179
	struct crypto_skcipher *cipher = crypto_skcipher_reqtfm(req);
1180
	struct artpec6_cryptotfm_context *ctx = crypto_skcipher_ctx(cipher);
1181
	size_t iv_len = crypto_skcipher_ivsize(cipher);
1182
	unsigned int counter = be32_to_cpup((__be32 *)
1183
					    (req->iv + iv_len - 4));
1184
	unsigned int nblks = ALIGN(req->cryptlen, AES_BLOCK_SIZE) /
1185
			     AES_BLOCK_SIZE;
1186

1187
	/*
1188
	 * The hardware uses only the last 32-bits as the counter while the
1189
	 * kernel tests (aes_ctr_enc_tv_template[4] for example) expect that
1190
	 * the whole IV is a counter.  So fallback if the counter is going to
1191
	 * overlow.
1192
	 */
1193
	if (counter + nblks < counter) {
1194
		int ret;
1195

1196
		pr_debug("counter %x will overflow (nblks %u), falling back\n",
1197
			 counter, counter + nblks);
1198

1199
		ret = crypto_sync_skcipher_setkey(ctx->fallback, ctx->aes_key,
1200
						  ctx->key_length);
1201
		if (ret)
1202
			return ret;
1203

1204
		{
1205
			SYNC_SKCIPHER_REQUEST_ON_STACK(subreq, ctx->fallback);
1206

1207
			skcipher_request_set_sync_tfm(subreq, ctx->fallback);
1208
			skcipher_request_set_callback(subreq, req->base.flags,
1209
						      NULL, NULL);
1210
			skcipher_request_set_crypt(subreq, req->src, req->dst,
1211
						   req->cryptlen, req->iv);
1212
			ret = encrypt ? crypto_skcipher_encrypt(subreq)
1213
				      : crypto_skcipher_decrypt(subreq);
1214
			skcipher_request_zero(subreq);
1215
		}
1216
		return ret;
1217
	}
1218

1219
	return encrypt ? artpec6_crypto_encrypt(req)
1220
		       : artpec6_crypto_decrypt(req);
1221
}
1222

1223
static int artpec6_crypto_ctr_encrypt(struct skcipher_request *req)
1224
{
1225
	return artpec6_crypto_ctr_crypt(req, true);
1226
}
1227

1228
static int artpec6_crypto_ctr_decrypt(struct skcipher_request *req)
1229
{
1230
	return artpec6_crypto_ctr_crypt(req, false);
1231
}
1232

1233
/*
1234
 * AEAD functions
1235
 */
1236
static int artpec6_crypto_aead_init(struct crypto_aead *tfm)
1237
{
1238
	struct artpec6_cryptotfm_context *tfm_ctx = crypto_aead_ctx(tfm);
1239

1240
	memset(tfm_ctx, 0, sizeof(*tfm_ctx));
1241

1242
	crypto_aead_set_reqsize(tfm,
1243
				sizeof(struct artpec6_crypto_aead_req_ctx));
1244

1245
	return 0;
1246
}
1247

1248
static int artpec6_crypto_aead_set_key(struct crypto_aead *tfm, const u8 *key,
1249
			       unsigned int len)
1250
{
1251
	struct artpec6_cryptotfm_context *ctx = crypto_tfm_ctx(&tfm->base);
1252

1253
	if (len != 16 && len != 24 && len != 32)
1254
		return -EINVAL;
1255

1256
	ctx->key_length = len;
1257

1258
	memcpy(ctx->aes_key, key, len);
1259
	return 0;
1260
}
1261

1262
static int artpec6_crypto_aead_encrypt(struct aead_request *req)
1263
{
1264
	int ret;
1265
	struct artpec6_crypto_aead_req_ctx *req_ctx = aead_request_ctx(req);
1266

1267
	req_ctx->decrypt = false;
1268
	ret = artpec6_crypto_common_init(&req_ctx->common, &req->base,
1269
				  artpec6_crypto_complete_aead,
1270
				  NULL, 0);
1271
	if (ret)
1272
		return ret;
1273

1274
	ret = artpec6_crypto_prepare_aead(req);
1275
	if (ret) {
1276
		artpec6_crypto_common_destroy(&req_ctx->common);
1277
		return ret;
1278
	}
1279

1280
	return artpec6_crypto_submit(&req_ctx->common);
1281
}
1282

1283
static int artpec6_crypto_aead_decrypt(struct aead_request *req)
1284
{
1285
	int ret;
1286
	struct artpec6_crypto_aead_req_ctx *req_ctx = aead_request_ctx(req);
1287

1288
	req_ctx->decrypt = true;
1289
	if (req->cryptlen < AES_BLOCK_SIZE)
1290
		return -EINVAL;
1291

1292
	ret = artpec6_crypto_common_init(&req_ctx->common,
1293
				  &req->base,
1294
				  artpec6_crypto_complete_aead,
1295
				  NULL, 0);
1296
	if (ret)
1297
		return ret;
1298

1299
	ret = artpec6_crypto_prepare_aead(req);
1300
	if (ret) {
1301
		artpec6_crypto_common_destroy(&req_ctx->common);
1302
		return ret;
1303
	}
1304

1305
	return artpec6_crypto_submit(&req_ctx->common);
1306
}
1307

1308
static int artpec6_crypto_prepare_hash(struct ahash_request *areq)
1309
{
1310
	struct artpec6_hashalg_context *ctx = crypto_tfm_ctx(areq->base.tfm);
1311
	struct artpec6_hash_request_context *req_ctx = ahash_request_ctx(areq);
1312
	size_t digestsize = crypto_ahash_digestsize(crypto_ahash_reqtfm(areq));
1313
	size_t contextsize = digestsize;
1314
	size_t blocksize = crypto_tfm_alg_blocksize(
1315
		crypto_ahash_tfm(crypto_ahash_reqtfm(areq)));
1316
	struct artpec6_crypto_req_common *common = &req_ctx->common;
1317
	struct artpec6_crypto *ac = dev_get_drvdata(artpec6_crypto_dev);
1318
	enum artpec6_crypto_variant variant = ac->variant;
1319
	u32 sel_ctx;
1320
	bool ext_ctx = false;
1321
	bool run_hw = false;
1322
	int error = 0;
1323

1324
	artpec6_crypto_init_dma_operation(common);
1325

1326
	/* Upload HMAC key, must be first the first packet */
1327
	if (req_ctx->hash_flags & HASH_FLAG_HMAC) {
1328
		if (variant == ARTPEC6_CRYPTO) {
1329
			req_ctx->key_md = FIELD_PREP(A6_CRY_MD_OPER,
1330
						     a6_regk_crypto_dlkey);
1331
		} else {
1332
			req_ctx->key_md = FIELD_PREP(A7_CRY_MD_OPER,
1333
						     a7_regk_crypto_dlkey);
1334
		}
1335

1336
		/* Copy and pad up the key */
1337
		memcpy(req_ctx->key_buffer, ctx->hmac_key,
1338
		       ctx->hmac_key_length);
1339
		memset(req_ctx->key_buffer + ctx->hmac_key_length, 0,
1340
		       blocksize - ctx->hmac_key_length);
1341

1342
		error = artpec6_crypto_setup_out_descr(common,
1343
					(void *)&req_ctx->key_md,
1344
					sizeof(req_ctx->key_md), false, false);
1345
		if (error)
1346
			return error;
1347

1348
		error = artpec6_crypto_setup_out_descr(common,
1349
					req_ctx->key_buffer, blocksize,
1350
					true, false);
1351
		if (error)
1352
			return error;
1353
	}
1354

1355
	if (!(req_ctx->hash_flags & HASH_FLAG_INIT_CTX)) {
1356
		/* Restore context */
1357
		sel_ctx = regk_crypto_ext;
1358
		ext_ctx = true;
1359
	} else {
1360
		sel_ctx = regk_crypto_init;
1361
	}
1362

1363
	if (variant == ARTPEC6_CRYPTO) {
1364
		req_ctx->hash_md &= ~A6_CRY_MD_HASH_SEL_CTX;
1365
		req_ctx->hash_md |= FIELD_PREP(A6_CRY_MD_HASH_SEL_CTX, sel_ctx);
1366

1367
		/* If this is the final round, set the final flag */
1368
		if (req_ctx->hash_flags & HASH_FLAG_FINALIZE)
1369
			req_ctx->hash_md |= A6_CRY_MD_HASH_HMAC_FIN;
1370
	} else {
1371
		req_ctx->hash_md &= ~A7_CRY_MD_HASH_SEL_CTX;
1372
		req_ctx->hash_md |= FIELD_PREP(A7_CRY_MD_HASH_SEL_CTX, sel_ctx);
1373

1374
		/* If this is the final round, set the final flag */
1375
		if (req_ctx->hash_flags & HASH_FLAG_FINALIZE)
1376
			req_ctx->hash_md |= A7_CRY_MD_HASH_HMAC_FIN;
1377
	}
1378

1379
	/* Setup up metadata descriptors */
1380
	error = artpec6_crypto_setup_out_descr(common,
1381
				(void *)&req_ctx->hash_md,
1382
				sizeof(req_ctx->hash_md), false, false);
1383
	if (error)
1384
		return error;
1385

1386
	error = artpec6_crypto_setup_in_descr(common, ac->pad_buffer, 4, false);
1387
	if (error)
1388
		return error;
1389

1390
	if (ext_ctx) {
1391
		error = artpec6_crypto_setup_out_descr(common,
1392
					req_ctx->digeststate,
1393
					contextsize, false, false);
1394

1395
		if (error)
1396
			return error;
1397
	}
1398

1399
	if (req_ctx->hash_flags & HASH_FLAG_UPDATE) {
1400
		size_t done_bytes = 0;
1401
		size_t total_bytes = areq->nbytes + req_ctx->partial_bytes;
1402
		size_t ready_bytes = round_down(total_bytes, blocksize);
1403
		struct artpec6_crypto_walk walk;
1404

1405
		run_hw = ready_bytes > 0;
1406
		if (req_ctx->partial_bytes && ready_bytes) {
1407
			/* We have a partial buffer and will at least some bytes
1408
			 * to the HW. Empty this partial buffer before tackling
1409
			 * the SG lists
1410
			 */
1411
			memcpy(req_ctx->partial_buffer_out,
1412
				req_ctx->partial_buffer,
1413
				req_ctx->partial_bytes);
1414

1415
			error = artpec6_crypto_setup_out_descr(common,
1416
						req_ctx->partial_buffer_out,
1417
						req_ctx->partial_bytes,
1418
						false, true);
1419
			if (error)
1420
				return error;
1421

1422
			/* Reset partial buffer */
1423
			done_bytes += req_ctx->partial_bytes;
1424
			req_ctx->partial_bytes = 0;
1425
		}
1426

1427
		artpec6_crypto_walk_init(&walk, areq->src);
1428

1429
		error = artpec6_crypto_setup_sg_descrs_out(common, &walk,
1430
							   ready_bytes -
1431
							   done_bytes);
1432
		if (error)
1433
			return error;
1434

1435
		if (walk.sg) {
1436
			size_t sg_skip = ready_bytes - done_bytes;
1437
			size_t sg_rem = areq->nbytes - sg_skip;
1438

1439
			sg_pcopy_to_buffer(areq->src, sg_nents(areq->src),
1440
					   req_ctx->partial_buffer +
1441
					   req_ctx->partial_bytes,
1442
					   sg_rem, sg_skip);
1443

1444
			req_ctx->partial_bytes += sg_rem;
1445
		}
1446

1447
		req_ctx->digcnt += ready_bytes;
1448
		req_ctx->hash_flags &= ~(HASH_FLAG_UPDATE);
1449
	}
1450

1451
	/* Finalize */
1452
	if (req_ctx->hash_flags & HASH_FLAG_FINALIZE) {
1453
		size_t hash_pad_len;
1454
		u64 digest_bits;
1455
		u32 oper;
1456

1457
		if (variant == ARTPEC6_CRYPTO)
1458
			oper = FIELD_GET(A6_CRY_MD_OPER, req_ctx->hash_md);
1459
		else
1460
			oper = FIELD_GET(A7_CRY_MD_OPER, req_ctx->hash_md);
1461

1462
		/* Write out the partial buffer if present */
1463
		if (req_ctx->partial_bytes) {
1464
			memcpy(req_ctx->partial_buffer_out,
1465
			       req_ctx->partial_buffer,
1466
			       req_ctx->partial_bytes);
1467
			error = artpec6_crypto_setup_out_descr(common,
1468
						req_ctx->partial_buffer_out,
1469
						req_ctx->partial_bytes,
1470
						false, true);
1471
			if (error)
1472
				return error;
1473

1474
			req_ctx->digcnt += req_ctx->partial_bytes;
1475
			req_ctx->partial_bytes = 0;
1476
		}
1477

1478
		if (req_ctx->hash_flags & HASH_FLAG_HMAC)
1479
			digest_bits = 8 * (req_ctx->digcnt + blocksize);
1480
		else
1481
			digest_bits = 8 * req_ctx->digcnt;
1482

1483
		/* Add the hash pad */
1484
		hash_pad_len = create_hash_pad(oper, req_ctx->pad_buffer,
1485
					       req_ctx->digcnt, digest_bits);
1486
		error = artpec6_crypto_setup_out_descr(common,
1487
						      req_ctx->pad_buffer,
1488
						      hash_pad_len, false,
1489
						      true);
1490
		req_ctx->digcnt = 0;
1491

1492
		if (error)
1493
			return error;
1494

1495
		/* Descriptor for the final result */
1496
		error = artpec6_crypto_setup_in_descr(common, areq->result,
1497
						      digestsize,
1498
						      true);
1499
		if (error)
1500
			return error;
1501

1502
	} else { /* This is not the final operation for this request */
1503
		if (!run_hw)
1504
			return ARTPEC6_CRYPTO_PREPARE_HASH_NO_START;
1505

1506
		/* Save the result to the context */
1507
		error = artpec6_crypto_setup_in_descr(common,
1508
						      req_ctx->digeststate,
1509
						      contextsize, false);
1510
		if (error)
1511
			return error;
1512
		/* fall through */
1513
	}
1514

1515
	req_ctx->hash_flags &= ~(HASH_FLAG_INIT_CTX | HASH_FLAG_UPDATE |
1516
				 HASH_FLAG_FINALIZE);
1517

1518
	error = artpec6_crypto_terminate_in_descrs(common);
1519
	if (error)
1520
		return error;
1521

1522
	error = artpec6_crypto_terminate_out_descrs(common);
1523
	if (error)
1524
		return error;
1525

1526
	error = artpec6_crypto_dma_map_descs(common);
1527
	if (error)
1528
		return error;
1529

1530
	return ARTPEC6_CRYPTO_PREPARE_HASH_START;
1531
}
1532

1533

1534
static int artpec6_crypto_aes_ecb_init(struct crypto_skcipher *tfm)
1535
{
1536
	struct artpec6_cryptotfm_context *ctx = crypto_skcipher_ctx(tfm);
1537

1538
	crypto_skcipher_set_reqsize(tfm,
1539
				    sizeof(struct artpec6_crypto_request_context));
1540
	ctx->crypto_type = ARTPEC6_CRYPTO_CIPHER_AES_ECB;
1541

1542
	return 0;
1543
}
1544

1545
static int artpec6_crypto_aes_ctr_init(struct crypto_skcipher *tfm)
1546
{
1547
	struct artpec6_cryptotfm_context *ctx = crypto_skcipher_ctx(tfm);
1548

1549
	ctx->fallback =
1550
		crypto_alloc_sync_skcipher(crypto_tfm_alg_name(&tfm->base),
1551
					   0, CRYPTO_ALG_NEED_FALLBACK);
1552
	if (IS_ERR(ctx->fallback))
1553
		return PTR_ERR(ctx->fallback);
1554

1555
	crypto_skcipher_set_reqsize(tfm,
1556
				    sizeof(struct artpec6_crypto_request_context));
1557
	ctx->crypto_type = ARTPEC6_CRYPTO_CIPHER_AES_CTR;
1558

1559
	return 0;
1560
}
1561

1562
static int artpec6_crypto_aes_cbc_init(struct crypto_skcipher *tfm)
1563
{
1564
	struct artpec6_cryptotfm_context *ctx = crypto_skcipher_ctx(tfm);
1565

1566
	crypto_skcipher_set_reqsize(tfm,
1567
				    sizeof(struct artpec6_crypto_request_context));
1568
	ctx->crypto_type = ARTPEC6_CRYPTO_CIPHER_AES_CBC;
1569

1570
	return 0;
1571
}
1572

1573
static int artpec6_crypto_aes_xts_init(struct crypto_skcipher *tfm)
1574
{
1575
	struct artpec6_cryptotfm_context *ctx = crypto_skcipher_ctx(tfm);
1576

1577
	crypto_skcipher_set_reqsize(tfm,
1578
				    sizeof(struct artpec6_crypto_request_context));
1579
	ctx->crypto_type = ARTPEC6_CRYPTO_CIPHER_AES_XTS;
1580

1581
	return 0;
1582
}
1583

1584
static void artpec6_crypto_aes_exit(struct crypto_skcipher *tfm)
1585
{
1586
	struct artpec6_cryptotfm_context *ctx = crypto_skcipher_ctx(tfm);
1587

1588
	memset(ctx, 0, sizeof(*ctx));
1589
}
1590

1591
static void artpec6_crypto_aes_ctr_exit(struct crypto_skcipher *tfm)
1592
{
1593
	struct artpec6_cryptotfm_context *ctx = crypto_skcipher_ctx(tfm);
1594

1595
	crypto_free_sync_skcipher(ctx->fallback);
1596
	artpec6_crypto_aes_exit(tfm);
1597
}
1598

1599
static int
1600
artpec6_crypto_cipher_set_key(struct crypto_skcipher *cipher, const u8 *key,
1601
			      unsigned int keylen)
1602
{
1603
	struct artpec6_cryptotfm_context *ctx =
1604
		crypto_skcipher_ctx(cipher);
1605

1606
	switch (keylen) {
1607
	case 16:
1608
	case 24:
1609
	case 32:
1610
		break;
1611
	default:
1612
		return -EINVAL;
1613
	}
1614

1615
	memcpy(ctx->aes_key, key, keylen);
1616
	ctx->key_length = keylen;
1617
	return 0;
1618
}
1619

1620
static int
1621
artpec6_crypto_xts_set_key(struct crypto_skcipher *cipher, const u8 *key,
1622
			      unsigned int keylen)
1623
{
1624
	struct artpec6_cryptotfm_context *ctx =
1625
		crypto_skcipher_ctx(cipher);
1626
	int ret;
1627

1628
	ret = xts_verify_key(cipher, key, keylen);
1629
	if (ret)
1630
		return ret;
1631

1632
	switch (keylen) {
1633
	case 32:
1634
	case 48:
1635
	case 64:
1636
		break;
1637
	default:
1638
		return -EINVAL;
1639
	}
1640

1641
	memcpy(ctx->aes_key, key, keylen);
1642
	ctx->key_length = keylen;
1643
	return 0;
1644
}
1645

1646
/** artpec6_crypto_process_crypto - Prepare an async block cipher crypto request
1647
 *
1648
 * @req: The asynch request to process
1649
 *
1650
 * @return 0 if the dma job was successfully prepared
1651
 *	  <0 on error
1652
 *
1653
 * This function sets up the PDMA descriptors for a block cipher request.
1654
 *
1655
 * The required padding is added for AES-CTR using a statically defined
1656
 * buffer.
1657
 *
1658
 * The PDMA descriptor list will be as follows:
1659
 *
1660
 * OUT: [KEY_MD][KEY][EOP]<CIPHER_MD>[IV]<data_0>...[data_n][AES-CTR_pad]<eop>
1661
 * IN:  <CIPHER_MD><data_0>...[data_n]<intr>
1662
 *
1663
 */
1664
static int artpec6_crypto_prepare_crypto(struct skcipher_request *areq)
1665
{
1666
	int ret;
1667
	struct artpec6_crypto_walk walk;
1668
	struct crypto_skcipher *cipher = crypto_skcipher_reqtfm(areq);
1669
	struct artpec6_cryptotfm_context *ctx = crypto_skcipher_ctx(cipher);
1670
	struct artpec6_crypto_request_context *req_ctx = NULL;
1671
	size_t iv_len = crypto_skcipher_ivsize(cipher);
1672
	struct artpec6_crypto *ac = dev_get_drvdata(artpec6_crypto_dev);
1673
	enum artpec6_crypto_variant variant = ac->variant;
1674
	struct artpec6_crypto_req_common *common;
1675
	bool cipher_decr = false;
1676
	size_t cipher_klen;
1677
	u32 cipher_len = 0; /* Same as regk_crypto_key_128 for NULL crypto */
1678
	u32 oper;
1679

1680
	req_ctx = skcipher_request_ctx(areq);
1681
	common = &req_ctx->common;
1682

1683
	artpec6_crypto_init_dma_operation(common);
1684

1685
	if (variant == ARTPEC6_CRYPTO)
1686
		ctx->key_md = FIELD_PREP(A6_CRY_MD_OPER, a6_regk_crypto_dlkey);
1687
	else
1688
		ctx->key_md = FIELD_PREP(A7_CRY_MD_OPER, a7_regk_crypto_dlkey);
1689

1690
	ret = artpec6_crypto_setup_out_descr(common, (void *)&ctx->key_md,
1691
					     sizeof(ctx->key_md), false, false);
1692
	if (ret)
1693
		return ret;
1694

1695
	ret = artpec6_crypto_setup_out_descr(common, ctx->aes_key,
1696
					      ctx->key_length, true, false);
1697
	if (ret)
1698
		return ret;
1699

1700
	req_ctx->cipher_md = 0;
1701

1702
	if (ctx->crypto_type == ARTPEC6_CRYPTO_CIPHER_AES_XTS)
1703
		cipher_klen = ctx->key_length/2;
1704
	else
1705
		cipher_klen =  ctx->key_length;
1706

1707
	/* Metadata */
1708
	switch (cipher_klen) {
1709
	case 16:
1710
		cipher_len = regk_crypto_key_128;
1711
		break;
1712
	case 24:
1713
		cipher_len = regk_crypto_key_192;
1714
		break;
1715
	case 32:
1716
		cipher_len = regk_crypto_key_256;
1717
		break;
1718
	default:
1719
		pr_err("%s: Invalid key length %zu!\n",
1720
			MODULE_NAME, ctx->key_length);
1721
		return -EINVAL;
1722
	}
1723

1724
	switch (ctx->crypto_type) {
1725
	case ARTPEC6_CRYPTO_CIPHER_AES_ECB:
1726
		oper = regk_crypto_aes_ecb;
1727
		cipher_decr = req_ctx->decrypt;
1728
		break;
1729

1730
	case ARTPEC6_CRYPTO_CIPHER_AES_CBC:
1731
		oper = regk_crypto_aes_cbc;
1732
		cipher_decr = req_ctx->decrypt;
1733
		break;
1734

1735
	case ARTPEC6_CRYPTO_CIPHER_AES_CTR:
1736
		oper = regk_crypto_aes_ctr;
1737
		cipher_decr = false;
1738
		break;
1739

1740
	case ARTPEC6_CRYPTO_CIPHER_AES_XTS:
1741
		oper = regk_crypto_aes_xts;
1742
		cipher_decr = req_ctx->decrypt;
1743

1744
		if (variant == ARTPEC6_CRYPTO)
1745
			req_ctx->cipher_md |= A6_CRY_MD_CIPHER_DSEQ;
1746
		else
1747
			req_ctx->cipher_md |= A7_CRY_MD_CIPHER_DSEQ;
1748
		break;
1749

1750
	default:
1751
		pr_err("%s: Invalid cipher mode %d!\n",
1752
			MODULE_NAME, ctx->crypto_type);
1753
		return -EINVAL;
1754
	}
1755

1756
	if (variant == ARTPEC6_CRYPTO) {
1757
		req_ctx->cipher_md |= FIELD_PREP(A6_CRY_MD_OPER, oper);
1758
		req_ctx->cipher_md |= FIELD_PREP(A6_CRY_MD_CIPHER_LEN,
1759
						 cipher_len);
1760
		if (cipher_decr)
1761
			req_ctx->cipher_md |= A6_CRY_MD_CIPHER_DECR;
1762
	} else {
1763
		req_ctx->cipher_md |= FIELD_PREP(A7_CRY_MD_OPER, oper);
1764
		req_ctx->cipher_md |= FIELD_PREP(A7_CRY_MD_CIPHER_LEN,
1765
						 cipher_len);
1766
		if (cipher_decr)
1767
			req_ctx->cipher_md |= A7_CRY_MD_CIPHER_DECR;
1768
	}
1769

1770
	ret = artpec6_crypto_setup_out_descr(common,
1771
					    &req_ctx->cipher_md,
1772
					    sizeof(req_ctx->cipher_md),
1773
					    false, false);
1774
	if (ret)
1775
		return ret;
1776

1777
	ret = artpec6_crypto_setup_in_descr(common, ac->pad_buffer, 4, false);
1778
	if (ret)
1779
		return ret;
1780

1781
	if (iv_len) {
1782
		ret = artpec6_crypto_setup_out_descr(common, areq->iv, iv_len,
1783
						     false, false);
1784
		if (ret)
1785
			return ret;
1786
	}
1787
	/* Data out */
1788
	artpec6_crypto_walk_init(&walk, areq->src);
1789
	ret = artpec6_crypto_setup_sg_descrs_out(common, &walk, areq->cryptlen);
1790
	if (ret)
1791
		return ret;
1792

1793
	/* Data in */
1794
	artpec6_crypto_walk_init(&walk, areq->dst);
1795
	ret = artpec6_crypto_setup_sg_descrs_in(common, &walk, areq->cryptlen);
1796
	if (ret)
1797
		return ret;
1798

1799
	/* CTR-mode padding required by the HW. */
1800
	if (ctx->crypto_type == ARTPEC6_CRYPTO_CIPHER_AES_CTR ||
1801
	    ctx->crypto_type == ARTPEC6_CRYPTO_CIPHER_AES_XTS) {
1802
		size_t pad = ALIGN(areq->cryptlen, AES_BLOCK_SIZE) -
1803
			     areq->cryptlen;
1804

1805
		if (pad) {
1806
			ret = artpec6_crypto_setup_out_descr(common,
1807
							     ac->pad_buffer,
1808
							     pad, false, false);
1809
			if (ret)
1810
				return ret;
1811

1812
			ret = artpec6_crypto_setup_in_descr(common,
1813
							    ac->pad_buffer, pad,
1814
							    false);
1815
			if (ret)
1816
				return ret;
1817
		}
1818
	}
1819

1820
	ret = artpec6_crypto_terminate_out_descrs(common);
1821
	if (ret)
1822
		return ret;
1823

1824
	ret = artpec6_crypto_terminate_in_descrs(common);
1825
	if (ret)
1826
		return ret;
1827

1828
	return artpec6_crypto_dma_map_descs(common);
1829
}
1830

1831
static int artpec6_crypto_prepare_aead(struct aead_request *areq)
1832
{
1833
	size_t count;
1834
	int ret;
1835
	size_t input_length;
1836
	struct artpec6_cryptotfm_context *ctx = crypto_tfm_ctx(areq->base.tfm);
1837
	struct artpec6_crypto_aead_req_ctx *req_ctx = aead_request_ctx(areq);
1838
	struct crypto_aead *cipher = crypto_aead_reqtfm(areq);
1839
	struct artpec6_crypto_req_common *common = &req_ctx->common;
1840
	struct artpec6_crypto *ac = dev_get_drvdata(artpec6_crypto_dev);
1841
	enum artpec6_crypto_variant variant = ac->variant;
1842
	u32 md_cipher_len;
1843

1844
	artpec6_crypto_init_dma_operation(common);
1845

1846
	/* Key */
1847
	if (variant == ARTPEC6_CRYPTO) {
1848
		ctx->key_md = FIELD_PREP(A6_CRY_MD_OPER,
1849
					 a6_regk_crypto_dlkey);
1850
	} else {
1851
		ctx->key_md = FIELD_PREP(A7_CRY_MD_OPER,
1852
					 a7_regk_crypto_dlkey);
1853
	}
1854
	ret = artpec6_crypto_setup_out_descr(common, (void *)&ctx->key_md,
1855
					     sizeof(ctx->key_md), false, false);
1856
	if (ret)
1857
		return ret;
1858

1859
	ret = artpec6_crypto_setup_out_descr(common, ctx->aes_key,
1860
					     ctx->key_length, true, false);
1861
	if (ret)
1862
		return ret;
1863

1864
	req_ctx->cipher_md = 0;
1865

1866
	switch (ctx->key_length) {
1867
	case 16:
1868
		md_cipher_len = regk_crypto_key_128;
1869
		break;
1870
	case 24:
1871
		md_cipher_len = regk_crypto_key_192;
1872
		break;
1873
	case 32:
1874
		md_cipher_len = regk_crypto_key_256;
1875
		break;
1876
	default:
1877
		return -EINVAL;
1878
	}
1879

1880
	if (variant == ARTPEC6_CRYPTO) {
1881
		req_ctx->cipher_md |= FIELD_PREP(A6_CRY_MD_OPER,
1882
						 regk_crypto_aes_gcm);
1883
		req_ctx->cipher_md |= FIELD_PREP(A6_CRY_MD_CIPHER_LEN,
1884
						 md_cipher_len);
1885
		if (req_ctx->decrypt)
1886
			req_ctx->cipher_md |= A6_CRY_MD_CIPHER_DECR;
1887
	} else {
1888
		req_ctx->cipher_md |= FIELD_PREP(A7_CRY_MD_OPER,
1889
						 regk_crypto_aes_gcm);
1890
		req_ctx->cipher_md |= FIELD_PREP(A7_CRY_MD_CIPHER_LEN,
1891
						 md_cipher_len);
1892
		if (req_ctx->decrypt)
1893
			req_ctx->cipher_md |= A7_CRY_MD_CIPHER_DECR;
1894
	}
1895

1896
	ret = artpec6_crypto_setup_out_descr(common,
1897
					    (void *) &req_ctx->cipher_md,
1898
					    sizeof(req_ctx->cipher_md), false,
1899
					    false);
1900
	if (ret)
1901
		return ret;
1902

1903
	ret = artpec6_crypto_setup_in_descr(common, ac->pad_buffer, 4, false);
1904
	if (ret)
1905
		return ret;
1906

1907
	/* For the decryption, cryptlen includes the tag. */
1908
	input_length = areq->cryptlen;
1909
	if (req_ctx->decrypt)
1910
		input_length -= crypto_aead_authsize(cipher);
1911

1912
	/* Prepare the context buffer */
1913
	req_ctx->hw_ctx.aad_length_bits =
1914
		__cpu_to_be64(8*areq->assoclen);
1915

1916
	req_ctx->hw_ctx.text_length_bits =
1917
		__cpu_to_be64(8*input_length);
1918

1919
	memcpy(req_ctx->hw_ctx.J0, areq->iv, crypto_aead_ivsize(cipher));
1920
	// The HW omits the initial increment of the counter field.
1921
	memcpy(req_ctx->hw_ctx.J0 + GCM_AES_IV_SIZE, "\x00\x00\x00\x01", 4);
1922

1923
	ret = artpec6_crypto_setup_out_descr(common, &req_ctx->hw_ctx,
1924
		sizeof(struct artpec6_crypto_aead_hw_ctx), false, false);
1925
	if (ret)
1926
		return ret;
1927

1928
	{
1929
		struct artpec6_crypto_walk walk;
1930

1931
		artpec6_crypto_walk_init(&walk, areq->src);
1932

1933
		/* Associated data */
1934
		count = areq->assoclen;
1935
		ret = artpec6_crypto_setup_sg_descrs_out(common, &walk, count);
1936
		if (ret)
1937
			return ret;
1938

1939
		if (!IS_ALIGNED(areq->assoclen, 16)) {
1940
			size_t assoc_pad = 16 - (areq->assoclen % 16);
1941
			/* The HW mandates zero padding here */
1942
			ret = artpec6_crypto_setup_out_descr(common,
1943
							     ac->zero_buffer,
1944
							     assoc_pad, false,
1945
							     false);
1946
			if (ret)
1947
				return ret;
1948
		}
1949

1950
		/* Data to crypto */
1951
		count = input_length;
1952
		ret = artpec6_crypto_setup_sg_descrs_out(common, &walk, count);
1953
		if (ret)
1954
			return ret;
1955

1956
		if (!IS_ALIGNED(input_length, 16)) {
1957
			size_t crypto_pad = 16 - (input_length % 16);
1958
			/* The HW mandates zero padding here */
1959
			ret = artpec6_crypto_setup_out_descr(common,
1960
							     ac->zero_buffer,
1961
							     crypto_pad,
1962
							     false,
1963
							     false);
1964
			if (ret)
1965
				return ret;
1966
		}
1967
	}
1968

1969
	/* Data from crypto */
1970
	{
1971
		struct artpec6_crypto_walk walk;
1972
		size_t output_len = areq->cryptlen;
1973

1974
		if (req_ctx->decrypt)
1975
			output_len -= crypto_aead_authsize(cipher);
1976

1977
		artpec6_crypto_walk_init(&walk, areq->dst);
1978

1979
		/* skip associated data in the output */
1980
		count = artpec6_crypto_walk_advance(&walk, areq->assoclen);
1981
		if (count)
1982
			return -EINVAL;
1983

1984
		count = output_len;
1985
		ret = artpec6_crypto_setup_sg_descrs_in(common, &walk, count);
1986
		if (ret)
1987
			return ret;
1988

1989
		/* Put padding between the cryptotext and the auth tag */
1990
		if (!IS_ALIGNED(output_len, 16)) {
1991
			size_t crypto_pad = 16 - (output_len % 16);
1992

1993
			ret = artpec6_crypto_setup_in_descr(common,
1994
							    ac->pad_buffer,
1995
							    crypto_pad, false);
1996
			if (ret)
1997
				return ret;
1998
		}
1999

2000
		/* The authentication tag shall follow immediately after
2001
		 * the output ciphertext. For decryption it is put in a context
2002
		 * buffer for later compare against the input tag.
2003
		 */
2004

2005
		if (req_ctx->decrypt) {
2006
			ret = artpec6_crypto_setup_in_descr(common,
2007
				req_ctx->decryption_tag, AES_BLOCK_SIZE, false);
2008
			if (ret)
2009
				return ret;
2010

2011
		} else {
2012
			/* For encryption the requested tag size may be smaller
2013
			 * than the hardware's generated tag.
2014
			 */
2015
			size_t authsize = crypto_aead_authsize(cipher);
2016

2017
			ret = artpec6_crypto_setup_sg_descrs_in(common, &walk,
2018
								authsize);
2019
			if (ret)
2020
				return ret;
2021

2022
			if (authsize < AES_BLOCK_SIZE) {
2023
				count = AES_BLOCK_SIZE - authsize;
2024
				ret = artpec6_crypto_setup_in_descr(common,
2025
					ac->pad_buffer,
2026
					count, false);
2027
				if (ret)
2028
					return ret;
2029
			}
2030
		}
2031

2032
	}
2033

2034
	ret = artpec6_crypto_terminate_in_descrs(common);
2035
	if (ret)
2036
		return ret;
2037

2038
	ret = artpec6_crypto_terminate_out_descrs(common);
2039
	if (ret)
2040
		return ret;
2041

2042
	return artpec6_crypto_dma_map_descs(common);
2043
}
2044

2045
static void artpec6_crypto_process_queue(struct artpec6_crypto *ac,
2046
	    struct list_head *completions)
2047
{
2048
	struct artpec6_crypto_req_common *req;
2049

2050
	while (!list_empty(&ac->queue) && !artpec6_crypto_busy()) {
2051
		req = list_first_entry(&ac->queue,
2052
				       struct artpec6_crypto_req_common,
2053
				       list);
2054
		list_move_tail(&req->list, &ac->pending);
2055
		artpec6_crypto_start_dma(req);
2056

2057
		list_add_tail(&req->complete_in_progress, completions);
2058
	}
2059

2060
	/*
2061
	 * In some cases, the hardware can raise an in_eop_flush interrupt
2062
	 * before actually updating the status, so we have an timer which will
2063
	 * recheck the status on timeout.  Since the cases are expected to be
2064
	 * very rare, we use a relatively large timeout value.  There should be
2065
	 * no noticeable negative effect if we timeout spuriously.
2066
	 */
2067
	if (ac->pending_count)
2068
		mod_timer(&ac->timer, jiffies + msecs_to_jiffies(100));
2069
	else
2070
		timer_delete(&ac->timer);
2071
}
2072

2073
static void artpec6_crypto_timeout(struct timer_list *t)
2074
{
2075
	struct artpec6_crypto *ac = timer_container_of(ac, t, timer);
2076

2077
	dev_info_ratelimited(artpec6_crypto_dev, "timeout\n");
2078

2079
	tasklet_schedule(&ac->task);
2080
}
2081

2082
static void artpec6_crypto_task(unsigned long data)
2083
{
2084
	struct artpec6_crypto *ac = (struct artpec6_crypto *)data;
2085
	struct artpec6_crypto_req_common *req;
2086
	struct artpec6_crypto_req_common *n;
2087
	struct list_head complete_done;
2088
	struct list_head complete_in_progress;
2089

2090
	INIT_LIST_HEAD(&complete_done);
2091
	INIT_LIST_HEAD(&complete_in_progress);
2092

2093
	if (list_empty(&ac->pending)) {
2094
		pr_debug("Spurious IRQ\n");
2095
		return;
2096
	}
2097

2098
	spin_lock(&ac->queue_lock);
2099

2100
	list_for_each_entry_safe(req, n, &ac->pending, list) {
2101
		struct artpec6_crypto_dma_descriptors *dma = req->dma;
2102
		u32 stat;
2103
		dma_addr_t stataddr;
2104

2105
		stataddr = dma->stat_dma_addr + 4 * (req->dma->in_cnt - 1);
2106
		dma_sync_single_for_cpu(artpec6_crypto_dev,
2107
					stataddr,
2108
					4,
2109
					DMA_BIDIRECTIONAL);
2110

2111
		stat = req->dma->stat[req->dma->in_cnt-1];
2112

2113
		/* A non-zero final status descriptor indicates
2114
		 * this job has finished.
2115
		 */
2116
		pr_debug("Request %p status is %X\n", req, stat);
2117
		if (!stat)
2118
			break;
2119

2120
		/* Allow testing of timeout handling with fault injection */
2121
#ifdef CONFIG_FAULT_INJECTION
2122
		if (should_fail(&artpec6_crypto_fail_status_read, 1))
2123
			continue;
2124
#endif
2125

2126
		pr_debug("Completing request %p\n", req);
2127

2128
		list_move_tail(&req->list, &complete_done);
2129

2130
		ac->pending_count--;
2131
	}
2132

2133
	artpec6_crypto_process_queue(ac, &complete_in_progress);
2134

2135
	spin_unlock(&ac->queue_lock);
2136

2137
	/* Perform the completion callbacks without holding the queue lock
2138
	 * to allow new request submissions from the callbacks.
2139
	 */
2140
	list_for_each_entry_safe(req, n, &complete_done, list) {
2141
		artpec6_crypto_dma_unmap_all(req);
2142
		artpec6_crypto_copy_bounce_buffers(req);
2143
		artpec6_crypto_common_destroy(req);
2144

2145
		req->complete(req->req);
2146
	}
2147

2148
	list_for_each_entry_safe(req, n, &complete_in_progress,
2149
				 complete_in_progress) {
2150
		crypto_request_complete(req->req, -EINPROGRESS);
2151
	}
2152
}
2153

2154
static void artpec6_crypto_complete_crypto(struct crypto_async_request *req)
2155
{
2156
	crypto_request_complete(req, 0);
2157
}
2158

2159
static void
2160
artpec6_crypto_complete_cbc_decrypt(struct crypto_async_request *req)
2161
{
2162
	struct skcipher_request *cipher_req = container_of(req,
2163
		struct skcipher_request, base);
2164

2165
	scatterwalk_map_and_copy(cipher_req->iv, cipher_req->src,
2166
				 cipher_req->cryptlen - AES_BLOCK_SIZE,
2167
				 AES_BLOCK_SIZE, 0);
2168
	skcipher_request_complete(cipher_req, 0);
2169
}
2170

2171
static void
2172
artpec6_crypto_complete_cbc_encrypt(struct crypto_async_request *req)
2173
{
2174
	struct skcipher_request *cipher_req = container_of(req,
2175
		struct skcipher_request, base);
2176

2177
	scatterwalk_map_and_copy(cipher_req->iv, cipher_req->dst,
2178
				 cipher_req->cryptlen - AES_BLOCK_SIZE,
2179
				 AES_BLOCK_SIZE, 0);
2180
	skcipher_request_complete(cipher_req, 0);
2181
}
2182

2183
static void artpec6_crypto_complete_aead(struct crypto_async_request *req)
2184
{
2185
	int result = 0;
2186

2187
	/* Verify GCM hashtag. */
2188
	struct aead_request *areq = container_of(req,
2189
		struct aead_request, base);
2190
	struct crypto_aead *aead = crypto_aead_reqtfm(areq);
2191
	struct artpec6_crypto_aead_req_ctx *req_ctx = aead_request_ctx(areq);
2192

2193
	if (req_ctx->decrypt) {
2194
		u8 input_tag[AES_BLOCK_SIZE];
2195
		unsigned int authsize = crypto_aead_authsize(aead);
2196

2197
		sg_pcopy_to_buffer(areq->src,
2198
				   sg_nents(areq->src),
2199
				   input_tag,
2200
				   authsize,
2201
				   areq->assoclen + areq->cryptlen -
2202
				   authsize);
2203

2204
		if (crypto_memneq(req_ctx->decryption_tag,
2205
				  input_tag,
2206
				  authsize)) {
2207
			pr_debug("***EBADMSG:\n");
2208
			print_hex_dump_debug("ref:", DUMP_PREFIX_ADDRESS, 32, 1,
2209
					     input_tag, authsize, true);
2210
			print_hex_dump_debug("out:", DUMP_PREFIX_ADDRESS, 32, 1,
2211
					     req_ctx->decryption_tag,
2212
					     authsize, true);
2213

2214
			result = -EBADMSG;
2215
		}
2216
	}
2217

2218
	aead_request_complete(areq, result);
2219
}
2220

2221
static void artpec6_crypto_complete_hash(struct crypto_async_request *req)
2222
{
2223
	crypto_request_complete(req, 0);
2224
}
2225

2226

2227
/*------------------- Hash functions -----------------------------------------*/
2228
static int
2229
artpec6_crypto_hash_set_key(struct crypto_ahash *tfm,
2230
		    const u8 *key, unsigned int keylen)
2231
{
2232
	struct artpec6_hashalg_context *tfm_ctx = crypto_tfm_ctx(&tfm->base);
2233
	size_t blocksize;
2234
	int ret;
2235

2236
	if (!keylen) {
2237
		pr_err("Invalid length (%d) of HMAC key\n",
2238
			keylen);
2239
		return -EINVAL;
2240
	}
2241

2242
	memset(tfm_ctx->hmac_key, 0, sizeof(tfm_ctx->hmac_key));
2243

2244
	blocksize = crypto_tfm_alg_blocksize(crypto_ahash_tfm(tfm));
2245

2246
	if (keylen > blocksize) {
2247
		tfm_ctx->hmac_key_length = blocksize;
2248

2249
		ret = crypto_shash_tfm_digest(tfm_ctx->child_hash, key, keylen,
2250
					      tfm_ctx->hmac_key);
2251
		if (ret)
2252
			return ret;
2253
	} else {
2254
		memcpy(tfm_ctx->hmac_key, key, keylen);
2255
		tfm_ctx->hmac_key_length = keylen;
2256
	}
2257

2258
	return 0;
2259
}
2260

2261
static int
2262
artpec6_crypto_init_hash(struct ahash_request *req, u8 type, int hmac)
2263
{
2264
	struct artpec6_crypto *ac = dev_get_drvdata(artpec6_crypto_dev);
2265
	enum artpec6_crypto_variant variant = ac->variant;
2266
	struct artpec6_hash_request_context *req_ctx = ahash_request_ctx(req);
2267
	u32 oper;
2268

2269
	memset(req_ctx, 0, sizeof(*req_ctx));
2270

2271
	req_ctx->hash_flags = HASH_FLAG_INIT_CTX;
2272
	if (hmac)
2273
		req_ctx->hash_flags |= (HASH_FLAG_HMAC | HASH_FLAG_UPDATE_KEY);
2274

2275
	switch (type) {
2276
	case ARTPEC6_CRYPTO_HASH_SHA1:
2277
		oper = hmac ? regk_crypto_hmac_sha1 : regk_crypto_sha1;
2278
		break;
2279
	case ARTPEC6_CRYPTO_HASH_SHA256:
2280
		oper = hmac ? regk_crypto_hmac_sha256 : regk_crypto_sha256;
2281
		break;
2282
	default:
2283
		pr_err("%s: Unsupported hash type 0x%x\n", MODULE_NAME, type);
2284
		return -EINVAL;
2285
	}
2286

2287
	if (variant == ARTPEC6_CRYPTO)
2288
		req_ctx->hash_md = FIELD_PREP(A6_CRY_MD_OPER, oper);
2289
	else
2290
		req_ctx->hash_md = FIELD_PREP(A7_CRY_MD_OPER, oper);
2291

2292
	return 0;
2293
}
2294

2295
static int artpec6_crypto_prepare_submit_hash(struct ahash_request *req)
2296
{
2297
	struct artpec6_hash_request_context *req_ctx = ahash_request_ctx(req);
2298
	int ret;
2299

2300
	if (!req_ctx->common.dma) {
2301
		ret = artpec6_crypto_common_init(&req_ctx->common,
2302
					  &req->base,
2303
					  artpec6_crypto_complete_hash,
2304
					  NULL, 0);
2305

2306
		if (ret)
2307
			return ret;
2308
	}
2309

2310
	ret = artpec6_crypto_prepare_hash(req);
2311
	switch (ret) {
2312
	case ARTPEC6_CRYPTO_PREPARE_HASH_START:
2313
		ret = artpec6_crypto_submit(&req_ctx->common);
2314
		break;
2315

2316
	case ARTPEC6_CRYPTO_PREPARE_HASH_NO_START:
2317
		ret = 0;
2318
		fallthrough;
2319

2320
	default:
2321
		artpec6_crypto_common_destroy(&req_ctx->common);
2322
		break;
2323
	}
2324

2325
	return ret;
2326
}
2327

2328
static int artpec6_crypto_hash_final(struct ahash_request *req)
2329
{
2330
	struct artpec6_hash_request_context *req_ctx = ahash_request_ctx(req);
2331

2332
	req_ctx->hash_flags |= HASH_FLAG_FINALIZE;
2333

2334
	return artpec6_crypto_prepare_submit_hash(req);
2335
}
2336

2337
static int artpec6_crypto_hash_update(struct ahash_request *req)
2338
{
2339
	struct artpec6_hash_request_context *req_ctx = ahash_request_ctx(req);
2340

2341
	req_ctx->hash_flags |= HASH_FLAG_UPDATE;
2342

2343
	return artpec6_crypto_prepare_submit_hash(req);
2344
}
2345

2346
static int artpec6_crypto_sha1_init(struct ahash_request *req)
2347
{
2348
	return artpec6_crypto_init_hash(req, ARTPEC6_CRYPTO_HASH_SHA1, 0);
2349
}
2350

2351
static int artpec6_crypto_sha1_digest(struct ahash_request *req)
2352
{
2353
	struct artpec6_hash_request_context *req_ctx = ahash_request_ctx(req);
2354

2355
	artpec6_crypto_init_hash(req, ARTPEC6_CRYPTO_HASH_SHA1, 0);
2356

2357
	req_ctx->hash_flags |= HASH_FLAG_UPDATE | HASH_FLAG_FINALIZE;
2358

2359
	return artpec6_crypto_prepare_submit_hash(req);
2360
}
2361

2362
static int artpec6_crypto_sha256_init(struct ahash_request *req)
2363
{
2364
	return artpec6_crypto_init_hash(req, ARTPEC6_CRYPTO_HASH_SHA256, 0);
2365
}
2366

2367
static int artpec6_crypto_sha256_digest(struct ahash_request *req)
2368
{
2369
	struct artpec6_hash_request_context *req_ctx = ahash_request_ctx(req);
2370

2371
	artpec6_crypto_init_hash(req, ARTPEC6_CRYPTO_HASH_SHA256, 0);
2372
	req_ctx->hash_flags |= HASH_FLAG_UPDATE | HASH_FLAG_FINALIZE;
2373

2374
	return artpec6_crypto_prepare_submit_hash(req);
2375
}
2376

2377
static int artpec6_crypto_hmac_sha256_init(struct ahash_request *req)
2378
{
2379
	return artpec6_crypto_init_hash(req, ARTPEC6_CRYPTO_HASH_SHA256, 1);
2380
}
2381

2382
static int artpec6_crypto_hmac_sha256_digest(struct ahash_request *req)
2383
{
2384
	struct artpec6_hash_request_context *req_ctx = ahash_request_ctx(req);
2385

2386
	artpec6_crypto_init_hash(req, ARTPEC6_CRYPTO_HASH_SHA256, 1);
2387
	req_ctx->hash_flags |= HASH_FLAG_UPDATE | HASH_FLAG_FINALIZE;
2388

2389
	return artpec6_crypto_prepare_submit_hash(req);
2390
}
2391

2392
static int artpec6_crypto_ahash_init_common(struct crypto_tfm *tfm,
2393
				    const char *base_hash_name)
2394
{
2395
	struct artpec6_hashalg_context *tfm_ctx = crypto_tfm_ctx(tfm);
2396

2397
	crypto_ahash_set_reqsize(__crypto_ahash_cast(tfm),
2398
				 sizeof(struct artpec6_hash_request_context));
2399
	memset(tfm_ctx, 0, sizeof(*tfm_ctx));
2400

2401
	if (base_hash_name) {
2402
		struct crypto_shash *child;
2403

2404
		child = crypto_alloc_shash(base_hash_name, 0,
2405
					   CRYPTO_ALG_NEED_FALLBACK);
2406

2407
		if (IS_ERR(child))
2408
			return PTR_ERR(child);
2409

2410
		tfm_ctx->child_hash = child;
2411
	}
2412

2413
	return 0;
2414
}
2415

2416
static int artpec6_crypto_ahash_init(struct crypto_tfm *tfm)
2417
{
2418
	return artpec6_crypto_ahash_init_common(tfm, NULL);
2419
}
2420

2421
static int artpec6_crypto_ahash_init_hmac_sha256(struct crypto_tfm *tfm)
2422
{
2423
	return artpec6_crypto_ahash_init_common(tfm, "sha256");
2424
}
2425

2426
static void artpec6_crypto_ahash_exit(struct crypto_tfm *tfm)
2427
{
2428
	struct artpec6_hashalg_context *tfm_ctx = crypto_tfm_ctx(tfm);
2429

2430
	if (tfm_ctx->child_hash)
2431
		crypto_free_shash(tfm_ctx->child_hash);
2432

2433
	memset(tfm_ctx->hmac_key, 0, sizeof(tfm_ctx->hmac_key));
2434
	tfm_ctx->hmac_key_length = 0;
2435
}
2436

2437
static int artpec6_crypto_hash_export(struct ahash_request *req, void *out)
2438
{
2439
	const struct artpec6_hash_request_context *ctx = ahash_request_ctx(req);
2440
	struct artpec6_hash_export_state *state = out;
2441
	struct artpec6_crypto *ac = dev_get_drvdata(artpec6_crypto_dev);
2442
	enum artpec6_crypto_variant variant = ac->variant;
2443

2444
	BUILD_BUG_ON(sizeof(state->partial_buffer) !=
2445
		     sizeof(ctx->partial_buffer));
2446
	BUILD_BUG_ON(sizeof(state->digeststate) != sizeof(ctx->digeststate));
2447

2448
	state->digcnt = ctx->digcnt;
2449
	state->partial_bytes = ctx->partial_bytes;
2450
	state->hash_flags = ctx->hash_flags;
2451

2452
	if (variant == ARTPEC6_CRYPTO)
2453
		state->oper = FIELD_GET(A6_CRY_MD_OPER, ctx->hash_md);
2454
	else
2455
		state->oper = FIELD_GET(A7_CRY_MD_OPER, ctx->hash_md);
2456

2457
	memcpy(state->partial_buffer, ctx->partial_buffer,
2458
	       sizeof(state->partial_buffer));
2459
	memcpy(state->digeststate, ctx->digeststate,
2460
	       sizeof(state->digeststate));
2461

2462
	return 0;
2463
}
2464

2465
static int artpec6_crypto_hash_import(struct ahash_request *req, const void *in)
2466
{
2467
	struct artpec6_hash_request_context *ctx = ahash_request_ctx(req);
2468
	const struct artpec6_hash_export_state *state = in;
2469
	struct artpec6_crypto *ac = dev_get_drvdata(artpec6_crypto_dev);
2470
	enum artpec6_crypto_variant variant = ac->variant;
2471

2472
	memset(ctx, 0, sizeof(*ctx));
2473

2474
	ctx->digcnt = state->digcnt;
2475
	ctx->partial_bytes = state->partial_bytes;
2476
	ctx->hash_flags = state->hash_flags;
2477

2478
	if (variant == ARTPEC6_CRYPTO)
2479
		ctx->hash_md = FIELD_PREP(A6_CRY_MD_OPER, state->oper);
2480
	else
2481
		ctx->hash_md = FIELD_PREP(A7_CRY_MD_OPER, state->oper);
2482

2483
	memcpy(ctx->partial_buffer, state->partial_buffer,
2484
	       sizeof(state->partial_buffer));
2485
	memcpy(ctx->digeststate, state->digeststate,
2486
	       sizeof(state->digeststate));
2487

2488
	return 0;
2489
}
2490

2491
static int init_crypto_hw(struct artpec6_crypto *ac)
2492
{
2493
	enum artpec6_crypto_variant variant = ac->variant;
2494
	void __iomem *base = ac->base;
2495
	u32 out_descr_buf_size;
2496
	u32 out_data_buf_size;
2497
	u32 in_data_buf_size;
2498
	u32 in_descr_buf_size;
2499
	u32 in_stat_buf_size;
2500
	u32 in, out;
2501

2502
	/*
2503
	 * The PDMA unit contains 1984 bytes of internal memory for the OUT
2504
	 * channels and 1024 bytes for the IN channel. This is an elastic
2505
	 * memory used to internally store the descriptors and data. The values
2506
	 * ares specified in 64 byte incremements.  Trustzone buffers are not
2507
	 * used at this stage.
2508
	 */
2509
	out_data_buf_size = 16;  /* 1024 bytes for data */
2510
	out_descr_buf_size = 15; /* 960 bytes for descriptors */
2511
	in_data_buf_size = 8;    /* 512 bytes for data */
2512
	in_descr_buf_size = 4;   /* 256 bytes for descriptors */
2513
	in_stat_buf_size = 4;   /* 256 bytes for stat descrs */
2514

2515
	BUILD_BUG_ON_MSG((out_data_buf_size
2516
				+ out_descr_buf_size) * 64 > 1984,
2517
			  "Invalid OUT configuration");
2518

2519
	BUILD_BUG_ON_MSG((in_data_buf_size
2520
				+ in_descr_buf_size
2521
				+ in_stat_buf_size) * 64 > 1024,
2522
			  "Invalid IN configuration");
2523

2524
	in = FIELD_PREP(PDMA_IN_BUF_CFG_DATA_BUF_SIZE, in_data_buf_size) |
2525
	     FIELD_PREP(PDMA_IN_BUF_CFG_DESCR_BUF_SIZE, in_descr_buf_size) |
2526
	     FIELD_PREP(PDMA_IN_BUF_CFG_STAT_BUF_SIZE, in_stat_buf_size);
2527

2528
	out = FIELD_PREP(PDMA_OUT_BUF_CFG_DATA_BUF_SIZE, out_data_buf_size) |
2529
	      FIELD_PREP(PDMA_OUT_BUF_CFG_DESCR_BUF_SIZE, out_descr_buf_size);
2530

2531
	writel_relaxed(out, base + PDMA_OUT_BUF_CFG);
2532
	writel_relaxed(PDMA_OUT_CFG_EN, base + PDMA_OUT_CFG);
2533

2534
	if (variant == ARTPEC6_CRYPTO) {
2535
		writel_relaxed(in, base + A6_PDMA_IN_BUF_CFG);
2536
		writel_relaxed(PDMA_IN_CFG_EN, base + A6_PDMA_IN_CFG);
2537
		writel_relaxed(A6_PDMA_INTR_MASK_IN_DATA |
2538
			       A6_PDMA_INTR_MASK_IN_EOP_FLUSH,
2539
			       base + A6_PDMA_INTR_MASK);
2540
	} else {
2541
		writel_relaxed(in, base + A7_PDMA_IN_BUF_CFG);
2542
		writel_relaxed(PDMA_IN_CFG_EN, base + A7_PDMA_IN_CFG);
2543
		writel_relaxed(A7_PDMA_INTR_MASK_IN_DATA |
2544
			       A7_PDMA_INTR_MASK_IN_EOP_FLUSH,
2545
			       base + A7_PDMA_INTR_MASK);
2546
	}
2547

2548
	return 0;
2549
}
2550

2551
static void artpec6_crypto_disable_hw(struct artpec6_crypto *ac)
2552
{
2553
	enum artpec6_crypto_variant variant = ac->variant;
2554
	void __iomem *base = ac->base;
2555

2556
	if (variant == ARTPEC6_CRYPTO) {
2557
		writel_relaxed(A6_PDMA_IN_CMD_STOP, base + A6_PDMA_IN_CMD);
2558
		writel_relaxed(0, base + A6_PDMA_IN_CFG);
2559
		writel_relaxed(A6_PDMA_OUT_CMD_STOP, base + PDMA_OUT_CMD);
2560
	} else {
2561
		writel_relaxed(A7_PDMA_IN_CMD_STOP, base + A7_PDMA_IN_CMD);
2562
		writel_relaxed(0, base + A7_PDMA_IN_CFG);
2563
		writel_relaxed(A7_PDMA_OUT_CMD_STOP, base + PDMA_OUT_CMD);
2564
	}
2565

2566
	writel_relaxed(0, base + PDMA_OUT_CFG);
2567

2568
}
2569

2570
static irqreturn_t artpec6_crypto_irq(int irq, void *dev_id)
2571
{
2572
	struct artpec6_crypto *ac = dev_id;
2573
	enum artpec6_crypto_variant variant = ac->variant;
2574
	void __iomem *base = ac->base;
2575
	u32 mask_in_data, mask_in_eop_flush;
2576
	u32 in_cmd_flush_stat, in_cmd_reg;
2577
	u32 ack_intr_reg;
2578
	u32 ack = 0;
2579
	u32 intr;
2580

2581
	if (variant == ARTPEC6_CRYPTO) {
2582
		intr = readl_relaxed(base + A6_PDMA_MASKED_INTR);
2583
		mask_in_data = A6_PDMA_INTR_MASK_IN_DATA;
2584
		mask_in_eop_flush = A6_PDMA_INTR_MASK_IN_EOP_FLUSH;
2585
		in_cmd_flush_stat = A6_PDMA_IN_CMD_FLUSH_STAT;
2586
		in_cmd_reg = A6_PDMA_IN_CMD;
2587
		ack_intr_reg = A6_PDMA_ACK_INTR;
2588
	} else {
2589
		intr = readl_relaxed(base + A7_PDMA_MASKED_INTR);
2590
		mask_in_data = A7_PDMA_INTR_MASK_IN_DATA;
2591
		mask_in_eop_flush = A7_PDMA_INTR_MASK_IN_EOP_FLUSH;
2592
		in_cmd_flush_stat = A7_PDMA_IN_CMD_FLUSH_STAT;
2593
		in_cmd_reg = A7_PDMA_IN_CMD;
2594
		ack_intr_reg = A7_PDMA_ACK_INTR;
2595
	}
2596

2597
	/* We get two interrupt notifications from each job.
2598
	 * The in_data means all data was sent to memory and then
2599
	 * we request a status flush command to write the per-job
2600
	 * status to its status vector. This ensures that the
2601
	 * tasklet can detect exactly how many submitted jobs
2602
	 * that have finished.
2603
	 */
2604
	if (intr & mask_in_data)
2605
		ack |= mask_in_data;
2606

2607
	if (intr & mask_in_eop_flush)
2608
		ack |= mask_in_eop_flush;
2609
	else
2610
		writel_relaxed(in_cmd_flush_stat, base + in_cmd_reg);
2611

2612
	writel_relaxed(ack, base + ack_intr_reg);
2613

2614
	if (intr & mask_in_eop_flush)
2615
		tasklet_schedule(&ac->task);
2616

2617
	return IRQ_HANDLED;
2618
}
2619

2620
/*------------------- Algorithm definitions ----------------------------------*/
2621

2622
/* Hashes */
2623
static struct ahash_alg hash_algos[] = {
2624
	/* SHA-1 */
2625
	{
2626
		.init = artpec6_crypto_sha1_init,
2627
		.update = artpec6_crypto_hash_update,
2628
		.final = artpec6_crypto_hash_final,
2629
		.digest = artpec6_crypto_sha1_digest,
2630
		.import = artpec6_crypto_hash_import,
2631
		.export = artpec6_crypto_hash_export,
2632
		.halg.digestsize = SHA1_DIGEST_SIZE,
2633
		.halg.statesize = sizeof(struct artpec6_hash_export_state),
2634
		.halg.base = {
2635
			.cra_name = "sha1",
2636
			.cra_driver_name = "artpec-sha1",
2637
			.cra_priority = 300,
2638
			.cra_flags = CRYPTO_ALG_ASYNC |
2639
				     CRYPTO_ALG_ALLOCATES_MEMORY,
2640
			.cra_blocksize = SHA1_BLOCK_SIZE,
2641
			.cra_ctxsize = sizeof(struct artpec6_hashalg_context),
2642
			.cra_module = THIS_MODULE,
2643
			.cra_init = artpec6_crypto_ahash_init,
2644
			.cra_exit = artpec6_crypto_ahash_exit,
2645
		}
2646
	},
2647
	/* SHA-256 */
2648
	{
2649
		.init = artpec6_crypto_sha256_init,
2650
		.update = artpec6_crypto_hash_update,
2651
		.final = artpec6_crypto_hash_final,
2652
		.digest = artpec6_crypto_sha256_digest,
2653
		.import = artpec6_crypto_hash_import,
2654
		.export = artpec6_crypto_hash_export,
2655
		.halg.digestsize = SHA256_DIGEST_SIZE,
2656
		.halg.statesize = sizeof(struct artpec6_hash_export_state),
2657
		.halg.base = {
2658
			.cra_name = "sha256",
2659
			.cra_driver_name = "artpec-sha256",
2660
			.cra_priority = 300,
2661
			.cra_flags = CRYPTO_ALG_ASYNC |
2662
				     CRYPTO_ALG_ALLOCATES_MEMORY,
2663
			.cra_blocksize = SHA256_BLOCK_SIZE,
2664
			.cra_ctxsize = sizeof(struct artpec6_hashalg_context),
2665
			.cra_module = THIS_MODULE,
2666
			.cra_init = artpec6_crypto_ahash_init,
2667
			.cra_exit = artpec6_crypto_ahash_exit,
2668
		}
2669
	},
2670
	/* HMAC SHA-256 */
2671
	{
2672
		.init = artpec6_crypto_hmac_sha256_init,
2673
		.update = artpec6_crypto_hash_update,
2674
		.final = artpec6_crypto_hash_final,
2675
		.digest = artpec6_crypto_hmac_sha256_digest,
2676
		.import = artpec6_crypto_hash_import,
2677
		.export = artpec6_crypto_hash_export,
2678
		.setkey = artpec6_crypto_hash_set_key,
2679
		.halg.digestsize = SHA256_DIGEST_SIZE,
2680
		.halg.statesize = sizeof(struct artpec6_hash_export_state),
2681
		.halg.base = {
2682
			.cra_name = "hmac(sha256)",
2683
			.cra_driver_name = "artpec-hmac-sha256",
2684
			.cra_priority = 300,
2685
			.cra_flags = CRYPTO_ALG_ASYNC |
2686
				     CRYPTO_ALG_ALLOCATES_MEMORY,
2687
			.cra_blocksize = SHA256_BLOCK_SIZE,
2688
			.cra_ctxsize = sizeof(struct artpec6_hashalg_context),
2689
			.cra_module = THIS_MODULE,
2690
			.cra_init = artpec6_crypto_ahash_init_hmac_sha256,
2691
			.cra_exit = artpec6_crypto_ahash_exit,
2692
		}
2693
	},
2694
};
2695

2696
/* Crypto */
2697
static struct skcipher_alg crypto_algos[] = {
2698
	/* AES - ECB */
2699
	{
2700
		.base = {
2701
			.cra_name = "ecb(aes)",
2702
			.cra_driver_name = "artpec6-ecb-aes",
2703
			.cra_priority = 300,
2704
			.cra_flags = CRYPTO_ALG_ASYNC |
2705
				     CRYPTO_ALG_ALLOCATES_MEMORY,
2706
			.cra_blocksize = AES_BLOCK_SIZE,
2707
			.cra_ctxsize = sizeof(struct artpec6_cryptotfm_context),
2708
			.cra_alignmask = 3,
2709
			.cra_module = THIS_MODULE,
2710
		},
2711
		.min_keysize = AES_MIN_KEY_SIZE,
2712
		.max_keysize = AES_MAX_KEY_SIZE,
2713
		.setkey = artpec6_crypto_cipher_set_key,
2714
		.encrypt = artpec6_crypto_encrypt,
2715
		.decrypt = artpec6_crypto_decrypt,
2716
		.init = artpec6_crypto_aes_ecb_init,
2717
		.exit = artpec6_crypto_aes_exit,
2718
	},
2719
	/* AES - CTR */
2720
	{
2721
		.base = {
2722
			.cra_name = "ctr(aes)",
2723
			.cra_driver_name = "artpec6-ctr-aes",
2724
			.cra_priority = 300,
2725
			.cra_flags = CRYPTO_ALG_ASYNC |
2726
				     CRYPTO_ALG_ALLOCATES_MEMORY |
2727
				     CRYPTO_ALG_NEED_FALLBACK,
2728
			.cra_blocksize = 1,
2729
			.cra_ctxsize = sizeof(struct artpec6_cryptotfm_context),
2730
			.cra_alignmask = 3,
2731
			.cra_module = THIS_MODULE,
2732
		},
2733
		.min_keysize = AES_MIN_KEY_SIZE,
2734
		.max_keysize = AES_MAX_KEY_SIZE,
2735
		.ivsize = AES_BLOCK_SIZE,
2736
		.setkey = artpec6_crypto_cipher_set_key,
2737
		.encrypt = artpec6_crypto_ctr_encrypt,
2738
		.decrypt = artpec6_crypto_ctr_decrypt,
2739
		.init = artpec6_crypto_aes_ctr_init,
2740
		.exit = artpec6_crypto_aes_ctr_exit,
2741
	},
2742
	/* AES - CBC */
2743
	{
2744
		.base = {
2745
			.cra_name = "cbc(aes)",
2746
			.cra_driver_name = "artpec6-cbc-aes",
2747
			.cra_priority = 300,
2748
			.cra_flags = CRYPTO_ALG_ASYNC |
2749
				     CRYPTO_ALG_ALLOCATES_MEMORY,
2750
			.cra_blocksize = AES_BLOCK_SIZE,
2751
			.cra_ctxsize = sizeof(struct artpec6_cryptotfm_context),
2752
			.cra_alignmask = 3,
2753
			.cra_module = THIS_MODULE,
2754
		},
2755
		.min_keysize = AES_MIN_KEY_SIZE,
2756
		.max_keysize = AES_MAX_KEY_SIZE,
2757
		.ivsize = AES_BLOCK_SIZE,
2758
		.setkey = artpec6_crypto_cipher_set_key,
2759
		.encrypt = artpec6_crypto_encrypt,
2760
		.decrypt = artpec6_crypto_decrypt,
2761
		.init = artpec6_crypto_aes_cbc_init,
2762
		.exit = artpec6_crypto_aes_exit
2763
	},
2764
	/* AES - XTS */
2765
	{
2766
		.base = {
2767
			.cra_name = "xts(aes)",
2768
			.cra_driver_name = "artpec6-xts-aes",
2769
			.cra_priority = 300,
2770
			.cra_flags = CRYPTO_ALG_ASYNC |
2771
				     CRYPTO_ALG_ALLOCATES_MEMORY,
2772
			.cra_blocksize = 1,
2773
			.cra_ctxsize = sizeof(struct artpec6_cryptotfm_context),
2774
			.cra_alignmask = 3,
2775
			.cra_module = THIS_MODULE,
2776
		},
2777
		.min_keysize = 2*AES_MIN_KEY_SIZE,
2778
		.max_keysize = 2*AES_MAX_KEY_SIZE,
2779
		.ivsize = 16,
2780
		.setkey = artpec6_crypto_xts_set_key,
2781
		.encrypt = artpec6_crypto_encrypt,
2782
		.decrypt = artpec6_crypto_decrypt,
2783
		.init = artpec6_crypto_aes_xts_init,
2784
		.exit = artpec6_crypto_aes_exit,
2785
	},
2786
};
2787

2788
static struct aead_alg aead_algos[] = {
2789
	{
2790
		.init   = artpec6_crypto_aead_init,
2791
		.setkey = artpec6_crypto_aead_set_key,
2792
		.encrypt = artpec6_crypto_aead_encrypt,
2793
		.decrypt = artpec6_crypto_aead_decrypt,
2794
		.ivsize = GCM_AES_IV_SIZE,
2795
		.maxauthsize = AES_BLOCK_SIZE,
2796

2797
		.base = {
2798
			.cra_name = "gcm(aes)",
2799
			.cra_driver_name = "artpec-gcm-aes",
2800
			.cra_priority = 300,
2801
			.cra_flags = CRYPTO_ALG_ASYNC |
2802
				     CRYPTO_ALG_ALLOCATES_MEMORY |
2803
				     CRYPTO_ALG_KERN_DRIVER_ONLY,
2804
			.cra_blocksize = 1,
2805
			.cra_ctxsize = sizeof(struct artpec6_cryptotfm_context),
2806
			.cra_alignmask = 3,
2807
			.cra_module = THIS_MODULE,
2808
		},
2809
	}
2810
};
2811

2812
#ifdef CONFIG_DEBUG_FS
2813

2814
static struct dentry *dbgfs_root;
2815

2816
static void artpec6_crypto_init_debugfs(void)
2817
{
2818
	dbgfs_root = debugfs_create_dir("artpec6_crypto", NULL);
2819

2820
#ifdef CONFIG_FAULT_INJECTION
2821
	fault_create_debugfs_attr("fail_status_read", dbgfs_root,
2822
				  &artpec6_crypto_fail_status_read);
2823

2824
	fault_create_debugfs_attr("fail_dma_array_full", dbgfs_root,
2825
				  &artpec6_crypto_fail_dma_array_full);
2826
#endif
2827
}
2828

2829
static void artpec6_crypto_free_debugfs(void)
2830
{
2831
	debugfs_remove_recursive(dbgfs_root);
2832
	dbgfs_root = NULL;
2833
}
2834
#endif
2835

2836
static const struct of_device_id artpec6_crypto_of_match[] = {
2837
	{ .compatible = "axis,artpec6-crypto", .data = (void *)ARTPEC6_CRYPTO },
2838
	{ .compatible = "axis,artpec7-crypto", .data = (void *)ARTPEC7_CRYPTO },
2839
	{}
2840
};
2841
MODULE_DEVICE_TABLE(of, artpec6_crypto_of_match);
2842

2843
static int artpec6_crypto_probe(struct platform_device *pdev)
2844
{
2845
	const struct of_device_id *match;
2846
	enum artpec6_crypto_variant variant;
2847
	struct artpec6_crypto *ac;
2848
	struct device *dev = &pdev->dev;
2849
	void __iomem *base;
2850
	int irq;
2851
	int err;
2852

2853
	if (artpec6_crypto_dev)
2854
		return -ENODEV;
2855

2856
	match = of_match_node(artpec6_crypto_of_match, dev->of_node);
2857
	if (!match)
2858
		return -EINVAL;
2859

2860
	variant = (enum artpec6_crypto_variant)match->data;
2861

2862
	base = devm_platform_ioremap_resource(pdev, 0);
2863
	if (IS_ERR(base))
2864
		return PTR_ERR(base);
2865

2866
	irq = platform_get_irq(pdev, 0);
2867
	if (irq < 0)
2868
		return -ENODEV;
2869

2870
	ac = devm_kzalloc(&pdev->dev, sizeof(struct artpec6_crypto),
2871
			  GFP_KERNEL);
2872
	if (!ac)
2873
		return -ENOMEM;
2874

2875
	platform_set_drvdata(pdev, ac);
2876
	ac->variant = variant;
2877

2878
	spin_lock_init(&ac->queue_lock);
2879
	INIT_LIST_HEAD(&ac->queue);
2880
	INIT_LIST_HEAD(&ac->pending);
2881
	timer_setup(&ac->timer, artpec6_crypto_timeout, 0);
2882

2883
	ac->base = base;
2884

2885
	ac->dma_cache = kmem_cache_create("artpec6_crypto_dma",
2886
		sizeof(struct artpec6_crypto_dma_descriptors),
2887
		64,
2888
		0,
2889
		NULL);
2890
	if (!ac->dma_cache)
2891
		return -ENOMEM;
2892

2893
#ifdef CONFIG_DEBUG_FS
2894
	artpec6_crypto_init_debugfs();
2895
#endif
2896

2897
	tasklet_init(&ac->task, artpec6_crypto_task,
2898
		     (unsigned long)ac);
2899

2900
	ac->pad_buffer = devm_kcalloc(&pdev->dev, 2, ARTPEC_CACHE_LINE_MAX,
2901
				      GFP_KERNEL);
2902
	if (!ac->pad_buffer)
2903
		return -ENOMEM;
2904
	ac->pad_buffer = PTR_ALIGN(ac->pad_buffer, ARTPEC_CACHE_LINE_MAX);
2905

2906
	ac->zero_buffer = devm_kcalloc(&pdev->dev, 2, ARTPEC_CACHE_LINE_MAX,
2907
				      GFP_KERNEL);
2908
	if (!ac->zero_buffer)
2909
		return -ENOMEM;
2910
	ac->zero_buffer = PTR_ALIGN(ac->zero_buffer, ARTPEC_CACHE_LINE_MAX);
2911

2912
	err = init_crypto_hw(ac);
2913
	if (err)
2914
		goto free_cache;
2915

2916
	err = devm_request_irq(&pdev->dev, irq, artpec6_crypto_irq, 0,
2917
			       "artpec6-crypto", ac);
2918
	if (err)
2919
		goto disable_hw;
2920

2921
	artpec6_crypto_dev = &pdev->dev;
2922

2923
	err = crypto_register_ahashes(hash_algos, ARRAY_SIZE(hash_algos));
2924
	if (err) {
2925
		dev_err(dev, "Failed to register ahashes\n");
2926
		goto disable_hw;
2927
	}
2928

2929
	err = crypto_register_skciphers(crypto_algos, ARRAY_SIZE(crypto_algos));
2930
	if (err) {
2931
		dev_err(dev, "Failed to register ciphers\n");
2932
		goto unregister_ahashes;
2933
	}
2934

2935
	err = crypto_register_aeads(aead_algos, ARRAY_SIZE(aead_algos));
2936
	if (err) {
2937
		dev_err(dev, "Failed to register aeads\n");
2938
		goto unregister_algs;
2939
	}
2940

2941
	return 0;
2942

2943
unregister_algs:
2944
	crypto_unregister_skciphers(crypto_algos, ARRAY_SIZE(crypto_algos));
2945
unregister_ahashes:
2946
	crypto_unregister_ahashes(hash_algos, ARRAY_SIZE(hash_algos));
2947
disable_hw:
2948
	artpec6_crypto_disable_hw(ac);
2949
free_cache:
2950
	kmem_cache_destroy(ac->dma_cache);
2951
	return err;
2952
}
2953

2954
static void artpec6_crypto_remove(struct platform_device *pdev)
2955
{
2956
	struct artpec6_crypto *ac = platform_get_drvdata(pdev);
2957
	int irq = platform_get_irq(pdev, 0);
2958

2959
	crypto_unregister_ahashes(hash_algos, ARRAY_SIZE(hash_algos));
2960
	crypto_unregister_skciphers(crypto_algos, ARRAY_SIZE(crypto_algos));
2961
	crypto_unregister_aeads(aead_algos, ARRAY_SIZE(aead_algos));
2962

2963
	tasklet_disable(&ac->task);
2964
	devm_free_irq(&pdev->dev, irq, ac);
2965
	tasklet_kill(&ac->task);
2966
	timer_delete_sync(&ac->timer);
2967

2968
	artpec6_crypto_disable_hw(ac);
2969

2970
	kmem_cache_destroy(ac->dma_cache);
2971
#ifdef CONFIG_DEBUG_FS
2972
	artpec6_crypto_free_debugfs();
2973
#endif
2974
}
2975

2976
static struct platform_driver artpec6_crypto_driver = {
2977
	.probe   = artpec6_crypto_probe,
2978
	.remove = artpec6_crypto_remove,
2979
	.driver  = {
2980
		.name  = "artpec6-crypto",
2981
		.of_match_table = artpec6_crypto_of_match,
2982
	},
2983
};
2984

2985
module_platform_driver(artpec6_crypto_driver);
2986

2987
MODULE_AUTHOR("Axis Communications AB");
2988
MODULE_DESCRIPTION("ARTPEC-6 Crypto driver");
2989
MODULE_LICENSE("GPL");
2990

2991