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/*
* Copyright 2016 Broadcom
*
* This program is free software; you can redistribute it and/or modify
* it under the terms of the GNU General Public License, version 2, as
* published by the Free Software Foundation (the "GPL").
*
* This program is distributed in the hope that it will be useful, but
* WITHOUT ANY WARRANTY; without even the implied warranty of
* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU
* General Public License version 2 (GPLv2) for more details.
*
* You should have received a copy of the GNU General Public License
* version 2 (GPLv2) along with this source code.
*/
#ifndef _CIPHER_H
#define _CIPHER_H
#include <linux/atomic.h>
#include <linux/mailbox/brcm-message.h>
#include <linux/mailbox_client.h>
#include <crypto/aes.h>
#include <crypto/internal/hash.h>
#include <crypto/aead.h>
#include <crypto/gcm.h>
#include <crypto/sha.h>
#include <crypto/sha3.h>
#include "spu.h"
#include "spum.h"
#include "spu2.h"
/* Driver supports up to MAX_SPUS SPU blocks */
#define MAX_SPUS 16
#define ARC4_MIN_KEY_SIZE 1
#define ARC4_MAX_KEY_SIZE 256
#define ARC4_BLOCK_SIZE 1
#define ARC4_STATE_SIZE 4
#define CCM_AES_IV_SIZE 16
#define CCM_ESP_IV_SIZE 8
#define RFC4543_ICV_SIZE 16
#define MAX_KEY_SIZE ARC4_MAX_KEY_SIZE
#define MAX_IV_SIZE AES_BLOCK_SIZE
#define MAX_DIGEST_SIZE SHA3_512_DIGEST_SIZE
#define MAX_ASSOC_SIZE 512
/* size of salt value for AES-GCM-ESP and AES-CCM-ESP */
#define GCM_ESP_SALT_SIZE 4
#define CCM_ESP_SALT_SIZE 3
#define MAX_SALT_SIZE GCM_ESP_SALT_SIZE
#define GCM_ESP_SALT_OFFSET 0
#define CCM_ESP_SALT_OFFSET 1
#define GCM_ESP_DIGESTSIZE 16
#define MAX_HASH_BLOCK_SIZE SHA512_BLOCK_SIZE
/*
* Maximum number of bytes from a non-final hash request that can be deferred
* until more data is available. With new crypto API framework, this
* can be no more than one block of data.
*/
#define HASH_CARRY_MAX MAX_HASH_BLOCK_SIZE
/* Force at least 4-byte alignment of all SPU message fields */
#define SPU_MSG_ALIGN 4
/* Number of times to resend mailbox message if mb queue is full */
#define SPU_MB_RETRY_MAX 1000
/* op_counts[] indexes */
enum op_type {
SPU_OP_CIPHER,
SPU_OP_HASH,
SPU_OP_HMAC,
SPU_OP_AEAD,
SPU_OP_NUM
};
enum spu_spu_type {
SPU_TYPE_SPUM,
SPU_TYPE_SPU2,
};
/*
* SPUM_NS2 and SPUM_NSP are the SPU-M block on Northstar 2 and Northstar Plus,
* respectively.
*/
enum spu_spu_subtype {
SPU_SUBTYPE_SPUM_NS2,
SPU_SUBTYPE_SPUM_NSP,
SPU_SUBTYPE_SPU2_V1,
SPU_SUBTYPE_SPU2_V2
};
struct spu_type_subtype {
enum spu_spu_type type;
enum spu_spu_subtype subtype;
};
struct cipher_op {
enum spu_cipher_alg alg;
enum spu_cipher_mode mode;
};
struct auth_op {
enum hash_alg alg;
enum hash_mode mode;
};
struct iproc_alg_s {
u32 type;
union {
struct crypto_alg crypto;
struct ahash_alg hash;
struct aead_alg aead;
} alg;
struct cipher_op cipher_info;
struct auth_op auth_info;
bool auth_first;
bool registered;
};
/*
* Buffers for a SPU request/reply message pair. All part of one structure to
* allow a single alloc per request.
*/
struct spu_msg_buf {
/* Request message fragments */
/*
* SPU request message header. For SPU-M, holds MH, EMH, SCTX, BDESC,
* and BD header. For SPU2, holds FMD, OMD.
*/
u8 bcm_spu_req_hdr[ALIGN(SPU2_HEADER_ALLOC_LEN, SPU_MSG_ALIGN)];
/* IV or counter. Size to include salt. Also used for XTS tweek. */
u8 iv_ctr[ALIGN(2 * AES_BLOCK_SIZE, SPU_MSG_ALIGN)];
/* Hash digest. request and response. */
u8 digest[ALIGN(MAX_DIGEST_SIZE, SPU_MSG_ALIGN)];
/* SPU request message padding */
u8 spu_req_pad[ALIGN(SPU_PAD_LEN_MAX, SPU_MSG_ALIGN)];
/* SPU-M request message STATUS field */
u8 tx_stat[ALIGN(SPU_TX_STATUS_LEN, SPU_MSG_ALIGN)];
/* Response message fragments */
/* SPU response message header */
u8 spu_resp_hdr[ALIGN(SPU2_HEADER_ALLOC_LEN, SPU_MSG_ALIGN)];
/* SPU response message STATUS field padding */
u8 rx_stat_pad[ALIGN(SPU_STAT_PAD_MAX, SPU_MSG_ALIGN)];
/* SPU response message STATUS field */
u8 rx_stat[ALIGN(SPU_RX_STATUS_LEN, SPU_MSG_ALIGN)];
union {
/* Buffers only used for ablkcipher */
struct {
/*
* Field used for either SUPDT when RC4 is used
* -OR- tweak value when XTS/AES is used
*/
u8 supdt_tweak[ALIGN(SPU_SUPDT_LEN, SPU_MSG_ALIGN)];
} c;
/* Buffers only used for aead */
struct {
/* SPU response pad for GCM data */
u8 gcmpad[ALIGN(AES_BLOCK_SIZE, SPU_MSG_ALIGN)];
/* SPU request msg padding for GCM AAD */
u8 req_aad_pad[ALIGN(SPU_PAD_LEN_MAX, SPU_MSG_ALIGN)];
/* SPU response data to be discarded */
u8 resp_aad[ALIGN(MAX_ASSOC_SIZE + MAX_IV_SIZE,
SPU_MSG_ALIGN)];
} a;
};
};
struct iproc_ctx_s {
u8 enckey[MAX_KEY_SIZE + ARC4_STATE_SIZE];
unsigned int enckeylen;
u8 authkey[MAX_KEY_SIZE + ARC4_STATE_SIZE];
unsigned int authkeylen;
u8 salt[MAX_SALT_SIZE];
unsigned int salt_len;
unsigned int salt_offset;
u8 iv[MAX_IV_SIZE];
unsigned int digestsize;
struct iproc_alg_s *alg;
bool is_esp;
struct cipher_op cipher;
enum spu_cipher_type cipher_type;
struct auth_op auth;
bool auth_first;
/*
* The maximum length in bytes of the payload in a SPU message for this
* context. For SPU-M, the payload is the combination of AAD and data.
* For SPU2, the payload is just data. A value of SPU_MAX_PAYLOAD_INF
* indicates that there is no limit to the length of the SPU message
* payload.
*/
unsigned int max_payload;
struct crypto_aead *fallback_cipher;
/* auth_type is determined during processing of request */
u8 ipad[MAX_HASH_BLOCK_SIZE];
u8 opad[MAX_HASH_BLOCK_SIZE];
/*
* Buffer to hold SPU message header template. Template is created at
* setkey time for ablkcipher requests, since most of the fields in the
* header are known at that time. At request time, just fill in a few
* missing pieces related to length of data in the request and IVs, etc.
*/
u8 bcm_spu_req_hdr[ALIGN(SPU2_HEADER_ALLOC_LEN, SPU_MSG_ALIGN)];
/* Length of SPU request header */
u16 spu_req_hdr_len;
/* Expected length of SPU response header */
u16 spu_resp_hdr_len;
/*
* shash descriptor - needed to perform incremental hashing in
* in software, when hw doesn't support it.
*/
struct shash_desc *shash;
bool is_rfc4543; /* RFC 4543 style of GMAC */
};
/* state from iproc_reqctx_s necessary for hash state export/import */
struct spu_hash_export_s {
unsigned int total_todo;
unsigned int total_sent;
u8 hash_carry[HASH_CARRY_MAX];
unsigned int hash_carry_len;
u8 incr_hash[MAX_DIGEST_SIZE];
bool is_sw_hmac;
};
struct iproc_reqctx_s {
/* general context */
struct crypto_async_request *parent;
/* only valid after enqueue() */
struct iproc_ctx_s *ctx;
u8 chan_idx; /* Mailbox channel to be used to submit this request */
/* total todo, rx'd, and sent for this request */
unsigned int total_todo;
unsigned int total_received; /* only valid for ablkcipher */
unsigned int total_sent;
/*
* num bytes sent to hw from the src sg in this request. This can differ
* from total_sent for incremental hashing. total_sent includes previous
* init() and update() data. src_sent does not.
*/
unsigned int src_sent;
/*
* For AEAD requests, start of associated data. This will typically
* point to the beginning of the src scatterlist from the request,
* since assoc data is at the beginning of the src scatterlist rather
* than in its own sg.
*/
struct scatterlist *assoc;
/*
* scatterlist entry and offset to start of data for next chunk. Crypto
* API src scatterlist for AEAD starts with AAD, if present. For first
* chunk, src_sg is sg entry at beginning of input data (after AAD).
* src_skip begins at the offset in that sg entry where data begins.
*/
struct scatterlist *src_sg;
int src_nents; /* Number of src entries with data */
u32 src_skip; /* bytes of current sg entry already used */
/*
* Same for destination. For AEAD, if there is AAD, output data must
* be written at offset following AAD.
*/
struct scatterlist *dst_sg;
int dst_nents; /* Number of dst entries with data */
u32 dst_skip; /* bytes of current sg entry already written */
/* Mailbox message used to send this request to PDC driver */
struct brcm_message mb_mssg;
bool bd_suppress; /* suppress BD field in SPU response? */
/* cipher context */
bool is_encrypt;
/*
* CBC mode: IV. CTR mode: counter. Else empty. Used as a DMA
* buffer for AEAD requests. So allocate as DMAable memory. If IV
* concatenated with salt, includes the salt.
*/
u8 *iv_ctr;
/* Length of IV or counter, in bytes */
unsigned int iv_ctr_len;
/*
* Hash requests can be of any size, whether initial, update, or final.
* A non-final request must be submitted to the SPU as an integral
* number of blocks. This may leave data at the end of the request
* that is not a full block. Since the request is non-final, it cannot
* be padded. So, we write the remainder to this hash_carry buffer and
* hold it until the next request arrives. The carry data is then
* submitted at the beginning of the data in the next SPU msg.
* hash_carry_len is the number of bytes currently in hash_carry. These
* fields are only used for ahash requests.
*/
u8 hash_carry[HASH_CARRY_MAX];
unsigned int hash_carry_len;
unsigned int is_final; /* is this the final for the hash op? */
/*
* Digest from incremental hash is saved here to include in next hash
* operation. Cannot be stored in req->result for truncated hashes,
* since result may be sized for final digest. Cannot be saved in
* msg_buf because that gets deleted between incremental hash ops
* and is not saved as part of export().
*/
u8 incr_hash[MAX_DIGEST_SIZE];
/* hmac context */
bool is_sw_hmac;
/* aead context */
struct crypto_tfm *old_tfm;
crypto_completion_t old_complete;
void *old_data;
gfp_t gfp;
/* Buffers used to build SPU request and response messages */
struct spu_msg_buf msg_buf;
};
/*
* Structure encapsulates a set of function pointers specific to the type of
* SPU hardware running. These functions handling creation and parsing of
* SPU request messages and SPU response messages. Includes hardware-specific
* values read from device tree.
*/
struct spu_hw {
void (*spu_dump_msg_hdr)(u8 *buf, unsigned int buf_len);
u32 (*spu_ctx_max_payload)(enum spu_cipher_alg cipher_alg,
enum spu_cipher_mode cipher_mode,
unsigned int blocksize);
u32 (*spu_payload_length)(u8 *spu_hdr);
u16 (*spu_response_hdr_len)(u16 auth_key_len, u16 enc_key_len,
bool is_hash);
u16 (*spu_hash_pad_len)(enum hash_alg hash_alg,
enum hash_mode hash_mode, u32 chunksize,
u16 hash_block_size);
u32 (*spu_gcm_ccm_pad_len)(enum spu_cipher_mode cipher_mode,
unsigned int data_size);
u32 (*spu_assoc_resp_len)(enum spu_cipher_mode cipher_mode,
unsigned int assoc_len,
unsigned int iv_len, bool is_encrypt);
u8 (*spu_aead_ivlen)(enum spu_cipher_mode cipher_mode,
u16 iv_len);
enum hash_type (*spu_hash_type)(u32 src_sent);
u32 (*spu_digest_size)(u32 digest_size, enum hash_alg alg,
enum hash_type);
u32 (*spu_create_request)(u8 *spu_hdr,
struct spu_request_opts *req_opts,
struct spu_cipher_parms *cipher_parms,
struct spu_hash_parms *hash_parms,
struct spu_aead_parms *aead_parms,
unsigned int data_size);
u16 (*spu_cipher_req_init)(u8 *spu_hdr,
struct spu_cipher_parms *cipher_parms);
void (*spu_cipher_req_finish)(u8 *spu_hdr,
u16 spu_req_hdr_len,
unsigned int is_inbound,
struct spu_cipher_parms *cipher_parms,
bool update_key,
unsigned int data_size);
void (*spu_request_pad)(u8 *pad_start, u32 gcm_padding,
u32 hash_pad_len, enum hash_alg auth_alg,
enum hash_mode auth_mode,
unsigned int total_sent, u32 status_padding);
u8 (*spu_xts_tweak_in_payload)(void);
u8 (*spu_tx_status_len)(void);
u8 (*spu_rx_status_len)(void);
int (*spu_status_process)(u8 *statp);
void (*spu_ccm_update_iv)(unsigned int digestsize,
struct spu_cipher_parms *cipher_parms,
unsigned int assoclen, unsigned int chunksize,
bool is_encrypt, bool is_esp);
u32 (*spu_wordalign_padlen)(u32 data_size);
/* The base virtual address of the SPU hw registers */
void __iomem *reg_vbase[MAX_SPUS];
/* Version of the SPU hardware */
enum spu_spu_type spu_type;
/* Sub-version of the SPU hardware */
enum spu_spu_subtype spu_subtype;
/* The number of SPUs on this platform */
u32 num_spu;
/* The number of SPU channels on this platform */
u32 num_chan;
};
struct device_private {
struct platform_device *pdev;
struct spu_hw spu;
atomic_t session_count; /* number of streams active */
atomic_t stream_count; /* monotonic counter for streamID's */
/* Length of BCM header. Set to 0 when hw does not expect BCM HEADER. */
u8 bcm_hdr_len;
/* The index of the channel to use for the next crypto request */
atomic_t next_chan;
struct dentry *debugfs_dir;
struct dentry *debugfs_stats;
/* Number of request bytes processed and result bytes returned */
atomic64_t bytes_in;
atomic64_t bytes_out;
/* Number of operations of each type */
atomic_t op_counts[SPU_OP_NUM];
atomic_t cipher_cnt[CIPHER_ALG_LAST][CIPHER_MODE_LAST];
atomic_t hash_cnt[HASH_ALG_LAST];
atomic_t hmac_cnt[HASH_ALG_LAST];
atomic_t aead_cnt[AEAD_TYPE_LAST];
/* Number of calls to setkey() for each operation type */
atomic_t setkey_cnt[SPU_OP_NUM];
/* Number of times request was resubmitted because mb was full */
atomic_t mb_no_spc;
/* Number of mailbox send failures */
atomic_t mb_send_fail;
/* Number of ICV check failures for AEAD messages */
atomic_t bad_icv;
struct mbox_client mcl;
/* Array of mailbox channel pointers, one for each channel */
struct mbox_chan **mbox;
};
extern struct device_private iproc_priv;
#endif