Google Git
Sign in
kunit / linux / 2fcfe7b79f081aa4cf2a9add6c20abc3663e5640 / . / drivers / crypto / cavium / nitrox / nitrox_req.h
blob: 76c0f0be7233693f173540dc0609d0067c74cd6d [file] [log] [blame]
/* SPDX-License-Identifier: GPL-2.0 */
#ifndef __NITROX_REQ_H
#define __NITROX_REQ_H
#include <linux/dma-mapping.h>
#include <crypto/aes.h>
#include "nitrox_dev.h"
#define PENDING_SIG 0xFFFFFFFFFFFFFFFFUL
#define PRIO 4001
/**
* struct gphdr - General purpose Header
* @param0: first parameter.
* @param1: second parameter.
* @param2: third parameter.
* @param3: fourth parameter.
*
* Params tell the iv and enc/dec data offsets.
*/
struct gphdr {
__be16 param0;
__be16 param1;
__be16 param2;
__be16 param3;
};
/**
* struct se_req_ctrl - SE request information.
* @arg: Minor number of the opcode
* @ctxc: Context control.
* @unca: Uncertainity enabled.
* @info: Additional information for SE cores.
* @ctxl: Context length in bytes.
* @uddl: User defined data length
*/
union se_req_ctrl {
u64 value;
struct {
u64 raz : 22;
u64 arg : 8;
u64 ctxc : 2;
u64 unca : 1;
u64 info : 3;
u64 unc : 8;
u64 ctxl : 12;
u64 uddl : 8;
} s;
};
#define MAX_IV_LEN 16
/**
* struct se_crypto_request - SE crypto request structure.
* @opcode: Request opcode (enc/dec)
* @flags: flags from crypto subsystem
* @ctx_handle: Crypto context handle.
* @gph: GP Header
* @ctrl: Request Information.
* @orh: ORH address
* @comp: completion address
* @src: Input sglist
* @dst: Output sglist
*/
struct se_crypto_request {
u8 opcode;
gfp_t gfp;
u32 flags;
u64 ctx_handle;
struct gphdr gph;
union se_req_ctrl ctrl;
u64 *orh;
u64 *comp;
struct scatterlist *src;
struct scatterlist *dst;
};
/* Crypto opcodes */
#define FLEXI_CRYPTO_ENCRYPT_HMAC 0x33
#define ENCRYPT 0
#define DECRYPT 1
/* IV from context */
#define IV_FROM_CTX 0
/* IV from Input data */
#define IV_FROM_DPTR 1
/**
* cipher opcodes for firmware
*/
enum flexi_cipher {
CIPHER_NULL = 0,
CIPHER_3DES_CBC,
CIPHER_3DES_ECB,
CIPHER_AES_CBC,
CIPHER_AES_ECB,
CIPHER_AES_CFB,
CIPHER_AES_CTR,
CIPHER_AES_GCM,
CIPHER_AES_XTS,
CIPHER_AES_CCM,
CIPHER_AES_CBC_CTS,
CIPHER_AES_ECB_CTS,
CIPHER_INVALID
};
enum flexi_auth {
AUTH_NULL = 0,
AUTH_MD5,
AUTH_SHA1,
AUTH_SHA2_SHA224,
AUTH_SHA2_SHA256,
AUTH_SHA2_SHA384,
AUTH_SHA2_SHA512,
AUTH_GMAC,
AUTH_INVALID
};
/**
* struct crypto_keys - Crypto keys
* @key: Encryption key or KEY1 for AES-XTS
* @iv: Encryption IV or Tweak for AES-XTS
*/
struct crypto_keys {
union {
u8 key[AES_MAX_KEY_SIZE];
u8 key1[AES_MAX_KEY_SIZE];
} u;
u8 iv[AES_BLOCK_SIZE];
};
/**
* struct auth_keys - Authentication keys
* @ipad: IPAD or KEY2 for AES-XTS
* @opad: OPAD or AUTH KEY if auth_input_type = 1
*/
struct auth_keys {
union {
u8 ipad[64];
u8 key2[64];
} u;
u8 opad[64];
};
union fc_ctx_flags {
__be64 f;
struct {
#if defined(__BIG_ENDIAN_BITFIELD)
u64 cipher_type : 4;
u64 reserved_59 : 1;
u64 aes_keylen : 2;
u64 iv_source : 1;
u64 hash_type : 4;
u64 reserved_49_51 : 3;
u64 auth_input_type: 1;
u64 mac_len : 8;
u64 reserved_0_39 : 40;
#else
u64 reserved_0_39 : 40;
u64 mac_len : 8;
u64 auth_input_type: 1;
u64 reserved_49_51 : 3;
u64 hash_type : 4;
u64 iv_source : 1;
u64 aes_keylen : 2;
u64 reserved_59 : 1;
u64 cipher_type : 4;
#endif
} w0;
};
/**
* struct flexi_crypto_context - Crypto context
* @cipher_type: Encryption cipher type
* @aes_keylen: AES key length
* @iv_source: Encryption IV source
* @hash_type: Authentication type
* @auth_input_type: Authentication input type
* 1 - Authentication IV and KEY, microcode calculates OPAD/IPAD
* 0 - Authentication OPAD/IPAD
* @mac_len: mac length
* @crypto: Crypto keys
* @auth: Authentication keys
*/
struct flexi_crypto_context {
union fc_ctx_flags flags;
struct crypto_keys crypto;
struct auth_keys auth;
};
struct crypto_ctx_hdr {
struct dma_pool *pool;
dma_addr_t dma;
void *vaddr;
};
struct nitrox_crypto_ctx {
struct nitrox_device *ndev;
union {
u64 ctx_handle;
struct flexi_crypto_context *fctx;
} u;
struct crypto_ctx_hdr *chdr;
};
struct nitrox_kcrypt_request {
struct se_crypto_request creq;
u8 *src;
u8 *dst;
};
/**
* struct pkt_instr_hdr - Packet Instruction Header
* @g: Gather used
* When [G] is set and [GSZ] != 0, the instruction is
* indirect gather instruction.
* When [G] is set and [GSZ] = 0, the instruction is
* direct gather instruction.
* @gsz: Number of pointers in the indirect gather list
* @ihi: When set hardware duplicates the 1st 8 bytes of pkt_instr_hdr
* and adds them to the packet after the pkt_instr_hdr but before any UDD
* @ssz: Not used by the input hardware. But can become slc_store_int[SSZ]
* when [IHI] is set.
* @fsz: The number of front data bytes directly included in the
* PCIe instruction.
* @tlen: The length of the input packet in bytes, include:
* - 16B pkt_hdr
* - Inline context bytes if any,
* - UDD if any,
* - packet payload bytes
*/
union pkt_instr_hdr {
u64 value;
struct {
#if defined(__BIG_ENDIAN_BITFIELD)
u64 raz_48_63 : 16;
u64 g : 1;
u64 gsz : 7;
u64 ihi : 1;
u64 ssz : 7;
u64 raz_30_31 : 2;
u64 fsz : 6;
u64 raz_16_23 : 8;
u64 tlen : 16;
#else
u64 tlen : 16;
u64 raz_16_23 : 8;
u64 fsz : 6;
u64 raz_30_31 : 2;
u64 ssz : 7;
u64 ihi : 1;
u64 gsz : 7;
u64 g : 1;
u64 raz_48_63 : 16;
#endif
} s;
};
/**
* struct pkt_hdr - Packet Input Header
* @opcode: Request opcode (Major)
* @arg: Request opcode (Minor)
* @ctxc: Context control.
* @unca: When set [UNC] is the uncertainty count for an input packet.
* The hardware uses uncertainty counts to predict
* output buffer use and avoid deadlock.
* @info: Not used by input hardware. Available for use
* during SE processing.
* @destport: The expected destination port/ring/channel for the packet.
* @unc: Uncertainty count for an input packet.
* @grp: SE group that will process the input packet.
* @ctxl: Context Length in 64-bit words.
* @uddl: User-defined data (UDD) length in bytes.
* @ctxp: Context pointer. CTXP<63,2:0> must be zero in all cases.
*/
union pkt_hdr {
u64 value[2];
struct {
#if defined(__BIG_ENDIAN_BITFIELD)
u64 opcode : 8;
u64 arg : 8;
u64 ctxc : 2;
u64 unca : 1;
u64 raz_44 : 1;
u64 info : 3;
u64 destport : 9;
u64 unc : 8;
u64 raz_19_23 : 5;
u64 grp : 3;
u64 raz_15 : 1;
u64 ctxl : 7;
u64 uddl : 8;
#else
u64 uddl : 8;
u64 ctxl : 7;
u64 raz_15 : 1;
u64 grp : 3;
u64 raz_19_23 : 5;
u64 unc : 8;
u64 destport : 9;
u64 info : 3;
u64 raz_44 : 1;
u64 unca : 1;
u64 ctxc : 2;
u64 arg : 8;
u64 opcode : 8;
#endif
__be64 ctxp;
} s;
};
/**
* struct slc_store_info - Solicited Paceket Output Store Information.
* @ssz: The number of scatterlist pointers for the solicited output port
* packet.
* @rptr: The result pointer for the solicited output port packet.
* If [SSZ]=0, [RPTR] must point directly to a buffer on the remote
* host that is large enough to hold the entire output packet.
* If [SSZ]!=0, [RPTR] must point to an array of ([SSZ]+3)/4
* sglist components at [RPTR] on the remote host.
*/
union slc_store_info {
u64 value[2];
struct {
#if defined(__BIG_ENDIAN_BITFIELD)
u64 raz_39_63 : 25;
u64 ssz : 7;
u64 raz_0_31 : 32;
#else
u64 raz_0_31 : 32;
u64 ssz : 7;
u64 raz_39_63 : 25;
#endif
__be64 rptr;
} s;
};
/**
* struct nps_pkt_instr - NPS Packet Instruction of SE cores.
* @dptr0 : Input pointer points to buffer in remote host.
* @ih: Packet Instruction Header (8 bytes)
* @irh: Packet Input Header (16 bytes)
* @slc: Solicited Packet Output Store Information (16 bytes)
* @fdata: Front data
*
* 64-Byte Instruction Format
*/
struct nps_pkt_instr {
__be64 dptr0;
union pkt_instr_hdr ih;
union pkt_hdr irh;
union slc_store_info slc;
u64 fdata[2];
};
/**
* struct ctx_hdr - Book keeping data about the crypto context
* @pool: Pool used to allocate crypto context
* @dma: Base DMA address of the cypto context
* @ctx_dma: Actual usable crypto context for NITROX
*/
struct ctx_hdr {
struct dma_pool *pool;
dma_addr_t dma;
dma_addr_t ctx_dma;
};
/*
* struct sglist_component - SG list component format
* @len0: The number of bytes at [PTR0] on the remote host.
* @len1: The number of bytes at [PTR1] on the remote host.
* @len2: The number of bytes at [PTR2] on the remote host.
* @len3: The number of bytes at [PTR3] on the remote host.
* @dma0: First pointer point to buffer in remote host.
* @dma1: Second pointer point to buffer in remote host.
* @dma2: Third pointer point to buffer in remote host.
* @dma3: Fourth pointer point to buffer in remote host.
*/
struct nitrox_sgcomp {
__be16 len[4];
__be64 dma[4];
};
/*
* strutct nitrox_sgtable - SG list information
* @sgmap_cnt: Number of buffers mapped
* @total_bytes: Total bytes in sglist.
* @sgcomp_len: Total sglist components length.
* @sgcomp_dma: DMA address of sglist component.
* @sg: crypto request buffer.
* @sgcomp: sglist component for NITROX.
*/
struct nitrox_sgtable {
u8 sgmap_cnt;
u16 total_bytes;
u32 sgcomp_len;
dma_addr_t sgcomp_dma;
struct scatterlist *sg;
struct nitrox_sgcomp *sgcomp;
};
/* Response Header Length */
#define ORH_HLEN 8
/* Completion bytes Length */
#define COMP_HLEN 8
struct resp_hdr {
u64 *orh;
u64 *completion;
};
typedef void (*completion_t)(void *arg, int err);
/**
* struct nitrox_softreq - Represents the NIROX Request.
* @response: response list entry
* @backlog: Backlog list entry
* @ndev: Device used to submit the request
* @cmdq: Command queue for submission
* @resp: Response headers
* @instr: 64B instruction
* @in: SG table for input
* @out SG table for output
* @tstamp: Request submitted time in jiffies
* @callback: callback after request completion/timeout
* @cb_arg: callback argument
*/
struct nitrox_softreq {
struct list_head response;
struct list_head backlog;
u32 flags;
gfp_t gfp;
atomic_t status;
struct nitrox_device *ndev;
struct nitrox_cmdq *cmdq;
struct nps_pkt_instr instr;
struct resp_hdr resp;
struct nitrox_sgtable in;
struct nitrox_sgtable out;
unsigned long tstamp;
completion_t callback;
void *cb_arg;
};
static inline int flexi_aes_keylen(int keylen)
{
int aes_keylen;
switch (keylen) {
case AES_KEYSIZE_128:
aes_keylen = 1;
break;
case AES_KEYSIZE_192:
aes_keylen = 2;
break;
case AES_KEYSIZE_256:
aes_keylen = 3;
break;
default:
aes_keylen = -EINVAL;
break;
}
return aes_keylen;
}
static inline void *alloc_req_buf(int nents, int extralen, gfp_t gfp)
{
size_t size;
size = sizeof(struct scatterlist) * nents;
size += extralen;
return kzalloc(size, gfp);
}
/**
* create_single_sg - Point SG entry to the data
* @sg: Destination SG list
* @buf: Data
* @buflen: Data length
*
* Returns next free entry in the destination SG list
**/
static inline struct scatterlist *create_single_sg(struct scatterlist *sg,
void *buf, int buflen)
{
sg_set_buf(sg, buf, buflen);
sg++;
return sg;
}
/**
* create_multi_sg - Create multiple sg entries with buflen data length from
* source sglist
* @to_sg: Destination SG list
* @from_sg: Source SG list
* @buflen: Data length
*
* Returns next free entry in the destination SG list
**/
static inline struct scatterlist *create_multi_sg(struct scatterlist *to_sg,
struct scatterlist *from_sg,
int buflen)
{
struct scatterlist *sg = to_sg;
unsigned int sglen;
for (; buflen; buflen -= sglen) {
sglen = from_sg->length;
if (sglen > buflen)
sglen = buflen;
sg_set_buf(sg, sg_virt(from_sg), sglen);
from_sg = sg_next(from_sg);
sg++;
}
return sg;
}
static inline void set_orh_value(u64 *orh)
{
WRITE_ONCE(*orh, PENDING_SIG);
}
static inline void set_comp_value(u64 *comp)
{
WRITE_ONCE(*comp, PENDING_SIG);
}
static inline int alloc_src_req_buf(struct nitrox_kcrypt_request *nkreq,
int nents, int ivsize)
{
struct se_crypto_request *creq = &nkreq->creq;
nkreq->src = alloc_req_buf(nents, ivsize, creq->gfp);
if (!nkreq->src)
return -ENOMEM;
return 0;
}
static inline void nitrox_creq_copy_iv(char *dst, char *src, int size)
{
memcpy(dst, src, size);
}
static inline struct scatterlist *nitrox_creq_src_sg(char *iv, int ivsize)
{
return (struct scatterlist *)(iv + ivsize);
}
static inline void nitrox_creq_set_src_sg(struct nitrox_kcrypt_request *nkreq,
int nents, int ivsize,
struct scatterlist *src, int buflen)
{
char *iv = nkreq->src;
struct scatterlist *sg;
struct se_crypto_request *creq = &nkreq->creq;
creq->src = nitrox_creq_src_sg(iv, ivsize);
sg = creq->src;
sg_init_table(sg, nents);
/* Input format:
* +----+----------------+
* | IV | SRC sg entries |
* +----+----------------+
*/
/* IV */
sg = create_single_sg(sg, iv, ivsize);
/* SRC entries */
create_multi_sg(sg, src, buflen);
}
static inline int alloc_dst_req_buf(struct nitrox_kcrypt_request *nkreq,
int nents)
{
int extralen = ORH_HLEN + COMP_HLEN;
struct se_crypto_request *creq = &nkreq->creq;
nkreq->dst = alloc_req_buf(nents, extralen, creq->gfp);
if (!nkreq->dst)
return -ENOMEM;
return 0;
}
static inline void nitrox_creq_set_orh(struct nitrox_kcrypt_request *nkreq)
{
struct se_crypto_request *creq = &nkreq->creq;
creq->orh = (u64 *)(nkreq->dst);
set_orh_value(creq->orh);
}
static inline void nitrox_creq_set_comp(struct nitrox_kcrypt_request *nkreq)
{
struct se_crypto_request *creq = &nkreq->creq;
creq->comp = (u64 *)(nkreq->dst + ORH_HLEN);
set_comp_value(creq->comp);
}
static inline struct scatterlist *nitrox_creq_dst_sg(char *dst)
{
return (struct scatterlist *)(dst + ORH_HLEN + COMP_HLEN);
}
static inline void nitrox_creq_set_dst_sg(struct nitrox_kcrypt_request *nkreq,
int nents, int ivsize,
struct scatterlist *dst, int buflen)
{
struct se_crypto_request *creq = &nkreq->creq;
struct scatterlist *sg;
char *iv = nkreq->src;
creq->dst = nitrox_creq_dst_sg(nkreq->dst);
sg = creq->dst;
sg_init_table(sg, nents);
/* Output format:
* +-----+----+----------------+-----------------+
* | ORH | IV | DST sg entries | COMPLETION Bytes|
* +-----+----+----------------+-----------------+
*/
/* ORH */
sg = create_single_sg(sg, creq->orh, ORH_HLEN);
/* IV */
sg = create_single_sg(sg, iv, ivsize);
/* DST entries */
sg = create_multi_sg(sg, dst, buflen);
/* COMPLETION Bytes */
create_single_sg(sg, creq->comp, COMP_HLEN);
}
#endif /* __NITROX_REQ_H */