linux_old1/drivers/crypto/chelsio/chcr_algo.h

472 lines
14 KiB
C

/*
* This file is part of the Chelsio T6 Crypto driver for Linux.
*
* Copyright (c) 2003-2016 Chelsio Communications, Inc. All rights reserved.
*
* This software is available to you under a choice of one of two
* licenses. You may choose to be licensed under the terms of the GNU
* General Public License (GPL) Version 2, available from the file
* COPYING in the main directory of this source tree, or the
* OpenIB.org BSD license below:
*
* Redistribution and use in source and binary forms, with or
* without modification, are permitted provided that the following
* conditions are met:
*
* - Redistributions of source code must retain the above
* copyright notice, this list of conditions and the following
* disclaimer.
*
* - Redistributions in binary form must reproduce the above
* copyright notice, this list of conditions and the following
* disclaimer in the documentation and/or other materials
* provided with the distribution.
*
* THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND,
* EXPRESS OR IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF
* MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE AND
* NONINFRINGEMENT. IN NO EVENT SHALL THE AUTHORS OR COPYRIGHT HOLDERS
* BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER LIABILITY, WHETHER IN AN
* ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM, OUT OF OR IN
* CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE
* SOFTWARE.
*
*/
#ifndef __CHCR_ALGO_H__
#define __CHCR_ALGO_H__
/* Crypto key context */
#define KEY_CONTEXT_CTX_LEN_S 24
#define KEY_CONTEXT_CTX_LEN_M 0xff
#define KEY_CONTEXT_CTX_LEN_V(x) ((x) << KEY_CONTEXT_CTX_LEN_S)
#define KEY_CONTEXT_CTX_LEN_G(x) \
(((x) >> KEY_CONTEXT_CTX_LEN_S) & KEY_CONTEXT_CTX_LEN_M)
#define KEY_CONTEXT_DUAL_CK_S 12
#define KEY_CONTEXT_DUAL_CK_M 0x1
#define KEY_CONTEXT_DUAL_CK_V(x) ((x) << KEY_CONTEXT_DUAL_CK_S)
#define KEY_CONTEXT_DUAL_CK_G(x) \
(((x) >> KEY_CONTEXT_DUAL_CK_S) & KEY_CONTEXT_DUAL_CK_M)
#define KEY_CONTEXT_DUAL_CK_F KEY_CONTEXT_DUAL_CK_V(1U)
#define KEY_CONTEXT_SALT_PRESENT_S 10
#define KEY_CONTEXT_SALT_PRESENT_M 0x1
#define KEY_CONTEXT_SALT_PRESENT_V(x) ((x) << KEY_CONTEXT_SALT_PRESENT_S)
#define KEY_CONTEXT_SALT_PRESENT_G(x) \
(((x) >> KEY_CONTEXT_SALT_PRESENT_S) & \
KEY_CONTEXT_SALT_PRESENT_M)
#define KEY_CONTEXT_SALT_PRESENT_F KEY_CONTEXT_SALT_PRESENT_V(1U)
#define KEY_CONTEXT_VALID_S 0
#define KEY_CONTEXT_VALID_M 0x1
#define KEY_CONTEXT_VALID_V(x) ((x) << KEY_CONTEXT_VALID_S)
#define KEY_CONTEXT_VALID_G(x) \
(((x) >> KEY_CONTEXT_VALID_S) & \
KEY_CONTEXT_VALID_M)
#define KEY_CONTEXT_VALID_F KEY_CONTEXT_VALID_V(1U)
#define KEY_CONTEXT_CK_SIZE_S 6
#define KEY_CONTEXT_CK_SIZE_M 0xf
#define KEY_CONTEXT_CK_SIZE_V(x) ((x) << KEY_CONTEXT_CK_SIZE_S)
#define KEY_CONTEXT_CK_SIZE_G(x) \
(((x) >> KEY_CONTEXT_CK_SIZE_S) & KEY_CONTEXT_CK_SIZE_M)
#define KEY_CONTEXT_MK_SIZE_S 2
#define KEY_CONTEXT_MK_SIZE_M 0xf
#define KEY_CONTEXT_MK_SIZE_V(x) ((x) << KEY_CONTEXT_MK_SIZE_S)
#define KEY_CONTEXT_MK_SIZE_G(x) \
(((x) >> KEY_CONTEXT_MK_SIZE_S) & KEY_CONTEXT_MK_SIZE_M)
#define KEY_CONTEXT_OPAD_PRESENT_S 11
#define KEY_CONTEXT_OPAD_PRESENT_M 0x1
#define KEY_CONTEXT_OPAD_PRESENT_V(x) ((x) << KEY_CONTEXT_OPAD_PRESENT_S)
#define KEY_CONTEXT_OPAD_PRESENT_G(x) \
(((x) >> KEY_CONTEXT_OPAD_PRESENT_S) & \
KEY_CONTEXT_OPAD_PRESENT_M)
#define KEY_CONTEXT_OPAD_PRESENT_F KEY_CONTEXT_OPAD_PRESENT_V(1U)
#define CHCR_HASH_MAX_DIGEST_SIZE 64
#define CHCR_MAX_SHA_DIGEST_SIZE 64
#define IPSEC_TRUNCATED_ICV_SIZE 12
#define TLS_TRUNCATED_HMAC_SIZE 10
#define CBCMAC_DIGEST_SIZE 16
#define MAX_HASH_NAME 20
#define SHA1_INIT_STATE_5X4B 5
#define SHA256_INIT_STATE_8X4B 8
#define SHA512_INIT_STATE_8X8B 8
#define SHA1_INIT_STATE SHA1_INIT_STATE_5X4B
#define SHA224_INIT_STATE SHA256_INIT_STATE_8X4B
#define SHA256_INIT_STATE SHA256_INIT_STATE_8X4B
#define SHA384_INIT_STATE SHA512_INIT_STATE_8X8B
#define SHA512_INIT_STATE SHA512_INIT_STATE_8X8B
#define DUMMY_BYTES 16
#define IPAD_DATA 0x36363636
#define OPAD_DATA 0x5c5c5c5c
#define TRANSHDR_SIZE(alignedkctx_len)\
(sizeof(struct ulptx_idata) +\
sizeof(struct ulp_txpkt) +\
sizeof(struct fw_crypto_lookaside_wr) +\
sizeof(struct cpl_tx_sec_pdu) +\
(alignedkctx_len))
#define CIPHER_TRANSHDR_SIZE(alignedkctx_len, sge_pairs) \
(TRANSHDR_SIZE(alignedkctx_len) + sge_pairs +\
sizeof(struct cpl_rx_phys_dsgl))
#define HASH_TRANSHDR_SIZE(alignedkctx_len)\
(TRANSHDR_SIZE(alignedkctx_len) + DUMMY_BYTES)
#define SEC_CPL_OFFSET (sizeof(struct fw_crypto_lookaside_wr) + \
sizeof(struct ulp_txpkt) + \
sizeof(struct ulptx_idata))
#define FILL_SEC_CPL_OP_IVINSR(id, len, hldr, ofst) \
htonl( \
CPL_TX_SEC_PDU_OPCODE_V(CPL_TX_SEC_PDU) | \
CPL_TX_SEC_PDU_RXCHID_V((id)) | \
CPL_TX_SEC_PDU_ACKFOLLOWS_V(0) | \
CPL_TX_SEC_PDU_ULPTXLPBK_V(1) | \
CPL_TX_SEC_PDU_CPLLEN_V((len)) | \
CPL_TX_SEC_PDU_PLACEHOLDER_V((hldr)) | \
CPL_TX_SEC_PDU_IVINSRTOFST_V((ofst)))
#define FILL_SEC_CPL_CIPHERSTOP_HI(a_start, a_stop, c_start, c_stop_hi) \
htonl( \
CPL_TX_SEC_PDU_AADSTART_V((a_start)) | \
CPL_TX_SEC_PDU_AADSTOP_V((a_stop)) | \
CPL_TX_SEC_PDU_CIPHERSTART_V((c_start)) | \
CPL_TX_SEC_PDU_CIPHERSTOP_HI_V((c_stop_hi)))
#define FILL_SEC_CPL_AUTHINSERT(c_stop_lo, a_start, a_stop, a_inst) \
htonl( \
CPL_TX_SEC_PDU_CIPHERSTOP_LO_V((c_stop_lo)) | \
CPL_TX_SEC_PDU_AUTHSTART_V((a_start)) | \
CPL_TX_SEC_PDU_AUTHSTOP_V((a_stop)) | \
CPL_TX_SEC_PDU_AUTHINSERT_V((a_inst)))
#define FILL_SEC_CPL_SCMD0_SEQNO(ctrl, seq, cmode, amode, opad, size, nivs) \
htonl( \
SCMD_SEQ_NO_CTRL_V(0) | \
SCMD_STATUS_PRESENT_V(0) | \
SCMD_PROTO_VERSION_V(CHCR_SCMD_PROTO_VERSION_GENERIC) | \
SCMD_ENC_DEC_CTRL_V((ctrl)) | \
SCMD_CIPH_AUTH_SEQ_CTRL_V((seq)) | \
SCMD_CIPH_MODE_V((cmode)) | \
SCMD_AUTH_MODE_V((amode)) | \
SCMD_HMAC_CTRL_V((opad)) | \
SCMD_IV_SIZE_V((size)) | \
SCMD_NUM_IVS_V((nivs)))
#define FILL_SEC_CPL_IVGEN_HDRLEN(last, more, ctx_in, mac, ivdrop, len) htonl( \
SCMD_ENB_DBGID_V(0) | \
SCMD_IV_GEN_CTRL_V(0) | \
SCMD_LAST_FRAG_V((last)) | \
SCMD_MORE_FRAGS_V((more)) | \
SCMD_TLS_COMPPDU_V(0) | \
SCMD_KEY_CTX_INLINE_V((ctx_in)) | \
SCMD_TLS_FRAG_ENABLE_V(0) | \
SCMD_MAC_ONLY_V((mac)) | \
SCMD_AADIVDROP_V((ivdrop)) | \
SCMD_HDR_LEN_V((len)))
#define FILL_KEY_CTX_HDR(ck_size, mk_size, d_ck, opad, ctx_len) \
htonl(KEY_CONTEXT_VALID_V(1) | \
KEY_CONTEXT_CK_SIZE_V((ck_size)) | \
KEY_CONTEXT_MK_SIZE_V(mk_size) | \
KEY_CONTEXT_DUAL_CK_V((d_ck)) | \
KEY_CONTEXT_OPAD_PRESENT_V((opad)) | \
KEY_CONTEXT_SALT_PRESENT_V(1) | \
KEY_CONTEXT_CTX_LEN_V((ctx_len)))
#define FILL_WR_OP_CCTX_SIZE(len, ctx_len) \
htonl( \
FW_CRYPTO_LOOKASIDE_WR_OPCODE_V( \
FW_CRYPTO_LOOKASIDE_WR) | \
FW_CRYPTO_LOOKASIDE_WR_COMPL_V(0) | \
FW_CRYPTO_LOOKASIDE_WR_IMM_LEN_V((len)) | \
FW_CRYPTO_LOOKASIDE_WR_CCTX_LOC_V(1) | \
FW_CRYPTO_LOOKASIDE_WR_CCTX_SIZE_V((ctx_len)))
#define FILL_WR_RX_Q_ID(cid, qid, wr_iv) \
htonl( \
FW_CRYPTO_LOOKASIDE_WR_RX_CHID_V((cid)) | \
FW_CRYPTO_LOOKASIDE_WR_RX_Q_ID_V((qid)) | \
FW_CRYPTO_LOOKASIDE_WR_LCB_V(0) | \
FW_CRYPTO_LOOKASIDE_WR_IV_V((wr_iv)))
#define FILL_ULPTX_CMD_DEST(cid) \
htonl(ULPTX_CMD_V(ULP_TX_PKT) | \
ULP_TXPKT_DEST_V(0) | \
ULP_TXPKT_DATAMODIFY_V(0) | \
ULP_TXPKT_CHANNELID_V((cid)) | \
ULP_TXPKT_RO_V(1) | \
ULP_TXPKT_FID_V(0))
#define KEYCTX_ALIGN_PAD(bs) ({unsigned int _bs = (bs);\
_bs == SHA1_DIGEST_SIZE ? 12 : 0; })
#define FILL_PLD_SIZE_HASH_SIZE(payload_sgl_len, sgl_lengths, total_frags) \
htonl(FW_CRYPTO_LOOKASIDE_WR_PLD_SIZE_V(payload_sgl_len ? \
sgl_lengths[total_frags] : 0) |\
FW_CRYPTO_LOOKASIDE_WR_HASH_SIZE_V(0))
#define FILL_LEN_PKD(calc_tx_flits_ofld, skb) \
htonl(FW_CRYPTO_LOOKASIDE_WR_LEN16_V(DIV_ROUND_UP((\
calc_tx_flits_ofld(skb) * 8), 16)))
#define FILL_CMD_MORE(immdatalen) htonl(ULPTX_CMD_V(ULP_TX_SC_IMM) |\
ULP_TX_SC_MORE_V((immdatalen) ? 0 : 1))
#define MAX_NK 8
#define CRYPTO_MAX_IMM_TX_PKT_LEN 256
struct algo_param {
unsigned int auth_mode;
unsigned int mk_size;
unsigned int result_size;
};
struct hash_wr_param {
unsigned int opad_needed;
unsigned int more;
unsigned int last;
struct algo_param alg_prm;
unsigned int sg_len;
unsigned int bfr_len;
u64 scmd1;
};
enum {
AES_KEYLENGTH_128BIT = 128,
AES_KEYLENGTH_192BIT = 192,
AES_KEYLENGTH_256BIT = 256
};
enum {
KEYLENGTH_3BYTES = 3,
KEYLENGTH_4BYTES = 4,
KEYLENGTH_6BYTES = 6,
KEYLENGTH_8BYTES = 8
};
enum {
NUMBER_OF_ROUNDS_10 = 10,
NUMBER_OF_ROUNDS_12 = 12,
NUMBER_OF_ROUNDS_14 = 14,
};
/*
* CCM defines values of 4, 6, 8, 10, 12, 14, and 16 octets,
* where they indicate the size of the integrity check value (ICV)
*/
enum {
AES_CCM_ICV_4 = 4,
AES_CCM_ICV_6 = 6,
AES_CCM_ICV_8 = 8,
AES_CCM_ICV_10 = 10,
AES_CCM_ICV_12 = 12,
AES_CCM_ICV_14 = 14,
AES_CCM_ICV_16 = 16
};
struct hash_op_params {
unsigned char mk_size;
unsigned char pad_align;
unsigned char auth_mode;
char hash_name[MAX_HASH_NAME];
unsigned short block_size;
unsigned short word_size;
unsigned short ipad_size;
};
struct phys_sge_pairs {
__be16 len[8];
__be64 addr[8];
};
struct phys_sge_parm {
unsigned int nents;
unsigned int obsize;
unsigned short qid;
unsigned char align;
};
struct crypto_result {
struct completion completion;
int err;
};
static const u32 sha1_init[SHA1_DIGEST_SIZE / 4] = {
SHA1_H0, SHA1_H1, SHA1_H2, SHA1_H3, SHA1_H4,
};
static const u32 sha224_init[SHA256_DIGEST_SIZE / 4] = {
SHA224_H0, SHA224_H1, SHA224_H2, SHA224_H3,
SHA224_H4, SHA224_H5, SHA224_H6, SHA224_H7,
};
static const u32 sha256_init[SHA256_DIGEST_SIZE / 4] = {
SHA256_H0, SHA256_H1, SHA256_H2, SHA256_H3,
SHA256_H4, SHA256_H5, SHA256_H6, SHA256_H7,
};
static const u64 sha384_init[SHA512_DIGEST_SIZE / 8] = {
SHA384_H0, SHA384_H1, SHA384_H2, SHA384_H3,
SHA384_H4, SHA384_H5, SHA384_H6, SHA384_H7,
};
static const u64 sha512_init[SHA512_DIGEST_SIZE / 8] = {
SHA512_H0, SHA512_H1, SHA512_H2, SHA512_H3,
SHA512_H4, SHA512_H5, SHA512_H6, SHA512_H7,
};
static inline void copy_hash_init_values(char *key, int digestsize)
{
u8 i;
__be32 *dkey = (__be32 *)key;
u64 *ldkey = (u64 *)key;
__be64 *sha384 = (__be64 *)sha384_init;
__be64 *sha512 = (__be64 *)sha512_init;
switch (digestsize) {
case SHA1_DIGEST_SIZE:
for (i = 0; i < SHA1_INIT_STATE; i++)
dkey[i] = cpu_to_be32(sha1_init[i]);
break;
case SHA224_DIGEST_SIZE:
for (i = 0; i < SHA224_INIT_STATE; i++)
dkey[i] = cpu_to_be32(sha224_init[i]);
break;
case SHA256_DIGEST_SIZE:
for (i = 0; i < SHA256_INIT_STATE; i++)
dkey[i] = cpu_to_be32(sha256_init[i]);
break;
case SHA384_DIGEST_SIZE:
for (i = 0; i < SHA384_INIT_STATE; i++)
ldkey[i] = be64_to_cpu(sha384[i]);
break;
case SHA512_DIGEST_SIZE:
for (i = 0; i < SHA512_INIT_STATE; i++)
ldkey[i] = be64_to_cpu(sha512[i]);
break;
}
}
static const u8 sgl_lengths[20] = {
0, 1, 2, 3, 4, 4, 5, 6, 7, 7, 8, 9, 10, 10, 11, 12, 13, 13, 14, 15
};
/* Number of len fields(8) * size of one addr field */
#define PHYSDSGL_MAX_LEN_SIZE 16
static inline u16 get_space_for_phys_dsgl(unsigned int sgl_entr)
{
/* len field size + addr field size */
return ((sgl_entr >> 3) + ((sgl_entr % 8) ?
1 : 0)) * PHYSDSGL_MAX_LEN_SIZE +
(sgl_entr << 3) + ((sgl_entr % 2 ? 1 : 0) << 3);
}
/* The AES s-transform matrix (s-box). */
static const u8 aes_sbox[256] = {
99, 124, 119, 123, 242, 107, 111, 197, 48, 1, 103, 43, 254, 215,
171, 118, 202, 130, 201, 125, 250, 89, 71, 240, 173, 212, 162, 175,
156, 164, 114, 192, 183, 253, 147, 38, 54, 63, 247, 204, 52, 165,
229, 241, 113, 216, 49, 21, 4, 199, 35, 195, 24, 150, 5, 154, 7,
18, 128, 226, 235, 39, 178, 117, 9, 131, 44, 26, 27, 110, 90,
160, 82, 59, 214, 179, 41, 227, 47, 132, 83, 209, 0, 237, 32,
252, 177, 91, 106, 203, 190, 57, 74, 76, 88, 207, 208, 239, 170,
251, 67, 77, 51, 133, 69, 249, 2, 127, 80, 60, 159, 168, 81,
163, 64, 143, 146, 157, 56, 245, 188, 182, 218, 33, 16, 255, 243,
210, 205, 12, 19, 236, 95, 151, 68, 23, 196, 167, 126, 61, 100,
93, 25, 115, 96, 129, 79, 220, 34, 42, 144, 136, 70, 238, 184,
20, 222, 94, 11, 219, 224, 50, 58, 10, 73, 6, 36, 92, 194,
211, 172, 98, 145, 149, 228, 121, 231, 200, 55, 109, 141, 213, 78,
169, 108, 86, 244, 234, 101, 122, 174, 8, 186, 120, 37, 46, 28, 166,
180, 198, 232, 221, 116, 31, 75, 189, 139, 138, 112, 62, 181, 102,
72, 3, 246, 14, 97, 53, 87, 185, 134, 193, 29, 158, 225, 248,
152, 17, 105, 217, 142, 148, 155, 30, 135, 233, 206, 85, 40, 223,
140, 161, 137, 13, 191, 230, 66, 104, 65, 153, 45, 15, 176, 84,
187, 22
};
static u32 aes_ks_subword(const u32 w)
{
u8 bytes[4];
*(u32 *)(&bytes[0]) = w;
bytes[0] = aes_sbox[bytes[0]];
bytes[1] = aes_sbox[bytes[1]];
bytes[2] = aes_sbox[bytes[2]];
bytes[3] = aes_sbox[bytes[3]];
return *(u32 *)(&bytes[0]);
}
static u32 round_constant[11] = {
0x01000000, 0x02000000, 0x04000000, 0x08000000,
0x10000000, 0x20000000, 0x40000000, 0x80000000,
0x1B000000, 0x36000000, 0x6C000000
};
/* dec_key - OUTPUT - Reverse round key
* key - INPUT - key
* keylength - INPUT - length of the key in number of bits
*/
static inline void get_aes_decrypt_key(unsigned char *dec_key,
const unsigned char *key,
unsigned int keylength)
{
u32 temp;
u32 w_ring[MAX_NK];
int i, j, k = 0;
u8 nr, nk;
switch (keylength) {
case AES_KEYLENGTH_128BIT:
nk = KEYLENGTH_4BYTES;
nr = NUMBER_OF_ROUNDS_10;
break;
case AES_KEYLENGTH_192BIT:
nk = KEYLENGTH_6BYTES;
nr = NUMBER_OF_ROUNDS_12;
break;
case AES_KEYLENGTH_256BIT:
nk = KEYLENGTH_8BYTES;
nr = NUMBER_OF_ROUNDS_14;
break;
default:
return;
}
for (i = 0; i < nk; i++ )
w_ring[i] = be32_to_cpu(*(u32 *)&key[4 * i]);
i = 0;
temp = w_ring[nk - 1];
while(i + nk < (nr + 1) * 4) {
if(!(i % nk)) {
/* RotWord(temp) */
temp = (temp << 8) | (temp >> 24);
temp = aes_ks_subword(temp);
temp ^= round_constant[i / nk];
}
else if (nk == 8 && (i % 4 == 0))
temp = aes_ks_subword(temp);
w_ring[i % nk] ^= temp;
temp = w_ring[i % nk];
i++;
}
for (k = 0, j = i % nk; k < nk; k++) {
*((u32 *)dec_key + k) = htonl(w_ring[j]);
j--;
if(j < 0)
j += nk;
}
}
#endif /* __CHCR_ALGO_H__ */