include/uapi/linux/qcedev.h - kernel/msm - Git at Google

 #ifndef _UAPI_QCEDEV__H
 #define _UAPI_QCEDEV__H

 #include <linux/types.h>
 #include <linux/ioctl.h>
 #include "fips_status.h"

 #define QCEDEV_MAX_SHA_BLOCK_SIZE	64
 #define QCEDEV_MAX_BEARER	31
 #define QCEDEV_MAX_KEY_SIZE	64
 #define QCEDEV_MAX_IV_SIZE	32

 #define QCEDEV_MAX_BUFFERS      16
 #define QCEDEV_MAX_SHA_DIGEST	32

 #define QCEDEV_USE_PMEM		1
 #define QCEDEV_NO_PMEM		0

 #define QCEDEV_AES_KEY_128	16
 #define QCEDEV_AES_KEY_192	24
 #define QCEDEV_AES_KEY_256	32
 /**
  *qcedev_oper_enum: Operation types
  * @QCEDEV_OPER_ENC:		Encrypt
  * @QCEDEV_OPER_DEC:		Decrypt
  * @QCEDEV_OPER_ENC_NO_KEY:	Encrypt. Do not need key to be specified by
  *				user. Key already set by an external processor.
  * @QCEDEV_OPER_DEC_NO_KEY:	Decrypt. Do not need the key to be specified by
  *				user. Key already set by an external processor.
  */
 enum qcedev_oper_enum {
 	QCEDEV_OPER_DEC		= 0,
 	QCEDEV_OPER_ENC		= 1,
 	QCEDEV_OPER_DEC_NO_KEY	= 2,
 	QCEDEV_OPER_ENC_NO_KEY	= 3,
 	QCEDEV_OPER_LAST
 };

 /**
  *qcedev_oper_enum: Cipher algorithm types
  * @QCEDEV_ALG_DES:		DES
  * @QCEDEV_ALG_3DES:		3DES
  * @QCEDEV_ALG_AES:		AES
  */
 enum qcedev_cipher_alg_enum {
 	QCEDEV_ALG_DES		= 0,
 	QCEDEV_ALG_3DES		= 1,
 	QCEDEV_ALG_AES		= 2,
 	QCEDEV_ALG_LAST
 };

 /**
  *qcedev_cipher_mode_enum : AES mode
  * @QCEDEV_AES_MODE_CBC:		CBC
  * @QCEDEV_AES_MODE_ECB:		ECB
  * @QCEDEV_AES_MODE_CTR:		CTR
  * @QCEDEV_AES_MODE_XTS:		XTS
  * @QCEDEV_AES_MODE_CCM:		CCM
  * @QCEDEV_DES_MODE_CBC:		CBC
  * @QCEDEV_DES_MODE_ECB:		ECB
  */
 enum qcedev_cipher_mode_enum {
 	QCEDEV_AES_MODE_CBC	= 0,
 	QCEDEV_AES_MODE_ECB	= 1,
 	QCEDEV_AES_MODE_CTR	= 2,
 	QCEDEV_AES_MODE_XTS	= 3,
 	QCEDEV_AES_MODE_CCM	= 4,
 	QCEDEV_DES_MODE_CBC	= 5,
 	QCEDEV_DES_MODE_ECB	= 6,
 	QCEDEV_AES_DES_MODE_LAST
 };

 /**
  *enum qcedev_sha_alg_enum : Secure Hashing Algorithm
  * @QCEDEV_ALG_SHA1:		Digest returned: 20 bytes (160 bits)
  * @QCEDEV_ALG_SHA256:		Digest returned: 32 bytes (256 bit)
  * @QCEDEV_ALG_SHA1_HMAC:	HMAC returned 20 bytes (160 bits)
  * @QCEDEV_ALG_SHA256_HMAC:	HMAC returned 32 bytes (256 bit)
  * @QCEDEV_ALG_AES_CMAC:		Configurable MAC size
  */
 enum qcedev_sha_alg_enum {
 	QCEDEV_ALG_SHA1		= 0,
 	QCEDEV_ALG_SHA256	= 1,
 	QCEDEV_ALG_SHA1_HMAC	= 2,
 	QCEDEV_ALG_SHA256_HMAC	= 3,
 	QCEDEV_ALG_AES_CMAC	= 4,
 	QCEDEV_ALG_SHA_ALG_LAST
 };

 /**
  * struct buf_info - Buffer information
  * @offset:			Offset from the base address of the buffer
  *				(Used when buffer is allocated using PMEM)
  * @vaddr:			Virtual buffer address pointer
  * @len:				Size of the buffer
  */
 struct	buf_info {
 	union {
 		uint32_t	offset;
 		uint8_t		*vaddr;
 	};
 	uint32_t	len;
 };

 /**
  * struct qcedev_vbuf_info - Source and destination Buffer information
  * @src:				Array of buf_info for input/source
  * @dst:				Array of buf_info for output/destination
  */
 struct	qcedev_vbuf_info {
 	struct buf_info	src[QCEDEV_MAX_BUFFERS];
 	struct buf_info	dst[QCEDEV_MAX_BUFFERS];
 };

 /**
  * struct qcedev_pmem_info - Stores PMEM buffer information
  * @fd_src:			Handle to /dev/adsp_pmem used to allocate
  *				memory for input/src buffer
  * @src:				Array of buf_info for input/source
  * @fd_dst:			Handle to /dev/adsp_pmem used to allocate
  *				memory for output/dst buffer
  * @dst:				Array of buf_info for output/destination
  * @pmem_src_offset:		The offset from input/src buffer
  *				(allocated by PMEM)
  */
 struct	qcedev_pmem_info {
 	int		fd_src;
 	struct buf_info	src[QCEDEV_MAX_BUFFERS];
 	int		fd_dst;
 	struct buf_info	dst[QCEDEV_MAX_BUFFERS];
 };

 /**
  * struct qcedev_cipher_op_req - Holds the ciphering request information
  * @use_pmem (IN):	Flag to indicate if buffer source is PMEM
  *			QCEDEV_USE_PMEM/QCEDEV_NO_PMEM
  * @pmem (IN):		Stores PMEM buffer information.
  *			Refer struct qcedev_pmem_info
  * @vbuf (IN/OUT):	Stores Source and destination Buffer information
  *			Refer to struct qcedev_vbuf_info
  * @data_len (IN):	Total Length of input/src and output/dst in bytes
  * @in_place_op (IN):	Indicates whether the operation is inplace where
  *			source == destination
  *			When using PMEM allocated memory, must set this to 1
  * @enckey (IN):		128 bits of confidentiality key
  *			enckey[0] bit 127-120, enckey[1] bit 119-112,..
  *			enckey[15] bit 7-0
  * @encklen (IN):	Length of the encryption key(set to 128  bits/16
  *			bytes in the driver)
  * @iv (IN/OUT):		Initialisation vector data
  *			This is updated by the driver, incremented by
  *			number of blocks encrypted/decrypted.
  * @ivlen (IN):		Length of the IV
  * @byteoffset (IN):	Offset in the Cipher BLOCK (applicable and to be set
  *			for AES-128 CTR mode only)
  * @alg (IN):		Type of ciphering algorithm: AES/DES/3DES
  * @mode (IN):		Mode use when using AES algorithm: ECB/CBC/CTR
  *			Apllicabel when using AES algorithm only
  * @op (IN):		Type of operation: QCEDEV_OPER_DEC/QCEDEV_OPER_ENC or
  *			QCEDEV_OPER_ENC_NO_KEY/QCEDEV_OPER_DEC_NO_KEY
  *
  *If use_pmem is set to 0, the driver assumes that memory was not allocated
  * via PMEM, and kernel will need to allocate memory and copy data from user
  * space buffer (data_src/dta_dst) and process accordingly and copy data back
  * to the user space buffer
  *
  * If use_pmem is set to 1, the driver assumes that memory was allocated via
  * PMEM.
  * The kernel driver will use the fd_src to determine the kernel virtual address
  * base that maps to the user space virtual address base for the  buffer
  * allocated in user space.
  * The final input/src and output/dst buffer pointer will be determined
  * by adding the offsets to the kernel virtual addr.
  *
  * If use of hardware key is supported in the target, user can configure the
  * key parameters (encklen, enckey) to use the hardware key.
  * In order to use the hardware key, set encklen to 0 and set the enckey
  * data array to 0.
  */
 struct	qcedev_cipher_op_req {
 	uint8_t				use_pmem;
 	union {
 		struct qcedev_pmem_info	pmem;
 		struct qcedev_vbuf_info	vbuf;
 	};
 	uint32_t			entries;
 	uint32_t			data_len;
 	uint8_t				in_place_op;
 	uint8_t				enckey[QCEDEV_MAX_KEY_SIZE];
 	uint32_t			encklen;
 	uint8_t				iv[QCEDEV_MAX_IV_SIZE];
 	uint32_t			ivlen;
 	uint32_t			byteoffset;
 	enum qcedev_cipher_alg_enum	alg;
 	enum qcedev_cipher_mode_enum	mode;
 	enum qcedev_oper_enum		op;
 };

 /**
  * struct qcedev_sha_op_req - Holds the hashing request information
  * @data (IN):			Array of pointers to the data to be hashed
  * @entries (IN):		Number of buf_info entries in the data array
  * @data_len (IN):		Length of data to be hashed
  * @digest (IN/OUT):		Returns the hashed data information
  * @diglen (OUT):		Size of the hashed/digest data
  * @authkey (IN):		Pointer to authentication key for HMAC
  * @authklen (IN):		Size of the authentication key
  * @alg (IN):			Secure Hash algorithm
  */
 struct	qcedev_sha_op_req {
 	struct buf_info			data[QCEDEV_MAX_BUFFERS];
 	uint32_t			entries;
 	uint32_t			data_len;
 	uint8_t				digest[QCEDEV_MAX_SHA_DIGEST];
 	uint32_t			diglen;
 	uint8_t				*authkey;
 	uint32_t			authklen;
 	enum qcedev_sha_alg_enum	alg;
 };

 /**
  * struct qfips_verify_t - Holds data for FIPS Integrity test
  * @kernel_size  (IN):		Size of kernel Image
  * @kernel       (IN):		pointer to buffer containing the kernel Image
  */
 struct qfips_verify_t {
 	unsigned int kernel_size;
 	void *kernel;
 };

 /**
  * struct qcedev_map_buf_req - Holds the mapping request information
  * fd (IN):            Array of fds.
  * num_fds (IN):       Number of fds in fd[].
  * fd_size (IN):       Array of sizes corresponding to each fd in fd[].
  * fd_offset (IN):     Array of offset corresponding to each fd in fd[].
  * vaddr (OUT):        Array of mapped virtual address corresponding to
  *			each fd in fd[].
  */
 struct qcedev_map_buf_req {
 	int32_t         fd[QCEDEV_MAX_BUFFERS];
 	uint32_t        num_fds;
 	uint32_t        fd_size[QCEDEV_MAX_BUFFERS];
 	uint32_t        fd_offset[QCEDEV_MAX_BUFFERS];
 	uint64_t        buf_vaddr[QCEDEV_MAX_BUFFERS];
 };

 /**
  * struct qcedev_unmap_buf_req - Holds the hashing request information
  * fd (IN):            Array of fds to unmap
  * num_fds (IN):       Number of fds in fd[].
  */
 struct  qcedev_unmap_buf_req {
 	int32_t         fd[QCEDEV_MAX_BUFFERS];
 	uint32_t        num_fds;
 };

 struct file;

 #define QCEDEV_IOC_MAGIC	0x87

 #define QCEDEV_IOCTL_ENC_REQ		\
 	_IOWR(QCEDEV_IOC_MAGIC, 1, struct qcedev_cipher_op_req)
 #define QCEDEV_IOCTL_DEC_REQ		\
 	_IOWR(QCEDEV_IOC_MAGIC, 2, struct qcedev_cipher_op_req)
 #define QCEDEV_IOCTL_SHA_INIT_REQ	\
 	_IOWR(QCEDEV_IOC_MAGIC, 3, struct qcedev_sha_op_req)
 #define QCEDEV_IOCTL_SHA_UPDATE_REQ	\
 	_IOWR(QCEDEV_IOC_MAGIC, 4, struct qcedev_sha_op_req)
 #define QCEDEV_IOCTL_SHA_FINAL_REQ	\
 	_IOWR(QCEDEV_IOC_MAGIC, 5, struct qcedev_sha_op_req)
 #define QCEDEV_IOCTL_GET_SHA_REQ	\
 	_IOWR(QCEDEV_IOC_MAGIC, 6, struct qcedev_sha_op_req)
 #define QCEDEV_IOCTL_LOCK_CE	\
 	_IO(QCEDEV_IOC_MAGIC, 7)
 #define QCEDEV_IOCTL_UNLOCK_CE	\
 	_IO(QCEDEV_IOC_MAGIC, 8)
 #define QCEDEV_IOCTL_GET_CMAC_REQ	\
 	_IOWR(QCEDEV_IOC_MAGIC, 9, struct qcedev_sha_op_req)
 #define QCEDEV_IOCTL_MAP_BUF_REQ	\
 	_IOWR(QCEDEV_IOC_MAGIC, 10, struct qcedev_map_buf_req)
 #define QCEDEV_IOCTL_UNMAP_BUF_REQ	\
 	_IOWR(QCEDEV_IOC_MAGIC, 11, struct qcedev_unmap_buf_req)
 #endif /* _UAPI_QCEDEV__H */
	#ifndef _UAPI_QCEDEV__H
	#define _UAPI_QCEDEV__H

	#include <linux/types.h>
	#include <linux/ioctl.h>
	#include "fips_status.h"

	#define QCEDEV_MAX_SHA_BLOCK_SIZE 64
	#define QCEDEV_MAX_BEARER 31
	#define QCEDEV_MAX_KEY_SIZE 64
	#define QCEDEV_MAX_IV_SIZE 32

	#define QCEDEV_MAX_BUFFERS 16
	#define QCEDEV_MAX_SHA_DIGEST 32

	#define QCEDEV_USE_PMEM 1
	#define QCEDEV_NO_PMEM 0

	#define QCEDEV_AES_KEY_128 16
	#define QCEDEV_AES_KEY_192 24
	#define QCEDEV_AES_KEY_256 32
	/**
	*qcedev_oper_enum: Operation types
	* @QCEDEV_OPER_ENC: Encrypt
	* @QCEDEV_OPER_DEC: Decrypt
	* @QCEDEV_OPER_ENC_NO_KEY: Encrypt. Do not need key to be specified by
	* user. Key already set by an external processor.
	* @QCEDEV_OPER_DEC_NO_KEY: Decrypt. Do not need the key to be specified by
	* user. Key already set by an external processor.
	*/
	enum qcedev_oper_enum {
	QCEDEV_OPER_DEC = 0,
	QCEDEV_OPER_ENC = 1,
	QCEDEV_OPER_DEC_NO_KEY = 2,
	QCEDEV_OPER_ENC_NO_KEY = 3,
	QCEDEV_OPER_LAST
	};

	/**
	*qcedev_oper_enum: Cipher algorithm types
	* @QCEDEV_ALG_DES: DES
	* @QCEDEV_ALG_3DES: 3DES
	* @QCEDEV_ALG_AES: AES
	*/
	enum qcedev_cipher_alg_enum {
	QCEDEV_ALG_DES = 0,
	QCEDEV_ALG_3DES = 1,
	QCEDEV_ALG_AES = 2,
	QCEDEV_ALG_LAST
	};

	/**
	*qcedev_cipher_mode_enum : AES mode
	* @QCEDEV_AES_MODE_CBC: CBC
	* @QCEDEV_AES_MODE_ECB: ECB
	* @QCEDEV_AES_MODE_CTR: CTR
	* @QCEDEV_AES_MODE_XTS: XTS
	* @QCEDEV_AES_MODE_CCM: CCM
	* @QCEDEV_DES_MODE_CBC: CBC
	* @QCEDEV_DES_MODE_ECB: ECB
	*/
	enum qcedev_cipher_mode_enum {
	QCEDEV_AES_MODE_CBC = 0,
	QCEDEV_AES_MODE_ECB = 1,
	QCEDEV_AES_MODE_CTR = 2,
	QCEDEV_AES_MODE_XTS = 3,
	QCEDEV_AES_MODE_CCM = 4,
	QCEDEV_DES_MODE_CBC = 5,
	QCEDEV_DES_MODE_ECB = 6,
	QCEDEV_AES_DES_MODE_LAST
	};

	/**
	*enum qcedev_sha_alg_enum : Secure Hashing Algorithm
	* @QCEDEV_ALG_SHA1: Digest returned: 20 bytes (160 bits)
	* @QCEDEV_ALG_SHA256: Digest returned: 32 bytes (256 bit)
	* @QCEDEV_ALG_SHA1_HMAC: HMAC returned 20 bytes (160 bits)
	* @QCEDEV_ALG_SHA256_HMAC: HMAC returned 32 bytes (256 bit)
	* @QCEDEV_ALG_AES_CMAC: Configurable MAC size
	*/
	enum qcedev_sha_alg_enum {
	QCEDEV_ALG_SHA1 = 0,
	QCEDEV_ALG_SHA256 = 1,
	QCEDEV_ALG_SHA1_HMAC = 2,
	QCEDEV_ALG_SHA256_HMAC = 3,
	QCEDEV_ALG_AES_CMAC = 4,
	QCEDEV_ALG_SHA_ALG_LAST
	};

	/**
	* struct buf_info - Buffer information
	* @offset: Offset from the base address of the buffer
	* (Used when buffer is allocated using PMEM)
	* @vaddr: Virtual buffer address pointer
	* @len: Size of the buffer
	*/
	struct buf_info {
	union {
	uint32_t offset;
	uint8_t *vaddr;
	};
	uint32_t len;
	};

	/**
	* struct qcedev_vbuf_info - Source and destination Buffer information
	* @src: Array of buf_info for input/source
	* @dst: Array of buf_info for output/destination
	*/
	struct qcedev_vbuf_info {
	struct buf_info src[QCEDEV_MAX_BUFFERS];
	struct buf_info dst[QCEDEV_MAX_BUFFERS];
	};

	/**
	* struct qcedev_pmem_info - Stores PMEM buffer information
	* @fd_src: Handle to /dev/adsp_pmem used to allocate
	* memory for input/src buffer
	* @src: Array of buf_info for input/source
	* @fd_dst: Handle to /dev/adsp_pmem used to allocate
	* memory for output/dst buffer
	* @dst: Array of buf_info for output/destination
	* @pmem_src_offset: The offset from input/src buffer
	* (allocated by PMEM)
	*/
	struct qcedev_pmem_info {
	int fd_src;
	struct buf_info src[QCEDEV_MAX_BUFFERS];
	int fd_dst;
	struct buf_info dst[QCEDEV_MAX_BUFFERS];
	};

	/**
	* struct qcedev_cipher_op_req - Holds the ciphering request information
	* @use_pmem (IN): Flag to indicate if buffer source is PMEM
	* QCEDEV_USE_PMEM/QCEDEV_NO_PMEM
	* @pmem (IN): Stores PMEM buffer information.
	* Refer struct qcedev_pmem_info
	* @vbuf (IN/OUT): Stores Source and destination Buffer information
	* Refer to struct qcedev_vbuf_info
	* @data_len (IN): Total Length of input/src and output/dst in bytes
	* @in_place_op (IN): Indicates whether the operation is inplace where
	* source == destination
	* When using PMEM allocated memory, must set this to 1
	* @enckey (IN): 128 bits of confidentiality key
	* enckey[0] bit 127-120, enckey[1] bit 119-112,..
	* enckey[15] bit 7-0
	* @encklen (IN): Length of the encryption key(set to 128 bits/16
	* bytes in the driver)
	* @iv (IN/OUT): Initialisation vector data
	* This is updated by the driver, incremented by
	* number of blocks encrypted/decrypted.
	* @ivlen (IN): Length of the IV
	* @byteoffset (IN): Offset in the Cipher BLOCK (applicable and to be set
	* for AES-128 CTR mode only)
	* @alg (IN): Type of ciphering algorithm: AES/DES/3DES
	* @mode (IN): Mode use when using AES algorithm: ECB/CBC/CTR
	* Apllicabel when using AES algorithm only
	* @op (IN): Type of operation: QCEDEV_OPER_DEC/QCEDEV_OPER_ENC or
	* QCEDEV_OPER_ENC_NO_KEY/QCEDEV_OPER_DEC_NO_KEY
	*
	*If use_pmem is set to 0, the driver assumes that memory was not allocated
	* via PMEM, and kernel will need to allocate memory and copy data from user
	* space buffer (data_src/dta_dst) and process accordingly and copy data back
	* to the user space buffer
	*
	* If use_pmem is set to 1, the driver assumes that memory was allocated via
	* PMEM.
	* The kernel driver will use the fd_src to determine the kernel virtual address
	* base that maps to the user space virtual address base for the buffer
	* allocated in user space.
	* The final input/src and output/dst buffer pointer will be determined
	* by adding the offsets to the kernel virtual addr.
	*
	* If use of hardware key is supported in the target, user can configure the
	* key parameters (encklen, enckey) to use the hardware key.
	* In order to use the hardware key, set encklen to 0 and set the enckey
	* data array to 0.
	*/
	struct qcedev_cipher_op_req {
	uint8_t use_pmem;
	union {
	struct qcedev_pmem_info pmem;
	struct qcedev_vbuf_info vbuf;
	};
	uint32_t entries;
	uint32_t data_len;
	uint8_t in_place_op;
	uint8_t enckey[QCEDEV_MAX_KEY_SIZE];
	uint32_t encklen;
	uint8_t iv[QCEDEV_MAX_IV_SIZE];
	uint32_t ivlen;
	uint32_t byteoffset;
	enum qcedev_cipher_alg_enum alg;
	enum qcedev_cipher_mode_enum mode;
	enum qcedev_oper_enum op;
	};

	/**
	* struct qcedev_sha_op_req - Holds the hashing request information
	* @data (IN): Array of pointers to the data to be hashed
	* @entries (IN): Number of buf_info entries in the data array
	* @data_len (IN): Length of data to be hashed
	* @digest (IN/OUT): Returns the hashed data information
	* @diglen (OUT): Size of the hashed/digest data
	* @authkey (IN): Pointer to authentication key for HMAC
	* @authklen (IN): Size of the authentication key
	* @alg (IN): Secure Hash algorithm
	*/
	struct qcedev_sha_op_req {
	struct buf_info data[QCEDEV_MAX_BUFFERS];
	uint32_t entries;
	uint32_t data_len;
	uint8_t digest[QCEDEV_MAX_SHA_DIGEST];
	uint32_t diglen;
	uint8_t *authkey;
	uint32_t authklen;
	enum qcedev_sha_alg_enum alg;
	};

	/**
	* struct qfips_verify_t - Holds data for FIPS Integrity test
	* @kernel_size (IN): Size of kernel Image
	* @kernel (IN): pointer to buffer containing the kernel Image
	*/
	struct qfips_verify_t {
	unsigned int kernel_size;
	void *kernel;
	};

	/**
	* struct qcedev_map_buf_req - Holds the mapping request information
	* fd (IN): Array of fds.
	* num_fds (IN): Number of fds in fd[].
	* fd_size (IN): Array of sizes corresponding to each fd in fd[].
	* fd_offset (IN): Array of offset corresponding to each fd in fd[].
	* vaddr (OUT): Array of mapped virtual address corresponding to
	* each fd in fd[].
	*/
	struct qcedev_map_buf_req {
	int32_t fd[QCEDEV_MAX_BUFFERS];
	uint32_t num_fds;
	uint32_t fd_size[QCEDEV_MAX_BUFFERS];
	uint32_t fd_offset[QCEDEV_MAX_BUFFERS];
	uint64_t buf_vaddr[QCEDEV_MAX_BUFFERS];
	};

	/**
	* struct qcedev_unmap_buf_req - Holds the hashing request information
	* fd (IN): Array of fds to unmap
	* num_fds (IN): Number of fds in fd[].
	*/
	struct qcedev_unmap_buf_req {
	int32_t fd[QCEDEV_MAX_BUFFERS];
	uint32_t num_fds;
	};

	struct file;

	#define QCEDEV_IOC_MAGIC 0x87

	#define QCEDEV_IOCTL_ENC_REQ \
	_IOWR(QCEDEV_IOC_MAGIC, 1, struct qcedev_cipher_op_req)
	#define QCEDEV_IOCTL_DEC_REQ \
	_IOWR(QCEDEV_IOC_MAGIC, 2, struct qcedev_cipher_op_req)
	#define QCEDEV_IOCTL_SHA_INIT_REQ \
	_IOWR(QCEDEV_IOC_MAGIC, 3, struct qcedev_sha_op_req)
	#define QCEDEV_IOCTL_SHA_UPDATE_REQ \
	_IOWR(QCEDEV_IOC_MAGIC, 4, struct qcedev_sha_op_req)
	#define QCEDEV_IOCTL_SHA_FINAL_REQ \
	_IOWR(QCEDEV_IOC_MAGIC, 5, struct qcedev_sha_op_req)
	#define QCEDEV_IOCTL_GET_SHA_REQ \
	_IOWR(QCEDEV_IOC_MAGIC, 6, struct qcedev_sha_op_req)
	#define QCEDEV_IOCTL_LOCK_CE \
	_IO(QCEDEV_IOC_MAGIC, 7)
	#define QCEDEV_IOCTL_UNLOCK_CE \
	_IO(QCEDEV_IOC_MAGIC, 8)
	#define QCEDEV_IOCTL_GET_CMAC_REQ \
	_IOWR(QCEDEV_IOC_MAGIC, 9, struct qcedev_sha_op_req)
	#define QCEDEV_IOCTL_MAP_BUF_REQ \
	_IOWR(QCEDEV_IOC_MAGIC, 10, struct qcedev_map_buf_req)
	#define QCEDEV_IOCTL_UNMAP_BUF_REQ \
	_IOWR(QCEDEV_IOC_MAGIC, 11, struct qcedev_unmap_buf_req)
	#endif /* _UAPI_QCEDEV__H */