include/crypto/cipher_structs.h - third_party/github/zephyrproject-rtos/zephyr - Git at Google

 /*
  * Copyright (c) 2016 Intel Corporation.
  *
  * SPDX-License-Identifier: Apache-2.0
  */

 /**
  * @file
  * @brief Crypto Cipher structure definitions
  *
  * This file contains the Crypto Abstraction layer structures.
  *
  * [Experimental] Users should note that the Structures can change
  * as a part of ongoing development.
  */

 #ifndef ZEPHYR_INCLUDE_CRYPTO_CIPHER_STRUCTS_H_
 #define ZEPHYR_INCLUDE_CRYPTO_CIPHER_STRUCTS_H_

 #include <device.h>
 #include <misc/util.h>

 enum cipher_algo {
 	CRYPTO_CIPHER_ALGO_AES = 1,
 };

 enum cipher_op {
 	CRYPTO_CIPHER_OP_DECRYPT = 0,
 	CRYPTO_CIPHER_OP_ENCRYPT = 1,
 };

 /* Possible cipher mode options. More to be
  * added as required.
  */

 enum cipher_mode {
 	CRYPTO_CIPHER_MODE_ECB = 1,
 	CRYPTO_CIPHER_MODE_CBC = 2,
 	CRYPTO_CIPHER_MODE_CTR = 3,
 	CRYPTO_CIPHER_MODE_CCM = 4,
 };

 /* Forward declarations */
 struct cipher_aead_pkt;
 struct cipher_ctx;
 struct cipher_pkt;

 typedef int (*block_op_t)(struct cipher_ctx *ctx, struct cipher_pkt *pkt);

 /* Function signatures for encryption/ decryption using standard cipher modes
  * like  CBC, CTR, CCM.
  */
 typedef int (*cbc_op_t)(struct cipher_ctx *ctx, struct cipher_pkt *pkt,
 			u8_t *iv);

 typedef int (*ctr_op_t)(struct cipher_ctx *ctx, struct cipher_pkt *pkt,
 			u8_t *ctr);

 typedef int (*ccm_op_t)(struct cipher_ctx *ctx, struct cipher_aead_pkt *pkt,
 			 u8_t *nonce);

 struct cipher_ops {

 	enum cipher_mode cipher_mode;

 	union {
 		block_op_t	block_crypt_hndlr;
 		cbc_op_t	cbc_crypt_hndlr;
 		ctr_op_t	ctr_crypt_hndlr;
 		ccm_op_t	ccm_crypt_hndlr;
 	};
 };

 struct ccm_params {
 	u16_t tag_len;
 	u16_t nonce_len;
 };

 struct ctr_params {
 	/* CTR mode counter is a split counter composed of iv and counter
 	 * such that ivlen + ctr_len = keylen
 	 */
 	u32_t ctr_len;
 };

 /* Structure encoding session parameters. Refer to comments for individual
  * fields to know the contract in terms of who fills what and when w.r.t
  * begin_session() call.
  */
 struct cipher_ctx {

 	/* Place for driver to return function pointers to be invoked per
 	 * cipher operation. To be populated by crypto driver on return from
 	 * begin_session() based on the algo/mode chosen by the app.
 	 */
 	struct cipher_ops ops;

 	/* To be populated by the app before calling begin_session() */
 	union {
 		/* Cryptographic key to be used in this session */
 		u8_t *bit_stream;
 		/* For cases where  key is protected and is not
 		 * available to caller
 		 */
 		void *handle;
 	} key;

 	/* The device driver instance this crypto context relates to. Will be
 	 * populated by the begin_session() API.
 	 */
 	struct device *device;

 	/* If the driver supports multiple simultaneously crypto sessions, this
 	 * will identify the specific driver state this crypto session relates
 	 * to. Since dynamic memory allocation is is not possible, it is
 	 * suggested that at build time drivers allocate space for the
 	 * max simultaneous sessions they intend to support. To be populated
 	 * by the driver on return from begin_session()
 	 */
 	void *drv_sessn_state;

 	/* Place for the app to put info relevant stuff for resuming when
 	 * completion call back happens for async ops. Totally managed by the
 	 * app.
 	 */
 	void *app_sessn_state;


 	/* Standard mode parameters, which remain constant for all ops
 	 * in a session. To be populated by the app before calling
 	 * begin_session()
 	 */
 	union {
 		struct ccm_params ccm_info;
 		struct ctr_params ctr_info;

 	} mode_params;


 	/* Cryptographic keylength in bytes. To be populated by the app
 	 * before calling begin_session()
 	 */
 	u16_t  keylen;


 	/* How certain fields are to be interpreted for this sesssion.
 	 * To be populated by the app before calling begin_session().
 	 * An app can obtain the capability flags supported by a hw/driver
 	 * by calling cipher_query_hwcaps(). (A bitmask of CAP_* below)
 	 */
 	u16_t flags;
 };

 /* Various cipher_ctx.flags options. Not all drivers support all flags.
  * An app can query the supported hw / driver
  * capabilities via provided API (cipher_query_hwcaps()), and choose a
  * supported config during the session setup.
  */
 #define CAP_OPAQUE_KEY_HNDL		BIT(0)
 #define CAP_RAW_KEY			BIT(1)

 /* TBD to define */
 #define CAP_KEY_LOADING_API		BIT(2)

 /* Whether the output is placed in separate buffer or not */
 #define CAP_INPLACE_OPS			BIT(3)
 #define CAP_SEPARATE_IO_BUFS		BIT(4)

 /* These denotes if the output (completion of a cipher_xxx_op) is conveyed
  * by the op function returning, or it is conveyed by an async notification
  */
 #define CAP_SYNC_OPS			BIT(5)
 #define CAP_ASYNC_OPS			BIT(6)

 /* Whether the hardware/driver supports autononce feature */
 #define CAP_AUTONONCE			BIT(7)


 /* More flags to be added as necessary */

 /* Structure encoding IO parameters of one cryptographic
  * operation like encrypt/decrypt. The fields which has not been explicitly
  * called out has to be filled up by the app before making the cipher_xxx_op()
  * call
  */
 struct cipher_pkt {

 	/* Start address of Input buffer */
 	u8_t *in_buf;

 	/* Bytes to be operated upon */
 	int  in_len;

 	/* Start of the Output buffer, to be allocated by
 	 * the application. Can be NULL for in place ops. To be populated
 	 * with contents by the driver on return from op / async_callback
 	 */
 	u8_t *out_buf;

 	/* Size of the out_buf area allocated by the application. Drivers should
 	 * not write past the size of output buffer
 	 */
 	int out_buf_max;

 	/* To be populated by driver on return from cipher_xxx_op() and
 	 * holds the size of the actual result
 	 */
 	int out_len;

 	/* Context this packet relates to. This can be useful to get the
 	 * session details esp for async ops. Will be populated by the
 	 * cipher_xxx_op() API based on the ctx parameter
 	 */
 	struct cipher_ctx *ctx;
 };

 /* Structure encoding IO parameters in AEAD (Authenticated Encryption
  * with Associated Data) scenario like in CCM. App has to furnish valid
  * contents prior to making cipher_ccm_op() call.
  */
 struct cipher_aead_pkt {
 	/* IO buffers for Encryption. This has to be supplied by the app */
 	struct cipher_pkt *pkt;

 	/* Start address for Associated data. This has to be supplied by app */
 	u8_t *ad;

 	/* Size of  Associated data. This has to be supplied by the app */
 	u32_t ad_len;

 	/* Start address for the Auth hash. For an Encryption op this will
 	 * be populated by the driver when it returns from cipher_ccm_op call.
 	 * For a decryption op this has to be  supplied by the app.
 	 */
 	u8_t *tag;
 };

 /* Prototype for the application function to be invoked by the crypto driver
  * on completion of an async request. The app may get the session context
  * via the pkt->ctx field. For ccm ops the  encopassing AEAD packet maybe
  * accessed via container_of(). The type of a packet can be determined via
  * pkt->ctx.ops.mode
  */
 typedef void (*crypto_completion_cb)(struct cipher_pkt *completed, int status);

 #endif /* ZEPHYR_INCLUDE_CRYPTO_CIPHER_STRUCTS_H_ */
	/*
	* Copyright (c) 2016 Intel Corporation.
	*
	* SPDX-License-Identifier: Apache-2.0
	*/

	/**
	* @file
	* @brief Crypto Cipher structure definitions
	*
	* This file contains the Crypto Abstraction layer structures.
	*
	* [Experimental] Users should note that the Structures can change
	* as a part of ongoing development.
	*/

	#ifndef ZEPHYR_INCLUDE_CRYPTO_CIPHER_STRUCTS_H_
	#define ZEPHYR_INCLUDE_CRYPTO_CIPHER_STRUCTS_H_

	#include <device.h>
	#include <misc/util.h>

	enum cipher_algo {
	CRYPTO_CIPHER_ALGO_AES = 1,
	};

	enum cipher_op {
	CRYPTO_CIPHER_OP_DECRYPT = 0,
	CRYPTO_CIPHER_OP_ENCRYPT = 1,
	};

	/* Possible cipher mode options. More to be
	* added as required.
	*/

	enum cipher_mode {
	CRYPTO_CIPHER_MODE_ECB = 1,
	CRYPTO_CIPHER_MODE_CBC = 2,
	CRYPTO_CIPHER_MODE_CTR = 3,
	CRYPTO_CIPHER_MODE_CCM = 4,
	};

	/* Forward declarations */
	struct cipher_aead_pkt;
	struct cipher_ctx;
	struct cipher_pkt;

	typedef int (block_op_t)(struct cipher_ctx ctx, struct cipher_pkt *pkt);

	/* Function signatures for encryption/ decryption using standard cipher modes
	* like CBC, CTR, CCM.
	*/
	typedef int (cbc_op_t)(struct cipher_ctx ctx, struct cipher_pkt *pkt,
	u8_t *iv);

	typedef int (ctr_op_t)(struct cipher_ctx ctx, struct cipher_pkt *pkt,
	u8_t *ctr);

	typedef int (ccm_op_t)(struct cipher_ctx ctx, struct cipher_aead_pkt *pkt,
	u8_t *nonce);

	struct cipher_ops {

	enum cipher_mode cipher_mode;

	union {
	block_op_t block_crypt_hndlr;
	cbc_op_t cbc_crypt_hndlr;
	ctr_op_t ctr_crypt_hndlr;
	ccm_op_t ccm_crypt_hndlr;
	};
	};

	struct ccm_params {
	u16_t tag_len;
	u16_t nonce_len;
	};

	struct ctr_params {
	/* CTR mode counter is a split counter composed of iv and counter
	* such that ivlen + ctr_len = keylen
	*/
	u32_t ctr_len;
	};

	/* Structure encoding session parameters. Refer to comments for individual
	* fields to know the contract in terms of who fills what and when w.r.t
	* begin_session() call.
	*/
	struct cipher_ctx {

	/* Place for driver to return function pointers to be invoked per
	* cipher operation. To be populated by crypto driver on return from
	* begin_session() based on the algo/mode chosen by the app.
	*/
	struct cipher_ops ops;

	/* To be populated by the app before calling begin_session() */
	union {
	/* Cryptographic key to be used in this session */
	u8_t *bit_stream;
	/* For cases where key is protected and is not
	* available to caller
	*/
	void *handle;
	} key;

	/* The device driver instance this crypto context relates to. Will be
	* populated by the begin_session() API.
	*/
	struct device *device;

	/* If the driver supports multiple simultaneously crypto sessions, this
	* will identify the specific driver state this crypto session relates
	* to. Since dynamic memory allocation is is not possible, it is
	* suggested that at build time drivers allocate space for the
	* max simultaneous sessions they intend to support. To be populated
	* by the driver on return from begin_session()
	*/
	void *drv_sessn_state;

	/* Place for the app to put info relevant stuff for resuming when
	* completion call back happens for async ops. Totally managed by the
	* app.
	*/
	void *app_sessn_state;


	/* Standard mode parameters, which remain constant for all ops
	* in a session. To be populated by the app before calling
	* begin_session()
	*/
	union {
	struct ccm_params ccm_info;
	struct ctr_params ctr_info;

	} mode_params;


	/* Cryptographic keylength in bytes. To be populated by the app
	* before calling begin_session()
	*/
	u16_t keylen;


	/* How certain fields are to be interpreted for this sesssion.
	* To be populated by the app before calling begin_session().
	* An app can obtain the capability flags supported by a hw/driver
	* by calling cipher_query_hwcaps(). (A bitmask of CAP_* below)
	*/
	u16_t flags;
	};

	/* Various cipher_ctx.flags options. Not all drivers support all flags.
	* An app can query the supported hw / driver
	* capabilities via provided API (cipher_query_hwcaps()), and choose a
	* supported config during the session setup.
	*/
	#define CAP_OPAQUE_KEY_HNDL BIT(0)
	#define CAP_RAW_KEY BIT(1)

	/* TBD to define */
	#define CAP_KEY_LOADING_API BIT(2)

	/* Whether the output is placed in separate buffer or not */
	#define CAP_INPLACE_OPS BIT(3)
	#define CAP_SEPARATE_IO_BUFS BIT(4)

	/* These denotes if the output (completion of a cipher_xxx_op) is conveyed
	* by the op function returning, or it is conveyed by an async notification
	*/
	#define CAP_SYNC_OPS BIT(5)
	#define CAP_ASYNC_OPS BIT(6)

	/* Whether the hardware/driver supports autononce feature */
	#define CAP_AUTONONCE BIT(7)


	/* More flags to be added as necessary */

	/* Structure encoding IO parameters of one cryptographic
	* operation like encrypt/decrypt. The fields which has not been explicitly
	* called out has to be filled up by the app before making the cipher_xxx_op()
	* call
	*/
	struct cipher_pkt {

	/* Start address of Input buffer */
	u8_t *in_buf;

	/* Bytes to be operated upon */
	int in_len;

	/* Start of the Output buffer, to be allocated by
	* the application. Can be NULL for in place ops. To be populated
	* with contents by the driver on return from op / async_callback
	*/
	u8_t *out_buf;

	/* Size of the out_buf area allocated by the application. Drivers should
	* not write past the size of output buffer
	*/
	int out_buf_max;

	/* To be populated by driver on return from cipher_xxx_op() and
	* holds the size of the actual result
	*/
	int out_len;

	/* Context this packet relates to. This can be useful to get the
	* session details esp for async ops. Will be populated by the
	* cipher_xxx_op() API based on the ctx parameter
	*/
	struct cipher_ctx *ctx;
	};

	/* Structure encoding IO parameters in AEAD (Authenticated Encryption
	* with Associated Data) scenario like in CCM. App has to furnish valid
	* contents prior to making cipher_ccm_op() call.
	*/
	struct cipher_aead_pkt {
	/* IO buffers for Encryption. This has to be supplied by the app */
	struct cipher_pkt *pkt;

	/* Start address for Associated data. This has to be supplied by app */
	u8_t *ad;

	/* Size of Associated data. This has to be supplied by the app */
	u32_t ad_len;

	/* Start address for the Auth hash. For an Encryption op this will
	* be populated by the driver when it returns from cipher_ccm_op call.
	* For a decryption op this has to be supplied by the app.
	*/
	u8_t *tag;
	};

	/* Prototype for the application function to be invoked by the crypto driver
	* on completion of an async request. The app may get the session context
	* via the pkt->ctx field. For ccm ops the encopassing AEAD packet maybe
	* accessed via container_of(). The type of a packet can be determined via
	* pkt->ctx.ops.mode
	*/
	typedef void (crypto_completion_cb)(struct cipher_pkt completed, int status);

	#endif /* ZEPHYR_INCLUDE_CRYPTO_CIPHER_STRUCTS_H_ */