xref: /titanic_50/usr/src/uts/common/sys/crypto/ops_impl.h (revision a60fc142342386d0b786e65fba901234400d7020)
1 /*
2  * CDDL HEADER START
3  *
4  * The contents of this file are subject to the terms of the
5  * Common Development and Distribution License (the "License").
6  * You may not use this file except in compliance with the License.
7  *
8  * You can obtain a copy of the license at usr/src/OPENSOLARIS.LICENSE
9  * or http://www.opensolaris.org/os/licensing.
10  * See the License for the specific language governing permissions
11  * and limitations under the License.
12  *
13  * When distributing Covered Code, include this CDDL HEADER in each
14  * file and include the License file at usr/src/OPENSOLARIS.LICENSE.
15  * If applicable, add the following below this CDDL HEADER, with the
16  * fields enclosed by brackets "[]" replaced with your own identifying
17  * information: Portions Copyright [yyyy] [name of copyright owner]
18  *
19  * CDDL HEADER END
20  */
21 /*
22  * Copyright 2007 Sun Microsystems, Inc.  All rights reserved.
23  * Use is subject to license terms.
24  */
25 
26 #ifndef _SYS_CRYPTO_OPS_IMPL_H
27 #define	_SYS_CRYPTO_OPS_IMPL_H
28 
29 #pragma ident	"%Z%%M%	%I%	%E% SMI"
30 
31 /*
32  * Scheduler internal structures.
33  */
34 
35 #ifdef __cplusplus
36 extern "C" {
37 #endif
38 
39 #include <sys/types.h>
40 #include <sys/mutex.h>
41 #include <sys/condvar.h>
42 #include <sys/crypto/api.h>
43 #include <sys/crypto/spi.h>
44 #include <sys/crypto/impl.h>
45 #include <sys/crypto/common.h>
46 
47 /*
48  * The parameters needed for each function group are batched
49  * in one structure. This is much simpler than having a
50  * separate structure for each function.
51  *
52  * In some cases, a field is generically named to keep the
53  * structure small. The comments indicate these cases.
54  */
55 typedef struct kcf_digest_ops_params {
56 	crypto_session_id_t	do_sid;
57 	crypto_mech_type_t	do_framework_mechtype;
58 	crypto_mechanism_t	do_mech;
59 	crypto_data_t		*do_data;
60 	crypto_data_t		*do_digest;
61 	crypto_key_t		*do_digest_key;	/* Argument for digest_key() */
62 } kcf_digest_ops_params_t;
63 
64 typedef struct kcf_mac_ops_params {
65 	crypto_session_id_t		mo_sid;
66 	crypto_mech_type_t		mo_framework_mechtype;
67 	crypto_mechanism_t		mo_mech;
68 	crypto_key_t			*mo_key;
69 	crypto_data_t			*mo_data;
70 	crypto_data_t			*mo_mac;
71 	crypto_spi_ctx_template_t	mo_templ;
72 } kcf_mac_ops_params_t;
73 
74 typedef struct kcf_encrypt_ops_params {
75 	crypto_session_id_t		eo_sid;
76 	crypto_mech_type_t		eo_framework_mechtype;
77 	crypto_mechanism_t		eo_mech;
78 	crypto_key_t			*eo_key;
79 	crypto_data_t			*eo_plaintext;
80 	crypto_data_t			*eo_ciphertext;
81 	crypto_spi_ctx_template_t	eo_templ;
82 } kcf_encrypt_ops_params_t;
83 
84 typedef struct kcf_decrypt_ops_params {
85 	crypto_session_id_t		dop_sid;
86 	crypto_mech_type_t		dop_framework_mechtype;
87 	crypto_mechanism_t		dop_mech;
88 	crypto_key_t			*dop_key;
89 	crypto_data_t			*dop_ciphertext;
90 	crypto_data_t			*dop_plaintext;
91 	crypto_spi_ctx_template_t	dop_templ;
92 } kcf_decrypt_ops_params_t;
93 
94 typedef struct kcf_sign_ops_params {
95 	crypto_session_id_t		so_sid;
96 	crypto_mech_type_t		so_framework_mechtype;
97 	crypto_mechanism_t		so_mech;
98 	crypto_key_t			*so_key;
99 	crypto_data_t			*so_data;
100 	crypto_data_t			*so_signature;
101 	crypto_spi_ctx_template_t	so_templ;
102 } kcf_sign_ops_params_t;
103 
104 typedef struct kcf_verify_ops_params {
105 	crypto_session_id_t		vo_sid;
106 	crypto_mech_type_t		vo_framework_mechtype;
107 	crypto_mechanism_t		vo_mech;
108 	crypto_key_t			*vo_key;
109 	crypto_data_t			*vo_data;
110 	crypto_data_t			*vo_signature;
111 	crypto_spi_ctx_template_t	vo_templ;
112 } kcf_verify_ops_params_t;
113 
114 typedef struct kcf_encrypt_mac_ops_params {
115 	crypto_session_id_t 		em_sid;
116 	crypto_mech_type_t		em_framework_encr_mechtype;
117 	crypto_mechanism_t		em_encr_mech;
118 	crypto_key_t			*em_encr_key;
119 	crypto_mech_type_t		em_framework_mac_mechtype;
120 	crypto_mechanism_t		em_mac_mech;
121 	crypto_key_t			*em_mac_key;
122 	crypto_data_t			*em_plaintext;
123 	crypto_dual_data_t		*em_ciphertext;
124 	crypto_data_t			*em_mac;
125 	crypto_spi_ctx_template_t	em_encr_templ;
126 	crypto_spi_ctx_template_t	em_mac_templ;
127 } kcf_encrypt_mac_ops_params_t;
128 
129 typedef struct kcf_mac_decrypt_ops_params {
130 	crypto_session_id_t 		md_sid;
131 	crypto_mech_type_t		md_framework_mac_mechtype;
132 	crypto_mechanism_t		md_mac_mech;
133 	crypto_key_t			*md_mac_key;
134 	crypto_mech_type_t		md_framework_decr_mechtype;
135 	crypto_mechanism_t		md_decr_mech;
136 	crypto_key_t			*md_decr_key;
137 	crypto_dual_data_t		*md_ciphertext;
138 	crypto_data_t			*md_mac;
139 	crypto_data_t			*md_plaintext;
140 	crypto_spi_ctx_template_t	md_mac_templ;
141 	crypto_spi_ctx_template_t	md_decr_templ;
142 } kcf_mac_decrypt_ops_params_t;
143 
144 typedef struct kcf_random_number_ops_params {
145 	crypto_session_id_t	rn_sid;
146 	uchar_t			*rn_buf;
147 	size_t			rn_buflen;
148 	uint_t			rn_entropy_est;
149 	uint32_t		rn_flags;
150 } kcf_random_number_ops_params_t;
151 
152 /*
153  * so_pd is useful when the provider descriptor (pd) supplying the
154  * provider handle is different from the pd supplying the ops vector.
155  * This is the case for session open/close where so_pd can be the pd
156  * of a logical provider. The pd supplying the ops vector is passed
157  * as an argument to kcf_submit_request().
158  */
159 typedef struct kcf_session_ops_params {
160 	crypto_session_id_t	*so_sid_ptr;
161 	crypto_session_id_t	so_sid;
162 	crypto_user_type_t	so_user_type;
163 	char			*so_pin;
164 	size_t			so_pin_len;
165 	kcf_provider_desc_t	*so_pd;
166 } kcf_session_ops_params_t;
167 
168 typedef struct kcf_object_ops_params {
169 	crypto_session_id_t		oo_sid;
170 	crypto_object_id_t		oo_object_id;
171 	crypto_object_attribute_t	*oo_template;
172 	uint_t 				oo_attribute_count;
173 	crypto_object_id_t		*oo_object_id_ptr;
174 	size_t				*oo_object_size;
175 	void				**oo_find_init_pp_ptr;
176 	void				*oo_find_pp;
177 	uint_t				oo_max_object_count;
178 	uint_t				*oo_object_count_ptr;
179 } kcf_object_ops_params_t;
180 
181 /*
182  * ko_key is used to encode wrapping key in key_wrap() and
183  * unwrapping key in key_unwrap(). ko_key_template and
184  * ko_key_attribute_count are used to encode public template
185  * and public template attr count in key_generate_pair().
186  * kops->ko_key_object_id_ptr is used to encode public key
187  * in key_generate_pair().
188  */
189 typedef struct kcf_key_ops_params {
190 	crypto_session_id_t		ko_sid;
191 	crypto_mech_type_t		ko_framework_mechtype;
192 	crypto_mechanism_t		ko_mech;
193 	crypto_object_attribute_t	*ko_key_template;
194 	uint_t				ko_key_attribute_count;
195 	crypto_object_id_t		*ko_key_object_id_ptr;
196 	crypto_object_attribute_t	*ko_private_key_template;
197 	uint_t				ko_private_key_attribute_count;
198 	crypto_object_id_t		*ko_private_key_object_id_ptr;
199 	crypto_key_t			*ko_key;
200 	uchar_t				*ko_wrapped_key;
201 	size_t				*ko_wrapped_key_len_ptr;
202 	crypto_object_attribute_t	*ko_out_template1;
203 	crypto_object_attribute_t	*ko_out_template2;
204 	uint_t				ko_out_attribute_count1;
205 	uint_t				ko_out_attribute_count2;
206 } kcf_key_ops_params_t;
207 
208 /*
209  * po_pin and po_pin_len are used to encode new_pin and new_pin_len
210  * when wrapping set_pin() function parameters.
211  *
212  * po_pd is useful when the provider descriptor (pd) supplying the
213  * provider handle is different from the pd supplying the ops vector.
214  * This is true for the ext_info provider entry point where po_pd
215  * can be the pd of a logical provider. The pd supplying the ops vector
216  * is passed as an argument to kcf_submit_request().
217  */
218 typedef struct kcf_provmgmt_ops_params {
219 	crypto_session_id_t 		po_sid;
220 	char				*po_pin;
221 	size_t				po_pin_len;
222 	char				*po_old_pin;
223 	size_t				po_old_pin_len;
224 	char				*po_label;
225 	crypto_provider_ext_info_t	*po_ext_info;
226 	kcf_provider_desc_t		*po_pd;
227 } kcf_provmgmt_ops_params_t;
228 
229 /*
230  * The operation type within a function group.
231  */
232 typedef enum kcf_op_type {
233 	/* common ops for all mechanisms */
234 	KCF_OP_INIT = 1,
235 	KCF_OP_SINGLE,	/* pkcs11 sense. So, INIT is already done */
236 	KCF_OP_UPDATE,
237 	KCF_OP_FINAL,
238 	KCF_OP_ATOMIC,
239 
240 	/* digest_key op */
241 	KCF_OP_DIGEST_KEY,
242 
243 	/* mac specific op */
244 	KCF_OP_MAC_VERIFY_ATOMIC,
245 
246 	/* mac/cipher specific op */
247 	KCF_OP_MAC_VERIFY_DECRYPT_ATOMIC,
248 
249 	/* sign_recover ops */
250 	KCF_OP_SIGN_RECOVER_INIT,
251 	KCF_OP_SIGN_RECOVER,
252 	KCF_OP_SIGN_RECOVER_ATOMIC,
253 
254 	/* verify_recover ops */
255 	KCF_OP_VERIFY_RECOVER_INIT,
256 	KCF_OP_VERIFY_RECOVER,
257 	KCF_OP_VERIFY_RECOVER_ATOMIC,
258 
259 	/* random number ops */
260 	KCF_OP_RANDOM_SEED,
261 	KCF_OP_RANDOM_GENERATE,
262 
263 	/* session management ops */
264 	KCF_OP_SESSION_OPEN,
265 	KCF_OP_SESSION_CLOSE,
266 	KCF_OP_SESSION_LOGIN,
267 	KCF_OP_SESSION_LOGOUT,
268 
269 	/* object management ops */
270 	KCF_OP_OBJECT_CREATE,
271 	KCF_OP_OBJECT_COPY,
272 	KCF_OP_OBJECT_DESTROY,
273 	KCF_OP_OBJECT_GET_SIZE,
274 	KCF_OP_OBJECT_GET_ATTRIBUTE_VALUE,
275 	KCF_OP_OBJECT_SET_ATTRIBUTE_VALUE,
276 	KCF_OP_OBJECT_FIND_INIT,
277 	KCF_OP_OBJECT_FIND,
278 	KCF_OP_OBJECT_FIND_FINAL,
279 
280 	/* key management ops */
281 	KCF_OP_KEY_GENERATE,
282 	KCF_OP_KEY_GENERATE_PAIR,
283 	KCF_OP_KEY_WRAP,
284 	KCF_OP_KEY_UNWRAP,
285 	KCF_OP_KEY_DERIVE,
286 	KCF_OP_KEY_CHECK,
287 
288 	/* provider management ops */
289 	KCF_OP_MGMT_EXTINFO,
290 	KCF_OP_MGMT_INITTOKEN,
291 	KCF_OP_MGMT_INITPIN,
292 	KCF_OP_MGMT_SETPIN
293 } kcf_op_type_t;
294 
295 /*
296  * The operation groups that need wrapping of parameters. This is somewhat
297  * similar to the function group type in spi.h except that this also includes
298  * all the functions that don't have a mechanism.
299  *
300  * The wrapper macros should never take these enum values as an argument.
301  * Rather, they are assigned in the macro itself since they are known
302  * from the macro name.
303  */
304 typedef enum kcf_op_group {
305 	KCF_OG_DIGEST = 1,
306 	KCF_OG_MAC,
307 	KCF_OG_ENCRYPT,
308 	KCF_OG_DECRYPT,
309 	KCF_OG_SIGN,
310 	KCF_OG_VERIFY,
311 	KCF_OG_ENCRYPT_MAC,
312 	KCF_OG_MAC_DECRYPT,
313 	KCF_OG_RANDOM,
314 	KCF_OG_SESSION,
315 	KCF_OG_OBJECT,
316 	KCF_OG_KEY,
317 	KCF_OG_PROVMGMT,
318 	KCF_OG_NOSTORE_KEY
319 } kcf_op_group_t;
320 
321 /*
322  * The kcf_op_type_t enum values used here should be only for those
323  * operations for which there is a k-api routine in sys/crypto/api.h.
324  */
325 #define	IS_INIT_OP(ftype)	((ftype) == KCF_OP_INIT)
326 #define	IS_SINGLE_OP(ftype)	((ftype) == KCF_OP_SINGLE)
327 #define	IS_UPDATE_OP(ftype)	((ftype) == KCF_OP_UPDATE)
328 #define	IS_FINAL_OP(ftype)	((ftype) == KCF_OP_FINAL)
329 #define	IS_ATOMIC_OP(ftype)	( \
330 	(ftype) == KCF_OP_ATOMIC || (ftype) == KCF_OP_MAC_VERIFY_ATOMIC || \
331 	(ftype) == KCF_OP_MAC_VERIFY_DECRYPT_ATOMIC || \
332 	(ftype) == KCF_OP_SIGN_RECOVER_ATOMIC || \
333 	(ftype) == KCF_OP_VERIFY_RECOVER_ATOMIC)
334 
335 /*
336  * Keep the parameters associated with a request around.
337  * We need to pass them to the SPI.
338  */
339 typedef struct kcf_req_params {
340 	kcf_op_group_t		rp_opgrp;
341 	kcf_op_type_t		rp_optype;
342 
343 	union {
344 		kcf_digest_ops_params_t		digest_params;
345 		kcf_mac_ops_params_t		mac_params;
346 		kcf_encrypt_ops_params_t	encrypt_params;
347 		kcf_decrypt_ops_params_t	decrypt_params;
348 		kcf_sign_ops_params_t		sign_params;
349 		kcf_verify_ops_params_t		verify_params;
350 		kcf_encrypt_mac_ops_params_t	encrypt_mac_params;
351 		kcf_mac_decrypt_ops_params_t	mac_decrypt_params;
352 		kcf_random_number_ops_params_t	random_number_params;
353 		kcf_session_ops_params_t	session_params;
354 		kcf_object_ops_params_t		object_params;
355 		kcf_key_ops_params_t		key_params;
356 		kcf_provmgmt_ops_params_t	provmgmt_params;
357 	} rp_u;
358 } kcf_req_params_t;
359 
360 
361 /*
362  * The ioctl/k-api code should bundle the parameters into a kcf_req_params_t
363  * structure before calling a scheduler routine. The following macros are
364  * available for that purpose.
365  *
366  * For the most part, the macro arguments closely correspond to the
367  * function parameters. In some cases, we use generic names. The comments
368  * for the structure should indicate these cases.
369  */
370 #define	KCF_WRAP_DIGEST_OPS_PARAMS(req, ftype, _sid, _mech, _key,	\
371 	_data, _digest) {						\
372 	kcf_digest_ops_params_t *dops = &(req)->rp_u.digest_params;	\
373 									\
374 	(req)->rp_opgrp = KCF_OG_DIGEST;				\
375 	(req)->rp_optype = ftype;					\
376 	dops->do_sid = _sid;						\
377 	kcf_dup_mech(_mech, &dops->do_mech, &dops->do_framework_mechtype); \
378 	dops->do_digest_key = _key;					\
379 	dops->do_data = _data;						\
380 	dops->do_digest = _digest;					\
381 }
382 
383 #define	KCF_WRAP_MAC_OPS_PARAMS(req, ftype, _sid, _mech, _key,		\
384 	_data, _mac, _templ) {						\
385 	kcf_mac_ops_params_t *mops = &(req)->rp_u.mac_params;		\
386 									\
387 	(req)->rp_opgrp = KCF_OG_MAC;					\
388 	(req)->rp_optype = ftype;					\
389 	mops->mo_sid = _sid;						\
390 	kcf_dup_mech(_mech, &mops->mo_mech, &mops->mo_framework_mechtype); \
391 	mops->mo_key = _key;						\
392 	mops->mo_data = _data;						\
393 	mops->mo_mac = _mac;						\
394 	mops->mo_templ = _templ;					\
395 }
396 
397 #define	KCF_WRAP_ENCRYPT_OPS_PARAMS(req, ftype, _sid, _mech, _key,	\
398 	_plaintext, _ciphertext, _templ) {				\
399 	kcf_encrypt_ops_params_t *cops = &(req)->rp_u.encrypt_params;	\
400 									\
401 	(req)->rp_opgrp = KCF_OG_ENCRYPT;				\
402 	(req)->rp_optype = ftype;					\
403 	cops->eo_sid = _sid;						\
404 	kcf_dup_mech(_mech, &cops->eo_mech, &cops->eo_framework_mechtype); \
405 	cops->eo_key = _key;						\
406 	cops->eo_plaintext = _plaintext;				\
407 	cops->eo_ciphertext = _ciphertext;				\
408 	cops->eo_templ = _templ;					\
409 }
410 
411 #define	KCF_WRAP_DECRYPT_OPS_PARAMS(req, ftype, _sid, _mech, _key,	\
412 	_ciphertext, _plaintext, _templ) {				\
413 	kcf_decrypt_ops_params_t *cops = &(req)->rp_u.decrypt_params;	\
414 									\
415 	(req)->rp_opgrp = KCF_OG_DECRYPT;				\
416 	(req)->rp_optype = ftype;					\
417 	cops->dop_sid = _sid;						\
418 	kcf_dup_mech(_mech, &cops->dop_mech, &cops->dop_framework_mechtype); \
419 	cops->dop_key = _key;						\
420 	cops->dop_ciphertext = _ciphertext;				\
421 	cops->dop_plaintext = _plaintext;				\
422 	cops->dop_templ = _templ;					\
423 }
424 
425 #define	KCF_WRAP_SIGN_OPS_PARAMS(req, ftype, _sid, _mech, _key,		\
426 	_data, _signature, _templ) {					\
427 	kcf_sign_ops_params_t *sops = &(req)->rp_u.sign_params;		\
428 									\
429 	(req)->rp_opgrp = KCF_OG_SIGN;					\
430 	(req)->rp_optype = ftype;					\
431 	sops->so_sid = _sid;						\
432 	kcf_dup_mech(_mech, &sops->so_mech, &sops->so_framework_mechtype); \
433 	sops->so_key = _key;						\
434 	sops->so_data = _data;						\
435 	sops->so_signature = _signature;				\
436 	sops->so_templ = _templ;					\
437 }
438 
439 #define	KCF_WRAP_VERIFY_OPS_PARAMS(req, ftype, _sid, _mech, _key,	\
440 	_data, _signature, _templ) {					\
441 	kcf_verify_ops_params_t *vops = &(req)->rp_u.verify_params;	\
442 									\
443 	(req)->rp_opgrp = KCF_OG_VERIFY;				\
444 	(req)->rp_optype = ftype;					\
445 	vops->vo_sid = _sid;						\
446 	kcf_dup_mech(_mech, &vops->vo_mech, &vops->vo_framework_mechtype); \
447 	vops->vo_key = _key;						\
448 	vops->vo_data = _data;						\
449 	vops->vo_signature = _signature;				\
450 	vops->vo_templ = _templ;					\
451 }
452 
453 #define	KCF_WRAP_ENCRYPT_MAC_OPS_PARAMS(req, ftype, _sid, _encr_key,	\
454 	_mac_key, _plaintext, _ciphertext, _mac, _encr_templ, _mac_templ) { \
455 	kcf_encrypt_mac_ops_params_t *cmops = &(req)->rp_u.encrypt_mac_params; \
456 									\
457 	(req)->rp_opgrp = KCF_OG_ENCRYPT_MAC;				\
458 	(req)->rp_optype = ftype;					\
459 	cmops->em_sid = _sid;						\
460 	cmops->em_encr_key = _encr_key;					\
461 	cmops->em_mac_key = _mac_key;					\
462 	cmops->em_plaintext = _plaintext;				\
463 	cmops->em_ciphertext = _ciphertext;				\
464 	cmops->em_mac = _mac;						\
465 	cmops->em_encr_templ = _encr_templ;				\
466 	cmops->em_mac_templ = _mac_templ;				\
467 }
468 
469 #define	KCF_WRAP_MAC_DECRYPT_OPS_PARAMS(req, ftype, _sid, _mac_key,	\
470 	_decr_key, _ciphertext, _mac, _plaintext, _mac_templ, _decr_templ) { \
471 	kcf_mac_decrypt_ops_params_t *cmops = &(req)->rp_u.mac_decrypt_params; \
472 									\
473 	(req)->rp_opgrp = KCF_OG_MAC_DECRYPT;				\
474 	(req)->rp_optype = ftype;					\
475 	cmops->md_sid = _sid;						\
476 	cmops->md_mac_key = _mac_key;					\
477 	cmops->md_decr_key = _decr_key;					\
478 	cmops->md_ciphertext = _ciphertext;				\
479 	cmops->md_mac = _mac;						\
480 	cmops->md_plaintext = _plaintext;				\
481 	cmops->md_mac_templ = _mac_templ;				\
482 	cmops->md_decr_templ = _decr_templ;				\
483 }
484 
485 #define	KCF_WRAP_RANDOM_OPS_PARAMS(req, ftype, _sid, _buf, _buflen,	\
486 	_est, _flags) {							\
487 	kcf_random_number_ops_params_t *rops =				\
488 		&(req)->rp_u.random_number_params;			\
489 									\
490 	(req)->rp_opgrp = KCF_OG_RANDOM;				\
491 	(req)->rp_optype = ftype;					\
492 	rops->rn_sid = _sid;						\
493 	rops->rn_buf = _buf;						\
494 	rops->rn_buflen = _buflen;					\
495 	rops->rn_entropy_est = _est;					\
496 	rops->rn_flags = _flags;					\
497 }
498 
499 #define	KCF_WRAP_SESSION_OPS_PARAMS(req, ftype, _sid_ptr, _sid,		\
500 	_user_type, _pin, _pin_len, _pd) {				\
501 	kcf_session_ops_params_t *sops = &(req)->rp_u.session_params;	\
502 									\
503 	(req)->rp_opgrp = KCF_OG_SESSION;				\
504 	(req)->rp_optype = ftype;					\
505 	sops->so_sid_ptr = _sid_ptr;					\
506 	sops->so_sid = _sid;						\
507 	sops->so_user_type = _user_type;				\
508 	sops->so_pin = _pin;						\
509 	sops->so_pin_len = _pin_len;					\
510 	sops->so_pd = _pd;						\
511 }
512 
513 #define	KCF_WRAP_OBJECT_OPS_PARAMS(req, ftype, _sid, _object_id,	\
514 	_template, _attribute_count, _object_id_ptr, _object_size,	\
515 	_find_init_pp_ptr, _find_pp, _max_object_count, _object_count_ptr) { \
516 	kcf_object_ops_params_t *jops = &(req)->rp_u.object_params;	\
517 									\
518 	(req)->rp_opgrp = KCF_OG_OBJECT;				\
519 	(req)->rp_optype = ftype;					\
520 	jops->oo_sid = _sid;						\
521 	jops->oo_object_id = _object_id;				\
522 	jops->oo_template = _template;					\
523 	jops->oo_attribute_count = _attribute_count;			\
524 	jops->oo_object_id_ptr = _object_id_ptr;			\
525 	jops->oo_object_size = _object_size;				\
526 	jops->oo_find_init_pp_ptr = _find_init_pp_ptr;			\
527 	jops->oo_find_pp = _find_pp;					\
528 	jops->oo_max_object_count = _max_object_count;			\
529 	jops->oo_object_count_ptr = _object_count_ptr;			\
530 }
531 
532 #define	KCF_WRAP_KEY_OPS_PARAMS(req, ftype, _sid, _mech, _key_template, \
533 	_key_attribute_count, _key_object_id_ptr, _private_key_template, \
534 	_private_key_attribute_count, _private_key_object_id_ptr,	\
535 	_key, _wrapped_key, _wrapped_key_len_ptr) {			\
536 	kcf_key_ops_params_t *kops = &(req)->rp_u.key_params;		\
537 									\
538 	(req)->rp_opgrp = KCF_OG_KEY;					\
539 	(req)->rp_optype = ftype;					\
540 	kops->ko_sid = _sid;						\
541 	kcf_dup_mech(_mech, &kops->ko_mech, &kops->ko_framework_mechtype); \
542 	kops->ko_key_template = _key_template;				\
543 	kops->ko_key_attribute_count = _key_attribute_count;		\
544 	kops->ko_key_object_id_ptr = _key_object_id_ptr;		\
545 	kops->ko_private_key_template = _private_key_template;		\
546 	kops->ko_private_key_attribute_count = _private_key_attribute_count; \
547 	kops->ko_private_key_object_id_ptr = _private_key_object_id_ptr; \
548 	kops->ko_key = _key;						\
549 	kops->ko_wrapped_key = _wrapped_key;				\
550 	kops->ko_wrapped_key_len_ptr = _wrapped_key_len_ptr;		\
551 }
552 
553 #define	KCF_WRAP_PROVMGMT_OPS_PARAMS(req, ftype, _sid, _old_pin,	\
554 	_old_pin_len, _pin, _pin_len, _label, _ext_info, _pd) {		\
555 	kcf_provmgmt_ops_params_t *pops = &(req)->rp_u.provmgmt_params;	\
556 									\
557 	(req)->rp_opgrp = KCF_OG_PROVMGMT;				\
558 	(req)->rp_optype = ftype;					\
559 	pops->po_sid = _sid;						\
560 	pops->po_pin = _pin;						\
561 	pops->po_pin_len = _pin_len;					\
562 	pops->po_old_pin = _old_pin;					\
563 	pops->po_old_pin_len = _old_pin_len;				\
564 	pops->po_label = _label;					\
565 	pops->po_ext_info = _ext_info;					\
566 	pops->po_pd = _pd;						\
567 }
568 
569 #define	KCF_WRAP_NOSTORE_KEY_OPS_PARAMS(req, ftype, _sid, _mech,	\
570 	_key_template, _key_attribute_count, _private_key_template,	\
571 	_private_key_attribute_count, _key, _out_template1,		\
572 	_out_attribute_count1, _out_template2, _out_attribute_count2) {	\
573 	kcf_key_ops_params_t *kops = &(req)->rp_u.key_params;		\
574 									\
575 	(req)->rp_opgrp = KCF_OG_NOSTORE_KEY;				\
576 	(req)->rp_optype = ftype;					\
577 	kops->ko_sid = _sid;						\
578 	kcf_dup_mech(_mech, &kops->ko_mech, &kops->ko_framework_mechtype); \
579 	kops->ko_key_template = _key_template;				\
580 	kops->ko_key_attribute_count = _key_attribute_count;		\
581 	kops->ko_key_object_id_ptr = NULL;				\
582 	kops->ko_private_key_template = _private_key_template;		\
583 	kops->ko_private_key_attribute_count = _private_key_attribute_count; \
584 	kops->ko_private_key_object_id_ptr = NULL;			\
585 	kops->ko_key = _key;						\
586 	kops->ko_wrapped_key = NULL;					\
587 	kops->ko_wrapped_key_len_ptr = 0;				\
588 	kops->ko_out_template1 = _out_template1;			\
589 	kops->ko_out_template2 = _out_template2;			\
590 	kops->ko_out_attribute_count1 = _out_attribute_count1;		\
591 	kops->ko_out_attribute_count2 = _out_attribute_count2;		\
592 }
593 
594 #define	KCF_SET_PROVIDER_MECHNUM(fmtype, pd, mechp)			\
595 	(mechp)->cm_type =						\
596 	    KCF_TO_PROV_MECHNUM(pd, fmtype);
597 
598 #ifdef __cplusplus
599 }
600 #endif
601 
602 #endif /* _SYS_CRYPTO_OPS_IMPL_H */
603