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 (c) 2003, 2010, Oracle and/or its affiliates. All rights reserved. 23 */ 24 25 #ifndef _SYS_CRYPTO_IMPL_H 26 #define _SYS_CRYPTO_IMPL_H 27 28 /* 29 * Kernel Cryptographic Framework private implementation definitions. 30 */ 31 32 #include <sys/types.h> 33 #include <sys/param.h> 34 35 #ifdef _KERNEL 36 #include <sys/crypto/common.h> 37 #include <sys/crypto/api.h> 38 #include <sys/crypto/spi.h> 39 #include <sys/crypto/ioctl.h> 40 #include <sys/tnf_probe.h> 41 #include <sys/atomic.h> 42 #include <sys/project.h> 43 #include <sys/taskq.h> 44 #include <sys/rctl.h> 45 #include <sys/cpuvar.h> 46 #endif /* _KERNEL */ 47 48 #ifdef __cplusplus 49 extern "C" { 50 #endif 51 52 #ifdef _KERNEL 53 54 /* 55 * Prefixes convention: structures internal to the kernel cryptographic 56 * framework start with 'kcf_'. Exposed structure start with 'crypto_'. 57 */ 58 59 /* Provider stats. Not protected. */ 60 typedef struct kcf_prov_stats { 61 kstat_named_t ps_ops_total; 62 kstat_named_t ps_ops_passed; 63 kstat_named_t ps_ops_failed; 64 kstat_named_t ps_ops_busy_rval; 65 } kcf_prov_stats_t; 66 67 /* Various kcf stats. Not protected. */ 68 typedef struct kcf_stats { 69 kstat_named_t ks_thrs_in_pool; 70 kstat_named_t ks_idle_thrs; 71 kstat_named_t ks_minthrs; 72 kstat_named_t ks_maxthrs; 73 kstat_named_t ks_swq_njobs; 74 kstat_named_t ks_swq_maxjobs; 75 kstat_named_t ks_taskq_threads; 76 kstat_named_t ks_taskq_minalloc; 77 kstat_named_t ks_taskq_maxalloc; 78 } kcf_stats_t; 79 80 #define CPU_SEQID (CPU->cpu_seqid) 81 82 typedef struct kcf_lock_withpad { 83 kmutex_t kl_lock; 84 uint8_t kl_pad[64 - sizeof (kmutex_t)]; 85 } kcf_lock_withpad_t; 86 87 /* 88 * Per-CPU structure used by a provider to keep track of 89 * various counters. 90 */ 91 typedef struct kcf_prov_cpu { 92 kmutex_t kp_lock; 93 int kp_holdcnt; /* can go negative! */ 94 uint_t kp_jobcnt; 95 96 uint64_t kp_ndispatches; 97 uint64_t kp_nfails; 98 uint64_t kp_nbusy_rval; 99 kcondvar_t kp_cv; 100 101 uint8_t kp_pad[64 - sizeof (kmutex_t) - 2 * sizeof (int) - 102 3 * sizeof (uint64_t) - sizeof (kcondvar_t)]; 103 } kcf_prov_cpu_t; 104 105 /* 106 * kcf_get_refcnt(pd) is the number of inflight requests to the 107 * provider. So, it is a good measure of the load on a provider when 108 * it is not in a busy state. Once a provider notifies it is busy, requests 109 * backup in the taskq. So, we use tq_nalloc in that case which gives 110 * the number of task entries in the task queue. Note that we do not 111 * acquire any locks here as it is not critical to get the exact number 112 * and the lock contention is too costly for this code path. 113 */ 114 #define KCF_PROV_LOAD(pd) ((pd)->pd_state != KCF_PROV_BUSY ? \ 115 kcf_get_refcnt(pd, B_FALSE) : (pd)->pd_taskq->tq_nalloc) 116 117 118 /* 119 * The following two macros should be 120 * #define KCF_OPS_CLASSSIZE (KCF_LAST_OPSCLASS - KCF_FIRST_OPSCLASS + 2) 121 * #define KCF_MAXMECHTAB KCF_MAXCIPHER 122 * 123 * However, doing that would involve reorganizing the header file a bit. 124 * When impl.h is broken up (bug# 4703218), this will be done. For now, 125 * we hardcode these values. 126 */ 127 #define KCF_OPS_CLASSSIZE 8 128 #define KCF_MAXMECHTAB 32 129 130 /* 131 * Valid values for the state of a provider. The order of 132 * the elements is important. 133 * 134 * Routines which get a provider or the list of providers 135 * should pick only those that are either in KCF_PROV_READY state 136 * or in KCF_PROV_BUSY state. 137 */ 138 typedef enum { 139 KCF_PROV_ALLOCATED = 1, 140 KCF_PROV_UNVERIFIED, 141 KCF_PROV_UNVERIFIED_FIPS140, 142 KCF_PROV_VERIFICATION_FAILED, 143 /* 144 * state < KCF_PROV_READY means the provider can not 145 * be used at all. 146 */ 147 KCF_PROV_READY, 148 KCF_PROV_BUSY, 149 /* 150 * state > KCF_PROV_BUSY means the provider can not 151 * be used for new requests. 152 */ 153 KCF_PROV_FAILED, 154 /* 155 * Threads setting the following two states should do so only 156 * if the current state < KCF_PROV_DISABLED. 157 */ 158 KCF_PROV_DISABLED, 159 KCF_PROV_UNREGISTERING, 160 KCF_PROV_UNREGISTERED 161 } kcf_prov_state_t; 162 163 #define KCF_IS_PROV_UNVERIFIED(pd) ((pd)->pd_state == KCF_PROV_UNVERIFIED) 164 #define KCF_IS_PROV_USABLE(pd) ((pd)->pd_state == KCF_PROV_READY || \ 165 (pd)->pd_state == KCF_PROV_BUSY) 166 #define KCF_IS_PROV_REMOVED(pd) ((pd)->pd_state >= KCF_PROV_UNREGISTERING) 167 168 /* Internal flags valid for pd_flags field */ 169 #define KCF_LPROV_MEMBER 0x80000000 /* is member of a logical provider */ 170 171 /* 172 * A provider descriptor structure. There is one such structure per 173 * provider. It is allocated and initialized at registration time and 174 * freed when the provider unregisters. 175 * 176 * pd_prov_type: Provider type, hardware or software 177 * pd_sid: Session ID of the provider used by kernel clients. 178 * This is valid only for session-oriented providers. 179 * pd_taskq: taskq used to dispatch crypto requests 180 * pd_nbins: number of bins in pd_percpu_bins 181 * pd_percpu_bins: Pointer to an array of per-CPU structures 182 * containing a lock, a cv and various counters. 183 * pd_lock: lock protects pd_state and pd_provider_list 184 * pd_state: State value of the provider 185 * pd_provider_list: Used to cross-reference logical providers and their 186 * members. Not used for software providers. 187 * pd_resume_cv: cv to wait for state to change from KCF_PROV_BUSY 188 * pd_prov_handle: Provider handle specified by provider 189 * pd_ops_vector: The ops vector specified by Provider 190 * pd_mech_indx: Lookup table which maps a core framework mechanism 191 * number to an index in pd_mechanisms array 192 * pd_mechanisms: Array of mechanisms supported by the provider, specified 193 * by the provider during registration 194 * pd_mech_list_count: The number of entries in pi_mechanisms, specified 195 * by the provider during registration 196 * pd_name: Device name or module name 197 * pd_instance: Device instance 198 * pd_module_id: Module ID returned by modload 199 * pd_mctlp: Pointer to modctl structure for this provider 200 * pd_description: Provider description string 201 * pd_flags: bitwise OR of pi_flags from crypto_provider_info_t 202 * and other internal flags defined above. 203 * pd_hash_limit: Maximum data size that hash mechanisms of this provider 204 * can support. 205 * pd_hmac_limit: Maximum data size that HMAC mechanisms of this provider 206 * can support. 207 * pd_kcf_prov_handle: KCF-private handle assigned by KCF 208 * pd_prov_id: Identification # assigned by KCF to provider 209 * pd_kstat: kstat associated with the provider 210 * pd_ks_data: kstat data 211 */ 212 typedef struct kcf_provider_desc { 213 crypto_provider_type_t pd_prov_type; 214 crypto_session_id_t pd_sid; 215 taskq_t *pd_taskq; 216 uint_t pd_nbins; 217 kcf_prov_cpu_t *pd_percpu_bins; 218 kmutex_t pd_lock; 219 kcf_prov_state_t pd_state; 220 struct kcf_provider_list *pd_provider_list; 221 kcondvar_t pd_resume_cv; 222 crypto_provider_handle_t pd_prov_handle; 223 crypto_ops_t *pd_ops_vector; 224 ushort_t pd_mech_indx[KCF_OPS_CLASSSIZE]\ 225 [KCF_MAXMECHTAB]; 226 crypto_mech_info_t *pd_mechanisms; 227 uint_t pd_mech_list_count; 228 char *pd_name; 229 uint_t pd_instance; 230 int pd_module_id; 231 struct modctl *pd_mctlp; 232 char *pd_description; 233 uint_t pd_flags; 234 uint_t pd_hash_limit; 235 uint_t pd_hmac_limit; 236 crypto_kcf_provider_handle_t pd_kcf_prov_handle; 237 crypto_provider_id_t pd_prov_id; 238 kstat_t *pd_kstat; 239 kcf_prov_stats_t pd_ks_data; 240 } kcf_provider_desc_t; 241 242 /* useful for making a list of providers */ 243 typedef struct kcf_provider_list { 244 struct kcf_provider_list *pl_next; 245 struct kcf_provider_desc *pl_provider; 246 } kcf_provider_list_t; 247 248 /* 249 * If a component has a reference to a kcf_provider_desc_t, 250 * it REFHOLD()s. A new provider descriptor which is referenced only 251 * by the providers table has a reference counter of one. 252 */ 253 #define KCF_PROV_REFHOLD(desc) { \ 254 kcf_prov_cpu_t *mp; \ 255 \ 256 mp = &((desc)->pd_percpu_bins[CPU_SEQID]); \ 257 mutex_enter(&mp->kp_lock); \ 258 mp->kp_holdcnt++; \ 259 mutex_exit(&mp->kp_lock); \ 260 } 261 262 #define KCF_PROV_REFRELE(desc) { \ 263 kcf_prov_cpu_t *mp; \ 264 \ 265 mp = &((desc)->pd_percpu_bins[CPU_SEQID]); \ 266 mutex_enter(&mp->kp_lock); \ 267 mp->kp_holdcnt--; \ 268 mutex_exit(&mp->kp_lock); \ 269 } 270 271 #define KCF_PROV_REFHELD(desc) (kcf_get_refcnt(desc, B_TRUE) >= 1) 272 273 /* 274 * The JOB macros are used only for a hardware provider. 275 * Hardware providers can have holds that stay forever. 276 * So, the job counter is used to check if it is safe to 277 * unregister a provider. 278 */ 279 #define KCF_PROV_JOB_HOLD(mp) { \ 280 mutex_enter(&(mp)->kp_lock); \ 281 (mp)->kp_jobcnt++; \ 282 mutex_exit(&(mp)->kp_lock); \ 283 } 284 285 #define KCF_PROV_JOB_RELE(mp) { \ 286 mutex_enter(&(mp)->kp_lock); \ 287 (mp)->kp_jobcnt--; \ 288 if ((mp)->kp_jobcnt == 0) \ 289 cv_signal(&(mp)->kp_cv); \ 290 mutex_exit(&(mp)->kp_lock); \ 291 } 292 293 #define KCF_PROV_JOB_RELE_STAT(mp, doincr) { \ 294 if (doincr) \ 295 (mp)->kp_nfails++; \ 296 KCF_PROV_JOB_RELE(mp); \ 297 } 298 299 #define KCF_PROV_INCRSTATS(pd, error) { \ 300 kcf_prov_cpu_t *mp; \ 301 \ 302 mp = &((pd)->pd_percpu_bins[CPU_SEQID]); \ 303 mp->kp_ndispatches++; \ 304 if ((error) == CRYPTO_BUSY) \ 305 mp->kp_nbusy_rval++; \ 306 else if ((error) != CRYPTO_SUCCESS && (error) != CRYPTO_QUEUED) \ 307 mp->kp_nfails++; \ 308 } 309 310 /* list of crypto_mech_info_t valid as the second mech in a dual operation */ 311 312 typedef struct crypto_mech_info_list { 313 struct crypto_mech_info_list *ml_next; 314 crypto_mech_type_t ml_kcf_mechid; /* KCF's id */ 315 crypto_mech_info_t ml_mech_info; 316 } crypto_mech_info_list_t; 317 318 /* 319 * An element in a mechanism provider descriptors chain. 320 * The kcf_prov_mech_desc_t is duplicated in every chain the provider belongs 321 * to. This is a small tradeoff memory vs mutex spinning time to access the 322 * common provider field. 323 */ 324 325 typedef struct kcf_prov_mech_desc { 326 struct kcf_mech_entry *pm_me; /* Back to the head */ 327 struct kcf_prov_mech_desc *pm_next; /* Next in the chain */ 328 crypto_mech_info_t pm_mech_info; /* Provider mech info */ 329 crypto_mech_info_list_t *pm_mi_list; /* list for duals */ 330 kcf_provider_desc_t *pm_prov_desc; /* Common desc. */ 331 } kcf_prov_mech_desc_t; 332 333 /* and the notation shortcuts ... */ 334 #define pm_provider_type pm_prov_desc.pd_provider_type 335 #define pm_provider_handle pm_prov_desc.pd_provider_handle 336 #define pm_ops_vector pm_prov_desc.pd_ops_vector 337 338 extern kcf_lock_withpad_t *me_mutexes; 339 340 #define KCF_CPU_PAD (128 - sizeof (crypto_mech_name_t) - \ 341 sizeof (crypto_mech_type_t) - \ 342 2 * sizeof (kcf_prov_mech_desc_t *) - \ 343 sizeof (int) - sizeof (uint32_t) - sizeof (size_t)) 344 345 /* 346 * A mechanism entry in an xxx_mech_tab[]. KCF_CPU_PAD needs 347 * to be adjusted if this structure is changed. 348 */ 349 typedef struct kcf_mech_entry { 350 crypto_mech_name_t me_name; /* mechanism name */ 351 crypto_mech_type_t me_mechid; /* Internal id for mechanism */ 352 kcf_prov_mech_desc_t *me_hw_prov_chain; /* list of HW providers */ 353 kcf_prov_mech_desc_t *me_sw_prov; /* SW provider */ 354 /* 355 * Number of HW providers in the chain. There is only one 356 * SW provider. So, we need only a count of HW providers. 357 */ 358 int me_num_hwprov; 359 /* 360 * When a SW provider is present, this is the generation number that 361 * ensures no objects from old SW providers are used in the new one 362 */ 363 uint32_t me_gen_swprov; 364 /* 365 * threshold for using hardware providers for this mech 366 */ 367 size_t me_threshold; 368 uint8_t me_pad[KCF_CPU_PAD]; 369 } kcf_mech_entry_t; 370 371 /* 372 * A policy descriptor structure. It is allocated and initialized 373 * when administrative ioctls load disabled mechanisms. 374 * 375 * pd_prov_type: Provider type, hardware or software 376 * pd_name: Device name or module name. 377 * pd_instance: Device instance. 378 * pd_refcnt: Reference counter for this policy descriptor 379 * pd_mutex: Protects array and count of disabled mechanisms. 380 * pd_disabled_count: Count of disabled mechanisms. 381 * pd_disabled_mechs: Array of disabled mechanisms. 382 */ 383 typedef struct kcf_policy_desc { 384 crypto_provider_type_t pd_prov_type; 385 char *pd_name; 386 uint_t pd_instance; 387 uint_t pd_refcnt; 388 kmutex_t pd_mutex; 389 uint_t pd_disabled_count; 390 crypto_mech_name_t *pd_disabled_mechs; 391 } kcf_policy_desc_t; 392 393 /* 394 * If a component has a reference to a kcf_policy_desc_t, 395 * it REFHOLD()s. A new policy descriptor which is referenced only 396 * by the policy table has a reference count of one. 397 */ 398 #define KCF_POLICY_REFHOLD(desc) { \ 399 atomic_add_32(&(desc)->pd_refcnt, 1); \ 400 ASSERT((desc)->pd_refcnt != 0); \ 401 } 402 403 /* 404 * Releases a reference to a policy descriptor. When the last 405 * reference is released, the descriptor is freed. 406 */ 407 #define KCF_POLICY_REFRELE(desc) { \ 408 ASSERT((desc)->pd_refcnt != 0); \ 409 membar_exit(); \ 410 if (atomic_add_32_nv(&(desc)->pd_refcnt, -1) == 0) \ 411 kcf_policy_free_desc(desc); \ 412 } 413 414 /* 415 * This entry stores the name of a software module and its 416 * mechanisms. The mechanisms are 'hints' that are used to 417 * trigger loading of the module. 418 */ 419 typedef struct kcf_soft_conf_entry { 420 struct kcf_soft_conf_entry *ce_next; 421 char *ce_name; 422 crypto_mech_name_t *ce_mechs; 423 uint_t ce_count; 424 } kcf_soft_conf_entry_t; 425 426 extern kmutex_t soft_config_mutex; 427 extern kcf_soft_conf_entry_t *soft_config_list; 428 429 /* 430 * Global tables. The sizes are from the predefined PKCS#11 v2.20 mechanisms, 431 * with a margin of few extra empty entry points 432 */ 433 434 #define KCF_MAXDIGEST 16 /* Digests */ 435 #define KCF_MAXCIPHER 64 /* Ciphers */ 436 #define KCF_MAXMAC 40 /* Message authentication codes */ 437 #define KCF_MAXSIGN 24 /* Sign/Verify */ 438 #define KCF_MAXKEYOPS 116 /* Key generation and derivation */ 439 #define KCF_MAXMISC 16 /* Others ... */ 440 441 #define KCF_MAXMECHS KCF_MAXDIGEST + KCF_MAXCIPHER + KCF_MAXMAC + \ 442 KCF_MAXSIGN + KCF_MAXKEYOPS + \ 443 KCF_MAXMISC 444 445 extern kcf_mech_entry_t kcf_digest_mechs_tab[]; 446 extern kcf_mech_entry_t kcf_cipher_mechs_tab[]; 447 extern kcf_mech_entry_t kcf_mac_mechs_tab[]; 448 extern kcf_mech_entry_t kcf_sign_mechs_tab[]; 449 extern kcf_mech_entry_t kcf_keyops_mechs_tab[]; 450 extern kcf_mech_entry_t kcf_misc_mechs_tab[]; 451 452 extern kmutex_t kcf_mech_tabs_lock; 453 454 typedef enum { 455 KCF_DIGEST_CLASS = 1, 456 KCF_CIPHER_CLASS, 457 KCF_MAC_CLASS, 458 KCF_SIGN_CLASS, 459 KCF_KEYOPS_CLASS, 460 KCF_MISC_CLASS 461 } kcf_ops_class_t; 462 463 #define KCF_FIRST_OPSCLASS KCF_DIGEST_CLASS 464 #define KCF_LAST_OPSCLASS KCF_MISC_CLASS 465 466 /* The table of all the kcf_xxx_mech_tab[]s, indexed by kcf_ops_class */ 467 468 typedef struct kcf_mech_entry_tab { 469 int met_size; /* Size of the met_tab[] */ 470 kcf_mech_entry_t *met_tab; /* the table */ 471 } kcf_mech_entry_tab_t; 472 473 extern kcf_mech_entry_tab_t kcf_mech_tabs_tab[]; 474 475 #define KCF_MECHID(class, index) \ 476 (((crypto_mech_type_t)(class) << 32) | (crypto_mech_type_t)(index)) 477 478 #define KCF_MECH2CLASS(mech_type) ((kcf_ops_class_t)((mech_type) >> 32)) 479 480 #define KCF_MECH2INDEX(mech_type) ((int)(mech_type)) 481 482 #define KCF_TO_PROV_MECH_INDX(pd, mech_type) \ 483 ((pd)->pd_mech_indx[KCF_MECH2CLASS(mech_type)] \ 484 [KCF_MECH2INDEX(mech_type)]) 485 486 #define KCF_TO_PROV_MECHINFO(pd, mech_type) \ 487 ((pd)->pd_mechanisms[KCF_TO_PROV_MECH_INDX(pd, mech_type)]) 488 489 #define KCF_TO_PROV_MECHNUM(pd, mech_type) \ 490 (KCF_TO_PROV_MECHINFO(pd, mech_type).cm_mech_number) 491 492 #define KCF_CAN_SHARE_OPSTATE(pd, mech_type) \ 493 ((KCF_TO_PROV_MECHINFO(pd, mech_type).cm_mech_flags) & \ 494 CRYPTO_CAN_SHARE_OPSTATE) 495 496 /* ps_refcnt is protected by cm_lock in the crypto_minor structure */ 497 typedef struct crypto_provider_session { 498 struct crypto_provider_session *ps_next; 499 crypto_session_id_t ps_session; 500 kcf_provider_desc_t *ps_provider; 501 kcf_provider_desc_t *ps_real_provider; 502 uint_t ps_refcnt; 503 } crypto_provider_session_t; 504 505 typedef struct crypto_session_data { 506 kmutex_t sd_lock; 507 kcondvar_t sd_cv; 508 uint32_t sd_flags; 509 int sd_pre_approved_amount; 510 crypto_ctx_t *sd_digest_ctx; 511 crypto_ctx_t *sd_encr_ctx; 512 crypto_ctx_t *sd_decr_ctx; 513 crypto_ctx_t *sd_sign_ctx; 514 crypto_ctx_t *sd_verify_ctx; 515 crypto_ctx_t *sd_sign_recover_ctx; 516 crypto_ctx_t *sd_verify_recover_ctx; 517 kcf_provider_desc_t *sd_provider; 518 void *sd_find_init_cookie; 519 crypto_provider_session_t *sd_provider_session; 520 } crypto_session_data_t; 521 522 #define CRYPTO_SESSION_IN_USE 0x00000001 523 #define CRYPTO_SESSION_IS_BUSY 0x00000002 524 #define CRYPTO_SESSION_IS_CLOSED 0x00000004 525 526 #define KCF_MAX_PIN_LEN 1024 527 528 /* Global FIPS 140 mode variable */ 529 extern uint32_t global_fips140_mode; 530 /* Global FIPS 140 mode lock */ 531 extern kmutex_t fips140_mode_lock; 532 /* Conditional variable for kcf to wait until kcfd tells the FIPS mode status */ 533 extern kcondvar_t cv_fips140; 534 535 /* 536 * Per-minor info. 537 * 538 * cm_lock protects everything in this structure except for cm_refcnt. 539 */ 540 typedef struct crypto_minor { 541 uint_t cm_refcnt; 542 kmutex_t cm_lock; 543 kcondvar_t cm_cv; 544 crypto_session_data_t **cm_session_table; 545 uint_t cm_session_table_count; 546 kcf_provider_desc_t **cm_provider_array; 547 uint_t cm_provider_count; 548 crypto_provider_session_t *cm_provider_session; 549 } crypto_minor_t; 550 551 /* resource control framework handle used by /dev/crypto */ 552 extern rctl_hndl_t rc_project_crypto_mem; 553 /* 554 * Return codes for internal functions 555 */ 556 #define KCF_SUCCESS 0x0 /* Successful call */ 557 #define KCF_INVALID_MECH_NUMBER 0x1 /* invalid mechanism number */ 558 #define KCF_INVALID_MECH_NAME 0x2 /* invalid mechanism name */ 559 #define KCF_INVALID_MECH_CLASS 0x3 /* invalid mechanism class */ 560 #define KCF_MECH_TAB_FULL 0x4 /* Need more room in the mech tabs. */ 561 #define KCF_INVALID_INDX ((ushort_t)-1) 562 563 /* 564 * kCF internal mechanism and function group for tracking RNG providers. 565 */ 566 #define SUN_RANDOM "random" 567 #define CRYPTO_FG_RANDOM 0x80000000 /* generate_random() */ 568 569 /* 570 * Wrappers for ops vectors. In the wrapper definitions below, the pd 571 * argument always corresponds to a pointer to a provider descriptor 572 * of type kcf_prov_desc_t. 573 */ 574 575 #define KCF_PROV_CONTROL_OPS(pd) ((pd)->pd_ops_vector->co_control_ops) 576 #define KCF_PROV_CTX_OPS(pd) ((pd)->pd_ops_vector->co_ctx_ops) 577 #define KCF_PROV_DIGEST_OPS(pd) ((pd)->pd_ops_vector->co_digest_ops) 578 #define KCF_PROV_CIPHER_OPS(pd) ((pd)->pd_ops_vector->co_cipher_ops) 579 #define KCF_PROV_MAC_OPS(pd) ((pd)->pd_ops_vector->co_mac_ops) 580 #define KCF_PROV_SIGN_OPS(pd) ((pd)->pd_ops_vector->co_sign_ops) 581 #define KCF_PROV_VERIFY_OPS(pd) ((pd)->pd_ops_vector->co_verify_ops) 582 #define KCF_PROV_DUAL_OPS(pd) ((pd)->pd_ops_vector->co_dual_ops) 583 #define KCF_PROV_DUAL_CIPHER_MAC_OPS(pd) \ 584 ((pd)->pd_ops_vector->co_dual_cipher_mac_ops) 585 #define KCF_PROV_RANDOM_OPS(pd) ((pd)->pd_ops_vector->co_random_ops) 586 #define KCF_PROV_SESSION_OPS(pd) ((pd)->pd_ops_vector->co_session_ops) 587 #define KCF_PROV_OBJECT_OPS(pd) ((pd)->pd_ops_vector->co_object_ops) 588 #define KCF_PROV_KEY_OPS(pd) ((pd)->pd_ops_vector->co_key_ops) 589 #define KCF_PROV_PROVIDER_OPS(pd) ((pd)->pd_ops_vector->co_provider_ops) 590 #define KCF_PROV_MECH_OPS(pd) ((pd)->pd_ops_vector->co_mech_ops) 591 #define KCF_PROV_NOSTORE_KEY_OPS(pd) \ 592 ((pd)->pd_ops_vector->co_nostore_key_ops) 593 #define KCF_PROV_FIPS140_OPS(pd) ((pd)->pd_ops_vector->co_fips140_ops) 594 #define KCF_PROV_PROVMGMT_OPS(pd) ((pd)->pd_ops_vector->co_provider_ops) 595 596 /* 597 * Wrappers for crypto_control_ops(9S) entry points. 598 */ 599 600 #define KCF_PROV_STATUS(pd, status) ( \ 601 (KCF_PROV_CONTROL_OPS(pd) && \ 602 KCF_PROV_CONTROL_OPS(pd)->provider_status) ? \ 603 KCF_PROV_CONTROL_OPS(pd)->provider_status( \ 604 (pd)->pd_prov_handle, status) : \ 605 CRYPTO_NOT_SUPPORTED) 606 607 /* 608 * Wrappers for crypto_ctx_ops(9S) entry points. 609 */ 610 611 #define KCF_PROV_CREATE_CTX_TEMPLATE(pd, mech, key, template, size, req) ( \ 612 (KCF_PROV_CTX_OPS(pd) && KCF_PROV_CTX_OPS(pd)->create_ctx_template) ? \ 613 KCF_PROV_CTX_OPS(pd)->create_ctx_template( \ 614 (pd)->pd_prov_handle, mech, key, template, size, req) : \ 615 CRYPTO_NOT_SUPPORTED) 616 617 #define KCF_PROV_FREE_CONTEXT(pd, ctx) ( \ 618 (KCF_PROV_CTX_OPS(pd) && KCF_PROV_CTX_OPS(pd)->free_context) ? \ 619 KCF_PROV_CTX_OPS(pd)->free_context(ctx) : CRYPTO_NOT_SUPPORTED) 620 621 #define KCF_PROV_COPYIN_MECH(pd, umech, kmech, errorp, mode) ( \ 622 (KCF_PROV_MECH_OPS(pd) && KCF_PROV_MECH_OPS(pd)->copyin_mechanism) ? \ 623 KCF_PROV_MECH_OPS(pd)->copyin_mechanism( \ 624 (pd)->pd_prov_handle, umech, kmech, errorp, mode) : \ 625 CRYPTO_NOT_SUPPORTED) 626 627 #define KCF_PROV_COPYOUT_MECH(pd, kmech, umech, errorp, mode) ( \ 628 (KCF_PROV_MECH_OPS(pd) && KCF_PROV_MECH_OPS(pd)->copyout_mechanism) ? \ 629 KCF_PROV_MECH_OPS(pd)->copyout_mechanism( \ 630 (pd)->pd_prov_handle, kmech, umech, errorp, mode) : \ 631 CRYPTO_NOT_SUPPORTED) 632 633 #define KCF_PROV_FREE_MECH(pd, prov_mech) ( \ 634 (KCF_PROV_MECH_OPS(pd) && KCF_PROV_MECH_OPS(pd)->free_mechanism) ? \ 635 KCF_PROV_MECH_OPS(pd)->free_mechanism( \ 636 (pd)->pd_prov_handle, prov_mech) : CRYPTO_NOT_SUPPORTED) 637 638 /* 639 * Wrappers for crypto_digest_ops(9S) entry points. 640 */ 641 642 #define KCF_PROV_DIGEST_INIT(pd, ctx, mech, req) ( \ 643 (KCF_PROV_DIGEST_OPS(pd) && KCF_PROV_DIGEST_OPS(pd)->digest_init) ? \ 644 KCF_PROV_DIGEST_OPS(pd)->digest_init(ctx, mech, req) : \ 645 CRYPTO_NOT_SUPPORTED) 646 647 /* 648 * The _ (underscore) in _digest is needed to avoid replacing the 649 * function digest(). 650 */ 651 #define KCF_PROV_DIGEST(pd, ctx, data, _digest, req) ( \ 652 (KCF_PROV_DIGEST_OPS(pd) && KCF_PROV_DIGEST_OPS(pd)->digest) ? \ 653 KCF_PROV_DIGEST_OPS(pd)->digest(ctx, data, _digest, req) : \ 654 CRYPTO_NOT_SUPPORTED) 655 656 #define KCF_PROV_DIGEST_UPDATE(pd, ctx, data, req) ( \ 657 (KCF_PROV_DIGEST_OPS(pd) && KCF_PROV_DIGEST_OPS(pd)->digest_update) ? \ 658 KCF_PROV_DIGEST_OPS(pd)->digest_update(ctx, data, req) : \ 659 CRYPTO_NOT_SUPPORTED) 660 661 #define KCF_PROV_DIGEST_KEY(pd, ctx, key, req) ( \ 662 (KCF_PROV_DIGEST_OPS(pd) && KCF_PROV_DIGEST_OPS(pd)->digest_key) ? \ 663 KCF_PROV_DIGEST_OPS(pd)->digest_key(ctx, key, req) : \ 664 CRYPTO_NOT_SUPPORTED) 665 666 #define KCF_PROV_DIGEST_FINAL(pd, ctx, digest, req) ( \ 667 (KCF_PROV_DIGEST_OPS(pd) && KCF_PROV_DIGEST_OPS(pd)->digest_final) ? \ 668 KCF_PROV_DIGEST_OPS(pd)->digest_final(ctx, digest, req) : \ 669 CRYPTO_NOT_SUPPORTED) 670 671 #define KCF_PROV_DIGEST_ATOMIC(pd, session, mech, data, digest, req) ( \ 672 (KCF_PROV_DIGEST_OPS(pd) && KCF_PROV_DIGEST_OPS(pd)->digest_atomic) ? \ 673 KCF_PROV_DIGEST_OPS(pd)->digest_atomic( \ 674 (pd)->pd_prov_handle, session, mech, data, digest, req) : \ 675 CRYPTO_NOT_SUPPORTED) 676 677 /* 678 * Wrappers for crypto_cipher_ops(9S) entry points. 679 */ 680 681 #define KCF_PROV_ENCRYPT_INIT(pd, ctx, mech, key, template, req) ( \ 682 (KCF_PROV_CIPHER_OPS(pd) && KCF_PROV_CIPHER_OPS(pd)->encrypt_init) ? \ 683 KCF_PROV_CIPHER_OPS(pd)->encrypt_init(ctx, mech, key, template, \ 684 req) : \ 685 CRYPTO_NOT_SUPPORTED) 686 687 #define KCF_PROV_ENCRYPT(pd, ctx, plaintext, ciphertext, req) ( \ 688 (KCF_PROV_CIPHER_OPS(pd) && KCF_PROV_CIPHER_OPS(pd)->encrypt) ? \ 689 KCF_PROV_CIPHER_OPS(pd)->encrypt(ctx, plaintext, ciphertext, req) : \ 690 CRYPTO_NOT_SUPPORTED) 691 692 #define KCF_PROV_ENCRYPT_UPDATE(pd, ctx, plaintext, ciphertext, req) ( \ 693 (KCF_PROV_CIPHER_OPS(pd) && KCF_PROV_CIPHER_OPS(pd)->encrypt_update) ? \ 694 KCF_PROV_CIPHER_OPS(pd)->encrypt_update(ctx, plaintext, \ 695 ciphertext, req) : \ 696 CRYPTO_NOT_SUPPORTED) 697 698 #define KCF_PROV_ENCRYPT_FINAL(pd, ctx, ciphertext, req) ( \ 699 (KCF_PROV_CIPHER_OPS(pd) && KCF_PROV_CIPHER_OPS(pd)->encrypt_final) ? \ 700 KCF_PROV_CIPHER_OPS(pd)->encrypt_final(ctx, ciphertext, req) : \ 701 CRYPTO_NOT_SUPPORTED) 702 703 #define KCF_PROV_ENCRYPT_ATOMIC(pd, session, mech, key, plaintext, ciphertext, \ 704 template, req) ( \ 705 (KCF_PROV_CIPHER_OPS(pd) && KCF_PROV_CIPHER_OPS(pd)->encrypt_atomic) ? \ 706 KCF_PROV_CIPHER_OPS(pd)->encrypt_atomic( \ 707 (pd)->pd_prov_handle, session, mech, key, plaintext, ciphertext, \ 708 template, req) : \ 709 CRYPTO_NOT_SUPPORTED) 710 711 #define KCF_PROV_DECRYPT_INIT(pd, ctx, mech, key, template, req) ( \ 712 (KCF_PROV_CIPHER_OPS(pd) && KCF_PROV_CIPHER_OPS(pd)->decrypt_init) ? \ 713 KCF_PROV_CIPHER_OPS(pd)->decrypt_init(ctx, mech, key, template, \ 714 req) : \ 715 CRYPTO_NOT_SUPPORTED) 716 717 #define KCF_PROV_DECRYPT(pd, ctx, ciphertext, plaintext, req) ( \ 718 (KCF_PROV_CIPHER_OPS(pd) && KCF_PROV_CIPHER_OPS(pd)->decrypt) ? \ 719 KCF_PROV_CIPHER_OPS(pd)->decrypt(ctx, ciphertext, plaintext, req) : \ 720 CRYPTO_NOT_SUPPORTED) 721 722 #define KCF_PROV_DECRYPT_UPDATE(pd, ctx, ciphertext, plaintext, req) ( \ 723 (KCF_PROV_CIPHER_OPS(pd) && KCF_PROV_CIPHER_OPS(pd)->decrypt_update) ? \ 724 KCF_PROV_CIPHER_OPS(pd)->decrypt_update(ctx, ciphertext, \ 725 plaintext, req) : \ 726 CRYPTO_NOT_SUPPORTED) 727 728 #define KCF_PROV_DECRYPT_FINAL(pd, ctx, plaintext, req) ( \ 729 (KCF_PROV_CIPHER_OPS(pd) && KCF_PROV_CIPHER_OPS(pd)->decrypt_final) ? \ 730 KCF_PROV_CIPHER_OPS(pd)->decrypt_final(ctx, plaintext, req) : \ 731 CRYPTO_NOT_SUPPORTED) 732 733 #define KCF_PROV_DECRYPT_ATOMIC(pd, session, mech, key, ciphertext, plaintext, \ 734 template, req) ( \ 735 (KCF_PROV_CIPHER_OPS(pd) && KCF_PROV_CIPHER_OPS(pd)->decrypt_atomic) ? \ 736 KCF_PROV_CIPHER_OPS(pd)->decrypt_atomic( \ 737 (pd)->pd_prov_handle, session, mech, key, ciphertext, plaintext, \ 738 template, req) : \ 739 CRYPTO_NOT_SUPPORTED) 740 741 /* 742 * Wrappers for crypto_mac_ops(9S) entry points. 743 */ 744 745 #define KCF_PROV_MAC_INIT(pd, ctx, mech, key, template, req) ( \ 746 (KCF_PROV_MAC_OPS(pd) && KCF_PROV_MAC_OPS(pd)->mac_init) ? \ 747 KCF_PROV_MAC_OPS(pd)->mac_init(ctx, mech, key, template, req) \ 748 : CRYPTO_NOT_SUPPORTED) 749 750 /* 751 * The _ (underscore) in _mac is needed to avoid replacing the 752 * function mac(). 753 */ 754 #define KCF_PROV_MAC(pd, ctx, data, _mac, req) ( \ 755 (KCF_PROV_MAC_OPS(pd) && KCF_PROV_MAC_OPS(pd)->mac) ? \ 756 KCF_PROV_MAC_OPS(pd)->mac(ctx, data, _mac, req) : \ 757 CRYPTO_NOT_SUPPORTED) 758 759 #define KCF_PROV_MAC_UPDATE(pd, ctx, data, req) ( \ 760 (KCF_PROV_MAC_OPS(pd) && KCF_PROV_MAC_OPS(pd)->mac_update) ? \ 761 KCF_PROV_MAC_OPS(pd)->mac_update(ctx, data, req) : \ 762 CRYPTO_NOT_SUPPORTED) 763 764 #define KCF_PROV_MAC_FINAL(pd, ctx, mac, req) ( \ 765 (KCF_PROV_MAC_OPS(pd) && KCF_PROV_MAC_OPS(pd)->mac_final) ? \ 766 KCF_PROV_MAC_OPS(pd)->mac_final(ctx, mac, req) : \ 767 CRYPTO_NOT_SUPPORTED) 768 769 #define KCF_PROV_MAC_ATOMIC(pd, session, mech, key, data, mac, template, \ 770 req) ( \ 771 (KCF_PROV_MAC_OPS(pd) && KCF_PROV_MAC_OPS(pd)->mac_atomic) ? \ 772 KCF_PROV_MAC_OPS(pd)->mac_atomic( \ 773 (pd)->pd_prov_handle, session, mech, key, data, mac, template, \ 774 req) : \ 775 CRYPTO_NOT_SUPPORTED) 776 777 #define KCF_PROV_MAC_VERIFY_ATOMIC(pd, session, mech, key, data, mac, \ 778 template, req) ( \ 779 (KCF_PROV_MAC_OPS(pd) && KCF_PROV_MAC_OPS(pd)->mac_verify_atomic) ? \ 780 KCF_PROV_MAC_OPS(pd)->mac_verify_atomic( \ 781 (pd)->pd_prov_handle, session, mech, key, data, mac, template, \ 782 req) : \ 783 CRYPTO_NOT_SUPPORTED) 784 785 /* 786 * Wrappers for crypto_sign_ops(9S) entry points. 787 */ 788 789 #define KCF_PROV_SIGN_INIT(pd, ctx, mech, key, template, req) ( \ 790 (KCF_PROV_SIGN_OPS(pd) && KCF_PROV_SIGN_OPS(pd)->sign_init) ? \ 791 KCF_PROV_SIGN_OPS(pd)->sign_init( \ 792 ctx, mech, key, template, req) : CRYPTO_NOT_SUPPORTED) 793 794 #define KCF_PROV_SIGN(pd, ctx, data, sig, req) ( \ 795 (KCF_PROV_SIGN_OPS(pd) && KCF_PROV_SIGN_OPS(pd)->sign) ? \ 796 KCF_PROV_SIGN_OPS(pd)->sign(ctx, data, sig, req) : \ 797 CRYPTO_NOT_SUPPORTED) 798 799 #define KCF_PROV_SIGN_UPDATE(pd, ctx, data, req) ( \ 800 (KCF_PROV_SIGN_OPS(pd) && KCF_PROV_SIGN_OPS(pd)->sign_update) ? \ 801 KCF_PROV_SIGN_OPS(pd)->sign_update(ctx, data, req) : \ 802 CRYPTO_NOT_SUPPORTED) 803 804 #define KCF_PROV_SIGN_FINAL(pd, ctx, sig, req) ( \ 805 (KCF_PROV_SIGN_OPS(pd) && KCF_PROV_SIGN_OPS(pd)->sign_final) ? \ 806 KCF_PROV_SIGN_OPS(pd)->sign_final(ctx, sig, req) : \ 807 CRYPTO_NOT_SUPPORTED) 808 809 #define KCF_PROV_SIGN_ATOMIC(pd, session, mech, key, data, template, \ 810 sig, req) ( \ 811 (KCF_PROV_SIGN_OPS(pd) && KCF_PROV_SIGN_OPS(pd)->sign_atomic) ? \ 812 KCF_PROV_SIGN_OPS(pd)->sign_atomic( \ 813 (pd)->pd_prov_handle, session, mech, key, data, sig, template, \ 814 req) : CRYPTO_NOT_SUPPORTED) 815 816 #define KCF_PROV_SIGN_RECOVER_INIT(pd, ctx, mech, key, template, \ 817 req) ( \ 818 (KCF_PROV_SIGN_OPS(pd) && KCF_PROV_SIGN_OPS(pd)->sign_recover_init) ? \ 819 KCF_PROV_SIGN_OPS(pd)->sign_recover_init(ctx, mech, key, template, \ 820 req) : CRYPTO_NOT_SUPPORTED) 821 822 #define KCF_PROV_SIGN_RECOVER(pd, ctx, data, sig, req) ( \ 823 (KCF_PROV_SIGN_OPS(pd) && KCF_PROV_SIGN_OPS(pd)->sign_recover) ? \ 824 KCF_PROV_SIGN_OPS(pd)->sign_recover(ctx, data, sig, req) : \ 825 CRYPTO_NOT_SUPPORTED) 826 827 #define KCF_PROV_SIGN_RECOVER_ATOMIC(pd, session, mech, key, data, template, \ 828 sig, req) ( \ 829 (KCF_PROV_SIGN_OPS(pd) && \ 830 KCF_PROV_SIGN_OPS(pd)->sign_recover_atomic) ? \ 831 KCF_PROV_SIGN_OPS(pd)->sign_recover_atomic( \ 832 (pd)->pd_prov_handle, session, mech, key, data, sig, template, \ 833 req) : CRYPTO_NOT_SUPPORTED) 834 835 /* 836 * Wrappers for crypto_verify_ops(9S) entry points. 837 */ 838 839 #define KCF_PROV_VERIFY_INIT(pd, ctx, mech, key, template, req) ( \ 840 (KCF_PROV_VERIFY_OPS(pd) && KCF_PROV_VERIFY_OPS(pd)->verify_init) ? \ 841 KCF_PROV_VERIFY_OPS(pd)->verify_init(ctx, mech, key, template, \ 842 req) : CRYPTO_NOT_SUPPORTED) 843 844 #define KCF_PROV_VERIFY(pd, ctx, data, sig, req) ( \ 845 (KCF_PROV_VERIFY_OPS(pd) && KCF_PROV_VERIFY_OPS(pd)->verify) ? \ 846 KCF_PROV_VERIFY_OPS(pd)->verify(ctx, data, sig, req) : \ 847 CRYPTO_NOT_SUPPORTED) 848 849 #define KCF_PROV_VERIFY_UPDATE(pd, ctx, data, req) ( \ 850 (KCF_PROV_VERIFY_OPS(pd) && KCF_PROV_VERIFY_OPS(pd)->verify_update) ? \ 851 KCF_PROV_VERIFY_OPS(pd)->verify_update(ctx, data, req) : \ 852 CRYPTO_NOT_SUPPORTED) 853 854 #define KCF_PROV_VERIFY_FINAL(pd, ctx, sig, req) ( \ 855 (KCF_PROV_VERIFY_OPS(pd) && KCF_PROV_VERIFY_OPS(pd)->verify_final) ? \ 856 KCF_PROV_VERIFY_OPS(pd)->verify_final(ctx, sig, req) : \ 857 CRYPTO_NOT_SUPPORTED) 858 859 #define KCF_PROV_VERIFY_ATOMIC(pd, session, mech, key, data, template, sig, \ 860 req) ( \ 861 (KCF_PROV_VERIFY_OPS(pd) && KCF_PROV_VERIFY_OPS(pd)->verify_atomic) ? \ 862 KCF_PROV_VERIFY_OPS(pd)->verify_atomic( \ 863 (pd)->pd_prov_handle, session, mech, key, data, sig, template, \ 864 req) : CRYPTO_NOT_SUPPORTED) 865 866 #define KCF_PROV_VERIFY_RECOVER_INIT(pd, ctx, mech, key, template, \ 867 req) ( \ 868 (KCF_PROV_VERIFY_OPS(pd) && \ 869 KCF_PROV_VERIFY_OPS(pd)->verify_recover_init) ? \ 870 KCF_PROV_VERIFY_OPS(pd)->verify_recover_init(ctx, mech, key, \ 871 template, req) : CRYPTO_NOT_SUPPORTED) 872 873 /* verify_recover() CSPI routine has different argument order than verify() */ 874 #define KCF_PROV_VERIFY_RECOVER(pd, ctx, sig, data, req) ( \ 875 (KCF_PROV_VERIFY_OPS(pd) && KCF_PROV_VERIFY_OPS(pd)->verify_recover) ? \ 876 KCF_PROV_VERIFY_OPS(pd)->verify_recover(ctx, sig, data, req) : \ 877 CRYPTO_NOT_SUPPORTED) 878 879 /* 880 * verify_recover_atomic() CSPI routine has different argument order 881 * than verify_atomic(). 882 */ 883 #define KCF_PROV_VERIFY_RECOVER_ATOMIC(pd, session, mech, key, sig, \ 884 template, data, req) ( \ 885 (KCF_PROV_VERIFY_OPS(pd) && \ 886 KCF_PROV_VERIFY_OPS(pd)->verify_recover_atomic) ? \ 887 KCF_PROV_VERIFY_OPS(pd)->verify_recover_atomic( \ 888 (pd)->pd_prov_handle, session, mech, key, sig, data, template, \ 889 req) : CRYPTO_NOT_SUPPORTED) 890 891 /* 892 * Wrappers for crypto_dual_ops(9S) entry points. 893 */ 894 895 #define KCF_PROV_DIGEST_ENCRYPT_UPDATE(digest_ctx, encrypt_ctx, plaintext, \ 896 ciphertext, req) ( \ 897 (KCF_PROV_DUAL_OPS(pd) && \ 898 KCF_PROV_DUAL_OPS(pd)->digest_encrypt_update) ? \ 899 KCF_PROV_DUAL_OPS(pd)->digest_encrypt_update( \ 900 digest_ctx, encrypt_ctx, plaintext, ciphertext, req) : \ 901 CRYPTO_NOT_SUPPORTED) 902 903 #define KCF_PROV_DECRYPT_DIGEST_UPDATE(decrypt_ctx, digest_ctx, ciphertext, \ 904 plaintext, req) ( \ 905 (KCF_PROV_DUAL_OPS(pd) && \ 906 KCF_PROV_DUAL_OPS(pd)->decrypt_digest_update) ? \ 907 KCF_PROV_DUAL_OPS(pd)->decrypt_digest_update( \ 908 decrypt_ctx, digest_ctx, ciphertext, plaintext, req) : \ 909 CRYPTO_NOT_SUPPORTED) 910 911 #define KCF_PROV_SIGN_ENCRYPT_UPDATE(sign_ctx, encrypt_ctx, plaintext, \ 912 ciphertext, req) ( \ 913 (KCF_PROV_DUAL_OPS(pd) && \ 914 KCF_PROV_DUAL_OPS(pd)->sign_encrypt_update) ? \ 915 KCF_PROV_DUAL_OPS(pd)->sign_encrypt_update( \ 916 sign_ctx, encrypt_ctx, plaintext, ciphertext, req) : \ 917 CRYPTO_NOT_SUPPORTED) 918 919 #define KCF_PROV_DECRYPT_VERIFY_UPDATE(decrypt_ctx, verify_ctx, ciphertext, \ 920 plaintext, req) ( \ 921 (KCF_PROV_DUAL_OPS(pd) && \ 922 KCF_PROV_DUAL_OPS(pd)->decrypt_verify_update) ? \ 923 KCF_PROV_DUAL_OPS(pd)->decrypt_verify_update( \ 924 decrypt_ctx, verify_ctx, ciphertext, plaintext, req) : \ 925 CRYPTO_NOT_SUPPORTED) 926 927 /* 928 * Wrappers for crypto_dual_cipher_mac_ops(9S) entry points. 929 */ 930 931 #define KCF_PROV_ENCRYPT_MAC_INIT(pd, ctx, encr_mech, encr_key, mac_mech, \ 932 mac_key, encr_ctx_template, mac_ctx_template, req) ( \ 933 (KCF_PROV_DUAL_CIPHER_MAC_OPS(pd) && \ 934 KCF_PROV_DUAL_CIPHER_MAC_OPS(pd)->encrypt_mac_init) ? \ 935 KCF_PROV_DUAL_CIPHER_MAC_OPS(pd)->encrypt_mac_init( \ 936 ctx, encr_mech, encr_key, mac_mech, mac_key, encr_ctx_template, \ 937 mac_ctx_template, req) : \ 938 CRYPTO_NOT_SUPPORTED) 939 940 #define KCF_PROV_ENCRYPT_MAC(pd, ctx, plaintext, ciphertext, mac, req) ( \ 941 (KCF_PROV_DUAL_CIPHER_MAC_OPS(pd) && \ 942 KCF_PROV_DUAL_CIPHER_MAC_OPS(pd)->encrypt_mac) ? \ 943 KCF_PROV_DUAL_CIPHER_MAC_OPS(pd)->encrypt_mac( \ 944 ctx, plaintext, ciphertext, mac, req) : \ 945 CRYPTO_NOT_SUPPORTED) 946 947 #define KCF_PROV_ENCRYPT_MAC_UPDATE(pd, ctx, plaintext, ciphertext, req) ( \ 948 (KCF_PROV_DUAL_CIPHER_MAC_OPS(pd) && \ 949 KCF_PROV_DUAL_CIPHER_MAC_OPS(pd)->encrypt_mac_update) ? \ 950 KCF_PROV_DUAL_CIPHER_MAC_OPS(pd)->encrypt_mac_update( \ 951 ctx, plaintext, ciphertext, req) : \ 952 CRYPTO_NOT_SUPPORTED) 953 954 #define KCF_PROV_ENCRYPT_MAC_FINAL(pd, ctx, ciphertext, mac, req) ( \ 955 (KCF_PROV_DUAL_CIPHER_MAC_OPS(pd) && \ 956 KCF_PROV_DUAL_CIPHER_MAC_OPS(pd)->encrypt_mac_final) ? \ 957 KCF_PROV_DUAL_CIPHER_MAC_OPS(pd)->encrypt_mac_final( \ 958 ctx, ciphertext, mac, req) : \ 959 CRYPTO_NOT_SUPPORTED) 960 961 #define KCF_PROV_ENCRYPT_MAC_ATOMIC(pd, session, encr_mech, encr_key, \ 962 mac_mech, mac_key, plaintext, ciphertext, mac, \ 963 encr_ctx_template, mac_ctx_template, req) ( \ 964 (KCF_PROV_DUAL_CIPHER_MAC_OPS(pd) && \ 965 KCF_PROV_DUAL_CIPHER_MAC_OPS(pd)->encrypt_mac_atomic) ? \ 966 KCF_PROV_DUAL_CIPHER_MAC_OPS(pd)->encrypt_mac_atomic( \ 967 (pd)->pd_prov_handle, session, encr_mech, encr_key, \ 968 mac_mech, mac_key, plaintext, ciphertext, mac, \ 969 encr_ctx_template, mac_ctx_template, req) : \ 970 CRYPTO_NOT_SUPPORTED) 971 972 #define KCF_PROV_MAC_DECRYPT_INIT(pd, ctx, mac_mech, mac_key, decr_mech, \ 973 decr_key, mac_ctx_template, decr_ctx_template, req) ( \ 974 (KCF_PROV_DUAL_CIPHER_MAC_OPS(pd) && \ 975 KCF_PROV_DUAL_CIPHER_MAC_OPS(pd)->mac_decrypt_init) ? \ 976 KCF_PROV_DUAL_CIPHER_MAC_OPS(pd)->mac_decrypt_init( \ 977 ctx, mac_mech, mac_key, decr_mech, decr_key, mac_ctx_template, \ 978 decr_ctx_template, req) : \ 979 CRYPTO_NOT_SUPPORTED) 980 981 #define KCF_PROV_MAC_DECRYPT(pd, ctx, ciphertext, mac, plaintext, req) ( \ 982 (KCF_PROV_DUAL_CIPHER_MAC_OPS(pd) && \ 983 KCF_PROV_DUAL_CIPHER_MAC_OPS(pd)->mac_decrypt) ? \ 984 KCF_PROV_DUAL_CIPHER_MAC_OPS(pd)->mac_decrypt( \ 985 ctx, ciphertext, mac, plaintext, req) : \ 986 CRYPTO_NOT_SUPPORTED) 987 988 #define KCF_PROV_MAC_DECRYPT_UPDATE(pd, ctx, ciphertext, plaintext, req) ( \ 989 (KCF_PROV_DUAL_CIPHER_MAC_OPS(pd) && \ 990 KCF_PROV_DUAL_CIPHER_MAC_OPS(pd)->mac_decrypt_update) ? \ 991 KCF_PROV_DUAL_CIPHER_MAC_OPS(pd)->mac_decrypt_update( \ 992 ctx, ciphertext, plaintext, req) : \ 993 CRYPTO_NOT_SUPPORTED) 994 995 #define KCF_PROV_MAC_DECRYPT_FINAL(pd, ctx, mac, plaintext, req) ( \ 996 (KCF_PROV_DUAL_CIPHER_MAC_OPS(pd) && \ 997 KCF_PROV_DUAL_CIPHER_MAC_OPS(pd)->mac_decrypt_final) ? \ 998 KCF_PROV_DUAL_CIPHER_MAC_OPS(pd)->mac_decrypt_final( \ 999 ctx, mac, plaintext, req) : \ 1000 CRYPTO_NOT_SUPPORTED) 1001 1002 #define KCF_PROV_MAC_DECRYPT_ATOMIC(pd, session, mac_mech, mac_key, \ 1003 decr_mech, decr_key, ciphertext, mac, plaintext, \ 1004 mac_ctx_template, decr_ctx_template, req) ( \ 1005 (KCF_PROV_DUAL_CIPHER_MAC_OPS(pd) && \ 1006 KCF_PROV_DUAL_CIPHER_MAC_OPS(pd)->mac_decrypt_atomic) ? \ 1007 KCF_PROV_DUAL_CIPHER_MAC_OPS(pd)->mac_decrypt_atomic( \ 1008 (pd)->pd_prov_handle, session, mac_mech, mac_key, \ 1009 decr_mech, decr_key, ciphertext, mac, plaintext, \ 1010 mac_ctx_template, decr_ctx_template, req) : \ 1011 CRYPTO_NOT_SUPPORTED) 1012 1013 #define KCF_PROV_MAC_VERIFY_DECRYPT_ATOMIC(pd, session, mac_mech, mac_key, \ 1014 decr_mech, decr_key, ciphertext, mac, plaintext, \ 1015 mac_ctx_template, decr_ctx_template, req) ( \ 1016 (KCF_PROV_DUAL_CIPHER_MAC_OPS(pd) && \ 1017 KCF_PROV_DUAL_CIPHER_MAC_OPS(pd)->mac_verify_decrypt_atomic \ 1018 != NULL) ? \ 1019 KCF_PROV_DUAL_CIPHER_MAC_OPS(pd)->mac_verify_decrypt_atomic( \ 1020 (pd)->pd_prov_handle, session, mac_mech, mac_key, \ 1021 decr_mech, decr_key, ciphertext, mac, plaintext, \ 1022 mac_ctx_template, decr_ctx_template, req) : \ 1023 CRYPTO_NOT_SUPPORTED) 1024 1025 /* 1026 * Wrappers for crypto_random_number_ops(9S) entry points. 1027 */ 1028 1029 #define KCF_PROV_SEED_RANDOM(pd, session, buf, len, est, flags, req) ( \ 1030 (KCF_PROV_RANDOM_OPS(pd) && KCF_PROV_RANDOM_OPS(pd)->seed_random) ? \ 1031 KCF_PROV_RANDOM_OPS(pd)->seed_random((pd)->pd_prov_handle, \ 1032 session, buf, len, est, flags, req) : CRYPTO_NOT_SUPPORTED) 1033 1034 #define KCF_PROV_GENERATE_RANDOM(pd, session, buf, len, req) ( \ 1035 (KCF_PROV_RANDOM_OPS(pd) && \ 1036 KCF_PROV_RANDOM_OPS(pd)->generate_random) ? \ 1037 KCF_PROV_RANDOM_OPS(pd)->generate_random((pd)->pd_prov_handle, \ 1038 session, buf, len, req) : CRYPTO_NOT_SUPPORTED) 1039 1040 /* 1041 * Wrappers for crypto_session_ops(9S) entry points. 1042 * 1043 * ops_pd is the provider descriptor that supplies the ops_vector. 1044 * pd is the descriptor that supplies the provider handle. 1045 * Only session open/close needs two handles. 1046 */ 1047 1048 #define KCF_PROV_SESSION_OPEN(ops_pd, session, req, pd) ( \ 1049 (KCF_PROV_SESSION_OPS(ops_pd) && \ 1050 KCF_PROV_SESSION_OPS(ops_pd)->session_open) ? \ 1051 KCF_PROV_SESSION_OPS(ops_pd)->session_open((pd)->pd_prov_handle, \ 1052 session, req) : CRYPTO_NOT_SUPPORTED) 1053 1054 #define KCF_PROV_SESSION_CLOSE(ops_pd, session, req, pd) ( \ 1055 (KCF_PROV_SESSION_OPS(ops_pd) && \ 1056 KCF_PROV_SESSION_OPS(ops_pd)->session_close) ? \ 1057 KCF_PROV_SESSION_OPS(ops_pd)->session_close((pd)->pd_prov_handle, \ 1058 session, req) : CRYPTO_NOT_SUPPORTED) 1059 1060 #define KCF_PROV_SESSION_LOGIN(pd, session, user_type, pin, len, req) ( \ 1061 (KCF_PROV_SESSION_OPS(pd) && \ 1062 KCF_PROV_SESSION_OPS(pd)->session_login) ? \ 1063 KCF_PROV_SESSION_OPS(pd)->session_login((pd)->pd_prov_handle, \ 1064 session, user_type, pin, len, req) : CRYPTO_NOT_SUPPORTED) 1065 1066 #define KCF_PROV_SESSION_LOGOUT(pd, session, req) ( \ 1067 (KCF_PROV_SESSION_OPS(pd) && \ 1068 KCF_PROV_SESSION_OPS(pd)->session_logout) ? \ 1069 KCF_PROV_SESSION_OPS(pd)->session_logout((pd)->pd_prov_handle, \ 1070 session, req) : CRYPTO_NOT_SUPPORTED) 1071 1072 /* 1073 * Wrappers for crypto_object_ops(9S) entry points. 1074 */ 1075 1076 #define KCF_PROV_OBJECT_CREATE(pd, session, template, count, object, req) ( \ 1077 (KCF_PROV_OBJECT_OPS(pd) && KCF_PROV_OBJECT_OPS(pd)->object_create) ? \ 1078 KCF_PROV_OBJECT_OPS(pd)->object_create((pd)->pd_prov_handle, \ 1079 session, template, count, object, req) : CRYPTO_NOT_SUPPORTED) 1080 1081 #define KCF_PROV_OBJECT_COPY(pd, session, object, template, count, \ 1082 new_object, req) ( \ 1083 (KCF_PROV_OBJECT_OPS(pd) && KCF_PROV_OBJECT_OPS(pd)->object_copy) ? \ 1084 KCF_PROV_OBJECT_OPS(pd)->object_copy((pd)->pd_prov_handle, \ 1085 session, object, template, count, new_object, req) : \ 1086 CRYPTO_NOT_SUPPORTED) 1087 1088 #define KCF_PROV_OBJECT_DESTROY(pd, session, object, req) ( \ 1089 (KCF_PROV_OBJECT_OPS(pd) && KCF_PROV_OBJECT_OPS(pd)->object_destroy) ? \ 1090 KCF_PROV_OBJECT_OPS(pd)->object_destroy((pd)->pd_prov_handle, \ 1091 session, object, req) : CRYPTO_NOT_SUPPORTED) 1092 1093 #define KCF_PROV_OBJECT_GET_SIZE(pd, session, object, size, req) ( \ 1094 (KCF_PROV_OBJECT_OPS(pd) && \ 1095 KCF_PROV_OBJECT_OPS(pd)->object_get_size) ? \ 1096 KCF_PROV_OBJECT_OPS(pd)->object_get_size((pd)->pd_prov_handle, \ 1097 session, object, size, req) : CRYPTO_NOT_SUPPORTED) 1098 1099 #define KCF_PROV_OBJECT_GET_ATTRIBUTE_VALUE(pd, session, object, template, \ 1100 count, req) ( \ 1101 (KCF_PROV_OBJECT_OPS(pd) && \ 1102 KCF_PROV_OBJECT_OPS(pd)->object_get_attribute_value) ? \ 1103 KCF_PROV_OBJECT_OPS(pd)->object_get_attribute_value( \ 1104 (pd)->pd_prov_handle, session, object, template, count, req) : \ 1105 CRYPTO_NOT_SUPPORTED) 1106 1107 #define KCF_PROV_OBJECT_SET_ATTRIBUTE_VALUE(pd, session, object, template, \ 1108 count, req) ( \ 1109 (KCF_PROV_OBJECT_OPS(pd) && \ 1110 KCF_PROV_OBJECT_OPS(pd)->object_set_attribute_value) ? \ 1111 KCF_PROV_OBJECT_OPS(pd)->object_set_attribute_value( \ 1112 (pd)->pd_prov_handle, session, object, template, count, req) : \ 1113 CRYPTO_NOT_SUPPORTED) 1114 1115 #define KCF_PROV_OBJECT_FIND_INIT(pd, session, template, count, ppriv, \ 1116 req) ( \ 1117 (KCF_PROV_OBJECT_OPS(pd) && \ 1118 KCF_PROV_OBJECT_OPS(pd)->object_find_init) ? \ 1119 KCF_PROV_OBJECT_OPS(pd)->object_find_init((pd)->pd_prov_handle, \ 1120 session, template, count, ppriv, req) : CRYPTO_NOT_SUPPORTED) 1121 1122 #define KCF_PROV_OBJECT_FIND(pd, ppriv, objects, max_objects, object_count, \ 1123 req) ( \ 1124 (KCF_PROV_OBJECT_OPS(pd) && KCF_PROV_OBJECT_OPS(pd)->object_find) ? \ 1125 KCF_PROV_OBJECT_OPS(pd)->object_find( \ 1126 (pd)->pd_prov_handle, ppriv, objects, max_objects, object_count, \ 1127 req) : CRYPTO_NOT_SUPPORTED) 1128 1129 #define KCF_PROV_OBJECT_FIND_FINAL(pd, ppriv, req) ( \ 1130 (KCF_PROV_OBJECT_OPS(pd) && \ 1131 KCF_PROV_OBJECT_OPS(pd)->object_find_final) ? \ 1132 KCF_PROV_OBJECT_OPS(pd)->object_find_final( \ 1133 (pd)->pd_prov_handle, ppriv, req) : CRYPTO_NOT_SUPPORTED) 1134 1135 /* 1136 * Wrappers for crypto_key_ops(9S) entry points. 1137 */ 1138 1139 #define KCF_PROV_KEY_GENERATE(pd, session, mech, template, count, object, \ 1140 req) ( \ 1141 (KCF_PROV_KEY_OPS(pd) && KCF_PROV_KEY_OPS(pd)->key_generate) ? \ 1142 KCF_PROV_KEY_OPS(pd)->key_generate((pd)->pd_prov_handle, \ 1143 session, mech, template, count, object, req) : \ 1144 CRYPTO_NOT_SUPPORTED) 1145 1146 #define KCF_PROV_KEY_GENERATE_PAIR(pd, session, mech, pub_template, \ 1147 pub_count, priv_template, priv_count, pub_key, priv_key, req) ( \ 1148 (KCF_PROV_KEY_OPS(pd) && KCF_PROV_KEY_OPS(pd)->key_generate_pair) ? \ 1149 KCF_PROV_KEY_OPS(pd)->key_generate_pair((pd)->pd_prov_handle, \ 1150 session, mech, pub_template, pub_count, priv_template, \ 1151 priv_count, pub_key, priv_key, req) : \ 1152 CRYPTO_NOT_SUPPORTED) 1153 1154 #define KCF_PROV_KEY_WRAP(pd, session, mech, wrapping_key, key, wrapped_key, \ 1155 wrapped_key_len, req) ( \ 1156 (KCF_PROV_KEY_OPS(pd) && KCF_PROV_KEY_OPS(pd)->key_wrap) ? \ 1157 KCF_PROV_KEY_OPS(pd)->key_wrap((pd)->pd_prov_handle, \ 1158 session, mech, wrapping_key, key, wrapped_key, wrapped_key_len, \ 1159 req) : \ 1160 CRYPTO_NOT_SUPPORTED) 1161 1162 #define KCF_PROV_KEY_UNWRAP(pd, session, mech, unwrapping_key, wrapped_key, \ 1163 wrapped_key_len, template, count, key, req) ( \ 1164 (KCF_PROV_KEY_OPS(pd) && KCF_PROV_KEY_OPS(pd)->key_unwrap) ? \ 1165 KCF_PROV_KEY_OPS(pd)->key_unwrap((pd)->pd_prov_handle, \ 1166 session, mech, unwrapping_key, wrapped_key, wrapped_key_len, \ 1167 template, count, key, req) : \ 1168 CRYPTO_NOT_SUPPORTED) 1169 1170 #define KCF_PROV_KEY_DERIVE(pd, session, mech, base_key, template, count, \ 1171 key, req) ( \ 1172 (KCF_PROV_KEY_OPS(pd) && KCF_PROV_KEY_OPS(pd)->key_derive) ? \ 1173 KCF_PROV_KEY_OPS(pd)->key_derive((pd)->pd_prov_handle, \ 1174 session, mech, base_key, template, count, key, req) : \ 1175 CRYPTO_NOT_SUPPORTED) 1176 1177 #define KCF_PROV_KEY_CHECK(pd, mech, key) ( \ 1178 (KCF_PROV_KEY_OPS(pd) && KCF_PROV_KEY_OPS(pd)->key_check) ? \ 1179 KCF_PROV_KEY_OPS(pd)->key_check((pd)->pd_prov_handle, mech, key) : \ 1180 CRYPTO_NOT_SUPPORTED) 1181 1182 /* 1183 * Wrappers for crypto_provider_management_ops(9S) entry points. 1184 * 1185 * ops_pd is the provider descriptor that supplies the ops_vector. 1186 * pd is the descriptor that supplies the provider handle. 1187 * Only ext_info needs two handles. 1188 */ 1189 1190 #define KCF_PROV_EXT_INFO(ops_pd, provext_info, req, pd) ( \ 1191 (KCF_PROV_PROVIDER_OPS(ops_pd) && \ 1192 KCF_PROV_PROVIDER_OPS(ops_pd)->ext_info) ? \ 1193 KCF_PROV_PROVIDER_OPS(ops_pd)->ext_info((pd)->pd_prov_handle, \ 1194 provext_info, req) : CRYPTO_NOT_SUPPORTED) 1195 1196 #define KCF_PROV_INIT_TOKEN(pd, pin, pin_len, label, req) ( \ 1197 (KCF_PROV_PROVIDER_OPS(pd) && KCF_PROV_PROVIDER_OPS(pd)->init_token) ? \ 1198 KCF_PROV_PROVIDER_OPS(pd)->init_token((pd)->pd_prov_handle, \ 1199 pin, pin_len, label, req) : CRYPTO_NOT_SUPPORTED) 1200 1201 #define KCF_PROV_INIT_PIN(pd, session, pin, pin_len, req) ( \ 1202 (KCF_PROV_PROVIDER_OPS(pd) && KCF_PROV_PROVIDER_OPS(pd)->init_pin) ? \ 1203 KCF_PROV_PROVIDER_OPS(pd)->init_pin((pd)->pd_prov_handle, \ 1204 session, pin, pin_len, req) : CRYPTO_NOT_SUPPORTED) 1205 1206 #define KCF_PROV_SET_PIN(pd, session, old_pin, old_len, new_pin, new_len, \ 1207 req) ( \ 1208 (KCF_PROV_PROVIDER_OPS(pd) && KCF_PROV_PROVIDER_OPS(pd)->set_pin) ? \ 1209 KCF_PROV_PROVIDER_OPS(pd)->set_pin((pd)->pd_prov_handle, \ 1210 session, old_pin, old_len, new_pin, new_len, req) : \ 1211 CRYPTO_NOT_SUPPORTED) 1212 1213 /* 1214 * Wrappers for crypto_nostore_key_ops(9S) entry points. 1215 */ 1216 1217 #define KCF_PROV_NOSTORE_KEY_GENERATE(pd, session, mech, template, count, \ 1218 out_template, out_count, req) ( \ 1219 (KCF_PROV_NOSTORE_KEY_OPS(pd) && \ 1220 KCF_PROV_NOSTORE_KEY_OPS(pd)->nostore_key_generate) ? \ 1221 KCF_PROV_NOSTORE_KEY_OPS(pd)->nostore_key_generate( \ 1222 (pd)->pd_prov_handle, session, mech, template, count, \ 1223 out_template, out_count, req) : CRYPTO_NOT_SUPPORTED) 1224 1225 #define KCF_PROV_NOSTORE_KEY_GENERATE_PAIR(pd, session, mech, pub_template, \ 1226 pub_count, priv_template, priv_count, out_pub_template, \ 1227 out_pub_count, out_priv_template, out_priv_count, req) ( \ 1228 (KCF_PROV_NOSTORE_KEY_OPS(pd) && \ 1229 KCF_PROV_NOSTORE_KEY_OPS(pd)->nostore_key_generate_pair) ? \ 1230 KCF_PROV_NOSTORE_KEY_OPS(pd)->nostore_key_generate_pair( \ 1231 (pd)->pd_prov_handle, session, mech, pub_template, pub_count, \ 1232 priv_template, priv_count, out_pub_template, out_pub_count, \ 1233 out_priv_template, out_priv_count, req) : CRYPTO_NOT_SUPPORTED) 1234 1235 #define KCF_PROV_NOSTORE_KEY_DERIVE(pd, session, mech, base_key, template, \ 1236 count, out_template, out_count, req) ( \ 1237 (KCF_PROV_NOSTORE_KEY_OPS(pd) && \ 1238 KCF_PROV_NOSTORE_KEY_OPS(pd)->nostore_key_derive) ? \ 1239 KCF_PROV_NOSTORE_KEY_OPS(pd)->nostore_key_derive( \ 1240 (pd)->pd_prov_handle, session, mech, base_key, template, count, \ 1241 out_template, out_count, req) : CRYPTO_NOT_SUPPORTED) 1242 1243 /* 1244 * The following routines are exported by the kcf module (/kernel/misc/kcf) 1245 * to the crypto and cryptoadmin modules. 1246 */ 1247 1248 /* Digest/mac/cipher entry points that take a provider descriptor and session */ 1249 extern int crypto_digest_single(crypto_context_t, crypto_data_t *, 1250 crypto_data_t *, crypto_call_req_t *); 1251 1252 extern int crypto_mac_single(crypto_context_t, crypto_data_t *, 1253 crypto_data_t *, crypto_call_req_t *); 1254 1255 extern int crypto_encrypt_single(crypto_context_t, crypto_data_t *, 1256 crypto_data_t *, crypto_call_req_t *); 1257 1258 extern int crypto_decrypt_single(crypto_context_t, crypto_data_t *, 1259 crypto_data_t *, crypto_call_req_t *); 1260 1261 1262 /* Other private digest/mac/cipher entry points not exported through k-API */ 1263 extern int crypto_digest_key_prov(crypto_context_t, crypto_key_t *, 1264 crypto_call_req_t *); 1265 1266 /* Private sign entry points exported by KCF */ 1267 extern int crypto_sign_single(crypto_context_t, crypto_data_t *, 1268 crypto_data_t *, crypto_call_req_t *); 1269 1270 extern int crypto_sign_recover_single(crypto_context_t, crypto_data_t *, 1271 crypto_data_t *, crypto_call_req_t *); 1272 1273 /* Private verify entry points exported by KCF */ 1274 extern int crypto_verify_single(crypto_context_t, crypto_data_t *, 1275 crypto_data_t *, crypto_call_req_t *); 1276 1277 extern int crypto_verify_recover_single(crypto_context_t, crypto_data_t *, 1278 crypto_data_t *, crypto_call_req_t *); 1279 1280 /* Private dual operations entry points exported by KCF */ 1281 extern int crypto_digest_encrypt_update(crypto_context_t, crypto_context_t, 1282 crypto_data_t *, crypto_data_t *, crypto_call_req_t *); 1283 extern int crypto_decrypt_digest_update(crypto_context_t, crypto_context_t, 1284 crypto_data_t *, crypto_data_t *, crypto_call_req_t *); 1285 extern int crypto_sign_encrypt_update(crypto_context_t, crypto_context_t, 1286 crypto_data_t *, crypto_data_t *, crypto_call_req_t *); 1287 extern int crypto_decrypt_verify_update(crypto_context_t, crypto_context_t, 1288 crypto_data_t *, crypto_data_t *, crypto_call_req_t *); 1289 1290 /* Random Number Generation */ 1291 int crypto_seed_random(crypto_provider_handle_t provider, uchar_t *buf, 1292 size_t len, crypto_call_req_t *req); 1293 int crypto_generate_random(crypto_provider_handle_t provider, uchar_t *buf, 1294 size_t len, crypto_call_req_t *req); 1295 1296 /* Provider Management */ 1297 int crypto_get_provider_info(crypto_provider_id_t id, 1298 crypto_provider_info_t **info, crypto_call_req_t *req); 1299 int crypto_get_provider_mechanisms(crypto_minor_t *, crypto_provider_id_t id, 1300 uint_t *count, crypto_mech_name_t **list); 1301 int crypto_init_token(crypto_provider_handle_t provider, char *pin, 1302 size_t pin_len, char *label, crypto_call_req_t *); 1303 int crypto_init_pin(crypto_provider_handle_t provider, char *pin, 1304 size_t pin_len, crypto_call_req_t *req); 1305 int crypto_set_pin(crypto_provider_handle_t provider, char *old_pin, 1306 size_t old_len, char *new_pin, size_t new_len, crypto_call_req_t *req); 1307 void crypto_free_provider_list(crypto_provider_entry_t *list, uint_t count); 1308 void crypto_free_provider_info(crypto_provider_info_t *info); 1309 1310 /* Administrative */ 1311 int crypto_get_dev_list(uint_t *count, crypto_dev_list_entry_t **list); 1312 int crypto_get_soft_list(uint_t *count, char **list, size_t *len); 1313 int crypto_get_dev_info(char *name, uint_t instance, uint_t *count, 1314 crypto_mech_name_t **list); 1315 int crypto_get_soft_info(caddr_t name, uint_t *count, 1316 crypto_mech_name_t **list); 1317 int crypto_load_dev_disabled(char *name, uint_t instance, uint_t count, 1318 crypto_mech_name_t *list); 1319 int crypto_load_soft_disabled(caddr_t name, uint_t count, 1320 crypto_mech_name_t *list); 1321 int crypto_unload_soft_module(caddr_t path); 1322 int crypto_load_soft_config(caddr_t name, uint_t count, 1323 crypto_mech_name_t *list); 1324 int crypto_load_door(uint_t did); 1325 void crypto_free_mech_list(crypto_mech_name_t *list, uint_t count); 1326 void crypto_free_dev_list(crypto_dev_list_entry_t *list, uint_t count); 1327 extern void kcf_activate(); 1328 1329 /* Miscellaneous */ 1330 int crypto_get_mechanism_number(caddr_t name, crypto_mech_type_t *number); 1331 int crypto_get_function_list(crypto_provider_id_t id, 1332 crypto_function_list_t **list, int kmflag); 1333 void crypto_free_function_list(crypto_function_list_t *list); 1334 int crypto_build_permitted_mech_names(kcf_provider_desc_t *, 1335 crypto_mech_name_t **, uint_t *, int); 1336 extern void kcf_init_mech_tabs(void); 1337 extern int kcf_add_mech_provider(short, kcf_provider_desc_t *, 1338 kcf_prov_mech_desc_t **); 1339 extern void kcf_remove_mech_provider(char *, kcf_provider_desc_t *); 1340 extern int kcf_get_mech_entry(crypto_mech_type_t, kcf_mech_entry_t **); 1341 extern kcf_provider_desc_t *kcf_alloc_provider_desc(crypto_provider_info_t *); 1342 extern void kcf_free_provider_desc(kcf_provider_desc_t *); 1343 extern void kcf_soft_config_init(void); 1344 extern int get_sw_provider_for_mech(crypto_mech_name_t, char **); 1345 extern crypto_mech_type_t crypto_mech2id_common(char *, boolean_t); 1346 extern void undo_register_provider(kcf_provider_desc_t *, boolean_t); 1347 extern void redo_register_provider(kcf_provider_desc_t *); 1348 extern void kcf_rnd_init(); 1349 extern boolean_t kcf_rngprov_check(void); 1350 extern int kcf_rnd_get_pseudo_bytes(uint8_t *, size_t); 1351 extern int kcf_rnd_get_bytes(uint8_t *, size_t, boolean_t); 1352 extern int random_add_pseudo_entropy(uint8_t *, size_t, uint_t); 1353 extern void kcf_rnd_chpoll(short, int, short *, struct pollhead **); 1354 extern void kcf_rnd_schedule_timeout(boolean_t); 1355 extern int crypto_uio_data(crypto_data_t *, uchar_t *, int, cmd_type_t, 1356 void *, void (*update)()); 1357 extern int crypto_mblk_data(crypto_data_t *, uchar_t *, int, cmd_type_t, 1358 void *, void (*update)()); 1359 extern int crypto_put_output_data(uchar_t *, crypto_data_t *, int); 1360 extern int crypto_get_input_data(crypto_data_t *, uchar_t **, uchar_t *); 1361 extern int crypto_copy_key_to_ctx(crypto_key_t *, crypto_key_t **, size_t *, 1362 int kmflag); 1363 extern int crypto_digest_data(crypto_data_t *, void *, uchar_t *, 1364 void (*update)(), void (*final)(), uchar_t); 1365 extern int crypto_update_iov(void *, crypto_data_t *, crypto_data_t *, 1366 int (*cipher)(void *, caddr_t, size_t, crypto_data_t *), 1367 void (*copy_block)(uint8_t *, uint64_t *)); 1368 extern int crypto_update_uio(void *, crypto_data_t *, crypto_data_t *, 1369 int (*cipher)(void *, caddr_t, size_t, crypto_data_t *), 1370 void (*copy_block)(uint8_t *, uint64_t *)); 1371 extern int crypto_update_mp(void *, crypto_data_t *, crypto_data_t *, 1372 int (*cipher)(void *, caddr_t, size_t, crypto_data_t *), 1373 void (*copy_block)(uint8_t *, uint64_t *)); 1374 extern int crypto_get_key_attr(crypto_key_t *, crypto_attr_type_t, uchar_t **, 1375 ssize_t *); 1376 1377 /* Access to the provider's table */ 1378 extern void kcf_prov_tab_init(void); 1379 extern int kcf_prov_tab_add_provider(kcf_provider_desc_t *); 1380 extern int kcf_prov_tab_rem_provider(crypto_provider_id_t); 1381 extern kcf_provider_desc_t *kcf_prov_tab_lookup_by_name(char *); 1382 extern kcf_provider_desc_t *kcf_prov_tab_lookup_by_dev(char *, uint_t); 1383 extern int kcf_get_hw_prov_tab(uint_t *, kcf_provider_desc_t ***, int, 1384 char *, uint_t, boolean_t); 1385 extern int kcf_get_slot_list(uint_t *, kcf_provider_desc_t ***, boolean_t); 1386 extern void kcf_free_provider_tab(uint_t, kcf_provider_desc_t **); 1387 extern kcf_provider_desc_t *kcf_prov_tab_lookup(crypto_provider_id_t); 1388 extern int kcf_get_sw_prov(crypto_mech_type_t, kcf_provider_desc_t **, 1389 kcf_mech_entry_t **, boolean_t); 1390 1391 extern kmutex_t prov_tab_mutex; 1392 extern boolean_t kcf_need_provtab_walk; 1393 extern int kcf_get_refcnt(kcf_provider_desc_t *, boolean_t); 1394 1395 /* Access to the policy table */ 1396 extern boolean_t is_mech_disabled(kcf_provider_desc_t *, crypto_mech_name_t); 1397 extern boolean_t is_mech_disabled_byname(crypto_provider_type_t, char *, 1398 uint_t, crypto_mech_name_t); 1399 extern void kcf_policy_tab_init(void); 1400 extern void kcf_policy_free_desc(kcf_policy_desc_t *); 1401 extern void kcf_policy_remove_by_name(char *, uint_t *, crypto_mech_name_t **); 1402 extern void kcf_policy_remove_by_dev(char *, uint_t, uint_t *, 1403 crypto_mech_name_t **); 1404 extern kcf_policy_desc_t *kcf_policy_lookup_by_name(char *); 1405 extern kcf_policy_desc_t *kcf_policy_lookup_by_dev(char *, uint_t); 1406 extern int kcf_policy_load_soft_disabled(char *, uint_t, crypto_mech_name_t *, 1407 uint_t *, crypto_mech_name_t **); 1408 extern int kcf_policy_load_dev_disabled(char *, uint_t, uint_t, 1409 crypto_mech_name_t *, uint_t *, crypto_mech_name_t **); 1410 extern void remove_soft_config(char *); 1411 1412 /* FIPS 140 functions */ 1413 extern int kcf_get_fips140_mode(void); 1414 extern void kcf_fips140_validate(); 1415 extern void kcf_activate(); 1416 1417 #endif /* _KERNEL */ 1418 1419 #ifdef __cplusplus 1420 } 1421 #endif 1422 1423 #endif /* _SYS_CRYPTO_IMPL_H */ 1424