/* * CDDL HEADER START * * The contents of this file are subject to the terms of the * Common Development and Distribution License (the "License"). * You may not use this file except in compliance with the License. * * You can obtain a copy of the license at usr/src/OPENSOLARIS.LICENSE * or http://www.opensolaris.org/os/licensing. * See the License for the specific language governing permissions * and limitations under the License. * * When distributing Covered Code, include this CDDL HEADER in each * file and include the License file at usr/src/OPENSOLARIS.LICENSE. * If applicable, add the following below this CDDL HEADER, with the * fields enclosed by brackets "[]" replaced with your own identifying * information: Portions Copyright [yyyy] [name of copyright owner] * * CDDL HEADER END */ /* * Copyright 2008 Sun Microsystems, Inc. All rights reserved. * Use is subject to license terms. */ #include #include #include #include #include #include #include "kernelGlobal.h" #include "kernelObject.h" #include "kernelSession.h" #include "kernelSlot.h" /* * Add an object to the session's object list. * * This function will acquire the lock on the session, and release * that lock after adding the object to the session's object list. */ void kernel_add_object_to_session(kernel_object_t *objp, kernel_session_t *sp) { /* Acquire the session lock. */ (void) pthread_mutex_lock(&sp->session_mutex); /* Insert the new object in front of session's object list. */ if (sp->object_list == NULL) { sp->object_list = objp; objp->next = NULL; objp->prev = NULL; } else { sp->object_list->prev = objp; objp->next = sp->object_list; objp->prev = NULL; sp->object_list = objp; } /* Release the session lock. */ (void) pthread_mutex_unlock(&sp->session_mutex); } /* * Clean up and release the storage allocated to the object. * * The function is called either with the object lock being held * (by caller kernel_delete_object()), or there is no object lock * yet (by kernel_build_XXX_object() during creating an object). */ void kernel_cleanup_object(kernel_object_t *objp) { /* * Free the storage allocated to a secret key object. */ if (objp->class == CKO_SECRET_KEY) { if (OBJ_SEC(objp) != NULL && OBJ_SEC_VALUE(objp) != NULL) { bzero(OBJ_SEC_VALUE(objp), OBJ_SEC_VALUE_LEN(objp)); free(OBJ_SEC_VALUE(objp)); OBJ_SEC_VALUE(objp) = NULL; OBJ_SEC_VALUE_LEN(objp) = 0; } free(OBJ_SEC(objp)); OBJ_SEC(objp) = NULL; } else { kernel_cleanup_object_bigint_attrs(objp); } /* * Free the storage allocated to the extra attribute list. */ kernel_cleanup_extra_attr(objp); } /* * Create a new object. Copy the attributes that can be modified * (in the boolean attribute mask field and extra attribute list) * from the old object to the new object. * * The caller of this function holds the lock on the old object. */ CK_RV kernel_copy_object(kernel_object_t *old_object, kernel_object_t **new_object, boolean_t copy_everything, kernel_session_t *sp) { CK_RV rv = CKR_OK; kernel_object_t *new_objp = NULL; CK_ATTRIBUTE_INFO_PTR attrp; /* Allocate new object. */ new_objp = calloc(1, sizeof (kernel_object_t)); if (new_objp == NULL) return (CKR_HOST_MEMORY); new_objp->class = old_object->class; new_objp->bool_attr_mask = old_object->bool_attr_mask; attrp = old_object->extra_attrlistp; while (attrp) { /* * Copy the attribute_info struct from the old * object to a new attribute_info struct, and add * that new struct to the extra attribute list * of the new object. */ rv = kernel_copy_extra_attr(attrp, new_objp); if (rv != CKR_OK) { kernel_cleanup_extra_attr(new_objp); free(new_objp); return (rv); } attrp = attrp->next; } *new_object = new_objp; if (!copy_everything) { /* done with copying all information that can be modified */ return (CKR_OK); } /* * Copy the rest of the object. * Certain fields that are not appropriate for coping will be * initialized. */ new_objp->key_type = old_object->key_type; new_objp->magic_marker = old_object->magic_marker; new_objp->mechanism = old_object->mechanism; new_objp->session_handle = (CK_SESSION_HANDLE)sp; (void) pthread_mutex_init(&(new_objp->object_mutex), NULL); /* copy key related information */ switch (new_objp->class) { case CKO_PUBLIC_KEY: rv = kernel_copy_public_key_attr(OBJ_PUB(old_object), &(OBJ_PUB(new_objp)), new_objp->key_type); break; case CKO_PRIVATE_KEY: rv = kernel_copy_private_key_attr(OBJ_PRI(old_object), &(OBJ_PRI(new_objp)), new_objp->key_type); break; case CKO_SECRET_KEY: rv = kernel_copy_secret_key_attr(OBJ_SEC(old_object), &(OBJ_SEC(new_objp))); break; default: /* should never be this case */ break; } if (rv != CKR_OK) { /* * don't need to cleanup the memory from failure of copying * any key related stuff. Each individual function for * copying key attr will free the memory if it fails */ kernel_cleanup_extra_attr(new_objp); free(new_objp); } return (rv); } /* * Copy the attributes (in the boolean attribute mask field and * extra attribute list) from the new object back to the original * object. Also, clean up and release all the storage in the extra * attribute list of the original object. * * The caller of this function holds the lock on the old object. */ void kernel_merge_object(kernel_object_t *old_object, kernel_object_t *new_object) { old_object->bool_attr_mask = new_object->bool_attr_mask; kernel_cleanup_extra_attr(old_object); old_object->extra_attrlistp = new_object->extra_attrlistp; } /* * Create a new object struct. If it is a session object, add the object to * the session's object list. If it is a token object, add it to the slot's * token object list. The caller does not hold the slot lock. */ CK_RV kernel_add_object(CK_ATTRIBUTE_PTR pTemplate, CK_ULONG ulCount, CK_ULONG *objecthandle_p, kernel_session_t *sp) { CK_RV rv = CKR_OK; kernel_object_t *new_objp = NULL; kernel_slot_t *pslot; crypto_object_create_t objc; CK_BBOOL is_pri_obj; CK_BBOOL is_token_obj = B_FALSE; int r; new_objp = calloc(1, sizeof (kernel_object_t)); if (new_objp == NULL) { rv = CKR_HOST_MEMORY; goto fail_cleanup; } new_objp->extra_attrlistp = NULL; new_objp->is_lib_obj = B_TRUE; /* * If the HW provider supports object creation, create the object * in the HW provider by calling the CRYPTO_OBJECT_CREATE ioctl. * Otherwise, create the object in the library. */ pslot = slot_table[sp->ses_slotid]; if (pslot->sl_func_list.fl_object_create) { new_objp->is_lib_obj = B_FALSE; objc.oc_session = sp->k_session; objc.oc_count = ulCount; rv = process_object_attributes(pTemplate, ulCount, &objc.oc_attributes, &is_token_obj); if (rv != CKR_OK) { goto fail_cleanup; } /* Cannot create a token object with a READ-ONLY session */ if (is_token_obj && sp->ses_RO) { free_object_attributes(objc.oc_attributes, ulCount); rv = CKR_SESSION_READ_ONLY; goto fail_cleanup; } while ((r = ioctl(kernel_fd, CRYPTO_OBJECT_CREATE, &objc)) < 0) { if (errno != EINTR) break; } if (r < 0) { rv = CKR_FUNCTION_FAILED; } else { rv = crypto2pkcs11_error_number(objc.oc_return_value); } free_object_attributes(objc.oc_attributes, ulCount); if (rv != CKR_OK) { goto fail_cleanup; } /* Get the CKA_PRIVATE value of this object. */ new_objp->k_handle = objc.oc_handle; rv = get_cka_private_value(sp, new_objp->k_handle, &is_pri_obj); if (rv != CKR_OK) { goto fail_cleanup; } /* Set the PRIVATE_BOOL_ON and TOKEN_BOOL_ON attributes */ if (is_pri_obj) new_objp->bool_attr_mask |= PRIVATE_BOOL_ON; else new_objp->bool_attr_mask &= ~PRIVATE_BOOL_ON; if (is_token_obj) new_objp->bool_attr_mask |= TOKEN_BOOL_ON; else new_objp->bool_attr_mask &= ~TOKEN_BOOL_ON; } else { /* * Create the object in the library. * Validate attribute template and fill in the attributes * in the kernel_object_t. */ rv = kernel_build_object(pTemplate, ulCount, new_objp, sp, KERNEL_CREATE_OBJ); if (rv != CKR_OK) { goto fail_cleanup; } } /* Initialize the rest of stuffs in kernel_object_t. */ (void) pthread_mutex_init(&new_objp->object_mutex, NULL); new_objp->magic_marker = KERNELTOKEN_OBJECT_MAGIC; new_objp->session_handle = (CK_SESSION_HANDLE)sp; if (is_token_obj) { /* Add the new object to the slot's token object list. */ pslot = slot_table[sp->ses_slotid]; kernel_add_token_object_to_slot(new_objp, pslot); } else { /* Add the new object to the session's object list. */ kernel_add_object_to_session(new_objp, sp); } /* Type casting the address of an object struct to an object handle. */ *objecthandle_p = (CK_ULONG)new_objp; return (CKR_OK); fail_cleanup: if (new_objp) { /* * If the object is created in the HW provider, the storage * allocated for the ioctl call is always cleaned up after * the call. If the object is created in the library, * the storage allocated inside of this object should * have been cleaned up in the kernel_build_object() * after an error occurred. Therefore, we can safely * free the object. */ free(new_objp); } return (rv); } /* * Remove an object from the session's object list. * * The caller of this function holds the session lock. */ CK_RV kernel_remove_object_from_session(kernel_object_t *objp, kernel_session_t *sp) { kernel_object_t *tmp_objp; boolean_t found = B_FALSE; /* * Remove the object from the session's object list. */ if ((sp == NULL) || (sp->magic_marker != KERNELTOKEN_SESSION_MAGIC)) { return (CKR_SESSION_HANDLE_INVALID); } if ((sp->object_list == NULL) || (objp == NULL) || (objp->magic_marker != KERNELTOKEN_OBJECT_MAGIC)) { return (CKR_OBJECT_HANDLE_INVALID); } tmp_objp = sp->object_list; while (tmp_objp) { if (tmp_objp == objp) { found = B_TRUE; break; } tmp_objp = tmp_objp->next; } if (!found) return (CKR_OBJECT_HANDLE_INVALID); if (sp->object_list == objp) { /* Object is the first one in the list. */ if (objp->next) { sp->object_list = objp->next; objp->next->prev = NULL; } else { /* Object is the only one in the list. */ sp->object_list = NULL; } } else { /* Object is not the first one in the list. */ if (objp->next) { /* Object is in the middle of the list. */ objp->prev->next = objp->next; objp->next->prev = objp->prev; } else { /* Object is the last one in the list. */ objp->prev->next = NULL; } } return (CKR_OK); } static void kernel_delete_object_cleanup(kernel_object_t *objp) { /* Acquire the lock on the object. */ (void) pthread_mutex_lock(&objp->object_mutex); /* * Make sure another thread hasn't freed the object. */ if (objp->magic_marker != KERNELTOKEN_OBJECT_MAGIC) { (void) pthread_mutex_unlock(&objp->object_mutex); return; } /* * The deletion of an object must be blocked when the object * reference count is not zero. This means if any object related * operation starts prior to the delete object operation gets in, * the object deleting thread must wait for the non-deleting * operation to be completed before it can proceed the delete * operation. */ while (objp->obj_refcnt != 0) { /* * We set the OBJECT_REFCNT_WAITING flag before we put * this deleting thread in a wait state, so other non-deleting * operation thread will signal to wake it up only when * the object reference count becomes zero and this flag * is set. */ objp->obj_delete_sync |= OBJECT_REFCNT_WAITING; (void) pthread_cond_wait(&objp->obj_free_cond, &objp->object_mutex); } objp->obj_delete_sync &= ~OBJECT_REFCNT_WAITING; /* Mark object as no longer valid. */ objp->magic_marker = 0; (void) pthread_cond_destroy(&objp->obj_free_cond); } /* * Delete a session object: * - Remove the object from the session's object list. * - Release the storage allocated to the object. * * The boolean argument ses_lock_held is used to indicate that whether * the caller holds the session lock or not. * - When called by kernel_delete_all_objects_in_session() or * kernel_delete_pri_objects_in_slot() -- ses_lock_held = TRUE. * * The boolean argument wrapper_only is used to indicate that whether * the caller only wants to clean up the object wrapper from the library and * needs not to make an ioctl call. * - This argument only applies to the object created in the provider level. * - When called by kernel_cleanup_pri_objects_in_slot(), wrapper_only is TRUE. * - When called by C_DestroyObject(), wrapper_only is FALSE. * - When called by kernel_delete_all_objects_in_session(), the value of * wrapper_only depends on its caller. */ CK_RV kernel_delete_session_object(kernel_session_t *sp, kernel_object_t *objp, boolean_t ses_lock_held, boolean_t wrapper_only) { CK_RV rv = CKR_OK; crypto_object_destroy_t obj_destroy; /* * Check to see if the caller holds the lock on the session. * If not, we need to acquire that lock in order to proceed. */ if (!ses_lock_held) { /* Acquire the session lock. */ (void) pthread_mutex_lock(&sp->session_mutex); } /* Remove the object from the session's object list first. */ rv = kernel_remove_object_from_session(objp, sp); if (!ses_lock_held) { /* * If the session lock is obtained by this function, * then release that lock after removing the object * from session's object list. * We want the releasing of the object storage to * be done without holding the session lock. */ (void) pthread_mutex_unlock(&sp->session_mutex); } if (rv != CKR_OK) return (rv); kernel_delete_object_cleanup(objp); /* Destroy the object. */ if (objp->is_lib_obj) { /* * If this object is created in the library, cleanup the * contents of this object such as free all the storage * allocated for this object. */ kernel_cleanup_object(objp); } else { /* * This object is created in the HW provider. If wrapper_only * is FALSE, make an ioctl call to destroy it in kernel. */ if (!wrapper_only) { obj_destroy.od_session = sp->k_session; obj_destroy.od_handle = objp->k_handle; while (ioctl(kernel_fd, CRYPTO_OBJECT_DESTROY, &obj_destroy) < 0) { if (errno != EINTR) break; } /* * Ignore ioctl return codes for a session object. * If the kernel can not delete a session object, it * is likely caused by the HW provider. There's not * much that can be done. The library will still * cleanup the object wrapper in the library. The HW * provider will destroy all session objects when * the application exits. */ } } /* Reset OBJECT_IS_DELETING flag. */ objp->obj_delete_sync &= ~OBJECT_IS_DELETING; (void) pthread_mutex_unlock(&objp->object_mutex); /* Destroy the object lock */ (void) pthread_mutex_destroy(&objp->object_mutex); /* Free the object itself */ kernel_object_delay_free(objp); return (CKR_OK); } /* * Delete all the objects in a session. The caller holds the lock * on the session. If the wrapper_only argument is TRUE, the caller only * want to clean up object wrappers in the library. */ void kernel_delete_all_objects_in_session(kernel_session_t *sp, boolean_t wrapper_only) { kernel_object_t *objp = sp->object_list; kernel_object_t *objp1; /* Delete all the objects in the session. */ while (objp) { objp1 = objp->next; /* * Delete an session object by calling * kernel_delete_session_object(): * - The 3rd TRUE boolean argument indicates that the caller * holds the session lock. * - The 4th boolean argument indicates whether we only want * clean up object wrappers in the library. */ (void) kernel_delete_session_object(sp, objp, B_TRUE, wrapper_only); objp = objp1; } } static CK_RV add_to_search_result(kernel_object_t *obj, find_context_t *fcontext, CK_ULONG *num_result_alloc) { /* * allocate space for storing results if the currently * allocated space is not enough */ if (*num_result_alloc <= fcontext->num_results) { fcontext->objs_found = realloc(fcontext->objs_found, sizeof (kernel_object_t *) * (*num_result_alloc + BUFSIZ)); if (fcontext->objs_found == NULL) { return (CKR_HOST_MEMORY); } *num_result_alloc += BUFSIZ; } (fcontext->objs_found)[(fcontext->num_results)++] = obj; return (CKR_OK); } static CK_RV search_for_objects(kernel_session_t *sp, CK_ATTRIBUTE_PTR pTemplate, CK_ULONG ulCount, find_context_t *fcontext) { kernel_session_t *session_p; kernel_object_t *obj; CK_OBJECT_CLASS pclasses[6]; /* classes attrs possibly exist */ CK_ULONG num_pclasses; /* number of possible classes */ CK_ULONG num_result_alloc = 0; /* spaces allocated for results */ CK_RV rv = CKR_OK; kernel_slot_t *pslot; if (ulCount > 0) { /* there are some search requirement */ kernel_process_find_attr(pclasses, &num_pclasses, pTemplate, ulCount); } /* Acquire the slot lock */ pslot = slot_table[sp->ses_slotid]; (void) pthread_mutex_lock(&pslot->sl_mutex); /* * Go through all objects in each session. * Acquire individual session lock for the session * we are searching. */ session_p = pslot->sl_sess_list; while (session_p) { (void) pthread_mutex_lock(&session_p->session_mutex); obj = session_p->object_list; while (obj) { (void) pthread_mutex_lock(&obj->object_mutex); if (ulCount > 0) { if (kernel_find_match_attrs(obj, pclasses, num_pclasses, pTemplate, ulCount)) { rv = add_to_search_result( obj, fcontext, &num_result_alloc); } } else { /* no search criteria, just record the object */ rv = add_to_search_result(obj, fcontext, &num_result_alloc); } (void) pthread_mutex_unlock(&obj->object_mutex); if (rv != CKR_OK) { (void) pthread_mutex_unlock( &session_p->session_mutex); goto cleanup; } obj = obj->next; } (void) pthread_mutex_unlock(&session_p->session_mutex); session_p = session_p->next; } cleanup: /* Release the slot lock */ (void) pthread_mutex_unlock(&pslot->sl_mutex); return (rv); } /* * Initialize the context for C_FindObjects() calls */ CK_RV kernel_find_objects_init(kernel_session_t *sp, CK_ATTRIBUTE_PTR pTemplate, CK_ULONG ulCount) { CK_RV rv = CKR_OK; CK_OBJECT_CLASS class; /* for kernel_validate_attr(). Value unused */ find_context_t *fcontext; if (ulCount) { rv = kernel_validate_attr(pTemplate, ulCount, &class); /* Make sure all attributes in template are valid */ if (rv != CKR_OK) { return (rv); } } /* prepare the find context */ fcontext = calloc(1, sizeof (find_context_t)); if (fcontext == NULL) { return (CKR_HOST_MEMORY); } rv = search_for_objects(sp, pTemplate, ulCount, fcontext); if (rv != CKR_OK) { free(fcontext); return (rv); } /* store the find_context in the session */ sp->find_objects.context = (CK_VOID_PTR)fcontext; return (rv); } void kernel_find_objects_final(kernel_session_t *sp) { find_context_t *fcontext; fcontext = sp->find_objects.context; sp->find_objects.context = NULL; sp->find_objects.flags = 0; if (fcontext->objs_found != NULL) { free(fcontext->objs_found); } free(fcontext); } void kernel_find_objects(kernel_session_t *sp, CK_OBJECT_HANDLE *obj_found, CK_ULONG max_obj_requested, CK_ULONG *found_obj_count) { find_context_t *fcontext; CK_ULONG num_obj_found = 0; CK_ULONG i; kernel_object_t *obj; fcontext = sp->find_objects.context; for (i = fcontext->next_result_index; ((num_obj_found < max_obj_requested) && (i < fcontext->num_results)); i++) { obj = fcontext->objs_found[i]; if (obj != NULL) { (void) pthread_mutex_lock(&obj->object_mutex); /* a sanity check to make sure the obj is still valid */ if (obj->magic_marker == KERNELTOKEN_OBJECT_MAGIC) { obj_found[num_obj_found] = (CK_OBJECT_HANDLE)obj; num_obj_found++; } (void) pthread_mutex_unlock(&obj->object_mutex); } } fcontext->next_result_index = i; *found_obj_count = num_obj_found; } /* * Add an token object to the token object list in slot. * * This function will acquire the lock on the slot, and release * that lock after adding the object to the slot's token object list. */ void kernel_add_token_object_to_slot(kernel_object_t *objp, kernel_slot_t *pslot) { /* Acquire the slot lock. */ (void) pthread_mutex_lock(&pslot->sl_mutex); /* Insert the new object in front of slot's token object list. */ if (pslot->sl_tobj_list == NULL) { pslot->sl_tobj_list = objp; objp->next = NULL; objp->prev = NULL; } else { pslot->sl_tobj_list->prev = objp; objp->next = pslot->sl_tobj_list; objp->prev = NULL; pslot->sl_tobj_list = objp; } /* Release the slot lock. */ (void) pthread_mutex_unlock(&pslot->sl_mutex); } /* * Remove an token object from the slot's token object list. * This routine is called by kernel_delete_token_object(). * The caller of this function hold the slot lock. */ void kernel_remove_token_object_from_slot(kernel_slot_t *pslot, kernel_object_t *objp) { if (pslot->sl_tobj_list == objp) { /* Object is the first one in the list */ if (objp->next) { pslot->sl_tobj_list = objp->next; objp->next->prev = NULL; } else { /* Object is the only one in the list. */ pslot->sl_tobj_list = NULL; } } else { /* Object is not the first one in the list. */ if (objp->next) { /* Object is in the middle of the list. */ objp->prev->next = objp->next; objp->next->prev = objp->prev; } else { /* Object is the last one in the list. */ objp->prev->next = NULL; } } } /* * Delete a token object: * - Remove the object from the slot's token object list. * - Release the storage allocated to the object. * * The boolean argument slot_lock_held is used to indicate that whether * the caller holds the slot lock or not. When the caller does not hold * the slot lock, this function will acquire that lock in order to proceed, * and also release that lock before returning to caller. * * The boolean argument wrapper_only is used to indicate that whether * the caller only wants to the object wrapper from library. */ CK_RV kernel_delete_token_object(kernel_slot_t *pslot, kernel_session_t *sp, kernel_object_t *objp, boolean_t slot_lock_held, boolean_t wrapper_only) { CK_RV rv; crypto_object_destroy_t obj_destroy; int r; /* * Check to see if the caller holds the lock on the slot. * If not, we need to acquire that lock in order to proceed. */ if (!slot_lock_held) { (void) pthread_mutex_lock(&pslot->sl_mutex); } /* Remove the object from the slot's token object list first. */ kernel_remove_token_object_from_slot(pslot, objp); /* Release the slot lock if the call doesn't hold the lock. */ if (!slot_lock_held) { (void) pthread_mutex_unlock(&pslot->sl_mutex); } kernel_delete_object_cleanup(objp); if (!wrapper_only) { obj_destroy.od_session = sp->k_session; obj_destroy.od_handle = objp->k_handle; while ((r = ioctl(kernel_fd, CRYPTO_OBJECT_DESTROY, &obj_destroy)) < 0) { if (errno != EINTR) break; } if (r < 0) { rv = CKR_FUNCTION_FAILED; } else { rv = crypto2pkcs11_error_number( obj_destroy.od_return_value); } /* * Could not destroy an object from kernel. Write a warning * in syslog, but we still clean up the object wrapper in * the library. */ if (rv != CKR_OK) { cryptoerror(LOG_ERR, "pkcs11_kernel: Could not " "destroy an object in kernel."); } } (void) pthread_mutex_unlock(&objp->object_mutex); /* Destroy the object lock */ (void) pthread_mutex_destroy(&objp->object_mutex); /* Free the object itself */ kernel_object_delay_free(objp); return (CKR_OK); } /* * Clean up private object wrappers in this slot. The caller holds the slot * lock. */ void kernel_cleanup_pri_objects_in_slot(kernel_slot_t *pslot, kernel_session_t *cur_sp) { kernel_session_t *session_p; kernel_object_t *objp; kernel_object_t *objp1; /* * Delete every private token object from the slot' token object list */ objp = pslot->sl_tobj_list; while (objp) { objp1 = objp->next; /* * The first TRUE boolean argument indicates that the caller * hold the slot lock. The second TRUE boolean argument * indicates that the caller just wants to clean up the object * wrapper from the library only. */ if (objp->bool_attr_mask & PRIVATE_BOOL_ON) { (void) kernel_delete_token_object(pslot, cur_sp, objp, B_TRUE, B_TRUE); } objp = objp1; } /* * Walk through all the sessions in this slot and delete every * private object. */ session_p = pslot->sl_sess_list; while (session_p) { /* Delete all the objects in the session. */ objp = session_p->object_list; while (objp) { objp1 = objp->next; /* * The FALSE boolean argument indicates that the * caller does not hold the session lock. The TRUE * boolean argument indicates that the caller just * want to clean upt the object wrapper from the * library only. */ if (objp->bool_attr_mask & PRIVATE_BOOL_ON) { (void) kernel_delete_session_object(session_p, objp, B_FALSE, B_TRUE); } objp = objp1; } session_p = session_p->next; } } /* * Get the object size in bytes for the objects created in the library. */ CK_RV kernel_get_object_size(kernel_object_t *obj, CK_ULONG_PTR pulSize) { CK_RV rv = CKR_OK; CK_ULONG obj_size; biginteger_t *big; obj_size = sizeof (kernel_object_t); switch (obj->class) { case CKO_PUBLIC_KEY: if (obj->key_type == CKK_RSA) { big = OBJ_PUB_RSA_PUBEXPO(obj); obj_size += big->big_value_len; big = OBJ_PUB_RSA_MOD(obj); obj_size += big->big_value_len; } else if (obj->key_type == CKK_DSA) { big = OBJ_PUB_DSA_PRIME(obj); obj_size += big->big_value_len; big = OBJ_PUB_DSA_SUBPRIME(obj); obj_size += big->big_value_len; big = OBJ_PUB_DSA_BASE(obj); obj_size += big->big_value_len; big = OBJ_PUB_DSA_VALUE(obj); obj_size += big->big_value_len; } else if (obj->key_type == CKK_EC) { big = OBJ_PUB_EC_POINT(obj); obj_size += big->big_value_len; } else { rv = CKR_OBJECT_HANDLE_INVALID; } break; case CKO_PRIVATE_KEY: if (obj->key_type == CKK_RSA) { big = OBJ_PRI_RSA_MOD(obj); obj_size += big->big_value_len; big = OBJ_PRI_RSA_PUBEXPO(obj); /* optional */ if (big != NULL) { obj_size += big->big_value_len; } big = OBJ_PRI_RSA_PRIEXPO(obj); obj_size += big->big_value_len; big = OBJ_PRI_RSA_PRIME1(obj); /* optional */ if (big != NULL) { obj_size += big->big_value_len; } big = OBJ_PRI_RSA_PRIME2(obj); /* optional */ if (big != NULL) { obj_size += big->big_value_len; } big = OBJ_PRI_RSA_EXPO1(obj); /* optional */ if (big != NULL) { obj_size += big->big_value_len; } big = OBJ_PRI_RSA_EXPO2(obj); /* optional */ if (big != NULL) { obj_size += big->big_value_len; } big = OBJ_PRI_RSA_COEF(obj); /* optional */ if (big != NULL) { obj_size += big->big_value_len; } } else if (obj->key_type == CKK_DSA) { big = OBJ_PRI_DSA_PRIME(obj); obj_size += big->big_value_len; big = OBJ_PRI_DSA_SUBPRIME(obj); obj_size += big->big_value_len; big = OBJ_PRI_DSA_BASE(obj); obj_size += big->big_value_len; big = OBJ_PRI_DSA_VALUE(obj); obj_size += big->big_value_len; } else if (obj->key_type == CKK_EC) { big = OBJ_PRI_EC_VALUE(obj); obj_size += big->big_value_len; } else { rv = CKR_OBJECT_HANDLE_INVALID; } break; case CKO_SECRET_KEY: obj_size += OBJ_SEC_VALUE_LEN(obj); break; default: rv = CKR_OBJECT_HANDLE_INVALID; } if (rv == CKR_OK) { *pulSize = obj_size; } return (rv); } /* * This function adds the to-be-freed session object to a linked list. * When the number of objects queued in the linked list reaches the * maximum threshold MAX_OBJ_TO_BE_FREED, it will free the first * object (FIFO) in the list. */ void kernel_object_delay_free(kernel_object_t *objp) { kernel_object_t *tmp; (void) pthread_mutex_lock(&obj_delay_freed.obj_to_be_free_mutex); /* Add the newly deleted object at the end of the list */ objp->next = NULL; if (obj_delay_freed.first == NULL) { obj_delay_freed.last = objp; obj_delay_freed.first = objp; } else { obj_delay_freed.last->next = objp; obj_delay_freed.last = objp; } if (++obj_delay_freed.count >= MAX_OBJ_TO_BE_FREED) { /* * Free the first object in the list only if * the total count reaches maximum threshold. */ obj_delay_freed.count--; tmp = obj_delay_freed.first->next; free(obj_delay_freed.first); obj_delay_freed.first = tmp; } (void) pthread_mutex_unlock(&obj_delay_freed.obj_to_be_free_mutex); }