/* * CDDL HEADER START * * The contents of this file are subject to the terms of the * Common Development and Distribution License, Version 1.0 only * (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 2004 Sun Microsystems, Inc. All rights reserved. * Use is subject to license terms. */ #pragma ident "%Z%%M% %I% %E% SMI" #include #include #include #include #include #include "pkcs11Global.h" #include "pkcs11Conf.h" #include "pkcs11Slot.h" #include "metaGlobal.h" static void *listener_waitforslotevent(void *arg); static void *child_waitforslotevent(void *arg); /* * C_GetSlotList is implemented entirely within this framework, * using the slottable that was created during the call to * C_Initialize in pkcs11_slot_mapping(). The plugged in providers * are only queried when tokenPresent is set. * * If metaslot is enabled, the slot that provides keystore support * needs to be hidden. Therefore, even when fastpath is enabled, * we can't go through fastpath because the slot needs to be * hidden. */ CK_RV C_GetSlotList(CK_BBOOL tokenPresent, CK_SLOT_ID_PTR pSlotList, CK_ULONG_PTR pulCount) { CK_RV rv; CK_RV prov_rv; CK_SLOT_ID true_id; CK_SLOT_INFO_PTR pinfo; CK_SLOT_ID count = 0, i; CK_SLOT_ID slot_id; /* slot ID for returning to the application */ /* Check for a fastpath */ if ((purefastpath || policyfastpath) && (!metaslot_enabled)) { return (fast_funcs->C_GetSlotList(tokenPresent, pSlotList, pulCount)); } if (!pkcs11_initialized) { return (CKR_CRYPTOKI_NOT_INITIALIZED); } if (pulCount == NULL) { return (CKR_ARGUMENTS_BAD); } if (tokenPresent) { /* Need to allocate memory for pinfo */ pinfo = malloc(sizeof (CK_SLOT_INFO)); if (pinfo == NULL) { return (CKR_HOST_MEMORY); } } /* * Count the number of valid slots for returning to the application. * If metaslot is enabled, the slot providing keystore support for * metaslot is skipped. Therefore, we can't simply sequentially * assign "i" as the slot id to be returned to the application. * The variable "slot_id" is used for keeping track of the * next slot id to be assigned. */ slot_id = slottable->st_first; for (i = slottable->st_first; i <= slottable->st_last; i++) { if ((pkcs11_is_valid_slot(i) == CKR_OK) && ((!metaslot_enabled) || (i != metaslot_keystore_slotid))) { /* Check if token present is required */ if (tokenPresent) { /* Check with provider */ true_id = TRUEID(i); prov_rv = FUNCLIST(i)-> C_GetSlotInfo(true_id, pinfo); if ((prov_rv != CKR_OK) || !(pinfo->flags & CKF_TOKEN_PRESENT)) { continue; } } /* Fill in the given buffer if it is sufficient */ if (pSlotList && (*pulCount > count)) { pSlotList[count] = slot_id; slot_id++; } count++; } } /* pSlotList set to NULL means caller only wants count */ if ((*pulCount < count) && (pSlotList != NULL)) { rv = CKR_BUFFER_TOO_SMALL; } else { rv = CKR_OK; } *pulCount = count; if (tokenPresent) { free(pinfo); } return (rv); } CK_RV C_GetSlotInfo(CK_SLOT_ID slotID, CK_SLOT_INFO_PTR pInfo) { CK_RV rv; CK_SLOT_ID true_id; CK_SLOT_ID fw_st_id; /* id for accessing framework's slottable */ if (!pkcs11_initialized) { return (CKR_CRYPTOKI_NOT_INITIALIZED); } if (slotID == METASLOT_FRAMEWORK_ID) { /* just need to get metaslot information */ return (meta_GetSlotInfo(METASLOT_SLOTID, pInfo)); } /* Check that slotID is valid */ if (pkcs11_validate_and_convert_slotid(slotID, &fw_st_id) != CKR_OK) { return (CKR_SLOT_ID_INVALID); } /* Check for a fastpath */ if (purefastpath || policyfastpath) { return (fast_funcs->C_GetSlotInfo(fw_st_id, pInfo)); } true_id = TRUEID(fw_st_id); rv = FUNCLIST(fw_st_id)->C_GetSlotInfo(true_id, pInfo); /* Present consistent interface to the application */ if (rv == CKR_FUNCTION_NOT_SUPPORTED) { return (CKR_FUNCTION_FAILED); } return (rv); } CK_RV C_GetTokenInfo(CK_SLOT_ID slotID, CK_TOKEN_INFO_PTR pInfo) { CK_RV rv; CK_SLOT_ID true_id; CK_SLOT_ID fw_st_id; /* id for accessing framework's slottable */ if (!pkcs11_initialized) { return (CKR_CRYPTOKI_NOT_INITIALIZED); } if (slotID == METASLOT_FRAMEWORK_ID) { /* just need to get metaslot information */ return (meta_GetTokenInfo(METASLOT_SLOTID, pInfo)); } /* Check that slotID is valid */ if (pkcs11_validate_and_convert_slotid(slotID, &fw_st_id) != CKR_OK) { return (CKR_SLOT_ID_INVALID); } /* Check for a fastpath */ if (purefastpath || policyfastpath) { return (fast_funcs->C_GetTokenInfo(fw_st_id, pInfo)); } true_id = TRUEID(fw_st_id); rv = FUNCLIST(fw_st_id)->C_GetTokenInfo(true_id, pInfo); /* Present consistent interface to the application */ if (rv == CKR_FUNCTION_NOT_SUPPORTED) { return (CKR_FUNCTION_FAILED); } return (rv); } /* * C_WaitForSlotEvent cannot be a direct pass through to the underlying * provider (except in the case of fastpath), due to the complex nature * of this function. The calling application is asking to be alerted * when an event has occurred on any of the slots in the framework, so * we need to check with all underlying providers and ask for events * on any of their slots. If this is called in blocking mode, we will * need to start threads to wait for slot events for each provider * plugged into the framework. */ CK_RV C_WaitForSlotEvent(CK_FLAGS flags, CK_SLOT_ID_PTR pSlot, CK_VOID_PTR pReserved) { CK_SLOT_ID i, j; uint32_t prov_id; int32_t last_prov_id = -1; CK_RV rv = CKR_OK; CK_SLOT_ID event_slot; pkcs11_slot_t *cur_slot; /* Check for a fastpath */ if (purefastpath || policyfastpath) { return (fast_funcs->C_WaitForSlotEvent(flags, pSlot, pReserved)); } if (!pkcs11_initialized) { return (CKR_CRYPTOKI_NOT_INITIALIZED); } if (pReserved != NULL) { return (CKR_ARGUMENTS_BAD); } /* * Check to see if we're already blocking on another threads * call to this function. If so, behaviour is undefined so * we should return to application. */ (void) pthread_mutex_lock(&slottable->st_mutex); if ((slottable->st_blocking) || (slottable->st_wfse_active)) { (void) pthread_mutex_unlock(&slottable->st_mutex); return (CKR_FUNCTION_FAILED); } else { slottable->st_wfse_active = B_TRUE; (void) pthread_mutex_unlock(&slottable->st_mutex); } /* * Check first to see if any events have been recorded * already on any of the slots, regardless of blocking or * thread status. */ for (i = slottable->st_first; i <= slottable->st_last; i++) { cur_slot = slottable->st_slots[i]; if (cur_slot->sl_wfse_state == WFSE_EVENT) { /* found one, clear event and notify application */ (void) pthread_mutex_lock(&cur_slot->sl_mutex); cur_slot->sl_wfse_state = WFSE_CLEAR; (void) pthread_mutex_unlock(&cur_slot->sl_mutex); *pSlot = i; /* * This event has been captured, clear the function's * active status. Other threads may now enter this * function. */ (void) pthread_mutex_lock(&slottable->st_mutex); slottable->st_wfse_active = B_FALSE; (void) pthread_mutex_unlock(&slottable->st_mutex); return (CKR_OK); } } /* * We could not find any existing event, so let's see * if we can block and start threads to watch for events. */ if (flags & CKF_DONT_BLOCK) { /* * Application does not want us to block so check with * underlying providers to see if any events have occurred. * Not every provider will have implemented this function, * so error codes or CKR_NO_EVENT can be ignored. */ for (i = slottable->st_first; i <= slottable->st_last; i++) { prov_id = slottable->st_slots[i]->sl_prov_id; cur_slot = slottable->st_slots[i]; /* * Only do process once per provider. */ if (prov_id == last_prov_id) { continue; } /* * Check to make sure a child thread is not already * running, due to another of the application's * thread calling this function. */ (void) pthread_mutex_lock(&cur_slot->sl_mutex); if (cur_slot->sl_wfse_state == WFSE_ACTIVE) { (void) pthread_mutex_unlock( &cur_slot->sl_mutex); continue; } cur_slot->sl_wfse_state = WFSE_ACTIVE; /* * Release the hold on the slot's mutex while we * are waiting for this function to complete. */ (void) pthread_mutex_unlock(&cur_slot->sl_mutex); rv = FUNCLIST(i)->C_WaitForSlotEvent(flags, pSlot, pReserved); (void) pthread_mutex_lock(&cur_slot->sl_mutex); cur_slot->sl_wfse_state = WFSE_CLEAR; (void) pthread_mutex_unlock(&cur_slot->sl_mutex); /* See if we've found a slot with an event */ if ((rv == CKR_OK) && (pSlot != NULL)) { /* * Try to map the returned slotid to a slot * allocated by the framework. All slots from * one provider are adjacent in the framework's * slottable, so search for a mapping while * the prov_id field is the same. */ j = i; while (prov_id == slottable->st_slots[j]->sl_prov_id) { /* Find the slot, remap pSlot */ if (*pSlot == TRUEID(j)) { *pSlot = j; (void) pthread_mutex_lock( &slottable->st_mutex); slottable->st_wfse_active = B_FALSE; (void) pthread_mutex_unlock( &slottable->st_mutex); return (CKR_OK); } j++; } } /* * If we reach this part of the loop, this * provider either had no events, did not support * this function, or set pSlot to a value we * could not find in the slots associated with * this provider. Continue checking with remaining * providers. */ last_prov_id = prov_id; } /* No provider had any events */ (void) pthread_mutex_lock(&slottable->st_mutex); slottable->st_wfse_active = B_FALSE; (void) pthread_mutex_unlock(&slottable->st_mutex); return (CKR_NO_EVENT); } else if (!(flags & CKF_DONT_BLOCK) && (pkcs11_cant_create_threads)) { /* * Application has asked us to block, but forbidden * us from creating threads. This is too risky to perform * with underlying providers (we may block indefinitely), * so will return an error in this case. */ (void) pthread_mutex_lock(&slottable->st_mutex); slottable->st_wfse_active = B_FALSE; (void) pthread_mutex_unlock(&slottable->st_mutex); return (CKR_FUNCTION_FAILED); } /* * Grab the st_start_mutex now, which will prevent the listener * thread from signaling on st_start_cond before we're ready to * wait for it. */ (void) pthread_mutex_lock(&slottable->st_start_mutex); /* * Application allows us to create threads and has * asked us to block. Create listener thread to wait for * child threads to return. */ (void) pthread_mutex_lock(&slottable->st_mutex); if (pthread_create(&slottable->st_tid, NULL, listener_waitforslotevent, NULL) != 0) { slottable->st_wfse_active = B_FALSE; (void) pthread_mutex_unlock(&slottable->st_mutex); (void) pthread_mutex_unlock(&slottable->st_start_mutex); return (CKR_FUNCTION_FAILED); } (void) pthread_mutex_unlock(&slottable->st_mutex); /* * Wait for the listening thread to get started before * we spawn child threads. */ (void) pthread_cond_wait(&slottable->st_start_cond, &slottable->st_start_mutex); (void) pthread_mutex_unlock(&slottable->st_start_mutex); /* * Need to hold the mutex on the entire slottable for the * entire setup of the child threads. Otherwise, the first * child thread may complete before a later child thread is * fully started, resulting in an inaccurate value of * st_thr_count and a potential race condition. */ (void) pthread_mutex_lock(&slottable->st_mutex); /* * Create child threads to check with the plugged in providers * to check for events. Keep a count of the current open threads, * so the listener thread knows when there are no more children * to listen for. Also, make sure a thread is not already active * for that provider. */ for (i = slottable->st_first; i <= slottable->st_last; i++) { prov_id = slottable->st_slots[i]->sl_prov_id; cur_slot = slottable->st_slots[i]; /* * Only do process once per provider. */ if (prov_id == last_prov_id) { continue; } /* * Check to make sure a child thread is not already running, * due to another of the application's threads calling * this function. Also, check that the provider has actually * implemented this function. */ (void) pthread_mutex_lock(&cur_slot->sl_mutex); if ((cur_slot->sl_wfse_state == WFSE_ACTIVE) || (cur_slot->sl_no_wfse)) { (void) pthread_mutex_unlock(&cur_slot->sl_mutex); last_prov_id = prov_id; continue; } /* Set slot to active */ cur_slot->sl_wfse_state = WFSE_ACTIVE; /* * set up variable to pass arguments to child threads. * Only need to set up once, as values will remain the * same for each successive call. */ if (cur_slot->sl_wfse_args == NULL) { cur_slot->sl_wfse_args = malloc(sizeof (wfse_args_t)); if (cur_slot->sl_wfse_args == NULL) { (void) pthread_mutex_unlock( &cur_slot->sl_mutex); slottable->st_wfse_active = B_FALSE; (void) pthread_mutex_unlock( &slottable->st_mutex); return (CKR_HOST_MEMORY); } cur_slot->sl_wfse_args->flags = flags; cur_slot->sl_wfse_args->pReserved = pReserved; cur_slot->sl_wfse_args->slotid = i; } /* Create child thread */ if (pthread_create(&cur_slot->sl_tid, NULL, child_waitforslotevent, (void *)cur_slot->sl_wfse_args) != 0) { (void) pthread_mutex_unlock(&cur_slot->sl_mutex); continue; } (void) pthread_mutex_unlock(&cur_slot->sl_mutex); /* * This counter is decremented every time a * child_waitforslotevent() wakes up the listener. */ slottable->st_thr_count++; last_prov_id = prov_id; } /* If no children are listening, kill the listener */ if (slottable->st_thr_count == 0) { (void) pthread_cancel(slottable->st_tid); /* If there are no child threads, no event will occur */ slottable->st_wfse_active = B_FALSE; (void) pthread_mutex_unlock(&slottable->st_mutex); return (CKR_NO_EVENT); } (void) pthread_mutex_unlock(&slottable->st_mutex); /* Wait for listener thread to terminate */ (void) pthread_join(slottable->st_tid, NULL); /* Make sure C_Finalize has not been called */ if (!pkcs11_initialized) { (void) pthread_mutex_lock(&slottable->st_mutex); slottable->st_wfse_active = B_FALSE; (void) pthread_mutex_unlock(&slottable->st_mutex); return (CKR_CRYPTOKI_NOT_INITIALIZED); } /* See if any events actually occurred */ (void) pthread_mutex_lock(&slottable->st_mutex); event_slot = slottable->st_event_slot; (void) pthread_mutex_unlock(&slottable->st_mutex); if (pkcs11_is_valid_slot(event_slot) == CKR_OK) { (void) pthread_mutex_lock(&slottable-> st_slots[event_slot]->sl_mutex); if (slottable->st_slots[event_slot]-> sl_wfse_state == WFSE_EVENT) { /* An event has occurred on this slot */ slottable->st_slots[event_slot]->sl_wfse_state = WFSE_CLEAR; (void) pthread_mutex_unlock(&slottable-> st_slots[event_slot]->sl_mutex); *pSlot = event_slot; (void) pthread_mutex_lock(&slottable->st_mutex); slottable->st_blocking = B_FALSE; slottable->st_wfse_active = B_FALSE; (void) pthread_mutex_unlock(&slottable->st_mutex); return (CKR_OK); } else { (void) pthread_mutex_unlock(&slottable-> st_slots[event_slot]->sl_mutex); } } (void) pthread_mutex_lock(&slottable->st_mutex); slottable->st_blocking = B_FALSE; slottable->st_wfse_active = B_FALSE; (void) pthread_mutex_unlock(&slottable->st_mutex); /* No provider reported any events, or no provider implemented this */ return (CKR_NO_EVENT); } /* * C_GetMechanismList cannot just be a direct pass through to the * underlying provider, because we allow the administrator to * disable certain mechanisms from specific providers. This affects * both pulCount and pMechanismList. Only when the fastpath with * no policy is in effect can we pass through directly to the * underlying provider. * * It is necessary, for policy filtering, to get the actual list * of mechanisms from the underlying provider, even if the calling * application is just requesting a count. It is the only way to * get an accurate count of the number of mechanisms actually available. */ CK_RV C_GetMechanismList(CK_SLOT_ID slotID, CK_MECHANISM_TYPE_PTR pMechanismList, CK_ULONG_PTR pulCount) { CK_RV rv = CKR_OK; CK_ULONG mech_count; CK_ULONG tmpmech_count; CK_MECHANISM_TYPE_PTR pmech_list, tmpmech_list; CK_SLOT_ID true_id; CK_SLOT_ID fw_st_id; /* id for accessing framework's slottable */ CK_FUNCTION_LIST_PTR prov_funcs; CK_ULONG i; if (!pkcs11_initialized) { return (CKR_CRYPTOKI_NOT_INITIALIZED); } if (slotID == METASLOT_FRAMEWORK_ID) { return (meta_GetMechanismList(METASLOT_SLOTID, pMechanismList, pulCount)); } /* Check that slotID is valid */ if (pkcs11_validate_and_convert_slotid(slotID, &fw_st_id) != CKR_OK) { return (CKR_SLOT_ID_INVALID); } /* Check for pure fastpath */ if (purefastpath) { return (fast_funcs->C_GetMechanismList(fw_st_id, pMechanismList, pulCount)); } if (policyfastpath) { true_id = fw_st_id; slotID = fast_slot; prov_funcs = fast_funcs; } else { true_id = TRUEID(fw_st_id); prov_funcs = FUNCLIST(fw_st_id); } mech_count = 0; tmpmech_count = MECHLIST_SIZE; /* * Allocate memory for a mechanism list. We are assuming * that most mechanism lists will be less than MECHLIST_SIZE. * If that is not enough memory, we will try a second time * with more memory allocated. */ pmech_list = malloc(tmpmech_count * sizeof (CK_MECHANISM_TYPE)); if (pmech_list == NULL) { return (CKR_HOST_MEMORY); } /* * Attempt to get the mechanism list. PKCS11 supports * removable media, so the mechanism list of a slot can vary * over the life of the application. */ rv = prov_funcs->C_GetMechanismList(true_id, pmech_list, &tmpmech_count); if (rv == CKR_BUFFER_TOO_SMALL) { /* Need to use more space */ tmpmech_list = pmech_list; pmech_list = realloc (tmpmech_list, tmpmech_count * sizeof (CK_MECHANISM_TYPE)); if (pmech_list == NULL) { free(tmpmech_list); return (CKR_HOST_MEMORY); } /* Try again to get mechanism list. */ rv = prov_funcs->C_GetMechanismList(true_id, pmech_list, &tmpmech_count); } /* * Present consistent face to calling application. * If something strange has happened, or this function * is not supported by this provider, return a count * of zero mechanisms. */ if (rv != CKR_OK) { *pulCount = 0; free(pmech_list); return (CKR_OK); } /* * Process the mechanism list, removing any mechanisms * that are disabled via the framework. Even if the * application is only asking for a count, we must * process the actual mechanisms being offered by this slot. * We could not just subtract our stored count of disabled * mechanisms, since it is not guaranteed that those * mechanisms are actually supported by the slot. */ for (i = 0; i < tmpmech_count; i++) { /* Filter out the disabled mechanisms */ if (pkcs11_is_dismech(fw_st_id, pmech_list[i])) { continue; } /* * Only set pMechanismList if enough memory * is available. If it was set to NULL * originally, this loop will just be counting * mechanims. */ if (pMechanismList && (*pulCount > mech_count)) { pMechanismList[mech_count] = pmech_list[i]; } mech_count++; } /* * Catch the case where pMechanismList was not set to NULL, * yet the buffer was not large enough. If pMechanismList is * set to NULL, this function will simply set pulCount and * return CKR_OK. */ if ((*pulCount < mech_count) && (pMechanismList != NULL)) { *pulCount = mech_count; free(pmech_list); return (CKR_BUFFER_TOO_SMALL); } *pulCount = mech_count; free(pmech_list); return (CKR_OK); } CK_RV C_GetMechanismInfo(CK_SLOT_ID slotID, CK_MECHANISM_TYPE type, CK_MECHANISM_INFO_PTR pInfo) { CK_RV rv; CK_SLOT_ID true_id; CK_SLOT_ID fw_st_id; /* id for accessing framework's slottable */ CK_FUNCTION_LIST_PTR prov_funcs; if (!pkcs11_initialized) { return (CKR_CRYPTOKI_NOT_INITIALIZED); } if (slotID == METASLOT_FRAMEWORK_ID) { /* just need to get metaslot information */ return (meta_GetMechanismInfo(METASLOT_SLOTID, type, pInfo)); } /* Check that slotID is valid */ if (pkcs11_validate_and_convert_slotid(slotID, &fw_st_id) != CKR_OK) { return (CKR_SLOT_ID_INVALID); } /* Check for pure fastpath */ if (purefastpath) { return (fast_funcs->C_GetMechanismInfo(fw_st_id, type, pInfo)); } if (policyfastpath) { true_id = fw_st_id; slotID = fast_slot; prov_funcs = fast_funcs; } else { true_id = TRUEID(fw_st_id); prov_funcs = FUNCLIST(fw_st_id); } /* Make sure this is not a disabled mechanism */ if (pkcs11_is_dismech(fw_st_id, type)) { return (CKR_MECHANISM_INVALID); } rv = prov_funcs->C_GetMechanismInfo(true_id, type, pInfo); /* Present consistent interface to the application */ if (rv == CKR_FUNCTION_NOT_SUPPORTED) { return (CKR_FUNCTION_FAILED); } return (rv); } CK_RV C_InitToken(CK_SLOT_ID slotID, CK_UTF8CHAR_PTR pPin, CK_ULONG ulPinLen, CK_UTF8CHAR_PTR pLabel) { CK_RV rv; CK_SLOT_ID true_id; CK_SLOT_ID fw_st_id; /* id for accessing framework's slottable */ if (!pkcs11_initialized) { return (CKR_CRYPTOKI_NOT_INITIALIZED); } if (slotID == METASLOT_FRAMEWORK_ID) { /* just need to get metaslot information */ return (meta_InitToken(METASLOT_SLOTID, pPin, ulPinLen, pLabel)); } /* Check that slotID is valid */ if (pkcs11_validate_and_convert_slotid(slotID, &fw_st_id) != CKR_OK) { return (CKR_SLOT_ID_INVALID); } /* Check for a fastpath */ if (purefastpath || policyfastpath) { return (fast_funcs->C_InitToken(fw_st_id, pPin, ulPinLen, pLabel)); } true_id = TRUEID(fw_st_id); rv = FUNCLIST(fw_st_id)->C_InitToken(true_id, pPin, ulPinLen, pLabel); /* Present consistent interface to the application */ if (rv == CKR_FUNCTION_NOT_SUPPORTED) { return (CKR_FUNCTION_FAILED); } return (rv); } CK_RV C_InitPIN(CK_SESSION_HANDLE hSession, CK_UTF8CHAR_PTR pPin, CK_ULONG ulPinLen) { CK_RV rv; pkcs11_session_t *sessp; /* Check for a fastpath */ if (purefastpath || policyfastpath) { return (fast_funcs->C_InitPIN(hSession, pPin, ulPinLen)); } if (!pkcs11_initialized) { return (CKR_CRYPTOKI_NOT_INITIALIZED); } /* Obtain the session pointer */ HANDLE2SESSION(hSession, sessp, rv); if (rv != CKR_OK) { return (rv); } /* Initialize the PIN with the provider */ rv = FUNCLIST(sessp->se_slotid)->C_InitPIN(sessp->se_handle, pPin, ulPinLen); /* Present consistent interface to the application */ if (rv == CKR_FUNCTION_NOT_SUPPORTED) { return (CKR_FUNCTION_FAILED); } return (rv); } CK_RV C_SetPIN(CK_SESSION_HANDLE hSession, CK_UTF8CHAR_PTR pOldPin, CK_ULONG ulOldPinLen, CK_UTF8CHAR_PTR pNewPin, CK_ULONG ulNewPinLen) { CK_RV rv; pkcs11_session_t *sessp; /* Check for a fastpath */ if (purefastpath || policyfastpath) { return (fast_funcs->C_SetPIN(hSession, pOldPin, ulOldPinLen, pNewPin, ulNewPinLen)); } if (!pkcs11_initialized) { return (CKR_CRYPTOKI_NOT_INITIALIZED); } /* Obtain the session pointer */ HANDLE2SESSION(hSession, sessp, rv); if (rv != CKR_OK) { return (rv); } /* Set the PIN with the provider */ rv = FUNCLIST(sessp->se_slotid)->C_SetPIN(sessp->se_handle, pOldPin, ulOldPinLen, pNewPin, ulNewPinLen); /* Present consistent interface to the application */ if (rv == CKR_FUNCTION_NOT_SUPPORTED) { return (CKR_FUNCTION_FAILED); } return (rv); } /* * listener_waitforslotevent is spawned by the main C_WaitForSlotEvent() * to listen for events from any of the providers. It also watches the * count of threads, which may go to zero with no recorded events, if * none of the underlying providers have actually implemented this * function. */ /*ARGSUSED*/ static void * listener_waitforslotevent(void *arg) { CK_SLOT_ID eventID; /* Mark slottable in state blocking */ (void) pthread_mutex_lock(&slottable->st_mutex); slottable->st_blocking = B_TRUE; /* alert calling thread that this thread has started */ (void) pthread_mutex_lock(&slottable->st_start_mutex); (void) pthread_cond_signal(&slottable->st_start_cond); (void) pthread_mutex_unlock(&slottable->st_start_mutex); /* wait for an event, or number of threads to reach zero */ for (;;) { /* * Make sure we've really been signaled, and not waking * for another reason. */ while (slottable->st_list_signaled != B_TRUE) { (void) pthread_cond_wait(&slottable->st_wait_cond, &slottable->st_mutex); } slottable->st_list_signaled = B_FALSE; /* See why we were woken up */ if (!pkcs11_initialized) { /* Another thread has called C_Finalize() */ (void) pthread_mutex_unlock(&slottable->st_mutex); return (NULL); } /* A thread has finished, decrement counter */ slottable->st_thr_count--; eventID = slottable->st_event_slot; if (pkcs11_is_valid_slot(eventID) == CKR_OK) { (void) pthread_mutex_lock(&slottable-> st_slots[eventID]->sl_mutex); if (slottable->st_slots[eventID]-> sl_wfse_state == WFSE_EVENT) { (void) pthread_mutex_unlock(&slottable-> st_slots[eventID]->sl_mutex); /* * st_event_slot is set to a valid value, event * flag is set for that slot. The flag will * be cleared by main C_WaitForSlotEvent(). */ (void) pthread_mutex_unlock( &slottable->st_mutex); pthread_exit(0); } else { (void) pthread_mutex_unlock(&slottable-> st_slots[eventID]->sl_mutex); } } if (slottable->st_thr_count == 0) { (void) pthread_mutex_unlock(&slottable->st_mutex); /* No more threads, no events found */ pthread_exit(0); } } /*NOTREACHED*/ return (NULL); } /* * child_waitforslotevent is used as a child thread to contact * underlying provider's C_WaitForSlotEvent(). */ static void * child_waitforslotevent(void *arg) { wfse_args_t *wfse = (wfse_args_t *)arg; CK_SLOT_ID slot; CK_RV rv; uint32_t cur_prov; CK_SLOT_ID i; rv = FUNCLIST(wfse->slotid)->C_WaitForSlotEvent(wfse->flags, &slot, wfse->pReserved); /* * Need to hold the mutex while processing the results, to * keep things synchronized with the listener thread and * the slottable. Otherwise, due to the timing * at which some underlying providers complete, the listener * thread may not actually be blocking on st_wait_cond when * this child signals. Holding the lock a bit longer prevents * this from happening. */ (void) pthread_mutex_lock(&slottable->st_mutex); while (slottable->st_list_signaled == B_TRUE) { /* * We've taken the mutex when the listener should have * control. Release the mutex, thread scheduler should * give control back to the listener. */ (void) pthread_mutex_unlock(&slottable->st_mutex); (void) sleep(1); (void) pthread_mutex_lock(&slottable->st_mutex); } if (rv == CKR_OK) { /* we've had an event, find slot and store it */ cur_prov = slottable->st_slots[wfse->slotid]->sl_prov_id; /* * It is safe to unset active status now, since call to * underlying provider has already terminated, and we * hold the slottable wide mutex (st_mutex). */ (void) pthread_mutex_lock(&slottable-> st_slots[wfse->slotid]->sl_mutex); slottable->st_slots[wfse->slotid]->sl_wfse_state = WFSE_CLEAR; (void) pthread_mutex_unlock(&slottable-> st_slots[wfse->slotid]->sl_mutex); for (i = wfse->slotid; i <= slottable->st_last; i++) { if (cur_prov != slottable->st_slots[i]->sl_prov_id) { break; } if (slot == slottable->st_slots[i]->sl_id) { (void) pthread_mutex_lock(&slottable-> st_slots[i]->sl_mutex); slottable->st_slots[i]-> sl_wfse_state = WFSE_EVENT; (void) pthread_mutex_unlock(&slottable-> st_slots[i]->sl_mutex); slottable->st_event_slot = i; if (slottable->st_blocking) { slottable->st_list_signaled = B_TRUE; (void) pthread_cond_signal(&slottable-> st_wait_cond); } (void) pthread_mutex_unlock( &slottable->st_mutex); pthread_exit(0); } } } (void) pthread_mutex_lock(&slottable-> st_slots[wfse->slotid]->sl_mutex); /* * If the provider told us that it does not support * this function, we should mark it so we do not waste * time later with it. If an error returned, we'll clean * up this thread now and possibly try it again later. */ if (rv == CKR_FUNCTION_NOT_SUPPORTED) { slottable->st_slots[wfse->slotid]->sl_no_wfse = B_TRUE; } /* * It is safe to unset active status now, since call to * underlying provider has already terminated, and we * hold the slottable wide mutex (st_mutex). */ slottable->st_slots[wfse->slotid]->sl_wfse_state = WFSE_CLEAR; (void) pthread_mutex_unlock(&slottable-> st_slots[wfse->slotid]->sl_mutex); if (slottable->st_blocking) { slottable->st_list_signaled = B_TRUE; (void) pthread_cond_signal(&slottable->st_wait_cond); } (void) pthread_mutex_unlock(&slottable->st_mutex); /* Manually exit the thread, since nobody will join to it */ pthread_exit(0); /*NOTREACHED*/ return (NULL); }