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/*- * This file is provided under a dual BSD/GPLv2 license. When using or * redistributing this file, you may do so under either license. * * GPL LICENSE SUMMARY * * Copyright(c) 2008 - 2011 Intel Corporation. All rights reserved. * * This program is free software; you can redistribute it and/or modify * it under the terms of version 2 of the GNU General Public License as * published by the Free Software Foundation. * * This program is distributed in the hope that it will be useful, but * WITHOUT ANY WARRANTY; without even the implied warranty of * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU * General Public License for more details. * * You should have received a copy of the GNU General Public License * along with this program; if not, write to the Free Software * Foundation, Inc., 51 Franklin St - Fifth Floor, Boston, MA 02110-1301 USA. * The full GNU General Public License is included in this distribution * in the file called LICENSE.GPL. * * BSD LICENSE * * Copyright(c) 2008 - 2011 Intel Corporation. All rights reserved. * All rights reserved. * * Redistribution and use in source and binary forms, with or without * modification, are permitted provided that the following conditions * are met: * * * Redistributions of source code must retain the above copyright * notice, this list of conditions and the following disclaimer. * * Redistributions in binary form must reproduce the above copyright * notice, this list of conditions and the following disclaimer in * the documentation and/or other materials provided with the * distribution. * * THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS * "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT * LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR * A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT * OWNER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, * SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT * LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, * DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY * THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT * (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE * OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE. */ #include <sys/cdefs.h> __FBSDID("$FreeBSD: release/9.1.0/sys/dev/isci/scil/scif_sas_smp_io_request.c 231689 2012-02-14 15:58:49Z jimharris $"); /** * @file * * @brief This file contains the method implementations for the * SCIF_SAS_SMP_IO_REQUEST object. The contents will implement SMP * specific functionality. */ #include <dev/isci/scil/scif_sas_smp_io_request.h> #include <dev/isci/scil/scif_sas_logger.h> #include <dev/isci/scil/scif_sas_controller.h> #include <dev/isci/scil/sci_controller.h> #include <dev/isci/scil/sci_status.h> #include <dev/isci/scil/scic_io_request.h> #include <dev/isci/scil/scic_user_callback.h> #include <dev/isci/scil/intel_sas.h> /** * @brief This routine is to fill in the space given by core the SMP command * frame. Then it calls core's construction. * * @param[in] fw_io The smp io request to be constructed. * @param[in] smp_command The SMP request filled according to SAS spec. * * @return none */ void scif_sas_smp_request_construct( SCIF_SAS_REQUEST_T * fw_request, SMP_REQUEST_T * smp_command ) { void * command_iu_address = scic_io_request_get_command_iu_address(fw_request->core_object); //copy the smp_command to the address; memcpy( (char*) command_iu_address, smp_command, sizeof(SMP_REQUEST_T) ); scic_io_request_construct_smp(fw_request->core_object); fw_request->protocol_complete_handler = NULL; } /** * @brief This method will perform all of the construction common to all * SMP requests (e.g. filling in the frame type, zero-out memory, * etc.). * * @param[out] smp_request This parameter specifies the SMP request * structure containing the SMP request to be sent to the * SMP target. * @param[in] smp_function This parameter specifies the SMP function to * sent. * @param[in] smp_response_length This parameter specifies the length of * the response (in DWORDs) that will be returned for this * SMP request. * @param[in] smp_request_length This parameter specifies the length of * the request (in DWORDs) that will be sent. */ static void scif_sas_smp_protocol_request_construct( SMP_REQUEST_T * smp_request, U8 smp_function, U8 smp_response_length, U8 smp_request_length ) { memset((char*)smp_request, 0, sizeof(SMP_REQUEST_T)); smp_request->header.smp_frame_type = SMP_FRAME_TYPE_REQUEST; smp_request->header.function = smp_function; smp_request->header.allocated_response_length = smp_response_length; smp_request->header.request_length = smp_request_length; } /** * @brief This method will allocate the internal IO request object and * construct its contents based upon the supplied SMP request. * * @param[in] fw_controller This parameter specifies the controller object * from which to allocate the internal IO request. * @param[in] fw_device This parameter specifies the remote device for * which the internal IO request is destined. * @param[in] smp_request This parameter specifies the SMP request contents * to be sent to the SMP target. * * @return void * The address of built scif sas smp request. */ static void * scif_sas_smp_request_build( SCIF_SAS_CONTROLLER_T * fw_controller, SCIF_SAS_REMOTE_DEVICE_T * fw_device, SMP_REQUEST_T * smp_request, void * external_request_object, void * external_memory ) { if (external_memory != NULL && external_request_object != NULL) { scif_sas_io_request_construct_smp( fw_controller, fw_device, external_memory, (char *)external_memory + sizeof(SCIF_SAS_IO_REQUEST_T), SCI_CONTROLLER_INVALID_IO_TAG, smp_request, external_request_object ); return external_memory; } else { void * internal_io_memory; internal_io_memory = scif_sas_controller_allocate_internal_request(fw_controller); ASSERT(internal_io_memory != NULL); if (internal_io_memory != NULL) { //construct, only when we got valid io memory. scif_sas_internal_io_request_construct_smp( fw_controller, fw_device, internal_io_memory, SCI_CONTROLLER_INVALID_IO_TAG, smp_request ); } else { SCIF_LOG_ERROR(( sci_base_object_get_logger(fw_controller), SCIF_LOG_OBJECT_IO_REQUEST, "scif_sas_smp_request_build, no memory available!\n" )); } return internal_io_memory; } } /** * @brief construct a smp Report Genernal command to the fw_device. * * @param[in] fw_controller The framework controller object. * @param[in] fw_device the framework device that the REPORT GENERAL command * targets to. * * @return void * address to the built scif sas smp request. */ void * scif_sas_smp_request_construct_report_general( SCIF_SAS_CONTROLLER_T * fw_controller, SCIF_SAS_REMOTE_DEVICE_T * fw_device ) { SMP_REQUEST_T smp_report_general; // Build the REPORT GENERAL request. scif_sas_smp_protocol_request_construct( &smp_report_general, SMP_FUNCTION_REPORT_GENERAL, sizeof(SMP_RESPONSE_REPORT_GENERAL_T) / sizeof(U32), 0 ); smp_report_general.request.report_general.crc = 0; SCIF_LOG_INFO(( sci_base_object_get_logger(fw_device), SCIF_LOG_OBJECT_IO_REQUEST | SCIF_LOG_OBJECT_DOMAIN_DISCOVERY, "SMP REPORT GENERAL - Device:0x%x\n", fw_device )); return scif_sas_smp_request_build( fw_controller, fw_device, &smp_report_general, NULL, NULL); } /** * @brief construct a SMP Report Manufacturer Info request to the fw_device. * * @param[in] fw_controller The framework controller object. * @param[in] fw_device the framework device that the REPORT MANUFACTURER * INFO targets to. * * @return void * address to the built scif sas smp request. */ void * scif_sas_smp_request_construct_report_manufacturer_info( SCIF_SAS_CONTROLLER_T * fw_controller, SCIF_SAS_REMOTE_DEVICE_T * fw_device ) { SMP_REQUEST_T smp_report_manufacturer_info; scif_sas_smp_protocol_request_construct( &smp_report_manufacturer_info, SMP_FUNCTION_REPORT_MANUFACTURER_INFORMATION, sizeof(SMP_RESPONSE_REPORT_MANUFACTURER_INFORMATION_T) / sizeof(U32), 0 ); smp_report_manufacturer_info.request.report_general.crc = 0; SCIF_LOG_INFO(( sci_base_object_get_logger(fw_device), SCIF_LOG_OBJECT_IO_REQUEST | SCIF_LOG_OBJECT_DOMAIN_DISCOVERY, "SMP REPORT MANUFACTURER_INFO - Device:0x%x\n", fw_device )); return scif_sas_smp_request_build( fw_controller, fw_device, &smp_report_manufacturer_info, NULL, NULL ); } /** * @brief construct a smp Discover command to the fw_device. * @param[in] fw_controller The framework controller object. * @param[in] fw_device the framework smp device that DISCOVER command targets * to. * @param[in] phy_identifier The phy index the DISCOVER command targets to. * * @return void * address to the built scif sas smp request. */ void * scif_sas_smp_request_construct_discover( SCIF_SAS_CONTROLLER_T * fw_controller, SCIF_SAS_REMOTE_DEVICE_T * fw_device, U8 phy_identifier, void * external_request_object, void * external_memory ) { SMP_REQUEST_T smp_discover; scif_sas_smp_protocol_request_construct( &smp_discover, SMP_FUNCTION_DISCOVER, sizeof(SMP_RESPONSE_DISCOVER_T) / sizeof(U32), sizeof(SMP_REQUEST_PHY_IDENTIFIER_T) / sizeof(U32) ); smp_discover.request.discover.phy_identifier = phy_identifier; SCIF_LOG_INFO(( sci_base_object_get_logger(fw_device), SCIF_LOG_OBJECT_IO_REQUEST | SCIF_LOG_OBJECT_DOMAIN_DISCOVERY, "SMP DISCOVER - Device:0x%x PhyId:0x%x\n", fw_device, phy_identifier )); return scif_sas_smp_request_build( fw_controller, fw_device, &smp_discover, external_request_object, external_memory ); } /** * @brief construct a smp REPORT PHY SATA command to the fw_device. * @param[in] fw_controller The framework controller object. * @param[in] fw_device the framework smp device that DISCOVER command targets * to. * @param[in] phy_identifier The phy index the DISCOVER command targets to. * * @return void * address to the built scif sas smp request. */ void * scif_sas_smp_request_construct_report_phy_sata( SCIF_SAS_CONTROLLER_T * fw_controller, SCIF_SAS_REMOTE_DEVICE_T * fw_device, U8 phy_identifier ) { SMP_REQUEST_T report_phy_sata; scif_sas_smp_protocol_request_construct( &report_phy_sata, SMP_FUNCTION_REPORT_PHY_SATA, sizeof(SMP_RESPONSE_REPORT_PHY_SATA_T) / sizeof(U32), sizeof(SMP_REQUEST_PHY_IDENTIFIER_T) / sizeof(U32) ); report_phy_sata.request.report_phy_sata.phy_identifier = phy_identifier; SCIF_LOG_INFO(( sci_base_object_get_logger(fw_device), SCIF_LOG_OBJECT_IO_REQUEST | SCIF_LOG_OBJECT_DOMAIN_DISCOVERY, "SMP REPORT PHY SATA - Device:0x%x PhyId:0x%x\n", fw_device, phy_identifier )); return scif_sas_smp_request_build( fw_controller, fw_device, &report_phy_sata, NULL, NULL); } /** * @brief construct a smp REPORT PHY SATA command to the fw_device. * @param[in] fw_controller The framework controller object. * @param[in] fw_device the framework smp device that PHY CONTROL command * targets to. * @param[in] phy_identifier The phy index the DISCOVER command targets to. * * @return void * address to the built scif sas smp request. */ void * scif_sas_smp_request_construct_phy_control( SCIF_SAS_CONTROLLER_T * fw_controller, SCIF_SAS_REMOTE_DEVICE_T * fw_device, U8 phy_operation, U8 phy_identifier, void * external_request_object, void * external_memory ) { SMP_REQUEST_T phy_control; scif_sas_smp_protocol_request_construct( &phy_control, SMP_FUNCTION_PHY_CONTROL, 0, sizeof(SMP_REQUEST_PHY_CONTROL_T) / sizeof(U32) ); phy_control.request.phy_control.phy_operation = phy_operation; phy_control.request.phy_control.phy_identifier = phy_identifier; return scif_sas_smp_request_build( fw_controller, fw_device, &phy_control, external_request_object, external_memory ); } /** * @brief construct a smp CONFIG ROUTE INFO command to the fw_device. * * @param[in] fw_controller The framework controller object. * @param[in] fw_device the framework smp device that PHY CONTROL command * targets to. * @param[in] phy_id The phy, whose route entry at route_index is to be configured. * @param[in] route_index The index of a phy's route entry that is to be configured. * @param[in] destination_sas_address A sas address for an route table entry * * @return void * address to the built scif sas smp request. */ void * scif_sas_smp_request_construct_config_route_info( struct SCIF_SAS_CONTROLLER * fw_controller, struct SCIF_SAS_REMOTE_DEVICE * fw_device, U8 phy_id, U16 route_index, SCI_SAS_ADDRESS_T destination_sas_address, BOOL disable_expander_route_entry ) { SMP_REQUEST_T config_route_info; scif_sas_smp_protocol_request_construct( &config_route_info, SMP_FUNCTION_CONFIGURE_ROUTE_INFORMATION, 0, sizeof(SMP_REQUEST_CONFIGURE_ROUTE_INFORMATION_T) / sizeof(U32) ); config_route_info.request.configure_route_information.phy_identifier = phy_id; config_route_info.request.configure_route_information.expander_route_index_high = ((route_index & 0xff00) >> 8); config_route_info.request.configure_route_information.expander_route_index = route_index & 0xff; config_route_info.request.configure_route_information.routed_sas_address[0] = destination_sas_address.high; config_route_info.request.configure_route_information.routed_sas_address[1] = destination_sas_address.low; if (disable_expander_route_entry == TRUE) config_route_info.request.configure_route_information.disable_route_entry = 1; return scif_sas_smp_request_build( fw_controller, fw_device, &config_route_info, NULL, NULL ); } /** * @brief This method retry the internal smp request. * * @param[in] fw_device This parameter specifies the remote device for * which the internal IO request is destined. * @param[in] retry_count This parameter specifies how many times the * old smp request has been retried. * * @return none. */ SCI_STATUS scif_sas_smp_internal_request_retry( SCIF_SAS_REMOTE_DEVICE_T * fw_device ) { SCIF_SAS_CONTROLLER_T * fw_controller; SCIF_SAS_IO_REQUEST_T * new_io; void * new_request_memory = NULL; U8 retry_count = fw_device->protocol_device.smp_device.io_retry_count; SCIF_LOG_TRACE(( sci_base_object_get_logger(fw_device), SCIF_LOG_OBJECT_IO_REQUEST | SCIF_LOG_OBJECT_DOMAIN_DISCOVERY, "scif_sas_smp_internal_request_retry(0x%x, 0x%x) time %d!\n", fw_device, retry_count )); fw_controller = fw_device->domain->controller; switch (fw_device->protocol_device.smp_device.current_smp_request) { case SMP_FUNCTION_REPORT_GENERAL: new_request_memory = scif_sas_smp_request_construct_report_general( fw_controller, fw_device ); break; case SMP_FUNCTION_DISCOVER: //We are retrying an internal io. So we are going to allocate //a new memory from internal io memory pool. new_request_memory = scif_sas_smp_request_construct_discover( fw_controller, fw_device, fw_device->protocol_device.smp_device.current_activity_phy_index, NULL, NULL ); break; case SMP_FUNCTION_REPORT_PHY_SATA: new_request_memory = scif_sas_smp_request_construct_report_phy_sata( fw_controller, fw_device, fw_device->protocol_device.smp_device.current_activity_phy_index ); break; default: //unsupported case, TBD break; } //end of switch if (new_request_memory != NULL) { //set the retry count to new built smp request. new_io = (SCIF_SAS_IO_REQUEST_T *) new_request_memory; new_io->retry_count = ++retry_count; //need to schedule the DPC here. scif_cb_start_internal_io_task_schedule( fw_controller, scif_sas_controller_start_high_priority_io, fw_controller ); return SCI_SUCCESS; } else return SCI_FAILURE_INSUFFICIENT_RESOURCES; } /** * @brief This method retry the external smp request. * * @param[in] fw_device This parameter specifies the remote device for * which the internal IO request is destined. * @param[in] old_internal_io This parameter specifies the old smp request to be * retried. * * @return none. */ SCI_STATUS scif_sas_smp_external_request_retry( SCIF_SAS_IO_REQUEST_T * old_io ) { SCIF_SAS_REMOTE_DEVICE_T * fw_device = old_io->parent.device; SCIF_SAS_CONTROLLER_T * fw_controller; SCIF_SAS_IO_REQUEST_T * new_io; void * new_request_memory = NULL; U8 retry_count = old_io->retry_count; SCIF_LOG_TRACE(( sci_base_object_get_logger(fw_device), SCIF_LOG_OBJECT_IO_REQUEST | SCIF_LOG_OBJECT_DOMAIN_DISCOVERY, "scif_sas_smp_external_request_retry(0x%x) time %d!\n", old_io )); fw_controller = fw_device->domain->controller; // Before we construct new io using the same memory, we need to // remove the IO from the list of outstanding requests on the domain // so that we don't damage the domain's fast list of request. sci_fast_list_remove_element(&old_io->parent.list_element); switch (fw_device->protocol_device.smp_device.current_smp_request) { case SMP_FUNCTION_DISCOVER: //we are retrying an external io, we are going to reuse the //old io's memory. new_request_memory is same as old_io. new_request_memory = scif_sas_smp_request_construct_discover( fw_controller, fw_device, fw_device->protocol_device.smp_device.current_activity_phy_index, (void *)sci_object_get_association(old_io), (void *)old_io ); break; case SMP_FUNCTION_PHY_CONTROL: //Phy Control command always uses external io memory. new_request_memory = scif_sas_smp_request_construct_phy_control( fw_controller, fw_device, PHY_OPERATION_HARD_RESET, fw_device->protocol_device.smp_device.current_activity_phy_index, (void *)sci_object_get_association(old_io), (void *)old_io ); break; default: //unsupported case, TBD return SCI_FAILURE; } //end of switch //set the retry count to new built smp request. new_io = (SCIF_SAS_IO_REQUEST_T *) new_request_memory; new_io->retry_count = ++retry_count; //put into the high priority queue. sci_pool_put(fw_controller->hprq.pool, (POINTER_UINT) new_request_memory); //schedule the DPC to start new io. scif_cb_start_internal_io_task_schedule( fw_controller, scif_sas_controller_start_high_priority_io, fw_controller ); return SCI_SUCCESS; }