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2622 2623 2624 2625 2626 2627 2628 2629 2630 2631 2632 2633 2634 2635 2636 2637 2638 2639 2640 2641 2642 2643 2644 2645 2646 2647 2648 2649 2650 2651 2652 2653 2654 2655 2656 2657 2658 2659 2660 2661 2662 2663 2664 2665 2666 2667 2668 2669 2670 2671 2672 2673 2674 2675 2676 2677 2678 2679 2680 2681 2682 2683 2684 2685 2686 2687 2688 2689 2690 2691 2692 2693 2694 2695 2696 2697 2698 2699 2700 2701 2702 2703 2704 2705 2706 2707 2708 2709 2710 2711 2712 2713 2714 2715 2716 2717 2718 2719 2720 2721 2722 2723 2724 2725 2726 2727 2728 2729 2730 2731 2732 2733 2734 2735 2736 2737 2738 2739 2740 2741 2742 2743 2744 2745 2746 2747 2748 2749 2750 2751 2752 2753 2754 2755 2756 2757 2758 2759 2760 2761 2762 2763 2764 2765 2766 2767 2768 2769 2770 2771 2772 2773 2774 2775 2776 2777 2778 2779 2780 2781 2782 2783 2784 2785 2786 2787 2788 2789 2790 2791 2792 2793 2794 2795 2796 2797 2798 2799 2800 2801 2802 2803 2804 | /* * 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. * * Neither the name of Intel Corporation nor the names of its * contributors may be used to endorse or promote products derived * from this software without specific prior written permission. * * 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 <linux/circ_buf.h> #include <linux/device.h> #include <scsi/sas.h> #include "host.h" #include "isci.h" #include "port.h" #include "probe_roms.h" #include "remote_device.h" #include "request.h" #include "scu_completion_codes.h" #include "scu_event_codes.h" #include "registers.h" #include "scu_remote_node_context.h" #include "scu_task_context.h" #define SCU_CONTEXT_RAM_INIT_STALL_TIME 200 #define smu_max_ports(dcc_value) \ (\ (((dcc_value) & SMU_DEVICE_CONTEXT_CAPACITY_MAX_LP_MASK) \ >> SMU_DEVICE_CONTEXT_CAPACITY_MAX_LP_SHIFT) + 1 \ ) #define smu_max_task_contexts(dcc_value) \ (\ (((dcc_value) & SMU_DEVICE_CONTEXT_CAPACITY_MAX_TC_MASK) \ >> SMU_DEVICE_CONTEXT_CAPACITY_MAX_TC_SHIFT) + 1 \ ) #define smu_max_rncs(dcc_value) \ (\ (((dcc_value) & SMU_DEVICE_CONTEXT_CAPACITY_MAX_RNC_MASK) \ >> SMU_DEVICE_CONTEXT_CAPACITY_MAX_RNC_SHIFT) + 1 \ ) #define SCIC_SDS_CONTROLLER_PHY_START_TIMEOUT 100 /* * The number of milliseconds to wait while a given phy is consuming power * before allowing another set of phys to consume power. Ultimately, this will * be specified by OEM parameter. */ #define SCIC_SDS_CONTROLLER_POWER_CONTROL_INTERVAL 500 /* * NORMALIZE_PUT_POINTER() - * * This macro will normalize the completion queue put pointer so its value can * be used as an array inde */ #define NORMALIZE_PUT_POINTER(x) \ ((x) & SMU_COMPLETION_QUEUE_PUT_POINTER_MASK) /* * NORMALIZE_EVENT_POINTER() - * * This macro will normalize the completion queue event entry so its value can * be used as an index. */ #define NORMALIZE_EVENT_POINTER(x) \ (\ ((x) & SMU_COMPLETION_QUEUE_GET_EVENT_POINTER_MASK) \ >> SMU_COMPLETION_QUEUE_GET_EVENT_POINTER_SHIFT \ ) /* * NORMALIZE_GET_POINTER() - * * This macro will normalize the completion queue get pointer so its value can * be used as an index into an array */ #define NORMALIZE_GET_POINTER(x) \ ((x) & SMU_COMPLETION_QUEUE_GET_POINTER_MASK) /* * NORMALIZE_GET_POINTER_CYCLE_BIT() - * * This macro will normalize the completion queue cycle pointer so it matches * the completion queue cycle bit */ #define NORMALIZE_GET_POINTER_CYCLE_BIT(x) \ ((SMU_CQGR_CYCLE_BIT & (x)) << (31 - SMU_COMPLETION_QUEUE_GET_CYCLE_BIT_SHIFT)) /* * COMPLETION_QUEUE_CYCLE_BIT() - * * This macro will return the cycle bit of the completion queue entry */ #define COMPLETION_QUEUE_CYCLE_BIT(x) ((x) & 0x80000000) /* Init the state machine and call the state entry function (if any) */ void sci_init_sm(struct sci_base_state_machine *sm, const struct sci_base_state *state_table, u32 initial_state) { sci_state_transition_t handler; sm->initial_state_id = initial_state; sm->previous_state_id = initial_state; sm->current_state_id = initial_state; sm->state_table = state_table; handler = sm->state_table[initial_state].enter_state; if (handler) handler(sm); } /* Call the state exit fn, update the current state, call the state entry fn */ void sci_change_state(struct sci_base_state_machine *sm, u32 next_state) { sci_state_transition_t handler; handler = sm->state_table[sm->current_state_id].exit_state; if (handler) handler(sm); sm->previous_state_id = sm->current_state_id; sm->current_state_id = next_state; handler = sm->state_table[sm->current_state_id].enter_state; if (handler) handler(sm); } static bool sci_controller_completion_queue_has_entries(struct isci_host *ihost) { u32 get_value = ihost->completion_queue_get; u32 get_index = get_value & SMU_COMPLETION_QUEUE_GET_POINTER_MASK; if (NORMALIZE_GET_POINTER_CYCLE_BIT(get_value) == COMPLETION_QUEUE_CYCLE_BIT(ihost->completion_queue[get_index])) return true; return false; } static bool sci_controller_isr(struct isci_host *ihost) { if (sci_controller_completion_queue_has_entries(ihost)) return true; /* we have a spurious interrupt it could be that we have already * emptied the completion queue from a previous interrupt * FIXME: really!? */ writel(SMU_ISR_COMPLETION, &ihost->smu_registers->interrupt_status); /* There is a race in the hardware that could cause us not to be * notified of an interrupt completion if we do not take this * step. We will mask then unmask the interrupts so if there is * another interrupt pending the clearing of the interrupt * source we get the next interrupt message. */ spin_lock(&ihost->scic_lock); if (test_bit(IHOST_IRQ_ENABLED, &ihost->flags)) { writel(0xFF000000, &ihost->smu_registers->interrupt_mask); writel(0, &ihost->smu_registers->interrupt_mask); } spin_unlock(&ihost->scic_lock); return false; } irqreturn_t isci_msix_isr(int vec, void *data) { struct isci_host *ihost = data; if (sci_controller_isr(ihost)) tasklet_schedule(&ihost->completion_tasklet); return IRQ_HANDLED; } static bool sci_controller_error_isr(struct isci_host *ihost) { u32 interrupt_status; interrupt_status = readl(&ihost->smu_registers->interrupt_status); interrupt_status &= (SMU_ISR_QUEUE_ERROR | SMU_ISR_QUEUE_SUSPEND); if (interrupt_status != 0) { /* * There is an error interrupt pending so let it through and handle * in the callback */ return true; } /* * There is a race in the hardware that could cause us not to be notified * of an interrupt completion if we do not take this step. We will mask * then unmask the error interrupts so if there was another interrupt * pending we will be notified. * Could we write the value of (SMU_ISR_QUEUE_ERROR | SMU_ISR_QUEUE_SUSPEND)? */ writel(0xff, &ihost->smu_registers->interrupt_mask); writel(0, &ihost->smu_registers->interrupt_mask); return false; } static void sci_controller_task_completion(struct isci_host *ihost, u32 ent) { u32 index = SCU_GET_COMPLETION_INDEX(ent); struct isci_request *ireq = ihost->reqs[index]; /* Make sure that we really want to process this IO request */ if (test_bit(IREQ_ACTIVE, &ireq->flags) && ireq->io_tag != SCI_CONTROLLER_INVALID_IO_TAG && ISCI_TAG_SEQ(ireq->io_tag) == ihost->io_request_sequence[index]) /* Yep this is a valid io request pass it along to the * io request handler */ sci_io_request_tc_completion(ireq, ent); } static void sci_controller_sdma_completion(struct isci_host *ihost, u32 ent) { u32 index; struct isci_request *ireq; struct isci_remote_device *idev; index = SCU_GET_COMPLETION_INDEX(ent); switch (scu_get_command_request_type(ent)) { case SCU_CONTEXT_COMMAND_REQUEST_TYPE_POST_TC: case SCU_CONTEXT_COMMAND_REQUEST_TYPE_DUMP_TC: ireq = ihost->reqs[index]; dev_warn(&ihost->pdev->dev, "%s: %x for io request %p\n", __func__, ent, ireq); /* @todo For a post TC operation we need to fail the IO * request */ break; case SCU_CONTEXT_COMMAND_REQUEST_TYPE_DUMP_RNC: case SCU_CONTEXT_COMMAND_REQUEST_TYPE_OTHER_RNC: case SCU_CONTEXT_COMMAND_REQUEST_TYPE_POST_RNC: idev = ihost->device_table[index]; dev_warn(&ihost->pdev->dev, "%s: %x for device %p\n", __func__, ent, idev); /* @todo For a port RNC operation we need to fail the * device */ break; default: dev_warn(&ihost->pdev->dev, "%s: unknown completion type %x\n", __func__, ent); break; } } static void sci_controller_unsolicited_frame(struct isci_host *ihost, u32 ent) { u32 index; u32 frame_index; struct scu_unsolicited_frame_header *frame_header; struct isci_phy *iphy; struct isci_remote_device *idev; enum sci_status result = SCI_FAILURE; frame_index = SCU_GET_FRAME_INDEX(ent); frame_header = ihost->uf_control.buffers.array[frame_index].header; ihost->uf_control.buffers.array[frame_index].state = UNSOLICITED_FRAME_IN_USE; if (SCU_GET_FRAME_ERROR(ent)) { /* * / @todo If the IAF frame or SIGNATURE FIS frame has an error will * / this cause a problem? We expect the phy initialization will * / fail if there is an error in the frame. */ sci_controller_release_frame(ihost, frame_index); return; } if (frame_header->is_address_frame) { index = SCU_GET_PROTOCOL_ENGINE_INDEX(ent); iphy = &ihost->phys[index]; result = sci_phy_frame_handler(iphy, frame_index); } else { index = SCU_GET_COMPLETION_INDEX(ent); if (index == SCIC_SDS_REMOTE_NODE_CONTEXT_INVALID_INDEX) { /* * This is a signature fis or a frame from a direct attached SATA * device that has not yet been created. In either case forwared * the frame to the PE and let it take care of the frame data. */ index = SCU_GET_PROTOCOL_ENGINE_INDEX(ent); iphy = &ihost->phys[index]; result = sci_phy_frame_handler(iphy, frame_index); } else { if (index < ihost->remote_node_entries) idev = ihost->device_table[index]; else idev = NULL; if (idev != NULL) result = sci_remote_device_frame_handler(idev, frame_index); else sci_controller_release_frame(ihost, frame_index); } } if (result != SCI_SUCCESS) { /* * / @todo Is there any reason to report some additional error message * / when we get this failure notifiction? */ } } static void sci_controller_event_completion(struct isci_host *ihost, u32 ent) { struct isci_remote_device *idev; struct isci_request *ireq; struct isci_phy *iphy; u32 index; index = SCU_GET_COMPLETION_INDEX(ent); switch (scu_get_event_type(ent)) { case SCU_EVENT_TYPE_SMU_COMMAND_ERROR: /* / @todo The driver did something wrong and we need to fix the condtion. */ dev_err(&ihost->pdev->dev, "%s: SCIC Controller 0x%p received SMU command error " "0x%x\n", __func__, ihost, ent); break; case SCU_EVENT_TYPE_SMU_PCQ_ERROR: case SCU_EVENT_TYPE_SMU_ERROR: case SCU_EVENT_TYPE_FATAL_MEMORY_ERROR: /* * / @todo This is a hardware failure and its likely that we want to * / reset the controller. */ dev_err(&ihost->pdev->dev, "%s: SCIC Controller 0x%p received fatal controller " "event 0x%x\n", __func__, ihost, ent); break; case SCU_EVENT_TYPE_TRANSPORT_ERROR: ireq = ihost->reqs[index]; sci_io_request_event_handler(ireq, ent); break; case SCU_EVENT_TYPE_PTX_SCHEDULE_EVENT: switch (scu_get_event_specifier(ent)) { case SCU_EVENT_SPECIFIC_SMP_RESPONSE_NO_PE: case SCU_EVENT_SPECIFIC_TASK_TIMEOUT: ireq = ihost->reqs[index]; if (ireq != NULL) sci_io_request_event_handler(ireq, ent); else dev_warn(&ihost->pdev->dev, "%s: SCIC Controller 0x%p received " "event 0x%x for io request object " "that doesn't exist.\n", __func__, ihost, ent); break; case SCU_EVENT_SPECIFIC_IT_NEXUS_TIMEOUT: idev = ihost->device_table[index]; if (idev != NULL) sci_remote_device_event_handler(idev, ent); else dev_warn(&ihost->pdev->dev, "%s: SCIC Controller 0x%p received " "event 0x%x for remote device object " "that doesn't exist.\n", __func__, ihost, ent); break; } break; case SCU_EVENT_TYPE_BROADCAST_CHANGE: /* * direct the broadcast change event to the phy first and then let * the phy redirect the broadcast change to the port object */ case SCU_EVENT_TYPE_ERR_CNT_EVENT: /* * direct error counter event to the phy object since that is where * we get the event notification. This is a type 4 event. */ case SCU_EVENT_TYPE_OSSP_EVENT: index = SCU_GET_PROTOCOL_ENGINE_INDEX(ent); iphy = &ihost->phys[index]; sci_phy_event_handler(iphy, ent); break; case SCU_EVENT_TYPE_RNC_SUSPEND_TX: case SCU_EVENT_TYPE_RNC_SUSPEND_TX_RX: case SCU_EVENT_TYPE_RNC_OPS_MISC: if (index < ihost->remote_node_entries) { idev = ihost->device_table[index]; if (idev != NULL) sci_remote_device_event_handler(idev, ent); } else dev_err(&ihost->pdev->dev, "%s: SCIC Controller 0x%p received event 0x%x " "for remote device object 0x%0x that doesn't " "exist.\n", __func__, ihost, ent, index); break; default: dev_warn(&ihost->pdev->dev, "%s: SCIC Controller received unknown event code %x\n", __func__, ent); break; } } static void sci_controller_process_completions(struct isci_host *ihost) { u32 completion_count = 0; u32 ent; u32 get_index; u32 get_cycle; u32 event_get; u32 event_cycle; dev_dbg(&ihost->pdev->dev, "%s: completion queue beginning get:0x%08x\n", __func__, ihost->completion_queue_get); /* Get the component parts of the completion queue */ get_index = NORMALIZE_GET_POINTER(ihost->completion_queue_get); get_cycle = SMU_CQGR_CYCLE_BIT & ihost->completion_queue_get; event_get = NORMALIZE_EVENT_POINTER(ihost->completion_queue_get); event_cycle = SMU_CQGR_EVENT_CYCLE_BIT & ihost->completion_queue_get; while ( NORMALIZE_GET_POINTER_CYCLE_BIT(get_cycle) == COMPLETION_QUEUE_CYCLE_BIT(ihost->completion_queue[get_index]) ) { completion_count++; ent = ihost->completion_queue[get_index]; /* increment the get pointer and check for rollover to toggle the cycle bit */ get_cycle ^= ((get_index+1) & SCU_MAX_COMPLETION_QUEUE_ENTRIES) << (SMU_COMPLETION_QUEUE_GET_CYCLE_BIT_SHIFT - SCU_MAX_COMPLETION_QUEUE_SHIFT); get_index = (get_index+1) & (SCU_MAX_COMPLETION_QUEUE_ENTRIES-1); dev_dbg(&ihost->pdev->dev, "%s: completion queue entry:0x%08x\n", __func__, ent); switch (SCU_GET_COMPLETION_TYPE(ent)) { case SCU_COMPLETION_TYPE_TASK: sci_controller_task_completion(ihost, ent); break; case SCU_COMPLETION_TYPE_SDMA: sci_controller_sdma_completion(ihost, ent); break; case SCU_COMPLETION_TYPE_UFI: sci_controller_unsolicited_frame(ihost, ent); break; case SCU_COMPLETION_TYPE_EVENT: sci_controller_event_completion(ihost, ent); break; case SCU_COMPLETION_TYPE_NOTIFY: { event_cycle ^= ((event_get+1) & SCU_MAX_EVENTS) << (SMU_COMPLETION_QUEUE_GET_EVENT_CYCLE_BIT_SHIFT - SCU_MAX_EVENTS_SHIFT); event_get = (event_get+1) & (SCU_MAX_EVENTS-1); sci_controller_event_completion(ihost, ent); break; } default: dev_warn(&ihost->pdev->dev, "%s: SCIC Controller received unknown " "completion type %x\n", __func__, ent); break; } } /* Update the get register if we completed one or more entries */ if (completion_count > 0) { ihost->completion_queue_get = SMU_CQGR_GEN_BIT(ENABLE) | SMU_CQGR_GEN_BIT(EVENT_ENABLE) | event_cycle | SMU_CQGR_GEN_VAL(EVENT_POINTER, event_get) | get_cycle | SMU_CQGR_GEN_VAL(POINTER, get_index); writel(ihost->completion_queue_get, &ihost->smu_registers->completion_queue_get); } dev_dbg(&ihost->pdev->dev, "%s: completion queue ending get:0x%08x\n", __func__, ihost->completion_queue_get); } static void sci_controller_error_handler(struct isci_host *ihost) { u32 interrupt_status; interrupt_status = readl(&ihost->smu_registers->interrupt_status); if ((interrupt_status & SMU_ISR_QUEUE_SUSPEND) && sci_controller_completion_queue_has_entries(ihost)) { sci_controller_process_completions(ihost); writel(SMU_ISR_QUEUE_SUSPEND, &ihost->smu_registers->interrupt_status); } else { dev_err(&ihost->pdev->dev, "%s: status: %#x\n", __func__, interrupt_status); sci_change_state(&ihost->sm, SCIC_FAILED); return; } /* If we dont process any completions I am not sure that we want to do this. * We are in the middle of a hardware fault and should probably be reset. */ writel(0, &ihost->smu_registers->interrupt_mask); } irqreturn_t isci_intx_isr(int vec, void *data) { irqreturn_t ret = IRQ_NONE; struct isci_host *ihost = data; if (sci_controller_isr(ihost)) { writel(SMU_ISR_COMPLETION, &ihost->smu_registers->interrupt_status); tasklet_schedule(&ihost->completion_tasklet); ret = IRQ_HANDLED; } else if (sci_controller_error_isr(ihost)) { spin_lock(&ihost->scic_lock); sci_controller_error_handler(ihost); spin_unlock(&ihost->scic_lock); ret = IRQ_HANDLED; } return ret; } irqreturn_t isci_error_isr(int vec, void *data) { struct isci_host *ihost = data; if (sci_controller_error_isr(ihost)) sci_controller_error_handler(ihost); return IRQ_HANDLED; } /** * isci_host_start_complete() - This function is called by the core library, * through the ISCI Module, to indicate controller start status. * @ihost: This parameter specifies the ISCI host object * @completion_status: This parameter specifies the completion status from the * core library. * */ static void isci_host_start_complete(struct isci_host *ihost, enum sci_status completion_status) { if (completion_status != SCI_SUCCESS) dev_info(&ihost->pdev->dev, "controller start timed out, continuing...\n"); clear_bit(IHOST_START_PENDING, &ihost->flags); wake_up(&ihost->eventq); } int isci_host_scan_finished(struct Scsi_Host *shost, unsigned long time) { struct sas_ha_struct *ha = SHOST_TO_SAS_HA(shost); struct isci_host *ihost = ha->lldd_ha; if (test_bit(IHOST_START_PENDING, &ihost->flags)) return 0; sas_drain_work(ha); return 1; } /** * sci_controller_get_suggested_start_timeout() - This method returns the * suggested sci_controller_start() timeout amount. The user is free to * use any timeout value, but this method provides the suggested minimum * start timeout value. The returned value is based upon empirical * information determined as a result of interoperability testing. * @ihost: the handle to the controller object for which to return the * suggested start timeout. * * This method returns the number of milliseconds for the suggested start * operation timeout. */ static u32 sci_controller_get_suggested_start_timeout(struct isci_host *ihost) { /* Validate the user supplied parameters. */ if (!ihost) return 0; /* * The suggested minimum timeout value for a controller start operation: * * Signature FIS Timeout * + Phy Start Timeout * + Number of Phy Spin Up Intervals * --------------------------------- * Number of milliseconds for the controller start operation. * * NOTE: The number of phy spin up intervals will be equivalent * to the number of phys divided by the number phys allowed * per interval - 1 (once OEM parameters are supported). * Currently we assume only 1 phy per interval. */ return SCIC_SDS_SIGNATURE_FIS_TIMEOUT + SCIC_SDS_CONTROLLER_PHY_START_TIMEOUT + ((SCI_MAX_PHYS - 1) * SCIC_SDS_CONTROLLER_POWER_CONTROL_INTERVAL); } static void sci_controller_enable_interrupts(struct isci_host *ihost) { set_bit(IHOST_IRQ_ENABLED, &ihost->flags); writel(0, &ihost->smu_registers->interrupt_mask); } void sci_controller_disable_interrupts(struct isci_host *ihost) { clear_bit(IHOST_IRQ_ENABLED, &ihost->flags); writel(0xffffffff, &ihost->smu_registers->interrupt_mask); readl(&ihost->smu_registers->interrupt_mask); /* flush */ } static void sci_controller_enable_port_task_scheduler(struct isci_host *ihost) { u32 port_task_scheduler_value; port_task_scheduler_value = readl(&ihost->scu_registers->peg0.ptsg.control); port_task_scheduler_value |= (SCU_PTSGCR_GEN_BIT(ETM_ENABLE) | SCU_PTSGCR_GEN_BIT(PTSG_ENABLE)); writel(port_task_scheduler_value, &ihost->scu_registers->peg0.ptsg.control); } static void sci_controller_assign_task_entries(struct isci_host *ihost) { u32 task_assignment; /* * Assign all the TCs to function 0 * TODO: Do we actually need to read this register to write it back? */ task_assignment = readl(&ihost->smu_registers->task_context_assignment[0]); task_assignment |= (SMU_TCA_GEN_VAL(STARTING, 0)) | (SMU_TCA_GEN_VAL(ENDING, ihost->task_context_entries - 1)) | (SMU_TCA_GEN_BIT(RANGE_CHECK_ENABLE)); writel(task_assignment, &ihost->smu_registers->task_context_assignment[0]); } static void sci_controller_initialize_completion_queue(struct isci_host *ihost) { u32 index; u32 completion_queue_control_value; u32 completion_queue_get_value; u32 completion_queue_put_value; ihost->completion_queue_get = 0; completion_queue_control_value = (SMU_CQC_QUEUE_LIMIT_SET(SCU_MAX_COMPLETION_QUEUE_ENTRIES - 1) | SMU_CQC_EVENT_LIMIT_SET(SCU_MAX_EVENTS - 1)); writel(completion_queue_control_value, &ihost->smu_registers->completion_queue_control); /* Set the completion queue get pointer and enable the queue */ completion_queue_get_value = ( (SMU_CQGR_GEN_VAL(POINTER, 0)) | (SMU_CQGR_GEN_VAL(EVENT_POINTER, 0)) | (SMU_CQGR_GEN_BIT(ENABLE)) | (SMU_CQGR_GEN_BIT(EVENT_ENABLE)) ); writel(completion_queue_get_value, &ihost->smu_registers->completion_queue_get); /* Set the completion queue put pointer */ completion_queue_put_value = ( (SMU_CQPR_GEN_VAL(POINTER, 0)) | (SMU_CQPR_GEN_VAL(EVENT_POINTER, 0)) ); writel(completion_queue_put_value, &ihost->smu_registers->completion_queue_put); /* Initialize the cycle bit of the completion queue entries */ for (index = 0; index < SCU_MAX_COMPLETION_QUEUE_ENTRIES; index++) { /* * If get.cycle_bit != completion_queue.cycle_bit * its not a valid completion queue entry * so at system start all entries are invalid */ ihost->completion_queue[index] = 0x80000000; } } static void sci_controller_initialize_unsolicited_frame_queue(struct isci_host *ihost) { u32 frame_queue_control_value; u32 frame_queue_get_value; u32 frame_queue_put_value; /* Write the queue size */ frame_queue_control_value = SCU_UFQC_GEN_VAL(QUEUE_SIZE, SCU_MAX_UNSOLICITED_FRAMES); writel(frame_queue_control_value, &ihost->scu_registers->sdma.unsolicited_frame_queue_control); /* Setup the get pointer for the unsolicited frame queue */ frame_queue_get_value = ( SCU_UFQGP_GEN_VAL(POINTER, 0) | SCU_UFQGP_GEN_BIT(ENABLE_BIT) ); writel(frame_queue_get_value, &ihost->scu_registers->sdma.unsolicited_frame_get_pointer); /* Setup the put pointer for the unsolicited frame queue */ frame_queue_put_value = SCU_UFQPP_GEN_VAL(POINTER, 0); writel(frame_queue_put_value, &ihost->scu_registers->sdma.unsolicited_frame_put_pointer); } void sci_controller_transition_to_ready(struct isci_host *ihost, enum sci_status status) { if (ihost->sm.current_state_id == SCIC_STARTING) { /* * We move into the ready state, because some of the phys/ports * may be up and operational. */ sci_change_state(&ihost->sm, SCIC_READY); isci_host_start_complete(ihost, status); } } static bool is_phy_starting(struct isci_phy *iphy) { enum sci_phy_states state; state = iphy->sm.current_state_id; switch (state) { case SCI_PHY_STARTING: case SCI_PHY_SUB_INITIAL: case SCI_PHY_SUB_AWAIT_SAS_SPEED_EN: case SCI_PHY_SUB_AWAIT_IAF_UF: case SCI_PHY_SUB_AWAIT_SAS_POWER: case SCI_PHY_SUB_AWAIT_SATA_POWER: case SCI_PHY_SUB_AWAIT_SATA_PHY_EN: case SCI_PHY_SUB_AWAIT_SATA_SPEED_EN: case SCI_PHY_SUB_AWAIT_OSSP_EN: case SCI_PHY_SUB_AWAIT_SIG_FIS_UF: case SCI_PHY_SUB_FINAL: return true; default: return false; } } bool is_controller_start_complete(struct isci_host *ihost) { int i; for (i = 0; i < SCI_MAX_PHYS; i++) { struct isci_phy *iphy = &ihost->phys[i]; u32 state = iphy->sm.current_state_id; /* in apc mode we need to check every phy, in * mpc mode we only need to check phys that have * been configured into a port */ if (is_port_config_apc(ihost)) /* pass */; else if (!phy_get_non_dummy_port(iphy)) continue; /* The controller start operation is complete iff: * - all links have been given an opportunity to start * - have no indication of a connected device * - have an indication of a connected device and it has * finished the link training process. */ if ((iphy->is_in_link_training == false && state == SCI_PHY_INITIAL) || (iphy->is_in_link_training == false && state == SCI_PHY_STOPPED) || (iphy->is_in_link_training == true && is_phy_starting(iphy)) || (ihost->port_agent.phy_ready_mask != ihost->port_agent.phy_configured_mask)) return false; } return true; } /** * sci_controller_start_next_phy - start phy * @ihost: controller * * If all the phys have been started, then attempt to transition the * controller to the READY state and inform the user * (sci_cb_controller_start_complete()). */ static enum sci_status sci_controller_start_next_phy(struct isci_host *ihost) { struct sci_oem_params *oem = &ihost->oem_parameters; struct isci_phy *iphy; enum sci_status status; status = SCI_SUCCESS; if (ihost->phy_startup_timer_pending) return status; if (ihost->next_phy_to_start >= SCI_MAX_PHYS) { if (is_controller_start_complete(ihost)) { sci_controller_transition_to_ready(ihost, SCI_SUCCESS); sci_del_timer(&ihost->phy_timer); ihost->phy_startup_timer_pending = false; } } else { iphy = &ihost->phys[ihost->next_phy_to_start]; if (oem->controller.mode_type == SCIC_PORT_MANUAL_CONFIGURATION_MODE) { if (phy_get_non_dummy_port(iphy) == NULL) { ihost->next_phy_to_start++; /* Caution recursion ahead be forwarned * * The PHY was never added to a PORT in MPC mode * so start the next phy in sequence This phy * will never go link up and will not draw power * the OEM parameters either configured the phy * incorrectly for the PORT or it was never * assigned to a PORT */ return sci_controller_start_next_phy(ihost); } } status = sci_phy_start(iphy); if (status == SCI_SUCCESS) { sci_mod_timer(&ihost->phy_timer, SCIC_SDS_CONTROLLER_PHY_START_TIMEOUT); ihost->phy_startup_timer_pending = true; } else { dev_warn(&ihost->pdev->dev, "%s: Controller stop operation failed " "to stop phy %d because of status " "%d.\n", __func__, ihost->phys[ihost->next_phy_to_start].phy_index, status); } ihost->next_phy_to_start++; } return status; } static void phy_startup_timeout(struct timer_list *t) { struct sci_timer *tmr = from_timer(tmr, t, timer); struct isci_host *ihost = container_of(tmr, typeof(*ihost), phy_timer); unsigned long flags; enum sci_status status; spin_lock_irqsave(&ihost->scic_lock, flags); if (tmr->cancel) goto done; ihost->phy_startup_timer_pending = false; do { status = sci_controller_start_next_phy(ihost); } while (status != SCI_SUCCESS); done: spin_unlock_irqrestore(&ihost->scic_lock, flags); } static u16 isci_tci_active(struct isci_host *ihost) { return CIRC_CNT(ihost->tci_head, ihost->tci_tail, SCI_MAX_IO_REQUESTS); } static enum sci_status sci_controller_start(struct isci_host *ihost, u32 timeout) { enum sci_status result; u16 index; if (ihost->sm.current_state_id != SCIC_INITIALIZED) { dev_warn(&ihost->pdev->dev, "%s invalid state: %d\n", __func__, ihost->sm.current_state_id); return SCI_FAILURE_INVALID_STATE; } /* Build the TCi free pool */ BUILD_BUG_ON(SCI_MAX_IO_REQUESTS > 1 << sizeof(ihost->tci_pool[0]) * 8); ihost->tci_head = 0; ihost->tci_tail = 0; for (index = 0; index < ihost->task_context_entries; index++) isci_tci_free(ihost, index); /* Build the RNi free pool */ sci_remote_node_table_initialize(&ihost->available_remote_nodes, ihost->remote_node_entries); /* * Before anything else lets make sure we will not be * interrupted by the hardware. */ sci_controller_disable_interrupts(ihost); /* Enable the port task scheduler */ sci_controller_enable_port_task_scheduler(ihost); /* Assign all the task entries to ihost physical function */ sci_controller_assign_task_entries(ihost); /* Now initialize the completion queue */ sci_controller_initialize_completion_queue(ihost); /* Initialize the unsolicited frame queue for use */ sci_controller_initialize_unsolicited_frame_queue(ihost); /* Start all of the ports on this controller */ for (index = 0; index < ihost->logical_port_entries; index++) { struct isci_port *iport = &ihost->ports[index]; result = sci_port_start(iport); if (result) return result; } sci_controller_start_next_phy(ihost); sci_mod_timer(&ihost->timer, timeout); sci_change_state(&ihost->sm, SCIC_STARTING); return SCI_SUCCESS; } void isci_host_start(struct Scsi_Host *shost) { struct isci_host *ihost = SHOST_TO_SAS_HA(shost)->lldd_ha; unsigned long tmo = sci_controller_get_suggested_start_timeout(ihost); set_bit(IHOST_START_PENDING, &ihost->flags); spin_lock_irq(&ihost->scic_lock); sci_controller_start(ihost, tmo); sci_controller_enable_interrupts(ihost); spin_unlock_irq(&ihost->scic_lock); } static void isci_host_stop_complete(struct isci_host *ihost) { sci_controller_disable_interrupts(ihost); clear_bit(IHOST_STOP_PENDING, &ihost->flags); wake_up(&ihost->eventq); } static void sci_controller_completion_handler(struct isci_host *ihost) { /* Empty out the completion queue */ if (sci_controller_completion_queue_has_entries(ihost)) sci_controller_process_completions(ihost); /* Clear the interrupt and enable all interrupts again */ writel(SMU_ISR_COMPLETION, &ihost->smu_registers->interrupt_status); /* Could we write the value of SMU_ISR_COMPLETION? */ writel(0xFF000000, &ihost->smu_registers->interrupt_mask); writel(0, &ihost->smu_registers->interrupt_mask); } void ireq_done(struct isci_host *ihost, struct isci_request *ireq, struct sas_task *task) { if (!test_bit(IREQ_ABORT_PATH_ACTIVE, &ireq->flags) && !(task->task_state_flags & SAS_TASK_STATE_ABORTED)) { if (test_bit(IREQ_COMPLETE_IN_TARGET, &ireq->flags)) { /* Normal notification (task_done) */ dev_dbg(&ihost->pdev->dev, "%s: Normal - ireq/task = %p/%p\n", __func__, ireq, task); task->lldd_task = NULL; task->task_done(task); } else { dev_dbg(&ihost->pdev->dev, "%s: Error - ireq/task = %p/%p\n", __func__, ireq, task); if (sas_protocol_ata(task->task_proto)) task->lldd_task = NULL; sas_task_abort(task); } } else task->lldd_task = NULL; if (test_and_clear_bit(IREQ_ABORT_PATH_ACTIVE, &ireq->flags)) wake_up_all(&ihost->eventq); if (!test_bit(IREQ_NO_AUTO_FREE_TAG, &ireq->flags)) isci_free_tag(ihost, ireq->io_tag); } /** * isci_host_completion_routine() - This function is the delayed service * routine that calls the sci core library's completion handler. It's * scheduled as a tasklet from the interrupt service routine when interrupts * in use, or set as the timeout function in polled mode. * @data: This parameter specifies the ISCI host object * */ void isci_host_completion_routine(unsigned long data) { struct isci_host *ihost = (struct isci_host *)data; u16 active; spin_lock_irq(&ihost->scic_lock); sci_controller_completion_handler(ihost); spin_unlock_irq(&ihost->scic_lock); /* * we subtract SCI_MAX_PORTS to account for the number of dummy TCs * issued for hardware issue workaround */ active = isci_tci_active(ihost) - SCI_MAX_PORTS; /* * the coalesence timeout doubles at each encoding step, so * update it based on the ilog2 value of the outstanding requests */ writel(SMU_ICC_GEN_VAL(NUMBER, active) | SMU_ICC_GEN_VAL(TIMER, ISCI_COALESCE_BASE + ilog2(active)), &ihost->smu_registers->interrupt_coalesce_control); } /** * sci_controller_stop() - This method will stop an individual controller * object.This method will invoke the associated user callback upon * completion. The completion callback is called when the following * conditions are met: -# the method return status is SCI_SUCCESS. -# the * controller has been quiesced. This method will ensure that all IO * requests are quiesced, phys are stopped, and all additional operation by * the hardware is halted. * @ihost: the handle to the controller object to stop. * @timeout: This parameter specifies the number of milliseconds in which the * stop operation should complete. * * The controller must be in the STARTED or STOPPED state. Indicate if the * controller stop method succeeded or failed in some way. SCI_SUCCESS if the * stop operation successfully began. SCI_WARNING_ALREADY_IN_STATE if the * controller is already in the STOPPED state. SCI_FAILURE_INVALID_STATE if the * controller is not either in the STARTED or STOPPED states. */ static enum sci_status sci_controller_stop(struct isci_host *ihost, u32 timeout) { if (ihost->sm.current_state_id != SCIC_READY) { dev_warn(&ihost->pdev->dev, "%s invalid state: %d\n", __func__, ihost->sm.current_state_id); return SCI_FAILURE_INVALID_STATE; } sci_mod_timer(&ihost->timer, timeout); sci_change_state(&ihost->sm, SCIC_STOPPING); return SCI_SUCCESS; } /** * sci_controller_reset() - This method will reset the supplied core * controller regardless of the state of said controller. This operation is * considered destructive. In other words, all current operations are wiped * out. No IO completions for outstanding devices occur. Outstanding IO * requests are not aborted or completed at the actual remote device. * @ihost: the handle to the controller object to reset. * * Indicate if the controller reset method succeeded or failed in some way. * SCI_SUCCESS if the reset operation successfully started. SCI_FATAL_ERROR if * the controller reset operation is unable to complete. */ static enum sci_status sci_controller_reset(struct isci_host *ihost) { switch (ihost->sm.current_state_id) { case SCIC_RESET: case SCIC_READY: case SCIC_STOPPING: case SCIC_FAILED: /* * The reset operation is not a graceful cleanup, just * perform the state transition. */ sci_change_state(&ihost->sm, SCIC_RESETTING); return SCI_SUCCESS; default: dev_warn(&ihost->pdev->dev, "%s invalid state: %d\n", __func__, ihost->sm.current_state_id); return SCI_FAILURE_INVALID_STATE; } } static enum sci_status sci_controller_stop_phys(struct isci_host *ihost) { u32 index; enum sci_status status; enum sci_status phy_status; status = SCI_SUCCESS; for (index = 0; index < SCI_MAX_PHYS; index++) { phy_status = sci_phy_stop(&ihost->phys[index]); if (phy_status != SCI_SUCCESS && phy_status != SCI_FAILURE_INVALID_STATE) { status = SCI_FAILURE; dev_warn(&ihost->pdev->dev, "%s: Controller stop operation failed to stop " "phy %d because of status %d.\n", __func__, ihost->phys[index].phy_index, phy_status); } } return status; } /** * isci_host_deinit - shutdown frame reception and dma * @ihost: host to take down * * This is called in either the driver shutdown or the suspend path. In * the shutdown case libsas went through port teardown and normal device * removal (i.e. physical links stayed up to service scsi_device removal * commands). In the suspend case we disable the hardware without * notifying libsas of the link down events since we want libsas to * remember the domain across the suspend/resume cycle */ void isci_host_deinit(struct isci_host *ihost) { int i; /* disable output data selects */ for (i = 0; i < isci_gpio_count(ihost); i++) writel(SGPIO_HW_CONTROL, &ihost->scu_registers->peg0.sgpio.output_data_select[i]); set_bit(IHOST_STOP_PENDING, &ihost->flags); spin_lock_irq(&ihost->scic_lock); sci_controller_stop(ihost, SCIC_CONTROLLER_STOP_TIMEOUT); spin_unlock_irq(&ihost->scic_lock); wait_for_stop(ihost); /* phy stop is after controller stop to allow port and device to * go idle before shutting down the phys, but the expectation is * that i/o has been shut off well before we reach this * function. */ sci_controller_stop_phys(ihost); /* disable sgpio: where the above wait should give time for the * enclosure to sample the gpios going inactive */ writel(0, &ihost->scu_registers->peg0.sgpio.interface_control); spin_lock_irq(&ihost->scic_lock); sci_controller_reset(ihost); spin_unlock_irq(&ihost->scic_lock); /* Cancel any/all outstanding port timers */ for (i = 0; i < ihost->logical_port_entries; i++) { struct isci_port *iport = &ihost->ports[i]; del_timer_sync(&iport->timer.timer); } /* Cancel any/all outstanding phy timers */ for (i = 0; i < SCI_MAX_PHYS; i++) { struct isci_phy *iphy = &ihost->phys[i]; del_timer_sync(&iphy->sata_timer.timer); } del_timer_sync(&ihost->port_agent.timer.timer); del_timer_sync(&ihost->power_control.timer.timer); del_timer_sync(&ihost->timer.timer); del_timer_sync(&ihost->phy_timer.timer); } static void __iomem *scu_base(struct isci_host *isci_host) { struct pci_dev *pdev = isci_host->pdev; int id = isci_host->id; return pcim_iomap_table(pdev)[SCI_SCU_BAR * 2] + SCI_SCU_BAR_SIZE * id; } static void __iomem *smu_base(struct isci_host *isci_host) { struct pci_dev *pdev = isci_host->pdev; int id = isci_host->id; return pcim_iomap_table(pdev)[SCI_SMU_BAR * 2] + SCI_SMU_BAR_SIZE * id; } static void sci_controller_initial_state_enter(struct sci_base_state_machine *sm) { struct isci_host *ihost = container_of(sm, typeof(*ihost), sm); sci_change_state(&ihost->sm, SCIC_RESET); } static inline void sci_controller_starting_state_exit(struct sci_base_state_machine *sm) { struct isci_host *ihost = container_of(sm, typeof(*ihost), sm); sci_del_timer(&ihost->timer); } #define INTERRUPT_COALESCE_TIMEOUT_BASE_RANGE_LOWER_BOUND_NS 853 #define INTERRUPT_COALESCE_TIMEOUT_BASE_RANGE_UPPER_BOUND_NS 1280 #define INTERRUPT_COALESCE_TIMEOUT_MAX_US 2700000 #define INTERRUPT_COALESCE_NUMBER_MAX 256 #define INTERRUPT_COALESCE_TIMEOUT_ENCODE_MIN 7 #define INTERRUPT_COALESCE_TIMEOUT_ENCODE_MAX 28 /** * sci_controller_set_interrupt_coalescence() - This method allows the user to * configure the interrupt coalescence. * @ihost: This parameter represents the handle to the controller object * for which its interrupt coalesce register is overridden. * @coalesce_number: Used to control the number of entries in the Completion * Queue before an interrupt is generated. If the number of entries exceed * this number, an interrupt will be generated. The valid range of the input * is [0, 256]. A setting of 0 results in coalescing being disabled. * @coalesce_timeout: Timeout value in microseconds. The valid range of the * input is [0, 2700000] . A setting of 0 is allowed and results in no * interrupt coalescing timeout. * * Indicate if the user successfully set the interrupt coalesce parameters. * SCI_SUCCESS The user successfully updated the interrutp coalescence. * SCI_FAILURE_INVALID_PARAMETER_VALUE The user input value is out of range. */ static enum sci_status sci_controller_set_interrupt_coalescence(struct isci_host *ihost, u32 coalesce_number, u32 coalesce_timeout) { u8 timeout_encode = 0; u32 min = 0; u32 max = 0; /* Check if the input parameters fall in the range. */ if (coalesce_number > INTERRUPT_COALESCE_NUMBER_MAX) return SCI_FAILURE_INVALID_PARAMETER_VALUE; /* * Defined encoding for interrupt coalescing timeout: * Value Min Max Units * ----- --- --- ----- * 0 - - Disabled * 1 13.3 20.0 ns * 2 26.7 40.0 * 3 53.3 80.0 * 4 106.7 160.0 * 5 213.3 320.0 * 6 426.7 640.0 * 7 853.3 1280.0 * 8 1.7 2.6 us * 9 3.4 5.1 * 10 6.8 10.2 * 11 13.7 20.5 * 12 27.3 41.0 * 13 54.6 81.9 * 14 109.2 163.8 * 15 218.5 327.7 * 16 436.9 655.4 * 17 873.8 1310.7 * 18 1.7 2.6 ms * 19 3.5 5.2 * 20 7.0 10.5 * 21 14.0 21.0 * 22 28.0 41.9 * 23 55.9 83.9 * 24 111.8 167.8 * 25 223.7 335.5 * 26 447.4 671.1 * 27 894.8 1342.2 * 28 1.8 2.7 s * Others Undefined */ /* * Use the table above to decide the encode of interrupt coalescing timeout * value for register writing. */ if (coalesce_timeout == 0) timeout_encode = 0; else{ /* make the timeout value in unit of (10 ns). */ coalesce_timeout = coalesce_timeout * 100; min = INTERRUPT_COALESCE_TIMEOUT_BASE_RANGE_LOWER_BOUND_NS / 10; max = INTERRUPT_COALESCE_TIMEOUT_BASE_RANGE_UPPER_BOUND_NS / 10; /* get the encode of timeout for register writing. */ for (timeout_encode = INTERRUPT_COALESCE_TIMEOUT_ENCODE_MIN; timeout_encode <= INTERRUPT_COALESCE_TIMEOUT_ENCODE_MAX; timeout_encode++) { if (min <= coalesce_timeout && max > coalesce_timeout) break; else if (coalesce_timeout >= max && coalesce_timeout < min * 2 && coalesce_timeout <= INTERRUPT_COALESCE_TIMEOUT_MAX_US * 100) { if ((coalesce_timeout - max) < (2 * min - coalesce_timeout)) break; else{ timeout_encode++; break; } } else { max = max * 2; min = min * 2; } } if (timeout_encode == INTERRUPT_COALESCE_TIMEOUT_ENCODE_MAX + 1) /* the value is out of range. */ return SCI_FAILURE_INVALID_PARAMETER_VALUE; } writel(SMU_ICC_GEN_VAL(NUMBER, coalesce_number) | SMU_ICC_GEN_VAL(TIMER, timeout_encode), &ihost->smu_registers->interrupt_coalesce_control); ihost->interrupt_coalesce_number = (u16)coalesce_number; ihost->interrupt_coalesce_timeout = coalesce_timeout / 100; return SCI_SUCCESS; } static void sci_controller_ready_state_enter(struct sci_base_state_machine *sm) { struct isci_host *ihost = container_of(sm, typeof(*ihost), sm); u32 val; /* enable clock gating for power control of the scu unit */ val = readl(&ihost->smu_registers->clock_gating_control); val &= ~(SMU_CGUCR_GEN_BIT(REGCLK_ENABLE) | SMU_CGUCR_GEN_BIT(TXCLK_ENABLE) | SMU_CGUCR_GEN_BIT(XCLK_ENABLE)); val |= SMU_CGUCR_GEN_BIT(IDLE_ENABLE); writel(val, &ihost->smu_registers->clock_gating_control); /* set the default interrupt coalescence number and timeout value. */ sci_controller_set_interrupt_coalescence(ihost, 0, 0); } static void sci_controller_ready_state_exit(struct sci_base_state_machine *sm) { struct isci_host *ihost = container_of(sm, typeof(*ihost), sm); /* disable interrupt coalescence. */ sci_controller_set_interrupt_coalescence(ihost, 0, 0); } static enum sci_status sci_controller_stop_ports(struct isci_host *ihost) { u32 index; enum sci_status port_status; enum sci_status status = SCI_SUCCESS; for (index = 0; index < ihost->logical_port_entries; index++) { struct isci_port *iport = &ihost->ports[index]; port_status = sci_port_stop(iport); if ((port_status != SCI_SUCCESS) && (port_status != SCI_FAILURE_INVALID_STATE)) { status = SCI_FAILURE; dev_warn(&ihost->pdev->dev, "%s: Controller stop operation failed to " "stop port %d because of status %d.\n", __func__, iport->logical_port_index, port_status); } } return status; } static enum sci_status sci_controller_stop_devices(struct isci_host *ihost) { u32 index; enum sci_status status; enum sci_status device_status; status = SCI_SUCCESS; for (index = 0; index < ihost->remote_node_entries; index++) { if (ihost->device_table[index] != NULL) { /* / @todo What timeout value do we want to provide to this request? */ device_status = sci_remote_device_stop(ihost->device_table[index], 0); if ((device_status != SCI_SUCCESS) && (device_status != SCI_FAILURE_INVALID_STATE)) { dev_warn(&ihost->pdev->dev, "%s: Controller stop operation failed " "to stop device 0x%p because of " "status %d.\n", __func__, ihost->device_table[index], device_status); } } } return status; } static void sci_controller_stopping_state_enter(struct sci_base_state_machine *sm) { struct isci_host *ihost = container_of(sm, typeof(*ihost), sm); sci_controller_stop_devices(ihost); sci_controller_stop_ports(ihost); if (!sci_controller_has_remote_devices_stopping(ihost)) isci_host_stop_complete(ihost); } static void sci_controller_stopping_state_exit(struct sci_base_state_machine *sm) { struct isci_host *ihost = container_of(sm, typeof(*ihost), sm); sci_del_timer(&ihost->timer); } static void sci_controller_reset_hardware(struct isci_host *ihost) { /* Disable interrupts so we dont take any spurious interrupts */ sci_controller_disable_interrupts(ihost); /* Reset the SCU */ writel(0xFFFFFFFF, &ihost->smu_registers->soft_reset_control); /* Delay for 1ms to before clearing the CQP and UFQPR. */ udelay(1000); /* The write to the CQGR clears the CQP */ writel(0x00000000, &ihost->smu_registers->completion_queue_get); /* The write to the UFQGP clears the UFQPR */ writel(0, &ihost->scu_registers->sdma.unsolicited_frame_get_pointer); /* clear all interrupts */ writel(~SMU_INTERRUPT_STATUS_RESERVED_MASK, &ihost->smu_registers->interrupt_status); } static void sci_controller_resetting_state_enter(struct sci_base_state_machine *sm) { struct isci_host *ihost = container_of(sm, typeof(*ihost), sm); sci_controller_reset_hardware(ihost); sci_change_state(&ihost->sm, SCIC_RESET); } static const struct sci_base_state sci_controller_state_table[] = { [SCIC_INITIAL] = { .enter_state = sci_controller_initial_state_enter, }, [SCIC_RESET] = {}, [SCIC_INITIALIZING] = {}, [SCIC_INITIALIZED] = {}, [SCIC_STARTING] = { .exit_state = sci_controller_starting_state_exit, }, [SCIC_READY] = { .enter_state = sci_controller_ready_state_enter, .exit_state = sci_controller_ready_state_exit, }, [SCIC_RESETTING] = { .enter_state = sci_controller_resetting_state_enter, }, [SCIC_STOPPING] = { .enter_state = sci_controller_stopping_state_enter, .exit_state = sci_controller_stopping_state_exit, }, [SCIC_FAILED] = {} }; static void controller_timeout(struct timer_list *t) { struct sci_timer *tmr = from_timer(tmr, t, timer); struct isci_host *ihost = container_of(tmr, typeof(*ihost), timer); struct sci_base_state_machine *sm = &ihost->sm; unsigned long flags; spin_lock_irqsave(&ihost->scic_lock, flags); if (tmr->cancel) goto done; if (sm->current_state_id == SCIC_STARTING) sci_controller_transition_to_ready(ihost, SCI_FAILURE_TIMEOUT); else if (sm->current_state_id == SCIC_STOPPING) { sci_change_state(sm, SCIC_FAILED); isci_host_stop_complete(ihost); } else /* / @todo Now what do we want to do in this case? */ dev_err(&ihost->pdev->dev, "%s: Controller timer fired when controller was not " "in a state being timed.\n", __func__); done: spin_unlock_irqrestore(&ihost->scic_lock, flags); } static enum sci_status sci_controller_construct(struct isci_host *ihost, void __iomem *scu_base, void __iomem *smu_base) { u8 i; sci_init_sm(&ihost->sm, sci_controller_state_table, SCIC_INITIAL); ihost->scu_registers = scu_base; ihost->smu_registers = smu_base; sci_port_configuration_agent_construct(&ihost->port_agent); /* Construct the ports for this controller */ for (i = 0; i < SCI_MAX_PORTS; i++) sci_port_construct(&ihost->ports[i], i, ihost); sci_port_construct(&ihost->ports[i], SCIC_SDS_DUMMY_PORT, ihost); /* Construct the phys for this controller */ for (i = 0; i < SCI_MAX_PHYS; i++) { /* Add all the PHYs to the dummy port */ sci_phy_construct(&ihost->phys[i], &ihost->ports[SCI_MAX_PORTS], i); } ihost->invalid_phy_mask = 0; sci_init_timer(&ihost->timer, controller_timeout); return sci_controller_reset(ihost); } int sci_oem_parameters_validate(struct sci_oem_params *oem, u8 version) { int i; for (i = 0; i < SCI_MAX_PORTS; i++) if (oem->ports[i].phy_mask > SCIC_SDS_PARM_PHY_MASK_MAX) return -EINVAL; for (i = 0; i < SCI_MAX_PHYS; i++) if (oem->phys[i].sas_address.high == 0 && oem->phys[i].sas_address.low == 0) return -EINVAL; if (oem->controller.mode_type == SCIC_PORT_AUTOMATIC_CONFIGURATION_MODE) { for (i = 0; i < SCI_MAX_PHYS; i++) if (oem->ports[i].phy_mask != 0) return -EINVAL; } else if (oem->controller.mode_type == SCIC_PORT_MANUAL_CONFIGURATION_MODE) { u8 phy_mask = 0; for (i = 0; i < SCI_MAX_PHYS; i++) phy_mask |= oem->ports[i].phy_mask; if (phy_mask == 0) return -EINVAL; } else return -EINVAL; if (oem->controller.max_concurr_spin_up > MAX_CONCURRENT_DEVICE_SPIN_UP_COUNT || oem->controller.max_concurr_spin_up < 1) return -EINVAL; if (oem->controller.do_enable_ssc) { if (version < ISCI_ROM_VER_1_1 && oem->controller.do_enable_ssc != 1) return -EINVAL; if (version >= ISCI_ROM_VER_1_1) { u8 test = oem->controller.ssc_sata_tx_spread_level; switch (test) { case 0: case 2: case 3: case 6: case 7: break; default: return -EINVAL; } test = oem->controller.ssc_sas_tx_spread_level; if (oem->controller.ssc_sas_tx_type == 0) { switch (test) { case 0: case 2: case 3: break; default: return -EINVAL; } } else if (oem->controller.ssc_sas_tx_type == 1) { switch (test) { case 0: case 3: case 6: break; default: return -EINVAL; } } } } return 0; } static u8 max_spin_up(struct isci_host *ihost) { if (ihost->user_parameters.max_concurr_spinup) return min_t(u8, ihost->user_parameters.max_concurr_spinup, MAX_CONCURRENT_DEVICE_SPIN_UP_COUNT); else return min_t(u8, ihost->oem_parameters.controller.max_concurr_spin_up, MAX_CONCURRENT_DEVICE_SPIN_UP_COUNT); } static void power_control_timeout(struct timer_list *t) { struct sci_timer *tmr = from_timer(tmr, t, timer); struct isci_host *ihost = container_of(tmr, typeof(*ihost), power_control.timer); struct isci_phy *iphy; unsigned long flags; u8 i; spin_lock_irqsave(&ihost->scic_lock, flags); if (tmr->cancel) goto done; ihost->power_control.phys_granted_power = 0; if (ihost->power_control.phys_waiting == 0) { ihost->power_control.timer_started = false; goto done; } for (i = 0; i < SCI_MAX_PHYS; i++) { if (ihost->power_control.phys_waiting == 0) break; iphy = ihost->power_control.requesters[i]; if (iphy == NULL) continue; if (ihost->power_control.phys_granted_power >= max_spin_up(ihost)) break; ihost->power_control.requesters[i] = NULL; ihost->power_control.phys_waiting--; ihost->power_control.phys_granted_power++; sci_phy_consume_power_handler(iphy); if (iphy->protocol == SAS_PROTOCOL_SSP) { u8 j; for (j = 0; j < SCI_MAX_PHYS; j++) { struct isci_phy *requester = ihost->power_control.requesters[j]; /* * Search the power_control queue to see if there are other phys * attached to the same remote device. If found, take all of * them out of await_sas_power state. */ if (requester != NULL && requester != iphy) { u8 other = memcmp(requester->frame_rcvd.iaf.sas_addr, iphy->frame_rcvd.iaf.sas_addr, sizeof(requester->frame_rcvd.iaf.sas_addr)); if (other == 0) { ihost->power_control.requesters[j] = NULL; ihost->power_control.phys_waiting--; sci_phy_consume_power_handler(requester); } } } } } /* * It doesn't matter if the power list is empty, we need to start the * timer in case another phy becomes ready. */ sci_mod_timer(tmr, SCIC_SDS_CONTROLLER_POWER_CONTROL_INTERVAL); ihost->power_control.timer_started = true; done: spin_unlock_irqrestore(&ihost->scic_lock, flags); } void sci_controller_power_control_queue_insert(struct isci_host *ihost, struct isci_phy *iphy) { BUG_ON(iphy == NULL); if (ihost->power_control.phys_granted_power < max_spin_up(ihost)) { ihost->power_control.phys_granted_power++; sci_phy_consume_power_handler(iphy); /* * stop and start the power_control timer. When the timer fires, the * no_of_phys_granted_power will be set to 0 */ if (ihost->power_control.timer_started) sci_del_timer(&ihost->power_control.timer); sci_mod_timer(&ihost->power_control.timer, SCIC_SDS_CONTROLLER_POWER_CONTROL_INTERVAL); ihost->power_control.timer_started = true; } else { /* * There are phys, attached to the same sas address as this phy, are * already in READY state, this phy don't need wait. */ u8 i; struct isci_phy *current_phy; for (i = 0; i < SCI_MAX_PHYS; i++) { u8 other; current_phy = &ihost->phys[i]; other = memcmp(current_phy->frame_rcvd.iaf.sas_addr, iphy->frame_rcvd.iaf.sas_addr, sizeof(current_phy->frame_rcvd.iaf.sas_addr)); if (current_phy->sm.current_state_id == SCI_PHY_READY && current_phy->protocol == SAS_PROTOCOL_SSP && other == 0) { sci_phy_consume_power_handler(iphy); break; } } if (i == SCI_MAX_PHYS) { /* Add the phy in the waiting list */ ihost->power_control.requesters[iphy->phy_index] = iphy; ihost->power_control.phys_waiting++; } } } void sci_controller_power_control_queue_remove(struct isci_host *ihost, struct isci_phy *iphy) { BUG_ON(iphy == NULL); if (ihost->power_control.requesters[iphy->phy_index]) ihost->power_control.phys_waiting--; ihost->power_control.requesters[iphy->phy_index] = NULL; } static int is_long_cable(int phy, unsigned char selection_byte) { return !!(selection_byte & (1 << phy)); } static int is_medium_cable(int phy, unsigned char selection_byte) { return !!(selection_byte & (1 << (phy + 4))); } static enum cable_selections decode_selection_byte( int phy, unsigned char selection_byte) { return ((selection_byte & (1 << phy)) ? 1 : 0) + (selection_byte & (1 << (phy + 4)) ? 2 : 0); } static unsigned char *to_cable_select(struct isci_host *ihost) { if (is_cable_select_overridden()) return ((unsigned char *)&cable_selection_override) + ihost->id; else return &ihost->oem_parameters.controller.cable_selection_mask; } enum cable_selections decode_cable_selection(struct isci_host *ihost, int phy) { return decode_selection_byte(phy, *to_cable_select(ihost)); } char *lookup_cable_names(enum cable_selections selection) { static char *cable_names[] = { [short_cable] = "short", [long_cable] = "long", [medium_cable] = "medium", [undefined_cable] = "<undefined, assumed long>" /* bit 0==1 */ }; return (selection <= undefined_cable) ? cable_names[selection] : cable_names[undefined_cable]; } #define AFE_REGISTER_WRITE_DELAY 10 static void sci_controller_afe_initialization(struct isci_host *ihost) { struct scu_afe_registers __iomem *afe = &ihost->scu_registers->afe; const struct sci_oem_params *oem = &ihost->oem_parameters; struct pci_dev *pdev = ihost->pdev; u32 afe_status; u32 phy_id; unsigned char cable_selection_mask = *to_cable_select(ihost); /* Clear DFX Status registers */ writel(0x0081000f, &afe->afe_dfx_master_control0); udelay(AFE_REGISTER_WRITE_DELAY); if (is_b0(pdev) || is_c0(pdev) || is_c1(pdev)) { /* PM Rx Equalization Save, PM SPhy Rx Acknowledgement * Timer, PM Stagger Timer */ writel(0x0007FFFF, &afe->afe_pmsn_master_control2); udelay(AFE_REGISTER_WRITE_DELAY); } /* Configure bias currents to normal */ if (is_a2(pdev)) writel(0x00005A00, &afe->afe_bias_control); else if (is_b0(pdev) || is_c0(pdev)) writel(0x00005F00, &afe->afe_bias_control); else if (is_c1(pdev)) writel(0x00005500, &afe->afe_bias_control); udelay(AFE_REGISTER_WRITE_DELAY); /* Enable PLL */ if (is_a2(pdev)) writel(0x80040908, &afe->afe_pll_control0); else if (is_b0(pdev) || is_c0(pdev)) writel(0x80040A08, &afe->afe_pll_control0); else if (is_c1(pdev)) { writel(0x80000B08, &afe->afe_pll_control0); udelay(AFE_REGISTER_WRITE_DELAY); writel(0x00000B08, &afe->afe_pll_control0); udelay(AFE_REGISTER_WRITE_DELAY); writel(0x80000B08, &afe->afe_pll_control0); } udelay(AFE_REGISTER_WRITE_DELAY); /* Wait for the PLL to lock */ do { afe_status = readl(&afe->afe_common_block_status); udelay(AFE_REGISTER_WRITE_DELAY); } while ((afe_status & 0x00001000) == 0); if (is_a2(pdev)) { /* Shorten SAS SNW lock time (RxLock timer value from 76 * us to 50 us) */ writel(0x7bcc96ad, &afe->afe_pmsn_master_control0); udelay(AFE_REGISTER_WRITE_DELAY); } for (phy_id = 0; phy_id < SCI_MAX_PHYS; phy_id++) { struct scu_afe_transceiver __iomem *xcvr = &afe->scu_afe_xcvr[phy_id]; const struct sci_phy_oem_params *oem_phy = &oem->phys[phy_id]; int cable_length_long = is_long_cable(phy_id, cable_selection_mask); int cable_length_medium = is_medium_cable(phy_id, cable_selection_mask); if (is_a2(pdev)) { /* All defaults, except the Receive Word * Alignament/Comma Detect Enable....(0xe800) */ writel(0x00004512, &xcvr->afe_xcvr_control0); udelay(AFE_REGISTER_WRITE_DELAY); writel(0x0050100F, &xcvr->afe_xcvr_control1); udelay(AFE_REGISTER_WRITE_DELAY); } else if (is_b0(pdev)) { /* Configure transmitter SSC parameters */ writel(0x00030000, &xcvr->afe_tx_ssc_control); udelay(AFE_REGISTER_WRITE_DELAY); } else if (is_c0(pdev)) { /* Configure transmitter SSC parameters */ writel(0x00010202, &xcvr->afe_tx_ssc_control); udelay(AFE_REGISTER_WRITE_DELAY); /* All defaults, except the Receive Word * Alignament/Comma Detect Enable....(0xe800) */ writel(0x00014500, &xcvr->afe_xcvr_control0); udelay(AFE_REGISTER_WRITE_DELAY); } else if (is_c1(pdev)) { /* Configure transmitter SSC parameters */ writel(0x00010202, &xcvr->afe_tx_ssc_control); udelay(AFE_REGISTER_WRITE_DELAY); /* All defaults, except the Receive Word * Alignament/Comma Detect Enable....(0xe800) */ writel(0x0001C500, &xcvr->afe_xcvr_control0); udelay(AFE_REGISTER_WRITE_DELAY); } /* Power up TX and RX out from power down (PWRDNTX and * PWRDNRX) & increase TX int & ext bias 20%....(0xe85c) */ if (is_a2(pdev)) writel(0x000003F0, &xcvr->afe_channel_control); else if (is_b0(pdev)) { writel(0x000003D7, &xcvr->afe_channel_control); udelay(AFE_REGISTER_WRITE_DELAY); writel(0x000003D4, &xcvr->afe_channel_control); } else if (is_c0(pdev)) { writel(0x000001E7, &xcvr->afe_channel_control); udelay(AFE_REGISTER_WRITE_DELAY); writel(0x000001E4, &xcvr->afe_channel_control); } else if (is_c1(pdev)) { writel(cable_length_long ? 0x000002F7 : 0x000001F7, &xcvr->afe_channel_control); udelay(AFE_REGISTER_WRITE_DELAY); writel(cable_length_long ? 0x000002F4 : 0x000001F4, &xcvr->afe_channel_control); } udelay(AFE_REGISTER_WRITE_DELAY); if (is_a2(pdev)) { /* Enable TX equalization (0xe824) */ writel(0x00040000, &xcvr->afe_tx_control); udelay(AFE_REGISTER_WRITE_DELAY); } if (is_a2(pdev) || is_b0(pdev)) /* RDPI=0x0(RX Power On), RXOOBDETPDNC=0x0, * TPD=0x0(TX Power On), RDD=0x0(RX Detect * Enabled) ....(0xe800) */ writel(0x00004100, &xcvr->afe_xcvr_control0); else if (is_c0(pdev)) writel(0x00014100, &xcvr->afe_xcvr_control0); else if (is_c1(pdev)) writel(0x0001C100, &xcvr->afe_xcvr_control0); udelay(AFE_REGISTER_WRITE_DELAY); /* Leave DFE/FFE on */ if (is_a2(pdev)) writel(0x3F11103F, &xcvr->afe_rx_ssc_control0); else if (is_b0(pdev)) { writel(0x3F11103F, &xcvr->afe_rx_ssc_control0); udelay(AFE_REGISTER_WRITE_DELAY); /* Enable TX equalization (0xe824) */ writel(0x00040000, &xcvr->afe_tx_control); } else if (is_c0(pdev)) { writel(0x01400C0F, &xcvr->afe_rx_ssc_control1); udelay(AFE_REGISTER_WRITE_DELAY); writel(0x3F6F103F, &xcvr->afe_rx_ssc_control0); udelay(AFE_REGISTER_WRITE_DELAY); /* Enable TX equalization (0xe824) */ writel(0x00040000, &xcvr->afe_tx_control); } else if (is_c1(pdev)) { writel(cable_length_long ? 0x01500C0C : cable_length_medium ? 0x01400C0D : 0x02400C0D, &xcvr->afe_xcvr_control1); udelay(AFE_REGISTER_WRITE_DELAY); writel(0x000003E0, &xcvr->afe_dfx_rx_control1); udelay(AFE_REGISTER_WRITE_DELAY); writel(cable_length_long ? 0x33091C1F : cable_length_medium ? 0x3315181F : 0x2B17161F, &xcvr->afe_rx_ssc_control0); udelay(AFE_REGISTER_WRITE_DELAY); /* Enable TX equalization (0xe824) */ writel(0x00040000, &xcvr->afe_tx_control); } udelay(AFE_REGISTER_WRITE_DELAY); writel(oem_phy->afe_tx_amp_control0, &xcvr->afe_tx_amp_control0); udelay(AFE_REGISTER_WRITE_DELAY); writel(oem_phy->afe_tx_amp_control1, &xcvr->afe_tx_amp_control1); udelay(AFE_REGISTER_WRITE_DELAY); writel(oem_phy->afe_tx_amp_control2, &xcvr->afe_tx_amp_control2); udelay(AFE_REGISTER_WRITE_DELAY); writel(oem_phy->afe_tx_amp_control3, &xcvr->afe_tx_amp_control3); udelay(AFE_REGISTER_WRITE_DELAY); } /* Transfer control to the PEs */ writel(0x00010f00, &afe->afe_dfx_master_control0); udelay(AFE_REGISTER_WRITE_DELAY); } static void sci_controller_initialize_power_control(struct isci_host *ihost) { sci_init_timer(&ihost->power_control.timer, power_control_timeout); memset(ihost->power_control.requesters, 0, sizeof(ihost->power_control.requesters)); ihost->power_control.phys_waiting = 0; ihost->power_control.phys_granted_power = 0; } static enum sci_status sci_controller_initialize(struct isci_host *ihost) { struct sci_base_state_machine *sm = &ihost->sm; enum sci_status result = SCI_FAILURE; unsigned long i, state, val; if (ihost->sm.current_state_id != SCIC_RESET) { dev_warn(&ihost->pdev->dev, "%s invalid state: %d\n", __func__, ihost->sm.current_state_id); return SCI_FAILURE_INVALID_STATE; } sci_change_state(sm, SCIC_INITIALIZING); sci_init_timer(&ihost->phy_timer, phy_startup_timeout); ihost->next_phy_to_start = 0; ihost->phy_startup_timer_pending = false; sci_controller_initialize_power_control(ihost); /* * There is nothing to do here for B0 since we do not have to * program the AFE registers. * / @todo The AFE settings are supposed to be correct for the B0 but * / presently they seem to be wrong. */ sci_controller_afe_initialization(ihost); /* Take the hardware out of reset */ writel(0, &ihost->smu_registers->soft_reset_control); /* * / @todo Provide meaningfull error code for hardware failure * result = SCI_FAILURE_CONTROLLER_HARDWARE; */ for (i = 100; i >= 1; i--) { u32 status; /* Loop until the hardware reports success */ udelay(SCU_CONTEXT_RAM_INIT_STALL_TIME); status = readl(&ihost->smu_registers->control_status); if ((status & SCU_RAM_INIT_COMPLETED) == SCU_RAM_INIT_COMPLETED) break; } if (i == 0) goto out; /* * Determine what are the actaul device capacities that the * hardware will support */ val = readl(&ihost->smu_registers->device_context_capacity); /* Record the smaller of the two capacity values */ ihost->logical_port_entries = min(smu_max_ports(val), SCI_MAX_PORTS); ihost->task_context_entries = min(smu_max_task_contexts(val), SCI_MAX_IO_REQUESTS); ihost->remote_node_entries = min(smu_max_rncs(val), SCI_MAX_REMOTE_DEVICES); /* * Make all PEs that are unassigned match up with the * logical ports */ for (i = 0; i < ihost->logical_port_entries; i++) { struct scu_port_task_scheduler_group_registers __iomem *ptsg = &ihost->scu_registers->peg0.ptsg; writel(i, &ptsg->protocol_engine[i]); } /* Initialize hardware PCI Relaxed ordering in DMA engines */ val = readl(&ihost->scu_registers->sdma.pdma_configuration); val |= SCU_PDMACR_GEN_BIT(PCI_RELAXED_ORDERING_ENABLE); writel(val, &ihost->scu_registers->sdma.pdma_configuration); val = readl(&ihost->scu_registers->sdma.cdma_configuration); val |= SCU_CDMACR_GEN_BIT(PCI_RELAXED_ORDERING_ENABLE); writel(val, &ihost->scu_registers->sdma.cdma_configuration); /* * Initialize the PHYs before the PORTs because the PHY registers * are accessed during the port initialization. */ for (i = 0; i < SCI_MAX_PHYS; i++) { result = sci_phy_initialize(&ihost->phys[i], &ihost->scu_registers->peg0.pe[i].tl, &ihost->scu_registers->peg0.pe[i].ll); if (result != SCI_SUCCESS) goto out; } for (i = 0; i < ihost->logical_port_entries; i++) { struct isci_port *iport = &ihost->ports[i]; iport->port_task_scheduler_registers = &ihost->scu_registers->peg0.ptsg.port[i]; iport->port_pe_configuration_register = &ihost->scu_registers->peg0.ptsg.protocol_engine[0]; iport->viit_registers = &ihost->scu_registers->peg0.viit[i]; } result = sci_port_configuration_agent_initialize(ihost, &ihost->port_agent); out: /* Advance the controller state machine */ if (result == SCI_SUCCESS) state = SCIC_INITIALIZED; else state = SCIC_FAILED; sci_change_state(sm, state); return result; } static int sci_controller_dma_alloc(struct isci_host *ihost) { struct device *dev = &ihost->pdev->dev; size_t size; int i; /* detect re-initialization */ if (ihost->completion_queue) return 0; size = SCU_MAX_COMPLETION_QUEUE_ENTRIES * sizeof(u32); ihost->completion_queue = dmam_alloc_coherent(dev, size, &ihost->cq_dma, GFP_KERNEL); if (!ihost->completion_queue) return -ENOMEM; size = ihost->remote_node_entries * sizeof(union scu_remote_node_context); ihost->remote_node_context_table = dmam_alloc_coherent(dev, size, &ihost->rnc_dma, GFP_KERNEL); if (!ihost->remote_node_context_table) return -ENOMEM; size = ihost->task_context_entries * sizeof(struct scu_task_context), ihost->task_context_table = dmam_alloc_coherent(dev, size, &ihost->tc_dma, GFP_KERNEL); if (!ihost->task_context_table) return -ENOMEM; size = SCI_UFI_TOTAL_SIZE; ihost->ufi_buf = dmam_alloc_coherent(dev, size, &ihost->ufi_dma, GFP_KERNEL); if (!ihost->ufi_buf) return -ENOMEM; for (i = 0; i < SCI_MAX_IO_REQUESTS; i++) { struct isci_request *ireq; dma_addr_t dma; ireq = dmam_alloc_coherent(dev, sizeof(*ireq), &dma, GFP_KERNEL); if (!ireq) return -ENOMEM; ireq->tc = &ihost->task_context_table[i]; ireq->owning_controller = ihost; ireq->request_daddr = dma; ireq->isci_host = ihost; ihost->reqs[i] = ireq; } return 0; } static int sci_controller_mem_init(struct isci_host *ihost) { int err = sci_controller_dma_alloc(ihost); if (err) return err; writel(lower_32_bits(ihost->cq_dma), &ihost->smu_registers->completion_queue_lower); writel(upper_32_bits(ihost->cq_dma), &ihost->smu_registers->completion_queue_upper); writel(lower_32_bits(ihost->rnc_dma), &ihost->smu_registers->remote_node_context_lower); writel(upper_32_bits(ihost->rnc_dma), &ihost->smu_registers->remote_node_context_upper); writel(lower_32_bits(ihost->tc_dma), &ihost->smu_registers->host_task_table_lower); writel(upper_32_bits(ihost->tc_dma), &ihost->smu_registers->host_task_table_upper); sci_unsolicited_frame_control_construct(ihost); /* * Inform the silicon as to the location of the UF headers and * address table. */ writel(lower_32_bits(ihost->uf_control.headers.physical_address), &ihost->scu_registers->sdma.uf_header_base_address_lower); writel(upper_32_bits(ihost->uf_control.headers.physical_address), &ihost->scu_registers->sdma.uf_header_base_address_upper); writel(lower_32_bits(ihost->uf_control.address_table.physical_address), &ihost->scu_registers->sdma.uf_address_table_lower); writel(upper_32_bits(ihost->uf_control.address_table.physical_address), &ihost->scu_registers->sdma.uf_address_table_upper); return 0; } /** * isci_host_init - (re-)initialize hardware and internal (private) state * @ihost: host to init * * Any public facing objects (like asd_sas_port, and asd_sas_phys), or * one-time initialization objects like locks and waitqueues, are * not touched (they are initialized in isci_host_alloc) */ int isci_host_init(struct isci_host *ihost) { int i, err; enum sci_status status; spin_lock_irq(&ihost->scic_lock); status = sci_controller_construct(ihost, scu_base(ihost), smu_base(ihost)); spin_unlock_irq(&ihost->scic_lock); if (status != SCI_SUCCESS) { dev_err(&ihost->pdev->dev, "%s: sci_controller_construct failed - status = %x\n", __func__, status); return -ENODEV; } spin_lock_irq(&ihost->scic_lock); status = sci_controller_initialize(ihost); spin_unlock_irq(&ihost->scic_lock); if (status != SCI_SUCCESS) { dev_warn(&ihost->pdev->dev, "%s: sci_controller_initialize failed -" " status = 0x%x\n", __func__, status); return -ENODEV; } err = sci_controller_mem_init(ihost); if (err) return err; /* enable sgpio */ writel(1, &ihost->scu_registers->peg0.sgpio.interface_control); for (i = 0; i < isci_gpio_count(ihost); i++) writel(SGPIO_HW_CONTROL, &ihost->scu_registers->peg0.sgpio.output_data_select[i]); writel(0, &ihost->scu_registers->peg0.sgpio.vendor_specific_code); return 0; } void sci_controller_link_up(struct isci_host *ihost, struct isci_port *iport, struct isci_phy *iphy) { switch (ihost->sm.current_state_id) { case SCIC_STARTING: sci_del_timer(&ihost->phy_timer); ihost->phy_startup_timer_pending = false; ihost->port_agent.link_up_handler(ihost, &ihost->port_agent, iport, iphy); sci_controller_start_next_phy(ihost); break; case SCIC_READY: ihost->port_agent.link_up_handler(ihost, &ihost->port_agent, iport, iphy); break; default: dev_dbg(&ihost->pdev->dev, "%s: SCIC Controller linkup event from phy %d in " "unexpected state %d\n", __func__, iphy->phy_index, ihost->sm.current_state_id); } } void sci_controller_link_down(struct isci_host *ihost, struct isci_port *iport, struct isci_phy *iphy) { switch (ihost->sm.current_state_id) { case SCIC_STARTING: case SCIC_READY: ihost->port_agent.link_down_handler(ihost, &ihost->port_agent, iport, iphy); break; default: dev_dbg(&ihost->pdev->dev, "%s: SCIC Controller linkdown event from phy %d in " "unexpected state %d\n", __func__, iphy->phy_index, ihost->sm.current_state_id); } } bool sci_controller_has_remote_devices_stopping(struct isci_host *ihost) { u32 index; for (index = 0; index < ihost->remote_node_entries; index++) { if ((ihost->device_table[index] != NULL) && (ihost->device_table[index]->sm.current_state_id == SCI_DEV_STOPPING)) return true; } return false; } void sci_controller_remote_device_stopped(struct isci_host *ihost, struct isci_remote_device *idev) { if (ihost->sm.current_state_id != SCIC_STOPPING) { dev_dbg(&ihost->pdev->dev, "SCIC Controller 0x%p remote device stopped event " "from device 0x%p in unexpected state %d\n", ihost, idev, ihost->sm.current_state_id); return; } if (!sci_controller_has_remote_devices_stopping(ihost)) isci_host_stop_complete(ihost); } void sci_controller_post_request(struct isci_host *ihost, u32 request) { dev_dbg(&ihost->pdev->dev, "%s[%d]: %#x\n", __func__, ihost->id, request); writel(request, &ihost->smu_registers->post_context_port); } struct isci_request *sci_request_by_tag(struct isci_host *ihost, u16 io_tag) { u16 task_index; u16 task_sequence; task_index = ISCI_TAG_TCI(io_tag); if (task_index < ihost->task_context_entries) { struct isci_request *ireq = ihost->reqs[task_index]; if (test_bit(IREQ_ACTIVE, &ireq->flags)) { task_sequence = ISCI_TAG_SEQ(io_tag); if (task_sequence == ihost->io_request_sequence[task_index]) return ireq; } } return NULL; } /** * sci_controller_allocate_remote_node_context() * This method allocates remote node index and the reserves the remote node * context space for use. This method can fail if there are no more remote * node index available. * @ihost: This is the controller object which contains the set of * free remote node ids * @idev: This is the device object which is requesting the a remote node * id * @node_id: This is the remote node id that is assinged to the device if one * is available * * enum sci_status SCI_FAILURE_OUT_OF_RESOURCES if there are no available remote * node index available. */ enum sci_status sci_controller_allocate_remote_node_context(struct isci_host *ihost, struct isci_remote_device *idev, u16 *node_id) { u16 node_index; u32 remote_node_count = sci_remote_device_node_count(idev); node_index = sci_remote_node_table_allocate_remote_node( &ihost->available_remote_nodes, remote_node_count ); if (node_index != SCIC_SDS_REMOTE_NODE_CONTEXT_INVALID_INDEX) { ihost->device_table[node_index] = idev; *node_id = node_index; return SCI_SUCCESS; } return SCI_FAILURE_INSUFFICIENT_RESOURCES; } void sci_controller_free_remote_node_context(struct isci_host *ihost, struct isci_remote_device *idev, u16 node_id) { u32 remote_node_count = sci_remote_device_node_count(idev); if (ihost->device_table[node_id] == idev) { ihost->device_table[node_id] = NULL; sci_remote_node_table_release_remote_node_index( &ihost->available_remote_nodes, remote_node_count, node_id ); } } void sci_controller_copy_sata_response(void *response_buffer, void *frame_header, void *frame_buffer) { /* XXX type safety? */ memcpy(response_buffer, frame_header, sizeof(u32)); memcpy(response_buffer + sizeof(u32), frame_buffer, sizeof(struct dev_to_host_fis) - sizeof(u32)); } void sci_controller_release_frame(struct isci_host *ihost, u32 frame_index) { if (sci_unsolicited_frame_control_release_frame(&ihost->uf_control, frame_index)) writel(ihost->uf_control.get, &ihost->scu_registers->sdma.unsolicited_frame_get_pointer); } void isci_tci_free(struct isci_host *ihost, u16 tci) { u16 tail = ihost->tci_tail & (SCI_MAX_IO_REQUESTS-1); ihost->tci_pool[tail] = tci; ihost->tci_tail = tail + 1; } static u16 isci_tci_alloc(struct isci_host *ihost) { u16 head = ihost->tci_head & (SCI_MAX_IO_REQUESTS-1); u16 tci = ihost->tci_pool[head]; ihost->tci_head = head + 1; return tci; } static u16 isci_tci_space(struct isci_host *ihost) { return CIRC_SPACE(ihost->tci_head, ihost->tci_tail, SCI_MAX_IO_REQUESTS); } u16 isci_alloc_tag(struct isci_host *ihost) { if (isci_tci_space(ihost)) { u16 tci = isci_tci_alloc(ihost); u8 seq = ihost->io_request_sequence[tci]; return ISCI_TAG(seq, tci); } return SCI_CONTROLLER_INVALID_IO_TAG; } enum sci_status isci_free_tag(struct isci_host *ihost, u16 io_tag) { u16 tci = ISCI_TAG_TCI(io_tag); u16 seq = ISCI_TAG_SEQ(io_tag); /* prevent tail from passing head */ if (isci_tci_active(ihost) == 0) return SCI_FAILURE_INVALID_IO_TAG; if (seq == ihost->io_request_sequence[tci]) { ihost->io_request_sequence[tci] = (seq+1) & (SCI_MAX_SEQ-1); isci_tci_free(ihost, tci); return SCI_SUCCESS; } return SCI_FAILURE_INVALID_IO_TAG; } enum sci_status sci_controller_start_io(struct isci_host *ihost, struct isci_remote_device *idev, struct isci_request *ireq) { enum sci_status status; if (ihost->sm.current_state_id != SCIC_READY) { dev_warn(&ihost->pdev->dev, "%s invalid state: %d\n", __func__, ihost->sm.current_state_id); return SCI_FAILURE_INVALID_STATE; } status = sci_remote_device_start_io(ihost, idev, ireq); if (status != SCI_SUCCESS) return status; set_bit(IREQ_ACTIVE, &ireq->flags); sci_controller_post_request(ihost, ireq->post_context); return SCI_SUCCESS; } enum sci_status sci_controller_terminate_request(struct isci_host *ihost, struct isci_remote_device *idev, struct isci_request *ireq) { /* terminate an ongoing (i.e. started) core IO request. This does not * abort the IO request at the target, but rather removes the IO * request from the host controller. */ enum sci_status status; if (ihost->sm.current_state_id != SCIC_READY) { dev_warn(&ihost->pdev->dev, "%s invalid state: %d\n", __func__, ihost->sm.current_state_id); return SCI_FAILURE_INVALID_STATE; } status = sci_io_request_terminate(ireq); dev_dbg(&ihost->pdev->dev, "%s: status=%d; ireq=%p; flags=%lx\n", __func__, status, ireq, ireq->flags); if ((status == SCI_SUCCESS) && !test_bit(IREQ_PENDING_ABORT, &ireq->flags) && !test_and_set_bit(IREQ_TC_ABORT_POSTED, &ireq->flags)) { /* Utilize the original post context command and or in the * POST_TC_ABORT request sub-type. */ sci_controller_post_request( ihost, ireq->post_context | SCU_CONTEXT_COMMAND_REQUEST_POST_TC_ABORT); } return status; } /** * sci_controller_complete_io() - This method will perform core specific * completion operations for an IO request. After this method is invoked, * the user should consider the IO request as invalid until it is properly * reused (i.e. re-constructed). * @ihost: The handle to the controller object for which to complete the * IO request. * @idev: The handle to the remote device object for which to complete * the IO request. * @ireq: the handle to the io request object to complete. */ enum sci_status sci_controller_complete_io(struct isci_host *ihost, struct isci_remote_device *idev, struct isci_request *ireq) { enum sci_status status; switch (ihost->sm.current_state_id) { case SCIC_STOPPING: /* XXX: Implement this function */ return SCI_FAILURE; case SCIC_READY: status = sci_remote_device_complete_io(ihost, idev, ireq); if (status != SCI_SUCCESS) return status; clear_bit(IREQ_ACTIVE, &ireq->flags); return SCI_SUCCESS; default: dev_warn(&ihost->pdev->dev, "%s invalid state: %d\n", __func__, ihost->sm.current_state_id); return SCI_FAILURE_INVALID_STATE; } } enum sci_status sci_controller_continue_io(struct isci_request *ireq) { struct isci_host *ihost = ireq->owning_controller; if (ihost->sm.current_state_id != SCIC_READY) { dev_warn(&ihost->pdev->dev, "%s invalid state: %d\n", __func__, ihost->sm.current_state_id); return SCI_FAILURE_INVALID_STATE; } set_bit(IREQ_ACTIVE, &ireq->flags); sci_controller_post_request(ihost, ireq->post_context); return SCI_SUCCESS; } /** * sci_controller_start_task() - This method is called by the SCIC user to * send/start a framework task management request. * @ihost: the handle to the controller object for which to start the task * management request. * @idev: the handle to the remote device object for which to start * the task management request. * @ireq: the handle to the task request object to start. */ enum sci_status sci_controller_start_task(struct isci_host *ihost, struct isci_remote_device *idev, struct isci_request *ireq) { enum sci_status status; if (ihost->sm.current_state_id != SCIC_READY) { dev_warn(&ihost->pdev->dev, "%s: SCIC Controller starting task from invalid " "state\n", __func__); return SCI_FAILURE_INVALID_STATE; } status = sci_remote_device_start_task(ihost, idev, ireq); switch (status) { case SCI_FAILURE_RESET_DEVICE_PARTIAL_SUCCESS: set_bit(IREQ_ACTIVE, &ireq->flags); /* * We will let framework know this task request started successfully, * although core is still woring on starting the request (to post tc when * RNC is resumed.) */ return SCI_SUCCESS; case SCI_SUCCESS: set_bit(IREQ_ACTIVE, &ireq->flags); sci_controller_post_request(ihost, ireq->post_context); break; default: break; } return status; } static int sci_write_gpio_tx_gp(struct isci_host *ihost, u8 reg_index, u8 reg_count, u8 *write_data) { int d; /* no support for TX_GP_CFG */ if (reg_index == 0) return -EINVAL; for (d = 0; d < isci_gpio_count(ihost); d++) { u32 val = 0x444; /* all ODx.n clear */ int i; for (i = 0; i < 3; i++) { int bit; bit = try_test_sas_gpio_gp_bit(to_sas_gpio_od(d, i), write_data, reg_index, reg_count); if (bit < 0) break; /* if od is set, clear the 'invert' bit */ val &= ~(bit << ((i << 2) + 2)); } if (i < 3) break; writel(val, &ihost->scu_registers->peg0.sgpio.output_data_select[d]); } /* unless reg_index is > 1, we should always be able to write at * least one register */ return d > 0; } int isci_gpio_write(struct sas_ha_struct *sas_ha, u8 reg_type, u8 reg_index, u8 reg_count, u8 *write_data) { struct isci_host *ihost = sas_ha->lldd_ha; int written; switch (reg_type) { case SAS_GPIO_REG_TX_GP: written = sci_write_gpio_tx_gp(ihost, reg_index, reg_count, write_data); break; default: written = -EINVAL; } return written; } |