// SPDX-License-Identifier: GPL-2.0-only /* * Copyright (C) 2020-21 Intel Corporation. */ #include #include "iosm_ipc_chnl_cfg.h" #include "iosm_ipc_devlink.h" #include "iosm_ipc_flash.h" #include "iosm_ipc_imem.h" #include "iosm_ipc_port.h" /* Check the wwan ips if it is valid with Channel as input. */ static int ipc_imem_check_wwan_ips(struct ipc_mem_channel *chnl) { if (chnl) return chnl->ctype == IPC_CTYPE_WWAN && chnl->if_id == IPC_MEM_MUX_IP_CH_IF_ID; return false; } static int ipc_imem_msg_send_device_sleep(struct iosm_imem *ipc_imem, u32 state) { union ipc_msg_prep_args prep_args = { .sleep.target = 1, .sleep.state = state, }; ipc_imem->device_sleep = state; return ipc_protocol_tq_msg_send(ipc_imem->ipc_protocol, IPC_MSG_PREP_SLEEP, &prep_args, NULL); } static bool ipc_imem_dl_skb_alloc(struct iosm_imem *ipc_imem, struct ipc_pipe *pipe) { /* limit max. nr of entries */ if (pipe->nr_of_queued_entries >= pipe->max_nr_of_queued_entries) return false; return ipc_protocol_dl_td_prepare(ipc_imem->ipc_protocol, pipe); } /* This timer handler will retry DL buff allocation if a pipe has no free buf * and gives doorbell if TD is available */ static int ipc_imem_tq_td_alloc_timer(struct iosm_imem *ipc_imem, int arg, void *msg, size_t size) { bool new_buffers_available = false; bool retry_allocation = false; int i; for (i = 0; i < IPC_MEM_MAX_CHANNELS; i++) { struct ipc_pipe *pipe = &ipc_imem->channels[i].dl_pipe; if (!pipe->is_open || pipe->nr_of_queued_entries > 0) continue; while (ipc_imem_dl_skb_alloc(ipc_imem, pipe)) new_buffers_available = true; if (pipe->nr_of_queued_entries == 0) retry_allocation = true; } if (new_buffers_available) ipc_protocol_doorbell_trigger(ipc_imem->ipc_protocol, IPC_HP_DL_PROCESS); if (retry_allocation) { ipc_imem->hrtimer_period = ktime_set(0, IPC_TD_ALLOC_TIMER_PERIOD_MS * 1000 * 1000ULL); if (!hrtimer_active(&ipc_imem->td_alloc_timer)) hrtimer_start(&ipc_imem->td_alloc_timer, ipc_imem->hrtimer_period, HRTIMER_MODE_REL); } return 0; } static enum hrtimer_restart ipc_imem_td_alloc_timer_cb(struct hrtimer *hr_timer) { struct iosm_imem *ipc_imem = container_of(hr_timer, struct iosm_imem, td_alloc_timer); /* Post an async tasklet event to trigger HP update Doorbell */ ipc_task_queue_send_task(ipc_imem, ipc_imem_tq_td_alloc_timer, 0, NULL, 0, false); return HRTIMER_NORESTART; } /* Fast update timer tasklet handler to trigger HP update */ static int ipc_imem_tq_fast_update_timer_cb(struct iosm_imem *ipc_imem, int arg, void *msg, size_t size) { ipc_protocol_doorbell_trigger(ipc_imem->ipc_protocol, IPC_HP_FAST_TD_UPD_TMR); return 0; } static enum hrtimer_restart ipc_imem_fast_update_timer_cb(struct hrtimer *hr_timer) { struct iosm_imem *ipc_imem = container_of(hr_timer, struct iosm_imem, fast_update_timer); /* Post an async tasklet event to trigger HP update Doorbell */ ipc_task_queue_send_task(ipc_imem, ipc_imem_tq_fast_update_timer_cb, 0, NULL, 0, false); return HRTIMER_NORESTART; } static int ipc_imem_setup_cp_mux_cap_init(struct iosm_imem *ipc_imem, struct ipc_mux_config *cfg) { ipc_mmio_update_cp_capability(ipc_imem->mmio); if (!ipc_imem->mmio->has_mux_lite) { dev_err(ipc_imem->dev, "Failed to get Mux capability."); return -EINVAL; } cfg->protocol = MUX_LITE; cfg->ul_flow = (ipc_imem->mmio->has_ul_flow_credit == 1) ? MUX_UL_ON_CREDITS : MUX_UL; /* The instance ID is same as channel ID because this is been reused * for channel alloc function. */ cfg->instance_id = IPC_MEM_MUX_IP_CH_IF_ID; cfg->nr_sessions = IPC_MEM_MUX_IP_SESSION_ENTRIES; return 0; } void ipc_imem_msg_send_feature_set(struct iosm_imem *ipc_imem, unsigned int reset_enable, bool atomic_ctx) { union ipc_msg_prep_args prep_args = { .feature_set.reset_enable = reset_enable }; if (atomic_ctx) ipc_protocol_tq_msg_send(ipc_imem->ipc_protocol, IPC_MSG_PREP_FEATURE_SET, &prep_args, NULL); else ipc_protocol_msg_send(ipc_imem->ipc_protocol, IPC_MSG_PREP_FEATURE_SET, &prep_args); } void ipc_imem_td_update_timer_start(struct iosm_imem *ipc_imem) { /* Use the TD update timer only in the runtime phase */ if (!ipc_imem->enter_runtime || ipc_imem->td_update_timer_suspended) { /* trigger the doorbell irq on CP directly. */ ipc_protocol_doorbell_trigger(ipc_imem->ipc_protocol, IPC_HP_TD_UPD_TMR_START); return; } if (!hrtimer_active(&ipc_imem->tdupdate_timer)) { ipc_imem->hrtimer_period = ktime_set(0, TD_UPDATE_DEFAULT_TIMEOUT_USEC * 1000ULL); if (!hrtimer_active(&ipc_imem->tdupdate_timer)) hrtimer_start(&ipc_imem->tdupdate_timer, ipc_imem->hrtimer_period, HRTIMER_MODE_REL); } } void ipc_imem_hrtimer_stop(struct hrtimer *hr_timer) { if (hrtimer_active(hr_timer)) hrtimer_cancel(hr_timer); } bool ipc_imem_ul_write_td(struct iosm_imem *ipc_imem) { struct ipc_mem_channel *channel; struct sk_buff_head *ul_list; bool hpda_pending = false; bool forced_hpdu = false; struct ipc_pipe *pipe; int i; /* Analyze the uplink pipe of all active channels. */ for (i = 0; i < ipc_imem->nr_of_channels; i++) { channel = &ipc_imem->channels[i]; if (channel->state != IMEM_CHANNEL_ACTIVE) continue; pipe = &channel->ul_pipe; /* Get the reference to the skbuf accumulator list. */ ul_list = &channel->ul_list; /* Fill the transfer descriptor with the uplink buffer info. */ hpda_pending |= ipc_protocol_ul_td_send(ipc_imem->ipc_protocol, pipe, ul_list); /* forced HP update needed for non data channels */ if (hpda_pending && !ipc_imem_check_wwan_ips(channel)) forced_hpdu = true; } if (forced_hpdu) { hpda_pending = false; ipc_protocol_doorbell_trigger(ipc_imem->ipc_protocol, IPC_HP_UL_WRITE_TD); } return hpda_pending; } void ipc_imem_ipc_init_check(struct iosm_imem *ipc_imem) { int timeout = IPC_MODEM_BOOT_TIMEOUT; ipc_imem->ipc_requested_state = IPC_MEM_DEVICE_IPC_INIT; /* Trigger the CP interrupt to enter the init state. */ ipc_doorbell_fire(ipc_imem->pcie, IPC_DOORBELL_IRQ_IPC, IPC_MEM_DEVICE_IPC_INIT); /* Wait for the CP update. */ do { if (ipc_mmio_get_ipc_state(ipc_imem->mmio) == ipc_imem->ipc_requested_state) { /* Prepare the MMIO space */ ipc_mmio_config(ipc_imem->mmio); /* Trigger the CP irq to enter the running state. */ ipc_imem->ipc_requested_state = IPC_MEM_DEVICE_IPC_RUNNING; ipc_doorbell_fire(ipc_imem->pcie, IPC_DOORBELL_IRQ_IPC, IPC_MEM_DEVICE_IPC_RUNNING); return; } msleep(20); } while (--timeout); /* timeout */ dev_err(ipc_imem->dev, "%s: ipc_status(%d) ne. IPC_MEM_DEVICE_IPC_INIT", ipc_imem_phase_get_string(ipc_imem->phase), ipc_mmio_get_ipc_state(ipc_imem->mmio)); ipc_uevent_send(ipc_imem->dev, UEVENT_MDM_TIMEOUT); } /* Analyze the packet type and distribute it. */ static void ipc_imem_dl_skb_process(struct iosm_imem *ipc_imem, struct ipc_pipe *pipe, struct sk_buff *skb) { u16 port_id; if (!skb) return; /* An AT/control or IP packet is expected. */ switch (pipe->channel->ctype) { case IPC_CTYPE_CTRL: port_id = pipe->channel->channel_id; if (port_id == IPC_MEM_CTRL_CHL_ID_7) ipc_imem_sys_devlink_notify_rx(ipc_imem->ipc_devlink, skb); else wwan_port_rx(ipc_imem->ipc_port[port_id]->iosm_port, skb); break; case IPC_CTYPE_WWAN: if (pipe->channel->if_id == IPC_MEM_MUX_IP_CH_IF_ID) ipc_mux_dl_decode(ipc_imem->mux, skb); break; default: dev_err(ipc_imem->dev, "Invalid channel type"); break; } } /* Process the downlink data and pass them to the char or net layer. */ static void ipc_imem_dl_pipe_process(struct iosm_imem *ipc_imem, struct ipc_pipe *pipe) { s32 cnt = 0, processed_td_cnt = 0; struct ipc_mem_channel *channel; u32 head = 0, tail = 0; bool processed = false; struct sk_buff *skb; channel = pipe->channel; ipc_protocol_get_head_tail_index(ipc_imem->ipc_protocol, pipe, &head, &tail); if (pipe->old_tail != tail) { if (pipe->old_tail < tail) cnt = tail - pipe->old_tail; else cnt = pipe->nr_of_entries - pipe->old_tail + tail; } processed_td_cnt = cnt; /* Seek for pipes with pending DL data. */ while (cnt--) { skb = ipc_protocol_dl_td_process(ipc_imem->ipc_protocol, pipe); /* Analyze the packet type and distribute it. */ ipc_imem_dl_skb_process(ipc_imem, pipe, skb); } /* try to allocate new empty DL SKbs from head..tail - 1*/ while (ipc_imem_dl_skb_alloc(ipc_imem, pipe)) processed = true; if (processed && !ipc_imem_check_wwan_ips(channel)) { /* Force HP update for non IP channels */ ipc_protocol_doorbell_trigger(ipc_imem->ipc_protocol, IPC_HP_DL_PROCESS); processed = false; /* If Fast Update timer is already running then stop */ ipc_imem_hrtimer_stop(&ipc_imem->fast_update_timer); } /* Any control channel process will get immediate HP update. * Start Fast update timer only for IP channel if all the TDs were * used in last process. */ if (processed && (processed_td_cnt == pipe->nr_of_entries - 1)) { ipc_imem->hrtimer_period = ktime_set(0, FORCE_UPDATE_DEFAULT_TIMEOUT_USEC * 1000ULL); hrtimer_start(&ipc_imem->fast_update_timer, ipc_imem->hrtimer_period, HRTIMER_MODE_REL); } if (ipc_imem->app_notify_dl_pend) complete(&ipc_imem->dl_pend_sem); } /* process open uplink pipe */ static void ipc_imem_ul_pipe_process(struct iosm_imem *ipc_imem, struct ipc_pipe *pipe) { struct ipc_mem_channel *channel; u32 tail = 0, head = 0; struct sk_buff *skb; s32 cnt = 0; channel = pipe->channel; /* Get the internal phase. */ ipc_protocol_get_head_tail_index(ipc_imem->ipc_protocol, pipe, &head, &tail); if (pipe->old_tail != tail) { if (pipe->old_tail < tail) cnt = tail - pipe->old_tail; else cnt = pipe->nr_of_entries - pipe->old_tail + tail; } /* Free UL buffers. */ while (cnt--) { skb = ipc_protocol_ul_td_process(ipc_imem->ipc_protocol, pipe); if (!skb) continue; /* If the user app was suspended in uplink direction - blocking * write, resume it. */ if (IPC_CB(skb)->op_type == UL_USR_OP_BLOCKED) complete(&channel->ul_sem); /* Free the skbuf element. */ if (IPC_CB(skb)->op_type == UL_MUX_OP_ADB) { if (channel->if_id == IPC_MEM_MUX_IP_CH_IF_ID) ipc_mux_ul_encoded_process(ipc_imem->mux, skb); else dev_err(ipc_imem->dev, "OP Type is UL_MUX, unknown if_id %d", channel->if_id); } else { ipc_pcie_kfree_skb(ipc_imem->pcie, skb); } } /* Trace channel stats for IP UL pipe. */ if (ipc_imem_check_wwan_ips(pipe->channel)) ipc_mux_check_n_restart_tx(ipc_imem->mux); if (ipc_imem->app_notify_ul_pend) complete(&ipc_imem->ul_pend_sem); } /* Executes the irq. */ static void ipc_imem_rom_irq_exec(struct iosm_imem *ipc_imem) { struct ipc_mem_channel *channel; channel = ipc_imem->ipc_devlink->devlink_sio.channel; ipc_imem->rom_exit_code = ipc_mmio_get_rom_exit_code(ipc_imem->mmio); complete(&channel->ul_sem); } /* Execute the UL bundle timer actions, generating the doorbell irq. */ static int ipc_imem_tq_td_update_timer_cb(struct iosm_imem *ipc_imem, int arg, void *msg, size_t size) { ipc_protocol_doorbell_trigger(ipc_imem->ipc_protocol, IPC_HP_TD_UPD_TMR); return 0; } /* Consider link power management in the runtime phase. */ static void ipc_imem_slp_control_exec(struct iosm_imem *ipc_imem) { /* link will go down, Test pending UL packets.*/ if (ipc_protocol_pm_dev_sleep_handle(ipc_imem->ipc_protocol) && hrtimer_active(&ipc_imem->tdupdate_timer)) { /* Generate the doorbell irq. */ ipc_imem_tq_td_update_timer_cb(ipc_imem, 0, NULL, 0); /* Stop the TD update timer. */ ipc_imem_hrtimer_stop(&ipc_imem->tdupdate_timer); /* Stop the fast update timer. */ ipc_imem_hrtimer_stop(&ipc_imem->fast_update_timer); } } /* Execute startup timer and wait for delayed start (e.g. NAND) */ static int ipc_imem_tq_startup_timer_cb(struct iosm_imem *ipc_imem, int arg, void *msg, size_t size) { /* Update & check the current operation phase. */ if (ipc_imem_phase_update(ipc_imem) != IPC_P_RUN) return -EIO; if (ipc_mmio_get_ipc_state(ipc_imem->mmio) == IPC_MEM_DEVICE_IPC_UNINIT) { ipc_imem->ipc_requested_state = IPC_MEM_DEVICE_IPC_INIT; ipc_doorbell_fire(ipc_imem->pcie, IPC_DOORBELL_IRQ_IPC, IPC_MEM_DEVICE_IPC_INIT); ipc_imem->hrtimer_period = ktime_set(0, 100 * 1000UL * 1000ULL); /* reduce period to 100 ms to check for mmio init state */ if (!hrtimer_active(&ipc_imem->startup_timer)) hrtimer_start(&ipc_imem->startup_timer, ipc_imem->hrtimer_period, HRTIMER_MODE_REL); } else if (ipc_mmio_get_ipc_state(ipc_imem->mmio) == IPC_MEM_DEVICE_IPC_INIT) { /* Startup complete - disable timer */ ipc_imem_hrtimer_stop(&ipc_imem->startup_timer); /* Prepare the MMIO space */ ipc_mmio_config(ipc_imem->mmio); ipc_imem->ipc_requested_state = IPC_MEM_DEVICE_IPC_RUNNING; ipc_doorbell_fire(ipc_imem->pcie, IPC_DOORBELL_IRQ_IPC, IPC_MEM_DEVICE_IPC_RUNNING); } return 0; } static enum hrtimer_restart ipc_imem_startup_timer_cb(struct hrtimer *hr_timer) { enum hrtimer_restart result = HRTIMER_NORESTART; struct iosm_imem *ipc_imem = container_of(hr_timer, struct iosm_imem, startup_timer); if (ktime_to_ns(ipc_imem->hrtimer_period)) { hrtimer_forward_now(&ipc_imem->startup_timer, ipc_imem->hrtimer_period); result = HRTIMER_RESTART; } ipc_task_queue_send_task(ipc_imem, ipc_imem_tq_startup_timer_cb, 0, NULL, 0, false); return result; } /* Get the CP execution stage */ static enum ipc_mem_exec_stage ipc_imem_get_exec_stage_buffered(struct iosm_imem *ipc_imem) { return (ipc_imem->phase == IPC_P_RUN && ipc_imem->ipc_status == IPC_MEM_DEVICE_IPC_RUNNING) ? ipc_protocol_get_ap_exec_stage(ipc_imem->ipc_protocol) : ipc_mmio_get_exec_stage(ipc_imem->mmio); } /* Callback to send the modem ready uevent */ static int ipc_imem_send_mdm_rdy_cb(struct iosm_imem *ipc_imem, int arg, void *msg, size_t size) { enum ipc_mem_exec_stage exec_stage = ipc_imem_get_exec_stage_buffered(ipc_imem); if (exec_stage == IPC_MEM_EXEC_STAGE_RUN) ipc_uevent_send(ipc_imem->dev, UEVENT_MDM_READY); return 0; } /* This function is executed in a task context via an ipc_worker object, * as the creation or removal of device can't be done from tasklet. */ static void ipc_imem_run_state_worker(struct work_struct *instance) { struct ipc_chnl_cfg chnl_cfg_port = { 0 }; struct ipc_mux_config mux_cfg; struct iosm_imem *ipc_imem; u8 ctrl_chl_idx = 0; ipc_imem = container_of(instance, struct iosm_imem, run_state_worker); if (ipc_imem->phase != IPC_P_RUN) { dev_err(ipc_imem->dev, "Modem link down. Exit run state worker."); return; } if (!ipc_imem_setup_cp_mux_cap_init(ipc_imem, &mux_cfg)) ipc_imem->mux = ipc_mux_init(&mux_cfg, ipc_imem); ipc_imem_wwan_channel_init(ipc_imem, mux_cfg.protocol); if (ipc_imem->mux) ipc_imem->mux->wwan = ipc_imem->wwan; while (ctrl_chl_idx < IPC_MEM_MAX_CHANNELS) { if (!ipc_chnl_cfg_get(&chnl_cfg_port, ctrl_chl_idx)) { ipc_imem->ipc_port[ctrl_chl_idx] = NULL; if (chnl_cfg_port.wwan_port_type != WWAN_PORT_UNKNOWN) { ipc_imem_channel_init(ipc_imem, IPC_CTYPE_CTRL, chnl_cfg_port, IRQ_MOD_OFF); ipc_imem->ipc_port[ctrl_chl_idx] = ipc_port_init(ipc_imem, chnl_cfg_port); } } ctrl_chl_idx++; } ipc_task_queue_send_task(ipc_imem, ipc_imem_send_mdm_rdy_cb, 0, NULL, 0, false); /* Complete all memory stores before setting bit */ smp_mb__before_atomic(); set_bit(FULLY_FUNCTIONAL, &ipc_imem->flag); /* Complete all memory stores after setting bit */ smp_mb__after_atomic(); } static void ipc_imem_handle_irq(struct iosm_imem *ipc_imem, int irq) { enum ipc_mem_device_ipc_state curr_ipc_status; enum ipc_phase old_phase, phase; bool retry_allocation = false; bool ul_pending = false; int i; if (irq != IMEM_IRQ_DONT_CARE) ipc_imem->ev_irq_pending[irq] = false; /* Get the internal phase. */ old_phase = ipc_imem->phase; if (old_phase == IPC_P_OFF_REQ) { dev_dbg(ipc_imem->dev, "[%s]: Ignoring MSI. Deinit sequence in progress!", ipc_imem_phase_get_string(old_phase)); return; } /* Update the phase controlled by CP. */ phase = ipc_imem_phase_update(ipc_imem); switch (phase) { case IPC_P_RUN: if (!ipc_imem->enter_runtime) { /* Excute the transition from flash/boot to runtime. */ ipc_imem->enter_runtime = 1; /* allow device to sleep, default value is * IPC_HOST_SLEEP_ENTER_SLEEP */ ipc_imem_msg_send_device_sleep(ipc_imem, ipc_imem->device_sleep); ipc_imem_msg_send_feature_set(ipc_imem, IPC_MEM_INBAND_CRASH_SIG, true); } curr_ipc_status = ipc_protocol_get_ipc_status(ipc_imem->ipc_protocol); /* check ipc_status change */ if (ipc_imem->ipc_status != curr_ipc_status) { ipc_imem->ipc_status = curr_ipc_status; if (ipc_imem->ipc_status == IPC_MEM_DEVICE_IPC_RUNNING) { schedule_work(&ipc_imem->run_state_worker); } } /* Consider power management in the runtime phase. */ ipc_imem_slp_control_exec(ipc_imem); break; /* Continue with skbuf processing. */ /* Unexpected phases. */ case IPC_P_OFF: case IPC_P_OFF_REQ: dev_err(ipc_imem->dev, "confused phase %s", ipc_imem_phase_get_string(phase)); return; case IPC_P_PSI: if (old_phase != IPC_P_ROM) break; fallthrough; /* On CP the PSI phase is already active. */ case IPC_P_ROM: /* Before CP ROM driver starts the PSI image, it sets * the exit_code field on the doorbell scratchpad and * triggers the irq. */ ipc_imem_rom_irq_exec(ipc_imem); return; default: break; } /* process message ring */ ipc_protocol_msg_process(ipc_imem, irq); /* process all open pipes */ for (i = 0; i < IPC_MEM_MAX_CHANNELS; i++) { struct ipc_pipe *ul_pipe = &ipc_imem->channels[i].ul_pipe; struct ipc_pipe *dl_pipe = &ipc_imem->channels[i].dl_pipe; if (dl_pipe->is_open && (irq == IMEM_IRQ_DONT_CARE || irq == dl_pipe->irq)) { ipc_imem_dl_pipe_process(ipc_imem, dl_pipe); if (dl_pipe->nr_of_queued_entries == 0) retry_allocation = true; } if (ul_pipe->is_open) ipc_imem_ul_pipe_process(ipc_imem, ul_pipe); } /* Try to generate new ADB or ADGH. */ if (ipc_mux_ul_data_encode(ipc_imem->mux)) ipc_imem_td_update_timer_start(ipc_imem); /* Continue the send procedure with accumulated SIO or NETIF packets. * Reset the debounce flags. */ ul_pending |= ipc_imem_ul_write_td(ipc_imem); /* if UL data is pending restart TD update timer */ if (ul_pending) { ipc_imem->hrtimer_period = ktime_set(0, TD_UPDATE_DEFAULT_TIMEOUT_USEC * 1000ULL); if (!hrtimer_active(&ipc_imem->tdupdate_timer)) hrtimer_start(&ipc_imem->tdupdate_timer, ipc_imem->hrtimer_period, HRTIMER_MODE_REL); } /* If CP has executed the transition * from IPC_INIT to IPC_RUNNING in the PSI * phase, wake up the flash app to open the pipes. */ if ((phase == IPC_P_PSI || phase == IPC_P_EBL) && ipc_imem->ipc_requested_state == IPC_MEM_DEVICE_IPC_RUNNING && ipc_mmio_get_ipc_state(ipc_imem->mmio) == IPC_MEM_DEVICE_IPC_RUNNING) { complete(&ipc_imem->ipc_devlink->devlink_sio.channel->ul_sem); } /* Reset the expected CP state. */ ipc_imem->ipc_requested_state = IPC_MEM_DEVICE_IPC_DONT_CARE; if (retry_allocation) { ipc_imem->hrtimer_period = ktime_set(0, IPC_TD_ALLOC_TIMER_PERIOD_MS * 1000 * 1000ULL); if (!hrtimer_active(&ipc_imem->td_alloc_timer)) hrtimer_start(&ipc_imem->td_alloc_timer, ipc_imem->hrtimer_period, HRTIMER_MODE_REL); } } /* Callback by tasklet for handling interrupt events. */ static int ipc_imem_tq_irq_cb(struct iosm_imem *ipc_imem, int arg, void *msg, size_t size) { ipc_imem_handle_irq(ipc_imem, arg); return 0; } void ipc_imem_ul_send(struct iosm_imem *ipc_imem) { /* start doorbell irq delay timer if UL is pending */ if (ipc_imem_ul_write_td(ipc_imem)) ipc_imem_td_update_timer_start(ipc_imem); } /* Check the execution stage and update the AP phase */ static enum ipc_phase ipc_imem_phase_update_check(struct iosm_imem *ipc_imem, enum ipc_mem_exec_stage stage) { switch (stage) { case IPC_MEM_EXEC_STAGE_BOOT: if (ipc_imem->phase != IPC_P_ROM) { /* Send this event only once */ ipc_uevent_send(ipc_imem->dev, UEVENT_ROM_READY); } ipc_imem->phase = IPC_P_ROM; break; case IPC_MEM_EXEC_STAGE_PSI: ipc_imem->phase = IPC_P_PSI; break; case IPC_MEM_EXEC_STAGE_EBL: ipc_imem->phase = IPC_P_EBL; break; case IPC_MEM_EXEC_STAGE_RUN: if (ipc_imem->phase != IPC_P_RUN && ipc_imem->ipc_status == IPC_MEM_DEVICE_IPC_RUNNING) { ipc_uevent_send(ipc_imem->dev, UEVENT_MDM_READY); } ipc_imem->phase = IPC_P_RUN; break; case IPC_MEM_EXEC_STAGE_CRASH: if (ipc_imem->phase != IPC_P_CRASH) ipc_uevent_send(ipc_imem->dev, UEVENT_CRASH); ipc_imem->phase = IPC_P_CRASH; break; case IPC_MEM_EXEC_STAGE_CD_READY: if (ipc_imem->phase != IPC_P_CD_READY) ipc_uevent_send(ipc_imem->dev, UEVENT_CD_READY); ipc_imem->phase = IPC_P_CD_READY; break; default: /* unknown exec stage: * assume that link is down and send info to listeners */ ipc_uevent_send(ipc_imem->dev, UEVENT_CD_READY_LINK_DOWN); break; } return ipc_imem->phase; } /* Send msg to device to open pipe */ static bool ipc_imem_pipe_open(struct iosm_imem *ipc_imem, struct ipc_pipe *pipe) { union ipc_msg_prep_args prep_args = { .pipe_open.pipe = pipe, }; if (ipc_protocol_msg_send(ipc_imem->ipc_protocol, IPC_MSG_PREP_PIPE_OPEN, &prep_args) == 0) pipe->is_open = true; return pipe->is_open; } /* Allocates the TDs for the given pipe along with firing HP update DB. */ static int ipc_imem_tq_pipe_td_alloc(struct iosm_imem *ipc_imem, int arg, void *msg, size_t size) { struct ipc_pipe *dl_pipe = msg; bool processed = false; int i; for (i = 0; i < dl_pipe->nr_of_entries - 1; i++) processed |= ipc_imem_dl_skb_alloc(ipc_imem, dl_pipe); /* Trigger the doorbell irq to inform CP that new downlink buffers are * available. */ if (processed) ipc_protocol_doorbell_trigger(ipc_imem->ipc_protocol, arg); return 0; } static enum hrtimer_restart ipc_imem_td_update_timer_cb(struct hrtimer *hr_timer) { struct iosm_imem *ipc_imem = container_of(hr_timer, struct iosm_imem, tdupdate_timer); ipc_task_queue_send_task(ipc_imem, ipc_imem_tq_td_update_timer_cb, 0, NULL, 0, false); return HRTIMER_NORESTART; } /* Get the CP execution state and map it to the AP phase. */ enum ipc_phase ipc_imem_phase_update(struct iosm_imem *ipc_imem) { enum ipc_mem_exec_stage exec_stage = ipc_imem_get_exec_stage_buffered(ipc_imem); /* If the CP stage is undef, return the internal precalculated phase. */ return ipc_imem->phase == IPC_P_OFF_REQ ? ipc_imem->phase : ipc_imem_phase_update_check(ipc_imem, exec_stage); } const char *ipc_imem_phase_get_string(enum ipc_phase phase) { switch (phase) { case IPC_P_RUN: return "A-RUN"; case IPC_P_OFF: return "A-OFF"; case IPC_P_ROM: return "A-ROM"; case IPC_P_PSI: return "A-PSI"; case IPC_P_EBL: return "A-EBL"; case IPC_P_CRASH: return "A-CRASH"; case IPC_P_CD_READY: return "A-CD_READY"; case IPC_P_OFF_REQ: return "A-OFF_REQ"; default: return "A-???"; } } void ipc_imem_pipe_close(struct iosm_imem *ipc_imem, struct ipc_pipe *pipe) { union ipc_msg_prep_args prep_args = { .pipe_close.pipe = pipe }; pipe->is_open = false; ipc_protocol_msg_send(ipc_imem->ipc_protocol, IPC_MSG_PREP_PIPE_CLOSE, &prep_args); ipc_imem_pipe_cleanup(ipc_imem, pipe); } void ipc_imem_channel_close(struct iosm_imem *ipc_imem, int channel_id) { struct ipc_mem_channel *channel; if (channel_id < 0 || channel_id >= ipc_imem->nr_of_channels) { dev_err(ipc_imem->dev, "invalid channel id %d", channel_id); return; } channel = &ipc_imem->channels[channel_id]; if (channel->state == IMEM_CHANNEL_FREE) { dev_err(ipc_imem->dev, "ch[%d]: invalid channel state %d", channel_id, channel->state); return; } /* Free only the channel id in the CP power off mode. */ if (channel->state == IMEM_CHANNEL_RESERVED) /* Release only the channel id. */ goto channel_free; if (ipc_imem->phase == IPC_P_RUN) { ipc_imem_pipe_close(ipc_imem, &channel->ul_pipe); ipc_imem_pipe_close(ipc_imem, &channel->dl_pipe); } ipc_imem_pipe_cleanup(ipc_imem, &channel->ul_pipe); ipc_imem_pipe_cleanup(ipc_imem, &channel->dl_pipe); channel_free: ipc_imem_channel_free(channel); } struct ipc_mem_channel *ipc_imem_channel_open(struct iosm_imem *ipc_imem, int channel_id, u32 db_id) { struct ipc_mem_channel *channel; if (channel_id < 0 || channel_id >= IPC_MEM_MAX_CHANNELS) { dev_err(ipc_imem->dev, "invalid channel ID: %d", channel_id); return NULL; } channel = &ipc_imem->channels[channel_id]; channel->state = IMEM_CHANNEL_ACTIVE; if (!ipc_imem_pipe_open(ipc_imem, &channel->ul_pipe)) goto ul_pipe_err; if (!ipc_imem_pipe_open(ipc_imem, &channel->dl_pipe)) goto dl_pipe_err; /* Allocate the downlink buffers in tasklet context. */ if (ipc_task_queue_send_task(ipc_imem, ipc_imem_tq_pipe_td_alloc, db_id, &channel->dl_pipe, 0, false)) { dev_err(ipc_imem->dev, "td allocation failed : %d", channel_id); goto task_failed; } /* Active channel. */ return channel; task_failed: ipc_imem_pipe_close(ipc_imem, &channel->dl_pipe); dl_pipe_err: ipc_imem_pipe_close(ipc_imem, &channel->ul_pipe); ul_pipe_err: ipc_imem_channel_free(channel); return NULL; } void ipc_imem_pm_suspend(struct iosm_imem *ipc_imem) { ipc_protocol_suspend(ipc_imem->ipc_protocol); } void ipc_imem_pm_s2idle_sleep(struct iosm_imem *ipc_imem, bool sleep) { ipc_protocol_s2idle_sleep(ipc_imem->ipc_protocol, sleep); } void ipc_imem_pm_resume(struct iosm_imem *ipc_imem) { enum ipc_mem_exec_stage stage; if (ipc_protocol_resume(ipc_imem->ipc_protocol)) { stage = ipc_mmio_get_exec_stage(ipc_imem->mmio); ipc_imem_phase_update_check(ipc_imem, stage); } } void ipc_imem_channel_free(struct ipc_mem_channel *channel) { /* Reset dynamic channel elements. */ channel->state = IMEM_CHANNEL_FREE; } int ipc_imem_channel_alloc(struct iosm_imem *ipc_imem, int index, enum ipc_ctype ctype) { struct ipc_mem_channel *channel; int i; /* Find channel of given type/index */ for (i = 0; i < ipc_imem->nr_of_channels; i++) { channel = &ipc_imem->channels[i]; if (channel->ctype == ctype && channel->index == index) break; } if (i >= ipc_imem->nr_of_channels) { dev_dbg(ipc_imem->dev, "no channel definition for index=%d ctype=%d", index, ctype); return -ECHRNG; } if (ipc_imem->channels[i].state != IMEM_CHANNEL_FREE) { dev_dbg(ipc_imem->dev, "channel is in use"); return -EBUSY; } if (channel->ctype == IPC_CTYPE_WWAN && index == IPC_MEM_MUX_IP_CH_IF_ID) channel->if_id = index; channel->channel_id = index; channel->state = IMEM_CHANNEL_RESERVED; return i; } void ipc_imem_channel_init(struct iosm_imem *ipc_imem, enum ipc_ctype ctype, struct ipc_chnl_cfg chnl_cfg, u32 irq_moderation) { struct ipc_mem_channel *channel; if (chnl_cfg.ul_pipe >= IPC_MEM_MAX_PIPES || chnl_cfg.dl_pipe >= IPC_MEM_MAX_PIPES) { dev_err(ipc_imem->dev, "invalid pipe: ul_pipe=%d, dl_pipe=%d", chnl_cfg.ul_pipe, chnl_cfg.dl_pipe); return; } if (ipc_imem->nr_of_channels >= IPC_MEM_MAX_CHANNELS) { dev_err(ipc_imem->dev, "too many channels"); return; } channel = &ipc_imem->channels[ipc_imem->nr_of_channels]; channel->channel_id = ipc_imem->nr_of_channels; channel->ctype = ctype; channel->index = chnl_cfg.id; channel->net_err_count = 0; channel->state = IMEM_CHANNEL_FREE; ipc_imem->nr_of_channels++; ipc_imem_channel_update(ipc_imem, channel->channel_id, chnl_cfg, IRQ_MOD_OFF); skb_queue_head_init(&channel->ul_list); init_completion(&channel->ul_sem); } void ipc_imem_channel_update(struct iosm_imem *ipc_imem, int id, struct ipc_chnl_cfg chnl_cfg, u32 irq_moderation) { struct ipc_mem_channel *channel; if (id < 0 || id >= ipc_imem->nr_of_channels) { dev_err(ipc_imem->dev, "invalid channel id %d", id); return; } channel = &ipc_imem->channels[id]; if (channel->state != IMEM_CHANNEL_FREE && channel->state != IMEM_CHANNEL_RESERVED) { dev_err(ipc_imem->dev, "invalid channel state %d", channel->state); return; } channel->ul_pipe.nr_of_entries = chnl_cfg.ul_nr_of_entries; channel->ul_pipe.pipe_nr = chnl_cfg.ul_pipe; channel->ul_pipe.is_open = false; channel->ul_pipe.irq = IPC_UL_PIPE_IRQ_VECTOR; channel->ul_pipe.channel = channel; channel->ul_pipe.dir = IPC_MEM_DIR_UL; channel->ul_pipe.accumulation_backoff = chnl_cfg.accumulation_backoff; channel->ul_pipe.irq_moderation = irq_moderation; channel->ul_pipe.buf_size = 0; channel->dl_pipe.nr_of_entries = chnl_cfg.dl_nr_of_entries; channel->dl_pipe.pipe_nr = chnl_cfg.dl_pipe; channel->dl_pipe.is_open = false; channel->dl_pipe.irq = IPC_DL_PIPE_IRQ_VECTOR; channel->dl_pipe.channel = channel; channel->dl_pipe.dir = IPC_MEM_DIR_DL; channel->dl_pipe.accumulation_backoff = chnl_cfg.accumulation_backoff; channel->dl_pipe.irq_moderation = irq_moderation; channel->dl_pipe.buf_size = chnl_cfg.dl_buf_size; } static void ipc_imem_channel_reset(struct iosm_imem *ipc_imem) { int i; for (i = 0; i < ipc_imem->nr_of_channels; i++) { struct ipc_mem_channel *channel; channel = &ipc_imem->channels[i]; ipc_imem_pipe_cleanup(ipc_imem, &channel->dl_pipe); ipc_imem_pipe_cleanup(ipc_imem, &channel->ul_pipe); ipc_imem_channel_free(channel); } } void ipc_imem_pipe_cleanup(struct iosm_imem *ipc_imem, struct ipc_pipe *pipe) { struct sk_buff *skb; /* Force pipe to closed state also when not explicitly closed through * ipc_imem_pipe_close() */ pipe->is_open = false; /* Empty the uplink skb accumulator. */ while ((skb = skb_dequeue(&pipe->channel->ul_list))) ipc_pcie_kfree_skb(ipc_imem->pcie, skb); ipc_protocol_pipe_cleanup(ipc_imem->ipc_protocol, pipe); } /* Send IPC protocol uninit to the modem when Link is active. */ static void ipc_imem_device_ipc_uninit(struct iosm_imem *ipc_imem) { int timeout = IPC_MODEM_UNINIT_TIMEOUT_MS; enum ipc_mem_device_ipc_state ipc_state; /* When PCIe link is up set IPC_UNINIT * of the modem otherwise ignore it when PCIe link down happens. */ if (ipc_pcie_check_data_link_active(ipc_imem->pcie)) { /* set modem to UNINIT * (in case we want to reload the AP driver without resetting * the modem) */ ipc_doorbell_fire(ipc_imem->pcie, IPC_DOORBELL_IRQ_IPC, IPC_MEM_DEVICE_IPC_UNINIT); ipc_state = ipc_mmio_get_ipc_state(ipc_imem->mmio); /* Wait for maximum 30ms to allow the Modem to uninitialize the * protocol. */ while ((ipc_state <= IPC_MEM_DEVICE_IPC_DONT_CARE) && (ipc_state != IPC_MEM_DEVICE_IPC_UNINIT) && (timeout > 0)) { usleep_range(1000, 1250); timeout--; ipc_state = ipc_mmio_get_ipc_state(ipc_imem->mmio); } } } void ipc_imem_cleanup(struct iosm_imem *ipc_imem) { ipc_imem->phase = IPC_P_OFF_REQ; /* forward MDM_NOT_READY to listeners */ ipc_uevent_send(ipc_imem->dev, UEVENT_MDM_NOT_READY); hrtimer_cancel(&ipc_imem->td_alloc_timer); hrtimer_cancel(&ipc_imem->tdupdate_timer); hrtimer_cancel(&ipc_imem->fast_update_timer); hrtimer_cancel(&ipc_imem->startup_timer); /* cancel the workqueue */ cancel_work_sync(&ipc_imem->run_state_worker); if (test_and_clear_bit(FULLY_FUNCTIONAL, &ipc_imem->flag)) { ipc_mux_deinit(ipc_imem->mux); ipc_wwan_deinit(ipc_imem->wwan); ipc_port_deinit(ipc_imem->ipc_port); } if (ipc_imem->ipc_devlink) ipc_devlink_deinit(ipc_imem->ipc_devlink); ipc_imem_device_ipc_uninit(ipc_imem); ipc_imem_channel_reset(ipc_imem); ipc_protocol_deinit(ipc_imem->ipc_protocol); ipc_task_deinit(ipc_imem->ipc_task); kfree(ipc_imem->ipc_task); kfree(ipc_imem->mmio); ipc_imem->phase = IPC_P_OFF; } /* After CP has unblocked the PCIe link, save the start address of the doorbell * scratchpad and prepare the shared memory region. If the flashing to RAM * procedure shall be executed, copy the chip information from the doorbell * scratchtpad to the application buffer and wake up the flash app. */ static int ipc_imem_config(struct iosm_imem *ipc_imem) { enum ipc_phase phase; /* Initialize the semaphore for the blocking read UL/DL transfer. */ init_completion(&ipc_imem->ul_pend_sem); init_completion(&ipc_imem->dl_pend_sem); /* clear internal flags */ ipc_imem->ipc_status = IPC_MEM_DEVICE_IPC_UNINIT; ipc_imem->enter_runtime = 0; phase = ipc_imem_phase_update(ipc_imem); /* Either CP shall be in the power off or power on phase. */ switch (phase) { case IPC_P_ROM: ipc_imem->hrtimer_period = ktime_set(0, 1000 * 1000 * 1000ULL); /* poll execution stage (for delayed start, e.g. NAND) */ if (!hrtimer_active(&ipc_imem->startup_timer)) hrtimer_start(&ipc_imem->startup_timer, ipc_imem->hrtimer_period, HRTIMER_MODE_REL); return 0; case IPC_P_PSI: case IPC_P_EBL: case IPC_P_RUN: /* The initial IPC state is IPC_MEM_DEVICE_IPC_UNINIT. */ ipc_imem->ipc_requested_state = IPC_MEM_DEVICE_IPC_UNINIT; /* Verify the exepected initial state. */ if (ipc_imem->ipc_requested_state == ipc_mmio_get_ipc_state(ipc_imem->mmio)) { ipc_imem_ipc_init_check(ipc_imem); return 0; } dev_err(ipc_imem->dev, "ipc_status(%d) != IPC_MEM_DEVICE_IPC_UNINIT", ipc_mmio_get_ipc_state(ipc_imem->mmio)); break; case IPC_P_CRASH: case IPC_P_CD_READY: dev_dbg(ipc_imem->dev, "Modem is in phase %d, reset Modem to collect CD", phase); return 0; default: dev_err(ipc_imem->dev, "unexpected operation phase %d", phase); break; } complete(&ipc_imem->dl_pend_sem); complete(&ipc_imem->ul_pend_sem); ipc_imem->phase = IPC_P_OFF; return -EIO; } /* Pass the dev ptr to the shared memory driver and request the entry points */ struct iosm_imem *ipc_imem_init(struct iosm_pcie *pcie, unsigned int device_id, void __iomem *mmio, struct device *dev) { struct iosm_imem *ipc_imem = kzalloc(sizeof(*pcie->imem), GFP_KERNEL); enum ipc_mem_exec_stage stage; if (!ipc_imem) return NULL; /* Save the device address. */ ipc_imem->pcie = pcie; ipc_imem->dev = dev; ipc_imem->pci_device_id = device_id; ipc_imem->ev_cdev_write_pending = false; ipc_imem->cp_version = 0; ipc_imem->device_sleep = IPC_HOST_SLEEP_ENTER_SLEEP; /* Reset the max number of configured channels */ ipc_imem->nr_of_channels = 0; /* allocate IPC MMIO */ ipc_imem->mmio = ipc_mmio_init(mmio, ipc_imem->dev); if (!ipc_imem->mmio) { dev_err(ipc_imem->dev, "failed to initialize mmio region"); goto mmio_init_fail; } ipc_imem->ipc_task = kzalloc(sizeof(*ipc_imem->ipc_task), GFP_KERNEL); /* Create tasklet for event handling*/ if (!ipc_imem->ipc_task) goto ipc_task_fail; if (ipc_task_init(ipc_imem->ipc_task)) goto ipc_task_init_fail; ipc_imem->ipc_task->dev = ipc_imem->dev; INIT_WORK(&ipc_imem->run_state_worker, ipc_imem_run_state_worker); ipc_imem->ipc_protocol = ipc_protocol_init(ipc_imem); if (!ipc_imem->ipc_protocol) goto protocol_init_fail; /* The phase is set to power off. */ ipc_imem->phase = IPC_P_OFF; hrtimer_init(&ipc_imem->startup_timer, CLOCK_MONOTONIC, HRTIMER_MODE_REL); ipc_imem->startup_timer.function = ipc_imem_startup_timer_cb; hrtimer_init(&ipc_imem->tdupdate_timer, CLOCK_MONOTONIC, HRTIMER_MODE_REL); ipc_imem->tdupdate_timer.function = ipc_imem_td_update_timer_cb; hrtimer_init(&ipc_imem->fast_update_timer, CLOCK_MONOTONIC, HRTIMER_MODE_REL); ipc_imem->fast_update_timer.function = ipc_imem_fast_update_timer_cb; hrtimer_init(&ipc_imem->td_alloc_timer, CLOCK_MONOTONIC, HRTIMER_MODE_REL); ipc_imem->td_alloc_timer.function = ipc_imem_td_alloc_timer_cb; if (ipc_imem_config(ipc_imem)) { dev_err(ipc_imem->dev, "failed to initialize the imem"); goto imem_config_fail; } stage = ipc_mmio_get_exec_stage(ipc_imem->mmio); if (stage == IPC_MEM_EXEC_STAGE_BOOT) { /* Alloc and Register devlink */ ipc_imem->ipc_devlink = ipc_devlink_init(ipc_imem); if (!ipc_imem->ipc_devlink) { dev_err(ipc_imem->dev, "Devlink register failed"); goto imem_config_fail; } if (ipc_flash_link_establish(ipc_imem)) goto devlink_channel_fail; } return ipc_imem; devlink_channel_fail: ipc_devlink_deinit(ipc_imem->ipc_devlink); imem_config_fail: hrtimer_cancel(&ipc_imem->td_alloc_timer); hrtimer_cancel(&ipc_imem->fast_update_timer); hrtimer_cancel(&ipc_imem->tdupdate_timer); hrtimer_cancel(&ipc_imem->startup_timer); protocol_init_fail: cancel_work_sync(&ipc_imem->run_state_worker); ipc_task_deinit(ipc_imem->ipc_task); ipc_task_init_fail: kfree(ipc_imem->ipc_task); ipc_task_fail: kfree(ipc_imem->mmio); mmio_init_fail: kfree(ipc_imem); return NULL; } void ipc_imem_irq_process(struct iosm_imem *ipc_imem, int irq) { /* Debounce IPC_EV_IRQ. */ if (ipc_imem && !ipc_imem->ev_irq_pending[irq]) { ipc_imem->ev_irq_pending[irq] = true; ipc_task_queue_send_task(ipc_imem, ipc_imem_tq_irq_cb, irq, NULL, 0, false); } } void ipc_imem_td_update_timer_suspend(struct iosm_imem *ipc_imem, bool suspend) { ipc_imem->td_update_timer_suspended = suspend; } /* Verify the CP execution state, copy the chip info, * change the execution phase to ROM */ static int ipc_imem_devlink_trigger_chip_info_cb(struct iosm_imem *ipc_imem, int arg, void *msg, size_t msgsize) { enum ipc_mem_exec_stage stage; struct sk_buff *skb; int rc = -EINVAL; size_t size; /* Test the CP execution state. */ stage = ipc_mmio_get_exec_stage(ipc_imem->mmio); if (stage != IPC_MEM_EXEC_STAGE_BOOT) { dev_err(ipc_imem->dev, "Execution_stage: expected BOOT, received = %X", stage); goto trigger_chip_info_fail; } /* Allocate a new sk buf for the chip info. */ size = ipc_imem->mmio->chip_info_size; if (size > IOSM_CHIP_INFO_SIZE_MAX) goto trigger_chip_info_fail; skb = ipc_pcie_alloc_local_skb(ipc_imem->pcie, GFP_ATOMIC, size); if (!skb) { dev_err(ipc_imem->dev, "exhausted skbuf kernel DL memory"); rc = -ENOMEM; goto trigger_chip_info_fail; } /* Copy the chip info characters into the ipc_skb. */ ipc_mmio_copy_chip_info(ipc_imem->mmio, skb_put(skb, size), size); /* First change to the ROM boot phase. */ dev_dbg(ipc_imem->dev, "execution_stage[%X] eq. BOOT", stage); ipc_imem->phase = ipc_imem_phase_update(ipc_imem); ipc_imem_sys_devlink_notify_rx(ipc_imem->ipc_devlink, skb); rc = 0; trigger_chip_info_fail: return rc; } int ipc_imem_devlink_trigger_chip_info(struct iosm_imem *ipc_imem) { return ipc_task_queue_send_task(ipc_imem, ipc_imem_devlink_trigger_chip_info_cb, 0, NULL, 0, true); }