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2222 2223 2224 2225 2226 2227 2228 2229 2230 2231 2232 2233 2234 2235 2236 2237 2238 2239 2240 2241 2242 2243 2244 2245 2246 2247 2248 2249 2250 2251 2252 2253 2254 2255 2256 2257 2258 2259 2260 2261 2262 2263 2264 2265 2266 2267 2268 2269 2270 2271 2272 2273 2274 2275 2276 2277 2278 2279 2280 2281 2282 2283 2284 2285 2286 2287 2288 | // SPDX-License-Identifier: GPL-2.0-only /* * cec-adap.c - HDMI Consumer Electronics Control framework - CEC adapter * * Copyright 2016 Cisco Systems, Inc. and/or its affiliates. All rights reserved. */ #include <linux/errno.h> #include <linux/init.h> #include <linux/module.h> #include <linux/kernel.h> #include <linux/kmod.h> #include <linux/ktime.h> #include <linux/slab.h> #include <linux/mm.h> #include <linux/string.h> #include <linux/types.h> #include <drm/drm_connector.h> #include <drm/drm_device.h> #include <drm/drm_edid.h> #include <drm/drm_file.h> #include "cec-priv.h" static void cec_fill_msg_report_features(struct cec_adapter *adap, struct cec_msg *msg, unsigned int la_idx); static int cec_log_addr2idx(const struct cec_adapter *adap, u8 log_addr) { int i; for (i = 0; i < adap->log_addrs.num_log_addrs; i++) if (adap->log_addrs.log_addr[i] == log_addr) return i; return -1; } static unsigned int cec_log_addr2dev(const struct cec_adapter *adap, u8 log_addr) { int i = cec_log_addr2idx(adap, log_addr); return adap->log_addrs.primary_device_type[i < 0 ? 0 : i]; } u16 cec_get_edid_phys_addr(const u8 *edid, unsigned int size, unsigned int *offset) { unsigned int loc = cec_get_edid_spa_location(edid, size); if (offset) *offset = loc; if (loc == 0) return CEC_PHYS_ADDR_INVALID; return (edid[loc] << 8) | edid[loc + 1]; } EXPORT_SYMBOL_GPL(cec_get_edid_phys_addr); void cec_fill_conn_info_from_drm(struct cec_connector_info *conn_info, const struct drm_connector *connector) { memset(conn_info, 0, sizeof(*conn_info)); conn_info->type = CEC_CONNECTOR_TYPE_DRM; conn_info->drm.card_no = connector->dev->primary->index; conn_info->drm.connector_id = connector->base.id; } EXPORT_SYMBOL_GPL(cec_fill_conn_info_from_drm); /* * Queue a new event for this filehandle. If ts == 0, then set it * to the current time. * * We keep a queue of at most max_event events where max_event differs * per event. If the queue becomes full, then drop the oldest event and * keep track of how many events we've dropped. */ void cec_queue_event_fh(struct cec_fh *fh, const struct cec_event *new_ev, u64 ts) { static const u16 max_events[CEC_NUM_EVENTS] = { 1, 1, 800, 800, 8, 8, 8, 8 }; struct cec_event_entry *entry; unsigned int ev_idx = new_ev->event - 1; if (WARN_ON(ev_idx >= ARRAY_SIZE(fh->events))) return; if (ts == 0) ts = ktime_get_ns(); mutex_lock(&fh->lock); if (ev_idx < CEC_NUM_CORE_EVENTS) entry = &fh->core_events[ev_idx]; else entry = kmalloc(sizeof(*entry), GFP_KERNEL); if (entry) { if (new_ev->event == CEC_EVENT_LOST_MSGS && fh->queued_events[ev_idx]) { entry->ev.lost_msgs.lost_msgs += new_ev->lost_msgs.lost_msgs; goto unlock; } entry->ev = *new_ev; entry->ev.ts = ts; if (fh->queued_events[ev_idx] < max_events[ev_idx]) { /* Add new msg at the end of the queue */ list_add_tail(&entry->list, &fh->events[ev_idx]); fh->queued_events[ev_idx]++; fh->total_queued_events++; goto unlock; } if (ev_idx >= CEC_NUM_CORE_EVENTS) { list_add_tail(&entry->list, &fh->events[ev_idx]); /* drop the oldest event */ entry = list_first_entry(&fh->events[ev_idx], struct cec_event_entry, list); list_del(&entry->list); kfree(entry); } } /* Mark that events were lost */ entry = list_first_entry_or_null(&fh->events[ev_idx], struct cec_event_entry, list); if (entry) entry->ev.flags |= CEC_EVENT_FL_DROPPED_EVENTS; unlock: mutex_unlock(&fh->lock); wake_up_interruptible(&fh->wait); } /* Queue a new event for all open filehandles. */ static void cec_queue_event(struct cec_adapter *adap, const struct cec_event *ev) { u64 ts = ktime_get_ns(); struct cec_fh *fh; mutex_lock(&adap->devnode.lock_fhs); list_for_each_entry(fh, &adap->devnode.fhs, list) cec_queue_event_fh(fh, ev, ts); mutex_unlock(&adap->devnode.lock_fhs); } /* Notify userspace that the CEC pin changed state at the given time. */ void cec_queue_pin_cec_event(struct cec_adapter *adap, bool is_high, bool dropped_events, ktime_t ts) { struct cec_event ev = { .event = is_high ? CEC_EVENT_PIN_CEC_HIGH : CEC_EVENT_PIN_CEC_LOW, .flags = dropped_events ? CEC_EVENT_FL_DROPPED_EVENTS : 0, }; struct cec_fh *fh; mutex_lock(&adap->devnode.lock_fhs); list_for_each_entry(fh, &adap->devnode.fhs, list) { if (fh->mode_follower == CEC_MODE_MONITOR_PIN) cec_queue_event_fh(fh, &ev, ktime_to_ns(ts)); } mutex_unlock(&adap->devnode.lock_fhs); } EXPORT_SYMBOL_GPL(cec_queue_pin_cec_event); /* Notify userspace that the HPD pin changed state at the given time. */ void cec_queue_pin_hpd_event(struct cec_adapter *adap, bool is_high, ktime_t ts) { struct cec_event ev = { .event = is_high ? CEC_EVENT_PIN_HPD_HIGH : CEC_EVENT_PIN_HPD_LOW, }; struct cec_fh *fh; mutex_lock(&adap->devnode.lock_fhs); list_for_each_entry(fh, &adap->devnode.fhs, list) cec_queue_event_fh(fh, &ev, ktime_to_ns(ts)); mutex_unlock(&adap->devnode.lock_fhs); } EXPORT_SYMBOL_GPL(cec_queue_pin_hpd_event); /* Notify userspace that the 5V pin changed state at the given time. */ void cec_queue_pin_5v_event(struct cec_adapter *adap, bool is_high, ktime_t ts) { struct cec_event ev = { .event = is_high ? CEC_EVENT_PIN_5V_HIGH : CEC_EVENT_PIN_5V_LOW, }; struct cec_fh *fh; mutex_lock(&adap->devnode.lock_fhs); list_for_each_entry(fh, &adap->devnode.fhs, list) cec_queue_event_fh(fh, &ev, ktime_to_ns(ts)); mutex_unlock(&adap->devnode.lock_fhs); } EXPORT_SYMBOL_GPL(cec_queue_pin_5v_event); /* * Queue a new message for this filehandle. * * We keep a queue of at most CEC_MAX_MSG_RX_QUEUE_SZ messages. If the * queue becomes full, then drop the oldest message and keep track * of how many messages we've dropped. */ static void cec_queue_msg_fh(struct cec_fh *fh, const struct cec_msg *msg) { static const struct cec_event ev_lost_msgs = { .event = CEC_EVENT_LOST_MSGS, .flags = 0, { .lost_msgs = { 1 }, }, }; struct cec_msg_entry *entry; mutex_lock(&fh->lock); entry = kmalloc(sizeof(*entry), GFP_KERNEL); if (entry) { entry->msg = *msg; /* Add new msg at the end of the queue */ list_add_tail(&entry->list, &fh->msgs); if (fh->queued_msgs < CEC_MAX_MSG_RX_QUEUE_SZ) { /* All is fine if there is enough room */ fh->queued_msgs++; mutex_unlock(&fh->lock); wake_up_interruptible(&fh->wait); return; } /* * if the message queue is full, then drop the oldest one and * send a lost message event. */ entry = list_first_entry(&fh->msgs, struct cec_msg_entry, list); list_del(&entry->list); kfree(entry); } mutex_unlock(&fh->lock); /* * We lost a message, either because kmalloc failed or the queue * was full. */ cec_queue_event_fh(fh, &ev_lost_msgs, ktime_get_ns()); } /* * Queue the message for those filehandles that are in monitor mode. * If valid_la is true (this message is for us or was sent by us), * then pass it on to any monitoring filehandle. If this message * isn't for us or from us, then only give it to filehandles that * are in MONITOR_ALL mode. * * This can only happen if the CEC_CAP_MONITOR_ALL capability is * set and the CEC adapter was placed in 'monitor all' mode. */ static void cec_queue_msg_monitor(struct cec_adapter *adap, const struct cec_msg *msg, bool valid_la) { struct cec_fh *fh; u32 monitor_mode = valid_la ? CEC_MODE_MONITOR : CEC_MODE_MONITOR_ALL; mutex_lock(&adap->devnode.lock_fhs); list_for_each_entry(fh, &adap->devnode.fhs, list) { if (fh->mode_follower >= monitor_mode) cec_queue_msg_fh(fh, msg); } mutex_unlock(&adap->devnode.lock_fhs); } /* * Queue the message for follower filehandles. */ static void cec_queue_msg_followers(struct cec_adapter *adap, const struct cec_msg *msg) { struct cec_fh *fh; mutex_lock(&adap->devnode.lock_fhs); list_for_each_entry(fh, &adap->devnode.fhs, list) { if (fh->mode_follower == CEC_MODE_FOLLOWER) cec_queue_msg_fh(fh, msg); } mutex_unlock(&adap->devnode.lock_fhs); } /* Notify userspace of an adapter state change. */ static void cec_post_state_event(struct cec_adapter *adap) { struct cec_event ev = { .event = CEC_EVENT_STATE_CHANGE, }; ev.state_change.phys_addr = adap->phys_addr; ev.state_change.log_addr_mask = adap->log_addrs.log_addr_mask; ev.state_change.have_conn_info = adap->conn_info.type != CEC_CONNECTOR_TYPE_NO_CONNECTOR; cec_queue_event(adap, &ev); } /* * A CEC transmit (and a possible wait for reply) completed. * If this was in blocking mode, then complete it, otherwise * queue the message for userspace to dequeue later. * * This function is called with adap->lock held. */ static void cec_data_completed(struct cec_data *data) { /* * Delete this transmit from the filehandle's xfer_list since * we're done with it. * * Note that if the filehandle is closed before this transmit * finished, then the release() function will set data->fh to NULL. * Without that we would be referring to a closed filehandle. */ if (data->fh) list_del_init(&data->xfer_list); if (data->blocking) { /* * Someone is blocking so mark the message as completed * and call complete. */ data->completed = true; complete(&data->c); } else { /* * No blocking, so just queue the message if needed and * free the memory. */ if (data->fh) cec_queue_msg_fh(data->fh, &data->msg); kfree(data); } } /* * A pending CEC transmit needs to be cancelled, either because the CEC * adapter is disabled or the transmit takes an impossibly long time to * finish, or the reply timed out. * * This function is called with adap->lock held. */ static void cec_data_cancel(struct cec_data *data, u8 tx_status, u8 rx_status) { struct cec_adapter *adap = data->adap; /* * It's either the current transmit, or it is a pending * transmit. Take the appropriate action to clear it. */ if (adap->transmitting == data) { adap->transmitting = NULL; } else { list_del_init(&data->list); if (!(data->msg.tx_status & CEC_TX_STATUS_OK)) if (!WARN_ON(!adap->transmit_queue_sz)) adap->transmit_queue_sz--; } if (data->msg.tx_status & CEC_TX_STATUS_OK) { data->msg.rx_ts = ktime_get_ns(); data->msg.rx_status = rx_status; if (!data->blocking) data->msg.tx_status = 0; } else { data->msg.tx_ts = ktime_get_ns(); data->msg.tx_status |= tx_status | CEC_TX_STATUS_MAX_RETRIES; data->msg.tx_error_cnt++; data->attempts = 0; if (!data->blocking) data->msg.rx_status = 0; } /* Queue transmitted message for monitoring purposes */ cec_queue_msg_monitor(adap, &data->msg, 1); if (!data->blocking && data->msg.sequence) /* Allow drivers to react to a canceled transmit */ call_void_op(adap, adap_nb_transmit_canceled, &data->msg); cec_data_completed(data); } /* * Flush all pending transmits and cancel any pending timeout work. * * This function is called with adap->lock held. */ static void cec_flush(struct cec_adapter *adap) { struct cec_data *data, *n; /* * If the adapter is disabled, or we're asked to stop, * then cancel any pending transmits. */ while (!list_empty(&adap->transmit_queue)) { data = list_first_entry(&adap->transmit_queue, struct cec_data, list); cec_data_cancel(data, CEC_TX_STATUS_ABORTED, 0); } if (adap->transmitting) adap->transmit_in_progress_aborted = true; /* Cancel the pending timeout work. */ list_for_each_entry_safe(data, n, &adap->wait_queue, list) { if (cancel_delayed_work(&data->work)) cec_data_cancel(data, CEC_TX_STATUS_OK, CEC_RX_STATUS_ABORTED); /* * If cancel_delayed_work returned false, then * the cec_wait_timeout function is running, * which will call cec_data_completed. So no * need to do anything special in that case. */ } /* * If something went wrong and this counter isn't what it should * be, then this will reset it back to 0. Warn if it is not 0, * since it indicates a bug, either in this framework or in a * CEC driver. */ if (WARN_ON(adap->transmit_queue_sz)) adap->transmit_queue_sz = 0; } /* * Main CEC state machine * * Wait until the thread should be stopped, or we are not transmitting and * a new transmit message is queued up, in which case we start transmitting * that message. When the adapter finished transmitting the message it will * call cec_transmit_done(). * * If the adapter is disabled, then remove all queued messages instead. * * If the current transmit times out, then cancel that transmit. */ int cec_thread_func(void *_adap) { struct cec_adapter *adap = _adap; for (;;) { unsigned int signal_free_time; struct cec_data *data; bool timeout = false; u8 attempts; if (adap->transmit_in_progress) { int err; /* * We are transmitting a message, so add a timeout * to prevent the state machine to get stuck waiting * for this message to finalize and add a check to * see if the adapter is disabled in which case the * transmit should be canceled. */ err = wait_event_interruptible_timeout(adap->kthread_waitq, (adap->needs_hpd && (!adap->is_configured && !adap->is_configuring)) || kthread_should_stop() || (!adap->transmit_in_progress && !list_empty(&adap->transmit_queue)), msecs_to_jiffies(adap->xfer_timeout_ms)); timeout = err == 0; } else { /* Otherwise we just wait for something to happen. */ wait_event_interruptible(adap->kthread_waitq, kthread_should_stop() || (!adap->transmit_in_progress && !list_empty(&adap->transmit_queue))); } mutex_lock(&adap->lock); if ((adap->needs_hpd && (!adap->is_configured && !adap->is_configuring)) || kthread_should_stop()) { cec_flush(adap); goto unlock; } if (adap->transmit_in_progress && adap->transmit_in_progress_aborted) { if (adap->transmitting) cec_data_cancel(adap->transmitting, CEC_TX_STATUS_ABORTED, 0); adap->transmit_in_progress = false; adap->transmit_in_progress_aborted = false; goto unlock; } if (adap->transmit_in_progress && timeout) { /* * If we timeout, then log that. Normally this does * not happen and it is an indication of a faulty CEC * adapter driver, or the CEC bus is in some weird * state. On rare occasions it can happen if there is * so much traffic on the bus that the adapter was * unable to transmit for xfer_timeout_ms (2.1s by * default). */ if (adap->transmitting) { pr_warn("cec-%s: message %*ph timed out\n", adap->name, adap->transmitting->msg.len, adap->transmitting->msg.msg); /* Just give up on this. */ cec_data_cancel(adap->transmitting, CEC_TX_STATUS_TIMEOUT, 0); } else { pr_warn("cec-%s: transmit timed out\n", adap->name); } adap->transmit_in_progress = false; adap->tx_timeouts++; goto unlock; } /* * If we are still transmitting, or there is nothing new to * transmit, then just continue waiting. */ if (adap->transmit_in_progress || list_empty(&adap->transmit_queue)) goto unlock; /* Get a new message to transmit */ data = list_first_entry(&adap->transmit_queue, struct cec_data, list); list_del_init(&data->list); if (!WARN_ON(!data->adap->transmit_queue_sz)) adap->transmit_queue_sz--; /* Make this the current transmitting message */ adap->transmitting = data; /* * Suggested number of attempts as per the CEC 2.0 spec: * 4 attempts is the default, except for 'secondary poll * messages', i.e. poll messages not sent during the adapter * configuration phase when it allocates logical addresses. */ if (data->msg.len == 1 && adap->is_configured) attempts = 2; else attempts = 4; /* Set the suggested signal free time */ if (data->attempts) { /* should be >= 3 data bit periods for a retry */ signal_free_time = CEC_SIGNAL_FREE_TIME_RETRY; } else if (adap->last_initiator != cec_msg_initiator(&data->msg)) { /* should be >= 5 data bit periods for new initiator */ signal_free_time = CEC_SIGNAL_FREE_TIME_NEW_INITIATOR; adap->last_initiator = cec_msg_initiator(&data->msg); } else { /* * should be >= 7 data bit periods for sending another * frame immediately after another. */ signal_free_time = CEC_SIGNAL_FREE_TIME_NEXT_XFER; } if (data->attempts == 0) data->attempts = attempts; adap->transmit_in_progress_aborted = false; /* Tell the adapter to transmit, cancel on error */ if (call_op(adap, adap_transmit, data->attempts, signal_free_time, &data->msg)) cec_data_cancel(data, CEC_TX_STATUS_ABORTED, 0); else adap->transmit_in_progress = true; unlock: mutex_unlock(&adap->lock); if (kthread_should_stop()) break; } return 0; } /* * Called by the CEC adapter if a transmit finished. */ void cec_transmit_done_ts(struct cec_adapter *adap, u8 status, u8 arb_lost_cnt, u8 nack_cnt, u8 low_drive_cnt, u8 error_cnt, ktime_t ts) { struct cec_data *data; struct cec_msg *msg; unsigned int attempts_made = arb_lost_cnt + nack_cnt + low_drive_cnt + error_cnt; bool done = status & (CEC_TX_STATUS_MAX_RETRIES | CEC_TX_STATUS_OK); bool aborted = adap->transmit_in_progress_aborted; dprintk(2, "%s: status 0x%02x\n", __func__, status); if (attempts_made < 1) attempts_made = 1; mutex_lock(&adap->lock); data = adap->transmitting; if (!data) { /* * This might happen if a transmit was issued and the cable is * unplugged while the transmit is ongoing. Ignore this * transmit in that case. */ if (!adap->transmit_in_progress) dprintk(1, "%s was called without an ongoing transmit!\n", __func__); adap->transmit_in_progress = false; goto wake_thread; } adap->transmit_in_progress = false; adap->transmit_in_progress_aborted = false; msg = &data->msg; /* Drivers must fill in the status! */ WARN_ON(status == 0); msg->tx_ts = ktime_to_ns(ts); msg->tx_status |= status; msg->tx_arb_lost_cnt += arb_lost_cnt; msg->tx_nack_cnt += nack_cnt; msg->tx_low_drive_cnt += low_drive_cnt; msg->tx_error_cnt += error_cnt; /* Mark that we're done with this transmit */ adap->transmitting = NULL; /* * If there are still retry attempts left and there was an error and * the hardware didn't signal that it retried itself (by setting * CEC_TX_STATUS_MAX_RETRIES), then we will retry ourselves. */ if (!aborted && data->attempts > attempts_made && !done) { /* Retry this message */ data->attempts -= attempts_made; if (msg->timeout) dprintk(2, "retransmit: %*ph (attempts: %d, wait for 0x%02x)\n", msg->len, msg->msg, data->attempts, msg->reply); else dprintk(2, "retransmit: %*ph (attempts: %d)\n", msg->len, msg->msg, data->attempts); /* Add the message in front of the transmit queue */ list_add(&data->list, &adap->transmit_queue); adap->transmit_queue_sz++; goto wake_thread; } if (aborted && !done) status |= CEC_TX_STATUS_ABORTED; data->attempts = 0; /* Always set CEC_TX_STATUS_MAX_RETRIES on error */ if (!(status & CEC_TX_STATUS_OK)) msg->tx_status |= CEC_TX_STATUS_MAX_RETRIES; /* Queue transmitted message for monitoring purposes */ cec_queue_msg_monitor(adap, msg, 1); if ((status & CEC_TX_STATUS_OK) && adap->is_configured && msg->timeout) { /* * Queue the message into the wait queue if we want to wait * for a reply. */ list_add_tail(&data->list, &adap->wait_queue); schedule_delayed_work(&data->work, msecs_to_jiffies(msg->timeout)); } else { /* Otherwise we're done */ cec_data_completed(data); } wake_thread: /* * Wake up the main thread to see if another message is ready * for transmitting or to retry the current message. */ wake_up_interruptible(&adap->kthread_waitq); mutex_unlock(&adap->lock); } EXPORT_SYMBOL_GPL(cec_transmit_done_ts); void cec_transmit_attempt_done_ts(struct cec_adapter *adap, u8 status, ktime_t ts) { switch (status & ~CEC_TX_STATUS_MAX_RETRIES) { case CEC_TX_STATUS_OK: cec_transmit_done_ts(adap, status, 0, 0, 0, 0, ts); return; case CEC_TX_STATUS_ARB_LOST: cec_transmit_done_ts(adap, status, 1, 0, 0, 0, ts); return; case CEC_TX_STATUS_NACK: cec_transmit_done_ts(adap, status, 0, 1, 0, 0, ts); return; case CEC_TX_STATUS_LOW_DRIVE: cec_transmit_done_ts(adap, status, 0, 0, 1, 0, ts); return; case CEC_TX_STATUS_ERROR: cec_transmit_done_ts(adap, status, 0, 0, 0, 1, ts); return; default: /* Should never happen */ WARN(1, "cec-%s: invalid status 0x%02x\n", adap->name, status); return; } } EXPORT_SYMBOL_GPL(cec_transmit_attempt_done_ts); /* * Called when waiting for a reply times out. */ static void cec_wait_timeout(struct work_struct *work) { struct cec_data *data = container_of(work, struct cec_data, work.work); struct cec_adapter *adap = data->adap; mutex_lock(&adap->lock); /* * Sanity check in case the timeout and the arrival of the message * happened at the same time. */ if (list_empty(&data->list)) goto unlock; /* Mark the message as timed out */ list_del_init(&data->list); cec_data_cancel(data, CEC_TX_STATUS_OK, CEC_RX_STATUS_TIMEOUT); unlock: mutex_unlock(&adap->lock); } /* * Transmit a message. The fh argument may be NULL if the transmit is not * associated with a specific filehandle. * * This function is called with adap->lock held. */ int cec_transmit_msg_fh(struct cec_adapter *adap, struct cec_msg *msg, struct cec_fh *fh, bool block) { struct cec_data *data; bool is_raw = msg_is_raw(msg); int err; if (adap->devnode.unregistered) return -ENODEV; msg->rx_ts = 0; msg->tx_ts = 0; msg->rx_status = 0; msg->tx_status = 0; msg->tx_arb_lost_cnt = 0; msg->tx_nack_cnt = 0; msg->tx_low_drive_cnt = 0; msg->tx_error_cnt = 0; msg->sequence = 0; if (msg->reply && msg->timeout == 0) { /* Make sure the timeout isn't 0. */ msg->timeout = 1000; } msg->flags &= CEC_MSG_FL_REPLY_TO_FOLLOWERS | CEC_MSG_FL_RAW; if (!msg->timeout) msg->flags &= ~CEC_MSG_FL_REPLY_TO_FOLLOWERS; /* Sanity checks */ if (msg->len == 0 || msg->len > CEC_MAX_MSG_SIZE) { dprintk(1, "%s: invalid length %d\n", __func__, msg->len); return -EINVAL; } memset(msg->msg + msg->len, 0, sizeof(msg->msg) - msg->len); if (msg->timeout) dprintk(2, "%s: %*ph (wait for 0x%02x%s)\n", __func__, msg->len, msg->msg, msg->reply, !block ? ", nb" : ""); else dprintk(2, "%s: %*ph%s\n", __func__, msg->len, msg->msg, !block ? " (nb)" : ""); if (msg->timeout && msg->len == 1) { dprintk(1, "%s: can't reply to poll msg\n", __func__); return -EINVAL; } if (is_raw) { if (!capable(CAP_SYS_RAWIO)) return -EPERM; } else { /* A CDC-Only device can only send CDC messages */ if ((adap->log_addrs.flags & CEC_LOG_ADDRS_FL_CDC_ONLY) && (msg->len == 1 || msg->msg[1] != CEC_MSG_CDC_MESSAGE)) { dprintk(1, "%s: not a CDC message\n", __func__); return -EINVAL; } if (msg->len >= 4 && msg->msg[1] == CEC_MSG_CDC_MESSAGE) { msg->msg[2] = adap->phys_addr >> 8; msg->msg[3] = adap->phys_addr & 0xff; } if (msg->len == 1) { if (cec_msg_destination(msg) == 0xf) { dprintk(1, "%s: invalid poll message\n", __func__); return -EINVAL; } if (cec_has_log_addr(adap, cec_msg_destination(msg))) { /* * If the destination is a logical address our * adapter has already claimed, then just NACK * this. It depends on the hardware what it will * do with a POLL to itself (some OK this), so * it is just as easy to handle it here so the * behavior will be consistent. */ msg->tx_ts = ktime_get_ns(); msg->tx_status = CEC_TX_STATUS_NACK | CEC_TX_STATUS_MAX_RETRIES; msg->tx_nack_cnt = 1; msg->sequence = ++adap->sequence; if (!msg->sequence) msg->sequence = ++adap->sequence; return 0; } } if (msg->len > 1 && !cec_msg_is_broadcast(msg) && cec_has_log_addr(adap, cec_msg_destination(msg))) { dprintk(1, "%s: destination is the adapter itself\n", __func__); return -EINVAL; } if (msg->len > 1 && adap->is_configured && !cec_has_log_addr(adap, cec_msg_initiator(msg))) { dprintk(1, "%s: initiator has unknown logical address %d\n", __func__, cec_msg_initiator(msg)); return -EINVAL; } /* * Special case: allow Ping and IMAGE/TEXT_VIEW_ON to be * transmitted to a TV, even if the adapter is unconfigured. * This makes it possible to detect or wake up displays that * pull down the HPD when in standby. */ if (!adap->is_configured && !adap->is_configuring && (msg->len > 2 || cec_msg_destination(msg) != CEC_LOG_ADDR_TV || (msg->len == 2 && msg->msg[1] != CEC_MSG_IMAGE_VIEW_ON && msg->msg[1] != CEC_MSG_TEXT_VIEW_ON))) { dprintk(1, "%s: adapter is unconfigured\n", __func__); return -ENONET; } } if (!adap->is_configured && !adap->is_configuring) { if (adap->needs_hpd) { dprintk(1, "%s: adapter is unconfigured and needs HPD\n", __func__); return -ENONET; } if (msg->reply) { dprintk(1, "%s: invalid msg->reply\n", __func__); return -EINVAL; } } if (adap->transmit_queue_sz >= CEC_MAX_MSG_TX_QUEUE_SZ) { dprintk(2, "%s: transmit queue full\n", __func__); return -EBUSY; } data = kzalloc(sizeof(*data), GFP_KERNEL); if (!data) return -ENOMEM; msg->sequence = ++adap->sequence; if (!msg->sequence) msg->sequence = ++adap->sequence; data->msg = *msg; data->fh = fh; data->adap = adap; data->blocking = block; init_completion(&data->c); INIT_DELAYED_WORK(&data->work, cec_wait_timeout); if (fh) list_add_tail(&data->xfer_list, &fh->xfer_list); else INIT_LIST_HEAD(&data->xfer_list); list_add_tail(&data->list, &adap->transmit_queue); adap->transmit_queue_sz++; if (!adap->transmitting) wake_up_interruptible(&adap->kthread_waitq); /* All done if we don't need to block waiting for completion */ if (!block) return 0; /* * Release the lock and wait, retake the lock afterwards. */ mutex_unlock(&adap->lock); err = wait_for_completion_killable(&data->c); cancel_delayed_work_sync(&data->work); mutex_lock(&adap->lock); if (err) adap->transmit_in_progress_aborted = true; /* Cancel the transmit if it was interrupted */ if (!data->completed) { if (data->msg.tx_status & CEC_TX_STATUS_OK) cec_data_cancel(data, CEC_TX_STATUS_OK, CEC_RX_STATUS_ABORTED); else cec_data_cancel(data, CEC_TX_STATUS_ABORTED, 0); } /* The transmit completed (possibly with an error) */ *msg = data->msg; if (WARN_ON(!list_empty(&data->list))) list_del(&data->list); if (WARN_ON(!list_empty(&data->xfer_list))) list_del(&data->xfer_list); kfree(data); return 0; } /* Helper function to be used by drivers and this framework. */ int cec_transmit_msg(struct cec_adapter *adap, struct cec_msg *msg, bool block) { int ret; mutex_lock(&adap->lock); ret = cec_transmit_msg_fh(adap, msg, NULL, block); mutex_unlock(&adap->lock); return ret; } EXPORT_SYMBOL_GPL(cec_transmit_msg); /* * I don't like forward references but without this the low-level * cec_received_msg() function would come after a bunch of high-level * CEC protocol handling functions. That was very confusing. */ static int cec_receive_notify(struct cec_adapter *adap, struct cec_msg *msg, bool is_reply); #define DIRECTED 0x80 #define BCAST1_4 0x40 #define BCAST2_0 0x20 /* broadcast only allowed for >= 2.0 */ #define BCAST (BCAST1_4 | BCAST2_0) #define BOTH (BCAST | DIRECTED) /* * Specify minimum length and whether the message is directed, broadcast * or both. Messages that do not match the criteria are ignored as per * the CEC specification. */ static const u8 cec_msg_size[256] = { [CEC_MSG_ACTIVE_SOURCE] = 4 | BCAST, [CEC_MSG_IMAGE_VIEW_ON] = 2 | DIRECTED, [CEC_MSG_TEXT_VIEW_ON] = 2 | DIRECTED, [CEC_MSG_INACTIVE_SOURCE] = 4 | DIRECTED, [CEC_MSG_REQUEST_ACTIVE_SOURCE] = 2 | BCAST, [CEC_MSG_ROUTING_CHANGE] = 6 | BCAST, [CEC_MSG_ROUTING_INFORMATION] = 4 | BCAST, [CEC_MSG_SET_STREAM_PATH] = 4 | BCAST, [CEC_MSG_STANDBY] = 2 | BOTH, [CEC_MSG_RECORD_OFF] = 2 | DIRECTED, [CEC_MSG_RECORD_ON] = 3 | DIRECTED, [CEC_MSG_RECORD_STATUS] = 3 | DIRECTED, [CEC_MSG_RECORD_TV_SCREEN] = 2 | DIRECTED, [CEC_MSG_CLEAR_ANALOGUE_TIMER] = 13 | DIRECTED, [CEC_MSG_CLEAR_DIGITAL_TIMER] = 16 | DIRECTED, [CEC_MSG_CLEAR_EXT_TIMER] = 13 | DIRECTED, [CEC_MSG_SET_ANALOGUE_TIMER] = 13 | DIRECTED, [CEC_MSG_SET_DIGITAL_TIMER] = 16 | DIRECTED, [CEC_MSG_SET_EXT_TIMER] = 13 | DIRECTED, [CEC_MSG_SET_TIMER_PROGRAM_TITLE] = 2 | DIRECTED, [CEC_MSG_TIMER_CLEARED_STATUS] = 3 | DIRECTED, [CEC_MSG_TIMER_STATUS] = 3 | DIRECTED, [CEC_MSG_CEC_VERSION] = 3 | DIRECTED, [CEC_MSG_GET_CEC_VERSION] = 2 | DIRECTED, [CEC_MSG_GIVE_PHYSICAL_ADDR] = 2 | DIRECTED, [CEC_MSG_GET_MENU_LANGUAGE] = 2 | DIRECTED, [CEC_MSG_REPORT_PHYSICAL_ADDR] = 5 | BCAST, [CEC_MSG_SET_MENU_LANGUAGE] = 5 | BCAST, [CEC_MSG_REPORT_FEATURES] = 6 | BCAST, [CEC_MSG_GIVE_FEATURES] = 2 | DIRECTED, [CEC_MSG_DECK_CONTROL] = 3 | DIRECTED, [CEC_MSG_DECK_STATUS] = 3 | DIRECTED, [CEC_MSG_GIVE_DECK_STATUS] = 3 | DIRECTED, [CEC_MSG_PLAY] = 3 | DIRECTED, [CEC_MSG_GIVE_TUNER_DEVICE_STATUS] = 3 | DIRECTED, [CEC_MSG_SELECT_ANALOGUE_SERVICE] = 6 | DIRECTED, [CEC_MSG_SELECT_DIGITAL_SERVICE] = 9 | DIRECTED, [CEC_MSG_TUNER_DEVICE_STATUS] = 7 | DIRECTED, [CEC_MSG_TUNER_STEP_DECREMENT] = 2 | DIRECTED, [CEC_MSG_TUNER_STEP_INCREMENT] = 2 | DIRECTED, [CEC_MSG_DEVICE_VENDOR_ID] = 5 | BCAST, [CEC_MSG_GIVE_DEVICE_VENDOR_ID] = 2 | DIRECTED, [CEC_MSG_VENDOR_COMMAND] = 2 | DIRECTED, [CEC_MSG_VENDOR_COMMAND_WITH_ID] = 5 | BOTH, [CEC_MSG_VENDOR_REMOTE_BUTTON_DOWN] = 2 | BOTH, [CEC_MSG_VENDOR_REMOTE_BUTTON_UP] = 2 | BOTH, [CEC_MSG_SET_OSD_STRING] = 3 | DIRECTED, [CEC_MSG_GIVE_OSD_NAME] = 2 | DIRECTED, [CEC_MSG_SET_OSD_NAME] = 2 | DIRECTED, [CEC_MSG_MENU_REQUEST] = 3 | DIRECTED, [CEC_MSG_MENU_STATUS] = 3 | DIRECTED, [CEC_MSG_USER_CONTROL_PRESSED] = 3 | DIRECTED, [CEC_MSG_USER_CONTROL_RELEASED] = 2 | DIRECTED, [CEC_MSG_GIVE_DEVICE_POWER_STATUS] = 2 | DIRECTED, [CEC_MSG_REPORT_POWER_STATUS] = 3 | DIRECTED | BCAST2_0, [CEC_MSG_FEATURE_ABORT] = 4 | DIRECTED, [CEC_MSG_ABORT] = 2 | DIRECTED, [CEC_MSG_GIVE_AUDIO_STATUS] = 2 | DIRECTED, [CEC_MSG_GIVE_SYSTEM_AUDIO_MODE_STATUS] = 2 | DIRECTED, [CEC_MSG_REPORT_AUDIO_STATUS] = 3 | DIRECTED, [CEC_MSG_REPORT_SHORT_AUDIO_DESCRIPTOR] = 2 | DIRECTED, [CEC_MSG_REQUEST_SHORT_AUDIO_DESCRIPTOR] = 2 | DIRECTED, [CEC_MSG_SET_SYSTEM_AUDIO_MODE] = 3 | BOTH, [CEC_MSG_SET_AUDIO_VOLUME_LEVEL] = 3 | DIRECTED, [CEC_MSG_SYSTEM_AUDIO_MODE_REQUEST] = 2 | DIRECTED, [CEC_MSG_SYSTEM_AUDIO_MODE_STATUS] = 3 | DIRECTED, [CEC_MSG_SET_AUDIO_RATE] = 3 | DIRECTED, [CEC_MSG_INITIATE_ARC] = 2 | DIRECTED, [CEC_MSG_REPORT_ARC_INITIATED] = 2 | DIRECTED, [CEC_MSG_REPORT_ARC_TERMINATED] = 2 | DIRECTED, [CEC_MSG_REQUEST_ARC_INITIATION] = 2 | DIRECTED, [CEC_MSG_REQUEST_ARC_TERMINATION] = 2 | DIRECTED, [CEC_MSG_TERMINATE_ARC] = 2 | DIRECTED, [CEC_MSG_REQUEST_CURRENT_LATENCY] = 4 | BCAST, [CEC_MSG_REPORT_CURRENT_LATENCY] = 6 | BCAST, [CEC_MSG_CDC_MESSAGE] = 2 | BCAST, }; /* Called by the CEC adapter if a message is received */ void cec_received_msg_ts(struct cec_adapter *adap, struct cec_msg *msg, ktime_t ts) { struct cec_data *data; u8 msg_init = cec_msg_initiator(msg); u8 msg_dest = cec_msg_destination(msg); u8 cmd = msg->msg[1]; bool is_reply = false; bool valid_la = true; u8 min_len = 0; if (WARN_ON(!msg->len || msg->len > CEC_MAX_MSG_SIZE)) return; if (adap->devnode.unregistered) return; /* * Some CEC adapters will receive the messages that they transmitted. * This test filters out those messages by checking if we are the * initiator, and just returning in that case. * * Note that this won't work if this is an Unregistered device. * * It is bad practice if the hardware receives the message that it * transmitted and luckily most CEC adapters behave correctly in this * respect. */ if (msg_init != CEC_LOG_ADDR_UNREGISTERED && cec_has_log_addr(adap, msg_init)) return; msg->rx_ts = ktime_to_ns(ts); msg->rx_status = CEC_RX_STATUS_OK; msg->sequence = msg->reply = msg->timeout = 0; msg->tx_status = 0; msg->tx_ts = 0; msg->tx_arb_lost_cnt = 0; msg->tx_nack_cnt = 0; msg->tx_low_drive_cnt = 0; msg->tx_error_cnt = 0; msg->flags = 0; memset(msg->msg + msg->len, 0, sizeof(msg->msg) - msg->len); mutex_lock(&adap->lock); dprintk(2, "%s: %*ph\n", __func__, msg->len, msg->msg); if (!adap->transmit_in_progress) adap->last_initiator = 0xff; /* Check if this message was for us (directed or broadcast). */ if (!cec_msg_is_broadcast(msg)) valid_la = cec_has_log_addr(adap, msg_dest); /* * Check if the length is not too short or if the message is a * broadcast message where a directed message was expected or * vice versa. If so, then the message has to be ignored (according * to section CEC 7.3 and CEC 12.2). */ if (valid_la && msg->len > 1 && cec_msg_size[cmd]) { u8 dir_fl = cec_msg_size[cmd] & BOTH; min_len = cec_msg_size[cmd] & 0x1f; if (msg->len < min_len) valid_la = false; else if (!cec_msg_is_broadcast(msg) && !(dir_fl & DIRECTED)) valid_la = false; else if (cec_msg_is_broadcast(msg) && !(dir_fl & BCAST)) valid_la = false; else if (cec_msg_is_broadcast(msg) && adap->log_addrs.cec_version < CEC_OP_CEC_VERSION_2_0 && !(dir_fl & BCAST1_4)) valid_la = false; } if (valid_la && min_len) { /* These messages have special length requirements */ switch (cmd) { case CEC_MSG_RECORD_ON: switch (msg->msg[2]) { case CEC_OP_RECORD_SRC_OWN: break; case CEC_OP_RECORD_SRC_DIGITAL: if (msg->len < 10) valid_la = false; break; case CEC_OP_RECORD_SRC_ANALOG: if (msg->len < 7) valid_la = false; break; case CEC_OP_RECORD_SRC_EXT_PLUG: if (msg->len < 4) valid_la = false; break; case CEC_OP_RECORD_SRC_EXT_PHYS_ADDR: if (msg->len < 5) valid_la = false; break; } break; } } /* It's a valid message and not a poll or CDC message */ if (valid_la && msg->len > 1 && cmd != CEC_MSG_CDC_MESSAGE) { bool abort = cmd == CEC_MSG_FEATURE_ABORT; /* The aborted command is in msg[2] */ if (abort) cmd = msg->msg[2]; /* * Walk over all transmitted messages that are waiting for a * reply. */ list_for_each_entry(data, &adap->wait_queue, list) { struct cec_msg *dst = &data->msg; /* * The *only* CEC message that has two possible replies * is CEC_MSG_INITIATE_ARC. * In this case allow either of the two replies. */ if (!abort && dst->msg[1] == CEC_MSG_INITIATE_ARC && (cmd == CEC_MSG_REPORT_ARC_INITIATED || cmd == CEC_MSG_REPORT_ARC_TERMINATED) && (dst->reply == CEC_MSG_REPORT_ARC_INITIATED || dst->reply == CEC_MSG_REPORT_ARC_TERMINATED)) dst->reply = cmd; /* Does the command match? */ if ((abort && cmd != dst->msg[1]) || (!abort && cmd != dst->reply)) continue; /* Does the addressing match? */ if (msg_init != cec_msg_destination(dst) && !cec_msg_is_broadcast(dst)) continue; /* We got a reply */ memcpy(dst->msg, msg->msg, msg->len); dst->len = msg->len; dst->rx_ts = msg->rx_ts; dst->rx_status = msg->rx_status; if (abort) dst->rx_status |= CEC_RX_STATUS_FEATURE_ABORT; msg->flags = dst->flags; msg->sequence = dst->sequence; /* Remove it from the wait_queue */ list_del_init(&data->list); /* Cancel the pending timeout work */ if (!cancel_delayed_work(&data->work)) { mutex_unlock(&adap->lock); cancel_delayed_work_sync(&data->work); mutex_lock(&adap->lock); } /* * Mark this as a reply, provided someone is still * waiting for the answer. */ if (data->fh) is_reply = true; cec_data_completed(data); break; } } mutex_unlock(&adap->lock); /* Pass the message on to any monitoring filehandles */ cec_queue_msg_monitor(adap, msg, valid_la); /* We're done if it is not for us or a poll message */ if (!valid_la || msg->len <= 1) return; if (adap->log_addrs.log_addr_mask == 0) return; /* * Process the message on the protocol level. If is_reply is true, * then cec_receive_notify() won't pass on the reply to the listener(s) * since that was already done by cec_data_completed() above. */ cec_receive_notify(adap, msg, is_reply); } EXPORT_SYMBOL_GPL(cec_received_msg_ts); /* Logical Address Handling */ /* * Attempt to claim a specific logical address. * * This function is called with adap->lock held. */ static int cec_config_log_addr(struct cec_adapter *adap, unsigned int idx, unsigned int log_addr) { struct cec_log_addrs *las = &adap->log_addrs; struct cec_msg msg = { }; const unsigned int max_retries = 2; unsigned int i; int err; if (cec_has_log_addr(adap, log_addr)) return 0; /* Send poll message */ msg.len = 1; msg.msg[0] = (log_addr << 4) | log_addr; for (i = 0; i < max_retries; i++) { err = cec_transmit_msg_fh(adap, &msg, NULL, true); /* * While trying to poll the physical address was reset * and the adapter was unconfigured, so bail out. */ if (adap->phys_addr == CEC_PHYS_ADDR_INVALID) return -EINTR; /* Also bail out if the PA changed while configuring. */ if (adap->must_reconfigure) return -EINTR; if (err) return err; /* * The message was aborted or timed out due to a disconnect or * unconfigure, just bail out. */ if (msg.tx_status & (CEC_TX_STATUS_ABORTED | CEC_TX_STATUS_TIMEOUT)) return -EINTR; if (msg.tx_status & CEC_TX_STATUS_OK) return 0; if (msg.tx_status & CEC_TX_STATUS_NACK) break; /* * Retry up to max_retries times if the message was neither * OKed or NACKed. This can happen due to e.g. a Lost * Arbitration condition. */ } /* * If we are unable to get an OK or a NACK after max_retries attempts * (and note that each attempt already consists of four polls), then * we assume that something is really weird and that it is not a * good idea to try and claim this logical address. */ if (i == max_retries) { dprintk(0, "polling for LA %u failed with tx_status=0x%04x\n", log_addr, msg.tx_status); return 0; } /* * Message not acknowledged, so this logical * address is free to use. */ err = call_op(adap, adap_log_addr, log_addr); if (err) return err; las->log_addr[idx] = log_addr; las->log_addr_mask |= 1 << log_addr; return 1; } /* * Unconfigure the adapter: clear all logical addresses and send * the state changed event. * * This function is called with adap->lock held. */ static void cec_adap_unconfigure(struct cec_adapter *adap) { if (!adap->needs_hpd || adap->phys_addr != CEC_PHYS_ADDR_INVALID) WARN_ON(call_op(adap, adap_log_addr, CEC_LOG_ADDR_INVALID)); adap->log_addrs.log_addr_mask = 0; adap->is_configured = false; cec_flush(adap); wake_up_interruptible(&adap->kthread_waitq); cec_post_state_event(adap); call_void_op(adap, adap_unconfigured); } /* * Attempt to claim the required logical addresses. */ static int cec_config_thread_func(void *arg) { /* The various LAs for each type of device */ static const u8 tv_log_addrs[] = { CEC_LOG_ADDR_TV, CEC_LOG_ADDR_SPECIFIC, CEC_LOG_ADDR_INVALID }; static const u8 record_log_addrs[] = { CEC_LOG_ADDR_RECORD_1, CEC_LOG_ADDR_RECORD_2, CEC_LOG_ADDR_RECORD_3, CEC_LOG_ADDR_BACKUP_1, CEC_LOG_ADDR_BACKUP_2, CEC_LOG_ADDR_INVALID }; static const u8 tuner_log_addrs[] = { CEC_LOG_ADDR_TUNER_1, CEC_LOG_ADDR_TUNER_2, CEC_LOG_ADDR_TUNER_3, CEC_LOG_ADDR_TUNER_4, CEC_LOG_ADDR_BACKUP_1, CEC_LOG_ADDR_BACKUP_2, CEC_LOG_ADDR_INVALID }; static const u8 playback_log_addrs[] = { CEC_LOG_ADDR_PLAYBACK_1, CEC_LOG_ADDR_PLAYBACK_2, CEC_LOG_ADDR_PLAYBACK_3, CEC_LOG_ADDR_BACKUP_1, CEC_LOG_ADDR_BACKUP_2, CEC_LOG_ADDR_INVALID }; static const u8 audiosystem_log_addrs[] = { CEC_LOG_ADDR_AUDIOSYSTEM, CEC_LOG_ADDR_INVALID }; static const u8 specific_use_log_addrs[] = { CEC_LOG_ADDR_SPECIFIC, CEC_LOG_ADDR_BACKUP_1, CEC_LOG_ADDR_BACKUP_2, CEC_LOG_ADDR_INVALID }; static const u8 *type2addrs[6] = { [CEC_LOG_ADDR_TYPE_TV] = tv_log_addrs, [CEC_LOG_ADDR_TYPE_RECORD] = record_log_addrs, [CEC_LOG_ADDR_TYPE_TUNER] = tuner_log_addrs, [CEC_LOG_ADDR_TYPE_PLAYBACK] = playback_log_addrs, [CEC_LOG_ADDR_TYPE_AUDIOSYSTEM] = audiosystem_log_addrs, [CEC_LOG_ADDR_TYPE_SPECIFIC] = specific_use_log_addrs, }; static const u16 type2mask[] = { [CEC_LOG_ADDR_TYPE_TV] = CEC_LOG_ADDR_MASK_TV, [CEC_LOG_ADDR_TYPE_RECORD] = CEC_LOG_ADDR_MASK_RECORD, [CEC_LOG_ADDR_TYPE_TUNER] = CEC_LOG_ADDR_MASK_TUNER, [CEC_LOG_ADDR_TYPE_PLAYBACK] = CEC_LOG_ADDR_MASK_PLAYBACK, [CEC_LOG_ADDR_TYPE_AUDIOSYSTEM] = CEC_LOG_ADDR_MASK_AUDIOSYSTEM, [CEC_LOG_ADDR_TYPE_SPECIFIC] = CEC_LOG_ADDR_MASK_SPECIFIC, }; struct cec_adapter *adap = arg; struct cec_log_addrs *las = &adap->log_addrs; int err; int i, j; mutex_lock(&adap->lock); dprintk(1, "physical address: %x.%x.%x.%x, claim %d logical addresses\n", cec_phys_addr_exp(adap->phys_addr), las->num_log_addrs); las->log_addr_mask = 0; if (las->log_addr_type[0] == CEC_LOG_ADDR_TYPE_UNREGISTERED) goto configured; reconfigure: for (i = 0; i < las->num_log_addrs; i++) { unsigned int type = las->log_addr_type[i]; const u8 *la_list; u8 last_la; /* * The TV functionality can only map to physical address 0. * For any other address, try the Specific functionality * instead as per the spec. */ if (adap->phys_addr && type == CEC_LOG_ADDR_TYPE_TV) type = CEC_LOG_ADDR_TYPE_SPECIFIC; la_list = type2addrs[type]; last_la = las->log_addr[i]; las->log_addr[i] = CEC_LOG_ADDR_INVALID; if (last_la == CEC_LOG_ADDR_INVALID || last_la == CEC_LOG_ADDR_UNREGISTERED || !((1 << last_la) & type2mask[type])) last_la = la_list[0]; err = cec_config_log_addr(adap, i, last_la); if (adap->must_reconfigure) { adap->must_reconfigure = false; las->log_addr_mask = 0; goto reconfigure; } if (err > 0) /* Reused last LA */ continue; if (err < 0) goto unconfigure; for (j = 0; la_list[j] != CEC_LOG_ADDR_INVALID; j++) { /* Tried this one already, skip it */ if (la_list[j] == last_la) continue; /* The backup addresses are CEC 2.0 specific */ if ((la_list[j] == CEC_LOG_ADDR_BACKUP_1 || la_list[j] == CEC_LOG_ADDR_BACKUP_2) && las->cec_version < CEC_OP_CEC_VERSION_2_0) continue; err = cec_config_log_addr(adap, i, la_list[j]); if (err == 0) /* LA is in use */ continue; if (err < 0) goto unconfigure; /* Done, claimed an LA */ break; } if (la_list[j] == CEC_LOG_ADDR_INVALID) dprintk(1, "could not claim LA %d\n", i); } if (adap->log_addrs.log_addr_mask == 0 && !(las->flags & CEC_LOG_ADDRS_FL_ALLOW_UNREG_FALLBACK)) goto unconfigure; configured: if (adap->log_addrs.log_addr_mask == 0) { /* Fall back to unregistered */ las->log_addr[0] = CEC_LOG_ADDR_UNREGISTERED; las->log_addr_mask = 1 << las->log_addr[0]; for (i = 1; i < las->num_log_addrs; i++) las->log_addr[i] = CEC_LOG_ADDR_INVALID; } for (i = las->num_log_addrs; i < CEC_MAX_LOG_ADDRS; i++) las->log_addr[i] = CEC_LOG_ADDR_INVALID; adap->is_configured = true; adap->is_configuring = false; adap->must_reconfigure = false; cec_post_state_event(adap); /* * Now post the Report Features and Report Physical Address broadcast * messages. Note that these are non-blocking transmits, meaning that * they are just queued up and once adap->lock is unlocked the main * thread will kick in and start transmitting these. * * If after this function is done (but before one or more of these * messages are actually transmitted) the CEC adapter is unconfigured, * then any remaining messages will be dropped by the main thread. */ for (i = 0; i < las->num_log_addrs; i++) { struct cec_msg msg = {}; if (las->log_addr[i] == CEC_LOG_ADDR_INVALID || (las->flags & CEC_LOG_ADDRS_FL_CDC_ONLY)) continue; msg.msg[0] = (las->log_addr[i] << 4) | 0x0f; /* Report Features must come first according to CEC 2.0 */ if (las->log_addr[i] != CEC_LOG_ADDR_UNREGISTERED && adap->log_addrs.cec_version >= CEC_OP_CEC_VERSION_2_0) { cec_fill_msg_report_features(adap, &msg, i); cec_transmit_msg_fh(adap, &msg, NULL, false); } /* Report Physical Address */ cec_msg_report_physical_addr(&msg, adap->phys_addr, las->primary_device_type[i]); dprintk(1, "config: la %d pa %x.%x.%x.%x\n", las->log_addr[i], cec_phys_addr_exp(adap->phys_addr)); cec_transmit_msg_fh(adap, &msg, NULL, false); /* Report Vendor ID */ if (adap->log_addrs.vendor_id != CEC_VENDOR_ID_NONE) { cec_msg_device_vendor_id(&msg, adap->log_addrs.vendor_id); cec_transmit_msg_fh(adap, &msg, NULL, false); } } adap->kthread_config = NULL; complete(&adap->config_completion); mutex_unlock(&adap->lock); call_void_op(adap, configured); return 0; unconfigure: for (i = 0; i < las->num_log_addrs; i++) las->log_addr[i] = CEC_LOG_ADDR_INVALID; cec_adap_unconfigure(adap); adap->is_configuring = false; adap->must_reconfigure = false; adap->kthread_config = NULL; complete(&adap->config_completion); mutex_unlock(&adap->lock); return 0; } /* * Called from either __cec_s_phys_addr or __cec_s_log_addrs to claim the * logical addresses. * * This function is called with adap->lock held. */ static void cec_claim_log_addrs(struct cec_adapter *adap, bool block) { if (WARN_ON(adap->is_claiming_log_addrs || adap->is_configuring || adap->is_configured)) return; adap->is_claiming_log_addrs = true; init_completion(&adap->config_completion); /* Ready to kick off the thread */ adap->is_configuring = true; adap->kthread_config = kthread_run(cec_config_thread_func, adap, "ceccfg-%s", adap->name); if (IS_ERR(adap->kthread_config)) { adap->kthread_config = NULL; adap->is_configuring = false; } else if (block) { mutex_unlock(&adap->lock); wait_for_completion(&adap->config_completion); mutex_lock(&adap->lock); } adap->is_claiming_log_addrs = false; } /* * Helper function to enable/disable the CEC adapter. * * This function is called with adap->lock held. */ int cec_adap_enable(struct cec_adapter *adap) { bool enable; int ret = 0; enable = adap->monitor_all_cnt || adap->monitor_pin_cnt || adap->log_addrs.num_log_addrs; if (adap->needs_hpd) enable = enable && adap->phys_addr != CEC_PHYS_ADDR_INVALID; if (adap->devnode.unregistered) enable = false; if (enable == adap->is_enabled) return 0; /* serialize adap_enable */ mutex_lock(&adap->devnode.lock); if (enable) { adap->last_initiator = 0xff; adap->transmit_in_progress = false; ret = adap->ops->adap_enable(adap, true); if (!ret) { /* * Enable monitor-all/pin modes if needed. We warn, but * continue if this fails as this is not a critical error. */ if (adap->monitor_all_cnt) WARN_ON(call_op(adap, adap_monitor_all_enable, true)); if (adap->monitor_pin_cnt) WARN_ON(call_op(adap, adap_monitor_pin_enable, true)); } } else { /* Disable monitor-all/pin modes if needed (needs_hpd == 1) */ if (adap->monitor_all_cnt) WARN_ON(call_op(adap, adap_monitor_all_enable, false)); if (adap->monitor_pin_cnt) WARN_ON(call_op(adap, adap_monitor_pin_enable, false)); WARN_ON(adap->ops->adap_enable(adap, false)); adap->last_initiator = 0xff; adap->transmit_in_progress = false; adap->transmit_in_progress_aborted = false; if (adap->transmitting) cec_data_cancel(adap->transmitting, CEC_TX_STATUS_ABORTED, 0); } if (!ret) adap->is_enabled = enable; wake_up_interruptible(&adap->kthread_waitq); mutex_unlock(&adap->devnode.lock); return ret; } /* Set a new physical address and send an event notifying userspace of this. * * This function is called with adap->lock held. */ void __cec_s_phys_addr(struct cec_adapter *adap, u16 phys_addr, bool block) { bool becomes_invalid = phys_addr == CEC_PHYS_ADDR_INVALID; bool is_invalid = adap->phys_addr == CEC_PHYS_ADDR_INVALID; if (phys_addr == adap->phys_addr) return; if (!becomes_invalid && adap->devnode.unregistered) return; dprintk(1, "new physical address %x.%x.%x.%x\n", cec_phys_addr_exp(phys_addr)); if (becomes_invalid || !is_invalid) { adap->phys_addr = CEC_PHYS_ADDR_INVALID; cec_post_state_event(adap); cec_adap_unconfigure(adap); if (becomes_invalid) { cec_adap_enable(adap); return; } } adap->phys_addr = phys_addr; if (is_invalid) cec_adap_enable(adap); cec_post_state_event(adap); if (!adap->log_addrs.num_log_addrs) return; if (adap->is_configuring) adap->must_reconfigure = true; else cec_claim_log_addrs(adap, block); } void cec_s_phys_addr(struct cec_adapter *adap, u16 phys_addr, bool block) { if (IS_ERR_OR_NULL(adap)) return; mutex_lock(&adap->lock); __cec_s_phys_addr(adap, phys_addr, block); mutex_unlock(&adap->lock); } EXPORT_SYMBOL_GPL(cec_s_phys_addr); void cec_s_phys_addr_from_edid(struct cec_adapter *adap, const struct edid *edid) { u16 pa = CEC_PHYS_ADDR_INVALID; if (edid && edid->extensions) pa = cec_get_edid_phys_addr((const u8 *)edid, EDID_LENGTH * (edid->extensions + 1), NULL); cec_s_phys_addr(adap, pa, false); } EXPORT_SYMBOL_GPL(cec_s_phys_addr_from_edid); void cec_s_conn_info(struct cec_adapter *adap, const struct cec_connector_info *conn_info) { if (IS_ERR_OR_NULL(adap)) return; if (!(adap->capabilities & CEC_CAP_CONNECTOR_INFO)) return; mutex_lock(&adap->lock); if (conn_info) adap->conn_info = *conn_info; else memset(&adap->conn_info, 0, sizeof(adap->conn_info)); cec_post_state_event(adap); mutex_unlock(&adap->lock); } EXPORT_SYMBOL_GPL(cec_s_conn_info); /* * Called from either the ioctl or a driver to set the logical addresses. * * This function is called with adap->lock held. */ int __cec_s_log_addrs(struct cec_adapter *adap, struct cec_log_addrs *log_addrs, bool block) { u16 type_mask = 0; int err; int i; if (adap->devnode.unregistered) return -ENODEV; if (!log_addrs || log_addrs->num_log_addrs == 0) { if (!adap->log_addrs.num_log_addrs) return 0; if (adap->is_configuring || adap->is_configured) cec_adap_unconfigure(adap); adap->log_addrs.num_log_addrs = 0; for (i = 0; i < CEC_MAX_LOG_ADDRS; i++) adap->log_addrs.log_addr[i] = CEC_LOG_ADDR_INVALID; adap->log_addrs.osd_name[0] = '\0'; adap->log_addrs.vendor_id = CEC_VENDOR_ID_NONE; adap->log_addrs.cec_version = CEC_OP_CEC_VERSION_2_0; cec_adap_enable(adap); return 0; } if (log_addrs->flags & CEC_LOG_ADDRS_FL_CDC_ONLY) { /* * Sanitize log_addrs fields if a CDC-Only device is * requested. */ log_addrs->num_log_addrs = 1; log_addrs->osd_name[0] = '\0'; log_addrs->vendor_id = CEC_VENDOR_ID_NONE; log_addrs->log_addr_type[0] = CEC_LOG_ADDR_TYPE_UNREGISTERED; /* * This is just an internal convention since a CDC-Only device * doesn't have to be a switch. But switches already use * unregistered, so it makes some kind of sense to pick this * as the primary device. Since a CDC-Only device never sends * any 'normal' CEC messages this primary device type is never * sent over the CEC bus. */ log_addrs->primary_device_type[0] = CEC_OP_PRIM_DEVTYPE_SWITCH; log_addrs->all_device_types[0] = 0; log_addrs->features[0][0] = 0; log_addrs->features[0][1] = 0; } /* Ensure the osd name is 0-terminated */ log_addrs->osd_name[sizeof(log_addrs->osd_name) - 1] = '\0'; /* Sanity checks */ if (log_addrs->num_log_addrs > adap->available_log_addrs) { dprintk(1, "num_log_addrs > %d\n", adap->available_log_addrs); return -EINVAL; } /* * Vendor ID is a 24 bit number, so check if the value is * within the correct range. */ if (log_addrs->vendor_id != CEC_VENDOR_ID_NONE && (log_addrs->vendor_id & 0xff000000) != 0) { dprintk(1, "invalid vendor ID\n"); return -EINVAL; } if (log_addrs->cec_version != CEC_OP_CEC_VERSION_1_4 && log_addrs->cec_version != CEC_OP_CEC_VERSION_2_0) { dprintk(1, "invalid CEC version\n"); return -EINVAL; } if (log_addrs->num_log_addrs > 1) for (i = 0; i < log_addrs->num_log_addrs; i++) if (log_addrs->log_addr_type[i] == CEC_LOG_ADDR_TYPE_UNREGISTERED) { dprintk(1, "num_log_addrs > 1 can't be combined with unregistered LA\n"); return -EINVAL; } for (i = 0; i < log_addrs->num_log_addrs; i++) { const u8 feature_sz = ARRAY_SIZE(log_addrs->features[0]); u8 *features = log_addrs->features[i]; bool op_is_dev_features = false; unsigned int j; log_addrs->log_addr[i] = CEC_LOG_ADDR_INVALID; if (log_addrs->log_addr_type[i] > CEC_LOG_ADDR_TYPE_UNREGISTERED) { dprintk(1, "unknown logical address type\n"); return -EINVAL; } if (type_mask & (1 << log_addrs->log_addr_type[i])) { dprintk(1, "duplicate logical address type\n"); return -EINVAL; } type_mask |= 1 << log_addrs->log_addr_type[i]; if ((type_mask & (1 << CEC_LOG_ADDR_TYPE_RECORD)) && (type_mask & (1 << CEC_LOG_ADDR_TYPE_PLAYBACK))) { /* Record already contains the playback functionality */ dprintk(1, "invalid record + playback combination\n"); return -EINVAL; } if (log_addrs->primary_device_type[i] > CEC_OP_PRIM_DEVTYPE_PROCESSOR) { dprintk(1, "unknown primary device type\n"); return -EINVAL; } if (log_addrs->primary_device_type[i] == 2) { dprintk(1, "invalid primary device type\n"); return -EINVAL; } for (j = 0; j < feature_sz; j++) { if ((features[j] & 0x80) == 0) { if (op_is_dev_features) break; op_is_dev_features = true; } } if (!op_is_dev_features || j == feature_sz) { dprintk(1, "malformed features\n"); return -EINVAL; } /* Zero unused part of the feature array */ memset(features + j + 1, 0, feature_sz - j - 1); } if (log_addrs->cec_version >= CEC_OP_CEC_VERSION_2_0) { if (log_addrs->num_log_addrs > 2) { dprintk(1, "CEC 2.0 allows no more than 2 logical addresses\n"); return -EINVAL; } if (log_addrs->num_log_addrs == 2) { if (!(type_mask & ((1 << CEC_LOG_ADDR_TYPE_AUDIOSYSTEM) | (1 << CEC_LOG_ADDR_TYPE_TV)))) { dprintk(1, "two LAs is only allowed for audiosystem and TV\n"); return -EINVAL; } if (!(type_mask & ((1 << CEC_LOG_ADDR_TYPE_PLAYBACK) | (1 << CEC_LOG_ADDR_TYPE_RECORD)))) { dprintk(1, "an audiosystem/TV can only be combined with record or playback\n"); return -EINVAL; } } } /* Zero unused LAs */ for (i = log_addrs->num_log_addrs; i < CEC_MAX_LOG_ADDRS; i++) { log_addrs->primary_device_type[i] = 0; log_addrs->log_addr_type[i] = 0; log_addrs->all_device_types[i] = 0; memset(log_addrs->features[i], 0, sizeof(log_addrs->features[i])); } log_addrs->log_addr_mask = adap->log_addrs.log_addr_mask; adap->log_addrs = *log_addrs; err = cec_adap_enable(adap); if (!err && adap->phys_addr != CEC_PHYS_ADDR_INVALID) cec_claim_log_addrs(adap, block); return err; } int cec_s_log_addrs(struct cec_adapter *adap, struct cec_log_addrs *log_addrs, bool block) { int err; mutex_lock(&adap->lock); err = __cec_s_log_addrs(adap, log_addrs, block); mutex_unlock(&adap->lock); return err; } EXPORT_SYMBOL_GPL(cec_s_log_addrs); /* High-level core CEC message handling */ /* Fill in the Report Features message */ static void cec_fill_msg_report_features(struct cec_adapter *adap, struct cec_msg *msg, unsigned int la_idx) { const struct cec_log_addrs *las = &adap->log_addrs; const u8 *features = las->features[la_idx]; bool op_is_dev_features = false; unsigned int idx; /* Report Features */ msg->msg[0] = (las->log_addr[la_idx] << 4) | 0x0f; msg->len = 4; msg->msg[1] = CEC_MSG_REPORT_FEATURES; msg->msg[2] = adap->log_addrs.cec_version; msg->msg[3] = las->all_device_types[la_idx]; /* Write RC Profiles first, then Device Features */ for (idx = 0; idx < ARRAY_SIZE(las->features[0]); idx++) { msg->msg[msg->len++] = features[idx]; if ((features[idx] & CEC_OP_FEAT_EXT) == 0) { if (op_is_dev_features) break; op_is_dev_features = true; } } } /* Transmit the Feature Abort message */ static int cec_feature_abort_reason(struct cec_adapter *adap, struct cec_msg *msg, u8 reason) { struct cec_msg tx_msg = { }; /* * Don't reply with CEC_MSG_FEATURE_ABORT to a CEC_MSG_FEATURE_ABORT * message! */ if (msg->msg[1] == CEC_MSG_FEATURE_ABORT) return 0; /* Don't Feature Abort messages from 'Unregistered' */ if (cec_msg_initiator(msg) == CEC_LOG_ADDR_UNREGISTERED) return 0; cec_msg_set_reply_to(&tx_msg, msg); cec_msg_feature_abort(&tx_msg, msg->msg[1], reason); return cec_transmit_msg(adap, &tx_msg, false); } static int cec_feature_abort(struct cec_adapter *adap, struct cec_msg *msg) { return cec_feature_abort_reason(adap, msg, CEC_OP_ABORT_UNRECOGNIZED_OP); } static int cec_feature_refused(struct cec_adapter *adap, struct cec_msg *msg) { return cec_feature_abort_reason(adap, msg, CEC_OP_ABORT_REFUSED); } /* * Called when a CEC message is received. This function will do any * necessary core processing. The is_reply bool is true if this message * is a reply to an earlier transmit. * * The message is either a broadcast message or a valid directed message. */ static int cec_receive_notify(struct cec_adapter *adap, struct cec_msg *msg, bool is_reply) { bool is_broadcast = cec_msg_is_broadcast(msg); u8 dest_laddr = cec_msg_destination(msg); u8 init_laddr = cec_msg_initiator(msg); u8 devtype = cec_log_addr2dev(adap, dest_laddr); int la_idx = cec_log_addr2idx(adap, dest_laddr); bool from_unregistered = init_laddr == 0xf; struct cec_msg tx_cec_msg = { }; dprintk(2, "%s: %*ph\n", __func__, msg->len, msg->msg); /* If this is a CDC-Only device, then ignore any non-CDC messages */ if (cec_is_cdc_only(&adap->log_addrs) && msg->msg[1] != CEC_MSG_CDC_MESSAGE) return 0; /* Allow drivers to process the message first */ if (adap->ops->received && !adap->devnode.unregistered && adap->ops->received(adap, msg) != -ENOMSG) return 0; /* * REPORT_PHYSICAL_ADDR, CEC_MSG_USER_CONTROL_PRESSED and * CEC_MSG_USER_CONTROL_RELEASED messages always have to be * handled by the CEC core, even if the passthrough mode is on. * The others are just ignored if passthrough mode is on. */ switch (msg->msg[1]) { case CEC_MSG_GET_CEC_VERSION: case CEC_MSG_ABORT: case CEC_MSG_GIVE_DEVICE_POWER_STATUS: case CEC_MSG_GIVE_OSD_NAME: /* * These messages reply with a directed message, so ignore if * the initiator is Unregistered. */ if (!adap->passthrough && from_unregistered) return 0; fallthrough; case CEC_MSG_GIVE_DEVICE_VENDOR_ID: case CEC_MSG_GIVE_FEATURES: case CEC_MSG_GIVE_PHYSICAL_ADDR: /* * Skip processing these messages if the passthrough mode * is on. */ if (adap->passthrough) goto skip_processing; /* Ignore if addressing is wrong */ if (is_broadcast) return 0; break; case CEC_MSG_USER_CONTROL_PRESSED: case CEC_MSG_USER_CONTROL_RELEASED: /* Wrong addressing mode: don't process */ if (is_broadcast || from_unregistered) goto skip_processing; break; case CEC_MSG_REPORT_PHYSICAL_ADDR: /* * This message is always processed, regardless of the * passthrough setting. * * Exception: don't process if wrong addressing mode. */ if (!is_broadcast) goto skip_processing; break; default: break; } cec_msg_set_reply_to(&tx_cec_msg, msg); switch (msg->msg[1]) { /* The following messages are processed but still passed through */ case CEC_MSG_REPORT_PHYSICAL_ADDR: { u16 pa = (msg->msg[2] << 8) | msg->msg[3]; dprintk(1, "reported physical address %x.%x.%x.%x for logical address %d\n", cec_phys_addr_exp(pa), init_laddr); break; } case CEC_MSG_USER_CONTROL_PRESSED: if (!(adap->capabilities & CEC_CAP_RC) || !(adap->log_addrs.flags & CEC_LOG_ADDRS_FL_ALLOW_RC_PASSTHRU)) break; #ifdef CONFIG_MEDIA_CEC_RC switch (msg->msg[2]) { /* * Play function, this message can have variable length * depending on the specific play function that is used. */ case CEC_OP_UI_CMD_PLAY_FUNCTION: if (msg->len == 2) rc_keydown(adap->rc, RC_PROTO_CEC, msg->msg[2], 0); else rc_keydown(adap->rc, RC_PROTO_CEC, msg->msg[2] << 8 | msg->msg[3], 0); break; /* * Other function messages that are not handled. * Currently the RC framework does not allow to supply an * additional parameter to a keypress. These "keys" contain * other information such as channel number, an input number * etc. * For the time being these messages are not processed by the * framework and are simply forwarded to the user space. */ case CEC_OP_UI_CMD_SELECT_BROADCAST_TYPE: case CEC_OP_UI_CMD_SELECT_SOUND_PRESENTATION: case CEC_OP_UI_CMD_TUNE_FUNCTION: case CEC_OP_UI_CMD_SELECT_MEDIA_FUNCTION: case CEC_OP_UI_CMD_SELECT_AV_INPUT_FUNCTION: case CEC_OP_UI_CMD_SELECT_AUDIO_INPUT_FUNCTION: break; default: rc_keydown(adap->rc, RC_PROTO_CEC, msg->msg[2], 0); break; } #endif break; case CEC_MSG_USER_CONTROL_RELEASED: if (!(adap->capabilities & CEC_CAP_RC) || !(adap->log_addrs.flags & CEC_LOG_ADDRS_FL_ALLOW_RC_PASSTHRU)) break; #ifdef CONFIG_MEDIA_CEC_RC rc_keyup(adap->rc); #endif break; /* * The remaining messages are only processed if the passthrough mode * is off. */ case CEC_MSG_GET_CEC_VERSION: cec_msg_cec_version(&tx_cec_msg, adap->log_addrs.cec_version); return cec_transmit_msg(adap, &tx_cec_msg, false); case CEC_MSG_GIVE_PHYSICAL_ADDR: /* Do nothing for CEC switches using addr 15 */ if (devtype == CEC_OP_PRIM_DEVTYPE_SWITCH && dest_laddr == 15) return 0; cec_msg_report_physical_addr(&tx_cec_msg, adap->phys_addr, devtype); return cec_transmit_msg(adap, &tx_cec_msg, false); case CEC_MSG_GIVE_DEVICE_VENDOR_ID: if (adap->log_addrs.vendor_id == CEC_VENDOR_ID_NONE) return cec_feature_abort(adap, msg); cec_msg_device_vendor_id(&tx_cec_msg, adap->log_addrs.vendor_id); return cec_transmit_msg(adap, &tx_cec_msg, false); case CEC_MSG_ABORT: /* Do nothing for CEC switches */ if (devtype == CEC_OP_PRIM_DEVTYPE_SWITCH) return 0; return cec_feature_refused(adap, msg); case CEC_MSG_GIVE_OSD_NAME: { if (adap->log_addrs.osd_name[0] == 0) return cec_feature_abort(adap, msg); cec_msg_set_osd_name(&tx_cec_msg, adap->log_addrs.osd_name); return cec_transmit_msg(adap, &tx_cec_msg, false); } case CEC_MSG_GIVE_FEATURES: if (adap->log_addrs.cec_version < CEC_OP_CEC_VERSION_2_0) return cec_feature_abort(adap, msg); cec_fill_msg_report_features(adap, &tx_cec_msg, la_idx); return cec_transmit_msg(adap, &tx_cec_msg, false); default: /* * Unprocessed messages are aborted if userspace isn't doing * any processing either. */ if (!is_broadcast && !is_reply && !adap->follower_cnt && !adap->cec_follower && msg->msg[1] != CEC_MSG_FEATURE_ABORT) return cec_feature_abort(adap, msg); break; } skip_processing: /* If this was a reply, then we're done, unless otherwise specified */ if (is_reply && !(msg->flags & CEC_MSG_FL_REPLY_TO_FOLLOWERS)) return 0; /* * Send to the exclusive follower if there is one, otherwise send * to all followers. */ if (adap->cec_follower) cec_queue_msg_fh(adap->cec_follower, msg); else cec_queue_msg_followers(adap, msg); return 0; } /* * Helper functions to keep track of the 'monitor all' use count. * * These functions are called with adap->lock held. */ int cec_monitor_all_cnt_inc(struct cec_adapter *adap) { int ret; if (adap->monitor_all_cnt++) return 0; ret = cec_adap_enable(adap); if (ret) adap->monitor_all_cnt--; return ret; } void cec_monitor_all_cnt_dec(struct cec_adapter *adap) { if (WARN_ON(!adap->monitor_all_cnt)) return; if (--adap->monitor_all_cnt) return; WARN_ON(call_op(adap, adap_monitor_all_enable, false)); cec_adap_enable(adap); } /* * Helper functions to keep track of the 'monitor pin' use count. * * These functions are called with adap->lock held. */ int cec_monitor_pin_cnt_inc(struct cec_adapter *adap) { int ret; if (adap->monitor_pin_cnt++) return 0; ret = cec_adap_enable(adap); if (ret) adap->monitor_pin_cnt--; return ret; } void cec_monitor_pin_cnt_dec(struct cec_adapter *adap) { if (WARN_ON(!adap->monitor_pin_cnt)) return; if (--adap->monitor_pin_cnt) return; WARN_ON(call_op(adap, adap_monitor_pin_enable, false)); cec_adap_enable(adap); } #ifdef CONFIG_DEBUG_FS /* * Log the current state of the CEC adapter. * Very useful for debugging. */ int cec_adap_status(struct seq_file *file, void *priv) { struct cec_adapter *adap = dev_get_drvdata(file->private); struct cec_data *data; mutex_lock(&adap->lock); seq_printf(file, "enabled: %d\n", adap->is_enabled); seq_printf(file, "configured: %d\n", adap->is_configured); seq_printf(file, "configuring: %d\n", adap->is_configuring); seq_printf(file, "phys_addr: %x.%x.%x.%x\n", cec_phys_addr_exp(adap->phys_addr)); seq_printf(file, "number of LAs: %d\n", adap->log_addrs.num_log_addrs); seq_printf(file, "LA mask: 0x%04x\n", adap->log_addrs.log_addr_mask); if (adap->cec_follower) seq_printf(file, "has CEC follower%s\n", adap->passthrough ? " (in passthrough mode)" : ""); if (adap->cec_initiator) seq_puts(file, "has CEC initiator\n"); if (adap->monitor_all_cnt) seq_printf(file, "file handles in Monitor All mode: %u\n", adap->monitor_all_cnt); if (adap->monitor_pin_cnt) seq_printf(file, "file handles in Monitor Pin mode: %u\n", adap->monitor_pin_cnt); if (adap->tx_timeouts) { seq_printf(file, "transmit timeouts: %u\n", adap->tx_timeouts); adap->tx_timeouts = 0; } data = adap->transmitting; if (data) seq_printf(file, "transmitting message: %*ph (reply: %02x, timeout: %ums)\n", data->msg.len, data->msg.msg, data->msg.reply, data->msg.timeout); seq_printf(file, "pending transmits: %u\n", adap->transmit_queue_sz); list_for_each_entry(data, &adap->transmit_queue, list) { seq_printf(file, "queued tx message: %*ph (reply: %02x, timeout: %ums)\n", data->msg.len, data->msg.msg, data->msg.reply, data->msg.timeout); } list_for_each_entry(data, &adap->wait_queue, list) { seq_printf(file, "message waiting for reply: %*ph (reply: %02x, timeout: %ums)\n", data->msg.len, data->msg.msg, data->msg.reply, data->msg.timeout); } call_void_op(adap, adap_status, file); mutex_unlock(&adap->lock); return 0; } #endif |