/**************************************************************************** * drivers/sensors/sensor_rpmsg.c * * Licensed to the Apache Software Foundation (ASF) under one or more * contributor license agreements. See the NOTICE file distributed with * this work for additional information regarding copyright ownership. The * ASF licenses this file to you under the Apache License, Version 2.0 (the * "License"); you may not use this file except in compliance with the * License. You may obtain a copy of the License at * * http://www.apache.org/licenses/LICENSE-2.0 * * Unless required by applicable law or agreed to in writing, software * distributed under the License is distributed on an "AS IS" BASIS, WITHOUT * WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. See the * License for the specific language governing permissions and limitations * under the License. * ****************************************************************************/ /**************************************************************************** * Included Files ****************************************************************************/ #include #include #include #include #include #include #include #include /**************************************************************************** * Pre-processor Definitions ****************************************************************************/ #define SENSOR_RPMSG_EPT_NAME "rpmsg-sensor" #define SENSOR_RPMSG_ADVERTISE 0 #define SENSOR_RPMSG_ADVERTISE_ACK 1 #define SENSOR_RPMSG_UNADVERTISE 2 #define SENSOR_RPMSG_SUBSCRIBE 3 #define SENSOR_RPMSG_SUBSCRIBE_ACK 4 #define SENSOR_RPMSG_UNSUBSCRIBE 5 #define SENSOR_RPMSG_PUBLISH 6 #define SENSOR_RPMSG_IOCTL 7 #define SENSOR_RPMSG_IOCTL_ACK 8 #define SENSOR_RPMSG_FUNCTION(name, cmd, arg1, arg2, size, wait) \ static int sensor_rpmsg_##name(FAR struct sensor_lowerhalf_s *lower, \ FAR struct file *filep, \ unsigned long arg1) \ { \ FAR struct sensor_rpmsg_dev_s *dev = lower->priv; \ FAR struct sensor_lowerhalf_s *drv = dev->drv; \ int ret; \ \ if (drv->ops->name) \ { \ return drv->ops->name(drv, filep, arg2); \ } \ else if (!(filep->f_oflags & SENSOR_REMOTE)) \ { \ ret = sensor_rpmsg_ioctl(dev, cmd, arg1, size, wait); \ return wait ? ret : 0; \ } \ else \ { \ return wait ? -ENOTSUP : 0; \ } \ } \ /**************************************************************************** * Private Types ****************************************************************************/ /* This structure describes the context of sensor rpmsg device driver. */ struct sensor_rpmsg_dev_s { struct sensor_lowerhalf_s lower; FAR struct sensor_lowerhalf_s *drv; struct list_node node; struct list_node stublist; struct list_node proxylist; uint8_t nadvertisers; uint8_t nsubscribers; FAR void *upper; sensor_push_event_t push_event; char path[1]; }; /* This structure describes the context of sensor rpmsg endpoint. */ struct sensor_rpmsg_ept_s { struct list_node node; struct rpmsg_endpoint ept; FAR struct rpmsg_device *rdev; struct work_s work; rmutex_t lock; FAR void *buffer; uint64_t expire; uint32_t space; size_t written; }; /* This structure describes the stub info about remote subscribers. */ struct sensor_rpmsg_stub_s { struct list_node node; FAR struct rpmsg_endpoint *ept; uint64_t cookie; struct file file; }; /* This structure describes the proxy info about remote advertisers. */ struct sensor_rpmsg_proxy_s { struct list_node node; FAR struct rpmsg_endpoint *ept; uint64_t cookie; }; /* Remote message structure */ /* This structure describes the message about initiating a remote * subscription and remote advertisement. */ struct sensor_rpmsg_advsub_s { uint32_t command; uint32_t nbuffer; uint64_t cookie; uint32_t persist; char path[1]; }; /* The structure sensor_rpmsg_cell_s describes a data message, * include remote receiver, the length of data and the data payload. * The structure sensor_rpmsg_data_s describes a set of data message. */ struct sensor_rpmsg_cell_s { uint64_t cookie; uint32_t len; char data[0]; }; struct sensor_rpmsg_data_s { uint32_t command; uint32_t reserved; struct sensor_rpmsg_cell_s cell[0]; }; /* This structure uses to send ioctl from remote device to physical device, * it supports pass pointer to remove device by cookie_xx member. */ struct sensor_rpmsg_ioctl_cookie_s { sem_t sem; FAR void *data; int result; }; struct sensor_rpmsg_ioctl_s { uint32_t command; int32_t result; uint64_t cookie; uint64_t proxy; int32_t request; uint32_t arglen; union { uint64_t arg; char argbuf[0]; }; }; /**************************************************************************** * Private Function Prototypes ****************************************************************************/ static int sensor_rpmsg_open(FAR struct sensor_lowerhalf_s *lower, FAR struct file *filep); static int sensor_rpmsg_close(FAR struct sensor_lowerhalf_s *lower, FAR struct file *filep); static int sensor_rpmsg_activate(FAR struct sensor_lowerhalf_s *lower, FAR struct file *filep, bool enable); static int sensor_rpmsg_set_interval(FAR struct sensor_lowerhalf_s *lower, FAR struct file *filep, FAR unsigned long *period_us); static int sensor_rpmsg_batch(FAR struct sensor_lowerhalf_s *lower, FAR struct file *filep, FAR unsigned long *latency_us); static int sensor_rpmsg_selftest(FAR struct sensor_lowerhalf_s *lower, FAR struct file *filep, unsigned long arg); static int sensor_rpmsg_set_calibvalue(FAR struct sensor_lowerhalf_s *lower, FAR struct file *filep, unsigned long arg); static int sensor_rpmsg_calibrate(FAR struct sensor_lowerhalf_s *lower, FAR struct file *filep, unsigned long arg); static int sensor_rpmsg_control(FAR struct sensor_lowerhalf_s *lower, FAR struct file *filep, int cmd, unsigned long arg); static int sensor_rpmsg_adv_handler(FAR struct rpmsg_endpoint *ept, FAR void *data, size_t len, uint32_t src, FAR void *priv); static int sensor_rpmsg_advack_handler(FAR struct rpmsg_endpoint *ept, FAR void *data, size_t len, uint32_t src, FAR void *priv); static int sensor_rpmsg_unadv_handler(FAR struct rpmsg_endpoint *ept, FAR void *data, size_t len, uint32_t src, FAR void *priv); static int sensor_rpmsg_sub_handler(FAR struct rpmsg_endpoint *ept, FAR void *data, size_t len, uint32_t src, FAR void *priv); static int sensor_rpmsg_suback_handler(FAR struct rpmsg_endpoint *ept, FAR void *data, size_t len, uint32_t src, FAR void *priv); static int sensor_rpmsg_unsub_handler(FAR struct rpmsg_endpoint *ept, FAR void *data, size_t len, uint32_t src, FAR void *priv); static int sensor_rpmsg_publish_handler(FAR struct rpmsg_endpoint *ept, FAR void *data, size_t len, uint32_t src, FAR void *priv); static int sensor_rpmsg_ioctl_handler(FAR struct rpmsg_endpoint *ept, FAR void *data, size_t len, uint32_t src, FAR void *priv); static int sensor_rpmsg_ioctlack_handler(FAR struct rpmsg_endpoint *ept, FAR void *data, size_t len, uint32_t src, FAR void *priv); static void sensor_rpmsg_push_event_one(FAR struct sensor_rpmsg_dev_s *dev, FAR struct sensor_rpmsg_stub_s *stub); /**************************************************************************** * Private Data ****************************************************************************/ static const struct sensor_ops_s g_sensor_rpmsg_ops = { .open = sensor_rpmsg_open, .close = sensor_rpmsg_close, .activate = sensor_rpmsg_activate, .set_interval = sensor_rpmsg_set_interval, .batch = sensor_rpmsg_batch, .selftest = sensor_rpmsg_selftest, .set_calibvalue = sensor_rpmsg_set_calibvalue, .calibrate = sensor_rpmsg_calibrate, .control = sensor_rpmsg_control }; static const rpmsg_ept_cb g_sensor_rpmsg_handler[] = { [SENSOR_RPMSG_ADVERTISE] = sensor_rpmsg_adv_handler, [SENSOR_RPMSG_ADVERTISE_ACK] = sensor_rpmsg_advack_handler, [SENSOR_RPMSG_UNADVERTISE] = sensor_rpmsg_unadv_handler, [SENSOR_RPMSG_SUBSCRIBE] = sensor_rpmsg_sub_handler, [SENSOR_RPMSG_SUBSCRIBE_ACK] = sensor_rpmsg_suback_handler, [SENSOR_RPMSG_UNSUBSCRIBE] = sensor_rpmsg_unsub_handler, [SENSOR_RPMSG_PUBLISH] = sensor_rpmsg_publish_handler, [SENSOR_RPMSG_IOCTL] = sensor_rpmsg_ioctl_handler, [SENSOR_RPMSG_IOCTL_ACK] = sensor_rpmsg_ioctlack_handler, }; static struct list_node g_devlist = LIST_INITIAL_VALUE(g_devlist); static struct list_node g_eptlist = LIST_INITIAL_VALUE(g_eptlist); static rmutex_t g_ept_lock = NXRMUTEX_INITIALIZER; static rmutex_t g_dev_lock = NXRMUTEX_INITIALIZER; /**************************************************************************** * Private Functions ****************************************************************************/ static void sensor_rpmsg_lock(FAR struct sensor_rpmsg_dev_s *dev) { dev->lower.sensor_lock(dev->upper); } static void sensor_rpmsg_unlock(FAR struct sensor_rpmsg_dev_s *dev) { dev->lower.sensor_unlock(dev->upper); } static void sensor_rpmsg_advsub_one(FAR struct sensor_rpmsg_dev_s *dev, FAR struct rpmsg_endpoint *ept, int command) { FAR struct sensor_rpmsg_advsub_s *msg; uint32_t space; int len = strlen(dev->path) + 1; int ret; msg = rpmsg_get_tx_payload_buffer(ept, &space, true); if (!msg) { snerr("ERROR: advsub:%d get buffer failed:%s, %s\n", command, dev->path, rpmsg_get_cpuname(ept->rdev)); return; } msg->command = command; msg->cookie = (uint64_t)(uintptr_t)dev; msg->nbuffer = dev->lower.nbuffer; msg->persist = dev->lower.persist; memcpy(msg->path, dev->path, len); ret = rpmsg_send_nocopy(ept, msg, sizeof(*msg) + len); if (ret < 0) { snerr("ERROR: advsub:%d rpmsg send failed:%s, %d, %s\n", command, dev->path, ret, rpmsg_get_cpuname(ept->rdev)); } } static void sensor_rpmsg_advsub(FAR struct sensor_rpmsg_dev_s *dev, int command) { FAR struct sensor_rpmsg_ept_s *sre; /* Broadcast advertise/subscribe message to all ready ept */ nxrmutex_lock(&g_ept_lock); list_for_every_entry(&g_eptlist, sre, struct sensor_rpmsg_ept_s, node) { sensor_rpmsg_advsub_one(dev, &sre->ept, command); } nxrmutex_unlock(&g_ept_lock); } static int sensor_rpmsg_ioctl(FAR struct sensor_rpmsg_dev_s *dev, int cmd, unsigned long arg, size_t len, bool wait) { struct sensor_rpmsg_ioctl_cookie_s cookie; FAR struct sensor_rpmsg_proxy_s *proxy; FAR struct sensor_rpmsg_ioctl_s *msg; uint32_t space; int ret = -ENOTTY; if (wait) { cookie.data = (FAR void *)(uintptr_t)arg; cookie.result = -ENXIO; nxsem_init(&cookie.sem, 0, 0); } /* All control is always send to own proxy(remote advertisers), * if device doesn't have proxy, it must return -ENOTTY. */ sensor_rpmsg_lock(dev); list_for_every_entry(&dev->proxylist, proxy, struct sensor_rpmsg_proxy_s, node) { msg = rpmsg_get_tx_payload_buffer(proxy->ept, &space, true); if (!msg) { ret = -ENOMEM; snerr("ERROR: ioctl get buffer failed:%s, %s\n", dev->path, rpmsg_get_cpuname(proxy->ept->rdev)); break; } msg->command = SENSOR_RPMSG_IOCTL; msg->cookie = wait ? (uint64_t)(uintptr_t)&cookie : 0; msg->proxy = proxy->cookie; msg->request = cmd; msg->arglen = len; if (len > 0) { memcpy(msg->argbuf, (FAR void *)(uintptr_t)arg, len); } else { msg->arg = arg; } ret = rpmsg_send_nocopy(proxy->ept, msg, sizeof(*msg) + len); if (ret < 0) { snerr("ERROR: ioctl rpmsg send failed:%s, %d, %s\n", dev->path, ret, rpmsg_get_cpuname(proxy->ept->rdev)); break; } if (!wait) { continue; } sensor_rpmsg_unlock(dev); ret = rpmsg_wait(proxy->ept, &cookie.sem); sensor_rpmsg_lock(dev); if (ret < 0) { snerr("ERROR: ioctl rpmsg wait failed:%s, %d, %s\n", dev->path, ret, rpmsg_get_cpuname(proxy->ept->rdev)); break; } ret = cookie.result; if (ret < 0 && ret != -ENOTTY) { break; } } sensor_rpmsg_unlock(dev); if (wait) { nxsem_destroy(&cookie.sem); } return ret; } static FAR struct sensor_rpmsg_proxy_s * sensor_rpmsg_alloc_proxy(FAR struct sensor_rpmsg_dev_s *dev, FAR struct rpmsg_endpoint *ept, FAR struct sensor_rpmsg_advsub_s *msg) { FAR struct sensor_rpmsg_proxy_s *proxy; struct sensor_state_s state; struct file file; int ret; sensor_rpmsg_lock(dev); list_for_every_entry(&dev->proxylist, proxy, struct sensor_rpmsg_proxy_s, node) { if (proxy->ept == ept && proxy->cookie == msg->cookie) { sensor_rpmsg_unlock(dev); return proxy; } } sensor_rpmsg_unlock(dev); /* Create new proxy to represent a remote advertiser */ proxy = kmm_malloc(sizeof(*proxy)); if (!proxy) { return NULL; } proxy->ept = ept; proxy->cookie = msg->cookie; ret = file_open(&file, dev->path, SENSOR_REMOTE); if (ret < 0) { kmm_free(proxy); return NULL; } file_ioctl(&file, SNIOC_SET_BUFFER_NUMBER, msg->nbuffer); file_ioctl(&file, SNIOC_GET_STATE, &state); file_close(&file); sensor_rpmsg_lock(dev); if (msg->persist) { dev->drv->persist = true; dev->lower.persist = true; } list_add_tail(&dev->proxylist, &proxy->node); sensor_rpmsg_unlock(dev); /* sync interval and latency */ if (state.min_interval != ULONG_MAX) { sensor_rpmsg_ioctl(dev, SNIOC_SET_INTERVAL, state.min_interval, 0, false); } if (state.min_latency != ULONG_MAX) { sensor_rpmsg_ioctl(dev, SNIOC_BATCH, state.min_latency, 0, false); } return proxy; } static FAR struct sensor_rpmsg_stub_s * sensor_rpmsg_alloc_stub(FAR struct sensor_rpmsg_dev_s *dev, FAR struct rpmsg_endpoint *ept, uint64_t cookie) { FAR struct sensor_rpmsg_stub_s *stub; int ret; sensor_rpmsg_lock(dev); list_for_every_entry(&dev->stublist, stub, struct sensor_rpmsg_stub_s, node) { if (stub->ept == ept && stub->cookie == cookie) { sensor_rpmsg_unlock(dev); return stub; } } sensor_rpmsg_unlock(dev); /* Create new stub to represent a remote subscribers */ stub = kmm_malloc(sizeof(*stub)); if (!stub) { return NULL; } stub->ept = ept; stub->cookie = cookie; ret = file_open(&stub->file, dev->path, O_RDOK | O_NONBLOCK | SENSOR_REMOTE); if (ret < 0) { kmm_free(stub); return NULL; } sensor_rpmsg_lock(dev); list_add_tail(&dev->stublist, &stub->node); if (dev->lower.persist) { sensor_rpmsg_push_event_one(dev, stub); } sensor_rpmsg_unlock(dev); return stub; } static void sensor_rpmsg_free_proxy(FAR struct sensor_rpmsg_proxy_s *proxy) { list_delete(&proxy->node); kmm_free(proxy); } static void sensor_rpmsg_free_stub(FAR struct sensor_rpmsg_stub_s *stub) { list_delete(&stub->node); file_close(&stub->file); kmm_free(stub); } static int sensor_rpmsg_open(FAR struct sensor_lowerhalf_s *lower, FAR struct file *filep) { FAR struct sensor_rpmsg_dev_s *dev = lower->priv; FAR struct sensor_lowerhalf_s *drv = dev->drv; int ret; if (drv->ops->open) { ret = drv->ops->open(drv, filep); if (ret < 0) { return ret; } } if (filep->f_oflags & SENSOR_REMOTE) { return 0; } sensor_rpmsg_lock(dev); if (filep->f_oflags & O_WROK) { if (dev->nadvertisers++ == 0) { sensor_rpmsg_advsub(dev, SENSOR_RPMSG_ADVERTISE); } } if (filep->f_oflags & O_RDOK) { if (dev->nsubscribers++ == 0) { sensor_rpmsg_advsub(dev, SENSOR_RPMSG_SUBSCRIBE); } } sensor_rpmsg_unlock(dev); return 0; } static int sensor_rpmsg_close(FAR struct sensor_lowerhalf_s *lower, FAR struct file *filep) { FAR struct sensor_rpmsg_dev_s *dev = lower->priv; FAR struct sensor_lowerhalf_s *drv = dev->drv; FAR struct sensor_rpmsg_proxy_s *proxy; FAR struct sensor_rpmsg_proxy_s *ptmp; FAR struct sensor_rpmsg_stub_s *stub; FAR struct sensor_rpmsg_stub_s *stmp; int ret = 0; if (drv->ops->close) { ret = drv->ops->close(drv, filep); } if (filep->f_oflags & SENSOR_REMOTE) { return ret; } sensor_rpmsg_lock(dev); if (filep->f_oflags & O_WROK) { if (dev->nadvertisers == 1) { sensor_rpmsg_advsub(dev, SENSOR_RPMSG_UNADVERTISE); list_for_every_entry_safe(&dev->stublist, stub, stmp, struct sensor_rpmsg_stub_s, node) { sensor_rpmsg_free_stub(stub); } } dev->nadvertisers--; } if (filep->f_oflags & O_RDOK) { if (dev->nsubscribers == 1) { sensor_rpmsg_advsub(dev, SENSOR_RPMSG_UNSUBSCRIBE); list_for_every_entry_safe(&dev->proxylist, proxy, ptmp, struct sensor_rpmsg_proxy_s, node) { sensor_rpmsg_free_proxy(proxy); } } dev->nsubscribers--; } sensor_rpmsg_unlock(dev); return ret; } static int sensor_rpmsg_activate(FAR struct sensor_lowerhalf_s *lower, FAR struct file *filep, bool enable) { FAR struct sensor_rpmsg_dev_s *dev = lower->priv; FAR struct sensor_lowerhalf_s *drv = dev->drv; if (drv->ops->activate) { return drv->ops->activate(drv, filep, enable); } return 0; } SENSOR_RPMSG_FUNCTION(set_interval, SNIOC_SET_INTERVAL, *interval, interval, 0, false) SENSOR_RPMSG_FUNCTION(batch, SNIOC_BATCH, *latency, latency, 0, false) SENSOR_RPMSG_FUNCTION(selftest, SNIOC_SELFTEST, arg, arg, 0, true) SENSOR_RPMSG_FUNCTION(set_calibvalue, SNIOC_SET_CALIBVALUE, arg, arg, 256, true) SENSOR_RPMSG_FUNCTION(calibrate, SNIOC_CALIBRATE, arg, arg, 256, true) static int sensor_rpmsg_control(FAR struct sensor_lowerhalf_s *lower, FAR struct file *filep, int cmd, unsigned long arg) { FAR struct sensor_rpmsg_dev_s *dev = lower->priv; FAR struct sensor_lowerhalf_s *drv = dev->drv; FAR struct sensor_ioctl_s *ioctl = (FAR void *)(uintptr_t)arg; if (drv->ops->control) { return drv->ops->control(drv, filep, cmd, arg); } else if (!(filep->f_oflags & SENSOR_REMOTE) && _SNIOCVALID(cmd)) { return sensor_rpmsg_ioctl(dev, cmd, arg, sizeof(*ioctl) + ioctl->len, true); } return -ENOTTY; } static void sensor_rpmsg_data_worker(FAR void *arg) { FAR struct sensor_rpmsg_ept_s *sre = arg; nxrmutex_lock(&sre->lock); if (sre->buffer) { rpmsg_send_nocopy(&sre->ept, sre->buffer, sre->written); sre->buffer = NULL; } nxrmutex_unlock(&sre->lock); } static void sensor_rpmsg_push_event_one(FAR struct sensor_rpmsg_dev_s *dev, FAR struct sensor_rpmsg_stub_s *stub) { FAR struct sensor_rpmsg_cell_s *cell; FAR struct sensor_rpmsg_ept_s *sre; FAR struct sensor_rpmsg_data_s *msg; struct sensor_ustate_s state; uint64_t now; bool updated; int ret; /* Get state of device to do send data with timeout */ ret = file_ioctl(&stub->file, SNIOC_GET_USTATE, &state); if (ret < 0) { return; } if (state.interval == ULONG_MAX) { state.interval = 0; } sre = container_of(stub->ept, struct sensor_rpmsg_ept_s, ept); nxrmutex_lock(&sre->lock); /* Cancel work to fill new data to buffer */ if (sre->buffer) { work_cancel(HPWORK, &sre->work); } for (; ; ) { ret = file_ioctl(&stub->file, SNIOC_UPDATED, &updated); if (ret < 0 || !updated) { break; } /* If buffer isn't created or it doesn't have enough space to fill * new data, you should create or send this buffer at once. */ if (!sre->buffer || sre->written + sizeof(*cell) + state.esize > sre->space) { if (sre->buffer) { rpmsg_send_nocopy(&sre->ept, sre->buffer, sre->written); } msg = rpmsg_get_tx_payload_buffer(&sre->ept, &sre->space, true); sre->buffer = msg; if (!msg) { snerr("ERROR: push event get buffer failed:%s\n", rpmsg_get_cpuname(sre->ept.rdev)); nxrmutex_unlock(&sre->lock); return; } msg->command = SENSOR_RPMSG_PUBLISH; sre->written = sizeof(*msg); sre->expire = UINT64_MAX; } cell = sre->buffer + sre->written; ret = file_read(&stub->file, cell->data, sre->space - sre->written - sizeof(*cell)); if (ret <= 0) { break; } cell->len = ret; cell->cookie = stub->cookie; sre->written += (sizeof(*cell) + ret + 0x7) & ~0x7; } /* If buffer timeout is expired, do rpmsg_send_nocopy, otherwise using * delay work to send data. */ now = sensor_get_timestamp(); if (sre->expire <= now && sre->buffer) { ret = rpmsg_send_nocopy(&sre->ept, sre->buffer, sre->written); sre->buffer = NULL; if (ret < 0) { snerr("ERROR: push event rpmsg send failed:%d, %s\n", ret, rpmsg_get_cpuname(sre->ept.rdev)); } } else { if (sre->expire == UINT64_MAX || sre->expire - now > state.interval / 2) { sre->expire = now + state.interval / 2; } work_queue(HPWORK, &sre->work, sensor_rpmsg_data_worker, sre, (sre->expire - now) / USEC_PER_TICK); } nxrmutex_unlock(&sre->lock); } static ssize_t sensor_rpmsg_push_event(FAR void *priv, FAR const void *data, size_t bytes) { FAR struct sensor_rpmsg_dev_s *dev = priv; FAR struct sensor_rpmsg_stub_s *stub; ssize_t ret; /* Push new data to upperhalf driver's circular buffer */ ret = dev->push_event(dev->upper, data, bytes); if (ret < 0) { return ret; } /* Send new data to own proxy(remote subscribers), don't care whether * is successful, and must return length of written. */ sensor_rpmsg_lock(dev); list_for_every_entry(&dev->stublist, stub, struct sensor_rpmsg_stub_s, node) { sensor_rpmsg_push_event_one(dev, stub); } sensor_rpmsg_unlock(dev); return ret; } static FAR struct sensor_rpmsg_dev_s * sensor_rpmsg_find_dev(FAR const char *path) { FAR struct sensor_rpmsg_dev_s *dev; nxrmutex_lock(&g_dev_lock); list_for_every_entry(&g_devlist, dev, struct sensor_rpmsg_dev_s, node) { if (strcmp(dev->path, path) == 0) { nxrmutex_unlock(&g_dev_lock); return dev; } } nxrmutex_unlock(&g_dev_lock); return NULL; } static int sensor_rpmsg_adv_handler(FAR struct rpmsg_endpoint *ept, FAR void *data, size_t len, uint32_t src, FAR void *priv) { FAR struct sensor_rpmsg_advsub_s *msg = data; FAR struct sensor_rpmsg_proxy_s *proxy; FAR struct sensor_rpmsg_dev_s *dev; int ret; dev = sensor_rpmsg_find_dev(msg->path); if (!dev || !dev->nsubscribers) { return 0; } proxy = sensor_rpmsg_alloc_proxy(dev, ept, msg); if (!proxy) { snerr("ERROR: adv alloc proxy failed:%s\n", dev->path); } else { msg->cookie = (uint64_t)(uintptr_t)dev; msg->command = SENSOR_RPMSG_ADVERTISE_ACK; ret = rpmsg_send(ept, msg, len); if (ret < 0) { sensor_rpmsg_lock(dev); sensor_rpmsg_free_proxy(proxy); sensor_rpmsg_unlock(dev); snerr("ERROR: adv rpmsg send failed:%s, %d, %s\n", dev->path, ret, rpmsg_get_cpuname(ept->rdev)); } } return 0; } static int sensor_rpmsg_advack_handler(FAR struct rpmsg_endpoint *ept, FAR void *data, size_t len, uint32_t src, FAR void *priv) { FAR struct sensor_rpmsg_advsub_s *msg = data; FAR struct sensor_rpmsg_dev_s *dev; dev = sensor_rpmsg_find_dev(msg->path); if (dev && !sensor_rpmsg_alloc_stub(dev, ept, msg->cookie)) { sensor_rpmsg_advsub_one(dev, ept, SENSOR_RPMSG_UNADVERTISE); snerr("ERROR: advack failed:%s, %s\n", dev->path, rpmsg_get_cpuname(ept->rdev)); } return 0; } static int sensor_rpmsg_unadv_handler(FAR struct rpmsg_endpoint *ept, FAR void *data, size_t len, uint32_t src, FAR void *priv) { FAR struct sensor_rpmsg_advsub_s *msg = data; FAR struct sensor_rpmsg_proxy_s *proxy; FAR struct sensor_rpmsg_dev_s *dev; dev = sensor_rpmsg_find_dev(msg->path); if (!dev) { return 0; } sensor_rpmsg_lock(dev); list_for_every_entry(&dev->proxylist, proxy, struct sensor_rpmsg_proxy_s, node) { if (proxy->ept == ept && proxy->cookie == msg->cookie) { sensor_rpmsg_free_proxy(proxy); break; } } sensor_rpmsg_unlock(dev); return 0; } static int sensor_rpmsg_sub_handler(FAR struct rpmsg_endpoint *ept, FAR void *data, size_t len, uint32_t src, FAR void *priv) { FAR struct sensor_rpmsg_advsub_s *msg = data; FAR struct sensor_rpmsg_dev_s *dev; FAR struct sensor_rpmsg_stub_s *stub; int ret; dev = sensor_rpmsg_find_dev(msg->path); if (!dev) { return 0; } stub = sensor_rpmsg_alloc_stub(dev, ept, msg->cookie); if (!stub) { snerr("ERROR: sub alloc stub failed:%s\n", dev->path); } else { msg->cookie = (uint64_t)(uintptr_t)dev; msg->command = SENSOR_RPMSG_SUBSCRIBE_ACK; msg->nbuffer = dev->lower.nbuffer; msg->persist = dev->lower.persist; ret = rpmsg_send(ept, msg, len); if (ret < 0) { sensor_rpmsg_lock(dev); sensor_rpmsg_free_stub(stub); sensor_rpmsg_unlock(dev); snerr("ERROR: sub rpmsg send failed:%s, %d, %s\n", dev->path, ret, rpmsg_get_cpuname(ept->rdev)); } } return 0; } static int sensor_rpmsg_suback_handler(FAR struct rpmsg_endpoint *ept, FAR void *data, size_t len, uint32_t src, FAR void *priv) { FAR struct sensor_rpmsg_advsub_s *msg = data; FAR struct sensor_rpmsg_dev_s *dev; dev = sensor_rpmsg_find_dev(msg->path); if (dev && (!dev->nsubscribers || !sensor_rpmsg_alloc_proxy(dev, ept, msg))) { sensor_rpmsg_advsub_one(dev, ept, SENSOR_RPMSG_UNSUBSCRIBE); snerr("ERROR: suback failed:%s\n", dev->path); } return 0; } static int sensor_rpmsg_unsub_handler(FAR struct rpmsg_endpoint *ept, FAR void *data, size_t len, uint32_t src, FAR void *priv) { FAR struct sensor_rpmsg_advsub_s *msg = data; FAR struct sensor_rpmsg_dev_s *dev; FAR struct sensor_rpmsg_stub_s *stub; dev = sensor_rpmsg_find_dev(msg->path); if (!dev) { return 0; } sensor_rpmsg_lock(dev); list_for_every_entry(&dev->stublist, stub, struct sensor_rpmsg_stub_s, node) { if (stub->ept == ept && stub->cookie == msg->cookie) { sensor_rpmsg_free_stub(stub); break; } } sensor_rpmsg_unlock(dev); return 0; } static int sensor_rpmsg_publish_handler(FAR struct rpmsg_endpoint *ept, FAR void *data, size_t len, uint32_t src, FAR void *priv) { FAR struct sensor_rpmsg_data_s *msg = data; FAR struct sensor_rpmsg_cell_s *cell; FAR struct sensor_rpmsg_dev_s *dev; size_t written = sizeof(*msg); while (written < len) { cell = (FAR struct sensor_rpmsg_cell_s *) ((FAR char *)data + written); dev = (FAR struct sensor_rpmsg_dev_s *)(uintptr_t)cell->cookie; dev->push_event(dev->upper, cell->data, cell->len); written += sizeof(*cell) + cell->len + 0x7; written &= ~0x7; } return 0; } static int sensor_rpmsg_ioctl_handler(FAR struct rpmsg_endpoint *ept, FAR void *data, size_t len, uint32_t src, FAR void *priv) { FAR struct sensor_rpmsg_ioctl_s *msg = data; FAR struct sensor_rpmsg_stub_s *stub; FAR struct sensor_rpmsg_dev_s *dev; unsigned long arg; int ret; arg = msg->arglen > 0 ? (unsigned long)(uintptr_t)msg->argbuf : msg->arg; dev = (FAR struct sensor_rpmsg_dev_s *)(uintptr_t)msg->proxy; sensor_rpmsg_lock(dev); list_for_every_entry(&dev->stublist, stub, struct sensor_rpmsg_stub_s, node) { if (stub->ept == ept) { msg->result = file_ioctl(&stub->file, msg->request, arg); if (msg->cookie) { msg->command = SENSOR_RPMSG_IOCTL_ACK; ret = rpmsg_send(ept, msg, len); if (ret < 0) { snerr("ERROR: ioctl rpmsg send failed:%s, %d, %s\n", dev->path, ret, rpmsg_get_cpuname(ept->rdev)); } } break; } } sensor_rpmsg_unlock(dev); return 0; } static int sensor_rpmsg_ioctlack_handler(FAR struct rpmsg_endpoint *ept, FAR void *data, size_t len, uint32_t src, FAR void *priv) { FAR struct sensor_rpmsg_ioctl_cookie_s *cookie; FAR struct sensor_rpmsg_ioctl_s *msg = data; cookie = (FAR struct sensor_rpmsg_ioctl_cookie_s *) (uintptr_t)msg->cookie; cookie->result = msg->result; if (msg->result >= 0 && msg->arglen > 0) { memcpy(cookie->data, msg->argbuf, msg->arglen); } rpmsg_post(ept, &cookie->sem); return 0; } static int sensor_rpmsg_ept_cb(FAR struct rpmsg_endpoint *ept, FAR void *data, size_t len, uint32_t src, FAR void *priv) { FAR struct sensor_rpmsg_advsub_s *msg = data; if (msg->command < sizeof(g_sensor_rpmsg_handler) / sizeof(g_sensor_rpmsg_handler[0])) { return g_sensor_rpmsg_handler[msg->command](ept, data, len, src, priv); } return -EINVAL; } static void sensor_rpmsg_ns_unbind_cb(FAR struct rpmsg_endpoint *ept) { FAR struct sensor_rpmsg_ept_s *sre; FAR struct sensor_rpmsg_dev_s *dev; FAR struct sensor_rpmsg_stub_s *stub; FAR struct sensor_rpmsg_proxy_s *proxy; sre = container_of(ept, struct sensor_rpmsg_ept_s, ept); /* Remove all proxy and stub info in sensor device with the ept * destoryed. */ nxrmutex_lock(&g_dev_lock); list_for_every_entry(&g_devlist, dev, struct sensor_rpmsg_dev_s, node) { sensor_rpmsg_lock(dev); list_for_every_entry(&dev->proxylist, proxy, struct sensor_rpmsg_proxy_s, node) { if (proxy->ept == ept) { sensor_rpmsg_free_proxy(proxy); break; } } list_for_every_entry(&dev->stublist, stub, struct sensor_rpmsg_stub_s, node) { if (stub->ept == ept) { sensor_rpmsg_free_stub(stub); break; } } sensor_rpmsg_unlock(dev); } nxrmutex_unlock(&g_dev_lock); nxrmutex_lock(&g_ept_lock); list_delete(&sre->node); nxrmutex_unlock(&g_ept_lock); nxrmutex_destroy(&sre->lock); kmm_free(sre); rpmsg_destroy_ept(ept); } static void sensor_rpmsg_device_ns_bound(FAR struct rpmsg_endpoint *ept) { FAR struct sensor_rpmsg_ept_s *sre; FAR struct sensor_rpmsg_dev_s *dev; sre = container_of(ept, struct sensor_rpmsg_ept_s, ept); nxrmutex_lock(&g_ept_lock); list_add_tail(&g_eptlist, &sre->node); nxrmutex_unlock(&g_ept_lock); /* Broadcast all device to ready ept */ nxrmutex_lock(&g_dev_lock); list_for_every_entry(&g_devlist, dev, struct sensor_rpmsg_dev_s, node) { sensor_rpmsg_lock(dev); if (dev->nadvertisers > 0) { sensor_rpmsg_advsub_one(dev, ept, SENSOR_RPMSG_ADVERTISE); } if (dev->nsubscribers > 0) { sensor_rpmsg_advsub_one(dev, ept, SENSOR_RPMSG_SUBSCRIBE); } sensor_rpmsg_unlock(dev); } nxrmutex_unlock(&g_dev_lock); } static void sensor_rpmsg_device_created(FAR struct rpmsg_device *rdev, FAR void *priv) { FAR struct sensor_rpmsg_ept_s *sre; sre = kmm_zalloc(sizeof(*sre)); if (!sre) { return; } sre->rdev = rdev; sre->ept.priv = sre; nxrmutex_init(&sre->lock); sre->ept.ns_bound_cb = sensor_rpmsg_device_ns_bound; if (rpmsg_create_ept(&sre->ept, rdev, SENSOR_RPMSG_EPT_NAME, RPMSG_ADDR_ANY, RPMSG_ADDR_ANY, sensor_rpmsg_ept_cb, sensor_rpmsg_ns_unbind_cb) < 0) { nxrmutex_destroy(&sre->lock); kmm_free(sre); } } /**************************************************************************** * Public Functions ****************************************************************************/ /**************************************************************************** * Name: sensor_rpmsg_register * * Description: * This function registers rpmsg takeover for the real lower half, and * initialize rpmsg resource. * * Input Parameters: * lower - The instance of lower half sensor driver. * path - The path of character node, ex: /dev/uorb/xxx. * * Returned Value: * The takeover rpmsg lowerhalf returned on success, NULL on failure. ****************************************************************************/ FAR struct sensor_lowerhalf_s * sensor_rpmsg_register(FAR struct sensor_lowerhalf_s *lower, FAR const char *path) { FAR struct sensor_rpmsg_ept_s *sre; FAR struct sensor_rpmsg_dev_s *dev; if (lower->ops->fetch) { return lower; } dev = kmm_zalloc(sizeof(*dev) + strlen(path)); if (!dev) { return NULL; } /* Initialize the sensor rpmsg device structure */ list_initialize(&dev->stublist); list_initialize(&dev->proxylist); strcpy(dev->path, path); dev->nadvertisers = !!lower->ops->activate; dev->push_event = lower->push_event; dev->upper = lower->priv; lower->push_event = sensor_rpmsg_push_event; lower->priv = dev; memcpy(&dev->lower, lower, sizeof(*lower)); dev->lower.ops = &g_sensor_rpmsg_ops; dev->drv = lower; /* If openamp is ready, send advertisement to remote proc */ nxrmutex_lock(&g_dev_lock); list_add_tail(&g_devlist, &dev->node); nxrmutex_unlock(&g_dev_lock); if (lower->ops->activate) { nxrmutex_lock(&g_ept_lock); list_for_every_entry(&g_eptlist, sre, struct sensor_rpmsg_ept_s, node) { sensor_rpmsg_advsub_one(dev, &sre->ept, SENSOR_RPMSG_ADVERTISE); } nxrmutex_unlock(&g_ept_lock); } return &dev->lower; } /**************************************************************************** * Name: sensor_rpmsg_unregister * * Description: * This function unregisters rpmsg takeover for the real lower half, and * release rpmsg resource. This API corresponds to sensor_rpmsg_register. * * Input Parameters: * lower - The instance of lower half sensor driver. ****************************************************************************/ void sensor_rpmsg_unregister(FAR struct sensor_lowerhalf_s *lower) { FAR struct sensor_rpmsg_dev_s *dev = lower->priv; if (lower->ops != &g_sensor_rpmsg_ops) { return; } nxrmutex_lock(&g_dev_lock); list_delete(&dev->node); nxrmutex_unlock(&g_dev_lock); kmm_free(dev); } /**************************************************************************** * Name: sensor_rpmsg_initialize * * Description: * This function initializes the context of sensor rpmsg, registers * rpmsg callback and prepares enviroment to intercat with remote sensor. * * Returned Value: * OK on success; A negated errno value is returned on any failure. ****************************************************************************/ int sensor_rpmsg_initialize(void) { return rpmsg_register_callback(NULL, sensor_rpmsg_device_created, NULL, NULL, NULL); }