/**************************************************************************** * drivers/wireless/cc3000.c * * Copyright (C) 2013-2016 Gregory Nutt. All rights reserved. * Authors: Gregory Nutt * David_s5 * * References: * CC30000 from Texas Instruments http://processors.wiki.ti.com/index.php/CC3000 * * See also: * http://processors.wiki.ti.com/index.php/CC3000_Host_Driver_Porting_Guide * http://processors.wiki.ti.com/index.php/CC3000_Host_Programming_Guide * * Redistribution and use in source and binary forms, with or without * modification, are permitted provided that the following conditions * are met: * * 1. Redistributions of source code must retain the above copyright * notice, this list of conditions and the following disclaimer. * 2. Redistributions in binary form must reproduce the above copyright * notice, this list of conditions and the following disclaimer in * the documentation and/or other materials provided with the * distribution. * 3. Neither the name NuttX nor the names of its contributors may be * used to endorse or promote products derived from this software * without specific prior written permission. * * THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS * "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT * LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS * FOR A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE * COPYRIGHT OWNER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, * INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, * BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS * OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED * AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT * LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN * ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE * POSSIBILITY OF SUCH DAMAGE. * ****************************************************************************/ /**************************************************************************** * Included Files ****************************************************************************/ #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include "cc3000_socket.h" #include "cc3000.h" /**************************************************************************** * Pre-processor Definitions ****************************************************************************/ #ifndef CCASSERT #define CCASSERT(predicate) _x_CCASSERT_LINE(predicate, __LINE__) #define _x_CCASSERT_LINE(predicate, line) typedef char constraint_violated_on_line_##line[2*((predicate)!=0)-1]; #endif CCASSERT(sizeof(cc3000_buffer_desc) <= CONFIG_MQ_MAXMSGSIZE); #ifndef CONFIG_CC3000_WORKER_THREAD_PRIORITY # define CONFIG_CC3000_WORKER_THREAD_PRIORITY (SCHED_PRIORITY_MAX) #endif #ifndef CONFIG_CC3000_WORKER_STACKSIZE # define CONFIG_CC3000_WORKER_STACKSIZE 240 #endif #ifndef CONFIG_CC3000_SELECT_THREAD_PRIORITY # define CONFIG_CC3000_SELECT_THREAD_PRIORITY (SCHED_PRIORITY_DEFAULT-1) #endif #ifndef CONFIG_CC3000_SELECT_STACKSIZE # define CONFIG_CC3000_SELECT_STACKSIZE 368 #endif #ifndef ARRAY_SIZE # define ARRAY_SIZE(x) (sizeof(x) / sizeof((x)[0])) #endif #define NUMBER_OF_MSGS 1 #define FREE_SLOT -1 #define CLOSE_SLOT -2 #if defined(CONFIG_DEBUG_FEATURES) && defined(CONFIG_CC3000_PROBES) # define CC3000_GUARD (0xc35aa53c) # define INIT_GUARD(p) p->guard = CC3000_GUARD # define CHECK_GUARD(p) DEBUGASSERT(p->guard == CC3000_GUARD) # define PROBE(pin,state) priv->config->probe(priv->config,pin, state) #else # define INIT_GUARD(p) # define CHECK_GUARD(p) # define PROBE(pin,state) #endif #define waiterr(x,...) // _err #define waitinfo(x,...) // _info /**************************************************************************** * Private Function Prototypes ****************************************************************************/ /* Low-level SPI helpers */ static void cc3000_lock_and_select(FAR struct spi_dev_s *spi); static void cc3000_deselect_and_unlock(FAR struct spi_dev_s *spi); /* Interrupts and data sampling */ static void cc3000_notify(FAR struct cc3000_dev_s *priv); static void *cc3000_worker(FAR void *arg); static int cc3000_interrupt(int irq, FAR void *context, FAR void *arg); /* Character driver methods */ static int cc3000_open(FAR struct file *filep); static int cc3000_close(FAR struct file *filep); static ssize_t cc3000_read(FAR struct file *filep, FAR char *buffer, size_t len); static ssize_t cc3000_write(FAR struct file *filep, FAR const char *buffer, size_t len); static int cc3000_ioctl(FAR struct file *filep, int cmd, unsigned long arg); #ifndef CONFIG_DISABLE_POLL static int cc3000_poll(FAR struct file *filep, struct pollfd *fds, bool setup); #endif static int cc3000_wait_data(FAR struct cc3000_dev_s *priv, int sockfd); static int cc3000_accept_socket(FAR struct cc3000_dev_s *priv, int sd, FAR struct sockaddr *addr, socklen_t *addrlen); static int cc3000_add_socket(FAR struct cc3000_dev_s *priv, int sd); static int cc3000_remove_socket(FAR struct cc3000_dev_s *priv, int sd); static int cc3000_remote_closed_socket(FAR struct cc3000_dev_s *priv, int sd); /**************************************************************************** * Private Data ****************************************************************************/ /* This the vtable that supports the character driver interface */ static const struct file_operations cc3000_fops = { cc3000_open, /* open */ cc3000_close, /* close */ cc3000_read, /* read */ cc3000_write, /* write */ 0, /* seek */ cc3000_ioctl, /* ioctl */ #ifndef CONFIG_DISABLE_POLL cc3000_poll /* poll */ #endif }; /* If only a single CC3000 device is supported, then the driver state * structure may as well be pre-allocated. */ #ifndef CONFIG_CC3000_MULTIPLE static struct cc3000_dev_s g_cc3000; /* Otherwise, we will need to maintain allocated driver instances in a list */ #else static struct cc3000_dev_s *g_cc3000list; #endif uint8_t spi_readCommand[] = READ_COMMAND; /**************************************************************************** * Private Functions ****************************************************************************/ /**************************************************************************** * Name: cc3000_devtake() and cc3000_devgive() * * Description: * Used to get exclusive access to a CC3000 driver. * ****************************************************************************/ static inline void cc3000_devtake(FAR struct cc3000_dev_s *priv) { /* Take the semaphore (perhaps waiting) */ while (sem_wait(&priv->devsem) < 0) { /* The only case that an error should occur here is if the wait was * awakened by a signal. */ DEBUGASSERT(errno == EINTR); } } static inline void cc3000_devgive(FAR struct cc3000_dev_s *priv) { (void)sem_post(&priv->devsem); } /**************************************************************************** * Name: cc3000_configspi * * Description: * Configure the SPI for use with the CC3000. This function should be * called to configure the SPI * bus. * * Parameters: * spi - Reference to the SPI driver structure * * Returned Value: * None * * Assumptions: * ****************************************************************************/ static inline void cc3000_configspi(FAR struct spi_dev_s *spi) { ninfo("Mode: %d Bits: 8 Frequency: %d\n", CONFIG_CC3000_SPI_MODE, CONFIG_CC3000_SPI_FREQUENCY); SPI_SETMODE(spi, CONFIG_CC3000_SPI_MODE); SPI_SETBITS(spi, 8); (void)SPI_HWFEATURES(spi, 0); (void)SPI_SETFREQUENCY(spi, CONFIG_CC3000_SPI_FREQUENCY); } /**************************************************************************** * Name: cc3000_lock * * Description: * Lock the SPI bus and re-configure as necessary. This function must be * to assure: (1) exclusive access to the SPI bus, and (2) to assure that * the shared bus is properly configured for the cc3000 module. * * Parameters: * spi - Reference to the SPI driver structure * * Returned Value: * None * * Assumptions: * ****************************************************************************/ static void cc3000_lock_and_select(FAR struct spi_dev_s *spi) { /* Lock the SPI bus so that we have exclusive access */ (void)SPI_LOCK(spi, true); /* We have the lock. Now make sure that the SPI bus is configured for the * CC3000 (it might have gotten configured for a different device while * unlocked) */ cc3000_configspi(spi); SPI_SELECT(spi, SPIDEV_WIRELESS(0), true); } /**************************************************************************** * Name: cc3000_unlock * * Description: * Un-lock the SPI bus after each transfer, possibly losing the current * configuration if we are sharing the SPI bus with other devices. * * Parameters: * spi - Reference to the SPI driver structure * * Returned Value: * None * * Assumptions: * ****************************************************************************/ static void cc3000_deselect_and_unlock(FAR struct spi_dev_s *spi) { /* De select */ SPI_SELECT(spi, SPIDEV_WIRELESS(0), false); /* Relinquish the SPI bus. */ (void)SPI_LOCK(spi, false); } /**************************************************************************** * Name: cc3000_wait * * Description: * Helper function to wait on the semaphore signaled by the * * Parameters: * priv - Reference to the CC3000 driver structure * priv - * * Returned Value: * 0 - Semaphore signaled and devsem retaken * < 0 - Some Error occurred * Assumptions: * Own the devsem on entry * ****************************************************************************/ static int cc3000_wait(FAR struct cc3000_dev_s *priv, sem_t *psem) { int ret; /* Give up */ sched_lock(); cc3000_devgive(priv); /* Wait on first psem to become signaled */ ret = sem_wait(psem); if (ret < 0) { return -errno; } /* Then retake the mutual exclusion semaphore */ cc3000_devtake(priv); sched_unlock(); return OK; } /**************************************************************************** * Name: cc3000_wait_irq * * Description: * Helper function to wait on the irqsem signaled by the interrupt * * Parameters: * priv - Reference to the CC3000 driver structure * * Returned Value: * 0 - Semaphore signaled and devsem retaken * < 0 - Some Error occurred * Assumptions: * Own the devsem on entry * ****************************************************************************/ static inline int cc3000_wait_irq(FAR struct cc3000_dev_s *priv) { return cc3000_wait(priv, &priv->irqsem); } /**************************************************************************** * Name: cc3000_wait_ready * * Description: * Helper function to wait on the readysem signaled by the interrupt * * Parameters: * priv - Reference to the CC3000 driver structure * * Returned Value: * 0 - Semaphore signaled and devsem retaken * < 0 - Some Error occurred * Assumptions: * Own the devsem on entry * ****************************************************************************/ static inline int cc3000_wait_ready(FAR struct cc3000_dev_s *priv) { return cc3000_wait(priv, &priv->readysem); } /**************************************************************************** * Name: cc3000_pollnotify ****************************************************************************/ #ifndef CONFIG_DISABLE_POLL static void cc3000_pollnotify(FAR struct cc3000_dev_s *priv, uint32_t type) { int i; for (i = 0; i < CONFIG_CC3000_NPOLLWAITERS; i++) { struct pollfd *fds = priv->fds[i]; if (fds) { fds->revents |= type; ninfo("Report events: %02x\n", fds->revents); sem_post(fds->sem); } } } #endif /**************************************************************************** * Name: cc3000_notify ****************************************************************************/ static void cc3000_notify(FAR struct cc3000_dev_s *priv) { /* If there are threads waiting for read data, then signal one of them * that the read data is available. */ if (priv->nwaiters > 0) { /* After posting this semaphore, we need to exit because the CC3000 * is no longer available. */ sem_post(&priv->waitsem); } /* If there are threads waiting on poll() for CC3000 data to become available, * then wake them up now. NOTE: we wake up all waiting threads because we * do not know that they are going to do. If they all try to read the data, * then some make end up blocking after all. */ #ifndef CONFIG_DISABLE_POLL cc3000_pollnotify(priv, POLLIN); #endif } /**************************************************************************** * Name: cc3000_worker ****************************************************************************/ static void *select_thread_func(FAR void *arg) { FAR struct cc3000_dev_s *priv = (FAR struct cc3000_dev_s *)arg; struct timeval timeout; TICC3000fd_set readsds; TICC3000fd_set exceptsds; int ret = 0; int maxFD = 0; int s = 0; memset(&timeout, 0, sizeof(struct timeval)); timeout.tv_sec = 0; timeout.tv_usec = (500000); /* 500 msecs */ while (1) { sem_wait(&priv->selectsem); CHECK_GUARD(priv); /* Increase the count back by one to be decreased by the original caller */ sem_post(&priv->selectsem); maxFD = -1; CC3000_FD_ZERO(&readsds); CC3000_FD_ZERO(&exceptsds); /* Ping correct socket descriptor param for select */ for (s = 0; s < CONFIG_WL_MAX_SOCKETS; s++) { if (priv->sockets[s].sd != FREE_SLOT) { if (priv->sockets[s].sd == CLOSE_SLOT) { priv->sockets[s].sd = FREE_SLOT; waitinfo("Close\n"); int count; do { sem_getvalue(&priv->sockets[s].semwait, &count); if (count < 0) { /* Release the waiting threads */ waitinfo("Closed Signaled %d\n", count); sem_post(&priv->sockets[s].semwait); } } while (count < 0); continue; } CC3000_FD_SET(priv->sockets[s].sd, &readsds); CC3000_FD_SET(priv->sockets[s].sd, &exceptsds); if (maxFD <= priv->sockets[s].sd) { maxFD = priv->sockets[s].sd + 1; } } } if (maxFD < 0) { /* Handled only socket close. */ continue; } /* Polling instead of blocking here to process "accept" below */ ret = cc3000_select(maxFD, (fd_set *) &readsds, NULL, (fd_set *) &exceptsds, &timeout); if (priv->selecttid == -1) { /* driver close will terminate the thread and by that all sync * objects owned by it will be released */ return OK; } for (s = 0; s < CONFIG_WL_MAX_SOCKETS; s++) { if ((priv->sockets[s].sd != FREE_SLOT || priv->sockets[s].sd != CLOSE_SLOT) && /* Check that the socket is valid */ priv->sockets[s].sd != priv->accepting_socket.acc.sd) /* Verify this is not an accept socket */ { if (ret > 0 && CC3000_FD_ISSET(priv->sockets[s].sd, &readsds)) /* and has pending data */ { waitinfo("Signaled %d\n", priv->sockets[s].sd); sem_post(&priv->sockets[s].semwait); /* release the waiting thread */ } else if (ret > 0 && CC3000_FD_ISSET(priv->sockets[s].sd, &exceptsds)) /* or has pending exception */ { waitinfo("Signaled %d (exception)\n", priv->sockets[s].sd); sem_post(&priv->sockets[s].semwait); /* release the waiting thread */ } else if (priv->sockets[s].received_closed_event) /* or remote has closed connection and we have now read all of HW buffer. */ { waitinfo("Signaled %d (closed & empty)\n", priv->sockets[s].sd); priv->sockets[s].emptied_and_remotely_closed = true; sem_post(&priv->sockets[s].semwait); /* release the waiting thread */ } } } if (priv->accepting_socket.acc.sd != FREE_SLOT) /* If accept polling in needed */ { if (priv->accepting_socket.acc.sd == CLOSE_SLOT) { ret = CC3000_SOC_ERROR; } else { ret = cc3000_do_accept(priv->accepting_socket.acc.sd, /* Send the select command on non blocking */ &priv->accepting_socket.addr, /* Set up in ioctl */ &priv->accepting_socket.addrlen); } if (ret != CC3000_SOC_IN_PROGRESS) /* Not waiting => error or accepted */ { priv->accepting_socket.acc.sd = FREE_SLOT; priv->accepting_socket.acc.status = ret; sem_post(&priv->accepting_socket.acc.semwait); /* Release the waiting thread */ } } } return OK; } /**************************************************************************** * Name: cc3000_worker ****************************************************************************/ static void *cc3000_worker(FAR void *arg) { FAR struct cc3000_dev_s *priv = (FAR struct cc3000_dev_s *)arg; int ret; ASSERT(priv != NULL && priv->config != NULL); /* We have started, release our creator */ sem_post(&priv->readysem); while (1) { PROBE(0, 1); CHECK_GUARD(priv); cc3000_devtake(priv); /* Done ? */ if ((cc3000_wait_irq(priv) != -EINTR) && (priv->workertid != -1)) { PROBE(0, 0); ninfo("State%d\n", priv->state); switch (priv->state) { case eSPI_STATE_POWERUP: /* Signal the device has interrupted after power up */ priv->state = eSPI_STATE_INITIALIZED; sem_post(&priv->readysem); break; case eSPI_STATE_WRITE_WAIT_IRQ: /* Signal the device has interrupted after Chip Select During a write operation */ priv->state = eSPI_STATE_WRITE_PROCEED; sem_post(&priv->readysem); break; case eSPI_STATE_WRITE_DONE: /* IRQ post a write => Solicited */ case eSPI_STATE_IDLE: /* IRQ when Idel => cc3000 has data for the hosts Unsolicited */ { uint16_t data_to_recv; priv->state = eSPI_STATE_READ_IRQ; /* Issue the read command */ cc3000_lock_and_select(priv->spi); /* Assert CS */ priv->state = eSPI_STATE_READ_PROCEED; SPI_EXCHANGE(priv->spi, spi_readCommand, priv->rx_buffer.pbuffer, ARRAY_SIZE(spi_readCommand)); /* Extract Length bytes from Rx Buffer. Here we need to convert * unaligned data in network order (big endian, MS byte first) to * host order. We cannot use ntohs here because the data is not * aligned. */ data_to_recv = (uint16_t)priv->rx_buffer.pbuffer[READ_OFFSET_TO_LENGTH] << 8 | (uint16_t)priv->rx_buffer.pbuffer[READ_OFFSET_TO_LENGTH + 1]; if (data_to_recv) { /* We will read ARRAY_SIZE(spi_readCommand) + data_to_recv. is it odd? */ if ((data_to_recv + ARRAY_SIZE(spi_readCommand)) & 1) { /* Odd so make it even */ data_to_recv++; } /* Read the whole payload in at the beginning of the buffer * Will it fit? */ if (data_to_recv >= priv->rx_buffer_max_len) { ninfo("data_to_recv %d", data_to_recv); } DEBUGASSERT(data_to_recv < priv->rx_buffer_max_len); SPI_RECVBLOCK(priv->spi, priv->rx_buffer.pbuffer, data_to_recv); } cc3000_deselect_and_unlock(priv->spi); /* De assert CS */ /* Disable more messages as the wl code will resume via CC3000IOC_COMPLETE */ if (data_to_recv) { int count; priv->state = eSPI_STATE_READ_READY; priv->rx_buffer.len = data_to_recv; ret = mq_send(priv->queue, (FAR const char *)&priv->rx_buffer, sizeof(priv->rx_buffer), 1); DEBUGASSERT(ret >= 0); UNUSED(ret); /* Notify any waiters that new CC3000 data is available */ cc3000_notify(priv); /* Give up driver */ cc3000_devgive(priv); ninfo("Wait On Completion\n"); sem_wait(priv->wrkwaitsem); ninfo("Completed S:%d irq :%d\n", priv->state, priv->config->irq_read(priv->config)); sem_getvalue(&priv->irqsem, &count); if (priv->config->irq_read(priv->config) && count == 0) { sem_post(&priv->irqsem); } if (priv->state == eSPI_STATE_READ_READY) { priv->state = eSPI_STATE_IDLE; } continue; } } break; default: ninfo("default: State%d\n", priv->state); break; } } cc3000_devgive(priv); } return OK; } /**************************************************************************** * Name: cc3000_interrupt ****************************************************************************/ static int cc3000_interrupt(int irq, FAR void *context, FAR void *arg) { FAR struct cc3000_dev_s *priv = (FAR struct cc3000_dev_s *)arg; DEBUGASSERT(priv != NULL); /* Run the worker thread */ PROBE(1, 0); sem_post(&priv->irqsem); PROBE(1, 1); /* Clear any pending interrupts and return success */ priv->config->irq_clear(priv->config); return OK; } /**************************************************************************** * Name: cc3000_open ****************************************************************************/ static int cc3000_open(FAR struct file *filep) { FAR struct inode *inode; struct mq_attr attr; pthread_attr_t tattr; pthread_t threadid; struct sched_param param; char queuename[QUEUE_NAMELEN]; FAR struct cc3000_dev_s *priv; uint8_t tmp; int ret; #ifdef CONFIG_CC3000_MT int s; #endif DEBUGASSERT(filep); inode = filep->f_inode; DEBUGASSERT(inode && inode->i_private); priv = (FAR struct cc3000_dev_s *)inode->i_private; CHECK_GUARD(priv); ninfo("crefs: %d\n", priv->crefs); /* Get exclusive access to the driver data structure */ cc3000_devtake(priv); /* Increment the reference count */ tmp = priv->crefs + 1; if (tmp == 0) { /* More than 255 opens; uint8_t overflows to zero */ ret = -EMFILE; goto out_with_sem; } /* When the reference increments to 1, this is the first open event * on the driver.. and an opportunity to do any one-time initialization. */ if (tmp == 1) { /* Initialize semaphores */ sem_init(&priv->waitsem, 0, 0); /* Initialize event wait semaphore */ sem_init(&priv->irqsem, 0, 0); /* Initialize IRQ Ready semaphore */ sem_init(&priv->readysem, 0, 0); /* Initialize Device Ready semaphore */ /* These semaphores are all used for signaling and, hence, should * not have priority inheritance enabled. */ sem_setprotocol(&priv->waitsem, SEM_PRIO_NONE); sem_setprotocol(&priv->irqsem, SEM_PRIO_NONE); sem_setprotocol(&priv->readysem, SEM_PRIO_NONE); #ifdef CONFIG_CC3000_MT priv->accepting_socket.acc.sd = FREE_SLOT; sem_init(&priv->accepting_socket.acc.semwait, 0, 0); sem_setprotocol(&priv->accepting_socket.acc.semwait, SEM_PRIO_NONE); for (s = 0; s < CONFIG_WL_MAX_SOCKETS; s++) { priv->sockets[s].sd = FREE_SLOT; priv->sockets[s].received_closed_event = false; priv->sockets[s].emptied_and_remotely_closed = false; sem_init(&priv->sockets[s].semwait, 0, 0); sem_setprotocol(&priv->sockets[s].semwait, SEM_PRIO_NONE); } #endif /* Ensure the power is off so we get the falling edge of IRQ */ priv->config->power_enable(priv->config, false); attr.mq_maxmsg = NUMBER_OF_MSGS; attr.mq_msgsize = sizeof(cc3000_buffer_desc); attr.mq_flags = 0; /* Set the flags for the open of the queue. * Make it a blocking open on the queue, meaning it will block if * this process tries to send to the queue and the queue is full. * * O_CREAT - the queue will get created if it does not already exist. * O_WRONLY - we are only planning to write to the queue. * * Open the queue, and create it if the receiving process hasn't * already created it. */ snprintf(queuename, QUEUE_NAMELEN, QUEUE_FORMAT, priv->minor); priv->queue = mq_open(queuename, O_WRONLY | O_CREAT, 0666, &attr); if (priv->queue < 0) { ret = -errno; goto errout_sem_destroy; } pthread_attr_init(&tattr); tattr.stacksize = CONFIG_CC3000_WORKER_STACKSIZE; param.sched_priority = CONFIG_CC3000_WORKER_THREAD_PRIORITY; pthread_attr_setschedparam(&tattr, ¶m); ret = pthread_create(&priv->workertid, &tattr, cc3000_worker, (pthread_addr_t)priv); if (ret != 0) { ret = -ret; /* pthread_create does not modify errno. */ goto errout_mq_close; } pthread_attr_init(&tattr); tattr.stacksize = CONFIG_CC3000_SELECT_STACKSIZE; param.sched_priority = CONFIG_CC3000_SELECT_THREAD_PRIORITY; pthread_attr_setschedparam(&tattr, ¶m); sem_init(&priv->selectsem, 0, 0); sem_setprotocol(&priv->selectsem, SEM_PRIO_NONE); ret = pthread_create(&priv->selecttid, &tattr, select_thread_func, (pthread_addr_t)priv); if (ret != 0) { ret = -ret; /* pthread_create does not modify errno. */ goto errout_worker_cancel; } /* Do late allocation with hopes of realloc not fragmenting */ priv->rx_buffer.pbuffer = kmm_malloc(priv->rx_buffer_max_len); DEBUGASSERT(priv->rx_buffer.pbuffer); if (!priv->rx_buffer.pbuffer) { ret = -errno; goto errout_select_cancel; } priv->state = eSPI_STATE_POWERUP; priv->config->irq_clear(priv->config); /* Bring the device Online A) on http://processors.wiki.ti.com/index.php/File:CC3000_Master_SPI_Write_Sequence_After_Power_Up.png */ priv->config->irq_enable(priv->config, true); /* Wait on child thread */ cc3000_wait_ready(priv); priv->config->power_enable(priv->config, true); } /* Save the new open count on success */ priv->crefs = tmp; ret = OK; goto out_with_sem; errout_select_cancel: threadid = priv->selecttid; priv->selecttid = -1; pthread_cancel(threadid); pthread_join(threadid, NULL); sem_destroy(&priv->selectsem); errout_worker_cancel: threadid = priv->workertid; priv->workertid = -1; pthread_cancel(threadid); pthread_join(threadid, NULL); errout_mq_close: mq_close(priv->queue); priv->queue = 0; errout_sem_destroy: #ifdef CONFIG_CC3000_MT sem_destroy(&priv->accepting_socket.acc.semwait); for (s = 0; s < CONFIG_WL_MAX_SOCKETS; s++) { priv->sockets[s].sd = FREE_SLOT; sem_destroy(&priv->sockets[s].semwait); } #endif sem_destroy(&priv->waitsem); sem_destroy(&priv->irqsem); sem_destroy(&priv->readysem); out_with_sem: cc3000_devgive(priv); return ret; } /**************************************************************************** * Name: cc3000_close ****************************************************************************/ static int cc3000_close(FAR struct file *filep) { FAR struct inode *inode; FAR struct cc3000_dev_s *priv; #ifdef CONFIG_CC3000_MT int s; #endif DEBUGASSERT(filep); inode = filep->f_inode; DEBUGASSERT(inode && inode->i_private); priv = (FAR struct cc3000_dev_s *)inode->i_private; CHECK_GUARD(priv); ninfo("crefs: %d\n", priv->crefs); /* Get exclusive access to the driver data structure */ cc3000_devtake(priv); /* Decrement the reference count unless it would decrement a negative * value. When the count decrements to zero, there are no further * open references to the driver. */ int tmp = priv->crefs; if (priv->crefs >= 1) { priv->crefs--; } if (tmp == 1) { pthread_t id = priv->selecttid; priv->selecttid = -1; pthread_cancel(id); pthread_join(id, NULL); sem_destroy(&priv->selectsem); priv->config->irq_enable(priv->config, false); priv->config->irq_clear(priv->config); priv->config->power_enable(priv->config, false); id = priv->workertid; priv->workertid = -1; pthread_cancel(id); pthread_join(id, NULL); mq_close(priv->queue); priv->queue = 0; kmm_free(priv->rx_buffer.pbuffer); priv->rx_buffer.pbuffer = 0; #ifdef CONFIG_CC3000_MT sem_destroy(&priv->accepting_socket.acc.semwait); for (s = 0; s < CONFIG_WL_MAX_SOCKETS; s++) { priv->sockets[s].sd = FREE_SLOT; sem_destroy(&priv->sockets[s].semwait); } #endif sem_destroy(&priv->waitsem); sem_destroy(&priv->irqsem); sem_destroy(&priv->readysem); } cc3000_devgive(priv); return OK; } /**************************************************************************** * Name: cc3000_read ****************************************************************************/ static ssize_t cc3000_read(FAR struct file *filep, FAR char *buffer, size_t len) { FAR struct inode *inode; FAR struct cc3000_dev_s *priv; int ret; ssize_t nread; ninfo("buffer:%p len:%d\n", buffer, len); DEBUGASSERT(filep); inode = filep->f_inode; DEBUGASSERT(inode && inode->i_private); priv = (FAR struct cc3000_dev_s *)inode->i_private; CHECK_GUARD(priv); /* Get exclusive access to the driver data structure */ cc3000_devtake(priv); /* Verify that the caller has provided a buffer large enough to receive * the maximum data. */ if (len < priv->rx_buffer_max_len) { nerr("ERROR: Unsupported read size: %d\n", len); nread = -ENOSYS; goto errout_with_sem; } for (nread = priv->rx_buffer.len; nread == 0; nread = priv->rx_buffer.len) { if (nread > 0) { /* Yes.. break out to return what we have. */ break; } /* data is not available now. We would have to wait to get * receive sample data. If the user has specified the O_NONBLOCK * option, then just return an error. */ ninfo("CC3000 data is not available\n"); if (filep->f_oflags & O_NONBLOCK) { nread = -EAGAIN; break; } /* Otherwise, wait for something to be written to the * buffer. Increment the number of waiters so that the notify * will know that it needs to post the semaphore to wake us up. */ sched_lock(); priv->nwaiters++; cc3000_devgive(priv); /* We may now be pre-empted! But that should be okay because we * have already incremented nwaiters. Pre-emptions is disabled * but will be re-enabled while we are waiting. */ ninfo("Waiting..\n"); ret = sem_wait(&priv->waitsem); priv->nwaiters--; sched_unlock(); /* Did we successfully get the waitsem? */ if (ret >= 0) { /* Yes... then retake the mutual exclusion semaphore */ cc3000_devtake(priv); } /* Was the semaphore wait successful? Did we successful re-take the * mutual exclusion semaphore? */ if (ret < 0) { /* No.. One of the two sem_wait's failed. */ int errval = errno; /* Were we awakened by a signal? Did we read anything before * we received the signal? */ if (errval != EINTR || nread >= 0) { /* Yes.. return the error. */ nread = -errval; } /* Break out to return what we have. Note, we can't exactly * "break" out because whichever error occurred, we do not hold * the exclusion semaphore. */ goto errout_without_sem; } } if (nread > 0) { memcpy(buffer, priv->rx_buffer.pbuffer, priv->rx_buffer.len); priv->rx_buffer.len = 0; } errout_with_sem: cc3000_devgive(priv); errout_without_sem: ninfo("Returning: %d\n", nread); #ifndef CONFIG_DISABLE_POLL if (nread > 0) { cc3000_pollnotify(priv, POLLOUT); } #endif return nread; } /**************************************************************************** * Name:cc3000_write * * Bit of non standard buffer management ahead * The buffer is memory allocated in the user space with space for the spi * header * ****************************************************************************/ static ssize_t cc3000_write(FAR struct file *filep, FAR const char *usrbuffer, size_t len) { FAR struct inode *inode; FAR struct cc3000_dev_s *priv; FAR char *buffer = (FAR char *) usrbuffer; ssize_t nwritten = 0; int ret; /* Set the padding if count(buffer) is even ( as it will be come odd with header) */ size_t tx_len = (len & 1) ? len : len +1; ninfo("buffer:%p len:%d tx_len:%d\n", buffer, len, tx_len); DEBUGASSERT(filep); inode = filep->f_inode; DEBUGASSERT(inode && inode->i_private); priv = (FAR struct cc3000_dev_s *)inode->i_private; CHECK_GUARD(priv); /* Get exclusive access to the driver data structure */ cc3000_devtake(priv); /* Figure out the total length of the packet in order to figure out if there is padding or not */ buffer[0] = WRITE; buffer[1] = HI(tx_len); buffer[2] = LO(tx_len); buffer[3] = 0; buffer[4] = 0; tx_len += SPI_HEADER_SIZE; /* The first write transaction to occur after release of the shutdown has * slightly different timing than the others. The normal Master SPI * write sequence is nCS low, followed by IRQ low (CC3000 host), * indicating that the CC3000 core device is ready to accept data. * However, after power up the sequence is slightly different, as shown * in the following Figure: * * http://processors.wiki.ti.com/index.php/File:CC3000_Master_SPI_Write_Sequence_After_Power_Up.png * * The following is a sequence of operations: * - The master detects the IRQ line low: in this case the detection of * IRQ low does not indicate the intention of the CC3000 device to * communicate with the master but rather CC3000 readiness after power * up. * - The master asserts nCS. * - The master introduces a delay of at least 50 μs before starting * actual transmission of data. * - The master transmits the first 4 bytes of the SPI header. * - The master introduces a delay of at least an additional 50 μs. * - The master transmits the rest of the packet. */ if (priv->state == eSPI_STATE_POWERUP) { ret = cc3000_wait_ready(priv); if (ret < 0) { nwritten = ret; goto errout_without_sem; } } if (priv->state == eSPI_STATE_INITIALIZED) { cc3000_lock_and_select(priv->spi); /* Assert CS */ usleep(55); SPI_SNDBLOCK(priv->spi, buffer, 4); usleep(55); SPI_SNDBLOCK(priv->spi, buffer+4, tx_len-4); } else { ninfo("Assert CS\n"); priv->state = eSPI_STATE_WRITE_WAIT_IRQ; cc3000_lock_and_select(priv->spi); /* Assert CS */ ninfo("Wait on IRQ Active\n"); ret = cc3000_wait_ready(priv); ninfo("IRQ Signaled\n"); if (ret < 0) { /* This should only happen if the wait was canceled by an signal */ cc3000_deselect_and_unlock(priv->spi); ninfo("sem_wait: %d\n", errno); DEBUGASSERT(errno == EINTR); nwritten = ret; goto errout_without_sem; } SPI_SNDBLOCK(priv->spi, buffer, tx_len); } priv->state = eSPI_STATE_WRITE_DONE; ninfo("Deassert CS S:eSPI_STATE_WRITE_DONE\n"); cc3000_deselect_and_unlock(priv->spi); nwritten = tx_len; cc3000_devgive(priv); errout_without_sem: ninfo("Returning: %d\n", ret); return nwritten; } /**************************************************************************** * Name:cc3000_ioctl ****************************************************************************/ static int cc3000_ioctl(FAR struct file *filep, int cmd, unsigned long arg) { FAR struct inode *inode; FAR struct cc3000_dev_s *priv; int ret; ninfo("cmd: %d arg: %ld\n", cmd, arg); DEBUGASSERT(filep); inode = filep->f_inode; DEBUGASSERT(inode && inode->i_private); priv = (FAR struct cc3000_dev_s *)inode->i_private; CHECK_GUARD(priv); /* Get exclusive access to the driver data structure */ cc3000_devtake(priv); /* Process the IOCTL by command */ ret = OK; switch (cmd) { case CC3000IOC_GETQUESEMID: { FAR int *pminor = (FAR int *)(arg); DEBUGASSERT(pminor != NULL); *pminor = priv->minor; break; } case CC3000IOC_ADDSOCKET: { FAR int *pfd = (FAR int *)(arg); DEBUGASSERT(pfd != NULL); *pfd = cc3000_add_socket(priv, *pfd); break; } case CC3000IOC_REMOVESOCKET: { FAR int *pfd = (FAR int *)(arg); DEBUGASSERT(pfd != NULL); *pfd = cc3000_remove_socket(priv, *pfd); break; } case CC3000IOC_REMOTECLOSEDSOCKET: { FAR int *pfd = (FAR int *)(arg); DEBUGASSERT(pfd != NULL); *pfd = cc3000_remote_closed_socket(priv, *pfd); break; } case CC3000IOC_SELECTDATA: { FAR int *pfd = (FAR int *)(arg); DEBUGASSERT(pfd != NULL); *pfd = cc3000_wait_data(priv, *pfd); break; } case CC3000IOC_SELECTACCEPT: { FAR cc3000_acceptcfg *pcfg = (FAR cc3000_acceptcfg *)(arg); DEBUGASSERT(pcfg != NULL); pcfg->sockfd = cc3000_accept_socket(priv, pcfg->sockfd, pcfg->addr, pcfg->addrlen); break; } case CC3000IOC_SETRX_SIZE: { irqstate_t flags; FAR int *psize = (FAR int *)(arg); int rv; DEBUGASSERT(psize != NULL); rv = priv->rx_buffer_max_len; flags = enter_critical_section(); priv->rx_buffer_max_len = *psize; priv->rx_buffer.pbuffer = kmm_realloc(priv->rx_buffer.pbuffer, *psize); leave_critical_section(flags); DEBUGASSERT(priv->rx_buffer.pbuffer); *psize = rv; break; } default: ret = -ENOTTY; break; } cc3000_devgive(priv); return ret; } /**************************************************************************** * Name: cc3000_poll ****************************************************************************/ #ifndef CONFIG_DISABLE_POLL static int cc3000_poll(FAR struct file *filep, FAR struct pollfd *fds, bool setup) { FAR struct inode *inode; FAR struct cc3000_dev_s *priv; int ret = OK; int i; ninfo("setup: %d\n", (int)setup); DEBUGASSERT(filep && fds); inode = filep->f_inode; DEBUGASSERT(inode && inode->i_private); priv = (FAR struct cc3000_dev_s *)inode->i_private; CHECK_GUARD(priv); /* Are we setting up the poll? Or tearing it down? */ cc3000_devtake(priv); if (setup) { /* Ignore waits that do not include POLLIN */ if ((fds->events & POLLIN) == 0) { ret = -EDEADLK; goto errout; } /* This is a request to set up the poll. Find an available * slot for the poll structure reference */ for (i = 0; i < CONFIG_CC3000_NPOLLWAITERS; i++) { /* Find an available slot */ if (!priv->fds[i]) { /* Bind the poll structure and this slot */ priv->fds[i] = fds; fds->priv = &priv->fds[i]; break; } } if (i >= CONFIG_CC3000_NPOLLWAITERS) { fds->priv = NULL; ret = -EBUSY; goto errout; } /* Should we immediately notify on any of the requested events? */ if (priv->rx_buffer.len) { cc3000_notify(priv); } } else if (fds->priv) { /* This is a request to tear down the poll. */ struct pollfd **slot = (struct pollfd **)fds->priv; DEBUGASSERT(slot != NULL); /* Remove all memory of the poll setup */ *slot = NULL; fds->priv = NULL; } errout: cc3000_devgive(priv); return ret; } #endif /**************************************************************************** * Public Functions ****************************************************************************/ /**************************************************************************** * Name: cc3000_register * * Description: * Configure the CC3000 to use the provided SPI device instance. This * will register the driver as /dev/inputN where N is the minor device * number * * Input Parameters: * dev - An SPI driver instance * config - Persistent board configuration data * minor - The input device minor number * * Returned Value: * Zero is returned on success. Otherwise, a negated errno value is * returned to indicate the nature of the failure. * ****************************************************************************/ int cc3000_register(FAR struct spi_dev_s *spi, FAR struct cc3000_config_s *config, int minor) { FAR struct cc3000_dev_s *priv; char drvname[DEV_NAMELEN]; char semname[SEM_NAMELEN]; #ifdef CONFIG_CC3000_MULTIPLE irqstate_t flags; #endif int ret; ninfo("spi: %p minor: %d\n", spi, minor); /* Debug-only sanity checks */ DEBUGASSERT(spi != NULL && config != NULL && minor >= 0 && minor < 100); /* Create and initialize a CC3000 device driver instance */ #ifndef CONFIG_CC3000_MULTIPLE priv = &g_cc3000; #else priv = (FAR struct cc3000_dev_s *)kmm_malloc(sizeof(struct cc3000_dev_s)); if (!priv) { nerr("ERROR: kmm_malloc(%d) failed\n", sizeof(struct cc3000_dev_s)); return -ENOMEM; } #endif /* Initialize the CC3000 device driver instance */ memset(priv, 0, sizeof(struct cc3000_dev_s)); INIT_GUARD(priv); priv->minor = minor; /* Save the minor number */ priv->spi = spi; /* Save the SPI device handle */ priv->config = config; /* Save the board configuration */ priv->rx_buffer_max_len = config->max_rx_size; sem_init(&priv->devsem, 0, 1); /* Initialize device structure semaphore */ (void)snprintf(semname, SEM_NAMELEN, SEM_FORMAT, minor); priv->wrkwaitsem = sem_open(semname, O_CREAT, 0, 0); /* Initialize Worker Wait semaphore */ #ifdef CONFIG_CC3000_MT pthread_mutex_init(&g_cc3000_mut, NULL); #endif /* Make sure that interrupts are disabled */ config->irq_clear(config); config->irq_enable(config, false); /* Attach the interrupt handler */ ret = config->irq_attach(config, cc3000_interrupt, priv); if (ret < 0) { nerr("ERROR: Failed to attach interrupt\n"); goto errout_with_priv; } /* Register the device as an input device */ (void)snprintf(drvname, DEV_NAMELEN, DEV_FORMAT, minor); ninfo("Registering %s\n", drvname); ret = register_driver(drvname, &cc3000_fops, 0666, priv); if (ret < 0) { nerr("ERROR: register_driver() failed: %d\n", ret); goto errout_with_priv; } /* If multiple CC3000 devices are supported, then we will need to add * this new instance to a list of device instances so that it can be * found by the interrupt handler based on the recieved IRQ number. */ #ifdef CONFIG_CC3000_MULTIPLE priv->flink = g_cc3000list; g_cc3000list = priv; leave_critical_section(flags); #endif /* And return success (?) */ return OK; errout_with_priv: sem_destroy(&priv->devsem); sem_close(priv->wrkwaitsem); sem_unlink(semname); #ifdef CONFIG_CC3000_MT pthread_mutex_destroy(&g_cc3000_mut); #endif #ifdef CONFIG_CC3000_MULTIPLE kmm_free(priv); #endif return ret; } /**************************************************************************** * Name: cc3000_wait_data * * Description: * Adds this socket for monitoring for the data available * * Input Parameters: * priv - The device cc3000_dev_s instance * sockfd cc3000 socket handle * * Returned Value: * Zero is returned on success. Otherwise, a -1 value is * returned to indicate socket not found or shut down occured. * ****************************************************************************/ static int cc3000_wait_data(FAR struct cc3000_dev_s *priv, int sockfd) { int s; for (s = 0; s < CONFIG_WL_MAX_SOCKETS; s++) { if (priv->sockets[s].sd == sockfd) { sched_lock(); cc3000_devgive(priv); sem_post(&priv->selectsem); /* Wake select thread if need be */ sem_wait(&priv->sockets[s].semwait); /* Wait caller on select to finish */ sem_wait(&priv->selectsem); /* Sleep select thread */ cc3000_devtake(priv); sched_unlock(); if (!priv->sockets[s].sd == sockfd) { return -1; } if (priv->sockets[s].emptied_and_remotely_closed) { return -ECONNABORTED; } return OK; } } return (s >= CONFIG_WL_MAX_SOCKETS || priv->selecttid == -1) ? -1 : OK; } /**************************************************************************** * Name: cc3000_accept_socket * * Description: * Adds this socket for monitoring for the accept operation * * Input Parameters: * priv - The device cc3000_dev_s instance * sockfd - cc3000 socket handle to monitor * * Returned Value: * Zero is returned on success. Otherwise, a negative value is * returned to indicate an error. * ****************************************************************************/ static int cc3000_accept_socket(FAR struct cc3000_dev_s *priv, int sd, struct sockaddr *addr, socklen_t *addrlen) { priv->accepting_socket.acc.status = CC3000_SOC_ERROR; priv->accepting_socket.acc.sd = sd; sched_lock(); cc3000_devgive(priv); sem_post(&priv->selectsem); /* Wake select thread if need be */ sem_wait(&priv->accepting_socket.acc.semwait); /* Wait caller on select to finish */ sem_wait(&priv->selectsem); /* Sleep the Thread */ cc3000_devtake(priv); sched_unlock(); if (priv->accepting_socket.acc.status != CC3000_SOC_ERROR) { *addr = priv->accepting_socket.addr; *addrlen = priv->accepting_socket.addrlen; cc3000_add_socket(priv, priv->accepting_socket.acc.status); } return priv->accepting_socket.acc.status; } /**************************************************************************** * Name: cc3000_add_socket * * Description: * Adds a socket to the list for monitoring for long operation * * Input Parameters: * sd cc3000 socket handle * minor - The input device minor number * * Returned Value: * Zero is returned on success. Otherwise, a -1 value is * returned to indicate socket not found. * ****************************************************************************/ static int cc3000_add_socket(FAR struct cc3000_dev_s *priv, int sd) { irqstate_t flags; int s; if (sd < 0) { return sd; } flags = enter_critical_section(); for (s = 0; s < CONFIG_WL_MAX_SOCKETS; s++) { if (priv->sockets[s].sd == FREE_SLOT) { priv->sockets[s].received_closed_event = false; priv->sockets[s].emptied_and_remotely_closed = false; priv->sockets[s].sd = sd; break; } } leave_critical_section(flags); return s >= CONFIG_WL_MAX_SOCKETS ? -1 : OK; } /**************************************************************************** * Name: cc3000_remove_socket * * Description: * Removes a socket from the list of monitoring for long operation * * Input Parameters: * sd cc3000 socket handle * minor - The input device minor number * * Returned Value: * Zero is returned on success. Otherwise, a -1 value is * returned to indicate socket not found. * ****************************************************************************/ static int cc3000_remove_socket(FAR struct cc3000_dev_s *priv, int sd) { irqstate_t flags; int s; sem_t *ps = 0; if (sd < 0) { return sd; } flags = enter_critical_section(); if (priv->accepting_socket.acc.sd == sd) { priv->accepting_socket.acc.sd = CLOSE_SLOT; ps = &priv->accepting_socket.acc.semwait; } for (s = 0; s < CONFIG_WL_MAX_SOCKETS; s++) { if (priv->sockets[s].sd == sd) { priv->sockets[s].received_closed_event = false; priv->sockets[s].emptied_and_remotely_closed = false; priv->sockets[s].sd = CLOSE_SLOT; ps = &priv->sockets[s].semwait; break; } } leave_critical_section(flags); if (ps) { sched_lock(); cc3000_devgive(priv); sem_post(&priv->selectsem); /* Wake select thread if need be */ sem_wait(ps); sem_wait(&priv->selectsem); /* Sleep the Thread */ cc3000_devtake(priv); sched_unlock(); } return s >= CONFIG_WL_MAX_SOCKETS ? -1 : OK; } /**************************************************************************** * Name: cc3000_remote_closed_socket * * Description: * Mark socket as closed by remote host * * Input Parameters: * sd cc3000 socket handle * * Returned Value: * Zero is returned on success. Otherwise, a -1 value is * returned to indicate socket not found. * ****************************************************************************/ static int cc3000_remote_closed_socket(FAR struct cc3000_dev_s *priv, int sd) { irqstate_t flags; int s; if (sd < 0) { return sd; } flags = enter_critical_section(); for (s = 0; s < CONFIG_WL_MAX_SOCKETS; s++) { if (priv->sockets[s].sd == sd) { priv->sockets[s].received_closed_event = true; } } leave_critical_section(flags); return s >= CONFIG_WL_MAX_SOCKETS ? -1 : OK; }