/* * Copyright (c) 2006-2022, RT-Thread Development Team * * SPDX-License-Identifier: Apache-2.0 * * Change Logs: * Date Author Notes * 2012-12-8 Bernard add file header * export bsd socket symbol for RT-Thread Application Module * 2013-05-25 Bernard port to v1.4.1 * 2017-03-26 HuangXiHans port to v2.0.2 * 2017-11-15 Bernard add lock for init_done callback * 2018-11-02 MurphyZhao port to v2.1.0 * 2020-06-20 liuxianliang port to v2.1.2 * 2021-06-25 liuxianliang port to v2.0.3 * 2022-01-18 Meco Man remove v2.0.2 * 2022-02-20 Meco Man integrate v1.4.1 v2.0.3 and v2.1.2 porting layer */ #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include /* * Initialize the ethernetif layer and set network interface device up */ static void tcpip_init_done_callback(void *arg) { rt_sem_release((rt_sem_t)arg); } /** * LwIP system initialization */ int lwip_system_init(void) { rt_err_t rc; struct rt_semaphore done_sem; static rt_bool_t init_ok = RT_FALSE; if (init_ok) { rt_kprintf("lwip system already init.\n"); return 0; } extern int eth_system_device_init_private(void); eth_system_device_init_private(); /* set default netif to NULL */ netif_default = RT_NULL; rc = rt_sem_init(&done_sem, "done", 0, RT_IPC_FLAG_FIFO); if (rc != RT_EOK) { LWIP_ASSERT("Failed to create semaphore", 0); return -1; } tcpip_init(tcpip_init_done_callback, (void *)&done_sem); /* waiting for initialization done */ if (rt_sem_take(&done_sem, RT_WAITING_FOREVER) != RT_EOK) { rt_sem_detach(&done_sem); return -1; } rt_sem_detach(&done_sem); rt_kprintf("lwIP-%d.%d.%d initialized!\n", LWIP_VERSION_MAJOR, LWIP_VERSION_MINOR, LWIP_VERSION_REVISION); init_ok = RT_TRUE; return 0; } INIT_PREV_EXPORT(lwip_system_init); void sys_init(void) { /* nothing on RT-Thread porting */ } void lwip_sys_init(void) { lwip_system_init(); } /* * Create a new semaphore * * @return the operation status, ERR_OK on OK; others on error */ err_t sys_sem_new(sys_sem_t *sem, u8_t count) { static unsigned short counter = 0; char tname[RT_NAME_MAX]; sys_sem_t tmpsem; RT_DEBUG_NOT_IN_INTERRUPT; rt_snprintf(tname, RT_NAME_MAX, "%s%d", SYS_LWIP_SEM_NAME, counter); counter ++; tmpsem = rt_sem_create(tname, count, RT_IPC_FLAG_FIFO); if (tmpsem == RT_NULL) { return ERR_MEM; } else { *sem = tmpsem; return ERR_OK; } } /* * Deallocate a semaphore */ void sys_sem_free(sys_sem_t *sem) { RT_DEBUG_NOT_IN_INTERRUPT; rt_sem_delete(*sem); } /* * Signal a semaphore */ void sys_sem_signal(sys_sem_t *sem) { rt_sem_release(*sem); } /* * Block the thread while waiting for the semaphore to be signaled * * @return If the timeout argument is non-zero, it will return the number of milliseconds * spent waiting for the semaphore to be signaled; If the semaphore isn't signaled * within the specified time, it will return SYS_ARCH_TIMEOUT; If the thread doesn't * wait for the semaphore, it will return zero */ u32_t sys_arch_sem_wait(sys_sem_t *sem, u32_t timeout) { rt_err_t ret; s32_t t; u32_t tick; RT_DEBUG_NOT_IN_INTERRUPT; /* get the begin tick */ tick = rt_tick_get(); if (timeout == 0) { t = RT_WAITING_FOREVER; } else { /* convert msecond to os tick */ if (timeout < (1000 / RT_TICK_PER_SECOND)) t = 1; else t = timeout / (1000 / RT_TICK_PER_SECOND); } ret = rt_sem_take(*sem, t); if (ret == -RT_ETIMEOUT) { return SYS_ARCH_TIMEOUT; } else { if (ret == RT_EOK) ret = 1; } /* get elapse msecond */ tick = rt_tick_get() - tick; /* convert tick to msecond */ tick = tick * (1000 / RT_TICK_PER_SECOND); if (tick == 0) tick = 1; return tick; } #ifndef sys_sem_valid /** Check if a semaphore is valid/allocated: * return 1 for valid, 0 for invalid */ int sys_sem_valid(sys_sem_t *sem) { int ret = 0; if (*sem) ret = 1; return ret; } #endif #ifndef sys_sem_set_invalid /** Set a semaphore invalid so that sys_sem_valid returns 0 */ void sys_sem_set_invalid(sys_sem_t *sem) { *sem = RT_NULL; } #endif /* ====================== Mutex ====================== */ /** Create a new mutex * @param mutex pointer to the mutex to create * @return a new mutex */ err_t sys_mutex_new(sys_mutex_t *mutex) { static unsigned short counter = 0; char tname[RT_NAME_MAX]; sys_mutex_t tmpmutex; RT_DEBUG_NOT_IN_INTERRUPT; rt_snprintf(tname, RT_NAME_MAX, "%s%d", SYS_LWIP_MUTEX_NAME, counter); counter ++; tmpmutex = rt_mutex_create(tname, RT_IPC_FLAG_PRIO); if (tmpmutex == RT_NULL) { return ERR_MEM; } else { *mutex = tmpmutex; return ERR_OK; } } /** Lock a mutex * @param mutex the mutex to lock */ void sys_mutex_lock(sys_mutex_t *mutex) { RT_DEBUG_NOT_IN_INTERRUPT; rt_mutex_take(*mutex, RT_WAITING_FOREVER); return; } /** Unlock a mutex * @param mutex the mutex to unlock */ void sys_mutex_unlock(sys_mutex_t *mutex) { rt_mutex_release(*mutex); } /** Delete a semaphore * @param mutex the mutex to delete */ void sys_mutex_free(sys_mutex_t *mutex) { RT_DEBUG_NOT_IN_INTERRUPT; rt_mutex_delete(*mutex); } #ifndef sys_mutex_valid /** Check if a mutex is valid/allocated: * return 1 for valid, 0 for invalid */ int sys_mutex_valid(sys_mutex_t *mutex) { int ret = 0; if (*mutex) ret = 1; return ret; } #endif #ifndef sys_mutex_set_invalid /** Set a mutex invalid so that sys_mutex_valid returns 0 */ void sys_mutex_set_invalid(sys_mutex_t *mutex) { *mutex = RT_NULL; } #endif /* ====================== Mailbox ====================== */ /* * Create an empty mailbox for maximum "size" elements * * @return the operation status, ERR_OK on OK; others on error */ err_t sys_mbox_new(sys_mbox_t *mbox, int size) { static unsigned short counter = 0; char tname[RT_NAME_MAX]; sys_mbox_t tmpmbox; RT_DEBUG_NOT_IN_INTERRUPT; rt_snprintf(tname, RT_NAME_MAX, "%s%d", SYS_LWIP_MBOX_NAME, counter); counter ++; tmpmbox = rt_mb_create(tname, size, RT_IPC_FLAG_FIFO); if (tmpmbox != RT_NULL) { *mbox = tmpmbox; return ERR_OK; } return ERR_MEM; } /* * Deallocate a mailbox */ void sys_mbox_free(sys_mbox_t *mbox) { RT_DEBUG_NOT_IN_INTERRUPT; rt_mb_delete(*mbox); return; } /** Post a message to an mbox - may not fail * -> blocks if full, only used from tasks not from ISR * @param mbox mbox to posts the message * @param msg message to post (ATTENTION: can be NULL) */ void sys_mbox_post(sys_mbox_t *mbox, void *msg) { RT_DEBUG_NOT_IN_INTERRUPT; rt_mb_send_wait(*mbox, (rt_ubase_t)msg, RT_WAITING_FOREVER); return; } /* * Try to post the "msg" to the mailbox * * @return return ERR_OK if the "msg" is posted, ERR_MEM if the mailbox is full */ err_t sys_mbox_trypost(sys_mbox_t *mbox, void *msg) { if (rt_mb_send(*mbox, (rt_ubase_t)msg) == RT_EOK) { return ERR_OK; } return ERR_MEM; } #if (LWIP_VERSION_MAJOR * 100 + LWIP_VERSION_MINOR) >= 201 /* >= v2.1.0 */ err_t sys_mbox_trypost_fromisr(sys_mbox_t *q, void *msg) { return sys_mbox_trypost(q, msg); } #endif /* (LWIP_VERSION_MAJOR * 100 + LWIP_VERSION_MINOR) >= 201 */ /** Wait for a new message to arrive in the mbox * @param mbox mbox to get a message from * @param msg pointer where the message is stored * @param timeout maximum time (in milliseconds) to wait for a message * @return time (in milliseconds) waited for a message, may be 0 if not waited or SYS_ARCH_TIMEOUT on timeout * The returned time has to be accurate to prevent timer jitter! */ u32_t sys_arch_mbox_fetch(sys_mbox_t *mbox, void **msg, u32_t timeout) { rt_err_t ret; s32_t t; u32_t tick; RT_DEBUG_NOT_IN_INTERRUPT; /* get the begin tick */ tick = rt_tick_get(); if(timeout == 0) { t = RT_WAITING_FOREVER; } else { /* convirt msecond to os tick */ if (timeout < (1000 / RT_TICK_PER_SECOND)) t = 1; else t = timeout / (1000 / RT_TICK_PER_SECOND); } ret = rt_mb_recv(*mbox, (rt_ubase_t *)msg, t); if(ret != RT_EOK) { return SYS_ARCH_TIMEOUT; } /* get elapse msecond */ tick = rt_tick_get() - tick; /* convert tick to msecond */ tick = tick * (1000 / RT_TICK_PER_SECOND); if (tick == 0) tick = 1; return tick; } /** * @ingroup sys_mbox * This is similar to sys_arch_mbox_fetch, however if a message is not * present in the mailbox, it immediately returns with the code * SYS_MBOX_EMPTY. On success 0 is returned. * To allow for efficient implementations, this can be defined as a * function-like macro in sys_arch.h instead of a normal function. For * example, a naive implementation could be: * \#define sys_arch_mbox_tryfetch(mbox,msg) sys_arch_mbox_fetch(mbox,msg,1) * although this would introduce unnecessary delays. * * @param mbox mbox to get a message from * @param msg pointer where the message is stored * @return 0 (milliseconds) if a message has been received * or SYS_MBOX_EMPTY if the mailbox is empty */ u32_t sys_arch_mbox_tryfetch(sys_mbox_t *mbox, void **msg) { int ret; ret = rt_mb_recv(*mbox, (rt_ubase_t *)msg, 0); if(ret == -RT_ETIMEOUT) { return SYS_ARCH_TIMEOUT; } else { if (ret == RT_EOK) ret = 0; } return ret; } #ifndef sys_mbox_valid /** Check if an mbox is valid/allocated: * return 1 for valid, 0 for invalid */ int sys_mbox_valid(sys_mbox_t *mbox) { int ret = 0; if (*mbox) ret = 1; return ret; } #endif #ifndef sys_mbox_set_invalid /** Set an mbox invalid so that sys_mbox_valid returns 0 */ void sys_mbox_set_invalid(sys_mbox_t *mbox) { *mbox = RT_NULL; } #endif /* ====================== System ====================== */ /* * Start a new thread named "name" with priority "prio" that will begin * its execution in the function "thread()". The "arg" argument will be * passed as an argument to the thread() function */ sys_thread_t sys_thread_new(const char *name, lwip_thread_fn thread, void *arg, int stacksize, int prio) { rt_thread_t t; RT_DEBUG_NOT_IN_INTERRUPT; /* create thread */ t = rt_thread_create(name, thread, arg, stacksize, prio, 20); RT_ASSERT(t != RT_NULL); /* startup thread */ rt_thread_startup(t); return t; } sys_prot_t sys_arch_protect(void) { rt_base_t level; level = rt_hw_interrupt_disable(); /* disable interrupt */ return level; } void sys_arch_unprotect(sys_prot_t pval) { rt_hw_interrupt_enable(pval); /* enable interrupt */ } void sys_arch_assert(const char *file, int line) { rt_kprintf("\nAssertion: %d in %s, thread %s\n", line, file, rt_thread_self()->parent.name); RT_ASSERT(0); } u32_t sys_jiffies(void) { return rt_tick_get(); } u32_t sys_now(void) { return rt_tick_get_millisecond(); } rt_weak void mem_init(void) { } void *mem_calloc(mem_size_t count, mem_size_t size) { return rt_calloc(count, size); } void *mem_trim(void *mem, mem_size_t size) { // return rt_realloc(mem, size); /* not support trim yet */ return mem; } void *mem_malloc(mem_size_t size) { return rt_malloc(size); } void mem_free(void *mem) { rt_free(mem); } #ifdef RT_LWIP_PPP u32_t sio_read(sio_fd_t fd, u8_t *buf, u32_t size) { u32_t len; RT_ASSERT(fd != RT_NULL); len = rt_device_read((rt_device_t)fd, 0, buf, size); if (len <= 0) return 0; return len; } u32_t sio_write(sio_fd_t fd, u8_t *buf, u32_t size) { RT_ASSERT(fd != RT_NULL); return rt_device_write((rt_device_t)fd, 0, buf, size); } void sio_read_abort(sio_fd_t fd) { rt_kprintf("read_abort\n"); } void ppp_trace(int level, const char *format, ...) { va_list args; rt_size_t length; static char rt_log_buf[RT_CONSOLEBUF_SIZE]; va_start(args, format); length = rt_vsprintf(rt_log_buf, format, args); rt_device_write((rt_device_t)rt_console_get_device(), 0, rt_log_buf, length); va_end(args); } #endif /* RT_LWIP_PPP */ #if LWIP_VERSION_MAJOR >= 2 /* >= v2.x */ #if MEM_OVERFLOW_CHECK || MEMP_OVERFLOW_CHECK /** * Check if a mep element was victim of an overflow or underflow * (e.g. the restricted area after/before it has been altered) * * @param p the mem element to check * @param size allocated size of the element * @param descr1 description of the element source shown on error * @param descr2 description of the element source shown on error */ void mem_overflow_check_raw(void *p, size_t size, const char *descr1, const char *descr2) { #if MEM_SANITY_REGION_AFTER_ALIGNED || MEM_SANITY_REGION_BEFORE_ALIGNED u16_t k; u8_t *m; #if MEM_SANITY_REGION_AFTER_ALIGNED > 0 m = (u8_t *)p + size; for (k = 0; k < MEM_SANITY_REGION_AFTER_ALIGNED; k++) { if (m[k] != 0xcd) { char errstr[128]; rt_snprintf(errstr, sizeof(errstr), "detected mem overflow in %s%s", descr1, descr2); LWIP_ASSERT(errstr, 0); } } #endif /* MEM_SANITY_REGION_AFTER_ALIGNED > 0 */ #if MEM_SANITY_REGION_BEFORE_ALIGNED > 0 m = (u8_t *)p - MEM_SANITY_REGION_BEFORE_ALIGNED; for (k = 0; k < MEM_SANITY_REGION_BEFORE_ALIGNED; k++) { if (m[k] != 0xcd) { char errstr[128]; rt_snprintf(errstr, sizeof(errstr), "detected mem underflow in %s%s", descr1, descr2); LWIP_ASSERT(errstr, 0); } } #endif /* MEM_SANITY_REGION_BEFORE_ALIGNED > 0 */ #else LWIP_UNUSED_ARG(p); LWIP_UNUSED_ARG(descr1); LWIP_UNUSED_ARG(descr2); #endif /* MEM_SANITY_REGION_AFTER_ALIGNED || MEM_SANITY_REGION_BEFORE_ALIGNED */ } /** * Initialize the restricted area of a mem element. */ void mem_overflow_init_raw(void *p, size_t size) { #if MEM_SANITY_REGION_BEFORE_ALIGNED > 0 || MEM_SANITY_REGION_AFTER_ALIGNED > 0 u8_t *m; #if MEM_SANITY_REGION_BEFORE_ALIGNED > 0 m = (u8_t *)p - MEM_SANITY_REGION_BEFORE_ALIGNED; rt_memset(m, 0xcd, MEM_SANITY_REGION_BEFORE_ALIGNED); #endif #if MEM_SANITY_REGION_AFTER_ALIGNED > 0 m = (u8_t *)p + size; rt_memset(m, 0xcd, MEM_SANITY_REGION_AFTER_ALIGNED); #endif #else /* MEM_SANITY_REGION_BEFORE_ALIGNED > 0 || MEM_SANITY_REGION_AFTER_ALIGNED > 0 */ LWIP_UNUSED_ARG(p); LWIP_UNUSED_ARG(size); #endif /* MEM_SANITY_REGION_BEFORE_ALIGNED > 0 || MEM_SANITY_REGION_AFTER_ALIGNED > 0 */ } #endif /* MEM_OVERFLOW_CHECK || MEMP_OVERFLOW_CHECK */ #ifdef LWIP_HOOK_IP4_ROUTE_SRC struct netif *lwip_ip4_route_src(const ip4_addr_t *dest, const ip4_addr_t *src) { struct netif *netif; /* iterate through netifs */ for (netif = netif_list; netif != NULL; netif = netif->next) { /* is the netif up, does it have a link and a valid address? */ if (netif_is_up(netif) && netif_is_link_up(netif) && !ip4_addr_isany_val(*netif_ip4_addr(netif))) { /* gateway matches on a non broadcast interface? (i.e. peer in a point to point interface) */ if (src != NULL) { if (ip4_addr_cmp(src, netif_ip4_addr(netif))) { return netif; } } } } netif = netif_default; return netif; } #endif /* LWIP_HOOK_IP4_ROUTE_SRC */ #endif /*LWIP_VERSION_MAJOR >= 2 */ #if LWIP_SOCKET #include RTM_EXPORT(lwip_accept); RTM_EXPORT(lwip_bind); RTM_EXPORT(lwip_shutdown); RTM_EXPORT(lwip_getpeername); RTM_EXPORT(lwip_getsockname); RTM_EXPORT(lwip_getsockopt); RTM_EXPORT(lwip_setsockopt); RTM_EXPORT(lwip_close); RTM_EXPORT(lwip_connect); RTM_EXPORT(lwip_listen); RTM_EXPORT(lwip_recv); RTM_EXPORT(lwip_read); RTM_EXPORT(lwip_recvfrom); RTM_EXPORT(lwip_send); RTM_EXPORT(lwip_sendto); RTM_EXPORT(lwip_socket); RTM_EXPORT(lwip_write); RTM_EXPORT(lwip_select); RTM_EXPORT(lwip_ioctl); RTM_EXPORT(lwip_fcntl); RTM_EXPORT(lwip_htons); RTM_EXPORT(lwip_htonl); #if LWIP_DNS #include RTM_EXPORT(lwip_gethostbyname); RTM_EXPORT(lwip_gethostbyname_r); RTM_EXPORT(lwip_freeaddrinfo); RTM_EXPORT(lwip_getaddrinfo); #endif /* LWIP_DNS */ #endif /* LWIP_SOCKET */ #if LWIP_DHCP #include RTM_EXPORT(dhcp_start); RTM_EXPORT(dhcp_renew); RTM_EXPORT(dhcp_stop); #endif /* LWIP_DHCP */ #if LWIP_NETIF_API #include RTM_EXPORT(netifapi_netif_set_addr); #endif /* LWIP_NETIF_API */ #if LWIP_NETIF_LINK_CALLBACK RTM_EXPORT(netif_set_link_callback); #endif /* LWIP_NETIF_LINK_CALLBACK */ #if LWIP_NETIF_STATUS_CALLBACK RTM_EXPORT(netif_set_status_callback); #endif /* LWIP_NETIF_STATUS_CALLBACK */ RTM_EXPORT(netif_find); RTM_EXPORT(netif_set_addr); RTM_EXPORT(netif_set_ipaddr); RTM_EXPORT(netif_set_gw); RTM_EXPORT(netif_set_netmask);