/** * @file * Sequential API Internal module * */ /* * Copyright (c) 2001-2004 Swedish Institute of Computer Science. * All rights reserved. * * 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. The name of the author may not be used to endorse or promote products * derived from this software without specific prior written permission. * * THIS SOFTWARE IS PROVIDED BY THE AUTHOR ``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 AUTHOR 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. * * This file is part of the lwIP TCP/IP stack. * * Author: Adam Dunkels * */ #include "lwip/opt.h" #if LWIP_NETCONN /* don't build if not configured for use in lwipopts.h */ #include "lwip/api_msg.h" #include "lwip/ip.h" #include "lwip/udp.h" #include "lwip/tcp.h" #include "lwip/raw.h" #include "lwip/memp.h" #include "lwip/tcpip.h" #include "lwip/igmp.h" #include "lwip/dns.h" #include /* forward declarations */ #if LWIP_TCP static err_t do_writemore(struct netconn *conn); static void do_close_internal(struct netconn *conn); #endif #if LWIP_RAW /** * Receive callback function for RAW netconns. * Doesn't 'eat' the packet, only references it and sends it to * conn->recvmbox * * @see raw.h (struct raw_pcb.recv) for parameters and return value */ static u8_t recv_raw(void *arg, struct raw_pcb *pcb, struct pbuf *p, struct ip_addr *addr) { struct pbuf *q; struct netbuf *buf; struct netconn *conn; #if LWIP_SO_RCVBUF int recv_avail; #endif /* LWIP_SO_RCVBUF */ LWIP_UNUSED_ARG(addr); conn = arg; #if LWIP_SO_RCVBUF SYS_ARCH_GET(conn->recv_avail, recv_avail); if ((conn != NULL) && (conn->recvmbox != SYS_MBOX_NULL) && ((recv_avail + (int)(p->tot_len)) <= conn->recv_bufsize)) { #else /* LWIP_SO_RCVBUF */ if ((conn != NULL) && (conn->recvmbox != SYS_MBOX_NULL)) { #endif /* LWIP_SO_RCVBUF */ /* copy the whole packet into new pbufs */ q = pbuf_alloc(PBUF_RAW, p->tot_len, PBUF_RAM); if(q != NULL) { if (pbuf_copy(q, p) != ERR_OK) { pbuf_free(q); q = NULL; } } if(q != NULL) { buf = memp_malloc(MEMP_NETBUF); if (buf == NULL) { pbuf_free(q); return 0; } buf->p = q; buf->ptr = q; buf->addr = &(((struct ip_hdr*)(q->payload))->src); buf->port = pcb->protocol; if (sys_mbox_trypost(conn->recvmbox, buf) != ERR_OK) { netbuf_delete(buf); return 0; } else { SYS_ARCH_INC(conn->recv_avail, q->tot_len); /* Register event with callback */ API_EVENT(conn, NETCONN_EVT_RCVPLUS, q->tot_len); } } } return 0; /* do not eat the packet */ } #endif /* LWIP_RAW*/ #if LWIP_UDP /** * Receive callback function for UDP netconns. * Posts the packet to conn->recvmbox or deletes it on memory error. * * @see udp.h (struct udp_pcb.recv) for parameters */ static void recv_udp(void *arg, struct udp_pcb *pcb, struct pbuf *p, struct ip_addr *addr, u16_t port) { struct netbuf *buf; struct netconn *conn; #if LWIP_SO_RCVBUF int recv_avail; #endif /* LWIP_SO_RCVBUF */ LWIP_UNUSED_ARG(pcb); /* only used for asserts... */ LWIP_ASSERT("recv_udp must have a pcb argument", pcb != NULL); LWIP_ASSERT("recv_udp must have an argument", arg != NULL); conn = arg; LWIP_ASSERT("recv_udp: recv for wrong pcb!", conn->pcb.udp == pcb); #if LWIP_SO_RCVBUF SYS_ARCH_GET(conn->recv_avail, recv_avail); if ((conn == NULL) || (conn->recvmbox == SYS_MBOX_NULL) || ((recv_avail + (int)(p->tot_len)) > conn->recv_bufsize)) { #else /* LWIP_SO_RCVBUF */ if ((conn == NULL) || (conn->recvmbox == SYS_MBOX_NULL)) { #endif /* LWIP_SO_RCVBUF */ pbuf_free(p); return; } buf = memp_malloc(MEMP_NETBUF); if (buf == NULL) { pbuf_free(p); return; } else { buf->p = p; buf->ptr = p; buf->addr = addr; buf->port = port; } if (sys_mbox_trypost(conn->recvmbox, buf) != ERR_OK) { netbuf_delete(buf); return; } else { SYS_ARCH_INC(conn->recv_avail, p->tot_len); /* Register event with callback */ API_EVENT(conn, NETCONN_EVT_RCVPLUS, p->tot_len); } } #endif /* LWIP_UDP */ #if LWIP_TCP /** * Receive callback function for TCP netconns. * Posts the packet to conn->recvmbox, but doesn't delete it on errors. * * @see tcp.h (struct tcp_pcb.recv) for parameters and return value */ static err_t recv_tcp(void *arg, struct tcp_pcb *pcb, struct pbuf *p, err_t err) { struct netconn *conn; u16_t len; LWIP_UNUSED_ARG(pcb); LWIP_ASSERT("recv_tcp must have a pcb argument", pcb != NULL); LWIP_ASSERT("recv_tcp must have an argument", arg != NULL); conn = arg; LWIP_ASSERT("recv_tcp: recv for wrong pcb!", conn->pcb.tcp == pcb); if ((conn == NULL) || (conn->recvmbox == SYS_MBOX_NULL)) { return ERR_VAL; } conn->err = err; if (p != NULL) { len = p->tot_len; SYS_ARCH_INC(conn->recv_avail, len); } else { len = 0; } if (sys_mbox_trypost(conn->recvmbox, p) != ERR_OK) { return ERR_MEM; } else { /* Register event with callback */ API_EVENT(conn, NETCONN_EVT_RCVPLUS, len); } return ERR_OK; } /** * Poll callback function for TCP netconns. * Wakes up an application thread that waits for a connection to close * or data to be sent. The application thread then takes the * appropriate action to go on. * * Signals the conn->sem. * netconn_close waits for conn->sem if closing failed. * * @see tcp.h (struct tcp_pcb.poll) for parameters and return value */ static err_t poll_tcp(void *arg, struct tcp_pcb *pcb) { struct netconn *conn = arg; LWIP_UNUSED_ARG(pcb); LWIP_ASSERT("conn != NULL", (conn != NULL)); if (conn->state == NETCONN_WRITE) { do_writemore(conn); } else if (conn->state == NETCONN_CLOSE) { do_close_internal(conn); } return ERR_OK; } /** * Sent callback function for TCP netconns. * Signals the conn->sem and calls API_EVENT. * netconn_write waits for conn->sem if send buffer is low. * * @see tcp.h (struct tcp_pcb.sent) for parameters and return value */ static err_t sent_tcp(void *arg, struct tcp_pcb *pcb, u16_t len) { struct netconn *conn = arg; LWIP_UNUSED_ARG(pcb); LWIP_ASSERT("conn != NULL", (conn != NULL)); if (conn->state == NETCONN_WRITE) { LWIP_ASSERT("conn->pcb.tcp != NULL", conn->pcb.tcp != NULL); do_writemore(conn); } else if (conn->state == NETCONN_CLOSE) { do_close_internal(conn); } if (conn) { if ((conn->pcb.tcp != NULL) && (tcp_sndbuf(conn->pcb.tcp) > TCP_SNDLOWAT)) { API_EVENT(conn, NETCONN_EVT_SENDPLUS, len); } } return ERR_OK; } /** * Error callback function for TCP netconns. * Signals conn->sem, posts to all conn mboxes and calls API_EVENT. * The application thread has then to decide what to do. * * @see tcp.h (struct tcp_pcb.err) for parameters */ static void err_tcp(void *arg, err_t err) { struct netconn *conn; conn = arg; LWIP_ASSERT("conn != NULL", (conn != NULL)); conn->pcb.tcp = NULL; conn->err = err; if (conn->recvmbox != SYS_MBOX_NULL) { /* Register event with callback */ API_EVENT(conn, NETCONN_EVT_RCVPLUS, 0); sys_mbox_post(conn->recvmbox, NULL); } if (conn->op_completed != SYS_SEM_NULL && conn->state == NETCONN_CONNECT) { conn->state = NETCONN_NONE; sys_sem_signal(conn->op_completed); } if (conn->acceptmbox != SYS_MBOX_NULL) { /* Register event with callback */ API_EVENT(conn, NETCONN_EVT_RCVPLUS, 0); sys_mbox_post(conn->acceptmbox, NULL); } if ((conn->state == NETCONN_WRITE) || (conn->state == NETCONN_CLOSE)) { /* calling do_writemore/do_close_internal is not necessary since the pcb has already been deleted! */ conn->state = NETCONN_NONE; /* wake up the waiting task */ sys_sem_signal(conn->op_completed); } } /** * Setup a tcp_pcb with the correct callback function pointers * and their arguments. * * @param conn the TCP netconn to setup */ static void setup_tcp(struct netconn *conn) { struct tcp_pcb *pcb; pcb = conn->pcb.tcp; tcp_arg(pcb, conn); tcp_recv(pcb, recv_tcp); tcp_sent(pcb, sent_tcp); tcp_poll(pcb, poll_tcp, 4); tcp_err(pcb, err_tcp); } /** * Accept callback function for TCP netconns. * Allocates a new netconn and posts that to conn->acceptmbox. * * @see tcp.h (struct tcp_pcb_listen.accept) for parameters and return value */ static err_t accept_function(void *arg, struct tcp_pcb *newpcb, err_t err) { struct netconn *newconn; struct netconn *conn; #if API_MSG_DEBUG #if TCP_DEBUG tcp_debug_print_state(newpcb->state); #endif /* TCP_DEBUG */ #endif /* API_MSG_DEBUG */ conn = (struct netconn *)arg; LWIP_ERROR("accept_function: invalid conn->acceptmbox", conn->acceptmbox != SYS_MBOX_NULL, return ERR_VAL;); /* We have to set the callback here even though * the new socket is unknown. conn->socket is marked as -1. */ newconn = netconn_alloc(conn->type, conn->callback); if (newconn == NULL) { return ERR_MEM; } newconn->pcb.tcp = newpcb; setup_tcp(newconn); newconn->err = err; if (sys_mbox_trypost(conn->acceptmbox, newconn) != ERR_OK) { /* When returning != ERR_OK, the connection is aborted in tcp_process(), so do nothing here! */ newconn->pcb.tcp = NULL; netconn_free(newconn); return ERR_MEM; } else { /* Register event with callback */ API_EVENT(conn, NETCONN_EVT_RCVPLUS, 0); } return ERR_OK; } #endif /* LWIP_TCP */ /** * Create a new pcb of a specific type. * Called from do_newconn(). * * @param msg the api_msg_msg describing the connection type * @return msg->conn->err, but the return value is currently ignored */ static err_t pcb_new(struct api_msg_msg *msg) { msg->conn->err = ERR_OK; LWIP_ASSERT("pcb_new: pcb already allocated", msg->conn->pcb.tcp == NULL); /* Allocate a PCB for this connection */ switch(NETCONNTYPE_GROUP(msg->conn->type)) { #if LWIP_RAW case NETCONN_RAW: msg->conn->pcb.raw = raw_new(msg->msg.n.proto); if(msg->conn->pcb.raw == NULL) { msg->conn->err = ERR_MEM; break; } raw_recv(msg->conn->pcb.raw, recv_raw, msg->conn); break; #endif /* LWIP_RAW */ #if LWIP_UDP case NETCONN_UDP: msg->conn->pcb.udp = udp_new(); if(msg->conn->pcb.udp == NULL) { msg->conn->err = ERR_MEM; break; } #if LWIP_UDPLITE if (msg->conn->type==NETCONN_UDPLITE) { udp_setflags(msg->conn->pcb.udp, UDP_FLAGS_UDPLITE); } #endif /* LWIP_UDPLITE */ if (msg->conn->type==NETCONN_UDPNOCHKSUM) { udp_setflags(msg->conn->pcb.udp, UDP_FLAGS_NOCHKSUM); } udp_recv(msg->conn->pcb.udp, recv_udp, msg->conn); break; #endif /* LWIP_UDP */ #if LWIP_TCP case NETCONN_TCP: msg->conn->pcb.tcp = tcp_new(); if(msg->conn->pcb.tcp == NULL) { msg->conn->err = ERR_MEM; break; } setup_tcp(msg->conn); break; #endif /* LWIP_TCP */ default: /* Unsupported netconn type, e.g. protocol disabled */ msg->conn->err = ERR_VAL; break; } return msg->conn->err; } /** * Create a new pcb of a specific type inside a netconn. * Called from netconn_new_with_proto_and_callback. * * @param msg the api_msg_msg describing the connection type */ void do_newconn(struct api_msg_msg *msg) { if(msg->conn->pcb.tcp == NULL) { pcb_new(msg); } /* Else? This "new" connection already has a PCB allocated. */ /* Is this an error condition? Should it be deleted? */ /* We currently just are happy and return. */ TCPIP_APIMSG_ACK(msg); } /** * Create a new netconn (of a specific type) that has a callback function. * The corresponding pcb is NOT created! * * @param t the type of 'connection' to create (@see enum netconn_type) * @param proto the IP protocol for RAW IP pcbs * @param callback a function to call on status changes (RX available, TX'ed) * @return a newly allocated struct netconn or * NULL on memory error */ struct netconn* netconn_alloc(enum netconn_type t, netconn_callback callback) { struct netconn *conn; int size; conn = memp_malloc(MEMP_NETCONN); if (conn == NULL) { return NULL; } conn->err = ERR_OK; conn->type = t; conn->pcb.tcp = NULL; #if (DEFAULT_RAW_RECVMBOX_SIZE == DEFAULT_UDP_RECVMBOX_SIZE) && \ (DEFAULT_RAW_RECVMBOX_SIZE == DEFAULT_TCP_RECVMBOX_SIZE) size = DEFAULT_RAW_RECVMBOX_SIZE; #else switch(NETCONNTYPE_GROUP(t)) { #if LWIP_RAW case NETCONN_RAW: size = DEFAULT_RAW_RECVMBOX_SIZE; break; #endif /* LWIP_RAW */ #if LWIP_UDP case NETCONN_UDP: size = DEFAULT_UDP_RECVMBOX_SIZE; break; #endif /* LWIP_UDP */ #if LWIP_TCP case NETCONN_TCP: size = DEFAULT_TCP_RECVMBOX_SIZE; break; #endif /* LWIP_TCP */ default: LWIP_ASSERT("netconn_alloc: undefined netconn_type", 0); break; } #endif if ((conn->op_completed = sys_sem_new(0)) == SYS_SEM_NULL) { memp_free(MEMP_NETCONN, conn); return NULL; } if ((conn->recvmbox = sys_mbox_new(size)) == SYS_MBOX_NULL) { sys_sem_free(conn->op_completed); memp_free(MEMP_NETCONN, conn); return NULL; } conn->acceptmbox = SYS_MBOX_NULL; conn->state = NETCONN_NONE; /* initialize socket to -1 since 0 is a valid socket */ conn->socket = -1; conn->callback = callback; conn->recv_avail = 0; #if LWIP_TCP conn->write_msg = NULL; conn->write_offset = 0; #if LWIP_TCPIP_CORE_LOCKING conn->write_delayed = 0; #endif /* LWIP_TCPIP_CORE_LOCKING */ #endif /* LWIP_TCP */ #if LWIP_SO_RCVTIMEO conn->recv_timeout = 0; #endif /* LWIP_SO_RCVTIMEO */ #if LWIP_SO_RCVBUF conn->recv_bufsize = RECV_BUFSIZE_DEFAULT; #endif /* LWIP_SO_RCVBUF */ return conn; } /** * Delete a netconn and all its resources. * The pcb is NOT freed (since we might not be in the right thread context do this). * * @param conn the netconn to free */ void netconn_free(struct netconn *conn) { void *mem; LWIP_ASSERT("PCB must be deallocated outside this function", conn->pcb.tcp == NULL); /* Drain the recvmbox. */ if (conn->recvmbox != SYS_MBOX_NULL) { while (sys_mbox_tryfetch(conn->recvmbox, &mem) != SYS_MBOX_EMPTY) { if (conn->type == NETCONN_TCP) { if(mem != NULL) { pbuf_free((struct pbuf *)mem); } } else { netbuf_delete((struct netbuf *)mem); } } sys_mbox_free(conn->recvmbox); conn->recvmbox = SYS_MBOX_NULL; } /* Drain the acceptmbox. */ if (conn->acceptmbox != SYS_MBOX_NULL) { while (sys_mbox_tryfetch(conn->acceptmbox, &mem) != SYS_MBOX_EMPTY) { netconn_delete((struct netconn *)mem); } sys_mbox_free(conn->acceptmbox); conn->acceptmbox = SYS_MBOX_NULL; } sys_sem_free(conn->op_completed); conn->op_completed = SYS_SEM_NULL; memp_free(MEMP_NETCONN, conn); } #if LWIP_TCP /** * Internal helper function to close a TCP netconn: since this sometimes * doesn't work at the first attempt, this function is called from multiple * places. * * @param conn the TCP netconn to close */ static void do_close_internal(struct netconn *conn) { err_t err; LWIP_ASSERT("invalid conn", (conn != NULL)); LWIP_ASSERT("this is for tcp netconns only", (conn->type == NETCONN_TCP)); LWIP_ASSERT("conn must be in state NETCONN_CLOSE", (conn->state == NETCONN_CLOSE)); LWIP_ASSERT("pcb already closed", (conn->pcb.tcp != NULL)); /* Set back some callback pointers */ tcp_arg(conn->pcb.tcp, NULL); if (conn->pcb.tcp->state == LISTEN) { tcp_accept(conn->pcb.tcp, NULL); } else { tcp_recv(conn->pcb.tcp, NULL); tcp_accept(conn->pcb.tcp, NULL); /* some callbacks have to be reset if tcp_close is not successful */ tcp_sent(conn->pcb.tcp, NULL); tcp_poll(conn->pcb.tcp, NULL, 4); tcp_err(conn->pcb.tcp, NULL); } /* Try to close the connection */ err = tcp_close(conn->pcb.tcp); if (err == ERR_OK) { /* Closing succeeded */ conn->state = NETCONN_NONE; /* Set back some callback pointers as conn is going away */ conn->pcb.tcp = NULL; conn->err = ERR_OK; /* Trigger select() in socket layer. This send should something else so the errorfd is set, not the read and write fd! */ API_EVENT(conn, NETCONN_EVT_RCVPLUS, 0); API_EVENT(conn, NETCONN_EVT_SENDPLUS, 0); /* wake up the application task */ sys_sem_signal(conn->op_completed); } else { /* Closing failed, restore some of the callbacks */ /* Closing of listen pcb will never fail! */ LWIP_ASSERT("Closing a listen pcb may not fail!", (conn->pcb.tcp->state != LISTEN)); tcp_sent(conn->pcb.tcp, sent_tcp); tcp_poll(conn->pcb.tcp, poll_tcp, 4); tcp_err(conn->pcb.tcp, err_tcp); tcp_arg(conn->pcb.tcp, conn); } /* If closing didn't succeed, we get called again either from poll_tcp or from sent_tcp */ } #endif /* LWIP_TCP */ /** * Delete the pcb inside a netconn. * Called from netconn_delete. * * @param msg the api_msg_msg pointing to the connection */ void do_delconn(struct api_msg_msg *msg) { if (msg->conn->pcb.tcp != NULL) { switch (NETCONNTYPE_GROUP(msg->conn->type)) { #if LWIP_RAW case NETCONN_RAW: raw_remove(msg->conn->pcb.raw); break; #endif /* LWIP_RAW */ #if LWIP_UDP case NETCONN_UDP: msg->conn->pcb.udp->recv_arg = NULL; udp_remove(msg->conn->pcb.udp); break; #endif /* LWIP_UDP */ #if LWIP_TCP case NETCONN_TCP: msg->conn->state = NETCONN_CLOSE; do_close_internal(msg->conn); /* API_EVENT is called inside do_close_internal, before releasing the application thread, so we can return at this point! */ return; #endif /* LWIP_TCP */ default: break; } } /* tcp netconns don't come here! */ /* Trigger select() in socket layer. This send should something else so the errorfd is set, not the read and write fd! */ API_EVENT(msg->conn, NETCONN_EVT_RCVPLUS, 0); API_EVENT(msg->conn, NETCONN_EVT_SENDPLUS, 0); if (msg->conn->op_completed != SYS_SEM_NULL) { sys_sem_signal(msg->conn->op_completed); } } /** * Bind a pcb contained in a netconn * Called from netconn_bind. * * @param msg the api_msg_msg pointing to the connection and containing * the IP address and port to bind to */ void do_bind(struct api_msg_msg *msg) { if (!ERR_IS_FATAL(msg->conn->err)) { if (msg->conn->pcb.tcp != NULL) { switch (NETCONNTYPE_GROUP(msg->conn->type)) { #if LWIP_RAW case NETCONN_RAW: msg->conn->err = raw_bind(msg->conn->pcb.raw, msg->msg.bc.ipaddr); break; #endif /* LWIP_RAW */ #if LWIP_UDP case NETCONN_UDP: msg->conn->err = udp_bind(msg->conn->pcb.udp, msg->msg.bc.ipaddr, msg->msg.bc.port); break; #endif /* LWIP_UDP */ #if LWIP_TCP case NETCONN_TCP: msg->conn->err = tcp_bind(msg->conn->pcb.tcp, msg->msg.bc.ipaddr, msg->msg.bc.port); break; #endif /* LWIP_TCP */ default: break; } } else { /* msg->conn->pcb is NULL */ msg->conn->err = ERR_VAL; } } TCPIP_APIMSG_ACK(msg); } #if LWIP_TCP /** * TCP callback function if a connection (opened by tcp_connect/do_connect) has * been established (or reset by the remote host). * * @see tcp.h (struct tcp_pcb.connected) for parameters and return values */ static err_t do_connected(void *arg, struct tcp_pcb *pcb, err_t err) { struct netconn *conn; LWIP_UNUSED_ARG(pcb); conn = arg; if (conn == NULL) { return ERR_VAL; } conn->err = err; if ((conn->type == NETCONN_TCP) && (err == ERR_OK)) { setup_tcp(conn); } conn->state = NETCONN_NONE; sys_sem_signal(conn->op_completed); return ERR_OK; } #endif /* LWIP_TCP */ /** * Connect a pcb contained inside a netconn * Called from netconn_connect. * * @param msg the api_msg_msg pointing to the connection and containing * the IP address and port to connect to */ void do_connect(struct api_msg_msg *msg) { if (msg->conn->pcb.tcp == NULL) { sys_sem_signal(msg->conn->op_completed); return; } switch (NETCONNTYPE_GROUP(msg->conn->type)) { #if LWIP_RAW case NETCONN_RAW: msg->conn->err = raw_connect(msg->conn->pcb.raw, msg->msg.bc.ipaddr); sys_sem_signal(msg->conn->op_completed); break; #endif /* LWIP_RAW */ #if LWIP_UDP case NETCONN_UDP: msg->conn->err = udp_connect(msg->conn->pcb.udp, msg->msg.bc.ipaddr, msg->msg.bc.port); sys_sem_signal(msg->conn->op_completed); break; #endif /* LWIP_UDP */ #if LWIP_TCP case NETCONN_TCP: msg->conn->state = NETCONN_CONNECT; setup_tcp(msg->conn); msg->conn->err = tcp_connect(msg->conn->pcb.tcp, msg->msg.bc.ipaddr, msg->msg.bc.port, do_connected); /* sys_sem_signal() is called from do_connected (or err_tcp()), * when the connection is established! */ break; #endif /* LWIP_TCP */ default: break; } } /** * Connect a pcb contained inside a netconn * Only used for UDP netconns. * Called from netconn_disconnect. * * @param msg the api_msg_msg pointing to the connection to disconnect */ void do_disconnect(struct api_msg_msg *msg) { #if LWIP_UDP if (NETCONNTYPE_GROUP(msg->conn->type) == NETCONN_UDP) { udp_disconnect(msg->conn->pcb.udp); } #endif /* LWIP_UDP */ TCPIP_APIMSG_ACK(msg); } /** * Set a TCP pcb contained in a netconn into listen mode * Called from netconn_listen. * * @param msg the api_msg_msg pointing to the connection */ void do_listen(struct api_msg_msg *msg) { #if LWIP_TCP if (!ERR_IS_FATAL(msg->conn->err)) { if (msg->conn->pcb.tcp != NULL) { if (msg->conn->type == NETCONN_TCP) { if (msg->conn->pcb.tcp->state == CLOSED) { #if TCP_LISTEN_BACKLOG struct tcp_pcb* lpcb = tcp_listen_with_backlog(msg->conn->pcb.tcp, msg->msg.lb.backlog); #else /* TCP_LISTEN_BACKLOG */ struct tcp_pcb* lpcb = tcp_listen(msg->conn->pcb.tcp); #endif /* TCP_LISTEN_BACKLOG */ if (lpcb == NULL) { msg->conn->err = ERR_MEM; } else { /* delete the recvmbox and allocate the acceptmbox */ if (msg->conn->recvmbox != SYS_MBOX_NULL) { /** @todo: should we drain the recvmbox here? */ sys_mbox_free(msg->conn->recvmbox); msg->conn->recvmbox = SYS_MBOX_NULL; } if (msg->conn->acceptmbox == SYS_MBOX_NULL) { if ((msg->conn->acceptmbox = sys_mbox_new(DEFAULT_ACCEPTMBOX_SIZE)) == SYS_MBOX_NULL) { msg->conn->err = ERR_MEM; } } if (msg->conn->err == ERR_OK) { msg->conn->state = NETCONN_LISTEN; msg->conn->pcb.tcp = lpcb; tcp_arg(msg->conn->pcb.tcp, msg->conn); tcp_accept(msg->conn->pcb.tcp, accept_function); } } } else { msg->conn->err = ERR_CONN; } } } } #endif /* LWIP_TCP */ TCPIP_APIMSG_ACK(msg); } /** * Send some data on a RAW or UDP pcb contained in a netconn * Called from netconn_send * * @param msg the api_msg_msg pointing to the connection */ void do_send(struct api_msg_msg *msg) { if (!ERR_IS_FATAL(msg->conn->err)) { if (msg->conn->pcb.tcp != NULL) { switch (NETCONNTYPE_GROUP(msg->conn->type)) { #if LWIP_RAW case NETCONN_RAW: if (msg->msg.b->addr == NULL) { msg->conn->err = raw_send(msg->conn->pcb.raw, msg->msg.b->p); } else { msg->conn->err = raw_sendto(msg->conn->pcb.raw, msg->msg.b->p, msg->msg.b->addr); } break; #endif #if LWIP_UDP case NETCONN_UDP: if (msg->msg.b->addr == NULL) { msg->conn->err = udp_send(msg->conn->pcb.udp, msg->msg.b->p); } else { msg->conn->err = udp_sendto(msg->conn->pcb.udp, msg->msg.b->p, msg->msg.b->addr, msg->msg.b->port); } break; #endif /* LWIP_UDP */ default: break; } } } TCPIP_APIMSG_ACK(msg); } /** * Indicate data has been received from a TCP pcb contained in a netconn * Called from netconn_recv * * @param msg the api_msg_msg pointing to the connection */ void do_recv(struct api_msg_msg *msg) { #if LWIP_TCP if (!ERR_IS_FATAL(msg->conn->err)) { if (msg->conn->pcb.tcp != NULL) { if (msg->conn->type == NETCONN_TCP) { #if TCP_LISTEN_BACKLOG if (msg->conn->pcb.tcp->state == LISTEN) { tcp_accepted(msg->conn->pcb.tcp); } else #endif /* TCP_LISTEN_BACKLOG */ { tcp_recved(msg->conn->pcb.tcp, msg->msg.r.len); } } } } #endif /* LWIP_TCP */ TCPIP_APIMSG_ACK(msg); } #if LWIP_TCP /** * See if more data needs to be written from a previous call to netconn_write. * Called initially from do_write. If the first call can't send all data * (because of low memory or empty send-buffer), this function is called again * from sent_tcp() or poll_tcp() to send more data. If all data is sent, the * blocking application thread (waiting in netconn_write) is released. * * @param conn netconn (that is currently in state NETCONN_WRITE) to process * @return ERR_OK * ERR_MEM if LWIP_TCPIP_CORE_LOCKING=1 and sending hasn't yet finished */ static err_t do_writemore(struct netconn *conn) { err_t err; void *dataptr; u16_t len, available; u8_t write_finished = 0; size_t diff; LWIP_ASSERT("conn->state == NETCONN_WRITE", (conn->state == NETCONN_WRITE)); dataptr = (u8_t*)conn->write_msg->msg.w.dataptr + conn->write_offset; diff = conn->write_msg->msg.w.len - conn->write_offset; if (diff > 0xffffUL) { /* max_u16_t */ len = 0xffff; #if LWIP_TCPIP_CORE_LOCKING conn->write_delayed = 1; #endif } else { len = (u16_t)diff; } available = tcp_sndbuf(conn->pcb.tcp); if (available < len) { /* don't try to write more than sendbuf */ len = available; #if LWIP_TCPIP_CORE_LOCKING conn->write_delayed = 1; #endif } err = tcp_write(conn->pcb.tcp, dataptr, len, conn->write_msg->msg.w.apiflags); LWIP_ASSERT("do_writemore: invalid length!", ((conn->write_offset + len) <= conn->write_msg->msg.w.len)); if (err == ERR_OK) { conn->write_offset += len; if (conn->write_offset == conn->write_msg->msg.w.len) { /* everything was written */ write_finished = 1; conn->write_msg = NULL; conn->write_offset = 0; /* API_EVENT might call tcp_tmr, so reset conn->state now */ conn->state = NETCONN_NONE; } err = tcp_output_nagle(conn->pcb.tcp); conn->err = err; if ((err == ERR_OK) && (tcp_sndbuf(conn->pcb.tcp) <= TCP_SNDLOWAT)) { API_EVENT(conn, NETCONN_EVT_SENDMINUS, len); } } else if (err == ERR_MEM) { /* If ERR_MEM, we wait for sent_tcp or poll_tcp to be called we do NOT return to the application thread, since ERR_MEM is only a temporary error! */ /* tcp_enqueue returned ERR_MEM, try tcp_output anyway */ err = tcp_output(conn->pcb.tcp); #if LWIP_TCPIP_CORE_LOCKING conn->write_delayed = 1; #endif } else { /* On errors != ERR_MEM, we don't try writing any more but return the error to the application thread. */ conn->err = err; write_finished = 1; } if (write_finished) { /* everything was written: set back connection state and back to application task */ conn->state = NETCONN_NONE; #if LWIP_TCPIP_CORE_LOCKING if (conn->write_delayed != 0) #endif { sys_sem_signal(conn->op_completed); } } #if LWIP_TCPIP_CORE_LOCKING else return ERR_MEM; #endif return ERR_OK; } #endif /* LWIP_TCP */ /** * Send some data on a TCP pcb contained in a netconn * Called from netconn_write * * @param msg the api_msg_msg pointing to the connection */ void do_write(struct api_msg_msg *msg) { if (!ERR_IS_FATAL(msg->conn->err)) { if ((msg->conn->pcb.tcp != NULL) && (msg->conn->type == NETCONN_TCP)) { #if LWIP_TCP msg->conn->state = NETCONN_WRITE; /* set all the variables used by do_writemore */ LWIP_ASSERT("already writing", msg->conn->write_msg == NULL && msg->conn->write_offset == 0); msg->conn->write_msg = msg; msg->conn->write_offset = 0; #if LWIP_TCPIP_CORE_LOCKING msg->conn->write_delayed = 0; if (do_writemore(msg->conn) != ERR_OK) { LWIP_ASSERT("state!", msg->conn->state == NETCONN_WRITE); UNLOCK_TCPIP_CORE(); sys_arch_sem_wait(msg->conn->op_completed, 0); LOCK_TCPIP_CORE(); LWIP_ASSERT("state!", msg->conn->state == NETCONN_NONE); } #else do_writemore(msg->conn); #endif /* for both cases: if do_writemore was called, don't ACK the APIMSG! */ return; #endif /* LWIP_TCP */ #if (LWIP_UDP || LWIP_RAW) } else { msg->conn->err = ERR_VAL; #endif /* (LWIP_UDP || LWIP_RAW) */ } } TCPIP_APIMSG_ACK(msg); } /** * Return a connection's local or remote address * Called from netconn_getaddr * * @param msg the api_msg_msg pointing to the connection */ void do_getaddr(struct api_msg_msg *msg) { if (msg->conn->pcb.ip != NULL) { *(msg->msg.ad.ipaddr) = (msg->msg.ad.local?msg->conn->pcb.ip->local_ip:msg->conn->pcb.ip->remote_ip); switch (NETCONNTYPE_GROUP(msg->conn->type)) { #if LWIP_RAW case NETCONN_RAW: if (msg->msg.ad.local) { *(msg->msg.ad.port) = msg->conn->pcb.raw->protocol; } else { /* return an error as connecting is only a helper for upper layers */ msg->conn->err = ERR_CONN; } break; #endif /* LWIP_RAW */ #if LWIP_UDP case NETCONN_UDP: if (msg->msg.ad.local) { *(msg->msg.ad.port) = msg->conn->pcb.udp->local_port; } else { if ((msg->conn->pcb.udp->flags & UDP_FLAGS_CONNECTED) == 0) { msg->conn->err = ERR_CONN; } else { *(msg->msg.ad.port) = msg->conn->pcb.udp->remote_port; } } break; #endif /* LWIP_UDP */ #if LWIP_TCP case NETCONN_TCP: *(msg->msg.ad.port) = (msg->msg.ad.local?msg->conn->pcb.tcp->local_port:msg->conn->pcb.tcp->remote_port); break; #endif /* LWIP_TCP */ } } else { msg->conn->err = ERR_CONN; } TCPIP_APIMSG_ACK(msg); } /** * Close a TCP pcb contained in a netconn * Called from netconn_close * * @param msg the api_msg_msg pointing to the connection */ void do_close(struct api_msg_msg *msg) { #if LWIP_TCP if ((msg->conn->pcb.tcp != NULL) && (msg->conn->type == NETCONN_TCP)) { msg->conn->state = NETCONN_CLOSE; do_close_internal(msg->conn); /* for tcp netconns, do_close_internal ACKs the message */ } else #endif /* LWIP_TCP */ { msg->conn->err = ERR_VAL; TCPIP_APIMSG_ACK(msg); } } #if LWIP_IGMP /** * Join multicast groups for UDP netconns. * Called from netconn_join_leave_group * * @param msg the api_msg_msg pointing to the connection */ void do_join_leave_group(struct api_msg_msg *msg) { if (!ERR_IS_FATAL(msg->conn->err)) { if (msg->conn->pcb.tcp != NULL) { if (NETCONNTYPE_GROUP(msg->conn->type) == NETCONN_UDP) { #if LWIP_UDP if (msg->msg.jl.join_or_leave == NETCONN_JOIN) { msg->conn->err = igmp_joingroup(msg->msg.jl.interface, msg->msg.jl.multiaddr); } else { msg->conn->err = igmp_leavegroup(msg->msg.jl.interface, msg->msg.jl.multiaddr); } #endif /* LWIP_UDP */ #if (LWIP_TCP || LWIP_RAW) } else { msg->conn->err = ERR_VAL; #endif /* (LWIP_TCP || LWIP_RAW) */ } } } TCPIP_APIMSG_ACK(msg); } #endif /* LWIP_IGMP */ #if LWIP_DNS /** * Callback function that is called when DNS name is resolved * (or on timeout). A waiting application thread is waked up by * signaling the semaphore. */ static void do_dns_found(const char *name, struct ip_addr *ipaddr, void *arg) { struct dns_api_msg *msg = (struct dns_api_msg*)arg; LWIP_ASSERT("DNS response for wrong host name", strcmp(msg->name, name) == 0); if (ipaddr == NULL) { /* timeout or memory error */ *msg->err = ERR_VAL; } else { /* address was resolved */ *msg->err = ERR_OK; *msg->addr = *ipaddr; } /* wake up the application task waiting in netconn_gethostbyname */ sys_sem_signal(msg->sem); } /** * Execute a DNS query * Called from netconn_gethostbyname * * @param arg the dns_api_msg pointing to the query */ void do_gethostbyname(void *arg) { struct dns_api_msg *msg = (struct dns_api_msg*)arg; *msg->err = dns_gethostbyname(msg->name, msg->addr, do_dns_found, msg); if (*msg->err != ERR_INPROGRESS) { /* on error or immediate success, wake up the application * task waiting in netconn_gethostbyname */ sys_sem_signal(msg->sem); } } #endif /* LWIP_DNS */ #endif /* LWIP_NETCONN */