/** * @file * @defgroup altcp Application layered TCP Functions * @ingroup altcp_api * * This file contains the common functions for altcp to work. * For more details see @ref altcp_api. */ /** * @defgroup altcp_api Application layered TCP Introduction * @ingroup callbackstyle_api * * Overview * -------- * altcp (application layered TCP connection API; to be used from TCPIP thread) * is an abstraction layer that prevents applications linking hard against the * @ref tcp.h functions while providing the same functionality. It is used to * e.g. add SSL/TLS (see LWIP_ALTCP_TLS) or proxy-connect support to an application * written for the tcp callback API without that application knowing the * protocol details. * * * This interface mimics the tcp callback API to the application while preventing * direct linking (much like virtual functions). * * This way, an application can make use of other application layer protocols * on top of TCP without knowing the details (e.g. TLS, proxy connection). * * This is achieved by simply including "lwip/altcp.h" instead of "lwip/tcp.h", * replacing "struct tcp_pcb" with "struct altcp_pcb" and prefixing all functions * with "altcp_" instead of "tcp_". * * With altcp support disabled (LWIP_ALTCP==0), applications written against the * altcp API can still be compiled but are directly linked against the tcp.h * callback API and then cannot use layered protocols. To minimize code changes * in this case, the use of altcp_allocators is strongly suggested. * * Usage * ----- * To make use of this API from an existing tcp raw API application: * * Include "lwip/altcp.h" instead of "lwip/tcp.h" * * Replace "struct tcp_pcb" with "struct altcp_pcb" * * Prefix all called tcp API functions with "altcp_" instead of "tcp_" to link * against the altcp functions * * @ref altcp_new (and @ref altcp_new_ip_type/@ref altcp_new_ip6) take * an @ref altcp_allocator_t as an argument, whereas the original tcp API * functions take no arguments. * * An @ref altcp_allocator_t allocator is an object that holds a pointer to an * allocator object and a corresponding state (e.g. for TLS, the corresponding * state may hold certificates or keys). This way, the application does not * even need to know if it uses TLS or pure TCP, this is handled at runtime * by passing a specific allocator. * * An application can alternatively bind hard to the altcp_tls API by calling * @ref altcp_tls_new or @ref altcp_tls_wrap. * * The TLS layer is not directly implemented by lwIP, but a port to mbedTLS is * provided. * * Another altcp layer is proxy-connect to use TLS behind a HTTP proxy (see * @ref altcp_proxyconnect.h) * * altcp_allocator_t * ----------------- * An altcp allocator is created by the application by combining an allocator * callback function and a corresponding state, e.g.:\code{.c} * static const unsigned char cert[] = {0x2D, ... (see mbedTLS doc for how to create this)}; * struct altcp_tls_config * conf = altcp_tls_create_config_client(cert, sizeof(cert)); * altcp_allocator_t tls_allocator = { * altcp_tls_alloc, conf * }; * \endcode * * * struct altcp_tls_config * ----------------------- * The struct altcp_tls_config holds state that is needed to create new TLS client * or server connections (e.g. certificates and private keys). * * It is not defined by lwIP itself but by the TLS port (e.g. altcp_tls to mbedTLS * adaption). However, the parameters used to create it are defined in @ref * altcp_tls.h (see @ref altcp_tls_create_config_server_privkey_cert for servers * and @ref altcp_tls_create_config_client/@ref altcp_tls_create_config_client_2wayauth * for clients). * * For mbedTLS, ensure that certificates can be parsed by 'mbedtls_x509_crt_parse()' and * private keys can be parsed by 'mbedtls_pk_parse_key()'. */ /* * Copyright (c) 2017 Simon Goldschmidt * 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: Simon Goldschmidt * */ #include "lwip/opt.h" #if LWIP_ALTCP /* don't build if not configured for use in lwipopts.h */ #include "lwip/altcp.h" #include "lwip/priv/altcp_priv.h" #include "lwip/altcp_tcp.h" #include "lwip/tcp.h" #include "lwip/mem.h" #include extern const struct altcp_functions altcp_tcp_functions; /** * For altcp layer implementations only: allocate a new struct altcp_pcb from the pool * and zero the memory */ struct altcp_pcb * altcp_alloc(void) { struct altcp_pcb *ret = (struct altcp_pcb *)memp_malloc(MEMP_ALTCP_PCB); if (ret != NULL) { memset(ret, 0, sizeof(struct altcp_pcb)); } return ret; } /** * For altcp layer implementations only: return a struct altcp_pcb to the pool */ void altcp_free(struct altcp_pcb *conn) { if (conn) { if (conn->fns && conn->fns->dealloc) { conn->fns->dealloc(conn); } memp_free(MEMP_ALTCP_PCB, conn); } } /** * @ingroup altcp * altcp_new_ip6: @ref altcp_new for IPv6 */ struct altcp_pcb * altcp_new_ip6(altcp_allocator_t *allocator) { return altcp_new_ip_type(allocator, IPADDR_TYPE_V6); } /** * @ingroup altcp * altcp_new: @ref altcp_new for IPv4 */ struct altcp_pcb * altcp_new(altcp_allocator_t *allocator) { return altcp_new_ip_type(allocator, IPADDR_TYPE_V4); } /** * @ingroup altcp * altcp_new_ip_type: called by applications to allocate a new pcb with the help of an * allocator function. * * @param allocator allocator function and argument * @param ip_type IP version of the pcb (@ref lwip_ip_addr_type) * @return a new altcp_pcb or NULL on error */ struct altcp_pcb * altcp_new_ip_type(altcp_allocator_t *allocator, u8_t ip_type) { struct altcp_pcb *conn; if (allocator == NULL) { /* no allocator given, create a simple TCP connection */ return altcp_tcp_new_ip_type(ip_type); } if (allocator->alloc == NULL) { /* illegal allocator */ return NULL; } conn = allocator->alloc(allocator->arg, ip_type); if (conn == NULL) { /* allocation failed */ return NULL; } return conn; } /** * @ingroup altcp * @see tcp_arg() */ void altcp_arg(struct altcp_pcb *conn, void *arg) { if (conn) { conn->arg = arg; } } /** * @ingroup altcp * @see tcp_accept() */ void altcp_accept(struct altcp_pcb *conn, altcp_accept_fn accept) { if (conn != NULL) { conn->accept = accept; } } /** * @ingroup altcp * @see tcp_recv() */ void altcp_recv(struct altcp_pcb *conn, altcp_recv_fn recv) { if (conn) { conn->recv = recv; } } /** * @ingroup altcp * @see tcp_sent() */ void altcp_sent(struct altcp_pcb *conn, altcp_sent_fn sent) { if (conn) { conn->sent = sent; } } /** * @ingroup altcp * @see tcp_poll() */ void altcp_poll(struct altcp_pcb *conn, altcp_poll_fn poll, u8_t interval) { if (conn) { conn->poll = poll; conn->pollinterval = interval; if (conn->fns && conn->fns->set_poll) { conn->fns->set_poll(conn, interval); } } } /** * @ingroup altcp * @see tcp_err() */ void altcp_err(struct altcp_pcb *conn, altcp_err_fn err) { if (conn) { conn->err = err; } } /* Generic functions calling the "virtual" ones */ /** * @ingroup altcp * @see tcp_recved() */ void altcp_recved(struct altcp_pcb *conn, u16_t len) { if (conn && conn->fns && conn->fns->recved) { conn->fns->recved(conn, len); } } /** * @ingroup altcp * @see tcp_bind() */ err_t altcp_bind(struct altcp_pcb *conn, const ip_addr_t *ipaddr, u16_t port) { if (conn && conn->fns && conn->fns->bind) { return conn->fns->bind(conn, ipaddr, port); } return ERR_VAL; } /** * @ingroup altcp * @see tcp_connect() */ err_t altcp_connect(struct altcp_pcb *conn, const ip_addr_t *ipaddr, u16_t port, altcp_connected_fn connected) { if (conn && conn->fns && conn->fns->connect) { return conn->fns->connect(conn, ipaddr, port, connected); } return ERR_VAL; } /** * @ingroup altcp * @see tcp_listen_with_backlog_and_err() */ struct altcp_pcb * altcp_listen_with_backlog_and_err(struct altcp_pcb *conn, u8_t backlog, err_t *err) { if (conn && conn->fns && conn->fns->listen) { return conn->fns->listen(conn, backlog, err); } return NULL; } /** * @ingroup altcp * @see tcp_abort() */ void altcp_abort(struct altcp_pcb *conn) { if (conn && conn->fns && conn->fns->abort) { conn->fns->abort(conn); } } /** * @ingroup altcp * @see tcp_close() */ err_t altcp_close(struct altcp_pcb *conn) { if (conn && conn->fns && conn->fns->close) { return conn->fns->close(conn); } return ERR_VAL; } /** * @ingroup altcp * @see tcp_shutdown() */ err_t altcp_shutdown(struct altcp_pcb *conn, int shut_rx, int shut_tx) { if (conn && conn->fns && conn->fns->shutdown) { return conn->fns->shutdown(conn, shut_rx, shut_tx); } return ERR_VAL; } /** * @ingroup altcp * @see tcp_write() */ err_t altcp_write(struct altcp_pcb *conn, const void *dataptr, u16_t len, u8_t apiflags) { if (conn && conn->fns && conn->fns->write) { return conn->fns->write(conn, dataptr, len, apiflags); } return ERR_VAL; } /** * @ingroup altcp * @see tcp_output() */ err_t altcp_output(struct altcp_pcb *conn) { if (conn && conn->fns && conn->fns->output) { return conn->fns->output(conn); } return ERR_VAL; } /** * @ingroup altcp * @see tcp_mss() */ u16_t altcp_mss(struct altcp_pcb *conn) { if (conn && conn->fns && conn->fns->mss) { return conn->fns->mss(conn); } return 0; } /** * @ingroup altcp * @see tcp_sndbuf() */ u16_t altcp_sndbuf(struct altcp_pcb *conn) { if (conn && conn->fns && conn->fns->sndbuf) { return conn->fns->sndbuf(conn); } return 0; } /** * @ingroup altcp * @see tcp_sndqueuelen() */ u16_t altcp_sndqueuelen(struct altcp_pcb *conn) { if (conn && conn->fns && conn->fns->sndqueuelen) { return conn->fns->sndqueuelen(conn); } return 0; } void altcp_nagle_disable(struct altcp_pcb *conn) { if (conn && conn->fns && conn->fns->nagle_disable) { conn->fns->nagle_disable(conn); } } void altcp_nagle_enable(struct altcp_pcb *conn) { if (conn && conn->fns && conn->fns->nagle_enable) { conn->fns->nagle_enable(conn); } } int altcp_nagle_disabled(struct altcp_pcb *conn) { if (conn && conn->fns && conn->fns->nagle_disabled) { return conn->fns->nagle_disabled(conn); } return 0; } /** * @ingroup altcp * @see tcp_setprio() */ void altcp_setprio(struct altcp_pcb *conn, u8_t prio) { if (conn && conn->fns && conn->fns->setprio) { conn->fns->setprio(conn, prio); } } err_t altcp_get_tcp_addrinfo(struct altcp_pcb *conn, int local, ip_addr_t *addr, u16_t *port) { if (conn && conn->fns && conn->fns->addrinfo) { return conn->fns->addrinfo(conn, local, addr, port); } return ERR_VAL; } ip_addr_t * altcp_get_ip(struct altcp_pcb *conn, int local) { if (conn && conn->fns && conn->fns->getip) { return conn->fns->getip(conn, local); } return NULL; } u16_t altcp_get_port(struct altcp_pcb *conn, int local) { if (conn && conn->fns && conn->fns->getport) { return conn->fns->getport(conn, local); } return 0; } #if LWIP_TCP_KEEPALIVE void altcp_keepalive_disable(struct altcp_pcb *conn) { if (conn && conn->fns && conn->fns->keepalive_disable) { conn->fns->keepalive_disable(conn); } } void altcp_keepalive_enable(struct altcp_pcb *conn, u32_t idle, u32_t intvl, u32_t count) { if (conn && conn->fns && conn->fns->keepalive_enable) { conn->fns->keepalive_enable(conn, idle, intvl, count); } } #endif #ifdef LWIP_DEBUG enum tcp_state altcp_dbg_get_tcp_state(struct altcp_pcb *conn) { if (conn && conn->fns && conn->fns->dbg_get_tcp_state) { return conn->fns->dbg_get_tcp_state(conn); } return CLOSED; } #endif /* Default implementations for the "virtual" functions */ void altcp_default_set_poll(struct altcp_pcb *conn, u8_t interval) { if (conn && conn->inner_conn) { altcp_poll(conn->inner_conn, conn->poll, interval); } } void altcp_default_recved(struct altcp_pcb *conn, u16_t len) { if (conn && conn->inner_conn) { altcp_recved(conn->inner_conn, len); } } err_t altcp_default_bind(struct altcp_pcb *conn, const ip_addr_t *ipaddr, u16_t port) { if (conn && conn->inner_conn) { return altcp_bind(conn->inner_conn, ipaddr, port); } return ERR_VAL; } err_t altcp_default_shutdown(struct altcp_pcb *conn, int shut_rx, int shut_tx) { if (conn) { if (shut_rx && shut_tx && conn->fns && conn->fns->close) { /* default shutdown for both sides is close */ return conn->fns->close(conn); } if (conn->inner_conn) { return altcp_shutdown(conn->inner_conn, shut_rx, shut_tx); } } return ERR_VAL; } err_t altcp_default_write(struct altcp_pcb *conn, const void *dataptr, u16_t len, u8_t apiflags) { if (conn && conn->inner_conn) { return altcp_write(conn->inner_conn, dataptr, len, apiflags); } return ERR_VAL; } err_t altcp_default_output(struct altcp_pcb *conn) { if (conn && conn->inner_conn) { return altcp_output(conn->inner_conn); } return ERR_VAL; } u16_t altcp_default_mss(struct altcp_pcb *conn) { if (conn && conn->inner_conn) { return altcp_mss(conn->inner_conn); } return 0; } u16_t altcp_default_sndbuf(struct altcp_pcb *conn) { if (conn && conn->inner_conn) { return altcp_sndbuf(conn->inner_conn); } return 0; } u16_t altcp_default_sndqueuelen(struct altcp_pcb *conn) { if (conn && conn->inner_conn) { return altcp_sndqueuelen(conn->inner_conn); } return 0; } void altcp_default_nagle_disable(struct altcp_pcb *conn) { if (conn && conn->inner_conn) { altcp_nagle_disable(conn->inner_conn); } } void altcp_default_nagle_enable(struct altcp_pcb *conn) { if (conn && conn->inner_conn) { altcp_nagle_enable(conn->inner_conn); } } int altcp_default_nagle_disabled(struct altcp_pcb *conn) { if (conn && conn->inner_conn) { return altcp_nagle_disabled(conn->inner_conn); } return 0; } void altcp_default_setprio(struct altcp_pcb *conn, u8_t prio) { if (conn && conn->inner_conn) { altcp_setprio(conn->inner_conn, prio); } } void altcp_default_dealloc(struct altcp_pcb *conn) { LWIP_UNUSED_ARG(conn); /* nothing to do */ } err_t altcp_default_get_tcp_addrinfo(struct altcp_pcb *conn, int local, ip_addr_t *addr, u16_t *port) { if (conn && conn->inner_conn) { return altcp_get_tcp_addrinfo(conn->inner_conn, local, addr, port); } return ERR_VAL; } ip_addr_t * altcp_default_get_ip(struct altcp_pcb *conn, int local) { if (conn && conn->inner_conn) { return altcp_get_ip(conn->inner_conn, local); } return NULL; } u16_t altcp_default_get_port(struct altcp_pcb *conn, int local) { if (conn && conn->inner_conn) { return altcp_get_port(conn->inner_conn, local); } return 0; } #if LWIP_TCP_KEEPALIVE void altcp_default_keepalive_disable(struct altcp_pcb *conn) { if (conn && conn->inner_conn) { altcp_keepalive_disable(conn->inner_conn); } } void altcp_default_keepalive_enable(struct altcp_pcb *conn, u32_t idle, u32_t intvl, u32_t count) { if (conn && conn->inner_conn) { altcp_keepalive_enable(conn->inner_conn, idle, intvl, count); } } #endif #ifdef LWIP_DEBUG enum tcp_state altcp_default_dbg_get_tcp_state(struct altcp_pcb *conn) { if (conn && conn->inner_conn) { return altcp_dbg_get_tcp_state(conn->inner_conn); } return CLOSED; } #endif #endif /* LWIP_ALTCP */