OVMS3-idf/components/lwip/api/api_lib.c
Liu Zhi Fu 2242bf9b37 lwip/esp32/examples: wifi throughput optimizations
1. Put some lwip udp rx/tx relating functions to IRAM
2. Put some wifi rx/tx relating functions to IRAMa
3. Reduce wifi dynamic malloc from 4 to 1 for each ebuf
4. Update iperf example accordingly
5. Update libphy.a to v383
2018-01-30 16:27:49 +08:00

984 lines
31 KiB
C
Executable file

/**
* @file
* Sequential API External 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 <adam@sics.se>
*
*/
/* This is the part of the API that is linked with
the application */
#include "lwip/opt.h"
#if LWIP_NETCONN /* don't build if not configured for use in lwipopts.h */
#include "lwip/api.h"
#include "lwip/memp.h"
#include "lwip/ip.h"
#include "lwip/raw.h"
#include "lwip/udp.h"
#include "lwip/priv/api_msg.h"
#include "lwip/priv/tcp_priv.h"
#include "lwip/priv/tcpip_priv.h"
#include <string.h>
#define API_MSG_VAR_REF(name) API_VAR_REF(name)
#define API_MSG_VAR_DECLARE(name) API_VAR_DECLARE(struct api_msg, name)
#define API_MSG_VAR_ALLOC(name) API_VAR_ALLOC(struct api_msg, MEMP_API_MSG, name)
#define API_MSG_VAR_ALLOC_DONTFAIL(name) API_VAR_ALLOC_DONTFAIL(struct api_msg, MEMP_API_MSG, name)
#define API_MSG_VAR_FREE(name) API_VAR_FREE(MEMP_API_MSG, name)
static err_t netconn_close_shutdown(struct netconn *conn, u8_t how);
#if !LWIP_TCPIP_CORE_LOCKING
/**
* Call the lower part of a netconn_* function
* This function is then running in the thread context
* of tcpip_thread and has exclusive access to lwIP core code.
*
* @param apimsg a struct containing the function to call and its parameters
* @return ERR_OK if the function was called, another err_t if not
*/
static err_t ESP_IRAM_ATTR
tcpip_apimsg(struct api_msg *apimsg)
{
#if LWIP_DEBUG
/* catch functions that don't set err */
apimsg->msg.err = ERR_VAL;
#endif
#if LWIP_NETCONN_SEM_PER_THREAD
apimsg->msg.op_completed_sem = LWIP_NETCONN_THREAD_SEM_GET();
LWIP_ASSERT("netconn semaphore not initialized",
sys_sem_valid(apimsg->msg.op_completed_sem));
#endif
if (tcpip_send_api_msg(apimsg->function, &apimsg->msg, LWIP_API_MSG_SEM(&apimsg->msg)) == ERR_OK) {
return apimsg->msg.err;
}
return ERR_VAL;
}
#endif /* !LWIP_TCPIP_CORE_LOCKING */
/**
* Create a new netconn (of a specific type) that has a callback function.
* The corresponding pcb is also 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_new_with_proto_and_callback(enum netconn_type t, u8_t proto, netconn_callback callback)
{
struct netconn *conn;
API_MSG_VAR_DECLARE(msg);
conn = netconn_alloc(t, callback);
if (conn != NULL) {
err_t err;
API_MSG_VAR_ALLOC_DONTFAIL(msg);
API_MSG_VAR_REF(msg).msg.msg.n.proto = proto;
API_MSG_VAR_REF(msg).msg.conn = conn;
TCPIP_APIMSG(&API_MSG_VAR_REF(msg), lwip_netconn_do_newconn, err);
API_MSG_VAR_FREE(msg);
if (err != ERR_OK) {
LWIP_ASSERT("freeing conn without freeing pcb", conn->pcb.tcp == NULL);
LWIP_ASSERT("conn has no recvmbox", sys_mbox_valid(&conn->recvmbox));
#if LWIP_TCP
LWIP_ASSERT("conn->acceptmbox shouldn't exist", !sys_mbox_valid(&conn->acceptmbox));
#endif /* LWIP_TCP */
#if !LWIP_NETCONN_SEM_PER_THREAD
LWIP_ASSERT("conn has no op_completed", sys_sem_valid(&conn->op_completed));
sys_sem_free(&conn->op_completed);
#endif /* !LWIP_NETCONN_SEM_PER_THREAD */
sys_mbox_free(&conn->recvmbox);
memp_free(MEMP_NETCONN, conn);
return NULL;
}
}
return conn;
}
static inline bool is_created_by_socket(struct netconn *conn)
{
#if LWIP_SOCKET
if (conn && (conn->socket != -1)) {
return true;
}
#endif
return false;
}
/**
* Close a netconn 'connection' and free its resources.
* UDP and RAW connection are completely closed, TCP pcbs might still be in a waitstate
* after this returns.
*
* @param conn the netconn to delete
* @return ERR_OK if the connection was deleted
*/
err_t
netconn_delete(struct netconn *conn)
{
err_t err;
API_MSG_VAR_DECLARE(msg);
/* No ASSERT here because possible to get a (conn == NULL) if we got an accept error */
if (conn == NULL) {
return ERR_OK;
}
API_MSG_VAR_ALLOC(msg);
API_MSG_VAR_REF(msg).msg.conn = conn;
#if LWIP_SO_SNDTIMEO || LWIP_SO_LINGER
/* get the time we started, which is later compared to
sys_now() + conn->send_timeout */
API_MSG_VAR_REF(msg).msg.msg.sd.time_started = sys_now();
#else /* LWIP_SO_SNDTIMEO || LWIP_SO_LINGER */
#if LWIP_TCP
API_MSG_VAR_REF(msg).msg.msg.sd.polls_left =
((LWIP_TCP_CLOSE_TIMEOUT_MS_DEFAULT + TCP_SLOW_INTERVAL - 1) / TCP_SLOW_INTERVAL) + 1;
#endif /* LWIP_TCP */
#endif /* LWIP_SO_SNDTIMEO || LWIP_SO_LINGER */
TCPIP_APIMSG(&API_MSG_VAR_REF(msg), lwip_netconn_do_delconn, err);
API_MSG_VAR_FREE(msg);
if (err != ERR_OK) {
return err;
}
#if ESP_THREAD_SAFE
if (is_created_by_socket(conn) == false) {
LWIP_DEBUGF(ESP_THREAD_SAFE_DEBUG, ("netconn_delete - free conn\n"));
netconn_free(conn);
}
#else
LWIP_DEBUGF(ESP_THREAD_SAFE_DEBUG, ("netconn_delete - free conn\n"));
netconn_free(conn);
#endif
return ERR_OK;
}
/**
* Get the local or remote IP address and port of a netconn.
* For RAW netconns, this returns the protocol instead of a port!
*
* @param conn the netconn to query
* @param addr a pointer to which to save the IP address
* @param port a pointer to which to save the port (or protocol for RAW)
* @param local 1 to get the local IP address, 0 to get the remote one
* @return ERR_CONN for invalid connections
* ERR_OK if the information was retrieved
*/
err_t
netconn_getaddr(struct netconn *conn, ip_addr_t *addr, u16_t *port, u8_t local)
{
API_MSG_VAR_DECLARE(msg);
err_t err;
LWIP_ERROR("netconn_getaddr: invalid conn", (conn != NULL), return ERR_ARG;);
LWIP_ERROR("netconn_getaddr: invalid addr", (addr != NULL), return ERR_ARG;);
LWIP_ERROR("netconn_getaddr: invalid port", (port != NULL), return ERR_ARG;);
API_MSG_VAR_ALLOC(msg);
API_MSG_VAR_REF(msg).msg.conn = conn;
API_MSG_VAR_REF(msg).msg.msg.ad.local = local;
#if LWIP_MPU_COMPATIBLE
TCPIP_APIMSG(msg, lwip_netconn_do_getaddr, err);
*addr = msg->msg.msg.ad.ipaddr;
*port = msg->msg.msg.ad.port;
#else /* LWIP_MPU_COMPATIBLE */
msg.msg.msg.ad.ipaddr = addr;
msg.msg.msg.ad.port = port;
TCPIP_APIMSG(&msg, lwip_netconn_do_getaddr, err);
#endif /* LWIP_MPU_COMPATIBLE */
API_MSG_VAR_FREE(msg);
return err;
}
/**
* Bind a netconn to a specific local IP address and port.
* Binding one netconn twice might not always be checked correctly!
*
* @param conn the netconn to bind
* @param addr the local IP address to bind the netconn to (use IP_ADDR_ANY
* to bind to all addresses)
* @param port the local port to bind the netconn to (not used for RAW)
* @return ERR_OK if bound, any other err_t on failure
*/
err_t
netconn_bind(struct netconn *conn, const ip_addr_t *addr, u16_t port)
{
API_MSG_VAR_DECLARE(msg);
err_t err;
LWIP_ERROR("netconn_bind: invalid conn", (conn != NULL), return ERR_ARG;);
/* Don't propagate NULL pointer (IP_ADDR_ANY alias) to subsequent functions */
if (addr == NULL) {
addr = IP_ADDR_ANY;
}
API_MSG_VAR_ALLOC(msg);
API_MSG_VAR_REF(msg).msg.conn = conn;
API_MSG_VAR_REF(msg).msg.msg.bc.ipaddr = API_MSG_VAR_REF(addr);
API_MSG_VAR_REF(msg).msg.msg.bc.port = port;
TCPIP_APIMSG(&API_MSG_VAR_REF(msg), lwip_netconn_do_bind, err);
API_MSG_VAR_FREE(msg);
return err;
}
/**
* Connect a netconn to a specific remote IP address and port.
*
* @param conn the netconn to connect
* @param addr the remote IP address to connect to
* @param port the remote port to connect to (no used for RAW)
* @return ERR_OK if connected, return value of tcp_/udp_/raw_connect otherwise
*/
err_t
netconn_connect(struct netconn *conn, const ip_addr_t *addr, u16_t port)
{
API_MSG_VAR_DECLARE(msg);
err_t err;
LWIP_ERROR("netconn_connect: invalid conn", (conn != NULL), return ERR_ARG;);
/* Don't propagate NULL pointer (IP_ADDR_ANY alias) to subsequent functions */
if (addr == NULL) {
addr = IP_ADDR_ANY;
}
API_MSG_VAR_ALLOC(msg);
API_MSG_VAR_REF(msg).msg.conn = conn;
API_MSG_VAR_REF(msg).msg.msg.bc.ipaddr = API_MSG_VAR_REF(addr);
API_MSG_VAR_REF(msg).msg.msg.bc.port = port;
TCPIP_APIMSG(&API_MSG_VAR_REF(msg), lwip_netconn_do_connect, err);
API_MSG_VAR_FREE(msg);
return err;
}
/**
* Disconnect a netconn from its current peer (only valid for UDP netconns).
*
* @param conn the netconn to disconnect
* @return TODO: return value is not set here...
*/
err_t
netconn_disconnect(struct netconn *conn)
{
API_MSG_VAR_DECLARE(msg);
err_t err;
LWIP_ERROR("netconn_disconnect: invalid conn", (conn != NULL), return ERR_ARG;);
API_MSG_VAR_ALLOC(msg);
API_MSG_VAR_REF(msg).msg.conn = conn;
TCPIP_APIMSG(&API_MSG_VAR_REF(msg), lwip_netconn_do_disconnect, err);
API_MSG_VAR_FREE(msg);
return err;
}
/**
* Set a TCP netconn into listen mode
*
* @param conn the tcp netconn to set to listen mode
* @param backlog the listen backlog, only used if TCP_LISTEN_BACKLOG==1
* @return ERR_OK if the netconn was set to listen (UDP and RAW netconns
* don't return any error (yet?))
*/
err_t
netconn_listen_with_backlog(struct netconn *conn, u8_t backlog)
{
#if LWIP_TCP
API_MSG_VAR_DECLARE(msg);
err_t err;
/* This does no harm. If TCP_LISTEN_BACKLOG is off, backlog is unused. */
LWIP_UNUSED_ARG(backlog);
LWIP_ERROR("netconn_listen: invalid conn", (conn != NULL), return ERR_ARG;);
API_MSG_VAR_ALLOC(msg);
API_MSG_VAR_REF(msg).msg.conn = conn;
#if TCP_LISTEN_BACKLOG
API_MSG_VAR_REF(msg).msg.msg.lb.backlog = backlog;
#endif /* TCP_LISTEN_BACKLOG */
TCPIP_APIMSG(&API_MSG_VAR_REF(msg), lwip_netconn_do_listen, err);
API_MSG_VAR_FREE(msg);
return err;
#else /* LWIP_TCP */
LWIP_UNUSED_ARG(conn);
LWIP_UNUSED_ARG(backlog);
return ERR_ARG;
#endif /* LWIP_TCP */
}
/**
* Accept a new connection on a TCP listening netconn.
*
* @param conn the TCP listen netconn
* @param new_conn pointer where the new connection is stored
* @return ERR_OK if a new connection has been received or an error
* code otherwise
*/
err_t
netconn_accept(struct netconn *conn, struct netconn **new_conn)
{
#if LWIP_TCP
struct netconn *newconn;
err_t err;
#if TCP_LISTEN_BACKLOG
API_MSG_VAR_DECLARE(msg);
#endif /* TCP_LISTEN_BACKLOG */
LWIP_ERROR("netconn_accept: invalid pointer", (new_conn != NULL), return ERR_ARG;);
*new_conn = NULL;
LWIP_ERROR("netconn_accept: invalid conn", (conn != NULL), return ERR_ARG;);
LWIP_ERROR("netconn_accept: invalid acceptmbox", sys_mbox_valid(&conn->acceptmbox), return ERR_ARG;);
err = conn->last_err;
if (ERR_IS_FATAL(err)) {
/* don't recv on fatal errors: this might block the application task
waiting on acceptmbox forever! */
return err;
}
#if LWIP_SO_RCVTIMEO
if (sys_arch_mbox_fetch(&conn->acceptmbox, (void **)&newconn, conn->recv_timeout) == SYS_ARCH_TIMEOUT) {
return ERR_TIMEOUT;
}
#else
sys_arch_mbox_fetch(&conn->acceptmbox, (void **)&newconn, 0);
#endif /* LWIP_SO_RCVTIMEO*/
/* Register event with callback */
API_EVENT(conn, NETCONN_EVT_RCVMINUS, 0);
if (newconn == NULL) {
/* connection has been aborted */
/* in this special case, we set the netconn error from application thread, as
on a ready-to-accept listening netconn, there should not be anything running
in tcpip_thread */
NETCONN_SET_SAFE_ERR(conn, ERR_ABRT);
return ERR_ABRT;
}
#if TCP_LISTEN_BACKLOG
/* Let the stack know that we have accepted the connection. */
API_MSG_VAR_ALLOC_DONTFAIL(msg);
API_MSG_VAR_REF(msg).msg.conn = conn;
/* don't care for the return value of lwip_netconn_do_recv */
TCPIP_APIMSG_NOERR(&API_MSG_VAR_REF(msg), lwip_netconn_do_recv);
API_MSG_VAR_FREE(msg);
#endif /* TCP_LISTEN_BACKLOG */
*new_conn = newconn;
/* don't set conn->last_err: it's only ERR_OK, anyway */
return ERR_OK;
#else /* LWIP_TCP */
LWIP_UNUSED_ARG(conn);
LWIP_UNUSED_ARG(new_conn);
return ERR_ARG;
#endif /* LWIP_TCP */
}
/**
* Receive data: actual implementation that doesn't care whether pbuf or netbuf
* is received
*
* @param conn the netconn from which to receive data
* @param new_buf pointer where a new pbuf/netbuf is stored when received data
* @return ERR_OK if data has been received, an error code otherwise (timeout,
* memory error or another error)
*/
static err_t ESP_IRAM_ATTR
netconn_recv_data(struct netconn *conn, void **new_buf)
{
void *buf = NULL;
u16_t len;
err_t err;
#if LWIP_TCP
API_MSG_VAR_DECLARE(msg);
#endif /* LWIP_TCP */
LWIP_ERROR("netconn_recv: invalid pointer", (new_buf != NULL), return ERR_ARG;);
*new_buf = NULL;
LWIP_ERROR("netconn_recv: invalid conn", (conn != NULL), return ERR_ARG;);
#if LWIP_TCP
#if (LWIP_UDP || LWIP_RAW)
if (NETCONNTYPE_GROUP(conn->type) == NETCONN_TCP)
#endif /* (LWIP_UDP || LWIP_RAW) */
{
if (!sys_mbox_valid(&conn->recvmbox)) {
/* This happens when calling this function after receiving FIN */
return sys_mbox_valid(&conn->acceptmbox) ? ERR_CONN : ERR_CLSD;
}
}
#endif /* LWIP_TCP */
LWIP_ERROR("netconn_recv: invalid recvmbox", sys_mbox_valid(&conn->recvmbox), return ERR_CONN;);
err = conn->last_err;
if (ERR_IS_FATAL(err)) {
/* don't recv on fatal errors: this might block the application task
waiting on recvmbox forever! */
/* @todo: this does not allow us to fetch data that has been put into recvmbox
before the fatal error occurred - is that a problem? */
return err;
}
#if LWIP_SO_RCVTIMEO
if (sys_arch_mbox_fetch(&conn->recvmbox, &buf, conn->recv_timeout) == SYS_ARCH_TIMEOUT) {
return ERR_TIMEOUT;
}
#else
sys_arch_mbox_fetch(&conn->recvmbox, &buf, 0);
#endif /* LWIP_SO_RCVTIMEO*/
#if LWIP_TCP
#if (LWIP_UDP || LWIP_RAW)
if (NETCONNTYPE_GROUP(conn->type) == NETCONN_TCP)
#endif /* (LWIP_UDP || LWIP_RAW) */
{
if (!netconn_get_noautorecved(conn) || (buf == NULL)) {
/* Let the stack know that we have taken the data. */
/* TODO: Speedup: Don't block and wait for the answer here
(to prevent multiple thread-switches). */
API_MSG_VAR_ALLOC_DONTFAIL(msg);
API_MSG_VAR_REF(msg).msg.conn = conn;
if (buf != NULL) {
API_MSG_VAR_REF(msg).msg.msg.r.len = ((struct pbuf *)buf)->tot_len;
} else {
API_MSG_VAR_REF(msg).msg.msg.r.len = 1;
}
/* don't care for the return value of lwip_netconn_do_recv */
TCPIP_APIMSG_NOERR(&API_MSG_VAR_REF(msg), lwip_netconn_do_recv);
API_MSG_VAR_FREE(msg);
}
/* If we are closed, we indicate that we no longer wish to use the socket */
if (buf == NULL) {
API_EVENT(conn, NETCONN_EVT_RCVMINUS, 0);
/* Don' store ERR_CLSD as conn->err since we are only half-closed */
return ERR_CLSD;
}
len = ((struct pbuf *)buf)->tot_len;
}
#endif /* LWIP_TCP */
#if LWIP_TCP && (LWIP_UDP || LWIP_RAW)
else
#endif /* LWIP_TCP && (LWIP_UDP || LWIP_RAW) */
#if (LWIP_UDP || LWIP_RAW)
{
#if ESP_THREAD_SAFE
if (buf == NULL){
API_EVENT(conn, NETCONN_EVT_RCVMINUS, 0);
return ERR_CLSD;
}
#endif
LWIP_ASSERT("buf != NULL", buf != NULL);
len = netbuf_len((struct netbuf *)buf);
}
#endif /* (LWIP_UDP || LWIP_RAW) */
#if ESP_PERF
if (len > DBG_PERF_FILTER_LEN) {
DBG_PERF_PATH_SET(DBG_PERF_DIR_RX, DBG_PERF_POINT_SOC_IN);
}
#endif
#if LWIP_SO_RCVBUF
SYS_ARCH_DEC(conn->recv_avail, len);
#endif /* LWIP_SO_RCVBUF */
/* Register event with callback */
API_EVENT(conn, NETCONN_EVT_RCVMINUS, len);
LWIP_DEBUGF(API_LIB_DEBUG, ("netconn_recv_data: received %p, len=%"U16_F"\n", buf, len));
*new_buf = buf;
/* don't set conn->last_err: it's only ERR_OK, anyway */
return ERR_OK;
}
/**
* Receive data (in form of a pbuf) from a TCP netconn
*
* @param conn the netconn from which to receive data
* @param new_buf pointer where a new pbuf is stored when received data
* @return ERR_OK if data has been received, an error code otherwise (timeout,
* memory error or another error)
* ERR_ARG if conn is not a TCP netconn
*/
err_t
netconn_recv_tcp_pbuf(struct netconn *conn, struct pbuf **new_buf)
{
LWIP_ERROR("netconn_recv: invalid conn", (conn != NULL) &&
NETCONNTYPE_GROUP(netconn_type(conn)) == NETCONN_TCP, return ERR_ARG;);
return netconn_recv_data(conn, (void **)new_buf);
}
/**
* Receive data (in form of a netbuf containing a packet buffer) from a netconn
*
* @param conn the netconn from which to receive data
* @param new_buf pointer where a new netbuf is stored when received data
* @return ERR_OK if data has been received, an error code otherwise (timeout,
* memory error or another error)
*/
err_t ESP_IRAM_ATTR
netconn_recv(struct netconn *conn, struct netbuf **new_buf)
{
#if LWIP_TCP
struct netbuf *buf = NULL;
err_t err;
#endif /* LWIP_TCP */
LWIP_ERROR("netconn_recv: invalid pointer", (new_buf != NULL), return ERR_ARG;);
*new_buf = NULL;
LWIP_ERROR("netconn_recv: invalid conn", (conn != NULL), return ERR_ARG;);
#if LWIP_TCP
#if (LWIP_UDP || LWIP_RAW)
if (NETCONNTYPE_GROUP(conn->type) == NETCONN_TCP)
#endif /* (LWIP_UDP || LWIP_RAW) */
{
struct pbuf *p = NULL;
/* This is not a listening netconn, since recvmbox is set */
buf = (struct netbuf *)memp_malloc(MEMP_NETBUF);
if (buf == NULL) {
return ERR_MEM;
}
err = netconn_recv_data(conn, (void **)&p);
if (err != ERR_OK) {
memp_free(MEMP_NETBUF, buf);
return err;
}
LWIP_ASSERT("p != NULL", p != NULL);
buf->p = p;
buf->ptr = p;
buf->port = 0;
ip_addr_set_zero(&buf->addr);
*new_buf = buf;
/* don't set conn->last_err: it's only ERR_OK, anyway */
return ERR_OK;
}
#endif /* LWIP_TCP */
#if LWIP_TCP && (LWIP_UDP || LWIP_RAW)
else
#endif /* LWIP_TCP && (LWIP_UDP || LWIP_RAW) */
{
#if (LWIP_UDP || LWIP_RAW)
return netconn_recv_data(conn, (void **)new_buf);
#endif /* (LWIP_UDP || LWIP_RAW) */
}
}
/**
* TCP: update the receive window: by calling this, the application
* tells the stack that it has processed data and is able to accept
* new data.
* ATTENTION: use with care, this is mainly used for sockets!
* Can only be used when calling netconn_set_noautorecved(conn, 1) before.
*
* @param conn the netconn for which to update the receive window
* @param length amount of data processed (ATTENTION: this must be accurate!)
*/
void
netconn_recved(struct netconn *conn, u32_t length)
{
#if LWIP_TCP
if ((conn != NULL) && (NETCONNTYPE_GROUP(conn->type) == NETCONN_TCP) &&
(netconn_get_noautorecved(conn))) {
API_MSG_VAR_DECLARE(msg);
/* Let the stack know that we have taken the data. */
/* TODO: Speedup: Don't block and wait for the answer here
(to prevent multiple thread-switches). */
API_MSG_VAR_ALLOC_DONTFAIL(msg);
API_MSG_VAR_REF(msg).msg.conn = conn;
API_MSG_VAR_REF(msg).msg.msg.r.len = length;
/* don't care for the return value of lwip_netconn_do_recv */
TCPIP_APIMSG_NOERR(&API_MSG_VAR_REF(msg), lwip_netconn_do_recv);
API_MSG_VAR_FREE(msg);
}
#else /* LWIP_TCP */
LWIP_UNUSED_ARG(conn);
LWIP_UNUSED_ARG(length);
#endif /* LWIP_TCP */
}
/**
* Send data (in form of a netbuf) to a specific remote IP address and port.
* Only to be used for UDP and RAW netconns (not TCP).
*
* @param conn the netconn over which to send data
* @param buf a netbuf containing the data to send
* @param addr the remote IP address to which to send the data
* @param port the remote port to which to send the data
* @return ERR_OK if data was sent, any other err_t on error
*/
err_t
netconn_sendto(struct netconn *conn, struct netbuf *buf, const ip_addr_t *addr, u16_t port)
{
if (buf != NULL) {
ip_addr_set(&buf->addr, addr);
buf->port = port;
return netconn_send(conn, buf);
}
return ERR_VAL;
}
/**
* Send data over a UDP or RAW netconn (that is already connected).
*
* @param conn the UDP or RAW netconn over which to send data
* @param buf a netbuf containing the data to send
* @return ERR_OK if data was sent, any other err_t on error
*/
err_t ESP_IRAM_ATTR
netconn_send(struct netconn *conn, struct netbuf *buf)
{
API_MSG_VAR_DECLARE(msg);
err_t err;
LWIP_ERROR("netconn_send: invalid conn", (conn != NULL), return ERR_ARG;);
LWIP_DEBUGF(API_LIB_DEBUG, ("netconn_send: sending %"U16_F" bytes\n", buf->p->tot_len));
API_MSG_VAR_ALLOC(msg);
API_MSG_VAR_REF(msg).msg.conn = conn;
API_MSG_VAR_REF(msg).msg.msg.b = buf;
TCPIP_APIMSG(&API_MSG_VAR_REF(msg), lwip_netconn_do_send, err);
API_MSG_VAR_FREE(msg);
return err;
}
/**
* Send data over a TCP netconn.
*
* @param conn the TCP netconn over which to send data
* @param dataptr pointer to the application buffer that contains the data to send
* @param size size of the application data to send
* @param apiflags combination of following flags :
* - NETCONN_COPY: data will be copied into memory belonging to the stack
* - NETCONN_MORE: for TCP connection, PSH flag will be set on last segment sent
* - NETCONN_DONTBLOCK: only write the data if all data can be written at once
* @param bytes_written pointer to a location that receives the number of written bytes
* @return ERR_OK if data was sent, any other err_t on error
*/
err_t
netconn_write_partly(struct netconn *conn, const void *dataptr, size_t size,
u8_t apiflags, size_t *bytes_written)
{
API_MSG_VAR_DECLARE(msg);
err_t err;
u8_t dontblock;
LWIP_ERROR("netconn_write: invalid conn", (conn != NULL), return ERR_ARG;);
LWIP_ERROR("netconn_write: invalid conn->type", (NETCONNTYPE_GROUP(conn->type)== NETCONN_TCP), return ERR_VAL;);
if (size == 0) {
return ERR_OK;
}
dontblock = netconn_is_nonblocking(conn) || (apiflags & NETCONN_DONTBLOCK);
if (dontblock && !bytes_written) {
/* This implies netconn_write() cannot be used for non-blocking send, since
it has no way to return the number of bytes written. */
return ERR_VAL;
}
API_MSG_VAR_ALLOC(msg);
/* non-blocking write sends as much */
API_MSG_VAR_REF(msg).msg.conn = conn;
API_MSG_VAR_REF(msg).msg.msg.w.dataptr = dataptr;
API_MSG_VAR_REF(msg).msg.msg.w.apiflags = apiflags;
API_MSG_VAR_REF(msg).msg.msg.w.len = size;
#if LWIP_SO_SNDTIMEO
if (conn->send_timeout != 0) {
/* get the time we started, which is later compared to
sys_now() + conn->send_timeout */
API_MSG_VAR_REF(msg).msg.msg.w.time_started = sys_now();
} else {
API_MSG_VAR_REF(msg).msg.msg.w.time_started = 0;
}
#endif /* LWIP_SO_SNDTIMEO */
/* For locking the core: this _can_ be delayed on low memory/low send buffer,
but if it is, this is done inside api_msg.c:do_write(), so we can use the
non-blocking version here. */
TCPIP_APIMSG(&API_MSG_VAR_REF(msg), lwip_netconn_do_write, err);
if ((err == ERR_OK) && (bytes_written != NULL)) {
if (dontblock
#if LWIP_SO_SNDTIMEO
|| (conn->send_timeout != 0)
#endif /* LWIP_SO_SNDTIMEO */
) {
/* nonblocking write: maybe the data has been sent partly */
*bytes_written = API_MSG_VAR_REF(msg).msg.msg.w.len;
} else {
/* blocking call succeeded: all data has been sent if it */
*bytes_written = size;
}
}
API_MSG_VAR_FREE(msg);
return err;
}
/**
* Close or shutdown a TCP netconn (doesn't delete it).
*
* @param conn the TCP netconn to close or shutdown
* @param how fully close or only shutdown one side?
* @return ERR_OK if the netconn was closed, any other err_t on error
*/
static err_t
netconn_close_shutdown(struct netconn *conn, u8_t how)
{
API_MSG_VAR_DECLARE(msg);
err_t err;
LWIP_UNUSED_ARG(how);
LWIP_ERROR("netconn_close: invalid conn", (conn != NULL), return ERR_ARG;);
API_MSG_VAR_ALLOC(msg);
API_MSG_VAR_REF(msg).msg.conn = conn;
#if LWIP_TCP
/* shutting down both ends is the same as closing */
API_MSG_VAR_REF(msg).msg.msg.sd.shut = how;
#if LWIP_SO_SNDTIMEO || LWIP_SO_LINGER
/* get the time we started, which is later compared to
sys_now() + conn->send_timeout */
API_MSG_VAR_REF(msg).msg.msg.sd.time_started = sys_now();
#else /* LWIP_SO_SNDTIMEO || LWIP_SO_LINGER */
API_MSG_VAR_REF(msg).msg.msg.sd.polls_left =
((LWIP_TCP_CLOSE_TIMEOUT_MS_DEFAULT + TCP_SLOW_INTERVAL - 1) / TCP_SLOW_INTERVAL) + 1;
#endif /* LWIP_SO_SNDTIMEO || LWIP_SO_LINGER */
#endif /* LWIP_TCP */
TCPIP_APIMSG(&API_MSG_VAR_REF(msg), lwip_netconn_do_close, err);
API_MSG_VAR_FREE(msg);
return err;
}
/**
* Close a TCP netconn (doesn't delete it).
*
* @param conn the TCP netconn to close
* @return ERR_OK if the netconn was closed, any other err_t on error
*/
err_t
netconn_close(struct netconn *conn)
{
/* shutting down both ends is the same as closing */
return netconn_close_shutdown(conn, NETCONN_SHUT_RDWR);
}
/**
* Shut down one or both sides of a TCP netconn (doesn't delete it).
*
* @param conn the TCP netconn to shut down
* @return ERR_OK if the netconn was closed, any other err_t on error
*/
err_t
netconn_shutdown(struct netconn *conn, u8_t shut_rx, u8_t shut_tx)
{
return netconn_close_shutdown(conn, (shut_rx ? NETCONN_SHUT_RD : 0) | (shut_tx ? NETCONN_SHUT_WR : 0));
}
#if LWIP_IGMP || (LWIP_IPV6 && LWIP_IPV6_MLD)
/**
* Join multicast groups for UDP netconns.
*
* @param conn the UDP netconn for which to change multicast addresses
* @param multiaddr IP address of the multicast group to join or leave
* @param netif_addr the IP address of the network interface on which to send
* the igmp message
* @param join_or_leave flag whether to send a join- or leave-message
* @return ERR_OK if the action was taken, any err_t on error
*/
err_t
netconn_join_leave_group(struct netconn *conn,
const ip_addr_t *multiaddr,
const ip_addr_t *netif_addr,
enum netconn_igmp join_or_leave)
{
API_MSG_VAR_DECLARE(msg);
err_t err;
LWIP_ERROR("netconn_join_leave_group: invalid conn", (conn != NULL), return ERR_ARG;);
API_MSG_VAR_ALLOC(msg);
/* Don't propagate NULL pointer (IP_ADDR_ANY alias) to subsequent functions */
if (multiaddr == NULL) {
multiaddr = IP_ADDR_ANY;
}
if (netif_addr == NULL) {
netif_addr = IP_ADDR_ANY;
}
API_MSG_VAR_REF(msg).msg.conn = conn;
API_MSG_VAR_REF(msg).msg.msg.jl.multiaddr = API_MSG_VAR_REF(multiaddr);
API_MSG_VAR_REF(msg).msg.msg.jl.netif_addr = API_MSG_VAR_REF(netif_addr);
API_MSG_VAR_REF(msg).msg.msg.jl.join_or_leave = join_or_leave;
TCPIP_APIMSG(&API_MSG_VAR_REF(msg), lwip_netconn_do_join_leave_group, err);
API_MSG_VAR_FREE(msg);
return err;
}
#endif /* LWIP_IGMP || (LWIP_IPV6 && LWIP_IPV6_MLD) */
#if LWIP_DNS
/**
* Execute a DNS query, only one IP address is returned
*
* @param name a string representation of the DNS host name to query
* @param addr a preallocated ip_addr_t where to store the resolved IP address
* @return ERR_OK: resolving succeeded
* ERR_MEM: memory error, try again later
* ERR_ARG: dns client not initialized or invalid hostname
* ERR_VAL: dns server response was invalid
*/
#if LWIP_IPV4 && LWIP_IPV6
err_t
netconn_gethostbyname_addrtype(const char *name, ip_addr_t *addr, u8_t dns_addrtype)
#else
err_t
netconn_gethostbyname(const char *name, ip_addr_t *addr)
#endif
{
API_VAR_DECLARE(struct dns_api_msg, msg);
err_t localerr;
#if !LWIP_MPU_COMPATIBLE
sys_sem_t sem;
#endif /* LWIP_MPU_COMPATIBLE */
err_t err = ERR_OK;
LWIP_ERROR("netconn_gethostbyname: invalid name", (name != NULL), return ERR_ARG;);
LWIP_ERROR("netconn_gethostbyname: invalid addr", (addr != NULL), return ERR_ARG;);
#if LWIP_MPU_COMPATIBLE
if (strlen(name) >= DNS_MAX_NAME_LENGTH) {
return ERR_ARG;
}
#endif
API_VAR_ALLOC(struct dns_api_msg, MEMP_DNS_API_MSG, msg);
#if LWIP_MPU_COMPATIBLE
strncpy(API_VAR_REF(msg).name, name, DNS_MAX_NAME_LENGTH-1);
API_VAR_REF(msg).name[DNS_MAX_NAME_LENGTH-1] = 0;
#else /* LWIP_MPU_COMPATIBLE */
msg.err = &err;
msg.sem = &sem;
API_VAR_REF(msg).addr = API_VAR_REF(addr);
API_VAR_REF(msg).name = name;
#endif /* LWIP_MPU_COMPATIBLE */
#if LWIP_IPV4 && LWIP_IPV6
API_VAR_REF(msg).dns_addrtype = dns_addrtype;
#endif /* LWIP_IPV4 && LWIP_IPV6 */
#if LWIP_NETCONN_SEM_PER_THREAD
API_VAR_REF(msg).sem = LWIP_NETCONN_THREAD_SEM_GET();
#else /* LWIP_NETCONN_SEM_PER_THREAD*/
err = sys_sem_new(API_EXPR_REF(API_VAR_REF(msg).sem), 0);
if (err != ERR_OK) {
API_VAR_FREE(MEMP_DNS_API_MSG, msg);
return err;
}
#endif /* LWIP_NETCONN_SEM_PER_THREAD */
localerr = tcpip_callback(lwip_netconn_do_gethostbyname, &API_VAR_REF(msg));
if (localerr != ERR_OK) {
#if !LWIP_NETCONN_SEM_PER_THREAD
sys_sem_free(API_EXPR_REF(API_VAR_REF(msg).sem));
#endif /* !LWIP_NETCONN_SEM_PER_THREAD */
API_VAR_FREE(MEMP_DNS_API_MSG, msg);
return localerr;
}
sys_sem_wait(API_EXPR_REF_SEM(API_VAR_REF(msg).sem));
#if !LWIP_NETCONN_SEM_PER_THREAD
sys_sem_free(API_EXPR_REF(API_VAR_REF(msg).sem));
#endif /* !LWIP_NETCONN_SEM_PER_THREAD */
#if LWIP_MPU_COMPATIBLE
*addr = msg->addr;
err = msg->err;
#endif /* LWIP_MPU_COMPATIBLE */
API_VAR_FREE(MEMP_DNS_API_MSG, msg);
return err;
}
#endif /* LWIP_DNS*/
#if LWIP_NETCONN_SEM_PER_THREAD
void
netconn_thread_init(void)
{
sys_sem_t *sem = LWIP_NETCONN_THREAD_SEM_GET();
if ((sem == NULL) || !sys_sem_valid(sem)) {
/* call alloc only once */
LWIP_NETCONN_THREAD_SEM_ALLOC();
LWIP_ASSERT("LWIP_NETCONN_THREAD_SEM_ALLOC() failed", sys_sem_valid(LWIP_NETCONN_THREAD_SEM_GET()));
}
}
void
netconn_thread_cleanup(void)
{
sys_sem_t *sem = LWIP_NETCONN_THREAD_SEM_GET();
if ((sem != NULL) && sys_sem_valid(sem)) {
/* call free only once */
LWIP_NETCONN_THREAD_SEM_FREE();
}
}
#endif /* LWIP_NETCONN_SEM_PER_THREAD */
#endif /* LWIP_NETCONN */