/**************************************************************************** * uip.h * Header file for the uIP TCP/IP stack. * * The uIP TCP/IP stack header file contains definitions for a number * of C macros that are used by uIP programs as well as internal uIP * structures, TCP/IP header structures and function declarations. * * Copyright (C) 2007 Gregory Nutt. All rights reserved. * Author: Gregory Nutt * * This logic was leveraged from uIP which also has a BSD-style license: * * Author Adam Dunkels * Copyright (c) 2001-2003, Adam Dunkels. * 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. * ****************************************************************************/ #ifndef __NET_UIP_UIP_H #define __NET_UIP_UIP_H /**************************************************************************** * Included Files ****************************************************************************/ #include #include #include #include #include /**************************************************************************** * Definitions ****************************************************************************/ /* The following flags may be set in the global variable uip_flags before * calling the application callback. The UIP_ACKDATA, UIP_NEWDATA, and * UIP_CLOSE flags may both be set at the same time, whereas the others are * mutualy exclusive. Note that these flags should *NOT* be accessed directly, * but only through the uIP functions/macros. */ #define UIP_ACKDATA (1 << 0) /* Signifies that the outstanding data was acked and the * application should send out new data instead of retransmitting * the last data. */ #define UIP_NEWDATA (1 << 1) /* Flags the fact that the peer has sent us new data. */ #define UIP_REXMIT (1 << 2) /* Tells the application to retransmit the data that was last * sent. */ #define UIP_POLL (1 << 3) /* Used for polling the application, to check if the application * has data that it wants to send. */ #define UIP_CLOSE (1 << 4) /* The remote host has closed the connection, thus the connection * has gone away. Or the application signals that it wants to * close the connection. */ #define UIP_ABORT (1 << 5) /* The remote host has aborted the connection, thus the connection * has gone away. Or the application signals that it wants to * abort the connection. */ #define UIP_CONNECTED (1 << 6) /* We have got a connection from a remote host and have set up a * new connection for it, or an active connection has been * successfully established. */ #define UIP_TIMEDOUT (1 << 7) /* The connection has been aborted due to too many retransmissions. */ #define UIP_DATA_EVENTS (UIP_ACKDATA|UIP_NEWDATA|UIP_REXMIT|UIP_POLL) #define UIP_CONN_EVENTS (UIP_CLOSE|UIP_ABORT|UIP_CONNECTED|UIP_TIMEDOUT) /* The TCP states used in the uip_conn->tcpstateflags. */ #define UIP_CLOSED 0 /* The connection is not in use and available */ #define UIP_ALLOCATED 1 /* The connection is allocated, but not yet initialized */ #define UIP_SYN_RCVD 2 #define UIP_SYN_SENT 3 #define UIP_ESTABLISHED 4 #define UIP_FIN_WAIT_1 5 #define UIP_FIN_WAIT_2 6 #define UIP_CLOSING 7 #define UIP_TIME_WAIT 8 #define UIP_LAST_ACK 9 #define UIP_TS_MASK 15 #define UIP_STOPPED 16 /* The buffer size available for user data in the d_buf buffer. * * This macro holds the available size for user data in the \ref * d_buf buffer. The macro is intended to be used for checking * bounds of available user data. * * Example: * * snprintf(dev->d_appdata, UIP_APPDATA_SIZE, "%u\n", i); */ #define UIP_APPDATA_SIZE (UIP_BUFSIZE - UIP_LLH_LEN - UIP_TCPIP_HLEN) #define UIP_PROTO_ICMP 1 #define UIP_PROTO_TCP 6 #define UIP_PROTO_UDP 17 #define UIP_PROTO_ICMP6 58 /* Header sizes */ #ifdef CONFIG_NET_IPv6 # define UIP_IPH_LEN 40 #else /* CONFIG_NET_IPv6 */ # define UIP_IPH_LEN 20 /* Size of IP header */ #endif /* CONFIG_NET_IPv6 */ #define UIP_UDPH_LEN 8 /* Size of UDP header */ #define UIP_TCPH_LEN 20 /* Size of TCP header */ #define UIP_IPUDPH_LEN (UIP_UDPH_LEN + UIP_IPH_LEN) /* Size of IP + UDP header */ #define UIP_IPTCPH_LEN (UIP_TCPH_LEN + UIP_IPH_LEN) /* Size of IP + TCP header */ #define UIP_TCPIP_HLEN UIP_IPTCPH_LEN /**************************************************************************** * Public Type Definitions ****************************************************************************/ /* Repressentation of an IP address. */ typedef in_addr_t uip_ip4addr_t; typedef uint16 uip_ip6addr_t[8]; #ifdef CONFIG_NET_IPv6 typedef uip_ip6addr_t uip_ipaddr_t; #else /* CONFIG_NET_IPv6 */ typedef uip_ip4addr_t uip_ipaddr_t; #endif /* CONFIG_NET_IPv6 */ /* Representation of a uIP TCP connection. * * The uip_conn structure is used for identifying a connection. All * but one field in the structure are to be considered read-only by an * application. The only exception is the "private: field whos purpose * is to let the application store application-specific state (e.g., * file pointers) for the connection. */ struct uip_driver_s; /* Forward reference */ struct uip_conn { dq_entry_t node; /* Implements a doubly linked list */ uip_ipaddr_t ripaddr; /* The IP address of the remote host. */ uint16 lport; /* The local TCP port, in network byte order. */ uint16 rport; /* The local remote TCP port, in network byte order. */ uint8 rcv_nxt[4]; /* The sequence number that we expect to * receive next. */ uint8 snd_nxt[4]; /* The sequence number that was last sent by us. */ uint16 len; /* Length of the data that was previously sent. */ uint16 mss; /* Current maximum segment size for the * connection. */ uint16 initialmss; /* Initial maximum segment size for the * connection. */ uint8 sa; /* Retransmission time-out calculation state * variable. */ uint8 sv; /* Retransmission time-out calculation state * variable. */ uint8 rto; /* Retransmission time-out. */ uint8 tcpstateflags; /* TCP state and flags. */ uint8 timer; /* The retransmission timer. */ uint8 nrtx; /* The number of retransmissions for the last * segment sent. */ /* Higher level logic can retain application specific information * in the following: */ void *data_private; void (*data_event)(struct uip_driver_s *dev, void *private); void *accept_private; int (*accept)(void *private, struct uip_conn *conn); void *connection_private; void (*connection_event)(void *private); }; #ifdef CONFIG_NET_UDP /* Representation of a uIP UDP connection. */ struct uip_udp_conn { dq_entry_t node; /* Implements a doubly linked list */ uip_ipaddr_t ripaddr; /* The IP address of the remote peer. */ uint16 lport; /* The local port number in network byte order. */ uint16 rport; /* The remote port number in network byte order. */ uint8 ttl; /* Default time-to-live. */ /* Defines the UDP callback */ void *private; void (*event)(struct uip_driver_s *dev, void *private); }; #endif /* CONFIG_NET_UDP */ /* The structure holding the TCP/IP statistics that are gathered if * UIP_STATISTICS is set to 1. */ struct uip_stats { struct { uip_stats_t drop; /* Number of dropped packets at the IP layer. */ uip_stats_t recv; /* Number of received packets at the IP layer. */ uip_stats_t sent; /* Number of sent packets at the IP layer. */ uip_stats_t vhlerr; /* Number of packets dropped due to wrong IP version or header length. */ uip_stats_t hblenerr; /* Number of packets dropped due to wrong IP length, high byte. */ uip_stats_t lblenerr; /* Number of packets dropped due to wrong IP length, low byte. */ uip_stats_t fragerr; /* Number of packets dropped since they were IP fragments. */ uip_stats_t chkerr; /* Number of packets dropped due to IP checksum errors. */ uip_stats_t protoerr; /* Number of packets dropped since they were neither ICMP, UDP nor TCP. */ } ip; /* IP statistics. */ struct { uip_stats_t drop; /* Number of dropped ICMP packets. */ uip_stats_t recv; /* Number of received ICMP packets. */ uip_stats_t sent; /* Number of sent ICMP packets. */ uip_stats_t typeerr; /* Number of ICMP packets with a wrong type. */ } icmp; /* ICMP statistics. */ struct { uip_stats_t drop; /* Number of dropped TCP segments. */ uip_stats_t recv; /* Number of recived TCP segments. */ uip_stats_t sent; /* Number of sent TCP segments. */ uip_stats_t chkerr; /* Number of TCP segments with a bad checksum. */ uip_stats_t ackerr; /* Number of TCP segments with a bad ACK number. */ uip_stats_t rst; /* Number of recevied TCP RST (reset) segments. */ uip_stats_t rexmit; /* Number of retransmitted TCP segments. */ uip_stats_t syndrop; /* Number of dropped SYNs due to too few connections was avaliable. */ uip_stats_t synrst; /* Number of SYNs for closed ports, triggering a RST. */ } tcp; /* TCP statistics. */ #ifdef CONFIG_NET_UDP struct { uip_stats_t drop; /* Number of dropped UDP segments. */ uip_stats_t recv; /* Number of recived UDP segments. */ uip_stats_t sent; /* Number of sent UDP segments. */ uip_stats_t chkerr; /* Number of UDP segments with a bad checksum. */ } udp; /* UDP statistics. */ #endif /* CONFIG_NET_UDP */ }; /* The TCP and IP headers. */ struct uip_tcpip_hdr { #ifdef CONFIG_NET_IPv6 /* IPv6 header. */ uint8 vtc; uint8 tcflow; uint16 flow; uint8 len[2]; uint8 proto, ttl; uip_ip6addr_t srcipaddr; uip_ip6addr_t destipaddr; #else /* CONFIG_NET_IPv6 */ /* IPv4 header. */ uint8 vhl; uint8 tos; uint8 len[2]; uint8 ipid[2]; uint8 ipoffset[2]; uint8 ttl; uint8 proto; uint16 ipchksum; uint16 srcipaddr[2]; uint16 destipaddr[2]; #endif /* CONFIG_NET_IPv6 */ /* TCP header. */ uint16 srcport; uint16 destport; uint8 seqno[4]; uint8 ackno[4]; uint8 tcpoffset; uint8 flags; uint8 wnd[2]; uint16 tcpchksum; uint8 urgp[2]; uint8 optdata[4]; }; /* The ICMP and IP headers. */ struct uip_icmpip_hdr { #ifdef CONFIG_NET_IPv6 /* IPv6 header. */ uint8 vtc; uint8 tcf; uint16 flow; uint8 len[2]; uint8 proto; uint8 ttl; uip_ip6addr_t srcipaddr; uip_ip6addr_t destipaddr; #else /* CONFIG_NET_IPv6 */ /* IPv4 header. */ uint8 vhl; uint8 tos; uint8 len[2]; uint8 ipid[2]; uint8 ipoffset[2]; uint8 ttl; uint8 proto; uint16 ipchksum; uint16 srcipaddr[2]; uint16 destipaddr[2]; #endif /* CONFIG_NET_IPv6 */ /* ICMP (echo) header. */ uint8 type; uint8 icode; uint16 icmpchksum; #ifndef CONFIG_NET_IPv6 uint16 id; uint16 seqno; #else /* !CONFIG_NET_IPv6 */ uint8 flags; uint8 reserved1; uint8 reserved2; uint8 reserved3; uint8 icmp6data[16]; uint8 options[1]; #endif /* !CONFIG_NET_IPv6 */ }; /* The UDP and IP headers. */ struct uip_udpip_hdr { #ifdef CONFIG_NET_IPv6 /* IPv6 header. */ uint8 vtc; uint8 tcf; uint16 flow; uint8 len[2]; uint8 proto, ttl; uip_ip6addr_t srcipaddr; uip_ip6addr_t destipaddr; #else /* CONFIG_NET_IPv6 */ /* IPv4 header. */ uint8 vhl; uint8 tos; uint8 len[2]; uint8 ipid[2]; uint8 ipoffset[2]; uint8 ttl; uint8 proto; uint16 ipchksum; uint16 srcipaddr[2]; uint16 destipaddr[2]; #endif /* CONFIG_NET_IPv6 */ /* UDP header. */ uint16 srcport; uint16 destport; uint16 udplen; uint16 udpchksum; }; /* Representation of a 48-bit Ethernet address. */ struct uip_eth_addr { uint8 addr[6]; }; /**************************************************************************** * Public Data ****************************************************************************/ #if UIP_URGDATA > 0 /* uint8 *uip_urgdata: * * This pointer points to any urgent data that has been received. Only * present if compiled with support for urgent data (UIP_URGDATA). */ extern void *uip_urgdata; #endif /* UIP_URGDATA > 0 */ /* Variables used in uIP device drivers * * uIP has a few global variables that are used in device drivers for * uIP. */ #if UIP_URGDATA > 0 extern uint16 uip_urglen, uip_surglen; #endif /* UIP_URGDATA > 0 */ /* Pointer to the current TCP connection. * * The uip_conn pointer can be used to access the current TCP * connection. */ extern struct uip_conn *uip_conn; /* 4-byte array used for the 32-bit sequence number calculations.*/ extern uint8 uip_acc32[4]; /* The current UDP connection. */ #ifdef CONFIG_NET_UDP extern struct uip_udp_conn *uip_udp_conn; #endif /* CONFIG_NET_UDP */ /* The uIP TCP/IP statistics. * * This is the variable in which the uIP TCP/IP statistics are gathered. */ extern struct uip_stats uip_stat; /* uint8 uip_flags: * * When the application is called, uip_flags will contain the flags * that are defined in this file. Please read below for more * infomation. */ extern uint8 uip_flags; /**************************************************************************** * Public Function Prototypes ****************************************************************************/ /* uIP configuration functions */ /* uIP initialization functions * * The uIP initialization functions are used for booting uIP. * * This function should be called at boot up to initilize the uIP * TCP/IP stack. */ void uip_init(void); /* This function may be used at boot time to set the initial ip_id.*/ void uip_setipid(uint16 id); /* uIP application functions * * Functions used by an application running of top of uIP. This includes * functions for opening and closing connections, sending and receiving * data, etc. * * Find a free connection structure and allocate it for use. This is * normally something done by the implementation of the socket() API */ extern struct uip_conn *uip_tcpalloc(void); #ifdef CONFIG_NET_UDP extern struct uip_udp_conn *uip_udpalloc(void); #endif /* Free a connection structure that is no longer in use. This should * be done by the implementation of close() */ extern void uip_tcpfree(struct uip_conn *conn); #ifdef CONFIG_NET_UDP extern void uip_udpfree(struct uip_udp_conn *conn); #endif /* Bind a TCP connection to a local address */ #ifdef CONFIG_NET_IPv6 extern int uip_tcpbind(struct uip_conn *conn, const struct sockaddr_in6 *addr); #else extern int uip_tcpbind(struct uip_conn *conn, const struct sockaddr_in *addr); #endif /* This function implements the UIP specific parts of the standard * TCP connect() operation: It connects to a remote host using TCP. * * This function is used to start a new connection to the specified * port on the specied host. It uses the connection structure that was * allocated by a preceding socket() call. It sets the connection to * the SYN_SENT state and sets the retransmission timer to 0. This will * cause a TCP SYN segment to be sent out the next time this connection * is periodically processed, which usually is done within 0.5 seconds * after the call to uip_tcpconnect(). * * This function is called from normal user level code. */ #ifdef CONFIG_NET_IPv6 extern int uip_tcpconnect(struct uip_conn *conn, const struct sockaddr_in6 *addr); #else extern int uip_tcpconnect(struct uip_conn *conn, const struct sockaddr_in *addr); #endif /* Start listening to the specified port. * * Note: Since this function expects the port number in network byte * order, a conversion using HTONS() or htons() is necessary. * * port A 16-bit port number in network byte order. */ int uip_listen(uint16 port); /* Stop listening to the specified port. * * Note: Since this function expects the port number in network byte * order, a conversion using HTONS() or htons() is necessary. * * port A 16-bit port number in network byte order. */ int uip_unlisten(uint16 port); /* Check if a connection has outstanding (i.e., unacknowledged) data. * * conn A pointer to the uip_conn structure for the connection. */ #define uip_outstanding(conn) ((conn)->len) /* Send data on the current connection. * * This function is used to send out a single segment of TCP * data. Only applications that have been invoked by uIP for event * processing can send data. * * The amount of data that actually is sent out after a call to this * funcion is determined by the maximum amount of data TCP allows. uIP * will automatically crop the data so that only the appropriate * amount of data is sent. The function uip_mss() can be used to query * uIP for the amount of data that actually will be sent. * * Note: This function does not guarantee that the sent data will * arrive at the destination. If the data is lost in the network, the * application will be invoked with the uip_rexmit() event being * set. The application will then have to resend the data using this * function. * * data A pointer to the data which is to be sent. * * len The maximum amount of data bytes to be sent. */ void uip_send(struct uip_driver_s *dev, const void *buf, int len); /* The length of any incoming data that is currently avaliable (if avaliable) * in the d_appdata buffer. * * The test function uip_data() must first be used to check if there * is any data available at all. */ #define uip_datalen(dev) ((dev)->d_len) /* The length of any out-of-band data (urgent data) that has arrived * on the connection. * * Note: The configuration parameter UIP_URGDATA must be set for this * function to be enabled. */ #define uip_urgdatalen() uip_urglen /* Close the current connection. * * This function will close the current connection in a nice way. */ #define uip_close() (uip_flags = UIP_CLOSE) /* Abort the current connection. * * This function will abort (reset) the current connection, and is * usually used when an error has occured that prevents using the * uip_close() function. */ #define uip_abort() (uip_flags = UIP_ABORT) /* Tell the sending host to stop sending data. * * This function will close our receiver's window so that we stop * receiving data for the current connection. */ #define uip_stop() (uip_conn->tcpstateflags |= UIP_STOPPED) /* Find out if the current connection has been previously stopped with * uip_stop(). */ #define uip_stopped(conn) ((conn)->tcpstateflags & UIP_STOPPED) /* Restart the current connection, if is has previously been stopped * with uip_stop(). * * This function will open the receiver's window again so that we * start receiving data for the current connection. */ #define uip_restart() do { uip_flags |= UIP_NEWDATA; \ uip_conn->tcpstateflags &= ~UIP_STOPPED; \ } while(0) /* uIP tests that can be made to determine in what state the current * connection is, and what the application function should do. * * Is the current connection a UDP connection? * * This function checks whether the current connection is a UDP connection. */ #define uip_udpconnection() (uip_conn == NULL) /* Is new incoming data available? * * Will reduce to non-zero if there is new data for the application * present at the d_appdata pointer. The size of the data is * avaliable through the d_len element. */ #define uip_newdata() (uip_flags & UIP_NEWDATA) /* Has previously sent data been acknowledged? * * Will reduce to non-zero if the previously sent data has been * acknowledged by the remote host. This means that the application * can send new data. */ #define uip_acked() (uip_flags & UIP_ACKDATA) /* Has the connection just been connected? * * Reduces to non-zero if the current connection has been connected to * a remote host. This will happen both if the connection has been * actively opened (with uip_connect()) or passively opened (with * uip_listen()). */ #define uip_connected() (uip_flags & UIP_CONNECTED) /* Has the connection been closed by the other end? * * Is non-zero if the connection has been closed by the remote * host. The application may then do the necessary clean-ups. */ #define uip_closed() (uip_flags & UIP_CLOSE) /* Has the connection been aborted by the other end? * * Non-zero if the current connection has been aborted (reset) by the * remote host. */ #define uip_aborted() (uip_flags & UIP_ABORT) /* Has the connection timed out? * * Non-zero if the current connection has been aborted due to too many * retransmissions. */ #define uip_timedout() (uip_flags & UIP_TIMEDOUT) /* Do we need to retransmit previously data? * * Reduces to non-zero if the previously sent data has been lost in * the network, and the application should retransmit it. The * application should send the exact same data as it did the last * time, using the uip_send() function. */ #define uip_rexmit() (uip_flags & UIP_REXMIT) /* Is the connection being polled by uIP? * * Is non-zero if the reason the application is invoked is that the * current connection has been idle for a while and should be * polled. * * The polling event can be used for sending data without having to * wait for the remote host to send data. */ #define uip_poll() (uip_flags & UIP_POLL) /* Get the initial maxium segment size (MSS) of the current * connection. */ #define uip_initialmss() (uip_conn->initialmss) /* Get the current maxium segment size that can be sent on the current * connection. * * The current maxiumum segment size that can be sent on the * connection is computed from the receiver's window and the MSS of * the connection (which also is available by calling * uip_initialmss()). */ #define uip_mss() (uip_conn->mss) /* Bind a UDP connection to a local address */ #ifdef CONFIG_NET_IPv6 extern int uip_udpbind(struct uip_udp_conn *conn, const struct sockaddr_in6 *addr); #else extern int uip_udpbind(struct uip_udp_conn *conn, const struct sockaddr_in *addr); #endif /* This function sets up a new UDP connection. The function will * automatically allocate an unused local port for the new * connection. However, another port can be chosen by using the * uip_udpbind() call, after the uip_udpconnect() function has been * called. * * This function is called as part of the implementation of sendto * and recvfrom. * * addr The address of the remote host. */ #ifdef CONFIG_NET_IPv6 extern int uip_udpconnect(struct uip_udp_conn *conn, const struct sockaddr_in6 *addr); #else extern int uip_udpconnect(struct uip_udp_conn *conn, const struct sockaddr_in *addr); #endif /* Enable/disable UDP callbacks on a connection */ extern void uip_udpenable(struct uip_udp_conn *conn); extern void uip_udpdisable(struct uip_udp_conn *conn); /* uIP convenience and converting functions. * * These functions can be used for converting between different data * formats used by uIP. * * Construct an IP address from four bytes. * * This function constructs an IP address of the type that uIP handles * internally from four bytes. The function is handy for specifying IP * addresses to use with e.g. the uip_connect() function. * * Example: * * uip_ipaddr_t ipaddr; * struct uip_conn *c; * * uip_ipaddr(&ipaddr, 192,168,1,2); * c = uip_connect(&ipaddr, HTONS(80)); * * addr A pointer to a uip_ipaddr_t variable that will be * filled in with the IP address. * * addr0 The first octet of the IP address. * addr1 The second octet of the IP address. * addr2 The third octet of the IP address. * addr3 The forth octet of the IP address. */ #define uip_ipaddr(addr, addr0, addr1, addr2, addr3) \ do { \ addr = HTONL((addr0) << 24 | (addr1) << 16 | (addr2) << 8 | (addr3)); \ } while(0) /* Convert an IPv4 address of the form uint16[2] to an in_addr_t */ #ifdef CONFIG_ENDIAN_BIG # define uip_ip4addr_conv(addr) (((in_addr_t)((uint16*)addr)[1] << 16) | (in_addr_t)((uint16*)addr)[0]) #else # define uip_ip4addr_conv(addr) (((in_addr_t)((uint16*)addr)[0] << 16) | (in_addr_t)((uint16*)addr)[1]) #endif /* Construct an IPv6 address from eight 16-bit words. * * This function constructs an IPv6 address. */ #define uip_ip6addr(addr, addr0,addr1,addr2,addr3,addr4,addr5,addr6,addr7) do { \ ((uint16*)(addr))[0] = HTONS((addr0)); \ ((uint16*)(addr))[1] = HTONS((addr1)); \ ((uint16*)(addr))[2] = HTONS((addr2)); \ ((uint16*)(addr))[3] = HTONS((addr3)); \ ((uint16*)(addr))[4] = HTONS((addr4)); \ ((uint16*)(addr))[5] = HTONS((addr5)); \ ((uint16*)(addr))[6] = HTONS((addr6)); \ ((uint16*)(addr))[7] = HTONS((addr7)); \ } while(0) /* Copy an IP address to another IP address. * * Copies an IP address from one place to another. * * Example: * * uip_ipaddr_t ipaddr1, ipaddr2; * * uip_ipaddr(&ipaddr1, 192,16,1,2); * uip_ipaddr_copy(&ipaddr2, &ipaddr1); * * dest The destination for the copy. * src The source from where to copy. */ #ifndef CONFIG_NET_IPv6 # define uip_ipaddr_copy(dest, src) \ do { \ (dest) = (in_addr_t)(src); \ } while(0) # define uiphdr_ipaddr_copy(dest, src) \ do { \ ((uint16*)(dest))[0] = ((uint16*)(src))[0]; \ ((uint16*)(dest))[1] = ((uint16*)(src))[1]; \ } while(0) #else /* !CONFIG_NET_IPv6 */ # define uip_ipaddr_copy(dest, src) memcpy(&dest, &src, sizeof(uip_ip6addr_t)) # define uiphdr_ipaddr_copy(dest, src) uip_ipaddr_copy(dest, src) #endif /* !CONFIG_NET_IPv6 */ /* Compare two IP addresses * * Example: * * uip_ipaddr_t ipaddr1, ipaddr2; * * uip_ipaddr(&ipaddr1, 192,16,1,2); * if(uip_ipaddr_cmp(&ipaddr2, &ipaddr1)) { * printf("They are the same"); * } * * addr1 The first IP address. * addr2 The second IP address. */ #ifndef CONFIG_NET_IPv6 # define uip_ipaddr_cmp(addr1, addr2) (addr1 == addr2) # define uiphdr_ipaddr_cmp(addr1, addr2) uip_ipaddr_cmp(uip_ip4addr_conv(addr1), uip_ip4addr_conv(addr2)) #else /* !CONFIG_NET_IPv6 */ # define uip_ipaddr_cmp(addr1, addr2) (memcmp(&addr1, &addr2, sizeof(uip_ip6addr_t)) == 0) # define uiphdr_ipaddr_cmp(addr1, addr2) uip_ipaddr_cmp(addr, addr2) #endif /* !CONFIG_NET_IPv6 */ /* Compare two IP addresses with netmasks * * Compares two IP addresses with netmasks. The masks are used to mask * out the bits that are to be compared. * * Example: * * uip_ipaddr_t ipaddr1, ipaddr2, mask; * * uip_ipaddr(&mask, 255,255,255,0); * uip_ipaddr(&ipaddr1, 192,16,1,2); * uip_ipaddr(&ipaddr2, 192,16,1,3); * if(uip_ipaddr_maskcmp(&ipaddr1, &ipaddr2, &mask)) { * printf("They are the same"); * } * * addr1 The first IP address. * addr2 The second IP address. * mask The netmask. */ #ifndef CONFIG_NET_IPv6 # define uip_ipaddr_maskcmp(addr1, addr2, mask) \ ((uip_ip4addr_conv(addr1) & (in_addr_t)mask) == ((in_addr_t)addr2 & (in_addr_t)mask)) #else /* !CONFIG_NET_IPv6 */ #endif /* !CONFIG_NET_IPv6 */ /* Mask out the network part of an IP address. * * Masks out the network part of an IP address, given the address and * the netmask. * * Example: * * uip_ipaddr_t ipaddr1, ipaddr2, netmask; * * uip_ipaddr(&ipaddr1, 192,16,1,2); * uip_ipaddr(&netmask, 255,255,255,0); * uip_ipaddr_mask(&ipaddr2, &ipaddr1, &netmask); * * In the example above, the variable "ipaddr2" will contain the IP * address 192.168.1.0. * * dest Where the result is to be placed. * src The IP address. * mask The netmask. */ #define uip_ipaddr_mask(dest, src, mask) \ do { \ (in_addr_t)(dest) = (in_addr_t)(src) & (in_addr_t)(mask); \ } while(0) /* Pick the first octet of an IP address. * * Picks out the first octet of an IP address. * * Example: * * uip_ipaddr_t ipaddr; * uint8 octet; * * uip_ipaddr(&ipaddr, 1,2,3,4); * octet = uip_ipaddr1(&ipaddr); * * In the example above, the variable "octet" will contain the value 1. */ #define uip_ipaddr1(addr) (htons(((uint16 *)(addr))[0]) >> 8) /* Pick the second octet of an IP address. * * Picks out the second octet of an IP address. * * Example: * * uip_ipaddr_t ipaddr; * uint8 octet; * * uip_ipaddr(&ipaddr, 1,2,3,4); * octet = uip_ipaddr2(&ipaddr); * * In the example above, the variable "octet" will contain the value 2. */ #define uip_ipaddr2(addr) (htons(((uint16 *)(addr))[0]) & 0xff) /* Pick the third octet of an IP address. * * Picks out the third octet of an IP address. * * Example: * * uip_ipaddr_t ipaddr; * uint8 octet; * * uip_ipaddr(&ipaddr, 1,2,3,4); * octet = uip_ipaddr3(&ipaddr); * * In the example above, the variable "octet" will contain the value 3. */ #define uip_ipaddr3(addr) (htons(((uint16 *)(addr))[1]) >> 8) /* Pick the fourth octet of an IP address. * * Picks out the fourth octet of an IP address. * * Example: * * uip_ipaddr_t ipaddr; * uint8 octet; * * uip_ipaddr(&ipaddr, 1,2,3,4); * octet = uip_ipaddr4(&ipaddr); * * In the example above, the variable "octet" will contain the value 4. */ #define uip_ipaddr4(addr) (htons(((uint16 *)(addr))[1]) & 0xff) /* Print out a uIP log message. * * This function must be implemented by the module that uses uIP, and * is called by uIP whenever a log message is generated. */ extern void uip_log(char *msg); #endif /* __NET_UIP_UIP_H */