rawapi.txt 21 KB

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  1. Raw TCP/IP interface for lwIP
  2. Authors: Adam Dunkels, Leon Woestenberg, Christiaan Simons
  3. lwIP provides three Application Program's Interfaces (APIs) for programs
  4. to use for communication with the TCP/IP code:
  5. * low-level "core" / "callback" or "raw" API.
  6. * higher-level "sequential" API.
  7. * BSD-style socket API.
  8. The raw API (sometimes called native API) is an event-driven API designed
  9. to be used without an operating system that implements zero-copy send and
  10. receive. This API is also used by the core stack for interaction between
  11. the various protocols. It is the only API available when running lwIP
  12. without an operating system.
  13. The sequential API provides a way for ordinary, sequential, programs
  14. to use the lwIP stack. It is quite similar to the BSD socket API. The
  15. model of execution is based on the blocking open-read-write-close
  16. paradigm. Since the TCP/IP stack is event based by nature, the TCP/IP
  17. code and the application program must reside in different execution
  18. contexts (threads).
  19. The socket API is a compatibility API for existing applications,
  20. currently it is built on top of the sequential API. It is meant to
  21. provide all functions needed to run socket API applications running
  22. on other platforms (e.g. unix / windows etc.). However, due to limitations
  23. in the specification of this API, there might be incompatibilities
  24. that require small modifications of existing programs.
  25. ** Multithreading
  26. lwIP started targeting single-threaded environments. When adding multi-
  27. threading support, instead of making the core thread-safe, another
  28. approach was chosen: there is one main thread running the lwIP core
  29. (also known as the "tcpip_thread"). When running in a multithreaded
  30. environment, raw API functions MUST only be called from the core thread
  31. since raw API functions are not protected from concurrent access (aside
  32. from pbuf- and memory management functions). Application threads using
  33. the sequential- or socket API communicate with this main thread through
  34. message passing.
  35. As such, the list of functions that may be called from
  36. other threads or an ISR is very limited! Only functions
  37. from these API header files are thread-safe:
  38. - api.h
  39. - netbuf.h
  40. - netdb.h
  41. - netifapi.h
  42. - pppapi.h
  43. - sockets.h
  44. - sys.h
  45. Additionaly, memory (de-)allocation functions may be
  46. called from multiple threads (not ISR!) with NO_SYS=0
  47. since they are protected by SYS_LIGHTWEIGHT_PROT and/or
  48. semaphores.
  49. Netconn or Socket API functions are thread safe against the
  50. core thread but they are not reentrant at the control block
  51. granularity level. That is, a UDP or TCP control block must
  52. not be shared among multiple threads without proper locking.
  53. If SYS_LIGHTWEIGHT_PROT is set to 1 and
  54. LWIP_ALLOW_MEM_FREE_FROM_OTHER_CONTEXT is set to 1,
  55. pbuf_free() may also be called from another thread or
  56. an ISR (since only then, mem_free - for PBUF_RAM - may
  57. be called from an ISR: otherwise, the HEAP is only
  58. protected by semaphores).
  59. ** The remainder of this document discusses the "raw" API. **
  60. The raw TCP/IP interface allows the application program to integrate
  61. better with the TCP/IP code. Program execution is event based by
  62. having callback functions being called from within the TCP/IP
  63. code. The TCP/IP code and the application program both run in the same
  64. thread. The sequential API has a much higher overhead and is not very
  65. well suited for small systems since it forces a multithreaded paradigm
  66. on the application.
  67. The raw TCP/IP interface is not only faster in terms of code execution
  68. time but is also less memory intensive. The drawback is that program
  69. development is somewhat harder and application programs written for
  70. the raw TCP/IP interface are more difficult to understand. Still, this
  71. is the preferred way of writing applications that should be small in
  72. code size and memory usage.
  73. All APIs can be used simultaneously by different application
  74. programs. In fact, the sequential API is implemented as an application
  75. program using the raw TCP/IP interface.
  76. Do not confuse the lwIP raw API with raw Ethernet or IP sockets.
  77. The former is a way of interfacing the lwIP network stack (including
  78. TCP and UDP), the later refers to processing raw Ethernet or IP data
  79. instead of TCP connections or UDP packets.
  80. Raw API applications may never block since all packet processing
  81. (input and output) as well as timer processing (TCP mainly) is done
  82. in a single execution context.
  83. --- Callbacks
  84. Program execution is driven by callbacks functions, which are then
  85. invoked by the lwIP core when activity related to that application
  86. occurs. A particular application may register to be notified via a
  87. callback function for events such as incoming data available, outgoing
  88. data sent, error notifications, poll timer expiration, connection
  89. closed, etc. An application can provide a callback function to perform
  90. processing for any or all of these events. Each callback is an ordinary
  91. C function that is called from within the TCP/IP code. Every callback
  92. function is passed the current TCP or UDP connection state as an
  93. argument. Also, in order to be able to keep program specific state,
  94. the callback functions are called with a program specified argument
  95. that is independent of the TCP/IP state.
  96. The function for setting the application connection state is:
  97. - void tcp_arg(struct tcp_pcb *pcb, void *arg)
  98. Specifies the program specific state that should be passed to all
  99. other callback functions. The "pcb" argument is the current TCP
  100. connection control block, and the "arg" argument is the argument
  101. that will be passed to the callbacks.
  102. --- TCP connection setup
  103. The functions used for setting up connections is similar to that of
  104. the sequential API and of the BSD socket API. A new TCP connection
  105. identifier (i.e., a protocol control block - PCB) is created with the
  106. tcp_new() function. This PCB can then be either set to listen for new
  107. incoming connections or be explicitly connected to another host.
  108. - struct tcp_pcb *tcp_new(void)
  109. Creates a new connection identifier (PCB). If memory is not
  110. available for creating the new pcb, NULL is returned.
  111. - err_t tcp_bind(struct tcp_pcb *pcb, ip_addr_t *ipaddr,
  112. u16_t port)
  113. Binds the pcb to a local IP address and port number. The IP address
  114. can be specified as IP_ADDR_ANY in order to bind the connection to
  115. all local IP addresses.
  116. If another connection is bound to the same port, the function will
  117. return ERR_USE, otherwise ERR_OK is returned.
  118. - struct tcp_pcb *tcp_listen(struct tcp_pcb *pcb)
  119. Commands a pcb to start listening for incoming connections. When an
  120. incoming connection is accepted, the function specified with the
  121. tcp_accept() function will be called. The pcb will have to be bound
  122. to a local port with the tcp_bind() function.
  123. The tcp_listen() function returns a new connection identifier, and
  124. the one passed as an argument to the function will be
  125. deallocated. The reason for this behavior is that less memory is
  126. needed for a connection that is listening, so tcp_listen() will
  127. reclaim the memory needed for the original connection and allocate a
  128. new smaller memory block for the listening connection.
  129. tcp_listen() may return NULL if no memory was available for the
  130. listening connection. If so, the memory associated with the pcb
  131. passed as an argument to tcp_listen() will not be deallocated.
  132. - struct tcp_pcb *tcp_listen_with_backlog(struct tcp_pcb *pcb, u8_t backlog)
  133. Same as tcp_listen, but limits the number of outstanding connections
  134. in the listen queue to the value specified by the backlog argument.
  135. To use it, your need to set TCP_LISTEN_BACKLOG=1 in your lwipopts.h.
  136. - void tcp_accept(struct tcp_pcb *pcb,
  137. err_t (* accept)(void *arg, struct tcp_pcb *newpcb,
  138. err_t err))
  139. Specified the callback function that should be called when a new
  140. connection arrives on a listening connection.
  141. - err_t tcp_connect(struct tcp_pcb *pcb, ip_addr_t *ipaddr,
  142. u16_t port, err_t (* connected)(void *arg,
  143. struct tcp_pcb *tpcb,
  144. err_t err));
  145. Sets up the pcb to connect to the remote host and sends the
  146. initial SYN segment which opens the connection.
  147. The tcp_connect() function returns immediately; it does not wait for
  148. the connection to be properly setup. Instead, it will call the
  149. function specified as the fourth argument (the "connected" argument)
  150. when the connection is established. If the connection could not be
  151. properly established, either because the other host refused the
  152. connection or because the other host didn't answer, the "err"
  153. callback function of this pcb (registered with tcp_err, see below)
  154. will be called.
  155. The tcp_connect() function can return ERR_MEM if no memory is
  156. available for enqueueing the SYN segment. If the SYN indeed was
  157. enqueued successfully, the tcp_connect() function returns ERR_OK.
  158. --- Sending TCP data
  159. TCP data is sent by enqueueing the data with a call to
  160. tcp_write(). When the data is successfully transmitted to the remote
  161. host, the application will be notified with a call to a specified
  162. callback function.
  163. - err_t tcp_write(struct tcp_pcb *pcb, const void *dataptr, u16_t len,
  164. u8_t apiflags)
  165. Enqueues the data pointed to by the argument dataptr. The length of
  166. the data is passed as the len parameter. The apiflags can be one or more of:
  167. - TCP_WRITE_FLAG_COPY: indicates whether the new memory should be allocated
  168. for the data to be copied into. If this flag is not given, no new memory
  169. should be allocated and the data should only be referenced by pointer. This
  170. also means that the memory behind dataptr must not change until the data is
  171. ACKed by the remote host
  172. - TCP_WRITE_FLAG_MORE: indicates that more data follows. If this is omitted,
  173. the PSH flag is set in the last segment created by this call to tcp_write.
  174. If this flag is given, the PSH flag is not set.
  175. The tcp_write() function will fail and return ERR_MEM if the length
  176. of the data exceeds the current send buffer size or if the length of
  177. the queue of outgoing segment is larger than the upper limit defined
  178. in lwipopts.h. The number of bytes available in the output queue can
  179. be retrieved with the tcp_sndbuf() function.
  180. The proper way to use this function is to call the function with at
  181. most tcp_sndbuf() bytes of data. If the function returns ERR_MEM,
  182. the application should wait until some of the currently enqueued
  183. data has been successfully received by the other host and try again.
  184. - void tcp_sent(struct tcp_pcb *pcb,
  185. err_t (* sent)(void *arg, struct tcp_pcb *tpcb,
  186. u16_t len))
  187. Specifies the callback function that should be called when data has
  188. successfully been received (i.e., acknowledged) by the remote
  189. host. The len argument passed to the callback function gives the
  190. amount bytes that was acknowledged by the last acknowledgment.
  191. --- Receiving TCP data
  192. TCP data reception is callback based - an application specified
  193. callback function is called when new data arrives. When the
  194. application has taken the data, it has to call the tcp_recved()
  195. function to indicate that TCP can advertise increase the receive
  196. window.
  197. - void tcp_recv(struct tcp_pcb *pcb,
  198. err_t (* recv)(void *arg, struct tcp_pcb *tpcb,
  199. struct pbuf *p, err_t err))
  200. Sets the callback function that will be called when new data
  201. arrives. The callback function will be passed a NULL pbuf to
  202. indicate that the remote host has closed the connection. If
  203. there are no errors and the callback function is to return
  204. ERR_OK, then it must free the pbuf. Otherwise, it must not
  205. free the pbuf so that lwIP core code can store it.
  206. - void tcp_recved(struct tcp_pcb *pcb, u16_t len)
  207. Must be called when the application has received the data. The len
  208. argument indicates the length of the received data.
  209. --- Application polling
  210. When a connection is idle (i.e., no data is either transmitted or
  211. received), lwIP will repeatedly poll the application by calling a
  212. specified callback function. This can be used either as a watchdog
  213. timer for killing connections that have stayed idle for too long, or
  214. as a method of waiting for memory to become available. For instance,
  215. if a call to tcp_write() has failed because memory wasn't available,
  216. the application may use the polling functionality to call tcp_write()
  217. again when the connection has been idle for a while.
  218. - void tcp_poll(struct tcp_pcb *pcb,
  219. err_t (* poll)(void *arg, struct tcp_pcb *tpcb),
  220. u8_t interval)
  221. Specifies the polling interval and the callback function that should
  222. be called to poll the application. The interval is specified in
  223. number of TCP coarse grained timer shots, which typically occurs
  224. twice a second. An interval of 10 means that the application would
  225. be polled every 5 seconds.
  226. --- Closing and aborting connections
  227. - err_t tcp_close(struct tcp_pcb *pcb)
  228. Closes the connection. The function may return ERR_MEM if no memory
  229. was available for closing the connection. If so, the application
  230. should wait and try again either by using the acknowledgment
  231. callback or the polling functionality. If the close succeeds, the
  232. function returns ERR_OK.
  233. The pcb is deallocated by the TCP code after a call to tcp_close().
  234. - void tcp_abort(struct tcp_pcb *pcb)
  235. Aborts the connection by sending a RST (reset) segment to the remote
  236. host. The pcb is deallocated. This function never fails.
  237. ATTENTION: When calling this from one of the TCP callbacks, make
  238. sure you always return ERR_ABRT (and never return ERR_ABRT otherwise
  239. or you will risk accessing deallocated memory or memory leaks!
  240. If a connection is aborted because of an error, the application is
  241. alerted of this event by the err callback. Errors that might abort a
  242. connection are when there is a shortage of memory. The callback
  243. function to be called is set using the tcp_err() function.
  244. - void tcp_err(struct tcp_pcb *pcb, void (* err)(void *arg,
  245. err_t err))
  246. The error callback function does not get the pcb passed to it as a
  247. parameter since the pcb may already have been deallocated.
  248. --- UDP interface
  249. The UDP interface is similar to that of TCP, but due to the lower
  250. level of complexity of UDP, the interface is significantly simpler.
  251. - struct udp_pcb *udp_new(void)
  252. Creates a new UDP pcb which can be used for UDP communication. The
  253. pcb is not active until it has either been bound to a local address
  254. or connected to a remote address.
  255. - void udp_remove(struct udp_pcb *pcb)
  256. Removes and deallocates the pcb.
  257. - err_t udp_bind(struct udp_pcb *pcb, ip_addr_t *ipaddr,
  258. u16_t port)
  259. Binds the pcb to a local address. The IP-address argument "ipaddr"
  260. can be IP_ADDR_ANY to indicate that it should listen to any local IP
  261. address. The function currently always return ERR_OK.
  262. - err_t udp_connect(struct udp_pcb *pcb, ip_addr_t *ipaddr,
  263. u16_t port)
  264. Sets the remote end of the pcb. This function does not generate any
  265. network traffic, but only set the remote address of the pcb.
  266. - err_t udp_disconnect(struct udp_pcb *pcb)
  267. Remove the remote end of the pcb. This function does not generate
  268. any network traffic, but only removes the remote address of the pcb.
  269. - err_t udp_send(struct udp_pcb *pcb, struct pbuf *p)
  270. Sends the pbuf p. The pbuf is not deallocated.
  271. - void udp_recv(struct udp_pcb *pcb,
  272. void (* recv)(void *arg, struct udp_pcb *upcb,
  273. struct pbuf *p,
  274. ip_addr_t *addr,
  275. u16_t port),
  276. void *recv_arg)
  277. Specifies a callback function that should be called when a UDP
  278. datagram is received.
  279. --- System initalization
  280. A truly complete and generic sequence for initializing the lwIP stack
  281. cannot be given because it depends on additional initializations for
  282. your runtime environment (e.g. timers).
  283. We can give you some idea on how to proceed when using the raw API.
  284. We assume a configuration using a single Ethernet netif and the
  285. UDP and TCP transport layers, IPv4 and the DHCP client.
  286. Call these functions in the order of appearance:
  287. - lwip_init()
  288. Initialize the lwIP stack and all of its subsystems.
  289. - netif_add(struct netif *netif, const ip4_addr_t *ipaddr,
  290. const ip4_addr_t *netmask, const ip4_addr_t *gw,
  291. void *state, netif_init_fn init, netif_input_fn input)
  292. Adds your network interface to the netif_list. Allocate a struct
  293. netif and pass a pointer to this structure as the first argument.
  294. Give pointers to cleared ip_addr structures when using DHCP,
  295. or fill them with sane numbers otherwise. The state pointer may be NULL.
  296. The init function pointer must point to a initialization function for
  297. your Ethernet netif interface. The following code illustrates its use.
  298. err_t netif_if_init(struct netif *netif)
  299. {
  300. u8_t i;
  301. for (i = 0; i < ETHARP_HWADDR_LEN; i++) {
  302. netif->hwaddr[i] = some_eth_addr[i];
  303. }
  304. init_my_eth_device();
  305. return ERR_OK;
  306. }
  307. For Ethernet drivers, the input function pointer must point to the lwIP
  308. function ethernet_input() declared in "netif/etharp.h". Other drivers
  309. must use ip_input() declared in "lwip/ip.h".
  310. - netif_set_default(struct netif *netif)
  311. Registers the default network interface.
  312. - netif_set_link_up(struct netif *netif)
  313. This is the hardware link state; e.g. whether cable is plugged for wired
  314. Ethernet interface. This function must be called even if you don't know
  315. the current state. Having link up and link down events is optional but
  316. DHCP and IPv6 discover benefit well from those events.
  317. - netif_set_up(struct netif *netif)
  318. This is the administrative (= software) state of the netif, when the
  319. netif is fully configured this function must be called.
  320. - dhcp_start(struct netif *netif)
  321. Creates a new DHCP client for this interface on the first call.
  322. You can peek in the netif->dhcp struct for the actual DHCP status.
  323. - sys_check_timeouts()
  324. When the system is running, you have to periodically call
  325. sys_check_timeouts() which will handle all timers for all protocols in
  326. the stack; add this to your main loop or equivalent.
  327. --- Optimalization hints
  328. The first thing you want to optimize is the lwip_standard_checksum()
  329. routine from src/core/inet.c. You can override this standard
  330. function with the #define LWIP_CHKSUM <your_checksum_routine>.
  331. There are C examples given in inet.c or you might want to
  332. craft an assembly function for this. RFC1071 is a good
  333. introduction to this subject.
  334. Other significant improvements can be made by supplying
  335. assembly or inline replacements for htons() and htonl()
  336. if you're using a little-endian architecture.
  337. #define lwip_htons(x) <your_htons>
  338. #define lwip_htonl(x) <your_htonl>
  339. If you #define them to htons() and htonl(), you should
  340. #define LWIP_DONT_PROVIDE_BYTEORDER_FUNCTIONS to prevent lwIP from
  341. defining hton*/ntoh* compatibility macros.
  342. Check your network interface driver if it reads at
  343. a higher speed than the maximum wire-speed. If the
  344. hardware isn't serviced frequently and fast enough
  345. buffer overflows are likely to occur.
  346. E.g. when using the cs8900 driver, call cs8900if_service(ethif)
  347. as frequently as possible. When using an RTOS let the cs8900 interrupt
  348. wake a high priority task that services your driver using a binary
  349. semaphore or event flag. Some drivers might allow additional tuning
  350. to match your application and network.
  351. For a production release it is recommended to set LWIP_STATS to 0.
  352. Note that speed performance isn't influenced much by simply setting
  353. high values to the memory options.
  354. For more optimization hints take a look at the lwIP wiki.
  355. --- Zero-copy MACs
  356. To achieve zero-copy on transmit, the data passed to the raw API must
  357. remain unchanged until sent. Because the send- (or write-)functions return
  358. when the packets have been enqueued for sending, data must be kept stable
  359. after that, too.
  360. This implies that PBUF_RAM/PBUF_POOL pbufs passed to raw-API send functions
  361. must *not* be reused by the application unless their ref-count is 1.
  362. For no-copy pbufs (PBUF_ROM/PBUF_REF), data must be kept unchanged, too,
  363. but the stack/driver will/must copy PBUF_REF'ed data when enqueueing, while
  364. PBUF_ROM-pbufs are just enqueued (as ROM-data is expected to never change).
  365. Also, data passed to tcp_write without the copy-flag must not be changed!
  366. Therefore, be careful which type of PBUF you use and if you copy TCP data
  367. or not!