1.. SPDX-License-Identifier: (GPL-2.0 OR MIT) 2 3=================== 4J1939 Documentation 5=================== 6 7Overview / What Is J1939 8======================== 9 10SAE J1939 defines a higher layer protocol on CAN. It implements a more 11sophisticated addressing scheme and extends the maximum packet size above 8 12bytes. Several derived specifications exist, which differ from the original 13J1939 on the application level, like MilCAN A, NMEA2000 and especially 14ISO-11783 (ISOBUS). This last one specifies the so-called ETP (Extended 15Transport Protocol) which is has been included in this implementation. This 16results in a maximum packet size of ((2 ^ 24) - 1) * 7 bytes == 111 MiB. 17 18Specifications used 19------------------- 20 21* SAE J1939-21 : data link layer 22* SAE J1939-81 : network management 23* ISO 11783-6 : Virtual Terminal (Extended Transport Protocol) 24 25.. _j1939-motivation: 26 27Motivation 28========== 29 30Given the fact there's something like SocketCAN with an API similar to BSD 31sockets, we found some reasons to justify a kernel implementation for the 32addressing and transport methods used by J1939. 33 34* **Addressing:** when a process on an ECU communicates via J1939, it should 35 not necessarily know its source address. Although at least one process per 36 ECU should know the source address. Other processes should be able to reuse 37 that address. This way, address parameters for different processes 38 cooperating for the same ECU, are not duplicated. This way of working is 39 closely related to the UNIX concept where programs do just one thing, and do 40 it well. 41 42* **Dynamic addressing:** Address Claiming in J1939 is time critical. 43 Furthermore data transport should be handled properly during the address 44 negotiation. Putting this functionality in the kernel eliminates it as a 45 requirement for _every_ user space process that communicates via J1939. This 46 results in a consistent J1939 bus with proper addressing. 47 48* **Transport:** both TP & ETP reuse some PGNs to relay big packets over them. 49 Different processes may thus use the same TP & ETP PGNs without actually 50 knowing it. The individual TP & ETP sessions _must_ be serialized 51 (synchronized) between different processes. The kernel solves this problem 52 properly and eliminates the serialization (synchronization) as a requirement 53 for _every_ user space process that communicates via J1939. 54 55J1939 defines some other features (relaying, gateway, fast packet transport, 56...). In-kernel code for these would not contribute to protocol stability. 57Therefore, these parts are left to user space. 58 59The J1939 sockets operate on CAN network devices (see SocketCAN). Any J1939 60user space library operating on CAN raw sockets will still operate properly. 61Since such library does not communicate with the in-kernel implementation, care 62must be taken that these two do not interfere. In practice, this means they 63cannot share ECU addresses. A single ECU (or virtual ECU) address is used by 64the library exclusively, or by the in-kernel system exclusively. 65 66J1939 concepts 67============== 68 69PGN 70--- 71 72The PGN (Parameter Group Number) is a number to identify a packet. The PGN 73is composed as follows: 741 bit : Reserved Bit 751 bit : Data Page 768 bits : PF (PDU Format) 778 bits : PS (PDU Specific) 78 79In J1939-21 distinction is made between PDU1 format (where PF < 240) and PDU2 80format (where PF >= 240). Furthermore, when using PDU2 format, the PS-field 81contains a so-called Group Extension, which is part of the PGN. When using PDU2 82format, the Group Extension is set in the PS-field. 83 84On the other hand, when using PDU1 format, the PS-field contains a so-called 85Destination Address, which is _not_ part of the PGN. When communicating a PGN 86from user space to kernel (or visa versa) and PDU2 format is used, the PS-field 87of the PGN shall be set to zero. The Destination Address shall be set 88elsewhere. 89 90Regarding PGN mapping to 29-bit CAN identifier, the Destination Address shall 91be get/set from/to the appropriate bits of the identifier by the kernel. 92 93 94Addressing 95---------- 96 97Both static and dynamic addressing methods can be used. 98 99For static addresses, no extra checks are made by the kernel, and provided 100addresses are considered right. This responsibility is for the OEM or system 101integrator. 102 103For dynamic addressing, so-called Address Claiming, extra support is foreseen 104in the kernel. In J1939 any ECU is known by it's 64-bit NAME. At the moment of 105a successful address claim, the kernel keeps track of both NAME and source 106address being claimed. This serves as a base for filter schemes. By default, 107packets with a destination that is not locally, will be rejected. 108 109Mixed mode packets (from a static to a dynamic address or vice versa) are 110allowed. The BSD sockets define separate API calls for getting/setting the 111local & remote address and are applicable for J1939 sockets. 112 113Filtering 114--------- 115 116J1939 defines white list filters per socket that a user can set in order to 117receive a subset of the J1939 traffic. Filtering can be based on: 118 119* SA 120* SOURCE_NAME 121* PGN 122 123When multiple filters are in place for a single socket, and a packet comes in 124that matches several of those filters, the packet is only received once for 125that socket. 126 127How to Use J1939 128================ 129 130API Calls 131--------- 132 133On CAN, you first need to open a socket for communicating over a CAN network. 134To use J1939, #include <linux/can/j1939.h>. From there, <linux/can.h> will be 135included too. To open a socket, use: 136 137.. code-block:: C 138 139 s = socket(PF_CAN, SOCK_DGRAM, CAN_J1939); 140 141J1939 does use SOCK_DGRAM sockets. In the J1939 specification, connections are 142mentioned in the context of transport protocol sessions. These still deliver 143packets to the other end (using several CAN packets). SOCK_STREAM is not 144supported. 145 146After the successful creation of the socket, you would normally use the bind(2) 147and/or connect(2) system call to bind the socket to a CAN interface. After 148binding and/or connecting the socket, you can read(2) and write(2) from/to the 149socket or use send(2), sendto(2), sendmsg(2) and the recv*() counterpart 150operations on the socket as usual. There are also J1939 specific socket options 151described below. 152 153In order to send data, a bind(2) must have been successful. bind(2) assigns a 154local address to a socket. 155 156Different from CAN is that the payload data is just the data that get send, 157without it's header info. The header info is derived from the sockaddr supplied 158to bind(2), connect(2), sendto(2) and recvfrom(2). A write(2) with size 4 will 159result in a packet with 4 bytes. 160 161The sockaddr structure has extensions for use with J1939 as specified below: 162 163.. code-block:: C 164 165 struct sockaddr_can { 166 sa_family_t can_family; 167 int can_ifindex; 168 union { 169 struct { 170 __u64 name; 171 /* pgn: 172 * 8 bit: PS in PDU2 case, else 0 173 * 8 bit: PF 174 * 1 bit: DP 175 * 1 bit: reserved 176 */ 177 __u32 pgn; 178 __u8 addr; 179 } j1939; 180 } can_addr; 181 } 182 183can_family & can_ifindex serve the same purpose as for other SocketCAN sockets. 184 185can_addr.j1939.pgn specifies the PGN (max 0x3ffff). Individual bits are 186specified above. 187 188can_addr.j1939.name contains the 64-bit J1939 NAME. 189 190can_addr.j1939.addr contains the address. 191 192The bind(2) system call assigns the local address, i.e. the source address when 193sending packages. If a PGN during bind(2) is set, it's used as a RX filter. 194I.e. only packets with a matching PGN are received. If an ADDR or NAME is set 195it is used as a receive filter, too. It will match the destination NAME or ADDR 196of the incoming packet. The NAME filter will work only if appropriate Address 197Claiming for this name was done on the CAN bus and registered/cached by the 198kernel. 199 200On the other hand connect(2) assigns the remote address, i.e. the destination 201address. The PGN from connect(2) is used as the default PGN when sending 202packets. If ADDR or NAME is set it will be used as the default destination ADDR 203or NAME. Further a set ADDR or NAME during connect(2) is used as a receive 204filter. It will match the source NAME or ADDR of the incoming packet. 205 206Both write(2) and send(2) will send a packet with local address from bind(2) and 207the remote address from connect(2). Use sendto(2) to overwrite the destination 208address. 209 210If can_addr.j1939.name is set (!= 0) the NAME is looked up by the kernel and 211the corresponding ADDR is used. If can_addr.j1939.name is not set (== 0), 212can_addr.j1939.addr is used. 213 214When creating a socket, reasonable defaults are set. Some options can be 215modified with setsockopt(2) & getsockopt(2). 216 217RX path related options: 218 219- SO_J1939_FILTER - configure array of filters 220- SO_J1939_PROMISC - disable filters set by bind(2) and connect(2) 221 222By default no broadcast packets can be send or received. To enable sending or 223receiving broadcast packets use the socket option SO_BROADCAST: 224 225.. code-block:: C 226 227 int value = 1; 228 setsockopt(sock, SOL_SOCKET, SO_BROADCAST, &value, sizeof(value)); 229 230The following diagram illustrates the RX path: 231 232.. code:: 233 234 +--------------------+ 235 | incoming packet | 236 +--------------------+ 237 | 238 V 239 +--------------------+ 240 | SO_J1939_PROMISC? | 241 +--------------------+ 242 | | 243 no | | yes 244 | | 245 .---------' `---------. 246 | | 247 +---------------------------+ | 248 | bind() + connect() + | | 249 | SOCK_BROADCAST filter | | 250 +---------------------------+ | 251 | | 252 |<---------------------' 253 V 254 +---------------------------+ 255 | SO_J1939_FILTER | 256 +---------------------------+ 257 | 258 V 259 +---------------------------+ 260 | socket recv() | 261 +---------------------------+ 262 263TX path related options: 264SO_J1939_SEND_PRIO - change default send priority for the socket 265 266Message Flags during send() and Related System Calls 267^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^ 268 269send(2), sendto(2) and sendmsg(2) take a 'flags' argument. Currently 270supported flags are: 271 272* MSG_DONTWAIT, i.e. non-blocking operation. 273 274recvmsg(2) 275^^^^^^^^^ 276 277In most cases recvmsg(2) is needed if you want to extract more information than 278recvfrom(2) can provide. For example package priority and timestamp. The 279Destination Address, name and packet priority (if applicable) are attached to 280the msghdr in the recvmsg(2) call. They can be extracted using cmsg(3) macros, 281with cmsg_level == SOL_J1939 && cmsg_type == SCM_J1939_DEST_ADDR, 282SCM_J1939_DEST_NAME or SCM_J1939_PRIO. The returned data is a uint8_t for 283priority and dst_addr, and uint64_t for dst_name. 284 285.. code-block:: C 286 287 uint8_t priority, dst_addr; 288 uint64_t dst_name; 289 290 for (cmsg = CMSG_FIRSTHDR(&msg); cmsg; cmsg = CMSG_NXTHDR(&msg, cmsg)) { 291 switch (cmsg->cmsg_level) { 292 case SOL_CAN_J1939: 293 if (cmsg->cmsg_type == SCM_J1939_DEST_ADDR) 294 dst_addr = *CMSG_DATA(cmsg); 295 else if (cmsg->cmsg_type == SCM_J1939_DEST_NAME) 296 memcpy(&dst_name, CMSG_DATA(cmsg), cmsg->cmsg_len - CMSG_LEN(0)); 297 else if (cmsg->cmsg_type == SCM_J1939_PRIO) 298 priority = *CMSG_DATA(cmsg); 299 break; 300 } 301 } 302 303Dynamic Addressing 304------------------ 305 306Distinction has to be made between using the claimed address and doing an 307address claim. To use an already claimed address, one has to fill in the 308j1939.name member and provide it to bind(2). If the name had claimed an address 309earlier, all further messages being sent will use that address. And the 310j1939.addr member will be ignored. 311 312An exception on this is PGN 0x0ee00. This is the "Address Claim/Cannot Claim 313Address" message and the kernel will use the j1939.addr member for that PGN if 314necessary. 315 316To claim an address following code example can be used: 317 318.. code-block:: C 319 320 struct sockaddr_can baddr = { 321 .can_family = AF_CAN, 322 .can_addr.j1939 = { 323 .name = name, 324 .addr = J1939_IDLE_ADDR, 325 .pgn = J1939_NO_PGN, /* to disable bind() rx filter for PGN */ 326 }, 327 .can_ifindex = if_nametoindex("can0"), 328 }; 329 330 bind(sock, (struct sockaddr *)&baddr, sizeof(baddr)); 331 332 /* for Address Claiming broadcast must be allowed */ 333 int value = 1; 334 setsockopt(sock, SOL_SOCKET, SO_BROADCAST, &value, sizeof(value)); 335 336 /* configured advanced RX filter with PGN needed for Address Claiming */ 337 const struct j1939_filter filt[] = { 338 { 339 .pgn = J1939_PGN_ADDRESS_CLAIMED, 340 .pgn_mask = J1939_PGN_PDU1_MAX, 341 }, { 342 .pgn = J1939_PGN_ADDRESS_REQUEST, 343 .pgn_mask = J1939_PGN_PDU1_MAX, 344 }, { 345 .pgn = J1939_PGN_ADDRESS_COMMANDED, 346 .pgn_mask = J1939_PGN_MAX, 347 }, 348 }; 349 350 setsockopt(sock, SOL_CAN_J1939, SO_J1939_FILTER, &filt, sizeof(filt)); 351 352 uint64_t dat = htole64(name); 353 const struct sockaddr_can saddr = { 354 .can_family = AF_CAN, 355 .can_addr.j1939 = { 356 .pgn = J1939_PGN_ADDRESS_CLAIMED, 357 .addr = J1939_NO_ADDR, 358 }, 359 }; 360 361 /* Afterwards do a sendto(2) with data set to the NAME (Little Endian). If the 362 * NAME provided, does not match the j1939.name provided to bind(2), EPROTO 363 * will be returned. 364 */ 365 sendto(sock, dat, sizeof(dat), 0, (const struct sockaddr *)&saddr, sizeof(saddr)); 366 367If no-one else contests the address claim within 250ms after transmission, the 368kernel marks the NAME-SA assignment as valid. The valid assignment will be kept 369among other valid NAME-SA assignments. From that point, any socket bound to the 370NAME can send packets. 371 372If another ECU claims the address, the kernel will mark the NAME-SA expired. 373No socket bound to the NAME can send packets (other than address claims). To 374claim another address, some socket bound to NAME, must bind(2) again, but with 375only j1939.addr changed to the new SA, and must then send a valid address claim 376packet. This restarts the state machine in the kernel (and any other 377participant on the bus) for this NAME. 378 379can-utils also include the jacd tool, so it can be used as code example or as 380default Address Claiming daemon. 381 382Send Examples 383------------- 384 385Static Addressing 386^^^^^^^^^^^^^^^^^ 387 388This example will send a PGN (0x12300) from SA 0x20 to DA 0x30. 389 390Bind: 391 392.. code-block:: C 393 394 struct sockaddr_can baddr = { 395 .can_family = AF_CAN, 396 .can_addr.j1939 = { 397 .name = J1939_NO_NAME, 398 .addr = 0x20, 399 .pgn = J1939_NO_PGN, 400 }, 401 .can_ifindex = if_nametoindex("can0"), 402 }; 403 404 bind(sock, (struct sockaddr *)&baddr, sizeof(baddr)); 405 406Now, the socket 'sock' is bound to the SA 0x20. Since no connect(2) was called, 407at this point we can use only sendto(2) or sendmsg(2). 408 409Send: 410 411.. code-block:: C 412 413 const struct sockaddr_can saddr = { 414 .can_family = AF_CAN, 415 .can_addr.j1939 = { 416 .name = J1939_NO_NAME; 417 .pgn = 0x30, 418 .addr = 0x12300, 419 }, 420 }; 421 422 sendto(sock, dat, sizeof(dat), 0, (const struct sockaddr *)&saddr, sizeof(saddr)); 423