/** * @ingroup intern * @brief send_mod_request - send a linkinfo modification request * * @param fd decriptor to a priorly opened netlink socket * @param n netlink message containing the request * * sends a request to setup the the linkinfo to netlink layer and awaits the * status. * * @return 0 if success * @return negativ if failed */ static int send_mod_request(int fd, struct nlmsghdr *n) { int status; struct sockaddr_nl nladdr; struct nlmsghdr *h; struct iovec iov = { .iov_base = (void *)n, .iov_len = n->nlmsg_len }; struct msghdr msg = { .msg_name = &nladdr, .msg_namelen = sizeof(nladdr), .msg_iov = &iov, .msg_iovlen = 1, }; char buf[16384]; memset(&nladdr, 0, sizeof(nladdr)); nladdr.nl_family = AF_NETLINK; nladdr.nl_pid = 0; nladdr.nl_groups = 0; n->nlmsg_seq = 0; n->nlmsg_flags |= NLM_F_ACK; status = sendmsg(fd, &msg, 0); if (status < 0) { perror("Cannot talk to rtnetlink"); return -1; } iov.iov_base = buf; while (1) { iov.iov_len = sizeof(buf); status = recvmsg(fd, &msg, 0); for (h = (struct nlmsghdr *)buf; (size_t) status >= sizeof(*h);) { int len = h->nlmsg_len; int l = len - sizeof(*h); if (l < 0 || len > status) { if (msg.msg_flags & MSG_TRUNC) { fprintf(stderr, "Truncated message\n"); return -1; } printf("!!!malformed message: len=%d\n", len); return -1; } if (h->nlmsg_type == NLMSG_ERROR) { struct nlmsgerr *err = (struct nlmsgerr *)NLMSG_DATA(h); if ((size_t) l < sizeof(struct nlmsgerr)) { fprintf(stderr, "ERROR truncated\n"); } else { errno = -err->error; if (errno == 0) return 0; perror("RTNETLINK answers"); } return -1; } status -= NLMSG_ALIGN(len); h = (struct nlmsghdr *)((char *)h + NLMSG_ALIGN(len)); } } return 0; } /** * @ingroup intern * @brief send_dump_request - send a dump linkinfo request * * @param fd decriptor to a priorly opened netlink socket * @param family rt_gen message family * @param type netlink message header type * * @return 0 if success * @return negativ if failed */ static int send_dump_request(int fd, int family, int type) { struct get_req req; memset(&req, 0, sizeof(req)); req.n.nlmsg_len = sizeof(req); req.n.nlmsg_type = type; req.n.nlmsg_flags = NLM_F_REQUEST | NLM_F_ROOT | NLM_F_MATCH; req.n.nlmsg_pid = 0; req.n.nlmsg_seq = 0; req.g.rtgen_family = family; return send(fd, (void *)&req, sizeof(req), 0); } //extern int optind, opterr, optopt; /** * @ingroup intern * @brief open_nl_sock - open a netlink socket * * opens a netlink socket and returns the socket descriptor * * @return 0 if success * @return negativ if failed */ static int open_nl_sock() { int fd; int sndbuf = 32768; int rcvbuf = 32768; unsigned int addr_len; struct sockaddr_nl local; fd = socket(AF_NETLINK, SOCK_RAW, NETLINK_ROUTE); if (fd < 0) { printf("Cannot open netlink socket"); return -1; } setsockopt(fd, SOL_SOCKET, SO_SNDBUF, (void *)&sndbuf, sizeof(sndbuf)); setsockopt(fd, SOL_SOCKET, SO_RCVBUF, (void *)&rcvbuf, sizeof(rcvbuf)); memset(&local, 0, sizeof(local)); local.nl_family = AF_NETLINK; local.nl_groups = 0; if (bind(fd, (struct sockaddr *)&local, sizeof(local)) < 0) { printf("Cannot bind netlink socket"); return -1; } addr_len = sizeof(local); if (getsockname(fd, (struct sockaddr *)&local, &addr_len) < 0) { printf("Cannot getsockname"); return -1; } if (addr_len != sizeof(local)) { printf("Wrong address length %u\n", addr_len); return -1; } if (local.nl_family != AF_NETLINK) { printf("Wrong address family %d\n", local.nl_family); return -1; } return fd; } /** * @ingroup intern * @brief do_get_nl_link - get linkinfo * * @param fd socket file descriptor to a priorly opened netlink socket * @param acquire which parameter we want to get * @param name name of the can device. This is the netdev name, as ifconfig -a * shows in your system. usually it contains prefix "can" and the numer of the * can line. e.g. "can0" * @param res pointer to store the result * * This callback send a dump request into the netlink layer, collect the packet * containing the linkinfo and fill the pointer res points to depending on the * acquire mode set in param acquire. * * @return 0 if success * @return -1 if failed */ static int do_get_nl_link(int fd, __u8 acquire, const char *name, void *res) { struct sockaddr_nl peer; char cbuf[64]; char nlbuf[1024 * 8]; int ret = -1; int done = 0; struct iovec iov = { .iov_base = (void *)nlbuf, .iov_len = sizeof(nlbuf), }; struct msghdr msg = { .msg_name = (void *)&peer, .msg_namelen = sizeof(peer), .msg_iov = &iov, .msg_iovlen = 1, .msg_control = &cbuf, .msg_controllen = sizeof(cbuf), .msg_flags = 0, }; struct nlmsghdr *nl_msg; ssize_t msglen; struct rtattr *linkinfo[IFLA_INFO_MAX + 1]; struct rtattr *can_attr[IFLA_CAN_MAX + 1]; if (send_dump_request(fd, AF_PACKET, RTM_GETLINK) < 0) { perror("Cannot send dump request"); return ret; } while (!done && (msglen = recvmsg(fd, &msg, 0)) > 0) { size_t u_msglen = (size_t) msglen; /* Check to see if the buffers in msg get truncated */ if (msg.msg_namelen != sizeof(peer) || (msg.msg_flags & (MSG_TRUNC | MSG_CTRUNC))) { fprintf(stderr, "Uhoh... truncated message.\n"); return -1; } for (nl_msg = (struct nlmsghdr *)nlbuf; NLMSG_OK(nl_msg, u_msglen); nl_msg = NLMSG_NEXT(nl_msg, u_msglen)) { int type = nl_msg->nlmsg_type; int len; if (type == NLMSG_DONE) { done++; continue; } if (type != RTM_NEWLINK) continue; struct ifinfomsg *ifi = NLMSG_DATA(nl_msg); struct rtattr *tb[IFLA_MAX + 1]; len = nl_msg->nlmsg_len - NLMSG_LENGTH(sizeof(struct ifaddrmsg)); parse_rtattr(tb, IFLA_MAX, IFLA_RTA(ifi), len); if (strcmp ((char *)RTA_DATA(tb[IFLA_IFNAME]), name) != 0) continue; if (tb[IFLA_LINKINFO]) parse_rtattr_nested(linkinfo, IFLA_INFO_MAX, tb[IFLA_LINKINFO]); else continue; if (acquire == GET_XSTATS) { if (!linkinfo[IFLA_INFO_XSTATS]) fprintf(stderr, "no can statistics found\n"); else { memcpy(res, RTA_DATA(linkinfo[IFLA_INFO_XSTATS]), sizeof(struct can_device_stats)); ret = 0; } continue; } if (!linkinfo[IFLA_INFO_DATA]) { fprintf(stderr, "no link data found\n"); return ret; } parse_rtattr_nested(can_attr, IFLA_CAN_MAX, linkinfo[IFLA_INFO_DATA]); switch (acquire) { case GET_STATE: if (can_attr[IFLA_CAN_STATE]) { *((int *)res) = *((__u32 *) RTA_DATA(can_attr [IFLA_CAN_STATE])); ret = 0; } else { fprintf(stderr, "no state data found\n"); } break; case GET_RESTART_MS: if (can_attr[IFLA_CAN_RESTART_MS]) { *((__u32 *) res) = *((__u32 *) RTA_DATA(can_attr [IFLA_CAN_RESTART_MS])); ret = 0; } else fprintf(stderr, "no restart_ms data found\n"); break; case GET_BITTIMING: if (can_attr[IFLA_CAN_BITTIMING]) { memcpy(res, RTA_DATA(can_attr[IFLA_CAN_BITTIMING]), sizeof(struct can_bittiming)); ret = 0; } else fprintf(stderr, "no bittiming data found\n"); break; case GET_CTRLMODE: if (can_attr[IFLA_CAN_CTRLMODE]) { memcpy(res, RTA_DATA(can_attr[IFLA_CAN_CTRLMODE]), sizeof(struct can_ctrlmode)); ret = 0; } else fprintf(stderr, "no ctrlmode data found\n"); break; case GET_CLOCK: if (can_attr[IFLA_CAN_CLOCK]) { memcpy(res, RTA_DATA(can_attr[IFLA_CAN_CLOCK]), sizeof(struct can_clock)); ret = 0; } else fprintf(stderr, "no clock parameter data found\n"); break; case GET_BITTIMING_CONST: if (can_attr[IFLA_CAN_BITTIMING_CONST]) { memcpy(res, RTA_DATA(can_attr[IFLA_CAN_BITTIMING_CONST]), sizeof(struct can_bittiming_const)); ret = 0; } else fprintf(stderr, "no bittiming_const data found\n"); break; case GET_BERR_COUNTER: if (can_attr[IFLA_CAN_BERR_COUNTER]) { memcpy(res, RTA_DATA(can_attr[IFLA_CAN_BERR_COUNTER]), sizeof(struct can_berr_counter)); ret = 0; } else fprintf(stderr, "no berr_counter data found\n"); break; default: fprintf(stderr, "unknown acquire mode\n"); } } } return ret; } /** * @ingroup intern * @brief get_link - get linkinfo * * @param name name of the can device. This is the netdev name, as ifconfig -a shows * in your system. usually it contains prefix "can" and the numer of the can * line. e.g. "can0" * @param acquire which parameter we want to get * @param res pointer to store the result * * This is a wrapper for do_get_nl_link * * @return 0 if success * @return -1 if failed */ static int get_link(const char *name, __u8 acquire, void *res) { int err, fd; fd = open_nl_sock(); if (fd < 0) return -1; err = do_get_nl_link(fd, acquire, name, res); close(fd); return err; } /** * @ingroup intern * @brief do_set_nl_link - setup linkinfo * * @param fd socket file descriptor to a priorly opened netlink socket * @param if_state state of the interface we want to put the device into. this * parameter is only set if you want to use the callback to driver up/down the * device * @param name name of the can device. This is the netdev name, as ifconfig -a shows * in your system. usually it contains prefix "can" and the numer of the can * line. e.g. "can0" * @param req_info request parameters * * This callback can do two different tasks: * - bring up/down the interface * - set up a netlink packet with request, as set up in req_info * Which task this callback will do depends on which parameters are set. * * @return 0 if success * @return -1 if failed */ static int do_set_nl_link(int fd, __u8 if_state, const char *name, struct req_info *req_info) { struct set_req req; const char *type = "can"; memset(&req, 0, sizeof(req)); req.n.nlmsg_len = NLMSG_LENGTH(sizeof(struct ifinfomsg)); req.n.nlmsg_flags = NLM_F_REQUEST | NLM_F_ACK; req.n.nlmsg_type = RTM_NEWLINK; req.i.ifi_family = 0; req.i.ifi_index = if_nametoindex(name); if (req.i.ifi_index == 0) { fprintf(stderr, "Cannot find device \"%s\"\n", name); return -1; } if (if_state) { switch (if_state) { case IF_DOWN: req.i.ifi_change |= IFF_UP; req.i.ifi_flags &= ~IFF_UP; break; case IF_UP: req.i.ifi_change |= IFF_UP; req.i.ifi_flags |= IFF_UP; break; default: fprintf(stderr, "unknown state\n"); return -1; } } if (req_info != NULL) { /* setup linkinfo section */ struct rtattr *linkinfo = NLMSG_TAIL(&req.n); addattr_l(&req.n, sizeof(req), IFLA_LINKINFO, NULL, 0); addattr_l(&req.n, sizeof(req), IFLA_INFO_KIND, type, strlen(type)); /* setup data section */ struct rtattr *data = NLMSG_TAIL(&req.n); addattr_l(&req.n, sizeof(req), IFLA_INFO_DATA, NULL, 0); if (req_info->restart_ms > 0 || req_info->disable_autorestart) addattr32(&req.n, 1024, IFLA_CAN_RESTART_MS, req_info->restart_ms); if (req_info->restart) addattr32(&req.n, 1024, IFLA_CAN_RESTART, 1); if (req_info->bittiming != NULL) { addattr_l(&req.n, 1024, IFLA_CAN_BITTIMING, req_info->bittiming, sizeof(struct can_bittiming)); } if (req_info->ctrlmode != NULL) { addattr_l(&req.n, 1024, IFLA_CAN_CTRLMODE, req_info->ctrlmode, sizeof(struct can_ctrlmode)); } /* mark end of data section */ data->rta_len = (void *)NLMSG_TAIL(&req.n) - (void *)data; /* mark end of link info section */ linkinfo->rta_len = (void *)NLMSG_TAIL(&req.n) - (void *)linkinfo; } return send_mod_request(fd, &req.n); } /** * @ingroup intern * @brief set_link - open a netlink socket and setup linkinfo * * @param name name of the can device. This is the netdev name, as ifconfig -a * shows in your system. usually it contains prefix "can" and the numer of the * can line. e.g. "can0" * @param if_state state of the interface we want to put the device into. this * parameter is only set if you want to use the callback to driver up/down the * device * @param req_info request parameters * * This is a wrapper for do_set_nl_link. It opens a netlink socket and sends * down the requests. * * @return 0 if success * @return -1 if failed */ static int set_link(const char *name, __u8 if_state, struct req_info *req_info) { int err, fd; fd = open_nl_sock(); if (fd < 0) return -1; err = do_set_nl_link(fd, if_state, name, req_info); close(fd); return err; } /** * @ingroup extern * can_do_start - start the can interface * @param name name of the can device. This is the netdev name, as ifconfig -a shows * in your system. usually it contains prefix "can" and the numer of the can * line. e.g. "can0" * * This starts the can interface with the given name. It simply changes the if * state of the interface to up. All initialisation works will be done in * kernel. The if state can also be queried by a simple ifconfig. * * @return 0 if success * @return -1 if failed */ int can_do_start(const char *name) { return set_link(name, IF_UP, NULL); } /** * @ingroup extern * can_do_stop - stop the can interface * @param name name of the can device. This is the netdev name, as ifconfig -a shows * in your system. usually it contains prefix "can" and the numer of the can * line. e.g. "can0" * * This stops the can interface with the given name. It simply changes the if * state of the interface to down. Any running communication would be stopped. * * @return 0 if success * @return -1 if failed */ int can_do_stop(const char *name) { return set_link(name, IF_DOWN, NULL); } /** * @ingroup extern * can_do_restart - restart the can interface * @param name name of the can device. This is the netdev name, as ifconfig -a shows * in your system. usually it contains prefix "can" and the numer of the can * line. e.g. "can0" * * This triggers the start mode of the can device. * * NOTE: * - restart mode can only be triggerd if the device is in BUS_OFF and the auto * restart not turned on (restart_ms == 0) * * @return 0 if success * @return -1 if failed */ int can_do_restart(const char *name) { int state; __u32 restart_ms; /* first we check if we can restart the device at all */ if ((can_get_state(name, &state)) < 0) { fprintf(stderr, "cannot get bustate, " "something is seriously wrong\n"); return -1; } else if (state != CAN_STATE_BUS_OFF) { fprintf(stderr, "Device is not in BUS_OFF," " no use to restart\n"); return -1; } if ((can_get_restart_ms(name, &restart_ms)) < 0) { fprintf(stderr, "cannot get restart_ms, " "something is seriously wrong\n"); return -1; } else if (restart_ms > 0) { fprintf(stderr, "auto restart with %ums interval is turned on," " no use to restart\n", restart_ms); return -1; } struct req_info req_info = { .restart = 1, }; return set_link(name, 0, &req_info); } /** * @ingroup extern * can_set_restart_ms - set interval of auto restart. * * @param name name of the can device. This is the netdev name, as ifconfig -a shows * in your system. usually it contains prefix "can" and the numer of the can * line. e.g. "can0" * @param restart_ms interval of auto restart in milliseconds * * This sets how often the device shall automatically restart the interface in * case that a bus_off is detected. * * @return 0 if success * @return -1 if failed */ int can_set_restart_ms(const char *name, __u32 restart_ms) { struct req_info req_info = { .restart_ms = restart_ms, }; if (restart_ms == 0) req_info.disable_autorestart = 1; return set_link(name, 0, &req_info); } /** * @ingroup extern * can_set_ctrlmode - setup the control mode. * * @param name name of the can device. This is the netdev name, as ifconfig -a shows * in your system. usually it contains prefix "can" and the numer of the can * line. e.g. "can0" * * @param cm pointer of a can_ctrlmode struct * * This sets the control mode of the can device. There're currently three * different control modes: * - LOOPBACK * - LISTEN_ONLY * - TRIPPLE_SAMPLING * * You have to define the control mode struct yourself. a can_ctrlmode struct * is declared as: * * @code * struct can_ctrlmode { * __u32 mask; * __u32 flags; * } * @endcode * * You can use mask to select modes you want to control and flags to determine * if you want to turn the selected mode(s) on or off. Every control mode is * mapped to an own macro * * @code * #define CAN_CTRLMODE_LOOPBACK 0x1 * #define CAN_CTRLMODE_LISTENONLY 0x2 * #define CAN_CTRLMODE_3_SAMPLES 0x4 * @endcode * * e.g. the following pseudocode * * @code * struct can_ctrlmode cm; * memset(&cm, 0, sizeof(cm)); * cm.mask = CAN_CTRLMODE_LOOPBACK | CAN_CTRLMODE_LISTENONLY; * cm.flags = CAN_CTRLMODE_LOOPBACK; * can_set_ctrlmode(candev, &cm); * @endcode * * will turn the loopback mode on and listenonly mode off. * * @return 0 if success * @return -1 if failed */ int can_set_ctrlmode(const char *name, struct can_ctrlmode *cm) { struct req_info req_info = { .ctrlmode = cm, }; return set_link(name, 0, &req_info); } /** * @ingroup extern * can_set_bittiming - setup the bittiming. * * @param name name of the can device. This is the netdev name, as ifconfig -a shows * in your system. usually it contains prefix "can" and the numer of the can * line. e.g. "can0" * @param bt pointer to a can_bittiming struct * * This sets the bittiming of the can device. This is for advantage usage. In * normal cases you should use can_set_bitrate to simply define the bitrate and * let the driver automatically calculate the bittiming. You will only need this * function if you wish to define the bittiming in expert mode with fully * manually defined timing values. * You have to define the bittiming struct yourself. a can_bittiming struct * consists of: * * @code * struct can_bittiming { * __u32 bitrate; * __u32 sample_point; * __u32 tq; * __u32 prop_seg; * __u32 phase_seg1; * __u32 phase_seg2; * __u32 sjw; * __u32 brp; * } * @endcode * * to define a customized bittiming, you have to define tq, prop_seq, * phase_seg1, phase_seg2 and sjw. See http://www.can-cia.org/index.php?id=88 * for more information about bittiming and synchronizations on can bus. * * @return 0 if success * @return -1 if failed */ int can_set_bittiming(const char *name, struct can_bittiming *bt) { struct req_info req_info = { .bittiming = bt, }; return set_link(name, 0, &req_info); } /** * @ingroup extern * can_set_bitrate - setup the bitrate. * * @param name name of the can device. This is the netdev name, as ifconfig -a shows * in your system. usually it contains prefix "can" and the numer of the can * line. e.g. "can0" * @param bitrate bitrate of the can bus * * This is the recommended way to setup the bus bit timing. You only have to * give a bitrate value here. The exact bit timing will be calculated * automatically. To use this function, make sure that CONFIG_CAN_CALC_BITTIMING * is set to y in your kernel configuration. bitrate can be a value between * 1000(1kbit/s) and 1000000(1000kbit/s). * * @return 0 if success * @return -1 if failed */ int can_set_bitrate(const char *name, __u32 bitrate) { struct can_bittiming bt; memset(&bt, 0, sizeof(bt)); bt.bitrate = bitrate; return can_set_bittiming(name, &bt); } /** * @ingroup extern * can_set_bitrate_samplepoint - setup the bitrate. * * @param name name of the can device. This is the netdev name, as ifconfig -a shows * in your system. usually it contains prefix "can" and the numer of the can * line. e.g. "can0" * @param bitrate bitrate of the can bus * @param sample_point sample point value * * This one is similar to can_set_bitrate, only you can additionally set up the * time point for sampling (sample point) customly instead of using the * CIA recommended value. sample_point can be a value between 0 and 999. * * @return 0 if success * @return -1 if failed */ int can_set_bitrate_samplepoint(const char *name, __u32 bitrate, __u32 sample_point) { struct can_bittiming bt; memset(&bt, 0, sizeof(bt)); bt.bitrate = bitrate; bt.sample_point = sample_point; return can_set_bittiming(name, &bt); } /** * @ingroup extern * can_get_state - get the current state of the device * * @param name name of the can device. This is the netdev name, as ifconfig -a shows * in your system. usually it contains prefix "can" and the numer of the can * line. e.g. "can0" * @param state pointer to store the state * * This one stores the current state of the can interface into the given * pointer. Valid states are: * - CAN_STATE_ERROR_ACTIVE * - CAN_STATE_ERROR_WARNING * - CAN_STATE_ERROR_PASSIVE * - CAN_STATE_BUS_OFF * - CAN_STATE_STOPPED * - CAN_STATE_SLEEPING * * The first four states is determined by the value of RX/TX error counter. * Please see relevant can specification for more information about this. A * device in STATE_STOPPED is an inactive device. STATE_SLEEPING is not * implemented on all devices. * * @return 0 if success * @return -1 if failed */ int can_get_state(const char *name, int *state) { return get_link(name, GET_STATE, state); } /** * @ingroup extern * can_get_restart_ms - get the current interval of auto restarting. * * @param name name of the can device. This is the netdev name, as ifconfig -a shows * in your system. usually it contains prefix "can" and the numer of the can * line. e.g. "can0" * @param restart_ms pointer to store the value. * * This one stores the current interval of auto restarting into the given * pointer. * * The socketcan framework can automatically restart a device if it is in * bus_off in a given interval. This function gets this value in milliseconds. * restart_ms == 0 means that autorestarting is turned off. * * @return 0 if success * @return -1 if failed */ int can_get_restart_ms(const char *name, __u32 *restart_ms) { return get_link(name, GET_RESTART_MS, restart_ms); } /** * @ingroup extern * can_get_bittiming - get the current bittimnig configuration. * * @param name name of the can device. This is the netdev name, as ifconfig -a shows * in your system. usually it contains prefix "can" and the numer of the can * line. e.g. "can0" * @param bt pointer to the bittiming struct. * * This one stores the current bittiming configuration. * * Please see can_set_bittiming for more information about bit timing. * * @return 0 if success * @return -1 if failed */ int can_get_bittiming(const char *name, struct can_bittiming *bt) { return get_link(name, GET_BITTIMING, bt); } /** * @ingroup extern * can_get_ctrlmode - get the current control mode. * * @param name name of the can device. This is the netdev name, as ifconfig -a shows * in your system. usually it contains prefix "can" and the numer of the can * line. e.g. "can0" * @param cm pointer to the ctrlmode struct. * * This one stores the current control mode configuration. * * Please see can_set_ctrlmode for more information about control modes. * * @return 0 if success * @return -1 if failed */ int can_get_ctrlmode(const char *name, struct can_ctrlmode *cm) { return get_link(name, GET_CTRLMODE, cm); } /** * @ingroup extern * can_get_clock - get the current clock struct. * * @param name: name of the can device. This is the netdev name, as ifconfig -a shows * in your system. usually it contains prefix "can" and the numer of the can * line. e.g. "can0" * @param clock pointer to the clock struct. * * This one stores the current clock configuration. At the time of writing the * can_clock struct only contains information about the clock frequecy. This * information is e.g. essential while setting up the bit timing. * * @return 0 if success * @return -1 if failed */ int can_get_clock(const char *name, struct can_clock *clock) { return get_link(name, GET_CLOCK, clock); } /** * @ingroup extern * can_get_bittiming_const - get the current bittimnig constant. * * @param name name of the can device. This is the netdev name, as ifconfig -a shows * in your system. usually it contains prefix "can" and the numer of the can * line. e.g. "can0" * @param btc pointer to the bittiming constant struct. * * This one stores the hardware dependent bittiming constant. The * can_bittiming_const struct consists: * * @code * struct can_bittiming_const { * char name[16]; * __u32 tseg1_min; * __u32 tseg1_max; * __u32 tseg2_min; * __u32 tseg2_max; * __u32 sjw_max; * __u32 brp_min; * __u32 brp_max; * __u32 brp_inc; * }; * @endcode * * The information in this struct is used to calculate the bus bit timing * automatically. * * @return 0 if success * @return -1 if failed */ int can_get_bittiming_const(const char *name, struct can_bittiming_const *btc) { return get_link(name, GET_BITTIMING_CONST, btc); } /** * @ingroup extern * can_get_berr_counter - get the tx/rx error counter. * * @param name name of the can device. This is the netdev name, as ifconfig -a shows * in your system. usually it contains prefix "can" and the numer of the can * line. e.g. "can0" * @param bc pointer to the error counter struct.. * * This one gets the current rx/tx error counter from the hardware. * * @code * struct can_berr_counter { * __u16 txerr; * __u16 rxerr; * }; * @endcode * * @return 0 if success * @return -1 if failed */ int can_get_berr_counter(const char *name, struct can_berr_counter *bc) { return get_link(name, GET_BERR_COUNTER, bc); } /** * @ingroup extern * can_get_device_stats - get the can_device_stats. * * @param name name of the can device. This is the netdev name, as ifconfig -a shows * in your system. usually it contains prefix "can" and the numer of the can * line. e.g. "can0" * @param bc pointer to the error counter struct.. * * This one gets the current can_device_stats. * * Please see struct can_device_stats for more information. * * @return 0 if success * @return -1 if failed */ int can_get_device_stats(const char *name, struct can_device_stats *cds) { return get_link(name, GET_XSTATS, cds); } int main(int argc, char **argv) { struct can_frame frame; struct can_frame Rx_frame; struct ifreq ifr; struct sockaddr_can addr; int family = PF_CAN, type = SOCK_RAW, proto = CAN_RAW; int dlc = 8; int s[2], ret, i, rtr = 0, extended = 0; int j; int ret1; can_set_bitrate("can0", 500000); can_do_start("can0"); can_set_bitrate("can1", 500000); can_do_start("can1"); for(j = 0; j <= 1; j++) { if(j == 0) { strcpy(ifr.ifr_name, "can0"); } else if(j == 1) { strcpy(ifr.ifr_name, "can1"); } s[j] = socket(family, type, proto); if (s[j] < 0) { printf("ERROR"); return 1; } addr.can_family = family; if (ioctl(s[j], SIOCGIFINDEX, &ifr) < 0) { printf("ERROR"); return 1; } addr.can_ifindex = ifr.ifr_ifindex; if (bind(s[j], (struct sockaddr *)&addr, sizeof(addr)) < 0) { printf("ERROR"); return 1; } } for(i = 0; i < dlc; i++) { frame.data[i] = 0x31 + i; Rx_frame.data[i] = 0; } frame.can_id = 0x100; frame.can_dlc = dlc; if (extended) { frame.can_id &= CAN_EFF_MASK; frame.can_id |= CAN_EFF_FLAG; } else { frame.can_id &= CAN_SFF_MASK; } if (rtr) frame.can_id |= CAN_RTR_FLAG; printf("\n Please connect CAN0 and CAN1 to CAN bus\n"); printf("\n CAN0 transfer id: %d", frame.can_id); printf("\n CAN0 transfer dlc: %d", frame.can_dlc); printf("\n CAN0 transfer Data:\n"); for (i = 0; i < frame.can_dlc; i++) printf(" 0x%02x", frame.data[i]); printf("\n"); ret1 = 0; while(ret1 < sizeof(frame)) { ret = write(s[0], &frame, sizeof(frame)); if (ret == -1) { printf("write error !! \n"); } ret1 += ret; } ret1 = 0; while(ret1 < sizeof(Rx_frame)) { ret = read(s[1], &Rx_frame, sizeof(Rx_frame)); if (ret == -1) { printf("write error !! \n"); } ret1 += ret; } printf("\n CAN1 receive id = %d", Rx_frame.can_id); printf("\n CAN1 receive dlc = %d", Rx_frame.can_dlc); printf("\n CAN1 receive Data:\n"); for (i = 0; i < frame.can_dlc; i++) printf(" 0x%02x", Rx_frame.data[i]); printf("\n"); can_do_stop("can0"); can_do_stop("can1"); return 0; }
bool InitIMUCan() { const int bitrate = 1000000; const char* interface = "can0"; if (can_do_stop(interface) < 0) { Writelog(LOG_ERR, "Can't stop can", __FILE__, __LINE__); return false; } if (can_set_bitrate(interface, bitrate) < 0) { Writelog(LOG_ERR, "Set can bit rate fail.", __FILE__, __LINE__); return false; } if (can_do_start(interface) < 0) { Writelog(LOG_ERR, "Fail to start can.", __FILE__, __LINE__); return false; } if ((s = socket(PF_CAN, SOCK_RAW, CAN_RAW)) < 0) { Writelog(LOG_ERR, "Socket Fail.", __FILE__, __LINE__); return false; } struct ifreq ifr; strncpy(ifr.ifr_name, interface, sizeof(ifr.ifr_name)); if (ioctl(s, SIOCGIFINDEX, &ifr)) { Writelog(LOG_ERR, "ioctl fail.", __FILE__, __LINE__); return false; } struct sockaddr_can addr; addr.can_family = PF_CAN; addr.can_ifindex = ifr.ifr_ifindex; if (bind(s, (struct sockaddr *)&addr, sizeof(addr)) < 0) { Writelog(LOG_ERR, "bind socket fail.", __FILE__, __LINE__); return false; } P_IMU_DATA = new char[(MAX_IMU_NUM + 1) * sizeof(imu_body)]; if (NULL == P_IMU_DATA) { return false; } memset(P_IMU_DATA, 0, (MAX_IMU_NUM + 1) * sizeof(imu_body)); begin_pos = 0; end_pos = MAX_IMU_NUM * sizeof(imu_body); fetch_pos = -1; store_pos = 0; return true; }