/****************************************************************************** L I B R M N E T C T L . C Copyright (c) 2013-2014, The Linux Foundation. All rights reserved. Redistribution and use in source and binary forms, with or without modification, are permitted provided that the following conditions are met: * Redistributions of source code must retain the above copyright notice, this list of conditions and the following disclaimer. * 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. * Neither the name of The Linux Foundation nor the names of its contributors may be used to endorse or promote products derived from this software without specific prior written permission. THIS SOFTWARE IS PROVIDED "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE AND NON-INFRINGEMENT ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT OWNER OR CONTRIBUTORS 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. ******************************************************************************/ /*! * @file librmnetctl.c * @brief rmnet control API's implentations file */ /*=========================================================================== INCLUDE FILES ===========================================================================*/ #include #include #include #include #include #include #include #include #include "librmnetctl_hndl.h" #include "librmnetctl.h" #ifdef USE_GLIB #include #define strlcpy g_strlcpy #endif #define RMNETCTL_SOCK_FLAG 0 #define ROOT_USER_ID 0 #define MIN_VALID_PROCESS_ID 0 #define MIN_VALID_SOCKET_FD 0 #define KERNEL_PROCESS_ID 0 #define UNICAST 0 #define MAX_BUF_SIZE sizeof(struct nlmsghdr) + sizeof(struct rmnet_nl_msg_s) #define INGRESS_FLAGS_MASK (RMNET_INGRESS_FIX_ETHERNET | \ RMNET_INGRESS_FORMAT_MAP | \ RMNET_INGRESS_FORMAT_DEAGGREGATION | \ RMNET_INGRESS_FORMAT_DEMUXING | \ RMNET_INGRESS_FORMAT_MAP_COMMANDS | \ RMNET_INGRESS_FORMAT_MAP_CKSUMV3) #define EGRESS_FLAGS_MASK (RMNET_EGRESS_FORMAT__RESERVED__ | \ RMNET_EGRESS_FORMAT_MAP | \ RMNET_EGRESS_FORMAT_AGGREGATION | \ RMNET_EGRESS_FORMAT_MUXING | \ RMNET_EGRESS_FORMAT_MAP_CKSUMV3) #define min(a, b) (((a) < (b)) ? (a) : (b)) /*=========================================================================== LOCAL FUNCTION DEFINITIONS ===========================================================================*/ /*! * @brief Synchronous method to send and receive messages to and from the kernel * using netlink sockets * @details Increments the transaction id for each message sent to the kernel. * Sends the netlink message to the kernel and receives the response from the * kernel. * @param *hndl RmNet handle for this transaction * @param request Message to be sent to the kernel * @param response Message received from the kernel * @return RMNETCTL_API_SUCCESS if successfully able to send and receive message * from the kernel * @return RMNETCTL_API_ERR_HNDL_INVALID if RmNet handle for the transaction was * NULL * @return RMNETCTL_API_ERR_REQUEST_NULL not enough memory to create buffer for * sending the message * @return RMNETCTL_API_ERR_MESSAGE_SEND if could not send the message to kernel * @return RMNETCTL_API_ERR_MESSAGE_RECEIVE if could not receive message from the * kernel * @return RMNETCTL_API_ERR_MESSAGE_TYPE if the request and response type do not * match */ static uint16_t rmnetctl_transact(rmnetctl_hndl_t *hndl, struct rmnet_nl_msg_s *request, struct rmnet_nl_msg_s *response) { uint8_t *request_buf, *response_buf; struct nlmsghdr *nlmsghdr_val; struct rmnet_nl_msg_s *rmnet_nl_msg_s_val; ssize_t bytes_read = -1; uint16_t return_code = RMNETCTL_API_ERR_HNDL_INVALID; struct sockaddr_nl* __attribute__((__may_alias__)) saddr_ptr; request_buf = NULL; response_buf = NULL; nlmsghdr_val = NULL; rmnet_nl_msg_s_val = NULL; do { if (!hndl){ break; } if (!request){ return_code = RMNETCTL_API_ERR_REQUEST_NULL; break; } if (!response){ return_code = RMNETCTL_API_ERR_RESPONSE_NULL; break; } request_buf = (uint8_t *)malloc(MAX_BUF_SIZE * sizeof(uint8_t)); if (!request_buf){ return_code = RMNETCTL_API_ERR_REQUEST_NULL; break; } response_buf = (uint8_t *)malloc(MAX_BUF_SIZE * sizeof(uint8_t)); if (!response_buf) { free(request_buf); return_code = RMNETCTL_API_ERR_RESPONSE_NULL; break; } nlmsghdr_val = (struct nlmsghdr *)request_buf; rmnet_nl_msg_s_val = (struct rmnet_nl_msg_s *)NLMSG_DATA(request_buf); memset(request_buf, 0, MAX_BUF_SIZE*sizeof(uint8_t)); memset(response_buf, 0, MAX_BUF_SIZE*sizeof(uint8_t)); nlmsghdr_val->nlmsg_seq = hndl->transaction_id; nlmsghdr_val->nlmsg_pid = hndl->pid; nlmsghdr_val->nlmsg_len = MAX_BUF_SIZE; memcpy((void *)NLMSG_DATA(request_buf), request, sizeof(struct rmnet_nl_msg_s)); rmnet_nl_msg_s_val->crd = RMNET_NETLINK_MSG_COMMAND; hndl->transaction_id++; saddr_ptr = &hndl->dest_addr; socklen_t addrlen = sizeof(struct sockaddr_nl); if (sendto(hndl->netlink_fd, request_buf, MAX_BUF_SIZE, RMNETCTL_SOCK_FLAG, (struct sockaddr*)saddr_ptr, sizeof(struct sockaddr_nl)) < 0) { return_code = RMNETCTL_API_ERR_MESSAGE_SEND; free(request_buf); free(response_buf); break; } saddr_ptr = &hndl->src_addr; bytes_read = recvfrom(hndl->netlink_fd, response_buf, MAX_BUF_SIZE, RMNETCTL_SOCK_FLAG, (struct sockaddr*)saddr_ptr, &addrlen); if (bytes_read < 0) { return_code = RMNETCTL_API_ERR_MESSAGE_RECEIVE; free(request_buf); free(response_buf); break; } memcpy(response, (void *)NLMSG_DATA(response_buf), sizeof(struct rmnet_nl_msg_s)); if (sizeof(*response) < sizeof(struct rmnet_nl_msg_s)) { return_code = RMNETCTL_API_ERR_RESPONSE_NULL; free(request_buf); free(response_buf); break; } if (request->message_type != response->message_type) { return_code = RMNETCTL_API_ERR_MESSAGE_TYPE; free(request_buf); free(response_buf); break; } return_code = RMNETCTL_SUCCESS; } while(0); free(request_buf); free(response_buf); return return_code; } /*! * @brief Static function to check the dev name * @details Checks if the name is not NULL and if the name is less than the * RMNET_MAX_STR_LEN * @param dev_name Name of the device * @return RMNETCTL_SUCCESS if successful * @return RMNETCTL_INVALID_ARG if invalid arguments were passed to the API */ static inline int _rmnetctl_check_dev_name(const char *dev_name) { int return_code = RMNETCTL_INVALID_ARG; do { if (!dev_name) break; if (strlen(dev_name) >= RMNET_MAX_STR_LEN) break; return_code = RMNETCTL_SUCCESS; } while(0); return return_code; } /*! * @brief Static function to check the string length after a copy * @details Checks if the string length is not lesser than zero and lesser than * RMNET_MAX_STR_LEN * @param str_len length of the string after a copy * @param error_code Status code of this operation * @return RMNETCTL_SUCCESS if successful * @return RMNETCTL_LIB_ERR if there was a library error. Check error_code */ static inline int _rmnetctl_check_len(size_t str_len, uint16_t *error_code) { int return_code = RMNETCTL_LIB_ERR; do { if (str_len > RMNET_MAX_STR_LEN) { *error_code = RMNETCTL_API_ERR_STRING_TRUNCATION; break; } return_code = RMNETCTL_SUCCESS; } while(0); return return_code; } /*! * @brief Static function to check the response type * @details Checks if the response type of this message was return code * @param crd The crd field passed * @param error_code Status code of this operation * @return RMNETCTL_SUCCESS if successful * @return RMNETCTL_LIB_ERR if there was a library error. Check error_code */ static inline int _rmnetctl_check_code(int crd, uint16_t *error_code) { int return_code = RMNETCTL_LIB_ERR; do { if (crd != RMNET_NETLINK_MSG_RETURNCODE) { *error_code = RMNETCTL_API_ERR_RETURN_TYPE; break; } return_code = RMNETCTL_SUCCESS; } while(0); return return_code; } /*! * @brief Static function to check the response type * @details Checks if the response type of this message was data * @param crd The crd field passed * @param error_code Status code of this operation * @return RMNETCTL_SUCCESS if successful * @return RMNETCTL_LIB_ERR if there was a library error. Check error_code */ static inline int _rmnetctl_check_data(int crd, uint16_t *error_code) { int return_code = RMNETCTL_LIB_ERR; do { if (crd != RMNET_NETLINK_MSG_RETURNDATA) { *error_code = RMNETCTL_API_ERR_RETURN_TYPE; break; } return_code = RMNETCTL_SUCCESS; } while(0); return return_code; } /*! * @brief Static function to set the return value * @details Checks if the error_code from the transaction is zero for a return * code type message and sets the message type as RMNETCTL_SUCCESS * @param crd The crd field passed * @param error_code Status code of this operation * @return RMNETCTL_SUCCESS if successful * @return RMNETCTL_KERNEL_ERR if there was an error in the kernel. * Check error_code */ static inline int _rmnetctl_set_codes(int error_val, uint16_t *error_code) { int return_code = RMNETCTL_KERNEL_ERR; if (error_val == RMNET_CONFIG_OK) return_code = RMNETCTL_SUCCESS; else *error_code = (uint16_t)error_val + RMNETCTL_KERNEL_FIRST_ERR; return return_code; } /*=========================================================================== EXPOSED API ===========================================================================*/ int rmnetctl_init(rmnetctl_hndl_t **hndl, uint16_t *error_code) { pid_t pid = 0; int netlink_fd = -1, return_code = RMNETCTL_LIB_ERR; struct sockaddr_nl* __attribute__((__may_alias__)) saddr_ptr; do { if ((!hndl) || (!error_code)){ return_code = RMNETCTL_INVALID_ARG; break; } *hndl = (rmnetctl_hndl_t *)malloc(sizeof(rmnetctl_hndl_t)); if (!*hndl) { *error_code = RMNETCTL_API_ERR_HNDL_INVALID; break; } memset(*hndl, 0, sizeof(rmnetctl_hndl_t)); pid = getpid(); if (pid < MIN_VALID_PROCESS_ID) { free(*hndl); *error_code = RMNETCTL_INIT_ERR_PROCESS_ID; break; } (*hndl)->pid = (uint32_t)pid; netlink_fd = socket(PF_NETLINK, SOCK_RAW, RMNET_NETLINK_PROTO); if (netlink_fd < MIN_VALID_SOCKET_FD) { free(*hndl); *error_code = RMNETCTL_INIT_ERR_NETLINK_FD; break; } (*hndl)->netlink_fd = netlink_fd; memset(&(*hndl)->src_addr, 0, sizeof(struct sockaddr_nl)); (*hndl)->src_addr.nl_family = AF_NETLINK; (*hndl)->src_addr.nl_pid = (*hndl)->pid; saddr_ptr = &(*hndl)->src_addr; if (bind((*hndl)->netlink_fd, (struct sockaddr*)saddr_ptr, sizeof(struct sockaddr_nl)) < 0) { close((*hndl)->netlink_fd); free(*hndl); *error_code = RMNETCTL_INIT_ERR_BIND; break; } memset(&(*hndl)->dest_addr, 0, sizeof(struct sockaddr_nl)); (*hndl)->dest_addr.nl_family = AF_NETLINK; (*hndl)->dest_addr.nl_pid = KERNEL_PROCESS_ID; (*hndl)->dest_addr.nl_groups = UNICAST; return_code = RMNETCTL_SUCCESS; } while(0); return return_code; } void rmnetctl_cleanup(rmnetctl_hndl_t *hndl) { if (!hndl) return; close(hndl->netlink_fd); free(hndl); } int rmnet_associate_network_device(rmnetctl_hndl_t *hndl, const char *dev_name, uint16_t *error_code, uint8_t assoc_dev) { struct rmnet_nl_msg_s request, response; size_t str_len = 0; int return_code = RMNETCTL_LIB_ERR; do { if ((!hndl) || (!error_code) || _rmnetctl_check_dev_name(dev_name) || ((assoc_dev != RMNETCTL_DEVICE_ASSOCIATE) && (assoc_dev != RMNETCTL_DEVICE_UNASSOCIATE))) { return_code = RMNETCTL_INVALID_ARG; break; } if (assoc_dev == RMNETCTL_DEVICE_ASSOCIATE) request.message_type = RMNET_NETLINK_ASSOCIATE_NETWORK_DEVICE; else request.message_type = RMNET_NETLINK_UNASSOCIATE_NETWORK_DEVICE; request.arg_length = RMNET_MAX_STR_LEN; str_len = strlcpy((char *)(request.data), dev_name, (size_t)RMNET_MAX_STR_LEN); if (_rmnetctl_check_len(str_len, error_code) != RMNETCTL_SUCCESS) break; if ((*error_code = rmnetctl_transact(hndl, &request, &response)) != RMNETCTL_SUCCESS) break; if (_rmnetctl_check_code(response.crd, error_code) != RMNETCTL_SUCCESS) break; return_code = _rmnetctl_set_codes(response.return_code, error_code); } while(0); return return_code; } int rmnet_get_network_device_associated(rmnetctl_hndl_t *hndl, const char *dev_name, int *register_status, uint16_t *error_code) { struct rmnet_nl_msg_s request, response; size_t str_len = 0; int return_code = RMNETCTL_LIB_ERR; do { if ((!hndl) || (!register_status) || (!error_code) || _rmnetctl_check_dev_name(dev_name)) { return_code = RMNETCTL_INVALID_ARG; break; } request.message_type = RMNET_NETLINK_GET_NETWORK_DEVICE_ASSOCIATED; request.arg_length = RMNET_MAX_STR_LEN; str_len = strlcpy((char *)(request.data), dev_name, RMNET_MAX_STR_LEN); if (_rmnetctl_check_len(str_len, error_code) != RMNETCTL_SUCCESS) break; if ((*error_code = rmnetctl_transact(hndl, &request, &response)) != RMNETCTL_SUCCESS) break; if (_rmnetctl_check_data(response.crd, error_code) != RMNETCTL_SUCCESS) break; *register_status = response.return_code; return_code = RMNETCTL_SUCCESS; } while(0); return return_code; } int rmnet_set_link_egress_data_format(rmnetctl_hndl_t *hndl, uint32_t egress_flags, uint16_t agg_size, uint16_t agg_count, const char *dev_name, uint16_t *error_code) { struct rmnet_nl_msg_s request, response; size_t str_len = 0; int return_code = RMNETCTL_LIB_ERR; do { if ((!hndl) || (!error_code) || _rmnetctl_check_dev_name(dev_name) || ((~EGRESS_FLAGS_MASK) & egress_flags)) { return_code = RMNETCTL_INVALID_ARG; break; } request.message_type = RMNET_NETLINK_SET_LINK_EGRESS_DATA_FORMAT; request.arg_length = RMNET_MAX_STR_LEN + sizeof(uint32_t) + sizeof(uint16_t) + sizeof(uint16_t); str_len = strlcpy((char *)(request.data_format.dev), dev_name, RMNET_MAX_STR_LEN); if (_rmnetctl_check_len(str_len, error_code) != RMNETCTL_SUCCESS) break; request.data_format.flags = egress_flags; request.data_format.agg_size = agg_size; request.data_format.agg_count = agg_count; if ((*error_code = rmnetctl_transact(hndl, &request, &response)) != RMNETCTL_SUCCESS) break; if (_rmnetctl_check_code(response.crd, error_code) != RMNETCTL_SUCCESS) break; return_code = _rmnetctl_set_codes(response.return_code, error_code); } while(0); return return_code; } int rmnet_get_link_egress_data_format(rmnetctl_hndl_t *hndl, const char *dev_name, uint32_t *egress_flags, uint16_t *agg_size, uint16_t *agg_count, uint16_t *error_code) { struct rmnet_nl_msg_s request, response; size_t str_len = 0; int return_code = RMNETCTL_LIB_ERR; do { if ((!hndl) || (!egress_flags) || (!agg_size) || (!agg_count) || (!error_code) || _rmnetctl_check_dev_name(dev_name)) { return_code = RMNETCTL_INVALID_ARG; break; } request.message_type = RMNET_NETLINK_GET_LINK_EGRESS_DATA_FORMAT; request.arg_length = RMNET_MAX_STR_LEN; str_len = strlcpy((char *)(request.data_format.dev), dev_name, RMNET_MAX_STR_LEN); if (_rmnetctl_check_len(str_len, error_code) != RMNETCTL_SUCCESS) break; if ((*error_code = rmnetctl_transact(hndl, &request, &response)) != RMNETCTL_SUCCESS) break; if (_rmnetctl_check_data(response.crd, error_code) != RMNETCTL_SUCCESS) break; *egress_flags = response.data_format.flags; *agg_size = response.data_format.agg_size; *agg_count = response.data_format.agg_count; return_code = RMNETCTL_SUCCESS; } while(0); return return_code; } int rmnet_set_link_ingress_data_format_tailspace(rmnetctl_hndl_t *hndl, uint32_t ingress_flags, uint8_t tail_spacing, const char *dev_name, uint16_t *error_code) { struct rmnet_nl_msg_s request, response; size_t str_len = 0; int return_code = RMNETCTL_LIB_ERR; do { if ((!hndl) || (!error_code) || _rmnetctl_check_dev_name(dev_name) || ((~INGRESS_FLAGS_MASK) & ingress_flags)) { return_code = RMNETCTL_INVALID_ARG; break; } request.message_type = RMNET_NETLINK_SET_LINK_INGRESS_DATA_FORMAT; request.arg_length = RMNET_MAX_STR_LEN + sizeof(uint32_t) + sizeof(uint16_t) + sizeof(uint16_t); str_len = strlcpy((char *)(request.data_format.dev), dev_name, RMNET_MAX_STR_LEN); if (_rmnetctl_check_len(str_len, error_code) != RMNETCTL_SUCCESS) break; request.data_format.flags = ingress_flags; request.data_format.tail_spacing = tail_spacing; if ((*error_code = rmnetctl_transact(hndl, &request, &response)) != RMNETCTL_SUCCESS) break; if (_rmnetctl_check_code(response.crd, error_code) != RMNETCTL_SUCCESS) break; return_code = _rmnetctl_set_codes(response.return_code, error_code); } while(0); return return_code; } int rmnet_get_link_ingress_data_format_tailspace(rmnetctl_hndl_t *hndl, const char *dev_name, uint32_t *ingress_flags, uint8_t *tail_spacing, uint16_t *error_code) { struct rmnet_nl_msg_s request, response; size_t str_len = 0; int return_code = RMNETCTL_LIB_ERR; do { if ((!hndl) || (!error_code) || _rmnetctl_check_dev_name(dev_name)) { return_code = RMNETCTL_INVALID_ARG; break; } request.message_type = RMNET_NETLINK_GET_LINK_INGRESS_DATA_FORMAT; request.arg_length = RMNET_MAX_STR_LEN; str_len = strlcpy((char *)(request.data_format.dev), dev_name, RMNET_MAX_STR_LEN); if (_rmnetctl_check_len(str_len, error_code) != RMNETCTL_SUCCESS) break; if ((*error_code = rmnetctl_transact(hndl, &request, &response)) != RMNETCTL_SUCCESS) break; if (_rmnetctl_check_data(response.crd, error_code) != RMNETCTL_SUCCESS) break; if (ingress_flags) *ingress_flags = response.data_format.flags; if (tail_spacing) *tail_spacing = response.data_format.tail_spacing; return_code = RMNETCTL_SUCCESS; } while(0); return return_code; } int rmnet_set_logical_ep_config(rmnetctl_hndl_t *hndl, int32_t ep_id, uint8_t operating_mode, const char *dev_name, const char *next_dev, uint16_t *error_code) { struct rmnet_nl_msg_s request, response; size_t str_len = 0; int return_code = RMNETCTL_LIB_ERR; do { if ((!hndl) || ((ep_id < -1) || (ep_id > 31)) || (!error_code) || _rmnetctl_check_dev_name(dev_name) || _rmnetctl_check_dev_name(next_dev) || operating_mode >= RMNET_EPMODE_LENGTH) { return_code = RMNETCTL_INVALID_ARG; break; } request.message_type = RMNET_NETLINK_SET_LOGICAL_EP_CONFIG; request.arg_length = RMNET_MAX_STR_LEN + RMNET_MAX_STR_LEN + sizeof(int32_t) + sizeof(uint8_t); str_len = strlcpy((char *)(request.local_ep_config.dev), dev_name, RMNET_MAX_STR_LEN); if (_rmnetctl_check_len(str_len, error_code) != RMNETCTL_SUCCESS) break; str_len = strlcpy((char *)(request.local_ep_config.next_dev), next_dev, RMNET_MAX_STR_LEN); if (_rmnetctl_check_len(str_len, error_code) != RMNETCTL_SUCCESS) break; request.local_ep_config.ep_id = ep_id; request.local_ep_config.operating_mode = operating_mode; if ((*error_code = rmnetctl_transact(hndl, &request, &response)) != RMNETCTL_SUCCESS) break; if (_rmnetctl_check_code(response.crd, error_code) != RMNETCTL_SUCCESS) break; return_code = _rmnetctl_set_codes(response.return_code, error_code); } while(0); return return_code; } int rmnet_unset_logical_ep_config(rmnetctl_hndl_t *hndl, int32_t ep_id, const char *dev_name, uint16_t *error_code) { struct rmnet_nl_msg_s request, response; size_t str_len = 0; int return_code = RMNETCTL_LIB_ERR; do { if ((!hndl) || ((ep_id < -1) || (ep_id > 31)) || (!error_code) || _rmnetctl_check_dev_name(dev_name)) { return_code = RMNETCTL_INVALID_ARG; break; } request.message_type = RMNET_NETLINK_UNSET_LOGICAL_EP_CONFIG; request.arg_length = RMNET_MAX_STR_LEN + sizeof(int32_t); str_len = strlcpy((char *)(request.local_ep_config.dev), dev_name, RMNET_MAX_STR_LEN); if (_rmnetctl_check_len(str_len, error_code) != RMNETCTL_SUCCESS) break; request.local_ep_config.ep_id = ep_id; if ((*error_code = rmnetctl_transact(hndl, &request, &response)) != RMNETCTL_SUCCESS) break; if (_rmnetctl_check_code(response.crd, error_code) != RMNETCTL_SUCCESS) break; return_code = _rmnetctl_set_codes(response.return_code, error_code); } while(0); return return_code; } int rmnet_get_logical_ep_config(rmnetctl_hndl_t *hndl, int32_t ep_id, const char *dev_name, uint8_t *operating_mode, char **next_dev, uint32_t next_dev_len, uint16_t *error_code) { struct rmnet_nl_msg_s request, response; size_t str_len = 0; int return_code = RMNETCTL_LIB_ERR; do { if ((!hndl) || (!operating_mode) || (!error_code) || ((ep_id < -1) || (ep_id > 31)) || _rmnetctl_check_dev_name(dev_name) || (!next_dev) || (0 == next_dev_len)) { return_code = RMNETCTL_INVALID_ARG; break; } request.message_type = RMNET_NETLINK_GET_LOGICAL_EP_CONFIG; request.arg_length = RMNET_MAX_STR_LEN + sizeof(int32_t); str_len = strlcpy((char *)(request.local_ep_config.dev), dev_name, RMNET_MAX_STR_LEN); if (_rmnetctl_check_len(str_len, error_code) != RMNETCTL_SUCCESS) break; request.local_ep_config.ep_id = ep_id; if ((*error_code = rmnetctl_transact(hndl, &request, &response)) != RMNETCTL_SUCCESS) break; if (_rmnetctl_check_data(response.crd, error_code) != RMNETCTL_SUCCESS) break; str_len = strlcpy(*next_dev, (char *)(response.local_ep_config.next_dev), min(RMNET_MAX_STR_LEN, next_dev_len)); if (_rmnetctl_check_len(str_len, error_code) != RMNETCTL_SUCCESS) break; *operating_mode = response.local_ep_config.operating_mode; return_code = RMNETCTL_SUCCESS; } while(0); return return_code; } int rmnet_new_vnd_prefix(rmnetctl_hndl_t *hndl, uint32_t id, uint16_t *error_code, uint8_t new_vnd, const char *prefix) { struct rmnet_nl_msg_s request, response; int return_code = RMNETCTL_LIB_ERR; size_t str_len = 0; do { if ((!hndl) || (!error_code) || ((new_vnd != RMNETCTL_NEW_VND) && (new_vnd != RMNETCTL_FREE_VND))) { return_code = RMNETCTL_INVALID_ARG; break; } memset(request.vnd.vnd_name, 0, RMNET_MAX_STR_LEN); if (new_vnd == RMNETCTL_NEW_VND) { if (prefix) { request.message_type =RMNET_NETLINK_NEW_VND_WITH_PREFIX; str_len = strlcpy((char *)request.vnd.vnd_name, prefix, RMNET_MAX_STR_LEN); if (_rmnetctl_check_len(str_len, error_code) != RMNETCTL_SUCCESS) break; } else { request.message_type = RMNET_NETLINK_NEW_VND; } } else { request.message_type = RMNET_NETLINK_FREE_VND; } request.arg_length = sizeof(uint32_t); request.vnd.id = id; if ((*error_code = rmnetctl_transact(hndl, &request, &response)) != RMNETCTL_SUCCESS) break; if (_rmnetctl_check_code(response.crd, error_code) != RMNETCTL_SUCCESS) break; return_code = _rmnetctl_set_codes(response.return_code, error_code); } while(0); return return_code; } int rmnet_new_vnd(rmnetctl_hndl_t *hndl, uint32_t id, uint16_t *error_code, uint8_t new_vnd) { return rmnet_new_vnd_prefix(hndl, id, error_code, new_vnd, 0); } int rmnet_get_vnd_name(rmnetctl_hndl_t *hndl, uint32_t id, uint16_t *error_code, char *buf, uint32_t buflen) { struct rmnet_nl_msg_s request, response; uint32_t str_len; int return_code = RMNETCTL_LIB_ERR; do { if ((!hndl) || (!error_code) || (!buf) || (0 == buflen)) { return_code = RMNETCTL_INVALID_ARG; break; } request.message_type = RMNET_NETLINK_GET_VND_NAME; request.arg_length = sizeof(uint32_t); request.vnd.id = id; if ((*error_code = rmnetctl_transact(hndl, &request, &response)) != RMNETCTL_SUCCESS) break; if (_rmnetctl_check_data(response.crd, error_code) != RMNETCTL_SUCCESS) break; str_len = (uint32_t)strlcpy(buf, (char *)(response.vnd.vnd_name), buflen); if (str_len >= buflen) { *error_code = RMNETCTL_API_ERR_STRING_TRUNCATION; break; } return_code = RMNETCTL_SUCCESS; } while (0); return return_code; } int rmnet_add_del_vnd_tc_flow(rmnetctl_hndl_t *hndl, uint32_t id, uint32_t map_flow_id, uint32_t tc_flow_id, uint8_t set_flow, uint16_t *error_code) { struct rmnet_nl_msg_s request, response; int return_code = RMNETCTL_LIB_ERR; do { if ((!hndl) || (!error_code) || ((set_flow != RMNETCTL_ADD_FLOW) && (set_flow != RMNETCTL_DEL_FLOW))) { return_code = RMNETCTL_INVALID_ARG; break; } if (set_flow == RMNETCTL_ADD_FLOW) request.message_type = RMNET_NETLINK_ADD_VND_TC_FLOW; else request.message_type = RMNET_NETLINK_DEL_VND_TC_FLOW; request.arg_length = (sizeof(uint32_t))*3; request.flow_control.id = id; request.flow_control.map_flow_id = map_flow_id; request.flow_control.tc_flow_id = tc_flow_id; if ((*error_code = rmnetctl_transact(hndl, &request, &response)) != RMNETCTL_SUCCESS) break; if (_rmnetctl_check_code(response.crd, error_code) != RMNETCTL_SUCCESS) break; return_code = _rmnetctl_set_codes(response.return_code, error_code); } while(0); return return_code; }