#include "dhcps.h" #include "tcpip.h" //static struct dhcp_server_state dhcp_server_state_machine; static uint8_t dhcp_server_state_machine = DHCP_SERVER_STATE_IDLE; /* recorded the client MAC addr(default sudo mac) */ //static uint8_t dhcps_record_first_client_mac[6] = {0xff,0xff,0xff,0xff,0xff,0xff}; /* recorded transaction ID (default sudo id)*/ static uint8_t dhcp_recorded_xid[4] = {0xff, 0xff, 0xff, 0xff}; /* UDP Protocol Control Block(PCB) */ static struct udp_pcb *dhcps_pcb; static struct ip_addr dhcps_send_broadcast_address; static struct ip_addr dhcps_local_address; static struct ip_addr dhcps_local_mask; static struct ip_addr dhcps_local_gateway; static struct ip_addr dhcps_network_id; static struct ip_addr dhcps_subnet_broadcast; static struct ip_addr dhcps_allocated_client_address; static int dhcps_addr_pool_set = 0; static struct ip_addr dhcps_addr_pool_start; static struct ip_addr dhcps_addr_pool_end; #if 0 static struct ip_addr dhcps_owned_first_ip; static struct ip_addr dhcps_owned_last_ip; static uint8_t dhcps_num_of_available_ips; #endif static struct dhcp_msg *dhcp_message_repository; static int dhcp_message_total_options_lenth; /* allocated IP range */ static struct table ip_table; static struct ip_addr client_request_ip; static uint8_t dhcp_client_ethernet_address[16]; static uint8_t bound_client_ethernet_address[16]; static xSemaphoreHandle dhcps_ip_table_semaphore; static struct netif * dhcps_netif = NULL; /** * @brief latch the specific ip in the ip table. * @param d the specific index * @retval None. */ #if (!IS_USE_FIXED_IP) static void mark_ip_in_table(uint8_t d) { #if (debug_dhcps) printf(" mark ip %d",d); #endif xSemaphoreTake(dhcps_ip_table_semaphore, portMAX_DELAY); if (0 < d && d <= 32) { ip_table.ip_range[0] = MARK_RANGE1_IP_BIT(ip_table, d); #if (debug_dhcps) printf(" ip_table.ip_range[0] = 0x%x",ip_table.ip_range[0]); #endif } else if (32 < d && d <= 64) { ip_table.ip_range[1] = MARK_RANGE2_IP_BIT(ip_table, (d - 32)); #if (debug_dhcps) printf(" ip_table.ip_range[1] = 0x%x",ip_table.ip_range[1]); #endif } else if (64 < d && d <= 96) { ip_table.ip_range[2] = MARK_RANGE3_IP_BIT(ip_table, (d - 64)); #if (debug_dhcps) printf(" ip_table.ip_range[2] = 0x%x",ip_table.ip_range[2]); #endif } else if (96 < d && d <= 128) { ip_table.ip_range[3] = MARK_RANGE4_IP_BIT(ip_table, (d - 96)); #if (debug_dhcps) printf(" ip_table.ip_range[3] = 0x%x",ip_table.ip_range[3]); #endif } else { #if (DHCPS_IP_RANGE_FROM_1_to_255) if (128 < d && d <= 160) { ip_table.ip_range[4] = MARK_RANGE5_IP_BIT(ip_table, d); #if (debug_dhcps) printf(" ip_table.ip_range[4] = 0x%x",ip_table.ip_range[4]); #endif } else if (160 < d && d <= 192) { ip_table.ip_range[5] = MARK_RANGE6_IP_BIT(ip_table, (d - 160)); #if (debug_dhcps) printf(" ip_table.ip_range[5] = 0x%x",ip_table.ip_range[5]); #endif } else if (192 < d && d <= 224) { ip_table.ip_range[6] = MARK_RANGE7_IP_BIT(ip_table, (d - 192)); #if (debug_dhcps) printf(" ip_table.ip_range[6] = 0x%x",ip_table.ip_range[6]); #endif } else if (224 < d) { ip_table.ip_range[7] = MARK_RANGE8_IP_BIT(ip_table, (d - 224)); #if (debug_dhcps) printf(" ip_table.ip_range[7] = 0x%x",ip_table.ip_range[7]); #endif } #else printf(" Request ip over the range(1-128) "); #endif } xSemaphoreGive(dhcps_ip_table_semaphore); } #endif /** * @brief get one usable ip from the ip table of dhcp server. * @param: None * @retval the usable index which represent the ip4_addr(ip) of allocated ip addr. */ #if (!IS_USE_FIXED_IP) static uint8_t search_next_ip(void) { uint8_t range_count, offset_count; uint8_t start, end; uint8_t max_count; if(dhcps_addr_pool_set){ start = (uint8_t)ip4_addr4(&dhcps_addr_pool_start); end = (uint8_t)ip4_addr4(&dhcps_addr_pool_end); }else{ start = 0; end = 255; } xSemaphoreTake(dhcps_ip_table_semaphore, portMAX_DELAY); for (range_count = 0; range_count < (max_count = (DHCPS_IP_RANGE_FROM_1_to_255 > 0 ? 8 : 4)); range_count++) { for (offset_count = 0;offset_count < 32; offset_count++) { if ((((ip_table.ip_range[range_count] >> offset_count) & 0x01) == 0) &&(((range_count * 32) + (offset_count + 1)) >= start) &&(((range_count * 32) + (offset_count + 1)) <= end)) { xSemaphoreGive(dhcps_ip_table_semaphore); return ((range_count * 32) + (offset_count + 1)); } } } xSemaphoreGive(dhcps_ip_table_semaphore); return 0; } #endif /** * @brief fill in the option field with message type of a dhcp message. * @param msg_option_base_addr: the addr be filled start. * message_type: the type code you want to fill in * @retval the start addr of the next dhcp option. */ static uint8_t *add_msg_type(uint8_t *msg_option_base_addr, uint8_t message_type) { uint8_t *option_start; msg_option_base_addr[0] = DHCP_OPTION_CODE_MSG_TYPE; msg_option_base_addr[1] = DHCP_OPTION_LENGTH_ONE; msg_option_base_addr[2] = message_type; option_start = msg_option_base_addr + 3; if (DHCP_MESSAGE_TYPE_NAK == message_type) *option_start++ = DHCP_OPTION_CODE_END; return option_start; } static uint8_t *fill_one_option_content(uint8_t *option_base_addr, uint8_t option_code, uint8_t option_length, void *copy_info) { uint8_t *option_data_base_address; uint8_t *next_option_start_address = NULL; option_base_addr[0] = option_code; option_base_addr[1] = option_length; option_data_base_address = option_base_addr + 2; switch (option_length) { case DHCP_OPTION_LENGTH_FOUR: memcpy(option_data_base_address, copy_info, DHCP_OPTION_LENGTH_FOUR); next_option_start_address = option_data_base_address + 4; break; case DHCP_OPTION_LENGTH_TWO: memcpy(option_data_base_address, copy_info, DHCP_OPTION_LENGTH_TWO); next_option_start_address = option_data_base_address + 2; break; case DHCP_OPTION_LENGTH_ONE: memcpy(option_data_base_address, copy_info, DHCP_OPTION_LENGTH_ONE); next_option_start_address = option_data_base_address + 1; break; } return next_option_start_address; } /** * @brief fill in the needed content of the dhcp offer message. * @param optptr the addr which the tail of dhcp magic field. * @retval the addr represent to add the end of option. */ static void add_offer_options(uint8_t *option_start_address) { uint8_t *temp_option_addr; /* add DHCP options 1. The subnet mask option specifies the client's subnet mask */ temp_option_addr = fill_one_option_content(option_start_address, DHCP_OPTION_CODE_SUBNET_MASK, DHCP_OPTION_LENGTH_FOUR, (void *)&dhcps_local_mask); /* add DHCP options 3 (i.e router(gateway)). The time server option specifies a list of RFC 868 [6] time servers available to the client. */ temp_option_addr = fill_one_option_content(temp_option_addr, DHCP_OPTION_CODE_ROUTER, DHCP_OPTION_LENGTH_FOUR, (void *)&dhcps_local_address); /* add DHCP options 6 (i.e DNS). The option specifies a list of DNS servers available to the client. */ temp_option_addr = fill_one_option_content(temp_option_addr, DHCP_OPTION_CODE_DNS_SERVER, DHCP_OPTION_LENGTH_FOUR, (void *)&dhcps_local_address); /* add DHCP options 51. This option is used to request a lease time for the IP address. */ temp_option_addr = fill_one_option_content(temp_option_addr, DHCP_OPTION_CODE_LEASE_TIME, DHCP_OPTION_LENGTH_FOUR, (void *)&dhcp_option_lease_time_one_day); /* add DHCP options 54. The identifier is the IP address of the selected server. */ temp_option_addr = fill_one_option_content(temp_option_addr, DHCP_OPTION_CODE_SERVER_ID, DHCP_OPTION_LENGTH_FOUR, (void *)&dhcps_local_address); /* add DHCP options 28. This option specifies the broadcast address in use on client's subnet.*/ temp_option_addr = fill_one_option_content(temp_option_addr, DHCP_OPTION_CODE_BROADCAST_ADDRESS, DHCP_OPTION_LENGTH_FOUR, (void *)&dhcps_subnet_broadcast); /* add DHCP options 26. This option specifies the Maximum transmission unit to use */ temp_option_addr = fill_one_option_content(temp_option_addr, DHCP_OPTION_CODE_INTERFACE_MTU, DHCP_OPTION_LENGTH_TWO, (void *) &dhcp_option_interface_mtu_576); /* add DHCP options 31. This option specifies whether or not the client should solicit routers */ temp_option_addr = fill_one_option_content(temp_option_addr, DHCP_OPTION_CODE_PERFORM_ROUTER_DISCOVERY, DHCP_OPTION_LENGTH_ONE, NULL); *temp_option_addr++ = DHCP_OPTION_CODE_END; } /** * @brief fill in common content of a dhcp message. * @param m the pointer which point to the dhcp message store in. * @retval None. */ static void dhcps_initialize_message(struct dhcp_msg *dhcp_message_repository, struct ip_addr yiaddr) { dhcp_message_repository->op = DHCP_MESSAGE_OP_REPLY; dhcp_message_repository->htype = DHCP_MESSAGE_HTYPE; dhcp_message_repository->hlen = DHCP_MESSAGE_HLEN; dhcp_message_repository->hops = 0; memcpy((char *)dhcp_recorded_xid, (char *) dhcp_message_repository->xid, sizeof(dhcp_message_repository->xid)); dhcp_message_repository->secs = 0; dhcp_message_repository->flags = htons(BOOTP_BROADCAST); memcpy((char *)dhcp_message_repository->yiaddr, (char *)&yiaddr, sizeof(dhcp_message_repository->yiaddr)); memset((char *)dhcp_message_repository->ciaddr, 0, sizeof(dhcp_message_repository->ciaddr)); memset((char *)dhcp_message_repository->siaddr, 0, sizeof(dhcp_message_repository->siaddr)); memset((char *)dhcp_message_repository->giaddr, 0, sizeof(dhcp_message_repository->giaddr)); memcpy((char *)dhcp_message_repository->chaddr, &dhcp_client_ethernet_address, sizeof(dhcp_message_repository->chaddr)); memset((char *)dhcp_message_repository->sname, 0, sizeof(dhcp_message_repository->sname)); memset((char *)dhcp_message_repository->file, 0, sizeof(dhcp_message_repository->file)); memset((char *)dhcp_message_repository->options, 0, dhcp_message_total_options_lenth); memcpy((char *)dhcp_message_repository->options, (char *)dhcp_magic_cookie, sizeof(dhcp_magic_cookie)); } /** * @brief init and fill in the needed content of dhcp offer message. * @param packet_buffer packet buffer for UDP. * @retval None. */ static void dhcps_send_offer(struct pbuf *packet_buffer) { uint8_t temp_ip = 0; dhcp_message_repository = (struct dhcp_msg *)packet_buffer->payload; #if (!IS_USE_FIXED_IP) if ((ip4_addr4(&dhcps_allocated_client_address) != 0) && (memcmp((void *)&dhcps_allocated_client_address, (void *)&client_request_ip, 4) == 0) && (memcmp((void *)&bound_client_ethernet_address, (void *)&dhcp_client_ethernet_address, 16) == 0)) { temp_ip = (uint8_t) ip4_addr4(&client_request_ip); } else if ((ip4_addr1(&client_request_ip) == ip4_addr1(&dhcps_network_id)) && (ip4_addr2(&client_request_ip) == ip4_addr2(&dhcps_network_id)) && (ip4_addr3(&client_request_ip) == ip4_addr3(&dhcps_network_id))) { uint8_t request_ip4 = (uint8_t) ip4_addr4(&client_request_ip); if ((request_ip4 != 0) && (((request_ip4 - 1) / 32) >= 0) && (((request_ip4 - 1) / 32) <= 3) && (((ip_table.ip_range[(request_ip4 - 1) / 32] >> ((request_ip4 - 1) % 32)) & 0x01) == 0)) { temp_ip = request_ip4; } } /* create new client ip */ if(temp_ip == 0) temp_ip = search_next_ip(); #if (debug_dhcps) printf(" temp_ip = %d\n",temp_ip); #endif if (temp_ip == 0) { #if 0 memset(&ip_table, 0, sizeof(struct table)); mark_ip_in_table((uint8_t)ip4_addr4(&dhcps_local_address)); printf("reset ip table!"); #endif printf("No useable ip!"); } IP4_ADDR(&dhcps_allocated_client_address, (ip4_addr1(&dhcps_network_id)), ip4_addr2(&dhcps_network_id), ip4_addr3(&dhcps_network_id), temp_ip); memcpy(bound_client_ethernet_address, dhcp_client_ethernet_address, sizeof(bound_client_ethernet_address)); #endif dhcps_initialize_message(dhcp_message_repository, dhcps_allocated_client_address); add_offer_options(add_msg_type(&dhcp_message_repository->options[4], DHCP_MESSAGE_TYPE_OFFER)); udp_sendto_if(dhcps_pcb, packet_buffer, &dhcps_send_broadcast_address, DHCP_CLIENT_PORT, dhcps_netif); } /** * @brief init and fill in the needed content of dhcp nak message. * @param packet buffer packet buffer for UDP. * @retval None. */ static void dhcps_send_nak(struct pbuf *packet_buffer) { struct ip_addr zero_address; IP4_ADDR(&zero_address, 0, 0, 0, 0); dhcp_message_repository = (struct dhcp_msg *)packet_buffer->payload; dhcps_initialize_message(dhcp_message_repository, zero_address); add_msg_type(&dhcp_message_repository->options[4], DHCP_MESSAGE_TYPE_NAK); udp_sendto_if(dhcps_pcb, packet_buffer, &dhcps_send_broadcast_address, DHCP_CLIENT_PORT, dhcps_netif); } /** * @brief init and fill in the needed content of dhcp ack message. * @param packet buffer packet buffer for UDP. * @retval None. */ static void dhcps_send_ack(struct pbuf *packet_buffer) { dhcp_message_repository = (struct dhcp_msg *)packet_buffer->payload; dhcps_initialize_message(dhcp_message_repository, dhcps_allocated_client_address); add_offer_options(add_msg_type(&dhcp_message_repository->options[4], DHCP_MESSAGE_TYPE_ACK)); udp_sendto_if(dhcps_pcb, packet_buffer, &dhcps_send_broadcast_address, DHCP_CLIENT_PORT, dhcps_netif); } /** * @brief according by the input message type to reflect the correspond state. * @param option_message_type the input server state * @retval the server state which already transfer to. */ uint8_t dhcps_handle_state_machine_change(uint8_t option_message_type) { switch (option_message_type) { case DHCP_MESSAGE_TYPE_DECLINE: dhcp_server_state_machine = DHCP_SERVER_STATE_IDLE; break; case DHCP_MESSAGE_TYPE_DISCOVER: if (dhcp_server_state_machine == DHCP_SERVER_STATE_IDLE) { dhcp_server_state_machine = DHCP_SERVER_STATE_OFFER; } break; case DHCP_MESSAGE_TYPE_REQUEST: #if (!IS_USE_FIXED_IP) if (dhcp_server_state_machine == DHCP_SERVER_STATE_OFFER) { if (ip4_addr4(&dhcps_allocated_client_address) != 0) { if (memcmp((void *)&dhcps_allocated_client_address, (void *)&client_request_ip, 4) == 0) { dhcp_server_state_machine = DHCP_SERVER_STATE_ACK; } else { dhcp_server_state_machine = DHCP_SERVER_STATE_NAK; } } else { dhcp_server_state_machine = DHCP_SERVER_STATE_NAK; } } else if (dhcp_server_state_machine == DHCP_SERVER_STATE_IDLE) { if ((ip4_addr4(&dhcps_allocated_client_address) != 0) && (memcmp((void *)&dhcps_allocated_client_address, (void *)&client_request_ip, 4) == 0) && (memcmp((void *)&bound_client_ethernet_address, (void *)&dhcp_client_ethernet_address, 16) == 0)) { dhcp_server_state_machine = DHCP_SERVER_STATE_ACK; } else if ((ip4_addr1(&client_request_ip) == ip4_addr1(&dhcps_network_id)) && (ip4_addr2(&client_request_ip) == ip4_addr2(&dhcps_network_id)) && (ip4_addr3(&client_request_ip) == ip4_addr3(&dhcps_network_id))) { uint8_t request_ip4 = (uint8_t) ip4_addr4(&client_request_ip); if ((request_ip4 != 0) && (((request_ip4 - 1) / 32) >= 0) && (((request_ip4 - 1) / 32) <= 3) && (((ip_table.ip_range[(request_ip4 - 1) / 32] >> ((request_ip4 - 1) % 32)) & 0x01) == 0)) { IP4_ADDR(&dhcps_allocated_client_address, (ip4_addr1(&dhcps_network_id)), ip4_addr2(&dhcps_network_id), ip4_addr3(&dhcps_network_id), request_ip4); memcpy(bound_client_ethernet_address, dhcp_client_ethernet_address, sizeof(bound_client_ethernet_address)); dhcp_server_state_machine = DHCP_SERVER_STATE_ACK; } else { dhcp_server_state_machine = DHCP_SERVER_STATE_NAK; } } else { dhcp_server_state_machine = DHCP_SERVER_STATE_NAK; } } else { dhcp_server_state_machine = DHCP_SERVER_STATE_NAK; } #else if (!(dhcp_server_state_machine == DHCP_SERVER_STATE_ACK || dhcp_server_state_machine == DHCP_SERVER_STATE_NAK)) { dhcp_server_state_machine = DHCP_SERVER_STATE_NAK; } #endif break; case DHCP_MESSAGE_TYPE_RELEASE: dhcp_server_state_machine = DHCP_SERVER_STATE_IDLE; break; } return dhcp_server_state_machine; } /** * @brief parse the dhcp message option part. * @param optptr: the addr of the first option field. * len: the total length of all option fields. * @retval dhcp server state. */ static uint8_t dhcps_handle_msg_options(uint8_t *option_start, int16_t total_option_length) { int16_t option_message_type = 0; uint8_t *option_end = option_start + total_option_length; //dhcp_server_state_machine = DHCP_SERVER_STATE_IDLE; /* begin process the dhcp option info */ while (option_start < option_end) { switch ((uint8_t)*option_start) { case DHCP_OPTION_CODE_MSG_TYPE: option_message_type = *(option_start + 2); // 2 => code(1)+lenth(1) break; case DHCP_OPTION_CODE_REQUEST_IP_ADDRESS : #if IS_USE_FIXED_IP if (memcmp((char *)&dhcps_allocated_client_address, (char *)option_start + 2, 4) == 0) dhcp_server_state_machine = DHCP_SERVER_STATE_ACK; else dhcp_server_state_machine = DHCP_SERVER_STATE_NAK; #else memcpy((char *)&client_request_ip, (char *)option_start + 2, 4); #endif break; } // calculate the options offset to get next option's base addr option_start += option_start[1] + 2; // optptr[1]: length value + (code(1)+ Len(1)) } return dhcps_handle_state_machine_change(option_message_type); } /** * @brief get message from buffer then check whether it is dhcp related or not. * if yes , parse it more to undersatnd the client's request. * @param same as recv callback function definition * @retval if message is dhcp related then return dhcp server state, * otherwise return 0 */ static uint8_t dhcps_check_msg_and_handle_options(struct pbuf *packet_buffer) { int dhcp_message_option_offset; dhcp_message_repository = (struct dhcp_msg *)packet_buffer->payload; memcpy(dhcp_client_ethernet_address, dhcp_message_repository->chaddr, sizeof(dhcp_client_ethernet_address)); dhcp_message_option_offset = ((int)dhcp_message_repository->options - (int)packet_buffer->payload); dhcp_message_total_options_lenth = (packet_buffer->len - dhcp_message_option_offset); /* check the magic number,if correct parse the content of options */ if (memcmp((char *)dhcp_message_repository->options, (char *)dhcp_magic_cookie, sizeof(dhcp_magic_cookie)) == 0) { return dhcps_handle_msg_options(&dhcp_message_repository->options[4], (dhcp_message_total_options_lenth - 4)); } return 0; } /** * @brief handle imcoming dhcp message and response message to client * @param same as recv callback function definition * @retval None */ static void dhcps_receive_udp_packet_handler(void *arg, struct udp_pcb *udp_pcb, struct pbuf *udp_packet_buffer, struct ip_addr *sender_addr, uint16_t sender_port) { int16_t total_length_of_packet_buffer; struct pbuf *merged_packet_buffer = NULL; dhcp_message_repository = (struct dhcp_msg *)udp_packet_buffer->payload; if (udp_packet_buffer == NULL) { printf("Error! System doesn't allocate any buffer\n"); return; } if (sender_port == DHCP_CLIENT_PORT) { total_length_of_packet_buffer = udp_packet_buffer->tot_len; if (udp_packet_buffer->next != NULL) { merged_packet_buffer = pbuf_coalesce(udp_packet_buffer, PBUF_TRANSPORT); if (merged_packet_buffer->tot_len != total_length_of_packet_buffer) { pbuf_free(udp_packet_buffer); return; } } switch (dhcps_check_msg_and_handle_options(udp_packet_buffer)) { case DHCP_SERVER_STATE_OFFER: dhcps_send_offer(udp_packet_buffer); break; case DHCP_SERVER_STATE_ACK: dhcps_send_ack(udp_packet_buffer); #if (!IS_USE_FIXED_IP) mark_ip_in_table((uint8_t)ip4_addr4(&dhcps_allocated_client_address)); #endif dhcp_server_state_machine = DHCP_SERVER_STATE_IDLE; break; case DHCP_SERVER_STATE_NAK: dhcps_send_nak(udp_packet_buffer); dhcp_server_state_machine = DHCP_SERVER_STATE_IDLE; break; case DHCP_OPTION_CODE_END: break; } } /* free the UDP connection, so we can accept new clients */ udp_disconnect(udp_pcb); /* Free the packet buffer */ if (merged_packet_buffer != NULL) pbuf_free(merged_packet_buffer); else pbuf_free(udp_packet_buffer); } void dhcps_set_addr_pool(int addr_pool_set, struct ip_addr * addr_pool_start, struct ip_addr *addr_pool_end) { if(addr_pool_set){ dhcps_addr_pool_set = 1; memcpy(&dhcps_addr_pool_start, addr_pool_start, sizeof(struct ip_addr)); memcpy(&dhcps_addr_pool_end, addr_pool_end, sizeof(struct ip_addr)); }else{ dhcps_addr_pool_set = 0; } } /** * @brief Initialize dhcp server. * @param None. * @retval None. * Note, for now,we assume the server latch ip 192.168.1.1 and support dynamic * or fixed IP allocation. */ void dhcps_init(struct netif * pnetif) { // printf("dhcps_init,wlan:%c\n\r",pnetif->name[1]); dhcps_netif = pnetif; if (dhcps_pcb != NULL) { udp_remove(dhcps_pcb); dhcps_pcb = NULL; } dhcps_pcb = udp_new(); if (dhcps_pcb == NULL) { printf("Error! upd_new error\n"); return; } IP4_ADDR(&dhcps_send_broadcast_address, 255, 255, 255, 255); /* get net info from net interface */ memcpy(&dhcps_local_address, &pnetif->ip_addr, sizeof(struct ip_addr)); memcpy(&dhcps_local_mask, &pnetif->netmask, sizeof(struct ip_addr)); memcpy(&dhcps_local_gateway, &pnetif->gw, sizeof(struct ip_addr)); /* calculate the usable network ip range */ dhcps_network_id.addr = ((pnetif->ip_addr.addr) & (pnetif->netmask.addr)); dhcps_subnet_broadcast.addr = ((dhcps_network_id.addr | ~(pnetif->netmask.addr))); #if 0 dhcps_owned_first_ip.addr = htonl((ntohl(dhcps_network_id.addr) + 1)); dhcps_owned_last_ip.addr = htonl(ntohl(dhcps_subnet_broadcast.addr) - 1); dhcps_num_of_available_ips = ((ntohl(dhcps_owned_last_ip.addr) - ntohl(dhcps_owned_first_ip.addr)) + 1); #endif #if IS_USE_FIXED_IP IP4_ADDR(&dhcps_allocated_client_address, ip4_addr1(&dhcps_local_address) , ip4_addr2(&dhcps_local_address), ip4_addr3(&dhcps_local_address), (ip4_addr4(&dhcps_local_address)) + 1 ); #else if (dhcps_ip_table_semaphore != NULL) { vSemaphoreDelete(dhcps_ip_table_semaphore); dhcps_ip_table_semaphore = NULL; } dhcps_ip_table_semaphore = xSemaphoreCreateMutex(); //dhcps_ip_table = (struct ip_table *)(pvPortMalloc(sizeof(struct ip_table))); memset(&ip_table, 0, sizeof(struct table)); memset(&dhcps_allocated_client_address, 0, sizeof(struct ip_addr)); memset(bound_client_ethernet_address, 0, sizeof(bound_client_ethernet_address)); mark_ip_in_table((uint8_t)ip4_addr4(&dhcps_local_address)); mark_ip_in_table((uint8_t)ip4_addr4(&dhcps_local_gateway)); #if 0 for (i = 1; i < ip4_addr4(&dhcps_local_address); i++) { mark_ip_in_table(i); } #endif #endif udp_bind(dhcps_pcb, IP_ADDR_ANY, DHCP_SERVER_PORT); udp_recv(dhcps_pcb, dhcps_receive_udp_packet_handler, NULL); } void dhcps_deinit(void) { if (dhcps_pcb != NULL) { udp_remove(dhcps_pcb); dhcps_pcb = NULL; } if (dhcps_ip_table_semaphore != NULL) { vSemaphoreDelete(dhcps_ip_table_semaphore); dhcps_ip_table_semaphore = NULL; } }