Ethernet test for tinydtls-0.5.0
Dependencies: EthernetInterface mbed-rtos mbed tinydtls
Fork of tinydtls_test_ethernet by
main.cpp
- Committer:
- ashleymills
- Date:
- 2013-10-11
- Revision:
- 3:0caeed7fd9f0
- Parent:
- 2:21019cad4c93
- Child:
- 4:4d466a913c11
File content as of revision 3:0caeed7fd9f0:
#define __DEBUG__ 4 #ifndef __MODULE__ #define __MODULE__ "main.cpp" #endif #include "mbed.h" #include "rtos.h" #include "bsd_socket.h" #include <dtls.h> #include "global.h" #include "debug.h" #include "errno.h" #include "dbg.h" #include "EthernetInterface.h" DigitalOut myled(LED1); void fail(int code) { while(1) { myled = !myled; Thread::wait(100); } } /* This function is the "key store" for tinyDTLS. It is called to * retrieve a key for the given identiy within this particular * session. */ int get_key(struct dtls_context_t *ctx, const session_t *session, const unsigned char *id, size_t id_len, const dtls_key_t **result) { DBG("Entered get_key"); static const dtls_key_t psk = { .type = DTLS_KEY_PSK, .key.psk.id = (unsigned char *)"Client_identity", .key.psk.id_length = 15, .key.psk.key = (unsigned char *)"secretPSK", .key.psk.key_length = 9 }; *result = &psk; return 0; } #define APN_GDSP //#define APN_CONTRACT #ifdef APN_GDSP #define APN "ppinternetd.gdsp" #define APN_USERNAME "" #define APN_PASSWORD "" #endif #ifdef APN_CONTRACT #define APN "internet" #define APN_USERNAME "web" #define APN_PASSWORD "web" #endif sockaddr_in bindAddr,serverAddress; bool connectToSocketUDP(char *ipAddress, int port, int *sockfd) { *sockfd = -1; // create the socket if((*sockfd=socket(AF_INET,SOCK_DGRAM,0))<0) { DBG("Error opening socket"); return false; } socklen_t sockAddrInLen = sizeof(struct sockaddr_in); // bind socket memset(&bindAddr, 0x00, sockAddrInLen); bindAddr.sin_family = AF_INET; // IP family bindAddr.sin_port = htons(port); bindAddr.sin_addr.s_addr = IPADDR_ANY; // 32 bit IP representation // call bind if(bind(*sockfd,(const struct sockaddr *)&bindAddr,sockAddrInLen)!=0) { DBG("Error binding socket"); perror(NULL); } INFO("UDP socket created and bound to: %s:%d",inet_ntoa(bindAddr.sin_addr),ntohs(bindAddr.sin_port)); // create the socket address memset(&serverAddress, 0x00, sizeof(struct sockaddr_in)); serverAddress.sin_addr.s_addr = inet_addr(ipAddress); serverAddress.sin_family = AF_INET; serverAddress.sin_port = htons(port); // do socket connect //LOG("Connecting socket to %s:%d", inet_ntoa(serverAddress.sin_addr), ntohs(serverAddress.sin_port)); if(connect(*sockfd, (const struct sockaddr *)&serverAddress, sizeof(serverAddress))<0) { shutdown(*sockfd,SHUT_RDWR); close(*sockfd); DBG("Could not connect"); return false; } return true; } int read_from_peer(struct dtls_context_t *ctx, session_t *session, uint8 *data, size_t len) { DBG("read_from_peer called"); size_t i; for (i = 0; i < len; i++) printf("%c", data[i]); return 0; } int send_to_peer(struct dtls_context_t *ctx, session_t *session, uint8 *data, size_t len) { DBG("send_to_peer called"); int fd = *(int *)dtls_get_app_data(ctx); return sendto(fd, data, len, MSG_DONTWAIT, &session->addr.sa, session->size); } int dtls_handle_read(struct dtls_context_t *ctx) { DBG("dtls_handle_read called"); int fd; session_t session; #define MAX_READ_BUF 512 static uint8 buf[MAX_READ_BUF]; int len; fd = *(int *)dtls_get_app_data(ctx); /* if(!fd) { DBG("FD NULL"); return -1; }*/ memset(&session, 0x00, sizeof(session_t)); DBG("BEFORE: "); for(uint8_t i=0; i<sizeof(session_t); i++) { DBGX("%x ",((uint8_t*)&session)[i]); } DBGX("\r\n"); session.size = sizeof(sockaddr_in); uint32_t bullshit = sizeof(sockaddr_in); len = recvfrom(fd, buf, MAX_READ_BUF, 0, &session.addr.sa, &bullshit); //((uint8_t*)&session)[4] = 0x00; //session.addr.sin.sin_family = AF_INET; DBG("AFTER: %d",bullshit); for(uint8_t i=0; i<sizeof(session_t); i++) { DBGX("%x ",((uint8_t*)&session)[i]); } DBGX("\r\n"); short x = session.addr.sin.sin_family; if(session.addr.sin.sin_family==AF_INET) { DBG("AF_INET alright"); } DBG("%x %x",((uint8_t*)x)[0],((uint8_t*)x)[1]); if (len < 0) { DBG("Got nothing from read"); perror("recvfrom"); return -1; } else { #ifndef NDEBUG unsigned char addrbuf[72]; dsrv_print_addr(&session, addrbuf, sizeof(addrbuf)); DBG("got %d bytes from %s\n", len, (char *)addrbuf); dump((unsigned char *)&session, sizeof(session_t)); DBGX("\r\n"); dump(buf, len); DBGX("\r\n"); #endif } return dtls_handle_message(ctx, &session, buf, len); } static dtls_handler_t cb = { .write = send_to_peer, .read = read_from_peer, .event = NULL, .get_key = get_key }; int main() { DBG_INIT(); DBG_SET_SPEED(115200); DBG_SET_NEWLINE("\r\n"); DBG("Tiny DTLS test"); // DTLS context struct dtls_context_t *dtls_context = NULL; int ret = 0; fd_set rfds, wfds; struct timeval timeout; session_t dst; // structure for getting address of incoming packets sockaddr_in fromAddr; socklen_t fromAddrLen = sizeof(struct sockaddr_in); memset(&fromAddr,0x00,fromAddrLen); // connect to cellular network /* VodafoneUSBModem modem; modem.connect(APN,APN_USERNAME,APN_PASSWORD); */ EthernetInterface modem; DBG("Connecting to network interface"); modem.init(); if(modem.connect(10000)) { DBG("Error initialising ethernet interface"); } DBG("DONE."); dtls_init(); dtls_set_log_level(LOG_DEBUG); // setup socket to remote server int sockfd = NULL; if(!connectToSocketUDP("109.74.199.96", 4433, &sockfd)) { //if(!connectToSocketUDP("192.168.1.99", 4433, &sockfd)) { DBG("Error connecting to socket"); fail(1); } DBG("\"Connected\" to UDP socket, sockfd: %d",sockfd); /* int on = 1; if(setsockopt(sockfd, SOL_SOCKET, SO_REUSEADDR, &on, sizeof(on) ) < 0) { dsrv_log(LOG_ALERT, "setsockopt SO_REUSEADDR: %s\n", strerror(errno)); }*/ // tinydtls stuff // destination address is stored in a session type memset(&dst, 0x00, sizeof(session_t)); dst.size = sizeof(sockaddr_in); DBG("starting copy at offset: %d",(int)&dst.addr-(int)&dst); serverAddress.sin_len = dst.size; memcpy(&dst.addr, &serverAddress, dst.size); //dst.addr.sin.sin_port = htons(4433); // dtls init must always be called for memory allocation // setup DTLS context DBG("Creating DTLS context"); dtls_context = dtls_new_context(&sockfd); if(!dtls_context) { DBG("Cannot create context"); fail(3); } DBG("DTLS context created"); // forced to use this call back system dtls_set_handler(dtls_context, &cb); DBG("Issuing dtls_connect"); ret = dtls_connect(dtls_context, &dst); if(ret<0) { DBG("Error in dtls_connect: %d",ret); modem.disconnect(); fail(4); } if(ret==0) { DBG("Channel already exists"); modem.disconnect(); fail(5); } DBG("dtls_connect successfull"); while (1) { // setup file descriptor lists for select FD_ZERO(&rfds); FD_ZERO(&wfds); //FD_SET(fileno(stdin), &rfds); FD_SET(sockfd, &rfds); // FD_SET(sockfd, &wfds); timeout.tv_sec = 5; timeout.tv_usec = 0; int result = select(sockfd+1, &rfds, &wfds, 0, &timeout); if(result < 0) { // error if (errno != EINTR) perror("select"); } else if (result == 0) { // timeout } else { // OK // check which file descriptor had an event if(FD_ISSET(sockfd, &wfds)) { // FIXME (from tinydtls) } else if (FD_ISSET(sockfd, &rfds)) if(dtls_handle_read(dtls_context)<0) { modem.disconnect(); fail(6); } } //else if (FD_ISSET(fileno(stdin), &rfds)) //handle_stdin(); //} //if(len) { // try_send(dtls_context, &dst); //} } }