/*
* Send a message to the other end of the socket.
*
* The send call should block until the remote host has ACKnowledged receipt of
* the message. This does not necessarily imply that the application has called
* 'minisocket_receive', only that the packet is buffered pending a future
* receive.
*
* It is expected that the order of calls to 'minisocket_send' implies the order
* in which the concatenated messages will be received.
*
* 'minisocket_send' should block until the whole message is reliably
* transmitted or an error/timeout occurs
*
* Arguments: the socket on which the communication is made (socket), the
* message to be transmitted (msg) and its length (len).
* Return value: returns the number of successfully transmitted bytes. Sets the
* error code and returns -1 if an error is encountered.
*/
int minisocket_send(minisocket_t socket, minimsg_t msg, int len, minisocket_error *error)
{
int portNumber;
int sentLength;
int sentData = 0;
int maxDataSize;
int check;
//interrupt_level_t prev_level;
if (error == NULL)
return -1;
if (socket == NULL || msg == NULL || len <= 0)
{
*error = SOCKET_INVALIDPARAMS;
return -1;
}
portNumber = socket->port_number;
if (socket->status == TCP_PORT_CLOSING || socket->waiting == TCP_PORT_WAITING_TO_CLOSE
|| minisockets[portNumber] == NULL)
{
*error = SOCKET_SENDERROR;
return -1;
}
/*prev_level = set_interrupt_level(DISABLED);
socket->num_waiting_on_mutex++;
semaphore_P(socket->mutex);
socket->num_waiting_on_mutex--;
set_interrupt_level(prev_level);
*/
if (socket->status == TCP_PORT_CLOSING || socket->waiting == TCP_PORT_WAITING_TO_CLOSE
|| minisockets[portNumber] == NULL)
{
*error = SOCKET_SENDERROR;
// semaphore_V(socket->mutex);
return -1;
}
maxDataSize = MAX_NETWORK_PKT_SIZE - sizeof(struct mini_header_reliable);
while (len > 0)
{
sentLength = (maxDataSize > len ? len : maxDataSize);
check = transmit_packet(socket, socket->destination_addr, socket->destination_port, 1,
MSG_ACK, sentLength, (msg+sentData), error);
if (check == -1)
{
// semaphore_V(socket->mutex);
minisocket_destroy(socket, 0);
return (sentData == 0 ? -1 : sentData);
}
len -= maxDataSize;
sentData += sentLength;
}
// semaphore_V(socket->mutex);
*error = SOCKET_NOERROR;
return sentData;
}
/* Close a connection. If minisocket_close is issued, any send or receive should
* fail. As soon as the other side knows about the close, it should fail any
* send or receive in progress. The minisocket is destroyed by minisocket_close
* function. The function should never fail.
*/
void minisocket_close(minisocket_t socket)
{
interrupt_level_t l;
minisocket_error error;
resend_arg_t resend_alarm_arg;
resend_alarm_arg = (resend_arg_t)calloc(1,sizeof(struct resend_arg));
if (!resend_alarm_arg){
return;
}
error = SOCKET_NOERROR;
//printf("in minisocket_close\n");
//set state to close_wait
//send close, wait using alarms
//(after 7 retries, close connection)
//P on ack_ready
//if ack_ready, close connection
//ill formed argument
if (!sock_array){
free(resend_alarm_arg);
return;
}
l = set_interrupt_level(DISABLED);
//ill formed argument
if (sock_array[socket->src_port] == NULL){
set_interrupt_level(l);
free(resend_alarm_arg);
return;
}
if (socket->curr_state == CLOSE_SEND || socket->curr_state == CLOSE_RCV){
set_interrupt_level(l);
free(resend_alarm_arg);
return;
}
socket->curr_state = CLOSE_SEND;
socket->try_count = 0;
socket->curr_seq++;
minisocket_send_ctrl( MSG_FIN, socket, &error);
//printf("in minisocket_close, sent my MSG_FIN\n");
resend_alarm_arg->sock = socket;
resend_alarm_arg->msg_type = MSG_FIN;
resend_alarm_arg->data_len = 0;
resend_alarm_arg->data = (char*) &socket; //placeholder
resend_alarm_arg->error = &error;
if (socket->resend_alarm){
deregister_alarm(socket->resend_alarm);
}
socket->resend_alarm = NULL;
socket->resend_alarm = set_alarm(RESEND_TIME_UNIT, minisocket_resend, resend_alarm_arg, minithread_time());
//printf("in minisocket_close, set my alarm.\n");
set_interrupt_level(l);
semaphore_P(socket->ack_ready_sem); //wait for ack packet...
//received ack, close connection
//printf("in minisocket_close, got my ACK baby\n");
l = set_interrupt_level(DISABLED);
if (socket->resend_alarm){
deregister_alarm(socket->resend_alarm);
}
socket->resend_alarm = NULL;
minisocket_destroy(socket, &error);
//printf("Closed. Error is %d", error);
if (error != SOCKET_NOERROR){
//printf("Something went wrong. Close connection failure.\n");
}
set_interrupt_level(l);
//printf("in minisocket_close, SUCCESS\n");
free(resend_alarm_arg);
return;
}
void delete_socket(void* arg)
{
minisocket_t socket = (minisocket_t) arg;
minisocket_destroy(socket, 0);
}
void self_destruct(void* arg) {
minisocket_error error;
minisocket_destroy((minisocket_t)arg, &error);
//printf("Goodby cruel world\n");
return;
}
/* Initiate the communication with a remote site. When communication is
* established create a minisocket through which the communication can be made
* from now on.
*
* The first argument is the network address of the remote machine.
*
* The argument "port" is the port number on the remote machine to which the
* connection is made. The port number of the local machine is one of the free
* port numbers.
*
* Return value: the minisocket_t created, otherwise NULL with the errorcode
* stored in the "error" variable.
*/
minisocket_t minisocket_client_create(network_address_t addr, int port, minisocket_error *error)
{
minisocket_t new_sock;
interrupt_level_t l;
resend_arg* resend_alarm_arg;
unsigned short start;
char tmp;
//check valid portnum
if (port < 0 || port >= CLIENT_START) {
*error = SOCKET_INVALIDPARAMS;
return NULL;
}
semaphore_P(client_lock);
start = curr_client_idx;
while (sock_array[curr_client_idx] != NULL){
curr_client_idx++;
if (curr_client_idx >= NUM_SOCKETS){
curr_client_idx = CLIENT_START;
}
if (curr_client_idx == start){ // client sockets full
semaphore_V(client_lock);
*error = SOCKET_NOMOREPORTS;
return NULL;
}
}
new_sock = (minisocket_t)malloc(sizeof(struct minisocket));
if (!new_sock){
semaphore_V(client_lock);
*error = SOCKET_OUTOFMEMORY;
return NULL;
}
new_sock->pkt_ready_sem = semaphore_create();
if (!(new_sock->pkt_ready_sem)){
semaphore_V(client_lock);
free(new_sock);
*error = SOCKET_OUTOFMEMORY;
return NULL;
}
new_sock->pkt_q = queue_new();
if (!(new_sock->pkt_q)){
semaphore_V(client_lock);
semaphore_destroy(new_sock->pkt_ready_sem);
free(new_sock);
*error = SOCKET_OUTOFMEMORY;
return NULL;
}
new_sock->sock_lock = semaphore_create();
if (!(new_sock->sock_lock)){
semaphore_V(client_lock);
semaphore_destroy(new_sock->pkt_ready_sem);
queue_free(new_sock->pkt_q);
free(new_sock);
*error = SOCKET_OUTOFMEMORY;
return NULL;
}
new_sock->ack_ready_sem = semaphore_create();
if (!(new_sock->ack_ready_sem)){
semaphore_V(client_lock);
semaphore_destroy(new_sock->pkt_ready_sem);
queue_free(new_sock->pkt_q);
semaphore_destroy(new_sock->sock_lock);
free(new_sock);
*error = SOCKET_OUTOFMEMORY;
return NULL;
}
semaphore_initialize(new_sock->pkt_ready_sem, 0);
semaphore_initialize(new_sock->ack_ready_sem, 0);
semaphore_initialize(new_sock->sock_lock, 1);
new_sock->curr_state = CONNECT_WAIT;
new_sock->try_count = 0;
new_sock->curr_ack = 0;
new_sock->curr_seq = 1;
new_sock->resend_alarm = NULL; //no alarm set
new_sock->src_port = curr_client_idx;
new_sock->dst_port = port;
network_address_copy(addr, new_sock->dst_addr);
sock_array[curr_client_idx] = new_sock;
semaphore_V(client_lock);
l = set_interrupt_level(DISABLED);
minisocket_send_ctrl(MSG_SYN, new_sock, error);
resend_alarm_arg = (resend_arg*)calloc(1, sizeof(resend_arg));
resend_alarm_arg->sock = new_sock;
resend_alarm_arg->msg_type = MSG_SYN;
resend_alarm_arg->data_len = 0;
resend_alarm_arg->data = &tmp; //placeholder
resend_alarm_arg->error = error;
new_sock->resend_alarm = set_alarm(RESEND_TIME_UNIT, minisocket_resend, resend_alarm_arg, minithread_time());
set_interrupt_level(l);
semaphore_P(new_sock->ack_ready_sem);
l = set_interrupt_level(DISABLED);
switch(new_sock->curr_state) {
case CONNECTED: //we are connected
// must have gotten a MSG_SYNACK
new_sock->curr_state = CONNECTED;
new_sock->try_count = 0;
if (new_sock->resend_alarm){
deregister_alarm(new_sock->resend_alarm);
}
new_sock->resend_alarm = NULL;
*error = SOCKET_NOERROR;
set_interrupt_level(l);
break;
case CLOSE_RCV:
*error = SOCKET_BUSY;
minisocket_destroy(new_sock, error);
if (new_sock->resend_alarm){
deregister_alarm(new_sock->resend_alarm);
}
new_sock->resend_alarm = NULL;
*error = SOCKET_BUSY;
set_interrupt_level(l);
new_sock = NULL;
break;
default:
// error
*error = SOCKET_NOSERVER;
minisocket_destroy(new_sock, error);
set_interrupt_level(l);
new_sock = NULL;
break;
}
free(resend_alarm_arg);
return new_sock;
}
void minisocket_close(minisocket_t *socket) {
if (socket == NULL || mini_socket_data[socket->local_port_number] == NULL || socket->state == CLOSED) {
return; // no cleanup necessary
}
fprintf(stderr, "Closing time \n");
mini_header_reliable_t header;
minisocket_create_reliable_header((mini_header_reliable_t *) &header, socket, socket->remote_port_number, socket->remote_address, MSG_FIN);
int send_success = 0;
int timeout = START_TIMEOUT / 2;
for (int i = 0; i < MAX_FAILURES; i++) {
if (socket->state == CLOSED) {
return; //received a MSG_FIN message in network_handler, so stop re-tries
}
timeout = timeout * 2;
network_send_pkt(socket->remote_address, sizeof(mini_header_reliable_t), (char *) &header, 0, empty_message);
alarm_id timeout_alarm_id = register_alarm(timeout, handshake_timeout_handler, (void *) socket->ack_ready);
int alarm_fired = 0;
//keep looking through received packets until either the alarm fires or it finds the correct packet
while (!send_success && !alarm_fired) {
semaphore_P(socket->ack_ready);
//alarm has fired, since there are no packets to be received
if (queue_length(socket->acknowledgements) == 0) {
printf("CLOSE queue length: %d\n", queue_length(socket->acknowledgements));
alarm_fired = 1; //goes to next iteration of for loop
}
//There is a packet (alarm hasnt fired yet)
else {
network_interrupt_arg_t* interrupt_message = NULL;
interrupt_level_t old_level = set_interrupt_level(DISABLED);
queue_dequeue(socket->acknowledgements, (void **) &interrupt_message);
set_interrupt_level(old_level);
// verify non null message
if (interrupt_message != NULL) {
mini_header_reliable_t* received_header = (mini_header_reliable_t *) interrupt_message->buffer;
//already checked port and address in network_handler
if (received_header->message_type == MSG_ACK) {
deregister_alarm(timeout_alarm_id); //only deregister alarm when the right packet is found
send_success = 1;
free(interrupt_message);
break;
}
else {
free(interrupt_message);
}
}
}
}
if (send_success) {
break;
}
}
printf("out of CLOSE\n");
//sender considers the connection closed, even if MSG_ACK not received
if (socket->state != CLOSED) {
printf("calling DESTROY from CLOSE\n");
minisocket_destroy(socket);
}
}
int minisocket_send(minisocket_t *socket, const char *msg, int len, minisocket_error *error) {
//Check params
if (socket == NULL || mini_socket_data[socket->local_port_number] != socket || len < 0 || msg == NULL) {
*error = SOCKET_INVALIDPARAMS;
return -1;
}
if (socket->state == CLOSED) {
*error = SOCKET_SENDERROR;
return -1;
}
if (len == 0) {
return 0;
}
//can't send more bytes than we have
if (len > strlen(msg)) {
len = strlen(msg);
}
int bytes_sent = 0;
int max_data_size = MAX_NETWORK_PKT_SIZE - sizeof(mini_header_reliable_t);
int data_left = len;
int packet_size;
mini_header_reliable_t header;
minisocket_create_reliable_header((mini_header_reliable_t *) &header, socket, socket->remote_port_number, socket->remote_address, MSG_ACK);
//Keep sending until all is sent
while (data_left != 0) {
if (data_left >= max_data_size) {
packet_size = max_data_size;
}
else {
packet_size = data_left;
}
data_left -= packet_size;
pack_unsigned_int(header.seq_number, socket->seq);
int send_success = 0;
//Attempt to send message
int timeout = START_TIMEOUT/2;
for (int i = 0; i < MAX_FAILURES; i++) {
//printf("i: %d\n", i);
timeout = timeout * 2;
//update the seq and ack numbers for the header from the socket
//printf("seq: %u, ack: %u\n", socket->seq, socket->ack);
pack_unsigned_int(header.ack_number, socket->ack);
pack_unsigned_int(header.seq_number, socket->seq);
network_send_pkt(socket->remote_address, sizeof(mini_header_reliable_t), (char *) &header, packet_size, (char *) msg);
alarm_id timeout_alarm_id = register_alarm(timeout, handshake_timeout_handler, (void *) socket->ack_ready);
int alarm_fired = 0;
//keep looking through received packets until either the alarm fires or it finds the correct packet
while (!send_success && !alarm_fired) {
semaphore_P(socket->ack_ready);
if (queue_length(socket->acknowledgements) == 0) {
// printf("no message in queue\n");
alarm_fired = 1; //goes to next iteration of for loop
}
else {
// printf("length of queue currently %d\n", queue_length(socket->acknowledgements));
network_interrupt_arg_t* interrupt_message = NULL;
interrupt_level_t old_level = set_interrupt_level(DISABLED);
queue_dequeue(socket->acknowledgements, (void **) &interrupt_message);
set_interrupt_level(old_level);
if (interrupt_message != NULL) {
mini_header_reliable_t* received_header = (mini_header_reliable_t *) interrupt_message->buffer;
network_address_t temp_address;
unpack_address(received_header->source_address, temp_address);
unsigned int new_ack = unpack_unsigned_int(received_header->ack_number);
//printf("Received an acknowledgment with ack number %u \n", new_ack);
if (socket->remote_port_number == unpack_unsigned_short(received_header->source_port) &&
network_compare_network_addresses(socket->remote_address, temp_address) != 0 &&
received_header->message_type == MSG_ACK && new_ack == (socket->seq + packet_size)) {
//same address, same ports, right message, right ack
deregister_alarm(timeout_alarm_id); //only deregister alarm when the right packet is found
send_success = 1;
bytes_sent += packet_size;
msg += packet_size;
socket->seq += packet_size;
free(interrupt_message);
break;
}
else {
free(interrupt_message);
}
}
}
}
if (send_success) {
break;
}
}
if (!send_success) { //Got a timeout, should close down socket
*error = SOCKET_SENDERROR;
minisocket_destroy(socket);
return bytes_sent;
}
}
//printf("\n\n");
return bytes_sent;
}
minisocket_t* minisocket_client_create(const network_address_t addr, int port, minisocket_error *error) {
//Check socket number first
if (valid_server_port(port) == 0) {
*error = SOCKET_INVALIDPARAMS;
return NULL;
}
//Then check if we can make another client
if (client_count >= MAX_CLIENTS) {
*error = SOCKET_NOMOREPORTS;
return NULL;
}
//create new minisocket
minisocket_t* socket = (minisocket_t *) malloc(sizeof(minisocket_t));
if (socket == NULL) {
*error = SOCKET_OUTOFMEMORY;
return NULL; //OOM
}
while (mini_socket_data[next_port]) {
next_port = ((next_port + 1) % PORT_RANGE);
}
socket->socket_type = CLIENT_TYPE;
socket->local_port_number = next_port;
next_port = ((next_port + 1) % PORT_RANGE);
socket->state = CONNECTING;
socket->seq = 0;
socket->ack = 0;
network_address_copy(addr, socket->remote_address);
socket->remote_port_number = (unsigned short) port;
network_address_copy(addr, socket->remote_address);
socket->next_read = 0;
network_address_t my_address;
network_get_my_address(my_address);
network_address_copy(my_address, socket->local_address);
socket->datagrams_ready = semaphore_create();
semaphore_initialize(socket->datagrams_ready, 0);
socket->ack_ready = semaphore_create();
semaphore_initialize(socket->ack_ready, 0);
socket->incoming_data = queue_new();
socket->acknowledgements = queue_new();
//add socket to global array
mini_socket_data[socket->local_port_number] = socket;
mini_header_reliable_t header;
minisocket_create_reliable_header((mini_header_reliable_t *) &header, socket, socket->remote_port_number, addr, MSG_SYN);
//minisocket and header now created, try to establish connection
pack_unsigned_int(header.seq_number, socket->seq);
pack_unsigned_int(header.ack_number, socket->ack);
//send first message and wait for response
int response = 0; //no response yet
int timeout = START_TIMEOUT / 2; //this way first timeout will be at START_TIMEOUT
for (int i = 0; i < MAX_FAILURES; i++) {
printf("sending MSG_SYN in client, i: %d\n", i);
timeout = timeout * 2;
network_send_pkt(addr, sizeof(mini_header_reliable_t), (char *) &header, 0, empty_message);
alarm_id timeout_alarm_id = register_alarm(timeout, handshake_timeout_handler, (void *) socket->ack_ready);
int alarm_fired = 0;
while (!response && !alarm_fired) {
semaphore_P(socket->ack_ready);
//If queue length == 0, then the alarm must have fired
if (queue_length(socket->acknowledgements) == 0) {
alarm_fired = 1; //goes to next iteration of for loop
}
//otherwise, we received a packet
else {
network_interrupt_arg_t *interrupt_message;
interrupt_level_t old_level = set_interrupt_level(DISABLED);
queue_dequeue(socket->acknowledgements, (void **) &interrupt_message);
set_interrupt_level(old_level);
// if message not null
if (interrupt_message != NULL) {
mini_header_reliable_t* received_header = (mini_header_reliable_t *) interrupt_message->buffer;
network_address_t temp_address;
unpack_address(received_header->source_address, temp_address);
if (socket->remote_port_number == unpack_unsigned_short(received_header->source_port) &&
network_compare_network_addresses(socket->remote_address, temp_address) != 0) {
//if SYNACK
printf("CLIENT\n");
if (received_header->message_type == MSG_SYNACK) {
printf("GOT message SYN_ACK\n");
deregister_alarm(timeout_alarm_id);
response = 1;
break;
}
//if MSG_FIN
else if (received_header->message_type == MSG_FIN) {
printf("got message MSG_FIN in client\n");
//server already in use
deregister_alarm(timeout_alarm_id);
*error = SOCKET_BUSY;
response = 1;
minisocket_destroy(socket);
return NULL;
}
//WRONG MESSAGE TYPE
else {
printf("wrong message type received in client\n");
//TODO : try another message type, maybe do nothing?
}
}
}
}
}
if (response) {
break;
}
}
// timeout after 12.8s occured, close down socket
if (response != 1) {
printf("full timeout in client sending SYN\n");
*error = SOCKET_NOSERVER;
minisocket_destroy(socket);
return NULL;
}
// send final MSG_ACK once to server (future data packets will also have MSG_ACK as header type)
header.message_type = MSG_ACK;
printf("sending final MSG_ACK and leaving client create\n");
network_send_pkt(addr, sizeof(mini_header_reliable_t), (char *) &header, 0, empty_message);
socket->state = CONNECTED;
client_count++;
return socket;
}
/* Close a connection. If minisocket_close is issued, any send or receive should
* fail. As soon as the other side knows about the close, it should fail any
* send or receive in progress. The minisocket is destroyed by minisocket_close
* function. The function should never fail.
*/
void minisocket_close(minisocket_t socket)
{
minisocket_destroy(socket, 1);
}
/*
* Send a message to the other end of the socket.
*
* The send call should block until the remote host has ACKnowledged receipt of
* the message. This does not necessarily imply that the application has called
* 'minisocket_receive', only that the packet is buffered pending a future
* receive.
*
* It is expected that the order of calls to 'minisocket_send' implies the order
* in which the concatenated messages will be received.
*
* 'minisocket_send' should block until the whole message is reliably
* transmitted or an error/timeout occurs
*
* Arguments: the socket on which the communication is made (socket), the
* message to be transmitted (msg) and its length (len).
* Return value: returns the number of successfully transmitted bytes. Sets the
* error code and returns -1 if an error is encountered.
*/
int minisocket_send(minisocket_t socket, minimsg_t msg, int len, minisocket_error *error)
{
int ret;
int max_data_size;
int data_sent = 0;
int len_sent;
int port_number;
if (socket == NULL)
{
*error = SOCKET_INVALIDPARAMS;
return -1;
}
if (msg == NULL)
{
*error = SOCKET_INVALIDPARAMS;
return -1;
}
if (len <= 0)
{
*error = SOCKET_INVALIDPARAMS;
return -1;
}
if (error == NULL)
{
return -1;
}
port_number = socket->port_number;
// First, check if the socket is closing
if (socket->status == TCP_PORT_CLOSING
|| socket->waiting == TCP_PORT_WAITING_CLOSE
|| minisockets[port_number] == NULL)
{
*error = SOCKET_SENDERROR;
return -1;
}
socket->num_waiting_on_mutex++;
semaphore_P(socket->mutex);
socket->num_waiting_on_mutex--;
// Check again - maybe we were awoken because it's now closing
if (socket->status == TCP_PORT_CLOSING
|| socket->waiting == TCP_PORT_WAITING_CLOSE
|| minisockets[port_number] == NULL)
{
*error = SOCKET_SENDERROR;
semaphore_V(socket->mutex);
return -1;
}
// Determine the max data size
max_data_size = MAX_NETWORK_PKT_SIZE - sizeof(struct mini_header_reliable);
if (len > max_data_size)
{
// Partition the large message into smaller packets
while (len > 0)
{
// See how much we can fit into the next packet
len_sent = (max_data_size > len ? len : max_data_size);
// Send the packet
ret = transmit_packet(socket, socket->dst_addr, socket->dst_port, 1,
MSG_ACK, len_sent, msg+data_sent, error);
// Check for errors
if (ret == -1)
{
// If we can't reach the host, close the connection
semaphore_V(socket->mutex);
minisocket_destroy(socket, 0);
return (data_sent == 0 ? -1 : data_sent);
}
// Update the amount of data left to send
len -= max_data_size; // can also be - len_sent, doesn't matter
// Update the number of bytes we've sent - also used w/ msg as a ptr
data_sent += len_sent;
}
}
else
{
// This can be transmitted as a single packet
ret = transmit_packet(socket, socket->dst_addr,
socket->dst_port, 1,
MSG_ACK, len, msg, error);
if (ret == -1)
{
// If we can't reach the host, close the connection
semaphore_V(socket->mutex);
minisocket_destroy(socket, 0);
return -1;
}
data_sent = len;
}
semaphore_V(socket->mutex);
*error = SOCKET_NOERROR;
return data_sent;
}
