I am trying to build a chat application between the server and the client. My doubt is for sending information from the client or from the server I was able to handle the partial send with the help of the loop, but I am unable to find out the length of the send data bytes from the client to the server or from the server to the client, thereby having problem in creating the memory for the received bytes and printing.
My chat function code for the client:
int chat_function(int sockfd)
{
char ch;
char *buf;
char *newp;
int ret_send = 0;
int ret_recv = 0;
int buf_size = 0;
while(1) {
printf("From client, enter the message : ");
buf = (char *)malloc(sizeof(char));
if (buf == NULL)
return -1;
while ((ch = getchar()) != '\n') {
buf[buf_size++] = ch;
newp = (char *)realloc(buf, (buf_size + 1) * sizeof(char));
if ( newp == NULL) {
free(buf);
return -1;
}
buf = newp;
}
buf[buf_size] = '\0';
ret_send = send_all(sockfd, buf, buf_size);
if (ret_send == -1)
error(1, errno, "error in send() function call\n");
memset(buf, 0, buf_size);
ret_recv = recv_all(sockfd, buf, buf_size);
if (ret_recv == -1) {
error(1, errno, "error in recv() function call\n");
} else if (ret_recv == -2) {
printf("Oops the server has closed the connection\n");
free(buf);
break;
}
printf("From Server : %s", buf);
if ((strncmp(buf, "exit", 4)) == 0) {
printf("Client Exit...\n");
free(buf);
break;
}
free(buf);
}
}
For handling partial send:
int send_all(int sockfd, char *buf, int buf_size)
{
int bytes_left = 0;
size_t send_bytes = 0;
bytes_left = buf_size
while (1) {
send_bytes = send(fd, buf, bytes_left, 0);
if (send_bytes == -1)
return -1;
buf = buf + send_bytes;
bytes_left = bytes_left - send_bytes;
if (bytes_left == 0)
break;
}
return 0;
}
TCP is a stream protocol, meaning there are no message boundaries: it is just a full-duplex (meaning data flows in both directions at the same time, as if there were two separate lanes) more or less continuous stream of data.
UDP is a datagram protocol, and does have message boundaries. There is an ioctl (FIONREAD/SIOCINQ) that provides the length of the next datagram, but because it involves a syscall, doing that for every message you receive is going to be slow and inefficient. Instead, you normally use a buffer large enough to hold the largest acceptable message, and copy it if/when necessary. However, UDP also has no reliability guarantees, and often UDP datagrams are completely lost without any trace or discernible reason; that's just what happens.
For a chat client-server connection, you'll want to use TCP.
Since the underlying connection is just a stream of data, you need to design a protocol for the communications, so that the stream can be split into messages, with each message processed separately.
The simplest case would be to use the nul character, \0, as a message separator.
The "send" function would then look something like this:
/* Returns 0 if message successfully sent,
nonzero errno code otherwise. */
int send_message(int descriptor, const char *message)
{
/* If message is NULL, we cannot use strlen(); use zero for that. */
const size_t message_len = (message) ? strlen(message) : 0;
/* Temporary variables for the sending part. */
const char *ptr = message;
const char *const end = message + message_len + 1; /* Include '\0' at end */
ssize_t bytes;
/* Check valid descriptor and message length. */
if (descriptor == -1 || message_len < 1)
return errno = EINVAL;
/* Write loop for sending the entire message. */
while (ptr < end) {
bytes = write(descriptor, ptr, (size_t)(end - ptr));
if (bytes > 0) {
ptr += bytes;
} else
if (bytes != -1) {
/* This should never happen. */
return errno = EIO;
} else
if (errno != EINTR) {
/* We do not consider EINTR an actual error; others we do. */
return errno;
}
}
return 0;
}
The above send_message() function writes the specified string, including the string terminating nul character \0, to the specified descriptor.
On the read end, we need a buffer large enough to hold at least one full message. Instead of always waiting for incoming data, we need to check if the buffer already contains a full message, and if it does, return that. Also, you do not necessarily want to always wait for an incoming message, because that would mean you cannot send two messages in a row.
So, here's my suggestion:
static int incoming_desc = -1;
static char *incoming_data = NULL;
static size_t incoming_size = 0;
static char *incoming_next = NULL; /* First received but not handled */
static char *incoming_ends = NULL; /* Last received but not handled */
#define INCOMING_CHUNK 4096
/* Receive a new message into dynamically allocated buffer,
and return the length. Returns 0 when no message, with errno set.
Waits at most ms milliseconds for a new message to arrive.
errno == EAGAIN: no message, timeout elapsed.
errno == ECONNABORTED: other end closed the connection.
*/
size_t get_message(char **message, size_t *size, long ms)
{
struct timeval timeout;
/* Make sure the parameters are sane. */
if (!message || !size || ms < 0) {
errno = EINVAL;
return 0;
}
/* For this function to work like getline() and getdelim() do,
we need to treat *message as NULL if *size == 0. */
if (!*size)
*message = NULL;
timeout.tv_sec = ms / 1000;
timeout.tv_usec = (ms % 1000) * 1000;
/* Timeout loop. */
while (1) {
fd_set readfds;
ssize_t bytes;
size_t used;
int result;
/* Is there a pending complete message in the buffer? */
if (incoming_ends > incoming_next) {
char *endmark = memchr(incoming_next, '\0', (size_t)(incoming_ends - incoming_next));
if (endmark) {
const size_t len = (size_t)(endmark - incoming_next) + 1;
/* Reallocate the message buffer, if necessary. */
if (len > *size) {
char *temp = realloc(*message, len);
if (!temp) {
errno = ENOMEM;
return 0;
}
*message = temp;
*size = len;
}
/* Copy message, */
memcpy(*message, incoming_next, len);
/* and remove it from the buffer. */
incoming_next += len;
/* In case the other end sent just the separator, clear errno. */
errno = 0;
/* We return the length sans the separator. */
return len - 1;
}
}
/* Do we have time left to check for input? */
if (timeout.tv_sec <= 0 && timeout.tv_usec <= 0)
break; /* Nope. */
/* Is incoming_desc one we can select() for? */
if (incoming_desc < 0 || incoming_desc >= FD_SETSIZE)
break; /* Nope. */
FD_ZERO(&readfds);
FD_SET(incoming_desc, &readfds);
result = select(incoming_desc + 1, &readfds, NULL, NULL, &timeout);
if (result < 1)
break; /* Nothing interesting happened (we ignore error here). */
if (!FD_ISSET(incoming_fd, &readfds))
break;
/* Number of bytes used in the buffer right now. */
used = (size_t)(incoming_ends - incoming_data);
/* Do we have at least INCOMING_CHUNK bytes available? */
if (used + INCOMING_CHUNK >= incoming_size) {
/* Nope. Repack the incoming buffer first. */
if (incoming_next > incoming_data) {
const size_t len = (size_t)(incoming_ends - incoming_next);
if (len > 0)
memmove(incoming_data, incoming_next, len);
incoming_next = incoming_data;
incoming_ends = incoming_data + len;
}
/* Recalculate the number of bytes we have free now. Enough? */
used = (size_t)(incoming_ends - incoming_data);
if (used + INCOMING_CHUNK > incoming_size) {
/* Grow incoming buffer. */
const size_t newsize = used + INCOMING_CHUNK;
char *temp = realloc(incoming_data, newsize);
if (!temp) {
errno = ENOMEM;
return 0;
}
incoming_next = temp + (size_t)(incoming_next - incoming_data);
incoming_ends = temp + used;
incoming_data = temp;
incoming_size = newsize;
}
}
/* Read more data into the buffer; up to a full buffer. */
bytes = read(incoming_fd, incoming_ends, incoming_size - used);
if (bytes > 0) {
incoming_ends += bytes;
} else
if (bytes == 0) {
/* Other end closed the connection. We may have a partial message
in the buffer, and should handle that too, but for now, we
just error out. */
errno = ECONNABORTED;
return 0;
} else
if (bytes != -1) {
/* Should never happen. */
errno = EIO;
return 0;
} else
if (errno == EINTR || errno == EAGAIN || errno == EWOULDBLOCK) {
/* No data yet, interrupted by signal delivery, etc. */
continue;
} else {
/* errno is set to indicate which error happened. */
return 0;
}
}
/* Timeout. */
errno = EAGAIN;
return 0;
}
Note that get_message() works like getline(): you do e.g.
char *msg = NULL;
size_t size = 0;
size_t len;
len = get_message(&msg, &size, 100); /* 100 ms = 0.1 seconds */
if (len) {
/* msg contains a full message of len characters */
} else
if (errno == ECONNABORTED) {
/* Other end closed the connection */
} else
if (errno != EAGAIN) {
fprintf(stderr, "Error receiving data: %s.\n", strerror(errno));
}
Then, you can reuse the same dynamically allocated buffer by just calling e.g.
len = get_message(&msg, &size, 100); /* 100 ms = 0.1 seconds */
again.
There is no such mechanism built into TCP or UDP. You need to implement your own protocol on top of it. One of the possible solutions is:
If the content delivered is static.
If the sending end knows the size of the data that is being delivered prior, your client and server can agree on specific terms. For example, the first four bytes sent by the server is the size of the remaining message represented in network byte order.
Server code
uint32_t n_size = htonl(size); // Convert the data size into network byte order.
write(sockfd, &n_size, sizeof(n_size)); // Send to the client.
Client code
uint32_t n_size;
int n_read = 0;
for ( ; ; ) {
int rd_status = read(sockfd, (void*) &n_size + n_read, sizeof(n_size) - n_read);
if (rd_status <= 0)
goto handle_this_case;
n_read = n_read + rd_status;
if (n_read == sizeof(n_size))
break;
}
uint32_t size = ntohl(n_size);
If the content delivered is generated on the fly.
In this case, even the server is not aware of the size of the message. You need to build your functions for handling this case. Below I have shown a bare minimal implementation:
Client-Side:
struct data_unit
{
void* data;
int size;
};
struct data_storage
{
struct data_unit unit;
struct data_storage* next;
};
void append_data(struct data_storage* storage, struct data_unit* unit);
struct data_unit* dump_data(struct data_storage* storage);
int main()
{
struct data_storage storage;
struct data_unit unit;
unit.data = malloc(MAX_SIZE);
for ( ; ; ) {
int rd_status = read(sockfd, unit.data, MAX_SIZE);
if (rd_status < 0)
goto handle_this_case;
else if (rd_status == 0)
break;
unit.size = rd_status;
append_data(&storage, &unit);
}
struct data_unit* t_data = dump_data(&storage);
}
My single threaded HTTP Server works just fine, but I'm having trouble multithreading it. I know I am supposed to use pthreads, locks, and condition variables, but I can't get the logic set up properly. The trouble starts after listening to the server. Currently I have a struct that contains a client socket variable, a lock variable, a condition variable, and some variables necessary for parsing and storing headers. I create a struct array sized with the amount of threads, then create a pthread array sized with the amount of threads. I go into a while(1) loop which goes into a for loop and iterates through all the threads accepting each connection, calling pthread_create and passing them to my handle connections function, then closing the client socket. My handle connections then does the request handling that my single threaded http server did (reading, parsing, processing, constructing), then returns NULL. No request gets read when I run this using pthread_create, but if I run handle connections without the pthreads, it works just fine. And below I'll attach my code. Any help is appreciated
Thank you for commenting so well ...
Okay, I coded up, but not tested the changes.
Your loop is inherently single threaded, so a bit of refactoring is in order
You have to scan for an unused thread control slot after doing accept.
You have to pthread_join completed/done threads [from any prior invocations].
The thread function has to close the per-client socket [not main thread]
You need a global (file scope) mutex.
I've coded it up, but not tested it. I put #if 0 around most of what I clipped out and #if 1 around new code.
Note that number of simultaneous connections [second arg to listen], herein 5 has to be less than or equal to threadNum. Although I didn't do it, I'd just do listen(...,threadNum) instead of hardwiring it.
Here's the short code with just the relevant changes:
#if 1
pthread_mutex_t global_mutex = PTHREAD_MUTEX_INITIALIZER;
#endif
struct threadObject {
char method[5]; // PUT, HEAD, GET. HEAD==4 letters+null terminator
char filename[28]; // what is the file we are worried about. Max 27 ASCII characters (NULL terminated on 28)
char httpversion[9]; // HTTP/1.1
ssize_t content_length; // example: 13
uint16_t status_code; // status code for the request
char buffer[BUFFER_SIZE]; // buffer to transfer data
char rest_of_PUT[BUFFER_SIZE]; // incase client send part of PUT message in header
int client_sockd;
pthread_mutex_t *dispatch_lock;
const pthread_cond_t *job_pool_empty;
// pthread_mutex_t* log_lock;
// const pthread_cond_t* log_pool_empty;
pthread_mutex_t *read_write_lock;
pthread_cond_t *file_list_update;
// JobQueue* job_pool;
// LogQueue log_pool;
// bool is_logging;
#if 1
pthread_t tsk_threadid;
int tsk_inuse;
int tsk_done;
#endif
};
void *
handle_connections(void *ptr_thread)
{
// create a mutual exclusion to lock out any other threads from the function
// pthread_mutex_t mutex = PTHREAD_MUTEX_INITIALIZER;
// pthread_mutex_lock(&mutex);
// operations go here
struct threadObject *thread = (struct threadObject *) ptr_thread;
// reset message after each loop
memset(thread->buffer, '\0', BUFFER_SIZE);
memset(thread->method, '\0', 5);
memset(thread->filename, '\0', 28);
memset(thread->httpversion, '\0', 9);
thread->content_length = 0;
thread->status_code = 0;
memset(thread->rest_of_PUT, '\0', BUFFER_SIZE);
// read message
if (read_http_response(thread) == true) {
// process message
process_request(thread);
}
// construct a response
construct_http_response(thread);
// unlock the function
// pthread_mutex_unlock(&mutex);
#if 1
close(thread->client_sockd);
pthread_mutex_lock(&global_mutex);
thread->tsk_done = 1;
pthread_mutex_unlock(&global_mutex);
#endif
return NULL;
}
int
main(int argc, char **argv)
{
// Create sockaddr_in with server information
if (argc < 2) {
perror("No arguments passed\n");
return -1;
}
// make sure port number is above 1024 and set the port # to it
if (atoi(argv[1]) < 1024) {
return 1;
}
char *port = argv[1];
// parse the command line args for options -l and -N. -l specifies it will use a log and the following parameter is the filename. -N specifies the number of threads it will use and the following parameter will be a number
int opt;
uint8_t threadNum = 1;
char *logName = NULL;
while ((opt = getopt(argc - 1, argv + 1, "N:l:")) != -1) {
if (opt == 'N') {
threadNum = atoi(optarg);
}
else if (opt == 'l') {
logName = optarg;
}
}
struct sockaddr_in server_addr;
memset(&server_addr, 0, sizeof(server_addr));
server_addr.sin_family = AF_INET;
server_addr.sin_port = htons(atoi(port));
server_addr.sin_addr.s_addr = htonl(INADDR_ANY);
socklen_t addrlen = sizeof(server_addr);
// Create server socket
int server_sockd = socket(AF_INET, SOCK_STREAM, 0);
// Need to check if server_sockd < 0, meaning an error
if (server_sockd < 0) {
perror("socket");
return 1;
}
// Configure server socket
int enable = 1;
// This allows you to avoid: 'Bind: Address Already in Use' error
int ret = setsockopt(server_sockd, SOL_SOCKET, SO_REUSEADDR, &enable, sizeof(enable));
if (ret < 0) {
return EXIT_FAILURE;
}
// Bind server address to socket that is open
ret = bind(server_sockd, (struct sockaddr *) &server_addr, addrlen);
if (ret < 0) {
return EXIT_FAILURE;
}
// Listen for incoming connections
ret = listen(server_sockd, 5); // 5 should be enough, if not use SOMAXCONN
if (ret < 0) {
return EXIT_FAILURE;
}
struct threadObject thread[threadNum];
// Connecting with a client
struct sockaddr client_addr;
socklen_t client_addrlen = sizeof(client_addr);
// create a pthread array of size (number of threads). specify this will be using the handle connections function. join the threads together
#if 0
pthread_t thread_id[threadNum];
#endif
#if 1
struct threadObject *tsk = NULL;
int tskidx;
// clear out the thread structs
for (tskidx = 0; tskidx < threadNum; tskidx++) {
tsk = &thread[tskidx];
memset(tsk,0,sizeof(struct threadObject));
}
while (true) {
// accept connection
int client_sockd = accept(server_sockd, &client_addr, &client_addrlen);
pthread_mutex_lock(&global_mutex);
// join any previously completed threads
for (tskidx = 0; tskidx < threadNum; tskidx++) {
tsk = &thread[tskidx];
if (tsk->tsk_done) {
pthread_join(tsk->tsk_threadid,NULL);
tsk->tsk_inuse = 0;
tsk->tsk_done = 0;
}
}
// find unused task slot
for (tskidx = 0; tskidx < threadNum; tskidx++) {
tsk = &thread[tskidx];
if (! tsk->tsk_inuse)
break;
}
memset(tsk,0,sizeof(struct threadObject));
tsk->client_sockd = client_sockd;
tsk->tsk_inuse = 1;
pthread_mutex_unlock(&global_mutex);
// fire in the hole ...
pthread_create(&tsk->tsk_threadid, NULL, handle_connections, tsk);
}
#endif
#if 0
for (int i = 0; i < threadNum; i++) {
printf("\n[+] server is waiting...\n");
thread[i].client_sockd = accept(server_sockd, &client_addr, &client_addrlen);
handle_connections(&thread[i]);
// pthread_create(&thread_id[i], NULL, handle_connections, &thread[i]);
printf("Response Sent\n");
// close the current client socket
close(thread[i].client_sockd);
}
}
#endif
return EXIT_SUCCESS;
}
Here's the complete code [just in case I clipped out too much]:
#include <sys/socket.h>
#include <sys/stat.h>
#include <stdio.h>
#include <netinet/in.h>
#include <netinet/ip.h>
#include <fcntl.h>
#include <unistd.h> // write
#include <string.h> // memset
#include <stdlib.h> // atoi
#include <stdbool.h> // true, false
#include <errno.h>
#include <sys/types.h>
#include <ctype.h>
#include <pthread.h>
#define BUFFER_SIZE 4096
#if 1
pthread_mutex_t global_mutex = PTHREAD_MUTEX_INITIALIZER;
#endif
struct threadObject {
char method[5]; // PUT, HEAD, GET. HEAD==4 letters+null terminator
char filename[28]; // what is the file we are worried about. Max 27 ASCII characters (NULL terminated on 28)
char httpversion[9]; // HTTP/1.1
ssize_t content_length; // example: 13
uint16_t status_code; // status code for the request
char buffer[BUFFER_SIZE]; // buffer to transfer data
char rest_of_PUT[BUFFER_SIZE]; // incase client send part of PUT message in header
int client_sockd;
pthread_mutex_t *dispatch_lock;
const pthread_cond_t *job_pool_empty;
// pthread_mutex_t* log_lock;
// const pthread_cond_t* log_pool_empty;
pthread_mutex_t *read_write_lock;
pthread_cond_t *file_list_update;
// JobQueue* job_pool;
// LogQueue log_pool;
// bool is_logging;
#if 1
pthread_t tsk_threadid;
int tsk_inuse;
int tsk_done;
#endif
};
//read in the header and store it in the appropriate places
bool
read_http_response(struct threadObject *thread)
{
printf("\nThis function will take care of reading message\n");
// how many bytes we're receiving from the header. also puts the message into the buffer
ssize_t bytes = recv(thread->client_sockd, thread->buffer, BUFFER_SIZE, 0);
// if nothing or too much gets sent in the header, return
if (bytes <= 0 || bytes >= BUFFER_SIZE) {
thread->status_code = 400;
printf("Too long or nothing in here\n");
return false;
}
// NULL terminate the last spot on the buffer
thread->buffer[bytes] = '\0';
// how many bytes we received
printf("[+] received %ld bytes from client\n[+] response: \n", bytes);
printf("those bytes are: %s\n", thread->buffer);
// make a char pointer pointer to the buffer to easily traverse it and parse it into the right spots
char *traverse = thread->buffer;
// first stop. sgnals the beginning of the filename
char *file = strstr(traverse, "/");
// 2nd stop. signls the beginning of the HTTP version. only 1.1 is accepted
char *http = strstr(traverse, "HTTP/1.1");
// 3rd stop. Signals the beginning of the content length
char *contlength1 = strstr(traverse, "Content-Length");
char *chunked = strstr(traverse, "chunked");
if (chunked != NULL) {
printf("MESSAGE NOT A FILE PUT\n");
thread->status_code = 403;
return false;
}
// store the method
sscanf(traverse, "%s", thread->method);
printf("method:%s\n", thread->method);
// if its not 1 of the 3 valid requests, throw 400 error
if (strcmp(thread->method, "GET") != 0 &&
strcmp(thread->method, "PUT") != 0 &&
strcmp(thread->method, "HEAD") != 0) {
thread->status_code = 400;
printf("Invalid Method:%s\n", thread->method);
return false;
}
// if the filename doesnt start with /, its invalid throw 400 error
if (*file != '/') {
thread->status_code = 400;
printf("bad filename\n");
return false;
}
// only store the filename portion after the required /
traverse = file + 1;
// to make sure the filename isnt too long
uint8_t size_check = 0;
// traverse filename until first whitespace
while (*traverse != ' ') {
// if any character in the filename isnt 1 of these, its invalid. throw 400 error
if (!isalnum(*traverse) && *traverse != '_' && *traverse != '-') {
// if theres no filename at all, throw a 404 error
if (size_check == 0) {
thread->status_code = 404;
printf("No file specified\n");
return thread->status_code;
}
thread->status_code = 400;
printf("Invalid filename character:%c\n", *traverse);
return false;
}
sscanf(traverse++, "%c", thread->filename + size_check++);
// if the filename breaks the 27 character limit, return a 400 error
if (size_check > 27) {
thread->status_code = 400;
printf("filename too long\n");
return false;
}
}
printf("filename:%s\n", thread->filename);
// if HTTP/1.1 isnt given, throw a 400 error
if (http == NULL) {
printf("HTTP/1.1 400 Bad Request\r\n\r\n");
thread->status_code = 400;
return false;
}
traverse = http;
// read in the http version until the first \r\n. this signals the end of the given version name
sscanf(traverse, "%[^\r\n]s", thread->httpversion);
printf("HTTP:%s\n", thread->httpversion);
// if its not a put request, this is the end of the header. return
if (strcmp(thread->method, "PUT") != 0) {
return true;
}
// for put requests only. traverse until the beginning of the content length
traverse = contlength1;
// last stop. signals the end of a normal PUT header. if a client wants to put some of the message in the header, it gets stored after this
char *end = strstr(traverse, "\r\n\r\n");
// if theres no \r\n\r\n, the header is bad. return 400
if (end == NULL) {
printf("bad header\n");
thread->status_code = 400;
return false;
}
// traverse to the next digit
while (!isdigit(*traverse)) {
// if theres no next digit after "content length", the header is bad. return 400
if (traverse == end) {
printf("bad header\n");
thread->status_code = 400;
return false;
}
traverse++;
}
// set to traverse to be sure fit the entire content length. use size_check to traverse through
char *temp = traverse;
size_check = 0;
// while its taking in digits, put them into the char array.
while (isdigit(*traverse)) {
sscanf(traverse++, "%c", temp + size_check++);
}
// convert the new string into numbers
thread->content_length = atoi(temp);
// if the content length is < 0 throw a 400 error
if (thread->content_length < 0) {
thread->status_code = 400;
printf("bad content length:%ld\n", thread->content_length);
return false;
}
// printf("Content Length:%ld\n", thread->content_length);
// move +4 spots to get to the end of this. if its a normal PUT, this will be the last spot. If the client puts part of the message in the header, it goes after this
traverse = end + 4;
// put the rest of the header into a char array to append later. if theres nothing, itll do nothing
strcpy(thread->rest_of_PUT, traverse);
// printf("Rest of PUT:%s\n", thread->rest_of_PUT);
// will only get here if status code is 0
return true;
}
//process the message we just recieved
void
process_request(struct threadObject *thread)
{
printf("\nProcessing Request\n");
// server side file descriptor
int fd;
// if the method is PUT
if (strcmp(thread->method, "PUT") == 0) {
// open the file for read only to check if its already there or not to set proper status code
fd = open(thread->filename, O_WRONLY);
// if it doesnt exist, set 201 status code
struct stat checkExist;
if (stat(thread->filename, &checkExist) != 0) {
thread->status_code = 201;
}
// if it exists, set 200 and overwrite
else {
struct stat fileStat;
fstat(fd, &fileStat);
// check write permission
if ((S_IWUSR & fileStat.st_mode) == 0) {
printf("MESSAGE NOT WRITEABLE PUT\n");
thread->status_code = 403;
return;
}
thread->status_code = 200;
}
// close it
close(fd);
// reopen it. this time for writing to or overwriting. if its there, overwrite it. if not, create it. cant use for status codes since it will always create a new file
fd = open(thread->filename, O_WRONLY | O_CREAT | O_TRUNC);
// printf("fd in process is:%d\n", fd);
// if theres a bad fd, throw a 403
if (fd < 0) {
printf("ERROR\n\n");
thread->status_code = 403;
return;
}
// to check that the amount of bytes sent = the amount received
ssize_t bytes_recv,
bytes_send;
// if theres no body, put an empty file on the server
if (thread->content_length == 0) {
bytes_send = write(fd, '\0', 0);
}
// if there is a body, put it onto the new file created on the server and make sure the received bytes = the sent ones
else {
ssize_t total = 0,
len_track = thread->content_length;
while (thread->content_length != 0) {
bytes_recv = recv(thread->client_sockd, thread->buffer, BUFFER_SIZE, 0);
bytes_send = write(fd, thread->buffer, bytes_recv);
total += bytes_send;
// if the received bytes != the sent byes, send a 500 error
if (bytes_recv != bytes_send) {
thread->status_code = 500;
printf("Recieved != sent for put request\n");
return;
}
thread->content_length -= bytes_recv;
// printf("Bytes read:%ld\nBytes sent:%ld\nMessage content length:%ld\n", bytes_recv, bytes_send, message->content_length);
}
// if the content length != bytes sent, throw a 403 error
if (len_track != total) {
thread->status_code = 403;
printf("Content length != sent for put request\n");
return;
}
}
printf("Message status code:%d\n", thread->status_code);
// close the fd
close(fd);
return;
}
// if the method is GET or HEAD
else if (strcmp(thread->method, "GET") == 0 || strcmp(thread->method, "HEAD") == 0) {
// open the file for reading only
fd = open(thread->filename, O_RDONLY);
// if bad fd, throw a 404
struct stat fileStat;
fstat(fd, &fileStat);
// check read permission and if it exists
if (((S_IRUSR & fileStat.st_mode) == 0) || stat(thread->filename, &fileStat) != 0) {
printf("BAD GET\n");
thread->status_code = 404;
return;
}
else {
thread->status_code = 200;
thread->content_length = lseek(fd, 0, SEEK_END);
}
// close the fd
close(fd);
return;
}
}
void
construct_http_response(struct threadObject *thread)
{
printf("Constructing Response\n");
// size 22 since the largest code is 21 characters + NULL
char response[22];
// 200=OK, 201=CREATED, 400=BAD REQUEST, 403=FORBIDDEN, 404=NOT FOUND, 500=INTERNAL SERVER ERROR
if (thread->status_code == 200) {
strcpy(response, "OK");
}
else if (thread->status_code == 201) {
strcpy(response, "CREATED");
}
else if (thread->status_code == 400) {
strcpy(response, "BAD REQUEST");
}
else if (thread->status_code == 403) {
strcpy(response, "FORBIDDEN");
}
else if (thread->status_code == 404) {
strcpy(response, "NOT FOUND");
}
else if (thread->status_code == 500) {
strcpy(response, "INTERNAL SERVER ERROR");
}
else {
printf("Bad response...\n");
return;
}
dprintf(thread->client_sockd, "%s %d %s\r\nContent-Length: %ld\r\n\r\n", thread->httpversion, thread->status_code, response, thread->content_length);
if (strcmp(thread->method, "GET") == 0 && thread->status_code == 200) {
int fd = open(thread->filename, O_RDONLY);
ssize_t total = 0,
len_track = thread->content_length,
bytes_recv,
bytes_send;
while (thread->content_length != 0) {
bytes_recv = read(fd, thread->buffer, BUFFER_SIZE);
bytes_send = send(thread->client_sockd, thread->buffer, bytes_recv, 0);
if (bytes_recv != bytes_send) {
thread->status_code = 500;
close(fd);
printf("Recieved != sent for GET request\nReceived:%ld\nSent:%ld\n", bytes_recv, bytes_send);
dprintf(thread->client_sockd, "%s %d %s\r\nContent-Length: %ld\r\n\r\n", thread->httpversion, thread->status_code, response, thread->content_length);
close(fd);
return;
}
total += bytes_send;
thread->content_length -= bytes_recv;
}
if (total != len_track) {
thread->status_code = 403;
printf("Content length != recvd for GET request\n");
dprintf(thread->client_sockd, "%s %d %s\r\nContent-Length: %ld\r\n\r\n", thread->httpversion, thread->status_code, response, thread->content_length);
close(fd);
return;
}
close(fd);
}
}
void *
handle_connections(void *ptr_thread)
{
// create a mutual exclusion to lock out any other threads from the function
// pthread_mutex_t mutex = PTHREAD_MUTEX_INITIALIZER;
// pthread_mutex_lock(&mutex);
// operations go here
struct threadObject *thread = (struct threadObject *) ptr_thread;
// reset message after each loop
memset(thread->buffer, '\0', BUFFER_SIZE);
memset(thread->method, '\0', 5);
memset(thread->filename, '\0', 28);
memset(thread->httpversion, '\0', 9);
thread->content_length = 0;
thread->status_code = 0;
memset(thread->rest_of_PUT, '\0', BUFFER_SIZE);
// read message
if (read_http_response(thread) == true) {
// process message
process_request(thread);
}
// construct a response
construct_http_response(thread);
// unlock the function
// pthread_mutex_unlock(&mutex);
#if 1
close(thread->client_sockd);
pthread_mutex_lock(&global_mutex);
thread->tsk_done = 1;
pthread_mutex_unlock(&global_mutex);
#endif
return NULL;
}
int
main(int argc, char **argv)
{
// Create sockaddr_in with server information
if (argc < 2) {
perror("No arguments passed\n");
return -1;
}
// make sure port number is above 1024 and set the port # to it
if (atoi(argv[1]) < 1024) {
return 1;
}
char *port = argv[1];
// parse the command line args for options -l and -N. -l specifies it will use a log and the following parameter is the filename. -N specifies the number of threads it will use and the following parameter will be a number
int opt;
uint8_t threadNum = 1;
char *logName = NULL;
while ((opt = getopt(argc - 1, argv + 1, "N:l:")) != -1) {
if (opt == 'N') {
threadNum = atoi(optarg);
}
else if (opt == 'l') {
logName = optarg;
}
}
struct sockaddr_in server_addr;
memset(&server_addr, 0, sizeof(server_addr));
server_addr.sin_family = AF_INET;
server_addr.sin_port = htons(atoi(port));
server_addr.sin_addr.s_addr = htonl(INADDR_ANY);
socklen_t addrlen = sizeof(server_addr);
// Create server socket
int server_sockd = socket(AF_INET, SOCK_STREAM, 0);
// Need to check if server_sockd < 0, meaning an error
if (server_sockd < 0) {
perror("socket");
return 1;
}
// Configure server socket
int enable = 1;
// This allows you to avoid: 'Bind: Address Already in Use' error
int ret = setsockopt(server_sockd, SOL_SOCKET, SO_REUSEADDR, &enable, sizeof(enable));
if (ret < 0) {
return EXIT_FAILURE;
}
// Bind server address to socket that is open
ret = bind(server_sockd, (struct sockaddr *) &server_addr, addrlen);
if (ret < 0) {
return EXIT_FAILURE;
}
// Listen for incoming connections
ret = listen(server_sockd, 5); // 5 should be enough, if not use SOMAXCONN
if (ret < 0) {
return EXIT_FAILURE;
}
struct threadObject thread[threadNum];
// Connecting with a client
struct sockaddr client_addr;
socklen_t client_addrlen = sizeof(client_addr);
// create a pthread array of size (number of threads). specify this will be using the handle connections function. join the threads together
#if 0
pthread_t thread_id[threadNum];
#endif
#if 1
struct threadObject *tsk = NULL;
int tskidx;
// clear out the thread structs
for (tskidx = 0; tskidx < threadNum; tskidx++) {
tsk = &thread[tskidx];
memset(tsk,0,sizeof(struct threadObject));
}
while (true) {
// accept connection
int client_sockd = accept(server_sockd, &client_addr, &client_addrlen);
pthread_mutex_lock(&global_mutex);
// join any previously completed threads
for (tskidx = 0; tskidx < threadNum; tskidx++) {
tsk = &thread[tskidx];
if (tsk->tsk_done) {
pthread_join(tsk->tsk_threadid,NULL);
tsk->tsk_inuse = 0;
tsk->tsk_done = 0;
}
}
// find unused task slot
for (tskidx = 0; tskidx < threadNum; tskidx++) {
tsk = &thread[tskidx];
if (! tsk->tsk_inuse)
break;
}
memset(tsk,0,sizeof(struct threadObject));
tsk->client_sockd = client_sockd;
tsk->tsk_inuse = 1;
pthread_mutex_unlock(&global_mutex);
// fire in the hole ...
pthread_create(&tsk->tsk_threadid, NULL, handle_connections, tsk);
}
#endif
#if 0
for (int i = 0; i < threadNum; i++) {
printf("\n[+] server is waiting...\n");
thread[i].client_sockd = accept(server_sockd, &client_addr, &client_addrlen);
handle_connections(&thread[i]);
// pthread_create(&thread_id[i], NULL, handle_connections, &thread[i]);
printf("Response Sent\n");
// close the current client socket
close(thread[i].client_sockd);
}
}
#endif
return EXIT_SUCCESS;
}
Got some trouble with TCP socket multiplexing.
//socket is non-blocking
const int MAX = 4096;
char *buff[MAX];
char *p = buff;
int fd, rvalue;
rvalue = 0;
if ( (fd = open(path, O_RDONLY)) < 0 ) {
return errno;
} else {
int didsend, didread;
int shouldsend;
while ((didread = read(fd, buff, MAX)) > 0) {
p = buff;
shouldsend = didread;
while ( 1 ) {
didsend = send(sockfd, p, shouldsend, 0);
//if send succeeds and returns the number of bytes fewer than asked for then try to send rest part in next time.
if (didsend < shouldsend) {
p += didsent;
shouldsend -= didsend;
continue;
}
//if there is no place for new data to send, then wait a brief time and try again.
if ( didsend < 0 && (errno == EWOULDBLOCK || errno == EAGAIN) ) {
usleep(1000);
continue;
}
//if all data has been sent then sending loop is over.
if (didsend == shouldsend) {
break;
}
//send error
if ( didsend < 0 ) {
rvalue = errno;
break;
}
}
}
close(fd);
if (didread == -1) {
return errno;
}
return rvalue;
}
Assume I use an I/O Multiplexing function poll() or kqueue(), and non-blocking socket, then if there are only some small data like send a short message, it works fine.
But if it comes to large data, I mean larger than send()'s buffer size, since using non-blocking socket, send() will just send a portion of data, and return how much data it sends, the rest part of data can only be sent in another call of send(), but it takes time, and can't tell how long it will takes. So the second while() is actually a blocking send which using non-blocking socket.
Equivalent to:
//socket is blocking
const int MAX = 4096;
char *buff[MAX];
int fd, n;
if ( (fd = open(path, O_RDONLY)) < 0 ) {
return errno;
} else {
while ((n = read(fd, buff, MAX)) > 0) {
if (send(sockfd, buff, n, 0) < 0) {
return errno;
}
}
close(fd);
return 0;
}
So, what is the solution to this, multithreading might work but that's kind of wasting resource maybe.
This is the general pattern for a single-threaded server that works with multiple connections and non-blocking sockets.
It's primarily pseudo-code in C and doesn't do the necessary error checking. But it gives you an idea that for each accepted connection, you keep a struct instance that maintains the socket handle, request parsing state, response stream, and any other "state" members of that connection. Then you just loop using "select" to wait or having multiple threads doing this same thing.
Again this is only pseudo-code and uses select/poll as an example. You can get even more scalability with epoll.
while (1)
{
fd_set readset = {};
fd_set writeset = {};
for (int i = 0; i < number_of_client_connections; i++)
{
if (client_connections[i].reading_request)
FD_SET(client_connection.sock, &readset);
else
FD_SET(client_connection.sock, &writeset);
}
// add the listen socket to the read set
FD_SET(listen_socket, &readset);
select(n + 1, &readset, &writeset, &timeout); // wait for a socket to be ready (not shown - check for errors and return value)
if (FD_ISSET(listen_socket, &readset))
{
int new_client_socket = accept(listen_socket, &addr, &addrlength);
// create a struct that keeps track of the connection state data
struct ConnectionData client_connection = {};
client_connection.sock = new_client_socket;
client_connection.reading_request = 1; // awaiting for all the request bytes to come in
client_connections[number_of_client_connections++] = client_connection; // pseudo code, add the client_connection to the list
}
for (int i = 0; i < number_of_client_connections; i++)
{
if (client_connections[i].reading_request)
{
if (FD_ISSET(client_connections[i], &readset))
{
char buffer[2000];
int len = recv(client_connections[i].sock, buffer, 2000, 0);
// not shown - handle error case when (recv < 0)
// not shown - handle case when (recv == 0)
ProcessIncomingData(client_connections[i], buffer, len); // do all the request parsing here. Flip the client_connections[i].reading_request to 0 if ready to respond
}
}
else if (client_connections[i].reading_request == 0)
{
if (FD_ISSET(client_connections[i], &writeset))
{
client_connection* conn = &client_connections[i];
int len = send(conn->sock, conn->response_buffer + conn->txCount, conn->response_size - conn->txCount, 0);
conn->txCount += len;
if (conn->txCount == conn->response_size)
{
// done sending response - we can close this connection or change it to back to the reading state
}
}
}
}