mongoose/examples/chat.c

388 lines
13 KiB
C

// This file is part of the Mongoose project, http://code.google.com/p/mongoose
// It implements an online chat server. For more details,
// see the documentation on the project web site.
// To test the application,
// 1. type "make" in the directory where this file lives
// 2. point your browser to http://127.0.0.1:8081
#include <stdio.h>
#include <stdlib.h>
#include <assert.h>
#include <string.h>
#include <time.h>
#include <stdarg.h>
#include <pthread.h>
#include "mongoose.h"
#define MAX_USER_LEN 20
#define MAX_MESSAGE_LEN 100
#define MAX_MESSAGES 5
#define MAX_SESSIONS 2
#define SESSION_TTL 120
static const char *authorize_url = "/authorize";
static const char *login_url = "/login.html";
static const char *ajax_reply_start =
"HTTP/1.1 200 OK\r\n"
"Cache: no-cache\r\n"
"Content-Type: application/x-javascript\r\n"
"\r\n";
// Describes single message sent to a chat. If user is empty (0 length),
// the message is then originated from the server itself.
struct message {
long id; // Message ID
char user[MAX_USER_LEN]; // User that have sent the message
char text[MAX_MESSAGE_LEN]; // Message text
time_t timestamp; // Message timestamp, UTC
};
// Describes web session.
struct session {
char session_id[33]; // Session ID, must be unique
char random[20]; // Random data used for extra user validation
char user[MAX_USER_LEN]; // Authenticated user
time_t expire; // Expiration timestamp, UTC
};
static struct message messages[MAX_MESSAGES]; // Ringbuffer for messages
static struct session sessions[MAX_SESSIONS]; // Current sessions
static long last_message_id;
// Protects messages, sessions, last_message_id
static pthread_rwlock_t rwlock = PTHREAD_RWLOCK_INITIALIZER;
// Get session object for the connection. Caller must hold the lock.
static struct session *get_session(const struct mg_connection *conn) {
int i;
char session_id[33];
time_t now = time(NULL);
mg_get_cookie(conn, "session", session_id, sizeof(session_id));
for (i = 0; i < MAX_SESSIONS; i++) {
if (sessions[i].expire != 0 &&
sessions[i].expire > now &&
strcmp(sessions[i].session_id, session_id) == 0) {
break;
}
}
return i == MAX_SESSIONS ? NULL : &sessions[i];
}
static void get_qsvar(const struct mg_request_info *request_info,
const char *name, char *dst, size_t dst_len) {
const char *qs = request_info->query_string;
mg_get_var(qs, strlen(qs == NULL ? "" : qs), name, dst, dst_len);
}
// Get a get of messages with IDs greater than last_id and transform them
// into a JSON string. Return that string to the caller. The string is
// dynamically allocated, caller must free it. If there are no messages,
// NULL is returned.
static char *messages_to_json(long last_id) {
const struct message *message;
int max_msgs, len;
char buf[sizeof(messages)]; // Large enough to hold all messages
// Read-lock the ringbuffer. Loop over all messages, making a JSON string.
pthread_rwlock_rdlock(&rwlock);
len = 0;
max_msgs = sizeof(messages) / sizeof(messages[0]);
// If client is too far behind, return all messages.
if (last_message_id - last_id > max_msgs) {
last_id = last_message_id - max_msgs;
}
for (; last_id < last_message_id; last_id++) {
message = &messages[last_id % max_msgs];
if (message->timestamp == 0) {
break;
}
// buf is allocated on stack and hopefully is large enough to hold all
// messages (it may be too small if the ringbuffer is full and all
// messages are large. in this case asserts will trigger).
len += snprintf(buf + len, sizeof(buf) - len,
"{user: '%s', text: '%s', timestamp: %lu, id: %lu},",
message->user, message->text, message->timestamp, message->id);
assert(len > 0);
assert((size_t) len < sizeof(buf));
}
pthread_rwlock_unlock(&rwlock);
return len == 0 ? NULL : strdup(buf);
}
// If "callback" param is present in query string, this is JSONP call.
// Return 1 in this case, or 0 if "callback" is not specified.
// Wrap an output in Javascript function call.
static int handle_jsonp(struct mg_connection *conn,
const struct mg_request_info *request_info) {
char cb[64];
get_qsvar(request_info, "callback", cb, sizeof(cb));
if (cb[0] != '\0') {
mg_printf(conn, "%s(", cb);
}
return cb[0] == '\0' ? 0 : 1;
}
// A handler for the /ajax/get_messages endpoint.
// Return a list of messages with ID greater than requested.
static void ajax_get_messages(struct mg_connection *conn,
const struct mg_request_info *request_info) {
char last_id[32], *json;
int is_jsonp;
mg_printf(conn, "%s", ajax_reply_start);
is_jsonp = handle_jsonp(conn, request_info);
get_qsvar(request_info, "last_id", last_id, sizeof(last_id));
if ((json = messages_to_json(strtoul(last_id, NULL, 10))) != NULL) {
mg_printf(conn, "[%s]", json);
free(json);
}
if (is_jsonp) {
mg_printf(conn, "%s", ")");
}
}
// Allocate new message. Caller must hold the lock.
static struct message *new_message(void) {
static int size = sizeof(messages) / sizeof(messages[0]);
struct message *message = &messages[last_message_id % size];
message->id = last_message_id++;
message->timestamp = time(0);
return message;
}
static void my_strlcpy(char *dst, const char *src, size_t len) {
strncpy(dst, src, len);
dst[len - 1] = '\0';
}
// A handler for the /ajax/send_message endpoint.
static void ajax_send_message(struct mg_connection *conn,
const struct mg_request_info *request_info) {
struct message *message;
struct session *session;
char text[sizeof(message->text) - 1];
int is_jsonp;
mg_printf(conn, "%s", ajax_reply_start);
is_jsonp = handle_jsonp(conn, request_info);
get_qsvar(request_info, "text", text, sizeof(text));
if (text[0] != '\0') {
// We have a message to store. Write-lock the ringbuffer,
// grab the next message and copy data into it.
pthread_rwlock_wrlock(&rwlock);
message = new_message();
// TODO(lsm): JSON-encode all text strings
session = get_session(conn);
assert(session != NULL);
my_strlcpy(message->text, text, sizeof(text));
my_strlcpy(message->user, session->user, sizeof(message->user));
pthread_rwlock_unlock(&rwlock);
}
mg_printf(conn, "%s", text[0] == '\0' ? "false" : "true");
if (is_jsonp) {
mg_printf(conn, "%s", ")");
}
}
// Redirect user to the login form. In the cookie, store the original URL
// we came from, so that after the authorization we could redirect back.
static void redirect_to_login(struct mg_connection *conn,
const struct mg_request_info *request_info) {
mg_printf(conn, "HTTP/1.1 302 Found\r\n"
"Set-Cookie: original_url=%s\r\n"
"Location: %s\r\n\r\n",
request_info->uri, login_url);
}
// Return 1 if username/password is allowed, 0 otherwise.
static int check_password(const char *user, const char *password) {
// In production environment we should ask an authentication system
// to authenticate the user.
// Here however we do trivial check that user and password are not empty
return (user[0] && password[0]);
}
// Allocate new session object
static struct session *new_session(void) {
int i;
time_t now = time(NULL);
pthread_rwlock_wrlock(&rwlock);
for (i = 0; i < MAX_SESSIONS; i++) {
if (sessions[i].expire == 0 || sessions[i].expire < now) {
sessions[i].expire = time(0) + SESSION_TTL;
break;
}
}
pthread_rwlock_unlock(&rwlock);
return i == MAX_SESSIONS ? NULL : &sessions[i];
}
// Generate session ID. buf must be 33 bytes in size.
// Note that it is easy to steal session cookies by sniffing traffic.
// This is why all communication must be SSL-ed.
static void generate_session_id(char *buf, const char *random,
const char *user) {
mg_md5(buf, random, user, NULL);
}
static void send_server_message(const char *fmt, ...) {
va_list ap;
struct message *message;
pthread_rwlock_wrlock(&rwlock);
message = new_message();
message->user[0] = '\0'; // Empty user indicates server message
va_start(ap, fmt);
vsnprintf(message->text, sizeof(message->text), fmt, ap);
va_end(ap);
pthread_rwlock_unlock(&rwlock);
}
// A handler for the /authorize endpoint.
// Login page form sends user name and password to this endpoint.
static void authorize(struct mg_connection *conn,
const struct mg_request_info *request_info) {
char user[MAX_USER_LEN], password[MAX_USER_LEN];
struct session *session;
// Fetch user name and password.
get_qsvar(request_info, "user", user, sizeof(user));
get_qsvar(request_info, "password", password, sizeof(password));
if (check_password(user, password) && (session = new_session()) != NULL) {
// Authentication success:
// 1. create new session
// 2. set session ID token in the cookie
// 3. remove original_url from the cookie - not needed anymore
// 4. redirect client back to the original URL
//
// The most secure way is to stay HTTPS all the time. However, just to
// show the technique, we redirect to HTTP after the successful
// authentication. The danger of doing this is that session cookie can
// be stolen and an attacker may impersonate the user.
// Secure application must use HTTPS all the time.
my_strlcpy(session->user, user, sizeof(session->user));
snprintf(session->random, sizeof(session->random), "%d", rand());
generate_session_id(session->session_id, session->random, session->user);
send_server_message("<%s> joined", session->user);
mg_printf(conn, "HTTP/1.1 302 Found\r\n"
"Set-Cookie: session=%s; max-age=3600; http-only\r\n" // Session ID
"Set-Cookie: user=%s\r\n" // Set user, needed by Javascript code
"Set-Cookie: original_url=/; max-age=0\r\n" // Delete original_url
"Location: /\r\n\r\n",
session->session_id, session->user);
} else {
// Authentication failure, redirect to login.
redirect_to_login(conn, request_info);
}
}
// Return 1 if request is authorized, 0 otherwise.
static int is_authorized(const struct mg_connection *conn,
const struct mg_request_info *request_info) {
struct session *session;
char valid_id[33];
int authorized = 0;
// Always authorize accesses to login page and to authorize URI
if (!strcmp(request_info->uri, login_url) ||
!strcmp(request_info->uri, authorize_url)) {
return 1;
}
pthread_rwlock_rdlock(&rwlock);
if ((session = get_session(conn)) != NULL) {
generate_session_id(valid_id, session->random, session->user);
if (strcmp(valid_id, session->session_id) == 0) {
session->expire = time(0) + SESSION_TTL;
authorized = 1;
}
}
pthread_rwlock_unlock(&rwlock);
return authorized;
}
static void redirect_to_ssl(struct mg_connection *conn,
const struct mg_request_info *request_info) {
const char *p, *host = mg_get_header(conn, "Host");
if (host != NULL && (p = strchr(host, ':')) != NULL) {
mg_printf(conn, "HTTP/1.1 302 Found\r\n"
"Location: https://%.*s:8082/%s:8082\r\n\r\n",
(int) (p - host), host, request_info->uri);
} else {
mg_printf(conn, "%s", "HTTP/1.1 500 Error\r\n\r\nHost: header is not set");
}
}
static void *event_handler(enum mg_event event,
struct mg_connection *conn) {
const struct mg_request_info *request_info = mg_get_request_info(conn);
void *processed = "yes";
if (event == MG_NEW_REQUEST) {
if (!request_info->is_ssl) {
redirect_to_ssl(conn, request_info);
} else if (!is_authorized(conn, request_info)) {
redirect_to_login(conn, request_info);
} else if (strcmp(request_info->uri, authorize_url) == 0) {
authorize(conn, request_info);
} else if (strcmp(request_info->uri, "/ajax/get_messages") == 0) {
ajax_get_messages(conn, request_info);
} else if (strcmp(request_info->uri, "/ajax/send_message") == 0) {
ajax_send_message(conn, request_info);
} else {
// No suitable handler found, mark as not processed. Mongoose will
// try to serve the request.
processed = NULL;
}
} else {
processed = NULL;
}
return processed;
}
static const char *options[] = {
"document_root", "html",
"listening_ports", "8081,8082s",
"ssl_certificate", "ssl_cert.pem",
"num_threads", "5",
NULL
};
int main(void) {
struct mg_context *ctx;
// Initialize random number generator. It will be used later on for
// the session identifier creation.
srand((unsigned) time(0));
// Setup and start Mongoose
if ((ctx = mg_start(&event_handler, NULL, options)) == NULL) {
printf("%s\n", "Cannot start chat server, fatal exit");
exit(EXIT_FAILURE);
}
// Wait until enter is pressed, then exit
printf("Chat server started on ports %s, press enter to quit.\n",
mg_get_option(ctx, "listening_ports"));
getchar();
mg_stop(ctx);
printf("%s\n", "Chat server stopped.");
return EXIT_SUCCESS;
}
// vim:ts=2:sw=2:et