/* Licensed to the Apache Software Foundation (ASF) under one or more * contributor license agreements. See the NOTICE file distributed with * this work for additional information regarding copyright ownership. * The ASF licenses this file to You under the Apache License, Version 2.0 * (the "License"); you may not use this file except in compliance with * the License. You may obtain a copy of the License at * * http://www.apache.org/licenses/LICENSE-2.0 * * Unless required by applicable law or agreed to in writing, software * distributed under the License is distributed on an "AS IS" BASIS, * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. * See the License for the specific language governing permissions and * limitations under the License. */ #ifdef WIN32 #define CORE_PRIVATE #include "httpd.h" #include "http_main.h" #include "http_log.h" #include "http_config.h" /* for read_config */ #include "http_core.h" /* for get_remote_host */ #include "http_connection.h" #include "apr_portable.h" #include "apr_thread_proc.h" #include "apr_getopt.h" #include "apr_strings.h" #include "apr_lib.h" #include "apr_shm.h" #include "apr_thread_mutex.h" #include "ap_mpm.h" #include "ap_config.h" #include "ap_listen.h" #include "mpm_default.h" #include "mpm_winnt.h" #include "mpm_common.h" #include #include "apr_atomic.h" /* shared with mpm_winnt.c */ extern DWORD my_pid; /* used by parent to signal the child to start and exit */ /* shared with mpm_winnt.c, but should be private to child.c */ apr_proc_mutex_t *start_mutex; HANDLE exit_event; /* child_main() should never need to modify is_graceful!?! */ extern int volatile is_graceful; /* Queue for managing the passing of COMP_CONTEXTs between * the accept and worker threads. */ static apr_pool_t *pchild; static int shutdown_in_progress = 0; static int workers_may_exit = 0; static unsigned int g_blocked_threads = 0; static HANDLE max_requests_per_child_event; static apr_thread_mutex_t *child_lock; static apr_thread_mutex_t *qlock; static PCOMP_CONTEXT qhead = NULL; static PCOMP_CONTEXT qtail = NULL; static int num_completion_contexts = 0; static int max_num_completion_contexts = 0; static HANDLE ThreadDispatchIOCP = NULL; static HANDLE qwait_event = NULL; AP_DECLARE(void) mpm_recycle_completion_context(PCOMP_CONTEXT context) { /* Recycle the completion context. * - clear the ptrans pool * - put the context on the queue to be consumed by the accept thread * Note: * context->accept_socket may be in a disconnected but reusable * state so -don't- close it. */ if (context) { apr_pool_clear(context->ptrans); context->ba = apr_bucket_alloc_create(context->ptrans); context->next = NULL; ResetEvent(context->Overlapped.hEvent); apr_thread_mutex_lock(qlock); if (qtail) { qtail->next = context; } else { qhead = context; SetEvent(qwait_event); } qtail = context; apr_thread_mutex_unlock(qlock); } } AP_DECLARE(PCOMP_CONTEXT) mpm_get_completion_context(void) { apr_status_t rv; PCOMP_CONTEXT context = NULL; while (1) { /* Grab a context off the queue */ apr_thread_mutex_lock(qlock); if (qhead) { context = qhead; qhead = qhead->next; if (!qhead) qtail = NULL; } else { ResetEvent(qwait_event); } apr_thread_mutex_unlock(qlock); if (!context) { /* We failed to grab a context off the queue, consider allocating * a new one out of the child pool. There may be up to * (ap_threads_per_child + num_listeners) contexts in the system * at once. */ if (num_completion_contexts >= max_num_completion_contexts) { /* All workers are busy, need to wait for one */ static int reported = 0; if (!reported) { ap_log_error(APLOG_MARK, APLOG_WARNING, 0, ap_server_conf, "Server ran out of threads to serve requests. Consider " "raising the ThreadsPerChild setting"); reported = 1; } /* Wait for a worker to free a context. Once per second, give * the caller a chance to check for shutdown. If the wait * succeeds, get the context off the queue. It must be available, * since there's only one consumer. */ rv = WaitForSingleObject(qwait_event, 1000); if (rv == WAIT_OBJECT_0) continue; else /* Hopefully, WAIT_TIMEOUT */ return NULL; } else { /* Allocate another context. * Note: * Multiple failures in the next two steps will cause the pchild pool * to 'leak' storage. I don't think this is worth fixing... */ apr_allocator_t *allocator; apr_thread_mutex_lock(child_lock); context = (PCOMP_CONTEXT) apr_pcalloc(pchild, sizeof(COMP_CONTEXT)); context->Overlapped.hEvent = CreateEvent(NULL, TRUE, FALSE, NULL); if (context->Overlapped.hEvent == NULL) { /* Hopefully this is a temporary condition ... */ ap_log_error(APLOG_MARK,APLOG_WARNING, apr_get_os_error(), ap_server_conf, "mpm_get_completion_context: CreateEvent failed."); apr_thread_mutex_unlock(child_lock); return NULL; } /* Create the tranaction pool */ apr_allocator_create(&allocator); apr_allocator_max_free_set(allocator, ap_max_mem_free); rv = apr_pool_create_ex(&context->ptrans, pchild, NULL, allocator); if (rv != APR_SUCCESS) { ap_log_error(APLOG_MARK,APLOG_WARNING, rv, ap_server_conf, "mpm_get_completion_context: Failed to create the transaction pool."); CloseHandle(context->Overlapped.hEvent); apr_thread_mutex_unlock(child_lock); return NULL; } apr_allocator_owner_set(allocator, context->ptrans); apr_pool_tag(context->ptrans, "transaction"); context->accept_socket = INVALID_SOCKET; context->ba = apr_bucket_alloc_create(context->ptrans); apr_atomic_inc(&num_completion_contexts); apr_thread_mutex_unlock(child_lock); break; } } else { /* Got a context from the queue */ break; } } return context; } AP_DECLARE(apr_status_t) mpm_post_completion_context(PCOMP_CONTEXT context, io_state_e state) { LPOVERLAPPED pOverlapped; if (context) pOverlapped = &context->Overlapped; else pOverlapped = NULL; PostQueuedCompletionStatus(ThreadDispatchIOCP, 0, state, pOverlapped); return APR_SUCCESS; } /* * find_ready_listener() * Only used by Win9* and should go away when the win9*_accept() function is * reimplemented using apr_poll(). */ static ap_listen_rec *head_listener; static APR_INLINE ap_listen_rec *find_ready_listener(fd_set * main_fds) { ap_listen_rec *lr; SOCKET nsd; lr = head_listener; do { apr_os_sock_get(&nsd, lr->sd); if (FD_ISSET(nsd, main_fds)) { head_listener = lr->next; if (!head_listener) { head_listener = ap_listeners; } return lr; } lr = lr->next; if (!lr) { lr = ap_listeners; } } while (lr != head_listener); return NULL; } /* Windows 9x specific code... * Accept processing for on Windows 95/98 uses a producer/consumer queue * model. A single thread accepts connections and queues the accepted socket * to the accept queue for consumption by a pool of worker threads. * * win9x_accept() * The accept threads runs this function, which accepts connections off * the network and calls add_job() to queue jobs to the accept_queue. * add_job()/remove_job() * Add or remove an accepted socket from the list of sockets * connected to clients. allowed_globals.jobmutex protects * against multiple concurrent access to the linked list of jobs. * win9x_get_connection() * Calls remove_job() to pull a job from the accept queue. All the worker * threads block on remove_job. */ typedef struct joblist_s { struct joblist_s *next; int sock; } joblist; typedef struct globals_s { HANDLE jobsemaphore; joblist *jobhead; joblist *jobtail; apr_thread_mutex_t *jobmutex; int jobcount; } globals; globals allowed_globals = {NULL, NULL, NULL, NULL, 0}; #define MAX_SELECT_ERRORS 100 static void add_job(int sock) { joblist *new_job; new_job = (joblist *) malloc(sizeof(joblist)); if (new_job == NULL) { ap_log_error(APLOG_MARK, APLOG_STARTUP, 0, NULL, "Ouch! Out of memory in add_job()!"); return; } new_job->next = NULL; new_job->sock = sock; apr_thread_mutex_lock(allowed_globals.jobmutex); if (allowed_globals.jobtail != NULL) allowed_globals.jobtail->next = new_job; allowed_globals.jobtail = new_job; if (!allowed_globals.jobhead) allowed_globals.jobhead = new_job; allowed_globals.jobcount++; ReleaseSemaphore(allowed_globals.jobsemaphore, 1, NULL); apr_thread_mutex_unlock(allowed_globals.jobmutex); } static int remove_job(void) { joblist *job; int sock; WaitForSingleObject(allowed_globals.jobsemaphore, INFINITE); apr_thread_mutex_lock(allowed_globals.jobmutex); if (shutdown_in_progress && !allowed_globals.jobhead) { apr_thread_mutex_unlock(allowed_globals.jobmutex); return (INVALID_SOCKET); } job = allowed_globals.jobhead; ap_assert(job); allowed_globals.jobhead = job->next; if (allowed_globals.jobhead == NULL) allowed_globals.jobtail = NULL; apr_thread_mutex_unlock(allowed_globals.jobmutex); sock = job->sock; free(job); return (sock); } static unsigned int __stdcall win9x_accept(void * dummy) { struct timeval tv; fd_set main_fds; int wait_time = 1; int csd; SOCKET nsd = INVALID_SOCKET; struct sockaddr_in sa_client; int count_select_errors = 0; int rc; int clen; ap_listen_rec *lr; struct fd_set listenfds; SOCKET listenmaxfd = INVALID_SOCKET; /* Setup the listeners * ToDo: Use apr_poll() */ FD_ZERO(&listenfds); for (lr = ap_listeners; lr; lr = lr->next) { if (lr->sd != NULL) { apr_os_sock_get(&nsd, lr->sd); FD_SET(nsd, &listenfds); if (listenmaxfd == INVALID_SOCKET || nsd > listenmaxfd) { listenmaxfd = nsd; } ap_log_error(APLOG_MARK, APLOG_NOTICE, 0, ap_server_conf, "Child %d: Listening on port %d.", my_pid, lr->bind_addr->port); } } head_listener = ap_listeners; while (!shutdown_in_progress) { tv.tv_sec = wait_time; tv.tv_usec = 0; memcpy(&main_fds, &listenfds, sizeof(fd_set)); rc = select(listenmaxfd + 1, &main_fds, NULL, NULL, &tv); if (rc == 0 || (rc == SOCKET_ERROR && APR_STATUS_IS_EINTR(apr_get_netos_error()))) { count_select_errors = 0; /* reset count of errors */ continue; } else if (rc == SOCKET_ERROR) { /* A "real" error occurred, log it and increment the count of * select errors. This count is used to ensure we don't go into * a busy loop of continuous errors. */ ap_log_error(APLOG_MARK, APLOG_INFO, apr_get_netos_error(), ap_server_conf, "select failed with error %d", apr_get_netos_error()); count_select_errors++; if (count_select_errors > MAX_SELECT_ERRORS) { shutdown_in_progress = 1; ap_log_error(APLOG_MARK, APLOG_ERR, apr_get_netos_error(), ap_server_conf, "Too many errors in select loop. Child process exiting."); break; } } else { ap_listen_rec *lr; lr = find_ready_listener(&main_fds); if (lr != NULL) { /* fetch the native socket descriptor */ apr_os_sock_get(&nsd, lr->sd); } } do { clen = sizeof(sa_client); csd = accept(nsd, (struct sockaddr *) &sa_client, &clen); } while (csd < 0 && APR_STATUS_IS_EINTR(apr_get_netos_error())); if (csd < 0) { if (APR_STATUS_IS_ECONNABORTED(apr_get_netos_error())) { ap_log_error(APLOG_MARK, APLOG_ERR, apr_get_netos_error(), ap_server_conf, "accept: (client socket)"); } } else { add_job(csd); } } SetEvent(exit_event); return 0; } static PCOMP_CONTEXT win9x_get_connection(PCOMP_CONTEXT context) { apr_os_sock_info_t sockinfo; int len; if (context == NULL) { /* allocate the completion context and the transaction pool */ apr_allocator_t *allocator; apr_thread_mutex_lock(child_lock); context = apr_pcalloc(pchild, sizeof(COMP_CONTEXT)); apr_allocator_create(&allocator); apr_allocator_max_free_set(allocator, ap_max_mem_free); apr_pool_create_ex(&context->ptrans, pchild, NULL, allocator); apr_allocator_owner_set(allocator, context->ptrans); apr_pool_tag(context->ptrans, "transaction"); apr_thread_mutex_unlock(child_lock); } while (1) { apr_pool_clear(context->ptrans); context->ba = apr_bucket_alloc_create(context->ptrans); context->accept_socket = remove_job(); if (context->accept_socket == INVALID_SOCKET) { return NULL; } len = sizeof(struct sockaddr); context->sa_server = apr_palloc(context->ptrans, len); if (getsockname(context->accept_socket, context->sa_server, &len)== SOCKET_ERROR) { ap_log_error(APLOG_MARK, APLOG_WARNING, apr_get_netos_error(), ap_server_conf, "getsockname failed"); continue; } len = sizeof(struct sockaddr); context->sa_client = apr_palloc(context->ptrans, len); if ((getpeername(context->accept_socket, context->sa_client, &len)) == SOCKET_ERROR) { ap_log_error(APLOG_MARK, APLOG_WARNING, apr_get_netos_error(), ap_server_conf, "getpeername failed"); memset(&context->sa_client, '\0', sizeof(context->sa_client)); } sockinfo.os_sock = &context->accept_socket; sockinfo.local = context->sa_server; sockinfo.remote = context->sa_client; sockinfo.family = APR_INET; sockinfo.type = SOCK_STREAM; apr_os_sock_make(&context->sock, &sockinfo, context->ptrans); return context; } } /* Windows NT/2000 specific code... * Accept processing for on Windows NT uses a producer/consumer queue * model. An accept thread accepts connections off the network then issues * PostQueuedCompletionStatus() to awake a thread blocked on the ThreadDispatch * IOCompletionPort. * * winnt_accept() * One or more accept threads run in this function, each of which accepts * connections off the network and calls PostQueuedCompletionStatus() to * queue an io completion packet to the ThreadDispatch IOCompletionPort. * winnt_get_connection() * Worker threads block on the ThreadDispatch IOCompletionPort awaiting * connections to service. */ #define MAX_ACCEPTEX_ERR_COUNT 250 static unsigned int __stdcall winnt_accept(void *lr_) { ap_listen_rec *lr = (ap_listen_rec *)lr_; apr_os_sock_info_t sockinfo; PCOMP_CONTEXT context = NULL; DWORD BytesRead; SOCKET nlsd; int rv, err_count = 0; apr_os_sock_get(&nlsd, lr->sd); while (!shutdown_in_progress) { if (!context) { context = mpm_get_completion_context(); if (!context) { /* Temporary resource constraint? */ Sleep(0); continue; } } /* Create and initialize the accept socket */ if (context->accept_socket == INVALID_SOCKET) { context->accept_socket = socket(AF_INET, SOCK_STREAM, IPPROTO_TCP); if (context->accept_socket == INVALID_SOCKET) { /* Another temporary condition? */ ap_log_error(APLOG_MARK,APLOG_WARNING, apr_get_netos_error(), ap_server_conf, "winnt_accept: Failed to allocate an accept socket. " "Temporary resource constraint? Try again."); Sleep(100); continue; } } /* AcceptEx on the completion context. The completion context will be * signaled when a connection is accepted. */ if (!AcceptEx(nlsd, context->accept_socket, context->buff, 0, PADDED_ADDR_SIZE, PADDED_ADDR_SIZE, &BytesRead, &context->Overlapped)) { rv = apr_get_netos_error(); if ((rv == APR_FROM_OS_ERROR(WSAEINVAL)) || (rv == APR_FROM_OS_ERROR(WSAENOTSOCK))) { /* We can get here when: * 1) the client disconnects early * 2) TransmitFile does not properly recycle the accept socket (typically * because the client disconnected) * 3) there is VPN or Firewall software installed with buggy AcceptEx implementation * 4) the webserver is using a dynamic address that has changed */ ++err_count; closesocket(context->accept_socket); context->accept_socket = INVALID_SOCKET; if (err_count > MAX_ACCEPTEX_ERR_COUNT) { ap_log_error(APLOG_MARK, APLOG_ERR, rv, ap_server_conf, "Child %d: Encountered too many errors accepting client connections. " "Possible causes: dynamic address renewal, or incompatible VPN or firewall software. " "Try using the Win32DisableAcceptEx directive.", my_pid); err_count = 0; } continue; } else if ((rv != APR_FROM_OS_ERROR(ERROR_IO_PENDING)) && (rv != APR_FROM_OS_ERROR(WSA_IO_PENDING))) { ++err_count; closesocket(context->accept_socket); context->accept_socket = INVALID_SOCKET; if (err_count > MAX_ACCEPTEX_ERR_COUNT) { ap_log_error(APLOG_MARK,APLOG_ERR, rv, ap_server_conf, "Child %d: Encountered too many errors accepting client connections. " "Possible causes: Unknown. " "Try using the Win32DisableAcceptEx directive.", my_pid); err_count = 0; } continue; } /* Wait for pending i/o. * Wake up once per second to check for shutdown . * XXX: We should be waiting on exit_event instead of polling */ while (1) { rv = WaitForSingleObject(context->Overlapped.hEvent, 1000); if (rv == WAIT_OBJECT_0) { if (context->accept_socket == INVALID_SOCKET) { /* socket already closed */ break; } if (!GetOverlappedResult((HANDLE)context->accept_socket, &context->Overlapped, &BytesRead, FALSE)) { ap_log_error(APLOG_MARK, APLOG_WARNING, apr_get_os_error(), ap_server_conf, "winnt_accept: Asynchronous AcceptEx failed."); closesocket(context->accept_socket); context->accept_socket = INVALID_SOCKET; } break; } /* WAIT_TIMEOUT */ if (shutdown_in_progress) { closesocket(context->accept_socket); context->accept_socket = INVALID_SOCKET; break; } } if (context->accept_socket == INVALID_SOCKET) { continue; } } err_count = 0; /* Inherit the listen socket settings. Required for * shutdown() to work */ if (setsockopt(context->accept_socket, SOL_SOCKET, SO_UPDATE_ACCEPT_CONTEXT, (char *)&nlsd, sizeof(nlsd))) { ap_log_error(APLOG_MARK, APLOG_WARNING, apr_get_netos_error(), ap_server_conf, "setsockopt(SO_UPDATE_ACCEPT_CONTEXT) failed."); /* Not a failure condition. Keep running. */ } /* Get the local & remote address */ GetAcceptExSockaddrs(context->buff, 0, PADDED_ADDR_SIZE, PADDED_ADDR_SIZE, &context->sa_server, &context->sa_server_len, &context->sa_client, &context->sa_client_len); sockinfo.os_sock = &context->accept_socket; sockinfo.local = context->sa_server; sockinfo.remote = context->sa_client; sockinfo.family = APR_INET; sockinfo.type = SOCK_STREAM; apr_os_sock_make(&context->sock, &sockinfo, context->ptrans); /* When a connection is received, send an io completion notification to * the ThreadDispatchIOCP. This function could be replaced by * mpm_post_completion_context(), but why do an extra function call... */ PostQueuedCompletionStatus(ThreadDispatchIOCP, 0, IOCP_CONNECTION_ACCEPTED, &context->Overlapped); context = NULL; } if (!shutdown_in_progress) { /* Yow, hit an irrecoverable error! Tell the child to die. */ SetEvent(exit_event); } ap_log_error(APLOG_MARK, APLOG_INFO, APR_SUCCESS, ap_server_conf, "Child %d: Accept thread exiting.", my_pid); return 0; } static PCOMP_CONTEXT winnt_get_connection(PCOMP_CONTEXT context) { int rc; DWORD BytesRead; DWORD CompKey; LPOVERLAPPED pol; mpm_recycle_completion_context(context); apr_atomic_inc(&g_blocked_threads); while (1) { if (workers_may_exit) { apr_atomic_dec(&g_blocked_threads); return NULL; } rc = GetQueuedCompletionStatus(ThreadDispatchIOCP, &BytesRead, &CompKey, &pol, INFINITE); if (!rc) { rc = apr_get_os_error(); ap_log_error(APLOG_MARK,APLOG_DEBUG, rc, ap_server_conf, "Child %d: GetQueuedComplationStatus returned %d", my_pid, rc); continue; } switch (CompKey) { case IOCP_CONNECTION_ACCEPTED: context = CONTAINING_RECORD(pol, COMP_CONTEXT, Overlapped); break; case IOCP_SHUTDOWN: apr_atomic_dec(&g_blocked_threads); return NULL; default: apr_atomic_dec(&g_blocked_threads); return NULL; } break; } apr_atomic_dec(&g_blocked_threads); return context; } /* * worker_main() * Main entry point for the worker threads. Worker threads block in * win*_get_connection() awaiting a connection to service. */ static unsigned int __stdcall worker_main(void *thread_num_val) { static int requests_this_child = 0; PCOMP_CONTEXT context = NULL; int thread_num = (int)thread_num_val; ap_sb_handle_t *sbh; ap_log_error(APLOG_MARK, APLOG_DEBUG, APR_SUCCESS, ap_server_conf, "Child %d: Worker thread %ld starting.", my_pid, thread_num); while (1) { conn_rec *c; apr_int32_t disconnected; ap_update_child_status_from_indexes(0, thread_num, SERVER_READY, NULL); /* Grab a connection off the network */ if (use_acceptex) { context = winnt_get_connection(context); } else { context = win9x_get_connection(context); } if (!context) { /* Time for the thread to exit */ break; } /* Have we hit MaxRequestPerChild connections? */ if (ap_max_requests_per_child) { requests_this_child++; if (requests_this_child > ap_max_requests_per_child) { SetEvent(max_requests_per_child_event); } } ap_create_sb_handle(&sbh, context->ptrans, 0, thread_num); c = ap_run_create_connection(context->ptrans, ap_server_conf, context->sock, thread_num, sbh, context->ba); if (c) { ap_process_connection(c, context->sock); apr_socket_opt_get(context->sock, APR_SO_DISCONNECTED, &disconnected); if (!disconnected) { context->accept_socket = INVALID_SOCKET; ap_lingering_close(c); } else if (!use_acceptex) { /* If the socket is disconnected but we are not using acceptex, * we cannot reuse the socket. Disconnected sockets are removed * from the apr_socket_t struct by apr_sendfile() to prevent the * socket descriptor from being inadvertently closed by a call * to apr_socket_close(), so close it directly. */ closesocket(context->accept_socket); context->accept_socket = INVALID_SOCKET; } } else { /* ap_run_create_connection closes the socket on failure */ context->accept_socket = INVALID_SOCKET; } } ap_update_child_status_from_indexes(0, thread_num, SERVER_DEAD, (request_rec *) NULL); ap_log_error(APLOG_MARK, APLOG_DEBUG, APR_SUCCESS, ap_server_conf, "Child %d: Worker thread %ld exiting.", my_pid, thread_num); return 0; } static void cleanup_thread(HANDLE *handles, int *thread_cnt, int thread_to_clean) { int i; CloseHandle(handles[thread_to_clean]); for (i = thread_to_clean; i < ((*thread_cnt) - 1); i++) handles[i] = handles[i + 1]; (*thread_cnt)--; } /* * child_main() * Entry point for the main control thread for the child process. * This thread creates the accept thread, worker threads and * monitors the child process for maintenance and shutdown * events. */ static void create_listener_thread() { int tid; int num_listeners = 0; if (!use_acceptex) { _beginthreadex(NULL, 0, win9x_accept, NULL, 0, &tid); } else { /* Start an accept thread per listener * XXX: Why would we have a NULL sd in our listeners? */ ap_listen_rec *lr; /* Number of completion_contexts allowed in the system is * (ap_threads_per_child + num_listeners). We need the additional * completion contexts to prevent server hangs when ThreadsPerChild * is configured to something less than or equal to the number * of listeners. This is not a usual case, but people have * encountered it. * */ for (lr = ap_listeners; lr ; lr = lr->next) { num_listeners++; } max_num_completion_contexts = ap_threads_per_child + num_listeners; /* Now start a thread per listener */ for (lr = ap_listeners; lr; lr = lr->next) { if (lr->sd != NULL) { _beginthreadex(NULL, 1000, winnt_accept, (void *) lr, 0, &tid); } } } } void child_main(apr_pool_t *pconf) { apr_status_t status; apr_hash_t *ht; ap_listen_rec *lr; HANDLE child_events[2]; HANDLE *child_handles; int listener_started = 0; int threads_created = 0; int watch_thread; int time_remains; int cld; int tid; int rv; int i; apr_pool_create(&pchild, pconf); apr_pool_tag(pchild, "pchild"); ap_run_child_init(pchild, ap_server_conf); ht = apr_hash_make(pchild); /* Initialize the child_events */ max_requests_per_child_event = CreateEvent(NULL, TRUE, FALSE, NULL); if (!max_requests_per_child_event) { ap_log_error(APLOG_MARK, APLOG_CRIT, apr_get_os_error(), ap_server_conf, "Child %d: Failed to create a max_requests event.", my_pid); exit(APEXIT_CHILDINIT); } child_events[0] = exit_event; child_events[1] = max_requests_per_child_event; allowed_globals.jobsemaphore = CreateSemaphore(NULL, 0, 1000000, NULL); apr_thread_mutex_create(&allowed_globals.jobmutex, APR_THREAD_MUTEX_DEFAULT, pchild); /* * Wait until we have permission to start accepting connections. * start_mutex is used to ensure that only one child ever * goes into the listen/accept loop at once. */ status = apr_proc_mutex_lock(start_mutex); if (status != APR_SUCCESS) { ap_log_error(APLOG_MARK,APLOG_ERR, status, ap_server_conf, "Child %d: Failed to acquire the start_mutex. Process will exit.", my_pid); exit(APEXIT_CHILDINIT); } ap_log_error(APLOG_MARK,APLOG_NOTICE, APR_SUCCESS, ap_server_conf, "Child %d: Acquired the start mutex.", my_pid); /* * Create the worker thread dispatch IOCompletionPort * on Windows NT/2000 */ if (use_acceptex) { /* Create the worker thread dispatch IOCP */ ThreadDispatchIOCP = CreateIoCompletionPort(INVALID_HANDLE_VALUE, NULL, 0, 0); /* CONCURRENT ACTIVE THREADS */ apr_thread_mutex_create(&qlock, APR_THREAD_MUTEX_DEFAULT, pchild); qwait_event = CreateEvent(NULL, TRUE, FALSE, NULL); if (!qwait_event) { ap_log_error(APLOG_MARK, APLOG_CRIT, apr_get_os_error(), ap_server_conf, "Child %d: Failed to create a qwait event.", my_pid); exit(APEXIT_CHILDINIT); } } /* * Create the pool of worker threads */ ap_log_error(APLOG_MARK,APLOG_NOTICE, APR_SUCCESS, ap_server_conf, "Child %d: Starting %d worker threads.", my_pid, ap_threads_per_child); child_handles = (HANDLE) apr_pcalloc(pchild, ap_threads_per_child * sizeof(int)); apr_thread_mutex_create(&child_lock, APR_THREAD_MUTEX_DEFAULT, pchild); while (1) { for (i = 0; i < ap_threads_per_child; i++) { int *score_idx; int status = ap_scoreboard_image->servers[0][i].status; if (status != SERVER_GRACEFUL && status != SERVER_DEAD) { continue; } ap_update_child_status_from_indexes(0, i, SERVER_STARTING, NULL); child_handles[i] = (HANDLE) _beginthreadex(NULL, 0, worker_main, (void *) i, 0, &tid); if (child_handles[i] == 0) { ap_log_error(APLOG_MARK, APLOG_CRIT, apr_get_os_error(), ap_server_conf, "Child %d: _beginthreadex failed. Unable to create all worker threads. " "Created %d of the %d threads requested with the ThreadsPerChild configuration directive.", my_pid, threads_created, ap_threads_per_child); ap_signal_parent(SIGNAL_PARENT_SHUTDOWN); goto shutdown; } threads_created++; /* Save the score board index in ht keyed to the thread handle. We need this * when cleaning up threads down below... */ apr_thread_mutex_lock(child_lock); score_idx = apr_pcalloc(pchild, sizeof(int)); *score_idx = i; apr_hash_set(ht, &child_handles[i], sizeof(HANDLE), score_idx); apr_thread_mutex_unlock(child_lock); } /* Start the listener only when workers are available */ if (!listener_started && threads_created) { create_listener_thread(); listener_started = 1; winnt_mpm_state = AP_MPMQ_RUNNING; } if (threads_created == ap_threads_per_child) { break; } /* Check to see if the child has been told to exit */ if (WaitForSingleObject(exit_event, 0) != WAIT_TIMEOUT) { break; } /* wait for previous generation to clean up an entry in the scoreboard */ apr_sleep(1 * APR_USEC_PER_SEC); } /* Wait for one of three events: * exit_event: * The exit_event is signaled by the parent process to notify * the child that it is time to exit. * * max_requests_per_child_event: * This event is signaled by the worker threads to indicate that * the process has handled MaxRequestsPerChild connections. * * TIMEOUT: * To do periodic maintenance on the server (check for thread exits, * number of completion contexts, etc.) * * XXX: thread exits *aren't* being checked. * * XXX: other_child - we need the process handles to the other children * in order to map them to apr_proc_other_child_read (which is not * named well, it's more like a_p_o_c_died.) * * XXX: however - if we get a_p_o_c handle inheritance working, and * the parent process creates other children and passes the pipes * to our worker processes, then we have no business doing such * things in the child_main loop, but should happen in master_main. */ while (1) { #if !APR_HAS_OTHER_CHILD rv = WaitForMultipleObjects(2, (HANDLE *) child_events, FALSE, INFINITE); cld = rv - WAIT_OBJECT_0; #else rv = WaitForMultipleObjects(2, (HANDLE *) child_events, FALSE, 1000); cld = rv - WAIT_OBJECT_0; if (rv == WAIT_TIMEOUT) { apr_proc_other_child_check(); } else #endif if (rv == WAIT_FAILED) { /* Something serious is wrong */ ap_log_error(APLOG_MARK, APLOG_CRIT, apr_get_os_error(), ap_server_conf, "Child %d: WAIT_FAILED -- shutting down server", my_pid); break; } else if (cld == 0) { /* Exit event was signaled */ ap_log_error(APLOG_MARK, APLOG_NOTICE, APR_SUCCESS, ap_server_conf, "Child %d: Exit event signaled. Child process is ending.", my_pid); break; } else { /* MaxRequestsPerChild event set by the worker threads. * Signal the parent to restart */ ap_log_error(APLOG_MARK, APLOG_NOTICE, APR_SUCCESS, ap_server_conf, "Child %d: Process exiting because it reached " "MaxRequestsPerChild. Signaling the parent to " "restart a new child process.", my_pid); ap_signal_parent(SIGNAL_PARENT_RESTART); break; } } /* * Time to shutdown the child process */ shutdown: winnt_mpm_state = AP_MPMQ_STOPPING; /* Setting is_graceful will cause threads handling keep-alive connections * to close the connection after handling the current request. */ is_graceful = 1; /* Close the listening sockets. Note, we must close the listeners * before closing any accept sockets pending in AcceptEx to prevent * memory leaks in the kernel. */ for (lr = ap_listeners; lr ; lr = lr->next) { apr_socket_close(lr->sd); } /* Shutdown listener threads and pending AcceptEx socksts * but allow the worker threads to continue consuming from * the queue of accepted connections. */ shutdown_in_progress = 1; Sleep(1000); /* Tell the worker threads to exit */ workers_may_exit = 1; /* Release the start_mutex to let the new process (in the restart * scenario) a chance to begin accepting and servicing requests */ rv = apr_proc_mutex_unlock(start_mutex); if (rv == APR_SUCCESS) { ap_log_error(APLOG_MARK,APLOG_NOTICE, rv, ap_server_conf, "Child %d: Released the start mutex", my_pid); } else { ap_log_error(APLOG_MARK,APLOG_ERR, rv, ap_server_conf, "Child %d: Failure releasing the start mutex", my_pid); } /* Shutdown the worker threads */ if (!use_acceptex) { for (i = 0; i < threads_created; i++) { add_job(INVALID_SOCKET); } } else { /* Windows NT/2000 */ /* Post worker threads blocked on the ThreadDispatch IOCompletion port */ while (g_blocked_threads > 0) { ap_log_error(APLOG_MARK,APLOG_INFO, APR_SUCCESS, ap_server_conf, "Child %d: %d threads blocked on the completion port", my_pid, g_blocked_threads); for (i=g_blocked_threads; i > 0; i--) { PostQueuedCompletionStatus(ThreadDispatchIOCP, 0, IOCP_SHUTDOWN, NULL); } Sleep(1000); } /* Empty the accept queue of completion contexts */ apr_thread_mutex_lock(qlock); while (qhead) { CloseHandle(qhead->Overlapped.hEvent); closesocket(qhead->accept_socket); qhead = qhead->next; } apr_thread_mutex_unlock(qlock); } /* Give busy threads a chance to service their connections, * (no more than the global server timeout period which * we track in msec remaining). */ watch_thread = 0; time_remains = (int)(ap_server_conf->timeout / APR_TIME_C(1000)); while (threads_created) { int nFailsafe = MAXIMUM_WAIT_OBJECTS; DWORD dwRet; /* Every time we roll over to wait on the first group * of MAXIMUM_WAIT_OBJECTS threads, take a breather, * and infrequently update the error log. */ if (watch_thread >= threads_created) { if ((time_remains -= 100) < 0) break; /* Every 30 seconds give an update */ if ((time_remains % 30000) == 0) { ap_log_error(APLOG_MARK, APLOG_NOTICE, APR_SUCCESS, ap_server_conf, "Child %d: Waiting %d more seconds " "for %d worker threads to finish.", my_pid, time_remains / 1000, threads_created); } /* We'll poll from the top, 10 times per second */ Sleep(100); watch_thread = 0; } /* Fairness, on each iteration we will pick up with the thread * after the one we just removed, even if it's a single thread. * We don't block here. */ dwRet = WaitForMultipleObjects(min(threads_created - watch_thread, MAXIMUM_WAIT_OBJECTS), child_handles + watch_thread, 0, 0); if (dwRet == WAIT_FAILED) { break; } if (dwRet == WAIT_TIMEOUT) { /* none ready */ watch_thread += MAXIMUM_WAIT_OBJECTS; continue; } else if (dwRet >= WAIT_ABANDONED_0) { /* We just got the ownership of the object, which * should happen at most MAXIMUM_WAIT_OBJECTS times. * It does NOT mean that the object is signaled. */ if ((nFailsafe--) < 1) break; } else { watch_thread += (dwRet - WAIT_OBJECT_0); if (watch_thread >= threads_created) break; cleanup_thread(child_handles, &threads_created, watch_thread); } } /* Kill remaining threads off the hard way */ if (threads_created) { ap_log_error(APLOG_MARK,APLOG_NOTICE, APR_SUCCESS, ap_server_conf, "Child %d: Terminating %d threads that failed to exit.", my_pid, threads_created); } for (i = 0; i < threads_created; i++) { int *score_idx; TerminateThread(child_handles[i], 1); CloseHandle(child_handles[i]); /* Reset the scoreboard entry for the thread we just whacked */ score_idx = apr_hash_get(ht, &child_handles[i], sizeof(HANDLE)); ap_update_child_status_from_indexes(0, *score_idx, SERVER_DEAD, NULL); } ap_log_error(APLOG_MARK,APLOG_NOTICE, APR_SUCCESS, ap_server_conf, "Child %d: All worker threads have exited.", my_pid); CloseHandle(allowed_globals.jobsemaphore); apr_thread_mutex_destroy(allowed_globals.jobmutex); apr_thread_mutex_destroy(child_lock); if (use_acceptex) { apr_thread_mutex_destroy(qlock); CloseHandle(qwait_event); } apr_pool_destroy(pchild); CloseHandle(exit_event); } #endif /* def WIN32 */