/* 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. */ /* The purpose of this file is to store the code that MOST mpm's will need * this does not mean a function only goes into this file if every MPM needs * it. It means that if a function is needed by more than one MPM, and * future maintenance would be served by making the code common, then the * function belongs here. * * This is going in src/main because it is not platform specific, it is * specific to multi-process servers, but NOT to Unix. Which is why it * does not belong in src/os/unix */ #include "apr.h" #include "apr_thread_proc.h" #include "apr_signal.h" #include "apr_strings.h" #define APR_WANT_STRFUNC #include "apr_want.h" #include "apr_getopt.h" #include "apr_optional.h" #include "apr_allocator.h" #include "httpd.h" #include "http_config.h" #include "http_core.h" #include "http_log.h" #include "http_main.h" #include "mpm_common.h" #include "mod_core.h" #include "ap_mpm.h" #include "ap_listen.h" #include "util_mutex.h" #include "scoreboard.h" #ifdef HAVE_PWD_H #include #endif #ifdef HAVE_GRP_H #include #endif #if APR_HAVE_UNISTD_H #include #endif /* we know core's module_index is 0 */ #undef APLOG_MODULE_INDEX #define APLOG_MODULE_INDEX AP_CORE_MODULE_INDEX #if AP_ENABLE_EXCEPTION_HOOK APR_HOOK_STRUCT( APR_HOOK_LINK(fatal_exception) APR_HOOK_LINK(monitor) APR_HOOK_LINK(drop_privileges) APR_HOOK_LINK(mpm) APR_HOOK_LINK(mpm_query) APR_HOOK_LINK(mpm_register_timed_callback) APR_HOOK_LINK(mpm_register_socket_callback) APR_HOOK_LINK(mpm_unregister_socket_callback) APR_HOOK_LINK(mpm_get_name) APR_HOOK_LINK(end_generation) APR_HOOK_LINK(child_status) ) AP_IMPLEMENT_HOOK_RUN_ALL(int, fatal_exception, (ap_exception_info_t *ei), (ei), OK, DECLINED) #else APR_HOOK_STRUCT( APR_HOOK_LINK(monitor) APR_HOOK_LINK(drop_privileges) APR_HOOK_LINK(mpm) APR_HOOK_LINK(mpm_query) APR_HOOK_LINK(mpm_register_timed_callback) APR_HOOK_LINK(mpm_register_socket_callback) APR_HOOK_LINK(mpm_unregister_socket_callback) APR_HOOK_LINK(mpm_get_name) APR_HOOK_LINK(end_generation) APR_HOOK_LINK(child_status) ) #endif AP_IMPLEMENT_HOOK_RUN_ALL(int, monitor, (apr_pool_t *p, server_rec *s), (p, s), OK, DECLINED) AP_IMPLEMENT_HOOK_RUN_ALL(int, drop_privileges, (apr_pool_t * pchild, server_rec * s), (pchild, s), OK, DECLINED) AP_IMPLEMENT_HOOK_RUN_FIRST(int, mpm, (apr_pool_t *pconf, apr_pool_t *plog, server_rec *s), (pconf, plog, s), DECLINED) AP_IMPLEMENT_HOOK_RUN_FIRST(int, mpm_query, (int query_code, int *result, apr_status_t *_rv), (query_code, result, _rv), DECLINED) AP_IMPLEMENT_HOOK_RUN_FIRST(apr_status_t, mpm_register_timed_callback, (apr_time_t t, ap_mpm_callback_fn_t *cbfn, void *baton), (t, cbfn, baton), APR_ENOTIMPL) AP_IMPLEMENT_HOOK_RUN_FIRST(apr_status_t, mpm_register_socket_callback, (apr_socket_t **s, apr_pool_t *p, int for_read, ap_mpm_callback_fn_t *cbfn, void *baton), (s, p, for_read, cbfn, baton), APR_ENOTIMPL) AP_IMPLEMENT_HOOK_RUN_FIRST(apr_status_t, mpm_unregister_socket_callback, (apr_socket_t **s, apr_pool_t *p), (s, p), APR_ENOTIMPL) AP_IMPLEMENT_HOOK_VOID(end_generation, (server_rec *s, ap_generation_t gen), (s, gen)) AP_IMPLEMENT_HOOK_VOID(child_status, (server_rec *s, pid_t pid, ap_generation_t gen, int slot, mpm_child_status status), (s,pid,gen,slot,status)) /* hooks with no args are implemented last, after disabling APR hook probes */ #if defined(APR_HOOK_PROBES_ENABLED) #undef APR_HOOK_PROBES_ENABLED #undef APR_HOOK_PROBE_ENTRY #define APR_HOOK_PROBE_ENTRY(ud,ns,name,args) #undef APR_HOOK_PROBE_RETURN #define APR_HOOK_PROBE_RETURN(ud,ns,name,rv,args) #undef APR_HOOK_PROBE_INVOKE #define APR_HOOK_PROBE_INVOKE(ud,ns,name,src,args) #undef APR_HOOK_PROBE_COMPLETE #define APR_HOOK_PROBE_COMPLETE(ud,ns,name,src,rv,args) #undef APR_HOOK_INT_DCL_UD #define APR_HOOK_INT_DCL_UD #endif AP_IMPLEMENT_HOOK_RUN_FIRST(const char *, mpm_get_name, (void), (), NULL) typedef struct mpm_gen_info_t { APR_RING_ENTRY(mpm_gen_info_t) link; int gen; /* which gen? */ int active; /* number of active processes */ int done; /* gen finished? (whether or not active processes) */ } mpm_gen_info_t; APR_RING_HEAD(mpm_gen_info_head_t, mpm_gen_info_t); static struct mpm_gen_info_head_t *geninfo, *unused_geninfo; static int gen_head_init; /* yuck */ /* variables representing config directives implemented here */ AP_DECLARE_DATA const char *ap_pid_fname; AP_DECLARE_DATA int ap_max_requests_per_child; AP_DECLARE_DATA char ap_coredump_dir[MAX_STRING_LEN]; AP_DECLARE_DATA int ap_coredumpdir_configured; AP_DECLARE_DATA int ap_graceful_shutdown_timeout; AP_DECLARE_DATA apr_uint32_t ap_max_mem_free; AP_DECLARE_DATA apr_size_t ap_thread_stacksize; #define ALLOCATOR_MAX_FREE_DEFAULT (2048*1024) /* Set defaults for config directives implemented here. This is * called from core's pre-config hook, so MPMs which need to override * one of these should run their pre-config hook after that of core. */ void mpm_common_pre_config(apr_pool_t *pconf) { ap_pid_fname = DEFAULT_PIDLOG; ap_max_requests_per_child = 0; /* unlimited */ apr_cpystrn(ap_coredump_dir, ap_server_root, sizeof(ap_coredump_dir)); ap_coredumpdir_configured = 0; ap_graceful_shutdown_timeout = 0; /* unlimited */ ap_max_mem_free = ALLOCATOR_MAX_FREE_DEFAULT; ap_thread_stacksize = 0; /* use system default */ } /* number of calls to wait_or_timeout between writable probes */ #ifndef INTERVAL_OF_WRITABLE_PROBES #define INTERVAL_OF_WRITABLE_PROBES 10 #endif static int wait_or_timeout_counter; AP_DECLARE(void) ap_wait_or_timeout(apr_exit_why_e *status, int *exitcode, apr_proc_t *ret, apr_pool_t *p, server_rec *s) { apr_status_t rv; ++wait_or_timeout_counter; if (wait_or_timeout_counter == INTERVAL_OF_WRITABLE_PROBES) { wait_or_timeout_counter = 0; ap_run_monitor(p, s); } rv = apr_proc_wait_all_procs(ret, exitcode, status, APR_NOWAIT, p); if (APR_STATUS_IS_EINTR(rv)) { ret->pid = -1; return; } if (APR_STATUS_IS_CHILD_DONE(rv)) { return; } apr_sleep(apr_time_from_sec(1)); ret->pid = -1; return; } #if defined(TCP_NODELAY) void ap_sock_disable_nagle(apr_socket_t *s) { /* The Nagle algorithm says that we should delay sending partial * packets in hopes of getting more data. We don't want to do * this; we are not telnet. There are bad interactions between * persistent connections and Nagle's algorithm that have very severe * performance penalties. (Failing to disable Nagle is not much of a * problem with simple HTTP.) * * In spite of these problems, failure here is not a shooting offense. */ apr_status_t status = apr_socket_opt_set(s, APR_TCP_NODELAY, 1); if (status != APR_SUCCESS) { ap_log_error(APLOG_MARK, APLOG_WARNING, status, ap_server_conf, APLOGNO(00542) "apr_socket_opt_set: (TCP_NODELAY)"); } } #endif #ifdef HAVE_GETPWNAM AP_DECLARE(uid_t) ap_uname2id(const char *name) { struct passwd *ent; if (name[0] == '#') return (atoi(&name[1])); if (!(ent = getpwnam(name))) { ap_log_error(APLOG_MARK, APLOG_STARTUP, 0, NULL, APLOGNO(00543) "%s: bad user name %s", ap_server_argv0, name); exit(1); } return (ent->pw_uid); } #endif #ifdef HAVE_GETGRNAM AP_DECLARE(gid_t) ap_gname2id(const char *name) { struct group *ent; if (name[0] == '#') return (atoi(&name[1])); if (!(ent = getgrnam(name))) { ap_log_error(APLOG_MARK, APLOG_STARTUP, 0, NULL, APLOGNO(00544) "%s: bad group name %s", ap_server_argv0, name); exit(1); } return (ent->gr_gid); } #endif #ifndef HAVE_INITGROUPS int initgroups(const char *name, gid_t basegid) { #if defined(_OSD_POSIX) || defined(OS2) || defined(WIN32) || defined(NETWARE) return 0; #else gid_t groups[NGROUPS_MAX]; struct group *g; int index = 0; setgrent(); groups[index++] = basegid; while (index < NGROUPS_MAX && ((g = getgrent()) != NULL)) { if (g->gr_gid != basegid) { char **names; for (names = g->gr_mem; *names != NULL; ++names) { if (!strcmp(*names, name)) groups[index++] = g->gr_gid; } } } endgrent(); return setgroups(index, groups); #endif } #endif /* def HAVE_INITGROUPS */ /* standard mpm configuration handling */ const char *ap_mpm_set_pidfile(cmd_parms *cmd, void *dummy, const char *arg) { const char *err = ap_check_cmd_context(cmd, GLOBAL_ONLY); if (err != NULL) { return err; } if (cmd->server->is_virtual) { return "PidFile directive not allowed in "; } ap_pid_fname = arg; return NULL; } void ap_mpm_dump_pidfile(apr_pool_t *p, apr_file_t *out) { apr_file_printf(out, "PidFile: \"%s\"\n", ap_runtime_dir_relative(p, ap_pid_fname)); } const char *ap_mpm_set_max_requests(cmd_parms *cmd, void *dummy, const char *arg) { const char *err = ap_check_cmd_context(cmd, GLOBAL_ONLY); if (err != NULL) { return err; } if (!strcasecmp(cmd->cmd->name, "MaxRequestsPerChild")) { ap_log_error(APLOG_MARK, APLOG_INFO, 0, NULL, APLOGNO(00545) "MaxRequestsPerChild is deprecated, use " "MaxConnectionsPerChild instead."); } ap_max_requests_per_child = atoi(arg); return NULL; } const char *ap_mpm_set_coredumpdir(cmd_parms *cmd, void *dummy, const char *arg) { apr_finfo_t finfo; const char *fname; const char *err = ap_check_cmd_context(cmd, GLOBAL_ONLY); if (err != NULL) { return err; } fname = ap_server_root_relative(cmd->pool, arg); if (!fname) { return apr_pstrcat(cmd->pool, "Invalid CoreDumpDirectory path ", arg, NULL); } if (apr_stat(&finfo, fname, APR_FINFO_TYPE, cmd->pool) != APR_SUCCESS) { return apr_pstrcat(cmd->pool, "CoreDumpDirectory ", fname, " does not exist", NULL); } if (finfo.filetype != APR_DIR) { return apr_pstrcat(cmd->pool, "CoreDumpDirectory ", fname, " is not a directory", NULL); } apr_cpystrn(ap_coredump_dir, fname, sizeof(ap_coredump_dir)); ap_coredumpdir_configured = 1; return NULL; } AP_DECLARE(const char *)ap_mpm_set_graceful_shutdown(cmd_parms *cmd, void *dummy, const char *arg) { const char *err = ap_check_cmd_context(cmd, GLOBAL_ONLY); if (err != NULL) { return err; } ap_graceful_shutdown_timeout = atoi(arg); return NULL; } const char *ap_mpm_set_max_mem_free(cmd_parms *cmd, void *dummy, const char *arg) { long value; const char *err = ap_check_cmd_context(cmd, GLOBAL_ONLY); if (err != NULL) { return err; } value = strtol(arg, NULL, 10); if (value < 0 || errno == ERANGE) return apr_pstrcat(cmd->pool, "Invalid MaxMemFree value: ", arg, NULL); ap_max_mem_free = (apr_uint32_t)value * 1024; return NULL; } const char *ap_mpm_set_thread_stacksize(cmd_parms *cmd, void *dummy, const char *arg) { long value; const char *err = ap_check_cmd_context(cmd, GLOBAL_ONLY); if (err != NULL) { return err; } value = strtol(arg, NULL, 10); if (value < 0 || errno == ERANGE) return apr_pstrcat(cmd->pool, "Invalid ThreadStackSize value: ", arg, NULL); ap_thread_stacksize = (apr_size_t)value; return NULL; } AP_DECLARE(apr_status_t) ap_mpm_query(int query_code, int *result) { apr_status_t rv; if (ap_run_mpm_query(query_code, result, &rv) == DECLINED) { rv = APR_EGENERAL; } return rv; } static void end_gen(mpm_gen_info_t *gi) { ap_log_error(APLOG_MARK, APLOG_TRACE4, 0, ap_server_conf, "end of generation %d", gi->gen); ap_run_end_generation(ap_server_conf, gi->gen); APR_RING_REMOVE(gi, link); APR_RING_INSERT_HEAD(unused_geninfo, gi, mpm_gen_info_t, link); } apr_status_t ap_mpm_end_gen_helper(void *unused) /* cleanup on pconf */ { int gen = ap_config_generation - 1; /* differs from MPM generation */ mpm_gen_info_t *cur; if (geninfo == NULL) { /* initial pconf teardown, MPM hasn't run */ return APR_SUCCESS; } cur = APR_RING_FIRST(geninfo); while (cur != APR_RING_SENTINEL(geninfo, mpm_gen_info_t, link) && cur->gen != gen) { cur = APR_RING_NEXT(cur, link); } if (cur == APR_RING_SENTINEL(geninfo, mpm_gen_info_t, link)) { /* last child of generation already exited */ ap_log_error(APLOG_MARK, APLOG_TRACE4, 0, ap_server_conf, "no record of generation %d", gen); } else { cur->done = 1; if (cur->active == 0) { end_gen(cur); } } return APR_SUCCESS; } /* core's child-status hook * tracks number of remaining children per generation and * runs the end-generation hook when the last child of * a generation exits */ void ap_core_child_status(server_rec *s, pid_t pid, ap_generation_t gen, int slot, mpm_child_status status) { mpm_gen_info_t *cur; const char *status_msg = "unknown status"; if (!gen_head_init) { /* where to run this? */ gen_head_init = 1; geninfo = apr_pcalloc(s->process->pool, sizeof *geninfo); unused_geninfo = apr_pcalloc(s->process->pool, sizeof *unused_geninfo); APR_RING_INIT(geninfo, mpm_gen_info_t, link); APR_RING_INIT(unused_geninfo, mpm_gen_info_t, link); } cur = APR_RING_FIRST(geninfo); while (cur != APR_RING_SENTINEL(geninfo, mpm_gen_info_t, link) && cur->gen != gen) { cur = APR_RING_NEXT(cur, link); } switch(status) { case MPM_CHILD_STARTED: status_msg = "started"; if (cur == APR_RING_SENTINEL(geninfo, mpm_gen_info_t, link)) { /* first child for this generation */ if (!APR_RING_EMPTY(unused_geninfo, mpm_gen_info_t, link)) { cur = APR_RING_FIRST(unused_geninfo); APR_RING_REMOVE(cur, link); cur->active = cur->done = 0; } else { cur = apr_pcalloc(s->process->pool, sizeof *cur); } cur->gen = gen; APR_RING_ELEM_INIT(cur, link); APR_RING_INSERT_HEAD(geninfo, cur, mpm_gen_info_t, link); } ap_random_parent_after_fork(); ++cur->active; break; case MPM_CHILD_EXITED: status_msg = "exited"; if (cur == APR_RING_SENTINEL(geninfo, mpm_gen_info_t, link)) { ap_log_error(APLOG_MARK, APLOG_ERR, 0, s, APLOGNO(00546) "no record of generation %d of exiting child %" APR_PID_T_FMT, gen, pid); } else { --cur->active; if (!cur->active && cur->done) { /* no children, server has stopped/restarted */ end_gen(cur); } } break; case MPM_CHILD_LOST_SLOT: status_msg = "lost slot"; /* we don't track by slot, so it doesn't matter */ break; } ap_log_error(APLOG_MARK, APLOG_TRACE4, 0, s, "mpm child %" APR_PID_T_FMT " (gen %d/slot %d) %s", pid, gen, slot, status_msg); } AP_DECLARE(apr_status_t) ap_mpm_register_timed_callback(apr_time_t t, ap_mpm_callback_fn_t *cbfn, void *baton) { return ap_run_mpm_register_timed_callback(t, cbfn, baton); } AP_DECLARE(apr_status_t) ap_mpm_register_socket_callback(apr_socket_t **s, apr_pool_t *p, int for_read, ap_mpm_callback_fn_t *cbfn, void *baton) { return ap_run_mpm_register_socket_callback(s, p, for_read, cbfn, baton); } AP_DECLARE(apr_status_t) ap_mpm_unregister_socket_callback(apr_socket_t **s, apr_pool_t *p) { return ap_run_mpm_unregister_socket_callback(s, p); } AP_DECLARE(const char *)ap_show_mpm(void) { const char *name = ap_run_mpm_get_name(); if (!name) { name = ""; } return name; } AP_DECLARE(const char *)ap_check_mpm(void) { static const char *last_mpm_name = NULL; if (!_hooks.link_mpm || _hooks.link_mpm->nelts == 0) return "No MPM loaded."; else if (_hooks.link_mpm->nelts > 1) return "More than one MPM loaded."; if (last_mpm_name) { if (strcmp(last_mpm_name, ap_show_mpm())) { return "The MPM cannot be changed during restart."; } } else { last_mpm_name = apr_pstrdup(ap_pglobal, ap_show_mpm()); } return NULL; }