/* Unix SMB/CIFS implementation. Common server globals Copyright (C) Simo Sorce 2011 This program is free software; you can redistribute it and/or modify it under the terms of the GNU General Public License as published by the Free Software Foundation; either version 3 of the License, or (at your option) any later version. This program is distributed in the hope that it will be useful, but WITHOUT ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License for more details. You should have received a copy of the GNU General Public License along with this program. If not, see . */ #include "system/network.h" #include enum pf_worker_status { PF_WORKER_NONE = 0, PF_WORKER_IDLE, PF_WORKER_ACCEPTING, PF_WORKER_BUSY, PF_WORKER_EXITING }; enum pf_server_cmds { PF_SRV_MSG_NONE = 0, PF_SRV_MSG_EXIT }; /** * @brief This structure is shared betwee the controlling parent and the * the child. The parent can only write to the 'cmds' and * 'allowed_clients' variables, while a child is running. * The child can change 'status', and 'num_clients'. * All other variables are initialized by the parent before forking the * child. */ struct pf_worker_data { pid_t pid; enum pf_worker_status status; time_t started; time_t last_used; int num_clients; enum pf_server_cmds cmds; int allowed_clients; }; /** * @brief This is the 'main' function called by a child right after the fork. * It is daemon specific and should initialize and perform whatever * operation the child is meant to do. Returning from this function will * cause the termination of the child. * * @param ev The event context * @param pf The mmaped area used to communicate with parent * @param listen_fd_size The number of file descriptors to monitor * @param listen_fds The array of file descriptors * @param lock_fd The locking file descriptor * @param private_data Private data that needs to be passed to the main * function from the calling parent. * * @return Returns the exit status to be reported to the parent via exit() */ typedef int (prefork_main_fn_t)(struct tevent_context *ev, struct pf_worker_data *pf, int listen_fd_size, int *listen_fds, int lock_fd, void *private_data); struct prefork_pool; /* ==== Functions used by controlling process ==== */ /** * @brief Creates the first pool of preforked processes * * @param ev_ctx The event context * @param mem_ctx The memory context used to hold the pool structure * @param listen_fd_size The number of file descriptors to monitor * @param listen_fds The array of file descriptors to monitor * @param min_children Minimum number of children that must be available at * any given time * @param max_children Maximum number of children that can be started. Also * determines the initial size of the pool. * @param main_fn The children 'main' function to be called after fork * @param private_data The children private data. * @param pf_pool The allocated pool. * * @return True if it was successful, False otherwise. */ bool prefork_create_pool(struct tevent_context *ev_ctx, TALLOC_CTX *mem_ctx, int listen_fd_size, int *listen_fds, int min_children, int max_children, prefork_main_fn_t *main_fn, void *private_data, struct prefork_pool **pf_pool); /** * @brief Function used to attemp to expand the size of children. * * @param pfp The pool structure. * @param new_max The new max number of children. * * @return 0 if operation was successful * ENOSPC if the mmap area could not be grown to the requested size * EINVAL if the new max is invalid. * * NOTE: this funciton can easily fail if the mmap area cannot be enlarged. * A well behaving parent MUST NOT error out if this happen. */ int prefork_expand_pool(struct prefork_pool *pfp, int new_max); /** * @brief Used to prefork a number of new children * * @param ev_ctx The event context * @param pfp The pool structure * @param num_children The number of children to be started * * @return The number of new children effectively forked. * * NOTE: This method does not expand the pool, if the max number of children * has already been forked it will do nothing. */ int prefork_add_children(struct tevent_context *ev_ctx, struct prefork_pool *pfp, int num_children); /** * @brief Commands a number fo children to stop and exit * * @param pfp The pool. * @param num_children The number of children we need to retire. * @param age_limit The minimum age a child has been active to be * considered for retirement. (Compared against the * 'started' value in the pf_worker_data structure of the * children. * * @return Number of children that were signaled to stop * * NOTE: Only children that has no attached clients can be stopped. * If all the available children are too young or are busy than it * is possible that none will be asked to stop. */ int prefork_retire_children(struct prefork_pool *pfp, int num_children, time_t age_limit); /** * @brief Count the number of active children * * @param pfp The pool. * @param total Returns the number of children currently alive * * @return The number of children actually serving clients */ int prefork_count_active_children(struct prefork_pool *pfp, int *total); /** * @brief Perform cleanups, like waiting (WNOHANG) dead children. * MUST be called regularly from the parent main loop. * * @param pfp The pool. */ void prefork_cleanup_loop(struct prefork_pool *pfp); /** * @brief Inform all children that they are allowed to accept 'max' clients * now. Use this when all children are already busy and more clients * are trying to connect. It will allow each child to handle more than * one client at a time, up to 'max'. * * @param pfp The pool. * @param max Max number of clients per child. */ void prefork_increase_allowed_clients(struct prefork_pool *pfp, int max); /** * @brief Reset the maximum allowd clients per child to 1. * Does not reduce the number of clients actually beeing served by * any given child, but prevents children from overcommitting from * now on. * * @param pfp The pool. */ void prefork_reset_allowed_clients(struct prefork_pool *pfp); /** * @brief Send a specific signal to all children. * Used to send SIGHUP when a reload of the configuration is needed * for example. * * @param pfp The pool. * @param signal_num The signal number to be sent. */ void prefork_send_signal_to_all(struct prefork_pool *pfp, int signal_num); /* ==== Functions used by children ==== */ /** * @brief Try to listen and accept on one of the listening sockets. * Asynchronusly tries to grab the lock and perform an accept. * Will automatically updated the 'status' of the child and handle * all the locking/unlocking/timingout as necessary. * Changes behavior depending on whether the child already has other * client connections. If not it blocks on the lock call for periods of * time. Otherwise it loops on the lock using a timer in order to allow * processing of the other clients requests. * * @param mem_ctx The memory context on whic to allocate the request * @param ev The event context * @param pf The child/parent shared structure * @param listen_fd_size The number of listening file descriptors * @param listen_fds The array of listening file descriptors * @param lock_fd The locking file descriptor * @param addr The structure that will hold the client address on * return * @param addrlen The structure length on return. * * @return The tevent request pointer or NULL on allocation errors. */ struct tevent_req *prefork_listen_send(TALLOC_CTX *mem_ctx, struct tevent_context *ev, struct pf_worker_data *pf, int listen_fd_size, int *listen_fds, int lock_fd, struct sockaddr *addr, socklen_t *addrlen); /** * @brief Returns the file descriptor after the new client connection has * been accepted. * * @param req The request * @param fd The new file descriptor. * * @return The error in case the operation failed. */ int prefork_listen_recv(struct tevent_req *req, int *fd);