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freeswitch/src/include/switch_apr.h

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/*
* FreeSWITCH Modular Media Switching Software Library / Soft-Switch Application
* Copyright (C) 2005/2006, Anthony Minessale II <anthmct@yahoo.com>
*
* Version: MPL 1.1
*
* The contents of this file are subject to the Mozilla Public License Version
* 1.1 (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.mozilla.org/MPL/
*
* Software distributed under the License is distributed on an "AS IS" basis,
* WITHOUT WARRANTY OF ANY KIND, either express or implied. See the License
* for the specific language governing rights and limitations under the
* License.
*
* The Original Code is FreeSWITCH Modular Media Switching Software Library / Soft-Switch Application
*
* The Initial Developer of the Original Code is
* Anthony Minessale II <anthmct@yahoo.com>
* Portions created by the Initial Developer are Copyright (C)
* the Initial Developer. All Rights Reserved.
*
* Contributor(s):
*
* Anthony Minessale II <anthmct@yahoo.com>
*
* switch_apr.h -- APR includes header
*
*/
/*! \file switch_apr.h
\brief APR includes header
The things powered by APR are renamed into the switch_ namespace to provide a cleaner
look to things and helps me to document what parts of APR I am using I'd like to take this
opportunity to thank APR for all the awesome stuff it does and for making my life much easier.
*/
#ifndef SWITCH_APR_H
#define SWITCH_APR_H
#ifdef __cplusplus
extern "C" {
#endif
#include <apr.h>
#include <apr_network_io.h>
#include <apr_errno.h>
#include <apr_general.h>
#include <apr_thread_proc.h>
#include <apr_thread_mutex.h>
#include <apr_thread_cond.h>
#include <apr_thread_rwlock.h>
#include <apr_file_io.h>
#include <apr_poll.h>
#include <apr_dso.h>
#include <apr_hash.h>
#include <apr_strings.h>
#include <apr_network_io.h>
#include <apr_poll.h>
#include <apr_queue.h>
#include <apr_uuid.h>
#include <apr_strmatch.h>
#define APR_WANT_STDIO
#define APR_WANT_STRFUNC
#include <apr_want.h>
#include <apr_env.h>
/*
The pieces of apr we allow ppl to pass around between modules we typedef into our namespace and wrap all the functions
any other apr code should be as hidden as possible.
*/
/**
* @defgroup switch_apr Brought To You By APR
* @ingroup FREESWITCH
* @{
*/
typedef apr_size_t swtich_size_t;
typedef apr_int16_t switch_int16_t;
/**
* @defgroup switch_file_io File I/O Handling Functions
* @ingroup switch_apr
* @{
*/
typedef apr_size_t switch_size_t;
/** Structure for referencing files. */
typedef apr_file_t switch_file_t;
#define SWITCH_SO_LINGER APR_SO_LINGER
#define SWITCH_SO_KEEPALIVE APR_SO_KEEPALIVE
#define SWITCH_SO_DEBUG APR_SO_DEBUG
#define SWITCH_SO_NONBLOCK APR_SO_NONBLOCK
#define SWITCH_SO_REUSEADDR APR_SO_REUSEADDR
#define SWITCH_SO_SNDBUF APR_SO_SNDBUF
#define SWITCH_SO_RCVBUF APR_SO_RCVBUF
#define SWITCH_SO_DISCONNECTED APR_SO_DISCONNECTED
/**
* @defgroup switch_file_permissions File Permissions flags
* @ingroup switch_file_io
* @{
*/
#define SWITCH_FPROT_USETID APR_FPROT_USETID /**< Set user id */
#define SWITCH_FPROT_UREAD APR_FPROT_UREAD /**< Read by user */
#define SWITCH_FPROT_UWRITE APR_FPROT_UWRITE /**< Write by user */
#define SWITCH_FPROT_UEXECUTE APR_FPROT_UEXECUTE /**< Execute by user */
#define SWITCH_FPROT_GSETID APR_FPROT_GSETID /**< Set group id */
#define SWITCH_FPROT_GREAD APR_FPROT_GREAD /**< Read by group */
#define SWITCH_FPROT_GWRITE APR_FPROT_GWRITE /**< Write by group */
#define SWITCH_FPROT_GEXECUTE APR_FPROT_GEXECUTE /**< Execute by group */
#define SWITCH_FPROT_WSETID APR_FPROT_U WSETID
#define SWITCH_FPROT_WREAD APR_FPROT_WREAD /**< Read by others */
#define SWITCH_FPROT_WWRITE APR_FPROT_WWRITE /**< Write by others */
#define SWITCH_FPROT_WEXECUTE APR_FPROT_WEXECUTE /**< Execute by others */
#define SWITCH_FPROT_OS_DEFAULT APR_FPROT_OS_DEFAULT /**< use OS's default permissions */
/* additional permission flags for apr_file_copy and apr_file_append */
#define SWITCH_FPROT_FILE_SOURCE_PERMS APR_FPROT_FILE_SOURCE_PERMS /**< Copy source file's permissions */
/** @} */
/**
* @defgroup switch_file_open_flags File Open Flags/Routines
* @ingroup switch_file_io
* @{
*/
#define SWITCH_FOPEN_READ APR_FOPEN_READ /**< Open the file for reading */
#define SWITCH_FOPEN_WRITE APR_FOPEN_WRITE /**< Open the file for writing */
#define SWITCH_FOPEN_CREATE APR_FOPEN_CREATE /**< Create the file if not there */
#define SWITCH_FOPEN_APPEND APR_FOPEN_APPEND /**< Append to the end of the file */
#define SWITCH_FOPEN_TRUNCATE APR_FOPEN_TRUNCATE /**< Open the file and truncate to 0 length */
#define SWITCH_FOPEN_BINARY APR_FOPEN_BINARY /**< Open the file in binary mode */
#define SWITCH_FOPEN_EXCL APR_FOPEN_EXCL /**< Open should fail if APR_CREATE and file exists. */
#define SWITCH_FOPEN_BUFFERED APR_FOPEN_BUFFERED /**< Open the file for buffered I/O */
#define SWITCH_FOPEN_DELONCLOSE APR_FOPEN_DELONCLOSE /**< Delete the file after close */
#define SWITCH_FOPEN_XTHREAD APR_FOPEN_XTHREAD /**< Platform dependent tag to open the file for use across multiple threads */
#define SWITCH_FOPEN_SHARELOCK APR_FOPEN_SHARELOCK /**< Platform dependent support for higher level locked read/write access to support writes across process/machines */
#define SWITCH_FOPEN_NOCLEANUP APR_FOPEN_NOCLEANUP /**< Do not register a cleanup when the file is opened */
#define SWITCH_FOPEN_SENDFILE_ENABLED APR_FOPEN_SENDFILE_ENABLED /**< Advisory flag that this file should support apr_socket_sendfile operation */
#define SWITCH_FOPEN_LARGEFILE APR_FOPEN_LAREFILE /**< Platform dependent flag to enable large file support */
/** @} */
/**
* Open the specified file.
* @param newf The opened file descriptor.
* @param fname The full path to the file (using / on all systems)
* @param flag Or'ed value of:
* <PRE>
* SWITCH_FOPEN_READ open for reading
* SWITCH_FOPEN_WRITE open for writing
* SWITCH_FOPEN_CREATE create the file if not there
* SWITCH_FOPEN_APPEND file ptr is set to end prior to all writes
* SWITCH_FOPEN_TRUNCATE set length to zero if file exists
* SWITCH_FOPEN_BINARY not a text file (This flag is ignored on
* UNIX because it has no meaning)
* SWITCH_FOPEN_BUFFERED buffer the data. Default is non-buffered
* SWITCH_FOPEN_EXCL return error if APR_CREATE and file exists
* SWITCH_FOPEN_DELONCLOSE delete the file after closing.
* SWITCH_FOPEN_XTHREAD Platform dependent tag to open the file
* for use across multiple threads
* SWITCH_FOPEN_SHARELOCK Platform dependent support for higher
* level locked read/write access to support
* writes across process/machines
* SWITCH_FOPEN_NOCLEANUP Do not register a cleanup with the pool
* passed in on the <EM>pool</EM> argument (see below).
* The apr_os_file_t handle in apr_file_t will not
* be closed when the pool is destroyed.
* SWITCH_FOPEN_SENDFILE_ENABLED Open with appropriate platform semantics
* for sendfile operations. Advisory only,
* apr_socket_sendfile does not check this flag.
* </PRE>
* @param perm Access permissions for file.
* @param pool The pool to use.
* @remark If perm is SWITCH_FPROT_OS_DEFAULT and the file is being created,
* appropriate default permissions will be used.
*/
DoxyDefine(apr_status_t switch_file_open(switch_file_t **newf, const char *fname, apr_int32_t flag, switch_fileperms_t perm, switch_pool_t *pool);)
#define switch_file_open apr_file_open
/**
* Close the specified file.
* @param file The file descriptor to close.
*/
DoxyDefine(apr_status_t switch_file_close(switch_file_t *file);)
#define switch_file_close apr_file_close
/**
* Read data from the specified file.
* @param thefile The file descriptor to read from.
* @param buf The buffer to store the data to.
* @param nbytes On entry, the number of bytes to read; on exit, the number
* of bytes read.
*
* @remark apr_file_read will read up to the specified number of
* bytes, but never more. If there isn't enough data to fill that
* number of bytes, all of the available data is read. The third
* argument is modified to reflect the number of bytes read. If a
* char was put back into the stream via ungetc, it will be the first
* character returned.
*
* @remark It is not possible for both bytes to be read and an APR_EOF
* or other error to be returned. APR_EINTR is never returned.
*/
DoxyDefine(apr_status_t switch_file_read(switch_file_t *thefile, void *buf, switch_size_t *nbytes);)
#define switch_file_read apr_file_read
/**
* Write data to the specified file.
* @param thefile The file descriptor to write to.
* @param buf The buffer which contains the data.
* @param nbytes On entry, the number of bytes to write; on exit, the number
* of bytes written.
*
* @remark apr_file_write will write up to the specified number of
* bytes, but never more. If the OS cannot write that many bytes, it
* will write as many as it can. The third argument is modified to
* reflect the * number of bytes written.
*
* @remark It is possible for both bytes to be written and an error to
* be returned. APR_EINTR is never returned.
*/
DoxyDefine(apr_status_t switch_file_write(switch_file_t *thefile, const void *buf, switch_size_t *nbytes);)
#define switch_file_write apr_file_write
/** @} */
/**
* @defgroup switch_thread_cond Condition Variable Routines
* @ingroup switch_apr
* @{
*/
/**
* Note: destroying a condition variable (or likewise, destroying or
* clearing the pool from which a condition variable was allocated) if
* any threads are blocked waiting on it gives undefined results.
*/
/** Opaque structure for thread condition variables */
typedef apr_thread_cond_t switch_thread_cond_t;
/**
* Create and initialize a condition variable that can be used to signal
* and schedule threads in a single process.
* @param cond the memory address where the newly created condition variable
* will be stored.
* @param pool the pool from which to allocate the mutex.
*/
DoxyDefine(apr_status_t switch_thread_cond_create(switch_thread_cond_t **cond, switch_pool_t *pool);)
#define switch_thread_cond_create apr_thread_cond_create
/**
* Put the active calling thread to sleep until signaled to wake up. Each
* condition variable must be associated with a mutex, and that mutex must
* be locked before calling this function, or the behavior will be
* undefined. As the calling thread is put to sleep, the given mutex
* will be simultaneously released; and as this thread wakes up the lock
* is again simultaneously acquired.
* @param cond the condition variable on which to block.
* @param mutex the mutex that must be locked upon entering this function,
* is released while the thread is asleep, and is again acquired before
* returning from this function.
*/
DoxyDefine(apr_status_t switch_thread_cond_wait(switch_thread_cond_t *cond, switch_thread_mutex_t *mutex);)
#define switch_thread_cond_wait apr_thread_cond_wait
/**
* Put the active calling thread to sleep until signaled to wake up or
* the timeout is reached. Each condition variable must be associated
* with a mutex, and that mutex must be locked before calling this
* function, or the behavior will be undefined. As the calling thread
* is put to sleep, the given mutex will be simultaneously released;
* and as this thread wakes up the lock is again simultaneously acquired.
* @param cond the condition variable on which to block.
* @param mutex the mutex that must be locked upon entering this function,
* is released while the thread is asleep, and is again acquired before
* returning from this function.
* @param timeout The amount of time in microseconds to wait. This is
* a maximum, not a minimum. If the condition is signaled, we
* will wake up before this time, otherwise the error APR_TIMEUP
* is returned.
*/
DoxyDefine(apr_status_t switch_thread_cond_timedwait(switch_thread_cond_t *cond, switch_thread_mutex_t *mutex, switch_interval_time_t timeout);)
#define switch_thread_cond_timedwait apr_thread_cond_timedwait
/**
* Signals a single thread, if one exists, that is blocking on the given
* condition variable. That thread is then scheduled to wake up and acquire
* the associated mutex. Although it is not required, if predictable scheduling
* is desired, that mutex must be locked while calling this function.
* @param cond the condition variable on which to produce the signal.
*/
DoxyDefine(apr_status_t switch_thread_cond_signal(switch_thread_cond_t *cond);)
#define switch_thread_cond_signal apr_thread_cond_signal
/**
* Signals all threads blocking on the given condition variable.
* Each thread that was signaled is then scheduled to wake up and acquire
* the associated mutex. This will happen in a serialized manner.
* @param cond the condition variable on which to produce the broadcast.
*/
DoxyDefine(apr_status_t switch_thread_cond_broadcast(switch_thread_cond_t *cond);)
#define switch_thread_cond_broadcast apr_thread_cond_broadcast
/**
* Destroy the condition variable and free the associated memory.
* @param cond the condition variable to destroy.
*/
DoxyDefine(apr_status_t switch_thread_cond_destroy(switch_thread_cond_t *cond);)
#define switch_thread_cond_destroy apr_thread_cond_destroy
/** @} */
/**
* @defgroup switch_thread_proc Threads and Process Functions
* @ingroup switch_apr
* @{
*/
/** Opaque Thread structure. */
typedef apr_thread_t switch_thread;
/** Opaque Thread attributes structure. */
typedef apr_threadattr_t switch_threadattr_t;
/**
* The prototype for any APR thread worker functions.
* typedef void *(SWITCH_THREAD_FUNC *switch_thread_start_t)(switch_thread_t*, void*);
*/
#define SWITCH_THREAD_FUNC APR_THREAD_FUNC
typedef apr_thread_start_t switch_thread_start_t;
#define switch_threadattr_stacksize_set apr_threadattr_stacksize_set
/**
* Create and initialize a new threadattr variable
* @param new_attr The newly created threadattr.
* @param cont The pool to use
*/
DoxyDefine(apr_status_t switch_threadattr_create(switch_threadattr_t **new_attr, switch_pool_t *cont);)
#define switch_threadattr_create apr_threadattr_create
/**
* Set if newly created threads should be created in detached state.
* @param attr The threadattr to affect
* @param on Non-zero if detached threads should be created.
*/
DoxyDefine(apr_status_t switch_threadattr_detach_set(switch_threadattr_t *attr, switch_int32_t on);)
#define switch_threadattr_detach_set apr_threadattr_detach_set
/**
* Create a new thread of execution
* @param new_thread The newly created thread handle.
* @param attr The threadattr to use to determine how to create the thread
* @param func The function to start the new thread in
* @param data Any data to be passed to the starting function
* @param cont The pool to use
*/
DoxyDefine(apr_status_t switch_thread_create(switch_thread_t **new_thread, switch_threadattr_t *attr, switch_thread_start_t func, void *data, switch_pool_t *cont);)
#define switch_thread_create apr_thread_create
/** @} */
/**
* @defgroup switch_network_io Network Routines
* @ingroup switch_apr
* @{
*/
/** descriptor refers to a socket */
#define SWITCH_POLL_SOCKET APR_POLL_SOCKET
/** @def SWITCH_UNSPEC
* Let the system decide which address family to use
*/
#define SWITCH_UNSPEC APR_UNSPEC
/** A structure to represent sockets */
typedef apr_socket_t switch_socket_t;
/** Freeswitch's socket address type, used to ensure protocol independence */
typedef apr_sockaddr_t switch_sockaddr_t;
typedef apr_port_t switch_port_t;
/* function definitions */
/**
* Create a socket.
* @param new_sock The new socket that has been set up.
* @param family The address family of the socket (e.g., APR_INET).
* @param type The type of the socket (e.g., SOCK_STREAM).
* @param protocol The protocol of the socket (e.g., APR_PROTO_TCP).
* @param cont The pool to use
*/
DoxyDefine(apr_status_t switch_socket_create(switch_socket_t **new_sock, int family, int type, int protocol, switch_pool_t *cont);)
#define switch_socket_create apr_socket_create
/**
* Shutdown either reading, writing, or both sides of a socket.
* @param thesocket The socket to close
* @param how How to shutdown the socket. One of:
* <PRE>
* APR_SHUTDOWN_READ no longer allow read requests
* APR_SHUTDOWN_WRITE no longer allow write requests
* APR_SHUTDOWN_READWRITE no longer allow read or write requests
* </PRE>
* @see apr_shutdown_how_e
* @remark This does not actually close the socket descriptor, it just
* controls which calls are still valid on the socket.
*/
DoxyDefine(apr_status_t switch_socket_shutdown(switch_socket_t *thesocket, switch_shutdown_how_e how);)
#define switch_socket_shutdown apr_socket_shutdown
/**
* Close a socket.
* @param thesocket The socket to close
*/
DoxyDefine(apr_status_t switch_socket_close(switch_socket_t *thesocket);)
#define switch_socket_close apr_socket_close
/**
* Bind the socket to its associated port
* @param sock The socket to bind
* @param sa The socket address to bind to
* @remark This may be where we will find out if there is any other process
* using the selected port.
*/
DoxyDefine(apr_status_t switch_socket_bind(switch_socket_t *sock, switch_sockaddr_t *sa);)
#define switch_socket_bind apr_socket_bind
/**
* Listen to a bound socket for connections.
* @param sock The socket to listen on
* @param backlog The number of outstanding connections allowed in the sockets
* listen queue. If this value is less than zero, the listen
* queue size is set to zero.
*/
DoxyDefine(apr_status_t switch_socket_listen(switch_socket_t *sock, switch_int32_t backlog);)
#define switch_socket_listen apr_socket_listen
/**
* Accept a new connection request
* @param new_sock A copy of the socket that is connected to the socket that
* made the connection request. This is the socket which should
* be used for all future communication.
* @param sock The socket we are listening on.
* @param connection_pool The pool for the new socket.
*/
DoxyDefine(apr_status_t switch_socket_accept(switch_socket_t **new_sock, switch_socket_t *sock, switch_pool_t *connection_pool);)
#define switch_socket_accept apr_socket_accept
/**
* Issue a connection request to a socket either on the same machine
* or a different one.
* @param sock The socket we wish to use for our side of the connection
* @param sa The address of the machine we wish to connect to.
*/
DoxyDefine(apr_status_t switch_socket_connect(switch_socket_t *sock, switch_sockaddr_t *sa);)
#define switch_socket_connect apr_socket_connect
/**
* Create apr_sockaddr_t from hostname, address family, and port.
* @param sa The new apr_sockaddr_t.
* @param hostname The hostname or numeric address string to resolve/parse, or
* NULL to build an address that corresponds to 0.0.0.0 or ::
* @param family The address family to use, or APR_UNSPEC if the system should
* decide.
* @param port The port number.
* @param flags Special processing flags:
* <PRE>
* APR_IPV4_ADDR_OK first query for IPv4 addresses; only look
* for IPv6 addresses if the first query failed;
* only valid if family is APR_UNSPEC and hostname
* isn't NULL; mutually exclusive with
* APR_IPV6_ADDR_OK
* APR_IPV6_ADDR_OK first query for IPv6 addresses; only look
* for IPv4 addresses if the first query failed;
* only valid if family is APR_UNSPEC and hostname
* isn't NULL and APR_HAVE_IPV6; mutually exclusive
* with APR_IPV4_ADDR_OK
* </PRE>
* @param p The pool for the apr_sockaddr_t and associated storage.
*/
DoxyDefine(apr_status_t switch_sockaddr_info_get(switch_sockaddr_t **sa,
const char *hostname,
switch_int32_t family,
switch_port_t port,
switch_int32_t flags,
switch_pool_t *p);)
#define switch_sockaddr_info_get apr_sockaddr_info_get
/**
* Look up the host name from an apr_sockaddr_t.
* @param hostname The hostname.
* @param sa The apr_sockaddr_t.
* @param flags Special processing flags.
*/
DoxyDefine(apr_status_t switch_getnameinfo(char **hostname,
switch_sockaddr_t *sa,
switch_int32_t flags);)
#define switch_getnameinfo apr_getnameinfo
/**
* Parse hostname/IP address with scope id and port.
*
* Any of the following strings are accepted:
* 8080 (just the port number)
* www.apache.org (just the hostname)
* www.apache.org:8080 (hostname and port number)
* [fe80::1]:80 (IPv6 numeric address string only)
* [fe80::1%eth0] (IPv6 numeric address string and scope id)
*
* Invalid strings:
* (empty string)
* [abc] (not valid IPv6 numeric address string)
* abc:65536 (invalid port number)
*
* @param addr The new buffer containing just the hostname. On output, *addr
* will be NULL if no hostname/IP address was specfied.
* @param scope_id The new buffer containing just the scope id. On output,
* *scope_id will be NULL if no scope id was specified.
* @param port The port number. On output, *port will be 0 if no port was
* specified.
* ### FIXME: 0 is a legal port (per RFC 1700). this should
* ### return something besides zero if the port is missing.
* @param str The input string to be parsed.
* @param p The pool from which *addr and *scope_id are allocated.
* @remark If scope id shouldn't be allowed, check for scope_id != NULL in
* addition to checking the return code. If addr/hostname should be
* required, check for addr == NULL in addition to checking the
* return code.
*/
DoxyDefine(apr_status_t switch_parse_addr_port(char **addr,
char **scope_id,
switch_port_t *port,
const char *str,
switch_pool_t *p);)
#define switch_parse_addr_port apr_parse_addr_port
/**
* Get name of the current machine
* @param buf A buffer to store the hostname in.
* @param len The maximum length of the hostname that can be stored in the
* buffer provided. The suggested length is APRMAXHOSTLEN + 1.
* @param cont The pool to use.
* @remark If the buffer was not large enough, an error will be returned.
*/
DoxyDefine(apr_status_t switch_gethostname(char *buf, int len, switch_pool_t *cont);)
#define switch_gethostname apr_gethostname
/**
* Return the data associated with the current socket
* @param data The user data associated with the socket.
* @param key The key to associate with the user data.
* @param sock The currently open socket.
*/
DoxyDefine(apr_status_t switch_socket_data_get(void **data, const char *key,
switch_socket_t *sock);)
#define switch_socket_data_get apr_socket_data_get
/**
* Set the data associated with the current socket.
* @param sock The currently open socket.
* @param data The user data to associate with the socket.
* @param key The key to associate with the data.
* @param cleanup The cleanup to call when the socket is destroyed.
*/
DoxyDefine(apr_status_t switch_socket_data_set(switch_socket_t *sock,
void *data,
const char *key,
switch_status_t (*cleanup)(void*));)
#define switch_socket_data_set apr_socket_data_set
/**
* Send data over a network.
* @param sock The socket to send the data over.
* @param buf The buffer which contains the data to be sent.
* @param len On entry, the number of bytes to send; on exit, the number
* of bytes sent.
* @remark
* <PRE>
* This functions acts like a blocking write by default. To change
* this behavior, use apr_socket_timeout_set() or the APR_SO_NONBLOCK
* socket option.
*
* It is possible for both bytes to be sent and an error to be returned.
*
* APR_EINTR is never returned.
* </PRE>
*/
DoxyDefine(apr_status_t switch_socket_send(switch_socket_t *sock,
const char *buf,
apr_size_t *len);)
#define switch_socket_send apr_socket_send
/**
* Send multiple packets of data over a network.
* @param sock The socket to send the data over.
* @param vec The array of iovec structs containing the data to send
* @param nvec The number of iovec structs in the array
* @param len Receives the number of bytes actually written
* @remark
* <PRE>
* This functions acts like a blocking write by default. To change
* this behavior, use apr_socket_timeout_set() or the APR_SO_NONBLOCK
* socket option.
* The number of bytes actually sent is stored in argument 3.
*
* It is possible for both bytes to be sent and an error to be returned.
*
* APR_EINTR is never returned.
* </PRE>
*/
DoxyDefine(apr_status_t switch_socket_sendv(switch_socket_t *sock,
const struct iovec *vec,
apr_int32_t nvec, apr_size_t *len);)
#define switch_socket_sendv apr_socket_sendv
/**
* @param sock The socket to send from
* @param where The apr_sockaddr_t describing where to send the data
* @param flags The flags to use
* @param buf The data to send
* @param len The length of the data to send
*/
DoxyDefine(apr_status_t switch_socket_sendto(switcj_socket_t *sock,
apr_sockaddr_t *where,
apr_int32_t flags,
const char *buf,
apr_size_t *len);)
#define switch_socket_sendto apr_socket_sendto
/**
* @param from The apr_sockaddr_t to fill in the recipient info
* @param sock The socket to use
* @param flags The flags to use
* @param buf The buffer to use
* @param len The length of the available buffer
*/
DoxyDefine(apr_status_t switch_socket_recvfrom(switch_sockaddr_t *from,
switch_socket_t *sock,
apr_int32_t flags,
char *buf,
apr_size_t *len);)
//#define switch_socket_recvfrom apr_socket_recvfrom
/**
* Send a file from an open file descriptor to a socket, along with
* optional headers and trailers
* @param sock The socket to which we're writing
* @param file The open file from which to read
* @param hdtr A structure containing the headers and trailers to send
* @param offset Offset into the file where we should begin writing
* @param len (input) - Number of bytes to send from the file
* (output) - Number of bytes actually sent,
* including headers, file, and trailers
* @param flags APR flags that are mapped to OS specific flags
* @remark This functions acts like a blocking write by default. To change
* this behavior, use apr_socket_timeout_set() or the
* APR_SO_NONBLOCK socket option.
* The number of bytes actually sent is stored in the len parameter.
* The offset parameter is passed by reference for no reason; its
* value will never be modified by the apr_socket_sendfile() function.
*/
DoxyDefine(apr_status_t switch_socket_sendfile(apr_socket_t *sock,
switch_file_t *file,
apr_hdtr_t *hdtr,
apr_off_t *offset,
apr_size_t *len,
apr_int32_t flags);)
#define switch_socket_sendfile apr_socket_sendfile
/**
* Read data from a network.
* @param sock The socket to read the data from.
* @param buf The buffer to store the data in.
* @param len On entry, the number of bytes to receive; on exit, the number
* of bytes received.
* @remark
* <PRE>
* This functions acts like a blocking read by default. To change
* this behavior, use apr_socket_timeout_set() or the APR_SO_NONBLOCK
* socket option.
* The number of bytes actually received is stored in argument 3.
*
* It is possible for both bytes to be received and an APR_EOF or
* other error to be returned.
*
* APR_EINTR is never returned.
* </PRE>
*/
DoxyDefine(apr_status_t switch_socket_recv(switch_socket_t *sock,
char *buf,
apr_size_t *len);)
#define switch_socket_recv apr_socket_recv
/**
* Setup socket options for the specified socket
* @param sock The socket to set up.
* @param opt The option we would like to configure. One of:
* <PRE>
* APR_SO_DEBUG -- turn on debugging information
* APR_SO_KEEPALIVE -- keep connections active
* APR_SO_LINGER -- lingers on close if data is present
* APR_SO_NONBLOCK -- Turns blocking on/off for socket
* When this option is enabled, use
* the APR_STATUS_IS_EAGAIN() macro to
* see if a send or receive function
* could not transfer data without
* blocking.
* APR_SO_REUSEADDR -- The rules used in validating addresses
* supplied to bind should allow reuse
* of local addresses.
* APR_SO_SNDBUF -- Set the SendBufferSize
* APR_SO_RCVBUF -- Set the ReceiveBufferSize
* </PRE>
* @param on Value for the option.
*/
DoxyDefine(apr_status_t switch_socket_opt_set(switch_socket_t *sock,
apr_int32_t opt,
apr_int32_t on);)
#define switch_socket_opt_set apr_socket_opt_set
/**
* Setup socket timeout for the specified socket
* @param sock The socket to set up.
* @param t Value for the timeout.
* <PRE>
* t > 0 -- read and write calls return APR_TIMEUP if specified time
* elapsess with no data read or written
* t == 0 -- read and write calls never block
* t < 0 -- read and write calls block
* </PRE>
*/
DoxyDefine(apr_status_t switch_socket_timeout_set(switch_socket_t *sock,
apr_interval_time_t t);)
#define switch_socket_timeout_set apr_socket_timeout_set
/**
* Query socket options for the specified socket
* @param sock The socket to query
* @param opt The option we would like to query. One of:
* <PRE>
* APR_SO_DEBUG -- turn on debugging information
* APR_SO_KEEPALIVE -- keep connections active
* APR_SO_LINGER -- lingers on close if data is present
* APR_SO_NONBLOCK -- Turns blocking on/off for socket
* APR_SO_REUSEADDR -- The rules used in validating addresses
* supplied to bind should allow reuse
* of local addresses.
* APR_SO_SNDBUF -- Set the SendBufferSize
* APR_SO_RCVBUF -- Set the ReceiveBufferSize
* APR_SO_DISCONNECTED -- Query the disconnected state of the socket.
* (Currently only used on Windows)
* </PRE>
* @param on Socket option returned on the call.
*/
DoxyDefine(apr_status_t switch_socket_opt_get(switch_socket_t *sock,
apr_int32_t opt, apr_int32_t *on);)
#define switch_socket_opt_get apr_socket_opt_get
/**
* Query socket timeout for the specified socket
* @param sock The socket to query
* @param t Socket timeout returned from the query.
*/
DoxyDefine(apr_status_t switch_socket_timeout_get(switch_socket_t *sock,
apr_interval_time_t *t);)
#define switch_socket_timeout_get apr_socket_timeout_get
/**
* Query the specified socket if at the OOB/Urgent data mark
* @param sock The socket to query
* @param atmark Is set to true if socket is at the OOB/urgent mark,
* otherwise is set to false.
*/
DoxyDefine(apr_status_t switch_socket_atmark(switch_socket_t *sock,
int *atmark);)
#define switch_socket_atmark apr_socket_atmark
/**
* Return an apr_sockaddr_t from an apr_socket_t
* @param sa The returned apr_sockaddr_t.
* @param which Which interface do we want the apr_sockaddr_t for?
* @param sock The socket to use
*/
DoxyDefine(apr_status_t switch_socket_addr_get(switch_sockaddr_t **sa,
apr_interface_e which,
switch_socket_t *sock);)
#define switch_socket_addr_get apr_socket_addr_get
/**
* Return the IP address (in numeric address string format) in
* an APR socket address. APR will allocate storage for the IP address
* string from the pool of the apr_sockaddr_t.
* @param addr The IP address.
* @param sockaddr The socket address to reference.
*/
DoxyDefine(apr_status_t switch_sockaddr_ip_get(char **addr,
switch_sockaddr_t *sockaddr);)
#define switch_sockaddr_ip_get apr_sockaddr_ip_get
/**
* See if the IP addresses in two APR socket addresses are
* equivalent. Appropriate logic is present for comparing
* IPv4-mapped IPv6 addresses with IPv4 addresses.
*
* @param addr1 One of the APR socket addresses.
* @param addr2 The other APR socket address.
* @remark The return value will be non-zero if the addresses
* are equivalent.
*/
DoxyDefine(int switch_sockaddr_equal(const switch_sockaddr_t *addr1,
const switch_sockaddr_t *addr2);)
#define switch_sockaddr_equal apr_sockaddr_equal
/**
* Return the type of the socket.
* @param sock The socket to query.
* @param type The returned type (e.g., SOCK_STREAM).
*/
DoxyDefine(apr_status_t switch_socket_type_get(switch_socket_t *sock,
int *type);)
#define switch_socket_type_get apr_socket_type_get
/**
* Given an switch_sockaddr_t and a service name, set the port for the service
* @param sockaddr The switch_sockaddr_t that will have its port set
* @param servname The name of the service you wish to use
*/
DoxyDefine(apr_status_t switch_getservbyname(switch_sockaddr_t *sockaddr,
const char *servname);)
#define switch_getservbyname apr_getservbyname
/**
* Build an ip-subnet representation from an IP address and optional netmask or
* number-of-bits.
* @param ipsub The new ip-subnet representation
* @param ipstr The input IP address string
* @param mask_or_numbits The input netmask or number-of-bits string, or NULL
* @param p The pool to allocate from
*/
DoxyDefine(apr_status_t switch_ipsubnet_create(apr_ipsubnet_t **ipsub,
const char *ipstr,
const char *mask_or_numbits,
switch_pool_t *p);)
#define switch_ipsubnet_create apr_ipsubnet_create
/**
* Test the IP address in an apr_sockaddr_t against a pre-built ip-subnet
* representation.
* @param ipsub The ip-subnet representation
* @param sa The socket address to test
* @return non-zero if the socket address is within the subnet, 0 otherwise
*/
DoxyDefine(int switch_ipsubnet_test(apr_ipsubnet_t *ipsub, switch_sockaddr_t *sa);)
#define switch_ipsubnet_test apr_ipsubnet_test
/**
* Return the protocol of the socket.
* @param sock The socket to query.
* @param protocol The returned protocol (e.g., APR_PROTO_TCP).
*/
DoxyDefine(apr_status_t switch_socket_protocol_get(switch_socket_t *sock,
int *protocol);)
#define switch_socket_protocol_get apr_socket_protocol_get
/**
* Join a Multicast Group
* @param sock The socket to join a multicast group
* @param join The address of the multicast group to join
* @param iface Address of the interface to use. If NULL is passed, the
* default multicast interface will be used. (OS Dependent)
* @param source Source Address to accept transmissions from (non-NULL
* implies Source-Specific Multicast)
*/
DoxyDefine(apr_status_t switch_mcast_join(switch_socket_t *sock,
switch_sockaddr_t *join,
switch_sockaddr_t *iface,
switch_sockaddr_t *source);)
#define switch_mcast_join apr_mcast_join
/**
* Leave a Multicast Group. All arguments must be the same as
* switch_mcast_join.
* @param sock The socket to leave a multicast group
* @param addr The address of the multicast group to leave
* @param iface Address of the interface to use. If NULL is passed, the
* default multicast interface will be used. (OS Dependent)
* @param source Source Address to accept transmissions from (non-NULL
* implies Source-Specific Multicast)
*/
DoxyDefine(apr_status_t switch_mcast_leave(switch_socket_t *sock,
switch_sockaddr_t *addr,
switch_sockaddr_t *iface,
switch_sockaddr_t *source);)
#define switch_mcast_leave apr_mcast_leave
/**
* Set the Multicast Time to Live (ttl) for a multicast transmission.
* @param sock The socket to set the multicast ttl
* @param ttl Time to live to Assign. 0-255, default=1
* @remark If the TTL is 0, packets will only be seen by sockets on
* the local machine, and only when multicast loopback is enabled.
*/
DoxyDefine(apr_status_t switch_mcast_hops(switch_socket_t *sock,
apr_byte_t ttl);)
#define switch_mcast_hops apr_mcast_hops
/**
* Toggle IP Multicast Loopback
* @param sock The socket to set multicast loopback
* @param opt 0=disable, 1=enable
*/
DoxyDefine(apr_status_t switch_mcast_loopback(switch_socket_t *sock,
apr_byte_t opt);)
#define switch_mcast_loopback apr_mcast_loopback
/**
* Set the Interface to be used for outgoing Multicast Transmissions.
* @param sock The socket to set the multicast interface on
* @param iface Address of the interface to use for Multicast
*/
DoxyDefine(apr_status_t switch_mcast_interface(switch_socket_t *sock,
switch_sockaddr_t *iface);)
#define switch_mcast_interface apr_mcast_interface
/** @} */
/**
* @defgroup switch_memory_pool Memory Pool Functions
* @ingroup switch_apr
* @{
*/
/** The fundamental pool type */
typedef apr_pool_t switch_memory_pool;
/**
* Clear all memory in the pool and run all the cleanups. This also destroys all
* subpools.
* @param p The pool to clear
* @remark This does not actually free the memory, it just allows the pool
* to re-use this memory for the next allocation.
* @see apr_pool_destroy()
*/
DoxyDefine(void switch_pool_clear(switch_memory_pool *p);)
#define switch_pool_clear apr_pool_clear
/** @} */
/**
* @defgroup apr_poll Poll Routines
* @ingroup switch_apr
* @{
*/
/** Poll descriptor set. */
typedef apr_pollfd_t switch_pollfd_t;
/** Opaque structure used for pollset API */
typedef apr_pollset_t switch_pollset_t;
/**
* Poll options
*/
#define SWITCH_POLLIN APR_POLLIN /**< Can read without blocking */
#define SWITCH_POLLPRI APR_POLLPRI /**< Priority data available */
#define SWITCH_POLLOUT APR_POLLOUT /**< Can write without blocking */
#define SWITCH_POLLERR APR_POLLERR /**< Pending error */
#define SWITCH_POLLHUP APR_POLLHUP /**< Hangup occurred */
#define SWITCH_POLLNVAL APR_POLLNVAL /**< Descriptior invalid */
/**
* Setup a pollset object
* @param pollset The pointer in which to return the newly created object
* @param size The maximum number of descriptors that this pollset can hold
* @param p The pool from which to allocate the pollset
* @param flags Optional flags to modify the operation of the pollset.
*
* @remark If flags equals APR_POLLSET_THREADSAFE, then a pollset is
* created on which it is safe to make concurrent calls to
* apr_pollset_add(), apr_pollset_remove() and apr_pollset_poll() from
* separate threads. This feature is only supported on some
* platforms; the apr_pollset_create() call will fail with
* APR_ENOTIMPL on platforms where it is not supported.
*/
DoxyDefine(apr_status_t switch_pollset_create(switch_pollset_t **pollset,
apr_uint32_t size,
switch_memory_pool_t *p,
apr_uint32_t flags);)
#define switch_pollset_create apr_pollset_create
/**
* Add a socket or file descriptor to a pollset
* @param pollset The pollset to which to add the descriptor
* @param descriptor The descriptor to add
* @remark If you set client_data in the descriptor, that value
* will be returned in the client_data field whenever this
* descriptor is signalled in apr_pollset_poll().
* @remark If the pollset has been created with APR_POLLSET_THREADSAFE
* and thread T1 is blocked in a call to apr_pollset_poll() for
* this same pollset that is being modified via apr_pollset_add()
* in thread T2, the currently executing apr_pollset_poll() call in
* T1 will either: (1) automatically include the newly added descriptor
* in the set of descriptors it is watching or (2) return immediately
* with APR_EINTR. Option (1) is recommended, but option (2) is
* allowed for implementations where option (1) is impossible
* or impractical.
*/
DoxyDefine(apr_status_t switch_pollset_add(switch_pollset_t *pollset,
const switch_pollfd_t *descriptor);)
#define switch_pollset_add apr_pollset_add
/**
* Poll the sockets in the poll structure
* @param aprset The poll structure we will be using.
* @param numsock The number of sockets we are polling
* @param nsds The number of sockets signalled.
* @param timeout The amount of time in microseconds to wait. This is
* a maximum, not a minimum. If a socket is signalled, we
* will wake up before this time. A negative number means
* wait until a socket is signalled.
* @remark The number of sockets signalled is returned in the third argument.
* This is a blocking call, and it will not return until either a
* socket has been signalled, or the timeout has expired.
*/
DoxyDefine(apr_status_t switch_poll(switch_pollfd_t *aprset, apr_int32_t numsock,
apr_int32_t *nsds,
apr_interval_time_t timeout);)
#define switch_poll apr_poll
/** @} */
/**
* @defgroup switch_time Time Routines
* @ingroup switch_apr
* @{
*/
/** number of microseconds since 00:00:00 january 1, 1970 UTC */
typedef apr_time_t switch_time_t;
/**
* a structure similar to ANSI struct tm with the following differences:
* - tm_usec isn't an ANSI field
* - tm_gmtoff isn't an ANSI field (it's a bsdism)
*/
typedef apr_time_exp_t switch_time_exp_t;
/**
* @return the current time
*/
DoxyDefine(switch_time_t switch_time_now(void);)
#define switch_time_now apr_time_now
/**
* formats the exploded time according to the format specified
* @param s string to write to
* @param retsize The length of the returned string
* @param max The maximum length of the string
* @param format The format for the time string
* @param tm The time to convert
*/
DoxyDefine(apr_status_t switch_strftime(char *s, apr_size_t *retsize,
apr_size_t max, const char *format,
switch_time_exp_t *tm);)
#define switch_strftime apr_strftime
/**
* switch_rfc822_date formats dates in the RFC822
* format in an efficient manner. It is a fixed length
* format which requires the indicated amount of storage,
* including the trailing NUL terminator.
* @param date_str String to write to.
* @param t the time to convert
*/
DoxyDefine(apr_status_t switch_rfc822_date(char *date_str, switch_time_t t);)
#define switch_rfc822_date apr_rfc822_date
/**
* convert a time to its human readable components in GMT timezone
* @param result the exploded time
* @param input the time to explode
*/
DoxyDefine(apr_status_t switch_time_exp_gmt(switch_time_exp_t *result,
switch_time_t input);)
#define switch_time_exp_gmt apr_time_exp_gmt
/**
* Convert time value from human readable format to a numeric apr_time_t
* e.g. elapsed usec since epoch
* @param result the resulting imploded time
* @param input the input exploded time
*/
DoxyDefine(apr_status_t switch_time_exp_get(switch_time_t *result,
switch_time_exp_t *input);)
#define switch_time_exp_get apr_time_exp_get
/**
* convert a time to its human readable components in local timezone
* @param result the exploded time
* @param input the time to explode
*/
DoxyDefine(apr_status_t switch_time_exp_lt(switch_time_exp_t *result,
switch_time_t input);)
#define switch_time_exp_lt apr_time_exp_lt
/**
* Sleep for the specified number of micro-seconds.
* @param t desired amount of time to sleep.
* @warning May sleep for longer than the specified time.
*/
DoxyDefine(void switch_sleep(apr_interval_time_t t);)
#define switch_sleep apr_sleep
/** @} */
/**
* @defgroup apr_hash Hash Tables
* @ingroup switch_apr
* @{
*/
/** Abstract type for hash tables. */
typedef apr_hash_t switch_hash;
/** Abstract type for scanning hash tables. */
typedef apr_hash_index_t switch_hash_index_t;
/**
* Start iterating over the entries in a hash table.
* @param p The pool to allocate the switch_hash_index_t iterator. If this
* pool is NULL, then an internal, non-thread-safe iterator is used.
* @param ht The hash table
* @remark There is no restriction on adding or deleting hash entries during
* an iteration (although the results may be unpredictable unless all you do
* is delete the current entry) and multiple iterations can be in
* progress at the same time.
*/
DoxyDefine(switch_hash_index_t * switch_hash_first(switch_memory_pool_t *p, switch_hash_t *ht);)
#define switch_hash_first apr_hash_first
/**
* Continue iterating over the entries in a hash table.
* @param hi The iteration state
* @return a pointer to the updated iteration state. NULL if there are no more
* entries.
*/
DoxyDefine(switch_hash_index_t * switch_hash_next(switch_hash_index_t *hi);)
#define switch_hash_next apr_hash_next
/**
* Get the current entry's details from the iteration state.
* @param hi The iteration state
* @param key Return pointer for the pointer to the key.
* @param klen Return pointer for the key length.
* @param val Return pointer for the associated value.
* @remark The return pointers should point to a variable that will be set to the
* corresponding data, or they may be NULL if the data isn't interesting.
*/
DoxyDefine(void switch_hash_this(switch_hash_index_t *hi, const void **key,
apr_ssize_t *klen, void **val);)
#define switch_hash_this apr_hash_this
/** @} */
/**
* @defgroup switch_StrMatch String matching routines
* @ingroup switch_apr
* @{
*/
/** Precompiled search pattern */
typedef apr_strmatch_pattern switch_strmatch_pattern;
/**
* Precompile a pattern for matching using the Boyer-Moore-Horspool algorithm
* @param p The pool from which to allocate the pattern
* @param s The pattern string
* @param case_sensitive Whether the matching should be case-sensitive
* @return a pointer to the compiled pattern, or NULL if compilation fails
*/
DoxyDefine(const switch_strmatch_pattern * switch_strmatch_precompile(switch_memory_pool_t *p, const char *s, int case_sensitive);)
#define switch_strmatch_precompile apr_strmatch_precompile
/**
* Search for a precompiled pattern within a string
* @param pattern The pattern
* @param s The string in which to search for the pattern
* @param slen The length of s (excluding null terminator)
* @return A pointer to the first instance of the pattern in s, or
* NULL if not found
*/
DoxyDefine(const char * switch_strmatch(const switch_strmatch_pattern *pattern,
const char *s, apr_size_t slen);)
#define switch_strmatch apr_strmatch
/** @} */
/**
* @defgroup switch_UUID UUID Handling
* @ingroup switch_apr
* @{
*/
/** we represent a UUID as a block of 16 bytes. */
typedef apr_uuid_t switch_uuid_t;
/** UUIDs are formatted as: 00112233-4455-6677-8899-AABBCCDDEEFF */
/**
* Format a UUID into a string, following the standard format
* @param buffer The buffer to place the formatted UUID string into. It must
* be at least APR_UUID_FORMATTED_LENGTH + 1 bytes long to hold
* the formatted UUID and a null terminator
* @param uuid The UUID to format
*/
DoxyDefine(void switch_uuid_format(char *buffer, const switch_uuid_t *uuid);)
#define switch_uuid_format apr_uuid_format
/**
* Generate and return a (new) UUID
* @param uuid The resulting UUID
*/
DoxyDefine(void switch_uuid_get(switch_uuid_t *uuid);)
#define switch_uuid_get apr_uuid_get
/**
* Parse a standard-format string into a UUID
* @param uuid The resulting UUID
* @param uuid_str The formatted UUID
*/
DoxyDefine(apr_status_t switch_uuid_parse(switch_uuid_t *uuid, const char *uuid_str);)
#define switch_uuid_parse apr_uuid_parse
/** @} */
/**
* @defgroup switch_FIFO Thread Safe FIFO bounded queue
* @ingroup switch_apr
* @{
*/
/** Opaque structure used for queue API */
typedef apr_queue_t switch_queue_t;
/**
* create a FIFO queue
* @param queue The new queue
* @param queue_capacity maximum size of the queue
* @param a pool to allocate queue from
*/
DoxyDefine(apr_status_t switch_queue_create(switch_queue_t **queue,
unsigned int queue_capacity,
switch_memory_pool_t *a);)
#define switch_queue_create apr_queue_create
/**
* interrupt all the threads blocking on this queue.
*
* @param queue the queue
*/
DoxyDefine(apr_status_t switch_queue_interrupt_all(switch_queue_t *queue);)
#define switch_queue_interrupt_all apr_queue_interrupt_all
/**
* pop/get an object from the queue, blocking if the queue is already empty
*
* @param queue the queue
* @param data the data
* @returns APR_EINTR the blocking was interrupted (try again)
* @returns APR_EOF if the queue has been terminated
* @returns APR_SUCCESS on a successfull pop
*/
DoxyDefine(apr_status_t switch_queue_pop(switch_queue_t *queue, void **data);)
#define switch_queue_pop apr_queue_pop
/**
* push/add a object to the queue, blocking if the queue is already full
*
* @param queue the queue
* @param data the data
* @returns APR_EINTR the blocking was interrupted (try again)
* @returns APR_EOF the queue has been terminated
* @returns APR_SUCCESS on a successfull push
*/
DoxyDefine(apr_status_t switch_queue_push(switch_queue_t *queue, void *data);)
#define switch_queue_push apr_queue_push
/**
* returns the size of the queue.
*
* @warning this is not threadsafe, and is intended for reporting/monitoring
* of the queue.
* @param queue the queue
* @returns the size of the queue
*/
DoxyDefine(unsigned int switch_queue_size(switch_queue_t *queue);)
#define switch_queue_size apr_queue_size
/**
* terminate all queue, sendinging a interupt to all the
* blocking threads
*
* @param queue the queue
*/
DoxyDefine(apr_status_t switch_queue_term(switch_queue_t *queue);)
#define switch_queue_term apr_queue_term
/**
* pop/get an object to the queue, returning immediatly if the queue is empty
*
* @param queue the queue
* @param data the data
* @returns APR_EINTR the blocking operation was interrupted (try again)
* @returns APR_EAGAIN the queue is empty
* @returns APR_EOF the queue has been terminated
* @returns APR_SUCCESS on a successfull push
*/
DoxyDefine(apr_status_t switch_queue_trypop(switch_queue_t *queue, void **data);)
#define switch_queue_trypop apr_queue_trypop
/**
* push/add a object to the queue, returning immediatly if the queue is full
*
* @param queue the queue
* @param data the data
* @returns APR_EINTR the blocking operation was interrupted (try again)
* @returns APR_EAGAIN the queue is full
* @returns APR_EOF the queue has been terminated
* @returns APR_SUCCESS on a successfull push
*/
DoxyDefine(apr_status_t switch_queue_trypush(switch_queue_t *queue, void *data);)
#define switch_queue_trypush apr_queue_trypush
/**
* @defgroup switch_thread_mutex Thread Mutex Routines
* @ingroup switch_apr
* @{
*/
/** Opaque thread-local mutex structure */
typedef apr_thread_mutex_t switch_mutex_t;
/** Lock Flags */
#define SWITCH_MUTEX_DEFAULT APR_THREAD_MUTEX_DEFAULT /**< platform-optimal lock behavior */
#define SWITCH_MUTEX_NESTED APR_THREAD_MUTEX_NESTED /**< enable nested (recursive) locks */
#define SWITCH_MUTEX_UNNESTED APR_THREAD_MUTEX_UNNESTED /**< disable nested locks */
/**
* Create and initialize a mutex that can be used to synchronize threads.
* @param lock the memory address where the newly created mutex will be
* stored.
* @param flags Or'ed value of:
* <PRE>
* SWITCH_THREAD_MUTEX_DEFAULT platform-optimal lock behavior.
* SWITCH_THREAD_MUTEX_NESTED enable nested (recursive) locks.
* SWITCH_THREAD_MUTEX_UNNESTED disable nested locks (non-recursive).
* </PRE>
* @param pool the pool from which to allocate the mutex.
* @warning Be cautious in using SWITCH_THREAD_MUTEX_DEFAULT. While this is the
* most optimial mutex based on a given platform's performance charateristics,
* it will behave as either a nested or an unnested lock.
*
SWITCH_DECLARE(switch_status) switch_mutex_init(switch_mutex_t **lock,
switch_lock_flag flags,
switch_memory_pool *pool);
*/
#define switch_mutex_init apr_thread_mutex_create
/**
* Destroy the mutex and free the memory associated with the lock.
* @param lock the mutex to destroy.
*/
//SWITCH_DECLARE(switch_status) switch_mutex_destroy(switch_mutex_t *lock);
#define switch_mutex_destroy apr_thread_mutex_destroy
/**
* Acquire the lock for the given mutex. If the mutex is already locked,
* the current thread will be put to sleep until the lock becomes available.
* @param lock the mutex on which to acquire the lock.
*/
//SWITCH_DECLARE(switch_status) switch_mutex_lock(switch_mutex_t *lock);
#define switch_mutex_lock apr_thread_mutex_lock
/**
* Release the lock for the given mutex.
* @param lock the mutex from which to release the lock.
*/
//SWITCH_DECLARE(switch_status) switch_mutex_unlock(switch_mutex_t *lock);
#define switch_mutex_unlock apr_thread_mutex_unlock
/**
* Attempt to acquire the lock for the given mutex. If the mutex has already
* been acquired, the call returns immediately with APR_EBUSY. Note: it
* is important that the APR_STATUS_IS_EBUSY(s) macro be used to determine
* if the return value was APR_EBUSY, for portability reasons.
* @param lock the mutex on which to attempt the lock acquiring.
*/
//SWITCH_DECLARE(switch_status) switch_mutex_trylock(switch_mutex_t *lock);
#define switch_mutex_trylock apr_thread_mutex_trylock
/** @} */
/** @} */
#ifdef __cplusplus
}
#endif
#endif
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