GIO OverviewIntroduction
GIO is striving to provide a modern, easy-to-use VFS API that sits
at the right level in the library stack, as well as other generally
useful APIs for desktop applications (such as networking and
D-Bus support). The goal is to overcome the shortcomings of GnomeVFS
and provide an API that is so good that developers prefer it over raw
POSIX calls. Among other things that means using GObject. It also means
not cloning the POSIX API, but providing higher-level, document-centric
interfaces.
The abstract file system model of GIO consists of a number of
interfaces and base classes for I/O and files:
GFilereference to a fileGFileInfoinformation about a file or filesystemGFileEnumeratorlist files in directoriesGDriverepresents a driveGVolumerepresents a file system in an abstract wayGMountrepresents a mounted file system
Then there is a number of stream classes, similar to the input and
output stream hierarchies that can be found in frameworks like Java:
GInputStreamread dataGOutputStreamwrite dataGIOStreamread and write dataGSeekableinterface optionally implemented by streams to support seeking
There are interfaces related to applications and the types
of files they handle:
GAppInfoinformation about an installed applicationGIconabstract type for file and application icons
There is a framework for storing and retrieving application settings:
GSettingsstores and retrieves application settings
There is support for network programming, including connectivity monitoring,
name resolution, lowlevel socket APIs and highlevel client and server
helper classes:
GSocketlowlevel platform independent socket objectGResolverasynchronous and cancellable DNS resolverGSocketClienthigh-level network client helperGSocketServicehigh-level network server helperGSocketConnectionnetwork connection streamGNetworkMonitornetwork connectivity monitoring
There is support for connecting to D-Bus,
sending and receiving messages, owning and watching bus names,
and making objects available on the bus:
GDBusConnectiona D-Bus connectionGDBusMethodInvocationfor handling remote callsGDBusServerhelper for accepting connectionsGDBusProxyproxy to access D-Bus interfaces on a remote object
Beyond these, GIO provides facilities for file monitoring,
asynchronous I/O and filename completion. In addition to the
interfaces, GIO provides implementations for the local case.
Implementations for various network file systems are provided
by the GVFS package as loadable modules.
Other design choices which consciously break with the GnomeVFS
design are to move backends out-of-process, which minimizes the
dependency bloat and makes the whole system more robust. The backends
are not included in GIO, but in the separate GVFS package. The GVFS
package also contains the GVFS daemon, which spawn further mount
daemons for each individual connection.
The GIO model of I/O is stateful: if an application establishes e.g.
a SFTP connection to a server, it becomes available to all applications
in the session; the user does not have to enter his password over
and over again.
One of the big advantages of putting the VFS in the GLib layer
is that GTK+ can directly use it, e.g. in the filechooser.
Writing GIO applications
The information in the GLib documentation about writing GLib
applications is generally applicable when writing GIO applications.
Threads
GDBus has its own private worker thread, so applications using
GDBus have at least 3 threads. GIO makes heavy use of the concept
of a thread-default
main context to execute callbacks of asynchronous
methods in the same context in which the operation was started.
Asynchronous Programming
Many GIO functions come in two versions: synchronous and asynchronous,
denoted by an _async suffix. It is important to use these
appropriately: synchronous calls should not be used from
within a main loop which is shared with other code, such as one in the
application’s main thread. Synchronous calls block until they complete,
and I/O operations can take noticeable amounts of time (even on ‘fast’
SSDs). Blocking a main loop iteration while waiting for I/O means that
other sources in the main loop will not be dispatched, such as input and
redraw handlers for the application’s UI. This can cause the application
to ‘freeze’ until I/O completes.
A few self-contained groups of functions, such as code generated by
gdbus-codegen,
use a different convention: functions are asynchronous default, and it is
the synchronous version which has a
_sync
suffix. Aside from naming differences, they should be treated the same
way as functions following the normal convention above.
The asynchronous (_async) versions of functions return
control to the caller immediately, after scheduling the I/O in the kernel
and adding a callback for it to the main loop. This callback will be
invoked when the operation has completed. From the callback, the paired
_finish function should be called to retrieve the return
value of the I/O operation, and any errors which occurred. For more
information on using and implementing asynchronous functions, see
GAsyncResult
and GTask.
By starting multiple asynchronous operations in succession, they will be
executed in parallel (up to an arbitrary limit imposed by GIO’s internal
worker thread pool).
The synchronous versions of functions can be used early in application
startup when there is no main loop to block, for example to load initial
configuration files. They can also be used for I/O on files which are
guaranteed to be small and on the local disk. Note that the user’s home
directory is not guaranteed to be on the local disk.
Security
When your program needs to carry out some privileged operation (say,
create a new user account), there are various ways in which you can go
about this:
Implement a daemon that offers the privileged operation. A convenient
way to do this is as a D-Bus system-bus service. The daemon will probably
need ways to check the identity and authorization of the caller before
executing the operation. polkit is a framework that allows this.
Use a small helper that is executed with elevated privileges via
pkexec. pkexec is a small program launcher that is part of polkit.
Use a small helper that is executed with elevated privileges by
being suid root.
None of these approaches is the clear winner, they all have their
advantages and disadvantages.
When writing code that runs with elevated privileges, it is important
to follow some basic rules of secure programming. David Wheeler has an
excellent book on this topic,
Secure Programming for Linux and Unix HOWTO.
When using GIO in code that runs with elevated privileges, you have to
be careful. GIO has extension points whose implementations get loaded
from modules (executable code in shared objects), which could allow
an attacker to sneak his own code into your application by tricking it
into loading the code as a module. However, GIO will never load modules
from your home directory except when explicitly asked to do so via an
environment variable.
In most cases, your helper program should be so small that you don't
need GIO, whose APIs are largely designed to support full-blown desktop
applications. If you can't resist the convenience of these APIs, here
are some steps you should take:
Clear the environment, e.g. using the clearenv()
function.
David Wheeler has a good explanation for why it is
important to sanitize the environment.
See
for a list of all environment variables affecting GIO. In particular,
PATH (used to locate binaries), GIO_EXTRA_MODULES (used to locate loadable modules) and DBUS_{SYSTEM,SESSION}_BUS_ADDRESS (used to locate the D-Bus system and session bus) are important.
Don't use GVfs, by setting GIO_USE_VFS=local in the environment.
The reason to avoid GVfs in security-sensitive programs is that it uses
many libraries which have not necessarily been audited for security problems.
Gvfs is also heavily distributed and relies on a session bus to be present.
Compiling GIO applications
GIO comes with a gio-2.0.pc file that you
should use together with pkg-config to obtain
the necessary information about header files and libraries. See
the pkg-config man page or the GLib documentation
for more information on how to use pkg-config
to compile your application.
If you are using GIO on UNIX-like systems, you may want to use
UNIX-specific GIO interfaces such as #GUnixInputStream,
#GUnixOutputStream, #GUnixMount or #GDesktopAppInfo.
To do so, use the gio-unix-2.0.pc file
instead of gio-2.0.pcRunning GIO applications
GIO inspects a few environment variables in addition to the
ones used by GLib.
XDG_DATA_HOME, XDG_DATA_DIRS
GIO uses these environment variables to locate MIME information.
For more information, see the Shared MIME-info Database
and the Base Directory Specification.
GVFS_DISABLE_FUSE
This variable can be set to keep #Gvfs from starting the fuse backend,
which may be unwanted or unnecessary in certain situations.
GIO_USE_VFS
This environment variable can be set to the name of a #GVfs
implementation to override the default for debugging purposes.
The #GVfs implementation for local files that is included in GIO
has the name "local", the implementation in the gvfs module has
the name "gvfs". Most commonly, system software will set this to "local"
to avoid having `GFile` APIs perform unnecessary DBus calls.
The special value help can be used to print a list of
available implementations to standard output.
The following environment variables are only useful for debugging
GIO itself or modules that it loads. They should not be set in a
production environment.
GIO_USE_FILE_MONITOR
This variable can be set to the name of a #GFileMonitor
implementation to override the default for debugging purposes.
The #GFileMonitor implementation for local files that is included
in GIO on Linux has the name "inotify", others that are built
are built as modules (depending on the platform) are called
"fam" and "fen".
The special value help can be used to print a list of
available implementations to standard output.
GIO_USE_VOLUME_MONITOR
This variable can be set to the name of a #GVolumeMonitor
implementation to override the default for debugging purposes.
The #GVolumeMonitor implementation for local files that is included
in GIO has the name "unix", the udisks2-based implementation in the
gvfs module has the name "udisks2".
The special value help can be used to print a list of
available implementations to standard output.
GIO_USE_TLS
This variable can be set to the name of a #GTlsBackend
implementation to override the default for debugging purposes.
GIO does not include a #GTlsBackend implementation, the gnutls-based
implementation in the glib-networking module has the name "gnutls".
The special value help can be used to print a list of
available implementations to standard output.
GIO_MODULE_DIR
When this environment variable is set to a path, GIO will load
modules from this alternate directory instead of the directory
built into GIO. This is useful when running tests, for example.
GIO_EXTRA_MODULES
When this environment variable is set to a path, or a set of
paths separated by a colon, GIO will attempt to load
additional modules from within the path.
GSETTINGS_BACKEND
This variable can be set to the name of a #GSettingsBackend
implementation to override the default for debugging purposes.
The memory-based implementation that is included in GIO has
the name "memory", the one in dconf has the name "dconf".
The special value help can be used to print a list of
available implementations to standard output.
GSETTINGS_SCHEMA_DIR
This variable can be set to the names of directories to consider when looking for compiled schemas for #GSettings,
in addition to the glib-2.0/schemas
subdirectories of the XDG system data dirs. To specify multiple directories, use G_SEARCHPATH_SEPARATOR_S as a separator.
DBUS_SYSTEM_BUS_ADDRESS
This variable is consulted to find the address of the D-Bus system
bus. For the format of D-Bus addresses, see the D-Bus
specification.
Setting this variable overrides platform-specific ways of determining
the system bus address.
DBUS_SESSION_BUS_ADDRESS
This variable is consulted to find the address of the D-Bus session bus.
Setting this variable overrides platform-specific ways of determining
the session bus address.
DBUS_STARTER_BUS_TYPE
This variable is consulted to find out the 'starter' bus for an
application that has been started via D-Bus activation. The possible
values are 'system' or 'session'.
G_DBUS_DEBUG
This variable can be set to a list of debug options, which
cause GLib to print out different types of debugging
information when using the D-Bus routines.
transportShow IO activity (e.g. reads and writes)messageShow all sent and received D-Bus messagespayloadShow payload for all sent and received D-Bus messages (implies message)callTrace g_dbus_connection_call() and g_dbus_connection_call_sync() API usagesignalShow when a D-Bus signal is receivedincomingShow when an incoming D-Bus method call is receivedreturnShow when a reply is returned via the #GDBusMethodInvocation APIemissionTrace g_dbus_connection_emit_signal() API usageauthenticationShow information about connection authenticationaddressShow information about D-Bus address lookups and autolaunching
The special value all can be used to turn
on all debug options. The special value
help can be used to print a list of
supported options to standard output.
G_DBUS_COOKIE_SHA1_KEYRING_DIR
Can be used to override the directory used to store the
keyring used in the DBUS_COOKIE_SHA1
authentication mechanism. Normally the directory used is
.dbus-keyrings in the user's home
directory.
G_DBUS_COOKIE_SHA1_KEYRING_DIR_IGNORE_PERMISSION
If set, the permissions of the directory used to store the
keyring used in the DBUS_COOKIE_SHA1
authentication mechanism won't be checked. Normally the
directory must be readable only by the user.
Extending GIO
A lot of the functionality that is accessible through GIO
is implemented in loadable modules, and modules provide a convenient
way to extend GIO. In addition to the #GIOModule API which supports
writing such modules, GIO has a mechanism to define extension points,
and register implementations thereof, see #GIOExtensionPoint.
The following extension points are currently defined by GIO:
G_VFS_EXTENSION_POINT_NAME
Allows to override the functionality of the #GVfs class.
Implementations of this extension point must be derived from #GVfs.
GIO uses the implementation with the highest priority that is active,
see g_vfs_is_active().
GIO implements this extension point for local files, gvfs contains
an implementation that supports all the backends in gvfs.
G_VOLUME_MONITOR_EXTENSION_POINT_NAME
Allows to add more volume monitors.
Implementations of this extension point must be derived from
#GVolumeMonitor. GIO uses all registered extensions.
gvfs contains an implementation that works together with the #GVfs
implementation in gvfs.
G_NATIVE_VOLUME_MONITOR_EXTENSION_POINT_NAME
Allows to override the 'native' volume monitor.
Implementations of this extension point must be derived from
#GNativeVolumeMonitor. GIO uses the implementation with
the highest priority that is supported, as determined by the
is_supported() vfunc in #GVolumeMonitorClass.
GIO implements this extension point for local mounts,
gvfs contains a udisks2-based implementation.
G_LOCAL_FILE_MONITOR_EXTENSION_POINT_NAME
Allows to override the file monitor implementation for
local files. Implementations of this extension point must
be derived from #GLocalFileMonitor. GIO uses the implementation
with the highest priority that is supported, as determined by the
is_supported() vfunc in #GLocalFileMonitorClass.
GIO uses this extension point internally, to switch between
its fam-based and inotify-based file monitoring implementations.
G_LOCAL_DIRECTORY_MONITOR_EXTENSION_POINT_NAME
Allows to override the directory monitor implementation for
local files. Implementations of this extension point must be
derived from #GLocalDirectoryMonitor. GIO uses the implementation
with the highest priority that is supported, as determined by the
is_supported() vfunc in #GLocalDirectoryMonitorClass.
GIO uses this extension point internally, to switch between
its fam-based and inotify-based directory monitoring implementations.
G_DESKTOP_APP_INFO_LOOKUP_EXTENSION_POINT_NAME
Unix-only. Allows to provide a way to associate default handlers
with URI schemes. Implementations of this extension point must
implement the #GDesktopAppInfoLookup interface. GIO uses the
implementation with the highest priority.
This extension point has been discontinued in GLib 2.28. It is
still available to keep API and ABI stability, but GIO is no
longer using it for default handlers. Instead, the mime handler
mechanism is used, together with x-scheme-handler pseudo-mimetypes.
G_SETTINGS_BACKEND_EXTENSION_POINT_NAME
Allows to provide an alternative storage for #GSettings.
Implementations of this extension point must derive from the
#GSettingsBackend type. GIO contains a keyfile-based
implementation of this extension point, another one is provided
by dconf.
G_PROXY_EXTENSION_POINT_NAME
Allows to provide implementations for network proxying.
Implementations of this extension point must provide the
#GProxy interface, and must be named after the network
protocol they are proxying.
glib-networking contains an implementation of this extension
point based on libproxy.
G_TLS_BACKEND_EXTENSION_POINT_NAME
Allows to provide implementations for TLS support.
Implementations of this extension point must implement
the #GTlsBackend interface.
glib-networking contains an implementation of this extension
point.
G_NETWORK_MONITOR_EXTENSION_POINT_NAME
Allows to provide implementations for network connectivity
monitoring.
Implementations of this extension point must implement
the #GNetworkMonitorInterface interface.
GIO contains an implementation of this extension point
that is using the netlink interface of the Linux kernel.