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// This file was generated by gir (https://github.com/gtk-rs/gir) // from gir-files (https://github.com/gtk-rs/gir-files) // DO NOT EDIT use crate::MemoryMonitorWarningLevel; use glib::object::Cast; use glib::object::IsA; use glib::signal::connect_raw; use glib::signal::SignalHandlerId; use glib::translate::*; use std::boxed::Box as Box_; use std::fmt; use std::mem::transmute; glib::wrapper! { /// [`MemoryMonitor`][crate::MemoryMonitor] will monitor system memory and suggest to the application /// when to free memory so as to leave more room for other applications. /// It is implemented on Linux using the [Low Memory Monitor](https://gitlab.freedesktop.org/hadess/low-memory-monitor/) /// ([API documentation](https://hadess.pages.freedesktop.org/low-memory-monitor/)). /// /// There is also an implementation for use inside Flatpak sandboxes. /// /// Possible actions to take when the signal is received are: /// - Free caches /// - Save files that haven't been looked at in a while to disk, ready to be reopened when needed /// - Run a garbage collection cycle /// - Try and compress fragmented allocations /// - Exit on idle if the process has no reason to stay around /// - Call [`malloc_trim(3)`](man:malloc_trim) to return cached heap pages to /// the kernel (if supported by your libc) /// /// Note that some actions may not always improve system performance, and so /// should be profiled for your application. ``malloc_trim()``, for example, may /// make future heap allocations slower (due to releasing cached heap pages back /// to the kernel). /// /// See [`MemoryMonitorWarningLevel`][crate::MemoryMonitorWarningLevel] for details on the various warning levels. /// /// /// /// **⚠️ The following code is in C ⚠️** /// /// ```C /// static void /// warning_cb (GMemoryMonitor *m, GMemoryMonitorWarningLevel level) /// { /// g_debug ("Warning level: %d", level); /// if (warning_level > G_MEMORY_MONITOR_WARNING_LEVEL_LOW) /// drop_caches (); /// } /// /// static GMemoryMonitor * /// monitor_low_memory (void) /// { /// GMemoryMonitor *m; /// m = g_memory_monitor_dup_default (); /// g_signal_connect (G_OBJECT (m), "low-memory-warning", /// G_CALLBACK (warning_cb), NULL); /// return m; /// } /// ``` /// /// Don't forget to disconnect the `signal::MemoryMonitor::low-memory-warning` /// signal, and unref the [`MemoryMonitor`][crate::MemoryMonitor] itself when exiting. /// /// # Implements /// /// [`MemoryMonitorExt`][trait@crate::prelude::MemoryMonitorExt] #[doc(alias = "GMemoryMonitor")] pub struct MemoryMonitor(Interface<ffi::GMemoryMonitor, ffi::GMemoryMonitorInterface>); match fn { type_ => || ffi::g_memory_monitor_get_type(), } } impl MemoryMonitor { /// Gets a reference to the default [`MemoryMonitor`][crate::MemoryMonitor] for the system. /// /// # Returns /// /// a new reference to the default [`MemoryMonitor`][crate::MemoryMonitor] #[doc(alias = "g_memory_monitor_dup_default")] pub fn dup_default() -> MemoryMonitor { unsafe { from_glib_full(ffi::g_memory_monitor_dup_default()) } } } pub const NONE_MEMORY_MONITOR: Option<&MemoryMonitor> = None; /// Trait containing all [`struct@MemoryMonitor`] methods. /// /// # Implementors /// /// [`MemoryMonitor`][struct@crate::MemoryMonitor] pub trait MemoryMonitorExt: 'static { /// Emitted when the system is running low on free memory. The signal /// handler should then take the appropriate action depending on the /// warning level. See the [`MemoryMonitorWarningLevel`][crate::MemoryMonitorWarningLevel] documentation for /// details. /// ## `level` /// the [`MemoryMonitorWarningLevel`][crate::MemoryMonitorWarningLevel] warning level #[cfg(any(feature = "v2_64", feature = "dox"))] #[cfg_attr(feature = "dox", doc(cfg(feature = "v2_64")))] #[doc(alias = "low-memory-warning")] fn connect_low_memory_warning<F: Fn(&Self, MemoryMonitorWarningLevel) + 'static>( &self, f: F, ) -> SignalHandlerId; } impl<O: IsA<MemoryMonitor>> MemoryMonitorExt for O { #[cfg(any(feature = "v2_64", feature = "dox"))] #[cfg_attr(feature = "dox", doc(cfg(feature = "v2_64")))] fn connect_low_memory_warning<F: Fn(&Self, MemoryMonitorWarningLevel) + 'static>( &self, f: F, ) -> SignalHandlerId { unsafe extern "C" fn low_memory_warning_trampoline< P: IsA<MemoryMonitor>, F: Fn(&P, MemoryMonitorWarningLevel) + 'static, >( this: *mut ffi::GMemoryMonitor, level: ffi::GMemoryMonitorWarningLevel, f: glib::ffi::gpointer, ) { let f: &F = &*(f as *const F); f( MemoryMonitor::from_glib_borrow(this).unsafe_cast_ref(), from_glib(level), ) } unsafe { let f: Box_<F> = Box_::new(f); connect_raw( self.as_ptr() as *mut _, b"low-memory-warning\0".as_ptr() as *const _, Some(transmute::<_, unsafe extern "C" fn()>( low_memory_warning_trampoline::<Self, F> as *const (), )), Box_::into_raw(f), ) } } } impl fmt::Display for MemoryMonitor { fn fmt(&self, f: &mut fmt::Formatter) -> fmt::Result { f.write_str("MemoryMonitor") } }