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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) // from gst-gir-files (https://gitlab.freedesktop.org/gstreamer/gir-files-rs.git) // DO NOT EDIT use glib::translate::*; use glib::ObjectExt; use std::mem; glib::wrapper! { /// This class is for elements that receive buffers in an undesired size. /// While for example raw video contains one image per buffer, the same is not /// true for a lot of other formats, especially those that come directly from /// a file. So if you have undefined buffer sizes and require a specific size, /// this object is for you. /// /// An adapter is created with [`new()`][Self::new()]. It can be freed again with /// `g_object_unref()`. /// /// The theory of operation is like this: All buffers received are put /// into the adapter using [`push()`][Self::push()] and the data is then read back /// in chunks of the desired size using `gst_adapter_map()`/`gst_adapter_unmap()` /// and/or `gst_adapter_copy()`. After the data has been processed, it is freed /// using `gst_adapter_unmap()`. /// /// Other methods such as `gst_adapter_take()` and `gst_adapter_take_buffer()` /// combine `gst_adapter_map()` and `gst_adapter_unmap()` in one method and are /// potentially more convenient for some use cases. /// /// For example, a sink pad's chain function that needs to pass data to a library /// in 512-byte chunks could be implemented like this: /// /// ```C /// static GstFlowReturn /// sink_pad_chain (GstPad *pad, GstObject *parent, GstBuffer *buffer) /// { /// MyElement *this; /// GstAdapter *adapter; /// GstFlowReturn ret = GST_FLOW_OK; /// /// this = MY_ELEMENT (parent); /// /// adapter = this->adapter; /// /// // put buffer into adapter /// gst_adapter_push (adapter, buffer); /// /// // while we can read out 512 bytes, process them /// while (gst_adapter_available (adapter) >= 512 && ret == GST_FLOW_OK) { /// const guint8 *data = gst_adapter_map (adapter, 512); /// // use flowreturn as an error value /// ret = my_library_foo (data); /// gst_adapter_unmap (adapter); /// gst_adapter_flush (adapter, 512); /// } /// return ret; /// } /// ``` /// /// For another example, a simple element inside GStreamer that uses [`Adapter`][crate::Adapter] /// is the libvisual element. /// /// An element using [`Adapter`][crate::Adapter] in its sink pad chain function should ensure that /// when the FLUSH_STOP event is received, that any queued data is cleared using /// [`clear()`][Self::clear()]. Data should also be cleared or processed on EOS and /// when changing state from [`gst::State::Paused`][crate::gst::State::Paused] to [`gst::State::Ready`][crate::gst::State::Ready]. /// /// Also check the GST_BUFFER_FLAG_DISCONT flag on the buffer. Some elements might /// need to clear the adapter after a discontinuity. /// /// The adapter will keep track of the timestamps of the buffers /// that were pushed. The last seen timestamp before the current position /// can be queried with [`prev_pts()`][Self::prev_pts()]. This function can /// optionally return the number of bytes between the start of the buffer that /// carried the timestamp and the current adapter position. The distance is /// useful when dealing with, for example, raw audio samples because it allows /// you to calculate the timestamp of the current adapter position by using the /// last seen timestamp and the amount of bytes since. Additionally, the /// [`prev_pts_at_offset()`][Self::prev_pts_at_offset()] can be used to determine the last /// seen timestamp at a particular offset in the adapter. /// /// The adapter will also keep track of the offset of the buffers /// (`GST_BUFFER_OFFSET`) that were pushed. The last seen offset before the /// current position can be queried with [`prev_offset()`][Self::prev_offset()]. This function /// can optionally return the number of bytes between the start of the buffer /// that carried the offset and the current adapter position. /// /// Additionally the adapter also keeps track of the PTS, DTS and buffer offset /// at the last discontinuity, which can be retrieved with /// [`pts_at_discont()`][Self::pts_at_discont()], [`dts_at_discont()`][Self::dts_at_discont()] and /// [`offset_at_discont()`][Self::offset_at_discont()]. The number of bytes that were consumed /// since then can be queried with [`distance_from_discont()`][Self::distance_from_discont()]. /// /// A last thing to note is that while [`Adapter`][crate::Adapter] is pretty optimized, /// merging buffers still might be an operation that requires a ``malloc()`` and /// ``memcpy()`` operation, and these operations are not the fastest. Because of /// this, some functions like [`available_fast()`][Self::available_fast()] are provided to help /// speed up such cases should you want to. To avoid repeated memory allocations, /// `gst_adapter_copy()` can be used to copy data into a (statically allocated) /// user provided buffer. /// /// [`Adapter`][crate::Adapter] is not MT safe. All operations on an adapter must be serialized by /// the caller. This is not normally a problem, however, as the normal use case /// of [`Adapter`][crate::Adapter] is inside one pad's chain function, in which case access is /// serialized via the pad's STREAM_LOCK. /// /// Note that [`push()`][Self::push()] takes ownership of the buffer passed. Use /// `gst_buffer_ref()` before pushing it into the adapter if you still want to /// access the buffer later. The adapter will never modify the data in the /// buffer pushed in it. /// /// # Implements /// /// [`trait@glib::ObjectExt`] #[doc(alias = "GstAdapter")] pub struct Adapter(Object<ffi::GstAdapter, ffi::GstAdapterClass>); match fn { type_ => || ffi::gst_adapter_get_type(), } } impl Adapter { /// Creates a new [`Adapter`][crate::Adapter]. Free with `g_object_unref()`. /// /// # Returns /// /// a new [`Adapter`][crate::Adapter] #[doc(alias = "gst_adapter_new")] pub fn new() -> Adapter { assert_initialized_main_thread!(); unsafe { from_glib_full(ffi::gst_adapter_new()) } } /// Gets the maximum amount of bytes available, that is it returns the maximum /// value that can be supplied to `gst_adapter_map()` without that function /// returning [`None`]. /// /// # Returns /// /// number of bytes available in `self` #[doc(alias = "gst_adapter_available")] pub fn available(&self) -> usize { unsafe { ffi::gst_adapter_available(self.to_glib_none().0) } } /// Gets the maximum number of bytes that are immediately available without /// requiring any expensive operations (like copying the data into a /// temporary buffer). /// /// # Returns /// /// number of bytes that are available in `self` without expensive /// operations #[doc(alias = "gst_adapter_available_fast")] pub fn available_fast(&self) -> usize { unsafe { ffi::gst_adapter_available_fast(self.to_glib_none().0) } } /// Removes all buffers from `self`. #[doc(alias = "gst_adapter_clear")] pub fn clear(&self) { unsafe { ffi::gst_adapter_clear(self.to_glib_none().0); } } /// Get the distance in bytes since the last buffer with the /// [`gst::BufferFlags::DISCONT`][crate::gst::BufferFlags::DISCONT] flag. /// /// The distance will be reset to 0 for all buffers with /// [`gst::BufferFlags::DISCONT`][crate::gst::BufferFlags::DISCONT] on them, and then calculated for all other /// following buffers based on their size. /// /// # Returns /// /// The offset. Can be `GST_BUFFER_OFFSET_NONE`. #[cfg(any(feature = "v1_10", feature = "dox"))] #[cfg_attr(feature = "dox", doc(cfg(feature = "v1_10")))] #[doc(alias = "gst_adapter_distance_from_discont")] pub fn distance_from_discont(&self) -> u64 { unsafe { ffi::gst_adapter_distance_from_discont(self.to_glib_none().0) } } /// Get the DTS that was on the last buffer with the GST_BUFFER_FLAG_DISCONT /// flag, or GST_CLOCK_TIME_NONE. /// /// # Returns /// /// The DTS at the last discont or GST_CLOCK_TIME_NONE. #[cfg(any(feature = "v1_10", feature = "dox"))] #[cfg_attr(feature = "dox", doc(cfg(feature = "v1_10")))] #[doc(alias = "gst_adapter_dts_at_discont")] pub fn dts_at_discont(&self) -> Option<gst::ClockTime> { unsafe { from_glib(ffi::gst_adapter_dts_at_discont(self.to_glib_none().0)) } } /// Get the offset that was on the last buffer with the GST_BUFFER_FLAG_DISCONT /// flag, or GST_BUFFER_OFFSET_NONE. /// /// # Returns /// /// The offset at the last discont or GST_BUFFER_OFFSET_NONE. #[cfg(any(feature = "v1_10", feature = "dox"))] #[cfg_attr(feature = "dox", doc(cfg(feature = "v1_10")))] #[doc(alias = "gst_adapter_offset_at_discont")] pub fn offset_at_discont(&self) -> u64 { unsafe { ffi::gst_adapter_offset_at_discont(self.to_glib_none().0) } } /// Get the dts that was before the current byte in the adapter. When /// `distance` is given, the amount of bytes between the dts and the current /// position is returned. /// /// The dts is reset to GST_CLOCK_TIME_NONE and the distance is set to 0 when /// the adapter is first created or when it is cleared. This also means that before /// the first byte with a dts is removed from the adapter, the dts /// and distance returned are GST_CLOCK_TIME_NONE and 0 respectively. /// /// # Returns /// /// The previously seen dts. /// /// ## `distance` /// pointer to location for distance, or [`None`] #[doc(alias = "gst_adapter_prev_dts")] pub fn prev_dts(&self) -> (Option<gst::ClockTime>, u64) { unsafe { let mut distance = mem::MaybeUninit::uninit(); let ret = from_glib(ffi::gst_adapter_prev_dts( self.to_glib_none().0, distance.as_mut_ptr(), )); let distance = distance.assume_init(); (ret, distance) } } /// Get the dts that was before the byte at offset `offset` in the adapter. When /// `distance` is given, the amount of bytes between the dts and the current /// position is returned. /// /// The dts is reset to GST_CLOCK_TIME_NONE and the distance is set to 0 when /// the adapter is first created or when it is cleared. This also means that before /// the first byte with a dts is removed from the adapter, the dts /// and distance returned are GST_CLOCK_TIME_NONE and 0 respectively. /// ## `offset` /// the offset in the adapter at which to get timestamp /// /// # Returns /// /// The previously seen dts at given offset. /// /// ## `distance` /// pointer to location for distance, or [`None`] #[doc(alias = "gst_adapter_prev_dts_at_offset")] pub fn prev_dts_at_offset(&self, offset: usize) -> (Option<gst::ClockTime>, u64) { unsafe { let mut distance = mem::MaybeUninit::uninit(); let ret = from_glib(ffi::gst_adapter_prev_dts_at_offset( self.to_glib_none().0, offset, distance.as_mut_ptr(), )); let distance = distance.assume_init(); (ret, distance) } } /// Get the offset that was before the current byte in the adapter. When /// `distance` is given, the amount of bytes between the offset and the current /// position is returned. /// /// The offset is reset to GST_BUFFER_OFFSET_NONE and the distance is set to 0 /// when the adapter is first created or when it is cleared. This also means that /// before the first byte with an offset is removed from the adapter, the offset /// and distance returned are GST_BUFFER_OFFSET_NONE and 0 respectively. /// /// # Returns /// /// The previous seen offset. /// /// ## `distance` /// pointer to a location for distance, or [`None`] #[cfg(any(feature = "v1_10", feature = "dox"))] #[cfg_attr(feature = "dox", doc(cfg(feature = "v1_10")))] #[doc(alias = "gst_adapter_prev_offset")] pub fn prev_offset(&self) -> (u64, u64) { unsafe { let mut distance = mem::MaybeUninit::uninit(); let ret = ffi::gst_adapter_prev_offset(self.to_glib_none().0, distance.as_mut_ptr()); let distance = distance.assume_init(); (ret, distance) } } /// Get the pts that was before the current byte in the adapter. When /// `distance` is given, the amount of bytes between the pts and the current /// position is returned. /// /// The pts is reset to GST_CLOCK_TIME_NONE and the distance is set to 0 when /// the adapter is first created or when it is cleared. This also means that before /// the first byte with a pts is removed from the adapter, the pts /// and distance returned are GST_CLOCK_TIME_NONE and 0 respectively. /// /// # Returns /// /// The previously seen pts. /// /// ## `distance` /// pointer to location for distance, or [`None`] #[doc(alias = "gst_adapter_prev_pts")] pub fn prev_pts(&self) -> (Option<gst::ClockTime>, u64) { unsafe { let mut distance = mem::MaybeUninit::uninit(); let ret = from_glib(ffi::gst_adapter_prev_pts( self.to_glib_none().0, distance.as_mut_ptr(), )); let distance = distance.assume_init(); (ret, distance) } } /// Get the pts that was before the byte at offset `offset` in the adapter. When /// `distance` is given, the amount of bytes between the pts and the current /// position is returned. /// /// The pts is reset to GST_CLOCK_TIME_NONE and the distance is set to 0 when /// the adapter is first created or when it is cleared. This also means that before /// the first byte with a pts is removed from the adapter, the pts /// and distance returned are GST_CLOCK_TIME_NONE and 0 respectively. /// ## `offset` /// the offset in the adapter at which to get timestamp /// /// # Returns /// /// The previously seen pts at given offset. /// /// ## `distance` /// pointer to location for distance, or [`None`] #[doc(alias = "gst_adapter_prev_pts_at_offset")] pub fn prev_pts_at_offset(&self, offset: usize) -> (Option<gst::ClockTime>, u64) { unsafe { let mut distance = mem::MaybeUninit::uninit(); let ret = from_glib(ffi::gst_adapter_prev_pts_at_offset( self.to_glib_none().0, offset, distance.as_mut_ptr(), )); let distance = distance.assume_init(); (ret, distance) } } /// Get the PTS that was on the last buffer with the GST_BUFFER_FLAG_DISCONT /// flag, or GST_CLOCK_TIME_NONE. /// /// # Returns /// /// The PTS at the last discont or GST_CLOCK_TIME_NONE. #[cfg(any(feature = "v1_10", feature = "dox"))] #[cfg_attr(feature = "dox", doc(cfg(feature = "v1_10")))] #[doc(alias = "gst_adapter_pts_at_discont")] pub fn pts_at_discont(&self) -> Option<gst::ClockTime> { unsafe { from_glib(ffi::gst_adapter_pts_at_discont(self.to_glib_none().0)) } } } impl Default for Adapter { fn default() -> Self { Self::new() } } unsafe impl glib::SendUnique for Adapter { fn is_unique(&self) -> bool { self.ref_count() == 1 } }