Copyright	Will Thompson Iñaki García Etxebarria and Jonas Platte
License	LGPL-2.1
Maintainer	Iñaki García Etxebarria (inaki@blueleaf.cc)
Safe Haskell	None
Language	Haskell2010

GI.Gst.Objects.Pipeline

Contents

Exported types
Methods
Properties

Description

A Pipeline is a special Bin used as the toplevel container for the filter graph. The Pipeline will manage the selection and distribution of a global Clock as well as provide a Bus to the application.

pipelineNew is used to create a pipeline. when you are done with the pipeline, use objectUnref to free its resources including all added Element objects (if not otherwise referenced).

Elements are added and removed from the pipeline using the Bin methods like binAdd and binRemove (see Bin).

Before changing the state of the Pipeline (see Element) a Bus can be retrieved with pipelineGetBus. This bus can then be used to receive Message from the elements in the pipeline.

By default, a Pipeline will automatically flush the pending Bus messages when going to the NULL state to ensure that no circular references exist when no messages are read from the Bus. This behaviour can be changed with pipelineSetAutoFlushBus.

When the Pipeline performs the PAUSED to PLAYING state change it will select a clock for the elements. The clock selection algorithm will by default select a clock provided by an element that is most upstream (closest to the source). For live pipelines (ones that return GST_STATE_CHANGE_NO_PREROLL from the elementSetState call) this will select the clock provided by the live source. For normal pipelines this will select a clock provided by the sinks (most likely the audio sink). If no element provides a clock, a default SystemClock is used.

The clock selection can be controlled with the pipelineUseClock method, which will enforce a given clock on the pipeline. With pipelineAutoClock the default clock selection algorithm can be restored.

A Pipeline maintains a running time for the elements. The running time is defined as the difference between the current clock time and the base time. When the pipeline goes to READY or a flushing seek is performed on it, the running time is reset to 0. When the pipeline is set from PLAYING to PAUSED, the current clock time is sampled and used to configure the base time for the elements when the pipeline is set to PLAYING again. The effect is that the running time (as the difference between the clock time and the base time) will count how much time was spent in the PLAYING state. This default behaviour can be changed with the elementSetStartTime method.

Synopsis

newtype Pipeline = Pipeline (ManagedPtr Pipeline)
class (GObject o, IsDescendantOf Pipeline o) => IsPipeline o
toPipeline :: (MonadIO m, IsPipeline o) => o -> m Pipeline
noPipeline :: Maybe Pipeline
pipelineAutoClock :: (HasCallStack, MonadIO m, IsPipeline a) => a -> m ()
pipelineGetAutoFlushBus :: (HasCallStack, MonadIO m, IsPipeline a) => a -> m Bool
pipelineGetBus :: (HasCallStack, MonadIO m, IsPipeline a) => a -> m Bus
pipelineGetDelay :: (HasCallStack, MonadIO m, IsPipeline a) => a -> m Word64
pipelineGetLatency :: (HasCallStack, MonadIO m, IsPipeline a) => a -> m Word64
pipelineGetPipelineClock :: (HasCallStack, MonadIO m, IsPipeline a) => a -> m Clock
pipelineNew :: (HasCallStack, MonadIO m) => Maybe Text -> m Pipeline
pipelineSetAutoFlushBus :: (HasCallStack, MonadIO m, IsPipeline a) => a -> Bool -> m ()
pipelineSetDelay :: (HasCallStack, MonadIO m, IsPipeline a) => a -> Word64 -> m ()
pipelineSetLatency :: (HasCallStack, MonadIO m, IsPipeline a) => a -> Word64 -> m ()
pipelineUseClock :: (HasCallStack, MonadIO m, IsPipeline a, IsClock b) => a -> Maybe b -> m ()
constructPipelineAutoFlushBus :: IsPipeline o => Bool -> IO (GValueConstruct o)
getPipelineAutoFlushBus :: (MonadIO m, IsPipeline o) => o -> m Bool
setPipelineAutoFlushBus :: (MonadIO m, IsPipeline o) => o -> Bool -> m ()
constructPipelineDelay :: IsPipeline o => Word64 -> IO (GValueConstruct o)
getPipelineDelay :: (MonadIO m, IsPipeline o) => o -> m Word64
setPipelineDelay :: (MonadIO m, IsPipeline o) => o -> Word64 -> m ()
constructPipelineLatency :: IsPipeline o => Word64 -> IO (GValueConstruct o)
getPipelineLatency :: (MonadIO m, IsPipeline o) => o -> m Word64
setPipelineLatency :: (MonadIO m, IsPipeline o) => o -> Word64 -> m ()

Exported types

newtype Pipeline Source #

Memory-managed wrapper type.

Constructors

Pipeline (ManagedPtr Pipeline)

Instances

GObject Pipeline Source #
Instance details Defined in GI.Gst.Objects.Pipeline Methods gobjectType :: IO GType #
HasParentTypes Pipeline Source #
Instance details Defined in GI.Gst.Objects.Pipeline
type ParentTypes Pipeline Source #
Instance details Defined in GI.Gst.Objects.Pipeline type ParentTypes Pipeline = Bin ': (Element ': (Object ': (Object ': (ChildProxy ': ([] :: [Type])))))

class (GObject o, IsDescendantOf Pipeline o) => IsPipeline o Source #

Type class for types which can be safely cast to Pipeline, for instance with toPipeline.

Instances

(GObject o, IsDescendantOf Pipeline o) => IsPipeline o Source #
Instance details Defined in GI.Gst.Objects.Pipeline

toPipeline :: (MonadIO m, IsPipeline o) => o -> m Pipeline Source #

Cast to Pipeline, for types for which this is known to be safe. For general casts, use castTo.

noPipeline :: Maybe Pipeline Source #

A convenience alias for Nothing :: Maybe Pipeline.

Methods

autoClock

pipelineAutoClock Source #

Arguments

:: (HasCallStack, MonadIO m, IsPipeline a)
=> a	`pipeline`: a `Pipeline`
-> m ()

Let pipeline select a clock automatically. This is the default behaviour.

Use this function if you previous forced a fixed clock with pipelineUseClock and want to restore the default pipeline clock selection algorithm.

MT safe.

getAutoFlushBus

pipelineGetAutoFlushBus Source #

Arguments

:: (HasCallStack, MonadIO m, IsPipeline a)

=> a

pipeline: a Pipeline

-> m Bool

Returns: whether the pipeline will automatically flush its bus when going from READY to NULL state or not.

MT safe.

Check if pipeline will automatically flush messages when going to the NULL state.

getBus

pipelineGetBus Source #

Arguments

:: (HasCallStack, MonadIO m, IsPipeline a)

=> a

pipeline: a Pipeline

-> m Bus

Returns: a Bus, unref after usage.

MT safe.

Gets the Bus of pipeline. The bus allows applications to receive Message packets.

getDelay

pipelineGetDelay Source #

Arguments

:: (HasCallStack, MonadIO m, IsPipeline a)

=> a

pipeline: a Pipeline

-> m Word64

Returns: The configured delay.

MT safe.

Get the configured delay (see pipelineSetDelay).

getLatency

pipelineGetLatency Source #

Arguments

:: (HasCallStack, MonadIO m, IsPipeline a)
=> a	`pipeline`: a `Pipeline`
-> m Word64	Returns: Latency to configure on the pipeline or GST_CLOCK_TIME_NONE

Gets the latency that should be configured on the pipeline. See pipelineSetLatency.

Since: 1.6

getPipelineClock

pipelineGetPipelineClock Source #

Arguments

:: (HasCallStack, MonadIO m, IsPipeline a)
=> a	`pipeline`: a `Pipeline`
-> m Clock	Returns: a `Clock`, unref after usage.

Gets the current clock used by pipeline.

Unlike elementGetClock, this function will always return a clock, even if the pipeline is not in the PLAYING state.

Since: 1.6

new

pipelineNew Source #

Arguments

:: (HasCallStack, MonadIO m)

=> Maybe Text

name: name of new pipeline

-> m Pipeline

Returns: newly created GstPipeline

MT safe.

Create a new pipeline with the given name.

setAutoFlushBus

pipelineSetAutoFlushBus Source #

Arguments

:: (HasCallStack, MonadIO m, IsPipeline a)
=> a	`pipeline`: a `Pipeline`
-> Bool	`autoFlush`: whether or not to automatically flush the bus when the pipeline goes from READY to NULL state
-> m ()

Usually, when a pipeline goes from READY to NULL state, it automatically flushes all pending messages on the bus, which is done for refcounting purposes, to break circular references.

This means that applications that update state using (async) bus messages (e.g. do certain things when a pipeline goes from PAUSED to READY) might not get to see messages when the pipeline is shut down, because they might be flushed before they can be dispatched in the main thread. This behaviour can be disabled using this function.

It is important that all messages on the bus are handled when the automatic flushing is disabled else memory leaks will be introduced.

MT safe.

setDelay

pipelineSetDelay Source #

Arguments

:: (HasCallStack, MonadIO m, IsPipeline a)
=> a	`pipeline`: a `Pipeline`
-> Word64	`delay`: the delay
-> m ()

Set the expected delay needed for all elements to perform the PAUSED to PLAYING state change. delay will be added to the base time of the elements so that they wait an additional delay amount of time before starting to process buffers and cannot be CLOCK_TIME_NONE.

This option is used for tuning purposes and should normally not be used.

MT safe.

setLatency

pipelineSetLatency Source #

Arguments

:: (HasCallStack, MonadIO m, IsPipeline a)
=> a	`pipeline`: a `Pipeline`
-> Word64	`latency`: latency to configure
-> m ()

Sets the latency that should be configured on the pipeline. Setting GST_CLOCK_TIME_NONE will restore the default behaviour of using the minimum latency from the LATENCY query. Setting this is usually not required and the pipeline will figure out an appropriate latency automatically.

Setting a too low latency, especially lower than the minimum latency from the LATENCY query, will most likely cause the pipeline to fail.

Since: 1.6

useClock

pipelineUseClock Source #

Arguments

:: (HasCallStack, MonadIO m, IsPipeline a, IsClock b)
=> a	`pipeline`: a `Pipeline`
-> Maybe b	`clock`: the clock to use
-> m ()

Force pipeline to use the given clock. The pipeline will always use the given clock even if new clock providers are added to this pipeline.

If clock is Nothing all clocking will be disabled which will make the pipeline run as fast as possible.

MT safe.

Properties

autoFlushBus

Whether or not to automatically flush all messages on the pipeline's bus when going from READY to NULL state. Please see pipelineSetAutoFlushBus for more information on this option.

constructPipelineAutoFlushBus :: IsPipeline o => Bool -> IO (GValueConstruct o) Source #

Construct a GValueConstruct with valid value for the “auto-flush-bus” property. This is rarely needed directly, but it is used by new.

getPipelineAutoFlushBus :: (MonadIO m, IsPipeline o) => o -> m Bool Source #

Get the value of the “auto-flush-bus” property. When overloading is enabled, this is equivalent to

get pipeline #autoFlushBus

setPipelineAutoFlushBus :: (MonadIO m, IsPipeline o) => o -> Bool -> m () Source #

Set the value of the “auto-flush-bus” property. When overloading is enabled, this is equivalent to

set pipeline [ #autoFlushBus := value ]

delay

The expected delay needed for elements to spin up to the PLAYING state expressed in nanoseconds. see pipelineSetDelay for more information on this option.

constructPipelineDelay :: IsPipeline o => Word64 -> IO (GValueConstruct o) Source #

Construct a GValueConstruct with valid value for the “delay” property. This is rarely needed directly, but it is used by new.

getPipelineDelay :: (MonadIO m, IsPipeline o) => o -> m Word64 Source #

Get the value of the “delay” property. When overloading is enabled, this is equivalent to

get pipeline #delay

setPipelineDelay :: (MonadIO m, IsPipeline o) => o -> Word64 -> m () Source #

Set the value of the “delay” property. When overloading is enabled, this is equivalent to

set pipeline [ #delay := value ]

latency

Latency to configure on the pipeline. See pipelineSetLatency.

Since: 1.6

constructPipelineLatency :: IsPipeline o => Word64 -> IO (GValueConstruct o) Source #

Construct a GValueConstruct with valid value for the “latency” property. This is rarely needed directly, but it is used by new.

getPipelineLatency :: (MonadIO m, IsPipeline o) => o -> m Word64 Source #

Get the value of the “latency” property. When overloading is enabled, this is equivalent to

get pipeline #latency

setPipelineLatency :: (MonadIO m, IsPipeline o) => o -> Word64 -> m () Source #

Set the value of the “latency” property. When overloading is enabled, this is equivalent to

set pipeline [ #latency := value ]