High-level Track Event Data Model
Track information in ACTS can be divided into two parts: track-level information and track state-level information.
Track-level information are properties that relate to the full track. This includes the fitted track parameters with respect to some reference point, often the origin of the detector or the beamspot. It can also include summary information from the track finding stage, like the overall number of clusters that were used in the creation of the track, or the fit quality from the track fit.
Tracks are built-up from track states, where each track state corresponds to a discrete state determining the track properties. This mainly includes measurements states, expected intersections with sensors where no measurement was found (holes), and intersections with known passive material. The EDM allows building up a track from these track states iteratively. For example, the Kalman Filter will append track states to the sequence whenever it encounters a sensitive detector layer. The content of the track states is defined such that the fitter can store all relevant information, with as little need for extra information as possible. It is also designed to be flexible enough to support different fitters, which might require different information to be stored, as well as the Combinatorial Kalman Filter, which produces a tree of track states, instead of a fully linear sequence.
Ultimately, each output track is associated with a well-defined sequence of track states, allowing downstream consumers of the EDM to access the fully detailed information produced during track reconstruction.
This section will first discuss the architecture and general implementation of the Track EDM in Conceptual, and then report on the API of the involved classes in Track API.
Conceptual
Architecture
The Track EDM is structured such that the memory-layout can be SoA, while presenting an object-oriented interface for convenient usage.
Fig. 19 shows this object-oriented access model for the example of the track container and track proxy object. The track container holds vectors of the various pieces of information, and has methods to add a track, and to allow iteration over all tracks. This iteration, or index based access, yields a track proxy object, which exposes the properties as methods returning references, while internally only holding a pointer to and an index into the track container. The types are built in a way that preserves const-correctness, i.e. even though a track proxy is a value type which can be copied, it will not allow modification of the underlying track container if it is immutable:
auto mutableTrackContainer = /*...*/;
auto trackProxy = mutableTrackContainer.getTrack(5); // is mutable
const auto& constTrackProxy = trackProxy; // is const
// ...
auto constTrackContainer = /*...*/;
auto trackProxy = trackContainer.getTrack(5); // is const, even as an lvalue
The track EDM is fully agnostic to the concrete persistency framework of an experiment. This avoids having to convert the data between different representations, if implemented correctly.
Implementation
To make the EDM implementation independent of an experiment persistency framework, it is separated into a frontend layer and a backend layer. The frontend layer contains user-facing getters and setters, as well as convenience methods that can be helpful. These methods are located either in the proxy objects or in the containers, depending on whether they operate on a single element or the entire container.
Overall, there are four main classes that make up the frontend layer:
Acts::TrackProxy
, Acts::TrackContainer
,
Acts::TrackStateProxy
and Acts::MultiTrajectory
. The latter
serves as the track state container, where the name indicates that it is able
to handle a branching tree structure of track states. TrackProxy
and
TrackStateProxy
expose methods to get the local track parameters and
covariance, corresponding reference surface, and also includes global
statistics like the total number of measurements, outliers or
holes in case of TrackProxy
. TrackProxy
also has a method to
conveniently iterate over the associated track states from the last track state
to the first one yielding TrackStateProxy
objects from the track state
container. In the common case of a track from the center of a cylindrical
detector going outward, the default iteration order is from the outside
inwards.
In case of TrackStateProxy
, functionality is exposed in the frontend
layer to allocate optional components, with the goal of reduced memory
footprint. There are two main use cases of this: track parameters and measurements.
The track-state EDM supports storing up to three sets of local track parameters
and covariance matrices, modeled after the information the Kalman Filter
formalism needs to store:
predicted parameter vector and covariance matrix
filtered parameter vector and covariance matrix
smoothed parameter vector and covariance matrix
In case of combinatorial track finding (see Track Finding, specifically Fig. 16), track hypothesis can start out with a common sequence of track states, and then branch out when multiple compatible measurements are encountered, as seen in Fig. 21.
The track state EDM allows allocating only the track parameters that are needed, and also allows sharing the same track parameters between multiple track states, so that branching track states can share for example the same predicted parameters. How this is achieved exactly is left to the backend layer. Measurements are handled in a similar way, where the track finding decides how much storage is needed based on the number of dimensions of an incoming measurement. It then instructs the EDM through the frontend layer to ensure enough memory is available, where the specifics are again left up to the backend layer.
The backend layer exposes an interface that is used by the frontend layer to store and retrieve information. It uses dedicated methods where needed, such as for storing reference surfaces or source-link objects, which are lightweight container objects for experiment-specific measurements. For the majority of components, the frontend communicates with the backend through a single method to obtain references to the underlying data. Components are accessed via hashes of the component name, where the hashes are calculated at compile-time wherever possible. The backend can then use the hashed component name to retrieve the relevant memory. To allow directly manipulating the backing memory, the frontend expects the backend to return references into the backing storage.
TrackProxy
provides a method to copy a track between different track
containers, and only uses the frontend layer to accomplish this. This means that
copying tracks between different backend implementations is trivial.
Fig. 20 shows a diagram of the EDM architecture. At the center
are the TrackProxy
and TrackContainer
. These classes are
produced by the track finding and track fitting components, and are the main
interface point with the clients of tracking. In ACTS itself, all of the
performance monitoring and downstream reconstruction is either directly built on
top of these objects, or converts them into an internal EDM on the use
case. Behind the backend interface, the track container coordinates with both a
track state and a track backend, where a few examples are shown, and will be
discussed below.
Track API
-
template<typename track_container_t, typename trajectory_t, template<typename> class holder_t, bool read_only = true>
class TrackProxy Proxy class representing a single track.
This class provides a view into an associated TrackContainer, and has reference semantics. You can think of it as a pointer to a vector of tracks, which exposes an object-oriented interface for accessing the track properties.
- Template Parameters:
track_container_t – the container backend
trajectory_t – the track state container backend
holder_t – ownership management class for the backend
read_only – true if this track container is not mutable
Constructors and assignment operator
Public constructors and assignment operators for
TrackProxy
only allow construction from anotherTrackProxy
. You should generally not have to constructTrackProxy
manually.-
inline TrackProxy(const MutableTrackProxy &other)
Copy constructor from a mutable track proxy.
This is always valid, either mutable to mutable or mutable to const
- Parameters:
other – the other track state proxy
-
inline TrackProxy &operator=(const MutableTrackProxy &other)
Copy assignment operator from mutable track proxy.
This is always valid, either mutable to mutable or mutable to const
- Parameters:
other – the other track state proxy
TrackProxy properties
Methods that give access to the properties of a track represented by
TrackProxy
.Many of these methods come in a
const
and a non-const
version. The non-const
version is only available if you have an instance ofTrackProxy
that does not have theread_only
template parameter set totrue
, even if you hold it as an lvalue.-
inline IndexType tipIndex() const
Get the tip index, i.e.
the entry point into the track state container
- Returns:
the tip index by value
-
inline IndexType stemIndex() const
Index of the stem, i.e.
the innermost track state of the track. This might be invalid, signifying that the track state is not forward-linked.
- Returns:
the stem index
-
inline IndexType &tipIndex()
requires (!ReadOnly) Get a mutable reference to the tip index, i.e.
the entry point into the track container
Note
Only available if the track proxy is not read-only
- Returns:
mutable reference to the tip index
-
inline IndexType &stemIndex()
requires (!ReadOnly) Index of the stem, i.e.
the innermost track state of the track. This might be invalid, signifying that the track state is not forward-linked.
Note
Only available if the track proxy is not read-only
- Returns:
mutable reference to the stem index
-
inline const Surface &referenceSurface() const
Get the reference surface of the track (e.g.
the perigee)
- Returns:
the reference surface
Set a new reference surface for this track.
- Parameters:
srf – The surface to set
-
inline bool hasReferenceSurface() const
Returns whether the track has a reference surface or not.
- Returns:
whether a surface exists or not
-
inline ConstParameters parameters() const
Get the parameters of the track at the reference surface (e.g.
perigee). Const version
- Returns:
Proxy vector for the parameters
-
inline ConstCovariance covariance() const
Get the covariance of the track at the reference surface (e.g.
perigee). Const version
- Returns:
Proxy matrix for the covariance
-
inline Parameters parameters()
requires (!ReadOnly) Get the parameters of the track at the reference surface (e.g.
perigee). Mutable version
Note
Only available if the track proxy is not read-only
- Returns:
Proxy vector for the parameters
-
inline Covariance covariance()
requires (!ReadOnly) Get the covariance of the track at the reference surface (e.g.
perigee). Mutable version
Note
Only available if the track proxy is not read-only
- Returns:
Proxy matrix for the covariance
-
inline ActsScalar theta() const
Access the theta parameter of the track at the reference surface.
- Returns:
The theta parameter
-
inline ActsScalar phi() const
Access the phi parameter of the track at the reference surface.
- Returns:
The phi parameter
-
inline ActsScalar loc0() const
Access the loc0 parameter of the track at the reference surface.
- Returns:
The loc0 parameter
-
inline ActsScalar loc1() const
Access the loc1 parameter of the track at the reference surface.
- Returns:
The loc1 parameter
-
inline ActsScalar time() const
Access the time parameter of the track at the reference surface.
- Returns:
The time parameter
-
inline ActsScalar qOverP() const
Access the q/p (curvature) parameter of the track at the reference surface.
- Returns:
The q/p parameter
-
inline ParticleHypothesis particleHypothesis() const
Get the particle hypothesis.
- Returns:
the particle hypothesis
-
inline void setParticleHypothesis(const ParticleHypothesis &particleHypothesis)
requires (!ReadOnly) Set a new particle hypothesis for this track.
Note
Only available if the track proxy is not read-only
- Parameters:
particleHypothesis – The particle hypothesis to set
-
inline ActsScalar charge() const
Get the charge of the tack.
Note
this depends on the charge hypothesis
- Returns:
The absolute track momentum
-
inline ActsScalar absoluteMomentum() const
Get the absolute momentum of the tack.
- Returns:
The absolute track momentum
-
inline ActsScalar transverseMomentum() const
Get the transverse momentum of the track.
- Returns:
The track transverse momentum value
-
inline Vector3 direction() const
Get a unit vector along the track direction at the reference surface.
- Returns:
The direction unit vector
-
inline Vector3 momentum() const
Get the global momentum vector.
- Returns:
the global momentum vector
-
inline unsigned int nTrackStates() const
Return the number of track states associated to this track.
Note
This is calculated by iterating over the track states which is somewhat expensive. Consider caching this value if you need It more than once.
- Returns:
The number of track states
-
inline unsigned int &nMeasurements()
requires (!ReadOnly) Return the number of measurements for the track.
Const version
Note
Only available if the track proxy is not read-only
- Returns:
The number of measurements
-
inline unsigned int nMeasurements() const
Return a mutable reference to the number of measurements for the track.
Mutable version
- Returns:
The number of measurements
-
inline unsigned int &nHoles()
requires (!ReadOnly) Return a mutable reference to the number of holes for the track.
Mutable version
Note
Only available if the track proxy is not read-only
- Returns:
The number of holes
-
inline unsigned int nHoles() const
Return the number of measurements for the track.
Const version
- Returns:
The number of measurements
-
inline unsigned int &nOutliers()
requires (!ReadOnly) Return a mutable reference to the number of outliers for the track.
Mutable version
Note
Only available if the track proxy is not read-only
- Returns:
The number of outliers
-
inline unsigned int nOutliers() const
Return the number of outliers for the track.
Const version
- Returns:
The number of outliers
Return a mutable reference to the number of shared hits for the track.
Mutable version
Note
Only available if the track proxy is not read-only
- Returns:
The number of shared hits
Return the number of shared hits for the track.
Const version
- Returns:
The number of shared hits
-
inline float &chi2()
requires (!ReadOnly) Return a mutable reference to the chi squared Mutable version.
Note
Only available if the track proxy is not read-only
- Returns:
The chi squared
-
inline float chi2() const
Return the chi squared for the track.
Const version
- Returns:
The chi squared
-
inline unsigned int &nDoF()
requires (!ReadOnly) Return a mutable reference to the number of degrees of freedom for the track.
Mutable version
Note
Only available if the track proxy is not read-only
- Returns:
The number of degrees of freedom
-
inline unsigned int nDoF() const
Return the number of degrees of freedom for the track.
Const version
- Returns:
The number of degrees of freedom
-
inline IndexType index() const
Return the index of this track in the track container.
Note
This is separate from the tip index
- Returns:
the track index
TrackProxy track state access
Methods that give access to the track states of a track represented by
TrackProxy
.-
inline ConstTrackStateProxy outermostTrackState() const
Return a const track state proxy to the outermost track state.
- Returns:
The outermost track state proxy
-
inline TrackStateProxy outermostTrackState()
requires (!ReadOnly) Return a mutable track state proxy to the outermost track state.
- Returns:
The outermost track state proxy
-
inline auto innermostTrackState() const
Return a const track state proxy to the innermost track state.
Note
This is only available, if the track is forward linked
- Returns:
The innermost track state proxy
-
inline auto innermostTrackState()
requires (!ReadOnly) Return a mutable track state proxy to the innermost track state.
Note
This is only available, if the track is forward linked
Note
Only available if the track proxy is not read-only
- Returns:
The innermost track state proxy
-
inline auto trackStatesReversed() const
Get a range over the track states of this track.
Return value is compatible with range based for loop. Const version
Note
This range is from the outside inwards!
- Returns:
Track state range to iterate over
-
inline auto trackStatesReversed()
requires (!ReadOnly) Get a range over the track states of this track.
Return value is compatible with range based for loop. Mutable version
Note
Only available if the track proxy is not read-only
Note
This range is from the outside inwards!
- Returns:
Track state range to iterate over
-
inline auto trackStates() const
Get a range over the track states of this track.
Return value is compatible with range based for loop. This overload returns a const-only track state range, which means you cannot modify the track states obtained in the iteration.
Note
This range is from the inside out!
Warning
This access direction is only possible if the track states are forward-linked.
- Returns:
Track state range to iterate over
-
inline auto trackStates()
requires (!ReadOnly) Get a range over the track states of this track.
Return value is compatible with range based for loop. This overload returns a mutable track state range, which means you can modify the track states obtained in the iteration.
Note
Only available if the track proxy is not read-only
Note
This range is from the inside out!
Warning
This access direction is only possible if the track states are forward-linked.
- Returns:
Track state range to iterate over
TrackProxy track state manipulation
Methods that manipulate the track states of a track represented by
TrackProxy
.-
inline void linkForward()
requires (!ReadOnly) Forward connect a track.
This means setting indices from the inside out on all track states.
Note
Only available if the track proxy is not read-only
-
inline auto appendTrackState(TrackStatePropMask mask = TrackStatePropMask::All)
requires (!ReadOnly) Append a track state to this track.
This will modify the tip index to point at the newly created track state, which will be directly after the previous track state at tip index.
Note
Only available if the track proxy is not read-only
- Parameters:
mask – The allocation prop mask for the new track state
- Returns:
The newly added track state
-
template<typename track_proxy_t>
inline void copyFrom(const track_proxy_t &other, bool copyTrackStates = true)
requires (!ReadOnly) Copy the content of another track proxy into this one.
Note
Only available if the track proxy is not read-only
- Template Parameters:
track_proxy_t – the other track proxy’s type
- Parameters:
other – The track proxy
copyTrackStates – Copy the track state sequence from
other
-
inline TrackProxy shallowCopy()
requires (!ReadOnly) Creates a shallow copy of the track.
Track states are not copied, but the resulting track points at the same track states as the original.
Note
Only available if the track proxy is not read-only
-
inline void reverseTrackStates(bool invertJacobians = false)
requires (!ReadOnly) Reverse the ordering of track states for this track Afterwards, the previous endpoint of the track state sequence will be the “innermost” track state.
Note
Only available if the track proxy is not read-only
Note
This is dangerous with branching track state sequences, as it will break them
Note
This also automatically forward-links the track!
- Parameters:
invertJacobians – Whether to invert the Jacobians of the track states
TrackProxy generic component access
Methods that give access to generic components of a track represented by
TrackProxy
.Internally, a compile-time hash of the component name is used to identify which component is being requested. Most of the named methods in TrackProxy properties use these methods to retrieve the actual data.
A number of overloads exist, where you can either supply the HashedString
key
as a template parameter or a runtime argument. The former has the advantage of being guaranteed to be evaluated at compile-time.-
template<typename T, HashedString key>
inline constexpr T &component()
requires (!ReadOnly) Retrieve a mutable reference to a component.
- Template Parameters:
T – The type of the component to access
key – String key for the component to access
- Returns:
Mutable reference to the component given by
key
-
template<typename T>
inline constexpr T &component(HashedString key)
requires (!ReadOnly) Retrieve a mutable reference to a component.
- Template Parameters:
T – The type of the component to access
- Parameters:
key – String key for the component to access
- Returns:
Mutable reference to the component given by
key
-
template<typename T>
inline constexpr T &component(std::string_view key)
requires (!ReadOnly) Retrieve a mutable reference to a component.
Note
This might hash the
key
at runtime instead of compile-time- Template Parameters:
T – The type of the component to access
- Parameters:
key – String key for the component to access
- Returns:
Mutable reference to the component given by
key
-
template<typename T, HashedString key>
inline constexpr const T &component() const Retrieve a const reference to a component.
- Template Parameters:
T – The type of the component to access
key – String key for the component to access
- Returns:
Const reference to the component given by
key
-
template<typename T>
inline constexpr const T &component(HashedString key) const Retrieve a const reference to a component.
- Template Parameters:
T – The type of the component to access
- Parameters:
key – String key for the component to access
- Returns:
Const reference to the component given by
key
-
template<typename T>
inline constexpr const T &component(std::string_view key) const Retrieve a const reference to a component.
Note
This might hash the
key
at runtime instead of compile-time- Template Parameters:
T – The type of the component to access
- Parameters:
key – String key for the component to access
- Returns:
Const reference to the component given by
key
Public Types
-
using ConstCovariance = typename detail_lt::FixedSizeTypes<eBoundSize, true>::CovarianceMap
Same as Covariance, but with const semantics.
-
using ConstParameters = typename detail_lt::FixedSizeTypes<eBoundSize, true>::CoefficientsMap
Same as Parameters, but with const semantics.
-
using ConstProxyType = ConstTrackProxy
Alias for an associated const track proxy, with the same backends.
-
using ConstTrackProxy = TrackProxy<track_container_t, trajectory_t, holder_t, true>
Alias for the const version of this track proxy, with the same backends.
-
using ConstTrackStateProxy = typename Trajectory::ConstTrackStateProxy
Alias for an associated const track state proxy, with the same backends.
-
using Container = track_container_t
The track container backend given as a template parameter.
-
using Covariance = typename detail_lt::FixedSizeTypes<eBoundSize, false>::CovarianceMap
Map-type for a bound covariance.
This has reference semantics, i.e. points at a matrix by an internal pointer.
-
using IndexType = typename Container::IndexType
The index type of the track container.
-
using MutableTrackProxy = TrackProxy<track_container_t, trajectory_t, holder_t, false>
Alias for the mutable version of this track proxy, with the same backends.
-
using Parameters = typename detail_lt::FixedSizeTypes<eBoundSize, false>::CoefficientsMap
Map-type for a bound parameter vector.
This has reference semantics, i.e. points at a matrix by an internal pointer.
-
using TrackStateProxy = typename Trajectory::TrackStateProxy
Alias for an associated mutable track state proxy, with the same backends.
-
using Trajectory = trajectory_t
The track state container backend given as a template parameter.
Public Functions
-
inline const auto &container() const
Return a reference to the track container backend, const version.
- Returns:
reference to the track container backend
-
inline auto &container()
requires (!ReadOnly) Return a reference to the track container backend, mutable version.
Note
Only available if the track proxy is not read-only
- Returns:
reference to the track container backend
-
inline BoundTrackParameters createParametersAtReference() const
Return the track parameters at the reference surface.
Note
The parameters are created on the fly
- Returns:
the track parameters
-
inline BoundTrackParameters createParametersFromState(const ConstTrackStateProxy &trackState) const
Convert a track state into track parameters.
Note
The parameters are created on the fly
- Returns:
the track parameters
-
inline bool operator==(const TrackProxy &other) const
Equality operator with another track proxy Checks the container identity and the track index.
- Returns:
True if the track proxies refer to the same track
-
template<TrackContainerBackend track_container_t, CommonMultiTrajectoryBackend traj_t, template<typename> class holder_t = detail::RefHolder>
class TrackContainer Track container interface class.
This type represents a collections of tracks. It uses a backend to store both the actual tracks and the associated track states.
- Template Parameters:
track_container_t – the track container backend
traj_t – the track state container backend
holder_t – ownership management class for the backend
TrackContainer construction
Constructors for the track container by using a set of backends (track + track state). The container can either take ownership of the backends or just hold references to them. This is driven by the
holder_t
template parameter, where you can also supply a custom holder type. Template deduction is used to try to guess the correct holder type.-
inline TrackContainer(holder_t<track_container_t> container, holder_t<traj_t> traj)
Constructor from a track container backend and a track state container backend.
- Parameters:
container – the track container backend
traj – the track state container backend
- inline TrackContainer (auto &container, auto &traj) requires(detail
Constructor from references to a track container backend and to a track state container backend.
Note
The track container will not assume ownership over the backends in this case. You need to ensure suitable lifetime
- Parameters:
container – the track container backend
traj – the track state container backend
- inline TrackContainer (const auto &container, const auto &traj) requires(detail
Constructor from const references to a track container backend and to a track state container backend.
Note
The track container will not assume ownership over the backends in this case. You need to ensure suitable lifetime
- Parameters:
container – the track container backend
traj – the track state container backend
TrackContainer track (proxy) access and manipulation
These methods allow accessing tracks, i.e. adding or retrieving a track proxy that points at a specific track in the container.
-
inline ConstTrackProxy getTrack(IndexType itrack) const
Get a const track proxy for a track index.
- Parameters:
itrack – the track index in the container
- Returns:
A const track proxy for the index
-
inline TrackProxy getTrack(IndexType itrack)
requires (!ReadOnly) Get a mutable track proxy for a track index.
Note
Only available if the track container is not read-only
- Parameters:
itrack – the track index in the container
- Returns:
A mutable track proxy for the index
-
inline IndexType addTrack()
requires (!ReadOnly) Add a track to the container.
Note this only creates the logical track and allocates memory. You can combine this with
getTrack
to obtain a track proxyNote
Only available if the track container is not read-only
- Returns:
the index to the newly added track
-
inline TrackProxy makeTrack()
requires (!ReadOnly) Add a track to the container and return a track proxy to it This effectively calls
addTrack
andgetTrack
.Note
Only available if the track container is not read-only
- Returns:
a track proxy to the newly added track
-
inline void removeTrack(IndexType itrack)
requires (!ReadOnly) Remove a track at index
itrack
from the container.Note
Only available if the track container is not read-only
Note
This invalidates track proxies that point to tracks with larger indices than
itrack!
- Parameters:
itrack – The index of the track to remove
-
inline auto begin()
requires (!ReadOnly) Get a mutable iterator to the first track in the container.
Note
Only available if the track container is not read-only
- Returns:
a mutable iterator to the first track
-
inline auto end()
requires (!ReadOnly) Get a past-the-end iterator for this container.
Note
Only available if the track container is not read-only
- Returns:
a past-the-end iterator
-
inline auto begin() const
Get an const iterator to the first track in the container.
- Returns:
a const iterator to the first track
-
inline auto end() const
Get a past-the-end iterator for this container.
- Returns:
a past-the-end iterator
TrackContainer column management
TrackContainer can manage a set of common static columns, and dynamic columns that can be added at runtime.
This set of methods allows you to manage the dynamic columns.
-
template<typename T>
inline constexpr void addColumn(std::string_view key)
requires (!ReadOnly) Add a dymanic column to the track container.
Note
Only available if the track container is not read-only
- Parameters:
key – the name of the column to be added
-
inline constexpr bool hasColumn(const std::string &key) const
Check if this track container has a specific dynamic column.
- Parameters:
key – the key to check for
-
inline constexpr bool hasColumn(HashedString key) const
Check if a this track container has a specific dynamic column.
- Parameters:
key – the key to check for
-
template<typename other_track_container_t>
inline void ensureDynamicColumns(const other_track_container_t &other)
requires (!ReadOnly) Helper function to make this track container match the dynamic columns of another one.
This will only work if the track container supports this source, and depends on the implementation details of the dynamic columns of the container
Note
Only available if the track container is not read-only
- Template Parameters:
other_track_container_t – Type of the other track container
- Parameters:
other – The other track container
TrackContainer backend access
These methods allow accessing the backend of the track container.
In most cases, this is not necessary for interacting with the container.
-
inline auto &container()
requires (!ReadOnly) Get a mutable reference to the track container backend.
Note
Only available if the track container is not read-only
- Returns:
a mutable reference to the backend
-
inline const auto &container() const
Get a const reference to the track container backend.
- Returns:
a const reference to the backend
-
inline auto &trackStateContainer()
requires (!ReadOnly) Get a mutable reference to the track state container backend.
Note
Only available if the track container is not read-only
- Returns:
a mutable reference to the backend
-
inline auto &trackStateContainerHolder()
requires (!ReadOnly) Retrieve the holder of the track state container.
Note
Only available if the track container is not read-only
- Returns:
The track state container including it’s holder
-
inline const auto &trackStateContainer() const
Get a const reference to the track state container backend.
- Returns:
a const reference to the backend
-
inline const auto &trackStateContainerHolder() const
Retrieve the holder of the track state container.
- Returns:
The track state container including it’s holder
Public Types
-
using ConstTrackProxy = Acts::TrackProxy<track_container_t, traj_t, holder_t, true>
Alias for the const version of a track proxy, with the same backends as this container.
-
using ConstTrackStateProxy = typename MultiTrajectory<traj_t>::ConstTrackStateProxy
-
using IndexType = TrackIndexType
The index type of the track container, taken from the container backend.
-
using TrackContainerBackend = track_container_t
-
using TrackProxy = Acts::TrackProxy<track_container_t, traj_t, holder_t, false>
Alias for the mutable version of a track proxy, with the same backends as this container.
-
using TrackStateContainerBackend = traj_t
-
using TrackStateProxy = typename MultiTrajectory<traj_t>::TrackStateProxy
Public Functions
-
inline void clear()
requires (!ReadOnly) Clear the content of the track container.
Note
Only available if the track container is not read-only
-
inline constexpr IndexType size() const
Get the size (number of tracks) of the track container.
- Returns:
the sixe
Public Static Attributes
-
static constexpr IndexType kInvalid = kTrackIndexInvalid
Sentinel value that indicates an invalid index.
-
static constexpr bool ReadOnly = IsReadOnlyTrackContainer<track_container_t>::value
Indicates if this track container is read-only, or if it can be modified.
-
static constexpr bool TrackStateReadOnly = IsReadOnlyMultiTrajectory<traj_t>::value
Indicates if the track state container is read-only, or if it can be modified.
Track state iteration and forward linking
By default, track states are connected as a one-directional linked list, where each track state knows its previous track state. Fig. 21 shows an example of a track state tree, like it is constructed by the combinatorial track finding.
In Fig. 21 states \(S_7\) and \(S_6\) are the two tip states of the track state tree, while \(S_1\) is the single stem state. In the case of combinatorial track finding starting from e.g. a seed, it could be the location of the innermost space point.
Each track object points at a single tip state to define its track state sequence.
The Acts::TrackProxy
class has various methods to access the track state sequence:
auto track = getTrackFromSomewhere();
for(const auto trackState : track.trackStatesReversed()) {
// do something with track state
}
Note that Acts::TrackProxy::trackStatesReversed()
iterates from the tip state to
the stem state, i.e. from the outside in.
Attention
By-default, it is not possible to iterate forward through the track states on a track! The track’s track states need to be forward-linked for this to be possible.
The reason for this is: As the trajectory branches at the second sensor into \(S_2\)/\(S_3\), it is not possible to connect the states forward, i.e. store in \(S_1\) what the next state is going to be: it is ambiguous!
However, when track finding has concluded, and the trajectories identified by
tip states \(S_7\) and \(S_8\) have been discarded or are being
copied into an output container, it is possible to forward link the track
state sequences. This is possible if the trajectory does not branch
anymore! Acts::TrackProxy::copyFrom()
will implicitly forward link the
track states, as it is guaranteed to not branch after copying.
You can manually add forward-linking to a track by calling
Acts::TrackProxy::linkForward()
or
Acts::TrackProxy::reverseTrackStates()
.
Warning
Calling either Acts::TrackProxy::linkForward()
or
Acts::TrackProxy::reverseTrackStates()
on a track state sequence which
has branching will break the branching! If you have other tracks pointing at a
tip state that branches from the sequence you’re trying to
forward-link, it will be corrupted!
In this example, before any forward linking, the sequence looks like this:
digraph { rankdir="LR"; S2 -> S1; S3 -> S1; S7 -> S5 -> S4 -> S2; S6 -> S3; }After a copy operation of \(S_6\) and \(S_7\) the resultig track state sequences will look like this:
digraph { rankdir="LR"; S11[label="S1 (copy)"]; S12[label="S1 (copy)"]; S7 -> S5 -> S4 -> S11; S11 -> S4 -> S5 -> S7; S6 -> S3 -> S12; S12 -> S3 -> S6; }This now includes both forward and backward links, which allows iteration from \(S_1\)/\(S_2\) to \(S_6\)/\(S_7\) and the other way around.
Forward iteration can then be achieved like this:
auto track = getTrackFromSomewhere();
for(const auto trackState : track.trackStates()) {
// iterate forward
// do something with track state
}
and the innermost track state becomes directly accessible via
Acts::TrackProxy::innermostTrackState()
.
Attention
If the track container has branching track state sequences, running a smoothing step in-place on branching tracks is problematic: if tracks are smoothed one by one, the last track of each shared track state (i.e. the track state where branching occurs) will overwrite the smoothing result of all previous tracks.
Consider again the track states in Fig. 21. \(S_1\) is the common ancestor for \(S_2\) and \(S_3\), and has a single slot to store smoothed parameters. If smoothing happens for the track ending in \(S_6\), then smoothing the track ending in \(S_7\) only the values written by the final smoothing of \(S_37 will survive in \)S_1$’s storage. This can be unexpected!
Track State API
-
template<typename trajectory_t, std::size_t M, bool read_only = true>
class TrackStateProxy Proxy object to access a single point on the trajectory.
- Template Parameters:
SourceLink – Type to link back to an original measurement
M – Maximum number of measurement dimensions
read_only – true for read-only access to underlying storage
Constructors and assignment operator
Public constructors and assignment operators for
TrackStateProxy
only allow construction from anotherTrackStateProxy
. You should generally not have to constructTrackStateProxy
manually.-
inline TrackStateProxy(const TrackStateProxy<Trajectory, M, false> &other)
Constructor and assignment operator to construct TrackStateProxy from mutable.
- Parameters:
other – The other TrackStateProxy to construct from
-
inline TrackStateProxy &operator=(const TrackStateProxy<Trajectory, M, false> &other)
Assignment operator to from mutable
TrackStateProxy
.- Parameters:
other – The other TrackStateProxy to construct from
- Returns:
Reference to this TrackStateProxy
Track state properties
Properties of the track state represented by
TrackStateProxy
.Many of these methods come in a
const
and a non-const
version. The non-const
version is only available if you have an instance ofTrackStateProxy
that does not have theread_only
template parameter set totrue
, even if you hold it as an lvalue.The track states each have an index in the track state container. The sequence of track states is implemented as a one or two-way linked list, which uses indices into the same container.
Each track state has a
previous
index, which points at the track state immediately preceding. A track state with aprevious
index ofkInvalid
is the first (innermost) track state in a track or track candidate. This is also referred to as a stem at the track level.During track finding and fitting, track states are usually appended to the sequence, populating the
previous
index of the new track state. Combinatorial track finding can produce track states which fork in this way, by having more than one track state with the sameprevious
index.The track states have static, optional and dynamic properties. Static properties are always present, and can always be retrieved. Optional components use an extra indirection mechanism that coordinates with the backend to allow both not having the component set, or sharing it with other track states. An example is a branching trajectory from track finding which shares the same predicted parameter vector and associated covariance.
Optional components are
predicted parameters and covariance
filtered parameters and covariance
smoothed parameters and covariance
jacobian
calibrated measurement info including projector
They can be unset via unset, getMask can be used to check which components are present. The first four are shareable between track states via shareFrom.
-
inline IndexType index() const
Index within the trajectory.
- Returns:
the index
-
inline IndexType previous() const
Return the index of the track state
previous
in the track sequence.- Returns:
The index of the previous track state.
-
inline IndexType &previous()
requires (!ReadOnly) Return a mutable reference to the index of the track state ‘previous’ in the track sequence.
Note
Only available if the track state proxy is not read-only
- Returns:
The index of the previous track state.
-
inline bool hasPrevious() const
Return whether this track state has a previous (parent) track state.
- Returns:
Boolean indicating whether a previous track state exists
-
TrackStatePropMask getMask() const
Build a mask that represents all the allocated components of this track state proxy.
- Returns:
The generated mask
-
inline void unset(TrackStatePropMask target)
requires (!ReadOnly) Unset an optional track state component.
Note
Only available if the track state proxy is not read-only
- Parameters:
target – The component to unset
-
inline void addComponents(TrackStatePropMask mask)
requires (!ReadOnly) Add additional components to the track state.
Note
Only available if the track state proxy is not read-only
- Parameters:
mask – The bitmask that instructs which components to allocate
-
inline const Surface &referenceSurface() const
Reference surface.
- Returns:
the reference surface
-
inline bool hasReferenceSurface() const
Returns if the track state has a non nullptr surface associated.
- Returns:
whether a surface exists or not
Set the reference surface to a given value.
Note
This overload is only present in case
ReadOnly
is false.- Parameters:
srf – Shared pointer to the surface to set
-
inline float &chi2()
requires (!ReadOnly) Getter/setter for chi2 value associated with the track state This overload returns a mutable reference, which allows setting a new value directly into the backing store.
Note
this overload is only enabled in case the proxy is not read-only
- Returns:
Mutable reference to the chi2 value
-
inline float chi2() const
Getter for the chi2 value associated with the track state.
This overload returns a copy of the chi2 value, and thus does not allow modification of the value in the backing storage.
- Returns:
the chi2 value of the track state
-
inline double &pathLength()
requires (!ReadOnly) Getter for the path length associated with the track state.
This overloaded is only enabled if not read-only, and returns a mutable reference.
- Returns:
Mutable reference to the pathlength.
-
inline double pathLength() const
Getter for the path length.
Returns a copy of the path length value.
- Returns:
The path length of this track state
-
inline TrackStateType typeFlags()
requires (!ReadOnly) Getter for the type flags associated with the track state.
This overloaded is only enabled if not read-only, and returns a mutable reference.
- Returns:
reference to the type flags.
-
inline ConstTrackStateType typeFlags() const
Getter for the type flags.
Returns a copy of the type flags value.
- Returns:
The type flags of this track state
Track state parameters
-
ConstParameters parameters() const
Track parameters vector.
This tries to be somewhat smart and return the first parameters that are set in this order: predicted -> filtered -> smoothed
- Returns:
one of predicted, filtered or smoothed parameters
-
ConstCovariance covariance() const
Track parameters covariance matrix.
This tries to be somewhat smart and return the first parameters that are set in this order: predicted -> filtered -> smoothed
- Returns:
one of predicted, filtered or smoothed covariances
-
inline ConstParameters predicted() const
Predicted track parameters vector.
- Returns:
The predicted parameters
-
inline Parameters predicted()
requires (!ReadOnly)
-
inline ConstCovariance predictedCovariance() const
Predicted track parameters covariance matrix.
- Returns:
The predicted track parameter covariance
-
inline Covariance predictedCovariance()
requires (!ReadOnly)
-
inline bool hasPredicted() const
Check whether the predicted parameters+covariance is set.
- Returns:
Whether it is set or not
-
inline ConstParameters filtered() const
Filtered track parameters vector.
Note
Const version
- Returns:
The filtered parameters
-
inline Parameters filtered()
requires (!ReadOnly) Filtered track parameters vector.
Note
Mutable version
- Returns:
The filtered parameters
-
inline ConstCovariance filteredCovariance() const
Filtered track parameters covariance matrix.
Note
Const version
- Returns:
The filtered parameters covariance
-
inline Covariance filteredCovariance()
requires (!ReadOnly) Filtered track parameters covariance matrix.
Note
Mutable version
- Returns:
The filtered parameters covariance
-
inline bool hasFiltered() const
Return whether filtered parameters+covariance is set.
- Returns:
Whether it is set
-
inline ConstParameters smoothed() const
Smoothed track parameters vector.
Note
Const version
- Returns:
The smoothed parameters
-
inline Parameters smoothed()
requires (!ReadOnly) Smoothed track parameters vector.
Note
Mutable version
- Returns:
The smoothed parameters
-
inline ConstCovariance smoothedCovariance() const
Smoothed track parameters covariance matrix.
Note
Const version
- Returns:
the parameter covariance matrix
-
inline Covariance smoothedCovariance()
requires (!ReadOnly) Smoothed track parameters covariance matrix.
Note
Mutable version
- Returns:
the parameter covariance matrix
-
inline bool hasSmoothed() const
Return whether smoothed parameters+covariance is set.
- Returns:
Whether it is set
-
inline ConstCovariance jacobian() const
Returns the jacobian from the previous trackstate to this one.
Note
Const version
- Returns:
The jacobian matrix
-
inline Covariance jacobian()
requires (!ReadOnly) Returns the jacobian from the previous trackstate to this one.
Note
Mutable version
- Returns:
The jacobian matrix
-
inline bool hasJacobian() const
Returns whether a jacobian is set for this trackstate.
- Returns:
Whether it is set
Track state measurement properties
Properties of the measurement associated with the track state represented. This consists of a vector and an associated square matrix of a measurement dimension which is between one and the size of the track parametrization. The measurement coordinate frame is required to be a strict subset of the bound track parametrization on the local geometry coordinate frame, i.e. using a pure projector matrix to convert from the bound parametrization to the measurement frame is possible.
The track state stores the parameter vector and covariance, and the backend is given the possibility to do so in a jagged way, i.e. only storing the number of values needed. This requires calling allocateCalibrated before storing the measurements (even if it might be a no-op).
The projector matrix is packed as a bitset, which is converted to a matrix on-demand (and therefore returned by value).
The track state also includes a SourceLink which acts as a proxy to the original uncalibrated measurement that the calibrated measurement was derived from. It is set and returned by value, to allow unpacking / repacking by the backend, if needed.
-
Projector projector() const
Returns the projector (measurement mapping function) for this track state.
It is derived from the uncalibrated measurement
Note
This function returns the overallocated projector. This means it is of dimension MxM, where M is the maximum number of measurement dimensions. The NxM submatrix, where N is the actual dimension of the measurement, is located in the top left corner, everything else is zero.
- Returns:
The overallocated projector
-
inline bool hasProjector() const
Returns whether a projector is set.
- Returns:
Whether it is set
-
inline EffectiveProjector effectiveProjector() const
Returns the projector (measurement mapping function) for this track state.
It is derived from the uncalibrated measurement
Warning
This function returns the effective projector. This means it is of dimension \(N\times M\), where \(N\) is the actual dimension of the measurement.
- Returns:
The effective projector
-
template<typename Derived>
inline void setProjector(const Eigen::MatrixBase<Derived> &projector)
requires (!ReadOnly) Set the projector on this track state This will convert the projector to a more compact bitset representation and store it.
Note
projector
is assumed to only have 0s or 1s as components.- Parameters:
projector – The projector in the form of a dense matrix
-
inline ProjectorBitset projectorBitset() const
Directly get the projector bitset, a compressed form of a projection matrix.
Note
This is mainly to copy explicitly a projector from one state to another. Use the
projector
oreffectiveProjector
method if you want to access the matrix.- Returns:
The projector bitset
-
inline void setProjectorBitset(ProjectorBitset proj)
requires (!ReadOnly) Set the projector bitset, a compressed form of a projection matrix.
Note
This is mainly to copy explicitly a projector from one state to another. If you have a projection matrix, set it with
setProjector
.- Parameters:
proj – The projector bitset
-
inline BoundSubspaceIndices boundSubspaceIndices() const
-
template<std::size_t measdim>
inline SubspaceIndices<measdim> subspaceIndices() const
-
inline void setBoundSubspaceIndices(BoundSubspaceIndices boundSubspace)
requires (!ReadOnly)
- template<std::size_t measdim> void setSubspaceIndices (SubspaceIndices< measdim > subspace) requires(!ReadOnly &&measdim<
- void index_t void setSubspaceIndices (std::array< index_t, measdim > subspaceIndices) requires(!ReadOnly &&measdim<
-
template<typename source_link_t>
inline void setUncalibratedSourceLink(source_link_t &&sourceLink)
requires (!ReadOnly) Set an uncalibrated source link.
- Parameters:
sourceLink – The uncalibrated source link to set
-
inline void setUncalibratedSourceLink(const SourceLink &sourceLink)
requires (!ReadOnly) Set an uncalibrated source link.
Note
Use the overload with an rvalue reference, this overload will be removed ith the next major version
- Parameters:
sourceLink – The uncalibrated source link to set
-
inline bool hasUncalibratedSourceLink() const
Check if the point has an associated uncalibrated measurement.
- Returns:
Whether it is set
-
inline bool hasCalibrated() const
Check if the point has an associated calibrated measurement.
- Returns:
Whether it is set
-
template<std::size_t measdim>
inline ConstCalibrated<measdim> calibrated() const Full calibrated measurement vector.
Might contain additional zeroed dimensions.
Note
Const version
- Returns:
The measurement vector
-
template<std::size_t measdim>
inline Calibrated<measdim> calibrated()
requires (!ReadOnly) Full calibrated measurement vector.
Might contain additional zeroed dimensions.
Note
Mutable version
- Returns:
The measurement vector
-
template<std::size_t measdim>
inline ConstCalibratedCovariance<measdim> calibratedCovariance() const Const full calibrated measurement covariance matrix.
The effective covariance is located in the top left corner, everything else is zeroed.
- Returns:
The measurement covariance matrix
-
template<std::size_t measdim>
inline CalibratedCovariance<measdim> calibratedCovariance()
requires (!ReadOnly) Mutable full calibrated measurement covariance matrix.
The effective covariance is located in the top left corner, everything else is zeroed.
- Returns:
The measurement covariance matrix
-
inline EffectiveCalibrated effectiveCalibrated()
requires (!ReadOnly) Mutable dynamic measurement vector with only the valid dimensions.
Warning
The dynamic vector has a runtime overhead!
- Returns:
The effective calibrated measurement vector
-
inline ConstEffectiveCalibrated effectiveCalibrated() const
Const dynamic measurement vector with only the valid dimensions.
Warning
The dynamic matrix has a runtime overhead!
- Returns:
The effective calibrated measurement vector
-
inline EffectiveCalibratedCovariance effectiveCalibratedCovariance()
Mutable dynamic measurement covariance matrix with only the valid dimensions.
Warning
The dynamic matrix has a runtime overhead!
- Returns:
The effective calibrated covariance matrix
-
inline ConstEffectiveCalibratedCovariance effectiveCalibratedCovariance() const
Const dynamic measurement covariance matrix with only the valid dimensions.
Warning
The dynamic matrix has a runtime overhead!
- Returns:
The effective calibrated covariance matrix
-
inline IndexType calibratedSize() const
Return the (dynamic) number of dimensions stored for this measurement.
Note
Depending on the backend, this size is used to determine the memory range of the measurement vector and covariance.
- Returns:
The number of dimensions
-
inline void allocateCalibrated(std::size_t measdim)
Allocate storage to be able to store a measurement of size
measdim
.This must be called before setting the measurement content.
Sharing and copying
Methods to share and copy track state components. Sharing means setting up more than one track state to point to the same component.
Shareable components are
predicted parameters and covariance
filtered parameters and covariance
smoothed parameters and covariance
jacobian
See TrackStatePropMask.
Share a shareable component within this track state.
- Parameters:
shareSource – Which component to share from
shareTarget – Which component to share as. This should be different from as
shareSource
, e.g. predicted can be shared as filtered.
Share a shareable component from another track state.
Note
The track states both need to be stored in the same
MultiTrajectory
instance- Parameters:
other – Track state proxy to share component from
component – Which component to share.
Share a shareable component from another track state.
Note
Shareable components are predicted, filtered, smoothed, calibrated, jacobian, or projector. See
TrackStatePropMask
.- Parameters:
other – Track state proxy to share component(s) from
shareSource – Which component to share from
shareTarget – Which component to share as. This can be be different from as
shareSource
, e.g. predicted can be shared as filtered.
-
template<TrackStateProxyConcept track_state_proxy_t>
inline void copyFrom(const track_state_proxy_t &other, TrackStatePropMask mask = TrackStatePropMask::All, bool onlyAllocated = true)
requires (!ReadOnly) Copy the contents of another track state proxy into this one.
Note
If the this track state proxy does not have compatible allocations with the source track state proxy, and
onlyAllocated
is false, an exception is thrown.Note
The mask parameter will not cause a copy of components that are not allocated in the source track state proxy.
- Parameters:
other – The other track state to copy from
mask – An optional mask to determine what to copy from
onlyAllocated – Whether to only copy allocated components
Track state proxy Generic component access
-
template<HashedString key>
inline constexpr bool has() const Check if a component is set.
- Template Parameters:
key – Hashed string key to check for
- Returns:
true if the component exists, false if not
-
inline constexpr bool has(HashedString key) const
Check if a component is set.
- Parameters:
key – Hashed string key to check for
- Returns:
true if the component exists, false if not
-
inline constexpr bool has(std::string_view key) const
Check if a component is set.
Note
This might hash the
key
at runtime instead of compile-time- Parameters:
key – String key to check for
- Returns:
true if the component exists, false if not
-
template<typename T, HashedString key>
inline constexpr T &component()
requires (!ReadOnly) Retrieve a mutable reference to a component.
- Template Parameters:
T – The type of the component to access
key – String key for the component to access
- Returns:
Mutable reference to the component given by
key
-
template<typename T>
inline constexpr T &component(HashedString key)
requires (!ReadOnly) Retrieve a mutable reference to a component.
- Template Parameters:
T – The type of the component to access
- Parameters:
key – String key for the component to access
- Returns:
Mutable reference to the component given by
key
-
template<typename T>
inline constexpr T &component(std::string_view key)
requires (!ReadOnly) Retrieve a mutable reference to a component.
Note
This might hash the
key
at runtime instead of compile-time- Template Parameters:
T – The type of the component to access
- Parameters:
key – String key for the component to access
- Returns:
Mutable reference to the component given by
key
-
template<typename T, HashedString key>
inline constexpr const T &component() const Retrieve a const reference to a component.
- Template Parameters:
T – The type of the component to access
key – String key for the component to access
- Returns:
Const reference to the component given by
key
-
template<typename T>
inline constexpr const T &component(HashedString key) const Retrieve a const reference to a component.
- Template Parameters:
T – The type of the component to access
- Parameters:
key – String key for the component to access
- Returns:
Const reference to the component given by
key
-
template<typename T>
inline constexpr const T &component(std::string_view key) const Retrieve a const reference to a component.
Note
This might hash the
key
at runtime instead of compile-time- Template Parameters:
T – The type of the component to access
- Parameters:
key – String key for the component to access
- Returns:
Const reference to the component given by
key
Public Types
-
template<std::size_t N>
using Calibrated = typename TrackStateTraits<N, ReadOnly>::Calibrated Map-type for a calibrated measurement vector, where the local measurement dimension is variable.
-
template<std::size_t N>
using CalibratedCovariance = typename TrackStateTraits<N, ReadOnly>::CalibratedCovariance Map-type for a calibrated measurement covariance matrix, where the local measurement dimension is variable.
-
template<std::size_t N>
using ConstCalibrated = typename TrackStateTraits<N, true>::Calibrated Same as
Calibrated
, but with const semantics.
-
template<std::size_t N>
using ConstCalibratedCovariance = typename TrackStateTraits<N, true>::CalibratedCovariance Same as CalibratedCovariance, but with const semantics.
-
using ConstCovariance = typename TrackStateTraits<M, true>::Covariance
Same as Covariance, but with const semantics.
-
using ConstEffectiveCalibrated = typename TrackStateTraits<M, true>::EffectiveCalibrated
Same as
EffectiveCalibrated
, but with const semantics.
-
using ConstEffectiveCalibratedCovariance = typename TrackStateTraits<M, true>::EffectiveCalibratedCovariance
Same as EffectiveCalibratedCovariance, but with const semantics.
-
using ConstParameters = typename TrackStateTraits<M, true>::Parameters
Same as Parameters, but with const semantics.
-
using ConstProxyType = TrackStateProxy<trajectory_t, M, true>
Alias for an associated const track state proxy, with the same backends.
-
using Covariance = typename TrackStateTraits<M, ReadOnly>::Covariance
Map-type for a bound covariance.
This has reference semantics, i.e. points at a matrix by an internal pointer.
-
using EffectiveCalibrated = typename TrackStateTraits<M, ReadOnly>::EffectiveCalibrated
Map-type for a measurement vector, where the local measurement dimension is variable.
-
using EffectiveCalibratedCovariance = typename TrackStateTraits<M, ReadOnly>::EffectiveCalibratedCovariance
Map-type for a measurement covariance matrix, where the local measurement dimension is variable.
-
using EffectiveProjector = typename TrackStateTraits<M, ReadOnly>::EffectiveProjector
Dynamic variant of the projector matrix.
Warning
Using this type is discouraged, as it has a runtime overhead
-
using IndexType = TrackIndexType
The index type of the track state container.
-
using Parameters = typename TrackStateTraits<M, ReadOnly>::Parameters
Map-type for a bound parameter vector.
This has reference semantics, i.e. points at a matrix by an internal pointer.
-
using Projector = typename TrackStateTraits<M, ReadOnly>::Projector
Matrix representing the projector (measurement mapping function) for a measurement.
This is not a map type, but an actual matrix. This matrix is always \(M \times M\), even if the local measurement dimension is lower. The actual \(N\times M\) projector is given by the top \(N\) rows.
-
using Trajectory = trajectory_t
The track state container backend given as a template parameter.
Public Functions
-
inline const auto &container() const
Get a const reference to the track state container backend.
- Returns:
a const reference to the backend
-
inline auto &container()
requires (!ReadOnly) Get a mutable reference to the track state container backend.
- Returns:
a mutable reference to the backend
-
inline const MultiTrajectory<Trajectory> &trajectory() const
Return a const reference to the underlying backend container.
- Returns:
A const reference to the backend container
-
inline MultiTrajectory<Trajectory> &trajectory()
requires (!ReadOnly) Return a mutable reference to the underlying backend container.
- Returns:
A reference to the backend container
Public Static Attributes
-
static constexpr IndexType kInvalid = kTrackIndexInvalid
Sentinel value that indicates an invalid index.
-
static constexpr bool ReadOnly = read_only
Indicates whether this track state proxy is read-only or if it can be modified.
Friends
- friend class Acts::MultiTrajectory< Trajectory >
-
template<typename derived_t>
class MultiTrajectory Store a trajectory of track states with multiple components.
This container supports both simple, sequential trajectories as well as combinatorial or multi-component trajectories. Each point can store a parent point such that the trajectory forms a directed, acyclic graph of sub-trajectories. From a set of endpoints, all possible sub-components can be easily identified. Some functionality is provided to simplify iterating over specific sub-components.
MultiTrajectory track state iteration
- template<typename F> void visitBackwards(IndexType iendpoint, F &&callable) const requires detail_lt void applyBackwards (IndexType iendpoint, F &&callable) requires(!ReadOnly) &&detail_lt
Visit all previous states starting at a given endpoint.
Note
Only available if the MultiTrajectory is not read-only Range for the track states from
iendpoint
to the trajectory startNote
Const version Range for the track states from
iendpoint
to the trajectory start, i.e from the outside in.Note
Only available if the MultiTrajectory is not read-only
Note
Mutable version
Warning
If the trajectory contains multiple components with common points, this can have an impact on the other components.
- Param iendpoint:
index of the last state
- Param callable:
non-modifying functor to be called with each point Apply a function to all previous states starting at a given endpoint.
- Param iendpoint:
index of the last state
- Param callable:
modifying functor to be called with each point
- Param iendpoint:
Trajectory entry point to start from
- Param iendpoint:
Trajectory entry point to start from
- Return:
Iterator pair to iterate over
- Return:
Iterator pair to iterate over
-
inline auto forwardTrackStateRange(IndexType istartpoint) const
Range for the track states from
istartpoint
to the trajectory end, i.e from inside out.Note
Const version
- Parameters:
istartpoint – Trajectory state index for the innermost track state to start from
- Returns:
Iterator pair to iterate over
-
inline auto forwardTrackStateRange(IndexType istartpoint)
requires (!ReadOnly) Range for the track states from
istartpoint
to the trajectory end, i.e from inside out.Note
Only available if the MultiTrajectory is not read-only
- Parameters:
istartpoint – Trajectory state index for the innermost track state to start from
- Returns:
Iterator pair to iterate over
MultiTrajectory track state (proxy) access and manipulation
These methods allow accessing track states, i.e. adding or retrieving a track state proxy that points at a specific track state in the container.
-
inline ConstTrackStateProxy getTrackState(IndexType istate) const
Access a read-only point on the trajectory by index.
Note
Only available if the MultiTrajectory is not read-only
- Parameters:
istate – The index to access
- Returns:
Read only proxy to the stored track state
-
inline TrackStateProxy getTrackState(IndexType istate)
requires (!ReadOnly) Access a writable point on the trajectory by index.
Note
Only available if the MultiTrajectory is not read-only
- Parameters:
istate – The index to access
- Returns:
Read-write proxy to the stored track state
-
inline IndexType addTrackState(TrackStatePropMask mask = TrackStatePropMask::All, IndexType iprevious = kInvalid)
requires (!ReadOnly) Add a track state without providing explicit information.
Which components of the track state are initialized/allocated can be controlled via
mask
Note
Only available if the MultiTrajectory is not read-only
- Parameters:
mask – The bitmask that instructs which components to allocate and which to leave invalid
iprevious – index of the previous state, kInvalid if first
- Returns:
Index of the newly added track state
-
inline TrackStateProxy makeTrackState(TrackStatePropMask mask = TrackStatePropMask::All, IndexType iprevious = kInvalid)
requires (!ReadOnly) Add a track state to the container and return a track state proxy to it This effectively calls
addTrackState
andgetTrackState
.Note
Only available if the track state container is not read-only
- Returns:
a track state proxy to the newly added track state
MultiTrajectory column management
MultiTrajectory can manage a set of common static columns, and dynamic columns that can be added at runtime.
This set of methods allows you to manage the dynamic columns.
-
template<typename T>
inline void addColumn(std::string_view key)
requires (!ReadOnly) Add a column to the
MultiTrajectory
.Note
This takes a string argument rather than a hashed string to maintain compatibility with backends.
Note
Only available if the MultiTrajectory is not read-only
- Template Parameters:
T – Type of the column values to add
- Parameters:
key – the name of the column to be added
-
inline bool hasColumn(HashedString key) const
Check if a column with a key
key
exists.- Parameters:
key – Key to check for a column with
- Returns:
True if the column exists, false if not.
Public Types
-
using ConstTrackStateProxy = Acts::TrackStateProxy<Derived, MeasurementSizeMax, true>
Alias for the const version of a track state proxy, with the same backends as this container.
-
using Derived = derived_t
-
using IndexType = typename TrackStateProxy::IndexType
The index type of the track state container.
-
using TrackStateProxy = Acts::TrackStateProxy<Derived, MeasurementSizeMax, false>
Alias for the mutable version of a track state proxy, with the same backends as this container.
Public Functions
-
inline void clear()
requires (!ReadOnly) Clear the
MultiTrajectory
.Leaves the underlying storage untouched
Note
Only available if the MultiTrajectory is not read-only
-
inline IndexType size() const
Returns the number of track states contained.
- Returns:
The number of track states
Public Static Attributes
-
static constexpr IndexType kInvalid = TrackStateProxy::kInvalid
Sentinel value that indicates an invalid index.
-
static constexpr unsigned int MeasurementSizeMax = MultiTrajectoryTraits::MeasurementSizeMax
-
static constexpr bool ReadOnly = IsReadOnlyMultiTrajectory<Derived>::value
Friends
- friend class MultiTrajectory
- friend class TrackStateProxy< Derived, MeasurementSizeMax, false >
- friend class TrackStateProxy< Derived, MeasurementSizeMax, true >
Component sharing
Acts::MultiTrajectory
is designed so that components can be shared
between track states. This can be achieved using the
Acts::TrackStateProxy::shareFrom()
can be used to set this up.
Shareable components are
predicted parameters and covariance
filtered parameters and covariance
smoothed parameters and covariance
jacobian
To illustrate why this can be useful, consider again Fig. 21, where \(S_2\) and \(S_3\) branch out from a shared \(S_1\). In this case, the predicted parameter vector and covariance, as well as the jacobian from \(S_1\to S_2\) and \(S_1 \to S_3\) will be identical. In this case, the combinatorial track finding will use the sharing functionality to share these components.
Attention
Sharing these components introduces cross-talk between track states, and this is intentional. If e.g. the predicted covariance is modified through either of the track states, the changes will be visible when accessed from the other track state as well.
Dynamic columns
Aside from the static properties that both the track states and the track have,
the EDM supports adding almost arbitrary additional information as
dynamic columns. The implementation of the dynamic column mechanism is given
by the backend, where the interface layer classes
Acts::MultiTrajectory
and Acts::TrackContainer
and associated
proxies only coordinate the creation, access and copying of dynamic columns.
The following illustrates the
usage of dynamic columns for Acts::TrackContainer
, but usage on
Acts::MultiTrajectory
is identical.
Assume you create a track container using some combination of backends (see Backends shipped with ACTS for information on the backends shipped with ACTS).
Acts::TrackContainer tc{/*...*/};
// add dynamic columns programmatically
tc.addColumn<float>("col_a");
tc.addColumn<uint8_t>("col_b");
Adding columns is only supported on mutable track containers, const track containers should contain the original dynamic columns from when they were created. It is up to the backend to implement recovering dynamic columns from e.g. input files.
Note
Which types are supported depends on the backend being used. See Backends shipped with ACTS for information on the backends shipped with ACTS, and which types they support.
With these dynamic columns registered, it is now possible to set and get values for these columns on tracks.
using namespace Acts::HashedStringLiterals;
auto track = tc.makeTrack();
// these two are equivalent
track.component<float, "col_a"_hash>() = 42.42;
track.component<float>("col_a"_hash) = 52.52;
std::cout << track.component<float, "col_a"_hash>() << std::endl; // prints: 52.52
Tip
The expression "col_a"_hash
is a user-defined literal that internally calls
Acts::hashedString("col_a");
This literal is only available after
using namespace Acts::HashedStringLiterals;
The components are accessed by a hash of the name of the component. This hash
can be calculated from a string at compile-time, if the string is known at
compile time. The difference between the two component access signatures is
that in the first case, the hash of the component is guaranteed to be evaluated
at compile-time, since it is given to the component
function as a template
argument. A third option is available to access components: see
Accessors.
Accessors
It can be inconvenient to have to write the full component access signature, especially if you want to access the same components repeatedly. An alternative are accessors. They encapsulate the type of the component, and the component name hash into an object:
// definition of the accessor with a type and the name of the component
Acts::ProxyAccessor<float> extra("extra");
// component access by calling it on a proxy
extra(track) = 42.2;
std::cout << extra(track) << std::endl; // prints 42.2
Tip
The same accessor also works for Acts::TrackStateProxy
objects, as it shares
the same component access mechanism with Acts::TrackProxy
.
The above accessor is a mutable accessor, meaning it can only be used with mutable proxy objects!
ConstTrackProxy<...> constTrack = /*...*/;
extra(constTrack); // this will give a compile error!
To access properties on const proxy objects, you need to use a dedicated accessor type:
Acts::ConstProxyAccessor<float> extraConst("extra");
std::cout << extraConst(constTrack) << std::endl; // prints 42.2
// using the const accessor on a mutable proxy also works
std::cout << extraConst(track) << std::endl; // prints 42.2
For both const and mutable proxy accessors you do not actually need a mutable reference, as the internal accessor state is not mutated after construction. You can safely use a static instance of these accessors to avoid constructing them over and over again:
template<