schrodinger.ui.qt.atom_weights_table_widget module¶
- class schrodinger.ui.qt.atom_weights_table_widget.AtomWeight(*args, _param_type=<object object>, **kwargs)¶
Bases:
schrodinger.models.parameters.CompoundParam
Represent weight parameters for a single atom.
- atom_number: int¶
Base class for all Param classes. A Param is a descriptor for storing data, which means that a single Param instance will manage the data values for multiple instances of the class that owns it. Example:
class Coord(CompoundParam): x: int y: int
An instance of the Coord class can be created normally, and Params can be accessed as normal attributes:
coord = Coord() coord.x = 4
When a Param value is set, the
valueChanged
signal is emitted. Params can be serialized and deserialized to and from JSON. Params can also be nested:class Atom(CompoundParam): coord: Coord element: str
- element: str¶
Base class for all Param classes. A Param is a descriptor for storing data, which means that a single Param instance will manage the data values for multiple instances of the class that owns it. Example:
class Coord(CompoundParam): x: int y: int
An instance of the Coord class can be created normally, and Params can be accessed as normal attributes:
coord = Coord() coord.x = 4
When a Param value is set, the
valueChanged
signal is emitted. Params can be serialized and deserialized to and from JSON. Params can also be nested:class Atom(CompoundParam): coord: Coord element: str
- pdb_name: str¶
Base class for all Param classes. A Param is a descriptor for storing data, which means that a single Param instance will manage the data values for multiple instances of the class that owns it. Example:
class Coord(CompoundParam): x: int y: int
An instance of the Coord class can be created normally, and Params can be accessed as normal attributes:
coord = Coord() coord.x = 4
When a Param value is set, the
valueChanged
signal is emitted. Params can be serialized and deserialized to and from JSON. Params can also be nested:class Atom(CompoundParam): coord: Coord element: str
- weight: float¶
Base class for all Param classes. A Param is a descriptor for storing data, which means that a single Param instance will manage the data values for multiple instances of the class that owns it. Example:
class Coord(CompoundParam): x: int y: int
An instance of the Coord class can be created normally, and Params can be accessed as normal attributes:
coord = Coord() coord.x = 4
When a Param value is set, the
valueChanged
signal is emitted. Params can be serialized and deserialized to and from JSON. Params can also be nested:class Atom(CompoundParam): coord: Coord element: str
- atom_numberChanged¶
pyqtSignal(*types, name: str = …, revision: int = …, arguments: Sequence = …) -> PYQT_SIGNAL
types is normally a sequence of individual types. Each type is either a type object or a string that is the name of a C++ type. Alternatively each type could itself be a sequence of types each describing a different overloaded signal. name is the optional C++ name of the signal. If it is not specified then the name of the class attribute that is bound to the signal is used. revision is the optional revision of the signal that is exported to QML. If it is not specified then 0 is used. arguments is the optional sequence of the names of the signal’s arguments.
- atom_numberReplaced¶
pyqtSignal(*types, name: str = …, revision: int = …, arguments: Sequence = …) -> PYQT_SIGNAL
types is normally a sequence of individual types. Each type is either a type object or a string that is the name of a C++ type. Alternatively each type could itself be a sequence of types each describing a different overloaded signal. name is the optional C++ name of the signal. If it is not specified then the name of the class attribute that is bound to the signal is used. revision is the optional revision of the signal that is exported to QML. If it is not specified then 0 is used. arguments is the optional sequence of the names of the signal’s arguments.
- elementChanged¶
pyqtSignal(*types, name: str = …, revision: int = …, arguments: Sequence = …) -> PYQT_SIGNAL
types is normally a sequence of individual types. Each type is either a type object or a string that is the name of a C++ type. Alternatively each type could itself be a sequence of types each describing a different overloaded signal. name is the optional C++ name of the signal. If it is not specified then the name of the class attribute that is bound to the signal is used. revision is the optional revision of the signal that is exported to QML. If it is not specified then 0 is used. arguments is the optional sequence of the names of the signal’s arguments.
- elementReplaced¶
pyqtSignal(*types, name: str = …, revision: int = …, arguments: Sequence = …) -> PYQT_SIGNAL
types is normally a sequence of individual types. Each type is either a type object or a string that is the name of a C++ type. Alternatively each type could itself be a sequence of types each describing a different overloaded signal. name is the optional C++ name of the signal. If it is not specified then the name of the class attribute that is bound to the signal is used. revision is the optional revision of the signal that is exported to QML. If it is not specified then 0 is used. arguments is the optional sequence of the names of the signal’s arguments.
- pdb_nameChanged¶
pyqtSignal(*types, name: str = …, revision: int = …, arguments: Sequence = …) -> PYQT_SIGNAL
types is normally a sequence of individual types. Each type is either a type object or a string that is the name of a C++ type. Alternatively each type could itself be a sequence of types each describing a different overloaded signal. name is the optional C++ name of the signal. If it is not specified then the name of the class attribute that is bound to the signal is used. revision is the optional revision of the signal that is exported to QML. If it is not specified then 0 is used. arguments is the optional sequence of the names of the signal’s arguments.
- pdb_nameReplaced¶
pyqtSignal(*types, name: str = …, revision: int = …, arguments: Sequence = …) -> PYQT_SIGNAL
types is normally a sequence of individual types. Each type is either a type object or a string that is the name of a C++ type. Alternatively each type could itself be a sequence of types each describing a different overloaded signal. name is the optional C++ name of the signal. If it is not specified then the name of the class attribute that is bound to the signal is used. revision is the optional revision of the signal that is exported to QML. If it is not specified then 0 is used. arguments is the optional sequence of the names of the signal’s arguments.
- weightChanged¶
pyqtSignal(*types, name: str = …, revision: int = …, arguments: Sequence = …) -> PYQT_SIGNAL
types is normally a sequence of individual types. Each type is either a type object or a string that is the name of a C++ type. Alternatively each type could itself be a sequence of types each describing a different overloaded signal. name is the optional C++ name of the signal. If it is not specified then the name of the class attribute that is bound to the signal is used. revision is the optional revision of the signal that is exported to QML. If it is not specified then 0 is used. arguments is the optional sequence of the names of the signal’s arguments.
- weightReplaced¶
pyqtSignal(*types, name: str = …, revision: int = …, arguments: Sequence = …) -> PYQT_SIGNAL
types is normally a sequence of individual types. Each type is either a type object or a string that is the name of a C++ type. Alternatively each type could itself be a sequence of types each describing a different overloaded signal. name is the optional C++ name of the signal. If it is not specified then the name of the class attribute that is bound to the signal is used. revision is the optional revision of the signal that is exported to QML. If it is not specified then 0 is used. arguments is the optional sequence of the names of the signal’s arguments.
- class schrodinger.ui.qt.atom_weights_table_widget.AtomWeightsSpec(*args, _param_type=<object object>, **kwargs)¶
Bases:
schrodinger.ui.qt.mapperwidgets.plptable.TableSpec
Table spec for the custom weights.
- atom_number = <schrodinger.ui.qt.mapperwidgets.plptable.FieldColumn object>¶
- element = <schrodinger.ui.qt.mapperwidgets.plptable.FieldColumn object>¶
- pdb_name = <schrodinger.ui.qt.mapperwidgets.plptable.FieldColumn object>¶
- weight = <schrodinger.ui.qt.mapperwidgets.plptable.FieldColumn object>¶
- sort_role(field)¶
- weight_font(weight)¶
- weight_color(weight)¶
- columnsChanged¶
pyqtSignal(*types, name: str = …, revision: int = …, arguments: Sequence = …) -> PYQT_SIGNAL
types is normally a sequence of individual types. Each type is either a type object or a string that is the name of a C++ type. Alternatively each type could itself be a sequence of types each describing a different overloaded signal. name is the optional C++ name of the signal. If it is not specified then the name of the class attribute that is bound to the signal is used. revision is the optional revision of the signal that is exported to QML. If it is not specified then 0 is used. arguments is the optional sequence of the names of the signal’s arguments.
- columnsReplaced¶
pyqtSignal(*types, name: str = …, revision: int = …, arguments: Sequence = …) -> PYQT_SIGNAL
types is normally a sequence of individual types. Each type is either a type object or a string that is the name of a C++ type. Alternatively each type could itself be a sequence of types each describing a different overloaded signal. name is the optional C++ name of the signal. If it is not specified then the name of the class attribute that is bound to the signal is used. revision is the optional revision of the signal that is exported to QML. If it is not specified then 0 is used. arguments is the optional sequence of the names of the signal’s arguments.
- class schrodinger.ui.qt.atom_weights_table_widget.AtomWeightsTableWidget(*args, **kwargs)¶
Bases:
schrodinger.ui.qt.mapperwidgets.plptable.PLPTableWidget
Table to display atom weights data.
- __init__(*args, **kwargs)¶
- Parameters
spec (TableSpec) – Table specification. Will be ignored if autospec is True.
autospec (bool) – Whether to automatically generate the table specification from the PLP item fields.
plp (parameters.ParamListParam) – ParamListParam containing data. It is more common to set the plp using mappers.
view (QtWidgets.QTableView) – Custom table view instance. If None, an instance of table_helper.SampleDataTableView will be created.
- class schrodinger.ui.qt.atom_weights_table_widget.AtomWeightsSettings(*args, _param_type=<object object>, **kwargs)¶
Bases:
schrodinger.models.parameters.CompoundParam
Class for storing Custom Weight Options. Contains all logic for updating the table data and spheres.
- allow_custom_weights: bool¶
Base class for all Param classes. A Param is a descriptor for storing data, which means that a single Param instance will manage the data values for multiple instances of the class that owns it. Example:
class Coord(CompoundParam): x: int y: int
An instance of the Coord class can be created normally, and Params can be accessed as normal attributes:
coord = Coord() coord.x = 4
When a Param value is set, the
valueChanged
signal is emitted. Params can be serialized and deserialized to and from JSON. Params can also be nested:class Atom(CompoundParam): coord: Coord element: str
- use_custom_weights: bool¶
Base class for all Param classes. A Param is a descriptor for storing data, which means that a single Param instance will manage the data values for multiple instances of the class that owns it. Example:
class Coord(CompoundParam): x: int y: int
An instance of the Coord class can be created normally, and Params can be accessed as normal attributes:
coord = Coord() coord.x = 4
When a Param value is set, the
valueChanged
signal is emitted. Params can be serialized and deserialized to and from JSON. Params can also be nested:class Atom(CompoundParam): coord: Coord element: str
- default_weight: float¶
Base class for all Param classes. A Param is a descriptor for storing data, which means that a single Param instance will manage the data values for multiple instances of the class that owns it. Example:
class Coord(CompoundParam): x: int y: int
An instance of the Coord class can be created normally, and Params can be accessed as normal attributes:
coord = Coord() coord.x = 4
When a Param value is set, the
valueChanged
signal is emitted. Params can be serialized and deserialized to and from JSON. Params can also be nested:class Atom(CompoundParam): coord: Coord element: str
- custom_weight: float¶
Base class for all Param classes. A Param is a descriptor for storing data, which means that a single Param instance will manage the data values for multiple instances of the class that owns it. Example:
class Coord(CompoundParam): x: int y: int
An instance of the Coord class can be created normally, and Params can be accessed as normal attributes:
coord = Coord() coord.x = 4
When a Param value is set, the
valueChanged
signal is emitted. Params can be serialized and deserialized to and from JSON. Params can also be nested:class Atom(CompoundParam): coord: Coord element: str
- atom_weights: List[schrodinger.ui.qt.atom_weights_table_widget.AtomWeight]¶
A list param that contains
CompoundParam
instances. Signals will be emitted any time an item in the list changes or the contents of the list itself change. See_SignalContainer
and_PLPSignalContainer
for information on specific signals.
- selected_weights: List[schrodinger.ui.qt.atom_weights_table_widget.AtomWeight]¶
A list param that contains
CompoundParam
instances. Signals will be emitted any time an item in the list changes or the contents of the list itself change. See_SignalContainer
and_PLPSignalContainer
for information on specific signals.
- template_stsChanged¶
pyqtSignal(*types, name: str = …, revision: int = …, arguments: Sequence = …) -> PYQT_SIGNAL
types is normally a sequence of individual types. Each type is either a type object or a string that is the name of a C++ type. Alternatively each type could itself be a sequence of types each describing a different overloaded signal. name is the optional C++ name of the signal. If it is not specified then the name of the class attribute that is bound to the signal is used. revision is the optional revision of the signal that is exported to QML. If it is not specified then 0 is used. arguments is the optional sequence of the names of the signal’s arguments.
- initConcrete()¶
Override to customize initialization of concrete params.
- property template_sts: List[schrodinger.structure._structure.Structure]¶
- property template_st: Optional[schrodinger.structure._structure.Structure]¶
Return the first template structure or None.
- updateAtomWeights()¶
Clear the table model and then add a row for each atom in the current template_st.
- applyDefaultWeight()¶
Apply the default weights to all rows that haven’t been assigned a custom weight, and update all spheres.
- applyCustomWeight()¶
Apply the custom weight to currently selected rows and update all spheres.
- addWeightPropsToTemplateStructures(weight_property: str)¶
Add
weight_property
as a property to the atoms in all template structures.- Parameters
weight_property – the name of the associated weight property
- allow_custom_weightsChanged¶
pyqtSignal(*types, name: str = …, revision: int = …, arguments: Sequence = …) -> PYQT_SIGNAL
types is normally a sequence of individual types. Each type is either a type object or a string that is the name of a C++ type. Alternatively each type could itself be a sequence of types each describing a different overloaded signal. name is the optional C++ name of the signal. If it is not specified then the name of the class attribute that is bound to the signal is used. revision is the optional revision of the signal that is exported to QML. If it is not specified then 0 is used. arguments is the optional sequence of the names of the signal’s arguments.
- allow_custom_weightsReplaced¶
pyqtSignal(*types, name: str = …, revision: int = …, arguments: Sequence = …) -> PYQT_SIGNAL
types is normally a sequence of individual types. Each type is either a type object or a string that is the name of a C++ type. Alternatively each type could itself be a sequence of types each describing a different overloaded signal. name is the optional C++ name of the signal. If it is not specified then the name of the class attribute that is bound to the signal is used. revision is the optional revision of the signal that is exported to QML. If it is not specified then 0 is used. arguments is the optional sequence of the names of the signal’s arguments.
- atom_weightsChanged¶
pyqtSignal(*types, name: str = …, revision: int = …, arguments: Sequence = …) -> PYQT_SIGNAL
types is normally a sequence of individual types. Each type is either a type object or a string that is the name of a C++ type. Alternatively each type could itself be a sequence of types each describing a different overloaded signal. name is the optional C++ name of the signal. If it is not specified then the name of the class attribute that is bound to the signal is used. revision is the optional revision of the signal that is exported to QML. If it is not specified then 0 is used. arguments is the optional sequence of the names of the signal’s arguments.
- atom_weightsReplaced¶
pyqtSignal(*types, name: str = …, revision: int = …, arguments: Sequence = …) -> PYQT_SIGNAL
types is normally a sequence of individual types. Each type is either a type object or a string that is the name of a C++ type. Alternatively each type could itself be a sequence of types each describing a different overloaded signal. name is the optional C++ name of the signal. If it is not specified then the name of the class attribute that is bound to the signal is used. revision is the optional revision of the signal that is exported to QML. If it is not specified then 0 is used. arguments is the optional sequence of the names of the signal’s arguments.
- custom_weightChanged¶
pyqtSignal(*types, name: str = …, revision: int = …, arguments: Sequence = …) -> PYQT_SIGNAL
types is normally a sequence of individual types. Each type is either a type object or a string that is the name of a C++ type. Alternatively each type could itself be a sequence of types each describing a different overloaded signal. name is the optional C++ name of the signal. If it is not specified then the name of the class attribute that is bound to the signal is used. revision is the optional revision of the signal that is exported to QML. If it is not specified then 0 is used. arguments is the optional sequence of the names of the signal’s arguments.
- custom_weightReplaced¶
pyqtSignal(*types, name: str = …, revision: int = …, arguments: Sequence = …) -> PYQT_SIGNAL
types is normally a sequence of individual types. Each type is either a type object or a string that is the name of a C++ type. Alternatively each type could itself be a sequence of types each describing a different overloaded signal. name is the optional C++ name of the signal. If it is not specified then the name of the class attribute that is bound to the signal is used. revision is the optional revision of the signal that is exported to QML. If it is not specified then 0 is used. arguments is the optional sequence of the names of the signal’s arguments.
- default_weightChanged¶
pyqtSignal(*types, name: str = …, revision: int = …, arguments: Sequence = …) -> PYQT_SIGNAL
types is normally a sequence of individual types. Each type is either a type object or a string that is the name of a C++ type. Alternatively each type could itself be a sequence of types each describing a different overloaded signal. name is the optional C++ name of the signal. If it is not specified then the name of the class attribute that is bound to the signal is used. revision is the optional revision of the signal that is exported to QML. If it is not specified then 0 is used. arguments is the optional sequence of the names of the signal’s arguments.
- default_weightReplaced¶
pyqtSignal(*types, name: str = …, revision: int = …, arguments: Sequence = …) -> PYQT_SIGNAL
types is normally a sequence of individual types. Each type is either a type object or a string that is the name of a C++ type. Alternatively each type could itself be a sequence of types each describing a different overloaded signal. name is the optional C++ name of the signal. If it is not specified then the name of the class attribute that is bound to the signal is used. revision is the optional revision of the signal that is exported to QML. If it is not specified then 0 is used. arguments is the optional sequence of the names of the signal’s arguments.
- selected_weightsChanged¶
pyqtSignal(*types, name: str = …, revision: int = …, arguments: Sequence = …) -> PYQT_SIGNAL
types is normally a sequence of individual types. Each type is either a type object or a string that is the name of a C++ type. Alternatively each type could itself be a sequence of types each describing a different overloaded signal. name is the optional C++ name of the signal. If it is not specified then the name of the class attribute that is bound to the signal is used. revision is the optional revision of the signal that is exported to QML. If it is not specified then 0 is used. arguments is the optional sequence of the names of the signal’s arguments.
- selected_weightsReplaced¶
pyqtSignal(*types, name: str = …, revision: int = …, arguments: Sequence = …) -> PYQT_SIGNAL
types is normally a sequence of individual types. Each type is either a type object or a string that is the name of a C++ type. Alternatively each type could itself be a sequence of types each describing a different overloaded signal. name is the optional C++ name of the signal. If it is not specified then the name of the class attribute that is bound to the signal is used. revision is the optional revision of the signal that is exported to QML. If it is not specified then 0 is used. arguments is the optional sequence of the names of the signal’s arguments.
- use_custom_weightsChanged¶
pyqtSignal(*types, name: str = …, revision: int = …, arguments: Sequence = …) -> PYQT_SIGNAL
types is normally a sequence of individual types. Each type is either a type object or a string that is the name of a C++ type. Alternatively each type could itself be a sequence of types each describing a different overloaded signal. name is the optional C++ name of the signal. If it is not specified then the name of the class attribute that is bound to the signal is used. revision is the optional revision of the signal that is exported to QML. If it is not specified then 0 is used. arguments is the optional sequence of the names of the signal’s arguments.
- use_custom_weightsReplaced¶
pyqtSignal(*types, name: str = …, revision: int = …, arguments: Sequence = …) -> PYQT_SIGNAL
types is normally a sequence of individual types. Each type is either a type object or a string that is the name of a C++ type. Alternatively each type could itself be a sequence of types each describing a different overloaded signal. name is the optional C++ name of the signal. If it is not specified then the name of the class attribute that is bound to the signal is used. revision is the optional revision of the signal that is exported to QML. If it is not specified then 0 is used. arguments is the optional sequence of the names of the signal’s arguments.
- class schrodinger.ui.qt.atom_weights_table_widget.WeightSphereManager¶
Bases:
schrodinger.models.mappers.MapperMixin
Manages 3D spheres representing atom weights of each individual atoms in AtomWeightsSettings.
- model_class¶
alias of
schrodinger.ui.qt.atom_weights_table_widget.AtomWeightsSettings
- OPACITY_DEFAULT = 0.4¶
- OPACITY_SELECTED = 1.0¶
- COLOR_DEFAULT = (0.5, 0.5, 1.0)¶
- COLOR_SELECTED = (1.0, 1.0, 0.0)¶
- RESOLUTION_DEFAULT = 50¶
- __init__()¶
- defineMappings()¶
Override this in the subclass to define mappings. Should return a list of tuples [(<target>, <param>)]. Targets can be:
a basic widget, like
QLineEdit
orQComboBox
a custom object that inherits
MapperMixin
orTargetMixin
a
TargetSpec
instancea slot
For common widgets, standard signals and getter/setter methods will be used, as defined in
mappers._get_default_access_names()
.For more fine-grained custom control, instantiate a
TargetSpec
object, which allows custom setters, getters, and signals to be specified.Supplying a slot as the first element of the tuple is equivalent to providing
TargetSpec(slot=my_slot)
.Note that all target slots are triggered on
setModel()
as well as in response to the specified signal.The param is an abstract param reference, e.g. MyModel.my_param.
Example:
def defineMappings(self): combo = self.style_combo return [(self.name_le, MyModel.name), (TargetSpec(combo, getter=combo.currentText, setter=combo.setCurrentText), MyModel.style), (self.coord_widget, MyModel.coord), (self._onASLTextChanged, MyModel.asl_text)]
- getSignalsAndSlots(model)¶
Override this method to specify signal and slot pairs that need to be connected/disconnected whenever the model instance is switched using setModel. The model instance is provided as an argument so that instance-specific signals can be used, but any pairs of signals and slots may be returned from this method.
- Returns
a list of 2-tuples where each tuple is a signal, slot pair
- updateSpheres()¶
Clear all spheres and, if necessary, create a sphere for each row in the atom weights table with appropriate colors.
- clearSpheres()¶
Delete all spheres from the sphere group. Clears all spheres in the WS.
- class schrodinger.ui.qt.atom_weights_table_widget.AtomWeightsWidget(*args, **kwargs)¶
Bases:
schrodinger.models.mappers.MapperMixin
,schrodinger.ui.qt.basewidgets.BaseWidget
A widget for the custom weights table. User can specify default and custom weights for the atoms and then use the values to run their custom job with an additional WEIGHT_PROPERTY.
Initially, set the template structures using setTemplateStructures() method. To add weights to the template structures, call addWeightPropsToTemplateStructures() with the WEIGHT_PROPERTY.
Atom weights can be visualized with sphere markers in the workspace by instantiating this alongside
WeightSphereManager
and mapping both views to the same model.All the params of
AtomWeightsSettings
need to be synced up with the parent widget for an ideal arrangement.- model_class¶
alias of
schrodinger.ui.qt.atom_weights_table_widget.AtomWeightsSettings
- ui_module = <module 'schrodinger.ui.qt.atom_weights_table_ui' from '/scr/buildbot/savedbuilds/2024-3/NB/build-133/internal/lib/python3.11/site-packages/schrodinger/ui/qt/atom_weights_table_ui.py'>¶
- ATOM_WEIGHTS = [0, 0.25, 0.5, 0.75, 1]¶
- initSetUp()¶
Creates widget from
ui
and stores itui_widget
.Suggested subclass use: create and initialize subwidgets, and connect signals.
- initLayOut()¶
@overrides: widgetmixins.InitMixin
- defineMappings()¶
Override this in the subclass to define mappings. Should return a list of tuples [(<target>, <param>)]. Targets can be:
a basic widget, like
QLineEdit
orQComboBox
a custom object that inherits
MapperMixin
orTargetMixin
a
TargetSpec
instancea slot
For common widgets, standard signals and getter/setter methods will be used, as defined in
mappers._get_default_access_names()
.For more fine-grained custom control, instantiate a
TargetSpec
object, which allows custom setters, getters, and signals to be specified.Supplying a slot as the first element of the tuple is equivalent to providing
TargetSpec(slot=my_slot)
.Note that all target slots are triggered on
setModel()
as well as in response to the specified signal.The param is an abstract param reference, e.g. MyModel.my_param.
Example:
def defineMappings(self): combo = self.style_combo return [(self.name_le, MyModel.name), (TargetSpec(combo, getter=combo.currentText, setter=combo.setCurrentText), MyModel.style), (self.coord_widget, MyModel.coord), (self._onASLTextChanged, MyModel.asl_text)]
- property template_sts: List[schrodinger.structure._structure.Structure]¶
Return the list of template structures currently held in the model.
- setTemplateStructures(template_sts: List[schrodinger.structure._structure.Structure])¶
Set the model’s template structures as
template_sts
or [] if query is an*.ivol
file, and determine whether the get_ws_selection_btn should be enabled.- Parameters
template_sts – Structures to apply custom atom weights to.
- addWeightPropsToTemplateStructures(weight_property)¶
Add weight_property as a property to the atoms in all template structures.
- Parameters
weight_property (str) – the name of the associated weight property