schrodinger.application.steps.docking module

class schrodinger.application.steps.docking.GlideSettings(*args, _param_type=<object object>, **kwargs)

Bases: schrodinger.models.parameters.CompoundParam

The glide_in_file input file should not have a LIGANDFILE keyword. The POSES_PER_LIG will be overridden with the value of 1, since we need to know whether the molecule can dock, and what the best docking score is.

glide_grid_file: schrodinger.tasks.stepper.StepperFile

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

glide_ref_ligand_file: schrodinger.tasks.stepper.StepperFile

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

glide_in_file: schrodinger.tasks.stepper.StepperFile

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

validate(step)

Validate the settings for use in step.

Parameters

step – stepper._BaseStep

Return type

list[TaskError or TaskWarning]

DataClass

This class can be used to declare a public attribute on a CompoundParam. Declared public attributes can be used without error.

Example usage:

class Coord(CompoundParam):
    x: int
    y: int
    note = NonParamAttribute()

coord = Coord()
coord.note = "hello" # No error

__init__(default_value=<object object>, _param_type=<object object>, **kwargs)

Initialize self. See help(type(self)) for accurate signature.

classmethod addSubParam(name, param, update_owner=True)

blockSignals(self, bool) → bool

block_signal_propagation()

childEvent(self, QChildEvent)

children(self) → List[QObject]

classmethod configureParam()

Override this class method to set up the abstract param class (e.g. setParamReference on child params.)

connectNotify(self, QMetaMethod)

customEvent(self, QEvent)

classmethod defaultValue(*args, **kwargs)

deleteLater(self)

destroyed

destroyed(self, object: QObject = None) [signal]

disconnect(self)

disconnectNotify(self, QMetaMethod)

dumpObjectInfo(self)

dumpObjectTree(self)

dynamicPropertyNames(self) → List[QByteArray]

event(self, QEvent) → bool

eventFilter(self, QObject, QEvent) → bool

findChild(self, type, name: str = '', options: Union[Qt.FindChildOptions, Qt.FindChildOption] = Qt.FindChildrenRecursively) → QObject

findChild(self, Tuple, name: str = ‘’, options: Union[Qt.FindChildOptions, Qt.FindChildOption] = Qt.FindChildrenRecursively) -> QObject

findChildren(self, type, name: str = '', options: Union[Qt.FindChildOptions, Qt.FindChildOption] = Qt.FindChildrenRecursively) → List[QObject]

findChildren(self, Tuple, name: str = ‘’, options: Union[Qt.FindChildOptions, Qt.FindChildOption] = Qt.FindChildrenRecursively) -> List[QObject] findChildren(self, type, QRegExp, options: Union[Qt.FindChildOptions, Qt.FindChildOption] = Qt.FindChildrenRecursively) -> List[QObject] findChildren(self, Tuple, QRegExp, options: Union[Qt.FindChildOptions, Qt.FindChildOption] = Qt.FindChildrenRecursively) -> List[QObject] findChildren(self, type, QRegularExpression, options: Union[Qt.FindChildOptions, Qt.FindChildOption] = Qt.FindChildrenRecursively) -> List[QObject] findChildren(self, Tuple, QRegularExpression, options: Union[Qt.FindChildOptions, Qt.FindChildOption] = Qt.FindChildrenRecursively) -> List[QObject]

classmethod fromJson(json_obj)

A factory method which constructs a new object from a given dict loaded from a json string or file.

Parameters

json_obj (dict) – A json-loaded dictionary to create an object from.

Returns

An instance of this class.

Return type

cls

classmethod fromJsonImplementation(json_dict)

Sets the value of this compound param value object from a JSON dict.

Warning

This should never be called directly.

getAbstractParam(*args, **kwargs)

classmethod getJsonBlacklist()

Override to customize what params are serialized.

Implementations should return a list of abstract params that should be omitted from serialization.

..NOTE

Returned abstract params must be direct child params of cls, e.g. cls.name, not cls.coord.x.

classmethod getParamSignal(*args, **kwargs)

classmethod getParamValue(*args, **kwargs)

classmethod getSubParam(name)

Get the value of a subparam using the string name:

c = Coord()
assert c.getSubParam('x') == 0

Note

Using the string name to access params is generally discouraged, but can be useful for serializing/deserializing param data.

Parameters

name (str) – The name of the subparam to get the value for.

classmethod getSubParams()

Return a dictionary mapping subparam names to their values.

getTypeHint()

get_version()

Method to get the version of a particular object. Defaults to the current version of mmshare. This class can be overridden for custom versioning behavior.

glide_grid_fileChanged

glide_grid_fileReplaced

glide_in_fileChanged

glide_in_fileReplaced

glide_ref_ligand_fileChanged

glide_ref_ligand_fileReplaced

inherits(self, str) → bool

initAbstract()

initConcrete()

Override to customize initialization of concrete params.

initializeValue()

Override to dynamically set up the default value of the param. Useful for default values that are determined at runtime. This is called any time the param is reset.

installEventFilter(self, QObject)

classmethod isAbstract()

Whether the param is an “abstract” param.

isDefault(*args, **kwargs)

isSignalConnected(self, QMetaMethod) → bool

isWidgetType(self) → bool

isWindowType(self) → bool

killTimer(self, int)

metaObject(self) → QMetaObject

moveToThread(self, QThread)

objectName(self) → str

objectNameChanged

objectNameChanged(self, str) [signal]

classmethod owner()

Get the owner of the param:

# Can be called on an abstract param:
assert Coord.x.owner() == Coord

# ...or on an instance of a CompoundParam
a = Atom()
assert a.coord.owner() == a

classmethod ownerChain()

Returns a list of param owners starting from the toplevel param and ending with self. Examples:

foo.bar.atom.coord.ownerChain() will return [foo, bar, atom, coord] where every item is a concrete param.

Foo.bar.atom.coord.x.ownerChain() will return [Foo, Foo.bar, Foo.atom.coord, Foo.atom.coord.x] where every item is an abstract params.

classmethod paramName()

Get the name of the param:

# Can be called on an abstract param:
print(Coord.x.paramName()) # 'x'

# ...or on an instance of a CompoundParam
a = Atom()
a.coord.paramName() # 'coord'

parent(self) → QObject

property(self, str) → Any

pyqtConfigure(...)

Each keyword argument is either the name of a Qt property or a Qt signal. For properties the property is set to the given value which should be of an appropriate type. For signals the signal is connected to the given value which should be a callable.

receivers(self, PYQT_SIGNAL) → int

removeEventFilter(self, QObject)

reset(*args, **kwargs)

sender(self) → QObject

senderSignalIndex(self) → int

setObjectName(self, str)

classmethod setParamValue(*args, **kwargs)

setParent(self, QObject)

setProperty(self, str, Any) → bool

classmethod setReference(param1, param2)

Call this class method from configureParam to indicate that two params should be kept in sync. The initial values will start with the default value of param1. Example:

class Square(CompoundParam):
    width: float = 5
    height: float = 10

    @classmethod
    def configureParam(cls):
        super().configureParam()
        cls.setReference(cls.width, cls.height)

square = Square()
assert square.width == square.height == 5 # Default value of width
                                          # takes priority
square.height = 7
assert square.width == square.height == 7
square.width = 6
assert square.width == square.height == 6

Parameters

• param1 – The first abstract param to keep synced

• param2 – The second abstract param. After instantiation, this param will take on the value of param1.

setValue(*args, **kwargs)

signalsBlocked(self) → bool

skip_eq_check()

startTimer(self, int, timerType: Qt.TimerType = Qt.CoarseTimer) → int

staticMetaObject = <PyQt5.QtCore.QMetaObject object>

thread(self) → QThread

timerEvent(self, QTimerEvent)

toDict(*args, **kwargs)

toJson(_mark_version=True)

Create and returns a data structure made up of jsonable items.

Return type

An instance of one the classes from NATIVE_JSON_DATATYPES

toJsonImplementation(*args, **kwargs)

Abstract method that must be defined by all derived classes. Converts an instance of the derived class into a jsonifiable object.

Returns

A dict made up of JSON native datatypes or Jsonable objects. See the link below for a table of such types. https://docs.python.org/2/library/json.html#encoders-and-decoders

tr(self, str, disambiguation: str = None, n: int = - 1) → str

valueChanged

class schrodinger.application.steps.docking.GlideDocker(*args, **kwargs)

Bases: schrodinger.application.steps.docking._MolDockerMixin, schrodinger.application.steps.basesteps.MolMapStep

Perform a glide docking step.

Only yields the original input molecule if at least 1 pose is found with a score less than or equal to the settings’ max_score.

Note: it is not the docked Mol in the ScoredMol that is yielded.

GLIDE_SERVER_START_TASK_CLASS

alias of _GlideServerStartTask

class Settings(*args, _param_type=<object object>, **kwargs)

Bases: schrodinger.application.steps.docking.GlideSettings

max_score: 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

DataClass

This class can be used to declare a public attribute on a CompoundParam. Declared public attributes can be used without error.

Example usage:

class Coord(CompoundParam):
    x: int
    y: int
    note = NonParamAttribute()

coord = Coord()
coord.note = "hello" # No error

__init__(default_value=<object object>, _param_type=<object object>, **kwargs)

Initialize self. See help(type(self)) for accurate signature.

classmethod addSubParam(name, param, update_owner=True)

blockSignals(self, bool) → bool

block_signal_propagation()

childEvent(self, QChildEvent)

children(self) → List[QObject]

classmethod configureParam()

Override this class method to set up the abstract param class (e.g. setParamReference on child params.)

connectNotify(self, QMetaMethod)

customEvent(self, QEvent)

classmethod defaultValue(*args, **kwargs)

deleteLater(self)

destroyed

destroyed(self, object: QObject = None) [signal]

disconnect(self)

disconnectNotify(self, QMetaMethod)

dumpObjectInfo(self)

dumpObjectTree(self)

dynamicPropertyNames(self) → List[QByteArray]

event(self, QEvent) → bool

eventFilter(self, QObject, QEvent) → bool

findChild(self, type, name: str = '', options: Union[Qt.FindChildOptions, Qt.FindChildOption] = Qt.FindChildrenRecursively) → QObject

findChild(self, Tuple, name: str = ‘’, options: Union[Qt.FindChildOptions, Qt.FindChildOption] = Qt.FindChildrenRecursively) -> QObject

findChildren(self, type, name: str = '', options: Union[Qt.FindChildOptions, Qt.FindChildOption] = Qt.FindChildrenRecursively) → List[QObject]

findChildren(self, Tuple, name: str = ‘’, options: Union[Qt.FindChildOptions, Qt.FindChildOption] = Qt.FindChildrenRecursively) -> List[QObject] findChildren(self, type, QRegExp, options: Union[Qt.FindChildOptions, Qt.FindChildOption] = Qt.FindChildrenRecursively) -> List[QObject] findChildren(self, Tuple, QRegExp, options: Union[Qt.FindChildOptions, Qt.FindChildOption] = Qt.FindChildrenRecursively) -> List[QObject] findChildren(self, type, QRegularExpression, options: Union[Qt.FindChildOptions, Qt.FindChildOption] = Qt.FindChildrenRecursively) -> List[QObject] findChildren(self, Tuple, QRegularExpression, options: Union[Qt.FindChildOptions, Qt.FindChildOption] = Qt.FindChildrenRecursively) -> List[QObject]

classmethod fromJson(json_obj)

A factory method which constructs a new object from a given dict loaded from a json string or file.

Parameters

json_obj (dict) – A json-loaded dictionary to create an object from.

Returns

An instance of this class.

Return type

cls

classmethod fromJsonImplementation(json_dict)

Sets the value of this compound param value object from a JSON dict.

Warning

This should never be called directly.

getAbstractParam(*args, **kwargs)

classmethod getJsonBlacklist()

Override to customize what params are serialized.

Implementations should return a list of abstract params that should be omitted from serialization.

..NOTE

Returned abstract params must be direct child params of cls, e.g. cls.name, not cls.coord.x.

classmethod getParamSignal(*args, **kwargs)

classmethod getParamValue(*args, **kwargs)

classmethod getSubParam(name)

Get the value of a subparam using the string name:

c = Coord()
assert c.getSubParam('x') == 0

Note

Using the string name to access params is generally discouraged, but can be useful for serializing/deserializing param data.

Parameters

name (str) – The name of the subparam to get the value for.

classmethod getSubParams()

Return a dictionary mapping subparam names to their values.

getTypeHint()

get_version()

Method to get the version of a particular object. Defaults to the current version of mmshare. This class can be overridden for custom versioning behavior.

glide_grid_file: schrodinger.tasks.stepper.StepperFile

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

glide_grid_fileChanged

glide_grid_fileReplaced

glide_in_file: schrodinger.tasks.stepper.StepperFile

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

glide_in_fileChanged

glide_in_fileReplaced

glide_ref_ligand_file: schrodinger.tasks.stepper.StepperFile

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

glide_ref_ligand_fileChanged

glide_ref_ligand_fileReplaced

inherits(self, str) → bool

initAbstract()

initConcrete()

Override to customize initialization of concrete params.

initializeValue()

Override to dynamically set up the default value of the param. Useful for default values that are determined at runtime. This is called any time the param is reset.

installEventFilter(self, QObject)

classmethod isAbstract()

Whether the param is an “abstract” param.

isDefault(*args, **kwargs)

isSignalConnected(self, QMetaMethod) → bool

isWidgetType(self) → bool

isWindowType(self) → bool

killTimer(self, int)

max_scoreChanged

max_scoreReplaced

metaObject(self) → QMetaObject

moveToThread(self, QThread)

objectName(self) → str

objectNameChanged

objectNameChanged(self, str) [signal]

classmethod owner()

Get the owner of the param:

# Can be called on an abstract param:
assert Coord.x.owner() == Coord

# ...or on an instance of a CompoundParam
a = Atom()
assert a.coord.owner() == a

classmethod ownerChain()

Returns a list of param owners starting from the toplevel param and ending with self. Examples:

foo.bar.atom.coord.ownerChain() will return [foo, bar, atom, coord] where every item is a concrete param.

Foo.bar.atom.coord.x.ownerChain() will return [Foo, Foo.bar, Foo.atom.coord, Foo.atom.coord.x] where every item is an abstract params.

classmethod paramName()

Get the name of the param:

# Can be called on an abstract param:
print(Coord.x.paramName()) # 'x'

# ...or on an instance of a CompoundParam
a = Atom()
a.coord.paramName() # 'coord'

parent(self) → QObject

property(self, str) → Any

pyqtConfigure(...)

Each keyword argument is either the name of a Qt property or a Qt signal. For properties the property is set to the given value which should be of an appropriate type. For signals the signal is connected to the given value which should be a callable.

receivers(self, PYQT_SIGNAL) → int

removeEventFilter(self, QObject)

reset(*args, **kwargs)

sender(self) → QObject

senderSignalIndex(self) → int

setObjectName(self, str)

classmethod setParamValue(*args, **kwargs)

setParent(self, QObject)

setProperty(self, str, Any) → bool

classmethod setReference(param1, param2)

Call this class method from configureParam to indicate that two params should be kept in sync. The initial values will start with the default value of param1. Example:

class Square(CompoundParam):
    width: float = 5
    height: float = 10

    @classmethod
    def configureParam(cls):
        super().configureParam()
        cls.setReference(cls.width, cls.height)

square = Square()
assert square.width == square.height == 5 # Default value of width
                                          # takes priority
square.height = 7
assert square.width == square.height == 7
square.width = 6
assert square.width == square.height == 6

Parameters

• param1 – The first abstract param to keep synced

• param2 – The second abstract param. After instantiation, this param will take on the value of param1.

setValue(*args, **kwargs)

signalsBlocked(self) → bool

skip_eq_check()

startTimer(self, int, timerType: Qt.TimerType = Qt.CoarseTimer) → int

staticMetaObject = <PyQt5.QtCore.QMetaObject object>

thread(self) → QThread

timerEvent(self, QTimerEvent)

toDict(*args, **kwargs)

toJson(_mark_version=True)

Create and returns a data structure made up of jsonable items.

Return type

An instance of one the classes from NATIVE_JSON_DATATYPES

toJsonImplementation(*args, **kwargs)

Abstract method that must be defined by all derived classes. Converts an instance of the derived class into a jsonifiable object.

Returns

A dict made up of JSON native datatypes or Jsonable objects. See the link below for a table of such types. https://docs.python.org/2/library/json.html#encoders-and-decoders

tr(self, str, disambiguation: str = None, n: int = - 1) → str

validate(step)

Validate the settings for use in step.

Parameters

step – stepper._BaseStep

Return type

list[TaskError or TaskWarning]

valueChanged

mapFunction(mol)

Input

alias of rdkit.Chem.rdchem.Mol

InputSerializer

alias of schrodinger.application.steps.dataclasses.MolToSmilesSerializer

Output

alias of rdkit.Chem.rdchem.Mol

OutputSerializer

alias of schrodinger.application.steps.dataclasses.MolToSmilesSerializer

__init__(*args, **kwargs)

Initialize self. See help(type(self)) for accurate signature.

blockSignals(self, bool) → bool

childEvent(self, QChildEvent)

children(self) → List[QObject]

cleanUp()

Hook for adding any type of work that needs to happen after all outputs are exhausted or if some outputs are created and the step is destroyed.

cleanUpTables()

connectNotify(self, QMetaMethod)

customEvent(self, QEvent)

deleteLater(self)

destroyed

destroyed(self, object: QObject = None) [signal]

disconnect(self)

disconnectNotify(self, QMetaMethod)

dumpObjectInfo(self)

dumpObjectTree(self)

dynamicPropertyNames(self) → List[QByteArray]

event(self, QEvent) → bool

eventFilter(self, QObject, QEvent) → bool

findChild(self, type, name: str = '', options: Union[Qt.FindChildOptions, Qt.FindChildOption] = Qt.FindChildrenRecursively) → QObject

findChild(self, Tuple, name: str = ‘’, options: Union[Qt.FindChildOptions, Qt.FindChildOption] = Qt.FindChildrenRecursively) -> QObject

findChildren(self, type, name: str = '', options: Union[Qt.FindChildOptions, Qt.FindChildOption] = Qt.FindChildrenRecursively) → List[QObject]

findChildren(self, Tuple, name: str = ‘’, options: Union[Qt.FindChildOptions, Qt.FindChildOption] = Qt.FindChildrenRecursively) -> List[QObject] findChildren(self, type, QRegExp, options: Union[Qt.FindChildOptions, Qt.FindChildOption] = Qt.FindChildrenRecursively) -> List[QObject] findChildren(self, Tuple, QRegExp, options: Union[Qt.FindChildOptions, Qt.FindChildOption] = Qt.FindChildrenRecursively) -> List[QObject] findChildren(self, type, QRegularExpression, options: Union[Qt.FindChildOptions, Qt.FindChildOption] = Qt.FindChildrenRecursively) -> List[QObject] findChildren(self, Tuple, QRegularExpression, options: Union[Qt.FindChildOptions, Qt.FindChildOption] = Qt.FindChildrenRecursively) -> List[QObject]

getDocker()

Returns

the singleton glide server manager

Return type

http_client.GlideServerManager

getLicenseRequirements()

getOutputSerializer()

getOutputs()

Gets all the outputs in a list by fully iterating the output generator.

getRunInfo()

getStepId()

inherits(self, str) → bool

inputs()

installEventFilter(self, QObject)

isBigQueryBatched()

isSignalConnected(self, QMetaMethod) → bool

isWidgetType(self) → bool

isWindowType(self) → bool

static is_bq_step(step)

killTimer(self, int)

metaObject(self) → QMetaObject

moveToThread(self, QThread)

objectName(self) → str

objectNameChanged

objectNameChanged(self, str) [signal]

outputs(*args, **kwargs)

parent(self) → QObject

prettyPrintRunInfo()

Format and print info about the step’s run.

progressUpdated

property(self, str) → Any

pyqtConfigure(...)

Each keyword argument is either the name of a Qt property or a Qt signal. For properties the property is set to the given value which should be of an appropriate type. For signals the signal is connected to the given value which should be a callable.

receivers(self, PYQT_SIGNAL) → int

reduceFunction(inputs)

The main computation for this step. This function should take in a iterable of inputs and return an iterable of outputs.

Example:

def reduceFunction(self, words):
    # Find all unique words
    seen_words = set()
    for word in words:
        if word not in seen_words:
            seen_words.add(word)
            yield word

removeEventFilter(self, QObject)

report(prefix='')

Report the settings and batch settings for this step.

sender(self) → QObject

senderSignalIndex(self) → int

setBatchSettings(*args, **kwargs)

setInputBQTable(bq_table, bq_dataset=None)

setInputFile(fname)

setInputs(*args, **kwargs)

setObjectName(self, str)

setOutputBQTable(bq_table)

setParent(self, QObject)

setProperty(self, str, Any) → bool

setSettings(*args, **kwargs)

setUp()

Hook for adding any type of work that needs to happen before any outputs are created.

signalsBlocked(self) → bool

startTimer(self, int, timerType: Qt.TimerType = Qt.CoarseTimer) → int

staticMetaObject = <PyQt5.QtCore.QMetaObject object>

thread(self) → QThread

timerEvent(self, QTimerEvent)

tr(self, str, disambiguation: str = None, n: int = - 1) → str

validateSettings()

Check whether the step settings are valid and return a list of SettingsError and SettingsWarning to report any invalid settings. Default implementation checks that all stepper files are set to valid file paths.

Return type

list[TaskError or TaskWarning]

writeOutputsToFile(fname)

Write outputs to fname. By default, the output file will consist of one line for each output with whatever is produced when passing the out- put to str. Override this method if more complex behavior is needed.

writeOutputsToTable()

class schrodinger.application.steps.docking.MaeGlideDocker(*args, **kwargs)

Bases: schrodinger.application.steps.docking._MolDockerMixin, schrodinger.application.steps.basesteps.MaeMapStep

Perform a glide docking step, yielding the best scored pose for the input structure.

GLIDE_SERVER_START_TASK_CLASS

alias of _GlideServerStartTask

class Settings(*args, _param_type=<object object>, **kwargs)

Bases: schrodinger.application.steps.docking.GlideSettings

max_score: 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

DataClass

This class can be used to declare a public attribute on a CompoundParam. Declared public attributes can be used without error.

Example usage:

class Coord(CompoundParam):
    x: int
    y: int
    note = NonParamAttribute()

coord = Coord()
coord.note = "hello" # No error

__init__(default_value=<object object>, _param_type=<object object>, **kwargs)

Initialize self. See help(type(self)) for accurate signature.

classmethod addSubParam(name, param, update_owner=True)

blockSignals(self, bool) → bool

block_signal_propagation()

childEvent(self, QChildEvent)

children(self) → List[QObject]

classmethod configureParam()

Override this class method to set up the abstract param class (e.g. setParamReference on child params.)

connectNotify(self, QMetaMethod)

customEvent(self, QEvent)

classmethod defaultValue(*args, **kwargs)

deleteLater(self)

destroyed

destroyed(self, object: QObject = None) [signal]

disconnect(self)

disconnectNotify(self, QMetaMethod)

dumpObjectInfo(self)

dumpObjectTree(self)

dynamicPropertyNames(self) → List[QByteArray]

event(self, QEvent) → bool

eventFilter(self, QObject, QEvent) → bool

findChild(self, type, name: str = '', options: Union[Qt.FindChildOptions, Qt.FindChildOption] = Qt.FindChildrenRecursively) → QObject

findChild(self, Tuple, name: str = ‘’, options: Union[Qt.FindChildOptions, Qt.FindChildOption] = Qt.FindChildrenRecursively) -> QObject

findChildren(self, type, name: str = '', options: Union[Qt.FindChildOptions, Qt.FindChildOption] = Qt.FindChildrenRecursively) → List[QObject]

findChildren(self, Tuple, name: str = ‘’, options: Union[Qt.FindChildOptions, Qt.FindChildOption] = Qt.FindChildrenRecursively) -> List[QObject] findChildren(self, type, QRegExp, options: Union[Qt.FindChildOptions, Qt.FindChildOption] = Qt.FindChildrenRecursively) -> List[QObject] findChildren(self, Tuple, QRegExp, options: Union[Qt.FindChildOptions, Qt.FindChildOption] = Qt.FindChildrenRecursively) -> List[QObject] findChildren(self, type, QRegularExpression, options: Union[Qt.FindChildOptions, Qt.FindChildOption] = Qt.FindChildrenRecursively) -> List[QObject] findChildren(self, Tuple, QRegularExpression, options: Union[Qt.FindChildOptions, Qt.FindChildOption] = Qt.FindChildrenRecursively) -> List[QObject]

classmethod fromJson(json_obj)

A factory method which constructs a new object from a given dict loaded from a json string or file.

Parameters

json_obj (dict) – A json-loaded dictionary to create an object from.

Returns

An instance of this class.

Return type

cls

classmethod fromJsonImplementation(json_dict)

Sets the value of this compound param value object from a JSON dict.

Warning

This should never be called directly.

getAbstractParam(*args, **kwargs)

classmethod getJsonBlacklist()

Override to customize what params are serialized.

Implementations should return a list of abstract params that should be omitted from serialization.

..NOTE

Returned abstract params must be direct child params of cls, e.g. cls.name, not cls.coord.x.

classmethod getParamSignal(*args, **kwargs)

classmethod getParamValue(*args, **kwargs)

classmethod getSubParam(name)

Get the value of a subparam using the string name:

c = Coord()
assert c.getSubParam('x') == 0

Note

Using the string name to access params is generally discouraged, but can be useful for serializing/deserializing param data.

Parameters

name (str) – The name of the subparam to get the value for.

classmethod getSubParams()

Return a dictionary mapping subparam names to their values.

getTypeHint()

get_version()

Method to get the version of a particular object. Defaults to the current version of mmshare. This class can be overridden for custom versioning behavior.

glide_grid_file: schrodinger.tasks.stepper.StepperFile

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

glide_grid_fileChanged

glide_grid_fileReplaced

glide_in_file: schrodinger.tasks.stepper.StepperFile

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

glide_in_fileChanged

glide_in_fileReplaced

glide_ref_ligand_file: schrodinger.tasks.stepper.StepperFile

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

glide_ref_ligand_fileChanged

glide_ref_ligand_fileReplaced

inherits(self, str) → bool

initAbstract()

initConcrete()

Override to customize initialization of concrete params.

initializeValue()

Override to dynamically set up the default value of the param. Useful for default values that are determined at runtime. This is called any time the param is reset.

installEventFilter(self, QObject)

classmethod isAbstract()

Whether the param is an “abstract” param.

isDefault(*args, **kwargs)

isSignalConnected(self, QMetaMethod) → bool

isWidgetType(self) → bool

isWindowType(self) → bool

killTimer(self, int)

max_scoreChanged

max_scoreReplaced

metaObject(self) → QMetaObject

moveToThread(self, QThread)

objectName(self) → str

objectNameChanged

objectNameChanged(self, str) [signal]

classmethod owner()

Get the owner of the param:

# Can be called on an abstract param:
assert Coord.x.owner() == Coord

# ...or on an instance of a CompoundParam
a = Atom()
assert a.coord.owner() == a

classmethod ownerChain()

Returns a list of param owners starting from the toplevel param and ending with self. Examples:

foo.bar.atom.coord.ownerChain() will return [foo, bar, atom, coord] where every item is a concrete param.

Foo.bar.atom.coord.x.ownerChain() will return [Foo, Foo.bar, Foo.atom.coord, Foo.atom.coord.x] where every item is an abstract params.

classmethod paramName()

Get the name of the param:

# Can be called on an abstract param:
print(Coord.x.paramName()) # 'x'

# ...or on an instance of a CompoundParam
a = Atom()
a.coord.paramName() # 'coord'

parent(self) → QObject

property(self, str) → Any

pyqtConfigure(...)

Each keyword argument is either the name of a Qt property or a Qt signal. For properties the property is set to the given value which should be of an appropriate type. For signals the signal is connected to the given value which should be a callable.

receivers(self, PYQT_SIGNAL) → int

removeEventFilter(self, QObject)

reset(*args, **kwargs)

sender(self) → QObject

senderSignalIndex(self) → int

setObjectName(self, str)

classmethod setParamValue(*args, **kwargs)

setParent(self, QObject)

setProperty(self, str, Any) → bool

classmethod setReference(param1, param2)

Call this class method from configureParam to indicate that two params should be kept in sync. The initial values will start with the default value of param1. Example:

class Square(CompoundParam):
    width: float = 5
    height: float = 10

    @classmethod
    def configureParam(cls):
        super().configureParam()
        cls.setReference(cls.width, cls.height)

square = Square()
assert square.width == square.height == 5 # Default value of width
                                          # takes priority
square.height = 7
assert square.width == square.height == 7
square.width = 6
assert square.width == square.height == 6

Parameters

• param1 – The first abstract param to keep synced

• param2 – The second abstract param. After instantiation, this param will take on the value of param1.

setValue(*args, **kwargs)

signalsBlocked(self) → bool

skip_eq_check()

startTimer(self, int, timerType: Qt.TimerType = Qt.CoarseTimer) → int

staticMetaObject = <PyQt5.QtCore.QMetaObject object>

thread(self) → QThread

timerEvent(self, QTimerEvent)

toDict(*args, **kwargs)

toJson(_mark_version=True)

Create and returns a data structure made up of jsonable items.

Return type

An instance of one the classes from NATIVE_JSON_DATATYPES

toJsonImplementation(*args, **kwargs)

Abstract method that must be defined by all derived classes. Converts an instance of the derived class into a jsonifiable object.

Returns

A dict made up of JSON native datatypes or Jsonable objects. See the link below for a table of such types. https://docs.python.org/2/library/json.html#encoders-and-decoders

tr(self, str, disambiguation: str = None, n: int = - 1) → str

validate(step)

Validate the settings for use in step.

Parameters

step – stepper._BaseStep

Return type

list[TaskError or TaskWarning]

valueChanged

mapFunction(struc)

Input

alias of schrodinger.structure._structure.Structure

InputSerializer

alias of schrodinger.tasks.stepper._DynamicSerializer

Output

alias of schrodinger.structure._structure.Structure

OutputSerializer

alias of schrodinger.tasks.stepper._DynamicSerializer

__init__(*args, **kwargs)

Initialize self. See help(type(self)) for accurate signature.

blockSignals(self, bool) → bool

childEvent(self, QChildEvent)

children(self) → List[QObject]

cleanUp()

Hook for adding any type of work that needs to happen after all outputs are exhausted or if some outputs are created and the step is destroyed.

cleanUpTables()

connectNotify(self, QMetaMethod)

customEvent(self, QEvent)

deleteLater(self)

destroyed

destroyed(self, object: QObject = None) [signal]

disconnect(self)

disconnectNotify(self, QMetaMethod)

dumpObjectInfo(self)

dumpObjectTree(self)

dynamicPropertyNames(self) → List[QByteArray]

event(self, QEvent) → bool

eventFilter(self, QObject, QEvent) → bool

findChild(self, type, name: str = '', options: Union[Qt.FindChildOptions, Qt.FindChildOption] = Qt.FindChildrenRecursively) → QObject

findChild(self, Tuple, name: str = ‘’, options: Union[Qt.FindChildOptions, Qt.FindChildOption] = Qt.FindChildrenRecursively) -> QObject

findChildren(self, type, name: str = '', options: Union[Qt.FindChildOptions, Qt.FindChildOption] = Qt.FindChildrenRecursively) → List[QObject]

findChildren(self, Tuple, name: str = ‘’, options: Union[Qt.FindChildOptions, Qt.FindChildOption] = Qt.FindChildrenRecursively) -> List[QObject] findChildren(self, type, QRegExp, options: Union[Qt.FindChildOptions, Qt.FindChildOption] = Qt.FindChildrenRecursively) -> List[QObject] findChildren(self, Tuple, QRegExp, options: Union[Qt.FindChildOptions, Qt.FindChildOption] = Qt.FindChildrenRecursively) -> List[QObject] findChildren(self, type, QRegularExpression, options: Union[Qt.FindChildOptions, Qt.FindChildOption] = Qt.FindChildrenRecursively) -> List[QObject] findChildren(self, Tuple, QRegularExpression, options: Union[Qt.FindChildOptions, Qt.FindChildOption] = Qt.FindChildrenRecursively) -> List[QObject]

getDocker()

Returns

the singleton glide server manager

Return type

http_client.GlideServerManager

getLicenseRequirements()

getOutputSerializer()

getOutputs()

Gets all the outputs in a list by fully iterating the output generator.

getRunInfo()

getStepId()

inherits(self, str) → bool

inputs()

installEventFilter(self, QObject)

isBigQueryBatched()

isSignalConnected(self, QMetaMethod) → bool

isWidgetType(self) → bool

isWindowType(self) → bool

static is_bq_step(step)

killTimer(self, int)

metaObject(self) → QMetaObject

moveToThread(self, QThread)

objectName(self) → str

objectNameChanged

objectNameChanged(self, str) [signal]

outputs(*args, **kwargs)

parent(self) → QObject

prettyPrintRunInfo()

Format and print info about the step’s run.

progressUpdated

property(self, str) → Any

pyqtConfigure(...)

Each keyword argument is either the name of a Qt property or a Qt signal. For properties the property is set to the given value which should be of an appropriate type. For signals the signal is connected to the given value which should be a callable.

receivers(self, PYQT_SIGNAL) → int

reduceFunction(inputs)

The main computation for this step. This function should take in a iterable of inputs and return an iterable of outputs.

Example:

def reduceFunction(self, words):
    # Find all unique words
    seen_words = set()
    for word in words:
        if word not in seen_words:
            seen_words.add(word)
            yield word

removeEventFilter(self, QObject)

report(prefix='')

Report the settings and batch settings for this step.

sender(self) → QObject

senderSignalIndex(self) → int

setBatchSettings(*args, **kwargs)

setInputBQTable(bq_table, bq_dataset=None)

setInputFile(fname)

setInputs(*args, **kwargs)

setObjectName(self, str)

setOutputBQTable(bq_table)

setParent(self, QObject)

setProperty(self, str, Any) → bool

setSettings(*args, **kwargs)

setUp()

Hook for adding any type of work that needs to happen before any outputs are created.

signalsBlocked(self) → bool

startTimer(self, int, timerType: Qt.TimerType = Qt.CoarseTimer) → int

staticMetaObject = <PyQt5.QtCore.QMetaObject object>

thread(self) → QThread

timerEvent(self, QTimerEvent)

tr(self, str, disambiguation: str = None, n: int = - 1) → str

validateSettings()

Check whether the step settings are valid and return a list of SettingsError and SettingsWarning to report any invalid settings. Default implementation checks that all stepper files are set to valid file paths.

Return type

list[TaskError or TaskWarning]

writeOutputsToFile(fname)

Write outputs to fname. By default, the output file will consist of one line for each output with whatever is produced when passing the out- put to str. Override this method if more complex behavior is needed.

writeOutputsToTable()

class schrodinger.application.steps.docking.SmilesDockerSettings(*args, _param_type=<object object>, **kwargs)

Bases: schrodinger.application.steps.docking.GlideSettings

arg_string: 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

ligprep_filter_file: schrodinger.tasks.stepper.StepperFile

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

validate(step)

Validate the settings for use in step.

Parameters

step – stepper._BaseStep

Return type

list[TaskError or TaskWarning]

DataClass

This class can be used to declare a public attribute on a CompoundParam. Declared public attributes can be used without error.

Example usage:

class Coord(CompoundParam):
    x: int
    y: int
    note = NonParamAttribute()

coord = Coord()
coord.note = "hello" # No error

__init__(default_value=<object object>, _param_type=<object object>, **kwargs)

Initialize self. See help(type(self)) for accurate signature.

classmethod addSubParam(name, param, update_owner=True)

arg_stringChanged

arg_stringReplaced

blockSignals(self, bool) → bool

block_signal_propagation()

childEvent(self, QChildEvent)

children(self) → List[QObject]

classmethod configureParam()

Override this class method to set up the abstract param class (e.g. setParamReference on child params.)

connectNotify(self, QMetaMethod)

customEvent(self, QEvent)

classmethod defaultValue(*args, **kwargs)

deleteLater(self)

destroyed

destroyed(self, object: QObject = None) [signal]

disconnect(self)

disconnectNotify(self, QMetaMethod)

dumpObjectInfo(self)

dumpObjectTree(self)

dynamicPropertyNames(self) → List[QByteArray]

event(self, QEvent) → bool

eventFilter(self, QObject, QEvent) → bool

findChild(self, type, name: str = '', options: Union[Qt.FindChildOptions, Qt.FindChildOption] = Qt.FindChildrenRecursively) → QObject

findChild(self, Tuple, name: str = ‘’, options: Union[Qt.FindChildOptions, Qt.FindChildOption] = Qt.FindChildrenRecursively) -> QObject

findChildren(self, type, name: str = '', options: Union[Qt.FindChildOptions, Qt.FindChildOption] = Qt.FindChildrenRecursively) → List[QObject]

findChildren(self, Tuple, name: str = ‘’, options: Union[Qt.FindChildOptions, Qt.FindChildOption] = Qt.FindChildrenRecursively) -> List[QObject] findChildren(self, type, QRegExp, options: Union[Qt.FindChildOptions, Qt.FindChildOption] = Qt.FindChildrenRecursively) -> List[QObject] findChildren(self, Tuple, QRegExp, options: Union[Qt.FindChildOptions, Qt.FindChildOption] = Qt.FindChildrenRecursively) -> List[QObject] findChildren(self, type, QRegularExpression, options: Union[Qt.FindChildOptions, Qt.FindChildOption] = Qt.FindChildrenRecursively) -> List[QObject] findChildren(self, Tuple, QRegularExpression, options: Union[Qt.FindChildOptions, Qt.FindChildOption] = Qt.FindChildrenRecursively) -> List[QObject]

classmethod fromJson(json_obj)

A factory method which constructs a new object from a given dict loaded from a json string or file.

Parameters

json_obj (dict) – A json-loaded dictionary to create an object from.

Returns

An instance of this class.

Return type

cls

classmethod fromJsonImplementation(json_dict)

Sets the value of this compound param value object from a JSON dict.

Warning

This should never be called directly.

getAbstractParam(*args, **kwargs)

classmethod getJsonBlacklist()

Override to customize what params are serialized.

Implementations should return a list of abstract params that should be omitted from serialization.

..NOTE

Returned abstract params must be direct child params of cls, e.g. cls.name, not cls.coord.x.

classmethod getParamSignal(*args, **kwargs)

classmethod getParamValue(*args, **kwargs)

classmethod getSubParam(name)

Get the value of a subparam using the string name:

c = Coord()
assert c.getSubParam('x') == 0

Note

Using the string name to access params is generally discouraged, but can be useful for serializing/deserializing param data.

Parameters

name (str) – The name of the subparam to get the value for.

classmethod getSubParams()

Return a dictionary mapping subparam names to their values.

getTypeHint()

get_version()

Method to get the version of a particular object. Defaults to the current version of mmshare. This class can be overridden for custom versioning behavior.

glide_grid_file: schrodinger.tasks.stepper.StepperFile

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

glide_grid_fileChanged

glide_grid_fileReplaced

glide_in_file: schrodinger.tasks.stepper.StepperFile

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

glide_in_fileChanged

glide_in_fileReplaced

glide_ref_ligand_file: schrodinger.tasks.stepper.StepperFile

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

glide_ref_ligand_fileChanged

glide_ref_ligand_fileReplaced

inherits(self, str) → bool

initAbstract()

initConcrete()

Override to customize initialization of concrete params.

initializeValue()

Override to dynamically set up the default value of the param. Useful for default values that are determined at runtime. This is called any time the param is reset.

installEventFilter(self, QObject)

classmethod isAbstract()

Whether the param is an “abstract” param.

isDefault(*args, **kwargs)

isSignalConnected(self, QMetaMethod) → bool

isWidgetType(self) → bool

isWindowType(self) → bool

killTimer(self, int)

ligprep_filter_fileChanged

ligprep_filter_fileReplaced

metaObject(self) → QMetaObject

moveToThread(self, QThread)

objectName(self) → str

objectNameChanged

objectNameChanged(self, str) [signal]

classmethod owner()

Get the owner of the param:

# Can be called on an abstract param:
assert Coord.x.owner() == Coord

# ...or on an instance of a CompoundParam
a = Atom()
assert a.coord.owner() == a

classmethod ownerChain()

Returns a list of param owners starting from the toplevel param and ending with self. Examples:

foo.bar.atom.coord.ownerChain() will return [foo, bar, atom, coord] where every item is a concrete param.

Foo.bar.atom.coord.x.ownerChain() will return [Foo, Foo.bar, Foo.atom.coord, Foo.atom.coord.x] where every item is an abstract params.

classmethod paramName()

Get the name of the param:

# Can be called on an abstract param:
print(Coord.x.paramName()) # 'x'

# ...or on an instance of a CompoundParam
a = Atom()
a.coord.paramName() # 'coord'

parent(self) → QObject

property(self, str) → Any

pyqtConfigure(...)

Each keyword argument is either the name of a Qt property or a Qt signal. For properties the property is set to the given value which should be of an appropriate type. For signals the signal is connected to the given value which should be a callable.

receivers(self, PYQT_SIGNAL) → int

removeEventFilter(self, QObject)

reset(*args, **kwargs)

sender(self) → QObject

senderSignalIndex(self) → int

setObjectName(self, str)

classmethod setParamValue(*args, **kwargs)

setParent(self, QObject)

setProperty(self, str, Any) → bool

classmethod setReference(param1, param2)

Call this class method from configureParam to indicate that two params should be kept in sync. The initial values will start with the default value of param1. Example:

class Square(CompoundParam):
    width: float = 5
    height: float = 10

    @classmethod
    def configureParam(cls):
        super().configureParam()
        cls.setReference(cls.width, cls.height)

square = Square()
assert square.width == square.height == 5 # Default value of width
                                          # takes priority
square.height = 7
assert square.width == square.height == 7
square.width = 6
assert square.width == square.height == 6

Parameters

• param1 – The first abstract param to keep synced

• param2 – The second abstract param. After instantiation, this param will take on the value of param1.

setValue(*args, **kwargs)

signalsBlocked(self) → bool

skip_eq_check()

startTimer(self, int, timerType: Qt.TimerType = Qt.CoarseTimer) → int

staticMetaObject = <PyQt5.QtCore.QMetaObject object>

thread(self) → QThread

timerEvent(self, QTimerEvent)

toDict(*args, **kwargs)

toJson(_mark_version=True)

Create and returns a data structure made up of jsonable items.

Return type

An instance of one the classes from NATIVE_JSON_DATATYPES

toJsonImplementation(*args, **kwargs)

Abstract method that must be defined by all derived classes. Converts an instance of the derived class into a jsonifiable object.

Returns

A dict made up of JSON native datatypes or Jsonable objects. See the link below for a table of such types. https://docs.python.org/2/library/json.html#encoders-and-decoders

tr(self, str, disambiguation: str = None, n: int = - 1) → str

valueChanged

class schrodinger.application.steps.docking.SmilesDocker(*args, **kwargs)

Bases: schrodinger.application.steps.docking._MolDockerMixin, schrodinger.application.steps.basesteps.MolMapStep

Perform a ligprep with glide docking step. This step will yield the molecules and their glide score value as ScoredMol objects only for molecules that had a score that is less than or equal to the max_score in the settings.

Since to ligprep may generate different tautomers the same molecule may be yielded more than once.

GLIDE_SERVER_START_TASK_CLASS

alias of _SmilesGlideServerStartTask

class Settings(*args, _param_type=<object object>, **kwargs)

Bases: schrodinger.application.steps.docking.SmilesDockerSettings

max_score: 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

DataClass

This class can be used to declare a public attribute on a CompoundParam. Declared public attributes can be used without error.

Example usage:

class Coord(CompoundParam):
    x: int
    y: int
    note = NonParamAttribute()

coord = Coord()
coord.note = "hello" # No error

__init__(default_value=<object object>, _param_type=<object object>, **kwargs)

Initialize self. See help(type(self)) for accurate signature.

classmethod addSubParam(name, param, update_owner=True)

arg_string: 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

arg_stringChanged

arg_stringReplaced

blockSignals(self, bool) → bool

block_signal_propagation()

childEvent(self, QChildEvent)

children(self) → List[QObject]

classmethod configureParam()

Override this class method to set up the abstract param class (e.g. setParamReference on child params.)

connectNotify(self, QMetaMethod)

customEvent(self, QEvent)

classmethod defaultValue(*args, **kwargs)

deleteLater(self)

destroyed

destroyed(self, object: QObject = None) [signal]

disconnect(self)

disconnectNotify(self, QMetaMethod)

dumpObjectInfo(self)

dumpObjectTree(self)

dynamicPropertyNames(self) → List[QByteArray]

event(self, QEvent) → bool

eventFilter(self, QObject, QEvent) → bool

findChild(self, type, name: str = '', options: Union[Qt.FindChildOptions, Qt.FindChildOption] = Qt.FindChildrenRecursively) → QObject

findChild(self, Tuple, name: str = ‘’, options: Union[Qt.FindChildOptions, Qt.FindChildOption] = Qt.FindChildrenRecursively) -> QObject

findChildren(self, type, name: str = '', options: Union[Qt.FindChildOptions, Qt.FindChildOption] = Qt.FindChildrenRecursively) → List[QObject]

findChildren(self, Tuple, name: str = ‘’, options: Union[Qt.FindChildOptions, Qt.FindChildOption] = Qt.FindChildrenRecursively) -> List[QObject] findChildren(self, type, QRegExp, options: Union[Qt.FindChildOptions, Qt.FindChildOption] = Qt.FindChildrenRecursively) -> List[QObject] findChildren(self, Tuple, QRegExp, options: Union[Qt.FindChildOptions, Qt.FindChildOption] = Qt.FindChildrenRecursively) -> List[QObject] findChildren(self, type, QRegularExpression, options: Union[Qt.FindChildOptions, Qt.FindChildOption] = Qt.FindChildrenRecursively) -> List[QObject] findChildren(self, Tuple, QRegularExpression, options: Union[Qt.FindChildOptions, Qt.FindChildOption] = Qt.FindChildrenRecursively) -> List[QObject]

classmethod fromJson(json_obj)

A factory method which constructs a new object from a given dict loaded from a json string or file.

Parameters

json_obj (dict) – A json-loaded dictionary to create an object from.

Returns

An instance of this class.

Return type

cls

classmethod fromJsonImplementation(json_dict)

Sets the value of this compound param value object from a JSON dict.

Warning

This should never be called directly.

getAbstractParam(*args, **kwargs)

classmethod getJsonBlacklist()

Override to customize what params are serialized.

Implementations should return a list of abstract params that should be omitted from serialization.

..NOTE

Returned abstract params must be direct child params of cls, e.g. cls.name, not cls.coord.x.

classmethod getParamSignal(*args, **kwargs)

classmethod getParamValue(*args, **kwargs)

classmethod getSubParam(name)

Get the value of a subparam using the string name:

c = Coord()
assert c.getSubParam('x') == 0

Note

Using the string name to access params is generally discouraged, but can be useful for serializing/deserializing param data.

Parameters

name (str) – The name of the subparam to get the value for.

classmethod getSubParams()

Return a dictionary mapping subparam names to their values.

getTypeHint()

get_version()

Method to get the version of a particular object. Defaults to the current version of mmshare. This class can be overridden for custom versioning behavior.

glide_grid_file: schrodinger.tasks.stepper.StepperFile

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

glide_grid_fileChanged

glide_grid_fileReplaced

glide_in_file: schrodinger.tasks.stepper.StepperFile

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

glide_in_fileChanged

glide_in_fileReplaced

glide_ref_ligand_file: schrodinger.tasks.stepper.StepperFile

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

glide_ref_ligand_fileChanged

glide_ref_ligand_fileReplaced

inherits(self, str) → bool

initAbstract()

initConcrete()

Override to customize initialization of concrete params.

initializeValue()

Override to dynamically set up the default value of the param. Useful for default values that are determined at runtime. This is called any time the param is reset.

installEventFilter(self, QObject)

classmethod isAbstract()

Whether the param is an “abstract” param.

isDefault(*args, **kwargs)

isSignalConnected(self, QMetaMethod) → bool

isWidgetType(self) → bool

isWindowType(self) → bool

killTimer(self, int)

ligprep_filter_file: schrodinger.tasks.stepper.StepperFile

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

ligprep_filter_fileChanged

ligprep_filter_fileReplaced

max_scoreChanged

max_scoreReplaced

metaObject(self) → QMetaObject

moveToThread(self, QThread)

objectName(self) → str

objectNameChanged

objectNameChanged(self, str) [signal]

classmethod owner()

Get the owner of the param:

# Can be called on an abstract param:
assert Coord.x.owner() == Coord

# ...or on an instance of a CompoundParam
a = Atom()
assert a.coord.owner() == a

classmethod ownerChain()

Returns a list of param owners starting from the toplevel param and ending with self. Examples:

foo.bar.atom.coord.ownerChain() will return [foo, bar, atom, coord] where every item is a concrete param.

Foo.bar.atom.coord.x.ownerChain() will return [Foo, Foo.bar, Foo.atom.coord, Foo.atom.coord.x] where every item is an abstract params.

classmethod paramName()

Get the name of the param:

# Can be called on an abstract param:
print(Coord.x.paramName()) # 'x'

# ...or on an instance of a CompoundParam
a = Atom()
a.coord.paramName() # 'coord'

parent(self) → QObject

property(self, str) → Any

pyqtConfigure(...)

Each keyword argument is either the name of a Qt property or a Qt signal. For properties the property is set to the given value which should be of an appropriate type. For signals the signal is connected to the given value which should be a callable.

receivers(self, PYQT_SIGNAL) → int

removeEventFilter(self, QObject)

reset(*args, **kwargs)

sender(self) → QObject

senderSignalIndex(self) → int

setObjectName(self, str)

classmethod setParamValue(*args, **kwargs)

setParent(self, QObject)

setProperty(self, str, Any) → bool

classmethod setReference(param1, param2)

Call this class method from configureParam to indicate that two params should be kept in sync. The initial values will start with the default value of param1. Example:

class Square(CompoundParam):
    width: float = 5
    height: float = 10

    @classmethod
    def configureParam(cls):
        super().configureParam()
        cls.setReference(cls.width, cls.height)

square = Square()
assert square.width == square.height == 5 # Default value of width
                                          # takes priority
square.height = 7
assert square.width == square.height == 7
square.width = 6
assert square.width == square.height == 6

Parameters

• param1 – The first abstract param to keep synced

• param2 – The second abstract param. After instantiation, this param will take on the value of param1.

setValue(*args, **kwargs)

signalsBlocked(self) → bool

skip_eq_check()

startTimer(self, int, timerType: Qt.TimerType = Qt.CoarseTimer) → int

staticMetaObject = <PyQt5.QtCore.QMetaObject object>

thread(self) → QThread

timerEvent(self, QTimerEvent)

toDict(*args, **kwargs)

toJson(_mark_version=True)

Create and returns a data structure made up of jsonable items.

Return type

An instance of one the classes from NATIVE_JSON_DATATYPES

toJsonImplementation(*args, **kwargs)

Abstract method that must be defined by all derived classes. Converts an instance of the derived class into a jsonifiable object.

Returns

A dict made up of JSON native datatypes or Jsonable objects. See the link below for a table of such types. https://docs.python.org/2/library/json.html#encoders-and-decoders

tr(self, str, disambiguation: str = None, n: int = - 1) → str

validate(step)

Validate the settings for use in step.

Parameters

step – stepper._BaseStep

Return type

list[TaskError or TaskWarning]

valueChanged

setUp()

Hook for adding any type of work that needs to happen before any outputs are created.

mapFunction(mol)

Input

alias of rdkit.Chem.rdchem.Mol

InputSerializer

alias of schrodinger.application.steps.dataclasses.MolToSmilesSerializer

Output

alias of rdkit.Chem.rdchem.Mol

OutputSerializer

alias of schrodinger.application.steps.dataclasses.MolToSmilesSerializer

__init__(*args, **kwargs)

Initialize self. See help(type(self)) for accurate signature.

blockSignals(self, bool) → bool

childEvent(self, QChildEvent)

children(self) → List[QObject]

cleanUp()

Hook for adding any type of work that needs to happen after all outputs are exhausted or if some outputs are created and the step is destroyed.

cleanUpTables()

connectNotify(self, QMetaMethod)

customEvent(self, QEvent)

deleteLater(self)

destroyed

destroyed(self, object: QObject = None) [signal]

disconnect(self)

disconnectNotify(self, QMetaMethod)

dumpObjectInfo(self)

dumpObjectTree(self)

dynamicPropertyNames(self) → List[QByteArray]

event(self, QEvent) → bool

eventFilter(self, QObject, QEvent) → bool

findChild(self, type, name: str = '', options: Union[Qt.FindChildOptions, Qt.FindChildOption] = Qt.FindChildrenRecursively) → QObject

findChild(self, Tuple, name: str = ‘’, options: Union[Qt.FindChildOptions, Qt.FindChildOption] = Qt.FindChildrenRecursively) -> QObject

findChildren(self, type, name: str = '', options: Union[Qt.FindChildOptions, Qt.FindChildOption] = Qt.FindChildrenRecursively) → List[QObject]

findChildren(self, Tuple, name: str = ‘’, options: Union[Qt.FindChildOptions, Qt.FindChildOption] = Qt.FindChildrenRecursively) -> List[QObject] findChildren(self, type, QRegExp, options: Union[Qt.FindChildOptions, Qt.FindChildOption] = Qt.FindChildrenRecursively) -> List[QObject] findChildren(self, Tuple, QRegExp, options: Union[Qt.FindChildOptions, Qt.FindChildOption] = Qt.FindChildrenRecursively) -> List[QObject] findChildren(self, type, QRegularExpression, options: Union[Qt.FindChildOptions, Qt.FindChildOption] = Qt.FindChildrenRecursively) -> List[QObject] findChildren(self, Tuple, QRegularExpression, options: Union[Qt.FindChildOptions, Qt.FindChildOption] = Qt.FindChildrenRecursively) -> List[QObject]

getDocker()

Returns

the singleton glide server manager

Return type

http_client.GlideServerManager

getLicenseRequirements()

getOutputSerializer()

getOutputs()

Gets all the outputs in a list by fully iterating the output generator.

getRunInfo()

getStepId()

inherits(self, str) → bool

inputs()

installEventFilter(self, QObject)

isBigQueryBatched()

isSignalConnected(self, QMetaMethod) → bool

isWidgetType(self) → bool

isWindowType(self) → bool

static is_bq_step(step)

killTimer(self, int)

metaObject(self) → QMetaObject

moveToThread(self, QThread)

objectName(self) → str

objectNameChanged

objectNameChanged(self, str) [signal]

outputs(*args, **kwargs)

parent(self) → QObject

prettyPrintRunInfo()

Format and print info about the step’s run.

progressUpdated

property(self, str) → Any

pyqtConfigure(...)

Each keyword argument is either the name of a Qt property or a Qt signal. For properties the property is set to the given value which should be of an appropriate type. For signals the signal is connected to the given value which should be a callable.

receivers(self, PYQT_SIGNAL) → int

reduceFunction(inputs)

The main computation for this step. This function should take in a iterable of inputs and return an iterable of outputs.

Example:

def reduceFunction(self, words):
    # Find all unique words
    seen_words = set()
    for word in words:
        if word not in seen_words:
            seen_words.add(word)
            yield word

removeEventFilter(self, QObject)

report(prefix='')

Report the settings and batch settings for this step.

sender(self) → QObject

senderSignalIndex(self) → int

setBatchSettings(*args, **kwargs)

setInputBQTable(bq_table, bq_dataset=None)

setInputFile(fname)

setInputs(*args, **kwargs)

setObjectName(self, str)

setOutputBQTable(bq_table)

setParent(self, QObject)

setProperty(self, str, Any) → bool

setSettings(*args, **kwargs)

signalsBlocked(self) → bool

startTimer(self, int, timerType: Qt.TimerType = Qt.CoarseTimer) → int

staticMetaObject = <PyQt5.QtCore.QMetaObject object>

thread(self) → QThread

timerEvent(self, QTimerEvent)

tr(self, str, disambiguation: str = None, n: int = - 1) → str

validateSettings()

Check whether the step settings are valid and return a list of SettingsError and SettingsWarning to report any invalid settings. Default implementation checks that all stepper files are set to valid file paths.

Return type

list[TaskError or TaskWarning]

writeOutputsToFile(fname)

Write outputs to fname. By default, the output file will consist of one line for each output with whatever is produced when passing the out- put to str. Override this method if more complex behavior is needed.

writeOutputsToTable()

class schrodinger.application.steps.docking.ScoredSmilesDocker(*args, **kwargs)

Bases: schrodinger.application.steps.docking.SmilesDocker

A SmilesDocker that returns ScoredSmiles objects.

Output

alias of schrodinger.application.steps.dataclasses.ScoredSmiles

OutputSerializer

alias of schrodinger.application.steps.dataclasses.ScoredSmilesSerializer

mapFunction(mol)

GLIDE_SERVER_START_TASK_CLASS

alias of _SmilesGlideServerStartTask

Input

alias of rdkit.Chem.rdchem.Mol

InputSerializer

alias of schrodinger.application.steps.dataclasses.MolToSmilesSerializer

class Settings(*args, _param_type=<object object>, **kwargs)

Bases: schrodinger.application.steps.docking.SmilesDockerSettings

DataClass

This class can be used to declare a public attribute on a CompoundParam. Declared public attributes can be used without error.

Example usage:

class Coord(CompoundParam):
    x: int
    y: int
    note = NonParamAttribute()

coord = Coord()
coord.note = "hello" # No error

__init__(default_value=<object object>, _param_type=<object object>, **kwargs)

Initialize self. See help(type(self)) for accurate signature.

classmethod addSubParam(name, param, update_owner=True)

arg_string: 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

arg_stringChanged

arg_stringReplaced

blockSignals(self, bool) → bool

block_signal_propagation()

childEvent(self, QChildEvent)

children(self) → List[QObject]

classmethod configureParam()

Override this class method to set up the abstract param class (e.g. setParamReference on child params.)

connectNotify(self, QMetaMethod)

customEvent(self, QEvent)

classmethod defaultValue(*args, **kwargs)

deleteLater(self)

destroyed

destroyed(self, object: QObject = None) [signal]

disconnect(self)

disconnectNotify(self, QMetaMethod)

dumpObjectInfo(self)

dumpObjectTree(self)

dynamicPropertyNames(self) → List[QByteArray]

event(self, QEvent) → bool

eventFilter(self, QObject, QEvent) → bool

findChild(self, type, name: str = '', options: Union[Qt.FindChildOptions, Qt.FindChildOption] = Qt.FindChildrenRecursively) → QObject

findChild(self, Tuple, name: str = ‘’, options: Union[Qt.FindChildOptions, Qt.FindChildOption] = Qt.FindChildrenRecursively) -> QObject

findChildren(self, type, name: str = '', options: Union[Qt.FindChildOptions, Qt.FindChildOption] = Qt.FindChildrenRecursively) → List[QObject]

findChildren(self, Tuple, name: str = ‘’, options: Union[Qt.FindChildOptions, Qt.FindChildOption] = Qt.FindChildrenRecursively) -> List[QObject] findChildren(self, type, QRegExp, options: Union[Qt.FindChildOptions, Qt.FindChildOption] = Qt.FindChildrenRecursively) -> List[QObject] findChildren(self, Tuple, QRegExp, options: Union[Qt.FindChildOptions, Qt.FindChildOption] = Qt.FindChildrenRecursively) -> List[QObject] findChildren(self, type, QRegularExpression, options: Union[Qt.FindChildOptions, Qt.FindChildOption] = Qt.FindChildrenRecursively) -> List[QObject] findChildren(self, Tuple, QRegularExpression, options: Union[Qt.FindChildOptions, Qt.FindChildOption] = Qt.FindChildrenRecursively) -> List[QObject]

classmethod fromJson(json_obj)

A factory method which constructs a new object from a given dict loaded from a json string or file.

Parameters

json_obj (dict) – A json-loaded dictionary to create an object from.

Returns

An instance of this class.

Return type

cls

classmethod fromJsonImplementation(json_dict)

Sets the value of this compound param value object from a JSON dict.

Warning

This should never be called directly.

getAbstractParam(*args, **kwargs)

classmethod getJsonBlacklist()

Override to customize what params are serialized.

Implementations should return a list of abstract params that should be omitted from serialization.

..NOTE

Returned abstract params must be direct child params of cls, e.g. cls.name, not cls.coord.x.

classmethod getParamSignal(*args, **kwargs)

classmethod getParamValue(*args, **kwargs)

classmethod getSubParam(name)

Get the value of a subparam using the string name:

c = Coord()
assert c.getSubParam('x') == 0

Note

Using the string name to access params is generally discouraged, but can be useful for serializing/deserializing param data.

Parameters

name (str) – The name of the subparam to get the value for.

classmethod getSubParams()

Return a dictionary mapping subparam names to their values.

getTypeHint()

get_version()

Method to get the version of a particular object. Defaults to the current version of mmshare. This class can be overridden for custom versioning behavior.

glide_grid_file: schrodinger.tasks.stepper.StepperFile

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

glide_grid_fileChanged

glide_grid_fileReplaced

glide_in_file: schrodinger.tasks.stepper.StepperFile

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

glide_in_fileChanged

glide_in_fileReplaced

glide_ref_ligand_file: schrodinger.tasks.stepper.StepperFile

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

glide_ref_ligand_fileChanged

glide_ref_ligand_fileReplaced

inherits(self, str) → bool

initAbstract()

initConcrete()

Override to customize initialization of concrete params.

initializeValue()

Override to dynamically set up the default value of the param. Useful for default values that are determined at runtime. This is called any time the param is reset.

installEventFilter(self, QObject)

classmethod isAbstract()

Whether the param is an “abstract” param.

isDefault(*args, **kwargs)

isSignalConnected(self, QMetaMethod) → bool

isWidgetType(self) → bool

isWindowType(self) → bool

killTimer(self, int)

ligprep_filter_file: schrodinger.tasks.stepper.StepperFile

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

ligprep_filter_fileChanged

ligprep_filter_fileReplaced

max_score: 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

max_scoreChanged

max_scoreReplaced

metaObject(self) → QMetaObject

moveToThread(self, QThread)

objectName(self) → str

objectNameChanged

objectNameChanged(self, str) [signal]

classmethod owner()

Get the owner of the param:

# Can be called on an abstract param:
assert Coord.x.owner() == Coord

# ...or on an instance of a CompoundParam
a = Atom()
assert a.coord.owner() == a

classmethod ownerChain()

Returns a list of param owners starting from the toplevel param and ending with self. Examples:

foo.bar.atom.coord.ownerChain() will return [foo, bar, atom, coord] where every item is a concrete param.

Foo.bar.atom.coord.x.ownerChain() will return [Foo, Foo.bar, Foo.atom.coord, Foo.atom.coord.x] where every item is an abstract params.

classmethod paramName()

Get the name of the param:

# Can be called on an abstract param:
print(Coord.x.paramName()) # 'x'

# ...or on an instance of a CompoundParam
a = Atom()
a.coord.paramName() # 'coord'

parent(self) → QObject

property(self, str) → Any

pyqtConfigure(...)

Each keyword argument is either the name of a Qt property or a Qt signal. For properties the property is set to the given value which should be of an appropriate type. For signals the signal is connected to the given value which should be a callable.

receivers(self, PYQT_SIGNAL) → int

removeEventFilter(self, QObject)

reset(*args, **kwargs)

sender(self) → QObject

senderSignalIndex(self) → int

setObjectName(self, str)

classmethod setParamValue(*args, **kwargs)

setParent(self, QObject)

setProperty(self, str, Any) → bool

classmethod setReference(param1, param2)

Call this class method from configureParam to indicate that two params should be kept in sync. The initial values will start with the default value of param1. Example:

class Square(CompoundParam):
    width: float = 5
    height: float = 10

    @classmethod
    def configureParam(cls):
        super().configureParam()
        cls.setReference(cls.width, cls.height)

square = Square()
assert square.width == square.height == 5 # Default value of width
                                          # takes priority
square.height = 7
assert square.width == square.height == 7
square.width = 6
assert square.width == square.height == 6

Parameters

• param1 – The first abstract param to keep synced

• param2 – The second abstract param. After instantiation, this param will take on the value of param1.

setValue(*args, **kwargs)

signalsBlocked(self) → bool

skip_eq_check()

startTimer(self, int, timerType: Qt.TimerType = Qt.CoarseTimer) → int

staticMetaObject = <PyQt5.QtCore.QMetaObject object>

thread(self) → QThread

timerEvent(self, QTimerEvent)

toDict(*args, **kwargs)

toJson(_mark_version=True)

Create and returns a data structure made up of jsonable items.

Return type

An instance of one the classes from NATIVE_JSON_DATATYPES

toJsonImplementation(*args, **kwargs)

Abstract method that must be defined by all derived classes. Converts an instance of the derived class into a jsonifiable object.

Returns

A dict made up of JSON native datatypes or Jsonable objects. See the link below for a table of such types. https://docs.python.org/2/library/json.html#encoders-and-decoders

tr(self, str, disambiguation: str = None, n: int = - 1) → str

validate(step)

Validate the settings for use in step.

Parameters

step – stepper._BaseStep

Return type

list[TaskError or TaskWarning]

valueChanged

__init__(*args, **kwargs)

Initialize self. See help(type(self)) for accurate signature.

blockSignals(self, bool) → bool

childEvent(self, QChildEvent)

children(self) → List[QObject]

cleanUp()

Hook for adding any type of work that needs to happen after all outputs are exhausted or if some outputs are created and the step is destroyed.

cleanUpTables()

connectNotify(self, QMetaMethod)

customEvent(self, QEvent)

deleteLater(self)

destroyed

destroyed(self, object: QObject = None) [signal]

disconnect(self)

disconnectNotify(self, QMetaMethod)

dumpObjectInfo(self)

dumpObjectTree(self)

dynamicPropertyNames(self) → List[QByteArray]

event(self, QEvent) → bool

eventFilter(self, QObject, QEvent) → bool

findChild(self, type, name: str = '', options: Union[Qt.FindChildOptions, Qt.FindChildOption] = Qt.FindChildrenRecursively) → QObject

findChild(self, Tuple, name: str = ‘’, options: Union[Qt.FindChildOptions, Qt.FindChildOption] = Qt.FindChildrenRecursively) -> QObject

findChildren(self, type, name: str = '', options: Union[Qt.FindChildOptions, Qt.FindChildOption] = Qt.FindChildrenRecursively) → List[QObject]

findChildren(self, Tuple, name: str = ‘’, options: Union[Qt.FindChildOptions, Qt.FindChildOption] = Qt.FindChildrenRecursively) -> List[QObject] findChildren(self, type, QRegExp, options: Union[Qt.FindChildOptions, Qt.FindChildOption] = Qt.FindChildrenRecursively) -> List[QObject] findChildren(self, Tuple, QRegExp, options: Union[Qt.FindChildOptions, Qt.FindChildOption] = Qt.FindChildrenRecursively) -> List[QObject] findChildren(self, type, QRegularExpression, options: Union[Qt.FindChildOptions, Qt.FindChildOption] = Qt.FindChildrenRecursively) -> List[QObject] findChildren(self, Tuple, QRegularExpression, options: Union[Qt.FindChildOptions, Qt.FindChildOption] = Qt.FindChildrenRecursively) -> List[QObject]

getDocker()

Returns

the singleton glide server manager

Return type

http_client.GlideServerManager

getLicenseRequirements()

getOutputSerializer()

getOutputs()

Gets all the outputs in a list by fully iterating the output generator.

getRunInfo()

getStepId()

inherits(self, str) → bool

inputs()

installEventFilter(self, QObject)

isBigQueryBatched()

isSignalConnected(self, QMetaMethod) → bool

isWidgetType(self) → bool

isWindowType(self) → bool

static is_bq_step(step)

killTimer(self, int)

metaObject(self) → QMetaObject

moveToThread(self, QThread)

objectName(self) → str

objectNameChanged

objectNameChanged(self, str) [signal]

outputs(*args, **kwargs)

parent(self) → QObject

prettyPrintRunInfo()

Format and print info about the step’s run.

progressUpdated

property(self, str) → Any

pyqtConfigure(...)

Each keyword argument is either the name of a Qt property or a Qt signal. For properties the property is set to the given value which should be of an appropriate type. For signals the signal is connected to the given value which should be a callable.

receivers(self, PYQT_SIGNAL) → int

reduceFunction(inputs)

The main computation for this step. This function should take in a iterable of inputs and return an iterable of outputs.

Example:

def reduceFunction(self, words):
    # Find all unique words
    seen_words = set()
    for word in words:
        if word not in seen_words:
            seen_words.add(word)
            yield word

removeEventFilter(self, QObject)

report(prefix='')

Report the settings and batch settings for this step.

sender(self) → QObject

senderSignalIndex(self) → int

setBatchSettings(*args, **kwargs)

setInputBQTable(bq_table, bq_dataset=None)

setInputFile(fname)

setInputs(*args, **kwargs)

setObjectName(self, str)

setOutputBQTable(bq_table)

setParent(self, QObject)

setProperty(self, str, Any) → bool

setSettings(*args, **kwargs)

setUp()

Hook for adding any type of work that needs to happen before any outputs are created.

signalsBlocked(self) → bool

startTimer(self, int, timerType: Qt.TimerType = Qt.CoarseTimer) → int

staticMetaObject = <PyQt5.QtCore.QMetaObject object>

thread(self) → QThread

timerEvent(self, QTimerEvent)

tr(self, str, disambiguation: str = None, n: int = - 1) → str

validateSettings()

Check whether the step settings are valid and return a list of SettingsError and SettingsWarning to report any invalid settings. Default implementation checks that all stepper files are set to valid file paths.

Return type

list[TaskError or TaskWarning]

writeOutputsToFile(fname)

Write outputs to fname. By default, the output file will consist of one line for each output with whatever is produced when passing the out- put to str. Override this method if more complex behavior is needed.

writeOutputsToTable()