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Module containing functions to encode and compare the shapes of molecules
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__package__ = None
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ComputeConfBox( (Conformer)conf [, (AtomPairsParameters)trans=None [, (float)padding=2.0]]) -> tuple :
Compute the lower and upper corners of a cuboid that will fit the conformer
C++ signature :
boost::python::tuple ComputeConfBox(RDKit::Conformer [,boost::python::api::object=None [,double=2.0]])
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ComputeConfDimsAndOffset( (Conformer)conf [, (AtomPairsParameters)trans=None [, (float)padding=2.0]]) -> tuple :
Compute the size of the box that can fit the conformations, and offset
of the box from the origin
C++ signature :
boost::python::tuple ComputeConfDimsAndOffset(RDKit::Conformer [,boost::python::api::object=None [,double=2.0]])
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ComputeUnionBox( (tuple)arg1, (tuple)arg2) -> tuple :
Compute the union of two boxes, so that all the points in both boxes are
contained in the new box
C++ signature :
boost::python::tuple ComputeUnionBox(boost::python::tuple,boost::python::tuple)
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EncodeShape( (Mol)mol, (UniformGrid3D_)grid [, (int)confId=-1 [, (AtomPairsParameters)trans=None [, (float)vdwScale=0.8 [, (float)stepSize=0.25 [, (int)maxLayers=-1 [, (bool)ignoreHs=True]]]]]]) -> None :
Encode the shape of a molecule (one of its conformer) onto a grid
ARGUMENTS:
- mol : the molecule of interest
- grid : grid onto which the encoding is written
- confId : id of the conformation of interest on mol (defaults to the first one)
- trans : any transformation that needs to be used to encode onto the grid (note the molecule remains unchanged)
- vdwScale : Scaling factor for the radius of the atoms to determine the base radius
used in the encoding - grid points inside this sphere carry the maximum occupancy
- setpSize : thickness of the layers outside the base radius, the occupancy value is decreased
from layer to layer from the maximum value
- maxLayers : the maximum number of layers - defaults to the number of bits
used per grid point - e.g. two bits per grid point will allow 3 layers
- ignoreHs : when set, the contribution of Hs to the shape will be ignored
C++ signature :
void EncodeShape(RDKit::ROMol,RDGeom::UniformGrid3D {lvalue} [,int=-1 [,boost::python::api::object=None [,double=0.8 [,double=0.25 [,int=-1 [,bool=True]]]]]])
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ShapeProtrudeDist( (Mol)mol1, (Mol)mol2 [, (int)confId1=-1 [, (int)confId2=-1 [, (float)gridSpacing=0.5 [, (DiscreteValueType)bitsPerPoint=rdkit.DataStructs.cDataStructs.DiscreteValueType.TWOBITVALUE [, (float)vdwScale=0.8 [, (float)stepSize=0.25 [, (int)maxLayers=-1 [, (bool)ignoreHs=True [, (bool)allowReordering=True]]]]]]]]]) -> float :
Compute the shape protrude distance between two molecule based on a predefined alignment
ARGUMENTS:
- mol1 : The first molecule of interest
- mol2 : The second molecule of interest
- confId1 : Conformer in the first molecule (defaults to first conformer)
- confId2 : Conformer in the second molecule (defaults to first conformer)
- gridSpacing : resolution of the grid used to encode the molecular shapes
- bitsPerPoint : number of bit used to encode the occupancy at each grid point
defaults to two bits per grid point
- vdwScale : Scaling factor for the radius of the atoms to determine the base radius
used in the encoding - grid points inside this sphere carry the maximum occupancy
- stepSize : thickness of the each layer outside the base radius, the occupancy value is decreased
from layer to layer from the maximum value
- maxLayers : the maximum number of layers - defaults to the number of bits
used per grid point - e.g. two bits per grid point will allow 3 layers
- ignoreHs : when set, the contribution of Hs to the shape will be ignored
- allowReordering : when set, the order will be automatically updated so that the value calculated
is the protrusion of the smaller shape from the larger one.
C++ signature :
double ShapeProtrudeDist(RDKit::ROMol,RDKit::ROMol [,int=-1 [,int=-1 [,double=0.5 [,RDKit::DiscreteValueVect::DiscreteValueType=rdkit.DataStructs.cDataStructs.DiscreteValueType.TWOBITVALUE [,double=0.8 [,double=0.25 [,int=-1 [,bool=True [,bool=True]]]]]]]]])
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ShapeTanimotoDist( (Mol)mol1, (Mol)mol2 [, (int)confId1=-1 [, (int)confId2=-1 [, (float)gridSpacing=0.5 [, (DiscreteValueType)bitsPerPoint=rdkit.DataStructs.cDataStructs.DiscreteValueType.TWOBITVALUE [, (float)vdwScale=0.8 [, (float)stepSize=0.25 [, (int)maxLayers=-1 [, (bool)ignoreHs=True]]]]]]]]) -> float :
Compute the shape tanimoto distance between two molecule based on a predefined alignment
ARGUMENTS:
- mol1 : The first molecule of interest
- mol2 : The second molecule of interest
- confId1 : Conformer in the first molecule (defaults to first conformer)
- confId2 : Conformer in the second molecule (defaults to first conformer)
- gridSpacing : resolution of the grid used to encode the molecular shapes
- bitsPerPoint : number of bits used to encode the occupancy at each grid point
defaults to two bits per grid point
- vdwScale : Scaling factor for the radius of the atoms to determine the base radius
used in the encoding - grid points inside this sphere carry the maximum occupancy
- stepSize : thickness of the each layer outside the base radius, the occupancy value is decreased
from layer to layer from the maximum value
- maxLayers : the maximum number of layers - defaults to the number of bits
used per grid point - e.g. two bits per grid point will allow 3 layers
- ignoreHs : when set, the contribution of Hs to the shape will be ignored
C++ signature :
double ShapeTanimotoDist(RDKit::ROMol,RDKit::ROMol [,int=-1 [,int=-1 [,double=0.5 [,RDKit::DiscreteValueVect::DiscreteValueType=rdkit.DataStructs.cDataStructs.DiscreteValueType.TWOBITVALUE [,double=0.8 [,double=0.25 [,int=-1 [,bool=True]]]]]]]])
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