fmeobjects.FMECompositeSurface
appendPart(surface), |
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This method returns the bounding box of the geometry. |
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This method returns the bounding cube of the geometry. |
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Returns the bounds of the geometry. |
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Remove all measures from the geometry. |
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Copies all the attributes from the given feature to traits on this geometry, if they match the (optional) regular expression. |
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Copies the name of the 'sourceGeometry' onto this geometry. |
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Copies all the traits from the given geometry that match the (optional) regular expression. |
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Copies all the traits from this geometry to attributes on the given feature, if they match the (optional) regular expression. |
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Deletes the geometry's name. |
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This method deletes the side specified by 'front' and indicates whether or not it existed before being deleted. |
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Reduces the geometry to 2D. |
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This sets the geometry's dimension to 3D. |
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This method returns the appearance reference within the Library associated with this surface. |
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Area calculation. |
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Returns the wireframe of the surface as a |
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Retrieve the names of the measures on this geometry. |
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This routine retrieves the 'name' of this geometry as a |
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getPartAt(index), |
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Retrieves the geometry trait value of the specified trait name. |
Retrieve the names of the traits on this geometry. |
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This method returns a tuple of a boolean, indicating if the trait is null, a boolean, indicating if the trait is missing, and an integer representing the type of the trait. |
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Returns the type of given trait. |
Check if this geometry or any sub part of this geometry has measures. |
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Returns whether or not the geometry has a name. |
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Returns whether or not the geometry is 3D. |
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Check if the geometry is an aggregate or multi-part collection. |
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Works similarly to |
A face with a donut area will not be oriented if the normal of any inner boundary has the same direction as the normal of the outer boundary. |
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Returns |
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Returns |
This returns the number of surfaces that make up this composite surface. |
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Offsets the surface by the coords specified by 'offsetPoint'. |
Flips the front and the back of parts of the surface as required to create a surface that is oriented. |
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This removes and returns the last surface of the composite surface. |
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Removes the measure with name 'measureName' if supplied, or the default measure, if there is one. |
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This method has 4 modes: |
Renames the measure specified by 'oldMeasureName' to the new name, specified by 'newMeasureName'. |
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Flips the surface such that the front and back of the surface are switched. |
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Recursively resolves surface parts with default appearances by replacing these defaults with the inherited appearance references stored by the parent surface, if such a value exists. |
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This reverses the order of the surface's points. |
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Rotates this surface about the z-axis by the specified angle, in degrees. |
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Scale the feature by the given amounts. |
This method associates an appearance within the Library with this surface. |
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Sets the geometry's name with a |
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Sets a geometry trait with the specified value. |
This method supplies a null trait value with a type to the geometry. |
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This method checks whether the side specified by 'front' exists. |
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This creates a simple surface iterator. |
- class FMECompositeSurface
FME Composite Surface Class
Create an instance of a Composite Surface geometry object.
init()
Default
FMECompositeSurfaceconstructor.- Return type:
- Returns:
An instance of a Composite Surface geometry object.
init(compositeSurface)
Create a copy of the passed in Composite Surface geometry object.
- Parameters:
compositeSurface (FMECompositeSurface) – The Composite Surface geometry object to create a copy of.
- Return type:
- Returns:
An instance of a Composite Surface geometry object.
- __init__(*args, **kwargs)
- appendPart()
appendPart(surface),
This appends the surface to the composite surface. If
Noneis passed in, nothing will be appended. All areas in the composite surface will be forced to have the same dimension. If any 3D areas exist, all 2D areas will be converted to 3D with a default Z value of 0.0.- Parameters:
surface (FMESurface) – The surface to be appended.
- Return type:
None
- Raises:
FMEException – An exception is raised if an error occurred.
- boundingBox()
This method returns the bounding box of the geometry.
- boundingCube()
This method returns the bounding cube of the geometry.
- bounds()
Returns the bounds of the geometry.
- clearMeasures()
Remove all measures from the geometry.
- Return type:
None
- copyAttributesFromFeature(sourceFeature, overwriteExisting, regexp, prefix)
Copies all the attributes from the given feature to traits on this geometry, if they match the (optional) regular expression.
- Parameters:
sourceFeature (FMEFeature) – The feature to copy attributes from.
overwriteExisting (bool) – Existing traits will be overwritten only if overwriteExisting is
True.regexp (str) – (Optional) The regular expression to match the attributes against. If regexp is not specified, then all attributes will be copied.
prefix (str) – (Optional) The prefix is put on all the trait names as they are copied. If it is not specified, a prefix will not be added to the trait names.
- Return type:
None
- copyNameFromGeometry(sourceGeometry)
Copies the name of the ‘sourceGeometry’ onto this geometry. If ‘sourceGeometry’s name is blank or
None, this geometry’s name will becomeNone.- Parameters:
sourceGeometry (FMEGeometry) – The geometry to copy the name from.
- Return type:
None
- copyTraitsFromGeometry(sourceGeometry, overwriteExisting, regexp, prefix)
Copies all the traits from the given geometry that match the (optional) regular expression.
- Parameters:
sourceGeometry (FMEGeometry) – The geometry to copy traits from.
overwriteExisting (bool) – Existing traits will be overwritten only if overwriteExisting is
True.regexp (str) – (Optional) The regular expression to match the traits against. If regexp is not specified, or is an empty string, then all traits will be copied.
prefix (str) – (Optional) The prefix is put on all the trait names as they are copied. If it is not specified, a prefix will not be added to the trait names.
- Return type:
None
- copyTraitsToFeature(destFeature, overwriteExisting, regexp, prefix)
Copies all the traits from this geometry to attributes on the given feature, if they match the (optional) regular expression.
- Parameters:
destFeature (FMEFeature) – The feature to copy traits to.
overwriteExisting (bool) – Existing attributes will be overwritten only if overwriteExisting is
True.regexp (str) – (Optional) The regular expression to match the traits against. If regexp is not specified, or is an empty string, then all traits will be copied.
prefix (str) – (Optional) The prefix is put on all the attribute names as they are copied. If it is not specified, a prefix will not be added to the attribute names.
- Return type:
None
- deleteName()
Deletes the geometry’s name. If a name existed prior to this call then
Trueis returned; otherwiseFalseis returned.- Return type:
- Returns:
Returns a boolean indicating whether or not the name existed before deletion.
- deleteSide(front)
This method deletes the side specified by ‘front’ and indicates whether or not it existed before being deleted.
- force2D()
Reduces the geometry to 2D.
- Return type:
None
- force3D(newZ)
This sets the geometry’s dimension to 3D. All Z values are set to the value passed in, even if the geometry is already 3D.
- Parameters:
newZ (float) – The new Z value.
- Return type:
None
- getAppearanceReference(front)
This method returns the appearance reference within the Library associated with this surface. The ‘front’ parameter controls whether this query should return the front or the back appearance reference. Both can be fetched independently. If this surface is a regular surface with no geometry instance, a
FMEExceptionwill be thrown.- Parameters:
front (bool) – Boolean indicating whether the appearance reference should be retrieved for the front or back of the surface.
- Return type:
- Returns:
The unique appearance reference for this appearance.
- Raises:
FMEException – An exception is raised if an error occurred or this surface is a regular surface with no geometry instance.
- getAsWireFrame()
Returns the wireframe of the surface as a
FMEMultiCurve.Noneis returned if a wireframe cannot be generated.- Return type:
FMEMultiCurve or None
- Returns:
The wireframe of the surface as a
FMEMultiCurve.
- getMeasureNames()
Retrieve the names of the measures on this geometry.
- Return type:
- Returns:
Return a tuple storing the names of the measures on this geometry. This will return an empty tuple if there are no measures. For
FMEAggregate,FMEMultiSurface, andFMECompositeSurface, this will return the union of all measure names of all of its parts.
- getName()
This routine retrieves the ‘name’ of this geometry as a
str. This will returnNoneif it did not have a name associated with it.- Return type:
str or None
- Returns:
The geometry’s name.
- getPartAt()
getPartAt(index),
This method returns the surface at the given index.
Noneis returned if the index is out of range.- Parameters:
index (int) – The index of the surface part to return.
- Return type:
FMESurface or None
- Returns:
The surface at the given index. Note: This method returns a terminal area type of the
FMESurface; i.e. one of the leaf classes in theFMESurfaceinheritance graph. For example, aFMEMeshis returned if the area truly is a Mesh.- Raises:
FMEException – An exception is raised if an error occurred.
- getTrait(traitName)
Retrieves the geometry trait value of the specified trait name. Null trait values will be returned as an empty string. Binary blob traits are returned as a bytearray.
Noneis returned when the trait is not found on the geometry.
- getTraitNames()
Retrieve the names of the traits on this geometry.
- getTraitNullMissingAndType(traitName)
This method returns a tuple of a boolean, indicating if the trait is null, a boolean, indicating if the trait is missing, and an integer representing the type of the trait. The first boolean is
Trueif ‘traitName’ maps to a null trait value on the geometry. Otherwise it isFalse. The second boolean isTrueif ‘traitName’ maps to a no value on the geometry. Otherwise it isFalse. If the trait is absent,FME_ATTR_UNDEFINEDis returned for the type.The possible trait types are
FME_ATTR_UNDEFINED,FME_ATTR_BOOLEAN,FME_ATTR_INT8,FME_ATTR_UINT8,FME_ATTR_INT16,FME_ATTR_UINT16,FME_ATTR_INT32,FME_ATTR_UINT32,FME_ATTR_REAL32,FME_ATTR_REAL64,FME_ATTR_REAL80,FME_ATTR_STRING,FME_ATTR_ENCODED_STRING,FME_ATTR_INT64,FME_ATTR_UINT64.
- getTraitType(traitName)
Returns the type of given trait. If the trait cannot be found,
FME_ATTR_UNDEFINEDwill be returned.Returns one of
FME_ATTR_UNDEFINED,FME_ATTR_BOOLEAN,FME_ATTR_INT8,FME_ATTR_UINT8,FME_ATTR_INT16,FME_ATTR_UINT16,FME_ATTR_INT32,FME_ATTR_UINT32,FME_ATTR_REAL32,FME_ATTR_REAL64,FME_ATTR_REAL80,FME_ATTR_STRING,FME_ATTR_ENCODED_STRING,FME_ATTR_INT64,FME_ATTR_UINT64.
- hasMeasures()
Check if this geometry or any sub part of this geometry has measures.
- hasName()
Returns whether or not the geometry has a name.
- is3D()
Returns whether or not the geometry is 3D.
- Return type:
- Returns:
Returns
Trueif the geometry is 3D andFalseotherwise. ForFMENull, this method will always returnTrue. ForFMEAggregate,FMEMultiPoint,FMEMultiArea,FMEMultiTextandFMEMultiCurve, this method will returnTrueif any one of the sub-parts is 3D. If the collection is empty or all of its members are 2D, this method will returnFalse.
- isCollection()
Check if the geometry is an aggregate or multi-part collection.
- isInPlane(tolerance, normalVector, valD, recalculateD)
Works similarly to
isPlanar(), but checks planarity with respect to given normal or given plane (if plane equation D is specified - see below).If given normal is the zero vector, the normal used to check the planarity is computed using Newell’s method as in
isPlanar(). valD is a reference to a value of D in the plane equation AX + BY + CZ = D. It can be used to make sure that multiple pieces lie in the same plane. If ‘recalculateD’ is set toFalse, the passed in value of D will be used in the calculation. If ‘recalcualteD’ is set toTrue, the passed in value is ignored and is instead automatically calculated (and returned in the second position of the returned tuple). A useful calling pattern for ensuring co-planarity is to get valD computed on the first call to the function setting ‘recalculateD’ toTrue, and then use this value for future calls with ‘recalculateD’ toFalse.- Parameters:
- Return type:
- Returns:
A tuple containing a boolean, tuple, and float representing: 1) Whether or not the surface is in plane; 2) The normal vector returned; and 3) The value ‘D’. Note: If recalculateD is
False, the tuple returned will only contain the boolean and vector tuple (i.e. ‘valD’ is not returned).
- isOriented()
A face with a donut area will not be oriented if the normal of any inner boundary has the same direction as the normal of the outer boundary. Meshes and composite surfaces will return
Falseif they have two parts that share an edge and those two parts are not consistently oriented with respect to each other. If the surface is improperly noded, the behaviour of this function is undefined.
- isPlanar(tolerance)
Returns
Trueif this is planar within the given tolerance, andFalseotherwise.The planarity condition is computed by the following algorithm. The normal vector <A, B, C> is determined by the vertices of this surface using Newell’s method. For the first point (x’, y’, z’) of this surface, we compute D’ = Ax’ + By’ + Cz’. Then, this surface is planar if and only if every subsequent point (x, y, z) of this surface gives a D = Ax + By + Cz, that is within the tolerance amount of D’. That is, | D - D’ | <= tolerance.
If the specified tolerance is negative, then this method always returns
True.
- measureExists(measureName)
Returns
Trueif the specified measure exists andFalseotherwise. If the ‘measureName’ parameter is not specified then the default measure is checked.
- numParts()
This returns the number of surfaces that make up this composite surface.
- Return type:
- Returns:
The number of surfaces in composite surface.
- offset(offsetPoint)
Offsets the surface by the coords specified by ‘offsetPoint’.
- Parameters:
offsetPoint (FMEPoint) – The
FMEPointto offset the surface by.- Return type:
None
- Raises:
FMEException – An exception is raised if an error occurred.
- orient()
Flips the front and the back of parts of the surface as required to create a surface that is oriented. Refer to
isOriented()for the specification of what it means to be an oriented surface. If the surface is improperly noded or non-orientable, the behaviour of this function is undefined. All measures are changed as needed, including the vertex normal measures. Note: The vertex normals are not flipped (scaled by -1).- Return type:
None
- removeEndPart()
This removes and returns the last surface of the composite surface. If there are no surfaces in the composite surface, it will return
None.- Return type:
FMESurface or None
- Returns:
The last surface of the composite surface. Note: This method returns a terminal surface type of the
FMESurface; i.e. one of the leaf classes in theFMESurfaceinheritance graph. For example, aFMEMeshis returned if the area truly is a mesh.- Raises:
FMEException – An exception is raised if an error occurred.
- removeMeasure(measureName)
Removes the measure with name ‘measureName’ if supplied, or the default measure, if there is one.
- Parameters:
measureName (str) – (Optional) The name of the measure to remove.
- Return type:
None
- removeTraits(regexp)
This method has 4 modes:
Remove all traits at the top level: regex == NULL
Remove some traits at the top level: regex == <string>
Remove all traits at all levels: regex ==
kFME_RecurseAllRemove some traits at all levels: regex ==
kFME_RecurseSome<string>
For example, specifying regex == NULL for a multi-surface will remove all traits at the root level of the multi-surface, whereas specifying regex ==
kFME_RecurseSome<string> will remove all traits from all levels of the multi surface that match <string>. If <string> is an illegal regular expression, no traits will be removed.- Return type:
None
- renameMeasure(oldMeasureName, newMeasureName)
Renames the measure specified by ‘oldMeasureName’ to the new name, specified by ‘newMeasureName’.
- reorient()
Flips the surface such that the front and back of the surface are switched. All measures are changed as needed, including the vertex normal measures. Note: The vertex normals are not flipped (scaled by -1). Refer to
reverse()if the vertex normals need to be flipped. Note:FMETriangleStriphave a method calledisFlipped()that is to be used in conjunction with the geometry to determine which side is the front. WhenisFlipped()returnsTrue, the front is actually the opposite side of what the coordinates of the first triangle in the strip indicate.- Return type:
None
- resolvePartDefaults()
Recursively resolves surface parts with default appearances by replacing these defaults with the inherited appearance references stored by the parent surface, if such a value exists. The nearest non-default ancestor value will be used to set the default appearances on the part.
- Return type:
None
- reverse()
This reverses the order of the surface’s points.
- Return type:
None
- rotate2D(center, angle)
Rotates this surface about the z-axis by the specified angle, in degrees. The rotation is performed relative to the center specified. A positive angle corresponds to a counter-clockwise rotation, when looking down onto the XY-plane.
- Parameters:
- Return type:
None
- Raises:
FMEException – An exception is raised if an error occurred.
- scale(xScale, yScale, zScale)
Scale the feature by the given amounts.
- Parameters:
- Return type:
None
- Raises:
FMEException – An exception is raised if an error occurred.
- setAppearanceReference(appearanceRef, front)
This method associates an appearance within the Library with this surface. This is done by passing in the unique appearance reference for this appearance. Subsequent calls to this method on the same side, will override the previous appearance used with the new appearance passed in.
An appearance reference of ‘0’ represents the default appearance. Interpretation of the default appearance is left to the consumer of this geometry. When set at this
FMESurfacelevel, the appearance represents the default appearance to apply when the contained surfaces use the default appearance instead of a specific appearance. Contained surfaces may be found within nested surfaces, geometry instances that reference geometries containing surfaces, or as surfaces or multi-surfaces.The second parameter controls whether this action should take place on the front of the contained surfaces or the back. Both can be set independently. The appearanceRef should be a valid reference to a definition stored in the
FMELibrary. If the reference was not found in the library, it will still attach the reference to the instance, but will throw aFMEException. This is an unhealthy situation as it represents a ‘dangling reference’.- Parameters:
- Raises:
FMEException – An exception is raised if an error occurred or the reference was not found in the library and a dangling reference was attached.
- setName(name)
Sets the geometry’s name with a
str. By supplying a blank name as input, this method will act asdeleteName().- Parameters:
name (str) – The geometry’s new name.
- Return type:
None
- setTrait(traitName, traitValue)
Sets a geometry trait with the specified value. If the geometry trait already exists, its value and type will be changed. The following type numeric mappings are used:
PyInt ==> FME_Int32
PyFloat ==> FME_Real64
PyLong ==> FME_Int64
Binary values are to be specified as bytearray values or bytes values.
- setTraitNullWithType(traitName, traitType)
This method supplies a null trait value with a type to the geometry. If a trait with the same name already exists, it is overwritten.
Trait type must be one of
FME_ATTR_UNDEFINED,FME_ATTR_BOOLEAN,FME_ATTR_INT8,FME_ATTR_UINT8,FME_ATTR_INT16,FME_ATTR_UINT16,FME_ATTR_INT32,FME_ATTR_UINT32,FME_ATTR_REAL32,FME_ATTR_REAL64,FME_ATTR_REAL80,FME_ATTR_STRING,FME_ATTR_ENCODED_STRING,FME_ATTR_INT64,FME_ATTR_UINT64.
- sideExists(front)
This method checks whether the side specified by ‘front’ exists.
- simpleSurfaceIter()
This creates a simple surface iterator.
- Return type:
- Returns:
Returns a simple surface iterator.