Notation used in Ruby API documentation
Module: db
Description: A generic edge-pair operator
Edge pair processors are an efficient way to process edge pairs from an edge pair collection. To apply a processor, derive your own operator class and pass an instance to the EdgePairs#processed or EdgePairs#process method.
Conceptually, these methods take each edge pair from the edge pair collection and present it to the operator's 'process' method. The result of this call is a list of zero to many output edge pairs derived from the input edge pair. The output edge pair collection is the sum over all these individual results.
The magic happens when deep mode edge pair collections are involved. In that case, the processor will use as few calls as possible and exploit the hierarchical compression if possible. It needs to know however, how the operator behaves. You need to configure the operator by calling is_isotropic, is_scale_invariant or is_isotropic_and_scale_invariant before using it.
You can skip this step, but the processor algorithm will assume the worst case then. This usually leads to cell variant formation which is not always desired and blows up the hierarchy.
Here is some example that flips the edge pairs (swaps first and second edge):
class FlipEdgePairs < RBA::EdgePairOperator
# Constructor
def initialize
self.is_isotropic_and_scale_invariant # orientation and scale do not matter
end
# Flips the edge pair
def process(edge_pair)
return [ RBA::EdgePair::new(edge_pair.second, edge_pair.first) ]
end
end
edge_pairs = ... # some EdgePairs object
flipped = edge_pairs.processed(FlipEdgePairs::new)
This class has been introduced in version 0.29.
| new EdgePairOperator ptr | new | Creates a new object of this class |
| void | _create | Ensures the C++ object is created | ||
| void | _destroy | Explicitly destroys the object | ||
| [const] | bool | _destroyed? | Returns a value indicating whether the object was already destroyed | |
| [const] | bool | _is_const_object? | Returns a value indicating whether the reference is a const reference | |
| void | _manage | Marks the object as managed by the script side. | ||
| void | _unmanage | Marks the object as no longer owned by the script side. | ||
| void | is_isotropic | Indicates that the filter has isotropic properties | ||
| void | is_isotropic_and_scale_invariant | Indicates that the filter is isotropic and scale invariant | ||
| void | is_scale_invariant | Indicates that the filter is scale invariant | ||
| [virtual,const] | EdgePair[] | process | (const EdgePair shape) | Processes a shape |
| void | wants_variants= | (bool flag) | Sets a value indicating whether the filter prefers cell variants | |
| [const] | bool | wants_variants? | Gets a value indicating whether the filter prefers cell variants |
| void | create | Use of this method is deprecated. Use _create instead | ||
| void | destroy | Use of this method is deprecated. Use _destroy instead | ||
| [const] | bool | destroyed? | Use of this method is deprecated. Use _destroyed? instead | |
| [const] | bool | is_const_object? | Use of this method is deprecated. Use _is_const_object? instead |
_create | Signature: void _create Description: Ensures the C++ object is created Use this method to ensure the C++ object is created, for example to ensure that resources are allocated. Usually C++ objects are created on demand and not necessarily when the script object is created. |
_destroy | Signature: void _destroy Description: Explicitly destroys the object Explicitly destroys the object on C++ side if it was owned by the script interpreter. Subsequent access to this object will throw an exception. If the object is not owned by the script, this method will do nothing. |
_destroyed? | Signature: [const] bool _destroyed? Description: Returns a value indicating whether the object was already destroyed This method returns true, if the object was destroyed, either explicitly or by the C++ side. The latter may happen, if the object is owned by a C++ object which got destroyed itself. |
_is_const_object? | Signature: [const] bool _is_const_object? Description: Returns a value indicating whether the reference is a const reference This method returns true, if self is a const reference. In that case, only const methods may be called on self. |
_manage | Signature: void _manage Description: Marks the object as managed by the script side. After calling this method on an object, the script side will be responsible for the management of the object. This method may be called if an object is returned from a C++ function and the object is known not to be owned by any C++ instance. If necessary, the script side may delete the object if the script's reference is no longer required. Usually it's not required to call this method. It has been introduced in version 0.24. |
_unmanage | Signature: void _unmanage Description: Marks the object as no longer owned by the script side. Calling this method will make this object no longer owned by the script's memory management. Instead, the object must be managed in some other way. Usually this method may be called if it is known that some C++ object holds and manages this object. Technically speaking, this method will turn the script's reference into a weak reference. After the script engine decides to delete the reference, the object itself will still exist. If the object is not managed otherwise, memory leaks will occur. Usually it's not required to call this method. It has been introduced in version 0.24. |
create | Signature: void create Description: Ensures the C++ object is created Use of this method is deprecated. Use _create instead Use this method to ensure the C++ object is created, for example to ensure that resources are allocated. Usually C++ objects are created on demand and not necessarily when the script object is created. |
destroy | Signature: void destroy Description: Explicitly destroys the object Use of this method is deprecated. Use _destroy instead Explicitly destroys the object on C++ side if it was owned by the script interpreter. Subsequent access to this object will throw an exception. If the object is not owned by the script, this method will do nothing. |
destroyed? | Signature: [const] bool destroyed? Description: Returns a value indicating whether the object was already destroyed Use of this method is deprecated. Use _destroyed? instead This method returns true, if the object was destroyed, either explicitly or by the C++ side. The latter may happen, if the object is owned by a C++ object which got destroyed itself. |
is_const_object? | Signature: [const] bool is_const_object? Description: Returns a value indicating whether the reference is a const reference Use of this method is deprecated. Use _is_const_object? instead This method returns true, if self is a const reference. In that case, only const methods may be called on self. |
is_isotropic | Signature: void is_isotropic Description: Indicates that the filter has isotropic properties Call this method before using the filter to indicate that the selection is independent of the orientation of the shape. This helps the filter algorithm optimizing the filter run, specifically in hierarchical mode. Examples for isotropic (polygon) processors are size or shrink operators. Size or shrink is not dependent on orientation unless size or shrink needs to be different in x and y direction. |
is_isotropic_and_scale_invariant | Signature: void is_isotropic_and_scale_invariant Description: Indicates that the filter is isotropic and scale invariant Call this method before using the filter to indicate that the selection is independent of the scale and orientation of the shape. This helps the filter algorithm optimizing the filter run, specifically in hierarchical mode. An example for such a (polygon) processor is the convex decomposition operator. The decomposition of a polygon into convex parts is an operation that is not depending on scale nor orientation. |
is_scale_invariant | Signature: void is_scale_invariant Description: Indicates that the filter is scale invariant Call this method before using the filter to indicate that the selection is independent of the scale of the shape. This helps the filter algorithm optimizing the filter run, specifically in hierarchical mode. An example for a scale invariant (polygon) processor is the rotation operator. Rotation is not depending on scale, but on the original orientation as mirrored versions need to be rotated differently. |
new | Signature: [static] new EdgePairOperator ptr new Description: Creates a new object of this class Python specific notes: |
process | Signature: [virtual,const] EdgePair[] process (const EdgePair shape) Description: Processes a shape This method is the actual payload. It needs to be reimplemented in a derived class. If needs to process the input shape and deliver a list of output shapes. The output list may be empty to entirely discard the input shape. It may also contain more than a single shape. In that case, the number of total shapes may grow during application of the processor. |
wants_variants= | Signature: void wants_variants= (bool flag) Description: Sets a value indicating whether the filter prefers cell variants This flag must be set before using this filter for hierarchical applications (deep mode). It tells the filter implementation whether cell variants should be created (true, the default) or shape propagation will be applied (false). This decision needs to be made, if the filter indicates that it will deliver different results for scaled or rotated versions of the shape (see is_isotropic and the other hints). If a cell is present with different qualities - as seen from the top cell - the respective instances need to be differentiated. Cell variant formation is one way, shape propagation the other way. Typically, cell variant formation is less expensive, but the hierarchy will be modified. Python specific notes: |
wants_variants? | Signature: [const] bool wants_variants? Description: Gets a value indicating whether the filter prefers cell variants See wants_variants= for details. Python specific notes: |