: Public abstract <<type>> Class
Created: 23.5.2022 18.05.07
Modified: 1.8.2022 13.54.08
An orientable primitives (Figure 10) are those that can be mirrored into new geometric objects in terms of their internal local coordinate systems (manifold charts). For curves, the orientation reflects the direction in which the curve is traversed, that is, the sense of its parameterization. When used as boundary curves, the surface being bounded is to the "left" of the oriented curve. For surfaces, the orientation reflects from which direction the local coordinate system can be viewed as right handed, the "top" or the surface being the direction of a completing z-axis that would form a right-handed system. When used as a boundary surface, the bounded solid is "below" the surface. The orientation of points and solids has no immediate geometric interpretation in 3-dimensional space.<br/>GM_OrientablePrimitive objects are essentially references to geometric primitives that carry an "orientation" reversal flag (either "+" or "-") that determines whether this primitive agrees or disagrees with the orientation of the referenced object. <br/>NOTE There are several reasons for subclassing the "positive" primitives under the orientable primitives. First is a matter of the semantics of subclassing. Subclassing is assumed to be a "is type of" hierarchy. In the view used, the "positive" primitive is simply the orientable one with the positive orientation. If the opposite view were taken, and orientable primitives were subclassed under the "positive" primitive, then by subclassing logic, the "negative" primitive would have to hold the same sort of geometric description that the "positive" primitive does. The only viable solution would be to separate "negative" primitives under the geometric root as being some sort of reference to their opposite. This adds a great deal of complexity to the subclassing tree.  To minimize the number of objects and to bypass this logical complexity, positively oriented primitives are self-referential (are instances of the corresponding primitive subtype) while negatively oriented primitives are not. <br/>Orientable primitives are often denoted by a sign (for the orientation) and a base geometry (curve or surface). The sign datatype is defined in ISO 19103. If "c" is a curve, then "#lt;+, c#gt;" is its positive orientable curve and "#lt;-, c#gt;" is its negative orientable curve. In most cases, leaving out the syntax for record "#lt; , #gt;" does not lead to confusion, so "#lt;+, c#gt;" may be written as "+c" or simply "c", and "#lt;-, c#gt;" as "-c". Curve space arithmetic can be performed if the curves align properly, so that:<br/>For c, d : GM_OrientableCurves such that c.endPoint = d.startPoint then<br/>( c + d ) ==: GM_CompositeCurve = #lt; c, d #gt;<br/>
Public Sign
Element Source Role Target Role
«type» GM_Primitive
Name: primitive
Name: proxy
Tag Value
persistence persistent
Constraint Type Status
(orientation = "+") = (primitive = self ) Invariant Approved
Property Value
isFinalSpecialization: 0
Object Type Connection Direction Notes
«type» GM_OrientableSurface Class Generalization From  
«type» GM_Primitive Class Generalization To  
Orientable Interface Dependency To  
«type» GM_OrientableCurve Class Generalization From