1253 lines
49 KiB
VB.net
1253 lines
49 KiB
VB.net
'-----------------------------------------------------------------------------
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' Some sample code for slvs.dll. We draw some geometric entities, provide
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' initial guesses for their positions, and then constrain them. The solver
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' calculates their new positions, in order to satisfy the constraints.
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'
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' The library is distributed as a DLL, but the functions are designed to
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' be usable from .net languages through a P/Invoke. This file contains an
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' example of that process, and a wrapper class around those P/Invoke'd
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' functions that you may wish to use a starting point in your own
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' application.
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'
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' Copyright 2008-2013 Jonathan Westhues.
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'-----------------------------------------------------------------------------
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Imports System.Runtime.InteropServices
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Module VbDemo
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' Call our example functions, which set up some kind of sketch, solve
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' it, and then print the result.
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Sub Main()
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Console.WriteLine("EXAMPLE IN 3d (by objects):")
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Example3dWithObjects()
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Console.WriteLine("")
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Console.WriteLine("EXAMPLE IN 2d (by objects):")
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Example2dWithObjects()
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Console.WriteLine("")
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Console.WriteLine("EXAMPLE IN 3d (by handles):")
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Example3dWithHandles()
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Console.WriteLine("")
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Console.WriteLine("EXAMPLE IN 2d (by handles):")
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Example2dWithHandles()
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Console.WriteLine("")
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End Sub
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'''''''''''''''''''''''''''''''
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' This is the simplest way to use the library. A set of wrapper
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' classes allow us to represent entities (e.g., lines and points)
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' as .net objects. So we create an Slvs object, which will contain
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' the entire sketch, with all the entities and constraints.
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'
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' We then create entity objects (for example, points and lines)
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' associated with that sketch, indicating the initial positions of
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' those entities and any hierarchical relationships among them (e.g.,
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' defining a line entity in terms of endpoint entities). We also add
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' constraints associated with those entities.
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'
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' Finally, we solve, and print the new positions of the entities. If the
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' solution succeeded, then the entities will satisfy the constraints. If
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' not, then the solver will suggest problematic constraints that, if
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' removed, would render the sketch solvable.
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Sub Example3dWithObjects()
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Dim g As UInteger
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Dim slv As New Slvs
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' This will contain a single group, which will arbitrarily number 1.
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g = 1
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Dim p1, p2 As Slvs.Point3d
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' A point, initially at (x y z) = (10 10 10)
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p1 = slv.NewPoint3d(g, 10.0, 10.0, 10.0)
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' and a second point at (20 20 20)
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p2 = slv.NewPoint3d(g, 20.0, 20.0, 20.0)
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Dim ln As Slvs.LineSegment
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' and a line segment connecting them.
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ln = slv.NewLineSegment(g, slv.FreeIn3d(), p1, p2)
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' The distance between the points should be 30.0 units.
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slv.AddConstraint(1, g, Slvs.SLVS_C_PT_PT_DISTANCE, _
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slv.FreeIn3d(), 30.0, p1, p2, Nothing, Nothing)
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' Let's tell the solver to keep the second point as close to constant
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' as possible, instead moving the first point.
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slv.Solve(g, p2, True)
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If (slv.GetResult() = Slvs.SLVS_RESULT_OKAY) Then
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' We call the GetX(), GetY(), and GetZ() functions to see
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' where the solver moved our points to.
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Console.WriteLine(String.Format( _
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"okay; now at ({0:F3}, {1:F3}, {2:F3})", _
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p1.GetX(), p1.GetY(), p1.GetZ()))
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Console.WriteLine(String.Format( _
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" ({0:F3}, {1:F3}, {2:F3})", _
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p2.GetX(), p2.GetY(), p2.GetZ()))
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Console.WriteLine(slv.GetDof().ToString() + " DOF")
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Else
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Console.WriteLine("solve failed")
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End If
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End Sub
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Sub Example2dWithObjects()
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Dim g As UInteger
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Dim slv As New Slvs
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g = 1
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' First, we create our workplane. Its origin corresponds to the origin
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' of our base frame (x y z) = (0 0 0)
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Dim origin As Slvs.Point3d
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origin = slv.NewPoint3d(g, 0.0, 0.0, 0.0)
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' and it is parallel to the xy plane, so it has basis vectors (1 0 0)
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' and (0 1 0).
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Dim normal As Slvs.Normal3d
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normal = slv.NewNormal3d(g, 1.0, 0.0, 0.0, _
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0.0, 1.0, 0.0)
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Dim wrkpl As Slvs.Workplane
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wrkpl = slv.NewWorkplane(g, origin, normal)
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' Now create a second group. We'll solve group 2, while leaving group 1
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' constant; so the workplane that we've created will be locked down,
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' and the solver can't move it.
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g = 2
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' These points are represented by their coordinates (u v) within the
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' workplane, so they need only two parameters each.
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Dim pl1, pl2 As Slvs.Point2d
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pl1 = slv.NewPoint2d(g, wrkpl, 10.0, 20.0)
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pl2 = slv.NewPoint2d(g, wrkpl, 20.0, 10.0)
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' And we create a line segment with those endpoints.
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Dim ln As Slvs.LineSegment
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ln = slv.NewLineSegment(g, wrkpl, pl1, pl2)
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' Now three more points.
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Dim pc, ps, pf As Slvs.Point2d
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pc = slv.NewPoint2d(g, wrkpl, 100.0, 120.0)
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ps = slv.NewPoint2d(g, wrkpl, 120.0, 110.0)
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pf = slv.NewPoint2d(g, wrkpl, 115.0, 115.0)
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' And arc, centered at point pc, starting at point ps, ending at
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' point pf.
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Dim arc As Slvs.ArcOfCircle
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arc = slv.NewArcOfCircle(g, wrkpl, normal, pc, ps, pf)
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' Now one more point, and a distance
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Dim pcc As Slvs.Point2d
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pcc = slv.NewPoint2d(g, wrkpl, 200.0, 200.0)
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Dim r As Slvs.Distance
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r = slv.NewDistance(g, wrkpl, 30.0)
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' And a complete circle, centered at point pcc with radius equal to
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' distance r. The normal is the same as for our workplane.
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Dim circle As Slvs.Circle
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circle = slv.NewCircle(g, wrkpl, pcc, normal, r)
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' The length of our line segment is 30.0 units.
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slv.AddConstraint(1, g, Slvs.SLVS_C_PT_PT_DISTANCE, _
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wrkpl, 30.0, pl1, pl2, Nothing, Nothing)
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' And the distance from our line segment to the origin is 10.0 units.
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slv.AddConstraint(2, g, Slvs.SLVS_C_PT_LINE_DISTANCE, _
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wrkpl, 10.0, origin, Nothing, ln, Nothing)
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' And the line segment is vertical.
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slv.AddConstraint(3, g, Slvs.SLVS_C_VERTICAL, _
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wrkpl, 0.0, Nothing, Nothing, ln, Nothing)
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' And the distance from one endpoint to the origin is 15.0 units.
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slv.AddConstraint(4, g, Slvs.SLVS_C_PT_PT_DISTANCE, _
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wrkpl, 15.0, pl1, origin, Nothing, Nothing)
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' And same for the other endpoint; so if you add this constraint then
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' the sketch is overconstrained and will signal an error.
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'slv.AddConstraint(5, g, Slvs.SLVS_C_PT_PT_DISTANCE, _
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' wrkpl, 18.0, pl2, origin, Nothing, Nothing)
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' The arc and the circle have equal radius.
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slv.AddConstraint(6, g, Slvs.SLVS_C_EQUAL_RADIUS, _
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wrkpl, 0.0, Nothing, Nothing, arc, circle)
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' The arc has radius 17.0 units.
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slv.AddConstraint(7, g, Slvs.SLVS_C_DIAMETER, _
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wrkpl, 2 * 17.0, Nothing, Nothing, arc, Nothing)
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' If the solver fails, then ask it to report which constraints caused
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' the problem.
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slv.Solve(g, True)
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If (slv.GetResult() = Slvs.SLVS_RESULT_OKAY) Then
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Console.WriteLine("solved okay")
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' We call the GetU(), GetV(), and GetDistance() functions to
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' see where the solver moved our points and distances to.
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Console.WriteLine(String.Format( _
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"line from ({0:F3} {1:F3}) to ({2:F3} {3:F3})", _
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pl1.GetU(), pl1.GetV(), _
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pl2.GetU(), pl2.GetV()))
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Console.WriteLine(String.Format( _
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"arc center ({0:F3} {1:F3}) start ({2:F3} {3:F3}) " + _
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"finish ({4:F3} {5:F3})", _
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pc.GetU(), pc.GetV(), _
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ps.GetU(), ps.GetV(), _
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pf.GetU(), pf.GetV()))
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Console.WriteLine(String.Format( _
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"circle center ({0:F3} {1:F3}) radius {2:F3}", _
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pcc.GetU(), pcc.GetV(), _
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r.GetDistance()))
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Console.WriteLine(slv.GetDof().ToString() + " DOF")
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Else
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Console.Write("solve failed; problematic constraints are:")
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Dim t As UInteger
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For Each t In slv.GetFaileds()
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Console.Write(" " + t.ToString())
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Next
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Console.WriteLine("")
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If (slv.GetResult() = Slvs.SLVS_RESULT_INCONSISTENT) Then
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Console.WriteLine("system inconsistent")
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Else
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Console.WriteLine("system nonconvergent")
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End If
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End If
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End Sub
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'''''''''''''''''''''''''''''''
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' This is a lower-level way to use the library. Internally, the library
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' represents parameters, entities, and constraints by integer handles.
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' Here, those handles are assigned manually, and not by the wrapper
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' classes.
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Sub Example3dWithHandles()
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Dim g As UInteger
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Dim slv As New Slvs
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' This will contain a single group, which will arbitrarily number 1.
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g = 1
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' A point, initially at (x y z) = (10 10 10)
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slv.AddParam(1, g, 10.0)
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slv.AddParam(2, g, 10.0)
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slv.AddParam(3, g, 10.0)
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slv.AddPoint3d(101, g, 1, 2, 3)
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' and a second point at (20 20 20)
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slv.AddParam(4, g, 20.0)
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slv.AddParam(5, g, 20.0)
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slv.AddParam(6, g, 20.0)
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slv.AddPoint3d(102, g, 4, 5, 6)
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' and a line segment connecting them.
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slv.AddLineSegment(200, g, Slvs.SLVS_FREE_IN_3D, 101, 102)
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' The distance between the points should be 30.0 units.
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slv.AddConstraint(1, g, Slvs.SLVS_C_PT_PT_DISTANCE, _
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Slvs.SLVS_FREE_IN_3D, 30.0, 101, 102, 0, 0)
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' Let's tell the solver to keep the second point as close to constant
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' as possible, instead moving the first point. That's parameters
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' 4, 5, and 6.
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slv.Solve(g, 4, 5, 6, 0, True)
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If (slv.GetResult() = Slvs.SLVS_RESULT_OKAY) Then
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' Note that we are referring to the parameters by their handles,
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' and not by their index in the list. This is a difference from
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' the C example.
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Console.WriteLine(String.Format( _
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"okay; now at ({0:F3}, {1:F3}, {2:F3})", _
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slv.GetParamByHandle(1), slv.GetParamByHandle(2), _
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slv.GetParamByHandle(3)))
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Console.WriteLine(String.Format( _
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" ({0:F3}, {1:F3}, {2:F3})", _
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slv.GetParamByHandle(4), slv.GetParamByHandle(5), _
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slv.GetParamByHandle(6)))
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Console.WriteLine(slv.GetDof().ToString() + " DOF")
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Else
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Console.WriteLine("solve failed")
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End If
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End Sub
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Sub Example2dWithHandles()
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Dim g As UInteger
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Dim qw, qx, qy, qz As Double
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Dim slv As New Slvs
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g = 1
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' First, we create our workplane. Its origin corresponds to the origin
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' of our base frame (x y z) = (0 0 0)
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slv.AddParam(1, g, 0.0)
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slv.AddParam(2, g, 0.0)
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slv.AddParam(3, g, 0.0)
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slv.AddPoint3d(101, g, 1, 2, 3)
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' and it is parallel to the xy plane, so it has basis vectors (1 0 0)
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' and (0 1 0).
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slv.MakeQuaternion(1, 0, 0, _
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0, 1, 0, qw, qx, qy, qz)
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slv.AddParam(4, g, qw)
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slv.AddParam(5, g, qx)
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slv.AddParam(6, g, qy)
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slv.AddParam(7, g, qz)
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slv.AddNormal3d(102, g, 4, 5, 6, 7)
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slv.AddWorkplane(200, g, 101, 102)
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' Now create a second group. We'll solve group 2, while leaving group 1
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' constant; so the workplane that we've created will be locked down,
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' and the solver can't move it.
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g = 2
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' These points are represented by their coordinates (u v) within the
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' workplane, so they need only two parameters each.
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slv.AddParam(11, g, 10.0)
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slv.AddParam(12, g, 20.0)
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slv.AddPoint2d(301, g, 200, 11, 12)
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slv.AddParam(13, g, 20.0)
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slv.AddParam(14, g, 10.0)
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slv.AddPoint2d(302, g, 200, 13, 14)
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' And we create a line segment with those endpoints.
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slv.AddLineSegment(400, g, 200, 301, 302)
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' Now three more points.
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slv.AddParam(15, g, 100.0)
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slv.AddParam(16, g, 120.0)
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slv.AddPoint2d(303, g, 200, 15, 16)
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slv.AddParam(17, g, 120.0)
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slv.AddParam(18, g, 110.0)
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slv.AddPoint2d(304, g, 200, 17, 18)
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slv.AddParam(19, g, 115.0)
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slv.AddParam(20, g, 115.0)
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slv.AddPoint2d(305, g, 200, 19, 20)
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' And arc, centered at point 303, starting at point 304, ending at
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' point 305.
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slv.AddArcOfCircle(401, g, 200, 102, 303, 304, 305)
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' Now one more point, and a distance
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slv.AddParam(21, g, 200.0)
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slv.AddParam(22, g, 200.0)
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slv.AddPoint2d(306, g, 200, 21, 22)
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slv.AddParam(23, g, 30.0)
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slv.AddDistance(307, g, 200, 23)
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' And a complete circle, centered at point 306 with radius equal to
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' distance 307. The normal is 102, the same as our workplane.
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slv.AddCircle(402, g, 200, 306, 102, 307)
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' The length of our line segment is 30.0 units.
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slv.AddConstraint(1, g, Slvs.SLVS_C_PT_PT_DISTANCE, _
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200, 30.0, 301, 302, 0, 0)
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' And the distance from our line segment to the origin is 10.0 units.
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slv.AddConstraint(2, g, Slvs.SLVS_C_PT_LINE_DISTANCE, _
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200, 10.0, 101, 0, 400, 0)
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' And the line segment is vertical.
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slv.AddConstraint(3, g, Slvs.SLVS_C_VERTICAL, _
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200, 0.0, 0, 0, 400, 0)
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' And the distance from one endpoint to the origin is 15.0 units.
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slv.AddConstraint(4, g, Slvs.SLVS_C_PT_PT_DISTANCE, _
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200, 15.0, 301, 101, 0, 0)
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' And same for the other endpoint; so if you add this constraint then
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' the sketch is overconstrained and will signal an error.
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'slv.AddConstraint(5, g, Slvs.SLVS_C_PT_PT_DISTANCE, _
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' 200, 18.0, 302, 101, 0, 0)
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' The arc and the circle have equal radius.
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slv.AddConstraint(6, g, Slvs.SLVS_C_EQUAL_RADIUS, _
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200, 0.0, 0, 0, 401, 402)
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' The arc has radius 17.0 units.
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slv.AddConstraint(7, g, Slvs.SLVS_C_DIAMETER, _
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200, 2 * 17.0, 0, 0, 401, 0)
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' If the solver fails, then ask it to report which constraints caused
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' the problem.
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slv.Solve(g, 0, 0, 0, 0, True)
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If (slv.GetResult() = Slvs.SLVS_RESULT_OKAY) Then
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Console.WriteLine("solved okay")
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' Note that we are referring to the parameters by their handles,
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' and not by their index in the list. This is a difference from
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' the C example.
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Console.WriteLine(String.Format( _
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"line from ({0:F3} {1:F3}) to ({2:F3} {3:F3})", _
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slv.GetParamByHandle(11), slv.GetParamByHandle(12), _
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slv.GetParamByHandle(13), slv.GetParamByHandle(14)))
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Console.WriteLine(String.Format( _
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"arc center ({0:F3} {1:F3}) start ({2:F3} {3:F3}) " + _
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"finish ({4:F3} {5:F3})", _
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slv.GetParamByHandle(15), slv.GetParamByHandle(16), _
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slv.GetParamByHandle(17), slv.GetParamByHandle(18), _
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slv.GetParamByHandle(19), slv.GetParamByHandle(20)))
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Console.WriteLine(String.Format( _
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"circle center ({0:F3} {1:F3}) radius {2:F3}", _
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slv.GetParamByHandle(21), slv.GetParamByHandle(22), _
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slv.GetParamByHandle(23)))
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Console.WriteLine(slv.GetDof().ToString() + " DOF")
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Else
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Console.Write("solve failed; problematic constraints are:")
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Dim t As UInteger
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For Each t In slv.GetFaileds()
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Console.Write(" " + t.ToString())
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Next
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Console.WriteLine("")
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If (slv.GetResult() = Slvs.SLVS_RESULT_INCONSISTENT) Then
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Console.WriteLine("system inconsistent")
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Else
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Console.WriteLine("system nonconvergent")
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End If
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End If
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End Sub
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'''''''''''''''''''''''''''''''
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' The interface to the library, and the wrapper functions around
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' that interface, follow.
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' These are the core functions imported from the DLL
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<DllImport("slvs.dll", CallingConvention:=CallingConvention.Cdecl)> _
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Public Sub Slvs_Solve(ByVal sys As IntPtr, ByVal hg As UInteger)
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End Sub
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<DllImport("slvs.dll", CallingConvention:=CallingConvention.Cdecl)> _
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Public Sub Slvs_MakeQuaternion(
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ByVal ux As Double, ByVal uy As Double, ByVal uz As Double,
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ByVal vx As Double, ByVal vy As Double, ByVal vz As Double,
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ByRef qw As Double, ByRef qx As Double, ByRef qy As Double,
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ByRef qz As Double)
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End Sub
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' And this is a thin wrapper around those functions, which provides
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' convenience functions similar to those provided in slvs.h for the C API.
|
|
Public Class Slvs
|
|
|
|
<StructLayout(LayoutKind.Sequential)> Public Structure Slvs_Param
|
|
Public h As UInteger
|
|
Public group As UInteger
|
|
Public val As Double
|
|
End Structure
|
|
|
|
Public Const SLVS_FREE_IN_3D As Integer = 0
|
|
|
|
Public Const SLVS_E_POINT_IN_3D As Integer = 50000
|
|
Public Const SLVS_E_POINT_IN_2D As Integer = 50001
|
|
Public Const SLVS_E_NORMAL_IN_3D As Integer = 60000
|
|
Public Const SLVS_E_NORMAL_IN_2D As Integer = 60001
|
|
Public Const SLVS_E_DISTANCE As Integer = 70000
|
|
Public Const SLVS_E_WORKPLANE As Integer = 80000
|
|
Public Const SLVS_E_LINE_SEGMENT As Integer = 80001
|
|
Public Const SLVS_E_CUBIC As Integer = 80002
|
|
Public Const SLVS_E_CIRCLE As Integer = 80003
|
|
Public Const SLVS_E_ARC_OF_CIRCLE As Integer = 80004
|
|
|
|
<StructLayout(LayoutKind.Sequential)> Public Structure Slvs_Entity
|
|
Public h As UInteger
|
|
Public group As UInteger
|
|
|
|
Public type As Integer
|
|
|
|
Public wrkpl As UInteger
|
|
Public point0 As UInteger
|
|
Public point1 As UInteger
|
|
Public point2 As UInteger
|
|
Public point3 As UInteger
|
|
Public normal As UInteger
|
|
Public distance As UInteger
|
|
|
|
Public param0 As UInteger
|
|
Public param1 As UInteger
|
|
Public param2 As UInteger
|
|
Public param3 As UInteger
|
|
End Structure
|
|
|
|
Public Const SLVS_C_POINTS_COINCIDENT As Integer = 100000
|
|
Public Const SLVS_C_PT_PT_DISTANCE As Integer = 100001
|
|
Public Const SLVS_C_PT_PLANE_DISTANCE As Integer = 100002
|
|
Public Const SLVS_C_PT_LINE_DISTANCE As Integer = 100003
|
|
Public Const SLVS_C_PT_FACE_DISTANCE As Integer = 100004
|
|
Public Const SLVS_C_PT_IN_PLANE As Integer = 100005
|
|
Public Const SLVS_C_PT_ON_LINE As Integer = 100006
|
|
Public Const SLVS_C_PT_ON_FACE As Integer = 100007
|
|
Public Const SLVS_C_EQUAL_LENGTH_LINES As Integer = 100008
|
|
Public Const SLVS_C_LENGTH_RATIO As Integer = 100009
|
|
Public Const SLVS_C_EQ_LEN_PT_LINE_D As Integer = 100010
|
|
Public Const SLVS_C_EQ_PT_LN_DISTANCES As Integer = 100011
|
|
Public Const SLVS_C_EQUAL_ANGLE As Integer = 100012
|
|
Public Const SLVS_C_EQUAL_LINE_ARC_LEN As Integer = 100013
|
|
Public Const SLVS_C_SYMMETRIC As Integer = 100014
|
|
Public Const SLVS_C_SYMMETRIC_HORIZ As Integer = 100015
|
|
Public Const SLVS_C_SYMMETRIC_VERT As Integer = 100016
|
|
Public Const SLVS_C_SYMMETRIC_LINE As Integer = 100017
|
|
Public Const SLVS_C_AT_MIDPOINT As Integer = 100018
|
|
Public Const SLVS_C_HORIZONTAL As Integer = 100019
|
|
Public Const SLVS_C_VERTICAL As Integer = 100020
|
|
Public Const SLVS_C_DIAMETER As Integer = 100021
|
|
Public Const SLVS_C_PT_ON_CIRCLE As Integer = 100022
|
|
Public Const SLVS_C_SAME_ORIENTATION As Integer = 100023
|
|
Public Const SLVS_C_ANGLE As Integer = 100024
|
|
Public Const SLVS_C_PARALLEL As Integer = 100025
|
|
Public Const SLVS_C_PERPENDICULAR As Integer = 100026
|
|
Public Const SLVS_C_ARC_LINE_TANGENT As Integer = 100027
|
|
Public Const SLVS_C_CUBIC_LINE_TANGENT As Integer = 100028
|
|
Public Const SLVS_C_EQUAL_RADIUS As Integer = 100029
|
|
Public Const SLVS_C_PROJ_PT_DISTANCE As Integer = 100030
|
|
Public Const SLVS_C_WHERE_DRAGGED As Integer = 100031
|
|
Public Const SLVS_C_CURVE_CURVE_TANGENT As Integer = 100032
|
|
Public Const SLVS_C_LENGTH_DIFFERENCE As Integer = 100033
|
|
|
|
<StructLayout(LayoutKind.Sequential)> Public Structure Slvs_Constraint
|
|
Public h As UInteger
|
|
Public group As UInteger
|
|
|
|
Public type As Integer
|
|
|
|
Public wrkpl As UInteger
|
|
|
|
Public valA As Double
|
|
Public ptA As UInteger
|
|
Public ptB As UInteger
|
|
Public entityA As UInteger
|
|
Public entityB As UInteger
|
|
Public entityC As UInteger
|
|
Public entityD As UInteger
|
|
|
|
Public other As Integer
|
|
Public other2 As Integer
|
|
End Structure
|
|
|
|
Public Const SLVS_RESULT_OKAY As Integer = 0
|
|
Public Const SLVS_RESULT_INCONSISTENT As Integer = 1
|
|
Public Const SLVS_RESULT_DIDNT_CONVERGE As Integer = 2
|
|
Public Const SLVS_RESULT_TOO_MANY_UNKNOWNS As Integer = 3
|
|
|
|
<StructLayout(LayoutKind.Sequential)> Public Structure Slvs_System
|
|
Public param As IntPtr
|
|
Public params As Integer
|
|
Public entity As IntPtr
|
|
Public entities As Integer
|
|
Public constraint As IntPtr
|
|
Public constraints As Integer
|
|
|
|
Public dragged0 As UInteger
|
|
Public dragged1 As UInteger
|
|
Public dragged2 As UInteger
|
|
Public dragged3 As UInteger
|
|
|
|
Public calculatedFaileds As Integer
|
|
|
|
Public failed As IntPtr
|
|
Public faileds As Integer
|
|
|
|
Public dof As Integer
|
|
|
|
Public result As Integer
|
|
End Structure
|
|
|
|
Dim Params As New List(Of Slvs_Param)
|
|
Dim Entities As New List(Of Slvs_Entity)
|
|
Dim Constraints As New List(Of Slvs_Constraint)
|
|
|
|
Dim Faileds As New List(Of UInteger)
|
|
|
|
Dim Result As Integer
|
|
Dim Dof As Integer
|
|
|
|
' Return the value of a parameter, by its handle. This function
|
|
' may be used, for example, to obtain the new values of the
|
|
' parameters after a call to Solve().
|
|
Public Function GetParamByHandle(ByVal h As UInteger) As Double
|
|
Dim t As Slvs_Param
|
|
For Each t In Params
|
|
If (t.h = h) Then
|
|
Return t.val
|
|
End If
|
|
Next
|
|
Throw New Exception("Invalid parameter handle.")
|
|
End Function
|
|
|
|
' Return the value of a parameter, by its index in the list (where
|
|
' that index is determined by the order in which the parameters
|
|
' were inserted with AddParam(), not by its handle).
|
|
Public Function GetParamByIndex(ByVal i As Integer) As Double
|
|
Return Params(i).val
|
|
End Function
|
|
|
|
' Get the result after a call to Solve(). This may be
|
|
' SLVS_RESULT_OKAY - it worked
|
|
' SLVS_RESULT_INCONSISTENT - failed, inconsistent
|
|
' SLVS_RESULT_DIDNT_CONVERGE - consistent, but still failed
|
|
' SLVS_RESULT_TOO_MANY_UNKNOWNS - too many parameters in one group
|
|
Public Function GetResult() As Integer
|
|
Return Result
|
|
End Function
|
|
|
|
' After a call to Solve(), this returns the number of unconstrained
|
|
' degrees of freedom for the sketch.
|
|
Public Function GetDof() As Integer
|
|
Return Dof
|
|
End Function
|
|
|
|
' After a failing call to Solve(), this returns the list of
|
|
' constraints, identified by their handle, that would fix the
|
|
' system if they were deleted. This list will be populated only
|
|
' if calculateFaileds is True in the Solve() call.
|
|
Public Function GetFaileds() As List(Of UInteger)
|
|
Return Faileds
|
|
End Function
|
|
|
|
' Clear our lists of entities, constraints, and parameters.
|
|
Public Sub ResetAll()
|
|
Params.Clear()
|
|
Entities.Clear()
|
|
Constraints.Clear()
|
|
End Sub
|
|
|
|
|
|
'''''''''''''''''''''''''''''''
|
|
' These functions are broadly similar to the Slvs_Make...
|
|
' functions in slvs.h. See the file DOC.txt accompanying the
|
|
' library for details.
|
|
|
|
Public Sub AddParam(ByVal h As UInteger, ByVal group As UInteger,
|
|
ByVal val As Double)
|
|
Dim p As Slvs_Param
|
|
p.h = h
|
|
p.group = group
|
|
p.val = val
|
|
Params.Add(p)
|
|
End Sub
|
|
|
|
Public Sub AddPoint2d(ByVal h As UInteger, ByVal group As UInteger,
|
|
ByVal wrkpl As UInteger,
|
|
ByVal u As UInteger, ByVal v As UInteger)
|
|
Dim e As Slvs_Entity
|
|
e.h = h
|
|
e.group = group
|
|
e.type = SLVS_E_POINT_IN_2D
|
|
e.wrkpl = wrkpl
|
|
e.param0 = u
|
|
e.param1 = v
|
|
Entities.Add(e)
|
|
End Sub
|
|
|
|
Public Sub AddPoint3d(ByVal h As UInteger, ByVal group As UInteger,
|
|
ByVal x As UInteger, ByVal y As UInteger, ByVal z As UInteger)
|
|
Dim e As Slvs_Entity
|
|
e.h = h
|
|
e.group = group
|
|
e.type = SLVS_E_POINT_IN_3D
|
|
e.wrkpl = SLVS_FREE_IN_3D
|
|
e.param0 = x
|
|
e.param1 = y
|
|
e.param2 = z
|
|
Entities.Add(e)
|
|
End Sub
|
|
|
|
Public Sub AddNormal3d(ByVal h As UInteger, ByVal group As UInteger,
|
|
ByVal qw As UInteger, ByVal qx As UInteger,
|
|
ByVal qy As UInteger, ByVal qz As UInteger)
|
|
Dim e As Slvs_Entity
|
|
e.h = h
|
|
e.group = group
|
|
e.type = SLVS_E_NORMAL_IN_3D
|
|
e.wrkpl = SLVS_FREE_IN_3D
|
|
e.param0 = qw
|
|
e.param1 = qx
|
|
e.param2 = qy
|
|
e.param3 = qz
|
|
Entities.Add(e)
|
|
End Sub
|
|
|
|
Public Sub AddNormal2d(ByVal h As UInteger, ByVal group As UInteger,
|
|
ByVal wrkpl As UInteger)
|
|
Dim e As Slvs_Entity
|
|
e.h = h
|
|
e.group = group
|
|
e.type = SLVS_E_NORMAL_IN_2D
|
|
e.wrkpl = wrkpl
|
|
Entities.Add(e)
|
|
End Sub
|
|
|
|
Public Sub AddDistance(ByVal h As UInteger, ByVal group As UInteger,
|
|
ByVal wrkpl As UInteger, ByVal d As UInteger)
|
|
Dim e As Slvs_Entity
|
|
e.h = h
|
|
e.group = group
|
|
e.type = SLVS_E_DISTANCE
|
|
e.wrkpl = wrkpl
|
|
e.param0 = d
|
|
Entities.Add(e)
|
|
End Sub
|
|
|
|
Public Sub AddLineSegment(ByVal h As UInteger, ByVal group As UInteger,
|
|
ByVal wrkpl As UInteger,
|
|
ByVal ptA As UInteger, ByVal ptB As UInteger)
|
|
Dim e As Slvs_Entity
|
|
e.h = h
|
|
e.group = group
|
|
e.type = SLVS_E_LINE_SEGMENT
|
|
e.wrkpl = wrkpl
|
|
e.point0 = ptA
|
|
e.point1 = ptB
|
|
Entities.Add(e)
|
|
End Sub
|
|
|
|
Public Sub AddCubic(ByVal h As UInteger, ByVal group As UInteger,
|
|
ByVal wrkpl As UInteger,
|
|
ByVal pt0 As UInteger, ByVal pt1 As UInteger,
|
|
ByVal pt2 As UInteger, ByVal pt3 As UInteger)
|
|
Dim e As Slvs_Entity
|
|
e.h = h
|
|
e.group = group
|
|
e.type = SLVS_E_CUBIC
|
|
e.wrkpl = wrkpl
|
|
e.point0 = pt0
|
|
e.point1 = pt1
|
|
e.point2 = pt2
|
|
e.point3 = pt3
|
|
Entities.Add(e)
|
|
End Sub
|
|
|
|
Public Sub AddArcOfCircle(ByVal h As UInteger, ByVal group As UInteger,
|
|
ByVal wrkpl As UInteger,
|
|
ByVal normal As UInteger,
|
|
ByVal center As UInteger,
|
|
ByVal pstart As UInteger,
|
|
ByVal pend As UInteger)
|
|
Dim e As Slvs_Entity
|
|
e.h = h
|
|
e.group = group
|
|
e.type = SLVS_E_ARC_OF_CIRCLE
|
|
e.wrkpl = wrkpl
|
|
e.normal = normal
|
|
e.point0 = center
|
|
e.point1 = pstart
|
|
e.point2 = pend
|
|
Entities.Add(e)
|
|
End Sub
|
|
|
|
Public Sub AddCircle(ByVal h As UInteger, ByVal group As UInteger,
|
|
ByVal wrkpl As UInteger,
|
|
ByVal center As UInteger, ByVal normal As UInteger,
|
|
ByVal radius As UInteger)
|
|
Dim e As Slvs_Entity
|
|
e.h = h
|
|
e.group = group
|
|
e.type = SLVS_E_CIRCLE
|
|
e.wrkpl = wrkpl
|
|
e.point0 = center
|
|
e.normal = normal
|
|
e.distance = radius
|
|
Entities.Add(e)
|
|
End Sub
|
|
|
|
Public Sub AddWorkplane(ByVal h As UInteger, ByVal group As UInteger,
|
|
ByVal origin As UInteger,
|
|
ByVal normal As UInteger)
|
|
Dim e As Slvs_Entity
|
|
e.h = h
|
|
e.group = group
|
|
e.type = SLVS_E_WORKPLANE
|
|
e.wrkpl = SLVS_FREE_IN_3D
|
|
e.point0 = origin
|
|
e.normal = normal
|
|
Entities.Add(e)
|
|
End Sub
|
|
|
|
Public Sub AddConstraint(ByVal h As UInteger,
|
|
ByVal group As UInteger,
|
|
ByVal type As Integer,
|
|
ByVal wrkpl As UInteger,
|
|
ByVal valA As Double,
|
|
ByVal ptA As UInteger,
|
|
ByVal ptB As UInteger,
|
|
ByVal entityA As UInteger,
|
|
ByVal entityB As UInteger)
|
|
Dim c As Slvs_Constraint
|
|
c.h = h
|
|
c.group = group
|
|
c.type = type
|
|
c.wrkpl = wrkpl
|
|
c.valA = valA
|
|
c.ptA = ptA
|
|
c.ptB = ptB
|
|
c.entityA = entityA
|
|
c.entityB = entityB
|
|
Constraints.Add(c)
|
|
End Sub
|
|
|
|
' Solve the system. The geometry of the system must already have
|
|
' been specified through the Add...() calls. The result of the
|
|
' solution process may be obtained by calling GetResult(),
|
|
' GetFaileds(), GetDof(), and GetParamByXXX().
|
|
'
|
|
' The parameters draggedx (indicated by their handles) will be held
|
|
' as close as possible to their original positions, even if this
|
|
' results in large moves for other parameters. This feature may be
|
|
' useful if, for example, the user is dragging the point whose
|
|
' location is defined by those parameters. Unused draggedx
|
|
' parameters may be specified as zero.
|
|
Public Sub Solve(ByVal group As UInteger,
|
|
ByVal dragged0 As UInteger, ByVal dragged1 As UInteger,
|
|
ByVal dragged2 As UInteger, ByVal dragged3 As UInteger,
|
|
ByVal calculateFaileds As Boolean)
|
|
Dim i As Integer
|
|
|
|
Dim pp, p(Params.Count()) As Slvs_Param
|
|
i = 0
|
|
For Each pp In Params
|
|
p(i) = pp
|
|
i += 1
|
|
Next
|
|
|
|
Dim ee, e(Entities.Count()) As Slvs_Entity
|
|
i = 0
|
|
For Each ee In Entities
|
|
e(i) = ee
|
|
i += 1
|
|
Next
|
|
|
|
Dim cc, c(Constraints.Count()) As Slvs_Constraint
|
|
i = 0
|
|
For Each cc In Constraints
|
|
c(i) = cc
|
|
i += 1
|
|
Next
|
|
Dim f(Constraints.Count()) As UInteger
|
|
|
|
Dim sys As Slvs_System
|
|
|
|
Dim pgc, egc, cgc As GCHandle
|
|
pgc = GCHandle.Alloc(p, GCHandleType.Pinned)
|
|
sys.param = pgc.AddrOfPinnedObject()
|
|
sys.params = Params.Count()
|
|
egc = GCHandle.Alloc(e, GCHandleType.Pinned)
|
|
sys.entity = egc.AddrOfPinnedObject()
|
|
sys.entities = Entities.Count()
|
|
cgc = GCHandle.Alloc(c, GCHandleType.Pinned)
|
|
sys.constraint = cgc.AddrOfPinnedObject()
|
|
sys.constraints = Constraints.Count()
|
|
|
|
sys.dragged0 = dragged0
|
|
sys.dragged1 = dragged1
|
|
sys.dragged2 = dragged2
|
|
sys.dragged3 = dragged3
|
|
|
|
Dim fgc As GCHandle
|
|
fgc = GCHandle.Alloc(f, GCHandleType.Pinned)
|
|
If calculateFaileds Then
|
|
sys.calculatedFaileds = 1
|
|
Else
|
|
sys.calculatedFaileds = 0
|
|
End If
|
|
sys.faileds = Constraints.Count()
|
|
sys.failed = fgc.AddrOfPinnedObject()
|
|
|
|
Dim sysgc As GCHandle
|
|
sysgc = GCHandle.Alloc(sys, GCHandleType.Pinned)
|
|
|
|
Slvs_Solve(sysgc.AddrOfPinnedObject(), group)
|
|
|
|
sys = sysgc.Target
|
|
|
|
For i = 0 To Params.Count() - 1
|
|
Params(i) = p(i)
|
|
Next
|
|
|
|
Faileds.Clear()
|
|
For i = 0 To sys.faileds - 1
|
|
Faileds.Add(f(i))
|
|
Next
|
|
|
|
sysgc.Free()
|
|
fgc.Free()
|
|
pgc.Free()
|
|
egc.Free()
|
|
cgc.Free()
|
|
|
|
Result = sys.result
|
|
Dof = sys.dof
|
|
End Sub
|
|
' A simpler version of the function, if the parameters being dragged
|
|
' correspond to a single point.
|
|
Public Sub Solve(ByVal group As UInteger, ByVal dragged As Point,
|
|
ByVal calculatedFaileds As Boolean)
|
|
If TypeOf dragged Is Point2d Then
|
|
Dim p As Point2d
|
|
p = dragged
|
|
Solve(group, p.up.H, p.vp.H, 0, 0, calculatedFaileds)
|
|
ElseIf TypeOf dragged Is Point3d Then
|
|
Dim p As Point3d
|
|
p = dragged
|
|
Solve(group, p.xp.H, p.yp.H, p.zp.H, 0, calculatedFaileds)
|
|
Else
|
|
Throw New Exception("Can't get dragged params for point.")
|
|
End If
|
|
End Sub
|
|
' or if it's a single distance (e.g., the radius of a circle)
|
|
Public Sub Solve(ByVal group As UInteger, ByVal dragged As Distance,
|
|
ByVal calculatedFaileds As Boolean)
|
|
Solve(group, dragged.dp.H, 0, 0, 0, calculatedFaileds)
|
|
End Sub
|
|
' or if it's nothing.
|
|
Public Sub Solve(ByVal group As UInteger,
|
|
ByVal calculateFaileds As Boolean)
|
|
Solve(group, 0, 0, 0, 0, calculateFaileds)
|
|
End Sub
|
|
|
|
' Return the quaternion in (qw, qx, qy, qz) that represents a
|
|
' rotation from the base frame to a coordinate system with the
|
|
' specified basis vectors u and v. For example, u = (0, 1, 0)
|
|
' and v = (0, 0, 1) specifies the yz plane, such that a point with
|
|
' (u, v) = (7, 12) has (x, y, z) = (0, 7, 12).
|
|
Public Sub MakeQuaternion(
|
|
ByVal ux As Double, ByVal uy As Double, ByVal uz As Double,
|
|
ByVal vx As Double, ByVal vy As Double, ByVal vz As Double,
|
|
ByRef qw As Double, ByRef qx As Double, ByRef qy As Double,
|
|
ByRef qz As Double)
|
|
Slvs_MakeQuaternion(ux, uy, uz, _
|
|
vx, vy, vz, _
|
|
qw, qx, qy, qz)
|
|
End Sub
|
|
|
|
Public Function FreeIn3d()
|
|
Return New Workplane(Me)
|
|
End Function
|
|
|
|
|
|
'''''''''''''''''''''''''''''''
|
|
' Functions to create the object-oriented wrappers defined below.
|
|
|
|
Public Function NewParam(ByVal group As UInteger, ByVal val As Double)
|
|
Return New Param(Me, group, val)
|
|
End Function
|
|
Public Function NewPoint2d(ByVal group As UInteger,
|
|
ByVal wrkpl As Workplane,
|
|
ByVal u As Double, ByVal v As Double)
|
|
Return New Point2d(Me, group, wrkpl, u, v)
|
|
End Function
|
|
Public Function NewPoint2d(ByVal group As UInteger,
|
|
ByVal wrkpl As Workplane,
|
|
ByVal u As Param, ByVal v As Param)
|
|
Return New Point2d(Me, group, wrkpl, u, v)
|
|
End Function
|
|
Public Function NewPoint3d(ByVal group As UInteger,
|
|
ByVal x As Double,
|
|
ByVal y As Double,
|
|
ByVal z As Double)
|
|
Return New Point3d(Me, group, x, y, z)
|
|
End Function
|
|
Public Function NewPoint3d(ByVal group As UInteger,
|
|
ByVal x As Param,
|
|
ByVal y As Param,
|
|
ByVal z As Param)
|
|
Return New Point3d(Me, group, x, y, z)
|
|
End Function
|
|
Public Function NewNormal3d(ByVal group As UInteger,
|
|
ByVal ux As Double, ByVal uy As Double, ByVal uz As Double,
|
|
ByVal vx As Double, ByVal vy As Double, ByVal vz As Double)
|
|
Return New Normal3d(Me, group, ux, uy, uz, vx, vy, vz)
|
|
End Function
|
|
Public Function NewNormal3d(ByVal group As UInteger,
|
|
ByVal qw As Param, ByVal qx As Param,
|
|
ByVal qy As Param, ByVal qz As Param)
|
|
Return New Normal3d(Me, group, qw, qx, qy, qz)
|
|
End Function
|
|
Public Function NewNormal2d(ByVal group As UInteger,
|
|
ByVal wrkpl As Workplane)
|
|
Return New Normal2d(Me, group, wrkpl)
|
|
End Function
|
|
Public Function NewDistance(ByVal group As UInteger,
|
|
ByVal wrkpl As Workplane, ByVal d As Double)
|
|
Return New Distance(Me, group, wrkpl, d)
|
|
End Function
|
|
Public Function NewDistance(ByVal group As UInteger,
|
|
ByVal wrkpl As Workplane, ByVal d As Param)
|
|
Return New Distance(Me, group, wrkpl, d)
|
|
End Function
|
|
Public Function NewLineSegment(ByVal group As UInteger,
|
|
ByVal wrkpl As Workplane,
|
|
ByVal ptA As Point, ByVal ptB As Point)
|
|
Return New LineSegment(Me, group, wrkpl, ptA, ptB)
|
|
End Function
|
|
Public Function NewArcOfCircle(ByVal group As UInteger,
|
|
ByVal wrkpl As Workplane,
|
|
ByVal normal As Normal,
|
|
ByVal center As Point,
|
|
ByVal pstart As Point,
|
|
ByVal pend As Point)
|
|
Return New ArcOfCircle(Me, group, wrkpl, normal, _
|
|
center, pstart, pend)
|
|
End Function
|
|
Public Function NewCircle(ByVal group As UInteger,
|
|
ByVal wrkpl As Workplane,
|
|
ByVal center As Point,
|
|
ByVal normal As Normal,
|
|
ByVal radius As Distance)
|
|
Return New Circle(Me, group, wrkpl, center, normal, radius)
|
|
End Function
|
|
Public Function NewWorkplane(ByVal group As UInteger,
|
|
ByVal origin As Point,
|
|
ByVal normal As Normal)
|
|
Return New Workplane(Me, group, origin, normal)
|
|
End Function
|
|
|
|
Public Sub AddConstraint(ByVal H As UInteger, ByVal group As UInteger,
|
|
ByVal type As Integer,
|
|
ByVal wrkpl As Workplane,
|
|
ByVal valA As Double,
|
|
ByVal ptA As Point, ByVal ptB As Point,
|
|
ByVal entityA As Entity,
|
|
ByVal entityB As Entity)
|
|
AddConstraint(H, group, type, _
|
|
If(IsNothing(wrkpl), 0, wrkpl.H), _
|
|
valA, _
|
|
If(IsNothing(ptA), 0, ptA.H), _
|
|
If(IsNothing(ptB), 0, ptB.H), _
|
|
If(IsNothing(entityA), 0, entityA.H), _
|
|
If(IsNothing(entityB), 0, entityB.H))
|
|
End Sub
|
|
|
|
|
|
'''''''''''''''''''''''''''''''
|
|
' The object-oriented wrapper classes themselves, to allow the
|
|
' representation of entities and constraints as .net objects, not
|
|
' integer handles. These don't do any work themselves, beyond
|
|
' allocating and storing a unique integer handle.
|
|
'
|
|
' These functions will assign parameters and entities with
|
|
' consecutive handles starting from 1. If they are intermixed
|
|
' with parameters and entities with user-specified handles, then
|
|
' those handles must be chosen not to conflict, e.g. starting
|
|
' from 100 000 or another large number.
|
|
|
|
Public Class Param
|
|
Public Slv As Slvs
|
|
Public H As UInteger
|
|
|
|
Public Sub New(ByVal s As Slvs, ByVal group As UInteger,
|
|
ByVal val As Double)
|
|
Slv = s
|
|
H = Slv.Params.Count() + 1
|
|
Slv.AddParam(H, group, val)
|
|
End Sub
|
|
End Class
|
|
|
|
Public MustInherit Class Entity
|
|
Public Slv As Slvs
|
|
Public H As UInteger
|
|
|
|
Public Sub New(ByVal s As Slvs)
|
|
Slv = s
|
|
H = Slv.Entities.Count() + 1
|
|
End Sub
|
|
End Class
|
|
|
|
Public MustInherit Class Point
|
|
Inherits Entity
|
|
Public Sub New(ByVal s As Slvs)
|
|
MyBase.New(s)
|
|
End Sub
|
|
End Class
|
|
|
|
Public MustInherit Class Normal
|
|
Inherits Entity
|
|
Public Sub New(ByVal s As Slvs)
|
|
MyBase.New(s)
|
|
End Sub
|
|
End Class
|
|
|
|
Public Class Point2d
|
|
Inherits Point
|
|
Public up, vp As Param
|
|
Public Sub New(ByVal s As Slvs, ByVal group As UInteger,
|
|
ByVal wrkpl As Workplane,
|
|
ByVal u As Double, ByVal v As Double)
|
|
MyBase.New(s)
|
|
up = New Param(Slv, group, u)
|
|
vp = New Param(Slv, group, v)
|
|
Slv.AddPoint2d(H, group, wrkpl.H, up.H, vp.H)
|
|
End Sub
|
|
Public Sub New(ByVal s As Slvs, ByVal group As UInteger,
|
|
ByVal wrkpl As Workplane,
|
|
ByVal u As Param, ByVal v As Param)
|
|
MyBase.New(s)
|
|
Slv.AddPoint2d(H, group, wrkpl.H, u.H, v.H)
|
|
up = u
|
|
vp = v
|
|
End Sub
|
|
Function GetU()
|
|
Return Slv.GetParamByHandle(up.H)
|
|
End Function
|
|
Function GetV()
|
|
Return Slv.GetParamByHandle(vp.H)
|
|
End Function
|
|
End Class
|
|
|
|
Public Class Point3d
|
|
Inherits Point
|
|
Public xp, yp, zp As Param
|
|
Public Sub New(ByVal s As Slvs, ByVal group As UInteger,
|
|
ByVal x As Double, ByVal y As Double,
|
|
ByVal z As Double)
|
|
MyBase.New(s)
|
|
xp = New Param(Slv, group, x)
|
|
yp = New Param(Slv, group, y)
|
|
zp = New Param(Slv, group, z)
|
|
Slv.AddPoint3d(H, group, xp.H, yp.H, zp.H)
|
|
End Sub
|
|
Public Sub New(ByVal s As Slvs, ByVal group As UInteger,
|
|
ByVal x As Param, ByVal y As Param, ByVal z As Param)
|
|
MyBase.New(s)
|
|
Slv.AddPoint3d(H, group, x.H, y.H, z.H)
|
|
xp = x
|
|
yp = y
|
|
zp = z
|
|
End Sub
|
|
Function GetX()
|
|
Return Slv.GetParamByHandle(xp.H)
|
|
End Function
|
|
Function GetY()
|
|
Return Slv.GetParamByHandle(yp.H)
|
|
End Function
|
|
Function GetZ()
|
|
Return Slv.GetParamByHandle(zp.H)
|
|
End Function
|
|
End Class
|
|
|
|
Public Class Normal3d
|
|
Inherits Normal
|
|
Dim qwp, qxp, qyp, qzp As Param
|
|
Public Sub New(ByVal s As Slvs, ByVal group As UInteger,
|
|
ByVal ux As Double, ByVal uy As Double, ByVal uz As Double,
|
|
ByVal vx As Double, ByVal vy As Double, ByVal vz As Double)
|
|
MyBase.New(s)
|
|
Dim qw, qx, qy, qz As Double
|
|
Slv.MakeQuaternion(ux, uy, uz, vx, vy, vz, qw, qx, qy, qz)
|
|
qwp = New Param(Slv, group, qw)
|
|
qxp = New Param(Slv, group, qx)
|
|
qyp = New Param(Slv, group, qy)
|
|
qzp = New Param(Slv, group, qz)
|
|
Slv.AddNormal3d(H, group, qwp.H, qxp.H, qyp.H, qzp.H)
|
|
End Sub
|
|
Public Sub New(ByVal s As Slvs, ByVal group As UInteger,
|
|
ByVal qw As Param, ByVal qx As Param,
|
|
ByVal qy As Param, ByVal qz As Param)
|
|
MyBase.New(s)
|
|
Slv.AddNormal3d(H, group, qw.H, qx.H, qy.H, qz.H)
|
|
qwp = qw
|
|
qxp = qx
|
|
qyp = qy
|
|
qzp = qz
|
|
End Sub
|
|
End Class
|
|
|
|
Public Class Normal2d
|
|
Inherits Normal
|
|
Public Sub New(ByVal s As Slvs, ByVal group As UInteger,
|
|
ByVal wrkpl As Workplane)
|
|
MyBase.New(s)
|
|
Slv.AddNormal2d(H, group, wrkpl.H)
|
|
End Sub
|
|
End Class
|
|
|
|
Public Class Distance
|
|
Inherits Entity
|
|
Public dp As Param
|
|
|
|
Public Sub New(ByVal s As Slvs, ByVal group As UInteger,
|
|
ByVal wrkpl As Workplane, ByVal d As Double)
|
|
MyBase.New(s)
|
|
dp = New Param(Slv, group, d)
|
|
Slv.AddDistance(H, group, wrkpl.H, dp.H)
|
|
End Sub
|
|
Public Sub New(ByVal s As Slvs, ByVal group As UInteger,
|
|
ByVal wrkpl As Workplane, ByVal d As Param)
|
|
MyBase.New(s)
|
|
Slv.AddDistance(H, group, wrkpl.H, d.H)
|
|
dp = d
|
|
End Sub
|
|
Function GetDistance() As Double
|
|
Return Slv.GetParamByHandle(dp.H)
|
|
End Function
|
|
End Class
|
|
|
|
Public Class LineSegment
|
|
Inherits Entity
|
|
Public Sub New(ByVal s As Slvs, ByVal group As UInteger,
|
|
ByVal wrkpl As Workplane,
|
|
ByVal ptA As Point, ByVal ptB As Point)
|
|
MyBase.New(s)
|
|
Slv.AddLineSegment(H, group, wrkpl.H, ptA.H, ptB.H)
|
|
End Sub
|
|
End Class
|
|
|
|
Public Class Cubic
|
|
Inherits Entity
|
|
Public Sub New(ByVal s As Slvs, ByVal group As UInteger,
|
|
ByVal wrkpl As Workplane,
|
|
ByVal pt0 As Point, ByVal pt1 As Point,
|
|
ByVal pt2 As Point, ByVal pt3 As Point)
|
|
MyBase.New(s)
|
|
Slv.AddCubic(H, group, wrkpl.H, pt0.H, pt1.H, pt2.H, pt3.H)
|
|
End Sub
|
|
End Class
|
|
|
|
Public Class ArcOfCircle
|
|
Inherits Entity
|
|
Public Sub New(ByVal s As Slvs, ByVal group As UInteger,
|
|
ByVal wrkpl As Workplane, ByVal normal As Normal,
|
|
ByVal center As Point, ByVal pstart As Point,
|
|
ByVal pend As Point)
|
|
MyBase.New(s)
|
|
Slv.AddArcOfCircle(H, group, wrkpl.H, normal.H, _
|
|
center.H, pstart.H, pend.H)
|
|
End Sub
|
|
End Class
|
|
|
|
Public Class Circle
|
|
Inherits Entity
|
|
Public Sub New(ByVal s As Slvs, ByVal group As UInteger,
|
|
ByVal wrkpl As Workplane, ByVal center As Point,
|
|
ByVal normal As Normal, ByVal radius As Distance)
|
|
MyBase.New(s)
|
|
Slv.AddCircle(H, group, wrkpl.H, center.H, normal.H, radius.H)
|
|
End Sub
|
|
End Class
|
|
|
|
Public Class Workplane
|
|
Inherits Entity
|
|
Public Sub New(ByVal s As Slvs)
|
|
MyBase.New(s)
|
|
H = SLVS_FREE_IN_3D
|
|
End Sub
|
|
Public Sub New(ByVal s As Slvs, ByVal group As UInteger,
|
|
ByVal origin As Point, ByVal normal As Normal)
|
|
MyBase.New(s)
|
|
Slv.AddWorkplane(H, group, origin.H, normal.H)
|
|
End Sub
|
|
End Class
|
|
|
|
End Class
|
|
|
|
End Module
|
|
|