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extern/opennurbs/opennurbs_revsurface.h

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/* $NoKeywords: $ */
/*
//
// Copyright (c) 1993-2012 Robert McNeel & Associates. All rights reserved.
// OpenNURBS, Rhinoceros, and Rhino3D are registered trademarks of Robert
// McNeel & Associates.
//
// THIS SOFTWARE IS PROVIDED "AS IS" WITHOUT EXPRESS OR IMPLIED WARRANTY.
// ALL IMPLIED WARRANTIES OF FITNESS FOR ANY PARTICULAR PURPOSE AND OF
// MERCHANTABILITY ARE HEREBY DISCLAIMED.
//
// For complete openNURBS copyright information see <http://www.opennurbs.org>.
//
////////////////////////////////////////////////////////////////
*/
#if !defined(OPENNURBS_REVSURFACE_INC_)
#define OPENNURBS_REVSURFACE_INC_
// surface of revolution
class ON_CLASS ON_RevSurface : public ON_Surface
{
ON_OBJECT_DECLARE(ON_RevSurface);
public:
// virtual ON_Object::DestroyRuntimeCache override
void DestroyRuntimeCache( bool bDelete = true ) override;
public:
// Revolute curve.
// If m_curve is not nullptr, then ~ON_RevSurface() deletes m_curve.
ON_Curve* m_curve;
// Axis of revolution.
ON_Line m_axis;
// Start and end angles of revolution in radians.
// The interval m_angle must be increasing and satisfiy
// ON_ZERO_TOLERANCE < m_angle.Length() <= 2.0*ON_PI
ON_Interval m_angle;
// The interval m_t specifies the parameterization for the
// angular parameter; m_t must be an increasing interval.
// The parameter m_t[0] corresonds to angle m_angle[0] and
// the parameter m_t[1] corresponds to angle m_angle[1].
// Changing m_t and leaving m_angle unchanged will change the
// parameterization but not change the locus of the surface.
// Changing m_angle and leaving m_t unchanged, will change the
// locus of the surface but not change the evaluation domain.
ON_Interval m_t;
// If false, the "u" parameter is the angle parameter
// and the "v" parameter is the curve parameter.
// If true, the "u" parameter is the curve parameter
// and the "v" parameter is the angle parameter.
bool m_bTransposed;
// Bounding box of the surface of revolution.
ON_BoundingBox m_bbox;
/*
Description:
Use ON_RevSurface::New(...) instead of new ON_RevSurface(...)
Returns:
Pointer to an ON_RevSurface. Destroy by calling delete.
Remarks:
See static ON_Brep* ON_Brep::New() for details.
*/
static ON_RevSurface* New();
static ON_RevSurface* New( const ON_RevSurface& rev_surface );
ON_RevSurface();
~ON_RevSurface();
ON_RevSurface( const ON_RevSurface& );
ON_RevSurface& operator=( const ON_RevSurface& );
void Destroy();
bool SetAngleRadians(
double start_angle_radians,
double end_angle_radians
);
bool SetAngleDegrees(
double start_angle_degrees,
double end_angle_degrees
);
////////////////////////////////////////////////////////////
//
// overrides of virtual ON_Object functions
//
// virtual ON_Object::SizeOf override
unsigned int SizeOf() const override;
// virtual ON_Object::DataCRC override
ON__UINT32 DataCRC(ON__UINT32 current_remainder) const override;
bool IsValid( class ON_TextLog* text_log = nullptr ) const override;
void Dump( ON_TextLog& ) const override; // for debugging
// Use ON_BinaryArchive::WriteObject() and ON_BinaryArchive::ReadObject()
// for top level serialization. These Read()/Write() members should just
// write/read specific definitions. In particular, they should not write/
// read any chunk typecode or length information. The default
// implementations return false and do nothing.
bool Write(
ON_BinaryArchive& // serialize definition to binary archive
) const override;
bool Read(
ON_BinaryArchive& // restore definition from binary archive
) override;
////////////////////////////////////////////////////////////
//
// overrides of virtual ON_Geometry functions
//
int Dimension() const override;
// virtual ON_Geometry GetBBox override
bool GetBBox( double* boxmin, double* boxmax, bool bGrowBox = false ) const override;
void ClearBoundingBox() override;
bool Transform(
const ON_Xform&
) override;
////////////////////////////////////////////////////////////
//
// overrides of virtual ON_Surface functions
//
bool SetDomain(
int dir, // 0 sets first parameter's domain, 1 gets second parameter's domain
double t0,
double t1
) override;
ON_Interval Domain(
int // 0 gets first parameter's domain, 1 gets second parameter's domain
) const override;
/*
Description:
Get an estimate of the size of the rectangle that would
be created if the 3d surface where flattened into a rectangle.
Parameters:
width - [out] (corresponds to the first surface parameter)
height - [out] (corresponds to the first surface parameter)
Remarks:
overrides virtual ON_Surface::GetSurfaceSize
Returns:
true if successful.
*/
bool GetSurfaceSize(
double* width,
double* height
) const override;
int SpanCount(
int // 0 gets first parameter's domain, 1 gets second parameter's domain
) const override; // number of smooth spans in curve
bool GetSpanVector( // span "knots"
int, // 0 gets first parameter's domain, 1 gets second parameter's domain
double* // array of length SpanCount() + 1
) const override; //
int Degree( // returns maximum algebraic degree of any span
// ( or a good estimate if curve spans are not algebraic )
int // 0 gets first parameter's domain, 1 gets second parameter's domain
) const override;
bool GetParameterTolerance( // returns tminus < tplus: parameters tminus <= s <= tplus
int, // 0 gets first parameter, 1 gets second parameter
double, // t = parameter in domain
double*, // tminus
double* // tplus
) const override;
/*
Description:
Test a surface of revolution to see if it is a portion
of a sphere.
Parameters:
sphere - [out] if not nullptr and true is returned,
the sphere parameters are filled in.
tolerance - [in] tolerance to use when checking
Returns:
true if the surface of revolution is a portion of a sphere.
*/
bool IsSpherical(
ON_Sphere* sphere = nullptr,
double tolerance = ON_ZERO_TOLERANCE
) const;
/*
Description:
Test a surface of revolution to see if it is a portion
of a cylinder.
Parameters:
cylinder - [out] if not nullptr and true is returned,
the cylinder parameters are filled in.
tolerance - [in] tolerance to use when checking
Returns:
true if the surface of revolution is a portion of a cylinder.
*/
bool IsCylindrical(
ON_Cylinder* cylinder = nullptr,
double tolerance = ON_ZERO_TOLERANCE
) const;
/*
Description:
Test a surface of revolution to see if it is a portion
of a cone.
Parameters:
cone - [out] if not nullptr and true is returned,
the cone parameters are filled in.
tolerance - [in] tolerance to use when checking
Returns:
true if the surface of revolution is a portion of a cone.
*/
bool IsConical(
ON_Cone* cone = nullptr,
double tolerance = ON_ZERO_TOLERANCE
) const;
/*
Description:
Test a surface to see if it is planar.
Parameters:
plane - [out] if not nullptr and true is returned,
the plane parameters are filled in.
tolerance - [in] tolerance to use when checking
Returns:
true if there is a plane such that the maximum distance from
the surface to the plane is <= tolerance.
Remarks:
Overrides virtual ON_Surface::IsPlanar.
*/
bool IsPlanar(
ON_Plane* plane = nullptr,
double tolerance = ON_ZERO_TOLERANCE
) const override;
bool IsClosed( // true if surface is closed in direction
int // dir 0 = "s", 1 = "t"
) const override;
bool IsPeriodic( // true if surface is periodic in direction
int // dir 0 = "s", 1 = "t"
) const override;
bool IsSingular( // true if surface side is collapsed to a point
int // side of parameter space to test
// 0 = south, 1 = east, 2 = north, 3 = west
) const override;
/*
Description:
Search for a derivatitive, tangent, or curvature
discontinuity.
Parameters:
dir - [in] If 0, then "u" parameter is checked. If 1, then
the "v" parameter is checked.
c - [in] type of continity to test for.
t0 - [in] Search begins at t0. If there is a discontinuity
at t0, it will be ignored. This makes it
possible to repeatedly call GetNextDiscontinuity
and step through the discontinuities.
t1 - [in] (t0 != t1) If there is a discontinuity at t1 is
will be ingored unless c is a locus discontinuity
type and t1 is at the start or end of the curve.
t - [out] if a discontinuity is found, then *t reports the
parameter at the discontinuity.
hint - [in/out] if GetNextDiscontinuity will be called
repeatedly, passing a "hint" with initial value *hint=0
will increase the speed of the search.
dtype - [out] if not nullptr, *dtype reports the kind of
discontinuity found at *t. A value of 1 means the first
derivative or unit tangent was discontinuous. A value
of 2 means the second derivative or curvature was
discontinuous. A value of 0 means teh curve is not
closed, a locus discontinuity test was applied, and
t1 is at the start of end of the curve.
cos_angle_tolerance - [in] default = cos(1 degree) Used only
when c is ON::continuity::G1_continuous or ON::continuity::G2_continuous. If the
cosine of the angle between two tangent vectors is
<= cos_angle_tolerance, then a G1 discontinuity is reported.
curvature_tolerance - [in] (default = ON_SQRT_EPSILON) Used
only when c is ON::continuity::G2_continuous. If K0 and K1 are
curvatures evaluated from above and below and
|K0 - K1| > curvature_tolerance, then a curvature
discontinuity is reported.
Returns:
Parametric continuity tests c = (C0_continuous, ..., G2_continuous):
true if a parametric discontinuity was found strictly
between t0 and t1. Note well that all curves are
parametrically continuous at the ends of their domains.
Locus continuity tests c = (C0_locus_continuous, ...,G2_locus_continuous):
true if a locus discontinuity was found strictly between
t0 and t1 or at t1 is the at the end of a curve.
Note well that all open curves (IsClosed()=false) are locus
discontinuous at the ends of their domains. All closed
curves (IsClosed()=true) are at least C0_locus_continuous at
the ends of their domains.
*/
bool GetNextDiscontinuity(
int dir,
ON::continuity c,
double t0,
double t1,
double* t,
int* hint=nullptr,
int* dtype=nullptr,
double cos_angle_tolerance=ON_DEFAULT_ANGLE_TOLERANCE_COSINE,
double curvature_tolerance=ON_SQRT_EPSILON
) const override;
/*
Description:
Test continuity at a surface parameter value.
Parameters:
c - [in] continuity to test for
s - [in] surface parameter to test
t - [in] surface parameter to test
hint - [in] evaluation hint
point_tolerance - [in] if the distance between two points is
greater than point_tolerance, then the surface is not C0.
d1_tolerance - [in] if the difference between two first derivatives is
greater than d1_tolerance, then the surface is not C1.
d2_tolerance - [in] if the difference between two second derivatives is
greater than d2_tolerance, then the surface is not C2.
cos_angle_tolerance - [in] default = cos(1 degree) Used only when
c is ON::continuity::G1_continuous or ON::continuity::G2_continuous. If the cosine
of the angle between two normal vectors
is <= cos_angle_tolerance, then a G1 discontinuity is reported.
curvature_tolerance - [in] (default = ON_SQRT_EPSILON) Used only when
c is ON::continuity::G2_continuous. If K0 and K1 are curvatures evaluated
from above and below and |K0 - K1| > curvature_tolerance,
then a curvature discontinuity is reported.
Returns:
true if the surface has at least the c type continuity at the parameter t.
Remarks:
Overrides virtual ON_Surface::IsContinuous
*/
bool IsContinuous(
ON::continuity c,
double s,
double t,
int* hint = nullptr,
double point_tolerance=ON_ZERO_TOLERANCE,
double d1_tolerance=ON_ZERO_TOLERANCE,
double d2_tolerance=ON_ZERO_TOLERANCE,
double cos_angle_tolerance=ON_DEFAULT_ANGLE_TOLERANCE_COSINE,
double curvature_tolerance=ON_SQRT_EPSILON
) const override;
bool Reverse( // reverse parameterizatrion, Domain changes from [a,b] to [-b,-a]
int // dir 0 = "s", 1 = "t"
) override;
bool Transpose() override; // transpose surface parameterization (swap "s" and "t")
bool Evaluate( // returns false if unable to evaluate
double, double, // evaluation parameters (see m_bTransposed)
int, // number of derivatives (>=0)
int, // array stride (>=Dimension())
double*, // array of length stride*(ndir+1)*(ndir+2)/2
int = 0, // optional - determines which quadrant to evaluate from
// 0 = default
// 1 from NE quadrant
// 2 from NW quadrant
// 3 from SW quadrant
// 4 from SE quadrant
int* = 0 // optional - evaluation hint (int[2]) used to speed
// repeated evaluations
) const override;
/*
Description:
Get isoparametric curve.
Overrides virtual ON_Surface::IsoCurve.
Parameters:
dir - [in] 0 first parameter varies and second parameter is constant
e.g., point on IsoCurve(0,c) at t is srf(t,c)
1 first parameter is constant and second parameter varies
e.g., point on IsoCurve(1,c) at t is srf(c,t)
c - [in] value of constant parameter
Returns:
Isoparametric curve.
*/
ON_Curve* IsoCurve(
int dir,
double c
) const override;
ON_Arc IsoArc(
double curve_parameter
) const;
/*
Description:
Removes the portions of the surface outside of the specified interval.
Parameters:
dir - [in] 0 The domain specifies an sub-interval of Domain(0)
(the first surface parameter).
1 The domain specifies an sub-interval of Domain(1)
(the second surface parameter).
domain - [in] interval of the surface to keep. If dir is 0, then
the portions of the surface with parameters (s,t) satisfying
s < Domain(0).Min() or s > Domain(0).Max() are trimmed away.
If dir is 1, then the portions of the surface with parameters
(s,t) satisfying t < Domain(1).Min() or t > Domain(1).Max()
are trimmed away.
*/
bool Trim(
int dir,
const ON_Interval& domain
) override;
/*
Description:
Where possible, analytically extends surface to include domain.
Parameters:
dir - [in] 0 new Domain(0) will include domain.
(the first surface parameter).
1 new Domain(1) will include domain.
(the second surface parameter).
domain - [in] if domain is not included in surface domain,
surface will be extended so that its domain includes domain.
Will not work if surface is closed in direction dir.
Original surface is identical to the restriction of the
resulting surface to the original surface domain,
Returns:
true if successful.
*/
bool Extend(
int dir,
const ON_Interval& domain
) override;
/*
Description:
Splits (divides) the surface into two parts at the
specified parameter.
Parameters:
dir - [in] 0 The surface is split vertically. The "west" side
is returned in "west_or_south_side" and the "east"
side is returned in "east_or_north_side".
1 The surface is split horizontally. The "south" side
is returned in "west_or_south_side" and the "north"
side is returned in "east_or_north_side".
c - [in] value of constant parameter in interval returned
by Domain(dir)
west_or_south_side - [out] west/south portion of surface returned here
east_or_north_side - [out] east/north portion of surface returned here
Example:
ON_NurbsSurface srf = ...;
int dir = 1;
ON_RevSurface* south_side = 0;
ON_RevSurface* north_side = 0;
srf.Split( dir, srf.Domain(dir).Mid() south_side, north_side );
*/
bool Split(
int dir,
double c,
ON_Surface*& west_or_south_side,
ON_Surface*& east_or_north_side
) const override;
int GetNurbForm( // returns 0: unable to create NURBS representation
// with desired accuracy.
// 1: success - returned NURBS parameterization
// matches the surface's to wthe desired accuracy
// 2: success - returned NURBS point locus matches
// the surfaces's to the desired accuracy but, on
// the interior of the surface's domain, the
// surface's parameterization and the NURBS
// parameterization may not match to the
// desired accuracy.
ON_NurbsSurface&,
double = 0.0
) const override;
int HasNurbForm( // returns 0: unable to create NURBS representation
// with desired accuracy.
// 1: success - returned NURBS parameterization
// matches the surface's to wthe desired accuracy
// 2: success - returned NURBS point locus matches
// the surfaces's to the desired accuracy but, on
// the interior of the surface's domain, the
// surface's parameterization and the NURBS
// parameterization may not match to the
// desired accuracy.
) const override;
bool GetSurfaceParameterFromNurbFormParameter(
double nurbs_s, double nurbs_t,
double* surface_s, double* surface_t
) const override;
bool GetNurbFormParameterFromSurfaceParameter(
double surface_s, double surface_t,
double* nurbs_s, double* nurbs_t
) const override;
};
#endif