static bool CheackTubeLenth(AcDbObjectId& objId)
{
objId = ArxUtilHelper::SelectObject( _T( "请选择一条瓦斯管路:" ) );
if( objId.isNull() ) return false;
if( !ArxUtilHelper::IsEqualType( _T( "GasTube" ), objId ) ) return false;
AcTransaction *pTrans = actrTransactionManager->startTransaction();
if ( 0 == pTrans ) return false;
AcDbObject *pObj;
if (Acad::eOk != pTrans->getObject(pObj,objId,AcDb::kForRead)) return false;
GasTube *pGasTube = GasTube::cast(pObj);
if ( 0 == pGasTube)
{
actrTransactionManager->abortTransaction();
return false;
}
AcGePoint3d spt,ept;
pGasTube->getSEPoint(spt,ept);
//double angle = pGasTube->getAngle();
actrTransactionManager->endTransaction();
AcGeVector3d v = ept - spt;
double tubeLenth = v.length();
return true;
}
static void AddDirection( const AcDbObjectId& objId, const AcGePoint3d& spt, const AcGePoint3d& ept )
{
AcGeVector3d v = ept - spt;
if( v.length() < 100 ) return;
double angle = v.angleTo( AcGeVector3d::kXAxis, -AcGeVector3d::kZAxis );
WindDirection* pDir = new WindDirection( spt + v * 0.5, angle ); // 巷道中心位置
pDir->setRelatedGE( objId );
ArxUtilHelper::PostToModelSpace( pDir );
}
static void EffectRanDrawed(AcDbObjectId ttunel)
{
AcTransaction *pTrans = actrTransactionManager->startTransaction();
if ( 0 == pTrans ) return;
AcDbObject *pObj;
if (Acad::eOk != pTrans->getObject(pObj,ttunel,AcDb::kForRead)) return;
TTunnel *pTTunnel = TTunnel::cast(pObj);
if ( 0 == pTTunnel)
{
actrTransactionManager->abortTransaction();
return;
}
AcGePoint3d spt,ept;
pTTunnel->getSEPoint(spt,ept);
double angle = pTTunnel->getAngle();
actrTransactionManager->endTransaction();
AcDbObjectIdArray eTags;
DrawHelper::GetTagGEById2( ttunel, _T( "EffectRanTagGE" ), eTags );
if (!eTags.isEmpty())
{
ArxEntityHelper::EraseObjects( eTags, true );
}
AcGeVector3d v = ept - spt;
double diatance = v.length();
CString area,way;
if(!DataHelper::GetPropertyData(ttunel,_T("断面面积"),area)) return;
if(!DataHelper::GetPropertyData(ttunel,_T("通风方法"),way)) return;
double minDistan,maxDistan;
if(way.IsEmpty()) return;
if(area.IsEmpty()) return;
if (_T("压入式") == way || _T("长压短抽") == way)
{
minDistan = 4*sqrtf(_tstof(area));
maxDistan = 5*sqrtf(_tstof(area));
}
else
{
minDistan = 0;
maxDistan = 1.5*sqrtf(_tstof(area));
}
EffectRanTagGE *pTag = new EffectRanTagGE(ept,angle,minDistan,maxDistan,diatance*0.1);
if (0 == pTag) return;
pTag->setRelatedGE(ttunel);
if( !ArxUtilHelper::PostToModelSpace( pTag ) ) delete pTag;
}
void SimpleChimneyDraw::drawSegment( AcGiWorldDraw* mode, const AcGePoint3d& spt, const AcGePoint3d& ept )
{
AcGeVector3d v = ept - spt;
int n = ( int )( ( v.length() + m_space ) / ( m_length + m_space ) );
//acutPrintf(_T("\n可绘制的个数:%d"), n);
v.normalize();
AcGePoint3d pt = spt;
for( int i = 0; i < n; i++ )
{
DrawSegment( mode, pt, v, m_length, m_width, m_lineWidth );
pt = pt + v * ( m_length + m_space );
}
double ll = ( ept - pt ).length();
if( ll > m_length * 0.5 ) // 如果有长度的50%,则绘制一小段
{
DrawSegment( mode, pt, v, ll, m_width, m_lineWidth );
}
}
// This function is called to update the entity based on the
// input values.
//
Adesk::Boolean
AsdkEllipseJig::update()
{
switch (mPromptCounter) {
case 0:
// At this time, mAxis contains the value of one
// endpoint of the desired major axis. The
// AcDbEllipse class stores the major axis as the
// vector from the center point to where the axis
// intersects the ellipse path (such as half of the true
// major axis), so we already have what we need.
//
mMajorAxis = mAxisPt - mCenterPt;
break;
case 1:
// Calculate the radius ratio. mRadiusRatio
// currently contains the distance from the ellipse
// center to the current pointer position. This is
// half of the actual minor axis length. Since
// AcDbEllipse stores the major axis vector as the
// vector from the center point to the ellipse curve
// (half the major axis), to get the radius ratio we
// simply divide the value currently in mRadiusRatio
// by the length of the stored major axis vector.
//
mRadiusRatio = mRadiusRatio / mMajorAxis.length();
break;
}
// Now update the ellipse with the latest setting.
//
mpEllipse->set(mCenterPt, mNormal, mMajorAxis,
mRadiusRatio);
return Adesk::kTrue;
}
AcBr::ErrorStatus
faceDump(const AcBrFace& faceEntity)
{
AcBr::ErrorStatus returnValue = AcBr::eOk;
// Verify that AcBr was explicitly and not implicitly loaded,
// by testing ObjectARX functions (which are unavailable unless
// explicitly loaded)
if (faceEntity.isA() == NULL) {
acutPrintf(ACRX_T("\n faceDump: AcBrEntity::isA() failed\n"));
return returnValue;
}
if (!faceEntity.isKindOf(AcBrFace::desc())) {
acutPrintf(ACRX_T("\n faceDump: AcBrEntity::isKindOf() failed\n"));
return returnValue;
}
AcBrEntity* entClass = (AcBrEntity*)&faceEntity;
AcBrEdge* pEdge = AcBrEdge::cast(entClass);
if (pEdge != NULL) {
acutPrintf(ACRX_T("\n faceDump: AcBrEntity::cast() failed\n"));
return (AcBrErrorStatus)Acad::eNotThatKindOfClass;
}
AcGe::EntityId entId;
returnValue = faceEntity.getSurfaceType(entId);
if (returnValue != AcBr::eOk) {
acutPrintf(ACRX_T("\n Error in AcBrFace::getSurfaceType:"));
errorReport(returnValue);
return returnValue;
}
AcGeSurface* surfaceGeometry = NULL;
AcGeSurface* nativeGeometry = NULL;
// NOTE: ignore unsupported geometry types for now, since we already know
// that elliptic cylinders and elliptic cones are rejected by AcGe, but we
// can still perform useful evaluations on the external bounded surface.
returnValue = getNativeSurface(faceEntity, surfaceGeometry, nativeGeometry);
if ((returnValue != AcBr::eOk) && (returnValue
!= (AcBrErrorStatus)Acad::eInvalidInput)) {
acutPrintf(ACRX_T("\n Error in getNativeSurface:"));
errorReport(returnValue);
delete surfaceGeometry;
delete nativeGeometry;
return returnValue;
}
switch (entId) {
case(kPlane):
{
acutPrintf(ACRX_T("\nSurface Type: Plane\n"));
AcGePlane* planeGeometry = (AcGePlane*)nativeGeometry;
AcGePoint3d pt = planeGeometry->pointOnPlane();
AcGeVector3d normal = planeGeometry->normal();
acutPrintf(ACRX_T("\nSurface Definition Data Begin:\n"));
acutPrintf(ACRX_T(" Point on Plane is ("));
acutPrintf (ACRX_T("%lf , "), pt.x);
acutPrintf (ACRX_T("%lf , "), pt.y);
acutPrintf (ACRX_T("%lf "), pt.z);
acutPrintf(ACRX_T(")\n"));
acutPrintf(ACRX_T(" Plane normal direction is ("));
acutPrintf (ACRX_T("%lf , "), normal.x);
acutPrintf (ACRX_T("%lf , "), normal.y);
acutPrintf (ACRX_T("%lf "), normal.z);
acutPrintf(ACRX_T(")\n"));
acutPrintf(ACRX_T("Surface Definition Data End\n"));
break;
}
case(kSphere):
{
acutPrintf(ACRX_T("\nSurface Type: Sphere\n"));
AcGeSphere* sphereGeometry = (AcGeSphere*)nativeGeometry;
AcGePoint3d centre = sphereGeometry->center();
double ang1, ang2, ang3, ang4;
sphereGeometry->getAnglesInU(ang1, ang2);
sphereGeometry->getAnglesInV(ang3, ang4);
AcGePoint3d north = sphereGeometry->northPole();
AcGePoint3d south = sphereGeometry->southPole();
acutPrintf(ACRX_T("\nSurface Definition Data Begin:\n"));
acutPrintf(ACRX_T(" Sphere centre is ("));
acutPrintf (ACRX_T("%lf , "), centre.x);
acutPrintf (ACRX_T("%lf , "), centre.y);
acutPrintf (ACRX_T("%lf "), centre.z);
acutPrintf(ACRX_T(")\n"));
acutPrintf(ACRX_T(" Sphere radius is %lf\n"), sphereGeometry->radius());
acutPrintf(ACRX_T(" Sphere start angle in U is %lf\n"), ang1);
acutPrintf(ACRX_T(" Sphere end angle in U is %lf\n"), ang2);
acutPrintf(ACRX_T(" Sphere start angle in V is %lf\n"), ang3);
acutPrintf(ACRX_T(" Sphere end angle in V is %lf\n"), ang4);
acutPrintf(ACRX_T(" Sphere north pole is ("));
acutPrintf (ACRX_T("%lf , "), north.x);
acutPrintf (ACRX_T("%lf , "), north.y);
acutPrintf (ACRX_T("%lf "), north.z);
acutPrintf(ACRX_T(")\n"));
acutPrintf(ACRX_T(" Sphere south pole is ("));
acutPrintf (ACRX_T("%lf , "), south.x);
acutPrintf (ACRX_T("%lf , "), south.y);
acutPrintf (ACRX_T("%lf "), south.z);
acutPrintf(ACRX_T(")\n"));
acutPrintf(ACRX_T("Surface Definition Data End\n"));
break;
}
case(kTorus):
{
acutPrintf(ACRX_T("\nSurface Type: Torus\n"));
AcGeTorus* torusGeometry = (AcGeTorus*)nativeGeometry;
AcGePoint3d centre = torusGeometry->center();
double ang1, ang2, ang3, ang4;
torusGeometry->getAnglesInU(ang1, ang2);
torusGeometry->getAnglesInV(ang3, ang4);
acutPrintf(ACRX_T("\nSurface Definition Data Begin:\n"));
acutPrintf(ACRX_T(" Torus centre is ("));
acutPrintf (ACRX_T("%lf , "), centre.x);
acutPrintf (ACRX_T("%lf , "), centre.y);
acutPrintf (ACRX_T("%lf "), centre.z);
acutPrintf(ACRX_T(")\n"));
acutPrintf(ACRX_T(" Torus major radius is %lf\n"), torusGeometry->majorRadius());
acutPrintf(ACRX_T(" Torus minor radius is %lf\n"), torusGeometry->minorRadius());
acutPrintf(ACRX_T(" Torus start angle in U is %lf\n"), ang1);
acutPrintf(ACRX_T(" Torus end angle in U is %lf\n"), ang2);
acutPrintf(ACRX_T(" Torus start angle in V is %lf\n"), ang3);
acutPrintf(ACRX_T(" Torus end angle in V is %lf\n"), ang4);
acutPrintf(ACRX_T("Surface Definition Data End\n"));
break;
}
case(kCylinder):
{
acutPrintf(ACRX_T("\nSurface Type: Circular Cylinder\n"));
AcGeCylinder* cylinderGeometry = (AcGeCylinder*)nativeGeometry;
AcGePoint3d origin = cylinderGeometry->origin();
double ang1, ang2;
cylinderGeometry->getAngles(ang1, ang2);
AcGeInterval ht;
cylinderGeometry->getHeight(ht);
double height = ht.upperBound() - ht.lowerBound();
AcGeVector3d refAxis = cylinderGeometry->refAxis();
AcGeVector3d symAxis = cylinderGeometry->axisOfSymmetry();
acutPrintf(ACRX_T("\nSurface Definition Data Begin:\n"));
acutPrintf(ACRX_T(" Circular Cylinder origin is ("));
acutPrintf (ACRX_T("%lf , "), origin.x);
acutPrintf (ACRX_T("%lf , "), origin.y);
acutPrintf (ACRX_T("%lf "), origin.z);
acutPrintf(ACRX_T(")\n"));
acutPrintf(ACRX_T(" Circular Cylinder radius is %lf\n"), cylinderGeometry->radius());
acutPrintf(ACRX_T(" Circular Cylinder start angle is %lf\n"), ang1);
acutPrintf(ACRX_T(" Circular Cylinder end angle is %lf\n"), ang2);
if (cylinderGeometry->isClosedInU())
acutPrintf(ACRX_T(" Circular Cylinder height is %lf\n"), height);
else acutPrintf(ACRX_T(" Circular Cylinder is not closed in U\n"));
acutPrintf(ACRX_T(" Circular Cylinder reference axis is ("));
acutPrintf (ACRX_T("%lf , "), refAxis.x);
acutPrintf (ACRX_T("%lf , "), refAxis.y);
acutPrintf (ACRX_T("%lf "), refAxis.z);
acutPrintf(ACRX_T(")\n"));
acutPrintf(ACRX_T(" Circular Cylinder axis of symmetry is ("));
acutPrintf (ACRX_T("%lf , "), symAxis.x);
acutPrintf (ACRX_T("%lf , "), symAxis.y);
acutPrintf (ACRX_T("%lf "), symAxis.z);
acutPrintf(ACRX_T(")\n"));
acutPrintf(ACRX_T("Surface Definition Data End\n"));
break;
}
case(kCone):
{
acutPrintf(ACRX_T("\nSurface Type: Circular Cone\n"));
AcGeCone* coneGeometry = (AcGeCone*)nativeGeometry;
AcGePoint3d centre = coneGeometry->baseCenter();
double ang1, ang2;
coneGeometry->getAngles(ang1, ang2);
AcGeVector3d axis1 = coneGeometry->axisOfSymmetry();
AcGeVector3d axis2 = coneGeometry->refAxis();
AcGePoint3d apex = coneGeometry->apex();
double cosAng, sinAng;
coneGeometry->getHalfAngle(cosAng, sinAng);
AcGeInterval ht;
coneGeometry->getHeight(ht);
double height = ht.upperBound() - ht.lowerBound();
acutPrintf(ACRX_T("\nSurface Definition Data Begin:\n"));
acutPrintf(ACRX_T(" Circular Cone base centre is ("));
acutPrintf (ACRX_T("%lf , "), centre.x);
acutPrintf (ACRX_T("%lf , "), centre.y);
acutPrintf (ACRX_T("%lf "), centre.z);
acutPrintf(ACRX_T(")\n"));
acutPrintf(ACRX_T(" Circular Cone base radius is %lf\n"), coneGeometry->baseRadius());
acutPrintf(ACRX_T(" Circular Cone start angle is %lf\n"), ang1);
acutPrintf(ACRX_T(" Circular Cone end angle is %lf\n"), ang2);
acutPrintf(ACRX_T(" Circular Cone axis of symmetry is ("));
acutPrintf (ACRX_T("%lf , "), axis1.x);
acutPrintf (ACRX_T("%lf , "), axis1.y);
acutPrintf (ACRX_T("%lf "), axis1.z);
acutPrintf(ACRX_T(")\n"));
acutPrintf(ACRX_T(" Circular Cone reference axis is ("));
acutPrintf (ACRX_T("%lf , "), axis2.x);
acutPrintf (ACRX_T("%lf , "), axis2.y);
acutPrintf (ACRX_T("%lf "), axis2.z);
acutPrintf(ACRX_T(")\n"));
acutPrintf(ACRX_T(" Circular Cone apex is ("));
acutPrintf (ACRX_T("%lf , "), apex.x);
acutPrintf (ACRX_T("%lf , "), apex.y);
acutPrintf (ACRX_T("%lf "), apex.z);
acutPrintf(ACRX_T(")\n"));
acutPrintf(ACRX_T(" Circular Cone cosine of major half-angle is %lf\n"), cosAng);
acutPrintf(ACRX_T(" Circular Cone sine of major half-angle is %lf\n"), sinAng);
if (coneGeometry->isClosedInU())
acutPrintf(ACRX_T(" Circular Cone height is %lf\n"), height);
else acutPrintf(ACRX_T(" Circular Cone is not closed in U\n"));
acutPrintf(ACRX_T("Surface Definition Data End\n"));
break;
}
case(kNurbSurface):
{
acutPrintf(ACRX_T("\nSurface Type: NURB Surface\n"));
AcGeNurbSurface* nurbGeometry = (AcGeNurbSurface*)nativeGeometry;
int nCtrlPtsU = nurbGeometry->numControlPointsInU();
int nCtrlPtsV = nurbGeometry->numControlPointsInV();
int nKnotsU = nurbGeometry->numKnotsInU();
int nKnotsV = nurbGeometry->numKnotsInV();
acutPrintf(ACRX_T("\nSurface Definition Data Begin:\n"));
acutPrintf(ACRX_T(" NURB Surface degree in U is %d\n"), nurbGeometry->degreeInU());
acutPrintf(ACRX_T(" NURB Surface degree in V is %d\n"), nurbGeometry->degreeInV());
acutPrintf(ACRX_T(" NURB Surface number of control points in U is %d\n"), nCtrlPtsU);
acutPrintf(ACRX_T(" NURB Surface number of control points in V is %d\n"), nCtrlPtsV);
acutPrintf(ACRX_T(" NURB Surface number of knots in U is %d\n"), nKnotsU);
acutPrintf(ACRX_T(" NURB Surface number of knots in V is %d\n"), nKnotsV);
acutPrintf(ACRX_T("Surface Definition Data End\n"));
break;
}
// NOTE: This surface is not yet supported in AcGe, so we infer the definition
// data by analysing evaluated data on the external bounded surface.
case(kEllipCylinder):
{
acutPrintf(ACRX_T("\nSurface Type: Elliptic Cylinder\n"));
AcGePoint3d p0 = surfaceGeometry->evalPoint(AcGePoint2d(0.0, 0.0));
AcGePoint3d p1 = surfaceGeometry->evalPoint(AcGePoint2d(0.0, kPi));
AcGePoint3d p2 = surfaceGeometry->evalPoint(AcGePoint2d(0.0, kHalfPi));
AcGePoint3d origin(((p0.x + p1.x) / 2.0),
((p0.y + p1.y) / 2.0),
((p0.z + p1.z) / 2.0));
AcGeVector3d majAxis = p0 - origin;
AcGeVector3d minAxis = p2 - origin;
AcGeVector3d symAxis = (majAxis.crossProduct(minAxis)).normalize();
acutPrintf(ACRX_T("\nSurface Definition Data Begin:\n"));
acutPrintf(ACRX_T(" Elliptic Cylinder origin is ("));
acutPrintf (ACRX_T("%lf , "), origin.x);
acutPrintf (ACRX_T("%lf , "), origin.y);
acutPrintf (ACRX_T("%lf "), origin.z);
acutPrintf(ACRX_T(")\n"));
acutPrintf(ACRX_T(" Elliptic Cylinder major radius is %lf\n"), majAxis.length());
acutPrintf(ACRX_T(" Elliptic Cylinder minor radius is %lf\n"), minAxis.length());
acutPrintf(ACRX_T(" Elliptic Cylinder major axis is ("));
acutPrintf (ACRX_T("%lf , "), majAxis.x);
acutPrintf (ACRX_T("%lf , "), majAxis.y);
acutPrintf (ACRX_T("%lf "), majAxis.z);
acutPrintf(ACRX_T(")\n"));
acutPrintf(ACRX_T(" Elliptic Cylinder minor axis is ("));
acutPrintf (ACRX_T("%lf , "), minAxis.x);
acutPrintf (ACRX_T("%lf , "), minAxis.y);
acutPrintf (ACRX_T("%lf "), minAxis.z);
acutPrintf(ACRX_T(")\n"));
acutPrintf(ACRX_T(" Elliptic Cylinder axis of symmetry is ("));
acutPrintf (ACRX_T("%lf , "), symAxis.x);
acutPrintf (ACRX_T("%lf , "), symAxis.y);
acutPrintf (ACRX_T("%lf "), symAxis.z);
acutPrintf(ACRX_T(")\n"));
acutPrintf(ACRX_T("Surface Definition Data End\n"));
break;
}
// NOTE: This surface is not yet supported in AcGe, so we infer the definition
// data by analysing evaluated data on the external bounded surface.
case(kEllipCone):
{
acutPrintf(ACRX_T("\nSurface Type: Elliptic Cone\n"));
AcGePoint3d p0 = surfaceGeometry->evalPoint(AcGePoint2d(0.0, 0.0));
AcGePoint3d p1 = surfaceGeometry->evalPoint(AcGePoint2d(0.0, kPi));
AcGePoint3d p2 = surfaceGeometry->evalPoint(AcGePoint2d(0.0, kHalfPi));
AcGePoint3d p3 = surfaceGeometry->evalPoint(AcGePoint2d(1.0, 0.0));
AcGePoint3d centre(((p0.x + p1.x) / 2.0),
((p0.y + p1.y) / 2.0),
((p0.z + p1.z) / 2.0));
AcGeVector3d majAxis = p0 - centre;
AcGeVector3d minAxis = p2 - centre;
AcGeVector3d symAxis = (majAxis.crossProduct(minAxis)).normalize();
double halfAng = kHalfPi - majAxis.angleTo(p3 - p0);
acutPrintf(ACRX_T("\nSurface Definition Data Begin:\n"));
acutPrintf(ACRX_T(" Elliptic Cone base centre is ("));
acutPrintf (ACRX_T("%lf , "), centre.x);
acutPrintf (ACRX_T("%lf , "), centre.y);
acutPrintf (ACRX_T("%lf "), centre.z);
acutPrintf(ACRX_T(")\n"));
acutPrintf(ACRX_T(" Elliptic Cone base major radius is %lf\n"), majAxis.length());
acutPrintf(ACRX_T(" Elliptic Cone base minor radius is %lf\n"), minAxis.length());
acutPrintf(ACRX_T(" Elliptic Cone major axis is ("));
acutPrintf (ACRX_T("%lf , "), majAxis.x);
acutPrintf (ACRX_T("%lf , "), majAxis.y);
acutPrintf (ACRX_T("%lf "), majAxis.z);
acutPrintf(ACRX_T(")\n"));
acutPrintf(ACRX_T(" Elliptic Cone minor axis is ("));
acutPrintf (ACRX_T("%lf , "), minAxis.x);
acutPrintf (ACRX_T("%lf , "), minAxis.y);
acutPrintf (ACRX_T("%lf "), minAxis.z);
acutPrintf(ACRX_T(")\n"));
acutPrintf(ACRX_T(" Elliptic Cone axis of symmetry is ("));
acutPrintf (ACRX_T("%lf , "), symAxis.x);
acutPrintf (ACRX_T("%lf , "), symAxis.y);
acutPrintf (ACRX_T("%lf "), symAxis.z);
acutPrintf(ACRX_T(")\n"));
acutPrintf(ACRX_T(" Elliptic Cone cosine of major half-angle is %lf\n"), cos(halfAng));
acutPrintf(ACRX_T(" Elliptic Cone sine of major half-angle is %lf\n"), sin(halfAng));
acutPrintf(ACRX_T("Surface Definition Data End\n"));
break;
}
default:
acutPrintf(ACRX_T("\nSurface Type: Unexpected Non Surface\n"));
return (AcBrErrorStatus)Acad::eInvalidInput;
} // end switch(entId)
delete nativeGeometry;
// Evaluate the surface - note that the u,v bounds will not consider any
// holes in the surface. To compute a u,v zone of exclusion for evaluation,
// check for additional (i.e., inner) loops and get the bounding boxes for
// the loops, then convert those to parameter space boxes. There is no
// particular guarantee that outer loop(s) are the first in the face-loop
// list, however, and we currently have no way to query a loop to find out
// which type it is. Still, the maximal u,v parameter range will be useful
// for most surfaces and most evaluation purposes.
AcGeInterval uParam;
AcGeInterval vParam;
((AcGeExternalBoundedSurface*)surfaceGeometry)->getEnvelope(uParam, vParam);
// Make sure the u,v values are legal and the envelope is bounded
if ((uParam.isBounded()) && (vParam.isBounded())) {
AcGePoint2d midRange;
midRange.x = uParam.lowerBound() + (uParam.length() / 2.0);
midRange.y = vParam.lowerBound() + (vParam.length() / 2.0);
AcGePoint3d pointOnSurface =
((AcGeExternalBoundedSurface*)surfaceGeometry)->evalPoint(midRange);
acutPrintf(ACRX_T("\nSurface Evaluation Begin:\n"));
acutPrintf(ACRX_T(" Parameter space bounds are (("));
acutPrintf(ACRX_T("%lf, "), uParam.lowerBound());
acutPrintf(ACRX_T("%lf "), uParam.upperBound());
acutPrintf(ACRX_T("), (\n"));
acutPrintf(ACRX_T("%lf, "), vParam.lowerBound());
acutPrintf(ACRX_T("%lf "), vParam.upperBound());
acutPrintf(ACRX_T("))\n"));
acutPrintf(ACRX_T(" Parameter space mid-range is ("));
acutPrintf(ACRX_T(" %lf, "), midRange.x);
acutPrintf(ACRX_T("%lf "), midRange.y);
acutPrintf(ACRX_T(")\n"));
acutPrintf(ACRX_T(" Point on surface is ("));
acutPrintf (ACRX_T("%lf , "), pointOnSurface.x);
acutPrintf (ACRX_T("%lf , "), pointOnSurface.y);
acutPrintf (ACRX_T("%lf "), pointOnSurface.z);
acutPrintf(ACRX_T(")\n"));
acutPrintf(ACRX_T("Surface Evaluation End\n"));
}
delete surfaceGeometry;
Adesk::Boolean oriented;
returnValue = faceEntity.getOrientToSurface(oriented);
if (returnValue != AcBr::eOk) {
acutPrintf(ACRX_T("\n Error in AcBrFace::getOrientToSurface:"));
errorReport(returnValue);
return returnValue;
}
oriented ? acutPrintf(ACRX_T("\nSurface Orientation is Positive\n"))
: acutPrintf(ACRX_T("\nSurface Orientation is Negative\n"));
return returnValue;
}
void Additional_Class::Get_ArcMiddle( AcDbObjectId PolyLineId, AcGePoint3dArray &Middle_List,AcGePoint3dArray &CenterListInput, LINEINFO &ArcInfoRList, LINEINFO &ArcInfoAList )
{
double PI=3.1415926535897932384626433832795;
AcDbEntity *pEnt_Temp = NULL;
Acad::ErrorStatus es = acdbOpenAcDbEntity(pEnt_Temp, PolyLineId, AcDb::kForRead);
if (es != Acad::eOk)
{
acutPrintf(_T("\nOPEN ENTITY ERROR"));
return;
}
if (!pEnt_Temp->isKindOf(AcDbPolyline::desc()))
{
acutPrintf(_T("\nENTITY NOT POLYLINE"));
return;
}
AcDbPolyline *pPolyLine = AcDbPolyline::cast(pEnt_Temp);
int num = pPolyLine->numVerts();
AcGePoint3d Start_temp_PT,End_temp_PT;
AcGePoint3dArray Center_List;
for (int index=0; index<num; index++)
{
if (pPolyLine->segType(index) == AcDbPolyline::kArc)
{
AcGeCircArc2d tempArc;
pPolyLine->getArcSegAt(index,tempArc);
AcGePoint2d CenterPoint;
CenterPoint = tempArc.center();
AcGePoint3d CenterPoint3d;
CenterPoint3d.set(CenterPoint.x, CenterPoint.y, 0);
Center_List.append(CenterPoint3d);
AcGePoint3d Start_temp_PT, End_temp_PT;
Start_temp_PT.set(tempArc.startPoint().x,tempArc.startPoint().y,0);
End_temp_PT.set(tempArc.endPoint().x,tempArc.endPoint().y,0);
AcGeVector3d tempVec;
tempVec = End_temp_PT - Start_temp_PT;
double tempVec_Len = tempVec.length();
tempVec.normalize();
tempVec = tempVec*(tempVec_Len/2);
AcGeVector3d CenterVec;
CenterVec = Start_temp_PT - CenterPoint3d;
CenterVec = CenterVec + tempVec;
AcGeLine2d CenterLine2d;
AcGePoint3d Middle_Pt_OnLine;
Middle_Pt_OnLine = CenterPoint3d+CenterVec;
AcGePoint2d middle2d;
middle2d.set(Middle_Pt_OnLine.x, Middle_Pt_OnLine.y);
CenterLine2d.set(CenterPoint, middle2d);
int s;
AcGePoint2d MiddlePT, pt2;
tempArc.intersectWith(CenterLine2d, s, MiddlePT, pt2);
AcGePoint3d MiddlePoint;
MiddlePoint.set(MiddlePT.x,MiddlePT.y,0);
Middle_List.append(MiddlePoint);
double StartAngle = tempArc.startAng();
double EndAngle = tempArc.endAng();
double Angle = EndAngle-StartAngle;
Angle = (180/PI)*Angle;
double Radius = tempArc.radius();
CString tempStr_Angle,tempStr_Radius,sita,du,banjing;
sita = "θ=";
du = "°";
banjing = "R=";
tempStr_Angle.Format(_T("%.1f"),Angle);
tempStr_Angle = sita+tempStr_Angle+du;
tempStr_Radius.Format(_T("%.1f"),Radius);
tempStr_Radius = banjing + tempStr_Radius;
ArcInfoRList.push_back(tempStr_Radius);
ArcInfoAList.push_back(tempStr_Angle);
}
}
CenterListInput = Center_List;
}
