// Copyright (c) 1999-2014 OPEN CASCADE SAS // // This file is part of Open CASCADE Technology software library. // // This library is free software; you can redistribute it and/or modify it under // the terms of the GNU Lesser General Public License version 2.1 as published // by the Free Software Foundation, with special exception defined in the file // OCCT_LGPL_EXCEPTION.txt. Consult the file LICENSE_LGPL_21.txt included in OCCT // distribution for complete text of the license and disclaimer of any warranty. // // Alternatively, this file may be used under the terms of Open CASCADE // commercial license or contractual agreement. #include #include #include #include IMPLEMENT_STANDARD_RTTIEXT(Aspect_RectangularGrid,Aspect_Grid) Aspect_RectangularGrid::Aspect_RectangularGrid( const Standard_Real aXStep, const Standard_Real aYStep, const Standard_Real anXOrigin, const Standard_Real anYOrigin, const Standard_Real aFirstAngle, const Standard_Real aSecondAngle, const Standard_Real aRotationAngle) :Aspect_Grid(anXOrigin,anYOrigin,aRotationAngle),myXStep(aXStep),myYStep(aYStep),myFirstAngle(aFirstAngle),mySecondAngle(aSecondAngle) { Standard_NumericError_Raise_if(!CheckAngle (aFirstAngle,mySecondAngle), "networks are parallel"); Standard_NegativeValue_Raise_if(aXStep < 0. , "invalid x step"); Standard_NegativeValue_Raise_if(aYStep < 0. , "invalid y step"); Standard_NullValue_Raise_if(aXStep == 0. , "invalid x step"); Standard_NullValue_Raise_if(aYStep == 0. , "invalid y step"); } void Aspect_RectangularGrid::SetXStep(const Standard_Real aStep) { Standard_NegativeValue_Raise_if(aStep < 0. , "invalid x step"); Standard_NullValue_Raise_if(aStep == 0. , "invalid y step"); myXStep = aStep; Init(); UpdateDisplay(); } void Aspect_RectangularGrid::SetYStep(const Standard_Real aStep) { Standard_NegativeValue_Raise_if(aStep < 0. , "invalid x step"); Standard_NullValue_Raise_if(aStep == 0. , "invalid y step"); myYStep = aStep; Init(); UpdateDisplay(); } void Aspect_RectangularGrid::SetAngle (const Standard_Real anAngle1, const Standard_Real anAngle2) { Standard_NumericError_Raise_if(!CheckAngle (anAngle1,anAngle2 ), "axis are parallel"); myFirstAngle = anAngle1; mySecondAngle = anAngle2; Init(); UpdateDisplay(); } void Aspect_RectangularGrid::SetGridValues( const Standard_Real theXOrigin, const Standard_Real theYOrigin, const Standard_Real theXStep, const Standard_Real theYStep, const Standard_Real theRotationAngle) { myXOrigin = theXOrigin; myYOrigin = theYOrigin; Standard_NegativeValue_Raise_if(theXStep < 0. , "invalid x step"); Standard_NullValue_Raise_if(theXStep == 0. , "invalid x step"); myXStep = theXStep; Standard_NegativeValue_Raise_if(theYStep < 0. , "invalid y step"); Standard_NullValue_Raise_if(theYStep == 0. , "invalid y step"); myYStep = theYStep; myRotationAngle = theRotationAngle; Init(); UpdateDisplay(); } void Aspect_RectangularGrid::Compute(const Standard_Real X, const Standard_Real Y, Standard_Real& gridX, Standard_Real& gridY) const { Standard_Real D1 = b1 * X - a1 * Y - c1; Standard_Real D2 = b2 * X - a2 * Y - c2; Standard_Integer n1 = Standard_Integer ( Abs(D1)/myXStep + 0.5); Standard_Integer n2 = Standard_Integer ( Abs(D2)/myYStep + 0.5); Standard_Real offset1 = c1 + Standard_Real(n1) * Sign (myXStep , D1); Standard_Real offset2 = c2 + Standard_Real(n2) * Sign (myYStep , D2); Standard_Real Delta = a1*b2 - b1*a2; gridX = ( offset2*a1 - offset1*a2) /Delta; gridY = ( offset2*b1 - offset1*b2) /Delta; } Standard_Real Aspect_RectangularGrid::XStep() const { return myXStep; } Standard_Real Aspect_RectangularGrid::YStep() const { return myYStep; } Standard_Real Aspect_RectangularGrid::FirstAngle() const { return myFirstAngle; } Standard_Real Aspect_RectangularGrid::SecondAngle() const { return mySecondAngle; } void Aspect_RectangularGrid::Init () { //+zov Fixing CTS17856 // a1 = Cos (myFirstAngle + RotationAngle() ); // b1 = Sin (myFirstAngle + RotationAngle() ); // c1 = XOrigin() * b1 - YOrigin() * a1; // // a2 = Cos (mySecondAngle + RotationAngle() + M_PI / 2.); // b2 = Sin (mySecondAngle + RotationAngle() + M_PI / 2.); // c2 = XOrigin() * b2 - YOrigin() * a2; Standard_Real angle1 = myFirstAngle + RotationAngle(); Standard_Real angle2 = mySecondAngle + RotationAngle(); if ( angle1 != 0. ) { a1 = -Sin (angle1); b1 = Cos (angle1); c1 = XOrigin() * b1 - YOrigin() * a1; } else { a1 = 0.; b1 = 1.; c1 = XOrigin(); } if ( angle2 != 0. ) { angle2 += M_PI / 2.; a2 = -Sin (angle2); b2 = Cos (angle2); c2 = XOrigin() * b2 - YOrigin() * a2; } else { a2 = -1.; b2 = 0.; c2 = YOrigin(); } //-zov } Standard_Boolean Aspect_RectangularGrid::CheckAngle(const Standard_Real alpha, const Standard_Real beta) const { return (Abs( Sin(alpha) * Cos(beta + M_PI / 2.) - Cos(alpha) * Sin(beta + M_PI / 2.)) != 0) ; } //======================================================================= //function : DumpJson //purpose : //======================================================================= void Aspect_RectangularGrid::DumpJson (Standard_OStream& theOStream, Standard_Integer theDepth) const { OCCT_DUMP_TRANSIENT_CLASS_BEGIN (theOStream) OCCT_DUMP_BASE_CLASS(theOStream, theDepth, Aspect_Grid) OCCT_DUMP_FIELD_VALUE_NUMERICAL (theOStream, myXStep) OCCT_DUMP_FIELD_VALUE_NUMERICAL (theOStream, myYStep) OCCT_DUMP_FIELD_VALUE_NUMERICAL (theOStream, myFirstAngle) OCCT_DUMP_FIELD_VALUE_NUMERICAL (theOStream, mySecondAngle) OCCT_DUMP_FIELD_VALUE_NUMERICAL (theOStream, a1) OCCT_DUMP_FIELD_VALUE_NUMERICAL (theOStream, b1) OCCT_DUMP_FIELD_VALUE_NUMERICAL (theOStream, c1) OCCT_DUMP_FIELD_VALUE_NUMERICAL (theOStream, a2) OCCT_DUMP_FIELD_VALUE_NUMERICAL (theOStream, b2) OCCT_DUMP_FIELD_VALUE_NUMERICAL (theOStream, c2) }