void CohesiveSurface3d :: drawDeformedGeometry(oofegGraphicContext &gc, TimeStep *tStep, UnknownType type)
{
GraphicObj *go1, *go2;
if ( !gc.testElementGraphicActivity(this) ) {
return;
}
double defScale = gc.getDefScale();
WCRec p [ 2 ];
EASValsSetLineWidth(OOFEG_DEFORMED_GEOMETRY_WIDTH);
EASValsSetColor( gc.getDeformedElementColor() );
EASValsSetLayer(OOFEG_DEFORMED_GEOMETRY_LAYER);
// get the displaced particle coordinates
Particle *nodeA = ( Particle * ) giveNode(1);
Particle *nodeB = ( Particle * ) giveNode(2);
p [ 0 ].x = nodeA->giveUpdatedCoordinate(1, tStep, defScale);
p [ 0 ].y = nodeA->giveUpdatedCoordinate(2, tStep, defScale);
p [ 0 ].z = nodeA->giveUpdatedCoordinate(3, tStep, defScale);
p [ 1 ].x = nodeB->giveUpdatedCoordinate(1, tStep, defScale);
p [ 1 ].y = nodeB->giveUpdatedCoordinate(2, tStep, defScale);
p [ 1 ].z = nodeB->giveUpdatedCoordinate(3, tStep, defScale);
// plot the displaced particles
EASValsSetMType(FILLED_CIRCLE_MARKER);
EASValsSetColor( gc.getNodeColor() );
EASValsSetMSize(6);
// plot the first particle
go1 = CreateMarker3D(p);
EGWithMaskChangeAttributes(COLOR_MASK | LAYER_MASK | MTYPE_MASK | MSIZE_MASK, go1);
EMAddGraphicsToModel(ESIModel(), go1);
// take into account periodic conditions
if ( giveNumberOfNodes() == 3 ) {
Node *nodeC = ( Particle * ) giveNode(3);
p [ 1 ].x += kxa + kxa * defScale * ( nodeC->giveDofWithID(D_u)->giveUnknown(VM_Total, tStep) ) + kyb * defScale * ( nodeC->giveDofWithID(R_u)->giveUnknown(VM_Total, tStep) );
p [ 1 ].y += kyb + kyb * defScale * ( nodeC->giveDofWithID(D_v)->giveUnknown(VM_Total, tStep) ) + kzc * defScale * ( nodeC->giveDofWithID(R_v)->giveUnknown(VM_Total, tStep) );
p [ 1 ].z += kzc + kzc * defScale * ( nodeC->giveDofWithID(D_w)->giveUnknown(VM_Total, tStep) ) + kxa * defScale * ( nodeC->giveDofWithID(R_w)->giveUnknown(VM_Total, tStep) );
EASValsSetMType(CIRCLE_MARKER);
}
// plot the second particle
go2 = CreateMarker3D(p + 1);
EGWithMaskChangeAttributes(COLOR_MASK | LAYER_MASK | MTYPE_MASK | MSIZE_MASK, go2);
EMAddGraphicsToModel(ESIModel(), go2);
}
void Brick1_ht :: drawRawGeometry(oofegGraphicContext &gc)
{
WCRec p [ 8 ];
GraphicObj *go;
if ( !gc.testElementGraphicActivity(this) ) {
return;
}
EASValsSetLineWidth(OOFEG_RAW_GEOMETRY_WIDTH);
EASValsSetColor( gc.getElementColor() );
EASValsSetEdgeColor( gc.getElementEdgeColor() );
EASValsSetEdgeFlag(true);
EASValsSetLayer(OOFEG_RAW_GEOMETRY_LAYER);
EASValsSetFillStyle(FILL_SOLID);
for ( int i = 0; i < 8; i++ ) {
p [ i ].x = ( FPNum ) this->giveNode(i + 1)->giveCoordinate(1);
p [ i ].y = ( FPNum ) this->giveNode(i + 1)->giveCoordinate(2);
p [ i ].z = ( FPNum ) this->giveNode(i + 1)->giveCoordinate(3);
}
go = CreateHexahedron(p);
EGWithMaskChangeAttributes(WIDTH_MASK | FILL_MASK | COLOR_MASK | EDGE_COLOR_MASK | EDGE_FLAG_MASK | LAYER_MASK, go);
EGAttachObject(go, ( EObjectP ) this);
EMAddGraphicsToModel(ESIModel(), go);
}
void
TR_SHELL02 :: drawDeformedGeometry(oofegGraphicContext &gc, TimeStep *tStep, UnknownType type)
{
WCRec p [ 3 ];
GraphicObj *go;
double defScale = gc.getDefScale();
if ( !gc.testElementGraphicActivity(this) ) {
return;
}
if ( this->giveMaterial()->isActivated(tStep) ) {
EASValsSetLineWidth(OOFEG_DEFORMED_GEOMETRY_WIDTH);
EASValsSetColor( gc.getDeformedElementColor() );
EASValsSetEdgeColor( gc.getElementEdgeColor() );
EASValsSetEdgeFlag(true);
EASValsSetFillStyle(FILL_SOLID);
EASValsSetLayer(OOFEG_DEFORMED_GEOMETRY_LAYER);
p [ 0 ].x = ( FPNum ) this->giveNode(1)->giveUpdatedCoordinate(1, tStep, defScale);
p [ 0 ].y = ( FPNum ) this->giveNode(1)->giveUpdatedCoordinate(2, tStep, defScale);
p [ 0 ].z = ( FPNum ) this->giveNode(1)->giveUpdatedCoordinate(3, tStep, defScale);
p [ 1 ].x = ( FPNum ) this->giveNode(2)->giveUpdatedCoordinate(1, tStep, defScale);
p [ 1 ].y = ( FPNum ) this->giveNode(2)->giveUpdatedCoordinate(2, tStep, defScale);
p [ 1 ].z = ( FPNum ) this->giveNode(2)->giveUpdatedCoordinate(3, tStep, defScale);
p [ 2 ].x = ( FPNum ) this->giveNode(3)->giveUpdatedCoordinate(1, tStep, defScale);
p [ 2 ].y = ( FPNum ) this->giveNode(3)->giveUpdatedCoordinate(2, tStep, defScale);
p [ 2 ].z = ( FPNum ) this->giveNode(3)->giveUpdatedCoordinate(3, tStep, defScale);
go = CreateTriangle3D(p);
EGWithMaskChangeAttributes(WIDTH_MASK | FILL_MASK | COLOR_MASK | EDGE_COLOR_MASK | EDGE_FLAG_MASK | LAYER_MASK, go);
EMAddGraphicsToModel(ESIModel(), go);
}
}
void QTrPlaneStrain :: drawDeformedGeometry(oofegGraphicContext &gc, UnknownType type)
{
WCRec p [ 3 ];
GraphicObj *go;
TimeStep *tStep = domain->giveEngngModel()->giveCurrentStep();
double defScale = gc.getDefScale();
if ( !gc.testElementGraphicActivity(this) ) {
return;
}
EASValsSetLineWidth(OOFEG_DEFORMED_GEOMETRY_WIDTH);
EASValsSetColor( gc.getDeformedElementColor() );
EASValsSetEdgeColor( gc.getElementEdgeColor() );
EASValsSetEdgeFlag(true);
EASValsSetLayer(OOFEG_DEFORMED_GEOMETRY_LAYER);
p [ 0 ].x = ( FPNum ) this->giveNode(1)->giveUpdatedCoordinate(1, tStep, EID_MomentumBalance, defScale);
p [ 0 ].y = ( FPNum ) this->giveNode(1)->giveUpdatedCoordinate(2, tStep, EID_MomentumBalance, defScale);
p [ 0 ].z = 0.;
p [ 1 ].x = ( FPNum ) this->giveNode(2)->giveUpdatedCoordinate(1, tStep, EID_MomentumBalance, defScale);
p [ 1 ].y = ( FPNum ) this->giveNode(2)->giveUpdatedCoordinate(2, tStep, EID_MomentumBalance, defScale);
p [ 1 ].z = 0.;
p [ 2 ].x = ( FPNum ) this->giveNode(3)->giveUpdatedCoordinate(1, tStep, EID_MomentumBalance, defScale);
p [ 2 ].y = ( FPNum ) this->giveNode(3)->giveUpdatedCoordinate(2, tStep, EID_MomentumBalance, defScale);
p [ 2 ].z = 0.;
go = CreateTriangle3D(p);
EGWithMaskChangeAttributes(WIDTH_MASK | COLOR_MASK | EDGE_COLOR_MASK | EDGE_FLAG_MASK | LAYER_MASK, go);
EMAddGraphicsToModel(ESIModel(), go);
}
void LIBeam3dNL :: drawDeformedGeometry(oofegGraphicContext &gc, UnknownType type)
{
GraphicObj *go;
if ( !gc.testElementGraphicActivity(this) ) {
return;
}
TimeStep *tStep = domain->giveEngngModel()->giveCurrentStep();
double defScale = gc.getDefScale();
// if (!go) { // create new one
WCRec p [ 2 ]; /* poin */
EASValsSetLineWidth(OOFEG_DEFORMED_GEOMETRY_WIDTH);
EASValsSetColor( gc.getDeformedElementColor() );
EASValsSetLayer(OOFEG_DEFORMED_GEOMETRY_LAYER);
p [ 0 ].x = ( FPNum ) this->giveNode(1)->giveUpdatedCoordinate(1, tStep, EID_MomentumBalance, defScale);
p [ 0 ].y = ( FPNum ) this->giveNode(1)->giveUpdatedCoordinate(2, tStep, EID_MomentumBalance, defScale);
p [ 0 ].z = ( FPNum ) this->giveNode(1)->giveUpdatedCoordinate(3, tStep, EID_MomentumBalance, defScale);
p [ 1 ].x = ( FPNum ) this->giveNode(2)->giveUpdatedCoordinate(1, tStep, EID_MomentumBalance, defScale);
p [ 1 ].y = ( FPNum ) this->giveNode(2)->giveUpdatedCoordinate(2, tStep, EID_MomentumBalance, defScale);
p [ 1 ].z = ( FPNum ) this->giveNode(2)->giveUpdatedCoordinate(3, tStep, EID_MomentumBalance, defScale);
go = CreateLine3D(p);
EGWithMaskChangeAttributes(WIDTH_MASK | COLOR_MASK | LAYER_MASK, go);
EMAddGraphicsToModel(ESIModel(), go);
}
void
Lattice2d :: drawRawCrossSections(oofegGraphicContext &gc, TimeStep *tStep)
{
GraphicObj *go;
// if (!go) { // create new one
WCRec p [ 2 ]; /* poin */
if ( !gc.testElementGraphicActivity(this) ) {
return;
}
EASValsSetLineWidth(OOFEG_RAW_GEOMETRY_WIDTH);
EASValsSetColor( gc.getCrossSectionColor() );
EASValsSetLayer(OOFEG_RAW_CROSSSECTION_LAYER);
FloatArray coords;
this->giveCrossSectionCoordinates(coords);
p [ 0 ].x = ( FPNum ) coords.at(1);
p [ 0 ].y = ( FPNum ) coords.at(2);
p [ 0 ].z = ( FPNum ) coords.at(3);
p [ 1 ].x = ( FPNum ) coords.at(4);
p [ 1 ].y = ( FPNum ) coords.at(5);
p [ 1 ].z = ( FPNum ) coords.at(6);
go = CreateLine3D(p);
EGWithMaskChangeAttributes(WIDTH_MASK | COLOR_MASK | LAYER_MASK, go);
EGAttachObject(go, ( EObjectP ) this);
EMAddGraphicsToModel(ESIModel(), go);
}
void InterfaceElem2dQuad :: drawRawGeometry(oofegGraphicContext &gc, TimeStep *tStep)
{
GraphicObj *go;
// if (!go) { // create new one
WCRec p [ 2 ]; /* poin */
if ( !gc.testElementGraphicActivity(this) ) {
return;
}
EASValsSetLineWidth(OOFEG_RAW_GEOMETRY_WIDTH);
EASValsSetColor( gc.getElementColor() );
EASValsSetLayer(OOFEG_RAW_GEOMETRY_LAYER);
p [ 0 ].x = ( FPNum ) this->giveNode(1)->giveCoordinate(1);
p [ 0 ].y = ( FPNum ) this->giveNode(1)->giveCoordinate(2);
p [ 0 ].z = 0.0;
p [ 1 ].x = ( FPNum ) this->giveNode(3)->giveCoordinate(1);
p [ 1 ].y = ( FPNum ) this->giveNode(3)->giveCoordinate(2);
p [ 1 ].z = 0.0;
go = CreateLine3D(p);
EGWithMaskChangeAttributes(WIDTH_MASK | COLOR_MASK | LAYER_MASK, go);
EGAttachObject(go, ( EObjectP ) this);
EMAddGraphicsToModel(ESIModel(), go);
p [ 0 ].x = ( FPNum ) this->giveNode(3)->giveCoordinate(1);
p [ 0 ].y = ( FPNum ) this->giveNode(3)->giveCoordinate(2);
p [ 0 ].z = 0.0;
p [ 1 ].x = ( FPNum ) this->giveNode(2)->giveCoordinate(1);
p [ 1 ].y = ( FPNum ) this->giveNode(2)->giveCoordinate(2);
p [ 1 ].z = 0.0;
go = CreateLine3D(p);
EGWithMaskChangeAttributes(WIDTH_MASK | COLOR_MASK | LAYER_MASK, go);
EGAttachObject(go, ( EObjectP ) this);
EMAddGraphicsToModel(ESIModel(), go);
}
void InterfaceElem2dQuad :: drawDeformedGeometry(oofegGraphicContext &gc, TimeStep *tStep, UnknownType type)
{
GraphicObj *go;
// if (!go) { // create new one
WCRec p [ 2 ]; /* poin */
if ( !gc.testElementGraphicActivity(this) ) {
return;
}
double defScale = gc.getDefScale();
EASValsSetLineWidth(OOFEG_DEFORMED_GEOMETRY_WIDTH);
EASValsSetColor( gc.getDeformedElementColor() );
EASValsSetLayer(OOFEG_DEFORMED_GEOMETRY_LAYER + 1);
p [ 0 ].x = ( FPNum ) this->giveNode(1)->giveUpdatedCoordinate(1, tStep, defScale);
p [ 0 ].y = ( FPNum ) this->giveNode(1)->giveUpdatedCoordinate(2, tStep, defScale);
p [ 0 ].z = 0.0;
p [ 1 ].x = ( FPNum ) this->giveNode(2)->giveUpdatedCoordinate(1, tStep, defScale);
p [ 1 ].y = ( FPNum ) this->giveNode(2)->giveUpdatedCoordinate(2, tStep, defScale);
p [ 1 ].z = 0.0;
go = CreateLine3D(p);
EGWithMaskChangeAttributes(WIDTH_MASK | COLOR_MASK | LAYER_MASK, go);
EMAddGraphicsToModel(ESIModel(), go);
p [ 0 ].x = ( FPNum ) this->giveNode(4)->giveUpdatedCoordinate(1, tStep, defScale);
p [ 0 ].y = ( FPNum ) this->giveNode(4)->giveUpdatedCoordinate(2, tStep, defScale);
p [ 0 ].z = 0.0;
p [ 1 ].x = ( FPNum ) this->giveNode(5)->giveUpdatedCoordinate(1, tStep, defScale);
p [ 1 ].y = ( FPNum ) this->giveNode(5)->giveUpdatedCoordinate(2, tStep, defScale);
p [ 1 ].z = 0.0;
go = CreateLine3D(p);
EGWithMaskChangeAttributes(WIDTH_MASK | COLOR_MASK | LAYER_MASK, go);
EMAddGraphicsToModel(ESIModel(), go);
}
void LSpace :: drawDeformedGeometry(oofegGraphicContext &gc, TimeStep *tStep, UnknownType type)
{
int i;
WCRec p [ 8 ];
GraphicObj *go;
double defScale = gc.getDefScale();
if ( !gc.testElementGraphicActivity(this) ) {
return;
}
EASValsSetLineWidth(OOFEG_DEFORMED_GEOMETRY_WIDTH);
EASValsSetColor( gc.getDeformedElementColor() );
EASValsSetEdgeColor( gc.getElementEdgeColor() );
EASValsSetEdgeFlag(true);
EASValsSetLayer(OOFEG_DEFORMED_GEOMETRY_LAYER);
EASValsSetFillStyle(FILL_SOLID);
for ( i = 0; i < 8; i++ ) {
p [ i ].x = ( FPNum ) this->giveNode(i + 1)->giveUpdatedCoordinate(1, tStep, defScale);
p [ i ].y = ( FPNum ) this->giveNode(i + 1)->giveUpdatedCoordinate(2, tStep, defScale);
p [ i ].z = ( FPNum ) this->giveNode(i + 1)->giveUpdatedCoordinate(3, tStep, defScale);
}
go = CreateHexahedron(p);
EGWithMaskChangeAttributes(WIDTH_MASK | FILL_MASK | COLOR_MASK | EDGE_COLOR_MASK | EDGE_FLAG_MASK | LAYER_MASK, go);
EMAddGraphicsToModel(ESIModel(), go);
}
void QTrPlaneStrain :: drawRawGeometry(oofegGraphicContext &gc)
{
WCRec p [ 3 ];
GraphicObj *go;
if ( !gc.testElementGraphicActivity(this) ) {
return;
}
EASValsSetLineWidth(OOFEG_RAW_GEOMETRY_WIDTH);
EASValsSetColor( gc.getElementColor() );
EASValsSetEdgeColor( gc.getElementEdgeColor() );
EASValsSetEdgeFlag(true);
EASValsSetLayer(OOFEG_RAW_GEOMETRY_LAYER);
p [ 0 ].x = ( FPNum ) this->giveNode(1)->giveCoordinate(1);
p [ 0 ].y = ( FPNum ) this->giveNode(1)->giveCoordinate(2);
p [ 0 ].z = 0.;
p [ 1 ].x = ( FPNum ) this->giveNode(2)->giveCoordinate(1);
p [ 1 ].y = ( FPNum ) this->giveNode(2)->giveCoordinate(2);
p [ 1 ].z = 0.;
p [ 2 ].x = ( FPNum ) this->giveNode(3)->giveCoordinate(1);
p [ 2 ].y = ( FPNum ) this->giveNode(3)->giveCoordinate(2);
p [ 2 ].z = 0.;
go = CreateTriangle3D(p);
EGWithMaskChangeAttributes(WIDTH_MASK | COLOR_MASK | EDGE_COLOR_MASK | EDGE_FLAG_MASK | LAYER_MASK, go);
EGAttachObject(go, ( EObjectP ) this);
EMAddGraphicsToModel(ESIModel(), go);
}
void
TR_SHELL02 :: drawRawGeometry(oofegGraphicContext &gc, TimeStep *tStep)
{
WCRec p [ 3 ];
GraphicObj *go;
if ( !gc.testElementGraphicActivity(this) ) {
return;
}
if ( this->giveMaterial()->isActivated(tStep) ) {
EASValsSetLineWidth(OOFEG_RAW_GEOMETRY_WIDTH);
EASValsSetColor( gc.getElementColor() );
EASValsSetEdgeColor( gc.getElementEdgeColor() );
EASValsSetEdgeFlag(true);
EASValsSetFillStyle(FILL_SOLID);
EASValsSetLayer(OOFEG_RAW_GEOMETRY_LAYER);
p [ 0 ].x = ( FPNum ) this->giveNode(1)->giveCoordinate(1);
p [ 0 ].y = ( FPNum ) this->giveNode(1)->giveCoordinate(2);
p [ 0 ].z = ( FPNum ) this->giveNode(1)->giveCoordinate(3);
p [ 1 ].x = ( FPNum ) this->giveNode(2)->giveCoordinate(1);
p [ 1 ].y = ( FPNum ) this->giveNode(2)->giveCoordinate(2);
p [ 1 ].z = ( FPNum ) this->giveNode(2)->giveCoordinate(3);
p [ 2 ].x = ( FPNum ) this->giveNode(3)->giveCoordinate(1);
p [ 2 ].y = ( FPNum ) this->giveNode(3)->giveCoordinate(2);
p [ 2 ].z = ( FPNum ) this->giveNode(3)->giveCoordinate(3);
go = CreateTriangle3D(p);
EGWithMaskChangeAttributes(WIDTH_MASK | FILL_MASK | COLOR_MASK | EDGE_COLOR_MASK | EDGE_FLAG_MASK | LAYER_MASK, go);
EGAttachObject(go, ( EObjectP ) this);
EMAddGraphicsToModel(ESIModel(), go);
}
}
void
Lattice2d :: drawSpecial(oofegGraphicContext &gc, TimeStep *tStep)
{
WCRec p [ 2 ];
GraphicObj *tr;
GaussPoint *gp;
FloatArray crackStatuses, cf;
if ( !gc.testElementGraphicActivity(this) ) {
return;
}
if ( gc.giveIntVarType() == IST_CrackState ) {
gp = integrationRulesArray [ 0 ]->getIntegrationPoint(0);
this->giveIPValue(crackStatuses, gp, IST_CrackStatuses, tStep);
if ( crackStatuses(0) == 1. || crackStatuses(0) == 2. || crackStatuses(0) == 3 || crackStatuses(0) == 4 ) {
FloatArray coords;
this->giveCrossSectionCoordinates(coords);
p [ 0 ].x = ( FPNum ) coords.at(1);
p [ 0 ].y = ( FPNum ) coords.at(2);
p [ 0 ].z = ( FPNum ) coords.at(3);
p [ 1 ].x = ( FPNum ) coords.at(4);
p [ 1 ].y = ( FPNum ) coords.at(5);
p [ 1 ].z = ( FPNum ) coords.at(6);
EASValsSetLayer(OOFEG_CRACK_PATTERN_LAYER);
EASValsSetLineWidth(OOFEG_CRACK_PATTERN_WIDTH);
if ( ( crackStatuses(0) == 1. ) ) {
EASValsSetColor( gc.getActiveCrackColor() );
} else if ( crackStatuses(0) == 2. ) {
EASValsSetColor( gc.getCrackPatternColor() );
} else if ( crackStatuses(0) == 3. ) {
EASValsSetColor( gc.getActiveCrackColor() );
} else if ( crackStatuses(0) == 4. ) {
EASValsSetColor( gc.getActiveCrackColor() );
}
tr = CreateLine3D(p);
EGWithMaskChangeAttributes(WIDTH_MASK | COLOR_MASK | LAYER_MASK, tr);
EGAttachObject(tr, ( EObjectP ) this);
EMAddGraphicsToModel(ESIModel(), tr);
}
}
}
void IntElPoint :: drawRawGeometry(oofegGraphicContext &gc, TimeStep *tStep)
{
GraphicObj *go;
// if (!go) { // create new one
WCRec p [ 1 ]; /* poin */
if ( !gc.testElementGraphicActivity(this) ) {
return;
}
EASValsSetColor( gc.getElementColor() );
EASValsSetLayer(OOFEG_RAW_GEOMETRY_LAYER);
EASValsSetLineWidth(OOFEG_DEFORMED_GEOMETRY_WIDTH);
EASValsSetColor( gc.getDeformedElementColor() );
p [ 0 ].x = ( FPNum ) ( this->giveNode(1)->giveCoordinate(1) );
p [ 0 ].y = ( FPNum ) ( this->giveNode(1)->giveCoordinate(2) );
p [ 0 ].z = ( FPNum ) ( this->giveNode(1)->giveCoordinate(3) );
EASValsSetMType(CIRCLE_MARKER);
go = CreateMarker3D(p);
EGWithMaskChangeAttributes(WIDTH_MASK | COLOR_MASK | LAYER_MASK, go);
EMAddGraphicsToModel(ESIModel(), go);
}
void Truss2d :: drawRawGeometry(oofegGraphicContext &gc)
{
int c1, c2;
resolveCoordIndices(c1, c2);
GraphicObj *go;
// if (!go) { // create new one
WCRec p [ 2 ]; /* point */
if ( !gc.testElementGraphicActivity(this) ) {
return;
}
EASValsSetLineWidth(OOFEG_RAW_GEOMETRY_WIDTH);
EASValsSetColor( gc.getElementColor() );
EASValsSetLayer(OOFEG_RAW_GEOMETRY_LAYER);
if ( cs_mode == 0 ) {
p [ 0 ].x = ( FPNum ) this->giveNode(1)->giveCoordinate(c1);
p [ 0 ].y = 0.;
p [ 0 ].z = ( FPNum ) this->giveNode(1)->giveCoordinate(c2);
p [ 1 ].x = ( FPNum ) this->giveNode(2)->giveCoordinate(c1);
p [ 1 ].y = 0.;
p [ 1 ].z = ( FPNum ) this->giveNode(2)->giveCoordinate(c2);
} else if ( cs_mode == 1 ) {
p [ 0 ].x = ( FPNum ) this->giveNode(1)->giveCoordinate(c1);
p [ 0 ].y = ( FPNum ) this->giveNode(1)->giveCoordinate(c2);
p [ 0 ].z = 0.;
p [ 1 ].x = ( FPNum ) this->giveNode(2)->giveCoordinate(c1);
p [ 1 ].y = ( FPNum ) this->giveNode(2)->giveCoordinate(c2);
p [ 1 ].z = 0.;
} else if ( cs_mode == 2 ) {
p [ 0 ].x = 0.;
p [ 0 ].y = ( FPNum ) this->giveNode(1)->giveCoordinate(c1);
p [ 0 ].z = ( FPNum ) this->giveNode(1)->giveCoordinate(c2);
p [ 1 ].x = 0.;
p [ 1 ].y = ( FPNum ) this->giveNode(2)->giveCoordinate(c1);
p [ 1 ].z = ( FPNum ) this->giveNode(2)->giveCoordinate(c2);
}
go = CreateLine3D(p);
EGWithMaskChangeAttributes(WIDTH_MASK | COLOR_MASK | LAYER_MASK, go);
EGAttachObject(go, ( EObjectP ) this);
EMAddGraphicsToModel(ESIModel(), go);
}
void CohesiveSurface3d :: drawRawGeometry(oofegGraphicContext &gc, TimeStep *tStep)
{
if ( !gc.testElementGraphicActivity(this) ) {
return;
}
//WCRec p[4];
GraphicObj *go;
Particle *nodeA = ( Particle * ) this->giveNode(1);
Particle *nodeB = ( Particle * ) this->giveNode(2);
//double rA = nodeA -> giveRadius();
//double rB = nodeB -> giveRadius();
//double r = (rA+rB)/4.;
EASValsSetLineWidth(OOFEG_RAW_GEOMETRY_WIDTH);
EASValsSetColor( gc.getElementColor() );
EASValsSetEdgeColor( gc.getElementEdgeColor() );
EASValsSetEdgeFlag(true);
EASValsSetLayer(OOFEG_RAW_GEOMETRY_LAYER);
WCRec pl [ 2 ];
// determine coordinates of the particles connected by this element
pl [ 0 ].x = ( FPNum ) nodeA->giveCoordinate(1);
pl [ 0 ].y = ( FPNum ) nodeA->giveCoordinate(2);
pl [ 0 ].z = ( FPNum ) nodeA->giveCoordinate(3);
pl [ 1 ].x = ( FPNum ) nodeB->giveCoordinate(1);
pl [ 1 ].y = ( FPNum ) nodeB->giveCoordinate(2);
pl [ 1 ].z = ( FPNum ) nodeB->giveCoordinate(3);
if ( giveNumberOfNodes() == 3 ) {
// the second particle should be shifted (periodic arrangement)
Particle *nodeC = ( Particle * ) this->giveNode(3);
pl [ 1 ].x += kx * ( nodeC->giveCoordinate(1) );
pl [ 1 ].y += ky * ( nodeC->giveCoordinate(2) );
pl [ 1 ].z += kz * ( nodeC->giveCoordinate(3) );
}
// plot a line segment connecting the particles
go = CreateLine3D(pl);
EGWithMaskChangeAttributes(WIDTH_MASK | COLOR_MASK | LAYER_MASK, go);
EGAttachObject(go, ( EObjectP ) this);
EMAddGraphicsToModel(ESIModel(), go);
}
void LumpedMassElement :: drawRawGeometry(oofegGraphicContext &gc)
{
GraphicObj *go;
WCRec p [ 1 ]; /* point */
if ( !gc.testElementGraphicActivity(this) ) {
return;
}
EASValsSetColor( gc.getElementColor() );
EASValsSetLayer(OOFEG_RAW_GEOMETRY_LAYER);
EASValsSetMType(SQUARE_MARKER);
EASValsSetMSize(8);
p [ 0 ].x = ( FPNum ) this->giveNode(1)->giveCoordinate(1);
p [ 0 ].y = ( FPNum ) this->giveNode(1)->giveCoordinate(2);
p [ 0 ].z = ( FPNum ) this->giveNode(1)->giveCoordinate(3);
go = CreateMarker3D(p);
EGWithMaskChangeAttributes(COLOR_MASK | LAYER_MASK | MTYPE_MASK | MSIZE_MASK, go);
EGAttachObject(go, ( EObjectP ) this);
EMAddGraphicsToModel(ESIModel(), go);
}
void LumpedMassElement :: drawDeformedGeometry(oofegGraphicContext &gc, TimeStep *tStep, UnknownType type)
{
GraphicObj *go;
double defScale = gc.getDefScale();
WCRec p [ 1 ]; /* point */
if ( !gc.testElementGraphicActivity(this) ) {
return;
}
EASValsSetColor( gc.getDeformedElementColor() );
EASValsSetLayer(OOFEG_DEFORMED_GEOMETRY_LAYER);
EASValsSetMType(SQUARE_MARKER);
EASValsSetMSize(8);
p [ 0 ].x = ( FPNum ) this->giveNode(1)->giveUpdatedCoordinate(1, tStep, defScale);
p [ 0 ].y = ( FPNum ) this->giveNode(1)->giveUpdatedCoordinate(2, tStep, defScale);
p [ 0 ].z = ( FPNum ) this->giveNode(1)->giveUpdatedCoordinate(3, tStep, defScale);
go = CreateMarker3D(p);
EGWithMaskChangeAttributes(COLOR_MASK | LAYER_MASK | MTYPE_MASK | MSIZE_MASK, go);
EGAttachObject(go, ( EObjectP ) this);
EMAddGraphicsToModel(ESIModel(), go);
}
void Truss1d :: drawScalar(oofegGraphicContext &gc, TimeStep *tStep)
{
int i, indx, result = 0;
WCRec p [ 2 ];
GraphicObj *tr;
FloatArray v1, v2;
double s [ 2 ], defScale;
if ( !gc.testElementGraphicActivity(this) ) {
return;
}
if ( gc.giveIntVarMode() == ISM_recovered ) {
result += this->giveInternalStateAtNode(v1, gc.giveIntVarType(), gc.giveIntVarMode(), 1, tStep);
result += this->giveInternalStateAtNode(v2, gc.giveIntVarType(), gc.giveIntVarMode(), 2, tStep);
} else if ( gc.giveIntVarMode() == ISM_local ) {
GaussPoint *gp = integrationRulesArray [ 0 ]->getIntegrationPoint(0);
result += giveIPValue(v1, gp, gc.giveIntVarType(), tStep);
v2 = v1;
result *= 2;
}
if ( result != 2 ) {
return;
}
indx = gc.giveIntVarIndx();
s [ 0 ] = v1.at(indx);
s [ 1 ] = v2.at(indx);
EASValsSetLayer(OOFEG_VARPLOT_PATTERN_LAYER);
if ( ( gc.getScalarAlgo() == SA_ISO_SURF ) || ( gc.getScalarAlgo() == SA_ISO_LINE ) ) {
for ( i = 0; i < 2; i++ ) {
if ( gc.getInternalVarsDefGeoFlag() ) {
// use deformed geometry
defScale = gc.getDefScale();
p [ i ].x = ( FPNum ) this->giveNode(i + 1)->giveUpdatedCoordinate(1, tStep, defScale);
p [ i ].y = 0.;
p [ i ].z = 0.;
} else {
p [ i ].x = ( FPNum ) this->giveNode(i + 1)->giveCoordinate(1);
p [ i ].y = 0.;
p [ i ].z = 0.;
}
}
//EASValsSetColor(gc.getYieldPlotColor(ratio));
tr = CreateLine3D(p);
EGWithMaskChangeAttributes(LAYER_MASK, tr);
EMAddGraphicsToModel(ESIModel(), tr);
} else if ( ( gc.getScalarAlgo() == SA_ZPROFILE ) || ( gc.getScalarAlgo() == SA_COLORZPROFILE ) ) {
double landScale = gc.getLandScale();
for ( i = 0; i < 2; i++ ) {
if ( gc.getInternalVarsDefGeoFlag() ) {
// use deformed geometry
defScale = gc.getDefScale();
p [ i ].x = ( FPNum ) this->giveNode(i + 1)->giveUpdatedCoordinate(1, tStep, defScale);
p [ i ].y = 0.0;
p [ i ].z = s [ i ] * landScale;
} else {
p [ i ].x = ( FPNum ) this->giveNode(i + 1)->giveCoordinate(1);
p [ i ].y = 0.0;
p [ i ].z = s [ i ] * landScale;
}
}
if ( gc.getScalarAlgo() == SA_ZPROFILE ) {
/*
* EASValsSetColor(gc.getDeformedElementColor());
* EASValsSetLineWidth(OOFEG_DEFORMED_GEOMETRY_WIDTH);
* tr = CreateLine3D(p);
* EGWithMaskChangeAttributes(WIDTH_MASK | COLOR_MASK | LAYER_MASK, tr);
*/
WCRec pp [ 4 ];
pp [ 0 ].x = p [ 0 ].x;
pp [ 0 ].y = 0.0;
pp [ 0 ].z = 0.0;
pp [ 1 ].x = p [ 0 ].x;
pp [ 1 ].y = 0.0;
pp [ 1 ].z = p [ 0 ].z;
pp [ 2 ].x = p [ 1 ].x;
pp [ 2 ].y = 0.0;
pp [ 2 ].z = p [ 1 ].z;
pp [ 3 ].x = p [ 1 ].x;
pp [ 3 ].y = 0.0;
pp [ 3 ].z = 0.0;
tr = CreateQuad3D(pp);
EASValsSetLineWidth(OOFEG_DEFORMED_GEOMETRY_WIDTH);
EASValsSetColor( gc.getDeformedElementColor() );
//EASValsSetLayer(OOFEG_DEFORMED_GEOMETRY_LAYER);
EASValsSetFillStyle(FILL_HOLLOW);
EGWithMaskChangeAttributes(WIDTH_MASK | FILL_MASK | COLOR_MASK | LAYER_MASK, tr);
EMAddGraphicsToModel(ESIModel(), tr);
} else {
//tr = CreateTriangleWD3D(p, s[0], s[1], s[2]);
EASValsSetColor( gc.getDeformedElementColor() );
tr = CreateLine3D(p);
EGWithMaskChangeAttributes(WIDTH_MASK | COLOR_MASK | LAYER_MASK, tr);
EMAddGraphicsToModel(ESIModel(), tr);
}
}
}
void LSpace :: drawTriad(FloatArray &coords, int isurf)
{
FloatMatrix jm(3, 3);
FloatArray gc(3);
GraphicObj *go;
WCRec p [ 2 ]; // point
double coeff = 1.0;
int i, succ;
/*
* // version I
* this->interpolation.giveJacobianMatrixAt (jm, domain, nodeArray, coords);
* // determine origin
* this->interpolation.local2global (gc, domain, nodeArray, coords, 0.0);
* // draw triad
*
*/
// version II
// determine surface center
IntArray snodes(4);
FloatArray h1(3), h2(3), nn(3), n(3);
int j;
const char *colors[] = {
"red", "green", "blue"
};
this->interpolation.computeSurfaceMapping(snodes, dofManArray, isurf);
for ( i = 1; i <= 4; i++ ) {
gc.add( * ( domain->giveNode( snodes.at(i) )->giveCoordinates() ) );
}
gc.times(1. / 4.);
// determine "average normal"
nn.zero();
for ( i = 1; i <= 4; i++ ) {
j = ( i ) % 4 + 1;
h1 = * domain->giveNode( snodes.at(i) )->giveCoordinates();
h1.subtract(gc);
h2 = * domain->giveNode( snodes.at(j) )->giveCoordinates();
h2.subtract(gc);
n.beVectorProductOf(h1, h2);
if ( n.dotProduct(n, 3) > 1.e-6 ) {
n.normalize();
}
nn.add(n);
}
nn.times(1. / 4.);
if ( nn.dotProduct(nn, 3) < 1.e-6 ) {
return;
}
nn.normalize();
for ( i = 1; i <= 3; i++ ) {
jm.at(i, 3) = nn.at(i);
}
// determine lcs of surface
// local x axis in xy plane
double test = fabs(fabs( nn.at(3) ) - 1.0);
if ( test < 1.e-5 ) {
h1.at(1) = jm.at(1, 1) = 1.0;
h1.at(2) = jm.at(2, 1) = 0.0;
} else {
h1.at(1) = jm.at(1, 1) = jm.at(2, 3);
h1.at(2) = jm.at(2, 1) = -jm.at(1, 3);
}
h1.at(3) = jm.at(3, 1) = 0.0;
// local y axis perpendicular to local x,z axes
h2.beVectorProductOf(nn, h1);
for ( i = 1; i <= 3; i++ ) {
jm.at(i, 2) = h2.at(i);
}
p [ 0 ].x = gc.at(1);
p [ 0 ].y = gc.at(2);
p [ 0 ].z = gc.at(3);
for ( i = 1; i <= 3; i++ ) {
p [ 1 ].x = p [ 0 ].x + coeff *jm.at(1, i);
p [ 1 ].y = p [ 0 ].y + coeff *jm.at(2, i);
p [ 1 ].z = p [ 0 ].z + coeff *jm.at(3, i);
EASValsSetColor( ColorGetPixelFromString(const_cast< char * >(colors [ i - 1 ]), & succ) );
go = CreateLine3D(p);
EGWithMaskChangeAttributes(WIDTH_MASK | COLOR_MASK | LAYER_MASK, go);
EMAddGraphicsToModel(ESIModel(), go);
}
}
void
LSpace :: drawSpecial(oofegGraphicContext &gc, TimeStep *tStep)
{
int i, j, k;
WCRec q [ 4 ];
GraphicObj *tr;
FloatArray crackStatuses, cf;
if ( !gc.testElementGraphicActivity(this) ) {
return;
}
if ( gc.giveIntVarType() == IST_CrackState ) {
int crackStatus;
FloatArray gpc;
double length;
FloatArray crackDir;
for ( GaussPoint *gp: *this->giveDefaultIntegrationRulePtr() ) {
if ( this->giveIPValue(cf, gp, IST_CrackedFlag, tStep) == 0 ) {
return;
}
if ( ( int ) cf.at(1) == 0 ) {
return;
}
//
// obtain gp global coordinates
this->computeGlobalCoordinates( gpc, * gp->giveNaturalCoordinates() );
length = 0.3333 * cbrt(this->computeVolumeAround(gp));
if ( this->giveIPValue(crackDir, gp, IST_CrackDirs, tStep) ) {
this->giveIPValue(crackStatuses, gp, IST_CrackStatuses, tStep);
for ( i = 1; i <= 3; i++ ) {
crackStatus = ( int ) crackStatuses.at(i);
if ( ( crackStatus != pscm_NONE ) && ( crackStatus != pscm_CLOSED ) ) {
// draw a crack
// this element is 3d element
if ( i == 1 ) {
j = 2;
k = 3;
} else if ( i == 2 ) {
j = 3;
k = 1;
} else {
j = 1;
k = 2;
}
q [ 0 ].x = ( FPNum ) gpc.at(1) + 0.5 * crackDir.at(0 + j) * length + 0.5 * crackDir.at(0 + k) * length;
q [ 0 ].y = ( FPNum ) gpc.at(2) + 0.5 * crackDir.at(3 + j) * length + 0.5 * crackDir.at(3 + k) * length;
q [ 0 ].z = ( FPNum ) gpc.at(3) + 0.5 * crackDir.at(6 + j) * length + 0.5 * crackDir.at(6 + k) * length;
q [ 1 ].x = ( FPNum ) gpc.at(1) + 0.5 * crackDir.at(0 + j) * length - 0.5 * crackDir.at(0 + k) * length;
q [ 1 ].y = ( FPNum ) gpc.at(2) + 0.5 * crackDir.at(3 + j) * length - 0.5 * crackDir.at(3 + k) * length;
q [ 1 ].z = ( FPNum ) gpc.at(3) + 0.5 * crackDir.at(6 + j) * length - 0.5 * crackDir.at(6 + k) * length;
q [ 2 ].x = ( FPNum ) gpc.at(1) - 0.5 * crackDir.at(0 + j) * length - 0.5 * crackDir.at(0 + k) * length;
q [ 2 ].y = ( FPNum ) gpc.at(2) - 0.5 * crackDir.at(3 + j) * length - 0.5 * crackDir.at(3 + k) * length;
q [ 2 ].z = ( FPNum ) gpc.at(3) - 0.5 * crackDir.at(6 + j) * length - 0.5 * crackDir.at(6 + k) * length;
q [ 3 ].x = ( FPNum ) gpc.at(1) - 0.5 * crackDir.at(0 + j) * length + 0.5 * crackDir.at(0 + k) * length;
q [ 3 ].y = ( FPNum ) gpc.at(2) - 0.5 * crackDir.at(3 + j) * length + 0.5 * crackDir.at(3 + k) * length;
q [ 3 ].z = ( FPNum ) gpc.at(3) - 0.5 * crackDir.at(6 + j) * length + 0.5 * crackDir.at(6 + k) * length;
EASValsSetLayer(OOFEG_CRACK_PATTERN_LAYER);
EASValsSetLineWidth(OOFEG_CRACK_PATTERN_WIDTH);
if ( ( crackStatus == pscm_SOFTENING ) || ( crackStatus == pscm_OPEN ) ) {
EASValsSetColor( gc.getActiveCrackColor() );
} else {
EASValsSetColor( gc.getCrackPatternColor() );
}
// EASValsSetFillStyle (FILL_HOLLOW);
tr = CreateQuad3D(q);
EGWithMaskChangeAttributes(WIDTH_MASK | COLOR_MASK | LAYER_MASK, tr);
EMAddGraphicsToModel(ESIModel(), tr);
}
}
}
} // end loop over gp
}
}
void
LTRSpace :: drawSpecial(oofegGraphicContext &gc, TimeStep *tStep)
{
int i, j, k;
WCRec q [ 4 ];
GraphicObj *tr;
double defScale = gc.getDefScale();
FloatArray crackStatuses, cf;
if ( !gc.testElementGraphicActivity(this) ) {
return;
}
if ( gc.giveIntVarType() == IST_CrackState ) {
int crackStatus;
double xc, yc, zc, length;
FloatArray crackDir;
if ( numberOfGaussPoints != 1 ) {
return;
}
// for (GaussPoint *gp: *integrationRulesArray [ 0 ] ) {
{
IntegrationRule *iRule = integrationRulesArray [ 0 ];
GaussPoint *gp = iRule->getIntegrationPoint(0);
if ( this->giveIPValue(cf, gp, IST_CrackedFlag, tStep) == 0 ) {
return;
}
if ( ( int ) cf.at(1) == 0 ) {
return;
}
//
// obtain gp global coordinates - here only one exists
// it is in centre of gravity.
xc = yc = zc = 0.;
for ( i = 0; i < 4; i++ ) {
if ( gc.getInternalVarsDefGeoFlag() ) {
// use deformed geometry
xc += ( FPNum ) this->giveNode(i + 1)->giveUpdatedCoordinate(1, tStep, defScale);
yc += ( FPNum ) this->giveNode(i + 1)->giveUpdatedCoordinate(2, tStep, defScale);
zc += ( FPNum ) this->giveNode(i + 1)->giveUpdatedCoordinate(3, tStep, defScale);
} else {
xc += ( FPNum ) this->giveNode(i + 1)->giveCoordinate(1);
yc += ( FPNum ) this->giveNode(i + 1)->giveCoordinate(2);
zc += ( FPNum ) this->giveNode(i + 1)->giveCoordinate(3);
}
}
xc = xc / 4.;
yc = yc / 4.;
zc = zc / 4.;
length = TR_LENGHT_REDUCT * pow(this->computeVolumeAround(gp), 1. / 3.) / 2.0;
if ( this->giveIPValue(crackDir, gp, IST_CrackDirs, tStep) ) {
this->giveIPValue(crackStatuses, gp, IST_CrackStatuses, tStep);
for ( i = 1; i <= 3; i++ ) {
crackStatus = ( int ) crackStatuses.at(i);
if ( ( crackStatus != pscm_NONE ) && ( crackStatus != pscm_CLOSED ) ) {
// draw a crack
// this element is 3d element
if ( i == 1 ) {
j = 2;
k = 3;
} else if ( i == 2 ) {
j = 3;
k = 1;
} else {
j = 1;
k = 2;
}
q [ 0 ].x = ( FPNum ) xc + 0.5 * crackDir.at(0 + j) * length + 0.5 * crackDir.at(0 + k) * length;
q [ 0 ].y = ( FPNum ) yc + 0.5 * crackDir.at(3 + j) * length + 0.5 * crackDir.at(3 + k) * length;
q [ 0 ].z = ( FPNum ) zc + 0.5 * crackDir.at(6 + j) * length + 0.5 * crackDir.at(6 + k) * length;
q [ 1 ].x = ( FPNum ) xc + 0.5 * crackDir.at(0 + j) * length - 0.5 * crackDir.at(0 + k) * length;
q [ 1 ].y = ( FPNum ) yc + 0.5 * crackDir.at(3 + j) * length - 0.5 * crackDir.at(3 + k) * length;
q [ 1 ].z = ( FPNum ) zc + 0.5 * crackDir.at(6 + j) * length - 0.5 * crackDir.at(6 + k) * length;
q [ 2 ].x = ( FPNum ) xc - 0.5 * crackDir.at(0 + j) * length - 0.5 * crackDir.at(0 + k) * length;
q [ 2 ].y = ( FPNum ) yc - 0.5 * crackDir.at(3 + j) * length - 0.5 * crackDir.at(3 + k) * length;
q [ 2 ].z = ( FPNum ) zc - 0.5 * crackDir.at(6 + j) * length - 0.5 * crackDir.at(6 + k) * length;
q [ 3 ].x = ( FPNum ) xc - 0.5 * crackDir.at(0 + j) * length + 0.5 * crackDir.at(0 + k) * length;
q [ 3 ].y = ( FPNum ) yc - 0.5 * crackDir.at(3 + j) * length + 0.5 * crackDir.at(3 + k) * length;
q [ 3 ].z = ( FPNum ) zc - 0.5 * crackDir.at(6 + j) * length + 0.5 * crackDir.at(6 + k) * length;
EASValsSetLayer(OOFEG_CRACK_PATTERN_LAYER);
EASValsSetLineWidth(OOFEG_CRACK_PATTERN_WIDTH);
if ( ( crackStatus == pscm_SOFTENING ) || ( crackStatus == pscm_OPEN ) ) {
EASValsSetColor( gc.getActiveCrackColor() );
} else {
EASValsSetColor( gc.getCrackPatternColor() );
}
// EASValsSetFillStyle (FILL_HOLLOW);
tr = CreateQuad3D(q);
EGWithMaskChangeAttributes(WIDTH_MASK | COLOR_MASK | LAYER_MASK, tr);
EMAddGraphicsToModel(ESIModel(), tr);
}
}
}
}
}
}
void QPlaneStress2d :: drawScalar(oofegGraphicContext &context)
{
int i, indx, n [ 4 ], result = 0;
WCRec p [ 4 ], pp [ 9 ];
GraphicObj *tr;
TimeStep *tStep = this->giveDomain()->giveEngngModel()->giveCurrentStep();
FloatArray v [ 8 ];
double s [ 9 ], ss [ 4 ], defScale;
int ip;
GaussPoint *gp;
if ( !context.testElementGraphicActivity(this) ) {
return;
}
EASValsSetLayer(OOFEG_VARPLOT_PATTERN_LAYER);
if ( context.giveIntVarMode() == ISM_recovered ) {
// ============ plot the recovered values (smoothed data) ===============
for ( i = 1; i <= 8; i++ ) {
result += this->giveInternalStateAtNode(v [ i - 1 ], context.giveIntVarType(), context.giveIntVarMode(), i, tStep);
}
if ( result != 8 ) {
return;
}
indx = context.giveIntVarIndx();
for ( i = 1; i <= 8; i++ ) {
s [ i - 1 ] = v [ i - 1 ].at(indx);
}
// auxiliary value at an added central node
// computed as average of the values at all Gauss points
s [ 8 ] = 0.;
for ( ip = 1; ip <= integrationRulesArray [ 0 ]->giveNumberOfIntegrationPoints(); ip++ ) {
gp = integrationRulesArray [ 0 ]->getIntegrationPoint(ip - 1);
if ( giveIPValue(v [ 0 ], gp, context.giveIntVarType(), tStep) == 0 ) {
return;
}
s [ 8 ] += v [ 0 ].at(indx);
}
s [ 8 ] /= integrationRulesArray [ 0 ]->giveNumberOfIntegrationPoints();
//s[8] = (s[4]+s[5]+s[6]+s[7])/4.;
for ( i = 0; i < 8; i++ ) {
if ( context.getInternalVarsDefGeoFlag() ) {
// use deformed geometry
defScale = context.getDefScale();
pp [ i ].x = ( FPNum ) this->giveNode(i + 1)->giveUpdatedCoordinate(1, tStep, defScale);
pp [ i ].y = ( FPNum ) this->giveNode(i + 1)->giveUpdatedCoordinate(2, tStep, defScale);
pp [ i ].z = 0.;
} else {
// use initial geometry
pp [ i ].x = ( FPNum ) this->giveNode(i + 1)->giveCoordinate(1);
pp [ i ].y = ( FPNum ) this->giveNode(i + 1)->giveCoordinate(2);
pp [ i ].z = 0.;
}
}
pp [ 8 ].x = ( pp [ 4 ].x + pp [ 5 ].x + pp [ 6 ].x + pp [ 7 ].x ) / 4.;
pp [ 8 ].y = ( pp [ 4 ].y + pp [ 5 ].y + pp [ 6 ].y + pp [ 7 ].y ) / 4.;
pp [ 8 ].z = 0.;
for ( int t = 1; t <= 4; t++ ) {
if ( t == 1 ) {
n [ 0 ] = 0;
n [ 1 ] = 4;
n [ 2 ] = 8;
n [ 3 ] = 7;
} else if ( t == 2 ) {
n [ 0 ] = 4;
n [ 1 ] = 1;
n [ 2 ] = 5;
n [ 3 ] = 8;
} else if ( t == 3 ) {
n [ 0 ] = 5;
n [ 1 ] = 2;
n [ 2 ] = 6;
n [ 3 ] = 8;
} else {
n [ 0 ] = 6;
n [ 1 ] = 3;
n [ 2 ] = 7;
n [ 3 ] = 8;
}
ss [ 0 ] = s [ n [ 0 ] ];
ss [ 1 ] = s [ n [ 1 ] ];
ss [ 2 ] = s [ n [ 2 ] ];
ss [ 3 ] = s [ n [ 3 ] ];
for ( i = 0; i < 4; i++ ) {
p [ i ].x = pp [ n [ i ] ].x;
p [ i ].y = pp [ n [ i ] ].y;
p [ i ].z = 0.;
}
if ( context.getScalarAlgo() == SA_ISO_SURF ) {
/*
* for ( i = 0; i < 4; i++ ) {
* if ( context.getInternalVarsDefGeoFlag() ) {
* // use deformed geometry
* defScale = context.getDefScale();
* p [ i ].x = ( FPNum ) this->giveNode(n[i] + 1)->giveUpdatedCoordinate(1, tStep, defScale);
* p [ i ].y = ( FPNum ) this->giveNode(n[i] + 1)->giveUpdatedCoordinate(2, tStep, defScale);
* p [ i ].z = 0.;
* } else {
* // use initial geometry
* p [ i ].x = ( FPNum ) this->giveNode(n[i] + 1)->giveCoordinate(1);
* p [ i ].y = ( FPNum ) this->giveNode(n[i] + 1)->giveCoordinate(2);
* p [ i ].z = 0.;
* }
* }
*/
//EASValsSetColor(gc.getYieldPlotColor(ratio));
context.updateFringeTableMinMax(ss, 4);
tr = CreateQuadWD3D(p, ss [ 0 ], ss [ 1 ], ss [ 2 ], ss [ 3 ]);
EGWithMaskChangeAttributes(LAYER_MASK, tr);
EMAddGraphicsToModel(ESIModel(), tr);
} else if ( ( context.getScalarAlgo() == SA_ZPROFILE ) || ( context.getScalarAlgo() == SA_COLORZPROFILE ) ) {
//double landScale = context.getLandScale();
for ( i = 0; i < 4; i++ ) {
/*
* if ( context.getInternalVarsDefGeoFlag() ) {
* // use deformed geometry
* defScale = context.getDefScale();
* p [ i ].x = ( FPNum ) this->giveNode(i + 1)->giveUpdatedCoordinate(1, tStep, defScale);
* p [ i ].y = ( FPNum ) this->giveNode(i + 1)->giveUpdatedCoordinate(2, tStep, defScale);
* p [ i ].z = ss [ i ] * landScale;
* } else {
* // use initial geometry
* p [ i ].x = ( FPNum ) this->giveNode(i + 1)->giveCoordinate(1);
* p [ i ].y = ( FPNum ) this->giveNode(i + 1)->giveCoordinate(2);
* p [ i ].z = ss [ i ] * landScale;
* }
*/
// this fixes a bug in ELIXIR
if ( fabs(ss [ i ]) < 1.0e-6 ) {
ss [ i ] = 1.0e-6;
}
}
if ( context.getScalarAlgo() == SA_ZPROFILE ) {
EASValsSetColor( context.getDeformedElementColor() );
EASValsSetLineWidth(OOFEG_DEFORMED_GEOMETRY_WIDTH);
tr = CreateQuad3D(p);
EGWithMaskChangeAttributes(WIDTH_MASK | COLOR_MASK | LAYER_MASK, tr);
} else {
context.updateFringeTableMinMax(s, 4);
tr = CreateQuadWD3D(p, ss [ 0 ], ss [ 1 ], ss [ 2 ], ss [ 3 ]);
EGWithMaskChangeAttributes(LAYER_MASK, tr);
}
EMAddGraphicsToModel(ESIModel(), tr);
}
}
} else if ( context.giveIntVarMode() == ISM_local ) {
// ========== plot the local values (raw data) =====================
if ( numberOfGaussPoints != 4 ) {
return;
}
IntArray ind(4);
FloatArray *gpCoords;
WCRec pp [ 9 ];
for ( i = 0; i < 8; i++ ) {
if ( context.getInternalVarsDefGeoFlag() ) {
// use deformed geometry
defScale = context.getDefScale();
pp [ i ].x = ( FPNum ) this->giveNode(i + 1)->giveUpdatedCoordinate(1, tStep, defScale);
pp [ i ].y = ( FPNum ) this->giveNode(i + 1)->giveUpdatedCoordinate(2, tStep, defScale);
pp [ i ].z = 0.;
} else {
pp [ i ].x = ( FPNum ) this->giveNode(i + 1)->giveCoordinate(1);
pp [ i ].y = ( FPNum ) this->giveNode(i + 1)->giveCoordinate(2);
pp [ i ].z = 0.;
}
}
pp [ 8 ].x = 0.25 * ( pp [ 0 ].x + pp [ 1 ].x + pp [ 2 ].x + pp [ 3 ].x );
pp [ 8 ].y = 0.25 * ( pp [ 0 ].y + pp [ 1 ].y + pp [ 2 ].y + pp [ 3 ].y );
pp [ 8 ].z = 0.;
for ( ip = 1; ip <= integrationRulesArray [ 0 ]->giveNumberOfIntegrationPoints(); ip++ ) {
gp = integrationRulesArray [ 0 ]->getIntegrationPoint(ip - 1);
gpCoords = gp->giveCoordinates();
if ( ( gpCoords->at(1) > 0. ) && ( gpCoords->at(2) > 0. ) ) {
ind.at(1) = 0;
ind.at(2) = 4;
ind.at(3) = 8;
ind.at(4) = 7;
} else if ( ( gpCoords->at(1) < 0. ) && ( gpCoords->at(2) > 0. ) ) {
ind.at(1) = 4;
ind.at(2) = 1;
ind.at(3) = 5;
ind.at(4) = 8;
} else if ( ( gpCoords->at(1) < 0. ) && ( gpCoords->at(2) < 0. ) ) {
ind.at(1) = 5;
ind.at(2) = 2;
ind.at(3) = 6;
ind.at(4) = 8;
} else {
ind.at(1) = 6;
ind.at(2) = 3;
ind.at(3) = 7;
ind.at(4) = 8;
}
if ( giveIPValue(v [ 0 ], gp, context.giveIntVarType(), tStep) == 0 ) {
return;
}
indx = context.giveIntVarIndx();
for ( i = 1; i <= 4; i++ ) {
s [ i - 1 ] = v [ 0 ].at(indx);
}
for ( i = 0; i < 4; i++ ) {
p [ i ].x = pp [ ind.at(i + 1) ].x;
p [ i ].y = pp [ ind.at(i + 1) ].y;
p [ i ].z = pp [ ind.at(i + 1) ].z;
}
context.updateFringeTableMinMax(s, 4);
tr = CreateQuadWD3D(p, s [ 0 ], s [ 1 ], s [ 2 ], s [ 3 ]);
EGWithMaskChangeAttributes(LAYER_MASK, tr);
EMAddGraphicsToModel(ESIModel(), tr);
}
}
}
void
Lattice2d :: drawSpecial(oofegGraphicContext &gc, TimeStep *tStep)
{
WCRec l [ 2 ];
GraphicObj *tr;
GaussPoint *gp;
FloatArray crackStatuses, cf;
if ( !gc.testElementGraphicActivity(this) ) {
return;
}
if ( gc.giveIntVarType() == IST_CrackState ) {
gp = integrationRulesArray [ 0 ]->getIntegrationPoint(0);
this->giveIPValue(crackStatuses, gp, IST_CrackStatuses, tStep);
if ( crackStatuses(0) == 1. || crackStatuses(0) == 2. || crackStatuses(0) == 3 || crackStatuses(0) == 4 ) {
double x1, y1, x2, y2;
x1 = this->giveNode(1)->giveCoordinate(1);
y1 = this->giveNode(1)->giveCoordinate(2);
x2 = this->giveNode(2)->giveCoordinate(1);
y2 = this->giveNode(2)->giveCoordinate(2);
//Compute normal and shear direction
FloatArray normalDirection;
FloatArray shearDirection;
normalDirection.resize(2);
normalDirection.zero();
shearDirection.resize(2);
shearDirection.zero();
normalDirection.at(1) = x2 - x1;
normalDirection.at(2) = y2 - y1;
normalDirection.normalize();
if ( normalDirection.at(2) == 0. ) {
shearDirection.at(1) = 0.;
shearDirection.at(2) = 1.;
} else {
shearDirection.at(1) = 1.0;
shearDirection.at(2) =
-normalDirection.at(1) / normalDirection.at(2);
}
shearDirection.normalize();
l [ 0 ].x = ( FPNum ) this->gpCoords.at(1) - shearDirection.at(1) * this->width / 2.;
l [ 0 ].y = ( FPNum ) this->gpCoords.at(2) - shearDirection.at(2) * this->width / 2.;
l [ 0 ].z = 0.;
l [ 1 ].x = ( FPNum ) this->gpCoords.at(1) + shearDirection.at(1) * this->width / 2.;
;
l [ 1 ].y = ( FPNum ) this->gpCoords.at(2) + shearDirection.at(2) * this->width / 2.;
l [ 1 ].z = 0.;
EASValsSetLayer(OOFEG_CRACK_PATTERN_LAYER);
EASValsSetLineWidth(OOFEG_CRACK_PATTERN_WIDTH);
if ( ( crackStatuses(0) == 1. ) ) {
EASValsSetColor( gc.getActiveCrackColor() );
} else if ( crackStatuses(0) == 2. ) {
EASValsSetColor( gc.getCrackPatternColor() );
} else if ( crackStatuses(0) == 3. ) {
EASValsSetColor( gc.getActiveCrackColor() );
} else if ( crackStatuses(0) == 4. ) {
EASValsSetColor( gc.getActiveCrackColor() );
}
tr = CreateLine3D(l);
EGWithMaskChangeAttributes(WIDTH_MASK | COLOR_MASK | LAYER_MASK, tr);
EMAddGraphicsToModel(ESIModel(), tr);
}
}
}
void
LEPlic :: doInterfaceRemapping(TimeStep *atTime)
{
/*
* Final step: deposition of volume materials truncated on Lagrangian (updated)
* grid to the target grid, which is the original one in our Eulerian case.
*/
int in = 0, ie = 0, neighbrNum, nelem = domain->giveNumberOfElements();
double in_vof, total_volume = 0.0, in_vol;
IntArray neighbours, elNum(1);
FloatArray normal;
Polygon matvolpoly, elemPoly;
Graph g;
double matVol = 0.0, matVolSum = 0.0;
LEPlicElementInterface *interface, *neghbrInterface;
// loop over elements
for ( ie = 1; ie <= nelem; ie++ ) {
if ( ( interface = ( LEPlicElementInterface * ) ( domain->giveElement(ie)->giveInterface(LEPlicElementInterfaceType) ) ) ) {
interface->setTempVolumeFraction(0.0);
}
}
// loop over elements
for ( ie = 1; ie <= nelem; ie++ ) {
//fprintf (stderr, "doInterfaceRemapping: processing elem %d\n", ie);
// examine only neighbours -> this is the limit on time step
elNum.at(1) = ie;
domain->giveConnectivityTable()->giveElementNeighbourList(neighbours, elNum);
// form polygon of material volume on Lagrangian element
if ( ( interface = ( LEPlicElementInterface * ) ( domain->giveElement(ie)->giveInterface(LEPlicElementInterfaceType) ) ) ) {
if ( interface->giveVolumeFraction() > LEPLIC_ZERO_VOF ) {
interface->giveTempInterfaceNormal(normal);
interface->formMaterialVolumePoly(matvolpoly, this, normal, interface->giveTempLineConstant(), true);
matVol = matvolpoly.computeVolume();
#ifdef __OOFEG
//EASValsSetColor(::gc[OOFEG_DEBUG_LAYER].getElementColor());
//GraphicObj *go = matvolpoly.draw(::gc[OOFEG_DEBUG_LAYER],true);
//EVHiliteGraphics (myview, go);
//ESIEventLoop (YES, "Press Ctrl-p to continue");
//EVFastRedraw(myview);
#endif
try {
matVolSum = 0.0;
// loop over neighbours to truncate material volume on target (original) grid
for ( in = 1; in <= neighbours.giveSize(); in++ ) {
neighbrNum = neighbours.at(in);
if ( ( neghbrInterface = ( LEPlicElementInterface * )
( domain->giveElement(neighbrNum)->giveInterface(LEPlicElementInterfaceType) ) ) ) {
in_vof = neghbrInterface->truncateMatVolume(matvolpoly, in_vol);
neghbrInterface->addTempVolumeFraction(in_vof);
total_volume += in_vol;
matVolSum += in_vol;
}
}
} catch(GT_Exception & c) {
c.print();
neighbrNum = neighbours.at(in);
if ( ( neghbrInterface = ( LEPlicElementInterface * )
( domain->giveElement(neighbrNum)->giveInterface(LEPlicElementInterfaceType) ) ) ) {
in_vof = neghbrInterface->truncateMatVolume(matvolpoly, in_vol);
neghbrInterface->addTempVolumeFraction(in_vof);
}
}
#ifdef __OOFEG
//ESIEventLoop (YES, "Step Finished; Press Ctrl-p to continue");
#endif
double err = fabs(matVol - matVolSum) / matVol;
if ( ( err > 1.e-12 ) && ( fabs(matVol - matVolSum) > 1.e-4 ) && ( matVol > 1.e-6 ) ) {
OOFEM_WARNING4("LEPlic::doInterfaceRemapping: volume inconsistency %5.2f%%\n\ttstep %d, element %d\n", err * 100, atTime->giveNumber(), ie);
}
#if 0
if ( ( err > 2.e-3 ) && ( fabs(matVol - matVolSum) > 2.e-3 ) ) {
//debug
#ifdef __OOFEG
//ESIEventLoop (YES, "Press Ctrl-p to continue");
deleteLayerGraphics(OOFEG_DEBUG_LAYER);
EASValsSetColor( :: gc [ OOFEG_DEBUG_LAYER ].getElementColor() );
//GraphicObj *go = matvolpoly.draw(::gc[OOFEG_DEBUG_LAYER],true);
matvolpoly.draw(:: gc [ OOFEG_DEBUG_LAYER ], true);
//EVHiliteGraphics (myview, go);
//ESIEventLoop (YES, "Press Ctrl-p to continue");
EVFastRedraw(myview);
#endif
matVolSum = 0.0;
// loop over neighbours to truncate material volume on target (original) grid
for ( in = 1; in <= neighbours.giveSize(); in++ ) {
neighbrNum = neighbours.at(in);
if ( neghbrInterface = ( LEPlicElementInterface * )
( domain->giveElement(neighbrNum)->giveInterface(LEPlicElementInterfaceType) ) ) {
in_vof = neghbrInterface->truncateMatVolume(matvolpoly, in_vol);
neghbrInterface->addTempVolumeFraction(in_vof);
total_volume += in_vol;
matVolSum += in_vol;
}
}
matVolSum = 0.0;
// loop over neighbours to truncate material volume on target (original) grid
for ( in = 1; in <= neighbours.giveSize(); in++ ) {
neighbrNum = neighbours.at(in);
if ( neghbrInterface = ( LEPlicElementInterface * )
( domain->giveElement(neighbrNum)->giveInterface(LEPlicElementInterfaceType) ) ) {
in_vof = neghbrInterface->truncateMatVolume(matvolpoly, in_vol);
neghbrInterface->addTempVolumeFraction(in_vof);
total_volume += in_vol;
matVolSum += in_vol;
}
}
matVolSum = 0.0;
// loop over neighbours to truncate material volume on target (original) grid
for ( in = 1; in <= neighbours.giveSize(); in++ ) {
neighbrNum = neighbours.at(in);
if ( neghbrInterface = ( LEPlicElementInterface * )
( domain->giveElement(neighbrNum)->giveInterface(LEPlicElementInterfaceType) ) ) {
in_vof = neghbrInterface->truncateMatVolume(matvolpoly, in_vol);
neghbrInterface->addTempVolumeFraction(in_vof);
total_volume += in_vol;
matVolSum += in_vol;
}
}
/*
* ESIEventLoop (YES, "Press Ctrl-p to exit");
* ESIEventLoop (YES, "Press Ctrl-p to exit");
*/
exit(1);
}
#endif
}
} else {
OOFEM_ERROR("LEPlic::doInterfaceRemapping: Element with no LEPlicInterface support encountered");
}
} // end loop over elements
// loop over elements
for ( ie = 1; ie <= nelem; ie++ ) {
if ( ( interface = ( LEPlicElementInterface * ) ( domain->giveElement(ie)->giveInterface(LEPlicElementInterfaceType) ) ) ) {
if ( interface->giveTempVolumeFraction() > 1.0 ) {
OOFEM_LOG_INFO("LEPlic::doInterfaceRemapping - Element %d: vof out of range, vof =%e", ie, interface->giveTempVolumeFraction() );
}
if ( interface->giveTempVolumeFraction() >= 0.99999999 ) {
interface->setTempVolumeFraction(1.0);
}
}
}
OOFEM_LOG_INFO("LEPlic::doInterfaceRemapping: Total volume is %e", total_volume);
if ( orig_reference_fluid_volume > 0.0 ) {
OOFEM_LOG_INFO("LEPlic::doInterfaceRemapping: Volume error is %5.2f%%",
( ( total_volume - orig_reference_fluid_volume ) / orig_reference_fluid_volume ) * 100.0);
}
#ifdef __OOFEG
//ESIEventLoop (YES, "Step Finished; Press Ctrl-p to continue");
//deleteLayerGraphics(OOFEG_DEBUG_LAYER);
#endif
}
void
Quad10_2D_SUPG :: drawScalar(oofegGraphicContext &gc, TimeStep *tStep)
{
int i, indx, result = 0;
WCRec p [ 3 ];
GraphicObj *tr;
FloatArray v1, v2, v3;
double s [ 3 ];
if ( !gc.testElementGraphicActivity(this) ) {
return;
}
EASValsSetLayer(OOFEG_VARPLOT_PATTERN_LAYER);
// if ((gc.giveIntVarMode() == ISM_local) && (gc.giveIntVarType() == IST_VOFFraction)) {
if ( ( gc.giveIntVarType() == IST_VOFFraction ) && ( gc.giveIntVarMode() == ISM_local ) ) {
Polygon matvolpoly;
//this->formMaterialVolumePoly(matvolpoly, NULL, temp_normal, temp_p, false);
EASValsSetColor( gc.getStandardSparseProfileColor() );
//GraphicObj *go = matvolpoly.draw(gc,true,OOFEG_VARPLOT_PATTERN_LAYER);
matvolpoly.draw(gc, true, OOFEG_VARPLOT_PATTERN_LAYER);
return;
}
if ( gc.giveIntVarMode() == ISM_recovered ) {
result += this->giveInternalStateAtNode(v1, gc.giveIntVarType(), gc.giveIntVarMode(), 1, tStep);
result += this->giveInternalStateAtNode(v2, gc.giveIntVarType(), gc.giveIntVarMode(), 2, tStep);
result += this->giveInternalStateAtNode(v3, gc.giveIntVarType(), gc.giveIntVarMode(), 3, tStep);
} else if ( gc.giveIntVarMode() == ISM_local ) {
GaussPoint *gp = integrationRulesArray [ 0 ]->getIntegrationPoint(0);
result += giveIPValue(v1, gp, gc.giveIntVarType(), tStep);
v2 = v1;
v3 = v1;
result *= 3;
}
if ( result != 3 ) {
return;
}
indx = gc.giveIntVarIndx();
s [ 0 ] = v1.at(indx);
s [ 1 ] = v2.at(indx);
s [ 2 ] = v3.at(indx);
EASValsSetLayer(OOFEG_VARPLOT_PATTERN_LAYER);
if ( gc.getScalarAlgo() == SA_ISO_SURF ) {
for ( i = 0; i < 3; i++ ) {
p [ i ].x = ( FPNum ) this->giveNode(i + 1)->giveCoordinate(1);
p [ i ].y = ( FPNum ) this->giveNode(i + 1)->giveCoordinate(2);
p [ i ].z = 0.;
}
//EASValsSetColor(gc.getYieldPlotColor(ratio));
gc.updateFringeTableMinMax(s, 3);
tr = CreateTriangleWD3D(p, s [ 0 ], s [ 1 ], s [ 2 ]);
EGWithMaskChangeAttributes(LAYER_MASK, tr);
EMAddGraphicsToModel(ESIModel(), tr);
} else if ( ( gc.getScalarAlgo() == SA_ZPROFILE ) || ( gc.getScalarAlgo() == SA_COLORZPROFILE ) ) {
double landScale = gc.getLandScale();
for ( i = 0; i < 3; i++ ) {
p [ i ].x = ( FPNum ) this->giveNode(i + 1)->giveCoordinate(1);
p [ i ].y = ( FPNum ) this->giveNode(i + 1)->giveCoordinate(2);
p [ i ].z = s [ i ] * landScale;
}
if ( gc.getScalarAlgo() == SA_ZPROFILE ) {
EASValsSetColor( gc.getDeformedElementColor() );
EASValsSetLineWidth(OOFEG_DEFORMED_GEOMETRY_WIDTH);
EASValsSetFillStyle(FILL_SOLID);
tr = CreateTriangle3D(p);
EGWithMaskChangeAttributes(WIDTH_MASK | COLOR_MASK | FILL_MASK | LAYER_MASK, tr);
} else {
gc.updateFringeTableMinMax(s, 3);
EASValsSetFillStyle(FILL_SOLID);
tr = CreateTriangleWD3D(p, s [ 0 ], s [ 1 ], s [ 2 ]);
EGWithMaskChangeAttributes(FILL_MASK | LAYER_MASK, tr);
}
EMAddGraphicsToModel(ESIModel(), tr);
}
}
