void StateRenderTest::Enter(beStateMachine* stateMachine)
{
auto renderInterface = m_appData->renderInterface;
auto shaderPack = m_appData->shaderPack;
shaderPack->UpdateFrameBuffers(renderInterface, m_camera.GetViewMatrix()); // Set ortho matrix buffer
m_font.Init(renderInterface, shaderPack, "tutefont.txt", "tutefont.dds");
m_models.AddNew()->Init(renderInterface, shaderPack, "boar.dds");
m_models.AddNew()->InitWithFilename(renderInterface, shaderPack, "zombie/obj/zombie.obj", "zombie/obj/zombie.mtl", beModel::LoadOptions::Swizzle(beModel::LoadOptions::swizZ, beModel::LoadOptions::swizX, beModel::LoadOptions::swizY));
m_models.AddNew()->InitWithFilename(renderInterface, shaderPack, "cube.obj", "seafloor.dds", {});
m_models.AddNew()->InitWithFilename(renderInterface, shaderPack, "cube2.obj", "seafloor.dds", {});
m_models.AddNew()->InitWithFilename(renderInterface, shaderPack, "teapot.obj", "seafloor.dds", {beRendering::Topology::TriangleList, true, 1.f,{0,2,1}});
m_models.AddNew()->InitWithFilename(renderInterface, shaderPack, "boxes.obj", "barrels.dds", {beRendering::Topology::TriangleList, true, 0.1f,{0,2,1}});
InitGrid(renderInterface);
beTexture::LoadOptions textureLoadOptions;
textureLoadOptions.height = 256;
textureLoadOptions.width = 256;
textureLoadOptions.format = beTextureFormat::R32G32B32_FLOAT;
m_screenGrabTexture.InitAsTarget(renderInterface, textureLoadOptions);
m_bitmapTexQuadNorm.Init(renderInterface, shaderPack, 0.2f, 0.2f, "boar.dds");
m_bitmapTexQuadNorm.SetPosition(0.1f, 0.1f);
m_bitmapTexQuadPixelCoord.Init(renderInterface, shaderPack, 128, 128, "bark.dds");
m_bitmapTexQuadPixelCoord.SetPosition(-0.8f, -0.5f);
m_bitmapTextDynamic.SetColour(Vec4(0.f, 1.f, 0.8f, 1.f));
m_camera.AttachGamepad(m_appData->gamepad);
m_camera.AttachMouse(m_appData->mouse);
}
void MultiViewerMain::Connect(const char* a_strHost, const char* a_strPort, const char* a_strDBName, const char* a_strID, const char* a_strPassword, const char* a_strType)
{
#ifdef __CUBRID__SUPPORT__
if(strncmp(a_strType, CURBRID_TYPENAME , strlen(CURBRID_TYPENAME)) == 0)
m_pSQLReader = new CubridReader();
else
return;
eDBReaderErr_t eDBReaderErr = m_pSQLReader->Connect(a_strHost, a_strPort, a_strDBName, a_strID, a_strPassword, NULL);
if(eDBReaderSuccess != eDBReaderErr )
{
ErrorDialog("Connect Error");
return;
}
m_eProgramState = eStateFileOpened;
InitSQLTableInfo();
InitGrid(m_pTableDBDataGrid, true);
m_bDirty = false;
#else
ErrorDialog("This version not support this action");
return;
#endif
}
void MultiViewerMain::Restore(VecArray2D<wxString>* a_p2DTableData, vector<wxString>* a_pColName, wxGrid* a_pwxGrid ,int a_nStartRow, int a_nEndRow)
{
int nStartRow = a_nStartRow;
InitGrid(a_pwxGrid, true);
unsigned int nRowTotal = a_nEndRow - a_nStartRow + 1;
unsigned int nColTotal = a_p2DTableData->GetColSize();
a_pwxGrid->AppendRows(nRowTotal);
a_pwxGrid->AppendCols(nColTotal);
SetColHeader(a_pwxGrid, a_pColName );
unsigned int nCol = 0;
unsigned int nRow = 0;
for(nRow=0; nRow < nRowTotal ; nRow++ , nStartRow++)
{
for(nCol = 0; nCol < nColTotal ; nCol++)
{
wxString wstrData;
wstrData = a_p2DTableData->GetData(nStartRow - 1, nCol);
a_pwxGrid->SetCellValue(nRow, nCol, wstrData);
}
wxString wxstrRowNumber;
wxstrRowNumber.Printf(_T("%d"), nStartRow);
a_pwxGrid->SetRowLabelValue(nRow , wxstrRowNumber);
}
}
BOOL KSceneSettingDialogV2::OnInitDialog()
{
BOOL bRet = CDialog::OnInitDialog();
///³õʼ»¯Grid
/*{
TypeGridCtrl::InitAppearanceStruct InitStruct;
InitStruct.m_nRowCount = 10;
InitStruct.m_nColumnCount = 2;
InitStruct.m_nFixedRowCount = 1;
InitStruct.m_nFixedColumnCount = 0;
InitStruct.m_nDefColumnWidth = 100;
InitStruct.m_nFixedColumnWidth = 100;
InitStruct.m_nDefRowHeight = 15;
InitStruct.m_bEditEnable = true;
InitStruct.m_bInitBasicTitles = false;
InitStruct.m_bEnableHightLighFixed = false;
InitStruct.m_bSingleRowSelection = true;
InitStruct.m_bSingleColomnSelection = true;
InitStruct.m_bEnableRowResize = false;
InitStruct.m_bEnableColResize = true;
InitStruct.m_csCornerDescription = _T("");
m_GridCtrl.InitAppearance(&InitStruct);
}*/
InitGrid();
return bRet;
}
CurveEditor::CurveEditor(MyGUI::Widget* _parent)
{
initialiseByAttributes(this, _parent);
mEditTimeEditBox->setEditReadOnly(true);
mEditValueEditBox->setEditReadOnly(true);
mRangeMinEditBox->eventKeyLostFocus += MyGUI::newDelegate(this, &CurveEditor::NotifyRangeLostFocus);
mRangeMinEditBox->eventEditSelectAccept += MyGUI::newDelegate(this, &CurveEditor::NotifyRangeEditAccept);
mRangeMaxEditBox->eventKeyLostFocus += MyGUI::newDelegate(this, &CurveEditor::NotifyRangeLostFocus);
mRangeMaxEditBox->eventEditSelectAccept += MyGUI::newDelegate(this, &CurveEditor::NotifyRangeEditAccept);
MyGUI::PolygonalSkin::CreateLineSets = false;
MyGUI::Widget* widget = mCurveCanvasWidget->createWidget<MyGUI::Widget>("PolygonalSkin",
MyGUI::IntCoord(MyGUI::IntPoint(), mCurveCanvasWidget->getSize()), MyGUI::Align::Stretch);
widget->setColour(MyGUI::Colour::Red);
MyGUI::ISubWidget* main = widget->getSubWidgetMain();
mCurveLines = main->castType<MyGUI::PolygonalSkin>();
MyGUI::PolygonalSkin::CreateLineSets = true;
widget = mCurveCanvasWidget->createWidget<MyGUI::Widget>("PolygonalSkin",
MyGUI::IntCoord(MyGUI::IntPoint(), mCurveCanvasWidget->getSize()), MyGUI::Align::Stretch);
widget->setColour(MyGUI::Colour::Red);
main = widget->getSubWidgetMain();
mCurveCanvas = main->castType<MyGUI::PolygonalSkin>();
widget->eventMouseButtonPressed += MyGUI::newDelegate(this, &CurveEditor::NotifyMousePressed);
MyGUI::PolygonalSkin::CreateLineSets = false;
mCanvasWidget = widget;
mCurveCanvas->setWidth(5.0f);
std::vector<MyGUI::FloatPoint> mLinePoints;
mLinePoints.push_back(MyGUI::FloatPoint(0, 0));
mLinePoints.push_back(MyGUI::FloatPoint(0, 1));
mCurveCanvas->setPoints(mLinePoints);
mLinePoints.clear();
mCurveCanvas->setPoints(mLinePoints); // todo fix it
mCurveLines->_setColour(MyGUI::Colour(0.2f, 0.2f, 0.2f));
// default range
mValueRange.x = 0;
mValueRange.y = 10;
mRangeMinEditBox->setCaption("0");
mRangeMaxEditBox->setCaption("10");
InitGrid();
RefreshNumbers();
MyGUI::Window* window = mMainWidget->castType<MyGUI::Window>(false);
if (window != nullptr)
window->eventWindowButtonPressed += newDelegate(this, &CurveEditor::NotifyWindowButtonPressed);
mSplineButton = mMainWidget->createWidget<MyGUI::Button>("CheckBox",
MyGUI::IntCoord(15, 10, 95, 25),
MyGUI::Align::Left | MyGUI::Align::Top);
mSplineButton->setCaption("Use Spline");
mSplineButton->eventMouseButtonClick += MyGUI::newDelegate(this, &CurveEditor::NotifySplineChecked);
}
void
ConstructLocalGrid (long my_id)
{
Local[my_id].Local_Grid = InitGrid(my_id); /* Create the root box */
InsertParticlesInTree(my_id, MY_PARTICLES, MY_NUM_PARTICLES,
Local[my_id].Local_Grid);
/* Put all of your particles into your local tree */
}
void MultiViewerMain::FileNew(const char* a_strFileName )
{
m_pSQLReader->FileNew(a_strFileName );
m_eProgramState = eStateFileOpened;
InitSQLTableInfo();
InitGrid(m_pTableDBDataGrid, true);
m_bDirty = false;
}
Grid(const Grid& rhs) :
index_translations(rhs.Indexing()),
level(rhs.Level()),
global(rhs.Global()),
local(rhs.Local()),
extent(rhs.Extent()),
iterators(rhs.Iterators()),
father(rhs.Father())
{
InitGrid();
SetGrid(rhs);
}
void MultiViewerMain::FileOpen(const char* a_strFileName )
{
if(m_eProgramState == eStateFileOpened && m_bDirty)
{
// wxMessageBox(_("Test"), _("OnMenuFileOpen"));
}
m_pSQLReader->FileOpen(a_strFileName );
m_eProgramState = eStateFileOpened;
InitSQLTableInfo();
InitGrid(m_pTableDBDataGrid, true);
m_bDirty = false;
}
Grid(const GlobalIndices& global_,
const LocalIndices& local_,
const SpatialExtent& extent_,
int level_ = 0,
Multigrid* father_ = NULL) :
index_translations(this),
level(level_),
global(global_),
local(local_),
extent(extent_),
iterators(local_),
father(father_)
{
InitGrid();
}
void AstarPathfind::GenerateGrid(CMap* map)
{
grid.resize(map->GetNumOfTiles_MapHeight());
for(int i = 0; i < map->GetNumOfTiles_MapHeight(); ++i)
{
grid[i].resize(map->GetNumOfTiles_MapWidth());
for(int j = 0; j < map->GetNumOfTiles_MapWidth(); ++j)
{
PositionNode* positionNode = new PositionNode;
grid[i][j] = positionNode;
}
}
InitGrid(map);
}
void GraphEditor::load(bool initgrid)
// by default initgrid = true
// when editing (erasing edges, vertices,reorienting) initgrid = false
{
if(!is_init) //MAC
{gwp->canvas->setSceneRect(0,0,contentsRect().width(),contentsRect().height());
is_init=true;
}
//if(!is_init)return;
clear();// delete all items
if(gwp->pGG->nv() > staticData::MaxND)
{Tprintf("Too big graph nv= %d (>%d)",gwp->pGG->nv(),staticData::MaxND);return;}
GeometricGraph & G = *(gwp->pGG);
if(initgrid)
{Normalise();
InitGrid(current_grid);
}
DrawGrid(current_grid);
if(ShowGrid)showGrid(true);
Prop<NodeItem *> nodeitem(G.Set(tvertex()),PROP_CANVAS_ITEM,(NodeItem *)NULL);
Prop<EdgeItem *> edgeitem(G.Set(tedge()),PROP_CANVAS_ITEM,(EdgeItem *)NULL);
nodeitem.SetName("nodeitem");edgeitem.SetName("edgeitem");
for(tvertex v = 1;v <= G.nv();v++)
nodeitem[v] = CreateNodeItem(v,gwp);
for(tedge e = 1;e <= G.ne();e++)
edgeitem[e] = CreateEdgeItem(e,gwp);
if(staticData::ShowExtTbrin())
{tedge e = G.extbrin().GetEdge();
EdgeItem *edge = (G.extbrin() > 0) ? edgeitem[e] : edgeitem[e]->opp;
edge->SetColor(color[Green],false);
}
Prop<bool> eoriented(G.Set(tedge()),PROP_ORIENTED,false);
CreateColorItems(gwp,color_node,color_edge);
G.vcolor.definit(color_node);
G.vlabel.definit(0L);
G.elabel.definit(0L);
CreateThickItems(gwp,width_edge);
G.ewidth.definit(width_edge);
}
int main( int argc, char *argv[]) /* FinalApplication */
{
time_t t0, t1, t_inter;
time(&t0);
fprintf(stdout,"Starting at: %s", asctime(localtime(&t0)));
time(&t_inter);
InitGrid("Particles.inp");
time(&t1);
fprintf(stdout,"time spent on InitGrid(): %lf\n seconds",difftime(t1,t_inter));
// GenFieldGrid initialization
printf("GeneratingField...\n");
time(&t_inter);
GeneratingField(&GenFieldGrid,MaxIters);
time(&t1);
fprintf(stdout,"time spent on GeneratingField(): %lf\n seconds",difftime(t1,t_inter));
// Particle population initialization
printf("ParticleGeneration...\n");
time(&t_inter);
ParticleGeneration(GenFieldGrid, ParticleGrid, &Particles);
time(&t1);
fprintf(stdout,"time spent on ParticleGeneration(): %lf\n seconds",difftime(t1,t_inter));
// Compute evolution of the particle population
printf("SystemEvolution...\n");
time(&t_inter);
SystemEvolution(&ParticleGrid, &Particles, MaxSteps);
time(&t1);
fprintf(stdout,"time spent on SystemEvolution(): %lf\n seconds",difftime(t1,t_inter));
time(&t1);
fprintf(stdout,"Ending at: %s", asctime(localtime(&t1)));
fprintf(stdout,"Computations ended in %lf seconds\n",difftime(t1,t0));
fprintf(stdout,"End of program!\n");
return(0);
} // end FinalApplication
void CNetworkControllView::OnInitialUpdate()
{
CFormView::OnInitialUpdate();
if(g_NetWorkLevel==1)
{
CAfxMessageDialog dlg;
CString strPromption;
strPromption.LoadString(IDS_STRNOPRIVILEGE);
dlg.SetPromtionTxt(strPromption);
dlg.DoModal();
}
GetDlgItem(IDC_MacSTATIC)->ShowWindow(SW_HIDE);
GetDlgItem(IDC_MACEDIT)->ShowWindow(SW_HIDE);
GetDlgItem(IDC_GETBTN)->ShowWindow(SW_HIDE);
GetDlgItem(IDC_SAVEBTN)->ShowWindow(SW_HIDE);
GetDlgItem(IDC_FARCALLIP_BTN)->ShowWindow(SW_HIDE);
/*
GetDlgItem(IDC_GETBTN)->ShowWindow(SW_HIDE);
GetDlgItem(IDC_SAVEBTN)->ShowWindow(SW_HIDE);
GetDlgItem(IDC_REBOOTBTN)->ShowWindow(SW_HIDE);
GetDlgItem(IDC_FARCALLBTN)->ShowWindow(SW_HIDE);
GetDlgItem(IDC_FARCALLIP_BTN)->ShowWindow(SW_HIDE);
*/
SetTimer(1,20000,NULL);
// TODO: Add your specialized code here and/or call the base class
//////////////////////////////////////////////////////////////////////////
// init timesever combobox
initTimeServerList();
InitGrid();
}
int main(int argc, char *argv[])
{
int i,j,k,l,inmethod,outmethod,info,errorstat;
int nogrids,nomeshes,nofile,dim,elementsredone=0;
int nodes3d,elements3d,showmem;
Real mergeeps;
char prefix[MAXFILESIZE];
struct GridType *grids;
struct CellType *cell[MAXCASES];
struct FemType data[MAXCASES];
struct BoundaryType *boundaries[MAXCASES];
struct ElmergridType eg;
showmem = TRUE;
printf("\nStarting program Elmergrid\n");
InitParameters(&eg);
grids = (struct GridType*)malloc((size_t) (MAXCASES)*sizeof(struct GridType));
InitGrid(grids);
info = TRUE;
if(argc <= 1) {
errorstat = LoadCommands(argv[1],&eg,grids,argc-1,info);
Instructions();
if(errorstat) Goodbye();
}
if(argc == 2) {
errorstat = LoadCommands(argv[1],&eg,grids,argc-1,info);
if(errorstat) Goodbye();
}
else if(argc < 4) {
Instructions();
Goodbye();
}
else {
errorstat = InlineParameters(&eg,argc,argv);
if(errorstat) Goodbye();
}
if(!eg.outmethod || !eg.inmethod) {
printf("Please define the input and output formats\n");
}
if(eg.inmethod != 1) {
if(eg.outmethod == 1 || eg.outmethod == 8 || eg.outmethod == 9 || eg.outmethod == 10) {
printf("input of type %d can't create output of type %d\n",
eg.inmethod,eg.outmethod);
errorstat++;
Goodbye();
}
}
#if 0
if(eg.inmethod != 8 && eg.outmethod == 5) {
printf("To write Easymesh format you need to read easymesh format!\n");
errorstat++;
}
#endif
if(eg.timeron) timer_activate(eg.infofile);
/**********************************/
printf("\nElmergrid loading data:\n");
printf( "-----------------------\n");
dim = eg.dim;
nofile = 0;
nomeshes = 0;
nogrids = 0;
inmethod = eg.inmethod;
outmethod = eg.outmethod;
read_another_file:
timer_show();
switch (inmethod) {
case 1:
if(LoadElmergrid(&grids,&nogrids,eg.filesin[nofile],eg.relh,info) == 1) {
if(dim == 3) ExampleGrid3D(&grids,&nogrids,info);
if(dim == 2) ExampleGrid2D(&grids,&nogrids,info);
if(dim == 1) ExampleGrid1D(&grids,&nogrids,info);
SaveElmergrid(grids,nogrids,eg.filesin[nofile],info);
printf("Because file %s didn't exist, it was created for you.\n",eg.filesin[nofile]);
Goodbye();
}
LoadCommands(eg.filesin[nofile],&eg,grids,2,info);
break;
case 2:
boundaries[nofile] = (struct BoundaryType*)
malloc((size_t) (MAXBOUNDARIES)*sizeof(struct BoundaryType));
for(i=0;i<MAXBOUNDARIES;i++) {
boundaries[nofile][i].created = FALSE;
boundaries[nofile][i].nosides = 0;
}
if(LoadElmerInput(&(data[nofile]),boundaries[nofile],eg.filesin[nofile],info))
Goodbye();
nomeshes++;
break;
case 3:
if(LoadSolutionElmer(&(data[nofile]),TRUE,eg.filesin[nofile],info))
Goodbye();
nomeshes++;
break;
case 4:
boundaries[nofile] = (struct BoundaryType*)
malloc((size_t) (MAXBOUNDARIES)*sizeof(struct BoundaryType));
if(LoadAnsysInput(&(data[0]),boundaries[0],eg.filesin[nofile],info))
Goodbye();
nomeshes++;
break;
case 5:
boundaries[nofile] = (struct BoundaryType*)
malloc((size_t) (MAXBOUNDARIES)*sizeof(struct BoundaryType));
for(i=0;i<MAXBOUNDARIES;i++) {
boundaries[nofile][i].created = FALSE;
boundaries[nofile][i].nosides = 0;
}
if(LoadAbaqusInput(&(data[nofile]),boundaries[nofile],eg.filesin[nofile],TRUE))
Goodbye();
nomeshes++;
break;
case 6:
if(LoadAbaqusOutput(&(data[nofile]),eg.filesin[nofile],TRUE))
Goodbye();
nomeshes++;
break;
case 7:
if(LoadFidapInput(&(data[nofile]),eg.filesin[nofile],TRUE))
Goodbye();
boundaries[nofile] = (struct BoundaryType*)
malloc((size_t) (MAXBOUNDARIES)*sizeof(struct BoundaryType));
for(i=0;i<MAXBOUNDARIES;i++) {
boundaries[nofile][i].created = FALSE;
boundaries[nofile][i].nosides = 0;
}
if(0 && !eg.usenames) data[nofile].boundarynamesexist = data[nofile].bodynamesexist = FALSE;
ElementsToBoundaryConditions(&(data[nofile]),boundaries[nofile],FALSE,TRUE);
RenumberBoundaryTypes(&data[nofile],boundaries[nofile],TRUE,0,info);
nomeshes++;
break;
case 8:
boundaries[nofile] = (struct BoundaryType*)
malloc((size_t) (MAXBOUNDARIES)*sizeof(struct BoundaryType));
for(i=0;i<MAXBOUNDARIES;i++) {
boundaries[nofile][i].created = FALSE;
boundaries[nofile][i].nosides = 0;
}
if (LoadUniversalMesh(&(data[nofile]),boundaries[nofile],eg.filesin[nofile],TRUE))
Goodbye();
nomeshes++;
break;
case 9:
boundaries[nofile] = (struct BoundaryType*)
malloc((size_t) (MAXBOUNDARIES)*sizeof(struct BoundaryType));
for(i=0;i<MAXBOUNDARIES;i++) {
boundaries[nofile][i].created = FALSE;
boundaries[nofile][i].nosides = 0;
}
if(LoadComsolMesh(&(data[nofile]),eg.filesin[nofile],info))
Goodbye();
ElementsToBoundaryConditions(&(data[nofile]),boundaries[nofile],FALSE,TRUE);
nomeshes++;
break;
case 10:
if(LoadFieldviewInput(&(data[nofile]),eg.filesin[nofile],TRUE))
Goodbye();
boundaries[nofile] = (struct BoundaryType*)
malloc((size_t) (MAXBOUNDARIES)*sizeof(struct BoundaryType));
for(i=0;i<MAXBOUNDARIES;i++) {
boundaries[nofile][i].created = FALSE;
boundaries[nofile][i].nosides = 0;
}
ElementsToBoundaryConditions(&(data[nofile]),boundaries[nofile],FALSE,TRUE);
nomeshes++;
break;
case 11:
boundaries[nofile] = (struct BoundaryType*)
malloc((size_t) (MAXBOUNDARIES)*sizeof(struct BoundaryType));
for(i=0;i<MAXBOUNDARIES;i++) {
boundaries[nofile][i].created = FALSE;
boundaries[nofile][i].nosides = 0;
}
if (LoadTriangleInput(&(data[nofile]),boundaries[nofile],eg.filesin[nofile],TRUE))
Goodbye();
nomeshes++;
break;
case 12:
boundaries[nofile] = (struct BoundaryType*)
malloc((size_t) (MAXBOUNDARIES)*sizeof(struct BoundaryType));
for(i=0;i<MAXBOUNDARIES;i++) {
boundaries[nofile][i].created = FALSE;
boundaries[nofile][i].nosides = 0;
}
if (LoadMeditInput(&(data[nofile]),boundaries[nofile],eg.filesin[nofile],TRUE))
Goodbye();
nomeshes++;
break;
case 13:
boundaries[nofile] = (struct BoundaryType*)
malloc((size_t) (MAXBOUNDARIES)*sizeof(struct BoundaryType));
for(i=0;i<MAXBOUNDARIES;i++) {
boundaries[nofile][i].created = FALSE;
boundaries[nofile][i].nosides = 0;
}
if (LoadGidInput(&(data[nofile]),boundaries[nofile],eg.filesin[nofile],TRUE))
Goodbye();
nomeshes++;
break;
case 14:
boundaries[nofile] = (struct BoundaryType*)
malloc((size_t) (MAXBOUNDARIES)*sizeof(struct BoundaryType));
for(i=0;i<MAXBOUNDARIES;i++) {
boundaries[nofile][i].created = FALSE;
boundaries[nofile][i].nosides = 0;
}
if (LoadGmshInput(&(data[nofile]),boundaries[nofile],eg.filesin[nofile],TRUE))
Goodbye();
nomeshes++;
break;
case 15:
if(info) printf("Partitioned solution is fused on-the-fly therefore no other operations may be performed.\n");
FuseSolutionElmerPartitioned(eg.filesin[nofile],eg.filesout[nofile],eg.decimals,eg.partjoin,
eg.saveinterval[0],eg.saveinterval[1],eg.saveinterval[2],info);
if(info) printf("Finishing with the fusion of partitioned Elmer solutions\n");
Goodbye();
break;
#if 0
case 16:
InitializeKnots(&(data[nofile]));
if( Easymesh(argc,argv,&data[nofile].noknots,
&data[nofile].noelements,&sides))
Goodbye();
data[nofile].dim = 2;
data[nofile].coordsystem = COORD_CART2;
data[nofile].maxnodes = 3;
AllocateKnots(&(data[nofile]));
boundaries[nofile] = (struct BoundaryType*)
malloc((size_t) (MAXBOUNDARIES)*sizeof(struct BoundaryType));
for(i=0;i<MAXBOUNDARIES;i++) {
boundaries[nofile][i].created = FALSE;
boundaries[nofile][i].nosides = 0;
}
if(EasymeshCopy(&(data[nofile]),boundaries[nofile]))
Goodbye();
nomeshes++;
break;
#endif
case 17:
boundaries[nofile] = (struct BoundaryType*)
malloc((size_t) (MAXBOUNDARIES)*sizeof(struct BoundaryType));
for(i=0;i<MAXBOUNDARIES;i++) {
boundaries[nofile][i].created = FALSE;
boundaries[nofile][i].nosides = 0;
}
if (LoadNastranInput(&(data[nofile]),boundaries[nofile],eg.filesin[nofile],TRUE))
Goodbye();
nomeshes++;
break;
case 18:
boundaries[nofile] = (struct BoundaryType*)
malloc((size_t) (MAXBOUNDARIES)*sizeof(struct BoundaryType));
for(i=0;i<MAXBOUNDARIES;i++) {
boundaries[nofile][i].created = FALSE;
boundaries[nofile][i].nosides = 0;
}
if(LoadCGsimMesh(&(data[nofile]),eg.filesin[nofile],info))
Goodbye();
nomeshes++;
break;
case 19:
boundaries[nofile] = (struct BoundaryType*)
malloc((size_t) (MAXBOUNDARIES)*sizeof(struct BoundaryType));
for(i=0;i<MAXBOUNDARIES;i++) {
boundaries[nofile][i].created = FALSE;
boundaries[nofile][i].nosides = 0;
}
if (LoadGeoInput(&(data[nofile]),boundaries[nofile],eg.filesin[nofile],TRUE))
Goodbye();
nomeshes++;
break;
default:
Instructions();
Goodbye();
}
nofile++;
if(nofile < eg.nofilesin) {
printf("\nElmergrid loading data from another file:\n");
goto read_another_file;
}
/***********************************/
redoelements:
printf("\nElmergrid creating and manipulating meshes:\n");
printf( "-------------------------------------------\n");
timer_show();
if(nogrids > nomeshes && outmethod != 1) {
nomeshes = nogrids;
for(k=0;k<nogrids;k++) {
CreateCells(&(grids[k]),&(cell[k]),info);
CreateKnots(&(grids[k]),cell[k],&(data[k]),0,0);
boundaries[k] = (struct BoundaryType*)
malloc((size_t) (MAXBOUNDARIES)*sizeof(struct BoundaryType));
for(j=0;j<MAXBOUNDARIES;j++) {
boundaries[k][j].created = FALSE;
boundaries[k][j].nosides = FALSE;
}
if(grids[k].noboundaries > 0) {
for(j=0;j<grids[k].noboundaries;j++) {
if(grids[k].boundsolid[j] < 4) {
CreateBoundary(cell[k],&(data[k]),&(boundaries[k][j]),
grids[k].boundext[j],grids[k].boundint[j],
1,grids[k].boundtype[j]);
}
else {
CreatePoints(cell[k],&(data[k]),&(boundaries[k][j]),
grids[k].boundext[j],grids[k].boundint[j],
grids[k].boundsolid[j],grids[k].boundtype[j]);
}
}
}
}
}
/* In some formats the dimension for curved 2D meshes seems to be set to 2.
This should fix the problem for all input types. */
if( data->dim < 3 ) {
data->dim = GetCoordinateDimension(data,info);
}
/* Make the discontinous boundary needed, for example, in poor thermal conduction */
for(k=0;k<nomeshes;k++) {
if(!eg.discont) {
for(j=0;j<grids[k].noboundaries;j++)
if(grids[k].boundsolid[j] == 2) {
eg.discontbounds[eg.discont] = grids[k].boundtype[j];
eg.discont++;
}
}
if(eg.discont) {
for(i=1;i<=eg.discont;i++)
SetDiscontinuousBoundary(&(data[k]),boundaries[k],eg.discontbounds[i-1],2,info);
}
}
/* Divide quadrilateral meshes into triangular meshes */
for(k=0;k<nomeshes;k++)
if(nogrids && (eg.triangles || grids[k].triangles == TRUE)) {
Real criticalangle;
criticalangle = MAX(eg.triangleangle , grids[k].triangleangle);
ElementsToTriangles(&data[k],boundaries[k],criticalangle,info);
}
/* Make a boundary layer with two different methods */
if(eg.layers > 0)
for(k=0;k<nomeshes;k++)
CreateBoundaryLayer(&data[k],boundaries[k],eg.layers,
eg.layerbounds, eg.layernumber, eg.layerratios, eg.layerthickness,
eg.layerparents, eg.layermove, eg.layereps, info);
else if(eg.layers < 0)
for(k=0;k<nomeshes;k++)
CreateBoundaryLayerDivide(&data[k],boundaries[k],abs(eg.layers),
eg.layerbounds, eg.layernumber, eg.layerratios, eg.layerthickness,
eg.layerparents, info);
/* Take up the infor on rotation */
for(k=0;k<nogrids;k++)
if( grids[k].rotatecurve ) {
eg.rotatecurve = TRUE;
eg.curvezet = grids[k].curvezet;
eg.curverad = grids[k].curverad;
eg.curveangle = grids[k].curveangle;
}
if(outmethod != 1 && dim != 2 && eg.dim != 2) {
j = MAX(nogrids,1);
for(k=0;k<j;k++) {
if(grids[k].dimension == 3 || grids[k].rotate) {
boundaries[j] = (struct BoundaryType*)
malloc((size_t) (MAXBOUNDARIES)*sizeof(struct BoundaryType));
for(i=0;i<MAXBOUNDARIES;i++)
boundaries[j][i].created = FALSE;
CreateKnotsExtruded(&(data[k]),boundaries[k],&(grids[k]),
&(data[j]),boundaries[j],info);
if(nogrids) {
elements3d = MAX(eg.elements3d, grids[k].wantedelems3d);
nodes3d = MAX(eg.nodes3d, grids[k].wantednodes3d);
if(elements3d) {
if( abs(data[j].noelements - elements3d) / (1.0*elements3d) > 0.01 && elementsredone < 5 ) {
grids[k].wantedelems *= pow(1.0*elements3d / data[j].noelements, (2.0/3.0));
elementsredone++;
}
else elementsredone = 0;
}
else if(nodes3d) {
if( abs(data[j].noknots - nodes3d) / (1.0*nodes3d) > 0.01 && elementsredone < 5 ) {
grids[k].wantedelems *= pow(1.0*nodes3d / data[j].noknots, (2.0/3.0));
elementsredone++;
}
else elementsredone = 0;
}
if(elementsredone) {
nomeshes = 0;
for(i=0;i < nogrids;i++) SetElementDivision(&(grids[i]),eg.relh,info);
DestroyKnots(&data[j]);
DestroyKnots(&data[k]);
free(cell[k]);
if(info) printf("Iteration %d of elements number targiting %d in 2D\n",
elementsredone,grids[k].wantedelems);
goto redoelements;
}
}
data[k] = data[j];
boundaries[k] = boundaries[j];
}
}
}
/* If the original mesh was given in polar coordinates make the transformation into cartesian ones */
for(k=0;k<nomeshes;k++) {
if(eg.polar || data[k].coordsystem == COORD_POLAR) {
if(!eg.polar) eg.polarradius = grids[k].polarradius;
PolarCoordinates(&data[k],eg.polarradius,info);
}
}
/* If the original mesh was given in cylindrical coordinates make the transformation into cartesian ones */
for(k=0;k<nomeshes;k++) {
if(eg.cylinder || data[k].coordsystem == COORD_CYL) {
CylinderCoordinates(&data[k],info);
}
}
if(1) for(k=0;k<nomeshes;k++)
RotateTranslateScale(&data[k],&eg,info);
/* Rotate may apply to 2d and 3d geometries as well */
for(k=0;k<nomeshes;k++)
if(eg.rotatecurve)
CylindricalCoordinateCurve(&data[k],eg.curvezet,eg.curverad,eg.curveangle);
/* Unite meshes if there are several of them */
if(eg.unitemeshes) {
for(k=1;k<nomeshes;k++)
UniteMeshes(&data[0],&data[k],boundaries[0],boundaries[k],info);
nomeshes = nogrids = 1;
}
if(eg.clone[0] || eg.clone[1] || eg.clone[2]) {
for(k=0;k<nomeshes;k++) {
CloneMeshes(&data[k],boundaries[k],eg.clone,eg.clonesize,FALSE,info);
mergeeps = fabs(eg.clonesize[0]+eg.clonesize[1]+eg.clonesize[2]) * 1.0e-8;
MergeElements(&data[k],boundaries[k],eg.order,eg.corder,mergeeps,TRUE,TRUE);
}
}
if(eg.mirror[0] || eg.mirror[1] || eg.mirror[2]) {
for(k=0;k<nomeshes;k++) {
MirrorMeshes(&data[k],boundaries[k],eg.mirror,FALSE,eg.clonesize,eg.mirrorbc,info);
mergeeps = fabs(eg.clonesize[0]+eg.clonesize[1]+eg.clonesize[2]) * 1.0e-8;
MergeElements(&data[k],boundaries[k],eg.order,eg.corder,mergeeps,FALSE,TRUE);
}
}
/* Naming convection for the case of several meshes */
if(nomeshes > 1) {
strcpy(prefix,eg.filesout[0]);
for(k=0;k<nomeshes;k++)
sprintf(eg.filesout[k],"%s%d",prefix,k+1);
}
for(k=0;k<nomeshes;k++) {
if(nogrids && grids[k].reduceordermatmax) {
eg.reduce = TRUE;
eg.reducemat1 = grids[k].reduceordermatmin;
eg.reducemat2 = grids[k].reduceordermatmax;
}
if(eg.reduce)
ReduceElementOrder(&data[k],eg.reducemat1,eg.reducemat2);
}
for(k=0;k<nomeshes;k++)
if(eg.increase) IncreaseElementOrder(&data[k],TRUE);
for(k=0;k<nomeshes;k++) {
if(eg.merge)
MergeElements(&data[k],boundaries[k],eg.order,eg.corder,eg.cmerge,FALSE,TRUE);
else if(eg.order == 3)
#if PARTMETIS
ReorderElementsMetis(&data[k],TRUE);
#else
printf("Cannot order nodes by Metis as it is not even compiled!\n");
#endif
else if(eg.order)
ReorderElements(&data[k],boundaries[k],eg.order,eg.corder,TRUE);
if(eg.isoparam)
IsoparametricElements(&data[k],boundaries[k],TRUE,info);
}
/************\
** Solver *****************************************************\
** **
** Solver runs the sudoku solver. Input puzzle is in the **
** buffer array, and somewhat controlled by a number of **
** globals (see the globals at the top of the main program **
** for globals and meanings). **
** **
\****************************************************************/
int bb_solver(unsigned *puzzle)
{ register unsigned i;
PuzSolCnt = 0;
InitGrid();
for (i = 0; i < 81; i++)
if (puzzle[i])
PushSingle((char)(i), V2B[puzzle[i]]);
// Loop through the puzzle solving routines until finished
while (Changed)
{ // If No Solution possible, jump straight to the backtrack routine
if (!No_Sol)
{ // Check if any Singles to be propogated
if (SingleCnt)
{
#ifdef CALC_STATS
SCnt++;
#endif
if (SingleCnt > 2) // If multiple singles
ProcessInitSingles(); // process them all at once
if (SingleCnt) // otherwise
ProcessSingles(); // process them one at a time
if (!Gp->CellsLeft)
{ if (!No_Sol)
{ PuzSolCnt++;
if (PuzSolCnt > 1) break;
}
No_Sol = Changed = 1;
continue;
}
}
// If nothing has changed, apply the next solver
if (Changed)
{
#ifdef CALC_STATS
HCnt++;
#endif
FindHiddenSingles(); if (SingleCnt) continue;
// if (use_methods & USE_LOCK_CAND)
{
#ifdef CALC_STATS
LCCnt++;
#endif
FindLockedCandidates(); if (Changed) continue; }
}
}
//If nothing new found, just make a guess
#ifdef CALC_STATS
GCnt++;
#endif
MakeGuess();
if (No_Sol) break;
// if (!initp && (MaxDepth < PIdx)) MaxDepth = PIdx;
// if (PIdx > 62) { printf ("Max Depth exceeded, recompile for more depth.\n\n"); exit(0); }
}
#ifdef CALC_STATS
TSCnt += SCnt; // Update Stats
THCnt += HCnt;
TGCnt += GCnt;
TLCCnt += LCCnt;
TSSCnt += SSCnt;
TFCnt += FCnt;
TOneCnt += OneCnt;
TTwoCnt += TwoCnt;
#endif
return PuzSolCnt;
}
int main(int argc, char **argv)
{
int nthreads = 0;
pthread_t threads[MAXTHREADS];
grain_type rowGranularity = NONE;
long initSum = 0, finalSum = 0;
int i;
if (argc > 3)
{
gridsize = atoi(argv[1]);
if (gridsize > MAXGRIDSIZE || gridsize < 1)
{
printf("Grid size must be between 1 and 10.\n");
return(1);
}
nthreads = atoi(argv[2]);
if (nthreads < 1 || nthreads > MAXTHREADS)
{
printf("Number of threads must be between 1 and 1000.");
return(1);
}
if (argv[3][1] == 'r' || argv[3][1] == 'R')
rowGranularity = ROW;
if (argv[3][1] == 'c' || argv[3][1] == 'C')
rowGranularity = CELL;
if (argv[3][1] == 'g' || argv[3][1] == 'G')
rowGranularity = GRID;
}
else
{
printf("Format: gridapp gridSize numThreads -cell\n");
printf(" gridapp gridSize numThreads -row\n");
printf(" gridapp gridSize numThreads -grid\n");
printf(" gridapp gridSize numThreads -none\n");
return(1);
}
printf("Initial Grid:\n\n");
initSum = InitGrid(grid, gridsize);
PrintGrid(grid, gridsize);
printf("\nInitial Sum: %d\n", initSum);
printf("Executing threads...\n");
/* better to seed the random number generator outside
of do swaps or all threads will start with same
choice
*/
srand((unsigned int)time( NULL ) );
time(&start_t);
for (i = 0; i < nthreads; i++)
{
if (pthread_create(&(threads[i]), NULL, do_swaps, (void *)(&rowGranularity)) != 0)
{
perror("thread creation failed:");
exit(-1);
}
}
for (i = 0; i < nthreads; i++)
pthread_detach(threads[i]);
while (1)
{
sleep(2);
if (threads_left == 0)
{
fprintf(stdout, "\nFinal Grid:\n\n");
PrintGrid(grid, gridsize);
finalSum = SumGrid(grid, gridsize);
fprintf(stdout, "\n\nFinal Sum: %d\n", finalSum);
if (initSum != finalSum){
fprintf(stdout,"DATA INTEGRITY VIOLATION!!!!!\n");
} else {
fprintf(stdout,"DATA INTEGRITY MAINTAINED!!!!!\n");
}
fprintf(stdout, "Secs elapsed: %g\n", difftime(end_t, start_t));
exit(0);
}
}
return(0);
}
int main(int argc, char* argv[])
{
int** grid; // grid containing the cells and whether they are alive or dead
// set up curses for displaying the grid
#ifdef USE_CURSES
initscr();
if(has_colors())
{
start_color();
init_pair(1, COLOR_BLACK, COLOR_WHITE);
init_pair(2, COLOR_WHITE, COLOR_CYAN);
}
#endif
// allocate the grid
grid = AllocateGrid();
if(grid == NULL)
{
printf("ERROR: Could not allocate memory for grid\n");
return -1;
}
// initialize and print the grid
InitGrid(grid);
#ifdef PRINT_GRID
PrintGrid(grid);
#endif
for(int time = 1; time <= TIME_STEPS; ++time)
{
// sleep to observe updates
#ifdef PRINT_GRID
usleep(SLEEP_TIME);
#endif
// allocate temporary grid for storing the simultaneous update
int** tempGrid = AllocateGrid();
if(tempGrid == NULL)
{
printf("ERROR: Could not allocate memory for grid\n");
return -1;
}
for(int i = 0; i < GRID_SIZE; ++i)
{
for(int j = 0; j < GRID_SIZE; ++j)
{
int numNeighborAlive = 0;
for(int k = -1; k <= 1; ++k)
{
for(int l = -1; l <= 1; ++l)
{
int row = (i + k) % GRID_SIZE;
int col = (j + l) % GRID_SIZE;
if(row == -1)
row = GRID_SIZE - 1;
if(col == -1)
col = GRID_SIZE - 1;
if( (row != i) || (col != j) )
numNeighborAlive += grid[row][col];
}
}
switch(numNeighborAlive)
{
case 2:
tempGrid[i][j] = grid[i][j];
break;
case 3:
tempGrid[i][j] = 1;
break;
default:
tempGrid[i][j] = 0;
}
}
}
free(grid);
grid = tempGrid;
#ifdef USE_CURSES
move(0, 0);
#endif
#ifdef PRINT_GRID
PrintGrid(grid);
#endif
}
CountLive(grid);
#ifdef USE_CURSES
printw("\nPress any key to continue...");
refresh();
getchar();
#endif
free(grid);
#ifdef USE_CURSES
endwin();
#endif
return 0;
}
SquareGrid::SquareGrid(unsigned int x, unsigned int y, const bool north_south = false, const bool east_west = false)
: size_x_(x), size_y_(y), linked_north_south_(north_south), linked_east_west_(east_west)
{
InitGrid();
};
SquareGrid::SquareGrid()
: size_x_(1), size_y_(1)
{
InitGrid();
};
int main(int argc, char **argv)
{
int nthreads = 0;
#ifdef UNIX
pthread_t threads[MAXTHREADS];
#endif UNIX
grain_type rowGranularity = NONE;
#ifdef WINDOWS
HANDLE threads[MAXTHREADS];
#endif
long initSum = 0, finalSum = 0;
int i;
if (argc > 3)
{
gridsize = atoi(argv[1]);
if (gridsize > MAXGRIDSIZE || gridsize < 1)
{
printf("Grid size must be between 1 and 10.\n");
return(1);
}
nthreads = atoi(argv[2]);
if (nthreads < 1 || nthreads > MAXTHREADS)
{
printf("Number of threads must be between 1 and 1000.");
return(1);
}
if (argv[3][1] == 'r' || argv[3][1] == 'R')
rowGranularity = ROW;
if (argv[3][1] == 'c' || argv[3][1] == 'C')
rowGranularity = CELL;
if (argv[3][1] == 'g' || argv[3][1] == 'G')
rowGranularity = GRID;
}
else
{
printf("Format: gridapp gridSize numThreads -cell\n");
printf(" gridapp gridSize numThreads -row\n");
printf(" gridapp gridSize numThreads -grid\n");
printf(" gridapp gridSize numThreads -none\n");
return(1);
}
printf("Initial Grid:\n\n");
initSum = InitGrid(grid, gridsize);
PrintGrid(grid, gridsize);
printf("\nInitial Sum: %d\n", initSum);
printf("Executing threads...\n");
//initialize all the mutex we need
#ifdef UNIX
init_row_mutex(row_mutex, gridsize);
init_cell_mutex(cell_mutex, gridsize);
#endif
#ifdef WINDOWS
init_row_mutex(row_mutex, gridsize);
init_cell_mutex(cell_mutex, gridsize);
#endif
/* better to seed the random number generator outside
of do swaps or all threads will start with same
choice
*/
srand((unsigned int)time( NULL ) );
time(&start_t);
for (i = 0; i < nthreads; i++)
{
//create thread
#ifdef UNIX
if (pthread_create(&(threads[i]), NULL, do_swaps, (void *)(&rowGranularity)) != 0)
{
perror("thread creation failed:");
exit(-1);
}
#endif
#ifdef WINDOWS
threads[i]=CreateThread(NULL,0,(LPTHREAD_START_ROUTINE)do_swaps,(void*)(&rowGranularity), 0, NULL);
#endif
}
for (i = 0; i < nthreads; i++)
{
#ifdef UNIX
pthread_detach(threads[i]);
#endif
#ifdef WINDOWS
for (i = 0; i < nthreads; i++)
CloseHandle(threads[i]);
#endif
}
while (1)
{
#ifdef UNIX
sleep(2);
#endif
#ifdef WINDOWS
_sleep(2000);
#endif
if (threads_left == 0)
{
fprintf(stdout, "\nFinal Grid:\n\n");
PrintGrid(grid, gridsize);
finalSum = SumGrid(grid, gridsize);
fprintf(stdout, "\n\nFinal Sum: %d\n", finalSum);
if (initSum != finalSum){
fprintf(stdout,"DATA INTEGRITY VIOLATION!!!!!\n");
} else {
fprintf(stdout,"DATA INTEGRITY MAINTAINED!!!!!\n");
}
#ifdef UNIX
fprintf(stdout, "Secs elapsed: %g\n", difftime(end_t, start_t));
#endif
#ifdef WINDOWS
printf("secs elapsed: %d\n", end_t - start_t);
getchar();
#endif
exit(0);
}
}
//destroy the mutex we have created
#ifdef UNIX
pthread_mutex_destroy(&grid_mutex);
pthread_mutex_destroy(&row_mutex);
pthread_mutex_destroy(&lock_enter);
pthread_mutex_destroy(&lock_exit);
pthread_mutex_destroy(&cell_mutex);
#endif
#ifdef WIINDOWS
CloseHandle(grid_mutex);
CloseHandle(row_mutex);
CloseHandle(lock_enter);
CloseHandle(lock_exit);
CloseHandle(cell_mutex);
#endif
system("pause");
return(0);
}
