bool SMFRenderStateGLSL::Init(const CSMFGroundDrawer* smfGroundDrawer) {
const std::string names[GLSL_SHADER_COUNT - 1] = {
"SMFShaderGLSL-Standard",
"SMFShaderGLSL-Deferred",
};
const std::string defs =
("#define SMF_TEXSQUARE_SIZE " + FloatToString( SMF_TEXSQUARE_SIZE) + "\n") +
("#define SMF_INTENSITY_MULT " + FloatToString(CGlobalRendering::SMF_INTENSITY_MULT) + "\n") +
("#define SMF_CLIP_PLANE_IDX " + IntToString( IWater::ClipPlaneIndex()) + "\n") +
("#define SMF_FRAGDATA_COUNT " + IntToString(GL::GeometryBuffer::ATTACHMENT_COUNT) + "\n");
if (useLuaShaders) {
for (unsigned int n = GLSL_SHADER_STANDARD; n <= GLSL_SHADER_DEFERRED; n++) {
glslShaders[n] = shaderHandler->CreateProgramObject("[SMFGroundDrawer::Lua]", names[n] + "-Lua");
// release ID created by GLSLProgramObject's ctor; should be 0
glslShaders[n]->Release();
}
} else {
for (unsigned int n = GLSL_SHADER_STANDARD; n <= GLSL_SHADER_DEFERRED; n++) {
// load from VFS files
glslShaders[n] = shaderHandler->CreateProgramObject("[SMFGroundDrawer::VFS]", names[n]);
glslShaders[n]->AttachShaderObject(shaderHandler->CreateShaderObject("GLSL/SMFVertProg4.glsl", defs, GL_VERTEX_SHADER));
glslShaders[n]->AttachShaderObject(shaderHandler->CreateShaderObject("GLSL/SMFFragProg4.glsl", defs, GL_FRAGMENT_SHADER));
}
}
glslShaders[GLSL_SHADER_CURRENT] = glslShaders[GLSL_SHADER_STANDARD];
return true;
}
std::string TextClass::XMFLOAT3ToString(XMFLOAT3 toConvert)
{
return "( " +
FloatToString(toConvert.x) + ", " +
FloatToString(toConvert.y) + ", " +
FloatToString(toConvert.z) + " )";
}
void DataClass::sendBluetooth(Measurement* measurement, int timeDec,
int valueDec) {
_signalBluetooth();
Serial.println(DataLine(measurement->_name,
FloatToString(measurement->_time, timeDec),
FloatToString(measurement->_value, valueDec)));
}
void DataClass::sendBluetooth(Actuator* actuator, int timeDec,
int valueDec) {
_signalBluetooth();
Serial.println(DataLine(actuator->_name,
FloatToString(actuator->_time, timeDec),
FloatToString(actuator->_value, valueDec)));
}
std::string ProfileReport::BuildProfileReport(){
std::string myReport = "==="+ m_name +" ===";
myReport += "\nTotal : " + FloatToString((float)m_totalElapsedTime, "%.03f") +"ms";
myReport += "\nAverage: " + FloatToString((float)m_averageElapsedTime, "%.03f") + "ms";
myReport += "\nNum Calls: " + IntToString(m_numCalls) +"\n";
//myReport += "\n% Frame Time: " + DoubleToString(m_percentFrameTime) + "\n";
return myReport;
}
static std::string GetUnitDefBuildOptionToolTip(const UnitDef* ud, bool disabled) {
std::string tooltip;
tooltip += (disabled)?
"\xff\xff\x22\x22" "DISABLED: " "\xff\xff\xff\xff":
"Build: ";
tooltip += (ud->humanName + " - " + ud->tooltip);
tooltip += ("\nHealth " + FloatToString(ud->health, "%.0f"));
tooltip += ("\nMetal cost " + FloatToString(ud->metal, "%.0f"));
tooltip += ("\nEnergy cost " + FloatToString(ud->energy, "%.0f"));
tooltip += ("\nBuild time " + FloatToString(ud->buildTime, "%.0f"));
return tooltip;
}
int printAllCutFlow(TString *cuts, int nbCuts){
cout << "<cutFlow_"+name+">" << endl;
printCutFlow(cuts,nbCuts,"all","1");
for (int i = 110; i < 160 ; i=i+10){
int lowRange = i - 5;
int highRange = i + 5;
TString lowPart = "dipho_mgg>"+FloatToString(lowRange);
TString highPart = "dipho_mgg<"+FloatToString(highRange);
TString theCond = lowPart + "&&" + highPart;
TString theName = "masse"+FloatToString(i);
printCutFlow(cuts,nbCuts,theName,theCond);
}
cout << "</cutFlow_"+name+">" << endl;
}
globle char *GetLogicalName(
void *theEnv,
int whichArgument,
char *defaultLogicalName)
{
char *logicalName;
DATA_OBJECT result;
EnvRtnUnknown(theEnv,whichArgument,&result);
if ((GetType(result) == SYMBOL) ||
(GetType(result) == STRING) ||
(GetType(result) == INSTANCE_NAME))
{
logicalName = ValueToString(result.value);
if ((strcmp(logicalName,"t") == 0) || (strcmp(logicalName,"T") == 0))
{ logicalName = defaultLogicalName; }
}
else if (GetType(result) == FLOAT)
{
logicalName = ValueToString(EnvAddSymbol(theEnv,FloatToString(theEnv,DOToDouble(result))));
}
else if (GetType(result) == INTEGER)
{
logicalName = ValueToString(EnvAddSymbol(theEnv,LongIntegerToString(theEnv,DOToLong(result))));
}
else
{ logicalName = NULL; }
return(logicalName);
}
const char *GetLogicalName(
UDFContext *context,
const char *defaultLogicalName)
{
Environment *theEnv = context->environment;
const char *logicalName;
UDFValue theArg;
if (! UDFNextArgument(context,ANY_TYPE_BITS,&theArg))
{ return NULL; }
if (CVIsType(&theArg,LEXEME_BITS) ||
CVIsType(&theArg,INSTANCE_NAME_BIT))
{
logicalName = theArg.lexemeValue->contents;
if ((strcmp(logicalName,"t") == 0) || (strcmp(logicalName,"T") == 0))
{ logicalName = defaultLogicalName; }
}
else if (CVIsType(&theArg,FLOAT_BIT))
{
logicalName = CreateSymbol(theEnv,FloatToString(theEnv,theArg.floatValue->contents))->contents;
}
else if (CVIsType(&theArg,INTEGER_BIT))
{
logicalName = CreateSymbol(theEnv,LongIntegerToString(theEnv,theArg.integerValue->contents))->contents;
}
else
{ logicalName = NULL; }
return(logicalName);
}
LispObject* SqrtFloat(LispObject* int1, LispEnvironment& aEnvironment,int aPrecision)
{
ANumber i1(*int1->Number(aPrecision)->iNumber);
ANumber res(aPrecision);
i1.ChangePrecision(aPrecision);
Sqrt(res,i1);
return FloatToString(res, aEnvironment);
}
void DataClass::sendSD(Measurement* measurement, int timeDec,
int valueDec) {
String filename = _filenameForSD(measurement->_name);
char buf[filename.length()+1];
filename.toCharArray(buf, filename.length()+1);
File dataFile = SD.open(buf, FILE_WRITE);
if (!measurement->_SDOpen) {
measurement->_SDOpen = true;
dataFile.println("---");
dataFile.println("Time,Value");
}
dataFile.println(FloatToString(measurement->_time, timeDec)
+ "," + FloatToString(measurement->_value, valueDec));
dataFile.close();
}
globle void PrintFloat(
char *fileid,
double number)
{
char *theString;
theString = FloatToString(number);
PrintRouter(fileid,theString);
}
LispObject* ModFloat( LispObject* int1, LispObject* int2, LispEnvironment& aEnvironment,
int aPrecision)
{
ANumber quotient(static_cast<int>(0));
ANumber remainder(static_cast<int>(0));
DivideInteger( quotient, remainder, int1->String()->c_str(), int2->String()->c_str(), aPrecision);
return FloatToString(remainder, aEnvironment,10);
}
Log& Log::operator<<( float i )
{
if(Instance)
{
string Message = FloatToString(i);
Instance->WriteAll(Message.c_str());
}
return *this;
}
globle void PrintFloat(
void *theEnv,
const char *fileid,
double number)
{
const char *theString;
theString = FloatToString(theEnv,number);
EnvPrintRouter(theEnv,fileid,theString);
}
void WriteFloat(
Environment *theEnv,
const char *fileid,
double number)
{
const char *theString;
theString = FloatToString(theEnv,number);
WriteString(theEnv,fileid,theString);
}
void CArborEdit::SetValue( double val)
{
if( EditStyleIs(EDIT_CURRENCY) || EditStyleIs(EDIT_FLOAT))
{
LPTSTR buff = new char[80];
FloatToString( buff, val) ;
SetWindowText(buff);
delete buff;
}
}
bool wxRealFormValidator::OnDisplayValue(wxProperty *property, wxPropertyFormView *WXUNUSED(view),
wxWindow *WXUNUSED(parentWindow) )
{
// The item used for viewing the real number: should be a text item.
wxWindow *m_propertyWindow = property->GetWindow();
if (!m_propertyWindow || !m_propertyWindow->IsKindOf(CLASSINFO(wxTextCtrl)))
return false;
wxTextCtrl *textItem = (wxTextCtrl *)m_propertyWindow;
textItem->SetValue(FloatToString(property->GetValue().RealValue()));
return true;
}
void DataClass::sendSD(Sensor* sensor, int newTrial, int trialNum,
int timeDec, int valueDec)
{
String filename = _filenameForSD(sensor->_name);
char buf[filename.length()+1];
filename.toCharArray(buf, filename.length()+1);
File dataFile = SD.open(buf, FILE_WRITE);
if (!sensor->_SDOpen) {
sensor->_SDOpen = true;
}
if (newTrial) {
dataFile.println("---");
dataFile.println("Trial " + String(trialNum));
dataFile.println("Time,Value");
}
dataFile.println(FloatToString(sensor->_timer.duration(), timeDec)
+ "," + FloatToString(sensor->readValue(), valueDec));
dataFile.close();
}
bool SMFRenderStateGLSL::Init(const CSMFGroundDrawer* smfGroundDrawer) {
if (!globalRendering->haveGLSL) {
// not possible to do (GLSL) shader-based map rendering
return false;
}
if (!configHandler->GetBool("AdvMapShading")) {
// not allowed to do (GLSL) shader-based map rendering
return false;
}
const std::string names[GLSL_SHADER_COUNT - 1] = {
"SMFShaderGLSL-Standard",
"SMFShaderGLSL-Deferred",
};
const std::string defs =
("#define SMF_TEXSQUARE_SIZE " + FloatToString( SMF_TEXSQUARE_SIZE) + "\n") +
("#define SMF_INTENSITY_MULT " + FloatToString(CGlobalRendering::SMF_INTENSITY_MULT) + "\n");
if (useLuaShaders) {
for (unsigned int n = GLSL_SHADER_STANDARD; n <= GLSL_SHADER_DEFERRED; n++) {
glslShaders[n] = shaderHandler->CreateProgramObject("[SMFGroundDrawer::Lua]", names[n] + "-Lua", false);
// release ID created by GLSLProgramObject's ctor; should be 0
glslShaders[n]->Release();
}
} else {
for (unsigned int n = GLSL_SHADER_STANDARD; n <= GLSL_SHADER_DEFERRED; n++) {
// load from VFS files
glslShaders[n] = shaderHandler->CreateProgramObject("[SMFGroundDrawer::VFS]", names[n], false);
glslShaders[n]->AttachShaderObject(shaderHandler->CreateShaderObject("GLSL/SMFVertProg.glsl", "#version 120\n" + defs, GL_VERTEX_SHADER));
glslShaders[n]->AttachShaderObject(shaderHandler->CreateShaderObject("GLSL/SMFFragProg.glsl", "#version 120\n" + defs, GL_FRAGMENT_SHADER));
}
}
glslShaders[GLSL_SHADER_CURRENT] = glslShaders[GLSL_SHADER_STANDARD];
return true;
}
LispObject* PowerFloat(LispObject* int1, LispObject* int2, LispEnvironment& aEnvironment,int aPrecision)
{
if (int2->Number(aPrecision)->iNumber->iExp != 0)
throw LispErrNotInteger();
// Raising to the power of an integer can be done fastest by squaring
// and bitshifting: x^(a+b) = x^a*x^b . Then, regarding each bit
// in y (seen as a binary number) as added, the algorithm becomes:
//
ANumber x(*int1->Number(aPrecision)->iNumber);
ANumber y(*int2->Number(aPrecision)->iNumber);
bool neg = y.iNegative;
y.iNegative=false;
// result <- 1
ANumber result("1",aPrecision);
// base <- x
ANumber base(aPrecision);
base.CopyFrom(x);
ANumber copy(aPrecision);
// while (y!=0)
while (!y.IsZero())
{
// if (y&1 != 0)
if ( (y[0] & 1) != 0)
{
// result <- result*base
copy.CopyFrom(result);
Multiply(result,copy,base);
}
// base <- base*base
copy.CopyFrom(base);
Multiply(base,copy,copy);
// y <- y>>1
BaseShiftRight(y,1);
}
if (neg)
{
ANumber one("1",aPrecision);
ANumber dummy(10);
copy.CopyFrom(result);
Divide(result,dummy,one,copy);
}
// result
return FloatToString(result, aEnvironment);
}
LispObject* LispFactorial(LispObject* int1, LispEnvironment& aEnvironment,int aPrecision)
{
int nr = InternalAsciiToInt(*int1->String());
if (nr < 0)
throw LispErrInvalidArg();
ANumber fac("1",aPrecision);
int i;
for (i=2;i<=nr;i++)
{
BaseTimesInt(fac,i, WordBase);
}
return FloatToString(fac, aEnvironment);
}
//upkeep
void SliderWidget::Update(double deltaSeconds) {
ProgressBarWidget::Update(deltaSeconds);
AABB2 mySliderBounds = GetRenderBounds();
Vector2 mySliderLength = mySliderBounds.CalcLengthOfSides();
m_sliderButton->SetDimensions(Vector2(mySliderLength.x * 0.1f, mySliderLength.y * 1.25f));
//set percent num
WidgetStateProperties& currentStateProperties = GetCurrentStateProperties();
float myPercent;
currentStateProperties.GetProperty("percent", myPercent);
std::string percentString = FloatToString(myPercent * 100, "%.0f") + "%";
m_sliderButton->SetText(percentString);
m_sliderButton->Update(deltaSeconds);
}
C_Game::C_Game(sf::RenderWindow* sc)
: C_Mod(sc)
{
sf::Clock loadTimer;
glewInit();
InitFog();
InitTexture();
_cam->setPosition(Vector3D(CHUNK_SIZE/2, CHUNK_SIZE/2, CHUNK_ZVALUE/2 +1.6f));
_cam->setSpeed(0.0006);
_screen->ShowMouseCursor(false);
glEnable(GL_TEXTURE_2D);
InitCubes();
_boolJumping = false;
_frameJumping = 0;
InitGUI();
SetItemInHotkeys(CUBE_DIRT, 0);
SetItemInHotkeys(CUBE_SAND, 1);
SetItemInHotkeys(CUBE_SAND+1, 2);
SetItemInHotkeys(CUBE_SAND+2, 3);
SetItemInHotkeys(CUBE_SAND+3, 4);
SetItemInHotkeys(CUBE_SAND+4, 5);
SetItemInHotkeys(CUBE_SAND+5, 6);
SetItemInHotkeys(CUBE_SAND+6, 7);
SetItemInHotkeys(CUBE_SAND+7, 8);
_actuelCubeInHand = _itemInHotkeys[0];
C_Log::GetSingleton()->AddMessage( std::string("Scene loaded in " + FloatToString(loadTimer.GetElapsedTime()) + "sec.") );
/*C_LineEdit *widg = new C_LineEdit();
widg->move(10, sc->GetHeight()-40);
widg->resize(350, 30);
AddWidget(widg);*/
Launch();
}
std::string info_getValueAsString(const InfoItem* infoItem) {
assert(infoItem != NULL);
std::string stringValue = "";
switch (infoItem->valueType) {
case INFO_VALUE_TYPE_STRING: {
stringValue = infoItem->valueTypeString;
} break;
case INFO_VALUE_TYPE_INTEGER: {
stringValue = IntToString(infoItem->value.typeInteger);
} break;
case INFO_VALUE_TYPE_FLOAT: {
stringValue = FloatToString(infoItem->value.typeFloat);
} break;
case INFO_VALUE_TYPE_BOOL: {
stringValue = IntToString((int) infoItem->value.typeBool);
} break;
}
return stringValue;
}
void QTPFSPathDrawer::DrawNode(
const QTPFS::QTNode* node,
const MoveDef* md,
CVertexArray* va,
bool fillQuad,
bool showCost,
bool batchDraw
) const {
#define xminw (node->xmin() * SQUARE_SIZE)
#define xmaxw (node->xmax() * SQUARE_SIZE)
#define zminw (node->zmin() * SQUARE_SIZE)
#define zmaxw (node->zmax() * SQUARE_SIZE)
#define xmidw (node->xmid() * SQUARE_SIZE)
#define zmidw (node->zmid() * SQUARE_SIZE)
const float3 verts[5] = {
float3(xminw, CGround::GetHeightReal(xminw, zminw, false) + 4.0f, zminw),
float3(xmaxw, CGround::GetHeightReal(xmaxw, zminw, false) + 4.0f, zminw),
float3(xmaxw, CGround::GetHeightReal(xmaxw, zmaxw, false) + 4.0f, zmaxw),
float3(xminw, CGround::GetHeightReal(xminw, zmaxw, false) + 4.0f, zmaxw),
float3(xmidw, CGround::GetHeightReal(xmidw, zmidw, false) + 4.0f, zmidw),
};
static const unsigned char colors[3][4] = {
{1 * 255, 0 * 255, 0 * 255, 1 * 255}, // red --> blocked
{0 * 255, 1 * 255, 0 * 255, 1 * 255}, // green --> passable
{0 * 255, 0 * 255, 1 * 64, 1 * 64}, // light blue --> pushed
};
const unsigned char* color =
(!showCost)?
&colors[2][0]:
(node->moveCostAvg == QTPFS_POSITIVE_INFINITY)?
&colors[0][0]:
&colors[1][0];
if (!batchDraw) {
if (!camera->InView(verts[4])) {
return;
}
va->Initialize();
va->EnlargeArrays(4, 0, VA_SIZE_C);
if (!fillQuad) {
glPolygonMode(GL_FRONT_AND_BACK, GL_LINE);
}
}
va->AddVertexQC(verts[0], color);
va->AddVertexQC(verts[1], color);
va->AddVertexQC(verts[2], color);
va->AddVertexQC(verts[3], color);
if (!batchDraw) {
va->DrawArrayC(GL_QUADS);
if (!fillQuad) {
glPolygonMode(GL_FRONT_AND_BACK, GL_FILL);
}
}
if (showCost && camera->GetPos().SqDistance(verts[4]) < (1000.0f * 1000.0f)) {
font->SetTextColor(0.0f, 0.0f, 0.0f, 1.0f);
font->glWorldPrint(verts[4], 5.0f, FloatToString(node->GetMoveCost(), "%8.2f"));
}
#undef xminw
#undef xmaxw
#undef zminw
#undef zmaxw
#undef xmidw
#undef zmidw
}
void CGWorldOpenGL::WriteGWorldToDXF(CStdioFile *pFile, BOOL bShowClosureError, STATIONSHOW bShowStationNames, BOOL bBoxFixedPoints)
{
// blocks
CString stationBlockName = "STATION";
CString fixedPointBlockName = "FIXEDPOINT";
// layers
CString stationLayerName1 = "S_STATION100";
CString stationLayerName2 = "S_STATION500";
CString shotLayerName = "S_SHOT";
CString wallsLayerName = "S_PASSAGEWIDTH";
CString ceilingLayerName = "S_PASSAGEHEIGHT";
CString errorLayerName = "S_ERRORS";
CString heightLayerName = "S_STATIONHEIGHT";
//CString heightLayerName2 = "S_STATIONHEIGHT500";
CString namesLayerName1 = "S_STATIONNAMES100";
CString namesLayerName2 = "S_STATIONNAMES500";
CString fixedPointLayerName = "S_FIXEDPOINT";
CString wireFrameLayerName = "S_SURFACEDATA";
CString crossSectionLayerName = "S_CROSSSECTION";
CString surfaceShotLayerName = "S_SURFACESHOT";
// show hourglass mouse pointer
CWinApp *pApp = AfxGetApp();
pApp -> BeginWaitCursor();
// write DXF header
///////////////////
pFile-> WriteString("0\nSECTION\n2\nHEADER\n"); // (note: a header section must exist (even if empty) to support LAYER tables)
// read value off one item to set drawing limits (otherwise the cave may end-up in one corner of the autocad screen)
if(m_ConstraintArray.GetSize()) // test just in case the user tries to export an empty file
{
const CGWorldOpenGLConstraint & fixedPoint=m_ConstraintArray.GetAt(0);
pFile-> WriteString("9\n$LIMMIN\n10\n"+FloatToString(fixedPoint.position[0])+ "\n20\n"+FloatToString(fixedPoint.position[1])+
"\n9\n$LIMMAX\n10\n"+FloatToString(fixedPoint.position[0])+"\n20\n"+FloatToString(fixedPoint.position[1])+"\n");
}
pFile-> WriteString("0\nENDSEC\n");
// write tables
///////////////
pFile-> WriteString("0\nSECTION\n2\nTABLES\n");
// write layers
const int countLayers = 14; //15;
CString layerNames[countLayers] = {"0", stationLayerName1, stationLayerName2, shotLayerName, wallsLayerName, ceilingLayerName,
errorLayerName, heightLayerName, /*heightLayerName2,*/ namesLayerName1, namesLayerName2,
fixedPointLayerName, wireFrameLayerName, crossSectionLayerName, surfaceShotLayerName
};
int layerColor[countLayers] = {7, 1, 1, 3, 5, 5, 1, 6, /*6,*/ 4, 4, 2, 8, 5, 9};
pFile-> WriteString("0\nTABLE\n2\nLAYER\n70\n"+IntToString(countLayers)+"\n"); // change last item (after 70) to max number of layers
for (int i=0; i<countLayers; ++i) // write each layer
pFile-> WriteString("0\nLAYER\n2\n"+layerNames[i]+"\n70\n0\n62\n"+IntToString(layerColor[i])+"\n6\nCONTINUOUS\n");
pFile-> WriteString("0\nENDTAB\n");
pFile-> WriteString("0\nENDSEC\n");
// define blocks (to be included later in the drawing)
////////////////
pFile-> WriteString("0\nSECTION\n2\nBLOCKS\n");
// define station block
pFile-> WriteString("0\nBLOCK\n8\n"+ stationLayerName1 + "\n2\n" + stationBlockName + "\n70\n0\n10\n0\n20\n0\n30\n0\n");
// small triangle
pFile-> WriteString("0\nSOLID\n8\n" + stationLayerName1 + "\n10\n0\n20\n0.15\n30\n0\n11\n-0.1299\n21\n-0.075\n31\n0\n12\n0.1299\n22\n-0.075\n32\n0\n13\n0.1299\n23\n-0.075\n33\n0\n");
// large triangle
pFile-> WriteString("0\nPOLYLINE\n8\n" + stationLayerName2 + "\n66\n1\n10\n0.0\n20\n0.0\n30\n0.0\n70\n1\n");
pFile-> WriteString("0\nVERTEX\n8\n" + stationLayerName2 + "\n10\n0\n20\n0.5\n30\n0\n");
pFile-> WriteString("0\nVERTEX\n8\n" + stationLayerName2 + "\n10\n-0.433\n20\n-0.25\n30\n0\n");
pFile-> WriteString("0\nVERTEX\n8\n" + stationLayerName2 + "\n10\n0.433\n20\n-0.25\n30\n0\n");
pFile-> WriteString("0\nSEQEND\n8\n" + stationLayerName2 + "\n");
pFile-> WriteString("0\nENDBLK\n8\n" + stationLayerName1+"\n");
// define fixedPoint block
pFile-> WriteString("0\nBLOCK\n8\n"+ fixedPointLayerName + "\n2\n" + fixedPointBlockName + "\n70\n0\n10\n0\n20\n0\n30\n0\n");
pFile-> WriteString("0\nSOLID\n8\n" + fixedPointLayerName + "\n10\n0.5\n20\n0.5\n30\n0\n11\n-0.5\n21\n0.5\n31\n0\n12\n0.5\n22\n-0.5\n32\n0\n13\n-0.5\n23\n-0.5\n33\n0\n");
pFile-> WriteString("0\nENDBLK\n8\n" + fixedPointLayerName+"\n");
pFile-> WriteString("0\nENDSEC\n");
// write DXF entities
/////////////////////
pFile-> WriteString("0\nSECTION\n2\nENTITIES\n");
// write lines
int iCount=m_LineArray.GetSize();
for (i=0; i<iCount; i++)
{
const CGWorldOpenGLLine& Line=m_LineArray.GetAt(i);
BOOL bShowThisLine=TRUE;
CString layer = "0"; // lines of undefined types go to layer 0
switch (Line.lineType)
{ // diferent types of lines are output to different layers
case LT_SHOT:
layer = shotLayerName;
break;
case LT_SURFACESHOT:
layer = surfaceShotLayerName;
break;
case LT_CLOSUREERROR:
layer = errorLayerName;
bShowThisLine=bShowClosureError;
break;
case LT_PASSAGEWIDTH:
layer = wallsLayerName;
break;
case LT_PASSAGEHEIGHT:
layer = ceilingLayerName;
break;
case LT_SURFACE:
layer = wireFrameLayerName;
break;
case LT_CROSSSECTION:
layer = crossSectionLayerName;
break;
// case LT_WIREFRAME: // those should not be seen since they only appear on screen when rotating
// default: // (there should be no other types)
// break;
}
if (bShowThisLine)
pFile-> WriteString("0\nLINE\n8\n" + layer +
"\n10\n" + FloatToString(Line.pt1[0]) + "\n20\n" + FloatToString(Line.pt1[1]) + "\n30\n" + FloatToString(Line.pt1[2]) +
"\n11\n" + FloatToString(Line.pt2[0]) + "\n21\n" + FloatToString(Line.pt2[1]) + "\n31\n" + FloatToString(Line.pt2[2]) + "\n");
}
// write stations and station's name and height
int iLabelCount=m_LabelArray.GetSize();
for (i=0; i<iLabelCount; i++)
{
const CGWorldOpenGLLabel & Label=m_LabelArray.GetAt(i);
// write station name
if (bShowStationNames==SHOW_ALL || (Label.bJunction && bShowStationNames==SHOW_INTERSECT))
{
// small text
pFile-> WriteString("0\nTEXT\n8\n" + namesLayerName1 + "\n72\n2\n" +
"10\n" + FloatToString(Label.position[0]) + "\n20\n" + FloatToString(Label.position[1]) + "\n30\n" + FloatToString(Label.position[2]) +
"\n11\n" + FloatToString(Label.position[0] - (float)0.1299) + "\n21\n" + FloatToString(Label.position[1]) + "\n31\n" + FloatToString(Label.position[2]) +
"\n40\n0.4\n1\n" + Label.szName + "\n");
// large text
pFile-> WriteString("0\nTEXT\n8\n" + namesLayerName2 + "\n72\n2\n" +
"10\n" + FloatToString(Label.position[0]) + "\n20\n" + FloatToString(Label.position[1]) + "\n30\n" + FloatToString(Label.position[2]) +
"\n11\n" + FloatToString(Label.position[0] - (float)0.433) + "\n21\n" + FloatToString(Label.position[1]) + "\n31\n" + FloatToString(Label.position[2]) +
"\n40\n1.0\n1\n" + Label.szName + "\n");
}
// write station height
// small text
pFile-> WriteString("0\nTEXT\n8\n" + heightLayerName + "\n" + //"73\n3\n" + // tag 73 is not recognized by AutoCAD v.10: we substract the font size from the y value
"10\n" + FloatToString(Label.position[0] + (float)0.1299) + "\n20\n" + FloatToString(Label.position[1]-(float)0.4) + "\n30\n" + FloatToString(Label.position[2]) +
"\n11\n" + FloatToString(Label.position[0] + (float)0.1299) + "\n21\n" + FloatToString(Label.position[1]-(float)0.4) + "\n31\n" + FloatToString(Label.position[2]) +
"\n40\n0.4\n1\n" + FloatToString(Label.position[2]) + "\n");
/* // large text
pFile-> WriteString("0\nTEXT\n8\n" + heightLayerName2 + "\n73\n3\n" +
"10\n" + FloatToString(Label.position[0]) + "\n20\n" + FloatToString(Label.position[1]) + "\n30\n" + FloatToString(Label.position[2]) +
"\n11\n" + FloatToString(Label.position[0] + (float)0.433) + "\n21\n" + FloatToString(Label.position[1]) + "\n31\n" + FloatToString(Label.position[2]) +
"\n40\n1.0\n1\n" + FloatToString(Label.position[2]) + "\n");
*/
// draw station
pFile-> WriteString("0\nINSERT\n2\n" + stationBlockName + "\n8\n" + stationLayerName1 +
"\n10\n" + FloatToString(Label.position[0])+ "\n20\n" + FloatToString(Label.position[1]) + "\n30\n" + FloatToString(Label.position[2]) + "\n");
}
// write fixed points and fixed points' text
int iFixedPointCount=m_ConstraintArray.GetSize();
for (i=0; i<iFixedPointCount; i++)
{
const CGWorldOpenGLConstraint & fixedPoint=m_ConstraintArray.GetAt(i);
if (!fixedPoint.bSearchResultTag) // only show fixed points: not search results '?' tags
{
// write text
pFile-> WriteString("0\nTEXT\n8\n" + fixedPointLayerName +
"\n10\n" + FloatToString(fixedPoint.position[0] + (float)0.6) + "\n20\n" + FloatToString(fixedPoint.position[1]) + "\n30\n" + FloatToString(fixedPoint.position[2]) +
"\n40\n1.0\n1\n" + fixedPoint.node->GetName() + "\n");
// draw fixed point
pFile-> WriteString("0\nINSERT\n2\n" + fixedPointBlockName + "\n8\n" + fixedPointLayerName +
"\n10\n" + FloatToString(fixedPoint.position[0])+ "\n20\n" + FloatToString(fixedPoint.position[1]) + "\n30\n" + FloatToString(fixedPoint.position[2]) + "\n");
}
}
// end of 'entities' section and end of file
pFile-> WriteString("0\nENDSEC\n0\nEOF\n");
// hide hourglass mouse pointer
pApp -> EndWaitCursor();
}
globle const char *DataObjectToString(
void *theEnv,
DATA_OBJECT *theDO)
{
void *thePtr;
const char *theString;
char *newString;
const char *prefix, *postfix;
size_t length;
struct externalAddressHashNode *theAddress;
char buffer[30];
switch (GetpType(theDO))
{
case MULTIFIELD:
prefix = "(";
theString = ValueToString(ImplodeMultifield(theEnv,theDO));
postfix = ")";
break;
case STRING:
prefix = "\"";
theString = DOPToString(theDO);
postfix = "\"";
break;
case INSTANCE_NAME:
prefix = "[";
theString = DOPToString(theDO);
postfix = "]";
break;
case SYMBOL:
return(DOPToString(theDO));
case FLOAT:
return(FloatToString(theEnv,DOPToDouble(theDO)));
case INTEGER:
return(LongIntegerToString(theEnv,DOPToLong(theDO)));
case RVOID:
return("");
#if OBJECT_SYSTEM
case INSTANCE_ADDRESS:
thePtr = DOPToPointer(theDO);
if (thePtr == (void *) &InstanceData(theEnv)->DummyInstance)
{ return("<Dummy Instance>"); }
if (((struct instance *) thePtr)->garbage)
{
prefix = "<Stale Instance-";
theString = ValueToString(((struct instance *) thePtr)->name);
postfix = ">";
}
else
{
prefix = "<Instance-";
theString = ValueToString(GetFullInstanceName(theEnv,(INSTANCE_TYPE *) thePtr));
postfix = ">";
}
break;
#endif
case EXTERNAL_ADDRESS:
theAddress = (struct externalAddressHashNode *) DOPToPointer(theDO);
/* TBD Need specific routine for creating name string. */
gensprintf(buffer,"<Pointer-%d-%p>",(int) theAddress->type,DOPToExternalAddress(theDO));
thePtr = EnvAddSymbol(theEnv,buffer);
return(ValueToString(thePtr));
#if DEFTEMPLATE_CONSTRUCT
case FACT_ADDRESS:
if (DOPToPointer(theDO) == (void *) &FactData(theEnv)->DummyFact)
{ return("<Dummy Fact>"); }
thePtr = DOPToPointer(theDO);
gensprintf(buffer,"<Fact-%lld>",((struct fact *) thePtr)->factIndex);
thePtr = EnvAddSymbol(theEnv,buffer);
return(ValueToString(thePtr));
#endif
default:
return("UNK");
}
length = strlen(prefix) + strlen(theString) + strlen(postfix) + 1;
newString = (char *) genalloc(theEnv,length);
newString[0] = '\0';
genstrcat(newString,prefix);
genstrcat(newString,theString);
genstrcat(newString,postfix);
thePtr = EnvAddSymbol(theEnv,newString);
genfree(theEnv,newString,length);
return(ValueToString(thePtr));
}
int stack_push_float(object store, string name, float entry)
{
return stack_push_string(store,name,FloatToString(entry));
}
int array_set_float(object store, string name, int i, float entry)
{
return array_set_string(store,name,i,FloatToString(entry));
}
