Example #1
0
void    
cgfxGetFxIncludePath( const MString &fxFile, MStringArray &pathOptions )
{
	// Append the path of the cgfx file as a possible include search path
	//
	MString option;
	if (fxFile.length())
	{
		MFileObject fobject;
		fobject.setRawFullName( fxFile );
		option = MString("-I") + fobject.resolvedPath();		
		pathOptions.append( option );
	}

	// Add in "standard" cgfx search for cgfx files as a possible include
	// search path
	//
	char * cgfxRoot = getenv("CGFX_ROOT");
	if (cgfxRoot)
	{
		option = MString("-I") + MString(cgfxRoot);
		pathOptions.append( option );
		option = MString("-I") + MString(cgfxRoot) + MString("/CgFX");
		pathOptions.append( option );
	}

	// Add in Maya's Cg directory
	char * mayaLocation = getenv("MAYA_LOCATION");
	if (mayaLocation)
	{
		MString mayaCgLocation(MString(mayaLocation) + MString("/bin/Cg/"));
		option = MString("-I") + mayaCgLocation;
		pathOptions.append( option );
	}
}
Example #2
0
// returns the list of files to archive.
MStringArray AlembicNode::getFilesToArchive(
    bool /* shortName */,
    bool unresolvedName,
    bool /* markCouldBeImageSequence */) const
{
    MStringArray files;
    MStatus status = MS::kSuccess;

    MPlug layerFilenamesPlug(thisMObject(), mAbcLayerFileNamesAttr);

    MFnStringArrayData fnSAD( layerFilenamesPlug.asMObject() );
	MStringArray layerFilenames = fnSAD.array();

	for( unsigned int i = 0; i < layerFilenames.length(); i++ )
	{
		MString fileName = layerFilenames[i];

		if (status == MS::kSuccess && fileName.length() > 0) {
			if(unresolvedName)
			{
				files.append(fileName);
			}
			else
			{
				//unresolvedName is false, resolve the path via MFileObject.
				MFileObject fileObject;
				fileObject.setRawFullName(fileName);
				files.append(fileObject.resolvedFullName());
			}
		}
	}

    return files;
}
	virtual bool getSourceStreams(const MObject& object,
		MStringArray &sourceStreams) const
	{
		sourceStreams.append( "Position" );
		sourceStreams.append( "Normal" );
		return true;
	}
Example #4
0
// returns the list of files to archive.
MStringArray AlembicNode::getFilesToArchive(
    bool /* shortName */,
    bool unresolvedName,
    bool /* markCouldBeImageSequence */) const
{
    MStringArray files;
    MStatus status = MS::kSuccess;

    MPlug fileNamePlug(thisMObject(), mAbcFileNameAttr);
    MString fileName = fileNamePlug.asString(MDGContext::fsNormal, &status);

    if (status == MS::kSuccess && fileName.length() > 0) {
        if(unresolvedName)
        {
            files.append(fileName);
        }
        else
        {
            //unresolvedName is false, resolve the path via MFileObject.
            MFileObject fileObject;
            fileObject.setRawFullName(fileName);
            files.append(fileObject.resolvedFullName());
        }
    }

    return files;
}
MStatus ClassParameterHandler::storeClass( IECore::ConstParameterPtr parameter, MPlug &plug )
{
	IECorePython::ScopedGILLock gilLock;
	try
	{
		boost::python::object pythonParameter( IECore::constPointerCast<IECore::Parameter>( parameter ) );
		boost::python::object classInfo = pythonParameter.attr( "getClass" )( true );
	
		std::string className = boost::python::extract<std::string>( classInfo[1] );
		int classVersion = boost::python::extract<int>( classInfo[2] );
		std::string searchPathEnvVar = boost::python::extract<std::string>( classInfo[3] );
		
		MString storedClassName;
		int storedClassVersion;
		MString storedSearchPathEnvVar;
		currentClass( plug, storedClassName, storedClassVersion, storedSearchPathEnvVar );
		
		// only set the plug values if the new value is genuinely different, as otherwise
		// we end up generating unwanted reference edits.
		if ( storedClassName != className.c_str() || storedClassVersion != classVersion || storedSearchPathEnvVar != searchPathEnvVar.c_str() )
		{
			MStringArray updatedClassInfo;
			updatedClassInfo.append( className.c_str() );
			MString classVersionStr;
			classVersionStr.set( classVersion, 0 );
			updatedClassInfo.append( classVersionStr );
			updatedClassInfo.append( searchPathEnvVar.c_str() );
			
			MObject attribute = plug.attribute();
			MFnTypedAttribute fnTAttr( attribute );
			if ( fnTAttr.attrType() == MFnData::kStringArray )
			{
				MObject data = MFnStringArrayData().create( updatedClassInfo );
				plug.setValue( data );
			}
			else
			{
				// compatibility for the deprecated compound plug behaviour. keeping this code
				// so we can still read old scenes. creation of these plugs has been removed.
				/// \todo: find all such notes and remove the unnecessary code for Cortex 9.
				plug.child( 0 ).setString( className.c_str() );
				plug.child( 1 ).setInt( classVersion );
				plug.child( 2 ).setString( searchPathEnvVar.c_str() );
			}
		}
	}
	catch( boost::python::error_already_set )
	{
		PyErr_Print();
		return MS::kFailure;
	}
	catch( const std::exception &e )
	{
		MGlobal::displayError( MString( "ClassParameterHandler::setClass : " ) + e.what() );
		return MS::kFailure;
	}
	
	return MS::kSuccess;
}
void CUniformParameterBuilder::logUnrecognisedSemantic(const char* pSemantic)
{
	MStringArray args;
	args.append(pSemantic);
	args.append(mDesc.Name);

	mWarnings += dx11ShaderStrings::getString( dx11ShaderStrings::kUnknowSemantic, args );
}
void CUniformParameterBuilder::logUnsupportedTypeWarning(const MStringResourceId& typeId)
{
	MString typeStr = dx11ShaderStrings::getString( typeId );

	MStringArray args;
	args.append(typeStr);
	args.append(mDesc.Name);

	mWarnings += dx11ShaderStrings::getString( dx11ShaderStrings::kUnsupportedType, args );
}
void ParameterisedHolderModificationCmd::restoreClassParameterStates( const IECore::CompoundData *classes, IECore::Parameter *parameter, const std::string &parentParameterPath )
{
	std::string parameterPath = parentParameterPath;
	if( parentParameterPath.size() )
	{
		parameterPath += ".";
	}
	parameterPath += parameter->name();
		
	if( parameter->isInstanceOf( "ClassParameter" ) )
	{				
		const CompoundData *c = classes->member<const CompoundData>( parameterPath );
		if( c )
		{
			ClassParameterHandler::setClass(
				parameter,
				c->member<const IECore::StringData>( "className" )->readable().c_str(),
				c->member<const IECore::IntData>( "classVersion" )->readable(),
				c->member<const IECore::StringData>( "searchPathEnvVar" )->readable().c_str()
			);
		}
	}
	else if( parameter->isInstanceOf( "ClassVectorParameter" ) )
	{		
		const CompoundData *c = classes->member<const CompoundData>( parameterPath );
		if( c )
		{
			IECore::ConstStringVectorDataPtr parameterNames = c->member<const IECore::StringVectorData>( "parameterNames" );
			IECore::ConstStringVectorDataPtr classNames = c->member<const IECore::StringVectorData>( "classNames" );
			IECore::ConstIntVectorDataPtr classVersions = c->member<const IECore::IntVectorData>( "classVersions" );
			MStringArray mParameterNames;
			MStringArray mClassNames;
			MIntArray mClassVersions;
			int numClasses = parameterNames->readable().size();
			for( int i=0; i<numClasses; i++ )
			{
				mParameterNames.append( parameterNames->readable()[i].c_str() );
				mClassNames.append( classNames->readable()[i].c_str() );
				mClassVersions.append( classVersions->readable()[i] );
			}
			ClassVectorParameterHandler::setClasses( parameter, mParameterNames, mClassNames, mClassVersions );
		}
	}
	
	if( parameter->isInstanceOf( IECore::CompoundParameter::staticTypeId() ) )
	{
		CompoundParameter *compoundParameter = static_cast<CompoundParameter *>( parameter );
		const CompoundParameter::ParameterVector &childParameters = compoundParameter->orderedParameters();
		for( CompoundParameter::ParameterVector::const_iterator it = childParameters.begin(); it!=childParameters.end(); it++ )
		{
			restoreClassParameterStates( classes, it->get(), parameterPath );
		}
	}
}
Example #9
0
//read out the animation layers from the animReader
//then create any missing layers and add them to the active selection
bool atomAnimLayers::readAnimLayers(ifstream &readAnim, char *dataType,atomReader &reader)
{

	if (strcmp(dataType, kAnimLayers) == 0)
	{
		dataType = reader.asWord(readAnim);
		if (strcmp(dataType, "{") == 0)
		{
			MStringArray layerNames;
			while((dataType = reader.asWord(readAnim)))
			{
				if(readAnim && ! readAnim.eof() && dataType && strcmp(dataType, "}") !=0)
				{
					MString name(dataType);
					layerNames.append(name);
				}
				else
					break;
			}
			if(layerNames.length() >0)
			{
				createMissingAnimLayers(layerNames);
				addAnimLayersToSelection();
			}
		}
		return true;
	}
	return false;
}
Example #10
0
MString AppleseedRenderer::getTextureColorProfile(MFnDependencyNode& fileTextureNode)
{
	MString colorProfileName;
	int profileId = 0;
	getEnum(MString("colorProfile"), fileTextureNode, profileId);
	logger.debug(MString("Color profile from fileNode: ") + profileId);
	
	MStringArray colorProfiles;
	colorProfiles.append("srgb"); //0 == none == default == sRGB
	colorProfiles.append("srgb"); //1 == undefined == default == sRGB
	colorProfiles.append("linear_rgb"); //2 == linear_rgb
	colorProfiles.append("srgb"); //3 == sRGB
	colorProfiles.append("linear_rgb"); //4 == linear_rec_709
	colorProfiles.append("linear_rgb"); //5 == hdtv_rec_709
	return colorProfiles[profileId];
}
//-----------------------------------------------------------------------------
//
//-----------------------------------------------------------------------------
MStatus CVsSkinnerCmd::DoLs()
{
	MSelectionList tmpList;

	if ( m_undo.ArgDatabase().isFlagSet( kOptSelected ) )
	{
		MSelectionList skinnerNodes;
		m_undo.ArgDatabase().getObjects( skinnerNodes );

		GetSpecifiedSkinnerNodes( skinnerNodes, tmpList );
	}
	else
	{
		MDagPath eDagPath;
		FindSkinnerNodesInHierarchy( eDagPath, tmpList );
	}

	const bool longPath( m_undo.ArgDatabase().isFlagSet( kOptLong ) );
	MStringArray result;

	MDagPath mDagPath;
	for ( MItSelectionList sIt( tmpList ); !sIt.isDone(); sIt.next() )
	{
		if ( sIt.getDagPath( mDagPath ) )
		{
			result.append( longPath ? mDagPath.fullPathName() : mDagPath.partialPathName() );
		}
	}

	setResult( result );

	return MS::kSuccess;
}
Example #12
0
void maTranslator::getSetAttrCmds(const MObject& node, MStringArray& cmds)
{
	//
	// Get rid of any garbage already in the array.
	//
	cmds.clear();

	//
	// Run through the node's attributes.
	//
	MFnDependencyNode	nodeFn(node);
	unsigned int		numAttrs = nodeFn.attributeCount();
	unsigned int		i;

	for (i = 0; i < numAttrs; i++)
	{
		//
		// Use the attribute ordering which Maya uses when doing I/O.
		//
		MObject			attr = nodeFn.reorderedAttribute(i);
		MFnAttribute	attrFn(attr);
		MStatus			status;

		attrFn.parent(&status);

		bool			isChild = (status != MS::kNotFound);

		//
		// We don't want attributes which are children of other attributes
		// because they will be processed when we process the parent.
		//
		// And we only want storable attributes which accept inputs.
		//
		if (!isChild && attrFn.isStorable() && attrFn.isWritable())
		{
			//
			// Get a plug for the attribute.
			//
			MPlug	plug(node, attr);

			//
			// Get setAttr commands for this attribute, and any of its
			// children, which have had their values changed by the scene.
			//
			MStringArray	newCmds;

			plug.getSetAttrCmds(newCmds, MPlug::kChanged, false);

			unsigned int	numCommands = newCmds.length();
			unsigned int	c;

			for (c = 0; c < numCommands; c++)
			{
				if (newCmds[c] != "")
					cmds.append(newCmds[c]);
			}
		}
	}
}
MStatus loadPlugin::doIt(const MArgList &args)
{
	MStatus stat=MStatus::kSuccess;

    MString getMayaLocation("getenv MAYA_LOCATION");
	MString locationPath;
	MGlobal::executeCommand(getMayaLocation,locationPath);
	MStringArray extraDlls;
	extraDlls.append("libpng14d");
	extraDlls.append("libtiff3");
	extraDlls.append("libxml2");
	extraDlls.append("yafaraycore");
	extraDlls.append("yafarayqt");
	extraDlls.append("yafarayplugin");
	extraDlls.append("zlib");
	MString pathAdded("/bin");
	MString suffix(".dll");
	for(unsigned int i=0; i<extraDlls.length();i++)
	{
		MString dll=locationPath+pathAdded+extraDlls[i]+suffix;
		cout<<"loading dll "<<extraDlls[i]<<".dll";
		LoadLibrary(dll.asChar());
		cout<<"........................succeeded!"<<endl;
	}


	MString yafPath("/bin/plug-ins/yafaray");
	MString yafDll=locationPath+yafPath;
    yafrayInterface_t * yafLoad=renderScene::getyI();
	yafLoad->loadPlugins(yafDll.asChar());
	MGlobal::displayInfo("load yafaray components succeeded!");


	return stat;
}
Example #14
0
MDoubleArray boingRbCmd::getBulletVectorAttribute(MString &name, MString &attr) {
    
    MVector vec;
    MDoubleArray result;
    
    shared_ptr<bSolverNode> b_solv = bSolverNode::get_bsolver_node();
    MStringArray nodes;
    if (name == "*") {
        nodes = b_solv->get_all_keys();
    } else {
        nodes.append(name);
    }
    
    //std::cout<<"nodes : "<<nodes<<std::endl;
    //std::cout<<"nodes.length() : "<<nodes.length()<<std::endl;
    
    for (int i=0; i<nodes.length(); i++) {
        
        std::cout<<"trying to get rb...."<<std::endl;
        rigid_body_t::pointer rb = b_solv->getdata(nodes[i])->m_rigid_body;
        std::cout<<"got rb : "<<b_solv->getdata(nodes[i])->name<<std::endl;
        
        //rigid_body_t::pointer rb = getPointerFromName(name);
        
        if (rb != 0) {
            float mass = rb->get_mass();
            bool active = (mass>0.f);
            if(active) {
                if (attr=="velocity") {
                    vec3f vel;
                    rb->get_linear_velocity(vel);
                    vec = MVector((double)vel[0], (double)vel[1], (double)vel[2]);
                } else if (attr=="position") {
                    vec3f pos;
                    quatf rot;
                    rb->get_transform(pos, rot);
                    vec = MVector((double)pos[0], (double)pos[1], (double)pos[2]);
                } else if (attr=="angularVelocity") {
                    vec3f av;
                    rb->get_angular_velocity(av);
                    vec = MVector((double)av[0], (double)av[1], (double)av[2]);
                } /*else {
                   boing *b = static_cast<boing*>( rb->impl()->body()->getUserPointer() );
                   MString vecStr = b->get_data(attr);
                   MStringArray vecArray = parseArguments(vecStr, ",");
                   vec = MVector(vecArray[0].asDouble(), vecArray[1].asDouble(), vecArray[2].asDouble());
                   }*/
            }
        }
        for (int j=0; j<3; j++) {
            //std::cout<<"vec["<<j<<"] : "<<vec[j]<<std::endl;
            result.append(vec[j]);
        }
    }
    return result;
    
}
MStatus initializePlugin( MObject obj )
{
    MFnPlugin plugin( obj, "Ivan Shiskin <*****@*****.**>", "1.0", "Any" );
	MStringArray extensions;
	extensions.append( "512" );
	extensions.append( "1024");
	extensions.append( "2048");
    MStatus s = plugin.registerImageFile( 
					"MetroImage",
					metro_image::creator, 
					extensions);

	if (!s) {
		s.perror("registerImageFile");
		return s;
	}

	s =  plugin.registerFileTranslator( "Metro Model Translator",
										"",
										metro_model_translator::creator );
	if (!s) {
		s.perror("registerFileTranslator");
		return s;
	}

	s =  plugin.registerFileTranslator( "Metro Mesh Translator",
										"",
										metro_mesh_translator::creator );
	if (!s) {
		s.perror("registerFileTranslator");
		return s;
	}

	s =  plugin.registerFileTranslator( "Metro Level Translator",
										"",
										metro_level_translator::creator );
	if (!s) {
		s.perror("registerFileTranslator");
		return s;
	}
    
    return s;
}
Example #16
0
//
// An effect
//
cgfxEffect::cgfxEffect(const MString& fileName, const cgfxProfile* profile)
  :	refcount(0),
    fEffect(NULL),
	fTechniques(NULL),
    fProfile(NULL)
{
    MStringArray fileOptions;
    cgfxGetFxIncludePath( fileName, fileOptions );
    fileOptions.append("-DMAYA_CGFX=1");

    if (cgfxProfile::getTexCoordOrientation() == cgfxProfile::TEXCOORD_OPENGL) {
        fileOptions.append("-DMAYA_TEXCOORD_ORIENTATION_OPENGL=1");
    }
    else {
        fileOptions.append("-DMAYA_TEXCOORD_ORIENTATION_DIRECTX=1");
    }
    
    const char *opts[_CGFX_PLUGIN_MAX_COMPILER_ARGS_];
    unsigned int numOpts = fileOptions.length();
    if (numOpts)
    {
        numOpts = (numOpts > _CGFX_PLUGIN_MAX_COMPILER_ARGS_-1) ?
            _CGFX_PLUGIN_MAX_COMPILER_ARGS_-1 : numOpts;
        for (unsigned int i=0; i<numOpts; i++)
            opts[i] = fileOptions[i].asChar();
        opts[numOpts] = NULL;
    }

    fEffect = cgCreateEffectFromFile(cgfxShaderNode::sCgContext, fileName.asChar(), opts);
    if (fEffect)
    {
        CGtechnique technique = cgGetFirstTechnique(fEffect);
        cgfxTechnique** nextTechnique = const_cast<cgfxTechnique**>(&fTechniques);
        while (technique)
        {
            *nextTechnique = new cgfxTechnique(technique, profile);
            nextTechnique = &(*nextTechnique)->fNext;
            technique = cgGetNextTechnique(technique);
        }

        fProfile = profile;
    }
}
Example #17
0
MObject getOtherSideNode(const MString& plugName, MObject& thisObject, MStringArray& otherSidePlugNames)
{
    MStatus stat;
    MObject result = MObject::kNullObj;
    MFnDependencyNode depFn(thisObject, &stat);
    if (stat != MStatus::kSuccess) return result;
    MPlug plug = depFn.findPlug(plugName, &stat);
    if (stat != MStatus::kSuccess)return result;
    if (!plug.isConnected())
    {
        int numChildConnects = plug.numConnectedChildren();
        if (numChildConnects == 0)
            return result;
        else
        {
            for (int i = 0; i < numChildConnects; i++)
            {
                MPlug child = plug.child(i);
                MString otherSidePlugName;
                MObject childObj = getOtherSideNode(child.partialName(false), thisObject, otherSidePlugName);
                if (childObj != MObject::kNullObj)
                {
                    otherSidePlugNames.append(otherSidePlugName);
                    result = childObj;
                } else
                    otherSidePlugNames.append(MString(""));
            }
        }
    }
    else
    {
        MPlugArray plugArray;
        plug.connectedTo(plugArray, 1, 0, &stat);
        if (stat != MStatus::kSuccess) return result;
        if (plugArray.length() == 0)
            return result;
        MPlug otherSidePlug = plugArray[0];
        result = otherSidePlug.node();
        otherSidePlugNames.append(otherSidePlug.name());
    }
    return result;
}
Example #18
0
MStringArray cgfxProfile::getProfileList()
{
    MStringArray result;
    cgfxProfile* profile = sProfileList;
    while (profile) {
        result.append(profile->fName);
        profile = profile->fNext;
    }

    return result;
}
 //---------------------------------------------------
 void DagHelper::getPlugValue ( const MPlug& plug, MStringArray& output, MStatus* status )
 {
     MObject str_obj;
     plug.getValue ( str_obj );
     MFnStringArrayData f_astr ( str_obj, status );
     unsigned int len = f_astr.length();
     for ( unsigned int i = 0; i < len; ++i )
     {
         const MString& val = f_astr[i];
         output.append ( val );
     }
 }
Example #20
0
// DESCRIPTION:
//////////////////////////////////////////////////////////////////
MStatus initializePlugin( MObject obj )
{
    MFnPlugin plugin( obj, PLUGIN_COMPANY, "8.0", "Any" );
	MStringArray extensions;
	extensions.append( "moo");
    CHECK_MSTATUS( plugin.registerImageFile(
					kImagePluginName,
					SimpleImageFile::creator, 
					extensions));
    
    return MS::kSuccess;
}
Example #21
0
MStringArray boingRbCmd::parseArguments(MString arg, MString token) {

        MStringArray jobArgsArray;
        MString stringBuffer;
        for (unsigned int charIdx = 0; charIdx < arg.numChars(); charIdx++) {
            MString ch = arg.substringW(charIdx, charIdx);
            //cout<<"ch = "<<ch<<endl;
            if (ch == token ) {
                if (stringBuffer.length() > 0) {
                    jobArgsArray.append(stringBuffer);
                    //cout<<"jobArgsArray = "<<jobArgsArray<<endl;
                    stringBuffer.clear();
                }
            } else {
                stringBuffer += ch;
                //cout<<"stringBuffer = "<<stringBuffer<<endl;
            }
        }
        jobArgsArray.append(stringBuffer);

        return jobArgsArray;
}
//
// Convert a DX space into a Maya space
//
MUniformParameter::DataSemantic CUniformParameterBuilder::convertSpace( MUniformParameter::DataSemantic defaultSpace)
{
	MUniformParameter::DataSemantic space = MUniformParameter::kSemanticUnknown;

	LPCSTR ann;
	if( getAnnotation( dx11ShaderAnnotation::kSpace, ann) && ann)
	{
		if( !_stricmp( ann, dx11ShaderAnnotationValue::kObject))		space = defaultSpace >= MUniformParameter::kSemanticObjectPos ? MUniformParameter::kSemanticObjectPos	: MUniformParameter::kSemanticObjectDir;
		else if( !_stricmp( ann, dx11ShaderAnnotationValue::kWorld))	space = defaultSpace >= MUniformParameter::kSemanticObjectPos ? MUniformParameter::kSemanticWorldPos	: MUniformParameter::kSemanticWorldDir;
		else if( !_stricmp( ann, dx11ShaderAnnotationValue::kView))		space = defaultSpace >= MUniformParameter::kSemanticObjectPos ? MUniformParameter::kSemanticViewPos		: MUniformParameter::kSemanticViewDir;
		else if( !_stricmp( ann, dx11ShaderAnnotationValue::kCamera))	space = defaultSpace >= MUniformParameter::kSemanticObjectPos ? MUniformParameter::kSemanticViewPos		: MUniformParameter::kSemanticViewDir;
		else
		{
			MStringArray args;
			args.append(ann);
			args.append(mDesc.Name);

			mWarnings += dx11ShaderStrings::getString( dx11ShaderStrings::kUnknowSpace, args );
		}
	}

	return space;
}
void  Visitor::addShaderMethodBody(
						 const MString &currentNode,
						 const MStringArray& inputVars,
						 const MStringArray& outputVars)
{
	CM_TRACE_FUNC("Visitor::addShaderMethodBody("<<currentNode<<","<<inputVars<<","<<outputVars<<")");

	MString varString;
	{
		MStringArray vars;
		for(std::size_t i=0; i<inputVars.length(); ++i){
			vars.append( renderman::getVariableName(inputVars[i]) );
		}
		for(std::size_t i=0; i<outputVars.length(); ++i){
			vars.append( renderman::getVariableName(outputVars[i]) );
		}

		for(std::size_t index=0; index<vars.length(); ++index){
			varString += (index == vars.length() - 1)?(vars[index]):(vars[index]+", ");
		}
	}

	// Add the current node method to the shader body
	shaderData[ SHADER_METHOD_BODY_I ] += " //" + currentNode +"\n";
	shaderData[ SHADER_METHOD_BODY_I ] += " " + renderman::getShaderName(currentNode) +"("+varString+");\n";
	
	// test the input and output of currentNode
	{	
		MString inputVarsStr; 
		MString outputVarsStr;
		connectMStringArray(inputVarsStr, inputVars);
		connectMStringArray(outputVarsStr, outputVars);
		shaderData[ SHADER_METHOD_BODY_I ] += "//input: " + inputVarsStr +"\n";
		shaderData[ SHADER_METHOD_BODY_I ] += "//output:" + outputVarsStr +"\n\n";
	}
}
Example #24
0
//-----------------------------------------------------------------------------------------
LPCSTR CXRayObjectExport::getMaterialName(MDagPath & mdagPath, int cid, int objectIdx)
{
    MStatus stat;
	
    int i, length;
	MIntArray * currentMaterials = new MIntArray();
	MStringArray mArray;


	for ( i=0; i<numSets; i++ )	{
		if ( lookup(mdagPath,i,cid) ) {
			MFnSet fnSet( (*sets)[i] );
			if ( MFnSet::kRenderableOnly == fnSet.restriction(&stat) ) {
				currentMaterials->append( i );
				mArray.append( fnSet.name() );
			}
		}
	}

	// Test for equivalent materials
	//
	bool materialsEqual = false;
	if ((lastMaterials != NULL) && (lastMaterials->length() == currentMaterials->length())){
		materialsEqual = true;
		length = lastMaterials->length();
		for (i=0; i<length; i++){
			if ((*lastMaterials)[i]!=(*currentMaterials)[i]){
				materialsEqual = false;
				break;
			}
		}			
	}

	if (!materialsEqual){
		if (lastMaterials!=NULL) xr_delete(lastMaterials);

		lastMaterials = currentMaterials;

		int mLength = mArray.length(); 
		if (mLength==0) xrDebug::Fatal(DEBUG_INFO,"Object '%s' has polygon '%d' without material.",0,cid);
		if (mLength>1){
			xrDebug::Fatal(DEBUG_INFO,"Object '%s' has polygon '%d' with more than one material.",0,cid);
		}
	}else{
		xr_delete(currentMaterials);
	}
	return mArray[0].asChar();
}
Example #25
0
//get attribute names for an animationlayer, like mute,weight, solo
void atomAnimLayers::getRelevantAttributes(MStringArray &attributes)
{
	MString attr("mute");
	attributes.append(attr);
	attr = MString("lock");
	attributes.append(attr);
	attr = MString("solo");
	attributes.append(attr);
	attr = MString("override");
	attributes.append(attr);
	attr = MString("passthrough");
	attributes.append(attr);
	attr = MString("preferred");
	attributes.append(attr);
	attr = MString("weight");
	attributes.append(attr);
	attr = MString("rotationAccumulationMode");
	attributes.append(attr);
	attr = MString("scaleAccumulationMode");
	attributes.append(attr);
}
Example #26
0
void rigidBodyNode::addContactInfo(const MString& contactObjectName, const MVector& point)
{
	MObject thisObject(thisMObject());

	// contactCount
	m_contactCount++;
	MPlug plugContactCount(thisObject, rigidBodyNode::oa_contactCount);
	plugContactCount.setValue(m_contactCount);
	
	// contactName
	MPlug plugContactName(thisObject, rigidBodyNode::oa_contactName);

	if ( !plugContactName.isNull() )
	{
		MObject strArrObject;
		plugContactName.getValue(strArrObject);

		MFnStringArrayData stringArrayData(strArrObject);
		MStringArray stringArray = stringArrayData.array();

		stringArray.append(contactObjectName);

		MFnStringArrayData newStringArrayData;
		MObject newStrArrObject = newStringArrayData.create(stringArray);
	
		plugContactName.setValue(newStrArrObject);
	}

	// contactPosition
	MPlug plugContactPosition(thisObject, rigidBodyNode::oa_contactPosition);

	if ( !plugContactPosition.isNull() )
	{
		MObject arrObject;
		plugContactPosition.getValue(arrObject);	

		MFnVectorArrayData vectorArrayData(arrObject);
		MVectorArray vectorArray = vectorArrayData.array();

		vectorArray.append(point);
	
		MFnVectorArrayData newVectorArrayData;
		MObject newArrObject = newVectorArrayData.create(vectorArray);	
	
		plugContactPosition.setValue(newArrObject);
	}
}
//MStringArray GlobalNodeHelper::getStringToArray(const MString& attrName )
//{
//	MStatus status;
//
//	MString strValue;
//	liquidGetPlugValue(m_GlobalNode, attrName.asChar(), strValue, status);
//	IfMErrorMsgWarn(status,"elvishray::GlobalNodeHelper::getStringArray("+attrName+")");
//	
//	MStringArray value;
//	status = strValue.split('|', value);
//	IfMErrorMsgWarn(status,"elvishray::GlobalNodeHelper::getStringArray --> split["+strValue+"] error.");
//
//	return value;
//}
MStringArray GlobalNodeHelper::getStringArray(const MString& attrName )
{
	MStatus status;
	MStringArray ret;

	unsigned int size = liquidGetPlugNumElements(m_GlobalNode, attrName.asChar(), &status);
	IfMErrorMsgWarn(status,"elvishray::GlobalNodeHelper::getStringArray("+attrName+"), liquidGetPlugNumElements()");

	for(unsigned int i=0; i < size; ++i)
	{
		MString val;
		IfMErrorMsgWarn(liquidGetPlugElementValue(m_GlobalNode, i, attrName.asChar(), val, status),
			"elvishray::GlobalNodeHelper::getStringArray("+attrName+"), liquidGetPlugElementValue()");
		ret.append(val);
	}
	return ret;
}
Example #28
0
bool XmlCacheFormat::readXmlTagValue( string tag, MStringArray& values )
{
	string endTag = XMLENDTAG(tag);
	bool status = true;

	values.clear();

	// Yes this could be much much smarter
	if( findXmlStartTag(tag) )
	{
		string token;
		fFile >> token;
		while ( !fFile.eof() && token != endTag )
		{
			values.append( token.data() );
			fFile >> token;
		} 
	}
	else
	{
// Load the file textures for the cube maps.
//
MStatus	hwRefractReflectShader_NV20::loadTextures(const MDrawRequest& request, M3dView& view)
{
	// Get the cube map file names
	//
	MStringArray	decalNames;
	MString			decalName;

	// Find the cubemap textures by tracing through the connection from the color atttribute
	//
	ShadingConnection	colorConnection(thisMObject(), request.multiPath().partialPathName(), "color");

	// If the color attribute is ultimately connected to a environment, 
	// find its filenames, otherwise use the default color texture.
	//
	bool gotAllEnvironmentMaps = TRUE;
	if (colorConnection.type() == ShadingConnection::TEXTURE &&
		colorConnection.texture().hasFn(MFn::kEnvCube))
	{
		// Get the filenames of the texture.
		MFnDependencyNode textureNode(colorConnection.texture());
		MString attributeName;
		MString envNames[6] = { "top", "bottom", "left", "right", "front", "back" };

		// Scan for connected file textures to the environment map node
		//
		for (int i=0; i<6; i++)
		{
			ShadingConnection conn(colorConnection.texture(), request.multiPath().partialPathName(), 
							envNames[i]);

			if (conn.type() == ShadingConnection::TEXTURE &&
				conn.texture().hasFn(MFn::kFileTexture))
			{
				MFnDependencyNode envNode(conn.texture());
				MPlug filenamePlug( conn.texture(), envNode.attribute(MString("fileTextureName")) );

				filenamePlug.getValue(decalName);

				if (decalName.length() == 0)	decalName = "internalDefaultTexture";

				// Append next environment map name
				decalNames.append( decalName );
			}

			// If any of the environment maps are not mapped put in a fake texture
			else
			{
				decalName = "internalDefaultTexture";
				decalNames.append( decalName );
			}
		}
	}
	else
	{
		// Put in a fake texture for each side
		decalName = "internalDefaultTexture";
		for (int i=0; i<6; i++)
		{
			decalNames.append( decalName );
		}
	}

	// Reload cube maps if the name of the textures
	// for any of the cube maps changes
	//
	bool reload = FALSE;
	for (int i=0; i<6; i++)
	{
		if (currentTextureNames[i] != decalNames[i])
		{
			reload = TRUE;
			break;
		}
	}

	view.beginGL();
	{
		if ( reload )
		{
			MString	ypTexName(decalNames[0]);	// y+ == top
			MString	ynTexName(decalNames[1]);	// y- == bottom
			MString	xpTexName(decalNames[2]);	// x+ == left
			MString	xnTexName(decalNames[3]);	// x- == right
			MString	zpTexName(decalNames[4]);	// z+ == front
			MString	znTexName(decalNames[5]);	// z- == back

			MStatus stat;
			if (! (stat = theImage_XP.readFromFile(xpTexName)) )	return MS::kFailure;
			if (! (stat = theImage_XN.readFromFile(xnTexName)) )	return MS::kFailure;
			if (! (stat = theImage_YP.readFromFile(ypTexName)) )	return MS::kFailure;
			if (! (stat = theImage_YN.readFromFile(ynTexName)) )	return MS::kFailure;
			if (! (stat = theImage_ZP.readFromFile(zpTexName)) )	return MS::kFailure;
			if (! (stat = theImage_ZN.readFromFile(znTexName)) )	return MS::kFailure;

			// Only create texture names the first time
			if (fTextureName == -1) 	glGenTextures(1, &fTextureName);

			glBindTexture( GL_TEXTURE_CUBE_MAP_ARB, fTextureName );
			glEnable( GL_TEXTURE_CUBE_MAP_ARB );

			// The cubeMap textures have to have the same size
			//
			unsigned int width, height;
			stat = theImage_XP.getSize( width, height );

			glTexImage2D(GL_TEXTURE_CUBE_MAP_POSITIVE_X_ARB,
				0, GL_RGBA8, width,	height, 0, GL_RGBA,	GL_UNSIGNED_BYTE, theImage_XP.pixels() );
			glTexImage2D(GL_TEXTURE_CUBE_MAP_NEGATIVE_X_ARB,
				0, GL_RGBA8, width,	height,	0, GL_RGBA,	GL_UNSIGNED_BYTE, theImage_XN.pixels() );
			glTexImage2D(GL_TEXTURE_CUBE_MAP_POSITIVE_Y_ARB,
				0, GL_RGBA8, width,	height,	0, GL_RGBA,	GL_UNSIGNED_BYTE, theImage_YP.pixels() );
			glTexImage2D(GL_TEXTURE_CUBE_MAP_NEGATIVE_Y_ARB,
				0, GL_RGBA8, width,	height,	0, GL_RGBA,	GL_UNSIGNED_BYTE, theImage_YN.pixels() );
			glTexImage2D(GL_TEXTURE_CUBE_MAP_POSITIVE_Z_ARB,
				0, GL_RGBA8, width,	height,	0, GL_RGBA,	GL_UNSIGNED_BYTE, theImage_ZP.pixels() );
			glTexImage2D(GL_TEXTURE_CUBE_MAP_NEGATIVE_Z_ARB,
				0, GL_RGBA8, width,	height,	0, GL_RGBA,	GL_UNSIGNED_BYTE, theImage_ZN.pixels() );

			glTexParameteri(GL_TEXTURE_CUBE_MAP_ARB, GL_TEXTURE_WRAP_S, GL_CLAMP_TO_EDGE);
			glTexParameteri(GL_TEXTURE_CUBE_MAP_ARB, GL_TEXTURE_WRAP_T, GL_CLAMP_TO_EDGE);
			glTexParameteri(GL_TEXTURE_CUBE_MAP_ARB, GL_TEXTURE_WRAP_R, GL_CLAMP_TO_EDGE);
			glTexParameteri(GL_TEXTURE_CUBE_MAP_EXT, GL_TEXTURE_MAG_FILTER, GL_LINEAR);
			glTexParameteri(GL_TEXTURE_CUBE_MAP_EXT, GL_TEXTURE_MIN_FILTER, GL_LINEAR);
			glTexEnvi(GL_TEXTURE_ENV, GL_TEXTURE_ENV_MODE, GL_REPLACE);

			for (i=0; i<6; i++)		currentTextureNames[i] = decalNames[i];
		}

		// stage 0 -- cubeMap texture for the refraction
		//
		glActiveTextureARB( GL_TEXTURE0_ARB );
		glBindTexture( GL_TEXTURE_CUBE_MAP_ARB, fTextureName );
		glEnable( GL_TEXTURE_CUBE_MAP_ARB );

		// stage 1 -- cubeMap texture for the reflection
		//
		glActiveTextureARB( GL_TEXTURE1_ARB );
		glBindTexture( GL_TEXTURE_CUBE_MAP_ARB, fTextureName );
		glEnable( GL_TEXTURE_CUBE_MAP_ARB );
	}
	view.endGL();

	return MS::kSuccess;
}
/** Create a RIB compatible representation of a Maya polygon mesh.
 */
liqRibMeshData::liqRibMeshData( MObject mesh )
: numFaces( 0 ),
  numPoints ( 0 ),
  numNormals ( 0 ),
  nverts(),
  verts(),
  vertexParam(NULL),
  normalParam(NULL)
{
	CM_TRACE_FUNC("liqRibMeshData::liqRibMeshData("<<MFnDagNode(mesh).fullPathName().asChar()<<")");

	unsigned int i;
	unsigned int j;
  areaLight = false;
  LIQDEBUGPRINTF( "-> creating mesh\n" );
  MFnMesh fnMesh( mesh );
  objDagPath = fnMesh.dagPath();
  MStatus astatus;
  
  name = fnMesh.name();
  areaLight =( liquidGetPlugValue( fnMesh, "areaIntensity", areaIntensity, astatus ) == MS::kSuccess )? true : false ; 

  if ( areaLight ) 
  {
    MDagPath meshDagPath;
    meshDagPath = fnMesh.dagPath();
    MTransformationMatrix worldMatrix = meshDagPath.inclusiveMatrix();
    MMatrix worldMatrixM = worldMatrix.asMatrix();
    worldMatrixM.get( transformationMatrix );
  }

  numPoints = fnMesh.numVertices();
  numNormals = fnMesh.numNormals();

  // UV sets -------------------
  //
  //const unsigned numSTs( fnMesh.numUVs() );
  const unsigned numUVSets( fnMesh.numUVSets() );
  MString currentUVSetName;
  MStringArray extraUVSetNames;
  fnMesh.getCurrentUVSetName( currentUVSetName );
  {
    MStringArray UVSetNames;
    fnMesh.getUVSetNames( UVSetNames );

    for ( unsigned i( 0 ); i<numUVSets; i++ ) 
      if ( UVSetNames[i] != currentUVSetName ) 
        extraUVSetNames.append( UVSetNames[i] );
  }

  numFaces = fnMesh.numPolygons();
  const unsigned numFaceVertices( fnMesh.numFaceVertices() );

	if ( numPoints < 1 )
	{
//		MGlobal::displayInfo( MString( "fnMesh: " ) + fnMesh.name() );
//		cerr << "Liquid : Could not export degenerate mesh '"<< fnMesh.fullPathName( &astatus ).asChar() << "'" << endl << flush;
		return;
	}

  unsigned face = 0;
  unsigned faceVertex = 0;
  unsigned count;
  unsigned vertex;
  unsigned normal;
  float S;
  float T;
  MPoint point;
  liqTokenPointer pointsPointerPair;
  liqTokenPointer normalsPointerPair;
  liqTokenPointer pFaceVertexSPointer;
  liqTokenPointer pFaceVertexTPointer;

  // Allocate memory and tokens
  numFaces = numFaces;
  nverts = shared_array< liqInt >( new liqInt[ numFaces ] );
  verts = shared_array< liqInt >( new liqInt[ numFaceVertices ] );

  pointsPointerPair.set( "P", rPoint, numPoints );
  pointsPointerPair.setDetailType( rVertex );

  if ( numNormals == numPoints ) 
  {
    normalsPointerPair.set( "N", rNormal, numPoints );
    normalsPointerPair.setDetailType( rVertex );
  } 
  else 
  {
    normalsPointerPair.set( "N", rNormal, numFaceVertices );
    normalsPointerPair.setDetailType( rFaceVarying );
  }
  	
  // uv
  std::vector<liqTokenPointer> UVSetsArray;
  UVSetsArray.reserve( 1 + extraUVSetNames.length() );

  liqTokenPointer currentUVSetUPtr;
  liqTokenPointer currentUVSetVPtr;
  liqTokenPointer currentUVSetNamePtr;
  liqTokenPointer extraUVSetsUPtr;
  liqTokenPointer extraUVSetsVPtr;
  liqTokenPointer extraUVSetsNamePtr;
  if(liqglo.liqglo_outputMeshAsRMSArrays)
  {
	  currentUVSetUPtr.set( "s", rFloat, numFaceVertices );
	  currentUVSetUPtr.setDetailType( rFaceVarying );

	  currentUVSetVPtr.set( "t", rFloat, numFaceVertices );
	  currentUVSetVPtr.setDetailType( rFaceVarying );

	  currentUVSetNamePtr.set( "currentUVSet", rString, 1 );
	  currentUVSetNamePtr.setDetailType( rConstant );

	  if( numUVSets > 1 )
	  {
		  extraUVSetsUPtr.set( "u_uvSet", rFloat, numFaceVertices, numUVSets-1 );
		  extraUVSetsUPtr.setDetailType( rFaceVarying );

		  extraUVSetsVPtr.set( "v_uvSet", rFloat, numFaceVertices, numUVSets-1 );
		  extraUVSetsVPtr.setDetailType( rFaceVarying );

		  extraUVSetsNamePtr.set( "extraUVSets", rString, numUVSets-1 );
		  extraUVSetsNamePtr.setDetailType( rConstant );
	  }
  }
  else
  {
	  if ( numUVSets > 0 ) 
	  {
		liqTokenPointer pFaceVertexPointerPair;

		pFaceVertexPointerPair.set( "st", rFloat, numFaceVertices, 2 );
		pFaceVertexPointerPair.setDetailType( rFaceVarying );

		UVSetsArray.push_back( pFaceVertexPointerPair );

		for ( unsigned j( 0 ); j<extraUVSetNames.length(); j++) 
		{
		  liqTokenPointer pFaceVertexPointerPair;

		  pFaceVertexPointerPair.set( extraUVSetNames[j].asChar(), rFloat, numFaceVertices, 2 );
		  pFaceVertexPointerPair.setDetailType( rFaceVarying );

		  UVSetsArray.push_back( pFaceVertexPointerPair );
		}

		if( liqglo.liqglo_outputMeshUVs ) 
		{
		  // Match MTOR, which also outputs face-varying STs as well for some reason - Paul
		  // not anymore - Philippe
		  pFaceVertexSPointer.set( "u", rFloat, numFaceVertices );
		  pFaceVertexSPointer.setDetailType( rFaceVarying );

		  pFaceVertexTPointer.set( "v", rFloat, numFaceVertices );
		  pFaceVertexTPointer.setDetailType( rFaceVarying );
		}
	  }
  }

  vertexParam = pointsPointerPair.getTokenFloatArray();
  normalParam = normalsPointerPair.getTokenFloatArray();

  // Read the mesh from Maya
  MFloatVectorArray normals;
  fnMesh.getNormals( normals );

  for ( MItMeshPolygon polyIt ( mesh ); polyIt.isDone() == false; polyIt.next() ) 
  {
    count = polyIt.polygonVertexCount();
    nverts[face] = count;
	for( i=0; i<count; i++ )    // boucle sur les vertex de la face
    {
      vertex = polyIt.vertexIndex( i );
      verts[faceVertex] = vertex;
      point = polyIt.point( i, MSpace::kObject );
      pointsPointerPair.setTokenFloat( vertex, point.x, point.y, point.z );
      normal = polyIt.normalIndex( i );

      if( numNormals == numPoints ) 
        normalsPointerPair.setTokenFloat( vertex, normals[normal].x, normals[normal].y, normals[normal].z );
      else 
        normalsPointerPair.setTokenFloat( faceVertex, normals[normal].x, normals[normal].y, normals[normal].z );

	  if( liqglo.liqglo_outputMeshAsRMSArrays )
	  {
		  for( j=0; j<numUVSets; j++ )
		  {
			  if(j==0)
			  {
				  MString uvSetName = currentUVSetName;
				  // set uvSet name
				  currentUVSetNamePtr.setTokenString( 0, currentUVSetName.asChar() );
				  // set uv values
				  fnMesh.getPolygonUV( face, i, S, T, &uvSetName );

				  currentUVSetUPtr.setTokenFloat( faceVertex, S );
				  currentUVSetVPtr.setTokenFloat( faceVertex, 1-T );
			  }
			  else
			  {
				  MString uvSetName = extraUVSetNames[j-1];
				  // set uvSet name
				  extraUVSetsNamePtr.setTokenString( j-1, extraUVSetNames[j-1].asChar() );
				  // set uv values
				  fnMesh.getPolygonUV( face, i, S, T, &uvSetName );
				  extraUVSetsUPtr.setTokenFloat( (numFaceVertices*(j-1)) + faceVertex, S );
				  extraUVSetsVPtr.setTokenFloat( (numFaceVertices*(j-1)) + faceVertex, 1-T );
			  }
		  }
	  }
	  else
	  {
		  if ( numUVSets ) 
		  {
			  for( j=0; j<numUVSets; j++ )
			  {
				  MString uvSetName;
				  if(j==0)
				  {
					  uvSetName = currentUVSetName;
				  }
				  else
				  {
					  uvSetName = extraUVSetNames[j-1];
				  }
				  fnMesh.getPolygonUV( face, i, S, T, &uvSetName );
				  UVSetsArray[j].setTokenFloat( faceVertex, 0, S );
				  UVSetsArray[j].setTokenFloat( faceVertex, 1, 1-T );
				  //printf("V%d  %s : %f %f  =>  %f %f \n", i, uvSetName.asChar(), S, T, S, 1-T);

				  if( liqglo.liqglo_outputMeshUVs && j==0)
				  {
					  // Match MTOR, which always outputs face-varying STs as well for some reason - Paul
					  pFaceVertexSPointer.setTokenFloat( faceVertex, S );
					  pFaceVertexTPointer.setTokenFloat( faceVertex, 1-T );
				  }
			  }
		  }
		}
      // printf( "[%d] faceVertex = %d  vertex = %d\n", i, faceVertex, vertex );

      ++faceVertex;
    }
    ++face;
  }
  // Add tokens to array and clean up after
  tokenPointerArray.push_back( pointsPointerPair );
  tokenPointerArray.push_back( normalsPointerPair );

  if(liqglo.liqglo_outputMeshAsRMSArrays)
  {
	  tokenPointerArray.push_back( currentUVSetNamePtr );
	  tokenPointerArray.push_back( currentUVSetUPtr );
	  tokenPointerArray.push_back( currentUVSetVPtr );
	  if( numUVSets > 1 )
	  {
		  tokenPointerArray.push_back( extraUVSetsNamePtr );
		  tokenPointerArray.push_back( extraUVSetsUPtr );
		  tokenPointerArray.push_back( extraUVSetsVPtr );
	  }
  }
  else
  {
	  if( UVSetsArray.size() ) 
		  tokenPointerArray.insert( tokenPointerArray.end(), UVSetsArray.begin(), UVSetsArray.end() );

	  if( liqglo.liqglo_outputMeshUVs ) 
	  {
		  tokenPointerArray.push_back( pFaceVertexSPointer );
		  tokenPointerArray.push_back( pFaceVertexTPointer );
	  }
  }

  addAdditionalSurfaceParameters( mesh );
}