/* Prints graph in dot language */
std::ostream& DirectionalGraph::print( std::ostream& out ) const{
	out << "digraph DataFlowGraph{" << std::endl;

	/* Print nodes */
	const_node_iterator node = getBeginNode();
	const_node_iterator endNode = getEndNode();

	for( ; node != endNode; node++ ){
		out << *node << std::endl;
	}

	/* Print arrows between nodes */
	node = getBeginNode();
	endNode = getEndNode();

	for( ; node != endNode; node++ ){
		const node_set outArrows = getOutNodesSet(*node);
		const_node_iterator nodeOut = outArrows.begin();
		const_node_iterator endNodeOut = outArrows.end();

		for( ; nodeOut != endNodeOut; nodeOut++ ){
			out << *node << "->" << *nodeOut << std::endl;
		}
	}

	out << '}' << std::endl;

	return out;
}
示例#2
0
文件: main.cpp 项目: haowu80s/IBAMR
double
compute_deformed_length(node_set& nodes, EquationSystems* equation_systems)
{
    System& X_system = equation_systems->get_system<System>(IBFEMethod::COORDS_SYSTEM_NAME);
    const unsigned int X_sys_num = X_system.number();
    NumericVector<double>* X_vec = X_system.solution.get();
    AutoPtr<NumericVector<Number> > X_serial_vec = NumericVector<Number>::build(X_vec->comm());
    X_serial_vec->init(X_vec->size(), true, SERIAL);
    X_vec->localize(*X_serial_vec);

    // Get the current positions of the points.
    std::vector<IBTK::Point> points;
    points.reserve(nodes.size());
    IBTK::Point p;
    for (typename node_set::iterator it = nodes.begin(); it != nodes.end(); ++it)
    {
        Node* node = *it;
        for (unsigned int d = 0; d < NDIM; ++d)
        {
            p(d) = (*X_serial_vec)(node->dof_number(X_sys_num, d, 0));
        }
        points.push_back(p);
    }

    // Compute the length of the center line.
    IBTK::Point p0, p1;
    double l = 0.0;
    std::vector<IBTK::Point>::iterator it = points.begin();
    p0 = *it;
    ++it;
    for (; it != points.end(); ++it)
    {
        p1 = *it;
        double l_segment_sq = 0.0;
        for (int d = 0; d < NDIM; ++d)
        {
            l_segment_sq += pow(p0(d) - p1(d), 2.0);
        }
        l += sqrt(l_segment_sq);
        p0 = p1;
    }
    return l;
}
示例#3
0
文件: main.cpp 项目: haowu80s/IBAMR
double
compute_displaced_area(node_set& nodes, EquationSystems* equation_systems)
{
    System& X_system = equation_systems->get_system<System>(IBFEMethod::COORDS_SYSTEM_NAME);
    const unsigned int X_sys_num = X_system.number();
    NumericVector<double>* X_vec = X_system.solution.get();
    AutoPtr<NumericVector<Number> > X_serial_vec = NumericVector<Number>::build(X_vec->comm());
    X_serial_vec->init(X_vec->size(), true, SERIAL);
    X_vec->localize(*X_serial_vec);

    // Get the current positions of the points.
    std::vector<IBTK::Point> points;
    points.reserve(nodes.size());
    IBTK::Point p;
    for (typename node_set::iterator it = nodes.begin(); it != nodes.end(); ++it)
    {
        Node* node = *it;
        for (unsigned int d = 0; d < NDIM; ++d)
        {
            p(d) = (*X_serial_vec)(node->dof_number(X_sys_num, d, 0));
        }
        points.push_back(p);
    }

    // Compute the area of the polygon.
    IBTK::Point p0, p1;
    double A2 = 0.0;
    p0 = *points.rbegin();
    for (std::vector<IBTK::Point>::iterator it = points.begin(); it != points.end(); ++it)
    {
        p1 = *it;
        A2 += p0(0) * p1(1) - p0(1) * p1(0);
        p0 = p1;
    }
    return 0.5 * abs(A2);
}
示例#4
0
文件: main.cpp 项目: ranjiao/raysdemo
//寻找最短路径,最短路径存储在path中。返回值为路径长度
int Dijkstra(path_vec& path)
{
    //初始化各个变量
    path.clear();
    dist2start.clear();
    open_set.clear();
    close_set.clear();

    close_set.insert(start_node);
    for(int i=0; i<node_count; i++)
    {
        if(i != start_node)
            open_set.insert(i);
        dist2start[i] = std::make_pair(start_node, GetCrtMap(start_node,i) );
    }

    //开始寻路
    while(!open_set.empty())
    {
        path_pair min_cost = std::make_pair(start_node, BIG_NUMBER);
        int min_cost_node = -1;
        for(note_set_iter nodeToDo = open_set.begin();
            nodeToDo != open_set.end();
            nodeToDo++)
        {
            for(note_set_iter nodeDone = close_set.begin();
                nodeDone != close_set.end();
                nodeDone++)
            {
                int tmp_cost = dist2start[*nodeDone].second + GetCrtMap(*nodeDone, *nodeToDo);
                if(min_cost.second >= tmp_cost)
                {
                    min_cost.first = *nodeDone;
                    min_cost.second = tmp_cost;
                    min_cost_node = *nodeToDo;
                }
            } 
        }
        assert(min_cost_node != start_node);
        if(min_cost_node < 0)
            return -1;
        open_set.erase(min_cost_node);
        close_set.insert(min_cost_node);
        dist2start[min_cost_node] = (min_cost);
        
        // update nodes connected with min_cost_node
        for(note_set_iter nodeRel = open_set.begin();
            nodeRel != open_set.end();
            nodeRel++)
        {
            int tmp_dist = GetCrtMap(min_cost_node, *nodeRel);
            if(tmp_dist < BIG_NUMBER && min_cost.second + tmp_dist < dist2start[*nodeRel].second)
            {
                dist2start[*nodeRel].first = min_cost_node;
                dist2start[*nodeRel].second = min_cost.second + tmp_dist < dist2start[*nodeRel].second;
            }
        }
    }

    //输出路径
    int crtNode = end_node;
    do
    {
        path.insert(path.begin(), crtNode);
        crtNode = dist2start[crtNode].first;
    }while( crtNode != start_node );
    path.insert(path.begin(), start_node);

    return dist2start[end_node].second;
}
/*!\brief Prints the divergence graph in dot language */
std::ostream& DivergenceGraph::print( std::ostream& out ) const{
	using ir::PTXOperand;
	out << "digraph DirtyVariablesGraph{" << endl;

	/* Print dirt sources */
	map<PTXOperand::SpecialRegister, node_set>::const_iterator dirt = _specials.begin();
	map<PTXOperand::SpecialRegister, node_set>::const_iterator endDirt = _specials.end();

	out << "//Dirt sources:" << endl;
	for( ; dirt != endDirt; dirt++ ){
		if( dirt->second.size() ){
			out << getSpecialName(dirt->first) << "[style=filled, fillcolor = \"" << (isDivSource(dirt->first)?"tomato":"lightblue") << "\"]" << endl;
		}
	}

	/* Print nodes */
	out << "//Nodes:" << endl;
	const_node_iterator node = getBeginNode();
	const_node_iterator endNode = getEndNode();

	for( ; node != endNode; node++ ){
		out << *node << " [style=filled, fillcolor = \"" << (isDivNode(*node)?"lightyellow":"white") << "\"]" << endl;
	}

	out << endl;

	/* Print edges coming out of dirt sources */
	dirt = _specials.begin();
	endDirt = _specials.end();

	out << "//Dirt out edges:" << endl;
	for( ; dirt != endDirt; dirt++ ){
		if( dirt->second.size() ){
			node = dirt->second.begin();
			endNode = dirt->second.end();

			for( ; node != endNode; node++ ){
				out << getSpecialName(dirt->first) << "->" << *node << "[color = \"" << (isDivSource(dirt->first)?"red":"blue") << "\"]" << endl;
			}
		}
	}

	/* Print arrows between nodes */
	node = getBeginNode();
	endNode = getEndNode();

	out << "//Nodes edges:" << endl;
	for( ; node != endNode; node++ ){
		const node_set outArrows = getOutNodesSet(*node);
		const_node_iterator nodeOut = outArrows.begin();
		const_node_iterator endNodeOut = outArrows.end();

		for( ; nodeOut != endNodeOut; nodeOut++ ){
			out << *node << "->" << *nodeOut << endl;
		}
	}

	out << '}';

	return out;
}