C++： 基于四叉树数据结构的自适应网格

二叉树是一种典型的非线性存储数据结构，查找效率可以达到\(O(log_2N)\)，同样，这类树状结构存在许多种变体，详细参考邓俊辉老师的《数据结构C++》课程。在这里不详细介绍树状数据结构的具体特性，只是初步尝试下基于四叉树数据结构如何实现\(CFD\)计算网格的自适应功能。

四叉树数据数据结构

四叉树数据结构与二维空间网格对应关系如下图所示

基于四叉树数据结构，容易实现对于二维空间区域的局部细化，这对于\(CFD\)计算是十分有用的。一般来说，网格的好坏能够很大程度上影响\(CFD\)数值计算过结果的准确性，网格越精细，流场空间分辨率也就越高，能够描述更为细致的流场，同时也意味着，需要求解的线性方程组更加庞大。

自适应网格就是为了优化此类问题而提出的，在流场内，物理量梯度较大的地方，设置更加细致的网格，流场平缓的区域，网格可以适当稀疏。然而，一般的多面体、多边形网格划分难度较大，为了划分合适的贴体网格，精确拟合物体表面，网格划分过程中计算量同样巨大。因此，自适应网格一般都是基于简单的几何体，规整地四分或者八分网格，以此达到网格划分。著名的\(CFD\)开源求解程序\(Gerris\)，便拥有基于四/八叉树建立的网格自适应功能。

源码项目地址(还没更新)

demo

例子：在一块宽度为\(\pi\)的方形区域中间，定义一条曲线\(z=sin(x+t)\)，在曲线周围设置网格加密最大至7层，曲线上下0.5为加密区域。效果如下

#include <iostream>

#include "QuadTree.h"

#include "PanelTree.h"

using namespace std;

#define PI 3.1415926

double Eta(const Panel& e, double t) {

	double x=e.Centroid(0, 0);

	double y=e.Centroid(1, 0);

	double z = e.Centroid(2, 0);

	return sin(x + t);

}

int main(){

	Panel patch({ -PI,0,-PI }, { -PI,0,PI }, { PI,0,PI }, { PI,0,-PI });

	PanelTree tree(patch);

	char buff[100];

	for (int i = 0; i < 100; i++) {

		sprintf_s(buff, "leafsfile_%04d.txt", i);

        //最大加密至7层，曲线上下0.5为加密区域

		tree.Expand_demo(tree.root, 7, i/30., Eta, 0.5, -0.5);

		tree.WriteLeafsNode(buff);

	}

	return 0;

}

四叉树模板类 ADT

四叉树模板类

/*QuadTree.h

* Include; TreeNode Class, QuadTree Class

*/

#pragma once

#include <iostream>

#include <vector>

#include <iomanip>

#include <fstream>

#define FormatOut(string,X) std::cout<< std::setw(20) << std::left <<string<<":"<< (#X)<<" = "<<X<<std::endl

template<class T> using vector = std::vector<T>;

template<class T> class TreeNode;

template<class T> using TreeNodePosi = TreeNode<T>*;

#define HasChild(p) (p->c1st!=NULL||p->c2nd!=NULL||p->c3rd!=NULL||p->c4th!=NULL)

#define HasParent(p) (p->parent!=NULL)

template<class T>

class TreeNode {

public:

	T element;

	TreeNodePosi<T> parent, c1st, c2nd, c3rd, c4th;

	int height;

	TreeNode() :parent(NULL), c1st(NULL), c2nd(NULL), c3rd(NULL), c4th(NULL), height(1) {}

	TreeNode(T e) : element(e), parent(NULL), c1st(NULL), c2nd(NULL), c3rd(NULL), c4th(NULL), height(1) {}

	TreeNode(T e, TreeNodePosi<T> p) :element(e), parent(p), c1st(NULL), c2nd(NULL), c3rd(NULL), c4th(NULL) {

		this->height = 1 + p->height;

	}

	void insertAsc1st(T const& e) { this->c1st = new TreeNode(e, this); this->c1st->height = this->height + 1; }

	void insertAsc2nd(T const& e) { this->c2nd = new TreeNode(e, this); this->c2nd->height = this->height + 1; }

	void insertAsc3rd(T const& e) { this->c3rd = new TreeNode(e, this); this->c3rd->height = this->height + 1; }

	void insertAsc4th(T const& e) { this->c4th = new TreeNode(e, this); this->c4th->height = this->height + 1; }

};

template<class T>

class QuadTree {

public:

	int Leaf_Num;

	vector<TreeNodePosi<T>> Leafs;

	int size;

	TreeNodePosi<T> root;

	QuadTree() :root(NULL), size(0), Leaf_Num() {}

	QuadTree(const T &root_node) :size(1), Leaf_Num(1) {

		root = new TreeNode<T> (root_node);

	}

	virtual void Expand(TreeNodePosi<T> p);					//Expend 1 Level

	virtual void Expand(TreeNodePosi<T> p, int Level);		//Expand to Level

	void DeleteTreeNode(TreeNodePosi<T>& p) { delete p; p = NULL;

	}					//delete TreeNode

	void DeleteTree(TreeNodePosi<T>& p);						//delete Tree at p

	~QuadTree() {

		DeleteTree(this->root);

		delete root;

		root = NULL;

		std::cout << "QuadTree deconstructor" << std::endl;

	}

	void Travers(TreeNodePosi<T> p, vector<TreeNodePosi<T>>& S);

	void Travers();

	void WriteLeafsNode(const char* filename);

};

template<class T>

void QuadTree<T>::Expand(TreeNodePosi<T> p) {

	T c1_sub, c2_sub, c3_sub, c4_sub;

	p->insertAsc1st(c1_sub);

	p->insertAsc2nd(c2_sub);

	p->insertAsc3rd(c3_sub);

	p->insertAsc4th(c4_sub);

	size += 4;

}

template<class T>

void QuadTree<T>::Expand(TreeNodePosi<T> p, int Level){

	if (p->height >= Level) return;

	else {

		this->Expand(p);

		this->Expand(p->c1st, Level);

		this->Expand(p->c2nd, Level);

		this->Expand(p->c3rd, Level);

		this->Expand(p->c4th, Level);

	}

}

template<class T>

inline void QuadTree<T>::DeleteTree(TreeNodePosi<T>& p){

	if (p == NULL) return;

	if (HasChild(p)) {

		DeleteTree(p->c1st); DeleteTreeNode(p->c1st);

		DeleteTree(p->c2nd); DeleteTreeNode(p->c2nd);

		DeleteTree(p->c3rd); DeleteTreeNode(p->c3rd);

		DeleteTree(p->c4th); DeleteTreeNode(p->c4th);

	}

	else {

		DeleteTreeNode(p);

	}

}

template<class T>

inline void QuadTree<T>::Travers(TreeNodePosi<T> p, vector<TreeNodePosi<T>>& S){

	if (p == NULL) return;

	if (!HasChild(p)) {

		S.push_back(p);

	}

	else {

		Travers(p->c1st, S);

		Travers(p->c2nd, S);

		Travers(p->c3rd, S);

		Travers(p->c4th, S);

	}

}

template<class T>

inline void QuadTree<T>::Travers(){

	Leafs.clear();

	Travers(this->root, this->Leafs);

	Leaf_Num = Leafs.size();

	FormatOut("Leaf Size", Leaf_Num);

}

//output file!!! Note: the class T should overload << operator

template<class T>

void QuadTree<T>::WriteLeafsNode(const char* filename){

	this->Travers();

	std::ofstream fout(filename);

	for (TreeNodePosi<T> p : this->Leafs)

		fout << p->element;

	fout.close();

}

PanelTree 类

PanelTree类继承自QuadTree类，数据成员为自定义的Panel结构体，源码依赖开源矩阵库\(Eigen\)

/*

*PanelTree.h

*/

#pragma once

#include "QuadTree.h"

#include <iostream>

#include <iomanip>

#include <fstream>

#include "Eigen/Dense"

#define FOUT_V(name) out << std::setw(20) << std::scientific << std::setprecision(4) << e.##name<<","

#define FOUT(name) out << std::setw(20) << std::scientific << std::setprecision(4) << e.##name(0, 0)<<","\

					   << std::setw(20) << std::scientific << std::setprecision(4) << e.##name(1, 0)<<","\

					   << std::setw(20) << std::scientific << std::setprecision(4) << e.##name(2, 0)<<","

template<class T> using Mat3 = Eigen::Matrix<T, 3, 1>;

using string = std::string;

using ofstream = std::ofstream;

struct Panel {

public:

	Mat3<double> P1 = { 0,0,0 };

	Mat3<double> P2 = { 0,0,0 };

	Mat3<double> P3 = { 0,0,0 };

	Mat3<double> P4 = { 0,0,0 };

	Mat3<double> Centroid = { 0,0,0 };

	Mat3<double> Normal = { 0,0,0 };

	double ds, Fraction;

	Panel(Mat3<double> p1, Mat3<double> p2, Mat3<double> p3, Mat3<double> p4);

	Panel() {};

	Panel(const Panel& e);                  //copy constructor

	Panel& operator =(const Panel& e);      //overload =

	void Cal();

	void Cal_Fraction(double eta);

	friend ofstream& operator << (ofstream& out, const Panel& e) {

		FOUT(Centroid); FOUT(Normal);

		FOUT_V(ds); FOUT_V(Fraction);

		FOUT(P1); FOUT(P2); FOUT(P3); FOUT(P4);

		out << std::endl;

		return out;

	}

};

class PanelTree : public QuadTree<Panel>

{

public:

	PanelTree(const Panel &root) :QuadTree<Panel>(root) {}

public:

	bool IsContainFreeSurface(Panel& e, double t, double (*Eta)(const Panel&, double));

	bool IsNearFreeSurface(Panel& e, double t, double (*Eta)(const Panel&, double), double up, double down);

	//bool IsContainCircle(Panel& e, double t, Mat3<double>(*Circle)(const Panel&, double));

	//bool IsNearCircle(Panel& e, double t, Mat3<double>(*Circle)(const Panel&, double), double r0);

	virtual void Expand(TreeNodePosi<Panel> p) override;

	void Expand_demo(TreeNodePosi<Panel> p, int Level, double t, double (*Eta)(const Panel&, double), double up, double down);

};

/*

*PanelTree.cpp

*/

#include "PanelTree.h"

Panel::Panel(Mat3<double> p1, Mat3<double> p2, Mat3<double> p3, Mat3<double> p4) {

	this->P1 = p1; this->P2 = p2; this->P3 = p3; this->P4 = p4;

	this->Cal();//计算中心、ds、法相向量等参数；

	this->Fraction = 0;

}

Panel::Panel(const Panel& e) {

	this->P1 = e.P1;    this->P2 = e.P2;    this->P3 = e.P3;    this->P4 = e.P4;

	this->Centroid = e.Centroid;

	this->Normal = e.Normal;

	this->Fraction = e.Fraction;

	this->ds = e.ds;

}

Panel& Panel::operator =(const Panel& e) {

	this->P1 = e.P1;    this->P2 = e.P2;    this->P3 = e.P3;    this->P4 = e.P4;

	this->Centroid = e.Centroid;

	this->Normal = e.Normal;

	this->Fraction = e.Fraction;

	this->ds = e.ds;

	return *this;

}

void Panel::Cal() {

	Mat3<double> n1 = { 0,0,0 }, n2 = { 0,0,0 };

	double Costheta = 0, Sintheta = 0;

	Mat3<double> tmp = { 0,0,0 };

	n1 = P1 - P3;

	n2 = P2 - P4;

	Costheta = n1.dot(n2) / (n1.norm() * n2.norm());

	Sintheta = sqrt(1 - pow(Costheta, 2));

	ds = 0.5 * (n1.norm() * n2.norm() * Sintheta);

	Centroid = (P1 + P2 + P3 + P4) / 4.;

	tmp = n1.cross(n2);

	Normal = tmp.normalized();

}

void Panel::Cal_Fraction(double eta) {

	double f[4]{};

	f[0] = this->P1(2, 0) - eta;

	f[1] = this->P2(2, 0) - eta;

	f[2] = this->P3(2, 0) - eta;

	f[3] = this->P4(2, 0) - eta;

	double fN = 0, fP = 0;

	if (f[0] <= 0 && f[1] <= 0 && f[2] <= 0 && f[3] <= 0)

		this->Fraction = 1.;

	else {

		if (f[0] >= 0 && f[1] >= 0 && f[2] >= 0 && f[3] >= 0)

			this->Fraction = 0.;

		else {

			for (int i = 0; i < 4; ++i) {

				if (f[i] >= 0) fP += f[i];

				else fN += f[i];

			}

			this->Fraction = abs(fN) / (abs(fP) + abs(fN));

		}

	}

}

bool PanelTree::IsContainFreeSurface(Panel& e,double t,double(*Eta)(const Panel&, double)){

	double eta = Eta(e, t);

	e.Cal_Fraction(eta);

	return !((abs(e.Fraction - 1) < 1.0e-5) || (abs(e.Fraction - 0) < 1.0e-5));

}

bool PanelTree::IsNearFreeSurface(Panel& e, double t, double(*Eta)(const Panel&, double), double up, double down){

	double eta = Eta(e, t);

	e.Cal_Fraction(eta);

	double z = e.Centroid(2, 0);

	return ((z - eta) >= down && (z - eta) <= up);

}

//bool PanelTree::IsContainCircle(Panel& e, double t, Mat3<double>(*Circle)(const Panel&, double))

//{

//	return false;

//}

//

//bool PanelTree::IsNearCircle(Panel& e, double t, Mat3<double> (*Circle)(const Panel&, double), double r0)

//{

//	Mat3<double> pos = Circle(e, t);

//	double dis = (e.Centroid - pos).norm();

//	return abs(dis)<=r0;

//}

void PanelTree::Expand(TreeNodePosi<Panel> p){

	Panel subP1, subP2, subP3, subP4;

	Mat3<double> c12 = { 0,0,0 };

	Mat3<double> c23 = { 0,0,0 };

	Mat3<double> c34 = { 0,0,0 };

	Mat3<double> c41 = { 0,0,0 };

	c12 = (p->element.P1 + p->element.P2) / 2.;

	c23 = (p->element.P2 + p->element.P3) / 2.;

	c34 = (p->element.P3 + p->element.P4) / 2.;

	c41 = (p->element.P4 + p->element.P1) / 2.;

	//subP1

	subP1.P1 = p->element.P1;

	subP1.P2 = c12;

	subP1.P3 = p->element.Centroid;

	subP1.P4 = c41;

	//subP2

	subP2.P1 = p->element.P2;

	subP2.P2 = c23;

	subP2.P3 = p->element.Centroid;

	subP2.P4 = c12;

	//subP3

	subP3.P1 = p->element.P3;

	subP3.P2 = c34;

	subP3.P3 = p->element.Centroid;

	subP3.P4 = c23;

	//subP4

	subP4.P1 = p->element.P4;

	subP4.P2 = c41;

	subP4.P3 = p->element.Centroid;

	subP4.P4 = c34;

	subP1.Cal();	subP2.Cal();	subP3.Cal();	subP4.Cal();

	p->insertAsc1st(subP1); p->insertAsc2nd(subP2);

	p->insertAsc3rd(subP3); p->insertAsc4th(subP4);

	Leaf_Num += 3;

	size += 4;

}

void PanelTree::Expand_demo(TreeNodePosi<Panel> p, int Level, double t, double (*Eta)(const Panel&, double), double up, double down)

{

	if (p->height >= Level) return;

	bool IsMin = p->height <= 4;

	bool IsContain = this->IsContainFreeSurface(p->element, t, Eta);

	bool IsNear = this->IsNearFreeSurface(p->element, t, Eta, up, down);

	if (IsMin||IsNear||IsContain) {

		this->Expand(p);

		this->Expand_demo(p->c1st, Level, t, Eta, up, down);

		this->Expand_demo(p->c2nd, Level, t, Eta, up, down);

		this->Expand_demo(p->c3rd, Level, t, Eta, up, down);

		this->Expand_demo(p->c4th, Level, t, Eta, up, down);

	}

}