OTS/OTSCPP/OTSRptCalculate/GBCal/GBFieldData.cpp

#pragma once
#include "stdafx.h"
#include "GBFieldData.h"
#include "CGBLevel.h"
#include <map>

namespace OTSGBCalculate
{
	using namespace std;
	using namespace OTSDATA;
#pragma region PrivateCode

	COTSParticlePtr CGBFieldData::FindAdjacentParticle(COTSParticlePtr p, COTSParticleList plist)
	{
		auto adjacentPart = find_if(plist.begin(), plist.end(), [p](COTSParticlePtr pBParticle)
			{
			    //the conditional particle
			    COTSRect rectParticle = p->GetOTSRect();
				CPoint ptParticleCenter = rectParticle.GetCenterPoint();
				int Bottom = rectParticle.GetBottomRight().y;
				int Top = rectParticle.GetTopLeft().y;

				//the iterational particle
				COTSRect rectBCurParticle = pBParticle->GetOTSRect();
				CPoint ptBParticleCenter = rectBCurParticle.GetCenterPoint();
				int BottomB = rectBCurParticle.GetBottomRight().y;
				int TopB = rectBCurParticle.GetTopLeft().y;

				if (rectParticle == rectBCurParticle)
				{
					return false;
				}

				double dd = 0, ds = 0;
				ds = abs(ptParticleCenter.x - ptBParticleCenter.x);
				if (ds < 10 )//recognize these two particle in the same level
				{
					if (Bottom > TopB)//current particle is on the above
					{
						dd = Bottom - TopB;
						if (dd < 40)//recognize these two particle in the same vertical string.
						{
							return true;
						}
					}
					else if (BottomB > Top)	//current particle is on the below
					{
						dd = BottomB - Top;
						if (dd < 40)
						{
							return true;
						}
					}
				}

				return false;
			});
		if (adjacentPart == plist.end())
		{
			return nullptr;
		}
		else
		{
			return *adjacentPart;
		}
	}
#pragma endregion

	CGBFieldData::CGBFieldData()							// constructor
	{
		Init();
	}

	CGBFieldData::CGBFieldData(const CGBFieldData& a_oSource)			// copy constructor
	{
		// can't copy itself
		if (&a_oSource == this)
		{
			return;
		}

		// copy data over
		Duplicate(a_oSource);
	}

	CGBFieldData::CGBFieldData(CGBFieldData* a_poSource)					// copy constructor
	{
		// input check
		ASSERT(a_poSource);
		if (!a_poSource)
		{
			return;
		}

		// can't copy itself
		if (a_poSource == this)
		{
			return;
		}

		// copy data over
		Duplicate(*a_poSource);
	}

	CGBFieldData& CGBFieldData::operator=(const CGBFieldData& a_oSource)	// =operator
	{
		// cleanup
		Cleanup();

		// copy the class data over
		Duplicate(a_oSource);

		// return class
		return *this;
	}

	BOOL CGBFieldData::operator==(const CGBFieldData& a_oSource)		// =operator
	{
		// return test result
		return((m_nFrameId == a_oSource.m_nFrameId) &&
			(*m_pALevel.get() == *a_oSource.m_pALevel.get()) &&
			(*m_pBLevel.get() == *a_oSource.m_pBLevel.get()) &&
			(*m_pCLevel.get() == *a_oSource.m_pCLevel.get()) &&
			(*m_pDLevel.get() == *a_oSource.m_pDLevel.get()) &&
			(*m_pDSLevel.get() == *a_oSource.m_pDSLevel.get()));
	}

	CGBFieldData::~CGBFieldData()					// detractor
	{
		Cleanup();
	}
	// serialization

	void CGBFieldData::Serialize(bool isStoring, tinyxml2::XMLDocument *classDoc, tinyxml2::XMLElement *rootNode)
	{
		xmls::xInt xFrameId;
		xmls::Slo slo;
		slo.Register("FrameId", &xFrameId);
		slo.Register("ALevel", m_pALevel.get());
		slo.Register("BLevel", m_pBLevel.get());
		slo.Register("CLevel", m_pCLevel.get());
		slo.Register("DLevel", m_pDLevel.get());
		slo.Register("DSLevel", m_pDSLevel.get());
		if (isStoring)
		{
			xFrameId = m_nFrameId;
			slo.Serialize(true, classDoc, rootNode);
		}
		else
		{
			slo.Serialize(false, classDoc, rootNode);
			m_nFrameId = xFrameId.value();
		}

	}




	// cleanup 
	void CGBFieldData::Cleanup()
	{

	}

	// initialization
	void CGBFieldData::Init()
	{
		// id
		m_nFrameId = -1;

		// A level
		m_pALevel = CGBLevelPtr(new CGBLevel(this, GB_LEVEL_TYPE::A_TYPE));

		// B level
		m_pBLevel = CGBLevelPtr(new CGBLevel(this, GB_LEVEL_TYPE::B_TYPE));

		// C level
		m_pCLevel = CGBLevelPtr(new CGBLevel(this, GB_LEVEL_TYPE::C_TYPE));

		// D level
		m_pDLevel = CGBLevelPtr(new CGBLevel(this, GB_LEVEL_TYPE::D_TYPE));

		// DS level
		m_pDSLevel = CGBLevelPtr(new CGBLevel(this, GB_LEVEL_TYPE::DS_TYPE));

		// DSulfide level
		m_pDSulfidLevel = CGBLevelPtr(new CGBLevel(this, GB_LEVEL_TYPE::DSulfide_TYPE));

		listAThinParticles.clear();
		listAWideParticles.clear();
		listASuperParticles.clear();
		listBThinParticles.clear();
		listBWideParticles.clear();
		listBSuperParticles.clear();
		listCThinParticles.clear();
		listCWideParticles.clear();
		listCSuperParticles.clear();
		listDThinParticles.clear();
		listDWideParticles.clear();
		listDSuperParticles.clear();
		listDSParticles.clear();
		listDSulfideThinParticles.clear();
		listDSulfideWideParticles.clear();
		listDSulfideSuperParticles.clear();
	}

	// duplication
	void CGBFieldData::Duplicate(const CGBFieldData& a_oSource)
	{
		// initialization
		Init();

		// id
		int m_nFrameId;

		// A level
		m_pALevel = CGBLevelPtr(new CGBLevel(*a_oSource.m_pALevel.get()));

		// B level
		m_pBLevel = CGBLevelPtr(new CGBLevel(*a_oSource.m_pBLevel.get()));

		// C level
		m_pCLevel = CGBLevelPtr(new CGBLevel(*a_oSource.m_pCLevel.get()));

		// D level
		m_pDLevel = CGBLevelPtr(new CGBLevel(*a_oSource.m_pDLevel.get()));

		// DS level
		m_pDSLevel = CGBLevelPtr(new CGBLevel(*a_oSource.m_pDSLevel.get()));

		m_nFrameId = a_oSource.m_nFrameId;

	}

	// caculate Level by method 1
	void CGBFieldData::CaculateLevelByMethod1()
	{
		// according to the shape
		if (m_listParticles.empty())
		{
			return;
		}
		vector<GBParticle> listBAndDParticles;//
		listBAndDParticles.clear();
		// get all the all particles for each level			
		mapAllParticles.clear();
		for (auto pParticle : m_listParticles)
		{	// compute length width ratio

			auto w = pParticle->GetDMin();
		
			if (w == 0)
			{
				continue;
			}
			//获取最大长度和最小宽度
			double h = pParticle->GetDMax();
		
			double dLengthWidthRatio = h / w;
			if (dLengthWidthRatio < 1)
			{
				dLengthWidthRatio = 1 / dLengthWidthRatio;
			}

			if (dLengthWidthRatio >= 3)//长宽比大于3的颗粒，根据化学元素不同，分为A类和C类
			{
				//A or C class
				GB_CHEMICAL_TYPE nChemicalType = pParticle->GetChemicalType();
				if (nChemicalType == GB_CHEMICAL_TYPE::CHE_S)
				{
					// A					
					//计算颗粒宽度是属于细系粗系还是超尺寸
					GB_WIDTH_TYPE wt = this->CaculateLevelWidth(pParticle, GB_LEVEL_TYPE::A_TYPE);
					switch (wt)
					{
					case GB_WIDTH_TYPE::THIN:
						listAThinParticles.push_back(pParticle);
						break;
					case GB_WIDTH_TYPE::WIDE:
						listAWideParticles.push_back(pParticle);
						break;
					case GB_WIDTH_TYPE::SUPER:
						listASuperParticles.push_back(pParticle);
						break;
					}
					mapAllParticles[pParticle] = GBParticle(pParticle, GB_LEVEL_TYPE::A_TYPE, wt);
				}
				else if (nChemicalType == GB_CHEMICAL_TYPE::CHE_O || nChemicalType== GB_CHEMICAL_TYPE::CHE_Si || nChemicalType == GB_CHEMICAL_TYPE::CHE_Al)
				{
					// C				
					//计算颗粒宽度是属于细系粗系还是超尺寸
					GB_WIDTH_TYPE wt = this->CaculateLevelWidth(pParticle, GB_LEVEL_TYPE::C_TYPE);

					switch (wt)
					{
					case GB_WIDTH_TYPE::THIN:
						listCThinParticles.push_back(pParticle);
						break;
					case GB_WIDTH_TYPE::WIDE:
						listCWideParticles.push_back(pParticle);
						break;
					case GB_WIDTH_TYPE::SUPER:
						listCSuperParticles.push_back(pParticle);
						break;
					}
					mapAllParticles[pParticle] = GBParticle(pParticle, GB_LEVEL_TYPE::C_TYPE, wt);
				}

			}
			else//长宽比小于3的颗粒，有3种情况，一种是串条状的B类颗粒，一种是单独的D类颗粒，如果费雷特直径大于13则为DS类颗粒
			{
				
				// B, or D or DS
				// compute Feret's diameter	
				double dFeretDiameter = pParticle->GetFeretDiameter();
				if (dFeretDiameter >= 13)
				{
					// DS		
					if (pParticle->GetType() != OTS_PARTICLE_TYPE::INVALID)//here we take all the particles 
					{
						listDSParticles.push_back(pParticle);
					}
				}
				else
				{
					if (pParticle->GetChemicalType() == GB_CHEMICAL_TYPE::CHE_S)//if it contains sulfide then it is a A particle.
					{
						GB_LEVEL_TYPE partType = GB_LEVEL_TYPE::A_TYPE;//把类型设为有效类型，以便不再找这个颗粒

						//计算颗粒宽度是属于细系粗系还是超尺寸
						GB_WIDTH_TYPE wt = this->CaculateLevelWidth(pParticle, GB_LEVEL_TYPE::A_TYPE);
						switch (wt)
						{
						case GB_WIDTH_TYPE::THIN:
							listAThinParticles.push_back(pParticle);
							break;
						case GB_WIDTH_TYPE::WIDE:
							listAWideParticles.push_back(pParticle);
							break;
						case GB_WIDTH_TYPE::SUPER:
							listASuperParticles.push_back(pParticle);
							break;
						}
						mapAllParticles[pParticle] = GBParticle(pParticle, partType, wt);

						

					}
					else
					{
						// B or D
						if (pParticle->GetType() != OTS_PARTICLE_TYPE::INVALID)//here we take all the particles 
						{
							GBParticle gbP = GBParticle(pParticle, GB_LEVEL_TYPE::INVALID, GB_WIDTH_TYPE::INVALID);
							//不能确定是B或D，先设为INVALID
							listBAndDParticles.push_back(gbP);
						}
						
					}
					

				}
			}



		}
		int n = listDSParticles.size();
		
			for (auto pGBParticle : listBAndDParticles)
			{
				
				
				 //check if the particle is alone			
				auto adjacentPart = find_if(listBAndDParticles.begin(), listBAndDParticles.end(), [pGBParticle](GBParticle pBParticle)
					{
					   //the conditional particle 
					     COTSRect rectParticle = pGBParticle.myPart->GetOTSRect();
						 CPoint ptParticleCenter = rectParticle.GetCenterPoint();
						int Bottom = rectParticle.GetBottomRight().y;
						int Top = rectParticle.GetTopLeft().y;
						//the current iteration particle
						COTSRect rectBCurParticle = pBParticle.myPart->GetOTSRect();
						CPoint ptBParticleCenter = rectBCurParticle.GetCenterPoint();
						int BottomB = rectBCurParticle.GetBottomRight().y;
						int TopB = rectBCurParticle.GetTopLeft().y;
						if (rectParticle == rectBCurParticle)
						{
							return false;
						}
						double dd = 0, ds = 0;
						ds = abs(ptParticleCenter.x - ptBParticleCenter.x);
						if (ds < 10 )//认为两个颗粒在一条竖直线上,但不在一起
						{
							if (Bottom > TopB)//current particle is on the above
							{
								dd = Bottom - TopB;
								if (dd < 40)//认为这两个颗粒在一个串条上
								{
									return true;
								}
							}
							else if (BottomB > Top)	//current particle is on the below
							{
								dd = BottomB - Top;
								if (dd < 40)
								{
									return true;
								}
							}
						}

						return false;
					});
			
				if (adjacentPart == listBAndDParticles.end())//没找到
				{
					if (pGBParticle.myPart->GetChemicalType() == GB_CHEMICAL_TYPE::CHE_O)
					{
						pGBParticle.myType = GB_LEVEL_TYPE::D_TYPE;

						//计算颗粒宽度是属于细系粗系还是超尺寸
						GB_WIDTH_TYPE wt = this->CaculateLevelWidth(pGBParticle.myPart, GB_LEVEL_TYPE::D_TYPE);
						switch (wt)
						{
						case GB_WIDTH_TYPE::THIN:
							listDThinParticles.push_back(pGBParticle.myPart);
							break;
						case GB_WIDTH_TYPE::WIDE:
							listDWideParticles.push_back(pGBParticle.myPart);
							break;
						case GB_WIDTH_TYPE::SUPER:
							listDSuperParticles.push_back(pGBParticle.myPart);
							break;
						}
						mapAllParticles[pGBParticle.myPart] = GBParticle(pGBParticle.myPart, GB_LEVEL_TYPE::D_TYPE, wt);
					}
					
				}
				else//找到了相邻接的颗粒，不是孤立的则为B类
				{
				
						pGBParticle.myType = GB_LEVEL_TYPE::B_TYPE;//把类型设为有效类型，以便不再找这个颗粒
						adjacentPart->myType = GB_LEVEL_TYPE::B_TYPE;

						//计算颗粒宽度是属于细系粗系还是超尺寸
						GB_WIDTH_TYPE wt = this->CaculateLevelWidth(pGBParticle.myPart, GB_LEVEL_TYPE::B_TYPE);
						switch (wt)
						{
						case GB_WIDTH_TYPE::THIN:
							listBThinParticles.insert(pGBParticle.myPart);
							break;
						case GB_WIDTH_TYPE::WIDE:
							listBWideParticles.insert(pGBParticle.myPart);
							break;
						case GB_WIDTH_TYPE::SUPER:
							listBSuperParticles.insert(pGBParticle.myPart);
							break;
						}
						mapAllParticles[pGBParticle.myPart] = GBParticle(pGBParticle.myPart, GB_LEVEL_TYPE::B_TYPE, wt);
						wt = this->CaculateLevelWidth(adjacentPart->myPart, GB_LEVEL_TYPE::B_TYPE);
						switch (wt)
						{
						case GB_WIDTH_TYPE::THIN:
							listBThinParticles.insert(adjacentPart->myPart);
							break;
						case GB_WIDTH_TYPE::WIDE:
							listBWideParticles.insert(adjacentPart->myPart);
							break;
						case GB_WIDTH_TYPE::SUPER:
							listBSuperParticles.insert(adjacentPart->myPart);
							break;
						}
						mapAllParticles[adjacentPart->myPart] = GBParticle(adjacentPart->myPart, GB_LEVEL_TYPE::B_TYPE, wt);
					
					

				}

			}

		}
	

	// caculate Level by method 2
	void CGBFieldData::CaculateLevelByMethod2()
	{
		vector<COTSParticlePtr> listABCParticles;//
		listABCParticles.clear();
		if (m_listParticles.empty())
		{
			return;
		}
		// get all the all particles for each level		
		for (auto pParticle : m_listParticles)
		{
			
			//check the denominator is zero or not
			auto w = pParticle->GetDMin();

			if (w == 0)
			{
				continue;
			}
			//获取最小外接矩形的宽和高
			double h = pParticle->GetDMax();
		
			double dLengthWidthRatio = h / w;
			if (dLengthWidthRatio < 1)
			{
				dLengthWidthRatio = 1 / dLengthWidthRatio;
			}

			if (dLengthWidthRatio < 3)//长宽比小于3的颗粒，且为孤立的颗粒，根据是否含硫化物，分为D类和DSulfide类,如果费雷特直径大于13 归为DS类
			{
				double dFeretDiameter = pParticle->GetFeretDiameter();
				if (dFeretDiameter >= 13)
				{
					// DS			
					if (pParticle->GetType() != OTS_PARTICLE_TYPE::INVALID)//here we take all the particles 
					{
						listDSParticles.push_back(pParticle);
					}
					
				}
				else
				{
					//  D or Dsulfide
					auto p = FindAdjacentParticle(pParticle, m_listParticles);
					if (p == nullptr)//pParticle是一个孤立的颗粒
					{
						GB_CHEMICAL_TYPE ChemicalType = pParticle->GetChemicalType();
						if (ChemicalType == GB_CHEMICAL_TYPE::CHE_S)
						{
							auto  wt = this->CaculateLevelWidth(pParticle, GB_LEVEL_TYPE::DSulfide_TYPE);
							switch (wt)
							{
							case GB_WIDTH_TYPE::THIN:
								listDSulfideThinParticles.push_back(pParticle);
								break;
							case GB_WIDTH_TYPE::WIDE:
								listDSulfideWideParticles.push_back(pParticle);
								break;
							case GB_WIDTH_TYPE::SUPER:
								listDSulfideSuperParticles.push_back(pParticle);
								break;
							}
							mapAllParticles[pParticle] = GBParticle(pParticle, GB_LEVEL_TYPE::DSulfide_TYPE, wt);

						}
						else
						{
							auto  wt = this->CaculateLevelWidth(pParticle, GB_LEVEL_TYPE::D_TYPE);
							switch (wt)
							{
							case GB_WIDTH_TYPE::THIN:
								listDThinParticles.push_back(pParticle);
								break;
							case GB_WIDTH_TYPE::WIDE:
								listDWideParticles.push_back(pParticle);
								break;
							case GB_WIDTH_TYPE::SUPER:
								listDSuperParticles.push_back(pParticle);
								break;
							}
							mapAllParticles[pParticle] = GBParticle(pParticle, GB_LEVEL_TYPE::D_TYPE, wt);

						}
					}
					else
					{
						listABCParticles.push_back(pParticle);
					}
				}
			}
			else
			{
				listABCParticles.push_back(pParticle);
			}
		}

		for (auto pParticle : listABCParticles)
		{
			
			GB_CHEMICAL_TYPE nChemicalType = pParticle->GetChemicalType();

			if (nChemicalType == GB_CHEMICAL_TYPE::CHE_S)
			{
				// A
				//COTSParticlePtr pParticleNew = COTSParticlePtr(pParticle);
				GB_WIDTH_TYPE wt = this->CaculateLevelWidth(pParticle, GB_LEVEL_TYPE::A_TYPE);

				switch (wt)
				{
				case GB_WIDTH_TYPE::THIN:
					listAThinParticles.push_back(pParticle);

					break;
				case GB_WIDTH_TYPE::WIDE:
					listAWideParticles.push_back(pParticle);
					break;
				case GB_WIDTH_TYPE::SUPER:
					listASuperParticles.push_back(pParticle);
					break;
				}
				mapAllParticles[pParticle] = GBParticle(pParticle, GB_LEVEL_TYPE::A_TYPE, wt);

			}
			else if (nChemicalType == GB_CHEMICAL_TYPE::CHE_Al)
			{
				// B
				GB_WIDTH_TYPE wt = this->CaculateLevelWidth(pParticle, GB_LEVEL_TYPE::B_TYPE);
				switch (wt)
				{
				case GB_WIDTH_TYPE::THIN:
					listBThinParticles.insert(pParticle);
					break;
				case GB_WIDTH_TYPE::WIDE:
					listBWideParticles.insert(pParticle);
					break;
				case GB_WIDTH_TYPE::SUPER:
					listBSuperParticles.insert(pParticle);
					break;
				}
				mapAllParticles[pParticle] = GBParticle(pParticle, GB_LEVEL_TYPE::B_TYPE, wt);

			}
			else if (nChemicalType == GB_CHEMICAL_TYPE::CHE_Si)
			{
				// C
				GB_WIDTH_TYPE wt = this->CaculateLevelWidth(pParticle, GB_LEVEL_TYPE::C_TYPE);

				switch (wt)
				{
				case GB_WIDTH_TYPE::THIN:
					listCThinParticles.push_back(pParticle);
					break;
				case GB_WIDTH_TYPE::WIDE:
					listCWideParticles.push_back(pParticle);
					break;
				case GB_WIDTH_TYPE::SUPER:
					listCSuperParticles.push_back(pParticle);
					break;
				}
				mapAllParticles[pParticle] = GBParticle(pParticle, GB_LEVEL_TYPE::C_TYPE, wt);

			}

		}
	}

	// caculate Level by ASTM
	void CGBFieldData::CaculateLevelASTM()
	{
		// according to the shape
		if (m_listParticles.empty())
		{
			return;
		}
		vector<GBParticle> listBAndDParticles;//
		listBAndDParticles.clear();
		// get all the all particles for each level			
		mapAllParticles.clear();
		for (auto pParticle : m_listParticles)
		{	// compute length width ratio

			auto w = pParticle->GetDMin();

			if (w == 0)
			{
				continue;
			}
			//获取最大长度和最小宽度
			double h = pParticle->GetDMax();
		
			double dLengthWidthRatio = h / w;
			if (dLengthWidthRatio < 1)
			{
				dLengthWidthRatio = 1 / dLengthWidthRatio;
			}

			if (dLengthWidthRatio >= 3)//长宽比大于3的颗粒，根据化学元素不同，分为A类和C类
			{
				//A or C class
				GB_CHEMICAL_TYPE nChemicalType = pParticle->GetChemicalType();
				if (nChemicalType == GB_CHEMICAL_TYPE::CHE_S)
				{
					// A					
					//计算颗粒宽度是属于细系粗系还是超尺寸
					GB_WIDTH_TYPE wt = this->CaculateLevelWidth(pParticle, GB_LEVEL_TYPE::A_TYPE);
					switch (wt)
					{
					case GB_WIDTH_TYPE::THIN:
						listAThinParticles.push_back(pParticle);
						break;
					case GB_WIDTH_TYPE::WIDE:
						listAWideParticles.push_back(pParticle);
						break;
					case GB_WIDTH_TYPE::SUPER:
						listASuperParticles.push_back(pParticle);
						break;
					}
					mapAllParticles[pParticle] = GBParticle(pParticle, GB_LEVEL_TYPE::A_TYPE, wt);
				}
				else if (nChemicalType == GB_CHEMICAL_TYPE::CHE_O || nChemicalType == GB_CHEMICAL_TYPE::CHE_Si || nChemicalType == GB_CHEMICAL_TYPE::CHE_Al)
				{
					// C				
					//计算颗粒宽度是属于细系粗系还是超尺寸
					GB_WIDTH_TYPE wt = this->CaculateLevelWidth(pParticle, GB_LEVEL_TYPE::C_TYPE);

					switch (wt)
					{
					case GB_WIDTH_TYPE::THIN:
						listCThinParticles.push_back(pParticle);
						break;
					case GB_WIDTH_TYPE::WIDE:
						listCWideParticles.push_back(pParticle);
						break;
					case GB_WIDTH_TYPE::SUPER:
						listCSuperParticles.push_back(pParticle);
						break;
					}
					mapAllParticles[pParticle] = GBParticle(pParticle, GB_LEVEL_TYPE::C_TYPE, wt);
				}



			}
			else//长宽比小于3的颗粒，有3种情况，一种是串条状的B类颗粒，一种是单独的D类颗粒，如果费雷特直径大于13则为DS类颗粒
			{
				// B, or D or DS
				// compute Feret's diameter	
				double dFeretDiameter = pParticle->GetFeretDiameter();
				if (dFeretDiameter >= 13)
				{
					// DS					
					if (pParticle->GetType() != OTS_PARTICLE_TYPE::INVALID)//here we take all the particles 
					{
						listDSParticles.push_back(pParticle);
					}
					
				}
				else
				{
					// B or D
					if (pParticle->GetChemicalType() != GB_CHEMICAL_TYPE::INVALID)//here we take all the particles 
					{
						GBParticle gbP = GBParticle(pParticle, GB_LEVEL_TYPE::INVALID, GB_WIDTH_TYPE::INVALID);
						//不能确定是B或D，先设为INVALID
						listBAndDParticles.push_back(gbP);
					}

				}
			}
		}
		
			for (auto pGBParticle : listBAndDParticles)
			{
				// check if the particle is alone			
				auto adjacentPart = find_if(listBAndDParticles.begin(), listBAndDParticles.end(), [pGBParticle](GBParticle pBParticle)
					{
					COTSRect rectParticle = pGBParticle.myPart->GetOTSRect();
						CPoint ptParticleCenter = rectParticle.GetCenterPoint();
						int Bottom = rectParticle.GetBottomRight().y;
						int Top = rectParticle.GetTopLeft().y;

						COTSRect rectBCurParticle = pBParticle.myPart->GetOTSRect();
						CPoint ptBParticleCenter = rectBCurParticle.GetCenterPoint();
						int BottomB = rectBCurParticle.GetBottomRight().y;
						int TopB = rectBCurParticle.GetTopLeft().y;

						double dd = 0, ds = 0;
						ds = abs(ptParticleCenter.x - ptBParticleCenter.x);
						if (ds <= 15)//认为两个颗粒在一条竖直线上,但不在一起
						{
							if (Bottom > TopB)//current particle is on the above
							{
								dd = Bottom - TopB;
								if (dd < 40)//认为这两个颗粒在一个串条上
								{
									return true;
								}
							}
							else if (BottomB > Top)	//current particle is on the below
							{
								dd = BottomB - Top;
								if (dd < 40)
								{
									return true;
								}
							}
						}

						return false;
					});
				if (adjacentPart == listBAndDParticles.end())//没找到
				{
					pGBParticle.myType = GB_LEVEL_TYPE::D_TYPE;

					//计算颗粒宽度是属于细系粗系还是超尺寸
					GB_WIDTH_TYPE wt = this->CaculateLevelWidth(pGBParticle.myPart, GB_LEVEL_TYPE::D_TYPE);
					switch (wt)
					{
					case GB_WIDTH_TYPE::THIN:
						listDThinParticles.push_back(pGBParticle.myPart);
						break;
					case GB_WIDTH_TYPE::WIDE:
						listDWideParticles.push_back(pGBParticle.myPart);
						break;
					case GB_WIDTH_TYPE::SUPER:
						listDSuperParticles.push_back(pGBParticle.myPart);
						break;
					}
					mapAllParticles[pGBParticle.myPart] = GBParticle(pGBParticle.myPart, GB_LEVEL_TYPE::D_TYPE, wt);
				}
				else//找到了相邻接的颗粒，不是孤立的则为B类
				{
					pGBParticle.myType = GB_LEVEL_TYPE::B_TYPE;//把类型设为有效类型，以便不再找这个颗粒
					adjacentPart->myType = GB_LEVEL_TYPE::B_TYPE;

					//计算颗粒宽度是属于细系粗系还是超尺寸
					GB_WIDTH_TYPE wt = this->CaculateLevelWidth(pGBParticle.myPart, GB_LEVEL_TYPE::B_TYPE);
					switch (wt)
					{
					case GB_WIDTH_TYPE::THIN:
						listBThinParticles.insert(pGBParticle.myPart);
						break;
					case GB_WIDTH_TYPE::WIDE:
						listBWideParticles.insert(pGBParticle.myPart);
						break;
					case GB_WIDTH_TYPE::SUPER:
						listBSuperParticles.insert(pGBParticle.myPart);
						break;
					}
					mapAllParticles[pGBParticle.myPart] = GBParticle(pGBParticle.myPart, GB_LEVEL_TYPE::B_TYPE, wt);
					wt = this->CaculateLevelWidth(adjacentPart->myPart, GB_LEVEL_TYPE::B_TYPE);
					switch (wt)
					{
					case GB_WIDTH_TYPE::THIN:
						listBThinParticles.insert(adjacentPart->myPart);
						break;
					case GB_WIDTH_TYPE::WIDE:
						listBWideParticles.insert(adjacentPart->myPart);
						break;
					case GB_WIDTH_TYPE::SUPER:
						listBSuperParticles.insert(adjacentPart->myPart);
						break;
					}
					mapAllParticles[adjacentPart->myPart] = GBParticle(adjacentPart->myPart, GB_LEVEL_TYPE::B_TYPE, wt);

				}

			}

		
	}
	// caculate Level by DIN
	void CGBFieldData::CaculateLevelDIN(COTSParticleList listParticle)
	{
		// according to the shape
		if (listParticle.empty())
		{
			return;
		}
		vector<GBParticle> listBAndDParticles;//
		listBAndDParticles.clear();
		// get all the all particles for each level			
		mapAllParticles.clear();
		for (auto pParticle : listParticle)
		{	// compute length width ratio

			CRect rectParticle = pParticle->GetParticleRect();
			//check the denominator is zero or not
			if (rectParticle.Width() == 0)
			{
				continue;
			}
			//获取最大长度和最小宽度
			double h = pParticle->GetDMax();
			double w = pParticle->GetDMin();
			double dLengthWidthRatio = h / w;
			if (dLengthWidthRatio < 1)
			{
				dLengthWidthRatio = 1 / dLengthWidthRatio;
			}

			if (dLengthWidthRatio >= 3)//长宽比大于3的颗粒，根据化学元素不同，分为A类和C类
			{
				//A or C class
				GB_CHEMICAL_TYPE nChemicalType = pParticle->GetChemicalType();


				if (nChemicalType == GB_CHEMICAL_TYPE::CHE_S)
				{
					// A					
					//计算颗粒宽度是属于细系粗系还是超尺寸
					GB_WIDTH_TYPE wt = this->CaculateLevelWidth(pParticle, GB_LEVEL_TYPE::A_TYPE);
					if (wt == GB_WIDTH_TYPE::THIN || wt == GB_WIDTH_TYPE::WIDE || wt == GB_WIDTH_TYPE::SUPER)
					{
						listAThinParticles.push_back(pParticle);
					}

					mapAllParticles[pParticle] = GBParticle(pParticle, GB_LEVEL_TYPE::A_TYPE, wt);
				}
				else if (nChemicalType == GB_CHEMICAL_TYPE::CHE_O)
				{
					// C				
					//计算颗粒宽度是属于细系粗系还是超尺寸
					GB_WIDTH_TYPE wt = this->CaculateLevelWidth(pParticle, GB_LEVEL_TYPE::C_TYPE);
					if (wt == GB_WIDTH_TYPE::THIN || wt == GB_WIDTH_TYPE::WIDE || wt == GB_WIDTH_TYPE::SUPER)
					{
						listAThinParticles.push_back(pParticle);
					}
					mapAllParticles[pParticle] = GBParticle(pParticle, GB_LEVEL_TYPE::C_TYPE, wt);
				}
			}
			else//长宽比小于3的颗粒，有3种情况，一种是串条状的B类颗粒，一种是单独的D类颗粒，如果费雷特直径大于13则为DS类颗粒
			{
				// B, or D or DS
				// compute Feret's diameter	
				double dFeretDiameter = pParticle->GetFeretDiameter();
				if (dFeretDiameter >= 13)
				{
					// DS					
					if (pParticle->GetType() != OTS_PARTICLE_TYPE::INVALID)//here we take all the particles 
					{
						listDSParticles.push_back(pParticle);
					}
				}
				else
				{
					// B or D
					GBParticle gbP = GBParticle(pParticle, GB_LEVEL_TYPE::INVALID, GB_WIDTH_TYPE::INVALID);
					//不能确定是B或D，先设为INVALID
					listBAndDParticles.push_back(gbP);

				}
			}
		}
		{
			for (auto pGBParticle : listBAndDParticles)
			{
				// check if the particle is alone			
				auto adjacentPart = find_if(listBAndDParticles.begin(), listBAndDParticles.end(), [pGBParticle](GBParticle pBParticle)
					{
						CRect rectParticle = pGBParticle.myPart->GetParticleRect();
						CPoint ptParticleCenter = rectParticle.CenterPoint();
						int Bottom = rectParticle.BottomRight().y;
						int Top = rectParticle.TopLeft().y;
						CRect rectBCurParticle = pBParticle.myPart->GetParticleRect();
						CPoint ptBParticleCenter = rectBCurParticle.CenterPoint();
						int BottomB = rectBCurParticle.BottomRight().y;
						int TopB = rectBCurParticle.TopLeft().y;

						double dd = 0, ds = 0;
						ds = abs(ptParticleCenter.x - ptBParticleCenter.x);
						if (ds <= 15)//认为两个颗粒在一条竖直线上,但不在一起
						{
							if (Bottom > TopB)//current particle is on the above
							{
								dd = Bottom - TopB;
								if (dd < 40)//认为这两个颗粒在一个串条上
								{
									return true;
								}
							}
							else if (BottomB > Top)	//current particle is on the below
							{
								dd = BottomB - Top;
								if (dd < 40)
								{
									return true;
								}
							}
						}

						return false;
					});
				if (adjacentPart == listBAndDParticles.end())//没找到
				{
					pGBParticle.myType = GB_LEVEL_TYPE::D_TYPE;

					//计算颗粒宽度是属于细系粗系还是超尺寸
					GB_WIDTH_TYPE wt = this->CaculateLevelWidth(pGBParticle.myPart, GB_LEVEL_TYPE::D_TYPE);


					if (wt == GB_WIDTH_TYPE::THIN || wt == GB_WIDTH_TYPE::WIDE || wt == GB_WIDTH_TYPE::SUPER)
					{
						listDThinParticles.push_back(pGBParticle.myPart);
					}
					mapAllParticles[pGBParticle.myPart] = GBParticle(pGBParticle.myPart, GB_LEVEL_TYPE::D_TYPE, wt);
				}
				else//找到了相邻接的颗粒，不是孤立的则为B类
				{
					pGBParticle.myType = GB_LEVEL_TYPE::B_TYPE;//把类型设为有效类型，以便不再找这个颗粒
					adjacentPart->myType = GB_LEVEL_TYPE::B_TYPE;

					//计算颗粒宽度是属于细系粗系还是超尺寸
					GB_WIDTH_TYPE wt = this->CaculateLevelWidth(pGBParticle.myPart, GB_LEVEL_TYPE::B_TYPE);
					if (wt == GB_WIDTH_TYPE::THIN || wt == GB_WIDTH_TYPE::WIDE || wt == GB_WIDTH_TYPE::SUPER)
					{
						listBThinParticles.insert(pGBParticle.myPart);
					}



					mapAllParticles[pGBParticle.myPart] = GBParticle(pGBParticle.myPart, GB_LEVEL_TYPE::B_TYPE, wt);
					wt = this->CaculateLevelWidth(adjacentPart->myPart, GB_LEVEL_TYPE::B_TYPE);

					if (wt == GB_WIDTH_TYPE::THIN || wt == GB_WIDTH_TYPE::WIDE || wt == GB_WIDTH_TYPE::SUPER)
					{
						listBThinParticles.insert(adjacentPart->myPart);
					}

					mapAllParticles[adjacentPart->myPart] = GBParticle(adjacentPart->myPart, GB_LEVEL_TYPE::B_TYPE, wt);

				}

			}

		}
	}

	// caculate Level Width
	BOOL CGBFieldData::CaculateLevelThinWidth(COTSParticleList& a_listParticles, GB_LEVEL_TYPE a_nLevel)
	{
		if (a_listParticles.empty())
		{
			return FALSE;
		}

		double dMin = 2, dMax = 0;

		switch ((int)a_nLevel)
		{
		case (int)GB_LEVEL_TYPE::A_TYPE:
			dMax = 4;
			break;
		case (int)GB_LEVEL_TYPE::B_TYPE:
			dMax = 9;
			break;
		case (int)GB_LEVEL_TYPE::C_TYPE:
			dMax = 5;
			break;
		case (int)GB_LEVEL_TYPE::D_TYPE:
			dMax = 8;
			break;
		}

		BOOL bThin = TRUE;
		for (auto pParticle : a_listParticles)
		{
			CRect rectParticle = pParticle->GetParticleRect();
			double dWidth = (double)rectParticle.Width();

			if (dWidth < dMin || dWidth > dMax)
			{
				bThin = FALSE;
				break;
			}
		}

		return bThin;
	}
	GB_WIDTH_TYPE 	 CGBFieldData::CaculateLevelWidth(COTSParticlePtr Particle, GB_LEVEL_TYPE a_nLevel)
	{

		double dWidth = (double)Particle->GetDMin();
		double dMin = 2, dMax = 0;

		switch ((int)a_nLevel)
		{
		case (int)GB_LEVEL_TYPE::A_TYPE:
			dMax = 4;
			break;
		case (int)GB_LEVEL_TYPE::B_TYPE:
			dMax = 9;
			break;
		case (int)GB_LEVEL_TYPE::C_TYPE:
			dMax = 5;
			break;
		case (int)GB_LEVEL_TYPE::D_TYPE:
			dMax = 8;
			break;
		}

		if (dWidth < dMin)
		{
			return GB_WIDTH_TYPE::INVALID;//小于2um不考虑
		}
		else if (dWidth >= dMin && dWidth < dMax)
		{
			return GB_WIDTH_TYPE::THIN;
		}

		switch ((int)a_nLevel)
		{
		case (int)GB_LEVEL_TYPE::A_TYPE:
			dMin = 4;
			dMax = 12;
			break;
		case (int)GB_LEVEL_TYPE::B_TYPE:
			dMin = 9;
			dMax = 15;
			break;
		case (int)GB_LEVEL_TYPE::C_TYPE:
			dMin = 5;
			dMax = 12;
			break;
		case (int)GB_LEVEL_TYPE::D_TYPE:
			dMin = 8;
			dMax = 13;
			break;
		}
		if (dWidth >= dMin && dWidth < dMax)
		{
			return GB_WIDTH_TYPE::WIDE;
		}
		switch ((int)a_nLevel)
		{
		case (int)GB_LEVEL_TYPE::A_TYPE:
			dMin = 12;
			break;
		case (int)GB_LEVEL_TYPE::B_TYPE:
			dMin = 15;
			break;
		case (int)GB_LEVEL_TYPE::C_TYPE:
			dMin = 12;
			break;
		case (int)GB_LEVEL_TYPE::D_TYPE:
			dMin = 13;
			break;
		}
		if (dWidth >= dMin)
		{
			return GB_WIDTH_TYPE::SUPER;
		}

		return GB_WIDTH_TYPE::INVALID;

	}

	BOOL CGBFieldData::CaculateLevelFatWidth(COTSParticleList& a_listParticles, GB_LEVEL_TYPE a_nLevel)
	{
		if (a_listParticles.empty())
		{
			return FALSE;
		}

		double dMin = 0, dMax = 0;

		switch ((int)a_nLevel)
		{
		case (int)GB_LEVEL_TYPE::A_TYPE:
			dMin = 4;
			dMax = 12;
			break;
		case (int)GB_LEVEL_TYPE::B_TYPE:
			dMin = 9;
			dMax = 15;
			break;
		case (int)GB_LEVEL_TYPE::C_TYPE:
			dMin = 5;
			dMax = 12;
			break;
		case (int)GB_LEVEL_TYPE::D_TYPE:
			dMin = 8;
			dMax = 13;
			break;
		}

		BOOL bFat = TRUE;
		for (auto pParticle : a_listParticles)
		{
			CRect rectParticle = pParticle->GetParticleRect();
			double dWidth = (double)rectParticle.Width();

			if (dWidth < dMin || dWidth > dMax)
			{
				bFat = FALSE;
				break;
			}
		}

		return bFat;
	}

	BOOL CGBFieldData::CaculateSuper(COTSParticleList& a_listParticles, GB_LEVEL_TYPE a_nLevel)
	{
		if (a_listParticles.empty())
		{
			return FALSE;
		}

		double dMin = 0;

		switch ((int)a_nLevel)
		{
		case (int)GB_LEVEL_TYPE::A_TYPE:
			dMin = 12;
			break;
		case (int)GB_LEVEL_TYPE::B_TYPE:
			dMin = 15;
			break;
		case (int)GB_LEVEL_TYPE::C_TYPE:
			dMin = 12;
			break;
		case (int)GB_LEVEL_TYPE::D_TYPE:
			dMin = 13;
			break;
		}

		BOOL bSuper = TRUE;
		for (auto pParticle : a_listParticles)
		{
			CRect rectParticle = pParticle->GetParticleRect();
			double dWidth = (double)rectParticle.Width();

			if (dWidth < dMin)
			{
				bSuper = FALSE;
				break;
			}
		}

		return bSuper;
	}
	BOOL CGBFieldData::IdentifyPartChemicalType(COTSParticlePtr Particle)
	{
		if (Particle->GetXrayInfo() == NULL)
		{
			Particle->SetChemicalType(GB_CHEMICAL_TYPE::INVALID);
			return false;
		}
		auto chamicalList = Particle->GetXrayInfo()->GetElementQuantifyData();

		double dOWeight = 0;
		double dSWeight = 0;
		double dNWeight = 0;
		double dSiWeight = 0;
		double dAlWeight = 0;
		double dMnWeight = 0;
		double dFeWeight = 0;
		double dCWeight = 0;
		



		for (auto pElChem : chamicalList)
		{

			if (pElChem->GetName().CompareNoCase(STR_O) == 0)
			{

				dOWeight = pElChem->GetPercentage();

			}
			else if (pElChem->GetName().CompareNoCase(STR_SUL) == 0)
			{

				dSWeight = pElChem->GetPercentage();

			}
			else if (pElChem->GetName().CompareNoCase(STR_N) == 0)
			{
				dNWeight = pElChem->GetPercentage();
			}
			else if (pElChem->GetName().CompareNoCase(STR_SI) == 0)
			{
				dSiWeight = pElChem->GetPercentage();
			}
			else if (pElChem->GetName().CompareNoCase(STR_Al) == 0)
			{
				dAlWeight = pElChem->GetPercentage();
			}
			else if (pElChem->GetName().CompareNoCase(STR_Mn) == 0)
			{
				dMnWeight = pElChem->GetPercentage();
			}
			else if (pElChem->GetName().CompareNoCase(STR_Fe) == 0)
			{
				dFeWeight = pElChem->GetPercentage();
			}
			else if (pElChem->GetName().CompareNoCase(STR_C) == 0)
			{
				dCWeight = pElChem->GetPercentage();
			}



		}


		if (dSWeight >= MIN_ELEMENT_SUM && dMnWeight > MIN_ELEMENT_SUM)
		{

			Particle->SetChemicalType(GB_CHEMICAL_TYPE::CHE_S);
		

		}
		else if (dSWeight >= MIN_ELEMENT_SUM && dOWeight < MIN_ELEMENT_SUM)//
		{
			Particle->SetChemicalType(GB_CHEMICAL_TYPE::CHE_S);
			
		}
		else if (dOWeight >= MIN_ELEMENT_SUM && dAlWeight >= MIN_ELEMENT_SUM)
		{
			Particle->SetChemicalType(GB_CHEMICAL_TYPE::CHE_Al);
			
		}
		else if (dOWeight >= MIN_ELEMENT_SUM && dSiWeight >= MIN_ELEMENT_SUM)
		{
			Particle->SetChemicalType(GB_CHEMICAL_TYPE::CHE_Si);
		}
		else if (dOWeight >= RICH_ELEMENT_SUM)
		{
			Particle->SetChemicalType(GB_CHEMICAL_TYPE::CHE_O);
		}
		else
		{
			Particle->SetChemicalType(GB_CHEMICAL_TYPE::INVALID);
		}



		return TRUE;



	
	}
}