415 lines
10 KiB
Text
Executable file
415 lines
10 KiB
Text
Executable file
/** @file
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* @brief GPU-ICP Algorithm
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* @author Deyuan Qiu, University of Applied Sciences Bonn-Rhein-Sieg, Sankt Augustin, Germany.
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* Fraunhofer IAIS, Sankt Augustin, Germany.
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*/
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#ifndef CICPGPUCUDA_H
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#define CICPGPUCUDA_H
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#include <cstdlib> // C standard library
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#include <cstdio> // C I/O (for sscanf)
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#include <cstring> // string manipulation
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#include <fstream> // file I/O
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#include <algorithm> // min()
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#include <time.h>
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#include "ANN/ANN.h" // ANN declarations
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#include "ANN/ANNperf.h" // kd-tree printing
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#include "kd_tree.h" // ANN node declaration
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#include "newmat/newmat.h"
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#include "newmat/newmatap.h"
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using namespace NEWMAT;
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#include "slam6d/cuda/CSystem.h"
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/*
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* The maximum block size. For nVidia G80 architecture, 192 is suggested.
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*/
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//#define BLOCKSIZE 512
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//#define BLOCKSIZE 256
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#define BLOCKSIZE 64
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//#define BLOCKSIZE 1
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/*
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* The big enough size of the AoS that is going to allocate for the kd-tree.
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*/
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//#define TREESIZE 262143
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#define TREESIZE 524288
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#ifdef use_namespace
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using namespace std;
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#endif
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/*
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* @class CIcpGpuCuda
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* @brief Iterative Closest Point algorithm is implemented on a programmable graphic
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* device. Kernels are implemented by CUDA (Compute Unified Device Architecture) GPGPU
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* programming language (http://www.nvidia.com/object/cuda_home.html). To compile the code,
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* nvcc compiler and related CUDA libraries must be installed. Kernel files are wrapped in
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* CIcpGpuCuda_kernel.cuh and CIcpGpuCuda.cu. Attention: only NVidia GeForce G80 architecture
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* and onwards graphic devices are garanteed to be supported.
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* @author Deyuan Qiu
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* @date 2008.Nov.
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*/
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class CIcpGpuCuda{
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public:
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/*
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* standard constructor
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* @param argc passed from application main function.
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* @param argv passed from application main function.
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* @param unWidth the width of point cloud image.
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* @param unHeight the height of pint cloud image.
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*/
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CIcpGpuCuda(unsigned unWidth, unsigned unHeight, unsigned max_iter){
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init(unWidth, unHeight,max_iter);
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}
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/*
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* standard destructor
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*/
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~CIcpGpuCuda();
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/*
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* Set maximum iteration for ICP.
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* @param unTimes number of times ICP iterates maximally.
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*/
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void setMaxIteration(unsigned unTimes);
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/*
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* Set maximum processing time for ICP, in milliseconds.
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* @param dMilliseconds ICP quits when elapsed time exceeds.
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*/
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void setMaxProcTime(double dMilliseconds);
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/*
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* Set maximum deviation for ICP.
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* @param dDeviation ICP quits when specified deviation is achieved.
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*/
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void setMaxDeviation(double dDeviation);
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/*
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* Set search radiuses for ICP. An iterative decreasing radius
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* is applied. Search radius decreases linearly from fRadiusMax to
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* fRadiusMin within unIterations iterations.
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* @param fRadiusMax Initial radius.
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* @param fRadiusMin Final radius.
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* @param unIterations Number of iterations, in which radius decreases.
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*/
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void setSearchRadius(float fRadiusMax, float fRadiusMin, unsigned unIterations);
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/*
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* Get the number of points in point cloud. Model point cloud
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* and scene point cloud must have the same number of points.
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* @return Number of points in point cloud.
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*/
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unsigned getSize(void);
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/*
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* Get the the 2 dimensional pointer to the scene point cloud. Page-lock memory is
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* allocated and freed by the class. The data type must be casted to single pricision
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* float, and the array should be loaded as [3][N].
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* @return 2 dimensional pointer to scene point cloud.
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*/
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float** getScenePointer(void);
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/*
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* Get the the 2 dimensional pointer to the model point cloud. Memory allocation
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* and freeing is handled by the class. The data type must be casted to double pricision
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* float, and the array should be loaded as [N][3]. Notice the difference to
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* getScenePointer().
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* @return 2 dimensional pointer to scene point cloud.
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*/
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double** getModelPointer(void);
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/*
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* The method is called after point clouds are loaded, and before iteration() is called.
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*/
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void setPointClouds(void);
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/*
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* ICP iterations.
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*/
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void iteration(void);
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/*
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* Get the transformation matrix.
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* @return The transformation matrix.
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*/
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Matrix* getMatrix(void);
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/**
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* These two functions are to set and get the tree pointer
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* It is supposed to be created in scan file and passed to this class
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**/
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void setTreePointer(ANNkd_tree *);
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void getTreePointer(ANNkd_tree *&);
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double getTime(void);
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void setMinimums(float x, float y, float z);
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Matrix** getMatrices();
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void setTrans_Trans_inv(const double[], const double[]);
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void findNearestNeighbors(float, unsigned);
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Matrix fillHomoMatrix(Matrix* , double*);
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void computeCentroid(float*, float*, float*, float *&);
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Matrix computeHMatrix();
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void printMatrix(Matrix *);
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void setSize(unsigned int width, unsigned int height);
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private:
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////////////////
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//cpu variables
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////////////////
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/*
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* Initialization. Memories are allocated and default environmental state
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* is set. Called by standard constructor.
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* @param unWidth the width of point cloud image.
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* @param unHeight the height of pint cloud image.
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*/
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void init(unsigned unWidth, unsigned unHeight, unsigned max_iter);
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/*
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* Initialization. Memories are allocated and default environmental state
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* is set. Called by init().
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* @param unWidth the width of point cloud image.
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* @param unHeight the height of pint cloud image.
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*/
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void setResolution(unsigned unWidth, unsigned unHeight);
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/*
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* The internal search structure is set.
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*/
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void setTree(void);
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/*
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* Set the model point cloud.
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*/
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void setModel(void);
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/*
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* Set the scene point cloud.
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*/
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void setScene(void);
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/*
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* Calculate the size of the search structure from its depth. The depth
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* is the number of levels of the tree. The search structure then is arraged
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* into a struture of arrays (SoA). A left-balanced binary tree is suggested.
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* @param nDepth Depth of the kd-tree.
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*/
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inline int depth2size(int nDepth);
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/*
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* Rearrange the search structure into a structure of arrays (SoA). The rule
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* is: the N node's left child has the index of 2N, while the right child 2N+1.
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* Arrangement is fulfilled in recursion.
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* @param root pointer to the root node
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* @param unStart the currenet node
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*/
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void rearrange(ANNkd_ptr root, unsigned unStart);
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/*
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* Get CUBLAS errors before this line.
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*/
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void getCublasErr(void);
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/*
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* Get CUDA errors before this line.
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*/
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void getCudaErr(void);
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/*
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* tree: structure of arrays (SoA)
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*/
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unsigned _unSizeTree; //Size of the allocated memory.
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float* fSplit;
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unsigned* unIdx;
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unsigned* unAxis;
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bool* bIsLeaf;
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float* fLoBound;
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float* fHiBound;
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unsigned unSizeTree; //Size of memory that the tree actually takes.
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/*
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* transformation matrix
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*/
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float m[16];
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Matrix* trans;
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Matrix* trans_inv;
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/*
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* kernel constants
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*/
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unsigned unSizeData;
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unsigned unNoThreads;
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unsigned unNoBlocks;
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unsigned _unWidth;
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unsigned _unHeight;
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/*
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* search structure
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*/
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ANNkd_tree* kdTree;
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ANNkdStats* st;
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/*
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* data pointers
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*/
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float* fHstScn[3];
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float* fHstScnX;
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float* fHstScnY;
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float* fHstScnZ;
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double** h_idata;
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/*
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* icp
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*/
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unsigned unMaxIteration;
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unsigned _unIterations;
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float fMaxProcTime;
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float fMaxDeviation;
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float _fSearchRadiusMax;
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float _fSearchRadiusMin;
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float _fRadiusStep;
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unsigned _unNoQSizeStep;
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float* temp_ones;
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float* ones;
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enum EnumIcpState { ICP_LIMIT = 0,
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ICP_PROCESSING = 1,
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ICP_NOTMATCHABLE = 2,
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ICP_MAXITERATIONS = 3,
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ICP_TIMEELAPSED = 4,
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ICP_SUCCESS = 5 };
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unsigned unPairs;
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unsigned* pNoPairs;
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Matrix* final_matrix;
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double _dElapsedTime;
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Matrix** matrices;
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/*
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Minimums of all values
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*/
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float min_x;
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float min_y;
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float min_z;
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clock_t init_time; // To save the starting point of the timer Added by Shams
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////////////////
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//gpu variables
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////////////////
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float* fDevSplit;
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unsigned* unDevIdx;
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unsigned* unDevAxis;
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bool* bDevIsLeaf;
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float* fDevLoBound;
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float* fDevHiBound;
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float* fDevScnX;
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float* fDevScnY;
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float* fDevScnZ;
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float* fDist;
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float* fDistCpt; //compacted distance list
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unsigned* unMask;
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float* fDevMdlPairX;
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float* fDevMdlPairY;
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float* fDevMdlPairZ;
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float* fDevScnPairX;
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float* fDevScnPairY;
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float* fDevScnPairZ;
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/////////////
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float* cngfDevScnX;
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float* cngfDevScnY;
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float* cngfDevScnZ;
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float* cngfDevMdlPairX;
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float* cngfDevMdlPairY;
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float* cngfDevMdlPairZ;
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float* cngfDevScnPairX;
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float* cngfDevScnPairY;
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float* cngfDevScnPairZ;
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/////////////
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float* fCenModX;
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float* fCenModY;
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float* fCenModZ;
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float* fCenScnX;
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float* fCenScnY;
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float* fCenScnZ;
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unsigned* unNoPairs;
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//kd-tree based nearest neighbor search, using a priority queue.
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void class_nns_priority(
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float* fDevScnX, //scene point cloud
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float* fDevScnY,
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float* fDevScnZ,
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float* fDist, //squared distance between pairs, for deviation calculation
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float* fDevSplit, //kd-tree: position of splitting plain (inner node)
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unsigned* unDevIdx, //kd-tree: index of point (leaf node)
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unsigned* unDevAxis, //kd-tree: axis where splitting plain locates (inner node)
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bool* bDevIsLeaf, //kd-tree: node type (both nodes)
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float* fDevLoBound, //kd-tree: lower bounding box (inner node)
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float* fDevHiBound, //kd-tree: higher bounding box (inner node)
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unsigned* unMask, //a 0-1 mask of pair and non-pairs.
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float* fDevMdlPairX,
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float* fDevMdlPairY,
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float* fDevMdlPairZ,
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float* fDevScnPairX,
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float* fDevScnPairY,
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float* fDevScnPairZ,
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float fSearchRadius,
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unsigned unSize,
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unsigned unWidth,
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unsigned unQStep); //for dubugging thread
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//centralize a pointcloud
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void class_centralize(unsigned* unMask,
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float* fDevMdlPairX,
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float* fDevMdlPairY,
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float* fDevMdlPairZ,
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float* fDevScnPairX,
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float* fDevScnPairY,
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float* fDevScnPairZ,
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float fcm0,
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float fcm1,
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float fcm2,
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float fcs0,
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float fcs1,
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float fcs2,
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float* fCenteredModX, //centered point cloud
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float* fCenteredModY,
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float* fCenteredModZ,
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float* fCenteredScnX,
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float* fCenteredScnY,
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float* fCenteredScnZ);
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//transform point cloud
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void class_transformation(float* fDevScnX, //piont cloud to be transformed
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float* fDevScnY,
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float* fDevScnZ,
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float m00, float m01, float m02, float m03,
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float m10, float m11, float m12, float m13,
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float m20, float m21, float m22, float m23);
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};
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#endif
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