Chaste  Release::3.4
CryptStatistics.cpp
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35 #include "CryptStatistics.hpp"
36 #include "RandomNumberGenerator.hpp"
37 
42 bool CellsHeightComparison(const std::pair<CellPtr, double> lhs, const std::pair<CellPtr, double> rhs)
43 {
44  return lhs.second < rhs.second;
45 }
46 
48  : AbstractCryptStatistics(rCrypt)
49 {
50 }
51 
52 std::vector<CellPtr> CryptStatistics::GetCryptSection(double yTop, double xBottom, double xTop, bool periodic)
53 {
54  double crypt_width = mrCrypt.rGetMesh().GetWidth(0);
55 
56  // Fill in the default values - in a sequential manner
57  if (xBottom == DBL_MAX)
58  {
59  xBottom = RandomNumberGenerator::Instance()->ranf()*crypt_width;
60  }
61 
62  if (xTop == DBL_MAX)
63  {
64  xTop = RandomNumberGenerator::Instance()->ranf()*crypt_width;
65  }
66 
67  assert(yTop>0.0);
68  std::list<std::pair<CellPtr, double> > cells_list; // the second entry is the y value (needed for sorting)
69 
70  if (fabs(xTop-xBottom)<0.5*crypt_width)
71  {
72  // The periodic version isn't needed, ignore even if periodic was set to true
73  periodic = false;
74  }
75 
76  // Loop over cells and add to the store if they are within a cell's radius of the specified line
78  cell_iter != mrCrypt.End();
79  ++cell_iter)
80  {
81  if (periodic)
82  {
83  if (CellIsInSectionPeriodic(xBottom, xTop, yTop, mrCrypt.GetLocationOfCellCentre(*cell_iter)))
84  {
85  // Set up a pair, equal to (cell,y_val) and insert
86  std::pair<CellPtr, double> pair(*cell_iter, mrCrypt.GetLocationOfCellCentre(*cell_iter)[1]);
87  cells_list.push_back(pair);
88  }
89  }
90  else
91  {
92  if (CellIsInSection(xBottom, xTop, yTop, mrCrypt.GetLocationOfCellCentre(*cell_iter)))
93  {
94  // Set up a pair, equal to (cell,y_val) and insert
95  std::pair<CellPtr, double> pair(*cell_iter, mrCrypt.GetLocationOfCellCentre(*cell_iter)[1]);
96  cells_list.push_back(pair);
97  }
98  }
99  }
100 
101  // Sort the list
102  cells_list.sort(CellsHeightComparison);
103 
104  // Copy to a vector
105  std::vector<CellPtr> ordered_cells;
106  for (std::list<std::pair<CellPtr, double> >::iterator iter = cells_list.begin();
107  iter!=cells_list.end();
108  ++iter)
109  {
110  ordered_cells.push_back(iter->first);
111  }
112 
113  return ordered_cells;
114 }
115 
116 std::vector<CellPtr> CryptStatistics::GetCryptSectionPeriodic(double yTop, double xBottom, double xTop)
117 {
118  return GetCryptSection(yTop, xBottom, xTop, true);
119 }
120 bool CryptStatistics::CellIsInSection(double xBottom, double xTop, double yTop, const c_vector<double,2>& rCellPosition, double widthOfSection)
121 {
122  c_vector<double,2> intercept;
123 
124  if (xBottom == xTop)
125  {
126  intercept[0] = xTop;
127  intercept[1] = rCellPosition[1];
128  }
129  else
130  {
131  double m = (yTop)/(xTop-xBottom); // gradient of line
132 
133  intercept[0] = (m*m*xBottom + rCellPosition[0] + m*rCellPosition[1])/(1+m*m);
134  intercept[1] = m*(intercept[0] - xBottom);
135  }
136 
137  c_vector<double,2> vec_from_A_to_B = mrCrypt.rGetMesh().GetVectorFromAtoB(intercept, rCellPosition);
138  double dist = norm_2(vec_from_A_to_B);
139 
140  return (dist <= widthOfSection);
141 }
142 
143 bool CryptStatistics::CellIsInSectionPeriodic(double xBottom, double xTop, double yTop, const c_vector<double,2>& rCellPosition, double widthOfSection)
144 {
145  bool is_in_section = false;
146 
147  c_vector<double,2> intercept;
148  double crypt_width = mrCrypt.rGetMesh().GetWidth(0u);
149 
150  double m; // gradient of line
151  double offset;
152 
153  if (xBottom < xTop)
154  {
155  offset = -crypt_width;
156  }
157  else
158  {
159  offset = crypt_width;
160  }
161 
162  m = (yTop)/(xTop-xBottom+offset); // gradient of line
163 
164  // 1st line
165  intercept[0] = (m*m*xBottom + rCellPosition[0] + m*rCellPosition[1])/(1+m*m);
166  intercept[1] = m*(intercept[0] - xBottom);
167 
168  c_vector<double,2> vec_from_A_to_B = mrCrypt.rGetMesh().GetVectorFromAtoB(intercept, rCellPosition);
169  double dist = norm_2(vec_from_A_to_B);
170 
171  if (dist < widthOfSection)
172  {
173  is_in_section = true;
174  }
175 
176  // 2nd line
177  intercept[0] = (m*m*(xBottom-offset) + rCellPosition[0] + m*rCellPosition[1])/(1+m*m);
178  intercept[1] = m*(intercept[0] - (xBottom-offset));
179 
180  vec_from_A_to_B = mrCrypt.rGetMesh().GetVectorFromAtoB(intercept, rCellPosition);
181  dist = norm_2(vec_from_A_to_B);
182 
183  if (dist < widthOfSection)
184  {
185  is_in_section = true;
186  }
187 
188  return is_in_section;
189 }
bool CellIsInSectionPeriodic(double xBottom, double xTop, double yTop, const c_vector< double, 2 > &rCellPosition, double widthOfSection=1.0)
MutableMesh< ELEMENT_DIM, SPACE_DIM > & rGetMesh()
std::vector< CellPtr > GetCryptSection(double yTop, double xBottom=DBL_MAX, double xTop=DBL_MAX, bool periodic=false)
MeshBasedCellPopulation< 2 > & mrCrypt
static RandomNumberGenerator * Instance()
CryptStatistics(MeshBasedCellPopulation< 2 > &rCrypt)
virtual double GetWidth(const unsigned &rDimension) const
virtual c_vector< double, SPACE_DIM > GetVectorFromAtoB(const c_vector< double, SPACE_DIM > &rLocationA, const c_vector< double, SPACE_DIM > &rLocationB)
c_vector< double, SPACE_DIM > GetLocationOfCellCentre(CellPtr pCell)
std::vector< CellPtr > GetCryptSectionPeriodic(double yTop, double xBottom=DBL_MAX, double xTop=DBL_MAX)
bool CellIsInSection(double xBottom, double xTop, double yTop, const c_vector< double, 2 > &rCellPosition, double widthOfSection=0.5)