- Timestamp:
- 03/15/14 02:30:20 (11 years ago)
- Location:
- cpp/frams/genetics/fF
- Files:
-
- 7 edited
Legend:
- Unmodified
- Added
- Removed
-
cpp/frams/genetics/fF/conv_fF.cpp
r174 r176 8 8 #include <common/nonstd_stl.h> 9 9 10 GenoConv_fF0::GenoConv_fF0() { 11 name = "7-value Foraminifera encoding"; 12 in_format = 'F'; 13 out_format = '0'; 14 mapsupport = 0; 15 cosines = new double[LATITUDE_NUM]; 16 sines = new double[LATITUDE_NUM]; 17 fill_cos_and_sin(); 18 } 19 20 GenoConv_fF0::~GenoConv_fF0() { 21 delete []cosines; 22 delete []sines; 23 } 24 25 SString GenoConv_fF0::convert(SString &in, MultiMap *map) { 26 fF_growth_params gp; 27 if (!gp.load(in)) //invalid input genotype? 28 return ""; //so we return an invalid f0 genotype 29 30 double div_radius_length = 1;//div_radius_lenght=1 or kx=ky=kz=1 31 double radius = 1; 32 33 Model m; 34 m.open(); 35 // subsequent parts (chambers) are placed relative to the previous part's orientation and location 36 Part *p1, *p2; 37 38 fF_chamber3d **chambers = new fF_chamber3d*[gp.number_of_chambers]; 39 40 for (int i = 0; i < gp.number_of_chambers; i++) { 41 createSphere(i, chambers, radius, div_radius_length, gp.translation, gp.angle1, gp.angle2, gp.scalex, gp.scaley, gp.scalez); 42 } 43 44 p1 = m.addNewPart(Part::SHAPE_ELLIPSOID); 45 p1->p = Pt3D(chambers[0]->centerX, chambers[0]->centerY, chambers[0]->centerZ); 46 47 48 for (int i = 1; i < gp.number_of_chambers; i++, p1 = p2) { 49 p2 = m.addNewPart(Part::SHAPE_ELLIPSOID); 50 p2->scale = p1->scale.entrywiseProduct(Pt3D(gp.scalex, gp.scaley, gp.scalez)); //each part's scale is its predecessor's scale * scaling 51 52 p2->p = Pt3D(chambers[i]->centerX, chambers[i]->centerY, chambers[i]->centerZ); 53 54 m.addNewJoint(p1, p2, Joint::SHAPE_SOLID); //all parts must be connected 55 } 56 57 for (int i = 0; i < gp.number_of_chambers; i++) 58 delete chambers[i]; 59 delete []chambers; 60 61 m.close(); 62 return m.getF0Geno().getGene(); 10 GenoConv_fF0::GenoConv_fF0() 11 { 12 name = "7-value Foraminifera encoding"; 13 in_format = 'F'; 14 out_format = '0'; 15 mapsupport = 0; 16 cosines = new double[fF_LATITUDE_NUM]; 17 sines = new double[fF_LATITUDE_NUM]; 18 fill_cos_and_sin(); 19 } 20 21 GenoConv_fF0::~GenoConv_fF0() 22 { 23 delete[] cosines; 24 delete[] sines; 25 } 26 27 SString GenoConv_fF0::convert(SString &in, MultiMap *map) 28 { 29 fF_growth_params gp; 30 if (!gp.load(in)) //invalid input genotype? 31 return ""; //so we return an invalid f0 genotype 32 33 double div_radius_length = 1;//div_radius_length=1 or kx=ky=kz=1 34 double radius = 1; 35 36 Model m; 37 m.open(); 38 // subsequent parts (chambers) are placed relative to the previous part's orientation and location 39 Part *p1, *p2; 40 41 fF_chamber3d **chambers = new fF_chamber3d*[gp.number_of_chambers]; 42 43 for (int i = 0; i < gp.number_of_chambers; i++) { 44 createSphere(i, chambers, radius, div_radius_length, gp.translation, gp.angle1, gp.angle2, gp.scalex, gp.scaley, gp.scalez); 45 } 46 47 p1 = m.addNewPart(Part::SHAPE_ELLIPSOID); 48 p1->p = Pt3D(chambers[0]->centerX, chambers[0]->centerY, chambers[0]->centerZ); 49 50 51 for (int i = 1; i < gp.number_of_chambers; i++, p1 = p2) { 52 p2 = m.addNewPart(Part::SHAPE_ELLIPSOID); 53 p2->scale = p1->scale.entrywiseProduct(Pt3D(gp.scalex, gp.scaley, gp.scalez)); //each part's scale is its predecessor's scale * scaling 54 55 p2->p = Pt3D(chambers[i]->centerX, chambers[i]->centerY, chambers[i]->centerZ); 56 57 m.addNewJoint(p1, p2, Joint::SHAPE_SOLID); //all parts must be connected 58 } 59 60 for (int i = 0; i < gp.number_of_chambers; i++) 61 delete chambers[i]; 62 delete[]chambers; 63 64 m.close(); 65 return m.getF0Geno().getGene(); 63 66 } 64 67 65 68 void GenoConv_fF0::createSphere(int which, fF_chamber3d **chambers, double radius_, double div_radius_length_, double div_vector_length_, 66 double alpha_, double gamma_, double kx_, double ky_, double kz_) 67 { 68 chambers[which]=new fF_chamber3d(0.0f, 0.0f, 0.0f, 69 (float) radius_, (float) radius_ * (float) kx_, 0.0f, 0.0f, 70 (float) (radius_ * div_vector_length_), 0.0f, 0.0f, 0.0f, 0.0f); 71 if (which == 0) 72 chambers[which]->points = generate_points(chambers[which], which, kx_, ky_, kz_); 73 if (which > 0) { 74 /* old radius */ 75 double radiusOld, radius; 76 radiusOld = chambers[which - 1]->radius; 77 radius = div_radius_length_ * radiusOld; 78 /* new growth vector length */ 79 double len = radius * div_vector_length_; 80 if (radius < TOO_LITTLE) { 81 radius = TOO_LITTLE; 82 if (fabs(len) > (TOO_MUCH * radius)) { 83 len = ((len < 0) ? (-1) : 1) * TOO_MUCH * radius; 84 } 85 } 86 if (len == 0) { 87 len = -0.0000001; 88 } 89 90 /* aperture of the previous chamber */ 91 double pzx = chambers[which - 1]->holeX; 92 double pzy = chambers[which - 1]->holeY; 93 double pzz = chambers[which - 1]->holeZ; 94 95 //center of the previous chamber 96 double pcx = chambers[which - 1]->centerX; 97 double pcy = chambers[which - 1]->centerY; 98 double pcz = chambers[which - 1]->centerZ; 99 100 /* aperture of the next to last chamber */ 101 double ppx; 102 double ppy; 103 double ppz; 104 105 if (which == 1) { 106 ppx = pcx; 107 ppy = pcy; 108 ppz = pcz; 109 } else { 110 ppx = chambers[which - 2]->holeX; 111 ppy = chambers[which - 2]->holeY; 112 ppz = chambers[which - 2]->holeZ; 113 } 114 115 double pzxprim = pzx - ppx; 116 double pzyprim = pzy - ppy; 117 double angle; 118 119 angle = atan2(pzyprim, pzxprim); 120 double alpha = angle - alpha_; 121 122 123 double gamma = chambers[which - 1]->phi + gamma_; 124 125 /* x */ 126 double wx = len * cos(alpha); 127 /* y */ 128 double wy = len * sin(alpha); 129 /* y */ 130 double wz = len * sin(alpha) * sin(gamma); 131 132 /*center of the new sphere*/ 133 double x = pzx + wx; 134 double y = pzy + wy; 135 double z = pzz + wz; 136 137 chambers[which]->centerX = (float) x; 138 chambers[which]->centerY = (float) y; 139 chambers[which]->centerZ = (float) z; 140 chambers[which]->radius= (float) radius; 141 chambers[which]->vectorTfX = (float) wx; 142 chambers[which]->vectorTfY = (float) wy; 143 chambers[which]->vectorTfZ = (float) wz; 144 chambers[which]->beta = (float) alpha; 145 chambers[which]->phi = (float) gamma; 146 147 chambers[which]->points = generate_points(chambers[which], which, kx_, ky_, kz_); 148 search_hid(which, chambers, kx_, ky_, kz_); 149 int pun; 150 pun = find_hole(which, pzx, pzy, pzz, chambers, kx_, ky_, kz_); 151 152 chambers[which]->holeX = (float) chambers[which]->points[pun][0]; 153 chambers[which]->holeY = (float) chambers[which]->points[pun][1]; 154 chambers[which]->holeZ = (float) chambers[which]->points[pun][2]; 155 } 156 } 157 158 void GenoConv_fF0::fill_cos_and_sin() { 159 int i; 160 double pi = acos(-1.0); 161 double angle = pi / (((double) LATITUDE_NUM)*0.5); 162 for (i = 0; i < LATITUDE_NUM; i++) { 163 cosines[i] = cos((double) i * angle); 164 sines[i] = sin((double) i * angle); 165 } 166 } 167 168 double** GenoConv_fF0::generate_points(fF_chamber3d *chamber, int which, double kx_, double ky_, double kz_) { 169 float radius = chamber->radius; 170 float cenx = chamber->centerX; 171 float ceny = chamber->centerY; 172 float cenz = chamber->centerZ; 173 174 double maxX = 0; 175 double maxY = 0; 176 double minX = 0; 177 double minY = 0; 178 double minZ = 0; 179 180 double kx = 1; 181 double ky = 1; 182 double kz = 1; 183 184 if (which > 0) { 185 for (int kt = 1; kt < (which + 1); kt++) { 186 kx = kx * kx_; 187 ky = ky * ky_; 188 kz = kz * kz_; 189 } 190 } 191 192 int i, j; 193 double x, y, z; 194 195 double **points = new double*[SIZE]; 196 for (int i = 0; i < SIZE; i++) { 197 points[i] = new double[4]; 198 } 199 200 for (i = 0; i < LONGITUDE_NUM; i++) { 201 if (kx_ == 1 && ky_ == 1 && kz_ == 1) { 202 y = ceny + radius * cosines[i]; 203 } 204 else { 205 y = ceny + ky * cosines[i]; 206 } 207 for (j = 0; j < LATITUDE_NUM; j++) { 208 if (kx_ == 1 && ky_ == 1 && kz_ == 1) { 209 points[(i * LATITUDE_NUM) + j][0] = x = cenx + radius * cosines[j] * sines[i]; 210 points[(i * LATITUDE_NUM) + j][1] = y; 211 points[(i * LATITUDE_NUM) + j][2] = z = cenz + radius * sines[j] * sines[i]; 212 } else { 213 points[(i * LATITUDE_NUM) + j][0] = x = cenx + kx * cosines[j] * sines[i]; 214 points[(i * LATITUDE_NUM) + j][1] = y; 215 points[(i * LATITUDE_NUM) + j][2] = z = cenz + kz * sines[j] * sines[i]; 216 } 217 218 points[(i * LATITUDE_NUM) + j][3] = 1.0; 219 if (x < minX) minX = x; 220 if (x > maxX) maxX = x; 221 if (y < minY) minY = y; 222 if (y > maxY) maxY = y; 223 224 if (z < minZ) minZ = z; 225 }; 226 }; 227 return points; 228 229 } 230 231 double GenoConv_fF0::dist(double x1, double y1, double z1, double x2, double y2, double z2) { 232 return sqrt((x2 - x1)*(x2 - x1) + (y2 - y1)*(y2 - y1) + (z2 - z1)*(z2 - z1)); 233 } 234 235 void GenoConv_fF0::search_hid(int nr, fF_chamber3d **spheres, double kx_, double ky_, double kz_) { 236 237 int i, j; 238 if (nr != 0) { 239 for (i = 0; i < nr; i++) { 240 for (j = 0; j < AMOUNT; j++) { 241 double X = spheres[nr]->points[j][0]; 242 double Y = spheres[nr]->points[j][1]; 243 double Z = spheres[nr]->points[j][2]; 244 245 double srX0 = spheres[i]->centerX; 246 double srY0 = spheres[i]->centerY; 247 double srZ0 = spheres[i]->centerZ; 248 249 double a2; 250 double b2; 251 double c2; 252 253 if (kx_ != 1) { 254 a2 = (kx_ * kx_); 255 } else { 256 a2 = (spheres[i]->radius * spheres[i]->radius); 257 } 258 259 if (ky_ != 1) { 260 b2 = (ky_ * ky_); 261 262 } else { 263 b2 = (spheres[i]->radius * spheres[i]->radius); 264 } 265 266 c2 = (kz_ * spheres[i]->radius) * (kz_ * spheres[i]->radius); 267 268 double up1 = (X - srX0) * (X - srX0); 269 double up2 = (Y - srY0) * (Y - srY0); 270 double up3 = (Z - srZ0) * (Z - srZ0); 271 272 double exp = up1 / a2; 273 double exp2 = up2 / b2; 274 double exp3 = up3 / c2; 275 276 double result = exp + exp2 + exp3; 277 278 if (result < (THICK_RATIO) 279 ) { 280 spheres[nr]->points[j][3] = 0; 281 } 282 } 283 } 284 } 285 } 286 287 int GenoConv_fF0::find_hole(int which, double x, double y, double z, fF_chamber3d **chambers, double kx_, double ky_, double kz_) { 288 int i; 289 double distance; 290 int found = 0; 291 double dist_found = 0; 292 int first = 1; 293 294 for (i = 0; i < AMOUNT; i++) { 295 if (chambers[which]->points[i][3] != 0) //nie jest wewnatrz inne komory 296 { 297 distance = sqrt((chambers[which]->points[i][0] - x)*(chambers[which]->points[i][0] - x) + 298 (chambers[which]->points[i][1] - y)*(chambers[which]->points[i][1] - y)+ 299 (chambers[which]->points[i][2] - z)*(chambers[which]->points[i][2] - z)); 300 if (first != 0) { 301 found = i; 302 dist_found = distance; 303 first = 0; 304 }; 305 if (distance < dist_found) { 306 if (which != 0) { 307 bool good = true; 308 for (int j = 0; j < which; j++) { 309 { 310 double X = chambers[which]->points[i][0]; 311 double Y = chambers[which]->points[i][1]; 312 double Z = chambers[which]->points[i][2]; 313 314 double srX0 = chambers[j]->centerX; 315 double srY0 = chambers[j]->centerY; 316 double srZ0 = chambers[j]->centerZ; 317 318 double a2 = (kx_ * chambers[j]->radius) * (kx_ * chambers[j]->radius); 319 double b2 = (ky_ * chambers[j]->radius) * (ky_ * chambers[j]->radius); 320 double c2 = (kz_ * chambers[j]->radius) * (kz_ * chambers[j]->radius); 321 322 double up1 = (X - srX0) * (X - srX0); 323 double up2 = (Y - srY0) * (Y - srY0); 324 double up3 = (Z - srZ0) * (Z - srZ0); 325 326 double exp1 = up1 / a2; 327 double exp2 = up2 / b2; 328 double exp3 = up3 / c2; 329 330 double result = exp1 + exp2 + exp3; 331 if (result < 1.0) 332 { 333 good = false; 334 } 335 } 336 } 337 if (good) { 338 found = i; 339 dist_found = distance; 340 } 341 } 342 }; 343 }; 344 }; 345 346 return (found); 347 } 69 double alpha_, double gamma_, double kx_, double ky_, double kz_) 70 { 71 chambers[which] = new fF_chamber3d(0.0f, 0.0f, 0.0f, 72 (float)radius_, (float)radius_ * (float)kx_, 0.0f, 0.0f, 73 (float)(radius_ * div_vector_length_), 0.0f, 0.0f, 0.0f, 0.0f); 74 if (which == 0) 75 chambers[which]->points = generate_points(chambers[which], which, kx_, ky_, kz_); 76 if (which > 0) { 77 /* old radius */ 78 double radiusOld, radius; 79 radiusOld = chambers[which - 1]->radius; 80 radius = div_radius_length_ * radiusOld; 81 /* new growth vector length */ 82 double len = radius * div_vector_length_; 83 if (radius < fF_TOO_LITTLE) { 84 radius = fF_TOO_LITTLE; 85 if (fabs(len) >(fF_TOO_MUCH * radius)) { 86 len = ((len < 0) ? (-1) : 1) * fF_TOO_MUCH * radius; 87 } 88 } 89 if (len == 0) { 90 len = -0.0000001; 91 } 92 93 /* aperture of the previous chamber */ 94 double pzx = chambers[which - 1]->holeX; 95 double pzy = chambers[which - 1]->holeY; 96 double pzz = chambers[which - 1]->holeZ; 97 98 //center of the previous chamber 99 double pcx = chambers[which - 1]->centerX; 100 double pcy = chambers[which - 1]->centerY; 101 double pcz = chambers[which - 1]->centerZ; 102 103 /* aperture of the next to last chamber */ 104 double ppx; 105 double ppy; 106 double ppz; 107 108 if (which == 1) { 109 ppx = pcx; 110 ppy = pcy; 111 ppz = pcz; 112 } 113 else { 114 ppx = chambers[which - 2]->holeX; 115 ppy = chambers[which - 2]->holeY; 116 ppz = chambers[which - 2]->holeZ; 117 } 118 119 double pzxprim = pzx - ppx; 120 double pzyprim = pzy - ppy; 121 double angle; 122 123 angle = atan2(pzyprim, pzxprim); 124 double alpha = angle - alpha_; 125 126 127 double gamma = chambers[which - 1]->phi + gamma_; 128 129 /* x */ 130 double wx = len * cos(alpha); 131 /* y */ 132 double wy = len * sin(alpha); 133 /* y */ 134 double wz = len * sin(alpha) * sin(gamma); 135 136 /*center of the new sphere*/ 137 double x = pzx + wx; 138 double y = pzy + wy; 139 double z = pzz + wz; 140 141 chambers[which]->centerX = (float)x; 142 chambers[which]->centerY = (float)y; 143 chambers[which]->centerZ = (float)z; 144 chambers[which]->radius = (float)radius; 145 chambers[which]->vectorTfX = (float)wx; 146 chambers[which]->vectorTfY = (float)wy; 147 chambers[which]->vectorTfZ = (float)wz; 148 chambers[which]->beta = (float)alpha; 149 chambers[which]->phi = (float)gamma; 150 151 chambers[which]->points = generate_points(chambers[which], which, kx_, ky_, kz_); 152 search_hid(which, chambers, kx_, ky_, kz_); 153 int pun; 154 pun = find_hole(which, pzx, pzy, pzz, chambers, kx_, ky_, kz_); 155 156 chambers[which]->holeX = (float)chambers[which]->points[pun][0]; 157 chambers[which]->holeY = (float)chambers[which]->points[pun][1]; 158 chambers[which]->holeZ = (float)chambers[which]->points[pun][2]; 159 } 160 } 161 162 void GenoConv_fF0::fill_cos_and_sin() 163 { 164 int i; 165 double pi = acos(-1.0); 166 double angle = pi / (((double)fF_LATITUDE_NUM)*0.5); 167 for (i = 0; i < fF_LATITUDE_NUM; i++) 168 { 169 cosines[i] = cos((double)i * angle); 170 sines[i] = sin((double)i * angle); 171 } 172 } 173 174 double** GenoConv_fF0::generate_points(fF_chamber3d *chamber, int which, double kx_, double ky_, double kz_) 175 { 176 float radius = chamber->radius; 177 float cenx = chamber->centerX; 178 float ceny = chamber->centerY; 179 float cenz = chamber->centerZ; 180 181 double maxX = 0; 182 double maxY = 0; 183 double minX = 0; 184 double minY = 0; 185 double minZ = 0; 186 187 double kx = 1; 188 double ky = 1; 189 double kz = 1; 190 191 if (which > 0) { 192 for (int kt = 1; kt < (which + 1); kt++) { 193 kx = kx * kx_; 194 ky = ky * ky_; 195 kz = kz * kz_; 196 } 197 } 198 199 int i, j; 200 double x, y, z; 201 202 double **points = new double*[fF_SIZE]; 203 for (int i = 0; i < fF_SIZE; i++) { 204 points[i] = new double[4]; 205 } 206 207 for (i = 0; i < fF_LONGITUDE_NUM; i++) { 208 if (kx_ == 1 && ky_ == 1 && kz_ == 1) { 209 y = ceny + radius * cosines[i]; 210 } 211 else { 212 y = ceny + ky * cosines[i]; 213 } 214 for (j = 0; j < fF_LATITUDE_NUM; j++) { 215 if (kx_ == 1 && ky_ == 1 && kz_ == 1) { 216 points[(i * fF_LATITUDE_NUM) + j][0] = x = cenx + radius * cosines[j] * sines[i]; 217 points[(i * fF_LATITUDE_NUM) + j][1] = y; 218 points[(i * fF_LATITUDE_NUM) + j][2] = z = cenz + radius * sines[j] * sines[i]; 219 } 220 else { 221 points[(i * fF_LATITUDE_NUM) + j][0] = x = cenx + kx * cosines[j] * sines[i]; 222 points[(i * fF_LATITUDE_NUM) + j][1] = y; 223 points[(i * fF_LATITUDE_NUM) + j][2] = z = cenz + kz * sines[j] * sines[i]; 224 } 225 226 points[(i * fF_LATITUDE_NUM) + j][3] = 1.0; 227 if (x < minX) minX = x; 228 if (x > maxX) maxX = x; 229 if (y < minY) minY = y; 230 if (y > maxY) maxY = y; 231 232 if (z < minZ) minZ = z; 233 }; 234 }; 235 return points; 236 237 } 238 239 double GenoConv_fF0::dist(double x1, double y1, double z1, double x2, double y2, double z2) 240 { 241 return sqrt((x2 - x1)*(x2 - x1) + (y2 - y1)*(y2 - y1) + (z2 - z1)*(z2 - z1)); 242 } 243 244 void GenoConv_fF0::search_hid(int nr, fF_chamber3d **spheres, double kx_, double ky_, double kz_) 245 { 246 int i, j; 247 if (nr != 0) { 248 for (i = 0; i < nr; i++) { 249 for (j = 0; j < fF_AMOUNT; j++) { 250 double X = spheres[nr]->points[j][0]; 251 double Y = spheres[nr]->points[j][1]; 252 double Z = spheres[nr]->points[j][2]; 253 254 double srX0 = spheres[i]->centerX; 255 double srY0 = spheres[i]->centerY; 256 double srZ0 = spheres[i]->centerZ; 257 258 double a2; 259 double b2; 260 double c2; 261 262 if (kx_ != 1) { 263 a2 = (kx_ * kx_); 264 } 265 else { 266 a2 = (spheres[i]->radius * spheres[i]->radius); 267 } 268 269 if (ky_ != 1) { 270 b2 = (ky_ * ky_); 271 272 } 273 else { 274 b2 = (spheres[i]->radius * spheres[i]->radius); 275 } 276 277 c2 = (kz_ * spheres[i]->radius) * (kz_ * spheres[i]->radius); 278 279 double up1 = (X - srX0) * (X - srX0); 280 double up2 = (Y - srY0) * (Y - srY0); 281 double up3 = (Z - srZ0) * (Z - srZ0); 282 283 double exp = up1 / a2; 284 double exp2 = up2 / b2; 285 double exp3 = up3 / c2; 286 287 double result = exp + exp2 + exp3; 288 289 if (result < (fF_THICK_RATIO) 290 ) { 291 spheres[nr]->points[j][3] = 0; 292 } 293 } 294 } 295 } 296 } 297 298 int GenoConv_fF0::find_hole(int which, double x, double y, double z, fF_chamber3d **chambers, double kx_, double ky_, double kz_) 299 { 300 int i; 301 double distance; 302 int found = 0; 303 double dist_found = 0; 304 int first = 1; 305 306 for (i = 0; i < fF_AMOUNT; i++) { 307 if (chambers[which]->points[i][3] != 0) //it is not inside another chamber 308 { 309 distance = sqrt((chambers[which]->points[i][0] - x)*(chambers[which]->points[i][0] - x) + 310 (chambers[which]->points[i][1] - y)*(chambers[which]->points[i][1] - y) + 311 (chambers[which]->points[i][2] - z)*(chambers[which]->points[i][2] - z)); 312 if (first != 0) { 313 found = i; 314 dist_found = distance; 315 first = 0; 316 } 317 if (distance < dist_found) { 318 if (which != 0) { 319 bool good = true; 320 for (int j = 0; j < which; j++) { 321 { 322 double X = chambers[which]->points[i][0]; 323 double Y = chambers[which]->points[i][1]; 324 double Z = chambers[which]->points[i][2]; 325 326 double srX0 = chambers[j]->centerX; 327 double srY0 = chambers[j]->centerY; 328 double srZ0 = chambers[j]->centerZ; 329 330 double a2 = (kx_ * chambers[j]->radius) * (kx_ * chambers[j]->radius); 331 double b2 = (ky_ * chambers[j]->radius) * (ky_ * chambers[j]->radius); 332 double c2 = (kz_ * chambers[j]->radius) * (kz_ * chambers[j]->radius); 333 334 double up1 = (X - srX0) * (X - srX0); 335 double up2 = (Y - srY0) * (Y - srY0); 336 double up3 = (Z - srZ0) * (Z - srZ0); 337 338 double exp1 = up1 / a2; 339 double exp2 = up2 / b2; 340 double exp3 = up3 / c2; 341 342 double result = exp1 + exp2 + exp3; 343 if (result < 1.0) 344 { 345 good = false; 346 } 347 } 348 } 349 if (good) { 350 found = i; 351 dist_found = distance; 352 } 353 } 354 } 355 } 356 } 357 358 return (found); 359 } -
cpp/frams/genetics/fF/conv_fF.h
r174 r176 6 6 #define _CONV_FF_H_ 7 7 8 #define TOO_MUCH 0.759 #define TOO_LITTLE 0.108 #define fF_TOO_MUCH 0.75 9 #define fF_TOO_LITTLE 0.10 10 10 11 #define HOLE_RADIUS 0.05f12 #define LONGITUDE_NUM 6911 #define fF_HOLE_RADIUS 0.05f 12 #define fF_LONGITUDE_NUM 69 13 13 14 #define LATITUDE_NUM ((LONGITUDE_NUM - 1)*2)15 #define AMOUNT ((LATITUDE_NUM)*(LONGITUDE_NUM))14 #define fF_LATITUDE_NUM ((fF_LONGITUDE_NUM - 1)*2) 15 #define fF_AMOUNT ((fF_LATITUDE_NUM)*(fF_LONGITUDE_NUM)) 16 16 17 #define THICK_RATIO 0.9517 #define fF_THICK_RATIO 0.95 18 18 19 #define SIZE LONGITUDE_NUM * LATITUDE_NUM +LATITUDE_NUM19 #define fF_SIZE fF_LONGITUDE_NUM * fF_LATITUDE_NUM + fF_LATITUDE_NUM 20 20 21 21 #include <frams/util/multimap.h> … … 25 25 26 26 // The f9->f0 converter 27 28 27 class GenoConv_fF0 : public GenoConverter { 29 28 public: 30 31 32 33 29 GenoConv_fF0(); 30 ~GenoConv_fF0(); 31 //implementation of the GenoConverter method 32 SString convert(SString &in, MultiMap *map); 34 33 35 34 protected: 36 37 38 39 40 41 42 43 44 35 double* cosines; 36 double* sines; 37 void createSphere(int ktora, fF_chamber3d **chambers, double radius, double div_radius_length, double div_vector_length, 38 double alpha, double gamma, double kx, double ky, double kz); 39 double** generate_points(fF_chamber3d *chamber, int which, double kx, double ky, double kz); 40 void fill_cos_and_sin(); 41 double dist(double x1, double y1, double z1, double x2, double y2, double z2); 42 void search_hid(int nr, fF_chamber3d **spheres, double kx_, double ky_, double kz_); 43 int find_hole(int which, double x, double y, double z, fF_chamber3d **chambers, double kx_, double ky_, double kz_); 45 44 }; 46 45 47 46 #endif 48 49 -
cpp/frams/genetics/fF/fF_chamber3d.cpp
r174 r176 2 2 // Copyright (C) 2002-2014 Maciej Komosinski and Szymon Ulatowski. See LICENSE.txt for details. 3 3 // Refer to http://www.framsticks.com/ for further information. 4 4 5 #include "fF_chamber3d.h" 5 6 #include "conv_fF.h" … … 8 9 fF_chamber3d::~fF_chamber3d() 9 10 { 10 for (int i = 0; i < SIZE; i++){ 11 delete []points[i]; 12 } 13 delete []points; 14 } 11 for (int i = 0; i < fF_SIZE; i++) 12 delete[] points[i]; 13 delete[] points; 14 } 15 15 16 16 fF_chamber3d::fF_chamber3d(float centerX, float centerY, float centerZ, 17 float radius, float holeX, float holeY, float holeZ,18 float vectorTfX, float vectorTfY, float vectorTfZ, float beta, float phi)17 float radius, float holeX, float holeY, float holeZ, 18 float vectorTfX, float vectorTfY, float vectorTfZ, float beta, float phi) 19 19 { 20 20 points = NULL; 21 21 this->centerX = centerX; 22 22 this->centerY = centerY; … … 30 30 this->vectorTfZ = vectorTfZ; 31 31 this->beta = beta; 32 this->phi = phi; 32 this->phi = phi; 33 33 } -
cpp/frams/genetics/fF/fF_chamber3d.h
r174 r176 2 2 // Copyright (C) 2002-2014 Maciej Komosinski and Szymon Ulatowski. See LICENSE.txt for details. 3 3 // Refer to http://www.framsticks.com/ for further information. 4 4 5 #ifndef CHAMBER3D_H 5 6 #define CHAMBER3D_H 6 7 7 //chamber parameters 8 8 //Chamber parameters; see http://www.framsticks.com/foraminifera 9 9 class fF_chamber3d 10 10 { … … 22 22 float beta; 23 23 float phi; 24 24 double **points; 25 25 26 26 ~fF_chamber3d(); 27 27 fF_chamber3d(float centerX, float centerY, float centerZ, 28 float radius, float holeX, float holeY, float holeZ, 29 float vectorTfX, float vectorTfY, float vectorTfZ, float beta, float phi); 30 28 float radius, float holeX, float holeY, float holeZ, 29 float vectorTfX, float vectorTfY, float vectorTfZ, float beta, float phi); 31 30 }; 32 31 33 34 32 #endif /* CHAMBER3D_H */ -
cpp/frams/genetics/fF/fF_genotype.cpp
r174 r176 10 10 { "fF", 1, 7, "fF" }, 11 11 { "n", 0, PARAM_CANOMITNAME, "number of chambers", "d 1 15 1", FIELD(number_of_chambers), }, 12 { "sx", 0, PARAM_CANOMITNAME, "scale x", "f 1.0 1.1 1.0 1", FIELD(scalex), },13 { "sy", 0, PARAM_CANOMITNAME, "scale y", "f 1.0 1.1 1.0 1", FIELD(scaley), },14 { "sz", 0, PARAM_CANOMITNAME, "scale z", "f 1.0 1.1 1.0 1", FIELD(scalez), },15 { "tr", 0, PARAM_CANOMITNAME, "translation factor", "f -1 1 0 .5", FIELD(translation), },12 { "sx", 0, PARAM_CANOMITNAME, "scale x", "f 1.0 1.1 1.05", FIELD(scalex), }, 13 { "sy", 0, PARAM_CANOMITNAME, "scale y", "f 1.0 1.1 1.05", FIELD(scaley), }, 14 { "sz", 0, PARAM_CANOMITNAME, "scale z", "f 1.0 1.1 1.05", FIELD(scalez), }, 15 { "tr", 0, PARAM_CANOMITNAME, "translation factor", "f -1 1 0", FIELD(translation), }, 16 16 { "a1", 0, PARAM_CANOMITNAME, "angle 1", "f -3.1415926 3.1415926 0", FIELD(angle1), }, 17 17 { "a2", 0, PARAM_CANOMITNAME, "angle 2", "f -3.1415926 3.1415926 0", FIELD(angle2), }, -
cpp/frams/genetics/fF/fF_genotype.h
r145 r176 10 10 #include <frams/param/param.h> 11 11 12 //Growth parameters; see http://www.framsticks.com/foraminifera 12 13 struct fF_growth_params 13 14 { … … 35 36 SString s = serialized; 36 37 int p = 0; //position in string 37 return ((param.load2(s, p) ==7) && (p==s.len()));38 return ((param.load2(s, p) == 7) && (p == s.len())); 38 39 } 39 40 … … 46 47 }; 47 48 48 49 49 #endif -
cpp/frams/genetics/fF/oper_fF.h
r145 r176 18 18 int crossOver(char *&g1, char *&g2, float& chg1, float& chg2); 19 19 unsigned long style(const char *g, int pos); 20 const char* getSimplest() { return "6, 0.8,0.85,0.9,0.6,0.3,0.7"; }20 const char* getSimplest() { return "6, 1.05, 1.05, 1.05, 0, 0, 0"; } 21 21 22 22 double xover_proportion; … … 24 24 25 25 #endif 26
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