116 lines
7.9 KiB
C
116 lines
7.9 KiB
C
/* global variables and definitions used by sub_wave_3d.c */
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/* plot types used by wave_3d */
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#define P_3D_AMPLITUDE 101 /* height/color depends on amplitude - DEPRECATED, instead use set SHADE_3D to 0 */
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#define P_3D_ANGLE 102 /* height/color depends on angle with fixed direction - TODO */
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#define P_3D_AMP_ANGLE 103 /* height/color depends on amplitude, luminosity depends on angle */
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#define P_3D_ENERGY 104 /* height/color depends on energy, luminosity depends on angle */
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#define P_3D_LOG_ENERGY 105 /* height/color depends on logarithm of energy, luminosity depends on angle */
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#define P_3D_TOTAL_ENERGY 106 /* height/color depends on total energy over time, luminosity depends on angle */
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#define P_3D_LOG_TOTAL_ENERGY 107 /* height/color depends on log on total energy over time, luminosity depends on angle */
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#define P_3D_MEAN_ENERGY 108 /* height/color depends on energy averaged over time, luminosity depends on angle */
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#define P_3D_LOG_MEAN_ENERGY 109 /* height/color depends on log on energy averaged over time, luminosity depends on angle */
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#define P_3D_PHASE 111 /* phase of wave */
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#define P_3D_FLUX_INTENSITY 112 /* energy flux intensity */
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#define P_3D_FLUX_DIRECTION 113 /* energy flux direction */
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/* Choice of simulated reaction-diffusion equation in rde.c */
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#define E_HEAT 0 /* heat equation */
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#define E_ALLEN_CAHN 1 /* Allen-Cahn equation */
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#define E_CAHN_HILLIARD 2 /* Cahn-Hilliard equation */
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#define E_FHN 3 /* FitzHugh-Nagumo equation */
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#define E_RPS 4 /* rock-paper-scissors equation */
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#define E_RPSLZ 41 /* rock-paper-scissors-lizard-Spock equation */
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#define E_SCHRODINGER 5 /* Schrodinger equation */
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#define E_EULER_INCOMP 6 /* incompressible Euler equation */
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#define E_EULER_COMP 7 /* compressible Euler equation */
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/* Choice of potential */
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#define POT_HARMONIC 1 /* harmonic oscillator */
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#define POT_COULOMB 2 /* Coulomb (1/r) potential */
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#define POT_PERIODIC 3 /* periodic potential */
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#define POT_DOUBLE_COULOMB 4 /* sum of Coulomb potentials located at focal points of ellipse */
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#define POT_FERMIONS 5 /* two interacting 1D fermions */
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#define POT_FERMIONS_PERIODIC 6 /* two interacting 1D fermions on the circle */
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#define POT_MAZE 7 /* higher potential on walls of a maze */
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/* Choice of vector potential */
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#define VPOT_CONSTANT_FIELD 100 /* constant magnetic field */
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#define VPOT_AHARONOV_BOHM 101 /* single flux line for Aharonov-Bohm effect */
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/* Choice of force field in compressible Euler equation */
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#define GF_VERTICAL 0 /* gravity acting vertically */
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#define GF_CIRCLE 1 /* repelling circle */
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/* macros to avoid unnecessary computations in 3D plots */
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#define COMPUTE_THETA ((cplot == Z_POLAR)||(cplot == Z_NORM_GRADIENT)||(cplot == Z_ANGLE_GRADIENT)||(cplot == Z_NORM_GRADIENT_INTENSITY)||(cplot == Z_VORTICITY)||(cplot == Z_VORTICITY_ABS))
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#define COMPUTE_THETAZ ((zplot == Z_POLAR)||(zplot == Z_NORM_GRADIENT)||(zplot == Z_ANGLE_GRADIENT)||(zplot == Z_NORM_GRADIENT_INTENSITY)||(zplot == Z_VORTICITY)||(zplot == Z_VORTICITY_ABS))
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#define COMPUTE_ENERGY ((zplot == P_3D_ENERGY)||(cplot == P_3D_ENERGY)||(zplot == P_3D_LOG_ENERGY)||(cplot == P_3D_LOG_ENERGY)||(zplot == P_3D_TOTAL_ENERGY)||(cplot == P_3D_TOTAL_ENERGY)||(zplot == P_3D_LOG_TOTAL_ENERGY)||(cplot == P_3D_LOG_TOTAL_ENERGY)||(zplot == P_3D_MEAN_ENERGY)||(cplot == P_3D_MEAN_ENERGY)||(zplot == P_3D_LOG_MEAN_ENERGY)||(cplot == P_3D_LOG_MEAN_ENERGY)||(ZPLOT == P_3D_FLUX_INTENSITY)||(CPLOT == P_3D_FLUX_INTENSITY)||(ZPLOT_B == P_3D_FLUX_INTENSITY)||(CPLOT_B == P_3D_FLUX_INTENSITY)||(ZPLOT == P_3D_FLUX_DIRECTION)||(CPLOT == P_3D_FLUX_DIRECTION)||(ZPLOT_B == P_3D_FLUX_DIRECTION)||(CPLOT_B == P_3D_FLUX_DIRECTION))
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#define COMPUTE_LOG_TOTAL_ENERGY ((ZPLOT == P_3D_LOG_TOTAL_ENERGY)||(CPLOT == P_3D_LOG_TOTAL_ENERGY)||(ZPLOT_B == P_3D_LOG_TOTAL_ENERGY)||(CPLOT_B == P_3D_LOG_TOTAL_ENERGY))
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#define COMPUTE_LOG_MEAN_ENERGY ((ZPLOT == P_3D_LOG_MEAN_ENERGY)||(CPLOT == P_3D_LOG_MEAN_ENERGY)||(ZPLOT_B == P_3D_LOG_MEAN_ENERGY)||(CPLOT_B == P_3D_LOG_MEAN_ENERGY))
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#define COMPUTE_LOG_ENERGY ((ZPLOT == P_3D_LOG_TOTAL_ENERGY)||(CPLOT == P_3D_LOG_TOTAL_ENERGY)||(ZPLOT_B == P_3D_LOG_TOTAL_ENERGY)||(CPLOT_B == P_3D_LOG_TOTAL_ENERGY)||(ZPLOT == P_3D_LOG_MEAN_ENERGY)||(CPLOT == P_3D_LOG_MEAN_ENERGY)||(ZPLOT_B == P_3D_LOG_MEAN_ENERGY)||(CPLOT_B == P_3D_LOG_MEAN_ENERGY))
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#define COMPUTE_MEAN_ENERGY ((ZPLOT == P_3D_MEAN_ENERGY)||(CPLOT == P_3D_MEAN_ENERGY)||(ZPLOT_B == P_3D_MEAN_ENERGY)||(CPLOT_B == P_3D_MEAN_ENERGY)||(ZPLOT == P_3D_LOG_MEAN_ENERGY)||(CPLOT == P_3D_LOG_MEAN_ENERGY)||(ZPLOT_B == P_3D_LOG_MEAN_ENERGY)||(CPLOT_B == P_3D_LOG_MEAN_ENERGY))
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#define COMPUTE_ENERGY_FLUX ((ZPLOT == P_3D_FLUX_INTENSITY)||(CPLOT == P_3D_FLUX_INTENSITY)||(ZPLOT_B == P_3D_FLUX_INTENSITY)||(CPLOT_B == P_3D_FLUX_INTENSITY)||(ZPLOT == P_3D_FLUX_DIRECTION)||(CPLOT == P_3D_FLUX_DIRECTION)||(ZPLOT_B == P_3D_FLUX_DIRECTION)||(CPLOT_B == P_3D_FLUX_DIRECTION))
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#define COMPUTE_TOTAL_ENERGY ((ZPLOT == P_3D_TOTAL_ENERGY)||(CPLOT == P_3D_TOTAL_ENERGY)||(ZPLOT == P_3D_LOG_TOTAL_ENERGY)||(CPLOT == P_3D_LOG_TOTAL_ENERGY)||(ZPLOT == P_3D_MEAN_ENERGY)||(CPLOT == P_3D_MEAN_ENERGY)||(ZPLOT == P_3D_LOG_MEAN_ENERGY)||(CPLOT == P_3D_LOG_MEAN_ENERGY)||(ZPLOT_B == P_3D_TOTAL_ENERGY)||(CPLOT_B == P_3D_TOTAL_ENERGY)||(ZPLOT_B == P_3D_LOG_TOTAL_ENERGY)||(CPLOT_B == P_3D_LOG_TOTAL_ENERGY)||(ZPLOT_B == P_3D_MEAN_ENERGY)||(CPLOT_B == P_3D_MEAN_ENERGY)||(ZPLOT_B == P_3D_LOG_MEAN_ENERGY)||(CPLOT_B == P_3D_LOG_MEAN_ENERGY))
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int global_time = 0;
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/* structure used for color and height representations */
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/* possible extra fields: zfield, cfield, interpolated coordinates */
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typedef struct
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{
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double energy; /* wave energy */
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double phase; /* wave phase */
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double log_energy; /* log of wave energy */
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double total_energy; /* total energy since beginning of simulation */
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double log_total_energy; /* log of total energy since beginning of simulation */
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double mean_energy; /* energy averaged since beginning of simulation */
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double log_mean_energy; /* log of energy averaged since beginning of simulation */
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double cos_angle; /* cos of angle between normal vector and direction of light */
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double flux_intensity; /* intensity of energy flux */
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double flux_direction; /* direction of energy flux */
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double flux_int_table[FLUX_WINDOW]; /* table of energy flux intensities (for averaging) */
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short int flux_counter; /* counter for averaging of energy flux */
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double rgb[3]; /* RGB color code */
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double *p_zfield[2]; /* pointers to z field (second pointer for option DOUBLE_MOVIE) */
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double *p_cfield[4]; /* pointers to color field (second pointer for option DOUBLE_MOVIE) */
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/* third and fourth pointer for color luminosity (for energy flux) */
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} t_wave;
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typedef struct
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{
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double theta; /* angle for Rock-Paper-Scissors equation */
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double nablax; /* gradient of first field */
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double nablay; /* gradient of first field */
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double field_norm; /* norm of field or gradient */
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double field_arg; /* argument of field or gradient */
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double curl; /* curl of field */
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double cos_angle; /* cos of angle between normal vector and direction of light */
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double log_vorticity; /* logarithm of vorticity (for Euler equation) */
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double Lpressure; /* Laplacian of pressure (for Euler equation) */
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double dxu, dyu, dxv, dyv; /* gradient of velocity field (for compressible Euler equation) */
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double rgb[3]; /* RGB color code */
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double *p_zfield[2]; /* pointers to z field (second pointer for option DOUBLE_MOVIE) */
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double *p_cfield[2]; /* pointers to color field (second pointer for option DOUBLE_MOVIE) */
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} t_rde;
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