#include "ace_common.h" #include #include #include #include #define M_PI 3.14159265358979323846f #define GRAVITY 9.80665f #define ABSOLUTE_ZERO_IN_CELSIUS -273.15f #define KELVIN(t) (t - ABSOLUTE_ZERO_IN_CELSIUS) #define CELSIUS(t) (t + ABSOLUTE_ZERO_IN_CELSIUS) #define UNIVERSAL_GAS_CONSTANT 8.314f #define WATER_VAPOR_MOLAR_MASS 0.018016f #define DRY_AIR_MOLAR_MASS 0.028964f #define SPECIFIC_GAS_CONSTANT_DRY_AIR 287.058f #define STD_AIR_DENSITY_ICAO 1.22498f #define STD_AIR_DENSITY_ASM 1.20885f struct Bullet { double airFriction; double caliber; double bulletLength; double bulletMass; std::vector ballisticCoefficients; std::vector velocityBoundaries; char* atmosphereModel; int dragModel; std::vector muzzleVelocities; std::vector barrelLengths; double stabilityFactor; double twistDirection; double transonicStabilityCoef; double muzzleVelocity; std::vector origin; double latitude; double temperature; double altitude; double humidity; double overcast; double startTime; double speed; double frames; double lastFrame; double hDeflection; double spinDrift; }; struct Map { std::vector gridHeights; std::vector gridBuildingNums; std::vector gridSurfaceIsWater; int mapSize; int mapGrids; }; std::vector bulletDatabase; std::map mapDatabase; std::string worldName = ""; Map* map = &mapDatabase[""]; double calculateRoughnessLength(double posX, double posY) { // Source: http://es.ucsc.edu/~jnoble/wind/extrap/index.html double roughness_lengths[10] = {0.0002, 0.0005, 0.0024, 0.03, 0.055, 0.1, 0.2, 0.4, 0.8, 1.6}; double roughnessLength = 0.0024; int gridX = (int)floor(posX / 50); int gridY = (int)floor(posY / 50); int gridCell = gridX * map->mapGrids + gridY; if (gridCell >= 0 && (std::size_t)gridCell < map->gridHeights.size() && (std::size_t)gridCell < map->gridBuildingNums.size()) { int nearBuildings = map->gridBuildingNums[gridCell]; int surfaceIsWater = map->gridSurfaceIsWater[gridCell]; if (nearBuildings == 0 && surfaceIsWater == 1) { return 0.0005; } if (nearBuildings >= 10) { return 1.6; } return roughness_lengths[2 + min(nearBuildings, 6)]; } return 0.0024; } double calculateAirDensity(double temperature, double pressure, double relativeHumidity) { pressure = pressure * 100; if (relativeHumidity > 0) { double _pSat = 6.1078 * pow(10, ((7.5 * temperature) / (temperature + 237.3))); double vaporPressure = relativeHumidity * _pSat; double partialPressure = pressure - vaporPressure; return (partialPressure * 0.028964 + vaporPressure * 0.018016) / (8.314 * (273.15 + temperature)); } else { return pressure / (287.058 * (273.15 + temperature)); } } double calculateAtmosphericCorrection(double ballisticCoefficient, double temperature, double pressure, double relativeHumidity, const char *atmosphereModel) { double airDensity = calculateAirDensity(temperature, pressure, relativeHumidity); if (!strcmp(atmosphereModel, "ICAO")) { return (1.22498 / airDensity) * ballisticCoefficient; } else { return (1.20885 / airDensity) * ballisticCoefficient; } } double calculateRetard(int DragFunction, double DragCoefficient, double Velocity) { double vel = Velocity * 3.2808399; double val = -1; double A = -1; double M = -1; switch (DragFunction) { case 1: if (vel> 4230) { A = 1.477404177730177e-04; M = 1.9565; } else if (vel> 3680) { A = 1.920339268755614e-04; M = 1.925; } else if (vel> 3450) { A = 2.894751026819746e-04; M = 1.875; } else if (vel> 3295) { A = 4.349905111115636e-04; M = 1.825; } else if (vel> 3130) { A = 6.520421871892662e-04; M = 1.775; } else if (vel> 2960) { A = 9.748073694078696e-04; M = 1.725; } else if (vel> 2830) { A = 1.453721560187286e-03; M = 1.675; } else if (vel> 2680) { A = 2.162887202930376e-03; M = 1.625; } else if (vel> 2460) { A = 3.209559783129881e-03; M = 1.575; } else if (vel> 2225) { A = 3.904368218691249e-03; M = 1.55; } else if (vel> 2015) { A = 3.222942271262336e-03; M = 1.575; } else if (vel> 1890) { A = 2.203329542297809e-03; M = 1.625; } else if (vel> 1810) { A = 1.511001028891904e-03; M = 1.675; } else if (vel> 1730) { A = 8.609957592468259e-04; M = 1.75; } else if (vel> 1595) { A = 4.086146797305117e-04; M = 1.85; } else if (vel> 1520) { A = 1.954473210037398e-04; M = 1.95; } else if (vel> 1420) { A = 5.431896266462351e-05; M = 2.125; } else if (vel> 1360) { A = 8.847742581674416e-06; M = 2.375; } else if (vel> 1315) { A = 1.456922328720298e-06; M = 2.625; } else if (vel> 1280) { A = 2.419485191895565e-07; M = 2.875; } else if (vel> 1220) { A = 1.657956321067612e-08; M = 3.25; } else if (vel> 1185) { A = 4.745469537157371e-10; M = 3.75; } else if (vel> 1150) { A = 1.379746590025088e-11; M = 4.25; } else if (vel> 1100) { A = 4.070157961147882e-13; M = 4.75; } else if (vel> 1060) { A = 2.938236954847331e-14; M = 5.125; } else if (vel> 1025) { A = 1.228597370774746e-14; M = 5.25; } else if (vel> 980) { A = 2.916938264100495e-14; M = 5.125; } else if (vel> 945) { A = 3.855099424807451e-13; M = 4.75; } else if (vel> 905) { A = 1.185097045689854e-11; M = 4.25; } else if (vel> 860) { A = 3.566129470974951e-10; M = 3.75; } else if (vel> 810) { A = 1.045513263966272e-08; M = 3.25; } else if (vel> 780) { A = 1.291159200846216e-07; M = 2.875; } else if (vel> 750) { A = 6.824429329105383e-07; M = 2.625; } else if (vel> 700) { A = 3.569169672385163e-06; M = 2.375; } else if (vel> 640) { A = 1.839015095899579e-05; M = 2.125; } else if (vel> 600) { A = 5.71117468873424e-05; M = 1.950; } else if (vel> 550) { A = 9.226557091973427e-05; M = 1.875; } else if (vel> 250) { A = 9.337991957131389e-05; M = 1.875; } else if (vel> 100) { A = 7.225247327590413e-05; M = 1.925; } else if (vel> 65) { A = 5.792684957074546e-05; M = 1.975; } else if (vel> 0) { A = 5.206214107320588e-05; M = 2.000; } break; case 2: if (vel> 1674) { A = .0079470052136733; M = 1.36999902851493; } else if (vel> 1172) { A = 1.00419763721974e-03; M = 1.65392237010294; } else if (vel> 1060) { A = 7.15571228255369e-23; M = 7.91913562392361; } else if (vel> 949) { A = 1.39589807205091e-10; M = 3.81439537623717; } else if (vel> 670) { A = 2.34364342818625e-04; M = 1.71869536324748; } else if (vel> 335) { A = 1.77962438921838e-04; M = 1.76877550388679; } else if (vel> 0) { A = 5.18033561289704e-05; M = 1.98160270524632; } break; case 5: if (vel> 1730) { A = 7.24854775171929e-03; M = 1.41538574492812; } else if (vel> 1228) { A = 3.50563361516117e-05; M = 2.13077307854948; } else if (vel> 1116) { A = 1.84029481181151e-13; M = 4.81927320350395; } else if (vel> 1004) { A = 1.34713064017409e-22; M = 7.8100555281422; } else if (vel> 837) { A = 1.03965974081168e-07; M = 2.84204791809926; } else if (vel> 335) { A = 1.09301593869823e-04; M = 1.81096361579504; } else if (vel> 0) { A = 3.51963178524273e-05; M = 2.00477856801111; } break; case 6: if (vel> 3236) { A = 0.0455384883480781; M = 1.15997674041274; } else if (vel> 2065) { A = 7.167261849653769e-02; M = 1.10704436538885; } else if (vel> 1311) { A = 1.66676386084348e-03; M = 1.60085100195952; } else if (vel> 1144) { A = 1.01482730119215e-07; M = 2.9569674731838; } else if (vel> 1004) { A = 4.31542773103552e-18; M = 6.34106317069757; } else if (vel> 670) { A = 2.04835650496866e-05; M = 2.11688446325998; } else if (vel> 0) { A = 7.50912466084823e-05; M = 1.92031057847052; } break; case 7: if (vel> 4200) { A = 1.29081656775919e-09; M = 3.24121295355962; } else if (vel> 3000) { A = 0.0171422231434847; M = 1.27907168025204; } else if (vel> 1470) { A = 2.33355948302505e-03; M = 1.52693913274526; } else if (vel> 1260) { A = 7.97592111627665e-04; M = 1.67688974440324; } else if (vel> 1110) { A = 5.71086414289273e-12; M = 4.3212826264889; } else if (vel> 960) { A = 3.02865108244904e-17; M = 5.99074203776707; } else if (vel> 670) { A = 7.52285155782535e-06; M = 2.1738019851075; } else if (vel> 540) { A = 1.31766281225189e-05; M = 2.08774690257991; } else if (vel> 0) { A = 1.34504843776525e-05; M = 2.08702306738884; } break; case 8: if (vel> 3571) { A = .0112263766252305; M = 1.33207346655961; } else if (vel> 1841) { A = .0167252613732636; M = 1.28662041261785; } else if (vel> 1120) { A = 2.20172456619625e-03; M = 1.55636358091189; } else if (vel> 1088) { A = 2.0538037167098e-16; M = 5.80410776994789; } else if (vel> 976) { A = 5.92182174254121e-12; M = 4.29275576134191; } else if (vel> 0) { A = 4.3917343795117e-05; M = 1.99978116283334; } break; default: break; } if (A != -1 && M != -1 && vel > 0 && vel < 10000) { val = A * pow(vel, M) / DragCoefficient; val = val / 3.2808399; return val; } return 0.0; } extern "C" { __declspec (dllexport) void __stdcall RVExtension(char *output, int outputSize, const char *function); } void __stdcall RVExtension(char *output, int outputSize, const char *function) { if (!strcmp(function, "version")) { int n = sprintf_s(output, outputSize, "%s", ACE_FULL_VERSION_STR); return; } char* input = _strdup(function); char* token = NULL; char* next_token = NULL; char* mode = strtok_s(input, ":", &next_token); if (!strcmp(mode, "retard")) { double ballisticCoefficient = 1.0; int dragModel = 1; double velocity = 0.0; double retard = 0.0; dragModel = strtol(strtok_s(NULL, ":", &next_token), NULL, 10); ballisticCoefficient = strtod(strtok_s(NULL, ":", &next_token), NULL); velocity = strtod(strtok_s(NULL, ":", &next_token), NULL); retard = calculateRetard(dragModel, ballisticCoefficient, velocity); int n = sprintf_s(output, outputSize, "%f", retard); return; } else if (!strcmp(mode, "atmosphericCorrection")) { double ballisticCoefficient = 1.0; double temperature = 15.0; double pressure = 1013.25; double humidity = 0.0; char* atmosphereModel; ballisticCoefficient = strtod(strtok_s(NULL, ":", &next_token), NULL); temperature = strtod(strtok_s(NULL, ":", &next_token), NULL); pressure = strtod(strtok_s(NULL, ":", &next_token), NULL); humidity = strtod(strtok_s(NULL, ":", &next_token), NULL); atmosphereModel = strtok_s(NULL, ":", &next_token); ballisticCoefficient = calculateAtmosphericCorrection(ballisticCoefficient, temperature, pressure, humidity, atmosphereModel); int n = sprintf_s(output, outputSize, "%f", ballisticCoefficient); return; } else if (!strcmp(mode, "new")) { unsigned int index = 0; double airFriction = 0.0; char* ballisticCoefficientArray; char* ballisticCoefficient; std::vector ballisticCoefficients; char* velocityBoundaryArray; char* velocityBoundary; std::vector velocityBoundaries; char* atmosphereModel; int dragModel = 1; double stabilityFactor = 1.5; int twistDirection = 1; double transonicStabilityCoef = 1; double muzzleVelocity = 850; char* originArray; char* originEntry; std::vector origin; double latitude = 0.0; double temperature = 0.0; double altitude = 0.0; double humidity = 0.0; double overcast = 0.0; double tickTime = 0.0; index = strtol(strtok_s(NULL, ":", &next_token), NULL, 10); airFriction = strtod(strtok_s(NULL, ":", &next_token), NULL); ballisticCoefficientArray = strtok_s(NULL, ":", &next_token); ballisticCoefficientArray++; ballisticCoefficientArray[strlen(ballisticCoefficientArray) - 1] = 0; ballisticCoefficient = strtok_s(ballisticCoefficientArray, ",", &token); while (ballisticCoefficient != NULL) { ballisticCoefficients.push_back(strtod(ballisticCoefficient, NULL)); ballisticCoefficient = strtok_s(NULL, ",", &token); } velocityBoundaryArray = strtok_s(NULL, ":", &next_token); velocityBoundaryArray++; velocityBoundaryArray[strlen(velocityBoundaryArray) - 1] = 0; velocityBoundary = strtok_s(velocityBoundaryArray, ",", &token); while (velocityBoundary != NULL) { velocityBoundaries.push_back(strtod(velocityBoundary, NULL)); velocityBoundary = strtok_s(NULL, ",", &token); } atmosphereModel = strtok_s(NULL, ":", &next_token); dragModel = strtol(strtok_s(NULL, ":", &next_token), NULL, 10); stabilityFactor = strtod(strtok_s(NULL, ":", &next_token), NULL); twistDirection = strtol(strtok_s(NULL, ":", &next_token), NULL, 10); muzzleVelocity = strtod(strtok_s(NULL, ":", &next_token), NULL); transonicStabilityCoef = strtod(strtok_s(NULL, ":", &next_token), NULL); originArray = strtok_s(NULL, ":", &next_token); originArray++; originArray[strlen(originArray) - 1] = 0; originEntry = strtok_s(originArray, ",", &token); while (originEntry != NULL) { origin.push_back(strtod(originEntry, NULL)); originEntry = strtok_s(NULL, ",", &token); } latitude = strtod(strtok_s(NULL, ":", &next_token), NULL); temperature = strtod(strtok_s(NULL, ":", &next_token), NULL); altitude = strtod(strtok_s(NULL, ":", &next_token), NULL); humidity = strtod(strtok_s(NULL, ":", &next_token), NULL); overcast = strtod(strtok_s(NULL, ":", &next_token), NULL); tickTime = strtod(strtok_s(NULL, ":", &next_token), NULL); tickTime += strtod(strtok_s(NULL, ":", &next_token), NULL); while (index >= bulletDatabase.size()) { Bullet bullet; bulletDatabase.push_back(bullet); } bulletDatabase[index].airFriction = airFriction; bulletDatabase[index].ballisticCoefficients = ballisticCoefficients; bulletDatabase[index].velocityBoundaries = velocityBoundaries; bulletDatabase[index].atmosphereModel = atmosphereModel; bulletDatabase[index].dragModel = dragModel; bulletDatabase[index].stabilityFactor = stabilityFactor; bulletDatabase[index].twistDirection = twistDirection; bulletDatabase[index].transonicStabilityCoef = transonicStabilityCoef; bulletDatabase[index].muzzleVelocity = muzzleVelocity; bulletDatabase[index].origin = origin; bulletDatabase[index].latitude = latitude / 180 * M_PI; bulletDatabase[index].temperature = temperature; bulletDatabase[index].altitude = altitude; bulletDatabase[index].humidity = humidity; bulletDatabase[index].overcast = overcast; bulletDatabase[index].startTime = tickTime; bulletDatabase[index].lastFrame = tickTime; bulletDatabase[index].hDeflection = 0.0; bulletDatabase[index].spinDrift = 0.0; bulletDatabase[index].speed = 0.0; bulletDatabase[index].frames = 0.0; int n = sprintf_s(output, outputSize, "%s", ""); return; } else if (!strcmp(mode, "simulate")) { // simulate:0:[-0.109985,542.529,-3.98301]:[3751.57,5332.23,214.252]:[0.598153,2.38829,0]:28.6:0:0.481542:0:215.16 unsigned int index = 0; char* velocityArray; double velocity[3] = { 0.0, 0.0, 0.0 }; char* positionArray; double position[3] = { 0.0, 0.0, 0.0 }; char* windArray; double wind[3]; double heightAGL = 0.0; double tickTime = 0.0; index = strtol(strtok_s(NULL, ":", &next_token), NULL, 10); velocityArray = strtok_s(NULL, ":", &next_token); velocityArray++; velocityArray[strlen(velocityArray) - 1] = 0; velocity[0] = strtod(strtok_s(velocityArray, ",", &token), NULL); velocity[1] = strtod(strtok_s(NULL, ",", &token), NULL); velocity[2] = strtod(strtok_s(NULL, ",", &token), NULL); positionArray = strtok_s(NULL, ":", &next_token); positionArray++; positionArray[strlen(positionArray) - 1] = 0; position[0] = strtod(strtok_s(positionArray, ",", &token), NULL); position[1] = strtod(strtok_s(NULL, ",", &token), NULL); position[2] = strtod(strtok_s(NULL, ",", &token), NULL); windArray = strtok_s(NULL, ":", &next_token); windArray++; windArray[strlen(windArray) - 1] = 0; wind[0] = strtod(strtok_s(windArray, ",", &token), NULL); wind[1] = strtod(strtok_s(NULL, ",", &token), NULL); wind[2] = strtod(strtok_s(NULL, ",", &token), NULL); heightAGL = strtod(strtok_s(NULL, ":", &next_token), NULL); tickTime = strtod(strtok_s(NULL, ":", &next_token), NULL); tickTime += strtod(strtok_s(NULL, ":", &next_token), NULL); double ballisticCoefficient = 1.0; double dragRef = 0.0; double drag = 0.0; double accelRef[3] = { 0.0, 0.0, 0.0 }; double accel[3] = { 0.0, 0.0, 0.0 }; double TOF = 0.0; double deltaT = 0.0; double bulletSpeed; double bulletDir; double bulletSpeedAvg = 0.0; double trueVelocity[3] = { 0.0, 0.0, 0.0 }; double trueSpeed = 0.0; double temperature = 0.0; double windSpeed = 0.0; double windAttenuation = 1.0; double velocityOffset[3] = { 0.0, 0.0, 0.0 }; double positionOffset[3] = { 0.0, 0.0, 0.0 }; TOF = tickTime - bulletDatabase[index].startTime; deltaT = tickTime - bulletDatabase[index].lastFrame; bulletDatabase[index].lastFrame = tickTime; bulletSpeed = sqrt(pow(velocity[0], 2) + pow(velocity[1], 2) + pow(velocity[2], 2)); bulletDir = atan2(velocity[0], velocity[1]); bulletDatabase[index].speed += bulletSpeed; bulletDatabase[index].frames += 1; bulletSpeedAvg = (bulletDatabase[index].speed / bulletDatabase[index].frames); windSpeed = sqrt(pow(wind[0], 2) + pow(wind[1], 2) + pow(wind[2], 2)); if (windSpeed > 0.1) { double windSourceTerrain[3]; windSourceTerrain[0] = position[0] - wind[0] / windSpeed * 100; windSourceTerrain[1] = position[1] - wind[1] / windSpeed * 100; windSourceTerrain[2] = position[2] - wind[2] / windSpeed * 100; int gridX = (int)floor(windSourceTerrain[0] / 50); int gridY = (int)floor(windSourceTerrain[1] / 50); int gridCell = gridX * map->mapGrids + gridY; if (gridCell >= 0 && (std::size_t)gridCell < map->gridHeights.size() && (std::size_t)gridCell < map->gridBuildingNums.size()) { double gridHeight = map->gridHeights[gridCell]; if (gridHeight > position[2]) { double angle = atan((gridHeight - position[2]) / 100); windAttenuation *= pow(abs(cos(angle)), 2); } } } if (windSpeed > 0.1) { double windSourceObstacles[3]; windSourceObstacles[0] = position[0] - wind[0] / windSpeed * 25; windSourceObstacles[1] = position[1] - wind[1] / windSpeed * 25; windSourceObstacles[2] = position[2] - wind[2] / windSpeed * 25; if (heightAGL > 0 && heightAGL < 20) { double roughnessLength = calculateRoughnessLength(windSourceObstacles[0], windSourceObstacles[1]); windAttenuation *= abs(log(heightAGL / roughnessLength) / log(20 / roughnessLength)); } } if (windAttenuation < 1) { wind[0] *= windAttenuation; wind[1] *= windAttenuation; wind[2] *= windAttenuation; windSpeed = sqrt(pow(wind[0], 2) + pow(wind[1], 2) + pow(wind[2], 2)); } trueVelocity[0] = velocity[0] - wind[0]; trueVelocity[1] = velocity[1] - wind[1]; trueVelocity[2] = velocity[2] - wind[2]; trueSpeed = sqrt(pow(trueVelocity[0], 2) + pow(trueVelocity[1], 2) + pow(trueVelocity[2], 2)); temperature = bulletDatabase[index].temperature - 0.0065 * position[2]; if (bulletDatabase[index].ballisticCoefficients.size() == bulletDatabase[index].velocityBoundaries.size() + 1) { double pressure = 1013.25 * exp(-(bulletDatabase[index].altitude + position[2]) / 7990) - 10 * bulletDatabase[index].overcast; dragRef = deltaT * bulletDatabase[index].airFriction * bulletSpeed * bulletSpeed; accelRef[0] = (velocity[0] / bulletSpeed) * dragRef; accelRef[1] = (velocity[1] / bulletSpeed) * dragRef; accelRef[2] = (velocity[2] / bulletSpeed) * dragRef; velocityOffset[0] -= accelRef[0]; velocityOffset[1] -= accelRef[1]; velocityOffset[2] -= accelRef[2]; ballisticCoefficient = bulletDatabase[index].ballisticCoefficients[0]; for (int i = (int)bulletDatabase[index].velocityBoundaries.size() - 1; i >= 0; i = i - 1) { if (bulletSpeed < bulletDatabase[index].velocityBoundaries[i]) { ballisticCoefficient = bulletDatabase[index].ballisticCoefficients[i + 1]; break; } } ballisticCoefficient = calculateAtmosphericCorrection(ballisticCoefficient, temperature, pressure, bulletDatabase[index].humidity, bulletDatabase[index].atmosphereModel); drag = deltaT * calculateRetard(bulletDatabase[index].dragModel, ballisticCoefficient, trueSpeed); accel[0] = (trueVelocity[0] / trueSpeed) * drag; accel[1] = (trueVelocity[1] / trueSpeed) * drag; accel[2] = (trueVelocity[2] / trueSpeed) * drag; velocityOffset[0] -= accel[0]; velocityOffset[1] -= accel[1]; velocityOffset[2] -= accel[2]; } else { double pressureDeviation = 1013.25 * exp(-(bulletDatabase[index].altitude + position[2]) / 7990) - 1013.25 - 10 * bulletDatabase[index].overcast; double airFriction = bulletDatabase[index].airFriction + ((temperature - 15) * 0.0000015 + bulletDatabase[index].humidity * 0.0000040 + pressureDeviation * -0.0000009); if (airFriction != bulletDatabase[index].airFriction || windSpeed > 0) { dragRef = deltaT * bulletDatabase[index].airFriction * bulletSpeed * bulletSpeed; accelRef[0] = (velocity[0] / bulletSpeed) * dragRef; accelRef[1] = (velocity[1] / bulletSpeed) * dragRef; accelRef[2] = (velocity[2] / bulletSpeed) * dragRef; velocityOffset[0] -= accelRef[0]; velocityOffset[1] -= accelRef[1]; velocityOffset[2] -= accelRef[2]; drag = deltaT * airFriction * trueSpeed * trueSpeed; accel[0] = (trueVelocity[0] / trueSpeed) * drag; accel[1] = (trueVelocity[1] / trueSpeed) * drag; accel[2] = (trueVelocity[2] / trueSpeed) * drag; velocityOffset[0] += accel[0]; velocityOffset[1] += accel[1]; velocityOffset[2] += accel[2]; } } if (bulletSpeedAvg > 0) { double distanceSqr = pow(bulletDatabase[index].origin[0] - position[0], 2) + pow(bulletDatabase[index].origin[1] - position[1], 2) + pow(bulletDatabase[index].origin[2] - position[2], 2); double horizontalDeflection = 0.0000729 * distanceSqr * sin(bulletDatabase[index].latitude) / bulletSpeedAvg; double horizontalDeflectionPartial = horizontalDeflection - bulletDatabase[index].hDeflection; bulletDatabase[index].hDeflection = horizontalDeflection; positionOffset[0] += sin(bulletDir + M_PI / 2) * horizontalDeflectionPartial; positionOffset[1] += cos(bulletDir + M_PI / 2) * horizontalDeflectionPartial; } double centripetalAccel = 2 * 0.0000729 * (bulletDatabase[index].muzzleVelocity / -32.2) * cos(bulletDatabase[index].latitude) * sin(bulletDir); velocityOffset[2] -= centripetalAccel * deltaT; double spinDrift = bulletDatabase[index].twistDirection * 0.0254 * 1.25 * (bulletDatabase[index].stabilityFactor + 1.2) * pow(TOF, 1.83); double spinDriftPartial = spinDrift - bulletDatabase[index].spinDrift; bulletDatabase[index].spinDrift = spinDrift; positionOffset[0] += sin(bulletDir + M_PI / 2) * spinDriftPartial; positionOffset[1] += cos(bulletDir + M_PI / 2) * spinDriftPartial; if (bulletSpeed < 345 && bulletSpeedAvg > 340 && bulletSpeed > 335) { srand((unsigned)time(NULL)); velocityOffset[0] += (((double)rand() / (RAND_MAX)) * 0.4 - 0.2) * (1 - bulletDatabase[index].transonicStabilityCoef); velocityOffset[1] += (((double)rand() / (RAND_MAX)) * 0.4 - 0.2) * (1 - bulletDatabase[index].transonicStabilityCoef); velocityOffset[2] += (((double)rand() / (RAND_MAX)) * 0.4 - 0.2) * (1 - bulletDatabase[index].transonicStabilityCoef); }; int n = sprintf_s(output, outputSize, "_bullet setVelocity (_bulletVelocity vectorAdd [%f, %f, %f]); _bullet setPosASL (_bulletPosition vectorAdd [%f, %f, %f]);", velocityOffset[0], velocityOffset[1], velocityOffset[2], positionOffset[0], positionOffset[1], positionOffset[2]); return; } else if (!strcmp(mode, "set")) { int height = 0; int numObjects = 0; int surfaceIsWater = 0; height = strtol(strtok_s(NULL, ":", &next_token), NULL, 10); numObjects = strtol(strtok_s(NULL, ":", &next_token), NULL, 10); surfaceIsWater = strtol(strtok_s(NULL, ":", &next_token), NULL, 10); map->gridHeights.push_back(height); map->gridBuildingNums.push_back(numObjects); map->gridSurfaceIsWater.push_back(surfaceIsWater); int n = sprintf_s(output, outputSize, "%s", ""); return; } else if (!strcmp(mode, "init")) { int mapSize = 0; int mapGrids = 0; int gridCells = 0; worldName = strtok_s(NULL, ":", &next_token); mapSize = strtol(strtok_s(NULL, ":", &next_token), NULL, 10); mapGrids = (int)ceil((double)mapSize / 50.0) + 1; gridCells = mapGrids * mapGrids; map = &mapDatabase[worldName]; if (map->gridHeights.size() == gridCells) { int n = sprintf_s(output, outputSize, "%s", "Terrain already initialized"); return; } map->mapSize = mapSize; map->mapGrids = mapGrids; map->gridHeights.clear(); map->gridBuildingNums.clear(); map->gridSurfaceIsWater.clear(); map->gridHeights.reserve(gridCells); map->gridBuildingNums.reserve(gridCells); map->gridSurfaceIsWater.reserve(gridCells); int n = sprintf_s(output, outputSize, "%s", ""); return; } int n = sprintf_s(output, outputSize, "%s", ""); return; }