#include "Body.hpp"
#include "Orbit.hpp"
#include "Planet.hpp"
+#include "Resource.hpp"
+#include "Set.hpp"
#include "Simulation.hpp"
#include "Sun.hpp"
#include "Tile.hpp"
+#include "TileType.hpp"
+#include "Creature.hpp"
#include "../const.hpp"
#include "../app/Assets.hpp"
#include "../graphics/Viewport.hpp"
+#include "../rand/OctaveNoise.hpp"
+#include "../rand/SimplexNoise.hpp"
#include <algorithm>
#include <cmath>
+#include <iostream>
#include <glm/gtc/matrix_transform.hpp>
#include <glm/gtx/euler_angles.hpp>
+#include <glm/gtx/io.hpp>
#include <glm/gtx/transform.hpp>
using blobs::G;
, orbital(1.0)
, inverse_orbital(1.0)
, local(1.0)
-, inverse_local(1.0) {
+, inverse_local(1.0)
+, creatures() {
}
Body::~Body() {
+ for (Creature *c : creatures) {
+ delete c;
+ }
}
void Body::SetSimulation(Simulation &s) noexcept {
* glm::eulerAngleY(-rotation);
}
+void Body::AddCreature(Creature *c) {
+ c->SetBody(*this);
+ creatures.push_back(c);
+}
+
Orbit::Orbit()
: sma(1.0)
double P = sma * (cos(E) - ecc);
double Q = sma * sin(E) * sqrt(1 - (ecc * ecc));
- return glm::translate(glm::yawPitchRoll(asc, inc, arg), glm::dvec3(P, 0.0, -Q));
+ return glm::yawPitchRoll(asc, inc, arg) * glm::translate(glm::dvec3(P, 0.0, -Q));
}
glm::dmat4 Orbit::InverseMatrix(double t) const noexcept {
double E = mean2eccentric(M, ecc);
double P = sma * (cos(E) - ecc);
double Q = sma * sin(E) * sqrt(1 - (ecc * ecc));
- return glm::transpose(glm::yawPitchRoll(asc, inc, arg)) * glm::translate(glm::dvec3(-P, 0.0, Q));
+ return glm::translate(glm::dvec3(-P, 0.0, Q)) * glm::transpose(glm::yawPitchRoll(asc, inc, arg));
}
Planet::Planet(int sidelength)
: Body()
, sidelength(sidelength)
-, tiles(new Tile[TilesTotal()])
+, tiles(TilesTotal())
+, atmosphere(-1)
, vao() {
Radius(double(sidelength) / 2.0);
}
Planet::~Planet() {
}
-void Planet::BuildVAOs() {
+glm::dvec3 Planet::TileCenter(int surface, int x, int y) const noexcept {
+ glm::dvec3 center(0.0f);
+ center[(surface + 0) % 3] = x + 0.5 - Radius();
+ center[(surface + 1) % 3] = y + 0.5 - Radius();
+ center[(surface + 2) % 3] = surface < 3 ? Radius() : -Radius();
+ return center;
+}
+
+void Planet::BuildVAO(const Set<TileType> &ts) {
vao.Bind();
vao.BindAttributes();
vao.EnableAttribute(0);
vao.ReserveAttributes(TilesTotal() * 4, GL_STATIC_DRAW);
{
auto attrib = vao.MapAttributes(GL_WRITE_ONLY);
- float offset = sidelength * 0.5f;
+ float offset = Radius();
// srf 0 1 2 3 4 5
// up +Z +X +Y -Z -X -Y
for (int index = 0, surface = 0; surface < 6; ++surface) {
for (int y = 0; y < sidelength; ++y) {
for (int x = 0; x < sidelength; ++x, ++index) {
- float tex = TileAt(surface, x, y).type;
+ float tex = ts[TileAt(surface, x, y).type].texture;
+ const float tex_u_begin = surface < 3 ? 1.0f : 0.0f;
+ const float tex_u_end = surface < 3 ? 0.0f : 1.0f;
attrib[4 * index + 0].position[(surface + 0) % 3] = x + 0 - offset;
attrib[4 * index + 0].position[(surface + 1) % 3] = y + 0 - offset;
attrib[4 * index + 0].position[(surface + 2) % 3] = surface < 3 ? offset : -offset;
- attrib[4 * index + 0].tex_coord[0] = 0.0f;
- attrib[4 * index + 0].tex_coord[1] = 0.0f;
+ attrib[4 * index + 0].tex_coord[0] = tex_u_begin;
+ attrib[4 * index + 0].tex_coord[1] = 1.0f;
attrib[4 * index + 0].tex_coord[2] = tex;
attrib[4 * index + 1].position[(surface + 0) % 3] = x + 0 - offset;
attrib[4 * index + 1].position[(surface + 1) % 3] = y + 1 - offset;
attrib[4 * index + 1].position[(surface + 2) % 3] = surface < 3 ? offset : -offset;
- attrib[4 * index + 1].tex_coord[0] = 0.0f;
+ attrib[4 * index + 1].tex_coord[0] = tex_u_end;
attrib[4 * index + 1].tex_coord[1] = 1.0f;
attrib[4 * index + 1].tex_coord[2] = tex;
attrib[4 * index + 2].position[(surface + 0) % 3] = x + 1 - offset;
attrib[4 * index + 2].position[(surface + 1) % 3] = y + 0 - offset;
attrib[4 * index + 2].position[(surface + 2) % 3] = surface < 3 ? offset : -offset;
- attrib[4 * index + 2].tex_coord[0] = 1.0f;
+ attrib[4 * index + 2].tex_coord[0] = tex_u_begin;
attrib[4 * index + 2].tex_coord[1] = 0.0f;
attrib[4 * index + 2].tex_coord[2] = tex;
attrib[4 * index + 3].position[(surface + 0) % 3] = x + 1 - offset;
attrib[4 * index + 3].position[(surface + 1) % 3] = y + 1 - offset;
attrib[4 * index + 3].position[(surface + 2) % 3] = surface < 3 ? offset : -offset;
- attrib[4 * index + 3].tex_coord[0] = 1.0f;
- attrib[4 * index + 3].tex_coord[1] = 1.0f;
+ attrib[4 * index + 3].tex_coord[0] = tex_u_end;
+ attrib[4 * index + 3].tex_coord[1] = 0.0f;
attrib[4 * index + 3].tex_coord[2] = tex;
}
}
}
-void GenerateTest(Planet &p) {
+void GenerateEarthlike(const Set<TileType> &tiles, Planet &p) noexcept {
+ rand::SimplexNoise elevation_gen(0);
+ rand::SimplexNoise variation_gen(45623752346);
+
+ const int ice = tiles["ice"].id;
+ const int ocean = tiles["ocean"].id;
+ const int water = tiles["water"].id;
+ const int sand = tiles["sand"].id;
+ const int grass = tiles["grass"].id;
+ const int tundra = tiles["tundra"].id;
+ const int taiga = tiles["taiga"].id;
+ const int desert = tiles["desert"].id;
+ const int mntn = tiles["mountain"].id;
+ const int algae = tiles["algae"].id;
+ const int forest = tiles["forest"].id;
+ const int jungle = tiles["jungle"].id;
+ const int rock = tiles["rock"].id;
+ const int wheat = tiles["wheat"].id;
+
+ constexpr double ocean_thresh = -0.2;
+ constexpr double water_thresh = 0.0;
+ constexpr double beach_thresh = 0.05;
+ constexpr double highland_thresh = 0.4;
+ constexpr double mountain_thresh = 0.5;
+
+ const glm::dvec3 axis(glm::dvec4(0.0, 1.0, 0.0, 0.0) * glm::eulerAngleXY(p.SurfaceTilt().x, p.SurfaceTilt().y));
+ const double cap_thresh = std::abs(std::cos(p.AxialTilt().x));
+ const double equ_thresh = std::abs(std::sin(p.AxialTilt().x)) / 2.0;
+ const double fzone_start = equ_thresh - (equ_thresh - cap_thresh) / 3.0;
+ const double fzone_end = cap_thresh + (equ_thresh - cap_thresh) / 3.0;
+
for (int surface = 0; surface <= 5; ++surface) {
for (int y = 0; y < p.SideLength(); ++y) {
for (int x = 0; x < p.SideLength(); ++x) {
- p.TileAt(surface, x, y).type = (x == p.SideLength()/2) + (y == p.SideLength()/2);
+ glm::dvec3 to_tile = p.TileCenter(surface, x, y);
+ double near_axis = std::abs(glm::dot(glm::normalize(to_tile), axis));
+ if (near_axis > cap_thresh) {
+ p.TileAt(surface, x, y).type = ice;
+ continue;
+ }
+ float elevation = rand::OctaveNoise(
+ elevation_gen,
+ to_tile / p.Radius(),
+ 3, // octaves
+ 0.5, // persistence
+ 5 / p.Radius(), // frequency
+ 2, // amplitude
+ 2 // growth
+ );
+ float variation = rand::OctaveNoise(
+ variation_gen,
+ to_tile / p.Radius(),
+ 3, // octaves
+ 0.5, // persistence
+ 16 / p.Radius(), // frequency
+ 2, // amplitude
+ 2 // growth
+ );
+ if (elevation < ocean_thresh) {
+ p.TileAt(surface, x, y).type = ocean;
+ } else if (elevation < water_thresh) {
+ if (variation > 0.3) {
+ p.TileAt(surface, x, y).type = algae;
+ } else {
+ p.TileAt(surface, x, y).type = water;
+ }
+ } else if (elevation < beach_thresh) {
+ p.TileAt(surface, x, y).type = sand;
+ } else if (elevation < highland_thresh) {
+ if (near_axis < equ_thresh) {
+ if (variation > 0.6) {
+ p.TileAt(surface, x, y).type = grass;
+ } else if (variation > 0.2) {
+ p.TileAt(surface, x, y).type = sand;
+ } else {
+ p.TileAt(surface, x, y).type = desert;
+ }
+ } else if (near_axis < fzone_start) {
+ if (variation > 0.4) {
+ p.TileAt(surface, x, y).type = forest;
+ } else if (variation < -0.5) {
+ p.TileAt(surface, x, y).type = jungle;
+ } else if (variation > -0.02 && variation < 0.02) {
+ p.TileAt(surface, x, y).type = wheat;
+ } else {
+ p.TileAt(surface, x, y).type = grass;
+ }
+ } else if (near_axis < fzone_end) {
+ p.TileAt(surface, x, y).type = tundra;
+ } else {
+ p.TileAt(surface, x, y).type = taiga;
+ }
+ } else if (elevation < mountain_thresh) {
+ if (variation > 0.3) {
+ p.TileAt(surface, x, y).type = mntn;
+ } else {
+ p.TileAt(surface, x, y).type = rock;
+ }
+ } else {
+ p.TileAt(surface, x, y).type = mntn;
+ }
+ }
+ }
+ }
+ p.BuildVAO(tiles);
+}
+
+void GenerateTest(const Set<TileType> &tiles, Planet &p) noexcept {
+ for (int surface = 0; surface <= 5; ++surface) {
+ for (int y = 0; y < p.SideLength(); ++y) {
+ for (int x = 0; x < p.SideLength(); ++x) {
+ if (x == p.SideLength() / 2 && y == p.SideLength() / 2) {
+ p.TileAt(surface, x, y).type = surface;
+ } else {
+ p.TileAt(surface, x, y).type = (x == p.SideLength()/2) + (y == p.SideLength()/2) + 6;
+ }
}
}
}
- p.BuildVAOs();
+ p.BuildVAO(tiles);
}