Michaël Lemaire
418fe54b26
git-svn-id: https://subversion.assembla.com/svn/thunderk/paysages@273 b1fd45b6-86a6-48da-8261-f70d1f35bdcc
317 lines
9.9 KiB
C
317 lines
9.9 KiB
C
#include "water.h"
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#include "shared/types.h"
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#include "shared/constants.h"
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#include "color.h"
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#include "euclid.h"
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#include "render.h"
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#include "terrain.h"
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#include "lighting.h"
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#include "tools.h"
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#include <math.h>
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void waterInit()
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{
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}
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void waterQuit()
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{
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}
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void waterSave(FILE* f, WaterDefinition* definition)
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{
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toolsSaveDouble(f, &definition->height);
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materialSave(f, &definition->material);
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colorSave(f, &definition->depth_color);
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toolsSaveDouble(f, &definition->transparency_depth);
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toolsSaveDouble(f, &definition->transparency);
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toolsSaveDouble(f, &definition->reflection);
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toolsSaveDouble(f, &definition->lighting_depth);
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noiseSaveGenerator(f, definition->waves_noise);
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toolsSaveDouble(f, &definition->waves_noise_height);
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toolsSaveDouble(f, &definition->waves_noise_scale);
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}
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void waterLoad(FILE* f, WaterDefinition* definition)
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{
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toolsLoadDouble(f, &definition->height);
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materialLoad(f, &definition->material);
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colorLoad(f, &definition->depth_color);
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toolsLoadDouble(f, &definition->transparency_depth);
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toolsLoadDouble(f, &definition->transparency);
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toolsLoadDouble(f, &definition->reflection);
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toolsLoadDouble(f, &definition->lighting_depth);
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noiseLoadGenerator(f, definition->waves_noise);
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toolsLoadDouble(f, &definition->waves_noise_height);
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toolsLoadDouble(f, &definition->waves_noise_scale);
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waterValidateDefinition(definition);
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}
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WaterDefinition waterCreateDefinition()
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{
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WaterDefinition result;
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result.material.base = COLOR_BLACK;
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result.material.reflection = 0.0;
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result.material.shininess = 0.0;
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result.depth_color = COLOR_BLACK;
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result.height = -1000.0;
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result.reflection = 0.0;
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result.transparency = 0.0;
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result.transparency_depth = 0.0;
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result.lighting_depth = 0.0;
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result.waves_noise = noiseCreateGenerator();
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result.waves_noise_height = 0.02;
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result.waves_noise_scale = 0.2;
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return result;
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}
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void waterDeleteDefinition(WaterDefinition* definition)
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{
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noiseDeleteGenerator(definition->waves_noise);
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}
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void waterCopyDefinition(WaterDefinition* source, WaterDefinition* destination)
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{
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NoiseGenerator* noise;
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noise = destination->waves_noise;
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*destination = *source;
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destination->waves_noise = noise;
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noiseCopy(source->waves_noise, destination->waves_noise);
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}
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void waterValidateDefinition(WaterDefinition* definition)
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{
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}
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static inline double _getHeight(WaterDefinition* definition, double x, double z, double detail)
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{
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return definition->height + noiseGet2DDetail(definition->waves_noise, x / definition->waves_noise_scale, z / definition->waves_noise_scale, detail) * definition->waves_noise_height;
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}
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static inline Vector3 _getNormal(WaterDefinition* definition, Vector3 base, double detail)
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{
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Vector3 back, right;
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double x, z;
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x = base.x;
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z = base.z;
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back.x = x;
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back.y = _getHeight(definition, x, z + detail, detail);
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back.z = z + detail;
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back = v3Sub(back, base);
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right.x = x + detail;
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right.y = _getHeight(definition, x + detail, z, detail);
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right.z = z;
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right = v3Sub(right, base);
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return v3Normalize(v3Cross(back, right));
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}
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static inline Vector3 _reflectRay(Vector3 incoming, Vector3 normal)
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{
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double c;
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c = v3Dot(normal, v3Scale(incoming, -1.0));
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return v3Add(incoming, v3Scale(normal, 2.0 * c));
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}
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static inline Vector3 _refractRay(Vector3 incoming, Vector3 normal)
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{
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double c1, c2, f;
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f = 1.0 / 1.33;
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c1 = v3Dot(normal, v3Scale(incoming, -1.0));
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c2 = sqrt(1.0 - pow(f, 2.0) * (1.0 - pow(c1, 2.0)));
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if (c1 >= 0.0)
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{
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return v3Add(v3Scale(incoming, f), v3Scale(normal, f * c1 - c2));
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}
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else
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{
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return v3Add(v3Scale(incoming, f), v3Scale(normal, c2 - f * c1));
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}
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}
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HeightInfo waterGetHeightInfo(WaterDefinition* definition)
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{
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HeightInfo info;
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info.base_height = definition->height;
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info.min_height = definition->height - noiseGetMaxValue(definition->waves_noise) * definition->waves_noise_height;
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info.max_height = definition->height + noiseGetMaxValue(definition->waves_noise) * definition->waves_noise_height;
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return info;
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}
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Color waterLightFilter(WaterDefinition* definition, Renderer* renderer, Color light, Vector3 location, Vector3 light_location, Vector3 direction_to_light)
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{
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double factor;
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if (location.y < definition->height)
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{
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if (direction_to_light.y > 0.00001)
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{
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factor = (definition->height - location.y) / (direction_to_light.y * definition->lighting_depth);
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if (factor > 1.0)
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{
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factor = 1.0;
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}
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factor = 1.0 - 0.8 * factor;
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light.r *= factor;
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light.g *= factor;
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light.b *= factor;
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return light;
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}
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else
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{
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return COLOR_BLACK;
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}
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}
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else
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{
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return light;
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}
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}
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WaterResult waterGetColorDetail(WaterDefinition* definition, Renderer* renderer, Vector3 location, Vector3 look)
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{
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WaterResult result;
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RayCastingResult refracted;
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Vector3 normal;
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Color color;
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SurfaceMaterial material;
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double detail, depth;
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detail = renderer->getPrecision(renderer, location);
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location.y = _getHeight(definition, location.x, location.z, detail);
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result.location = location;
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normal = _getNormal(definition, location, detail);
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look = v3Normalize(look);
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result.reflected = renderer->rayWalking(renderer, location, _reflectRay(look, normal), 1, 0, 1, 1).hit_color;
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refracted = renderer->rayWalking(renderer, location, _refractRay(look, normal), 1, 0, 1, 1);
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depth = v3Norm(v3Sub(location, refracted.hit_location));
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if (depth > definition->transparency_depth)
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{
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result.refracted = definition->depth_color;
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}
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else
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{
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depth /= definition->transparency_depth;
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result.refracted.r = refracted.hit_color.r * (1.0 - depth) + definition->depth_color.r * depth;
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result.refracted.g = refracted.hit_color.g * (1.0 - depth) + definition->depth_color.g * depth;
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result.refracted.b = refracted.hit_color.b * (1.0 - depth) + definition->depth_color.b * depth;
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result.refracted.a = 1.0;
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}
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color.r = definition->material.base.r * (1.0 - definition->transparency) + result.reflected.r * definition->reflection + result.refracted.r * definition->transparency;
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color.g = definition->material.base.g * (1.0 - definition->transparency) + result.reflected.g * definition->reflection + result.refracted.g * definition->transparency;
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color.b = definition->material.base.b * (1.0 - definition->transparency) + result.reflected.b * definition->reflection + result.refracted.b * definition->transparency;
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color.a = 1.0;
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material = definition->material;
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material.base = color;
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color = renderer->applyLightingToSurface(renderer, location, normal, material);
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color = renderer->applyAtmosphere(renderer, location, color);
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color = renderer->applyClouds(renderer, color, renderer->camera_location, location);
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result.base = definition->material.base;
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result.final = color;
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return result;
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}
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Color waterGetColor(WaterDefinition* definition, Renderer* renderer, Vector3 location, Vector3 look)
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{
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return waterGetColorDetail(definition, renderer, location, look).final;
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}
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static int _postProcessFragment(RenderFragment* fragment, Renderer* renderer, void* data)
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{
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fragment->vertex.color = waterGetColor((WaterDefinition*)data, renderer, fragment->vertex.location, v3Sub(fragment->vertex.location, renderer->camera_location));
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return 1;
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}
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static Vertex _getFirstPassVertex(WaterDefinition* definition, double x, double z, double precision)
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{
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Vertex result;
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double value;
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result.location.x = x;
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result.location.y = _getHeight(definition, x, z, 0.0);
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result.location.z = z;
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value = sin(x) * sin(x) * cos(z) * cos(z);
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result.color.r = 0.0;
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result.color.g = value;
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result.color.b = value;
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result.color.a = 1.0;
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result.normal.x = result.normal.y = result.normal.z = 0.0;
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result.callback = _postProcessFragment;
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result.callback_data = definition;
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return result;
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}
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static void _renderQuad(WaterDefinition* definition, Renderer* renderer, double x, double z, double size)
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{
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Vertex v1, v2, v3, v4;
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v1 = _getFirstPassVertex(definition, x, z, size);
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v2 = _getFirstPassVertex(definition, x, z + size, size);
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v3 = _getFirstPassVertex(definition, x + size, z + size, size);
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v4 = _getFirstPassVertex(definition, x + size, z, size);
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renderer->pushQuad(renderer, &v1, &v2, &v3, &v4);
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}
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void waterRender(WaterDefinition* definition, Renderer* renderer)
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{
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int chunk_factor, chunk_count, i;
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double cx = renderer->camera_location.x;
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double cz = renderer->camera_location.z;
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double radius_int, radius_ext, base_chunk_size, chunk_size;
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base_chunk_size = 2.0 / (double)renderer->render_quality;
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chunk_factor = 1;
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chunk_count = 2;
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radius_int = 0.0;
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radius_ext = base_chunk_size;
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chunk_size = base_chunk_size;
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while (radius_ext < 1000.0)
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{
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if (!renderer->addRenderProgress(renderer, 0.0))
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{
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return;
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}
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for (i = 0; i < chunk_count - 1; i++)
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{
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_renderQuad(definition, renderer, cx - radius_ext + chunk_size * i, cz - radius_ext, chunk_size);
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_renderQuad(definition, renderer, cx + radius_int, cz - radius_ext + chunk_size * i, chunk_size);
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_renderQuad(definition, renderer, cx + radius_int - chunk_size * i, cz + radius_int, chunk_size);
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_renderQuad(definition, renderer, cx - radius_ext, cz + radius_int - chunk_size * i, chunk_size);
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}
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if (radius_int > 20.0 && chunk_count % 64 == 0 && (double)chunk_factor < radius_int / 20.0)
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{
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chunk_count /= 2;
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chunk_factor *= 2;
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}
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chunk_count += 2;
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chunk_size = base_chunk_size * chunk_factor;
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radius_int = radius_ext;
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radius_ext += chunk_size;
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}
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}
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