96 lines
3.2 KiB
C++
96 lines
3.2 KiB
C++
#include "SkyRasterizer.h"
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#include "Vector3.h"
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#include "Color.h"
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#include "SoftwareRenderer.h"
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#include "AtmosphereRenderer.h"
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#include "AtmosphereResult.h"
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#include "CloudsRenderer.h"
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#include "Rasterizer.h"
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#include "CanvasFragment.h"
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#include "RenderProgress.h"
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#include "GodRaysSampler.h"
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#define SPHERE_SIZE 20000.0
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SkyRasterizer::SkyRasterizer(SoftwareRenderer *renderer, RenderProgress *progress, int client_id)
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: Rasterizer(renderer, progress, client_id, Color(0.9, 0.9, 1.0)) {
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}
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int SkyRasterizer::prepareRasterization() {
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return res_i * res_j;
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}
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void SkyRasterizer::rasterizeToCanvas(CanvasPortion *canvas) {
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int i, j;
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double step_i, step_j;
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double current_i, current_j;
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Vector3 vertex1, vertex2, vertex3, vertex4;
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Vector3 camera_location, direction;
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step_i = M_PI * 2.0 / (double)res_i;
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step_j = M_PI / (double)res_j;
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camera_location = renderer->getCameraLocation(VECTOR_ZERO);
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for (j = 0; j < res_j; j++) {
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if (interrupted) {
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return;
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}
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current_j = (double)(j - res_j / 2) * step_j;
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for (i = 0; i < res_i; i++) {
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current_i = (double)i * step_i;
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direction.x = SPHERE_SIZE * cos(current_i) * cos(current_j);
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direction.y = SPHERE_SIZE * sin(current_j);
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direction.z = SPHERE_SIZE * sin(current_i) * cos(current_j);
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vertex1 = camera_location.add(direction);
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direction.x = SPHERE_SIZE * cos(current_i + step_i) * cos(current_j);
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direction.y = SPHERE_SIZE * sin(current_j);
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direction.z = SPHERE_SIZE * sin(current_i + step_i) * cos(current_j);
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vertex2 = camera_location.add(direction);
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direction.x = SPHERE_SIZE * cos(current_i + step_i) * cos(current_j + step_j);
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direction.y = SPHERE_SIZE * sin(current_j + step_j);
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direction.z = SPHERE_SIZE * sin(current_i + step_i) * cos(current_j + step_j);
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vertex3 = camera_location.add(direction);
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direction.x = SPHERE_SIZE * cos(current_i) * cos(current_j + step_j);
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direction.y = SPHERE_SIZE * sin(current_j + step_j);
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direction.z = SPHERE_SIZE * sin(current_i) * cos(current_j + step_j);
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vertex4 = camera_location.add(direction);
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// TODO Triangles at poles
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pushQuad(canvas, vertex1, vertex4, vertex3, vertex2);
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}
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progress->add(res_i);
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}
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}
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Color SkyRasterizer::shadeFragment(const CanvasFragment &fragment, const CanvasFragment *) const {
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Vector3 location = fragment.getLocation();
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Vector3 camera_location, direction;
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Color result;
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camera_location = renderer->getCameraLocation(location);
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direction = location.sub(camera_location);
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// TODO Don't compute sky color if it's fully covered by clouds
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result = renderer->getAtmosphereRenderer()->getSkyColor(direction.normalize()).final;
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result =
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renderer->getCloudsRenderer()->getColor(camera_location, camera_location.add(direction.scale(10.0)), result);
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return result;
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}
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void SkyRasterizer::setQuality(int res_i, int res_j) {
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this->res_i = res_i;
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this->res_j = res_j;
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}
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void SkyRasterizer::setQuality(double factor) {
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setQuality(20.0 * (1.0 + factor * 10.0), 10.0 * (1.0 + factor * 10.0));
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}
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