Added render test for clouds lighting

This will allow to validate future changes

src/basics/Maths.cpp

@@ -1,6 +1,7 @@
 #include "Maths.h"
 
 #include <cmath>
+#include <algorithm>
 
 double Maths::modInRange(double value, double min, double max) {
     double size = max - min;
@@ -12,3 +13,12 @@ double Maths::modInRange(double value, double min, double max) {
         return modulo * size + min;
     }
 }
+
+double Maths::clamp(double x, double minval, double maxval) {
+    return min(max(x, minval), maxval);
+}
+
+double Maths::smoothstep(double edge0, double edge1, double x) {
+    x = clamp((x - edge0) / (edge1 - edge0), 0.0, 1.0);
+    return x * x * (3.0 - 2.0 * x);
+}

src/basics/Maths.h

@@ -16,6 +16,16 @@ class BASICSSHARED_EXPORT Maths {
      */
     static double modInRange(double value, double min, double max);
 
+    /**
+     * Constraint a value in the [min,max[ range, by clamping it.
+     */
+    static double clamp(double x, double minval, double maxval);
+
+    /**
+     * Returns 0.0 when x < edge0, 1.0 when y > edge1, and a smoothly interpolated value in-between.
+     */
+    static double smoothstep(double edge0, double edge1, double x);
+
     static constexpr double PI = 3.141592653589793238462643383279;
     static constexpr double PI_2 = PI / 2.0;
     static constexpr double PI_4 = PI / 4.0;

src/interface/commandline/tests.cpp

@@ -1,6 +1,7 @@
 #include "SoftwareCanvasRenderer.h"
 #include "TerrainRenderer.h"
 #include "Scenery.h"
+#include "Maths.h"
 #include "CameraDefinition.h"
 #include "TerrainDefinition.h"
 #include "AtmosphereDefinition.h"
@@ -24,6 +25,9 @@
 #include "VegetationModelDefinition.h"
 #include "VegetationInstance.h"
 #include "VegetationRenderer.h"
+#include "CloudsRenderer.h"
+#include "CloudLayerDefinition.h"
+#include "clouds/BaseCloudsModel.h"
 #include "CelestialBodyDefinition.h"
 #include "RayCastingResult.h"
 #include "OpenGLVegetationImpostor.h"
@@ -283,8 +287,7 @@ static void testAtmosphereBruneton() {
 
     class TestRasterizer : public OverlayRasterizer {
       public:
-        TestRasterizer(SoftwareCanvasRenderer *renderer)
-            : OverlayRasterizer(renderer, renderer->getProgressHelper()), renderer(renderer) {
+        TestRasterizer(SoftwareCanvasRenderer *renderer) : OverlayRasterizer(renderer), renderer(renderer) {
         }
         virtual Color processPixel(int, int, double relx, double rely) const override {
             if (rely > 0.0) {
@@ -313,8 +316,8 @@ static void testVegetationModels() {
     class InstanceRenderer : public SoftwareCanvasRenderer, public OverlayRasterizer, public LightFilter {
       public:
         InstanceRenderer(Scenery *scenery, const VegetationModelDefinition &model)
-            : SoftwareCanvasRenderer(scenery), OverlayRasterizer(this, this->getProgressHelper()),
-              instance(model, VECTOR_ZERO), vegetation(renderer->getVegetationRenderer()) {
+            : SoftwareCanvasRenderer(scenery), OverlayRasterizer(this), instance(model, VECTOR_ZERO),
+              vegetation(renderer->getVegetationRenderer()) {
         }
         virtual void prepare() override {
             SoftwareCanvasRenderer::prepare();
@@ -454,12 +457,78 @@ static void testCelestialBodies() {
     startTestRender(&renderer, "celestial_bodies_solar_eclipse");
 }
 
+static void testCloudsLighting() {
+    class FakeModel : public BaseCloudsModel {
+      public:
+        FakeModel(CloudLayerDefinition *layer, double scale) : BaseCloudsModel(layer), scale(scale) {
+        }
+        virtual void getAltitudeRange(double *min_altitude, double *max_altitude) const override {
+            *min_altitude = -scale;
+            *max_altitude = scale;
+        }
+        virtual void getDetailRange(double *min_step, double *max_step) const override {
+            *min_step = *max_step = scale * 0.01;
+        }
+        virtual double getDensity(const Vector3 &location) const override {
+            return Maths::smoothstep(0.0, 0.2, 1.0 - location.getNorm() / scale);
+        }
+        double scale;
+    };
+
+    class FakeRasterizer : public OverlayRasterizer {
+      public:
+        FakeRasterizer(SoftwareCanvasRenderer *renderer, double scale) : OverlayRasterizer(renderer), scale(scale) {
+        }
+        virtual Color processPixel(int, int, double relx, double rely) const override {
+            auto cloud_renderer = renderer->getCloudsRenderer();
+            auto atmo_renderer = renderer->getAtmosphereRenderer();
+            return cloud_renderer->getColor(Vector3(relx * scale * 1.2, rely * scale * 1.2, scale),
+                                            Vector3(relx * scale * 1.2, rely * scale * 1.2, -scale),
+                                            atmo_renderer->getSkyColor(Vector3(relx, rely, 1.0).normalize()).final);
+        }
+        virtual int prepareRasterization() override {
+            auto model = new FakeModel(renderer->getScenery()->getClouds()->getCloudLayer(0), scale);
+            renderer->getCloudsRenderer()->setLayerModel(0, model);
+            renderer->getCloudsRenderer()->setQuality(0.9);
+            renderer->getLightingManager()->clearFilters();
+            renderer->getLightingManager()->registerFilter(renderer->getCloudsRenderer());
+            return OverlayRasterizer::prepareRasterization();
+        }
+        double scale;
+        FakeModel *model;
+    };
+
+    Scenery scenery;
+    scenery.autoPreset(1);
+    scenery.getCamera()->setTarget(VECTOR_ZERO);
+    scenery.getCamera()->setLocation(Vector3(0.0, 0.0, 5.0));
+
+    CloudLayerDefinition layer(NULL, "test");
+    scenery.getClouds()->clear();
+    scenery.getClouds()->addLayer(layer);
+
+    SoftwareCanvasRenderer renderer(&scenery);
+    FakeRasterizer rasterizer(&renderer, 10.0);
+    renderer.setSize(800, 800);
+    renderer.setSoloRasterizer(&rasterizer);
+    renderer.getGodRaysSampler()->setEnabled(false);
+    renderer.setAerialPerspectiveEnabled(false);
+
+    scenery.getAtmosphere()->setDayTime(10);
+    startTestRender(&renderer, "clouds_lighting_day");
+    scenery.getAtmosphere()->setDayTime(6, 30);
+    startTestRender(&renderer, "clouds_lighting_dusk");
+    scenery.getAtmosphere()->setDayTime(3);
+    startTestRender(&renderer, "clouds_lighting_night");
+}
+
 void runTestSuite() {
     testNoise();
     testTextures();
     testGodRays();
     testCelestialBodies();
     testNearFrustum();
+    testCloudsLighting();
     testCloudsNearGround();
     testVegetationModels();
     testOpenGLVegetationImpostor();

src/render/software/OverlayRasterizer.cpp

@@ -2,12 +2,12 @@
 
 #include <cmath>
 #include "Color.h"
-#include "SoftwareRenderer.h"
+#include "SoftwareCanvasRenderer.h"
 #include "CameraDefinition.h"
 #include "CanvasFragment.h"
 
-OverlayRasterizer::OverlayRasterizer(SoftwareRenderer *renderer, RenderProgress *progress)
-    : Rasterizer(renderer, progress, 0, COLOR_WHITE) {
+OverlayRasterizer::OverlayRasterizer(SoftwareCanvasRenderer *renderer)
+    : Rasterizer(renderer, renderer->getProgressHelper(), 0, COLOR_WHITE) {
 }
 
 int OverlayRasterizer::prepareRasterization() {

src/render/software/OverlayRasterizer.h

@@ -15,15 +15,17 @@ namespace software {
  */
 class SOFTWARESHARED_EXPORT OverlayRasterizer : public Rasterizer {
   public:
-    OverlayRasterizer(SoftwareRenderer *renderer, RenderProgress *progress);
+    OverlayRasterizer(SoftwareCanvasRenderer *renderer);
 
     /**
      * Abstract method to implement to shade each pixel.
      */
     virtual Color processPixel(int x, int y, double relx, double rely) const = 0;
 
-  private:
+  protected:
     virtual int prepareRasterization();
+
+  private:
     virtual void rasterizeToCanvas(CanvasPortion *canvas);
     virtual Color shadeFragment(const CanvasFragment &fragment, const CanvasFragment *previous) const;
 };

src/render/software/SoftwareRenderer.cpp

@@ -40,10 +40,12 @@ SoftwareRenderer::SoftwareRenderer(Scenery *scenery) : scenery(scenery) {
     nightsky_renderer = new NightSky(this);
     moon_renderer = new MoonRenderer(scenery->getAtmosphere()->childMoon());
 
-    fluid_medium = new FluidMediumManager(this);
+    fluid_medium = new FluidMediumManager(this); // TODO Not used yet
     lighting = new LightingManager();
     godrays = new GodRaysSampler();
 
+    aerial_perspective = true;
+
     lighting->registerFilter(water_renderer);
     lighting->registerFilter(terrain_renderer);
     lighting->registerFilter(vegetation_renderer);
@@ -111,15 +113,23 @@ void SoftwareRenderer::setQuality(double quality) {
     render_quality = trunc_to_int(quality * 9.0) + 1;
 }
 
+void SoftwareRenderer::setAerialPerspectiveEnabled(bool enabled) {
+    aerial_perspective = enabled;
+}
+
 Color SoftwareRenderer::applyLightingToSurface(const Vector3 &location, const Vector3 &normal,
                                                const SurfaceMaterial &material) {
     return lighting->apply(getCameraLocation(), location, normal, material);
 }
 
 Color SoftwareRenderer::applyMediumTraversal(const Vector3 &location, const Color &color) {
-    Color result = atmosphere_renderer->applyAerialPerspective(location, color).final;
-    result = clouds_renderer->getColor(getCameraLocation(), location, result);
-    return result;
+    if (aerial_perspective) {
+        Color result = atmosphere_renderer->applyAerialPerspective(location, color).final;
+        result = clouds_renderer->getColor(getCameraLocation(), location, result);
+        return result;
+    } else {
+        return color;
+    }
 }
 
 RayCastingResult SoftwareRenderer::rayWalking(const Vector3 &location, const Vector3 &direction, int, int, int, int) {

src/render/software/SoftwareRenderer.h

@@ -82,6 +82,8 @@ class SOFTWARESHARED_EXPORT SoftwareRenderer {
         return godrays;
     }
 
+    void setAerialPerspectiveEnabled(bool enabled);
+
     virtual Color applyLightingToSurface(const Vector3 &location, const Vector3 &normal,
                                          const SurfaceMaterial &material);
     virtual Color applyMediumTraversal(const Vector3 &location, const Color &color);
@@ -91,6 +93,8 @@ class SOFTWARESHARED_EXPORT SoftwareRenderer {
   private:
     Scenery *scenery;
 
+    bool aerial_perspective;
+
     FluidMediumManager *fluid_medium;
     LightingManager *lighting;
     GodRaysSampler *godrays;

src/render/software/clouds/BaseCloudsModel.cpp

@@ -25,6 +25,7 @@ void BaseCloudsModel::getDetailRange(double *min_step, double *max_step) const {
 }
 
 double BaseCloudsModel::getProbability(const Vector3 &, double) const {
+    // FIXME not used !
     return 1.0;
 }
 
@@ -33,9 +34,11 @@ double BaseCloudsModel::getDensity(const Vector3 &) const {
 }
 
 Color BaseCloudsModel::filterLight(const Color &light, double, double) const {
+    // FIXME not used !
     return light;
 }
 
 Color BaseCloudsModel::applyLightExit(const Color &light, const Vector3 &, const Vector3 &) const {
+    // FIXME not used !
     return light;
 }

src/tests/OverlayRasterizer_Test.cpp

@@ -13,12 +13,12 @@ typedef struct {
     double rely;
 } PixelCall;
 
-vector<PixelCall> calls;
+static vector<PixelCall> calls;
 
+namespace {
 class MockOverlayRasterizer : public OverlayRasterizer {
   public:
-    MockOverlayRasterizer(SoftwareCanvasRenderer *renderer)
-        : OverlayRasterizer(renderer, renderer->getProgressHelper()) {
+    MockOverlayRasterizer(SoftwareCanvasRenderer *renderer) : OverlayRasterizer(renderer) {
     }
 
     virtual Color processPixel(int x, int y, double relx, double rely) const override {
@@ -27,6 +27,7 @@ class MockOverlayRasterizer : public OverlayRasterizer {
         return COLOR_BLUE;
     }
 };
+}
 
 void checkCall(const PixelCall &call, int x, int y, double relx, double rely) {
     EXPECT_EQ(x, call.x);
@@ -45,7 +46,7 @@ TEST(OverlayRasterizer, pixelProcessing) {
     renderer.setSoloRasterizer(&rasterizer);
     renderer.render();
 
-    ASSERT_EQ(12, (int)calls.size());
+    ASSERT_EQ(12u, calls.size());
     checkCall(calls[0], 0, 0, -1.5, -1.0);
     checkCall(calls[1], 0, 2, -1.5, 1.0);
     checkCall(calls[2], 2, 0, 0.5, -1.0);