Make weather system interpolate gradients based on elevation angles rather than time of day

3 years ago · 065f180471
--- a/src/game/bootloader.cpp
+++ b/src/game/bootloader.cpp
@ -1179,7 +1179,7 @@ void setup_controls(game_context* ctx)
 	(
 		[ctx, time_scale]()
 		{
 			ctx->weather_system->set_time_scale(time_scale * 500.0f);
 			ctx->weather_system->set_time_scale(time_scale * 50.0f);
 		}
 	);
 	ctx->control_system->get_fast_forward_control()->set_deactivated_callback
@ -1193,7 +1193,7 @@ void setup_controls(game_context* ctx)
 	(
 		[ctx, time_scale]()
 		{
 			ctx->weather_system->set_time_scale(time_scale * -500.0f);
 			ctx->weather_system->set_time_scale(time_scale * -50.0f);
 		}
 	);
 	ctx->control_system->get_rewind_control()->set_deactivated_callback
--- a/src/game/systems/weather-system.cpp
+++ b/src/game/systems/weather-system.cpp
@ -150,8 +150,8 @@ void equatorial_to_horizontal(double right_ascension, double declination, double
 	double horiz_y = y;
 	double horiz_z = x * std::sin(math::half_pi<double> - latitude) + z * std::cos(math::half_pi<double> - latitude);
 	
 	*azimuth = std::atan2(horiz_y, horiz_x) + math::pi<double>;
 	*elevation = std::atan2(horiz_z, std::sqrt(horiz_x * horiz_x + horiz_y * horiz_y));
 	*azimuth = math::wrap_radians<double>(std::atan2(horiz_y, horiz_x) + math::pi<double>);
 	*elevation = math::wrap_radians<double>(std::atan2(horiz_z, std::sqrt(horiz_x * horiz_x + horiz_y * horiz_y)));
 }

 /**
@ -289,37 +289,39 @@ void weather_system::update(double t, double dt)
 	std::size_t hour_index = static_cast<std::size_t>(hour);
 	float lerp_factor = hour - std::floor(hour);
 	
 	
 	float sun_gradient_position = static_cast<float>(std::max<double>(0.0, ((sun_elevation + math::half_pi<double>) / math::pi<double>)));
 	float moon_gradient_position = static_cast<float>(std::max<double>(0.0, ((moon_elevation + math::half_pi<double>) / math::pi<double>)));
 	float sky_gradient_position = sun_gradient_position;
 	float ambient_gradient_position = sun_gradient_position;
 	
 	if (sky_pass)
 	{
 		const std::array<float4, 4>& gradient0 = sky_gradients[hour_index];
 		const std::array<float4, 4>& gradient1 = sky_gradients[(hour_index + 1) % sky_gradients.size()];

 		
 		std::array<float4, 4> gradient;
 		for (int i = 0; i < 4; ++i)
 		//std::cout << "sungrad: " << (sun_gradient_position* static_cast<float>(sky_gradients.size() - 1)) << std::endl;
 		//std::cout << "sunel: " << math::degrees(sun_elevation) << std::endl;
 		
 		std::array<float4, 4> sky_gradient;
 		{
 			gradient[i] = math::lerp(gradient0[i], gradient1[i], lerp_factor);
 			sky_gradient_position *= static_cast<float>(sky_gradients.size() - 1);
 			int index0 = static_cast<int>(sky_gradient_position) % sky_gradients.size();
 			int index1 = (index0 + 1) % sky_gradients.size();
 			sky_gradient_position -= std::floor(sky_gradient_position);
 			for (int i = 0; i < 4; ++i)
 				sky_gradient[i] = math::lerp(sky_gradients[index0][i], sky_gradients[index1][i], sky_gradient_position);
 		}
 		
 		float3 sun_color0 = sun_colors[hour_index];
 		float3 sun_color1 = sun_colors[(hour_index + 1) % sun_colors.size()];
 		float3 sun_color = math::lerp(sun_color0, sun_color1, lerp_factor);
 		
 		float3 moon_color0 = moon_colors[hour_index];
 		float3 moon_color1 = moon_colors[(hour_index + 1) % moon_colors.size()];
 		float3 moon_color = math::lerp(moon_color0, moon_color1, lerp_factor);
 		
 		float3 ambient_color0 = ambient_colors[hour_index];
 		float3 ambient_color1 = ambient_colors[(hour_index + 1) % sun_colors.size()];
 		float3 ambient_color = math::lerp(ambient_color0, ambient_color1, lerp_factor);
 		float3 sun_color = interpolate_gradient(sun_colors, sun_gradient_position);
 		float3 moon_color = interpolate_gradient(moon_colors, moon_gradient_position);
 		float3 ambient_color = interpolate_gradient(ambient_colors, ambient_gradient_position);
 		
 		sun_light->set_color(sun_color);
 		
 		moon_light->set_color(moon_color);
 		moon_light->set_intensity(1.0f);
 		
 		ambient_light->set_color(ambient_color);
 		
 		sky_pass->set_sky_gradient(gradient);
 		sky_pass->set_sky_gradient(sky_gradient);
 		sky_pass->set_time_of_day(static_cast<float>(hour * 60.0 * 60.0));
 		sky_pass->set_observer_coordinates(coordinates);
 		sky_pass->set_sun_coordinates(sun_position, sun_az_el);
@ -342,10 +344,7 @@ void weather_system::update(double t, double dt)
 	
 	if (material_pass)
 	{
 		float shadow_strength0 = shadow_strengths[hour_index];
 		float shadow_strength1 = shadow_strengths[(hour_index + 1) % shadow_strengths.size()];
 		float shadow_strength = math::lerp(shadow_strength0, shadow_strength1, lerp_factor);
 		
 		float shadow_strength = interpolate_gradient(shadow_strengths, sun_gradient_position);
 		material_pass->set_shadow_strength(shadow_strength);
 	}
 }
--- a/src/game/systems/weather-system.hpp
+++ b/src/game/systems/weather-system.hpp
@ -57,10 +57,11 @@ public:
 	void set_shadow_palette(const ::image* image);
 	
 private:
 	template <typename T>
 	static T interpolate_gradient(const std::vector<T>& gradient, float position);

 	double jd;
 	
 	float2 coordinates;
 	
 	float time_scale;
 	float3 sun_direction;
 	ambient_light* ambient_light;
@ -82,4 +83,13 @@ private:
 	std::vector<std::array<float4, 4>> sky_gradients;
 };

 template <typename T>
 T weather_system::interpolate_gradient(const std::vector<T>& gradient, float position)
 {
 	position *= static_cast<float>(gradient.size() - 1);
 	int index0 = static_cast<int>(position) % gradient.size();
 	int index1 = (index0 + 1) % gradient.size();
 	return math::lerp<T>(gradient[index0], gradient[index1], position - std::floor(position));
 }

 #endif // ANTKEEPER_WEATHER_SYSTEM_HPP