/** * ========================================================================= * File : LightEnv.h * Project : Pyrogenesis * Description : CLightEnv, a class describing the current lights * * @author Rich Cross * @author Nicolai Haehnle * ========================================================================= */ #ifndef __LIGHTENV_H #define __LIGHTENV_H #include "Color.h" #include "maths/Vector3D.h" class CMapWriter; class CMapReader; /** * Class CLightEnv: description of a lighting environment - contains all the * necessary parameters for representation of the lighting within a scenario */ class CLightEnv { friend class CMapWriter; friend class CMapReader; friend class CXMLReader; private: /** * m_Elevation: Height of sun above the horizon, in radians. * For example, an elevation of PI/2 means the sun is straight up. */ float m_Elevation; /** * m_Rotation: Direction of sun on the compass, in radians. * For example, a rotation of zero means the sun is in the direction (0,0,-1) * and a rotation of PI/2 means the sun is in the direction (1,0,0) (not taking * elevation into account). */ float m_Rotation; /** * m_TerrainShadowTransparency: Fraction of diffuse light that reaches shadowed terrain. * A value of 0.0 means shadowed polygons get only ambient light, while a value of 1.0 * means shadows don't have any effect at all. */ float m_TerrainShadowTransparency; CVector3D m_SunDir; public: RGBColor m_SunColor; RGBColor m_TerrainAmbientColor; RGBColor m_UnitsAmbientColor; public: CLightEnv(); float GetElevation() const { return m_Elevation; } float GetRotation() const { return m_Rotation; } const CVector3D& GetSunDir() const { return m_SunDir; } float GetTerrainShadowTransparency() const { return m_TerrainShadowTransparency; } void SetElevation(float f); void SetRotation(float f); void SetTerrainShadowTransparency(float f); /** * EvaluateTerrain: Calculate brightness of a point of the terrain with the given normal * vector. * The resulting color contains both ambient and diffuse light. * * @param normal normal vector (must have length 1) * @param color resulting color */ void EvaluateTerrain(const CVector3D& normal, RGBColor& color) const { float dot = -normal.Dot(m_SunDir); color = m_TerrainAmbientColor; if (dot > 0) color += m_SunColor * dot; } /** * EvaluateUnit: Calculate brightness of a point of a unit with the given normal * vector. * The resulting color contains both ambient and diffuse light. * * @param normal normal vector (must have length 1) * @param color resulting color */ void EvaluateUnit(const CVector3D& normal, RGBColor& color) const { float dot = -normal.Dot(m_SunDir); color = m_UnitsAmbientColor; if (dot > 0) color += m_SunColor * dot; } /** * EvaluateDirect: Like EvaluateTerrain and EvaluateUnit, but return only the direct * sunlight term without ambient. * * @param normal normal vector (must have length 1) * @param color resulting color */ void EvaluateDirect(const CVector3D& normal, RGBColor& color) const { float dot = -normal.Dot(m_SunDir); if (dot > 0) color = m_SunColor * dot; else color = CVector3D(0,0,0); } // Comparison operators bool operator==(const CLightEnv& o) const { return m_Elevation == o.m_Elevation && m_Rotation == o.m_Rotation && m_TerrainShadowTransparency == o.m_TerrainShadowTransparency && m_SunColor == o.m_SunColor && m_TerrainAmbientColor == o.m_TerrainAmbientColor && m_UnitsAmbientColor == o.m_UnitsAmbientColor; } bool operator!=(const CLightEnv& o) const { return !(*this == o); } private: void CalculateSunDirection(); }; #endif