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//
// Created by Keuin on 2022/4/15.
//
#ifndef RT_MATERIAL_H
#define RT_MATERIAL_H
#include "object.h"
class object;
// A material is of some characteristics that manipulates the lighted ray in some certain ways.
// An object can have one certain subclass of material, making it seemed to be different with other objects.
// A material instance can be configured when constructing. It should be immutable and thread-safe.
// It is suggested not to have mutable states in its internal implementation.
// User should have a global table containing references to all the materials the scene is using.
class material {
public:
// If this matter scatters, manipulate r and return true. Otherwise return false (the light is absorbed entirely).
// To make it thread-safe without locking mechanism, private states are passed-in as parameters.
virtual bool scatter(ray3d &r, const object &hit_obj, double hit_t, random_uv_gen_3d &ruvg) const = 0;
};
class material_diffuse_lambertian : public material {
vec3d albedo;
public:
explicit material_diffuse_lambertian(vec3d albedo);
explicit material_diffuse_lambertian(double albedo);
bool scatter(ray3d &r, const object &hit_obj, double hit_t, random_uv_gen_3d &ruvg) const override;
};
class material_diffuse_simple : public material {
vec3d albedo;
public:
explicit material_diffuse_simple(vec3d albedo);
explicit material_diffuse_simple(double albedo);
bool scatter(ray3d &r, const object &hit_obj, double hit_t, random_uv_gen_3d &ruvg) const override;
};
class material_diffuse_hemispherical : public material {
vec3d albedo;
public:
explicit material_diffuse_hemispherical(vec3d albedo);
explicit material_diffuse_hemispherical(double albedo);
bool scatter(ray3d &r, const object &hit_obj, double hit_t, random_uv_gen_3d &ruvg) const override;
};
#endif //RT_MATERIAL_H
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