《Ray Tracing in One Weekend》完结篇
最近课程上机实验,封面图渲染时间也超长,所以写东西就落下了,见谅
这篇之后,我会继续《Ray Tracing The Next Week》,还请多多关注
这几天我在渲染这本书的封面图,封面图还没出,不算结束,刚好安排了10节
今天呢,有两件事:
1.阐述整个工程的文件组织即内容
2.阐述封面,完结
12.1工程文件组织
试过很多方法,问过很多老师,无奈,子类继承实现的父类纯虚函数实在无法和类声明分成两个文件(即声明放于.h,其他实现放在.cpp中),室友说,纯虚函数继承实现和模板很类似
所以,我们在合适的时候使用hpp
在学习过程中,我们遇到了诸如反射、折射之类的函数,它们并不应该属于某个具体子类,或者抽象基类
所以,我把它们写在了泛型3D数学库里面了
C++泛型3D数学库是我们学光线追踪的数学专用库了吧算是
在回头看我们的光线追踪的项目代码
1.工程定义文件
我们之前是在ray这个最基本的类中定义了一些基本的命名,尔后,发现,所有的东西都要用ray::val_type诸如此类的代码去描述光线追踪所用到的一些普遍类型,这个非常麻烦,代码也长,后来,我们将它们移出了ray-class,放在了namespace rt中,但是,仍然放在ray文件中,这个很不合理,所以我们定义了一个RTdef.h,专门用于定义一些光线追踪的常量和命名
/// RTdef.h // ----------------------------------------------------- // [author] lv // [begin ] 2019.1.1 // [brief ] the basic concept of rt // ----------------------------------------------------- #pragma once #include <lvgm\type_vec\type_vec.h> //https://www.cnblogs.com/lv-anchoret/p/10163085.html #include <lvgm\opticsfunc.hpp> //https://www.cnblogs.com/lv-anchoret/p/10241904.html #include <lvgm\randfunc.hpp> //https://www.cnblogs.com/lv-anchoret/p/10241904.html namespace rt { using rtvar = lvgm::precision; using rtvec = lvgm::vec3<rtvar>; constexpr static rtvar rtInf() { return static_cast<rtvar>(0x3f3f3f3f); } //最大值 constexpr rtvar π = 3.1415926; }
2.光线类
/// ray.h // ----------------------------------------------------- // [author] lv // [begin ] 2018.12 // [brief ] the ray-class for the ray-tracing project // from the 《ray tracing in one week》 // ----------------------------------------------------- #pragma once #include "RTdef.h" namespace rt { class ray { public: ray() :_a{ rtvec() } , _b{ rtvec() } { } ray(const rtvec& a, const rtvec& b) :_a(a) , _b(b) { } ray(const ray& r) :_a(r._a) , _b(r._b) { } inline rtvec origin()const { return _a; } inline rtvec direction()const { return _b; } inline rtvec go(const rtvar t)const { return _a + t * _b; } private: rtvec _a; rtvec _b; }; }
3.相机类
/// camera.h //https://www.cnblogs.com/lv-anchoret/p/10221058.html // ----------------------------------------------------- // [author] lv // [begin ] 2019.1 // [brief ] the camera-class for the ray-tracing project // from the 《ray tracing in one week》 // ----------------------------------------------------- #pragma once #include "ray.h" namespace rt { class camera { public: camera(rtvec lookfrom, rtvec lookat, rtvec vup, rtvar vfov, rtvar aspect, rtvar aperture, rtvar focus) :_eye(lookfrom) , _lens_radius(aperture / 2) { rtvar theta = vfov * π / 180; rtvar half_height = tan(theta / 2) * focus; //tan(theta/2) = (height/2) / 焦距 rtvar half_width = aspect * half_height; _w = (lookfrom - lookat).ret_unitization(); _u = cross(vup, _w).ret_unitization(); _v = cross(_w, _u); //向量运算 _start = _eye - half_width * _u - half_height * _v - focus * _w;//高和宽都乘了焦距,w也要乘,不然公式是错的 _horizontal = 2 * half_width * _u; _vertical = 2 * half_height * _v; } const ray get_ray(const rtvar u, const rtvar v)const { rtvec rd = rtvec(_lens_radius * lvgm::random_unit_plane()); rtvec offset = _u * rd.x() + _v * rd.y(); return ray{ _eye + offset, _start + u*_horizontal + v*_vertical - (_eye + offset) }; } const ray get_ray(const lvgm::vec2<rtvar>& para)const { return get_ray(para.u(), para.v()); } inline const rtvec& eye()const { return _eye; } inline const rtvec& start()const { return _start; } inline const rtvec& horizontal()const { return _horizontal; } inline const rtvec& vertical()const { return _vertical; } inline const rtvec& u()const { return _u; } inline const rtvec& v()const { return _v; } inline const rtvec& w()const { return _w; } inline const rtvar lens_r()const { return _lens_radius; } private: rtvec _u; rtvec _v; rtvec _w; rtvec _eye; rtvec _start; //left-bottom rtvec _horizontal; rtvec _vertical; rtvar _lens_radius; //the radius of lens }; }
4.碰撞相交部分
有一个碰撞相交基类
/// intersect.h //https://www.cnblogs.com/lv-anchoret/p/10190092.html // ----------------------------------------------------- // [author] lv // [begin ] 2018.12 // [brief ] the intersect-class for the ray-tracing project // from the 《ray tracing in one week》 // ----------------------------------------------------- #pragma once namespace rt { class material; struct hitInfo { lvgm::precision _t; //ray 中的系数t rtvec _p; //相交点、撞击点 rtvec _n; //_p点的表面法线 material* materialp; //材质 }; class intersect { public: intersect() { } /* @brief: 撞击函数,求取撞击点相关记录信息 @param: sight->视线 系数t的上下界->筛选撞击点 rec->返回撞击点信息 @retur: 是否存在合法撞击点 */ virtual bool hit(const ray& sight, rtvar t_min, rtvar t_max, hitInfo& rec)const = 0; virtual ~intersect() { } }; }
后面有一个子类intersections是用于处理一组碰撞相交的类,类比于容器
/// intersections.h // https://www.cnblogs.com/lv-anchoret/p/10190092.html // ----------------------------------------------------- // [author] lv // [begin ] 2018.12 // [brief ] the intersections-class for the ray-tracing project // from the 《ray tracing in one week》 // ----------------------------------------------------- #pragma once namespace rt { class intersections :public intersect { public: intersections() { } intersections(intersect** list, size_t n) :_list(list), _size(n) { } virtual bool hit(const ray& sight, rtvar t_min, rtvar t_max, hitInfo& rec)const override; private: intersect** _list; size_t _size; }; bool intersections::hit(const ray& sight, rtvar t_min, rtvar t_max, hitInfo& rec)const { hitInfo t_rec; bool hitSomething = false; rtvar far = t_max; //刚开始可以看到无限远 for (int i = 0; i < _size; ++i) { if (_list[i]->hit(sight, t_min, far, t_rec)) { hitSomething = true; far = t_rec._t; //将上一次的最近撞击点作为视线可达最远处 rec = t_rec; } } return hitSomething; } }
还有一个子类sphere是一种几何体用来做自身的碰撞检测的,之后,我们可能还会加入心形几何体类
/// sphere.h // https://www.cnblogs.com/lv-anchoret/p/10190092.html // ----------------------------------------------------- // [author] lv // [begin ] 2018.1.1 // [brief ] the sphere-class for the ray-tracing project // from the 《ray tracing in one week》 // ----------------------------------------------------- #pragma once namespace rt { class sphere :public intersect { public: sphere() { } /* @para1: 球心坐标 @para2: 球半径 @para3: 材质 */ sphere(const rtvec& h, rtvar r, material* ma) :_heart(h), _radius(r), _materialp(ma) { } ~sphere() { if (_materialp) delete _materialp; } virtual bool hit(const ray& sight, rtvar t_min, rtvar t_max, hitInfo& rec)const override; inline const rtvar r()const { return _radius; } inline const rtvec& heart()const { return _heart; } inline rtvar& r() { return _radius; } inline rtvec& heart() { return _heart; } private: rtvec _heart; rtvar _radius; material* _materialp; }; bool sphere::hit(const ray& sight, rtvar t_min, rtvar t_max, hitInfo& rec)const { rtvec trace = sight.origin() - _heart; rtvar a = dot(sight.direction(), sight.direction()); rtvar b = 2.0 * dot(trace, sight.direction()); rtvar c = dot(trace, trace) - _radius * _radius; rtvar delt = b*b - 4.0*a*c; if (delt > 0) { rec.materialp = _materialp; rtvar x = (-b - sqrt(delt)) / (2.0*a); if (x < t_max && x > t_min) { rec._t = x; rec._p = sight.go(rec._t); rec._n = (rec._p - _heart) / _radius; return true; } x = (-b + sqrt(delt)) / (2.0*a); if (x < t_max && x > t_min) { rec._t = x; rec._p = sight.go(x); rec._n = (rec._p - _heart) / _radius; return true; } } return false; } }
一个总文件
/// RThit.h // https://www.cnblogs.com/lv-anchoret/p/10190092.html // ----------------------------------------------------- // [author] lv // [begin ] 2019.1 // [brief ] some intersects // intersections // sphere // heart // ----------------------------------------------------- #pragma once #include "ray.h" #include "intersect.h" #include "sphere.hpp" #include "intersections.hpp"
5.材质类
材质有一个基类和三个子类
/// material.h // ----------------------------------------------------- // [author] lv // [begin ] 2018.12 // [brief ] the material-class for the ray-tracing project // from the 《ray tracing in one week》 // ----------------------------------------------------- #pragma once namespace rt { //abstract basic class class material { public: /* @brief: produce a scattered ray @param: InRay -> Incident light info -> the information of intersect-point(hit-point) attenuation -> when scattered, how much the ray should be attenuated by tis reflectance R scattered -> as we talk, it is a new sight; or it is the scattered ray with the intersect-point @retur: the function calculate a scattered ray or not */ virtual bool scatter(const ray& InRay, const hitInfo& info, rtvec& attenuation, ray& scattered)const = 0; }; }
/// diffuse.hpp // https://www.cnblogs.com/lv-anchoret/p/10198423.html // ----------------------------------------------------- // [author] lv // [begin ] 2018.12 // [brief ] one of the materials // ----------------------------------------------------- #pragma once namespace rt { //diffuse material class lambertian : public material { public: lambertian(const rtvec& a) :_albedo(a) { } bool scatter(const ray& rIn, const hitInfo& info, rtvec& attenuation, ray& scattered)const override { rtvec target = info._p + info._n + lvgm::random_unit_sphere(); scattered = ray{ info._p, target - info._p }; attenuation = _albedo; return true; } protected: rtvec _albedo; }; }
/// metal.hpp // https://www.cnblogs.com/lv-anchoret/p/10206773.html // ----------------------------------------------------- // [author] lv // [begin ] 2018.12 // [brief ] one of the materials // ----------------------------------------------------- #pragma once namespace rt { //metal material class metal :public material { public: metal(const rtvec& a, const rtvar f = 0.) :_albedo(a) { if (f < 1 && f >= 0)_fuzz = f; else _fuzz = 1; } virtual bool scatter(const ray& rIn, const hitInfo& info, rtvec& attenuation, ray& scattered)const { rtvec target = reflect(rIn.direction().ret_unitization(), info._n); scattered = ray{ info._p, target + _fuzz * lvgm::random_unit_sphere() }; attenuation = _albedo; return dot(scattered.direction(), info._n) != 0; } inline static rtvec reflect(const rtvec& in, const rtvec& n) { return in - 2 * dot(in, n)*n; } protected: rtvec _albedo; rtvar _fuzz; }; }
/// dielectric.hpp // https://www.cnblogs.com/lv-anchoret/p/10217719.html // ----------------------------------------------------- // [author] lv // [begin ] 2019.1 // [brief ] one of the materials // ----------------------------------------------------- #pragma once namespace rt { class dielectric :public material { public: dielectric(const rtvar RI) :_RI(RI) { } virtual bool scatter(const ray& InRay, const hitInfo& info, rtvec& attenuation, ray& scattered)const override; protected: rtvar _RI; inline rtvar schlick(const rtvar cosine)const; }; bool dielectric::scatter(const ray& InRay, const hitInfo& info, rtvec& attenuation, ray& scattered)const { rtvec outward_normal; rtvec refracted; rtvec reflected = reflect(InRay.direction(), info._n); rtvar eta; rtvar reflect_prob; rtvar cos; attenuation = rtvec(1., 1., 1.); if (dot(InRay.direction(), info._n) > 0) { outward_normal = -info._n; eta = _RI; cos = _RI * dot(InRay.direction(), info._n) / InRay.direction().normal(); } else { outward_normal = info._n; eta = 1.0 / _RI; cos = -dot(InRay.direction(), info._n) / InRay.direction().normal(); } if (refract(InRay.direction(), outward_normal, eta, refracted)) reflect_prob = schlick(cos); //如果有折射,计算反射系数 else reflect_prob = 1.0; //如果没有折射,那么为全反射 if (lvgm::rand01() < reflect_prob) scattered = ray(info._p, reflected); else scattered = ray(info._p, refracted); return true; } inline rtvar dielectric::schlick(const rtvar cosine)const { rtvar r0 = (1. - _RI) / (1. + _RI); r0 *= r0; return r0 + (1 - r0)*pow((1 - cosine), 5); } }
总文件
/// RTmaterial.h // ----------------------------------------------------- // [author] lv // [begin ] 2019.1 // [brief ] some materials // diffuse // metal // dielectric // ----------------------------------------------------- #pragma once #include "ray.h" #include "intersect.h" #include "material.h" #include "diffuse.hpp" #include "metal.hpp" #include "dielectric.hpp"
我们所有的文件就写完了
12.2封面完结
这个图让我学会了分段渲染。。。
这个图非常好看,于是乎,整了一个600*400的,整整渲染了两天(....),内心是崩溃的
我试过并发编程,结果效果不好(自己也不怎么会上锁。。。)
所以,就只能单线程处理,时间超过十个小时左右吧,VS那个时间过程诊断框就坏死了。。。
有时候,不能一直渲染,这个时候,被迫结束后,只需要读取已有文件的行数,然后计算出渲染了多少个点了,然后在渲染的双重for循环中从下一个点开始渲染写入文件即可,就可以随时随地想停就停,想渲染就渲染,因为图像本事就是一个一个像素点,我们只需要24w个点的文件数据即可,你也可以并发写入多个文件,最后拼在一起
我们采用的相机参数是这样的
据说是官方的,我也不清楚
还有一个文章写得非常好,是写相机的参数测试的,大家可以阅读一下,对相机的参数有一个更直观深入的了解
因为这个图实在是渲染了好久,所以也没有出一些其他的效果图,可能之后会更,大家可以自己设置球体以及相机,欢迎在评论区发出你的渲染图~
下面是代码:
#define LOWPRECISION #include <fstream> #include "RTmaterial.h" #include "RThit.h" #include "camera.h" #define stds std:: using namespace rt; rtvec lerp(const ray& sight, intersect* world, int depth) { hitInfo info; if (world->hit(sight, (rtvar)0.001, rtInf(), info)) { ray scattered; rtvec attenuation; if (depth < 50 && info.materialp->scatter(sight, info, attenuation, scattered)) return attenuation * lerp(scattered, world, depth + 1); else return rtvec(0, 0, 0); } else { rtvec unit_dir = sight.direction().ret_unitization(); rtvar t = 0.5*(unit_dir.y() + 1.); return (1. - t)*rtvec(1., 1., 1.) + t*rtvec(0.5, 0.7, 1.0); } } intersect* random_sphere() { int cnt = 500; intersect **list = new intersect*[cnt + 1]; list[0] = new sphere(rtvec(0, -1000, 0), 1000, new lambertian(rtvec(0.5, 0.5, 0.5))); int size = 1; for (int a = -11; a < 11; ++a) for (int b = -11; b < 11; ++b) { rtvar choose_mat = lvgm::rand01(); rtvec center(a + 0.9 * lvgm::rand01(), 0.2, b + 0.9*lvgm::rand01()); if ((center - rtvec(4, 0.2, 0)).normal()>0.9) { if (choose_mat < 0.75) { list[size++] = new sphere(center, 0.2, new lambertian(rtvec(lvgm::rand01()*lvgm::rand01(), lvgm::rand01()*lvgm::rand01(), lvgm::rand01()*lvgm::rand01()))); } else if (choose_mat < 0.9) { list[size++] = new sphere(center, 0.2, new metal(rtvec(0.5*(1 + lvgm::rand01()), 0.5*(1 + lvgm::rand01()), 0.5*(1 + lvgm::rand01())), 0.5*lvgm::rand01())); } else { list[size++] = new sphere(center, 0.2, new dielectric(1.5)); } } } list[size++] = new sphere(rtvec(0, 1, 0), 1.0, new dielectric(1.5)); list[size++] = new sphere(rtvec(-4, 1, 0), 1.0, new lambertian(rtvec(0.4, 0.2, 0.1))); list[size++] = new sphere(rtvec(4, 1, 0), 1.0, new metal(rtvec(0.7, 0.6, 0.5), 0.)); return new intersections(list, size); } void build_12_1() { stds ofstream file("graph12-1.ppm"); size_t W = 200, H = 120, sample = 100; if (file.is_open()) { file << "P3\n" << W << " " << H << "\n255\n" << stds endl; intersect* world = random_sphere(); rtvec lookfrom(13, 2, 3); rtvec lookat(0, 0, 0); float dist_to_focus = (lookfrom - lookat).normal(); float aperture = 0.0; camera cma(lookfrom, lookat, rtvec(0, 1, 0), 20, rtvar(W) / rtvar(H), aperture, 0.7*dist_to_focus); for (int y = H - 1; y >= 0; --y) for (int x = 0; x < W; ++x) { rtvec color; for (int cnt = 0; cnt < sample; ++cnt) { lvgm::vec2<rtvar> para{ (lvgm::rand01() + x) / W, (lvgm::rand01() + y) / H }; color += lerp(cma.get_ray(para), world, 0); } color /= sample; color = rtvec(sqrt(color.r()), sqrt(color.g()), sqrt(color.b())); //gamma 校正 int r = int(255.99 * color.r()); int g = int(255.99 * color.g()); int b = int(255.99 * color.b()); file << r << " " << g << " " << b << stds endl; } file.close(); if (world)delete world; stds cout << "complished" << stds endl; } else stds cerr << "open file error" << stds endl; } int main() { build_12_1(); }
感谢您的阅读,生活愉快~