vectozavr-shooter/engine/Mesh.cpp

216 lines
5.6 KiB
C++

//
// Created by Иван Ильин on 13.01.2021.
//
#include <string>
#include <fstream>
#include <sstream>
#include <utility>
#include "Mesh.h"
#include "utils/Log.h"
using namespace std;
Mesh &Mesh::operator*=(const Matrix4x4 &matrix4X4) {
for (auto& t : _tris)
t = t * matrix4X4;
return *this;
}
Mesh &Mesh::loadObj(const std::string& filename, const std::string &materials, const Point4D& scale) {
auto objects = Mesh::LoadObjects(filename, materials, scale);
for(auto& obj : objects) {
for (auto &tri : obj->triangles()) {
_tris.push_back(tri);
}
}
return *this;
}
Mesh::Mesh(const std::string& filename, const std::string &materials, const Point4D& scale){
loadObj(filename, materials, scale);
}
Mesh::Mesh(const vector<Triangle> &tries){
_tris = tries;
}
Mesh::Mesh(const Mesh& mesh) {
*this = mesh;
}
Mesh Mesh::Obj(const std::string& filename) {
return Mesh(filename);
}
void Mesh::rotate(const Point4D &r) {
Object::rotate(r);
*this *= Matrix4x4::Rotation(r);
}
void Mesh::rotate(const Point4D &v, double r) {
Object::rotate(v, r);
*this *= Matrix4x4::Rotation(v, r);
}
void Mesh::scale(const Point4D &s) {
Object::scale(s);
*this *= Matrix4x4::Scale(s);
}
Mesh &Mesh::operator=(const Mesh &mesh) {
_tris = mesh._tris;
_position = mesh._position;
_color = mesh._color;
return *this;
}
void Mesh::rotateRelativePoint(const Point4D &s, const Point4D &r) {
Object::rotateRelativePoint(s, r);
*this *= Matrix4x4::Rotation(r);
}
void Mesh::rotateRelativePoint(const Point4D &s, const Point4D &v, double r) {
Object::rotateRelativePoint(s, v, r);
*this *= Matrix4x4::Rotation(v, r);
}
void Mesh::setColor(sf::Color c) {
_color = c;
for (auto& t : _tris)
t = Triangle(t[0], t[1], t[2], _color);
}
std::vector<std::shared_ptr<Mesh>> Mesh::LoadObjects(const string &filename, const string &materials, const Point4D &scale) {
std::vector<std::shared_ptr<Mesh>> objects;
map<string, sf::Color> maters;
ifstream file(filename);
if (!file.is_open())
{
Log::log("Mesh::LoadObjects(): cannot load file from " + filename);
return objects;
}
if(!materials.empty()) {
ifstream mat(materials);
if (!mat.is_open())
{
Log::log("Mesh::LoadObjects(): cannot load mat from " + materials);
return objects;
} else {
while (!mat.eof())
{
char line[128];
mat.getline(line, 128);
stringstream s;
s << line;
int color[4];
string matName;
s >> matName >> color[0] >> color[1] >> color[2] >> color[3];
maters.insert({matName, sf::Color(color[0],color[1],color[2], color[3])});
}
mat.close();
}
}
vector<Point4D> verts;
std::vector<Triangle> tris;
sf::Color currentColor = sf::Color(255, 245, 194, 255);
while (!file.eof())
{
char line[128];
file.getline(line, 128);
stringstream s;
s << line;
char junk;
if(line[0] == 'o') {
if(!tris.empty()) {
objects.push_back(make_shared<Mesh>(tris));
objects.back()->scale(scale);
}
tris.clear();
}
if (line[0] == 'v')
{
double x, y, z;
s >> junk >> x >> y >> z;
verts.emplace_back(x, y, z, 1);
}
if(line[0] == 'g') {
string matInfo;
s >> junk >> matInfo;
string colorName = matInfo.substr(matInfo.size()-3, 3);
currentColor = maters[matInfo.substr(matInfo.size()-3, 3)];
}
if (line[0] == 'f')
{
int f[3];
s >> junk >> f[0] >> f[1] >> f[2];
tris.emplace_back(verts[f[0] - 1], verts[f[1] - 1], verts[f[2] - 1], currentColor);
}
}
if(!tris.empty()) {
objects.push_back(make_shared<Mesh>(tris));
objects.back()->scale(scale);
}
file.close();
return objects;
}
Mesh Mesh::LineTo(const Point4D& from, const Point4D& to, double line_width, sf::Color color) {
Mesh line;
Point4D v1 = (to - from).normalized();
Point4D v2 = from.cross3D(from + Point4D{1, 0, 0}).normalized();
Point4D v3 = v1.cross3D(v2).normalized();
// from plane
Point4D p1 = from - v2 * line_width/2.0 - v3 * line_width/2.0;
Point4D p2 = from - v2 * line_width/2.0 + v3 * line_width/2.0;
Point4D p3 = from + v2 * line_width/2.0 + v3 * line_width/2.0;
Point4D p4 = from + v2 * line_width/2.0 - v3 * line_width/2.0;
// to plane
Point4D p5 = to - v2 * line_width/2.0 - v3 * line_width/2.0;
Point4D p6 = to - v2 * line_width/2.0 + v3 * line_width/2.0;
Point4D p7 = to + v2 * line_width/2.0 + v3 * line_width/2.0;
Point4D p8 = to + v2 * line_width/2.0 - v3 * line_width/2.0;
line._tris = {
{ p2, p4, p1 },
{ p2, p3, p4 },
{ p1, p6, p2 },
{ p1, p5, p6 },
{ p2, p6, p7 },
{ p2, p7, p3 },
{ p6, p5, p8 },
{ p6, p8, p7 },
{ p4, p3, p7 },
{ p4, p7, p8 },
{ p1, p8, p5 },
{ p1, p4, p8 }
};
line.setColor(color);
for(auto& triangle : line._tris)
triangle = Triangle(Point4D{triangle[0].x(), triangle[0].y(), triangle[0].z(), 1},
Point4D{triangle[1].x(), triangle[1].y(), triangle[1].z(), 1},
Point4D{triangle[2].x(), triangle[2].y(), triangle[2].z(), 1}, line.color());
return line;
}