TDT4102-Ovinger/Oving1/include/Graph_lib/Graph.cpp

#include "Graph.h"
#include <map>

namespace Graph_lib {

void Shape::draw_lines() const
{
	if (color().visibility() && 1 < points.size()) // draw sole pixel?
		for (unsigned int i = 1; i < points.size(); ++i)
			fl_line(points[i - 1].x, points[i - 1].y, points[i].x, points[i].y);
}

void Shape::draw() const
{
	Fl_Color oldc = fl_color();
	// there is no good portable way of retrieving the current style
	fl_color(lcolor.as_int());
	fl_line_style(ls.style(), ls.width());
	draw_lines();
	fl_color(oldc); // reset color (to pevious) and style (to default)
	fl_line_style(0);
}


// does two lines (p1,p2) and (p3,p4) intersect?
// if se return the distance of the intersect point as distances from p1
inline pair<double, double> line_intersect(Point p1, Point p2, Point p3, Point p4, bool& parallel)
{
	double x1 = p1.x;
	double x2 = p2.x;
	double x3 = p3.x;
	double x4 = p4.x;
	double y1 = p1.y;
	double y2 = p2.y;
	double y3 = p3.y;
	double y4 = p4.y;

	double denom = ((y4 - y3) * (x2 - x1) - (x4 - x3) * (y2 - y1));
	if (denom == 0) {
		parallel = true;
		return pair<double, double>(0, 0);
	}
	parallel = false;
	return pair<double, double>(((x4 - x3) * (y1 - y3) - (y4 - y3) * (x1 - x3)) / denom,
								((x2 - x1) * (y1 - y3) - (y2 - y1) * (x1 - x3)) / denom);
}


// intersection between two line segments
// Returns true if the two segments intersect,
// in which case intersection is set to the point of intersection
bool line_segment_intersect(Point p1, Point p2, Point p3, Point p4, Point& intersection)
{
	bool parallel;
	pair<double, double> u = line_intersect(p1, p2, p3, p4, parallel);
	if (parallel || u.first < 0 || u.first > 1 || u.second < 0 || u.second > 1)
		return false;
	intersection.x = p1.x + u.first * (p2.x - p1.x);
	intersection.y = p1.y + u.first * (p2.y - p1.y);
	return true;
}

void Polygon::add(Point p)
{
	int np = number_of_points();

	if (1 < np) { // check that thenew line isn't parallel to the previous one
		if (p == point(np - 1))
			error("polygon point equal to previous point");
		bool parallel;
		line_intersect(point(np - 1), p, point(np - 2), point(np - 1), parallel);
		if (parallel)
			error("two polygon points lie in a straight line");
	}

	for (int i = 1; i < np - 1; ++i) { // check that new segment doesn't interset and old point
		Point ignore{0, 0};
		if (line_segment_intersect(point(np - 1), p, point(i - 1), point(i), ignore))
			error("intersect in polygon");
	}

	Closed_polyline::add(p);
}


void Polygon::draw_lines() const
{
	if (number_of_points() < 3)
		error("less than 3 points in a Polygon");
	Closed_polyline::draw_lines();
}

void Open_polyline::draw_lines() const
{
	if (fill_color().visibility()) {
		fl_color(fill_color().as_int());
		fl_begin_complex_polygon();
		for (int i = 0; i < number_of_points(); ++i) {
			fl_vertex(point(i).x, point(i).y);
		}
		fl_end_complex_polygon();
		fl_color(color().as_int()); // reset color
	}

	if (color().visibility())
		Shape::draw_lines();
}


void Closed_polyline::draw_lines() const
{
	Open_polyline::draw_lines();

	if (color().visibility()) // draw closing line:
		fl_line(point(number_of_points() - 1).x, point(number_of_points() - 1).y, point(0).x,
				point(0).y);
}
void Shape::move(int dx, int dy)
{
	for (unsigned int i = 0; i < points.size(); ++i) {
		points[i].x += dx;
		points[i].y += dy;
	}
}

void Lines::draw_lines() const
{
	//	if (number_of_points()%2==1) error("odd number of points in set of lines");
	if (color().visibility())
		for (int i = 1; i < number_of_points(); i += 2)
			fl_line(point(i - 1).x, point(i - 1).y, point(i).x, point(i).y);
}

void Text::draw_lines() const
{
	int ofnt = fl_font();
	int osz = fl_size();
	fl_font(fnt.as_int(), fnt_sz);
	fl_draw(lab.c_str(), point(0).x, point(0).y);
	fl_font(ofnt, osz);
}

Function::Function(Fct f, double r1, double r2, Point xy, int count, double xscale, double yscale)
// graph f(x) for x in [r1:r2) using count line segments with (0,0) displayed at
// xy x coordinates are scaled by xscale and y coordinates scaled by yscale
{
	if (r2 - r1 <= 0)
		error("bad graphing range");
	if (count <= 0)
		error("non-positive graphing count");
	double dist = (r2 - r1) / count;
	double r = r1;
	for (int i = 0; i < count; ++i) {
		add(Point{xy.x + int(r * xscale), xy.y - int(f(r) * yscale)});
		r += dist;
	}
}

void Rectangle::draw_lines() const
{
	if (fill_color().visibility()) { // fill
		fl_color(fill_color().as_int());
		fl_rectf(point(0).x, point(0).y, w, h);
		fl_color(color().as_int()); // reset color
	}

	if (color().visibility()) { // edge on top of fill
		fl_color(color().as_int());
		fl_rect(point(0).x, point(0).y, w, h);
	}
}


Axis::Axis(Orientation d, Point xy, int length, int n, string lab) : label(Point{0, 0}, lab)
{
	if (length < 0)
		error("bad axis length");
	switch (d) {
	case Axis::x: {
		Shape::add(xy);							// axis line
		Shape::add(Point{xy.x + length, xy.y}); // axis line
		if (1 < n) {
			int dist = length / n;
			int x = xy.x + dist;
			for (int i = 0; i < n; ++i) {
				notches.add(Point{x, xy.y}, Point{x, xy.y - 5});
				x += dist;
			}
		}
		// label under the line
		label.move(length / 3, xy.y + 20);
		break;
	}
	case Axis::y: {
		Shape::add(xy); // a y-axis goes up
		Shape::add(Point{xy.x, xy.y - length});
		if (1 < n) {
			int dist = length / n;
			int y = xy.y - dist;
			for (int i = 0; i < n; ++i) {
				notches.add(Point{xy.x, y}, Point{xy.x + 5, y});
				y -= dist;
			}
		}
		// label at top
		label.move(xy.x - 10, xy.y - length - 10);
		break;
	}
	case Axis::z:
		error("z axis not implemented");
	}
}

void Axis::draw_lines() const
{
	Shape::draw_lines(); // the line
	notches.draw();		 // the notches may have a different color from the line
	label.draw();		 // the label may have a different color from the line
}


void Axis::set_color(Color c)
{
	Shape::set_color(c);
	notches.set_color(c);
	label.set_color(c);
}

void Axis::move(int dx, int dy)
{
	Shape::move(dx, dy);
	notches.move(dx, dy);
	label.move(dx, dy);
}

void Circle::draw_lines() const
{
	if (fill_color().visibility()) { // fill
		fl_color(fill_color().as_int());
		fl_pie(point(0).x, point(0).y, r + r - 1, r + r - 1, 0, 360);
		fl_color(color().as_int()); // reset color
	}

	if (color().visibility()) {
		fl_color(color().as_int());
		fl_arc(point(0).x, point(0).y, r + r, r + r, 0, 360);
	}
}


void Ellipse::draw_lines() const
{
	if (fill_color().visibility()) { // fill
		fl_color(fill_color().as_int());
		fl_pie(point(0).x, point(0).y, w + w - 1, h + h - 1, 0, 360);
		fl_color(color().as_int()); // reset color
	}

	if (color().visibility()) {
		fl_color(color().as_int());
		fl_arc(point(0).x, point(0).y, w + w, h + h, 0, 360);
	}
}

void draw_mark(Point xy, char c)
{
	static const int dx = 4;
	static const int dy = 4;
	string m(1, c);
	fl_draw(m.c_str(), xy.x - dx, xy.y + dy);
}

void Marked_polyline::draw_lines() const
{
	Open_polyline::draw_lines();
	for (int i = 0; i < number_of_points(); ++i)
		draw_mark(point(i), mark[i % mark.size()]);
}

std::map<string, Suffix::Encoding> suffix_map;

int init_suffix_map()
{
	suffix_map["jpg"] = Suffix::jpg;
	suffix_map["JPG"] = Suffix::jpg;
	suffix_map["jpeg"] = Suffix::jpg;
	suffix_map["JPEG"] = Suffix::jpg;
	suffix_map["gif"] = Suffix::gif;
	suffix_map["GIF"] = Suffix::gif;
	suffix_map["bmp"] = Suffix::bmp;
	suffix_map["BMP"] = Suffix::bmp;
	return 0;
}

Suffix::Encoding get_encoding(const string& s)
// try to deduce type from file name using a lookup table
{
	static int x = init_suffix_map(); // oneshot map init

	string::const_iterator p = find(s.begin(), s.end(), '.');
	if (p == s.end())
		return Suffix::none; // no suffix

	string suf(p + 1, s.end());
	return suffix_map[suf];
}

bool can_open(const string& s)
// check if a file named s exists and can be opened for reading
{
	ifstream ff(s.c_str());
	return bool{ff};
}


// somewhat overelaborate constructor
// because errors related to image files can be such a pain to debug
Image::Image(Point xy, string s, Suffix::Encoding e) : w(0), h(0), fn(xy, "")
{
	add(xy);

	if (!can_open(s)) {
		fn.set_label("cannot open \"" + s + '\"');
		p = new Bad_image(30, 20); // the "error image"
		return;
	}

	if (e == Suffix::none)
		e = get_encoding(s);

	switch (e) {
	case Suffix::jpg:
		p = new Fl_JPEG_Image(s.c_str());
		break;
	case Suffix::gif:
		p = new Fl_GIF_Image(s.c_str());
		break;
		//	case Suffix::bmp:
		//		p = new Fl_BMP_Image(s.c_str());
		//		break;
	default: // Unsupported image encoding
		fn.set_label("unsupported file type \"" + s + '\"');
		p = new Bad_image(30, 20); // the "error image"
	}
}

void Image::draw_lines() const
{
	if (fn.label() != "")
		fn.draw_lines();

	if (w && h)
		p->draw(point(0).x, point(0).y, w, h, cx, cy);
	else
		p->draw(point(0).x, point(0).y);
}

} // namespace Graph_lib