Improve train color selection to always choose saturated colors

[r2c2.git] / source / engineer / engineer.cpp

#include <algorithm>
#include <cmath>
#include <cstdlib>
#include <limits>
#include <signal.h>
#include <msp/fs/stat.h>
#include <msp/fs/utils.h>
#include <msp/graphics/display.h>
#include <msp/graphics/window.h>
#include <msp/gl/blend.h>
#include <msp/gl/framebuffer.h>
#include <msp/gl/matrix.h>
#include <msp/gl/misc.h>
#include <msp/gl/projection.h>
#include <msp/gl/tests.h>
#include <msp/io/print.h>
#include <msp/strings/format.h>
#include <msp/time/units.h>
#include <msp/time/utils.h>
#include "libr2c2/driver.h"
#include "libr2c2/tracktype.h"
#include "3d/path.h"
#include "3d/track.h"
#include "3d/vehicle.h"
#include "engineer.h"
#include "mainpanel.h"
#include "trainpanel.h"
#include "trainproperties.h"
#include "trainview.h"

using namespace std;
using namespace R2C2;
using namespace Msp;

Engineer::Engineer(int argc, char **argv):
        options(argc, argv),
        window(options.screen_w, options.screen_h, options.fullscreen),
        keyboard(window),
        mouse(window),
        ui_res("r2c2.res"),
        layout(catalogue, (options.driver.empty() ? 0 : Driver::create(options.driver))),
        layout_3d(layout),
        server(0),
        pipeline(window.get_width(), window.get_height(), false),
        picking(false),
        picking_track(0),
        picking_entry(0),
        picking_path(0),
        pointer_moved(false)
{
        // Setup GUI
        window.set_title("Railroad Engineer");
        window.signal_close.connect(sigc::bind(sigc::mem_fun(this, &Engineer::exit), 0));

        root = new GLtk::Root(ui_res, window);
        mouse.signal_button_press.connect(sigc::mem_fun(this, &Engineer::button_press));
        mouse.signal_axis_motion.connect(sigc::mem_fun(this, &Engineer::axis_motion));
        root->set_visible(true);

        main_panel = new MainPanel(*this);
        root->add(*main_panel);
        main_panel->set_position(0, window.get_height()-main_panel->get_geometry().h);
        main_panel->set_visible(true);

        overlay = new Overlay3D(ui_res.get_default_font());

        // Setup railroad control
        DataFile::load(catalogue, "tracks.dat");
        DataFile::load(catalogue, "locos.dat");
        DataFile::load(catalogue, "wagons.dat");
        DataFile::load(layout, options.layout_fn);

        layout.signal_train_added.connect(sigc::mem_fun(this, &Engineer::train_added));
        layout.signal_block_reserved.connect(sigc::hide<1>(sigc::mem_fun(this, &Engineer::reset_block_color)));
        layout.signal_block_state_changed.connect(sigc::hide<1>(sigc::mem_fun(this, &Engineer::reset_block_color)));
        layout.signal_emergency.connect(sigc::mem_fun(this, &Engineer::set_status));

        if(FS::exists(options.state_fn))
                DataFile::load(layout, options.state_fn);

        if(options.network)
        {
                server = new Server(layout);
                server->use_event_dispatcher(event_disp);
        }

        // Setup 3D view
        DataFile::load(arrow_mesh, "arrow.mesh");

        pipeline.set_camera(&camera);
        pipeline.add_renderable_for_pass(layout_3d.get_scene(), 0);
        pipeline.add_renderable_for_pass(layout_3d.get_path_scene(), "unlit");
        pipeline.add_renderable_for_pass(*overlay, "overlay");

        light.set_position(GL::Vector4(0, -0.259, 0.966, 0));
        light.set_diffuse(GL::Color(0.9));
        lighting.set_ambient(GL::Color(0.4));
        lighting.attach(0, light);

        GL::Pipeline::Pass *pass = &pipeline.add_pass(0);
        pass->set_depth_test(&GL::DepthTest::lequal());
        pass->set_lighting(&lighting);

        pass = &pipeline.add_pass("unlit");
        pass->set_depth_test(&GL::DepthTest::lequal());

        pass = &pipeline.add_pass("overlay");
        pass->set_blend(&GL::Blend::alpha());

        view_all();

        // Catch various signals so we can stop the trains in case we get terminated
        catch_signal(SIGINT);
        catch_signal(SIGTERM);
        catch_signal(SIGSEGV);
        catch_signal(SIGILL);
        catch_signal(SIGFPE);
        catch_signal(SIGABRT);
}

Engineer::~Engineer()
{
        const map<unsigned, Train *> &trains = layout.get_trains();
        for(map<unsigned, Train *>::const_iterator i=trains.begin(); i!=trains.end(); ++i)
                layout.get_driver().set_loco_speed(i->first, 0);
        layout.get_driver().flush();

        if(!options.simulate)
        {
                layout.save_dynamic(options.state_fn+".tmp");
                FS::rename(options.state_fn+".tmp", options.state_fn);
        }

        delete overlay;
        delete root;

        delete server;
}

void Engineer::set_status(const string &text)
{
        main_panel->set_status_text(text);
        status_timeout = Time::now()+10*Time::sec;
}

void Engineer::rearrange_panels()
{
        int y = main_panel->get_geometry().y;
        for(list<TrainPanel *>::iterator i=train_panels.begin(); i!=train_panels.end(); ++i)
        {
                y -= (*i)->get_geometry().h;
                (*i)->set_position(0, y);
        }
}

void Engineer::add_train_view(TrainView &tv)
{
        train_views.push_back(&tv);
}

void Engineer::remove_train_view(TrainView &tv)
{
        train_views.erase(remove(train_views.begin(), train_views.end(), &tv), train_views.end());
}

void Engineer::pick(bool with_ep)
{
        picking = true;
        picking_track = 0;
        picking_entry = (with_ep ? 0 : -1);
}

int Engineer::main()
{
        window.show();

        return Application::main();
}

void Engineer::tick()
{
        window.get_display().tick();

        for(list<Train *>::iterator i=new_trains.begin(); i!=new_trains.end(); ++i)
                process_new_train(**i);
        new_trains.clear();

        layout.tick();
        event_disp.tick(Time::zero);

        for(list<TrainView *>::iterator i=train_views.begin(); i!=train_views.end(); ++i)
                (*i)->prepare();

        if(status_timeout && Time::now()>status_timeout)
        {
                main_panel->set_status_text(string());
                status_timeout = Time::TimeStamp();
        }

        GL::Framebuffer::system().clear(GL::COLOR_BUFFER_BIT|GL::DEPTH_BUFFER_BIT);

        pipeline.render();

        if(pointer_moved)
        {
                pointer_moved = false;

                if(picking)
                {
                        Track *track = pick_track(pointer);
                        if(track && track!=picking_track)
                        {
                                picking_track = track;
                                if(picking_entry>=0)
                                        picking_entry = 0;

                                delete picking_path;
                                picking_path = new Path3D(layout_3d.get_track(*track));
                                if(picking_entry>=0)
                                        picking_path->set_mask(picking_track->get_type().get_endpoint(picking_entry).paths);
                                else
                                        picking_path->set_mask(picking_track->get_type().get_paths());
                                picking_path->set_color(GL::Color(0));
                                picking_path->set_layer(1);
                        }
                }
        }

        if(picking && picking_track && picking_entry>=0)
        {
                camera.apply();
                GL::MatrixStack::Push push_mat(GL::MatrixStack::modelview());

                float rot = picking_track->get_endpoint_direction(picking_entry);
                Vector pos = picking_track->get_endpoint_position(picking_entry);

                GL::MatrixStack::modelview() *= GL::Matrix::translation(pos.x, pos.y, pos.z+0.03);
                GL::MatrixStack::modelview() *= GL::Matrix::rotation(rot+M_PI, 0, 0, 1);

                arrow_mesh.draw();
        }

        root->render();

        window.swap_buffers();
}

void Engineer::button_press(unsigned btn)
{
        if(picking)
        {
                if(btn==1 && picking_track)
                {
                        picking = false;
                        delete picking_path;
                        picking_path = 0;
                        signal_pick_done.emit(picking_track, picking_entry);
                }
                else if(btn==3 && picking_entry>=0)
                {
                        picking_entry = (picking_entry+1)%picking_track->get_type().get_endpoints().size();
                        picking_path->set_mask(picking_track->get_type().get_endpoint(picking_entry).paths);
                }
        }
        else
        {
                Track *track = pick_track(pointer);
                if(track)
                {
                        if(track->get_turnout_id())
                        {
                                Block &block = track->get_block();
                                if(block.get_train() && !block.get_train()->free_block(block))
                                        set_status("Turnout is busy");
                                else
                                {
                                        unsigned paths = track->get_type().get_paths();
                                        unsigned i = track->get_active_path()+1;
                                        while(!(paths&(1<<i)))
                                        {
                                                if(!(paths>>i))
                                                        i = 0;
                                                else
                                                        ++i;
                                        }
                                        track->set_active_path(i);
                                        set_status(format("Turnout %d", track->get_turnout_id()));
                                }
                        }
                        if(unsigned sid = track->get_sensor_id())
                        {
                                if(options.simulate)
                                        layout.get_driver().set_sensor(sid, !layout.get_driver().get_sensor(sid));
                                set_status(format("Sensor %d", sid));
                        }
                }
        }
}

void Engineer::axis_motion(unsigned axis, float value, float)
{
        if(axis==0)
                pointer.x = value;
        if(axis==1)
                pointer.y = value;
        pointer_moved = true;
}

void Engineer::view_all()
{
        const Layout3D::TrackMap &tracks = layout_3d.get_tracks();

        float view_aspect = float(window.get_width()-200)/window.get_height();
        float view_height = tan(camera.get_field_of_view()/2)*2;
        float best_score = 0;
        GL::Vector3 pos;
        GL::Vector3 up;
        for(float angle=0; angle<M_PI; angle+=0.01)
        {
                float min_x = 0;
                float max_x = 0;
                float min_y = 0;
                float max_y = 0;
                for(Layout3D::TrackMap::const_iterator i=tracks.begin(); i!=tracks.end(); ++i)
                {
                        Vector minp, maxp;
                        i->second->get_bounds(angle, minp, maxp);
                        min_x = min(min_x, minp.x);
                        max_x = max(max_x, maxp.x);
                        min_y = min(min_y, minp.y);
                        max_y = max(max_y, maxp.y);
                }

                float width = max_x-min_x;
                float height = max_y-min_y;
                float aspect = width/height;
                float score = min(aspect/view_aspect, view_aspect/aspect);

                if(score>best_score)
                {
                        best_score = score;

                        float size = max(width/view_aspect, height);
                        float c = cos(angle);
                        float s = sin(angle);
                        float x = (min_x+max_x)/2-size*105/window.get_height();
                        float y = (min_y+max_y)/2;
                        float z = max(size*1.05/view_height, 0.15);

                        pos = GL::Vector3(c*x-s*y, s*x+c*y, z);
                        up = GL::Vector3(-s, c, 0);
                }
        }

        camera.set_position(pos);
        camera.set_up_direction(up);
        camera.set_look_direction(GL::Vector3(0, 0, -1));
        camera.set_aspect(float(window.get_width())/window.get_height());
        camera.set_depth_clip(pos.z*0.5, pos.z*1.5);
}

void Engineer::set_block_color(const Block &block, const GL::Color &color)
{
        const set<Track *> &tracks = block.get_tracks();
        for(set<Track *>::const_iterator i=tracks.begin(); i!=tracks.end(); ++i)
                layout_3d.get_track(**i).get_path().set_color(color);
}

void Engineer::reset_block_color(const Block &block)
{
        bool active = block.get_state()>Block::INACTIVE;

        if(block.get_train())
        {
                GL::Color color;
                map<Train *, GL::Color>::iterator i = train_colors.find(block.get_train());
                if(i!=train_colors.end())
                        color = i->second;

                if(active)
                        set_block_color(block, color*0.6);
                else
                        set_block_color(block, color*0.5+0.5);
        }
        else if(active)
                set_block_color(block, GL::Color(0.6));
        else
                set_block_color(block, GL::Color(1));
}

Track *Engineer::pick_track(const Vector &p)
{
        const GL::Vector3 &start = camera.get_position();
        GL::Vector4 ray = camera.unproject(GL::Vector4(p.x, p.y, 0, 0));

        return layout.pick_track(Vector(start.x, start.y, start.z), Vector(ray.x, ray.y, ray.z));
}

void Engineer::process_new_train(Train &train)
{
        TrainPanel *tpanel = new TrainPanel(*this, train);
        root->add(*tpanel);
        train_panels.push_back(tpanel);
        rearrange_panels();

        Vehicle3D &loco3d = layout_3d.get_vehicle(train.get_vehicle(0));
        overlay->set_label(loco3d, train.get_name());
        train.signal_name_changed.connect(sigc::bind<0>(sigc::mem_fun(overlay, &Overlay3D::set_label), sigc::ref(loco3d)));
}

void Engineer::train_added(Train &train)
{
        new_trains.push_back(&train);

        GL::Color best_color;
        float best_d_sq = 0;
        for(unsigned i=0; i<10; ++i)
        {
                GL::Color color;
                unsigned h = rand()%3;
                color.r = (h==0 ? 0.0 : rand()*1.0/RAND_MAX);
                color.g = (h==1 ? 0.0 : rand()*1.0/RAND_MAX);
                color.b = (h==2 ? 0.0 : rand()*1.0/RAND_MAX);
                color = color*(1/max(max(color.r, color.g), color.b));
                float min_d_sq = 3;
                for(map<Train *, GL::Color>::const_iterator j=train_colors.begin(); j!=train_colors.end(); ++j)
                {
                        float dr = color.r-j->second.r;
                        float dg = color.g-j->second.g;
                        float db = color.b-j->second.b;
                        float d_sq = dr*dr+dg*dg+db*db;
                        if(d_sq<min_d_sq)
                                min_d_sq = d_sq;
                }
                if(min_d_sq>best_d_sq)
                {
                        best_color = color;
                        best_d_sq = min_d_sq;
                }
        }
        train_colors[&train] = best_color;
}

void Engineer::sighandler(int sig)
{
        if(sig==SIGSEGV || sig==SIGILL || sig==SIGFPE || sig==SIGABRT)
        {
                signal(sig, SIG_DFL);
                IO::print(IO::cerr, "Fatal signal received, terminating\n");
                const map<unsigned, Train *> &trains = layout.get_trains();
                for(map<unsigned, Train *>::const_iterator i=trains.begin(); i!=trains.end(); ++i)
                        layout.get_driver().set_loco_speed(i->first, 0);
                layout.get_driver().flush();
                raise(sig);
        }
        else if(sig==SIGTERM || sig==SIGINT)
                exit(0);
}