source/libr2c2/signal.cpp

   1 #include "blockiter.h"
   2 #include "driver.h"
   3 #include "layout.h"
   4 #include "signal.h"
   5 #include "signaltype.h"
   6 #include "trackiter.h"
   7 #include "tracktype.h"
   8 #include "train.h"
   9
  10 using namespace std;
  11 using namespace Msp;
  12
  13 namespace R2C2 {
  14
  15 Signal::Signal(Layout &l, const SignalType &t):
  16         Object(l),
  17         type(t),
  18         address(0),
  19         track(0),
  20         block(0),
  21         entry(0),
  22         train(0),
  23         check_allocated_blocks(false),
  24         passing(false)
  25 {
  26         layout.add_signal(*this);
  27
  28         layout.signal_block_reserved.connect(sigc::mem_fun(this, &Signal::block_reserved));
  29 }
  30
  31 Signal::~Signal()
  32 {
  33         layout.remove_signal(*this);
  34 }
  35
  36 Signal *Signal::clone(Layout *to_layout) const
  37 {
  38         Signal *sig = new Signal((to_layout ? *to_layout : layout), type);
  39         sig->set_position(position);
  40         sig->set_rotation(rotation);
  41         return sig;
  42 }
  43
  44 void Signal::set_address(unsigned a)
  45 {
  46         address = a;
  47
  48         if(layout.has_driver() && address)
  49                 layout.get_driver().add_signal(address, type);
  50 }
  51
  52 void Signal::set_position(const Vector &p)
  53 {
  54         const set<Track *> &tracks = layout.get_tracks();
  55         float dist = -1;
  56         for(set<Track *>::const_iterator i=tracks.begin(); i!=tracks.end(); ++i)
  57                 if(!(*i)->get_type().is_turnout())
  58                 {
  59                         Snap sn;
  60                         sn.position = p;
  61                         sn.rotation = rotation;
  62                         (*i)->snap(sn, 1000, SNAP_SEGMENT);
  63                         float d = distance(p, sn.position);
  64                         if(d<dist || dist<0)
  65                         {
  66                                 position = sn.position;
  67                                 rotation = sn.rotation;
  68                                 track = *i;
  69                                 dist = d;
  70                         }
  71                 }
  72
  73         normalize_location();
  74 }
  75
  76 void Signal::normalize_location()
  77 {
  78         block = &track->get_block();
  79
  80         unsigned n_endpoints = track->get_type().get_endpoints().size();
  81         for(unsigned j=0; j<n_endpoints; ++j)
  82         {
  83                 Angle a = wrap_with_base(track->get_snap_node(j).rotation-rotation, -Angle::quarter_turn());
  84                 if(a>=Angle::quarter_turn())
  85                 {
  86                         BlockIter biter = TrackIter(track, j).block_iter();
  87                         entry = biter.entry();
  88                 }
  89         }
  90 }
  91
  92 void Signal::set_rotation(const Angle &r)
  93 {
  94         Angle a = wrap_with_base(rotation-r, -Angle::quarter_turn());
  95         if(a>=Angle::quarter_turn())
  96                 rotation = wrap_positive(rotation+Angle::half_turn());
  97
  98         normalize_location();
  99 }
 100
 101 unsigned Signal::get_n_snap_nodes() const
 102 {
 103         return 1;
 104 }
 105
 106 Snap Signal::get_snap_node(unsigned i) const
 107 {
 108         if(i>=1)
 109                 throw out_of_range("Signal::get_snap_node");
 110
 111         Snap sn;
 112         sn.position = position;
 113         sn.rotation = rotation;
 114         return sn;
 115 }
 116
 117 SnapType Signal::get_default_snap_type_to(const Object &other) const
 118 {
 119         if(dynamic_cast<const Track *>(&other))
 120                 return SNAP_SEGMENT;
 121
 122         return NO_SNAP;
 123 }
 124
 125 void Signal::tick(const Time::TimeDelta &)
 126 {
 127         if(check_allocated_blocks)
 128         {
 129                 unsigned n_blocks = 0;
 130                 BlockIter iter(block, entry);
 131                 iter = iter.next();
 132                 while(iter && iter->get_train()==train)
 133                 {
 134                         if(iter->get_sensor_id())
 135                                 ++n_blocks;
 136                         iter=iter.next();
 137                 }
 138                 check_allocated_blocks = false;
 139
 140                 const list<SignalType::Indication> &indications = type.get_indications();
 141                 unsigned aspect = indications.back().aspect;
 142                 for(list<SignalType::Indication>::const_iterator i=indications.begin(); i!=indications.end(); ++i)
 143                         if(n_blocks>=i->free_blocks)
 144                         {
 145                                 aspect = i->aspect;
 146                                 break;
 147                         }
 148
 149                 layout.get_driver().set_signal(address, aspect);
 150         }
 151 }
 152
 153 void Signal::block_reserved(const Block &b, Train *t)
 154 {
 155         if(&b==block)
 156         {
 157                 if(t)
 158                 {
 159                         int train_entry = t->get_entry_to_block(*block);
 160                         if(train_entry>=0 && static_cast<unsigned>(train_entry)==entry)
 161                         {
 162                                 if(train_conn)
 163                                         train_conn.disconnect();
 164                                 train = t;
 165                                 passing = false;
 166                                 train_conn = train->signal_advanced.connect(sigc::mem_fun(this, &Signal::train_advanced));
 167                                 check_allocated_blocks = true;
 168                         }
 169                 }
 170                 else
 171                 {
 172                         layout.get_driver().set_signal(address, type.get_indications().back().aspect);
 173                         reset();
 174                 }
 175         }
 176         else if(train && t==train)
 177                 check_allocated_blocks = true;
 178 }
 179
 180 void Signal::train_advanced(Block &b)
 181 {
 182         if(&b==block)
 183                 passing = true;
 184         else if(passing && b.get_sensor_id())
 185         {
 186                 layout.get_driver().set_signal(address, type.get_indications().back().aspect);
 187                 reset();
 188         }
 189 }
 190
 191 void Signal::reset()
 192 {
 193         train = 0;
 194         if(train_conn)
 195                 train_conn.disconnect();
 196         check_allocated_blocks = false;
 197 }
 198
 199 void Signal::save(list<DataFile::Statement> &st) const
 200 {
 201         st.push_back((DataFile::Statement("position"), position.x, position.y, position.z));
 202         st.push_back((DataFile::Statement("rotation"), rotation.radians()));
 203         if(address)
 204                 st.push_back((DataFile::Statement("address"), address));
 205 }
 206
 207
 208 Signal::Loader::Loader(Signal &s):
 209         DataFile::ObjectLoader<Signal>(s)
 210 {
 211         add("address",  &Loader::address);
 212         add("position", &Loader::position);
 213         add("rotation", &Loader::rotation);
 214 }
 215
 216 void Signal::Loader::address(unsigned a)
 217 {
 218         obj.set_address(a);
 219 }
 220
 221 void Signal::Loader::position(float x, float y, float z)
 222 {
 223         obj.set_position(Vector(x, y, z));
 224 }
 225
 226 void Signal::Loader::rotation(float d)
 227 {
 228         obj.set_rotation(Angle::from_radians(d));
 229 }
 230
 231 } // namespace R2C2