Resume allocation if a train moves out of its own way

[r2c2.git] / source / libr2c2 / blockallocator.cpp

#include <msp/core/maputils.h>
#include <msp/core/raii.h>
#include "beamgate.h"
#include "blockallocator.h"
#include "block.h"
#include "catalogue.h"
#include "driver.h"
#include "layout.h"
#include "trackcircuit.h"
#include "trackiter.h"
#include "train.h"
#include "vehicle.h"

using namespace std;
using namespace Msp;

namespace R2C2 {

struct BlockAllocator::BlockMatch
{
        const Block &block;

        BlockMatch(const Block &b): block(b) { }

        bool operator()(const BlockIter &bi) const { return &*bi==&block; }
};


BlockAllocator::BlockAllocator(Train &t):
        train(t),
        active(false),
        cur_blocks_end(blocks.end()),
        next_sensor(0),
        pending_block(0),
        stop_at_block(0),
        reserving(false),
        advancing(false)
{
        Layout &layout = train.get_layout();
        layout.signal_block_reserved.connect(sigc::mem_fun(this, &BlockAllocator::block_reserved));
        layout.signal_sensor_state_changed.connect(sigc::mem_fun(this, &BlockAllocator::sensor_state_changed));

        const set<Track *> &tracks = layout.get_all<Track>();
        for(set<Track *>::const_iterator i=tracks.begin(); i!=tracks.end(); ++i)
                if((*i)->get_type().is_turnout())
                {
                        (*i)->signal_path_changing.connect(sigc::hide(sigc::bind(sigc::mem_fun(this, &BlockAllocator::turnout_path_changing), sigc::ref(**i))));
                        (*i)->signal_path_changed.connect(sigc::hide(sigc::bind(sigc::mem_fun(this, &BlockAllocator::turnout_path_changed), sigc::ref(**i))));
                }
}

void BlockAllocator::set_active(bool a)
{
        active = a;
        if(active)
                reserve_more();
        else
        {
                release_blocks_end(cur_blocks_end);
                pending_block = 0;
        }
}

bool BlockAllocator::start_from(const BlockIter &block)
{
        if(!block)
                throw invalid_argument("BlockAllocator::start_from");

        float remaining_length = 0;
        unsigned n_vehs = train.get_n_vehicles();
        for(unsigned i=0; i<n_vehs; ++i)
                remaining_length += train.get_vehicle(i).get_type().get_length();

        clear();

        BlockList blocks_to_reserve;
        for(BlockIter b=block; b; b=b.next())
        {
                if(b->get_train())
                        break;
                blocks_to_reserve.push_back(b);
                for(TrackIter t=b.track_iter(); (t && &t->get_block()==&*b); t=t.next())
                        remaining_length -= t->get_path_length();
                if(remaining_length<=0)
                        break;
        }

        if(remaining_length>0)
                return false;

        for(BlockList::iterator i=blocks_to_reserve.begin(); i!=blocks_to_reserve.end(); ++i)
        {
                blocks.push_back(*i);
                try
                {
                        (*i)->reserve(&train);
                }
                catch(...)
                {
                        blocks.pop_back();
                        while(i!=blocks_to_reserve.begin())
                        {
                                blocks.pop_back();
                                (*--i)->reserve(0);
                        }
                        throw;
                }
        }

        return true;
}

void BlockAllocator::rewind_to(const Block &block)
{
        if(!active)
                return;

        BlockList::iterator i = find_if(cur_blocks_end, blocks.end(), BlockMatch(block));
        if(i!=blocks.end())
        {
                release_blocks_end(i);
                reserve_more();
        }
}

void BlockAllocator::clear()
{
        release_blocks_begin(blocks.end());
        active = false;
        next_sensor = 0;
        pending_block = 0;
        stop_at_block = 0;
}

void BlockAllocator::stop_at(const Block *block)
{
        stop_at_block = block;
        if(active && !block)
                reserve_more();
}

const BlockIter &BlockAllocator::first() const
{
        if(blocks.empty())
                throw logic_error("no blocks");
        return blocks.front();
}

const BlockIter &BlockAllocator::last() const
{
        if(blocks.empty())
                throw logic_error("no blocks");
        BlockList::const_iterator i = --blocks.end();
        if(i->block()==pending_block)
                --i;
        return *i;
}

const BlockIter &BlockAllocator::last_current() const
{
        if(blocks.empty())
                throw logic_error("no blocks");
        if(cur_blocks_end==blocks.begin())
                throw logic_error("internal error (no current blocks)");
        BlockList::const_iterator i = cur_blocks_end;
        return *--i;
}

const BlockIter &BlockAllocator::iter_for(const Block &block) const
{
        BlockList::const_iterator i = find_if(blocks.begin(), blocks.end(), BlockMatch(block));
        if(i==blocks.end())
                throw key_error(&block);
        return *i;
}

bool BlockAllocator::has_block(const Block &block) const
{
        return find_if(blocks.begin(), blocks.end(), BlockMatch(block))!=blocks.end();
}

bool BlockAllocator::is_block_current(const Block &block) const
{
        BlockList::const_iterator end = cur_blocks_end;
        return find_if(blocks.begin(), end, BlockMatch(block))!=cur_blocks_end;
}

void BlockAllocator::reserve_more()
{
        if(blocks.empty())
                throw logic_error("no blocks");

        BlockIter start = blocks.back();
        if(&*start==stop_at_block)
                return;
        else if(&*start==pending_block)
        {
                TrackIter track = start.track_iter();
                if(track->is_path_changing() || !track.endpoint().has_path(track->get_active_path()))
                        return;
        }

        pending_block = 0;

        // See how many sensor blocks and how much track we already have
        unsigned nsens = 0;
        float dist = 0;
        for(BlockList::const_iterator i=cur_blocks_end; i!=blocks.end(); ++i)
        {
                if((*i)->get_sensor_address())
                        ++nsens;
                if(nsens>0)
                        dist += (*i)->get_path_length(i->entry());
        }

        float approach_margin = 50*train.get_layout().get_catalogue().get_scale();
        float min_dist = train.get_controller().get_braking_distance()*1.3+approach_margin*2;

        BlockIter block = start;

        SetFlag setf(reserving);

        while(1)
        {
                BlockIter prev = block;
                block = block.next();
                if(!block || block->get_endpoints().size()<2)
                        // The track ends here
                        break;

                if(block->get_turnout_address() && !prev->get_turnout_address())
                {
                        /* We are arriving at a turnout.  See if we have enough blocks and
                        distance reserved. */
                        if(nsens>=3 && dist>=min_dist)
                                break;
                }

                if(!reserve_block(block))
                {
                        pending_block = &*block;
                        break;
                }

                if(cur_blocks_end==blocks.end())
                        --cur_blocks_end;

                TrackIter track = block.track_iter();
                if(track->is_path_changing())
                {
                        pending_block = &*block;
                        break;
                }
                else
                {
                        unsigned path = track->get_active_path();
                        if(!track.endpoint().has_path(path))
                        {
                                path = track->get_type().coerce_path(track.entry(), path);
                                track->set_active_path(path);
                                if(track->is_path_changing())
                                {
                                        pending_block = &*block;
                                        break;
                                }
                        }
                }

                if(&*block==stop_at_block)
                        break;

                if(block->get_sensor_address())
                        ++nsens;
                if(nsens>0)
                        dist += block->get_path_length(block.entry());
        }

        if(!next_sensor)
        {
                update_next_sensor(0);
                // Immediately advance to just before the next sensor
                advance_front(next_sensor);
        }
}

bool BlockAllocator::reserve_block(const BlockIter &block)
{
        /* Add it to the list first to present a consistent state in block_reserved
        signal. */
        blocks.push_back(block);

        bool first_reserve = (cur_blocks_end==blocks.end());
        if(first_reserve)
                --cur_blocks_end;

        try
        {
                if(!block->reserve(&train))
                {
                        if(first_reserve)
                                cur_blocks_end = blocks.end();
                        blocks.pop_back();
                        return false;
                }

                return true;
        }
        catch(...)
        {
                if(first_reserve)
                        cur_blocks_end = blocks.end();
                blocks.pop_back();
                throw;
        }
}

void BlockAllocator::advance_front(const Block *block, bool inclusive)
{
        BlockList::iterator end;
        if(block)
        {
                end = cur_blocks_end;
                if(inclusive)
                        --end;
                end = find_if(end, blocks.end(), BlockMatch(*block));
                if(inclusive && end!=blocks.end())
                        ++end;
        }
        else
                end = blocks.end();

        if(end==blocks.end() && blocks.back().block()==pending_block)
                --end;

        SetFlag setf(advancing);
        BlockList::iterator i = cur_blocks_end;
        // Update cur_blocks_end first to keep things consistent.
        cur_blocks_end = end;
        for(; i!=end; ++i)
                signal_advanced.emit(**i, (*i)->get_sensor());
}

void BlockAllocator::advance_front(const Sensor *sensor)
{
        if(sensor)
                advance_front(sensor->get_block(), dynamic_cast<const BeamGate *>(sensor));
        else
                advance_front(0, false);
}

void BlockAllocator::advance_back()
{
        bool rev = train.get_controller().get_reverse();
        const Vehicle &veh = train.get_vehicle(rev ? 0 : train.get_n_vehicles()-1);
        const Block &veh_block = veh.get_placement().get_position(rev ? VehiclePlacement::FRONT_AXLE : VehiclePlacement::BACK_AXLE)->get_block();

        bool pending_cleared = false;

        /* Sensors aren't guaranteed to be detriggered in order.  Go through the
        block list and locate the first sensor that's still active. */
        BlockList::iterator end = blocks.end();
        for(BlockList::iterator i=blocks.begin(); i!=cur_blocks_end; ++i)
        {
                Block *block = &**i;
                list<Sensor *> sensors;

                /* Collect all sensors from the block in the order they are expected to
                detrigger. */
                for(TrackIter j=i->track_iter(); (j && &j->get_block()==block); j=j.next())
                        if(!j->get_attachments().empty())
                        {
                                Track::AttachmentList attachments = j->get_attachments_ordered(j.entry());
                                for(Track::AttachmentList::const_iterator k=attachments.begin(); k!=attachments.end(); ++k)
                                        if(BeamGate *gate = dynamic_cast<BeamGate *>(*k))
                                                sensors.push_back(gate);
                        }

                if(Sensor *sensor = (*i)->get_sensor())
                        sensors.push_back(sensor);

                /* See if any sensor is still active, and record the position of the
                last inactive sensor. */
                bool active_sensor = false;
                for(list<Sensor *>::const_iterator j=sensors.begin(); (!active_sensor && j!=sensors.end()); ++j)
                {
                        if((*j)->get_state())
                                active_sensor = true;
                        else
                                end = i;
                }

                if(block==pending_block)
                        pending_cleared = true;

                // Stop if we encounter an active sensor or the train's last vehicle
                if(block==&veh_block || active_sensor)
                {
                        if(end!=blocks.end())
                        {
                                /* If the last inactive sensor was in an earlier block, release
                                that block as well. */
                                if(i!=end)
                                        ++end;
                                release_blocks_begin(end);
                                signal_rear_advanced.emit(*last());
                        }

                        if(pending_cleared)
                                reserve_more();

                        return;
                }
        }
}

void BlockAllocator::release_blocks_begin(const BlockList::iterator &end)
{
        for(BlockList::iterator i=blocks.begin(); i!=end; )
                release_block(i++);
}

void BlockAllocator::release_blocks_end(const BlockList::iterator &begin)
{
        // Guard against decrementing blocks.begin()
        if(begin==blocks.begin())
                return release_blocks_begin(blocks.end());

        if(begin==blocks.end())
                return;

        /* Release the blocks in reverse order so that a consistent state is
        presented in block_reserved signal. */
        bool done = false;
        for(BlockList::iterator i=--blocks.end(); !done; )
        {
                done = (i==begin);
                release_block(i--);
        }
}

void BlockAllocator::release_block(const BlockList::iterator &i)
{
        if(advancing)
                throw logic_error("cannot release while advancing");
        if(i==cur_blocks_end)
                ++cur_blocks_end;
        if(next_sensor && &**i==next_sensor->get_block())
                next_sensor = 0;
        if(&**i==pending_block)
                pending_block = 0;

        Block &block = **i;
        blocks.erase(i);
        block.reserve(0);
}

void BlockAllocator::reverse()
{
        release_blocks_end(cur_blocks_end);
        blocks.reverse();
        for(BlockList::iterator i=blocks.begin(); i!=blocks.end(); ++i)
                *i = i->reverse();

        if(active)
                reserve_more();
}

void BlockAllocator::turnout_path_changing(Track &track)
{
        BlockList::iterator i = find_if(cur_blocks_end, blocks.end(), BlockMatch(track.get_block()));
        if(i!=blocks.end())
        {
                ++i;
                release_blocks_end(i);
                pending_block = &track.get_block();
        }
}

void BlockAllocator::turnout_path_changed(Track &track)
{
        if(&track.get_block()==pending_block && !reserving)
                reserve_more();
}

void BlockAllocator::block_reserved(Block &block, const Train *tr)
{
        if(&block==pending_block && !tr && !reserving)
                reserve_more();
}

void BlockAllocator::sensor_state_changed(Sensor &sensor, Sensor::State state)
{
        Block *block = sensor.get_block();
        if(!block || block->get_train()!=&train)
                return;

        if(state==Sensor::MAYBE_ACTIVE)
        {
                if(&sensor==next_sensor)
                {
                        if(is_block_current(*block))
                                signal_advanced.emit(*block, &sensor);
                        update_next_sensor(next_sensor);
                        advance_front(next_sensor);

                        if(active)
                                reserve_more();
                }
                else if(!is_block_current(*block))
                        train.get_layout().emergency(block, "Sensor for "+train.get_name()+" triggered out of order");
        }
        else if(state==Sensor::INACTIVE)
                advance_back();
}

void BlockAllocator::update_next_sensor(Sensor *after)
{
        BeamGate *after_gate = dynamic_cast<BeamGate *>(after);

        BlockList::iterator i = cur_blocks_end;
        if(after)
        {
                if(after_gate)
                        --i;
                i = find_if(i, blocks.end(), BlockMatch(*after->get_block()));
        }

        for(; i!=blocks.end(); ++i)
        {
                if(Sensor *sensor = (*i)->get_sensor())
                {
                        if(!after_gate && sensor!=next_sensor)
                        {
                                next_sensor = sensor;
                                return;
                        }
                }

                Block *block = &**i;
                for(TrackIter j=i->track_iter(); (j && &j->get_block()==block); j=j.next())
                        if(!j->get_attachments().empty())
                        {
                                Track::AttachmentList attachments = j->get_attachments_ordered(j.entry());
                                for(Track::AttachmentList::const_iterator k=attachments.begin(); k!=attachments.end(); ++k)
                                        if(BeamGate *gate = dynamic_cast<BeamGate *>(*k))
                                        {
                                                if(after_gate)
                                                {
                                                        if(gate==after_gate)
                                                                after_gate = 0;
                                                }
                                                else
                                                {
                                                        next_sensor = gate;
                                                        return;
                                                }
                                        }
                        }
        }

        next_sensor = 0;
}

void BlockAllocator::save(list<DataFile::Statement> &st) const
{
        if(!blocks.empty() && cur_blocks_end!=blocks.begin())
        {
                BlockList cur_blocks(blocks.begin(), BlockList::const_iterator(cur_blocks_end));
                BlockIter prev;
                if(train.get_controller().get_reverse())
                {
                        cur_blocks.reverse();
                        prev = cur_blocks.front().next();
                }
                else
                        prev = cur_blocks.front().flip();

                st.push_back((DataFile::Statement("hint"), prev->get_id()));

                for(BlockList::const_iterator i=cur_blocks.begin(); i!=cur_blocks.end(); ++i)
                        st.push_back((DataFile::Statement("block"), (*i)->get_id()));
        }
}


BlockAllocator::Loader::Loader(BlockAllocator &ba):
        DataFile::ObjectLoader<BlockAllocator>(ba),
        valid(true)
{
        add("block", &Loader::block);
        add("hint",  &Loader::hint);
}

void BlockAllocator::Loader::block(unsigned id)
{
        if(!valid)
                return;

        Block *blk;
        try
        {
                blk = &obj.train.get_layout().get_block(id);
        }
        catch(const key_error &)
        {
                valid = false;
                return;
        }

        int entry = -1;
        if(prev_block)
                entry = blk->get_endpoint_by_link(*prev_block);
        if(entry<0)
                entry = 0;

        obj.blocks.push_back(BlockIter(blk, entry));
        blk->reserve(&obj.train);

        if(blk->get_sensor_address())
                obj.train.get_layout().get_driver().set_sensor(blk->get_sensor_address(), true);

        prev_block = blk;
}

void BlockAllocator::Loader::hint(unsigned id)
{
        try
        {
                prev_block = &obj.train.get_layout().get_block(id);
        }
        catch(const key_error &)
        {
                valid = false;
        }
}

} // namespace R2C2