std::pair<MSVehicle*, SUMOReal>
MSLink::getLeaderInfo(const std::map<const MSLink*, std::string>& previousLeaders, SUMOReal dist) const {
    if (MSGlobals::gUsingInternalLanes && myJunctionInlane == 0) {
        // this is an exit link

        // there might have been a link leader from previous steps who still qualifies
        // but is not the last vehicle on the foe lane anymore
        std::map<const MSLink*, std::string>::const_iterator it = previousLeaders.find(this);
        if (it != previousLeaders.end()) {
            MSVehicle* leader = dynamic_cast<MSVehicle*>(MSNet::getInstance()->getVehicleControl().getVehicle(it->second));
            if (leader != 0 && std::find(myFoeLanes.begin(), myFoeLanes.end(), leader->getLane()) != myFoeLanes.end()) {
                return std::make_pair(leader,
                                      dist - (leader->getLane()->getLength() - leader->getPositionOnLane()) - leader->getVehicleType().getLength());
            }
        }
        // now check for last vehicle on foe lane
        for (std::vector<MSLane*>::const_iterator i = myFoeLanes.begin(); i != myFoeLanes.end(); ++i) {
            assert((*i)->getLinkCont().size() == 1);
            MSLink* exitLink = (*i)->getLinkCont()[0];
            if (myLane == exitLink->getLane()) {
                MSVehicle* leader = (*i)->getLastVehicle();
                if (leader != 0) {
                    return std::make_pair(leader,
                                          dist - ((*i)->getLength() - leader->getPositionOnLane()) - leader->getVehicleType().getLength());
                }
            }
        }
    }
    return std::make_pair<MSVehicle*, SUMOReal>(0, 0);
}
示例#2
0
int
MSLaneChangerSublane::checkChangeSublane(
    int laneOffset,
    const std::vector<MSVehicle::LaneQ>& preb,
    SUMOReal& latDist) const {

    ChangerIt target = myCandi + laneOffset;
    MSVehicle* vehicle = veh(myCandi);
    const MSLane& neighLane = *(target->lane);
    int blocked = 0;

    //gDebugFlag1 = vehicle->getLaneChangeModel().debugVehicle();

    MSLeaderDistanceInfo neighLeaders = getLeaders(target, vehicle);
    MSLeaderDistanceInfo neighFollowers = target->lane->getFollowersOnConsecutive(vehicle, true);
    MSLeaderDistanceInfo neighBlockers(&neighLane, vehicle, vehicle->getLane()->getRightSideOnEdge() - neighLane.getRightSideOnEdge());
    MSLeaderDistanceInfo leaders = getLeaders(myCandi, vehicle);
    MSLeaderDistanceInfo followers = myCandi->lane->getFollowersOnConsecutive(vehicle, true);
    MSLeaderDistanceInfo blockers(vehicle->getLane(), vehicle, 0);

    if (gDebugFlag1) std::cout << SIMTIME
                                   << " checkChangeSublane: veh=" << vehicle->getID()
                                   << " laneOffset=" << laneOffset
                                   << "\n  leaders=" << leaders.toString()
                                   << "\n  neighLeaders=" << neighLeaders.toString()
                                   << "\n";


    const int wish = vehicle->getLaneChangeModel().wantsChangeSublane(
                         laneOffset,
                         leaders, followers, blockers,
                         neighLeaders, neighFollowers, neighBlockers,
                         neighLane, preb,
                         &(myCandi->lastBlocked), &(myCandi->firstBlocked), latDist, blocked);
    int state = blocked | wish;

    // XXX
    // do are more carefull (but expensive) check to ensure that a
    // safety-critical leader is not being overloocked

    // XXX
    // ensure that a continuous lane change manoeuvre can be completed
    // before the next turning movement

#ifndef NO_TRACI
    // let TraCI influence the wish to change lanes and the security to take
    //const int oldstate = state;
    state = vehicle->influenceChangeDecision(state);
    //if (vehicle->getID() == "150_2_36000000") {
    //    std::cout << STEPS2TIME(MSNet::getInstance()->getCurrentTimeStep()) << " veh=" << vehicle->getID() << " oldstate=" << oldstate << " newstate=" << state << "\n";
    //}
#endif
    gDebugFlag1 = false;
    return state;
}
示例#3
0
bool
MSLaneChangerSublane::change() {
    // variant of change() for the sublane case
    myCandi = findCandidate();
    MSVehicle* vehicle = veh(myCandi);
#ifdef DEBUG_VEHICLE_GUI_SELECTION
    if (gDebugSelectedVehicle == vehicle->getID()) {
        int bla = 0;
    }
#endif
    assert(vehicle->getLane() == (*myCandi).lane);
    assert(!vehicle->getLaneChangeModel().isChangingLanes());
#ifndef NO_TRACI
    if (vehicle->isRemoteControlled()) {
        return false; // !!! temporary; just because it broke, here
    }
#endif
    vehicle->updateBestLanes(); // needed?
    for (int i = 0; i < (int) myChanger.size(); ++i) {
        vehicle->adaptBestLanesOccupation(i, myChanger[i].dens);
    }

    // update expected speeds
    int sublaneIndex = 0;
    for (ChangerIt ce = myChanger.begin(); ce != myChanger.end(); ++ce) {
        vehicle->getLaneChangeModel().updateExpectedSublaneSpeeds(ce->ahead, sublaneIndex, ce->lane->getIndex());
        sublaneIndex += ce->ahead.numSublanes();
    }

    StateAndDist right = checkChangeHelper(vehicle, -1);
    StateAndDist left = checkChangeHelper(vehicle, 1);
    StateAndDist current = checkChangeHelper(vehicle, 0);

    StateAndDist decision = vehicle->getLaneChangeModel().decideDirection(current,
                            vehicle->getLaneChangeModel().decideDirection(right, left));
    if ((decision.state & LCA_WANTS_LANECHANGE) != 0 && (decision.state & LCA_BLOCKED) == 0) {
        // change if the vehicle wants to and is allowed to change
        if (vehicle->getLaneChangeModel().debugVehicle()) {
            std::cout << SIMTIME << " decision=" << toString((LaneChangeAction)decision.state) << " latDist=" << decision.latDist << "\n";
        }
        vehicle->getLaneChangeModel().setOwnState(decision.state);
        return startChangeSublane(vehicle, myCandi, decision.latDist);
    }

    if ((right.state & (LCA_URGENT)) != 0 && (left.state & (LCA_URGENT)) != 0) {
        // ... wants to go to the left AND to the right
        // just let them go to the right lane...
        left.state = 0;
    }
    vehicle->getLaneChangeModel().setOwnState(right.state | left.state | current.state);

    registerUnchanged(vehicle);
    return false;
}
示例#4
0
void
MSLaneChangerSublane::updateChanger(bool vehHasChanged) {
    MSLaneChanger::updateChanger(vehHasChanged);
    if (!vehHasChanged) {
        MSVehicle* lead = myCandi->lead;
        //std::cout << SIMTIME << " updateChanger lane=" << myCandi->lane->getID() << " lead=" << Named::getIDSecure(lead) << "\n";
        myCandi->ahead.addLeader(lead, false, 0);
        MSLane* shadowLane = lead->getLaneChangeModel().getShadowLane();
        if (shadowLane != 0) {
            const SUMOReal latOffset = lead->getLane()->getRightSideOnEdge() - shadowLane->getRightSideOnEdge();
            //std::cout << SIMTIME << " updateChanger shadowLane=" << shadowLane->getID() << " lead=" << Named::getIDSecure(lead) << "\n";
            (myChanger.begin() + shadowLane->getIndex())->ahead.addLeader(lead, false, latOffset);
        }
    }
    //std::cout << SIMTIME << " updateChanger: lane=" << myCandi->lane->getID() << " lead=" << Named::getIDSecure(myCandi->lead) << " ahead=" << myCandi->ahead.toString() << " vehHasChanged=" << vehHasChanged << "\n";
    //for (ChangerIt ce = myChanger.begin(); ce != myChanger.end(); ++ce) {
    //    std::cout << " lane=" << ce->lane->getID() << " vehicles=" << toString(ce->lane->myVehicles) << "\n";
    //}
}
bool
MSCalibrator::removePending() {
    if (myToRemove.size() > 0) {
        MSVehicleControl& vc = MSNet::getInstance()->getVehicleControl();
        // it is not save to remove the vehicles inside
        // VehicleRemover::notifyEnter so we do it here
        for (std::set<std::string>::iterator it = myToRemove.begin(); it != myToRemove.end(); ++it) {
            MSVehicle* vehicle = dynamic_cast<MSVehicle*>(vc.getVehicle(*it));
            if (vehicle != nullptr) {
                vehicle->onRemovalFromNet(MSMoveReminder::NOTIFICATION_VAPORIZED);
                vehicle->getLane()->removeVehicle(vehicle, MSMoveReminder::NOTIFICATION_VAPORIZED);
                vc.scheduleVehicleRemoval(vehicle);
            } else {
                WRITE_WARNING("Calibrator '" + getID() + "' could not remove vehicle '" + *it + "'.");
            }
        }
        myToRemove.clear();
        return true;
    }
    return false;
}
示例#6
0
std::pair<MSVehicle * const, SUMOReal>
MSLane::getFollowerOnConsecutive(SUMOReal dist, SUMOReal seen, SUMOReal leaderSpeed, SUMOReal backOffset) const {
    // ok, a vehicle has not noticed the lane about itself;
    //  iterate as long as necessary to search for an approaching one
    std::set<MSLane*> visited;
    std::vector<std::pair<MSVehicle *, SUMOReal> > possible;
    std::vector<MSLane::IncomingLaneInfo> newFound;
    std::vector<MSLane::IncomingLaneInfo> toExamine = myIncomingLanes;
    while (toExamine.size()!=0) {
        for (std::vector<MSLane::IncomingLaneInfo>::iterator i=toExamine.begin(); i!=toExamine.end(); ++i) {
            /*
            if ((*i).viaLink->getState()==MSLink::LINKSTATE_TL_RED) {
                continue;
            }
            */
            MSLane *next = (*i).lane;
            if (next->getFirstVehicle()!=0) {
                MSVehicle * v = (MSVehicle*) next->getFirstVehicle();
                SUMOReal agap = (*i).length - v->getPositionOnLane() + backOffset;
                if (!v->getCarFollowModel().hasSafeGap(v->getCarFollowModel().maxNextSpeed(v->getSpeed()), agap, leaderSpeed, v->getLane().getMaxSpeed())) {
                    possible.push_back(std::make_pair(v, (*i).length-v->getPositionOnLane()+seen));
                }
            } else {
                if ((*i).length+seen<dist) {
                    const std::vector<MSLane::IncomingLaneInfo> &followers = next->getIncomingLanes();
                    for (std::vector<MSLane::IncomingLaneInfo>::const_iterator j=followers.begin(); j!=followers.end(); ++j) {
                        if (visited.find((*j).lane)==visited.end()) {
                            visited.insert((*j).lane);
                            MSLane::IncomingLaneInfo ili;
                            ili.lane = (*j).lane;
                            ili.length = (*j).length + (*i).length;
                            ili.viaLink = (*j).viaLink;
                            newFound.push_back(ili);
                        }
                    }
                }
            }
        }
        toExamine.clear();
        swap(newFound, toExamine);
    }
    if (possible.size()==0) {
        return std::pair<MSVehicle * const, SUMOReal>(0, -1);
    }
    sort(possible.begin(), possible.end(), by_second_sorter());
    return *(possible.begin());
}
void
MSE2Collector::detectorUpdate(const SUMOTime /* step */) {
    JamInfo* currentJam = 0;
    std::map<SUMOVehicle*, SUMOTime> haltingVehicles;
    std::map<SUMOVehicle*, SUMOTime> intervalHaltingVehicles;
    std::vector<JamInfo*> jams;

    SUMOReal lengthSum = 0;
    myCurrentMeanSpeed = 0;
    myCurrentMeanLength = 0;
    myCurrentStartedHalts = 0;
    myCurrentHaltingsNumber = 0;

    // go through the (sorted) list of vehicles positioned on the detector
    //  sum up values and prepare the list of jams
    myKnownVehicles.sort(by_vehicle_position_sorter(getLane()));
    for (std::list<SUMOVehicle*>::const_iterator i = myKnownVehicles.begin(); i != myKnownVehicles.end(); ++i) {
        MSVehicle* veh = static_cast<MSVehicle*>(*i);

        SUMOReal length = veh->getVehicleType().getLength();
        if (veh->getLane() == getLane()) {
            if (veh->getPositionOnLane() - veh->getVehicleType().getLength() < myStartPos) {
                // vehicle entered detector partially
                length -= (veh->getVehicleType().getLength() - (veh->getPositionOnLane() - myStartPos));
            }
            if (veh->getPositionOnLane() > myEndPos && veh->getPositionOnLane() - veh->getVehicleType().getLength() <= myEndPos) {
                // vehicle left detector partially
                length -= (veh->getPositionOnLane() - myEndPos);
            }
        } else {
            // ok, the vehicle is only partially still on the detector, has already moved to the
            //  next lane; still, we do not know how far away it is
            assert(veh == myLane->getPartialOccupator());
            length = myEndPos - myLane->getPartialOccupatorEnd();
        }
        assert(length >= 0);

        mySpeedSum += veh->getSpeed();
        myCurrentMeanSpeed += veh->getSpeed();
        lengthSum += length;
        myCurrentMeanLength += length;

        // jam-checking begins
        bool isInJam = false;
        // first, check whether the vehicle is slow enough to be states as halting
        if (veh->getSpeed() < myJamHaltingSpeedThreshold) {
            myCurrentHaltingsNumber++;
            // we have to track the time it was halting;
            //  so let's look up whether it was halting before and compute the overall halting time
            bool wasHalting = myHaltingVehicleDurations.find(veh) != myHaltingVehicleDurations.end();
            if (wasHalting) {
                haltingVehicles[veh] = myHaltingVehicleDurations[veh] + DELTA_T;
                intervalHaltingVehicles[veh] = myIntervalHaltingVehicleDurations[veh] + DELTA_T;
            } else {
                haltingVehicles[veh] = DELTA_T;
                intervalHaltingVehicles[veh] = DELTA_T;
                myCurrentStartedHalts++;
                myStartedHalts++;
            }
            // we now check whether the halting time is large enough
            if (haltingVehicles[veh] > myJamHaltingTimeThreshold) {
                // yep --> the vehicle is a part of a jam
                isInJam = true;
            }
        } else {
            // is not standing anymore; keep duration information
            std::map<SUMOVehicle*, SUMOTime>::iterator v = myHaltingVehicleDurations.find(veh);
            if (v != myHaltingVehicleDurations.end()) {
                myPastStandingDurations.push_back((*v).second);
                myHaltingVehicleDurations.erase(v);
            }
            v = myIntervalHaltingVehicleDurations.find(veh);
            if (v != myIntervalHaltingVehicleDurations.end()) {
                myPastIntervalStandingDurations.push_back((*v).second);
                myIntervalHaltingVehicleDurations.erase(v);
            }
        }

        // jam-building
        if (isInJam) {
            // the vehicle is in a jam;
            //  it may be a new one or already an existing one
            if (currentJam == 0) {
                // the vehicle is the first vehicle in a jam
                currentJam = new JamInfo;
                currentJam->firstStandingVehicle = i;
            } else {
                // ok, we have a jam already. But - maybe it is too far away
                //  ... honestly, I can hardly find a reason for doing this,
                //  but jams were defined this way in an earlier version...
                if (veh->getPositionOnLane() - (*currentJam->lastStandingVehicle)->getPositionOnLane() > myJamDistanceThreshold) {
                    // yep, yep, yep - it's a new one...
                    //  close the frist, build a new
                    jams.push_back(currentJam);
                    currentJam = new JamInfo;
                    currentJam->firstStandingVehicle = i;
                }
            }
            currentJam->lastStandingVehicle = i;
        } else {
            // the vehicle is not part of a jam...
            //  maybe we have to close an already computed jam
            if (currentJam != 0) {
                jams.push_back(currentJam);
                currentJam = 0;
            }
        }
    }
    if (currentJam != 0) {
        jams.push_back(currentJam);
        currentJam = 0;
    }

    myCurrentMaxJamLengthInMeters = 0;
    myCurrentMaxJamLengthInVehicles = 0;
    myCurrentJamLengthInMeters = 0;
    myCurrentJamLengthInVehicles = 0;
    // process jam information
    for (std::vector<JamInfo*>::iterator i = jams.begin(); i != jams.end(); ++i) {
        // compute current jam's values
        SUMOReal jamLengthInMeters =
            (*(*i)->firstStandingVehicle)->getPositionOnLane()
            - (*(*i)->lastStandingVehicle)->getPositionOnLane()
            + (*(*i)->lastStandingVehicle)->getVehicleType().getLengthWithGap();
        const MSVehicle* const occ = myLane->getPartialOccupator();
        if (occ && occ == *(*i)->firstStandingVehicle && occ != *(*i)->lastStandingVehicle) {
            jamLengthInMeters = myLane->getPartialOccupatorEnd() + occ->getVehicleType().getLengthWithGap()
                                - (*(*i)->lastStandingVehicle)->getPositionOnLane()
                                + (*(*i)->lastStandingVehicle)->getVehicleType().getLengthWithGap();
        }
        unsigned jamLengthInVehicles = (unsigned) distance((*i)->firstStandingVehicle, (*i)->lastStandingVehicle) + 1;
        // apply them to the statistics
        myCurrentMaxJamLengthInMeters = MAX2(myCurrentMaxJamLengthInMeters, jamLengthInMeters);
        myCurrentMaxJamLengthInVehicles = MAX2(myCurrentMaxJamLengthInVehicles, jamLengthInVehicles);
        myJamLengthInMetersSum += jamLengthInMeters;
        myJamLengthInVehiclesSum += jamLengthInVehicles;
        myCurrentJamLengthInMeters += jamLengthInMeters;
        myCurrentJamLengthInVehicles += jamLengthInVehicles;
    }
    myCurrentJamNo = (unsigned) jams.size();

    unsigned noVehicles = (unsigned) myKnownVehicles.size();
    myVehicleSamples += noVehicles;
    myTimeSamples += 1;
    // compute occupancy values
    SUMOReal currentOccupancy = lengthSum / (myEndPos - myStartPos) * (SUMOReal) 100.;
    myCurrentOccupancy = currentOccupancy;
    myOccupancySum += currentOccupancy;
    myMaxOccupancy = MAX2(myMaxOccupancy, currentOccupancy);
    // compute jam values
    myMeanMaxJamInVehicles += myCurrentMaxJamLengthInVehicles;
    myMeanMaxJamInMeters += myCurrentMaxJamLengthInMeters;
    myMaxJamInVehicles = MAX2(myMaxJamInVehicles, myCurrentMaxJamLengthInVehicles);
    myMaxJamInMeters = MAX2(myMaxJamInMeters, myCurrentMaxJamLengthInMeters);
    // save information about halting vehicles
    myHaltingVehicleDurations = haltingVehicles;
    myIntervalHaltingVehicleDurations = intervalHaltingVehicles;
    // compute information about vehicle numbers
    myMeanVehicleNumber += (unsigned) myKnownVehicles.size();
    myMaxVehicleNumber = MAX2((unsigned) myKnownVehicles.size(), myMaxVehicleNumber);
    // norm current values
    myCurrentMeanSpeed = noVehicles != 0 ? myCurrentMeanSpeed / (SUMOReal) noVehicles : -1;
    myCurrentMeanLength = noVehicles != 0 ? myCurrentMeanLength / (SUMOReal) noVehicles : -1;

    // clean up
    for (std::vector<JamInfo*>::iterator i = jams.begin(); i != jams.end(); ++i) {
        delete *i;
    }
    jams.clear();
}
示例#8
0
bool
MSLaneChanger::changeOpposite(std::pair<MSVehicle*, SUMOReal> leader) {
    if (!myChangeToOpposite) {
        return false;
    }
    myCandi = findCandidate();
    MSVehicle* vehicle = veh(myCandi);
    MSLane* source = vehicle->getLane();
    if (vehicle->isStopped()) {
        // stopped vehicles obviously should not change lanes. Usually this is
        // prevent by appropriate bestLane distances
        return false;
    }
    const bool isOpposite = vehicle->getLaneChangeModel().isOpposite();
    if (!isOpposite && leader.first == 0) {
        // no reason to change unless there is a leader
        // or we are changing back to the propper direction
        // XXX also check whether the leader is so far away as to be irrelevant
        return false;
    }
    MSLane* opposite = source->getOpposite();
    if (opposite == 0) {
        return false;
    }

    // changing into the opposite direction is always to the left (XXX except for left-hand networkds)
    int direction = isOpposite ? -1 : 1;
    std::pair<MSVehicle*, SUMOReal> neighLead((MSVehicle*)0, -1);

    // preliminary sanity checks for overtaking space
    SUMOReal timeToOvertake;
    SUMOReal spaceToOvertake;
    if (!isOpposite) {
        assert(leader.first != 0);
        // find a leader vehicle with sufficient space ahead for merging back
        const SUMOReal overtakingSpeed = source->getVehicleMaxSpeed(vehicle); // just a guess
        const SUMOReal mergeBrakeGap = vehicle->getCarFollowModel().brakeGap(overtakingSpeed);
        std::pair<MSVehicle*, SUMOReal> columnLeader = leader;
        SUMOReal egoGap = leader.second;
        bool foundSpaceAhead = false;
        SUMOReal seen = leader.second + leader.first->getVehicleType().getLengthWithGap();
        std::vector<MSLane*> conts = vehicle->getBestLanesContinuation();
        while (!foundSpaceAhead) {
            const SUMOReal requiredSpaceAfterLeader = (columnLeader.first->getCarFollowModel().getSecureGap(
                        columnLeader.first->getSpeed(), overtakingSpeed, vehicle->getCarFollowModel().getMaxDecel())
                    + vehicle->getVehicleType().getLengthWithGap());


            // all leader vehicles on the current laneChanger edge are already moved into MSLane::myTmpVehicles
            const bool checkTmpVehicles = (&columnLeader.first->getLane()->getEdge() == &source->getEdge());
            std::pair<MSVehicle* const, SUMOReal> leadLead = columnLeader.first->getLane()->getLeader(
                        columnLeader.first, columnLeader.first->getPositionOnLane(), conts, requiredSpaceAfterLeader + mergeBrakeGap, 
                        checkTmpVehicles);

#ifdef DEBUG_CHANGE_OPPOSITE
            if (DEBUG_COND) {
                std::cout << "   leadLead=" << Named::getIDSecure(leadLead.first) << " gap=" << leadLead.second << "\n";
            }
#endif
            if (leadLead.first == 0) {
                foundSpaceAhead = true;
            } else {
                const SUMOReal requiredSpace = (requiredSpaceAfterLeader
                                                + vehicle->getCarFollowModel().getSecureGap(overtakingSpeed, leadLead.first->getSpeed(), leadLead.first->getCarFollowModel().getMaxDecel()));
                if (leadLead.second > requiredSpace) {
                    foundSpaceAhead = true;
                } else {
#ifdef DEBUG_CHANGE_OPPOSITE
                    if (DEBUG_COND) {
                        std::cout << "   not enough space after columnLeader=" << columnLeader.first->getID() << " required=" << requiredSpace << "\n";
                    }
#endif
                    seen += MAX2((SUMOReal)0, leadLead.second) + leadLead.first->getVehicleType().getLengthWithGap();
                    if (seen > OPPOSITE_OVERTAKING_MAX_LOOKAHEAD) {
#ifdef DEBUG_CHANGE_OPPOSITE
                        if (DEBUG_COND) {
                            std::cout << "   cannot changeOpposite due to insufficient free space after columnLeader (seen=" << seen << " columnLeader=" << columnLeader.first->getID() << ")\n";
                        }
#endif
                        return false;
                    }
                    // see if merging after leadLead is possible
                    egoGap += columnLeader.first->getVehicleType().getLengthWithGap() + leadLead.second;
                    columnLeader = leadLead;
#ifdef DEBUG_CHANGE_OPPOSITE
                    if (DEBUG_COND) {
                        std::cout << "   new columnLeader=" << columnLeader.first->getID() << "\n";
                    }
#endif
                }
            }
        }
#ifdef DEBUG_CHANGE_OPPOSITE
        if (DEBUG_COND) {
            std::cout << "   compute time/space to overtake for columnLeader=" << columnLeader.first->getID() << " gap=" << columnLeader.second << "\n";
        }
#endif
        computeOvertakingTime(vehicle, columnLeader.first, egoGap, timeToOvertake, spaceToOvertake);
        // check for upcoming stops
        if (vehicle->nextStopDist() < spaceToOvertake) {
#ifdef DEBUG_CHANGE_OPPOSITE
            if (DEBUG_COND) {
                std::cout << "   cannot changeOpposite due to upcoming stop (dist=" << vehicle->nextStopDist() << " spaceToOvertake=" << spaceToOvertake << ")\n";
            }
#endif
            return false;
        }
        neighLead = opposite->getOppositeLeader(vehicle, timeToOvertake * opposite->getSpeedLimit() * 2 + spaceToOvertake, true);

#ifdef DEBUG_CHANGE_OPPOSITE
        if (DEBUG_COND) {
            std::cout << SIMTIME
                      << " veh=" << vehicle->getID()
                      << " changeOpposite opposite=" << opposite->getID()
                      << " lead=" << Named::getIDSecure(leader.first)
                      << " timeToOvertake=" << timeToOvertake
                      << " spaceToOvertake=" << spaceToOvertake
                      << "\n";
        }
#endif

        // check for dangerous oncoming leader
        if (neighLead.first != 0) {
            const MSVehicle* oncoming = neighLead.first;

#ifdef DEBUG_CHANGE_OPPOSITE
            if (DEBUG_COND) {
                std::cout << SIMTIME
                          << " oncoming=" << oncoming->getID()
                          << " oncomingGap=" << neighLead.second
                          << " leaderGap=" << leader.second
                          << "\n";
            }
#endif
            if (neighLead.second - spaceToOvertake - timeToOvertake * oncoming->getSpeed() < 0) {

#ifdef DEBUG_CHANGE_OPPOSITE
                if (DEBUG_COND) {
                    std::cout << "   cannot changeOpposite due to dangerous oncoming\n";
                }
#endif
                return false;
            }
        }
    } else {
        timeToOvertake = -1;
        // look forward as far as possible
        spaceToOvertake = std::numeric_limits<SUMOReal>::max();
        leader = source->getOppositeLeader(vehicle, OPPOSITE_OVERTAKING_ONCOMING_LOOKAHEAD, true);
        // -1 will use getMaximumBrakeDist() as look-ahead distance
        neighLead = opposite->getOppositeLeader(vehicle, -1, false); 
    }

    // compute remaining space on the opposite side
    // 1. the part that remains on the current lane
    SUMOReal usableDist = isOpposite ? vehicle->getPositionOnLane() : source->getLength() - vehicle->getPositionOnLane();
    if (usableDist < spaceToOvertake) {
        // look forward along the next lanes
        const std::vector<MSLane*>& bestLaneConts = vehicle->getBestLanesContinuation();
        assert(bestLaneConts.size() >= 1);
        std::vector<MSLane*>::const_iterator it = bestLaneConts.begin() + 1;
        while (usableDist < spaceToOvertake && it != bestLaneConts.end()) {
#ifdef DEBUG_CHANGE_OPPOSITE
            if (DEBUG_COND) {
                std::cout << "      usableDist=" << usableDist << " opposite=" << Named::getIDSecure((*it)->getOpposite()) << "\n";
            }
#endif
            if ((*it)->getOpposite() == 0) {
                // opposite lane ends
                break;
            }
            // do not overtake past a minor link or turn
            if (*(it - 1) != 0) {
                MSLink* link = MSLinkContHelper::getConnectingLink(**(it - 1), **it);
                if (link == 0 || !link->havePriority() || link->getState() == LINKSTATE_ZIPPER || link->getDirection() != LINKDIR_STRAIGHT) {
                    break;
                }
            }
            usableDist += (*it)->getLength();
            ++it;
        }
    }
    if (!isOpposite && usableDist < spaceToOvertake) {
#ifdef DEBUG_CHANGE_OPPOSITE
        if (DEBUG_COND) {
            std::cout << "   cannot changeOpposite due to insufficient space (seen=" << usableDist << " spaceToOvertake=" << spaceToOvertake << ")\n";
        }
#endif
        return false;
    }
#ifdef DEBUG_CHANGE_OPPOSITE
    if (DEBUG_COND) {
        std::cout << "   usableDist=" << usableDist << " spaceToOvertake=" << spaceToOvertake << " timeToOvertake=" << timeToOvertake << "\n";
    }
#endif

    // compute wish to change
    std::vector<MSVehicle::LaneQ> preb = vehicle->getBestLanes();
    if (isOpposite) {
        // compute the remaining distance that can be drive on the opposite side
        // this value will put into LaneQ.length of the leftmost lane
        // @note: length counts from the start of the current lane
        // @note: see MSLCM_LC2013::_wantsChange @1092 (isOpposite()
        MSVehicle::LaneQ& laneQ = preb[preb.size() - 1];
        // position on the target lane 
        const SUMOReal forwardPos = source->getOppositePos(vehicle->getPositionOnLane());

        // consider usableDist (due to minor links or end of opposite lanes)
        laneQ.length = MIN2(laneQ.length, usableDist + forwardPos);
        // consider upcoming stops
        laneQ.length = MIN2(laneQ.length, vehicle->nextStopDist() + forwardPos);
        // consider oncoming leaders
        if (leader.first != 0) {
            laneQ.length = MIN2(laneQ.length, leader.second / 2 + forwardPos);
#ifdef DEBUG_CHANGE_OPPOSITE
        if (DEBUG_COND) {
            std::cout << SIMTIME << " found oncoming leader=" << leader.first->getID() << " gap=" << leader.second << "\n";
        }
#endif
            leader.first = 0; // ignore leader after this
        } 
#ifdef DEBUG_CHANGE_OPPOSITE
        if (DEBUG_COND) {
            std::cout << SIMTIME << " veh=" << vehicle->getID() << " remaining dist=" << laneQ.length - forwardPos << " forwardPos=" << forwardPos << " laneQ.length=" << laneQ.length << "\n";
        }
#endif
    }
    std::pair<MSVehicle* const, SUMOReal> neighFollow = opposite->getOppositeFollower(vehicle);
    int state = checkChange(direction, opposite, leader, neighLead, neighFollow, preb);

    bool changingAllowed = (state & LCA_BLOCKED) == 0;
    // change if the vehicle wants to and is allowed to change
    if ((state & LCA_WANTS_LANECHANGE) != 0 && changingAllowed
            // do not change to the opposite direction for cooperative reasons
            && (isOpposite || (state & LCA_COOPERATIVE) == 0)) {
        vehicle->getLaneChangeModel().startLaneChangeManeuver(source, opposite, direction);
        /// XXX use a dedicated transformation function
        vehicle->myState.myPos = source->getOppositePos(vehicle->myState.myPos);
        /// XXX compute a better lateral position
        opposite->forceVehicleInsertion(vehicle, vehicle->getPositionOnLane(), MSMoveReminder::NOTIFICATION_LANE_CHANGE, 0);
        if (!isOpposite) {
            vehicle->myState.myBackPos = source->getOppositePos(vehicle->myState.myBackPos);
        }
#ifdef DEBUG_CHANGE_OPPOSITE
        if (DEBUG_COND) {
            std::cout << SIMTIME << " changing to opposite veh=" << vehicle->getID() << " dir=" << direction << " opposite=" << Named::getIDSecure(opposite) << " state=" << state << "\n";
        }
#endif
        return true;
    }
#ifdef DEBUG_CHANGE_OPPOSITE
    if (DEBUG_COND) {
        std::cout << SIMTIME << " not changing to opposite veh=" << vehicle->getID() << " dir=" << direction 
            << " opposite=" << Named::getIDSecure(opposite) << " state=" << toString((LaneChangeAction)state) << "\n";
    }
#endif
    return false;
}
示例#9
0
int
MSLaneChanger::checkChange(
    int laneOffset,
    const MSLane* targetLane,
    const std::pair<MSVehicle* const, SUMOReal>& leader,
    const std::pair<MSVehicle* const, SUMOReal>& neighLead,
    const std::pair<MSVehicle* const, SUMOReal>& neighFollow,
    const std::vector<MSVehicle::LaneQ>& preb) const {

    MSVehicle* vehicle = veh(myCandi);

    // Debug (Leo)
#ifdef DEBUG_CHECK_CHANGE
    if (DEBUG_COND) {
        std::cout
                << "\n" << SIMTIME << " checkChange() for vehicle '" << vehicle->getID() << "'"
                << std::endl;
    }
#endif


    int blocked = 0;
    int blockedByLeader = (laneOffset == -1 ? LCA_BLOCKED_BY_RIGHT_LEADER : LCA_BLOCKED_BY_LEFT_LEADER);
    int blockedByFollower = (laneOffset == -1 ? LCA_BLOCKED_BY_RIGHT_FOLLOWER : LCA_BLOCKED_BY_LEFT_FOLLOWER);
    // overlap
    if (neighFollow.first != 0 && neighFollow.second < 0) {
        blocked |= (blockedByFollower | LCA_OVERLAPPING);

        // Debug (Leo)
#ifdef DEBUG_CHECK_CHANGE
        if (DEBUG_COND) {
            std::cout << SIMTIME
                      << " overlapping with follower..."
                      << std::endl;
        }
#endif

    }
    if (neighLead.first != 0 && neighLead.second < 0) {
        blocked |= (blockedByLeader | LCA_OVERLAPPING);

        // Debug (Leo)
#ifdef DEBUG_CHECK_CHANGE
        if (DEBUG_COND) {
            std::cout << SIMTIME
                      <<  " overlapping with leader..."
                      << std::endl;
        }
#endif

    }

    // safe back gap
    if ((blocked & blockedByFollower) == 0 && neighFollow.first != 0) {
        // !!! eigentlich: vsafe braucht die Max. Geschwindigkeit beider Spuren
        if (neighFollow.second < neighFollow.first->getCarFollowModel().getSecureGap(neighFollow.first->getSpeed(), vehicle->getSpeed(), vehicle->getCarFollowModel().getMaxDecel())) {
            blocked |= blockedByFollower;

            // Debug (Leo)
#ifdef DEBUG_CHECK_CHANGE
            if (DEBUG_COND) {
                std::cout << SIMTIME
                          << " back gap unsafe: "
                          << "gap = " << neighFollow.second
                          << ", secureGap = "
                          << neighFollow.first->getCarFollowModel().getSecureGap(neighFollow.first->getSpeed(),
                                  vehicle->getSpeed(), vehicle->getCarFollowModel().getMaxDecel())
                          << std::endl;
            }
#endif

        }
    }

    // safe front gap
    if ((blocked & blockedByLeader) == 0 && neighLead.first != 0) {
        // !!! eigentlich: vsafe braucht die Max. Geschwindigkeit beider Spuren
        if (neighLead.second < vehicle->getCarFollowModel().getSecureGap(vehicle->getSpeed(), neighLead.first->getSpeed(), neighLead.first->getCarFollowModel().getMaxDecel())) {
            blocked |= blockedByLeader;

            // Debug (Leo)
#ifdef DEBUG_CHECK_CHANGE
            if (DEBUG_COND) {
                std::cout << SIMTIME
                          << " front gap unsafe: "
                          << "gap = " << neighLead.second
                          << ", secureGap = "
                          << vehicle->getCarFollowModel().getSecureGap(vehicle->getSpeed(),
                                  neighLead.first->getSpeed(), neighLead.first->getCarFollowModel().getMaxDecel())
                          << std::endl;
            }
#endif

        }
    }


    MSAbstractLaneChangeModel::MSLCMessager msg(leader.first, neighLead.first, neighFollow.first);
    int state = blocked | vehicle->getLaneChangeModel().wantsChange(
                    laneOffset, msg, blocked, leader, neighLead, neighFollow, *targetLane, preb, &(myCandi->lastBlocked), &(myCandi->firstBlocked));

    if (blocked == 0 && (state & LCA_WANTS_LANECHANGE) != 0 && neighLead.first != 0) {
        // do are more carefull (but expensive) check to ensure that a
        // safety-critical leader is not being overloocked
        const SUMOReal seen = myCandi->lane->getLength() - vehicle->getPositionOnLane();
        const SUMOReal speed = vehicle->getSpeed();
        const SUMOReal dist = vehicle->getCarFollowModel().brakeGap(speed) + vehicle->getVehicleType().getMinGap();
        if (seen < dist) {
            std::pair<MSVehicle* const, SUMOReal> neighLead2 = targetLane->getCriticalLeader(dist, seen, speed, *vehicle);
            if (neighLead2.first != 0 && neighLead2.first != neighLead.first
                    && (neighLead2.second < vehicle->getCarFollowModel().getSecureGap(
                            vehicle->getSpeed(), neighLead2.first->getSpeed(), neighLead2.first->getCarFollowModel().getMaxDecel()))) {
                state |= blockedByLeader;
            }
        }
    }
    if (blocked == 0 && (state & LCA_WANTS_LANECHANGE)) {
        // ensure that merging is safe for any upcoming zipper links after changing
        if (vehicle->unsafeLinkAhead(targetLane)) {
            state |= blockedByLeader;
        }
    }

    if ((state & LCA_BLOCKED) == 0 && (state & LCA_WANTS_LANECHANGE) != 0 && MSGlobals::gLaneChangeDuration > DELTA_T) {
        // ensure that a continuous lane change manoeuvre can be completed
        // before the next turning movement
        SUMOReal seen = myCandi->lane->getLength() - vehicle->getPositionOnLane();
        const SUMOReal decel = vehicle->getCarFollowModel().getMaxDecel() * STEPS2TIME(MSGlobals::gLaneChangeDuration);
        const SUMOReal avgSpeed = 0.5 * (
                                      MAX2((SUMOReal)0, vehicle->getSpeed() - ACCEL2SPEED(vehicle->getCarFollowModel().getMaxDecel())) +
                                      MAX2((SUMOReal)0, vehicle->getSpeed() - decel));
        const SUMOReal space2change = avgSpeed * STEPS2TIME(MSGlobals::gLaneChangeDuration);
        // for finding turns it doesn't matter whether we look along the current lane or the target lane
        const std::vector<MSLane*>& bestLaneConts = vehicle->getBestLanesContinuation();
        int view = 1;
        MSLane* nextLane = vehicle->getLane();
        MSLinkCont::const_iterator link = MSLane::succLinkSec(*vehicle, view, *nextLane, bestLaneConts);
        while (!nextLane->isLinkEnd(link) && seen <= space2change) {
            if ((*link)->getDirection() == LINKDIR_LEFT || (*link)->getDirection() == LINKDIR_RIGHT
                    // the lanes after an internal junction are on different
                    // edges and do not allow lane-changing
                    || (nextLane->getEdge().isInternal() && (*link)->getViaLaneOrLane()->getEdge().isInternal())
               ) {
                state |= LCA_INSUFFICIENT_SPACE;
                break;
            }
#ifdef HAVE_INTERNAL_LANES
            if ((*link)->getViaLane() == 0) {
                view++;
            }
#else
            view++;
#endif
            nextLane = (*link)->getViaLaneOrLane();
            seen += nextLane->getLength();
            // get the next link used
            link = MSLane::succLinkSec(*vehicle, view, *nextLane, bestLaneConts);
        }
        if (nextLane->isLinkEnd(link) && seen < space2change) {
#ifdef DEBUG_CHECK_CHANGE
            if (DEBUG_COND) {
                std::cout << SIMTIME << " checkChange insufficientSpace: seen=" << seen << " space2change=" << space2change << "\n";
            }
#endif
            state |= LCA_INSUFFICIENT_SPACE;
        }

        if ((state & LCA_BLOCKED) == 0) {
            // check for dangerous leaders in case the target lane changes laterally between
            // now and the lane-changing midpoint
            const SUMOReal speed = vehicle->getSpeed();
            seen = myCandi->lane->getLength() - vehicle->getPositionOnLane();
            nextLane = vehicle->getLane();
            view = 1;
            const SUMOReal dist = vehicle->getCarFollowModel().brakeGap(speed) + vehicle->getVehicleType().getMinGap();
            MSLinkCont::const_iterator link = MSLane::succLinkSec(*vehicle, view, *nextLane, bestLaneConts);
            while (!nextLane->isLinkEnd(link) && seen <= space2change && seen <= dist) {
                nextLane = (*link)->getViaLaneOrLane();
                MSLane* targetLane = nextLane->getParallelLane(laneOffset);
                if (targetLane == 0) {
                    state |= LCA_INSUFFICIENT_SPACE;
                    break;
                } else {
                    std::pair<MSVehicle* const, SUMOReal> neighLead2 = targetLane->getLeader(vehicle, -seen, std::vector<MSLane*>());
                    if (neighLead2.first != 0 && neighLead2.first != neighLead.first
                            && (neighLead2.second < vehicle->getCarFollowModel().getSecureGap(
                                    vehicle->getSpeed(), neighLead2.first->getSpeed(), neighLead2.first->getCarFollowModel().getMaxDecel()))) {
                        state |= blockedByLeader;
                        break;
                    }
                }
#ifdef HAVE_INTERNAL_LANES
                if ((*link)->getViaLane() == 0) {
                    view++;
                }
#else
                view++;
#endif
                seen += nextLane->getLength();
                // get the next link used
                link = MSLane::succLinkSec(*vehicle, view, *nextLane, bestLaneConts);
            }
        }
    }
#ifndef NO_TRACI
#ifdef DEBUG_CHECK_CHANGE
    const int oldstate = state;
#endif
    // let TraCI influence the wish to change lanes and the security to take
    state = vehicle->influenceChangeDecision(state);
#endif
#ifdef DEBUG_CHECK_CHANGE
    if (DEBUG_COND) {
        std::cout << SIMTIME
                  << " veh=" << vehicle->getID()
                  << " oldState=" << toString((LaneChangeAction)oldstate)
                  << " newState=" << toString((LaneChangeAction)state)
                  << ((blocked & LCA_BLOCKED) ? " (blocked)" : "")
                  << ((blocked & LCA_OVERLAPPING) ? " (overlap)" : "")
                  << "\n";
    }
#endif
    return state;
}
示例#10
0
bool
MSLaneChanger::changeOpposite(std::pair<MSVehicle*, SUMOReal> leader) {
    if (!myChangeToOpposite) {
        return false;
    }
    myCandi = findCandidate();
    MSVehicle* vehicle = veh(myCandi);
    MSLane* source = vehicle->getLane();
    if (vehicle->isStopped()) {
        // stopped vehicles obviously should not change lanes. Usually this is
        // prevent by appropriate bestLane distances
        return false;
    }
    const bool isOpposite = vehicle->getLaneChangeModel().isOpposite();
    if (!isOpposite && leader.first == 0) {
        // no reason to change unless there is a leader
        // or we are changing back to the propper direction
        // XXX also check whether the leader is so far away as to be irrelevant
        return false;
    }
    if (!source->getEdge().canChangeToOpposite()) {
        return false;
    }
    MSLane* opposite = source->getOpposite();
    if (opposite == 0) {
        return false;
    }

    // changing into the opposite direction is always to the left (XXX except for left-hand networkds)
    int direction = vehicle->getLaneChangeModel().isOpposite() ? -1 : 1;
    std::pair<MSVehicle*, SUMOReal> neighLead((MSVehicle*)0, -1);

    // preliminary sanity checks for overtaking space
    if (!isOpposite) {
        assert(leader.first != 0);
        // find a leader vehicle with sufficient space ahead for merging back
        const SUMOReal overtakingSpeed = source->getVehicleMaxSpeed(vehicle); // just a guess
        const SUMOReal mergeBrakeGap = vehicle->getCarFollowModel().brakeGap(overtakingSpeed);
        const SUMOReal maxLookAhead = 150; // just a guess
        std::pair<MSVehicle*, SUMOReal> columnLeader = leader;
        SUMOReal egoGap = leader.second;
        bool foundSpaceAhead = false;
        SUMOReal seen = leader.second + leader.first->getVehicleType().getLengthWithGap();
        std::vector<MSLane*> conts = vehicle->getBestLanesContinuation();
        while (!foundSpaceAhead) {
            const SUMOReal requiredSpaceAfterLeader = (columnLeader.first->getCarFollowModel().getSecureGap(
                        columnLeader.first->getSpeed(), overtakingSpeed, vehicle->getCarFollowModel().getMaxDecel())
                    + vehicle->getVehicleType().getLengthWithGap());


            std::pair<MSVehicle* const, SUMOReal> leadLead = columnLeader.first->getLane()->getLeader(
                        columnLeader.first, columnLeader.first->getPositionOnLane(), conts, requiredSpaceAfterLeader + mergeBrakeGap, true);

#ifdef DEBUG_CHANGE_OPPOSITE
            if (DEBUG_COND) {
            	std::cout << "   leadLead=" << Named::getIDSecure(leadLead.first) << " gap=" << leadLead.second << "\n";
            }
#endif
            if (leadLead.first == 0) {
                foundSpaceAhead = true;
            } else {
                const SUMOReal requiredSpace = (requiredSpaceAfterLeader
                                                + vehicle->getCarFollowModel().getSecureGap(overtakingSpeed, leadLead.first->getSpeed(), leadLead.first->getCarFollowModel().getMaxDecel()));
                if (leadLead.second > requiredSpace) {
                    foundSpaceAhead = true;
                } else {
#ifdef DEBUG_CHANGE_OPPOSITE
                	if (DEBUG_COND) {
                		std::cout << "   not enough space after columnLeader=" << leadLead.first->getID() << " gap=" << leadLead.second << " required=" << requiredSpace << "\n";
                	}
#endif
                    seen += leadLead.second + leadLead.first->getVehicleType().getLengthWithGap();
                    if (seen > maxLookAhead) {
#ifdef DEBUG_CHANGE_OPPOSITE
                    	if (DEBUG_COND) {
                    		std::cout << "   cannot changeOpposite due to insufficient free space after columnLeader (seen=" << seen << " columnLeader=" << leadLead.first->getID() << ")\n";
                    	}
#endif
                        return false;
                    }
                    // see if merging after leadLead is possible
                    egoGap += columnLeader.first->getVehicleType().getLengthWithGap() + leadLead.second;
                    columnLeader = leadLead;
#ifdef DEBUG_CHANGE_OPPOSITE
    if (DEBUG_COND) {
                        std::cout << "   new columnLeader=" << columnLeader.first->getID() << "\n";
                    }
#endif
                }
            }
        }
#ifdef DEBUG_CHANGE_OPPOSITE
    if (DEBUG_COND) {
            std::cout << "   compute time/space to overtake for columnLeader=" << columnLeader.first->getID() << " gap=" << columnLeader.second << "\n";
        }
#endif
        SUMOReal timeToOvertake;
        SUMOReal spaceToOvertake;
        computeOvertakingTime(vehicle, columnLeader.first, egoGap, timeToOvertake, spaceToOvertake);
        // check for upcoming stops
        if (vehicle->nextStopDist() < spaceToOvertake) {
#ifdef DEBUG_CHANGE_OPPOSITE
    if (DEBUG_COND) {
                std::cout << "   cannot changeOpposite due to upcoming stop (dist=" << vehicle->nextStopDist() << " spaceToOvertake=" << spaceToOvertake << ")\n";
            }
#endif
            return false;
        }
        neighLead = opposite->getOppositeLeader(vehicle, timeToOvertake * opposite->getSpeedLimit() * 2 + spaceToOvertake);

#ifdef DEBUG_CHANGE_OPPOSITE
    if (DEBUG_COND) {
            std::cout << SIMTIME
                      << " veh=" << vehicle->getID()
                      << " changeOpposite opposite=" << opposite->getID()
                      << " lead=" << Named::getIDSecure(leader.first)
                      << " oncoming=" << Named::getIDSecure(neighLead.first)
                      << " timeToOvertake=" << timeToOvertake
                      << " spaceToOvertake=" << spaceToOvertake
                      << "\n";
        }
#endif

        // check for dangerous oncoming leader
        if (!vehicle->getLaneChangeModel().isOpposite() && neighLead.first != 0) {
            const MSVehicle* oncoming = neighLead.first;
            /// XXX what about overtaking multiple vehicles?

#ifdef DEBUG_CHANGE_OPPOSITE
            if (DEBUG_COND) {
            	std::cout << SIMTIME
            			<< " timeToOvertake=" << timeToOvertake
            			<< " spaceToOvertake=" << spaceToOvertake
            			<< " oncomingGap=" << neighLead.second
            			<< " leaderGap=" << leader.second
            			<< "\n";
            }
#endif
            if (neighLead.second - spaceToOvertake - timeToOvertake * oncoming->getSpeed() < 0) {

#ifdef DEBUG_CHANGE_OPPOSITE
            	if (DEBUG_COND) {
            		std::cout << "   cannot changeOpposite due to dangerous oncoming\n";
            	}
#endif
                return false;
            }
        }
        // check for sufficient space on the opposite side
        seen = source->getLength() - vehicle->getPositionOnLane();
        if (!vehicle->getLaneChangeModel().isOpposite() && seen < spaceToOvertake) {
            const std::vector<MSLane*>& bestLaneConts = vehicle->getBestLanesContinuation();
            assert(bestLaneConts.size() >= 1);
            std::vector<MSLane*>::const_iterator it = bestLaneConts.begin() + 1;
            while (seen < spaceToOvertake && it != bestLaneConts.end()) {
                if ((*it)->getOpposite() == 0) {
                    break;
                }
                // do not overtake past a minor link
                if (*(it - 1) != 0) {
                    MSLink* link = MSLinkContHelper::getConnectingLink(**(it - 1), **it);
                    if (link == 0 || !link->havePriority() || link->getState() == LINKSTATE_ZIPPER) {
                        break;
                    }
                }
                seen += (*it)->getLength();
            }
            if (seen < spaceToOvertake) {
#ifdef DEBUG_CHANGE_OPPOSITE
            	if (DEBUG_COND) {
            		std::cout << "   cannot changeOpposite due to insufficient space (seen=" << seen << " spaceToOvertake=" << spaceToOvertake << ")\n";
            	}
#endif
                return false;
            }
#ifdef DEBUG_CHANGE_OPPOSITE
            if (DEBUG_COND) {
            	std::cout << "   seen=" << seen << " spaceToOvertake=" << spaceToOvertake << " timeToOvertake=" << timeToOvertake << "\n";
            }
#endif
        }
    } else {
        /// XXX compute sensible distance
        leader = source->getOppositeLeader(vehicle, 200);
        neighLead = opposite->getOppositeLeader(vehicle, -1);
    }

    // compute wish to change
    std::vector<MSVehicle::LaneQ> preb = vehicle->getBestLanes();
    if (isOpposite && leader.first != 0) {
        MSVehicle::LaneQ& laneQ = preb[preb.size() - 1];
        /// XXX compute sensible usable dist
        laneQ.length -= MIN2(laneQ.length, opposite->getOppositePos(vehicle->getPositionOnLane()) + leader.second / 2);
        leader.first = 0; // ignore leader
    }
    std::pair<MSVehicle* const, SUMOReal> neighFollow = opposite->getOppositeFollower(vehicle);
    int state = checkChange(direction, opposite, leader, neighLead, neighFollow, preb);

    bool changingAllowed = (state & LCA_BLOCKED) == 0;
    // change if the vehicle wants to and is allowed to change
    if ((state & LCA_WANTS_LANECHANGE) != 0 && changingAllowed) {
        vehicle->getLaneChangeModel().startLaneChangeManeuver(source, opposite, direction);
        /// XXX use a dedicated transformation function
        vehicle->myState.myPos = source->getOppositePos(vehicle->myState.myPos);
        vehicle->myState.myBackPos = source->getOppositePos(vehicle->myState.myBackPos);
        /// XXX compute a bette lateral position
        opposite->forceVehicleInsertion(vehicle, vehicle->getPositionOnLane(), MSMoveReminder::NOTIFICATION_LANE_CHANGE, 0);
#ifdef DEBUG_CHANGE_OPPOSITE
        if (DEBUG_COND) {
        	std::cout << SIMTIME << " changing to opposite veh=" << vehicle->getID() << " dir=" << direction << " opposite=" << Named::getIDSecure(opposite) << " state=" << state << "\n";
        }
#endif
        return true;
    }
#ifdef DEBUG_CHANGE_OPPOSITE
    if (DEBUG_COND) {
    	std::cout << SIMTIME << " not changing to opposite veh=" << vehicle->getID() << " dir=" << direction << " opposite=" << Named::getIDSecure(opposite) << " state=" << state << "\n";
    }
#endif
    return false;
}