enhanced geofencing
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601b1d91e6
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@ -2,27 +2,27 @@ GOTO_MAXVEL = 1.5 # m/steps
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GOTO_MAXDIST = 150 # m.
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GOTO_MAXDIST = 150 # m.
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GOTODIST_TOL = 0.4 # m.
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GOTODIST_TOL = 0.4 # m.
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GOTOANG_TOL = 0.1 # rad.
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GOTOANG_TOL = 0.1 # rad.
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GPSlimit = {.1={.lat=45.510386, .lng=-73.610400},
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GPSlimit = {.1={.lat=45.510400, .lng=-73.610421},
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.2={.lat=45.509839, .lng=-73.610047},
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.2={.lat=45.510896, .lng=-73.608731},
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.3={.lat=45.510859, .lng=-73.608714},
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.3={.lat=45.510355, .lng=-73.608404},
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.4={.lat=45.510327, .lng=-73.608393}}
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.4={.lat=45.509840, .lng=-73.610072}}
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# Core naviguation function to travel to a GPS target location.
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# Core naviguation function to travel to a GPS target location.
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function goto_gps(transf) {
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function goto_gps(transf) {
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if(Geofence()) {
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m_navigation = vec_from_gps(cur_goal.latitude, cur_goal.longitude, 0)
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m_navigation = vec_from_gps(cur_goal.latitude, cur_goal.longitude, 0)
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#print(" has to move ", math.vec2.length(m_navigation), math.vec2.angle(m_navigation))
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#print(" has to move ", math.vec2.length(m_navigation), math.vec2.angle(m_navigation))
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if(math.vec2.length(m_navigation)>GOTO_MAXDIST)
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if(math.vec2.length(m_navigation)>GOTO_MAXDIST)
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log("Sorry this is too far (", math.vec2.length(m_navigation), " / ", GOTO_MAXDIST, " )")
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log("Sorry this is too far (", math.vec2.length(m_navigation), " / ", GOTO_MAXDIST, " )")
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else if(math.vec2.length(m_navigation) < GOTODIST_TOL and math.vec2.angle(m_navigation) < GOTOANG_TOL){ # reached destination
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else if(math.vec2.length(m_navigation) < GOTODIST_TOL and math.vec2.angle(m_navigation) < GOTOANG_TOL){ # reached destination
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transf()
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transf()
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} else {
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} else {
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m_navigation = LimitSpeed(m_navigation, 1.0)
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m_navigation = LimitSpeed(m_navigation, 1.0)
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table_print(m_navigation)
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#m_navigation = LCA(m_navigation)
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gf = {.0=m_navigation, .1=vec_from_gps(GPSlimit[1].lat, GPSlimit[1].lng, 0), .2=vec_from_gps(GPSlimit[2].lat, GPSlimit[2].lng, 0), .3=vec_from_gps(GPSlimit[3].lat, GPSlimit[3].lng, 0), .4=vec_from_gps(GPSlimit[4].lat, GPSlimit[4].lng, 0)}
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goto_abs(m_navigation.x, m_navigation.y, cur_goal.altitude - pose.position.altitude, 0.0)
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geofence(gf)
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}
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#m_navigation = LCA(m_navigation)
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} else
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goto_abs(m_navigation.x, m_navigation.y, cur_goal.altitude - pose.position.altitude, 0.0)
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log("Geofencing prevents from going to that location!")
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}
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}
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}
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function LimitSpeed(vel_vec, factor){
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function LimitSpeed(vel_vec, factor){
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@ -30,16 +30,3 @@ function LimitSpeed(vel_vec, factor){
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vel_vec = math.vec2.scale(vel_vec, GOTO_MAXVEL*factor/math.vec2.length(vel_vec))
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vel_vec = math.vec2.scale(vel_vec, GOTO_MAXVEL*factor/math.vec2.length(vel_vec))
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return vel_vec
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return vel_vec
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}
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}
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function Geofence(){ #TODO: rotate the fence box to really fit the coordinates
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if(cur_goal.latitude > GPSlimit[1].lat and cur_goal.latitude > GPSlimit[2].lat and cur_goal.latitude > GPSlimit[3].lat and cur_goal.latitude > GPSlimit[4].lat)
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return 0;
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if(cur_goal.latitude < GPSlimit[1].lat and cur_goal.latitude < GPSlimit[2].lat and cur_goal.latitude < GPSlimit[3].lat and cur_goal.latitude < GPSlimit[4].lat)
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return 0;
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if(cur_goal.longitude > GPSlimit[1].lng and cur_goal.longitude > GPSlimit[2].lng and cur_goal.longitude > GPSlimit[3].lng and cur_goal.longitude > GPSlimit[4].lng)
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return 0;
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if(cur_goal.longitude < GPSlimit[1].lng and cur_goal.longitude < GPSlimit[2].lng and cur_goal.longitude < GPSlimit[3].lng and cur_goal.longitude < GPSlimit[4].lng)
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return 0;
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return 1
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}
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@ -12,7 +12,7 @@ include "utils/takeoff_heights.bzz"
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#State launched after takeoff
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#State launched after takeoff
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AUTO_LAUNCH_STATE = "IDLE"
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AUTO_LAUNCH_STATE = "DEPLOY"
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TARGET = 9.0
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TARGET = 9.0
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EPSILON = 30.0
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EPSILON = 30.0
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ROOT_ID = 3
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ROOT_ID = 3
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@ -44,7 +44,7 @@ function init() {
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nei_cmd_listen()
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nei_cmd_listen()
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# Starting state: TURNEDOFF to wait for user input.
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# Starting state: TURNEDOFF to wait for user input.
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BVMSTATE = "TURNEDOFF"
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BVMSTATE = "LAUNCH"
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}
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}
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# Executed at each time step.
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# Executed at each time step.
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@ -154,6 +154,7 @@ int buzzuav_land(buzzvm_t vm);
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* Command the UAV to go to home location
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* Command the UAV to go to home location
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*/
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*/
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int buzzuav_gohome(buzzvm_t vm);
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int buzzuav_gohome(buzzvm_t vm);
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int buzzuav_geofence(buzzvm_t vm);
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/*
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/*
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* Updates battery information in Buzz
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* Updates battery information in Buzz
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@ -243,6 +243,9 @@ static int buzz_register_hooks()
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buzzvm_pushs(VM, buzzvm_string_register(VM, "voronoi", 1));
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buzzvm_pushs(VM, buzzvm_string_register(VM, "voronoi", 1));
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buzzvm_pushcc(VM, buzzvm_function_register(VM, buzzuav_closures::voronoi_center));
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buzzvm_pushcc(VM, buzzvm_function_register(VM, buzzuav_closures::voronoi_center));
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buzzvm_gstore(VM);
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buzzvm_gstore(VM);
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buzzvm_pushs(VM, buzzvm_string_register(VM, "geofence", 1));
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buzzvm_pushcc(VM, buzzvm_function_register(VM, buzzuav_closures::buzzuav_geofence));
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buzzvm_gstore(VM);
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return VM->state;
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return VM->state;
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}
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}
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@ -376,6 +376,152 @@ int voronoi_center(buzzvm_t vm) {
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return buzzvm_ret0(vm);
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return buzzvm_ret0(vm);
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}
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}
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/*
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* Geofence(): test for a point in a polygon
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* TAKEN from https://www.geeksforgeeks.org/how-to-check-if-a-given-point-lies-inside-a-polygon/
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*/
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struct Point
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{
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int x;
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int y;
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};
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// Given three colinear points p, q, r, the function checks if
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// point q lies on line segment 'pr'
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bool onSegment(Point p, Point q, Point r)
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{
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if (q.x <= max(p.x, r.x) && q.x >= min(p.x, r.x) &&
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q.y <= max(p.y, r.y) && q.y >= min(p.y, r.y))
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return true;
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return false;
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}
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// To find orientation of ordered triplet (p, q, r).
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// The function returns following values
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// 0 --> p, q and r are colinear
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// 1 --> Clockwise
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// 2 --> Counterclockwise
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int orientation(Point p, Point q, Point r)
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{
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int val = (q.y - p.y) * (r.x - q.x) -
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(q.x - p.x) * (r.y - q.y);
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if (val == 0) return 0; // colinear
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return (val > 0)? 1: 2; // clock or counterclock wise
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}
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// The function that returns true if line segment 'p1q1'
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// and 'p2q2' intersect.
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bool doIntersect(Point p1, Point q1, Point p2, Point q2)
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{
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// Find the four orientations needed for general and
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// special cases
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int o1 = orientation(p1, q1, p2);
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int o2 = orientation(p1, q1, q2);
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int o3 = orientation(p2, q2, p1);
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int o4 = orientation(p2, q2, q1);
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// General case
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if (o1 != o2 && o3 != o4)
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return true;
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// Special Cases
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// p1, q1 and p2 are colinear and p2 lies on segment p1q1
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if (o1 == 0 && onSegment(p1, p2, q1)) return true;
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// p1, q1 and p2 are colinear and q2 lies on segment p1q1
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if (o2 == 0 && onSegment(p1, q2, q1)) return true;
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// p2, q2 and p1 are colinear and p1 lies on segment p2q2
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if (o3 == 0 && onSegment(p2, p1, q2)) return true;
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// p2, q2 and q1 are colinear and q1 lies on segment p2q2
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if (o4 == 0 && onSegment(p2, q1, q2)) return true;
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return false; // Doesn't fall in any of the above cases
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}
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int buzzuav_geofence(buzzvm_t vm)
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{
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bool onedge = false;
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Point P;
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Point V[4];
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int tmp;
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buzzvm_lnum_assert(vm, 1);
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// Get the parameter
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buzzvm_lload(vm, 1);
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buzzvm_type_assert(vm, 1, BUZZTYPE_TABLE); // dictionary
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buzzobj_t t = buzzvm_stack_at(vm, 1);
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if(buzzdict_size(t->t.value) != 5) {
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ROS_ERROR("Wrong Geofence input size (%i).", buzzdict_size(t->t.value));
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return buzzvm_ret0(vm);
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}
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for(int32_t i = 0; i < buzzdict_size(t->t.value); ++i) {
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buzzvm_dup(vm);
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buzzvm_pushi(vm, i);
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buzzvm_tget(vm);
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buzzvm_dup(vm);
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buzzvm_pushs(vm, buzzvm_string_register(vm, "x", 1));
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buzzvm_tget(vm);
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tmp = round(buzzvm_stack_at(vm, 1)->f.value*10);
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ROS_INFO("[%i]---x-->%i",buzz_utility::get_robotid(), tmp);
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if(i==0)
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P.x = tmp;
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else
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V[i-1].x = tmp;
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buzzvm_pop(vm);
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buzzvm_dup(vm);
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buzzvm_pushs(vm, buzzvm_string_register(vm, "y", 1));
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buzzvm_tget(vm);
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tmp = round(buzzvm_stack_at(vm, 1)->f.value*10);
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ROS_INFO("[%i]---x-->%i",buzz_utility::get_robotid(), tmp);
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if(i==0)
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P.y = tmp;
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else
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V[i-1].y = tmp;
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buzzvm_pop(vm);
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buzzvm_pop(vm);
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}
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// simple polygon: rectangle, 4 points
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int n = 4;
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// Create a point for line segment from p to infinite
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Point extreme = {10000, P.y};
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// Count intersections of the above line with sides of polygon
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int count = 0, i = 0;
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do
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{
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int next = (i+1)%n;
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// Check if the line segment from 'p' to 'extreme' intersects
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// with the line segment from 'polygon[i]' to 'polygon[next]'
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if (doIntersect(V[i], V[next], P, extreme))
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{
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// If the point 'p' is colinear with line segment 'i-next',
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// then check if it lies on segment. If it lies, return true,
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// otherwise false
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if (orientation(V[i], P, V[next]) == 0) {
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onedge = onSegment(V[i], P, V[next]);
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if(onedge)
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break;
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}
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count++;
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}
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i = next;
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} while (i != 0);
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ROS_INFO("[%i] Geofence: %i, %i",buzz_utility::get_robotid(),count, onedge);
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if((count%2 == 0) || onedge) {
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goto_gpsgoal[0] = cur_pos[0];
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goto_gpsgoal[1] = cur_pos[1];
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ROS_WARN("Geofencing trigered, not going any further!");
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}
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return buzzvm_ret0(vm);
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}
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int buzzuav_moveto(buzzvm_t vm)
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int buzzuav_moveto(buzzvm_t vm)
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/*
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/*
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/ Buzz closure to move following a 3D vector + Yaw
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/ Buzz closure to move following a 3D vector + Yaw
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@ -457,8 +603,8 @@ int buzzuav_addNeiStatus(buzzvm_t vm)
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buzzvm_type_assert(vm, 1, BUZZTYPE_TABLE);
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buzzvm_type_assert(vm, 1, BUZZTYPE_TABLE);
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buzzobj_t t = buzzvm_stack_at(vm, 1);
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buzzobj_t t = buzzvm_stack_at(vm, 1);
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if(buzzdict_size(t->t.value) != 5) {
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if(buzzdict_size(t->t.value) != 5) {
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ROS_WARN("Wrong neighbor status size.");
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ROS_ERROR("Wrong neighbor status size.");
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return vm->state;
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return buzzvm_ret0(vm);
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}
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}
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buzz_utility::neighbors_status newRS;
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buzz_utility::neighbors_status newRS;
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