--- **Core** - Define zones within your mission of various forms, with various capabilities. -- -- === -- -- ## Features: -- -- * Create radius zones. -- * Create trigger zones. -- * Create polygon zones. -- * Create moving zones around a unit. -- * Create moving zones around a group. -- * Provide the zone behaviour. Some zones are static, while others are moveable. -- * Enquiry if a coordinate is within a zone. -- * Smoke zones. -- * Set a zone probability to control zone selection. -- * Get zone coordinates. -- * Get zone properties. -- * Get zone bounding box. -- * Set/get zone name. -- * Draw zones (circular and polygon) on the F10 map. -- -- -- There are essentially two core functions that zones accomodate: -- -- * Test if an object is within the zone boundaries. -- * Provide the zone behaviour. Some zones are static, while others are moveable. -- -- The object classes are using the zone classes to test the zone boundaries, which can take various forms: -- -- * Test if completely within the zone. -- * Test if partly within the zone (for @{Wrapper.Group#GROUP} objects). -- * Test if not in the zone. -- * Distance to the nearest intersecting point of the zone. -- * Distance to the center of the zone. -- * ... -- -- Each of these ZONE classes have a zone name, and specific parameters defining the zone type: -- -- * @{#ZONE_BASE}: The ZONE_BASE class defining the base for all other zone classes. -- * @{#ZONE_RADIUS}: The ZONE_RADIUS class defined by a zone name, a location and a radius. -- * @{#ZONE}: The ZONE class, defined by the zone name as defined within the Mission Editor. -- * @{#ZONE_UNIT}: The ZONE_UNIT class defines by a zone around a @{Wrapper.Unit#UNIT} with a radius. -- * @{#ZONE_GROUP}: The ZONE_GROUP class defines by a zone around a @{Wrapper.Group#GROUP} with a radius. -- * @{#ZONE_POLYGON}: The ZONE_POLYGON class defines by a sequence of @{Wrapper.Group#GROUP} waypoints within the Mission Editor, forming a polygon. -- -- === -- -- ### Author: **FlightControl** -- ### Contributions: -- -- === -- -- @module Core.Zone -- @image Core_Zones.JPG --- @type ZONE_BASE -- @field #string ZoneName Name of the zone. -- @field #number ZoneProbability A value between 0 and 1. 0 = 0% and 1 = 100% probability. -- @field #number DrawID Unique ID of the drawn zone on the F10 map. -- @field #table Color Table with four entries, e.g. {1, 0, 0, 0.15}. First three are RGB color code. Fourth is the transparency Alpha value. -- @extends Core.Fsm#FSM --- This class is an abstract BASE class for derived classes, and is not meant to be instantiated. -- -- ## Each zone has a name: -- -- * @{#ZONE_BASE.GetName}(): Returns the name of the zone. -- * @{#ZONE_BASE.SetName}(): Sets the name of the zone. -- -- -- ## Each zone implements two polymorphic functions defined in @{Core.Zone#ZONE_BASE}: -- -- * @{#ZONE_BASE.IsVec2InZone}(): Returns if a 2D vector is within the zone. -- * @{#ZONE_BASE.IsVec3InZone}(): Returns if a 3D vector is within the zone. -- * @{#ZONE_BASE.IsPointVec2InZone}(): Returns if a 2D point vector is within the zone. -- * @{#ZONE_BASE.IsPointVec3InZone}(): Returns if a 3D point vector is within the zone. -- -- ## A zone has a probability factor that can be set to randomize a selection between zones: -- -- * @{#ZONE_BASE.SetZoneProbability}(): Set the randomization probability of a zone to be selected, taking a value between 0 and 1 ( 0 = 0%, 1 = 100% ) -- * @{#ZONE_BASE.GetZoneProbability}(): Get the randomization probability of a zone to be selected, passing a value between 0 and 1 ( 0 = 0%, 1 = 100% ) -- * @{#ZONE_BASE.GetZoneMaybe}(): Get the zone taking into account the randomization probability. nil is returned if this zone is not a candidate. -- -- ## A zone manages vectors: -- -- * @{#ZONE_BASE.GetVec2}(): Returns the 2D vector coordinate of the zone. -- * @{#ZONE_BASE.GetVec3}(): Returns the 3D vector coordinate of the zone. -- * @{#ZONE_BASE.GetPointVec2}(): Returns the 2D point vector coordinate of the zone. -- * @{#ZONE_BASE.GetPointVec3}(): Returns the 3D point vector coordinate of the zone. -- * @{#ZONE_BASE.GetRandomVec2}(): Define a random 2D vector within the zone. -- * @{#ZONE_BASE.GetRandomPointVec2}(): Define a random 2D point vector within the zone. -- * @{#ZONE_BASE.GetRandomPointVec3}(): Define a random 3D point vector within the zone. -- -- ## A zone has a bounding square: -- -- * @{#ZONE_BASE.GetBoundingSquare}(): Get the outer most bounding square of the zone. -- -- ## A zone can be marked: -- -- * @{#ZONE_BASE.SmokeZone}(): Smokes the zone boundaries in a color. -- * @{#ZONE_BASE.FlareZone}(): Flares the zone boundaries in a color. -- -- @field #ZONE_BASE ZONE_BASE = { ClassName = "ZONE_BASE", ZoneName = "", ZoneProbability = 1, DrawID=nil, Color={} } --- The ZONE_BASE.BoundingSquare -- @type ZONE_BASE.BoundingSquare -- @field DCS#Distance x1 The lower x coordinate (left down) -- @field DCS#Distance y1 The lower y coordinate (left down) -- @field DCS#Distance x2 The higher x coordinate (right up) -- @field DCS#Distance y2 The higher y coordinate (right up) --- ZONE_BASE constructor -- @param #ZONE_BASE self -- @param #string ZoneName Name of the zone. -- @return #ZONE_BASE self function ZONE_BASE:New( ZoneName ) local self = BASE:Inherit( self, FSM:New() ) self:F( ZoneName ) self.ZoneName = ZoneName return self end --- Returns the name of the zone. -- @param #ZONE_BASE self -- @return #string The name of the zone. function ZONE_BASE:GetName() self:F2() return self.ZoneName end --- Sets the name of the zone. -- @param #ZONE_BASE self -- @param #string ZoneName The name of the zone. -- @return #ZONE_BASE function ZONE_BASE:SetName( ZoneName ) self:F2() self.ZoneName = ZoneName end --- Returns if a Vec2 is within the zone. -- @param #ZONE_BASE self -- @param DCS#Vec2 Vec2 The Vec2 to test. -- @return #boolean true if the Vec2 is within the zone. function ZONE_BASE:IsVec2InZone( Vec2 ) self:F2( Vec2 ) return false end --- Returns if a Vec3 is within the zone. -- @param #ZONE_BASE self -- @param DCS#Vec3 Vec3 The point to test. -- @return #boolean true if the Vec3 is within the zone. function ZONE_BASE:IsVec3InZone( Vec3 ) local InZone = self:IsVec2InZone( { x = Vec3.x, y = Vec3.z } ) return InZone end --- Returns if a Coordinate is within the zone. -- @param #ZONE_BASE self -- @param Core.Point#COORDINATE Coordinate The coordinate to test. -- @return #boolean true if the coordinate is within the zone. function ZONE_BASE:IsCoordinateInZone( Coordinate ) local InZone = self:IsVec2InZone( Coordinate:GetVec2() ) return InZone end --- Returns if a PointVec2 is within the zone. (Name is misleading, actually takes a #COORDINATE) -- @param #ZONE_BASE self -- @param Core.Point#COORDINATE PointVec2 The coordinate to test. -- @return #boolean true if the PointVec2 is within the zone. function ZONE_BASE:IsPointVec2InZone( Coordinate ) local InZone = self:IsVec2InZone( Coordinate:GetVec2() ) return InZone end --- Returns if a PointVec3 is within the zone. -- @param #ZONE_BASE self -- @param Core.Point#POINT_VEC3 PointVec3 The PointVec3 to test. -- @return #boolean true if the PointVec3 is within the zone. function ZONE_BASE:IsPointVec3InZone( PointVec3 ) local InZone = self:IsPointVec2InZone( PointVec3 ) return InZone end --- Returns the @{DCS#Vec2} coordinate of the zone. -- @param #ZONE_BASE self -- @return #nil. function ZONE_BASE:GetVec2() return nil end --- Returns a @{Core.Point#POINT_VEC2} of the zone. -- @param #ZONE_BASE self -- @param DCS#Distance Height The height to add to the land height where the center of the zone is located. -- @return Core.Point#POINT_VEC2 The PointVec2 of the zone. function ZONE_BASE:GetPointVec2() self:F2( self.ZoneName ) local Vec2 = self:GetVec2() local PointVec2 = POINT_VEC2:NewFromVec2( Vec2 ) self:T2( { PointVec2 } ) return PointVec2 end --- Returns the @{DCS#Vec3} of the zone. -- @param #ZONE_BASE self -- @param DCS#Distance Height The height to add to the land height where the center of the zone is located. -- @return DCS#Vec3 The Vec3 of the zone. function ZONE_BASE:GetVec3( Height ) self:F2( self.ZoneName ) Height = Height or 0 local Vec2 = self:GetVec2() local Vec3 = { x = Vec2.x, y = Height and Height or land.getHeight( self:GetVec2() ), z = Vec2.y } self:T2( { Vec3 } ) return Vec3 end --- Returns a @{Core.Point#POINT_VEC3} of the zone. -- @param #ZONE_BASE self -- @param DCS#Distance Height The height to add to the land height where the center of the zone is located. -- @return Core.Point#POINT_VEC3 The PointVec3 of the zone. function ZONE_BASE:GetPointVec3( Height ) self:F2( self.ZoneName ) local Vec3 = self:GetVec3( Height ) local PointVec3 = POINT_VEC3:NewFromVec3( Vec3 ) self:T2( { PointVec3 } ) return PointVec3 end --- Returns a @{Core.Point#COORDINATE} of the zone. -- @param #ZONE_BASE self -- @param DCS#Distance Height The height to add to the land height where the center of the zone is located. -- @return Core.Point#COORDINATE The Coordinate of the zone. function ZONE_BASE:GetCoordinate( Height ) --R2.1 self:F2(self.ZoneName) local Vec3 = self:GetVec3( Height ) if self.Coordinate then -- Update coordinates. self.Coordinate.x=Vec3.x self.Coordinate.y=Vec3.y self.Coordinate.z=Vec3.z --env.info("FF GetCoordinate NEW for ZONE_BASE "..tostring(self.ZoneName)) else -- Create a new coordinate object. self.Coordinate=COORDINATE:NewFromVec3(Vec3) --env.info("FF GetCoordinate NEW for ZONE_BASE "..tostring(self.ZoneName)) end return self.Coordinate end --- Get 2D distance to a coordinate. -- @param #ZONE_BASE self -- @param Core.Point#COORDINATE Coordinate Reference coordinate. Can also be a DCS#Vec2 or DCS#Vec3 object. -- @return #number Distance to the reference coordinate in meters. function ZONE_BASE:Get2DDistance(Coordinate) local a=self:GetVec2() local b={} if Coordinate.z then b.x=Coordinate.x b.y=Coordinate.z else b.x=Coordinate.x b.y=Coordinate.y end local dist=UTILS.VecDist2D(a,b) return dist end --- Define a random @{DCS#Vec2} within the zone. -- @param #ZONE_BASE self -- @return DCS#Vec2 The Vec2 coordinates. function ZONE_BASE:GetRandomVec2() return nil end --- Define a random @{Core.Point#POINT_VEC2} within the zone. -- @param #ZONE_BASE self -- @return Core.Point#POINT_VEC2 The PointVec2 coordinates. function ZONE_BASE:GetRandomPointVec2() return nil end --- Define a random @{Core.Point#POINT_VEC3} within the zone. -- @param #ZONE_BASE self -- @return Core.Point#POINT_VEC3 The PointVec3 coordinates. function ZONE_BASE:GetRandomPointVec3() return nil end --- Get the bounding square the zone. -- @param #ZONE_BASE self -- @return #nil The bounding square. function ZONE_BASE:GetBoundingSquare() --return { x1 = 0, y1 = 0, x2 = 0, y2 = 0 } return nil end --- Bound the zone boundaries with a tires. -- @param #ZONE_BASE self function ZONE_BASE:BoundZone() self:F2() end --- Set color of zone. -- @param #ZONE_BASE self -- @param #table RGBcolor RGB color table. Default `{1, 0, 0}`. -- @param #number Alpha Transparacy between 0 and 1. Default 0.15. -- @return #ZONE_BASE self function ZONE_BASE:SetColor(RGBcolor, Alpha) RGBcolor=RGBcolor or {1, 0, 0} Alpha=Alpha or 0.15 self.Color={} self.Color[1]=RGBcolor[1] self.Color[2]=RGBcolor[2] self.Color[3]=RGBcolor[3] self.Color[4]=Alpha return self end --- Get color table of the zone. -- @param #ZONE_BASE self -- @return #table Table with four entries, e.g. {1, 0, 0, 0.15}. First three are RGB color code. Fourth is the transparency Alpha value. function ZONE_BASE:GetColor() return self.Color end --- Get RGB color of zone. -- @param #ZONE_BASE self -- @return #table Table with three entries, e.g. {1, 0, 0}, which is the RGB color code. function ZONE_BASE:GetColorRGB() local rgb={} rgb[1]=self.Color[1] rgb[2]=self.Color[2] rgb[3]=self.Color[3] return rgb end --- Get transperency Alpha value of zone. -- @param #ZONE_BASE self -- @return #number Alpha value. function ZONE_BASE:GetColorAlpha() local alpha=self.Color[4] return alpha end --- Remove the drawing of the zone from the F10 map. -- @param #ZONE_BASE self -- @param #number Delay (Optional) Delay before the drawing is removed. -- @return #ZONE_BASE self function ZONE_BASE:UndrawZone(Delay) if Delay and Delay>0 then self:ScheduleOnce(Delay, ZONE_BASE.UndrawZone, self) else if self.DrawID then UTILS.RemoveMark(self.DrawID) end end return self end --- Get ID of the zone object drawn on the F10 map. -- The ID can be used to remove the drawn object from the F10 map view via `UTILS.RemoveMark(MarkID)`. -- @param #ZONE_BASE self -- @return #number Unique ID of the function ZONE_BASE:GetDrawID() return self.DrawID end --- Smokes the zone boundaries in a color. -- @param #ZONE_BASE self -- @param Utilities.Utils#SMOKECOLOR SmokeColor The smoke color. function ZONE_BASE:SmokeZone( SmokeColor ) self:F2( SmokeColor ) end --- Set the randomization probability of a zone to be selected. -- @param #ZONE_BASE self -- @param #number ZoneProbability A value between 0 and 1. 0 = 0% and 1 = 100% probability. -- @return #ZONE_BASE self function ZONE_BASE:SetZoneProbability( ZoneProbability ) self:F( { self:GetName(), ZoneProbability = ZoneProbability } ) self.ZoneProbability = ZoneProbability or 1 return self end --- Get the randomization probability of a zone to be selected. -- @param #ZONE_BASE self -- @return #number A value between 0 and 1. 0 = 0% and 1 = 100% probability. function ZONE_BASE:GetZoneProbability() self:F2() return self.ZoneProbability end --- Get the zone taking into account the randomization probability of a zone to be selected. -- @param #ZONE_BASE self -- @return #ZONE_BASE The zone is selected taking into account the randomization probability factor. -- @return #nil The zone is not selected taking into account the randomization probability factor. -- @usage -- -- local ZoneArray = { ZONE:New( "Zone1" ), ZONE:New( "Zone2" ) } -- -- -- We set a zone probability of 70% to the first zone and 30% to the second zone. -- ZoneArray[1]:SetZoneProbability( 0.5 ) -- ZoneArray[2]:SetZoneProbability( 0.5 ) -- -- local ZoneSelected = nil -- -- while ZoneSelected == nil do -- for _, Zone in pairs( ZoneArray ) do -- ZoneSelected = Zone:GetZoneMaybe() -- if ZoneSelected ~= nil then -- break -- end -- end -- end -- -- -- The result should be that Zone1 would be more probable selected than Zone2. -- function ZONE_BASE:GetZoneMaybe() self:F2() local Randomization = math.random() if Randomization <= self.ZoneProbability then return self else return nil end end --- The ZONE_RADIUS class, defined by a zone name, a location and a radius. -- @type ZONE_RADIUS -- @field DCS#Vec2 Vec2 The current location of the zone. -- @field DCS#Distance Radius The radius of the zone. -- @extends #ZONE_BASE --- The ZONE_RADIUS class defined by a zone name, a location and a radius. -- This class implements the inherited functions from Core.Zone#ZONE_BASE taking into account the own zone format and properties. -- -- ## ZONE_RADIUS constructor -- -- * @{#ZONE_RADIUS.New}(): Constructor. -- -- ## Manage the radius of the zone -- -- * @{#ZONE_RADIUS.SetRadius}(): Sets the radius of the zone. -- * @{#ZONE_RADIUS.GetRadius}(): Returns the radius of the zone. -- -- ## Manage the location of the zone -- -- * @{#ZONE_RADIUS.SetVec2}(): Sets the @{DCS#Vec2} of the zone. -- * @{#ZONE_RADIUS.GetVec2}(): Returns the @{DCS#Vec2} of the zone. -- * @{#ZONE_RADIUS.GetVec3}(): Returns the @{DCS#Vec3} of the zone, taking an additional height parameter. -- -- ## Zone point randomization -- -- Various functions exist to find random points within the zone. -- -- * @{#ZONE_RADIUS.GetRandomVec2}(): Gets a random 2D point in the zone. -- * @{#ZONE_RADIUS.GetRandomPointVec2}(): Gets a @{Core.Point#POINT_VEC2} object representing a random 2D point in the zone. -- * @{#ZONE_RADIUS.GetRandomPointVec3}(): Gets a @{Core.Point#POINT_VEC3} object representing a random 3D point in the zone. Note that the height of the point is at landheight. -- -- ## Draw zone -- -- * @{#ZONE_RADIUS.DrawZone}(): Draws the zone on the F10 map. -- -- @field #ZONE_RADIUS ZONE_RADIUS = { ClassName="ZONE_RADIUS", } --- Constructor of @{#ZONE_RADIUS}, taking the zone name, the zone location and a radius. -- @param #ZONE_RADIUS self -- @param #string ZoneName Name of the zone. -- @param DCS#Vec2 Vec2 The location of the zone. -- @param DCS#Distance Radius The radius of the zone. -- @return #ZONE_RADIUS self function ZONE_RADIUS:New( ZoneName, Vec2, Radius ) -- Inherit ZONE_BASE. local self = BASE:Inherit( self, ZONE_BASE:New( ZoneName ) ) -- #ZONE_RADIUS self:F( { ZoneName, Vec2, Radius } ) self.Radius = Radius self.Vec2 = Vec2 --self.Coordinate=COORDINATE:NewFromVec2(Vec2) return self end --- Update zone from a 2D vector. -- @param #ZONE_RADIUS self -- @param DCS#Vec2 Vec2 The location of the zone. -- @param DCS#Distance Radius The radius of the zone. -- @return #ZONE_RADIUS self function ZONE_RADIUS:UpdateFromVec2(Vec2, Radius) -- New center of the zone. self.Vec2=Vec2 if Radius then self.Radius=Radius end return self end --- Update zone from a 2D vector. -- @param #ZONE_RADIUS self -- @param DCS#Vec3 Vec3 The location of the zone. -- @param DCS#Distance Radius The radius of the zone. -- @return #ZONE_RADIUS self function ZONE_RADIUS:UpdateFromVec3(Vec3, Radius) -- New center of the zone. self.Vec2.x=Vec3.x self.Vec2.y=Vec3.z if Radius then self.Radius=Radius end return self end --- Mark the zone with markers on the F10 map. -- @param #ZONE_RADIUS self -- @param #number Points (Optional) The amount of points in the circle. Default 360. -- @return #ZONE_RADIUS self function ZONE_RADIUS:MarkZone(Points) local Point = {} local Vec2 = self:GetVec2() Points = Points and Points or 360 local Angle local RadialBase = math.pi*2 for Angle = 0, 360, (360 / Points ) do local Radial = Angle * RadialBase / 360 Point.x = Vec2.x + math.cos( Radial ) * self:GetRadius() Point.y = Vec2.y + math.sin( Radial ) * self:GetRadius() COORDINATE:NewFromVec2(Point):MarkToAll(self:GetName()) end end --- Draw the zone circle on the F10 map. -- @param #ZONE_RADIUS self -- @param #number Coalition Coalition: All=-1, Neutral=0, Red=1, Blue=2. Default -1=All. -- @param #table Color RGB color table {r, g, b}, e.g. {1,0,0} for red. -- @param #number Alpha Transparency [0,1]. Default 1. -- @param #table FillColor RGB color table {r, g, b}, e.g. {1,0,0} for red. Default is same as `Color` value. -- @param #number FillAlpha Transparency [0,1]. Default 0.15. -- @param #number LineType Line type: 0=No line, 1=Solid, 2=Dashed, 3=Dotted, 4=Dot dash, 5=Long dash, 6=Two dash. Default 1=Solid. -- @param #boolean ReadOnly (Optional) Mark is readonly and cannot be removed by users. Default false. -- @return #ZONE_RADIUS self function ZONE_RADIUS:DrawZone(Coalition, Color, Alpha, FillColor, FillAlpha, LineType, ReadOnly) local coordinate=self:GetCoordinate() local Radius=self:GetRadius() Color=Color or self:GetColorRGB() Alpha=Alpha or 1 FillColor=FillColor or Color FillAlpha=FillAlpha or self:GetColorAlpha() self.DrawID=coordinate:CircleToAll(Radius, Coalition, Color, Alpha, FillColor, FillAlpha, LineType, ReadOnly) return self end --- Bounds the zone with tires. -- @param #ZONE_RADIUS self -- @param #number Points (optional) The amount of points in the circle. Default 360. -- @param DCS#country.id CountryID The country id of the tire objects, e.g. country.id.USA for blue or country.id.RUSSIA for red. -- @param #boolean UnBound (Optional) If true the tyres will be destroyed. -- @return #ZONE_RADIUS self function ZONE_RADIUS:BoundZone( Points, CountryID, UnBound ) local Point = {} local Vec2 = self:GetVec2() Points = Points and Points or 360 local Angle local RadialBase = math.pi*2 -- for Angle = 0, 360, (360 / Points ) do local Radial = Angle * RadialBase / 360 Point.x = Vec2.x + math.cos( Radial ) * self:GetRadius() Point.y = Vec2.y + math.sin( Radial ) * self:GetRadius() local CountryName = _DATABASE.COUNTRY_NAME[CountryID] local Tire = { ["country"] = CountryName, ["category"] = "Fortifications", ["canCargo"] = false, ["shape_name"] = "H-tyre_B_WF", ["type"] = "Black_Tyre_WF", --["unitId"] = Angle + 10000, ["y"] = Point.y, ["x"] = Point.x, ["name"] = string.format( "%s-Tire #%0d", self:GetName(), Angle ), ["heading"] = 0, } -- end of ["group"] local Group = coalition.addStaticObject( CountryID, Tire ) if UnBound and UnBound == true then Group:destroy() end end return self end --- Smokes the zone boundaries in a color. -- @param #ZONE_RADIUS self -- @param Utilities.Utils#SMOKECOLOR SmokeColor The smoke color. -- @param #number Points (optional) The amount of points in the circle. -- @param #number AddHeight (optional) The height to be added for the smoke. -- @param #number AddOffSet (optional) The angle to be added for the smoking start position. -- @return #ZONE_RADIUS self function ZONE_RADIUS:SmokeZone( SmokeColor, Points, AddHeight, AngleOffset ) self:F2( SmokeColor ) local Point = {} local Vec2 = self:GetVec2() AddHeight = AddHeight or 0 AngleOffset = AngleOffset or 0 Points = Points and Points or 360 local Angle local RadialBase = math.pi*2 for Angle = 0, 360, 360 / Points do local Radial = ( Angle + AngleOffset ) * RadialBase / 360 Point.x = Vec2.x + math.cos( Radial ) * self:GetRadius() Point.y = Vec2.y + math.sin( Radial ) * self:GetRadius() POINT_VEC2:New( Point.x, Point.y, AddHeight ):Smoke( SmokeColor ) end return self end --- Flares the zone boundaries in a color. -- @param #ZONE_RADIUS self -- @param Utilities.Utils#FLARECOLOR FlareColor The flare color. -- @param #number Points (optional) The amount of points in the circle. -- @param DCS#Azimuth Azimuth (optional) Azimuth The azimuth of the flare. -- @param #number AddHeight (optional) The height to be added for the smoke. -- @return #ZONE_RADIUS self function ZONE_RADIUS:FlareZone( FlareColor, Points, Azimuth, AddHeight ) self:F2( { FlareColor, Azimuth } ) local Point = {} local Vec2 = self:GetVec2() AddHeight = AddHeight or 0 Points = Points and Points or 360 local Angle local RadialBase = math.pi*2 for Angle = 0, 360, 360 / Points do local Radial = Angle * RadialBase / 360 Point.x = Vec2.x + math.cos( Radial ) * self:GetRadius() Point.y = Vec2.y + math.sin( Radial ) * self:GetRadius() POINT_VEC2:New( Point.x, Point.y, AddHeight ):Flare( FlareColor, Azimuth ) end return self end --- Returns the radius of the zone. -- @param #ZONE_RADIUS self -- @return DCS#Distance The radius of the zone. function ZONE_RADIUS:GetRadius() self:F2( self.ZoneName ) self:T2( { self.Radius } ) return self.Radius end --- Sets the radius of the zone. -- @param #ZONE_RADIUS self -- @param DCS#Distance Radius The radius of the zone. -- @return DCS#Distance The radius of the zone. function ZONE_RADIUS:SetRadius( Radius ) self:F2( self.ZoneName ) self.Radius = Radius self:T2( { self.Radius } ) return self.Radius end --- Returns the @{DCS#Vec2} of the zone. -- @param #ZONE_RADIUS self -- @return DCS#Vec2 The location of the zone. function ZONE_RADIUS:GetVec2() self:F2( self.ZoneName ) self:T2( { self.Vec2 } ) return self.Vec2 end --- Sets the @{DCS#Vec2} of the zone. -- @param #ZONE_RADIUS self -- @param DCS#Vec2 Vec2 The new location of the zone. -- @return DCS#Vec2 The new location of the zone. function ZONE_RADIUS:SetVec2( Vec2 ) self:F2( self.ZoneName ) self.Vec2 = Vec2 self:T2( { self.Vec2 } ) return self.Vec2 end --- Returns the @{DCS#Vec3} of the ZONE_RADIUS. -- @param #ZONE_RADIUS self -- @param DCS#Distance Height The height to add to the land height where the center of the zone is located. -- @return DCS#Vec3 The point of the zone. function ZONE_RADIUS:GetVec3( Height ) self:F2( { self.ZoneName, Height } ) Height = Height or 0 local Vec2 = self:GetVec2() local Vec3 = { x = Vec2.x, y = land.getHeight( self:GetVec2() ) + Height, z = Vec2.y } self:T2( { Vec3 } ) return Vec3 end --- Scan the zone for the presence of units of the given ObjectCategories. -- Note that after a zone has been scanned, the zone can be evaluated by: -- -- * @{ZONE_RADIUS.IsAllInZoneOfCoalition}(): Scan the presence of units in the zone of a coalition. -- * @{ZONE_RADIUS.IsAllInZoneOfOtherCoalition}(): Scan the presence of units in the zone of an other coalition. -- * @{ZONE_RADIUS.IsSomeInZoneOfCoalition}(): Scan if there is some presence of units in the zone of the given coalition. -- * @{ZONE_RADIUS.IsNoneInZoneOfCoalition}(): Scan if there isn't any presence of units in the zone of an other coalition than the given one. -- * @{ZONE_RADIUS.IsNoneInZone}(): Scan if the zone is empty. -- @{#ZONE_RADIUS. -- @param #ZONE_RADIUS self -- @param ObjectCategories An array of categories of the objects to find in the zone. -- @param UnitCategories An array of unit categories of the objects to find in the zone. -- @usage -- self.Zone:Scan() -- local IsAttacked = self.Zone:IsSomeInZoneOfCoalition( self.Coalition ) function ZONE_RADIUS:Scan( ObjectCategories, UnitCategories ) self.ScanData = {} self.ScanData.Coalitions = {} self.ScanData.Scenery = {} self.ScanData.Units = {} local ZoneCoord = self:GetCoordinate() local ZoneRadius = self:GetRadius() self:F({ZoneCoord = ZoneCoord, ZoneRadius = ZoneRadius, ZoneCoordLL = ZoneCoord:ToStringLLDMS()}) local SphereSearch = { id = world.VolumeType.SPHERE, params = { point = ZoneCoord:GetVec3(), radius = ZoneRadius, } } local function EvaluateZone( ZoneObject ) --if ZoneObject:isExist() then --FF: isExist always returns false for SCENERY objects since DCS 2.2 and still in DCS 2.5 if ZoneObject then local ObjectCategory = ZoneObject:getCategory() --local name=ZoneObject:getName() --env.info(string.format("Zone object %s", tostring(name))) --self:E(ZoneObject) if ( ObjectCategory == Object.Category.UNIT and ZoneObject:isExist() and ZoneObject:isActive() ) or (ObjectCategory == Object.Category.STATIC and ZoneObject:isExist()) then local CoalitionDCSUnit = ZoneObject:getCoalition() local Include = false if not UnitCategories then -- Anythink found is included. Include = true else -- Check if found object is in specified categories. local CategoryDCSUnit = ZoneObject:getDesc().category for UnitCategoryID, UnitCategory in pairs( UnitCategories ) do if UnitCategory == CategoryDCSUnit then Include = true break end end end if Include then local CoalitionDCSUnit = ZoneObject:getCoalition() -- This coalition is inside the zone. self.ScanData.Coalitions[CoalitionDCSUnit] = true self.ScanData.Units[ZoneObject] = ZoneObject self:F2( { Name = ZoneObject:getName(), Coalition = CoalitionDCSUnit } ) end end if ObjectCategory == Object.Category.SCENERY then local SceneryType = ZoneObject:getTypeName() local SceneryName = ZoneObject:getName() self.ScanData.Scenery[SceneryType] = self.ScanData.Scenery[SceneryType] or {} self.ScanData.Scenery[SceneryType][SceneryName] = SCENERY:Register( SceneryName, ZoneObject ) self:F2( { SCENERY = self.ScanData.Scenery[SceneryType][SceneryName] } ) end end return true end -- Search objects. world.searchObjects( ObjectCategories, SphereSearch, EvaluateZone ) end --- Count the number of different coalitions inside the zone. -- @param #ZONE_RADIUS self -- @return #table Table of DCS units and DCS statics inside the zone. function ZONE_RADIUS:GetScannedUnits() return self.ScanData.Units end --- Get a set of scanned units. -- @param #ZONE_RADIUS self -- @return Core.Set#SET_UNIT Set of units and statics inside the zone. function ZONE_RADIUS:GetScannedSetUnit() local SetUnit = SET_UNIT:New() if self.ScanData then for ObjectID, UnitObject in pairs( self.ScanData.Units ) do local UnitObject = UnitObject -- DCS#Unit if UnitObject:isExist() then local FoundUnit = UNIT:FindByName( UnitObject:getName() ) if FoundUnit then SetUnit:AddUnit( FoundUnit ) else local FoundStatic = STATIC:FindByName( UnitObject:getName() ) if FoundStatic then SetUnit:AddUnit( FoundStatic ) end end end end end return SetUnit end --- Get a set of scanned units. -- @param #ZONE_RADIUS self -- @return Core.Set#SET_GROUP Set of groups. function ZONE_RADIUS:GetScannedSetGroup() self.ScanSetGroup=self.ScanSetGroup or SET_GROUP:New() --Core.Set#SET_GROUP self.ScanSetGroup.Set={} if self.ScanData then for ObjectID, UnitObject in pairs( self.ScanData.Units ) do local UnitObject = UnitObject -- DCS#Unit if UnitObject:isExist() then local FoundUnit=UNIT:FindByName(UnitObject:getName()) if FoundUnit then local group=FoundUnit:GetGroup() self.ScanSetGroup:AddGroup(group) end end end end return self.ScanSetGroup end --- Count the number of different coalitions inside the zone. -- @param #ZONE_RADIUS self -- @return #number Counted coalitions. function ZONE_RADIUS:CountScannedCoalitions() local Count = 0 for CoalitionID, Coalition in pairs( self.ScanData.Coalitions ) do Count = Count + 1 end return Count end --- Check if a certain coalition is inside a scanned zone. -- @param #ZONE_RADIUS self -- @param #number Coalition The coalition id, e.g. coalition.side.BLUE. -- @return #boolean If true, the coalition is inside the zone. function ZONE_RADIUS:CheckScannedCoalition( Coalition ) if Coalition then return self.ScanData.Coalitions[Coalition] end return nil end --- Get Coalitions of the units in the Zone, or Check if there are units of the given Coalition in the Zone. -- Returns nil if there are none to two Coalitions in the zone! -- Returns one Coalition if there are only Units of one Coalition in the Zone. -- Returns the Coalition for the given Coalition if there are units of the Coalition in the Zone. -- @param #ZONE_RADIUS self -- @return #table function ZONE_RADIUS:GetScannedCoalition( Coalition ) if Coalition then return self.ScanData.Coalitions[Coalition] else local Count = 0 local ReturnCoalition = nil for CoalitionID, Coalition in pairs( self.ScanData.Coalitions ) do Count = Count + 1 ReturnCoalition = CoalitionID end if Count ~= 1 then ReturnCoalition = nil end return ReturnCoalition end end --- Get scanned scenery type -- @param #ZONE_RADIUS self -- @return #table Table of DCS scenery type objects. function ZONE_RADIUS:GetScannedSceneryType( SceneryType ) return self.ScanData.Scenery[SceneryType] end --- Get scanned scenery table -- @param #ZONE_RADIUS self -- @return #table Table of DCS scenery objects. function ZONE_RADIUS:GetScannedScenery() return self.ScanData.Scenery end --- Is All in Zone of Coalition? -- Check if only the specifed coalition is inside the zone and noone else. -- @param #ZONE_RADIUS self -- @param #number Coalition Coalition ID of the coalition which is checked to be the only one in the zone. -- @return #boolean True, if **only** that coalition is inside the zone and no one else. -- @usage -- self.Zone:Scan() -- local IsGuarded = self.Zone:IsAllInZoneOfCoalition( self.Coalition ) function ZONE_RADIUS:IsAllInZoneOfCoalition( Coalition ) --self:E( { Coalitions = self.Coalitions, Count = self:CountScannedCoalitions() } ) return self:CountScannedCoalitions() == 1 and self:GetScannedCoalition( Coalition ) == true end --- Is All in Zone of Other Coalition? -- Check if only one coalition is inside the zone and the specified coalition is not the one. -- You first need to use the @{#ZONE_RADIUS.Scan} method to scan the zone before it can be evaluated! -- Note that once a zone has been scanned, multiple evaluations can be done on the scan result set. -- @param #ZONE_RADIUS self -- @param #number Coalition Coalition ID of the coalition which is not supposed to be in the zone. -- @return #boolean True, if and only if only one coalition is inside the zone and the specified coalition is not it. -- @usage -- self.Zone:Scan() -- local IsCaptured = self.Zone:IsAllInZoneOfOtherCoalition( self.Coalition ) function ZONE_RADIUS:IsAllInZoneOfOtherCoalition( Coalition ) --self:E( { Coalitions = self.Coalitions, Count = self:CountScannedCoalitions() } ) return self:CountScannedCoalitions() == 1 and self:GetScannedCoalition( Coalition ) == nil end --- Is Some in Zone of Coalition? -- Check if more than one coaltion is inside the zone and the specifed coalition is one of them. -- You first need to use the @{#ZONE_RADIUS.Scan} method to scan the zone before it can be evaluated! -- Note that once a zone has been scanned, multiple evaluations can be done on the scan result set. -- @param #ZONE_RADIUS self -- @param #number Coalition ID of the coaliton which is checked to be inside the zone. -- @return #boolean True if more than one coalition is inside the zone and the specified coalition is one of them. -- @usage -- self.Zone:Scan() -- local IsAttacked = self.Zone:IsSomeInZoneOfCoalition( self.Coalition ) function ZONE_RADIUS:IsSomeInZoneOfCoalition( Coalition ) return self:CountScannedCoalitions() > 1 and self:GetScannedCoalition( Coalition ) == true end --- Is None in Zone of Coalition? -- You first need to use the @{#ZONE_RADIUS.Scan} method to scan the zone before it can be evaluated! -- Note that once a zone has been scanned, multiple evaluations can be done on the scan result set. -- @param #ZONE_RADIUS self -- @param Coalition -- @return #boolean -- @usage -- self.Zone:Scan() -- local IsOccupied = self.Zone:IsNoneInZoneOfCoalition( self.Coalition ) function ZONE_RADIUS:IsNoneInZoneOfCoalition( Coalition ) return self:GetScannedCoalition( Coalition ) == nil end --- Is None in Zone? -- You first need to use the @{#ZONE_RADIUS.Scan} method to scan the zone before it can be evaluated! -- Note that once a zone has been scanned, multiple evaluations can be done on the scan result set. -- @param #ZONE_RADIUS self -- @return #boolean -- @usage -- self.Zone:Scan() -- local IsEmpty = self.Zone:IsNoneInZone() function ZONE_RADIUS:IsNoneInZone() return self:CountScannedCoalitions() == 0 end --- Searches the zone -- @param #ZONE_RADIUS self -- @param ObjectCategories A list of categories, which are members of Object.Category -- @param EvaluateFunction function ZONE_RADIUS:SearchZone( EvaluateFunction, ObjectCategories ) local SearchZoneResult = true local ZoneCoord = self:GetCoordinate() local ZoneRadius = self:GetRadius() self:F({ZoneCoord = ZoneCoord, ZoneRadius = ZoneRadius, ZoneCoordLL = ZoneCoord:ToStringLLDMS()}) local SphereSearch = { id = world.VolumeType.SPHERE, params = { point = ZoneCoord:GetVec3(), radius = ZoneRadius / 2, } } local function EvaluateZone( ZoneDCSUnit ) local ZoneUnit = UNIT:Find( ZoneDCSUnit ) return EvaluateFunction( ZoneUnit ) end world.searchObjects( Object.Category.UNIT, SphereSearch, EvaluateZone ) end --- Returns if a location is within the zone. -- @param #ZONE_RADIUS self -- @param DCS#Vec2 Vec2 The location to test. -- @return #boolean true if the location is within the zone. function ZONE_RADIUS:IsVec2InZone( Vec2 ) self:F2( Vec2 ) local ZoneVec2 = self:GetVec2() if ZoneVec2 then if (( Vec2.x - ZoneVec2.x )^2 + ( Vec2.y - ZoneVec2.y ) ^2 ) ^ 0.5 <= self:GetRadius() then return true end end return false end --- Returns if a point is within the zone. -- @param #ZONE_RADIUS self -- @param DCS#Vec3 Vec3 The point to test. -- @return #boolean true if the point is within the zone. function ZONE_RADIUS:IsVec3InZone( Vec3 ) self:F2( Vec3 ) local InZone = self:IsVec2InZone( { x = Vec3.x, y = Vec3.z } ) return InZone end --- Returns a random Vec2 location within the zone. -- @param #ZONE_RADIUS self -- @param #number inner (Optional) Minimal distance from the center of the zone. Default is 0. -- @param #number outer (Optional) Maximal distance from the outer edge of the zone. Default is the radius of the zone. -- @param #table surfacetypes (Optional) Table of surface types. Can also be a single surface type. We will try max 1000 times to find the right type! -- @return DCS#Vec2 The random location within the zone. function ZONE_RADIUS:GetRandomVec2(inner, outer, surfacetypes) local Vec2 = self:GetVec2() local _inner = inner or 0 local _outer = outer or self:GetRadius() if surfacetypes and type(surfacetypes)~="table" then surfacetypes={surfacetypes} end local function _getpoint() local point = {} local angle = math.random() * math.pi * 2 point.x = Vec2.x + math.cos(angle) * math.random(_inner, _outer) point.y = Vec2.y + math.sin(angle) * math.random(_inner, _outer) return point end local function _checkSurface(point) for _,sf in pairs(surfacetypes) do if sf==land.getSurfaceType(point) then return true end end return false end local point=_getpoint() if surfacetypes then local N=1 ; local Nmax=1000 while _checkSurface(point)==false and N<=Nmax do point=_getpoint() N=N+1 end end return point end --- Returns a @{Core.Point#POINT_VEC2} object reflecting a random 2D location within the zone. -- @param #ZONE_RADIUS self -- @param #number inner (optional) Minimal distance from the center of the zone. Default is 0. -- @param #number outer (optional) Maximal distance from the outer edge of the zone. Default is the radius of the zone. -- @return Core.Point#POINT_VEC2 The @{Core.Point#POINT_VEC2} object reflecting the random 3D location within the zone. function ZONE_RADIUS:GetRandomPointVec2( inner, outer ) self:F( self.ZoneName, inner, outer ) local PointVec2 = POINT_VEC2:NewFromVec2( self:GetRandomVec2( inner, outer ) ) self:T3( { PointVec2 } ) return PointVec2 end --- Returns Returns a random Vec3 location within the zone. -- @param #ZONE_RADIUS self -- @param #number inner (optional) Minimal distance from the center of the zone. Default is 0. -- @param #number outer (optional) Maximal distance from the outer edge of the zone. Default is the radius of the zone. -- @return DCS#Vec3 The random location within the zone. function ZONE_RADIUS:GetRandomVec3( inner, outer ) self:F( self.ZoneName, inner, outer ) local Vec2 = self:GetRandomVec2( inner, outer ) self:T3( { x = Vec2.x, y = self.y, z = Vec2.y } ) return { x = Vec2.x, y = self.y, z = Vec2.y } end --- Returns a @{Core.Point#POINT_VEC3} object reflecting a random 3D location within the zone. -- @param #ZONE_RADIUS self -- @param #number inner (optional) Minimal distance from the center of the zone. Default is 0. -- @param #number outer (optional) Maximal distance from the outer edge of the zone. Default is the radius of the zone. -- @return Core.Point#POINT_VEC3 The @{Core.Point#POINT_VEC3} object reflecting the random 3D location within the zone. function ZONE_RADIUS:GetRandomPointVec3( inner, outer ) self:F( self.ZoneName, inner, outer ) local PointVec3 = POINT_VEC3:NewFromVec2( self:GetRandomVec2( inner, outer ) ) self:T3( { PointVec3 } ) return PointVec3 end --- Returns a @{Core.Point#COORDINATE} object reflecting a random 3D location within the zone. -- @param #ZONE_RADIUS self -- @param #number inner (Optional) Minimal distance from the center of the zone. Default is 0. -- @param #number outer (Optional) Maximal distance from the outer edge of the zone. Default is the radius of the zone. -- @param #table surfacetypes (Optional) Table of surface types. Can also be a single surface type. We will try max 1000 times to find the right type! -- @return Core.Point#COORDINATE The random coordinate. function ZONE_RADIUS:GetRandomCoordinate(inner, outer, surfacetypes) local vec2=self:GetRandomVec2(inner, outer, surfacetypes) local Coordinate = COORDINATE:NewFromVec2(vec2) return Coordinate end --- @type ZONE -- @extends #ZONE_RADIUS --- The ZONE class, defined by the zone name as defined within the Mission Editor. -- This class implements the inherited functions from @{#ZONE_RADIUS} taking into account the own zone format and properties. -- -- ## ZONE constructor -- -- * @{#ZONE.New}(): Constructor. This will search for a trigger zone with the name given, and will return for you a ZONE object. -- -- ## Declare a ZONE directly in the DCS mission editor! -- -- You can declare a ZONE using the DCS mission editor by adding a trigger zone in the mission editor. -- -- Then during mission startup, when loading Moose.lua, this trigger zone will be detected as a ZONE declaration. -- Within the background, a ZONE object will be created within the @{Core.Database}. -- The ZONE name will be the trigger zone name. -- -- So, you can search yourself for the ZONE object by using the @{#ZONE.FindByName}() method. -- In this example, `local TriggerZone = ZONE:FindByName( "DefenseZone" )` would return the ZONE object -- that was created at mission startup, and reference it into the `TriggerZone` local object. -- -- Refer to mission `ZON-110` for a demonstration. -- -- This is especially handy if you want to quickly setup a SET_ZONE... -- So when you would declare `local SetZone = SET_ZONE:New():FilterPrefixes( "Defense" ):FilterStart()`, -- then SetZone would contain the ZONE object `DefenseZone` as part of the zone collection, -- without much scripting overhead!!! -- -- -- @field #ZONE ZONE = { ClassName="ZONE", } --- Constructor of ZONE taking the zone name. -- @param #ZONE self -- @param #string ZoneName The name of the zone as defined within the mission editor. -- @return #ZONE self function ZONE:New( ZoneName ) -- First try to find the zone in the DB. local zone=_DATABASE:FindZone(ZoneName) if zone then --env.info("FF found zone in DB") return zone end -- Get zone from DCS trigger function. local Zone = trigger.misc.getZone( ZoneName ) -- Error! if not Zone then env.error( "ERROR: Zone " .. ZoneName .. " does not exist!" ) return nil end -- Create a new ZONE_RADIUS. local self=BASE:Inherit( self, ZONE_RADIUS:New(ZoneName, {x=Zone.point.x, y=Zone.point.z}, Zone.radius)) self:F(ZoneName) -- Color of zone. self.Color={1, 0, 0, 0.15} -- DCS zone. self.Zone = Zone return self end --- Find a zone in the _DATABASE using the name of the zone. -- @param #ZONE_BASE self -- @param #string ZoneName The name of the zone. -- @return #ZONE_BASE self function ZONE:FindByName( ZoneName ) local ZoneFound = _DATABASE:FindZone( ZoneName ) return ZoneFound end --- @type ZONE_UNIT -- @field Wrapper.Unit#UNIT ZoneUNIT -- @extends Core.Zone#ZONE_RADIUS --- # ZONE_UNIT class, extends @{Zone#ZONE_RADIUS} -- -- The ZONE_UNIT class defined by a zone attached to a @{Wrapper.Unit#UNIT} with a radius and optional offsets. -- This class implements the inherited functions from @{#ZONE_RADIUS} taking into account the own zone format and properties. -- -- @field #ZONE_UNIT ZONE_UNIT = { ClassName="ZONE_UNIT", } --- Constructor to create a ZONE_UNIT instance, taking the zone name, a zone unit and a radius and optional offsets in X and Y directions. -- @param #ZONE_UNIT self -- @param #string ZoneName Name of the zone. -- @param Wrapper.Unit#UNIT ZoneUNIT The unit as the center of the zone. -- @param Dcs.DCSTypes#Distance Radius The radius of the zone. -- @param #table Offset A table specifying the offset. The offset table may have the following elements: -- dx The offset in X direction, +x is north. -- dy The offset in Y direction, +y is east. -- rho The distance of the zone from the unit -- theta The azimuth of the zone relative to unit -- relative_to_unit If true, theta is measured clockwise from unit's direction else clockwise from north. If using dx, dy setting this to true makes +x parallel to unit heading. -- dx, dy OR rho, theta may be used, not both. -- @return #ZONE_UNIT self function ZONE_UNIT:New( ZoneName, ZoneUNIT, Radius, Offset) if Offset then -- check if the inputs was reasonable, either (dx, dy) or (rho, theta) can be given, else raise an exception. if (Offset.dx or Offset.dy) and (Offset.rho or Offset.theta) then error("Cannot use (dx, dy) with (rho, theta)") end self.dy = Offset.dy or 0.0 self.dx = Offset.dx or 0.0 self.rho = Offset.rho or 0.0 self.theta = (Offset.theta or 0.0) * math.pi / 180.0 self.relative_to_unit = Offset.relative_to_unit or false end local self = BASE:Inherit( self, ZONE_RADIUS:New( ZoneName, ZoneUNIT:GetVec2(), Radius ) ) self:F( { ZoneName, ZoneUNIT:GetVec2(), Radius } ) self.ZoneUNIT = ZoneUNIT self.LastVec2 = ZoneUNIT:GetVec2() -- Zone objects are added to the _DATABASE and SET_ZONE objects. _EVENTDISPATCHER:CreateEventNewZone( self ) return self end --- Returns the current location of the @{Wrapper.Unit#UNIT}. -- @param #ZONE_UNIT self -- @return DCS#Vec2 The location of the zone based on the @{Wrapper.Unit#UNIT}location and the offset, if any. function ZONE_UNIT:GetVec2() self:F2( self.ZoneName ) local ZoneVec2 = self.ZoneUNIT:GetVec2() if ZoneVec2 then local heading if self.relative_to_unit then heading = ( self.ZoneUNIT:GetHeading() or 0.0 ) * math.pi / 180.0 else heading = 0.0 end -- update the zone position with the offsets. if (self.dx or self.dy) then -- use heading to rotate offset relative to unit using rotation matrix in 2D. -- see: https://en.wikipedia.org/wiki/Rotation_matrix ZoneVec2.x = ZoneVec2.x + self.dx * math.cos( -heading ) + self.dy * math.sin( -heading ) ZoneVec2.y = ZoneVec2.y - self.dx * math.sin( -heading ) + self.dy * math.cos( -heading ) end -- if using the polar coordinates if (self.rho or self.theta) then ZoneVec2.x = ZoneVec2.x + self.rho * math.cos( self.theta + heading ) ZoneVec2.y = ZoneVec2.y + self.rho * math.sin( self.theta + heading ) end self.LastVec2 = ZoneVec2 return ZoneVec2 else return self.LastVec2 end self:T2( { ZoneVec2 } ) return nil end --- Returns a random location within the zone. -- @param #ZONE_UNIT self -- @return DCS#Vec2 The random location within the zone. function ZONE_UNIT:GetRandomVec2() self:F( self.ZoneName ) local RandomVec2 = {} --local Vec2 = self.ZoneUNIT:GetVec2() -- FF: This does not take care of the new offset feature! local Vec2 = self:GetVec2() if not Vec2 then Vec2 = self.LastVec2 end local angle = math.random() * math.pi*2; RandomVec2.x = Vec2.x + math.cos( angle ) * math.random() * self:GetRadius(); RandomVec2.y = Vec2.y + math.sin( angle ) * math.random() * self:GetRadius(); self:T( { RandomVec2 } ) return RandomVec2 end --- Returns the @{DCS#Vec3} of the ZONE_UNIT. -- @param #ZONE_UNIT self -- @param DCS#Distance Height The height to add to the land height where the center of the zone is located. -- @return DCS#Vec3 The point of the zone. function ZONE_UNIT:GetVec3( Height ) self:F2( self.ZoneName ) Height = Height or 0 local Vec2 = self:GetVec2() local Vec3 = { x = Vec2.x, y = land.getHeight( self:GetVec2() ) + Height, z = Vec2.y } self:T2( { Vec3 } ) return Vec3 end --- @type ZONE_GROUP -- @extends #ZONE_RADIUS --- The ZONE_GROUP class defines by a zone around a @{Wrapper.Group#GROUP} with a radius. The current leader of the group defines the center of the zone. -- This class implements the inherited functions from @{Core.Zone#ZONE_RADIUS} taking into account the own zone format and properties. -- -- @field #ZONE_GROUP ZONE_GROUP = { ClassName="ZONE_GROUP", } --- Constructor to create a ZONE_GROUP instance, taking the zone name, a zone @{Wrapper.Group#GROUP} and a radius. -- @param #ZONE_GROUP self -- @param #string ZoneName Name of the zone. -- @param Wrapper.Group#GROUP ZoneGROUP The @{Wrapper.Group} as the center of the zone. -- @param DCS#Distance Radius The radius of the zone. -- @return #ZONE_GROUP self function ZONE_GROUP:New( ZoneName, ZoneGROUP, Radius ) local self = BASE:Inherit( self, ZONE_RADIUS:New( ZoneName, ZoneGROUP:GetVec2(), Radius ) ) self:F( { ZoneName, ZoneGROUP:GetVec2(), Radius } ) self._.ZoneGROUP = ZoneGROUP self._.ZoneVec2Cache = self._.ZoneGROUP:GetVec2() -- Zone objects are added to the _DATABASE and SET_ZONE objects. _EVENTDISPATCHER:CreateEventNewZone( self ) return self end --- Returns the current location of the @{Wrapper.Group}. -- @param #ZONE_GROUP self -- @return DCS#Vec2 The location of the zone based on the @{Wrapper.Group} location. function ZONE_GROUP:GetVec2() self:F( self.ZoneName ) local ZoneVec2 = nil if self._.ZoneGROUP:IsAlive() then ZoneVec2 = self._.ZoneGROUP:GetVec2() self._.ZoneVec2Cache = ZoneVec2 else ZoneVec2 = self._.ZoneVec2Cache end self:T( { ZoneVec2 } ) return ZoneVec2 end --- Returns a random location within the zone of the @{Wrapper.Group}. -- @param #ZONE_GROUP self -- @return DCS#Vec2 The random location of the zone based on the @{Wrapper.Group} location. function ZONE_GROUP:GetRandomVec2() self:F( self.ZoneName ) local Point = {} local Vec2 = self._.ZoneGROUP:GetVec2() local angle = math.random() * math.pi*2; Point.x = Vec2.x + math.cos( angle ) * math.random() * self:GetRadius(); Point.y = Vec2.y + math.sin( angle ) * math.random() * self:GetRadius(); self:T( { Point } ) return Point end --- Returns a @{Core.Point#POINT_VEC2} object reflecting a random 2D location within the zone. -- @param #ZONE_GROUP self -- @param #number inner (optional) Minimal distance from the center of the zone. Default is 0. -- @param #number outer (optional) Maximal distance from the outer edge of the zone. Default is the radius of the zone. -- @return Core.Point#POINT_VEC2 The @{Core.Point#POINT_VEC2} object reflecting the random 3D location within the zone. function ZONE_GROUP:GetRandomPointVec2( inner, outer ) self:F( self.ZoneName, inner, outer ) local PointVec2 = POINT_VEC2:NewFromVec2( self:GetRandomVec2() ) self:T3( { PointVec2 } ) return PointVec2 end --- @type ZONE_POLYGON_BASE -- --@field #ZONE_POLYGON_BASE.ListVec2 Polygon The polygon defined by an array of @{DCS#Vec2}. -- @extends #ZONE_BASE --- The ZONE_POLYGON_BASE class defined by a sequence of @{Wrapper.Group#GROUP} waypoints within the Mission Editor, forming a polygon. -- This class implements the inherited functions from @{Core.Zone#ZONE_RADIUS} taking into account the own zone format and properties. -- This class is an abstract BASE class for derived classes, and is not meant to be instantiated. -- -- ## Zone point randomization -- -- Various functions exist to find random points within the zone. -- -- * @{#ZONE_POLYGON_BASE.GetRandomVec2}(): Gets a random 2D point in the zone. -- * @{#ZONE_POLYGON_BASE.GetRandomPointVec2}(): Return a @{Core.Point#POINT_VEC2} object representing a random 2D point within the zone. -- * @{#ZONE_POLYGON_BASE.GetRandomPointVec3}(): Return a @{Core.Point#POINT_VEC3} object representing a random 3D point at landheight within the zone. -- -- ## Draw zone -- -- * @{#ZONE_POLYGON_BASE.DrawZone}(): Draws the zone on the F10 map. -- * @{#ZONE_POLYGON_BASE.Boundary}(): Draw a frontier on the F10 map with small filled circles. -- -- -- @field #ZONE_POLYGON_BASE ZONE_POLYGON_BASE = { ClassName="ZONE_POLYGON_BASE", } --- A 2D points array. -- @type ZONE_POLYGON_BASE.ListVec2 -- @list Table of 2D vectors. --- A 3D points array. -- @type ZONE_POLYGON_BASE.ListVec3 -- @list Table of 3D vectors. --- Constructor to create a ZONE_POLYGON_BASE instance, taking the zone name and an array of @{DCS#Vec2}, forming a polygon. -- The @{Wrapper.Group#GROUP} waypoints define the polygon corners. The first and the last point are automatically connected. -- @param #ZONE_POLYGON_BASE self -- @param #string ZoneName Name of the zone. -- @param #ZONE_POLYGON_BASE.ListVec2 PointsArray An array of @{DCS#Vec2}, forming a polygon. -- @return #ZONE_POLYGON_BASE self function ZONE_POLYGON_BASE:New( ZoneName, PointsArray ) -- Inherit ZONE_BASE. local self = BASE:Inherit( self, ZONE_BASE:New( ZoneName ) ) self:F( { ZoneName, PointsArray } ) if PointsArray then self._.Polygon = {} for i = 1, #PointsArray do self._.Polygon[i] = {} self._.Polygon[i].x = PointsArray[i].x self._.Polygon[i].y = PointsArray[i].y end end return self end --- Update polygon points with an array of @{DCS#Vec2}. -- @param #ZONE_POLYGON_BASE self -- @param #ZONE_POLYGON_BASE.ListVec2 Vec2Array An array of @{DCS#Vec2}, forming a polygon. -- @return #ZONE_POLYGON_BASE self function ZONE_POLYGON_BASE:UpdateFromVec2(Vec2Array) self._.Polygon = {} for i=1,#Vec2Array do self._.Polygon[i] = {} self._.Polygon[i].x=Vec2Array[i].x self._.Polygon[i].y=Vec2Array[i].y end return self end --- Update polygon points with an array of @{DCS#Vec3}. -- @param #ZONE_POLYGON_BASE self -- @param #ZONE_POLYGON_BASE.ListVec3 Vec2Array An array of @{DCS#Vec3}, forming a polygon. -- @return #ZONE_POLYGON_BASE self function ZONE_POLYGON_BASE:UpdateFromVec3(Vec3Array) self._.Polygon = {} for i=1,#Vec3Array do self._.Polygon[i] = {} self._.Polygon[i].x=Vec3Array[i].x self._.Polygon[i].y=Vec3Array[i].z end return self end --- Returns the center location of the polygon. -- @param #ZONE_POLYGON_BASE self -- @return DCS#Vec2 The location of the zone based on the @{Wrapper.Group} location. function ZONE_POLYGON_BASE:GetVec2() self:F( self.ZoneName ) local Bounds = self:GetBoundingSquare() return { x = ( Bounds.x2 + Bounds.x1 ) / 2, y = ( Bounds.y2 + Bounds.y1 ) / 2 } end --- Get a vertex of the polygon. -- @param #ZONE_POLYGON_BASE self -- @param #number Index Index of the vertex. Default 1. -- @return DCS#Vec2 Vertex of the polygon. function ZONE_POLYGON_BASE:GetVertexVec2(Index) return self._.Polygon[Index or 1] end --- Get a vertex of the polygon. -- @param #ZONE_POLYGON_BASE self -- @param #number Index Index of the vertex. Default 1. -- @return DCS#Vec3 Vertex of the polygon. function ZONE_POLYGON_BASE:GetVertexVec3(Index) local vec2=self:GetVertexVec2(Index) if vec2 then local vec3={x=vec2.x, y=land.getHeight(vec2), z=vec2.y} return vec3 end return nil end --- Get a vertex of the polygon. -- @param #ZONE_POLYGON_BASE self -- @param #number Index Index of the vertex. Default 1. -- @return Core.Point#COORDINATE Vertex of the polygon. function ZONE_POLYGON_BASE:GetVertexCoordinate(Index) local vec2=self:GetVertexVec2(Index) if vec2 then local coord=COORDINATE:NewFromVec2(vec2) return coord end return nil end --- Get a list of verticies of the polygon. -- @param #ZONE_POLYGON_BASE self -- @return List of DCS#Vec2 verticies defining the edges of the polygon. function ZONE_POLYGON_BASE:GetVerticiesVec2() return self._.Polygon end --- Get a list of verticies of the polygon. -- @param #ZONE_POLYGON_BASE self -- @return #table List of DCS#Vec3 verticies defining the edges of the polygon. function ZONE_POLYGON_BASE:GetVerticiesVec3() local coords={} for i,vec2 in ipairs(self._.Polygon) do local vec3={x=vec2.x, y=land.getHeight(vec2), z=vec2.y} table.insert(coords, vec3) end return coords end --- Get a list of verticies of the polygon. -- @param #ZONE_POLYGON_BASE self -- @return #table List of COORDINATES verticies defining the edges of the polygon. function ZONE_POLYGON_BASE:GetVerticiesCoordinates() local coords={} for i,vec2 in ipairs(self._.Polygon) do local coord=COORDINATE:NewFromVec2(vec2) table.insert(coords, coord) end return coords end --- Flush polygon coordinates as a table in DCS.log. -- @param #ZONE_POLYGON_BASE self -- @return #ZONE_POLYGON_BASE self function ZONE_POLYGON_BASE:Flush() self:F2() self:F( { Polygon = self.ZoneName, Coordinates = self._.Polygon } ) return self end --- Smokes the zone boundaries in a color. -- @param #ZONE_POLYGON_BASE self -- @param #boolean UnBound If true, the tyres will be destroyed. -- @return #ZONE_POLYGON_BASE self function ZONE_POLYGON_BASE:BoundZone( UnBound ) local i local j local Segments = 10 i = 1 j = #self._.Polygon while i <= #self._.Polygon do self:T( { i, j, self._.Polygon[i], self._.Polygon[j] } ) local DeltaX = self._.Polygon[j].x - self._.Polygon[i].x local DeltaY = self._.Polygon[j].y - self._.Polygon[i].y for Segment = 0, Segments do -- We divide each line in 5 segments and smoke a point on the line. local PointX = self._.Polygon[i].x + ( Segment * DeltaX / Segments ) local PointY = self._.Polygon[i].y + ( Segment * DeltaY / Segments ) local Tire = { ["country"] = "USA", ["category"] = "Fortifications", ["canCargo"] = false, ["shape_name"] = "H-tyre_B_WF", ["type"] = "Black_Tyre_WF", ["y"] = PointY, ["x"] = PointX, ["name"] = string.format( "%s-Tire #%0d", self:GetName(), ((i - 1) * Segments) + Segment ), ["heading"] = 0, } -- end of ["group"] local Group = coalition.addStaticObject( country.id.USA, Tire ) if UnBound and UnBound == true then Group:destroy() end end j = i i = i + 1 end return self end --- Draw the zone on the F10 map. **NOTE** Currently, only polygons with **exactly four points** are supported! -- @param #ZONE_POLYGON_BASE self -- @param #number Coalition Coalition: All=-1, Neutral=0, Red=1, Blue=2. Default -1=All. -- @param #table Color RGB color table {r, g, b}, e.g. {1,0,0} for red. -- @param #number Alpha Transparency [0,1]. Default 1. -- @param #table FillColor RGB color table {r, g, b}, e.g. {1,0,0} for red. Default is same as `Color` value. -- @param #number FillAlpha Transparency [0,1]. Default 0.15. -- @param #number LineType Line type: 0=No line, 1=Solid, 2=Dashed, 3=Dotted, 4=Dot dash, 5=Long dash, 6=Two dash. Default 1=Solid. -- @param #boolean ReadOnly (Optional) Mark is readonly and cannot be removed by users. Default false. -- @return #ZONE_POLYGON_BASE self function ZONE_POLYGON_BASE:DrawZone(Coalition, Color, Alpha, FillColor, FillAlpha, LineType, ReadOnly) local coordinate=COORDINATE:NewFromVec2(self._.Polygon[1]) Color=Color or self:GetColorRGB() Alpha=Alpha or 1 FillColor=FillColor or Color FillAlpha=FillAlpha or self:GetColorAlpha() if #self._.Polygon==4 then local Coord2=COORDINATE:NewFromVec2(self._.Polygon[2]) local Coord3=COORDINATE:NewFromVec2(self._.Polygon[3]) local Coord4=COORDINATE:NewFromVec2(self._.Polygon[4]) self.DrawID=coordinate:QuadToAll(Coord2, Coord3, Coord4, Coalition, Color, Alpha, FillColor, FillAlpha, LineType, ReadOnly) else local Coordinates=self:GetVerticiesCoordinates() table.remove(Coordinates, 1) self.DrawID=coordinate:MarkupToAllFreeForm(Coordinates, Coalition, Color, Alpha, FillColor, FillAlpha, LineType, ReadOnly) end return self end --- Smokes the zone boundaries in a color. -- @param #ZONE_POLYGON_BASE self -- @param Utilities.Utils#SMOKECOLOR SmokeColor The smoke color. -- @param #number Segments (Optional) Number of segments within boundary line. Default 10. -- @return #ZONE_POLYGON_BASE self function ZONE_POLYGON_BASE:SmokeZone( SmokeColor, Segments ) self:F2( SmokeColor ) Segments=Segments or 10 local i=1 local j=#self._.Polygon while i <= #self._.Polygon do self:T( { i, j, self._.Polygon[i], self._.Polygon[j] } ) local DeltaX = self._.Polygon[j].x - self._.Polygon[i].x local DeltaY = self._.Polygon[j].y - self._.Polygon[i].y for Segment = 0, Segments do -- We divide each line in 5 segments and smoke a point on the line. local PointX = self._.Polygon[i].x + ( Segment * DeltaX / Segments ) local PointY = self._.Polygon[i].y + ( Segment * DeltaY / Segments ) POINT_VEC2:New( PointX, PointY ):Smoke( SmokeColor ) end j = i i = i + 1 end return self end --- Flare the zone boundaries in a color. -- @param #ZONE_POLYGON_BASE self -- @param Utilities.Utils#FLARECOLOR FlareColor The flare color. -- @param #number Segments (Optional) Number of segments within boundary line. Default 10. -- @param DCS#Azimuth Azimuth (optional) Azimuth The azimuth of the flare. -- @param #number AddHeight (optional) The height to be added for the smoke. -- @return #ZONE_POLYGON_BASE self function ZONE_POLYGON_BASE:FlareZone( FlareColor, Segments, Azimuth, AddHeight ) self:F2(FlareColor) Segments=Segments or 10 AddHeight = AddHeight or 0 local i=1 local j=#self._.Polygon while i <= #self._.Polygon do self:T( { i, j, self._.Polygon[i], self._.Polygon[j] } ) local DeltaX = self._.Polygon[j].x - self._.Polygon[i].x local DeltaY = self._.Polygon[j].y - self._.Polygon[i].y for Segment = 0, Segments do -- We divide each line in 5 segments and smoke a point on the line. local PointX = self._.Polygon[i].x + ( Segment * DeltaX / Segments ) local PointY = self._.Polygon[i].y + ( Segment * DeltaY / Segments ) POINT_VEC2:New( PointX, PointY, AddHeight ):Flare(FlareColor, Azimuth) end j = i i = i + 1 end return self end --- Returns if a location is within the zone. -- Source learned and taken from: https://www.ecse.rpi.edu/Homepages/wrf/Research/Short_Notes/pnpoly.html -- @param #ZONE_POLYGON_BASE self -- @param DCS#Vec2 Vec2 The location to test. -- @return #boolean true if the location is within the zone. function ZONE_POLYGON_BASE:IsVec2InZone( Vec2 ) self:F2( Vec2 ) local Next local Prev local InPolygon = false Next = 1 Prev = #self._.Polygon while Next <= #self._.Polygon do self:T( { Next, Prev, self._.Polygon[Next], self._.Polygon[Prev] } ) if ( ( ( self._.Polygon[Next].y > Vec2.y ) ~= ( self._.Polygon[Prev].y > Vec2.y ) ) and ( Vec2.x < ( self._.Polygon[Prev].x - self._.Polygon[Next].x ) * ( Vec2.y - self._.Polygon[Next].y ) / ( self._.Polygon[Prev].y - self._.Polygon[Next].y ) + self._.Polygon[Next].x ) ) then InPolygon = not InPolygon end self:T2( { InPolygon = InPolygon } ) Prev = Next Next = Next + 1 end self:T( { InPolygon = InPolygon } ) return InPolygon end --- Define a random @{DCS#Vec2} within the zone. -- @param #ZONE_POLYGON_BASE self -- @return DCS#Vec2 The Vec2 coordinate. function ZONE_POLYGON_BASE:GetRandomVec2() -- It is a bit tricky to find a random point within a polygon. Right now i am doing it the dirty and inefficient way... -- Get the bounding square. local BS = self:GetBoundingSquare() local Nmax=1000 ; local n=0 while n self._.Polygon[i].x ) and self._.Polygon[i].x or x1 x2 = ( x2 < self._.Polygon[i].x ) and self._.Polygon[i].x or x2 y1 = ( y1 > self._.Polygon[i].y ) and self._.Polygon[i].y or y1 y2 = ( y2 < self._.Polygon[i].y ) and self._.Polygon[i].y or y2 end return { x1 = x1, y1 = y1, x2 = x2, y2 = y2 } end --- Draw a frontier on the F10 map with small filled circles. -- @param #ZONE_POLYGON_BASE self -- @param #number Coalition (Optional) Coalition: All=-1, Neutral=0, Red=1, Blue=2. Default -1= All. -- @param #table Color (Optional) RGB color table {r, g, b}, e.g. {1, 0, 0} for red. Default {1, 1, 1}= White. -- @param #number Radius (Optional) Radius of the circles in meters. Default 1000. -- @param #number Alpha (Optional) Alpha transparency [0,1]. Default 1. -- @param #number Segments (Optional) Number of segments within boundary line. Default 10. -- @param #boolean Closed (Optional) Link the last point with the first one to obtain a closed boundary. Default false -- @return #ZONE_POLYGON_BASE self function ZONE_POLYGON_BASE:Boundary(Coalition, Color, Radius, Alpha, Segments, Closed) Coalition = Coalition or -1 Color = Color or {1, 1, 1} Radius = Radius or 1000 Alpha = Alpha or 1 Segments = Segments or 10 Closed = Closed or false local i = 1 local j = #self._.Polygon if (Closed) then Limit = #self._.Polygon + 1 else Limit = #self._.Polygon end while i <= #self._.Polygon do self:T( { i, j, self._.Polygon[i], self._.Polygon[j] } ) if j ~= Limit then local DeltaX = self._.Polygon[j].x - self._.Polygon[i].x local DeltaY = self._.Polygon[j].y - self._.Polygon[i].y for Segment = 0, Segments do local PointX = self._.Polygon[i].x + ( Segment * DeltaX / Segments ) local PointY = self._.Polygon[i].y + ( Segment * DeltaY / Segments ) ZONE_RADIUS:New( "Zone", {x = PointX, y = PointY}, Radius ):DrawZone(Coalition, Color, 1, Color, Alpha, nil, true) end end j = i i = i + 1 end return self end --- @type ZONE_POLYGON -- @extends #ZONE_POLYGON_BASE --- The ZONE_POLYGON class defined by a sequence of @{Wrapper.Group#GROUP} waypoints within the Mission Editor, forming a polygon. -- This class implements the inherited functions from @{Core.Zone#ZONE_RADIUS} taking into account the own zone format and properties. -- -- ## Declare a ZONE_POLYGON directly in the DCS mission editor! -- -- You can declare a ZONE_POLYGON using the DCS mission editor by adding the ~ZONE_POLYGON tag in the group name. -- -- So, imagine you have a group declared in the mission editor, with group name `DefenseZone~ZONE_POLYGON`. -- Then during mission startup, when loading Moose.lua, this group will be detected as a ZONE_POLYGON declaration. -- Within the background, a ZONE_POLYGON object will be created within the @{Core.Database} using the properties of the group. -- The ZONE_POLYGON name will be the group name without the ~ZONE_POLYGON tag. -- -- So, you can search yourself for the ZONE_POLYGON by using the @{#ZONE_POLYGON.FindByName}() method. -- In this example, `local PolygonZone = ZONE_POLYGON:FindByName( "DefenseZone" )` would return the ZONE_POLYGON object -- that was created at mission startup, and reference it into the `PolygonZone` local object. -- -- Mission `ZON-510` shows a demonstration of this feature or method. -- -- This is especially handy if you want to quickly setup a SET_ZONE... -- So when you would declare `local SetZone = SET_ZONE:New():FilterPrefixes( "Defense" ):FilterStart()`, -- then SetZone would contain the ZONE_POLYGON object `DefenseZone` as part of the zone collection, -- without much scripting overhead! -- -- @field #ZONE_POLYGON ZONE_POLYGON = { ClassName="ZONE_POLYGON", } --- Constructor to create a ZONE_POLYGON instance, taking the zone name and the @{Wrapper.Group#GROUP} defined within the Mission Editor. -- The @{Wrapper.Group#GROUP} waypoints define the polygon corners. The first and the last point are automatically connected by ZONE_POLYGON. -- @param #ZONE_POLYGON self -- @param #string ZoneName Name of the zone. -- @param Wrapper.Group#GROUP ZoneGroup The GROUP waypoints as defined within the Mission Editor define the polygon shape. -- @return #ZONE_POLYGON self function ZONE_POLYGON:New( ZoneName, ZoneGroup ) local GroupPoints = ZoneGroup:GetTaskRoute() local self = BASE:Inherit( self, ZONE_POLYGON_BASE:New( ZoneName, GroupPoints ) ) self:F( { ZoneName, ZoneGroup, self._.Polygon } ) -- Zone objects are added to the _DATABASE and SET_ZONE objects. _EVENTDISPATCHER:CreateEventNewZone( self ) return self end --- Constructor to create a ZONE_POLYGON instance, taking the zone name and the **name** of the @{Wrapper.Group#GROUP} defined within the Mission Editor. -- The @{Wrapper.Group#GROUP} waypoints define the polygon corners. The first and the last point are automatically connected by ZONE_POLYGON. -- @param #ZONE_POLYGON self -- @param #string GroupName The group name of the GROUP defining the waypoints within the Mission Editor to define the polygon shape. -- @return #ZONE_POLYGON self function ZONE_POLYGON:NewFromGroupName( GroupName ) local ZoneGroup = GROUP:FindByName( GroupName ) local GroupPoints = ZoneGroup:GetTaskRoute() local self = BASE:Inherit( self, ZONE_POLYGON_BASE:New( GroupName, GroupPoints ) ) self:F( { GroupName, ZoneGroup, self._.Polygon } ) -- Zone objects are added to the _DATABASE and SET_ZONE objects. _EVENTDISPATCHER:CreateEventNewZone( self ) return self end --- Find a polygon zone in the _DATABASE using the name of the polygon zone. -- @param #ZONE_POLYGON self -- @param #string ZoneName The name of the polygon zone. -- @return #ZONE_POLYGON self function ZONE_POLYGON:FindByName( ZoneName ) local ZoneFound = _DATABASE:FindZone( ZoneName ) return ZoneFound end do -- ZONE_AIRBASE --- @type ZONE_AIRBASE -- @extends #ZONE_RADIUS --- The ZONE_AIRBASE class defines by a zone around a @{Wrapper.Airbase#AIRBASE} with a radius. -- This class implements the inherited functions from @{Core.Zone#ZONE_RADIUS} taking into account the own zone format and properties. -- -- @field #ZONE_AIRBASE ZONE_AIRBASE = { ClassName="ZONE_AIRBASE", } --- Constructor to create a ZONE_AIRBASE instance, taking the zone name, a zone @{Wrapper.Airbase#AIRBASE} and a radius. -- @param #ZONE_AIRBASE self -- @param #string AirbaseName Name of the airbase. -- @param DCS#Distance Radius (Optional)The radius of the zone in meters. Default 4000 meters. -- @return #ZONE_AIRBASE self function ZONE_AIRBASE:New( AirbaseName, Radius ) Radius=Radius or 4000 local Airbase = AIRBASE:FindByName( AirbaseName ) local self = BASE:Inherit( self, ZONE_RADIUS:New( AirbaseName, Airbase:GetVec2(), Radius ) ) self._.ZoneAirbase = Airbase self._.ZoneVec2Cache = self._.ZoneAirbase:GetVec2() if Airbase:IsShip() then self.isShip=true self.isHelipad=false self.isAirdrome=false elseif Airbase:IsHelipad() then self.isShip=false self.isHelipad=true self.isAirdrome=false elseif Airbase:IsAirdrome() then self.isShip=false self.isHelipad=false self.isAirdrome=true end -- Zone objects are added to the _DATABASE and SET_ZONE objects. _EVENTDISPATCHER:CreateEventNewZone( self ) return self end --- Get the airbase as part of the ZONE_AIRBASE object. -- @param #ZONE_AIRBASE self -- @return Wrapper.Airbase#AIRBASE The airbase. function ZONE_AIRBASE:GetAirbase() return self._.ZoneAirbase end --- Returns the current location of the @{Wrapper.Group}. -- @param #ZONE_AIRBASE self -- @return DCS#Vec2 The location of the zone based on the @{Wrapper.Group} location. function ZONE_AIRBASE:GetVec2() self:F( self.ZoneName ) local ZoneVec2 = nil if self._.ZoneAirbase:IsAlive() then ZoneVec2 = self._.ZoneAirbase:GetVec2() self._.ZoneVec2Cache = ZoneVec2 else ZoneVec2 = self._.ZoneVec2Cache end self:T( { ZoneVec2 } ) return ZoneVec2 end --- Returns a random location within the zone of the @{Wrapper.Group}. -- @param #ZONE_AIRBASE self -- @return DCS#Vec2 The random location of the zone based on the @{Wrapper.Group} location. function ZONE_AIRBASE:GetRandomVec2() self:F( self.ZoneName ) local Point = {} local Vec2 = self._.ZoneAirbase:GetVec2() local angle = math.random() * math.pi*2; Point.x = Vec2.x + math.cos( angle ) * math.random() * self:GetRadius(); Point.y = Vec2.y + math.sin( angle ) * math.random() * self:GetRadius(); self:T( { Point } ) return Point end --- Returns a @{Core.Point#POINT_VEC2} object reflecting a random 2D location within the zone. -- @param #ZONE_AIRBASE self -- @param #number inner (optional) Minimal distance from the center of the zone. Default is 0. -- @param #number outer (optional) Maximal distance from the outer edge of the zone. Default is the radius of the zone. -- @return Core.Point#POINT_VEC2 The @{Core.Point#POINT_VEC2} object reflecting the random 3D location within the zone. function ZONE_AIRBASE:GetRandomPointVec2( inner, outer ) self:F( self.ZoneName, inner, outer ) local PointVec2 = POINT_VEC2:NewFromVec2( self:GetRandomVec2() ) self:T3( { PointVec2 } ) return PointVec2 end end