Changeset 9272 for code/branches/presentation2012merge/data/levels/includes

Timestamp:

Jun 3, 2012, 6:05:24 PM (12 years ago)

Author:

landauf

Message:

replaced tabs with spaces (no code changed)

Location:

code/branches/presentation2012merge/data/levels/includes

Files:

• CuboidSpaceStation.lua (modified) (20 diffs)
• asteroidField.lua (modified) (2 diffs)
• weaponSettingsFPS.oxi (modified) (4 diffs)

code/branches/presentation2012merge/data/levels/includes/CuboidSpaceStation.lua

@@ -1 +1 @@
 ----------------------------------------------------------------------------------------------------
 -- This lua script creates a totally random generated space station for the orxonox computer game!--
--- (c) Wallah 2008, published under GPL licence!                                                                                                  --
+-- (c) Wallah 2008, published under GPL licence!                                                  --
 ----------------------------------------------------------------------------------------------------
 
 --------------------------------------------------------------------------------------------------------------------------------------------------------------------
--- IMPORTANT: If you need more parameters, do the following: copy the actual function (just the headline and the end statement) to the end of the file,                   --
+-- IMPORTANT: If you need more parameters, do the following: copy the actual function (just the headline and the end statement) to the end of the file,           --
 -- like I did with createSpaceStation() and let that function call the new function where you can modify the parameters. For all parameters which the old function--
 -- doesn't have you just give the standard default values, which I have defined. This is to make sure, that anyone else who uses the old function can still use it--
--- the same way he/she always did. If you want a function with less parameters, just create a new one at the end of the file and call this function with some     --
--- default values. REMEMBER: Function overloading is not possible, be sure to call your function differently from others already existing ones.                                   --
+-- the same way he/she always did. If you want a function with less parameters, just create a new one at the end of the file and call this function with some     --
+-- default values. REMEMBER: Function overloading is not possible, be sure to call your function differently from others already existing ones.                   --
 --------------------------------------------------------------------------------------------------------------------------------------------------------------------
 
 -- This function creates a randomly generated space station.
 -- The first argument ranSeed, must be 0, or a positive Integer, if it is 0 your space station is always chosen randomly, if you give an integer,
---      your space station will be generated randomly, but once you have the space station it will always be the same.
+--  your space station will be generated randomly, but once you have the space station it will always be the same.
 -- The argument xLength defines how large the space station will be into the x-direction.
 -- The argument xVar defines how much the space station will vary at the ends in x-direction, this is so that the station is no cube.
@@ -37 +37 @@
 -- Create a randomseed, so that the math.random() function is actually random.
 if ranSeed == 0 then
-        math.randomseed(os.time())
+    math.randomseed(os.time())
 else
-        math.randomseed(ranSeed)
+    math.randomseed(ranSeed)
 end
 -- End create randomseed.
@@ -52 +52 @@
 sSSize=30
 if xLength>=yLength and xLength>=zLength then
-        sSSize=xLength+20
+    sSSize=xLength+20
 elseif yLength>=xLength and yLength>=zLength then
-        sSSize=yLength+20
+    sSSize=yLength+20
 elseif zLength>=xLength and zLength>=yLength then
-        sSSize=zLength+20
+    sSSize=zLength+20
 end
 -- Define how many parts the space station has, this value has to be exact, so be sure to increment it if you're adding a new part.
@@ -78 +78 @@
 pDim=6
 -- Define the griddimension, be sure this value matches the size of a single space station part plus the size of a connection part, which means your parts must be:
---      integer*(gridDim-connectionSize), then integer tells you how many griddimensions your part is.
+--  integer*(gridDim-connectionSize), then integer tells you how many griddimensions your part is.
 gridDim=2.25
 -- End define global parameters.
@@ -89 +89 @@
 -- The parameters x,y,z are the axis of the space station, which iterate to sSSize, the maximal size of the space station.
 -- The griddimension, this word I will use later, means that the distance of a point to the next point is gridDim in the game, so the absolute x-axis is x*gridDim*sSScale,
---      and so on for the other dimensions y and z.
+--  and so on for the other dimensions y and z.
 -- grid[x][y][z][0] contains 0 if there is no part at the position (x,y,z), otherwise 1.
 -- grid[x][y][z][1] contains 0 if there is no connection from (x,y,z) in x-direction, "+" if there is one in the positive x-direction,
---      "-" if there is one in the negative x-direction, "+-" if there are in both x-directions.
+--  "-" if there is one in the negative x-direction, "+-" if there are in both x-directions.
 -- grid[x][y][z][2] contains 0 if there is no connection from (x,y,z) in y-direction, "+" if there is one in the positive y-direction,
---      "-" if there is one in the negative y-direction, "+-" if there are in both y-directions.
+--  "-" if there is one in the negative y-direction, "+-" if there are in both y-directions.
 -- grid[x][y][z][3] contains 0 if there is no connection from (x,y,z) in z-direction, "+" if there is one in the positive z-direction,
---      "-" if there is one in the negative z-direction, "+-" if there are in both z-directions.
+--  "-" if there is one in the negative z-direction, "+-" if there are in both z-directions.
 grid = {}
 for x=-math.floor(sSSize/2),math.floor(sSSize/2) do
-        grid[x] = {}
-        for y=-math.floor(sSSize/2),math.floor(sSSize/2) do
-                grid[x][y]= {}
-                for z=-math.floor(sSSize/2),math.floor(sSSize/2) do
-                        grid[x][y][z]={}
-                        for i=0,3 do
-                                grid[x][y][z][i]=0
-                        end
-                end
-        end
+    grid[x] = {}
+    for y=-math.floor(sSSize/2),math.floor(sSSize/2) do
+        grid[x][y]= {}
+        for z=-math.floor(sSSize/2),math.floor(sSSize/2) do
+            grid[x][y][z]={}
+            for i=0,3 do
+                grid[x][y][z][i]=0
+            end
+        end
+    end
 end
 -- End create 4-dim grid.
@@ -119 +119 @@
 -- The first parameter i, tells us how many parts fit into the array, so it iterates from 1 to sSParts, each part has his own value i.
 -- The second, third and fourth parameters are the relative coordinates of the part, you have to start at (0,0,0) and be sure you fill the array into the right direction.
---      A short example: your part is 2 griddimensions long and you place it in the game, that the relative coordinate point is at (0,0,0) and the part lies in the positive
---      z-axis, then you have to use the coordinate point (0,0,1).
+--  A short example: your part is 2 griddimensions long and you place it in the game, that the relative coordinate point is at (0,0,0) and the part lies in the positive
+--  z-axis, then you have to use the coordinate point (0,0,1).
 -- The fifth parameter is an array with size 4, at index=0, you have to set 1 if your part covers the gridpoint at (x,y,z), otherwise 0.
---      At index=1,2,3 you define the possible connection directions (1 for x, 2 for y and 3 for z), be sure to use the notation from above (0, "+-", "+", "-").
+--  At index=1,2,3 you define the possible connection directions (1 for x, 2 for y and 3 for z), be sure to use the notation from above (0, "+-", "+", "-").
 bodyParts={}
 for i=1,sSParts do
-        bodyParts[i]={}
-        for x=-math.floor(pDim/2),math.floor(pDim/2) do
-                bodyParts[i][x]={}
-                for y=-math.floor(pDim/2),math.floor(pDim/2) do
-                        bodyParts[i][x][y]={}
-                        for z=-math.floor(pDim/2),math.floor(pDim/2) do
-                                bodyParts[i][x][y][z]={}
-                                for k=0,3 do
-                                        bodyParts[i][x][y][z][k]=0
-                                end
-                        end
-                end
-        end
-        -- This contains the name of the mesh file.
-        bodyParts[i][0][0][0][4]=""
-        -- This contains the first possible rotation of your part, pitch=... yaw=... roll=... .
-        bodyParts[i][0][0][0][5]=""
-        -- This contains the second possible rotation of your part, pitch=... yaw=... roll=... .
-        bodyParts[i][0][0][0][6]=""
-        -- This contains the third possible rotation of your part, pitch=... yaw=... roll=... .
-        bodyParts[i][0][0][0][7]=""
-        -- Contains the movement rotation, rotationaxis=... rotationrate=... .
-        bodyParts[i][0][0][0][8]=""
-        -- Contains the attachment, if your part has an attachment, e.g. <ParticleEmitter .../>.
-        bodyParts[i][0][0][0][9]=""
-        -- Contains how many of this part you want to attach to your space station.
-        bodyParts[i][0][0][0][10]=1
+    bodyParts[i]={}
+    for x=-math.floor(pDim/2),math.floor(pDim/2) do
+        bodyParts[i][x]={}
+        for y=-math.floor(pDim/2),math.floor(pDim/2) do
+            bodyParts[i][x][y]={}
+            for z=-math.floor(pDim/2),math.floor(pDim/2) do
+                bodyParts[i][x][y][z]={}
+                for k=0,3 do
+                    bodyParts[i][x][y][z][k]=0
+                end
+            end
+        end
+    end
+    -- This contains the name of the mesh file.
+    bodyParts[i][0][0][0][4]=""
+    -- This contains the first possible rotation of your part, pitch=... yaw=... roll=... .
+    bodyParts[i][0][0][0][5]=""
+    -- This contains the second possible rotation of your part, pitch=... yaw=... roll=... .
+    bodyParts[i][0][0][0][6]=""
+    -- This contains the third possible rotation of your part, pitch=... yaw=... roll=... .
+    bodyParts[i][0][0][0][7]=""
+    -- Contains the movement rotation, rotationaxis=... rotationrate=... .
+    bodyParts[i][0][0][0][8]=""
+    -- Contains the attachment, if your part has an attachment, e.g. <ParticleEmitter .../>.
+    bodyParts[i][0][0][0][9]=""
+    -- Contains how many of this part you want to attach to your space station.
+    bodyParts[i][0][0][0][10]=1
 end
 ----------------------------------------------------------------------------------------------------------------------------------------------------------------------------
@@ -193 +193 @@
 
 -- Insert the CuboidConnectionBody, it is three griddimensions long and one wide and high and can have only connections at griddimension 1
---      (except the side in direction of griddimension 2) and griddimension 3 (except the side in direction of griddimension 2).
+--  (except the side in direction of griddimension 2) and griddimension 3 (except the side in direction of griddimension 2).
 bodyParts[3][0][0][0][4]="CuboidConnBody.mesh"
 bodyParts[3][0][0][0][5]="pitch=-90"
@@ -373 +373 @@
 --This function actualizes the grid, which I have to call always after I have added a new part to the space station.
 function actualizeGrid(Index,x,y,z)
-        for i=math.floor(-pDim/2)+1,math.floor(pDim/2) do
-                for j=math.floor(-pDim/2)+1,math.floor(pDim/2) do
-                        for k=math.floor(-pDim/2)+1,math.floor(pDim/2) do
-                                if bodyParts[Index][i][j][k][0] == 1 then
-                                        for l=0,3 do
-                                                grid[x+i][y+j][z+k][l] = bodyParts[Index][i][j][k][l]
-                                        end
-                                end
-                        end
-                end
-        end
+    for i=math.floor(-pDim/2)+1,math.floor(pDim/2) do
+        for j=math.floor(-pDim/2)+1,math.floor(pDim/2) do
+            for k=math.floor(-pDim/2)+1,math.floor(pDim/2) do
+                if bodyParts[Index][i][j][k][0] == 1 then
+                    for l=0,3 do
+                        grid[x+i][y+j][z+k][l] = bodyParts[Index][i][j][k][l]
+                    end
+                end
+            end
+        end
+    end
 end
 -- End actualizeGrid.
@@ -390 +390 @@
 -- If the part fits there it returns 1, otherwise 0.
 function checkPart(Index,x,y,z)
-        check=1
-        for i=math.floor(-pDim/2)+1,math.floor(pDim/2) do
-                for j=math.floor(-pDim/2)+1,math.floor(pDim/2) do
-                        for k=math.floor(-pDim/2)+1,math.floor(pDim/2) do
-                                -- If the part occupies the position (i,j,k), the grid must be empty there ((x+i, y+j, z+k)==0), if not, check is zero,
-                                --      which means that the part doesn't fit there.
-                                if bodyParts[Index][i][j][k][0] == 1 and grid[x+i][y+j][z+k][0] == 1 then
-                                        check=0
-                                end
-                        end
-                end
-        end
-        return check
+    check=1
+    for i=math.floor(-pDim/2)+1,math.floor(pDim/2) do
+        for j=math.floor(-pDim/2)+1,math.floor(pDim/2) do
+            for k=math.floor(-pDim/2)+1,math.floor(pDim/2) do
+                -- If the part occupies the position (i,j,k), the grid must be empty there ((x+i, y+j, z+k)==0), if not, check is zero,
+                --  which means that the part doesn't fit there.
+                if bodyParts[Index][i][j][k][0] == 1 and grid[x+i][y+j][z+k][0] == 1 then
+                    check=0
+                end
+            end
+        end
+    end
+    return check
 end
 -- End checkPart function.
@@ -408 +408 @@
 -- This function prints the model with tempPartIndex in the bodyParts array at position lx,ly,lz.
 -- If you need to rotate the model around his own axis, then you have to set movEntity true and define the details of the rotation in
---      bodyParts[tempPartIndex][0][0][0][8].
+--  bodyParts[tempPartIndex][0][0][0][8].
 -- If your model needs to be rotated like bodyParts[tempPartIndex][0][0][0][5], then side must be 1, for bodyParts[tempPartIndex][0][0][0][6] side must be 2,
---      for bodyParts[tempPartIndex][0][0][0][7] side must be 3.
+--  for bodyParts[tempPartIndex][0][0][0][7] side must be 3.
 function printModel(lx,ly,lz,tempPartIndex,movEntity,side)
-        if movEntity == true then
-                print("<MovableEntity scale=1 position=\"") print(lx*gridDim*sSScale) print(",") print(ly*gridDim*sSScale) print(",") print(lz*gridDim*sSScale) print("\" ")
-                print(bodyParts[tempPartIndex][0][0][0][8]) print(">")
-                print("<attached>")
-                lx=0 ly=0 lz=0
-        end
-
-        print("<Model position=\"") print(lx*gridDim*sSScale) print(",") print(ly*gridDim*sSScale) print(",") print(lz*gridDim*sSScale)
-        print("\" scale=") print(sSScale) print(" mesh= \"") print(bodyParts[tempPartIndex][0][0][0][4]) print("\"")
-
-                if side == 1 then
-                        print(bodyParts[tempPartIndex][0][0][0][5]) print(">")
-                elseif side == 2 then
-                        print(bodyParts[tempPartIndex][0][0][0][6]) print(">")
-                elseif side == 3 then
-                        print(bodyParts[tempPartIndex][0][0][0][7]) print(">")
-                end
-
-                print("<attached>")
-                        print(bodyParts[tempPartIndex][0][0][0][9])
-                print("</attached>")
-
-        print("</Model>")
-
-        if movEntity == true then
-                print("</attached>")
-                print("</MovableEntity>")
-        end
+    if movEntity == true then
+        print("<MovableEntity scale=1 position=\"") print(lx*gridDim*sSScale) print(",") print(ly*gridDim*sSScale) print(",") print(lz*gridDim*sSScale) print("\" ")
+        print(bodyParts[tempPartIndex][0][0][0][8]) print(">")
+        print("<attached>")
+        lx=0 ly=0 lz=0
+    end
+
+    print("<Model position=\"") print(lx*gridDim*sSScale) print(",") print(ly*gridDim*sSScale) print(",") print(lz*gridDim*sSScale)
+    print("\" scale=") print(sSScale) print(" mesh= \"") print(bodyParts[tempPartIndex][0][0][0][4]) print("\"")
+
+        if side == 1 then
+            print(bodyParts[tempPartIndex][0][0][0][5]) print(">")
+        elseif side == 2 then
+            print(bodyParts[tempPartIndex][0][0][0][6]) print(">")
+        elseif side == 3 then
+            print(bodyParts[tempPartIndex][0][0][0][7]) print(">")
+        end
+
+        print("<attached>")
+            print(bodyParts[tempPartIndex][0][0][0][9])
+        print("</attached>")
+
+    print("</Model>")
+
+    if movEntity == true then
+        print("</attached>")
+        print("</MovableEntity>")
+    end
 end
 -- End function printModel().
@@ -446 +446 @@
 -- The arguments lx,ly,lz are the coordinates of the grid, where you want to set the part.
 -- The arguments xAxis,yAxis,zAxis can be 0 or 1, but only one argument out of the three can be 1. This means two of them must always be zero. You have to set xAxis to one,
---      if your part is attached to a side, which faces into the x-direction (negative or positive, this is later specified with Dir), that means the x-Axis is a normal vector
---      of the side to which you want to attach the part. The same for yAxis and zAxis.
+--  if your part is attached to a side, which faces into the x-direction (negative or positive, this is later specified with Dir), that means the x-Axis is a normal vector
+--  of the side to which you want to attach the part. The same for yAxis and zAxis.
 -- The argument Dir must be 1 if your side, where you want to attach the part, faces into the positive direction, -1 if the side faces into the negative direction. The side
---      faces into the positive direction means, that the side of the side where the part will be attached is directed into the direction of the positive direction of the
---      corresponding axis.
+--  faces into the positive direction means, that the side of the side where the part will be attached is directed into the direction of the positive direction of the
+--  corresponding axis.
 -- The argument index is the index of the part for the bodyParts array.
 -- The argument printMovEnt must be false if your part doesn't need to be attached to an extra MovableEntity. If your part must be attached to an extra MovableEntity
---      this argument must be true. The extra MovableEntity is used to rotate the part around his own axis, or something like that.
+--  this argument must be true. The extra MovableEntity is used to rotate the part around his own axis, or something like that.
 -- The argument printSide is like the argument side of the printModel() function. It defines how your part will be rotated. Read the commentary there.
 -- The function returns 0 if the part couldn't be set, because it did not fit there or there was no side to attach the part. It returns 1 if the part is successfully set.
 function setPart(lx,ly,lz,xAxis,yAxis,zAxis,Dir,index,printMovEnt,printSide)
 
-        partSet=0
-        -- For the bodyParts array I use 1 as x-, 2 as y- and 3 as z-Axis for the definition in which directions a part can have connections.
-        coord=1*xAxis+2*yAxis+3*zAxis
-        -- If I try to attach the part from the positive direction to the side of the space station, the part of the station (where I want to attach the new part) must have
-        --      a connection into the positive direction. Otherwise I look from the negative side and so the part of the station must have a connection into the negative direction.
-        if Dir==1 then
-                conn="+"
-        elseif Dir==-1 then
-                conn="-"
-        end
-        -- I look from the direction defined through Dir, and here I check, whether I have reached a side of the space station, which means at position lx,ly,lz is nothing and
-        --      at the next position is a part which can have a connection into the direction from where I look.
-        if grid[lx][ly][lz][0] == 0 and grid[lx+(-1*xAxis*Dir)][ly+(-1*yAxis*Dir)][lz+(-1*zAxis*Dir)][0] == 1 and (grid[lx+(-1*xAxis*Dir)][ly+(-1*yAxis*Dir)][lz+(-1*zAxis*Dir)][coord]=="+-" or grid[lx+(-1*xAxis*Dir)][ly+(-1*yAxis*Dir)][lz+(-1*zAxis*Dir)][coord]==conn) then
-                -- This checks whether the part fits at that position or not.
-                check=checkPart(index,lx,ly,lz)
-                if check == 1 then
-                        -- This prints the part.
-                        printModel(lx,ly,lz,index,printMovEnt,printSide)
-                        partSet=1
-                        -- This actualizes the grid array with the values of the array bodyParts at the position index.
-                        actualizeGrid(index,lx,ly,lz)
-                end
-        end
-        return partSet
+    partSet=0
+    -- For the bodyParts array I use 1 as x-, 2 as y- and 3 as z-Axis for the definition in which directions a part can have connections.
+    coord=1*xAxis+2*yAxis+3*zAxis
+    -- If I try to attach the part from the positive direction to the side of the space station, the part of the station (where I want to attach the new part) must have
+    --  a connection into the positive direction. Otherwise I look from the negative side and so the part of the station must have a connection into the negative direction.
+    if Dir==1 then
+        conn="+"
+    elseif Dir==-1 then
+        conn="-"
+    end
+    -- I look from the direction defined through Dir, and here I check, whether I have reached a side of the space station, which means at position lx,ly,lz is nothing and
+    --  at the next position is a part which can have a connection into the direction from where I look.
+    if grid[lx][ly][lz][0] == 0 and grid[lx+(-1*xAxis*Dir)][ly+(-1*yAxis*Dir)][lz+(-1*zAxis*Dir)][0] == 1 and (grid[lx+(-1*xAxis*Dir)][ly+(-1*yAxis*Dir)][lz+(-1*zAxis*Dir)][coord]=="+-" or grid[lx+(-1*xAxis*Dir)][ly+(-1*yAxis*Dir)][lz+(-1*zAxis*Dir)][coord]==conn) then
+        -- This checks whether the part fits at that position or not.
+        check=checkPart(index,lx,ly,lz)
+        if check == 1 then
+            -- This prints the part.
+            printModel(lx,ly,lz,index,printMovEnt,printSide)
+            partSet=1
+            -- This actualizes the grid array with the values of the array bodyParts at the position index.
+            actualizeGrid(index,lx,ly,lz)
+        end
+    end
+    return partSet
 end
 -- End function setPart().
@@ -490 +490 @@
 -- The argument parts is the number of different parts which you want to attach to a side.
 function spiralSet(xAxis,yAxis,zAxis,Dir,index,parts,printMovEnt,printSide)
-        if index[0] ~= false then
-                -- The array vector contains the actual position where you try to set the part. vector[0],vector[1] and vector[3] contains the x,y,z-coordinate.
-                vector={}
-                -- This must be done, because there are different sides from where I try to attach a part.
-                coord1=1*yAxis+2*zAxis
-                coord2=math.mod(coord1+1,3)
-                coord3=math.mod(coord2+1,3)
-
-                for pc=1,parts do
-                        tempIndex = index[pc]
-                        for eachPart=1,bodyParts[tempIndex][0][0][0][10] do
-                                partSet=0
-                                vector[coord1]=math.floor(Dir*sSSize/2)-2*Dir
-                                while vector[coord1]~=math.floor(-1*Dir*sSSize/2)+2*Dir and partSet==0 do
-                                        round=0
-                                        while round<=math.floor(sSSize/2)-2 and partSet==0 do
-                                                vector[coord2]=round
-                                                vector[coord3]=-round
-                                                while vector[coord3]<=round and partSet==0 do
-                                                        partSet=setPart(vector[0],vector[1],vector[2],xAxis,yAxis,zAxis,Dir,tempIndex,printMovEnt,printSide)
-                                                        vector[coord3]=vector[coord3]+1
-                                                end
-                                                while vector[coord2]>=-round and partSet==0 do
-                                                        partSet=setPart(vector[0],vector[1],vector[2],xAxis,yAxis,zAxis,Dir,tempIndex,printMovEnt,printSide)
-                                                        vector[coord2]=vector[coord2]-1
-                                                end
-                                                while vector[coord3]>-round and partSet==0 do
-                                                        partSet=setPart(vector[0],vector[1],vector[2],xAxis,yAxis,zAxis,Dir,tempIndex,printMovEnt,printSide)
-                                                        vector[coord3]=vector[coord3]-1
-                                                end
-                                                while vector[coord2]<=round and partSet==0 do
-                                                        partSet=setPart(vector[0],vector[1],vector[2],xAxis,yAxis,zAxis,Dir,tempIndex,printMovEnt,printSide)
-                                                        vector[coord2]=vector[coord2]+1
-                                                end
-                                                round=round+1
-                                        end
-                                        vector[coord1]=vector[coord1]-Dir
-                                end
-                        end
-                end
-        end
+    if index[0] ~= false then
+        -- The array vector contains the actual position where you try to set the part. vector[0],vector[1] and vector[3] contains the x,y,z-coordinate.
+        vector={}
+        -- This must be done, because there are different sides from where I try to attach a part.
+        coord1=1*yAxis+2*zAxis
+        coord2=math.mod(coord1+1,3)
+        coord3=math.mod(coord2+1,3)
+
+        for pc=1,parts do
+            tempIndex = index[pc]
+            for eachPart=1,bodyParts[tempIndex][0][0][0][10] do
+                partSet=0
+                vector[coord1]=math.floor(Dir*sSSize/2)-2*Dir
+                while vector[coord1]~=math.floor(-1*Dir*sSSize/2)+2*Dir and partSet==0 do
+                    round=0
+                    while round<=math.floor(sSSize/2)-2 and partSet==0 do
+                        vector[coord2]=round
+                        vector[coord3]=-round
+                        while vector[coord3]<=round and partSet==0 do
+                            partSet=setPart(vector[0],vector[1],vector[2],xAxis,yAxis,zAxis,Dir,tempIndex,printMovEnt,printSide)
+                            vector[coord3]=vector[coord3]+1
+                        end
+                        while vector[coord2]>=-round and partSet==0 do
+                            partSet=setPart(vector[0],vector[1],vector[2],xAxis,yAxis,zAxis,Dir,tempIndex,printMovEnt,printSide)
+                            vector[coord2]=vector[coord2]-1
+                        end
+                        while vector[coord3]>-round and partSet==0 do
+                            partSet=setPart(vector[0],vector[1],vector[2],xAxis,yAxis,zAxis,Dir,tempIndex,printMovEnt,printSide)
+                            vector[coord3]=vector[coord3]-1
+                        end
+                        while vector[coord2]<=round and partSet==0 do
+                            partSet=setPart(vector[0],vector[1],vector[2],xAxis,yAxis,zAxis,Dir,tempIndex,printMovEnt,printSide)
+                            vector[coord2]=vector[coord2]+1
+                        end
+                        round=round+1
+                    end
+                    vector[coord1]=vector[coord1]-Dir
+                end
+            end
+        end
+    end
 end
 -- End function spiralSet().
@@ -554 +554 @@
 xMax=math.random(math.floor(xLength/2),math.floor(xLength/2)+xVar)
 while x<xMax do
-        -- The same for the y- and z-direction.
-        y=math.random(-math.floor(yLength/2),-math.floor(yLength/2)+yVar)
-        yMax=math.random(math.floor(yLength/2),math.floor(yLength/2)+yVar)
-        while y<yMax do
-                yMax=math.random(math.floor(yLength/2),math.floor(yLength/2)+yVar)
-                z=math.random(-math.floor(zLength/2),-math.floor(zLength/2)+zVar)
-                zMax=math.random(math.floor(zLength/2),math.floor(zLength/2)+zVar)
-                while z<zMax do
-                        -- This loop choses a bodypart, which fits at position (x,y,z).
-                        -- If after the fifth time the part does still not fit we terminate the loop and set no part at postition (x,y,z).
-                        partSet=0
-                        counter=0
-                        while counter<5 and partSet==0 do
-                                -- This choses randomly a bodyPartIndex, which is the index used for the parts in the array bodyParts.
-                                tempBodyPartIndex=math.random(1,sSBodyParts)
-                                check=checkPart(tempBodyPartIndex,x,y,z)
-                                -- If check == 1, this means that the part fits there, so we put it there and break the while true loop, to go on.
-                                if check == 1 then
-                                        -- This prints the chosen part at position (x*gridDim*sSScale,y*gridDim*sSScale,z*gridDim*sSScale).
-                                        printModel(x,y,z,tempBodyPartIndex,false,1)
-                                        -- This actualizes the grid array with the values of the array bodyParts at the position tempBodyPartIndex, which is our randomly chosen part.
-                                        actualizeGrid(tempBodyPartIndex,x,y,z)
-                                        partSet=1
-                                end
-                                counter=counter+1
-                        end
-                        z=z+1
-                end
-                y=y+1
-        end
-        x=x+1
+    -- The same for the y- and z-direction.
+    y=math.random(-math.floor(yLength/2),-math.floor(yLength/2)+yVar)
+    yMax=math.random(math.floor(yLength/2),math.floor(yLength/2)+yVar)
+    while y<yMax do
+        yMax=math.random(math.floor(yLength/2),math.floor(yLength/2)+yVar)
+        z=math.random(-math.floor(zLength/2),-math.floor(zLength/2)+zVar)
+        zMax=math.random(math.floor(zLength/2),math.floor(zLength/2)+zVar)
+        while z<zMax do
+            -- This loop choses a bodypart, which fits at position (x,y,z).
+            -- If after the fifth time the part does still not fit we terminate the loop and set no part at postition (x,y,z).
+            partSet=0
+            counter=0
+            while counter<5 and partSet==0 do
+                -- This choses randomly a bodyPartIndex, which is the index used for the parts in the array bodyParts.
+                tempBodyPartIndex=math.random(1,sSBodyParts)
+                check=checkPart(tempBodyPartIndex,x,y,z)
+                -- If check == 1, this means that the part fits there, so we put it there and break the while true loop, to go on.
+                if check == 1 then
+                    -- This prints the chosen part at position (x*gridDim*sSScale,y*gridDim*sSScale,z*gridDim*sSScale).
+                    printModel(x,y,z,tempBodyPartIndex,false,1)
+                    -- This actualizes the grid array with the values of the array bodyParts at the position tempBodyPartIndex, which is our randomly chosen part.
+                    actualizeGrid(tempBodyPartIndex,x,y,z)
+                    partSet=1
+                end
+                counter=counter+1
+            end
+            z=z+1
+        end
+        y=y+1
+    end
+    x=x+1
 end
 -- End attach all bodyparts.
@@ -593 +593 @@
 ----------------------------------------------------------------------------------------------------------------------------------------------------------------------------
 -- Attach backParts, if there are some.
-        spiralSet(0,0,1,1,backPartsIndex,backParts,false,1)
+    spiralSet(0,0,1,1,backPartsIndex,backParts,false,1)
 -- End attach backParts.
 ----------------------------------------------------------------------------------------------------------------------------------------------------------------------------
@@ -599 +599 @@
 ----------------------------------------------------------------------------------------------------------------------------------------------------------------------------
 -- Attach frontParts, if there are.
-        spiralSet(0,0,1,-1,frontPartsIndex,frontParts,false,1)
+    spiralSet(0,0,1,-1,frontPartsIndex,frontParts,false,1)
 -- End attach frontParts.
 ----------------------------------------------------------------------------------------------------------------------------------------------------------------------------
@@ -605 +605 @@
 ----------------------------------------------------------------------------------------------------------------------------------------------------------------------------
 -- Attach parts on the left side of the space station.
-        spiralSet(1,0,0,-1,leftSidePartsIndex,leftSideParts,true,1)
+    spiralSet(1,0,0,-1,leftSidePartsIndex,leftSideParts,true,1)
 -- End attach left side parts.
 ----------------------------------------------------------------------------------------------------------------------------------------------------------------------------
@@ -611 +611 @@
 ----------------------------------------------------------------------------------------------------------------------------------------------------------------------------
 -- Attach parts on the right side of the space station.
-        spiralSet(1,0,0,1,rightSidePartsIndex,rightSideParts,true,2)
+    spiralSet(1,0,0,1,rightSidePartsIndex,rightSideParts,true,2)
 -- End attach right side parts.
 ----------------------------------------------------------------------------------------------------------------------------------------------------------------------------
@@ -617 +617 @@
 ----------------------------------------------------------------------------------------------------------------------------------------------------------------------------
 -- Attach parts on top of the space station.
-        spiralSet(0,1,0,1,topPartsIndex,topParts,true,1)
+    spiralSet(0,1,0,1,topPartsIndex,topParts,true,1)
 -- End attach top parts.
 ----------------------------------------------------------------------------------------------------------------------------------------------------------------------------
@@ -627 +627 @@
 -- This iterates through the whole grid array.
 if connPartsIndex[0] ~= false then
-        for x=math.floor(-sSSize/2)+2,math.floor(sSSize/2)-2 do
-                for y=math.floor(-sSSize/2)+2,math.floor(sSSize/2)-2 do
-                        for z=math.floor(-sSSize/2)+2,math.floor(sSSize/2)-2 do
-                                tempConnPartIndex=connPartsIndex[math.random(1,connParts)]
-                                -- This checks whether there has to be a connection part between (x,y,z) and (x+1,y,z) or not. First it checks if there is a part at (x,y,z) and
-                                --      then it checks if that part can have a connection into the positive x-direction, if it can, it checks if there is a part at (x+1,y,z) and
-                                --      if that part can have a connection into the negative x-direction, if both can, it prints the xml code to set a connection part.
-                                if grid[x][y][z][0]==1 and (grid[x][y][z][1]=="+" or grid[x][y][z][1]=="+-") and grid[x+1][y][z][0]==1 and (grid[x+1][y][z][1]=="-" or grid[x+1][y][z][1]=="+-") then
-                                        -- This prints the connection part, the +1/2 is because the connection is set exactly in the middle of two gridpoints.
-                                        printModel(x+1/2,y,z,tempConnPartIndex,false,1)
-                                end
-                                -- The same as in the x-direction, but for the y-direction.
-                                if grid[x][y][z][0]==1 and ( grid[x][y][z][2]=="+" or grid[x][y][z][2]=="+-" ) and grid[x][y+1][z][0]==1 and ( grid[x][y+1][z][2]=="-" or grid[x][y+1][z][2]=="+-" ) then
-                                        printModel(x,y+1/2,z,tempConnPartIndex,false,2)
-                                end
-                                -- The same as in the x-direction, but for the z-direction.
-                                if grid[x][y][z][0]==1 and ( grid[x][y][z][3]=="+" or grid[x][y][z][3]=="+-" ) and grid[x][y][z+1][0]==1 and ( grid[x][y][z+1][3]=="-" or grid[x][y][z+1][3]=="+-" ) then
-                                        printModel(x,y,z+1/2,tempConnPartIndex,false,3)
-                                end
-                        end
-                end
-        end
+    for x=math.floor(-sSSize/2)+2,math.floor(sSSize/2)-2 do
+        for y=math.floor(-sSSize/2)+2,math.floor(sSSize/2)-2 do
+            for z=math.floor(-sSSize/2)+2,math.floor(sSSize/2)-2 do
+                tempConnPartIndex=connPartsIndex[math.random(1,connParts)]
+                -- This checks whether there has to be a connection part between (x,y,z) and (x+1,y,z) or not. First it checks if there is a part at (x,y,z) and
+                --  then it checks if that part can have a connection into the positive x-direction, if it can, it checks if there is a part at (x+1,y,z) and
+                --  if that part can have a connection into the negative x-direction, if both can, it prints the xml code to set a connection part.
+                if grid[x][y][z][0]==1 and (grid[x][y][z][1]=="+" or grid[x][y][z][1]=="+-") and grid[x+1][y][z][0]==1 and (grid[x+1][y][z][1]=="-" or grid[x+1][y][z][1]=="+-") then
+                    -- This prints the connection part, the +1/2 is because the connection is set exactly in the middle of two gridpoints.
+                    printModel(x+1/2,y,z,tempConnPartIndex,false,1)
+                end
+                -- The same as in the x-direction, but for the y-direction.
+                if grid[x][y][z][0]==1 and ( grid[x][y][z][2]=="+" or grid[x][y][z][2]=="+-" ) and grid[x][y+1][z][0]==1 and ( grid[x][y+1][z][2]=="-" or grid[x][y+1][z][2]=="+-" ) then
+                    printModel(x,y+1/2,z,tempConnPartIndex,false,2)
+                end
+                -- The same as in the x-direction, but for the z-direction.
+                if grid[x][y][z][0]==1 and ( grid[x][y][z][3]=="+" or grid[x][y][z][3]=="+-" ) and grid[x][y][z+1][0]==1 and ( grid[x][y][z+1][3]=="-" or grid[x][y][z+1][3]=="+-" ) then
+                    printModel(x,y,z+1/2,tempConnPartIndex,false,3)
+                end
+            end
+        end
+    end
 end
 -- End attach all connectionparts.
@@ -671 +671 @@
 -- This function is for the lazy guys, which do not care how the space station looks like, so I use some good standard values.
 function createSpaceStation()
-        createSpaceStationPar(0,4,1,2,1,6,1,100)
+    createSpaceStationPar(0,4,1,2,1,6,1,100)
 end
 -- End createSpaceStaion() function.

code/branches/presentation2012merge/data/levels/includes/asteroidField.lua

@@ -1 +1 @@
 --[[ fog generator
 generates fog
-        posX, posY, posZ - position in space
-        size - size of billboard
-        brightness - [0,1] fog brightness
+    posX, posY, posZ - position in space
+    size - size of billboard
+    brightness - [0,1] fog brightness
 --]]
 function generateFog(posX, posY, posZ, size, brightness)
-                print("<Billboard ")
-                        print("position = \"") 
-                                print(posX) print(",") 
-                                print(posY) print(",") 
-                                print(posZ) print("\" ") 
-                        print("colour=\"")
-                                print(brightness) print(",") 
-                                print(brightness) print(",") 
-                                print(brightness) print("\" ") 
-                        print("material=\"Smoke/Smoke\" scale=")
-                        print(size)
-                        print(" />")
+    print("<Billboard ")
+        print("position = \"")
+            print(posX) print(",")
+            print(posY) print(",")
+            print(posZ) print("\" ")
+        print("colour=\"")
+            print(brightness) print(",")
+            print(brightness) print(",")
+            print(brightness) print("\" ")
+        print("material=\"Smoke/Smoke\" scale=")
+        print(size)
+    print(" />")
 end
 
 --[[ asteroid field generator
 generates asteroid field
-        posX, posY, posZ - position in space
-        minSize, maxSize - size boundaries of each asteroid
-        radius - size of the cube around position in space
-        count - number of asteroids
-        fog - enable fog 0/1
+    posX, posY, posZ - position in space
+    minSize, maxSize - size boundaries of each asteroid
+    radius - size of the cube around position in space
+    count - number of asteroids
+    fog - enable fog 0/1
 --]]
 function asteroidField(posX, posY, posZ, minSize, maxSize, radius, count, fog)
-        for i = 1, count, 1
-        do
-                size = (math.random() * (maxSize - minSize)) + minSize
-                pX = (2 * math.random() * radius) - radius + posX
-                pY = (2 * math.random() * radius) - radius + posY
-                pZ = (2 * math.random() * radius) - radius + posZ
-                print("<StaticEntity ")
-                
-                print("position = \"") 
-                print(pX) print(",") 
-                print(pY) print(",") 
-                print(pZ) print("\" ")
-                
-                print("scale = \"") print(size) print("\" ")
-                
-                print("collisionType = static linearDamping = 0.8 angularDamping = 1 ") 
-                print("collisiondamage = 1000 enablecollisiondamage = true>")
-                
-                print("<attached>")
-                        print("<Model mass=\"") print(size * 10) print("\" ")
-                        print("mesh=\"ast") print(math.mod(i,6) + 1) print(".mesh\" />")
-                print("</attached>")
-                
-                print("<collisionShapes> ")
-                        print("<SphereCollisionShape radius=\"") 
-                        print(size * 2.5) print("\" />")
-                print("</collisionShapes>")
-                
-                print("</StaticEntity>")
-                
-                if fog == 1 and i % 5 == 0 then
-                        generateFog(pX, pY, pZ, radius*0.04, 0.2)
-                end
-        end
+    for i = 1, count, 1 do
+        size = (math.random() * (maxSize - minSize)) + minSize
+        pX = (2 * math.random() * radius) - radius + posX
+        pY = (2 * math.random() * radius) - radius + posY
+        pZ = (2 * math.random() * radius) - radius + posZ
+        print("<StaticEntity ")
+
+        print("position = \"")
+        print(pX) print(",")
+        print(pY) print(",")
+        print(pZ) print("\" ")
+
+        print("scale = \"") print(size) print("\" ")
+
+        print("collisionType = static linearDamping = 0.8 angularDamping = 1 ")
+        print("collisiondamage = 1000 enablecollisiondamage = true>")
+
+        print("<attached>")
+            print("<Model mass=\"") print(size * 10) print("\" ")
+            print("mesh=\"ast") print(math.mod(i,6) + 1) print(".mesh\" />")
+        print("</attached>")
+
+        print("<collisionShapes> ")
+            print("<SphereCollisionShape radius=\"")
+            print(size * 2.5) print("\" />")
+        print("</collisionShapes>")
+
+        print("</StaticEntity>")
+
+        if fog == 1 and i % 5 == 0 then
+            generateFog(pX, pY, pZ, radius*0.04, 0.2)
+        end
+    end
 end
 
@@ -68 +67 @@
 --[[ asteroid belt generator
 generates asteroid belt
-        posX, posY, posZ - position in space
-        yaw, pitch - rotation
-        minSize, maxSize - size boundaries of each asteroid
-        radius0, radius1 - inner/outer radius
-        count - number of asteroids
-        fog - enable fog 0/1
+    posX, posY, posZ - position in space
+    yaw, pitch - rotation
+    minSize, maxSize - size boundaries of each asteroid
+    radius0, radius1 - inner/outer radius
+    count - number of asteroids
+    fog - enable fog 0/1
 --]]
 function asteroidBelt(centerX, centerY, centerZ, yaw, pitch, segments, minSize, maxSize, radius0, radius1, count, fog)
-        dPhi = (2 * math.pi) / segments
-        width = math.abs(radius1 - radius0)
-        radius = (radius1 + radius0) / 2
-        segmentCount = count / segments
-        
-        print("<StaticEntity collisionType=static yaw=") print(yaw) 
-        print(" pitch=") print(pitch)
-        
-        print(" position = \"") 
-                print(centerX) print(",") 
-                print(centerY) print(",") 
-                print(centerZ) print("\"") 
-        print(">")
-        
-        print("<attached>")
-        
-        for i = 0, segments - 1, 1
-        do
-                asteroidField((radius * math.cos(i * dPhi)),
-                                        (radius * math.sin(i * dPhi)),
-                                        0, minSize, maxSize, width, segmentCount, fog)
-        end
-        
-        print("</attached>")
-        print("</StaticEntity>")
+    dPhi = (2 * math.pi) / segments
+    width = math.abs(radius1 - radius0)
+    radius = (radius1 + radius0) / 2
+    segmentCount = count / segments
+
+    print("<StaticEntity collisionType=static yaw=") print(yaw)
+    print(" pitch=") print(pitch)
+
+    print(" position = \"")
+        print(centerX) print(",")
+        print(centerY) print(",")
+        print(centerZ) print("\"")
+    print(">")
+
+    print("<attached>")
+
+    for i = 0, segments - 1, 1 do
+        asteroidField((radius * math.cos(i * dPhi)),
+                    (radius * math.sin(i * dPhi)),
+                    0, minSize, maxSize, width, segmentCount, fog)
+    end
+
+    print("</attached>")
+    print("</StaticEntity>")
 end

code/branches/presentation2012merge/data/levels/includes/weaponSettingsFPS.oxi

@@ -1 +1 @@
     <weaponslots>
       <WeaponSlot position="0,0,0" yaw=0 pitch=0 roll=0 />
- <!--      <WeaponSlot position="-0.5,0.8,2.5" yaw=0 pitch=0 roll=0 />
+<!--
+      <WeaponSlot position="-0.5,0.8,2.5" yaw=0 pitch=0 roll=0 />
       <WeaponSlot position="15,-1.5,-25" yaw=0 pitch=0 roll=0 />
-      <WeaponSlot position="0,0,-45" yaw=0 pitch=0 roll=0 /> -->
+      <WeaponSlot position="0,0,-45" yaw=0 pitch=0 roll=0 />
+-->
     </weaponslots>
     <weaponsets>
@@ -11 +13 @@
     <weapons>
       <WeaponPack firemode=0>
-        <links>
+        <links>
           <DefaultWeaponmodeLink firemode=0 weaponmode=0 />
           <DefaultWeaponmodeLink firemode=1 weaponmode=1 />
           <DefaultWeaponmodeLink firemode=2 weaponmode=2 />
         </links>
-        <Weapon>
-           <HsW01 mode=0 munitionpershot=0 delay=0.0 damage=2.5 material="Flares/point_lensflare" muzzleoffset=" 0.7, -0.3, -3" />
-           <LightningGun mode=1 muzzleoffset="0,0,0" damage=3.14159 shielddamage=20/>
+        <Weapon>
+          <HsW01 mode=0 munitionpershot=0 delay=0.0 damage=2.5 material="Flares/point_lensflare" muzzleoffset=" 0.7, -0.3, -3" />
+          <LightningGun mode=1 muzzleoffset="0,0,0" damage=3.14159 shielddamage=20/>
         </Weapon>
         <LaserGun
@@ -28 +30 @@
             unlimitedMunition=true
         />
-  <!--       <LaserGun
+        <!--LaserGun
             position="0,0,0"
             munitionType="LaserGunMunition"
@@ -45 +47 @@
             speed="600"
             unlimitedMunition=true
-        /> -->
+        /-->
       </WeaponPack>
     </weapons>