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The Gilbert–Johnson–Keerthi collision detection algorithm is significantly faster than collision detection using the separating axis theorem. GJK can only determine whether two shapes collide, but not the penetration vector. The expanding polytype algorithm can use information from GJK to quickly find the required vector.
174 lines
4.7 KiB
Lua
174 lines
4.7 KiB
Lua
--[[
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Copyright (c) 2012 Matthias Richter
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Permission is hereby granted, free of charge, to any person obtaining a copy
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of this software and associated documentation files (the "Software"), to deal
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in the Software without restriction, including without limitation the rights
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to use, copy, modify, merge, publish, distribute, sublicense, and/or sell
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copies of the Software, and to permit persons to whom the Software is
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furnished to do so, subject to the following conditions:
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The above copyright notice and this permission notice shall be included in
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all copies or substantial portions of the Software.
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Except as contained in this notice, the name(s) of the above copyright holders
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shall not be used in advertising or otherwise to promote the sale, use or
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other dealings in this Software without prior written authorization.
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THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR
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IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY,
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FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE
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AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER
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LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM,
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OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN
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THE SOFTWARE.
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]]--
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local _PACKAGE = (...):match("^(.+)%.[^%.]+")
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local vector = require(_PACKAGE .. '.vector-light')
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local function support(shape_a, shape_b, dx, dy)
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local x,y = shape_a:support(dx,dy)
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return vector.sub(x,y, shape_b:support(-dx, -dy))
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end
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-- returns closest edge to the origin
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local function closest_edge(simplex)
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local e = {dist = math.huge}
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local i = #simplex-1
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for k = 1,#simplex-1,2 do
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local ax,ay = simplex[i], simplex[i+1]
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local bx,by = simplex[k], simplex[k+1]
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i = k
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local ex,ey = vector.perpendicular(bx-ax, by-ay)
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local nx,ny = vector.normalize(ex,ey)
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local d = vector.dot(ax,ay, nx,ny)
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if d < e.dist then
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e.dist = d
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e.nx, e.ny = nx, ny
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e.i = k
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end
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end
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return e
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end
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local function EPA(shape_a, shape_b, simplex)
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-- make sure simplex is oriented counter clockwise
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local cx,cy, bx,by, ax,ay = unpack(simplex)
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if vector.dot(ax-bx,ay-by, cx-bx,cy-by) < 0 then
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simplex[1],simplex[2] = ax,ay
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simplex[5],simplex[6] = cx,cy
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end
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-- the expanding polytype algorithm
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while true do
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local e = closest_edge(simplex)
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local px,py = support(shape_a, shape_b, e.nx, e.ny)
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local d = vector.dot(px,py, e.nx, e.ny)
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if d - e.dist < 1e-6 then
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return -d*e.nx, -d*e.ny
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end
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-- simplex = {..., simplex[e.i-1], px, py, simplex[e.i]
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table.insert(simplex, e.i, py)
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table.insert(simplex, e.i, px)
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end
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end
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-- : : origin must be in plane between A and B
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-- B o------o A since A is the furthest point on the MD
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-- : : in direction of the origin.
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local function do_line(simplex)
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local bx,by, ax,ay = unpack(simplex)
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local abx,aby = bx-ax, by-ay
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local dx,dy = vector.perpendicular(abx,aby)
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if vector.dot(dx,dy, -ax,-ay) < 0 then
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dx,dy = -dx,-dy
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end
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return simplex, dx,dy
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end
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-- B .'
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-- o-._ 1
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-- | `-. .' The origin can only be in regions 1, 3 or 4:
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-- | 4 o A 2 A lies on the edge of the MD and we came
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-- | _.-' '. from left of BC.
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-- o-' 3
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-- C '.
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local function do_triangle(simplex)
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local cx,cy, bx,by, ax,ay = unpack(simplex)
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local aox,aoy = -ax,-ay
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local abx,aby = bx-ax, by-ay
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local acx,acy = cx-ax, cy-ay
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-- test region 1
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local dx,dy = vector.perpendicular(abx,aby)
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if vector.dot(dx,dy, acx,acy) > 0 then
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dx,dy = -dx,-dy
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end
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if vector.dot(dx,dy, aox,aoy) > 0 then
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-- simplex = {bx,by, ax,ay}
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simplex[1], simplex[2] = bx,by
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simplex[3], simplex[4] = ax,ay
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simplex[5], simplex[6] = nil, nil
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return simplex, dx,dy
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end
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-- test region 3
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dx,dy = vector.perpendicular(acx,acy)
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if vector.dot(dx,dy, abx,aby) > 0 then
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dx,dy = -dx,-dy
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end
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if vector.dot(dx,dy, aox, aoy) > 0 then
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-- simplex = {cx,cy, ax,ay}
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simplex[3], simplex[4] = ax,ay
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simplex[5], simplex[6] = nil, nil
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return simplex, dx,dy
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end
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-- must be in region 4
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return simplex
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end
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local function GJK(shape_a, shape_b)
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local ax,ay = support(shape_a, shape_b, 1,0)
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local simplex = {ax,ay}
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local n = 2
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local dx,dy = -ax,-ay
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-- first iteration: line case
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ax,ay = support(shape_a, shape_b, dx,dy)
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if vector.dot(ax,ay, dx,dy) <= 0 then
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return false
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end
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simplex[n+1], simplex[n+2] = ax,ay
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simplex, dx, dy = do_line(simplex, dx, dy)
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n = 4
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-- all other iterations must be the triangle case
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while true do
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ax,ay = support(shape_a, shape_b, dx,dy)
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if vector.dot(ax,ay, dx,dy) <= 0 then
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return false
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end
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simplex[n+1], simplex[n+2] = ax,ay
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simplex, dx, dy = do_triangle(simplex, dx,dy)
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n = #simplex
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if n == 6 then
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return true, EPA(shape_a, shape_b, simplex)
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end
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end
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end
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return GJK
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