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questhelperredux/QuestHelper/graph_core.lua
2010-10-25 01:54:08 +00:00

662 lignes
22 Kio
Lua

QuestHelper_File["graph_core.lua"] = "1.4.0"
QuestHelper_Loadtime["graph_core.lua"] = GetTime()
-- Alright so what's the interface here
-- There's the obvious "find a path from A to B"
-- function QH_Graph_Pathfind(st, nd, make_path)
-- Right now, we're pretending that the world consists of infinite planes with links between them. That's where the whole "between-zone" thing occurs. So one way or another, we need to add links. We'll use name as an identifier so we can get rid of flight paths links later, and the coords will include a plane ID number.
-- function QH_Graph_Plane_Makelink(name, coord1, coord2, cost)
-- And then we need a way to get rid of links, so:
-- how does flying work zorba
-- how can we fly
-- howwwwww
-- Make a map from "phase" to "flyphase". Store all the links we're being told to make. When placing links, if the flyphase is flyable, we use the flyphase instead of the phase for placing. We don't place if it's an internal boundary (there's a few ways we can detect this, but let's just use the hacky one where we just look at the ID.) From there it's all pretty standard.
-- performance hack :(
local QH_Timeslice_Yield = QH_Timeslice_Yield
local tinsert, tremove = table.insert, table.remove
local pairs, ipairs = pairs, ipairs
local sqrt = math.sqrt
local GetTime = GetTime
local function heap_left(x) return (2*x) end
local function heap_right(x) return (2*x + 1) end
local function heap_sane(heap)
local dmp = ""
local finishbefore = 2
for i = 1, #heap do
if i == finishbefore then
print(dmp)
dmp = ""
finishbefore = finishbefore * 2
end
dmp = dmp .. string.format("%f ", heap[i].c)
end
print(dmp)
print("")
for i = 1, #heap do
--[[ assert(not heap[heap_left(i)] or heap[i].c <= heap[heap_left(i)].c) ]]
--[[ assert(not heap[heap_right(i)] or heap[i].c <= heap[heap_right(i)].c) ]]
end
end
local function heap_insert(heap, item)
--[[ assert(item) ]]
tinsert(heap, item)
local pt = #heap
while pt > 1 do
local ptd2 = math.floor(pt / 2)
if heap[ptd2].c <= heap[pt].c then
break
end
local tmp = heap[pt]
heap[pt] = heap[ptd2]
heap[ptd2] = tmp
pt = ptd2
end
--heap_sane(heap)
end
local function heap_extract(heap)
local rv = heap[1]
if #heap == 1 then tremove(heap) return rv end
heap[1] = tremove(heap)
local idx = 1
while idx < #heap do
local minix = idx
--local hl, hr = heap_left(idx), heap_right(idx)
local hl, hr = 2*idx, 2*idx+1 -- these had better be equivalent to the line above one
if heap[hl] and heap[hl].c < heap[minix].c then minix = hl end
if heap[hr] and heap[hr].c < heap[minix].c then minix = hr end
if minix ~= idx then
local tx = heap[minix]
heap[minix] = heap[idx]
heap[idx] = tx
idx = minix
else
break
end
end
--heap_sane(heap)
return rv
end
-- incremented on each graph iteration, so we don't have to clear everything. "GRaph ID" :D
local grid = 0
-- Plane format: each plane contains an array of nodes that exist in that plane.
-- Each node contains both its parent ID and its coordinates within that plane. It may contain a node it links to, along with cost.
local plane = {}
local plane_to_flyplane = {}
local continent_to_flyplane = {}
local flyplanes_enabled = {}
local plane_multiplier = {}
local plane_cull = {}
-- canonical plane :D
local function canoplane(plane)
if flyplanes_enabled[plane_to_flyplane[plane]] then return plane_to_flyplane[plane] else return plane end
end
local function xydist_raw(plane, stx, sty, ndx, ndy)
local dx, dy = stx - ndx, sty - ndy
return sqrt(dx * dx + dy * dy) / (plane_multiplier[plane] or 7)
end
local function xydist(st, nd)
--QuestHelper: Assert(canoplane(st.p) == canoplane(nd.p))
local dx, dy = st.x - nd.x, st.y - nd.y
return sqrt(dx * dx + dy * dy) / (plane_multiplier[canoplane(nd.p)] or 7) -- we're getting a result in seconds, not in yards
end
function QH_Graph_Pathfind(st, nd, reverse, make_path)
return QH_Graph_Pathmultifind(st, {nd}, reverse, make_path)[1]
end
local active = false
local prepared = false
local extrctime = 0
local wextrctime = 0
local actualtime = 0
local planetime = 0
local linktime = 0
function QH_Graph_Pathmultifind(st, nda, reverse, make_path)
--QuestHelper:TextOut("Starting PMF")
QuestHelper: Assert(not active)
QuestHelper: Assert(prepared)
active = true -- The fun thing about coroutines is that this is actually safe.
local out = QuestHelper:CreateTable("graphcore output") -- THIS HAD BETTER BE RELEASABLE OR IT WILL BE BAD
local undone = QuestHelper:CreateTable("graphcore undone")
local remaining = 0
local link = QuestHelper:CreateTable("graphcore link")
--local stats = QuestHelper:CreateTable("graphcore --stats")
QuestHelper: Assert(st.x and st.y and st.p)
--stats.dests_complex = 0
--stats.dests_total = 0
for k, v in ipairs(nda) do
QuestHelper: Assert(v.x and v.y and v.p)
local cpvp = canoplane(v.p)
if plane[cpvp] then
--print("Destination plane insertion")
local dest = QuestHelper:CreateTable("graphcore destination")
dest.x, dest.y, dest.p, dest.goal = v.x, v.y, cpvp, k
link[k] = dest
tinsert(plane[cpvp], link[k])
undone[k] = true
remaining = remaining + 1
--stats.dests_complex = --stats.dests_complex + 1
end
--stats.dests_total = --stats.dests_total + 1
end
local link_id = reverse and "rlinks" or "links"
--stats.node_initialized_first = 0
--stats.node_done = 0
--stats.node_done_already = 0
--stats.node_modified_before_use = 0
--stats.node_link_reprocessed = 0
--stats.node_link_first = 0
--stats.node_link_alreadydone = 0
--stats.node_inner_reprocessed = 0
--stats.node_inner_first = 0
--stats.node_inner_alreadydone = 0
local dijheap = QuestHelper:CreateTable("graphcore heap container")
local stnode = QuestHelper:CreateTable("graphcore stnode")
do
stnode.x, stnode.y, stnode.p, stnode.c, stnode.scan_id, stnode.scan_cost = st.x, st.y, canoplane(st.p), st.c, grid, 0
QuestHelper: Assert(plane[canoplane(st.p)])
tinsert(plane[stnode.p], stnode)
local hep = QuestHelper:CreateTable("graphcore heap")
hep.c, hep.n = 0, stnode -- more than the subtraction, less than the minimum
heap_insert(dijheap, hep)
end
--stats.heap_max = #dijheap
--QuestHelper:TextOut("Starting routing")
local extrc = 0
local actual = 0
local planescan = 0
local linkscan = 0
local planeyes = 0
local planeno = 0
local linkyes = 0
local linkno = 0
while remaining > 0 and #dijheap > 0 do
QH_Timeslice_Yield()
local ett = GetTime()
extrc = extrc + 1
--stats.heap_max = math.max(--stats.heap_max, #dijheap)
local cdj = heap_extract(dijheap)
local snode = cdj.n
--print(string.format("Extracted cost %f/%s pointing at %d/%f/%f", cdj.c, tostring(cdj.n.scan_cost), cdj.n.p, cdj.n.x, cdj.n.y))
if snode.scan_cost == cdj.c then -- if we've modified it since then, don't bother
local actt = GetTime()
actual = actual + 1
-- Are we at an end node?
if snode.goal then
-- we wouldn't be here if we hadn't found a better solution
--QuestHelper: Assert(undone[snode.goal])
out[snode.goal] = cdj.c
undone[snode.goal] = nil
remaining = remaining - 1
end
-- Link to everything else on the plane
if not cdj.pi then -- Did we come from this plane? If so, there's no reason to scan it again (flag means "plane internal")
local planet = GetTime()
planescan = planescan + 1
for _, v in ipairs(plane[snode.p]) do
if v.scan_id ~= grid or v.scan_cost > snode.scan_cost then
planeyes = planeyes + 1
local dst = xydist(snode, v)
local modcost = snode.scan_cost + dst
--print(string.format("Doing %d/%f vs %s/%s at %d/%f/%f", grid, modcost, tostring(v.scan_id), tostring(v.scan_cost), v.p, v.x, v.y))
if v.scan_id ~= grid or v.scan_cost > modcost then
v.scan_id = grid
v.scan_cost = modcost
v.scan_from = snode
v.scan_processed = false
v.scan_outnode = nil
v.scan_outnode_from = nil
do
local ncdj = QuestHelper:CreateTable("graphcore heap")
ncdj.c, ncdj.n, ncdj.pi = modcost, v, true
heap_insert(dijheap, ncdj)
--print(string.format("Inserting %f at %d/%f/%f, plane", snude.c, v.p, v.x, v.y))
end
end
else
planeno = planeno + 1
end
end
planetime = planetime + GetTime() - planet
end
-- Link to everything we link to
if not cdj.li and snode[link_id] then
local linkt = GetTime()
linkscan = linkscan + 1
for _, lnk in pairs(snode[link_id]) do
local mc2 = snode.scan_cost + lnk.cost
local linkto = lnk.link
if linkto.scan_id ~= grid or linkto.scan_cost > mc2 then
linkyes = linkyes + 1
linkto.scan_id = grid
linkto.scan_cost = mc2
linkto.scan_from = snode
linkto.scan_outnode = lnk.outnode_to
linkto.scan_outnode_from = lnk.outnode_from
local hep = QuestHelper:CreateTable("graphcore heap")
hep.c, hep.n, hep.li = mc2, linkto, true
heap_insert(dijheap, hep)
--print(string.format("Inserting %f at %d/%f/%f, link", hep.c, linkto.p, linkto.x, linkto.y))
else
linkno = linkno + 1
end
end
linktime = linktime + GetTime() - linkt
end
actualtime = actualtime + GetTime() - actt
extrctime = extrctime + GetTime() - ett
else
wextrctime = wextrctime + GetTime() - ett
end
QuestHelper:ReleaseTable(cdj)
end
--QuestHelper:TextOut(string.format("%d extracted, %d processed, %d planescan, %d linkscan, %d/%d plane, %d/%d link", extrc, actual, planescan, linkscan, planeyes, planeno, linkyes, linkno))
--QuestHelper:TextOut(string.format("times: %f/%f extracted, %f processed, %f planescan, %f linkscan", extrctime, wextrctime, actualtime, planetime, linktime))
for _, v in ipairs(dijheap) do
QuestHelper:ReleaseTable(v)
end
QuestHelper:ReleaseTable(dijheap)
dijheap = nil
--QuestHelper:TextOut(string.format("Earlyout with %d/%d remaining", #dijheap, remaining))
if remaining > 0 then
for k, v in ipairs(nda) do
if not out[k] then
QuestHelper: Assert(false, string.format("Couldn't find path to %d/%f/%f from %d/%f/%f", nda[k].p, nda[k].x, nda[k].y, st.p, st.x, st.y))
end
end
end
QuestHelper: Assert(remaining == 0)
grid = grid + 1
QuestHelper: Assert(grid < 1000000000) -- if this ever triggers I will be amazed
if make_path then
--print("mpath")
for k, v in pairs(out) do
QH_Timeslice_Yield()
--print(out[k])
local rp = QuestHelper:CreateTable("graphcore return")
rp.d = v
out[k] = rp
--print(out[k])
if link[k] then
QuestHelper: Assert(link[k].scan_from)
local tpath = reverse and rp or QuestHelper:CreateTable("graphcore path reversal")
local cpx = link[k].scan_from
local mdlast = nil
while cpx do
QuestHelper: Assert(cpx)
if cpx.scan_outnode then
tinsert(tpath, cpx.scan_outnode)
end
if cpx.scan_outnode_from then
tinsert(tpath, cpx.scan_outnode_from)
end
cpx = cpx.scan_from
end
QuestHelper: Assert(not mdlast)
if not reverse then
for i = #tpath, 1, -1 do
tinsert(rp, tpath[i])
end
QuestHelper: Assert(tpath ~= rp)
QuestHelper:ReleaseTable(tpath)
end
end
end
end
QuestHelper:ReleaseTable(table.remove(plane[stnode.p])) -- always added last, so we remove it first
for k, v in ipairs(nda) do
if plane[canoplane(v.p)] and plane[canoplane(v.p)][#plane[canoplane(v.p)]].goal then -- might not be the exact one, but we'll remove 'em all once we get there anyway :D
QuestHelper:ReleaseTable(table.remove(plane[canoplane(v.p)]))
end
end
QuestHelper:ReleaseTable(link)
QuestHelper:ReleaseTable(undone)
--QuestHelper:TextOut("Finishing")
--for k, v in pairs(stats) do
--print(k, v)
--end
active = false
return out -- THIS HAD BETTER BE RELEASABLE OR IT WILL BE BAD
end
function QH_Graph_Init()
for c, d in pairs(QuestHelper_IndexLookup) do
if type(c) == "number" then
QuestHelper: Assert(d[0])
continent_to_flyplane[c] = d[0]
for z, p in pairs(d) do
if type(z) == "number" then
--QuestHelper:TextOut(string.format("%d/%d: %d", c, z, p))
plane_to_flyplane[p] = d[0]
end
end
end
end
end
local linkages = {}
local function findnode(coord)
local p = canoplane(coord.p)
if not plane[p] then plane[p] = {} end
for _, v in ipairs(plane[p]) do
if v.x == coord.x and v.y == coord.y and v.name == coord.name then
return v
end
end
local nd = {x = coord.x, y = coord.y, p = p, name = coord.name}
tinsert(plane[p], nd)
return nd
end
function QH_Graph_Plane_Makelink(name, coord1, coord2, cost, cost_reverse)
QuestHelper: Assert(not active)
prepared = false
--QuestHelper: TextOut(string.format("Link '%s' made from %d/%f/%f to %d/%f/%f of cost %f, asymflag %s", name, coord1.p, coord1.x, coord1.y, coord2.p, coord2.x, coord2.y, cost, tostring(not not asymmetrical)))
QuestHelper: Assert(name)
QuestHelper: Assert(coord1)
QuestHelper: Assert(coord2)
QuestHelper: Assert(cost)
QuestHelper: Assert(cost >= 0)
QuestHelper: Assert(not cost_reverse or cost_reverse >= 0)
--cost = math.max(cost, 0.01)
--if cost_reverse then cost_reverse = math.max(cost_reverse, 0.01) end
local tlink = {name, coord1, coord2, cost, cost_reverse}
if not linkages[name] then linkages[name] = {} end
tinsert(linkages[name], tlink)
--print(name, coord1.map_desc[1], coord2.map_desc[1], coord)
end
function QH_Graph_Plane_Destroylinks(name)
QuestHelper: Assert(not active)
prepared = false
linkages[name] = nil
-- we'll actually clean things out once the refresh function is called
end
function QH_Graph_Flyplaneset(fpset, speed, cull)
QuestHelper: Assert(not active)
prepared = false
local index = QuestHelper_IndexLookup[fpset][0]
if not flyplanes_enabled[index] or plane_multiplier[index] ~= speed or plane_cull[index] ~= cull then
flyplanes_enabled[index] = true
plane_multiplier[index] = speed
plane_cull[index] = cull
end
-- we'll actually clean things out once the refresh function is called
end
function QH_Graph_Plane_Refresh()
--QuestHelper:TextOut("Graph plane refresh now")
QuestHelper: Assert(not active)
plane = {} -- reset it all
-- we take all our links, process them, and jam them together
-- mmmm
-- jam
for name, v in pairs(linkages) do
--print("Starting linkage", name)
local titx = {}
local nodeitems = {}
local nodedests = {}
local function makenodedest(outnode, package)
if not nodedests[outnode] then
nodedests[outnode] = {x = package.x, y = package.y, p = package.p, c = package.c, map_desc = package.map_desc, condense_class = package.condense_class} -- note: this is where the actual node objects that eventually get passed into the routing controller's path replot engine come from. So if you intend for anything to exist in that module, it's gotta be inserted here.
end
end
for _, i in ipairs(v) do
local name, coord1, coord2, cost, cost_reverse = unpack(i)
QuestHelper: Assert(name)
QuestHelper: Assert(coord1)
QuestHelper: Assert(coord2)
QuestHelper: Assert(cost)
i.n1, i.n2 = findnode(coord1), findnode(coord2)
table.insert(titx, i)
if not nodeitems[i.n1] then nodeitems[i.n1] = QuestHelper:CreateTable("graph plane refresh") end
if not nodeitems[i.n2] then nodeitems[i.n2] = QuestHelper:CreateTable("graph plane refresh") end
table.insert(nodeitems[i.n1], i)
table.insert(nodeitems[i.n2], i)
makenodedest(i.n1, coord1)
makenodedest(i.n2, coord2)
end
--QuestHelper:TextOut(string.format("%d titx", #titx))
-- all nodes are created, links are posted
local nodedone = {}
local mark
mark = function(tnode, acum)
if acum[tnode] then return end
acum[tnode] = true
nodedone[tnode] = true
for _, d in ipairs(nodeitems[tnode]) do
mark(d.n1, acum)
mark(d.n2, acum)
end
end
local infinity = 1e10
for _, connect in ipairs(titx) do
QH_Timeslice_Yield()
QuestHelper: Assert(nodedone[connect.n1] == nodedone[connect.n2])
if not nodedone[connect.n1] then
local nods = QuestHelper:CreateTable("graph plane nods")
local nods_reverse = QuestHelper:CreateTable("graph plane nods_reverse")
mark(connect.n1, nods)
local lookupindex = 1
for k, v in pairs(nods) do
nods[k] = lookupindex
nods_reverse[lookupindex] = k
lookupindex = lookupindex + 1
end
--QuestHelper:TextOut(string.format("Processing cluster of %d", lookupindex))
local tab = QuestHelper:CreateTable("graph plane floyd core")
for r = 1, lookupindex do
local inner = QuestHelper:CreateTable("graph plane floyd inner")
table.insert(tab, inner)
for tr = 1, lookupindex do
table.insert(inner, infinity)
end
end
for k, _ in pairs(nods) do
for _, titem in pairs(nodeitems[k]) do
local a, b = nods[titem.n1], nods[titem.n2]
tab[a][b] = math.min(tab[a][b], titem[4])
if titem[5] then
tab[b][a] = math.min(tab[b][a], titem[5])
end
end
end
for pivot in ipairs(tab) do
for s in ipairs(tab) do
for e in ipairs(tab) do
tab[s][e] = math.min(tab[s][e], tab[s][pivot] + tab[pivot][e])
end
end
end
-- add node link destinations here (we only need one sample per item)
for s, t in ipairs(tab) do
local n1 = nods_reverse[s]
for e, c in ipairs(t) do
local n2 = nods_reverse[e]
local doit = true
if c == infinity then doit = false end
if doit then
local n1p = canoplane(nodedests[n1].p)
local n2p = canoplane(nodedests[n2].p)
if n1p == n2p then
if name == "static_transition" then doit = false end -- ha ha, yep, that's how we find out, tooootally reliable
if plane_cull[n1p] then doit = false end -- DENIED
if doit then
local xyd = xydist_raw(n1p, nodedests[n1].x, nodedests[n1].y, nodedests[n2].x, nodedests[n2].y)
if c >= xyd then doit = false end -- it's faster to just fly directly. this won't fuck with the total-connectedness at all, because if it is faster to just fly directly from cluster A to cluster B, we'll just pick up cluster B when we get there
end
end
end
if doit then
if not n1.links then n1.links = {} end
if not n2.rlinks then n2.rlinks = {} end
--if name == "flightpath" then print("linking from", nodedests[n1].map_desc[1], "to", nodedests[n2].map_desc[1]) end
tinsert(n1.links, {cost = c, link = n2, outnode_to = nodedests[n2], outnode_from = nodedests[n1]})
tinsert(n2.rlinks, {cost = c, link = n1, outnode_to = nodedests[n1], outnode_from = nodedests[n2]})
end
end
end
QuestHelper:ReleaseTable(nods)
QuestHelper:ReleaseTable(nods_reverse)
for _, v in ipairs(tab) do QuestHelper:ReleaseTable(v) end
QuestHelper:ReleaseTable(tab)
end
end
for _, v in pairs(titx) do v.n1, v.n2 = nil, nil end
for _, v in pairs(nodeitems) do QuestHelper:ReleaseTable(v) end
end
prepared = true
--QuestHelper:TextOut("Graph plane refresh done")
end
--[[
local function QH_Graph_Plane_ReallyMakeLink(item)
local name, coord1, coord2, cost, cost_reverse = unpack(item)
QuestHelper: Assert(not active)
--QuestHelper: TextOut(string.format("Link '%s' made from %d/%f/%f to %d/%f/%f of cost %f, asymflag %s", name, coord1.p, coord1.x, coord1.y, coord2.p, coord2.x, coord2.y, cost, tostring(not not asymmetrical)))
QuestHelper: Assert(name)
QuestHelper: Assert(coord1)
QuestHelper: Assert(coord2)
QuestHelper: Assert(cost)
local n1p = canoplane(coord1.p)
local n2p = canoplane(coord2.p)
if n1p == n2p then
if name == "static_transition" then return end -- ha ha, yep, that's how we find out, tooootally reliable
local xyd = xydist_raw(n1p, coord1.x, coord1.y, coord2.x, coord2.y)
if plane_cull[n1p] then return end -- DENIED
if cost >= xyd and (not cost_reverse or cost_reverse >= xyd) then
return -- DENIED
end
end
local node1 = findnode(coord1)
local node2 = findnode(coord2)
local n1d = {x = coord1.x, y = coord1.y, p = coord1.p, c = coord1.c, map_desc = coord1.map_desc, condense_class = coord1.condense_class}
local n2d = {x = coord2.x, y = coord2.y, p = coord2.p, c = coord2.c, map_desc = coord2.map_desc, condense_class = coord2.condense_class}
if not node1.links then node1.links = {} end
if not node2.rlinks then node2.rlinks = {} end
tinsert(node1.links, {cost = cost, link = node2, outnode_to = n2d, outnode_from = n1d})
tinsert(node2.rlinks, {cost = cost, link = node1, outnode_to = n1d, outnode_from = n2d})
if cost_reverse then
if not node1.rlinks then node1.rlinks = {} end
if not node2.links then node2.links = {} end
tinsert(node1.rlinks, {cost = cost_reverse, link = node2, outnode_to = n2d, outnode_from = n1d})
tinsert(node2.links, {cost = cost_reverse, link = node1, outnode_to = n1d, outnode_from = n2d})
end
end
]]