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- hb4 = hb4 or {}
- hb4.floodfill = hb4.floodfill or {}
- local function get_node_name(pos)
- local node = minetest.get_node_or_nil(pos)
- if node then
- return node.name
- end
- local meta = minetest.get_meta(pos)
- return meta:get_string("nodename")
- end
- -- Recursive algorithm.
- local function floodfill(startpos, nodelist, maxdepth)
- local traversal = {}
- local queue = {}
- local output = {}
- local curpos, hash, exists, name, found, norm, cb, count, depth
- local maxlength = 1
- local first = true
- local get_node_hash = minetest.hash_node_position
- startpos.d = 1
- queue[#queue+1] = startpos
- count = 1
- ::continue::
- curpos = queue[#queue]
- queue[#queue] = nil
- depth = curpos.d
- curpos.d = nil
- hash = get_node_hash(curpos)
- exists = false
- if traversal[hash] then
- exists = true
- if depth >= traversal[hash] then
- goto next
- end
- end
- if depth >= maxdepth then
- goto next
- end
- count = count + 1
- name = get_node_name(curpos)
- found = false
- norm = true
- cb = nil
- for n, m in pairs(nodelist) do
- if n == name then
- found = true
- if type(m) == "function" then
- cb = m
- elseif type(m) == "string" then
- if m == "leaf" then
- -- The first node scanned musn't be treated as a leaf.
- if not first then
- norm = false
- end
- end
- end
- break
- end
- end
- if not found then
- goto next
- end
- traversal[hash] = depth
- if not exists then
- output[#output+1] = {pos=curpos, name=name}
- end
- if cb then
- -- The node callback can add to the adjacency list.
- cb(curpos, queue, depth+1)
- elseif norm then
- queue[#queue+1] = {x=curpos.x+1, y=curpos.y, z=curpos.z, d=depth+1}
- queue[#queue+1] = {x=curpos.x-1, y=curpos.y, z=curpos.z, d=depth+1}
- queue[#queue+1] = {x=curpos.x, y=curpos.y+1, z=curpos.z, d=depth+1}
- queue[#queue+1] = {x=curpos.x, y=curpos.y-1, z=curpos.z, d=depth+1}
- queue[#queue+1] = {x=curpos.x, y=curpos.y, z=curpos.z+1, d=depth+1}
- queue[#queue+1] = {x=curpos.x, y=curpos.y, z=curpos.z-1, d=depth+1}
- end
- if #queue > maxlength then
- maxlength = #queue
- end
- ::next::
- first = false
- if #queue > 0 then
- goto continue
- end
- --minetest.chat_send_all("# Server: Array size: " .. maxlength)
- return count, output
- end
- local function floodfill2(startpos, nodelist, depth, maxdepth)
- local queue = {}
- local traversal = {}
- local output = {}
- local pos = startpos
- local hash
- local adjacent = {}
- local node
- local name
- local found
- local normaladjacency
- local nodecallback
- ::continue::
- if #queue > 0 then
- -- This should be the normal case.
- pos = queue[#queue]
- queue[#queue] = nil
- end
- hash = minetest.hash_node_position(pos)
- if traversal[hash] then
- -- This method makes the algorithm very slow, but is needed
- -- in order to correctly bind the flood distance to a given range.
- if traversal[hash] < depth then
- goto next
- end
- end
- traversal[hash] = depth
- if depth > maxdepth then
- goto next
- end
- node = minetest.get_node(pos)
- name = node.name
- found = false
- normaladjacency = true
- nodecallback = nil
- for n, m in pairs(nodelist) do
- if n == name then
- found = true
- if type(m) == "function" then
- nodecallback = m
- elseif type(m) == "string" then
- if m == "leaf" then
- normaladjacency = false
- end
- end
- break
- end
- end
- if not found then
- goto next
- end
- output[#output+1] = {pos=table.copy(pos), name=name}
- adjacent = {}
- if nodecallback then
- -- The node callback can set the adjacency list.
- adjacent = nodecallback(pos, node)
- elseif normaladjacency then
- adjacent = {
- {x=pos.x+1, y=pos.y, z=pos.z},
- {x=pos.x-1, y=pos.y, z=pos.z},
- {x=pos.x, y=pos.y+1, z=pos.z},
- {x=pos.x, y=pos.y-1, z=pos.z},
- {x=pos.x, y=pos.y, z=pos.z+1},
- {x=pos.x, y=pos.y, z=pos.z-1},
- }
- end
- -- Add adjacent nodes to the queue for checking.
- for k, v in ipairs(adjacent) do
- queue[#queue+1] = v
- end
- ::next::
- if #queue > 0 then
- goto continue
- end
- return output
- end
- -- Find all nodes attached to a given node, following only nodes in
- -- the given list of nodes. Uses a 'floodfill' recursive style algorithm.
- function hb4.floodfill.execute(pos, nodes, max)
- local count, out = floodfill(pos, nodes, max)
- return out, count
- --return floodfill2(pos, nodes, 1, max)
- end
- --[===[
- local function floodfill(startpos, nodelist, traversal, depth, maxdepth, output, calls)
- local hash = minetest.hash_node_position(startpos)
- local exists = false
- if traversal[hash] then
- exists = true
- if depth >= traversal[hash] then
- return calls
- end
- end
- if depth > maxdepth then
- return calls
- end
- local name = get_node_name(startpos)
- local found = false
- local normaladjacency = true
- local nodecallback
- for n, m in pairs(nodelist) do
- if n == name then
- found = true
- if type(m) == "function" then
- nodecallback = m
- elseif type(m) == "string" then
- if m == "leaf" then
- normaladjacency = false
- end
- end
- break
- end
- end
- if not found then
- return calls
- end
- traversal[hash] = depth
- if not exists then
- output[#output+1] = {pos=table.copy(startpos), name=name}
- end
- local adjacent = {}
- if nodecallback then
- -- The node callback can set the adjacency list.
- adjacent = nodecallback(startpos)
- elseif normaladjacency then
- adjacent = {
- {x=startpos.x+1, y=startpos.y, z=startpos.z},
- {x=startpos.x-1, y=startpos.y, z=startpos.z},
- {x=startpos.x, y=startpos.y+1, z=startpos.z},
- {x=startpos.x, y=startpos.y-1, z=startpos.z},
- {x=startpos.x, y=startpos.y, z=startpos.z+1},
- {x=startpos.x, y=startpos.y, z=startpos.z-1},
- }
- end
- for k, v in ipairs(adjacent) do
- calls = floodfill(v, nodelist, traversal, depth+1, maxdepth, output, calls+1)
- end
- return calls
- end
- --]===]
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