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mirror of https://github.com/moparisthebest/minetest synced 2024-11-13 12:55:04 -05:00
minetest/builtin/game/falling.lua
Auke Kok 855a305057 falling: walk 4 additional diagonally down directions.
This seems very little cost and matches the old behavior more
closely. This will cause some more falling nodes to get added
to falling clusters. With the efficiency of the algorithm, this
really doesn't do much damage.
2016-04-20 06:51:11 +01:00

261 lines
7.1 KiB
Lua

-- Minetest: builtin/item.lua
--
-- Falling stuff
--
core.register_entity(":__builtin:falling_node", {
initial_properties = {
visual = "wielditem",
visual_size = {x = 0.667, y = 0.667},
textures = {},
physical = true,
is_visible = false,
collide_with_objects = false,
collisionbox = {-0.5, -0.5, -0.5, 0.5, 0.5, 0.5},
},
node = {},
set_node = function(self, node)
self.node = node
self.object:set_properties({
is_visible = true,
textures = {node.name},
})
end,
get_staticdata = function(self)
return core.serialize(self.node)
end,
on_activate = function(self, staticdata)
self.object:set_armor_groups({immortal = 1})
local node = core.deserialize(staticdata)
if node then
self:set_node(node)
elseif staticdata ~= "" then
self:set_node({name = staticdata})
end
end,
on_step = function(self, dtime)
-- Set gravity
local acceleration = self.object:getacceleration()
if not vector.equals(acceleration, {x = 0, y = -10, z = 0}) then
self.object:setacceleration({x = 0, y = -10, z = 0})
end
-- Turn to actual sand when collides to ground or just move
local pos = self.object:getpos()
local bcp = {x = pos.x, y = pos.y - 0.7, z = pos.z} -- Position of bottom center point
local bcn = core.get_node(bcp)
local bcd = core.registered_nodes[bcn.name]
-- Note: walkable is in the node definition, not in item groups
if not bcd or
(bcd.walkable or
(core.get_item_group(self.node.name, "float") ~= 0 and
bcd.liquidtype ~= "none")) then
if bcd and bcd.leveled and
bcn.name == self.node.name then
local addlevel = self.node.level
if not addlevel or addlevel <= 0 then
addlevel = bcd.leveled
end
if core.add_node_level(bcp, addlevel) == 0 then
self.object:remove()
return
end
elseif bcd and bcd.buildable_to and
(core.get_item_group(self.node.name, "float") == 0 or
bcd.liquidtype == "none") then
core.remove_node(bcp)
return
end
local np = {x = bcp.x, y = bcp.y + 1, z = bcp.z}
-- Check what's here
local n2 = core.get_node(np)
-- If it's not air or liquid, remove node and replace it with
-- it's drops
if n2.name ~= "air" and (not core.registered_nodes[n2.name] or
core.registered_nodes[n2.name].liquidtype == "none") then
core.remove_node(np)
if core.registered_nodes[n2.name].buildable_to == false then
-- Add dropped items
local drops = core.get_node_drops(n2.name, "")
for _, dropped_item in ipairs(drops) do
core.add_item(np, dropped_item)
end
end
-- Run script hook
for _, callback in ipairs(core.registered_on_dignodes) do
callback(np, n2)
end
end
-- Create node and remove entity
if core.registered_nodes[self.node.name] then
core.add_node(np, self.node)
end
self.object:remove()
nodeupdate(np)
return
end
local vel = self.object:getvelocity()
if vector.equals(vel, {x = 0, y = 0, z = 0}) then
local npos = self.object:getpos()
self.object:setpos(vector.round(npos))
end
end
})
function spawn_falling_node(p, node)
local obj = core.add_entity(p, "__builtin:falling_node")
obj:get_luaentity():set_node(node)
end
function drop_attached_node(p)
local nn = core.get_node(p).name
core.remove_node(p)
for _, item in ipairs(core.get_node_drops(nn, "")) do
local pos = {
x = p.x + math.random()/2 - 0.25,
y = p.y + math.random()/2 - 0.25,
z = p.z + math.random()/2 - 0.25,
}
core.add_item(pos, item)
end
end
function check_attached_node(p, n)
local def = core.registered_nodes[n.name]
local d = {x = 0, y = 0, z = 0}
if def.paramtype2 == "wallmounted" then
d = core.wallmounted_to_dir(n.param2)
else
d.y = -1
end
local p2 = vector.add(p, d)
local nn = core.get_node(p2).name
local def2 = core.registered_nodes[nn]
if def2 and not def2.walkable then
return false
end
return true
end
--
-- Some common functions
--
function nodeupdate_single(p)
local n = core.get_node(p)
if core.get_item_group(n.name, "falling_node") ~= 0 then
local p_bottom = {x = p.x, y = p.y - 1, z = p.z}
local n_bottom = core.get_node(p_bottom)
-- Note: walkable is in the node definition, not in item groups
if core.registered_nodes[n_bottom.name] and
(core.get_item_group(n.name, "float") == 0 or
core.registered_nodes[n_bottom.name].liquidtype == "none") and
(n.name ~= n_bottom.name or (core.registered_nodes[n_bottom.name].leveled and
core.get_node_level(p_bottom) < core.get_node_max_level(p_bottom))) and
(not core.registered_nodes[n_bottom.name].walkable or
core.registered_nodes[n_bottom.name].buildable_to) then
n.level = core.get_node_level(p)
core.remove_node(p)
spawn_falling_node(p, n)
return true
end
end
if core.get_item_group(n.name, "attached_node") ~= 0 then
if not check_attached_node(p, n) then
drop_attached_node(p)
return true
end
end
return false
end
-- This table is specifically ordered.
-- We don't walk diagonals, only our direct neighbors, and self.
-- Down first as likely case, but always before self. The same with sides.
-- Up must come last, so that things above self will also fall all at once.
local nodeupdate_neighbors = {
{x = -1, y = -1, z = 0},
{x = 1, y = -1, z = 0},
{x = 0, y = -1, z = -1},
{x = 0, y = -1, z = 1},
{x = 0, y = -1, z = 0},
{x = -1, y = 0, z = 0},
{x = 1, y = 0, z = 0},
{x = 0, y = 0, z = 1},
{x = 0, y = 0, z = -1},
{x = 0, y = 0, z = 0},
{x = 0, y = 1, z = 0},
}
function nodeupdate(p)
-- Round p to prevent falling entities to get stuck.
p = vector.round(p)
-- We make a stack, and manually maintain size for performance.
-- Stored in the stack, we will maintain tables with pos, and
-- last neighbor visited. This way, when we get back to each
-- node, we know which directions we have already walked, and
-- which direction is the next to walk.
local s = {}
local n = 0
-- The neighbor order we will visit from our table.
local v = 1
while true do
-- Push current pos onto the stack.
n = n + 1
s[n] = {p = p, v = v}
-- Select next node from neighbor list.
p = vector.add(p, nodeupdate_neighbors[v])
-- Now we check out the node. If it is in need of an update,
-- it will let us know in the return value (true = updated).
if not nodeupdate_single(p) then
-- If we don't need to "recurse" (walk) to it then pop
-- our previous pos off the stack and continue from there,
-- with the v value we were at when we last were at that
-- node
repeat
local pop = s[n]
p = pop.p
v = pop.v
s[n] = nil
n = n - 1
-- If there's nothing left on the stack, and no
-- more sides to walk to, we're done and can exit
if n == 0 and v == 11 then
return
end
until v < 11
-- The next round walk the next neighbor in list.
v = v + 1
else
-- If we did need to walk the neighbor, then
-- start walking it from the walk order start (1),
-- and not the order we just pushed up the stack.
v = 1
end
end
end
--
-- Global callbacks
--
function on_placenode(p, node)
nodeupdate(p)
end
core.register_on_placenode(on_placenode)
function on_dignode(p, node)
nodeupdate(p)
end
core.register_on_dignode(on_dignode)