techage/power/power.lua
Joachim Stolberg 821e80fe88 rotor distance reduced
power distribution bugfix
powerswitch bugfix
2019-09-17 22:28:39 +02:00

568 lines
16 KiB
Lua

--[[
TechAge
=======
Copyright (C) 2019 Joachim Stolberg
GPL v3
See LICENSE.txt for more information
Power distribution and consumption calculation
for any kind of power distribution network
]]--
-- for lazy programmers
local S = function(pos) if pos then return minetest.pos_to_string(pos) end end
local P = minetest.string_to_pos
local M = minetest.get_meta
local D = techage.Debug
-- Techage Related Data
local PWR = function(pos) return (minetest.registered_nodes[minetest.get_node(pos).name] or {}).power end
-- Used to determine the already passed nodes while power distribution
local Route = {}
local NumNodes = 0
techage.power = {}
local MAX_NUM_NODES = 1000
techage.MAX_NUM_NODES = MAX_NUM_NODES
-- Consumer States
local STOPPED = 1
local NOPOWER = 2
local RUNNING = 3
-------------------------------------------------- Migrate
local CRD = function(pos) return (minetest.registered_nodes[minetest.get_node(pos).name] or {}).consumer end
local Consumer = {
["techage:streetlamp_off"] = 0,
["techage:streetlamp_on"] = 0.5,
["techage:industriallamp1_off"] = 0,
["techage:industriallamp1_on"] = 0.5,
["techage:industriallamp2_off"] = 0,
["techage:industriallamp2_on"] = 0.5,
["techage:industriallamp3_off"] = 0,
["techage:industriallamp3_on"] = 0.5,
["techage:simplelamp_off"] = 0,
["techage:simplelamp_on"] = 0.5,
["techage:ceilinglamp_off"] = 0,
["techage:ceilinglamp_on"] = 0.5,
["techage:ta2_autocrafter_pas"] = 0,
["techage:ta2_autocrafter_act"] = 4,
["techage:ta3_autocrafter_pas"] = 0,
["techage:ta3_autocrafter_act"] = 6,
["techage:ta2_electronic_fab_pas"] = 0,
["techage:ta2_electronic_fab_act"] = 8,
["techage:ta3_electronic_fab_pas"] = 0,
["techage:ta3_electronic_fab_act"] = 12,
["techage:ta2_gravelsieve_pas"] = 0,
["techage:ta2_gravelsieve_act"] = 3,
["techage:ta3_gravelsieve_pas"] = 0,
["techage:ta3_gravelsieve_act"] = 4,
["techage:ta2_grinder_pas"] = 0,
["techage:ta2_grinder_act"] = 4,
["techage:ta3_grinder_pas"] = 0,
["techage:ta3_grinder_act"] = 6,
["techage:ta2_rinser_pas"] = 0,
["techage:ta2_rinser_act"] = 3,
["techage:ta3_booster"] = 0,
["techage:ta3_booster_on"] = 3,
["techage:ta3_drillbox_pas"] = 0,
["techage:ta3_drillbox_act"] = 16,
["techage:ta3_pumpjack_pas"] = 0,
["techage:ta3_pumpjack_act"] = 16,
["techage:gearbox"] = 0,
["techage:gearbox_on"] = 1,
}
local Generator = {
["techage:t2_source"] = 20,
["techage:t3_source"] = 20,
["techage:t4_source"] = 20,
["techage:flywheel"] = 0,
["techage:flywheel_on"] = 25,
["techage:generator"] = 0,
["techage:generator_on"] = 80,
["techage:tiny_generator"] = 0,
["techage:tiny_generator_on"] = 12,
}
local Akku = {
["techage:ta3_akku"] = 10
}
local function migrate(pos, mem, node)
if mem.master_pos or mem.is_master ~= nil then
print("migrate", S(pos), node.name)
if mem.master_pos then
mem.pwr_master_pos = table.copy(mem.master_pos)
mem.master_pos = nil
end
mem.pwr_is_master = mem.is_master; mem.is_master = nil
mem.available1 = nil
mem.available2 = nil
mem.supply1 = nil
mem.supply2 = nil
mem.needed1 = nil
mem.needed2 = nil
mem.demand1 = nil
mem.demand2 = nil
mem.reserve = nil
mem.could_be_master = nil
mem.node_loaded = nil
mem.pwr_power_provided_cnt = 2
mem.pwr_node_alive_cnt = 4
local name = minetest.get_node(pos).name
mem.pwr_needed = Consumer[name]
mem.pwr_available = Generator[name]
mem.pwr_could_provide = Akku[name]
mem.pwr_could_need = Akku[name]
if Consumer[name] then
if mem.techage_state then
if mem.techage_state == techage.STOPPED then
mem.pwr_state = STOPPED
elseif mem.techage_state == techage.NOPOWER or mem.techage_state == techage.RUNNING then
local crd = CRD(pos)
techage.power.consumer_start(pos, mem, crd.cycle_time, crd.power_consumption)
end
elseif mem.turned_on then
mem.pwr_state = RUNNING
elseif mem.pwr_needed then
mem.pwr_state = RUNNING
else
mem.pwr_state = STOPPED
end
if techage.in_list({"techage:ta2_electronic_fab_pas", "techage:ta2_electronic_fab_act", "techage:ta3_electronic_fab_pas", "techage:ta3_electronic_fab_act"}, name) then
mem.pwr_cycle_time = 6
elseif techage.in_list({"techage:ta3_drillbox_pas", "techage:ta3_drillbox_act"}, name) then
mem.pwr_cycle_time = 16
elseif techage.in_list({"techage:ta3_pumpjack_pas", "techage:ta3_pumpjack_act"}, name) then
mem.pwr_cycle_time = 8
else
mem.pwr_cycle_time = 4
end
elseif Generator[name] then
mem.pwr_cycle_time = 2
if mem.generating then
techage.power.generator_start(pos, mem, Generator[name])
else
techage.power.generator_stop(pos, mem)
end
elseif Akku[name] then
mem.pwr_cycle_time = 2
if mem.techage_state and mem.techage_state == techage.RUNNING then
mem.running = true
minetest.get_node_timer(pos):start(2)
techage.power.secondary_start(pos, mem, mem.pwr_could_provide, mem.pwr_could_need)
end
end
end
end
local Nodenames={}
local n=0
for k,v in pairs(Consumer) do
n=n+1
Nodenames[n]=k
end
for k,v in pairs(Generator) do
n=n+1
Nodenames[n]=k
end
for k,v in pairs(Akku) do
n=n+1
Nodenames[n]=k
end
minetest.register_lbm({
label = "[techage] Power Conversion",
name = "techage:power",
nodenames = Nodenames,
run_at_every_load = true,
action = function(pos, node)
local mem = tubelib2.get_mem(pos)
migrate(pos, mem, node)
end
})
-------------------------------------------------- Migrate
local function pos_already_reached(pos)
local key = minetest.hash_node_position(pos)
if not Route[key] and NumNodes < MAX_NUM_NODES then
Route[key] = true
NumNodes = NumNodes + 1
return false
end
return true
end
local function min(val, max)
if val < 0 then return 0 end
if val > max then return max end
return val
end
local function accounting(pos, mem)
if mem.pwr_is_master then
-- calculate the primary and secondary supply and demand
mem.mst_supply1 = min(mem.mst_needed1 + mem.mst_needed2, mem.mst_available1)
mem.mst_demand1 = min(mem.mst_needed1, mem.mst_available1 + mem.mst_available2)
mem.mst_supply2 = min(mem.mst_demand1 - mem.mst_supply1, mem.mst_available2)
mem.mst_demand2 = min(mem.mst_supply1 - mem.mst_demand1, mem.mst_available1)
mem.mst_reserve = (mem.mst_available1 + mem.mst_available2) - mem.mst_needed1
if D.sts then D.dbg("needed = "..mem.mst_needed1.."/"..mem.mst_needed2..", available = "..mem.mst_available1.."/"..mem.mst_available2) end
if D.sts then D.dbg("supply = "..mem.mst_supply1.."/"..mem.mst_supply2..", demand = "..mem.mst_demand1.."/"..mem.mst_demand2..", reserve = "..mem.mst_reserve) end
end
end
local function connection_walk(pos, clbk)
local mem = tubelib2.get_mem(pos)
mem.interrupted_dirs = mem.interrupted_dirs or {}
if clbk then
clbk(pos, mem)
end
for out_dir,item in pairs(mem.connections or {}) do
if item.pos and not pos_already_reached(item.pos) and
not mem.interrupted_dirs[out_dir] then
connection_walk(item.pos, clbk)
end
end
end
-- if no power available
local function consumer_turn_off(pos, mem)
local pwr = PWR(pos)
if D.pwr then D.dbg("consumer_turn_off") end
if pwr and pwr.on_nopower then
pwr.on_nopower(pos, mem)
end
mem.pwr_state = NOPOWER
mem.pwr_power_provided_cnt = -1
end
local function consumer_turn_on(pos, mem)
local pwr = PWR(pos)
if D.pwr then D.dbg("consumer_turn_on") end
if pwr and pwr.on_power then
pwr.on_power(pos, mem)
end
mem.pwr_state = RUNNING
-- to avoid consumer starvation
mem.pwr_node_alive_cnt = (mem.pwr_cycle_time or 2)/2 + 1
end
-- determine one "generating" node as master (largest hash number)
local function determine_master(pos)
Route = {}
NumNodes = 0
pos_already_reached(pos)
local hash = 0
local master = nil
connection_walk(pos, function(pos, mem)
if (mem.pwr_node_alive_cnt or 0) >= 0 and
((mem.pwr_available or 0) > 0 or
(mem.pwr_available2 or 0) > 0) then -- active generator?
local new = minetest.hash_node_position(pos)
if hash <= new then
hash = new
master = pos
end
end
end)
return master
end
-- store master position on all network nodes
local function store_master(pos, master_pos)
Route = {}
NumNodes = 0
pos_already_reached(pos)
connection_walk(pos, function(pos, mem)
mem.pwr_master_pos = master_pos
mem.pwr_is_master = false
end)
end
local function handle_generator(mst_mem, mem, pos, power_available)
-- for next cycle
mst_mem.mst_available1 = (mst_mem.mst_available1 or 0) + power_available
-- current cycle
mst_mem.mst_supply1 = mst_mem.mst_supply1 or 0
if mst_mem.mst_supply1 < power_available then
mem.pwr_provided = mst_mem.mst_supply1
mst_mem.mst_supply1 = 0
else
mst_mem.mst_supply1 = mst_mem.mst_supply1 - power_available
mem.pwr_provided = power_available
end
end
local function handle_consumer(mst_mem, mem, pos, power_needed)
if mem.pwr_state == NOPOWER then
-- for next cycle
mst_mem.mst_needed1 = (mst_mem.mst_needed1 or 0) + power_needed
-- current cycle
if (mst_mem.mst_demand1 or 0) >= power_needed then
mst_mem.mst_demand1 = (mst_mem.mst_demand1 or 0) - power_needed
if D.sts then D.dbg("consumer_turn_on: mst_demand = "..mst_mem.mst_demand1..", node = "..minetest.get_node(pos).name) end
consumer_turn_on(pos, mem)
end
elseif mem.pwr_state == RUNNING then
-- for next cycle
mst_mem.mst_needed1 = (mst_mem.mst_needed1 or 0) + power_needed
-- current cycle
if (mst_mem.mst_demand1 or 0) >= power_needed then
mst_mem.mst_demand1 = (mst_mem.mst_demand1 or 0) - power_needed
-- small consumer like lamps are allowed to "use" the reserve
elseif power_needed <= 2 and (mst_mem.mst_reserve or 0) >= power_needed then
mst_mem.mst_reserve = (mst_mem.mst_reserve or 0) - power_needed
else -- no power available
mst_mem.mst_demand1 = 0
if D.sts then D.dbg("consumer_turn_off: mst_demand = "..mst_mem.mst_demand1..", node = "..minetest.get_node(pos).name) end
consumer_turn_off(pos, mem)
end
end
end
local function handle_secondary(mst_mem, mem, pos, provides, needed)
-- for next cycle
mst_mem.mst_available2 = (mst_mem.mst_available2 or 0) + provides
mst_mem.mst_needed2 = (mst_mem.mst_needed2 or 0) + needed
-- check as generator
mst_mem.mst_supply2 = mst_mem.mst_supply2 or 0
mst_mem.mst_demand2 = mst_mem.mst_demand2 or 0
if mst_mem.mst_supply2 > 0 then
local val = math.min(provides, mst_mem.mst_supply2)
mst_mem.mst_supply2 = mst_mem.mst_supply2 - val
mem.pwr_provided = val
-- check as consumer
elseif mst_mem.mst_demand2 > 0 then
local val = math.min(needed, mst_mem.mst_demand2)
mst_mem.mst_demand2 = mst_mem.mst_demand2 - val
mem.pwr_provided = -val
else
mem.pwr_provided = 0
end
end
local function trigger_nodes(mst_pos, mst_mem, dec)
Route = {}
NumNodes = 0
pos_already_reached(mst_pos)
connection_walk(mst_pos, function(pos, mem)
mem.pwr_node_alive_cnt = (mem.pwr_node_alive_cnt or 1) - dec
mem.pwr_power_provided_cnt = 2
if D.pwr then D.dbg("trigger_nodes", minetest.get_node(pos).name, mem.pwr_node_alive_cnt, mem.pwr_available2 or mem.pwr_available or mem.pwr_needed) end
if mem.pwr_node_alive_cnt >= 0 or mem.pwr_state == NOPOWER then
if mem.pwr_available then
handle_generator(mst_mem, mem, pos, mem.pwr_available)
elseif mem.pwr_needed then
handle_consumer(mst_mem, mem, pos, mem.pwr_needed)
elseif mem.pwr_available2 then
handle_secondary(mst_mem, mem, pos, mem.pwr_available2, mem.pwr_needed2)
end
end
end)
end
local function turn_off_nodes(mst_pos)
Route = {}
NumNodes = 0
pos_already_reached(mst_pos)
if D.pwr then D.dbg("turn_off_nodes") end
connection_walk(mst_pos, function(pos, mem)
if (mem.pwr_node_alive_cnt or -1) >= 0 then
if mem.pwr_needed then
consumer_turn_off(pos, mem)
end
end
end)
end
local function determine_new_master(pos, mem)
local was_master = mem.pwr_is_master
mem.pwr_is_master = false
local mpos = determine_master(pos)
store_master(pos, mpos)
if mpos then
local mmem = tubelib2.get_mem(mpos)
mmem.pwr_is_master = true
mmem.mst_num_nodes = NumNodes
elseif was_master then -- no master any more
-- delete data
mem.mst_supply1 = 0
mem.mst_supply2 = 0
mem.mst_reserve = 0
end
return was_master or mem.pwr_is_master
end
-- called from master position
local function power_distribution(pos, mem, dec)
if D.pwr then D.dbg("power_distribution") end
if mem.pwr_is_master then
mem.mst_needed1 = 0
mem.mst_needed2 = 0
mem.mst_available1 = 0
mem.mst_available2 = 0
end
trigger_nodes(pos, mem, dec or 0)
accounting(pos, mem)
end
--
-- Power API functions
--
-- To be called for each network change from any node
function techage.power.network_changed(pos, mem)
if D.pwr then D.dbg("network_changed") end
mem.pwr_node_alive_cnt = (mem.pwr_cycle_time or 2)/2 + 1
if determine_new_master(pos, mem) then -- new master?
power_distribution(pos, mem)
elseif not mem.pwr_master_pos then -- no master?
turn_off_nodes(pos)
elseif not next(mem.connections) then -- isolated?
if mem.pwr_needed then -- consumer?
consumer_turn_off(pos, mem)
end
end
end
--
-- Generator related functions
--
function techage.power.generator_start(pos, mem, available)
mem.pwr_node_alive_cnt = 2
mem.pwr_cycle_time = 2
mem.pwr_available = available
if determine_new_master(pos, mem) then -- new master
power_distribution(pos, mem)
end
end
function techage.power.generator_stop(pos, mem)
mem.pwr_node_alive_cnt = 0
mem.pwr_available = 0
if determine_new_master(pos, mem) then -- last available master
power_distribution(pos, mem)
end
end
function techage.power.generator_alive(pos, mem)
mem.pwr_node_alive_cnt = 2
if mem.pwr_is_master then
power_distribution(pos, mem, 1)
end
return mem.pwr_provided or 0
end
--
-- Consumer related functions
--
-- this is more a try to start, the start will be performed by consumer_turn_on()
function techage.power.consumer_start(pos, mem, cycle_time, needed)
mem.pwr_cycle_time = cycle_time
mem.pwr_power_provided_cnt = 0 -- must be zero!
mem.pwr_node_alive_cnt = 2
mem.pwr_needed = needed
mem.pwr_state = NOPOWER
end
function techage.power.consumer_stop(pos, mem)
mem.pwr_node_alive_cnt = 0
mem.pwr_needed = 0
mem.pwr_state = STOPPED
end
function techage.power.consumer_alive(pos, mem)
if D.pwr then D.dbg("consumer_alive", mem.pwr_power_provided_cnt, mem.pwr_cycle_time) end
mem.pwr_node_alive_cnt = (mem.pwr_cycle_time or 2)/2 + 1
mem.pwr_power_provided_cnt = (mem.pwr_power_provided_cnt or 0) - 1
if mem.pwr_power_provided_cnt < 0 and mem.pwr_state == RUNNING then
consumer_turn_off(pos, mem)
end
end
-- Lamp related function to speed up the turn on
function techage.power.power_available(pos, mem, needed)
if mem.pwr_master_pos and (mem.pwr_power_provided_cnt or 0) > 0 then
mem = tubelib2.get_mem(mem.pwr_master_pos)
if (mem.mst_reserve or 0) >= needed then
mem.mst_reserve = (mem.mst_reserve or 0) - needed
return true
end
end
return false
end
-- Power terminal function
function techage.power.power_accounting(pos, mem)
if mem.pwr_master_pos and (mem.pwr_power_provided_cnt or 0) > 0 then
mem.pwr_power_provided_cnt = (mem.pwr_power_provided_cnt or 0) - 1
mem = tubelib2.get_mem(mem.pwr_master_pos)
return {
prim_available = mem.mst_available1 or 0,
sec_available = mem.mst_available2 or 0,
prim_needed = mem.mst_needed1 or 0,
sec_needed = mem.mst_needed2 or 0,
num_nodes = mem.mst_num_nodes or 0,
}
end
return {
prim_available = 0,
sec_available = 0,
prim_needed = 0,
sec_needed = 0,
num_nodes = 0,
}
end
--
-- Akku related functions
--
function techage.power.secondary_start(pos, mem, available, needed)
mem.pwr_node_alive_cnt = 2
mem.pwr_could_provide = available
mem.pwr_could_need = needed
if determine_new_master(pos, mem) then -- new master
power_distribution(pos, mem)
end
end
function techage.power.secondary_stop(pos, mem)
mem.pwr_node_alive_cnt = 0
mem.pwr_could_provide = 0
mem.pwr_could_need = 0
if determine_new_master(pos, mem) then -- last available master
power_distribution(pos, mem)
end
end
function techage.power.secondary_alive(pos, mem, capa_curr, capa_max)
if D.pwr then D.dbg("secondary_alive") end
if capa_curr >= capa_max then
mem.pwr_available2, mem.pwr_needed2 = mem.pwr_could_provide, 0 -- can provide only
elseif capa_curr <= 0 then
mem.pwr_available2, mem.pwr_needed2 = 0, mem.pwr_could_need -- can deliver only
else
mem.pwr_available2, mem.pwr_needed2 = mem.pwr_could_provide, mem.pwr_could_need
end
mem.pwr_node_alive_cnt = 2
if mem.pwr_is_master then
if D.pwr then D.dbg("secondary_alive is master") end
power_distribution(pos, mem, 1)
end
return mem.pwr_provided or 0
end