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|
-- interlocking/database.lua
-- saving the location of TCB's, their neighbors and their state
--[[
The interlocking system is based on track circuits.
Track circuit breaks must be manually set by the user. Signals must be assigned to track circuit breaks and to a direction(connid).
To simplify the whole system, there is no overlap.
== Trains ==
Trains always occupy certain track circuits. These are shown red in the signalbox view (TRAIN occupation entry).
== Database storage ==
The things that are actually saved are the Track Circuit Breaks. Each TCB holds a list of the TCBs that are adjacent in each direction.
TC occupation/state is then saved inside each (TCB,Direction) and held in sync across all TCBs adjacent to this one. If something should not be in sync,
all entries are merged to perform the most restrictive setup.
== Traverser function ==
To determine and update the list of neighboring TCBs, we need a traverser function.
It will start at one TCB in a specified direction (connid) and use get_adjacent_rail to crawl along the track. When encountering a turnout or a crossing,
it needs to branch(call itself recursively) to find all required TCBs. Those found TCBs are then saved in a list as tuples (TCB,Dir)
In the last step, they exchange their neighbors.
== TC states ==
A track circuit does not have a state as such, but has more or less a list of "reservations"
type can be one of these:
TRAIN See Trains obove
ROUTE Route set from a signal, but no train has yet passed that signal.
Not implemented (see note by reversible): OWNED - former ROUTE segments that a train has begun passing (train_id assigned)
- Space behind a train up to the next signal, when a TC is set as REVERSIBLE
Certain TCs can be marked as "allow call-on".
== Route setting: ==
Routes are set from a signal (the entry signal) to another signal facing the same direction (the exit signal)
Remember that signals are assigned to a TCB and a connid.
Whenever this is done, the following track circuits are set "reserved" by the train by saving the entry signal's ID:
- all TCs on the direct way of the route - set as ROUTE
Route setting fails whenever any TC that we want to set ROUTE to is already set ROUTE or TRAIN from another signal (except call-on, see below)
Apart from this, we need to set turnouts
- Turnouts on the track are set held as ROUTE
- Turnouts that purpose as flank protection are set held as FLANK (NOTE: left as an idea for later, because it's not clear how to do this properly without an engineer)
Note: In SimSig, it is possible to set a route into an still occupied section on the victoria line sim. (at the depot exit at seven sisters), although
there are still segments set ahead of the first train passing, remaining from another route.
Because our system will be able to remember "requested routes" and set them automatically once ready, this is not necessary here.
== Call-On/Multiple Trains ==
It will be necessary to join and split trains using call-on routes. A call-on route may be set when:
- there are no ROUTE reservations
- there are TRAIN reservations only inside TCs that have "allow call-on" set
== TC Properties ==
Note: Reversible property will not be implemented, assuming everything as non-rev.
This is sufficient to cover all use cases, and is done this way in reality.
REVERSIBLE - Whether trains are allowed to reverse while on track circuit
This property is supposed to be set for station tracks, where there is a signal at each end, and for sidings.
It should in no case be set for TCs covering turnouts, or for main running lines.
When a TC is not set as reversible, the OWNED status is cleared from the TC right after the train left it,
to allow other trains to pass it.
If it is set reversible, interlocking will keep the OWNED state behind the train up to the next signal, clearing it
as soon as the train passes another signal or enters a non-reversible section.
CALL_ON_ALLOWED - Whether this TC being blocked (TRAIN or ROUTE) does not prevent shunt routes being set through this TC
== More notes ==
- It may not be possible to switch turnouts when their TC has any state entry
== Route releasing (TORR) ==
A train passing through a route happens as follows:
Route set from entry to exit signal
Train passes entry signal and enters first TC past the signal
-> Route from signal cleared (TCs remain locked)
-> ROUTE status of first TC past signal cleared
Train continues along the route.
Whenever train leaves a TC
-> Clearing any routes set from this TC outward recursively - see "Reversing problem"
Whenever train enters a TC
-> Clear route status from the just entered TC
== Reversing Problem ==
Encountered at the Royston simulation in SimSig. It is solved there by imposing a time limit on the set route. Call-on routes can somehow be set anyway.
Imagine this setup: (T=Train, R=Route, >=in_dir TCB)
O-| Royston P2 |-O
T->---|->RRR-|->RRR-|--
Train T enters from the left, the route is set to the right signal. But train is supposed to reverse here and stops this way:
O-| Royston P2 |-O
------|-TTTT-|->RRR-|--
The "Route" on the right is still set. Imposing a timeout here is a thing only professional engineers can determine, not an algorithm.
O-| Royston P2 |-O
<-T---|------|->RRR-|--
The train has left again, while route on the right is still set.
So, we have to clear the set route when the train has left the left TC.
This does not conflict with call-on routes, because both station tracks are set as "allow call-on"
Because none of the routes extends past any non-call-on sections, call-on route would be allowed here, even though the route
is locked in opposite direction at the time of routesetting.
Another case of this:
--TTT/--|->RRR--
The / here is a non-interlocked turnout (to a non-frequently used siding). For some reason, there is no exit node there,
so the route is set to the signal at the right end. The train is taking the exit to the siding and frees the TC, without ever
having touched the right TC.
]]--
local TRAVERSER_LIMIT = 100
local ildb = {}
local track_circuit_breaks = {}
local track_sections = {}
function ildb.load(data)
if not data then return end
if data.tcbs then
track_circuit_breaks = data.tcbs
end
if data.ts then
track_sections = data.ts
end
end
function ildb.save()
return {tcbs = track_circuit_breaks, ts=track_sections}
end
--
--[[
TCB data structure
{
[1] = { -- Variant: with adjacent TCs.
ts_id = <id> -- ID of the assigned track section
signal = <pos> -- optional: when set, routes can be set from this tcb/direction and signal
-- aspect will be set accordingly.
routetar = <signal> -- Route set from this signal. This is the entry that is cleared once
-- train has passed the signal. (which will set the aspect to "danger" again)
route_committed = <boolean> -- When setting/requesting a route, routetar will be set accordingly,
-- while the signal still displays danger and nothing is written to the TCs
-- As soon as the route can actually be set, all relevant TCs and turnouts are set and this field
-- is set true, clearing the signal
},
[2] = { -- Variant: end of track-circuited area (initial state of TC)
ts_id = nil, -- this is the indication for end_of_interlocking
section_free = <boolean>, --this can be set by an exit node via mesecons or atlatc,
-- or from the tc formspec.
}
}
Track section
[id] = {
name = "Some human-readable name"
tc_breaks = { <signal specifier>,... } -- Bounding TC's (signal specifiers)
-- Can be direct ends (auto-detected), conflicting routes or TCBs that are too far away from each other
route = {origin = <signal>, from_tcb = <index>}
-- Set whenever a route has been set through this TC. It saves the origin tcb id and side
-- (=the origin signal). index is the TCB of the route origin
trains = {<id>, ...} -- Set whenever a train (or more) reside in this TC
}
Signal specifier (sigd) (a pair of TCB/Side):
{p = <pos>, s = <1/2>}
]]
--
function ildb.create_tcb(pos)
local new_tcb = {
[1] = {},
[2] = {},
}
local pts = advtrains.roundfloorpts(pos)
if not track_circuit_breaks[pts] then
track_circuit_breaks[pts] = new_tcb
return true
else
return false
end
end
function ildb.get_tcb(pos)
local pts = advtrains.roundfloorpts(pos)
return track_circuit_breaks[pts]
end
function ildb.get_tcbs(sigd)
local tcb = ildb.get_tcb(sigd.p)
if not tcb then return nil end
return tcb[sigd.s]
end
function ildb.create_ts(sigd)
local tcbs = ildb.get_tcbs(sigd)
local id = advtrains.random_id()
while track_sections[id] do
id = advtrains.random_id()
end
track_sections[id] = {
name = "Section "..id,
tc_breaks = { sigd }
}
tcbs.ts_id = id
end
function ildb.get_ts(id)
return track_sections[id]
end
-- various helper functions handling sigd's
local function sigd_equal(sigd, cmp)
return vector.equals(sigd.p, cmp.p) and sigd.s==cmp.s
end
local function insert_sigd_nodouble(list, sigd)
for idx, cmp in pairs(list) do
if sigd_equal(sigd, cmp) then
return
end
end
table.insert(list, sigd)
end
-- This function will actually handle the node that is in connid direction from the node at pos
-- so, this needs the conns of the node at pos, since these are already calculated
local function traverser(found_tcbs, pos, conns, connid, count)
local adj_pos, adj_connid, conn_idx, nextrail_y, next_conns = advtrains.get_adjacent_rail(pos, conns, connid, advtrains.all_tracktypes)
if not adj_pos then
-- end of track
return
end
-- look whether there is a TCB here
if #next_conns == 2 then --if not, don't even try!
local tcb = ildb.get_tcb(adj_pos)
if tcb then
-- done with this branch
atdebug("Traverser found tcb at",adj_pos, adj_connid)
insert_sigd_nodouble(found_tcbs, {p=adj_pos, s=adj_connid})
return
end
end
-- recursion abort condition
if count > TRAVERSER_LIMIT then
atdebug("Traverser hit counter at",adj_pos, adj_connid)
return true
end
-- continue traversing
local counter_hit = false
for nconnid, nconn in ipairs(next_conns) do
if adj_connid ~= nconnid then
counter_hit = counter_hit or traverser(found_tcbs, adj_pos, next_conns, nconnid, count + 1, hit_counter)
end
end
return counter_hit
end
-- Merges the TS with merge_id into root_id and then deletes merge_id
local function merge_ts(root_id, merge_id)
local rts = ildb.get_ts(root_id)
local mts = ildb.get_ts(merge_id)
-- cobble together the list of TCBs
for _, msigd in ipairs(mts.tc_breaks) do
local tcbs = ildb.get_tcbs(msigd)
if tcbs then
insert_sigd_nodouble(rts.tc_breaks, msigd)
tcbs.ts_id = root_id
end
advtrains.interlocking.show_tcb_marker(msigd.p)
end
-- done
track_sections[merge_id] = nil
end
-- TODO temporary
local lntrans = { "A", "B" }
local function sigd_to_string(sigd)
return minetest.pos_to_string(sigd.p).." / "..lntrans[sigd.s]
end
-- Check for near TCBs and connect to their TS if they have one, and syncs their data.
function ildb.sync_tcb_neighbors(pos, connid)
local found_tcbs = { {p = pos, s = connid} }
local node_ok, conns, rhe = advtrains.get_rail_info_at(pos, advtrains.all_tracktypes)
if not node_ok then
error("update_tcb_neighbors but node is NOK: "..minetest.pos_to_string(pos))
end
atdebug("Traversing from ",pos, connid)
local counter_hit = traverser(found_tcbs, pos, conns, connid, 0, hit_counter)
local ts_id
local list_eoi = {}
local list_ok = {}
local list_mismatch = {}
local ts_to_merge = {}
for idx, sigd in pairs(found_tcbs) do
local tcbs = ildb.get_tcbs(sigd)
if not tcbs.ts_id then
atdebug("Sync: put",sigd_to_string(sigd),"into list_eoi")
table.insert(list_eoi, sigd)
elseif not ts_id and tcbs.ts_id then
if not ildb.get_ts(tcbs.ts_id) then
atwarn("Track section database is inconsistent, there's no TS with ID=",tcbs.ts_id)
tcbs.ts_id = nil
table.insert(list_eoi, sigd)
else
atdebug("Sync: put",sigd_to_string(sigd),"into list_ok")
ts_id = tcbs.ts_id
table.insert(list_ok, sigd)
end
elseif ts_id and tcbs.ts_id and tcbs.ts_id ~= ts_id then
atwarn("Track section database is inconsistent, sections share track!")
atwarn("Merging",tcbs.ts_id,"into",ts_id,".")
table.insert(list_mismatch, sigd)
table.insert(ts_to_merge, tcbs.ts_id)
end
end
if ts_id then
local ts = ildb.get_ts(ts_id)
for _, sigd in ipairs(list_eoi) do
local tcbs = ildb.get_tcbs(sigd)
tcbs.ts_id = ts_id
table.insert(ts.tc_breaks, sigd)
advtrains.interlocking.show_tcb_marker(sigd.p)
end
for _, mts in ipairs(ts_to_merge) do
merge_ts(ts_id, mts)
end
end
end
function ildb.link_track_sections(merge_id, root_id)
if merge_id == root_id then
return
end
merge_ts(root_id, merge_id)
end
function ildb.remove_from_interlocking(sigd)
local tcbs = ildb.get_tcbs(sigd)
if tcbs.ts_id then
local tsid = tcbs.ts_id
local ts = ildb.get_ts(tsid)
if not ts then
tcbs.ts_id = nil
return
end
-- remove entry from the list
local idx = 1
while idx <= #ts.tc_breaks do
local cmp = ts.tc_breaks[idx]
if sigd_equal(sigd, cmp) then
table.remove(ts.tc_breaks, idx)
else
idx = idx + 1
end
end
tcbs.ts_id = nil
--ildb.sync_tcb_neighbors(sigd.p, sigd.s)
if #ts.tc_breaks == 0 then
track_sections[tsid] = nil
end
end
advtrains.interlocking.show_tcb_marker(sigd.p)
end
function ildb.remove_tcb(pos)
for connid=1,2 do
ildb.remove_from_interlocking({p=pos, s=connid})
end
local pts = advtrains.roundfloorpts(pos)
track_circuit_breaks[pts] = nil
end
function ildb.dissolve_ts(ts_id)
local ts = ildb.get_ts(ts_id)
local tcbr = advtrains.merge_tables(ts.tc_breaks)
for _,sigd in ipairs(tcbr) do
ildb.remove_from_interlocking(sigd)
end
-- Note: ts gets removed in the moment of the removal of the last TCB.
end
advtrains.interlocking.db = ildb
|