-- Signal API implementation local F = advtrains.formspec local signal = {} signal.MASP_HALT = { name = "_halt", halt = true, } signal.MASP_DEFAULT = { name = "_default", default = true, } signal.ASPI_HALT = { main = 0, shunt = false, } signal.ASPI_FREE = { main = -1, shunt = false, proceed_as_main = true, } --[[ Implementation plan orwell 2024-01-28: Most parts of ywang's implementation are fine, especially I like the formspecs. But I would like to change a few aspects (no pun intended) of this. - Signal gets distant assigned via field in signal aspect table (instead of explicitly) - Signal speed/shunt are no longer free-text but rather they need to be predefined in the node definition To do this: Differentiation between: == Main Aspect == This is what a signal is assigned by either the route system or the user. It is a string key which has an appropriate entry in the node definition (where it has a description assigned) The signal mod defines a function to set a signal to the most appropriate aspect. This function gets a) the main aspect table (straight from node def) b) the distant signal's aspect group name & aspect table == Aspect == One concrete combination of lights/shapes that a signal signal shows. Handling these is at the discretion of the signal mod defining the signal, and they are typically combinations of main aspect and distant aspect Example: - A Ks signal has the main_aspect="proceed_12" set for a route - The signal at the end of the route shows main_aspect="proceed_8", advtrains also passes on that this means {main=8, shunt=false} - The ndef.afunction(pos, node, main_aspect, rem_aspect, rem_aspinfo) determines that the signal should now show blinking green with main indicator 12 and dst indicator 8, and sets the nodes accordingly. This function can now return the Aspect Info table, which will be cached by advtrains until the aspect changes again and will be used when a train approaches the signal. If nil is returned, then the aspect will be queried next time by calling ndef.advtrains.get_aspect_info(pos) Note that once apply_aspect returns, there is no need for advtrains anymore to query the aspect info. When the signal, for any reason, wants to change its aspect by itself *without* going through the signal API then it should update the aspect info cache by calling advtrains.interlocking.signal.update_aspect_info(pos) Apply_aspect may also receive the special main aspect { name = "_halt", halt = true }. It usually means that the signal is not assigned to anything particular, and it should cause the signal to show its most restrictive aspect. Typically it is a halt aspect, but e.g. for distant-only signals this would be "expect stop". A special case occurs for pure distant signals: Such signals must set apply_aspect, but must not set main_aspects. Behavior is as follows: - Signal is uninitialized, distant signal is not assigned to a main signal, or no route is set: main_aspect == { name = "_halt", halt = true } and rem_aspect == nil - A remote main signal is assigned (either by user or by route): main_aspect is always { name = "_default" } and rem_aspect / rem_aspinfo give the correct information Main aspect names starting with underscore (e.g. "_default") are reserved and must not be used! == Aspect Info == The actual signal aspect in the already-known format. This is what the trains use to determine halt/proceed and speed. asp = { main = 0 (halt) / -1 (max speed) / false (no info) / (speed limit) shunt = true (shunt free) / false (shunt not free) proceed_as_main = true (shunt move can proceed and become train move when main!=0) / false (no) dst = speed of the remote signal (like main, informative character, not actually used) } Node definition of signals: - The signal needs some logic to figure out, for each combination of its own aspect group and the distant signal's aspect, what aspect info it can/will show. ndef.advtrains = { main_aspects = { { name = "proceed" description = "Proceed at full speed", } { name = "reduced" description = "Proceed at reduced speed", } } -- This list is mainly for the selection dialog. Order of entries determines list order in the dropdown. -- Some fields have special meaning: -- name: A unique key to identify the main aspect. Might be required by some code. -- description: Text shown in UI dropdown -- Node can set any other fields at its discretion. They are not touched. -- Note: Pure distant signals (that cannot show halt) should NOT have a main_aspects table. -- For these signals no main aspect selection UI is shown and they cannot be startpoint of a route apply_aspect = function(pos, node, main_aspect, rem_aspect, rem_aspinfo) -- set the node to show the desired aspect -- called by advtrains when this signal's aspect group or the remote signal's aspect changes -- main_aspect is never nil, but can be one of the special aspects { halt = true } or { default = true } -- MAY return the aspect_info. If it returns nil then get_aspect_info will be queried at a later point. get_aspect_info(pos, main_aspect) -- Returns the aspect info table (main, shunt, dst etc.) distant_support = true or false -- If true, signal is considered in distant signalling. If false or nil, rem_aspect and rem_aspinfo are never set. route_role = one of "main", "main_distant", "shunt", "distant", "distant_repeater", "end" -- Determines how the signal behaves when routes are set. Only in effect when signal is assigned to a TCB. -- main: The signal is a possible endpoint for a train move route. Distant signals before it refer to it. -- shunt: The signal is a possible endpoint for a shunt move route. Ignored for distant signals. -- distant, distant_repeater: The next signal with role="main" is set as the remote signal. main_aspects may be undefined, the main aspect passed to apply_aspect is a dummy one in this case. -- distant: if more than one distant signal is before a main signal, only the last one is assigned (but any number of distant_repeater signals are allowed) -- main_distant: Combination of main and distant - like "main", but additionally gets assigned to the next main like a "distant" -- end: like main, but signifies that it marks an end of track and trains cannot continue further. (currently no practical implications above main) } == Nomenclature == The distant/main relation is named as follows: V M =====>====> Main signal (main) always refers to the signal that is in focus right now (even if that is a distant-only signal) From the standpoint of M, V is the distant (dst) signal. M does not need to concern itself with V's aspect but needs to notify V when it changes From the standpoint of V, M is the remote (rem) signal. V needs to show an aspect that matches its remote signal M == Criteria for which signals are eligible for routes == All signals must define: - get_aspect_info() Signals that can be assigned to a TCB must satisfy: - apply_aspect() defined Signals that are possible start and end points for a route must satisfy: - main_aspects defined (note, pure distant signals should therefore not define main_aspects) ]] -- Database -- Signal Aspect store -- Stores for each signal the main aspect and other info, like the assigned remote signal -- [signal encodePos] = { main = , [remote = encodedPos] } -- main is a string: "named aspect" is looked up in the main_aspects table of the ndef -- main is a table: this table directly is the main aspect (used for advanced signals with additional lights/indicators) signal.aspects = {} -- Distant signal notification. Records for each signal the distant signals that refer to it -- Note: this mapping is weak. Needs always backreference check. -- [signal encodePos] = { [distant signal encodePos] = true } signal.distant_refs = {} function signal.load(data) signal.aspects = data.aspects or {} -- rebuild distant_refs after load signal.distant_refs = {} for main, aspt in pairs(signal.aspects) do if aspt.remote then if not signal.distant_refs[aspt.remote] then signal.distant_refs[aspt.remote] = {} end signal.distant_refs[aspt.remote][main] = true end end end function signal.save(data) data.aspects = signal.aspects end -- Set a signal's aspect. -- Signal aspects should only be set through this function. It takes care of: -- - Storing the main aspect and dst pos for this signal permanently (until next change) -- - Assigning the distant signal for this signal -- - Calling apply_aspect() in the signal's node definition to make the signal show the aspect -- - Calling apply_aspect() again whenever the remote signal changes its aspect -- - Notifying this signal's distant signals about changes to this signal (unless skip_dst_notify is specified) -- main_asp: either a string (==name in ndef.advtrains.main_aspects) or the main aspect table directly (for advanced signals) function signal.set_aspect(pos, main_asp, rem_pos, skip_dst_notify) -- safeguard for the two integrated aspects (these two must be passed as string key) if type(main_asp)=="table" and (main_asp.name=="_default" or main_asp.name=="_halt") then error("MASP_HALT and MASP_DEFAULT must be passed via string keys _halt or _default, not as tables!") end local main_pts = advtrains.encode_pos(pos) local old_tbl = signal.aspects[main_pts] local old_remote = old_tbl and old_tbl.remote local new_remote = rem_pos and advtrains.encode_pos(rem_pos) -- if remote has changed, unregister from old remote if old_remote and old_remote~=new_remote and signal.distant_refs[old_remote] then --atdebug("unregister old remote: ",old_remote,"from",main_pts) signal.distant_refs[old_remote][main_pts] = nil end signal.aspects[main_pts] = { main = main_asp, remote = new_remote } -- apply aspect on main signal, this also checks new_remote signal.reapply_aspect(main_pts) -- notify my distants about this change (with limit 2) if not skip_dst_notify then signal.notify_distants_of(main_pts, 2) end end function signal.clear_aspect(pos, skip_dst_notify) local main_pts = advtrains.encode_pos(pos) local old_tbl = signal.aspects[main_pts] local old_remote = old_tbl and old_tbl.remote -- unregister from old remote if old_remote then signal.distant_refs[old_remote][main_pts] = nil end signal.aspects[main_pts] = nil -- apply aspect on main signal, this also checks new_remote signal.reapply_aspect(main_pts) -- notify my distants about this change (with limit 2) if not skip_dst_notify then signal.notify_distants_of(main_pts, 2) end end -- Clear any info about aspects from this signal, without resetting/reapplying the aspect. -- Supposed to be used for legacy on-off signals when the on-off toggle is used function signal.unregister_aspect(pos) local main_pts = advtrains.encode_pos(pos) local old_tbl = signal.aspects[main_pts] local old_remote = old_tbl and old_tbl.remote -- unregister from old remote if old_remote then signal.distant_refs[old_remote][main_pts] = nil end signal.aspects[main_pts] = nil end -- Notify distant signals of main_pts of a change in the aspect of this signal -- function signal.notify_distants_of(main_pts, limit) --atdebug("notify_distants_of",advtrains.decode_pos(main_pts),"limit",limit) if limit <= 0 then return end local dstrefs = signal.distant_refs[main_pts] --atdebug("dstrefs",dstrefs,"") if dstrefs then for dst,_ in pairs(dstrefs) do -- ensure that the backref is still valid local dst_asp = signal.aspects[dst] if dst_asp and dst_asp.remote == main_pts then signal.reapply_aspect(dst) signal.notify_distants_of(dst, limit - 1) else atwarn("Distant signal backref is not purged: main =",main_pts,", distant =",dst,", remote =",dst_asp.remote,"") end end end end function signal.notify_trains(pos) local ipts, iconn = advtrains.interlocking.db.get_ip_by_signalpos(pos) if not ipts then return end local ipos = minetest.string_to_pos(ipts) -- FIXME: invalidate_all_paths_ahead does not appear to always work as expected --advtrains.invalidate_all_paths_ahead(ipos) minetest.after(0, advtrains.invalidate_all_paths, ipos) end -- Update waiting trains and distant signals about a changed signal aspect -- Must be called when a signal's aspect changes through some other means -- and not via the signal mechanism function signal.notify_on_aspect_changed(pos, skip_dst_notify) signal.notify_trains(pos) if not skip_dst_notify then signal.notify_distants_of(advtrains.encode_pos(pos), 2) end end -- Gets the stored main aspect and distant signal position for this signal -- This information equals the information last passed to set_aspect -- It does not take into consideration the actual speed signalling, please use -- get_aspect_info() for this -- pos: the position of the signal -- returns: main_aspect, dst_pos function signal.get_aspect(pos) local aspt = signal.aspects[advtrains.encode_pos(pos)] local ma,dp = signal.get_aspect_internal(pos, aspt) return ma, dp and advtrains.decode_pos(dp) end local function cache_mainaspects(ndefat) ndefat.main_aspects_lookup = {} for _,ma in ipairs(ndefat.main_aspects) do ndefat.main_aspects_lookup[ma.name] = ma end ndefat.main_aspects_lookup[signal.MASP_HALT.name] = signal.MASP_HALT.name -- halt is always defined ndefat.main_aspects_lookup[signal.MASP_DEFAULT.name] = ndefat.main_aspects[1] -- default is the first one end -- gets the main aspect. resolves named aspects to aspect table on demand function signal.get_aspect_internal(pos, aspt) -- look up node and nodedef local node = advtrains.ndb.get_node_or_nil(pos) local ndef = node and minetest.registered_nodes[node.name] if not aspt then -- oh, no main aspect, nevermind return signal.MASP_HALT, nil, node, ndef end local ndefat = ndef.advtrains or {} local masp = aspt.main or signal.MASP_HALT if type(masp) == "string" then if masp=="_halt" then masp = signal.MASP_HALT elseif masp=="_default" and not ndefat.main_aspects then -- case is fine, distant only signal masp = signal.MASP_DEFAULT else assert(ndefat.main_aspects, "With named aspects, node "..node.name.." needs advtrains.main_aspects table!") -- resolve the main aspect from the mainaspects table if not ndefat.main_aspects_lookup then cache_mainaspects(ndefat) end masp = ndefat.main_aspects_lookup[aspt.main] or signal.MASP_DEFAULT end end -- return whatever the main aspect is return masp, aspt.remote, node, ndef end -- For the signal at pos, get the "aspect info" table. This contains the speed signalling information at this location function signal.get_aspect_info(pos) -- get aspect internal local aspt = signal.aspects[advtrains.encode_pos(pos)] local masp, remote, node, ndef = signal.get_aspect_internal(pos, aspt) -- call into ndef if ndef.advtrains and ndef.advtrains.get_aspect_info then local ai = ndef.advtrains.get_aspect_info if type(ai)=="function" then ai = ai(pos, masp) end if type(ai)=="table" then --atdebug(pos,"aspectinfo",ai) return ai else error("For node "..node.name..": ndef.advtrains.get_aspect_info must be function or table") end end end -- Called when either this signal has changed its main aspect -- or when this distant signal's currently assigned main signal has changed its aspect -- It retrieves the signal's main aspect and aspect info and calls apply_aspect of the node definition -- to update the signal's appearance and aspect info -- pts: The signal position to update as encoded_pos -- returns: the return value of the nodedef call which may be aspect_info function signal.reapply_aspect(pts) -- get aspt local aspt = signal.aspects[pts] --atdebug("reapply_aspect",advtrains.decode_pos(pts),"aspt",aspt) local pos = advtrains.decode_pos(pts) -- resolve mainaspect table by name local masp, remote, node, ndef = signal.get_aspect_internal(pos, aspt) -- if we have remote, resolve remote local rem_masp, rem_aspi if remote then -- register in remote signal as distant if not signal.distant_refs[remote] then signal.distant_refs[remote] = {} end signal.distant_refs[remote][pts] = true local rem_aspt = signal.aspects[remote] --atdebug("resolving remote",advtrains.decode_pos(remote),"aspt",rem_aspt) local rem_pos = advtrains.decode_pos(remote) rem_masp, _, _, rem_ndef = signal.get_aspect_internal(rem_pos, rem_aspt) if rem_masp then if rem_ndef.advtrains and rem_ndef.advtrains.get_aspect_info then rem_aspi = rem_ndef.advtrains.get_aspect_info(rem_pos, rem_masp) end end end -- call into ndef --atdebug("applying to",pos,": main_asp",masp,"rem_masp",rem_masp,"rem_aspi",rem_aspi) if ndef.advtrains and ndef.advtrains.apply_aspect then ndef.advtrains.apply_aspect(pos, node, masp, rem_masp, rem_aspi) end -- notify trains signal.notify_trains(pos) end -- Update this signal's aspect based on the set route -- function signal.update_route_aspect(tcbs, skip_dst_notify) if tcbs.signal then local asp = tcbs.route_aspect or "_halt" local rem = tcbs.route_remote signal.set_aspect(tcbs.signal, asp, rem, skip_dst_notify) end end -- Returns how capable the signal is with regards to aspect setting -- 0: not a signal at all -- 1: signal has get_aspect_info() but the aspect is not variable (e.g. a sign) -- 2: signal has apply_aspect() but does not have main aspects (e.g. a pure distant signal) -- 3: signal has main signal role but can only ever display a halt aspect, such as a bumper (can be endpoint, but not startpoint, of a route) -- 4: Full capabilities, signal has main aspects and can be used as main/shunt signal (can be start/endpoint of a route) function signal.get_signal_cap_level(pos) local node = advtrains.ndb.get_node_or_nil(pos) local ndef = node and minetest.registered_nodes[node.name] local ndefat = ndef and ndef.advtrains if ndefat and ndefat.get_aspect_info then if ndefat.apply_aspect then if ndefat.main_aspects then -- if the table contains anything, 4, otherwise 3 for _,_ in pairs(ndefat.main_aspects) do return 4 end return 3 end return 2 end return 1 end return 0 end ---------------- function signal.can_dig(pos, player) local sigd = advtrains.interlocking.db.get_sigd_for_signal(pos) if sigd then -- check privileges if not player or not minetest.check_player_privs(player:get_player_name(), "interlocking") then if not player then -- intermediate debug to uncover hard-to-find bugz atdebug("advtrains.interlocking.signal.can_dig(",pos,") called with player==nil!") end return false end -- check if route is set local tcbs = advtrains.interlocking.db.get_tcbs(sigd) if tcbs.routeset then return false end end return true end function signal.after_dig(pos, oldnode, oldmetadata, player) -- unassign signal if necessary local sigd = advtrains.interlocking.db.get_sigd_for_signal(pos) if sigd then advtrains.interlocking.db.unassign_signal_for_tcbs(sigd) minetest.chat_send_player(player:get_player_name(), "Signal has been unassigned. Name and routes are kept for reuse.") end -- TODO clear influence point advtrains.interlocking.signal.unregister_aspect(pos) end function signal.on_rightclick(pos, node, player, itemstack, pointed_thing) local pname = player:get_player_name() local control = player:get_player_control() advtrains.interlocking.show_signal_form(pos, node, pname, control.aux1) end advtrains.interlocking.signal = signal