local comms = require("scada-common.comms")
local const = require("scada-common.constants")
local log = require("scada-common.log")
local ppm = require("scada-common.ppm")
local rsio = require("scada-common.rsio")
local types = require("scada-common.types")
local util = require("scada-common.util")
local themes = require("graphics.themes")
local databus = require("reactor-plc.databus")
local plc = {}
local RPS_TRIP_CAUSE = types.RPS_TRIP_CAUSE
local PROTOCOL = comms.PROTOCOL
local DEVICE_TYPE = comms.DEVICE_TYPE
local ESTABLISH_ACK = comms.ESTABLISH_ACK
local RPLC_TYPE = comms.RPLC_TYPE
local MGMT_TYPE = comms.MGMT_TYPE
local AUTO_ACK = comms.PLC_AUTO_ACK
local RPS_LIMITS = const.RPS_LIMITS
-- I sure hope the devs don't change this error message, not that it would have safety implications
-- I wish they didn't change it to be like this
local PCALL_SCRAM_MSG = "Scram requires the reactor to be active."
local PCALL_START_MSG = "Reactor is already active."
---@type plc_config
local config = {}
plc.config = config
-- load the PLC configuration
function plc.load_config()
if not settings.load("/reactor-plc.settings") then return false end
config.Networked = settings.get("Networked")
config.UnitID = settings.get("UnitID")
config.EmerCoolEnable = settings.get("EmerCoolEnable")
config.EmerCoolSide = settings.get("EmerCoolSide")
config.EmerCoolColor = settings.get("EmerCoolColor")
config.SVR_Channel = settings.get("SVR_Channel")
config.PLC_Channel = settings.get("PLC_Channel")
config.ConnTimeout = settings.get("ConnTimeout")
config.TrustedRange = settings.get("TrustedRange")
config.AuthKey = settings.get("AuthKey")
config.LogMode = settings.get("LogMode")
config.LogPath = settings.get("LogPath")
config.LogDebug = settings.get("LogDebug")
config.FrontPanelTheme = settings.get("FrontPanelTheme")
config.ColorMode = settings.get("ColorMode")
local cfv = util.new_validator()
cfv.assert_type_bool(config.Networked)
cfv.assert_type_int(config.UnitID)
cfv.assert_type_bool(config.EmerCoolEnable)
if config.Networked == true then
cfv.assert_channel(config.SVR_Channel)
cfv.assert_channel(config.PLC_Channel)
cfv.assert_type_num(config.ConnTimeout)
cfv.assert_min(config.ConnTimeout, 2)
cfv.assert_type_num(config.TrustedRange)
cfv.assert_min(config.TrustedRange, 0)
cfv.assert_type_str(config.AuthKey)
if type(config.AuthKey) == "string" then
local len = string.len(config.AuthKey)
cfv.assert(len == 0 or len >= 8)
end
end
cfv.assert_type_int(config.LogMode)
cfv.assert_range(config.LogMode, 0, 1)
cfv.assert_type_str(config.LogPath)
cfv.assert_type_bool(config.LogDebug)
cfv.assert_type_int(config.FrontPanelTheme)
cfv.assert_range(config.FrontPanelTheme, 1, 2)
cfv.assert_type_int(config.ColorMode)
cfv.assert_range(config.ColorMode, 1, themes.COLOR_MODE.NUM_MODES)
-- check emergency coolant configuration if enabled
if config.EmerCoolEnable then
cfv.assert_eq(rsio.is_valid_side(config.EmerCoolSide), true)
cfv.assert_eq(config.EmerCoolColor == nil or rsio.is_color(config.EmerCoolColor), true)
end
return cfv.valid()
end
-- RPS: Reactor Protection System
-- identifies dangerous states and SCRAMs reactor if warranted
-- autonomous from main SCADA supervisor/coordinator control
---@nodiscard
---@param reactor table
---@param is_formed boolean
function plc.rps_init(reactor, is_formed)
local state_keys = {
high_dmg = 1,
high_temp = 2,
low_coolant = 3,
ex_waste = 4,
ex_hcoolant = 5,
no_fuel = 6,
fault = 7,
timeout = 8,
manual = 9,
automatic = 10,
sys_fail = 11,
force_disabled = 12
}
local self = {
state = { false, false, false, false, false, false, false, false, false, false, false, false },
reactor_enabled = false,
enabled_at = 0,
emer_cool_active = nil, ---@type boolean
formed = is_formed,
force_disabled = false,
tripped = false,
trip_cause = "ok" ---@type rps_trip_cause
}
-- PRIVATE FUNCTIONS --
-- set reactor access fault flag
local function _set_fault()
if reactor.__p_last_fault() ~= "Terminated" then
self.state[state_keys.fault] = true
end
end
-- check if the result of a peripheral call was OK, handle the failure if not
---@nodiscard
---@param result any PPM function call result
---@return boolean succeeded if the result is OK, false if it was a PPM failure
local function _check_and_handle_ppm_call(result)
if result == ppm.ACCESS_FAULT then
_set_fault()
-- if undefined, then the reactor isn't formed
if reactor.__p_last_fault() == ppm.UNDEFINED_FIELD then self.formed = false end
else return true end
return false
end
-- set emergency coolant control (if configured)
---@param state boolean true to enable emergency coolant, false to disable
local function _set_emer_cool(state)
-- check if this was configured: if it's a table, fields have already been validated.
if config.EmerCoolEnable then
local level = rsio.digital_write_active(rsio.IO.U_EMER_COOL, state)
if level ~= false then
if rsio.is_color(config.EmerCoolColor) then
local output = rs.getBundledOutput(config.EmerCoolSide)
if rsio.digital_write(level) then
output = colors.combine(output, config.EmerCoolColor)
else
output = colors.subtract(output, config.EmerCoolColor)
end
rs.setBundledOutput(config.EmerCoolSide, output)
else
rs.setOutput(config.EmerCoolSide, rsio.digital_write(level))
end
if state ~= self.emer_cool_active then
if state then
log.info("RPS: emergency coolant valve OPENED")
else
log.info("RPS: emergency coolant valve CLOSED")
end
self.emer_cool_active = state
end
end
end
end
-- check if the reactor is formed
local function _is_formed()
local formed = reactor.isFormed()
if _check_and_handle_ppm_call(formed) then
self.formed = formed
end
-- always update, since some ppm failures constitute not being formed
if not self.state[state_keys.sys_fail] then
self.state[state_keys.sys_fail] = not self.formed
end
end
-- check if the reactor is force disabled
local function _is_force_disabled()
local disabled = reactor.isForceDisabled()
if _check_and_handle_ppm_call(disabled) then
self.force_disabled = disabled
if not self.state[state_keys.force_disabled] then
self.state[state_keys.force_disabled] = disabled
end
end
end
-- check for high damage
local function _high_damage()
local damage_percent = reactor.getDamagePercent()
if _check_and_handle_ppm_call(damage_percent) and not self.state[state_keys.high_dmg] then
self.state[state_keys.high_dmg] = damage_percent >= RPS_LIMITS.MAX_DAMAGE_PERCENT
end
end
-- check if the reactor is at a critically high temperature
local function _high_temp()
-- mekanism: MAX_DAMAGE_TEMPERATURE = 1200K
local temp = reactor.getTemperature()
if _check_and_handle_ppm_call(temp) and not self.state[state_keys.high_temp] then
self.state[state_keys.high_temp] = temp >= RPS_LIMITS.MAX_DAMAGE_TEMPERATURE
end
end
-- check if there is very low coolant
local function _low_coolant()
local coolant_filled = reactor.getCoolantFilledPercentage()
if _check_and_handle_ppm_call(coolant_filled) and not self.state[state_keys.low_coolant] then
self.state[state_keys.low_coolant] = coolant_filled < RPS_LIMITS.MIN_COOLANT_FILL
end
end
-- check for excess waste (>80% filled)
local function _excess_waste()
local w_filled = reactor.getWasteFilledPercentage()
if _check_and_handle_ppm_call(w_filled) and not self.state[state_keys.ex_waste] then
self.state[state_keys.ex_waste] = w_filled > RPS_LIMITS.MAX_WASTE_FILL
end
end
-- check for heated coolant backup (>95% filled)
local function _excess_heated_coolant()
local hc_filled = reactor.getHeatedCoolantFilledPercentage()
if _check_and_handle_ppm_call(hc_filled) and not self.state[state_keys.ex_hcoolant] then
self.state[state_keys.ex_hcoolant] = hc_filled > RPS_LIMITS.MAX_HEATED_COLLANT_FILL
end
end
-- check if there is no fuel
local function _insufficient_fuel()
local fuel = reactor.getFuelFilledPercentage()
if _check_and_handle_ppm_call(fuel) and not self.state[state_keys.no_fuel] then
self.state[state_keys.no_fuel] = fuel <= RPS_LIMITS.NO_FUEL_FILL
end
end
-- PUBLIC FUNCTIONS --
---@class rps
local public = {}
-- re-link a reactor after a peripheral re-connect
---@param new_reactor table reconnected reactor
function public.reconnect_reactor(new_reactor)
reactor = new_reactor
end
-- trip for lost peripheral
function public.trip_fault()
_set_fault()
end
-- trip for a PLC comms timeout
function public.trip_timeout()
self.state[state_keys.timeout] = true
end
-- manually SCRAM the reactor
function public.trip_manual()
self.state[state_keys.manual] = true
end
-- automatic SCRAM commanded by supervisor
function public.trip_auto()
self.state[state_keys.automatic] = true
end
-- trip for unformed reactor
function public.trip_sys_fail()
self.state[state_keys.fault] = true
self.state[state_keys.sys_fail] = true
end
-- SCRAM the reactor now
---@return boolean success
--- EVENT_CONSUMER: this function consumes events
function public.scram()
log.info("RPS: reactor SCRAM")
reactor.scram()
if reactor.__p_is_faulted() and not string.find(reactor.__p_last_fault(), PCALL_SCRAM_MSG) then
log.error("RPS: failed reactor SCRAM")
return false
else
self.reactor_enabled = false
self.last_runtime = util.time_ms() - self.enabled_at
return true
end
end
-- start the reactor now
---@return boolean success
--- EVENT_CONSUMER: this function consumes events
function public.activate()
if not self.tripped then
log.info("RPS: reactor start")
reactor.activate()
if reactor.__p_is_faulted() and not string.find(reactor.__p_last_fault(), PCALL_START_MSG) then
log.error("RPS: failed reactor start")
else
self.reactor_enabled = true
self.enabled_at = util.time_ms()
return true
end
else
log.debug(util.c("RPS: failed start, RPS tripped: ", self.trip_cause))
end
return false
end
-- automatic control activate/re-activate
---@return boolean success
function public.auto_activate()
-- clear automatic SCRAM if it was the cause
if self.tripped and self.trip_cause == "automatic" then
self.state[state_keys.automatic] = true
self.trip_cause = RPS_TRIP_CAUSE.OK
self.tripped = false
log.debug("RPS: cleared automatic SCRAM for re-activation")
end
return public.activate()
end
-- check all safety conditions
---@nodiscard
---@return boolean tripped, rps_trip_cause trip_status, boolean first_trip
function public.check()
local status = RPS_TRIP_CAUSE.OK
local was_tripped = self.tripped
local first_trip = false
if self.formed then
-- update state
parallel.waitForAll(
_is_formed,
_is_force_disabled,
_high_damage,
_high_temp,
_low_coolant,
_excess_waste,
_excess_heated_coolant,
_insufficient_fuel
)
else
-- check to see if its now formed
_is_formed()
end
-- check system states in order of severity
if self.tripped then
status = self.trip_cause
elseif self.state[state_keys.sys_fail] then
log.warning("RPS: system failure, reactor not formed")
status = RPS_TRIP_CAUSE.SYS_FAIL
elseif self.state[state_keys.force_disabled] then
log.warning("RPS: reactor was force disabled")
status = RPS_TRIP_CAUSE.FORCE_DISABLED
elseif self.state[state_keys.high_dmg] then
log.warning("RPS: high damage")
status = RPS_TRIP_CAUSE.HIGH_DMG
elseif self.state[state_keys.high_temp] then
log.warning("RPS: high temperature")
status = RPS_TRIP_CAUSE.HIGH_TEMP
elseif self.state[state_keys.low_coolant] then
log.warning("RPS: low coolant")
status = RPS_TRIP_CAUSE.LOW_COOLANT
elseif self.state[state_keys.ex_waste] then
log.warning("RPS: full waste")
status = RPS_TRIP_CAUSE.EX_WASTE
elseif self.state[state_keys.ex_hcoolant] then
log.warning("RPS: heated coolant backup")
status = RPS_TRIP_CAUSE.EX_HCOOLANT
elseif self.state[state_keys.no_fuel] then
log.warning("RPS: no fuel")
status = RPS_TRIP_CAUSE.NO_FUEL
elseif self.state[state_keys.fault] then
log.warning("RPS: reactor access fault")
status = RPS_TRIP_CAUSE.FAULT
elseif self.state[state_keys.timeout] then
log.warning("RPS: supervisor connection timeout")
status = RPS_TRIP_CAUSE.TIMEOUT
elseif self.state[state_keys.manual] then
log.warning("RPS: manual SCRAM requested")
status = RPS_TRIP_CAUSE.MANUAL
elseif self.state[state_keys.automatic] then
log.warning("RPS: automatic SCRAM requested")
status = RPS_TRIP_CAUSE.AUTOMATIC
else
self.tripped = false
self.trip_cause = RPS_TRIP_CAUSE.OK
end
-- if a new trip occured...
if (not was_tripped) and (status ~= RPS_TRIP_CAUSE.OK) then
first_trip = true
self.tripped = true
self.trip_cause = status
-- in the case that the reactor is detected to be active,
-- it will be scrammed shortly after this in the main RPS loop if we don't here
if self.formed then
if not self.force_disabled then
public.scram()
else
log.warning("RPS: skipping SCRAM due to reactor being force disabled")
end
else
log.warning("RPS: skipping SCRAM due to not being formed")
end
end
-- update emergency coolant control if configured
_set_emer_cool(self.state[state_keys.low_coolant])
-- report RPS status
databus.tx_rps(self.tripped, self.state, self.emer_cool_active)
return self.tripped, status, first_trip
end
---@nodiscard
function public.status() return self.state end
---@nodiscard
function public.is_tripped() return self.tripped end
---@nodiscard
function public.get_trip_cause() return self.trip_cause end
---@nodiscard
function public.is_low_coolant() return self.states[state_keys.low_coolant] end
---@nodiscard
function public.is_active() return self.reactor_enabled end
---@nodiscard
function public.is_formed() return self.formed end
---@nodiscard
function public.is_force_disabled() return self.force_disabled end
-- get the runtime of the reactor if active, or the last runtime if disabled
---@nodiscard
---@return integer runtime time since last enable
function public.get_runtime() return util.trinary(self.reactor_enabled, util.time_ms() - self.enabled_at, self.last_runtime) end
-- reset the RPS
---@param quiet? boolean true to suppress the info log message
function public.reset(quiet)
self.tripped = false
self.trip_cause = RPS_TRIP_CAUSE.OK
for i = 1, #self.state do self.state[i] = false end
if not quiet then log.info("RPS: reset") end
end
-- partial RPS reset that only clears fault and sys_fail
function public.reset_formed()
self.tripped = false
self.trip_cause = RPS_TRIP_CAUSE.OK
self.state[state_keys.fault] = false
self.state[state_keys.sys_fail] = false
log.info("RPS: partial reset on formed")
end
-- reset the automatic and timeout trip flags, then clear trip if that was the trip cause
function public.auto_reset()
self.state[state_keys.automatic] = false
self.state[state_keys.timeout] = false
if self.trip_cause == RPS_TRIP_CAUSE.AUTOMATIC or self.trip_cause == RPS_TRIP_CAUSE.TIMEOUT then
self.trip_cause = RPS_TRIP_CAUSE.OK
self.tripped = false
log.info("RPS: auto reset")
end
end
-- link functions with databus
databus.link_rps(public.trip_manual, public.reset)
return public
end
-- Reactor PLC Communications
---@nodiscard
---@param version string PLC version
---@param nic nic network interface device
---@param reactor table reactor device
---@param rps rps RPS reference
---@param conn_watchdog watchdog watchdog reference
function plc.comms(version, nic, reactor, rps, conn_watchdog)
local self = {
sv_addr = comms.BROADCAST,
seq_num = 0,
r_seq_num = nil,
scrammed = false,
linked = false,
last_est_ack = ESTABLISH_ACK.ALLOW,
resend_build = false,
auto_ack_token = 0,
status_cache = nil,
max_burn_rate = nil
}
comms.set_trusted_range(config.TrustedRange)
-- PRIVATE FUNCTIONS --
-- configure network channels
nic.closeAll()
nic.open(config.PLC_Channel)
-- send an RPLC packet
---@param msg_type RPLC_TYPE
---@param msg table
local function _send(msg_type, msg)
local s_pkt = comms.scada_packet()
local r_pkt = comms.rplc_packet()
r_pkt.make(config.UnitID, msg_type, msg)
s_pkt.make(self.sv_addr, self.seq_num, PROTOCOL.RPLC, r_pkt.raw_sendable())
nic.transmit(config.SVR_Channel, config.PLC_Channel, s_pkt)
self.seq_num = self.seq_num + 1
end
-- send a SCADA management packet
---@param msg_type MGMT_TYPE
---@param msg table
local function _send_mgmt(msg_type, msg)
local s_pkt = comms.scada_packet()
local m_pkt = comms.mgmt_packet()
m_pkt.make(msg_type, msg)
s_pkt.make(self.sv_addr, self.seq_num, PROTOCOL.SCADA_MGMT, m_pkt.raw_sendable())
nic.transmit(config.SVR_Channel, config.PLC_Channel, s_pkt)
self.seq_num = self.seq_num + 1
end
-- variable reactor status information, excluding heating rate
---@return table data_table, boolean faulted
local function _reactor_status()
local fuel = nil
local waste = nil
local coolant = nil
local hcoolant = nil
local data_table = {
false, -- getStatus
0, -- getBurnRate
0, -- getActualBurnRate
0, -- getTemperature
0, -- getDamagePercent
0, -- getBoilEfficiency
0, -- getEnvironmentalLoss
0, -- fuel_amnt
0, -- getFuelFilledPercentage
0, -- waste_amnt
0, -- getWasteFilledPercentage
"", -- coolant_name
0, -- coolant_amnt
0, -- getCoolantFilledPercentage
"", -- hcoolant_name
0, -- hcoolant_amnt
0 -- getHeatedCoolantFilledPercentage
}
local tasks = {
function () data_table[1] = reactor.getStatus() end,
function () data_table[2] = reactor.getBurnRate() end,
function () data_table[3] = reactor.getActualBurnRate() end,
function () data_table[4] = reactor.getTemperature() end,
function () data_table[5] = reactor.getDamagePercent() end,
function () data_table[6] = reactor.getBoilEfficiency() end,
function () data_table[7] = reactor.getEnvironmentalLoss() end,
function () fuel = reactor.getFuel() end,
function () data_table[9] = reactor.getFuelFilledPercentage() end,
function () waste = reactor.getWaste() end,
function () data_table[11] = reactor.getWasteFilledPercentage() end,
function () coolant = reactor.getCoolant() end,
function () data_table[14] = reactor.getCoolantFilledPercentage() end,
function () hcoolant = reactor.getHeatedCoolant() end,
function () data_table[17] = reactor.getHeatedCoolantFilledPercentage() end
}
parallel.waitForAll(table.unpack(tasks))
if fuel ~= nil then
data_table[8] = fuel.amount
end
if waste ~= nil then
data_table[10] = waste.amount
end
if coolant ~= nil then
data_table[12] = coolant.name
data_table[13] = coolant.amount
end
if hcoolant ~= nil then
data_table[15] = hcoolant.name
data_table[16] = hcoolant.amount
end
return data_table, reactor.__p_is_faulted()
end
-- update the status cache if changed
---@return boolean changed
local function _update_status_cache()
local status, faulted = _reactor_status()
local changed = false
if self.status_cache ~= nil then
if not faulted then
for i = 1, #status do
if status[i] ~= self.status_cache[i] then
changed = true
break
end
end
end
else
changed = true
end
if changed and not faulted then
self.status_cache = status
end
return changed
end
-- keep alive ack
---@param srv_time integer
local function _send_keep_alive_ack(srv_time)
_send_mgmt(MGMT_TYPE.KEEP_ALIVE, { srv_time, util.time() })
end
-- general ack
---@param msg_type RPLC_TYPE
---@param status boolean|integer
local function _send_ack(msg_type, status)
_send(msg_type, { status })
end
-- send structure properties (these should not change, server will cache these)
local function _send_struct()
local mek_data = { false, 0, 0, 0, types.new_zero_coordinate(), types.new_zero_coordinate(), 0, 0, 0, 0, 0, 0, 0, 0 }
local tasks = {
function () mek_data[1] = reactor.getLength() end,
function () mek_data[2] = reactor.getWidth() end,
function () mek_data[3] = reactor.getHeight() end,
function () mek_data[4] = reactor.getMinPos() end,
function () mek_data[5] = reactor.getMaxPos() end,
function () mek_data[6] = reactor.getHeatCapacity() end,
function () mek_data[7] = reactor.getFuelAssemblies() end,
function () mek_data[8] = reactor.getFuelSurfaceArea() end,
function () mek_data[9] = reactor.getFuelCapacity() end,
function () mek_data[10] = reactor.getWasteCapacity() end,
function () mek_data[11] = reactor.getCoolantCapacity() end,
function () mek_data[12] = reactor.getHeatedCoolantCapacity() end,
function () mek_data[13] = reactor.getMaxBurnRate() end
}
parallel.waitForAll(table.unpack(tasks))
if reactor.__p_is_ok() then
_send(RPLC_TYPE.MEK_STRUCT, mek_data)
self.resend_build = false
end
end
-- PUBLIC FUNCTIONS --
---@class plc_comms
local public = {}
-- reconnect a newly connected reactor
---@param new_reactor table
function public.reconnect_reactor(new_reactor)
reactor = new_reactor
self.status_cache = nil
self.resend_build = true
self.max_burn_rate = nil
end
-- unlink from the server
function public.unlink()
self.sv_addr = comms.BROADCAST
self.linked = false
self.r_seq_num = nil
self.status_cache = nil
databus.tx_link_state(types.PANEL_LINK_STATE.DISCONNECTED)
end
-- close the connection to the server
function public.close()
conn_watchdog.cancel()
public.unlink()
_send_mgmt(MGMT_TYPE.CLOSE, {})
end
-- attempt to establish link with supervisor
function public.send_link_req()
_send_mgmt(MGMT_TYPE.ESTABLISH, { comms.version, version, DEVICE_TYPE.PLC, config.UnitID })
end
-- send live status information
---@param no_reactor boolean PLC lost reactor connection
---@param formed boolean reactor formed (from PLC state)
function public.send_status(no_reactor, formed)
if self.linked then
local mek_data = nil ---@type table
local heating_rate = 0.0 ---@type number
if (not no_reactor) and rps.is_formed() then
if _update_status_cache() then mek_data = self.status_cache end
heating_rate = reactor.getHeatingRate()
end
local sys_status = {
util.time(), -- timestamp
(not self.scrammed), -- requested control state
no_reactor, -- no reactor peripheral connected
formed, -- reactor formed
self.auto_ack_token, -- indicate auto command received prior to this status update
heating_rate, -- heating rate
mek_data -- mekanism status data
}
_send(RPLC_TYPE.STATUS, sys_status)
if self.resend_build then _send_struct() end
end
end
-- send reactor protection system status
function public.send_rps_status()
if self.linked then
_send(RPLC_TYPE.RPS_STATUS, { rps.is_tripped(), rps.get_trip_cause(), table.unpack(rps.status()) })
end
end
-- send reactor protection system alarm
---@param cause rps_trip_cause reactor protection system status
function public.send_rps_alarm(cause)
if self.linked then
_send(RPLC_TYPE.RPS_ALARM, { cause, table.unpack(rps.status()) })
end
end
-- parse a packet
---@nodiscard
---@param side string
---@param sender integer
---@param reply_to integer
---@param message any
---@param distance integer
---@return rplc_frame|mgmt_frame|nil packet
function public.parse_packet(side, sender, reply_to, message, distance)
local s_pkt = nic.receive(side, sender, reply_to, message, distance)
local pkt = nil
if s_pkt then
-- get as RPLC packet
if s_pkt.protocol() == PROTOCOL.RPLC then
local rplc_pkt = comms.rplc_packet()
if rplc_pkt.decode(s_pkt) then
pkt = rplc_pkt.get()
end
-- get as SCADA management packet
elseif s_pkt.protocol() == PROTOCOL.SCADA_MGMT then
local mgmt_pkt = comms.mgmt_packet()
if mgmt_pkt.decode(s_pkt) then
pkt = mgmt_pkt.get()
end
else
log.debug("unsupported packet type " .. s_pkt.protocol(), true)
end
end
return pkt
end
-- handle RPLC and MGMT packets
---@param packet rplc_frame|mgmt_frame packet frame
---@param plc_state plc_state PLC state
---@param setpoints setpoints setpoint control table
function public.handle_packet(packet, plc_state, setpoints)
-- print a log message to the terminal as long as the UI isn't running
local function println_ts(message) if not plc_state.fp_ok then util.println_ts(message) end end
local protocol = packet.scada_frame.protocol()
local l_chan = packet.scada_frame.local_channel()
local src_addr = packet.scada_frame.src_addr()
-- handle packets now that we have prints setup
if l_chan == config.PLC_Channel then
-- check sequence number
if self.r_seq_num == nil then
self.r_seq_num = packet.scada_frame.seq_num()
elseif self.linked and ((self.r_seq_num + 1) ~= packet.scada_frame.seq_num()) then
log.warning("sequence out-of-order: last = " .. self.r_seq_num .. ", new = " .. packet.scada_frame.seq_num())
return
elseif self.linked and (src_addr ~= self.sv_addr) then
log.debug("received packet from unknown computer " .. src_addr .. " while linked (expected " .. self.sv_addr ..
"); channel in use by another system?")
return
else
self.r_seq_num = packet.scada_frame.seq_num()
end
-- feed the watchdog first so it doesn't uhh...eat our packets :)
conn_watchdog.feed()
-- handle packet
if protocol == PROTOCOL.RPLC then
---@cast packet rplc_frame
-- if linked, only accept packets from configured supervisor
if self.linked then
if packet.type == RPLC_TYPE.STATUS then
-- request of full status, clear cache first
self.status_cache = nil
public.send_status(plc_state.no_reactor, plc_state.reactor_formed)
log.debug("sent out status cache again, did supervisor miss it?")
elseif packet.type == RPLC_TYPE.MEK_STRUCT then
-- request for physical structure
_send_struct()
log.debug("sent out structure again, did supervisor miss it?")
elseif packet.type == RPLC_TYPE.MEK_BURN_RATE then
-- set the burn rate
if (packet.length == 2) and (type(packet.data[1]) == "number") then
local success = false
local burn_rate = math.floor(packet.data[1] * 10) / 10
local ramp = packet.data[2]
-- if no known max burn rate, check again
if self.max_burn_rate == nil then
self.max_burn_rate = reactor.getMaxBurnRate()
end
-- if we know our max burn rate, update current burn rate setpoint if in range
if self.max_burn_rate ~= ppm.ACCESS_FAULT then
if burn_rate > 0 and burn_rate <= self.max_burn_rate then
if ramp then
setpoints.burn_rate_en = true
setpoints.burn_rate = burn_rate
success = true
else
reactor.setBurnRate(burn_rate)
success = reactor.__p_is_ok()
end
else
log.debug(burn_rate .. " rate outside of 0 < x <= " .. self.max_burn_rate)
end
end
_send_ack(packet.type, success)
else
log.debug("RPLC set burn rate packet length mismatch or non-numeric burn rate")
end
elseif packet.type == RPLC_TYPE.RPS_ENABLE then
-- enable the reactor
self.scrammed = false
_send_ack(packet.type, rps.activate())
elseif packet.type == RPLC_TYPE.RPS_DISABLE then
-- disable the reactor, but do not trip
self.scrammed = true
_send_ack(packet.type, rps.scram())
elseif packet.type == RPLC_TYPE.RPS_SCRAM then
-- disable the reactor per manual request
self.scrammed = true
rps.trip_manual()
_send_ack(packet.type, true)
elseif packet.type == RPLC_TYPE.RPS_ASCRAM then
-- disable the reactor per automatic request
self.scrammed = true
rps.trip_auto()
_send_ack(packet.type, true)
elseif packet.type == RPLC_TYPE.RPS_RESET then
-- reset the RPS status
rps.reset()
_send_ack(packet.type, true)
elseif packet.type == RPLC_TYPE.RPS_AUTO_RESET then
-- reset automatic SCRAM and timeout trips
rps.auto_reset()
_send_ack(packet.type, true)
elseif packet.type == RPLC_TYPE.AUTO_BURN_RATE then
-- automatic control requested a new burn rate
if (packet.length == 3) and (type(packet.data[1]) == "number") and (type(packet.data[3]) == "number") then
local ack = AUTO_ACK.FAIL
local burn_rate = math.floor(packet.data[1] * 100) / 100
local ramp = packet.data[2]
self.auto_ack_token = packet.data[3]
-- if no known max burn rate, check again
if self.max_burn_rate == nil then
self.max_burn_rate = reactor.getMaxBurnRate()
end
-- if we know our max burn rate, update current burn rate setpoint if in range
if self.max_burn_rate ~= ppm.ACCESS_FAULT then
if burn_rate < 0.01 then
if rps.is_active() then
-- auto scram to disable
log.debug("AUTO: stopping the reactor to meet 0.0 burn rate")
if rps.scram() then
ack = AUTO_ACK.ZERO_DIS_OK
else
log.warning("AUTO: automatic reactor stop failed")
end
else
ack = AUTO_ACK.ZERO_DIS_OK
end
elseif burn_rate <= self.max_burn_rate then
if not rps.is_active() then
-- activate the reactor
log.debug("AUTO: activating the reactor")
reactor.setBurnRate(0.01)
if reactor.__p_is_faulted() then
log.warning("AUTO: failed to reset burn rate for auto activation")
else
if not rps.auto_activate() then
log.warning("AUTO: automatic reactor activation failed")
end
end
end
-- if active, set/ramp burn rate
if rps.is_active() then
if ramp then
log.debug(util.c("AUTO: setting burn rate ramp to ", burn_rate))
setpoints.burn_rate_en = true
setpoints.burn_rate = burn_rate
ack = AUTO_ACK.RAMP_SET_OK
else
log.debug(util.c("AUTO: setting burn rate directly to ", burn_rate))
reactor.setBurnRate(burn_rate)
ack = util.trinary(reactor.__p_is_faulted(), AUTO_ACK.FAIL, AUTO_ACK.DIRECT_SET_OK)
end
end
else
log.debug(util.c(burn_rate, " rate outside of 0 < x <= ", self.max_burn_rate))
end
end
_send_ack(packet.type, ack)
else
log.debug("RPLC set automatic burn rate packet length mismatch or non-numeric burn rate")
end
else
log.debug("received unknown RPLC packet type " .. packet.type)
end
else
log.debug("discarding RPLC packet before linked")
end
elseif protocol == PROTOCOL.SCADA_MGMT then
---@cast packet mgmt_frame
-- if linked, only accept packets from configured supervisor
if self.linked then
if packet.type == MGMT_TYPE.KEEP_ALIVE then
-- keep alive request received, echo back
if packet.length == 1 and type(packet.data[1]) == "number" then
local timestamp = packet.data[1]
local trip_time = util.time() - timestamp
if trip_time > 750 then
log.warning("PLC KEEP_ALIVE trip time > 750ms (" .. trip_time .. "ms)")
end
-- log.debug("PLC RTT = " .. trip_time .. "ms")
_send_keep_alive_ack(timestamp)
else
log.debug("SCADA_MGMT keep alive packet length/type mismatch")
end
elseif packet.type == MGMT_TYPE.CLOSE then
-- handle session close
conn_watchdog.cancel()
public.unlink()
println_ts("server connection closed by remote host")
log.warning("server connection closed by remote host")
else
log.debug("received unsupported SCADA_MGMT packet type " .. packet.type)
end
elseif packet.type == MGMT_TYPE.ESTABLISH then
-- link request confirmation
if packet.length == 1 then
local est_ack = packet.data[1]
if est_ack == ESTABLISH_ACK.ALLOW then
println_ts("linked!")
log.info("supervisor establish request approved, linked to SV (CID#" .. src_addr .. ")")
-- link + reset remote sequence number and cache
self.sv_addr = src_addr
self.linked = true
self.r_seq_num = nil
self.status_cache = nil
if plc_state.reactor_formed then _send_struct() end
public.send_status(plc_state.no_reactor, plc_state.reactor_formed)
log.debug("sent initial status data")
else
if self.last_est_ack ~= est_ack then
if est_ack == ESTABLISH_ACK.DENY then
println_ts("link request denied, retrying...")
log.info("supervisor establish request denied, retrying")
elseif est_ack == ESTABLISH_ACK.COLLISION then
println_ts("reactor PLC ID collision (check config), retrying...")
log.warning("establish request collision, retrying")
elseif est_ack == ESTABLISH_ACK.BAD_VERSION then
println_ts("supervisor version mismatch (try updating), retrying...")
log.warning("establish request version mismatch, retrying")
else
println_ts("invalid link response, bad channel? retrying...")
log.error("unknown establish request response, retrying")
end
end
-- unlink
self.sv_addr = comms.BROADCAST
self.linked = false
end
self.last_est_ack = est_ack
-- report link state
databus.tx_link_state(est_ack + 1)
else
log.debug("SCADA_MGMT establish packet length mismatch")
end
else
log.debug("discarding non-link SCADA_MGMT packet before linked")
end
else
-- should be unreachable assuming packet is from parse_packet()
log.error("illegal packet type " .. protocol, true)
end
else
log.debug("received packet on unconfigured channel " .. l_chan, true)
end
end
---@nodiscard
function public.is_scrammed() return self.scrammed end
---@nodiscard
function public.is_linked() return self.linked end
return public
end
return plc