The TA4 Lua Controller is a small computer, programmable in Lua to control your machinery.
In contrast to the ICTA Controller this controller allows to implement larger and more complex programs.
But to write Lua scripts, some knowledge with the programming language Lua is required.
Minetest uses Lua 5.1. The reference document for Lua 5.1 is [here](https://www.lua.org/manual/5.1/). The book [Programming in Lua (first edition)](https://www.lua.org/pil/contents.html) is also a perfect source for learning Lua.
This TA4 Lua Controller manual is also available as PDF:
The controller block has a menu form with the following tabs:
- the `init` tab for the initialization code block
- the `func` tab for the Lua functions
- the `loop` tab for the main code block
- the `outp` tab for debugging outputs via `$print()`
- the `notes` tab for your code snippets or other notes (like a clipboard)
- the `help` tab with information to the available functions
The controller needs power to work. A battery pack has to be placed nearby.
### Battery
The battery pack has to be placed near the controller (1 block distance).
The needed battery power is directly dependent on the CPU time the controller consumes.
Because of that, it is important to optimize the execution time of the code (which helps the admin to keep server lags down :))
The controller will be restarted (init() is called) every time the Minetest server starts again.
To store data non-volatile (to pass a server restart), the "TA4 Lua Server" block has to be used.
### TA4 Lua Server
The Server block is used to store data from Lua Controllers nonvolatile. It can also be used for communication purposes between several Lua Controllers.
Only configured players have access to the server. Therefore, the server has a menu to enter player names.
For special Server functions, see "Server and Terminal Functions"
### TA4 Lua Controller Terminal
The Terminal is used to send command strings to the controller.
In turn, the controller can send text strings to the terminal.
The Terminal has a help system for internal commands. Its supports the following commands:
-`clear` = clear the screen
-`help` = output this message
-`pub` = switch terminal to public use (everybody can enter commands)
-`priv` = switch terminal to private use (only the owner can enter commands)
-`send <num> on/off` = send on/off event to e. g. lamps (for testing purposes)
-`msg <num> <text>` = send a text message to another Controller (for testing purposes)
For special Terminal functions for the TA4 Lua Controller, see "Server and Terminal Functions"
### TA4 Sensor Chest
tbd.
## Lua Functions and Environment
### Lua Functions and Limitations
The controller uses a subset of the language Lua, called SaferLua. It allows the safe and secure execution of Lua scripts, but has the following limitations:
- limited code length
- limited execution time
- limited memory use
- limited possibilities to call functions
SaferLua follows the standard Lua syntax with the following restrictions:
- no `while` or `repeat` loops (to prevent endless loops)
- no table constructor {..}, see "Arrays, Stores, and Sets" for comfortable alternatives
- limited runtime environment
SaferLua directly supports the following standard functions:
For own function definitions, the menu tab 'func' can be used. Here you write your functions like:
```lua
function foo(a, b)
return a + b
end
```
Each SaferLua program has access to the following system variables:
- ticks - a counter which increments by one each call of `loop()`
- elapsed - the amount of seconds since the last call of `loop()`
- event - a boolean flag (true/false) to signal the execution of `loop()` based on an occurred event
### Arrays, Stores, and Sets
It is not possible to easily control the memory usage of a Lua table at runtime. Therefore, Lua tables can't be used for SaferLua programs. Because of this, there are the following alternatives, which are secure shells over the Lua table type:
#### Arrays
_Arrays_ are lists of elements, which can be addressed by means of an index. An index must be an integer number. The first element in an _array_ has the index value 1. _Arrays_ have the following methods:
- add(value) - add a new element at the end of the array
- set(idx, value) - overwrite an existing array element on index `idx`
- get(idx) - return the value of the array element on index `idx`
- remove(idx) - remove the array element on index `idx`
- insert(idx, val) - insert a new element at index `idx` (the array becomes one element longer)
- size() - return the number of _array_ elements
- memsize() - return the needed _array_ memory space
- sort(reverse) - sort the _array_ elements in place. If _reverse_ is `true`, sort in descending order.
Example:
```lua
a = Array(1,2,3,4) --> {1,2,3,4}
a.add(6) --> {1,2,3,4,6}
a.set(2, 8) --> {1,8,3,4,6}
a.get(2) --> function returns 8
a.insert(5,7) --> {1,8,3,4,7,6}
a.remove(3) --> {1,8,4,7,6}
a.insert(1, "hello") --> {"hello",1,8,4,7,6}
a.size() --> function returns 6
a.memsize() --> function returns 10
for idx,val in a.next() do
...
end
```
#### Stores
Unlike _arrays_, which are indexed by a range of numbers, _stores_ are indexed by keys, which can be a string or a number. The main operations on a _store_ are storing a value with some key and extracting the value given the key.
The _store_ has the following methods:
- set(key, val) - store/overwrite the value `val` behind the keyword `key`
- get(key) - read the value behind `key`
- del(key) - delete a value
- size() - return the number of _store_ elements
- memsize() - return the needed _store_ memory space
- keys(order) - return an _array_ with the keys. If _order_ is `"up"` or `"down"`, return the keys as sorted _array_, in order of the _store_ values.
Example:
```lua
s = Store("a", 4, "b", 5) --> {a = 4, b = 5}
s.set("val", 12) --> {a = 4, b = 5, val = 12}
s.get("val") --> returns 12
s.set(0, "hello") --> {a = 4, b = 5, val = 12, [0] = "hello"}
s.del("val") --> {a = 4, b = 5, [0] = "hello"}
s.size() --> function returns 3
s.memsize() --> function returns 9
for key,val in s.next() do
...
end
```
Keys sort example:
```lua
s = Store() --> {}
s.set("Joe", 800) --> {Joe=800}
s.set("Susi", 1000) --> {Joe=800, Susi=1000}
s.set("Tom", 60) --> {Joe=800, Susi=1000, Tom=60}
s.keys() --> {Joe, Susi, Tom}
s.keys("down") --> {Susi, Joe, Tom}
s.keys("up") --> {Tom, Joe, Susi}
```
#### Sets
A _set_ is an unordered collection with no duplicate elements. The basic use of a _set_ is to test if an element is in the _set_, e.g. if a player name is stored in the _set_.
The _set_ has the following methods:
- add(val) - add a value to the _set_
- del(val) - delete a value from the _set_
- has(val) - test if value is stored in the _set_
- size() - return the number of _set_ elements
- memsize() - return the needed _set_ memory space
All three types of data structures allow nested elements, e.g. you can store a _set_ in a _store_ or an _array_ and so on. But note that the overall size over all data structures can't exceed the predefined limit. This value is configurable for the server admin. The default value is 1000.
The configured limit can be determined via `memsize()`:
```lua
memsize() --> function returns 1000 (example)
```
### Initialization, Cyclic Task, and Events
The TA4 Lua Controller distinguishes between the initialization phase (just after the controller was started) and the continuous operational phase, in which the normal code is executed.
#### Initialization
During the initialization phase the function `init()` is executed once. The `init()` function is typically used to initialize variables, clean the display, or reset other blocks:
```lua
-- initialize variables
counter = 1
table = Store()
player_name = "unknown"
# reset blocks
$clear_screen("123") -- "123" is the number of the display
$send_cmnd("2345", "off") -- turn off the blocks with the number "2345"
```
#### Cyclic Task
During the continuous operational phase the `loop()` function is cyclically called.
Code witch should be executed cyclically has to be placed here.
The cycle frequency is per default once per second but can be changed via:
```lua
$loopcycle(0) -- no loop cyle any more
$loopcycle(1) -- call the loop function every second
$loopcycle(10) -- call the loop function every 10 seconds
```
The provided number must be an integer value.
The cycle frequency can be changed in the `init()` function, but also in the `loop()` function.
#### Events
To be able to react directly on received commands, the TA4 Lua Controller supports events.
Events are usually turned off, but can be activated with the function `events()`:
```lua
$events(true) -- enable events
$events(false) -- disable events
```
If an event occurs (a command was received from another block), the `loop()` is executed (in addition to the normal loop cycle). In this case the system variable 'event' is set:
```lua
if event then
-- event has occurred
if $get_input("3456") == "on" then -- check input from block "3456"
-- do some action...
end
end
```
The first occurred event will directly be processed, further events may be delayed. The TA4 Lua Controller allows a maximum of one event every 100 ms.
## Lua Controller Functions
In addition to Lua standard function the Lua Controller provides the following functions:
### Controller local Functions
-`$print(text)` - Output a text string on the 'outp' tab of the controller menu.
E.g.: `$print("Hello "..name)`
-`$loopcycle(seconds)` - This function allows to change the call frequency of the controller loop() function, witch is per default one second. For more info, see "Cyclic Task"
-`$events(bool)` - Enable/disable event handling. For more info, see "Events"
-`$time_as_str()` - Read the time of day (ingame) as text string in 24h format, like "18:45"
-`$time_as_num()` - Read the time of day (ingame) as integer number in 24h format, like 1845
-`$get_input(num)` - Read an input value provided by an external block with the given number _num_. The block has to be configured with the number of the controller to be able to send status messages (on/off commands) to the controller. _num_ is the number of the remote block, like "1234".
#### Input Example
- A Player Detector with number "456" is configured to send on/off commands to the TA4 Lua Controller with number "345".
- The TA4 Lua Controller will receive these commands as input value.
- The program on the SaferLua Controller can always read the last input value from the Player Detector with number "456" by means of:
| "load" | number | Read the load value in percent (0..100) of a tank, silo, accu, or battery block, or from the Signs Bot Box. Silo and tank return two values: The percentage value and the absolute value in units.<br/> Example: percent, absolute = $send_cmnd("223", "load") |
| "count" | number of items | Read the total amount of TA4 chest items. An optional number as `add_data` is used to address only one inventory slot (1..8, from left to right). |
| "itemstring" | item string of the given slot | Specific command for the TA4 8x2000 Chest to read the item type (technical name) of one chest slot, specified via `add_data` (1..8).<br/>Example: s = $send_cmnd("223", "itemstring", 1) |
| "output" | recipe output string, <br/>e.g.: "default:glass" | Only for the Industrial Furnace. If no recipe is active, the command returns "unknown" |
| "a2b" | nil | TA4 Move Controller command to move the block(s) from position A to B |
| "b2a" | nil | TA4 Move Controller command to move the block(s) from position B to A |
| "move" | nil | TA4 Move Controller command to move the block(s) to the opposite position |
| "left" | nil | TA4 Turn Controller command to turn the block(s) to the left |
| "right" | nil | TA4 Turn Controller command to turn the block(s) to the right |
| "uturn" | nil | TA4 Turn Controller command to turn the block(s) 180 degrees |
| "recipe" | `<item_name>,<item_name>,...` | Set the TA4 Autocrafter recipe. <br/>Example for the torch recipe: `default:coal_lump,,,default:stick`<br/>Hint: Empty fields may only be left out at the end of the item list! |
| "recipe" | `<number>.<index>` | Set the TA4 Autocrafter recipe with a recipe from a TA4 Recipe Block.<br/>`<number>` is the TA4 Recipe Block number<br/>`<index>` is the number of the recipe in the TA4 Recipe Block |
| "goto" | `<slot>` | Start command for the TA4 Sequencer. `<slot>` is the time slot like `[1]` where the execution starts. |
| "stop" | nil | Stop command for the TA4 Sequencer. |
| "gain" | volume | Set volume of the sound block (`volume` is a value between 0 and 1.0) |
| "sound" | index | Select sound sample of the sound block |
The Server is used to store data permanently/non-volatile. It can also be used to share data between several Controllers.
-`$server_write(num, key, value)` - Store a value on the server under the key _key_. _key_ must be a string. _value_ can be either a number, string, boolean, nil or data structure.
**This function does not allow nested data structures**.
_num_ is the number of the Server.
Example: `$server_write("0123", "state", state)`
-`$server_read(num, key)` - Read a value from the server. _key_ must be a string. _num_ is the number of the Server, like "1234".
The Terminal can send text strings as events to the Controller.
In contrast the Controller can send text strings to the terminal.
-`$get_term()` - Read a text command received from the Terminal
-`$put_term(num, text)` - Send a text string to the Terminal. _num_ is the number of the Terminal.
Messages are used to transport data between Controllers. Messages can contain arbitrary data. Incoming messages are stored in order (up to 10) and can be read one after the other.
*`$get_msg([raw])` - Read a received message. The function returns the sender number and the message. (see example "Emails"). If the _raw_ parameter is not set or false, the message is guaranteed to be a string.
*`$display(num, row, text)` Send a text string to the display with number _num_. _row_ is the display row, a value from 1 to 5, or 0 to add the text string at the bottom (scroll screen mode). _text_ is the string to be displayed. If the first char of the string is a blank, the text will be horizontally centered.
*`$clear_screen(num)` Clear the screen of the display with number _num_.
*`$position(num)` Returns the position as string "'(x,y,z)" of the device with the given _num_.
