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table: [hexadecimal digits]
table: [hexadecimal digits]
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===Metatable Demonstration===
===Metatable Demonstration===
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*__index(Table, Index) — Fires when Table[Index] is nil
*__index(Table, Index) — Fires when Table[Index] is nil
*__newindex(Table, Index, Value) — Fires at Table[Index] = Value when Table[Index] is nil
*__newindex(Table, Index, Value) — Fires at Table[Index] = Value when Table[Index] is nil
*__call(Table, arg) — Allows the table to be used as a function, arg is the arguments passed
*__call(Table, arg) — Allows the table to be used as a function, arg is the arguments passed, Table(arg)
*__concat(Table, Object) — The .. concatenation operator.
*__concat(Table, Object) — The .. concatenation operator.
*__unm(Table) — The unary – operator.
*__unm(Table) — The unary – operator.

Revision as of 21:46, 8 July 2011

Metatables

The metatables for Strings and all ROBLOX types are locked; however, in normal Lua (not RBX.lua) you can set the metatables of these objects using the debug library.[1]

What is a Metatable?

Metatables allow tables to become more powerful than before. You may think that if you have code like this:

local list = {1,2}
print(list[3])

The code will search through the list for the third index in list, realize it's not there, and return nil. That's totally wrong. What really happens is the code will search through the list for the third index, realize it's not there and then try and see if there's a metatable attached to the list and then return nil if there isn't one.

get and setmetatable

There are two main functions when dealing with metatables: getmetatable and setmetatable. You use setmetatable to give a table a metatable, and you use getmetatable to retrieve the metatable of an object. Here's an example:

x={}
metaTable={}
setmetatable(x, metaTable) --Give x a metatable called metaTable!
print(getmetatable(x))

Output:
table: [hexadecimal digits]

Metatable Demonstration

Example

local List={1,2}
print("In table List, index z is "..List.z)

Output:
attempt to concatenate field 'z' (a nil value)


z is nil. Now, look at what happens with metatables:

Example
local List={1,2} -- A normal table
local Metatable={ -- A metatable
__index=function(Table, Index) 
    rawset(Table, Index, 0) -- Set Table[Index] to 0
    return Table[Index] -- return Table[Index] (which is now 0)
end
}
setmetatable(List, Metatable) -- Now List has the metatable Metatable
print("In table List, index z is "..List.z)

Output:
In table List, index z is 0


What happened there? List is a normal table, with nothing unusual about it. Metatable is also a table, but it has something special: the __index metamethod. The __index metamethod is fired when Table[Index] is nil; or, in this case, List.z is nil. Now, nothing would happen because the two tables (List and Metatable) aren't linked. That's what the third line does: sets List's metatable to Metatable, which means that when List is indexed (__index) in an index that's nil (List.z), the function associated with __index in Metatable is run. The function with __index in Metatable uses rawset to make a new value in the Table (or List). Then, that value is returned. So, List.z is set equal to 0, and then List.z is returned (which is 0).

Metamethods

Metamethods are the functions that are stored inside a metatable. They can go from calling a table, to adding a table, to even dividing tables as well. Here's a list of metamethods that can be used:

  • __index(Table, Index) — Fires when Table[Index] is nil
  • __newindex(Table, Index, Value) — Fires at Table[Index] = Value when Table[Index] is nil
  • __call(Table, arg) — Allows the table to be used as a function, arg is the arguments passed, Table(arg)
  • __concat(Table, Object) — The .. concatenation operator.
  • __unm(Table) — The unary – operator.
  • __add(Table, Object) — The + addition operator.
  • __sub(Table, Object) — The – subtraction operator.
  • __mul(Table, Object) — The * mulitplication operator.
  • __div(Table, Object) — The / division operator.
  • __mod(Table, Object) — The % modulus operator.
  • __pow(Table, Object) — The ^ exponentiation operator.
  • __tostring(Table) — Fired when tostring is called on the table.
  • __metatable — if present, locks the metatable so getmetatable will return this instead of the metatable and setmetatable will error. Non-function value.
  • __eq(Table, Table2) — The == equal to operator˚
  • __lt(Table, Table2) — The < less than operator˚
  • __le(Table, Table2) — The <= operator˚
  • __gc(Object) - Fired when the Object is garbage-collected
  • __len(Object) - Fired when the # operator is used on the Object.

˚ Requires two tables; does not work with a table and a number, string, etc. The tables must have the same metatable.

Using Metatables

There are many ways to use metatables, for example, the __unm operator to make the table negative:

Example
local Table1 = {10,11,12}

local Metatable = {
	__unm = function (Table) -- __unm is for the unary operator -
		local t={} -- the table to return
		for i,v in pairs(Table) do
			t[i]=-v -- Set t[i] to -1*Table[i]
		end
		return t -- return the negative Table!
	end
}
setmetatable(Table1, Metatable)
print(table.concat(-Table1, "; "))

Output:
-10; -11; -12


Now, you can easily do that with a simple function, but there's a lot more where that came from. Take this for example:

Table = {10,20,30}
print(Table(5))

Now, obviously you can't call a table. That's just crazy, but (surprise, surprise!) with metatables you can.

Example
local Table = {10,20,30}

local Metatable = {
	__call = function (table, param)
		local t = {}
		for i, v in ipairs(table) do
			t[i] = v + param -- Add the argument (5) to the value, then place it in the new table (t).
		end
		return unpack(t) -- Return a string version of t.
	end
}

setmetatable(Table, Metatable)
print(Table(5))

Output:
15	25	35


You can do a lot more as well, such as adding tables!

Example
local Table1 = {10,11,12}
local Table2 = {13,14,15}

for k, v in pairs(Table1 + Table2) do
	print(k, v)
end


This will error saying that you're attempting to perform arithmetic on a table. Let's try this with a metatable.

Example
local Table1 = {10,11,12}
local Table2 = {13,14,15}

local Metatable = {
	__add = function (table1, table2)
		local t = {}
		for i, v in ipairs(table1) do
			t[i]=v+table2[i] -- t[i] is equal to table1[i]+table2[i]
		end
		return t
	end
}

setmetatable(Table1, Metatable)
setmetatable(Table2, Metatable)

for k, v in pairs(Table1 + Table2) do
	print(k, v) 
end

Output:
1	23
2	25
3	27



If the two tables have two different __add functions, then Lua will go to table1 first and if it doesn't have an __add function, then it'll go to the second one. That means that you really only have to set the metatable of Table1 or Table2, but it's nicer and more readable to set the metatable of both.

Here is one last example breaking away from using separate variables when it isn't necessary.

Example
local t = setmetatable({10, 20, 30}, {__call = function(a, b) 
return table.concat(a, b..' ')..b 
end}) 
print('Tables contains '..t(1)) --> Tables contains 101 201 301


Use Cases

Now, I am well aware that you can do all of these as a simple function yourself, but there's a lot more than what you think it can do. Let's try a simple program that will memorize a number when a possibly laggy math problem is put into it.

For this one we will be using the __index metamethod just to make it simple:

Example
local Table = {}

local function mathProblem(num)
	for i = 1, 20 do
		num = math.floor(num * 10 + 65)
	end
	for i = 1, 10 do
		num = num + i - 1
	end
	return num
end

local Metatable = {
	__index = function (object, key)
		local num = mathProblem(key)
		object[key] = num
		return num
	end
}

local setmetatable(Table, Metatable)

print(Table[1]) -- Will be slow because it's the first time using this number.
print(Table[2]) -- will be slow because it's the first time using this number.
print(Table[1]) -- will be fast because it's just grabbing the number from the table.


See Also

http://www.lua.org/manual/5.1/manual.html#2.8

http://www.lua.org/pil