Difference between revisions of "Lua Language"
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===Introduction=== | ===Introduction=== | ||
− | Lua is a lightweight, scripting programming language based on an interpreter generating compiled bytecodes. | + | Lua is a lightweight, scripting programming language based on an interpreter generating compiled bytecodes (code executing in a virtual machine). |
It was designed in Brasil by Roberto Ierusalimschy, Waldemar Celes and Luiz Henrique de Figueiredo in 1993. | It was designed in Brasil by Roberto Ierusalimschy, Waldemar Celes and Luiz Henrique de Figueiredo in 1993. | ||
− | CE Lua is a specific version of Lua interpreter adapted by Dark Byte for Cheat Engine. | + | CE Lua is a specific version of Lua interpreter adapted by Dark Byte for Cheat Engine. The CE Lua Engine is a main component of Cheat Engine. |
+ | |||
+ | ''This wiki page is written for Lua beginners. If you know the basic Lua syntax then you can go to the next page.'' | ||
===Syntax=== | ===Syntax=== | ||
Line 14: | Line 16: | ||
==Comments== | ==Comments== | ||
− | In Lua simple comments begin with <code><nowiki>--</nowiki></code> and end at the end of line. | + | In Lua simple comments begin with <code><nowiki>--</nowiki></code> and end at the end of the line. |
Multi-line comments begin with <code><nowiki>--[[</nowiki></code> and end with <code><nowiki>]]</nowiki></code> . | Multi-line comments begin with <code><nowiki>--[[</nowiki></code> and end with <code><nowiki>]]</nowiki></code> . | ||
Line 25: | Line 27: | ||
</pre> | </pre> | ||
− | ==Variables== | + | ==Variables, types and operators== |
− | In Lua variables are polymorphic (can change the type during theirs lifes). By default a variable is global at Lua Engine level unless the declaration begins with <code | + | In Lua variables are polymorphic (can change the type during theirs lifes). By default a variable is '''global''' at Lua Engine level unless the declaration begins with <code>local</code> modifier. |
− | Any variable can host: | + | Any variable can host different data types and use specific operators: |
− | * nothing (not defined, | + | * '''nil''' meaning nothing (a variable not defined, or not assigned, or assigned to '''<code>nil</code>''') |
− | * a | + | ** Comparing operators: comparing any variable to '''<code>nil</code>''' ( <code>var == nil</code> or <code>var ~= nil</code> ) |
− | * a boolean value (true/false) | + | * a '''number''' value (no difference between integer or float values, nor between different precisions) |
− | * a string | + | ** Binary arithmetic operators between two numbers: <code>+</code>, <code>-</code>, <code>*</code>, <code>/</code>, <code>//</code> (floor division), <code>%</code> (modulo), <code>^</code> (power). |
− | * a table | + | ** Unary arithmetic operator: <code>-</code> (example: <code>var1 = -var2</code>) |
− | * a function | + | ** Comparing operators between two numbers giving a boolean: <code>></code>, <code>>=</code>, <code><</code>, <code><=</code>, <code>==</code>, <code>~=</code>. |
+ | ** Bitwise operators (only on integer values): <code>&</code> bitwise AND, <code>|</code> bitwise OR, <code>~</code> bitwise XOR, <code>~</code> bitwise NOT, <code><<</code> left shift, <code>>></code> right shift. | ||
+ | * a '''boolean''' value (equal to <code>true</code> or <code>false</code>) | ||
+ | ** Binary boolean operators: <code>and</code>, <code>or</code>. | ||
+ | ** Unary boolean operator: <code>not</code>. | ||
+ | * a '''string''' (constants can be surrounded by single <code>'string'</code>or double quotes <code>"string"</code> or double square brackets <code><nowiki>[[string]]</nowiki></code>; the last case accepts new lines inside) | ||
+ | ** Concatenation operator: <code>..</code> between two strings. | ||
+ | ** Comparing operators between two strings '''content''' giving a boolean: <code>></code>, <code>>=</code>, <code><</code>, <code><=</code>, <code>==</code>, <code>~=</code>. | ||
+ | ** Length operator: <code>#</code> returns the number of characters | ||
+ | * a '''table''' | ||
+ | ** Indexing operator: <code>[ ]</code> returns the associated value of an index/key in a table | ||
+ | ** Indexing operator: <code>.</code> returns the associated value of a string key in a table | ||
+ | ** Length operator: <code>#</code> returns the integer index of the first element not equal to <code>nil</code> | ||
+ | * a '''function''' | ||
− | ''' | + | The assign operator <code>=</code> is mandatory just for the global variable declaration and can be use later to modify any variable. Lua supports parallel assignment from a list of values to a list of variables: <code>Var1, Var2, Var3 = 7, "GoesInVar2", 12*12</code>. First, all values expressions in the right side list are evaluated, any extra value is ignored and any missing value is replaced by '''<code>nil</code>'''. Then these values are assigned to the corresponding variables. |
+ | |||
+ | '''Tips:''' | ||
+ | * Always use the right operators for the right types. | ||
+ | * Always use parethesis for complex expressions (the expression <code>not var1==nil or var1~=3</code> is not equal to <code>not (var1==nil or var1~=3)</code> ). | ||
+ | * Use the function <code>type</code> to get a '''string''' containing the real type of a variable. | ||
+ | * Prefer using local variables versus global variables. | ||
'''Examples:''' | '''Examples:''' | ||
<pre> | <pre> | ||
+ | local MyVar0 -- local variable having nothing inside so equal to nil | ||
MyVar1 = nil -- global variable MyVar1 having nothing inside (no type neither) | MyVar1 = nil -- global variable MyVar1 having nothing inside (no type neither) | ||
MyVar2 = UnknownVar -- another global variable equal to nil (because UnknowVar is not yet defined) | MyVar2 = UnknownVar -- another global variable equal to nil (because UnknowVar is not yet defined) | ||
− | local MyVar3 = 2 | + | local MyVar3 = 2+0x10 -- local number variable MyVar3 equal to 18 (2+16) |
MyVar4 = 'Hello' -- global string variable MyVar4 | MyVar4 = 'Hello' -- global string variable MyVar4 | ||
local MyVar5 = "Hello" -- local string variable MyVar5 having the same string as MyVar3 | local MyVar5 = "Hello" -- local string variable MyVar5 having the same string as MyVar3 | ||
MyVar6 = [[First Line | MyVar6 = [[First Line | ||
Second Line.]] -- global multi-line string variable MyVar6 beginning with 'First' and ending with 'Line.' | Second Line.]] -- global multi-line string variable MyVar6 beginning with 'First' and ending with 'Line.' | ||
− | MyVar2 = ( | + | MyVar2 = (1e3 > 7.55) -- now MyVar2 becomes a boolean equal to true |
+ | MyVar7 = print -- global function variable MyVar7 which can be used as an alias of print function | ||
+ | MyVar2, MyVar3 = MyVar3, MyVar2 -- parallel assignment: MyVar2 becomes 18 and MyVar3 becomes true | ||
+ | </pre> | ||
+ | |||
+ | '''Automatic typecast (coercion):''' | ||
+ | |||
+ | When some operators or function calls need it, Lua will try to convert automatically '''numbers''' to '''strings''' or '''strings''' to '''numbers''': | ||
+ | * The expression <code>'1'+9</code> is valid and is a number because the string <code>'1'</code> will be automatically converted to the number <code>1</code>. | ||
+ | * But the expression <code>'one'+9</code> is a not valid because the string <code>'one'</code> can't be automatically converted to a number. | ||
+ | * The expression <code>'Waiting '..10</code> is valid and is a string because the number <code>10</code> will be automatically converted to the string <code>'10'</code> by the presence of <code>..</code> operator. | ||
+ | * But the expressions <code>7..'days'</code> or <code>'Waiting '..10..' seconds'</code> are invalid because Lua interprets the first dot <code>.</code> after <code>7</code> or <code>10</code> as a decimal separator and then it is unable to detect the concatenation operator <code>..</code>. | ||
+ | * Solution: use spaces and parenthesis as much as you need. The following expressions are valid: <code>('Waiting '..10)..' seconds'</code> , <code>'Waiting '.. 10 ..' seconds'</code> , and <code>7 ..'days'</code> . | ||
+ | |||
+ | '''Copy operations:''' | ||
+ | |||
+ | For any copy operation like assignment, function calling arguments and function returns, Lua performs a '''''copy by value''''' (real copy) for '''nil''', '''numbers''', '''strings''', '''booleans''' types and performs a '''''copy by reference''''' (not a new copy, just pointing to the original) for '''tables''' and '''functions'''. | ||
+ | |||
+ | ==Console output== | ||
+ | |||
+ | Lua uses the <code>print</code> function to output numericals and strings to the console (use the menu to open the Lua Engine console). | ||
+ | The <code>print</code> function has a variable number of arguments. Each argument ('''string''' or '''number''') will be printed to the console with spaces between arguments and a new line will be added at the end. The default format for '''numbers''' is the decimal base with automatic use of decimal point and/or decimal power if necessary. | ||
+ | |||
+ | '''Examples:''' | ||
+ | <pre> | ||
+ | print(MyVar1) -- prints an empty line because MyVal1 is nil | ||
+ | print('MyVar3=',MyVar3,MyVar3,MyVar3) -- prints the line 'MyVar3=2 2 2' | ||
+ | print("MyVar2 = ",MyVar2) -- prints just the line 'MyVar2 = ' because MyVar2 is not a numerical nor a string | ||
+ | print(MyVar4..' and '..MyVar5..' again') -- prints 'Hello and Hello again' | ||
+ | print(#MyVar5) -- prints 5 (the lenght of MyVar5) | ||
+ | MyVar7("9.9+0.1=",9.9+0.1) -- prints the line '9.9+0.1=10.0' (because MyVar7 is now equal to print) | ||
+ | MyVar7('1/0=',1/0) -- prints the line '1/0=inf' | ||
</pre> | </pre> | ||
==Flow control== | ==Flow control== | ||
− | Lua provides a conditional test with | + | Lua provides a conditional test with multiple, optional branches: |
<pre> | <pre> | ||
Line 76: | Line 129: | ||
until BooleanExpression -- until BooleanExpression becomes true | until BooleanExpression -- until BooleanExpression becomes true | ||
− | for | + | for Idx = Start,Stop,Step do -- any numerical value for Start, Stop and Step (Step is optional and defaults to 1) |
--statements | --statements | ||
− | end -- loop while | + | end -- loop while Idx <= Stop (for positive Step) or Idx >= Stop (for negative Step) |
− | for | + | for KeyIdx,Val in ListExpr do -- it loops over all the ListExpr, giving for each element the KeyIdx and the Val |
− | --statements -- | + | --statements -- KeyIdx and Val available inside the for loop |
end | end | ||
</pre> | </pre> | ||
+ | |||
+ | Lua has a special unconditional block mainly used to isolate some local variables: | ||
+ | <pre> | ||
+ | do | ||
+ | --statements | ||
+ | end | ||
+ | </pre> | ||
+ | |||
+ | The <code>break</code> instruction breaks any type of loop and jump to the next instruction after the loop. | ||
+ | Any flow control instruction can be embedded in any other flow control instruction. | ||
'''Examples''': | '''Examples''': | ||
Line 114: | Line 177: | ||
end | end | ||
− | for i = 14, 10, -2.1 do -- it loops for i equal to 14 and 11. | + | for i = 14, 10, -2.1 do -- it loops for i equal to 14 and 11.9 |
+ | end | ||
+ | |||
+ | do | ||
+ | local MyVar=314; | ||
+ | print(MyVar) -- prints '314' and new line | ||
end | end | ||
+ | print(MyVar) -- prints nothing but a new line | ||
</pre> | </pre> | ||
==Functions== | ==Functions== | ||
+ | |||
+ | Functions are just some special variables, and can be declared at the global level or inside a block or another function. | ||
+ | |||
+ | <pre> | ||
+ | -- first syntax version | ||
+ | function MyFunction(arg1, arg2, ...) -- takes 0, 1 to several arguments or undefined number of arguments | ||
+ | -- statements | ||
+ | return result1, result2 -- returns 0, 1 to several variables | ||
+ | end | ||
+ | |||
+ | -- second syntax version | ||
+ | MyFunction = function(arg1, arg2, ...) -- takes 0, 1 to several arguments or undefined number of arguments | ||
+ | -- statements | ||
+ | return result1, result2 -- returns 0, 1 to several variables | ||
+ | end | ||
+ | </pre> | ||
+ | |||
+ | Any of preceding 2 declaration versions creates a function variable named <code>MyFunction</code>. Then the user can call it, use it or assign it a new value. | ||
+ | |||
+ | '''Examples''': | ||
+ | <pre> | ||
+ | MyFunction(MyVar4, MyVar2, MyVar7) -- calling MyFunction with 3 arguments | ||
+ | MyVar1 = MyFunction(MyVar2, MyVar7) -- calling MyFunction with 2 arguments and keep the first result in MyVar1 | ||
+ | print = MyFunction -- now the official print function will be MyFunction | ||
+ | MyFunction = nil -- MyFunction will be unavailable now (but print still keeps original MyFunction) | ||
+ | MyFunction = MyVar7 -- now MyFunction is an alias of the original print function | ||
+ | </pre> | ||
+ | |||
+ | Any type of arguments or return values are copied ''by value'' '''except for table arguments''' copied ''by reference''. | ||
+ | Any absent argument at function call will have a <code>nil</code> value during calling execution. | ||
+ | |||
+ | '''Examples''': | ||
+ | <pre> | ||
+ | Func1=function(Tab, Idx) | ||
+ | if(Idx==nil) then Idx=1 end -- giving a default value 1 | ||
+ | Tab[Idx]=-100 -- changing Idx-th element in the real calling argument table (reference not copy) | ||
+ | Idx=33 -- changing Idx value, no effect to the real argument, this is a local copy value | ||
+ | end | ||
+ | |||
+ | function Show(Tab) -- prints the first 3 elements of Tab, on the same line | ||
+ | print(Tab[1],Tab[2],Tab[3]) | ||
+ | end | ||
+ | |||
+ | function Show2(Tab) -- prints the first 3 elements of Tab, one by line | ||
+ | for Idx=1,3 do print(Tab[Idx]) end | ||
+ | end | ||
+ | |||
+ | function Show3(Tab) -- prints all elements of Tab, one by line | ||
+ | for Idx in ipairs(Tab) do -- using the build-in iterator ipairs on input table | ||
+ | print(Tab[Idx]) -- prints value using the [] operator | ||
+ | end | ||
+ | end | ||
+ | |||
+ | function Show4(Tab) -- prints all elements of Tab, one by line | ||
+ | for Idx,Val in ipairs(Tab) do -- using the build-in iterator ipairs on input table | ||
+ | print(Val) -- prints directly the value | ||
+ | end | ||
+ | end | ||
+ | |||
+ | local MyTab1 = {10, 20, 30} -- local table with 3 numbers | ||
+ | local MyIdx = 2 | ||
+ | Show(MyTab1) -- prints '10 20 30' | ||
+ | Func1(MyTab1,MyIdx) -- change value of 2nd element of MyTab1 but not the value of MyIdx | ||
+ | Show(MyTab1) -- prints '20 -100 30' | ||
+ | Func1(MyTab1) -- change value of 1st element of MyTab1 but not the value of MyIdx | ||
+ | Show(MyTab1) -- prints '-100 -100 30' | ||
+ | Show2(MyTab1) -- prints on 3 lines '-100' '-100' '30' | ||
+ | Show3(MyTab1) -- prints on 3 lines '-100' '-100' '30' | ||
+ | Show4(MyTab1) -- prints on 3 lines '-100' '-100' '30' | ||
+ | </pre> | ||
==Tables== | ==Tables== | ||
+ | |||
+ | Tables are a very special build-in data type providing the only way to create user-defined data structures. Tables are heterogeneous associative arrays where each element is a pair of a '''key/index''' and a '''data/value'''. Data and key types can be different between elements. Lua provides automatic numeric key creation and build-in functions for access, iteration, adding etc. | ||
+ | |||
+ | A table declaration uses <code>{ }</code> and inside elements are separated by <code>,</code> . Implicit keys/indexes are automatically generated and start with 1. Explicit keys/indexes declaration uses a special syntax for each element:<code>[key]=value</code> . A key can't be <code>nil</code> nor a <code>NaN</code> number. | ||
+ | |||
+ | '''Tables syntactic sugar:''' | ||
+ | * Keys of type string, without spaces: | ||
+ | ** Can be declared without surrounding squared breaks and unquoted (like the key of the first element of Tab3 in examples). | ||
+ | ** Can use the point operator <code>.</code> instead of squared brackets operator <code>[ ]</code>. These make tables usage similar to structures/records/classes/namespaces in C/C++/Pascal. | ||
+ | * Automatic insertion: | ||
+ | ** Assigning an unknown (but valid) key in a existing table will automatically create/add this element. | ||
+ | |||
+ | '''Examples''': | ||
+ | <pre> | ||
+ | -- Creates an empty table | ||
+ | Tab0 = {} | ||
+ | |||
+ | -- Creates a homogenous table of 3 pairs (number key/index, number value): (1,5), (2,10), and (3,20) | ||
+ | Tab1 = {5, 10, 20} | ||
+ | |||
+ | -- Creates a heterogeneous table of 3 pairs: (number 1,number 0), (number 2,string "second"), (number 3,function print) | ||
+ | Tab2 = {0, "hours", print} | ||
+ | |||
+ | -- creates a heterogeneous table Tab3 of 3 pairs: (string 'no_space',number 8), (string 'string with spaces',boolean true), (number 12,table Tab2) | ||
+ | -- Warning: the value of the 3rd element is not a new copy of Tab2 but really Tab2 (Lua uses copy by reference for tables!) | ||
+ | Tab3 = {no_space = 8, ['string with spaces'] = true, [12] = Tab2} | ||
+ | |||
+ | -- The next quasi-unreadable instruction will print '8 hours' | ||
+ | Tab2[3](Tab3["no_space"],Tab3[12][2]) | ||
+ | -- Explanation: Tab2[3] value is print, Tab3["no_space"] is 8, Tab3[12] is Tab2 and Tab2[2] is "hours" | ||
+ | |||
+ | Tab3[12][1]=Tab1[2] -- write 10 (value of 2nd element of Tab1) in the value of Tab2[1] (first element of Tab2) | ||
+ | Tab3.no_space = -8 -- write -8 in the value of the first element of Tab3 | ||
+ | Tab3.FourthElement=3.7 -- create a new element in Tab3 with key 'FourthElement' and value 3.7 | ||
+ | |||
+ | function ShowTab(tab) | ||
+ | for i,val in ipairs(tab) | ||
+ | print('tab[',i,']=',val); | ||
+ | end | ||
+ | end | ||
+ | |||
+ | ShowTab(Tab1); -- prints each element of Tab1, one by line | ||
+ | |||
+ | function ShowTypeTab(tab) | ||
+ | for key,val in pairs(tab) | ||
+ | print('type(tab[',key,']) =',type(val)) | ||
+ | end | ||
+ | end | ||
+ | |||
+ | ShowTypeTab(Tab1); -- type(tab[ 1 ]) = number | ||
+ | -- type(tab[ 2 ]) = number | ||
+ | -- type(tab[ 3 ]) = number | ||
+ | |||
+ | ShowTypeTab(Tab3); -- type(tab[ string with spaces ]) = boolean | ||
+ | -- type(tab[ no_spaces ]) = number | ||
+ | -- type(tab[ ForthElement ]) = number | ||
+ | -- type(tab[ 12 ]) = table | ||
+ | |||
+ | Tab2D = {{9,2,3}, | ||
+ | {6,5,4}, | ||
+ | {7,8,1}} -- embedded tables emulate a 3x3 matrix | ||
+ | print(Tab2D[1][1],Tab2D[2][2],#Tab2D,#Tab2D[3],#Tab2D[4]) | ||
+ | -- prints '9 5 3 3' (lenght of Tab2D is 3 and lenght of Tab2D[3] is 3 too) | ||
+ | </pre> | ||
+ | |||
+ | '''Table functions:''' | ||
+ | Lua provides several functions in the table (namespace) <code>table</code>: | ||
+ | * <code>table.insert(tab, val, pos)</code> : insert <code>val</code> in the table <code>tab</code> as new element, after the optional key <code>pos</code> or at the end. | ||
+ | * <code>table.remove(tab, pos)</code> : remove from table <code>tab</code> the element with key <code>pos</code>. | ||
+ | * <code>table.sort(tab)</code> : sort all elements of <code>tab</code> in increasing order of theirs values. | ||
+ | * <code>table.concat(tab, sep)</code> : concatenates all values of <code>tab</code> using an optional separator. | ||
+ | |||
+ | '''Examples''': | ||
+ | <pre> | ||
+ | numbs = {'One','Two','Three','Four'} | ||
+ | print(table.concat(numbs,' ')) -- 'One Two Three Four' | ||
+ | table.insert(numbs,'Five') | ||
+ | print(table.concat(numbs,' ')) -- 'One Two Three Four Five' | ||
+ | table.sort(numbs) | ||
+ | print(table.concat(numbs,' ')) -- 'Five Four One Three Two' | ||
+ | table.remove(numbs,3) | ||
+ | print(table.concat(numbs,' ')) -- 'Five Four Three Two' | ||
+ | </pre> | ||
== External links == | == External links == | ||
* [https://wikipedia.org/wiki/Wikipedia:Lua wikipedia.org/wiki/Wikipedia:Lua] | * [https://wikipedia.org/wiki/Wikipedia:Lua wikipedia.org/wiki/Wikipedia:Lua] | ||
* [https://www.lua.org/ www.lua.org] | * [https://www.lua.org/ www.lua.org] | ||
− | * [http://lua-users.org/wiki/ Lua Wiki] | + | * [http://lua-users.org/wiki/ Lua Users Wiki] |
+ | * [https://upload.wikimedia.org/wikipedia/commons/2/25/LuaProgramming.pdf Wikimedia Lua Programing Book] |
Latest revision as of 17:30, 1 June 2024
Contents
Introduction[edit]
Lua is a lightweight, scripting programming language based on an interpreter generating compiled bytecodes (code executing in a virtual machine).
It was designed in Brasil by Roberto Ierusalimschy, Waldemar Celes and Luiz Henrique de Figueiredo in 1993.
CE Lua is a specific version of Lua interpreter adapted by Dark Byte for Cheat Engine. The CE Lua Engine is a main component of Cheat Engine.
This wiki page is written for Lua beginners. If you know the basic Lua syntax then you can go to the next page.
Syntax[edit]
CE Lua interpreter respects traditional LUA syntax and provides some extra features. The Lua Script Editor provide a real-time colored syntax and a Syntax Check feature (Ctrl+Alt+C).
Comments[edit]
In Lua simple comments begin with --
and end at the end of the line.
Multi-line comments begin with --[[
and end with ]]
.
-- This is a simple comment just to the end of this line This is not a comment but a future syntax error -- This is a new simple comment --[[ First line of a multi-line comment Second line of a multi-line comment Last line of a multi-line comment]]
Variables, types and operators[edit]
In Lua variables are polymorphic (can change the type during theirs lifes). By default a variable is global at Lua Engine level unless the declaration begins with local
modifier.
Any variable can host different data types and use specific operators:
- nil meaning nothing (a variable not defined, or not assigned, or assigned to
nil
)- Comparing operators: comparing any variable to
nil
(var == nil
orvar ~= nil
)
- Comparing operators: comparing any variable to
- a number value (no difference between integer or float values, nor between different precisions)
- Binary arithmetic operators between two numbers:
+
,-
,*
,/
,//
(floor division),%
(modulo),^
(power). - Unary arithmetic operator:
-
(example:var1 = -var2
) - Comparing operators between two numbers giving a boolean:
>
,>=
,<
,<=
,==
,~=
. - Bitwise operators (only on integer values):
&
bitwise AND,|
bitwise OR,~
bitwise XOR,~
bitwise NOT,<<
left shift,>>
right shift.
- Binary arithmetic operators between two numbers:
- a boolean value (equal to
true
orfalse
)- Binary boolean operators:
and
,or
. - Unary boolean operator:
not
.
- Binary boolean operators:
- a string (constants can be surrounded by single
'string'
or double quotes"string"
or double square brackets[[string]]
; the last case accepts new lines inside)- Concatenation operator:
..
between two strings. - Comparing operators between two strings content giving a boolean:
>
,>=
,<
,<=
,==
,~=
. - Length operator:
#
returns the number of characters
- Concatenation operator:
- a table
- Indexing operator:
[ ]
returns the associated value of an index/key in a table - Indexing operator:
.
returns the associated value of a string key in a table - Length operator:
#
returns the integer index of the first element not equal tonil
- Indexing operator:
- a function
The assign operator =
is mandatory just for the global variable declaration and can be use later to modify any variable. Lua supports parallel assignment from a list of values to a list of variables: Var1, Var2, Var3 = 7, "GoesInVar2", 12*12
. First, all values expressions in the right side list are evaluated, any extra value is ignored and any missing value is replaced by nil
. Then these values are assigned to the corresponding variables.
Tips:
- Always use the right operators for the right types.
- Always use parethesis for complex expressions (the expression
not var1==nil or var1~=3
is not equal tonot (var1==nil or var1~=3)
). - Use the function
type
to get a string containing the real type of a variable. - Prefer using local variables versus global variables.
Examples:
local MyVar0 -- local variable having nothing inside so equal to nil MyVar1 = nil -- global variable MyVar1 having nothing inside (no type neither) MyVar2 = UnknownVar -- another global variable equal to nil (because UnknowVar is not yet defined) local MyVar3 = 2+0x10 -- local number variable MyVar3 equal to 18 (2+16) MyVar4 = 'Hello' -- global string variable MyVar4 local MyVar5 = "Hello" -- local string variable MyVar5 having the same string as MyVar3 MyVar6 = [[First Line Second Line.]] -- global multi-line string variable MyVar6 beginning with 'First' and ending with 'Line.' MyVar2 = (1e3 > 7.55) -- now MyVar2 becomes a boolean equal to true MyVar7 = print -- global function variable MyVar7 which can be used as an alias of print function MyVar2, MyVar3 = MyVar3, MyVar2 -- parallel assignment: MyVar2 becomes 18 and MyVar3 becomes true
Automatic typecast (coercion):
When some operators or function calls need it, Lua will try to convert automatically numbers to strings or strings to numbers:
- The expression
'1'+9
is valid and is a number because the string'1'
will be automatically converted to the number1
. - But the expression
'one'+9
is a not valid because the string'one'
can't be automatically converted to a number. - The expression
'Waiting '..10
is valid and is a string because the number10
will be automatically converted to the string'10'
by the presence of..
operator. - But the expressions
7..'days'
or'Waiting '..10..' seconds'
are invalid because Lua interprets the first dot.
after7
or10
as a decimal separator and then it is unable to detect the concatenation operator..
. - Solution: use spaces and parenthesis as much as you need. The following expressions are valid:
('Waiting '..10)..' seconds'
,'Waiting '.. 10 ..' seconds'
, and7 ..'days'
.
Copy operations:
For any copy operation like assignment, function calling arguments and function returns, Lua performs a copy by value (real copy) for nil, numbers, strings, booleans types and performs a copy by reference (not a new copy, just pointing to the original) for tables and functions.
Console output[edit]
Lua uses the print
function to output numericals and strings to the console (use the menu to open the Lua Engine console).
The print
function has a variable number of arguments. Each argument (string or number) will be printed to the console with spaces between arguments and a new line will be added at the end. The default format for numbers is the decimal base with automatic use of decimal point and/or decimal power if necessary.
Examples:
print(MyVar1) -- prints an empty line because MyVal1 is nil print('MyVar3=',MyVar3,MyVar3,MyVar3) -- prints the line 'MyVar3=2 2 2' print("MyVar2 = ",MyVar2) -- prints just the line 'MyVar2 = ' because MyVar2 is not a numerical nor a string print(MyVar4..' and '..MyVar5..' again') -- prints 'Hello and Hello again' print(#MyVar5) -- prints 5 (the lenght of MyVar5) MyVar7("9.9+0.1=",9.9+0.1) -- prints the line '9.9+0.1=10.0' (because MyVar7 is now equal to print) MyVar7('1/0=',1/0) -- prints the line '1/0=inf'
Flow control[edit]
Lua provides a conditional test with multiple, optional branches:
if BooleanExpression then -- if statement(s) body elseif BooleanExpression then -- optional -- elseif statement(s) body else -- optional -- else/default statement(s) body end
and several conditional loops:
while BooleanExpression do -- do statements while BooleanExpression is true --statements end repeat -- repeat statements --statements until BooleanExpression -- until BooleanExpression becomes true for Idx = Start,Stop,Step do -- any numerical value for Start, Stop and Step (Step is optional and defaults to 1) --statements end -- loop while Idx <= Stop (for positive Step) or Idx >= Stop (for negative Step) for KeyIdx,Val in ListExpr do -- it loops over all the ListExpr, giving for each element the KeyIdx and the Val --statements -- KeyIdx and Val available inside the for loop end
Lua has a special unconditional block mainly used to isolate some local variables:
do --statements end
The break
instruction breaks any type of loop and jump to the next instruction after the loop.
Any flow control instruction can be embedded in any other flow control instruction.
Examples:
i=5 while i<80 do -- it loops for i equal to 5, 10, 20, and 40 i=i*2 end i=5 repeat -- it loops for i equal to 10, 20, 40, 80 i=i*2 until i==80 i=5 repeat i=i*2 until i==82 -- warning: this loop will never ending and will block the Lua Engine & Cheat Engine for i = 10, 14 do -- it loops for i equal to 10, 11, 12, 13, and 14 end for i = 10, 14, 2 do -- it loops for i equal to 10, 12, and 14 end for i = 10, 14, 2.1 do -- it loops for i equal to 10 and 12.1 end for i = 10, 14, -2.1 do -- it never loops because the start value 10<14 and step is negative end for i = 14, 10, -2.1 do -- it loops for i equal to 14 and 11.9 end do local MyVar=314; print(MyVar) -- prints '314' and new line end print(MyVar) -- prints nothing but a new line
Functions[edit]
Functions are just some special variables, and can be declared at the global level or inside a block or another function.
-- first syntax version function MyFunction(arg1, arg2, ...) -- takes 0, 1 to several arguments or undefined number of arguments -- statements return result1, result2 -- returns 0, 1 to several variables end -- second syntax version MyFunction = function(arg1, arg2, ...) -- takes 0, 1 to several arguments or undefined number of arguments -- statements return result1, result2 -- returns 0, 1 to several variables end
Any of preceding 2 declaration versions creates a function variable named MyFunction
. Then the user can call it, use it or assign it a new value.
Examples:
MyFunction(MyVar4, MyVar2, MyVar7) -- calling MyFunction with 3 arguments MyVar1 = MyFunction(MyVar2, MyVar7) -- calling MyFunction with 2 arguments and keep the first result in MyVar1 print = MyFunction -- now the official print function will be MyFunction MyFunction = nil -- MyFunction will be unavailable now (but print still keeps original MyFunction) MyFunction = MyVar7 -- now MyFunction is an alias of the original print function
Any type of arguments or return values are copied by value except for table arguments copied by reference.
Any absent argument at function call will have a nil
value during calling execution.
Examples:
Func1=function(Tab, Idx) if(Idx==nil) then Idx=1 end -- giving a default value 1 Tab[Idx]=-100 -- changing Idx-th element in the real calling argument table (reference not copy) Idx=33 -- changing Idx value, no effect to the real argument, this is a local copy value end function Show(Tab) -- prints the first 3 elements of Tab, on the same line print(Tab[1],Tab[2],Tab[3]) end function Show2(Tab) -- prints the first 3 elements of Tab, one by line for Idx=1,3 do print(Tab[Idx]) end end function Show3(Tab) -- prints all elements of Tab, one by line for Idx in ipairs(Tab) do -- using the build-in iterator ipairs on input table print(Tab[Idx]) -- prints value using the [] operator end end function Show4(Tab) -- prints all elements of Tab, one by line for Idx,Val in ipairs(Tab) do -- using the build-in iterator ipairs on input table print(Val) -- prints directly the value end end local MyTab1 = {10, 20, 30} -- local table with 3 numbers local MyIdx = 2 Show(MyTab1) -- prints '10 20 30' Func1(MyTab1,MyIdx) -- change value of 2nd element of MyTab1 but not the value of MyIdx Show(MyTab1) -- prints '20 -100 30' Func1(MyTab1) -- change value of 1st element of MyTab1 but not the value of MyIdx Show(MyTab1) -- prints '-100 -100 30' Show2(MyTab1) -- prints on 3 lines '-100' '-100' '30' Show3(MyTab1) -- prints on 3 lines '-100' '-100' '30' Show4(MyTab1) -- prints on 3 lines '-100' '-100' '30'
Tables[edit]
Tables are a very special build-in data type providing the only way to create user-defined data structures. Tables are heterogeneous associative arrays where each element is a pair of a key/index and a data/value. Data and key types can be different between elements. Lua provides automatic numeric key creation and build-in functions for access, iteration, adding etc.
A table declaration uses { }
and inside elements are separated by ,
. Implicit keys/indexes are automatically generated and start with 1. Explicit keys/indexes declaration uses a special syntax for each element:[key]=value
. A key can't be nil
nor a NaN
number.
Tables syntactic sugar:
- Keys of type string, without spaces:
- Can be declared without surrounding squared breaks and unquoted (like the key of the first element of Tab3 in examples).
- Can use the point operator
.
instead of squared brackets operator[ ]
. These make tables usage similar to structures/records/classes/namespaces in C/C++/Pascal.
- Automatic insertion:
- Assigning an unknown (but valid) key in a existing table will automatically create/add this element.
Examples:
-- Creates an empty table Tab0 = {} -- Creates a homogenous table of 3 pairs (number key/index, number value): (1,5), (2,10), and (3,20) Tab1 = {5, 10, 20} -- Creates a heterogeneous table of 3 pairs: (number 1,number 0), (number 2,string "second"), (number 3,function print) Tab2 = {0, "hours", print} -- creates a heterogeneous table Tab3 of 3 pairs: (string 'no_space',number 8), (string 'string with spaces',boolean true), (number 12,table Tab2) -- Warning: the value of the 3rd element is not a new copy of Tab2 but really Tab2 (Lua uses copy by reference for tables!) Tab3 = {no_space = 8, ['string with spaces'] = true, [12] = Tab2} -- The next quasi-unreadable instruction will print '8 hours' Tab2[3](Tab3["no_space"],Tab3[12][2]) -- Explanation: Tab2[3] value is print, Tab3["no_space"] is 8, Tab3[12] is Tab2 and Tab2[2] is "hours" Tab3[12][1]=Tab1[2] -- write 10 (value of 2nd element of Tab1) in the value of Tab2[1] (first element of Tab2) Tab3.no_space = -8 -- write -8 in the value of the first element of Tab3 Tab3.FourthElement=3.7 -- create a new element in Tab3 with key 'FourthElement' and value 3.7 function ShowTab(tab) for i,val in ipairs(tab) print('tab[',i,']=',val); end end ShowTab(Tab1); -- prints each element of Tab1, one by line function ShowTypeTab(tab) for key,val in pairs(tab) print('type(tab[',key,']) =',type(val)) end end ShowTypeTab(Tab1); -- type(tab[ 1 ]) = number -- type(tab[ 2 ]) = number -- type(tab[ 3 ]) = number ShowTypeTab(Tab3); -- type(tab[ string with spaces ]) = boolean -- type(tab[ no_spaces ]) = number -- type(tab[ ForthElement ]) = number -- type(tab[ 12 ]) = table Tab2D = {{9,2,3}, {6,5,4}, {7,8,1}} -- embedded tables emulate a 3x3 matrix print(Tab2D[1][1],Tab2D[2][2],#Tab2D,#Tab2D[3],#Tab2D[4]) -- prints '9 5 3 3' (lenght of Tab2D is 3 and lenght of Tab2D[3] is 3 too)
Table functions:
Lua provides several functions in the table (namespace) table
:
table.insert(tab, val, pos)
: insertval
in the tabletab
as new element, after the optional keypos
or at the end.table.remove(tab, pos)
: remove from tabletab
the element with keypos
.table.sort(tab)
: sort all elements oftab
in increasing order of theirs values.table.concat(tab, sep)
: concatenates all values oftab
using an optional separator.
Examples:
numbs = {'One','Two','Three','Four'} print(table.concat(numbs,' ')) -- 'One Two Three Four' table.insert(numbs,'Five') print(table.concat(numbs,' ')) -- 'One Two Three Four Five' table.sort(numbs) print(table.concat(numbs,' ')) -- 'Five Four One Three Two' table.remove(numbs,3) print(table.concat(numbs,' ')) -- 'Five Four Three Two'