Copyright © 2015–2018 Lua.org, PUC-Rio. Freely available under the terms of the Lua license.
This section describes the lexis, the syntax, and the semantics of Lua. In other words, this section describes which tokens are valid, how they can be combined, and what their combinations mean.
Language constructs will be explained using the usual extended BNF notation, in which {a} means 0 or more a's, and [a] means an optional a. Non-terminals are shown like non-terminal, keywords are shown like kword, and other terminal symbols are shown like '='. The complete syntax of Lua can be found in Complete Syntax at the end of this manual.
Lua is a free-form language. It ignores spaces (including new lines) and comments between lexical elements (tokens), except as delimiters between names and keywords.
Names (also called identifiers) in Lua can be any string of letters, digits, and underscores, not beginning with a digit and not being a reserved word. Identifiers are used to name variables, table fields, and labels.
The following keywords are reserved and cannot be used as names:
and break do else elseif end false for function goto if in local nil not or repeat return then true until while
Lua is a case-sensitive language:
and
is a reserved word, but And
and AND
are two different, valid names.
As a convention,
programs should avoid creating
names that start with an underscore followed by
one or more uppercase letters (such as _VERSION
).
The following strings denote other tokens:
+ - * / % ^ # & ~ | << >> // == ~= <= >= < > = ( ) { } [ ] :: ; : , . .. ...
Literal strings
can be delimited by matching single or double quotes,
and can contain the following C-like escape sequences:
'\a
' (bell),
'\b
' (backspace),
'\f
' (form feed),
'\n
' (newline),
'\r
' (carriage return),
'\t
' (horizontal tab),
'\v
' (vertical tab),
'\\
' (backslash),
'\"
' (quotation mark [double quote]),
and '\'
' (apostrophe [single quote]).
A backslash followed by a real newline
results in a newline in the string.
The escape sequence '\z
' skips the following span
of white-space characters,
including line breaks;
it is particularly useful to break and indent a long literal string
into multiple lines without adding the newlines and spaces
into the string contents.
Strings in Lua can contain any 8-bit value, including embedded zeros,
which can be specified as '\0
'.
More generally,
we can specify any byte in a literal string by its numeric value.
This can be done
with the escape sequence \xXX
,
where XX is a sequence of exactly two hexadecimal digits,
or with the escape sequence \ddd
,
where ddd is a sequence of up to three decimal digits.
(Note that if a decimal escape sequence is to be followed by a digit,
it must be expressed using exactly three digits.)
The UTF-8 encoding of a Unicode character
can be inserted in a literal string with
the escape sequence \u{XXX}
(note the mandatory enclosing brackets),
where XXX is a sequence of one or more hexadecimal digits
representing the character code point.
Literal strings can also be defined using a long format
enclosed by long brackets.
We define an opening long bracket of level n as an opening
square bracket followed by n equal signs followed by another
opening square bracket.
So, an opening long bracket of level 0 is written as [[
,
an opening long bracket of level 1 is written as [=[
,
and so on.
A closing long bracket is defined similarly;
for instance,
a closing long bracket of level 4 is written as ]====]
.
A long literal starts with an opening long bracket of any level and
ends at the first closing long bracket of the same level.
It can contain any text except a closing bracket of the same level.
Literals in this bracketed form can run for several lines,
do not interpret any escape sequences,
and ignore long brackets of any other level.
Any kind of end-of-line sequence
(carriage return, newline, carriage return followed by newline,
or newline followed by carriage return)
is converted to a simple newline.
Any byte in a literal string not explicitly affected by the previous rules represents itself. However, Lua opens files for parsing in text mode, and the system file functions may have problems with some control characters. So, it is safer to represent non-text data as a quoted literal with explicit escape sequences for non-text characters.
For convenience,
when the opening long bracket is immediately followed by a newline,
the newline is not included in the string.
As an example, in a system using ASCII
(in which 'a
' is coded as 97,
newline is coded as 10, and '1
' is coded as 49),
the five literal strings below denote the same string:
a = 'alo\n123"' a = "alo\n123\"" a = '\97lo\10\04923"' a = [[alo 123"]] a = [==[ alo 123"]==]
A numeric constant (or numeral)
can be written with an optional fractional part
and an optional decimal exponent,
marked by a letter 'e
' or 'E
'.
Lua also accepts hexadecimal constants,
which start with 0x
or 0X
.
Hexadecimal constants also accept an optional fractional part
plus an optional binary exponent,
marked by a letter 'p
' or 'P
'.
A numeric constant with a fractional dot or an exponent
denotes a float;
otherwise it denotes an integer.
Examples of valid integer constants are
3 345 0xff 0xBEBADA
Examples of valid float constants are
3.0 3.1416 314.16e-2 0.31416E1 34e1 0x0.1E 0xA23p-4 0X1.921FB54442D18P+1
A comment starts with a double hyphen (--
)
anywhere outside a string.
If the text immediately after --
is not an opening long bracket,
the comment is a short comment,
which runs until the end of the line.
Otherwise, it is a long comment,
which runs until the corresponding closing long bracket.
Long comments are frequently used to disable code temporarily.
Variables are places that store values. There are three kinds of variables in Lua: global variables, local variables, and table fields.
A single name can denote a global variable or a local variable (or a function's formal parameter, which is a particular kind of local variable):
var ::= Name
Name denotes identifiers, as defined in Lexical Conventions.
Any variable name is assumed to be global unless explicitly declared as a local (see Local Declarations). Local variables are lexically scoped: local variables can be freely accessed by functions defined inside their scope (see Visibility Rules).
Before the first assignment to a variable, its value is nil.
Square brackets are used to index a table:
var ::= prefixexp '[' exp ']'
The meaning of accesses to table fields can be changed via metatables (see Metatables and Metamethods).
The syntax var.Name
is just syntactic sugar for
var["Name"]
:
var ::= prefixexp '.' Name
An access to a global variable x
is equivalent to _ENV.x
.
Due to the way that chunks are compiled,
_ENV
is never a global name (see Environments and the Global Environment).
Lua supports an almost conventional set of statements, similar to those in Pascal or C. This set includes assignments, control structures, function calls, and variable declarations.
A block is a list of statements, which are executed sequentially:
block ::= {stat}
Lua has empty statements that allow you to separate statements with semicolons, start a block with a semicolon or write two semicolons in sequence:
stat ::= ';'
Function calls and assignments can start with an open parenthesis. This possibility leads to an ambiguity in Lua's grammar. Consider the following fragment:
a = b + c (print or io.write)('done')
The grammar could see it in two ways:
a = b + c(print or io.write)('done') a = b + c; (print or io.write)('done')
The current parser always sees such constructions in the first way, interpreting the open parenthesis as the start of the arguments to a call. To avoid this ambiguity, it is a good practice to always precede with a semicolon statements that start with a parenthesis:
;(print or io.write)('done')
A block can be explicitly delimited to produce a single statement:
stat ::= do block end
Explicit blocks are useful to control the scope of variable declarations. Explicit blocks are also sometimes used to add a return statement in the middle of another block (see Control Structures).
The unit of compilation of Lua is called a chunk. Syntactically, a chunk is simply a block:
chunk ::= block
Lua handles a chunk as the body of an anonymous function
with a variable number of arguments
(see Function Definitions).
As such, chunks can define local variables,
receive arguments, and return values.
Moreover, such anonymous function is compiled as in the
scope of an external local variable called _ENV
(see Environments and the Global Environment).
The resulting function always has _ENV
as its only upvalue,
even if it does not use that variable.
A chunk can be stored in a file or in a string inside the host program. To execute a chunk, Lua first loads it, precompiling the chunk's code into instructions for a virtual machine, and then Lua executes the compiled code with an interpreter for the virtual machine.
Chunks can also be precompiled into binary form;
see program luac
and function string.dump
for details.
Programs in source and compiled forms are interchangeable;
Lua automatically detects the file type and acts accordingly (see load
).
Lua allows multiple assignments. Therefore, the syntax for assignment defines a list of variables on the left side and a list of expressions on the right side. The elements in both lists are separated by commas:
stat ::= varlist '=' explist varlist ::= var {',' var} explist ::= exp {',' exp}
Expressions are discussed in Expressions.
Before the assignment, the list of values is adjusted to the length of the list of variables. If there are more values than needed, the excess values are thrown away. If there are fewer values than needed, the list is extended with as many nil's as needed. If the list of expressions ends with a function call, then all values returned by that call enter the list of values, before the adjustment (except when the call is enclosed in parentheses; see Expressions).
The assignment statement first evaluates all its expressions and only then the assignments are performed. Thus the code
i = 3 i, a[i] = i+1, 20
sets a[3]
to 20, without affecting a[4]
because the i
in a[i]
is evaluated (to 3)
before it is assigned 4.
Similarly, the line
x, y = y, x
exchanges the values of x
and y
,
and
x, y, z = y, z, x
cyclically permutes the values of x
, y
, and z
.
The meaning of assignments to table fields and global variables (which are actually table fields, too) can be changed via metatables (see Metatables and Metamethods).
An assignment to a global name x = val
is equivalent to the assignment
_ENV.x = val
(see Environments and the Global Environment).
The control structures if, while, and repeat have the usual meaning and familiar syntax:
stat ::= while exp do block end stat ::= repeat block until exp stat ::= if exp then block {elseif exp then block} [else block] end
Lua also has a for statement, in two flavors (see For Statement).
The condition expression of a control structure can return any value. Both false and nil are considered false. All values different from nil and false are considered true (in particular, the number 0 and the empty string are also true).
In the repeat–until loop, the inner block does not end at the until keyword, but only after the condition. So, the condition can refer to local variables declared inside the loop block.
The goto statement transfers the program control to a label. For syntactical reasons, labels in Lua are considered statements too:
stat ::= goto Name stat ::= label label ::= '::' Name '::'
A label is visible in the entire block where it is defined, except inside nested blocks where a label with the same name is defined and inside nested functions. A goto may jump to any visible label as long as it does not enter into the scope of a local variable.
Labels and empty statements are called void statements, as they perform no actions.
The break statement terminates the execution of a while, repeat, or for loop, skipping to the next statement after the loop:
stat ::= break
A break ends the innermost enclosing loop.
The return statement is used to return values from a function or a chunk (which is an anonymous function). Functions can return more than one value, so the syntax for the return statement is
stat ::= return [explist] [';']
The return statement can only be written
as the last statement of a block.
If it is really necessary to return in the middle of a block,
then an explicit inner block can be used,
as in the idiom do return end
,
because now return is the last statement in its (inner) block.
The for statement has two forms: one numerical and one generic.
The numerical for loop repeats a block of code while a control variable runs through an arithmetic progression. It has the following syntax:
stat ::= for Name '=' exp ',' exp [',' exp] do block end
The block is repeated for name starting at the value of the first exp, until it passes the second exp by steps of the third exp. More precisely, a for statement like
for v = e1, e2, e3 do block end
is equivalent to the code:
do local var, limit, step = tonumber(e1), tonumber(e2), tonumber(e3) if not (var and limit and step) then error() end var = var - step while true do var = var + step if (step >= 0 and var > limit) or (step < 0 and var < limit) then break end local v = var block end end
Note the following:
var
, limit
, and step
are invisible variables.
The names shown here are for explanatory purposes only.
v
is local to the loop body.
If you need its value after the loop,
assign it to another variable before exiting the loop.
The generic for statement works over functions, called iterators. On each iteration, the iterator function is called to produce a new value, stopping when this new value is nil. The generic for loop has the following syntax:
stat ::= for namelist in explist do block end namelist ::= Name {',' Name}
A for statement like
for var_1, ···, var_n in explist do block end
is equivalent to the code:
do local f, s, var = explist while true do local var_1, ···, var_n = f(s, var) if var_1 == nil then break end var = var_1 block end end
Note the following:
explist
is evaluated only once.
Its results are an iterator function,
a state,
and an initial value for the first iterator variable.
f
, s
, and var
are invisible variables.
The names are here for explanatory purposes only.
var_i
are local to the loop;
you cannot use their values after the for ends.
If you need these values,
then assign them to other variables before breaking or exiting the loop.
To allow possible side-effects, function calls can be executed as statements:
stat ::= functioncall
In this case, all returned values are thrown away. Function calls are explained in Function Calls.
Local variables can be declared anywhere inside a block. The declaration can include an initial assignment:
stat ::= local namelist ['=' explist]
If present, an initial assignment has the same semantics of a multiple assignment (see Assignment). Otherwise, all variables are initialized with nil.
A chunk is also a block (see Chunks), and so local variables can be declared in a chunk outside any explicit block.
The visibility rules for local variables are explained in Visibility Rule.
The basic expressions in Lua are the following:
exp ::= prefixexp exp ::= nil | false | true exp ::= Numeral exp ::= LiteralString exp ::= functiondef exp ::= tableconstructor exp ::= '...' exp ::= exp binop exp exp ::= unop exp prefixexp ::= var | functioncall | '(' exp ')'
Numerals and literal strings are explained in Lexical Conventions;
variables are explained here;
function definitions are explained here;
function calls are explained here;
table constructors are explained here.
Vararg expressions,
denoted by three dots ('...
'), can only be used when
directly inside a vararg function;
they are explained in Function Definitions.
Binary operators comprise arithmetic operators, bitwise operators, relational operators, logical operators, and the concatenation operator. Unary operators comprise the unary minus (see Arithmetic Operators), the unary bitwise not (see Bitwise Operators), the unary logical not (see Logical Operators), and the unary length operator.
Both function calls and vararg expressions can result in multiple values. If a function call is used as a statement, then its return list is adjusted to zero elements, thus discarding all returned values. If an expression is used as the last (or the only) element of a list of expressions, then no adjustment is made (unless the expression is enclosed in parentheses). In all other contexts, Lua adjusts the result list to one element, either discarding all values except the first one or adding a single nil if there are no values.
Here are some examples:
f() -- adjusted to 0 results g(f(), x) -- f() is adjusted to 1 result g(x, f()) -- g gets x plus all results from f() a,b,c = f(), x -- f() is adjusted to 1 result (c gets nil) a,b = ... -- a gets the first vararg argument, b gets the second (both a and b can get nil if there is no corresponding vararg argument) a,b,c = x, f() -- f() is adjusted to 2 results a,b,c = f() -- f() is adjusted to 3 results return f() -- returns all results from f() return ... -- returns all received vararg arguments return x,y,f() -- returns x, y, and all results from f() {f()} -- creates a list with all results from f() {...} -- creates a list with all vararg arguments {f(), nil} -- f() is adjusted to 1 result
Any expression enclosed in parentheses always results in only one value.
Thus,
(f(x,y,z))
is always a single value,
even if f
returns several values.
(The value of (f(x,y,z))
is the first value returned by f
or nil if f
does not return any values.)
Lua supports the following arithmetic operators:
+
: addition-
: subtraction*
: multiplication/
: float division//
: floor division%
: modulo^
: exponentiation-
: unary minusWith the exception of exponentiation and float division, the arithmetic operators work as follows: If both operands are integers, the operation is performed over integers and the result is an integer. Otherwise, if both operands are numbers or strings that can be converted to numbers (see Coercions and Conversions), then they are converted to floats, the operation is performed following the usual rules for floating-point arithmetic (usually the IEEE 754 standard), and the result is a float.
Exponentiation and float division (/
)
always convert their operands to floats
and the result is always a float.
Exponentiation uses the ISO C function pow
,
so that it works for non-integer exponents too.
Floor division (//
) is a division
that rounds the quotient towards minus infinity,
that is, the floor of the division of its operands.
Modulo is defined as the remainder of a division that rounds the quotient towards minus infinity (floor division).
In case of overflows in integer arithmetic, all operations wrap around, according to the usual rules of two-complement arithmetic. (In other words, they return the unique representable integer that is equal modulo 264 to the mathematical result.)
Lua supports the following bitwise operators:
&
: bitwise and|
: bitwise or~
: bitwise exclusive or>>
: right shift<<
: left shift~
: unary bitwise notAll bitwise operations convert its operands to integers (see Coercions and Conversions), operate on all bits of those integers, and result in an integer.
Both right and left shifts fill the vacant bits with zeros. Negative displacements shift to the other direction; displacements with absolute values equal to or higher than the number of bits in an integer result in zero (as all bits are shifted out).
Lua provides some automatic conversions between some types and representations at run time. Bitwise operators always convert float operands to integers. Exponentiation and float division always convert integer operands to floats. All other arithmetic operations applied to mixed numbers (integers and floats) convert the integer operand to a float; this is called the usual rule. The C API also converts both integers to floats and floats to integers, as needed. Moreover, string concatenation accepts numbers as arguments, besides strings.
Lua also converts strings to numbers, whenever a number is expected.
In a conversion from integer to float, if the integer value has an exact representation as a float, that is the result. Otherwise, the conversion gets the nearest higher or the nearest lower representable value. This kind of conversion never fails.
The conversion from float to integer checks whether the float has an exact representation as an integer (that is, the float has an integral value and it is in the range of integer representation). If it does, that representation is the result. Otherwise, the conversion fails.
The conversion from strings to numbers goes as follows: First, the string is converted to an integer or a float, following its syntax and the rules of the Lua lexer. (The string may have also leading and trailing spaces and a sign.) Then, the resulting number (float or integer) is converted to the type (float or integer) required by the context (e.g., the operation that forced the conversion).
The conversion from numbers to strings uses a
non-specified human-readable format.
For complete control over how numbers are converted to strings,
use the format
function from the string library
(see string.format
).
Lua supports the following relational operators:
==
: equality~=
: inequality<
: less than>
: greater than<=
: less or equal>=
: greater or equalThese operators always result in false or true.
Equality (==
) first compares the type of its operands.
If the types are different, then the result is false.
Otherwise, the values of the operands are compared.
Strings are compared in the obvious way.
Numbers are equal if they denote the same mathematical value.
Tables, userdata, and threads are compared by reference: two objects are considered equal only if they are the same object. Every time you create a new object (a table, userdata, or thread), this new object is different from any previously existing object. A closure is always equal to itself. Closures with any detectable difference (different behavior, different definition) are always different. Closures created at different times but with no detectable differences may be classified as equal or not (depending on internal caching details).
You can change the way that Lua compares tables and userdata by using the "eq" metamethod (see Metatables and Metamethods).
Equality comparisons do not convert strings to numbers
or vice versa.
Thus, "0"==0
evaluates to false,
and t[0]
and t["0"]
denote different
entries in a table.
The operator ~=
is exactly the negation of equality (==
).
The order operators work as follows.
If both arguments are numbers,
then they are compared according to their mathematical values
(regardless of their subtypes).
Otherwise, if both arguments are strings,
then their values are compared according to the current locale.
Otherwise, Lua tries to call the "lt" or the "le"
metamethod (see Metatables and Metamethods).
A comparison a > b
is translated to b < a
and a >= b
is translated to b <= a
.
Following the IEEE 754 standard, NaN is considered neither smaller than, nor equal to, nor greater than any value (including itself).
The logical operators in Lua are and, or, and not. Like the control structures, all logical operators consider both false and nil as false and anything else as true.
The negation operator not always returns false or true. The conjunction operator and returns its first argument if this value is false or nil; otherwise, and returns its second argument. The disjunction operator or returns its first argument if this value is different from nil and false; otherwise, or returns its second argument. Both and and or use short-circuit evaluation; that is, the second operand is evaluated only if necessary. Here are some examples:
10 or 20 --> 10 10 or error() --> 10 nil or "a" --> "a" nil and 10 --> nil false and error() --> false false and nil --> false false or nil --> nil 10 and 20 --> 20
(In this manual,
-->
indicates the result of the preceding expression.)
The string concatenation operator in Lua is
denoted by two dots ('..
').
If both operands are strings or numbers, then they are converted to
strings according to the rules described in Coercions and Conversions.
Otherwise, the __concat
metamethod is called (see Metatables and Metamethods).
The length operator is denoted by the unary prefix operator #
.
The length of a string is its number of bytes
(that is, the usual meaning of string length when each
character is one byte).
A program can modify the behavior of the length operator for
any value but strings through the __len
metamethod (see Metatables and Metamethods).
Unless a __len
metamethod is given,
the length of a table t
is only defined if the
table is a sequence,
that is,
the set of its positive numeric keys is equal to {1..n}
for some non-negative integer n.
In that case, n is its length.
Note that a table like
{10, 20, nil, 40}
is not a sequence, because it has the key 4
but does not have the key 3
.
(So, there is no n such that the set {1..n} is equal
to the set of positive numeric keys of that table.)
Note, however, that non-numeric keys do not interfere
with whether a table is a sequence.
Operator precedence in Lua follows the table below, from lower to higher priority:
or and < > <= >= ~= == | ~ & << >> .. + - * / // % unary operators (not # - ~) ^
As usual,
you can use parentheses to change the precedences of an expression.
The concatenation ('..
') and exponentiation ('^
')
operators are right associative.
All other binary operators are left associative.
Table constructors are expressions that create tables. Every time a constructor is evaluated, a new table is created. A constructor can be used to create an empty table or to create a table and initialize some of its fields. The general syntax for constructors is
tableconstructor ::= '{' [fieldlist] '}' fieldlist ::= field {fieldsep field} [fieldsep] field ::= '[' exp ']' '=' exp | Name '=' exp | exp fieldsep ::= ',' | ';'
Each field of the form [exp1] = exp2
adds to the new table an entry
with key exp1
and value exp2
.
A field of the form name = exp
is equivalent to
["name"] = exp
.
Finally, fields of the form exp
are equivalent to
[i] = exp
, where i
are consecutive integers
starting with 1.
Fields in the other formats do not affect this counting.
For example,
a = { [f(1)] = g; "x", "y"; x = 1, f(x), [30] = 23; 45 }
is equivalent to
do local t = {} t[f(1)] = g t[1] = "x" -- 1st exp t[2] = "y" -- 2nd exp t.x = 1 -- t["x"] = 1 t[3] = f(x) -- 3rd exp t[30] = 23 t[4] = 45 -- 4th exp a = t end
The order of the assignments in a constructor is undefined. (This order would be relevant only when there are repeated keys.)
If the last field in the list has the form exp
and the expression is a function call or a vararg expression,
then all values returned by this expression enter the list consecutively
(see Function Calls).
The field list can have an optional trailing separator, as a convenience for machine-generated code.
A function call in Lua has the following syntax:
functioncall ::= prefixexp args
In a function call, first prefixexp and args are evaluated. If the value of prefixexp has type function, then this function is called with the given arguments. Otherwise, the prefixexp "call" metamethod is called, having as first argument the value of prefixexp, followed by the original call arguments (see Metatables and Metamethods).
The form
functioncall ::= prefixexp ':' Name args
can be used to call "methods".
A call v:name(args)
is syntactic sugar for v.name(v,args)
,
except that v
is evaluated only once.
Arguments have the following syntax:
args ::= '(' [explist] ')' args ::= tableconstructor args ::= LiteralString
All argument expressions are evaluated before the call.
A call of the form f{fields}
is
syntactic sugar for f({fields})
;
that is, the argument list is a single new table.
A call of the form f'string'
(or f"string"
or f[[string]]
)
is syntactic sugar for f('string')
;
that is, the argument list is a single literal string.
A call of the form return functioncall
is called
a tail call.
Lua implements proper tail calls
(or proper tail recursion):
in a tail call,
the called function reuses the stack entry of the calling function.
Therefore, there is no limit on the number of nested tail calls that
a program can execute.
However, a tail call erases any debug information about the
calling function.
Note that a tail call only happens with a particular syntax,
where the return has one single function call as argument;
this syntax makes the calling function return exactly
the returns of the called function.
So, none of the following examples are tail calls:
return (f(x)) -- results adjusted to 1 return 2 * f(x) return x, f(x) -- additional results f(x); return -- results discarded return x or f(x) -- results adjusted to 1
The syntax for function definition is
functiondef ::= function funcbody funcbody ::= '(' [parlist] ')' block end
The following syntactic sugar simplifies function definitions:
stat ::= function funcname funcbody stat ::= local function Name funcbody funcname ::= Name {'.' Name} [':' Name]
The statement
function f () body end
translates to
f = function () body end
The statement
function t.a.b.c.f () body end
translates to
t.a.b.c.f = function () body end
The statement
local function f () body end
translates to
local f; f = function () body end
not to
local f = function () body end
(This only makes a difference when the body of the function
contains references to f
.)
A function definition is an executable expression, whose value has type function. When Lua precompiles a chunk, all its function bodies are precompiled too. Then, whenever Lua executes the function definition, the function is instantiated (or closed). This function instance (or closure) is the final value of the expression.
Parameters act as local variables that are initialized with the argument values:
parlist ::= namelist [',' '...'] | '...'
When a function is called,
the list of arguments is adjusted to
the length of the list of parameters,
unless the function is a vararg function,
which is indicated by three dots ('...
')
at the end of its parameter list.
A vararg function does not adjust its argument list;
instead, it collects all extra arguments and supplies them
to the function through a vararg expression,
which is also written as three dots.
The value of this expression is a list of all actual extra arguments,
similar to a function with multiple results.
If a vararg expression is used inside another expression
or in the middle of a list of expressions,
then its return list is adjusted to one element.
If the expression is used as the last element of a list of expressions,
then no adjustment is made
(unless that last expression is enclosed in parentheses).
As an example, consider the following definitions:
function f(a, b) end function g(a, b, ...) end function r() return 1,2,3 end
Then, we have the following mapping from arguments to parameters and to the vararg expression:
CALL PARAMETERS f(3) a=3, b=nil f(3, 4) a=3, b=4 f(3, 4, 5) a=3, b=4 f(r(), 10) a=1, b=10 f(r()) a=1, b=2 g(3) a=3, b=nil, ... --> (nothing) g(3, 4) a=3, b=4, ... --> (nothing) g(3, 4, 5, 8) a=3, b=4, ... --> 5 8 g(5, r()) a=5, b=1, ... --> 2 3
Results are returned using the return statement (see Control Structures). If control reaches the end of a function without encountering a return statement, then the function returns with no results.
There is a system-dependent limit on the number of values that a function may return. This limit is guaranteed to be larger than 1000.
The colon syntax
is used for defining methods,
that is, functions that have an implicit extra parameter self
.
Thus, the statement
function t.a.b.c:f (params) body end
is syntactic sugar for
t.a.b.c.f = function (self, params) body end
Lua is a lexically scoped language. The scope of a local variable begins at the first statement after its declaration and lasts until the last non-void statement of the innermost block that includes the declaration. Consider the following example:
x = 10 -- global variable do -- new block local x = x -- new 'x', with value 10 print(x) --> 10 x = x+1 do -- another block local x = x+1 -- another 'x' print(x) --> 12 end print(x) --> 11 end print(x) --> 10 (the global one)
Notice that, in a declaration like local x = x
,
the new x
being declared is not in scope yet,
and so the second x
refers to the outside variable.
Because of the lexical scoping rules, local variables can be freely accessed by functions defined inside their scope. A local variable used by an inner function is called an upvalue, or external local variable, inside the inner function.
Notice that each execution of a local statement defines new local variables. Consider the following example:
a = {} local x = 20 for i=1,10 do local y = 0 a[i] = function () y=y+1; return x+y end end
The loop creates ten closures
(that is, ten instances of the anonymous function).
Each of these closures uses a different y
variable,
while all of them share the same x
.
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