This document covers the syntax, built-in macros, and special forms recognized by the Fennel compiler. It does not include built-in Lua functions; see the Lua reference manual or the Lua primer for that. This is not an introductory text; see the tutorial for that. If you already have a piece of Lua code you just want to see translated to Fennel, use antifennel.
A macro is a function which runs at compile time and transforms some Fennel code into different Fennel. A special form (or special) is a primitive construct which emits Lua code directly. When you are coding, you don't need to care about the difference between built-in macros and special forms; it is an implementation detail.
Remember that Fennel relies completely on Lua for its runtime. Everything Fennel does happens at compile-time, so you will need to familiarize yourself with Lua's standard library functions. Thankfully it's much smaller than almost any other language.
The one exception to this compile-time rule is the fennel.view
function which returns a string representation of any Fennel data
suitable for printing. But this is not part of the language itself; it
is a library function which can be used from Lua just as easily.
Fennel source code should be UTF-8-encoded text.
(parentheses)
: used to delimit lists, which are primarily used to
denote calls to functions, macros, and specials, but also can be used
in binding contexts to bind to multiple values. Lists are a
compile-time construct; they are not used at runtime. For example:
(print "hello world")
{curly brackets}
: used to denote key/value table
literals, for example: {:a 1 :b 2}
[square brackets]
: used to denote sequential
tables, which can be used for literal data structures and also in
specials and macros to delimit where new identifiers are introduced,
such as argument lists or let bindings. For example: [1 2 3]
The syntax for numbers is the same as Lua's, except that underscores may be used to separate digits for readability. Non-ASCII digits are not yet supported.
The syntax for strings uses double-quotes "
around the
string's contents. Double quotes inside a string must be escaped with
backslashes. The syntax for these is the same as Lua's, except
that strings may contain newline characters. Single-quoted or long
bracket strings are not supported.
Fennel has a lot fewer restrictions on identifiers than Lua. Identifiers are represented by symbols, but identifiers are not exactly the same as symbols; some symbols are used by macros for things other than identifiers. Symbols may not begin with digits or a colon, but may have digits anywhere else. Beyond that, any unicode characters are accepted as long as they are not unprintable or whitespace, one of the delimiter characters mentioned above, one of the a prefix characters listed below, or one of these reserved characters:
- single quote:
'
- tilde:
~
- semicolon:
;
- at:
@
Underscores are allowed in identifier names, but dashes are preferred as word separators. By convention, identifiers starting with underscores are used to indicate that a local is bound but not meant to be used.
The ampersand character &
is allowed in symbols but not in
identifiers. This allows it to be reserved for macros, like the
behavior of &as
in destructuring.
Symbols that contain a dot .
or colon :
are considered
"multi symbols". The part of the symbol before the first dot or colon is
used as an identifier, and the part after the dot or colon is a field
looked up on the local identified. A colon is only allowed before the
final segment of a multi symbol, so x.y:z
is valid but a:b.c
is
not. Colon multi symbols cannot be used for anything but method calls.
Fennel also supports certain kinds of strings that begin with a colon
as long as they don't contain any characters which wouldn't be allowed
in a symbol, for example :fennel-lang.org
is a string.
Spaces, tabs, newlines, vertical tabs, form feeds, and carriage returns are counted as whitespace. Non-ASCII whitespace characters are not yet supported.
Certain prefixes are expanded by the parser into longhand equivalents:
#foo
expands to(hashfn foo)
`foo
expands to(quote foo)
,foo
expands to(unquote foo)
A semicolon and everything following it up to the end of the line is a comment.
Creates a function which binds the arguments given inside the square
brackets. Will accept any number of arguments; ones in excess of the
declared ones are ignored, and if not enough arguments are supplied to
cover the declared ones, the remaining ones are given values of nil
.
Example:
(fn pxy [x y]
(print (+ x y)))
Giving it a name is optional; if one is provided it will be bound to it as a local. The following mean exactly the same thing; the first is preferred mostly for indentation reasons, but also because it allows recursion:
(fn pxy [x y]
(print (+ x y)))
(local pxy (fn [x y]
(print (+ x y))))
Providing a name that's a table field will cause it to be inserted in a table instead of bound as a local:
(local functions {})
(fn functions.p [x y z]
(print (* x (+ y z))))
;; equivalent to:
(set functions.p (fn [x y z]
(print (* x (+ y z)))))
Like Lua, functions in Fennel support tail-call optimization, allowing (among other things) functions to recurse indefinitely without overflowing the stack, provided the call is in a tail position.
The final form in this and all other function forms is used as the return value.
Creates a function like fn
does, but throws an error at runtime if
any of the listed arguments are nil, unless its identifier begins with ?
.
Example:
(lambda [x ?y z]
(print (- x (* (or ?y 1) z))))
Note that the Lua runtime will fill in missing arguments with nil when they are not provided by the caller, so an explicit nil argument is no different than omitting an argument.
Programmers coming from other languages in which it is an error to
call a function with a different number of arguments than it is
defined with often get tripped up by the behavior of fn
. This is
where lambda
is most useful.
The lambda
, case
, case-try
, match
and match-try
forms are the only
place where the ?foo
notation is used by the compiler to indicate that a nil
value is allowed, but it is a useful notation to communicate intent anywhere a
new local is introduced.
The λ
form is an alias for lambda
and behaves identically.
(Since 0.3.0)
The fn
, lambda
, λ
and macro
forms accept an optional docstring.
(fn pxy [x y]
"Print the sum of x and y"
(print (+ x y)))
(λ pxyz [x ?y z]
"Print the sum of x, y, and z. If y is not provided, defaults to 0."
(print (+ x (or ?y 0) z)))
These are ignored by default outside of the REPL, unless metadata
is enabled from the CLI (---metadata
) or compiler options {useMetadata=true}
,
in which case they are stored in a metadata table along with the arglist,
enabling viewing function docs via the doc
macro.
;; this only works in the repl
>> ,doc pxy
(pxy x y)
Print the sum of x and y
All function metadata will be garbage collected along with the function itself.
Docstrings and other metadata can also be accessed via functions on the fennel
API with fennel.doc
and fennel.metadata
.
(Since 1.1.0)
All forms that accept a docstring will also accept a metadata table in the same place:
(fn add [...]
{:fnl/docstring "Add arbitrary amount of numbers."
:fnl/arglist [a b & more]}
(match (values (select :# ...) ...)
(0) 0
(1 a) a
(2 a b) (+ a b)
(_ a b) (add (+ a b) (select 3 ...))))
Here the arglist is overridden by that in the metadata table (note
that the contents of the table are implicitly quoted). Calling ,doc
command in the REPL prints specified argument list:
>> ,doc add
(add a b & more)
Add arbitrary amount of numbers.
(Since 1.3.0)
Arbitrary metadata keys are allowed in the metadata table syntax:
(fn foo []
{:deprecated "v1.9.0"
:fnl/docstring "*DEPRECATED* use foo2"}
;; old way to do stuff
)
(fn foo2 [x]
{:added "v2.0.0"
:fnl/docstring "Incompatible but better version of foo!"}
;; do stuff better, now with x!
x)
In this example, the deprecated
and added
keys are used to store a
version of a hypothetical library on which the functions were
deprecated or added. External tooling then can leverage this
information by using Fennel's metadata API:
>> (local {: metadata} (require :fennel))
>> (metadata:get foo :deprecated)
"v1.9.0"
>> (metadata:get foo2 :added)
"v2.0.0"
Such metadata can be any data literal, including tables, with the only restriction that there are no side effects. Fennel's lists are disallowed as metadata values.
(Since 1.3.1)
For editing convenience, the metadata table literals are allowed after docstrings:
(fn some-function [x ...]
"Docstring for some-function."
{:fnl/arglist [x & xs]
:other :metadata}
(let [xs [...]]
;; ...
))
In this case, the documentation string is automatically inserted to the metadata table by the compiler.
The whole metadata table can be obtained by calling metadata:get
without the key
argument:
>> (local {: metadata} (require :fennel))
>> (metadata:get some-function)
{:fnl/arglist ["x" "&" "xs"]
:fnl/docstring "Docstring for some-function."
:other "metadata"}
Fennel itself only uses the fnl/docstring
and fnl/arglist
metadata
keys but third-party code can make use of arbitrary keys.
(Since 0.3.0)
It's pretty easy to create function literals, but Fennel provides an even shorter form of functions. Hash functions are anonymous functions of one form, with implicitly named arguments. All of the below functions are functionally equivalent:
(fn [a b] (+ a b))
(hashfn (+ $1 $2)) ; implementation detail; don't use directly
#(+ $1 $2)
This style of anonymous function is useful as a parameter to higher order functions. It's recommended only for simple one-line functions that get passed as arguments to other functions.
The current implementation only allows for hash functions to use up to
9 arguments, each named $1
through $9
, or those with varargs,
delineated by $...
instead of the usual ...
. A lone $
in a hash
function is treated as an alias for $1
.
Hash functions are defined with the hashfn
macro or special character #
,
which wraps its single argument in a function literal. For example,
#$3 ; same as (fn [x y z] z)
#[$1 $2 $3] ; same as (fn [a b c] [a b c])
#{:a $1 :b $2} ; same as (fn [a b] {:a a :b b})
#$ ; same as (fn [x] x) (aka the identity function)
#val ; same as (fn [] val)
#[:one :two $...] ; same as (fn [...] ["one" "two" ...])
Hash arguments can also be used as parts of multisyms. For instance,
#$.foo
is a function which will return the value of the "foo" key in
its first argument.
Unlike regular functions, there is no implicit do
in a hash
function, and thus it cannot contain multiple forms without an
explicit do
. The body itself is directly used as the return value
rather than the last element in the body.
Returns a new function which works like its first argument, but fills the first few arguments in place with the given ones. This is related to currying but different because calling it will call the underlying function instead of waiting till it has the "correct" number of args.
Example:
(partial (fn [x y] (print (+ x y))) 2)
This example returns a function which will print a number that is 2 greater than the argument it is passed.
Introduces a new scope in which a given set of local bindings are used.
Example:
(let [x 89
y 198]
(print (+ x y 12))) ; => 299
These locals cannot be changed with set
but they can be shadowed by
an inner let
or local
. Outside the body of the let
, the bindings
it introduces are no longer visible. The last form in the body is used
as the return value.
Any time you bind a local, you can destructure it if the value is a table or a function call which returns multiple values:
Example:
(let [(x y z) (unpack [10 9 8])]
(+ x y z)) ; => 27
Example:
(let [[a b c] [1 2 3]]
(+ a b c)) ; => 6
If a table key is a string with the same name as the local you want to
bind to, you can use shorthand of just :
for the key name followed
by the local name.
Example:
(let [{:msg message : val} {:msg "hello there" :val 19}]
(print message)
val) ; prints "hello there" and returns 19
When destructuring a sequential table, you can capture all the remainder
of the table in a local by using &
:
Example:
(let [[a b & c] [1 2 3 4 5 6]]
(table.concat c ",")) ; => "3,4,5,6"
(Since 1.3.0): This also works with function argument lists, but it
has a small performance cost, so it's recommended to use ...
instead
in cases that are sensitive to overhead.
If a table implements __fennelrest
metamethod it is used to capture the
remainder of the table. It can be used with custom data structures
implemented in terms of tables, which wish to provide custom rest
destructuring. The metamethod receives the table as the first
argument, and the amount of values it needs to drop from the beginning
of the table, much like table.unpack
Example:
(local t [1 2 3 4 5 6])
(setmetatable
t
{:__fennelrest (fn [t k]
(let [res {}]
(for [i k (length t)]
(tset res (tostring (. t i)) (. t i)))
res))})
(let [[a b & c] t]
c) ;; => {:3 3 :4 4 :5 5 :6 6}
When destructuring a non-sequential table, you can capture the
original table along with the destructuring by using &as
:
Example:
(let [{:a a :b b &as all} {:a 1 :b 2 :c 3 :d 4}]
(+ a b all.c all.d)) ; => 10
Introduces a new local inside an existing scope. Similar to let
but
without a body argument. Recommended for use at the top-level of a
file for locals which will be used throughout the file.
Example:
(local tau-approx 6.28318)
Supports destructuring and multiple-value binding.
(Since 1.3.0)
Evaluates its first argument, then searches thru the subsequent pattern/body clauses to find one where the pattern matches the value, and evaluates the corresponding body. Pattern matching can be thought of as a combination of destructuring and conditionals.
Note: Lua also has "patterns" which are matched against strings similar to how regular expressions work in other languages; these are two distinct concepts with similar names.
Example:
(case mytable
59 :will-never-match-hopefully
[9 q 5] (print :q q)
[1 a b] (+ a b))
In the example above, we have a mytable
value followed by three
pattern/body clauses.
The first clause will only match if mytable
is 59.
The second clause will match if mytable
is a table with 9 as its first
element, any non-nil value as its second value and 5 as its third element; if
it matches, then it evaluates (print :q q)
with q
bound to the second
element of mytable
.
The final clause will only match if mytable
has 1 as its first element and
two non-nil values after it; if so then it will add up the second and third
elements.
If no clause matches, the form evaluates to nil.
Patterns can be tables, literal values, or symbols. Any symbol is implicitly
checked to be not nil
. Symbols can be repeated in an expression to check for
the same value.
Example:
(case mytable
;; the first and second values of mytable are not nil and are the same value
[a a] (* a 2)
;; the first and second values are not nil and are not the same value
[a b] (+ a b))
It's important to note that expressions are checked in order! In the above
example, since [a a]
is checked first, we can be confident that when [a b]
is checked, the two values must be different. Had the order been reversed,
[a b]
would always match as long as they're not nil
- even if they have the
same value!
You may allow a symbol to optionally be nil
by prefixing it with ?
.
Example:
(case mytable
;; not-nil, maybe-nil
[a ?b] :maybe-one-maybe-two-values
;; maybe-nil == maybe-nil, both are nil or both are the same value
[?a ?a] :maybe-none-maybe-two-same-values
;; maybe-nil, maybe-nil
[?a ?b] :maybe-none-maybe-one-maybe-two-values)
Symbols prefixed by an _
are ignored and may stand in as positional
placeholders or markers for "any" value - including a nil
value. A single _
is also often used at the end of a case
expression to define an "else" style
fall-through value.
Example:
(case mytable
;; not-nil, anything
[a _b] :maybe-one-maybe-two-values
;; anything, anything (different to the previous ?a example!)
;; note this is effectively the same as []
[_a _a] :maybe-none-maybe-one-maybe-two-values
;; anything, anything
;; this is identical to [_a _a] and in this example would never actually match.
[_a _b] :maybe-none-maybe-one-maybe-two-values
;; when no other clause matched, in this case any non-table value
_ :no-match)
Tables can be nested, and they may be either sequential ([]
style) or
key/value ({}
style) tables. Sequential tables will match if they have at
least as many elements as the pattern. (To allow an element to be nil, see ?
and _
as above.) Tables will never fail to match due to having too many
elements - this means []
matches any table, not an empty table. You can
use &
to capture all the remaining elements of a sequential table, just like
let
.
(case mytable
{:subtable [a b ?c] :depth depth} (* b depth)
_ :unknown)
You can also match against multiple return values using parentheses. (These cannot be nested, but they can contain tables.) This can be useful for error checking.
(case (io.open "/some/file")
(nil msg) (report-error msg)
f (read-file f))
Sometimes you need to match on something more general than a structure or specific value. In these cases you can use guard clauses:
(case [91 12 53]
(where [a b c] (= 5 a)) :will-not-match
(where [a b c] (= 0 (math.fmod (+ a b c) 2)) (= 91 a)) c) ; -> 53
In this case the pattern should be wrapped in parentheses (like when
matching against multiple values) but the first thing in the
parentheses is the where
symbol. Each form after the pattern is a
condition; all the conditions must evaluate to true for that pattern
to match.
If several patterns share the same body and guards, such patterns can
be combined with or
special in the where
clause:
(case [5 1 2]
(where (or [a 3 9] [a 1 2]) (= 5 a)) "Either [5 3 9] or [5 1 2]"
_ "anything else")
This is essentially equivalent to:
(case [5 1 2]
(where [a 3 9] (= 5 a)) "Either [5 3 9] or [5 1 2]"
(where [a 1 2] (= 5 a)) "Either [5 3 9] or [5 1 2]"
_ "anything else")
However, patterns which bind variables should not be combined with
or
if different variables are bound in different patterns or some
variables are missing:
;; bad
(case [1 2 3]
;; Will throw an error because `b' is nil for the first
;; pattern but the guard still uses it.
(where (or [a 1 2] [a b 3]) (< a 0) (< b 1))
:body)
;; ok
(case [1 2 3]
(where (or [a b 2] [a b 3]) (< a 0) (<= b 1))
:body)
Symbols bound inside a case
pattern are independent from any existing
symbols in the current scope, that is - names may be re-used without
consequence.
Example:
(let [x 1]
(case [:hello]
;; `x` is simply bound to the first value of [:hello]
[x] x)) ; -> :hello
Sometimes it may be desirable to match against an existing value in the outer
scope. To do this we can "pin" a binding inside the pattern with an existing
outer binding with the unary (= binding-name)
form. The unary (= binding-name)
form is only valid in a case
pattern and must be inside a (where)
guard.
Example:
(let [x 1]
(case [:hello]
;; 1 != :hello
(where [(= x)]) x
_ :no-match)) ; -> no-match
(let [x 1]
(case [1]
;; 1 == 1
(where [(= x)]) x
_ :no-match)) ; -> 1
(let [pass :hunter2]
(case (user-input)
(where (= pass)) :login
_ :try-again!))
Pinning is only required inside the pattern. Outer bindings are automatically available inside guards and bodies as long as the name has not been rebound in the pattern.
Note: The case
macro can be used in place of the if-let
macro
from Clojure. The reason Fennel doesn't have if-let
is that case
makes it redundant.
(since 0.2.0)
match
is conceptually equivalent to case
, except symbols in the patterns are
always pinned with outer-scope symbols if they exist.
It supports all the same syntax as described in case
except the pin
((= binding-name)
) expression, as it is always performed.
Be careful when using
match
that your symbols are not accidentally the same as any existing symbols! If you know you don't intend to pin any existing symbols you should use thecase
expression.
(let [x 95]
(match [52 85 95]
[b a a] :no ; because a=85 and a=95
[x y z] :no ; because x=95 and x=52
[a b x] :yes)) ; a and b are fresh values while x=95 and x=95
Unlike in case
, if an existing binding has the value nil
, the ?
prefix is
not necessary - it would instead create a new un-pinned binding!
Example:
(let [name nil
get-input (fn [] "Dave")]
(match (get-input)
;; name already exists as nil, "Dave" != nil so this *wont* match
name (.. "Hello " name)
?no-input (.. "Hello anonymous"))) ; -> "Hello anonymous"
Note: The match
macro can be used in place of the if-let
macro
from Clojure. The reason Fennel doesn't have if-let
is that match
makes it redundant.
Note 2: Prior to Fennel 0.9.0 the match
macro used infix ?
operator to test patterns against the guards. While this syntax is
still supported, where
should be preferred instead:
(match [1 2 3]
(where [a 2 3] (< 0 a)) "new guard syntax"
([a 2 3] ? (< 0 a)) "obsolete guard syntax")
Evaluates a series of pattern matching steps. The value from the first expression is matched against the first pattern. If it matches, the first body is evaluated and its value is matched against the second pattern, etc.
If there is a (catch pat1 body1 pat2 body2 ...)
form at the end, any mismatch
from the steps will be tried against these patterns in sequence as a fallback
just like a normal case
. If no catch
pattern matches, nil is returned.
If there is no catch, the mismatched value will be returned as the value of the entire expression.
(fn handle [conn token]
(case-try (conn:receive :*l)
input (parse input)
(command-name params (= token)) (commands.get command-name)
command (pcall command (table.unpack params))
(catch
(_ :timeout) nil
(_ :closed) (pcall disconnect conn "connection closed")
(_ msg) (print "Error handling input" msg))))
This is useful when you want to perform a series of steps, any of which could
fail. The catch
clause lets you keep all your error handling in one
place. Note that there are two ways to indicate failure in Fennel and Lua:
using the assert
/error
functions or returning nil followed by some data
representing the failure. This form only works on the latter, but you can use
pcall
to transform error
calls into values.
Equivalent to case-try
but uses match
internally. See case
and match
for details on the differences between these two forms.
Unlike case-try
, match-try
will pin values in a given catch
block with
those in the original steps.
(fn handle [conn token]
(match-try (conn:receive :*l)
input (parse input)
(command-name params token) (commands.get command-name)
command (pcall command (table.unpack params))
(catch
(_ :timeout) nil
(_ :closed) (pcall disconnect conn "connection closed")
(_ msg) (print "Error handling input" msg))))
Introduces a new local inside an existing scope which may have its
value changed. Identical to local
apart from allowing set
to work
on it.
Example:
(var x 83)
Supports destructuring and multiple-value binding.
Changes the value of a variable introduced with var
. Will not work
on globals or let
/local
-bound locals. Can also be used to change a
field of a table, even if the table is bound with let
or local
,
provided the field is given at compile-time.
Example:
(set x (+ x 91))
Example:
(let [t {:a 4 :b 8}]
(set t.a 2) t) ; => {:a 2 :b 8}
Supports destructuring and multiple-value binding.
Sets the field of a given table to a new value. The field name does not
need to be known at compile-time. Works on any table; the table does
not have to be declared with var
to change its fields.
Example:
(let [tbl {:d 32} field :d]
(tset tbl field 19) tbl) ; => {:d 19}
You can provide multiple successive field names to perform nested sets. For example:
(let [tbl {:a {:b {}}} field :c]
(tset tbl :a :b field "d") tbl) ; => {:a {:b {:c "d"}}}
In any of the above contexts where you can make a new binding, you can use multiple value binding. Otherwise you will only capture the first value.
Example:
(let [x (values 1 2 3)]
x) ; => 1
Example:
(let [(file-handle message code) (io.open "foo.blah")]
message) ; => "foo.blah: No such file or directory"
Example:
(do (local (_ _ z) (unpack [:a :b :c :d :e])) z) => c
(Since 0.4.2)
While Lua will automatically close an open file handle when it's garbage collected,
GC may not run right away; with-open
ensures handles are closed immediately, error
or no, without boilerplate.
The usage is similar to let
, except:
- destructuring is disallowed (symbols only on the left-hand side)
- every binding should be a file handle or other value with a
:close
method.
After executing the body, or upon encountering an error, with-open
will invoke (value:close)
on every bound variable before returning the results.
The body is implicitly wrapped in a function and run with xpcall
so that all bound
handles are closed before it re-raises the error.
Example:
;; Basic usage
(with-open [fout (io.open :output.txt :w) fin (io.open :input.txt)]
(fout:write "Here is some text!\n")
((fin:lines))) ; => first line of input.txt
;; This demonstrates that the file will also be closed upon error.
(var fh nil)
(local (ok err)
(pcall #(with-open [file (io.open :test.txt :w)]
(set fh file) ; you would normally never do this
(error :whoops!))))
(io.type fh) ; => "closed file"
[ok err] ; => [false "<error message and stacktrace>"]
(Since 0.4.0)
Discards all values after the first n when dealing with multi-values (...
)
and multiple returns. Useful for composing functions that return multiple values
with variadic functions. Expands to a let
expression that binds and re-emits
exactly n values, e.g.
(pick-values 2 (func))
expands to
(let [(_0_ _1_) (func)] (values _0_ _1_))
Example:
(pick-values 0 :a :b :c :d :e) ; => nil
[(pick-values 2 (table.unpack [:a :b :c]))] ;-> ["a" "b"]
(fn add [x y ...] (let [sum (+ (or x 0) (or y 0))]
(if (= (select :# ...) 0) sum (add sum ...))))
(add (pick-values 2 10 10 10 10)) ; => 20
(->> [1 2 3 4 5] (table.unpack) (pick-values 3) (add)) ; => 6
Note: If n is greater than the number of values supplied, n values will still be emitted.
This is reflected when using (select "#" ...)
to count varargs, but tables [...]
ignore trailing nils:
(select :# (pick-values 5 "one" "two")) ; => 5
[(pick-values 5 "one" "two")] ; => ["one" "two"]
Checks a condition and evaluates a corresponding body. Accepts any
number of condition/body pairs; if an odd number of arguments is
given, the last value is treated as a catch-all "else". Similar to
cond
in other lisps.
Example:
(let [x (math.random 64)]
(if (= 0 (% x 10))
"multiple of ten"
(= 0 (% x 2))
"even"
"I dunno, something else"))
All values other than nil or false are treated as true.
Takes a single condition and evaluates the rest as a body if it's not nil or false. This is intended for side-effects. The last form in the body is used as the return value.
Example:
(when launch-missiles?
(power-on)
(open-doors)
(fire))
Runs the body once for each value provided by the iterator. Commonly
used with ipairs
(for sequential tables) or pairs
(for any table
in undefined order) but can be used with any iterator. Returns nil.
Example:
(each [key value (pairs mytbl)]
(print "executing key")
(print (f value)))
Any loop can be terminated early by placing an &until
clause at the
end of the bindings:
(local out [])
(each [_ value (pairs tbl) &until (< max-len (length out))]
(table.insert out value))
Note: prior to fennel version 1.2.0, :until
was used instead of &until
;
the old syntax is still supported for backwards compatibility.
Most iterators return two values, but each
will bind any number. See
Programming in Lua for details about how iterators work.
Counts a number from a start to stop point (inclusive), evaluating the body once for each value. Accepts an optional step. Returns nil.
Example:
(for [i 1 10 2]
(log-number i)
(print i))
This example will print all odd numbers under ten.
Like each
, loops using for
can also be terminated early with an
&until
clause. The clause is checked before each iteration of the
body; if it is true at the beginning then the body will not run at all.
(var x 0)
(for [i 1 128 &until (maxed-out? x)]
(set x (+ x i)))
Loops over a body until a condition is met. Uses a native Lua while
loop. Returns nil.
Example:
(var done? false)
(while (not done?)
(print :not-done)
(when (< 0.95 (math.random))
(set done? true)))
Accepts any number of forms and evaluates all of them in order,
returning the last value. This is used for inserting side-effects into
a form which accepts only a single value, such as in a body of an if
when multiple clauses make it so you can't use when
. Some lisps call
this begin
or progn
.
(if launch-missiles?
(do
(power-on)
(open-doors)
(fire))
false-alarm?
(promote lt-petrov))
Some other forms like fn
and let
have an implicit do
.
and
,or
,not
: boolean+
,-
,*
,/
,//
,%
,^
: arithmetic>
,<
,>=
,<=
,=
,not=
: comparisonlshift
,rshift
,band
,bor
,bxor
,bnot
: bitwise operations
These all work as you would expect, with a few caveats. The bitwise operators
are only available in Lua 5.3+, unless you use the --use-bit-lib
flag or
the useBitLib
flag in the options table, which lets them be used in
LuaJIT. The integer division operator (//
) is only available in Lua 5.3+.
They all take any number of arguments, as long as that number is fixed
at compile-time. For instance, (= 2 2 (unpack [2 5]))
will evaluate
to true
because the compile-time number of values being compared is 3.
Multiple values at runtime will not be taken into account.
Note that these are all special forms which cannot be used as higher-order functions.
Concatenates its arguments into one string. Will coerce numbers into strings, but not other types.
Example:
(.. "Hello" " " "world" 7 "!!!") ; => "Hello world7!!!"
String concatenation is subject to the same compile-time limit as the operators above; it is not aware of multiple values at runtime.
(Changed in 0.3.0: the function was called #
before.)
Returns the length of a string or table. Note that the length of a
table with gaps (nils) in it is undefined; it can return a number
corresponding to any of the table's "boundary" positions between nil
and non-nil values. If a table has nils and you want to know the last
consecutive numeric index starting at 1, you must calculate it
yourself with ipairs
; if you want to know the maximum numeric key in
a table with nils, you can use table.maxn
.
Example:
(+ (length [1 2 3 nil 8]) (length "abc")) ; => 6 or 8
Looks up a given key in a table. Multiple arguments will perform nested lookup.
Example:
(. mytbl myfield)
Example:
(let [t {:a [2 3 4]}] (. t :a 2)) ; => 3
Note that if the field name is a string known at compile time, you
don't need this and can just use mytbl.field
.
Looks up a given key in a table. Multiple arguments will perform
nested lookup. If any of subsequent keys is not present, will
short-circuit to nil
.
Example:
(?. mytbl myfield)
Example:
(let [t {:a [2 3 4]}] (?. t :a 4 :b)) ; => nil
(let [t {:a [2 3 4 {:b 42}]}] (?. t :a 4 :b)) ; => 42
(Since 0.8.0)
The icollect
macro takes a "iterator binding table" in the format that each
takes, and returns a sequential table containing all the values produced by
each iteration of the macro's body. This is similar to how map
works in
several other languages, but it is a macro, not a function.
If the value is nil, it is omitted from the return table. This is analogous to
filter
in other languages.
(icollect [_ v (ipairs [1 2 3 4 5 6])]
(if (> v 2) (* v v)))
;; -> [9 16 25 36]
;; equivalent to:
(let [tbl []]
(each [_ v (ipairs [1 2 3 4 5 6])]
(tset tbl (+ (length tbl) 1) (if (> v 2) (* v v))))
tbl)
The collect
macro is almost identical, except that the
body should return two things: a key and a value.
(collect [k v (pairs {:apple "red" :orange "orange" :lemon "yellow"})]
(if (not= v "yellow")
(values (.. "color-" v) k)))
;; -> {:color-orange "orange" :color-red "apple"}
;; equivalent to:
(let [tbl {}]
(each [k v (pairs {:apple "red" :orange "orange"})]
(if (not= v "yellow")
(match (values (.. "color-" v) k)
(key value) (tset tbl key value))))
tbl)
If the key and value are given directly in the body of collect
and
not nested in an outer form, then the values
can be omitted for brevity:
(collect [k v (pairs {:a 85 :b 52 :c 621 :d 44})]
k (* v 5))
Like each
and for
, the table comprehensions support an &until
clause for early termination.
Both icollect
and collect
take an &into
clause which allows you
put your results into an existing table instead of starting with an
empty one:
(icollect [_ x (ipairs [2 3]) &into [9]]
(* x 11))
;; -> [9 22 33]
Note: Prior to fennel version 1.2.0, :into
was used instead of &into
;
the old syntax is still supported for backwards compatibility.
(Since 0.10.0)
Runs through an iterator and performs accumulation, similar to fold
and reduce
commonly used in functional programming languages.
Like collect
and icollect
, it takes an iterator binding table
and an expression as its arguments. The difference is that in
accumulate
, the first two items in the binding table are used as
an "accumulator" variable and its initial value.
For each iteration step, it evaluates the given expression and
its value becomes the next accumulator variable.
accumulate
returns the final value of the accumulator variable.
Example:
(accumulate [sum 0
i n (ipairs [10 20 30 40])]
(+ sum n)) ; -> 100
The &until
clause is also supported here for early termination.
(Since 1.3.0)
Identical to accumulate, but instead of taking an iterator and the same bindings
as each
, it accepts the same bindings as for
and will iterate the numerical range.
Accepts &until
just like for
and accumulate
.
Example:
(faccumulate [n 0 i 1 5] (+ n i)) ; => 15
(Since 1.1.1)
Similarly to icollect
, fcollect
provides a way of building a
sequential table. Unlike icollect
, instead of an iterator it
traverses a range, as accepted by the for
special. The &into
and
&until
clauses work the same as in icollect
.
Example:
(fcollect [i 0 10 2]
(if (> i 2) (* i i)))
;; -> [16 36 64 100]
;; equivalent to:
(let [tbl {}]
(for [i 0 10 2]
(if (> i 2)
(table.insert tbl (* i i))))
tbl)
Returns multiple values from a function. Usually used to signal failure by returning nil followed by a message.
Example:
(fn [filename]
(if (valid-file-name? filename)
(open-file filename)
(values nil (.. "Invalid filename: " filename))))
Looks up a function in a table and calls it with the table as its first argument. This is a common idiom in many Lua APIs, including some built-in ones.
(Since 0.3.0) Just like Lua, you can perform a method call by calling a function
name where :
separates the table variable and method name.
Example:
(let [f (assert (io.open "hello" "w"))]
(f:write "world")
(f:close))
If the name of the method isn't known at compile time, you can use :
followed by the table and then the method's name as a string.
Example:
(let [f (assert (io.open "hello" "w"))
method1 :write
method2 :close]
(: f method1 "world")
(: f method2))
Both of these examples are equivalent to the following:
(let [f (assert (io.open "hello" "w"))]
(f.write f "world")
(f.close f))
Unlike Lua, there's nothing special about defining functions that get
called this way; typically it is given an extra argument called self
but this is just a convention; you can name it anything.
(local t {})
(fn t.enable [self]
(set self.enabled? true))
(t:enable)
The ->
macro takes its first value and splices it into the second
form as the first argument. The result of evaluating the second form
gets spliced into the first argument of the third form, and so on.
Example:
(-> 52
(+ 91 2) ; (+ 52 91 2)
(- 8) ; (- (+ 52 91 2) 8)
(print "is the answer")) ; (print (- (+ 52 91 2) 8) "is the answer")
The ->>
macro works the same, except it splices it into the last
position of each form instead of the first.
-?>
and -?>>
, the thread maybe macros, are similar to ->
& ->>
but they also do checking after the evaluation of each threaded
form. If the result is false or nil then the threading stops and the result
is returned. -?>
splices the threaded value as the first argument,
like ->
, and -?>>
splices it into the last position, like ->>
.
This example shows how to use them to avoid accidentally indexing a nil value:
(-?> {:a {:b {:c 42}}}
(. :a)
(. :missing)
(. :c)) ; -> nil
(-?>> :a
(. {:a :b})
(. {:b :missing})
(. {:c 42})) ; -> nil
While ->
and ->>
pass multiple values thru without any trouble,
the checks in -?>
and -?>>
prevent the same from happening there
without performance overhead, so these pipelines are limited to a
single value.
Note that these have nothing to do with "threads" used for concurrency; they are named after the thread which is used in sewing. This is similar to the way that
|>
works in OCaml and Elixir.
Similarly, the doto
macro splices the first value into subsequent
forms. However, it keeps the same value and continually splices the
same thing in rather than using the value from the previous form for
the next form.
(doto (io.open "/tmp/err.log")
(: :write contents)
(: :close))
;; equivalent to:
(let [x (io.open "/tmp/err.log")]
(: x :write contents)
(: x :close)
x)
The first form becomes the return value for the whole expression, and subsequent forms are evaluated solely for side-effects.
(since 0.3.0)
(include :my.embedded.module)
Loads Fennel/Lua module code at compile time and embeds it in the
compiled output. The module name must resolve to a string literal
during compilation. The bundled code will be wrapped in a function
invocation in the emitted Lua and set on
package.preload[modulename]
; a normal require
is then emitted
where include
was used to load it on demand as a normal module.
In most cases it's better to use require
in your code and use the
requireAsInclude
option in the API documentation and the
--require-as-include
CLI flag (fennel --help
) to accomplish this.
The require
function is not part of Fennel; it comes from
Lua. However, it works to load Fennel code. See the Modules and
multiple files section in the
tutorial and Programming in Lua for details about require
.
Starting from version 0.10.0 include
and hence
--require-as-include
support semi-dynamic compile-time resolution of
module paths similarly to import-macros
. See the relative
require section in the tutorial for more
information.
All forms which introduce macros do so inside the current scope. This is usually the top level for a given file, but you can introduce macros into smaller scopes as well. Note that macros are a compile-time construct; they do not exist at runtime. As such macros cannot be exported at the bottom of a module like functions and other values.
(Since 0.4.0)
Loads a module at compile-time and binds its functions as local macros.
A macro module exports any number of functions which take code forms
as arguments at compile time and emit lists which are fed back into
the compiler as code. The module calling import-macros
gets whatever
functions have been exported to use as macros. For instance, here is a
macro module which implements when2
in terms of if
and do
:
(fn when2 [condition body1 & rest-body]
(assert body1 "expected body")
`(if ,condition
(do ,body1 ,(unpack rest-body))))
{:when2 when2}
For a full explanation of how this works see the macro guide.
All forms in Fennel are normal tables you can use table.insert
,
ipairs
, destructuring, etc on. The backtick on the third line
creates a template list for the code emitted by the macro, and the
comma serves as "unquote" which splices values into the
template. (Changed in 0.3.0: @
was used instead of ,
before.)
Assuming the code above is in the file "my-macros.fnl" then it turns this input:
(import-macros {: when2} :my-macros)
(when2 (= 3 (+ 2 a))
(print "yes")
(finish-calculation))
and transforms it into this code at compile time by splicing the arguments into the backtick template:
(if (= 3 (+ 2 a))
(do
(print "yes")
(finish-calculation)))
The import-macros
macro can take any number of binding/module-name
pairs. It can also bind the entire macro module to a single name
rather than destructuring it. In this case you can use a dot to call
the individual macros inside the module:
(import-macros mine :my-macros)
(mine.when2 (= 3 (+ 2 a))
(print "yes")
(finish-calculation))
Note that all macro code runs at compile time, which happens before runtime. Locals which are in scope at runtime are not visible during compile-time. So this code will not work:
(local (module-name file-name) ...)
(import-macros mymacros (.. module-name ".macros"))
However, this code will work, provided the module in question exists:
(import-macros mymacros (.. ... ".macros"))
See "Compiler API" below for details about additional functions visible inside compiler scope which macros run in.
By default, Fennel will search for macro modules similarly to how it
searches for normal runtime modules: by walking thru entries on
fennel.macro-path
and checking the filesystem for matches. However,
in some cases this might not be suitable, for instance if your Fennel
program is packaged in some kind of archive file and the modules do
not exist as distinct files on disk.
To support this case you can add your own searcher function to the
fennel.macro-searchers
table. For example, assuming find-in-archive
is a function which can look up strings from the archive given a path:
(local fennel (require :fennel))
(fn my-searcher [module-name]
(let [filename (.. "src/" module-name ".fnl")]
(match (find-in-archive filename)
code (values (partial fennel.eval code {:env :_COMPILER})
filename))))
(table.insert fennel.macro-searchers my-searcher)
The searcher function should take a module name as a string and return two values if it can find the macro module: a loader function which will return the macro table when called, and an optional filename. The loader function will receive the module name and the filename as arguments.
(Since 0.3.0)
Defines a table of macros. Note that inside the macro definitions, you cannot access variables and bindings from the surrounding code. The macros are essentially compiled in their own compiler environment. Again, see the "Compiler API" section for more details about the functions available here.
(macros {:my-max (fn [x y]
`(let [x# ,x y# ,y]
(if (< x# y#) y# x#)))})
(print (my-max 10 20))
(print (my-max 20 10))
(print (my-max 20 20))
(macro my-max [x y]
`(let [x# ,x y# ,y]
(if (< x# y#) y# x#)))
If you are only defining a single macro, this is equivalent to the
previous example. The syntax mimics fn
.
(macrodebug (-> abc
(+ 99)
(< 0)
(when (os.exit))))
; -> (if (< (+ abc 99) 0) (do (os.exit)))
Call the macrodebug
macro with a form and it will repeatedly expand
top-level macros in that form and print out the resulting form. Note
that the resulting form will usually not be sensibly indented, so you
might need to copy it and reformat it into something more readable.
Note that this prints at compile-time since macrodebug
is a macro.
It's easy to make macros which accidentally evaluate their arguments more than once. This is fine if they are passed literal values, but if they are passed a form which has side-effects, the result will be unexpected:
(var v 1)
(macros {:my-max (fn [x y]
`(if (< ,x ,y) ,y ,x))})
(fn f [] (set v (+ v 1)) v)
(print (my-max (f) 2)) ; -> 3 since (f) is called twice in the macro body above
(Since 0.3.0) In order to prevent accidental symbol capture, you may not bind a
bare symbol inside a backtick as an identifier. Appending a #
on
the end of the identifier name as above invokes "auto gensym" which
guarantees the local name is unique.
(macros {:my-max (fn [x y]
`(let [x2 ,x y2 ,y]
(if (< x2 y2) y2 x2)))})
(print (my-max 10 20))
; Compile error in 'x2' unknown:?: macro tried to bind x2 without gensym; try x2# instead
macros
is useful for one-off, quick macros, or even some more complicated
macros, but be careful. It may be tempting to try and use some function
you have previously defined, but if you need such functionality, you
should probably use import-macros
.
For example, this will not compile in strict mode! Even when it does
allow the macro to be called, it will fail trying to call a global
my-fn
when the code is run:
(fn my-fn [] (print "hi!"))
(macros {:my-max (fn [x y]
(my-fn)
`(let [x# ,x y# ,y]
(if (< x# y#) y# x#)))})
; Compile error in 'my-max': attempt to call global '__fnl_global__my_2dfn' (a nil value)
Evaluate a block of code during compile-time with access to compiler scope. This gives you a superset of the features you can get with macros, but you should use macros if you can.
Example:
(eval-compiler
(each [name (pairs _G)]
(print name)))
This prints all the functions available in compiler scope.
Inside eval-compiler
, macros
, or macro
blocks, as well as
import-macros
modules, the functions listed below are visible to
your code.
-
list
- return a list, which is a special kind of table used for code. -
sym
- turn a string into a symbol. -
gensym
- generates a unique symbol for use in macros, accepts an optional prefix string. -
list?
- is the argument a list? Returns the argument orfalse
. -
sym?
- is the argument a symbol? Returns the argument orfalse
. -
table?
- is the argument a non-list table? Returns the argument orfalse
. -
sequence?
- is the argument a non-list sequential table (created with[]
, as opposed to{}
)? Returns the argument orfalse
. -
varg?
- is this a...
symbol which indicates var args? Returns a special table describing the type orfalse
. -
multi-sym?
- a multi-sym is a dotted symbol which refers to a table's field. Returns a table containing each separate symbol, orfalse
. -
comment?
- is the argument a comment? Comments are only included whenopts.comments
is truthy. -
view
-fennel.view
table serializer. -
get-scope
- return the scope table for the current macro call site. -
assert-compile
- works likeassert
but takes a list/symbol as its third argument in order to provide pinpointed error messages.
These functions can be used from within macros only, not from any
eval-compiler
call:
in-scope?
- does the symbol refer to an in-scope local? Returns the symbol ornil
.macroexpand
- performs macroexpansion on its argument form; returns an AST.
Note that lists are compile-time concepts that don't exist at runtime; they
are implemented as tables which have a special metatable to distinguish them
from regular tables defined with square or curly brackets. Similarly symbols
are tables with a string entry for their name and a marker metatable. You
can use tostring
to get the name of a symbol.
As of 1.0.0 the compiler will not allow access to the outside world
(os
, io
, etc) from macros. The one exception is print
which is
included for debugging purposes. You can disable this by providing the
command-line argument --no-compiler-sandbox
or by passing
{:compiler-env _G}
in the options table when using the compiler
API to get full access.
Please note that the sandbox is not suitable to be used as a robust security mechanism. It has not been audited and should not be relied upon to protect you from running untrusted code.
Note that other internals of the compiler exposed in compiler scope but not listed above are subject to change.
There are some cases when you need to emit Lua output from Fennel in
ways that don't match Fennel's semantics. For instance, if you are
porting an algorithm from Lua that uses early returns, you may want
to do the port as literally as possible first, and then come back to
it later to make it idiomatic. You can use the lua
special form to
accomplish this:
(fn find [tbl pred]
(each [key val (pairs tbl)]
(when (pred val)
(lua "return key"))))
Lua code inside the string can refer to locals which are in scope;
however note that it must refer to the names after mangling has been
done, because the identifiers must be valid Lua. The Fennel compiler
will change foo-bar
to foo_bar
in the Lua output in order for it
to be valid, as well as other transformations. When in doubt, inspect
the compiler output to see what it looks like. For example the
following Fennel code:
(local foo-bar 3)
(let [foo-bar :hello]
(lua "print(foo_bar0 .. \" world\")"))
will produce this Lua code:
local foo_bar = 3
local foo_bar0 = "hello"
print(foo_bar0 .. " world")
return nil
Normally in these cases you would want to emit a statement, in which case you would pass a string of Lua code as the first argument. But you can also use it to emit an expression if you pass in a string as the second argument.
Note that this should only be used in exceptional circumstances, and if you are able to avoid it, you should.
(Since 0.1.0, deprecated in 0.4.0)
The require-macros
form is like import-macros
, except it imports
all macros without making it clear what new identifiers are brought
into scope. It is strongly recommended to use import-macros
instead.
(Since 0.4.0, deprecated 0.10.0)
Like pick-values
, but takes an integer n
and a function/operator
f
, and creates a new function that applies exactly n
arguments to f
.
(Deprecated in 1.1.0)
Sets a global variable to a new value. Note that there is no distinction between introducing a new global and changing the value of an existing one. This supports destructuring and multiple-value binding.
Example:
(global prettyprint (fn [x] (print (fennel.view x))))
Using global
adds the identifier in question to the list of allowed
globals so that referring to it later on will not cause a compiler error.
However, globals are also available in the _G
table, and accessing
them that way instead is recommended for clarity.