Support for variable expansion and templates within s-expressions. The functions in this module evaluate the following constructs within s-expressions:
(:include filename)
is replaced with the list of s-expressions contained
in filename
, as if the contents of filename
were directly inserted in
place of (:include filename)
. A relative filename
is taken with respect
to the file that contains the include macro.(:let v (v1 ... vn) S1 ... Sm)
defines a template v
with arguments v1,
..., vn
and body S1 ... Sm
. The definition itself is removed from the
input. The variables v1, ..., vn
must be exactly the free variables of S1,
..., Sm
(see below for the meaning of "free variable"). In particular, since
a macro argument cannot be a function, a let body cannot call a macro that is
defined elsewhere, only a macro that is defined in the body itself. However if
you want to use the same macro inside two macros, it is still possible to define
it in a separate file and include it in both macros. The list S1 ... Sm
may
not be empty.(:use v (v1 SS1) ... (vn SSn))
expands to the body of the template v
with lists of s-expressions SS1, ..., SSn
substituted for the arguments
v1, ..., vn
of v
.(:concat S1 ... Sn)
evaluates S1 ... Sn
to atoms C1, ..., Cn
when
possible and is replaced by the string concatenation C1 | ... | Cn
.Macros other than :include
will be called 'local'. All :include
macros
are resolved before all the local macros, which means that included file
names cannot contain variables.
The occurrence of variable v
in (:use v ...)
can be either free or bound, depending
on the surrounding sexp. The occurrence is free iff it it's not bound, and it's bound
iff one of the following two conditions apply:
v1
, ..., vn
in the body of (:let v (v1 ... vn) S1 ... Sm)
are bound.v
from the appearance of (:let v (v1 ... vn) S1 ... Sm)
to
the end of the sexp nesting level are bound.Trying to :use
an unbound variable is an error. Neither the top level file nor any of
the included files may contain unbound variables.
The load...
functions of this module mirror the corresponding functions of
the Sexp
module except that they expand the macros in the loaded file and
may throw additional exceptions.
Example -------
Assume that input.sexp
contains
(:include defs.sexp)
(:include template.sexp)
(:use f (a (:use a)) (b (:use b)))
the file defs.sexp
contains
(:let a () hello)
(:let b () " world")
and the file template.sexp
contains
(:let f (a b) (:concat (:use a) (:use b)))
Then load_sexp "input.sexp"
will return "hello world".
Formal Evaluation Rules -----------------------
In the following v
denotes a variable (an atom), S
denotes a sexp, and
SS
denotes a list of sexps. Given a map V
we write V(v ~> a)
to update
the map.
Evaluation rules are of the form V : SS => SS'
where V
is a set of
bindings of the form v ~> SSv
, each binding defining a template v
with
body SSv
.
First some boilerplate rules: a sexp without macros evaluates to itself:
V : <empty sexp list> => <empty sexp list>
V : S => SS1
V : SS => SS2
-------------------
V : S SS => SS1 SS2
C is an atom
------------
V : C => C
V : SS => SS'
-----------------
V : (SS) => (SS')
Now the interesting rules.
free_vars(SSv) = {v1, ..., vn}
V(v ~> SSv) : SS => SS'
--------------------------------------
V : (:let v (v1 ... vn) SSv) SS => SS'
V(v) = SS
V : SSi => SSi' for each i
V(v1 ~> SS1', ..., vn ~> SSn') : SS => SS'
------------------------------------------
V : (:use v (v1 SS1) ... (vn SSn)) => SS'
v not defined in V
-----------------------
V : (:use v ...) => _|_
V : Si => Ci
Each Ci is an atom
-------------------------------------------------------
V : (:concat S1 ... Sn) => String.concat [C1; ...; Cn]
As follows from the let-rule, let definitions may only refer to the variables explicitly mentioned in the argument list. This avoids the complexities of variable capture and allows us to forego closure building.
type 'a annot_conv
= [ `Result of 'a | `Error of exn * Sexplib.Sexp.Annotated.t ] as body
constraint 'body = 'a Sexplib.Sexp.Annotated.conv
val load_sexp : string ‑> Sexplib.Sexp.t
load_sexp file
like {!Sexp.load_sexp} file
, but resolves the macros
contained in file
.
val load_sexps : string ‑> Sexplib.Sexp.t list
load_sexps file
like {!Sexp.load_sexps} file
, but resolves the macros
contained in file
.
val load_sexp_conv : string ‑> (Sexplib.Sexp.t ‑> 'a) ‑> 'a annot_conv
load_sexp_conv file f
uses load_sexp and converts the result using
f
.
val load_sexps_conv : string ‑> (Sexplib.Sexp.t ‑> 'a) ‑> 'a annot_conv list
load_sexps_conv file f
uses load_sexps and converts the result using
f
.
val load_sexp_conv_exn : string ‑> (Sexplib.Sexp.t ‑> 'a) ‑> 'a
load_sexp_conv_exn file f
like load_sexp_conv, but raises an exception
in case of conversion error.
val load_sexps_conv_exn : string ‑> (Sexplib.Sexp.t ‑> 'a) ‑> 'a list
load_sexps_conv_exn file f
like load_sexps_conv, but raises an
exception in case of conversion error.
val expand_local_macros : Sexplib.Sexp.t list ‑> Sexplib.Sexp.t list conv
expand_local_macros sexps
takes a list of sexps and performs macro-expansion on
them, except that an error will be returned if an :include macro is found.
module type Sexp_loader : sig ... end
A version of load_sexps
that is functorized with respect to the functions
that load the sexps from files and the corresponding monad.
module Loader : functor (S : Sexp_loader) -> sig ... end