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Parsing and operator precedence
The syntax of F* pretty much follows the syntax of OCaml. In particular, the precedence and associativity of custom operators is determined by their first character. For a quick reference, this StackOverflow post is your best bet.
The snippet below defines the ++
operator to be the +
operator... not very useful, but well.
let (++) = (+)
let main = List.fold_left (++) 0 [ 1; 2 ]
F* also supports the F#
syntax, i.e.
let op_Plus_Plus = op_Addition
It's not very clear to me why the left-hand side uses Plus
vs. Addition
in the right-hand side, so... probably better off using the OCaml-style syntax.
We support syntax à la Haskell where `f`
is an infix application of function f
(e.g. e `f` e'
).
Since F* uses a unified syntax, where types and terms are on the same level, this means that arrows, conjunctions and disjunctions can now appear alongside regular terms. Here's the precedence, arity and associativity of various operators. ==>
binds looser, **
binds tighter.
-
==>
infix, left -
->
infix, left -
\/
infix, left -
/\
infix, left -
! ~ ?
prefix, -
|
infix, left -
&
infix, left -
=, <, >
infix, left -
$
infix, left -
|>
infix, left -
@, ^
infix, right -
+, -
infix, left -
*, /, %
infix, left -
`foo`
,`M.bar`
infix, left ← syntax for infix application of functions -
**
infix, left
The only exception is let x: t = e
(and type t = e
): to avoid shift/reduce conflicts, t
may be an arrow, or anything that has the precedence of infix1
or above.
Note: I didn't write down any special behavior for <|
... not sure where it should stand. Shout out if it's wrong.
The array, string assignment and dereference operators of OCaml are modeled as regular operators that can be overridden.
Any code that contains an expression of the form e1.[e2] <- e3
is desugared as a a call to the operator .[]<-
. Please note that .(
and .[
are one token (instead of two, say, in OCaml). This is due to obscure conflicts in the grammar... This means that forall (x: t).( ... )
no longer works! You need to insert a space between the .
and the (
.
-
e1.(e2) <- e3
is desugared as a reference toop_Array_Assignment
-
e1.[e2] <- e3
is desugared as a reference toop_String_Assignment
-
e1.(e2)
is desugared as a reference toop_Array_Access
-
e1.[e2]
is desugared as a reference toop_String_Access
Example:
open FStar
let op_Array_Assignment = Buffer.upd
let op_Array_Access = Buffer.index
let test =
let buf = Buffer.create false 16ul in
buf.(0ul) <- not buf.(0ul);
buf.(15ul) <- false
Note: you cannot do let (.()<-)
because .()<-
is not a valid sequence of operator characters. So, use the op_*
form.
Assignment operators sit at the precedence level of statements, which bind looser than expressions. This means that you cannot use h.[x] <- e
in an expression, for instance, if you overload op_String_Assignment
to represent functional updates of the heap in a specification. In practice, you'll have to write (ensures (h' == (h.[x] <- e)))
. This is unlike OCaml, where you can write the (not very useful) () = e1.[e2] <- e3
.
(tentative)
-
op_String_
variants (with square brackets) are used for HyperHeap (and possibly other heap models) -- this are functional updates -
op_Array_
variants (with parentheses) are used for Buffers (and possibly other Array variants) -- these are stateful updates -
op_Curly_
variants (to be added) are used for Sequences -- these are functional updates -
op_Angle_
variants (to be added)