feat: Initial statix assignment of types to expressions

2021-02-14 10:25:23 -08:00 · 2021-02-14 10:25:23 -08:00 · 5cd75b8177
parent b3f9cdf372
commit 5cd75b8177
5 changed files with 186 additions and 7 deletions
--- a/bin/extract_tests.xsh
+++ b/bin/extract_tests.xsh
@ -27,9 +27,9 @@ for path in TEST_LIST:
    if pfm: continue   # skip examples that don't parse
    ntfm = re.search(r'\n\s*\]\].*?don.t.test', details)
    if ntfm: continue  # explicit skip
-    em = re.search(r'\n\s*\]\]', details)
+    em = re.search(r'\n\]\]', details)
    if not em: continue
-    example = details[:em.start()+1]
+    example = details[:em.start()+1].replace('[[','').replace(']]','')
    expath = destdir / f"{name}.{EXT}"
    expath.write_text(example)
    echo Wrote @(expath)
--- a/editor/Analysis.esv
+++ b/editor/Analysis.esv
@ -22,3 +22,4 @@ menus

    action: "Show pre-analyzed AST" = debug-show-pre-analyzed (source)
    action: "Show analyzed AST"     = debug-show-analyzed
+    action: "Show analyzed type"    = debug-show-type
--- a/tests/basic.spt
+++ b/tests/basic.spt
@ -1,6 +1,16 @@
 module basic
 language fostr

+
+test hw1_type [[
+[[stream]] << [['Hello,	world!']]
+]]
+run get-type on #1 to STREAM()
+run get-type on #2 to STRING()
+run get-type to STREAM()
+/** writes
+Hello,	world!**/
+
 /** md
 Title: A whirlwind tour of fostr

--- a/trans/analysis.str
+++ b/trans/analysis.str
@ -1,5 +1,14 @@
 module analysis

+signature
+  sorts
+    TYPE
+
+  constructors
+    INT : TYPE
+    STRING : TYPE
+    STREAM : TYPE
+
 imports

  statixruntime
@ -51,3 +60,18 @@ rules // Debugging
  debug-show-analyzed: (sel, _, _, path, projp) -> (filename, result)
    with filename := <guarantee-extension(|"analyzed.aterm")> path
       ; result   := sel
+
+  // Extract the type assigned to a node by Statix
+  get-type: node -> type
+    where
+      // Assigns variable a to be the result of the Statix analysis of the entire program (or throws an error)
+      a := <stx-get-ast-analysis <+ fail-msg(|$[no analysis on node [<strip-annos;write-to-string> node]])>;
+      // Gets the type of the given node (or throws an error)
+      type := <stx-get-ast-type(|a) <+ fail-msg(|$[no type on node [<strip-annos;write-to-string> node]])> node
+
+  fail-msg(|msg) = err-msg(|$[get-type: [msg]]); fail
+
+  // Prints the analyzed type of a selection.
+  debug-show-type: (sel, _, _, path, projp) -> (filename, result)
+    with filename := <guarantee-extension(|"type.aterm")> path
+       ; result   := <get-type> sel
--- a/trans/statics.stx
+++ b/trans/statics.stx
@ -25,17 +25,18 @@ to be "OK" from the point of view of Statix:

 Then I reached the point at which the grammar was basically just
 ```SDF3
-// Start.TopLevel = <Ex>
-// Ex.Sequence    = sq:Ex+ {layout: align-list sq}
+// Start.TopLevel = <Seq>
+// Seq            = <Ex>
+// Seq.Sequence   = sq:Ex+ {layout(align-list sq)}
 // Ex.Terminated  = <<Ex>;>
 {! "\git docs/statix_start:syntax/fostr.sdf3" extract:
  start: TermEx.Terminate
  stop: (.*bracket.*)
 !}
 ```
-(The first three clauses are in comments because they approximate fostr's
+(The first four clauses are in comments because they approximate fostr's
 grammar; it actually uses a few more sorts for sequences of
-expressions, to acheive fostr's exact layout rules.)
+expressions, to achieve fostr's exact layout rules.)

 This was the first point at which there were two different types that might
 need to be written to standard output (Int and String), and although of course
@ -46,15 +47,158 @@ that point since I knew it would be hopeless without statically typing fostr
 programs).

 So it was time to bite the bullet and add type checking via Statix to fostr.
+The first step is to replace the simple assertion that any TopLevel
+is OK with a constraint that its Seq must type properly, and an assignment of
+that type to the top level node:
+```statix
+programOk(tl@TopLevel(seq)) :- {T}
+  type_Seq(seq) == T,
+  @tl.type := T.
+```
+Of course, for this to even parse, we must have a definition of `type_Seq`:
+```statix
 **/

+/** md */
+signature
+  sorts TYPE // semantic type
+  constructors
+    INT    : TYPE
+    STRING : TYPE
+    STREAM : TYPE
+/* **/
+
 // see docs/implementation.md for detail on how to switch to multi-file analysis

 rules // single-file entry point

  programOk : Start

-  programOk(TopLevel(_)).
+  /** md
+rules
+  type_Seq : Seq -> TYPE
+```
+  **/
+
+  type_LineSeq : LineSeq -> TYPE
+
+  programOk(tl@TopLevel(seq)) :- {T}
+    type_LineSeq(seq) == T,
+    @tl.type := T.
+
+  /** md
+Now to type a Seq, we look to the syntax, and see that there are two
+possibilities for what it might be: just an Ex, or a Sequence(_) of a
+list of 'Ex's. For the first, Statix does not allow one sort to simply
+"become" another, but the Spoofax infrastructure automatically inserts
+"injection" constructors for us, in this case one named Ex2Seq. So the
+first rule for `type_Seq` is straightforward:
+
+```statix
+  type_Seq(s@Ex2Seq(e)) = T : -
+    type_Ex(e) == T,
+    @s.type := T.
+```
+where of course type_Ex needs its own declaration analogous to the above.
+  **/
+
+  type_Line : Line -> TYPE
+
+  type_LineSeq(ls@Line2LineSeq(l)) = T :-
+    type_Line(l) == T,
+    @ls.type := T.
+
+  type_OptTermEx : OptTermEx -> TYPE
+
+  type_Line(l@OptTermEx2Line(ote)) = T :-
+    type_OptTermEx(ote) == T,
+    @l.type := T.
+
+  type_Ex : Ex -> TYPE
+
+  type_OptTermEx(ote@Ex2OptTermEx(e)) = T :-
+    type_Ex(e) == T,
+    @ote.type :=T.
+
+  /** md
+
+This brings us to the syntax rules for the basic expressions themselves,
+which comprise almost all of the remaining fostr language constructs.
+But first a mechanism suggested by Ivo Wilms to avoid repeating the node
+type annotation in every rule:
+```statix
+  **/
+
+  /** md */
+  ty_Ex : Ex -> TYPE
+
+  type_Ex(e) = ty@ty_Ex(e) :-
+    @e.type := ty.
+  /* **/
+
+  /** md
+```
+At this stage in fostr's development, there was no difference between a
+terminated and unterminated expression, so the typing rule for that
+constructor was trivial:
+```statix
+  ty_Ex(Terminated(e)) = ty_Ex(e).
+```
+  **/
+
+  type_TermEx: TermEx -> TYPE
+
+  type_TermEx(te@Terminate(e)) = T :-
+    type_Ex(e) == T,
+    @te.type := T.
+
+  /** md
+
+Now typing literals is straightforward:
+```statix
+  **/
+
+  /** md */
+  ty_Ex(Int(_))       = INT().
+  ty_Ex(LitString(_)) = STRING().
+  ty_Ex(e@Stream())   = STREAM().
+  /* **/
+
+  /** md
+```
+
+Finally we get to the binary operators, and here we use the pattern found in
+recent versions of the
+"[chicago](https://github.com/MetaBorgCube/statix-sandbox/tree/master/chicago)"
+example language and in the Fall 2020 TU-Delft class lecture on
+[Name Binding and Name Resolution](https://tudelft-cs4200-2020.github.io/lectures/2020/09/24/lecture5/).
+This pattern lets us specify error messages.
+
+```statix
+  **/
+
+  /** md */
+  ty_Ex(Sum(e1, e2)) = INT() :-
+    type_Ex(e1) == INT() | error $[Expression [e1] not an Int in sum.]@e1,
+    type_Ex(e2) == INT() | error $[Expression [e2] not an Int in sum.]@e2.
+
+  ty_Ex(Gets(e1, e2)) = STREAM() :- {T}
+    type_Ex(e1) == STREAM() | error $[Only Streams may receive items.]@e1,
+    type_Ex(e2) == T.
+
+  ty_Ex(To(e1, e2)) = T :-
+    type_Ex(e1) == T,
+    type_Ex(e2) == STREAM() | error $[Items may only be sent to Streams.]@e2.
+  /* **/
+
+  /** md
+```
+
+### Using type annotations in transformation
+
+_Probably want to include stuff from analysis.str/ haskell.str here_
+
+  **/

 rules // multi-file entry point