Add literal string constants (#19)
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In addition, for the sake of Haskell code generation, this PR adds static typing
  with Statix.

  Resolves #5.

Co-authored-by: Glen Whitney <glen@studioinfinity.org>
Reviewed-on: #19
Co-Authored-By: Glen Whitney <glen@nobody@nowhere.net>
Co-Committed-By: Glen Whitney <glen@nobody@nowhere.net>
This commit is contained in:
Glen Whitney 2021-02-18 04:17:05 +00:00
parent c516ed6d7f
commit 2772fd0c5c
16 changed files with 386 additions and 34 deletions

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@ -11,7 +11,8 @@ language as possible to work in, given that I inevitably will be doing a
bunch of coding. The language will be centrally organized around the bunch of coding. The language will be centrally organized around the
concept of "streams" (somewhat in the spirit of concept of "streams" (somewhat in the spirit of
[streem](https://github.com/matz/streem) and/or [streem](https://github.com/matz/streem) and/or
[Orc](http://orc.csres.utexas.edu/index.shtml)). In fact all higher-type [Orc](http://orc.csres.utexas.edu/index.shtml), or to a lesser extent,
[Sisal-is](https://github.com/parsifal-47/sisal-is)). In fact all higher-type
entities will be cast in terms of streams, or in slogan form, "++f++unctions entities will be cast in terms of streams, or in slogan form, "++f++unctions
and (binary) ++o++perators are ++str++eams" (hence the name "fostr"). and (binary) ++o++perators are ++str++eams" (hence the name "fostr").

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@ -27,9 +27,9 @@ for path in TEST_LIST:
if pfm: continue # skip examples that don't parse if pfm: continue # skip examples that don't parse
ntfm = re.search(r'\n\s*\]\].*?don.t.test', details) ntfm = re.search(r'\n\s*\]\].*?don.t.test', details)
if ntfm: continue # explicit skip if ntfm: continue # explicit skip
em = re.search(r'\n\s*\]\]', details) em = re.search(r'\n\]\]', details)
if not em: continue if not em: continue
example = details[:em.start()+1] example = details[:em.start()+1].replace('[[','').replace(']]','')
expath = destdir / f"{name}.{EXT}" expath = destdir / f"{name}.{EXT}"
expath.write_text(example) expath.write_text(example)
echo Wrote @(expath) echo Wrote @(expath)

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@ -22,3 +22,4 @@ menus
action: "Show pre-analyzed AST" = debug-show-pre-analyzed (source) action: "Show pre-analyzed AST" = debug-show-pre-analyzed (source)
action: "Show analyzed AST" = debug-show-analyzed action: "Show analyzed AST" = debug-show-analyzed
action: "Show analyzed type" = debug-show-type

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@ -2,6 +2,7 @@ site_name: fostr language
nav: nav:
- README.md - README.md
- tests/basic.md - tests/basic.md
- trans/statics.md
- implementation.md - implementation.md
plugins: plugins:

1
signature/TYPE.str Symbolic link
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@ -0,0 +1 @@
TYPE.stx

7
signature/TYPE.stx Normal file
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@ -0,0 +1,7 @@
module signature/TYPE
signature
sorts TYPE // semantic type
constructors
INT : TYPE
STRING : TYPE
STREAM : TYPE

7
statics/util.stx Normal file
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@ -0,0 +1,7 @@
module statics/util
imports signature/TYPE
rules
lastTYPE : list(TYPE) -> TYPE
lastTYPE([T]) = T.
lastTYPE([U | TS]) = lastTYPE(TS).

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@ -8,6 +8,14 @@ context-free start-symbols
Start Start
lexical sorts
STRING_LITERAL
lexical syntax
STRING_LITERAL = "'"~[\']*"'"
context-free sorts context-free sorts
Start LineSeq Line OptTermEx TermExLst TermEx Ex Start LineSeq Line OptTermEx TermExLst TermEx Ex
@ -30,8 +38,9 @@ context-free syntax
TermEx.Terminate = <<Ex>;> TermEx.Terminate = <<Ex>;>
Ex.Int = INT Ex.Int = INT
Ex.LitString = STRING_LITERAL
Ex.Stream = <stream> Ex.Stream = <stream>
Ex.Sum = [[Ex] + [Ex]] {left} Ex.Sum = <<Ex> + <Ex>> {left}
Ex.Gets = [[Ex] << [Ex]] {left} Ex.Gets = [[Ex] << [Ex]] {left}
Ex.To = [[Ex] >> [Ex]] {left} Ex.To = [[Ex] >> [Ex]] {left}

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@ -1,6 +1,16 @@
module basic module basic
language fostr language fostr
test hw1_type [[
[[stream]] << [['Hello, world! ']] << [[3+2]] << ' times.'
]]
run get-type on #1 to STREAM()
run get-type on #2 to STRING()
run get-type on #3 to INT()
run get-type to STREAM()
/** writes
Hello, world! 5 times.**/
/** md /** md
Title: A whirlwind tour of fostr Title: A whirlwind tour of fostr

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@ -1,4 +1,4 @@
stream << 72 + 87 stream << 'Some numbers: '
stream << 88 stream << 88
+ 96 + 96
99 + 12 >> 99 + 12 >>

1
tests/hw.fos Normal file
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@ -0,0 +1 @@
stream << 'Hello, world!'

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@ -1,5 +1,4 @@
module analysis module analysis
imports imports
statixruntime statixruntime
@ -51,3 +50,18 @@ rules // Debugging
debug-show-analyzed: (sel, _, _, path, projp) -> (filename, result) debug-show-analyzed: (sel, _, _, path, projp) -> (filename, result)
with filename := <guarantee-extension(|"analyzed.aterm")> path with filename := <guarantee-extension(|"analyzed.aterm")> path
; result := sel ; 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

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@ -1,15 +1,25 @@
module haskell module haskell
imports libstrategolib signatures/- util imports libstrategolib signatures/- signature/TYPE util analysis
rules rules
/* Approach: Generate code from the bottom up. /* Approach:
At every node, we create a pair of the implementation and A) We will define a local transformation taking a term with value strings
necessary preamble of IO actions. at each child to a value string for the node.
We concatenate preambles as we go up. B) We will append IO actions needed to set up for the value progressively
Finally, at the toplevel we emit the preamble before returning the to a Preactions rule (mapping () to the list of actions). There will
final value. be a utility `add-preaction` to append a new clause to value of this
rule.
C) We will use bottomup-para to traverse the full AST with the
transformation from A so that we have access to the original expression
(and get get the Statix-associated type when we need to).
Hence the transformation in (A) must actually take a pair of
an (original) term and a term with value strings at each child,
and be certain to return a value string.
Finally, at the toplevel we emit the result of <Preactions>() before
returning the final value.
*/ */
hs: TopLevel((c,p)) -> $[import System.IO hs: (_, TopLevel(val)) -> $[import System.IO
data IOStream = StdIO data IOStream = StdIO
gets :: Show b => a -> b -> IO a gets :: Show b => a -> b -> IO a
@ -17,27 +27,61 @@ rules
putStr(show d) putStr(show d)
return s return s
getsStr :: a -> String -> IO a
getsStr s d = do
putStr(d)
return s
main = do main = do
[p]return [c]] [<Preactions>()]return [val]]
hs: Stream() -> ("StdIO", "") hs: (_, Stream()) -> "StdIO"
hs: Int(x) -> (x, "") hs: (_, Int(x)) -> x
hs: Sum( (c, p), (d, q)) -> ($[([c] + [d])], <conc-strings>(p,q)) hs: (_, LitString(x)) -> <haskLitString>x
hs: (_, Sum(x, y)) -> $[([x] + [y])]
hs: Gets((c, p), (d, q)) -> <hsget>(c,d,<conc-strings>(p,q),<newname>"fosgt") hs: (Gets(_, xn), Gets(s, x)) -> v
hsget: (s, x, p, v) -> (v, <concat-strings>[p, $[[v] <- [s] `gets` [x]], with v := <newname>"_fostr_get"
"\n"]) ; <add-preactions>[$[[v] <- [<hs_gets>(s, xn, x)]]]
hs: (To(xn, _), To(x, s)) -> v
with v := <newname>"_fostr_to"
; <add-preactions>[$[let [v] = [x]], <hs_gets>(s, xn, v)]
hs: To( (c, p), (d, q)) -> <hsto>(c,d,<conc-strings>(p,q),<newname>"fosto") hs_gets: (s, xn, x ) -> $[[s] [<hs_getOp>xn] [x]]
hsto: (x, s, p, v) -> (v, <concat-strings>[p, $[let [v] = [x]], "\n", hs_getOp = get-type; (?STRING() < !"`getsStr`" + !"`gets`")
$[[s] `gets` [v]], "\n"])
hs: Terminate((c,p)) -> ($[[c];;], p) hs: (_, Terminate(x)) -> $[[x];;]
hs: Sequence(l) -> (<last; Fst>l, <map(Snd); concat-strings>l) hs: (_, Sequence(l)) -> <last>l
/* One drawback of using paramorphism is we have to handle lists
explicitly:
*/
hs: (_, []) -> []
hs: (_, [x | xs]) -> [x | xs]
/* Another drawback of using paramorphism is at the very leaves we have
to undouble the tuple:
*/
hs: (x, x) -> x where <is-string>x
/* Characters we need to escape in Haskell string constants */
Hascape: ['\t' | cs ] -> ['\', 't' | cs ]
/* I think I can just use ASCII constants for characters... */
Hascape: [ 0 | cs ] -> ['\', '0' | cs ]
Hascape: [ 7 | cs ] -> ['\', 'a' | cs ] // Alert
Hascape: [ 8 | cs ] -> ['\', 'b' | cs ] // Backspace
Hascape: [ 11 | cs ] -> ['\', 'v' | cs ] // Vertical tab
Hascape: [ 12 | cs ] -> ['\', 'f' | cs ] // Form feed
strategies strategies
haskLitString = un-single-quote
; string-as-chars(escape-chars(Escape <+ Hascape))
; double-quote
haskell = bottomup(try(hs)) haskell = rules(Preactions: () -> ""); bottomup-para(try(hs))
/* See "Approach" at top of file */
add-preactions = newp := <conc-strings>(<Preactions>(), <lines>)
; rules(Preactions: () -> newp)
// Interface haskell code generation with editor services and file system // Interface haskell code generation with editor services and file system
to-haskell: (selected, _, _, path, project-path) -> (filename, result) to-haskell: (selected, _, _, path, project-path) -> (filename, result)

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@ -13,13 +13,25 @@ rules
js: Stream() -> $[Stdio] js: Stream() -> $[Stdio]
js: Int(x) -> x js: Int(x) -> x
js: LitString(x) -> <javaLitString>x
js: Sum(x,y) -> $[[x] + [y]] js: Sum(x,y) -> $[[x] + [y]]
js: Gets(x, y) -> $[[x].gets([y])] js: Gets(x, y) -> $[[x].gets([y])]
js: To(x, y) -> $[to([x],[y])] js: To(x, y) -> $[to([x],[y])]
js: Terminate(x) -> x js: Terminate(x) -> x
js: Sequence(l) -> <join(|";\n")>l js: Sequence(l) -> <join(|";\n")>l
/* Characters we need to escape in Javascript string constants */
Jscape: ['\t' | cs ] -> ['\', 't' | cs ]
/* I think I can just use ASCII constants for characters... */
Jscape: [ 0 | cs ] -> ['\', '0' | cs ]
Jscape: [ 8 | cs ] -> ['\', 'b' | cs ] // Backspace
Jscape: [ 11 | cs ] -> ['\', 'v' | cs ] // Vertical tab
Jscape: [ 12 | cs ] -> ['\', 'f' | cs ] // Form feed
strategies strategies
javaLitString = un-single-quote
; string-as-chars(escape-chars(Escape <+ Jscape))
; single-quote
javascript = bottomup(try(js)) javascript = bottomup(try(js))

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@ -15,6 +15,7 @@ rules
py: Stream() -> $[Stdio] py: Stream() -> $[Stdio]
py: Int(x) -> x py: Int(x) -> x
py: LitString(x) -> $[r[x]]
py: Sum(x,y) -> $[[x] + [y]] py: Sum(x,y) -> $[[x] + [y]]
py: Gets(x, y) -> $[[x].gets([y])] py: Gets(x, y) -> $[[x].gets([y])]
py: To(x, y) -> $[to([x],[y])] py: To(x, y) -> $[to([x],[y])]

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@ -1,14 +1,257 @@
module statics module statics
imports signatures/fostr-sig imports signatures/fostr-sig
imports signature/TYPE
imports statics/util
// see docs/implementation.md for details on how to switch to multi-file analysis /** md
Title: Adding Program Analysis with Statix
## Development of fostr static analysis
This section is more documentation of Spoofax in general and Statix
in particular than of fostr itself, but is being maintained here in case
it could be either helpful to someone getting started with Statix or
helpful in understanding how the static characteristics of fostr were designed.
As mentioned in the [Overview](../README.md), I don't like to program and a
corollary of that is never to use a facility unless/until there's a need for
it. So the first few rudimentary passes at fostr simply declared every program
to be "OK" from the point of view of Statix:
```statix
{! "\git docs/statix_start:trans/statics.stx" extract:
start: programOk
stop: (.*TopLevel.*)
!}
```
Then I reached the point at which the grammar was basically just
```SDF3
// 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 four clauses are in comments because they approximate fostr's
grammar; it actually uses a few more sorts for sequences of
expressions, to achieve fostr's exact layout rules. Also note that the parsing
of literal strings later evolved to include the surrounding single quotes,
because the rule above implicitly allows layout between the quotes and the
string contents, creating ambiguity.)
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
the dynamically-typed Python and Javascript code generated dealt with both fine,
the Haskell code needed to differ depending on the
type of the item written (and I hadn't even started OCaml code generation at
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 was 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
{! ../signature/TYPE.stx extract: {start: module, stop: rules} !}
**/
// see docs/implementation.md for detail on how to switch to multi-file analysis
rules // single-file entry point rules // single-file entry point
programOk : Start 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.
/** md
The other (and in fact more typical) rule for `type_Seq`, when it actually
consists of a sequence of expressions, is a bit more involved. Fortunately
Statix provides a primitive for mapping over a list, so we can proceed as
follows:
```statix
types_Exs maps type_Ex(list(*)) = list(*)
type_Seq(s@Sequence(l)) = T :- {lt}
types_Exs(l) == lt,
lastTYPE(lt) == T,
@s.type := T.
```
Here `lastTYPE` is a function that extracts the last TYPE from a list.
Unless/until Statix develops some sort of standard library, it must be
hand-defined, as done in "statics/util.stx" like so:
```statix
{! ../statics/util.stx extract: {start: lastTYPE} !}
```
**/
types_Lines maps type_Line(list(*)) = list(*)
type_LineSeq(ls@Sequence(l)) = T :- {lt}
types_Lines(l) == lt,
lastTYPE(lt) == 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_TermEx : TermEx -> TYPE
type_OptTermEx(ote@Ex2OptTermEx(e)) = T :-
type_Ex(e) == T,
@ote.type := T.
type_OptTermEx(ote@TermEx2OptTermEx(te)) = T :-
type_TermEx(te) == 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(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
At this point, Statix properly types all of the valid programs of the very
rudimentary language defined by the grammar above. But the proximate purpose
for implementing this typing was to aid Haskell code generation. So how
do we actually use the assigned types in a Stratego transformation?
Statix provides a Stratego api that includes, among other items, strategies
`stx-get-ast-analysis` and `stx-get-ast-type(|analysis)` that provide access
to the assigned types. However, it's easiest to use the information via
a wrapper like this, essentially lifted from the "chicago" language project:
```stratego
{! analysis.str extract:
start: Extract.the.type
terminate: Prints.the.analyzed.type
!}
```
Now `get_type` run on a node of the analyzed AST produces the assigned `TYPE`
(as an ATerm in the constructors of sort TYPE in Statix).
Thus, you can select on the assigned type, as in the strategy to select
the correct Haskell operator to use to send an item to standard output:
```stratego
{! haskell.str extract:
start: '(.*hs_getOp.=.*)'
stop: \s
!}
```
**/
rules // multi-file entry point rules // multi-file entry point