This commit is contained in:
Sander Spies 2020-04-14 10:32:12 +02:00
commit 2b82a74d93
192 changed files with 5863 additions and 2879 deletions

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@ -19,7 +19,7 @@ RUN echo "Package: ligo\n\
Version: $version\n\ Version: $version\n\
Architecture: all\n\ Architecture: all\n\
Maintainer: info@ligolang.org\n\ Maintainer: info@ligolang.org\n\
Depends: libev4, libgmp10, libgmpxx4ldbl, cpp\n\ Depends: libev4, libgmp10, libgmpxx4ldbl\n\
Homepage: http://ligolang.org\n\ Homepage: http://ligolang.org\n\
Description: LIGO is a statically typed high-level smart-contract language that compiles down to Michelson." >> /package/DEBIAN/control Description: LIGO is a statically typed high-level smart-contract language that compiles down to Michelson." >> /package/DEBIAN/control

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@ -29,7 +29,7 @@ RUN opam update
# Install ligo # Install ligo
RUN sh scripts/install_vendors_deps.sh RUN sh scripts/install_vendors_deps.sh
RUN opam install -y . RUN opam install -y . || (tail -n +1 ~/.opam/log/* ; false)
# Use the ligo binary as a default command # Use the ligo binary as a default command
ENTRYPOINT [ "/home/opam/.opam/4.07/bin/ligo" ] ENTRYPOINT [ "/home/opam/.opam/4.07/bin/ligo" ]

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@ -466,8 +466,8 @@ let proxy = ((action, store): (parameter, storage)) : return => {
| Some (contract) => contract; | Some (contract) => contract;
| None => (failwith ("Contract not found.") : contract (parameter)); | None => (failwith ("Contract not found.") : contract (parameter));
}; };
(* Reuse the parameter in the subsequent /* Reuse the parameter in the subsequent
transaction or use another one, `mock_param`. *) transaction or use another one, `mock_param`. */
let mock_param : parameter = Increment (5n); let mock_param : parameter = Increment (5n);
let op : operation = Tezos.transaction (action, 0tez, counter); let op : operation = Tezos.transaction (action, 0tez, counter);
([op], store) ([op], store)

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@ -1,6 +1,6 @@
name: "ligo" name: "ligo"
opam-version: "2.0" opam-version: "2.0"
maintainer: "ligolang@gmail.com" maintainer: "Galfour <contact@ligolang.org>"
authors: [ "Galfour" ] authors: [ "Galfour" ]
homepage: "https://gitlab.com/ligolang/tezos" homepage: "https://gitlab.com/ligolang/tezos"
bug-reports: "https://gitlab.com/ligolang/tezos/issues" bug-reports: "https://gitlab.com/ligolang/tezos/issues"
@ -23,6 +23,8 @@ depends: [
"getopt" "getopt"
"terminal_size" "terminal_size"
"pprint" "pprint"
"UnionFind"
"RedBlackTrees"
# work around upstream in-place update # work around upstream in-place update
"ocaml-migrate-parsetree" { = "1.4.0" } "ocaml-migrate-parsetree" { = "1.4.0" }
] ]

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@ -1,5 +1,6 @@
#!/bin/sh #!/bin/sh
set -e set -e
set -x
if test $# -ne 1 || test "x$1" = "-h" -o "x$1" = "x--help"; then if test $# -ne 1 || test "x$1" = "-h" -o "x$1" = "x--help"; then
echo "Usage: build_docker_image.sh TAG_NAME" echo "Usage: build_docker_image.sh TAG_NAME"

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@ -1,5 +1,6 @@
#!/bin/sh #!/bin/sh
set -e set -e
set -x
eval $(opam config env) eval $(opam config env)
dune build -p ligo dune build -p ligo

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@ -1,4 +1,6 @@
#!/bin/sh #!/bin/sh
set -e
set -x
dockerfile_name="build" dockerfile_name="build"
# Generic dockerfile # Generic dockerfile

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@ -1,4 +1,6 @@
#!/bin/sh #!/bin/sh
set -e
set -x
dockerfile_name="package" dockerfile_name="package"
dockerfile="" dockerfile=""

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@ -1,11 +1,15 @@
#!/bin/sh
set -e
set -x
# This script accepts three arguments, os family, os and its version, # This script accepts three arguments, os family, os and its version,
# which are subsequently used to fetch the respective docker # which are subsequently used to fetch the respective docker
# image from the ocaml/infrastructure project. # image from the ocaml/infrastructure project.
# #
# https://github.com/ocaml/infrastructure/wiki/Containers#selecting-linux-distributions # https://github.com/ocaml/infrastructure/wiki/Containers#selecting-linux-distributions
target_os_family=$1 target_os_family="$1"
target_os=$2 target_os="$2"
target_os_version=$3 target_os_version="$3"
# Variables configured at the CI level # Variables configured at the CI level
dist="$LIGO_DIST_DIR" dist="$LIGO_DIST_DIR"

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@ -22,6 +22,7 @@ echo "Installing dependencies.."
if [ -n "`uname -a | grep -i arch`" ] if [ -n "`uname -a | grep -i arch`" ]
then then
sudo pacman -Sy --noconfirm \ sudo pacman -Sy --noconfirm \
rakudo \
make \ make \
m4 \ m4 \
gcc \ gcc \
@ -34,6 +35,8 @@ fi
if [ -n "`uname -a | grep -i ubuntu`" ] if [ -n "`uname -a | grep -i ubuntu`" ]
then then
sudo apt-get install -y make \ sudo apt-get install -y make \
perl6 \
make \
m4 \ m4 \
gcc \ gcc \
patch \ patch \

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@ -1,11 +1,13 @@
#!/bin/sh #!/bin/sh
set -e set -e
set -x
. /etc/os-release . /etc/os-release
if [ $ID = arch ] if [ $ID = arch ]
then then
pacman -Sy pacman -Sy
sudo pacman -S --noconfirm \ sudo pacman -S --noconfirm \
rakudo \
libevdev \ libevdev \
perl \ perl \
pkg-config \ pkg-config \
@ -20,6 +22,7 @@ then
else else
apt-get update -qq apt-get update -qq
apt-get -y -qq install \ apt-get -y -qq install \
perl6 \
libev-dev \ libev-dev \
perl \ perl \
pkg-config \ pkg-config \

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@ -1,5 +1,6 @@
#!/bin/sh #!/bin/sh
set -e set -e
set -x
# Install local dependencies # Install local dependencies
opam install -y --deps-only --with-test ./ligo.opam $(find vendors -name \*.opam) opam install -y --deps-only --with-test ./ligo.opam $(find vendors -name \*.opam)

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@ -152,6 +152,18 @@ let compile_file =
let doc = "Subcommand: Compile a contract." in let doc = "Subcommand: Compile a contract." in
(Term.ret term , Term.info ~doc cmdname) (Term.ret term , Term.info ~doc cmdname)
let preprocess =
let f source_file syntax display_format = (
toplevel ~display_format @@
let%bind pp =
Compile.Of_source.preprocess source_file (Syntax_name syntax) in
ok @@ Format.asprintf "%s \n" (Buffer.contents pp)
) in
let term = Term.(const f $ source_file 0 $ syntax $ display_format) in
let cmdname = "preprocess" in
let doc = "Subcommand: Preprocess the source file.\nWarning: Intended for development of LIGO and can break at any time." in
(Term.ret term, Term.info ~doc cmdname)
let print_cst = let print_cst =
let f source_file syntax display_format = ( let f source_file syntax display_format = (
toplevel ~display_format @@ toplevel ~display_format @@
@ -470,4 +482,5 @@ let run ?argv () =
print_ast_typed ; print_ast_typed ;
print_mini_c ; print_mini_c ;
list_declarations ; list_declarations ;
preprocess
] ]

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@ -3,7 +3,7 @@ open Cli_expect
let%expect_test _ = let%expect_test _ =
run_ligo_bad [ "compile-contract" ; "../../test/contracts/negative/gitlab_111.religo" ; "main" ] ; run_ligo_bad [ "compile-contract" ; "../../test/contracts/negative/gitlab_111.religo" ; "main" ] ;
[%expect {| [%expect {|
ligo: : Parse error in file "gitlab_111.religo", line 2, characters 0-3, after "=" and before "let": ligo: : Parse error in file "gitlab_111.religo", line 2, characters 0-3 at "let", after "=":
This is an incorrect let binding. This is an incorrect let binding.
- -
Examples of correct let bindings: Examples of correct let bindings:
@ -23,7 +23,7 @@ let%expect_test _ =
run_ligo_bad [ "compile-contract" ; "../../test/contracts/negative/missing_rpar.religo" ; "main" ] ; run_ligo_bad [ "compile-contract" ; "../../test/contracts/negative/missing_rpar.religo" ; "main" ] ;
[%expect {| [%expect {|
ligo: : Parse error in file "missing_rpar.religo", line 5, characters 0-3, after "m" and before "let": ligo: : Parse error in file "missing_rpar.religo", line 5, characters 0-3 at "let", after "m":
Missing `)`. Missing `)`.
{} {}

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@ -53,6 +53,10 @@ let%expect_test _ =
measure-contract measure-contract
Subcommand: Measure a contract's compiled size in bytes. Subcommand: Measure a contract's compiled size in bytes.
preprocess
Subcommand: Preprocess the source file. Warning: Intended for
development of LIGO and can break at any time.
print-ast print-ast
Subcommand: Print the AST. Warning: Intended for development of Subcommand: Print the AST. Warning: Intended for development of
LIGO and can break at any time. LIGO and can break at any time.
@ -140,6 +144,10 @@ let%expect_test _ =
measure-contract measure-contract
Subcommand: Measure a contract's compiled size in bytes. Subcommand: Measure a contract's compiled size in bytes.
preprocess
Subcommand: Preprocess the source file. Warning: Intended for
development of LIGO and can break at any time.
print-ast print-ast
Subcommand: Print the AST. Warning: Intended for development of Subcommand: Print the AST. Warning: Intended for development of
LIGO and can break at any time. LIGO and can break at any time.

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@ -3,7 +3,7 @@ open Cli_expect
let%expect_test _ = let%expect_test _ =
run_ligo_bad [ "compile-contract" ; "../../test/contracts/negative/error_syntax.ligo" ; "main" ] ; run_ligo_bad [ "compile-contract" ; "../../test/contracts/negative/error_syntax.ligo" ; "main" ] ;
[%expect {| [%expect {|
ligo: : Parse error in file "error_syntax.ligo", line 1, characters 16-17, after "bar" and before "-": ligo: : Parse error in file "error_syntax.ligo", line 1, characters 16-17 at "-", after "bar":
15: <syntax error> {} 15: <syntax error> {}

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@ -1,14 +1,13 @@
(dirs (:standard \ toto)) (dirs (:standard))
(library (library
(name ligo) (name ligo)
(public_name ligo) (public_name ligo)
(libraries (libraries
Preprocessor
simple-utils simple-utils
tezos-utils tezos-utils
tezos-micheline tezos-micheline
main main)
)
(preprocess (preprocess
(pps ppx_let bisect_ppx --conditional) (pps ppx_let bisect_ppx --conditional)))
)
)

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@ -148,18 +148,18 @@ let pretty_print_cameligo source =
~offsets:true ~offsets:true
~mode:`Point ~mode:`Point
~buffer in ~buffer in
Parser.Cameligo.ParserLog.pp_ast state ast; Parser_cameligo.ParserLog.pp_ast state ast;
ok buffer ok buffer
let pretty_print_reasonligo source = let pretty_print_reasonligo source =
let%bind ast = Parser.Reasonligo.parse_file source in let%bind ast = Parser.Reasonligo.parse_file source in
let buffer = Buffer.create 59 in let buffer = Buffer.create 59 in
let state = (* TODO: Should flow from the CLI *) let state = (* TODO: Should flow from the CLI *)
Parser.Reasonligo.ParserLog.mk_state Parser_cameligo.ParserLog.mk_state
~offsets:true ~offsets:true
~mode:`Point ~mode:`Point
~buffer in ~buffer in
Parser.Reasonligo.ParserLog.pp_ast state ast; Parser_cameligo.ParserLog.pp_ast state ast;
ok buffer ok buffer
let pretty_print syntax source = let pretty_print syntax source =
@ -169,3 +169,17 @@ let pretty_print syntax source =
PascaLIGO -> pretty_print_pascaligo source PascaLIGO -> pretty_print_pascaligo source
| CameLIGO -> pretty_print_cameligo source | CameLIGO -> pretty_print_cameligo source
| ReasonLIGO -> pretty_print_reasonligo source | ReasonLIGO -> pretty_print_reasonligo source
let preprocess_pascaligo = Parser.Pascaligo.preprocess
let preprocess_cameligo = Parser.Cameligo.preprocess
let preprocess_reasonligo = Parser.Reasonligo.preprocess
let preprocess syntax source =
let%bind v_syntax =
syntax_to_variant syntax (Some source) in
match v_syntax with
PascaLIGO -> preprocess_pascaligo source
| CameLIGO -> preprocess_cameligo source
| ReasonLIGO -> preprocess_reasonligo source

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@ -21,3 +21,6 @@ let compile_contract_input : string -> string -> v_syntax -> Ast_imperative.expr
let pretty_print source_filename syntax = let pretty_print source_filename syntax =
Helpers.pretty_print syntax source_filename Helpers.pretty_print syntax source_filename
let preprocess source_filename syntax =
Helpers.preprocess syntax source_filename

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@ -4,26 +4,46 @@ module Lexer = Lexer.Make(LexToken)
module Scoping = Parser_cameligo.Scoping module Scoping = Parser_cameligo.Scoping
module Region = Simple_utils.Region module Region = Simple_utils.Region
module ParErr = Parser_cameligo.ParErr module ParErr = Parser_cameligo.ParErr
module SSet = Utils.String.Set module SSet = Set.Make (String)
(* Mock IOs TODO: Fill them with CLI options *) (* Mock IOs TODO: Fill them with CLI options *)
module type IO = type language = [`PascaLIGO | `CameLIGO | `ReasonLIGO]
sig
val ext : string module SubIO =
val options : EvalOpt.options struct
type options = <
libs : string list;
verbose : SSet.t;
offsets : bool;
lang : language;
ext : string; (* ".mligo" *)
mode : [`Byte | `Point];
cmd : EvalOpt.command;
mono : bool
>
let options : options =
object
method libs = []
method verbose = SSet.empty
method offsets = true
method lang = `CameLIGO
method ext = ".mligo"
method mode = `Point
method cmd = EvalOpt.Quiet
method mono = false
end end
module PreIO = let make =
struct EvalOpt.make ~libs:options#libs
let ext = ".ligo" ~verbose:options#verbose
let pre_options = ~offsets:options#offsets
EvalOpt.make ~libs:[] ~lang:options#lang
~verbose:SSet.empty ~ext:options#ext
~offsets:true ~mode:options#mode
~mode:`Point ~cmd:options#cmd
~cmd:EvalOpt.Quiet ~mono:options#mono
~mono:false
end end
module Parser = module Parser =
@ -40,34 +60,33 @@ module ParserLog =
include Parser_cameligo.ParserLog include Parser_cameligo.ParserLog
end end
module PreUnit = module Unit =
ParserUnit.Make (Lexer)(AST)(Parser)(ParErr)(ParserLog) ParserUnit.Make (Lexer)(AST)(Parser)(ParErr)(ParserLog)(SubIO)
module Errors = module Errors =
struct struct
(* let data =
[("location",
fun () -> Format.asprintf "%a" Location.pp_lift @@ loc)] *)
let generic message = let generic message =
let title () = "" let title () = ""
and message () = message.Region.value and message () = message.Region.value
in Trace.error ~data:[] title message in Trace.error ~data:[] title message
end end
let parse (module IO : IO) parser = let apply parser =
let module Unit = PreUnit (IO) in
let local_fail error = let local_fail error =
Trace.fail Trace.fail
@@ Errors.generic @@ Errors.generic
@@ Unit.format_error ~offsets:IO.options#offsets @@ Unit.format_error ~offsets:SubIO.options#offsets
IO.options#mode error in SubIO.options#mode error in
match parser () with match parser () with
Stdlib.Ok semantic_value -> Trace.ok semantic_value Stdlib.Ok semantic_value -> Trace.ok semantic_value
(* Lexing and parsing errors *) (* Lexing and parsing errors *)
| Stdlib.Error error -> Trace.fail @@ Errors.generic error | Stdlib.Error error -> Trace.fail @@ Errors.generic error
(* System errors *)
| exception Sys_error msg ->
Trace.fail @@ Errors.generic (Region.wrap_ghost msg)
(* Scoping errors *) (* Scoping errors *)
| exception Scoping.Error (Scoping.Reserved_name name) -> | exception Scoping.Error (Scoping.Reserved_name name) ->
@ -110,71 +129,18 @@ let parse (module IO : IO) parser =
Hint: Change the name.\n", Hint: Change the name.\n",
None, invalid)) None, invalid))
let parse_file (source: string) = (* Parsing a contract in a file *)
let module IO =
struct
let ext = PreIO.ext
let options =
PreIO.pre_options ~input:(Some source) ~expr:false
end in
let lib_path =
match IO.options#libs with
[] -> ""
| libs -> let mk_I dir path = Printf.sprintf " -I %s%s" dir path
in List.fold_right mk_I libs "" in
let prefix =
match IO.options#input with
None | Some "-" -> "temp"
| Some file -> Filename.(remove_extension @@ basename file) in
let suffix = ".pp" ^ IO.ext in
let pp_input =
if SSet.mem "cpp" IO.options#verbose
then prefix ^ suffix
else let pp_input, pp_out =
Filename.open_temp_file prefix suffix
in close_out pp_out; pp_input in
let cpp_cmd =
match IO.options#input with
None | Some "-" ->
Printf.sprintf "cpp -traditional-cpp%s - > %s"
lib_path pp_input
| Some file ->
Printf.sprintf "cpp -traditional-cpp%s %s > %s"
lib_path file pp_input in
let open Trace in
let%bind () = sys_command cpp_cmd in
let module Unit = PreUnit (IO) in
match Lexer.(open_token_stream @@ File pp_input) with
Ok instance ->
let thunk () = Unit.apply instance Unit.parse_contract
in parse (module IO) thunk
| Stdlib.Error (Lexer.File_opening msg) ->
Trace.fail @@ Errors.generic @@ Region.wrap_ghost msg
let parse_string (s: string) = let parse_file source = apply (fun () -> Unit.contract_in_file source)
let module IO =
struct
let ext = PreIO.ext
let options = PreIO.pre_options ~input:None ~expr:false
end in
let module Unit = PreUnit (IO) in
match Lexer.(open_token_stream @@ String s) with
Ok instance ->
let thunk () = Unit.apply instance Unit.parse_contract
in parse (module IO) thunk
| Stdlib.Error (Lexer.File_opening msg) ->
Trace.fail @@ Errors.generic @@ Region.wrap_ghost msg
let parse_expression (s: string) = (* Parsing a contract in a string *)
let module IO =
struct let parse_string source = apply (fun () -> Unit.contract_in_string source)
let ext = PreIO.ext
let options = PreIO.pre_options ~input:None ~expr:true (* Parsing an expression in a string *)
end in
let module Unit = PreUnit (IO) in let parse_expression source = apply (fun () -> Unit.expr_in_string source)
match Lexer.(open_token_stream @@ String s) with
Ok instance -> (* Preprocessing a contract in a file *)
let thunk () = Unit.apply instance Unit.parse_expr
in parse (module IO) thunk let preprocess source = apply (fun () -> Unit.preprocess source)
| Stdlib.Error (Lexer.File_opening msg) ->
Trace.fail @@ Errors.generic @@ Region.wrap_ghost msg

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@ -0,0 +1,21 @@
(** This file provides an interface to the CameLIGO parser. *)
module AST = Parser_cameligo.AST
(** Open a CameLIGO filename given by string and convert into an
abstract syntax tree. *)
val parse_file : string -> AST.t Trace.result
(** Convert a given string into a CameLIGO abstract syntax tree *)
val parse_string : string -> AST.t Trace.result
(** Parse a given string as a CameLIGO expression and return an
expression AST.
This is intended to be used for interactive interpreters, or other
scenarios where you would want to parse a CameLIGO expression
outside of a contract. *)
val parse_expression : string -> AST.expr Trace.result
(** Preprocess a given CameLIGO file and preprocess it. *)
val preprocess : string -> Buffer.t Trace.result

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@ -1,8 +1,5 @@
$HOME/git/OCaml-build/Makefile $HOME/git/OCaml-build/Makefile
$HOME/git/ligo/vendors/ligo-utils/simple-utils/pos.mli
$HOME/git/ligo/vendors/ligo-utils/simple-utils/pos.ml
$HOME/git/ligo/vendors/ligo-utils/simple-utils/region.mli
$HOME/git/ligo/vendors/ligo-utils/simple-utils/region.ml
../shared/Lexer.mli ../shared/Lexer.mli
../shared/Lexer.mll ../shared/Lexer.mll
../shared/EvalOpt.ml ../shared/EvalOpt.ml
@ -17,7 +14,9 @@ $HOME/git/ligo/vendors/ligo-utils/simple-utils/region.ml
../shared/Utils.ml ../shared/Utils.ml
../shared/ParserAPI.mli ../shared/ParserAPI.mli
../shared/ParserAPI.ml ../shared/ParserAPI.ml
../shared/LexerUnit.mli
../shared/LexerUnit.ml ../shared/LexerUnit.ml
../shared/ParserUnit.mli
../shared/ParserUnit.ml ../shared/ParserUnit.ml
Stubs/Simple_utils.ml
$HOME/git/ligo/_build/default/src/passes/1-parser/cameligo/ParErr.ml $HOME/git/ligo/_build/default/src/passes/1-parser/cameligo/ParErr.ml

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@ -19,6 +19,8 @@ open Utils
denoting the _region_ of the occurrence of the keyword "and". denoting the _region_ of the occurrence of the keyword "and".
*) *)
module Region = Simple_utils.Region
type 'a reg = 'a Region.reg type 'a reg = 'a Region.reg
(* Keywords of OCaml *) (* Keywords of OCaml *)

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@ -4,8 +4,7 @@ module Region = Simple_utils.Region
module IO = module IO =
struct struct
let ext = ".mligo" let options = EvalOpt.(read ~lang:`CameLIGO ~ext:".mligo")
let options = EvalOpt.read "CameLIGO" ext
end end
module M = LexerUnit.Make (IO) (Lexer.Make (LexToken)) module M = LexerUnit.Make (IO) (Lexer.Make (LexToken))

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@ -2,4 +2,4 @@ SHELL := dash
BFLAGS := -strict-sequence -w +A-48-4 -g BFLAGS := -strict-sequence -w +A-48-4 -g
clean:: clean::
> rm -f Parser.msg Parser.msg.map Parser.msg.states Version.ml > \rm -f Parser.msg Parser.msg.map Parser.msg.states Version.ml

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@ -3,7 +3,7 @@
[@@@warning "-42"] [@@@warning "-42"]
open Region open Simple_utils.Region
open AST open AST
(* END HEADER *) (* END HEADER *)

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@ -2,6 +2,7 @@
[@@@coverage exclude_file] [@@@coverage exclude_file]
open AST open AST
module Region = Simple_utils.Region
open! Region open! Region
let sprintf = Printf.sprintf let sprintf = Printf.sprintf

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@ -1,9 +1,47 @@
(** Driver for the CameLIGO parser *) (* Driver for the CameLIGO parser *)
module Region = Simple_utils.Region
module SSet = Set.Make (String)
module IO = module IO =
struct struct
let ext = ".mligo" let options = EvalOpt.(read ~lang:`CameLIGO ~ext:".mligo")
let options = EvalOpt.read "CameLIGO" ext end
module SubIO =
struct
type options = <
libs : string list;
verbose : SSet.t;
offsets : bool;
lang : EvalOpt.language;
ext : string;
mode : [`Byte | `Point];
cmd : EvalOpt.command;
mono : bool
>
let options : options =
object
method libs = IO.options#libs
method verbose = IO.options#verbose
method offsets = IO.options#offsets
method lang = IO.options#lang
method ext = IO.options#ext
method mode = IO.options#mode
method cmd = IO.options#cmd
method mono = IO.options#mono
end
let make =
EvalOpt.make ~libs:options#libs
~verbose:options#verbose
~offsets:options#offsets
~lang:options#lang
~ext:options#ext
~mode:options#mode
~cmd:options#cmd
~mono:options#mono
end end
module Parser = module Parser =
@ -23,118 +61,16 @@ module ParserLog =
module Lexer = Lexer.Make (LexToken) module Lexer = Lexer.Make (LexToken)
module Unit = module Unit =
ParserUnit.Make (Lexer)(AST)(Parser)(ParErr)(ParserLog)(IO) ParserUnit.Make (Lexer)(AST)(Parser)(ParErr)(ParserLog)(SubIO)
(* Main *) (* Main *)
let issue_error error : ('a, string Region.reg) Stdlib.result = let wrap = function
Stdlib.Error (Unit.format_error ~offsets:IO.options#offsets Stdlib.Ok _ -> flush_all ()
IO.options#mode error) | Error msg ->
(flush_all (); Printf.eprintf "\027[31m%s\027[0m%!" msg.Region.value)
let parse parser : ('a, string Region.reg) Stdlib.result =
try parser () with
(* Scoping errors *)
| Scoping.Error (Scoping.Reserved_name name) ->
let token =
Lexer.Token.mk_ident name.Region.value name.Region.region in
(match token with
(* Cannot fail because [name] is a not a
reserved name for the lexer. *)
Stdlib.Error _ -> assert false
| Ok invalid ->
issue_error
("Reserved name.\nHint: Change the name.\n", None, invalid))
| Scoping.Error (Scoping.Duplicate_variant name) ->
let token =
Lexer.Token.mk_constr name.Region.value name.Region.region in
let point = "Duplicate constructor in this sum type declaration.\n\
Hint: Change the constructor.\n",
None, token
in issue_error point
| Scoping.Error (Scoping.Non_linear_pattern var) ->
let token =
Lexer.Token.mk_ident var.Region.value var.Region.region in
(match token with
(* Cannot fail because [var] is a not a
reserved name for the lexer. *)
Stdlib.Error _ -> assert false
| Ok invalid ->
let point = "Repeated variable in this pattern.\n\
Hint: Change the name.\n",
None, invalid
in issue_error point)
| Scoping.Error (Scoping.Duplicate_field name) ->
let token =
Lexer.Token.mk_ident name.Region.value name.Region.region in
(match token with
(* Cannot fail because [name] is a not a
reserved name for the lexer. *)
Stdlib.Error _ -> assert false
| Ok invalid ->
let point = "Duplicate field name in this record declaration.\n\
Hint: Change the name.\n",
None, invalid
in issue_error point)
(* Preprocessing the input source with CPP *)
module SSet = Utils.String.Set
let sprintf = Printf.sprintf
(* Path for CPP inclusions (#include) *)
let lib_path =
match IO.options#libs with
[] -> ""
| libs -> let mk_I dir path = sprintf " -I %s%s" dir path
in List.fold_right mk_I libs ""
let prefix =
match IO.options#input with
None | Some "-" -> "temp"
| Some file -> Filename.(file |> basename |> remove_extension)
let suffix = ".pp" ^ IO.ext
let pp_input =
if SSet.mem "cpp" IO.options#verbose
then prefix ^ suffix
else let pp_input, pp_out =
Filename.open_temp_file prefix suffix
in close_out pp_out; pp_input
let cpp_cmd =
match IO.options#input with
None | Some "-" ->
sprintf "cpp -traditional-cpp%s - > %s"
lib_path pp_input
| Some file ->
sprintf "cpp -traditional-cpp%s %s > %s"
lib_path file pp_input
let () = let () =
if Sys.command cpp_cmd <> 0 then match IO.options#input with
Printf.eprintf "External error: \"%s\" failed." cpp_cmd None -> Unit.contract_in_stdin () |> wrap
| Some file_path -> Unit.contract_in_file file_path |> wrap
(* Instantiating the lexer and calling the parser *)
let lexer_inst =
match Lexer.open_token_stream (Lexer.File pp_input) with
Ok instance ->
if IO.options#expr
then
match parse (fun () -> Unit.apply instance Unit.parse_expr) with
Stdlib.Ok _ -> ()
| Error Region.{value; _} ->
Printf.eprintf "\027[31m%s\027[0m%!" value
else
(match parse (fun () -> Unit.apply instance Unit.parse_contract) with
Stdlib.Ok _ -> ()
| Error Region.{value; _} ->
Printf.eprintf "\027[31m%s\027[0m%!" value)
| Stdlib.Error (Lexer.File_opening msg) ->
Printf.eprintf "\027[31m%s\027[0m%!" msg

View File

@ -1,5 +1,6 @@
[@@@warning "-42"] [@@@warning "-42"]
module Region = Simple_utils.Region
type t = type t =
Reserved_name of AST.variable Reserved_name of AST.variable

View File

@ -1,5 +1,7 @@
(* This module exports checks on scoping, called from the parser. *) (* This module exports checks on scoping, called from the parser. *)
module Region = Simple_utils.Region
type t = type t =
Reserved_name of AST.variable Reserved_name of AST.variable
| Duplicate_variant of AST.variable | Duplicate_variant of AST.variable

View File

@ -1,2 +0,0 @@
module Region = Region
module Pos = Pos

View File

@ -4,26 +4,46 @@ module Lexer = Lexer.Make(LexToken)
module Scoping = Parser_pascaligo.Scoping module Scoping = Parser_pascaligo.Scoping
module Region = Simple_utils.Region module Region = Simple_utils.Region
module ParErr = Parser_pascaligo.ParErr module ParErr = Parser_pascaligo.ParErr
module SSet = Utils.String.Set module SSet = Set.Make (String)
(* Mock IOs TODO: Fill them with CLI options *) (* Mock IOs TODO: Fill them with CLI options *)
module type IO = type language = [`PascaLIGO | `CameLIGO | `ReasonLIGO]
sig
val ext : string module SubIO =
val options : EvalOpt.options struct
type options = <
libs : string list;
verbose : SSet.t;
offsets : bool;
lang : language;
ext : string; (* ".ligo" *)
mode : [`Byte | `Point];
cmd : EvalOpt.command;
mono : bool
>
let options : options =
object
method libs = []
method verbose = SSet.empty
method offsets = true
method lang = `PascaLIGO
method ext = ".ligo"
method mode = `Point
method cmd = EvalOpt.Quiet
method mono = false
end end
module PreIO = let make =
struct EvalOpt.make ~libs:options#libs
let ext = ".ligo" ~verbose:options#verbose
let pre_options = ~offsets:options#offsets
EvalOpt.make ~libs:[] ~lang:options#lang
~verbose:SSet.empty ~ext:options#ext
~offsets:true ~mode:options#mode
~mode:`Point ~cmd:options#cmd
~cmd:EvalOpt.Quiet ~mono:options#mono
~mono:false
end end
module Parser = module Parser =
@ -40,34 +60,34 @@ module ParserLog =
include Parser_pascaligo.ParserLog include Parser_pascaligo.ParserLog
end end
module PreUnit = module Unit =
ParserUnit.Make (Lexer)(AST)(Parser)(ParErr)(ParserLog) ParserUnit.Make (Lexer)(AST)(Parser)(ParErr)(ParserLog)(SubIO)
module Errors = module Errors =
struct struct
(* let data =
[("location",
fun () -> Format.asprintf "%a" Location.pp_lift @@ loc)] *)
let generic message = let generic message =
let title () = "" let title () = ""
and message () = message.Region.value and message () = message.Region.value
in Trace.error ~data:[] title message in Trace.error ~data:[] title message
end end
let parse (module IO : IO) parser = let apply parser =
let module Unit = PreUnit (IO) in
let local_fail error = let local_fail error =
Trace.fail Trace.fail
@@ Errors.generic @@ Errors.generic
@@ Unit.format_error ~offsets:IO.options#offsets @@ Unit.format_error ~offsets:SubIO.options#offsets
IO.options#mode error in SubIO.options#mode error in
match parser () with match parser () with
Stdlib.Ok semantic_value -> Trace.ok semantic_value Stdlib.Ok semantic_value -> Trace.ok semantic_value
(* Lexing and parsing errors *) (* Lexing and parsing errors *)
| Stdlib.Error error -> Trace.fail @@ Errors.generic error | Stdlib.Error error -> Trace.fail @@ Errors.generic error
(* System errors *)
| exception Sys_error msg ->
Trace.fail @@ Errors.generic (Region.wrap_ghost msg)
(* Scoping errors *) (* Scoping errors *)
| exception Scoping.Error (Scoping.Reserved_name name) -> | exception Scoping.Error (Scoping.Reserved_name name) ->
@ -121,71 +141,18 @@ let parse (module IO : IO) parser =
Hint: Change the name.\n", Hint: Change the name.\n",
None, invalid)) None, invalid))
let parse_file source = (* Parsing a contract in a file *)
let module IO =
struct
let ext = PreIO.ext
let options =
PreIO.pre_options ~input:(Some source) ~expr:false
end in
let module Unit = PreUnit (IO) in
let lib_path =
match IO.options#libs with
[] -> ""
| libs -> let mk_I dir path = Printf.sprintf " -I %s%s" dir path
in List.fold_right mk_I libs "" in
let prefix =
match IO.options#input with
None | Some "-" -> "temp"
| Some file -> Filename.(remove_extension @@ basename file) in
let suffix = ".pp" ^ IO.ext in
let pp_input =
if SSet.mem "cpp" IO.options#verbose
then prefix ^ suffix
else let pp_input, pp_out =
Filename.open_temp_file prefix suffix
in close_out pp_out; pp_input in
let cpp_cmd =
match IO.options#input with
None | Some "-" ->
Printf.sprintf "cpp -traditional-cpp%s - > %s"
lib_path pp_input
| Some file ->
Printf.sprintf "cpp -traditional-cpp%s %s > %s"
lib_path file pp_input in
let open Trace in
let%bind () = sys_command cpp_cmd in
match Lexer.(open_token_stream @@ File pp_input) with
Ok instance ->
let thunk () = Unit.apply instance Unit.parse_contract
in parse (module IO) thunk
| Stdlib.Error (Lexer.File_opening msg) ->
Trace.fail @@ Errors.generic @@ Region.wrap_ghost msg
let parse_string (s: string) = let parse_file source = apply (fun () -> Unit.contract_in_file source)
let module IO =
struct
let ext = PreIO.ext
let options = PreIO.pre_options ~input:None ~expr:false
end in
let module Unit = PreUnit (IO) in
match Lexer.(open_token_stream @@ String s) with
Ok instance ->
let thunk () = Unit.apply instance Unit.parse_contract
in parse (module IO) thunk
| Stdlib.Error (Lexer.File_opening msg) ->
Trace.fail @@ Errors.generic @@ Region.wrap_ghost msg
let parse_expression (s: string) = (* Parsing a contract in a string *)
let module IO =
struct let parse_string source = apply (fun () -> Unit.contract_in_string source)
let ext = PreIO.ext
let options = PreIO.pre_options ~input:None ~expr:true (* Parsing an expression in a string *)
end in
let module Unit = PreUnit (IO) in let parse_expression source = apply (fun () -> Unit.expr_in_string source)
match Lexer.(open_token_stream @@ String s) with
Ok instance -> (* Preprocessing a contract in a file *)
let thunk () = Unit.apply instance Unit.parse_expr
in parse (module IO) thunk let preprocess source = apply (fun () -> Unit.preprocess source)
| Stdlib.Error (Lexer.File_opening msg) ->
Trace.fail @@ Errors.generic @@ Region.wrap_ghost msg

View File

@ -16,3 +16,6 @@ val parse_string : string -> AST.t Trace.result
scenarios where you would want to parse a PascaLIGO expression scenarios where you would want to parse a PascaLIGO expression
outside of a contract. *) outside of a contract. *)
val parse_expression : string -> AST.expr Trace.result val parse_expression : string -> AST.expr Trace.result
(** Preprocess a given PascaLIGO file and preprocess it. *)
val preprocess : string -> Buffer.t Trace.result

View File

@ -1,8 +1,5 @@
$HOME/git/OCaml-build/Makefile $HOME/git/OCaml-build/Makefile
$HOME/git/ligo/vendors/ligo-utils/simple-utils/pos.mli
$HOME/git/ligo/vendors/ligo-utils/simple-utils/pos.ml
$HOME/git/ligo/vendors/ligo-utils/simple-utils/region.mli
$HOME/git/ligo/vendors/ligo-utils/simple-utils/region.ml
../shared/Lexer.mli ../shared/Lexer.mli
../shared/Lexer.mll ../shared/Lexer.mll
../shared/EvalOpt.ml ../shared/EvalOpt.ml
@ -21,7 +18,5 @@ $HOME/git/ligo/vendors/ligo-utils/simple-utils/region.ml
../shared/LexerUnit.ml ../shared/LexerUnit.ml
../shared/ParserUnit.mli ../shared/ParserUnit.mli
../shared/ParserUnit.ml ../shared/ParserUnit.ml
../shared/Memo.mli
../shared/Memo.ml
Stubs/Simple_utils.ml
$HOME/git/ligo/_build/default/src/passes/1-parser/pascaligo/ParErr.ml $HOME/git/ligo/_build/default/src/passes/1-parser/pascaligo/ParErr.ml

View File

@ -19,6 +19,8 @@ open Utils
denoting the _region_ of the occurrence of the keyword "and". denoting the _region_ of the occurrence of the keyword "and".
*) *)
module Region = Simple_utils.Region
type 'a reg = 'a Region.reg type 'a reg = 'a Region.reg
(* Keywords of LIGO *) (* Keywords of LIGO *)

View File

@ -11,8 +11,8 @@ let sprintf = Printf.sprintf
module Region = Simple_utils.Region module Region = Simple_utils.Region
module Pos = Simple_utils.Pos module Pos = Simple_utils.Pos
module SMap = Utils.String.Map module SMap = Map.Make (String)
module SSet = Utils.String.Set module SSet = Set.Make (String)
(* Hack to roll back one lexeme in the current semantic action *) (* Hack to roll back one lexeme in the current semantic action *)
(* (*

View File

@ -4,8 +4,7 @@ module Region = Simple_utils.Region
module IO = module IO =
struct struct
let ext = ".ligo" let options = EvalOpt.(read ~lang:`PascaLIGO ~ext:".ligo")
let options = EvalOpt.read "PascaLIGO" ext
end end
module M = LexerUnit.Make (IO) (Lexer.Make (LexToken)) module M = LexerUnit.Make (IO) (Lexer.Make (LexToken))
@ -13,4 +12,4 @@ module M = LexerUnit.Make (IO) (Lexer.Make (LexToken))
let () = let () =
match M.trace () with match M.trace () with
Stdlib.Ok () -> () Stdlib.Ok () -> ()
| Error Region.{value; _} -> Utils.highlight value | Error Region.{value; _} -> Printf.eprintf "\027[31m%s\027[0m%!" value

View File

@ -2,4 +2,4 @@ SHELL := dash
BFLAGS := -strict-sequence -w +A-48-4 -g BFLAGS := -strict-sequence -w +A-48-4 -g
clean:: clean::
> rm -f Parser.msg Parser.msg.map Parser.msg.states Version.ml > \rm -f Parser.msg Parser.msg.map Parser.msg.states Version.ml

View File

@ -1,39 +0,0 @@
module ParserLog = Parser_pascaligo.ParserLog
module ParErr = Parser_pascaligo.ParErr
module SSet = Utils.String.Set
(* Mock options. TODO: Plug in cmdliner. *)
let pre_options =
EvalOpt.make
~libs:[]
~verbose:SSet.empty
~offsets:true
~mode:`Point
~cmd:EvalOpt.Quiet
~mono:true (* Monolithic API of Menhir for now *)
(* ~input:None *)
(* ~expr:true *)
module Parser =
struct
type ast = AST.t
type expr = AST.expr
include Parser_pascaligo.Parser
end
module ParserLog =
struct
type ast = AST.t
type expr = AST.expr
include Parser_pascaligo.ParserLog
end
module PreUnit = ParserUnit.Make (Lexer)(AST)(Parser)(ParErr)(ParserLog)
module Front = ParserAPI.Make (Lexer)(Parser)(ParErr)
let issue_error point =
let error = Front.format_error ~offsets:true (* TODO: CLI *)
`Point (* TODO: CLI *) point
in Stdlib.Error error

View File

@ -3,7 +3,7 @@
[@@@warning "-42"] [@@@warning "-42"]
open Region open Simple_utils.Region
open AST open AST
(* END HEADER *) (* END HEADER *)

View File

@ -2,6 +2,8 @@
[@@@coverage exclude_file] [@@@coverage exclude_file]
open AST open AST
module Region = Simple_utils.Region
open! Region open! Region
let sprintf = Printf.sprintf let sprintf = Printf.sprintf

View File

@ -1,9 +1,47 @@
(* Driver for the PascaLIGO parser *) (* Driver for the PascaLIGO parser *)
module Region = Simple_utils.Region
module SSet = Set.Make (String)
module IO = module IO =
struct struct
let ext = ".ligo" let options = EvalOpt.(read ~lang:`PascaLIGO ~ext:".ligo")
let options = EvalOpt.read "PascaLIGO" ext end
module SubIO =
struct
type options = <
libs : string list;
verbose : SSet.t;
offsets : bool;
lang : EvalOpt.language;
ext : string;
mode : [`Byte | `Point];
cmd : EvalOpt.command;
mono : bool
>
let options : options =
object
method libs = IO.options#libs
method verbose = IO.options#verbose
method offsets = IO.options#offsets
method lang = IO.options#lang
method ext = IO.options#ext
method mode = IO.options#mode
method cmd = IO.options#cmd
method mono = IO.options#mono
end
let make =
EvalOpt.make ~libs:options#libs
~verbose:options#verbose
~offsets:options#offsets
~lang:options#lang
~ext:options#ext
~mode:options#mode
~cmd:options#cmd
~mono:options#mono
end end
module Parser = module Parser =
@ -23,130 +61,16 @@ module ParserLog =
module Lexer = Lexer.Make (LexToken) module Lexer = Lexer.Make (LexToken)
module Unit = module Unit =
ParserUnit.Make (Lexer)(AST)(Parser)(ParErr)(ParserLog)(IO) ParserUnit.Make (Lexer)(AST)(Parser)(ParErr)(ParserLog)(SubIO)
(* Main *) (* Main *)
let issue_error error : ('a, string Region.reg) Stdlib.result = let wrap = function
Stdlib.Error (Unit.format_error ~offsets:IO.options#offsets Stdlib.Ok _ -> flush_all ()
IO.options#mode error) | Error msg ->
(flush_all (); Printf.eprintf "\027[31m%s\027[0m%!" msg.Region.value)
let parse parser : ('a, string Region.reg) Stdlib.result =
try parser () with
(* Scoping errors *)
| Scoping.Error (Scoping.Duplicate_parameter name) ->
let token =
Lexer.Token.mk_ident name.Region.value name.Region.region in
(match token with
(* Cannot fail because [name] is a not a
reserved name for the lexer. *)
Stdlib.Error _ -> assert false
| Ok invalid ->
issue_error ("Duplicate parameter.\nHint: Change the name.\n",
None, invalid))
| Scoping.Error (Scoping.Reserved_name name) ->
let token =
Lexer.Token.mk_ident name.Region.value name.Region.region in
(match token with
(* Cannot fail because [name] is a not a
reserved name for the lexer. *)
Stdlib.Error _ -> assert false
| Ok invalid ->
issue_error
("Reserved name.\nHint: Change the name.\n", None, invalid))
| Scoping.Error (Scoping.Duplicate_variant name) ->
let token =
Lexer.Token.mk_constr name.Region.value name.Region.region in
let point = "Duplicate constructor in this sum type declaration.\n\
Hint: Change the constructor.\n",
None, token
in issue_error point
| Scoping.Error (Scoping.Non_linear_pattern var) ->
let token =
Lexer.Token.mk_ident var.Region.value var.Region.region in
(match token with
(* Cannot fail because [var] is a not a
reserved name for the lexer. *)
Stdlib.Error _ -> assert false
| Ok invalid ->
let point = "Repeated variable in this pattern.\n\
Hint: Change the name.\n",
None, invalid
in issue_error point)
| Scoping.Error (Scoping.Duplicate_field name) ->
let token =
Lexer.Token.mk_ident name.Region.value name.Region.region in
(match token with
(* Cannot fail because [name] is a not a
reserved name for the lexer. *)
Stdlib.Error _ -> assert false
| Ok invalid ->
let point =
"Duplicate field name in this record declaration.\n\
Hint: Change the name.\n",
None, invalid
in issue_error point)
(* Preprocessing the input source with CPP *)
module SSet = Utils.String.Set
let sprintf = Printf.sprintf
(* Path for CPP inclusions (#include) *)
let lib_path =
match IO.options#libs with
[] -> ""
| libs -> let mk_I dir path = sprintf " -I %s%s" dir path
in List.fold_right mk_I libs ""
let prefix =
match IO.options#input with
None | Some "-" -> "temp"
| Some file -> Filename.(file |> basename |> remove_extension)
let suffix = ".pp" ^ IO.ext
let pp_input =
if SSet.mem "cpp" IO.options#verbose
then prefix ^ suffix
else let pp_input, pp_out =
Filename.open_temp_file prefix suffix
in close_out pp_out; pp_input
let cpp_cmd =
match IO.options#input with
None | Some "-" ->
sprintf "cpp -traditional-cpp%s - > %s"
lib_path pp_input
| Some file ->
sprintf "cpp -traditional-cpp%s %s > %s"
lib_path file pp_input
let () = let () =
if Sys.command cpp_cmd <> 0 then match IO.options#input with
Printf.eprintf "External error: \"%s\" failed." cpp_cmd None -> Unit.contract_in_stdin () |> wrap
| Some file_path -> Unit.contract_in_file file_path |> wrap
(* Instantiating the lexer and calling the parser *)
let lexer_inst =
match Lexer.open_token_stream (Lexer.File pp_input) with
Ok instance ->
if IO.options#expr
then
match parse (fun () -> Unit.apply instance Unit.parse_expr) with
Stdlib.Ok _ -> ()
| Error Region.{value; _} ->
Printf.eprintf "\027[31m%s\027[0m%!" value
else
(match parse (fun () -> Unit.apply instance Unit.parse_contract) with
Stdlib.Ok _ -> ()
| Error Region.{value; _} ->
Printf.eprintf "\027[31m%s\027[0m%!" value)
| Stdlib.Error (Lexer.File_opening msg) ->
Printf.eprintf "\027[31m%s\027[0m%!" msg

View File

@ -1,5 +1,6 @@
[@@@warning "-42"] [@@@warning "-42"]
module Region = Simple_utils.Region
type t = type t =
Reserved_name of AST.variable Reserved_name of AST.variable

View File

@ -1,5 +1,7 @@
(* This module exports checks on scoping, called from the parser. *) (* This module exports checks on scoping, called from the parser. *)
module Region = Simple_utils.Region
type t = type t =
Reserved_name of AST.variable Reserved_name of AST.variable
| Duplicate_parameter of AST.variable | Duplicate_parameter of AST.variable

View File

@ -1,2 +0,0 @@
module Region = Region
module Pos = Pos

View File

@ -20,6 +20,7 @@
menhirLib menhirLib
parser_shared parser_shared
hex hex
Preprocessor
simple-utils) simple-utils)
(preprocess (preprocess
(pps bisect_ppx --conditional)) (pps bisect_ppx --conditional))
@ -170,4 +171,3 @@
) )
)) ))
) )

View File

@ -7,26 +7,46 @@ module Scoping = Parser_cameligo.Scoping
module Region = Simple_utils.Region module Region = Simple_utils.Region
module ParErr = Parser_reasonligo.ParErr module ParErr = Parser_reasonligo.ParErr
module SyntaxError = Parser_reasonligo.SyntaxError module SyntaxError = Parser_reasonligo.SyntaxError
module SSet = Utils.String.Set module SSet = Set.Make (String)
(* Mock IOs TODO: Fill them with CLI options *) (* Mock IOs TODO: Fill them with CLI options *)
module type IO = type language = [`PascaLIGO | `CameLIGO | `ReasonLIGO]
sig
val ext : string module SubIO =
val options : EvalOpt.options struct
type options = <
libs : string list;
verbose : SSet.t;
offsets : bool;
lang : language;
ext : string; (* ".religo" *)
mode : [`Byte | `Point];
cmd : EvalOpt.command;
mono : bool
>
let options : options =
object
method libs = []
method verbose = SSet.empty
method offsets = true
method lang = `ReasonLIGO
method ext = ".religo"
method mode = `Point
method cmd = EvalOpt.Quiet
method mono = false
end end
module PreIO = let make =
struct EvalOpt.make ~libs:options#libs
let ext = ".ligo" ~verbose:options#verbose
let pre_options = ~offsets:options#offsets
EvalOpt.make ~libs:[] ~lang:options#lang
~verbose:SSet.empty ~ext:options#ext
~offsets:true ~mode:options#mode
~mode:`Point ~cmd:options#cmd
~cmd:EvalOpt.Quiet ~mono:options#mono
~mono:false
end end
module Parser = module Parser =
@ -43,8 +63,8 @@ module ParserLog =
include Parser_cameligo.ParserLog include Parser_cameligo.ParserLog
end end
module PreUnit = module Unit =
ParserUnit.Make (Lexer)(AST)(Parser)(ParErr)(ParserLog) ParserUnit.Make (Lexer)(AST)(Parser)(ParErr)(ParserLog)(SubIO)
module Errors = module Errors =
struct struct
@ -55,14 +75,14 @@ module Errors =
let wrong_function_arguments (expr: AST.expr) = let wrong_function_arguments (expr: AST.expr) =
let title () = "" in let title () = "" in
let message () = "It looks like you are defining a function, \ let message () =
"It looks like you are defining a function, \
however we do not\n\ however we do not\n\
understand the parameters declaration.\n\ understand the parameters declaration.\n\
Examples of valid functions:\n\ Examples of valid functions:\n\
let x = (a: string, b: int) : int => 3;\n\ let x = (a: string, b: int) : int => 3;\n\
let tuple = ((a, b): (int, int)) => a + b; \n\ let tuple = ((a, b): (int, int)) => a + b; \n\
let x = (a: string) : string => \"Hello, \" ++ a;\n" let x = (a: string) : string => \"Hello, \" ++ a;\n" in
in
let expression_loc = AST.expr_to_region expr in let expression_loc = AST.expr_to_region expr in
let data = [ let data = [
("location", ("location",
@ -82,13 +102,12 @@ module Errors =
end end
let parse (module IO : IO) parser = let apply parser =
let module Unit = PreUnit (IO) in
let local_fail error = let local_fail error =
Trace.fail Trace.fail
@@ Errors.generic @@ Errors.generic
@@ Unit.format_error ~offsets:IO.options#offsets @@ Unit.format_error ~offsets:SubIO.options#offsets
IO.options#mode error in SubIO.options#mode error in
match parser () with match parser () with
Stdlib.Ok semantic_value -> Trace.ok semantic_value Stdlib.Ok semantic_value -> Trace.ok semantic_value
@ -142,71 +161,18 @@ let parse (module IO : IO) parser =
| exception SyntaxError.Error (SyntaxError.InvalidWild expr) -> | exception SyntaxError.Error (SyntaxError.InvalidWild expr) ->
Trace.fail @@ Errors.invalid_wild expr Trace.fail @@ Errors.invalid_wild expr
let parse_file (source: string) = (* Parsing a contract in a file *)
let module IO =
struct
let ext = PreIO.ext
let options =
PreIO.pre_options ~input:(Some source) ~expr:false
end in
let lib_path =
match IO.options#libs with
[] -> ""
| libs -> let mk_I dir path = Printf.sprintf " -I %s%s" dir path
in List.fold_right mk_I libs "" in
let prefix =
match IO.options#input with
None | Some "-" -> "temp"
| Some file -> Filename.(remove_extension @@ basename file) in
let suffix = ".pp" ^ IO.ext in
let pp_input =
if SSet.mem "cpp" IO.options#verbose
then prefix ^ suffix
else let pp_input, pp_out =
Filename.open_temp_file prefix suffix
in close_out pp_out; pp_input in
let cpp_cmd =
match IO.options#input with
None | Some "-" ->
Printf.sprintf "cpp -traditional-cpp%s - > %s"
lib_path pp_input
| Some file ->
Printf.sprintf "cpp -traditional-cpp%s %s > %s"
lib_path file pp_input in
let open Trace in
let%bind () = sys_command cpp_cmd in
let module Unit = PreUnit (IO) in
match Lexer.(open_token_stream @@ File pp_input) with
Ok instance ->
let thunk () = Unit.apply instance Unit.parse_contract
in parse (module IO) thunk
| Stdlib.Error (Lexer.File_opening msg) ->
Trace.fail @@ Errors.generic @@ Region.wrap_ghost msg
let parse_string (s: string) = let parse_file source = apply (fun () -> Unit.contract_in_file source)
let module IO =
struct
let ext = PreIO.ext
let options = PreIO.pre_options ~input:None ~expr:false
end in
let module Unit = PreUnit (IO) in
match Lexer.(open_token_stream @@ String s) with
Ok instance ->
let thunk () = Unit.apply instance Unit.parse_contract
in parse (module IO) thunk
| Stdlib.Error (Lexer.File_opening msg) ->
Trace.fail @@ Errors.generic @@ Region.wrap_ghost msg
let parse_expression (s: string) = (* Parsing a contract in a string *)
let module IO =
struct let parse_string source = apply (fun () -> Unit.contract_in_string source)
let ext = PreIO.ext
let options = PreIO.pre_options ~input:None ~expr:true (* Parsing an expression in a string *)
end in
let module Unit = PreUnit (IO) in let parse_expression source = apply (fun () -> Unit.expr_in_string source)
match Lexer.(open_token_stream @@ String s) with
Ok instance -> (* Preprocessing a contract in a file *)
let thunk () = Unit.apply instance Unit.parse_expr
in parse (module IO) thunk let preprocess source = apply (fun () -> Unit.preprocess source)
| Stdlib.Error (Lexer.File_opening msg) ->
Trace.fail @@ Errors.generic @@ Region.wrap_ghost msg

View File

@ -0,0 +1,21 @@
(** This file provides an interface to the ReasonLIGO parser. *)
module AST = Parser_cameligo.AST
(** Open a ReasonLIGO filename given by string and convert into an
abstract syntax tree. *)
val parse_file : string -> AST.t Trace.result
(** Convert a given string into a ReasonLIGO abstract syntax tree *)
val parse_string : string -> AST.t Trace.result
(** Parse a given string as a ReasonLIGO expression and return an
expression AST.
This is intended to be used for interactive interpreters, or other
scenarios where you would want to parse a ReasonLIGO expression
outside of a contract. *)
val parse_expression : string -> AST.expr Trace.result
(** Preprocess a given ReasonLIGO file and preprocess it. *)
val preprocess : string -> Buffer.t Trace.result

View File

@ -1,8 +1,5 @@
$HOME/git/OCaml-build/Makefile $HOME/git/OCaml-build/Makefile
$HOME/git/ligo/vendors/ligo-utils/simple-utils/pos.mli
$HOME/git/ligo/vendors/ligo-utils/simple-utils/pos.ml
$HOME/git/ligo/vendors/ligo-utils/simple-utils/region.mli
$HOME/git/ligo/vendors/ligo-utils/simple-utils/region.ml
../shared/Lexer.mli ../shared/Lexer.mli
../shared/Lexer.mll ../shared/Lexer.mll
../shared/EvalOpt.ml ../shared/EvalOpt.ml
@ -17,13 +14,17 @@ $HOME/git/ligo/vendors/ligo-utils/simple-utils/region.ml
../shared/Utils.ml ../shared/Utils.ml
../shared/ParserAPI.mli ../shared/ParserAPI.mli
../shared/ParserAPI.ml ../shared/ParserAPI.ml
../shared/LexerUnit.mli
../shared/LexerUnit.ml ../shared/LexerUnit.ml
../shared/ParserUnit.mli
../shared/ParserUnit.ml ../shared/ParserUnit.ml
Stubs/Simple_utils.ml
Stubs/Parser_cameligo.ml Stubs/Parser_cameligo.ml
../cameligo/AST.ml ../cameligo/AST.ml
../cameligo/ParserLog.mli ../cameligo/ParserLog.mli
../cameligo/ParserLog.ml ../cameligo/ParserLog.ml
../cameligo/Scoping.mli ../cameligo/Scoping.mli
../cameligo/Scoping.ml ../cameligo/Scoping.ml
$HOME/git/ligo/_build/default/src/passes/1-parser/reasonligo/ParErr.ml $HOME/git/ligo/_build/default/src/passes/1-parser/reasonligo/ParErr.ml

View File

@ -4,8 +4,7 @@ module Region = Simple_utils.Region
module IO = module IO =
struct struct
let ext = ".religo" let options = EvalOpt.(read ~lang:`ReasonLIGO ~ext:".religo")
let options = EvalOpt.read "ReasonLIGO" ext
end end
module M = LexerUnit.Make (IO) (Lexer.Make (LexToken)) module M = LexerUnit.Make (IO) (Lexer.Make (LexToken))

View File

@ -2,4 +2,4 @@ SHELL := dash
BFLAGS := -strict-sequence -w +A-48-4 -g BFLAGS := -strict-sequence -w +A-48-4 -g
clean:: clean::
> rm -f Parser.msg Parser.msg.map Parser.msg.states Version.ml > \rm -f Parser.msg Parser.msg.map Parser.msg.states Version.ml

View File

@ -3,6 +3,7 @@
[@@@warning "-42"] [@@@warning "-42"]
module Region = Simple_utils.Region
open Region open Region
module AST = Parser_cameligo.AST module AST = Parser_cameligo.AST
open! AST open! AST

View File

@ -1,9 +1,47 @@
(** Driver for the ReasonLIGO parser *) (* Driver for the ReasonLIGO parser *)
module Region = Simple_utils.Region
module SSet = Set.Make (String)
module IO = module IO =
struct struct
let ext = ".religo" let options = EvalOpt.(read ~lang:`ReasonLIGO ~ext:".religo")
let options = EvalOpt.read "ReasonLIGO" ext end
module SubIO =
struct
type options = <
libs : string list;
verbose : SSet.t;
offsets : bool;
lang : EvalOpt.language;
ext : string;
mode : [`Byte | `Point];
cmd : EvalOpt.command;
mono : bool
>
let options : options =
object
method libs = IO.options#libs
method verbose = IO.options#verbose
method offsets = IO.options#offsets
method lang = IO.options#lang
method ext = IO.options#ext
method mode = IO.options#mode
method cmd = IO.options#cmd
method mono = IO.options#mono
end
let make =
EvalOpt.make ~libs:options#libs
~verbose:options#verbose
~offsets:options#offsets
~lang:options#lang
~ext:options#ext
~mode:options#mode
~cmd:options#cmd
~mono:options#mono
end end
module Parser = module Parser =
@ -23,138 +61,16 @@ module ParserLog =
module Lexer = Lexer.Make (LexToken) module Lexer = Lexer.Make (LexToken)
module Unit = module Unit =
ParserUnit.Make (Lexer)(AST)(Parser)(ParErr)(ParserLog)(IO) ParserUnit.Make (Lexer)(AST)(Parser)(ParErr)(ParserLog)(SubIO)
(* Main *) (* Main *)
let issue_error error : ('a, string Region.reg) Stdlib.result = let wrap = function
Stdlib.Error (Unit.format_error ~offsets:IO.options#offsets Stdlib.Ok _ -> flush_all ()
IO.options#mode error) | Error msg ->
(flush_all (); Printf.eprintf "\027[31m%s\027[0m%!" msg.Region.value)
let parse parser : ('a, string Region.reg) Stdlib.result =
try parser () with
(* Ad hoc errors from the parser *)
SyntaxError.Error (SyntaxError.WrongFunctionArguments expr) ->
let msg = "It looks like you are defining a function, \
however we do not\n\
understand the parameters declaration.\n\
Examples of valid functions:\n\
let x = (a: string, b: int) : int => 3;\n\
let x = (a: string) : string => \"Hello, \" ++ a;\n"
and region = AST.expr_to_region expr in
let error = Unit.short_error ~offsets:IO.options#offsets
IO.options#mode msg region
in Stdlib.Error Region.{value=error; region}
(* Scoping errors *)
| SyntaxError.Error (SyntaxError.InvalidWild expr) ->
let msg = "It looks like you are using a wild pattern where it cannot be used.\n"
and region = AST.expr_to_region expr in
let error = Unit.short_error ~offsets:IO.options#offsets
IO.options#mode msg region
in Stdlib.Error Region.{value=error; region}
| Scoping.Error (Scoping.Reserved_name name) ->
let token =
Lexer.Token.mk_ident name.Region.value name.Region.region in
(match token with
(* Cannot fail because [name] is a not a
reserved name for the lexer. *)
Stdlib.Error _ -> assert false
| Ok invalid ->
issue_error
("Reserved name.\nHint: Change the name.\n", None, invalid))
| Scoping.Error (Scoping.Duplicate_variant name) ->
let token =
Lexer.Token.mk_constr name.Region.value name.Region.region in
let point = "Duplicate constructor in this sum type declaration.\n\
Hint: Change the constructor.\n",
None, token
in issue_error point
| Scoping.Error (Scoping.Non_linear_pattern var) ->
let token =
Lexer.Token.mk_ident var.Region.value var.Region.region in
(match token with
(* Cannot fail because [var] is a not a
reserved name for the lexer. *)
Stdlib.Error _ -> assert false
| Ok invalid ->
let point = "Repeated variable in this pattern.\n\
Hint: Change the name.\n",
None, invalid
in issue_error point)
| Scoping.Error (Scoping.Duplicate_field name) ->
let token =
Lexer.Token.mk_ident name.Region.value name.Region.region in
(match token with
(* Cannot fail because [name] is a not a
reserved name for the lexer. *)
Stdlib.Error _ -> assert false
| Ok invalid ->
let point =
"Duplicate field name in this record declaration.\n\
Hint: Change the name.\n",
None, invalid
in issue_error point)
(* Preprocessing the input source with CPP *)
module SSet = Utils.String.Set
let sprintf = Printf.sprintf
(* Path for CPP inclusions (#include) *)
let lib_path =
match IO.options#libs with
[] -> ""
| libs -> let mk_I dir path = sprintf " -I %s%s" dir path
in List.fold_right mk_I libs ""
let prefix =
match IO.options#input with
None | Some "-" -> "temp"
| Some file -> Filename.(file |> basename |> remove_extension)
let suffix = ".pp" ^ IO.ext
let pp_input =
if SSet.mem "cpp" IO.options#verbose
then prefix ^ suffix
else let pp_input, pp_out =
Filename.open_temp_file prefix suffix
in close_out pp_out; pp_input
let cpp_cmd =
match IO.options#input with
None | Some "-" ->
sprintf "cpp -traditional-cpp%s - > %s"
lib_path pp_input
| Some file ->
sprintf "cpp -traditional-cpp%s %s > %s"
lib_path file pp_input
let () = let () =
if Sys.command cpp_cmd <> 0 then match IO.options#input with
Printf.eprintf "External error: \"%s\" failed." cpp_cmd None -> Unit.contract_in_stdin () |> wrap
| Some file_path -> Unit.contract_in_file file_path |> wrap
(* Instantiating the lexer and calling the parser *)
let lexer_inst =
match Lexer.open_token_stream (Lexer.File pp_input) with
Ok instance ->
if IO.options#expr
then
match parse (fun () -> Unit.apply instance Unit.parse_expr) with
Stdlib.Ok _ -> ()
| Error Region.{value; _} ->
Printf.eprintf "\027[31m%s\027[0m%!" value
else
(match parse (fun () -> Unit.apply instance Unit.parse_contract) with
Stdlib.Ok _ -> ()
| Error Region.{value; _} ->
Printf.eprintf "\027[31m%s\027[0m%!" value)
| Stdlib.Error (Lexer.File_opening msg) ->
Printf.eprintf "\027[31m%s\027[0m%!" msg

View File

@ -1,2 +0,0 @@
module Region = Region
module Pos = Pos

View File

@ -73,7 +73,6 @@
(action (run %{script_cover} --lex-tokens=LexToken.mli --par-tokens=ParToken.mly --ext=religo --unlexer=./Unlexer.exe --messages=Parser.msg --dir=. --concatenate Parser.mly ))) (action (run %{script_cover} --lex-tokens=LexToken.mli --par-tokens=ParToken.mly --ext=religo --unlexer=./Unlexer.exe --messages=Parser.msg --dir=. --concatenate Parser.mly )))
;; Error messages ;; Error messages
;; Generate error messages from scratch ;; Generate error messages from scratch
; (rule ; (rule
; (targets error.messages) ; (targets error.messages)

View File

@ -1,7 +1,7 @@
$HOME/git/OCaml-build/Makefile $HOME/git/OCaml-build/Makefile
$HOME/git/OCaml-build/Makefile.cfg $HOME/git/OCaml-build/Makefile.cfg
$HOME/git/ligo/vendors/ligo-utils/simple-utils/pos.mli $HOME/git/ligo/vendors/ligo-utils/simple-utils/pos.mli
$HOME/git/ligo/vendors/ligo-utils/simple-utils/pos.ml $HOME/git/ligo/vendors/ligo-utils/simple-utils/pos.ml
$HOME/git/ligo/vendors/ligo-utils/simple-utils/region.mli $HOME/git/ligo/vendors/ligo-utils/simple-utils/region.mli
$HOME/git/ligo/vendors/ligo-utils/simple-utils/region.ml $HOME/git/ligo/vendors/ligo-utils/simple-utils/region.ml
$HOME/git/ligo/vendors/ligo-utils/simple-utils/region.ml

View File

@ -1,45 +1,62 @@
(** Parsing command-line options *) (* Parsing command-line options *)
(* The type [command] denotes some possible behaviours of the
compiler. *)
(** The type [command] denotes some possible behaviours of the
compiler.
*)
type command = Quiet | Copy | Units | Tokens type command = Quiet | Copy | Units | Tokens
(** The type [options] gathers the command-line options. type language = [`PascaLIGO | `CameLIGO | `ReasonLIGO]
*)
let lang_to_string = function
`PascaLIGO -> "PascaLIGO"
| `CameLIGO -> "CameLIGO"
| `ReasonLIGO -> "ReasonLIGO"
(* The type [options] gathers the command-line options. *)
module SSet = Set.Make (String)
type options = < type options = <
input : string option; input : string option;
libs : string list; libs : string list;
verbose : Utils.String.Set.t; verbose : SSet.t;
offsets : bool; offsets : bool;
lang : language;
ext : string; (* ".ligo", ".mligo", ".religo" *)
mode : [`Byte | `Point]; mode : [`Byte | `Point];
cmd : command; cmd : command;
mono : bool; mono : bool;
expr : bool expr : bool
> >
let make ~input ~libs ~verbose ~offsets ~mode ~cmd ~mono ~expr = let make ~input ~libs ~verbose ~offsets ~lang ~ext ~mode ~cmd ~mono ~expr : options =
object object
method input = input method input = input
method libs = libs method libs = libs
method verbose = verbose method verbose = verbose
method offsets = offsets method offsets = offsets
method lang = lang
method ext = ext
method mode = mode method mode = mode
method cmd = cmd method cmd = cmd
method mono = mono method mono = mono
method expr = expr method expr = expr
end end
(** {1 Auxiliary functions} *) (* Auxiliary functions *)
let printf = Printf.printf let printf = Printf.printf
let sprintf = Printf.sprintf let sprintf = Printf.sprintf
let print = print_endline let print = print_endline
let abort msg = (* Printing a string in red to standard error *)
Utils.highlight (sprintf "Command-line error: %s\n" msg); exit 1
(** {1 Help} *) let highlight msg = Printf.eprintf "\027[31m%s\027[0m%!" msg
let abort msg =
highlight (sprintf "Command-line error: %s\n" msg); exit 1
(* Help *)
let help language extension () = let help language extension () =
let file = Filename.basename Sys.argv.(0) in let file = Filename.basename Sys.argv.(0) in
@ -55,16 +72,16 @@ let help language extension () =
print " --bytes Bytes for source locations"; print " --bytes Bytes for source locations";
print " --mono Use Menhir monolithic API"; print " --mono Use Menhir monolithic API";
print " --expr Parse an expression"; print " --expr Parse an expression";
print " --verbose=<stages> cli, cpp, ast-tokens, ast (colon-separated)"; print " --verbose=<stages> cli, preproc, ast-tokens, ast (colon-separated)";
print " --version Commit hash on stdout"; print " --version Commit hash on stdout";
print " -h, --help This help"; print " -h, --help This help";
exit 0 exit 0
(** {1 Version} *) (* Version *)
let version () = printf "%s\n" Version.version; exit 0 let version () = printf "%s\n" Version.version; exit 0
(** {1 Specifying the command-line options a la GNU} *) (* Specifying the command-line options a la GNU *)
let copy = ref false let copy = ref false
and tokens = ref false and tokens = ref false
@ -72,7 +89,7 @@ and units = ref false
and quiet = ref false and quiet = ref false
and columns = ref false and columns = ref false
and bytes = ref false and bytes = ref false
and verbose = ref Utils.String.Set.empty and verbose = ref SSet.empty
and input = ref None and input = ref None
and libs = ref [] and libs = ref []
and verb_str = ref "" and verb_str = ref ""
@ -84,11 +101,12 @@ let split_at_colon = Str.(split (regexp ":"))
let add_path p = libs := !libs @ split_at_colon p let add_path p = libs := !libs @ split_at_colon p
let add_verbose d = let add_verbose d =
verbose := List.fold_left (Utils.swap Utils.String.Set.add) verbose := List.fold_left (fun x y -> SSet.add y x)
!verbose !verbose
(split_at_colon d) (split_at_colon d)
let specs language extension = let specs language extension =
let language = lang_to_string language in
let open! Getopt in [ let open! Getopt in [
'I', nolong, None, Some add_path; 'I', nolong, None, Some add_path;
'c', "copy", set copy true, None; 'c', "copy", set copy true, None;
@ -105,17 +123,15 @@ let specs language extension =
] ]
;; ;;
(** Handler of anonymous arguments (* Handler of anonymous arguments *)
*)
let anonymous arg = let anonymous arg =
match !input with match !input with
None -> input := Some arg None -> input := Some arg
| Some s -> Printf.printf "s=%s\n" s; | Some _ -> abort (sprintf "Multiple inputs")
abort (sprintf "Multiple inputs")
;; (* Checking options and exporting them as non-mutable values *)
(** Checking options and exporting them as non-mutable values
*)
let string_of convert = function let string_of convert = function
None -> "None" None -> "None"
| Some s -> sprintf "Some %s" (convert s) | Some s -> sprintf "Some %s" (convert s)
@ -139,21 +155,20 @@ let print_opt () =
printf "verbose = %s\n" !verb_str; printf "verbose = %s\n" !verb_str;
printf "input = %s\n" (string_of quote !input); printf "input = %s\n" (string_of quote !input);
printf "libs = %s\n" (string_of_path !libs) printf "libs = %s\n" (string_of_path !libs)
;;
let check extension = let check lang ext =
let () = let () =
if Utils.String.Set.mem "cli" !verbose then print_opt () in if SSet.mem "cli" !verbose then print_opt () in
let input = let input =
match !input with match !input with
None | Some "-" -> !input None | Some "-" -> None
| Some file_path -> | Some file_path ->
if Filename.check_suffix file_path extension if Filename.check_suffix file_path ext
then if Sys.file_exists file_path then if Sys.file_exists file_path
then Some file_path then Some file_path
else abort "Source file not found." else abort "Source file not found."
else abort ("Source file lacks the extension " ^ extension ^ ".") in else abort ("Source file lacks the extension " ^ ext ^ ".") in
(* Exporting remaining options as non-mutable values *) (* Exporting remaining options as non-mutable values *)
@ -169,7 +184,7 @@ let check extension =
and libs = !libs in and libs = !libs in
let () = let () =
if Utils.String.Set.mem "cli" verbose then if SSet.mem "cli" verbose then
begin begin
printf "\nEXPORTED COMMAND LINE\n"; printf "\nEXPORTED COMMAND LINE\n";
printf "copy = %b\n" copy; printf "copy = %b\n" copy;
@ -194,16 +209,16 @@ let check extension =
| false, false, false, true -> Tokens | false, false, false, true -> Tokens
| _ -> abort "Choose one of -q, -c, -u, -t." | _ -> abort "Choose one of -q, -c, -u, -t."
in make ~input ~libs ~verbose ~offsets ~mode ~cmd ~mono ~expr in make ~input ~libs ~verbose ~offsets ~mode ~cmd ~mono ~expr ~lang ~ext
(** {1 Parsing the command-line options} *) (* Parsing the command-line options *)
let read language extension = let read ~lang ~ext =
try try
Getopt.parse_cmdline (specs language extension) anonymous; Getopt.parse_cmdline (specs lang ext) anonymous;
(verb_str := (verb_str :=
let apply e a = let apply e a =
if a = "" then e else Printf.sprintf "%s, %s" e a if a = "" then e else Printf.sprintf "%s, %s" e a
in Utils.String.Set.fold apply !verbose ""); in SSet.fold apply !verbose "");
check extension check lang ext
with Getopt.Error msg -> abort msg with Getopt.Error msg -> abort msg

View File

@ -48,11 +48,20 @@ type command = Quiet | Copy | Units | Tokens
expressions is used, otherwise a full-fledged contract is expressions is used, otherwise a full-fledged contract is
expected.} expected.}
} *) } *)
type language = [`PascaLIGO | `CameLIGO | `ReasonLIGO]
val lang_to_string : language -> string
module SSet : Set.S with type elt = string and type t = Set.Make(String).t
type options = < type options = <
input : string option; input : string option;
libs : string list; libs : string list;
verbose : Utils.String.Set.t; verbose : SSet.t;
offsets : bool; offsets : bool;
lang : language;
ext : string; (* ".ligo", ".mligo", ".religo" *)
mode : [`Byte | `Point]; mode : [`Byte | `Point];
cmd : command; cmd : command;
mono : bool; mono : bool;
@ -62,8 +71,10 @@ type options = <
val make : val make :
input:string option -> input:string option ->
libs:string list -> libs:string list ->
verbose:Utils.String.Set.t -> verbose:SSet.t ->
offsets:bool -> offsets:bool ->
lang:language ->
ext:string ->
mode:[`Byte | `Point] -> mode:[`Byte | `Point] ->
cmd:command -> cmd:command ->
mono:bool -> mono:bool ->
@ -71,7 +82,7 @@ val make :
options options
(** Parsing the command-line options on stdin. The first parameter is (** Parsing the command-line options on stdin. The first parameter is
the name of the concrete syntax, e.g., "pascaligo", and the second the name of the concrete syntax, e.g., [PascaLIGO], and the second
is the file extension, e.g., ".ligo". is the expected file extension, e.g., ".ligo". *)
*)
val read : string -> string -> options val read : lang:language -> ext:string -> options

View File

@ -135,7 +135,14 @@ module type S =
val slide : token -> window -> window val slide : token -> window -> window
type input =
File of file_path
| String of string
| Channel of in_channel
| Buffer of Lexing.lexbuf
type instance = { type instance = {
input : input;
read : log:logger -> Lexing.lexbuf -> token; read : log:logger -> Lexing.lexbuf -> token;
buffer : Lexing.lexbuf; buffer : Lexing.lexbuf;
get_win : unit -> window; get_win : unit -> window;
@ -145,16 +152,15 @@ module type S =
close : unit -> unit close : unit -> unit
} }
type input =
File of file_path (* "-" means stdin *)
| Stdin
| String of string
| Channel of in_channel
| Buffer of Lexing.lexbuf
type open_err = File_opening of string type open_err = File_opening of string
val open_token_stream : input -> (instance, open_err) Stdlib.result val lexbuf_from_input :
input -> (Lexing.lexbuf * (unit -> unit), open_err) Stdlib.result
type language = [`PascaLIGO | `CameLIGO | `ReasonLIGO]
val open_token_stream :
language -> input -> (instance, open_err) Stdlib.result
(* Error reporting *) (* Error reporting *)

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@ -157,7 +157,14 @@ module type S =
val slide : token -> window -> window val slide : token -> window -> window
type input =
File of file_path
| String of string
| Channel of in_channel
| Buffer of Lexing.lexbuf
type instance = { type instance = {
input : input;
read : log:logger -> Lexing.lexbuf -> token; read : log:logger -> Lexing.lexbuf -> token;
buffer : Lexing.lexbuf; buffer : Lexing.lexbuf;
get_win : unit -> window; get_win : unit -> window;
@ -167,16 +174,15 @@ module type S =
close : unit -> unit close : unit -> unit
} }
type input =
File of file_path (* "-" means stdin *)
| Stdin
| String of string
| Channel of in_channel
| Buffer of Lexing.lexbuf
type open_err = File_opening of string type open_err = File_opening of string
val open_token_stream : input -> (instance, open_err) Stdlib.result val lexbuf_from_input :
input -> (Lexing.lexbuf * (unit -> unit), open_err) Stdlib.result
type language = [`PascaLIGO | `CameLIGO | `ReasonLIGO]
val open_token_stream :
language -> input -> (instance, open_err) Stdlib.result
(* Error reporting *) (* Error reporting *)
@ -254,7 +260,7 @@ module Make (Token: TOKEN) : (S with module Token = Token) =
Nil -> One token Nil -> One token
| One t | Two (t,_) -> Two (token,t) | One t | Two (t,_) -> Two (token,t)
(** Beyond tokens, the result of lexing is a state. The type (* Beyond tokens, the result of lexing is a state. The type
[state] represents the logical state of the lexing engine, that [state] represents the logical state of the lexing engine, that
is, a value which is threaded during scanning and which denotes is, a value which is threaded during scanning and which denotes
useful, high-level information beyond what the type useful, high-level information beyond what the type
@ -292,6 +298,9 @@ module Make (Token: TOKEN) : (S with module Token = Token) =
it to [decoder]. See the documentation of the third-party it to [decoder]. See the documentation of the third-party
library Uutf. library Uutf.
*) *)
type language = [`PascaLIGO | `CameLIGO | `ReasonLIGO]
type state = { type state = {
units : (Markup.t list * token) FQueue.t; units : (Markup.t list * token) FQueue.t;
markup : Markup.t list; markup : Markup.t list;
@ -299,7 +308,8 @@ module Make (Token: TOKEN) : (S with module Token = Token) =
last : Region.t; last : Region.t;
pos : Pos.t; pos : Pos.t;
decoder : Uutf.decoder; decoder : Uutf.decoder;
supply : Bytes.t -> int -> int -> unit supply : Bytes.t -> int -> int -> unit;
lang : language
} }
(* The call [enqueue (token, state)] updates functionally the (* The call [enqueue (token, state)] updates functionally the
@ -388,7 +398,7 @@ module Make (Token: TOKEN) : (S with module Token = Token) =
| Unterminated_string | Unterminated_string
| Unterminated_integer | Unterminated_integer
| Odd_lengthed_bytes | Odd_lengthed_bytes
| Unterminated_comment | Unterminated_comment of string
| Orphan_minus | Orphan_minus
| Non_canonical_zero | Non_canonical_zero
| Negative_byte_sequence | Negative_byte_sequence
@ -401,51 +411,51 @@ module Make (Token: TOKEN) : (S with module Token = Token) =
let error_to_string = function let error_to_string = function
Invalid_utf8_sequence -> Invalid_utf8_sequence ->
"Invalid UTF-8 sequence.\n" "Invalid UTF-8 sequence."
| Unexpected_character c -> | Unexpected_character c ->
sprintf "Unexpected character '%s'.\n" (Char.escaped c) sprintf "Unexpected character '%s'." (Char.escaped c)
| Undefined_escape_sequence -> | Undefined_escape_sequence ->
"Undefined escape sequence.\n\ "Undefined escape sequence.\n\
Hint: Remove or replace the sequence.\n" Hint: Remove or replace the sequence."
| Missing_break -> | Missing_break ->
"Missing break.\n\ "Missing break.\n\
Hint: Insert some space.\n" Hint: Insert some space."
| Unterminated_string -> | Unterminated_string ->
"Unterminated string.\n\ "Unterminated string.\n\
Hint: Close with double quotes.\n" Hint: Close with double quotes."
| Unterminated_integer -> | Unterminated_integer ->
"Unterminated integer.\n\ "Unterminated integer.\n\
Hint: Remove the sign or proceed with a natural number.\n" Hint: Remove the sign or proceed with a natural number."
| Odd_lengthed_bytes -> | Odd_lengthed_bytes ->
"The length of the byte sequence is an odd number.\n\ "The length of the byte sequence is an odd number.\n\
Hint: Add or remove a digit.\n" Hint: Add or remove a digit."
| Unterminated_comment -> | Unterminated_comment ending ->
"Unterminated comment.\n\ sprintf "Unterminated comment.\n\
Hint: Close with \"*)\".\n" Hint: Close with \"%s\"." ending
| Orphan_minus -> | Orphan_minus ->
"Orphan minus sign.\n\ "Orphan minus sign.\n\
Hint: Remove the trailing space.\n" Hint: Remove the trailing space."
| Non_canonical_zero -> | Non_canonical_zero ->
"Non-canonical zero.\n\ "Non-canonical zero.\n\
Hint: Use 0.\n" Hint: Use 0."
| Negative_byte_sequence -> | Negative_byte_sequence ->
"Negative byte sequence.\n\ "Negative byte sequence.\n\
Hint: Remove the leading minus sign.\n" Hint: Remove the leading minus sign."
| Broken_string -> | Broken_string ->
"The string starting here is interrupted by a line break.\n\ "The string starting here is interrupted by a line break.\n\
Hint: Remove the break, close the string before or insert a \ Hint: Remove the break, close the string before or insert a \
backslash.\n" backslash."
| Invalid_character_in_string -> | Invalid_character_in_string ->
"Invalid character in string.\n\ "Invalid character in string.\n\
Hint: Remove or replace the character.\n" Hint: Remove or replace the character."
| Reserved_name s -> | Reserved_name s ->
sprintf "Reserved name: \"%s\".\n\ sprintf "Reserved name: \"%s\".\n\
Hint: Change the name.\n" s Hint: Change the name." s
| Invalid_symbol -> | Invalid_symbol ->
"Invalid symbol.\n\ "Invalid symbol.\n\
Hint: Check the LIGO syntax you use.\n" Hint: Check the LIGO syntax you use."
| Invalid_natural -> | Invalid_natural ->
"Invalid natural." "Invalid natural number."
| Invalid_attribute -> | Invalid_attribute ->
"Invalid attribute." "Invalid attribute."
@ -454,7 +464,7 @@ module Make (Token: TOKEN) : (S with module Token = Token) =
let format_error ?(offsets=true) mode Region.{region; value} ~file = let format_error ?(offsets=true) mode Region.{region; value} ~file =
let msg = error_to_string value let msg = error_to_string value
and reg = region#to_string ~file ~offsets mode in and reg = region#to_string ~file ~offsets mode in
let value = sprintf "Lexical error %s:\n%s" reg msg let value = sprintf "Lexical error %s:\n%s\n" reg msg
in Region.{value; region} in Region.{value; region}
let fail region value = raise (Error Region.{region; value}) let fail region value = raise (Error Region.{region; value})
@ -638,31 +648,43 @@ and scan state = parse
let thread = {opening; len=1; acc=['"']} in let thread = {opening; len=1; acc=['"']} in
scan_string thread state lexbuf |> mk_string |> enqueue } scan_string thread state lexbuf |> mk_string |> enqueue }
| "(*" { let opening, _, state = sync state lexbuf in | "(*" { if state.lang = `PascaLIGO || state.lang = `CameLIGO then
let opening, _, state = sync state lexbuf in
let thread = {opening; len=2; acc=['*';'(']} in let thread = {opening; len=2; acc=['*';'(']} in
let state = scan_block thread state lexbuf |> push_block let state = scan_pascaligo_block thread state lexbuf |> push_block
in scan state lexbuf } in scan state lexbuf
else (rollback lexbuf; scan_two_sym state lexbuf)
}
| "/*" { if state.lang = `ReasonLIGO then
let opening, _, state = sync state lexbuf in
let thread = {opening; len=2; acc=['*';'/']} in
let state = scan_reasonligo_block thread state lexbuf |> push_block
in scan state lexbuf
else (rollback lexbuf; scan_two_sym state lexbuf)
}
| "//" { let opening, _, state = sync state lexbuf in | "//" { let opening, _, state = sync state lexbuf in
let thread = {opening; len=2; acc=['/';'/']} in let thread = {opening; len=2; acc=['/';'/']} in
let state = scan_line thread state lexbuf |> push_line let state = scan_line thread state lexbuf |> push_line
in scan state lexbuf } in scan state lexbuf }
(* Management of #include CPP directives (* Management of #include preprocessing directives
An input LIGO program may contain GNU CPP (C preprocessor) An input LIGO program may contain preprocessing directives, and
directives, and the entry modules (named *Main.ml) run CPP on them the entry modules (named *Main.ml) run the preprocessor on them,
in traditional mode: as if using the GNU C preprocessor in traditional mode:
https://gcc.gnu.org/onlinedocs/cpp/Traditional-Mode.html https://gcc.gnu.org/onlinedocs/cpp/Traditional-Mode.html
The main interest in using CPP is that it can stand for a poor The main interest in using a preprocessor is that it can stand
man's (flat) module system for LIGO thanks to #include for a poor man's (flat) module system for LIGO thanks to #include
directives, and the traditional mode leaves the markup mostly directives, and the equivalent of the traditional mode leaves the
undisturbed. markup undisturbed.
Some of the #line resulting from processing #include directives Contrary to the C preprocessor, our preprocessor does not
deal with system file headers and thus have to be ignored for our generate #line resulting from processing #include directives deal
with system file headers and thus have to be ignored for our
purpose. Moreover, these #line directives may also carry some purpose. Moreover, these #line directives may also carry some
additional flags: additional flags:
@ -714,6 +736,14 @@ and scan state = parse
| _ as c { let region, _, _ = sync state lexbuf | _ as c { let region, _, _ = sync state lexbuf
in fail region (Unexpected_character c) } in fail region (Unexpected_character c) }
(* Scanning two symbols *)
and scan_two_sym state = parse
symbol { scan_one_sym (mk_sym state lexbuf |> enqueue) lexbuf }
and scan_one_sym state = parse
symbol { scan (mk_sym state lexbuf |> enqueue) lexbuf }
(* Scanning CPP #include flags *) (* Scanning CPP #include flags *)
and scan_flags state acc = parse and scan_flags state acc = parse
@ -745,39 +775,70 @@ and scan_string thread state = parse
(* Finishing a block comment (* Finishing a block comment
(Note for Emacs: ("(*") (For Emacs: ("(*") The lexing of block comments must take care of
The lexing of block comments must take care of embedded block embedded block comments that may occur within, as well as strings,
comments that may occur within, as well as strings, so no substring so no substring "*/" or "*)" may inadvertently close the
"*)" may inadvertently close the block. This is the purpose block. This is the purpose of the first case of the scanners
of the first case of the scanner [scan_block]. [scan_pascaligo_block] and [scan_reasonligo_block].
*) *)
and scan_block thread state = parse and scan_pascaligo_block thread state = parse
'"' | "(*" { let opening = thread.opening in '"' | "(*" { let opening = thread.opening in
let opening', lexeme, state = sync state lexbuf in let opening', lexeme, state = sync state lexbuf in
let thread = push_string lexeme thread in let thread = push_string lexeme thread in
let thread = {thread with opening=opening'} in let thread = {thread with opening=opening'} in
let next = if lexeme = "\"" then scan_string let next = if lexeme = "\"" then scan_string
else scan_block in else scan_pascaligo_block in
let thread, state = next thread state lexbuf in let thread, state = next thread state lexbuf in
let thread = {thread with opening} let thread = {thread with opening}
in scan_block thread state lexbuf } in scan_pascaligo_block thread state lexbuf }
| "*)" { let _, lexeme, state = sync state lexbuf | "*)" { let _, lexeme, state = sync state lexbuf
in push_string lexeme thread, state } in push_string lexeme thread, state }
| nl as nl { let () = Lexing.new_line lexbuf | nl as nl { let () = Lexing.new_line lexbuf
and state = {state with pos = state.pos#new_line nl} and state = {state with pos = state.pos#new_line nl}
and thread = push_string nl thread and thread = push_string nl thread
in scan_block thread state lexbuf } in scan_pascaligo_block thread state lexbuf }
| eof { fail thread.opening Unterminated_comment } | eof { fail thread.opening (Unterminated_comment "*)") }
| _ { let () = rollback lexbuf in | _ { let () = rollback lexbuf in
let len = thread.len in let len = thread.len in
let thread, let thread,
status = scan_utf8 thread state lexbuf in status = scan_utf8 "*)" thread state lexbuf in
let delta = thread.len - len in let delta = thread.len - len in
let pos = state.pos#shift_one_uchar delta in let pos = state.pos#shift_one_uchar delta in
match status with match status with
None -> scan_block thread {state with pos} lexbuf Stdlib.Ok () ->
| Some error -> scan_pascaligo_block thread {state with pos} lexbuf
| Error error ->
let region = Region.make ~start:state.pos ~stop:pos
in fail region error }
and scan_reasonligo_block thread state = parse
'"' | "/*" { let opening = thread.opening in
let opening', lexeme, state = sync state lexbuf in
let thread = push_string lexeme thread in
let thread = {thread with opening=opening'} in
let next = if lexeme = "\"" then scan_string
else scan_reasonligo_block in
let thread, state = next thread state lexbuf in
let thread = {thread with opening}
in scan_reasonligo_block thread state lexbuf }
| "*/" { let _, lexeme, state = sync state lexbuf
in push_string lexeme thread, state }
| nl as nl { let () = Lexing.new_line lexbuf
and state = {state with pos = state.pos#new_line nl}
and thread = push_string nl thread
in scan_reasonligo_block thread state lexbuf }
| eof { fail thread.opening (Unterminated_comment "*/") }
| _ { let () = rollback lexbuf in
let len = thread.len in
let thread,
status = scan_utf8 "*/" thread state lexbuf in
let delta = thread.len - len in
let pos = state.pos#shift_one_uchar delta in
match status with
Stdlib.Ok () ->
scan_reasonligo_block thread {state with pos} lexbuf
| Error error ->
let region = Region.make ~start:state.pos ~stop:pos let region = Region.make ~start:state.pos ~stop:pos
in fail region error } in fail region error }
@ -792,24 +853,36 @@ and scan_line thread state = parse
| _ { let () = rollback lexbuf in | _ { let () = rollback lexbuf in
let len = thread.len in let len = thread.len in
let thread, let thread,
status = scan_utf8 thread state lexbuf in status = scan_utf8_inline thread state lexbuf in
let delta = thread.len - len in let delta = thread.len - len in
let pos = state.pos#shift_one_uchar delta in let pos = state.pos#shift_one_uchar delta in
match status with match status with
None -> scan_line thread {state with pos} lexbuf Stdlib.Ok () ->
| Some error -> scan_line thread {state with pos} lexbuf
| Error error ->
let region = Region.make ~start:state.pos ~stop:pos let region = Region.make ~start:state.pos ~stop:pos
in fail region error } in fail region error }
and scan_utf8 thread state = parse and scan_utf8 closing thread state = parse
eof { fail thread.opening Unterminated_comment } eof { fail thread.opening (Unterminated_comment closing) }
| _ as c { let thread = push_char c thread in | _ as c { let thread = push_char c thread in
let lexeme = Lexing.lexeme lexbuf in let lexeme = Lexing.lexeme lexbuf in
let () = state.supply (Bytes.of_string lexeme) 0 1 in let () = state.supply (Bytes.of_string lexeme) 0 1 in
match Uutf.decode state.decoder with match Uutf.decode state.decoder with
`Uchar _ -> thread, None `Uchar _ -> thread, Stdlib.Ok ()
| `Malformed _ -> thread, Some Invalid_utf8_sequence | `Malformed _ -> thread, Stdlib.Error Invalid_utf8_sequence
| `Await -> scan_utf8 thread state lexbuf | `Await -> scan_utf8 closing thread state lexbuf
| `End -> assert false }
and scan_utf8_inline thread state = parse
eof { thread, Stdlib.Ok () }
| _ as c { let thread = push_char c thread in
let lexeme = Lexing.lexeme lexbuf in
let () = state.supply (Bytes.of_string lexeme) 0 1 in
match Uutf.decode state.decoder with
`Uchar _ -> thread, Stdlib.Ok ()
| `Malformed _ -> thread, Stdlib.Error Invalid_utf8_sequence
| `Await -> scan_utf8_inline thread state lexbuf
| `End -> assert false } | `End -> assert false }
(* END LEXER DEFINITION *) (* END LEXER DEFINITION *)
@ -863,7 +936,14 @@ and scan_utf8 thread state = parse
type logger = Markup.t list -> token -> unit type logger = Markup.t list -> token -> unit
type input =
File of file_path
| String of string
| Channel of in_channel
| Buffer of Lexing.lexbuf
type instance = { type instance = {
input : input;
read : log:logger -> Lexing.lexbuf -> token; read : log:logger -> Lexing.lexbuf -> token;
buffer : Lexing.lexbuf; buffer : Lexing.lexbuf;
get_win : unit -> window; get_win : unit -> window;
@ -873,19 +953,29 @@ type instance = {
close : unit -> unit close : unit -> unit
} }
type input =
File of file_path (* "-" means stdin *)
| Stdin
| String of string
| Channel of in_channel
| Buffer of Lexing.lexbuf
type open_err = File_opening of string type open_err = File_opening of string
let open_token_stream input = let lexbuf_from_input = function
File path ->
(try
let chan = open_in path in
let close () = close_in chan in
let lexbuf = Lexing.from_channel chan in
let () =
let open Lexing in
lexbuf.lex_curr_p <- {lexbuf.lex_curr_p with pos_fname = path}
in Ok (lexbuf, close)
with Sys_error msg -> Stdlib.Error (File_opening msg))
| String s ->
Ok (Lexing.from_string s, fun () -> ())
| Channel chan ->
let close () = close_in chan in
Ok (Lexing.from_channel chan, close)
| Buffer b -> Ok (b, fun () -> ())
let open_token_stream (lang: language) input =
let file_path = match input with let file_path = match input with
File file_path -> File path -> path
if file_path = "-" then "" else file_path
| _ -> "" in | _ -> "" in
let pos = Pos.min ~file:file_path in let pos = Pos.min ~file:file_path in
let buf_reg = ref (pos#byte, pos#byte) let buf_reg = ref (pos#byte, pos#byte)
@ -898,7 +988,8 @@ let open_token_stream input =
pos; pos;
markup = []; markup = [];
decoder; decoder;
supply} in supply;
lang} in
let get_pos () = !state.pos let get_pos () = !state.pos
and get_last () = !state.last and get_last () = !state.last
@ -966,32 +1057,14 @@ let open_token_stream input =
check_right_context token buffer; check_right_context token buffer;
patch_buffer (Token.to_region token)#byte_pos buffer; patch_buffer (Token.to_region token)#byte_pos buffer;
token in token in
match lexbuf_from_input input with
let buf_close_res =
match input with
File "" | File "-" | Stdin ->
Ok (Lexing.from_channel stdin, fun () -> close_in stdin)
| File path ->
(try
let chan = open_in path in
let close () = close_in chan in
Ok (Lexing.from_channel chan, close)
with
Sys_error msg -> Stdlib.Error (File_opening msg))
| String s ->
Ok (Lexing.from_string s, fun () -> ())
| Channel chan ->
let close () = close_in chan in
Ok (Lexing.from_channel chan, close)
| Buffer b -> Ok (b, fun () -> ()) in
match buf_close_res with
Ok (buffer, close) -> Ok (buffer, close) ->
let () = let () =
match input with match input with
File path when path <> "" -> reset ~file:path buffer File path when path <> "" -> reset ~file:path buffer
| _ -> () in | _ -> () in
let instance = { let instance = {
read; buffer; get_win; get_pos; get_last; get_file; close} input; read; buffer; get_win; get_pos; get_last; get_file; close}
in Ok instance in Ok instance
| Error _ as e -> e | Error _ as e -> e

View File

@ -7,15 +7,22 @@ module type S =
module Lexer : Lexer.S module Lexer : Lexer.S
val output_token : val output_token :
?offsets:bool -> [`Byte | `Point] -> ?offsets:bool ->
EvalOpt.command -> out_channel -> [`Byte | `Point] ->
Markup.t list -> Lexer.token -> unit EvalOpt.command ->
out_channel ->
Markup.t list ->
Lexer.token ->
unit
type file_path = string type file_path = string
val trace : val trace :
?offsets:bool -> [`Byte | `Point] -> ?offsets:bool ->
file_path option -> EvalOpt.command -> [`Byte | `Point] ->
EvalOpt.language ->
Lexer.input ->
EvalOpt.command ->
(unit, string Region.reg) Stdlib.result (unit, string Region.reg) Stdlib.result
end end
@ -49,16 +56,12 @@ module Make (Lexer: Lexer.S) : (S with module Lexer = Lexer) =
type file_path = string type file_path = string
let trace ?(offsets=true) mode file_path_opt command : let trace ?(offsets=true) mode lang input command :
(unit, string Region.reg) Stdlib.result = (unit, string Region.reg) Stdlib.result =
let input = match Lexer.open_token_stream lang input with
match file_path_opt with
Some file_path -> Lexer.File file_path
| None -> Lexer.Stdin in
match Lexer.open_token_stream input with
Ok Lexer.{read; buffer; close; _} -> Ok Lexer.{read; buffer; close; _} ->
let log = output_token ~offsets mode command stdout let log = output_token ~offsets mode command stdout
and close_all () = close (); close_out stdout in and close_all () = flush_all (); close () in
let rec iter () = let rec iter () =
match read ~log buffer with match read ~log buffer with
token -> token ->
@ -66,15 +69,11 @@ module Make (Lexer: Lexer.S) : (S with module Lexer = Lexer) =
then Stdlib.Ok () then Stdlib.Ok ()
else iter () else iter ()
| exception Lexer.Error error -> | exception Lexer.Error error ->
let file =
match file_path_opt with
None | Some "-" -> false
| Some _ -> true in
let msg = let msg =
Lexer.format_error ~offsets mode ~file error Lexer.format_error ~offsets mode ~file:true error
in Stdlib.Error msg in in Stdlib.Error msg in
let result = iter () let result = iter ()
in close_all (); result in close_all (); result
| Stdlib.Error (Lexer.File_opening msg) -> | Stdlib.Error (Lexer.File_opening msg) ->
close_out stdout; Stdlib.Error (Region.wrap_ghost msg) flush_all (); Stdlib.Error (Region.wrap_ghost msg)
end end

View File

@ -5,15 +5,22 @@ module type S =
module Lexer : Lexer.S module Lexer : Lexer.S
val output_token : val output_token :
?offsets:bool -> [`Byte | `Point] -> ?offsets:bool ->
EvalOpt.command -> out_channel -> [`Byte | `Point] ->
Markup.t list -> Lexer.token -> unit EvalOpt.command ->
out_channel ->
Markup.t list ->
Lexer.token ->
unit
type file_path = string type file_path = string
val trace : val trace :
?offsets:bool -> [`Byte | `Point] -> ?offsets:bool ->
file_path option -> EvalOpt.command -> [`Byte | `Point] ->
EvalOpt.language ->
Lexer.input ->
EvalOpt.command ->
(unit, string Region.reg) Stdlib.result (unit, string Region.reg) Stdlib.result
end end

View File

@ -1,71 +1,48 @@
(* Functor to build a standalone LIGO lexer *) (* Functor to build a LIGO lexer *)
module Region = Simple_utils.Region module Region = Simple_utils.Region
module Preproc = Preprocessor.Preproc
module SSet = Set.Make (String)
module type IO = module type IO =
sig sig
val ext : string (* LIGO file extension *)
val options : EvalOpt.options (* CLI options *) val options : EvalOpt.options (* CLI options *)
end end
module Make (IO: IO) (Lexer: Lexer.S) = module Make (IO: IO) (Lexer: Lexer.S) =
struct struct
open Printf
module SSet = Utils.String.Set
(* Error printing and exception tracing *) (* Error printing and exception tracing *)
let () = Printexc.record_backtrace true let () = Printexc.record_backtrace true
(* Preprocessing the input source and opening the input channels *) (* Preprocessing and lexing the input source *)
(* Path for CPP inclusions (#include) *)
let lib_path =
match IO.options#libs with
[] -> ""
| libs -> let mk_I dir path = sprintf " -I %s%s" dir path
in List.fold_right mk_I libs ""
let prefix =
match IO.options#input with
None | Some "-" -> "temp"
| Some file -> Filename.(file |> basename |> remove_extension)
let suffix = ".pp" ^ IO.ext
let pp_input =
if Utils.String.Set.mem "cpp" IO.options#verbose
then prefix ^ suffix
else let pp_input, pp_out = Filename.open_temp_file prefix suffix
in close_out pp_out; pp_input
let cpp_cmd =
match IO.options#input with
None | Some "-" ->
sprintf "cpp -traditional-cpp%s - > %s"
lib_path pp_input
| Some file ->
sprintf "cpp -traditional-cpp%s %s > %s"
lib_path file pp_input
(* Running the lexer on the input file *)
let scan () : (Lexer.token list, string Region.reg) Stdlib.result = let scan () : (Lexer.token list, string Region.reg) Stdlib.result =
(* Preprocessing the input *) (* Preprocessing the input source *)
if SSet.mem "cpp" IO.options#verbose let preproc cin =
then eprintf "%s\n%!" cpp_cmd let buffer = Lexing.from_channel cin in
else (); let open Lexing in
let () =
match IO.options#input with
None -> ()
| Some pos_fname ->
buffer.lex_curr_p <- {buffer.lex_curr_p with pos_fname} in
let opt = (IO.options :> Preprocessor.EvalOpt.options) in
match Preproc.lex opt buffer with
Stdlib.Error (pp_buffer, err) ->
if SSet.mem "preproc" IO.options#verbose then
Printf.printf "%s\n%!" (Buffer.contents pp_buffer);
let formatted =
Preproc.format ~offsets:IO.options#offsets ~file:true err
in Stdlib.Error formatted
| Stdlib.Ok pp_buffer ->
(* Running the lexer on the preprocessed input *)
if Sys.command cpp_cmd <> 0 then let source = Lexer.String (Buffer.contents pp_buffer) in
let msg = match Lexer.open_token_stream IO.options#lang source with
sprintf "External error: the command \"%s\" failed." cpp_cmd
in Stdlib.Error (Region.wrap_ghost msg)
else
match Lexer.open_token_stream (Lexer.File pp_input) with
Ok Lexer.{read; buffer; close; _} -> Ok Lexer.{read; buffer; close; _} ->
let close_all () = close (); close_out stdout in let close_all () = flush_all (); close () in
let rec read_tokens tokens = let rec read_tokens tokens =
match read ~log:(fun _ _ -> ()) buffer with match read ~log:(fun _ _ -> ()) buffer with
token -> token ->
@ -77,6 +54,8 @@ module Make (IO: IO) (Lexer: Lexer.S) =
match IO.options#input with match IO.options#input with
None | Some "-" -> false None | Some "-" -> false
| Some _ -> true in | Some _ -> true in
let () =
Printf.eprintf "[LexerUnit] file = %b\n%!" file in
let msg = let msg =
Lexer.format_error ~offsets:IO.options#offsets Lexer.format_error ~offsets:IO.options#offsets
IO.options#mode ~file error IO.options#mode ~file error
@ -84,27 +63,50 @@ module Make (IO: IO) (Lexer: Lexer.S) =
let result = read_tokens [] let result = read_tokens []
in close_all (); result in close_all (); result
| Stdlib.Error (Lexer.File_opening msg) -> | Stdlib.Error (Lexer.File_opening msg) ->
close_out stdout; Stdlib.Error (Region.wrap_ghost msg) flush_all (); Stdlib.Error (Region.wrap_ghost msg) in
match IO.options#input with
None -> preproc stdin
| Some file_path ->
try open_in file_path |> preproc with
Sys_error msg -> Stdlib.Error (Region.wrap_ghost msg)
(* Tracing the lexing (effectful) *) (* Tracing the lexing *)
module Log = LexerLog.Make (Lexer) module Log = LexerLog.Make (Lexer)
let trace () : (unit, string Region.reg) Stdlib.result = let trace () : (unit, string Region.reg) Stdlib.result =
(* Preprocessing the input *) (* Preprocessing the input *)
let preproc cin =
if SSet.mem "cpp" IO.options#verbose let buffer = Lexing.from_channel cin in
then eprintf "%s\n%!" cpp_cmd let open Lexing in
else (); let () =
match IO.options#input with
if Sys.command cpp_cmd <> 0 then None | Some "-" -> ()
let msg = | Some pos_fname ->
sprintf "External error: the command \"%s\" failed." cpp_cmd buffer.lex_curr_p <- {buffer.lex_curr_p with pos_fname} in
in Stdlib.Error (Region.wrap_ghost msg) let opt = (IO.options :> Preprocessor.EvalOpt.options) in
else match Preproc.lex opt buffer with
Log.trace ~offsets:IO.options#offsets Stdlib.Error (pp_buffer, err) ->
IO.options#mode if SSet.mem "preproc" IO.options#verbose then
(Some pp_input) Printf.printf "%s\n%!" (Buffer.contents pp_buffer);
IO.options#cmd let formatted =
Preproc.format ~offsets:IO.options#offsets ~file:true err
in Stdlib.Error formatted
| Stdlib.Ok pp_buffer ->
let preproc_str = Buffer.contents pp_buffer in
if SSet.mem "preproc" IO.options#verbose then
begin
Printf.printf "%s\n%!" (Buffer.contents pp_buffer);
Stdlib.Ok ()
end
else Log.trace ~offsets:IO.options#offsets
IO.options#mode
IO.options#lang
(Lexer.String preproc_str)
IO.options#cmd
in match IO.options#input with
None -> preproc stdin
| Some file_path ->
try open_in file_path |> preproc with
Sys_error msg -> Stdlib.Error (Region.wrap_ghost msg)
end end

View File

@ -4,7 +4,6 @@ module Region = Simple_utils.Region
module type IO = module type IO =
sig sig
val ext : string (* LIGO file extension *)
val options : EvalOpt.options (* CLI options *) val options : EvalOpt.options (* CLI options *)
end end

View File

@ -2,10 +2,15 @@
module Region = Simple_utils.Region module Region = Simple_utils.Region
type options = <
offsets : bool;
mode : [`Byte | `Point];
cmd : EvalOpt.command
>
module type IO = module type IO =
sig sig
val ext : string (* LIGO file extension *) val options : options
val options : EvalOpt.options (* CLI options *)
end end
module type PARSER = module type PARSER =
@ -95,14 +100,15 @@ module Make (IO : IO)
None -> None ->
if Lexer.Token.is_eof invalid then "" if Lexer.Token.is_eof invalid then ""
else let invalid_lexeme = Lexer.Token.to_lexeme invalid in else let invalid_lexeme = Lexer.Token.to_lexeme invalid in
Printf.sprintf ", before \"%s\"" invalid_lexeme Printf.sprintf ", at \"%s\"" invalid_lexeme
| Some valid -> | Some valid ->
let valid_lexeme = Lexer.Token.to_lexeme valid in let valid_lexeme = Lexer.Token.to_lexeme valid in
let s = Printf.sprintf ", after \"%s\"" valid_lexeme in if Lexer.Token.is_eof invalid then
if Lexer.Token.is_eof invalid then s Printf.sprintf ", after \"%s\"" valid_lexeme
else else
let invalid_lexeme = Lexer.Token.to_lexeme invalid in let invalid_lexeme = Lexer.Token.to_lexeme invalid in
Printf.sprintf "%s and before \"%s\"" s invalid_lexeme in Printf.sprintf " at \"%s\", after \"%s\""
invalid_lexeme valid_lexeme in
let header = header ^ trailer in let header = header ^ trailer in
let msg = let msg =
header ^ (if msg = "" then ".\n" else ":\n" ^ msg) header ^ (if msg = "" then ".\n" else ":\n" ^ msg)
@ -133,7 +139,8 @@ module Make (IO : IO)
module Incr = Parser.Incremental module Incr = Parser.Incremental
module Log = LexerLog.Make (Lexer) module Log = LexerLog.Make (Lexer)
let log = Log.output_token ~offsets:IO.options#offsets let log = Log.output_token
~offsets:IO.options#offsets
IO.options#mode IO.options#cmd stdout IO.options#mode IO.options#cmd stdout
let incr_contract Lexer.{read; buffer; get_win; close; _} = let incr_contract Lexer.{read; buffer; get_win; close; _} =
@ -141,12 +148,12 @@ module Make (IO : IO)
and failure = failure get_win in and failure = failure get_win in
let parser = Incr.contract buffer.Lexing.lex_curr_p in let parser = Incr.contract buffer.Lexing.lex_curr_p in
let ast = I.loop_handle success failure supplier parser let ast = I.loop_handle success failure supplier parser
in close (); ast in flush_all (); close (); ast
let incr_expr Lexer.{read; buffer; get_win; close; _} = let incr_expr Lexer.{read; buffer; get_win; close; _} =
let supplier = I.lexer_lexbuf_to_supplier (read ~log) buffer let supplier = I.lexer_lexbuf_to_supplier (read ~log) buffer
and failure = failure get_win in and failure = failure get_win in
let parser = Incr.interactive_expr buffer.Lexing.lex_curr_p in let parser = Incr.interactive_expr buffer.Lexing.lex_curr_p in
let expr = I.loop_handle success failure supplier parser let expr = I.loop_handle success failure supplier parser
in close (); expr in flush_all (); close (); expr
end end

View File

@ -2,10 +2,15 @@
module Region = Simple_utils.Region module Region = Simple_utils.Region
type options = <
offsets : bool;
mode : [`Byte | `Point];
cmd : EvalOpt.command
>
module type IO = module type IO =
sig sig
val ext : string (* LIGO file extension *) val options : options
val options : EvalOpt.options (* CLI options *)
end end
(* The signature generated by Menhir with additional type definitions (* The signature generated by Menhir with additional type definitions

View File

@ -1,11 +1,26 @@
(* Functor to build a standalone LIGO parser *) (* Functor to build a LIGO parser *)
module Region = Simple_utils.Region module Region = Simple_utils.Region
module Preproc = Preprocessor.Preproc
module SSet = Set.Make (String)
module type IO = type language = [`PascaLIGO | `CameLIGO | `ReasonLIGO]
module type SubIO =
sig sig
val ext : string (* LIGO file extension *) type options = <
val options : EvalOpt.options (* CLI options *) libs : string list;
verbose : SSet.t;
offsets : bool;
lang : language;
ext : string; (* ".ligo", ".mligo", ".religo" *)
mode : [`Byte | `Point];
cmd : EvalOpt.command;
mono : bool
>
val options : options
val make : input:string option -> expr:bool -> EvalOpt.options
end end
module type Pretty = module type Pretty =
@ -32,18 +47,18 @@ module Make (Lexer: Lexer.S)
(ParErr: sig val message : int -> string end) (ParErr: sig val message : int -> string end)
(ParserLog: Pretty with type ast = AST.t (ParserLog: Pretty with type ast = AST.t
and type expr = AST.expr) and type expr = AST.expr)
(IO: IO) = (SubIO: SubIO) =
struct struct
open Printf open Printf
module SSet = Utils.String.Set module SSet = Set.Make (String)
(* Log of the lexer *) (* Log of the lexer *)
module Log = LexerLog.Make (Lexer) module Log = LexerLog.Make (Lexer)
let log = let log =
Log.output_token ~offsets:IO.options#offsets Log.output_token ~offsets:SubIO.options#offsets
IO.options#mode IO.options#cmd stdout SubIO.options#mode SubIO.options#cmd stdout
(* Error handling (reexported from [ParserAPI]) *) (* Error handling (reexported from [ParserAPI]) *)
@ -54,7 +69,12 @@ module Make (Lexer: Lexer.S)
(* Instantiating the parser *) (* Instantiating the parser *)
module Front = ParserAPI.Make (IO)(Lexer)(Parser)(ParErr) module API_IO =
struct
let options = (SubIO.options :> ParserAPI.options)
end
module Front = ParserAPI.Make (API_IO)(Lexer)(Parser)(ParErr)
let format_error = Front.format_error let format_error = Front.format_error
@ -67,13 +87,13 @@ module Make (Lexer: Lexer.S)
(AST.expr, message Region.reg) Stdlib.result = (AST.expr, message Region.reg) Stdlib.result =
let output = Buffer.create 131 in let output = Buffer.create 131 in
let state = let state =
ParserLog.mk_state ~offsets:IO.options#offsets ParserLog.mk_state ~offsets:SubIO.options#offsets
~mode:IO.options#mode ~mode:SubIO.options#mode
~buffer:output in ~buffer:output in
let close () = lexer_inst.Lexer.close () in let close () = lexer_inst.Lexer.close () in
let expr = let expr =
try try
if IO.options#mono then if SubIO.options#mono then
let tokeniser = lexer_inst.Lexer.read ~log let tokeniser = lexer_inst.Lexer.read ~log
and lexbuf = lexer_inst.Lexer.buffer and lexbuf = lexer_inst.Lexer.buffer
in Front.mono_expr tokeniser lexbuf in Front.mono_expr tokeniser lexbuf
@ -81,20 +101,20 @@ module Make (Lexer: Lexer.S)
Front.incr_expr lexer_inst Front.incr_expr lexer_inst
with exn -> close (); raise exn in with exn -> close (); raise exn in
let () = let () =
if SSet.mem "ast-tokens" IO.options#verbose then if SSet.mem "ast-tokens" SubIO.options#verbose then
begin begin
Buffer.clear output; Buffer.clear output;
ParserLog.print_expr state expr; ParserLog.print_expr state expr;
Buffer.output_buffer stdout output Buffer.output_buffer stdout output
end in end in
let () = let () =
if SSet.mem "ast" IO.options#verbose then if SSet.mem "ast" SubIO.options#verbose then
begin begin
Buffer.clear output; Buffer.clear output;
ParserLog.pp_expr state expr; ParserLog.pp_expr state expr;
Buffer.output_buffer stdout output Buffer.output_buffer stdout output
end end
in close (); Ok expr in flush_all (); close (); Ok expr
(* Parsing a contract *) (* Parsing a contract *)
@ -102,13 +122,13 @@ module Make (Lexer: Lexer.S)
(AST.t, message Region.reg) Stdlib.result = (AST.t, message Region.reg) Stdlib.result =
let output = Buffer.create 131 in let output = Buffer.create 131 in
let state = let state =
ParserLog.mk_state ~offsets:IO.options#offsets ParserLog.mk_state ~offsets:SubIO.options#offsets
~mode:IO.options#mode ~mode:SubIO.options#mode
~buffer:output in ~buffer:output in
let close () = lexer_inst.Lexer.close () in let close () = lexer_inst.Lexer.close () in
let ast = let ast =
try try
if IO.options#mono then if SubIO.options#mono then
let tokeniser = lexer_inst.Lexer.read ~log let tokeniser = lexer_inst.Lexer.read ~log
and lexbuf = lexer_inst.Lexer.buffer and lexbuf = lexer_inst.Lexer.buffer
in Front.mono_contract tokeniser lexbuf in Front.mono_contract tokeniser lexbuf
@ -116,25 +136,23 @@ module Make (Lexer: Lexer.S)
Front.incr_contract lexer_inst Front.incr_contract lexer_inst
with exn -> close (); raise exn in with exn -> close (); raise exn in
let () = let () =
if SSet.mem "ast-tokens" IO.options#verbose then if SSet.mem "ast-tokens" SubIO.options#verbose then
begin begin
Buffer.clear output; Buffer.clear output;
ParserLog.print_tokens state ast; ParserLog.print_tokens state ast;
Buffer.output_buffer stdout output Buffer.output_buffer stdout output
end in end in
let () = let () =
if SSet.mem "ast" IO.options#verbose then if SSet.mem "ast" SubIO.options#verbose then
begin begin
Buffer.clear output; Buffer.clear output;
ParserLog.pp_ast state ast; ParserLog.pp_ast state ast;
Buffer.output_buffer stdout output Buffer.output_buffer stdout output
end end
in close (); Ok ast in flush_all (); close (); Ok ast
(* Wrapper for the parsers above *) (* Wrapper for the parsers above *)
type 'a parser = Lexer.instance -> ('a, message Region.reg) result
let apply lexer_inst parser = let apply lexer_inst parser =
(* Calling the parser and filtering errors *) (* Calling the parser and filtering errors *)
@ -146,20 +164,18 @@ module Make (Lexer: Lexer.S)
| exception Lexer.Error err -> | exception Lexer.Error err ->
let file = let file =
match IO.options#input with lexer_inst.Lexer.buffer.Lexing.lex_curr_p.Lexing.pos_fname in
None | Some "-" -> false
| Some _ -> true in
let error = let error =
Lexer.format_error ~offsets:IO.options#offsets Lexer.format_error ~offsets:SubIO.options#offsets
IO.options#mode err ~file SubIO.options#mode err ~file:(file <> "")
in Stdlib.Error error in Stdlib.Error error
(* Incremental API of Menhir *) (* Incremental API of Menhir *)
| exception Front.Point point -> | exception Front.Point point ->
let error = let error =
Front.format_error ~offsets:IO.options#offsets Front.format_error ~offsets:SubIO.options#offsets
IO.options#mode point SubIO.options#mode point
in Stdlib.Error error in Stdlib.Error error
(* Monolithic API of Menhir *) (* Monolithic API of Menhir *)
@ -173,12 +189,102 @@ module Make (Lexer: Lexer.S)
| Lexer.Two (invalid, valid) -> invalid, Some valid in | Lexer.Two (invalid, valid) -> invalid, Some valid in
let point = "", valid_opt, invalid in let point = "", valid_opt, invalid in
let error = let error =
Front.format_error ~offsets:IO.options#offsets Front.format_error ~offsets:SubIO.options#offsets
IO.options#mode point SubIO.options#mode point
in Stdlib.Error error in Stdlib.Error error
(* I/O errors *) (* I/O errors *)
| exception Sys_error error -> | exception Sys_error error ->
Stdlib.Error (Region.wrap_ghost error) flush_all (); Stdlib.Error (Region.wrap_ghost error)
(* Preprocessing the input source *)
let preproc options lexbuf =
Preproc.lex (options :> Preprocessor.EvalOpt.options) lexbuf
(* Parsing a contract *)
let gen_parser options input parser =
match Lexer.lexbuf_from_input input with
Stdlib.Error (Lexer.File_opening msg) ->
Stdlib.Error (Region.wrap_ghost msg)
| Ok (lexbuf, close) ->
(* Preprocessing the input source *)
let file = Lexing.(lexbuf.lex_curr_p.pos_fname) in
match preproc options lexbuf with
Stdlib.Error (pp_buffer, err) ->
if SSet.mem "preproc" options#verbose then
Printf.printf "%s\n%!" (Buffer.contents pp_buffer);
let formatted =
Preproc.format ~offsets:options#offsets
~file:(file <> "")
err
in close (); Stdlib.Error formatted
| Stdlib.Ok buffer ->
(* Lexing and parsing the preprocessed input source *)
let () = close () in
let input' = Lexer.String (Buffer.contents buffer) in
match Lexer.open_token_stream options#lang input' with
Ok instance ->
let open Lexing in
instance.Lexer.buffer.lex_curr_p <-
{instance.Lexer.buffer.lex_curr_p with pos_fname = file};
apply instance parser
| Stdlib.Error (Lexer.File_opening msg) ->
Stdlib.Error (Region.wrap_ghost msg)
(* Parsing a contract in a file *)
let contract_in_file (source : string) =
let options = SubIO.make ~input:(Some source) ~expr:false
in gen_parser options (Lexer.File source) parse_contract
(* Parsing a contract in a string *)
let contract_in_string (source : string) =
let options = SubIO.make ~input:None ~expr:false in
gen_parser options (Lexer.String source) parse_contract
(* Parsing a contract in stdin *)
let contract_in_stdin () =
let options = SubIO.make ~input:None ~expr:false in
gen_parser options (Lexer.Channel stdin) parse_contract
(* Parsing an expression in a string *)
let expr_in_string (source : string) =
let options = SubIO.make ~input:None ~expr:true in
gen_parser options (Lexer.String source) parse_expr
(* Parsing an expression in stdin *)
let expr_in_stdin () =
let options = SubIO.make ~input:None ~expr:true in
gen_parser options (Lexer.Channel stdin) parse_expr
(* Preprocess only *)
let preprocess (source : string) =
let options = SubIO.make ~input:(Some source) ~expr:false in
try
let cin = open_in source in
let lexbuf = Lexing.from_channel cin in
let () =
let open Lexing in
lexbuf.lex_curr_p <- {lexbuf.lex_curr_p with pos_fname=source}
and options = (options :> Preprocessor.EvalOpt.options) in
match Preprocessor.Preproc.lex options lexbuf with
Stdlib.Ok _ as ok -> ok
| Error (_, err) ->
let formatted =
Preproc.format ~offsets:options#offsets
~file:true
err
in close_in cin; Stdlib.Error formatted
with Sys_error error ->
flush_all (); Stdlib.Error (Region.wrap_ghost error)
end end

View File

@ -2,10 +2,25 @@
module Region = Simple_utils.Region module Region = Simple_utils.Region
module type IO = type language = [`PascaLIGO | `CameLIGO | `ReasonLIGO]
module SSet : Set.S with type elt = string and type t = Set.Make(String).t
module type SubIO =
sig sig
val ext : string (* LIGO file extension *) type options = <
val options : EvalOpt.options (* CLI options *) libs : string list;
verbose : SSet.t;
offsets : bool;
lang : language;
ext : string; (* ".ligo", ".mligo", ".religo" *)
mode : [`Byte | `Point];
cmd : EvalOpt.command;
mono : bool
>
val options : options
val make : input:string option -> expr:bool -> EvalOpt.options
end end
module type Pretty = module type Pretty =
@ -32,7 +47,7 @@ module Make (Lexer : Lexer.S)
(ParErr : sig val message : int -> string end) (ParErr : sig val message : int -> string end)
(ParserLog : Pretty with type ast = AST.t (ParserLog : Pretty with type ast = AST.t
and type expr = AST.expr) and type expr = AST.expr)
(IO: IO) : (SubIO: SubIO) :
sig sig
(* Error handling reexported from [ParserAPI] without the (* Error handling reexported from [ParserAPI] without the
exception [Point] *) exception [Point] *)
@ -50,10 +65,21 @@ module Make (Lexer : Lexer.S)
(* Parsers *) (* Parsers *)
type 'a parser = Lexer.instance -> ('a, message Region.reg) result val contract_in_file :
string -> (AST.t, message Region.reg) Stdlib.result
val apply : Lexer.instance -> 'a parser -> ('a, message Region.reg) result val contract_in_string :
string -> (AST.t, message Region.reg) Stdlib.result
val parse_contract : AST.t parser val contract_in_stdin :
val parse_expr : AST.expr parser unit -> (AST.t, message Region.reg) Stdlib.result
val expr_in_string :
string -> (AST.expr, message Region.reg) Stdlib.result
val expr_in_stdin :
unit -> (AST.expr, message Region.reg) Stdlib.result
val preprocess :
string -> (Buffer.t, message Region.reg) Stdlib.result
end end

View File

@ -8,7 +8,8 @@
simple-utils simple-utils
uutf uutf
getopt getopt
zarith) zarith
Preprocessor)
(preprocess (preprocess
(pps bisect_ppx --conditional)) (pps bisect_ppx --conditional))
(modules (modules
@ -17,8 +18,8 @@
ParserAPI ParserAPI
Lexer Lexer
LexerLog LexerLog
Utils
Markup Markup
Utils
FQueue FQueue
EvalOpt EvalOpt
Version)) Version))

View File

@ -1,7 +1,7 @@
open Trace open Trace
open Ligo_interpreter.Types open Ligo_interpreter.Types
open Ligo_interpreter.Combinators open Ligo_interpreter.Combinators
include Stage_common.Types include Ast_typed.Types
module Env = Ligo_interpreter.Environment module Env = Ligo_interpreter.Environment
@ -210,7 +210,7 @@ let rec apply_operator : Ast_typed.constant' -> value list -> value result =
| ( C_SET_MEM , [ v ; V_Set (elts) ] ) -> ok @@ v_bool (List.mem v elts) | ( C_SET_MEM , [ v ; V_Set (elts) ] ) -> ok @@ v_bool (List.mem v elts)
| ( C_SET_REMOVE , [ v ; V_Set (elts) ] ) -> ok @@ V_Set (List.filter (fun el -> not (el = v)) elts) | ( C_SET_REMOVE , [ v ; V_Set (elts) ] ) -> ok @@ V_Set (List.filter (fun el -> not (el = v)) elts)
| _ -> | _ ->
let () = Format.printf "%a\n" Stage_common.PP.constant c in let () = Format.printf "%a\n" Ast_typed.PP.constant c in
let () = List.iter ( fun e -> Format.printf "%s\n" (Ligo_interpreter.PP.pp_value e)) operands in let () = List.iter ( fun e -> Format.printf "%s\n" (Ligo_interpreter.PP.pp_value e)) operands in
simple_fail "Unsupported constant op" simple_fail "Unsupported constant op"
) )
@ -338,25 +338,24 @@ and eval : Ast_typed.expression -> env -> value result
| Match_list cases , V_List [] -> | Match_list cases , V_List [] ->
eval cases.match_nil env eval cases.match_nil env
| Match_list cases , V_List (head::tail) -> | Match_list cases , V_List (head::tail) ->
let (head_var,tail_var,body,_) = cases.match_cons in let {hd;tl;body;tv=_} = cases.match_cons in
let env' = Env.extend (Env.extend env (head_var,head)) (tail_var, V_List tail) in let env' = Env.extend (Env.extend env (hd,head)) (tl, V_List tail) in
eval body env' eval body env'
| Match_variant (case_list , _) , V_Construct (matched_c , proj) -> | Match_variant {cases ; tv=_} , V_Construct (matched_c , proj) ->
let ((_, var) , body) = let {constructor=_ ; pattern ; body} =
List.find List.find
(fun case -> (fun {constructor = (Constructor c) ; pattern=_ ; body=_} ->
let (Constructor c , _) = fst case in
String.equal matched_c c) String.equal matched_c c)
case_list in cases in
let env' = Env.extend env (var, proj) in let env' = Env.extend env (pattern, proj) in
eval body env' eval body env'
| Match_bool cases , V_Ct (C_bool true) -> | Match_bool cases , V_Ct (C_bool true) ->
eval cases.match_true env eval cases.match_true env
| Match_bool cases , V_Ct (C_bool false) -> | Match_bool cases , V_Ct (C_bool false) ->
eval cases.match_false env eval cases.match_false env
| Match_option cases, V_Construct ("Some" , proj) -> | Match_option cases, V_Construct ("Some" , proj) ->
let (var,body,_) = cases.match_some in let {opt;body;tv=_} = cases.match_some in
let env' = Env.extend env (var,proj) in let env' = Env.extend env (opt,proj) in
eval body env' eval body env'
| Match_option cases, V_Construct ("None" , V_Ct C_unit) -> | Match_option cases, V_Construct ("None" , V_Ct C_unit) ->
eval cases.match_none env eval cases.match_none env
@ -370,16 +369,16 @@ let dummy : Ast_typed.program -> string result =
fun prg -> fun prg ->
let%bind (res,_) = bind_fold_list let%bind (res,_) = bind_fold_list
(fun (pp,top_env) el -> (fun (pp,top_env) el ->
let (Ast_typed.Declaration_constant (exp_name, exp , _ , _)) = Location.unwrap el in let (Ast_typed.Declaration_constant {binder; expr ; inline=_ ; _}) = Location.unwrap el in
let%bind v = let%bind v =
(*TODO This TRY-CATCH is here until we properly implement effects*) (*TODO This TRY-CATCH is here until we properly implement effects*)
try try
eval exp top_env eval expr top_env
with Temporary_hack s -> ok @@ V_Failure s with Temporary_hack s -> ok @@ V_Failure s
(*TODO This TRY-CATCH is here until we properly implement effects*) (*TODO This TRY-CATCH is here until we properly implement effects*)
in in
let pp' = pp^"\n val "^(Var.to_name exp_name)^" = "^(Ligo_interpreter.PP.pp_value v) in let pp' = pp^"\n val "^(Var.to_name binder)^" = "^(Ligo_interpreter.PP.pp_value v) in
let top_env' = Env.extend top_env (exp_name, v) in let top_env' = Env.extend top_env (binder, v) in
ok @@ (pp',top_env') ok @@ (pp',top_env')
) )
("",Env.empty_env) prg in ("",Env.empty_env) prg in

View File

@ -3,7 +3,9 @@ module Append_tree = Tree.Append
open Trace open Trace
open Mini_c open Mini_c
open Stage_common.Types (*Todo : to remove *) (* open Stage_common.Types (\*Todo : to remove *\) *)
module LMap = AST.Types.LMap
module CMap = AST.Types.CMap
let list_of_lmap m = List.rev @@ LMap.fold (fun _ v prev -> v :: prev) m [] let list_of_lmap m = List.rev @@ LMap.fold (fun _ v prev -> v :: prev) m []
let kv_list_of_lmap m = List.rev @@ LMap.fold (fun k v prev -> (k, v) :: prev) m [] let kv_list_of_lmap m = List.rev @@ LMap.fold (fun k v prev -> (k, v) :: prev) m []
@ -25,7 +27,7 @@ let extract_constructor (v : value) (tree : _ Append_tree.t') : (string * value
let open Append_tree in let open Append_tree in
let rec aux tv : (string * value * AST.type_expression) result= let rec aux tv : (string * value * AST.type_expression) result=
match tv with match tv with
| Leaf (Constructor k, t), v -> ok (k, v, t) | Leaf (Ast_typed.Constructor k, t), v -> ok (k, v, t)
| Node {a}, D_left v -> aux (a, v) | Node {a}, D_left v -> aux (a, v)
| Node {b}, D_right v -> aux (b, v) | Node {b}, D_right v -> aux (b, v)
| _ -> fail @@ internal_assertion_failure "bad constructor path" | _ -> fail @@ internal_assertion_failure "bad constructor path"

View File

@ -114,6 +114,121 @@ them. please report this to the developers." in
end end
open Errors open Errors
let transpile_constant' : AST.constant' -> constant' = function
| C_INT -> C_INT
| C_UNIT -> C_UNIT
| C_NIL -> C_NIL
| C_NOW -> C_NOW
| C_IS_NAT -> C_IS_NAT
| C_SOME -> C_SOME
| C_NONE -> C_NONE
| C_ASSERTION -> C_ASSERTION
| C_ASSERT_INFERRED -> C_ASSERT_INFERRED
| C_FAILWITH -> C_FAILWITH
| C_UPDATE -> C_UPDATE
(* Loops *)
| C_ITER -> C_ITER
| C_FOLD_WHILE -> C_FOLD_WHILE
| C_FOLD_CONTINUE -> C_FOLD_CONTINUE
| C_FOLD_STOP -> C_FOLD_STOP
| C_LOOP_LEFT -> C_LOOP_LEFT
| C_LOOP_CONTINUE -> C_LOOP_CONTINUE
| C_LOOP_STOP -> C_LOOP_STOP
| C_FOLD -> C_FOLD
(* MATH *)
| C_NEG -> C_NEG
| C_ABS -> C_ABS
| C_ADD -> C_ADD
| C_SUB -> C_SUB
| C_MUL -> C_MUL
| C_EDIV -> C_EDIV
| C_DIV -> C_DIV
| C_MOD -> C_MOD
(* LOGIC *)
| C_NOT -> C_NOT
| C_AND -> C_AND
| C_OR -> C_OR
| C_XOR -> C_XOR
| C_LSL -> C_LSL
| C_LSR -> C_LSR
(* COMPARATOR *)
| C_EQ -> C_EQ
| C_NEQ -> C_NEQ
| C_LT -> C_LT
| C_GT -> C_GT
| C_LE -> C_LE
| C_GE -> C_GE
(* Bytes/ String *)
| C_SIZE -> C_SIZE
| C_CONCAT -> C_CONCAT
| C_SLICE -> C_SLICE
| C_BYTES_PACK -> C_BYTES_PACK
| C_BYTES_UNPACK -> C_BYTES_UNPACK
| C_CONS -> C_CONS
(* Pair *)
| C_PAIR -> C_PAIR
| C_CAR -> C_CAR
| C_CDR -> C_CDR
| C_LEFT -> C_LEFT
| C_RIGHT -> C_RIGHT
(* Set *)
| C_SET_EMPTY -> C_SET_EMPTY
| C_SET_LITERAL -> C_SET_LITERAL
| C_SET_ADD -> C_SET_ADD
| C_SET_REMOVE -> C_SET_REMOVE
| C_SET_ITER -> C_SET_ITER
| C_SET_FOLD -> C_SET_FOLD
| C_SET_MEM -> C_SET_MEM
(* List *)
| C_LIST_EMPTY -> C_LIST_EMPTY
| C_LIST_LITERAL -> C_LIST_LITERAL
| C_LIST_ITER -> C_LIST_ITER
| C_LIST_MAP -> C_LIST_MAP
| C_LIST_FOLD -> C_LIST_FOLD
(* Maps *)
| C_MAP -> C_MAP
| C_MAP_EMPTY -> C_MAP_EMPTY
| C_MAP_LITERAL -> C_MAP_LITERAL
| C_MAP_GET -> C_MAP_GET
| C_MAP_GET_FORCE -> C_MAP_GET_FORCE
| C_MAP_ADD -> C_MAP_ADD
| C_MAP_REMOVE -> C_MAP_REMOVE
| C_MAP_UPDATE -> C_MAP_UPDATE
| C_MAP_ITER -> C_MAP_ITER
| C_MAP_MAP -> C_MAP_MAP
| C_MAP_FOLD -> C_MAP_FOLD
| C_MAP_MEM -> C_MAP_MEM
| C_MAP_FIND -> C_MAP_FIND
| C_MAP_FIND_OPT -> C_MAP_FIND_OPT
(* Big Maps *)
| C_BIG_MAP -> C_BIG_MAP
| C_BIG_MAP_EMPTY -> C_BIG_MAP_EMPTY
| C_BIG_MAP_LITERAL -> C_BIG_MAP_LITERAL
(* Crypto *)
| C_SHA256 -> C_SHA256
| C_SHA512 -> C_SHA512
| C_BLAKE2b -> C_BLAKE2b
| C_HASH -> C_HASH
| C_HASH_KEY -> C_HASH_KEY
| C_CHECK_SIGNATURE -> C_CHECK_SIGNATURE
| C_CHAIN_ID -> C_CHAIN_ID
(* Blockchain *)
| C_CALL -> C_CALL
| C_CONTRACT -> C_CONTRACT
| C_CONTRACT_OPT -> C_CONTRACT_OPT
| C_CONTRACT_ENTRYPOINT -> C_CONTRACT_ENTRYPOINT
| C_CONTRACT_ENTRYPOINT_OPT -> C_CONTRACT_ENTRYPOINT_OPT
| C_AMOUNT -> C_AMOUNT
| C_BALANCE -> C_BALANCE
| C_SOURCE -> C_SOURCE
| C_SENDER -> C_SENDER
| C_ADDRESS -> C_ADDRESS
| C_SELF -> C_SELF
| C_SELF_ADDRESS -> C_SELF_ADDRESS
| C_IMPLICIT_ACCOUNT -> C_IMPLICIT_ACCOUNT
| C_SET_DELEGATE -> C_SET_DELEGATE
| C_CREATE_CONTRACT -> C_CREATE_CONTRACT
let rec transpile_type (t:AST.type_expression) : type_value result = let rec transpile_type (t:AST.type_expression) : type_value result =
match t.type_content with match t.type_content with
| T_variable (name) -> fail @@ no_type_variable @@ name | T_variable (name) -> fail @@ no_type_variable @@ name
@ -135,15 +250,15 @@ let rec transpile_type (t:AST.type_expression) : type_value result =
| T_operator (TC_contract x) -> | T_operator (TC_contract x) ->
let%bind x' = transpile_type x in let%bind x' = transpile_type x in
ok (T_contract x') ok (T_contract x')
| T_operator (TC_map (key,value)) -> | T_operator (TC_map {k;v}) ->
let%bind kv' = bind_map_pair transpile_type (key, value) in let%bind kv' = bind_map_pair transpile_type (k, v) in
ok (T_map kv') ok (T_map kv')
| T_operator (TC_big_map (key,value)) -> | T_operator (TC_big_map {k;v}) ->
let%bind kv' = bind_map_pair transpile_type (key, value) in let%bind kv' = bind_map_pair transpile_type (k, v) in
ok (T_big_map kv') ok (T_big_map kv')
| T_operator (TC_map_or_big_map (_,_)) -> | T_operator (TC_map_or_big_map _) ->
fail @@ corner_case ~loc:"transpiler" "TC_map_or_big_map should have been resolved before transpilation" fail @@ corner_case ~loc:"transpiler" "TC_map_or_big_map should have been resolved before transpilation"
| T_operator (TC_michelson_or (l,r)) -> | T_operator (TC_michelson_or {l;r}) ->
let%bind l' = transpile_type l in let%bind l' = transpile_type l in
let%bind r' = transpile_type r in let%bind r' = transpile_type r in
ok (T_or ((None,l'),(None,r'))) ok (T_or ((None,l'),(None,r')))
@ -156,7 +271,7 @@ let rec transpile_type (t:AST.type_expression) : type_value result =
| T_operator (TC_option o) -> | T_operator (TC_option o) ->
let%bind o' = transpile_type o in let%bind o' = transpile_type o in
ok (T_option o') ok (T_option o')
| T_operator (TC_arrow (param , result)) -> ( | T_operator (TC_arrow {type1=param ; type2=result}) -> (
let%bind param' = transpile_type param in let%bind param' = transpile_type param in
let%bind result' = transpile_type result in let%bind result' = transpile_type result in
ok (T_function (param', result')) ok (T_function (param', result'))
@ -171,7 +286,7 @@ let rec transpile_type (t:AST.type_expression) : type_value result =
ok (None, T_or (a, b)) ok (None, T_or (a, b))
in in
let%bind m' = Append_tree.fold_ne let%bind m' = Append_tree.fold_ne
(fun (Stage_common.Types.Constructor ann, a) -> (fun (Ast_typed.Types.Constructor ann, a) ->
let%bind a = transpile_type a in let%bind a = transpile_type a in
ok (( ok ((
if is_michelson_or then if is_michelson_or then
@ -213,7 +328,7 @@ let rec transpile_type (t:AST.type_expression) : type_value result =
) )
let record_access_to_lr : type_value -> type_value AST.label_map -> AST.label -> (type_value * [`Left | `Right]) list result = fun ty tym ind -> let record_access_to_lr : type_value -> type_value AST.label_map -> AST.label -> (type_value * [`Left | `Right]) list result = fun ty tym ind ->
let tys = Stage_common.Helpers.kv_list_of_record_or_tuple tym in let tys = Ast_typed.Helpers.kv_list_of_record_or_tuple tym in
let node_tv = Append_tree.of_list tys in let node_tv = Append_tree.of_list tys in
let%bind path = let%bind path =
let aux (i , _) = i = ind in let aux (i , _) = i = ind in
@ -313,7 +428,7 @@ and transpile_annotated_expression (ae:AST.expression) : expression result =
) )
| E_record m -> ( | E_record m -> (
(*list_of_lmap to record_to_list*) (*list_of_lmap to record_to_list*)
let node = Append_tree.of_list @@ Stage_common.Helpers.list_of_record_or_tuple m in let node = Append_tree.of_list @@ Ast_typed.Helpers.list_of_record_or_tuple m in
let aux a b : expression result = let aux a b : expression result =
let%bind a = a in let%bind a = a in
let%bind b = b in let%bind b = b in
@ -330,7 +445,7 @@ and transpile_annotated_expression (ae:AST.expression) : expression result =
let%bind ty_lmap = let%bind ty_lmap =
trace_strong (corner_case ~loc:__LOC__ "not a record") @@ trace_strong (corner_case ~loc:__LOC__ "not a record") @@
get_t_record (get_type_expression record) in get_t_record (get_type_expression record) in
let%bind ty'_lmap = Stage_common.Helpers.bind_map_lmap transpile_type ty_lmap in let%bind ty'_lmap = Ast_typed.Helpers.bind_map_lmap transpile_type ty_lmap in
let%bind path = let%bind path =
trace_strong (corner_case ~loc:__LOC__ "record access") @@ trace_strong (corner_case ~loc:__LOC__ "record access") @@
record_access_to_lr ty' ty'_lmap path in record_access_to_lr ty' ty'_lmap path in
@ -347,7 +462,7 @@ and transpile_annotated_expression (ae:AST.expression) : expression result =
let%bind ty_lmap = let%bind ty_lmap =
trace_strong (corner_case ~loc:__LOC__ "not a record") @@ trace_strong (corner_case ~loc:__LOC__ "not a record") @@
get_t_record (get_type_expression record) in get_t_record (get_type_expression record) in
let%bind ty'_lmap = Stage_common.Helpers.bind_map_lmap transpile_type ty_lmap in let%bind ty'_lmap = Ast_typed.Helpers.bind_map_lmap transpile_type ty_lmap in
let%bind path = let%bind path =
trace_strong (corner_case ~loc:__LOC__ "record access") @@ trace_strong (corner_case ~loc:__LOC__ "record access") @@
record_access_to_lr ty' ty'_lmap path in record_access_to_lr ty' ty'_lmap path in
@ -406,7 +521,7 @@ and transpile_annotated_expression (ae:AST.expression) : expression result =
| (C_MAP_FOLD , lst) -> fold lst | (C_MAP_FOLD , lst) -> fold lst
| _ -> ( | _ -> (
let%bind lst' = bind_map_list (transpile_annotated_expression) lst in let%bind lst' = bind_map_list (transpile_annotated_expression) lst in
return @@ E_constant {cons_name=name;arguments=lst'} return @@ E_constant {cons_name=transpile_constant' name;arguments=lst'}
) )
) )
| E_lambda l -> | E_lambda l ->
@ -420,30 +535,30 @@ and transpile_annotated_expression (ae:AST.expression) : expression result =
| Match_bool {match_true ; match_false} -> | Match_bool {match_true ; match_false} ->
let%bind (t , f) = bind_map_pair (transpile_annotated_expression) (match_true, match_false) in let%bind (t , f) = bind_map_pair (transpile_annotated_expression) (match_true, match_false) in
return @@ E_if_bool (expr', t, f) return @@ E_if_bool (expr', t, f)
| Match_option { match_none; match_some = (name, s, tv) } -> | Match_option { match_none; match_some = {opt; body; tv} } ->
let%bind n = transpile_annotated_expression match_none in let%bind n = transpile_annotated_expression match_none in
let%bind (tv' , s') = let%bind (tv' , s') =
let%bind tv' = transpile_type tv in let%bind tv' = transpile_type tv in
let%bind s' = transpile_annotated_expression s in let%bind s' = transpile_annotated_expression body in
ok (tv' , s') ok (tv' , s')
in in
return @@ E_if_none (expr' , n , ((name , tv') , s')) return @@ E_if_none (expr' , n , ((opt , tv') , s'))
| Match_list { | Match_list {
match_nil ; match_nil ;
match_cons = ((hd_name) , (tl_name), match_cons, ty) ; match_cons = {hd; tl; body; tv} ;
} -> ( } -> (
let%bind nil = transpile_annotated_expression match_nil in let%bind nil = transpile_annotated_expression match_nil in
let%bind cons = let%bind cons =
let%bind ty' = transpile_type ty in let%bind ty' = transpile_type tv in
let%bind match_cons' = transpile_annotated_expression match_cons in let%bind match_cons' = transpile_annotated_expression body in
ok (((hd_name , ty') , (tl_name , ty')) , match_cons') ok (((hd , ty') , (tl , ty')) , match_cons')
in in
return @@ E_if_cons (expr' , nil , cons) return @@ E_if_cons (expr' , nil , cons)
) )
| Match_variant (lst , variant) -> ( | Match_variant {cases ; tv} -> (
let%bind tree = let%bind tree =
trace_strong (corner_case ~loc:__LOC__ "getting lr tree") @@ trace_strong (corner_case ~loc:__LOC__ "getting lr tree") @@
tree_of_sum variant in tree_of_sum tv in
let%bind tree' = match tree with let%bind tree' = match tree with
| Empty -> fail (corner_case ~loc:__LOC__ "match empty variant") | Empty -> fail (corner_case ~loc:__LOC__ "match empty variant")
| Full x -> ok x in | Full x -> ok x in
@ -463,12 +578,14 @@ and transpile_annotated_expression (ae:AST.expression) : expression result =
let rec aux top t = let rec aux top t =
match t with match t with
| ((`Leaf constructor_name) , tv) -> ( | ((`Leaf (AST.Constructor constructor_name)) , tv) -> (
let%bind ((_ , name) , body) = let%bind {constructor=_ ; pattern ; body} =
trace_option (corner_case ~loc:__LOC__ "missing match clause") @@ trace_option (corner_case ~loc:__LOC__ "missing match clause") @@
List.find_opt (fun ((constructor_name' , _) , _) -> constructor_name' = constructor_name) lst in let aux ({constructor = Constructor c ; pattern=_ ; body=_} : AST.matching_content_case) =
(c = constructor_name) in
List.find_opt aux cases in
let%bind body' = transpile_annotated_expression body in let%bind body' = transpile_annotated_expression body in
return @@ E_let_in ((name , tv) , false , top , body') return @@ E_let_in ((pattern , tv) , false , top , body')
) )
| ((`Node (a , b)) , tv) -> | ((`Node (a , b)) , tv) ->
let%bind a' = let%bind a' =
@ -541,30 +658,30 @@ and transpile_recursive {fun_name; fun_type; lambda} =
Match_bool {match_true; match_false} -> Match_bool {match_true; match_false} ->
let%bind (t , f) = bind_map_pair (replace_callback fun_name loop_type shadowed) (match_true, match_false) in let%bind (t , f) = bind_map_pair (replace_callback fun_name loop_type shadowed) (match_true, match_false) in
return @@ E_if_bool (expr, t, f) return @@ E_if_bool (expr, t, f)
| Match_option { match_none; match_some = (name, s, tv) } -> | Match_option { match_none; match_some = {opt; body; tv} } ->
let%bind n = replace_callback fun_name loop_type shadowed match_none in let%bind n = replace_callback fun_name loop_type shadowed match_none in
let%bind (tv' , s') = let%bind (tv' , s') =
let%bind tv' = transpile_type tv in let%bind tv' = transpile_type tv in
let%bind s' = replace_callback fun_name loop_type shadowed s in let%bind s' = replace_callback fun_name loop_type shadowed body in
ok (tv' , s') ok (tv' , s')
in in
return @@ E_if_none (expr , n , ((name , tv') , s')) return @@ E_if_none (expr , n , ((opt , tv') , s'))
| Match_list { | Match_list {
match_nil ; match_nil ;
match_cons = ((hd_name) , (tl_name), match_cons, ty) ; match_cons = { hd ; tl ; body ; tv } ;
} -> ( } -> (
let%bind nil = replace_callback fun_name loop_type shadowed match_nil in let%bind nil = replace_callback fun_name loop_type shadowed match_nil in
let%bind cons = let%bind cons =
let%bind ty' = transpile_type ty in let%bind ty' = transpile_type tv in
let%bind match_cons' = replace_callback fun_name loop_type shadowed match_cons in let%bind match_cons' = replace_callback fun_name loop_type shadowed body in
ok (((hd_name , ty') , (tl_name , ty')) , match_cons') ok (((hd , ty') , (tl , ty')) , match_cons')
in in
return @@ E_if_cons (expr , nil , cons) return @@ E_if_cons (expr , nil , cons)
) )
| Match_variant (lst , variant) -> ( | Match_variant {cases;tv} -> (
let%bind tree = let%bind tree =
trace_strong (corner_case ~loc:__LOC__ "getting lr tree") @@ trace_strong (corner_case ~loc:__LOC__ "getting lr tree") @@
tree_of_sum variant in tree_of_sum tv in
let%bind tree' = match tree with let%bind tree' = match tree with
| Empty -> fail (corner_case ~loc:__LOC__ "match empty variant") | Empty -> fail (corner_case ~loc:__LOC__ "match empty variant")
| Full x -> ok x in | Full x -> ok x in
@ -583,12 +700,14 @@ and transpile_recursive {fun_name; fun_type; lambda} =
in in
let rec aux top t = let rec aux top t =
match t with match t with
| ((`Leaf constructor_name) , tv) -> ( | ((`Leaf (AST.Constructor constructor_name)) , tv) -> (
let%bind ((_ , name) , body) = let%bind {constructor=_ ; pattern ; body} =
trace_option (corner_case ~loc:__LOC__ "missing match clause") @@ trace_option (corner_case ~loc:__LOC__ "missing match clause") @@
List.find_opt (fun ((constructor_name' , _) , _) -> constructor_name' = constructor_name) lst in let aux ({constructor = Constructor c ; pattern=_ ; body=_} : AST.matching_content_case) =
(c = constructor_name) in
List.find_opt aux cases in
let%bind body' = replace_callback fun_name loop_type shadowed body in let%bind body' = replace_callback fun_name loop_type shadowed body in
return @@ E_let_in ((name , tv) , false , top , body') return @@ E_let_in ((pattern , tv) , false , top , body')
) )
| ((`Node (a , b)) , tv) -> | ((`Node (a , b)) , tv) ->
let%bind a' = let%bind a' =
@ -622,12 +741,11 @@ and transpile_recursive {fun_name; fun_type; lambda} =
let transpile_declaration env (d:AST.declaration) : toplevel_statement result = let transpile_declaration env (d:AST.declaration) : toplevel_statement result =
match d with match d with
| Declaration_constant (name,expression, inline, _) -> | Declaration_constant { binder ; expr ; inline ; post_env=_ } ->
let name = name in let%bind expression = transpile_annotated_expression expr in
let%bind expression = transpile_annotated_expression expression in
let tv = Combinators.Expression.get_type expression in let tv = Combinators.Expression.get_type expression in
let env' = Environment.add (name, tv) env in let env' = Environment.add (binder, tv) env in
ok @@ ((name, inline, expression), environment_wrap env env') ok @@ ((binder, inline, expression), environment_wrap env env')
let transpile_program (lst : AST.program) : program result = let transpile_program (lst : AST.program) : program result =
let aux (prev:(toplevel_statement list * Environment.t) result) cur = let aux (prev:(toplevel_statement list * Environment.t) result) cur =

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@ -150,43 +150,42 @@ let rec untranspile (v : value) (t : AST.type_expression) : AST.expression resul
let%bind s' = untranspile s o in let%bind s' = untranspile s o in
ok (e_a_empty_some s') ok (e_a_empty_some s')
) )
| TC_map (k_ty,v_ty)-> ( | TC_map {k=k_ty;v=v_ty}-> (
let%bind map = let%bind map =
trace_strong (wrong_mini_c_value "map" v) @@ trace_strong (wrong_mini_c_value "map" v) @@
get_map v in get_map v in
let%bind map' = let%bind map' =
let aux = fun (k, v) -> let aux = fun (k, v) ->
let%bind k' = untranspile k k_ty in let%bind k = untranspile k k_ty in
let%bind v' = untranspile v v_ty in let%bind v = untranspile v v_ty in
ok (k', v') in ok ({k; v} : AST.map_kv) in
bind_map_list aux map in bind_map_list aux map in
let map' = List.sort_uniq compare map' in let map' = List.sort_uniq compare map' in
let aux = fun prev (k, v) -> let aux = fun prev ({ k ; v } : AST.map_kv) ->
let (k', v') = (k , v ) in return @@ E_constant {cons_name=C_MAP_ADD;arguments=[k ; v ; prev]}
return @@ E_constant {cons_name=C_MAP_ADD;arguments=[k' ; v' ; prev]}
in in
let%bind init = return @@ E_constant {cons_name=C_MAP_EMPTY;arguments=[]} in let%bind init = return @@ E_constant {cons_name=C_MAP_EMPTY;arguments=[]} in
bind_fold_right_list aux init map' bind_fold_right_list aux init map'
) )
| TC_big_map (k_ty, v_ty) -> ( | TC_big_map {k=k_ty; v=v_ty} -> (
let%bind big_map = let%bind big_map =
trace_strong (wrong_mini_c_value "big_map" v) @@ trace_strong (wrong_mini_c_value "big_map" v) @@
get_big_map v in get_big_map v in
let%bind big_map' = let%bind big_map' =
let aux = fun (k, v) -> let aux = fun (k, v) ->
let%bind k' = untranspile k k_ty in let%bind k = untranspile k k_ty in
let%bind v' = untranspile v v_ty in let%bind v = untranspile v v_ty in
ok (k', v') in ok ({k; v} : AST.map_kv) in
bind_map_list aux big_map in bind_map_list aux big_map in
let big_map' = List.sort_uniq compare big_map' in let big_map' = List.sort_uniq compare big_map' in
let aux = fun prev (k, v) -> let aux = fun prev ({ k ; v } : AST.map_kv) ->
return @@ E_constant {cons_name=C_MAP_ADD;arguments=[k ; v ; prev]} return @@ E_constant {cons_name=C_MAP_ADD;arguments=[k ; v ; prev]}
in in
let%bind init = return @@ E_constant {cons_name=C_BIG_MAP_EMPTY;arguments=[]} in let%bind init = return @@ E_constant {cons_name=C_BIG_MAP_EMPTY;arguments=[]} in
bind_fold_right_list aux init big_map' bind_fold_right_list aux init big_map'
) )
| TC_map_or_big_map (_, _) -> fail @@ corner_case ~loc:"untranspiler" "TC_map_or_big_map t should not be present in mini-c" | TC_map_or_big_map _ -> fail @@ corner_case ~loc:"untranspiler" "TC_map_or_big_map t should not be present in mini-c"
| TC_michelson_or (l_ty, r_ty) -> ( | TC_michelson_or {l=l_ty; r=r_ty} -> (
let%bind v' = bind_map_or (get_left , get_right) v in let%bind v' = bind_map_or (get_left , get_right) v in
( match v' with ( match v' with
| D_left l -> | D_left l ->
@ -244,7 +243,7 @@ let rec untranspile (v : value) (t : AST.type_expression) : AST.expression resul
let%bind sub = untranspile v tv in let%bind sub = untranspile v tv in
return (E_constructor {constructor=Constructor name;element=sub}) return (E_constructor {constructor=Constructor name;element=sub})
| T_record m -> | T_record m ->
let lst = Stage_common.Helpers.kv_list_of_record_or_tuple m in let lst = Ast_typed.Helpers.kv_list_of_record_or_tuple m in
let%bind node = match Append_tree.of_list lst with let%bind node = match Append_tree.of_list lst with
| Empty -> fail @@ corner_case ~loc:__LOC__ "empty record" | Empty -> fail @@ corner_case ~loc:__LOC__ "empty record"
| Full t -> ok t in | Full t -> ok t in

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@ -120,7 +120,7 @@ module Errors = struct
let data = [ let data = [
("expression" , ("expression" ,
(** TODO: The labelled arguments should be flowing from the CLI. *) (** TODO: The labelled arguments should be flowing from the CLI. *)
thunk @@ Parser.Cameligo.ParserLog.expr_to_string thunk @@ Parser_cameligo.ParserLog.expr_to_string
~offsets:true ~mode:`Point t)] ~offsets:true ~mode:`Point t)]
in error ~data title message in error ~data title message
@ -996,7 +996,7 @@ and compile_cases : type a . (Raw.pattern * a) list -> (a, unit) matching_conten
(** TODO: The labelled arguments should be flowing from the CLI. *) (** TODO: The labelled arguments should be flowing from the CLI. *)
let content () = let content () =
Printf.sprintf "Pattern : %s" Printf.sprintf "Pattern : %s"
(Parser.Cameligo.ParserLog.pattern_to_string (Parser_cameligo.ParserLog.pattern_to_string
~offsets:true ~mode:`Point x) in ~offsets:true ~mode:`Point x) in
error title content error title content
in in

View File

@ -68,11 +68,11 @@ module Wrap = struct
let (csttag, args) = Core.(match type_operator with let (csttag, args) = Core.(match type_operator with
| TC_option o -> (C_option, [o]) | TC_option o -> (C_option, [o])
| TC_set s -> (C_set, [s]) | TC_set s -> (C_set, [s])
| TC_map ( k , v ) -> (C_map, [k;v]) | TC_map { k ; v } -> (C_map, [k;v])
| TC_big_map ( k , v) -> (C_big_map, [k;v]) | TC_big_map { k ; v } -> (C_big_map, [k;v])
| TC_map_or_big_map ( k , v) -> (C_map, [k;v]) | TC_map_or_big_map { k ; v } -> (C_map, [k;v])
| TC_michelson_or ( k , v) -> (C_michelson_or, [k;v]) | TC_michelson_or { l; r } -> (C_michelson_or, [l;r])
| TC_arrow ( arg , ret ) -> (C_arrow, [ arg ; ret ]) | TC_arrow { type1 ; type2 } -> (C_arrow, [ type1 ; type2 ])
| TC_list l -> (C_list, [l]) | TC_list l -> (C_list, [l])
| TC_contract c -> (C_contract, [c]) | TC_contract c -> (C_contract, [c])
) )

View File

@ -163,6 +163,274 @@ end
open Errors open Errors
let convert_constructor' (I.Constructor c) = O.Constructor c
let unconvert_constructor' (O.Constructor c) = I.Constructor c
let convert_label (I.Label c) = O.Label c
let unconvert_label (O.Label c) = I.Label c
let convert_type_constant : I.type_constant -> O.type_constant = function
| TC_unit -> TC_unit
| TC_string -> TC_string
| TC_bytes -> TC_bytes
| TC_nat -> TC_nat
| TC_int -> TC_int
| TC_mutez -> TC_mutez
| TC_bool -> TC_bool
| TC_operation -> TC_operation
| TC_address -> TC_address
| TC_key -> TC_key
| TC_key_hash -> TC_key_hash
| TC_chain_id -> TC_chain_id
| TC_signature -> TC_signature
| TC_timestamp -> TC_timestamp
| TC_void -> TC_void
let unconvert_type_constant : O.type_constant -> I.type_constant = function
| TC_unit -> TC_unit
| TC_string -> TC_string
| TC_bytes -> TC_bytes
| TC_nat -> TC_nat
| TC_int -> TC_int
| TC_mutez -> TC_mutez
| TC_bool -> TC_bool
| TC_operation -> TC_operation
| TC_address -> TC_address
| TC_key -> TC_key
| TC_key_hash -> TC_key_hash
| TC_chain_id -> TC_chain_id
| TC_signature -> TC_signature
| TC_timestamp -> TC_timestamp
| TC_void -> TC_void
let convert_constant' : I.constant' -> O.constant' = function
| C_INT -> C_INT
| C_UNIT -> C_UNIT
| C_NIL -> C_NIL
| C_NOW -> C_NOW
| C_IS_NAT -> C_IS_NAT
| C_SOME -> C_SOME
| C_NONE -> C_NONE
| C_ASSERTION -> C_ASSERTION
| C_ASSERT_INFERRED -> C_ASSERT_INFERRED
| C_FAILWITH -> C_FAILWITH
| C_UPDATE -> C_UPDATE
(* Loops *)
| C_ITER -> C_ITER
| C_FOLD_WHILE -> C_FOLD_WHILE
| C_FOLD_CONTINUE -> C_FOLD_CONTINUE
| C_FOLD_STOP -> C_FOLD_STOP
| C_LOOP_LEFT -> C_LOOP_LEFT
| C_LOOP_CONTINUE -> C_LOOP_CONTINUE
| C_LOOP_STOP -> C_LOOP_STOP
| C_FOLD -> C_FOLD
(* MATH *)
| C_NEG -> C_NEG
| C_ABS -> C_ABS
| C_ADD -> C_ADD
| C_SUB -> C_SUB
| C_MUL -> C_MUL
| C_EDIV -> C_EDIV
| C_DIV -> C_DIV
| C_MOD -> C_MOD
(* LOGIC *)
| C_NOT -> C_NOT
| C_AND -> C_AND
| C_OR -> C_OR
| C_XOR -> C_XOR
| C_LSL -> C_LSL
| C_LSR -> C_LSR
(* COMPARATOR *)
| C_EQ -> C_EQ
| C_NEQ -> C_NEQ
| C_LT -> C_LT
| C_GT -> C_GT
| C_LE -> C_LE
| C_GE -> C_GE
(* Bytes/ String *)
| C_SIZE -> C_SIZE
| C_CONCAT -> C_CONCAT
| C_SLICE -> C_SLICE
| C_BYTES_PACK -> C_BYTES_PACK
| C_BYTES_UNPACK -> C_BYTES_UNPACK
| C_CONS -> C_CONS
(* Pair *)
| C_PAIR -> C_PAIR
| C_CAR -> C_CAR
| C_CDR -> C_CDR
| C_LEFT -> C_LEFT
| C_RIGHT -> C_RIGHT
(* Set *)
| C_SET_EMPTY -> C_SET_EMPTY
| C_SET_LITERAL -> C_SET_LITERAL
| C_SET_ADD -> C_SET_ADD
| C_SET_REMOVE -> C_SET_REMOVE
| C_SET_ITER -> C_SET_ITER
| C_SET_FOLD -> C_SET_FOLD
| C_SET_MEM -> C_SET_MEM
(* List *)
| C_LIST_EMPTY -> C_LIST_EMPTY
| C_LIST_LITERAL -> C_LIST_LITERAL
| C_LIST_ITER -> C_LIST_ITER
| C_LIST_MAP -> C_LIST_MAP
| C_LIST_FOLD -> C_LIST_FOLD
(* Maps *)
| C_MAP -> C_MAP
| C_MAP_EMPTY -> C_MAP_EMPTY
| C_MAP_LITERAL -> C_MAP_LITERAL
| C_MAP_GET -> C_MAP_GET
| C_MAP_GET_FORCE -> C_MAP_GET_FORCE
| C_MAP_ADD -> C_MAP_ADD
| C_MAP_REMOVE -> C_MAP_REMOVE
| C_MAP_UPDATE -> C_MAP_UPDATE
| C_MAP_ITER -> C_MAP_ITER
| C_MAP_MAP -> C_MAP_MAP
| C_MAP_FOLD -> C_MAP_FOLD
| C_MAP_MEM -> C_MAP_MEM
| C_MAP_FIND -> C_MAP_FIND
| C_MAP_FIND_OPT -> C_MAP_FIND_OPT
(* Big Maps *)
| C_BIG_MAP -> C_BIG_MAP
| C_BIG_MAP_EMPTY -> C_BIG_MAP_EMPTY
| C_BIG_MAP_LITERAL -> C_BIG_MAP_LITERAL
(* Crypto *)
| C_SHA256 -> C_SHA256
| C_SHA512 -> C_SHA512
| C_BLAKE2b -> C_BLAKE2b
| C_HASH -> C_HASH
| C_HASH_KEY -> C_HASH_KEY
| C_CHECK_SIGNATURE -> C_CHECK_SIGNATURE
| C_CHAIN_ID -> C_CHAIN_ID
(* Blockchain *)
| C_CALL -> C_CALL
| C_CONTRACT -> C_CONTRACT
| C_CONTRACT_OPT -> C_CONTRACT_OPT
| C_CONTRACT_ENTRYPOINT -> C_CONTRACT_ENTRYPOINT
| C_CONTRACT_ENTRYPOINT_OPT -> C_CONTRACT_ENTRYPOINT_OPT
| C_AMOUNT -> C_AMOUNT
| C_BALANCE -> C_BALANCE
| C_SOURCE -> C_SOURCE
| C_SENDER -> C_SENDER
| C_ADDRESS -> C_ADDRESS
| C_SELF -> C_SELF
| C_SELF_ADDRESS -> C_SELF_ADDRESS
| C_IMPLICIT_ACCOUNT -> C_IMPLICIT_ACCOUNT
| C_SET_DELEGATE -> C_SET_DELEGATE
| C_CREATE_CONTRACT -> C_CREATE_CONTRACT
let unconvert_constant' : O.constant' -> I.constant' = function
| C_INT -> C_INT
| C_UNIT -> C_UNIT
| C_NIL -> C_NIL
| C_NOW -> C_NOW
| C_IS_NAT -> C_IS_NAT
| C_SOME -> C_SOME
| C_NONE -> C_NONE
| C_ASSERTION -> C_ASSERTION
| C_ASSERT_INFERRED -> C_ASSERT_INFERRED
| C_FAILWITH -> C_FAILWITH
| C_UPDATE -> C_UPDATE
(* Loops *)
| C_ITER -> C_ITER
| C_FOLD_WHILE -> C_FOLD_WHILE
| C_FOLD_CONTINUE -> C_FOLD_CONTINUE
| C_FOLD_STOP -> C_FOLD_STOP
| C_LOOP_LEFT -> C_LOOP_LEFT
| C_LOOP_CONTINUE -> C_LOOP_CONTINUE
| C_LOOP_STOP -> C_LOOP_STOP
| C_FOLD -> C_FOLD
(* MATH *)
| C_NEG -> C_NEG
| C_ABS -> C_ABS
| C_ADD -> C_ADD
| C_SUB -> C_SUB
| C_MUL -> C_MUL
| C_EDIV -> C_EDIV
| C_DIV -> C_DIV
| C_MOD -> C_MOD
(* LOGIC *)
| C_NOT -> C_NOT
| C_AND -> C_AND
| C_OR -> C_OR
| C_XOR -> C_XOR
| C_LSL -> C_LSL
| C_LSR -> C_LSR
(* COMPARATOR *)
| C_EQ -> C_EQ
| C_NEQ -> C_NEQ
| C_LT -> C_LT
| C_GT -> C_GT
| C_LE -> C_LE
| C_GE -> C_GE
(* Bytes/ String *)
| C_SIZE -> C_SIZE
| C_CONCAT -> C_CONCAT
| C_SLICE -> C_SLICE
| C_BYTES_PACK -> C_BYTES_PACK
| C_BYTES_UNPACK -> C_BYTES_UNPACK
| C_CONS -> C_CONS
(* Pair *)
| C_PAIR -> C_PAIR
| C_CAR -> C_CAR
| C_CDR -> C_CDR
| C_LEFT -> C_LEFT
| C_RIGHT -> C_RIGHT
(* Set *)
| C_SET_EMPTY -> C_SET_EMPTY
| C_SET_LITERAL -> C_SET_LITERAL
| C_SET_ADD -> C_SET_ADD
| C_SET_REMOVE -> C_SET_REMOVE
| C_SET_ITER -> C_SET_ITER
| C_SET_FOLD -> C_SET_FOLD
| C_SET_MEM -> C_SET_MEM
(* List *)
| C_LIST_EMPTY -> C_LIST_EMPTY
| C_LIST_LITERAL -> C_LIST_LITERAL
| C_LIST_ITER -> C_LIST_ITER
| C_LIST_MAP -> C_LIST_MAP
| C_LIST_FOLD -> C_LIST_FOLD
(* Maps *)
| C_MAP -> C_MAP
| C_MAP_EMPTY -> C_MAP_EMPTY
| C_MAP_LITERAL -> C_MAP_LITERAL
| C_MAP_GET -> C_MAP_GET
| C_MAP_GET_FORCE -> C_MAP_GET_FORCE
| C_MAP_ADD -> C_MAP_ADD
| C_MAP_REMOVE -> C_MAP_REMOVE
| C_MAP_UPDATE -> C_MAP_UPDATE
| C_MAP_ITER -> C_MAP_ITER
| C_MAP_MAP -> C_MAP_MAP
| C_MAP_FOLD -> C_MAP_FOLD
| C_MAP_MEM -> C_MAP_MEM
| C_MAP_FIND -> C_MAP_FIND
| C_MAP_FIND_OPT -> C_MAP_FIND_OPT
(* Big Maps *)
| C_BIG_MAP -> C_BIG_MAP
| C_BIG_MAP_EMPTY -> C_BIG_MAP_EMPTY
| C_BIG_MAP_LITERAL -> C_BIG_MAP_LITERAL
(* Crypto *)
| C_SHA256 -> C_SHA256
| C_SHA512 -> C_SHA512
| C_BLAKE2b -> C_BLAKE2b
| C_HASH -> C_HASH
| C_HASH_KEY -> C_HASH_KEY
| C_CHECK_SIGNATURE -> C_CHECK_SIGNATURE
| C_CHAIN_ID -> C_CHAIN_ID
(* Blockchain *)
| C_CALL -> C_CALL
| C_CONTRACT -> C_CONTRACT
| C_CONTRACT_OPT -> C_CONTRACT_OPT
| C_CONTRACT_ENTRYPOINT -> C_CONTRACT_ENTRYPOINT
| C_CONTRACT_ENTRYPOINT_OPT -> C_CONTRACT_ENTRYPOINT_OPT
| C_AMOUNT -> C_AMOUNT
| C_BALANCE -> C_BALANCE
| C_SOURCE -> C_SOURCE
| C_SENDER -> C_SENDER
| C_ADDRESS -> C_ADDRESS
| C_SELF -> C_SELF
| C_SELF_ADDRESS -> C_SELF_ADDRESS
| C_IMPLICIT_ACCOUNT -> C_IMPLICIT_ACCOUNT
| C_SET_DELEGATE -> C_SET_DELEGATE
| C_CREATE_CONTRACT -> C_CREATE_CONTRACT
(* (*
let rec type_program (p:I.program) : O.program result = let rec type_program (p:I.program) : O.program result =
let aux (e, acc:(environment * O.declaration Location.wrap list)) (d:I.declaration Location.wrap) = let aux (e, acc:(environment * O.declaration Location.wrap list)) (d:I.declaration Location.wrap) =
@ -187,16 +455,16 @@ let rec type_declaration env state : I.declaration -> (environment * Solver.stat
let%bind tv = evaluate_type env type_expression in let%bind tv = evaluate_type env type_expression in
let env' = Environment.add_type (type_name) tv env in let env' = Environment.add_type (type_name) tv env in
ok (env', state , None) ok (env', state , None)
| Declaration_constant (name , tv_opt , inline, expression) -> ( | Declaration_constant (binder , tv_opt , inline, expression) -> (
(* (*
Determine the type of the expression and add it to the environment Determine the type of the expression and add it to the environment
*) *)
let%bind tv'_opt = bind_map_option (evaluate_type env) tv_opt in let%bind tv'_opt = bind_map_option (evaluate_type env) tv_opt in
let%bind (ae' , state') = let%bind (expr , state') =
trace (constant_declaration_error name expression tv'_opt) @@ trace (constant_declaration_error binder expression tv'_opt) @@
type_expression env state expression in type_expression env state expression in
let env' = Environment.add_ez_ae name ae' env in let post_env = Environment.add_ez_ae binder expr env in
ok (env', state' , Some (O.Declaration_constant (name, ae', inline, env') )) ok (post_env, state' , Some (O.Declaration_constant { binder ; expr ; inline ; post_env} ))
) )
and type_match : environment -> Solver.state -> O.type_expression -> I.matching_expr -> I.expression -> Location.t -> (O.matching_expr * Solver.state) result = and type_match : environment -> Solver.state -> O.type_expression -> I.matching_expr -> I.expression -> Location.t -> (O.matching_expr * Solver.state) result =
@ -209,14 +477,14 @@ and type_match : environment -> Solver.state -> O.type_expression -> I.matching_
let%bind (match_false , state'') = type_expression e state' match_false in let%bind (match_false , state'') = type_expression e state' match_false in
ok (O.Match_bool {match_true ; match_false} , state'') ok (O.Match_bool {match_true ; match_false} , state'')
| Match_option {match_none ; match_some} -> | Match_option {match_none ; match_some} ->
let%bind t_opt = let%bind tv =
trace_strong (match_error ~expected:i ~actual:t loc) trace_strong (match_error ~expected:i ~actual:t loc)
@@ get_t_option t in @@ get_t_option t in
let%bind (match_none , state') = type_expression e state match_none in let%bind (match_none , state') = type_expression e state match_none in
let (n, b, _) = match_some in let (opt, b, _) = match_some in
let e' = Environment.add_ez_binder n t_opt e in let e' = Environment.add_ez_binder opt tv e in
let%bind (b' , state'') = type_expression e' state' b in let%bind (body , state'') = type_expression e' state' b in
ok (O.Match_option {match_none ; match_some = (n, b', t_opt)} , state'') ok (O.Match_option {match_none ; match_some = { opt; body; tv}} , state'')
| Match_list {match_nil ; match_cons} -> | Match_list {match_nil ; match_cons} ->
let%bind t_elt = let%bind t_elt =
trace_strong (match_error ~expected:i ~actual:t loc) trace_strong (match_error ~expected:i ~actual:t loc)
@ -225,19 +493,19 @@ and type_match : environment -> Solver.state -> O.type_expression -> I.matching_
let (hd, tl, b, _) = match_cons in let (hd, tl, b, _) = match_cons in
let e' = Environment.add_ez_binder hd t_elt e in let e' = Environment.add_ez_binder hd t_elt e in
let e' = Environment.add_ez_binder tl t e' in let e' = Environment.add_ez_binder tl t e' in
let%bind (b' , state'') = type_expression e' state' b in let%bind (body , state'') = type_expression e' state' b in
ok (O.Match_list {match_nil ; match_cons = (hd, tl, b',t)} , state'') ok (O.Match_list {match_nil ; match_cons = {hd; tl; body;tv=t}} , state'')
| Match_tuple ((lst, b),_) -> | Match_tuple ((vars, b),_) ->
let%bind t_tuple = let%bind tvs =
trace_strong (match_error ~expected:i ~actual:t loc) trace_strong (match_error ~expected:i ~actual:t loc)
@@ get_t_tuple t in @@ get_t_tuple t in
let%bind lst' = let%bind lst' =
generic_try (match_tuple_wrong_arity t_tuple lst loc) generic_try (match_tuple_wrong_arity tvs vars loc)
@@ (fun () -> List.combine lst t_tuple) in @@ (fun () -> List.combine vars tvs) in
let aux prev (name, tv) = Environment.add_ez_binder name tv prev in let aux prev (name, tv) = Environment.add_ez_binder name tv prev in
let e' = List.fold_left aux e lst' in let e' = List.fold_left aux e lst' in
let%bind (b' , state') = type_expression e' state b in let%bind (body , state') = type_expression e' state b in
ok (O.Match_tuple ((lst, b'), t_tuple) , state') ok (O.Match_tuple {vars ; body ; tvs} , state')
| Match_variant (lst,_) -> | Match_variant (lst,_) ->
let%bind variant_opt = let%bind variant_opt =
let aux acc ((constructor_name , _) , _) = let aux acc ((constructor_name , _) , _) =
@ -267,8 +535,8 @@ and type_match : environment -> Solver.state -> O.type_expression -> I.matching_
let%bind variant_cases' = let%bind variant_cases' =
trace (match_error ~expected:i ~actual:t loc) trace (match_error ~expected:i ~actual:t loc)
@@ Ast_typed.Combinators.get_t_sum variant in @@ Ast_typed.Combinators.get_t_sum variant in
let variant_cases = List.map fst @@ I.CMap.to_kv_list variant_cases' in let variant_cases = List.map fst @@ O.CMap.to_kv_list variant_cases' in
let match_cases = List.map (Function.compose fst fst) lst in let match_cases = List.map (fun x -> convert_constructor' @@ fst @@ fst x) lst in
let test_case = fun c -> let test_case = fun c ->
Assert.assert_true (List.mem c match_cases) Assert.assert_true (List.mem c match_cases)
in in
@ -280,17 +548,18 @@ and type_match : environment -> Solver.state -> O.type_expression -> I.matching_
Assert.assert_true List.(length variant_cases = length match_cases) in Assert.assert_true List.(length variant_cases = length match_cases) in
ok () ok ()
in in
let%bind (state'' , lst') = let%bind (state'' , cases) =
let aux state ((constructor_name , name) , b) = let aux state ((constructor_name , pattern) , b) =
let%bind (constructor , _) = let%bind (constructor , _) =
trace_option (unbound_constructor e constructor_name loc) @@ trace_option (unbound_constructor e constructor_name loc) @@
Environment.get_constructor constructor_name e in Environment.get_constructor constructor_name e in
let e' = Environment.add_ez_binder name constructor e in let e' = Environment.add_ez_binder pattern constructor e in
let%bind (b' , state') = type_expression e' state b in let%bind (body , state') = type_expression e' state b in
ok (state' , ((constructor_name , name) , b')) let constructor = convert_constructor' constructor_name in
ok (state' , ({constructor ; pattern ; body = body} : O.matching_content_case))
in in
bind_fold_map_list aux state lst in bind_fold_map_list aux state lst in
ok (O.Match_variant (lst' , variant) , state'') ok (O.Match_variant {cases ; tv=variant } , state'')
(* (*
Recursively search the type_expression and return a result containing the Recursively search the type_expression and return a result containing the
@ -307,17 +576,17 @@ and evaluate_type (e:environment) (t:I.type_expression) : O.type_expression resu
let aux k v prev = let aux k v prev =
let%bind prev' = prev in let%bind prev' = prev in
let%bind v' = evaluate_type e v in let%bind v' = evaluate_type e v in
ok @@ I.CMap.add k v' prev' ok @@ O.CMap.add (convert_constructor' k) v' prev'
in in
let%bind m = I.CMap.fold aux m (ok I.CMap.empty) in let%bind m = I.CMap.fold aux m (ok O.CMap.empty) in
return (T_sum m) return (T_sum m)
| T_record m -> | T_record m ->
let aux k v prev = let aux k v prev =
let%bind prev' = prev in let%bind prev' = prev in
let%bind v' = evaluate_type e v in let%bind v' = evaluate_type e v in
ok @@ I.LMap.add k v' prev' ok @@ O.LMap.add (convert_label k) v' prev'
in in
let%bind m = I.LMap.fold aux m (ok I.LMap.empty) in let%bind m = I.LMap.fold aux m (ok O.LMap.empty) in
return (T_record m) return (T_record m)
| T_variable name -> | T_variable name ->
let%bind tv = let%bind tv =
@ -325,7 +594,7 @@ and evaluate_type (e:environment) (t:I.type_expression) : O.type_expression resu
@@ Environment.get_type_opt (name) e in @@ Environment.get_type_opt (name) e in
ok tv ok tv
| T_constant cst -> | T_constant cst ->
return (T_constant cst) return (T_constant (convert_type_constant cst))
| T_operator opt -> | T_operator opt ->
let%bind opt = match opt with let%bind opt = match opt with
| TC_set s -> | TC_set s ->
@ -340,26 +609,26 @@ and evaluate_type (e:environment) (t:I.type_expression) : O.type_expression resu
| TC_map (k,v) -> | TC_map (k,v) ->
let%bind k = evaluate_type e k in let%bind k = evaluate_type e k in
let%bind v = evaluate_type e v in let%bind v = evaluate_type e v in
ok @@ O.TC_map (k,v) ok @@ O.TC_map {k;v}
| TC_big_map (k,v) -> | TC_big_map (k,v) ->
let%bind k = evaluate_type e k in let%bind k = evaluate_type e k in
let%bind v = evaluate_type e v in let%bind v = evaluate_type e v in
ok @@ O.TC_big_map (k,v) ok @@ O.TC_big_map {k;v}
| TC_map_or_big_map (k,v) -> | TC_map_or_big_map (k,v) ->
let%bind k = evaluate_type e k in let%bind k = evaluate_type e k in
let%bind v = evaluate_type e v in let%bind v = evaluate_type e v in
ok @@ O.TC_map_or_big_map (k,v) ok @@ O.TC_map_or_big_map {k;v}
| TC_michelson_or (l,r) -> | TC_michelson_or (l,r) ->
let%bind l = evaluate_type e l in let%bind l = evaluate_type e l in
let%bind r = evaluate_type e r in let%bind r = evaluate_type e r in
ok @@ O.TC_michelson_or (l,r) ok @@ O.TC_michelson_or {l;r}
| TC_contract c -> | TC_contract c ->
let%bind c = evaluate_type e c in let%bind c = evaluate_type e c in
ok @@ O.TC_contract c ok @@ O.TC_contract c
| TC_arrow ( arg , ret ) -> | TC_arrow ( arg , ret ) ->
let%bind arg' = evaluate_type e arg in let%bind arg' = evaluate_type e arg in
let%bind ret' = evaluate_type e ret in let%bind ret' = evaluate_type e ret in
ok @@ O.TC_arrow ( arg' , ret' ) ok @@ O.TC_arrow { type1=arg' ; type2=ret' }
in in
return (T_operator (opt)) return (T_operator (opt))
@ -461,6 +730,7 @@ and type_expression : environment -> Solver.state -> ?tv_opt:O.type_expression -
* ) *) * ) *)
| E_record_accessor {record;path} -> ( | E_record_accessor {record;path} -> (
let%bind (base' , state') = type_expression e state record in let%bind (base' , state') = type_expression e state record in
let path = convert_label path in
let wrapped = Wrap.access_label ~base:base'.type_expression ~label:path in let wrapped = Wrap.access_label ~base:base'.type_expression ~label:path in
return_wrapped (E_record_accessor {record=base';path}) state' wrapped return_wrapped (E_record_accessor {record=base';path}) state' wrapped
) )
@ -481,28 +751,30 @@ and type_expression : environment -> Solver.state -> ?tv_opt:O.type_expression -
let%bind (expr' , state') = type_expression e state element in let%bind (expr' , state') = type_expression e state element in
let%bind _assert = O.assert_type_expression_eq (expr'.type_expression, c_tv) in let%bind _assert = O.assert_type_expression_eq (expr'.type_expression, c_tv) in
let wrapped = Wrap.constructor expr'.type_expression c_tv sum_tv in let wrapped = Wrap.constructor expr'.type_expression c_tv sum_tv in
let constructor = convert_constructor' constructor in
return_wrapped (E_constructor {constructor; element=expr'}) state' wrapped return_wrapped (E_constructor {constructor; element=expr'}) state' wrapped
(* Record *) (* Record *)
| E_record m -> | E_record m ->
let aux (acc, state) k expr = let aux (acc, state) k expr =
let%bind (expr' , state') = type_expression e state expr in let%bind (expr' , state') = type_expression e state expr in
ok (I.LMap.add k expr' acc , state') ok (O.LMap.add (convert_label k) expr' acc , state')
in in
let%bind (m' , state') = Stage_common.Helpers.bind_fold_lmap aux (ok (I.LMap.empty , state)) m in let%bind (m' , state') = Stage_common.Helpers.bind_fold_lmap aux (ok (O.LMap.empty , state)) m in
let wrapped = Wrap.record (I.LMap.map get_type_expression m') in let wrapped = Wrap.record (O.LMap.map get_type_expression m') in
return_wrapped (E_record m') state' wrapped return_wrapped (E_record m') state' wrapped
| E_record_update {record; path; update} -> | E_record_update {record; path; update} ->
let%bind (record, state) = type_expression e state record in let%bind (record, state) = type_expression e state record in
let%bind (update,state) = type_expression e state update in let%bind (update,state) = type_expression e state update in
let wrapped = get_type_expression record in let wrapped = get_type_expression record in
let path = convert_label path in
let%bind (wrapped,tv) = let%bind (wrapped,tv) =
match wrapped.type_content with match wrapped.type_content with
| T_record record -> ( | T_record record -> (
let field_op = I.LMap.find_opt path record in let field_op = O.LMap.find_opt path record in
match field_op with match field_op with
| Some tv -> ok (record,tv) | Some tv -> ok (record,tv)
| None -> failwith @@ Format.asprintf "field %a is not part of record" Stage_common.PP.label path | None -> failwith @@ Format.asprintf "field %a is not part of record" O.PP.label path
) )
| _ -> failwith "Update an expression which is not a record" | _ -> failwith "Update an expression which is not a record"
in in
@ -510,6 +782,7 @@ and type_expression : environment -> Solver.state -> ?tv_opt:O.type_expression -
return_wrapped (E_record_update {record; path; update}) state (Wrap.record wrapped) return_wrapped (E_record_update {record; path; update}) state (Wrap.record wrapped)
(* Data-structure *) (* Data-structure *)
(* | E_lambda { (* | E_lambda {
* binder ; * binder ;
* input_type ; * input_type ;
@ -558,7 +831,6 @@ and type_expression : environment -> Solver.state -> ?tv_opt:O.type_expression -
let wrapped = Wrap.application f'.type_expression args.type_expression in let wrapped = Wrap.application f'.type_expression args.type_expression in
return_wrapped (E_application {lamb=f';args}) state'' wrapped return_wrapped (E_application {lamb=f';args}) state'' wrapped
(* Advanced *) (* Advanced *)
(* | E_matching (ex, m) -> ( (* | E_matching (ex, m) -> (
* let%bind ex' = type_expression e ex in * let%bind ex' = type_expression e ex in
@ -608,13 +880,13 @@ and type_expression : environment -> Solver.state -> ?tv_opt:O.type_expression -
let%bind (ex' , state') = type_expression e state matchee in let%bind (ex' , state') = type_expression e state matchee in
let%bind (m' , state'') = type_match e state' ex'.type_expression cases ae ae.location in let%bind (m' , state'') = type_match e state' ex'.type_expression cases ae ae.location in
let tvs = let tvs =
let aux (cur:(O.expression, O.type_expression) O.matching_content) = let aux (cur : O.matching_expr) =
match cur with match cur with
| Match_bool { match_true ; match_false } -> [ match_true ; match_false ] | Match_bool { match_true ; match_false } -> [ match_true ; match_false ]
| Match_list { match_nil ; match_cons = (_ , _ , match_cons, _) } -> [ match_nil ; match_cons ] | Match_list { match_nil ; match_cons = { hd=_ ; tl=_ ; body ; tv=_} } -> [ match_nil ; body ]
| Match_option { match_none ; match_some = (_ , match_some, _) } -> [ match_none ; match_some ] | Match_option { match_none ; match_some = {opt=_; body; tv=_} } -> [ match_none ; body ]
| Match_tuple ((_ , match_tuple), _) -> [ match_tuple ] | Match_tuple { vars=_ ; body ; tvs=_ } -> [ body ]
| Match_variant (lst , _) -> List.map snd lst in | Match_variant { cases ; tv=_ } -> List.map (fun ({constructor=_; pattern=_; body} : O.matching_content_case) -> body) cases in
List.map get_type_expression @@ aux m' in List.map get_type_expression @@ aux m' in
let%bind () = match tvs with let%bind () = match tvs with
[] -> fail @@ match_empty_variant cases ae.location [] -> fail @@ match_empty_variant cases ae.location
@ -667,7 +939,7 @@ and type_expression : environment -> Solver.state -> ?tv_opt:O.type_expression -
return_wrapped (E_recursive {fun_name;fun_type;lambda}) state wrapped return_wrapped (E_recursive {fun_name;fun_type;lambda}) state wrapped
| E_constant {cons_name=name; arguments=lst} -> | E_constant {cons_name=name; arguments=lst} ->
let () = ignore (name , lst) in let name = convert_constant' name in
let%bind t = Operators.Typer.Operators_types.constant_type name in let%bind t = Operators.Typer.Operators_types.constant_type name in
let aux acc expr = let aux acc expr =
let (lst , state) = acc in let (lst , state) = acc in
@ -705,6 +977,7 @@ and type_lambda e state {
(* Advanced *) (* Advanced *)
and type_constant (name:I.constant') (lst:O.type_expression list) (tv_opt:O.type_expression option) : (O.constant' * O.type_expression) result = and type_constant (name:I.constant') (lst:O.type_expression list) (tv_opt:O.type_expression option) : (O.constant' * O.type_expression) result =
let name = convert_constant' name in
let%bind typer = Operators.Typer.constant_typers name in let%bind typer = Operators.Typer.constant_typers name in
let%bind tv = typer lst tv_opt in let%bind tv = typer lst tv_opt in
ok(name, tv) ok(name, tv)
@ -814,13 +1087,21 @@ let rec untype_type_expression (t:O.type_expression) : (I.type_expression) resul
(* TODO: or should we use t.core if present? *) (* TODO: or should we use t.core if present? *)
let%bind t = match t.type_content with let%bind t = match t.type_content with
| O.T_sum x -> | O.T_sum x ->
let%bind x' = Stage_common.Helpers.bind_map_cmap untype_type_expression x in let aux k v acc =
let%bind acc = acc in
let%bind v' = untype_type_expression v in
ok @@ I.CMap.add (unconvert_constructor' k) v' acc in
let%bind x' = O.CMap.fold aux x (ok I.CMap.empty) in
ok @@ I.T_sum x' ok @@ I.T_sum x'
| O.T_record x -> | O.T_record x ->
let%bind x' = Stage_common.Helpers.bind_map_lmap untype_type_expression x in let aux k v acc =
let%bind acc = acc in
let%bind v' = untype_type_expression v in
ok @@ I.LMap.add (unconvert_label k) v' acc in
let%bind x' = O.LMap.fold aux x (ok I.LMap.empty) in
ok @@ I.T_record x' ok @@ I.T_record x'
| O.T_constant (tag) -> | O.T_constant (tag) ->
ok @@ I.T_constant (tag) ok @@ I.T_constant (unconvert_type_constant tag)
| O.T_variable (name) -> ok @@ I.T_variable (name) (* TODO: is this the right conversion? *) | O.T_variable (name) -> ok @@ I.T_variable (name) (* TODO: is this the right conversion? *)
| O.T_arrow {type1;type2} -> | O.T_arrow {type1;type2} ->
let%bind type1 = untype_type_expression type1 in let%bind type1 = untype_type_expression type1 in
@ -837,23 +1118,23 @@ let rec untype_type_expression (t:O.type_expression) : (I.type_expression) resul
| O.TC_set t -> | O.TC_set t ->
let%bind t' = untype_type_expression t in let%bind t' = untype_type_expression t in
ok @@ I.TC_set t' ok @@ I.TC_set t'
| O.TC_map (k,v) -> | O.TC_map {k;v} ->
let%bind k = untype_type_expression k in let%bind k = untype_type_expression k in
let%bind v = untype_type_expression v in let%bind v = untype_type_expression v in
ok @@ I.TC_map (k,v) ok @@ I.TC_map (k,v)
| O.TC_big_map (k,v) -> | O.TC_big_map {k;v} ->
let%bind k = untype_type_expression k in let%bind k = untype_type_expression k in
let%bind v = untype_type_expression v in let%bind v = untype_type_expression v in
ok @@ I.TC_big_map (k,v) ok @@ I.TC_big_map (k,v)
| O.TC_map_or_big_map (k,v) -> | O.TC_map_or_big_map {k;v} ->
let%bind k = untype_type_expression k in let%bind k = untype_type_expression k in
let%bind v = untype_type_expression v in let%bind v = untype_type_expression v in
ok @@ I.TC_map_or_big_map (k,v) ok @@ I.TC_map_or_big_map (k,v)
| O.TC_michelson_or (l,r) -> | O.TC_michelson_or {l;r} ->
let%bind l = untype_type_expression l in let%bind l = untype_type_expression l in
let%bind r = untype_type_expression r in let%bind r = untype_type_expression r in
ok @@ I.TC_michelson_or (l,r) ok @@ I.TC_michelson_or (l,r)
| O.TC_arrow ( arg , ret ) -> | O.TC_arrow { type1=arg ; type2=ret } ->
let%bind arg' = untype_type_expression arg in let%bind arg' = untype_type_expression arg in
let%bind ret' = untype_type_expression ret in let%bind ret' = untype_type_expression ret in
ok @@ I.TC_arrow ( arg' , ret' ) ok @@ I.TC_arrow ( arg' , ret' )
@ -904,7 +1185,7 @@ let rec untype_expression (e:O.expression) : (I.expression) result =
return (e_literal l) return (e_literal l)
| E_constant {cons_name;arguments} -> | E_constant {cons_name;arguments} ->
let%bind lst' = bind_map_list untype_expression arguments in let%bind lst' = bind_map_list untype_expression arguments in
return (e_constant cons_name lst') return (e_constant (unconvert_constant' cons_name) lst')
| E_variable (n) -> | E_variable (n) ->
return (e_variable (n)) return (e_variable (n))
| E_application {lamb;args} -> | E_application {lamb;args} ->
@ -920,8 +1201,8 @@ let rec untype_expression (e:O.expression) : (I.expression) result =
let Constructor n = constructor in let Constructor n = constructor in
return (e_constructor n p') return (e_constructor n p')
| E_record r -> | E_record r ->
let r = LMap.to_kv_list r in let r = O.LMap.to_kv_list r in
let%bind r' = bind_map_list (fun (k,e) -> let%bind e = untype_expression e in ok (k,e)) r in let%bind r' = bind_map_list (fun (O.Label k,e) -> let%bind e = untype_expression e in ok (I.Label k,e)) r in
return (e_record @@ LMap.of_list r') return (e_record @@ LMap.of_list r')
| E_record_accessor {record; path} -> | E_record_accessor {record; path} ->
let%bind r' = untype_expression record in let%bind r' = untype_expression record in
@ -930,7 +1211,7 @@ let rec untype_expression (e:O.expression) : (I.expression) result =
| E_record_update {record; path; update} -> | E_record_update {record; path; update} ->
let%bind r' = untype_expression record in let%bind r' = untype_expression record in
let%bind e = untype_expression update in let%bind e = untype_expression update in
return (e_record_update r' path e) return (e_record_update r' (unconvert_label path) e)
| E_matching {matchee;cases} -> | E_matching {matchee;cases} ->
let%bind ae' = untype_expression matchee in let%bind ae' = untype_expression matchee in
let%bind m' = untype_matching untype_expression cases in let%bind m' = untype_matching untype_expression cases in
@ -964,22 +1245,22 @@ and untype_matching : (O.expression -> I.expression result) -> O.matching_expr -
let%bind match_true = f match_true in let%bind match_true = f match_true in
let%bind match_false = f match_false in let%bind match_false = f match_false in
ok @@ Match_bool {match_true ; match_false} ok @@ Match_bool {match_true ; match_false}
| Match_tuple ((lst, b),_) -> | Match_tuple { vars ; body ; tvs=_ } ->
let%bind b = f b in let%bind b = f body in
ok @@ I.Match_tuple ((lst, b),[]) ok @@ I.Match_tuple ((vars, b),[])
| Match_option {match_none ; match_some = (v, some,_)} -> | Match_option {match_none ; match_some = {opt; body;tv=_}} ->
let%bind match_none = f match_none in let%bind match_none = f match_none in
let%bind some = f some in let%bind some = f body in
let match_some = v, some, () in let match_some = opt, some, () in
ok @@ Match_option {match_none ; match_some} ok @@ Match_option {match_none ; match_some}
| Match_list {match_nil ; match_cons = (hd_name, tl_name, cons,_)} -> | Match_list {match_nil ; match_cons = {hd;tl;body;tv=_}} ->
let%bind match_nil = f match_nil in let%bind match_nil = f match_nil in
let%bind cons = f cons in let%bind cons = f body in
let match_cons = hd_name , tl_name , cons, () in let match_cons = hd , tl , cons, () in
ok @@ Match_list {match_nil ; match_cons} ok @@ Match_list {match_nil ; match_cons}
| Match_variant (lst , _) -> | Match_variant { cases ; tv=_ } ->
let aux ((a,b),c) = let aux ({constructor;pattern;body} : O.matching_content_case) =
let%bind c' = f c in let%bind body = f body in
ok ((a,b),c') in ok ((unconvert_constructor' constructor,pattern),body) in
let%bind lst' = bind_map_list aux lst in let%bind lst' = bind_map_list aux cases in
ok @@ Match_variant (lst',()) ok @@ Match_variant (lst',())

View File

@ -217,6 +217,256 @@ module Errors = struct
end end
open Errors open Errors
let convert_constructor' (I.Constructor c) = O.Constructor c
let unconvert_constructor' (O.Constructor c) = I.Constructor c
let convert_label (I.Label c) = O.Label c
let convert_type_constant : I.type_constant -> O.type_constant = function
| TC_unit -> TC_unit
| TC_string -> TC_string
| TC_bytes -> TC_bytes
| TC_nat -> TC_nat
| TC_int -> TC_int
| TC_mutez -> TC_mutez
| TC_bool -> TC_bool
| TC_operation -> TC_operation
| TC_address -> TC_address
| TC_key -> TC_key
| TC_key_hash -> TC_key_hash
| TC_chain_id -> TC_chain_id
| TC_signature -> TC_signature
| TC_timestamp -> TC_timestamp
| TC_void -> TC_void
let convert_constant' : I.constant' -> O.constant' = function
| C_INT -> C_INT
| C_UNIT -> C_UNIT
| C_NIL -> C_NIL
| C_NOW -> C_NOW
| C_IS_NAT -> C_IS_NAT
| C_SOME -> C_SOME
| C_NONE -> C_NONE
| C_ASSERTION -> C_ASSERTION
| C_ASSERT_INFERRED -> C_ASSERT_INFERRED
| C_FAILWITH -> C_FAILWITH
| C_UPDATE -> C_UPDATE
(* Loops *)
| C_ITER -> C_ITER
| C_FOLD_WHILE -> C_FOLD_WHILE
| C_FOLD_CONTINUE -> C_FOLD_CONTINUE
| C_FOLD_STOP -> C_FOLD_STOP
| C_LOOP_LEFT -> C_LOOP_LEFT
| C_LOOP_CONTINUE -> C_LOOP_CONTINUE
| C_LOOP_STOP -> C_LOOP_STOP
| C_FOLD -> C_FOLD
(* MATH *)
| C_NEG -> C_NEG
| C_ABS -> C_ABS
| C_ADD -> C_ADD
| C_SUB -> C_SUB
| C_MUL -> C_MUL
| C_EDIV -> C_EDIV
| C_DIV -> C_DIV
| C_MOD -> C_MOD
(* LOGIC *)
| C_NOT -> C_NOT
| C_AND -> C_AND
| C_OR -> C_OR
| C_XOR -> C_XOR
| C_LSL -> C_LSL
| C_LSR -> C_LSR
(* COMPARATOR *)
| C_EQ -> C_EQ
| C_NEQ -> C_NEQ
| C_LT -> C_LT
| C_GT -> C_GT
| C_LE -> C_LE
| C_GE -> C_GE
(* Bytes/ String *)
| C_SIZE -> C_SIZE
| C_CONCAT -> C_CONCAT
| C_SLICE -> C_SLICE
| C_BYTES_PACK -> C_BYTES_PACK
| C_BYTES_UNPACK -> C_BYTES_UNPACK
| C_CONS -> C_CONS
(* Pair *)
| C_PAIR -> C_PAIR
| C_CAR -> C_CAR
| C_CDR -> C_CDR
| C_LEFT -> C_LEFT
| C_RIGHT -> C_RIGHT
(* Set *)
| C_SET_EMPTY -> C_SET_EMPTY
| C_SET_LITERAL -> C_SET_LITERAL
| C_SET_ADD -> C_SET_ADD
| C_SET_REMOVE -> C_SET_REMOVE
| C_SET_ITER -> C_SET_ITER
| C_SET_FOLD -> C_SET_FOLD
| C_SET_MEM -> C_SET_MEM
(* List *)
| C_LIST_EMPTY -> C_LIST_EMPTY
| C_LIST_LITERAL -> C_LIST_LITERAL
| C_LIST_ITER -> C_LIST_ITER
| C_LIST_MAP -> C_LIST_MAP
| C_LIST_FOLD -> C_LIST_FOLD
(* Maps *)
| C_MAP -> C_MAP
| C_MAP_EMPTY -> C_MAP_EMPTY
| C_MAP_LITERAL -> C_MAP_LITERAL
| C_MAP_GET -> C_MAP_GET
| C_MAP_GET_FORCE -> C_MAP_GET_FORCE
| C_MAP_ADD -> C_MAP_ADD
| C_MAP_REMOVE -> C_MAP_REMOVE
| C_MAP_UPDATE -> C_MAP_UPDATE
| C_MAP_ITER -> C_MAP_ITER
| C_MAP_MAP -> C_MAP_MAP
| C_MAP_FOLD -> C_MAP_FOLD
| C_MAP_MEM -> C_MAP_MEM
| C_MAP_FIND -> C_MAP_FIND
| C_MAP_FIND_OPT -> C_MAP_FIND_OPT
(* Big Maps *)
| C_BIG_MAP -> C_BIG_MAP
| C_BIG_MAP_EMPTY -> C_BIG_MAP_EMPTY
| C_BIG_MAP_LITERAL -> C_BIG_MAP_LITERAL
(* Crypto *)
| C_SHA256 -> C_SHA256
| C_SHA512 -> C_SHA512
| C_BLAKE2b -> C_BLAKE2b
| C_HASH -> C_HASH
| C_HASH_KEY -> C_HASH_KEY
| C_CHECK_SIGNATURE -> C_CHECK_SIGNATURE
| C_CHAIN_ID -> C_CHAIN_ID
(* Blockchain *)
| C_CALL -> C_CALL
| C_CONTRACT -> C_CONTRACT
| C_CONTRACT_OPT -> C_CONTRACT_OPT
| C_CONTRACT_ENTRYPOINT -> C_CONTRACT_ENTRYPOINT
| C_CONTRACT_ENTRYPOINT_OPT -> C_CONTRACT_ENTRYPOINT_OPT
| C_AMOUNT -> C_AMOUNT
| C_BALANCE -> C_BALANCE
| C_SOURCE -> C_SOURCE
| C_SENDER -> C_SENDER
| C_ADDRESS -> C_ADDRESS
| C_SELF -> C_SELF
| C_SELF_ADDRESS -> C_SELF_ADDRESS
| C_IMPLICIT_ACCOUNT -> C_IMPLICIT_ACCOUNT
| C_SET_DELEGATE -> C_SET_DELEGATE
| C_CREATE_CONTRACT -> C_CREATE_CONTRACT
let unconvert_constant' : O.constant' -> I.constant' = function
| C_INT -> C_INT
| C_UNIT -> C_UNIT
| C_NIL -> C_NIL
| C_NOW -> C_NOW
| C_IS_NAT -> C_IS_NAT
| C_SOME -> C_SOME
| C_NONE -> C_NONE
| C_ASSERTION -> C_ASSERTION
| C_ASSERT_INFERRED -> C_ASSERT_INFERRED
| C_FAILWITH -> C_FAILWITH
| C_UPDATE -> C_UPDATE
(* Loops *)
| C_ITER -> C_ITER
| C_FOLD_WHILE -> C_FOLD_WHILE
| C_FOLD_CONTINUE -> C_FOLD_CONTINUE
| C_FOLD_STOP -> C_FOLD_STOP
| C_LOOP_LEFT -> C_LOOP_LEFT
| C_LOOP_CONTINUE -> C_LOOP_CONTINUE
| C_LOOP_STOP -> C_LOOP_STOP
| C_FOLD -> C_FOLD
(* MATH *)
| C_NEG -> C_NEG
| C_ABS -> C_ABS
| C_ADD -> C_ADD
| C_SUB -> C_SUB
| C_MUL -> C_MUL
| C_EDIV -> C_EDIV
| C_DIV -> C_DIV
| C_MOD -> C_MOD
(* LOGIC *)
| C_NOT -> C_NOT
| C_AND -> C_AND
| C_OR -> C_OR
| C_XOR -> C_XOR
| C_LSL -> C_LSL
| C_LSR -> C_LSR
(* COMPARATOR *)
| C_EQ -> C_EQ
| C_NEQ -> C_NEQ
| C_LT -> C_LT
| C_GT -> C_GT
| C_LE -> C_LE
| C_GE -> C_GE
(* Bytes/ String *)
| C_SIZE -> C_SIZE
| C_CONCAT -> C_CONCAT
| C_SLICE -> C_SLICE
| C_BYTES_PACK -> C_BYTES_PACK
| C_BYTES_UNPACK -> C_BYTES_UNPACK
| C_CONS -> C_CONS
(* Pair *)
| C_PAIR -> C_PAIR
| C_CAR -> C_CAR
| C_CDR -> C_CDR
| C_LEFT -> C_LEFT
| C_RIGHT -> C_RIGHT
(* Set *)
| C_SET_EMPTY -> C_SET_EMPTY
| C_SET_LITERAL -> C_SET_LITERAL
| C_SET_ADD -> C_SET_ADD
| C_SET_REMOVE -> C_SET_REMOVE
| C_SET_ITER -> C_SET_ITER
| C_SET_FOLD -> C_SET_FOLD
| C_SET_MEM -> C_SET_MEM
(* List *)
| C_LIST_EMPTY -> C_LIST_EMPTY
| C_LIST_LITERAL -> C_LIST_LITERAL
| C_LIST_ITER -> C_LIST_ITER
| C_LIST_MAP -> C_LIST_MAP
| C_LIST_FOLD -> C_LIST_FOLD
(* Maps *)
| C_MAP -> C_MAP
| C_MAP_EMPTY -> C_MAP_EMPTY
| C_MAP_LITERAL -> C_MAP_LITERAL
| C_MAP_GET -> C_MAP_GET
| C_MAP_GET_FORCE -> C_MAP_GET_FORCE
| C_MAP_ADD -> C_MAP_ADD
| C_MAP_REMOVE -> C_MAP_REMOVE
| C_MAP_UPDATE -> C_MAP_UPDATE
| C_MAP_ITER -> C_MAP_ITER
| C_MAP_MAP -> C_MAP_MAP
| C_MAP_FOLD -> C_MAP_FOLD
| C_MAP_MEM -> C_MAP_MEM
| C_MAP_FIND -> C_MAP_FIND
| C_MAP_FIND_OPT -> C_MAP_FIND_OPT
(* Big Maps *)
| C_BIG_MAP -> C_BIG_MAP
| C_BIG_MAP_EMPTY -> C_BIG_MAP_EMPTY
| C_BIG_MAP_LITERAL -> C_BIG_MAP_LITERAL
(* Crypto *)
| C_SHA256 -> C_SHA256
| C_SHA512 -> C_SHA512
| C_BLAKE2b -> C_BLAKE2b
| C_HASH -> C_HASH
| C_HASH_KEY -> C_HASH_KEY
| C_CHECK_SIGNATURE -> C_CHECK_SIGNATURE
| C_CHAIN_ID -> C_CHAIN_ID
(* Blockchain *)
| C_CALL -> C_CALL
| C_CONTRACT -> C_CONTRACT
| C_CONTRACT_OPT -> C_CONTRACT_OPT
| C_CONTRACT_ENTRYPOINT -> C_CONTRACT_ENTRYPOINT
| C_CONTRACT_ENTRYPOINT_OPT -> C_CONTRACT_ENTRYPOINT_OPT
| C_AMOUNT -> C_AMOUNT
| C_BALANCE -> C_BALANCE
| C_SOURCE -> C_SOURCE
| C_SENDER -> C_SENDER
| C_ADDRESS -> C_ADDRESS
| C_SELF -> C_SELF
| C_SELF_ADDRESS -> C_SELF_ADDRESS
| C_IMPLICIT_ACCOUNT -> C_IMPLICIT_ACCOUNT
| C_SET_DELEGATE -> C_SET_DELEGATE
| C_CREATE_CONTRACT -> C_CREATE_CONTRACT
let rec type_program (p:I.program) : (O.program * Solver.state) result = let rec type_program (p:I.program) : (O.program * Solver.state) result =
let aux (e, acc:(environment * O.declaration Location.wrap list)) (d:I.declaration Location.wrap) = let aux (e, acc:(environment * O.declaration Location.wrap list)) (d:I.declaration Location.wrap) =
let%bind ed' = (bind_map_location (type_declaration e (Solver.placeholder_for_state_of_new_typer ()))) d in let%bind ed' = (bind_map_location (type_declaration e (Solver.placeholder_for_state_of_new_typer ()))) d in
@ -236,13 +486,13 @@ and type_declaration env (_placeholder_for_state_of_new_typer : Solver.state) :
let%bind tv = evaluate_type env type_expression in let%bind tv = evaluate_type env type_expression in
let env' = Environment.add_type (type_name) tv env in let env' = Environment.add_type (type_name) tv env in
ok (env', (Solver.placeholder_for_state_of_new_typer ()) , None) ok (env', (Solver.placeholder_for_state_of_new_typer ()) , None)
| Declaration_constant (name , tv_opt , inline, expression) -> ( | Declaration_constant (binder , tv_opt , inline, expression) -> (
let%bind tv'_opt = bind_map_option (evaluate_type env) tv_opt in let%bind tv'_opt = bind_map_option (evaluate_type env) tv_opt in
let%bind ae' = let%bind expr =
trace (constant_declaration_error name expression tv'_opt) @@ trace (constant_declaration_error binder expression tv'_opt) @@
type_expression' ?tv_opt:tv'_opt env expression in type_expression' ?tv_opt:tv'_opt env expression in
let env' = Environment.add_ez_ae name ae' env in let post_env = Environment.add_ez_ae binder expr env in
ok (env', (Solver.placeholder_for_state_of_new_typer ()) , Some (O.Declaration_constant (name,ae', inline, env'))) ok (post_env, (Solver.placeholder_for_state_of_new_typer ()) , Some (O.Declaration_constant { binder ; expr ; inline ; post_env}))
) )
and type_match : (environment -> I.expression -> O.expression result) -> environment -> O.type_expression -> I.matching_expr -> I.expression -> Location.t -> O.matching_expr result = and type_match : (environment -> I.expression -> O.expression result) -> environment -> O.type_expression -> I.matching_expr -> I.expression -> Location.t -> O.matching_expr result =
@ -255,14 +505,14 @@ and type_match : (environment -> I.expression -> O.expression result) -> environ
let%bind match_false = f e match_false in let%bind match_false = f e match_false in
ok (O.Match_bool {match_true ; match_false}) ok (O.Match_bool {match_true ; match_false})
| Match_option {match_none ; match_some} -> | Match_option {match_none ; match_some} ->
let%bind t_opt = let%bind tv =
trace_strong (match_error ~expected:i ~actual:t loc) trace_strong (match_error ~expected:i ~actual:t loc)
@@ get_t_option t in @@ get_t_option t in
let%bind match_none = f e match_none in let%bind match_none = f e match_none in
let (n, b,_) = match_some in let (opt, b,_) = match_some in
let e' = Environment.add_ez_binder n t_opt e in let e' = Environment.add_ez_binder opt tv e in
let%bind b' = f e' b in let%bind body = f e' b in
ok (O.Match_option {match_none ; match_some = (n, b', t_opt)}) ok (O.Match_option {match_none ; match_some = {opt; body; tv}})
| Match_list {match_nil ; match_cons} -> | Match_list {match_nil ; match_cons} ->
let%bind t_elt = let%bind t_elt =
trace_strong (match_error ~expected:i ~actual:t loc) trace_strong (match_error ~expected:i ~actual:t loc)
@ -271,19 +521,19 @@ and type_match : (environment -> I.expression -> O.expression result) -> environ
let (hd, tl, b,_) = match_cons in let (hd, tl, b,_) = match_cons in
let e' = Environment.add_ez_binder hd t_elt e in let e' = Environment.add_ez_binder hd t_elt e in
let e' = Environment.add_ez_binder tl t e' in let e' = Environment.add_ez_binder tl t e' in
let%bind b' = f e' b in let%bind body = f e' b in
ok (O.Match_list {match_nil ; match_cons = (hd, tl, b', t_elt)}) ok (O.Match_list {match_nil ; match_cons = {hd; tl; body; tv=t_elt}})
| Match_tuple ((lst, b),_) -> | Match_tuple ((vars, b),_) ->
let%bind t_tuple = let%bind tvs =
trace_strong (match_error ~expected:i ~actual:t loc) trace_strong (match_error ~expected:i ~actual:t loc)
@@ get_t_tuple t in @@ get_t_tuple t in
let%bind lst' = let%bind vars' =
generic_try (match_tuple_wrong_arity t_tuple lst loc) generic_try (match_tuple_wrong_arity tvs vars loc)
@@ (fun () -> List.combine lst t_tuple) in @@ (fun () -> List.combine vars tvs) in
let aux prev (name, tv) = Environment.add_ez_binder name tv prev in let aux prev (name, tv) = Environment.add_ez_binder name tv prev in
let e' = List.fold_left aux e lst' in let e' = List.fold_left aux e vars' in
let%bind b' = f e' b in let%bind body = f e' b in
ok (O.Match_tuple ((lst, b'),t_tuple)) ok (O.Match_tuple { vars ; body ; tvs})
| Match_variant (lst,_) -> | Match_variant (lst,_) ->
let%bind variant_opt = let%bind variant_opt =
let aux acc ((constructor_name , _) , _) = let aux acc ((constructor_name , _) , _) =
@ -306,15 +556,15 @@ and type_match : (environment -> I.expression -> O.expression result) -> environ
ok acc in ok acc in
trace (simple_info "in match variant") @@ trace (simple_info "in match variant") @@
bind_fold_list aux None lst in bind_fold_list aux None lst in
let%bind variant = let%bind tv =
trace_option (match_empty_variant i loc) @@ trace_option (match_empty_variant i loc) @@
variant_opt in variant_opt in
let%bind () = let%bind () =
let%bind variant_cases' = let%bind variant_cases' =
trace (match_error ~expected:i ~actual:t loc) trace (match_error ~expected:i ~actual:t loc)
@@ Ast_typed.Combinators.get_t_sum variant in @@ Ast_typed.Combinators.get_t_sum tv in
let variant_cases = List.map fst @@ I.CMap.to_kv_list variant_cases' in let variant_cases = List.map fst @@ O.CMap.to_kv_list variant_cases' in
let match_cases = List.map (Function.compose fst fst) lst in let match_cases = List.map (fun x -> convert_constructor' @@ fst @@ fst x) lst in
let test_case = fun c -> let test_case = fun c ->
Assert.assert_true (List.mem c match_cases) Assert.assert_true (List.mem c match_cases)
in in
@ -326,17 +576,18 @@ and type_match : (environment -> I.expression -> O.expression result) -> environ
Assert.assert_true List.(length variant_cases = length match_cases) in Assert.assert_true List.(length variant_cases = length match_cases) in
ok () ok ()
in in
let%bind lst' = let%bind cases =
let aux ((constructor_name , name) , b) = let aux ((constructor_name , pattern) , b) =
let%bind (constructor , _) = let%bind (constructor , _) =
trace_option (unbound_constructor e constructor_name loc) @@ trace_option (unbound_constructor e constructor_name loc) @@
Environment.get_constructor constructor_name e in Environment.get_constructor constructor_name e in
let e' = Environment.add_ez_binder name constructor e in let e' = Environment.add_ez_binder pattern constructor e in
let%bind b' = f e' b in let%bind body = f e' b in
ok ((constructor_name , name) , b') let constructor = convert_constructor' constructor_name in
ok ({constructor ; pattern ; body} : O.matching_content_case)
in in
bind_map_list aux lst in bind_map_list aux lst in
ok (O.Match_variant (lst' , variant)) ok (O.Match_variant { cases ; tv })
and evaluate_type (e:environment) (t:I.type_expression) : O.type_expression result = and evaluate_type (e:environment) (t:I.type_expression) : O.type_expression result =
let return tv' = ok (make_t tv' (Some t)) in let return tv' = ok (make_t tv' (Some t)) in
@ -355,17 +606,17 @@ and evaluate_type (e:environment) (t:I.type_expression) : O.type_expression resu
ok () ok ()
else fail (redundant_constructor e k) else fail (redundant_constructor e k)
| None -> ok () in | None -> ok () in
ok @@ I.CMap.add k v' prev' ok @@ O.CMap.add (convert_constructor' k) v' prev'
in in
let%bind m = I.CMap.fold aux m (ok I.CMap.empty) in let%bind m = I.CMap.fold aux m (ok O.CMap.empty) in
return (T_sum m) return (T_sum m)
| T_record m -> | T_record m ->
let aux k v prev = let aux k v prev =
let%bind prev' = prev in let%bind prev' = prev in
let%bind v' = evaluate_type e v in let%bind v' = evaluate_type e v in
ok @@ I.LMap.add k v' prev' ok @@ O.LMap.add (convert_label k) v' prev'
in in
let%bind m = I.LMap.fold aux m (ok I.LMap.empty) in let%bind m = I.LMap.fold aux m (ok O.LMap.empty) in
return (T_record m) return (T_record m)
| T_variable name -> | T_variable name ->
let%bind tv = let%bind tv =
@ -373,7 +624,7 @@ and evaluate_type (e:environment) (t:I.type_expression) : O.type_expression resu
@@ Environment.get_type_opt (name) e in @@ Environment.get_type_opt (name) e in
ok tv ok tv
| T_constant cst -> | T_constant cst ->
return (T_constant cst) return (T_constant (convert_type_constant cst))
| T_operator opt -> | T_operator opt ->
let%bind opt = match opt with let%bind opt = match opt with
| TC_set s -> | TC_set s ->
@ -388,23 +639,23 @@ and evaluate_type (e:environment) (t:I.type_expression) : O.type_expression resu
| TC_map (k,v) -> | TC_map (k,v) ->
let%bind k = evaluate_type e k in let%bind k = evaluate_type e k in
let%bind v = evaluate_type e v in let%bind v = evaluate_type e v in
ok @@ O.TC_map (k,v) ok @@ O.TC_map {k;v}
| TC_big_map (k,v) -> | TC_big_map (k,v) ->
let%bind k = evaluate_type e k in let%bind k = evaluate_type e k in
let%bind v = evaluate_type e v in let%bind v = evaluate_type e v in
ok @@ O.TC_big_map (k,v) ok @@ O.TC_big_map {k;v}
| TC_map_or_big_map (k,v) -> | TC_map_or_big_map (k,v) ->
let%bind k = evaluate_type e k in let%bind k = evaluate_type e k in
let%bind v = evaluate_type e v in let%bind v = evaluate_type e v in
ok @@ O.TC_map_or_big_map (k,v) ok @@ O.TC_map_or_big_map {k;v}
| TC_michelson_or (l,r) -> | TC_michelson_or (l,r) ->
let%bind l = evaluate_type e l in let%bind l = evaluate_type e l in
let%bind r = evaluate_type e r in let%bind r = evaluate_type e r in
ok @@ O.TC_michelson_or (l,r) ok @@ O.TC_michelson_or {l;r}
| TC_arrow ( arg , ret ) -> | TC_arrow ( arg , ret ) ->
let%bind arg' = evaluate_type e arg in let%bind arg' = evaluate_type e arg in
let%bind ret' = evaluate_type e ret in let%bind ret' = evaluate_type e ret in
ok @@ O.TC_arrow ( arg' , ret' ) ok @@ O.TC_arrow { type1=arg' ; type2=ret' }
| TC_contract c -> | TC_contract c ->
let%bind c = evaluate_type e c in let%bind c = evaluate_type e c in
ok @@ O.TC_contract c ok @@ O.TC_contract c
@ -477,9 +728,9 @@ and type_expression' : environment -> ?tv_opt:O.type_expression -> I.expression
let%bind r_tv = get_t_record prev.type_expression in let%bind r_tv = get_t_record prev.type_expression in
let%bind tv = let%bind tv =
generic_try (bad_record_access property ae prev.type_expression ae.location) generic_try (bad_record_access property ae prev.type_expression ae.location)
@@ (fun () -> I.LMap.find property r_tv) in @@ (fun () -> O.LMap.find (convert_label property) r_tv) in
let location = ae.location in let location = ae.location in
ok @@ make_e ~location (E_record_accessor {record=prev; path=property}) tv e ok @@ make_e ~location (E_record_accessor {record=prev; path=convert_label property}) tv e
in in
let%bind ae = let%bind ae =
trace (simple_info "accessing") @@ aux e' path in trace (simple_info "accessing") @@ aux e' path in
@ -494,7 +745,7 @@ and type_expression' : environment -> ?tv_opt:O.type_expression -> I.expression
let%bind expr' = type_expression' e element in let%bind expr' = type_expression' e element in
( match t.type_content with ( match t.type_content with
| T_sum c -> | T_sum c ->
let ct = I.CMap.find (I.Constructor s) c in let ct = O.CMap.find (O.Constructor s) c in
let%bind _assert = O.assert_type_expression_eq (expr'.type_expression, ct) in let%bind _assert = O.assert_type_expression_eq (expr'.type_expression, ct) in
return (E_constructor {constructor = Constructor s; element=expr'}) t return (E_constructor {constructor = Constructor s; element=expr'}) t
| _ -> simple_fail "ll" | _ -> simple_fail "ll"
@ -515,27 +766,28 @@ and type_expression' : environment -> ?tv_opt:O.type_expression -> I.expression
Environment.get_constructor constructor e in Environment.get_constructor constructor e in
let%bind expr' = type_expression' e element in let%bind expr' = type_expression' e element in
let%bind _assert = O.assert_type_expression_eq (expr'.type_expression, c_tv) in let%bind _assert = O.assert_type_expression_eq (expr'.type_expression, c_tv) in
let constructor = convert_constructor' constructor in
return (E_constructor {constructor; element=expr'}) sum_tv return (E_constructor {constructor; element=expr'}) sum_tv
(* Record *) (* Record *)
| E_record m -> | E_record m ->
let aux prev k expr = let aux prev k expr =
let%bind expr' = type_expression' e expr in let%bind expr' = type_expression' e expr in
ok (I.LMap.add k expr' prev) ok (O.LMap.add (convert_label k) expr' prev)
in in
let%bind m' = Stage_common.Helpers.bind_fold_lmap aux (ok I.LMap.empty) m in let%bind m' = Stage_common.Helpers.bind_fold_lmap aux (ok O.LMap.empty) m in
return (E_record m') (t_record (I.LMap.map get_type_expression m') ()) return (E_record m') (t_record (O.LMap.map get_type_expression m') ())
| E_record_update {record; path; update} -> | E_record_update {record; path; update} ->
let path = convert_label path in
let%bind record = type_expression' e record in let%bind record = type_expression' e record in
let%bind update = type_expression' e update in let%bind update = type_expression' e update in
let wrapped = get_type_expression record in let wrapped = get_type_expression record in
let%bind tv = let%bind tv =
match wrapped.type_content with match wrapped.type_content with
| T_record record -> ( | T_record record -> (
let field_op = I.LMap.find_opt path record in let field_op = O.LMap.find_opt path record in
match field_op with match field_op with
| Some tv -> ok (tv) | Some tv -> ok (tv)
| None -> failwith @@ Format.asprintf "field %a is not part of record %a" Stage_common.PP.label path O.PP.type_expression wrapped | None -> failwith @@ Format.asprintf "field %a is not part of record %a" Ast_typed.PP.label path O.PP.type_expression wrapped
) )
| _ -> failwith "Update an expression which is not a record" | _ -> failwith "Update an expression which is not a record"
in in
@ -562,12 +814,11 @@ and type_expression' : environment -> ?tv_opt:O.type_expression -> I.expression
let tv_out = get_type_expression v_initr in (* this is the output type of the lambda*) let tv_out = get_type_expression v_initr in (* this is the output type of the lambda*)
let%bind input_type = match tv_col.type_content with let%bind input_type = match tv_col.type_content with
| O.T_operator ( TC_list t | TC_set t) -> ok @@ make_t_ez_record (("0",tv_out)::[("1",t)]) | O.T_operator ( TC_list t | TC_set t) -> ok @@ make_t_ez_record (("0",tv_out)::[("1",t)])
| O.T_operator ( TC_map (k,v)| TC_big_map (k,v)) -> ok @@ make_t_ez_record (("0",tv_out)::[("1",make_t_ez_record [("0",k);("1",v)])]) | O.T_operator ( TC_map {k;v}| TC_big_map {k;v}) -> ok @@ make_t_ez_record (("0",tv_out)::[("1",make_t_ez_record [("0",k);("1",v)])])
| _ -> | _ ->
let wtype = Format.asprintf let wtype = Format.asprintf
"Loops over collections expect lists, sets or maps, got type %a" O.PP.type_expression tv_col in "Loops over collections expect lists, sets or maps, got type %a" O.PP.type_expression tv_col in
fail @@ simple_error wtype in fail @@ simple_error wtype in
let lname = lname in
let e' = Environment.add_ez_binder lname input_type e in let e' = Environment.add_ez_binder lname input_type e in
let%bind body = type_expression' ?tv_opt:(Some tv_out) e' result in let%bind body = type_expression' ?tv_opt:(Some tv_out) e' result in
let output_type = body.type_expression in let output_type = body.type_expression in
@ -669,10 +920,10 @@ and type_expression' : environment -> ?tv_opt:O.type_expression -> I.expression
let aux (cur:O.matching_expr) = let aux (cur:O.matching_expr) =
match cur with match cur with
| Match_bool { match_true ; match_false } -> [ match_true ; match_false ] | Match_bool { match_true ; match_false } -> [ match_true ; match_false ]
| Match_list { match_nil ; match_cons = (_ , _ , match_cons, _) } -> [ match_nil ; match_cons ] | Match_list { match_nil ; match_cons = {hd=_ ; tl=_ ; body ; tv=_} } -> [ match_nil ; body ]
| Match_option { match_none ; match_some = (_ , match_some, _) } -> [ match_none ; match_some ] | Match_option { match_none ; match_some = {opt=_ ; body ; tv=_ } } -> [ match_none ; body ]
| Match_tuple ((_ , match_tuple), _) -> [ match_tuple ] | Match_tuple {vars=_;body;tvs=_} -> [ body ]
| Match_variant (lst , _) -> List.map snd lst in | Match_variant {cases; tv=_} -> List.map (fun (c : O.matching_content_case) -> c.body) cases in
List.map get_type_expression @@ aux m' in List.map get_type_expression @@ aux m' in
let aux prec cur = let aux prec cur =
let%bind () = let%bind () =
@ -751,6 +1002,7 @@ and type_lambda e {
and type_constant (name:I.constant') (lst:O.type_expression list) (tv_opt:O.type_expression option) : (O.constant' * O.type_expression) result = and type_constant (name:I.constant') (lst:O.type_expression list) (tv_opt:O.type_expression option) : (O.constant' * O.type_expression) result =
let name = convert_constant' name in
let%bind typer = Operators.Typer.constant_typers name in let%bind typer = Operators.Typer.constant_typers name in
let%bind tv = typer lst tv_opt in let%bind tv = typer lst tv_opt in
ok(name, tv) ok(name, tv)
@ -791,7 +1043,7 @@ let rec untype_expression (e:O.expression) : (I.expression) result =
return (e_literal l) return (e_literal l)
| E_constant {cons_name;arguments} -> | E_constant {cons_name;arguments} ->
let%bind lst' = bind_map_list untype_expression arguments in let%bind lst' = bind_map_list untype_expression arguments in
return (e_constant cons_name lst') return (e_constant (unconvert_constant' cons_name) lst')
| E_variable n -> | E_variable n ->
return (e_variable (n)) return (e_variable (n))
| E_application {lamb;args} -> | E_application {lamb;args} ->
@ -809,17 +1061,17 @@ let rec untype_expression (e:O.expression) : (I.expression) result =
let Constructor n = constructor in let Constructor n = constructor in
return (e_constructor n p') return (e_constructor n p')
| E_record r -> | E_record r ->
let r = LMap.to_kv_list r in let r = O.LMap.to_kv_list r in
let%bind r' = bind_map_list (fun (k,e) -> let%bind e = untype_expression e in ok (k,e)) r in let%bind r' = bind_map_list (fun (O.Label k,e) -> let%bind e = untype_expression e in ok (I.Label k,e)) r in
return (e_record @@ LMap.of_list r') return (e_record @@ LMap.of_list r')
| E_record_accessor {record; path} -> | E_record_accessor {record; path} ->
let%bind r' = untype_expression record in let%bind r' = untype_expression record in
let Label s = path in let Label s = path in
return (e_record_accessor r' s) return (e_record_accessor r' s)
| E_record_update {record=r; path=l; update=e} -> | E_record_update {record=r; path=O.Label l; update=e} ->
let%bind r' = untype_expression r in let%bind r' = untype_expression r in
let%bind e = untype_expression e in let%bind e = untype_expression e in
return (e_record_update r' l e) return (e_record_update r' (I.Label l) e)
| E_matching {matchee;cases} -> | E_matching {matchee;cases} ->
let%bind ae' = untype_expression matchee in let%bind ae' = untype_expression matchee in
let%bind m' = untype_matching untype_expression cases in let%bind m' = untype_matching untype_expression cases in
@ -842,22 +1094,22 @@ and untype_matching : (O.expression -> I.expression result) -> O.matching_expr -
let%bind match_true = f match_true in let%bind match_true = f match_true in
let%bind match_false = f match_false in let%bind match_false = f match_false in
ok @@ Match_bool {match_true ; match_false} ok @@ Match_bool {match_true ; match_false}
| Match_tuple ((lst, b),_) -> | Match_tuple {vars; body;tvs=_} ->
let%bind b = f b in let%bind b = f body in
ok @@ I.Match_tuple ((lst, b),[]) ok @@ I.Match_tuple ((vars, b),[])
| Match_option {match_none ; match_some = (v, some,_)} -> | Match_option {match_none ; match_some = {opt; body ; tv=_}} ->
let%bind match_none = f match_none in let%bind match_none = f match_none in
let%bind some = f some in let%bind some = f body in
let match_some = v, some, () in let match_some = opt, some, () in
ok @@ Match_option {match_none ; match_some} ok @@ Match_option {match_none ; match_some}
| Match_list {match_nil ; match_cons = (hd_name, tl_name, cons,_)} -> | Match_list {match_nil ; match_cons = {hd ; tl ; body ; tv=_}} ->
let%bind match_nil = f match_nil in let%bind match_nil = f match_nil in
let%bind cons = f cons in let%bind cons = f body in
let match_cons = hd_name , tl_name , cons, () in let match_cons = hd , tl , cons, () in
ok @@ Match_list {match_nil ; match_cons} ok @@ Match_list {match_nil ; match_cons}
| Match_variant (lst , _) -> | Match_variant {cases;tv=_} ->
let aux ((a,b),c) = let aux ({constructor;pattern;body} : O.matching_content_case) =
let%bind c' = f c in let%bind c' = f body in
ok ((a,b),c') in ok ((unconvert_constructor' constructor,pattern),c') in
let%bind lst' = bind_map_list aux lst in let%bind lst' = bind_map_list aux cases in
ok @@ Match_variant (lst',()) ok @@ Match_variant (lst',())

View File

@ -1,4 +1,4 @@
open Ast_typed open Ast_typed.Types
open Trace open Trace
type contract_pass_data = { type contract_pass_data = {
@ -63,7 +63,7 @@ let self_typing : contract_pass_data -> expression -> (bool * contract_pass_data
| _ -> fail @@ Errors.entrypoint_annotation_not_literal entrypoint_exp.location in | _ -> fail @@ Errors.entrypoint_annotation_not_literal entrypoint_exp.location in
let%bind entrypoint_t = match dat.contract_type.parameter.type_content with let%bind entrypoint_t = match dat.contract_type.parameter.type_content with
| T_sum cmap -> trace_option (Errors.unmatched_entrypoint entrypoint_exp.location) | T_sum cmap -> trace_option (Errors.unmatched_entrypoint entrypoint_exp.location)
@@ Stage_common.Types.CMap.find_opt (Constructor entrypoint) cmap @@ CMap.find_opt (Constructor entrypoint) cmap
| t -> ok {dat.contract_type.parameter with type_content = t} in | t -> ok {dat.contract_type.parameter with type_content = t} in
let%bind () = let%bind () =
trace_strong (bad_self_err ()) @@ trace_strong (bad_self_err ()) @@

View File

@ -1,9 +1,9 @@
open Ast_typed open Ast_typed
open Trace open Trace
open Stage_common.Helpers open Ast_typed.Helpers
type 'a folder = 'a -> expression -> 'a result type 'a folder = 'a -> expression -> 'a result
let rec fold_expression : 'a folder -> 'a -> expression -> 'a result = fun f init e -> let rec fold_expression : 'a . 'a folder -> 'a -> expression -> 'a result = fun f init e ->
let self = fold_expression f in let self = fold_expression f in
let%bind init' = f init e in let%bind init' = f init e in
match e.expression_content with match e.expression_content with
@ -51,32 +51,32 @@ let rec fold_expression : 'a folder -> 'a -> expression -> 'a result = fun f ini
ok res ok res
) )
and fold_cases : 'a folder -> 'a -> matching_expr -> 'a result = fun f init m -> and fold_cases : 'a . 'a folder -> 'a -> matching_expr -> 'a result = fun f init m ->
match m with match m with
| Match_bool { match_true ; match_false } -> ( | Match_bool { match_true ; match_false } -> (
let%bind res = fold_expression f init match_true in let%bind res = fold_expression f init match_true in
let%bind res = fold_expression f res match_false in let%bind res = fold_expression f res match_false in
ok res ok res
) )
| Match_list { match_nil ; match_cons = (_ , _ , cons, _) } -> ( | Match_list { match_nil ; match_cons = {hd=_; tl=_ ; body; tv=_} } -> (
let%bind res = fold_expression f init match_nil in let%bind res = fold_expression f init match_nil in
let%bind res = fold_expression f res cons in let%bind res = fold_expression f res body in
ok res ok res
) )
| Match_option { match_none ; match_some = (_ , some, _) } -> ( | Match_option { match_none ; match_some = {opt=_; body; tv=_} } -> (
let%bind res = fold_expression f init match_none in let%bind res = fold_expression f init match_none in
let%bind res = fold_expression f res some in let%bind res = fold_expression f res body in
ok res ok res
) )
| Match_tuple ((_ , e), _) -> ( | Match_tuple {vars=_ ; body; tvs=_} -> (
let%bind res = fold_expression f init e in let%bind res = fold_expression f init body in
ok res ok res
) )
| Match_variant (lst, _) -> ( | Match_variant {cases;tv=_} -> (
let aux init' ((_ , _) , e) = let aux init' {constructor=_; pattern=_ ; body} =
let%bind res' = fold_expression f init' e in let%bind res' = fold_expression f init' body in
ok res' in ok res' in
let%bind res = bind_fold_list aux init lst in let%bind res = bind_fold_list aux init cases in
ok res ok res
) )
@ -140,41 +140,41 @@ and map_cases : mapper -> matching_expr -> matching_expr result = fun f m ->
let%bind match_false = map_expression f match_false in let%bind match_false = map_expression f match_false in
ok @@ Match_bool { match_true ; match_false } ok @@ Match_bool { match_true ; match_false }
) )
| Match_list { match_nil ; match_cons = (hd , tl , cons, te) } -> ( | Match_list { match_nil ; match_cons = {hd ; tl ; body ; tv} } -> (
let%bind match_nil = map_expression f match_nil in let%bind match_nil = map_expression f match_nil in
let%bind cons = map_expression f cons in let%bind body = map_expression f body in
ok @@ Match_list { match_nil ; match_cons = (hd , tl , cons, te) } ok @@ Match_list { match_nil ; match_cons = {hd ; tl ; body; tv} }
) )
| Match_option { match_none ; match_some = (name , some, te) } -> ( | Match_option { match_none ; match_some = {opt ; body ; tv } } -> (
let%bind match_none = map_expression f match_none in let%bind match_none = map_expression f match_none in
let%bind some = map_expression f some in let%bind body = map_expression f body in
ok @@ Match_option { match_none ; match_some = (name , some, te) } ok @@ Match_option { match_none ; match_some = { opt ; body ; tv } }
) )
| Match_tuple ((names , e), te) -> ( | Match_tuple { vars ; body ; tvs } -> (
let%bind e' = map_expression f e in let%bind body = map_expression f body in
ok @@ Match_tuple ((names , e'), te) ok @@ Match_tuple { vars ; body ; tvs }
) )
| Match_variant (lst, te) -> ( | Match_variant {cases;tv} -> (
let aux ((a , b) , e) = let aux { constructor ; pattern ; body } =
let%bind e' = map_expression f e in let%bind body = map_expression f body in
ok ((a , b) , e') ok {constructor;pattern;body}
in in
let%bind lst' = bind_map_list aux lst in let%bind cases = bind_map_list aux cases in
ok @@ Match_variant (lst', te) ok @@ Match_variant {cases ; tv}
) )
and map_program : mapper -> program -> program result = fun m p -> and map_program : mapper -> program -> program result = fun m p ->
let aux = fun (x : declaration) -> let aux = fun (x : declaration) ->
match x with match x with
| Declaration_constant (n , e , i, env) -> ( | Declaration_constant {binder; expr ; inline ; post_env} -> (
let%bind e' = map_expression m e in let%bind expr = map_expression m expr in
ok (Declaration_constant (n , e' , i, env)) ok (Declaration_constant {binder; expr ; inline ; post_env})
) )
in in
bind_map_list (bind_map_location aux) p bind_map_list (bind_map_location aux) p
type 'a fold_mapper = 'a -> expression -> (bool * 'a * expression) result type 'a fold_mapper = 'a -> expression -> (bool * 'a * expression) result
let rec fold_map_expression : 'a fold_mapper -> 'a -> expression -> ('a * expression) result = fun f a e -> let rec fold_map_expression : 'a . 'a fold_mapper -> 'a -> expression -> ('a * expression) result = fun f a e ->
let self = fold_map_expression f in let self = fold_map_expression f in
let%bind (continue, init',e') = f a e in let%bind (continue, init',e') = f a e in
if (not continue) then ok(init',e') if (not continue) then ok(init',e')
@ -228,42 +228,42 @@ let rec fold_map_expression : 'a fold_mapper -> 'a -> expression -> ('a * expres
) )
| E_literal _ | E_variable _ as e' -> ok (init', return e') | E_literal _ | E_variable _ as e' -> ok (init', return e')
and fold_map_cases : 'a fold_mapper -> 'a -> matching_expr -> ('a * matching_expr) result = fun f init m -> and fold_map_cases : 'a . 'a fold_mapper -> 'a -> matching_expr -> ('a * matching_expr) result = fun f init m ->
match m with match m with
| Match_bool { match_true ; match_false } -> ( | Match_bool { match_true ; match_false } -> (
let%bind (init, match_true) = fold_map_expression f init match_true in let%bind (init, match_true) = fold_map_expression f init match_true in
let%bind (init, match_false) = fold_map_expression f init match_false in let%bind (init, match_false) = fold_map_expression f init match_false in
ok @@ (init, Match_bool { match_true ; match_false }) ok @@ (init, Match_bool { match_true ; match_false })
) )
| Match_list { match_nil ; match_cons = (hd , tl , cons, te) } -> ( | Match_list { match_nil ; match_cons = { hd ; tl ; body ; tv } } -> (
let%bind (init, match_nil) = fold_map_expression f init match_nil in let%bind (init, match_nil) = fold_map_expression f init match_nil in
let%bind (init, cons) = fold_map_expression f init cons in let%bind (init, body) = fold_map_expression f init body in
ok @@ (init, Match_list { match_nil ; match_cons = (hd , tl , cons, te) }) ok @@ (init, Match_list { match_nil ; match_cons = { hd ; tl ; body ; tv } })
) )
| Match_option { match_none ; match_some = (name , some, te) } -> ( | Match_option { match_none ; match_some = { opt ; body ; tv } } -> (
let%bind (init, match_none) = fold_map_expression f init match_none in let%bind (init, match_none) = fold_map_expression f init match_none in
let%bind (init, some) = fold_map_expression f init some in let%bind (init, body) = fold_map_expression f init body in
ok @@ (init, Match_option { match_none ; match_some = (name , some, te) }) ok @@ (init, Match_option { match_none ; match_some = { opt ; body ; tv } })
) )
| Match_tuple ((names , e), te) -> ( | Match_tuple { vars ; body ; tvs } -> (
let%bind (init, e') = fold_map_expression f init e in let%bind (init, body) = fold_map_expression f init body in
ok @@ (init, Match_tuple ((names , e'), te)) ok @@ (init, Match_tuple {vars ; body ; tvs })
) )
| Match_variant (lst, te) -> ( | Match_variant {cases ; tv} -> (
let aux init ((a , b) , e) = let aux init {constructor ; pattern ; body} =
let%bind (init,e') = fold_map_expression f init e in let%bind (init, body) = fold_map_expression f init body in
ok (init, ((a , b) , e')) ok (init, {constructor; pattern ; body})
in in
let%bind (init,lst') = bind_fold_map_list aux init lst in let%bind (init,cases) = bind_fold_map_list aux init cases in
ok @@ (init, Match_variant (lst', te)) ok @@ (init, Match_variant {cases ; tv})
) )
and fold_map_program : 'a fold_mapper -> 'a -> program -> ('a * program) result = fun m init p -> and fold_map_program : 'a . 'a fold_mapper -> 'a -> program -> ('a * program) result = fun m init p ->
let aux = fun (acc,acc_prg) (x : declaration Location.wrap) -> let aux = fun (acc,acc_prg) (x : declaration Location.wrap) ->
match Location.unwrap x with match Location.unwrap x with
| Declaration_constant (v , e , i, env) -> ( | Declaration_constant {binder ; expr ; inline ; post_env} -> (
let%bind (acc',e') = fold_map_expression m acc e in let%bind (acc', expr) = fold_map_expression m acc expr in
let wrap_content = Declaration_constant (v , e' , i, env) in let wrap_content = Declaration_constant {binder ; expr ; inline ; post_env} in
ok (acc', List.append acc_prg [{x with wrap_content}]) ok (acc', List.append acc_prg [{x with wrap_content}])
) )
in in
@ -315,28 +315,28 @@ type contract_type = {
let fetch_contract_type : string -> program -> contract_type result = fun main_fname program -> let fetch_contract_type : string -> program -> contract_type result = fun main_fname program ->
let main_decl = List.rev @@ List.filter let main_decl = List.rev @@ List.filter
(fun declt -> (fun declt ->
let (Declaration_constant (v , _ , _ , _)) = Location.unwrap declt in let (Declaration_constant { binder ; expr=_ ; inline=_ ; post_env=_ }) = Location.unwrap declt in
String.equal (Var.to_name v) main_fname String.equal (Var.to_name binder) main_fname
) )
program program
in in
match main_decl with match main_decl with
| (hd::_) -> ( | (hd::_) -> (
let (Declaration_constant (_,e,_,_)) = Location.unwrap hd in let (Declaration_constant { binder=_ ; expr ; inline=_ ; post_env=_ }) = Location.unwrap hd in
match e.type_expression.type_content with match expr.type_expression.type_content with
| T_arrow {type1 ; type2} -> ( | T_arrow {type1 ; type2} -> (
match type1.type_content , type2.type_content with match type1.type_content , type2.type_content with
| T_record tin , T_record tout when (is_tuple_lmap tin) && (is_tuple_lmap tout) -> | T_record tin , T_record tout when (is_tuple_lmap tin) && (is_tuple_lmap tout) ->
let%bind (parameter,storage) = Stage_common.Helpers.get_pair tin in let%bind (parameter,storage) = Ast_typed.Helpers.get_pair tin in
let%bind (listop,storage') = Stage_common.Helpers.get_pair tout in let%bind (listop,storage') = Ast_typed.Helpers.get_pair tout in
let%bind () = trace_strong (Errors.expected_list_operation main_fname listop e) @@ let%bind () = trace_strong (Errors.expected_list_operation main_fname listop expr) @@
Ast_typed.assert_t_list_operation listop in Ast_typed.assert_t_list_operation listop in
let%bind () = trace_strong (Errors.expected_same main_fname storage storage' e) @@ let%bind () = trace_strong (Errors.expected_same main_fname storage storage' expr) @@
Ast_typed.assert_type_expression_eq (storage,storage') in Ast_typed.assert_type_expression_eq (storage,storage') in
(* TODO: on storage/parameter : assert_storable, assert_passable ? *) (* TODO: on storage/parameter : assert_storable, assert_passable ? *)
ok { parameter ; storage } ok { parameter ; storage }
| _ -> fail @@ Errors.bad_contract_io main_fname e | _ -> fail @@ Errors.bad_contract_io main_fname expr
) )
| _ -> fail @@ Errors.bad_contract_io main_fname e | _ -> fail @@ Errors.bad_contract_io main_fname expr
) )
| [] -> simple_fail ("Entrypoint '"^main_fname^"' does not exist") | [] -> simple_fail ("Entrypoint '"^main_fname^"' does not exist")

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@ -15,15 +15,15 @@ end
let rec check_no_nested_bigmap is_in_bigmap e = let rec check_no_nested_bigmap is_in_bigmap e =
match e.type_content with match e.type_content with
| T_operator (TC_big_map (_, _)) when is_in_bigmap -> | T_operator (TC_big_map _) when is_in_bigmap ->
fail @@ Errors.no_nested_bigmap fail @@ Errors.no_nested_bigmap
| T_operator (TC_big_map (key, value)) -> | T_operator (TC_big_map {k ; v}) ->
let%bind _ = check_no_nested_bigmap false key in let%bind _ = check_no_nested_bigmap false k in
let%bind _ = check_no_nested_bigmap true value in let%bind _ = check_no_nested_bigmap true v in
ok () ok ()
| T_operator (TC_map_or_big_map (key, value)) -> | T_operator (TC_map_or_big_map {k ; v}) ->
let%bind _ = check_no_nested_bigmap false key in let%bind _ = check_no_nested_bigmap false k in
let%bind _ = check_no_nested_bigmap true value in let%bind _ = check_no_nested_bigmap true v in
ok () ok ()
| T_operator (TC_contract t) | T_operator (TC_contract t)
| T_operator (TC_option t) | T_operator (TC_option t)
@ -31,17 +31,17 @@ let rec check_no_nested_bigmap is_in_bigmap e =
| T_operator (TC_set t) -> | T_operator (TC_set t) ->
let%bind _ = check_no_nested_bigmap is_in_bigmap t in let%bind _ = check_no_nested_bigmap is_in_bigmap t in
ok () ok ()
| T_operator (TC_map (a, b)) -> | T_operator (TC_map { k ; v }) ->
let%bind _ = check_no_nested_bigmap is_in_bigmap a in let%bind _ = check_no_nested_bigmap is_in_bigmap k in
let%bind _ = check_no_nested_bigmap is_in_bigmap b in let%bind _ = check_no_nested_bigmap is_in_bigmap v in
ok () ok ()
| T_operator (TC_arrow (a, b)) -> | T_operator (TC_arrow { type1 ; type2 }) ->
let%bind _ = check_no_nested_bigmap false a in let%bind _ = check_no_nested_bigmap false type1 in
let%bind _ = check_no_nested_bigmap false b in let%bind _ = check_no_nested_bigmap false type2 in
ok () ok ()
| T_operator (TC_michelson_or (a, b)) -> | T_operator (TC_michelson_or {l; r}) ->
let%bind _ = check_no_nested_bigmap false a in let%bind _ = check_no_nested_bigmap false l in
let%bind _ = check_no_nested_bigmap false b in let%bind _ = check_no_nested_bigmap false r in
ok () ok ()
| T_sum s -> | T_sum s ->
let es = CMap.to_list s in let es = CMap.to_list s in

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@ -63,23 +63,23 @@ and check_recursive_call_in_matching = fun n final_path c ->
let%bind _ = check_recursive_call n final_path match_true in let%bind _ = check_recursive_call n final_path match_true in
let%bind _ = check_recursive_call n final_path match_false in let%bind _ = check_recursive_call n final_path match_false in
ok () ok ()
| Match_list {match_nil;match_cons=(_,_,e,_)} -> | Match_list {match_nil;match_cons={hd=_;tl=_;body;tv=_}} ->
let%bind _ = check_recursive_call n final_path match_nil in let%bind _ = check_recursive_call n final_path match_nil in
let%bind _ = check_recursive_call n final_path e in let%bind _ = check_recursive_call n final_path body in
ok () ok ()
| Match_option {match_none; match_some=(_,e,_)} -> | Match_option {match_none; match_some={opt=_;body;tv=_}} ->
let%bind _ = check_recursive_call n final_path match_none in let%bind _ = check_recursive_call n final_path match_none in
let%bind _ = check_recursive_call n final_path e in let%bind _ = check_recursive_call n final_path body in
ok () ok ()
| Match_tuple ((_,e),_) -> | Match_tuple {vars=_;body;tvs=_} ->
let%bind _ = check_recursive_call n final_path e in let%bind _ = check_recursive_call n final_path body in
ok () ok ()
| Match_variant (l,_) -> | Match_variant {cases;tv=_} ->
let aux (_,e) = let aux {constructor=_; pattern=_; body} =
let%bind _ = check_recursive_call n final_path e in let%bind _ = check_recursive_call n final_path body in
ok () ok ()
in in
let%bind _ = bind_map_list aux l in let%bind _ = bind_map_list aux cases in
ok () ok ()

View File

@ -595,7 +595,7 @@ module Typer = struct
| C_SELF_ADDRESS -> ok @@ t_self_address; | C_SELF_ADDRESS -> ok @@ t_self_address;
| C_IMPLICIT_ACCOUNT -> ok @@ t_implicit_account; | C_IMPLICIT_ACCOUNT -> ok @@ t_implicit_account;
| C_SET_DELEGATE -> ok @@ t_set_delegate ; | C_SET_DELEGATE -> ok @@ t_set_delegate ;
| c -> simple_fail @@ Format.asprintf "Typer not implemented for consant %a" Stage_common.PP.constant c | c -> simple_fail @@ Format.asprintf "Typer not implemented for consant %a" Ast_typed.PP.constant c
end end
let none = typer_0 "NONE" @@ fun tv_opt -> let none = typer_0 "NONE" @@ fun tv_opt ->

View File

@ -1,10 +1,245 @@
[@@@coverage exclude_file] [@@@coverage exclude_file]
(* open Types
* open Format
* open PP_helpers *)
(* include Stage_common.PP *)
open Types open Types
open Format open Format
open PP_helpers open PP_helpers
include Stage_common.PP let constructor ppf (c:constructor') : unit =
include Ast_PP_type(Ast_typed_type_parameter) let Constructor c = c in fprintf ppf "%s" c
let label ppf (l:label) : unit =
let Label l = l in fprintf ppf "%s" l
let cmap_sep value sep ppf m =
let lst = CMap.to_kv_list m in
let lst = List.sort (fun (Constructor a,_) (Constructor b,_) -> String.compare a b) lst in
let new_pp ppf (k, v) = fprintf ppf "@[<h>%a -> %a@]" constructor k value v in
fprintf ppf "%a" (list_sep new_pp sep) lst
let record_sep value sep ppf (m : 'a label_map) =
let lst = LMap.to_kv_list m in
let lst = List.sort_uniq (fun (Label a,_) (Label b,_) -> String.compare a b) lst in
let new_pp ppf (k, v) = fprintf ppf "@[<h>%a -> %a@]" label k value v in
fprintf ppf "%a" (list_sep new_pp sep) lst
let tuple_sep value sep ppf m =
assert (Helpers.is_tuple_lmap m);
let lst = Helpers.tuple_of_record m in
let new_pp ppf (_, v) = fprintf ppf "%a" value v in
fprintf ppf "%a" (list_sep new_pp sep) lst
(* Prints records which only contain the consecutive fields
0..(cardinal-1) as tuples *)
let tuple_or_record_sep value format_record sep_record format_tuple sep_tuple ppf m =
if Helpers.is_tuple_lmap m then
fprintf ppf format_tuple (tuple_sep value (tag sep_tuple)) m
else
fprintf ppf format_record (record_sep value (tag sep_record)) m
let list_sep_d x = list_sep x (tag " ,@ ")
let cmap_sep_d x = cmap_sep x (tag " ,@ ")
let tuple_or_record_sep_expr value = tuple_or_record_sep value "@[<hv 7>record[%a]@]" " ,@ " "@[<hv 2>( %a )@]" " ,@ "
let tuple_or_record_sep_type value = tuple_or_record_sep value "@[<hv 7>record[%a]@]" " ,@ " "@[<hv 2>( %a )@]" " *@ "
let constant ppf : constant' -> unit = function
| C_INT -> fprintf ppf "INT"
| C_UNIT -> fprintf ppf "UNIT"
| C_NIL -> fprintf ppf "NIL"
| C_NOW -> fprintf ppf "NOW"
| C_IS_NAT -> fprintf ppf "IS_NAT"
| C_SOME -> fprintf ppf "SOME"
| C_NONE -> fprintf ppf "NONE"
| C_ASSERTION -> fprintf ppf "ASSERTION"
| C_ASSERT_INFERRED -> fprintf ppf "ASSERT_INFERRED"
| C_FAILWITH -> fprintf ppf "FAILWITH"
| C_UPDATE -> fprintf ppf "UPDATE"
(* Loops *)
| C_ITER -> fprintf ppf "ITER"
| C_FOLD -> fprintf ppf "FOLD"
| C_FOLD_WHILE -> fprintf ppf "FOLD_WHILE"
| C_FOLD_CONTINUE -> fprintf ppf "CONTINUE"
| C_FOLD_STOP -> fprintf ppf "STOP"
| C_LOOP_LEFT -> fprintf ppf "LOOP_LEFT"
| C_LOOP_CONTINUE -> fprintf ppf "LOOP_CONTINUE"
| C_LOOP_STOP -> fprintf ppf "LOOP_STOP"
(* MATH *)
| C_NEG -> fprintf ppf "NEG"
| C_ABS -> fprintf ppf "ABS"
| C_ADD -> fprintf ppf "ADD"
| C_SUB -> fprintf ppf "SUB"
| C_MUL -> fprintf ppf "MUL"
| C_EDIV -> fprintf ppf "EDIV"
| C_DIV -> fprintf ppf "DIV"
| C_MOD -> fprintf ppf "MOD"
(* LOGIC *)
| C_NOT -> fprintf ppf "NOT"
| C_AND -> fprintf ppf "AND"
| C_OR -> fprintf ppf "OR"
| C_XOR -> fprintf ppf "XOR"
| C_LSL -> fprintf ppf "LSL"
| C_LSR -> fprintf ppf "LSR"
(* COMPARATOR *)
| C_EQ -> fprintf ppf "EQ"
| C_NEQ -> fprintf ppf "NEQ"
| C_LT -> fprintf ppf "LT"
| C_GT -> fprintf ppf "GT"
| C_LE -> fprintf ppf "LE"
| C_GE -> fprintf ppf "GE"
(* Bytes/ String *)
| C_SIZE -> fprintf ppf "SIZE"
| C_CONCAT -> fprintf ppf "CONCAT"
| C_SLICE -> fprintf ppf "SLICE"
| C_BYTES_PACK -> fprintf ppf "BYTES_PACK"
| C_BYTES_UNPACK -> fprintf ppf "BYTES_UNPACK"
| C_CONS -> fprintf ppf "CONS"
(* Pair *)
| C_PAIR -> fprintf ppf "PAIR"
| C_CAR -> fprintf ppf "CAR"
| C_CDR -> fprintf ppf "CDR"
| C_LEFT -> fprintf ppf "LEFT"
| C_RIGHT -> fprintf ppf "RIGHT"
(* Set *)
| C_SET_EMPTY -> fprintf ppf "SET_EMPTY"
| C_SET_LITERAL -> fprintf ppf "SET_LITERAL"
| C_SET_ADD -> fprintf ppf "SET_ADD"
| C_SET_REMOVE -> fprintf ppf "SET_REMOVE"
| C_SET_ITER -> fprintf ppf "SET_ITER"
| C_SET_FOLD -> fprintf ppf "SET_FOLD"
| C_SET_MEM -> fprintf ppf "SET_MEM"
(* List *)
| C_LIST_EMPTY -> fprintf ppf "LIST_EMPTY"
| C_LIST_LITERAL -> fprintf ppf "LIST_LITERAL"
| C_LIST_ITER -> fprintf ppf "LIST_ITER"
| C_LIST_MAP -> fprintf ppf "LIST_MAP"
| C_LIST_FOLD -> fprintf ppf "LIST_FOLD"
(* Maps *)
| C_MAP -> fprintf ppf "MAP"
| C_MAP_EMPTY -> fprintf ppf "MAP_EMPTY"
| C_MAP_LITERAL -> fprintf ppf "MAP_LITERAL"
| C_MAP_GET -> fprintf ppf "MAP_GET"
| C_MAP_GET_FORCE -> fprintf ppf "MAP_GET_FORCE"
| C_MAP_ADD -> fprintf ppf "MAP_ADD"
| C_MAP_REMOVE -> fprintf ppf "MAP_REMOVE"
| C_MAP_UPDATE -> fprintf ppf "MAP_UPDATE"
| C_MAP_ITER -> fprintf ppf "MAP_ITER"
| C_MAP_MAP -> fprintf ppf "MAP_MAP"
| C_MAP_FOLD -> fprintf ppf "MAP_FOLD"
| C_MAP_MEM -> fprintf ppf "MAP_MEM"
| C_MAP_FIND -> fprintf ppf "MAP_FIND"
| C_MAP_FIND_OPT -> fprintf ppf "MAP_FIND_OP"
(* Big Maps *)
| C_BIG_MAP -> fprintf ppf "BIG_MAP"
| C_BIG_MAP_EMPTY -> fprintf ppf "BIG_MAP_EMPTY"
| C_BIG_MAP_LITERAL -> fprintf ppf "BIG_MAP_LITERAL"
(* Crypto *)
| C_SHA256 -> fprintf ppf "SHA256"
| C_SHA512 -> fprintf ppf "SHA512"
| C_BLAKE2b -> fprintf ppf "BLAKE2b"
| C_HASH -> fprintf ppf "HASH"
| C_HASH_KEY -> fprintf ppf "HASH_KEY"
| C_CHECK_SIGNATURE -> fprintf ppf "CHECK_SIGNATURE"
| C_CHAIN_ID -> fprintf ppf "CHAIN_ID"
(* Blockchain *)
| C_CALL -> fprintf ppf "CALL"
| C_CONTRACT -> fprintf ppf "CONTRACT"
| C_CONTRACT_OPT -> fprintf ppf "CONTRACT_OPT"
| C_CONTRACT_ENTRYPOINT -> fprintf ppf "CONTRACT_ENTRYPOINT"
| C_CONTRACT_ENTRYPOINT_OPT -> fprintf ppf "CONTRACT_ENTRYPOINT_OPT"
| C_AMOUNT -> fprintf ppf "AMOUNT"
| C_BALANCE -> fprintf ppf "BALANCE"
| C_SOURCE -> fprintf ppf "SOURCE"
| C_SENDER -> fprintf ppf "SENDER"
| C_ADDRESS -> fprintf ppf "ADDRESS"
| C_SELF -> fprintf ppf "SELF"
| C_SELF_ADDRESS -> fprintf ppf "SELF_ADDRESS"
| C_IMPLICIT_ACCOUNT -> fprintf ppf "IMPLICIT_ACCOUNT"
| C_SET_DELEGATE -> fprintf ppf "SET_DELEGATE"
| C_CREATE_CONTRACT -> fprintf ppf "CREATE_CONTRACT"
let literal ppf (l : literal) =
match l with
| Literal_unit -> fprintf ppf "unit"
| Literal_void -> fprintf ppf "void"
| Literal_bool b -> fprintf ppf "%b" b
| Literal_int n -> fprintf ppf "%d" n
| Literal_nat n -> fprintf ppf "+%d" n
| Literal_timestamp n -> fprintf ppf "+%d" n
| Literal_mutez n -> fprintf ppf "%dmutez" n
| Literal_string s -> fprintf ppf "%S" s
| Literal_bytes b -> fprintf ppf "0x%a" Hex.pp (Hex.of_bytes b)
| Literal_address s -> fprintf ppf "@%S" s
| Literal_operation _ -> fprintf ppf "Operation(...bytes)"
| Literal_key s -> fprintf ppf "key %s" s
| Literal_key_hash s -> fprintf ppf "key_hash %s" s
| Literal_signature s -> fprintf ppf "Signature %s" s
| Literal_chain_id s -> fprintf ppf "Chain_id %s" s
let type_variable ppf (t : type_variable) : unit = fprintf ppf "%a" Var.pp t
and type_constant ppf (tc : type_constant) : unit =
let s =
match tc with
| TC_unit -> "unit"
| TC_string -> "string"
| TC_bytes -> "bytes"
| TC_nat -> "nat"
| TC_int -> "int"
| TC_mutez -> "mutez"
| TC_bool -> "bool"
| TC_operation -> "operation"
| TC_address -> "address"
| TC_key -> "key"
| TC_key_hash -> "key_hash"
| TC_signature -> "signature"
| TC_timestamp -> "timestamp"
| TC_chain_id -> "chain_id"
| TC_void -> "void"
in
fprintf ppf "%s" s
open Format
let rec type_expression' :
(formatter -> type_expression -> unit)
-> formatter
-> type_expression
-> unit =
fun f ppf te ->
match te.type_content with
| T_sum m -> fprintf ppf "@[<hv 4>sum[%a]@]" (cmap_sep_d f) m
| T_record m -> fprintf ppf "%a" (tuple_or_record_sep_type f) m
| T_arrow a -> fprintf ppf "%a -> %a" f a.type1 f a.type2
| T_variable tv -> type_variable ppf tv
| T_constant tc -> type_constant ppf tc
| T_operator to_ -> type_operator f ppf to_
and type_expression ppf (te : type_expression) : unit =
type_expression' type_expression ppf te
and type_operator :
(formatter -> type_expression -> unit)
-> formatter
-> type_operator
-> unit =
fun f ppf to_ ->
let s =
match to_ with
| TC_option te -> Format.asprintf "option(%a)" f te
| TC_list te -> Format.asprintf "list(%a)" f te
| TC_set te -> Format.asprintf "set(%a)" f te
| TC_map {k; v} -> Format.asprintf "Map (%a,%a)" f k f v
| TC_big_map {k; v} -> Format.asprintf "Big Map (%a,%a)" f k f v
| TC_map_or_big_map {k; v} -> Format.asprintf "Map Or Big Map (%a,%a)" f k f v
| TC_michelson_or {l; r} -> Format.asprintf "michelson_or (%a,%a)" f l f r
| TC_arrow {type1; type2} -> Format.asprintf "arrow (%a,%a)" f type1 f type2
| TC_contract te -> Format.asprintf "Contract (%a)" f te
in
fprintf ppf "(TO_%s)" s
(* end include Stage_common.PP *)
let expression_variable ppf (ev : expression_variable) : unit = let expression_variable ppf (ev : expression_variable) : unit =
fprintf ppf "%a" Var.pp ev fprintf ppf "%a" Var.pp ev
@ -46,10 +281,10 @@ and expression_content ppf (ec: expression_content) =
type_expression fun_type type_expression fun_type
expression_content (E_lambda lambda) expression_content (E_lambda lambda)
and assoc_expression ppf : expr * expr -> unit = and assoc_expression ppf : map_kv -> unit =
fun (a, b) -> fprintf ppf "%a -> %a" expression a expression b fun {k ; v} -> fprintf ppf "%a -> %a" expression k expression v
and single_record_patch ppf ((p, expr) : label * expr) = and single_record_patch ppf ((p, expr) : label * expression) =
fprintf ppf "%a <- %a" label p expression expr fprintf ppf "%a <- %a" label p expression expr
@ -59,26 +294,26 @@ and option_inline ppf inline =
else else
fprintf ppf "" fprintf ppf ""
and matching_variant_case : type a . (_ -> a -> unit) -> _ -> (constructor' * expression_variable) * a -> unit = and matching_variant_case : (_ -> expression -> unit) -> _ -> matching_content_case -> unit =
fun f ppf ((c,n),a) -> fun f ppf {constructor=c; pattern; body} ->
fprintf ppf "| %a %a -> %a" constructor c expression_variable n f a fprintf ppf "| %a %a -> %a" constructor c expression_variable pattern f body
and matching : type a . (formatter -> a -> unit) -> _ -> (a, 'var) matching_content -> unit = fun f ppf m -> match m with and matching : (formatter -> expression -> unit) -> _ -> matching_expr -> unit = fun f ppf m -> match m with
| Match_tuple ((lst, b),_) -> | Match_tuple {vars; body; tvs=_} ->
fprintf ppf "let (%a) = %a" (list_sep_d expression_variable) lst f b fprintf ppf "let (%a) = %a" (list_sep_d expression_variable) vars f body
| Match_variant (lst, _) -> | Match_variant {cases ; tv=_} ->
fprintf ppf "%a" (list_sep (matching_variant_case f) (tag "@.")) lst fprintf ppf "%a" (list_sep (matching_variant_case f) (tag "@.")) cases
| Match_bool {match_true ; match_false} -> | Match_bool {match_true ; match_false} ->
fprintf ppf "| True -> %a @.| False -> %a" f match_true f match_false fprintf ppf "| True -> %a @.| False -> %a" f match_true f match_false
| Match_list {match_nil ; match_cons = (hd_name, tl_name, match_cons, _)} -> | Match_list {match_nil ; match_cons = {hd; tl; body; tv=_}} ->
fprintf ppf "| Nil -> %a @.| %a :: %a -> %a" f match_nil expression_variable hd_name expression_variable tl_name f match_cons fprintf ppf "| Nil -> %a @.| %a :: %a -> %a" f match_nil expression_variable hd expression_variable tl f body
| Match_option {match_none ; match_some = (some, match_some, _)} -> | Match_option {match_none ; match_some = {opt; body; tv=_}} ->
fprintf ppf "| None -> %a @.| Some %a -> %a" f match_none expression_variable some f match_some fprintf ppf "| None -> %a @.| Some %a -> %a" f match_none expression_variable opt f body
let declaration ppf (d : declaration) = let declaration ppf (d : declaration) =
match d with match d with
| Declaration_constant (name, expr, inline,_) -> | Declaration_constant {binder; expr; inline; post_env=_} ->
fprintf ppf "const %a = %a%a" expression_variable name expression expr option_inline inline fprintf ppf "const %a = %a%a" expression_variable binder expression expr option_inline inline
let program ppf (p : program) = let program ppf (p : program) =
fprintf ppf "@[<v>%a@]" fprintf ppf "@[<v>%a@]"

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@ -0,0 +1,42 @@
open Types
open Fold
open Format
let print_program : formatter -> program -> unit = fun ppf p ->
ignore ppf ;
let assert_nostate _ = () in (* (needs_parens, state) = assert (not needs_parens && match state with None -> true | Some _ -> false) in *)
let nostate = false, "" in
let op = {
generic = (fun state info ->
assert_nostate state;
match info.node_instance.instance_kind with
| RecordInstance { fields } ->
false, "{ " ^ String.concat " ; " (List.map (fun (fld : 'x Adt_info.ctor_or_field_instance) -> fld.cf.name ^ " = " ^ snd (fld.cf_continue nostate)) fields) ^ " }"
| VariantInstance { constructor={ cf = { name; is_builtin=_; type_=_ }; cf_continue }; variant=_ } ->
(match cf_continue nostate with
| true, arg -> true, name ^ " (" ^ arg ^ ")"
| false, arg -> true, name ^ " " ^ arg)
| PolyInstance { poly=_; arguments=_; poly_continue } ->
(poly_continue nostate)
);
type_variable = (fun _visitor state type_meta -> assert_nostate state; false , (ignore type_meta;"TODO:TYPE_META")) ;
type_meta = (fun _visitor state type_meta -> assert_nostate state; false , (ignore type_meta;"TODO:TYPE_META")) ;
bool = (fun _visitor state b -> assert_nostate state; false , if b then "true" else "false") ;
int = (fun _visitor state i -> assert_nostate state; false , string_of_int i) ;
string = (fun _visitor state str -> assert_nostate state; false , "\"" ^ str ^ "\"") ;
bytes = (fun _visitor state bytes -> assert_nostate state; false , (ignore bytes;"TODO:BYTES")) ;
packed_internal_operation = (fun _visitor state op -> assert_nostate state; false , (ignore op;"TODO:PACKED_INTERNAL_OPERATION")) ;
expression_variable = (fun _visitor state ev -> assert_nostate state; false , (ignore ev;"TODO:EXPRESSION_VARIABLE")) ;
constructor' = (fun _visitor state c -> assert_nostate state; false , (ignore c;"TODO:CONSTRUCTOR'")) ;
location = (fun _visitor state loc -> assert_nostate state; false , (ignore loc;"TODO:LOCATION'")) ;
label = (fun _visitor state (Label lbl) -> assert_nostate state; true, "Label " ^ lbl) ;
constructor_map = (fun _visitor continue state cmap -> assert_nostate state; false , (ignore (continue,cmap);"TODO:constructor_map")) ;
label_map = (fun _visitor continue state lmap -> assert_nostate state; false , (ignore (continue,lmap);"TODO:label_map")) ;
list = (fun _visitor continue state lst ->
assert_nostate state;
false , "[ " ^ String.concat " ; " (List.map snd @@ List.map (continue nostate) lst) ^ " ]") ;
location_wrap = (fun _visitor continue state lwrap -> assert_nostate state; false , (ignore (continue,lwrap);"TODO:location_wrap")) ;
list_ne = (fun _visitor continue state list_ne -> assert_nostate state; false , (ignore (continue,list_ne);"TODO:location_wrap")) ;
} in
let (_ , state) = fold__program op nostate p in
Printf.printf "%s" state

View File

@ -9,6 +9,7 @@ module Misc = struct
include Misc include Misc
include Misc_smart include Misc_smart
end end
module Helpers = Helpers
include Types include Types
include Misc include Misc

View File

@ -62,9 +62,9 @@ let ez_t_record lst ?s () : type_expression =
t_record m ?s () t_record m ?s ()
let t_pair a b ?s () : type_expression = ez_t_record [(Label "0",a) ; (Label "1",b)] ?s () let t_pair a b ?s () : type_expression = ez_t_record [(Label "0",a) ; (Label "1",b)] ?s ()
let t_map key value ?s () = make_t (T_operator (TC_map (key , value))) s let t_map k v ?s () = make_t (T_operator (TC_map { k ; v })) s
let t_big_map key value ?s () = make_t (T_operator (TC_big_map (key , value))) s let t_big_map k v ?s () = make_t (T_operator (TC_big_map { k ; v })) s
let t_map_or_big_map key value ?s () = make_t (T_operator (TC_map_or_big_map (key,value))) s let t_map_or_big_map k v ?s () = make_t (T_operator (TC_map_or_big_map { k ; v })) s
let t_sum m ?s () : type_expression = make_t (T_sum m) s let t_sum m ?s () : type_expression = make_t (T_sum m) s
let make_t_ez_sum (lst:(constructor' * type_expression) list) : type_expression = let make_t_ez_sum (lst:(constructor' * type_expression) list) : type_expression =
@ -190,14 +190,14 @@ let get_t_record (t:type_expression) : type_expression label_map result = match
let get_t_map (t:type_expression) : (type_expression * type_expression) result = let get_t_map (t:type_expression) : (type_expression * type_expression) result =
match t.type_content with match t.type_content with
| T_operator (TC_map (k,v)) -> ok (k, v) | T_operator (TC_map { k ; v }) -> ok (k, v)
| T_operator (TC_map_or_big_map (k,v)) -> ok (k, v) | T_operator (TC_map_or_big_map { k ; v }) -> ok (k, v)
| _ -> fail @@ Errors.not_a_x_type "map" t () | _ -> fail @@ Errors.not_a_x_type "map" t ()
let get_t_big_map (t:type_expression) : (type_expression * type_expression) result = let get_t_big_map (t:type_expression) : (type_expression * type_expression) result =
match t.type_content with match t.type_content with
| T_operator (TC_big_map (k,v)) -> ok (k, v) | T_operator (TC_big_map { k ; v }) -> ok (k, v)
| T_operator (TC_map_or_big_map (k,v)) -> ok (k, v) | T_operator (TC_map_or_big_map { k ; v }) -> ok (k, v)
| _ -> fail @@ Errors.not_a_x_type "big_map" t () | _ -> fail @@ Errors.not_a_x_type "big_map" t ()
let get_t_map_key : type_expression -> type_expression result = fun t -> let get_t_map_key : type_expression -> type_expression result = fun t ->
@ -341,7 +341,7 @@ let get_a_record_accessor = fun t ->
let get_declaration_by_name : program -> string -> declaration result = fun p name -> let get_declaration_by_name : program -> string -> declaration result = fun p name ->
let aux : declaration -> bool = fun declaration -> let aux : declaration -> bool = fun declaration ->
match declaration with match declaration with
| Declaration_constant (d, _, _, _) -> d = Var.of_name name | Declaration_constant { binder ; expr=_ ; inline=_ ; post_env=_ } -> binder = Var.of_name name
in in
trace_option (Errors.declaration_not_found name ()) @@ trace_option (Errors.declaration_not_found name ()) @@
List.find_opt aux @@ List.map Location.unwrap p List.find_opt aux @@ List.map Location.unwrap p

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@ -126,7 +126,7 @@ val e_chain_id : string -> expression_content
val e_operation : Memory_proto_alpha.Protocol.Alpha_context.packed_internal_operation -> expression_content val e_operation : Memory_proto_alpha.Protocol.Alpha_context.packed_internal_operation -> expression_content
val e_lambda : lambda -> expression_content val e_lambda : lambda -> expression_content
val e_pair : expression -> expression -> expression_content val e_pair : expression -> expression -> expression_content
val e_application : expression -> expr -> expression_content val e_application : expression -> expression -> expression_content
val e_variable : expression_variable -> expression_content val e_variable : expression_variable -> expression_content
val e_let_in : expression_variable -> inline -> expression -> expression -> expression_content val e_let_in : expression_variable -> inline -> expression -> expression -> expression_content

View File

@ -1,3 +1,10 @@
(rule
(target generated_fold.ml)
(deps ../adt_generator/generator.raku types.ml)
(action (with-stdout-to generated_fold.ml (run perl6 ../adt_generator/generator.raku types.ml)))
; (mode (promote (until-clean)))
)
(library (library
(name ast_typed) (name ast_typed)
(public_name ligo.ast_typed) (public_name ligo.ast_typed)
@ -6,6 +13,7 @@
tezos-utils tezos-utils
ast_core ; Is that a good idea? ast_core ; Is that a good idea?
stage_common stage_common
adt_generator
) )
(preprocess (preprocess
(pps ppx_let bisect_ppx --conditional) (pps ppx_let bisect_ppx --conditional)

View File

@ -43,12 +43,14 @@ let add_type : type_variable -> type_expression -> t -> t = fun k v -> List.Ne.h
let get_opt : expression_variable -> t -> element option = fun k x -> List.Ne.find_map (Small.get_opt k) x let get_opt : expression_variable -> t -> element option = fun k x -> List.Ne.find_map (Small.get_opt k) x
let get_type_opt : type_variable -> t -> type_expression option = fun k x -> List.Ne.find_map (Small.get_type_opt k) x let get_type_opt : type_variable -> t -> type_expression option = fun k x -> List.Ne.find_map (Small.get_type_opt k) x
let get_constructor : constructor' -> t -> (type_expression * type_expression) option = fun k x -> (* Left is the constructor, right is the sum type *) let convert_constructor' (S.Constructor c) = Constructor c
let get_constructor : Ast_core.constructor' -> t -> (type_expression * type_expression) option = fun k x -> (* Left is the constructor, right is the sum type *)
let aux = fun x -> let aux = fun x ->
let aux = fun {type_variable=_ ; type_} -> let aux = fun {type_variable=_ ; type_} ->
match type_.type_content with match type_.type_content with
| T_sum m -> | T_sum m ->
(match CMap.find_opt k m with (match CMap.find_opt (convert_constructor' k) m with
Some km -> Some (km , type_) Some km -> Some (km , type_)
| None -> None) | None -> None)
| _ -> None | _ -> None

View File

@ -14,7 +14,7 @@ val add_ez_ae : expression_variable -> expression -> t -> t
val add_type : type_variable -> type_expression -> t -> t val add_type : type_variable -> type_expression -> t -> t
val get_opt : expression_variable -> t -> element option val get_opt : expression_variable -> t -> element option
val get_type_opt : type_variable -> t -> type_expression option val get_type_opt : type_variable -> t -> type_expression option
val get_constructor : constructor' -> t -> (type_expression * type_expression) option val get_constructor : Ast_core.constructor' -> t -> (type_expression * type_expression) option
module Small : sig module Small : sig
type t = small_environment type t = small_environment

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@ -0,0 +1 @@
include Generated_fold

View File

@ -0,0 +1,165 @@
open Types
open Trace
let map_type_operator f = function
TC_contract x -> TC_contract (f x)
| TC_option x -> TC_option (f x)
| TC_list x -> TC_list (f x)
| TC_set x -> TC_set (f x)
| TC_map {k ; v} -> TC_map { k = f k ; v = f v }
| TC_big_map {k ; v}-> TC_big_map { k = f k ; v = f v }
| TC_map_or_big_map { k ; v }-> TC_map_or_big_map { k = f k ; v = f v }
| TC_michelson_or { l ; r } -> TC_michelson_or { l = f l ; r = f r }
| TC_arrow {type1 ; type2} -> TC_arrow { type1 = f type1 ; type2 = f type2 }
let bind_map_type_operator f = function
TC_contract x -> let%bind x = f x in ok @@ TC_contract x
| TC_option x -> let%bind x = f x in ok @@ TC_option x
| TC_list x -> let%bind x = f x in ok @@ TC_list x
| TC_set x -> let%bind x = f x in ok @@ TC_set x
| TC_map {k ; v} -> let%bind k = f k in let%bind v = f v in ok @@ TC_map {k ; v}
| TC_big_map {k ; v} -> let%bind k = f k in let%bind v = f v in ok @@ TC_big_map {k ; v}
| TC_map_or_big_map {k ; v} -> let%bind k = f k in let%bind v = f v in ok @@ TC_map_or_big_map {k ; v}
| TC_michelson_or {l ; r}-> let%bind l = f l in let%bind r = f r in ok @@ TC_michelson_or {l ; r}
| TC_arrow {type1 ; type2}-> let%bind type1 = f type1 in let%bind type2 = f type2 in ok @@ TC_arrow {type1 ; type2}
let type_operator_name = function
TC_contract _ -> "TC_contract"
| TC_option _ -> "TC_option"
| TC_list _ -> "TC_list"
| TC_set _ -> "TC_set"
| TC_map _ -> "TC_map"
| TC_big_map _ -> "TC_big_map"
| TC_map_or_big_map _ -> "TC_map_or_big_map"
| TC_michelson_or _ -> "TC_michelson_or"
| TC_arrow _ -> "TC_arrow"
let type_expression'_of_string = function
| "TC_contract" , [x] -> ok @@ T_operator(TC_contract x)
| "TC_option" , [x] -> ok @@ T_operator(TC_option x)
| "TC_list" , [x] -> ok @@ T_operator(TC_list x)
| "TC_set" , [x] -> ok @@ T_operator(TC_set x)
| "TC_map" , [k ; v] -> ok @@ T_operator(TC_map { k ; v })
| "TC_big_map" , [k ; v] -> ok @@ T_operator(TC_big_map { k ; v })
| ("TC_contract" | "TC_option" | "TC_list" | "TC_set" | "TC_map" | "TC_big_map"), _ ->
failwith "internal error: wrong number of arguments for type operator"
| "TC_unit" , [] -> ok @@ T_constant(TC_unit)
| "TC_string" , [] -> ok @@ T_constant(TC_string)
| "TC_bytes" , [] -> ok @@ T_constant(TC_bytes)
| "TC_nat" , [] -> ok @@ T_constant(TC_nat)
| "TC_int" , [] -> ok @@ T_constant(TC_int)
| "TC_mutez" , [] -> ok @@ T_constant(TC_mutez)
| "TC_bool" , [] -> ok @@ T_constant(TC_bool)
| "TC_operation" , [] -> ok @@ T_constant(TC_operation)
| "TC_address" , [] -> ok @@ T_constant(TC_address)
| "TC_key" , [] -> ok @@ T_constant(TC_key)
| "TC_key_hash" , [] -> ok @@ T_constant(TC_key_hash)
| "TC_chain_id" , [] -> ok @@ T_constant(TC_chain_id)
| "TC_signature" , [] -> ok @@ T_constant(TC_signature)
| "TC_timestamp" , [] -> ok @@ T_constant(TC_timestamp)
| _, [] ->
failwith "internal error: wrong number of arguments for type constant"
| _ ->
failwith "internal error: unknown type operator"
let string_of_type_operator = function
| TC_contract x -> "TC_contract" , [x]
| TC_option x -> "TC_option" , [x]
| TC_list x -> "TC_list" , [x]
| TC_set x -> "TC_set" , [x]
| TC_map { k ; v } -> "TC_map" , [k ; v]
| TC_big_map { k ; v } -> "TC_big_map" , [k ; v]
| TC_map_or_big_map { k ; v } -> "TC_map_or_big_map" , [k ; v]
| TC_michelson_or { l ; r } -> "TC_michelson_or" , [l ; r]
| TC_arrow { type1 ; type2 } -> "TC_arrow" , [type1 ; type2]
let string_of_type_constant = function
| TC_unit -> "TC_unit", []
| TC_string -> "TC_string", []
| TC_bytes -> "TC_bytes", []
| TC_nat -> "TC_nat", []
| TC_int -> "TC_int", []
| TC_mutez -> "TC_mutez", []
| TC_bool -> "TC_bool", []
| TC_operation -> "TC_operation", []
| TC_address -> "TC_address", []
| TC_key -> "TC_key", []
| TC_key_hash -> "TC_key_hash", []
| TC_chain_id -> "TC_chain_id", []
| TC_signature -> "TC_signature", []
| TC_timestamp -> "TC_timestamp", []
| TC_void -> "TC_void", []
let string_of_type_expression' = function
| T_operator o -> string_of_type_operator o
| T_constant c -> string_of_type_constant c
| T_sum _ | T_record _ | T_arrow _ | T_variable _ ->
failwith "not a type operator or constant"
let bind_lmap (l:_ label_map) =
let open Trace in
let open LMap in
let aux k v prev =
prev >>? fun prev' ->
v >>? fun v' ->
ok @@ add k v' prev' in
fold aux l (ok empty)
let bind_cmap (c:_ constructor_map) =
let open Trace in
let open CMap in
let aux k v prev =
prev >>? fun prev' ->
v >>? fun v' ->
ok @@ add k v' prev' in
fold aux c (ok empty)
let bind_fold_lmap f init (lmap:_ LMap.t) =
let open Trace in
let aux k v prev =
prev >>? fun prev' ->
f prev' k v
in
LMap.fold aux lmap init
let bind_map_lmap f map = bind_lmap (LMap.map f map)
let bind_map_cmap f map = bind_cmap (CMap.map f map)
let bind_map_lmapi f map = bind_lmap (LMap.mapi f map)
let bind_map_cmapi f map = bind_cmap (CMap.mapi f map)
let range i j =
let rec aux i j acc = if i >= j then acc else aux i (j-1) (j-1 :: acc) in
aux i j []
let label_range i j =
List.map (fun i -> Label (string_of_int i)) @@ range i j
let is_tuple_lmap m =
List.for_all (fun i -> LMap.mem i m) @@ (label_range 0 (LMap.cardinal m))
let get_pair m =
let open Trace in
match (LMap.find_opt (Label "0") m , LMap.find_opt (Label "1") m) with
| Some e1, Some e2 -> ok (e1,e2)
| _ -> simple_fail "not a pair"
let tuple_of_record (m: _ LMap.t) =
let aux i =
let label = Label (string_of_int i) in
let opt = LMap.find_opt (label) m in
Option.bind (fun opt -> Some ((label,opt),i+1)) opt
in
Base.Sequence.to_list @@ Base.Sequence.unfold ~init:0 ~f:aux
let list_of_record_or_tuple (m: _ LMap.t) =
if (is_tuple_lmap m) then
List.map snd @@ tuple_of_record m
else
List.rev @@ LMap.to_list m
let kv_list_of_record_or_tuple (m: _ LMap.t) =
if (is_tuple_lmap m) then
tuple_of_record m
else
List.rev @@ LMap.to_kv_list m

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@ -1,5 +1,6 @@
open Trace open Trace
open Types open Types
open Helpers
module Errors = struct module Errors = struct
let different_kinds a b () = let different_kinds a b () =
@ -53,7 +54,7 @@ module Errors = struct
error ~data title message () error ~data title message ()
let different_props_in_record a b ra rb ka kb () = let different_props_in_record a b ra rb ka kb () =
let names () = if Stage_common.Helpers.is_tuple_lmap ra && Stage_common.Helpers.is_tuple_lmap rb then "tuples" else "records" in let names () = if Helpers.is_tuple_lmap ra && Helpers.is_tuple_lmap rb then "tuples" else "records" in
let title () = "different keys in " ^ (names ()) in let title () = "different keys in " ^ (names ()) in
let message () = "" in let message () = "" in
let data = [ let data = [
@ -65,8 +66,8 @@ module Errors = struct
error ~data title message () error ~data title message ()
let different_kind_record_tuple a b ra rb () = let different_kind_record_tuple a b ra rb () =
let name_a () = if Stage_common.Helpers.is_tuple_lmap ra then "tuple" else "record" in let name_a () = if Helpers.is_tuple_lmap ra then "tuple" else "record" in
let name_b () = if Stage_common.Helpers.is_tuple_lmap rb then "tuple" else "record" in let name_b () = if Helpers.is_tuple_lmap rb then "tuple" else "record" in
let title () = "different keys in " ^ (name_a ()) ^ " and " ^ (name_b ()) in let title () = "different keys in " ^ (name_a ()) ^ " and " ^ (name_b ()) in
let message () = "Expected these two types to be the same, but they're different (one is a " ^ (name_a ()) ^ " and the other is a " ^ (name_b ()) ^ ")" in let message () = "Expected these two types to be the same, but they're different (one is a " ^ (name_a ()) ^ " and the other is a " ^ (name_b ()) ^ ")" in
let data = [ let data = [
@ -82,7 +83,7 @@ module Errors = struct
let different_size_records_tuples a b ra rb = let different_size_records_tuples a b ra rb =
different_size_type different_size_type
(if Stage_common.Helpers.is_tuple_lmap ra && Stage_common.Helpers.is_tuple_lmap rb (if Helpers.is_tuple_lmap ra && Helpers.is_tuple_lmap rb
then "tuples" then "tuples"
else "records") else "records")
a b a b
@ -228,17 +229,17 @@ module Free_variables = struct
and expression : bindings -> expression -> bindings = fun b e -> and expression : bindings -> expression -> bindings = fun b e ->
expression_content b e.expression_content expression_content b e.expression_content
and matching_variant_case : type a . (bindings -> a -> bindings) -> bindings -> ((constructor' * expression_variable) * a) -> bindings = fun f b ((_,n),c) -> and matching_variant_case : (bindings -> expression -> bindings) -> bindings -> matching_content_case -> bindings = fun f b { constructor=_ ; pattern ; body } ->
f (union (singleton n) b) c f (union (singleton pattern) b) body
and matching : type a . (bindings -> a -> bindings) -> bindings -> (a,'var) matching_content -> bindings = fun f b m -> and matching : (bindings -> expression -> bindings) -> bindings -> matching_expr -> bindings = fun f b m ->
match m with match m with
| Match_bool { match_true = t ; match_false = fa } -> union (f b t) (f b fa) | Match_bool { match_true = t ; match_false = fa } -> union (f b t) (f b fa)
| Match_list { match_nil = n ; match_cons = (hd, tl, c, _) } -> union (f b n) (f (union (of_list [hd ; tl]) b) c) | Match_list { match_nil = n ; match_cons = {hd; tl; body; tv=_} } -> union (f b n) (f (union (of_list [hd ; tl]) b) body)
| Match_option { match_none = n ; match_some = (opt, s, _) } -> union (f b n) (f (union (singleton opt) b) s) | Match_option { match_none = n ; match_some = {opt; body; tv=_} } -> union (f b n) (f (union (singleton opt) b) body)
| Match_tuple ((lst , a), _) -> | Match_tuple { vars ; body ; tvs=_ } ->
f (union (of_list lst) b) a f (union (of_list vars) b) body
| Match_variant (lst,_) -> unions @@ List.map (matching_variant_case f b) lst | Match_variant { cases ; tv=_ } -> unions @@ List.map (matching_variant_case f b) cases
and matching_expression = fun x -> matching expression x and matching_expression = fun x -> matching expression x
@ -338,12 +339,13 @@ let rec assert_type_expression_eq (a, b: (type_expression * type_expression)) :
| TC_list la, TC_list lb | TC_list la, TC_list lb
| TC_contract la, TC_contract lb | TC_contract la, TC_contract lb
| TC_set la, TC_set lb -> ok @@ ([la], [lb]) | TC_set la, TC_set lb -> ok @@ ([la], [lb])
| (TC_map (ka,va) | TC_map_or_big_map (ka,va)), (TC_map (kb,vb) | TC_map_or_big_map (kb,vb)) | (TC_map {k=ka;v=va} | TC_map_or_big_map {k=ka;v=va}), (TC_map {k=kb;v=vb} | TC_map_or_big_map {k=kb;v=vb})
| (TC_big_map (ka,va) | TC_map_or_big_map (ka,va)), (TC_big_map (kb,vb) | TC_map_or_big_map (kb,vb)) | (TC_big_map {k=ka;v=va} | TC_map_or_big_map {k=ka;v=va}), (TC_big_map {k=kb;v=vb} | TC_map_or_big_map {k=kb;v=vb})
-> ok @@ ([ka;va] ,[kb;vb]) -> ok @@ ([ka;va] ,[kb;vb])
| TC_michelson_or (la,ra), TC_michelson_or (lb,rb) -> ok @@ ([la;ra] , [lb;rb]) | TC_michelson_or {l=la;r=ra}, TC_michelson_or {l=lb;r=rb} -> ok @@ ([la;ra] , [lb;rb])
| (TC_option _ | TC_list _ | TC_contract _ | TC_set _ | TC_map _ | TC_big_map _ | TC_map_or_big_map _ | TC_arrow _| TC_michelson_or _ ), | (TC_option _ | TC_list _ | TC_contract _ | TC_set _ | TC_map _ | TC_big_map _ | TC_map_or_big_map _ | TC_arrow _| TC_michelson_or _ ),
(TC_option _ | TC_list _ | TC_contract _ | TC_set _ | TC_map _ | TC_big_map _ | TC_map_or_big_map _ | TC_arrow _ | TC_michelson_or _ ) -> fail @@ different_operators opa opb (TC_option _ | TC_list _ | TC_contract _ | TC_set _ | TC_map _ | TC_big_map _ | TC_map_or_big_map _ | TC_arrow _| TC_michelson_or _ )
-> fail @@ different_operators opa opb
in in
if List.length lsta <> List.length lstb then if List.length lsta <> List.length lstb then
fail @@ different_operator_number_of_arguments opa opb (List.length lsta) (List.length lstb) fail @@ different_operator_number_of_arguments opa opb (List.length lsta) (List.length lstb)
@ -369,7 +371,7 @@ let rec assert_type_expression_eq (a, b: (type_expression * type_expression)) :
) )
| T_sum _, _ -> fail @@ different_kinds a b | T_sum _, _ -> fail @@ different_kinds a b
| T_record ra, T_record rb | T_record ra, T_record rb
when Stage_common.Helpers.is_tuple_lmap ra <> Stage_common.Helpers.is_tuple_lmap rb -> ( when Helpers.is_tuple_lmap ra <> Helpers.is_tuple_lmap rb -> (
fail @@ different_kind_record_tuple a b ra rb fail @@ different_kind_record_tuple a b ra rb
) )
| T_record ra, T_record rb -> ( | T_record ra, T_record rb -> (
@ -489,7 +491,7 @@ let rec assert_value_eq (a, b: (expression*expression)) : unit result =
| Some a, Some b -> Some (assert_value_eq (a, b)) | Some a, Some b -> Some (assert_value_eq (a, b))
| _ -> Some (fail @@ missing_key_in_record_value k) | _ -> Some (fail @@ missing_key_in_record_value k)
in in
let%bind _all = Stage_common.Helpers.bind_lmap @@ LMap.merge aux sma smb in let%bind _all = Helpers.bind_lmap @@ LMap.merge aux sma smb in
ok () ok ()
) )
| E_record _, _ -> | E_record _, _ ->
@ -515,8 +517,8 @@ let merge_annotation (a:type_expression option) (b:type_expression option) err :
let get_entry (lst : program) (name : string) : expression result = let get_entry (lst : program) (name : string) : expression result =
trace_option (Errors.missing_entry_point name) @@ trace_option (Errors.missing_entry_point name) @@
let aux x = let aux x =
let (Declaration_constant (an , expr, _, _)) = Location.unwrap x in let (Declaration_constant { binder ; expr ; inline=_ ; _ }) = Location.unwrap x in
if (an = Var.of_name name) if Var.equal binder (Var.of_name name)
then Some expr then Some expr
else None else None
in in
@ -525,4 +527,4 @@ let get_entry (lst : program) (name : string) : expression result =
let program_environment (program : program) : full_environment = let program_environment (program : program) : full_environment =
let last_declaration = Location.unwrap List.(hd @@ rev program) in let last_declaration = Location.unwrap List.(hd @@ rev program) in
match last_declaration with match last_declaration with
| Declaration_constant (_ , _, _, post_env) -> post_env | Declaration_constant { binder=_ ; expr=_ ; inline=_ ; post_env } -> post_env

View File

@ -2,13 +2,13 @@ open Trace
open Types open Types
open Combinators open Combinators
open Misc open Misc
open Stage_common.Types (* open Stage_common.Types *)
let program_to_main : program -> string -> lambda result = fun p s -> let program_to_main : program -> string -> lambda result = fun p s ->
let%bind (main , input_type , _) = let%bind (main , input_type , _) =
let pred = fun d -> let pred = fun d ->
match d with match d with
| Declaration_constant (d , expr, _, _) when d = Var.of_name s -> Some expr | Declaration_constant { binder; expr; inline=_ ; post_env=_ } when binder = Var.of_name s -> Some expr
| Declaration_constant _ -> None | Declaration_constant _ -> None
in in
let%bind main = let%bind main =
@ -23,7 +23,7 @@ let program_to_main : program -> string -> lambda result = fun p s ->
let env = let env =
let aux = fun _ d -> let aux = fun _ d ->
match d with match d with
| Declaration_constant (_ , _, _, post_env) -> post_env in | Declaration_constant {binder=_ ; expr= _ ; inline=_ ; post_env } -> post_env in
List.fold_left aux Environment.full_empty (List.map Location.unwrap p) in List.fold_left aux Environment.full_empty (List.map Location.unwrap p) in
let binder = Var.of_name "@contract_input" in let binder = Var.of_name "@contract_input" in
let result = let result =
@ -86,27 +86,27 @@ module Captured_variables = struct
let b' = union (singleton r.fun_name) b in let b' = union (singleton r.fun_name) b in
expression_content b' env @@ E_lambda r.lambda expression_content b' env @@ E_lambda r.lambda
and matching_variant_case : type a . (bindings -> a -> bindings result) -> bindings -> ((constructor' * expression_variable) * a) -> bindings result = fun f b ((_,n),c) -> and matching_variant_case : (bindings -> expression -> bindings result) -> bindings -> matching_content_case -> bindings result = fun f b { constructor=_ ; pattern ; body } ->
f (union (singleton n) b) c f (union (singleton pattern) b) body
and matching : type a . (bindings -> a -> bindings result) -> bindings -> (a, 'tv) matching_content -> bindings result = fun f b m -> and matching : (bindings -> expression -> bindings result) -> bindings -> matching_expr -> bindings result = fun f b m ->
match m with match m with
| Match_bool { match_true = t ; match_false = fa } -> | Match_bool { match_true = t ; match_false = fa } ->
let%bind t' = f b t in let%bind t' = f b t in
let%bind fa' = f b fa in let%bind fa' = f b fa in
ok @@ union t' fa' ok @@ union t' fa'
| Match_list { match_nil = n ; match_cons = (hd, tl, c, _) } -> | Match_list { match_nil = n ; match_cons = {hd; tl; body; tv=_} } ->
let%bind n' = f b n in let%bind n' = f b n in
let%bind c' = f (union (of_list [hd ; tl]) b) c in let%bind c' = f (union (of_list [hd ; tl]) b) body in
ok @@ union n' c' ok @@ union n' c'
| Match_option { match_none = n ; match_some = (opt, s, _) } -> | Match_option { match_none = n ; match_some = {opt; body; tv=_} } ->
let%bind n' = f b n in let%bind n' = f b n in
let%bind s' = f (union (singleton opt) b) s in let%bind s' = f (union (singleton opt) b) body in
ok @@ union n' s' ok @@ union n' s'
| Match_tuple ((lst , a),_) -> | Match_tuple { vars ; body ; tvs=_ } ->
f (union (of_list lst) b) a f (union (of_list vars) b) body
| Match_variant (lst , _) -> | Match_variant { cases ; tv=_ } ->
let%bind lst' = bind_map_list (matching_variant_case f b) lst in let%bind lst' = bind_map_list (matching_variant_case f b) cases in
ok @@ unions lst' ok @@ unions lst'
and matching_expression = fun x -> matching expression x and matching_expression = fun x -> matching expression x

View File

@ -6,7 +6,7 @@ val program_to_main : program -> string -> lambda result
module Captured_variables : sig module Captured_variables : sig
type bindings = expression_variable list type bindings = expression_variable list
val matching : (bindings -> 'a -> bindings result) -> bindings -> ('a, type_expression) matching_content -> bindings result val matching : (bindings -> expression -> bindings result) -> bindings -> matching_expr -> bindings result
val matching_expression : bindings -> matching_expr -> bindings result val matching_expression : bindings -> matching_expr -> bindings result

View File

@ -1,17 +1,266 @@
[@@@warning "-30"] [@@@warning "-30"]
module S = Ast_core include Types_utils
include Stage_common.Types
module Ast_typed_type_parameter = struct type type_constant =
type type_meta = S.type_expression option | TC_unit
end | TC_string
| TC_bytes
| TC_nat
| TC_int
| TC_mutez
| TC_bool
| TC_operation
| TC_address
| TC_key
| TC_key_hash
| TC_chain_id
| TC_signature
| TC_timestamp
| TC_void
include Ast_generic_type (Ast_typed_type_parameter) type te_cmap = type_expression constructor_map
and te_lmap = type_expression label_map
type program = declaration Location.wrap list and type_content =
| T_sum of te_cmap
| T_record of te_lmap
| T_arrow of arrow
| T_variable of type_variable
| T_constant of type_constant
| T_operator of type_operator
and inline = bool and arrow = {
type1: type_expression;
type2: type_expression;
}
and type_map_args = {
k : type_expression;
v : type_expression;
}
and michelson_or_args = {
l : type_expression;
r : type_expression;
}
and type_operator =
| TC_contract of type_expression
| TC_option of type_expression
| TC_list of type_expression
| TC_set of type_expression
| TC_map of type_map_args
| TC_big_map of type_map_args
| TC_map_or_big_map of type_map_args
| TC_michelson_or of michelson_or_args
| TC_arrow of arrow
and type_expression = {
type_content: type_content;
type_meta: type_meta;
}
type literal =
| Literal_unit
| Literal_bool of bool
| Literal_int of int
| Literal_nat of int
| Literal_timestamp of int
| Literal_mutez of int
| Literal_string of string
| Literal_bytes of bytes
| Literal_address of string
| Literal_signature of string
| Literal_key of string
| Literal_key_hash of string
| Literal_chain_id of string
| Literal_void
| Literal_operation of packed_internal_operation
type matching_content_bool = {
match_true : expression ;
match_false : expression ;
}
and matching_content_cons = {
hd : expression_variable;
tl : expression_variable;
body : expression;
tv : type_expression;
}
and matching_content_list = {
match_nil : expression ;
match_cons : matching_content_cons;
}
and matching_content_some = {
opt : expression_variable ;
body : expression ;
tv : type_expression ;
}
and matching_content_option = {
match_none : expression ;
match_some : matching_content_some ;
}
and expression_variable_list = expression_variable list
and type_expression_list = type_expression list
and matching_content_tuple = {
vars : expression_variable_list ;
body : expression ;
tvs : type_expression_list ;
}
and matching_content_case = {
constructor : constructor' ;
pattern : expression_variable ;
body : expression ;
}
and matching_content_case_list = matching_content_case list
and matching_content_variant = {
cases: matching_content_case_list;
tv: type_expression;
}
and matching_expr =
| Match_bool of matching_content_bool
| Match_list of matching_content_list
| Match_option of matching_content_option
| Match_tuple of matching_content_tuple
| Match_variant of matching_content_variant
and constant' =
| C_INT
| C_UNIT
| C_NIL
| C_NOW
| C_IS_NAT
| C_SOME
| C_NONE
| C_ASSERTION
| C_ASSERT_INFERRED
| C_FAILWITH
| C_UPDATE
(* Loops *)
| C_ITER
| C_FOLD_WHILE
| C_FOLD_CONTINUE
| C_FOLD_STOP
| C_LOOP_LEFT
| C_LOOP_CONTINUE
| C_LOOP_STOP
| C_FOLD
(* MATH *)
| C_NEG
| C_ABS
| C_ADD
| C_SUB
| C_MUL
| C_EDIV
| C_DIV
| C_MOD
(* LOGIC *)
| C_NOT
| C_AND
| C_OR
| C_XOR
| C_LSL
| C_LSR
(* COMPARATOR *)
| C_EQ
| C_NEQ
| C_LT
| C_GT
| C_LE
| C_GE
(* Bytes/ String *)
| C_SIZE
| C_CONCAT
| C_SLICE
| C_BYTES_PACK
| C_BYTES_UNPACK
| C_CONS
(* Pair *)
| C_PAIR
| C_CAR
| C_CDR
| C_LEFT
| C_RIGHT
(* Set *)
| C_SET_EMPTY
| C_SET_LITERAL
| C_SET_ADD
| C_SET_REMOVE
| C_SET_ITER
| C_SET_FOLD
| C_SET_MEM
(* List *)
| C_LIST_EMPTY
| C_LIST_LITERAL
| C_LIST_ITER
| C_LIST_MAP
| C_LIST_FOLD
(* Maps *)
| C_MAP
| C_MAP_EMPTY
| C_MAP_LITERAL
| C_MAP_GET
| C_MAP_GET_FORCE
| C_MAP_ADD
| C_MAP_REMOVE
| C_MAP_UPDATE
| C_MAP_ITER
| C_MAP_MAP
| C_MAP_FOLD
| C_MAP_MEM
| C_MAP_FIND
| C_MAP_FIND_OPT
(* Big Maps *)
| C_BIG_MAP
| C_BIG_MAP_EMPTY
| C_BIG_MAP_LITERAL
(* Crypto *)
| C_SHA256
| C_SHA512
| C_BLAKE2b
| C_HASH
| C_HASH_KEY
| C_CHECK_SIGNATURE
| C_CHAIN_ID
(* Blockchain *)
| C_CALL
| C_CONTRACT
| C_CONTRACT_OPT
| C_CONTRACT_ENTRYPOINT
| C_CONTRACT_ENTRYPOINT_OPT
| C_AMOUNT
| C_BALANCE
| C_SOURCE
| C_SENDER
| C_ADDRESS
| C_SELF
| C_SELF_ADDRESS
| C_IMPLICIT_ACCOUNT
| C_SET_DELEGATE
| C_CREATE_CONTRACT
and declaration_loc = declaration location_wrap
and program = declaration_loc list
and declaration_constant = {
binder : expression_variable ;
expr : expression ;
inline : bool ;
post_env : full_environment ;
}
and declaration = and declaration =
(* A Declaration_constant is described by (* A Declaration_constant is described by
@ -19,7 +268,7 @@ and declaration =
* a boolean indicating whether it should be inlined * a boolean indicating whether it should be inlined
* the environment before the declaration (the original environment) * the environment before the declaration (the original environment)
* the environment after the declaration (i.e. with that new declaration added to the original environment). *) * the environment after the declaration (i.e. with that new declaration added to the original environment). *)
| Declaration_constant of (expression_variable * expression * inline * full_environment) | Declaration_constant of declaration_constant
(* (*
| Declaration_type of (type_variable * type_expression) | Declaration_type of (type_variable * type_expression)
| Declaration_constant of (named_expression * (full_environment * full_environment)) | Declaration_constant of (named_expression * (full_environment * full_environment))
@ -28,11 +277,25 @@ and declaration =
and expression = { and expression = {
expression_content: expression_content ; expression_content: expression_content ;
location: Location.t ; location: location ;
type_expression: type_expression ; type_expression: type_expression ;
environment: full_environment ; environment: full_environment ;
} }
and map_kv = {
k : expression ;
v : expression ;
}
and look_up = {
ds : expression;
ind : expression;
}
and expression_label_map = expression label_map
and map_kv_list = map_kv list
and expression_list = expression list
and expression_content = and expression_content =
(* Base *) (* Base *)
| E_literal of literal | E_literal of literal
@ -46,13 +309,14 @@ and expression_content =
| E_constructor of constructor (* For user defined constructors *) | E_constructor of constructor (* For user defined constructors *)
| E_matching of matching | E_matching of matching
(* Record *) (* Record *)
| E_record of expression label_map | E_record of expression_label_map
| E_record_accessor of record_accessor | E_record_accessor of record_accessor
| E_record_update of record_update | E_record_update of record_update
and constant = and constant = {
{ cons_name: constant' cons_name: constant' ;
; arguments: expression list } arguments: expression_list ;
}
and application = { and application = {
lamb: expression ; lamb: expression ;
@ -70,7 +334,7 @@ and let_in = {
let_binder: expression_variable ; let_binder: expression_variable ;
rhs: expression ; rhs: expression ;
let_result: expression ; let_result: expression ;
inline : inline ; inline : bool ;
} }
and recursive = { and recursive = {
@ -95,10 +359,9 @@ and record_update = {
update: expression ; update: expression ;
} }
and matching_expr = (expression,type_expression) matching_content and matching = {
and matching = matchee: expression ;
{ matchee: expression cases: matching_expr ;
; cases: matching_expr
} }
and ascription = { and ascription = {
@ -106,7 +369,6 @@ and ascription = {
type_annotation: type_expression ; type_annotation: type_expression ;
} }
and environment_element_definition = and environment_element_definition =
| ED_binder | ED_binder
| ED_declaration of environment_element_definition_declaration | ED_declaration of environment_element_definition_declaration
@ -144,13 +406,10 @@ and small_environment = {
type_environment: type_environment ; type_environment: type_environment ;
} }
and full_environment = small_environment List.Ne.t and full_environment = small_environment list_ne
and expr = expression
and texpr = type_expression
and named_type_content = { and named_type_content = {
type_name : type_variable; type_name : type_variable;
type_value : type_expression; type_value : type_expression;
} }

View File

@ -0,0 +1,71 @@
module S = Ast_core
open Simple_utils.Trace
(* include Stage_common.Types *)
(* type expression_
* and expression_variable = expression_ Var.t
* type type_
* and type_variable = type_ Var.t *)
type expression_ = Stage_common.Types.expression_
type expression_variable = Stage_common.Types.expression_variable
type type_ = Stage_common.Types.type_
type type_variable = Stage_common.Types.type_variable
type constructor' =
| Constructor of string
type label =
| Label of string
module CMap = Map.Make( struct type t = constructor' let compare (Constructor a) (Constructor b) = compare a b end)
module LMap = Map.Make( struct type t = label let compare (Label a) (Label b) = String.compare a b end)
type 'a label_map = 'a LMap.t
type 'a constructor_map = 'a CMap.t
type type_meta = S.type_expression option
type 'a location_wrap = 'a Location.wrap
type 'a list_ne = 'a List.Ne.t
type packed_internal_operation = Memory_proto_alpha.Protocol.Alpha_context.packed_internal_operation
type location = Location.t
type inline = bool
let fold_map__constructor_map : type a new_a state . (state -> a -> (state * new_a) result) -> state -> a constructor_map -> (state * new_a constructor_map) result =
fun f state m ->
let aux k v acc =
let%bind (state , m) = acc in
let%bind (state , new_v) = f state v in
ok (state , CMap.add k new_v m) in
let%bind (state , m) = CMap.fold aux m (ok (state, CMap.empty)) in
ok (state , m)
let fold_map__label_map : type a state new_a . (state -> a -> (state * new_a) result) -> state -> a label_map -> (state * new_a label_map) result =
fun f state m ->
let aux k v acc =
let%bind (state , m) = acc in
let%bind (state , new_v) = f state v in
ok (state , LMap.add k new_v m) in
let%bind (state , m) = LMap.fold aux m (ok (state, LMap.empty)) in
ok (state , m)
let fold_map__list : type a state new_a . (state -> a -> (state * new_a) result) -> state -> a list -> (state * new_a list) Simple_utils.Trace.result =
fun f state l ->
let aux acc element =
let%bind state , l = acc in
let%bind (state , new_element) = f state element in ok (state , new_element :: l) in
let%bind (state , l) = List.fold_left aux (ok (state , [])) l in
ok (state , l)
let fold_map__location_wrap : type a state new_a . (state -> a -> (state * new_a) result) -> state -> a location_wrap -> (state * new_a location_wrap) Simple_utils.Trace.result =
fun f state { wrap_content ; location } ->
let%bind ( state , wrap_content ) = f state wrap_content in
ok (state , ({ wrap_content ; location } : new_a location_wrap))
let fold_map__list_ne : type a state new_a . (state -> a -> (state * new_a) result) -> state -> a list_ne -> (state * new_a list_ne) Simple_utils.Trace.result =
fun f state (first , l) ->
let%bind (state , new_first) = f state first in
let aux acc element =
let%bind state , l = acc in
let%bind (state , new_element) = f state element in
ok (state , new_element :: l) in
let%bind (state , l) = List.fold_left aux (ok (state , [])) l in
ok (state , (new_first , l))

View File

@ -77,7 +77,7 @@ and expression = {
} }
and constant = { and constant = {
cons_name : constant'; (* this is at the end because it is huge *) cons_name : constant';
arguments : expression list; arguments : expression list;
} }

2
src/stages/adt_generator/.gitignore vendored Normal file
View File

@ -0,0 +1,2 @@
# This is an auto-generated test file
/generated_fold.ml

View File

@ -1,7 +1,7 @@
Build with: Build & test with:
dune build adt_generator.a dune build adt_generator.exe && ../../../_build/default/src/stages/adt_generator/adt_generator.exe
Run with Run with
python ./generator.py perl6 ./generator.raku amodule.ml

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