enso/lib/rust/parser/debug/tests/parse.rs

//! Parse expressions and compare their results to expected values.

// === Non-Standard Linter Configuration ===
#![allow(clippy::option_map_unit_fn)]
#![allow(clippy::precedence)]
#![allow(dead_code)]
#![deny(non_ascii_idents)]
#![deny(unconditional_recursion)]
#![warn(unsafe_code)]
#![warn(missing_copy_implementations)]
#![warn(missing_debug_implementations)]
#![warn(missing_docs)]
#![warn(trivial_casts)]
#![warn(trivial_numeric_casts)]
#![warn(unused_import_braces)]
#![warn(unused_qualifications)]



mod metadata;

use enso_parser_debug::to_s_expr;
use lexpr::sexp;



// ===========================
// === Test support macros ===
// ===========================

/// Parses input as a sequence of S-expressions, and wraps it in a `BodyBlock`.
macro_rules! block {
    ( $($statements:tt)* ) => {
        sexp![(BodyBlock #( $( $statements )* ) )]
    }
}

macro_rules! test {
    ( $code:expr, $($statements:tt)* ) => {
        test($code, block![$( $statements )*])
    }
}

macro_rules! test_block {
    ( $code:expr, $($statements:tt)* ) => {
        test_block($code, block![$( $statements )*])
    }
}



// ================================
// === Language Construct Tests ===
// ================================

#[test]
fn nothing() {
    test("", block![()]);
}

#[test]
fn application() {
    test("a b c", block![(App (App (Ident a) (Ident b)) (Ident c))]);
}

#[test]
fn parentheses() {
    test!("(a b)", (Group (App (Ident a) (Ident b))));
    expect_invalid_node("x)");
    test!("(x", (Invalid));
    test!("(a) (b)", (App (Group (Ident a)) (Group (Ident b))));
    test!("((a b) c)",
        (Group
         (App (Group (App (Ident a) (Ident b)))
              (Ident c))));
    test!("(a).b", (OprApp (Group (Ident a)) (Ok ".") (Ident b)));
}

#[test]
fn section_simple() {
    test!("+ a", (OprSectionBoundary 1 (OprApp () (Ok "+") (Ident a))));
    test!("a +", (OprSectionBoundary 1 (OprApp (Ident a) (Ok "+") ())));
}

#[test]
fn inline_if() {
    test!("if True then True else False",
       (MultiSegmentApp #(((Ident if) (Ident True))
                          ((Ident then) (Ident True))
                          ((Ident else) (Ident False)))));
}

#[test]
fn then_block() {
    test!("if True then\n True",
       (MultiSegmentApp #(((Ident if) (Ident True)) ((Ident then) (BodyBlock #((Ident True)))))));
}

#[test]
fn else_block() {
    test!("if True then True else\n False",
       (MultiSegmentApp #(((Ident if) (Ident True))
                          ((Ident then) (Ident True))
                          ((Ident else) (BodyBlock #((Ident False)))))));
}

#[test]
fn if_then_else_chained_block() {
    test!("if True then True else False\n    . to_text",
    (OperatorBlockApplication
        (MultiSegmentApp #(((Ident if) (Ident True))
            ((Ident then) (Ident True))
            ((Ident else) (Ident False)
        )))
        #(((Ok ".") (Ident to_text)))
        #()
    ));
    test!("(if True then True else False)\n    . to_text",
    (OperatorBlockApplication
        (Group (MultiSegmentApp #(((Ident if) (Ident True))
            ((Ident then) (Ident True))
            ((Ident else) (Ident False)
        ))))
        #(((Ok ".") (Ident to_text)))
        #()
    ));
    test!("if True then True else False\n    . to_text\n    . as_value",
    (OperatorBlockApplication
        (MultiSegmentApp #(((Ident if) (Ident True))
            ((Ident then) (Ident True))
            ((Ident else) (Ident False)
        )))
        #(((Ok ".") (Ident to_text)) ((Ok ".") (Ident as_value)))
        #()
    ));
    test!("if True then True else False\n    . to_text\n    . as_value\n    . done 42",
    (OperatorBlockApplication
        (MultiSegmentApp #(((Ident if) (Ident True))
            ((Ident then) (Ident True))
            ((Ident else) (Ident False)
        )))
        #(((Ok ".") (Ident to_text)) ((Ok ".") (Ident as_value)) ((Ok ".") (App (Ident done) (Number () "42" ()))))
        #()
    ));
}

// === Comments ===

#[test]
fn plain_comments() {
    test!("# a b c", ()());
    test(
        "main = # define main\n 4",
        block!(,(Function::new("main", block![() (Number () "4" ())]))),
    );
}

#[test]
fn doc_comments() {
    let lines = [
        "## The Identity Function",
        "",
        "   Arguments:",
        "   - x: value to do nothing to",
        "id x = x",
    ];
    test!(lines.join("\n"),
        (Documented
         (#((Section " The Identity Function") (Newline)
           (Newline)
           (Section "Arguments:") (Newline)
           (Section "- x: value to do nothing to"))
         #(()))
         ,(Function::new("id", sexp![(Ident x)]).with_arg("x"))));
    let lines = ["type Foo", " ## Test indent handling", "  ", " foo bar = foo"];
    test!(&lines.join("\n"),
        (TypeDef Foo #() #(
         (Documented
          (#((Section " Test indent handling")) #(() ()))
          ,(Function::new("foo", sexp![(Ident foo)]).with_arg("bar"))))));
    expect_invalid_node("expression ## unexpected doc comment on same line");
}


// === Type Definitions ===

#[test]
fn type_definition_no_body() {
    test!("type Bool", (TypeDef Bool #() #()));
    test!("type Option a", (TypeDef Option #((() (Ident a) () ())) #()));
    test!("type Option (a)", (TypeDef Option #((() (Ident a) () ())) #()));
    test!("type Foo (a : Int)", (TypeDef Foo #((() (Ident a) (":" (Ident Int)) ())) #()));
    test!("type A a=0", (TypeDef A #((() (Ident a) () ((Number () "0" ())))) #()));
    test!("type Existing_Headers (column_names : Vector Text)",
        (TypeDef Existing_Headers #(
         (() (Ident column_names) (":" (App (Ident Vector) (Ident Text))) ())) #()));
    test!("type 1", (Invalid));
}

#[test]
fn type_constructors() {
    let code = [
        "type Geo",
        "    Circle",
        "        radius",
        "        x",
        "    Rectangle width height",
        "    Point",
    ];
    test!(code.join("\n"),
        (TypeDef Geo #()
         #((ConstructorDefinition ()
             Circle #() #(((() (Ident radius) () ())) ((() (Ident x) () ()))))
           (ConstructorDefinition ()
             Rectangle #((() (Ident width) () ()) (() (Ident height) () ())) #())
           (ConstructorDefinition () Point #() #()))));
    test!("type Foo\n Bar (a : B = C.D)", (TypeDef Foo #() #(
        (ConstructorDefinition ()
         Bar
         #((() (Ident a) (":" (Ident B)) ((OprApp (Ident C) (Ok ".") (Ident D)))))
         #()))));
    test!("type Foo\n ## Bar\n Baz", (TypeDef Foo #() #(
        (Documented (#((Section " Bar")) #(())) (ConstructorDefinition () Baz #() #())))));
    let code = ["type A", "    Foo (a : Integer, b : Integer)"];
    test!(code.join("\n"), (TypeDef A #()
        #((ConstructorDefinition () Foo #((() (Ident a) (":" (Invalid)) ())) #()))));
}

#[test]
fn type_constructor_private() {
    test!(["type Foo", "    private Bar"].join("\n"),
        (TypeDef Foo #() #((ConstructorDefinition private Bar #() #()))));
    test!(["type Foo", "    private Bar", "    Foo"].join("\n"),
        (TypeDef Foo #()
         #((ConstructorDefinition private Bar #() #())
           (ConstructorDefinition () Foo #() #()))));
    test!([ "type Geo",
            "    private Circle",
            "        radius",
            "        x",
            "    Rectangle width height",
            "    Point",
        ].join("\n"),
        (TypeDef Geo #()
         #((ConstructorDefinition private
             Circle #() #(((() (Ident radius) () ())) ((() (Ident x) () ()))))
           (ConstructorDefinition ()
             Rectangle #((() (Ident width) () ()) (() (Ident height) () ())) #())
           (ConstructorDefinition () Point #() #()))));
    test!(["type My_Type", "    private Value a b c"].join("\n"),
        (TypeDef My_Type #()
         #((ConstructorDefinition private Value
            #((() (Ident a) () ()) (() (Ident b) () ()) (() (Ident c) () ())) #()))));
}

#[test]
fn type_methods() {
    test!(["type Geo", "    number =", "        x", "    area self = x + x"].join("\n"),
        (TypeDef Geo #()
         #(,(Function::new("number", block![(Ident x)]))
           ,(Function::new("area", sexp![(OprApp (Ident x) (Ok "+") (Ident x))])
             .with_arg("self")))));
    let code = [
        "type Problem_Builder",
        "    ## Returns a vector containing all reported problems, aggregated.",
        "    build_problemset : Vector",
        "    build_problemset self =",
        "        self",
    ];
    test!(code.join("\n"),
        (TypeDef Problem_Builder #() #(
         (Documented
          (#((Section " Returns a vector containing all reported problems, aggregated.")) #(()))
          (TypeSignature (Ident build_problemset) ":" (Ident Vector)))
         ,(Function::new("build_problemset", block![(Ident self)])
           .with_arg("self")))));
    test!("[foo., bar.]",
        (Array (OprSectionBoundary 1 (OprApp (Ident foo) (Ok ".") ()))
               #(("," (OprSectionBoundary 1 (OprApp (Ident bar) (Ok ".") ()))))));
}

#[test]
fn type_operator_methods() {
    test!([ "type Foo",
            "    + : Foo -> Foo -> Foo",
            "    + self b = b",
            "    Foo.+ : Foo",
            "    Foo.+ self b = b",
        ].join("\n"),
        (TypeDef Foo #()
         #((TypeSignature (Ident #"+") ":"
            (OprApp (Ident Foo) (Ok "->") (OprApp (Ident Foo) (Ok "->") (Ident Foo))))
           ,(Function::new("+", sexp![(Ident b)]).with_arg("self").with_arg("b"))
           (TypeSignature (OprApp (Ident Foo) (Ok ".") (Ident #"+")) ":" (Ident Foo))
           ,(Function::named(sexp![(OprApp (Ident Foo) (Ok ".") (Ident #"+"))], sexp![(Ident b)])
             .with_arg("self").with_arg("b")))));
    test!("Any.==", (OprApp (Ident Any) (Ok ".") (Ident #"==")));
    expect_invalid_node("x.-y");
    expect_invalid_node("x.-1");
    expect_invalid_node("x.+y");
    expect_invalid_node("x.+1");
    expect_invalid_node("x.+'a'");
    // Compile-time operators are never operator-identifiers.
    test!("x.~y", (OprApp (Ident x) (Ok ".") (UnaryOprApp "~" (Ident y))));
    test!("x.~1", (OprApp (Ident x) (Ok ".") (UnaryOprApp "~" (Number () "1" ()))));
}

#[test]
fn type_def_full() {
    test!([ "type Geo",
            "    Circle",
            "        radius : float",
            "        x",
            "    Rectangle width height",
            "    Point",
            "",
            "    number =",
            "        x",
            "    area self = x + x",
        ].join("\n"),
        (TypeDef Geo #()
         #((ConstructorDefinition () Circle #() #(
             ((() (Ident radius) (":" (Ident float)) ()))
             ((() (Ident x) () ()))))
           (ConstructorDefinition ()
             Rectangle #((() (Ident width) () ()) (() (Ident height) () ())) #())
           (ConstructorDefinition () Point #() #())
           ()
           ,(Function::new("number", block![(Ident x)]))
           ,(Function::new("area", sexp![(OprApp (Ident x) (Ok "+") (Ident x))])
             .with_arg("self")))));
}

#[test]
fn type_def_defaults() {
    let code = ["type Result error ok=Nothing", "    Ok value:ok = Nothing"];
    test!(code.join("\n"),
        (TypeDef Result #((() (Ident error) () ())
                               (() (Ident ok) () ((Ident Nothing))))
         #((ConstructorDefinition () Ok
            #((() (Ident value) (":" (Ident ok)) ((Ident Nothing)))) #()))));
}

#[test]
fn type_def_nested() {
    let code = ["type Foo", "    type Bar", "    type Baz"];
    test!(code.join("\n"),
        (TypeDef Foo #()
         #((TypeDef Bar #() #())
           (TypeDef Baz #() #()))));
}


// === Variable Assignment ===

#[test]
fn assignment_simple() {
    // At the top level of a module, this defines a function with no arguments.
    test!("foo = x", ,(Function::new("foo", sexp![(Ident x)])));
    // In a body block, this is a variable binding.
    test_block!("main =\n    foo = x",
        ,(Function::new("main", block![(Assignment (Ident foo) (Ident x))])));
    test_block!("foo=x", (Assignment (Ident foo) (Ident x)));
    test_block!("foo= x", (Assignment (Ident foo) (Ident x)));
    expect_invalid_node("foo =x");
}


// === Functions ===

#[test]
fn function_inline_simple_args() {
    test!("foo a = x",
        ,(Function::new("foo", sexp![(Ident x)]).with_arg("a")));
    test!("foo a b = x",
        ,(Function::new("foo", sexp![(Ident x)]).with_arg("a").with_arg("b")));
    test!("foo a b c = x",
        ,(Function::new("foo", sexp![(Ident x)]).with_arg("a").with_arg("b").with_arg("c")));
    test!("foo _ = x",
        ,(Function::new("foo", sexp![(Ident x)]).with_arg(sexp![(() (Wildcard -1) () ())])));
    expect_invalid_node("foo a =x");
}

#[test]
fn function_noargs_nobody() {
    test!("foo =", ,(Function::new("foo", sexp![()])));
}

#[test]
fn function_no_body() {
    test!("foo a =",
        ,(Function::new("foo", sexp![()]).with_arg("a")));
    test!("foo a b =",
        ,(Function::new("foo", sexp![()]).with_arg("a").with_arg("b")));
    test!("foo a b c =",
        ,(Function::new("foo", sexp![()]).with_arg("a").with_arg("b").with_arg("c")));
    test!("foo _ =",
        ,(Function::new("foo", sexp![()]).with_arg(sexp![(() (Wildcard -1) () ())])));
}

#[test]
fn function_block_body() {
    test!("foo a =\n    a",
        ,(Function::new("foo", block![(Ident a)]).with_arg("a")));
    test!("foo a b =\n    a",
        ,(Function::new("foo", block![(Ident a)]).with_arg("a").with_arg("b")));
    test!("foo a b c =\n    a",
        ,(Function::new("foo", block![(Ident a)]).with_arg("a").with_arg("b").with_arg("c")));
}

#[test]
fn function_qualified() {
    test!("Id.id x = x",
        ,(Function::named(sexp![(OprApp (Ident Id) (Ok ".") (Ident id))], sexp![(Ident x)])
          .with_arg("x")));
}

#[test]
fn ignored_arguments() {
    test!("f _ = x",
        ,(Function::new("f", sexp![(Ident x)]).with_arg(sexp![(() (Wildcard -1) () ())])));
    test!("f ~_ = x",
        ,(Function::new("f", sexp![(Ident x)]).with_arg(sexp![("~" (Wildcard -1) () ())])));
}

#[test]
fn foreign_functions() {
    test!("foreign python my_method a b = \"42\"",
        (ForeignFunction python my_method
            #((() (Ident a) () ()) (() (Ident b) () ()))
            (TextLiteral #((Section "42")))));
    test!("foreign python my_method = \"42\"",
        (ForeignFunction python my_method #() (TextLiteral #((Section "42")))));
    expect_invalid_node("private foreign python my_method = \"42\"");
}

#[test]
fn function_inline_return_specification() {
    // Typical usage
    test!("id self that:Integer -> Integer = that",
        ,(Function::new("id", sexp![(Ident that)])
          .with_arg("self")
          .with_arg(sexp![(() (Ident that) (":" (Ident Integer)) ())])
          .with_return(sexp![(Ident Integer)])));
    // Edge case
    test!("number -> Integer = 23",
        ,(Function::new("number", sexp![(Number () "23" ())])
          .with_return(sexp![(Ident Integer)])));
    expect_invalid_node("f x : Integer -> Integer = 23");
}


// === Named arguments ===

#[test]
fn named_arguments() {
    test!("f x=y", (NamedApp (Ident f) x (Ident y)));
    test!("f (x = y)", (NamedApp (Ident f) x (Ident y)));
    test!("(x a=b)", (Group (NamedApp (Ident x) a (Ident b))));
    test!("(x a=b.c)", (Group (NamedApp (Ident x) a (OprApp (Ident b) (Ok ".") (Ident c)))));
    test!("catch handler=exc->\n    throw",
        (NamedApp (Ident catch) handler
         (OprApp (Ident exc) (Ok "->") (BodyBlock #((Ident throw))))));
    test!("sort by=x-> y-> compare x y",
        (NamedApp (Ident sort) by
         (OprApp (Ident x) (Ok "->")
          (OprApp (Ident y) (Ok "->") (App (App (Ident compare) (Ident x)) (Ident y))))));
    test!("sort by=(<) xs",
        (App
         (NamedApp (Ident sort) by (Group (OprSectionBoundary 2 (OprApp () (Ok "<") ()))))
         (Ident xs)));
    test!("sort by=(x-> x) y-> compare x y",
        (App
         (NamedApp (Ident sort) by (Group (OprApp (Ident x) (Ok "->") (Ident x))))
         (OprApp (Ident y) (Ok "->") (App (App (Ident compare) (Ident x)) (Ident y)))));
    test!("sort by=(x-> x) 1",
        (App
         (NamedApp (Ident sort) by (Group (OprApp (Ident x) (Ok "->") (Ident x))))
         (Number () "1" ())));
    test!("foo to=", (App (Ident foo) (Invalid)));
    test!("(foo to=)", (Group (App (Ident foo) (Invalid))));
    test!("filter (foo to=(1))",
        (App (Ident filter) (Group (NamedApp (Ident foo) to (Group (Number () "1" ()))))));
    test!("foo . bar baz=quux",
        (NamedApp (OprApp (Ident foo) (Ok ".") (Ident bar)) baz (Ident quux)));
}


// === Default arguments ===

#[test]
fn default_app() {
    test!("f default", (App (Ident f) (Ident default)));
}

#[test]
fn argument_named_default() {
    test!("f default x = x",
        ,(Function::new("f", sexp![(Ident x)]).with_arg("default").with_arg("x")));
    test!("f x default = x",
        ,(Function::new("f", sexp![(Ident x)]).with_arg("x").with_arg("default")));
}

#[test]
fn complex_arguments() {
    test!("f x=1 = x", ,(Function::new("f", sexp![(Ident x)])
        .with_arg(sexp![(() (Ident x) () ((Number () "1" ())))])));
    test!("f (x : Number) = x", ,(Function::new("f", sexp![(Ident x)])
        .with_arg(sexp![(() (Ident x) (":" (Ident Number)) ())])));
    test!("f (x = 1) = x", ,(Function::new("f", sexp![(Ident x)])
        .with_arg(sexp![(() (Ident x) () ((Number () "1" ())))])));
    test!("f ((x = 1) : Number) = x", ,(Function::new("f", sexp![(Ident x)])
        .with_arg(sexp![(() (Invalid) (":" (Ident Number)) ())])));
    test!("f (x=1 : Number) = x", ,(Function::new("f", sexp![(Ident x)])
        .with_arg(sexp![(() (Invalid) (":" (Ident Number)) ())])));
    test!("f (x : Number = 1) = x", ,(Function::new("f", sexp![(Ident x)])
        .with_arg(sexp![(() (Ident x) (":" (Ident Number)) ((Number () "1" ())))])));
    test!("f (x y) = x", ,(Function::new("f", sexp![(Ident x)])
        .with_arg(sexp![(() (Invalid) () ())])));
    test!("f ((x : Number) = 1) = x", ,(Function::new("f", sexp![(Ident x)])
        .with_arg(sexp![(() (Ident x) (":" (Ident Number)) ((Number () "1" ())))])));
    test!("f ((x : Array Number) = 1) = x", ,(Function::new("f", sexp![(Ident x)])
        .with_arg(sexp![
           (() (Ident x) (":" (App (Ident Array) (Ident Number))) ((Number () "1" ())))])));
    test!("f (x):Number=1 = x", ,(Function::new("f", sexp![(Ident x)])
        .with_arg(sexp![(() (Invalid) (":" (Ident Number)) ((Number () "1" ())))])));
    test!("f ((x:Number=1)) = x",
        ,(Function::new("f", sexp![(Ident x)]).with_arg(sexp![(() (Invalid) () ())])));
    test!("f (x : Number)=1 = x", ,(Function::new("f", sexp![(Ident x)])
        .with_arg(sexp![(() (Ident x) (":" (Ident Number)) ((Number () "1" ())))])));
    test!("f (x:Number = 1) = x", ,(Function::new("f", sexp![(Ident x)])
        .with_arg(sexp![(() (Ident x) (":" (Ident Number)) ((Number () "1" ())))])));
    test!("f (x:Number=1) = x", ,(Function::new("f", sexp![(Ident x)])
        .with_arg(sexp![(() (Ident x) (":" (Ident Number)) ((Number () "1" ())))])));
    test!("f x:Number=1 = x", ,(Function::new("f", sexp![(Ident x)])
        .with_arg(sexp![(() (Ident x) (":" (Ident Number)) ((Number () "1" ())))])));
    // Pattern in LHS:
    test!("f ~x=1 = x", ,(Function::new("f", sexp![(Ident x)])
        .with_arg(sexp![("~" (Ident x) () ((Number () "1" ())))])));
    test!("f (~x = 1) = x", ,(Function::new("f", sexp![(Ident x)])
        .with_arg(sexp![("~" (Ident x) () ((Number () "1" ())))])));
}


// === Code Blocks ===

#[test]
fn code_block_body() {
    test!(["main =", "    x"].join("\n"),
        ,(Function::new("main", block![(Ident x)])));
    test!(["main =", "      ", "    x"].join("\n"),
        ,(Function::new("main", block![() (Ident x)])));
    test!(["main =", "    ", "    x"].join("\n"),
        ,(Function::new("main", block![() (Ident x)])));
    test!(["main =", "  ", "    x"].join("\n"),
        ,(Function::new("main", block![() (Ident x)])));
    test!(["main =", "", "    x"].join("\n"),
        ,(Function::new("main", block![() (Ident x)])));
    test!(["main =", "    +x", "    print x"].join("\n"),
        ,(Function::new("main", block![
          (OprSectionBoundary 1 (OprApp () (Ok "+") (Ident x)))
          (App (Ident print) (Ident x))])));
}

#[test]
fn code_block_operator() {
    let code = ["value = nums", "    * each random", "    + constant"];
    test_block!(code.join("\n"),
        (Assignment (Ident value)
         (OperatorBlockApplication (Ident nums)
          #(((Ok "*") (App (Ident each) (Ident random)))
            ((Ok "+") (Ident constant)))
          #())));
}

#[test]
fn dot_operator_blocks() {
    let code = ["rect1", "    . width * 7", "    . abs", "        + x"];
    test!(code.join("\n"),
        (OperatorBlockApplication (Ident rect1)
         #(((Ok ".") (OprApp (Ident width) (Ok "*") (Number () "7" ())))
           ((Ok ".") (OperatorBlockApplication (Ident abs)
                     #(((Ok "+") (Ident x))) #()))) #()));
    expect_invalid_node("rect1\n    . width = 7");
}

#[test]
fn code_block_argument_list() {
    test!("foo\n    bar", (ArgumentBlockApplication (Ident foo) #((Ident bar))));

    test_block!("value = foo\n    bar",
        (Assignment (Ident value) (ArgumentBlockApplication (Ident foo) #((Ident bar)))));

    let code = ["value = foo", "    +x", "    bar"];
    test_block!(code.join("\n"),
        (Assignment (Ident value)
         (ArgumentBlockApplication (Ident foo) #(
          (OprSectionBoundary 1 (OprApp () (Ok "+") (Ident x)))
          (Ident bar)))));
}

#[test]
fn code_block_empty() {
    // The first line here should parse as a function with no body expression (which is an error).
    // No input would parse as an empty `ArgumentBlock` or `OperatorBlock`, because those types are
    // distinguished from a body continuation by the presence of non-empty indented lines.
    test!(["foo =", "bar"].join("\n"), ,(Function::new("foo", sexp![()])) (Ident bar));
    // This parses similarly to above; a line with no non-whitespace content does not create a code
    // block.
    test!(["foo =", "    ", "bar"].join("\n"), ,(Function::new("foo", sexp![()])) () (Ident bar));
}

#[test]
fn code_block_bad_indents1() {
    test!(["main =", "  foo", " bar", "  baz"].join("\n"),
        ,(Function::new("main", block![(Ident foo) (Ident bar) (Ident baz)])));
}

#[test]
fn code_block_bad_indents2() {
    test!(["main =", "  foo", " bar", "baz"].join("\n"),
        ,(Function::new("main", block![(Ident foo) (Ident bar)]))
        (Ident baz));
}

#[test]
fn code_block_with_following_statement() {
    test!(["main =", "    foo", "bar"].join("\n"),
        ,(Function::new("main", block![(Ident foo)]))
        (Ident bar));
}

#[test]
fn operator_block_nested() {
    let code = ["foo", "    + bar", "        - baz"];
    #[rustfmt::skip]
    let expected = block![
        (OperatorBlockApplication (Ident foo)
         #(((Ok "+") (OperatorBlockApplication (Ident bar) #(((Ok "-") (Ident baz))) #())))
         #())];
    test(code.join("\n"), expected);
}

#[test]
fn operator_section_in_operator_block() {
    let code = ["foo", "    + bar +"];
    #[rustfmt::skip]
    let expected = block![
        (OperatorBlockApplication (Ident foo)
         #(((Ok "+") (OprSectionBoundary 1 (OprApp (Ident bar) (Ok "+") ()))))
         #())];
    test(code.join("\n"), expected);
}

#[test]
fn first_line_indented() {
    test!(" a", (BodyBlock #((Ident a))));
}


// === Binary Operators ===

#[test]
fn multiple_operator_error() {
    expect_multiple_operator_error("x + + x");
    expect_multiple_operator_error("x + + + x");
    expect_multiple_operator_error("x + +");
    expect_multiple_operator_error("+ + x");
    expect_multiple_operator_error("+ +");
    expect_multiple_operator_error("+ -");
    expect_multiple_operator_error("x + -");
}

#[test]
fn precedence() {
    test!("x * y + z", (OprApp (OprApp (Ident x) (Ok "*") (Ident y)) (Ok "+") (Ident z)));
    test!("x + y * z", (OprApp (Ident x) (Ok "+") (OprApp (Ident y) (Ok "*") (Ident z))));
    test!("w + x + y * z",
        (OprApp (OprApp (Ident w) (Ok "+") (Ident x)) (Ok "+")
                (OprApp (Ident y) (Ok "*") (Ident z))));
    test!("x - 1 + 2",
        (OprApp (OprApp (Ident x) (Ok "-") (Number () "1" ())) (Ok "+") (Number () "2" ())));
    test!("x+y * z", (OprApp (Ident x) (Ok "+") (OprApp (Ident y) (Ok "*") (Ident z))));
}

#[test]
fn dot_operator_precedence() {
    test!("x y . f v", (App (OprApp (App (Ident x) (Ident y)) (Ok ".") (Ident f)) (Ident v)));
}

#[test]
fn dot_operator_template_function() {
    test!("foo._", (TemplateFunction 1 (OprApp (Ident foo) (Ok ".") (Wildcard 0))));
    test!("_.foo", (TemplateFunction 1 (OprApp (Wildcard 0) (Ok ".") (Ident foo))));
}

#[test]
fn right_associative_operators() {
    test!("x --> y ---> z", (OprApp (Ident x) (Ok "-->") (OprApp (Ident y) (Ok "--->") (Ident z))));
    test!("x <| y <<| z", (OprApp (Ident x) (Ok "<|") (OprApp (Ident y) (Ok "<<|") (Ident z))));
}

#[test]
fn left_associative_operators() {
    test!("x + y + z", (OprApp (OprApp (Ident x) (Ok "+") (Ident y)) (Ok "+") (Ident z)));
}

#[test]
fn pipeline_operators() {
    test("f <| a", block![(OprApp (Ident f) (Ok "<|") (Ident a))]);
    test("a |> f", block![(OprApp (Ident a) (Ok "|>") (Ident f))]);
}

#[test]
fn accessor_operator() {
    // Test that the accessor operator `.` is treated like any other operator.
    test!("Console.", (OprSectionBoundary 1 (OprApp (Ident Console) (Ok ".") ())));
    test!(".", (OprSectionBoundary 2 (OprApp () (Ok ".") ())));
    test!(".log", (OprSectionBoundary 1 (OprApp () (Ok ".") (Ident log))));
}

#[test]
fn operator_sections() {
    test!(".map (+2 * 3) *7",
        (OprSectionBoundary 1
         (App (App (OprApp () (Ok ".") (Ident map))
                   (Group
                    (OprSectionBoundary 1 (OprApp (OprApp () (Ok "+") (Number () "2" ()))
                    (Ok "*") (Number () "3" ())))))
              (OprSectionBoundary 1 (OprApp () (Ok "*") (Number () "7" ()))))));
    test!(".sum 1",
        (OprSectionBoundary 1 (App (OprApp () (Ok ".") (Ident sum)) (Number () "1" ()))));
    test!("+1 + x",
        (OprSectionBoundary 1 (OprApp (OprApp () (Ok "+") (Number () "1" ()))
                               (Ok "+") (Ident x))));
    test_block!("increment = 1 +",
        (Assignment (Ident increment)
         (OprSectionBoundary 1 (OprApp (Number () "1" ()) (Ok "+") ()))));
    test!("1+ << 2*",
        (OprSectionBoundary 1
         (OprApp (OprApp (Number () "1" ()) (Ok "+") ())
                 (Ok "<<")
                 (OprSectionBoundary 1 (OprApp (Number () "2" ()) (Ok "*") ())))));
    test!("1+1+ << 2*2*",
        (OprSectionBoundary 1
         (OprApp (OprApp (OprApp (Number () "1" ())
                                 (Ok "+")
                                 (Number () "1" ()))
                         (Ok "+") ())
                 (Ok "<<")
                 (OprSectionBoundary 1
                  (OprApp (OprApp (Number () "2" ()) (Ok "*") (Number () "2" ()))
                          (Ok "*") ())))));
    test!("+1 << *2",
        (OprSectionBoundary 1
         (OprApp (OprApp () (Ok "+") (Number () "1" ()))
                 (Ok "<<")
                 (OprSectionBoundary 1 (OprApp () (Ok "*") (Number () "2" ()))))));
    test!("+1+1 << *2*2",
        (OprSectionBoundary 1
         (OprApp (OprApp (OprApp () (Ok "+") (Number () "1" ())) (Ok "+") (Number () "1" ()))
                 (Ok "<<")
                 (OprSectionBoundary 1 (OprApp (OprApp () (Ok "*") (Number () "2" ())) (Ok "*") (Number () "2" ()))))));
}

#[test]
fn template_functions() {
    #[rustfmt::skip]
    test("_.map (_ + 2*3) _*7", block![
        (TemplateFunction 1
         (App (App (OprApp (Wildcard 0) (Ok ".") (Ident map))
                   (Group (TemplateFunction 1
                    (OprApp (Wildcard 0)
                            (Ok "+")
                            (OprApp (Number () "2" ()) (Ok "*") (Number () "3" ()))))))
              (TemplateFunction 1 (OprApp (Wildcard 0) (Ok "*") (Number () "7" ())))))]);
    #[rustfmt::skip]
    test("_.sum 1", block![
        (TemplateFunction 1 (App (OprApp (Wildcard 0) (Ok ".") (Ident sum)) (Number () "1" ())))]);
    #[rustfmt::skip]
    test("_+1 + x", block![
        (TemplateFunction 1 (OprApp (OprApp (Wildcard 0) (Ok "+") (Number () "1" ()))
                           (Ok "+") (Ident x)))]);
}


// === Unary Operators ===

#[test]
fn unevaluated_argument() {
    test!("main ~foo = x",
        ,(Function::new("main", sexp![(Ident x)]).with_arg(sexp![("~" (Ident foo) () ())])));
}

#[test]
fn unary_operator_missing_operand() {
    expect_invalid_node("main ~ = x");
}

#[test]
fn unary_operator_at_end_of_expression() {
    expect_invalid_node("foo ~");
}

#[test]
fn unspaced_operator_sequence() {
    // Add a negated value.
    test_block!("x = y+-z",
        (Assignment (Ident x) (OprApp (Ident y) (Ok "+") (UnaryOprApp "-" (Ident z)))));
    // Create an operator section that adds a negated value to its input.
    test_block!("x = +-z",
        (Assignment (Ident x) (OprSectionBoundary 1
            (OprApp () (Ok "+") (UnaryOprApp "-" (Ident z))))));
    // The `-` can only be lexed as a unary operator, and unary operators cannot form sections.
    expect_invalid_node("main =\n    x = y+-");
    // Assign a negative number to x.
    test_block!("x=-1", (Assignment (Ident x) (UnaryOprApp "-" (Number () "1" ()))));
    // Assign a negated value to x.
    test_block!("x=-y", (Assignment (Ident x) (UnaryOprApp "-" (Ident y))));
}

#[test]
fn minus_binary() {
    test!("x - x", (OprApp (Ident x) (Ok "-") (Ident x)));
    test!("x-x", (OprApp (Ident x) (Ok "-") (Ident x)));
    test!("x-1", (OprApp (Ident x) (Ok "-") (Number () "1" ())));
}

#[test]
fn minus_section() {
    #[rustfmt::skip]
    let cases = [
        ("- x", block![(OprSectionBoundary 1 (OprApp () (Ok "-") (Ident x)))]),
        ("(- x)", block![(Group (OprSectionBoundary 1 (OprApp () (Ok "-") (Ident x))))]),
        ("- (x * x)", block![
            (OprSectionBoundary 1 (OprApp () (Ok "-")
             (Group (OprApp (Ident x) (Ok "*") (Ident x)))))]),
    ];
    cases.into_iter().for_each(|(code, expected)| test(code, expected));
}

#[test]
fn minus_unary() {
    test!("f -x", (App (Ident f) (UnaryOprApp "-" (Ident x))));
    test!("-x", (UnaryOprApp "-" (Ident x)));
    test!("(-x)", (Group (UnaryOprApp "-" (Ident x))));
    test!("-(x * x)", (UnaryOprApp "-" (Group (OprApp (Ident x) (Ok "*") (Ident x)))));
    test_block!("x=-x", (Assignment (Ident x) (UnaryOprApp "-" (Ident x))));
    test!("-x+x", (OprApp (UnaryOprApp "-" (Ident x)) (Ok "+") (Ident x)));
    test!("-x*x", (OprApp (UnaryOprApp "-" (Ident x)) (Ok "*") (Ident x)));
}

#[test]
fn minus_unary_decimal() {
    test!("-2.1", (UnaryOprApp "-" (Number () "2" ("." "1"))));
}

#[test]
fn minus_unary_in_method_app() {
    test!("-1.x", (OprApp (UnaryOprApp "-" (Number () "1" ())) (Ok ".") (Ident x)));
    test!("-1.up_to 100",
        (App (OprApp (UnaryOprApp "-" (Number () "1" ())) (Ok ".") (Ident up_to))
             (Number () "100" ())));
}

#[test]
fn method_app_in_minus_unary() {
    test!("-Number.positive_infinity",
        (UnaryOprApp "-" (OprApp (Ident Number) (Ok ".") (Ident positive_infinity))));
}

#[test]
fn autoscope_operator() {
    test_block!("x : ..True", (TypeSignature (Ident x) ":" (AutoscopedIdentifier ".." True)));
    test_block!("x = ..True", (Assignment (Ident x) (AutoscopedIdentifier ".." True)));
    test_block!("x = f ..True",
        (Assignment (Ident x) (App (Ident f) (AutoscopedIdentifier ".." True))));
    expect_invalid_node("x = ..not_a_constructor");
    expect_invalid_node("x = case a of ..True -> True");
    expect_invalid_node("x = ..4");
    expect_invalid_node("x = ..Foo.Bar");
    expect_invalid_node("x = f .. True");
    expect_invalid_node("x = f (.. ..)");
    expect_invalid_node("x = f (.. *)");
    expect_invalid_node("x = f (.. True)");
    expect_invalid_node("x = True..");
    expect_invalid_node("x = True..True");
    expect_invalid_node("x = ..");
    expect_invalid_node("x = .. True");
    expect_invalid_node("x : .. True");
}


// === Import/Export ===

#[test]
fn import() {
    #[rustfmt::skip]
    let cases = [
        ("import project.IO", block![
            (Import () () ((Ident import) (OprApp (Ident project) (Ok ".") (Ident IO))) () () ())]),
        ("import Standard.Base as Enso_List", block![
            (Import () ()
             ((Ident import) (OprApp (Ident Standard) (Ok ".") (Ident Base)))
             ()
             ((Ident as) (Ident Enso_List))
             ())]),
        ("from Standard.Base import all", block![
            (Import ()
             ((Ident from) (OprApp (Ident Standard) (Ok ".") (Ident Base)))
             ((Ident import) ())
             all () ())]),
        ("from Standard.Base import all hiding Number, Boolean", block![
            (Import ()
             ((Ident from) (OprApp (Ident Standard) (Ok ".") (Ident Base)))
             ((Ident import) ())
             all
             ()
             ((Ident hiding) (OprApp (Ident Number) (Ok ",") (Ident Boolean))))]),
        ("polyglot java import java.lang.Float", block![
            (Import
             ((Ident polyglot) (Ident java))
             ()
             ((Ident import)
              (OprApp (OprApp (Ident java) (Ok ".") (Ident lang)) (Ok ".") (Ident Float)))
             () () ())]),
        ("polyglot java import java.net.URI as Java_URI", block![
            (Import
             ((Ident polyglot) (Ident java))
             ()
             ((Ident import)
              (OprApp (OprApp (Ident java) (Ok ".") (Ident net)) (Ok ".") (Ident URI)))
             ()
             ((Ident as) (Ident Java_URI))
             ())]),
        ("from Standard.Base import Foo, Bar, Baz", block![
            (Import ()
             ((Ident from) (OprApp (Ident Standard) (Ok ".") (Ident Base)))
             ((Ident import) (OprApp (OprApp (Ident Foo) (Ok ",") (Ident Bar)) (Ok ",") (Ident Baz)))
             () () ())]),
    ];
    cases.into_iter().for_each(|(code, expected)| test(code, expected));
    expect_invalid_node("from Standard.Base.Data.Array import new as array_new");
}

#[test]
fn export() {
    test!("export prj.Data.Foo",
        (Export ()
         ((Ident export)
          (OprApp (OprApp (Ident prj) (Ok ".") (Ident Data)) (Ok ".") (Ident Foo)))
         ()));
    test!("export Foo as Bar",
        (Export () ((Ident export) (Ident Foo)) ((Ident as) (Ident Bar))));
    test!("from Foo export Bar, Baz",
        (Export
         ((Ident from) (Ident Foo))
         ((Ident export) (OprApp (Ident Bar) (Ok ",") (Ident Baz)))
         ()));
    expect_invalid_node("from Foo export all hiding Bar, Baz");
    test!("from Foo export all", (Invalid));
}


// === Metadata ===


#[test]
fn metadata_raw() {
    let code = [
        "x",
        "",
        "",
        "",
        "#### METADATA ####",
        r#"[[{"index":{"value":7},"size":{"value":8}},"5bad897e-099b-4b00-9348-64092636746d"]]"#,
    ];
    let code = code.join("\n");
    let (_meta, code) = enso_parser::metadata::parse(&code).unwrap();
    let expected = block![
        (Ident x)
        ()
    ];
    test(code, expected);
}

#[test]
fn metadata_parsing() {
    let code = metadata::ORDERS_WITH_METADATA;
    let (meta, code) = enso_parser::metadata::parse(code).unwrap();
    let _ast = parse(code);
    let _meta: enso_parser::metadata::Metadata = meta.unwrap();
}


// === Type annotations and signatures ===

#[test]
fn type_signatures() {
    test!("val : Bool", (TypeSignature (Ident val) ":" (Ident Bool)));
    test!("val : List Int", (TypeSignature (Ident val) ":" (App (Ident List) (Ident Int))));
    test!("foo : [Integer | Text] -> (Integer | Text)",
        (TypeSignature (Ident foo) ":"
         (OprApp (Array (OprApp (Ident Integer) (Ok "|") (Ident Text)) #())
                 (Ok "->")
                 (Group (OprApp (Ident Integer) (Ok "|") (Ident Text))))));
    test!("f a (b : Int) : Double",
        (TypeAnnotated
         (App (App (Ident f) (Ident a)) (Group (TypeAnnotated (Ident b) ":" (Ident Int))))
          ":" (Ident Double)));
    test!("f a (b = 1 : Int) : Double",
        (TypeAnnotated
         (NamedApp (App (Ident f) (Ident a)) b
          (TypeAnnotated (Number () "1" ()) ":" (Ident Int))) ":" (Ident Double)));
}

#[test]
fn type_annotations() {
    test_block!("val = x : Int",
        (Assignment (Ident val) (TypeAnnotated (Ident x) ":" (Ident Int))));
    test_block!("val = foo (x : Int)",
        (Assignment (Ident val)
         (App (Ident foo)
          (Group (TypeAnnotated (Ident x) ":" (Ident Int))))));
    test!("(x : My_Type _)",
        (Group
         (TypeAnnotated (Ident x)
                        ":"
                        (App (Ident My_Type) (TemplateFunction 1 (Wildcard 0))))));
    test!("x : List Int -> Int",
        (TypeSignature (Ident x) ":"
         (OprApp (App (Ident List) (Ident Int)) (Ok "->") (Ident Int))));
    test!("p:Plus + m:Plus",
        (OprApp (TypeAnnotated (Ident p) ":" (Ident Plus))
         (Ok "+") (TypeAnnotated (Ident m) ":" (Ident Plus))));
}


// === Text Literals ===

#[test]
fn inline_text_literals() {
    test!(r#""I'm an inline raw text!""#, (TextLiteral #((Section "I'm an inline raw text!"))));
    test_block!(r#"zero_length = """#, (Assignment (Ident zero_length) (TextLiteral #())));
    test!(r#""type""#, (TextLiteral #((Section "type"))));
    test_block!(r#"unclosed = ""#, (Assignment (Ident unclosed) (TextLiteral #())));
    test_block!(r#"unclosed = "a"#, (Assignment (Ident unclosed) (TextLiteral #((Section "a")))));
    test!(r#"'Other quote type'"#, (TextLiteral #((Section "Other quote type"))));
    test!(r#""Non-escape: \n""#, (TextLiteral #((Section "Non-escape: \\n"))));
    test!(r#""Non-escape: \""#, (TextLiteral #((Section "Non-escape: \\"))));
    test!(r#"'String with \' escape'"#,
        (TextLiteral #((Section "String with ") (Escape 0x27) (Section " escape"))));
    test!(r#"'\u0915\u094D\u0937\u093F'"#, (TextLiteral
        #((Escape 0x0915) (Escape 0x094D) (Escape 0x0937) (Escape 0x093F))));
    test!(r#"('\n')"#, (Group (TextLiteral #((Escape 0x0A)))));
    test!(r#"`"#, (Invalid));
    test!(r#"(")")"#, (Group (TextLiteral #((Section ")")))));
    test!(r#"'\x'"#, (TextLiteral #((Escape 0xFFFFFFFFu32))));
    test!(r#"'\u'"#, (TextLiteral #((Escape 0xFFFFFFFFu32))));
    test!(r#"'\U'"#, (TextLiteral #((Escape 0xFFFFFFFFu32))));
}

#[test]
fn multiline_text_literals() {
    test!("'''", (TextLiteral #()));
    let code = r#""""
    part of the string
       3-spaces indented line, part of the Text Block
    this does not end the string -> '''

    `also` part of the string

x"#;
    test!(code,
        (TextLiteral
         #((Section "part of the string") (Newline)
           (Section "   3-spaces indented line, part of the Text Block") (Newline)
           (Section "this does not end the string -> '''") (Newline)
           (Newline)
           (Section "`also` part of the string")))
        ()
        (Ident x));
    test!(r#""""
    multiline string that doesn't end in a newline
x"#,
        (TextLiteral #((Section "multiline string that doesn't end in a newline")))
        (Ident x));
    test_block!("x = \"\"\"\n    Indented multiline\nx",
        (Assignment (Ident x) (TextLiteral #((Section "Indented multiline"))))
        (Ident x));
    test!("'''\n    \\nEscape at start\n",
        (TextLiteral #((Escape 0x0A) (Section "Escape at start"))) ());
    test!("x =\n x = '''\n  x\nx",
        ,(Function::new("x", block![(Assignment (Ident x) (TextLiteral #((Section "x"))))]))
        (Ident x));
    test_block!("foo = bar '''\n baz",
        (Assignment (Ident foo) (App (Ident bar) (TextLiteral #((Section "baz"))))));
    test!("'''\n \\t'", (TextLiteral #((Escape 0x09) (Section "'"))));
    test!("'''\n x\n \\t'", (TextLiteral #((Section "x") (Newline) (Escape 0x09) (Section "'"))));
}

#[test]
fn interpolated_literals_in_inline_text() {
    test!(r#"'Simple case.'"#, (TextLiteral #((Section "Simple case."))));
    test!(r#"'With a `splice`.'"#, (TextLiteral
        #((Section "With a ")
          (Splice (Ident splice))
          (Section "."))));
    test!(r#"'` SpliceWithLeadingWhitespace`'"#,
        (TextLiteral #((Splice (Ident SpliceWithLeadingWhitespace)))));
    test!(r#"'String with \n escape'"#,
        (TextLiteral #((Section "String with ") (Escape 0x0A) (Section " escape"))));
    test!(r#"'\x0Aescape'"#, (TextLiteral #((Escape 0x0A) (Section "escape"))));
    test!(r#"'\u000Aescape'"#, (TextLiteral #((Escape 0x0A) (Section "escape"))));
    test!(r#"'\u{0000A}escape'"#, (TextLiteral #((Escape 0x0A) (Section "escape"))));
    test!(r#"'\U0000000Aescape'"#, (TextLiteral #((Escape 0x0A) (Section "escape"))));
}

#[test]
fn interpolated_literals_in_multiline_text() {
    let code = r#"'''
    `splice` at start"#;
    #[rustfmt::skip]
    let expected = block![
        (TextLiteral #((Splice (Ident splice)) (Section " at start")))];
    test(code, expected);

    let code = r#"'''
    text with a `splice`
    and some \u000Aescapes\'"#;
    #[rustfmt::skip]
    let expected = block![
        (TextLiteral
         #((Section "text with a ") (Splice (Ident splice)) (Newline)
           (Section "and some ") (Escape 0x0A) (Section "escapes") (Escape 0x27)))];
    test(code, expected);
}


// === Lambdas ===

#[test]
fn new_lambdas() {
    test!(r#"\v-> v"#, (Lambda "\\" #((() (Ident v) () ())) "->" (Ident v)));
    test!(r#"\ v -> v"#, (Lambda "\\" #((() (Ident v) () ())) "->" (Ident v)));
    test!(r#"\v -> v"#, (Lambda "\\" #((() (Ident v) () ())) "->" (Ident v)));
    test!(r#"\ v-> v"#, (Lambda "\\" #((() (Ident v) () ())) "->" (Ident v)));
    test!(r#"\ x -> x + y"#,
        (Lambda "\\" #((() (Ident x) () ())) "->" (OprApp (Ident x) (Ok "+") (Ident y))));
    test!("\\v->\n    v", (Lambda "\\" #((() (Ident v) () ())) "->" (BodyBlock #((Ident v)))));
    test!("\\ v ->\n    v", (Lambda "\\" #((() (Ident v) () ())) "->" (BodyBlock #((Ident v)))));
    test!("f \\ v ->\n    v",
        (App (Ident f) (Lambda "\\" #((() (Ident v) () ())) "->" (BodyBlock #((Ident v))))));
    test!(r#"\a b -> x"#,
        (Lambda "\\" #((() (Ident a) () ()) (() (Ident b) () ())) "->" (Ident x)));
    test!(r#"\~x -> x"#, (Lambda "\\" #(("~" (Ident x) () ())) "->" (Ident x)));
    test!(r#"\a (b = f _ 1) -> f a"#,
        (Lambda "\\"
         #((() (Ident a) () ())
           (() (Ident b) ()
               ((App (App (Ident f) (TemplateFunction 1 (Wildcard 0)))
                     (Number () "1" ())))))
         "->" (App (Ident f) (Ident a))));
    expect_invalid_node("\\");
    expect_invalid_node("\\ v");
    expect_invalid_node("\\v");
    expect_invalid_node("\\v->");
    expect_invalid_node("\\v->\n");
    expect_invalid_node("\\v->\nv");
}

#[test]
fn old_lambdas() {
    test!("x -> y", (OprApp (Ident x) (Ok "->") (Ident y)));
    test!("x->y", (OprApp (Ident x) (Ok "->") (Ident y)));
    test!("x-> y", (OprApp (Ident x) (Ok "->") (Ident y)));
    test!("x-> x + y", (OprApp (Ident x) (Ok "->") (OprApp (Ident x) (Ok "+") (Ident y))));
    test!("x->\n y", (OprApp (Ident x) (Ok "->") (BodyBlock #((Ident y)))));
    test!("x ->\n y", (OprApp (Ident x) (Ok "->") (BodyBlock #((Ident y)))));
    test!("f x->\n y",
        (App (Ident f) (OprApp (Ident x) (Ok "->") (BodyBlock #((Ident y))))));
    test!("x->y-> z", (OprApp (Ident x) (Ok "->") (OprApp (Ident y) (Ok "->") (Ident z))));
    test_block!("foo = x -> (y = bar x) -> x + y",
        (Assignment (Ident foo)
         (OprApp (Ident x) (Ok "->")
          (OprApp (Group (OprApp (Ident y) (Ok "=") (App (Ident bar) (Ident x)))) (Ok "->")
           (OprApp (Ident x) (Ok "+") (Ident y))))));
}


// === Pattern Matching ===

#[test]
fn pattern_irrefutable() {
    test_block!("Point x_val = my_point",
        (Assignment (App (Ident Point) (Ident x_val)) (Ident my_point)));
    test_block!("Vector _ = x", (Assignment (App (Ident Vector) (Wildcard -1)) (Ident x)));
    test_block!("X.y = z",
        ,(Function::named(sexp![(OprApp (Ident X) (Ok ".") (Ident y))], sexp![(Ident z)])));
}

#[test]
fn pattern_invalid() {
    expect_invalid_node("x + y = z");
    expect_invalid_node("(x y) = z");
}

#[test]
fn case_expression() {
    #[rustfmt::skip]
    let code = [
        "case a of",
        "    Some -> x",
        "    Int -> x",
    ];
    test!(code.join("\n"),
        (CaseOf (Ident a) #(
         ((() (Ident Some) "->" (Ident x)))
         ((() (Ident Int) "->" (Ident x))))));

    let code = ["case a of", "    Vector_2d x y -> x"];
    test!(code.join("\n"),
        (CaseOf (Ident a) #(
         ((() (App (App (Ident Vector_2d) (Ident x)) (Ident y)) "->" (Ident x))))));

    #[rustfmt::skip]
    let code = [
        "case self of",
        "    Vector_2d -> x",
        "    _ -> x",
    ];
    test!(code.join("\n"),
        (CaseOf (Ident self) #(
         ((() (Ident Vector_2d) "->" (Ident x)))
         ((() (Wildcard -1) "->" (Ident x))))));

    #[rustfmt::skip]
    let code = [
        "case foo of",
        "    v:My_Type -> x",
        "    v:(My_Type _ _) -> x",
    ];
    test!(code.join("\n"),
        (CaseOf (Ident foo) #(
         ((() (TypeAnnotated (Ident v) ":" (Ident My_Type)) "->" (Ident x)))
         ((() (TypeAnnotated (Ident v) ":"
          (Group (App
                  (App
                   (Ident My_Type)
                   (TemplateFunction 1 (Wildcard 0)))
                  (TemplateFunction 1 (Wildcard 0)))))
          "->" (Ident x))))));
}

#[test]
fn case_documentation() {
    #[rustfmt::skip]
    let code = [
        "case a of",
        "    ## The Some case",
        "    Some -> x",
        "    ## The Int case",
        "    Int -> x",
    ];
    #[rustfmt::skip]
    let expected = block![
        (CaseOf (Ident a) #(
            (((#((Section " The Some case")) #()) () () ()))
            ((() (Ident Some) "->" (Ident x)))
            (((#((Section " The Int case")) #()) () () ()))
            ((() (Ident Int) "->" (Ident x)))))
    ];
    test(code.join("\n"), expected);
}

#[test]
fn case_by_type() {
    macro_rules! test_case {
        ( $code:expr, $case:tt ) => {
            test(&format!("case foo of\n {}", $code), block![(CaseOf (Ident foo) #(($case)))]);
        }
    }
    test_case!("f:A->B -> x",
        (() (TypeAnnotated (Ident f) ":" (OprApp (Ident A) (Ok "->") (Ident B))) "->" (Ident x)));
    test_case!("f : A->B -> x",
        (() (TypeAnnotated (Ident f) ":" (OprApp (Ident A) (Ok "->") (Ident B))) "->" (Ident x)));
    test_case!("v : A -> x->x",
        (() (TypeAnnotated (Ident v) ":" (Ident A)) "->" (OprApp (Ident x) (Ok "->") (Ident x))));
    test_case!("v : A -> x -> x",
        (() (TypeAnnotated (Ident v) ":" (Ident A)) "->" (OprApp (Ident x) (Ok "->") (Ident x))));
    test_case!("v:A->x->x",
        (() (TypeAnnotated (Ident v) ":" (Ident A)) "->" (OprApp (Ident x) (Ok "->") (Ident x))));
    test_case!("v:A->x", (() (TypeAnnotated (Ident v) ":" (Ident A)) "->" (Ident x)));
    test_case!("v : A -> _ + x",
        (() (TypeAnnotated (Ident v) ":" (Ident A)) "->"
         (TemplateFunction 1 (OprApp (Wildcard 0) (Ok "+") (Ident x)))));
}

#[test]
fn suspended_default_arguments_in_pattern() {
    test!("case self of\n    Vector_2d ... -> x",
        (CaseOf (Ident self)
         #(((() (App (Ident Vector_2d) (SuspendedDefaultArguments)) "->" (Ident x))))))
}

#[test]
fn suspended_default_arguments_in_expression() {
    test_block!("c = self.value ...",
        (Assignment (Ident c)
         (App (OprApp (Ident self) (Ok ".") (Ident value)) (SuspendedDefaultArguments))));
    test_block!("c = self.value...",
        (Assignment (Ident c)
         (App (OprApp (Ident self) (Ok ".") (Ident value)) (SuspendedDefaultArguments))));
}

// === Private (project-private) keyword ===

#[test]
fn private_keyword() {
    test!("private", (Private private));
    expect_invalid_node("private func");
    // Private binding is not supported.
    expect_invalid_node("main =\n    private var = 42");
    // Private function is not allowed in body block.
    expect_invalid_node("main =\n    private func x = 42");
    expect_invalid_node("private ConstructorOutsideType");
    expect_invalid_node("type My_Type\n    private");
    expect_invalid_node("private type My_Type\n    Ctor");
}

#[test]
fn private_methods() {
    test!("private method x = x",
        ,(Function::new("method", sexp![(Ident x)]).private().with_arg("x")));
    test!("private method =\n    42",
        ,(Function::new("method", block![(Number () "42" ())]).private()));
    test!("type T\n    private method x = x",
         (TypeDef T #() #(
          ,(Function::new("method", sexp![(Ident x)]).private().with_arg("x")))));
}


#[test]
#[ignore]
fn private_is_first_statement() {
    // Comments and empty lines are allowed before `private`.
    #[rustfmt::skip]
    let lines = [
        "# Some comment",
        "# Other comment",
        "",
        "private"
    ];
    test(lines.join("\n"), block![()()()(Private)]);

    #[rustfmt::skip]
    let lines = [
        "type T",
        "",
        "private"
    ];
    expect_invalid_node(&lines.join("\n"));
}

// === Array/tuple literals ===

#[test]
fn array_literals() {
    let cases = [
        ("[]", block![(Array () #())]),
        ("[x]", block![(Array (Ident x) #())]),
        ("[x, y]", block![(Array (Ident x) #(("," (Ident y))))]),
        ("[x, y, z]", block![(Array (Ident x) #(("," (Ident y)) ("," (Ident z))))]),
        ("[ x , y ]", block![(Array (Ident x) #(("," (Ident y))))]),
        ("[ x , y , z ]", block![(Array (Ident x) #(("," (Ident y)) ("," (Ident z))))]),
    ];
    cases.into_iter().for_each(|(code, expected)| test(code, expected));
}

#[test]
fn tuple_literals() {
    let cases = [
        ("{}", block![(Tuple () #())]),
        ("{x}", block![(Tuple (Ident x) #())]),
        ("{x, y}", block![(Tuple (Ident x) #(("," (Ident y))))]),
    ];
    cases.into_iter().for_each(|(code, expected)| test(code, expected));
}


// === Numeric literals ===

#[cfg(test)]
mod numbers {
    use super::*;

    #[test]
    fn with_decimal() {
        test_block!("pi = 3.14", (Assignment (Ident pi) (Number () "3" ("." "14"))));
    }

    #[test]
    fn digits_spaced_dot() {
        test!("1 . 0", (OprApp (Number () "1" ()) (Ok ".") (Number () "0" ())));
        test!("1 .0",
            (App (Number () "1" ()) (OprSectionBoundary 1 (OprApp () (Ok ".") (Number () "0" ())))));
        test!("1. 0",
            (OprSectionBoundary 1 (App (OprApp (Number () "1" ()) (Ok ".") ()) (Number () "0" ()))));
    }

    #[test]
    fn non_digits_dot_digits() {
        test!("x.0", (OprApp (Ident x) (Ok ".") (Number () "0" ())));
    }

    #[test]
    fn digits_dot_non_digits() {
        test!("0.0.x", (OprApp (Number () "0" ("." "0")) (Ok ".") (Ident x)));
        test!("1.0.0", (OprApp (Number () "1" ("." "0")) (Ok ".") (Number () "0" ())));
        test!("1.0x", (OprApp (Number () "1" ()) (Ok ".") (Number "0x" () ())));
        test!("876543.is_even.should_be_false",
            (OprApp
             (OprApp (Number () "876543" ()) (Ok ".") (Ident is_even))
             (Ok ".")
             (Ident should_be_false)));
    }

    #[test]
    fn with_base() {
        test!("0b10101010", (Number "0b" "10101010" ()));
        test!("0o122137", (Number "0o" "122137" ()));
        test!("0xAE2F14", (Number "0x" "AE2F14" ()));
    }

    #[test]
    fn base_only() {
        test!("0x", (Number "0x" () ()));
        test!("0b", (Number "0b" () ()));
        test!("0o", (Number "0o" () ()));
    }

    #[test]
    fn delimited() {
        test!("100_000", (Number () "100_000" ()));
        test!("10_000.99", (Number () "10_000" ("." "99")));
    }

    #[test]
    fn old_hex() {
        expect_invalid_node("16_17ffffffffffffffa");
    }
}


// === Whitespace ===

#[test]
fn trailing_whitespace() {
    test!("a ", (Ident a) ());
    test!("a \n", (Ident a) ());
    test!("a = \n x", ,(Function::new("a", block![(Ident x)])));
}


// === Annotations ===

#[test]
fn at_operator() {
    expect_invalid_node("foo@bar");
    expect_invalid_node("foo @ bar");
}

#[test]
fn attributes() {
    test!("@on_problems P.g\nTable.select_columns : Text -> Table",
        (Annotated on_problems
         (OprApp (Ident P) (Ok ".") (Ident g))
         #(())
         (TypeSignature (OprApp (Ident Table) (Ok ".") (Ident select_columns))
                        ":"
                        (OprApp (Ident Text) (Ok "->") (Ident Table)))));
    test!("@a z\n@b\nx", (Annotated a (Ident z) #(()) (Annotated b () #(()) (Ident x))));
    test!("@a\n@b\nx", (Annotated a () #(()) (Annotated b () #(()) (Ident x))));
}

#[test]
fn attributes_in_types() {
    test!("type A\n @a z\n @b\n x y = x",
        (TypeDef A #() #(
         (Annotated a (Ident z) #(())
          (Annotated b () #(())
           ,(Function::new("x", sexp![(Ident x)]).with_arg("y")))))));
}

#[test]
fn inline_builtin_annotations() {
    test!("@Tail_Call go t", (AnnotatedBuiltin Tail_Call #() (App (Ident go) (Ident t))));
    test!("@Tail_Call go (x = y)",
        (AnnotatedBuiltin Tail_Call #() (NamedApp (Ident go) x (Ident y))));
    test!("@Tail_Call go\n a\n b",
        (AnnotatedBuiltin Tail_Call #()
         (ArgumentBlockApplication (Ident go) #((Ident a) (Ident b)))));
    test!("map _-> @Tail_Call f",
        (App (Ident map)
         (OprApp (Wildcard 0) (Ok "->") (AnnotatedBuiltin Tail_Call #() (Ident f)))));
}

#[test]
fn multiline_builtin_annotations() {
    test!("@Builtin_Type\ntype Date",
        (AnnotatedBuiltin Builtin_Type #(()) (TypeDef Date #() #())));
}


// === SKIP and FREEZE ===

#[test]
fn freeze() {
    test!("FREEZE x", (MultiSegmentApp #(((Ident FREEZE) (Ident x)))));
    test!("FREEZE x + y", (MultiSegmentApp
                           #(((Ident FREEZE) (OprApp (Ident x) (Ok "+") (Ident y))))));
    test!("FREEZE x.f", (MultiSegmentApp
                         #(((Ident FREEZE) (OprApp (Ident x) (Ok ".") (Ident f))))));
    test!("FREEZE x.f y", (MultiSegmentApp #(((Ident FREEZE)
                           (App (OprApp (Ident x) (Ok ".") (Ident f)) (Ident y))))));
}

#[test]
fn skip() {
    test!("SKIP x", (MultiSegmentApp #(((Ident SKIP) (Ident x)))));
    test!("SKIP x + y", (MultiSegmentApp #(((Ident SKIP) (OprApp (Ident x) (Ok "+") (Ident y))))));
    test!("SKIP x.f", (MultiSegmentApp #(((Ident SKIP) (OprApp (Ident x) (Ok ".") (Ident f))))));
    test!("SKIP x.f y", (MultiSegmentApp #(((Ident SKIP)
                         (App (OprApp (Ident x) (Ok ".") (Ident f)) (Ident y))))));
}

// === Context errors ===

#[test]
fn statement_in_expression_context() {
    test_block!("x = y = z", (Assignment (Ident x) (Invalid)));
    test!("(y = z)", (Group(Invalid)));
    test!("(y = z) x", (App (Group (Invalid)) (Ident x)));
    test_block!("(f x = x)", (Group(Invalid)));
    test_block!("y = f x = x", (Assignment (Ident y) (Invalid)));
}



// =========================
// === Scalability Tests ===
// =========================

/// Test an input that caused a stack overflow in a version of the parser that used recursion to
/// resolve macro segments.
#[test]
fn big_array() {
    let mut big_array = "[".to_owned();
    // This value was chosen to be large enough to cause a stack overflow, but not so large that it
    // would take a long time to do so.
    let array_length = 1000;
    for _ in 0..array_length {
        big_array.push_str(
            r#"[{"index":{"value":1},"size":{"value":8}},"6063e6d3-3341-40f4-b4fb-7e986eb31ae8"],"#,
        );
    }
    big_array.push_str("1]");
    expect_valid(&big_array);
}



// ==========================
// === Syntax Error Tests ===
// ==========================

#[test]
fn space_required() {
    expect_invalid_node("foo = if cond.x else.y");
}

#[test]
fn incomplete_type_definition() {
    expect_invalid_node("type");
}

#[test]
fn bad_case() {
    expect_invalid_node("foo = case x of\n 4");
    expect_invalid_node("foo = case x of\n 4 ->");
    expect_invalid_node("foo = case x of\n 4->");
}

#[test]
fn malformed_sequence() {
    expect_invalid_node("(1, )");
    expect_invalid_node("foo = (1, )");
}

#[test]
fn unmatched_delimiter() {
    expect_invalid_node("(");
    expect_invalid_node(")");
    expect_invalid_node("[");
    expect_invalid_node("]");
    expect_invalid_node("foo = (");
    expect_invalid_node("foo = )");
    expect_invalid_node("foo = [");
    expect_invalid_node("foo = ]");
}

#[test]
fn unexpected_special_operator() {
    expect_invalid_node("foo = 1, 2");
}

#[test]
fn malformed_import() {
    expect_invalid_node("import");
    expect_invalid_node("import as Foo");
    expect_invalid_node("import Foo as Foo, Bar");
    expect_invalid_node("import Foo as Foo.Bar");
    expect_invalid_node("import Foo as");
    expect_invalid_node("import Foo as Bar.Baz");
    expect_invalid_node("import Foo hiding");
    expect_invalid_node("import Foo hiding X,");
    expect_invalid_node("polyglot import Foo");
    expect_invalid_node("polyglot java import");
    expect_invalid_node("from import all");
    expect_invalid_node("from Foo import all hiding");
    expect_invalid_node("from Foo import all hiding X.Y");
    expect_invalid_node("export");
    expect_invalid_node("export as Foo");
    expect_invalid_node("export Foo as Foo, Bar");
    expect_invalid_node("export Foo as Foo.Bar");
    expect_invalid_node("export Foo as");
    expect_invalid_node("export Foo as Bar.Baz");
    expect_invalid_node("export Foo hiding");
    expect_invalid_node("export Foo hiding X,");
    expect_invalid_node("from export all");
    expect_invalid_node("from Foo export all hiding");
    expect_invalid_node("from Foo export all hiding X.Y");
}

#[test]
fn invalid_token() {
    expect_invalid_node("`");
    expect_invalid_node("splice_outside_text = `");
}

#[test]
fn illegal_foreign_body() {
    // Foreign is only a keyword on the LHS of an assignment operator.
    test!("foreign 4", (App (Ident foreign) (Number () "4" ())));
    // Missing name
    expect_invalid_node("foreign foo = \"4\"");
    // Body must be a type
    expect_invalid_node("foreign js foo = 4");
}

#[test]
fn unexpected_tokens_in_inner_macro_segment() {
    expect_invalid_node("from Foo import all What_Is_This_Doing_Here hiding Bar");
}

#[test]
fn invalid_unspaced_operator_sequence() {
    // Typically, a sequence of operator identifiers is lexed as a single operator. However, an
    // exception is made for some sequences of operator characters ending in the `-` character: An
    // expression such as `x+-x` is accepted, and read equivalently to `x + -x` (see
    // [`unspaced_operator_sequence`]).
    //
    // Due to this special case, there is no reasonable way to interpret this type of expression as
    // valid when spaces are added in the following way:
    expect_invalid_node("x = y +- z");
    expect_multiple_operator_error("x =- y");
    //
    // Treating the `-` as a unary operator applied to `z` would be confusing, as it would be in
    // contradiction to the associativity implied by the whitespace rules.
    //
    // However, it would also be confusing to lex a sequence of characters like `+-` as a single
    // operator in spaced expressions, but as two operators in unspaced expressions.
    //
    // Lacking any reasonable valid interpretation, we treat this case as an error.
    //
    // Similar expressions with missing operands should be treated likewise:
    expect_invalid_node("x = y +-");
    expect_invalid_node("x = +- z");
    expect_multiple_operator_error("x =-");
    expect_multiple_operator_error("=- y");
    expect_multiple_operator_error("=-");
}

#[test]
fn nonsense_inputs() {
    expect_invalid_node("`a (b = 1).`");
    expect_invalid_node("type M = B<d f<'a> F(M<'a>) -> S>;");
    expect_invalid_node("'`'\nx `y`\nz");
    expect_invalid_node("if (asGuestValue\n  a");
    expect_invalid_node("foo(\n  a");
    expect_invalid_node("(Vector(), true)");
}

#[test]
#[ignore]
fn nonsense_inputs_broken() {
    // FIXME
    expect_invalid_node("'`\n");
    expect_invalid_node(".'\\\n");
}



// ====================
// === Test Support ===
// ====================


// === Testing helpers ===

/// Check that the given [`Tree`] is a valid representation of the given source code:
/// - Assert that the given [`Tree`] is composed of tokens that concatenate back to the given source
///   code.
/// - Assert that the given [`Tree`] can be serialized and deserialized without error.
fn expect_tree_representing_code(code: &str, ast: &enso_parser::syntax::Tree) {
    assert_eq!(ast.code(), code, "{:?}", &ast);
    let serialized = enso_parser::serialization::serialize_tree(ast).unwrap();
    let deserialized = enso_parser::serialization::deserialize_tree(&serialized);
    deserialized.unwrap();
}


// === Testing valid inputs ===

/// Given a block of input Enso code, test that:
/// - The given code parses to the AST represented by the given S-expression.
/// - The AST pretty-prints back to the original code.
/// - Rust's deserialization is compatible with Rust's serialization for the type. (The Java format
///   tests check Java's deserialization against Rust's deserialization).
///
/// The S-expression format is as documented for [`enso_metamodel_lexpr`], with some
/// postprocessing:
/// - For concision, field names are stripped (as if all structs were tuple structs).
/// - Most token types are represented as their contents, rather than as a token struct. For
///   example, a `token::Number` may be represented like: `sexp![10]`, and a `token::Ident` may look
///   like `sexp![foo]`.
fn test<T: AsRef<str>>(code: T, expect: lexpr::Value) {
    let code = code.as_ref();
    let ast = parse(code);
    let ast_s_expr = to_s_expr(&ast, code);
    assert_eq!(ast_s_expr.to_string(), expect.to_string(), "{:?}", &ast);
    expect_tree_representing_code(code, &ast);
}

fn test_block<T: AsRef<str>>(code: T, expect: lexpr::Value) {
    let code = code.as_ref();
    let ast = parse_block(code);
    let ast_s_expr = to_s_expr(&ast, code);
    assert_eq!(ast_s_expr.to_string(), expect.to_string(), "{:?}", &ast);
    expect_tree_representing_code(code, &ast);
}

fn parse(code: &str) -> enso_parser::syntax::tree::Tree {
    let ast = enso_parser::Parser::new().parse_module(code);
    validate_parse(code, &ast);
    ast
}

fn parse_block(code: &str) -> enso_parser::syntax::tree::Tree {
    let ast = enso_parser::Parser::new().parse_block(code);
    validate_parse(code, &ast);
    ast
}

fn validate_parse(code: &str, ast: &enso_parser::syntax::Tree) {
    let expected_span = 0..(code.encode_utf16().count() as u32);
    let mut locations = enso_parser::source::code::debug::LocationCheck::new();
    enso_parser_debug::validate_spans(ast, expected_span, &mut locations).unwrap();
    locations.check(code);
}


// === Testing inputs containing syntax errors ===

#[derive(Debug, Eq, PartialEq, Default, Copy, Clone)]
struct Errors {
    invalid_node:      bool,
    multiple_operator: bool,
}

impl Errors {
    fn collect(ast: &enso_parser::syntax::Tree, code: &str) -> Self {
        expect_tree_representing_code(code, ast);
        let errors = core::cell::Cell::new(Errors::default());
        ast.visit_trees(|tree| match &tree.variant {
            enso_parser::syntax::tree::Variant::Invalid(_) => {
                errors.set(Self { invalid_node: true, ..errors.get() });
            }
            enso_parser::syntax::tree::Variant::OprApp(opr_app) if opr_app.opr.is_err() => {
                errors.set(Self { multiple_operator: true, ..errors.get() });
            }
            _ => (),
        });
        errors.into_inner()
    }
}

/// Checks that an input contains an `Invalid` node somewhere.
fn expect_invalid_node(code: &str) {
    let ast = enso_parser::Parser::new().parse_module(code);
    expect_tree_representing_code(code, &ast);
    let errors = Errors::collect(&ast, code);
    assert!(errors.invalid_node, "{}", to_s_expr(&ast, code));
}

/// Checks that an input contains a multiple-operator error somewhere.
fn expect_multiple_operator_error(code: &str) {
    let ast = enso_parser::Parser::new().parse_module(code);
    expect_tree_representing_code(code, &ast);
    let errors = Errors::collect(&ast, code);
    assert!(errors.multiple_operator || errors.invalid_node, "{}", to_s_expr(&ast, code));
    assert!(errors.multiple_operator, "{:?}", ast);
}

/// Check that the input can be parsed, and doesn't yield any `Invalid` nodes.
fn expect_valid(code: &str) {
    let ast = enso_parser::Parser::new().parse_module(code);
    expect_tree_representing_code(code, &ast);
    let errors = Errors::collect(&ast, code);
    assert!(!errors.invalid_node);
}

// =========================
// === Test case helpers ===
// =========================

// === Functions ===

/// Builder for function definitions.
struct Function {
    private: lexpr::Value,
    name:    lexpr::Value,
    args:    Vec<lexpr::Value>,
    body:    lexpr::Value,
    ret:     lexpr::Value,
}

impl Function {
    fn new(name: &str, body: lexpr::Value) -> Self {
        let name = lexpr::Value::symbol(name);
        Self::named(sexp![(Ident, name)], body)
    }

    fn named(name: lexpr::Value, body: lexpr::Value) -> Self {
        Self { private: sexp![()], name, args: vec![], body, ret: sexp![()] }
    }

    fn with_arg(mut self, arg: impl Into<Arg>) -> Self {
        self.args.push(arg.into().into());
        self
    }

    fn with_return(self, ret: lexpr::Value) -> Self {
        Self { ret: sexp![("->", ret)], ..self }
    }

    fn private(self) -> Self {
        Self { private: sexp![private], ..self }
    }
}

impl From<Function> for lexpr::Value {
    #[rustfmt::skip]
    fn from(Function { private, name, args, ret, body }: Function) -> Self {
        sexp![(Function ,private ,name ,args ,ret ,body)]
    }
}

struct Arg(lexpr::Value);

impl From<&str> for Arg {
    fn from(name: &str) -> Self {
        let name = lexpr::Value::symbol(name);
        Self(sexp![(()(Ident, name)()())])
    }
}

impl From<lexpr::Value> for Arg {
    fn from(arg: lexpr::Value) -> Self {
        Self(arg)
    }
}

impl From<Arg> for lexpr::Value {
    fn from(Arg(arg): Arg) -> Self {
        arg
    }
}