.assert_msg_has(1, "has been resolved to 'bool'");

    });

}

#[test]

fn test_correct_tuple_members() {

    // Tuples with zero members

    Tester::new_single_source_expect_ok(

        "single zero-tuple",

        "struct Foo{ () bar }"

    ).for_struct("Foo", |s| { s

        .for_field("bar", |f| { f.assert_parser_type("()"); })

        .assert_size_alignment("Foo", 0, 1);

    });

    Tester::new_single_source_expect_ok(

        "triple zero-tuple",

        "struct Foo{ () bar, () baz, () qux }"

    ).for_struct("Foo", |s| { s

        .assert_size_alignment("Foo", 0, 1);

    });

    // Tuples with one member (which are elided, because due to ambiguity

    // between a one-tuple literal and a parenthesized expression, we're not

    // going to be able to construct one-tuples).

    Tester::new_single_source_expect_ok(

        "single elided one-tuple",

        "struct Foo{ (u32) bar }"

    ).for_struct("Foo", |s| { s

        .for_field("bar", |f| { f.assert_parser_type("u32"); })

        .assert_size_alignment("Foo", 4, 4);

    });

    Tester::new_single_source_expect_ok(

        "triple elided one-tuple",

        "struct Foo{ (u8) bar, (u16) baz, (u32) qux }"

    ).for_struct("Foo", |s| { s

        .assert_size_alignment("Foo", 8, 4);

    });

    // Tuples with three members

    Tester::new_single_source_expect_ok(

        "single three-tuple",

        "struct Foo{ (u8, u16, u32) bar }"

    ).for_struct("Foo", |s| { s

        .for_field("bar", |f| { f.assert_parser_type("(u8,u16,u32)"); })

        .assert_size_alignment("Foo", 8, 4);

    });

    Tester::new_single_source_expect_ok(

        "double three-tuple",

        "struct Foo{ (u8,u16,u32,) bar, (s8,s16,s32,) baz }"

    ).for_struct("Foo", |s| { s

        .for_field("bar", |f| { f.assert_parser_type("(u8,u16,u32)"); })

        .for_field("baz", |f| { f.assert_parser_type("(s8,s16,s32)"); })

        .assert_size_alignment("Foo", 16, 4);

    });

}

#[test]

fn test_incorrect_tuple_member() {

    // Test not really necessary, but hey, what's a test between friends

    Tester::new_single_source_expect_err(

        "unknown tuple member",

        "struct Foo{ (u32, u32, u32, YouThirstySchmoo) field }"

    ).error(|e| { e

        .assert_num(1)

        .assert_msg_has(0, "unknown type")

        .assert_occurs_at(0, "YouThirstySchmoo");

    });

}

#[test]

fn test_correct_tuple_polymorph_args() {

    Tester::new_single_source_expect_ok(

        "single tuple arg",

        "

        union Option<T>{ Some(T), None }

        func thing() -> u32 {

            auto a = Option<()>::None;

            auto b = Option<(u32, u64)>::None;

            auto c = Option<(Option<(u8, s8)>, Option<(s8, u8)>)>::None;

            return 0;

        }

        "

    ).for_union("Option", |u| { u

        .assert_has_monomorph("Option<()>")

        .assert_has_monomorph("Option<(u32,u64)>")

        .assert_has_monomorph("Option<(Option<(u8,s8)>,Option<(s8,u8)>)>")

        .assert_size_alignment("Option<()>", 1, 1, 0, 0)

        .assert_size_alignment("Option<(u32,u64)>", 24, 8, 0, 0) // (u32, u64) becomes size 16, alignment 8. Hence union tag is aligned to 8

        .assert_size_alignment("Option<(Option<(u8,s8)>,Option<(s8,u8)>)>", 7, 1, 0, 0); // inner unions are size 3, alignment 1. Two of those with a tag is size 7

    });

}

#[test]

fn test_incorrect_tuple_polymorph_args() {

    // Do some mismatching brackets. I don't know what else to test

    Tester::new_single_source_expect_err(

        "mismatch angle bracket",

        "

        union Option<T>{ Some(T), None }

        func f() -> u32 {

            auto a = Option<(u32>)::None;

            return 0;

        }"

    ).error(|e| { e

        .assert_num(2)

        .assert_msg_has(0, "closing '>'").assert_occurs_at(0, ">)::None")

        .assert_msg_has(1, "match this '('").assert_occurs_at(1, "(u32>");

    });

    Tester::new_single_source_expect_err(

        "wrongly placed angle",

        "

        union O<T>{ S(T), N }

        func f() -> u32 {

            auto a = O<(<u32>)>::None;

            return 0;

        }

        "

    ).error(|e| { e

        .assert_num(1)

        .assert_msg_has(0, "expected typename")

        .assert_occurs_at(0, "<u32");

    });

}

#[test]

fn test_incorrect_tuple_member_access() {

    Tester::new_single_source_expect_err(

        "zero-tuple",

        "func foo() -> () { () a = (); auto b = a.0; return a; }"

    ).error(|e| { e

        .assert_num(1)

        .assert_msg_has(0, "out of bounds")

        .assert_occurs_at(0, "a.0");

    });

    // Make the type checker do some shenanigans before we can decide the tuple

    // type.

    Tester::new_single_source_expect_err(

        "sized tuple",

        "

        func determinator<A,B>((A,B,A) v) -> B { return v.1; }

        func tester() -> u64 {

            auto v = (0,1,2);

            u32 a_u32 = 5;

            v.2 = a_u32;

            v.8 = 5;

            return determinator(v);

        }

        "

    ).error(|e| { e

        .assert_num(1)

        .assert_msg_has(0, "out of bounds")

        .assert_occurs_at(0, "v.8");

    });

}

#[test]

fn test_polymorph_array_types() {

    Tester::new_single_source_expect_ok(

        "array of polymorph in struct",

        "

        struct Foo<T> { T[] hello }

        struct Bar { Foo<u32>[] world }

        "

    ).for_struct("Bar", |s| { s

        .for_field("world", |f| { f.assert_parser_type("Foo<u32>[]"); });

    });

    Tester::new_single_source_expect_ok(

        "array of port in struct",

        "

        struct Bar { in<u32>[] inputs }

        "

    ).for_struct("Bar", |s| { s

        .for_field("inputs", |f| { f.assert_parser_type("in<u32>[]"); });

    });

}

#[test]

fn test_correct_modifying_operators() {

    // Not testing the types, just that it parses

    Tester::new_single_source_expect_ok(

        "valid uses",

        "

        func f() -> u32 {

            auto a = 5;

            a += 2; a -= 2; a *= 2; a /= 2; a %= 2;

            a <<= 2; a >>= 2;

            a |= 2; a &= 2; a ^= 2;

            return a;

        }

        "

    );

}

#[test]

fn test_incorrect_modifying_operators() {

    Tester::new_single_source_expect_err(

        "wrong declaration",

        "func f() -> u8 { auto a += 2; return a; }"

    ).error(|e| { e.assert_msg_has(0, "expected '='"); });

    Tester::new_single_source_expect_err(

        "inside function",

        "func f(u32 a) -> u32 { auto b = 0; auto c = f(a += 2); }"

    ).error(|e| { e.assert_msg_has(0, "assignments are statements"); });

    Tester::new_single_source_expect_err(

        "inside tuple",

        "func f(u32 a) -> u32 { auto b = (a += 2, a /= 2); return 0; }"

    ).error(|e| { e.assert_msg_has(0, "assignments are statements"); });

}

#[test]

fn test_variable_introduction_in_scope() {

    Tester::new_single_source_expect_err(

        "variable use before declaration",

        "func f() -> u8 { return thing; auto thing = 5; }"

    ).error(|e| { e.assert_msg_has(0, "unresolved variable"); });

    Tester::new_single_source_expect_err(

        "variable use in declaration",

        "func f() -> u8 { auto thing = 5 + thing; return thing; }"

    ).error(|e| { e.assert_msg_has(0, "unresolved variable"); });

    Tester::new_single_source_expect_ok(

        "variable use after declaration",

        "func f() -> u8 { auto thing = 5; return thing; }"

    );

    Tester::new_single_source_expect_err(

        "variable use of closed scope",

        "func f() -> u8 { { auto thing = 5; } return thing; }"

    ).error(|e| { e.assert_msg_has(0, "unresolved variable"); });

}

#[test]

fn test_correct_select_statement() {

    Tester::new_single_source_expect_ok(

        "guard variable decl",

        "

        primitive f() {

            channel<u32> unused -> input;

            u32 outer_value = 0;

            sync select {

                auto in_same_guard = get(input) -> {} // decl A1

                auto in_same_gaurd = get(input) -> {} // decl A2

                auto in_guard_and_block = get(input) -> {} // decl B1

                outer_value = get(input) -> { auto in_guard_and_block = outer_value; } // decl B2

            }

        }

        "

    );

    Tester::new_single_source_expect_ok(

        "empty select",

        "primitive f() { sync select {} }"

    );

    Tester::new_single_source_expect_ok(

        "mixed uses", "

        primitive f() {

            channel unused_output -> input;

            u32 outer_value = 0;

            sync select {

                outer_value = get(input) -> outer_value = 0;

                auto new_value = get(input) -> {

                    outer_value = new_value;

                }

                get(input) + get(input) ->

                    outer_value = 8;

                get(input) ->

                    {}

                outer_value %= get(input) -> {

                    outer_value *= outer_value;

                    auto new_value = get(input);

                    outer_value += new_value;

                }

            }

        }

        "

    );

}

#[test]

fn test_incorrect_select_statement() {

    Tester::new_single_source_expect_err(

        "outside sync",

        "primitive f() { select {} }"

    ).error(|e| { e

        .assert_num(1)

        .assert_occurs_at(0, "select")

        .assert_msg_has(0, "inside sync blocks");

    });

    Tester::new_single_source_expect_err(

        "variable in previous block",

        "primitive f() {

            channel<u32> tx -> rx;

            u32 a = 0; // this one will be shadowed

            sync select { auto a = get(rx) -> {} }

        }"

    ).error(|e| { e

        .assert_num(2)

        .assert_occurs_at(0, "a = get").assert_msg_has(0, "variable name conflicts")

        .assert_occurs_at(1, "a = 0").assert_msg_has(1, "Previous variable");

    });

    Tester::new_single_source_expect_err(

        "put inside arm",

        "primitive f() {

            channel<u32> a -> b;

            sync select { put(a) -> {} }

        }"

    ).error(|e| { e

        .assert_occurs_at(0, "put")

        .assert_msg_has(0, "may not occur");

    });

}

#[test]

fn test_incorrect_goto_statement() {

    Tester::new_single_source_expect_err(

        "goto missing var in same scope",

        "func f() -> u32 {

            goto exit;

            auto v = 5;

            exit: return 0;

        }"

    ).error(|e| { e

        .assert_num(3)

        .assert_occurs_at(0, "exit;").assert_msg_has(0, "skips over a variable")

        .assert_occurs_at(1, "exit:").assert_msg_has(1, "jumps to this label")

        .assert_occurs_at(2, "v = 5").assert_msg_has(2, "skips over this variable");

    });

    Tester::new_single_source_expect_err(

        "goto missing var in outer scope",

        "func f() -> u32 {

            if (true) {

                goto exit;

            }

            auto v = 0;

            exit: return 1;

        }"

    ).error(|e| { e

        .assert_num(3)

        .assert_occurs_at(0, "exit;").assert_msg_has(0, "skips over a variable")

        .assert_occurs_at(1, "exit:").assert_msg_has(1, "jumps to this label")

        .assert_occurs_at(2, "v = 0").assert_msg_has(2, "skips over this variable");

    });

    Tester::new_single_source_expect_err(

        "goto jumping into scope",

        "func f() -> u32 {

            goto nested;

            {

                nested: return 0;

            }

            return 1;

        }"

    ).error(|e| { e

        .assert_num(1)

        .assert_occurs_at(0, "nested;")

        .assert_msg_has(0, "could not find this label");

    });

    Tester::new_single_source_expect_err(

        "goto jumping outside sync",

        "primitive f() {

            sync { goto exit; }

            exit: u32 v = 0;

        }"

    ).error(|e| { e

        .assert_num(3)

        .assert_occurs_at(0, "goto exit;").assert_msg_has(0, "not escape the surrounding sync")

        .assert_occurs_at(1, "exit: u32 v").assert_msg_has(1, "target of the goto")

        .assert_occurs_at(2, "sync {").assert_msg_has(2, "jump past this");

}

#[test]

fn test_incorrect_while_statement() {

    // Just testing the error cases caught at compile-time. Other ones need

    // evaluation testing

    Tester::new_single_source_expect_err(

        "break wrong earlier loop",

        "func f() -> u32 {

            target: while (true) {}

            while (true) { break target; }

            return 0;

        }"

    ).error(|e| { e

        .assert_num(2)

        .assert_occurs_at(0, "target; }").assert_msg_has(0, "not nested under the target")

        .assert_occurs_at(1, "target: while").assert_msg_has(1, "is found here");

    });

    Tester::new_single_source_expect_err(

        "break wrong later loop",

        "func f() -> u32 {

            while (true) { break target; }

            target: while (true) {}

            return 0;

        }"

    ).error(|e| { e

        .assert_num(2)

        .assert_occurs_at(0, "target; }").assert_msg_has(0, "not nested under the target")

        .assert_occurs_at(1, "target: while").assert_msg_has(1, "is found here");

    });

    Tester::new_single_source_expect_err(

        "break outside of sync",

        "primitive f() {

            outer: while (true) { //mark

                sync while(true) { break outer; }

            }

        }"

    ).error(|e| { e

        .assert_num(3)

        .assert_occurs_at(0, "break outer;").assert_msg_has(0, "may not escape the surrounding")

        .assert_occurs_at(1, "while (true) { //mark").assert_msg_has(1, "escapes out of this loop")

        .assert_occurs_at(2, "sync while").assert_msg_has(2, "escape this synchronous block");

    });

}