luau/tests/TypeInfer.aliases.test.cpp
Andy Friesen d2ab5df62b
Sync to upstream/release/565 (#845)
We've made a few small changes to reduce the amount of stack we use when
typechecking nested method calls (eg `foo:bar():baz():quux()`).

We've also fixed a small bytecode compiler issue that caused us to emit
redundant jump instructions in code that conditionally uses `break` or
`continue`.

On the new solver, we've switched to a new, better way to handle
augmentations to unsealed tables. We've also made some substantial
improvements to type inference and error reporting on function calls.
These things should both be on par with the old solver now.

The main improvements to the native code generator have been elimination
of some redundant type tag checks. Also, we are starting to inline
particular fastcalls directly to IR.

---------

Co-authored-by: Arseny Kapoulkine <arseny.kapoulkine@gmail.com>
Co-authored-by: Vyacheslav Egorov <vegorov@roblox.com>
2023-02-24 13:49:38 -08:00

926 lines
27 KiB
C++

// This file is part of the Luau programming language and is licensed under MIT License; see LICENSE.txt for details
#include "Fixture.h"
#include "doctest.h"
#include "Luau/BuiltinDefinitions.h"
using namespace Luau;
LUAU_FASTFLAG(DebugLuauDeferredConstraintResolution)
LUAU_FASTFLAG(LuauTypeMismatchInvarianceInError)
TEST_SUITE_BEGIN("TypeAliases");
TEST_CASE_FIXTURE(Fixture, "basic_alias")
{
CheckResult result = check(R"(
type T = number
local x: T = 1
)");
LUAU_REQUIRE_NO_ERRORS(result);
CHECK_EQ("number", toString(requireType("x")));
}
TEST_CASE_FIXTURE(Fixture, "cyclic_function_type_in_type_alias")
{
CheckResult result = check(R"(
type F = () -> F?
local function f()
return f
end
local g: F = f
)");
LUAU_REQUIRE_NO_ERRORS(result);
CHECK_EQ("t1 where t1 = () -> t1?", toString(requireType("g")));
}
TEST_CASE_FIXTURE(Fixture, "names_are_ascribed")
{
CheckResult result = check(R"(
type T = { x: number }
local x: T
)");
LUAU_REQUIRE_NO_ERRORS(result);
CHECK_EQ("T", toString(requireType("x")));
}
TEST_CASE_FIXTURE(Fixture, "cannot_steal_hoisted_type_alias")
{
// This is a tricky case. In order to support recursive type aliases,
// we first walk the block and generate free types as placeholders.
// We then walk the AST as normal. If we declare a type alias as below,
// we generate a free type. We then begin our normal walk, examining
// local x: T = "foo", which establishes two constraints:
// a <: b
// string <: a
// We then visit the type alias, and establish that
// b <: number
// Then, when solving these constraints, we dispatch them in the order
// they appear above. This means that a ~ b, and a ~ string, thus
// b ~ string. This means the b <: number constraint has no effect.
// Essentially we've "stolen" the alias's type out from under it.
// This test ensures that we don't actually do this.
CheckResult result = check(R"(
local x: T = "foo"
type T = number
)");
LUAU_REQUIRE_ERROR_COUNT(1, result);
if (FFlag::DebugLuauDeferredConstraintResolution)
{
CHECK(result.errors[0] == TypeError{
Location{{1, 21}, {1, 26}},
getMainSourceModule()->name,
TypeMismatch{
builtinTypes->numberType,
builtinTypes->stringType,
},
});
}
else
{
CHECK(result.errors[0] == TypeError{
Location{{1, 8}, {1, 26}},
getMainSourceModule()->name,
TypeMismatch{
builtinTypes->numberType,
builtinTypes->stringType,
},
});
}
}
TEST_CASE_FIXTURE(Fixture, "mismatched_generic_type_param")
{
CheckResult result = check(R"(
type T<A> = (A...) -> ()
)");
LUAU_REQUIRE_ERROR_COUNT(1, result);
CHECK(toString(result.errors[0]) ==
"Generic type 'A' is used as a variadic type parameter; consider changing 'A' to 'A...' in the generic argument list");
CHECK(result.errors[0].location == Location{{1, 21}, {1, 25}});
}
TEST_CASE_FIXTURE(Fixture, "mismatched_generic_pack_type_param")
{
CheckResult result = check(R"(
type T<A...> = (A) -> ()
)");
LUAU_REQUIRE_ERROR_COUNT(1, result);
CHECK(toString(result.errors[0]) ==
"Variadic type parameter 'A...' is used as a regular generic type; consider changing 'A...' to 'A' in the generic argument list");
CHECK(result.errors[0].location == Location{{1, 24}, {1, 25}});
}
TEST_CASE_FIXTURE(Fixture, "default_type_parameter")
{
CheckResult result = check(R"(
type T<A = number, B = string> = { a: A, b: B }
local x: T<string> = { a = "foo", b = "bar" }
)");
LUAU_REQUIRE_NO_ERRORS(result);
CHECK(toString(requireType("x")) == "T<string, string>");
}
TEST_CASE_FIXTURE(Fixture, "default_pack_parameter")
{
CheckResult result = check(R"(
type T<A... = (number, string)> = { fn: (A...) -> () }
local x: T
)");
LUAU_REQUIRE_NO_ERRORS(result);
CHECK(toString(requireType("x")) == "T<number, string>");
}
TEST_CASE_FIXTURE(Fixture, "saturate_to_first_type_pack")
{
CheckResult result = check(R"(
type T<A, B, C...> = { fn: (A, B) -> C... }
local x: T<string, number, string, boolean>
local f = x.fn
)");
LUAU_REQUIRE_NO_ERRORS(result);
CHECK(toString(requireType("x")) == "T<string, number, string, boolean>");
CHECK(toString(requireType("f")) == "(string, number) -> (string, boolean)");
}
TEST_CASE_FIXTURE(Fixture, "cyclic_types_of_named_table_fields_do_not_expand_when_stringified")
{
CheckResult result = check(R"(
--!strict
type Node = { Parent: Node?; }
local node: Node;
node.Parent = 1
)");
LUAU_REQUIRE_ERROR_COUNT(1, result);
TypeMismatch* tm = get<TypeMismatch>(result.errors[0]);
REQUIRE(tm);
CHECK_EQ("Node?", toString(tm->wantedType));
CHECK_EQ(typeChecker.numberType, tm->givenType);
}
TEST_CASE_FIXTURE(Fixture, "mutually_recursive_aliases")
{
CheckResult result = check(R"(
--!strict
type T = { f: number, g: U }
type U = { h: number, i: T? }
local x: T = { f = 37, g = { h = 5, i = nil } }
x.g.i = x
local y: T = { f = 3, g = { h = 5, i = nil } }
y.g.i = y
)");
LUAU_REQUIRE_NO_ERRORS(result);
}
TEST_CASE_FIXTURE(Fixture, "generic_aliases")
{
ScopedFastFlag sff_DebugLuauDeferredConstraintResolution{"DebugLuauDeferredConstraintResolution", true};
CheckResult result = check(R"(
type T<a> = { v: a }
local x: T<number> = { v = 123 }
local y: T<string> = { v = "foo" }
local bad: T<number> = { v = "foo" }
)");
LUAU_REQUIRE_ERROR_COUNT(1, result);
const char* expectedError;
if (FFlag::LuauTypeMismatchInvarianceInError)
expectedError = "Type 'bad' could not be converted into 'T<number>'\n"
"caused by:\n"
" Property 'v' is not compatible. Type 'string' could not be converted into 'number' in an invariant context";
else
expectedError = "Type 'bad' could not be converted into 'T<number>'\n"
"caused by:\n"
" Property 'v' is not compatible. Type 'string' could not be converted into 'number'";
CHECK(result.errors[0].location == Location{{4, 31}, {4, 44}});
CHECK(toString(result.errors[0]) == expectedError);
}
TEST_CASE_FIXTURE(Fixture, "dependent_generic_aliases")
{
ScopedFastFlag sff_DebugLuauDeferredConstraintResolution{"DebugLuauDeferredConstraintResolution", true};
CheckResult result = check(R"(
type T<a> = { v: a }
type U<a> = { t: T<a> }
local x: U<number> = { t = { v = 123 } }
local bad: U<number> = { t = { v = "foo" } }
)");
LUAU_REQUIRE_ERROR_COUNT(1, result);
std::string expectedError;
if (FFlag::LuauTypeMismatchInvarianceInError)
expectedError = "Type 'bad' could not be converted into 'U<number>'\n"
"caused by:\n"
" Property 't' is not compatible. Type '{ v: string }' could not be converted into 'T<number>'\n"
"caused by:\n"
" Property 'v' is not compatible. Type 'string' could not be converted into 'number' in an invariant context";
else
expectedError = "Type 'bad' could not be converted into 'U<number>'\n"
"caused by:\n"
" Property 't' is not compatible. Type '{ v: string }' could not be converted into 'T<number>'\n"
"caused by:\n"
" Property 'v' is not compatible. Type 'string' could not be converted into 'number'";
CHECK(result.errors[0].location == Location{{4, 31}, {4, 52}});
CHECK(toString(result.errors[0]) == expectedError);
}
TEST_CASE_FIXTURE(Fixture, "mutually_recursive_generic_aliases")
{
CheckResult result = check(R"(
--!strict
type T<a> = { f: a, g: U<a> }
type U<a> = { h: a, i: T<a>? }
local x: T<number> = { f = 37, g = { h = 5, i = nil } }
x.g.i = x
local y: T<string> = { f = "hi", g = { h = "lo", i = nil } }
y.g.i = y
)");
LUAU_REQUIRE_NO_ERRORS(result);
}
TEST_CASE_FIXTURE(Fixture, "mutually_recursive_types_errors")
{
CheckResult result = check(R"(
--!strict
type T<a> = { f: a, g: U<a> }
type U<b> = { h: b, i: T<b>? }
local x: T<number> = { f = 37, g = { h = 5, i = nil } }
x.g.i = x
local y: T<string> = { f = "hi", g = { h = 5, i = nil } }
y.g.i = y
)");
LUAU_REQUIRE_ERRORS(result);
// We had a UAF in this example caused by not cloning type function arguments
ModulePtr module = frontend.moduleResolver.getModule("MainModule");
unfreeze(module->interfaceTypes);
copyErrors(module->errors, module->interfaceTypes);
freeze(module->interfaceTypes);
module->internalTypes.clear();
module->astTypes.clear();
// Make sure the error strings don't include "VALUELESS"
for (auto error : module->errors)
CHECK_MESSAGE(toString(error).find("VALUELESS") == std::string::npos, toString(error));
}
TEST_CASE_FIXTURE(Fixture, "use_table_name_and_generic_params_in_errors")
{
CheckResult result = check(R"(
type Pair<T, U> = {first: T, second: U}
local a: Pair<string, number>
local b: Pair<string, string>
a = b
)");
LUAU_REQUIRE_ERROR_COUNT(1, result);
TypeMismatch* tm = get<TypeMismatch>(result.errors[0]);
REQUIRE(tm);
CHECK_EQ("Pair<string, number>", toString(tm->wantedType));
CHECK_EQ("Pair<string, string>", toString(tm->givenType));
}
TEST_CASE_FIXTURE(Fixture, "dont_stop_typechecking_after_reporting_duplicate_type_definition")
{
CheckResult result = check(R"(
type A = number
type A = string -- Redefinition of type 'A', previously defined at line 1
local foo: string = 1 -- "Type 'number' could not be converted into 'string'"
)");
LUAU_REQUIRE_ERROR_COUNT(2, result);
}
TEST_CASE_FIXTURE(Fixture, "stringify_type_alias_of_recursive_template_table_type")
{
CheckResult result = check(R"(
type Table<T> = { a: T }
type Wrapped = Table<Wrapped>
local l: Wrapped = 2
)");
LUAU_REQUIRE_ERROR_COUNT(1, result);
TypeMismatch* tm = get<TypeMismatch>(result.errors[0]);
REQUIRE(tm);
CHECK_EQ("Wrapped", toString(tm->wantedType));
CHECK_EQ(typeChecker.numberType, tm->givenType);
}
TEST_CASE_FIXTURE(Fixture, "stringify_type_alias_of_recursive_template_table_type2")
{
CheckResult result = check(R"(
type Table<T> = { a: T }
type Wrapped = (Table<Wrapped>) -> string
local l: Wrapped = 2
)");
LUAU_REQUIRE_ERROR_COUNT(1, result);
TypeMismatch* tm = get<TypeMismatch>(result.errors[0]);
REQUIRE(tm);
CHECK_EQ("t1 where t1 = ({| a: t1 |}) -> string", toString(tm->wantedType));
CHECK_EQ(typeChecker.numberType, tm->givenType);
}
// Check that recursive intersection type doesn't generate an OOM
TEST_CASE_FIXTURE(Fixture, "cli_38393_recursive_intersection_oom")
{
CheckResult result = check(R"(
function _(l0:(t0)&((t0)&(((t0)&((t0)->()))->(typeof(_),typeof(# _)))),l39,...):any
end
type t0<t0> = ((typeof(_))&((t0)&(((typeof(_))&(t0))->typeof(_))),{n163:any,})->(any,typeof(_))
_(_)
)");
}
TEST_CASE_FIXTURE(Fixture, "type_alias_fwd_declaration_is_precise")
{
CheckResult result = check(R"(
local foo: Id<number> = 1
type Id<T> = T
)");
LUAU_REQUIRE_NO_ERRORS(result);
}
TEST_CASE_FIXTURE(Fixture, "corecursive_types_generic")
{
const std::string code = R"(
type A<T> = {v:T, b:B<T>}
type B<T> = {v:T, a:A<T>}
local aa:A<number>
local bb = aa
)";
const std::string expected = R"(
type A<T> = {v:T, b:B<T>}
type B<T> = {v:T, a:A<T>}
local aa:A<number>
local bb:A<number>=aa
)";
CHECK_EQ(expected, decorateWithTypes(code));
CheckResult result = check(code);
LUAU_REQUIRE_NO_ERRORS(result);
}
TEST_CASE_FIXTURE(Fixture, "corecursive_function_types")
{
CheckResult result = check(R"(
type A = () -> (number, B)
type B = () -> (string, A)
local a: A
local b: B
)");
LUAU_REQUIRE_NO_ERRORS(result);
CHECK_EQ("t1 where t1 = () -> (number, () -> (string, t1))", toString(requireType("a")));
CHECK_EQ("t1 where t1 = () -> (string, () -> (number, t1))", toString(requireType("b")));
}
TEST_CASE_FIXTURE(Fixture, "generic_param_remap")
{
const std::string code = R"(
-- An example of a forwarded use of a type that has different type arguments than parameters
type A<T,U> = {t:T, u:U, next:A<U,T>?}
local aa:A<number,string> = { t = 5, u = 'hi', next = { t = 'lo', u = 8 } }
local bb = aa
)";
const std::string expected = R"(
type A<T,U> = {t:T, u:U, next:A<U,T>?}
local aa:A<number,string> = { t = 5, u = 'hi', next = { t = 'lo', u = 8 } }
local bb:A<number,string>=aa
)";
CHECK_EQ(expected, decorateWithTypes(code));
CheckResult result = check(code);
LUAU_REQUIRE_ERRORS(result);
}
TEST_CASE_FIXTURE(Fixture, "export_type_and_type_alias_are_duplicates")
{
CheckResult result = check(R"(
export type Foo = number
type Foo = number
)");
LUAU_REQUIRE_ERROR_COUNT(1, result);
auto dtd = get<DuplicateTypeDefinition>(result.errors[0]);
REQUIRE(dtd);
CHECK_EQ(dtd->name, "Foo");
}
TEST_CASE_FIXTURE(Fixture, "reported_location_is_correct_when_type_alias_are_duplicates")
{
CheckResult result = check(R"(
type A = string
type B = number
type C = string
type B = number
)");
LUAU_REQUIRE_ERROR_COUNT(1, result);
auto dtd = get<DuplicateTypeDefinition>(result.errors[0]);
REQUIRE(dtd);
CHECK_EQ(dtd->name, "B");
REQUIRE(dtd->previousLocation);
CHECK_EQ(dtd->previousLocation->begin.line + 1, 3);
}
TEST_CASE_FIXTURE(Fixture, "stringify_optional_parameterized_alias")
{
CheckResult result = check(R"(
type Node<T> = { value: T, child: Node<T>? }
local function visitor<T>(node: Node<T>?)
local a: Node<T>
if node then
a = node.child -- Observe the output of the error message.
end
end
)");
LUAU_REQUIRE_ERROR_COUNT(1, result);
auto e = get<TypeMismatch>(result.errors[0]);
REQUIRE(e != nullptr);
CHECK_EQ("Node<T>?", toString(e->givenType));
CHECK_EQ("Node<T>", toString(e->wantedType));
}
TEST_CASE_FIXTURE(BuiltinsFixture, "general_require_multi_assign")
{
fileResolver.source["workspace/A"] = R"(
export type myvec2 = {x: number, y: number}
return {}
)";
fileResolver.source["workspace/B"] = R"(
export type myvec3 = {x: number, y: number, z: number}
return {}
)";
fileResolver.source["workspace/C"] = R"(
local Foo, Bar = require(workspace.A), require(workspace.B)
local a: Foo.myvec2
local b: Bar.myvec3
)";
CheckResult result = frontend.check("workspace/C");
LUAU_REQUIRE_NO_ERRORS(result);
TypeId aTypeId = requireType("workspace/C", "a");
const Luau::TableType* aType = get<TableType>(follow(aTypeId));
REQUIRE(aType);
REQUIRE(aType->props.size() == 2);
TypeId bTypeId = requireType("workspace/C", "b");
const Luau::TableType* bType = get<TableType>(follow(bTypeId));
REQUIRE(bType);
REQUIRE(bType->props.size() == 3);
}
TEST_CASE_FIXTURE(BuiltinsFixture, "type_alias_import_mutation")
{
CheckResult result = check("type t10<x> = typeof(table)");
LUAU_REQUIRE_NO_ERRORS(result);
TypeId ty = getGlobalBinding(frontend, "table");
CHECK(toString(ty) == "typeof(table)");
const TableType* ttv = get<TableType>(ty);
REQUIRE(ttv);
CHECK(ttv->instantiatedTypeParams.empty());
}
TEST_CASE_FIXTURE(Fixture, "type_alias_local_mutation")
{
CheckResult result = check(R"(
type Cool = { a: number, b: string }
local c: Cool = { a = 1, b = "s" }
type NotCool<x> = Cool
)");
LUAU_REQUIRE_NO_ERRORS(result);
std::optional<TypeId> ty = requireType("c");
REQUIRE(ty);
CHECK_EQ(toString(*ty), "Cool");
const TableType* ttv = get<TableType>(*ty);
REQUIRE(ttv);
CHECK(ttv->instantiatedTypeParams.empty());
}
TEST_CASE_FIXTURE(Fixture, "type_alias_local_rename")
{
CheckResult result = check(R"(
type Cool = { a: number, b: string }
type NotCool = Cool
local c: Cool = { a = 1, b = "s" }
local d: NotCool = { a = 1, b = "s" }
)");
LUAU_REQUIRE_NO_ERRORS(result);
std::optional<TypeId> ty = requireType("c");
REQUIRE(ty);
CHECK_EQ(toString(*ty), "Cool");
ty = requireType("d");
REQUIRE(ty);
CHECK_EQ(toString(*ty), "NotCool");
}
TEST_CASE_FIXTURE(Fixture, "type_alias_local_synthetic_mutation")
{
CheckResult result = check(R"(
local c = { a = 1, b = "s" }
type Cool = typeof(c)
)");
LUAU_REQUIRE_NO_ERRORS(result);
std::optional<TypeId> ty = requireType("c");
REQUIRE(ty);
const TableType* ttv = get<TableType>(*ty);
REQUIRE(ttv);
CHECK_EQ(ttv->name, "Cool");
}
TEST_CASE_FIXTURE(BuiltinsFixture, "type_alias_of_an_imported_recursive_type")
{
fileResolver.source["game/A"] = R"(
export type X = { a: number, b: X? }
return {}
)";
CheckResult aResult = frontend.check("game/A");
LUAU_REQUIRE_NO_ERRORS(aResult);
CheckResult bResult = check(R"(
local Import = require(game.A)
type X = Import.X
)");
LUAU_REQUIRE_NO_ERRORS(bResult);
std::optional<TypeId> ty1 = lookupImportedType("Import", "X");
REQUIRE(ty1);
std::optional<TypeId> ty2 = lookupType("X");
REQUIRE(ty2);
CHECK_EQ(follow(*ty1), follow(*ty2));
}
TEST_CASE_FIXTURE(BuiltinsFixture, "type_alias_of_an_imported_recursive_generic_type")
{
fileResolver.source["game/A"] = R"(
export type X<T, U> = { a: T, b: U, C: X<T, U>? }
return {}
)";
CheckResult aResult = frontend.check("game/A");
LUAU_REQUIRE_NO_ERRORS(aResult);
CheckResult bResult = check(R"(
local Import = require(game.A)
type X<T, U> = Import.X<T, U>
)");
LUAU_REQUIRE_NO_ERRORS(bResult);
std::optional<TypeId> ty1 = lookupImportedType("Import", "X");
REQUIRE(ty1);
std::optional<TypeId> ty2 = lookupType("X");
REQUIRE(ty2);
CHECK_EQ(toString(*ty1, {true}), toString(*ty2, {true}));
bResult = check(R"(
local Import = require(game.A)
type X<T, U> = Import.X<U, T>
)");
LUAU_REQUIRE_NO_ERRORS(bResult);
ty1 = lookupImportedType("Import", "X");
REQUIRE(ty1);
ty2 = lookupType("X");
REQUIRE(ty2);
CHECK_EQ(toString(*ty1, {true}), "t1 where t1 = {| C: t1?, a: T, b: U |}");
CHECK_EQ(toString(*ty2, {true}), "{| C: t1, a: U, b: T |} where t1 = {| C: t1, a: U, b: T |}?");
}
TEST_CASE_FIXTURE(Fixture, "module_export_free_type_leak")
{
CheckResult result = check(R"(
function get()
return function(obj) return true end
end
export type f = typeof(get())
)");
LUAU_REQUIRE_NO_ERRORS(result);
}
TEST_CASE_FIXTURE(Fixture, "module_export_wrapped_free_type_leak")
{
CheckResult result = check(R"(
function get()
return {a = 1, b = function(obj) return true end}
end
export type f = typeof(get())
)");
LUAU_REQUIRE_NO_ERRORS(result);
}
TEST_CASE_FIXTURE(Fixture, "mutually_recursive_types_restriction_ok")
{
CheckResult result = check(R"(
type Tree<T> = { data: T, children: Forest<T> }
type Forest<T> = {Tree<T>}
)");
LUAU_REQUIRE_NO_ERRORS(result);
}
TEST_CASE_FIXTURE(Fixture, "mutually_recursive_types_restriction_not_ok_1")
{
CheckResult result = check(R"(
-- OK because forwarded types are used with their parameters.
type Tree<T> = { data: T, children: Forest<T> }
type Forest<T> = {Tree<{T}>}
)");
LUAU_REQUIRE_ERRORS(result);
}
TEST_CASE_FIXTURE(Fixture, "mutually_recursive_types_restriction_not_ok_2")
{
CheckResult result = check(R"(
-- Not OK because forwarded types are used with different types than their parameters.
type Forest<T> = {Tree<{T}>}
type Tree<T> = { data: T, children: Forest<T> }
)");
LUAU_REQUIRE_ERRORS(result);
}
TEST_CASE_FIXTURE(Fixture, "mutually_recursive_types_swapsies_ok")
{
CheckResult result = check(R"(
type Tree1<T,U> = { data: T, children: {Tree2<U,T>} }
type Tree2<U,T> = { data: U, children: {Tree1<T,U>} }
)");
LUAU_REQUIRE_NO_ERRORS(result);
}
TEST_CASE_FIXTURE(Fixture, "mutually_recursive_types_swapsies_not_ok")
{
CheckResult result = check(R"(
type Tree1<T,U> = { data: T, children: {Tree2<U,T>} }
type Tree2<T,U> = { data: U, children: {Tree1<T,U>} }
)");
LUAU_REQUIRE_ERRORS(result);
}
TEST_CASE_FIXTURE(Fixture, "free_variables_from_typeof_in_aliases")
{
CheckResult result = check(R"(
function f(x) return x[1] end
-- x has type X? for a free type variable X
local x = f ({})
type ContainsFree<a> = { this: a, that: typeof(x) }
type ContainsContainsFree = { that: ContainsFree<number> }
)");
LUAU_REQUIRE_NO_ERRORS(result);
}
TEST_CASE_FIXTURE(Fixture, "non_recursive_aliases_that_reuse_a_generic_name")
{
CheckResult result = check(R"(
type Array<T> = { [number]: T }
type Tuple<T, V> = Array<T | V>
local p: Tuple<number, string>
)");
LUAU_REQUIRE_NO_ERRORS(result);
CHECK_EQ("{number | string}", toString(requireType("p"), {true}));
}
/*
* We had a problem where all type aliases would be prototyped into a child scope that happened
* to have the same level. This caused a problem where, if a sibling function referred to that
* type alias in its type signature, it would erroneously be quantified away, even though it doesn't
* actually belong to the function.
*
* We solved this by ascribing a unique subLevel to each prototyped alias.
*/
TEST_CASE_FIXTURE(BuiltinsFixture, "do_not_quantify_unresolved_aliases")
{
CheckResult result = check(R"(
--!strict
local KeyPool = {}
local function newkey(pool: KeyPool, index)
return {}
end
function newKeyPool()
local pool = {
available = {} :: {Key},
}
return setmetatable(pool, KeyPool)
end
export type KeyPool = typeof(newKeyPool())
export type Key = typeof(newkey(newKeyPool(), 1))
)");
LUAU_REQUIRE_NO_ERRORS(result);
}
/*
* We keep a cache of type alias onto Type to prevent infinite types from
* being constructed via recursive or corecursive aliases. We have to adjust
* the TypeLevels of those generic Types so that the unifier doesn't think
* they have improperly leaked out of their scope.
*/
TEST_CASE_FIXTURE(Fixture, "generic_typevars_are_not_considered_to_escape_their_scope_if_they_are_reused_in_multiple_aliases")
{
CheckResult result = check(R"(
type Array<T> = {T}
type Exclude<T, V> = T
)");
LUAU_REQUIRE_NO_ERRORS(result);
}
/*
* The two-pass alias definition system starts by ascribing a free Type to each alias. It then
* circles back to fill in the actual type later on.
*
* If this free type is unified with something degenerate like `any`, we need to take extra care
* to ensure that the alias actually binds to the type that the user expected.
*/
TEST_CASE_FIXTURE(Fixture, "forward_declared_alias_is_not_clobbered_by_prior_unification_with_any")
{
CheckResult result = check(R"(
local function x()
local y: FutureType = {}::any
return 1
end
type FutureType = { foo: typeof(x()) }
local d: FutureType = { smth = true } -- missing error, 'd' is resolved to 'any'
)");
CHECK_EQ("{| foo: number |}", toString(requireType("d"), {true}));
LUAU_REQUIRE_ERROR_COUNT(1, result);
}
TEST_CASE_FIXTURE(Fixture, "forward_declared_alias_is_not_clobbered_by_prior_unification_with_any_2")
{
ScopedFastFlag sff[] = {
{"DebugLuauSharedSelf", true},
};
CheckResult result = check(R"(
local B = {}
B.bar = 4
function B:smth1()
local self: FutureIntersection = self
self.foo = 4
return 4
end
function B:smth2()
local self: FutureIntersection = self
self.bar = 5 -- error, even though we should have B part with bar
end
type A = { foo: typeof(B.smth1({foo=3})) } -- trick toposort into sorting functions before types
type B = typeof(B)
type FutureIntersection = A & B
)");
// TODO: shared self causes this test to break in bizarre ways.
LUAU_REQUIRE_ERRORS(result);
}
TEST_CASE_FIXTURE(Fixture, "recursive_types_restriction_ok")
{
CheckResult result = check(R"(
type Tree<T> = { data: T, children: {Tree<T>} }
)");
LUAU_REQUIRE_NO_ERRORS(result);
}
TEST_CASE_FIXTURE(Fixture, "recursive_types_restriction_not_ok")
{
CheckResult result = check(R"(
-- this would be an infinite type if we allowed it
type Tree<T> = { data: T, children: {Tree<{T}>} }
)");
LUAU_REQUIRE_ERRORS(result);
}
TEST_CASE_FIXTURE(Fixture, "report_shadowed_aliases")
{
// We allow a previous type alias to depend on a future type alias. That exact feature enables a confusing example, like the following snippet,
// which has the type alias FakeString point to the type alias `string` that which points to `number`.
CheckResult result = check(R"(
type MyString = string
type string = number
)");
LUAU_REQUIRE_ERROR_COUNT(1, result);
CHECK(toString(result.errors[0]) == "Redefinition of type 'string'");
std::optional<TypeId> t1 = lookupType("MyString");
REQUIRE(t1);
CHECK(isPrim(*t1, PrimitiveType::String));
std::optional<TypeId> t2 = lookupType("string");
REQUIRE(t2);
CHECK(isPrim(*t2, PrimitiveType::String));
}
TEST_CASE_FIXTURE(Fixture, "it_is_ok_to_shadow_user_defined_alias")
{
CheckResult result = check(R"(
type T = number
do
type T = string
end
)");
LUAU_REQUIRE_NO_ERRORS(result);
}
TEST_CASE_FIXTURE(Fixture, "cannot_create_cyclic_type_with_unknown_module")
{
CheckResult result = check(R"(
type AAA = B.AAA
)");
LUAU_REQUIRE_ERROR_COUNT(1, result);
CHECK(toString(result.errors[0]) == "Unknown type 'B.AAA'");
}
TEST_SUITE_END();