// This file is part of the Luau programming language and is licensed under MIT License; see LICENSE.txt for details
#include "Luau/Scope.h"
#include "Luau/ToDot.h"
#include "Fixture.h"
#include "doctest.h"
using namespace Luau;
LUAU_FASTFLAG(LuauSolverV2);
struct ToDotClassFixture : Fixture
{
ToDotClassFixture()
{
TypeArena& arena = frontend.globals.globalTypes;
unfreeze(arena);
TypeId baseClassMetaType = arena.addType(TableType{});
TypeId baseClassInstanceType = arena.addType(ClassType{"BaseClass", {}, std::nullopt, baseClassMetaType, {}, {}, "Test", {}});
getMutable<ClassType>(baseClassInstanceType)->props = {
{"BaseField", {builtinTypes->numberType}},
};
frontend.globals.globalScope->exportedTypeBindings["BaseClass"] = TypeFun{{}, baseClassInstanceType};
TypeId childClassInstanceType = arena.addType(ClassType{"ChildClass", {}, baseClassInstanceType, std::nullopt, {}, {}, "Test", {}});
getMutable<ClassType>(childClassInstanceType)->props = {
{"ChildField", {builtinTypes->stringType}},
};
frontend.globals.globalScope->exportedTypeBindings["ChildClass"] = TypeFun{{}, childClassInstanceType};
for (const auto& [name, ty] : frontend.globals.globalScope->exportedTypeBindings)
persist(ty.type);
freeze(arena);
}
};
TEST_SUITE_BEGIN("ToDot");
TEST_CASE_FIXTURE(Fixture, "primitive")
{
CHECK_EQ(
R"(digraph graphname {
n1 [label="nil"];
})",
toDot(builtinTypes->nilType)
);
CHECK_EQ(
R"(digraph graphname {
n1 [label="number"];
})",
toDot(builtinTypes->numberType)
);
CHECK_EQ(
R"(digraph graphname {
n1 [label="any"];
})",
toDot(builtinTypes->anyType)
);
CHECK_EQ(
R"(digraph graphname {
n1 [label="unknown"];
})",
toDot(builtinTypes->unknownType)
);
CHECK_EQ(
R"(digraph graphname {
n1 [label="never"];
})",
toDot(builtinTypes->neverType)
);
}
TEST_CASE_FIXTURE(Fixture, "no_duplicatePrimitives")
{
ToDotOptions opts;
opts.showPointers = false;
opts.duplicatePrimitives = false;
CHECK_EQ(
R"(digraph graphname {
n1 [label="PrimitiveType number"];
})",
toDot(builtinTypes->numberType, opts)
);
CHECK_EQ(
R"(digraph graphname {
n1 [label="AnyType 1"];
})",
toDot(builtinTypes->anyType, opts)
);
CHECK_EQ(
R"(digraph graphname {
n1 [label="UnknownType 1"];
})",
toDot(builtinTypes->unknownType, opts)
);
CHECK_EQ(
R"(digraph graphname {
n1 [label="NeverType 1"];
})",
toDot(builtinTypes->neverType, opts)
);
}
TEST_CASE_FIXTURE(Fixture, "bound")
{
TypeArena arena;
TypeId ty = arena.addType(BoundType{builtinTypes->numberType});
ToDotOptions opts;
opts.showPointers = false;
CHECK_EQ(
R"(digraph graphname {
n1 [label="BoundType 1"];
n1 -> n2;
n2 [label="number"];
})",
toDot(ty, opts)
);
}
TEST_CASE_FIXTURE(Fixture, "function")
{
CheckResult result = check(R"(
local function f(a, ...: string) return a end
)");
LUAU_REQUIRE_NO_ERRORS(result);
CHECK_EQ("<a>(a, ...string) -> a", toString(requireType("f")));
ToDotOptions opts;
opts.showPointers = false;
if (FFlag::LuauSolverV2)
{
CHECK_EQ(
R"(digraph graphname {
n1 [label="FunctionType 1"];
n1 -> n2 [label="arg"];
n2 [label="TypePack 2"];
n2 -> n3;
n3 [label="GenericType 3"];
n2 -> n4 [label="tail"];
n4 [label="VariadicTypePack 4"];
n4 -> n5;
n5 [label="string"];
n1 -> n6 [label="ret"];
n6 [label="BoundTypePack 6"];
n6 -> n7;
n7 [label="TypePack 7"];
n7 -> n3;
})",
toDot(requireType("f"), opts)
);
}
else
{
CHECK_EQ(
R"(digraph graphname {
n1 [label="FunctionType 1"];
n1 -> n2 [label="arg"];
n2 [label="TypePack 2"];
n2 -> n3;
n3 [label="GenericType 3"];
n2 -> n4 [label="tail"];
n4 [label="VariadicTypePack 4"];
n4 -> n5;
n5 [label="string"];
n1 -> n6 [label="ret"];
n6 [label="BoundTypePack 6"];
n6 -> n7;
n7 [label="TypePack 7"];
n7 -> n3;
})",
toDot(requireType("f"), opts)
);
}
}
TEST_CASE_FIXTURE(Fixture, "union")
{
CheckResult result = check(R"(
local a: string | number
)");
LUAU_REQUIRE_NO_ERRORS(result);
ToDotOptions opts;
opts.showPointers = false;
CHECK_EQ(
R"(digraph graphname {
n1 [label="UnionType 1"];
n1 -> n2;
n2 [label="string"];
n1 -> n3;
n3 [label="number"];
})",
toDot(requireType("a"), opts)
);
}
TEST_CASE_FIXTURE(Fixture, "intersection")
{
TypeArena arena;
TypeId ty = arena.addType(IntersectionType{{builtinTypes->stringType, builtinTypes->numberType}});
ToDotOptions opts;
opts.showPointers = false;
CHECK_EQ(
R"(digraph graphname {
n1 [label="IntersectionType 1"];
n1 -> n2;
n2 [label="string"];
n1 -> n3;
n3 [label="number"];
})",
toDot(ty, opts)
);
}
TEST_CASE_FIXTURE(Fixture, "table")
{
CheckResult result = check(R"(
type A<T, U...> = { x: T, y: (U...) -> (), [string]: any }
local a: A<number, ...string>
)");
LUAU_REQUIRE_NO_ERRORS(result);
ToDotOptions opts;
opts.showPointers = false;
if (FFlag::LuauSolverV2)
{
CHECK_EQ(
R"(digraph graphname {
n1 [label="TableType A"];
n1 -> n2 [label="x"];
n2 [label="number"];
n1 -> n3 [label="y"];
n3 [label="FunctionType 3"];
n3 -> n4 [label="arg"];
n4 [label="VariadicTypePack 4"];
n4 -> n5;
n5 [label="string"];
n3 -> n6 [label="ret"];
n6 [label="TypePack 6"];
n1 -> n7 [label="[index]"];
n7 [label="string"];
n1 -> n8 [label="[value]"];
n8 [label="any"];
n1 -> n9 [label="typeParam"];
n9 [label="number"];
n1 -> n4 [label="typePackParam"];
})",
toDot(requireType("a"), opts)
);
}
else
{
CHECK_EQ(
R"(digraph graphname {
n1 [label="TableType A"];
n1 -> n2 [label="x"];
n2 [label="number"];
n1 -> n3 [label="y"];
n3 [label="FunctionType 3"];
n3 -> n4 [label="arg"];
n4 [label="VariadicTypePack 4"];
n4 -> n5;
n5 [label="string"];
n3 -> n6 [label="ret"];
n6 [label="TypePack 6"];
n1 -> n7 [label="[index]"];
n7 [label="string"];
n1 -> n8 [label="[value]"];
n8 [label="any"];
n1 -> n9 [label="typeParam"];
n9 [label="number"];
n1 -> n4 [label="typePackParam"];
})",
toDot(requireType("a"), opts)
);
}
// Extra coverage with pointers (unstable values)
(void)toDot(requireType("a"));
}
TEST_CASE_FIXTURE(BuiltinsFixture, "metatable")
{
CheckResult result = check(R"(
local a: typeof(setmetatable({}, {}))
)");
LUAU_REQUIRE_NO_ERRORS(result);
ToDotOptions opts;
opts.showPointers = false;
CHECK_EQ(
R"(digraph graphname {
n1 [label="MetatableType 1"];
n1 -> n2 [label="table"];
n2 [label="TableType 2"];
n1 -> n3 [label="metatable"];
n3 [label="TableType 3"];
})",
toDot(requireType("a"), opts)
);
}
TEST_CASE_FIXTURE(Fixture, "free")
{
ScopedFastFlag sff[] = {
{FFlag::LuauSolverV2, false},
};
Type type{TypeVariant{FreeType{TypeLevel{0, 0}}}};
ToDotOptions opts;
opts.showPointers = false;
CHECK_EQ(
R"(digraph graphname {
n1 [label="FreeType 1"];
})",
toDot(&type, opts)
);
}
TEST_CASE_FIXTURE(Fixture, "free_with_constraints")
{
ScopedFastFlag sff[] = {
{FFlag::LuauSolverV2, true},
};
Type type{TypeVariant{FreeType{nullptr, builtinTypes->numberType, builtinTypes->optionalNumberType}}};
ToDotOptions opts;
opts.showPointers = false;
CHECK_EQ(
R"(digraph graphname {
n1 [label="FreeType 1"];
n1 -> n2 [label="[lowerBound]"];
n2 [label="number"];
n1 -> n3 [label="[upperBound]"];
n3 [label="UnionType 3"];
n3 -> n4;
n4 [label="number"];
n3 -> n5;
n5 [label="nil"];
})",
toDot(&type, opts)
);
}
TEST_CASE_FIXTURE(Fixture, "error")
{
Type type{TypeVariant{ErrorType{}}};
ToDotOptions opts;
opts.showPointers = false;
CHECK_EQ(
R"(digraph graphname {
n1 [label="ErrorType 1"];
})",
toDot(&type, opts)
);
}
TEST_CASE_FIXTURE(Fixture, "generic")
{
Type type{TypeVariant{GenericType{"T"}}};
ToDotOptions opts;
opts.showPointers = false;
CHECK_EQ(
R"(digraph graphname {
n1 [label="GenericType T"];
})",
toDot(&type, opts)
);
}
TEST_CASE_FIXTURE(ToDotClassFixture, "class")
{
CheckResult result = check(R"(
local a: ChildClass
)");
LUAU_REQUIRE_NO_ERRORS(result);
ToDotOptions opts;
opts.showPointers = false;
CHECK_EQ(
R"(digraph graphname {
n1 [label="ClassType ChildClass"];
n1 -> n2 [label="ChildField"];
n2 [label="string"];
n1 -> n3 [label="[parent]"];
n3 [label="ClassType BaseClass"];
n3 -> n4 [label="BaseField"];
n4 [label="number"];
n3 -> n5 [label="[metatable]"];
n5 [label="TableType 5"];
})",
toDot(requireType("a"), opts)
);
}
TEST_CASE_FIXTURE(Fixture, "free_pack")
{
TypePackVar pack{TypePackVariant{FreeTypePack{TypeLevel{0, 0}}}};
ToDotOptions opts;
opts.showPointers = false;
CHECK_EQ(
R"(digraph graphname {
n1 [label="FreeTypePack 1"];
})",
toDot(&pack, opts)
);
}
TEST_CASE_FIXTURE(Fixture, "error_pack")
{
TypePackVar pack{TypePackVariant{Unifiable::Error{}}};
ToDotOptions opts;
opts.showPointers = false;
CHECK_EQ(
R"(digraph graphname {
n1 [label="ErrorTypePack 1"];
})",
toDot(&pack, opts)
);
// Extra coverage with pointers (unstable values)
(void)toDot(&pack);
}
TEST_CASE_FIXTURE(Fixture, "generic_pack")
{
TypePackVar pack1{TypePackVariant{GenericTypePack{}}};
TypePackVar pack2{TypePackVariant{GenericTypePack{"T"}}};
ToDotOptions opts;
opts.showPointers = false;
CHECK_EQ(
R"(digraph graphname {
n1 [label="GenericTypePack 1"];
})",
toDot(&pack1, opts)
);
CHECK_EQ(
R"(digraph graphname {
n1 [label="GenericTypePack T"];
})",
toDot(&pack2, opts)
);
}
TEST_CASE_FIXTURE(Fixture, "bound_pack")
{
TypePackVar pack{TypePackVariant{TypePack{{builtinTypes->numberType}, {}}}};
TypePackVar bound{TypePackVariant{BoundTypePack{&pack}}};
ToDotOptions opts;
opts.showPointers = false;
CHECK_EQ(
R"(digraph graphname {
n1 [label="BoundTypePack 1"];
n1 -> n2;
n2 [label="TypePack 2"];
n2 -> n3;
n3 [label="number"];
})",
toDot(&bound, opts)
);
}
TEST_CASE_FIXTURE(Fixture, "bound_table")
{
TypeArena arena;
TypeId ty = arena.addType(TableType{});
getMutable<TableType>(ty)->props["x"] = {builtinTypes->numberType};
TypeId boundTy = arena.addType(TableType{});
getMutable<TableType>(boundTy)->boundTo = ty;
ToDotOptions opts;
opts.showPointers = false;
CHECK_EQ(
R"(digraph graphname {
n1 [label="TableType 1"];
n1 -> n2 [label="boundTo"];
n2 [label="TableType 2"];
n2 -> n3 [label="x"];
n3 [label="number"];
})",
toDot(boundTy, opts)
);
}
TEST_CASE_FIXTURE(Fixture, "builtintypes")
{
CheckResult result = check(R"(
local x: "hi" | "\"hello\"" | true | false
)");
ToDotOptions opts;
opts.showPointers = false;
CHECK_EQ(
R"(digraph graphname {
n1 [label="UnionType 1"];
n1 -> n2;
n2 [label="SingletonType string: hi"];
n1 -> n3;
)"
"n3 [label=\"SingletonType string: \\\"hello\\\"\"];"
R"(
n1 -> n4;
n4 [label="SingletonType boolean: true"];
n1 -> n5;
n5 [label="SingletonType boolean: false"];
})",
toDot(requireType("x"), opts)
);
}
TEST_CASE_FIXTURE(Fixture, "negation")
{
TypeArena arena;
TypeId t = arena.addType(NegationType{builtinTypes->stringType});
ToDotOptions opts;
opts.showPointers = false;
CHECK(R"(digraph graphname {
n1 [label="NegationType 1"];
n1 -> n2 [label="[negated]"];
n2 [label="string"];
})" == toDot(t, opts));
}
TEST_SUITE_END();