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97965c7c0a
* `ClassType` can now have an indexer defined on it. This allows custom types to be used in `t[x]` expressions. * Fixed search for closest executable breakpoint line. Previously, breakpoints might have been skipped in `else` blocks at the end of a function * Fixed how unification is performed for two optional types `a? <: b?`, previously it might have unified either 'a' or 'b' with 'nil'. Note that this fix is not enabled by default yet (see the list in `ExperimentalFlags.h`) In the new type solver, a concept of 'Type Families' has been introduced. Type families can be thought of as type aliases with custom type inference/reduction logic included with them. For example, we can have an `Add<T, U>` type family that will resolve the type that is the result of adding two values together. This will help type inference to figure out what 'T' and 'U' might be when explicit type annotations are not provided. In this update we don't define any type families, but they will be added in the near future. It is also possible for Luau embedders to define their own type families in the global/environment scope. Other changes include: * Fixed scope used to find out which generic types should be included in the function generic type list * Fixed a crash after cyclic bound types were created during unification And in native code generation (jit): * Use of arm64 target on M1 now requires macOS 13 * Entry into native code has been optimized. This is especially important for coroutine call/pcall performance as they involve going through a C call frame * LOP_LOADK(X) translation into IR has been improved to enable type tag/constant propagation * arm64 can use integer immediate values to synthesize floating-point values * x64 assembler removes duplicate 64bit numbers from the data section to save space * Linux `perf` can now be used to profile native Luau code (when running with --codegen-perf CLI argument)
177 lines
6.9 KiB
C++
177 lines
6.9 KiB
C++
// This file is part of the Luau programming language and is licensed under MIT License; see LICENSE.txt for details
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#pragma once
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#include "Luau/Error.h"
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#include "Luau/Location.h"
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#include "Luau/ParseOptions.h"
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#include "Luau/Scope.h"
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#include "Luau/Substitution.h"
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#include "Luau/TxnLog.h"
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#include "Luau/TypeArena.h"
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#include "Luau/UnifierSharedState.h"
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#include "Normalize.h"
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#include <unordered_set>
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namespace Luau
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{
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enum Variance
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{
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Covariant,
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Invariant
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};
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// A substitution which replaces singleton types by their wider types
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struct Widen : Substitution
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{
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Widen(TypeArena* arena, NotNull<BuiltinTypes> builtinTypes)
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: Substitution(TxnLog::empty(), arena)
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, builtinTypes(builtinTypes)
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{
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}
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NotNull<BuiltinTypes> builtinTypes;
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bool isDirty(TypeId ty) override;
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bool isDirty(TypePackId ty) override;
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TypeId clean(TypeId ty) override;
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TypePackId clean(TypePackId ty) override;
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bool ignoreChildren(TypeId ty) override;
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TypeId operator()(TypeId ty);
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TypePackId operator()(TypePackId ty);
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};
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// TODO: Use this more widely.
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struct UnifierOptions
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{
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bool isFunctionCall = false;
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};
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struct Unifier
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{
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TypeArena* const types;
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NotNull<BuiltinTypes> builtinTypes;
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NotNull<Normalizer> normalizer;
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Mode mode;
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NotNull<Scope> scope; // const Scope maybe
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TxnLog log;
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bool failure = false;
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ErrorVec errors;
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Location location;
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Variance variance = Covariant;
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bool normalize = true; // Normalize unions and intersections if necessary
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bool checkInhabited = true; // Normalize types to check if they are inhabited
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CountMismatch::Context ctx = CountMismatch::Arg;
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// If true, generics act as free types when unifying.
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bool hideousFixMeGenericsAreActuallyFree = false;
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UnifierSharedState& sharedState;
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// When the Unifier is forced to unify two blocked types (or packs), they
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// get added to these vectors. The ConstraintSolver can use this to know
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// when it is safe to reattempt dispatching a constraint.
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std::vector<TypeId> blockedTypes;
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std::vector<TypePackId> blockedTypePacks;
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Unifier(
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NotNull<Normalizer> normalizer, Mode mode, NotNull<Scope> scope, const Location& location, Variance variance, TxnLog* parentLog = nullptr);
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// Configure the Unifier to test for scope subsumption via embedded Scope
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// pointers rather than TypeLevels.
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void enableScopeTests();
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// Test whether the two type vars unify. Never commits the result.
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ErrorVec canUnify(TypeId subTy, TypeId superTy);
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ErrorVec canUnify(TypePackId subTy, TypePackId superTy, bool isFunctionCall = false);
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/** Attempt to unify.
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* Populate the vector errors with any type errors that may arise.
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* Populate the transaction log with the set of TypeIds that need to be reset to undo the unification attempt.
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*/
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void tryUnify(TypeId subTy, TypeId superTy, bool isFunctionCall = false, bool isIntersection = false);
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private:
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void tryUnify_(TypeId subTy, TypeId superTy, bool isFunctionCall = false, bool isIntersection = false);
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void tryUnifyUnionWithType(TypeId subTy, const UnionType* uv, TypeId superTy);
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// Traverse the two types provided and block on any BlockedTypes we find.
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// Returns true if any types were blocked on.
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bool DEPRECATED_blockOnBlockedTypes(TypeId subTy, TypeId superTy);
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void tryUnifyTypeWithUnion(TypeId subTy, TypeId superTy, const UnionType* uv, bool cacheEnabled, bool isFunctionCall);
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void tryUnifyTypeWithIntersection(TypeId subTy, TypeId superTy, const IntersectionType* uv);
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void tryUnifyIntersectionWithType(TypeId subTy, const IntersectionType* uv, TypeId superTy, bool cacheEnabled, bool isFunctionCall);
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void tryUnifyNormalizedTypes(TypeId subTy, TypeId superTy, const NormalizedType& subNorm, const NormalizedType& superNorm, std::string reason,
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std::optional<TypeError> error = std::nullopt);
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void tryUnifyPrimitives(TypeId subTy, TypeId superTy);
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void tryUnifySingletons(TypeId subTy, TypeId superTy);
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void tryUnifyFunctions(TypeId subTy, TypeId superTy, bool isFunctionCall = false);
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void tryUnifyTables(TypeId subTy, TypeId superTy, bool isIntersection = false);
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void tryUnifyScalarShape(TypeId subTy, TypeId superTy, bool reversed);
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void tryUnifyWithMetatable(TypeId subTy, TypeId superTy, bool reversed);
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void tryUnifyWithClass(TypeId subTy, TypeId superTy, bool reversed);
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void tryUnifyNegations(TypeId subTy, TypeId superTy);
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TypePackId tryApplyOverloadedFunction(TypeId function, const NormalizedFunctionType& overloads, TypePackId args);
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TypeId widen(TypeId ty);
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TypePackId widen(TypePackId tp);
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TypeId deeplyOptional(TypeId ty, std::unordered_map<TypeId, TypeId> seen = {});
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bool canCacheResult(TypeId subTy, TypeId superTy);
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void cacheResult(TypeId subTy, TypeId superTy, size_t prevErrorCount);
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public:
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void tryUnify(TypePackId subTy, TypePackId superTy, bool isFunctionCall = false);
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private:
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void tryUnify_(TypePackId subTy, TypePackId superTy, bool isFunctionCall = false);
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void tryUnifyVariadics(TypePackId subTy, TypePackId superTy, bool reversed, int subOffset = 0);
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void tryUnifyWithAny(TypeId subTy, TypeId anyTy);
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void tryUnifyWithAny(TypePackId subTy, TypePackId anyTp);
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std::optional<TypeId> findTablePropertyRespectingMeta(TypeId lhsType, Name name);
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TxnLog combineLogsIntoIntersection(std::vector<TxnLog> logs);
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TxnLog combineLogsIntoUnion(std::vector<TxnLog> logs);
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public:
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// Returns true if the type "needle" already occurs within "haystack" and reports an "infinite type error"
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bool occursCheck(TypeId needle, TypeId haystack, bool reversed);
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bool occursCheck(DenseHashSet<TypeId>& seen, TypeId needle, TypeId haystack);
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bool occursCheck(TypePackId needle, TypePackId haystack, bool reversed);
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bool occursCheck(DenseHashSet<TypePackId>& seen, TypePackId needle, TypePackId haystack);
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Unifier makeChildUnifier();
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void reportError(TypeError err);
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LUAU_NOINLINE void reportError(Location location, TypeErrorData data);
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private:
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bool isNonstrictMode() const;
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TypeMismatch::Context mismatchContext();
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void checkChildUnifierTypeMismatch(const ErrorVec& innerErrors, TypeId wantedType, TypeId givenType);
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void checkChildUnifierTypeMismatch(const ErrorVec& innerErrors, const std::string& prop, TypeId wantedType, TypeId givenType);
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[[noreturn]] void ice(const std::string& message, const Location& location);
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[[noreturn]] void ice(const std::string& message);
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// Available after regular type pack unification errors
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std::optional<int> firstPackErrorPos;
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// If true, we use the scope hierarchy rather than TypeLevels
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bool useScopes = false;
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};
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void promoteTypeLevels(TxnLog& log, const TypeArena* arena, TypeLevel minLevel, Scope* outerScope, bool useScope, TypePackId tp);
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std::optional<TypeError> hasUnificationTooComplex(const ErrorVec& errors);
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std::optional<TypeError> hasCountMismatch(const ErrorVec& errors);
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} // namespace Luau
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