luau/Analysis/include/Luau/Constraint.h
Andy Friesen e25de95445
Sync to upstream/release/583 (#974)
* Fixed indexing table intersections using `x["prop"]` syntax:
https://github.com/Roblox/luau/pull/971
* Add console output codepage for Windows:
https://github.com/Roblox/luau/pull/967
* Added `Frontend::parse` for a fast source graph preparation
* luau_load should check GC
* Work toward a type-diff system for nicer error messages

New Solver
* Correctly suppress errors in more cases
* Further improvements to typechecking of function calls and return
statements
* Crash fixes
* Propagate refinements drawn from the condition of a while loop into
the loop body

JIT
* Fix accidental bailout for math.frexp/modf/sign in A64
* Work toward bringing type annotation info in
* Do not propagate Luau IR constants of wrong type into load
instructions
* CHECK_SAFEENV exits to VM on failure
* Implement error handling in A64 reg allocator
* Inline the string.len builtin
* Do not enter native code of a function if arguments don’t match

---------

Co-authored-by: Arseny Kapoulkine <arseny.kapoulkine@gmail.com>
Co-authored-by: Vyacheslav Egorov <vegorov@roblox.com>
2023-07-07 13:10:48 -07:00

298 lines
7.6 KiB
C++

// This file is part of the Luau programming language and is licensed under MIT License; see LICENSE.txt for details
#pragma once
#include "Luau/Ast.h" // Used for some of the enumerations
#include "Luau/DenseHash.h"
#include "Luau/NotNull.h"
#include "Luau/Type.h"
#include "Luau/Variant.h"
#include <string>
#include <memory>
#include <vector>
namespace Luau
{
struct Scope;
struct Type;
using TypeId = const Type*;
struct TypePackVar;
using TypePackId = const TypePackVar*;
// subType <: superType
struct SubtypeConstraint
{
TypeId subType;
TypeId superType;
};
// subPack <: superPack
struct PackSubtypeConstraint
{
TypePackId subPack;
TypePackId superPack;
// HACK!! TODO clip.
// We need to know which of `PackSubtypeConstraint` are emitted from `AstStatReturn` vs any others.
// Then we force these specific `PackSubtypeConstraint` to only dispatch in the order of the `return`s.
bool returns = false;
};
// generalizedType ~ gen sourceType
struct GeneralizationConstraint
{
TypeId generalizedType;
TypeId sourceType;
};
// subType ~ inst superType
struct InstantiationConstraint
{
TypeId subType;
TypeId superType;
};
struct UnaryConstraint
{
AstExprUnary::Op op;
TypeId operandType;
TypeId resultType;
};
// let L : leftType
// let R : rightType
// in
// L op R : resultType
struct BinaryConstraint
{
AstExprBinary::Op op;
TypeId leftType;
TypeId rightType;
TypeId resultType;
// When we dispatch this constraint, we update the key at this map to record
// the overload that we selected.
const AstNode* astFragment;
DenseHashMap<const AstNode*, TypeId>* astOriginalCallTypes;
DenseHashMap<const AstNode*, TypeId>* astOverloadResolvedTypes;
};
// iteratee is iterable
// iterators is the iteration types.
struct IterableConstraint
{
TypePackId iterator;
TypePackId variables;
const AstNode* nextAstFragment;
DenseHashMap<const AstNode*, TypeId>* astForInNextTypes;
};
// name(namedType) = name
struct NameConstraint
{
TypeId namedType;
std::string name;
bool synthetic = false;
std::vector<TypeId> typeParameters;
std::vector<TypePackId> typePackParameters;
};
// target ~ inst target
struct TypeAliasExpansionConstraint
{
// Must be a PendingExpansionType.
TypeId target;
};
struct FunctionCallConstraint
{
TypeId fn;
TypePackId argsPack;
TypePackId result;
class AstExprCall* callSite = nullptr;
std::vector<std::optional<TypeId>> discriminantTypes;
// When we dispatch this constraint, we update the key at this map to record
// the overload that we selected.
DenseHashMap<const AstNode*, TypeId>* astOverloadResolvedTypes = nullptr;
};
// result ~ prim ExpectedType SomeSingletonType MultitonType
//
// If ExpectedType is potentially a singleton (an actual singleton or a union
// that contains a singleton), then result ~ SomeSingletonType
//
// else result ~ MultitonType
struct PrimitiveTypeConstraint
{
TypeId resultType;
TypeId expectedType;
TypeId singletonType;
TypeId multitonType;
};
// result ~ hasProp type "prop_name"
//
// If the subject is a table, bind the result to the named prop. If the table
// has an indexer, bind it to the index result type. If the subject is a union,
// bind the result to the union of its constituents' properties.
//
// It would be nice to get rid of this constraint and someday replace it with
//
// T <: {p: X}
//
// Where {} describes an inexact shape type.
struct HasPropConstraint
{
TypeId resultType;
TypeId subjectType;
std::string prop;
// HACK: We presently need types like true|false or string|"hello" when
// deciding whether a particular literal expression should have a singleton
// type. This boolean is set to true when extracting the property type of a
// value that may be a union of tables.
//
// For example, in the following code fragment, we want the lookup of the
// success property to yield true|false when extracting an expectedType in
// this expression:
//
// type Result<T, E> = {success:true, result: T} | {success:false, error: E}
//
// local r: Result<number, string> = {success=true, result=9}
//
// If we naively simplify the expectedType to boolean, we will erroneously
// compute the type boolean for the success property of the table literal.
// This causes type checking to fail.
bool suppressSimplification = false;
};
// result ~ setProp subjectType ["prop", "prop2", ...] propType
//
// If the subject is a table or table-like thing that already has the named
// property chain, we unify propType with that existing property type.
//
// If the subject is a free table, we augment it in place.
//
// If the subject is an unsealed table, result is an augmented table that
// includes that new prop.
struct SetPropConstraint
{
TypeId resultType;
TypeId subjectType;
std::vector<std::string> path;
TypeId propType;
};
// result ~ setIndexer subjectType indexType propType
//
// If the subject is a table or table-like thing that already has an indexer,
// unify its indexType and propType with those from this constraint.
//
// If the table is a free or unsealed table, we augment it with a new indexer.
struct SetIndexerConstraint
{
TypeId resultType;
TypeId subjectType;
TypeId indexType;
TypeId propType;
};
// if negation:
// result ~ if isSingleton D then ~D else unknown where D = discriminantType
// if not negation:
// result ~ if isSingleton D then D else unknown where D = discriminantType
struct SingletonOrTopTypeConstraint
{
TypeId resultType;
TypeId discriminantType;
bool negated;
};
// resultType ~ unpack sourceTypePack
//
// Similar to PackSubtypeConstraint, but with one important difference: If the
// sourcePack is blocked, this constraint blocks.
struct UnpackConstraint
{
TypePackId resultPack;
TypePackId sourcePack;
};
// resultType ~ refine type mode discriminant
//
// Compute type & discriminant (or type | discriminant) as soon as possible (but
// no sooner), simplify, and bind resultType to that type.
struct RefineConstraint
{
enum
{
Intersection,
Union
} mode;
TypeId resultType;
TypeId type;
TypeId discriminant;
};
// ty ~ reduce ty
//
// Try to reduce ty, if it is a TypeFamilyInstanceType. Otherwise, do nothing.
struct ReduceConstraint
{
TypeId ty;
};
// tp ~ reduce tp
//
// Analogous to ReduceConstraint, but for type packs.
struct ReducePackConstraint
{
TypePackId tp;
};
using ConstraintV = Variant<SubtypeConstraint, PackSubtypeConstraint, GeneralizationConstraint, InstantiationConstraint, UnaryConstraint,
BinaryConstraint, IterableConstraint, NameConstraint, TypeAliasExpansionConstraint, FunctionCallConstraint, PrimitiveTypeConstraint,
HasPropConstraint, SetPropConstraint, SetIndexerConstraint, SingletonOrTopTypeConstraint, UnpackConstraint, RefineConstraint, ReduceConstraint,
ReducePackConstraint>;
struct Constraint
{
Constraint(NotNull<Scope> scope, const Location& location, ConstraintV&& c);
Constraint(const Constraint&) = delete;
Constraint& operator=(const Constraint&) = delete;
NotNull<Scope> scope;
Location location;
ConstraintV c;
std::vector<NotNull<Constraint>> dependencies;
};
using ConstraintPtr = std::unique_ptr<Constraint>;
inline Constraint& asMutable(const Constraint& c)
{
return const_cast<Constraint&>(c);
}
template<typename T>
T* getMutable(Constraint& c)
{
return ::Luau::get_if<T>(&c.c);
}
template<typename T>
const T* get(const Constraint& c)
{
return getMutable<T>(asMutable(c));
}
} // namespace Luau