luau/Analysis/include/Luau/EqSatSimplificationImpl.h

// This file is part of the Luau programming language and is licensed under MIT License; see LICENSE.txt for details

#pragma once

#include "Luau/EGraph.h"
#include "Luau/Id.h"
#include "Luau/Language.h"
#include "Luau/Lexer.h" // For Allocator
#include "Luau/NotNull.h"
#include "Luau/TypeArena.h"
#include "Luau/TypeFwd.h"

namespace Luau
{
struct TypeFunction;
}

namespace Luau::EqSatSimplification
{

using StringId = uint32_t;
using Id = Luau::EqSat::Id;

LUAU_EQSAT_UNIT(TNil);
LUAU_EQSAT_UNIT(TBoolean);
LUAU_EQSAT_UNIT(TNumber);
LUAU_EQSAT_UNIT(TString);
LUAU_EQSAT_UNIT(TThread);
LUAU_EQSAT_UNIT(TTopFunction);
LUAU_EQSAT_UNIT(TTopTable);
LUAU_EQSAT_UNIT(TTopClass);
LUAU_EQSAT_UNIT(TBuffer);

// Used for any type that eqsat can't do anything interesting with.
LUAU_EQSAT_ATOM(TOpaque, TypeId);

LUAU_EQSAT_ATOM(SBoolean, bool);
LUAU_EQSAT_ATOM(SString, StringId);

LUAU_EQSAT_ATOM(TFunction, TypeId);

LUAU_EQSAT_ATOM(TImportedTable, TypeId);

LUAU_EQSAT_ATOM(TClass, TypeId);

LUAU_EQSAT_UNIT(TAny);
LUAU_EQSAT_UNIT(TError);
LUAU_EQSAT_UNIT(TUnknown);
LUAU_EQSAT_UNIT(TNever);

LUAU_EQSAT_NODE_SET(Union);
LUAU_EQSAT_NODE_SET(Intersection);

LUAU_EQSAT_NODE_ARRAY(Negation, 1);

LUAU_EQSAT_NODE_ATOM_WITH_VECTOR(TTypeFun, const TypeFunction*);

LUAU_EQSAT_UNIT(TNoRefine);
LUAU_EQSAT_UNIT(Invalid);

// enodes are immutable, but types are cyclic.  We need a way to tie the knot.
// We handle this by generating TBound nodes at points where we encounter cycles.
// Each TBound has an ordinal that we later map onto the type.
// We use a substitution rule to replace all TBound nodes with their referrent.
LUAU_EQSAT_ATOM(TBound, size_t);

// Tables are sufficiently unlike other enodes that the Language.h macros won't cut it.
struct TTable
{
    explicit TTable(Id basis);
    TTable(Id basis, std::vector<StringId> propNames_, std::vector<Id> propTypes_);

    // All TTables extend some other table.  This may be TTopTable.
    //
    // It will frequently be a TImportedTable, in which case we can reuse things
    // like source location and documentation info.
    Id getBasis() const;
    EqSat::Slice<const Id> propTypes() const;
    // TODO: Also support read-only table props
    // TODO: Indexer type, index result type.

    std::vector<StringId> propNames;

    // The enode interface
    EqSat::Slice<Id> mutableOperands();
    EqSat::Slice<const Id> operands() const;
    bool operator==(const TTable& rhs) const;
    bool operator!=(const TTable& rhs) const
    {
        return !(*this == rhs);
    }

    struct Hash
    {
        size_t operator()(const TTable& value) const;
    };

private:
    // The first element of this vector is the basis.  Subsequent elements are
    // property types. As we add other things like read-only properties and
    // indexers, the structure of this array is likely to change.
    //
    // We encode our data in this way so that the operands() method can properly
    // return a Slice<Id>.
    std::vector<Id> storage;
};

using EType = EqSat::Language<
    TNil,
    TBoolean,
    TNumber,
    TString,
    TThread,
    TTopFunction,
    TTopTable,
    TTopClass,
    TBuffer,

    TOpaque,

    SBoolean,
    SString,

    TFunction,
    TTable,
    TImportedTable,
    TClass,

    TAny,
    TError,
    TUnknown,
    TNever,

    Union,
    Intersection,

    Negation,

    TTypeFun,

    Invalid,
    TNoRefine,
    TBound>;


struct StringCache
{
    Allocator allocator;
    DenseHashMap<size_t, StringId> strings{{}};
    std::vector<std::string_view> views;

    StringId add(std::string_view s);
    std::string_view asStringView(StringId id) const;
    std::string asString(StringId id) const;
};

using EGraph = Luau::EqSat::EGraph<EType, struct Simplify>;

struct Simplify
{
    using Data = bool;

    template<typename T>
    Data make(const EGraph&, const T&) const;

    void join(Data& left, const Data& right) const;
};

struct Subst
{
    Id eclass;
    Id newClass;

    std::string desc;

    Subst(Id eclass, Id newClass, std::string desc = "");
};

struct Simplifier
{
    NotNull<TypeArena> arena;
    NotNull<BuiltinTypes> builtinTypes;
    EGraph egraph;
    StringCache stringCache;

    // enodes are immutable but types can be cyclic, so we need some way to
    // encode the cycle. This map is used to connect TBound nodes to the right
    // eclass.
    //
    // The cyclicIntersection rewrite rule uses this to sense when a cycle can
    // be deleted from an intersection or union.
    std::unordered_map<size_t, Id> mappingIdToClass;

    std::vector<Subst> substs;

    using RewriteRuleFn = void (Simplifier::*)(Id id);

    Simplifier(NotNull<TypeArena> arena, NotNull<BuiltinTypes> builtinTypes);

    // Utilities
    const EqSat::EClass<EType, Simplify::Data>& get(Id id) const;
    Id find(Id id) const;
    Id add(EType enode);

    template<typename Tag>
    const Tag* isTag(Id id) const;

    template<typename Tag>
    const Tag* isTag(const EType& enode) const;

    void subst(Id from, Id to);
    void subst(Id from, Id to, const std::string& ruleName);
    void subst(Id from, Id to, const std::string& ruleName, const std::unordered_map<Id, size_t>& forceNodes);

    void unionClasses(std::vector<Id>& hereParts, Id there);

    // Rewrite rules
    void simplifyUnion(Id id);
    void uninhabitedIntersection(Id id);
    void intersectWithNegatedClass(Id id);
    void intersectWithNoRefine(Id id);
    void cyclicIntersectionOfUnion(Id id);
    void cyclicUnionOfIntersection(Id id);
    void expandNegation(Id id);
    void intersectionOfUnion(Id id);
    void intersectTableProperty(Id id);
    void uninhabitedTable(Id id);
    void unneededTableModification(Id id);
    void builtinTypeFunctions(Id id);
    void iffyTypeFunctions(Id id);
};

template<typename Tag>
struct QueryIterator
{
    QueryIterator();
    QueryIterator(EGraph* egraph, Id eclass);

    bool operator==(const QueryIterator& other) const;
    bool operator!=(const QueryIterator& other) const;

    std::pair<const Tag*, size_t> operator*() const;

    QueryIterator& operator++();
    QueryIterator& operator++(int);

private:
    EGraph* egraph = nullptr;
    Id eclass;
    size_t index = 0;
};

template<typename Tag>
struct Query
{
    EGraph* egraph;
    Id eclass;

    Query(EGraph* egraph, Id eclass)
        : egraph(egraph)
        , eclass(eclass)
    {
    }

    QueryIterator<Tag> begin()
    {
        return QueryIterator<Tag>{egraph, eclass};
    }

    QueryIterator<Tag> end()
    {
        return QueryIterator<Tag>{};
    }
};

template<typename Tag>
QueryIterator<Tag>::QueryIterator()
    : egraph(nullptr)
    , eclass(Id{0})
    , index(0)
{
}

template<typename Tag>
QueryIterator<Tag>::QueryIterator(EGraph* egraph_, Id eclass)
    : egraph(egraph_)
    , eclass(eclass)
    , index(0)
{
    const auto& ecl = (*egraph)[eclass];

    static constexpr const int idx = EType::VariantTy::getTypeId<Tag>();

    for (const auto& enode : ecl.nodes)
    {
        if (enode.index() < idx)
            ++index;
        else
            break;
    }

    if (index >= ecl.nodes.size() || ecl.nodes[index].index() != idx)
    {
        egraph = nullptr;
        index = 0;
    }
}

template<typename Tag>
bool QueryIterator<Tag>::operator==(const QueryIterator<Tag>& rhs) const
{
    if (egraph == nullptr && rhs.egraph == nullptr)
        return true;

    return egraph == rhs.egraph && eclass == rhs.eclass && index == rhs.index;
}

template<typename Tag>
bool QueryIterator<Tag>::operator!=(const QueryIterator<Tag>& rhs) const
{
    return !(*this == rhs);
}

template<typename Tag>
std::pair<const Tag*, size_t> QueryIterator<Tag>::operator*() const
{
    LUAU_ASSERT(egraph != nullptr);

    EGraph::EClassT& ecl = (*egraph)[eclass];

    LUAU_ASSERT(index < ecl.nodes.size());
    auto& enode = ecl.nodes[index];
    Tag* result = enode.template get<Tag>();
    LUAU_ASSERT(result);
    return {result, index};
}

// pre-increment
template<typename Tag>
QueryIterator<Tag>& QueryIterator<Tag>::operator++()
{
    const auto& ecl = (*egraph)[eclass];

    ++index;
    if (index >= ecl.nodes.size() || ecl.nodes[index].index() != EType::VariantTy::getTypeId<Tag>())
    {
        egraph = nullptr;
        index = 0;
    }

    return *this;
}

// post-increment
template<typename Tag>
QueryIterator<Tag>& QueryIterator<Tag>::operator++(int)
{
    QueryIterator<Tag> res = *this;
    ++res;
    return res;
}

} // namespace Luau::EqSatSimplification
Sync to `upstream/release/651` (#1513) ### What's New? * Fragment Autocomplete: a new API allows for type checking a small fragment of code against an existing file, significantly speeding up autocomplete performance in large files. ### New Solver * E-Graphs have landed: this is an ongoing approach to make the new type solver simplify types in a more consistent and principled manner, based on similar work (see: https://egraphs-good.github.io/). * Adds support for exporting / local user type functions (previously they were always exported). * Fixes a set of bugs in which the new solver will fail to complete inference for simple expressions with just literals and operators. ### General Updates * Requiring a path with a ".lua" or ".luau" extension will now have a bespoke error suggesting to remove said extension. * Fixes a bug in which whether two `Luau::Symbol`s are equal depends on whether the new solver is enabled. --- Internal Contributors: Co-authored-by: Aaron Weiss <aaronweiss@roblox.com> Co-authored-by: Andy Friesen <afriesen@roblox.com> Co-authored-by: David Cope <dcope@roblox.com> Co-authored-by: Hunter Goldstein <hgoldstein@roblox.com> Co-authored-by: Varun Saini <vsaini@roblox.com> Co-authored-by: Vighnesh Vijay <vvijay@roblox.com> Co-authored-by: Vyacheslav Egorov <vegorov@roblox.com> 2024-11-09 05:41:45 +08:00			`// This file is part of the Luau programming language and is licensed under MIT License; see LICENSE.txt for details`

			`#pragma once`

			`#include "Luau/EGraph.h"`
			`#include "Luau/Id.h"`
			`#include "Luau/Language.h"`
			`#include "Luau/Lexer.h" // For Allocator`
			`#include "Luau/NotNull.h"`
			`#include "Luau/TypeArena.h"`
			`#include "Luau/TypeFwd.h"`

			`namespace Luau`
			`{`
			`struct TypeFunction;`
			`}`

			`namespace Luau::EqSatSimplification`
			`{`

			`using StringId = uint32_t;`
			`using Id = Luau::EqSat::Id;`

			`LUAU_EQSAT_UNIT(TNil);`
			`LUAU_EQSAT_UNIT(TBoolean);`
			`LUAU_EQSAT_UNIT(TNumber);`
			`LUAU_EQSAT_UNIT(TString);`
			`LUAU_EQSAT_UNIT(TThread);`
			`LUAU_EQSAT_UNIT(TTopFunction);`
			`LUAU_EQSAT_UNIT(TTopTable);`
			`LUAU_EQSAT_UNIT(TTopClass);`
			`LUAU_EQSAT_UNIT(TBuffer);`

			`// Used for any type that eqsat can't do anything interesting with.`
			`LUAU_EQSAT_ATOM(TOpaque, TypeId);`

			`LUAU_EQSAT_ATOM(SBoolean, bool);`
			`LUAU_EQSAT_ATOM(SString, StringId);`

			`LUAU_EQSAT_ATOM(TFunction, TypeId);`

			`LUAU_EQSAT_ATOM(TImportedTable, TypeId);`

			`LUAU_EQSAT_ATOM(TClass, TypeId);`

			`LUAU_EQSAT_UNIT(TAny);`
			`LUAU_EQSAT_UNIT(TError);`
			`LUAU_EQSAT_UNIT(TUnknown);`
			`LUAU_EQSAT_UNIT(TNever);`

			`LUAU_EQSAT_NODE_SET(Union);`
			`LUAU_EQSAT_NODE_SET(Intersection);`

			`LUAU_EQSAT_NODE_ARRAY(Negation, 1);`

			`LUAU_EQSAT_NODE_ATOM_WITH_VECTOR(TTypeFun, const TypeFunction*);`

			`LUAU_EQSAT_UNIT(TNoRefine);`
			`LUAU_EQSAT_UNIT(Invalid);`

			`// enodes are immutable, but types are cyclic. We need a way to tie the knot.`
			`// We handle this by generating TBound nodes at points where we encounter cycles.`
			`// Each TBound has an ordinal that we later map onto the type.`
			`// We use a substitution rule to replace all TBound nodes with their referrent.`
			`LUAU_EQSAT_ATOM(TBound, size_t);`

			`// Tables are sufficiently unlike other enodes that the Language.h macros won't cut it.`
			`struct TTable`
			`{`
			`explicit TTable(Id basis);`
			`TTable(Id basis, std::vector<StringId> propNames_, std::vector<Id> propTypes_);`

			`// All TTables extend some other table. This may be TTopTable.`
			`//`
			`// It will frequently be a TImportedTable, in which case we can reuse things`
			`// like source location and documentation info.`
			`Id getBasis() const;`
			`EqSat::Slice<const Id> propTypes() const;`
			`// TODO: Also support read-only table props`
			`// TODO: Indexer type, index result type.`

			`std::vector<StringId> propNames;`

			`// The enode interface`
			`EqSat::Slice<Id> mutableOperands();`
			`EqSat::Slice<const Id> operands() const;`
			`bool operator==(const TTable& rhs) const;`
			`bool operator!=(const TTable& rhs) const`
			`{`
			`return !(*this == rhs);`
			`}`

			`struct Hash`
			`{`
			`size_t operator()(const TTable& value) const;`
			`};`

			`private:`
			`// The first element of this vector is the basis. Subsequent elements are`
			`// property types. As we add other things like read-only properties and`
			`// indexers, the structure of this array is likely to change.`
			`//`
			`// We encode our data in this way so that the operands() method can properly`
			`// return a Slice<Id>.`
			`std::vector<Id> storage;`
			`};`

			`using EType = EqSat::Language<`
			`TNil,`
			`TBoolean,`
			`TNumber,`
			`TString,`
			`TThread,`
			`TTopFunction,`
			`TTopTable,`
			`TTopClass,`
			`TBuffer,`

			`TOpaque,`

			`SBoolean,`
			`SString,`

			`TFunction,`
			`TTable,`
			`TImportedTable,`
			`TClass,`

			`TAny,`
			`TError,`
			`TUnknown,`
			`TNever,`

			`Union,`
			`Intersection,`

			`Negation,`

			`TTypeFun,`

			`Invalid,`
			`TNoRefine,`
			`TBound>;`


			`struct StringCache`
			`{`
			`Allocator allocator;`
			`DenseHashMap<size_t, StringId> strings{{}};`
			`std::vector<std::string_view> views;`

			`StringId add(std::string_view s);`
			`std::string_view asStringView(StringId id) const;`
			`std::string asString(StringId id) const;`
			`};`

			`using EGraph = Luau::EqSat::EGraph<EType, struct Simplify>;`

			`struct Simplify`
			`{`
			`using Data = bool;`

			`template<typename T>`
			`Data make(const EGraph&, const T&) const;`

			`void join(Data& left, const Data& right) const;`
			`};`

			`struct Subst`
			`{`
			`Id eclass;`
			`Id newClass;`

			`std::string desc;`

			`Subst(Id eclass, Id newClass, std::string desc = "");`
			`};`

			`struct Simplifier`
			`{`
			`NotNull<TypeArena> arena;`
			`NotNull<BuiltinTypes> builtinTypes;`
			`EGraph egraph;`
			`StringCache stringCache;`

			`// enodes are immutable but types can be cyclic, so we need some way to`
			`// encode the cycle. This map is used to connect TBound nodes to the right`
			`// eclass.`
			`//`
			`// The cyclicIntersection rewrite rule uses this to sense when a cycle can`
			`// be deleted from an intersection or union.`
			`std::unordered_map<size_t, Id> mappingIdToClass;`

			`std::vector<Subst> substs;`

			`using RewriteRuleFn = void (Simplifier::*)(Id id);`

			`Simplifier(NotNull<TypeArena> arena, NotNull<BuiltinTypes> builtinTypes);`

			`// Utilities`
			`const EqSat::EClass<EType, Simplify::Data>& get(Id id) const;`
			`Id find(Id id) const;`
			`Id add(EType enode);`

			`template<typename Tag>`
			`const Tag* isTag(Id id) const;`

			`template<typename Tag>`
			`const Tag* isTag(const EType& enode) const;`

			`void subst(Id from, Id to);`
			`void subst(Id from, Id to, const std::string& ruleName);`
			`void subst(Id from, Id to, const std::string& ruleName, const std::unordered_map<Id, size_t>& forceNodes);`

			`void unionClasses(std::vector<Id>& hereParts, Id there);`

			`// Rewrite rules`
			`void simplifyUnion(Id id);`
			`void uninhabitedIntersection(Id id);`
			`void intersectWithNegatedClass(Id id);`
			`void intersectWithNoRefine(Id id);`
			`void cyclicIntersectionOfUnion(Id id);`
			`void cyclicUnionOfIntersection(Id id);`
			`void expandNegation(Id id);`
			`void intersectionOfUnion(Id id);`
			`void intersectTableProperty(Id id);`
			`void uninhabitedTable(Id id);`
			`void unneededTableModification(Id id);`
			`void builtinTypeFunctions(Id id);`
			`void iffyTypeFunctions(Id id);`
			`};`

			`template<typename Tag>`
			`struct QueryIterator`
			`{`
			`QueryIterator();`
			`QueryIterator(EGraph* egraph, Id eclass);`

			`bool operator==(const QueryIterator& other) const;`
			`bool operator!=(const QueryIterator& other) const;`

			`std::pair<const Tag, size_t> operator() const;`

			`QueryIterator& operator++();`
			`QueryIterator& operator++(int);`

			`private:`
			`EGraph* egraph = nullptr;`
			`Id eclass;`
			`size_t index = 0;`
			`};`

			`template<typename Tag>`
			`struct Query`
			`{`
			`EGraph* egraph;`
			`Id eclass;`

			`Query(EGraph* egraph, Id eclass)`
			`: egraph(egraph)`
			`, eclass(eclass)`
			`{`
			`}`

			`QueryIterator<Tag> begin()`
			`{`
			`return QueryIterator<Tag>{egraph, eclass};`
			`}`

			`QueryIterator<Tag> end()`
			`{`
			`return QueryIterator<Tag>{};`
			`}`
			`};`

			`template<typename Tag>`
			`QueryIterator<Tag>::QueryIterator()`
			`: egraph(nullptr)`
			`, eclass(Id{0})`
			`, index(0)`
			`{`
			`}`

			`template<typename Tag>`
			`QueryIterator<Tag>::QueryIterator(EGraph* egraph_, Id eclass)`
			`: egraph(egraph_)`
			`, eclass(eclass)`
			`, index(0)`
			`{`
			`const auto& ecl = (*egraph)[eclass];`

			`static constexpr const int idx = EType::VariantTy::getTypeId<Tag>();`

			`for (const auto& enode : ecl.nodes)`
			`{`
			`if (enode.index() < idx)`
			`++index;`
			`else`
			`break;`
			`}`

			`if (index >= ecl.nodes.size() \|\| ecl.nodes[index].index() != idx)`
			`{`
			`egraph = nullptr;`
			`index = 0;`
			`}`
			`}`

			`template<typename Tag>`
			`bool QueryIterator<Tag>::operator==(const QueryIterator<Tag>& rhs) const`
			`{`
			`if (egraph == nullptr && rhs.egraph == nullptr)`
			`return true;`

			`return egraph == rhs.egraph && eclass == rhs.eclass && index == rhs.index;`
			`}`

			`template<typename Tag>`
			`bool QueryIterator<Tag>::operator!=(const QueryIterator<Tag>& rhs) const`
			`{`
			`return !(*this == rhs);`
			`}`

			`template<typename Tag>`
			`std::pair<const Tag, size_t> QueryIterator<Tag>::operator() const`
			`{`
			`LUAU_ASSERT(egraph != nullptr);`

			`EGraph::EClassT& ecl = (*egraph)[eclass];`

			`LUAU_ASSERT(index < ecl.nodes.size());`
			`auto& enode = ecl.nodes[index];`
			`Tag* result = enode.template get<Tag>();`
			`LUAU_ASSERT(result);`
			`return {result, index};`
			`}`

			`// pre-increment`
			`template<typename Tag>`
			`QueryIterator<Tag>& QueryIterator<Tag>::operator++()`
			`{`
			`const auto& ecl = (*egraph)[eclass];`

			`++index;`
			`if (index >= ecl.nodes.size() \|\| ecl.nodes[index].index() != EType::VariantTy::getTypeId<Tag>())`
			`{`
			`egraph = nullptr;`
			`index = 0;`
			`}`

			`return *this;`
			`}`

			`// post-increment`
			`template<typename Tag>`
			`QueryIterator<Tag>& QueryIterator<Tag>::operator++(int)`
			`{`
			`QueryIterator<Tag> res = *this;`
			`++res;`
			`return res;`
			`}`

			`} // namespace Luau::EqSatSimplification`