/* * Copyright 2019 Google LLC * * Use of this source code is governed by a BSD-style license that can be * found in the LICENSE file. */ #ifndef SkReflected_DEFINED #define SkReflected_DEFINED #include "include/core/SkColor.h" #include "include/core/SkRefCnt.h" #include "include/private/SkTArray.h" #include // std::function #include struct SkCurve; class SkFieldVisitor; struct SkPoint; class SkString; /** * Classes and macros for a lightweight reflection system. * * Classes that derive from SkReflected have several features: * - Access to an SkReflected::Type instance, via static GetType() or virtual getType() * The Type instance can be used to create additional instances (fFactory), get the name * of the type, and answer queries of the form "is X derived from Y". * - Given a string containing a type name, SkReflected can create an instance of that type. * - SkReflected::VisitTypes can be used to enumerate all Types. * * Together, this simplifies the implementation of serialization and other dynamic type factories. * * Finally, all SkReflected-derived types must implement visitFields, which provides field-level * reflection, in conjunction with SkFieldVisitor. See SkFieldVisitor, below. * * To create a new reflected class: * - Derive the class (directly or indirectly) from SkReflected. * - Ensure that the class can be default constructed. * - In the public area of the class declaration, add REFLECTED(, ). * If the class is abstract, use REFLECTED_ABSTRACT(, ) instead. * - Add a one-time call to REGISTER_REFLECTED() at initialization time. * - Implement visitFields(), as described below. */ class SkReflected : public SkRefCnt { public: typedef sk_sp(*Factory)(); struct Type { const char* fName; const Type* fBase; Factory fFactory; bool fRegistered = false; bool isDerivedFrom(const Type* t) const { const Type* base = fBase; while (base) { if (base == t) { return true; } base = base->fBase; } return false; } }; virtual const Type* getType() const = 0; static const Type* GetType() { static Type gType{ "SkReflected", nullptr, nullptr }; RegisterOnce(&gType); return &gType; } bool isOfType(const Type* t) const { const Type* thisType = this->getType(); return thisType == t || thisType->isDerivedFrom(t); } static sk_sp CreateInstance(const char* name) { for (const Type* type : gTypes) { if (0 == strcmp(name, type->fName)) { return type->fFactory(); } } return nullptr; } virtual void visitFields(SkFieldVisitor*) = 0; static void VisitTypes(std::function visitor); protected: static void RegisterOnce(Type* type) { if (!type->fRegistered) { gTypes.push_back(type); type->fRegistered = true; } } private: static SkSTArray<16, const Type*, true> gTypes; }; #define REFLECTED(TYPE, BASE) \ static sk_sp CreateProc() { \ return sk_sp(new TYPE()); \ } \ static const Type* GetType() { \ static Type gType{ #TYPE, BASE::GetType(), CreateProc }; \ RegisterOnce(&gType); \ return &gType; \ } \ const Type* getType() const override { return GetType(); } #define REFLECTED_ABSTRACT(TYPE, BASE) \ static const Type* GetType() { \ static Type gType{ #TYPE, BASE::GetType(), nullptr }; \ RegisterOnce(&gType); \ return &gType; \ } \ const Type* getType() const override { return GetType(); } #define REGISTER_REFLECTED(TYPE) TYPE::GetType() /////////////////////////////////////////////////////////////////////////////// /** * SkFieldVisitor is an interface that can be implemented by any class to visit all fields of * SkReflected types, and of types that implement the visitFields() function. * * Classes implementing the interface must supply implementations of virtual functions that visit * basic types (float, int, bool, SkString, etc...), as well as helper methods for entering the * scope of an object or array. * * All visit functions supply a field name, and a non-constant reference to an actual field. * This allows visitors to serialize or deserialize collections of objects, or perform edits on * existing objects. * * Classes that implement visitFields (typically derived from SkReflected) should simply call * visit() for each of their fields, passing a (unique) field name, and the actual field. If your * class has derived fields, it's best to only visit() the fields that you would serialize, then * enforce any constraints afterwards. * * See SkParticleSerialization.h for example visitors that perform serialization to and from JSON. */ class SkFieldVisitor { public: virtual ~SkFieldVisitor() {} // Visit functions for primitive types, to be implemented by derived visitors. virtual void visit(const char*, float&) = 0; virtual void visit(const char*, int&) = 0; virtual void visit(const char*, bool&) = 0; virtual void visit(const char*, SkString&) = 0; virtual void visit(const char*, SkPoint&) = 0; virtual void visit(const char*, SkColor4f&) = 0; // Accommodation for enums, where caller can supply a value <-> string map struct EnumStringMapping { int fValue; const char* fName; }; virtual void visit(const char*, int&, const EnumStringMapping*, int count) = 0; // Specific virtual signature for SkCurve, to allow for heavily customized UI in SkGuiVisitor. virtual void visit(const char* name, SkCurve& c); // Default visit function for structs with no special behavior. It is assumed that any such // struct implements visitFields(SkFieldVisitor*) to recursively visit each of its fields. template void visit(const char* name, T& value) { this->enterObject(name); value.visitFields(this); this->exitObject(); } // Specialization for SkTArrays. In conjunction with the enterArray/exitArray virtuals, this // allows visitors to resize an array (for deserialization), and apply a single edit operation // (remove or move a single element). Each element of the array is visited as normal. template void visit(const char* name, SkTArray& arr) { arr.resize_back(this->enterArray(name, arr.count())); for (int i = 0; i < arr.count(); ++i) { this->visit(nullptr, arr[i]); } this->exitArray().apply(arr); } // Specialization for sk_sp pointers to types derived from SkReflected. Those types are known // to implement visitFields. This allows the visitor to modify the contents of the object, or // even replace it with an entirely new object. The virtual function uses SkReflected as a // common type, but uses SkReflected::Type to communicate the required base-class. In this way, // the new object can be verified to match the type of the original (templated) pointer. template void visit(const char* name, sk_sp& obj) { this->enterObject(name); sk_sp newObj = obj; this->visit(newObj, T::GetType()); if (newObj != obj) { if (!newObj || newObj->isOfType(T::GetType())) { obj.reset(static_cast(newObj.release())); } else { obj.reset(); } } if (obj) { obj->visitFields(this); } this->exitObject(); } protected: // Helper struct to allow exitArray to specify a single operation performed on the array. struct ArrayEdit { enum class Verb { kNone, kRemove, kMoveForward, }; Verb fVerb = Verb::kNone; int fIndex = 0; template void apply(SkTArray& arr) const { switch (fVerb) { case Verb::kNone: break; case Verb::kRemove: for (int i = fIndex; i < arr.count() - 1; ++i) { arr[i] = arr[i + 1]; } arr.pop_back(); break; case Verb::kMoveForward: if (fIndex > 0 && fIndex < arr.count()) { std::swap(arr[fIndex - 1], arr[fIndex]); } break; } } }; static const char* EnumToString(int value, const EnumStringMapping* map, int count) { for (int i = 0; i < count; ++i) { if (map[i].fValue == value) { return map[i].fName; } } return nullptr; } static int StringToEnum(const char* str, const EnumStringMapping* map, int count) { for (int i = 0; i < count; ++i) { if (0 == strcmp(str, map[i].fName)) { return map[i].fValue; } } return -1; } virtual void enterObject(const char* name) = 0; virtual void exitObject() = 0; virtual int enterArray(const char* name, int oldCount) = 0; virtual ArrayEdit exitArray() = 0; virtual void visit(sk_sp&, const SkReflected::Type* baseType) = 0; }; #endif // SkReflected_DEFINED