src/utils/SkJSON.h - skia - Git at Google

 /*
  * Copyright 2018 Google Inc.
  *
  * Use of this source code is governed by a BSD-style license that can be
  * found in the LICENSE file.
  */

 #ifndef SkJSON_DEFINED
 #define SkJSON_DEFINED

 #include "include/core/SkTypes.h"
 #include "include/private/SkNoncopyable.h"
 #include "include/private/SkTo.h"
 #include "src/core/SkArenaAlloc.h"

 #include <cstring>

 class SkString;
 class SkWStream;

 namespace skjson {

 /**
  *  A fast and likely non-conforming JSON parser.
  *
  *  Some known limitations/compromises:
  *
  *    -- single-precision FP numbers
  *
  *    -- missing string unescaping (no current users, could be easily added)
  *
  *
  *  Values are opaque, fixed-size (64 bits), immutable records.
  *
  *  They can be converted to facade types for type-specific functionality.
  *
  *  E.g.:
  *
  *     if (v.is<ArrayValue>()) {
  *         for (const auto& item : v.as<ArrayValue>()) {
  *             if (const NumberValue* n = item) {
  *                 printf("Found number: %f", **n);
  *             }
  *         }
  *     }
  *
  *     if (v.is<ObjectValue>()) {
  *         const StringValue* id = v.as<ObjectValue>()["id"];
  *         if (id) {
  *             printf("Found object ID: %s", id->begin());
  *         } else {
  *             printf("Missing object ID");
  *         }
  *     }
  */
 class alignas(8) Value {
 public:
     enum class Type {
         kNull,
         kBool,
         kNumber,
         kString,
         kArray,
         kObject,
     };

     /**
      * @return    The type of this value.
      */
     Type getType() const;

     /**
      * @return    True if the record matches the facade type T.
      */
     template <typename T>
     bool is() const { return this->getType() == T::kType; }

     /**
      * Unguarded conversion to facade types.
      *
      * @return    The record cast as facade type T&.
      */
     template <typename T>
     const T& as() const {
         SkASSERT(this->is<T>());
         return *reinterpret_cast<const T*>(this);
     }

     /**
      * Guarded conversion to facade types.
      *
      * @return    The record cast as facade type T*.
      */
     template <typename T>
     operator const T*() const {
         return this->is<T>() ? &this->as<T>() : nullptr;
     }

     /**
      * @return    The string representation of this value.
      */
     SkString toString() const;

 protected:
     /*
       Value implementation notes:

         -- fixed 64-bit size

         -- 8-byte aligned

         -- union of:

              bool
              int32
              float
              char[8] (short string storage)
              external payload (tagged) pointer

          -- highest 3 bits reserved for type storage

      */
     enum class Tag : uint8_t {
         // We picked kShortString == 0 so that tag 0x00 and stored max_size-size (7-7=0)
         // conveniently overlap the '\0' terminator, allowing us to store a 7 character
         // C string inline.
         kShortString                  = 0b00000000,  // inline payload
         kNull                         = 0b00100000,  // no payload
         kBool                         = 0b01000000,  // inline payload
         kInt                          = 0b01100000,  // inline payload
         kFloat                        = 0b10000000,  // inline payload
         kString                       = 0b10100000,  // ptr to external storage
         kArray                        = 0b11000000,  // ptr to external storage
         kObject                       = 0b11100000,  // ptr to external storage
     };
     static constexpr uint8_t kTagMask = 0b11100000;

     void init_tagged(Tag);
     void init_tagged_pointer(Tag, void*);

     Tag getTag() const {
         return static_cast<Tag>(fData8[kTagOffset] & kTagMask);
     }

     // Access the record data as T.
     //
     // This is also used to access the payload for inline records.  Since the record type lives in
     // the high bits, sizeof(T) must be less than sizeof(Value) when accessing inline payloads.
     //
     // E.g.
     //
     //   uint8_t
     //    -----------------------------------------------------------------------
     //   |  val8  |  val8  |  val8  |  val8  |  val8  |  val8  |  val8  |    TYPE|
     //    -----------------------------------------------------------------------
     //
     //   uint32_t
     //    -----------------------------------------------------------------------
     //   |               val32               |          unused          |    TYPE|
     //    -----------------------------------------------------------------------
     //
     //   T* (64b)
     //    -----------------------------------------------------------------------
     //   |                        T* (kTypeShift bits)                      |TYPE|
     //    -----------------------------------------------------------------------
     //
     template <typename T>
     const T* cast() const {
         static_assert(sizeof (T) <=  sizeof(Value), "");
         static_assert(alignof(T) <= alignof(Value), "");
         return reinterpret_cast<const T*>(this);
     }

     template <typename T>
     T* cast() { return const_cast<T*>(const_cast<const Value*>(this)->cast<T>()); }

     // Access the pointer payload.
     template <typename T>
     const T* ptr() const {
         static_assert(sizeof(uintptr_t)     == sizeof(Value) ||
                       sizeof(uintptr_t) * 2 == sizeof(Value), "");

         return (sizeof(uintptr_t) < sizeof(Value))
             // For 32-bit, pointers are stored unmodified.
             ? *this->cast<const T*>()
             // For 64-bit, we use the high bits of the pointer as tag storage.
             : reinterpret_cast<T*>(*this->cast<uintptr_t>() & kTagPointerMask);
     }

 private:
     static constexpr size_t kValueSize = 8;

     uint8_t fData8[kValueSize];

 #if defined(SK_CPU_LENDIAN)
     static constexpr size_t kTagOffset = kValueSize - 1;

     static constexpr uintptr_t kTagPointerMask =
             ~(static_cast<uintptr_t>(kTagMask) << ((sizeof(uintptr_t) - 1) * 8));
 #else
     // The current value layout assumes LE and will take some tweaking for BE.
     static_assert(false, "Big-endian builds are not supported at this time.");
 #endif
 };

 class NullValue final : public Value {
 public:
     static constexpr Type kType = Type::kNull;

     NullValue();
 };

 class BoolValue final : public Value {
 public:
     static constexpr Type kType = Type::kBool;

     explicit BoolValue(bool);

     bool operator *() const {
         SkASSERT(this->getTag() == Tag::kBool);
         return *this->cast<bool>();
     }
 };

 class NumberValue final : public Value {
 public:
     static constexpr Type kType = Type::kNumber;

     explicit NumberValue(int32_t);
     explicit NumberValue(float);

     double operator *() const {
         SkASSERT(this->getTag() == Tag::kInt ||
                  this->getTag() == Tag::kFloat);

         return this->getTag() == Tag::kInt
             ? static_cast<double>(*this->cast<int32_t>())
             : static_cast<double>(*this->cast<float>());
     }
 };

 template <typename T, Value::Type vtype>
 class VectorValue : public Value {
 public:
     using ValueT = T;
     static constexpr Type kType = vtype;

     size_t size() const {
         SkASSERT(this->getType() == kType);
         return *this->ptr<size_t>();
     }

     const T* begin() const {
         SkASSERT(this->getType() == kType);
         const auto* size_ptr = this->ptr<size_t>();
         return reinterpret_cast<const T*>(size_ptr + 1);
     }

     const T* end() const {
         SkASSERT(this->getType() == kType);
         const auto* size_ptr = this->ptr<size_t>();
         return reinterpret_cast<const T*>(size_ptr + 1) + *size_ptr;
     }

     const T& operator[](size_t i) const {
         SkASSERT(this->getType() == kType);
         SkASSERT(i < this->size());

         return *(this->begin() + i);
     }
 };

 class ArrayValue final : public VectorValue<Value, Value::Type::kArray> {
 public:
     ArrayValue(const Value* src, size_t size, SkArenaAlloc& alloc);
 };

 class StringValue final : public Value {
 public:
     static constexpr Type kType = Type::kString;

     StringValue();
     StringValue(const char* src, size_t size, SkArenaAlloc& alloc);

     size_t size() const {
         switch (this->getTag()) {
         case Tag::kShortString:
             // We don't bother storing a length for short strings on the assumption
             // that strlen is fast in this case.  If this becomes problematic, we
             // can either go back to storing (7-len) in the tag byte or write a fast
             // short_strlen.
             return strlen(this->cast<char>());
         case Tag::kString:
             return this->cast<VectorValue<char, Value::Type::kString>>()->size();
         default:
             return 0;
         }
     }

     const char* begin() const {
         return this->getTag() == Tag::kShortString
             ? this->cast<char>()
             : this->cast<VectorValue<char, Value::Type::kString>>()->begin();
     }

     const char* end() const {
         return this->getTag() == Tag::kShortString
             ? strchr(this->cast<char>(), '\0')
             : this->cast<VectorValue<char, Value::Type::kString>>()->end();
     }
 };

 struct Member {
     StringValue fKey;
           Value fValue;
 };

 class ObjectValue final : public VectorValue<Member, Value::Type::kObject> {
 public:
     ObjectValue(const Member* src, size_t size, SkArenaAlloc& alloc);

     const Value& operator[](const char*) const;

 private:
     // Not particularly interesting - hiding for disambiguation.
     const Member& operator[](size_t i) const = delete;
 };

 class DOM final : public SkNoncopyable {
 public:
     DOM(const char*, size_t);

     const Value& root() const { return fRoot; }

     void write(SkWStream*) const;

 private:
     SkArenaAlloc fAlloc;
     Value        fRoot;
 };

 inline Value::Type Value::getType() const {
     switch (this->getTag()) {
     case Tag::kNull:        return Type::kNull;
     case Tag::kBool:        return Type::kBool;
     case Tag::kInt:         return Type::kNumber;
     case Tag::kFloat:       return Type::kNumber;
     case Tag::kShortString: return Type::kString;
     case Tag::kString:      return Type::kString;
     case Tag::kArray:       return Type::kArray;
     case Tag::kObject:      return Type::kObject;
     }

     SkASSERT(false); // unreachable
     return Type::kNull;
 }

 } // namespace skjson

 #endif // SkJSON_DEFINED
	/*
	* Copyright 2018 Google Inc.
	*
	* Use of this source code is governed by a BSD-style license that can be
	* found in the LICENSE file.
	*/

	#ifndef SkJSON_DEFINED
	#define SkJSON_DEFINED

	#include "include/core/SkTypes.h"
	#include "include/private/SkNoncopyable.h"
	#include "include/private/SkTo.h"
	#include "src/core/SkArenaAlloc.h"

	#include <cstring>

	class SkString;
	class SkWStream;

	namespace skjson {

	/**
	* A fast and likely non-conforming JSON parser.
	*
	* Some known limitations/compromises:
	*
	* -- single-precision FP numbers
	*
	* -- missing string unescaping (no current users, could be easily added)
	*
	*
	* Values are opaque, fixed-size (64 bits), immutable records.
	*
	* They can be converted to facade types for type-specific functionality.
	*
	* E.g.:
	*
	* if (v.is<ArrayValue>()) {
	* for (const auto& item : v.as<ArrayValue>()) {
	* if (const NumberValue* n = item) {
	* printf("Found number: %f", **n);
	* }
	* }
	* }
	*
	* if (v.is<ObjectValue>()) {
	* const StringValue* id = v.as<ObjectValue>()["id"];
	* if (id) {
	* printf("Found object ID: %s", id->begin());
	* } else {
	* printf("Missing object ID");
	* }
	* }
	*/
	class alignas(8) Value {
	public:
	enum class Type {
	kNull,
	kBool,
	kNumber,
	kString,
	kArray,
	kObject,
	};

	/**
	* @return The type of this value.
	*/
	Type getType() const;

	/**
	* @return True if the record matches the facade type T.
	*/
	template <typename T>
	bool is() const { return this->getType() == T::kType; }

	/**
	* Unguarded conversion to facade types.
	*
	* @return The record cast as facade type T&.
	*/
	template <typename T>
	const T& as() const {
	SkASSERT(this->is<T>());
	return reinterpret_cast<const T>(this);
	}

	/**
	* Guarded conversion to facade types.
	*
	* @return The record cast as facade type T*.
	*/
	template <typename T>
	operator const T*() const {
	return this->is<T>() ? &this->as<T>() : nullptr;
	}

	/**
	* @return The string representation of this value.
	*/
	SkString toString() const;

	protected:
	/*
	Value implementation notes:

	-- fixed 64-bit size

	-- 8-byte aligned

	-- union of:

	bool
	int32
	float
	char[8] (short string storage)
	external payload (tagged) pointer

	-- highest 3 bits reserved for type storage

	*/
	enum class Tag : uint8_t {
	// We picked kShortString == 0 so that tag 0x00 and stored max_size-size (7-7=0)
	// conveniently overlap the '\0' terminator, allowing us to store a 7 character
	// C string inline.
	kShortString = 0b00000000, // inline payload
	kNull = 0b00100000, // no payload
	kBool = 0b01000000, // inline payload
	kInt = 0b01100000, // inline payload
	kFloat = 0b10000000, // inline payload
	kString = 0b10100000, // ptr to external storage
	kArray = 0b11000000, // ptr to external storage
	kObject = 0b11100000, // ptr to external storage
	};
	static constexpr uint8_t kTagMask = 0b11100000;

	void init_tagged(Tag);
	void init_tagged_pointer(Tag, void*);

	Tag getTag() const {
	return static_cast<Tag>(fData8[kTagOffset] & kTagMask);
	}

	// Access the record data as T.
	//
	// This is also used to access the payload for inline records. Since the record type lives in
	// the high bits, sizeof(T) must be less than sizeof(Value) when accessing inline payloads.
	//
	// E.g.
	//
	// uint8_t
	// -----------------------------------------------------------------------
	// \| val8 \| val8 \| val8 \| val8 \| val8 \| val8 \| val8 \| TYPE\|
	// -----------------------------------------------------------------------
	//
	// uint32_t
	// -----------------------------------------------------------------------
	// \| val32 \| unused \| TYPE\|
	// -----------------------------------------------------------------------
	//
	// T* (64b)
	// -----------------------------------------------------------------------
	// \| T* (kTypeShift bits) \|TYPE\|
	// -----------------------------------------------------------------------
	//
	template <typename T>
	const T* cast() const {
	static_assert(sizeof (T) <= sizeof(Value), "");
	static_assert(alignof(T) <= alignof(Value), "");
	return reinterpret_cast<const T*>(this);
	}

	template <typename T>
	T* cast() { return const_cast<T>(const_cast<const Value>(this)->cast<T>()); }

	// Access the pointer payload.
	template <typename T>
	const T* ptr() const {
	static_assert(sizeof(uintptr_t) == sizeof(Value) \|\|
	sizeof(uintptr_t) * 2 == sizeof(Value), "");

	return (sizeof(uintptr_t) < sizeof(Value))
	// For 32-bit, pointers are stored unmodified.
	? this->cast<const T>()
	// For 64-bit, we use the high bits of the pointer as tag storage.
	: reinterpret_cast<T>(this->cast<uintptr_t>() & kTagPointerMask);
	}

	private:
	static constexpr size_t kValueSize = 8;

	uint8_t fData8[kValueSize];

	#if defined(SK_CPU_LENDIAN)
	static constexpr size_t kTagOffset = kValueSize - 1;

	static constexpr uintptr_t kTagPointerMask =
	~(static_cast<uintptr_t>(kTagMask) << ((sizeof(uintptr_t) - 1) * 8));
	#else
	// The current value layout assumes LE and will take some tweaking for BE.
	static_assert(false, "Big-endian builds are not supported at this time.");
	#endif
	};

	class NullValue final : public Value {
	public:
	static constexpr Type kType = Type::kNull;

	NullValue();
	};

	class BoolValue final : public Value {
	public:
	static constexpr Type kType = Type::kBool;

	explicit BoolValue(bool);

	bool operator *() const {
	SkASSERT(this->getTag() == Tag::kBool);
	return *this->cast<bool>();
	}
	};

	class NumberValue final : public Value {
	public:
	static constexpr Type kType = Type::kNumber;

	explicit NumberValue(int32_t);
	explicit NumberValue(float);

	double operator *() const {
	SkASSERT(this->getTag() == Tag::kInt \|\|
	this->getTag() == Tag::kFloat);

	return this->getTag() == Tag::kInt
	? static_cast<double>(*this->cast<int32_t>())
	: static_cast<double>(*this->cast<float>());
	}
	};

	template <typename T, Value::Type vtype>
	class VectorValue : public Value {
	public:
	using ValueT = T;
	static constexpr Type kType = vtype;

	size_t size() const {
	SkASSERT(this->getType() == kType);
	return *this->ptr<size_t>();
	}

	const T* begin() const {
	SkASSERT(this->getType() == kType);
	const auto* size_ptr = this->ptr<size_t>();
	return reinterpret_cast<const T*>(size_ptr + 1);
	}

	const T* end() const {
	SkASSERT(this->getType() == kType);
	const auto* size_ptr = this->ptr<size_t>();
	return reinterpret_cast<const T>(size_ptr + 1) + size_ptr;
	}

	const T& operator[](size_t i) const {
	SkASSERT(this->getType() == kType);
	SkASSERT(i < this->size());

	return *(this->begin() + i);
	}
	};

	class ArrayValue final : public VectorValue<Value, Value::Type::kArray> {
	public:
	ArrayValue(const Value* src, size_t size, SkArenaAlloc& alloc);
	};

	class StringValue final : public Value {
	public:
	static constexpr Type kType = Type::kString;

	StringValue();
	StringValue(const char* src, size_t size, SkArenaAlloc& alloc);

	size_t size() const {
	switch (this->getTag()) {
	case Tag::kShortString:
	// We don't bother storing a length for short strings on the assumption
	// that strlen is fast in this case. If this becomes problematic, we
	// can either go back to storing (7-len) in the tag byte or write a fast
	// short_strlen.
	return strlen(this->cast<char>());
	case Tag::kString:
	return this->cast<VectorValue<char, Value::Type::kString>>()->size();
	default:
	return 0;
	}
	}

	const char* begin() const {
	return this->getTag() == Tag::kShortString
	? this->cast<char>()
	: this->cast<VectorValue<char, Value::Type::kString>>()->begin();
	}

	const char* end() const {
	return this->getTag() == Tag::kShortString
	? strchr(this->cast<char>(), '\0')
	: this->cast<VectorValue<char, Value::Type::kString>>()->end();
	}
	};

	struct Member {
	StringValue fKey;
	Value fValue;
	};

	class ObjectValue final : public VectorValue<Member, Value::Type::kObject> {
	public:
	ObjectValue(const Member* src, size_t size, SkArenaAlloc& alloc);

	const Value& operator[](const char*) const;

	private:
	// Not particularly interesting - hiding for disambiguation.
	const Member& operator[](size_t i) const = delete;
	};

	class DOM final : public SkNoncopyable {
	public:
	DOM(const char*, size_t);

	const Value& root() const { return fRoot; }

	void write(SkWStream*) const;

	private:
	SkArenaAlloc fAlloc;
	Value fRoot;
	};

	inline Value::Type Value::getType() const {
	switch (this->getTag()) {
	case Tag::kNull: return Type::kNull;
	case Tag::kBool: return Type::kBool;
	case Tag::kInt: return Type::kNumber;
	case Tag::kFloat: return Type::kNumber;
	case Tag::kShortString: return Type::kString;
	case Tag::kString: return Type::kString;
	case Tag::kArray: return Type::kArray;
	case Tag::kObject: return Type::kObject;
	}

	SkASSERT(false); // unreachable
	return Type::kNull;
	}

	} // namespace skjson

	#endif // SkJSON_DEFINED