src/core/SkRecordPattern.h - skia - Git at Google

 #ifndef SkRecordPattern_DEFINED
 #define SkRecordPattern_DEFINED

 #include "SkTLogic.h"

 namespace SkRecords {

 // First, some matchers.  These match a single command in the SkRecord,
 // and may hang onto some data from it.  If so, you can get the data by calling .get().

 // Matches a command of type T, and stores that command.
 template <typename T>
 class Is {
 public:
     Is() : fPtr(NULL) {}

     typedef T type;
     type* get() { return fPtr; }

     bool operator()(T* ptr) {
         fPtr = ptr;
         return true;
     }

     template <typename U>
     bool operator()(U*) {
         fPtr = NULL;
         return false;
     }

 private:
     type* fPtr;
 };

 // Matches any command that draws, and stores its paint.
 class IsDraw {
     SK_CREATE_MEMBER_DETECTOR(paint);
 public:
     IsDraw() : fPaint(NULL) {}

     typedef SkPaint type;
     type* get() { return fPaint; }

     template <typename T>
     SK_WHEN(HasMember_paint<T>, bool) operator()(T* draw) {
         fPaint = AsPtr(draw->paint);
         return true;
     }

     template <typename T>
     SK_WHEN(!HasMember_paint<T>, bool) operator()(T*) {
         fPaint = NULL;
         return false;
     }

     // SaveLayer has an SkPaint named paint, but it's not a draw.
     bool operator()(SaveLayer*) {
         fPaint = NULL;
         return false;
     }

 private:
     // Abstracts away whether the paint is always part of the command or optional.
     template <typename T> static T* AsPtr(SkRecords::Optional<T>& x) { return x; }
     template <typename T> static T* AsPtr(T& x) { return &x; }

     type* fPaint;
 };

 // Matches if Matcher doesn't.  Stores nothing.
 template <typename Matcher>
 struct Not {
     template <typename T>
     bool operator()(T* ptr) { return !Matcher()(ptr); }
 };

 // Matches if either of A or B does.  Stores nothing.
 template <typename A, typename B>
 struct Or {
     template <typename T>
     bool operator()(T* ptr) { return A()(ptr) || B()(ptr); }
 };

 // Matches if any of A, B or C does.  Stores nothing.
 template <typename A, typename B, typename C>
 struct Or3 : Or<A, Or<B, C> > {};

 // Star is a special matcher that greedily matches Matcher 0 or more times.  Stores nothing.
 template <typename Matcher>
 struct Star {
     template <typename T>
     bool operator()(T* ptr) { return Matcher()(ptr); }
 };

 // Cons builds a list of Matchers.
 // It first matches Matcher (something from above), then Pattern (another Cons or Nil).
 //
 // This is the main entry point to pattern matching, and so provides a couple of extra API bits:
 //  - search scans through the record to look for matches;
 //  - first, second, and third return the data stored by their respective matchers in the pattern.
 //
 // These Cons build lists analogously to Lisp's "cons".  See Pattern# for the "list" equivalent.
 template <typename Matcher, typename Pattern>
 class Cons {
 public:
     // If this pattern matches the SkRecord starting at i,
     // return the index just past the end of the pattern, otherwise return 0.
     SK_ALWAYS_INLINE unsigned match(SkRecord* record, unsigned i) {
         i = this->matchHead(&fHead, record, i);
         return i == 0 ? 0 : fTail.match(record, i);
     }

     // Starting from *end, walk through the SkRecord to find the first span matching this pattern.
     // If there is no such span, return false.  If there is, return true and set [*begin, *end).
     SK_ALWAYS_INLINE bool search(SkRecord* record, unsigned* begin, unsigned* end) {
         for (*begin = *end; *begin < record->count(); ++(*begin)) {
             *end = this->match(record, *begin);
             if (*end != 0) {
                 return true;
             }
         }
         return false;
     }

     // Once either match or search has succeeded, access the stored data of the first, second,
     // or third matcher in this pattern.  Add as needed for longer patterns.
     // T is checked statically at compile time; no casting is involved.  It's just an API wart.
     template <typename T> T* first()  { return fHead.get(); }
     template <typename T> T* second() { return fTail.fHead.get(); }
     template <typename T> T* third()  { return fTail.fTail.fHead.get(); }

 private:
     // If head isn't a Star, try to match at i once.
     template <typename T>
     unsigned matchHead(T*, SkRecord* record, unsigned i) {
         if (i < record->count()) {
             if (record->mutate<bool>(i, fHead)) {
                 return i+1;
             }
         }
         return 0;
     }

     // If head is a Star, walk i until it doesn't match.
     template <typename T>
     unsigned matchHead(Star<T>*, SkRecord* record, unsigned i) {
         while (i < record->count()) {
             if (!record->mutate<bool>(i, fHead)) {
                 return i;
             }
             i++;
         }
         return 0;
     }

     Matcher fHead;
     Pattern fTail;

     // All Cons are friends with each other.  This lets first, second, and third work.
     template <typename, typename> friend class Cons;
 };

 // Nil is the end of every pattern Cons chain.
 struct Nil {
     // Bottoms out recursion down the fTail chain.  Just return whatever i the front decided on.
     unsigned match(SkRecord*, unsigned i) { return i; }
 };

 // These Pattern# types are syntax sugar over Cons and Nil, just to help eliminate some of the
 // template noise.  Use these if you can.  Feel free to add more for longer patterns.
 // All types A, B, C, ... are Matchers.
 template <typename A>
 struct Pattern1 : Cons<A, Nil> {};

 template <typename A, typename B>
 struct Pattern2 : Cons<A, Pattern1<B> > {};

 template <typename A, typename B, typename C>
 struct Pattern3 : Cons<A, Pattern2<B, C> > {};

 }  // namespace SkRecords

 #endif//SkRecordPattern_DEFINED
	#ifndef SkRecordPattern_DEFINED
	#define SkRecordPattern_DEFINED

	#include "SkTLogic.h"

	namespace SkRecords {

	// First, some matchers. These match a single command in the SkRecord,
	// and may hang onto some data from it. If so, you can get the data by calling .get().

	// Matches a command of type T, and stores that command.
	template <typename T>
	class Is {
	public:
	Is() : fPtr(NULL) {}

	typedef T type;
	type* get() { return fPtr; }

	bool operator()(T* ptr) {
	fPtr = ptr;
	return true;
	}

	template <typename U>
	bool operator()(U*) {
	fPtr = NULL;
	return false;
	}

	private:
	type* fPtr;
	};

	// Matches any command that draws, and stores its paint.
	class IsDraw {
	SK_CREATE_MEMBER_DETECTOR(paint);
	public:
	IsDraw() : fPaint(NULL) {}

	typedef SkPaint type;
	type* get() { return fPaint; }

	template <typename T>
	SK_WHEN(HasMember_paint<T>, bool) operator()(T* draw) {
	fPaint = AsPtr(draw->paint);
	return true;
	}

	template <typename T>
	SK_WHEN(!HasMember_paint<T>, bool) operator()(T*) {
	fPaint = NULL;
	return false;
	}

	// SaveLayer has an SkPaint named paint, but it's not a draw.
	bool operator()(SaveLayer*) {
	fPaint = NULL;
	return false;
	}

	private:
	// Abstracts away whether the paint is always part of the command or optional.
	template <typename T> static T* AsPtr(SkRecords::Optional<T>& x) { return x; }
	template <typename T> static T* AsPtr(T& x) { return &x; }

	type* fPaint;
	};

	// Matches if Matcher doesn't. Stores nothing.
	template <typename Matcher>
	struct Not {
	template <typename T>
	bool operator()(T* ptr) { return !Matcher()(ptr); }
	};

	// Matches if either of A or B does. Stores nothing.
	template <typename A, typename B>
	struct Or {
	template <typename T>
	bool operator()(T* ptr) { return A()(ptr) \|\| B()(ptr); }
	};

	// Matches if any of A, B or C does. Stores nothing.
	template <typename A, typename B, typename C>
	struct Or3 : Or<A, Or<B, C> > {};

	// Star is a special matcher that greedily matches Matcher 0 or more times. Stores nothing.
	template <typename Matcher>
	struct Star {
	template <typename T>
	bool operator()(T* ptr) { return Matcher()(ptr); }
	};

	// Cons builds a list of Matchers.
	// It first matches Matcher (something from above), then Pattern (another Cons or Nil).
	//
	// This is the main entry point to pattern matching, and so provides a couple of extra API bits:
	// - search scans through the record to look for matches;
	// - first, second, and third return the data stored by their respective matchers in the pattern.
	//
	// These Cons build lists analogously to Lisp's "cons". See Pattern# for the "list" equivalent.
	template <typename Matcher, typename Pattern>
	class Cons {
	public:
	// If this pattern matches the SkRecord starting at i,
	// return the index just past the end of the pattern, otherwise return 0.
	SK_ALWAYS_INLINE unsigned match(SkRecord* record, unsigned i) {
	i = this->matchHead(&fHead, record, i);
	return i == 0 ? 0 : fTail.match(record, i);
	}

	// Starting from *end, walk through the SkRecord to find the first span matching this pattern.
	// If there is no such span, return false. If there is, return true and set [begin, end).
	SK_ALWAYS_INLINE bool search(SkRecord* record, unsigned* begin, unsigned* end) {
	for (begin = end; begin < record->count(); ++(begin)) {
	end = this->match(record, begin);
	if (*end != 0) {
	return true;
	}
	}
	return false;
	}

	// Once either match or search has succeeded, access the stored data of the first, second,
	// or third matcher in this pattern. Add as needed for longer patterns.
	// T is checked statically at compile time; no casting is involved. It's just an API wart.
	template <typename T> T* first() { return fHead.get(); }
	template <typename T> T* second() { return fTail.fHead.get(); }
	template <typename T> T* third() { return fTail.fTail.fHead.get(); }

	private:
	// If head isn't a Star, try to match at i once.
	template <typename T>
	unsigned matchHead(T, SkRecord record, unsigned i) {
	if (i < record->count()) {
	if (record->mutate<bool>(i, fHead)) {
	return i+1;
	}
	}
	return 0;
	}

	// If head is a Star, walk i until it doesn't match.
	template <typename T>
	unsigned matchHead(Star<T>, SkRecord record, unsigned i) {
	while (i < record->count()) {
	if (!record->mutate<bool>(i, fHead)) {
	return i;
	}
	i++;
	}
	return 0;
	}

	Matcher fHead;
	Pattern fTail;

	// All Cons are friends with each other. This lets first, second, and third work.
	template <typename, typename> friend class Cons;
	};

	// Nil is the end of every pattern Cons chain.
	struct Nil {
	// Bottoms out recursion down the fTail chain. Just return whatever i the front decided on.
	unsigned match(SkRecord*, unsigned i) { return i; }
	};

	// These Pattern# types are syntax sugar over Cons and Nil, just to help eliminate some of the
	// template noise. Use these if you can. Feel free to add more for longer patterns.
	// All types A, B, C, ... are Matchers.
	template <typename A>
	struct Pattern1 : Cons<A, Nil> {};

	template <typename A, typename B>
	struct Pattern2 : Cons<A, Pattern1<B> > {};

	template <typename A, typename B, typename C>
	struct Pattern3 : Cons<A, Pattern2<B, C> > {};

	} // namespace SkRecords

	#endif//SkRecordPattern_DEFINED