re2/prefilter.h - re2 - Git at Google

 // Copyright 2009 The RE2 Authors.  All Rights Reserved.
 // Use of this source code is governed by a BSD-style
 // license that can be found in the LICENSE file.

 #ifndef RE2_PREFILTER_H_
 #define RE2_PREFILTER_H_

 // Prefilter is the class used to extract string guards from regexps.
 // Rather than using Prefilter class directly, use FilteredRE2.
 // See filtered_re2.h

 #include <set>
 #include <string>
 #include <vector>

 #include "util/logging.h"

 namespace re2 {

 class RE2;

 class Regexp;

 class Prefilter {
   // Instead of using Prefilter directly, use FilteredRE2; see filtered_re2.h
  public:
   enum Op {
     ALL = 0,  // Everything matches
     NONE,  // Nothing matches
     ATOM,  // The string atom() must match
     AND,   // All in subs() must match
     OR,   // One of subs() must match
   };

   explicit Prefilter(Op op);
   ~Prefilter();

   Op op() { return op_; }
   const std::string& atom() const { return atom_; }
   void set_unique_id(int id) { unique_id_ = id; }
   int unique_id() const { return unique_id_; }

   // The children of the Prefilter node.
   std::vector<Prefilter*>* subs() {
     DCHECK(op_ == AND || op_ == OR);
     return subs_;
   }

   // Set the children vector. Prefilter takes ownership of subs and
   // subs_ will be deleted when Prefilter is deleted.
   void set_subs(std::vector<Prefilter*>* subs) { subs_ = subs; }

   // Given a RE2, return a Prefilter. The caller takes ownership of
   // the Prefilter and should deallocate it. Returns NULL if Prefilter
   // cannot be formed.
   static Prefilter* FromRE2(const RE2* re2);

   // Returns a readable debug string of the prefilter.
   std::string DebugString() const;

  private:
   template <typename H>
   friend H AbslHashValue(H h, const Prefilter& a) {
     h = H::combine(std::move(h), a.op_);
     if (a.op_ == ATOM) {
       h = H::combine(std::move(h), a.atom_);
     } else if (a.op_ == AND || a.op_ == OR) {
       h = H::combine(std::move(h), a.subs_->size());
       for (size_t i = 0; i < a.subs_->size(); ++i) {
         h = H::combine(std::move(h), (*a.subs_)[i]->unique_id_);
       }
     }
     return h;
   }

   friend bool operator==(const Prefilter& a, const Prefilter& b) {
     if (&a == &b) {
       return true;
     }
     if (a.op_ != b.op_) {
       return false;
     }
     if (a.op_ == ATOM) {
       if (a.atom_ != b.atom_) {
         return false;
       }
     } else if (a.op_ == AND || a.op_ == OR) {
       if (a.subs_->size() != b.subs_->size()) {
         return false;
       }
       for (size_t i = 0; i < a.subs_->size(); ++i) {
         if ((*a.subs_)[i]->unique_id_ != (*b.subs_)[i]->unique_id_) {
           return false;
         }
       }
     }
     return true;
   }

   // A comparator used to store exact strings. We compare by length,
   // then lexicographically. This ordering makes it easier to reduce the
   // set of strings in SimplifyStringSet.
   struct LengthThenLex {
     bool operator()(const std::string& a, const std::string& b) const {
        return (a.size() < b.size()) || (a.size() == b.size() && a < b);
     }
   };

   class Info;

   using SSet = std::set<std::string, LengthThenLex>;
   using SSIter = SSet::iterator;
   using ConstSSIter = SSet::const_iterator;

   // Combines two prefilters together to create an AND. The passed
   // Prefilters will be part of the returned Prefilter or deleted.
   static Prefilter* And(Prefilter* a, Prefilter* b);

   // Combines two prefilters together to create an OR. The passed
   // Prefilters will be part of the returned Prefilter or deleted.
   static Prefilter* Or(Prefilter* a, Prefilter* b);

   // Generalized And/Or
   static Prefilter* AndOr(Op op, Prefilter* a, Prefilter* b);

   static Prefilter* FromRegexp(Regexp* a);

   static Prefilter* FromString(const std::string& str);

   static Prefilter* OrStrings(SSet* ss);

   static Info* BuildInfo(Regexp* re);

   Prefilter* Simplify();

   // Removes redundant strings from the set. A string is redundant if
   // any of the other strings appear as a substring. The empty string
   // is a special case, which is ignored.
   static void SimplifyStringSet(SSet* ss);

   // Adds the cross-product of a and b to dst.
   // (For each string i in a and j in b, add i+j.)
   static void CrossProduct(const SSet& a, const SSet& b, SSet* dst);

   // Kind of Prefilter.
   Op op_;

   // Sub-matches for AND or OR Prefilter.
   std::vector<Prefilter*>* subs_;

   // Actual string to match in leaf node.
   std::string atom_;

   // If different prefilters have the same string atom, or if they are
   // structurally the same (e.g., OR of same atom strings) they are
   // considered the same unique nodes. This is the id for each unique
   // node. This field is populated with a unique id for every node,
   // and -1 for duplicate nodes.
   int unique_id_;

   Prefilter(const Prefilter&) = delete;
   Prefilter& operator=(const Prefilter&) = delete;
 };

 }  // namespace re2

 #endif  // RE2_PREFILTER_H_
	// Copyright 2009 The RE2 Authors. All Rights Reserved.
	// Use of this source code is governed by a BSD-style
	// license that can be found in the LICENSE file.

	#ifndef RE2_PREFILTER_H_
	#define RE2_PREFILTER_H_

	// Prefilter is the class used to extract string guards from regexps.
	// Rather than using Prefilter class directly, use FilteredRE2.
	// See filtered_re2.h

	#include <set>
	#include <string>
	#include <vector>

	#include "util/logging.h"

	namespace re2 {

	class RE2;

	class Regexp;

	class Prefilter {
	// Instead of using Prefilter directly, use FilteredRE2; see filtered_re2.h
	public:
	enum Op {
	ALL = 0, // Everything matches
	NONE, // Nothing matches
	ATOM, // The string atom() must match
	AND, // All in subs() must match
	OR, // One of subs() must match
	};

	explicit Prefilter(Op op);
	~Prefilter();

	Op op() { return op_; }
	const std::string& atom() const { return atom_; }
	void set_unique_id(int id) { unique_id_ = id; }
	int unique_id() const { return unique_id_; }

	// The children of the Prefilter node.
	std::vector<Prefilter> subs() {
	DCHECK(op_ == AND \|\| op_ == OR);
	return subs_;
	}

	// Set the children vector. Prefilter takes ownership of subs and
	// subs_ will be deleted when Prefilter is deleted.
	void set_subs(std::vector<Prefilter> subs) { subs_ = subs; }

	// Given a RE2, return a Prefilter. The caller takes ownership of
	// the Prefilter and should deallocate it. Returns NULL if Prefilter
	// cannot be formed.
	static Prefilter* FromRE2(const RE2* re2);

	// Returns a readable debug string of the prefilter.
	std::string DebugString() const;

	private:
	template <typename H>
	friend H AbslHashValue(H h, const Prefilter& a) {
	h = H::combine(std::move(h), a.op_);
	if (a.op_ == ATOM) {
	h = H::combine(std::move(h), a.atom_);
	} else if (a.op_ == AND \|\| a.op_ == OR) {
	h = H::combine(std::move(h), a.subs_->size());
	for (size_t i = 0; i < a.subs_->size(); ++i) {
	h = H::combine(std::move(h), (*a.subs_)[i]->unique_id_);
	}
	}
	return h;
	}

	friend bool operator==(const Prefilter& a, const Prefilter& b) {
	if (&a == &b) {
	return true;
	}
	if (a.op_ != b.op_) {
	return false;
	}
	if (a.op_ == ATOM) {
	if (a.atom_ != b.atom_) {
	return false;
	}
	} else if (a.op_ == AND \|\| a.op_ == OR) {
	if (a.subs_->size() != b.subs_->size()) {
	return false;
	}
	for (size_t i = 0; i < a.subs_->size(); ++i) {
	if ((a.subs_)[i]->unique_id_ != (b.subs_)[i]->unique_id_) {
	return false;
	}
	}
	}
	return true;
	}

	// A comparator used to store exact strings. We compare by length,
	// then lexicographically. This ordering makes it easier to reduce the
	// set of strings in SimplifyStringSet.
	struct LengthThenLex {
	bool operator()(const std::string& a, const std::string& b) const {
	return (a.size() < b.size()) \|\| (a.size() == b.size() && a < b);
	}
	};

	class Info;

	using SSet = std::set<std::string, LengthThenLex>;
	using SSIter = SSet::iterator;
	using ConstSSIter = SSet::const_iterator;

	// Combines two prefilters together to create an AND. The passed
	// Prefilters will be part of the returned Prefilter or deleted.
	static Prefilter* And(Prefilter* a, Prefilter* b);

	// Combines two prefilters together to create an OR. The passed
	// Prefilters will be part of the returned Prefilter or deleted.
	static Prefilter* Or(Prefilter* a, Prefilter* b);

	// Generalized And/Or
	static Prefilter* AndOr(Op op, Prefilter* a, Prefilter* b);

	static Prefilter* FromRegexp(Regexp* a);

	static Prefilter* FromString(const std::string& str);

	static Prefilter* OrStrings(SSet* ss);

	static Info* BuildInfo(Regexp* re);

	Prefilter* Simplify();

	// Removes redundant strings from the set. A string is redundant if
	// any of the other strings appear as a substring. The empty string
	// is a special case, which is ignored.
	static void SimplifyStringSet(SSet* ss);

	// Adds the cross-product of a and b to dst.
	// (For each string i in a and j in b, add i+j.)
	static void CrossProduct(const SSet& a, const SSet& b, SSet* dst);

	// Kind of Prefilter.
	Op op_;

	// Sub-matches for AND or OR Prefilter.
	std::vector<Prefilter> subs_;

	// Actual string to match in leaf node.
	std::string atom_;

	// If different prefilters have the same string atom, or if they are
	// structurally the same (e.g., OR of same atom strings) they are
	// considered the same unique nodes. This is the id for each unique
	// node. This field is populated with a unique id for every node,
	// and -1 for duplicate nodes.
	int unique_id_;

	Prefilter(const Prefilter&) = delete;
	Prefilter& operator=(const Prefilter&) = delete;
	};

	} // namespace re2

	#endif // RE2_PREFILTER_H_