re2/bitstate.cc - re2 - Git at Google

 // Copyright 2008 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.

 // Tested by search_test.cc, exhaustive_test.cc, tester.cc

 // Prog::SearchBitState is a regular expression search with submatch
 // tracking for small regular expressions and texts.  Like
 // testing/backtrack.cc, it allocates a bit vector with (length of
 // text) * (length of prog) bits, to make sure it never explores the
 // same (character position, instruction) state multiple times.  This
 // limits the search to run in time linear in the length of the text.
 //
 // Unlike testing/backtrack.cc, SearchBitState is not recursive
 // on the text.
 //
 // SearchBitState is a fast replacement for the NFA code on small
 // regexps and texts when SearchOnePass cannot be used.

 #include <stddef.h>
 #include <stdint.h>
 #include <string.h>
 #include <utility>

 #include "util/logging.h"
 #include "util/pod_array.h"
 #include "re2/prog.h"
 #include "re2/regexp.h"

 namespace re2 {

 struct Job {
   int id;
   int arg;
   const char* p;
 };

 class BitState {
  public:
   explicit BitState(Prog* prog);

   // The usual Search prototype.
   // Can only call Search once per BitState.
   bool Search(const StringPiece& text, const StringPiece& context,
               bool anchored, bool longest,
               StringPiece* submatch, int nsubmatch);

  private:
   inline bool ShouldVisit(int id, const char* p);
   void Push(int id, const char* p, int arg);
   void GrowStack();
   bool TrySearch(int id, const char* p);

   // Search parameters
   Prog* prog_;              // program being run
   StringPiece text_;        // text being searched
   StringPiece context_;     // greater context of text being searched
   bool anchored_;           // whether search is anchored at text.begin()
   bool longest_;            // whether search wants leftmost-longest match
   bool endmatch_;           // whether match must end at text.end()
   StringPiece* submatch_;   // submatches to fill in
   int nsubmatch_;           //   # of submatches to fill in

   // Search state
   static const int VisitedBits = 32;
   PODArray<uint32_t> visited_;  // bitmap: (Inst*, char*) pairs visited
   PODArray<const char*> cap_;   // capture registers
   PODArray<Job> job_;           // stack of text positions to explore
   int njob_;                    // stack size
 };

 BitState::BitState(Prog* prog)
   : prog_(prog),
     anchored_(false),
     longest_(false),
     endmatch_(false),
     submatch_(NULL),
     nsubmatch_(0),
     njob_(0) {
 }

 // Should the search visit the pair ip, p?
 // If so, remember that it was visited so that the next time,
 // we don't repeat the visit.
 bool BitState::ShouldVisit(int id, const char* p) {
   int n = id * static_cast<int>(text_.size()+1) +
           static_cast<int>(p-text_.begin());
   if (visited_[n/VisitedBits] & (1 << (n & (VisitedBits-1))))
     return false;
   visited_[n/VisitedBits] |= 1 << (n & (VisitedBits-1));
   return true;
 }

 // Grow the stack.
 void BitState::GrowStack() {
   PODArray<Job> tmp(2*job_.size());
   memmove(tmp.data(), job_.data(), njob_*sizeof job_[0]);
   job_ = std::move(tmp);
 }

 // Push the triple (id, p, arg) onto the stack, growing it if necessary.
 void BitState::Push(int id, const char* p, int arg) {
   if (njob_ >= job_.size()) {
     GrowStack();
     if (njob_ >= job_.size()) {
       LOG(DFATAL) << "GrowStack() failed: "
                   << "njob_ = " << njob_ << ", "
                   << "job_.size() = " << job_.size();
       return;
     }
   }
   int op = prog_->inst(id)->opcode();
   if (op == kInstFail)
     return;

   // Only check ShouldVisit when arg == 0.
   // When arg > 0, we are continuing a previous visit.
   if (arg == 0 && !ShouldVisit(id, p))
     return;

   Job* j = &job_[njob_++];
   j->id = id;
   j->p = p;
   j->arg = arg;
 }

 // Try a search from instruction id0 in state p0.
 // Return whether it succeeded.
 bool BitState::TrySearch(int id0, const char* p0) {
   bool matched = false;
   bool inaltmatch = false;
   const char* end = text_.end();
   njob_ = 0;
   Push(id0, p0, 0);
   while (njob_ > 0) {
     // Pop job off stack.
     --njob_;
     int id = job_[njob_].id;
     const char* p = job_[njob_].p;
     int arg = job_[njob_].arg;

     // Optimization: rather than push and pop,
     // code that is going to Push and continue
     // the loop simply updates ip, p, and arg
     // and jumps to CheckAndLoop.  We have to
     // do the ShouldVisit check that Push
     // would have, but we avoid the stack
     // manipulation.
     if (0) {
     Next:
       // If the Match of a non-greedy AltMatch failed,
       // we stop ourselves from trying the ByteRange,
       // which would steer us off the short circuit.
       if (prog_->inst(id)->last() || inaltmatch)
         continue;
       id++;

     CheckAndLoop:
       if (!ShouldVisit(id, p))
         continue;
     }

     // Visit ip, p.
     Prog::Inst* ip = prog_->inst(id);
     switch (ip->opcode()) {
       default:
         LOG(DFATAL) << "Unexpected opcode: " << ip->opcode() << " arg " << arg;
         return false;

       case kInstFail:
         continue;

       case kInstAltMatch:
         switch (arg) {
           case 0:
             inaltmatch = true;
             Push(id, p, 1);  // come back when we're done

             // One opcode is ByteRange; the other leads to Match
             // (possibly via Nop or Capture).
             if (ip->greedy(prog_)) {
               // out1 is the match
               Push(ip->out1(), p, 0);
               id = ip->out1();
               p = end;
               goto CheckAndLoop;
             }
             // out is the match - non-greedy
             Push(ip->out(), end, 0);
             id = ip->out();
             goto CheckAndLoop;

           case 1:
             inaltmatch = false;
             continue;
         }
         LOG(DFATAL) << "Bad arg in kInstAltMatch: " << arg;
         continue;

       case kInstByteRange: {
         int c = -1;
         if (p < end)
           c = *p & 0xFF;
         if (!ip->Matches(c))
           goto Next;

         if (!ip->last())
           Push(id+1, p, 0);  // try the next when we're done
         id = ip->out();
         p++;
         goto CheckAndLoop;
       }

       case kInstCapture:
         switch (arg) {
           case 0:
             if (!ip->last())
               Push(id+1, p, 0);  // try the next when we're done

             if (0 <= ip->cap() && ip->cap() < cap_.size()) {
               // Capture p to register, but save old value.
               Push(id, cap_[ip->cap()], 1);  // come back when we're done
               cap_[ip->cap()] = p;
             }

             // Continue on.
             id = ip->out();
             goto CheckAndLoop;

           case 1:
             // Finished ip->out(); restore the old value.
             cap_[ip->cap()] = p;
             continue;
         }
         LOG(DFATAL) << "Bad arg in kInstCapture: " << arg;
         continue;

       case kInstEmptyWidth:
         if (ip->empty() & ~Prog::EmptyFlags(context_, p))
           goto Next;

         if (!ip->last())
           Push(id+1, p, 0);  // try the next when we're done
         id = ip->out();
         goto CheckAndLoop;

       case kInstNop:
         if (!ip->last())
           Push(id+1, p, 0);  // try the next when we're done
         id = ip->out();
         goto CheckAndLoop;

       case kInstMatch: {
         if (endmatch_ && p != text_.end())
           goto Next;

         // We found a match.  If the caller doesn't care
         // where the match is, no point going further.
         if (nsubmatch_ == 0)
           return true;

         // Record best match so far.
         // Only need to check end point, because this entire
         // call is only considering one start position.
         matched = true;
         cap_[1] = p;
         if (submatch_[0].data() == NULL ||
             (longest_ && p > submatch_[0].end())) {
           for (int i = 0; i < nsubmatch_; i++)
             submatch_[i] =
                 StringPiece(cap_[2 * i],
                             static_cast<size_t>(cap_[2 * i + 1] - cap_[2 * i]));
         }

         // If going for first match, we're done.
         if (!longest_)
           return true;

         // If we used the entire text, no longer match is possible.
         if (p == text_.end())
           return true;

         // Otherwise, continue on in hope of a longer match.
         goto Next;
       }
     }
   }
   return matched;
 }

 // Search text (within context) for prog_.
 bool BitState::Search(const StringPiece& text, const StringPiece& context,
                       bool anchored, bool longest,
                       StringPiece* submatch, int nsubmatch) {
   // Search parameters.
   text_ = text;
   context_ = context;
   if (context_.begin() == NULL)
     context_ = text;
   if (prog_->anchor_start() && context_.begin() != text.begin())
     return false;
   if (prog_->anchor_end() && context_.end() != text.end())
     return false;
   anchored_ = anchored || prog_->anchor_start();
   longest_ = longest || prog_->anchor_end();
   endmatch_ = prog_->anchor_end();
   submatch_ = submatch;
   nsubmatch_ = nsubmatch;
   for (int i = 0; i < nsubmatch_; i++)
     submatch_[i] = StringPiece();

   // Allocate scratch space.
   int nvisited = prog_->size() * static_cast<int>(text.size()+1);
   nvisited = (nvisited + VisitedBits-1) / VisitedBits;
   visited_ = PODArray<uint32_t>(nvisited);
   memset(visited_.data(), 0, nvisited*sizeof visited_[0]);

   int ncap = 2*nsubmatch;
   if (ncap < 2)
     ncap = 2;
   cap_ = PODArray<const char*>(ncap);
   memset(cap_.data(), 0, ncap*sizeof cap_[0]);

   // When sizeof(Job) == 16, we start with a nice round 4KiB. :)
   job_ = PODArray<Job>(256);

   // Anchored search must start at text.begin().
   if (anchored_) {
     cap_[0] = text.begin();
     return TrySearch(prog_->start(), text.begin());
   }

   // Unanchored search, starting from each possible text position.
   // Notice that we have to try the empty string at the end of
   // the text, so the loop condition is p <= text.end(), not p < text.end().
   // This looks like it's quadratic in the size of the text,
   // but we are not clearing visited_ between calls to TrySearch,
   // so no work is duplicated and it ends up still being linear.
   for (const char* p = text.begin(); p <= text.end(); p++) {
     // Try to use memchr to find the first byte quickly.
     int fb = prog_->first_byte();
     if (fb >= 0 && p < text.end() && (p[0] & 0xFF) != fb) {
       p = reinterpret_cast<const char*>(memchr(p, fb, text.end() - p));
       if (p == NULL)
         p = text.end();
     }

     cap_[0] = p;
     if (TrySearch(prog_->start(), p))  // Match must be leftmost; done.
       return true;
   }
   return false;
 }

 // Bit-state search.
 bool Prog::SearchBitState(const StringPiece& text,
                           const StringPiece& context,
                           Anchor anchor,
                           MatchKind kind,
                           StringPiece* match,
                           int nmatch) {
   // If full match, we ask for an anchored longest match
   // and then check that match[0] == text.
   // So make sure match[0] exists.
   StringPiece sp0;
   if (kind == kFullMatch) {
     anchor = kAnchored;
     if (nmatch < 1) {
       match = &sp0;
       nmatch = 1;
     }
   }

   // Run the search.
   BitState b(this);
   bool anchored = anchor == kAnchored;
   bool longest = kind != kFirstMatch;
   if (!b.Search(text, context, anchored, longest, match, nmatch))
     return false;
   if (kind == kFullMatch && match[0].end() != text.end())
     return false;
   return true;
 }

 }  // namespace re2
	// Copyright 2008 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.

	// Tested by search_test.cc, exhaustive_test.cc, tester.cc

	// Prog::SearchBitState is a regular expression search with submatch
	// tracking for small regular expressions and texts. Like
	// testing/backtrack.cc, it allocates a bit vector with (length of
	// text) * (length of prog) bits, to make sure it never explores the
	// same (character position, instruction) state multiple times. This
	// limits the search to run in time linear in the length of the text.
	//
	// Unlike testing/backtrack.cc, SearchBitState is not recursive
	// on the text.
	//
	// SearchBitState is a fast replacement for the NFA code on small
	// regexps and texts when SearchOnePass cannot be used.

	#include <stddef.h>
	#include <stdint.h>
	#include <string.h>
	#include <utility>

	#include "util/logging.h"
	#include "util/pod_array.h"
	#include "re2/prog.h"
	#include "re2/regexp.h"

	namespace re2 {

	struct Job {
	int id;
	int arg;
	const char* p;
	};

	class BitState {
	public:
	explicit BitState(Prog* prog);

	// The usual Search prototype.
	// Can only call Search once per BitState.
	bool Search(const StringPiece& text, const StringPiece& context,
	bool anchored, bool longest,
	StringPiece* submatch, int nsubmatch);

	private:
	inline bool ShouldVisit(int id, const char* p);
	void Push(int id, const char* p, int arg);
	void GrowStack();
	bool TrySearch(int id, const char* p);

	// Search parameters
	Prog* prog_; // program being run
	StringPiece text_; // text being searched
	StringPiece context_; // greater context of text being searched
	bool anchored_; // whether search is anchored at text.begin()
	bool longest_; // whether search wants leftmost-longest match
	bool endmatch_; // whether match must end at text.end()
	StringPiece* submatch_; // submatches to fill in
	int nsubmatch_; // # of submatches to fill in

	// Search state
	static const int VisitedBits = 32;
	PODArray<uint32_t> visited_; // bitmap: (Inst, char) pairs visited
	PODArray<const char*> cap_; // capture registers
	PODArray<Job> job_; // stack of text positions to explore
	int njob_; // stack size
	};

	BitState::BitState(Prog* prog)
	: prog_(prog),
	anchored_(false),
	longest_(false),
	endmatch_(false),
	submatch_(NULL),
	nsubmatch_(0),
	njob_(0) {
	}

	// Should the search visit the pair ip, p?
	// If so, remember that it was visited so that the next time,
	// we don't repeat the visit.
	bool BitState::ShouldVisit(int id, const char* p) {
	int n = id * static_cast<int>(text_.size()+1) +
	static_cast<int>(p-text_.begin());
	if (visited_[n/VisitedBits] & (1 << (n & (VisitedBits-1))))
	return false;
	visited_[n/VisitedBits] \|= 1 << (n & (VisitedBits-1));
	return true;
	}

	// Grow the stack.
	void BitState::GrowStack() {
	PODArray<Job> tmp(2*job_.size());
	memmove(tmp.data(), job_.data(), njob_*sizeof job_[0]);
	job_ = std::move(tmp);
	}

	// Push the triple (id, p, arg) onto the stack, growing it if necessary.
	void BitState::Push(int id, const char* p, int arg) {
	if (njob_ >= job_.size()) {
	GrowStack();
	if (njob_ >= job_.size()) {
	LOG(DFATAL) << "GrowStack() failed: "
	<< "njob_ = " << njob_ << ", "
	<< "job_.size() = " << job_.size();
	return;
	}
	}
	int op = prog_->inst(id)->opcode();
	if (op == kInstFail)
	return;

	// Only check ShouldVisit when arg == 0.
	// When arg > 0, we are continuing a previous visit.
	if (arg == 0 && !ShouldVisit(id, p))
	return;

	Job* j = &job_[njob_++];
	j->id = id;
	j->p = p;
	j->arg = arg;
	}

	// Try a search from instruction id0 in state p0.
	// Return whether it succeeded.
	bool BitState::TrySearch(int id0, const char* p0) {
	bool matched = false;
	bool inaltmatch = false;
	const char* end = text_.end();
	njob_ = 0;
	Push(id0, p0, 0);
	while (njob_ > 0) {
	// Pop job off stack.
	--njob_;
	int id = job_[njob_].id;
	const char* p = job_[njob_].p;
	int arg = job_[njob_].arg;

	// Optimization: rather than push and pop,
	// code that is going to Push and continue
	// the loop simply updates ip, p, and arg
	// and jumps to CheckAndLoop. We have to
	// do the ShouldVisit check that Push
	// would have, but we avoid the stack
	// manipulation.
	if (0) {
	Next:
	// If the Match of a non-greedy AltMatch failed,
	// we stop ourselves from trying the ByteRange,
	// which would steer us off the short circuit.
	if (prog_->inst(id)->last() \|\| inaltmatch)
	continue;
	id++;

	CheckAndLoop:
	if (!ShouldVisit(id, p))
	continue;
	}

	// Visit ip, p.
	Prog::Inst* ip = prog_->inst(id);
	switch (ip->opcode()) {
	default:
	LOG(DFATAL) << "Unexpected opcode: " << ip->opcode() << " arg " << arg;
	return false;

	case kInstFail:
	continue;

	case kInstAltMatch:
	switch (arg) {
	case 0:
	inaltmatch = true;
	Push(id, p, 1); // come back when we're done

	// One opcode is ByteRange; the other leads to Match
	// (possibly via Nop or Capture).
	if (ip->greedy(prog_)) {
	// out1 is the match
	Push(ip->out1(), p, 0);
	id = ip->out1();
	p = end;
	goto CheckAndLoop;
	}
	// out is the match - non-greedy
	Push(ip->out(), end, 0);
	id = ip->out();
	goto CheckAndLoop;

	case 1:
	inaltmatch = false;
	continue;
	}
	LOG(DFATAL) << "Bad arg in kInstAltMatch: " << arg;
	continue;

	case kInstByteRange: {
	int c = -1;
	if (p < end)
	c = *p & 0xFF;
	if (!ip->Matches(c))
	goto Next;

	if (!ip->last())
	Push(id+1, p, 0); // try the next when we're done
	id = ip->out();
	p++;
	goto CheckAndLoop;
	}

	case kInstCapture:
	switch (arg) {
	case 0:
	if (!ip->last())
	Push(id+1, p, 0); // try the next when we're done

	if (0 <= ip->cap() && ip->cap() < cap_.size()) {
	// Capture p to register, but save old value.
	Push(id, cap_[ip->cap()], 1); // come back when we're done
	cap_[ip->cap()] = p;
	}

	// Continue on.
	id = ip->out();
	goto CheckAndLoop;

	case 1:
	// Finished ip->out(); restore the old value.
	cap_[ip->cap()] = p;
	continue;
	}
	LOG(DFATAL) << "Bad arg in kInstCapture: " << arg;
	continue;

	case kInstEmptyWidth:
	if (ip->empty() & ~Prog::EmptyFlags(context_, p))
	goto Next;

	if (!ip->last())
	Push(id+1, p, 0); // try the next when we're done
	id = ip->out();
	goto CheckAndLoop;

	case kInstNop:
	if (!ip->last())
	Push(id+1, p, 0); // try the next when we're done
	id = ip->out();
	goto CheckAndLoop;

	case kInstMatch: {
	if (endmatch_ && p != text_.end())
	goto Next;

	// We found a match. If the caller doesn't care
	// where the match is, no point going further.
	if (nsubmatch_ == 0)
	return true;

	// Record best match so far.
	// Only need to check end point, because this entire
	// call is only considering one start position.
	matched = true;
	cap_[1] = p;
	if (submatch_[0].data() == NULL \|\|
	(longest_ && p > submatch_[0].end())) {
	for (int i = 0; i < nsubmatch_; i++)
	submatch_[i] =
	StringPiece(cap_[2 * i],
	static_cast<size_t>(cap_[2 * i + 1] - cap_[2 * i]));
	}

	// If going for first match, we're done.
	if (!longest_)
	return true;

	// If we used the entire text, no longer match is possible.
	if (p == text_.end())
	return true;

	// Otherwise, continue on in hope of a longer match.
	goto Next;
	}
	}
	}
	return matched;
	}

	// Search text (within context) for prog_.
	bool BitState::Search(const StringPiece& text, const StringPiece& context,
	bool anchored, bool longest,
	StringPiece* submatch, int nsubmatch) {
	// Search parameters.
	text_ = text;
	context_ = context;
	if (context_.begin() == NULL)
	context_ = text;
	if (prog_->anchor_start() && context_.begin() != text.begin())
	return false;
	if (prog_->anchor_end() && context_.end() != text.end())
	return false;
	anchored_ = anchored \|\| prog_->anchor_start();
	longest_ = longest \|\| prog_->anchor_end();
	endmatch_ = prog_->anchor_end();
	submatch_ = submatch;
	nsubmatch_ = nsubmatch;
	for (int i = 0; i < nsubmatch_; i++)
	submatch_[i] = StringPiece();

	// Allocate scratch space.
	int nvisited = prog_->size() * static_cast<int>(text.size()+1);
	nvisited = (nvisited + VisitedBits-1) / VisitedBits;
	visited_ = PODArray<uint32_t>(nvisited);
	memset(visited_.data(), 0, nvisited*sizeof visited_[0]);

	int ncap = 2*nsubmatch;
	if (ncap < 2)
	ncap = 2;
	cap_ = PODArray<const char*>(ncap);
	memset(cap_.data(), 0, ncap*sizeof cap_[0]);

	// When sizeof(Job) == 16, we start with a nice round 4KiB. :)
	job_ = PODArray<Job>(256);

	// Anchored search must start at text.begin().
	if (anchored_) {
	cap_[0] = text.begin();
	return TrySearch(prog_->start(), text.begin());
	}

	// Unanchored search, starting from each possible text position.
	// Notice that we have to try the empty string at the end of
	// the text, so the loop condition is p <= text.end(), not p < text.end().
	// This looks like it's quadratic in the size of the text,
	// but we are not clearing visited_ between calls to TrySearch,
	// so no work is duplicated and it ends up still being linear.
	for (const char* p = text.begin(); p <= text.end(); p++) {
	// Try to use memchr to find the first byte quickly.
	int fb = prog_->first_byte();
	if (fb >= 0 && p < text.end() && (p[0] & 0xFF) != fb) {
	p = reinterpret_cast<const char*>(memchr(p, fb, text.end() - p));
	if (p == NULL)
	p = text.end();
	}

	cap_[0] = p;
	if (TrySearch(prog_->start(), p)) // Match must be leftmost; done.
	return true;
	}
	return false;
	}

	// Bit-state search.
	bool Prog::SearchBitState(const StringPiece& text,
	const StringPiece& context,
	Anchor anchor,
	MatchKind kind,
	StringPiece* match,
	int nmatch) {
	// If full match, we ask for an anchored longest match
	// and then check that match[0] == text.
	// So make sure match[0] exists.
	StringPiece sp0;
	if (kind == kFullMatch) {
	anchor = kAnchored;
	if (nmatch < 1) {
	match = &sp0;
	nmatch = 1;
	}
	}

	// Run the search.
	BitState b(this);
	bool anchored = anchor == kAnchored;
	bool longest = kind != kFirstMatch;
	if (!b.Search(text, context, anchored, longest, match, nmatch))
	return false;
	if (kind == kFullMatch && match[0].end() != text.end())
	return false;
	return true;
	}

	} // namespace re2