1 // Copyright 2007 The RE2 Authors.  All Rights Reserved.
2 // Use of this source code is governed by a BSD-style
3 // license that can be found in the LICENSE file.
4 
5 // Compile regular expression to Prog.
6 //
7 // Prog and Inst are defined in prog.h.
8 // This file's external interface is just Regexp::CompileToProg.
9 // The Compiler class defined in this file is private.
10 
11 #include <stdint.h>
12 #include <string.h>
13 #include <unordered_map>
14 #include <utility>
15 
16 #include "util/logging.h"
17 #include "util/utf.h"
18 #include "re2/pod_array.h"
19 #include "re2/prog.h"
20 #include "re2/re2.h"
21 #include "re2/regexp.h"
22 #include "re2/walker-inl.h"
23 
24 namespace re2 {
25 
26 // List of pointers to Inst* that need to be filled in (patched).
27 // Because the Inst* haven't been filled in yet,
28 // we can use the Inst* word to hold the list's "next" pointer.
29 // It's kind of sleazy, but it works well in practice.
30 // See http://swtch.com/~rsc/regexp/regexp1.html for inspiration.
31 //
32 // Because the out and out1 fields in Inst are no longer pointers,
33 // we can't use pointers directly here either.  Instead, p refers
34 // to inst_[p>>1].out (p&1 == 0) or inst_[p>>1].out1 (p&1 == 1).
35 // p == 0 represents the NULL list.  This is okay because instruction #0
36 // is always the fail instruction, which never appears on a list.
37 
38 struct PatchList {
39   uint32_t p;
40 
41   // Returns patch list containing just p.
42   static PatchList Mk(uint32_t p);
43 
44   // Patches all the entries on l to have value v.
45   // Caller must not ever use patch list again.
46   static void Patch(Prog::Inst *inst0, PatchList l, uint32_t v);
47 
48   // Deref returns the next pointer pointed at by p.
49   static PatchList Deref(Prog::Inst *inst0, PatchList l);
50 
51   // Appends two patch lists and returns result.
52   static PatchList Append(Prog::Inst *inst0, PatchList l1, PatchList l2);
53 };
54 
55 static PatchList nullPatchList = { 0 };
56 
57 // Returns patch list containing just p.
Mk(uint32_t p)58 PatchList PatchList::Mk(uint32_t p) {
59   PatchList l;
60   l.p = p;
61   return l;
62 }
63 
64 // Returns the next pointer pointed at by l.
Deref(Prog::Inst * inst0,PatchList l)65 PatchList PatchList::Deref(Prog::Inst* inst0, PatchList l) {
66   Prog::Inst* ip = &inst0[l.p>>1];
67   if (l.p&1)
68     l.p = ip->out1();
69   else
70     l.p = ip->out();
71   return l;
72 }
73 
74 // Patches all the entries on l to have value v.
Patch(Prog::Inst * inst0,PatchList l,uint32_t val)75 void PatchList::Patch(Prog::Inst *inst0, PatchList l, uint32_t val) {
76   while (l.p != 0) {
77     Prog::Inst* ip = &inst0[l.p>>1];
78     if (l.p&1) {
79       l.p = ip->out1();
80       ip->out1_ = val;
81     } else {
82       l.p = ip->out();
83       ip->set_out(val);
84     }
85   }
86 }
87 
88 // Appends two patch lists and returns result.
Append(Prog::Inst * inst0,PatchList l1,PatchList l2)89 PatchList PatchList::Append(Prog::Inst* inst0, PatchList l1, PatchList l2) {
90   if (l1.p == 0)
91     return l2;
92   if (l2.p == 0)
93     return l1;
94 
95   PatchList l = l1;
96   for (;;) {
97     PatchList next = PatchList::Deref(inst0, l);
98     if (next.p == 0)
99       break;
100     l = next;
101   }
102 
103   Prog::Inst* ip = &inst0[l.p>>1];
104   if (l.p&1)
105     ip->out1_ = l2.p;
106   else
107     ip->set_out(l2.p);
108 
109   return l1;
110 }
111 
112 // Compiled program fragment.
113 struct Frag {
114   uint32_t begin;
115   PatchList end;
116 
Fragre2::Frag117   Frag() : begin(0) { end.p = 0; }  // needed so Frag can go in vector
Fragre2::Frag118   Frag(uint32_t begin, PatchList end) : begin(begin), end(end) {}
119 };
120 
121 // Input encodings.
122 enum Encoding {
123   kEncodingUTF8 = 1,  // UTF-8 (0-10FFFF)
124   kEncodingLatin1,    // Latin-1 (0-FF)
125 };
126 
127 class Compiler : public Regexp::Walker<Frag> {
128  public:
129   explicit Compiler();
130   ~Compiler();
131 
132   // Compiles Regexp to a new Prog.
133   // Caller is responsible for deleting Prog when finished with it.
134   // If reversed is true, compiles for walking over the input
135   // string backward (reverses all concatenations).
136   static Prog *Compile(Regexp* re, bool reversed, int64_t max_mem);
137 
138   // Compiles alternation of all the re to a new Prog.
139   // Each re has a match with an id equal to its index in the vector.
140   static Prog* CompileSet(Regexp* re, RE2::Anchor anchor, int64_t max_mem);
141 
142   // Interface for Regexp::Walker, which helps traverse the Regexp.
143   // The walk is purely post-recursive: given the machines for the
144   // children, PostVisit combines them to create the machine for
145   // the current node.  The child_args are Frags.
146   // The Compiler traverses the Regexp parse tree, visiting
147   // each node in depth-first order.  It invokes PreVisit before
148   // visiting the node's children and PostVisit after visiting
149   // the children.
150   Frag PreVisit(Regexp* re, Frag parent_arg, bool* stop);
151   Frag PostVisit(Regexp* re, Frag parent_arg, Frag pre_arg, Frag* child_args,
152                  int nchild_args);
153   Frag ShortVisit(Regexp* re, Frag parent_arg);
154   Frag Copy(Frag arg);
155 
156   // Given fragment a, returns a+ or a+?; a* or a*?; a? or a??
157   Frag Plus(Frag a, bool nongreedy);
158   Frag Star(Frag a, bool nongreedy);
159   Frag Quest(Frag a, bool nongreedy);
160 
161   // Given fragment a, returns (a) capturing as \n.
162   Frag Capture(Frag a, int n);
163 
164   // Given fragments a and b, returns ab; a|b
165   Frag Cat(Frag a, Frag b);
166   Frag Alt(Frag a, Frag b);
167 
168   // Returns a fragment that can't match anything.
169   Frag NoMatch();
170 
171   // Returns a fragment that matches the empty string.
172   Frag Match(int32_t id);
173 
174   // Returns a no-op fragment.
175   Frag Nop();
176 
177   // Returns a fragment matching the byte range lo-hi.
178   Frag ByteRange(int lo, int hi, bool foldcase);
179 
180   // Returns a fragment matching an empty-width special op.
181   Frag EmptyWidth(EmptyOp op);
182 
183   // Adds n instructions to the program.
184   // Returns the index of the first one.
185   // Returns -1 if no more instructions are available.
186   int AllocInst(int n);
187 
188   // Rune range compiler.
189 
190   // Begins a new alternation.
191   void BeginRange();
192 
193   // Adds a fragment matching the rune range lo-hi.
194   void AddRuneRange(Rune lo, Rune hi, bool foldcase);
195   void AddRuneRangeLatin1(Rune lo, Rune hi, bool foldcase);
196   void AddRuneRangeUTF8(Rune lo, Rune hi, bool foldcase);
197   void Add_80_10ffff();
198 
199   // New suffix that matches the byte range lo-hi, then goes to next.
200   int UncachedRuneByteSuffix(uint8_t lo, uint8_t hi, bool foldcase, int next);
201   int CachedRuneByteSuffix(uint8_t lo, uint8_t hi, bool foldcase, int next);
202 
203   // Returns true iff the suffix is cached.
204   bool IsCachedRuneByteSuffix(int id);
205 
206   // Adds a suffix to alternation.
207   void AddSuffix(int id);
208 
209   // Adds a suffix to the trie starting from the given root node.
210   // Returns zero iff allocating an instruction fails. Otherwise, returns
211   // the current root node, which might be different from what was given.
212   int AddSuffixRecursive(int root, int id);
213 
214   // Finds the trie node for the given suffix. Returns a Frag in order to
215   // distinguish between pointing at the root node directly (end.p == 0)
216   // and pointing at an Alt's out1 or out (end.p&1 == 1 or 0, respectively).
217   Frag FindByteRange(int root, int id);
218 
219   // Compares two ByteRanges and returns true iff they are equal.
220   bool ByteRangeEqual(int id1, int id2);
221 
222   // Returns the alternation of all the added suffixes.
223   Frag EndRange();
224 
225   // Single rune.
226   Frag Literal(Rune r, bool foldcase);
227 
228   void Setup(Regexp::ParseFlags flags, int64_t max_mem, RE2::Anchor anchor);
229   Prog* Finish(Regexp* re);
230 
231   // Returns .* where dot = any byte
232   Frag DotStar();
233 
234  private:
235   Prog* prog_;         // Program being built.
236   bool failed_;        // Did we give up compiling?
237   Encoding encoding_;  // Input encoding
238   bool reversed_;      // Should program run backward over text?
239 
240   PODArray<Prog::Inst> inst_;
241   int ninst_;          // Number of instructions used.
242   int max_ninst_;      // Maximum number of instructions.
243 
244   int64_t max_mem_;    // Total memory budget.
245 
246   std::unordered_map<uint64_t, int> rune_cache_;
247   Frag rune_range_;
248 
249   RE2::Anchor anchor_;  // anchor mode for RE2::Set
250 
251   Compiler(const Compiler&) = delete;
252   Compiler& operator=(const Compiler&) = delete;
253 };
254 
Compiler()255 Compiler::Compiler() {
256   prog_ = new Prog();
257   failed_ = false;
258   encoding_ = kEncodingUTF8;
259   reversed_ = false;
260   ninst_ = 0;
261   max_ninst_ = 1;  // make AllocInst for fail instruction okay
262   max_mem_ = 0;
263   int fail = AllocInst(1);
264   inst_[fail].InitFail();
265   max_ninst_ = 0;  // Caller must change
266 }
267 
~Compiler()268 Compiler::~Compiler() {
269   delete prog_;
270 }
271 
AllocInst(int n)272 int Compiler::AllocInst(int n) {
273   if (failed_ || ninst_ + n > max_ninst_) {
274     failed_ = true;
275     return -1;
276   }
277 
278   if (ninst_ + n > inst_.size()) {
279     int cap = inst_.size();
280     if (cap == 0)
281       cap = 8;
282     while (ninst_ + n > cap)
283       cap *= 2;
284     PODArray<Prog::Inst> inst(cap);
285     if (inst_.data() != NULL)
286       memmove(inst.data(), inst_.data(), ninst_*sizeof inst_[0]);
287     memset(inst.data() + ninst_, 0, (cap - ninst_)*sizeof inst_[0]);
288     inst_ = std::move(inst);
289   }
290   int id = ninst_;
291   ninst_ += n;
292   return id;
293 }
294 
295 // These routines are somewhat hard to visualize in text --
296 // see http://swtch.com/~rsc/regexp/regexp1.html for
297 // pictures explaining what is going on here.
298 
299 // Returns an unmatchable fragment.
NoMatch()300 Frag Compiler::NoMatch() {
301   return Frag(0, nullPatchList);
302 }
303 
304 // Is a an unmatchable fragment?
IsNoMatch(Frag a)305 static bool IsNoMatch(Frag a) {
306   return a.begin == 0;
307 }
308 
309 // Given fragments a and b, returns fragment for ab.
Cat(Frag a,Frag b)310 Frag Compiler::Cat(Frag a, Frag b) {
311   if (IsNoMatch(a) || IsNoMatch(b))
312     return NoMatch();
313 
314   // Elide no-op.
315   Prog::Inst* begin = &inst_[a.begin];
316   if (begin->opcode() == kInstNop &&
317       a.end.p == (a.begin << 1) &&
318       begin->out() == 0) {
319     // in case refs to a somewhere
320     PatchList::Patch(inst_.data(), a.end, b.begin);
321     return b;
322   }
323 
324   // To run backward over string, reverse all concatenations.
325   if (reversed_) {
326     PatchList::Patch(inst_.data(), b.end, a.begin);
327     return Frag(b.begin, a.end);
328   }
329 
330   PatchList::Patch(inst_.data(), a.end, b.begin);
331   return Frag(a.begin, b.end);
332 }
333 
334 // Given fragments for a and b, returns fragment for a|b.
Alt(Frag a,Frag b)335 Frag Compiler::Alt(Frag a, Frag b) {
336   // Special case for convenience in loops.
337   if (IsNoMatch(a))
338     return b;
339   if (IsNoMatch(b))
340     return a;
341 
342   int id = AllocInst(1);
343   if (id < 0)
344     return NoMatch();
345 
346   inst_[id].InitAlt(a.begin, b.begin);
347   return Frag(id, PatchList::Append(inst_.data(), a.end, b.end));
348 }
349 
350 // When capturing submatches in like-Perl mode, a kOpAlt Inst
351 // treats out_ as the first choice, out1_ as the second.
352 //
353 // For *, +, and ?, if out_ causes another repetition,
354 // then the operator is greedy.  If out1_ is the repetition
355 // (and out_ moves forward), then the operator is non-greedy.
356 
357 // Given a fragment a, returns a fragment for a* or a*? (if nongreedy)
Star(Frag a,bool nongreedy)358 Frag Compiler::Star(Frag a, bool nongreedy) {
359   int id = AllocInst(1);
360   if (id < 0)
361     return NoMatch();
362   inst_[id].InitAlt(0, 0);
363   PatchList::Patch(inst_.data(), a.end, id);
364   if (nongreedy) {
365     inst_[id].out1_ = a.begin;
366     return Frag(id, PatchList::Mk(id << 1));
367   } else {
368     inst_[id].set_out(a.begin);
369     return Frag(id, PatchList::Mk((id << 1) | 1));
370   }
371 }
372 
373 // Given a fragment for a, returns a fragment for a+ or a+? (if nongreedy)
Plus(Frag a,bool nongreedy)374 Frag Compiler::Plus(Frag a, bool nongreedy) {
375   // a+ is just a* with a different entry point.
376   Frag f = Star(a, nongreedy);
377   return Frag(a.begin, f.end);
378 }
379 
380 // Given a fragment for a, returns a fragment for a? or a?? (if nongreedy)
Quest(Frag a,bool nongreedy)381 Frag Compiler::Quest(Frag a, bool nongreedy) {
382   if (IsNoMatch(a))
383     return Nop();
384   int id = AllocInst(1);
385   if (id < 0)
386     return NoMatch();
387   PatchList pl;
388   if (nongreedy) {
389     inst_[id].InitAlt(0, a.begin);
390     pl = PatchList::Mk(id << 1);
391   } else {
392     inst_[id].InitAlt(a.begin, 0);
393     pl = PatchList::Mk((id << 1) | 1);
394   }
395   return Frag(id, PatchList::Append(inst_.data(), pl, a.end));
396 }
397 
398 // Returns a fragment for the byte range lo-hi.
ByteRange(int lo,int hi,bool foldcase)399 Frag Compiler::ByteRange(int lo, int hi, bool foldcase) {
400   int id = AllocInst(1);
401   if (id < 0)
402     return NoMatch();
403   inst_[id].InitByteRange(lo, hi, foldcase, 0);
404   return Frag(id, PatchList::Mk(id << 1));
405 }
406 
407 // Returns a no-op fragment.  Sometimes unavoidable.
Nop()408 Frag Compiler::Nop() {
409   int id = AllocInst(1);
410   if (id < 0)
411     return NoMatch();
412   inst_[id].InitNop(0);
413   return Frag(id, PatchList::Mk(id << 1));
414 }
415 
416 // Returns a fragment that signals a match.
Match(int32_t match_id)417 Frag Compiler::Match(int32_t match_id) {
418   int id = AllocInst(1);
419   if (id < 0)
420     return NoMatch();
421   inst_[id].InitMatch(match_id);
422   return Frag(id, nullPatchList);
423 }
424 
425 // Returns a fragment matching a particular empty-width op (like ^ or $)
EmptyWidth(EmptyOp empty)426 Frag Compiler::EmptyWidth(EmptyOp empty) {
427   int id = AllocInst(1);
428   if (id < 0)
429     return NoMatch();
430   inst_[id].InitEmptyWidth(empty, 0);
431   return Frag(id, PatchList::Mk(id << 1));
432 }
433 
434 // Given a fragment a, returns a fragment with capturing parens around a.
Capture(Frag a,int n)435 Frag Compiler::Capture(Frag a, int n) {
436   if (IsNoMatch(a))
437     return NoMatch();
438   int id = AllocInst(2);
439   if (id < 0)
440     return NoMatch();
441   inst_[id].InitCapture(2*n, a.begin);
442   inst_[id+1].InitCapture(2*n+1, 0);
443   PatchList::Patch(inst_.data(), a.end, id+1);
444 
445   return Frag(id, PatchList::Mk((id+1) << 1));
446 }
447 
448 // A Rune is a name for a Unicode code point.
449 // Returns maximum rune encoded by UTF-8 sequence of length len.
MaxRune(int len)450 static int MaxRune(int len) {
451   int b;  // number of Rune bits in len-byte UTF-8 sequence (len < UTFmax)
452   if (len == 1)
453     b = 7;
454   else
455     b = 8-(len+1) + 6*(len-1);
456   return (1<<b) - 1;   // maximum Rune for b bits.
457 }
458 
459 // The rune range compiler caches common suffix fragments,
460 // which are very common in UTF-8 (e.g., [80-bf]).
461 // The fragment suffixes are identified by their start
462 // instructions.  NULL denotes the eventual end match.
463 // The Frag accumulates in rune_range_.  Caching common
464 // suffixes reduces the UTF-8 "." from 32 to 24 instructions,
465 // and it reduces the corresponding one-pass NFA from 16 nodes to 8.
466 
BeginRange()467 void Compiler::BeginRange() {
468   rune_cache_.clear();
469   rune_range_.begin = 0;
470   rune_range_.end = nullPatchList;
471 }
472 
UncachedRuneByteSuffix(uint8_t lo,uint8_t hi,bool foldcase,int next)473 int Compiler::UncachedRuneByteSuffix(uint8_t lo, uint8_t hi, bool foldcase,
474                                      int next) {
475   Frag f = ByteRange(lo, hi, foldcase);
476   if (next != 0) {
477     PatchList::Patch(inst_.data(), f.end, next);
478   } else {
479     rune_range_.end = PatchList::Append(inst_.data(), rune_range_.end, f.end);
480   }
481   return f.begin;
482 }
483 
MakeRuneCacheKey(uint8_t lo,uint8_t hi,bool foldcase,int next)484 static uint64_t MakeRuneCacheKey(uint8_t lo, uint8_t hi, bool foldcase,
485                                  int next) {
486   return (uint64_t)next << 17 |
487          (uint64_t)lo   <<  9 |
488          (uint64_t)hi   <<  1 |
489          (uint64_t)foldcase;
490 }
491 
CachedRuneByteSuffix(uint8_t lo,uint8_t hi,bool foldcase,int next)492 int Compiler::CachedRuneByteSuffix(uint8_t lo, uint8_t hi, bool foldcase,
493                                    int next) {
494   uint64_t key = MakeRuneCacheKey(lo, hi, foldcase, next);
495   std::unordered_map<uint64_t, int>::const_iterator it = rune_cache_.find(key);
496   if (it != rune_cache_.end())
497     return it->second;
498   int id = UncachedRuneByteSuffix(lo, hi, foldcase, next);
499   rune_cache_[key] = id;
500   return id;
501 }
502 
IsCachedRuneByteSuffix(int id)503 bool Compiler::IsCachedRuneByteSuffix(int id) {
504   uint8_t lo = inst_[id].lo_;
505   uint8_t hi = inst_[id].hi_;
506   bool foldcase = inst_[id].foldcase() != 0;
507   int next = inst_[id].out();
508 
509   uint64_t key = MakeRuneCacheKey(lo, hi, foldcase, next);
510   return rune_cache_.find(key) != rune_cache_.end();
511 }
512 
AddSuffix(int id)513 void Compiler::AddSuffix(int id) {
514   if (failed_)
515     return;
516 
517   if (rune_range_.begin == 0) {
518     rune_range_.begin = id;
519     return;
520   }
521 
522   if (encoding_ == kEncodingUTF8) {
523     // Build a trie in order to reduce fanout.
524     rune_range_.begin = AddSuffixRecursive(rune_range_.begin, id);
525     return;
526   }
527 
528   int alt = AllocInst(1);
529   if (alt < 0) {
530     rune_range_.begin = 0;
531     return;
532   }
533   inst_[alt].InitAlt(rune_range_.begin, id);
534   rune_range_.begin = alt;
535 }
536 
AddSuffixRecursive(int root,int id)537 int Compiler::AddSuffixRecursive(int root, int id) {
538   DCHECK(inst_[root].opcode() == kInstAlt ||
539          inst_[root].opcode() == kInstByteRange);
540 
541   Frag f = FindByteRange(root, id);
542   if (IsNoMatch(f)) {
543     int alt = AllocInst(1);
544     if (alt < 0)
545       return 0;
546     inst_[alt].InitAlt(root, id);
547     return alt;
548   }
549 
550   int br;
551   if (f.end.p == 0)
552     br = root;
553   else if (f.end.p&1)
554     br = inst_[f.begin].out1();
555   else
556     br = inst_[f.begin].out();
557 
558   if (IsCachedRuneByteSuffix(br)) {
559     // We can't fiddle with cached suffixes, so make a clone of the head.
560     int byterange = AllocInst(1);
561     if (byterange < 0)
562       return 0;
563     inst_[byterange].InitByteRange(inst_[br].lo(), inst_[br].hi(),
564                                    inst_[br].foldcase(), inst_[br].out());
565 
566     // Ensure that the parent points to the clone, not to the original.
567     // Note that this could leave the head unreachable except via the cache.
568     br = byterange;
569     if (f.end.p == 0)
570       root = br;
571     else if (f.end.p&1)
572       inst_[f.begin].out1_ = br;
573     else
574       inst_[f.begin].set_out(br);
575   }
576 
577   int out = inst_[id].out();
578   if (!IsCachedRuneByteSuffix(id)) {
579     // The head should be the instruction most recently allocated, so free it
580     // instead of leaving it unreachable.
581     DCHECK_EQ(id, ninst_-1);
582     inst_[id].out_opcode_ = 0;
583     inst_[id].out1_ = 0;
584     ninst_--;
585   }
586 
587   out = AddSuffixRecursive(inst_[br].out(), out);
588   if (out == 0)
589     return 0;
590 
591   inst_[br].set_out(out);
592   return root;
593 }
594 
ByteRangeEqual(int id1,int id2)595 bool Compiler::ByteRangeEqual(int id1, int id2) {
596   return inst_[id1].lo() == inst_[id2].lo() &&
597          inst_[id1].hi() == inst_[id2].hi() &&
598          inst_[id1].foldcase() == inst_[id2].foldcase();
599 }
600 
FindByteRange(int root,int id)601 Frag Compiler::FindByteRange(int root, int id) {
602   if (inst_[root].opcode() == kInstByteRange) {
603     if (ByteRangeEqual(root, id))
604       return Frag(root, nullPatchList);
605     else
606       return NoMatch();
607   }
608 
609   while (inst_[root].opcode() == kInstAlt) {
610     int out1 = inst_[root].out1();
611     if (ByteRangeEqual(out1, id))
612       return Frag(root, PatchList::Mk((root << 1) | 1));
613 
614     // CharClass is a sorted list of ranges, so if out1 of the root Alt wasn't
615     // what we're looking for, then we can stop immediately. Unfortunately, we
616     // can't short-circuit the search in reverse mode.
617     if (!reversed_)
618       return NoMatch();
619 
620     int out = inst_[root].out();
621     if (inst_[out].opcode() == kInstAlt)
622       root = out;
623     else if (ByteRangeEqual(out, id))
624       return Frag(root, PatchList::Mk(root << 1));
625     else
626       return NoMatch();
627   }
628 
629   LOG(DFATAL) << "should never happen";
630   return NoMatch();
631 }
632 
EndRange()633 Frag Compiler::EndRange() {
634   return rune_range_;
635 }
636 
637 // Converts rune range lo-hi into a fragment that recognizes
638 // the bytes that would make up those runes in the current
639 // encoding (Latin 1 or UTF-8).
640 // This lets the machine work byte-by-byte even when
641 // using multibyte encodings.
642 
AddRuneRange(Rune lo,Rune hi,bool foldcase)643 void Compiler::AddRuneRange(Rune lo, Rune hi, bool foldcase) {
644   switch (encoding_) {
645     default:
646     case kEncodingUTF8:
647       AddRuneRangeUTF8(lo, hi, foldcase);
648       break;
649     case kEncodingLatin1:
650       AddRuneRangeLatin1(lo, hi, foldcase);
651       break;
652   }
653 }
654 
AddRuneRangeLatin1(Rune lo,Rune hi,bool foldcase)655 void Compiler::AddRuneRangeLatin1(Rune lo, Rune hi, bool foldcase) {
656   // Latin-1 is easy: runes *are* bytes.
657   if (lo > hi || lo > 0xFF)
658     return;
659   if (hi > 0xFF)
660     hi = 0xFF;
661   AddSuffix(UncachedRuneByteSuffix(static_cast<uint8_t>(lo),
662                                    static_cast<uint8_t>(hi), foldcase, 0));
663 }
664 
Add_80_10ffff()665 void Compiler::Add_80_10ffff() {
666   // The 80-10FFFF (Runeself-Runemax) rune range occurs frequently enough
667   // (for example, for /./ and /[^a-z]/) that it is worth simplifying: by
668   // permitting overlong encodings in E0 and F0 sequences and code points
669   // over 10FFFF in F4 sequences, the size of the bytecode and the number
670   // of equivalence classes are reduced significantly.
671   int id;
672   if (reversed_) {
673     // Prefix factoring matters, but we don't have to handle it here
674     // because the rune range trie logic takes care of that already.
675     id = UncachedRuneByteSuffix(0xC2, 0xDF, false, 0);
676     id = UncachedRuneByteSuffix(0x80, 0xBF, false, id);
677     AddSuffix(id);
678 
679     id = UncachedRuneByteSuffix(0xE0, 0xEF, false, 0);
680     id = UncachedRuneByteSuffix(0x80, 0xBF, false, id);
681     id = UncachedRuneByteSuffix(0x80, 0xBF, false, id);
682     AddSuffix(id);
683 
684     id = UncachedRuneByteSuffix(0xF0, 0xF4, false, 0);
685     id = UncachedRuneByteSuffix(0x80, 0xBF, false, id);
686     id = UncachedRuneByteSuffix(0x80, 0xBF, false, id);
687     id = UncachedRuneByteSuffix(0x80, 0xBF, false, id);
688     AddSuffix(id);
689   } else {
690     // Suffix factoring matters - and we do have to handle it here.
691     int cont1 = UncachedRuneByteSuffix(0x80, 0xBF, false, 0);
692     id = UncachedRuneByteSuffix(0xC2, 0xDF, false, cont1);
693     AddSuffix(id);
694 
695     int cont2 = UncachedRuneByteSuffix(0x80, 0xBF, false, cont1);
696     id = UncachedRuneByteSuffix(0xE0, 0xEF, false, cont2);
697     AddSuffix(id);
698 
699     int cont3 = UncachedRuneByteSuffix(0x80, 0xBF, false, cont2);
700     id = UncachedRuneByteSuffix(0xF0, 0xF4, false, cont3);
701     AddSuffix(id);
702   }
703 }
704 
AddRuneRangeUTF8(Rune lo,Rune hi,bool foldcase)705 void Compiler::AddRuneRangeUTF8(Rune lo, Rune hi, bool foldcase) {
706   if (lo > hi)
707     return;
708 
709   // Pick off 80-10FFFF as a common special case.
710   if (lo == 0x80 && hi == 0x10ffff) {
711     Add_80_10ffff();
712     return;
713   }
714 
715   // Split range into same-length sized ranges.
716   for (int i = 1; i < UTFmax; i++) {
717     Rune max = MaxRune(i);
718     if (lo <= max && max < hi) {
719       AddRuneRangeUTF8(lo, max, foldcase);
720       AddRuneRangeUTF8(max+1, hi, foldcase);
721       return;
722     }
723   }
724 
725   // ASCII range is always a special case.
726   if (hi < Runeself) {
727     AddSuffix(UncachedRuneByteSuffix(static_cast<uint8_t>(lo),
728                                      static_cast<uint8_t>(hi), foldcase, 0));
729     return;
730   }
731 
732   // Split range into sections that agree on leading bytes.
733   for (int i = 1; i < UTFmax; i++) {
734     uint32_t m = (1<<(6*i)) - 1;  // last i bytes of a UTF-8 sequence
735     if ((lo & ~m) != (hi & ~m)) {
736       if ((lo & m) != 0) {
737         AddRuneRangeUTF8(lo, lo|m, foldcase);
738         AddRuneRangeUTF8((lo|m)+1, hi, foldcase);
739         return;
740       }
741       if ((hi & m) != m) {
742         AddRuneRangeUTF8(lo, (hi&~m)-1, foldcase);
743         AddRuneRangeUTF8(hi&~m, hi, foldcase);
744         return;
745       }
746     }
747   }
748 
749   // Finally.  Generate byte matching equivalent for lo-hi.
750   uint8_t ulo[UTFmax], uhi[UTFmax];
751   int n = runetochar(reinterpret_cast<char*>(ulo), &lo);
752   int m = runetochar(reinterpret_cast<char*>(uhi), &hi);
753   (void)m;  // USED(m)
754   DCHECK_EQ(n, m);
755 
756   // The logic below encodes this thinking:
757   //
758   // 1. When we have built the whole suffix, we know that it cannot
759   // possibly be a suffix of anything longer: in forward mode, nothing
760   // else can occur before the leading byte; in reverse mode, nothing
761   // else can occur after the last continuation byte or else the leading
762   // byte would have to change. Thus, there is no benefit to caching
763   // the first byte of the suffix whereas there is a cost involved in
764   // cloning it if it begins a common prefix, which is fairly likely.
765   //
766   // 2. Conversely, the last byte of the suffix cannot possibly be a
767   // prefix of anything because next == 0, so we will never want to
768   // clone it, but it is fairly likely to be a common suffix. Perhaps
769   // more so in reverse mode than in forward mode because the former is
770   // "converging" towards lower entropy, but caching is still worthwhile
771   // for the latter in cases such as 80-BF.
772   //
773   // 3. Handling the bytes between the first and the last is less
774   // straightforward and, again, the approach depends on whether we are
775   // "converging" towards lower entropy: in forward mode, a single byte
776   // is unlikely to be part of a common suffix whereas a byte range
777   // is more likely so; in reverse mode, a byte range is unlikely to
778   // be part of a common suffix whereas a single byte is more likely
779   // so. The same benefit versus cost argument applies here.
780   int id = 0;
781   if (reversed_) {
782     for (int i = 0; i < n; i++) {
783       // In reverse UTF-8 mode: cache the leading byte; don't cache the last
784       // continuation byte; cache anything else iff it's a single byte (XX-XX).
785       if (i == 0 || (ulo[i] == uhi[i] && i != n-1))
786         id = CachedRuneByteSuffix(ulo[i], uhi[i], false, id);
787       else
788         id = UncachedRuneByteSuffix(ulo[i], uhi[i], false, id);
789     }
790   } else {
791     for (int i = n-1; i >= 0; i--) {
792       // In forward UTF-8 mode: don't cache the leading byte; cache the last
793       // continuation byte; cache anything else iff it's a byte range (XX-YY).
794       if (i == n-1 || (ulo[i] < uhi[i] && i != 0))
795         id = CachedRuneByteSuffix(ulo[i], uhi[i], false, id);
796       else
797         id = UncachedRuneByteSuffix(ulo[i], uhi[i], false, id);
798     }
799   }
800   AddSuffix(id);
801 }
802 
803 // Should not be called.
Copy(Frag arg)804 Frag Compiler::Copy(Frag arg) {
805   // We're using WalkExponential; there should be no copying.
806   LOG(DFATAL) << "Compiler::Copy called!";
807   failed_ = true;
808   return NoMatch();
809 }
810 
811 // Visits a node quickly; called once WalkExponential has
812 // decided to cut this walk short.
ShortVisit(Regexp * re,Frag)813 Frag Compiler::ShortVisit(Regexp* re, Frag) {
814   failed_ = true;
815   return NoMatch();
816 }
817 
818 // Called before traversing a node's children during the walk.
PreVisit(Regexp * re,Frag,bool * stop)819 Frag Compiler::PreVisit(Regexp* re, Frag, bool* stop) {
820   // Cut off walk if we've already failed.
821   if (failed_)
822     *stop = true;
823 
824   return Frag();  // not used by caller
825 }
826 
Literal(Rune r,bool foldcase)827 Frag Compiler::Literal(Rune r, bool foldcase) {
828   switch (encoding_) {
829     default:
830       return Frag();
831 
832     case kEncodingLatin1:
833       return ByteRange(r, r, foldcase);
834 
835     case kEncodingUTF8: {
836       if (r < Runeself)  // Make common case fast.
837         return ByteRange(r, r, foldcase);
838       uint8_t buf[UTFmax];
839       int n = runetochar(reinterpret_cast<char*>(buf), &r);
840       Frag f = ByteRange((uint8_t)buf[0], buf[0], false);
841       for (int i = 1; i < n; i++)
842         f = Cat(f, ByteRange((uint8_t)buf[i], buf[i], false));
843       return f;
844     }
845   }
846 }
847 
848 // Called after traversing the node's children during the walk.
849 // Given their frags, build and return the frag for this re.
PostVisit(Regexp * re,Frag,Frag,Frag * child_frags,int nchild_frags)850 Frag Compiler::PostVisit(Regexp* re, Frag, Frag, Frag* child_frags,
851                          int nchild_frags) {
852   // If a child failed, don't bother going forward, especially
853   // since the child_frags might contain Frags with NULLs in them.
854   if (failed_)
855     return NoMatch();
856 
857   // Given the child fragments, return the fragment for this node.
858   switch (re->op()) {
859     case kRegexpRepeat:
860       // Should not see; code at bottom of function will print error
861       break;
862 
863     case kRegexpNoMatch:
864       return NoMatch();
865 
866     case kRegexpEmptyMatch:
867       return Nop();
868 
869     case kRegexpHaveMatch: {
870       Frag f = Match(re->match_id());
871       if (anchor_ == RE2::ANCHOR_BOTH) {
872         // Append \z or else the subexpression will effectively be unanchored.
873         // Complemented by the UNANCHORED case in CompileSet().
874         f = Cat(EmptyWidth(kEmptyEndText), f);
875       }
876       return f;
877     }
878 
879     case kRegexpConcat: {
880       Frag f = child_frags[0];
881       for (int i = 1; i < nchild_frags; i++)
882         f = Cat(f, child_frags[i]);
883       return f;
884     }
885 
886     case kRegexpAlternate: {
887       Frag f = child_frags[0];
888       for (int i = 1; i < nchild_frags; i++)
889         f = Alt(f, child_frags[i]);
890       return f;
891     }
892 
893     case kRegexpStar:
894       return Star(child_frags[0], (re->parse_flags()&Regexp::NonGreedy) != 0);
895 
896     case kRegexpPlus:
897       return Plus(child_frags[0], (re->parse_flags()&Regexp::NonGreedy) != 0);
898 
899     case kRegexpQuest:
900       return Quest(child_frags[0], (re->parse_flags()&Regexp::NonGreedy) != 0);
901 
902     case kRegexpLiteral:
903       return Literal(re->rune(), (re->parse_flags()&Regexp::FoldCase) != 0);
904 
905     case kRegexpLiteralString: {
906       // Concatenation of literals.
907       if (re->nrunes() == 0)
908         return Nop();
909       Frag f;
910       for (int i = 0; i < re->nrunes(); i++) {
911         Frag f1 = Literal(re->runes()[i],
912                           (re->parse_flags()&Regexp::FoldCase) != 0);
913         if (i == 0)
914           f = f1;
915         else
916           f = Cat(f, f1);
917       }
918       return f;
919     }
920 
921     case kRegexpAnyChar:
922       BeginRange();
923       AddRuneRange(0, Runemax, false);
924       return EndRange();
925 
926     case kRegexpAnyByte:
927       return ByteRange(0x00, 0xFF, false);
928 
929     case kRegexpCharClass: {
930       CharClass* cc = re->cc();
931       if (cc->empty()) {
932         // This can't happen.
933         LOG(DFATAL) << "No ranges in char class";
934         failed_ = true;
935         return NoMatch();
936       }
937 
938       // ASCII case-folding optimization: if the char class
939       // behaves the same on A-Z as it does on a-z,
940       // discard any ranges wholly contained in A-Z
941       // and mark the other ranges as foldascii.
942       // This reduces the size of a program for
943       // (?i)abc from 3 insts per letter to 1 per letter.
944       bool foldascii = cc->FoldsASCII();
945 
946       // Character class is just a big OR of the different
947       // character ranges in the class.
948       BeginRange();
949       for (CharClass::iterator i = cc->begin(); i != cc->end(); ++i) {
950         // ASCII case-folding optimization (see above).
951         if (foldascii && 'A' <= i->lo && i->hi <= 'Z')
952           continue;
953 
954         // If this range contains all of A-Za-z or none of it,
955         // the fold flag is unnecessary; don't bother.
956         bool fold = foldascii;
957         if ((i->lo <= 'A' && 'z' <= i->hi) || i->hi < 'A' || 'z' < i->lo ||
958             ('Z' < i->lo && i->hi < 'a'))
959           fold = false;
960 
961         AddRuneRange(i->lo, i->hi, fold);
962       }
963       return EndRange();
964     }
965 
966     case kRegexpCapture:
967       // If this is a non-capturing parenthesis -- (?:foo) --
968       // just use the inner expression.
969       if (re->cap() < 0)
970         return child_frags[0];
971       return Capture(child_frags[0], re->cap());
972 
973     case kRegexpBeginLine:
974       return EmptyWidth(reversed_ ? kEmptyEndLine : kEmptyBeginLine);
975 
976     case kRegexpEndLine:
977       return EmptyWidth(reversed_ ? kEmptyBeginLine : kEmptyEndLine);
978 
979     case kRegexpBeginText:
980       return EmptyWidth(reversed_ ? kEmptyEndText : kEmptyBeginText);
981 
982     case kRegexpEndText:
983       return EmptyWidth(reversed_ ? kEmptyBeginText : kEmptyEndText);
984 
985     case kRegexpWordBoundary:
986       return EmptyWidth(kEmptyWordBoundary);
987 
988     case kRegexpNoWordBoundary:
989       return EmptyWidth(kEmptyNonWordBoundary);
990   }
991   LOG(DFATAL) << "Missing case in Compiler: " << re->op();
992   failed_ = true;
993   return NoMatch();
994 }
995 
996 // Is this regexp required to start at the beginning of the text?
997 // Only approximate; can return false for complicated regexps like (\Aa|\Ab),
998 // but handles (\A(a|b)).  Could use the Walker to write a more exact one.
IsAnchorStart(Regexp ** pre,int depth)999 static bool IsAnchorStart(Regexp** pre, int depth) {
1000   Regexp* re = *pre;
1001   Regexp* sub;
1002   // The depth limit makes sure that we don't overflow
1003   // the stack on a deeply nested regexp.  As the comment
1004   // above says, IsAnchorStart is conservative, so returning
1005   // a false negative is okay.  The exact limit is somewhat arbitrary.
1006   if (re == NULL || depth >= 4)
1007     return false;
1008   switch (re->op()) {
1009     default:
1010       break;
1011     case kRegexpConcat:
1012       if (re->nsub() > 0) {
1013         sub = re->sub()[0]->Incref();
1014         if (IsAnchorStart(&sub, depth+1)) {
1015           PODArray<Regexp*> subcopy(re->nsub());
1016           subcopy[0] = sub;  // already have reference
1017           for (int i = 1; i < re->nsub(); i++)
1018             subcopy[i] = re->sub()[i]->Incref();
1019           *pre = Regexp::Concat(subcopy.data(), re->nsub(), re->parse_flags());
1020           re->Decref();
1021           return true;
1022         }
1023         sub->Decref();
1024       }
1025       break;
1026     case kRegexpCapture:
1027       sub = re->sub()[0]->Incref();
1028       if (IsAnchorStart(&sub, depth+1)) {
1029         *pre = Regexp::Capture(sub, re->parse_flags(), re->cap());
1030         re->Decref();
1031         return true;
1032       }
1033       sub->Decref();
1034       break;
1035     case kRegexpBeginText:
1036       *pre = Regexp::LiteralString(NULL, 0, re->parse_flags());
1037       re->Decref();
1038       return true;
1039   }
1040   return false;
1041 }
1042 
1043 // Is this regexp required to start at the end of the text?
1044 // Only approximate; can return false for complicated regexps like (a\z|b\z),
1045 // but handles ((a|b)\z).  Could use the Walker to write a more exact one.
IsAnchorEnd(Regexp ** pre,int depth)1046 static bool IsAnchorEnd(Regexp** pre, int depth) {
1047   Regexp* re = *pre;
1048   Regexp* sub;
1049   // The depth limit makes sure that we don't overflow
1050   // the stack on a deeply nested regexp.  As the comment
1051   // above says, IsAnchorEnd is conservative, so returning
1052   // a false negative is okay.  The exact limit is somewhat arbitrary.
1053   if (re == NULL || depth >= 4)
1054     return false;
1055   switch (re->op()) {
1056     default:
1057       break;
1058     case kRegexpConcat:
1059       if (re->nsub() > 0) {
1060         sub = re->sub()[re->nsub() - 1]->Incref();
1061         if (IsAnchorEnd(&sub, depth+1)) {
1062           PODArray<Regexp*> subcopy(re->nsub());
1063           subcopy[re->nsub() - 1] = sub;  // already have reference
1064           for (int i = 0; i < re->nsub() - 1; i++)
1065             subcopy[i] = re->sub()[i]->Incref();
1066           *pre = Regexp::Concat(subcopy.data(), re->nsub(), re->parse_flags());
1067           re->Decref();
1068           return true;
1069         }
1070         sub->Decref();
1071       }
1072       break;
1073     case kRegexpCapture:
1074       sub = re->sub()[0]->Incref();
1075       if (IsAnchorEnd(&sub, depth+1)) {
1076         *pre = Regexp::Capture(sub, re->parse_flags(), re->cap());
1077         re->Decref();
1078         return true;
1079       }
1080       sub->Decref();
1081       break;
1082     case kRegexpEndText:
1083       *pre = Regexp::LiteralString(NULL, 0, re->parse_flags());
1084       re->Decref();
1085       return true;
1086   }
1087   return false;
1088 }
1089 
Setup(Regexp::ParseFlags flags,int64_t max_mem,RE2::Anchor anchor)1090 void Compiler::Setup(Regexp::ParseFlags flags, int64_t max_mem,
1091                      RE2::Anchor anchor) {
1092   if (flags & Regexp::Latin1)
1093     encoding_ = kEncodingLatin1;
1094   max_mem_ = max_mem;
1095   if (max_mem <= 0) {
1096     max_ninst_ = 100000;  // more than enough
1097   } else if (static_cast<size_t>(max_mem) <= sizeof(Prog)) {
1098     // No room for anything.
1099     max_ninst_ = 0;
1100   } else {
1101     int64_t m = (max_mem - sizeof(Prog)) / sizeof(Prog::Inst);
1102     // Limit instruction count so that inst->id() fits nicely in an int.
1103     // SparseArray also assumes that the indices (inst->id()) are ints.
1104     // The call to WalkExponential uses 2*max_ninst_ below,
1105     // and other places in the code use 2 or 3 * prog->size().
1106     // Limiting to 2^24 should avoid overflow in those places.
1107     // (The point of allowing more than 32 bits of memory is to
1108     // have plenty of room for the DFA states, not to use it up
1109     // on the program.)
1110     if (m >= 1<<24)
1111       m = 1<<24;
1112     // Inst imposes its own limit (currently bigger than 2^24 but be safe).
1113     if (m > Prog::Inst::kMaxInst)
1114       m = Prog::Inst::kMaxInst;
1115     max_ninst_ = static_cast<int>(m);
1116   }
1117   anchor_ = anchor;
1118 }
1119 
1120 // Compiles re, returning program.
1121 // Caller is responsible for deleting prog_.
1122 // If reversed is true, compiles a program that expects
1123 // to run over the input string backward (reverses all concatenations).
1124 // The reversed flag is also recorded in the returned program.
Compile(Regexp * re,bool reversed,int64_t max_mem)1125 Prog* Compiler::Compile(Regexp* re, bool reversed, int64_t max_mem) {
1126   Compiler c;
1127   c.Setup(re->parse_flags(), max_mem, RE2::UNANCHORED /* unused */);
1128   c.reversed_ = reversed;
1129 
1130   // Simplify to remove things like counted repetitions
1131   // and character classes like \d.
1132   Regexp* sre = re->Simplify();
1133   if (sre == NULL)
1134     return NULL;
1135 
1136   // Record whether prog is anchored, removing the anchors.
1137   // (They get in the way of other optimizations.)
1138   bool is_anchor_start = IsAnchorStart(&sre, 0);
1139   bool is_anchor_end = IsAnchorEnd(&sre, 0);
1140 
1141   // Generate fragment for entire regexp.
1142   Frag all = c.WalkExponential(sre, Frag(), 2*c.max_ninst_);
1143   sre->Decref();
1144   if (c.failed_)
1145     return NULL;
1146 
1147   // Success!  Finish by putting Match node at end, and record start.
1148   // Turn off c.reversed_ (if it is set) to force the remaining concatenations
1149   // to behave normally.
1150   c.reversed_ = false;
1151   all = c.Cat(all, c.Match(0));
1152 
1153   c.prog_->set_reversed(reversed);
1154   if (c.prog_->reversed()) {
1155     c.prog_->set_anchor_start(is_anchor_end);
1156     c.prog_->set_anchor_end(is_anchor_start);
1157   } else {
1158     c.prog_->set_anchor_start(is_anchor_start);
1159     c.prog_->set_anchor_end(is_anchor_end);
1160   }
1161 
1162   c.prog_->set_start(all.begin);
1163   if (!c.prog_->anchor_start()) {
1164     // Also create unanchored version, which starts with a .*? loop.
1165     all = c.Cat(c.DotStar(), all);
1166   }
1167   c.prog_->set_start_unanchored(all.begin);
1168 
1169   // Hand ownership of prog_ to caller.
1170   return c.Finish(re);
1171 }
1172 
Finish(Regexp * re)1173 Prog* Compiler::Finish(Regexp* re) {
1174   if (failed_)
1175     return NULL;
1176 
1177   if (prog_->start() == 0 && prog_->start_unanchored() == 0) {
1178     // No possible matches; keep Fail instruction only.
1179     ninst_ = 1;
1180   }
1181 
1182   // Hand off the array to Prog.
1183   prog_->inst_ = std::move(inst_);
1184   prog_->size_ = ninst_;
1185 
1186   prog_->Optimize();
1187   prog_->Flatten();
1188   prog_->ComputeByteMap();
1189 
1190   if (!prog_->reversed()) {
1191     std::string prefix;
1192     bool prefix_foldcase;
1193     if (re->RequiredPrefixForAccel(&prefix, &prefix_foldcase) &&
1194         !prefix_foldcase) {
1195       prog_->prefix_size_ = prefix.size();
1196       prog_->prefix_front_ = prefix.front();
1197       prog_->prefix_back_ = prefix.back();
1198     }
1199   }
1200 
1201   // Record remaining memory for DFA.
1202   if (max_mem_ <= 0) {
1203     prog_->set_dfa_mem(1<<20);
1204   } else {
1205     int64_t m = max_mem_ - sizeof(Prog);
1206     m -= prog_->size_*sizeof(Prog::Inst);  // account for inst_
1207     if (prog_->CanBitState())
1208       m -= prog_->size_*sizeof(uint16_t);  // account for list_heads_
1209     if (m < 0)
1210       m = 0;
1211     prog_->set_dfa_mem(m);
1212   }
1213 
1214   Prog* p = prog_;
1215   prog_ = NULL;
1216   return p;
1217 }
1218 
1219 // Converts Regexp to Prog.
CompileToProg(int64_t max_mem)1220 Prog* Regexp::CompileToProg(int64_t max_mem) {
1221   return Compiler::Compile(this, false, max_mem);
1222 }
1223 
CompileToReverseProg(int64_t max_mem)1224 Prog* Regexp::CompileToReverseProg(int64_t max_mem) {
1225   return Compiler::Compile(this, true, max_mem);
1226 }
1227 
DotStar()1228 Frag Compiler::DotStar() {
1229   return Star(ByteRange(0x00, 0xff, false), true);
1230 }
1231 
1232 // Compiles RE set to Prog.
CompileSet(Regexp * re,RE2::Anchor anchor,int64_t max_mem)1233 Prog* Compiler::CompileSet(Regexp* re, RE2::Anchor anchor, int64_t max_mem) {
1234   Compiler c;
1235   c.Setup(re->parse_flags(), max_mem, anchor);
1236 
1237   Regexp* sre = re->Simplify();
1238   if (sre == NULL)
1239     return NULL;
1240 
1241   Frag all = c.WalkExponential(sre, Frag(), 2*c.max_ninst_);
1242   sre->Decref();
1243   if (c.failed_)
1244     return NULL;
1245 
1246   c.prog_->set_anchor_start(true);
1247   c.prog_->set_anchor_end(true);
1248 
1249   if (anchor == RE2::UNANCHORED) {
1250     // Prepend .* or else the expression will effectively be anchored.
1251     // Complemented by the ANCHOR_BOTH case in PostVisit().
1252     all = c.Cat(c.DotStar(), all);
1253   }
1254   c.prog_->set_start(all.begin);
1255   c.prog_->set_start_unanchored(all.begin);
1256 
1257   Prog* prog = c.Finish(re);
1258   if (prog == NULL)
1259     return NULL;
1260 
1261   // Make sure DFA has enough memory to operate,
1262   // since we're not going to fall back to the NFA.
1263   bool dfa_failed = false;
1264   StringPiece sp = "hello, world";
1265   prog->SearchDFA(sp, sp, Prog::kAnchored, Prog::kManyMatch,
1266                   NULL, &dfa_failed, NULL);
1267   if (dfa_failed) {
1268     delete prog;
1269     return NULL;
1270   }
1271 
1272   return prog;
1273 }
1274 
CompileSet(Regexp * re,RE2::Anchor anchor,int64_t max_mem)1275 Prog* Prog::CompileSet(Regexp* re, RE2::Anchor anchor, int64_t max_mem) {
1276   return Compiler::CompileSet(re, anchor, max_mem);
1277 }
1278 
1279 }  // namespace re2
1280