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394 lines
12 KiB
C++
394 lines
12 KiB
C++
// Copyright 2006 The RE2 Authors. All Rights Reserved.
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// Use of this source code is governed by a BSD-style
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// license that can be found in the LICENSE file.
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// Rewrite POSIX and other features in re
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// to use simple extended regular expression features.
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// Also sort and simplify character classes.
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#include "util/util.h"
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#include "re2/regexp.h"
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#include "re2/walker-inl.h"
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namespace re2 {
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// Parses the regexp src and then simplifies it and sets *dst to the
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// string representation of the simplified form. Returns true on success.
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// Returns false and sets *error (if error != NULL) on error.
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bool Regexp::SimplifyRegexp(const StringPiece& src, ParseFlags flags,
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string* dst,
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RegexpStatus* status) {
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Regexp* re = Parse(src, flags, status);
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if (re == NULL)
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return false;
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Regexp* sre = re->Simplify();
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re->Decref();
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if (sre == NULL) {
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// Should not happen, since Simplify never fails.
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LOG(ERROR) << "Simplify failed on " << src;
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if (status) {
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status->set_code(kRegexpInternalError);
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status->set_error_arg(src);
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}
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return false;
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}
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*dst = sre->ToString();
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sre->Decref();
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return true;
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}
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// Assuming the simple_ flags on the children are accurate,
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// is this Regexp* simple?
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bool Regexp::ComputeSimple() {
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Regexp** subs;
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switch (op_) {
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case kRegexpNoMatch:
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case kRegexpEmptyMatch:
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case kRegexpLiteral:
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case kRegexpLiteralString:
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case kRegexpBeginLine:
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case kRegexpEndLine:
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case kRegexpBeginText:
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case kRegexpWordBoundary:
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case kRegexpNoWordBoundary:
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case kRegexpEndText:
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case kRegexpAnyChar:
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case kRegexpAnyByte:
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case kRegexpHaveMatch:
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return true;
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case kRegexpConcat:
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case kRegexpAlternate:
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// These are simple as long as the subpieces are simple.
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subs = sub();
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for (int i = 0; i < nsub_; i++)
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if (!subs[i]->simple_)
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return false;
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return true;
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case kRegexpCharClass:
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// Simple as long as the char class is not empty, not full.
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if (ccb_ != NULL)
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return !ccb_->empty() && !ccb_->full();
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return !cc_->empty() && !cc_->full();
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case kRegexpCapture:
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subs = sub();
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return subs[0]->simple_;
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case kRegexpStar:
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case kRegexpPlus:
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case kRegexpQuest:
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subs = sub();
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if (!subs[0]->simple_)
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return false;
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switch (subs[0]->op_) {
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case kRegexpStar:
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case kRegexpPlus:
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case kRegexpQuest:
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case kRegexpEmptyMatch:
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case kRegexpNoMatch:
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return false;
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default:
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break;
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}
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return true;
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case kRegexpRepeat:
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return false;
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}
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LOG(DFATAL) << "Case not handled in ComputeSimple: " << op_;
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return false;
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}
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// Walker subclass used by Simplify.
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// The simplify walk is purely post-recursive: given the simplified children,
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// PostVisit creates the simplified result.
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// The child_args are simplified Regexp*s.
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class SimplifyWalker : public Regexp::Walker<Regexp*> {
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public:
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SimplifyWalker() {}
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virtual Regexp* PreVisit(Regexp* re, Regexp* parent_arg, bool* stop);
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virtual Regexp* PostVisit(Regexp* re,
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Regexp* parent_arg,
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Regexp* pre_arg,
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Regexp** child_args, int nchild_args);
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virtual Regexp* Copy(Regexp* re);
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virtual Regexp* ShortVisit(Regexp* re, Regexp* parent_arg);
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private:
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// These functions are declared inside SimplifyWalker so that
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// they can edit the private fields of the Regexps they construct.
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// Creates a concatenation of two Regexp, consuming refs to re1 and re2.
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// Caller must Decref return value when done with it.
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static Regexp* Concat2(Regexp* re1, Regexp* re2, Regexp::ParseFlags flags);
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// Simplifies the expression re{min,max} in terms of *, +, and ?.
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// Returns a new regexp. Does not edit re. Does not consume reference to re.
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// Caller must Decref return value when done with it.
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static Regexp* SimplifyRepeat(Regexp* re, int min, int max,
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Regexp::ParseFlags parse_flags);
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// Simplifies a character class by expanding any named classes
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// into rune ranges. Does not edit re. Does not consume ref to re.
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// Caller must Decref return value when done with it.
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static Regexp* SimplifyCharClass(Regexp* re);
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DISALLOW_EVIL_CONSTRUCTORS(SimplifyWalker);
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};
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// Simplifies a regular expression, returning a new regexp.
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// The new regexp uses traditional Unix egrep features only,
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// plus the Perl (?:) non-capturing parentheses.
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// Otherwise, no POSIX or Perl additions. The new regexp
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// captures exactly the same subexpressions (with the same indices)
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// as the original.
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// Does not edit current object.
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// Caller must Decref() return value when done with it.
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Regexp* Regexp::Simplify() {
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if (simple_)
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return Incref();
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SimplifyWalker w;
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return w.Walk(this, NULL);
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}
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#define Simplify DontCallSimplify // Avoid accidental recursion
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Regexp* SimplifyWalker::Copy(Regexp* re) {
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return re->Incref();
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}
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Regexp* SimplifyWalker::ShortVisit(Regexp* re, Regexp* parent_arg) {
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// This should never be called, since we use Walk and not
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// WalkExponential.
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LOG(DFATAL) << "SimplifyWalker::ShortVisit called";
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return re->Incref();
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}
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Regexp* SimplifyWalker::PreVisit(Regexp* re, Regexp* parent_arg, bool* stop) {
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if (re->simple_) {
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*stop = true;
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return re->Incref();
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}
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return NULL;
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}
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Regexp* SimplifyWalker::PostVisit(Regexp* re,
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Regexp* parent_arg,
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Regexp* pre_arg,
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Regexp** child_args,
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int nchild_args) {
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switch (re->op()) {
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case kRegexpNoMatch:
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case kRegexpEmptyMatch:
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case kRegexpLiteral:
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case kRegexpLiteralString:
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case kRegexpBeginLine:
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case kRegexpEndLine:
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case kRegexpBeginText:
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case kRegexpWordBoundary:
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case kRegexpNoWordBoundary:
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case kRegexpEndText:
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case kRegexpAnyChar:
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case kRegexpAnyByte:
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case kRegexpHaveMatch:
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// All these are always simple.
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re->simple_ = true;
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return re->Incref();
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case kRegexpConcat:
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case kRegexpAlternate: {
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// These are simple as long as the subpieces are simple.
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// Two passes to avoid allocation in the common case.
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bool changed = false;
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Regexp** subs = re->sub();
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for (int i = 0; i < re->nsub_; i++) {
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Regexp* sub = subs[i];
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Regexp* newsub = child_args[i];
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if (newsub != sub) {
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changed = true;
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break;
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}
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}
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if (!changed) {
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for (int i = 0; i < re->nsub_; i++) {
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Regexp* newsub = child_args[i];
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newsub->Decref();
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}
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re->simple_ = true;
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return re->Incref();
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}
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Regexp* nre = new Regexp(re->op(), re->parse_flags());
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nre->AllocSub(re->nsub_);
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Regexp** nre_subs = nre->sub();
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for (int i = 0; i <re->nsub_; i++)
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nre_subs[i] = child_args[i];
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nre->simple_ = true;
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return nre;
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}
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case kRegexpCapture: {
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Regexp* newsub = child_args[0];
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if (newsub == re->sub()[0]) {
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newsub->Decref();
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re->simple_ = true;
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return re->Incref();
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}
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Regexp* nre = new Regexp(kRegexpCapture, re->parse_flags());
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nre->AllocSub(1);
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nre->sub()[0] = newsub;
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nre->cap_ = re->cap_;
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nre->simple_ = true;
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return nre;
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}
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case kRegexpStar:
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case kRegexpPlus:
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case kRegexpQuest: {
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Regexp* newsub = child_args[0];
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// Special case: repeat the empty string as much as
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// you want, but it's still the empty string.
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if (newsub->op() == kRegexpEmptyMatch)
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return newsub;
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// These are simple as long as the subpiece is simple.
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if (newsub == re->sub()[0]) {
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newsub->Decref();
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re->simple_ = true;
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return re->Incref();
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}
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// These are also idempotent if flags are constant.
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if (re->op() == newsub->op() &&
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re->parse_flags() == newsub->parse_flags())
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return newsub;
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Regexp* nre = new Regexp(re->op(), re->parse_flags());
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nre->AllocSub(1);
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nre->sub()[0] = newsub;
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nre->simple_ = true;
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return nre;
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}
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case kRegexpRepeat: {
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Regexp* newsub = child_args[0];
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// Special case: repeat the empty string as much as
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// you want, but it's still the empty string.
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if (newsub->op() == kRegexpEmptyMatch)
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return newsub;
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Regexp* nre = SimplifyRepeat(newsub, re->min_, re->max_,
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re->parse_flags());
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newsub->Decref();
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nre->simple_ = true;
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return nre;
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}
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case kRegexpCharClass: {
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Regexp* nre = SimplifyCharClass(re);
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nre->simple_ = true;
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return nre;
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}
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}
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LOG(ERROR) << "Simplify case not handled: " << re->op();
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return re->Incref();
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}
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// Creates a concatenation of two Regexp, consuming refs to re1 and re2.
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// Returns a new Regexp, handing the ref to the caller.
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Regexp* SimplifyWalker::Concat2(Regexp* re1, Regexp* re2,
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Regexp::ParseFlags parse_flags) {
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Regexp* re = new Regexp(kRegexpConcat, parse_flags);
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re->AllocSub(2);
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Regexp** subs = re->sub();
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subs[0] = re1;
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subs[1] = re2;
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return re;
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}
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// Simplifies the expression re{min,max} in terms of *, +, and ?.
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// Returns a new regexp. Does not edit re. Does not consume reference to re.
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// Caller must Decref return value when done with it.
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// The result will *not* necessarily have the right capturing parens
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// if you call ToString() and re-parse it: (x){2} becomes (x)(x),
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// but in the Regexp* representation, both (x) are marked as $1.
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Regexp* SimplifyWalker::SimplifyRepeat(Regexp* re, int min, int max,
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Regexp::ParseFlags f) {
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// x{n,} means at least n matches of x.
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if (max == -1) {
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// Special case: x{0,} is x*
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if (min == 0)
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return Regexp::Star(re->Incref(), f);
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// Special case: x{1,} is x+
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if (min == 1)
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return Regexp::Plus(re->Incref(), f);
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// General case: x{4,} is xxxx+
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Regexp* nre = new Regexp(kRegexpConcat, f);
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nre->AllocSub(min);
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VLOG(1) << "Simplify " << min;
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Regexp** nre_subs = nre->sub();
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for (int i = 0; i < min-1; i++)
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nre_subs[i] = re->Incref();
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nre_subs[min-1] = Regexp::Plus(re->Incref(), f);
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return nre;
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}
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// Special case: (x){0} matches only empty string.
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if (min == 0 && max == 0)
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return new Regexp(kRegexpEmptyMatch, f);
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// Special case: x{1} is just x.
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if (min == 1 && max == 1)
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return re->Incref();
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// General case: x{n,m} means n copies of x and m copies of x?.
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// The machine will do less work if we nest the final m copies,
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// so that x{2,5} = xx(x(x(x)?)?)?
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// Build leading prefix: xx. Capturing only on the last one.
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Regexp* nre = NULL;
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if (min > 0) {
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nre = new Regexp(kRegexpConcat, f);
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nre->AllocSub(min);
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Regexp** nre_subs = nre->sub();
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for (int i = 0; i < min; i++)
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nre_subs[i] = re->Incref();
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}
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// Build and attach suffix: (x(x(x)?)?)?
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if (max > min) {
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Regexp* suf = Regexp::Quest(re->Incref(), f);
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for (int i = min+1; i < max; i++)
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suf = Regexp::Quest(Concat2(re->Incref(), suf, f), f);
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if (nre == NULL)
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nre = suf;
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else
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nre = Concat2(nre, suf, f);
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}
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if (nre == NULL) {
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// Some degenerate case, like min > max, or min < max < 0.
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// This shouldn't happen, because the parser rejects such regexps.
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LOG(DFATAL) << "Malformed repeat " << re->ToString() << " " << min << " " << max;
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return new Regexp(kRegexpNoMatch, f);
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}
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return nre;
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}
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// Simplifies a character class.
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// Caller must Decref return value when done with it.
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Regexp* SimplifyWalker::SimplifyCharClass(Regexp* re) {
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CharClass* cc = re->cc();
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// Special cases
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if (cc->empty())
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return new Regexp(kRegexpNoMatch, re->parse_flags());
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if (cc->full())
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return new Regexp(kRegexpAnyChar, re->parse_flags());
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return re->Incref();
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}
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} // namespace re2
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