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615 lines
22 KiB
C++
615 lines
22 KiB
C++
// Copyright 2008 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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// Tested by search_test.cc.
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//
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// Prog::SearchOnePass is an efficient implementation of
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// regular expression search with submatch tracking for
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// what I call "one-pass regular expressions". (An alternate
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// name might be "backtracking-free regular expressions".)
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//
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// One-pass regular expressions have the property that
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// at each input byte during an anchored match, there may be
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// multiple alternatives but only one can proceed for any
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// given input byte.
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//
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// For example, the regexp /x*yx*/ is one-pass: you read
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// x's until a y, then you read the y, then you keep reading x's.
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// At no point do you have to guess what to do or back up
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// and try a different guess.
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//
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// On the other hand, /x*x/ is not one-pass: when you're
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// looking at an input "x", it's not clear whether you should
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// use it to extend the x* or as the final x.
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//
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// More examples: /([^ ]*) (.*)/ is one-pass; /(.*) (.*)/ is not.
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// /(\d+)-(\d+)/ is one-pass; /(\d+).(\d+)/ is not.
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//
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// A simple intuition for identifying one-pass regular expressions
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// is that it's always immediately obvious when a repetition ends.
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// It must also be immediately obvious which branch of an | to take:
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//
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// /x(y|z)/ is one-pass, but /(xy|xz)/ is not.
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//
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// The NFA-based search in nfa.cc does some bookkeeping to
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// avoid the need for backtracking and its associated exponential blowup.
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// But if we have a one-pass regular expression, there is no
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// possibility of backtracking, so there is no need for the
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// extra bookkeeping. Hence, this code.
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//
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// On a one-pass regular expression, the NFA code in nfa.cc
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// runs at about 1/20 of the backtracking-based PCRE speed.
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// In contrast, the code in this file runs at about the same
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// speed as PCRE.
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//
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// One-pass regular expressions get used a lot when RE is
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// used for parsing simple strings, so it pays off to
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// notice them and handle them efficiently.
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//
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// See also Anne Brüggemann-Klein and Derick Wood,
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// "One-unambiguous regular languages", Information and Computation 142(2).
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#include <string.h>
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#include <map>
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#include "util/util.h"
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#include "util/arena.h"
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#include "util/sparse_set.h"
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#include "re2/prog.h"
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#include "re2/stringpiece.h"
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namespace re2 {
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static const int Debug = 0;
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// The key insight behind this implementation is that the
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// non-determinism in an NFA for a one-pass regular expression
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// is contained. To explain what that means, first a
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// refresher about what regular expression programs look like
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// and how the usual NFA execution runs.
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//
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// In a regular expression program, only the kInstByteRange
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// instruction processes an input byte c and moves on to the
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// next byte in the string (it does so if c is in the given range).
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// The kInstByteRange instructions correspond to literal characters
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// and character classes in the regular expression.
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//
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// The kInstAlt instructions are used as wiring to connect the
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// kInstByteRange instructions together in interesting ways when
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// implementing | + and *.
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// The kInstAlt instruction forks execution, like a goto that
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// jumps to ip->out() and ip->out1() in parallel. Each of the
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// resulting computation paths is called a thread.
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//
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// The other instructions -- kInstEmptyWidth, kInstMatch, kInstCapture --
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// are interesting in their own right but like kInstAlt they don't
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// advance the input pointer. Only kInstByteRange does.
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//
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// The automaton execution in nfa.cc runs all the possible
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// threads of execution in lock-step over the input. To process
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// a particular byte, each thread gets run until it either dies
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// or finds a kInstByteRange instruction matching the byte.
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// If the latter happens, the thread stops just past the
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// kInstByteRange instruction (at ip->out()) and waits for
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// the other threads to finish processing the input byte.
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// Then, once all the threads have processed that input byte,
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// the whole process repeats. The kInstAlt state instruction
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// might create new threads during input processing, but no
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// matter what, all the threads stop after a kInstByteRange
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// and wait for the other threads to "catch up".
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// Running in lock step like this ensures that the NFA reads
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// the input string only once.
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//
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// Each thread maintains its own set of capture registers
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// (the string positions at which it executed the kInstCapture
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// instructions corresponding to capturing parentheses in the
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// regular expression). Repeated copying of the capture registers
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// is the main performance bottleneck in the NFA implementation.
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//
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// A regular expression program is "one-pass" if, no matter what
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// the input string, there is only one thread that makes it
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// past a kInstByteRange instruction at each input byte. This means
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// that there is in some sense only one active thread throughout
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// the execution. Other threads might be created during the
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// processing of an input byte, but they are ephemeral: only one
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// thread is left to start processing the next input byte.
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// This is what I meant above when I said the non-determinism
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// was "contained".
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//
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// To execute a one-pass regular expression program, we can build
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// a DFA (no non-determinism) that has at most as many states as
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// the NFA (compare this to the possibly exponential number of states
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// in the general case). Each state records, for each possible
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// input byte, the next state along with the conditions required
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// before entering that state -- empty-width flags that must be true
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// and capture operations that must be performed. It also records
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// whether a set of conditions required to finish a match at that
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// point in the input rather than process the next byte.
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// A state in the one-pass NFA (aka DFA) - just an array of actions.
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struct OneState;
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// A state in the one-pass NFA - just an array of actions indexed
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// by the bytemap_[] of the next input byte. (The bytemap
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// maps next input bytes into equivalence classes, to reduce
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// the memory footprint.)
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struct OneState {
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uint32 matchcond; // conditions to match right now.
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uint32 action[1];
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};
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// The uint32 conditions in the action are a combination of
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// condition and capture bits and the next state. The bottom 16 bits
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// are the condition and capture bits, and the top 16 are the index of
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// the next state.
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//
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// Bits 0-5 are the empty-width flags from prog.h.
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// Bit 6 is kMatchWins, which means the match takes
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// priority over moving to next in a first-match search.
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// The remaining bits mark capture registers that should
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// be set to the current input position. The capture bits
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// start at index 2, since the search loop can take care of
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// cap[0], cap[1] (the overall match position).
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// That means we can handle up to 5 capturing parens: $1 through $4, plus $0.
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// No input position can satisfy both kEmptyWordBoundary
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// and kEmptyNonWordBoundary, so we can use that as a sentinel
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// instead of needing an extra bit.
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static const int kIndexShift = 16; // number of bits below index
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static const int kEmptyShift = 6; // number of empty flags in prog.h
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static const int kRealCapShift = kEmptyShift + 1;
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static const int kRealMaxCap = (kIndexShift - kRealCapShift) / 2 * 2;
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// Parameters used to skip over cap[0], cap[1].
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static const int kCapShift = kRealCapShift - 2;
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static const int kMaxCap = kRealMaxCap + 2;
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static const uint32 kMatchWins = 1 << kEmptyShift;
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static const uint32 kCapMask = ((1 << kRealMaxCap) - 1) << kRealCapShift;
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static const uint32 kImpossible = kEmptyWordBoundary | kEmptyNonWordBoundary;
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// Check, at compile time, that prog.h agrees with math above.
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// This function is never called.
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void OnePass_Checks() {
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COMPILE_ASSERT((1<<kEmptyShift)-1 == kEmptyAllFlags,
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kEmptyShift_disagrees_with_kEmptyAllFlags);
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// kMaxCap counts pointers, kMaxOnePassCapture counts pairs.
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COMPILE_ASSERT(kMaxCap == Prog::kMaxOnePassCapture*2,
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kMaxCap_disagrees_with_kMaxOnePassCapture);
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}
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static bool Satisfy(uint32 cond, const StringPiece& context, const char* p) {
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uint32 satisfied = Prog::EmptyFlags(context, p);
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if (cond & kEmptyAllFlags & ~satisfied)
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return false;
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return true;
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}
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// Apply the capture bits in cond, saving p to the appropriate
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// locations in cap[].
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static void ApplyCaptures(uint32 cond, const char* p,
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const char** cap, int ncap) {
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for (int i = 2; i < ncap; i++)
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if (cond & (1 << kCapShift << i))
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cap[i] = p;
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}
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// Compute a node pointer.
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// Basically (OneState*)(nodes + statesize*nodeindex)
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// but the version with the C++ casts overflows 80 characters (and is ugly).
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static inline OneState* IndexToNode(volatile uint8* nodes, int statesize,
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int nodeindex) {
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return reinterpret_cast<OneState*>(
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const_cast<uint8*>(nodes + statesize*nodeindex));
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}
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bool Prog::SearchOnePass(const StringPiece& text,
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const StringPiece& const_context,
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Anchor anchor, MatchKind kind,
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StringPiece* match, int nmatch) {
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if (anchor != kAnchored && kind != kFullMatch) {
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LOG(DFATAL) << "Cannot use SearchOnePass for unanchored matches.";
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return false;
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}
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// Make sure we have at least cap[1],
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// because we use it to tell if we matched.
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int ncap = 2*nmatch;
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if (ncap < 2)
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ncap = 2;
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const char* cap[kMaxCap];
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for (int i = 0; i < ncap; i++)
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cap[i] = NULL;
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const char* matchcap[kMaxCap];
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for (int i = 0; i < ncap; i++)
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matchcap[i] = NULL;
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StringPiece context = const_context;
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if (context.begin() == NULL)
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context = text;
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if (anchor_start() && context.begin() != text.begin())
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return false;
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if (anchor_end() && context.end() != text.end())
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return false;
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if (anchor_end())
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kind = kFullMatch;
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// State and act are marked volatile to
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// keep the compiler from re-ordering the
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// memory accesses walking over the NFA.
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// This is worth about 5%.
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volatile OneState* state = onepass_start_;
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volatile uint8* nodes = onepass_nodes_;
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volatile uint32 statesize = onepass_statesize_;
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uint8* bytemap = bytemap_;
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const char* bp = text.begin();
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const char* ep = text.end();
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const char* p;
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bool matched = false;
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matchcap[0] = bp;
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cap[0] = bp;
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uint32 nextmatchcond = state->matchcond;
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for (p = bp; p < ep; p++) {
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int c = bytemap[*p & 0xFF];
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uint32 matchcond = nextmatchcond;
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uint32 cond = state->action[c];
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// Determine whether we can reach act->next.
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// If so, advance state and nextmatchcond.
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if ((cond & kEmptyAllFlags) == 0 || Satisfy(cond, context, p)) {
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uint32 nextindex = cond >> kIndexShift;
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state = IndexToNode(nodes, statesize, nextindex);
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nextmatchcond = state->matchcond;
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} else {
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state = NULL;
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nextmatchcond = kImpossible;
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}
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// This code section is carefully tuned.
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// The goto sequence is about 10% faster than the
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// obvious rewrite as a large if statement in the
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// ASCIIMatchRE2 and DotMatchRE2 benchmarks.
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// Saving the match capture registers is expensive.
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// Is this intermediate match worth thinking about?
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// Not if we want a full match.
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if (kind == kFullMatch)
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goto skipmatch;
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// Not if it's impossible.
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if (matchcond == kImpossible)
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goto skipmatch;
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// Not if the possible match is beaten by the certain
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// match at the next byte. When this test is useless
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// (e.g., HTTPPartialMatchRE2) it slows the loop by
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// about 10%, but when it avoids work (e.g., DotMatchRE2),
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// it cuts the loop execution by about 45%.
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if ((cond & kMatchWins) == 0 && (nextmatchcond & kEmptyAllFlags) == 0)
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goto skipmatch;
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// Finally, the match conditions must be satisfied.
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if ((matchcond & kEmptyAllFlags) == 0 || Satisfy(matchcond, context, p)) {
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for (int i = 2; i < 2*nmatch; i++)
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matchcap[i] = cap[i];
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if (nmatch > 1 && (matchcond & kCapMask))
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ApplyCaptures(matchcond, p, matchcap, ncap);
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matchcap[1] = p;
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matched = true;
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// If we're in longest match mode, we have to keep
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// going and see if we find a longer match.
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// In first match mode, we can stop if the match
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// takes priority over the next state for this input byte.
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// That bit is per-input byte and thus in cond, not matchcond.
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if (kind == kFirstMatch && (cond & kMatchWins))
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goto done;
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}
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skipmatch:
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if (state == NULL)
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goto done;
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if ((cond & kCapMask) && nmatch > 1)
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ApplyCaptures(cond, p, cap, ncap);
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}
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// Look for match at end of input.
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{
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uint32 matchcond = state->matchcond;
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if (matchcond != kImpossible &&
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((matchcond & kEmptyAllFlags) == 0 || Satisfy(matchcond, context, p))) {
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if (nmatch > 1 && (matchcond & kCapMask))
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ApplyCaptures(matchcond, p, cap, ncap);
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for (int i = 2; i < ncap; i++)
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matchcap[i] = cap[i];
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matchcap[1] = p;
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matched = true;
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}
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}
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done:
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if (!matched)
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return false;
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for (int i = 0; i < nmatch; i++)
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match[i].set(matchcap[2*i], matchcap[2*i+1] - matchcap[2*i]);
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return true;
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}
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// Analysis to determine whether a given regexp program is one-pass.
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// If ip is not on workq, adds ip to work queue and returns true.
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// If ip is already on work queue, does nothing and returns false.
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// If ip is NULL, does nothing and returns true (pretends to add it).
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typedef SparseSet Instq;
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static bool AddQ(Instq *q, int id) {
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if (id == 0)
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return true;
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if (q->contains(id))
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return false;
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q->insert(id);
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return true;
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}
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struct InstCond {
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int id;
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uint32 cond;
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};
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// Returns whether this is a one-pass program; that is,
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// returns whether it is safe to use SearchOnePass on this program.
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// These conditions must be true for any instruction ip:
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//
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// (1) for any other Inst nip, there is at most one input-free
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// path from ip to nip.
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// (2) there is at most one kInstByte instruction reachable from
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// ip that matches any particular byte c.
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// (3) there is at most one input-free path from ip to a kInstMatch
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// instruction.
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//
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// This is actually just a conservative approximation: it might
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// return false when the answer is true, when kInstEmptyWidth
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// instructions are involved.
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// Constructs and saves corresponding one-pass NFA on success.
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bool Prog::IsOnePass() {
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if (did_onepass_)
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return onepass_start_ != NULL;
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did_onepass_ = true;
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if (start() == 0) // no match
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return false;
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// Steal memory for the one-pass NFA from the overall DFA budget.
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// Willing to use at most 1/4 of the DFA budget (heuristic).
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// Limit max node count to 65000 as a conservative estimate to
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// avoid overflowing 16-bit node index in encoding.
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int maxnodes = 2 + byte_inst_count_;
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int statesize = sizeof(OneState) + (bytemap_range_-1)*sizeof(uint32);
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if (maxnodes >= 65000 || dfa_mem_ / 4 / statesize < maxnodes)
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return false;
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// Flood the graph starting at the start state, and check
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// that in each reachable state, each possible byte leads
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// to a unique next state.
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int size = this->size();
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InstCond *stack = new InstCond[size];
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int* nodebyid = new int[size]; // indexed by ip
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memset(nodebyid, 0xFF, size*sizeof nodebyid[0]);
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uint8* nodes = new uint8[maxnodes*statesize];
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uint8* nodep = nodes;
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Instq tovisit(size), workq(size);
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AddQ(&tovisit, start());
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nodebyid[start()] = 0;
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nodep += statesize;
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int nalloc = 1;
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for (Instq::iterator it = tovisit.begin(); it != tovisit.end(); ++it) {
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int id = *it;
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int nodeindex = nodebyid[id];
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OneState* node = IndexToNode(nodes, statesize, nodeindex);
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// Flood graph using manual stack, filling in actions as found.
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// Default is none.
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for (int b = 0; b < bytemap_range_; b++)
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node->action[b] = kImpossible;
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node->matchcond = kImpossible;
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workq.clear();
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bool matched = false;
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int nstack = 0;
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stack[nstack].id = id;
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stack[nstack++].cond = 0;
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while (nstack > 0) {
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int id = stack[--nstack].id;
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Prog::Inst* ip = inst(id);
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uint32 cond = stack[nstack].cond;
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switch (ip->opcode()) {
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case kInstAltMatch:
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// TODO(rsc): Ignoring kInstAltMatch optimization.
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// Should implement it in this engine, but it's subtle.
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// Fall through.
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case kInstAlt:
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// If already on work queue, (1) is violated: bail out.
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if (!AddQ(&workq, ip->out()) || !AddQ(&workq, ip->out1()))
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goto fail;
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stack[nstack].id = ip->out1();
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stack[nstack++].cond = cond;
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stack[nstack].id = ip->out();
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stack[nstack++].cond = cond;
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break;
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case kInstByteRange: {
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int nextindex = nodebyid[ip->out()];
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if (nextindex == -1) {
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if (nalloc >= maxnodes) {
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if (Debug)
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LOG(ERROR)
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<< StringPrintf("Not OnePass: hit node limit %d > %d",
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nalloc, maxnodes);
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goto fail;
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}
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nextindex = nalloc;
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nodep += statesize;
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nodebyid[ip->out()] = nextindex;
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nalloc++;
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AddQ(&tovisit, ip->out());
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}
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if (matched)
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cond |= kMatchWins;
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for (int c = ip->lo(); c <= ip->hi(); c++) {
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int b = bytemap_[c];
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c = unbytemap_[b]; // last c in byte class
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uint32 act = node->action[b];
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uint32 newact = (nextindex << kIndexShift) | cond;
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if ((act & kImpossible) == kImpossible) {
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node->action[b] = newact;
|
|
} else if (act != newact) {
|
|
if (Debug) {
|
|
LOG(ERROR)
|
|
<< StringPrintf("Not OnePass: conflict on byte "
|
|
"%#x at state %d",
|
|
c, *it);
|
|
}
|
|
goto fail;
|
|
}
|
|
}
|
|
if (ip->foldcase()) {
|
|
Rune lo = max<Rune>(ip->lo(), 'a') + 'A' - 'a';
|
|
Rune hi = min<Rune>(ip->hi(), 'z') + 'A' - 'a';
|
|
for (int c = lo; c <= hi; c++) {
|
|
int b = bytemap_[c];
|
|
c = unbytemap_[b]; // last c in class
|
|
uint32 act = node->action[b];
|
|
uint32 newact = (nextindex << kIndexShift) | cond;
|
|
if ((act & kImpossible) == kImpossible) {
|
|
node->action[b] = newact;
|
|
} else if (act != newact) {
|
|
if (Debug) {
|
|
LOG(ERROR)
|
|
<< StringPrintf("Not OnePass: conflict on byte "
|
|
"%#x at state %d",
|
|
c, *it);
|
|
}
|
|
goto fail;
|
|
}
|
|
}
|
|
}
|
|
break;
|
|
}
|
|
|
|
case kInstCapture:
|
|
if (ip->cap() < kMaxCap)
|
|
cond |= (1 << kCapShift) << ip->cap();
|
|
goto QueueEmpty;
|
|
|
|
case kInstEmptyWidth:
|
|
cond |= ip->empty();
|
|
goto QueueEmpty;
|
|
|
|
case kInstNop:
|
|
QueueEmpty:
|
|
// kInstCapture and kInstNop always proceed to ip->out().
|
|
// kInstEmptyWidth only sometimes proceeds to ip->out(),
|
|
// but as a conservative approximation we assume it always does.
|
|
// We could be a little more precise by looking at what c
|
|
// is, but that seems like overkill.
|
|
|
|
// If already on work queue, (1) is violated: bail out.
|
|
if (!AddQ(&workq, ip->out())) {
|
|
if (Debug) {
|
|
LOG(ERROR) << StringPrintf("Not OnePass: multiple paths"
|
|
" %d -> %d\n",
|
|
*it, ip->out());
|
|
}
|
|
goto fail;
|
|
}
|
|
stack[nstack].id = ip->out();
|
|
stack[nstack++].cond = cond;
|
|
break;
|
|
|
|
case kInstMatch:
|
|
if (matched) {
|
|
// (3) is violated
|
|
if (Debug) {
|
|
LOG(ERROR) << StringPrintf("Not OnePass: multiple matches"
|
|
" from %d\n", *it);
|
|
}
|
|
goto fail;
|
|
}
|
|
matched = true;
|
|
node->matchcond = cond;
|
|
break;
|
|
|
|
case kInstFail:
|
|
break;
|
|
}
|
|
}
|
|
}
|
|
|
|
if (Debug) { // For debugging, dump one-pass NFA to LOG(ERROR).
|
|
string dump = "prog dump:\n" + Dump() + "node dump\n";
|
|
map<int, int> idmap;
|
|
for (int i = 0; i < size; i++)
|
|
if (nodebyid[i] != -1)
|
|
idmap[nodebyid[i]] = i;
|
|
|
|
StringAppendF(&dump, "byte ranges:\n");
|
|
int i = 0;
|
|
for (int b = 0; b < bytemap_range_; b++) {
|
|
int lo = i;
|
|
while (bytemap_[i] == b)
|
|
i++;
|
|
StringAppendF(&dump, "\t%d: %#x-%#x\n", b, lo, i - 1);
|
|
}
|
|
|
|
for (Instq::iterator it = tovisit.begin(); it != tovisit.end(); ++it) {
|
|
int id = *it;
|
|
int nodeindex = nodebyid[id];
|
|
if (nodeindex == -1)
|
|
continue;
|
|
OneState* node = IndexToNode(nodes, statesize, nodeindex);
|
|
string s;
|
|
StringAppendF(&dump, "node %d id=%d: matchcond=%#x\n",
|
|
nodeindex, id, node->matchcond);
|
|
for (int i = 0; i < bytemap_range_; i++) {
|
|
if ((node->action[i] & kImpossible) == kImpossible)
|
|
continue;
|
|
StringAppendF(&dump, " %d cond %#x -> %d id=%d\n",
|
|
i, node->action[i] & 0xFFFF,
|
|
node->action[i] >> kIndexShift,
|
|
idmap[node->action[i] >> kIndexShift]);
|
|
}
|
|
}
|
|
LOG(ERROR) << dump;
|
|
}
|
|
|
|
// Overallocated earlier; cut down to actual size.
|
|
nodep = new uint8[nalloc*statesize];
|
|
memmove(nodep, nodes, nalloc*statesize);
|
|
delete[] nodes;
|
|
nodes = nodep;
|
|
|
|
onepass_start_ = IndexToNode(nodes, statesize, nodebyid[start()]);
|
|
onepass_nodes_ = nodes;
|
|
onepass_statesize_ = statesize;
|
|
dfa_mem_ -= nalloc*statesize;
|
|
|
|
delete[] stack;
|
|
delete[] nodebyid;
|
|
return true;
|
|
|
|
fail:
|
|
delete[] stack;
|
|
delete[] nodebyid;
|
|
delete[] nodes;
|
|
return false;
|
|
}
|
|
|
|
} // namespace re2
|