// Copyright 2006-2008 The RE2 Authors. All Rights Reserved.
// Use of this source code is governed by a BSD-style
// license that can be found in the LICENSE file.
#include "util/test.h"
#include "util/thread.h"
#include "re2/prog.h"
#include "re2/re2.h"
#include "re2/regexp.h"
#include "re2/testing/regexp_generator.h"
#include "re2/testing/string_generator.h"
DECLARE_bool(re2_dfa_bail_when_slow);
DEFINE_int32(size, 8, "log2(number of DFA nodes)");
DEFINE_int32(repeat, 2, "Repetition count.");
DEFINE_int32(threads, 4, "number of threads");
namespace re2 {
// Check that multithreaded access to DFA class works.
// Helper thread: builds entire DFA for prog.
class BuildThread : public Thread {
public:
BuildThread(Prog* prog) : prog_(prog) {}
virtual void Run() {
CHECK(prog_->BuildEntireDFA(Prog::kFirstMatch));
}
private:
Prog* prog_;
};
TEST(Multithreaded, BuildEntireDFA) {
// Create regexp with 2^FLAGS_size states in DFA.
string s = "a";
for (int i = 0; i < FLAGS_size; i++)
s += "[ab]";
s += "b";
// Check that single-threaded code works.
{
//LOG(INFO) << s;
Regexp* re = Regexp::Parse(s.c_str(), Regexp::LikePerl, NULL);
CHECK(re);
Prog* prog = re->CompileToProg(0);
CHECK(prog);
BuildThread* t = new BuildThread(prog);
t->SetJoinable(true);
t->Start();
t->Join();
delete t;
delete prog;
re->Decref();
}
// Build the DFA simultaneously in a bunch of threads.
for (int i = 0; i < FLAGS_repeat; i++) {
Regexp* re = Regexp::Parse(s.c_str(), Regexp::LikePerl, NULL);
CHECK(re);
Prog* prog = re->CompileToProg(0);
CHECK(prog);
vector<BuildThread*> threads;
for (int j = 0; j < FLAGS_threads; j++) {
BuildThread *t = new BuildThread(prog);
t->SetJoinable(true);
threads.push_back(t);
}
for (int j = 0; j < FLAGS_threads; j++)
threads[j]->Start();
for (int j = 0; j < FLAGS_threads; j++) {
threads[j]->Join();
delete threads[j];
}
// One more compile, to make sure everything is okay.
prog->BuildEntireDFA(Prog::kFirstMatch);
delete prog;
re->Decref();
}
}
// Check that DFA size requirements are followed.
// BuildEntireDFA will, like SearchDFA, stop building out
// the DFA once the memory limits are reached.
TEST(SingleThreaded, BuildEntireDFA) {
// Create regexp with 2^30 states in DFA.
string s = "a";
for (int i = 0; i < 30; i++)
s += "[ab]";
s += "b";
//LOG(INFO) << s;
Regexp* re = Regexp::Parse(s.c_str(), Regexp::LikePerl, NULL);
CHECK(re);
int max = 24;
for (int i = 17; i < max; i++) {
int limit = 1<<i;
int usage, progusage, dfamem;
{
testing::MallocCounter m(testing::MallocCounter::THIS_THREAD_ONLY);
Prog* prog = re->CompileToProg(limit);
CHECK(prog);
progusage = m.HeapGrowth();
dfamem = prog->dfa_mem();
prog->BuildEntireDFA(Prog::kFirstMatch);
prog->BuildEntireDFA(Prog::kLongestMatch);
usage = m.HeapGrowth();
delete prog;
}
if (!UsingMallocCounter)
continue;
//LOG(INFO) << StringPrintf("Limit %d: prog used %d, DFA budget %d, total %d\n",
// limit, progusage, dfamem, usage);
CHECK_GT(usage, limit*9/10);
CHECK_LT(usage, limit + (16<<10)); // 16kB of slop okay
}
re->Decref();
}
// Generates and returns a string over binary alphabet {0,1} that contains
// all possible binary sequences of length n as subsequences. The obvious
// brute force method would generate a string of length n * 2^n, but this
// generates a string of length n + 2^n - 1 called a De Bruijn cycle.
// See Knuth, The Art of Computer Programming, Vol 2, Exercise 3.2.2 #17.
// Such a string is useful for testing a DFA. If you have a DFA
// where distinct last n bytes implies distinct states, then running on a
// DeBruijn string causes the DFA to need to create a new state at every
// position in the input, never reusing any states until it gets to the
// end of the string. This is the worst possible case for DFA execution.
static string DeBruijnString(int n) {
CHECK_LT(n, 8*sizeof(int));
CHECK_GT(n, 0);
vector<bool> did(1<<n);
for (int i = 0; i < 1<<n; i++)
did[i] = false;
string s;
for (int i = 0; i < n-1; i++)
s.append("0");
int bits = 0;
int mask = (1<<n) - 1;
for (int i = 0; i < (1<<n); i++) {
bits <<= 1;
bits &= mask;
if (!did[bits|1]) {
bits |= 1;
s.append("1");
} else {
s.append("0");
}
CHECK(!did[bits]);
did[bits] = true;
}
return s;
}
// Test that the DFA gets the right result even if it runs
// out of memory during a search. The regular expression
// 0[01]{n}$ matches a binary string of 0s and 1s only if
// the (n+1)th-to-last character is a 0. Matching this in
// a single forward pass (as done by the DFA) requires
// keeping one bit for each of the last n+1 characters
// (whether each was a 0), or 2^(n+1) possible states.
// If we run this regexp to search in a string that contains
// every possible n-character binary string as a substring,
// then it will have to run through at least 2^n states.
// States are big data structures -- certainly more than 1 byte --
// so if the DFA can search correctly while staying within a
// 2^n byte limit, it must be handling out-of-memory conditions
// gracefully.
TEST(SingleThreaded, SearchDFA) {
// Choice of n is mostly arbitrary, except that:
// * making n too big makes the test run for too long.
// * making n too small makes the DFA refuse to run,
// because it has so little memory compared to the program size.
// Empirically, n = 18 is a good compromise between the two.
const int n = 18;
Regexp* re = Regexp::Parse(StringPrintf("0[01]{%d}$", n),
Regexp::LikePerl, NULL);
CHECK(re);
// The De Bruijn string for n ends with a 1 followed by n 0s in a row,
// which is not a match for 0[01]{n}$. Adding one more 0 is a match.
string no_match = DeBruijnString(n);
string match = no_match + "0";
// The De Bruijn string is the worst case input for this regexp.
// By default, the DFA will notice that it is flushing its cache
// too frequently and will bail out early, so that RE2 can use the
// NFA implementation instead. (The DFA loses its speed advantage
// if it can't get a good cache hit rate.)
// Tell the DFA to trudge along instead.
FLAGS_re2_dfa_bail_when_slow = false;
int64 usage;
int64 peak_usage;
{
testing::MallocCounter m(testing::MallocCounter::THIS_THREAD_ONLY);
Prog* prog = re->CompileToProg(1<<n);
CHECK(prog);
for (int i = 0; i < 10; i++) {
bool matched, failed = false;
matched = prog->SearchDFA(match, NULL,
Prog::kUnanchored, Prog::kFirstMatch,
NULL, &failed, NULL);
CHECK(!failed);
CHECK(matched);
matched = prog->SearchDFA(no_match, NULL,
Prog::kUnanchored, Prog::kFirstMatch,
NULL, &failed, NULL);
CHECK(!failed);
CHECK(!matched);
}
usage = m.HeapGrowth();
peak_usage = m.PeakHeapGrowth();
delete prog;
}
re->Decref();
if (!UsingMallocCounter)
return;
//LOG(INFO) << "usage " << usage << " " << peak_usage;
CHECK_LT(usage, 1<<n);
CHECK_LT(peak_usage, 1<<n);
}
// Helper thread: searches for match, which should match,
// and no_match, which should not.
class SearchThread : public Thread {
public:
SearchThread(Prog* prog, const StringPiece& match,
const StringPiece& no_match)
: prog_(prog), match_(match), no_match_(no_match) {}
virtual void Run() {
for (int i = 0; i < 2; i++) {
bool matched, failed = false;
matched = prog_->SearchDFA(match_, NULL,
Prog::kUnanchored, Prog::kFirstMatch,
NULL, &failed, NULL);
CHECK(!failed);
CHECK(matched);
matched = prog_->SearchDFA(no_match_, NULL,
Prog::kUnanchored, Prog::kFirstMatch,
NULL, &failed, NULL);
CHECK(!failed);
CHECK(!matched);
}
}
private:
Prog* prog_;
StringPiece match_;
StringPiece no_match_;
};
TEST(Multithreaded, SearchDFA) {
// Same as single-threaded test above.
const int n = 18;
Regexp* re = Regexp::Parse(StringPrintf("0[01]{%d}$", n),
Regexp::LikePerl, NULL);
CHECK(re);
string no_match = DeBruijnString(n);
string match = no_match + "0";
FLAGS_re2_dfa_bail_when_slow = false;
// Check that single-threaded code works.
{
Prog* prog = re->CompileToProg(1<<n);
CHECK(prog);
SearchThread* t = new SearchThread(prog, match, no_match);
t->SetJoinable(true);
t->Start();
t->Join();
delete t;
delete prog;
}
// Run the search simultaneously in a bunch of threads.
// Reuse same flags for Multithreaded.BuildDFA above.
for (int i = 0; i < FLAGS_repeat; i++) {
//LOG(INFO) << "Search " << i;
Prog* prog = re->CompileToProg(1<<n);
CHECK(prog);
vector<SearchThread*> threads;
for (int j = 0; j < FLAGS_threads; j++) {
SearchThread *t = new SearchThread(prog, match, no_match);
t->SetJoinable(true);
threads.push_back(t);
}
for (int j = 0; j < FLAGS_threads; j++)
threads[j]->Start();
for (int j = 0; j < FLAGS_threads; j++) {
threads[j]->Join();
delete threads[j];
}
delete prog;
}
re->Decref();
}
struct ReverseTest {
const char *regexp;
const char *text;
bool match;
};
// Test that reverse DFA handles anchored/unanchored correctly.
// It's in the DFA interface but not used by RE2.
ReverseTest reverse_tests[] = {
{ "\\A(a|b)", "abc", true },
{ "(a|b)\\z", "cba", true },
{ "\\A(a|b)", "cba", false },
{ "(a|b)\\z", "abc", false },
};
TEST(DFA, ReverseMatch) {
int nfail = 0;
for (int i = 0; i < arraysize(reverse_tests); i++) {
const ReverseTest& t = reverse_tests[i];
Regexp* re = Regexp::Parse(t.regexp, Regexp::LikePerl, NULL);
CHECK(re);
Prog *prog = re->CompileToReverseProg(0);
CHECK(prog);
bool failed = false;
bool matched = prog->SearchDFA(t.text, NULL, Prog::kUnanchored, Prog::kFirstMatch, NULL, &failed, NULL);
if (matched != t.match) {
LOG(ERROR) << t.regexp << " on " << t.text << ": want " << t.match;
nfail++;
}
delete prog;
re->Decref();
}
EXPECT_EQ(nfail, 0);
}
} // namespace re2