ClickHouse/src/Functions/Regexps.h
Yatsishin Ilya 17bb938541 fix style
2021-08-23 13:59:01 +03:00

294 lines
10 KiB
C++

#pragma once
#include <map>
#include <memory>
#include <mutex>
#include <optional>
#include <string>
#include <utility>
#include <vector>
#include <Functions/likePatternToRegexp.h>
#include <Common/Exception.h>
#include <Common/ObjectPool.h>
#include <Common/OptimizedRegularExpression.h>
#include <Common/ProfileEvents.h>
#include <common/StringRef.h>
#if !defined(ARCADIA_BUILD)
# include "config_functions.h"
#endif
#if USE_HYPERSCAN
# include <hs.h>
#endif
namespace ProfileEvents
{
extern const Event RegexpCreated;
}
namespace DB
{
namespace ErrorCodes
{
extern const int CANNOT_ALLOCATE_MEMORY;
extern const int LOGICAL_ERROR;
extern const int BAD_ARGUMENTS;
}
namespace Regexps
{
using Regexp = OptimizedRegularExpressionImpl<false>;
using Pool = ObjectPoolMap<Regexp, String>;
template <bool like>
inline Regexp createRegexp(const std::string & pattern, int flags)
{
return {pattern, flags};
}
template <>
inline Regexp createRegexp<true>(const std::string & pattern, int flags)
{
return {likePatternToRegexp(pattern), flags};
}
/** Returns holder of an object from Pool.
* You must hold the ownership while using the object.
* In destructor, it returns the object back to the Pool for further reuse.
*/
template <bool like, bool no_capture, bool case_insensitive = false>
inline Pool::Pointer get(const std::string & pattern)
{
/// C++11 has thread-safe function-local static on most modern compilers.
static Pool known_regexps; /// Different variables for different pattern parameters.
return known_regexps.get(pattern, [&pattern]
{
int flags = OptimizedRegularExpression::RE_DOT_NL;
if (no_capture)
flags |= OptimizedRegularExpression::RE_NO_CAPTURE;
if (case_insensitive)
flags |= Regexps::Regexp::RE_CASELESS;
ProfileEvents::increment(ProfileEvents::RegexpCreated);
return new Regexp{createRegexp<like>(pattern, flags)};
});
}
}
#if USE_HYPERSCAN
namespace MultiRegexps
{
template <typename Deleter, Deleter deleter>
struct HyperscanDeleter
{
template <typename T>
void operator()(T * ptr) const
{
deleter(ptr);
}
};
/// Helper unique pointers to correctly delete the allocated space when hyperscan cannot compile something and we throw an exception.
using CompilerError = std::unique_ptr<hs_compile_error_t, HyperscanDeleter<decltype(&hs_free_compile_error), &hs_free_compile_error>>;
using ScratchPtr = std::unique_ptr<hs_scratch_t, HyperscanDeleter<decltype(&hs_free_scratch), &hs_free_scratch>>;
using DataBasePtr = std::unique_ptr<hs_database_t, HyperscanDeleter<decltype(&hs_free_database), &hs_free_database>>;
/// Database is thread safe across multiple threads and Scratch is not but we can copy it whenever we use it in the searcher.
class Regexps
{
public:
Regexps(hs_database_t * db_, hs_scratch_t * scratch_) : db{db_}, scratch{scratch_} { }
hs_database_t * getDB() const { return db.get(); }
hs_scratch_t * getScratch() const { return scratch.get(); }
private:
DataBasePtr db;
ScratchPtr scratch;
};
class RegexpsConstructor
{
public:
RegexpsConstructor() = default;
void setConstructor(std::function<Regexps()> constructor_) { constructor = std::move(constructor_); }
Regexps * operator()()
{
std::unique_lock lock(mutex);
if (regexp)
return &*regexp;
regexp = constructor();
return &*regexp;
}
private:
std::function<Regexps()> constructor;
std::optional<Regexps> regexp;
std::mutex mutex;
};
struct Pool
{
/// Mutex for finding in map.
std::mutex mutex;
/// Patterns + possible edit_distance to database and scratch.
std::map<std::pair<std::vector<String>, std::optional<UInt32>>, RegexpsConstructor> storage;
};
template <bool save_indices, bool CompileForEditDistance>
inline Regexps constructRegexps(const std::vector<String> & str_patterns, std::optional<UInt32> edit_distance)
{
(void)edit_distance;
/// Common pointers
std::vector<const char *> patterns;
std::vector<unsigned int> flags;
/// Pointer for external edit distance compilation
std::vector<hs_expr_ext> ext_exprs;
std::vector<const hs_expr_ext *> ext_exprs_ptrs;
patterns.reserve(str_patterns.size());
flags.reserve(str_patterns.size());
if constexpr (CompileForEditDistance)
{
ext_exprs.reserve(str_patterns.size());
ext_exprs_ptrs.reserve(str_patterns.size());
}
for (const StringRef ref : str_patterns)
{
patterns.push_back(ref.data);
/* Flags below are the pattern matching flags.
* HS_FLAG_DOTALL is a compile flag where matching a . will not exclude newlines. This is a good
* performance practice according to Hyperscan API. https://intel.github.io/hyperscan/dev-reference/performance.html#dot-all-mode
* HS_FLAG_ALLOWEMPTY is a compile flag where empty strings are allowed to match.
* HS_FLAG_UTF8 is a flag where UTF8 literals are matched.
* HS_FLAG_SINGLEMATCH is a compile flag where each pattern match will be returned only once. it is a good performance practice
* as it is said in the Hyperscan documentation. https://intel.github.io/hyperscan/dev-reference/performance.html#single-match-flag
*/
flags.push_back(HS_FLAG_DOTALL | HS_FLAG_SINGLEMATCH | HS_FLAG_ALLOWEMPTY | HS_FLAG_UTF8);
if constexpr (CompileForEditDistance)
{
/// Hyperscan currently does not support UTF8 matching with edit distance.
flags.back() &= ~HS_FLAG_UTF8;
ext_exprs.emplace_back();
/// HS_EXT_FLAG_EDIT_DISTANCE is a compile flag responsible for Levenstein distance.
ext_exprs.back().flags = HS_EXT_FLAG_EDIT_DISTANCE;
ext_exprs.back().edit_distance = edit_distance.value();
ext_exprs_ptrs.push_back(&ext_exprs.back());
}
}
hs_database_t * db = nullptr;
hs_compile_error_t * compile_error;
std::unique_ptr<unsigned int[]> ids;
/// We mark the patterns to provide the callback results.
if constexpr (save_indices)
{
ids.reset(new unsigned int[patterns.size()]);
for (size_t i = 0; i < patterns.size(); ++i)
ids[i] = i + 1;
}
hs_error_t err;
if constexpr (!CompileForEditDistance)
err = hs_compile_multi(
patterns.data(),
flags.data(),
ids.get(),
patterns.size(),
HS_MODE_BLOCK,
nullptr,
&db,
&compile_error);
else
err = hs_compile_ext_multi(
patterns.data(),
flags.data(),
ids.get(),
ext_exprs_ptrs.data(),
patterns.size(),
HS_MODE_BLOCK,
nullptr,
&db,
&compile_error);
if (err != HS_SUCCESS)
{
/// CompilerError is a unique_ptr, so correct memory free after the exception is thrown.
CompilerError error(compile_error);
if (error->expression < 0)
throw Exception(String(error->message), ErrorCodes::LOGICAL_ERROR);
else
throw Exception(
"Pattern '" + str_patterns[error->expression] + "' failed with error '" + String(error->message),
ErrorCodes::BAD_ARGUMENTS);
}
ProfileEvents::increment(ProfileEvents::RegexpCreated);
/// We allocate the scratch space only once, then copy it across multiple threads with hs_clone_scratch
/// function which is faster than allocating scratch space each time in each thread.
hs_scratch_t * scratch = nullptr;
err = hs_alloc_scratch(db, &scratch);
/// If not HS_SUCCESS, it is guaranteed that the memory would not be allocated for scratch.
if (err != HS_SUCCESS)
throw Exception("Could not allocate scratch space for hyperscan", ErrorCodes::CANNOT_ALLOCATE_MEMORY);
return Regexps{db, scratch};
}
/// If CompileForEditDistance is False, edit_distance must be nullopt
/// Also, we use templates here because each instantiation of function
/// template has its own copy of local static variables which must not be the same
/// for different hyperscan compilations.
template <bool save_indices, bool CompileForEditDistance>
inline Regexps * get(const std::vector<StringRef> & patterns, std::optional<UInt32> edit_distance)
{
/// C++11 has thread-safe function-local static on most modern compilers.
static Pool known_regexps; /// Different variables for different pattern parameters.
std::vector<String> str_patterns;
str_patterns.reserve(patterns.size());
for (const StringRef & ref : patterns)
str_patterns.push_back(ref.toString());
/// Get the lock for finding database.
std::unique_lock lock(known_regexps.mutex);
auto it = known_regexps.storage.find({str_patterns, edit_distance});
/// If not found, compile and let other threads wait.
if (known_regexps.storage.end() == it)
{
it = known_regexps.storage
.emplace(std::piecewise_construct, std::make_tuple(std::move(str_patterns), edit_distance), std::make_tuple())
.first;
it->second.setConstructor([&str_patterns = it->first.first, edit_distance]()
{
return constructRegexps<save_indices, CompileForEditDistance>(str_patterns, edit_distance);
});
}
/// Unlock before possible construction.
lock.unlock();
return it->second();
}
}
#endif // USE_HYPERSCAN
}