ClickHouse/dbms/src/Functions/FunctionsStringSearch.cpp

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#include <Functions/FunctionsStringSearch.h>
#include <memory>
#include <mutex>
#include <Poco/UTF8String.h>
#include <Columns/ColumnFixedString.h>
#include <Common/Volnitsky.h>
#include <DataTypes/DataTypeFixedString.h>
#include <Functions/FunctionFactory.h>
#include <Functions/Regexps.h>
#include <IO/WriteHelpers.h>
#include <Common/config.h>
#include <re2/re2.h>
#include <re2/stringpiece.h>
#if USE_RE2_ST
#include <re2_st/re2.h>
#else
#define re2_st re2
#endif
namespace DB
{
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namespace ErrorCodes
{
extern const int BAD_ARGUMENTS;
}
/** Implementation details for functions of 'position' family depending on ASCII/UTF8 and case sensitiveness.
*/
struct PositionCaseSensitiveASCII
{
/// For searching single substring inside big-enough contiguous chunk of data. Coluld have slightly expensive initialization.
using SearcherInBigHaystack = VolnitskyImpl<true, true>;
/// For searching single substring, that is different each time. This object is created for each row of data. It must have cheap initialization.
using SearcherInSmallHaystack = LibCASCIICaseSensitiveStringSearcher;
static SearcherInBigHaystack createSearcherInBigHaystack(const char * needle_data, size_t needle_size, size_t haystack_size_hint)
{
return SearcherInBigHaystack(needle_data, needle_size, haystack_size_hint);
}
static SearcherInSmallHaystack createSearcherInSmallHaystack(const char * needle_data, size_t needle_size)
{
return SearcherInSmallHaystack(needle_data, needle_size);
}
/// Number of code points between 'begin' and 'end' (this has different behaviour for ASCII and UTF-8).
static size_t countChars(const char * begin, const char * end)
{
return end - begin;
}
/// Convert string to lowercase. Only for case-insensitive search.
/// Implementation is permitted to be inefficient because it is called for single string.
static void toLowerIfNeed(std::string & s)
{
}
};
struct PositionCaseInsensitiveASCII
{
/// `Volnitsky` is not used here, because one person has measured that this is better. It will be good if you question it.
using SearcherInBigHaystack = ASCIICaseInsensitiveStringSearcher;
using SearcherInSmallHaystack = LibCASCIICaseInsensitiveStringSearcher;
static SearcherInBigHaystack createSearcherInBigHaystack(const char * needle_data, size_t needle_size, size_t haystack_size_hint)
{
return SearcherInBigHaystack(needle_data, needle_size);
}
static SearcherInSmallHaystack createSearcherInSmallHaystack(const char * needle_data, size_t needle_size)
{
return SearcherInSmallHaystack(needle_data, needle_size);
}
static size_t countChars(const char * begin, const char * end)
{
return end - begin;
}
static void toLowerIfNeed(std::string & s)
{
std::transform(std::begin(s), std::end(s), std::begin(s), tolower);
}
};
struct PositionCaseSensitiveUTF8
{
using SearcherInBigHaystack = VolnitskyImpl<true, false>;
using SearcherInSmallHaystack = LibCASCIICaseSensitiveStringSearcher;
static SearcherInBigHaystack createSearcherInBigHaystack(const char * needle_data, size_t needle_size, size_t haystack_size_hint)
{
return SearcherInBigHaystack(needle_data, needle_size, haystack_size_hint);
}
static SearcherInSmallHaystack createSearcherInSmallHaystack(const char * needle_data, size_t needle_size)
{
return SearcherInSmallHaystack(needle_data, needle_size);
}
static size_t countChars(const char * begin, const char * end)
{
size_t res = 0;
for (auto it = begin; it != end; ++it)
if (!UTF8::isContinuationOctet(static_cast<UInt8>(*it)))
++res;
return res;
}
static void toLowerIfNeed(std::string & s)
{
}
};
struct PositionCaseInsensitiveUTF8
{
using SearcherInBigHaystack = VolnitskyImpl<false, false>;
using SearcherInSmallHaystack = UTF8CaseInsensitiveStringSearcher; /// TODO Very suboptimal.
static SearcherInBigHaystack createSearcherInBigHaystack(const char * needle_data, size_t needle_size, size_t haystack_size_hint)
{
return SearcherInBigHaystack(needle_data, needle_size, haystack_size_hint);
}
static SearcherInSmallHaystack createSearcherInSmallHaystack(const char * needle_data, size_t needle_size)
{
return SearcherInSmallHaystack(needle_data, needle_size);
}
static size_t countChars(const char * begin, const char * end)
{
size_t res = 0;
for (auto it = begin; it != end; ++it)
if (!UTF8::isContinuationOctet(static_cast<UInt8>(*it)))
++res;
return res;
}
static void toLowerIfNeed(std::string & s)
{
Poco::UTF8::toLowerInPlace(s);
}
};
template <typename Impl>
struct PositionImpl
{
using ResultType = UInt64;
/// Find one substring in many strings.
static void vector_constant(const ColumnString::Chars_t & data,
const ColumnString::Offsets_t & offsets,
const std::string & needle,
PaddedPODArray<UInt64> & res)
{
const UInt8 * begin = &data[0];
const UInt8 * pos = begin;
const UInt8 * end = pos + data.size();
/// Current index in the array of strings.
size_t i = 0;
typename Impl::SearcherInBigHaystack searcher = Impl::createSearcherInBigHaystack(needle.data(), needle.size(), end - pos);
/// We will search for the next occurrence in all strings at once.
while (pos < end && end != (pos = searcher.search(pos, end - pos)))
{
/// Determine which index it refers to.
while (begin + offsets[i] <= pos)
{
res[i] = 0;
++i;
}
/// We check that the entry does not pass through the boundaries of strings.
if (pos + needle.size() < begin + offsets[i])
{
size_t prev_offset = i != 0 ? offsets[i - 1] : 0;
res[i] = 1 + Impl::countChars(reinterpret_cast<const char *>(begin + prev_offset), reinterpret_cast<const char *>(pos));
}
else
res[i] = 0;
pos = begin + offsets[i];
++i;
}
memset(&res[i], 0, (res.size() - i) * sizeof(res[0]));
}
/// Search for substring in string.
static void constant_constant(std::string data, std::string needle, UInt64 & res)
{
Impl::toLowerIfNeed(data);
Impl::toLowerIfNeed(needle);
res = data.find(needle);
if (res == std::string::npos)
res = 0;
else
res = 1 + Impl::countChars(data.data(), data.data() + res);
}
/// Search each time for a different single substring inside each time different string.
static void vector_vector(const ColumnString::Chars_t & haystack_data,
const ColumnString::Offsets_t & haystack_offsets,
const ColumnString::Chars_t & needle_data,
const ColumnString::Offsets_t & needle_offsets,
PaddedPODArray<UInt64> & res)
{
ColumnString::Offset_t prev_haystack_offset = 0;
ColumnString::Offset_t prev_needle_offset = 0;
size_t size = haystack_offsets.size();
for (size_t i = 0; i < size; ++i)
{
size_t needle_size = needle_offsets[i] - prev_needle_offset - 1;
size_t haystack_size = haystack_offsets[i] - prev_haystack_offset - 1;
if (0 == needle_size)
{
/// An empty string is always at the very beginning of `haystack`.
res[i] = 1;
}
else
{
/// It is assumed that the StringSearcher is not very difficult to initialize.
typename Impl::SearcherInSmallHaystack searcher
= Impl::createSearcherInSmallHaystack(reinterpret_cast<const char *>(&needle_data[prev_needle_offset]),
needle_offsets[i] - prev_needle_offset - 1); /// zero byte at the end
/// searcher returns a pointer to the found substring or to the end of `haystack`.
size_t pos = searcher.search(&haystack_data[prev_haystack_offset], &haystack_data[haystack_offsets[i] - 1])
- &haystack_data[prev_haystack_offset];
if (pos != haystack_size)
{
res[i] = 1 + Impl::countChars(reinterpret_cast<const char *>(&haystack_data[prev_haystack_offset]),
reinterpret_cast<const char *>(&haystack_data[prev_haystack_offset + pos]));
}
else
res[i] = 0;
}
prev_haystack_offset = haystack_offsets[i];
prev_needle_offset = needle_offsets[i];
}
}
/// Find many substrings in one line.
static void constant_vector(const String & haystack,
const ColumnString::Chars_t & needle_data,
const ColumnString::Offsets_t & needle_offsets,
PaddedPODArray<UInt64> & res)
{
// NOTE You could use haystack indexing. But this is a rare case.
ColumnString::Offset_t prev_needle_offset = 0;
size_t size = needle_offsets.size();
for (size_t i = 0; i < size; ++i)
{
size_t needle_size = needle_offsets[i] - prev_needle_offset - 1;
if (0 == needle_size)
{
res[i] = 1;
}
else
{
typename Impl::SearcherInSmallHaystack searcher = Impl::createSearcherInSmallHaystack(
reinterpret_cast<const char *>(&needle_data[prev_needle_offset]), needle_offsets[i] - prev_needle_offset - 1);
size_t pos = searcher.search(reinterpret_cast<const UInt8 *>(haystack.data()),
reinterpret_cast<const UInt8 *>(haystack.data()) + haystack.size())
- reinterpret_cast<const UInt8 *>(haystack.data());
if (pos != haystack.size())
{
res[i] = 1 + Impl::countChars(haystack.data(), haystack.data() + pos);
}
else
res[i] = 0;
}
prev_needle_offset = needle_offsets[i];
}
}
};
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/// Is the LIKE expression reduced to finding a substring in a string?
inline bool likePatternIsStrstr(const String & pattern, String & res)
{
res = "";
if (pattern.size() < 2 || pattern.front() != '%' || pattern.back() != '%')
return false;
res.reserve(pattern.size() * 2);
const char * pos = pattern.data();
const char * end = pos + pattern.size();
++pos;
--end;
while (pos < end)
{
switch (*pos)
{
case '%':
case '_':
return false;
case '\\':
++pos;
if (pos == end)
return false;
else
res += *pos;
break;
default:
res += *pos;
break;
}
++pos;
}
return true;
}
/** 'like' - if true, treat pattern as SQL LIKE; if false - treat pattern as re2 regexp.
* NOTE: We want to run regexp search for whole block by one call (as implemented in function 'position')
* but for that, regexp engine must support \0 bytes and their interpretation as string boundaries.
*/
template <bool like, bool revert = false>
struct MatchImpl
{
using ResultType = UInt8;
static void vector_constant(const ColumnString::Chars_t & data,
const ColumnString::Offsets_t & offsets,
const std::string & pattern,
PaddedPODArray<UInt8> & res)
{
String strstr_pattern;
/// A simple case where the LIKE expression reduces to finding a substring in a string
if (like && likePatternIsStrstr(pattern, strstr_pattern))
{
const UInt8 * begin = &data[0];
const UInt8 * pos = begin;
const UInt8 * end = pos + data.size();
/// The current index in the array of strings.
size_t i = 0;
/// TODO You need to make that `searcher` is common to all the calls of the function.
Volnitsky searcher(strstr_pattern.data(), strstr_pattern.size(), end - pos);
/// We will search for the next occurrence in all rows at once.
while (pos < end && end != (pos = searcher.search(pos, end - pos)))
{
/// Let's determine which index it refers to.
while (begin + offsets[i] <= pos)
{
res[i] = revert;
++i;
}
/// We check that the entry does not pass through the boundaries of strings.
if (pos + strstr_pattern.size() < begin + offsets[i])
res[i] = !revert;
else
res[i] = revert;
pos = begin + offsets[i];
++i;
}
/// Tail, in which there can be no substring.
memset(&res[i], revert, (res.size() - i) * sizeof(res[0]));
}
else
{
size_t size = offsets.size();
const auto & regexp = Regexps::get<like, true>(pattern);
std::string required_substring;
bool is_trivial;
bool required_substring_is_prefix; /// for `anchored` execution of the regexp.
regexp->getAnalyzeResult(required_substring, is_trivial, required_substring_is_prefix);
if (required_substring.empty())
{
if (!regexp->getRE2()) /// An empty regexp. Always matches.
{
memset(&res[0], 1, size * sizeof(res[0]));
}
else
{
size_t prev_offset = 0;
for (size_t i = 0; i < size; ++i)
{
res[i] = revert
^ regexp->getRE2()->Match(
re2_st::StringPiece(reinterpret_cast<const char *>(&data[prev_offset]), offsets[i] - prev_offset - 1),
0,
offsets[i] - prev_offset - 1,
re2_st::RE2::UNANCHORED,
nullptr,
0);
prev_offset = offsets[i];
}
}
}
else
{
/// NOTE This almost matches with the case of LikePatternIsStrstr.
const UInt8 * begin = &data[0];
const UInt8 * pos = begin;
const UInt8 * end = pos + data.size();
/// The current index in the array of strings.
size_t i = 0;
Volnitsky searcher(required_substring.data(), required_substring.size(), end - pos);
/// We will search for the next occurrence in all rows at once.
while (pos < end && end != (pos = searcher.search(pos, end - pos)))
{
/// Determine which index it refers to.
while (begin + offsets[i] <= pos)
{
res[i] = revert;
++i;
}
/// We check that the entry does not pass through the boundaries of strings.
if (pos + strstr_pattern.size() < begin + offsets[i])
{
/// And if it does not, if necessary, we check the regexp.
if (is_trivial)
res[i] = !revert;
else
{
const char * str_data = reinterpret_cast<const char *>(&data[i != 0 ? offsets[i - 1] : 0]);
size_t str_size = (i != 0 ? offsets[i] - offsets[i - 1] : offsets[0]) - 1;
/** Even in the case of `required_substring_is_prefix` use UNANCHORED check for regexp,
* so that it can match when `required_substring` occurs into the line several times,
* and at the first occurrence, the regexp is not a match.
*/
if (required_substring_is_prefix)
res[i] = revert
^ regexp->getRE2()->Match(re2_st::StringPiece(str_data, str_size),
reinterpret_cast<const char *>(pos) - str_data,
str_size,
re2_st::RE2::UNANCHORED,
nullptr,
0);
else
res[i] = revert
^ regexp->getRE2()->Match(
re2_st::StringPiece(str_data, str_size), 0, str_size, re2_st::RE2::UNANCHORED, nullptr, 0);
}
}
else
res[i] = revert;
pos = begin + offsets[i];
++i;
}
memset(&res[i], revert, (res.size() - i) * sizeof(res[0]));
}
}
}
static void constant_constant(const std::string & data, const std::string & pattern, UInt8 & res)
{
const auto & regexp = Regexps::get<like, true>(pattern);
res = revert ^ regexp->match(data);
}
static void vector_vector(const ColumnString::Chars_t & haystack_data,
const ColumnString::Offsets_t & haystack_offsets,
const ColumnString::Chars_t & needle_data,
const ColumnString::Offsets_t & needle_offsets,
PaddedPODArray<UInt8> & res)
{
throw Exception("Functions 'like' and 'match' doesn't support non-constant needle argument", ErrorCodes::ILLEGAL_COLUMN);
}
/// Search different needles in single haystack.
static void constant_vector(const String & haystack,
const ColumnString::Chars_t & needle_data,
const ColumnString::Offsets_t & needle_offsets,
PaddedPODArray<UInt8> & res)
{
throw Exception("Functions 'like' and 'match' doesn't support non-constant needle argument", ErrorCodes::ILLEGAL_COLUMN);
}
};
struct ExtractImpl
{
static void vector(const ColumnString::Chars_t & data,
const ColumnString::Offsets_t & offsets,
const std::string & pattern,
ColumnString::Chars_t & res_data,
ColumnString::Offsets_t & res_offsets)
{
res_data.reserve(data.size() / 5);
res_offsets.resize(offsets.size());
const auto & regexp = Regexps::get<false, false>(pattern);
unsigned capture = regexp->getNumberOfSubpatterns() > 0 ? 1 : 0;
OptimizedRegularExpression::MatchVec matches;
matches.reserve(capture + 1);
size_t prev_offset = 0;
size_t res_offset = 0;
for (size_t i = 0; i < offsets.size(); ++i)
{
size_t cur_offset = offsets[i];
unsigned count
= regexp->match(reinterpret_cast<const char *>(&data[prev_offset]), cur_offset - prev_offset - 1, matches, capture + 1);
if (count > capture && matches[capture].offset != std::string::npos)
{
const auto & match = matches[capture];
res_data.resize(res_offset + match.length + 1);
memcpySmallAllowReadWriteOverflow15(&res_data[res_offset], &data[prev_offset + match.offset], match.length);
res_offset += match.length;
}
else
{
res_data.resize(res_offset + 1);
}
res_data[res_offset] = 0;
++res_offset;
res_offsets[i] = res_offset;
prev_offset = cur_offset;
}
}
};
/** Replace all matches of regexp 'needle' to string 'replacement'. 'needle' and 'replacement' are constants.
* 'replacement' could contain substitutions, for example: '\2-\3-\1'
*/
template <bool replace_one = false>
struct ReplaceRegexpImpl
{
/// Sequence of instructions, describing how to get resulting string.
/// Each element is either:
/// - substitution (in that case first element of pair is their number and second element is empty)
/// - string that need to be inserted (in that case, first element of pair is that string and second element is -1)
using Instructions = std::vector<std::pair<int, std::string>>;
static const size_t max_captures = 10;
static Instructions createInstructions(const std::string & s, int num_captures)
{
Instructions instructions;
String now = "";
for (size_t i = 0; i < s.size(); ++i)
{
if (s[i] == '\\' && i + 1 < s.size())
{
if (isdigit(s[i + 1])) /// Substitution
{
if (!now.empty())
{
instructions.emplace_back(-1, now);
now = "";
}
instructions.emplace_back(s[i + 1] - '0', String());
}
else
now += s[i + 1]; /// Escaping
++i;
}
else
now += s[i]; /// Plain character
}
if (!now.empty())
{
instructions.emplace_back(-1, now);
now = "";
}
for (const auto & it : instructions)
if (it.first >= num_captures)
throw Exception("Invalid replace instruction in replacement string. Id: " + toString(it.first) + ", but regexp has only "
+ toString(num_captures - 1)
+ " subpatterns",
ErrorCodes::BAD_ARGUMENTS);
return instructions;
}
static void processString(const re2_st::StringPiece & input,
ColumnString::Chars_t & res_data,
ColumnString::Offset_t & res_offset,
re2_st::RE2 & searcher,
int num_captures,
const Instructions & instructions)
{
re2_st::StringPiece matches[max_captures];
int start_pos = 0;
while (start_pos < input.length())
{
/// If no more replacements possible for current string
bool can_finish_current_string = false;
if (searcher.Match(input, start_pos, input.length(), re2_st::RE2::Anchor::UNANCHORED, matches, num_captures))
{
const auto & match = matches[0];
size_t bytes_to_copy = (match.data() - input.data()) - start_pos;
/// Copy prefix before matched regexp without modification
res_data.resize(res_data.size() + bytes_to_copy);
memcpySmallAllowReadWriteOverflow15(&res_data[res_offset], input.data() + start_pos, bytes_to_copy);
res_offset += bytes_to_copy;
start_pos += bytes_to_copy + match.length();
/// Do substitution instructions
for (const auto & it : instructions)
{
if (it.first >= 0)
{
res_data.resize(res_data.size() + matches[it.first].length());
memcpy(&res_data[res_offset], matches[it.first].data(), matches[it.first].length());
res_offset += matches[it.first].length();
}
else
{
res_data.resize(res_data.size() + it.second.size());
memcpy(&res_data[res_offset], it.second.data(), it.second.size());
res_offset += it.second.size();
}
}
if (replace_one || match.length() == 0) /// Stop after match of zero length, to avoid infinite loop.
can_finish_current_string = true;
}
else
can_finish_current_string = true;
/// If ready, append suffix after match to end of string.
if (can_finish_current_string)
{
res_data.resize(res_data.size() + input.length() - start_pos);
memcpySmallAllowReadWriteOverflow15(&res_data[res_offset], input.data() + start_pos, input.length() - start_pos);
res_offset += input.length() - start_pos;
start_pos = input.length();
}
}
res_data.resize(res_data.size() + 1);
res_data[res_offset] = 0;
++res_offset;
}
static void vector(const ColumnString::Chars_t & data,
const ColumnString::Offsets_t & offsets,
const std::string & needle,
const std::string & replacement,
ColumnString::Chars_t & res_data,
ColumnString::Offsets_t & res_offsets)
{
ColumnString::Offset_t res_offset = 0;
res_data.reserve(data.size());
size_t size = offsets.size();
res_offsets.resize(size);
re2_st::RE2 searcher(needle);
int num_captures = std::min(searcher.NumberOfCapturingGroups() + 1, static_cast<int>(max_captures));
Instructions instructions = createInstructions(replacement, num_captures);
/// Cannot perform search for whole block. Will process each string separately.
for (size_t i = 0; i < size; ++i)
{
int from = i > 0 ? offsets[i - 1] : 0;
re2_st::StringPiece input(reinterpret_cast<const char *>(&data[0] + from), offsets[i] - from - 1);
processString(input, res_data, res_offset, searcher, num_captures, instructions);
res_offsets[i] = res_offset;
}
}
static void vector_fixed(const ColumnString::Chars_t & data,
size_t n,
const std::string & needle,
const std::string & replacement,
ColumnString::Chars_t & res_data,
ColumnString::Offsets_t & res_offsets)
{
ColumnString::Offset_t res_offset = 0;
size_t size = data.size() / n;
res_data.reserve(data.size());
res_offsets.resize(size);
re2_st::RE2 searcher(needle);
int num_captures = std::min(searcher.NumberOfCapturingGroups() + 1, static_cast<int>(max_captures));
Instructions instructions = createInstructions(replacement, num_captures);
for (size_t i = 0; i < size; ++i)
{
int from = i * n;
re2_st::StringPiece input(reinterpret_cast<const char *>(&data[0] + from), n);
processString(input, res_data, res_offset, searcher, num_captures, instructions);
res_offsets[i] = res_offset;
}
}
static void constant(const std::string & data, const std::string & needle, const std::string & replacement, std::string & res_data)
{
ColumnString src;
ColumnString dst;
src.insert(data);
vector(src.getChars(), src.getOffsets(), needle, replacement, dst.getChars(), dst.getOffsets());
res_data = dst[0].safeGet<String>();
}
};
/** Replace one or all occurencies of substring 'needle' to 'replacement'. 'needle' and 'replacement' are constants.
*/
template <bool replace_one = false>
struct ReplaceStringImpl
{
static void vector(const ColumnString::Chars_t & data,
const ColumnString::Offsets_t & offsets,
const std::string & needle,
const std::string & replacement,
ColumnString::Chars_t & res_data,
ColumnString::Offsets_t & res_offsets)
{
const UInt8 * begin = &data[0];
const UInt8 * pos = begin;
const UInt8 * end = pos + data.size();
ColumnString::Offset_t res_offset = 0;
res_data.reserve(data.size());
size_t size = offsets.size();
res_offsets.resize(size);
/// The current index in the array of strings.
size_t i = 0;
Volnitsky searcher(needle.data(), needle.size(), end - pos);
/// We will search for the next occurrence in all rows at once.
while (pos < end)
{
const UInt8 * match = searcher.search(pos, end - pos);
/// Copy the data without changing
res_data.resize(res_data.size() + (match - pos));
memcpy(&res_data[res_offset], pos, match - pos);
/// Determine which index it belongs to.
while (i < offsets.size() && begin + offsets[i] <= match)
{
res_offsets[i] = res_offset + ((begin + offsets[i]) - pos);
++i;
}
res_offset += (match - pos);
/// If you have reached the end, it's time to stop
if (i == offsets.size())
break;
/// Is it true that this line no longer needs to perform transformations.
bool can_finish_current_string = false;
/// We check that the entry does not go through the boundaries of strings.
if (match + needle.size() < begin + offsets[i])
{
res_data.resize(res_data.size() + replacement.size());
memcpy(&res_data[res_offset], replacement.data(), replacement.size());
res_offset += replacement.size();
pos = match + needle.size();
if (replace_one)
can_finish_current_string = true;
}
else
{
pos = match;
can_finish_current_string = true;
}
if (can_finish_current_string)
{
res_data.resize(res_data.size() + (begin + offsets[i] - pos));
memcpy(&res_data[res_offset], pos, (begin + offsets[i] - pos));
res_offset += (begin + offsets[i] - pos);
res_offsets[i] = res_offset;
pos = begin + offsets[i];
++i;
}
}
}
static void vector_fixed(const ColumnString::Chars_t & data,
size_t n,
const std::string & needle,
const std::string & replacement,
ColumnString::Chars_t & res_data,
ColumnString::Offsets_t & res_offsets)
{
const UInt8 * begin = &data[0];
const UInt8 * pos = begin;
const UInt8 * end = pos + data.size();
ColumnString::Offset_t res_offset = 0;
size_t size = data.size() / n;
res_data.reserve(data.size());
res_offsets.resize(size);
/// The current index in the string array.
size_t i = 0;
Volnitsky searcher(needle.data(), needle.size(), end - pos);
/// We will search for the next occurrence in all rows at once.
while (pos < end)
{
const UInt8 * match = searcher.search(pos, end - pos);
/// Copy the data without changing
res_data.resize(res_data.size() + (match - pos));
memcpy(&res_data[res_offset], pos, match - pos);
/// Let's determine which index it belongs to.
while (i < size && begin + n * (i + 1) <= match)
{
res_offsets[i] = res_offset + ((begin + n * (i + 1)) - pos) + 1;
++i;
}
res_offset += (match - pos);
/// If you have reached the end, it's time to stop
if (i == size)
break;
/// Is it true that this line no longer needs to perform conversions.
bool can_finish_current_string = false;
/// We check that the entry does not pass through the boundaries of strings.
if (match + needle.size() - 1 < begin + n * (i + 1))
{
res_data.resize(res_data.size() + replacement.size());
memcpy(&res_data[res_offset], replacement.data(), replacement.size());
res_offset += replacement.size();
pos = match + needle.size();
if (replace_one)
can_finish_current_string = true;
}
else
{
pos = match;
can_finish_current_string = true;
}
if (can_finish_current_string)
{
res_data.resize(res_data.size() + (begin + n * (i + 1) - pos));
memcpy(&res_data[res_offset], pos, (begin + n * (i + 1) - pos));
res_offset += (begin + n * (i + 1) - pos);
res_offsets[i] = res_offset;
pos = begin + n * (i + 1);
}
}
if (i < size)
{
res_offsets[i] = res_offset + ((begin + n * (i + 1)) - pos) + 1;
}
}
static void constant(const std::string & data, const std::string & needle, const std::string & replacement, std::string & res_data)
{
res_data = "";
int replace_cnt = 0;
for (size_t i = 0; i < data.size(); ++i)
{
bool match = true;
if (i + needle.size() > data.size() || (replace_one && replace_cnt > 0))
match = false;
for (size_t j = 0; match && j < needle.size(); ++j)
if (data[i + j] != needle[j])
match = false;
if (match)
{
++replace_cnt;
res_data += replacement;
i = i + needle.size() - 1;
}
else
res_data += data[i];
}
}
};
template <typename Impl, typename Name>
class FunctionStringReplace : public IFunction
{
public:
static constexpr auto name = Name::name;
static FunctionPtr create(const Context & context)
{
return std::make_shared<FunctionStringReplace>();
}
String getName() const override
{
return name;
}
size_t getNumberOfArguments() const override
{
return 3;
}
DataTypePtr getReturnTypeImpl(const DataTypes & arguments) const override
{
if (!typeid_cast<const DataTypeString *>(&*arguments[0]) && !typeid_cast<const DataTypeFixedString *>(&*arguments[0]))
throw Exception("Illegal type " + arguments[0]->getName() + " of first argument of function " + getName(),
ErrorCodes::ILLEGAL_TYPE_OF_ARGUMENT);
if (!typeid_cast<const DataTypeString *>(&*arguments[1]) && !typeid_cast<const DataTypeFixedString *>(&*arguments[1]))
throw Exception("Illegal type " + arguments[1]->getName() + " of second argument of function " + getName(),
ErrorCodes::ILLEGAL_TYPE_OF_ARGUMENT);
if (!typeid_cast<const DataTypeString *>(&*arguments[2]) && !typeid_cast<const DataTypeFixedString *>(&*arguments[2]))
throw Exception("Illegal type " + arguments[2]->getName() + " of third argument of function " + getName(),
ErrorCodes::ILLEGAL_TYPE_OF_ARGUMENT);
return std::make_shared<DataTypeString>();
}
void executeImpl(Block & block, const ColumnNumbers & arguments, size_t result) override
{
const ColumnPtr column_src = block.safeGetByPosition(arguments[0]).column;
const ColumnPtr column_needle = block.safeGetByPosition(arguments[1]).column;
const ColumnPtr column_replacement = block.safeGetByPosition(arguments[2]).column;
if (!column_needle->isConst() || !column_replacement->isConst())
throw Exception("2nd and 3rd arguments of function " + getName() + " must be constants.");
const IColumn * c1 = block.safeGetByPosition(arguments[1]).column.get();
const IColumn * c2 = block.safeGetByPosition(arguments[2]).column.get();
const ColumnConstString * c1_const = typeid_cast<const ColumnConstString *>(c1);
const ColumnConstString * c2_const = typeid_cast<const ColumnConstString *>(c2);
String needle = c1_const->getData();
String replacement = c2_const->getData();
if (needle.size() == 0)
throw Exception("Length of the second argument of function replace must be greater than 0.", ErrorCodes::ARGUMENT_OUT_OF_BOUND);
if (const ColumnString * col = typeid_cast<const ColumnString *>(&*column_src))
{
std::shared_ptr<ColumnString> col_res = std::make_shared<ColumnString>();
block.safeGetByPosition(result).column = col_res;
Impl::vector(col->getChars(), col->getOffsets(), needle, replacement, col_res->getChars(), col_res->getOffsets());
}
else if (const ColumnFixedString * col = typeid_cast<const ColumnFixedString *>(&*column_src))
{
std::shared_ptr<ColumnString> col_res = std::make_shared<ColumnString>();
block.safeGetByPosition(result).column = col_res;
Impl::vector_fixed(col->getChars(), col->getN(), needle, replacement, col_res->getChars(), col_res->getOffsets());
}
else if (const ColumnConstString * col = typeid_cast<const ColumnConstString *>(&*column_src))
{
String res;
Impl::constant(col->getData(), needle, replacement, res);
auto col_res = std::make_shared<ColumnConstString>(col->size(), res);
block.safeGetByPosition(result).column = col_res;
}
else
throw Exception(
"Illegal column " + block.safeGetByPosition(arguments[0]).column->getName() + " of first argument of function " + getName(),
ErrorCodes::ILLEGAL_COLUMN);
}
};
struct NamePosition
{
static constexpr auto name = "position";
};
struct NamePositionUTF8
{
static constexpr auto name = "positionUTF8";
};
struct NamePositionCaseInsensitive
{
static constexpr auto name = "positionCaseInsensitive";
};
struct NamePositionCaseInsensitiveUTF8
{
static constexpr auto name = "positionCaseInsensitiveUTF8";
};
struct NameMatch
{
static constexpr auto name = "match";
};
struct NameLike
{
static constexpr auto name = "like";
};
struct NameNotLike
{
static constexpr auto name = "notLike";
};
struct NameExtract
{
static constexpr auto name = "extract";
};
struct NameReplaceOne
{
static constexpr auto name = "replaceOne";
};
struct NameReplaceAll
{
static constexpr auto name = "replaceAll";
};
struct NameReplaceRegexpOne
{
static constexpr auto name = "replaceRegexpOne";
};
struct NameReplaceRegexpAll
{
static constexpr auto name = "replaceRegexpAll";
};
using FunctionPosition = FunctionsStringSearch<PositionImpl<PositionCaseSensitiveASCII>, NamePosition>;
using FunctionPositionUTF8 = FunctionsStringSearch<PositionImpl<PositionCaseSensitiveUTF8>, NamePositionUTF8>;
using FunctionPositionCaseInsensitive = FunctionsStringSearch<PositionImpl<PositionCaseInsensitiveASCII>, NamePositionCaseInsensitive>;
using FunctionPositionCaseInsensitiveUTF8
= FunctionsStringSearch<PositionImpl<PositionCaseInsensitiveUTF8>, NamePositionCaseInsensitiveUTF8>;
using FunctionMatch = FunctionsStringSearch<MatchImpl<false>, NameMatch>;
using FunctionLike = FunctionsStringSearch<MatchImpl<true>, NameLike>;
using FunctionNotLike = FunctionsStringSearch<MatchImpl<true, true>, NameNotLike>;
using FunctionExtract = FunctionsStringSearchToString<ExtractImpl, NameExtract>;
using FunctionReplaceOne = FunctionStringReplace<ReplaceStringImpl<true>, NameReplaceOne>;
using FunctionReplaceAll = FunctionStringReplace<ReplaceStringImpl<false>, NameReplaceAll>;
using FunctionReplaceRegexpOne = FunctionStringReplace<ReplaceRegexpImpl<true>, NameReplaceRegexpOne>;
using FunctionReplaceRegexpAll = FunctionStringReplace<ReplaceRegexpImpl<false>, NameReplaceRegexpAll>;
void registerFunctionsStringSearch(FunctionFactory & factory)
{
factory.registerFunction<FunctionReplaceOne>();
factory.registerFunction<FunctionReplaceAll>();
factory.registerFunction<FunctionReplaceRegexpOne>();
factory.registerFunction<FunctionReplaceRegexpAll>();
factory.registerFunction<FunctionPosition>();
factory.registerFunction<FunctionPositionUTF8>();
factory.registerFunction<FunctionPositionCaseInsensitive>();
factory.registerFunction<FunctionPositionCaseInsensitiveUTF8>();
factory.registerFunction<FunctionMatch>();
factory.registerFunction<FunctionLike>();
factory.registerFunction<FunctionNotLike>();
factory.registerFunction<FunctionExtract>();
}
}