#pragma once #include #include #include #include #include #include #include #include class Collator; namespace DB { namespace ErrorCodes { extern const int PARAMETER_OUT_OF_BOUND; extern const int SIZES_OF_COLUMNS_DOESNT_MATCH; } /** A column of values of type `String`. */ class ColumnString final : public IColumn { public: using Chars_t = PaddedPODArray; private: /// On the index i there is an offset to the beginning of the i + 1 -th element. Offsets_t offsets; /// Bytes of rows laid in succession. Strings are stored with the trailing zero byte. Chars_t chars; size_t __attribute__((__always_inline__)) offsetAt(size_t i) const { return i == 0 ? 0 : offsets[i - 1]; } /// Size, including the trailing zero byte. size_t __attribute__((__always_inline__)) sizeAt(size_t i) const { return i == 0 ? offsets[0] : (offsets[i] - offsets[i - 1]); } template friend struct lessWithCollation; public: /** Create an empty column of rows */ ColumnString() {} std::string getName() const override { return "ColumnString"; } size_t size() const override { return offsets.size(); } size_t byteSize() const override { return chars.size() + offsets.size() * sizeof(offsets[0]); } size_t allocatedSize() const override { return chars.allocated_size() + offsets.allocated_size() * sizeof(offsets[0]); } ColumnPtr cloneResized(size_t size) const override { ColumnPtr new_col_holder = std::make_shared(); if (size > 0) { auto & new_col = static_cast(*new_col_holder); size_t count = std::min(this->size(), size); /// First create the offsets. new_col.offsets.resize(size); new_col.offsets.assign(offsets.begin(), offsets.begin() + count); size_t byte_count = new_col.offsets.back(); if (size > count) { /// Create offsets for the (size - count) new empty strings. for (size_t i = count; i < size; ++i) new_col.offsets[i] = new_col.offsets[i - 1] + 1; } /// Then store the strings. new_col.chars.resize(new_col.offsets.back()); new_col.chars.assign(chars.begin(), chars.begin() + byte_count); if (size > count) { /// Create (size - count) empty strings. size_t from = new_col.offsets[count]; size_t n = new_col.offsets.back() - from; memset(&new_col.chars[from], '\0', n); } } return new_col_holder; } Field operator[](size_t n) const override { return Field(&chars[offsetAt(n)], sizeAt(n) - 1); } void get(size_t n, Field & res) const override { res.assignString(&chars[offsetAt(n)], sizeAt(n) - 1); } StringRef getDataAt(size_t n) const override { return StringRef(&chars[offsetAt(n)], sizeAt(n) - 1); } StringRef getDataAtWithTerminatingZero(size_t n) const override { return StringRef(&chars[offsetAt(n)], sizeAt(n)); } void insert(const Field & x) override { const String & s = DB::get(x); const size_t old_size = chars.size(); const size_t size_to_append = s.size() + 1; const size_t new_size = old_size + size_to_append; chars.resize(new_size); memcpy(&chars[old_size], s.c_str(), size_to_append); offsets.push_back(new_size); } void insertFrom(const IColumn & src_, size_t n) override { const ColumnString & src = static_cast(src_); if (n != 0) { const size_t size_to_append = src.offsets[n] - src.offsets[n - 1]; if (size_to_append == 1) { /// shortcut for empty string chars.push_back(0); offsets.push_back(chars.size()); } else { const size_t old_size = chars.size(); const size_t offset = src.offsets[n - 1]; const size_t new_size = old_size + size_to_append; chars.resize(new_size); memcpySmallAllowReadWriteOverflow15(&chars[old_size], &src.chars[offset], size_to_append); offsets.push_back(new_size); } } else { const size_t old_size = chars.size(); const size_t size_to_append = src.offsets[0]; const size_t new_size = old_size + size_to_append; chars.resize(new_size); memcpySmallAllowReadWriteOverflow15(&chars[old_size], &src.chars[0], size_to_append); offsets.push_back(new_size); } } void insertData(const char * pos, size_t length) override { const size_t old_size = chars.size(); const size_t new_size = old_size + length + 1; chars.resize(new_size); memcpy(&chars[old_size], pos, length); chars[old_size + length] = 0; offsets.push_back(new_size); } void insertDataWithTerminatingZero(const char * pos, size_t length) override { const size_t old_size = chars.size(); const size_t new_size = old_size + length; chars.resize(new_size); memcpy(&chars[old_size], pos, length); offsets.push_back(new_size); } void popBack(size_t n) override { size_t nested_n = offsets.back() - offsetAt(offsets.size() - n); chars.resize(chars.size() - nested_n); offsets.resize_assume_reserved(offsets.size() - n); } StringRef serializeValueIntoArena(size_t n, Arena & arena, char const *& begin) const override { size_t string_size = sizeAt(n); size_t offset = offsetAt(n); StringRef res; res.size = sizeof(string_size) + string_size; char * pos = arena.allocContinue(res.size, begin); memcpy(pos, &string_size, sizeof(string_size)); memcpy(pos + sizeof(string_size), &chars[offset], string_size); res.data = pos; return res; } const char * deserializeAndInsertFromArena(const char * pos) override { const size_t string_size = *reinterpret_cast(pos); pos += sizeof(string_size); const size_t old_size = chars.size(); const size_t new_size = old_size + string_size; chars.resize(new_size); memcpy(&chars[old_size], pos, string_size); offsets.push_back(new_size); return pos + string_size; } void updateHashWithValue(size_t n, SipHash & hash) const override { size_t string_size = sizeAt(n); size_t offset = offsetAt(n); hash.update(reinterpret_cast(&string_size), sizeof(string_size)); hash.update(reinterpret_cast(&chars[offset]), string_size); } void insertRangeFrom(const IColumn & src, size_t start, size_t length) override { if (length == 0) return; const ColumnString & src_concrete = static_cast(src); if (start + length > src_concrete.offsets.size()) throw Exception("Parameter out of bound in IColumnString::insertRangeFrom method.", ErrorCodes::PARAMETER_OUT_OF_BOUND); size_t nested_offset = src_concrete.offsetAt(start); size_t nested_length = src_concrete.offsets[start + length - 1] - nested_offset; size_t old_chars_size = chars.size(); chars.resize(old_chars_size + nested_length); memcpy(&chars[old_chars_size], &src_concrete.chars[nested_offset], nested_length); if (start == 0 && offsets.empty()) { offsets.assign(src_concrete.offsets.begin(), src_concrete.offsets.begin() + length); } else { size_t old_size = offsets.size(); size_t prev_max_offset = old_size ? offsets.back() : 0; offsets.resize(old_size + length); for (size_t i = 0; i < length; ++i) offsets[old_size + i] = src_concrete.offsets[start + i] - nested_offset + prev_max_offset; } } ColumnPtr filter(const Filter & filt, ssize_t result_size_hint) const override { if (offsets.size() == 0) return std::make_shared(); auto res = std::make_shared(); Chars_t & res_chars = res->chars; Offsets_t & res_offsets = res->offsets; filterArraysImpl(chars, offsets, res_chars, res_offsets, filt, result_size_hint); return res; } ColumnPtr permute(const Permutation & perm, size_t limit) const override { size_t size = offsets.size(); if (limit == 0) limit = size; else limit = std::min(size, limit); if (perm.size() < limit) throw Exception("Size of permutation is less than required.", ErrorCodes::SIZES_OF_COLUMNS_DOESNT_MATCH); if (limit == 0) return std::make_shared(); std::shared_ptr res = std::make_shared(); Chars_t & res_chars = res->chars; Offsets_t & res_offsets = res->offsets; if (limit == size) res_chars.resize(chars.size()); else { size_t new_chars_size = 0; for (size_t i = 0; i < limit; ++i) new_chars_size += sizeAt(perm[i]); res_chars.resize(new_chars_size); } res_offsets.resize(limit); Offset_t current_new_offset = 0; for (size_t i = 0; i < limit; ++i) { size_t j = perm[i]; size_t string_offset = j == 0 ? 0 : offsets[j - 1]; size_t string_size = offsets[j] - string_offset; memcpySmallAllowReadWriteOverflow15(&res_chars[current_new_offset], &chars[string_offset], string_size); current_new_offset += string_size; res_offsets[i] = current_new_offset; } return res; } void insertDefault() override { chars.push_back(0); offsets.push_back(offsets.size() == 0 ? 1 : (offsets.back() + 1)); } int compareAt(size_t n, size_t m, const IColumn & rhs_, int nan_direction_hint) const override { const ColumnString & rhs = static_cast(rhs_); /** For performance, the strings are compared to the first zero byte. * (if zero byte is in the middle of the line, then what is after it is ignored) * Note that the terminating zero byte is always present. */ return strcmp( reinterpret_cast(&chars[offsetAt(n)]), reinterpret_cast(&rhs.chars[rhs.offsetAt(m)])); } /// Version `compareAt` for locale-sensitive string comparison int compareAtWithCollation(size_t n, size_t m, const IColumn & rhs_, const Collator & collator) const; template struct less { const ColumnString & parent; less(const ColumnString & parent_) : parent(parent_) {} bool operator()(size_t lhs, size_t rhs) const { int res = strcmp( reinterpret_cast(&parent.chars[parent.offsetAt(lhs)]), reinterpret_cast(&parent.chars[parent.offsetAt(rhs)])); return positive ? (res < 0) : (res > 0); } }; void getPermutation(bool reverse, size_t limit, Permutation & res) const override { size_t s = offsets.size(); res.resize(s); for (size_t i = 0; i < s; ++i) res[i] = i; if (limit >= s) limit = 0; if (limit) { if (reverse) std::partial_sort(res.begin(), res.begin() + limit, res.end(), less(*this)); else std::partial_sort(res.begin(), res.begin() + limit, res.end(), less(*this)); } else { if (reverse) std::sort(res.begin(), res.end(), less(*this)); else std::sort(res.begin(), res.end(), less(*this)); } } /// Sorting with regard to `Collation` void getPermutationWithCollation(const Collator & collator, bool reverse, size_t limit, Permutation & res) const; ColumnPtr replicate(const Offsets_t & replicate_offsets) const override { size_t col_size = size(); if (col_size != replicate_offsets.size()) throw Exception("Size of offsets doesn't match size of column.", ErrorCodes::SIZES_OF_COLUMNS_DOESNT_MATCH); std::shared_ptr res = std::make_shared(); if (0 == col_size) return res; Chars_t & res_chars = res->chars; Offsets_t & res_offsets = res->offsets; res_chars.reserve(chars.size() / col_size * replicate_offsets.back()); res_offsets.reserve(replicate_offsets.back()); Offset_t prev_replicate_offset = 0; Offset_t prev_string_offset = 0; Offset_t current_new_offset = 0; for (size_t i = 0; i < col_size; ++i) { size_t size_to_replicate = replicate_offsets[i] - prev_replicate_offset; size_t string_size = offsets[i] - prev_string_offset; for (size_t j = 0; j < size_to_replicate; ++j) { current_new_offset += string_size; res_offsets.push_back(current_new_offset); res_chars.resize(res_chars.size() + string_size); memcpySmallAllowReadWriteOverflow15( &res_chars[res_chars.size() - string_size], &chars[prev_string_offset], string_size); } prev_replicate_offset = replicate_offsets[i]; prev_string_offset = offsets[i]; } return res; } Columns scatter(ColumnIndex num_columns, const Selector & selector) const override { return scatterImpl(num_columns, selector); } void reserve(size_t n) override { offsets.reserve(n); chars.reserve(n * DBMS_APPROX_STRING_SIZE); } Chars_t & getChars() { return chars; } const Chars_t & getChars() const { return chars; } Offsets_t & getOffsets() { return offsets; } const Offsets_t & getOffsets() const { return offsets; } void getExtremes(Field & min, Field & max) const override { min = String(); max = String(); } }; }