ukui-search/libchinese-segmentation/cppjieba/Unicode.hpp

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#ifndef CPPJIEBA_UNICODE_H
#define CPPJIEBA_UNICODE_H
#include <stdint.h>
#include <stdlib.h>
#include <string>
#include <vector>
#include <ostream>
#include "limonp/LocalVector.hpp"
namespace cppjieba {
using std::string;
using std::vector;
typedef uint32_t Rune;
struct Word {
string word;
uint32_t offset;
uint32_t unicode_offset;
uint32_t unicode_length;
Word(const string& w, uint32_t o)
: word(w), offset(o) {
}
Word(const string& w, uint32_t o, uint32_t unicode_offset, uint32_t unicode_length)
: word(w), offset(o), unicode_offset(unicode_offset), unicode_length(unicode_length) {
}
}; // struct Word
inline std::ostream& operator << (std::ostream& os, const Word& w) {
return os << "{\"word\": \"" << w.word << "\", \"offset\": " << w.offset << "}";
}
struct RuneStr {
Rune rune;
uint32_t offset;
uint32_t len;
uint32_t unicode_offset;
uint32_t unicode_length;
RuneStr(): rune(0), offset(0), len(0), unicode_offset(0), unicode_length(0) {
}
RuneStr(Rune r, uint32_t o, uint32_t l)
: rune(r), offset(o), len(l), unicode_offset(0), unicode_length(0) {
}
RuneStr(Rune r, uint32_t o, uint32_t l, uint32_t unicode_offset, uint32_t unicode_length)
: rune(r), offset(o), len(l), unicode_offset(unicode_offset), unicode_length(unicode_length) {
}
}; // struct RuneStr
inline std::ostream& operator << (std::ostream& os, const RuneStr& r) {
return os << "{\"rune\": \"" << r.rune << "\", \"offset\": " << r.offset << ", \"len\": " << r.len << "}";
}
typedef limonp::LocalVector<Rune> Unicode;
typedef limonp::LocalVector<struct RuneStr> RuneStrArray;
// [left, right]
struct WordRange {
RuneStrArray::const_iterator left;
RuneStrArray::const_iterator right;
WordRange(RuneStrArray::const_iterator l, RuneStrArray::const_iterator r)
: left(l), right(r) {
}
size_t Length() const {
return right - left + 1;
}
bool IsAllAscii() const {
for (RuneStrArray::const_iterator iter = left; iter <= right; ++iter) {
if (iter->rune >= 0x80) {
return false;
}
}
return true;
}
}; // struct WordRange
struct RuneStrLite {
uint32_t rune;
uint32_t len;
RuneStrLite(): rune(0), len(0) {
}
RuneStrLite(uint32_t r, uint32_t l): rune(r), len(l) {
}
}; // struct RuneStrLite
inline RuneStrLite DecodeRuneInString(const char* str, size_t len) {
RuneStrLite rp(0, 0);
if (str == NULL || len == 0) {
return rp;
}
if (!(str[0] & 0x80)) { // 0xxxxxxx
// 7bit, total 7bit
rp.rune = (uint8_t)(str[0]) & 0x7f;
rp.len = 1;
} else if ((uint8_t)str[0] <= 0xdf && 1 < len) {
// 110xxxxxx
// 5bit, total 5bit
rp.rune = (uint8_t)(str[0]) & 0x1f;
// 6bit, total 11bit
rp.rune <<= 6;
rp.rune |= (uint8_t)(str[1]) & 0x3f;
rp.len = 2;
} else if((uint8_t)str[0] <= 0xef && 2 < len) { // 1110xxxxxx
// 4bit, total 4bit
rp.rune = (uint8_t)(str[0]) & 0x0f;
// 6bit, total 10bit
rp.rune <<= 6;
rp.rune |= (uint8_t)(str[1]) & 0x3f;
// 6bit, total 16bit
rp.rune <<= 6;
rp.rune |= (uint8_t)(str[2]) & 0x3f;
rp.len = 3;
} else if((uint8_t)str[0] <= 0xf7 && 3 < len) { // 11110xxxx
// 3bit, total 3bit
rp.rune = (uint8_t)(str[0]) & 0x07;
// 6bit, total 9bit
rp.rune <<= 6;
rp.rune |= (uint8_t)(str[1]) & 0x3f;
// 6bit, total 15bit
rp.rune <<= 6;
rp.rune |= (uint8_t)(str[2]) & 0x3f;
// 6bit, total 21bit
rp.rune <<= 6;
rp.rune |= (uint8_t)(str[3]) & 0x3f;
rp.len = 4;
} else {
rp.rune = 0;
rp.len = 0;
}
return rp;
}
inline bool DecodeRunesInString(const char* s, size_t len, RuneStrArray& runes) {
runes.clear();
runes.reserve(len / 2);
for (uint32_t i = 0, j = 0; i < len;) {
RuneStrLite rp = DecodeRuneInString(s + i, len - i);
if (rp.len == 0) {
runes.clear();
return false;
}
RuneStr x(rp.rune, i, rp.len, j, 1);
runes.push_back(x);
i += rp.len;
++j;
}
return true;
}
inline bool DecodeRunesInString(const string& s, RuneStrArray& runes) {
return DecodeRunesInString(s.c_str(), s.size(), runes);
}
inline bool DecodeRunesInString(const char* s, size_t len, Unicode& unicode) {
unicode.clear();
RuneStrArray runes;
if (!DecodeRunesInString(s, len, runes)) {
return false;
}
unicode.reserve(runes.size());
for (size_t i = 0; i < runes.size(); i++) {
unicode.push_back(runes[i].rune);
}
return true;
}
inline bool IsSingleWord(const string& str) {
RuneStrLite rp = DecodeRuneInString(str.c_str(), str.size());
return rp.len == str.size();
}
inline bool DecodeRunesInString(const string& s, Unicode& unicode) {
return DecodeRunesInString(s.c_str(), s.size(), unicode);
}
inline Unicode DecodeRunesInString(const string& s) {
Unicode result;
DecodeRunesInString(s, result);
return result;
}
// [left, right]
inline Word GetWordFromRunes(const string& s, RuneStrArray::const_iterator left, RuneStrArray::const_iterator right) {
assert(right->offset >= left->offset);
uint32_t len = right->offset - left->offset + right->len;
uint32_t unicode_length = right->unicode_offset - left->unicode_offset + right->unicode_length;
return Word(s.substr(left->offset, len), left->offset, left->unicode_offset, unicode_length);
}
inline string GetStringFromRunes(const string& s, RuneStrArray::const_iterator left, RuneStrArray::const_iterator right) {
assert(right->offset >= left->offset);
uint32_t len = right->offset - left->offset + right->len;
return s.substr(left->offset, len);
}
inline void GetWordsFromWordRanges(const string& s, const vector<WordRange>& wrs, vector<Word>& words) {
for (size_t i = 0; i < wrs.size(); i++) {
words.push_back(GetWordFromRunes(s, wrs[i].left, wrs[i].right));
}
}
inline vector<Word> GetWordsFromWordRanges(const string& s, const vector<WordRange>& wrs) {
vector<Word> result;
GetWordsFromWordRanges(s, wrs, result);
return result;
}
inline void GetStringsFromWords(const vector<Word>& words, vector<string>& strs) {
strs.resize(words.size());
for (size_t i = 0; i < words.size(); ++i) {
strs[i] = words[i].word;
}
}
} // namespace cppjieba
#endif // CPPJIEBA_UNICODE_H