/* * Copyright (C) 2009 The Android Open Source Project * * Licensed under the Apache License, Version 2.0 (the "License"); * you may not use this file except in compliance with the License. * You may obtain a copy of the License at * * http://www.apache.org/licenses/LICENSE-2.0 * * Unless required by applicable law or agreed to in writing, software * distributed under the License is distributed on an "AS IS" BASIS, * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. * See the License for the specific language governing permissions and * limitations under the License. */ #include <assert.h> #include <stdio.h> #include <string.h> #include "../include/dicttrie.h" #include "../include/dictbuilder.h" #include "../include/lpicache.h" #include "../include/mystdlib.h" #include "../include/ngram.h" namespace ime_pinyin { DictTrie::DictTrie() { spl_trie_ = SpellingTrie::get_cpinstance(); root_ = NULL; splid_le0_index_ = NULL; lma_node_num_le0_ = 0; nodes_ge1_ = NULL; lma_node_num_ge1_ = 0; lma_idx_buf_ = NULL; lma_idx_buf_len_ = 0; total_lma_num_ = 0; top_lmas_num_ = 0; dict_list_ = NULL; parsing_marks_ = NULL; mile_stones_ = NULL; reset_milestones(0, kFirstValidMileStoneHandle); } DictTrie::~DictTrie() { free_resource(true); } void DictTrie::free_resource(bool free_dict_list) { if (NULL != root_) free(root_); root_ = NULL; if (NULL != splid_le0_index_) free(splid_le0_index_); splid_le0_index_ = NULL; if (NULL != nodes_ge1_) free(nodes_ge1_); nodes_ge1_ = NULL; if (NULL != nodes_ge1_) free(nodes_ge1_); nodes_ge1_ = NULL; if (free_dict_list) { if (NULL != dict_list_) { delete dict_list_; } dict_list_ = NULL; } if (parsing_marks_) delete [] parsing_marks_; parsing_marks_ = NULL; if (mile_stones_) delete [] mile_stones_; mile_stones_ = NULL; reset_milestones(0, kFirstValidMileStoneHandle); } inline size_t DictTrie::get_son_offset(const LmaNodeGE1 *node) { return ((size_t)node->son_1st_off_l + ((size_t)node->son_1st_off_h << 16)); } inline size_t DictTrie::get_homo_idx_buf_offset(const LmaNodeGE1 *node) { return ((size_t)node->homo_idx_buf_off_l + ((size_t)node->homo_idx_buf_off_h << 16)); } inline LemmaIdType DictTrie::get_lemma_id(size_t id_offset) { LemmaIdType id = 0; for (uint16 pos = kLemmaIdSize - 1; pos > 0; pos--) id = (id << 8) + lma_idx_buf_[id_offset * kLemmaIdSize + pos]; id = (id << 8) + lma_idx_buf_[id_offset * kLemmaIdSize]; return id; } #ifdef ___BUILD_MODEL___ bool DictTrie::build_dict(const char* fn_raw, const char* fn_validhzs) { DictBuilder* dict_builder = new DictBuilder(); free_resource(true); return dict_builder->build_dict(fn_raw, fn_validhzs, this); } bool DictTrie::save_dict(FILE *fp) { if (NULL == fp) return false; if (fwrite(&lma_node_num_le0_, sizeof(size_t), 1, fp) != 1) return false; if (fwrite(&lma_node_num_ge1_, sizeof(size_t), 1, fp) != 1) return false; if (fwrite(&lma_idx_buf_len_, sizeof(size_t), 1, fp) != 1) return false; if (fwrite(&top_lmas_num_, sizeof(size_t), 1, fp) != 1) return false; if (fwrite(root_, sizeof(LmaNodeLE0), lma_node_num_le0_, fp) != lma_node_num_le0_) return false; if (fwrite(nodes_ge1_, sizeof(LmaNodeGE1), lma_node_num_ge1_, fp) != lma_node_num_ge1_) return false; if (fwrite(lma_idx_buf_, sizeof(unsigned char), lma_idx_buf_len_, fp) != lma_idx_buf_len_) return false; return true; } bool DictTrie::save_dict(const char *filename) { if (NULL == filename) return false; if (NULL == root_ || NULL == dict_list_) return false; SpellingTrie &spl_trie = SpellingTrie::get_instance(); NGram &ngram = NGram::get_instance(); FILE *fp = fopen(filename, "wb"); if (NULL == fp) return false; if (!spl_trie.save_spl_trie(fp) || !dict_list_->save_list(fp) || !save_dict(fp) || !ngram.save_ngram(fp)) { fclose(fp); return false; } fclose(fp); return true; } #endif // ___BUILD_MODEL___ bool DictTrie::load_dict(FILE *fp) { if (NULL == fp) return false; if (fread(&lma_node_num_le0_, sizeof(size_t), 1, fp) != 1) return false; if (fread(&lma_node_num_ge1_, sizeof(size_t), 1, fp) != 1) return false; if (fread(&lma_idx_buf_len_, sizeof(size_t), 1, fp) != 1) return false; if (fread(&top_lmas_num_, sizeof(size_t), 1, fp) != 1 || top_lmas_num_ >= lma_idx_buf_len_) return false; free_resource(false); root_ = static_cast<LmaNodeLE0*> (malloc(lma_node_num_le0_ * sizeof(LmaNodeLE0))); nodes_ge1_ = static_cast<LmaNodeGE1*> (malloc(lma_node_num_ge1_ * sizeof(LmaNodeGE1))); lma_idx_buf_ = (unsigned char*)malloc(lma_idx_buf_len_); total_lma_num_ = lma_idx_buf_len_ / kLemmaIdSize; size_t buf_size = SpellingTrie::get_instance().get_spelling_num() + 1; assert(lma_node_num_le0_ <= buf_size); splid_le0_index_ = static_cast<uint16*>(malloc(buf_size * sizeof(uint16))); // Init the space for parsing. parsing_marks_ = new ParsingMark[kMaxParsingMark]; mile_stones_ = new MileStone[kMaxMileStone]; reset_milestones(0, kFirstValidMileStoneHandle); if (NULL == root_ || NULL == nodes_ge1_ || NULL == lma_idx_buf_ || NULL == splid_le0_index_ || NULL == parsing_marks_ || NULL == mile_stones_) { free_resource(false); return false; } if (fread(root_, sizeof(LmaNodeLE0), lma_node_num_le0_, fp) != lma_node_num_le0_) return false; if (fread(nodes_ge1_, sizeof(LmaNodeGE1), lma_node_num_ge1_, fp) != lma_node_num_ge1_) return false; if (fread(lma_idx_buf_, sizeof(unsigned char), lma_idx_buf_len_, fp) != lma_idx_buf_len_) return false; // The quick index for the first level sons uint16 last_splid = kFullSplIdStart; size_t last_pos = 0; for (size_t i = 1; i < lma_node_num_le0_; i++) { for (uint16 splid = last_splid; splid < root_[i].spl_idx; splid++) splid_le0_index_[splid - kFullSplIdStart] = last_pos; splid_le0_index_[root_[i].spl_idx - kFullSplIdStart] = static_cast<uint16>(i); last_splid = root_[i].spl_idx; last_pos = i; } for (uint16 splid = last_splid + 1; splid < buf_size + kFullSplIdStart; splid++) { assert(static_cast<size_t>(splid - kFullSplIdStart) < buf_size); splid_le0_index_[splid - kFullSplIdStart] = last_pos + 1; } return true; } bool DictTrie::load_dict(const char *filename, LemmaIdType start_id, LemmaIdType end_id) { if (NULL == filename || end_id <= start_id) return false; FILE *fp = fopen(filename, "rb"); if (NULL == fp) return false; free_resource(true); dict_list_ = new DictList(); if (NULL == dict_list_) { fclose(fp); return false; } SpellingTrie &spl_trie = SpellingTrie::get_instance(); NGram &ngram = NGram::get_instance(); if (!spl_trie.load_spl_trie(fp) || !dict_list_->load_list(fp) || !load_dict(fp) || !ngram.load_ngram(fp) || total_lma_num_ > end_id - start_id + 1) { free_resource(true); fclose(fp); return false; } fclose(fp); return true; } bool DictTrie::load_dict_fd(int sys_fd, long start_offset, long length, LemmaIdType start_id, LemmaIdType end_id) { if (start_offset < 0 || length <= 0 || end_id <= start_id) return false; FILE *fp = fdopen(sys_fd, "rb"); if (NULL == fp) return false; if (-1 == fseek(fp, start_offset, SEEK_SET)) { fclose(fp); return false; } free_resource(true); dict_list_ = new DictList(); if (NULL == dict_list_) { fclose(fp); return false; } SpellingTrie &spl_trie = SpellingTrie::get_instance(); NGram &ngram = NGram::get_instance(); if (!spl_trie.load_spl_trie(fp) || !dict_list_->load_list(fp) || !load_dict(fp) || !ngram.load_ngram(fp) || ftell(fp) < start_offset + length || total_lma_num_ > end_id - start_id + 1) { free_resource(true); fclose(fp); return false; } fclose(fp); return true; } size_t DictTrie::fill_lpi_buffer(LmaPsbItem lpi_items[], size_t lpi_max, LmaNodeLE0 *node) { size_t lpi_num = 0; NGram& ngram = NGram::get_instance(); for (size_t homo = 0; homo < (size_t)node->num_of_homo; homo++) { lpi_items[lpi_num].id = get_lemma_id(node->homo_idx_buf_off + homo); lpi_items[lpi_num].lma_len = 1; lpi_items[lpi_num].psb = static_cast<LmaScoreType>(ngram.get_uni_psb(lpi_items[lpi_num].id)); lpi_num++; if (lpi_num >= lpi_max) break; } return lpi_num; } size_t DictTrie::fill_lpi_buffer(LmaPsbItem lpi_items[], size_t lpi_max, size_t homo_buf_off, LmaNodeGE1 *node, uint16 lma_len) { size_t lpi_num = 0; NGram& ngram = NGram::get_instance(); for (size_t homo = 0; homo < (size_t)node->num_of_homo; homo++) { lpi_items[lpi_num].id = get_lemma_id(homo_buf_off + homo); lpi_items[lpi_num].lma_len = lma_len; lpi_items[lpi_num].psb = static_cast<LmaScoreType>(ngram.get_uni_psb(lpi_items[lpi_num].id)); lpi_num++; if (lpi_num >= lpi_max) break; } return lpi_num; } void DictTrie::reset_milestones(uint16 from_step, MileStoneHandle from_handle) { if (0 == from_step) { parsing_marks_pos_ = 0; mile_stones_pos_ = kFirstValidMileStoneHandle; } else { if (from_handle > 0 && from_handle < mile_stones_pos_) { mile_stones_pos_ = from_handle; MileStone *mile_stone = mile_stones_ + from_handle; parsing_marks_pos_ = mile_stone->mark_start; } } } MileStoneHandle DictTrie::extend_dict(MileStoneHandle from_handle, const DictExtPara *dep, LmaPsbItem *lpi_items, size_t lpi_max, size_t *lpi_num) { if (NULL == dep) return 0; // from LmaNodeLE0 (root) to LmaNodeLE0 if (0 == from_handle) { assert(0 == dep->splids_extended); return extend_dict0(from_handle, dep, lpi_items, lpi_max, lpi_num); } // from LmaNodeLE0 to LmaNodeGE1 if (1 == dep->splids_extended) return extend_dict1(from_handle, dep, lpi_items, lpi_max, lpi_num); // From LmaNodeGE1 to LmaNodeGE1 return extend_dict2(from_handle, dep, lpi_items, lpi_max, lpi_num); } MileStoneHandle DictTrie::extend_dict0(MileStoneHandle from_handle, const DictExtPara *dep, LmaPsbItem *lpi_items, size_t lpi_max, size_t *lpi_num) { assert(NULL != dep && 0 == from_handle); *lpi_num = 0; MileStoneHandle ret_handle = 0; uint16 splid = dep->splids[dep->splids_extended]; uint16 id_start = dep->id_start; uint16 id_num = dep->id_num; LpiCache& lpi_cache = LpiCache::get_instance(); bool cached = lpi_cache.is_cached(splid); // 2. Begin exgtending // 2.1 Get the LmaPsbItem list LmaNodeLE0 *node = root_; size_t son_start = splid_le0_index_[id_start - kFullSplIdStart]; size_t son_end = splid_le0_index_[id_start + id_num - kFullSplIdStart]; for (size_t son_pos = son_start; son_pos < son_end; son_pos++) { assert(1 == node->son_1st_off); LmaNodeLE0 *son = root_ + son_pos; assert(son->spl_idx >= id_start && son->spl_idx < id_start + id_num); if (!cached && *lpi_num < lpi_max) { bool need_lpi = true; if (spl_trie_->is_half_id_yunmu(splid) && son_pos != son_start) need_lpi = false; if (need_lpi) *lpi_num += fill_lpi_buffer(lpi_items + (*lpi_num), lpi_max - *lpi_num, son); } // If necessary, fill in a new mile stone. if (son->spl_idx == id_start) { if (mile_stones_pos_ < kMaxMileStone && parsing_marks_pos_ < kMaxParsingMark) { parsing_marks_[parsing_marks_pos_].node_offset = son_pos; parsing_marks_[parsing_marks_pos_].node_num = id_num; mile_stones_[mile_stones_pos_].mark_start = parsing_marks_pos_; mile_stones_[mile_stones_pos_].mark_num = 1; ret_handle = mile_stones_pos_; parsing_marks_pos_++; mile_stones_pos_++; } } if (son->spl_idx >= id_start + id_num -1) break; } // printf("----- parsing marks: %d, mile stone: %d \n", parsing_marks_pos_, // mile_stones_pos_); return ret_handle; } MileStoneHandle DictTrie::extend_dict1(MileStoneHandle from_handle, const DictExtPara *dep, LmaPsbItem *lpi_items, size_t lpi_max, size_t *lpi_num) { assert(NULL != dep && from_handle > 0 && from_handle < mile_stones_pos_); MileStoneHandle ret_handle = 0; // 1. If this is a half Id, get its corresponding full starting Id and // number of full Id. size_t ret_val = 0; uint16 id_start = dep->id_start; uint16 id_num = dep->id_num; // 2. Begin extending. MileStone *mile_stone = mile_stones_ + from_handle; for (uint16 h_pos = 0; h_pos < mile_stone->mark_num; h_pos++) { ParsingMark p_mark = parsing_marks_[mile_stone->mark_start + h_pos]; uint16 ext_num = p_mark.node_num; for (uint16 ext_pos = 0; ext_pos < ext_num; ext_pos++) { LmaNodeLE0 *node = root_ + p_mark.node_offset + ext_pos; size_t found_start = 0; size_t found_num = 0; for (size_t son_pos = 0; son_pos < (size_t)node->num_of_son; son_pos++) { assert(node->son_1st_off <= lma_node_num_ge1_); LmaNodeGE1 *son = nodes_ge1_ + node->son_1st_off + son_pos; if (son->spl_idx >= id_start && son->spl_idx < id_start + id_num) { if (*lpi_num < lpi_max) { size_t homo_buf_off = get_homo_idx_buf_offset(son); *lpi_num += fill_lpi_buffer(lpi_items + (*lpi_num), lpi_max - *lpi_num, homo_buf_off, son, 2); } // If necessary, fill in the new DTMI if (0 == found_num) { found_start = son_pos; } found_num++; } if (son->spl_idx >= id_start + id_num - 1 || son_pos == (size_t)node->num_of_son - 1) { if (found_num > 0) { if (mile_stones_pos_ < kMaxMileStone && parsing_marks_pos_ < kMaxParsingMark) { parsing_marks_[parsing_marks_pos_].node_offset = node->son_1st_off + found_start; parsing_marks_[parsing_marks_pos_].node_num = found_num; if (0 == ret_val) mile_stones_[mile_stones_pos_].mark_start = parsing_marks_pos_; parsing_marks_pos_++; } ret_val++; } break; } // for son_pos } // for ext_pos } // for h_pos } if (ret_val > 0) { mile_stones_[mile_stones_pos_].mark_num = ret_val; ret_handle = mile_stones_pos_; mile_stones_pos_++; ret_val = 1; } // printf("----- parsing marks: %d, mile stone: %d \n", parsing_marks_pos_, // mile_stones_pos_); return ret_handle; } MileStoneHandle DictTrie::extend_dict2(MileStoneHandle from_handle, const DictExtPara *dep, LmaPsbItem *lpi_items, size_t lpi_max, size_t *lpi_num) { assert(NULL != dep && from_handle > 0 && from_handle < mile_stones_pos_); MileStoneHandle ret_handle = 0; // 1. If this is a half Id, get its corresponding full starting Id and // number of full Id. size_t ret_val = 0; uint16 id_start = dep->id_start; uint16 id_num = dep->id_num; // 2. Begin extending. MileStone *mile_stone = mile_stones_ + from_handle; for (uint16 h_pos = 0; h_pos < mile_stone->mark_num; h_pos++) { ParsingMark p_mark = parsing_marks_[mile_stone->mark_start + h_pos]; uint16 ext_num = p_mark.node_num; for (uint16 ext_pos = 0; ext_pos < ext_num; ext_pos++) { LmaNodeGE1 *node = nodes_ge1_ + p_mark.node_offset + ext_pos; size_t found_start = 0; size_t found_num = 0; for (size_t son_pos = 0; son_pos < (size_t)node->num_of_son; son_pos++) { assert(node->son_1st_off_l > 0 || node->son_1st_off_h > 0); LmaNodeGE1 *son = nodes_ge1_ + get_son_offset(node) + son_pos; if (son->spl_idx >= id_start && son->spl_idx < id_start + id_num) { if (*lpi_num < lpi_max) { size_t homo_buf_off = get_homo_idx_buf_offset(son); *lpi_num += fill_lpi_buffer(lpi_items + (*lpi_num), lpi_max - *lpi_num, homo_buf_off, son, dep->splids_extended + 1); } // If necessary, fill in the new DTMI if (0 == found_num) { found_start = son_pos; } found_num++; } if (son->spl_idx >= id_start + id_num - 1 || son_pos == (size_t)node->num_of_son - 1) { if (found_num > 0) { if (mile_stones_pos_ < kMaxMileStone && parsing_marks_pos_ < kMaxParsingMark) { parsing_marks_[parsing_marks_pos_].node_offset = get_son_offset(node) + found_start; parsing_marks_[parsing_marks_pos_].node_num = found_num; if (0 == ret_val) mile_stones_[mile_stones_pos_].mark_start = parsing_marks_pos_; parsing_marks_pos_++; } ret_val++; } break; } } // for son_pos } // for ext_pos } // for h_pos if (ret_val > 0) { mile_stones_[mile_stones_pos_].mark_num = ret_val; ret_handle = mile_stones_pos_; mile_stones_pos_++; } // printf("----- parsing marks: %d, mile stone: %d \n", parsing_marks_pos_, // mile_stones_pos_); return ret_handle; } bool DictTrie::try_extend(const uint16 *splids, uint16 splid_num, LemmaIdType id_lemma) { if (0 == splid_num || NULL == splids) return false; void *node = root_ + splid_le0_index_[splids[0] - kFullSplIdStart]; for (uint16 pos = 1; pos < splid_num; pos++) { if (1 == pos) { LmaNodeLE0 *node_le0 = reinterpret_cast<LmaNodeLE0*>(node); LmaNodeGE1 *node_son; uint16 son_pos; for (son_pos = 0; son_pos < static_cast<uint16>(node_le0->num_of_son); son_pos++) { assert(node_le0->son_1st_off <= lma_node_num_ge1_); node_son = nodes_ge1_ + node_le0->son_1st_off + son_pos; if (node_son->spl_idx == splids[pos]) break; } if (son_pos < node_le0->num_of_son) node = reinterpret_cast<void*>(node_son); else return false; } else { LmaNodeGE1 *node_ge1 = reinterpret_cast<LmaNodeGE1*>(node); LmaNodeGE1 *node_son; uint16 son_pos; for (son_pos = 0; son_pos < static_cast<uint16>(node_ge1->num_of_son); son_pos++) { assert(node_ge1->son_1st_off_l > 0 || node_ge1->son_1st_off_h > 0); node_son = nodes_ge1_ + get_son_offset(node_ge1) + son_pos; if (node_son->spl_idx == splids[pos]) break; } if (son_pos < node_ge1->num_of_son) node = reinterpret_cast<void*>(node_son); else return false; } } if (1 == splid_num) { LmaNodeLE0* node_le0 = reinterpret_cast<LmaNodeLE0*>(node); size_t num_of_homo = (size_t)node_le0->num_of_homo; for (size_t homo_pos = 0; homo_pos < num_of_homo; homo_pos++) { LemmaIdType id_this = get_lemma_id(node_le0->homo_idx_buf_off + homo_pos); char16 str[2]; get_lemma_str(id_this, str, 2); if (id_this == id_lemma) return true; } } else { LmaNodeGE1* node_ge1 = reinterpret_cast<LmaNodeGE1*>(node); size_t num_of_homo = (size_t)node_ge1->num_of_homo; for (size_t homo_pos = 0; homo_pos < num_of_homo; homo_pos++) { size_t node_homo_off = get_homo_idx_buf_offset(node_ge1); if (get_lemma_id(node_homo_off + homo_pos) == id_lemma) return true; } } return false; } size_t DictTrie::get_lpis(const uint16* splid_str, uint16 splid_str_len, LmaPsbItem* lma_buf, size_t max_lma_buf) { if (splid_str_len > kMaxLemmaSize) return 0; #define MAX_EXTENDBUF_LEN 200 size_t* node_buf1[MAX_EXTENDBUF_LEN]; // use size_t for data alignment size_t* node_buf2[MAX_EXTENDBUF_LEN]; LmaNodeLE0** node_fr_le0 = reinterpret_cast<LmaNodeLE0**>(node_buf1); // Nodes from. LmaNodeLE0** node_to_le0 = reinterpret_cast<LmaNodeLE0**>(node_buf2); // Nodes to. LmaNodeGE1** node_fr_ge1 = NULL; LmaNodeGE1** node_to_ge1 = NULL; size_t node_fr_num = 1; size_t node_to_num = 0; node_fr_le0[0] = root_; if (NULL == node_fr_le0[0]) return 0; size_t spl_pos = 0; while (spl_pos < splid_str_len) { uint16 id_num = 1; uint16 id_start = splid_str[spl_pos]; // If it is a half id if (spl_trie_->is_half_id(splid_str[spl_pos])) { id_num = spl_trie_->half_to_full(splid_str[spl_pos], &id_start); assert(id_num > 0); } // Extend the nodes if (0 == spl_pos) { // From LmaNodeLE0 (root) to LmaNodeLE0 nodes for (size_t node_fr_pos = 0; node_fr_pos < node_fr_num; node_fr_pos++) { LmaNodeLE0 *node = node_fr_le0[node_fr_pos]; assert(node == root_ && 1 == node_fr_num); size_t son_start = splid_le0_index_[id_start - kFullSplIdStart]; size_t son_end = splid_le0_index_[id_start + id_num - kFullSplIdStart]; for (size_t son_pos = son_start; son_pos < son_end; son_pos++) { assert(1 == node->son_1st_off); LmaNodeLE0 *node_son = root_ + son_pos; assert(node_son->spl_idx >= id_start && node_son->spl_idx < id_start + id_num); if (node_to_num < MAX_EXTENDBUF_LEN) { node_to_le0[node_to_num] = node_son; node_to_num++; } // id_start + id_num - 1 is the last one, which has just been // recorded. if (node_son->spl_idx >= id_start + id_num - 1) break; } } spl_pos++; if (spl_pos >= splid_str_len || node_to_num == 0) break; // Prepare the nodes for next extending // next time, from LmaNodeLE0 to LmaNodeGE1 LmaNodeLE0** node_tmp = node_fr_le0; node_fr_le0 = node_to_le0; node_to_le0 = NULL; node_to_ge1 = reinterpret_cast<LmaNodeGE1**>(node_tmp); } else if (1 == spl_pos) { // From LmaNodeLE0 to LmaNodeGE1 nodes for (size_t node_fr_pos = 0; node_fr_pos < node_fr_num; node_fr_pos++) { LmaNodeLE0 *node = node_fr_le0[node_fr_pos]; for (size_t son_pos = 0; son_pos < (size_t)node->num_of_son; son_pos++) { assert(node->son_1st_off <= lma_node_num_ge1_); LmaNodeGE1 *node_son = nodes_ge1_ + node->son_1st_off + son_pos; if (node_son->spl_idx >= id_start && node_son->spl_idx < id_start + id_num) { if (node_to_num < MAX_EXTENDBUF_LEN) { node_to_ge1[node_to_num] = node_son; node_to_num++; } } // id_start + id_num - 1 is the last one, which has just been // recorded. if (node_son->spl_idx >= id_start + id_num - 1) break; } } spl_pos++; if (spl_pos >= splid_str_len || node_to_num == 0) break; // Prepare the nodes for next extending // next time, from LmaNodeGE1 to LmaNodeGE1 node_fr_ge1 = node_to_ge1; node_to_ge1 = reinterpret_cast<LmaNodeGE1**>(node_fr_le0); node_fr_le0 = NULL; node_to_le0 = NULL; } else { // From LmaNodeGE1 to LmaNodeGE1 nodes for (size_t node_fr_pos = 0; node_fr_pos < node_fr_num; node_fr_pos++) { LmaNodeGE1 *node = node_fr_ge1[node_fr_pos]; for (size_t son_pos = 0; son_pos < (size_t)node->num_of_son; son_pos++) { assert(node->son_1st_off_l > 0 || node->son_1st_off_h > 0); LmaNodeGE1 *node_son = nodes_ge1_ + get_son_offset(node) + son_pos; if (node_son->spl_idx >= id_start && node_son->spl_idx < id_start + id_num) { if (node_to_num < MAX_EXTENDBUF_LEN) { node_to_ge1[node_to_num] = node_son; node_to_num++; } } // id_start + id_num - 1 is the last one, which has just been // recorded. if (node_son->spl_idx >= id_start + id_num - 1) break; } } spl_pos++; if (spl_pos >= splid_str_len || node_to_num == 0) break; // Prepare the nodes for next extending // next time, from LmaNodeGE1 to LmaNodeGE1 LmaNodeGE1 **node_tmp = node_fr_ge1; node_fr_ge1 = node_to_ge1; node_to_ge1 = node_tmp; } // The number of node for next extending node_fr_num = node_to_num; node_to_num = 0; } // while if (0 == node_to_num) return 0; NGram &ngram = NGram::get_instance(); size_t lma_num = 0; // If the length is 1, and the splid is a one-char Yunmu like 'a', 'o', 'e', // only those candidates for the full matched one-char id will be returned. if (1 == splid_str_len && spl_trie_->is_half_id_yunmu(splid_str[0])) node_to_num = node_to_num > 0 ? 1 : 0; for (size_t node_pos = 0; node_pos < node_to_num; node_pos++) { size_t num_of_homo = 0; if (spl_pos <= 1) { // Get from LmaNodeLE0 nodes LmaNodeLE0* node_le0 = node_to_le0[node_pos]; num_of_homo = (size_t)node_le0->num_of_homo; for (size_t homo_pos = 0; homo_pos < num_of_homo; homo_pos++) { size_t ch_pos = lma_num + homo_pos; lma_buf[ch_pos].id = get_lemma_id(node_le0->homo_idx_buf_off + homo_pos); lma_buf[ch_pos].lma_len = 1; lma_buf[ch_pos].psb = static_cast<LmaScoreType>(ngram.get_uni_psb(lma_buf[ch_pos].id)); if (lma_num + homo_pos >= max_lma_buf - 1) break; } } else { // Get from LmaNodeGE1 nodes LmaNodeGE1* node_ge1 = node_to_ge1[node_pos]; num_of_homo = (size_t)node_ge1->num_of_homo; for (size_t homo_pos = 0; homo_pos < num_of_homo; homo_pos++) { size_t ch_pos = lma_num + homo_pos; size_t node_homo_off = get_homo_idx_buf_offset(node_ge1); lma_buf[ch_pos].id = get_lemma_id(node_homo_off + homo_pos); lma_buf[ch_pos].lma_len = splid_str_len; lma_buf[ch_pos].psb = static_cast<LmaScoreType>(ngram.get_uni_psb(lma_buf[ch_pos].id)); if (lma_num + homo_pos >= max_lma_buf - 1) break; } } lma_num += num_of_homo; if (lma_num >= max_lma_buf) { lma_num = max_lma_buf; break; } } return lma_num; } uint16 DictTrie::get_lemma_str(LemmaIdType id_lemma, char16 *str_buf, uint16 str_max) { return dict_list_->get_lemma_str(id_lemma, str_buf, str_max); } uint16 DictTrie::get_lemma_splids(LemmaIdType id_lemma, uint16 *splids, uint16 splids_max, bool arg_valid) { char16 lma_str[kMaxLemmaSize + 1]; uint16 lma_len = get_lemma_str(id_lemma, lma_str, kMaxLemmaSize + 1); assert((!arg_valid && splids_max >= lma_len) || lma_len == splids_max); uint16 spl_mtrx[kMaxLemmaSize * 5]; uint16 spl_start[kMaxLemmaSize + 1]; spl_start[0] = 0; uint16 try_num = 1; for (uint16 pos = 0; pos < lma_len; pos++) { uint16 cand_splids_this = 0; if (arg_valid && spl_trie_->is_full_id(splids[pos])) { spl_mtrx[spl_start[pos]] = splids[pos]; cand_splids_this = 1; } else { cand_splids_this = dict_list_->get_splids_for_hanzi(lma_str[pos], arg_valid ? splids[pos] : 0, spl_mtrx + spl_start[pos], kMaxLemmaSize * 5 - spl_start[pos]); assert(cand_splids_this > 0); } spl_start[pos + 1] = spl_start[pos] + cand_splids_this; try_num *= cand_splids_this; } for (uint16 try_pos = 0; try_pos < try_num; try_pos++) { uint16 mod = 1; for (uint16 pos = 0; pos < lma_len; pos++) { uint16 radix = spl_start[pos + 1] - spl_start[pos]; splids[pos] = spl_mtrx[ spl_start[pos] + try_pos / mod % radix]; mod *= radix; } if (try_extend(splids, lma_len, id_lemma)) return lma_len; } return 0; } void DictTrie::set_total_lemma_count_of_others(size_t count) { NGram& ngram = NGram::get_instance(); ngram.set_total_freq_none_sys(count); } void DictTrie::convert_to_hanzis(char16 *str, uint16 str_len) { return dict_list_->convert_to_hanzis(str, str_len); } void DictTrie::convert_to_scis_ids(char16 *str, uint16 str_len) { return dict_list_->convert_to_scis_ids(str, str_len); } LemmaIdType DictTrie::get_lemma_id(const char16 lemma_str[], uint16 lemma_len) { if (NULL == lemma_str || lemma_len > kMaxLemmaSize) return 0; return dict_list_->get_lemma_id(lemma_str, lemma_len); } size_t DictTrie::predict_top_lmas(size_t his_len, NPredictItem *npre_items, size_t npre_max, size_t b4_used) { NGram &ngram = NGram::get_instance(); size_t item_num = 0; size_t top_lmas_id_offset = lma_idx_buf_len_ / kLemmaIdSize - top_lmas_num_; size_t top_lmas_pos = 0; while (item_num < npre_max && top_lmas_pos < top_lmas_num_) { memset(npre_items + item_num, 0, sizeof(NPredictItem)); LemmaIdType top_lma_id = get_lemma_id(top_lmas_id_offset + top_lmas_pos); top_lmas_pos += 1; if (dict_list_->get_lemma_str(top_lma_id, npre_items[item_num].pre_hzs, kMaxLemmaSize - 1) == 0) { continue; } npre_items[item_num].psb = ngram.get_uni_psb(top_lma_id); npre_items[item_num].his_len = his_len; item_num++; } return item_num; } size_t DictTrie::predict(const char16 *last_hzs, uint16 hzs_len, NPredictItem *npre_items, size_t npre_max, size_t b4_used) { return dict_list_->predict(last_hzs, hzs_len, npre_items, npre_max, b4_used); } } // namespace ime_pinyin