/* * Open Chinese Convert * * Copyright 2010-2020 Carbo Kuo * * 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 #include #include #include "BinaryDict.hpp" #include "Lexicon.hpp" using namespace opencc; size_t BinaryDict::KeyMaxLength() const { size_t maxLength = 0; for (const std::unique_ptr& entry : *lexicon) { maxLength = (std::max)(maxLength, entry->KeyLength()); } return maxLength; } void BinaryDict::SerializeToFile(FILE* fp) const { std::string keyBuf, valueBuf; std::vector keyOffsets, valueOffsets; size_t keyTotalLength = 0, valueTotalLength = 0; ConstructBuffer(keyBuf, keyOffsets, keyTotalLength, valueBuf, valueOffsets, valueTotalLength); // Number of items size_t numItems = lexicon->Length(); fwrite(&numItems, sizeof(size_t), 1, fp); // Data fwrite(&keyTotalLength, sizeof(size_t), 1, fp); fwrite(keyBuf.c_str(), sizeof(char), keyTotalLength, fp); fwrite(&valueTotalLength, sizeof(size_t), 1, fp); fwrite(valueBuf.c_str(), sizeof(char), valueTotalLength, fp); size_t keyCursor = 0, valueCursor = 0; for (const std::unique_ptr& entry : *lexicon) { // Number of values size_t numValues = entry->NumValues(); fwrite(&numValues, sizeof(size_t), 1, fp); // Key offset size_t keyOffset = keyOffsets[keyCursor++]; fwrite(&keyOffset, sizeof(size_t), 1, fp); // Values offset for (size_t i = 0; i < numValues; i++) { size_t valueOffset = valueOffsets[valueCursor++]; fwrite(&valueOffset, sizeof(size_t), 1, fp); } } assert(keyCursor == numItems); } BinaryDictPtr BinaryDict::NewFromFile(FILE* fp) { long savedOffset = ftell(fp); fseek(fp, 0L, SEEK_END); long offsetBoundLong = ftell(fp) - savedOffset; fseek(fp, savedOffset, SEEK_SET); assert(offsetBoundLong >= 0); size_t offsetBound = static_cast(offsetBoundLong); BinaryDictPtr dict(new BinaryDict(LexiconPtr(new Lexicon))); // Number of items size_t numItems; size_t unitsRead = fread(&numItems, sizeof(size_t), 1, fp); if (unitsRead != 1) { throw InvalidFormat("Invalid OpenCC binary dictionary (numItems)"); } // Keys size_t keyTotalLength; unitsRead = fread(&keyTotalLength, sizeof(size_t), 1, fp); if (unitsRead != 1) { throw InvalidFormat("Invalid OpenCC binary dictionary (keyTotalLength)"); } dict->keyBuffer.resize(keyTotalLength); unitsRead = fread(const_cast(dict->keyBuffer.c_str()), sizeof(char), keyTotalLength, fp); if (unitsRead != keyTotalLength) { throw InvalidFormat("Invalid OpenCC binary dictionary (keyBuffer)"); } // Values size_t valueTotalLength; unitsRead = fread(&valueTotalLength, sizeof(size_t), 1, fp); if (unitsRead != 1) { throw InvalidFormat("Invalid OpenCC binary dictionary (valueTotalLength)"); } dict->valueBuffer.resize(valueTotalLength); unitsRead = fread(const_cast(dict->valueBuffer.c_str()), sizeof(char), valueTotalLength, fp); if (unitsRead != valueTotalLength) { throw InvalidFormat("Invalid OpenCC binary dictionary (valueBuffer)"); } // Offsets for (size_t i = 0; i < numItems; i++) { // Number of values size_t numValues; unitsRead = fread(&numValues, sizeof(size_t), 1, fp); if (unitsRead != 1) { throw InvalidFormat("Invalid OpenCC binary dictionary (numValues)"); } // Key offset size_t keyOffset; unitsRead = fread(&keyOffset, sizeof(size_t), 1, fp); if (unitsRead != 1 || keyOffset >= offsetBound) { throw InvalidFormat("Invalid OpenCC binary dictionary (keyOffset)"); } std::string key = dict->keyBuffer.c_str() + keyOffset; // Value offset std::vector values; for (size_t j = 0; j < numValues; j++) { size_t valueOffset; unitsRead = fread(&valueOffset, sizeof(size_t), 1, fp); if (unitsRead != 1 || valueOffset >= offsetBound) { throw InvalidFormat("Invalid OpenCC binary dictionary (valueOffset)"); } const char* value = dict->valueBuffer.c_str() + valueOffset; values.push_back(value); } DictEntry* entry = DictEntryFactory::New(key, values); dict->lexicon->Add(entry); } return dict; } void BinaryDict::ConstructBuffer(std::string& keyBuf, std::vector& keyOffset, size_t& keyTotalLength, std::string& valueBuf, std::vector& valueOffset, size_t& valueTotalLength) const { keyTotalLength = 0; valueTotalLength = 0; // Calculate total length for (const std::unique_ptr& entry : *lexicon) { keyTotalLength += entry->KeyLength() + 1; assert(entry->NumValues() != 0); if (entry->NumValues() == 1) { const auto* svEntry = static_cast(entry.get()); valueTotalLength += svEntry->Value().length() + 1; } else { const auto* mvEntry = static_cast(entry.get()); for (const auto& value : mvEntry->Values()) { valueTotalLength += value.length() + 1; } } } // Write keys and values to buffers keyBuf.resize(keyTotalLength, '\0'); valueBuf.resize(valueTotalLength, '\0'); char* pKeyBuffer = const_cast(keyBuf.c_str()); char* pValueBuffer = const_cast(valueBuf.c_str()); for (const std::unique_ptr& entry : *lexicon) { strcpy(pKeyBuffer, entry->Key().c_str()); keyOffset.push_back(pKeyBuffer - keyBuf.c_str()); pKeyBuffer += entry->KeyLength() + 1; if (entry->NumValues() == 1) { const auto* svEntry = static_cast(entry.get()); strcpy(pValueBuffer, svEntry->Value().c_str()); valueOffset.push_back(pValueBuffer - valueBuf.c_str()); pValueBuffer += svEntry->Value().length() + 1; } else { const auto* mvEntry = static_cast(entry.get()); for (const auto& value : mvEntry->Values()) { strcpy(pValueBuffer, value.c_str()); valueOffset.push_back(pValueBuffer - valueBuf.c_str()); pValueBuffer += value.length() + 1; } } } assert(keyBuf.c_str() + keyTotalLength == pKeyBuffer); assert(valueBuf.c_str() + valueTotalLength == pValueBuffer); }