blob: 33b7ffb432fa6f13cd3a1e0caa62a201c523f232 [file] [log] [blame]
//
// 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 <stdint.h>
#include <stdio.h>
#include <iostream>
#include <fstream>
#include <fcntl.h>
#include <stdlib.h>
#include <string.h>
#include <sys/mman.h>
#include "cld2_dynamic_data.h"
#include "cld2_dynamic_data_loader.h"
#include "integral_types.h"
#include "cld2tablesummary.h"
#include "utf8statetable.h"
#include "scoreonescriptspan.h"
namespace CLD2DynamicDataLoader {
static int DEBUG=0;
CLD2DynamicData::FileHeader* loadHeaderFromFile(const char* fileName) {
FILE* inFile = fopen(fileName, "r");
if (inFile == NULL) {
return NULL;
}
return loadInternal(inFile, NULL, -1);
}
CLD2DynamicData::FileHeader* loadHeaderFromRaw(const void* basePointer,
const uint32_t length) {
return loadInternal(NULL, basePointer, length);
}
#define CLD2_READINT(field) \
if (sourceIsFile) {\
bytesRead += 4 * fread(&(header->field), 4, 1, inFile);\
} else {\
memcpy(&(header->field), (((char*)(basePointer)) + bytesRead), 4);\
bytesRead += 4;\
}
CLD2DynamicData::FileHeader* loadInternal(FILE* inFile, const void* basePointer, const uint32_t length) {
const bool sourceIsFile = (inFile != NULL);
int bytesRead = 0;
CLD2DynamicData::FileHeader* header = new CLD2DynamicData::FileHeader;
// TODO: force null-terminate char* strings for safety
if (sourceIsFile) {
bytesRead += fread(header->sanityString, 1, CLD2DynamicData::DATA_FILE_MARKER_LENGTH, inFile);
} else {
memcpy(header->sanityString, basePointer, CLD2DynamicData::DATA_FILE_MARKER_LENGTH);
bytesRead += CLD2DynamicData::DATA_FILE_MARKER_LENGTH;
}
if (!CLD2DynamicData::mem_compare(
header->sanityString,
CLD2DynamicData::DATA_FILE_MARKER,
CLD2DynamicData::DATA_FILE_MARKER_LENGTH)) {
std::cerr << "Malformed header: bad file marker!" << std::endl;
delete header;
return NULL;
}
CLD2_READINT(totalFileSizeBytes);
CLD2_READINT(utf8PropObj_state0);
CLD2_READINT(utf8PropObj_state0_size);
CLD2_READINT(utf8PropObj_total_size);
CLD2_READINT(utf8PropObj_max_expand);
CLD2_READINT(utf8PropObj_entry_shift);
CLD2_READINT(utf8PropObj_bytes_per_entry);
CLD2_READINT(utf8PropObj_losub);
CLD2_READINT(utf8PropObj_hiadd);
CLD2_READINT(startOf_utf8PropObj_state_table);
CLD2_READINT(lengthOf_utf8PropObj_state_table);
CLD2_READINT(startOf_utf8PropObj_remap_base);
CLD2_READINT(lengthOf_utf8PropObj_remap_base);
CLD2_READINT(startOf_utf8PropObj_remap_string);
CLD2_READINT(lengthOf_utf8PropObj_remap_string);
CLD2_READINT(startOf_utf8PropObj_fast_state);
CLD2_READINT(lengthOf_utf8PropObj_fast_state);
CLD2_READINT(startOf_kAvgDeltaOctaScore);
CLD2_READINT(lengthOf_kAvgDeltaOctaScore);
CLD2_READINT(numTablesEncoded);
CLD2DynamicData::TableHeader* tableHeaders = new CLD2DynamicData::TableHeader[header->numTablesEncoded];
header->tableHeaders = tableHeaders;
for (int x=0; x<header->numTablesEncoded; x++) {
CLD2DynamicData::TableHeader *header = &(tableHeaders[x]);
CLD2_READINT(kCLDTableSizeOne);
CLD2_READINT(kCLDTableSize);
CLD2_READINT(kCLDTableKeyMask);
CLD2_READINT(kCLDTableBuildDate);
CLD2_READINT(startOf_kCLDTable);
CLD2_READINT(lengthOf_kCLDTable);
CLD2_READINT(startOf_kCLDTableInd);
CLD2_READINT(lengthOf_kCLDTableInd);
CLD2_READINT(startOf_kRecognizedLangScripts);
CLD2_READINT(lengthOf_kRecognizedLangScripts);
}
// Confirm header size is correct.
int expectedHeaderSize = CLD2DynamicData::calculateHeaderSize(header->numTablesEncoded);
if (expectedHeaderSize != bytesRead) {
std::cerr << "Header size mismatch! Expected " << expectedHeaderSize << ", but read " << bytesRead << std::endl;
delete header;
delete[] tableHeaders;
return NULL;
}
int actualSize = 0;
if (sourceIsFile) {
// Confirm file size is correct.
fseek(inFile, 0, SEEK_END);
actualSize = ftell(inFile);
fclose(inFile);
} else {
actualSize = length;
}
if (actualSize != header->totalFileSizeBytes) {
std::cerr << "File size mismatch! Expected " << header->totalFileSizeBytes << ", but found " << actualSize << std::endl;
delete header;
delete[] tableHeaders;
return NULL;
}
return header;
}
void unloadDataFile(CLD2::ScoringTables** scoringTables,
void** mmapAddress, uint32_t* mmapLength) {
CLD2DynamicDataLoader::unloadDataRaw(scoringTables);
munmap(*mmapAddress, *mmapLength);
*mmapAddress = NULL;
*mmapLength = 0;
}
void unloadDataRaw(CLD2::ScoringTables** scoringTables) {
free(const_cast<CLD2::UTF8PropObj*>((*scoringTables)->unigram_obj));
(*scoringTables)->unigram_obj = NULL;
delete((*scoringTables)->unigram_compat_obj); // tableSummaries[0] from loadDataFile
(*scoringTables)->unigram_compat_obj = NULL;
delete(*scoringTables);
*scoringTables = NULL;
}
CLD2::ScoringTables* loadDataFile(const char* fileName,
void** mmapAddressOut, uint32_t* mmapLengthOut) {
CLD2DynamicData::FileHeader* header = loadHeaderFromFile(fileName);
if (header == NULL) {
return NULL;
}
// Initialize the memory map
int inFileHandle = open(fileName, O_RDONLY);
void* mapped = mmap(NULL, header->totalFileSizeBytes,
PROT_READ, MAP_PRIVATE, inFileHandle, 0);
// Record the map address. This allows callers to unmap
*mmapAddressOut=mapped;
*mmapLengthOut=header->totalFileSizeBytes;
close(inFileHandle);
return loadDataInternal(header, mapped, header->totalFileSizeBytes);
}
CLD2::ScoringTables* loadDataRaw(const void* basePointer, const uint32_t length) {
CLD2DynamicData::FileHeader* header = loadHeaderFromRaw(basePointer, length);
return loadDataInternal(header, basePointer, length);
}
CLD2::ScoringTables* loadDataInternal(CLD2DynamicData::FileHeader* header, const void* basePointer, const uint32_t length) {
// 1. UTF8 Object
const CLD2::uint8* state_table = static_cast<const CLD2::uint8*>(basePointer) +
header->startOf_utf8PropObj_state_table;
// FIXME: Unsafe to rely on this since RemapEntry is not a bit-packed structure
const CLD2::RemapEntry* remap_base =
reinterpret_cast<const CLD2::RemapEntry*>(
static_cast<const CLD2::uint8*>(basePointer) +
header->startOf_utf8PropObj_remap_base);
const CLD2::uint8* remap_string = static_cast<const CLD2::uint8*>(basePointer) +
header->startOf_utf8PropObj_remap_string;
const CLD2::uint8* fast_state =
header->startOf_utf8PropObj_fast_state == 0 ? 0 :
static_cast<const CLD2::uint8*>(basePointer) +
header->startOf_utf8PropObj_fast_state;
// Populate intermediate object. Horrible casting required because the struct
// is all read-only integers, and doesn't have a constructor. Yikes.
// TODO: It might actually be less horrible to memcpy the data in <shudder>
const CLD2::UTF8PropObj* unigram_obj = reinterpret_cast<CLD2::UTF8PropObj*>(malloc(sizeof(CLD2::UTF8PropObj)));
*const_cast<CLD2::uint32*>(&unigram_obj->state0) = header->utf8PropObj_state0;
*const_cast<CLD2::uint32*>(&unigram_obj->state0_size) = header->utf8PropObj_state0_size;
*const_cast<CLD2::uint32*>(&unigram_obj->total_size) = header->utf8PropObj_total_size;
*const_cast<int*>(&unigram_obj->max_expand) = header->utf8PropObj_max_expand;
*const_cast<int*>(&unigram_obj->entry_shift) = header->utf8PropObj_entry_shift;
*const_cast<int*>(&unigram_obj->bytes_per_entry) = header->utf8PropObj_bytes_per_entry;
*const_cast<CLD2::uint32*>(&unigram_obj->losub) = header->utf8PropObj_losub;
*const_cast<CLD2::uint32*>(&unigram_obj->hiadd) = header->utf8PropObj_hiadd;
*const_cast<const CLD2::uint8**>(&unigram_obj->state_table) = state_table;
*const_cast<const CLD2::RemapEntry**>(&unigram_obj->remap_base) = remap_base;
*const_cast<const CLD2::uint8**>(&unigram_obj->remap_string) = remap_string;
*const_cast<const CLD2::uint8**>(&unigram_obj->fast_state) = fast_state;
// 2. kAvgDeltaOctaScore array
const short* read_kAvgDeltaOctaScore = reinterpret_cast<const short*>(
static_cast<const CLD2::uint8*>(basePointer) +
header->startOf_kAvgDeltaOctaScore);
// 3. Each table
CLD2::CLD2TableSummary* tableSummaries = new CLD2::CLD2TableSummary[header->numTablesEncoded];
for (int x=0; x<header->numTablesEncoded; x++) {
CLD2::CLD2TableSummary &summary = tableSummaries[x];
CLD2DynamicData::TableHeader& tHeader = header->tableHeaders[x];
const CLD2::IndirectProbBucket4* kCLDTable =
reinterpret_cast<const CLD2::IndirectProbBucket4*>(
static_cast<const CLD2::uint8*>(basePointer) + tHeader.startOf_kCLDTable);
const CLD2::uint32* kCLDTableInd =
reinterpret_cast<const CLD2::uint32*>(
static_cast<const CLD2::uint8*>(basePointer) + tHeader.startOf_kCLDTableInd);
const char* kRecognizedLangScripts =
static_cast<const char*>(basePointer) + tHeader.startOf_kRecognizedLangScripts;
summary.kCLDTable = kCLDTable;
summary.kCLDTableInd = kCLDTableInd;
summary.kCLDTableSizeOne = tHeader.kCLDTableSizeOne;
summary.kCLDTableSize = tHeader.kCLDTableSize;
summary.kCLDTableKeyMask = tHeader.kCLDTableKeyMask;
summary.kCLDTableBuildDate = tHeader.kCLDTableBuildDate;
summary.kRecognizedLangScripts = kRecognizedLangScripts;
}
// Tie everything together
CLD2::ScoringTables* result = new CLD2::ScoringTables;
result->unigram_obj = unigram_obj;
result->unigram_compat_obj = &tableSummaries[0];
result->deltabi_obj = &tableSummaries[1];
result->distinctbi_obj = &tableSummaries[2];
result->quadgram_obj = &tableSummaries[3];
result->quadgram_obj2 = &tableSummaries[4];
result->deltaocta_obj = &tableSummaries[5];
result->distinctocta_obj = &tableSummaries[6];
result->kExpectedScore = read_kAvgDeltaOctaScore;
delete[] header->tableHeaders;
delete header;
return result;
}
} // namespace CLD2DynamicDataLoader