void _mergeData() {
// fill in tags from the document vector fields
// unnecessary to filter out any fields to remove, as they will
// be ignored when indexing.
indri::utility::greedy_vector<indri::index::FieldExtent>& fields = _docIter->currentEntry()->fields() ;
tl.clear();
for (size_t i = 0; i < fields.size(); i++) {
const indri::index::FieldExtent& field = fields[i];
std::string fieldName = _index->field(fields[i].id);;
tl.addTag(fieldName.c_str(), fieldName.c_str(), field.begin);
tl.endTag(fieldName.c_str(), fieldName.c_str(), field.end);
}
//stuff it into the parsed doc
tl.writeTagList(parsed->tags);
// fill in terms from the document text so that they will stop/stem
// correctly when added to the new repository.
// Potentially issues with url injection here...
// probably best not to do this with trecweb/html docs....
// TODO: test this
termBuffer.clear();
termBuffer.grow( parsed->textLength * 2 );
for (size_t i = 0; i < parsed->positions.size(); i++ ) {
int start = parsed->positions[i].begin;
int end = parsed->positions[i].end;
int token_len = end - start;
const char *token = parsed->text + start;
char* write_loc = termBuffer.write( token_len + 1 );
strncpy( write_loc, token, token_len );
write_loc[token_len] = '\0';
parsed->terms.push_back( write_loc );
}
}
void IndexWriter::_writeBatch( indri::file::SequentialWriteBuffer* buffer, int document, int length, indri::utility::Buffer& data ) {
assert( length < 100*1000*1000 );
_writeSkip( buffer, document, length );
if( data.position() != 0 ) {
buffer->write( data.front(), data.position() );
data.clear();
}
}
void open( const std::string& anchorFile ) {
_in.close();
_in.clear();
_in.open( anchorFile.c_str() );
_buffer.clear();
_readDocumentHeader();
}
static void zlib_read_document( z_stream_s& stream, indri::file::File& infile, UINT64 offset, indri::utility::Buffer& outputBuffer ) {
// read in data from the file until the stream ends
// split up the data as necessary
// decompress positional info
// read some data
char inputBuffer[INPUT_BUFFER_SIZE];
outputBuffer.grow( INPUT_BUFFER_SIZE );
outputBuffer.write( sizeof(indri::api::ParsedDocument) );
stream.avail_in = 0;
stream.avail_out = 0;
while(true) {
if( !stream.avail_in ) {
UINT64 readSize = infile.read( inputBuffer, offset, sizeof inputBuffer );
offset += readSize;
stream.avail_in = readSize;
stream.next_in = (Bytef*) inputBuffer;
}
stream.avail_out = outputBuffer.size() - outputBuffer.position();
stream.next_out = (Bytef*) outputBuffer.write( outputBuffer.size() - outputBuffer.position() );
int result = inflate( &stream, Z_NO_FLUSH );
outputBuffer.unwrite( stream.avail_out );
if( result == Z_STREAM_END ) {
result = inflate( &stream, Z_FINISH );
if( result < 0 )
LEMUR_THROW( result, "Something bad happened while trying to finish decompressing a document." );
inflateEnd( &stream );
break;
}
if( result < 0 ) {
LEMUR_THROW( result, "Something bad happened while trying to decompress a document." );
}
if( stream.avail_out == 0 ) {
outputBuffer.grow();
}
}
}
indri::api::ParsedDocument* transform( indri::api::ParsedDocument* document ) {
// find the url metadata pair
indri::utility::greedy_vector<indri::parse::MetadataPair>::iterator iter;
iter = std::find_if( document->metadata.begin(),
document->metadata.end(),
indri::parse::MetadataPair::key_equal( "url" ) );
// no need to stick around if there is no url
if( iter == document->metadata.end() )
return document;
// need to copy this into the buffer and parse it:
_buffer.clear();
_buffer.grow( iter->valueLength + 1 );
char* urlText = _buffer.write( iter->valueLength );
// pushes the buffer pointer, trash in urlText
// memcpy( _buffer.write( iter->valueLength ), iter->value, iter->valueLength );
memcpy( urlText, iter->value, iter->valueLength );
*_buffer.write(1) = '\0';
// now we're pointing to the copied urlText, so we can start parsing
int urlStart = (int)document->terms.size();
char* c = urlText;
bool lastSkipped = true;
bool foundSlash = false;
int remainingStart = -1;
// skip the beginning stuff (http://)
for( c = urlText; *c; c++ ) {
if( *c == '/' && c[1] && c[1] == '/' ) {
urlText = c + 2;
}
}
int cnt = 0;
// now, try to find the
for( c = urlText; *c; c++ ) {
if( (*c >= 'A' && *c <= 'Z') ||
(*c >= 'a' && *c <= 'z') ||
(*c >= '0' && *c <= '9') )
{
if( lastSkipped ) {
lastSkipped = false;
document->terms.push_back( c );
cnt++;
}
} else if( *c == '/' && remainingStart < 0 ) {
*c = 0;
lastSkipped = true;
remainingStart = document->terms.size();
} else {
lastSkipped = true;
*c = 0;
}
}
// put in phony positions entries
int tokEnd = document->positions.size() ? document->positions[document->positions.size()-1].end : 0;
for (size_t n = document->terms.size()-cnt; n < document->terms.size(); n++) {
TermExtent extent;
extent.begin = tokEnd++; // hope this doesn't run off the end
extent.end = tokEnd;
document->positions.push_back( extent );
}
// the URL text is now parsed and stored in the document
// all we need to do now is put some tags around the text.
TagExtent *url = new TagExtent;
url->begin = urlStart;
url->end = document->terms.size();
url->name = "url";
url->number = 0;
document->tags.push_back(url);
TagExtent *domain = new TagExtent;
domain->begin = urlStart;
domain->end = (remainingStart >= 0) ? remainingStart : document->terms.size();
domain->name = "urldomain";
domain->number = 0;
document->tags.push_back(domain);
if( remainingStart > 0 ) {
indri::parse::TagExtent *urlpath = new TagExtent;
urlpath->begin = remainingStart;
urlpath->end = document->terms.size();
urlpath->name = "urlpath";
urlpath->number = 0;
document->tags.push_back(urlpath);
}
return document;
}
bool lemur::file::SortMergeTextFiles::_readLine(FILE *_in, char*& beginLine, size_t& lineLength, indri::utility::Buffer &_buffer ) {
lineLength = 0;
size_t actual;
// make a buffer of a reasonable size so we're not always allocating
if( _buffer.size() < 1024*1024 )
_buffer.grow( 1024*1024 );
// if we're running out of room, add 25MB
if( (_buffer.size() - _buffer.position()) < 512*1024 ) {
_buffer.grow( _buffer.size() + 1024*1024*25 );
}
if( _buffer.position() ) {
// get rid of null terminator from previous call
_buffer.unwrite(1);
}
size_t readAmount = _buffer.size() - _buffer.position() - 2;
// fetch next document line
char* buffer = _buffer.write( readAmount );
char* result = fgets( buffer, (int)readAmount, _in );
if(!result) {
return false;
}
actual = strlen(buffer);
lineLength += actual;
_buffer.unwrite( readAmount - actual );
// all finished reading
*_buffer.write(1) = 0;
beginLine = _buffer.front() + _buffer.position() - lineLength - 1;
// strip the \n off the end
if (beginLine[lineLength-1]=='\n') {
beginLine[lineLength-1]=0;
}
return true;
}
void IndexWriter::_addInvertedListData( indri::utility::greedy_vector<WriterIndexContext*>& lists, indri::index::TermData* termData, indri::utility::Buffer& listBuffer, UINT64& endOffset ) {
indri::utility::greedy_vector<WriterIndexContext*>::iterator iter;
const int minimumSkip = 1<<12; // 4k
int documentsWritten = 0;
const float topdocsFraction = 0.01f;
bool hasTopdocs = termData->corpus.documentCount > TOPDOCS_DOCUMENT_COUNT;
bool isFrequent = termData->corpus.totalCount > FREQUENT_TERM_COUNT;
int topdocsCount = hasTopdocs ? int(termData->corpus.documentCount * 0.01) : 0;
int topdocsSpace = hasTopdocs ? ((topdocsCount*3*sizeof(UINT32)) + sizeof(int)) : 0;
// write a control byte
char control = (hasTopdocs ? 0x01 : 0) | (isFrequent ? 0x02 : 0);
_invertedOutput->write( &control, 1 );
UINT64 initialPosition = _invertedOutput->tell();
// leave some room for the topdocs list
if( hasTopdocs ) {
_invertedOutput->seek( topdocsSpace + initialPosition );
}
// maintain a list of top documents
std::priority_queue<DocListIterator::TopDocument,
std::vector<DocListIterator::TopDocument>,
DocListIterator::TopDocument::greater> topdocs;
double threshold = 0;
int lastDocument = 0;
int positions = 0;
int docs = 0;
// for each matching list:
for( iter = lists.begin(); iter != lists.end(); ++iter ) {
indri::index::DocListFileIterator::DocListData* listData = (*iter)->iterator->currentEntry();
DocListIterator* iterator = listData->iterator;
Index* index = (*iter)->index;
indri::utility::RVLCompressStream stream( listBuffer );
int listDocs = 0;
int listPositions = 0;
while( !iterator->finished() ) {
// get the latest entry from the list
DocListIterator::DocumentData* documentData = iterator->currentEntry();
// add to document counter
docs++; listDocs++;
// update the topdocs list
if( hasTopdocs ) {
int length = index->documentLength( documentData->document );
int count = documentData->positions.size();
// compute DocListIterator::TopDocument::greater (current, top())
// if false, no reason to insert this entry.
// note that the test is inverted.
// int(length * threshold) <= count is equivalent to
// count/length > topdocs.top().count/topdocs.top().length
// but we use < to force breaking a tie in favor of keeping
// the first seen document.
if( int(length * threshold) < count || topdocs.size() < topdocsCount ) {
// form a topdocs entry for this document
DocListIterator::TopDocument topDocument( documentData->document,
count,
length );
topdocs.push( topDocument );
while( topdocs.size() > topdocsCount )
topdocs.pop();
threshold = topdocs.top().count / double(topdocs.top().length);
}
}
if( listBuffer.position() > minimumSkip ) {
// time to write in a skip
_writeBatch( _invertedOutput, documentData->document, listBuffer.position(), listBuffer );
// delta encode documents by batch
lastDocument = 0;
}
assert( documentData->document > lastDocument );
// write this entry out to the list
stream << documentData->document - lastDocument;
stream << (int) documentData->positions.size();
lastDocument = documentData->document;
int lastPosition = 0;
for( int i=0; i<documentData->positions.size(); i++ ) {
stream << (documentData->positions[i] - lastPosition);
lastPosition = documentData->positions[i];
positions++; listPositions++;
}
iterator->nextEntry();
}
indri::index::TermData* td = iterator->termData();
assert( listPositions == td->corpus.totalCount );
assert( listDocs == td->corpus.documentCount );
}
assert( docs == termData->corpus.documentCount );
assert( positions == termData->corpus.totalCount );
// write in the final skip info
_writeBatch( _invertedOutput, -1, listBuffer.position(), listBuffer );
UINT64 finalPosition = _invertedOutput->tell();
if( hasTopdocs ) {
_invertedOutput->seek( initialPosition );
_invertedOutput->write( &topdocsCount, sizeof(int) );
assert( topdocs.size() == topdocsCount );
// write these into the topdocs list in order from smallest fraction to largest fraction,
// where fraction = c(w;D)/|D|
while( topdocs.size() ) {
DocListIterator::TopDocument topDocument = topdocs.top();
_invertedOutput->write( &topDocument.document, sizeof(int) );
_invertedOutput->write( &topDocument.count, sizeof(int) );
_invertedOutput->write( &topDocument.length, sizeof(int) );
topdocs.pop();
}
assert( (_invertedOutput->tell() - initialPosition) == topdocsSpace );
_invertedOutput->seek( finalPosition );
}
endOffset = finalPosition;
}
void _fetchText( indri::utility::greedy_vector<TagExtent *>& tags, indri::utility::greedy_vector<char*>& terms ) {
// now, fetch the additional terms
char line[65536];
_buffer.clear();
for( int i=0; i<_count; i++ ) {
// LINK
_in.getline( line, sizeof line-1 );
// LINKDOCNO
_in.getline( line, sizeof line-1 );
// TEXT=
_in.getline( line, sizeof line-1 );
int textLen = strlen(line+6);
strcpy( _buffer.write(textLen+1), line+6 );
_buffer.unwrite(1);
assert( *(_buffer.front()+_buffer.position()-1) == '\"' && "Last character should be a quote" );
}
*(_buffer.write(1)) = 0;
// now there's a bunch of text in _buffer, space separated, with each
// link separated by a " symbol
char* beginWord = 0;
int beginIndex = 0;
char* buffer = _buffer.front();
for( unsigned int i=0; i<_buffer.position(); i++ ) {
if( isalnum(buffer[i]) && !beginWord ) {
beginWord = buffer+i;
if(!beginIndex)
beginIndex = terms.size();
} else if( isspace(buffer[i]) ) {
buffer[i] = 0;
if( beginWord )
terms.push_back( beginWord );
beginWord = 0;
} else if( buffer[i] == '\"' ) {
buffer[i] = 0;
if( beginWord )
terms.push_back( beginWord );
beginWord = 0;
TagExtent * extent = new TagExtent;
extent->name = "inlink";
extent->begin = beginIndex;
extent->end = terms.size();
extent->number = 0;
extent->parent = 0;
assert( extent->begin <= extent->end );
if( beginIndex ) {
tags.push_back(extent);
if( terms.size() > 125000 )
break;
}
beginIndex = 0;
}
}
}
FieldModifier() : fce(NULL), parsed(NULL), _docIter(NULL)
{
termBuffer.grow(1024*1024);
}
