File indexing completed on 2024-04-21 03:50:45

 // SPDX-FileCopyrightText: 2011 Dennis Nienhüser <nienhueser@kde.org>
 //
 // SPDX-License-Identifier: GPL-3.0-or-later
 //
 // This file originates from the MoNav project where it was named pbfreader.h and
 // SPDX-FileCopyrightText: 2010 Christian Vetter <veaac.fdirct@gmail.com>
 //
 
 #include "PbfParser.h"
 
 #include <QDebug>
 
 #include <zlib.h>
 
 #include <fstream>
 
 #include <netinet/in.h>
 
 using namespace std;
 using namespace OSMPBF;
 
 PbfParser::PbfParser() :
     m_currentGroup( 0 ),
     m_currentEntity( 0 ),
     m_loadBlock( false )
 {
     GOOGLE_PROTOBUF_VERIFY_VERSION;
 }
 
 bool PbfParser::parse( const QFileInfo &fileInfo, int pass, bool &needAnotherPass )
 {
     m_pass = pass;
     needAnotherPass = pass < 2;
 
     QFile file( fileInfo.absoluteFilePath() );
     if ( !file.open( QFile::ReadOnly ) ) {
         qCritical() << "Unable to open file " << fileInfo.absoluteFilePath() << " for reading.";
         return false;
     }
 
     m_stream.setDevice( &file );
     m_stream.setByteOrder( QDataStream::BigEndian );
 
     if ( !parseBlobHeader() ) {
         return false;
     }
 
     if ( m_blobHeader.type() != "OSMHeader" ) {
         qCritical() << "Unable to parse blob header type " << m_blobHeader.type().c_str();
         return false;
     }
 
     if ( !parseBlob() ) {
         return false;
     }
 
     if ( !parseData() ) {
         return false;
     }
 
     m_loadBlock = true;
 
     while ( true ) {
 
         if ( m_loadBlock ) {
             if ( !readNext() ) {
                 if ( pass == 1 ) {
                     m_referencedWays.clear();
                 } else if ( pass == 2 ) {
                     m_referencedNodes.clear();
                 }
 
                 return true;
             }
             loadBlock();
             loadGroup();
         }
 
         switch ( m_mode ) {
         case ModeNode:
             parseNode();
             break;
         case ModeWay:
             parseWay();
             break;
         case ModeRelation:
             parseRelation();
             break;
         case ModeDense:
             parseDense();
             break;
         }
     }
 
     return true;
 }
 
 bool PbfParser::parseBlobHeader()
 {
     int size( -1 );
     m_stream >> size;
 
     if ( size < 0 ) {
         qCritical() << "Invalid blob header size " << size;
         return false;
     }
 
     m_buffer.resize( size );
     int readBytes = m_stream.readRawData( m_buffer.data(), size );
     if ( readBytes != size ) {
         qCritical() << "Unable to read blob header";
         return false;
     }
 
     if ( !m_blobHeader.ParseFromArray( m_buffer.constData(), size ) ) {
         qCritical() << "Unable to parse blob header";
         return false;
     }
 
     return true;
 }
 
 bool PbfParser::parseBlob()
 {
     int size = m_blobHeader.datasize();
     if ( size < 0 ) {
         qCritical() << "invalid blob size:" << size;
         return false;
     }
 
     m_buffer.resize( size );
     int readBytes = m_stream.readRawData( m_buffer.data(), size );
     if ( readBytes != size ) {
         qCritical() << "failed to read blob";
         return false;
     }
 
     if ( !m_blob.ParseFromArray( m_buffer.constData(), size ) ) {
         qCritical() << "failed to parse blob";
         return false;
     }
 
     if ( m_blob.has_raw() ) {
         const std::string& data = m_blob.raw();
         m_buffer.resize( data.size() );
         for ( unsigned int i = 0; i < data.size(); ++i ) {
             m_buffer[i] = data[i];
         }
     } else if ( m_blob.has_zlib_data() ) {
         m_buffer.resize( m_blob.raw_size() );
         z_stream zStream;
         zStream.next_in = ( unsigned char* ) m_blob.zlib_data().data();
         zStream.avail_in = m_blob.zlib_data().size();
         zStream.next_out = ( unsigned char* ) m_buffer.data();
         zStream.avail_out = m_blob.raw_size();
         zStream.zalloc = Z_NULL;
         zStream.zfree = Z_NULL;
         zStream.opaque = Z_NULL;
         int result = inflateInit( &zStream );
         if ( result != Z_OK ) {
             qCritical() << "failed to open zlib m_stream";
             return false;
         }
         result = inflate( &zStream, Z_FINISH );
         if ( result != Z_STREAM_END ) {
             qCritical() << "failed to inflate zlib m_stream";
             return false;
         }
         result = inflateEnd( &zStream );
         if ( result != Z_OK ) {
             qCritical() << "failed to close zlib m_stream";
             return false;
         }
 
         return true;
     } else if ( m_blob.has_lzma_data() ) {
         qCritical() << "No support for lzma decryption implemented, sorry.";
         return false;
     } else {
         qCritical() << "Blob contains no data";
         return false;
     }
 
     return true;
 }
 
 bool PbfParser::parseData()
 {
     if ( !m_headerBlock.ParseFromArray( m_buffer.data(), m_buffer.size() ) ) {
         qCritical() << "failed to parse header block";
         return false;
     }
 
     for ( int i = 0; i < m_headerBlock.required_features_size(); ++i ) {
         string const & feature = m_headerBlock.required_features( i );
         if ( feature != "OsmSchema-V0.6" && feature != "DenseNodes" ) {
             qCritical() << "Support for feature " << feature.c_str() << "not implemented";
             return false;
         }
     }
 
     return true;
 }
 
 bool PbfParser::readNext()
 {
     if ( !parseBlobHeader() )
         return false;
 
     if ( m_blobHeader.type() != "OSMData" ) {
         qCritical() << "invalid block type, found" << m_blobHeader.type().data() << "instead of OSMData";
         return false;
     }
 
     if ( !parseBlob() )
         return false;
 
     if ( !m_primitiveBlock.ParseFromArray( m_buffer.data(), m_buffer.size() ) ) {
         qCritical() << "failed to parse PrimitiveBlock";
         return false;
     }
     return true;
 }
 
 void PbfParser::loadGroup()
 {
     const PrimitiveGroup& group = m_primitiveBlock.primitivegroup( m_currentGroup );
     if ( group.nodes_size() != 0 ) {
         m_mode = ModeNode;
     } else if ( group.ways_size() != 0 ) {
         m_mode = ModeWay;
     } else if ( group.relations_size() != 0 ) {
         m_mode = ModeRelation;
     } else if ( group.has_dense() )  {
         m_mode = ModeDense;
         m_lastDenseID = 0;
         m_lastDenseTag = 0;
         m_lastDenseLatitude = 0;
         m_lastDenseLongitude = 0;
         assert( group.dense().id_size() != 0 );
     } else
         assert( false );
 }
 
 void PbfParser::loadBlock()
 {
     m_loadBlock = false;
     m_currentGroup = 0;
     m_currentEntity = 0;
 }
 
 void PbfParser::parseNode()
 {
     if ( m_pass == 2 ) {
         const Node& inputNode = m_primitiveBlock.primitivegroup( m_currentGroup ).nodes( m_currentEntity );
         Marble::Node node;
         node.lat = ( ( double ) inputNode.lat() * m_primitiveBlock.granularity() + m_primitiveBlock.lat_offset() ) / ( 1000.0 * 1000.0 * 1000.0 );
         node.lon = ( ( double ) inputNode.lon() * m_primitiveBlock.granularity() + m_primitiveBlock.lon_offset() ) / ( 1000.0 * 1000.0 * 1000.0 );
 
         for ( int tag = 0; tag < inputNode.keys_size(); tag++ ) {
 
             QString key = QString::fromUtf8( m_primitiveBlock.stringtable().s( inputNode.keys( tag ) ).data() );
             QString value = QString::fromUtf8( m_primitiveBlock.stringtable().s( inputNode.vals( tag ) ).data() );
 
             if (key == QLatin1String("name")) {
                 node.name = value.trimmed();
             } else if (key == QLatin1String("addr:street")) {
                 node.street = value.trimmed();
                 node.save = true;
             } else if (key == QLatin1String("addr:housenumber")) {
                 node.houseNumber = value;
                 node.save = true;
             } else if (key == QLatin1String("addr:city")) {
                 node.city = value;
                 node.save = true;
             } else {
                 if ( shouldSave( Marble::NodeType, key, value ) ) {
                     node.save = true;
                 }
                 setCategory( node, key, value );
             }
         }
 
         if ( node.save ) {
             m_nodes[inputNode.id()] = node;
         }
 
         if ( m_referencedNodes.contains( inputNode.id() ) ) {
             m_coordinates[inputNode.id()] = node;
         }
     }
 
     m_currentEntity++;
     if ( m_currentEntity >= m_primitiveBlock.primitivegroup( m_currentGroup ).nodes_size() ) {
         m_currentEntity = 0;
         m_currentGroup++;
         if ( m_currentGroup >= m_primitiveBlock.primitivegroup_size() )
             m_loadBlock = true;
         else
             loadGroup();
     }
 }
 
 void PbfParser::parseWay()
 {
     if ( m_pass == 1 ) {
         const Way& inputWay = m_primitiveBlock.primitivegroup( m_currentGroup ).ways( m_currentEntity );
         Marble::Way way;
         Marble::Relation relation;
 
         for ( int tag = 0; tag < inputWay.keys_size(); tag++ ) {
             QString key = QString::fromUtf8( m_primitiveBlock.stringtable().s( inputWay.keys( tag ) ).data() );
             QString value = QString::fromUtf8( m_primitiveBlock.stringtable().s( inputWay.vals( tag ) ).data() );
 
             if (key == QLatin1String("name")) {
                 way.name = value.trimmed();
             } else if (key == QLatin1String("addr:street")) {
                 way.street = value.trimmed();
                 way.save = true;
             } else if (key == QLatin1String("addr:housenumber")) {
                 way.houseNumber = value;
                 way.save = true;
             } else if (key == QLatin1String("addr:city")) {
                 way.city = value;
                 way.save = true;
             } else if (key == QLatin1String("building") && value == QLatin1String("yes")) {
                 way.isBuilding = true;
             } else if (key == QLatin1String("boundary") && value == QLatin1String("administrative")) {
                 relation.isAdministrativeBoundary = true;
             } else if (key == QLatin1String("admin_level")) {
                 relation.adminLevel = value.toInt();
             } else  {
                 if ( shouldSave( Marble::WayType, key, value ) ) {
                     way.save = true;
                 }
                 setCategory( way, key, value );
             }
         }
 
         long long lastRef = 0;
         for ( int i = 0; i < inputWay.refs_size(); i++ ) {
             lastRef += inputWay.refs( i );
             way.nodes.push_back( lastRef );
         }
 
         if ( relation.isAdministrativeBoundary && !way.name.isEmpty() ) {
             relation.name = way.name;
             relation.ways << QPair<int, Marble::RelationRole>( inputWay.id(), Marble::Outer );
             m_relations[inputWay.id()] = relation;
         }
 
         if ( way.save || m_referencedWays.contains( inputWay.id() ) ) {
             if ( !way.isBuilding && way.nodes.size() > 1 && !m_referencedWays.contains( inputWay.id() ) ) {
                 QList<int> nodes = way.nodes;
                 way.nodes.clear();
                 way.nodes << nodes.first();
                 if ( nodes.size() > 2 ) {
                     way.nodes << nodes.at( nodes.size() / 2 );
                 }
                 way.nodes << nodes.last();
             }
 
             for( int node: way.nodes ) {
                 m_referencedNodes << node;
             }
 
             m_ways[inputWay.id()] = way;
         }
     }
 
     m_currentEntity++;
     if ( m_currentEntity >= m_primitiveBlock.primitivegroup( m_currentGroup ).ways_size() ) {
         m_currentEntity = 0;
         m_currentGroup++;
         if ( m_currentGroup >= m_primitiveBlock.primitivegroup_size() )
             m_loadBlock = true;
         else
             loadGroup();
     }
 }
 
 void PbfParser::parseRelation()
 {
     if ( m_pass == 0 ) {
         const Relation& inputRelation = m_primitiveBlock.primitivegroup( m_currentGroup ).relations( m_currentEntity );
         Marble::Relation relation;
 
         for ( int tag = 0; tag < inputRelation.keys_size(); tag++ ) {
 
             QString key = QString::fromUtf8( m_primitiveBlock.stringtable().s( inputRelation.keys( tag ) ).data() );
             QString value = QString::fromUtf8( m_primitiveBlock.stringtable().s( inputRelation.vals( tag ) ).data() );
 
             if (key == QLatin1String("boundary") && value == QLatin1String("administrative")) {
                 relation.isAdministrativeBoundary = true;
             } else if (key == QLatin1String("admin_level")) {
                 relation.adminLevel = value.toInt();
             } else if (key == QLatin1String("name")) {
                 relation.name = value.trimmed();
             } else if (key == QLatin1String("type") && value == QLatin1String("multipolygon")) {
                 relation.isMultipolygon = true;
             }
         }
 
         if ( relation.isAdministrativeBoundary ) {
             long long lastRef = 0;
             for ( int i = 0; i < inputRelation.types_size(); i++ ) {
                 lastRef += inputRelation.memids( i );
                 switch ( inputRelation.types( i ) ) {
                 case OSMPBF::Relation::NODE:
                     relation.nodes.push_back( lastRef );
                     break;
                 case OSMPBF::Relation::WAY: {
                     string role = m_primitiveBlock.stringtable().s( inputRelation.roles_sid( i ) ).data();
                     Marble::RelationRole relationRole = Marble::None;
                     if ( role == "outer" ) relationRole = Marble::Outer;
                     if ( role == "inner" ) relationRole = Marble::Inner;
                     m_referencedWays << lastRef;
                     relation.ways.push_back( QPair<int, Marble::RelationRole>( lastRef, relationRole ) );
                 }
                 break;
                 case OSMPBF::Relation::RELATION:
                     relation.relations.push_back( lastRef );
                 }
             }
 
             m_relations[inputRelation.id()] = relation;
         }
     }
 
     m_currentEntity++;
     if ( m_currentEntity >= m_primitiveBlock.primitivegroup( m_currentGroup ).relations_size() ) {
         m_currentEntity = 0;
         m_currentGroup++;
         if ( m_currentGroup >= m_primitiveBlock.primitivegroup_size() )
             m_loadBlock = true;
         else
             loadGroup();
     }
 }
 
 void PbfParser::parseDense()
 {
     const DenseNodes& dense = m_primitiveBlock.primitivegroup( m_currentGroup ).dense();
     if ( m_pass == 2 ) {
         m_lastDenseID += dense.id( m_currentEntity );
         m_lastDenseLatitude += dense.lat( m_currentEntity );
         m_lastDenseLongitude += dense.lon( m_currentEntity );
 
         Marble::Node node;
         node.lat = ( ( double ) m_lastDenseLatitude * m_primitiveBlock.granularity() + m_primitiveBlock.lat_offset() ) / ( 1000.0 * 1000.0 * 1000.0 );
         node.lon = ( ( double ) m_lastDenseLongitude * m_primitiveBlock.granularity() + m_primitiveBlock.lon_offset() ) / ( 1000.0 * 1000.0 * 1000.0 );
 
         while ( true ) {
             if ( m_lastDenseTag >= dense.keys_vals_size() )
                 break;
 
             int tagValue = dense.keys_vals( m_lastDenseTag );
             if ( tagValue == 0 ) {
                 m_lastDenseTag++;
                 break;
             }
 
             QString key = QString::fromUtf8( m_primitiveBlock.stringtable().s( dense.keys_vals( m_lastDenseTag ) ).data() );
             QString value = QString::fromUtf8( m_primitiveBlock.stringtable().s( dense.keys_vals( m_lastDenseTag + 1 ) ).data() );
 
             if (key == QLatin1String("name")) {
                 node.name = value.trimmed();
             } else if (key == QLatin1String("addr:street")) {
                 node.street = value.trimmed();
                 node.save = true;
             } else if (key == QLatin1String("addr:housenumber")) {
                 node.houseNumber = value;
                 node.save = true;
             } else if (key == QLatin1String("addr:city")) {
                 node.city = value;
                 node.save = true;
             } else {
                 if ( shouldSave( Marble::NodeType, key, value ) ) {
                     node.save = true;
                 }
                 setCategory( node, key, value );
             }
 
             m_lastDenseTag += 2;
         }
 
         if ( node.save) {
             m_nodes[m_lastDenseID] = node;
         }
 
         if ( m_referencedNodes.contains( m_lastDenseID ) ) {
             m_coordinates[m_lastDenseID] = node;
         }
     }
 
     ++m_currentEntity;
     if ( m_currentEntity >= dense.id_size() ) {
         m_currentEntity = 0;
         m_currentGroup++;
         if ( m_currentGroup >= m_primitiveBlock.primitivegroup_size() ) {
             m_loadBlock = true;
         } else {
             loadGroup();
         }
     }
 }