QGIS Developer Tutorials Tim Sutton, 2008 ------------------------------------------------------------------------ 1. Tutorial 1 - Hello World, QGIS style 2. Working with QgsMapCanvas 3. Working with Labels ------------------------------------------------------------------------ 1. Tutorial 1 - Hello World, QGIS style ======================================= [images/tim50x50.png] Ok so not everyone wants a full blown GIS desktop application. Sometimes you want to just have a widget inside your application that displays a map while the main goal of the application lies elsewhere. Perhaps a database frontend with a map display? Updated November 2008 to use cmake build system and the updated QGIS 1.0.0 API. Tim So lets take a little walk through creating a simple mapping widget. It wont do anything much - just load a shape file and display it in a random colour. But it should give you an idea of the potential for using QGIS as an embedded mapping component. Before I carry on, many thanks to Francis Bolduc who wrote the beginnings of this demo and then came onto IRC today to do some communal debugging of his prototype. Francis kindly agreed to make his work generally available - though I've tweaked it a bit to use shapefiles instead of his original postgis demo. We start with typical adding the neccessary includes for our app: // // QGIS Includes // #include <qgsapplication.h> #include <qgsproviderregistry.h> #include <qgssinglesymbolrenderer.h> #include <qgsmaplayerregistry.h> #include <qgsvectorlayer.h> #include <qgsmapcanvas.h> // // Qt Includes // #include <QString> #include <QApplication> #include <QWidget> We use QgsApplication instead of Qt's QApplication, and get some added benifits of various static methods that can be used to locate library paths and so on. The provider registry is a singleton that keeps track of vector data provider plugins. It does all the work for you of loading the plugins and so on. The single symbol renderer is the most basic symbology class. It renders points, lines or polygons in a single colour which is chosen at random by default (though you can set it yourself). Every vector layer must have a symbology associated with it. The map layer registry keeps track of all the layers you are using. The vector layer class inherits from maplayer and extends it to include specialist functionality for vector data. Finally the mapcanvas is really the nub of the matter. Its the drawable widget that our map will be drawn onto. Now we can move on to initialising our application.... int main(int argc, char ** argv) { // Start the Application QgsApplication app(argc, argv, true); QString myPluginsDir = "/home/timlinux/apps/lib/qgis"; QString myLayerPath = "/home/timlinux/gisdata/brazil/BR_Cidades/"; QString myLayerBaseName = "Brasil_Cap"; QString myProviderName = "ogr"; So now we have a qgsapplication and we have defined some variables. Since I tested this on the Ubuntu 8.10, I just specified the location of the vector provider plugins as being inside the my development install directory. It would probaby make more sense in general to keep the QGIS libs in one of the standard library search paths on your system (e.g. /usr/lib) but this way will do for now. The next two variables defined here just point to the shapefile I am going to be using (and you should substitute your own data here). The provider name is important - it tells qgis which data provider to use to load the file. Typically you will use 'ogr' or 'postgres'. Now we can go on to actually create our layer object. // Instantiate Provider Registry QgsProviderRegistry::instance(myPluginsDir); First we get the provider registry initialised. Its a singleton class so we use the static instance call and pass it the provider lib search path. As it initialises it will scan this path for provider libs. Now we go on to create a layer... QgsVectorLayer * mypLayer = new QgsVectorLayer(myLayerPath, myLayerBaseName, myProviderName); QgsSingleSymbolRenderer *mypRenderer = new QgsSingleSymbolRenderer(mypLayer->geometryType()); QList <QgsMapCanvasLayer> myLayerSet; mypLayer->setRenderer(mypRenderer); if (mypLayer->isValid()) { qDebug("Layer is valid"); } else { qDebug("Layer is NOT valid"); } // Add the Vector Layer to the Layer Registry QgsMapLayerRegistry::instance()->addMapLayer(mypLayer, TRUE); // Add the Layer to the Layer Set myLayerSet.append(QgsMapCanvasLayer(mypLayer, TRUE)); The code is fairly self explanatory here. We create a layer using the variables we defined earlier. Then we assign the layer a renderer. When we create a renderer, we need to specify the geometry type, which do do by asking the vector layer for its geometry type. Next we add the layer to a layerset (which is used by the QgsMapCanvas to keep track of which layers to render and in what order) and to the maplayer registry. Finally we make sure the layer will be visible. Now we create a map canvas on to which we can draw the layer. // Create the Map Canvas QgsMapCanvas * mypMapCanvas = new QgsMapCanvas(0, 0); mypMapCanvas->setExtent(mypLayer->extent()); mypMapCanvas->enableAntiAliasing(true); mypMapCanvas->setCanvasColor(QColor(255, 255, 255)); mypMapCanvas->freeze(false); // Set the Map Canvas Layer Set mypMapCanvas->setLayerSet(myLayerSet); mypMapCanvas->setVisible(true); mypMapCanvas->refresh(); Once again there is nothing particularly tricky here. We create the canvas and then we set its extents to those of our layer. Next we tweak the canvas a bit to draw antialiased vectors. Next we set the background colour, unfreeze the canvas, make it visible and then refresh it. // Start the Application Event Loop return app.exec(); } In the last step we simply start the Qt event loop and we are all done. Easy as 1-2-3 eh? This example can be checked out of subversion, compiled and run using cmake like this: svn co https://svn.osgeo.org/qgis/trunk/code_examples/1_hello_world_qgis_style cd 1_hello_world_qgis_style mkdir build #optionally specify where your QGIS is installed (should work on all platforms) #if your QGIS is installed to /usr or /usr/local you can leave this next step out export LIB_DIR=/home/timlinux/apps cmake .. make ./timtut1 When we compile and run it here is what the running app looks like: [images/tutorial1.jpg] 2. Working with QgsMapCanvas ============================ [images/tim50x50.png]Tutorial 1 showed you the useage of the QgsMapCanvas api to create a simple application that loads a shapefile and displays the points in it. But what good is map that you can't interact with? Enter our second tutorial where we show you how to use QgsMapTool - the base class for all tools that need to interact with the canvas. **Updated November 2008 to use cmake build system and the updated QGIS 1.0.0 API. Tim** [images/tutorial2.jpg] Today I will extend the last tutorial by making it a QMainWindow application with a menu, toolbar and canvas area. The purpose of the tutorial is to provide a demonstrator project, so I wont promise to write the most elegant or robust C++ code. The project will provide 4 toolbar icons for - loading a map layer (layer name is hard coded in the application - zooming in - zooming out - panning The entire project can be checked out form the QGIS Subversion repository using the following command: `svn co https://svn.osgeo.org/qgis/trunk/code_examples/2_basic_main_window` In the working directory for the tutorial code you will find a number of files including c++ sources, icons and a simple data file under data. There is also the .ui file for the main window. Since much of the code is the same as the previous tutorial, I will focus on the MapTool specifics - the rest of the implementation details can be investigated by checking out the project form SVN. A QgsMapTool is a class that interacts with the MapCanvas using the mouse pointer. QGIS has a number of QgsMapTools implemented, and you can subclass QgsMapTool to create your own. In mainwindow.cpp you will see I include the headers for the QgsMapTools near the start of the file: // // QGIS Map tools // #include "qgsmaptoolpan.h" #include "qgsmaptoolzoom.h" // // These are the other headers for available map tools // (not used in this example) // //#include "qgsmaptoolcapture.h" //#include "qgsmaptoolidentify.h" //#include "qgsmaptoolselect.h" //#include "qgsmaptoolvertexedit.h" //#include "qgsmeasure.h" As you can see, I am only using two types of MapTool subclasses for this tutorial, but there are more available in the QGIS library. Hooking up our MapTools to the canvas is very easy using the normal Qt4 signal/slot mechanism: //create the action behaviours connect(mActionPan, SIGNAL(triggered()), this, SLOT(panMode())); connect(mActionZoomIn, SIGNAL(triggered()), this, SLOT(zoomInMode())); connect(mActionZoomOut, SIGNAL(triggered()), this, SLOT(zoomOutMode())); connect(mActionAddLayer, SIGNAL(triggered()), this, SLOT(addLayer())); Next we make a small toolbar to hold our toolbuttons. Note that the mpAction* actions were created in designer. //create a little toolbar mpMapToolBar = addToolBar(tr("File")); mpMapToolBar->addAction(mpActionAddLayer); mpMapToolBar->addAction(mpActionZoomIn); mpMapToolBar->addAction(mpActionZoomOut); mpMapToolBar->addAction(mpActionPan); Thats really pretty straightforward Qt stuff too. Now we create our three map tools: //create the maptools mpPanTool = new QgsMapToolPan(mpMapCanvas); mpPanTool->setAction(mpActionPan); mpZoomInTool = new QgsMapToolZoom(mpMapCanvas, FALSE); // false = in mpZoomInTool->setAction(mpActionZoomIn); mpZoomOutTool = new QgsMapToolZoom(mpMapCanvas, TRUE ); //true = out mpZoomOutTool->setAction(mpActionZoomOut); Again nothing here is very complicated - we are creating tool instances, each of which is associated with the same mapcanvas, and a different QAction. When the user selects one of the toolbar icons, the active MapTool for the canvas is set. For example when the pan icon is clicked, we do this: void MainWindow::panMode() { mpMapCanvas->setMapTool(mpPanTool); } Conclusion As you can see extending our previous example into something more functional using MapTools is really easy and only requires a few lines of code for each MapTool you want to provide. You can check out and build this tutorial using SVN and CMake using the following steps: svn co https://svn.osgeo.org/qgis/trunk/code_examples/2_basic_main_window cd 2_basic_main_window mkdir build cd build #optionally specify where your QGIS is installed (should work on all platforms) #if your QGIS is installed to /usr or /usr/local you can leave this next step out export LIB_DIR=/home/timlinux/apps cmake .. make ./timtut2 A final note I don't often check the comments on these posts - if you are stuck please write to the [QGIS Developer mailing list http://qgis.org/content/view/115/96/"]! Thanks.Tim 3. Working with Labels ====================== [images/tim50x50.png]In my last tutorial I briefly ran through using map tools to facilitate user interaction with the map canvas. Today we will take a brief look at labelling features. Updated November 2008 to use cmake build system and the updated QGIS 1.0.0 API. Tim [images/tutorial3.jpg] Before I carry on too far, note that QGIS's automatic labelling algorithm is very primative. Martin Dobias is planning to implement a much more useful label placement routine - but its not available at the time of writing this. For the best label placement results you should defined fields in your attribute table for position, rotation etc of the label. Since this is only intended to be a 'get you started' introduction, I won't be doing all that here... The entire project can be checked out form the QGIS Subversion repository using the following command: svn co https://svn.osgeo.org/qgis/trunk/code_examples/3_basic_labelling In the working directory for the tutorial code you will find a number of files including c++ sources, icons and a simple data file under data. There is also the .ui file for the main window. Labelling Specifics If you look in mainwindow.cpp you will notice a couple of new includes introduced since the last tutorial: #include <qgslabel.h> #include <qgslabelattributes.h> #include <qgsfield.h> Each vector layer can have a QgsLabel associated with it. A QgsLabel is a renderer for labels. It has a member of type QgsLabelAttributes which determines the placement (above / below / left / right etc), rotation, size, size units (points or map units), font, colour and various other elements of the label. The QgsField include is needed because we will be querying the vector layer for its available fields so that we can determine which field should be used for labelling. In the same cpp file you will see I define a label and a label attributes pointer. These will be used to setup the labelling characteristics we want and then assigned to the layer: QgsLabel * mypLabel; QgsLabelAttributes * mypLabelAttributes; Now we will see how we actually initialise and assign the QgsLabel and the QgsLabelAttributes to the vector layer. // //set up labelling for the layer // //get the label instance associated with the layer QgsLabel * mypLabel; mypLabel = mypLayer->label(); //and the label attributes associated with the label QgsLabelAttributes * mypLabelAttributes; mypLabelAttributes = mypLabel->layerAttributes(); Great now we have a handle on the QgsLabel and QgsLabelAttributes we can start to manipulate how the label will be displayed. Note that the mypLabel->layerAttributes() method is poorly named and will likely be changed (to labelAttributes()) before the final release of QGIS 1.0. Ok next lets ask the vector layer's data provider what attribute fields it has so that we can select one to be used for labelling: //get the field list associated with the layer //we'll print the names out to console for diagnostic purposes QgsFieldMap myFields = mypLayer->dataProvider()->fields(); for (unsigned int i = 0; i < myFields.size(); i++ ) { qDebug("Field Name: " + QString(myFields[i].name()).toLocal8Bit() ); } By the way - you can browse the code for field, label, label attributes etc from ["QGIS Source browser" http://trac.osgeo.org/qgis/browser/trunk/qgis/src/]. Look in the 'core' and 'gui' subdirectories. Also for more implementation examples of how to set up labelling, it is worth taking a look at [qgslabeldialog.cpp http://trac.osgeo.org/qgis/browser/trunk/qgis/src/gui/qgslabeldialog.cpp]. With access to the list of fields in your vector layer, you can then for example present the user with a combo box to select a label field. In this simple tutorial though I am simply going to use the last field in the attribute table. Its a bit of a no brainer because our attribute table only has one field! But at least this way its soft coded... //just use the last field's name in the fields list as the label field! qDebug("set label field to " + myFields[myFields.size()-1].name()); mypLabel->setLabelField( QgsLabel::Text, myFields.size()-1); There are a bunch of other things we can do to manipulate the appearance of the label. Lets set the text colour to black and draw a yellow 1 point 'halo' buffer around it so the label won't get lost when there are black features behind it: //set the colour of the label text mypLabelAttributes->setColor(Qt::black); //create a 'halo' effect around each label so it //can still be read on dark backgrounds mypLabelAttributes->setBufferEnabled(true); mypLabelAttributes->setBufferColor(Qt::yellow); int myType = QgsLabelAttributes::PointUnits; mypLabelAttributes->setBufferSize(1,myType); Finally we need to tell the layer that rendering of labels should be enabled: mypLayer->enableLabels(true); For the absolute best labelling results, I advise you to store all the label properties you can inside your attribute table. Doing this will allow you to set rotation, placement etc on a per label basis. I left some comments in the tutorial source code that will get you started with this: /* * Here are a bunch of other things you can set based on values on a database field * the second parameter in each case would be the field name from which the * attribute can be retrieved. mypLabel->setLabelField( QgsLabel::Family, "fontFamily" ); mypLabel->setLabelField( QgsLabel::Bold, "fontIsBold" ); mypLabel->setLabelField( QgsLabel::Italic, "fontIsItalic" ); mypLabel->setLabelField( QgsLabel::Underline, "fontIsUnderlined" ); mypLabel->setLabelField( QgsLabel::Size, "fontSize" ); mypLabel->setLabelField( QgsLabel::BufferSize,"fontBufferSize" ); mypLabel->setLabelField( QgsLabel::XCoordinate, "labelX" ); mypLabel->setLabelField( QgsLabel::YCoordinate, "labelY"); mypLabel->setLabelField( QgsLabel::XOffset, "labelXOffset"); mypLabel->setLabelField( QgsLabel::YOffset, "labelYOffset"); mypLabel->setLabelField( QgsLabel::Alignment, "labelAlignment" ); mypLabel->setLabelField( QgsLabel::Angle, "labelAngle"); */ Well that wraps up this tutorial. One thing I noticed is that the canvas is not refreshing properly sometimes on the mac unless you cover the application briefly with another window. Ill post an update here if I figure out what is causing this. You can check out and build this tutorial using SVN and CMake using the following steps: svn co https://svn.osgeo.org/qgis/trunk/code_examples/3_basic_labelling cd 3_basic_labelling mkdir build cd build #optionally specify where your QGIS is installed (should work on all platforms) #if your QGIS is installed to /usr or /usr/local you can leave this next step out export LIB_DIR=/home/timlinux/apps cmake .. make ./timtut3 Mac Specific Notes After building the application bundle (cmake; make) you can copy the spatial reference system database into the bundle to avoid 'cant find resource' type errors: mkdir -p qgis_example3.app/Contents/MacOS/share/qgis/resources/ cp -r /Applications/qgis.app/Contents/MacOS/share/qgis/resources/* \ qgis_example3.app/Contents/MacOS/share/qgis/resources/