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https://github.com/minetest/irrlicht.git
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392 lines
12 KiB
C++
392 lines
12 KiB
C++
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/** Example 016 Quake3 Map Shader Support
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This tutorial shows how to load a Quake 3 map into the
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engine, create a SceneNode for optimizing the speed of
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rendering and how to create a user controlled camera.
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Lets start like the HelloWorld example: We include
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the irrlicht header files and an additional file to be able
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to ask the user for a driver type using the console.
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*/
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#include <irrlicht.h>
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#include "driverChoice.h"
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#include "exampleHelper.h"
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/*
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define which Quake3 Level should be loaded
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*/
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#define IRRLICHT_QUAKE3_ARENA
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//#define ORIGINAL_QUAKE3_ARENA
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//#define CUSTOM_QUAKE3_ARENA
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//#define SHOW_SHADER_NAME
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#ifdef ORIGINAL_QUAKE3_ARENA
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#define QUAKE3_STORAGE_FORMAT addFolderFileArchive
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#define QUAKE3_STORAGE_1 "/baseq3/"
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#ifdef CUSTOM_QUAKE3_ARENA
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#define QUAKE3_STORAGE_2 "/cf/"
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#define QUAKE3_MAP_NAME "maps/cf.bsp"
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#else
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#define QUAKE3_MAP_NAME "maps/q3dm8.bsp"
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#endif
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#endif
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#ifdef IRRLICHT_QUAKE3_ARENA
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#define QUAKE3_STORAGE_FORMAT addFileArchive
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#define QUAKE3_STORAGE_1 getExampleMediaPath() + "map-20kdm2.pk3"
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#define QUAKE3_MAP_NAME "maps/20kdm2.bsp"
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#endif
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using namespace irr;
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using namespace scene;
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/*
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Again, to be able to use the Irrlicht.DLL file, we need to link with the
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Irrlicht.lib. We could set this option in the project settings, but
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to make it easy, we use a pragma comment lib:
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*/
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#ifdef _MSC_VER
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#pragma comment(lib, "Irrlicht.lib")
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#endif
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/*
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A class to produce a series of screenshots
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*/
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class CScreenShotFactory : public IEventReceiver
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{
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public:
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CScreenShotFactory( IrrlichtDevice *device, const c8 * templateName, ISceneNode* node )
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: Device(device), Number(0), FilenameTemplate(templateName), Node(node)
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{
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FilenameTemplate.replace ( '/', '_' );
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FilenameTemplate.replace ( '\\', '_' );
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}
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bool OnEvent(const SEvent& event)
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{
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// check if user presses the key F9
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if ((event.EventType == EET_KEY_INPUT_EVENT) &&
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event.KeyInput.PressedDown)
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{
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if (event.KeyInput.Key == KEY_F9)
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{
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video::IImage* image = Device->getVideoDriver()->createScreenShot();
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if (image)
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{
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c8 buf[256];
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snprintf_irr(buf, 256, "%s_shot%04d.jpg",
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FilenameTemplate.c_str(),
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++Number);
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Device->getVideoDriver()->writeImageToFile(image, buf, 85 );
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image->drop();
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}
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}
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else
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if (event.KeyInput.Key == KEY_F8)
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{
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if (Node->isDebugDataVisible())
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Node->setDebugDataVisible(scene::EDS_OFF);
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else
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Node->setDebugDataVisible(scene::EDS_BBOX_ALL);
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}
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}
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return false;
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}
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private:
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IrrlichtDevice *Device;
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u32 Number;
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core::stringc FilenameTemplate;
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ISceneNode* Node;
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};
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/*
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Ok, lets start.
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*/
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int IRRCALLCONV main(int argc, char* argv[])
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{
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/*
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Like in the HelloWorld example, we create an IrrlichtDevice with
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createDevice(). The difference now is that we ask the user to select
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which hardware accelerated driver to use. The Software device would be
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too slow to draw a huge Quake 3 map, but just for the fun of it, we make
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this decision possible too.
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*/
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// ask user for driver
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video::E_DRIVER_TYPE driverType=driverChoiceConsole();
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if (driverType==video::EDT_COUNT)
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return 1;
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// create device and exit if creation failed
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const core::dimension2du videoDim(800,600);
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IrrlichtDevice *device = createDevice(driverType, videoDim, 32, false );
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if (device == 0)
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return 1; // could not create selected driver.
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const char* mapname=0;
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if (argc>2)
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mapname = argv[2];
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else
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mapname = QUAKE3_MAP_NAME;
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/*
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Get a pointer to the video driver and the SceneManager so that
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we do not always have to write device->getVideoDriver() and
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device->getSceneManager().
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*/
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video::IVideoDriver* driver = device->getVideoDriver();
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scene::ISceneManager* smgr = device->getSceneManager();
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gui::IGUIEnvironment* gui = device->getGUIEnvironment();
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const io::path mediaPath = getExampleMediaPath();
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//! add our private media directory to the file system
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device->getFileSystem()->addFileArchive(mediaPath);
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/*
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To display the Quake 3 map, we first need to load it. Quake 3 maps
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are packed into .pk3 files, which are nothing other than .zip files.
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So we add the .pk3 file to our FileSystem. After it was added,
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we are able to read from the files in that archive as they would
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directly be stored on disk.
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*/
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if (argc>2)
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device->getFileSystem()->QUAKE3_STORAGE_FORMAT(argv[1]);
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else
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device->getFileSystem()->QUAKE3_STORAGE_FORMAT(QUAKE3_STORAGE_1);
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#ifdef QUAKE3_STORAGE_2
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device->getFileSystem()->QUAKE3_STORAGE_FORMAT(QUAKE3_STORAGE_2);
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#endif
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// Quake3 Shader controls Z-Writing
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smgr->getParameters()->setAttribute(scene::ALLOW_ZWRITE_ON_TRANSPARENT, true);
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/*
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Now we can load the mesh by calling getMesh(). We get a pointer returned
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to a IAnimatedMesh. As you know, Quake 3 maps are not really animated,
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they are only a huge chunk of static geometry with some materials
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attached. Hence the IAnimated mesh consists of only one frame,
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so we get the "first frame" of the "animation", which is our quake level
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and create an Octree scene node with it, using addOctreeSceneNode().
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The Octree optimizes the scene a little bit, trying to draw only geometry
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which is currently visible. An alternative to the Octree would be a
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AnimatedMeshSceneNode, which would draw always the complete geometry of
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the mesh, without optimization. Try it out: Write addAnimatedMeshSceneNode
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instead of addOctreeSceneNode and compare the primitives drawn by the
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video driver. (There is a getPrimitiveCountDrawed() method in the
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IVideoDriver class). Note that this optimization with the Octree is only
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useful when drawing huge meshes consisting of lots of geometry.
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*/
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scene::IQ3LevelMesh* const mesh =
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(scene::IQ3LevelMesh*) smgr->getMesh(mapname);
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/*
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add the geometry mesh to the Scene ( polygon & patches )
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The Geometry mesh is optimised for faster drawing
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*/
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scene::ISceneNode* node = 0;
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if (mesh)
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{
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scene::IMesh * const geometry = mesh->getMesh(quake3::E_Q3_MESH_GEOMETRY);
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node = smgr->addOctreeSceneNode(geometry, 0, -1, 4096);
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}
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// create an event receiver for making screenshots
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CScreenShotFactory screenshotFactory(device, mapname, node);
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device->setEventReceiver(&screenshotFactory);
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/*
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now construct SceneNodes for each Shader
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The Objects are stored in the quake mesh scene::E_Q3_MESH_ITEMS
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and the Shader ID is stored in the MaterialParameters
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mostly dark looking skulls and moving lava.. or green flashing tubes?
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*/
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if ( mesh )
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{
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// the additional mesh can be quite huge and is unoptimized
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const scene::IMesh * const additional_mesh = mesh->getMesh(quake3::E_Q3_MESH_ITEMS);
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#ifdef SHOW_SHADER_NAME
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gui::IGUIFont *font = device->getGUIEnvironment()->getFont(mediaPath + "fontlucida.png");
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u32 count = 0;
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#endif
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for ( u32 i = 0; i!= additional_mesh->getMeshBufferCount(); ++i )
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{
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const IMeshBuffer* meshBuffer = additional_mesh->getMeshBuffer(i);
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const video::SMaterial& material = meshBuffer->getMaterial();
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// The ShaderIndex is stored in the material parameter
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const s32 shaderIndex = (s32) material.MaterialTypeParam2;
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// the meshbuffer can be rendered without additional support, or it has no shader
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const quake3::IShader *shader = mesh->getShader(shaderIndex);
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if (0 == shader)
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{
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continue;
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}
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// we can dump the shader to the console in its
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// original but already parsed layout in a pretty
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// printers way.. commented out, because the console
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// would be full...
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// quake3::dumpShader ( Shader );
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node = smgr->addQuake3SceneNode(meshBuffer, shader);
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#ifdef SHOW_SHADER_NAME
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count += 1;
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core::stringw name( node->getName() );
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node = smgr->addBillboardTextSceneNode(
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font, name.c_str(), node,
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core::dimension2d<f32>(80.0f, 8.0f),
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core::vector3df(0, 10, 0));
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#endif
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}
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}
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/*
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Now we only need a Camera to look at the Quake 3 map. And we want to
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create a user controlled camera. There are some different cameras
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available in the Irrlicht engine. For example the Maya Camera which can
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be controlled comparable to the camera in Maya: Rotate with left mouse
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button pressed, Zoom with both buttons pressed, translate with right
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mouse button pressed. This could be created with
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addCameraSceneNodeMaya(). But for this example, we want to create a
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camera which behaves like the ones in first person shooter games (FPS).
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*/
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scene::ICameraSceneNode* camera = smgr->addCameraSceneNodeFPS();
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/*
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so we need a good starting Position in the level.
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we can ask the Quake3 Loader for all entities with class_name
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"info_player_deathmatch"
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we choose a random launch
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*/
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if ( mesh )
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{
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quake3::tQ3EntityList &entityList = mesh->getEntityList();
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quake3::IEntity search;
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search.name = "info_player_deathmatch";
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s32 index = entityList.binary_search(search);
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if (index >= 0)
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{
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s32 notEndList;
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do
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{
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const quake3::SVarGroup *group = entityList[index].getGroup(1);
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u32 parsepos = 0;
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const core::vector3df pos =
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quake3::getAsVector3df(group->get("origin"), parsepos);
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parsepos = 0;
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const f32 angle = quake3::getAsFloat(group->get("angle"), parsepos);
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core::vector3df target(0.f, 0.f, 1.f);
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target.rotateXZBy(angle);
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camera->setPosition(pos);
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camera->setTarget(pos + target);
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++index;
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/*
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notEndList = ( index < (s32) entityList.size () &&
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entityList[index].name == search.name &&
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(device->getTimer()->getRealTime() >> 3 ) & 1
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);
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*/
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notEndList = index == 2;
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} while ( notEndList );
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}
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}
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/*
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The mouse cursor needs not to be visible, so we make it invisible.
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*/
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device->getCursorControl()->setVisible(false);
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// load the engine logo
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gui->addImage(driver->getTexture("irrlichtlogo2.png"),
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core::position2d<s32>(10, 10));
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// show the driver logo
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const core::position2di pos(videoDim.Width - 128, videoDim.Height - 64);
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switch ( driverType )
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{
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case video::EDT_BURNINGSVIDEO:
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gui->addImage(driver->getTexture("burninglogo.png"), pos);
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break;
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case video::EDT_OPENGL:
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gui->addImage(driver->getTexture("opengllogo.png"), pos);
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break;
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case video::EDT_DIRECT3D9:
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gui->addImage(driver->getTexture("directxlogo.png"), pos);
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break;
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}
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/*
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We have done everything, so lets draw it. We also write the current
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frames per second and the drawn primitives to the caption of the
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window. The 'if (device->isWindowActive())' line is optional, but
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prevents the engine render to set the position of the mouse cursor
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after task switching when other program are active.
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*/
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int lastFPS = -1;
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while(device->run())
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if (device->isWindowActive())
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{
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driver->beginScene(video::ECBF_COLOR | video::ECBF_DEPTH, video::SColor(255,20,20,40));
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smgr->drawAll();
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gui->drawAll();
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driver->endScene();
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int fps = driver->getFPS();
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//if (lastFPS != fps)
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{
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io::IAttributes * const attr = smgr->getParameters();
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core::stringw str = L"Q3 [";
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str += driver->getName();
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str += "] FPS:";
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str += fps;
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#ifdef _IRR_SCENEMANAGER_DEBUG
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str += " Cull:";
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str += attr->getAttributeAsInt("calls");
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str += "/";
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str += attr->getAttributeAsInt("culled");
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str += " Draw: ";
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str += attr->getAttributeAsInt("drawn_solid");
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str += "/";
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str += attr->getAttributeAsInt("drawn_transparent");
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str += "/";
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str += attr->getAttributeAsInt("drawn_transparent_effect");
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#endif
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device->setWindowCaption(str.c_str());
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lastFPS = fps;
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}
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}
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/*
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In the end, delete the Irrlicht device.
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*/
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device->drop();
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return 0;
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}
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/*
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**/
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