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2ae2a551a6
GLES drivers adapted, but only did make compile-tests. git-svn-id: svn://svn.code.sf.net/p/irrlicht/code/branches/ogl-es@6038 dfc29bdd-3216-0410-991c-e03cc46cb475
508 lines
16 KiB
C++
508 lines
16 KiB
C++
// This file is part of the "Irrlicht Engine".
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// For conditions of distribution and use, see copyright notice in irrlicht.h
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// Copyright by Michael Zeilfelder
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/** Example 030 Profiling
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Profiling is used to get runtime information about code code.
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There exist several independent profiling tools.
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Examples for free profilers are "gprof" for the GNU toolchain and "very sleepy"
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from codersnotes for Windows. Proprietary tools are for example "VTune" from
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Intel or "AMD APP Profiler". Those tools work by sampling the running
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application regularly to get statistic information about the called functions.
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The way to use them is to compile your application with special flags
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to include profiling information (some also work with debug information). They
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also might allow to profile only certain parts of the code, although
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most can't do that. The sampling is usually rather time-consuming which means
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the application will be very slow when collecting the profiling data. It's often
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useful to start with one of those tools to get an overview over the bottlenecks
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in your application. Those tools have the advantage that they don't need any
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modifications inside the code.
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Once you need to dig deeper the Irrlicht profiler can help you. It works nearly
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like a stopwatch. You add start/stop blocks into the parts of your code which
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you need to check and the Irrlicht profiler will give you then the exact times
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of execution for those parts. And unlike general profiler tools you don't just
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get average information about the run-time but also worst-cases. Which tends
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to be information you really for a stable framerate. Also the Irrlicht profiler
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has a low overhead and affects only the areas which you want to time. So you
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can profile applications with nearly original speed.
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Irrlicht itself has such profiling information, which is useful to figure out
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where the runtime inside the engine is spend. To get that profiling data you
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need to recompile Irrlicht with _IRR_COMPILE_WITH_PROFILING_ enabled as
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collecting profiling information is disabled by default for speed reasons.
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*/
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/*
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It's usually a good idea to wrap all your profile code with a define.
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That way you don't have to worry too much about the runtime profiling
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itself takes. You can remove the profiling code completely when you release
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the software by removing a single define.Or sometimes you might want to
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have several such defines for different areas of your application code.
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*/
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#define ENABLE_MY_PROFILE // comment out to remove the profiling code
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#ifdef ENABLE_MY_PROFILE
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// calls code X
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#define MY_PROFILE(X) X
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#else
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// removes the code for X in the pre-processor
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#define MY_PROFILE(X)
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#endif // IRR_PROFILE
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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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#ifdef _MSC_VER
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#pragma comment(lib, "Irrlicht.lib")
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#endif
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using namespace irr;
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using namespace core;
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using namespace scene;
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using namespace video;
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using namespace io;
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using namespace gui;
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/*
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We have the choice between working with fixed and with automatic profiling id's.
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Here are some fixed ID's we will be using.
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*/
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enum EProfiles
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{
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EP_APP_TIME_ONCE,
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EP_APP_TIME_UPDATED,
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EP_SCOPE1,
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EP_SCOPE2,
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EP_DRAW_SCENE
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};
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// For our example scenes
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enum EScenes
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{
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ES_NONE, // no scene set
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ES_CUBE,
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ES_QUAKE_MAP,
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ES_DWARVES,
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ES_COUNT // counting how many scenes we have
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};
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/*
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Controlling the profiling display is application specific behavior.
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We use function keys in our case and play around with all the parameters.
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In real applications you will likely only need something to make the
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profiling-display visible/invisible and switch pages while the parameters
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can be set to fixed values.
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*/
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class MyEventReceiver : public IEventReceiver
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{
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public:
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// constructor
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MyEventReceiver(ISceneManager * smgr) : GuiProfiler(0), IncludeOverview(true), IgnoreUncalled(false), ActiveScene(ES_NONE), SceneManager(smgr) {}
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virtual bool OnEvent(const SEvent& event)
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{
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if (event.EventType == EET_KEY_INPUT_EVENT)
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{
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if ( event.KeyInput.PressedDown )
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{
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/*
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Catching keys to control the profiling display and the profiler itself
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*/
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switch ( event.KeyInput.Key )
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{
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case KEY_F1:
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GuiProfiler->setVisible( !GuiProfiler->isVisible() );
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break;
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case KEY_F2:
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GuiProfiler->nextPage(IncludeOverview);
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break;
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case KEY_F3:
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GuiProfiler->previousPage(IncludeOverview);
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break;
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case KEY_F4:
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GuiProfiler->firstPage(IncludeOverview);
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break;
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case KEY_F5:
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IncludeOverview = !IncludeOverview;
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GuiProfiler->firstPage(IncludeOverview); // not strictly needed, but otherwise the update won't update
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break;
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case KEY_F6:
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/*
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You can set more filters. This one filters out profile data which was never called.
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*/
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IgnoreUncalled = !IgnoreUncalled;
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GuiProfiler->setFilters(IgnoreUncalled ? 1 : 0, 0, 0.f, 0);
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break;
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case KEY_F7:
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GuiProfiler->setShowGroupsTogether( !GuiProfiler->getShowGroupsTogether() );
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break;
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case KEY_F8:
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NextScene();
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break;
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case KEY_F9:
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{
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u32 index = 0;
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if ( getProfiler().findGroupIndex(index, L"grp runtime") )
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{
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getProfiler().resetGroup(index);
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}
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}
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break;
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case KEY_F10:
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{
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u32 index = 0;
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if ( getProfiler().findDataIndex(index, L"scope 3") )
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{
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getProfiler().resetDataByIndex(index);
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}
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}
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break;
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case KEY_F11:
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getProfiler().resetAll();
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break;
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case KEY_KEY_F:
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GuiProfiler->setFrozen(!GuiProfiler->getFrozen());
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break;
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default:
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break;
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}
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}
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}
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return false;
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}
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/*
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Some example scenes so we have something to profile
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*/
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void NextScene()
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{
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SceneManager->clear();
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ActiveScene = (ActiveScene+1) % ES_COUNT;
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if ( ActiveScene == 0 )
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ActiveScene = ActiveScene+1;
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switch ( ActiveScene )
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{
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case ES_CUBE:
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{
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/*
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Simple scene with cube and light.
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*/
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MY_PROFILE(CProfileScope p(L"cube", L"grp switch scene");)
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SceneManager->addCameraSceneNode (0, core::vector3df(0, 0, 0),
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core::vector3df(0, 0, 100),
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-1);
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SceneManager->addCubeSceneNode (30.0f, 0, -1,
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core::vector3df(0, 20, 100),
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core::vector3df(45, 45, 45),
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core::vector3df(1.0f, 1.0f, 1.0f));
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SceneManager->addLightSceneNode(0, core::vector3df(0, 0, 0),
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video::SColorf(1.0f, 1.0f, 1.0f),
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100.0f);
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}
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break;
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case ES_QUAKE_MAP:
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{
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/*
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Our typical Irrlicht example quake map.
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*/
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MY_PROFILE(CProfileScope p(L"quake map", L"grp switch scene");)
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scene::IAnimatedMesh* mesh = SceneManager->getMesh("20kdm2.bsp");
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scene::ISceneNode* node = 0;
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if (mesh)
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node = SceneManager->addOctreeSceneNode(mesh->getMesh(0), 0, -1, 1024);
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if (node)
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node->setPosition(core::vector3df(-1300,-144,-1249));
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SceneManager->addCameraSceneNodeFPS();
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}
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break;
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case ES_DWARVES:
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{
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/*
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Stress-test Irrlicht a little bit by creating many objects.
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*/
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MY_PROFILE(CProfileScope p(L"dwarfes", L"grp switch scene");)
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scene::IAnimatedMesh* aniMesh = SceneManager->getMesh( getExampleMediaPath() + "dwarf.x" );
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if (aniMesh)
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{
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scene::IMesh * mesh = aniMesh->getMesh (0);
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if ( !mesh )
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break;
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/*
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You can never have too many dwarves. So let's make some.
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*/
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const int nodesX = 30;
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const int nodesY = 5;
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const int nodesZ = 30;
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aabbox3df bbox = mesh->getBoundingBox();
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vector3df extent = bbox.getExtent();
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const f32 GAP = 10.f;
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f32 halfSizeX = 0.5f * (nodesX*extent.X + GAP*(nodesX-1));
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f32 halfSizeY = 0.5f * (nodesY*extent.Y + GAP*(nodesY-1));
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f32 halfSizeZ = 0.5f * (nodesZ*extent.Z + GAP*(nodesZ-1));
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for ( int x = 0; x < nodesX; ++x )
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{
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irr::f32 gapX = x > 0 ? (x-1)*GAP : 0.f;
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irr::f32 posX = -halfSizeX + x*extent.X + gapX;
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for ( int y = 0; y < nodesY; ++y )
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{
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irr::f32 gapY = y > 0 ? (y-1)*GAP : 0.f;
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irr::f32 posY = -halfSizeY + y*extent.Y + gapY;
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for ( int z=0; z < nodesZ; ++z )
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{
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irr::f32 gapZ = z > 0 ? (z-1)*GAP : 0.f;
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irr::f32 posZ = -halfSizeZ + z*extent.Z + gapZ;
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scene::IAnimatedMeshSceneNode * node = SceneManager->addAnimatedMeshSceneNode(aniMesh, NULL, -1, vector3df(posX, posY, posZ) );
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node->setMaterialFlag(video::EMF_LIGHTING, false);
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}
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}
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}
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irr::scene::ICameraSceneNode * camera = SceneManager->addCameraSceneNodeFPS(0, 20.f, 0.1f );
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camera->updateAbsolutePosition();
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camera->setTarget( vector3df(0,0,0) );
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camera->updateAbsolutePosition();
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camera->setPosition(irr::core::vector3df(halfSizeX+extent.X, halfSizeY+extent.Y, halfSizeZ+extent.Z));
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camera->updateAbsolutePosition();
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}
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}
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break;
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}
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}
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IGUIProfiler * GuiProfiler;
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bool IncludeOverview;
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bool IgnoreUncalled;
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u32 ActiveScene;
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scene::ISceneManager* SceneManager;
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};
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void recursive(int recursion)
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{
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/*
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As the profiler uses internally counters for start stop and only
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takes profile data when that counter is zero we count all recursions
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as a single call.
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If you want to profile each call on it's own you have to use explicit start/stop calls and
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stop the profile id right before the recursive call.
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*/
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MY_PROFILE(CProfileScope p3(L"recursive", L"grp runtime");)
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if (recursion > 0 )
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recursive(recursion-1);
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}
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int main()
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{
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/*
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Setup, nothing special here.
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*/
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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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/*
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Profiler is independent of the device - so we can time the device setup
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*/
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MY_PROFILE(s32 pDev = getProfiler().add(L"createDevice", L"grp runtime");)
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MY_PROFILE(getProfiler().start(pDev);)
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IrrlichtDevice * device = createDevice(driverType, core::dimension2d<u32>(640, 480));
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if (device == 0)
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{
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/*
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When working with start/stop you should add a stop to all exit paths.
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Although in this case it wouldn't matter as we don't do anything with it when we quit here.
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*/
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MY_PROFILE(getProfiler().stop(pDev);)
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return 1; // could not create selected driver.
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}
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MY_PROFILE(getProfiler().stop(pDev);)
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video::IVideoDriver* driver = device->getVideoDriver();
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IGUIEnvironment* env = device->getGUIEnvironment();
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scene::ISceneManager* smgr = device->getSceneManager();
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const io::path mediaPath = getExampleMediaPath();
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/*
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A map we use for one of our test-scenes.
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*/
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device->getFileSystem()->addFileArchive(mediaPath + "map-20kdm2.pk3");
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MyEventReceiver receiver(smgr);
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device->setEventReceiver(&receiver);
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receiver.NextScene();
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/*
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Show some info about the controls used in this example
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*/
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IGUIStaticText * staticText = env->addStaticText(
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L"<F1> to show/hide the profiling display\n"
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L"<F2> to show the next page\n"
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L"<F3> to show the previous page\n"
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L"<F4> to show the first page\n"
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L"<F5> to flip between including the group overview\n"
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L"<F6> to flip between ignoring and showing uncalled data\n"
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L"<F7> to flip between showing 1 group per page or all together\n"
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L"<F8> to change our scene\n"
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L"<F9> to reset the \"grp runtime\" data\n"
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L"<F10> to reset the scope 3 data\n"
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L"<F11> to reset all data\n"
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L"<f> to freeze/unfreeze the display\n"
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, recti(10,10, 250, 140), true, true, 0, -1, true);
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staticText->setWordWrap(false);
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/*
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IGUIProfiler is can be used to show active profiling data at runtime.
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*/
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receiver.GuiProfiler = env->addProfilerDisplay(core::recti(40, 140, 600, 470));
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receiver.GuiProfiler->setDrawBackground(true);
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/*
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Get a monospaced font - it's nicer when working with rows of numbers.
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*/
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IGUIFont* font = env->getFont(mediaPath + "fontcourier.bmp");
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if (font)
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receiver.GuiProfiler->setOverrideFont(font);
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/*
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Adding ID's has to be done before the start/stop calls.
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This allows start/stop to be really fast and we still have nice information like
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names and groups.
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Groups are created automatically each time an ID with a new group-name is added.
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Groups exist to sort the display data in a nicer way.
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*/
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MY_PROFILE(
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getProfiler().add(EP_APP_TIME_ONCE, L"full time", L"grp runtime");
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getProfiler().add(EP_APP_TIME_UPDATED, L"full time updated", L"grp runtime");
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getProfiler().add(EP_SCOPE1, L"scope 1", L"grp runtime");
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getProfiler().add(EP_DRAW_SCENE, L"draw scene", L"grp runtime");
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)
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/*
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Two timers which run the whole time. One will be continuously updated the other won't.
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*/
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MY_PROFILE(getProfiler().start(EP_APP_TIME_ONCE);)
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MY_PROFILE(getProfiler().start(EP_APP_TIME_UPDATED);)
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s32 lastFPS = -1;
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while(device->run() && driver)
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{
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if (device->isWindowActive())
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{
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/*
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For comparison show the FPS in the title bar
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*/
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s32 fps = driver->getFPS();
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if (lastFPS != fps)
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{
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core::stringw str = L"FPS: ";
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str += fps;
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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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Times are only updated on stop() calls. So if we want a long-running timer
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to update we have to stop() and start() it in between.
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Note that this will also update the call-counter and is rarely needed.
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*/
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MY_PROFILE(getProfiler().stop(EP_APP_TIME_UPDATED);)
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MY_PROFILE(getProfiler().start(EP_APP_TIME_UPDATED);)
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/*
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The following CProfileScope's will all do the same thing:
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they measure the time this loop takes. They call start()
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when the object is created and call stop() when it
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is destroyed.
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The first one creates an ID on it's first call and will
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do constant string-comparisons for the name. It's
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the slowest, but most comfortable solution. Use it when you
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just need to run a quick check without the hassle of setting
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up id's.
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*/
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MY_PROFILE(CProfileScope p3(L"scope 3", L"grp runtime");)
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/*
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Second CProfileScope solution will create a data block on first
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call. So it's a little bit slower on the first run. But usually
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that's hardly noticeable.
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*/
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MY_PROFILE(CProfileScope p2(EP_SCOPE2, L"scope 2", L"grp runtime");)
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/*
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Last CProfileScope solution is the fastest one. But you must add
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the id before you can use it like that.
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*/
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MY_PROFILE(CProfileScope p1(EP_SCOPE1));
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/*
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Call a recursive function to show how profiler only counts it once.
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*/
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recursive(5);
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driver->beginScene(video::ECBF_COLOR | video::ECBF_DEPTH, SColor(0,200,200,200));
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/*
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If you want to profile only some lines and not a complete scope
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then you have to work with start() and stop() calls.
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*/
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MY_PROFILE(getProfiler().start(EP_DRAW_SCENE);)
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smgr->drawAll();
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MY_PROFILE(getProfiler().stop(EP_DRAW_SCENE);)
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/*
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If it doesn't matter if the profiler takes some time you can also
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be lazy and create id's automatically on the spot:
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*/
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MY_PROFILE(s32 pEnv = getProfiler().add(L"draw env", L"grp runtime");)
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MY_PROFILE(getProfiler().start(pEnv);)
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env->drawAll();
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MY_PROFILE(getProfiler().stop(pEnv);)
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driver->endScene();
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}
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}
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/*
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Shutdown.
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*/
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device->drop();
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/*
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The profiler is independent of an device - so we can still work with it.
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*/
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MY_PROFILE(getProfiler().stop(EP_APP_TIME_UPDATED));
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MY_PROFILE(getProfiler().stop(EP_APP_TIME_ONCE));
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/*
|
|
Print a complete overview of the profiling data to the console.
|
|
*/
|
|
MY_PROFILE(core::stringw output);
|
|
MY_PROFILE(getProfiler().printAll(output));
|
|
MY_PROFILE(printf("%s", core::stringc(output).c_str() ));
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|
|
|
return 0;
|
|
}
|
|
|
|
/*
|
|
**/
|