irrlicht/include/SIrrCreationParameters.h
2023-03-11 15:04:09 +01:00

335 lines
13 KiB
C++

// Copyright (C) 2002-2012 Nikolaus Gebhardt
// This file is part of the "Irrlicht Engine".
// For conditions of distribution and use, see copyright notice in irrlicht.h
#ifndef __I_IRRLICHT_CREATION_PARAMETERS_H_INCLUDED__
#define __I_IRRLICHT_CREATION_PARAMETERS_H_INCLUDED__
#include "EDriverTypes.h"
#include "EDeviceTypes.h"
#include "dimension2d.h"
#include "ILogger.h"
#include "position2d.h"
#include "path.h"
#include "IrrCompileConfig.h" // for IRRLICHT_SDK_VERSION
namespace irr
{
class IEventReceiver;
//! Structure for holding Irrlicht Device creation parameters.
/** This structure is used in the createDeviceEx() function. */
struct SIrrlichtCreationParameters
{
//! Constructs a SIrrlichtCreationParameters structure with default values.
SIrrlichtCreationParameters() :
DeviceType(EIDT_BEST),
DriverType(video::EDT_BURNINGSVIDEO),
WindowSize(core::dimension2d<u32>(800, 600)),
WindowPosition(core::position2di(-1,-1)),
Bits(32),
ZBufferBits(24),
Fullscreen(false),
WindowMaximized(false),
WindowResizable(2),
Stencilbuffer(true),
Vsync(false),
AntiAlias(0),
HandleSRGB(false),
WithAlphaChannel(false),
Doublebuffer(true),
IgnoreInput(false),
Stereobuffer(false),
HighPrecisionFPU(false),
EventReceiver(0),
WindowId(0),
#ifdef _DEBUG
LoggingLevel(ELL_DEBUG),
#else
LoggingLevel(ELL_INFORMATION),
#endif
DisplayAdapter(0),
DriverMultithreaded(false),
UsePerformanceTimer(true),
SDK_version_do_not_use(IRRLICHT_SDK_VERSION),
PrivateData(0),
#ifdef IRR_MOBILE_PATHS
OGLES2ShaderPath("media/Shaders/")
#else
OGLES2ShaderPath("../../media/Shaders/")
#endif
{
}
SIrrlichtCreationParameters(const SIrrlichtCreationParameters& other) :
SDK_version_do_not_use(IRRLICHT_SDK_VERSION)
{*this = other;}
SIrrlichtCreationParameters& operator=(const SIrrlichtCreationParameters& other)
{
DeviceType = other.DeviceType;
DriverType = other.DriverType;
WindowSize = other.WindowSize;
WindowPosition = other.WindowPosition;
Bits = other.Bits;
ZBufferBits = other.ZBufferBits;
Fullscreen = other.Fullscreen;
WindowMaximized = other.WindowMaximized;
WindowResizable = other.WindowResizable;
Stencilbuffer = other.Stencilbuffer;
Vsync = other.Vsync;
AntiAlias = other.AntiAlias;
HandleSRGB = other.HandleSRGB;
WithAlphaChannel = other.WithAlphaChannel;
Doublebuffer = other.Doublebuffer;
IgnoreInput = other.IgnoreInput;
Stereobuffer = other.Stereobuffer;
HighPrecisionFPU = other.HighPrecisionFPU;
EventReceiver = other.EventReceiver;
WindowId = other.WindowId;
LoggingLevel = other.LoggingLevel;
DisplayAdapter = other.DisplayAdapter;
DriverMultithreaded = other.DriverMultithreaded;
UsePerformanceTimer = other.UsePerformanceTimer;
PrivateData = other.PrivateData;
OGLES2ShaderPath = other.OGLES2ShaderPath;
return *this;
}
//! Type of the device.
/** This setting decides the windowing system used by the device, most device types are native
to a specific operating system and so may not be available.
EIDT_WIN32 is only available on Windows desktops,
EIDT_COCOA is only available on Mac OSX,
EIDT_X11 is available on Linux, Solaris, BSD and other operating systems which use X11,
EIDT_SDL is available on most systems if compiled in,
EIDT_BEST will select the best available device for your operating system.
Default: EIDT_BEST. */
E_DEVICE_TYPE DeviceType;
//! Type of video driver used to render graphics.
/** This can currently be video::EDT_NULL, video::EDT_SOFTWARE,
video::EDT_BURNINGSVIDEO, video::EDT_DIRECT3D9, and video::EDT_OPENGL.
Default: EDT_BURNINGSVIDEO. */
video::E_DRIVER_TYPE DriverType;
//! Size of the window or the video mode in fullscreen mode. Default: 800x600
core::dimension2d<u32> WindowSize;
//! Position of the window on-screen. Default: (-1, -1) or centered.
core::position2di WindowPosition;
//! Minimum Bits per pixel of the color buffer in fullscreen mode. Ignored if windowed mode. Default: 32.
u8 Bits;
//! Minimum Bits per pixel of the depth buffer. Default: 24.
u8 ZBufferBits;
//! Should be set to true if the device should run in fullscreen.
/** Otherwise the device runs in windowed mode. Default: false. */
bool Fullscreen;
//! Maximised window. (Only supported on SDL.) Default: false
bool WindowMaximized;
//! Should a non-fullscreen window be resizable.
/** Might not be supported by all devices. Ignored when Fullscreen is true.
Values: 0 = not resizable, 1 = resizable, 2 = system decides default itself
Default: 2*/
u8 WindowResizable;
//! Specifies if the stencil buffer should be enabled.
/** Set this to true, if you want the engine be able to draw
stencil buffer shadows. Note that not all drivers are able to
use the stencil buffer, hence it can be ignored during device
creation. Without the stencil buffer no shadows will be drawn.
Default: true. */
bool Stencilbuffer;
//! Specifies vertical synchronization.
/** If set to true, the driver will wait for the vertical
retrace period, otherwise not. May be silently ignored.
Default: false */
bool Vsync;
//! Specifies if the device should use fullscreen anti aliasing
/** Makes sharp/pixelated edges softer, but requires more
performance. Also, 2D elements might look blurred with this
switched on. The resulting rendering quality also depends on
the hardware and driver you are using, your program might look
different on different hardware with this. So if you are
writing a game/application with AntiAlias switched on, it would
be a good idea to make it possible to switch this option off
again by the user.
The value is the maximal antialiasing factor requested for
the device. The creation method will automatically try smaller
values if no window can be created with the given value.
Value one is usually the same as 0 (disabled), but might be a
special value on some platforms. On D3D devices it maps to
NONMASKABLE.
Default value: 0 - disabled */
u8 AntiAlias;
//! Flag to enable proper sRGB and linear color handling
/** In most situations, it is desirable to have the color handling in
non-linear sRGB color space, and only do the intermediate color
calculations in linear RGB space. If this flag is enabled, the device and
driver try to assure that all color input and output are color corrected
and only the internal color representation is linear. This means, that
the color output is properly gamma-adjusted to provide the brighter
colors for monitor display. And that blending and lighting give a more
natural look, due to proper conversion from non-linear colors into linear
color space for blend operations. If this flag is enabled, all texture colors
(which are usually in sRGB space) are correctly displayed. However vertex colors
and other explicitly set values have to be manually encoded in linear color space.
Default value: false. */
bool HandleSRGB;
//! Whether the main framebuffer uses an alpha channel.
/** In some situations it might be desirable to get a color
buffer with an alpha channel, e.g. when rendering into a
transparent window or overlay. If this flag is set the device
tries to create a framebuffer with alpha channel.
If this flag is set, only color buffers with alpha channel
are considered. Otherwise, it depends on the actual hardware
if the colorbuffer has an alpha channel or not.
Default value: false */
bool WithAlphaChannel;
//! Whether the main framebuffer uses doublebuffering.
/** This should be usually enabled, in order to avoid render
artifacts on the visible framebuffer. However, it might be
useful to use only one buffer on very small devices. If no
doublebuffering is available, the drivers will fall back to
single buffers. Default value: true */
bool Doublebuffer;
//! Specifies if the device should ignore input events
/** This is only relevant when using external I/O handlers.
External windows need to take care of this themselves.
Currently only supported by X11.
Default value: false */
bool IgnoreInput;
//! Specifies if the device should use stereo buffers
/** Some high-end gfx cards support two framebuffers for direct
support of stereoscopic output devices. If this flag is set the
device tries to create a stereo context.
Currently only supported by OpenGL.
Default value: false */
bool Stereobuffer;
//! Specifies if the device should use high precision FPU setting
/** This is only relevant for DirectX Devices, which switch to
low FPU precision by default for performance reasons. However,
this may lead to problems with the other computations of the
application. In this case setting this flag to true should help
- on the expense of performance loss, though.
Default value: false */
bool HighPrecisionFPU;
//! A user created event receiver.
IEventReceiver* EventReceiver;
//! Window Id.
/** If this is set to a value other than 0, the Irrlicht Engine
will be created in an already existing window.
For Windows, set this to the HWND of the window you want.
For iOS, assign UIView to this variable.
The windowSize and FullScreen options will be ignored when using
the WindowId parameter. Default this is set to 0.
To make Irrlicht run inside the custom window, you still will
have to draw Irrlicht on your own. You can use this loop, as
usual:
\code
while (device->run())
{
driver->beginScene(video::ECBF_COLOR | video::ECBF_DEPTH, 0);
smgr->drawAll();
driver->endScene();
}
\endcode
Instead of this, you can also simply use your own message loop
using GetMessage, DispatchMessage and whatever. Calling
IrrlichtDevice::run() will cause Irrlicht to dispatch messages
internally too. You need not call Device->run() if you want to
do your own message dispatching loop, but Irrlicht will not be
able to fetch user input then and you have to do it on your own
using the window messages, DirectInput, or whatever. Also,
you'll have to increment the Irrlicht timer.
An alternative, own message dispatching loop without
device->run() would look like this:
\code
MSG msg;
while (true)
{
if (PeekMessage(&msg, NULL, 0, 0, PM_REMOVE))
{
TranslateMessage(&msg);
DispatchMessage(&msg);
if (msg.message == WM_QUIT)
break;
}
// increase virtual timer time
device->getTimer()->tick();
// draw engine picture
driver->beginScene(video::ECBF_COLOR | video::ECBF_DEPTH, 0);
smgr->drawAll();
driver->endScene();
}
\endcode
However, there is no need to draw the picture this often. Just
do it how you like. */
void* WindowId;
//! Specifies the logging level used in the logging interface.
/** The default value is ELL_INFORMATION. You can access the ILogger interface
later on from the IrrlichtDevice with getLogger() and set another level.
But if you need more or less logging information already from device creation,
then you have to change it here.
*/
ELOG_LEVEL LoggingLevel;
//! Allows to select which graphic card is used for rendering when more than one card is in the system.
/** So far only supported on D3D */
u32 DisplayAdapter;
//! Create the driver multithreaded.
/** Default is false. Enabling this can slow down your application.
Note that this does _not_ make Irrlicht threadsafe, but only the underlying driver-API for the graphiccard.
So far only supported on D3D. */
bool DriverMultithreaded;
//! Enables use of high performance timers on Windows platform.
/** When performance timers are not used, standard GetTickCount()
is used instead which usually has worse resolution, but also less
problems with speed stepping and other techniques.
*/
bool UsePerformanceTimer;
//! Don't use or change this parameter.
/** Always set it to IRRLICHT_SDK_VERSION, which is done by default.
This is needed for sdk version checks. */
const c8* const SDK_version_do_not_use;
//! Define some private data storage.
/** Used when platform devices need access to OS specific data structures etc.
This is only used for Android at th emoment in order to access the native
Java RE. */
void *PrivateData;
//! Set the path where default-shaders to simulate the fixed-function pipeline can be found.
/** This is about the shaders which can be found in media/Shaders by default. It's only necessary
to set when using OGL-ES 2.0 */
irr::io::path OGLES2ShaderPath;
};
} // end namespace irr
#endif