unit sdl;
{
$Id: sdl.pas,v 1.38 2008/01/26 10:09:32 savage Exp $
}
{******************************************************************************}
{ }
{ JEDI-SDL : Pascal units for SDL - Simple DirectMedia Layer }
{ Conversion of the Simple DirectMedia Layer Headers }
{ }
{ Portions created by Sam Lantinga <slouken@devolution.com> are }
{ Copyright (C) 1997-2004 Sam Lantinga }
{ 5635-34 Springhouse Dr. }
{ Pleasanton, CA 94588 (USA) }
{ }
{ All Rights Reserved. }
{ }
{ The original files are : SDL.h }
{ SDL_main.h }
{ SDL_types.h }
{ SDL_rwops.h }
{ SDL_timer.h }
{ SDL_audio.h }
{ SDL_cdrom.h }
{ SDL_joystick.h }
{ SDL_mouse.h }
{ SDL_keyboard.h }
{ SDL_events.h }
{ SDL_video.h }
{ SDL_byteorder.h }
{ SDL_version.h }
{ SDL_active.h }
{ SDL_thread.h }
{ SDL_mutex .h }
{ SDL_getenv.h }
{ SDL_loadso.h }
{ }
{ The initial developer of this Pascal code was : }
{ Dominique Louis <Dominique@SavageSoftware.com.au> }
{ }
{ Portions created by Dominique Louis are }
{ Copyright (C) 2000 - 2004 Dominique Louis. }
{ }
{ }
{ Contributor(s) }
{ -------------- }
{ Tom Jones <tigertomjones@gmx.de> His Project inspired this conversion }
{ Matthias Thoma <ma.thoma@gmx.de> }
{ }
{ Obtained through: }
{ Joint Endeavour of Delphi Innovators ( Project JEDI ) }
{ }
{ You may retrieve the latest version of this file at the Project }
{ JEDI home page, located at http://delphi-jedi.org }
{ }
{ The contents of this file are used with permission, subject to }
{ the Mozilla Public License Version 1.1 (the "License"); you may }
{ not use this file except in compliance with the License. You may }
{ obtain a copy of the License at }
{ http://www.mozilla.org/MPL/MPL-1.1.html }
{ }
{ Software distributed under the License is distributed on an }
{ "AS IS" basis, WITHOUT WARRANTY OF ANY KIND, either express or }
{ implied. See the License for the specific language governing }
{ rights and limitations under the License. }
{ }
{ Description }
{ ----------- }
{ }
{ }
{ }
{ }
{ }
{ }
{ }
{ Requires }
{ -------- }
{ The SDL Runtime libraris on Win32 : SDL.dll on Linux : libSDL.so }
{ They are available from... }
{ http://www.libsdl.org . }
{ }
{ Programming Notes }
{ ----------------- }
{ }
{ }
{ }
{ }
{ Revision History }
{ ---------------- }
{ May 08 2001 - DL : Added Keyboard State Array ( See demos for how to }
{ use ) }
{ PKeyStateArr = ^TKeyStateArr; }
{ TKeyStateArr = array[0..65000] of UInt8; }
{ As most games will need it. }
{ }
{ April 02 2001 - DL : Added SDL_getenv.h definitions and tested version }
{ 1.2.0 compatability. }
{ }
{ March 13 2001 - MT : Added Linux compatibility. }
{ }
{ March 10 2001 - MT : Added externalsyms for DEFINES }
{ Changed the license header }
{ }
{ March 09 2001 - MT : Added Kylix Ifdefs/Deleted the uses mmsystem }
{ }
{ March 01 2001 - DL : Update conversion of version 1.1.8 }
{ }
{ July 22 2001 - DL : Added TUInt8Array and PUIntArray after suggestions }
{ from Matthias Thoma and Eric Grange. }
{ }
{ October 12 2001 - DL : Various changes as suggested by Matthias Thoma and }
{ David Acklam }
{ }
{ October 24 2001 - DL : Added FreePascal support as per suggestions from }
{ Dean Ellis. }
{ }
{ October 27 2001 - DL : Added SDL_BUTTON macro }
{ }
{ November 08 2001 - DL : Bug fix as pointed out by Puthoon. }
{ }
{ November 29 2001 - DL : Bug fix of SDL_SetGammaRamp as pointed out by Simon}
{ Rushton. }
{ }
{ November 30 2001 - DL : SDL_NOFRAME added as pointed out by Simon Rushton. }
{ }
{ December 11 2001 - DL : Added $WEAKPACKAGEUNIT ON to facilitate useage in }
{ Components }
{ }
{ January 05 2002 - DL : Added SDL_Swap32 function as suggested by Matthias }
{ Thoma and also made sure the _getenv from }
{ MSVCRT.DLL uses the right calling convention }
{ }
{ January 25 2002 - DL : Updated conversion of SDL_AddTimer & }
{ SDL_RemoveTimer as per suggestions from Matthias }
{ Thoma. }
{ }
{ January 27 2002 - DL : Commented out exported function putenv and getenv }
{ So that developers get used to using SDL_putenv }
{ SDL_getenv, as they are more portable }
{ }
{ March 05 2002 - DL : Added FreeAnNil procedure for Delphi 4 users. }
{ }
{ October 23 2002 - DL : Added Delphi 3 Define of Win32. }
{ If you intend to you Delphi 3... }
{ ( which is officially unsupported ) make sure you }
{ remove references to $EXTERNALSYM in this and other}
{ SDL files. }
{ }
{ November 29 2002 - DL : Fixed bug in Declaration of SDL_GetRGBA that was }
{ pointed out by Todd Lang }
{ }
{ April 03 2003 - DL : Added jedi-sdl.inc include file to support more }
{ Pascal compilers. Initial support is now included }
{ for GnuPascal, VirtualPascal, TMT and obviously }
{ continue support for Delphi Kylix and FreePascal. }
{ }
{ April 08 2003 - MK : Aka Mr Kroket - Added Better FPC support }
{ }
{ April 24 2003 - DL : under instruction from Alexey Barkovoy, I have added}
{ better TMT Pascal support and under instruction }
{ from Prof. Abimbola Olowofoyeku (The African Chief),}
{ I have added better Gnu Pascal support }
{ }
{ April 30 2003 - DL : under instruction from David Mears AKA }
{ Jason Siletto, I have added FPC Linux support. }
{ This was compiled with fpc 1.1, so remember to set }
{ include file path. ie. -Fi/usr/share/fpcsrc/rtl/* }
{ }
{
$Log: sdl.pas,v $
Revision 1.38 2008/01/26 10:09:32 savage
Added SDL_BUTTON_X1 and SDL_BUTTON_X2 constants for extended mouse buttons. Now makes SDL v1.2.13 compliant.
Revision 1.37 2007/12/20 22:36:56 savage
Added SKYOS support, thanks to Sebastian-Torsten Tillmann
Revision 1.36 2007/12/05 22:52:04 savage
Better Mac OS X support for Frameworks.
Revision 1.35 2007/12/02 22:41:13 savage
Change for Mac OS X to link to SDL Framework
Revision 1.34 2007/08/26 23:50:53 savage
Jonas supplied another fix.
Revision 1.33 2007/08/26 15:59:46 savage
Mac OS changes as suggested by Jonas Maebe
Revision 1.32 2007/08/22 21:18:43 savage
Thanks to Dean for his MouseDelta patch.
Revision 1.31 2007/05/29 21:30:48 savage
Changes as suggested by Almindor for 64bit compatibility.
Revision 1.30 2007/05/29 19:31:03 savage
Fix to TSDL_Overlay structure - thanks David Pethes (aka imcold)
Revision 1.29 2007/05/20 20:29:11 savage
Initial Changes to Handle 64 Bits
Revision 1.26 2007/02/11 13:38:04 savage
Added Nintendo DS support - Thanks Dean.
Revision 1.25 2006/12/02 00:12:52 savage
Updated to latest version
Revision 1.24 2006/05/18 21:10:04 savage
Added 1.2.10 Changes
Revision 1.23 2005/12/04 23:17:52 drellis
Added declaration of SInt8 and PSInt8
Revision 1.22 2005/05/24 21:59:03 savage
Re-arranged uses clause to work on Win32 and Linux, Thanks again Michalis.
Revision 1.21 2005/05/22 18:42:31 savage
Changes as suggested by Michalis Kamburelis. Thanks again.
Revision 1.20 2005/04/10 11:48:33 savage
Changes as suggested by Michalis, thanks.
Revision 1.19 2005/01/05 01:47:06 savage
Changed LibName to reflect what MacOS X should have. ie libSDL*-1.2.0.dylib respectively.
Revision 1.18 2005/01/04 23:14:41 savage
Changed LibName to reflect what most Linux distros will have. ie libSDL*-1.2.so.0 respectively.
Revision 1.17 2005/01/03 18:40:59 savage
Updated Version number to reflect latest one
Revision 1.16 2005/01/01 02:02:06 savage
Updated to v1.2.8
Revision 1.15 2004/12/24 18:57:11 savage
forgot to apply Michalis Kamburelis' patch to the implementation section. now fixed
Revision 1.14 2004/12/23 23:42:18 savage
Applied Patches supplied by Michalis Kamburelis ( THANKS! ), for greater FreePascal compatability.
Revision 1.13 2004/09/30 22:31:59 savage
Updated with slightly different header comments
Revision 1.12 2004/09/12 21:52:58 savage
Slight changes to fix some issues with the sdl classes.
Revision 1.11 2004/08/14 22:54:30 savage
Updated so that Library name defines are correctly defined for MacOS X.
Revision 1.10 2004/07/20 23:57:33 savage
Thanks to Paul Toth for spotting an error in the SDL Audio Convertion structures.
In TSDL_AudioCVT the filters variable should point to and array of pointers and not what I had there previously.
Revision 1.9 2004/07/03 22:07:22 savage
Added Bitwise Manipulation Functions for TSDL_VideoInfo struct.
Revision 1.8 2004/05/10 14:10:03 savage
Initial MacOS X support. Fixed defines for MACOS ( Classic ) and DARWIN ( MacOS X ).
Revision 1.7 2004/04/13 09:32:08 savage
Changed Shared object names back to just the .so extension to avoid conflicts on various Linux/Unix distros. Therefore developers will need to create Symbolic links to the actual Share Objects if necessary.
Revision 1.6 2004/04/01 20:53:23 savage
Changed Linux Shared Object names so they reflect the Symbolic Links that are created when installing the RPMs from the SDL site.
Revision 1.5 2004/02/22 15:32:10 savage
SDL_GetEnv Fix so it also works on FPC/Linux. Thanks to Rodrigo for pointing this out.
Revision 1.4 2004/02/21 23:24:29 savage
SDL_GetEnv Fix so that it is not define twice for FPC. Thanks to Rene Hugentobler for pointing out this bug,
Revision 1.3 2004/02/18 22:35:51 savage
Brought sdl.pas up to 1.2.7 compatability
Thus...
Added SDL_GL_STEREO,
SDL_GL_MULTISAMPLEBUFFERS,
SDL_GL_MULTISAMPLESAMPLES
Add DLL/Shared object functions
function SDL_LoadObject( const sofile : PChar ) : Pointer;
function SDL_LoadFunction( handle : Pointer; const name : PChar ) : Pointer;
procedure SDL_UnloadObject( handle : Pointer );
Added function to create RWops from const memory: SDL_RWFromConstMem()
function SDL_RWFromConstMem(const mem: Pointer; size: Integer) : PSDL_RWops;
Ported SDL_cpuinfo.h so Now you can test for Specific CPU types.
Revision 1.2 2004/02/17 21:37:12 savage
Tidying up of units
Revision 1.1 2004/02/05 00:08:20 savage
Module 1.0 release
}
{******************************************************************************}
{$I jedi-sdl.inc}
interface
uses
{$IFDEF __GPC__}
system,
{$IFDEF WINDOWS}
wintypes,
{$ELSE}
{$ENDIF}
gpc;
{$ENDIF}
{$IFDEF HAS_TYPES}
Types{$IFNDEF NDS},{$ELSE};{$ENDIF}
{$ENDIF}
{$IFDEF WINDOWS}
Windows;
{$ENDIF}
{$IFDEF UNIX}
{$IFDEF FPC}
{$IFNDEF SKYOS}
pthreads,
{$ENDIF}
baseunix,
{$IFNDEF GP2X}
{$IFNDEF DARWIN}
{$IFNDEF SKYOS}
unix,
{$ELSE}
unix;
{$ENDIF}
{$ELSE}
unix;
{$ENDIF}
{$ELSE}
unix;
{$ENDIF}
{$IFNDEF GP2X}
{$IFNDEF DARWIN}
{$IFNDEF SKYOS}
x,
xlib;
{$ENDIF}
{$ENDIF}
{$ENDIF}
{$ELSE}
Libc,
Xlib;
{$ENDIF}
{$ENDIF}
{$IFDEF __MACH__}
GPCMacOSAll;
{$ENDIF}
{$ifndef FPC}
type
PtrInt = LongInt;
PtrUInt = LongWord;
{$endif}
const
{$IFDEF WINDOWS}
SDLLibName = 'SDL.dll';
{$ENDIF}
{$IFDEF UNIX}
{$IFDEF DARWIN}
SDLLibName = 'libSDL-1.2.0.dylib';
{$linklib libSDL-1.2.0}
// {$linklib gcc}
{$linklib SDLmain}
{$linkframework Cocoa}
{$PASCALMAINNAME SDL_main}
{$ELSE}
{$IFDEF FPC}
SDLLibName = 'libSDL.so';
{$ELSE}
SDLLibName = 'libSDL-1.2.so.0';
{$ENDIF}
{$ENDIF}
{$ENDIF}
{$IFDEF MACOS}
SDLLibName = 'SDL';
{$linklib libSDL}
{$ENDIF}
{$IFDEF NDS}
SDLLibName = 'libSDL.a';
{$linklib libSDL.a}
{$linklib libnds9.a}
{$linklib libc.a}
{$linklib libgcc.a}
{$linklib libsysbase.a}
{$ENDIF}
// SDL_verion.h constants
// Printable format: "%d.%d.%d", MAJOR, MINOR, PATCHLEVEL
SDL_MAJOR_VERSION = 1;
{$EXTERNALSYM SDL_MAJOR_VERSION}
SDL_MINOR_VERSION = 2;
{$EXTERNALSYM SDL_MINOR_VERSION}
SDL_PATCHLEVEL = 13;
{$EXTERNALSYM SDL_PATCHLEVEL}
// SDL.h constants
SDL_INIT_TIMER = $00000001;
{$EXTERNALSYM SDL_INIT_TIMER}
SDL_INIT_AUDIO = $00000010;
{$EXTERNALSYM SDL_INIT_AUDIO}
SDL_INIT_VIDEO = $00000020;
{$EXTERNALSYM SDL_INIT_VIDEO}
SDL_INIT_CDROM = $00000100;
{$EXTERNALSYM SDL_INIT_CDROM}
SDL_INIT_JOYSTICK = $00000200;
{$EXTERNALSYM SDL_INIT_JOYSTICK}
SDL_INIT_NOPARACHUTE = $00100000; // Don't catch fatal signals
{$EXTERNALSYM SDL_INIT_NOPARACHUTE}
SDL_INIT_EVENTTHREAD = $01000000; // Not supported on all OS's
{$EXTERNALSYM SDL_INIT_EVENTTHREAD}
SDL_INIT_EVERYTHING = $0000FFFF;
{$EXTERNALSYM SDL_INIT_EVERYTHING}
// SDL_error.h constants
ERR_MAX_STRLEN = 128;
{$EXTERNALSYM ERR_MAX_STRLEN}
ERR_MAX_ARGS = 5;
{$EXTERNALSYM ERR_MAX_ARGS}
// SDL_types.h constants
SDL_PRESSED = $01;
{$EXTERNALSYM SDL_PRESSED}
SDL_RELEASED = $00;
{$EXTERNALSYM SDL_RELEASED}
// SDL_timer.h constants
// This is the OS scheduler timeslice, in milliseconds
SDL_TIMESLICE = 10;
{$EXTERNALSYM SDL_TIMESLICE}
// This is the maximum resolution of the SDL timer on all platforms
TIMER_RESOLUTION = 10; // Experimentally determined
{$EXTERNALSYM TIMER_RESOLUTION}
// SDL_audio.h constants
AUDIO_U8 = $0008; // Unsigned 8-bit samples
{$EXTERNALSYM AUDIO_U8}
AUDIO_S8 = $8008; // Signed 8-bit samples
{$EXTERNALSYM AUDIO_S8}
AUDIO_U16LSB = $0010; // Unsigned 16-bit samples
{$EXTERNALSYM AUDIO_U16LSB}
AUDIO_S16LSB = $8010; // Signed 16-bit samples
{$EXTERNALSYM AUDIO_S16LSB}
AUDIO_U16MSB = $1010; // As above, but big-endian byte order
{$EXTERNALSYM AUDIO_U16MSB}
AUDIO_S16MSB = $9010; // As above, but big-endian byte order
{$EXTERNALSYM AUDIO_S16MSB}
AUDIO_U16 = AUDIO_U16LSB;
{$EXTERNALSYM AUDIO_U16}
AUDIO_S16 = AUDIO_S16LSB;
{$EXTERNALSYM AUDIO_S16}
// SDL_cdrom.h constants
// The maximum number of CD-ROM tracks on a disk
SDL_MAX_TRACKS = 99;
{$EXTERNALSYM SDL_MAX_TRACKS}
// The types of CD-ROM track possible
SDL_AUDIO_TRACK = $00;
{$EXTERNALSYM SDL_AUDIO_TRACK}
SDL_DATA_TRACK = $04;
{$EXTERNALSYM SDL_DATA_TRACK}
// Conversion functions from frames to Minute/Second/Frames and vice versa
CD_FPS = 75;
{$EXTERNALSYM CD_FPS}
// SDL_byteorder.h constants
// The two types of endianness
SDL_LIL_ENDIAN = 1234;
{$EXTERNALSYM SDL_LIL_ENDIAN}
SDL_BIG_ENDIAN = 4321;
{$EXTERNALSYM SDL_BIG_ENDIAN}
{$IFDEF IA32}
SDL_BYTEORDER = SDL_LIL_ENDIAN;
{$EXTERNALSYM SDL_BYTEORDER}
// Native audio byte ordering
AUDIO_U16SYS = AUDIO_U16LSB;
{$EXTERNALSYM AUDIO_U16SYS}
AUDIO_S16SYS = AUDIO_S16LSB;
{$EXTERNALSYM AUDIO_S16SYS}
{$ELSE}
SDL_BYTEORDER = SDL_BIG_ENDIAN;
{$EXTERNALSYM SDL_BYTEORDER}
// Native audio byte ordering
AUDIO_U16SYS = AUDIO_U16MSB;
{$EXTERNALSYM AUDIO_U16SYS}
AUDIO_S16SYS = AUDIO_S16MSB;
{$EXTERNALSYM AUDIO_S16SYS}
{$ENDIF}
SDL_MIX_MAXVOLUME = 128;
{$EXTERNALSYM SDL_MIX_MAXVOLUME}
// SDL_joystick.h constants
MAX_JOYSTICKS = 2; // only 2 are supported in the multimedia API
{$EXTERNALSYM MAX_JOYSTICKS}
MAX_AXES = 6; // each joystick can have up to 6 axes
{$EXTERNALSYM MAX_AXES}
MAX_BUTTONS = 32; // and 32 buttons
{$EXTERNALSYM MAX_BUTTONS}
AXIS_MIN = -32768; // minimum value for axis coordinate
{$EXTERNALSYM AXIS_MIN}
AXIS_MAX = 32767; // maximum value for axis coordinate
{$EXTERNALSYM AXIS_MAX}
JOY_AXIS_THRESHOLD = (((AXIS_MAX) - (AXIS_MIN)) / 100); // 1% motion
{$EXTERNALSYM JOY_AXIS_THRESHOLD}
//JOY_BUTTON_FLAG(n) (1<<n)
// array to hold joystick ID values
//static UInt SYS_JoystickID[MAX_JOYSTICKS];
//static JOYCAPS SYS_Joystick[MAX_JOYSTICKS];
{ Get the current state of a POV hat on a joystick
The return value is one of the following positions: }
SDL_HAT_CENTERED = $00;
{$EXTERNALSYM SDL_HAT_CENTERED}
SDL_HAT_UP = $01;
{$EXTERNALSYM SDL_HAT_UP}
SDL_HAT_RIGHT = $02;
{$EXTERNALSYM SDL_HAT_RIGHT}
SDL_HAT_DOWN = $04;
{$EXTERNALSYM SDL_HAT_DOWN}
SDL_HAT_LEFT = $08;
{$EXTERNALSYM SDL_HAT_LEFT}
SDL_HAT_RIGHTUP = SDL_HAT_RIGHT or SDL_HAT_UP;
{$EXTERNALSYM SDL_HAT_RIGHTUP}
SDL_HAT_RIGHTDOWN = SDL_HAT_RIGHT or SDL_HAT_DOWN;
{$EXTERNALSYM SDL_HAT_RIGHTDOWN}
SDL_HAT_LEFTUP = SDL_HAT_LEFT or SDL_HAT_UP;
{$EXTERNALSYM SDL_HAT_LEFTUP}
SDL_HAT_LEFTDOWN = SDL_HAT_LEFT or SDL_HAT_DOWN;
{$EXTERNALSYM SDL_HAT_LEFTDOWN}
// SDL_events.h constants
SDL_NOEVENT = 0; // Unused (do not remove)
{$EXTERNALSYM SDL_NOEVENT}
SDL_ACTIVEEVENT = 1; // Application loses/gains visibility
{$EXTERNALSYM SDL_ACTIVEEVENT}
SDL_KEYDOWN = 2; // Keys pressed
{$EXTERNALSYM SDL_KEYDOWN}
SDL_KEYUP = 3; // Keys released
{$EXTERNALSYM SDL_KEYUP}
SDL_MOUSEMOTION = 4; // Mouse moved
{$EXTERNALSYM SDL_MOUSEMOTION}
SDL_MOUSEBUTTONDOWN = 5; // Mouse button pressed
{$EXTERNALSYM SDL_MOUSEBUTTONDOWN}
SDL_MOUSEBUTTONUP = 6; // Mouse button released
{$EXTERNALSYM SDL_MOUSEBUTTONUP}
SDL_JOYAXISMOTION = 7; // Joystick axis motion
{$EXTERNALSYM SDL_JOYAXISMOTION}
SDL_JOYBALLMOTION = 8; // Joystick trackball motion
{$EXTERNALSYM SDL_JOYBALLMOTION}
SDL_JOYHATMOTION = 9; // Joystick hat position change
{$EXTERNALSYM SDL_JOYHATMOTION}
SDL_JOYBUTTONDOWN = 10; // Joystick button pressed
{$EXTERNALSYM SDL_JOYBUTTONDOWN}
SDL_JOYBUTTONUP = 11; // Joystick button released
{$EXTERNALSYM SDL_JOYBUTTONUP}
SDL_QUITEV = 12; // User-requested quit ( Changed due to procedure conflict )
{$EXTERNALSYM SDL_QUIT}
SDL_SYSWMEVENT = 13; // System specific event
{$EXTERNALSYM SDL_SYSWMEVENT}
SDL_EVENT_RESERVEDA = 14; // Reserved for future use..
{$EXTERNALSYM SDL_EVENT_RESERVEDA}
SDL_EVENT_RESERVED = 15; // Reserved for future use..
{$EXTERNALSYM SDL_EVENT_RESERVED}
SDL_VIDEORESIZE = 16; // User resized video mode
{$EXTERNALSYM SDL_VIDEORESIZE}
SDL_VIDEOEXPOSE = 17; // Screen needs to be redrawn
{$EXTERNALSYM SDL_VIDEOEXPOSE}
SDL_EVENT_RESERVED2 = 18; // Reserved for future use..
{$EXTERNALSYM SDL_EVENT_RESERVED2}
SDL_EVENT_RESERVED3 = 19; // Reserved for future use..
{$EXTERNALSYM SDL_EVENT_RESERVED3}
SDL_EVENT_RESERVED4 = 20; // Reserved for future use..
{$EXTERNALSYM SDL_EVENT_RESERVED4}
SDL_EVENT_RESERVED5 = 21; // Reserved for future use..
{$EXTERNALSYM SDL_EVENT_RESERVED5}
SDL_EVENT_RESERVED6 = 22; // Reserved for future use..
{$EXTERNALSYM SDL_EVENT_RESERVED6}
SDL_EVENT_RESERVED7 = 23; // Reserved for future use..
{$EXTERNALSYM SDL_EVENT_RESERVED7}
// Events SDL_USEREVENT through SDL_MAXEVENTS-1 are for your use
SDL_USEREVENT = 24;
{$EXTERNALSYM SDL_USEREVENT}
// This last event is only for bounding internal arrays
// It is the number of bits in the event mask datatype -- UInt32
SDL_NUMEVENTS = 32;
{$EXTERNALSYM SDL_NUMEVENTS}
SDL_ALLEVENTS = $FFFFFFFF;
{$EXTERNALSYM SDL_ALLEVENTS}
SDL_ACTIVEEVENTMASK = 1 shl SDL_ACTIVEEVENT;
{$EXTERNALSYM SDL_ACTIVEEVENTMASK}
SDL_KEYDOWNMASK = 1 shl SDL_KEYDOWN;
{$EXTERNALSYM SDL_KEYDOWNMASK}
SDL_KEYUPMASK = 1 shl SDL_KEYUP;
{$EXTERNALSYM SDL_KEYUPMASK}
SDL_MOUSEMOTIONMASK = 1 shl SDL_MOUSEMOTION;
{$EXTERNALSYM SDL_MOUSEMOTIONMASK}
SDL_MOUSEBUTTONDOWNMASK = 1 shl SDL_MOUSEBUTTONDOWN;
{$EXTERNALSYM SDL_MOUSEBUTTONDOWNMASK}
SDL_MOUSEBUTTONUPMASK = 1 shl SDL_MOUSEBUTTONUP;
{$EXTERNALSYM SDL_MOUSEBUTTONUPMASK}
SDL_MOUSEEVENTMASK = 1 shl SDL_MOUSEMOTION or
1 shl SDL_MOUSEBUTTONDOWN or
1 shl SDL_MOUSEBUTTONUP;
{$EXTERNALSYM SDL_MOUSEEVENTMASK}
SDL_JOYAXISMOTIONMASK = 1 shl SDL_JOYAXISMOTION;
{$EXTERNALSYM SDL_JOYAXISMOTIONMASK}
SDL_JOYBALLMOTIONMASK = 1 shl SDL_JOYBALLMOTION;
{$EXTERNALSYM SDL_JOYBALLMOTIONMASK}
SDL_JOYHATMOTIONMASK = 1 shl SDL_JOYHATMOTION;
{$EXTERNALSYM SDL_JOYHATMOTIONMASK}
SDL_JOYBUTTONDOWNMASK = 1 shl SDL_JOYBUTTONDOWN;
{$EXTERNALSYM SDL_JOYBUTTONDOWNMASK}
SDL_JOYBUTTONUPMASK = 1 shl SDL_JOYBUTTONUP;
{$EXTERNALSYM SDL_JOYBUTTONUPMASK}
SDL_JOYEVENTMASK = 1 shl SDL_JOYAXISMOTION or
1 shl SDL_JOYBALLMOTION or
1 shl SDL_JOYHATMOTION or
1 shl SDL_JOYBUTTONDOWN or
1 shl SDL_JOYBUTTONUP;
{$EXTERNALSYM SDL_JOYEVENTMASK}
SDL_VIDEORESIZEMASK = 1 shl SDL_VIDEORESIZE;
{$EXTERNALSYM SDL_VIDEORESIZEMASK}
SDL_QUITMASK = 1 shl SDL_QUITEV;
{$EXTERNALSYM SDL_QUITMASK}
SDL_SYSWMEVENTMASK = 1 shl SDL_SYSWMEVENT;
{$EXTERNALSYM SDL_SYSWMEVENTMASK}
{ This function allows you to set the state of processing certain events.
If 'state' is set to SDL_IGNORE, that event will be automatically dropped
from the event queue and will not event be filtered.
If 'state' is set to SDL_ENABLE, that event will be processed normally.
If 'state' is set to SDL_QUERY, SDL_EventState() will return the
current processing state of the specified event. }
SDL_QUERY = -1;
{$EXTERNALSYM SDL_QUERY}
SDL_IGNORE = 0;
{$EXTERNALSYM SDL_IGNORE}
SDL_DISABLE = 0;
{$EXTERNALSYM SDL_DISABLE}
SDL_ENABLE = 1;
{$EXTERNALSYM SDL_ENABLE}
//SDL_keyboard.h constants
// This is the mask which refers to all hotkey bindings
SDL_ALL_HOTKEYS = $FFFFFFFF;
{$EXTERNALSYM SDL_ALL_HOTKEYS}
{ Enable/Disable keyboard repeat. Keyboard repeat defaults to off.
'delay' is the initial delay in ms between the time when a key is
pressed, and keyboard repeat begins.
'interval' is the time in ms between keyboard repeat events. }
SDL_DEFAULT_REPEAT_DELAY = 500;
{$EXTERNALSYM SDL_DEFAULT_REPEAT_DELAY}
SDL_DEFAULT_REPEAT_INTERVAL = 30;
{$EXTERNALSYM SDL_DEFAULT_REPEAT_INTERVAL}
// The keyboard syms have been cleverly chosen to map to ASCII
SDLK_UNKNOWN = 0;
{$EXTERNALSYM SDLK_UNKNOWN}
SDLK_FIRST = 0;
{$EXTERNALSYM SDLK_FIRST}
SDLK_BACKSPACE = 8;
{$EXTERNALSYM SDLK_BACKSPACE}
SDLK_TAB = 9;
{$EXTERNALSYM SDLK_TAB}
SDLK_CLEAR = 12;
{$EXTERNALSYM SDLK_CLEAR}
SDLK_RETURN = 13;
{$EXTERNALSYM SDLK_RETURN}
SDLK_PAUSE = 19;
{$EXTERNALSYM SDLK_PAUSE}
SDLK_ESCAPE = 27;
{$EXTERNALSYM SDLK_ESCAPE}
SDLK_SPACE = 32;
{$EXTERNALSYM SDLK_SPACE}
SDLK_EXCLAIM = 33;
{$EXTERNALSYM SDLK_EXCLAIM}
SDLK_QUOTEDBL = 34;
{$EXTERNALSYM SDLK_QUOTEDBL}
SDLK_HASH = 35;
{$EXTERNALSYM SDLK_HASH}
SDLK_DOLLAR = 36;
{$EXTERNALSYM SDLK_DOLLAR}
SDLK_AMPERSAND = 38;
{$EXTERNALSYM SDLK_AMPERSAND}
SDLK_QUOTE = 39;
{$EXTERNALSYM SDLK_QUOTE}
SDLK_LEFTPAREN = 40;
{$EXTERNALSYM SDLK_LEFTPAREN}
SDLK_RIGHTPAREN = 41;
{$EXTERNALSYM SDLK_RIGHTPAREN}
SDLK_ASTERISK = 42;
{$EXTERNALSYM SDLK_ASTERISK}
SDLK_PLUS = 43;
{$EXTERNALSYM SDLK_PLUS}
SDLK_COMMA = 44;
{$EXTERNALSYM SDLK_COMMA}
SDLK_MINUS = 45;
{$EXTERNALSYM SDLK_MINUS}
SDLK_PERIOD = 46;
{$EXTERNALSYM SDLK_PERIOD}
SDLK_SLASH = 47;
{$EXTERNALSYM SDLK_SLASH}
SDLK_0 = 48;
{$EXTERNALSYM SDLK_0}
SDLK_1 = 49;
{$EXTERNALSYM SDLK_1}
SDLK_2 = 50;
{$EXTERNALSYM SDLK_2}
SDLK_3 = 51;
{$EXTERNALSYM SDLK_3}
SDLK_4 = 52;
{$EXTERNALSYM SDLK_4}
SDLK_5 = 53;
{$EXTERNALSYM SDLK_5}
SDLK_6 = 54;
{$EXTERNALSYM SDLK_6}
SDLK_7 = 55;
{$EXTERNALSYM SDLK_7}
SDLK_8 = 56;
{$EXTERNALSYM SDLK_8}
SDLK_9 = 57;
{$EXTERNALSYM SDLK_9}
SDLK_COLON = 58;
{$EXTERNALSYM SDLK_COLON}
SDLK_SEMICOLON = 59;
{$EXTERNALSYM SDLK_SEMICOLON}
SDLK_LESS = 60;
{$EXTERNALSYM SDLK_LESS}
SDLK_EQUALS = 61;
{$EXTERNALSYM SDLK_EQUALS}
SDLK_GREATER = 62;
{$EXTERNALSYM SDLK_GREATER}
SDLK_QUESTION = 63;
{$EXTERNALSYM SDLK_QUESTION}
SDLK_AT = 64;
{$EXTERNALSYM SDLK_AT}
{ Skip uppercase letters }
SDLK_LEFTBRACKET = 91;
{$EXTERNALSYM SDLK_LEFTBRACKET}
SDLK_BACKSLASH = 92;
{$EXTERNALSYM SDLK_BACKSLASH}
SDLK_RIGHTBRACKET = 93;
{$EXTERNALSYM SDLK_RIGHTBRACKET}
SDLK_CARET = 94;
{$EXTERNALSYM SDLK_CARET}
SDLK_UNDERSCORE = 95;
{$EXTERNALSYM SDLK_UNDERSCORE}
SDLK_BACKQUOTE = 96;
{$EXTERNALSYM SDLK_BACKQUOTE}
SDLK_a = 97;
{$EXTERNALSYM SDLK_a}
SDLK_b = 98;
{$EXTERNALSYM SDLK_b}
SDLK_c = 99;
{$EXTERNALSYM SDLK_c}
SDLK_d = 100;
{$EXTERNALSYM SDLK_d}
SDLK_e = 101;
{$EXTERNALSYM SDLK_e}
SDLK_f = 102;
{$EXTERNALSYM SDLK_f}
SDLK_g = 103;
{$EXTERNALSYM SDLK_g}
SDLK_h = 104;
{$EXTERNALSYM SDLK_h}
SDLK_i = 105;
{$EXTERNALSYM SDLK_i}
SDLK_j = 106;
{$EXTERNALSYM SDLK_j}
SDLK_k = 107;
{$EXTERNALSYM SDLK_k}
SDLK_l = 108;
{$EXTERNALSYM SDLK_l}
SDLK_m = 109;
{$EXTERNALSYM SDLK_m}
SDLK_n = 110;
{$EXTERNALSYM SDLK_n}
SDLK_o = 111;
{$EXTERNALSYM SDLK_o}
SDLK_p = 112;
{$EXTERNALSYM SDLK_p}
SDLK_q = 113;
{$EXTERNALSYM SDLK_q}
SDLK_r = 114;
{$EXTERNALSYM SDLK_r}
SDLK_s = 115;
{$EXTERNALSYM SDLK_s}
SDLK_t = 116;
{$EXTERNALSYM SDLK_t}
SDLK_u = 117;
{$EXTERNALSYM SDLK_u}
SDLK_v = 118;
{$EXTERNALSYM SDLK_v}
SDLK_w = 119;
{$EXTERNALSYM SDLK_w}
SDLK_x = 120;
{$EXTERNALSYM SDLK_x}
SDLK_y = 121;
{$EXTERNALSYM SDLK_y}
SDLK_z = 122;
{$EXTERNALSYM SDLK_z}
SDLK_DELETE = 127;
{$EXTERNALSYM SDLK_DELETE}
// End of ASCII mapped keysyms
// International keyboard syms
SDLK_WORLD_0 = 160; // 0xA0
{$EXTERNALSYM SDLK_WORLD_0}
SDLK_WORLD_1 = 161;
{$EXTERNALSYM SDLK_WORLD_1}
SDLK_WORLD_2 = 162;
{$EXTERNALSYM SDLK_WORLD_2}
SDLK_WORLD_3 = 163;
{$EXTERNALSYM SDLK_WORLD_3}
SDLK_WORLD_4 = 164;
{$EXTERNALSYM SDLK_WORLD_4}
SDLK_WORLD_5 = 165;
{$EXTERNALSYM SDLK_WORLD_5}
SDLK_WORLD_6 = 166;
{$EXTERNALSYM SDLK_WORLD_6}
SDLK_WORLD_7 = 167;
{$EXTERNALSYM SDLK_WORLD_7}
SDLK_WORLD_8 = 168;
{$EXTERNALSYM SDLK_WORLD_8}
SDLK_WORLD_9 = 169;
{$EXTERNALSYM SDLK_WORLD_9}
SDLK_WORLD_10 = 170;
{$EXTERNALSYM SDLK_WORLD_10}
SDLK_WORLD_11 = 171;
{$EXTERNALSYM SDLK_WORLD_11}
SDLK_WORLD_12 = 172;
{$EXTERNALSYM SDLK_WORLD_12}
SDLK_WORLD_13 = 173;
{$EXTERNALSYM SDLK_WORLD_13}
SDLK_WORLD_14 = 174;
{$EXTERNALSYM SDLK_WORLD_14}
SDLK_WORLD_15 = 175;
{$EXTERNALSYM SDLK_WORLD_15}
SDLK_WORLD_16 = 176;
{$EXTERNALSYM SDLK_WORLD_16}
SDLK_WORLD_17 = 177;
{$EXTERNALSYM SDLK_WORLD_17}
SDLK_WORLD_18 = 178;
{$EXTERNALSYM SDLK_WORLD_18}
SDLK_WORLD_19 = 179;
{$EXTERNALSYM SDLK_WORLD_19}
SDLK_WORLD_20 = 180;
{$EXTERNALSYM SDLK_WORLD_20}
SDLK_WORLD_21 = 181;
{$EXTERNALSYM SDLK_WORLD_21}
SDLK_WORLD_22 = 182;
{$EXTERNALSYM SDLK_WORLD_22}
SDLK_WORLD_23 = 183;
{$EXTERNALSYM SDLK_WORLD_23}
SDLK_WORLD_24 = 184;
{$EXTERNALSYM SDLK_WORLD_24}
SDLK_WORLD_25 = 185;
{$EXTERNALSYM SDLK_WORLD_25}
SDLK_WORLD_26 = 186;
{$EXTERNALSYM SDLK_WORLD_26}
SDLK_WORLD_27 = 187;
{$EXTERNALSYM SDLK_WORLD_27}
SDLK_WORLD_28 = 188;
{$EXTERNALSYM SDLK_WORLD_28}
SDLK_WORLD_29 = 189;
{$EXTERNALSYM SDLK_WORLD_29}
SDLK_WORLD_30 = 190;
{$EXTERNALSYM SDLK_WORLD_30}
SDLK_WORLD_31 = 191;
{$EXTERNALSYM SDLK_WORLD_31}
SDLK_WORLD_32 = 192;
{$EXTERNALSYM SDLK_WORLD_32}
SDLK_WORLD_33 = 193;
{$EXTERNALSYM SDLK_WORLD_33}
SDLK_WORLD_34 = 194;
{$EXTERNALSYM SDLK_WORLD_34}
SDLK_WORLD_35 = 195;
{$EXTERNALSYM SDLK_WORLD_35}
SDLK_WORLD_36 = 196;
{$EXTERNALSYM SDLK_WORLD_36}
SDLK_WORLD_37 = 197;
{$EXTERNALSYM SDLK_WORLD_37}
SDLK_WORLD_38 = 198;
{$EXTERNALSYM SDLK_WORLD_38}
SDLK_WORLD_39 = 199;
{$EXTERNALSYM SDLK_WORLD_39}
SDLK_WORLD_40 = 200;
{$EXTERNALSYM SDLK_WORLD_40}
SDLK_WORLD_41 = 201;
{$EXTERNALSYM SDLK_WORLD_41}
SDLK_WORLD_42 = 202;
{$EXTERNALSYM SDLK_WORLD_42}
SDLK_WORLD_43 = 203;
{$EXTERNALSYM SDLK_WORLD_43}
SDLK_WORLD_44 = 204;
{$EXTERNALSYM SDLK_WORLD_44}
SDLK_WORLD_45 = 205;
{$EXTERNALSYM SDLK_WORLD_45}
SDLK_WORLD_46 = 206;
{$EXTERNALSYM SDLK_WORLD_46}
SDLK_WORLD_47 = 207;
{$EXTERNALSYM SDLK_WORLD_47}
SDLK_WORLD_48 = 208;
{$EXTERNALSYM SDLK_WORLD_48}
SDLK_WORLD_49 = 209;
{$EXTERNALSYM SDLK_WORLD_49}
SDLK_WORLD_50 = 210;
{$EXTERNALSYM SDLK_WORLD_50}
SDLK_WORLD_51 = 211;
{$EXTERNALSYM SDLK_WORLD_51}
SDLK_WORLD_52 = 212;
{$EXTERNALSYM SDLK_WORLD_52}
SDLK_WORLD_53 = 213;
{$EXTERNALSYM SDLK_WORLD_53}
SDLK_WORLD_54 = 214;
{$EXTERNALSYM SDLK_WORLD_54}
SDLK_WORLD_55 = 215;
{$EXTERNALSYM SDLK_WORLD_55}
SDLK_WORLD_56 = 216;
{$EXTERNALSYM SDLK_WORLD_56}
SDLK_WORLD_57 = 217;
{$EXTERNALSYM SDLK_WORLD_57}
SDLK_WORLD_58 = 218;
{$EXTERNALSYM SDLK_WORLD_58}
SDLK_WORLD_59 = 219;
{$EXTERNALSYM SDLK_WORLD_59}
SDLK_WORLD_60 = 220;
{$EXTERNALSYM SDLK_WORLD_60}
SDLK_WORLD_61 = 221;
{$EXTERNALSYM SDLK_WORLD_61}
SDLK_WORLD_62 = 222;
{$EXTERNALSYM SDLK_WORLD_62}
SDLK_WORLD_63 = 223;
{$EXTERNALSYM SDLK_WORLD_63}
SDLK_WORLD_64 = 224;
{$EXTERNALSYM SDLK_WORLD_64}
SDLK_WORLD_65 = 225;
{$EXTERNALSYM SDLK_WORLD_65}
SDLK_WORLD_66 = 226;
{$EXTERNALSYM SDLK_WORLD_66}
SDLK_WORLD_67 = 227;
{$EXTERNALSYM SDLK_WORLD_67}
SDLK_WORLD_68 = 228;
{$EXTERNALSYM SDLK_WORLD_68}
SDLK_WORLD_69 = 229;
{$EXTERNALSYM SDLK_WORLD_69}
SDLK_WORLD_70 = 230;
{$EXTERNALSYM SDLK_WORLD_70}
SDLK_WORLD_71 = 231;
{$EXTERNALSYM SDLK_WORLD_71}
SDLK_WORLD_72 = 232;
{$EXTERNALSYM SDLK_WORLD_72}
SDLK_WORLD_73 = 233;
{$EXTERNALSYM SDLK_WORLD_73}
SDLK_WORLD_74 = 234;
{$EXTERNALSYM SDLK_WORLD_74}
SDLK_WORLD_75 = 235;
{$EXTERNALSYM SDLK_WORLD_75}
SDLK_WORLD_76 = 236;
{$EXTERNALSYM SDLK_WORLD_76}
SDLK_WORLD_77 = 237;
{$EXTERNALSYM SDLK_WORLD_77}
SDLK_WORLD_78 = 238;
{$EXTERNALSYM SDLK_WORLD_78}
SDLK_WORLD_79 = 239;
{$EXTERNALSYM SDLK_WORLD_79}
SDLK_WORLD_80 = 240;
{$EXTERNALSYM SDLK_WORLD_80}
SDLK_WORLD_81 = 241;
{$EXTERNALSYM SDLK_WORLD_81}
SDLK_WORLD_82 = 242;
{$EXTERNALSYM SDLK_WORLD_82}
SDLK_WORLD_83 = 243;
{$EXTERNALSYM SDLK_WORLD_83}
SDLK_WORLD_84 = 244;
{$EXTERNALSYM SDLK_WORLD_84}
SDLK_WORLD_85 = 245;
{$EXTERNALSYM SDLK_WORLD_85}
SDLK_WORLD_86 = 246;
{$EXTERNALSYM SDLK_WORLD_86}
SDLK_WORLD_87 = 247;
{$EXTERNALSYM SDLK_WORLD_87}
SDLK_WORLD_88 = 248;
{$EXTERNALSYM SDLK_WORLD_88}
SDLK_WORLD_89 = 249;
{$EXTERNALSYM SDLK_WORLD_89}
SDLK_WORLD_90 = 250;
{$EXTERNALSYM SDLK_WORLD_90}
SDLK_WORLD_91 = 251;
{$EXTERNALSYM SDLK_WORLD_91}
SDLK_WORLD_92 = 252;
{$EXTERNALSYM SDLK_WORLD_92}
SDLK_WORLD_93 = 253;
{$EXTERNALSYM SDLK_WORLD_93}
SDLK_WORLD_94 = 254;
{$EXTERNALSYM SDLK_WORLD_94}
SDLK_WORLD_95 = 255; // 0xFF
{$EXTERNALSYM SDLK_WORLD_95}
// Numeric keypad
SDLK_KP0 = 256;
{$EXTERNALSYM SDLK_KP0}
SDLK_KP1 = 257;
{$EXTERNALSYM SDLK_KP1}
SDLK_KP2 = 258;
{$EXTERNALSYM SDLK_KP2}
SDLK_KP3 = 259;
{$EXTERNALSYM SDLK_KP3}
SDLK_KP4 = 260;
{$EXTERNALSYM SDLK_KP4}
SDLK_KP5 = 261;
{$EXTERNALSYM SDLK_KP5}
SDLK_KP6 = 262;
{$EXTERNALSYM SDLK_KP6}
SDLK_KP7 = 263;
{$EXTERNALSYM SDLK_KP7}
SDLK_KP8 = 264;
{$EXTERNALSYM SDLK_KP8}
SDLK_KP9 = 265;
{$EXTERNALSYM SDLK_KP9}
SDLK_KP_PERIOD = 266;
{$EXTERNALSYM SDLK_KP_PERIOD}
SDLK_KP_DIVIDE = 267;
{$EXTERNALSYM SDLK_KP_DIVIDE}
SDLK_KP_MULTIPLY = 268;
{$EXTERNALSYM SDLK_KP_MULTIPLY}
SDLK_KP_MINUS = 269;
{$EXTERNALSYM SDLK_KP_MINUS}
SDLK_KP_PLUS = 270;
{$EXTERNALSYM SDLK_KP_PLUS}
SDLK_KP_ENTER = 271;
{$EXTERNALSYM SDLK_KP_ENTER}
SDLK_KP_EQUALS = 272;
{$EXTERNALSYM SDLK_KP_EQUALS}
// Arrows + Home/End pad
SDLK_UP = 273;
{$EXTERNALSYM SDLK_UP}
SDLK_DOWN = 274;
{$EXTERNALSYM SDLK_DOWN}
SDLK_RIGHT = 275;
{$EXTERNALSYM SDLK_RIGHT}
SDLK_LEFT = 276;
{$EXTERNALSYM SDLK_LEFT}
SDLK_INSERT = 277;
{$EXTERNALSYM SDLK_INSERT}
SDLK_HOME = 278;
{$EXTERNALSYM SDLK_HOME}
SDLK_END = 279;
{$EXTERNALSYM SDLK_END}
SDLK_PAGEUP = 280;
{$EXTERNALSYM SDLK_PAGEUP}
SDLK_PAGEDOWN = 281;
{$EXTERNALSYM SDLK_PAGEDOWN}
// Function keys
SDLK_F1 = 282;
{$EXTERNALSYM SDLK_F1}
SDLK_F2 = 283;
{$EXTERNALSYM SDLK_F2}
SDLK_F3 = 284;
{$EXTERNALSYM SDLK_F3}
SDLK_F4 = 285;
{$EXTERNALSYM SDLK_F4}
SDLK_F5 = 286;
{$EXTERNALSYM SDLK_F5}
SDLK_F6 = 287;
{$EXTERNALSYM SDLK_F6}
SDLK_F7 = 288;
{$EXTERNALSYM SDLK_F7}
SDLK_F8 = 289;
{$EXTERNALSYM SDLK_F8}
SDLK_F9 = 290;
{$EXTERNALSYM SDLK_F9}
SDLK_F10 = 291;
{$EXTERNALSYM SDLK_F10}
SDLK_F11 = 292;
{$EXTERNALSYM SDLK_F11}
SDLK_F12 = 293;
{$EXTERNALSYM SDLK_F12}
SDLK_F13 = 294;
{$EXTERNALSYM SDLK_F13}
SDLK_F14 = 295;
{$EXTERNALSYM SDLK_F14}
SDLK_F15 = 296;
{$EXTERNALSYM SDLK_F15}
// Key state modifier keys
SDLK_NUMLOCK = 300;
{$EXTERNALSYM SDLK_NUMLOCK}
SDLK_CAPSLOCK = 301;
{$EXTERNALSYM SDLK_CAPSLOCK}
SDLK_SCROLLOCK = 302;
{$EXTERNALSYM SDLK_SCROLLOCK}
SDLK_RSHIFT = 303;
{$EXTERNALSYM SDLK_RSHIFT}
SDLK_LSHIFT = 304;
{$EXTERNALSYM SDLK_LSHIFT}
SDLK_RCTRL = 305;
{$EXTERNALSYM SDLK_RCTRL}
SDLK_LCTRL = 306;
{$EXTERNALSYM SDLK_LCTRL}
SDLK_RALT = 307;
{$EXTERNALSYM SDLK_RALT}
SDLK_LALT = 308;
{$EXTERNALSYM SDLK_LALT}
SDLK_RMETA = 309;
{$EXTERNALSYM SDLK_RMETA}
SDLK_LMETA = 310;
{$EXTERNALSYM SDLK_LMETA}
SDLK_LSUPER = 311; // Left "Windows" key
{$EXTERNALSYM SDLK_LSUPER}
SDLK_RSUPER = 312; // Right "Windows" key
{$EXTERNALSYM SDLK_RSUPER}
SDLK_MODE = 313; // "Alt Gr" key
{$EXTERNALSYM SDLK_MODE}
SDLK_COMPOSE = 314; // Multi-key compose key
{$EXTERNALSYM SDLK_COMPOSE}
// Miscellaneous function keys
SDLK_HELP = 315;
{$EXTERNALSYM SDLK_HELP}
SDLK_PRINT = 316;
{$EXTERNALSYM SDLK_PRINT}
SDLK_SYSREQ = 317;
{$EXTERNALSYM SDLK_SYSREQ}
SDLK_BREAK = 318;
{$EXTERNALSYM SDLK_BREAK}
SDLK_MENU = 319;
{$EXTERNALSYM SDLK_MENU}
SDLK_POWER = 320; // Power Macintosh power key
{$EXTERNALSYM SDLK_POWER}
SDLK_EURO = 321; // Some european keyboards
{$EXTERNALSYM SDLK_EURO}
{$IFDEF GP2X}
SDLK_GP2X_UP = 0;
{$EXTERNALSYM SDLK_GP2X_UP}
SDLK_GP2X_UPLEFT = 1;
{$EXTERNALSYM SDLK_GP2X_UPLEFT}
SDLK_GP2X_LEFT = 2;
{$EXTERNALSYM SDLK_GP2X_LEFT}
SDLK_GP2X_DOWNLEFT = 3;
{$EXTERNALSYM SDLK_GP2X_DOWNLEFT}
SDLK_GP2X_DOWN = 4;
{$EXTERNALSYM SDLK_GP2X_DOWN}
SDLK_GP2X_DOWNRIGHT = 5;
{$EXTERNALSYM SDLK_GP2X_DOWNRIGHT}
SDLK_GP2X_RIGHT = 6;
{$EXTERNALSYM SDLK_GP2X_RIGHT}
SDLK_GP2X_UPRIGHT = 7;
{$EXTERNALSYM SDLK_GP2X_UPRIGHT}
SDLK_GP2X_START = 8;
{$EXTERNALSYM SDLK_GP2X_START}
SDLK_GP2X_SELECT = 9;
{$EXTERNALSYM SDLK_GP2X_SELECT}
SDLK_GP2X_L = 10;
{$EXTERNALSYM SDLK_GP2X_L}
SDLK_GP2X_R = 11;
{$EXTERNALSYM SDLK_GP2X_R}
SDLK_GP2X_A = 12;
{$EXTERNALSYM SDLK_GP2X_A}
SDLK_GP2X_B = 13;
{$EXTERNALSYM SDLK_GP2X_B}
SDLK_GP2X_Y = 14;
{$EXTERNALSYM SDLK_GP2X_Y}
SDLK_GP2X_X = 15;
{$EXTERNALSYM SDLK_GP2X_X}
SDLK_GP2X_VOLUP = 16;
{$EXTERNALSYM SDLK_GP2X_VOLUP}
SDLK_GP2X_VOLDOWN = 17;
{$EXTERNALSYM SDLK_GP2X_VOLDOWN}
SDLK_GP2X_CLICK = 18;
{$EXTERNALSYM SDLK_GP2X_CLICK}
{$ENDIF}
// Enumeration of valid key mods (possibly OR'd together)
KMOD_NONE = $0000;
{$EXTERNALSYM KMOD_NONE}
KMOD_LSHIFT = $0001;
{$EXTERNALSYM KMOD_LSHIFT}
KMOD_RSHIFT = $0002;
{$EXTERNALSYM KMOD_RSHIFT}
KMOD_LCTRL = $0040;
{$EXTERNALSYM KMOD_LCTRL}
KMOD_RCTRL = $0080;
{$EXTERNALSYM KMOD_RCTRL}
KMOD_LALT = $0100;
{$EXTERNALSYM KMOD_LALT}
KMOD_RALT = $0200;
{$EXTERNALSYM KMOD_RALT}
KMOD_LMETA = $0400;
{$EXTERNALSYM KMOD_LMETA}
KMOD_RMETA = $0800;
{$EXTERNALSYM KMOD_RMETA}
KMOD_NUM = $1000;
{$EXTERNALSYM KMOD_NUM}
KMOD_CAPS = $2000;
{$EXTERNALSYM KMOD_CAPS}
KMOD_MODE = 44000;
{$EXTERNALSYM KMOD_MODE}
KMOD_RESERVED = $8000;
{$EXTERNALSYM KMOD_RESERVED}
KMOD_CTRL = (KMOD_LCTRL or KMOD_RCTRL);
{$EXTERNALSYM KMOD_CTRL}
KMOD_SHIFT = (KMOD_LSHIFT or KMOD_RSHIFT);
{$EXTERNALSYM KMOD_SHIFT}
KMOD_ALT = (KMOD_LALT or KMOD_RALT);
{$EXTERNALSYM KMOD_ALT}
KMOD_META = (KMOD_LMETA or KMOD_RMETA);
{$EXTERNALSYM KMOD_META}
//SDL_video.h constants
// Transparency definitions: These define alpha as the opacity of a surface */
SDL_ALPHA_OPAQUE = 255;
{$EXTERNALSYM SDL_ALPHA_OPAQUE}
SDL_ALPHA_TRANSPARENT = 0;
{$EXTERNALSYM SDL_ALPHA_TRANSPARENT}
// These are the currently supported flags for the SDL_surface
// Available for SDL_CreateRGBSurface() or SDL_SetVideoMode()
SDL_SWSURFACE = $00000000; // Surface is in system memory
{$EXTERNALSYM SDL_SWSURFACE}
SDL_HWSURFACE = $00000001; // Surface is in video memory
{$EXTERNALSYM SDL_HWSURFACE}
SDL_ASYNCBLIT = $00000004; // Use asynchronous blits if possible
{$EXTERNALSYM SDL_ASYNCBLIT}
// Available for SDL_SetVideoMode()
SDL_ANYFORMAT = $10000000; // Allow any video depth/pixel-format
{$EXTERNALSYM SDL_ANYFORMAT}
SDL_HWPALETTE = $20000000; // Surface has exclusive palette
{$EXTERNALSYM SDL_HWPALETTE}
SDL_DOUBLEBUF = $40000000; // Set up double-buffered video mode
{$EXTERNALSYM SDL_DOUBLEBUF}
SDL_FULLSCREEN = $80000000; // Surface is a full screen display
{$EXTERNALSYM SDL_FULLSCREEN}
SDL_OPENGL = $00000002; // Create an OpenGL rendering context
{$EXTERNALSYM SDL_OPENGL}
SDL_OPENGLBLIT = $00000002; // Create an OpenGL rendering context
{$EXTERNALSYM SDL_OPENGLBLIT}
SDL_RESIZABLE = $00000010; // This video mode may be resized
{$EXTERNALSYM SDL_RESIZABLE}
SDL_NOFRAME = $00000020; // No window caption or edge frame
{$EXTERNALSYM SDL_NOFRAME}
// Used internally (read-only)
SDL_HWACCEL = $00000100; // Blit uses hardware acceleration
{$EXTERNALSYM SDL_HWACCEL}
SDL_SRCCOLORKEY = $00001000; // Blit uses a source color key
{$EXTERNALSYM SDL_SRCCOLORKEY}
SDL_RLEACCELOK = $00002000; // Private flag
{$EXTERNALSYM SDL_RLEACCELOK}
SDL_RLEACCEL = $00004000; // Colorkey blit is RLE accelerated
{$EXTERNALSYM SDL_RLEACCEL}
SDL_SRCALPHA = $00010000; // Blit uses source alpha blending
{$EXTERNALSYM SDL_SRCALPHA}
SDL_SRCCLIPPING = $00100000; // Blit uses source clipping
{$EXTERNALSYM SDL_SRCCLIPPING}
SDL_PREALLOC = $01000000; // Surface uses preallocated memory
{$EXTERNALSYM SDL_PREALLOC}
{ The most common video overlay formats.
For an explanation of these pixel formats, see:
http://www.webartz.com/fourcc/indexyuv.htm
For information on the relationship between color spaces, see:
http://www.neuro.sfc.keio.ac.jp/~aly/polygon/info/color-space-faq.html }
SDL_YV12_OVERLAY = $32315659; // Planar mode: Y + V + U (3 planes)
{$EXTERNALSYM SDL_YV12_OVERLAY}
SDL_IYUV_OVERLAY = $56555949; // Planar mode: Y + U + V (3 planes)
{$EXTERNALSYM SDL_IYUV_OVERLAY}
SDL_YUY2_OVERLAY = $32595559; // Packed mode: Y0+U0+Y1+V0 (1 plane)
{$EXTERNALSYM SDL_YUY2_OVERLAY}
SDL_UYVY_OVERLAY = $59565955; // Packed mode: U0+Y0+V0+Y1 (1 plane)
{$EXTERNALSYM SDL_UYVY_OVERLAY}
SDL_YVYU_OVERLAY = $55595659; // Packed mode: Y0+V0+Y1+U0 (1 plane)
{$EXTERNALSYM SDL_YVYU_OVERLAY}
// flags for SDL_SetPalette()
SDL_LOGPAL = $01;
{$EXTERNALSYM SDL_LOGPAL}
SDL_PHYSPAL = $02;
{$EXTERNALSYM SDL_PHYSPAL}
//SDL_mouse.h constants
{ Used as a mask when testing buttons in buttonstate
Button 1: Left mouse button
Button 2: Middle mouse button
Button 3: Right mouse button
Button 4: Mouse Wheel Up (may also be a real button)
Button 5: Mouse Wheel Down (may also be a real button)
Button 6: Mouse X1 (may also be a real button)
Button 7: Mouse X2 (may also be a real button)
}
SDL_BUTTON_LEFT = 1;
{$EXTERNALSYM SDL_BUTTON_LEFT}
SDL_BUTTON_MIDDLE = 2;
{$EXTERNALSYM SDL_BUTTON_MIDDLE}
SDL_BUTTON_RIGHT = 3;
{$EXTERNALSYM SDL_BUTTON_RIGHT}
SDL_BUTTON_WHEELUP = 4;
{$EXTERNALSYM SDL_BUTTON_WHEELUP}
SDL_BUTTON_WHEELDOWN = 5;
{$EXTERNALSYM SDL_BUTTON_WHEELDOWN}
SDL_BUTTON_X1 = 6;
{$EXTERNALSYM SDL_BUTTON_X1}
SDL_BUTTON_X2 = 7;
{$EXTERNALSYM SDL_BUTTON_X2}
SDL_BUTTON_LMASK = SDL_PRESSED shl (SDL_BUTTON_LEFT - 1);
{$EXTERNALSYM SDL_BUTTON_LMASK}
SDL_BUTTON_MMASK = SDL_PRESSED shl (SDL_BUTTON_MIDDLE - 1);
{$EXTERNALSYM SDL_BUTTON_MMASK}
SDL_BUTTON_RMASK = SDL_PRESSED shl (SDL_BUTTON_RIGHT - 1);
{$EXTERNALSYM SDL_BUTTON_RMASK}
SDL_BUTTON_X1MASK = SDL_PRESSED shl (SDL_BUTTON_X1 - 1);
{$EXTERNALSYM SDL_BUTTON_X1MASK}
SDL_BUTTON_X2MASK = SDL_PRESSED shl (SDL_BUTTON_X2 - 1);
{$EXTERNALSYM SDL_BUTTON_X2MASK}
// SDL_active.h constants
// The available application states
SDL_APPMOUSEFOCUS = $01; // The app has mouse coverage
{$EXTERNALSYM SDL_APPMOUSEFOCUS}
SDL_APPINPUTFOCUS = $02; // The app has input focus
{$EXTERNALSYM SDL_APPINPUTFOCUS}
SDL_APPACTIVE = $04; // The application is active
{$EXTERNALSYM SDL_APPACTIVE}
// SDL_mutex.h constants
// Synchronization functions which can time out return this value
// they time out.
SDL_MUTEX_TIMEDOUT = 1;
{$EXTERNALSYM SDL_MUTEX_TIMEDOUT}
// This is the timeout value which corresponds to never time out
SDL_MUTEX_MAXWAIT = not Cardinal(0);
{$EXTERNALSYM SDL_MUTEX_MAXWAIT}
{TSDL_GrabMode = (
SDL_GRAB_QUERY,
SDL_GRAB_OFF,
SDL_GRAB_ON,
SDL_GRAB_FULLSCREEN ); // Used internally}
SDL_GRAB_QUERY = -1;
SDL_GRAB_OFF = 0;
SDL_GRAB_ON = 1;
//SDL_GRAB_FULLSCREEN // Used internally
type
THandle = Cardinal;
//SDL_types.h types
// Basic data types
SDL_Bool = (SDL_FALSE, SDL_TRUE);
TSDL_Bool = SDL_Bool;
PUInt8Array = ^TUInt8Array;
PUInt8 = ^UInt8;
PPUInt8 = ^PUInt8;
UInt8 = Byte;
{$EXTERNALSYM UInt8}
TUInt8Array = array [0..MAXINT shr 1] of UInt8;
PUInt16 = ^UInt16;
UInt16 = word;
{$EXTERNALSYM UInt16}
PSInt8 = ^SInt8;
SInt8 = Shortint;
{$EXTERNALSYM SInt8}
PSInt16 = ^SInt16;
SInt16 = smallint;
{$EXTERNALSYM SInt16}
PUInt32 = ^UInt32;
UInt32 = Cardinal;
{$EXTERNALSYM UInt32}
SInt32 = Integer;
{$EXTERNALSYM SInt32}
PInt = ^Integer;
PShortInt = ^ShortInt;
PUInt64 = ^UInt64;
UInt64 = record
hi: UInt32;
lo: UInt32;
end;
{$EXTERNALSYM UInt64}
PSInt64 = ^SInt64;
SInt64 = record
hi: UInt32;
lo: UInt32;
end;
{$EXTERNALSYM SInt64}
TSDL_GrabMode = Integer;
// SDL_error.h types
TSDL_errorcode = (
SDL_ENOMEM,
SDL_EFREAD,
SDL_EFWRITE,
SDL_EFSEEK,
SDL_LASTERROR);
SDL_errorcode = TSDL_errorcode;
{$EXTERNALSYM SDL_errorcode}
TArg = record
case Byte of
0: (value_ptr: Pointer);
(* #if 0 means: never
1 : ( value_c : Byte );
*)
2: (value_i: Integer);
3: (value_f: double);
4: (buf: array[0..ERR_MAX_STRLEN - 1] of Byte);
end;
PSDL_error = ^TSDL_error;
TSDL_error = record
{ This is a numeric value corresponding to the current error }
error: Integer;
{ This is a key used to index into a language hashtable containing
internationalized versions of the SDL error messages. If the key
is not in the hashtable, or no hashtable is available, the key is
used directly as an error message format string. }
key: array[0..ERR_MAX_STRLEN - 1] of Byte;
{ These are the arguments for the error functions }
argc: Integer;
args: array[0..ERR_MAX_ARGS - 1] of TArg;
end;
// SDL_rwops.h types
// This is the read/write operation structure -- very basic
// some helper types to handle the unions
// "packed" is only guessed
TStdio = record
autoclose: Integer;
// FILE * is only defined in Kylix so we use a simple Pointer
fp: Pointer;
end;
TMem = record
base: PUInt8;
here: PUInt8;
stop: PUInt8;
end;
TUnknown = record
data1: Pointer;
end;
// first declare the pointer type
PSDL_RWops = ^TSDL_RWops;
// now the pointer to function types
{$IFNDEF __GPC__}
TSeek = function( context: PSDL_RWops; offset: Integer; whence: Integer ): Integer; cdecl;
TRead = function( context: PSDL_RWops; Ptr: Pointer; size: Integer; maxnum : Integer ): Integer; cdecl;
TWrite = function( context: PSDL_RWops; Ptr: Pointer; size: Integer; num: Integer ): Integer; cdecl;
TClose = function( context: PSDL_RWops ): Integer; cdecl;
{$ELSE}
TSeek = function( context: PSDL_RWops; offset: Integer; whence: Integer ): Integer;
TRead = function( context: PSDL_RWops; Ptr: Pointer; size: Integer; maxnum : Integer ): Integer;
TWrite = function( context: PSDL_RWops; Ptr: Pointer; size: Integer; num: Integer ): Integer;
TClose = function( context: PSDL_RWops ): Integer;
{$ENDIF}
// the variant record itself
TSDL_RWops = record
seek: TSeek;
read: TRead;
write: TWrite;
close: TClose;
// a keyword as name is not allowed
type_: UInt32;
// be warned! structure alignment may arise at this point
case Integer of
0: (stdio: TStdio);
1: (mem: TMem);
2: (unknown: TUnknown);
end;
SDL_RWops = TSDL_RWops;
{$EXTERNALSYM SDL_RWops}
// SDL_timer.h types
// Function prototype for the timer callback function
{$IFNDEF __GPC__}
TSDL_TimerCallback = function( interval: UInt32 ): UInt32; cdecl;
{$ELSE}
TSDL_TimerCallback = function( interval: UInt32 ): UInt32;
{$ENDIF}
{ New timer API, supports multiple timers
Written by Stephane Peter <megastep@lokigames.com> }
{ Function prototype for the new timer callback function.
The callback function is passed the current timer interval and returns
the next timer interval. If the returned value is the same as the one
passed in, the periodic alarm continues, otherwise a new alarm is
scheduled. If the callback returns 0, the periodic alarm is cancelled. }
{$IFNDEF __GPC__}
TSDL_NewTimerCallback = function( interval: UInt32; param: Pointer ): UInt32; cdecl;
{$ELSE}
TSDL_NewTimerCallback = function( interval: UInt32; param: Pointer ): UInt32;
{$ENDIF}
// Definition of the timer ID type
PSDL_TimerID = ^TSDL_TimerID;
TSDL_TimerID = record
interval: UInt32;
callback: TSDL_NewTimerCallback;
param: Pointer;
last_alarm: UInt32;
next: PSDL_TimerID;
end;
{$IFNDEF __GPC__}
TSDL_AudioSpecCallback = procedure( userdata: Pointer; stream: PUInt8; len: Integer ); cdecl;
{$ELSE}
TSDL_AudioSpecCallback = procedure( userdata: Pointer; stream: PUInt8; len: Integer );
{$ENDIF}
// SDL_audio.h types
// The calculated values in this structure are calculated by SDL_OpenAudio()
PSDL_AudioSpec = ^TSDL_AudioSpec;
TSDL_AudioSpec = record
freq: Integer; // DSP frequency -- samples per second
format: UInt16; // Audio data format
channels: UInt8; // Number of channels: 1 mono, 2 stereo
silence: UInt8; // Audio buffer silence value (calculated)
samples: UInt16; // Audio buffer size in samples
padding: UInt16; // Necessary for some compile environments
size: UInt32; // Audio buffer size in bytes (calculated)
{ This function is called when the audio device needs more data.
'stream' is a pointer to the audio data buffer
'len' is the length of that buffer in bytes.
Once the callback returns, the buffer will no longer be valid.
Stereo samples are stored in a LRLRLR ordering.}
callback: TSDL_AudioSpecCallback;
userdata: Pointer;
end;
// A structure to hold a set of audio conversion filters and buffers
PSDL_AudioCVT = ^TSDL_AudioCVT;
PSDL_AudioCVTFilter = ^TSDL_AudioCVTFilter;
TSDL_AudioCVTFilter = record
cvt: PSDL_AudioCVT;
format: UInt16;
end;
PSDL_AudioCVTFilterArray = ^TSDL_AudioCVTFilterArray;
TSDL_AudioCVTFilterArray = array[0..9] of PSDL_AudioCVTFilter;
TSDL_AudioCVT = record
needed: Integer; // Set to 1 if conversion possible
src_format: UInt16; // Source audio format
dst_format: UInt16; // Target audio format
rate_incr: double; // Rate conversion increment
buf: PUInt8; // Buffer to hold entire audio data
len: Integer; // Length of original audio buffer
len_cvt: Integer; // Length of converted audio buffer
len_mult: Integer; // buffer must be len*len_mult big
len_ratio: double; // Given len, final size is len*len_ratio
filters: TSDL_AudioCVTFilterArray;
filter_index: Integer; // Current audio conversion function
end;
TSDL_Audiostatus = (
SDL_AUDIO_STOPPED,
SDL_AUDIO_PLAYING,
SDL_AUDIO_PAUSED
);
// SDL_cdrom.h types
TSDL_CDStatus = (
CD_ERROR,
CD_TRAYEMPTY,
CD_STOPPED,
CD_PLAYING,
CD_PAUSED );
PSDL_CDTrack = ^TSDL_CDTrack;
TSDL_CDTrack = record
id: UInt8; // Track number
type_: UInt8; // Data or audio track
unused: UInt16;
length: UInt32; // Length, in frames, of this track
offset: UInt32; // Offset, in frames, from start of disk
end;
// This structure is only current as of the last call to SDL_CDStatus()
PSDL_CD = ^TSDL_CD;
TSDL_CD = record
id: Integer; // Private drive identifier
status: TSDL_CDStatus; // Current drive status
// The rest of this structure is only valid if there's a CD in drive
numtracks: Integer; // Number of tracks on disk
cur_track: Integer; // Current track position
cur_frame: Integer; // Current frame offset within current track
track: array[0..SDL_MAX_TRACKS] of TSDL_CDTrack;
end;
//SDL_joystick.h types
PTransAxis = ^TTransAxis;
TTransAxis = record
offset: Integer;
scale: single;
end;
// The private structure used to keep track of a joystick
PJoystick_hwdata = ^TJoystick_hwdata;
TJoystick_hwdata = record
// joystick ID
id: Integer;
// values used to translate device-specific coordinates into SDL-standard ranges
transaxis: array[0..5] of TTransAxis;
end;
PBallDelta = ^TBallDelta;
TBallDelta = record
dx: Integer;
dy: Integer;
end; // Current ball motion deltas
// The SDL joystick structure
PSDL_Joystick = ^TSDL_Joystick;
TSDL_Joystick = record
index: UInt8; // Device index
name: PChar; // Joystick name - system dependent
naxes: Integer; // Number of axis controls on the joystick
axes: PUInt16; // Current axis states
nhats: Integer; // Number of hats on the joystick
hats: PUInt8; // Current hat states
nballs: Integer; // Number of trackballs on the joystick
balls: PBallDelta; // Current ball motion deltas
nbuttons: Integer; // Number of buttons on the joystick
buttons: PUInt8; // Current button states
hwdata: PJoystick_hwdata; // Driver dependent information
ref_count: Integer; // Reference count for multiple opens
end;
// SDL_verion.h types
PSDL_version = ^TSDL_version;
TSDL_version = record
major: UInt8;
minor: UInt8;
patch: UInt8;
end;
// SDL_keyboard.h types
TSDLKey = LongWord;
TSDLMod = LongWord;
PSDL_KeySym = ^TSDL_KeySym;
TSDL_KeySym = record
scancode: UInt8; // hardware specific scancode
sym: TSDLKey; // SDL virtual keysym
modifier: TSDLMod; // current key modifiers
unicode: UInt16; // translated character
end;
// SDL_events.h types
{Checks the event queue for messages and optionally returns them.
If 'action' is SDL_ADDEVENT, up to 'numevents' events will be added to
the back of the event queue.
If 'action' is SDL_PEEKEVENT, up to 'numevents' events at the front
of the event queue, matching 'mask', will be returned and will not
be removed from the queue.
If 'action' is SDL_GETEVENT, up to 'numevents' events at the front
of the event queue, matching 'mask', will be returned and will be
removed from the queue.
This function returns the number of events actually stored, or -1
if there was an error. This function is thread-safe. }
TSDL_EventAction = (SDL_ADDEVENT, SDL_PEEKEVENT, SDL_GETEVENT);
// Application visibility event structure
TSDL_ActiveEvent = record
type_: UInt8; // SDL_ACTIVEEVENT
gain: UInt8; // Whether given states were gained or lost (1/0)
state: UInt8; // A mask of the focus states
end;
// Keyboard event structure
TSDL_KeyboardEvent = record
type_: UInt8; // SDL_KEYDOWN or SDL_KEYUP
which: UInt8; // The keyboard device index
state: UInt8; // SDL_PRESSED or SDL_RELEASED
keysym: TSDL_KeySym;
end;
// Mouse motion event structure
TSDL_MouseMotionEvent = record
type_: UInt8; // SDL_MOUSEMOTION
which: UInt8; // The mouse device index
state: UInt8; // The current button state
x, y: UInt16; // The X/Y coordinates of the mouse
xrel: SInt16; // The relative motion in the X direction
yrel: SInt16; // The relative motion in the Y direction
end;
// Mouse button event structure
TSDL_MouseButtonEvent = record
type_: UInt8; // SDL_MOUSEBUTTONDOWN or SDL_MOUSEBUTTONUP
which: UInt8; // The mouse device index
button: UInt8; // The mouse button index
state: UInt8; // SDL_PRESSED or SDL_RELEASED
x: UInt16; // The X coordinates of the mouse at press time
y: UInt16; // The Y coordinates of the mouse at press time
end;
// Joystick axis motion event structure
TSDL_JoyAxisEvent = record
type_: UInt8; // SDL_JOYAXISMOTION
which: UInt8; // The joystick device index
axis: UInt8; // The joystick axis index
value: SInt16; // The axis value (range: -32768 to 32767)
end;
// Joystick trackball motion event structure
TSDL_JoyBallEvent = record
type_: UInt8; // SDL_JOYAVBALLMOTION
which: UInt8; // The joystick device index
ball: UInt8; // The joystick trackball index
xrel: SInt16; // The relative motion in the X direction
yrel: SInt16; // The relative motion in the Y direction
end;
// Joystick hat position change event structure
TSDL_JoyHatEvent = record
type_: UInt8; // SDL_JOYHATMOTION */
which: UInt8; // The joystick device index */
hat: UInt8; // The joystick hat index */
value: UInt8; { The hat position value:
8 1 2
7 0 3
6 5 4
Note that zero means the POV is centered. }
end;
// Joystick button event structure
TSDL_JoyButtonEvent = record
type_: UInt8; // SDL_JOYBUTTONDOWN or SDL_JOYBUTTONUP
which: UInt8; // The joystick device index
button: UInt8; // The joystick button index
state: UInt8; // SDL_PRESSED or SDL_RELEASED
end;
{ The "window resized" event
When you get this event, you are responsible for setting a new video
mode with the new width and height. }
TSDL_ResizeEvent = record
type_: UInt8; // SDL_VIDEORESIZE
w: Integer; // New width
h: Integer; // New height
end;
// The "quit requested" event
PSDL_QuitEvent = ^TSDL_QuitEvent;
TSDL_QuitEvent = record
type_: UInt8;
end;
// A user-defined event type
PSDL_UserEvent = ^TSDL_UserEvent;
TSDL_UserEvent = record
type_: UInt8; // SDL_USEREVENT through SDL_NUMEVENTS-1
code: Integer; // User defined event code */
data1: Pointer; // User defined data pointer */
data2: Pointer; // User defined data pointer */
end;
// The "screen redraw" event
PSDL_ExposeEvent = ^TSDL_ExposeEvent;
TSDL_ExposeEvent = record
type_ : Uint8; // SDL_VIDEOEXPOSE
end;
{$IFDEF Unix}
//These are the various supported subsystems under UNIX
TSDL_SysWm = ( SDL_SYSWM_X11 ) ;
{$ENDIF}
// The windows custom event structure
{$IFDEF WINDOWS}
PSDL_SysWMmsg = ^TSDL_SysWMmsg;
TSDL_SysWMmsg = record
version: TSDL_version;
h_wnd: HWND; // The window for the message
msg: UInt; // The type of message
w_Param: WPARAM; // WORD message parameter
lParam: LPARAM; // LONG message parameter
end;
{$ELSE}
{$IFDEF Unix}
{ The Linux custom event structure }
PSDL_SysWMmsg = ^TSDL_SysWMmsg;
TSDL_SysWMmsg = record
version : TSDL_version;
subsystem : TSDL_SysWm;
{$IFDEF FPC}
{$IFNDEF GP2X}
{$IFNDEF DARWIN}
{$IFNDEF SKYOS}
event : TXEvent;
{$ENDIF}
{$ENDIF}
{$ENDIF}
{$ELSE}
event : XEvent;
{$ENDIF}
end;
{$ELSE}
{ The generic custom event structure }
PSDL_SysWMmsg = ^TSDL_SysWMmsg;
TSDL_SysWMmsg = record
version: TSDL_version;
data: Integer;
end;
{$ENDIF}
{$ENDIF}
// The Windows custom window manager information structure
{$IFDEF WINDOWS}
PSDL_SysWMinfo = ^TSDL_SysWMinfo;
TSDL_SysWMinfo = record
version : TSDL_version;
window : HWnd; // The display window
end;
{$ELSE}
// The Linux custom window manager information structure
{$IFDEF Unix}
{$IFNDEF GP2X}
{$IFNDEF DARWIN}
{$IFNDEF SKYOS}
TX11 = record
display : PDisplay; // The X11 display
window : TWindow ; // The X11 display window */
{* These locking functions should be called around
any X11 functions using the display variable.
They lock the event thread, so should not be
called around event functions or from event filters.
*}
lock_func : Pointer;
unlock_func : Pointer;
// Introduced in SDL 1.0.2
fswindow : TWindow ; // The X11 fullscreen window */
wmwindow : TWindow ; // The X11 managed input window */
end;
{$ENDIF}
{$ENDIF}
{$ENDIF}
PSDL_SysWMinfo = ^TSDL_SysWMinfo;
TSDL_SysWMinfo = record
version : TSDL_version ;
subsystem : TSDL_SysWm;
{$IFNDEF GP2X}
{$IFNDEF DARWIN}
{$IFNDEF SKYOS}
X11 : TX11;
{$ENDIF}
{$ENDIF}
{$ENDIF}
end;
{$ELSE}
// The generic custom window manager information structure
PSDL_SysWMinfo = ^TSDL_SysWMinfo;
TSDL_SysWMinfo = record
version : TSDL_version ;
data : integer;
end;
{$ENDIF}
{$ENDIF}
PSDL_SysWMEvent = ^TSDL_SysWMEvent;
TSDL_SysWMEvent = record
type_: UInt8;
msg: PSDL_SysWMmsg;
end;
PSDL_Event = ^TSDL_Event;
TSDL_Event = record
case UInt8 of
SDL_NOEVENT: (type_: byte);
SDL_ACTIVEEVENT: (active: TSDL_ActiveEvent);
SDL_KEYDOWN, SDL_KEYUP: (key: TSDL_KeyboardEvent);
SDL_MOUSEMOTION: (motion: TSDL_MouseMotionEvent);
SDL_MOUSEBUTTONDOWN, SDL_MOUSEBUTTONUP: (button: TSDL_MouseButtonEvent );
SDL_JOYAXISMOTION: (jaxis: TSDL_JoyAxisEvent );
SDL_JOYBALLMOTION: (jball: TSDL_JoyBallEvent );
SDL_JOYHATMOTION: (jhat: TSDL_JoyHatEvent );
SDL_JOYBUTTONDOWN, SDL_JOYBUTTONUP: (jbutton: TSDL_JoyButtonEvent );
SDL_VIDEORESIZE: (resize: TSDL_ResizeEvent );
SDL_QUITEV: (quit: TSDL_QuitEvent );
SDL_USEREVENT : ( user : TSDL_UserEvent );
SDL_SYSWMEVENT: (syswm: TSDL_SysWMEvent );
end;
{ This function sets up a filter to process all events before they
change internal state and are posted to the internal event queue.
The filter is protypted as: }
{$IFNDEF __GPC__}
TSDL_EventFilter = function( event : PSDL_Event ): Integer; cdecl;
{$ELSE}
TSDL_EventFilter = function( event : PSDL_Event ): Integer;
{$ENDIF}
// SDL_video.h types
// Useful data types
PPSDL_Rect = ^PSDL_Rect;
PSDL_Rect = ^TSDL_Rect;
TSDL_Rect = record
x, y: SInt16;
w, h: UInt16;
end;
SDL_Rect = TSDL_Rect;
{$EXTERNALSYM SDL_Rect}
PSDL_Color = ^TSDL_Color;
TSDL_Color = record
r: UInt8;
g: UInt8;
b: UInt8;
unused: UInt8;
end;
PSDL_ColorArray = ^TSDL_ColorArray;
TSDL_ColorArray = array[0..65000] of TSDL_Color;
PSDL_Palette = ^TSDL_Palette;
TSDL_Palette = record
ncolors: Integer;
colors: PSDL_ColorArray;
end;
// Everything in the pixel format structure is read-only
PSDL_PixelFormat = ^TSDL_PixelFormat;
TSDL_PixelFormat = record
palette: PSDL_Palette;
BitsPerPixel: UInt8;
BytesPerPixel: UInt8;
Rloss: UInt8;
Gloss: UInt8;
Bloss: UInt8;
Aloss: UInt8;
Rshift: UInt8;
Gshift: UInt8;
Bshift: UInt8;
Ashift: UInt8;
RMask: UInt32;
GMask: UInt32;
BMask: UInt32;
AMask: UInt32;
colorkey: UInt32; // RGB color key information
alpha: UInt8; // Alpha value information (per-surface alpha)
end;
{$IFDEF WINDOWS}
{PPrivate_hwdata = ^TPrivate_hwdata;
TPrivate_hwdata = record
dd_surface : IDIRECTDRAWSURFACE3;
dd_writebuf : IDIRECTDRAWSURFACE3;
end;}
{ELSE}
{$ENDIF}
// The structure passed to the low level blit functions
PSDL_BlitInfo = ^TSDL_BlitInfo;
TSDL_BlitInfo = record
s_pixels: PUInt8;
s_width: Integer;
s_height: Integer;
s_skip: Integer;
d_pixels: PUInt8;
d_width: Integer;
d_height: Integer;
d_skip: Integer;
aux_data: Pointer;
src: PSDL_PixelFormat;
table: PUInt8;
dst: PSDL_PixelFormat;
end;
// typedef for private surface blitting functions
PSDL_Surface = ^TSDL_Surface;
{$IFNDEF __GPC__}
TSDL_Blit = function( src: PSDL_Surface; srcrect: PSDL_Rect; dst: PSDL_Surface; dstrect: PSDL_Rect ): Integer; cdecl;
{$ELSE}
TSDL_Blit = function( src: PSDL_Surface; srcrect: PSDL_Rect; dst: PSDL_Surface; dstrect: PSDL_Rect ): Integer;
{$ENDIF}
// The type definition for the low level blit functions
//TSDL_LoBlit = procedure( info : PSDL_BlitInfo ); cdecl;
// This is the private info structure for software accelerated blits
{PPrivate_swaccel = ^TPrivate_swaccel;
TPrivate_swaccel = record
blit : TSDL_LoBlit;
aux_data : Pointer;
end;}
// Blit mapping definition
{PSDL_BlitMap = ^TSDL_BlitMap;
TSDL_BlitMap = record
dst : PSDL_Surface;
identity : Integer;
table : PUInt8;
hw_blit : TSDL_Blit;
sw_blit : TSDL_Blit;
hw_data : PPrivate_hwaccel;
sw_data : PPrivate_swaccel;
// the version count matches the destination; mismatch indicates an invalid mapping
format_version : Cardinal;
end;}
TSDL_Surface = record
flags: UInt32; // Read-only
format: PSDL_PixelFormat; // Read-only
w, h: Integer; // Read-only
pitch: UInt16; // Read-only
pixels: Pointer; // Read-write
offset: Integer; // Private
hwdata: Pointer; //TPrivate_hwdata; Hardware-specific surface info
// clipping information:
clip_rect: TSDL_Rect; // Read-only
unused1: UInt32; // for binary compatibility
// Allow recursive locks
locked: UInt32; // Private
// info for fast blit mapping to other surfaces
Blitmap: Pointer; // PSDL_BlitMap; // Private
// format version, bumped at every change to invalidate blit maps
format_version: Cardinal; // Private
refcount: Integer;
end;
// Useful for determining the video hardware capabilities
PSDL_VideoInfo = ^TSDL_VideoInfo;
TSDL_VideoInfo = record
hw_available: UInt8; // Hardware and WindowManager flags in first 2 bits ( see below )
{hw_available: 1; // Can you create hardware surfaces
wm_available: 1; // Can you talk to a window manager?
UnusedBits1: 6;}
blit_hw: UInt8; // Blit Hardware flags. See below for which bits do what
{UnusedBits2: 1;
blit_hw: 1; // Flag:UInt32 Accelerated blits HW --> HW
blit_hw_CC: 1; // Flag:UInt32 Accelerated blits with Colorkey
blit_hw_A: 1; // Flag:UInt32 Accelerated blits with Alpha
blit_sw: 1; // Flag:UInt32 Accelerated blits SW --> HW
blit_sw_CC: 1; // Flag:UInt32 Accelerated blits with Colorkey
blit_sw_A: 1; // Flag:UInt32 Accelerated blits with Alpha
blit_fill: 1; // Flag:UInt32 Accelerated color fill}
UnusedBits3: UInt8; // Unused at this point
video_mem: UInt32; // The total amount of video memory (in K)
vfmt: PSDL_PixelFormat; // Value: The format of the video surface
current_w : SInt32; // Value: The current video mode width
current_h : SInt32; // Value: The current video mode height
end;
// The YUV hardware video overlay
PSDL_Overlay = ^TSDL_Overlay;
TSDL_Overlay = record
format: UInt32; // Overlay format
w, h: Integer; // Width and height of overlay
planes: Integer; // Number of planes in the overlay. Usually either 1 or 3
pitches: PUInt16;
// An array of pitches, one for each plane. Pitch is the length of a row in bytes.
pixels: PPUInt8;
// An array of pointers to the data of each plane. The overlay should be locked before these pointers are used.
hw_overlay: UInt32;
// This will be set to 1 if the overlay is hardware accelerated.
end;
// Public enumeration for setting the OpenGL window attributes.
TSDL_GLAttr = (
SDL_GL_RED_SIZE,
SDL_GL_GREEN_SIZE,
SDL_GL_BLUE_SIZE,
SDL_GL_ALPHA_SIZE,
SDL_GL_BUFFER_SIZE,
SDL_GL_DOUBLEBUFFER,
SDL_GL_DEPTH_SIZE,
SDL_GL_STENCIL_SIZE,
SDL_GL_ACCUM_RED_SIZE,
SDL_GL_ACCUM_GREEN_SIZE,
SDL_GL_ACCUM_BLUE_SIZE,
SDL_GL_ACCUM_ALPHA_SIZE,
SDL_GL_STEREO,
SDL_GL_MULTISAMPLEBUFFERS,
SDL_GL_MULTISAMPLESAMPLES,
SDL_GL_ACCELERATED_VISUAL,
SDL_GL_SWAP_CONTROL);
PSDL_Cursor = ^TSDL_Cursor;
TSDL_Cursor = record
area: TSDL_Rect; // The area of the mouse cursor
hot_x, hot_y: SInt16; // The "tip" of the cursor
data: PUInt8; // B/W cursor data
mask: PUInt8; // B/W cursor mask
save: array[1..2] of PUInt8; // Place to save cursor area
wm_cursor: Pointer; // Window-manager cursor
end;
// SDL_mutex.h types
{$IFDEF WINDOWS}
PSDL_Mutex = ^TSDL_Mutex;
TSDL_Mutex = record
id: THANDLE;
end;
{$ENDIF}
{$IFDEF Unix}
PSDL_Mutex = ^TSDL_Mutex;
TSDL_mutex = record
id: pthread_mutex_t;
{$IFDEF PTHREAD_NO_RECURSIVE_MUTEX}
recursive: Integer;
owner: pthread_t;
{$ENDIF}
end;
{$ENDIF}
{$IFDEF NDS}
PSDL_mutex = ^TSDL_Mutex;
TSDL_Mutex = record
recursive: Integer;
Owner: UInt32;
sem: PSDL_sem;
end;
{$ENDIF}
{$IFDEF __MACH__}
{$define USE_NAMED_SEMAPHORES}
// Broken sem_getvalue() in MacOS X Public Beta */
{$define BROKEN_SEMGETVALUE}
{$ENDIF}
PSDL_semaphore = ^TSDL_semaphore;
{$IFDEF WINDOWS}
// WINDOWS or Machintosh
TSDL_semaphore = record
id: THANDLE;
count: UInt32;
end;
{$ELSE}
{$IFDEF FPC}
// This should be semaphore.h
__sem_lock_t = {packed} record { Not in header file - anonymous }
status: Longint;
spinlock: Integer;
end;
sem_t = {packed} record
__sem_lock: __sem_lock_t;
__sem_value: Integer;
__sem_waiting: longint ; {_pthread_queue;}
end;
{$ENDIF}
TSDL_semaphore = record
sem: Pointer; //PSem_t;
{$IFNDEF USE_NAMED_SEMAPHORES}
sem_data: Sem_t;
{$ENDIF}
{$IFDEF BROKEN_SEMGETVALUE}
{ This is a little hack for MacOS X -
It's not thread-safe, but it's better than nothing }
sem_value: Integer;
{$ENDIF}
end;
{$ENDIF}
PSDL_Sem = ^TSDL_Sem;
TSDL_Sem = TSDL_Semaphore;
PSDL_Cond = ^TSDL_Cond;
TSDL_Cond = record
{$IFDEF Unix}
cond: pthread_cond_t;
{$ELSE}
// Generic Cond structure
lock: PSDL_mutex;
waiting: Integer;
signals: Integer;
wait_sem: PSDL_Sem;
wait_done: PSDL_Sem;
{$ENDIF}
end;
// SDL_thread.h types
{$IFDEF WINDOWS}
TSYS_ThreadHandle = THandle;
{$ENDIF}
{$IFDEF Unix}
TSYS_ThreadHandle = pthread_t;
{$ENDIF}
{$IFDEF NDS}
TSYS_ThreadHandle = Integer;
{$ENDIF}
{ This is the system-independent thread info structure }
PSDL_Thread = ^TSDL_Thread;
TSDL_Thread = record
threadid: UInt32;
handle: TSYS_ThreadHandle;
status: Integer;
errbuf: TSDL_Error;
data: Pointer;
end;
// Helper Types
// Keyboard State Array ( See demos for how to use )
PKeyStateArr = ^TKeyStateArr;
TKeyStateArr = array[0..65000] of UInt8;
// Types required so we don't need to use Windows.pas
PInteger = ^Integer;
PByte = ^Byte;
PWord = ^Word;
PLongWord = ^Longword;
// General arrays
PByteArray = ^TByteArray;
TByteArray = array[0..32767] of Byte;
PWordArray = ^TWordArray;
TWordArray = array[0..16383] of Word;
PPoint = ^TPoint;
{$IFDEF HAS_TYPES}
TPoint = Types.TPoint;
{$ELSE}
{$IFDEF WINDOWS}
{$IFDEF __GPC__}
TPoint = wintypes.TPoint;
{$ELSE}
TPoint = Windows.TPoint;
{$ENDIF}
{$ELSE}
//Can't define TPoint : neither Types nor Windows unit available.
{$ENDIF}
{$ENDIF}
PRect = ^TRect;
{$IFDEF HAS_TYPES}
TRect = Types.TRect;
{$ELSE}
{$IFDEF WINDOWS}
{$IFDEF __GPC__}
TRect = wintypes.TRect;
{$ELSE}
TRect = Windows.TRect;
{$ENDIF}
{$ELSE}
//Can't define TRect: neither Types nor Windows unit available.
{$ENDIF}
{$ENDIF}
{ Generic procedure pointer }
TProcedure = procedure;
{------------------------------------------------------------------------------}
{ initialization }
{------------------------------------------------------------------------------}
{ This function loads the SDL dynamically linked library and initializes
the subsystems specified by 'flags' (and those satisfying dependencies)
Unless the SDL_INIT_NOPARACHUTE flag is set, it will install cleanup
signal handlers for some commonly ignored fatal signals (like SIGSEGV) }
function SDL_Init( flags : UInt32 ) : Integer;
cdecl; external {$IFNDEF NDS}{$IFDEF __GPC__}name 'SDL_Init'{$ELSE} SDLLibName{$ENDIF __GPC__}{$ENDIF};
{$EXTERNALSYM SDL_Init}
// This function initializes specific SDL subsystems
function SDL_InitSubSystem( flags : UInt32 ) : Integer;
cdecl; external {$IFNDEF NDS}{$IFDEF __GPC__}name 'SDL_InitSubSystem'{$ELSE} SDLLibName{$ENDIF __GPC__}{$ENDIF};
{$EXTERNALSYM SDL_InitSubSystem}
// This function cleans up specific SDL subsystems
procedure SDL_QuitSubSystem( flags : UInt32 );
cdecl; external {$IFNDEF NDS}{$IFDEF __GPC__}name 'SDL_QuitSubSystem'{$ELSE} SDLLibName{$ENDIF __GPC__}{$ENDIF};
{$EXTERNALSYM SDL_QuitSubSystem}
{ This function returns mask of the specified subsystems which have
been initialized.
If 'flags' is 0, it returns a mask of all initialized subsystems. }
function SDL_WasInit( flags : UInt32 ): UInt32;
cdecl; external {$IFNDEF NDS}{$IFDEF __GPC__}name 'SDL_WasInit'{$ELSE} SDLLibName{$ENDIF __GPC__}{$ENDIF};
{$EXTERNALSYM SDL_WasInit}
{ This function cleans up all initialized subsystems and unloads the
dynamically linked library. You should call it upon all exit conditions. }
procedure SDL_Quit;
cdecl; external {$IFNDEF NDS}{$IFDEF __GPC__}name 'SDL_Quit'{$ELSE} SDLLibName{$ENDIF __GPC__}{$ENDIF};
{$EXTERNALSYM SDL_Quit}
{$IFDEF WINDOWS}
// This should be called from your WinMain() function, if any
function SDL_RegisterApp(name: PChar; style: UInt32; h_Inst: Pointer): Integer;
cdecl; external {$IFNDEF NDS}{$IFDEF __GPC__}name 'SDL_RegisterApp'{$ELSE} SDLLibName{$ENDIF __GPC__}{$ENDIF};
{$EXTERNALSYM SDL_RegisterApp}
{$ENDIF}
{$IFDEF __MACH__}
// This should be called from your main() function, if any
procedure SDL_InitQuickDraw( the_qd: QDGlobals );
cdecl; external {$IFNDEF NDS}{$IFDEF __GPC__}name 'SDL_InitQuickDraw'{$ELSE} SDLLibName{$ENDIF __GPC__}{$ENDIF};
{$EXTERNALSYM SDL_InitQuickDraw}
{$ENDIF}
{------------------------------------------------------------------------------}
{ types }
{------------------------------------------------------------------------------}
// The number of elements in a table
function SDL_TableSize( table: PChar ): Integer;
{$EXTERNALSYM SDL_TABLESIZE}
{------------------------------------------------------------------------------}
{ error-handling }
{------------------------------------------------------------------------------}
// Public functions
function SDL_GetError: PChar;
cdecl; external {$IFNDEF NDS}{$IFDEF __GPC__}name 'SDL_GetError'{$ELSE} SDLLibName{$ENDIF __GPC__}{$ENDIF};
{$EXTERNALSYM SDL_GetError}
procedure SDL_SetError(fmt: PChar);
cdecl; external {$IFNDEF NDS}{$IFDEF __GPC__}name 'SDL_SetError'{$ELSE} SDLLibName{$ENDIF __GPC__}{$ENDIF};
{$EXTERNALSYM SDL_SetError}
procedure SDL_ClearError;
cdecl; external {$IFNDEF NDS}{$IFDEF __GPC__}name 'SDL_ClearError'{$ELSE} SDLLibName{$ENDIF __GPC__}{$ENDIF};
{$EXTERNALSYM SDL_ClearError}
{$IFNDEF WINDOWS}
procedure SDL_Error(Code: TSDL_errorcode);
cdecl; external {$IFNDEF NDS}{$IFDEF __GPC__}name 'SDL_Error'{$ELSE} SDLLibName{$ENDIF __GPC__}{$ENDIF};
{$EXTERNALSYM SDL_Error}
{$ENDIF}
// Private error message function - used internally
procedure SDL_OutOfMemory;
{------------------------------------------------------------------------------}
{ io handling }
{------------------------------------------------------------------------------}
// Functions to create SDL_RWops structures from various data sources
function SDL_RWFromFile(filename, mode: PChar): PSDL_RWops;
cdecl; external {$IFNDEF NDS}{$IFDEF __GPC__}name 'SDL_RWFromFile'{$ELSE} SDLLibName{$ENDIF __GPC__}{$ENDIF};
{$EXTERNALSYM SDL_RWFromFile}
procedure SDL_FreeRW(area: PSDL_RWops);
cdecl; external {$IFNDEF NDS}{$IFDEF __GPC__}name 'SDL_FreeRW'{$ELSE} SDLLibName{$ENDIF __GPC__}{$ENDIF};
{$EXTERNALSYM SDL_FreeRW}
//fp is FILE *fp ???
function SDL_RWFromFP(fp: Pointer; autoclose: Integer): PSDL_RWops;
cdecl; external {$IFNDEF NDS}{$IFDEF __GPC__}name 'SDL_RWFromFP'{$ELSE} SDLLibName{$ENDIF __GPC__}{$ENDIF};
{$EXTERNALSYM SDL_RWFromFP}
function SDL_RWFromMem(mem: Pointer; size: Integer): PSDL_RWops;
cdecl; external {$IFNDEF NDS}{$IFDEF __GPC__}name 'SDL_RWFromMem'{$ELSE} SDLLibName{$ENDIF __GPC__}{$ENDIF};
{$EXTERNALSYM SDL_RWFromMem}
function SDL_RWFromConstMem(const mem: Pointer; size: Integer) : PSDL_RWops;
cdecl; external {$IFNDEF NDS}{$IFDEF __GPC__}name 'SDL_RWFromConstMem'{$ELSE} SDLLibName{$ENDIF __GPC__}{$ENDIF};
{$EXTERNALSYM SDL_RWFromConstMem}
function SDL_AllocRW: PSDL_RWops;
cdecl; external {$IFNDEF NDS}{$IFDEF __GPC__}name 'SDL_AllocRW'{$ELSE} SDLLibName{$ENDIF __GPC__}{$ENDIF};
{$EXTERNALSYM SDL_AllocRW}
function SDL_RWSeek(context: PSDL_RWops; offset: Integer; whence: Integer) : Integer;
{$EXTERNALSYM SDL_RWSeek}
function SDL_RWTell(context: PSDL_RWops): Integer;
{$EXTERNALSYM SDL_RWTell}
function SDL_RWRead(context: PSDL_RWops; ptr: Pointer; size: Integer; n : Integer): Integer;
{$EXTERNALSYM SDL_RWRead}
function SDL_RWWrite(context: PSDL_RWops; ptr: Pointer; size: Integer; n : Integer): Integer;
{$EXTERNALSYM SDL_RWWrite}
function SDL_RWClose(context: PSDL_RWops): Integer;
{$EXTERNALSYM SDL_RWClose}
{------------------------------------------------------------------------------}
{ time-handling }
{------------------------------------------------------------------------------}
{ Get the number of milliseconds since the SDL library initialization. }
{ Note that this value wraps if the program runs for more than ~49 days. }
function SDL_GetTicks: UInt32;
cdecl; external {$IFNDEF NDS}{$IFDEF __GPC__}name 'SDL_GetTicks'{$ELSE} SDLLibName{$ENDIF __GPC__}{$ENDIF};
{$EXTERNALSYM SDL_GetTicks}
// Wait a specified number of milliseconds before returning
procedure SDL_Delay(msec: UInt32);
cdecl; external {$IFNDEF NDS}{$IFDEF __GPC__}name 'SDL_Delay'{$ELSE} SDLLibName{$ENDIF __GPC__}{$ENDIF};
{$EXTERNALSYM SDL_Delay}
{ Add a new timer to the pool of timers already running. }
{ Returns a timer ID, or NULL when an error occurs. }
function SDL_AddTimer(interval: UInt32; callback: TSDL_NewTimerCallback; param : Pointer): PSDL_TimerID;
cdecl; external {$IFNDEF NDS}{$IFDEF __GPC__}name 'SDL_AddTimer'{$ELSE} SDLLibName{$ENDIF __GPC__}{$ENDIF};
{$EXTERNALSYM SDL_AddTimer}
{ Remove one of the multiple timers knowing its ID. }
{ Returns a boolean value indicating success. }
function SDL_RemoveTimer(t: PSDL_TimerID): TSDL_Bool;
cdecl; external {$IFNDEF NDS}{$IFDEF __GPC__}name 'SDL_RemoveTimer'{$ELSE} SDLLibName{$ENDIF __GPC__}{$ENDIF};
{$EXTERNALSYM SDL_RemoveTimer}
function SDL_SetTimer(interval: UInt32; callback: TSDL_TimerCallback): Integer;
cdecl; external {$IFNDEF NDS}{$IFDEF __GPC__}name 'SDL_SetTimer'{$ELSE} SDLLibName{$ENDIF __GPC__}{$ENDIF};
{$EXTERNALSYM SDL_SetTimer}
{------------------------------------------------------------------------------}
{ audio-routines }
{------------------------------------------------------------------------------}
{ These functions are used internally, and should not be used unless you
have a specific need to specify the audio driver you want to use.
You should normally use SDL_Init() or SDL_InitSubSystem(). }
function SDL_AudioInit(driver_name: PChar): Integer;
cdecl; external {$IFNDEF NDS}{$IFDEF __GPC__}name 'SDL_AudioInit'{$ELSE} SDLLibName{$ENDIF __GPC__}{$ENDIF};
{$EXTERNALSYM SDL_AudioInit}
procedure SDL_AudioQuit;
cdecl; external {$IFNDEF NDS}{$IFDEF __GPC__}name 'SDL_AudioQuit'{$ELSE} SDLLibName{$ENDIF __GPC__}{$ENDIF};
{$EXTERNALSYM SDL_AudioQuit}
{ This function fills the given character buffer with the name of the
current audio driver, and returns a Pointer to it if the audio driver has
been initialized. It returns NULL if no driver has been initialized. }
function SDL_AudioDriverName(namebuf: PChar; maxlen: Integer): PChar;
cdecl; external {$IFNDEF NDS}{$IFDEF __GPC__}name 'SDL_AudioDriverName'{$ELSE} SDLLibName{$ENDIF __GPC__}{$ENDIF};
{$EXTERNALSYM SDL_AudioDriverName}
{ This function opens the audio device with the desired parameters, and
returns 0 if successful, placing the actual hardware parameters in the
structure pointed to by 'obtained'. If 'obtained' is NULL, the audio
data passed to the callback function will be guaranteed to be in the
requested format, and will be automatically converted to the hardware
audio format if necessary. This function returns -1 if it failed
to open the audio device, or couldn't set up the audio thread.
When filling in the desired audio spec structure,
'desired->freq' should be the desired audio frequency in samples-per-second.
'desired->format' should be the desired audio format.
'desired->samples' is the desired size of the audio buffer, in samples.
This number should be a power of two, and may be adjusted by the audio
driver to a value more suitable for the hardware. Good values seem to
range between 512 and 8096 inclusive, depending on the application and
CPU speed. Smaller values yield faster response time, but can lead
to underflow if the application is doing heavy processing and cannot
fill the audio buffer in time. A stereo sample consists of both right
and left channels in LR ordering.
Note that the number of samples is directly related to time by the
following formula: ms = (samples*1000)/freq
'desired->size' is the size in bytes of the audio buffer, and is
calculated by SDL_OpenAudio().
'desired->silence' is the value used to set the buffer to silence,
and is calculated by SDL_OpenAudio().
'desired->callback' should be set to a function that will be called
when the audio device is ready for more data. It is passed a pointer
to the audio buffer, and the length in bytes of the audio buffer.
This function usually runs in a separate thread, and so you should
protect data structures that it accesses by calling SDL_LockAudio()
and SDL_UnlockAudio() in your code.
'desired->userdata' is passed as the first parameter to your callback
function.
The audio device starts out playing silence when it's opened, and should
be enabled for playing by calling SDL_PauseAudio(0) when you are ready
for your audio callback function to be called. Since the audio driver
may modify the requested size of the audio buffer, you should allocate
any local mixing buffers after you open the audio device. }
function SDL_OpenAudio(desired, obtained: PSDL_AudioSpec): Integer;
cdecl; external {$IFNDEF NDS}{$IFDEF __GPC__}name 'SDL_OpenAudio'{$ELSE} SDLLibName{$ENDIF __GPC__}{$ENDIF};
{$EXTERNALSYM SDL_OpenAudio}
{ Get the current audio state: }
function SDL_GetAudioStatus: TSDL_Audiostatus;
cdecl; external {$IFNDEF NDS}{$IFDEF __GPC__}name 'SDL_GetAudioStatus'{$ELSE} SDLLibName{$ENDIF __GPC__}{$ENDIF};
{$EXTERNALSYM SDL_GetAudioStatus}
{ This function pauses and unpauses the audio callback processing.
It should be called with a parameter of 0 after opening the audio
device to start playing sound. This is so you can safely initialize
data for your callback function after opening the audio device.
Silence will be written to the audio device during the pause. }
procedure SDL_PauseAudio(pause_on: Integer);
cdecl; external {$IFNDEF NDS}{$IFDEF __GPC__}name 'SDL_PauseAudio'{$ELSE} SDLLibName{$ENDIF __GPC__}{$ENDIF};
{$EXTERNALSYM SDL_PauseAudio}
{ This function loads a WAVE from the data source, automatically freeing
that source if 'freesrc' is non-zero. For example, to load a WAVE file,
you could do:
SDL_LoadWAV_RW(SDL_RWFromFile("sample.wav", "rb"), 1, ...);
If this function succeeds, it returns the given SDL_AudioSpec,
filled with the audio data format of the wave data, and sets
'audio_buf' to a malloc()'d buffer containing the audio data,
and sets 'audio_len' to the length of that audio buffer, in bytes.
You need to free the audio buffer with SDL_FreeWAV() when you are
done with it.
This function returns NULL and sets the SDL error message if the
wave file cannot be opened, uses an unknown data format, or is
corrupt. Currently raw and MS-ADPCM WAVE files are supported. }
function SDL_LoadWAV_RW(src: PSDL_RWops; freesrc: Integer; spec:
PSDL_AudioSpec; audio_buf: PUInt8; audiolen: PUInt32): PSDL_AudioSpec;
cdecl; external {$IFNDEF NDS}{$IFDEF __GPC__}name 'SDL_LoadWAV_RW'{$ELSE} SDLLibName{$ENDIF __GPC__}{$ENDIF};
{$EXTERNALSYM SDL_LoadWAV_RW}
// Compatibility convenience function -- loads a WAV from a file
function SDL_LoadWAV(filename: PChar; spec: PSDL_AudioSpec; audio_buf:
PUInt8; audiolen: PUInt32): PSDL_AudioSpec;
{$EXTERNALSYM SDL_LoadWAV}
{ This function frees data previously allocated with SDL_LoadWAV_RW() }
procedure SDL_FreeWAV(audio_buf: PUInt8);
cdecl; external {$IFNDEF NDS}{$IFDEF __GPC__}name 'SDL_FreeWAV'{$ELSE} SDLLibName{$ENDIF __GPC__}{$ENDIF};
{$EXTERNALSYM SDL_FreeWAV}
{ This function takes a source format and rate and a destination format
and rate, and initializes the 'cvt' structure with information needed
by SDL_ConvertAudio() to convert a buffer of audio data from one format
to the other.
This function returns 0, or -1 if there was an error. }
function SDL_BuildAudioCVT(cvt: PSDL_AudioCVT; src_format: UInt16;
src_channels: UInt8; src_rate: Integer; dst_format: UInt16; dst_channels: UInt8;
dst_rate: Integer): Integer;
cdecl; external {$IFNDEF NDS}{$IFDEF __GPC__}name 'SDL_BuildAudioCVT'{$ELSE} SDLLibName{$ENDIF __GPC__}{$ENDIF};
{$EXTERNALSYM SDL_BuildAudioCVT}
{ Once you have initialized the 'cvt' structure using SDL_BuildAudioCVT(),
created an audio buffer cvt->buf, and filled it with cvt->len bytes of
audio data in the source format, this function will convert it in-place
to the desired format.
The data conversion may expand the size of the audio data, so the buffer
cvt->buf should be allocated after the cvt structure is initialized by
SDL_BuildAudioCVT(), and should be cvt->len*cvt->len_mult bytes long. }
function SDL_ConvertAudio(cvt: PSDL_AudioCVT): Integer;
cdecl; external {$IFNDEF NDS}{$IFDEF __GPC__}name 'SDL_ConvertAudio'{$ELSE} SDLLibName{$ENDIF __GPC__}{$ENDIF};
{$EXTERNALSYM SDL_ConvertAudio}
{ This takes two audio buffers of the playing audio format and mixes
them, performing addition, volume adjustment, and overflow clipping.
The volume ranges from 0 - 128, and should be set to SDL_MIX_MAXVOLUME
for full audio volume. Note this does not change hardware volume.
This is provided for convenience -- you can mix your own audio data. }
procedure SDL_MixAudio(dst, src: PUInt8; len: UInt32; volume: Integer);
cdecl; external {$IFNDEF NDS}{$IFDEF __GPC__}name 'SDL_MixAudio'{$ELSE} SDLLibName{$ENDIF __GPC__}{$ENDIF};
{$EXTERNALSYM SDL_MixAudio}
{ The lock manipulated by these functions protects the callback function.
During a LockAudio/UnlockAudio pair, you can be guaranteed that the
callback function is not running. Do not call these from the callback
function or you will cause deadlock. }
procedure SDL_LockAudio;
cdecl; external {$IFNDEF NDS}{$IFDEF __GPC__}name 'SDL_LockAudio'{$ELSE} SDLLibName{$ENDIF __GPC__}{$ENDIF};
{$EXTERNALSYM SDL_LockAudio}
procedure SDL_UnlockAudio;
cdecl; external {$IFNDEF NDS}{$IFDEF __GPC__}name 'SDL_UnlockAudio'{$ELSE} SDLLibName{$ENDIF __GPC__}{$ENDIF};
{$EXTERNALSYM SDL_UnlockAudio}
{ This function shuts down audio processing and closes the audio device. }
procedure SDL_CloseAudio;
cdecl; external {$IFNDEF NDS}{$IFDEF __GPC__}name 'SDL_CloseAudio'{$ELSE} SDLLibName{$ENDIF __GPC__}{$ENDIF};
{$EXTERNALSYM SDL_CloseAudio}
{------------------------------------------------------------------------------}
{ CD-routines }
{------------------------------------------------------------------------------}
{ Returns the number of CD-ROM drives on the system, or -1 if
SDL_Init() has not been called with the SDL_INIT_CDROM flag. }
function SDL_CDNumDrives: Integer;
cdecl; external {$IFNDEF NDS}{$IFDEF __GPC__}name 'SDL_CDNumDrives'{$ELSE} SDLLibName{$ENDIF __GPC__}{$ENDIF};
{$EXTERNALSYM SDL_CDNumDrives}
{ Returns a human-readable, system-dependent identifier for the CD-ROM.
Example:
"/dev/cdrom"
"E:"
"/dev/disk/ide/1/master" }
function SDL_CDName(drive: Integer): PChar;
cdecl; external {$IFNDEF NDS}{$IFDEF __GPC__}name 'SDL_CDName'{$ELSE} SDLLibName{$ENDIF __GPC__}{$ENDIF};
{$EXTERNALSYM SDL_CDName}
{ Opens a CD-ROM drive for access. It returns a drive handle on success,
or NULL if the drive was invalid or busy. This newly opened CD-ROM
becomes the default CD used when other CD functions are passed a NULL
CD-ROM handle.
Drives are numbered starting with 0. Drive 0 is the system default CD-ROM. }
function SDL_CDOpen(drive: Integer): PSDL_CD;
cdecl; external {$IFNDEF NDS}{$IFDEF __GPC__}name 'SDL_CDOpen'{$ELSE} SDLLibName{$ENDIF __GPC__}{$ENDIF};
{$EXTERNALSYM SDL_CDOpen}
{ This function returns the current status of the given drive.
If the drive has a CD in it, the table of contents of the CD and current
play position of the CD will be stored in the SDL_CD structure. }
function SDL_CDStatus(cdrom: PSDL_CD): TSDL_CDStatus;
cdecl; external {$IFNDEF NDS}{$IFDEF __GPC__}name 'SDL_CDStatus'{$ELSE} SDLLibName{$ENDIF __GPC__}{$ENDIF};
{$EXTERNALSYM SDL_CDStatus}
{ Play the given CD starting at 'start_track' and 'start_frame' for 'ntracks'
tracks and 'nframes' frames. If both 'ntrack' and 'nframe' are 0, play
until the end of the CD. This function will skip data tracks.
This function should only be called after calling SDL_CDStatus() to
get track information about the CD.
For example:
// Play entire CD:
if ( CD_INDRIVE(SDL_CDStatus(cdrom)) ) then
SDL_CDPlayTracks(cdrom, 0, 0, 0, 0);
// Play last track:
if ( CD_INDRIVE(SDL_CDStatus(cdrom)) ) then
begin
SDL_CDPlayTracks(cdrom, cdrom->numtracks-1, 0, 0, 0);
end;
// Play first and second track and 10 seconds of third track:
if ( CD_INDRIVE(SDL_CDStatus(cdrom)) )
SDL_CDPlayTracks(cdrom, 0, 0, 2, 10);
This function returns 0, or -1 if there was an error. }
function SDL_CDPlayTracks(cdrom: PSDL_CD; start_track: Integer; start_frame:
Integer; ntracks: Integer; nframes: Integer): Integer;
cdecl; external {$IFNDEF NDS}{$IFDEF __GPC__}name 'SDL_CDPlayTracks'{$ELSE} SDLLibName{$ENDIF __GPC__}{$ENDIF};
{$EXTERNALSYM SDL_CDPlayTracks}
{ Play the given CD starting at 'start' frame for 'length' frames.
It returns 0, or -1 if there was an error. }
function SDL_CDPlay(cdrom: PSDL_CD; start: Integer; length: Integer): Integer;
cdecl; external {$IFNDEF NDS}{$IFDEF __GPC__}name 'SDL_CDPlay'{$ELSE} SDLLibName{$ENDIF __GPC__}{$ENDIF};
{$EXTERNALSYM SDL_CDPlay}
// Pause play -- returns 0, or -1 on error
function SDL_CDPause(cdrom: PSDL_CD): Integer;
cdecl; external {$IFNDEF NDS}{$IFDEF __GPC__}name 'SDL_CDPause'{$ELSE} SDLLibName{$ENDIF __GPC__}{$ENDIF};
{$EXTERNALSYM SDL_CDPause}
// Resume play -- returns 0, or -1 on error
function SDL_CDResume(cdrom: PSDL_CD): Integer;
cdecl; external {$IFNDEF NDS}{$IFDEF __GPC__}name 'SDL_CDResume'{$ELSE} SDLLibName{$ENDIF __GPC__}{$ENDIF};
{$EXTERNALSYM SDL_CDResume}
// Stop play -- returns 0, or -1 on error
function SDL_CDStop(cdrom: PSDL_CD): Integer;
cdecl; external {$IFNDEF NDS}{$IFDEF __GPC__}name 'SDL_CDStop'{$ELSE} SDLLibName{$ENDIF __GPC__}{$ENDIF};
{$EXTERNALSYM SDL_CDStop}
// Eject CD-ROM -- returns 0, or -1 on error
function SDL_CDEject(cdrom: PSDL_CD): Integer;
cdecl; external {$IFNDEF NDS}{$IFDEF __GPC__}name 'SDL_CDEject'{$ELSE} SDLLibName{$ENDIF __GPC__}{$ENDIF};
{$EXTERNALSYM SDL_CDEject}
// Closes the handle for the CD-ROM drive
procedure SDL_CDClose(cdrom: PSDL_CD);
cdecl; external {$IFNDEF NDS}{$IFDEF __GPC__}name 'SDL_CDClose'{$ELSE} SDLLibName{$ENDIF __GPC__}{$ENDIF};
{$EXTERNALSYM SDL_CDClose}
// Given a status, returns true if there's a disk in the drive
function SDL_CDInDrive( status : TSDL_CDStatus ) : LongBool;
{$EXTERNALSYM SDL_CDInDrive}
// Conversion functions from frames to Minute/Second/Frames and vice versa
procedure FRAMES_TO_MSF(frames: Integer; var M: Integer; var S: Integer; var
F: Integer);
{$EXTERNALSYM FRAMES_TO_MSF}
function MSF_TO_FRAMES(M: Integer; S: Integer; F: Integer): Integer;
{$EXTERNALSYM MSF_TO_FRAMES}
{------------------------------------------------------------------------------}
{ JoyStick-routines }
{------------------------------------------------------------------------------}
{ Count the number of joysticks attached to the system }
function SDL_NumJoysticks: Integer;
cdecl; external {$IFNDEF NDS}{$IFDEF __GPC__}name 'SDL_NumJoysticks'{$ELSE} SDLLibName{$ENDIF __GPC__}{$ENDIF};
{$EXTERNALSYM SDL_NumJoysticks}
{ Get the implementation dependent name of a joystick.
This can be called before any joysticks are opened.
If no name can be found, this function returns NULL. }
function SDL_JoystickName(index: Integer): PChar;
cdecl; external {$IFNDEF NDS}{$IFDEF __GPC__}name 'SDL_JoystickName'{$ELSE} SDLLibName{$ENDIF __GPC__}{$ENDIF};
{$EXTERNALSYM SDL_JoystickName}
{ Open a joystick for use - the index passed as an argument refers to
the N'th joystick on the system. This index is the value which will
identify this joystick in future joystick events.
This function returns a joystick identifier, or NULL if an error occurred. }
function SDL_JoystickOpen(index: Integer): PSDL_Joystick;
cdecl; external {$IFNDEF NDS}{$IFDEF __GPC__}name 'SDL_JoystickOpen'{$ELSE} SDLLibName{$ENDIF __GPC__}{$ENDIF};
{$EXTERNALSYM SDL_JoystickOpen}
{ Returns 1 if the joystick has been opened, or 0 if it has not. }
function SDL_JoystickOpened(index: Integer): Integer;
cdecl; external {$IFNDEF NDS}{$IFDEF __GPC__}name 'SDL_JoystickOpened'{$ELSE} SDLLibName{$ENDIF __GPC__}{$ENDIF};
{$EXTERNALSYM SDL_JoystickOpened}
{ Get the device index of an opened joystick. }
function SDL_JoystickIndex(joystick: PSDL_Joystick): Integer;
cdecl; external {$IFNDEF NDS}{$IFDEF __GPC__}name 'SDL_JoystickIndex'{$ELSE} SDLLibName{$ENDIF __GPC__}{$ENDIF};
{$EXTERNALSYM SDL_JoystickIndex}
{ Get the number of general axis controls on a joystick }
function SDL_JoystickNumAxes(joystick: PSDL_Joystick): Integer;
cdecl; external {$IFNDEF NDS}{$IFDEF __GPC__}name 'SDL_JoystickNumAxes'{$ELSE} SDLLibName{$ENDIF __GPC__}{$ENDIF};
{$EXTERNALSYM SDL_JoystickNumAxes}
{ Get the number of trackballs on a joystick
Joystick trackballs have only relative motion events associated
with them and their state cannot be polled. }
function SDL_JoystickNumBalls(joystick: PSDL_Joystick): Integer;
cdecl; external {$IFNDEF NDS}{$IFDEF __GPC__}name 'SDL_JoystickNumBalls'{$ELSE} SDLLibName{$ENDIF __GPC__}{$ENDIF};
{$EXTERNALSYM SDL_JoystickNumBalls}
{ Get the number of POV hats on a joystick }
function SDL_JoystickNumHats(joystick: PSDL_Joystick): Integer;
cdecl; external {$IFNDEF NDS}{$IFDEF __GPC__}name 'SDL_JoystickNumHats'{$ELSE} SDLLibName{$ENDIF __GPC__}{$ENDIF};
{$EXTERNALSYM SDL_JoystickNumHats}
{ Get the number of buttons on a joystick }
function SDL_JoystickNumButtons(joystick: PSDL_Joystick): Integer;
cdecl; external {$IFNDEF NDS}{$IFDEF __GPC__}name 'SDL_JoystickNumButtons'{$ELSE} SDLLibName{$ENDIF __GPC__}{$ENDIF};
{$EXTERNALSYM SDL_JoystickNumButtons}
{ Update the current state of the open joysticks.
This is called automatically by the event loop if any joystick
events are enabled. }
procedure SDL_JoystickUpdate;
cdecl; external {$IFNDEF NDS}{$IFDEF __GPC__}name 'SDL_JoystickUpdate'{$ELSE} SDLLibName{$ENDIF __GPC__}{$ENDIF};
{$EXTERNALSYM SDL_JoystickUpdate;}
{ Enable/disable joystick event polling.
If joystick events are disabled, you must call SDL_JoystickUpdate()
yourself and check the state of the joystick when you want joystick
information.
The state can be one of SDL_QUERY, SDL_ENABLE or SDL_IGNORE. }
function SDL_JoystickEventState(state: Integer): Integer;
cdecl; external {$IFNDEF NDS}{$IFDEF __GPC__}name 'SDL_JoystickEventState'{$ELSE} SDLLibName{$ENDIF __GPC__}{$ENDIF};
{$EXTERNALSYM SDL_JoystickEventState}
{ Get the current state of an axis control on a joystick
The state is a value ranging from -32768 to 32767.
The axis indices start at index 0. }
function SDL_JoystickGetAxis(joystick: PSDL_Joystick; axis: Integer) : SInt16;
cdecl; external {$IFNDEF NDS}{$IFDEF __GPC__}name 'SDL_JoystickGetAxis'{$ELSE} SDLLibName{$ENDIF __GPC__}{$ENDIF};
{$EXTERNALSYM SDL_JoystickGetAxis}
{ The hat indices start at index 0. }
function SDL_JoystickGetHat(joystick: PSDL_Joystick; hat: Integer): UInt8;
cdecl; external {$IFNDEF NDS}{$IFDEF __GPC__}name 'SDL_JoystickGetHat'{$ELSE} SDLLibName{$ENDIF __GPC__}{$ENDIF};
{$EXTERNALSYM SDL_JoystickGetHat}
{ Get the ball axis change since the last poll
This returns 0, or -1 if you passed it invalid parameters.
The ball indices start at index 0. }
function SDL_JoystickGetBall(joystick: PSDL_Joystick; ball: Integer; var dx: Integer; var dy: Integer): Integer;
cdecl; external {$IFNDEF NDS}{$IFDEF __GPC__}name 'SDL_JoystickGetBall'{$ELSE} SDLLibName{$ENDIF __GPC__}{$ENDIF};
{$EXTERNALSYM SDL_JoystickGetBall}
{ Get the current state of a button on a joystick
The button indices start at index 0. }
function SDL_JoystickGetButton( joystick: PSDL_Joystick; Button: Integer): UInt8;
cdecl; external {$IFNDEF NDS}{$IFDEF __GPC__}name 'SDL_JoystickGetButton'{$ELSE} SDLLibName{$ENDIF __GPC__}{$ENDIF};
{$EXTERNALSYM SDL_JoystickGetButton}
{ Close a joystick previously opened with SDL_JoystickOpen() }
procedure SDL_JoystickClose(joystick: PSDL_Joystick);
cdecl; external {$IFNDEF NDS}{$IFDEF __GPC__}name 'SDL_JoystickClose'{$ELSE} SDLLibName{$ENDIF __GPC__}{$ENDIF};
{$EXTERNALSYM SDL_JoystickClose}
{------------------------------------------------------------------------------}
{ event-handling }
{------------------------------------------------------------------------------}
{ Pumps the event loop, gathering events from the input devices.
This function updates the event queue and internal input device state.
This should only be run in the thread that sets the video mode. }
procedure SDL_PumpEvents;
cdecl; external {$IFNDEF NDS}{$IFDEF __GPC__}name 'SDL_PumpEvents'{$ELSE} SDLLibName{$ENDIF __GPC__}{$ENDIF};
{$EXTERNALSYM SDL_PumpEvents;}
{ Checks the event queue for messages and optionally returns them.
If 'action' is SDL_ADDEVENT, up to 'numevents' events will be added to
the back of the event queue.
If 'action' is SDL_PEEKEVENT, up to 'numevents' events at the front
of the event queue, matching 'mask', will be returned and will not
be removed from the queue.
If 'action' is SDL_GETEVENT, up to 'numevents' events at the front
of the event queue, matching 'mask', will be returned and will be
removed from the queue.
This function returns the number of events actually stored, or -1
if there was an error. This function is thread-safe. }
function SDL_PeepEvents(events: PSDL_Event; numevents: Integer; action: TSDL_eventaction; mask: UInt32): Integer;
cdecl; external {$IFNDEF NDS}{$IFDEF __GPC__}name 'SDL_PeepEvents'{$ELSE} SDLLibName{$ENDIF __GPC__}{$ENDIF};
{$EXTERNALSYM SDL_PeepEvents}
{ Polls for currently pending events, and returns 1 if there are any pending
events, or 0 if there are none available. If 'event' is not NULL, the next
event is removed from the queue and stored in that area. }
function SDL_PollEvent(event: PSDL_Event): Integer;
cdecl; external {$IFNDEF NDS}{$IFDEF __GPC__}name 'SDL_PollEvent'{$ELSE} SDLLibName{$ENDIF __GPC__}{$ENDIF};
{$EXTERNALSYM SDL_PollEvent}
{ Waits indefinitely for the next available event, returning 1, or 0 if there
was an error while waiting for events. If 'event' is not NULL, the next
event is removed from the queue and stored in that area. }
function SDL_WaitEvent(event: PSDL_Event): Integer;
cdecl; external {$IFNDEF NDS}{$IFDEF __GPC__}name 'SDL_WaitEvent'{$ELSE} SDLLibName{$ENDIF __GPC__}{$ENDIF};
{$EXTERNALSYM SDL_WaitEvent}
function SDL_PushEvent( event : PSDL_Event ) : Integer;
cdecl; external {$IFNDEF NDS}{$IFDEF __GPC__}name 'SDL_PushEvent'{$ELSE} SDLLibName{$ENDIF __GPC__}{$ENDIF};
{$EXTERNALSYM SDL_PushEvent}
{ If the filter returns 1, then the event will be added to the internal queue.
If it returns 0, then the event will be dropped from the queue, but the
internal state will still be updated. This allows selective filtering of
dynamically arriving events.
WARNING: Be very careful of what you do in the event filter function, as
it may run in a different thread!
There is one caveat when dealing with the SDL_QUITEVENT event type. The
event filter is only called when the window manager desires to close the
application window. If the event filter returns 1, then the window will
be closed, otherwise the window will remain open if possible.
If the quit event is generated by an interrupt signal, it will bypass the
internal queue and be delivered to the application at the next event poll. }
procedure SDL_SetEventFilter( filter : TSDL_EventFilter );
cdecl; external {$IFNDEF NDS}{$IFDEF __GPC__}name 'SDL_SetEventFilter'{$ELSE} SDLLibName{$ENDIF __GPC__}{$ENDIF};
{$EXTERNALSYM SDL_SetEventFilter}
{ Return the current event filter - can be used to "chain" filters.
If there is no event filter set, this function returns NULL. }
function SDL_GetEventFilter: TSDL_EventFilter;
cdecl; external {$IFNDEF NDS}{$IFDEF __GPC__}name 'SDL_GetEventFilter'{$ELSE} SDLLibName{$ENDIF __GPC__}{$ENDIF};
{$EXTERNALSYM SDL_GetEventFilter}
{ This function allows you to set the state of processing certain events.
If 'state' is set to SDL_IGNORE, that event will be automatically dropped
from the event queue and will not event be filtered.
If 'state' is set to SDL_ENABLE, that event will be processed normally.
If 'state' is set to SDL_QUERY, SDL_EventState() will return the
current processing state of the specified event. }
function SDL_EventState(type_: UInt8; state: Integer): UInt8;
cdecl; external {$IFNDEF NDS}{$IFDEF __GPC__}name 'SDL_EventState'{$ELSE} SDLLibName{$ENDIF __GPC__}{$ENDIF};
{$EXTERNALSYM SDL_EventState}
{------------------------------------------------------------------------------}
{ Version Routines }
{------------------------------------------------------------------------------}
{ This macro can be used to fill a version structure with the compile-time
version of the SDL library. }
procedure SDL_VERSION(var X: TSDL_Version);
{$EXTERNALSYM SDL_VERSION}
{ This macro turns the version numbers into a numeric value:
(1,2,3) -> (1203)
This assumes that there will never be more than 100 patchlevels }
function SDL_VERSIONNUM(X, Y, Z: Integer): Integer;
{$EXTERNALSYM SDL_VERSIONNUM}
// This is the version number macro for the current SDL version
function SDL_COMPILEDVERSION: Integer;
{$EXTERNALSYM SDL_COMPILEDVERSION}
// This macro will evaluate to true if compiled with SDL at least X.Y.Z
function SDL_VERSION_ATLEAST(X: Integer; Y: Integer; Z: Integer) : LongBool;
{$EXTERNALSYM SDL_VERSION_ATLEAST}
{ This function gets the version of the dynamically linked SDL library.
it should NOT be used to fill a version structure, instead you should
use the SDL_Version() macro. }
function SDL_Linked_Version: PSDL_version;
cdecl; external {$IFNDEF NDS}{$IFDEF __GPC__}name 'SDL_Linked_Version'{$ELSE} SDLLibName{$ENDIF __GPC__}{$ENDIF};
{$EXTERNALSYM SDL_Linked_Version}
{------------------------------------------------------------------------------}
{ video }
{------------------------------------------------------------------------------}
{ These functions are used internally, and should not be used unless you
have a specific need to specify the video driver you want to use.
You should normally use SDL_Init() or SDL_InitSubSystem().
SDL_VideoInit() initializes the video subsystem -- sets up a connection
to the window manager, etc, and determines the current video mode and
pixel format, but does not initialize a window or graphics mode.
Note that event handling is activated by this routine.
If you use both sound and video in your application, you need to call
SDL_Init() before opening the sound device, otherwise under Win32 DirectX,
you won't be able to set full-screen display modes. }
function SDL_VideoInit(driver_name: PChar; flags: UInt32): Integer;
cdecl; external {$IFNDEF NDS}{$IFDEF __GPC__}name 'SDL_VideoInit'{$ELSE} SDLLibName{$ENDIF __GPC__}{$ENDIF};
{$EXTERNALSYM SDL_VideoInit}
procedure SDL_VideoQuit;
cdecl; external {$IFNDEF NDS}{$IFDEF __GPC__}name 'SDL_VideoQuit'{$ELSE} SDLLibName{$ENDIF __GPC__}{$ENDIF};
{$EXTERNALSYM SDL_VideoQuit}
{ This function fills the given character buffer with the name of the
video driver, and returns a pointer to it if the video driver has
been initialized. It returns NULL if no driver has been initialized. }
function SDL_VideoDriverName(namebuf: PChar; maxlen: Integer): PChar;
cdecl; external {$IFNDEF NDS}{$IFDEF __GPC__}name 'SDL_VideoDriverName'{$ELSE} SDLLibName{$ENDIF __GPC__}{$ENDIF};
{$EXTERNALSYM SDL_VideoDriverName}
{ This function returns a pointer to the current display surface.
If SDL is doing format conversion on the display surface, this
function returns the publicly visible surface, not the real video
surface. }
function SDL_GetVideoSurface: PSDL_Surface;
cdecl; external {$IFNDEF NDS}{$IFDEF __GPC__}name 'SDL_GetVideoSurface'{$ELSE} SDLLibName{$ENDIF __GPC__}{$ENDIF};
{$EXTERNALSYM SDL_GetVideoSurface}
{ This function returns a read-only pointer to information about the
video hardware. If this is called before SDL_SetVideoMode(), the 'vfmt'
member of the returned structure will contain the pixel format of the
"best" video mode. }
function SDL_GetVideoInfo: PSDL_VideoInfo;
cdecl; external {$IFNDEF NDS}{$IFDEF __GPC__}name 'SDL_GetVideoInfo'{$ELSE} SDLLibName{$ENDIF __GPC__}{$ENDIF};
{$EXTERNALSYM SDL_GetVideoInfo}
{ Check to see if a particular video mode is supported.
It returns 0 if the requested mode is not supported under any bit depth,
or returns the bits-per-pixel of the closest available mode with the
given width and height. If this bits-per-pixel is different from the
one used when setting the video mode, SDL_SetVideoMode() will succeed,
but will emulate the requested bits-per-pixel with a shadow surface.
The arguments to SDL_VideoModeOK() are the same ones you would pass to
SDL_SetVideoMode() }
function SDL_VideoModeOK(width, height, bpp: Integer; flags: UInt32): Integer;
cdecl; external {$IFNDEF NDS}{$IFDEF __GPC__}name 'SDL_VideoModeOK'{$ELSE} SDLLibName{$ENDIF __GPC__}{$ENDIF};
{$EXTERNALSYM SDL_VideoModeOK}
{ Return a pointer to an array of available screen dimensions for the
given format and video flags, sorted largest to smallest. Returns
NULL if there are no dimensions available for a particular format,
or (SDL_Rect **)-1 if any dimension is okay for the given format.
if 'format' is NULL, the mode list will be for the format given
by SDL_GetVideoInfo( ) - > vfmt }
function SDL_ListModes(format: PSDL_PixelFormat; flags: UInt32): PPSDL_Rect;
cdecl; external {$IFNDEF NDS}{$IFDEF __GPC__}name 'SDL_ListModes'{$ELSE} SDLLibName{$ENDIF __GPC__}{$ENDIF};
{$EXTERNALSYM SDL_ListModes}
{ Set up a video mode with the specified width, height and bits-per-pixel.
If 'bpp' is 0, it is treated as the current display bits per pixel.
If SDL_ANYFORMAT is set in 'flags', the SDL library will try to set the
requested bits-per-pixel, but will return whatever video pixel format is
available. The default is to emulate the requested pixel format if it
is not natively available.
If SDL_HWSURFACE is set in 'flags', the video surface will be placed in
video memory, if possible, and you may have to call SDL_LockSurface()
in order to access the raw framebuffer. Otherwise, the video surface
will be created in system memory.
If SDL_ASYNCBLIT is set in 'flags', SDL will try to perform rectangle
updates asynchronously, but you must always lock before accessing pixels.
SDL will wait for updates to complete before returning from the lock.
If SDL_HWPALETTE is set in 'flags', the SDL library will guarantee
that the colors set by SDL_SetColors() will be the colors you get.
Otherwise, in 8-bit mode, SDL_SetColors() may not be able to set all
of the colors exactly the way they are requested, and you should look
at the video surface structure to determine the actual palette.
If SDL cannot guarantee that the colors you request can be set,
i.e. if the colormap is shared, then the video surface may be created
under emulation in system memory, overriding the SDL_HWSURFACE flag.
If SDL_FULLSCREEN is set in 'flags', the SDL library will try to set
a fullscreen video mode. The default is to create a windowed mode
if the current graphics system has a window manager.
If the SDL library is able to set a fullscreen video mode, this flag
will be set in the surface that is returned.
If SDL_DOUBLEBUF is set in 'flags', the SDL library will try to set up
two surfaces in video memory and swap between them when you call
SDL_Flip(). This is usually slower than the normal single-buffering
scheme, but prevents "tearing" artifacts caused by modifying video
memory while the monitor is refreshing. It should only be used by
applications that redraw the entire screen on every update.
This function returns the video framebuffer surface, or NULL if it fails. }
function SDL_SetVideoMode(width, height, bpp: Integer; flags: UInt32): PSDL_Surface;
cdecl; external {$IFNDEF NDS}{$IFDEF __GPC__}name 'SDL_SetVideoMode'{$ELSE} SDLLibName{$ENDIF __GPC__}{$ENDIF};
{$EXTERNALSYM SDL_SetVideoMode}
{ Makes sure the given list of rectangles is updated on the given screen.
If 'x', 'y', 'w' and 'h' are all 0, SDL_UpdateRect will update the entire
screen.
These functions should not be called while 'screen' is locked. }
procedure SDL_UpdateRects(screen: PSDL_Surface; numrects: Integer; rects: PSDL_Rect);
cdecl; external {$IFNDEF NDS}{$IFDEF __GPC__}name 'SDL_UpdateRects'{$ELSE} SDLLibName{$ENDIF __GPC__}{$ENDIF};
{$EXTERNALSYM SDL_UpdateRects}
procedure SDL_UpdateRect(screen: PSDL_Surface; x, y: SInt32; w, h: UInt32);
cdecl; external {$IFNDEF NDS}{$IFDEF __GPC__}name 'SDL_UpdateRect'{$ELSE} SDLLibName{$ENDIF __GPC__}{$ENDIF};
{$EXTERNALSYM SDL_UpdateRect}
{ On hardware that supports double-buffering, this function sets up a flip
and returns. The hardware will wait for vertical retrace, and then swap
video buffers before the next video surface blit or lock will return.
On hardware that doesn not support double-buffering, this is equivalent
to calling SDL_UpdateRect(screen, 0, 0, 0, 0);
The SDL_DOUBLEBUF flag must have been passed to SDL_SetVideoMode() when
setting the video mode for this function to perform hardware flipping.
This function returns 0 if successful, or -1 if there was an error.}
function SDL_Flip(screen: PSDL_Surface): Integer;
cdecl; external {$IFNDEF NDS}{$IFDEF __GPC__}name 'SDL_Flip'{$ELSE} SDLLibName{$ENDIF __GPC__}{$ENDIF};
{$EXTERNALSYM SDL_Flip}
{ Set the gamma correction for each of the color channels.
The gamma values range (approximately) between 0.1 and 10.0
If this function isn't supported directly by the hardware, it will
be emulated using gamma ramps, if available. If successful, this
function returns 0, otherwise it returns -1. }
function SDL_SetGamma(redgamma: single; greengamma: single; bluegamma: single ): Integer;
cdecl; external {$IFNDEF NDS}{$IFDEF __GPC__}name 'SDL_SetGamma'{$ELSE} SDLLibName{$ENDIF __GPC__}{$ENDIF};
{$EXTERNALSYM SDL_SetGamma}
{ Set the gamma translation table for the red, green, and blue channels
of the video hardware. Each table is an array of 256 16-bit quantities,
representing a mapping between the input and output for that channel.
The input is the index into the array, and the output is the 16-bit
gamma value at that index, scaled to the output color precision.
You may pass NULL for any of the channels to leave it unchanged.
If the call succeeds, it will return 0. If the display driver or
hardware does not support gamma translation, or otherwise fails,
this function will return -1. }
function SDL_SetGammaRamp( redtable: PUInt16; greentable: PUInt16; bluetable: PUInt16): Integer;
cdecl; external {$IFNDEF NDS}{$IFDEF __GPC__}name 'SDL_SetGammaRamp'{$ELSE} SDLLibName{$ENDIF __GPC__}{$ENDIF};
{$EXTERNALSYM SDL_SetGammaRamp}
{ Retrieve the current values of the gamma translation tables.
You must pass in valid pointers to arrays of 256 16-bit quantities.
Any of the pointers may be NULL to ignore that channel.
If the call succeeds, it will return 0. If the display driver or
hardware does not support gamma translation, or otherwise fails,
this function will return -1. }
function SDL_GetGammaRamp( redtable: PUInt16; greentable: PUInt16; bluetable: PUInt16): Integer;
cdecl; external {$IFNDEF NDS}{$IFDEF __GPC__}name 'SDL_GetGammaRamp'{$ELSE} SDLLibName{$ENDIF __GPC__}{$ENDIF};
{$EXTERNALSYM SDL_GetGammaRamp}
{ Sets a portion of the colormap for the given 8-bit surface. If 'surface'
is not a palettized surface, this function does nothing, returning 0.
If all of the colors were set as passed to SDL_SetColors(), it will
return 1. If not all the color entries were set exactly as given,
it will return 0, and you should look at the surface palette to
determine the actual color palette.
When 'surface' is the surface associated with the current display, the
display colormap will be updated with the requested colors. If
SDL_HWPALETTE was set in SDL_SetVideoMode() flags, SDL_SetColors()
will always return 1, and the palette is guaranteed to be set the way
you desire, even if the window colormap has to be warped or run under
emulation. }
function SDL_SetColors(surface: PSDL_Surface; colors: PSDL_Color; firstcolor : Integer; ncolors: Integer) : Integer;
cdecl; external {$IFNDEF NDS}{$IFDEF __GPC__}name 'SDL_SetColors'{$ELSE} SDLLibName{$ENDIF __GPC__}{$ENDIF};
{$EXTERNALSYM SDL_SetColors}
{ Sets a portion of the colormap for a given 8-bit surface.
'flags' is one or both of:
SDL_LOGPAL -- set logical palette, which controls how blits are mapped
to/from the surface,
SDL_PHYSPAL -- set physical palette, which controls how pixels look on
the screen
Only screens have physical palettes. Separate change of physical/logical
palettes is only possible if the screen has SDL_HWPALETTE set.
The return value is 1 if all colours could be set as requested, and 0
otherwise.
SDL_SetColors() is equivalent to calling this function with
flags = (SDL_LOGPAL or SDL_PHYSPAL). }
function SDL_SetPalette(surface: PSDL_Surface; flags: Integer; colors: PSDL_Color; firstcolor: Integer; ncolors: Integer): Integer;
cdecl; external {$IFNDEF NDS}{$IFDEF __GPC__}name 'SDL_SetPalette'{$ELSE} SDLLibName{$ENDIF __GPC__}{$ENDIF};
{$EXTERNALSYM SDL_SetPalette}
{ Maps an RGB triple to an opaque pixel value for a given pixel format }
function SDL_MapRGB(format: PSDL_PixelFormat; r: UInt8; g: UInt8; b: UInt8) : UInt32;
cdecl; external {$IFNDEF NDS}{$IFDEF __GPC__}name 'SDL_MapRGB'{$ELSE} SDLLibName{$ENDIF __GPC__}{$ENDIF};
{$EXTERNALSYM SDL_MapRGB}
{ Maps an RGBA quadruple to a pixel value for a given pixel format }
function SDL_MapRGBA(format: PSDL_PixelFormat; r: UInt8; g: UInt8; b: UInt8; a: UInt8): UInt32;
cdecl; external {$IFNDEF NDS}{$IFDEF __GPC__}name 'SDL_MapRGBA'{$ELSE} SDLLibName{$ENDIF __GPC__}{$ENDIF};
{$EXTERNALSYM SDL_MapRGBA}
{ Maps a pixel value into the RGB components for a given pixel format }
procedure SDL_GetRGB(pixel: UInt32; fmt: PSDL_PixelFormat; r: PUInt8; g: PUInt8; b: PUInt8);
cdecl; external {$IFNDEF NDS}{$IFDEF __GPC__}name 'SDL_GetRGB'{$ELSE} SDLLibName{$ENDIF __GPC__}{$ENDIF};
{$EXTERNALSYM SDL_GetRGB}
{ Maps a pixel value into the RGBA components for a given pixel format }
procedure SDL_GetRGBA(pixel: UInt32; fmt: PSDL_PixelFormat; r: PUInt8; g: PUInt8; b: PUInt8; a: PUInt8);
cdecl; external {$IFNDEF NDS}{$IFDEF __GPC__}name 'SDL_GetRGBA'{$ELSE} SDLLibName{$ENDIF __GPC__}{$ENDIF};
{$EXTERNALSYM SDL_GetRGBA}
{ Allocate and free an RGB surface (must be called after SDL_SetVideoMode)
If the depth is 4 or 8 bits, an empty palette is allocated for the surface.
If the depth is greater than 8 bits, the pixel format is set using the
flags '[RGB]mask'.
If the function runs out of memory, it will return NULL.
The 'flags' tell what kind of surface to create.
SDL_SWSURFACE means that the surface should be created in system memory.
SDL_HWSURFACE means that the surface should be created in video memory,
with the same format as the display surface. This is useful for surfaces
that will not change much, to take advantage of hardware acceleration
when being blitted to the display surface.
SDL_ASYNCBLIT means that SDL will try to perform asynchronous blits with
this surface, but you must always lock it before accessing the pixels.
SDL will wait for current blits to finish before returning from the lock.
SDL_SRCCOLORKEY indicates that the surface will be used for colorkey blits.
If the hardware supports acceleration of colorkey blits between
two surfaces in video memory, SDL will try to place the surface in
video memory. If this isn't possible or if there is no hardware
acceleration available, the surface will be placed in system memory.
SDL_SRCALPHA means that the surface will be used for alpha blits and
if the hardware supports hardware acceleration of alpha blits between
two surfaces in video memory, to place the surface in video memory
if possible, otherwise it will be placed in system memory.
If the surface is created in video memory, blits will be _much_ faster,
but the surface format must be identical to the video surface format,
and the only way to access the pixels member of the surface is to use
the SDL_LockSurface() and SDL_UnlockSurface() calls.
If the requested surface actually resides in video memory, SDL_HWSURFACE
will be set in the flags member of the returned surface. If for some
reason the surface could not be placed in video memory, it will not have
the SDL_HWSURFACE flag set, and will be created in system memory instead. }
function SDL_AllocSurface(flags: UInt32; width, height, depth: Integer;
RMask, GMask, BMask, AMask: UInt32): PSDL_Surface;
{$EXTERNALSYM SDL_AllocSurface}
function SDL_CreateRGBSurface(flags: UInt32; width, height, depth: Integer; RMask, GMask, BMask, AMask: UInt32): PSDL_Surface;
cdecl; external {$IFNDEF NDS}{$IFDEF __GPC__}name 'SDL_CreateRGBSurface'{$ELSE} SDLLibName{$ENDIF __GPC__}{$ENDIF};
{$EXTERNALSYM SDL_CreateRGBSurface}
function SDL_CreateRGBSurfaceFrom(pixels: Pointer; width, height, depth, pitch
: Integer; RMask, GMask, BMask, AMask: UInt32): PSDL_Surface;
cdecl; external {$IFNDEF NDS}{$IFDEF __GPC__}name 'SDL_CreateRGBSurfaceFrom'{$ELSE} SDLLibName{$ENDIF __GPC__}{$ENDIF};
{$EXTERNALSYM SDL_CreateRGBSurfaceFrom}
procedure SDL_FreeSurface(surface: PSDL_Surface);
cdecl; external {$IFNDEF NDS}{$IFDEF __GPC__}name 'SDL_FreeSurface'{$ELSE} SDLLibName{$ENDIF __GPC__}{$ENDIF};
{$EXTERNALSYM SDL_FreeSurface}
function SDL_MustLock(Surface: PSDL_Surface): Boolean;
{$EXTERNALSYM SDL_MustLock}
{ SDL_LockSurface() sets up a surface for directly accessing the pixels.
Between calls to SDL_LockSurface()/SDL_UnlockSurface(), you can write
to and read from 'surface->pixels', using the pixel format stored in
'surface->format'. Once you are done accessing the surface, you should
use SDL_UnlockSurface() to release it.
Not all surfaces require locking. If SDL_MUSTLOCK(surface) evaluates
to 0, then you can read and write to the surface at any time, and the
pixel format of the surface will not change. In particular, if the
SDL_HWSURFACE flag is not given when calling SDL_SetVideoMode(), you
will not need to lock the display surface before accessing it.
No operating system or library calls should be made between lock/unlock
pairs, as critical system locks may be held during this time.
SDL_LockSurface() returns 0, or -1 if the surface couldn't be locked. }
function SDL_LockSurface(surface: PSDL_Surface): Integer;
cdecl; external {$IFNDEF NDS}{$IFDEF __GPC__}name 'SDL_LockSurface'{$ELSE} SDLLibName{$ENDIF __GPC__}{$ENDIF};
{$EXTERNALSYM SDL_LockSurface}
procedure SDL_UnlockSurface(surface: PSDL_Surface);
cdecl; external {$IFNDEF NDS}{$IFDEF __GPC__}name 'SDL_UnlockSurface'{$ELSE} SDLLibName{$ENDIF __GPC__}{$ENDIF};
{$EXTERNALSYM SDL_UnlockSurface}
{ Load a surface from a seekable SDL data source (memory or file.)
If 'freesrc' is non-zero, the source will be closed after being read.
Returns the new surface, or NULL if there was an error.
The new surface should be freed with SDL_FreeSurface(). }
function SDL_LoadBMP_RW(src: PSDL_RWops; freesrc: Integer): PSDL_Surface;
cdecl; external {$IFNDEF NDS}{$IFDEF __GPC__}name 'SDL_LoadBMP_RW'{$ELSE} SDLLibName{$ENDIF __GPC__}{$ENDIF};
{$EXTERNALSYM SDL_LoadBMP_RW}
// Convenience macro -- load a surface from a file
function SDL_LoadBMP(filename: PChar): PSDL_Surface;
{$EXTERNALSYM SDL_LoadBMP}
{ Save a surface to a seekable SDL data source (memory or file.)
If 'freedst' is non-zero, the source will be closed after being written.
Returns 0 if successful or -1 if there was an error. }
function SDL_SaveBMP_RW(surface: PSDL_Surface; dst: PSDL_RWops; freedst: Integer): Integer;
cdecl; external {$IFNDEF NDS}{$IFDEF __GPC__}name 'SDL_SaveBMP_RW'{$ELSE} SDLLibName{$ENDIF __GPC__}{$ENDIF};
{$EXTERNALSYM SDL_SaveBMP_RW}
// Convenience macro -- save a surface to a file
function SDL_SaveBMP(surface: PSDL_Surface; filename: PChar): Integer;
{$EXTERNALSYM SDL_SaveBMP}
{ Sets the color key (transparent pixel) in a blittable surface.
If 'flag' is SDL_SRCCOLORKEY (optionally OR'd with SDL_RLEACCEL),
'key' will be the transparent pixel in the source image of a blit.
SDL_RLEACCEL requests RLE acceleration for the surface if present,
and removes RLE acceleration if absent.
If 'flag' is 0, this function clears any current color key.
This function returns 0, or -1 if there was an error. }
function SDL_SetColorKey(surface: PSDL_Surface; flag, key: UInt32) : Integer;
cdecl; external {$IFNDEF NDS}{$IFDEF __GPC__}name 'SDL_SetColorKey'{$ELSE} SDLLibName{$ENDIF __GPC__}{$ENDIF};
{$EXTERNALSYM SDL_SetColorKey}
{ This function sets the alpha value for the entire surface, as opposed to
using the alpha component of each pixel. This value measures the range
of transparency of the surface, 0 being completely transparent to 255
being completely opaque. An 'alpha' value of 255 causes blits to be
opaque, the source pixels copied to the destination (the default). Note
that per-surface alpha can be combined with colorkey transparency.
If 'flag' is 0, alpha blending is disabled for the surface.
If 'flag' is SDL_SRCALPHA, alpha blending is enabled for the surface.
OR:ing the flag with SDL_RLEACCEL requests RLE acceleration for the
surface; if SDL_RLEACCEL is not specified, the RLE accel will be removed. }
function SDL_SetAlpha(surface: PSDL_Surface; flag: UInt32; alpha: UInt8): Integer;
cdecl; external {$IFNDEF NDS}{$IFDEF __GPC__}name 'SDL_SetAlpha'{$ELSE} SDLLibName{$ENDIF __GPC__}{$ENDIF};
{$EXTERNALSYM SDL_SetAlpha}
{ Sets the clipping rectangle for the destination surface in a blit.
If the clip rectangle is NULL, clipping will be disabled.
If the clip rectangle doesn't intersect the surface, the function will
return SDL_FALSE and blits will be completely clipped. Otherwise the
function returns SDL_TRUE and blits to the surface will be clipped to
the intersection of the surface area and the clipping rectangle.
Note that blits are automatically clipped to the edges of the source
and destination surfaces. }
procedure SDL_SetClipRect(surface: PSDL_Surface; rect: PSDL_Rect); cdecl;
external {$IFNDEF NDS}{$IFDEF __GPC__}name 'SDL_SetClipRect'{$ELSE} SDLLibName{$ENDIF __GPC__}{$ENDIF};
{$EXTERNALSYM SDL_SetClipRect}
{ Gets the clipping rectangle for the destination surface in a blit.
'rect' must be a pointer to a valid rectangle which will be filled
with the correct values. }
procedure SDL_GetClipRect(surface: PSDL_Surface; rect: PSDL_Rect); cdecl;
external {$IFNDEF NDS}{$IFDEF __GPC__}name 'SDL_GetClipRect'{$ELSE} SDLLibName{$ENDIF __GPC__}{$ENDIF};
{$EXTERNALSYM SDL_GetClipRect}
{ Creates a new surface of the specified format, and then copies and maps
the given surface to it so the blit of the converted surface will be as
fast as possible. If this function fails, it returns NULL.
The 'flags' parameter is passed to SDL_CreateRGBSurface() and has those
semantics. You can also pass SDL_RLEACCEL in the flags parameter and
SDL will try to RLE accelerate colorkey and alpha blits in the resulting
surface.
This function is used internally by SDL_DisplayFormat(). }
function SDL_ConvertSurface(src: PSDL_Surface; fmt: PSDL_PixelFormat; flags: UInt32): PSDL_Surface;
cdecl; external {$IFNDEF NDS}{$IFDEF __GPC__}name 'SDL_ConvertSurface'{$ELSE} SDLLibName{$ENDIF __GPC__}{$ENDIF};
{$EXTERNALSYM SDL_ConvertSurface}
{
This performs a fast blit from the source surface to the destination
surface. It assumes that the source and destination rectangles are
the same size. If either 'srcrect' or 'dstrect' are NULL, the entire
surface (src or dst) is copied. The final blit rectangles are saved
in 'srcrect' and 'dstrect' after all clipping is performed.
If the blit is successful, it returns 0, otherwise it returns -1.
The blit function should not be called on a locked surface.
The blit semantics for surfaces with and without alpha and colorkey
are defined as follows:
RGBA->RGB:
SDL_SRCALPHA set:
alpha-blend (using alpha-channel).
SDL_SRCCOLORKEY ignored.
SDL_SRCALPHA not set:
copy RGB.
if SDL_SRCCOLORKEY set, only copy the pixels matching the
RGB values of the source colour key, ignoring alpha in the
comparison.
RGB->RGBA:
SDL_SRCALPHA set:
alpha-blend (using the source per-surface alpha value);
set destination alpha to opaque.
SDL_SRCALPHA not set:
copy RGB, set destination alpha to opaque.
both:
if SDL_SRCCOLORKEY set, only copy the pixels matching the
source colour key.
RGBA->RGBA:
SDL_SRCALPHA set:
alpha-blend (using the source alpha channel) the RGB values;
leave destination alpha untouched. [Note: is this correct?]
SDL_SRCCOLORKEY ignored.
SDL_SRCALPHA not set:
copy all of RGBA to the destination.
if SDL_SRCCOLORKEY set, only copy the pixels matching the
RGB values of the source colour key, ignoring alpha in the
comparison.
RGB->RGB:
SDL_SRCALPHA set:
alpha-blend (using the source per-surface alpha value).
SDL_SRCALPHA not set:
copy RGB.
both:
if SDL_SRCCOLORKEY set, only copy the pixels matching the
source colour key.
If either of the surfaces were in video memory, and the blit returns -2,
the video memory was lost, so it should be reloaded with artwork and
re-blitted:
while ( SDL_BlitSurface(image, imgrect, screen, dstrect) = -2 ) do
begin
while ( SDL_LockSurface(image) < 0 ) do
Sleep(10);
-- Write image pixels to image->pixels --
SDL_UnlockSurface(image);
end;
This happens under DirectX 5.0 when the system switches away from your
fullscreen application. The lock will also fail until you have access
to the video memory again. }
{ You should call SDL_BlitSurface() unless you know exactly how SDL
blitting works internally and how to use the other blit functions. }
function SDL_BlitSurface(src: PSDL_Surface; srcrect: PSDL_Rect; dst: PSDL_Surface; dstrect: PSDL_Rect): Integer;
{$EXTERNALSYM SDL_BlitSurface}
{ This is the public blit function, SDL_BlitSurface(), and it performs
rectangle validation and clipping before passing it to SDL_LowerBlit() }
function SDL_UpperBlit(src: PSDL_Surface; srcrect: PSDL_Rect; dst: PSDL_Surface; dstrect: PSDL_Rect): Integer;
cdecl; external {$IFNDEF NDS}{$IFDEF __GPC__}name 'SDL_UpperBlit'{$ELSE} SDLLibName{$ENDIF __GPC__}{$ENDIF};
{$EXTERNALSYM SDL_UpperBlit}
{ This is a semi-private blit function and it performs low-level surface
blitting only. }
function SDL_LowerBlit(src: PSDL_Surface; srcrect: PSDL_Rect; dst: PSDL_Surface; dstrect: PSDL_Rect): Integer;
cdecl; external {$IFNDEF NDS}{$IFDEF __GPC__}name 'SDL_LowerBlit'{$ELSE} SDLLibName{$ENDIF __GPC__}{$ENDIF};
{$EXTERNALSYM SDL_LowerBlit}
{ This function performs a fast fill of the given rectangle with 'color'
The given rectangle is clipped to the destination surface clip area
and the final fill rectangle is saved in the passed in pointer.
If 'dstrect' is NULL, the whole surface will be filled with 'color'
The color should be a pixel of the format used by the surface, and
can be generated by the SDL_MapRGB() function.
This function returns 0 on success, or -1 on error. }
function SDL_FillRect(dst: PSDL_Surface; dstrect: PSDL_Rect; color: UInt32) : Integer;
cdecl; external {$IFNDEF NDS}{$IFDEF __GPC__}name 'SDL_FillRect'{$ELSE} SDLLibName{$ENDIF __GPC__}{$ENDIF};
{$EXTERNALSYM SDL_FillRect}
{ This function takes a surface and copies it to a new surface of the
pixel format and colors of the video framebuffer, suitable for fast
blitting onto the display surface. It calls SDL_ConvertSurface()
If you want to take advantage of hardware colorkey or alpha blit
acceleration, you should set the colorkey and alpha value before
calling this function.
If the conversion fails or runs out of memory, it returns NULL }
function SDL_DisplayFormat(surface: PSDL_Surface): PSDL_Surface; cdecl;
external {$IFNDEF NDS}{$IFDEF __GPC__}name 'SDL_DisplayFormat'{$ELSE} SDLLibName{$ENDIF __GPC__}{$ENDIF};
{$EXTERNALSYM SDL_DisplayFormat}
{ This function takes a surface and copies it to a new surface of the
pixel format and colors of the video framebuffer (if possible),
suitable for fast alpha blitting onto the display surface.
The new surface will always have an alpha channel.
If you want to take advantage of hardware colorkey or alpha blit
acceleration, you should set the colorkey and alpha value before
calling this function.
If the conversion fails or runs out of memory, it returns NULL }
function SDL_DisplayFormatAlpha(surface: PSDL_Surface): PSDL_Surface; cdecl;
external {$IFNDEF NDS}{$IFDEF __GPC__}name 'SDL_DisplayFormatAlpha'{$ELSE} SDLLibName{$ENDIF __GPC__}{$ENDIF};
{$EXTERNALSYM SDL_DisplayFormatAlpha}
//* * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * */
//* YUV video surface overlay functions */
//* * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * */
{ This function creates a video output overlay
Calling the returned surface an overlay is something of a misnomer because
the contents of the display surface underneath the area where the overlay
is shown is undefined - it may be overwritten with the converted YUV data. }
function SDL_CreateYUVOverlay(width: Integer; height: Integer; format: UInt32; display: PSDL_Surface): PSDL_Overlay;
cdecl; external {$IFNDEF NDS}{$IFDEF __GPC__}name 'SDL_CreateYUVOverlay'{$ELSE} SDLLibName{$ENDIF __GPC__}{$ENDIF};
{$EXTERNALSYM SDL_CreateYUVOverlay}
// Lock an overlay for direct access, and unlock it when you are done
function SDL_LockYUVOverlay(Overlay: PSDL_Overlay): Integer;
cdecl; external {$IFNDEF NDS}{$IFDEF __GPC__}name 'SDL_LockYUVOverlay'{$ELSE} SDLLibName{$ENDIF __GPC__}{$ENDIF};
{$EXTERNALSYM SDL_LockYUVOverlay}
procedure SDL_UnlockYUVOverlay(Overlay: PSDL_Overlay); cdecl;
external {$IFNDEF NDS}{$IFDEF __GPC__}name 'SDL_UnlockYUVOverlay'{$ELSE} SDLLibName{$ENDIF __GPC__}{$ENDIF};
{$EXTERNALSYM SDL_UnlockYUVOverlay}
{ Blit a video overlay to the display surface.
The contents of the video surface underneath the blit destination are
not defined.
The width and height of the destination rectangle may be different from
that of the overlay, but currently only 2x scaling is supported. }
function SDL_DisplayYUVOverlay(Overlay: PSDL_Overlay; dstrect: PSDL_Rect) : Integer;
cdecl; external {$IFNDEF NDS}{$IFDEF __GPC__}name 'SDL_DisplayYUVOverlay'{$ELSE} SDLLibName{$ENDIF __GPC__}{$ENDIF};
{$EXTERNALSYM SDL_DisplayYUVOverlay}
// Free a video overlay
procedure SDL_FreeYUVOverlay(Overlay: PSDL_Overlay);
cdecl; external {$IFNDEF NDS}{$IFDEF __GPC__}name 'SDL_FreeYUVOverlay'{$ELSE} SDLLibName{$ENDIF __GPC__}{$ENDIF};
{$EXTERNALSYM SDL_FreeYUVOverlay}
{------------------------------------------------------------------------------}
{ OpenGL Routines }
{------------------------------------------------------------------------------}
{ Dynamically load a GL driver, if SDL is built with dynamic GL.
SDL links normally with the OpenGL library on your system by default,
but you can compile it to dynamically load the GL driver at runtime.
If you do this, you need to retrieve all of the GL functions used in
your program from the dynamic library using SDL_GL_GetProcAddress().
This is disabled in default builds of SDL. }
function SDL_GL_LoadLibrary(filename: PChar): Integer;
cdecl; external {$IFNDEF NDS}{$IFDEF __GPC__}name 'SDL_GL_LoadLibrary'{$ELSE} SDLLibName{$ENDIF __GPC__}{$ENDIF};
{$EXTERNALSYM SDL_GL_LoadLibrary}
{ Get the address of a GL function (for extension functions) }
function SDL_GL_GetProcAddress(procname: PChar) : Pointer;
cdecl; external {$IFNDEF NDS}{$IFDEF __GPC__}name 'SDL_GL_GetProcAddress'{$ELSE} SDLLibName{$ENDIF __GPC__}{$ENDIF};
{$EXTERNALSYM SDL_GL_GetProcAddress}
{ Set an attribute of the OpenGL subsystem before intialization. }
function SDL_GL_SetAttribute(attr: TSDL_GLAttr; value: Integer) : Integer;
cdecl; external {$IFNDEF NDS}{$IFDEF __GPC__}name 'SDL_GL_SetAttribute'{$ELSE} SDLLibName{$ENDIF __GPC__}{$ENDIF};
{$EXTERNALSYM SDL_GL_SetAttribute}
{ Get an attribute of the OpenGL subsystem from the windowing
interface, such as glX. This is of course different from getting
the values from SDL's internal OpenGL subsystem, which only
stores the values you request before initialization.
Developers should track the values they pass into SDL_GL_SetAttribute
themselves if they want to retrieve these values. }
function SDL_GL_GetAttribute(attr: TSDL_GLAttr; var value: Integer): Integer;
cdecl; external {$IFNDEF NDS}{$IFDEF __GPC__}name 'SDL_GL_GetAttribute'{$ELSE} SDLLibName{$ENDIF __GPC__}{$ENDIF};
{$EXTERNALSYM SDL_GL_GetAttribute}
{ Swap the OpenGL buffers, if double-buffering is supported. }
procedure SDL_GL_SwapBuffers;
cdecl; external {$IFNDEF NDS}{$IFDEF __GPC__}name 'SDL_GL_SwapBuffers'{$ELSE} SDLLibName{$ENDIF __GPC__}{$ENDIF};
{$EXTERNALSYM SDL_GL_SwapBuffers;}
{ Internal functions that should not be called unless you have read
and understood the source code for these functions. }
procedure SDL_GL_UpdateRects(numrects: Integer; rects: PSDL_Rect);
cdecl; external {$IFNDEF NDS}{$IFDEF __GPC__}name 'SDL_GL_UpdateRects'{$ELSE} SDLLibName{$ENDIF __GPC__}{$ENDIF};
{$EXTERNALSYM SDL_GL_UpdateRects}
procedure SDL_GL_Lock;
cdecl; external {$IFNDEF NDS}{$IFDEF __GPC__}name 'SDL_GL_Lock'{$ELSE} SDLLibName{$ENDIF __GPC__}{$ENDIF};
{$EXTERNALSYM SDL_GL_Lock;}
procedure SDL_GL_Unlock;
cdecl; external {$IFNDEF NDS}{$IFDEF __GPC__}name 'SDL_GL_Unlock'{$ELSE} SDLLibName{$ENDIF __GPC__}{$ENDIF};
{$EXTERNALSYM SDL_GL_Unlock;}
{* * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * *}
{* These functions allow interaction with the window manager, if any. *}
{* * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * *}
{ Sets/Gets the title and icon text of the display window }
procedure SDL_WM_GetCaption(var title : PChar; var icon : PChar);
cdecl; external {$IFNDEF NDS}{$IFDEF __GPC__}name 'SDL_WM_GetCaption'{$ELSE} SDLLibName{$ENDIF __GPC__}{$ENDIF};
{$EXTERNALSYM SDL_WM_GetCaption}
procedure SDL_WM_SetCaption( const title : PChar; const icon : PChar);
cdecl; external {$IFNDEF NDS}{$IFDEF __GPC__}name 'SDL_WM_SetCaption'{$ELSE} SDLLibName{$ENDIF __GPC__}{$ENDIF};
{$EXTERNALSYM SDL_WM_SetCaption}
{ Sets the icon for the display window.
This function must be called before the first call to SDL_SetVideoMode().
It takes an icon surface, and a mask in MSB format.
If 'mask' is NULL, the entire icon surface will be used as the icon. }
procedure SDL_WM_SetIcon(icon: PSDL_Surface; mask: PUInt8);
cdecl; external {$IFNDEF NDS}{$IFDEF __GPC__}name 'SDL_WM_SetIcon'{$ELSE} SDLLibName{$ENDIF __GPC__}{$ENDIF};
{$EXTERNALSYM SDL_WM_SetIcon}
{ This function iconifies the window, and returns 1 if it succeeded.
If the function succeeds, it generates an SDL_APPACTIVE loss event.
This function is a noop and returns 0 in non-windowed environments. }
function SDL_WM_IconifyWindow: Integer;
cdecl; external {$IFNDEF NDS}{$IFDEF __GPC__}name 'SDL_WM_IconifyWindow'{$ELSE} SDLLibName{$ENDIF __GPC__}{$ENDIF};
{$EXTERNALSYM SDL_WM_IconifyWindow}
{ Toggle fullscreen mode without changing the contents of the screen.
If the display surface does not require locking before accessing
the pixel information, then the memory pointers will not change.
If this function was able to toggle fullscreen mode (change from
running in a window to fullscreen, or vice-versa), it will return 1.
If it is not implemented, or fails, it returns 0.
The next call to SDL_SetVideoMode() will set the mode fullscreen
attribute based on the flags parameter - if SDL_FULLSCREEN is not
set, then the display will be windowed by default where supported.
This is currently only implemented in the X11 video driver. }
function SDL_WM_ToggleFullScreen(surface: PSDL_Surface): Integer;
cdecl; external {$IFNDEF NDS}{$IFDEF __GPC__}name 'SDL_WM_ToggleFullScreen'{$ELSE} SDLLibName{$ENDIF __GPC__}{$ENDIF};
{$EXTERNALSYM SDL_WM_ToggleFullScreen}
{ Grabbing means that the mouse is confined to the application window,
and nearly all keyboard input is passed directly to the application,
and not interpreted by a window manager, if any. }
function SDL_WM_GrabInput(mode: TSDL_GrabMode): TSDL_GrabMode;
cdecl; external {$IFNDEF NDS}{$IFDEF __GPC__}name 'SDL_WM_GrabInput'{$ELSE} SDLLibName{$ENDIF __GPC__}{$ENDIF};
{$EXTERNALSYM SDL_WM_GrabInput}
{------------------------------------------------------------------------------}
{ mouse-routines }
{------------------------------------------------------------------------------}
{ Retrieve the current state of the mouse.
The current button state is returned as a button bitmask, which can
be tested using the SDL_BUTTON(X) macros, and x and y are set to the
current mouse cursor position. You can pass NULL for either x or y. }
function SDL_GetMouseState(var x: Integer; var y: Integer): UInt8;
cdecl; external {$IFNDEF NDS}{$IFDEF __GPC__}name 'SDL_GetMouseState'{$ELSE} SDLLibName{$ENDIF __GPC__}{$ENDIF};
{$EXTERNALSYM SDL_GetMouseState}
{ Retrieve the current state of the mouse.
The current button state is returned as a button bitmask, which can
be tested using the SDL_BUTTON(X) macros, and x and y are set to the
mouse deltas since the last call to SDL_GetRelativeMouseState(). }
function SDL_GetRelativeMouseState(var x: Integer; var y: Integer): UInt8;
cdecl; external {$IFNDEF NDS}{$IFDEF __GPC__}name 'SDL_GetRelativeMouseState'{$ELSE} SDLLibName{$ENDIF __GPC__}{$ENDIF};
{$EXTERNALSYM SDL_GetRelativeMouseState}
{ Set the position of the mouse cursor (generates a mouse motion event) }
procedure SDL_WarpMouse(x, y: UInt16);
cdecl; external {$IFNDEF NDS}{$IFDEF __GPC__}name 'SDL_WarpMouse'{$ELSE} SDLLibName{$ENDIF __GPC__}{$ENDIF};
{$EXTERNALSYM SDL_WarpMouse}
{ Create a cursor using the specified data and mask (in MSB format).
The cursor width must be a multiple of 8 bits.
The cursor is created in black and white according to the following:
data mask resulting pixel on screen
0 1 White
1 1 Black
0 0 Transparent
1 0 Inverted color if possible, black if not.
Cursors created with this function must be freed with SDL_FreeCursor(). }
function SDL_CreateCursor(data, mask: PUInt8; w, h, hot_x, hot_y: Integer): PSDL_Cursor;
cdecl; external {$IFNDEF NDS}{$IFDEF __GPC__}name 'SDL_CreateCursor'{$ELSE} SDLLibName{$ENDIF __GPC__}{$ENDIF};
{$EXTERNALSYM SDL_CreateCursor}
{ Set the currently active cursor to the specified one.
If the cursor is currently visible, the change will be immediately
represented on the display. }
procedure SDL_SetCursor(cursor: PSDL_Cursor);
cdecl; external {$IFNDEF NDS}{$IFDEF __GPC__}name 'SDL_SetCursor'{$ELSE} SDLLibName{$ENDIF __GPC__}{$ENDIF};
{$EXTERNALSYM SDL_SetCursor}
{ Returns the currently active cursor. }
function SDL_GetCursor: PSDL_Cursor;
cdecl; external {$IFNDEF NDS}{$IFDEF __GPC__}name 'SDL_GetCursor'{$ELSE} SDLLibName{$ENDIF __GPC__}{$ENDIF};
{$EXTERNALSYM SDL_GetCursor}
{ Deallocates a cursor created with SDL_CreateCursor(). }
procedure SDL_FreeCursor(cursor: PSDL_Cursor);
cdecl; external {$IFNDEF NDS}{$IFDEF __GPC__}name 'SDL_FreeCursor'{$ELSE} SDLLibName{$ENDIF __GPC__}{$ENDIF};
{$EXTERNALSYM SDL_FreeCursor}
{ Toggle whether or not the cursor is shown on the screen.
The cursor start off displayed, but can be turned off.
SDL_ShowCursor() returns 1 if the cursor was being displayed
before the call, or 0 if it was not. You can query the current
state by passing a 'toggle' value of -1. }
function SDL_ShowCursor(toggle: Integer): Integer;
cdecl; external {$IFNDEF NDS}{$IFDEF __GPC__}name 'SDL_ShowCursor'{$ELSE} SDLLibName{$ENDIF __GPC__}{$ENDIF};
{$EXTERNALSYM SDL_ShowCursor}
function SDL_BUTTON( Button : Integer ) : Integer;
{------------------------------------------------------------------------------}
{ Keyboard-routines }
{------------------------------------------------------------------------------}
{ Enable/Disable UNICODE translation of keyboard input.
This translation has some overhead, so translation defaults off.
If 'enable' is 1, translation is enabled.
If 'enable' is 0, translation is disabled.
If 'enable' is -1, the translation state is not changed.
It returns the previous state of keyboard translation. }
function SDL_EnableUNICODE(enable: Integer): Integer;
cdecl; external {$IFNDEF NDS}{$IFDEF __GPC__}name 'SDL_EnableUNICODE'{$ELSE} SDLLibName{$ENDIF __GPC__}{$ENDIF};
{$EXTERNALSYM SDL_EnableUNICODE}
{ If 'delay' is set to 0, keyboard repeat is disabled. }
function SDL_EnableKeyRepeat(delay: Integer; interval: Integer): Integer;
cdecl; external {$IFNDEF NDS}{$IFDEF __GPC__}name 'SDL_EnableKeyRepeat'{$ELSE} SDLLibName{$ENDIF __GPC__}{$ENDIF};
{$EXTERNALSYM SDL_EnableKeyRepeat}
procedure SDL_GetKeyRepeat(delay : PInteger; interval: PInteger);
cdecl; external {$IFNDEF NDS}{$IFDEF __GPC__}name 'SDL_GetKeyRepeat'{$ELSE} SDLLibName{$ENDIF __GPC__}{$ENDIF};
{$EXTERNALSYM SDL_GetKeyRepeat}
{ Get a snapshot of the current state of the keyboard.
Returns an array of keystates, indexed by the SDLK_* syms.
Used:
UInt8 *keystate = SDL_GetKeyState(NULL);
if ( keystate[SDLK_RETURN] ) ... <RETURN> is pressed }
function SDL_GetKeyState(numkeys: PInt): PUInt8;
cdecl; external {$IFNDEF NDS}{$IFDEF __GPC__}name 'SDL_GetKeyState'{$ELSE} SDLLibName{$ENDIF __GPC__}{$ENDIF};
{$EXTERNALSYM SDL_GetKeyState}
{ Get the current key modifier state }
function SDL_GetModState: TSDLMod;
cdecl; external {$IFNDEF NDS}{$IFDEF __GPC__}name 'SDL_GetModState'{$ELSE} SDLLibName{$ENDIF __GPC__}{$ENDIF};
{$EXTERNALSYM SDL_GetModState}
{ Set the current key modifier state
This does not change the keyboard state, only the key modifier flags. }
procedure SDL_SetModState(modstate: TSDLMod);
cdecl; external {$IFNDEF NDS}{$IFDEF __GPC__}name 'SDL_SetModState'{$ELSE} SDLLibName{$ENDIF __GPC__}{$ENDIF};
{$EXTERNALSYM SDL_SetModState}
{ Get the name of an SDL virtual keysym }
function SDL_GetKeyName(key: TSDLKey): PChar;
cdecl; external {$IFNDEF NDS}{$IFDEF __GPC__}name 'SDL_GetKeyName'{$ELSE} SDLLibName{$ENDIF __GPC__}{$ENDIF};
{$EXTERNALSYM SDL_GetKeyName}
{------------------------------------------------------------------------------}
{ Active Routines }
{------------------------------------------------------------------------------}
{ This function returns the current state of the application, which is a
bitwise combination of SDL_APPMOUSEFOCUS, SDL_APPINPUTFOCUS, and
SDL_APPACTIVE. If SDL_APPACTIVE is set, then the user is able to
see your application, otherwise it has been iconified or disabled. }
function SDL_GetAppState: UInt8;
cdecl; external {$IFNDEF NDS}{$IFDEF __GPC__}name 'SDL_GetAppState'{$ELSE} SDLLibName{$ENDIF __GPC__}{$ENDIF};
{$EXTERNALSYM SDL_GetAppState}
{ Mutex functions }
{ Create a mutex, initialized unlocked }
function SDL_CreateMutex: PSDL_Mutex;
cdecl; external {$IFNDEF NDS}{$IFDEF __GPC__}name 'SDL_CreateMutex'{$ELSE} SDLLibName{$ENDIF __GPC__}{$ENDIF};
{$EXTERNALSYM SDL_CreateMutex}
{ Lock the mutex (Returns 0, or -1 on error) }
function SDL_mutexP(mutex: PSDL_mutex): Integer;
cdecl; external {$IFNDEF NDS}{$IFDEF __GPC__}name 'SDL_mutexP'{$ELSE} SDLLibName{$ENDIF __GPC__}{$ENDIF};
{ $ EXTERNALSYM SDL_mutexP}
function SDL_LockMutex(mutex: PSDL_mutex): Integer;
{$EXTERNALSYM SDL_LockMutex}
{ Unlock the mutex (Returns 0, or -1 on error) }
function SDL_mutexV(mutex: PSDL_mutex): Integer;
cdecl; external {$IFNDEF NDS}{$IFDEF __GPC__}name 'SDL_mutexV'{$ELSE} SDLLibName{$ENDIF __GPC__}{$ENDIF};
{$EXTERNALSYM SDL_mutexV}
function SDL_UnlockMutex(mutex: PSDL_mutex): Integer;
{$EXTERNALSYM SDL_UnlockMutex}
{ Destroy a mutex }
procedure SDL_DestroyMutex(mutex: PSDL_mutex);
cdecl; external {$IFNDEF NDS}{$IFDEF __GPC__}name 'SDL_DestroyMutex'{$ELSE} SDLLibName{$ENDIF __GPC__}{$ENDIF};
{$EXTERNALSYM SDL_DestroyMutex}
{ * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * }
{ Semaphore functions }
{ * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * }
{ Create a semaphore, initialized with value, returns NULL on failure. }
function SDL_CreateSemaphore(initial_value: UInt32): PSDL_Sem;
cdecl; external {$IFNDEF NDS}{$IFDEF __GPC__}name 'SDL_CreateSemaphore'{$ELSE} SDLLibName{$ENDIF __GPC__}{$ENDIF};
{$EXTERNALSYM SDL_CreateSemaphore}
{ Destroy a semaphore }
procedure SDL_DestroySemaphore(sem: PSDL_sem);
cdecl; external {$IFNDEF NDS}{$IFDEF __GPC__}name 'SDL_DestroySemaphore'{$ELSE} SDLLibName{$ENDIF __GPC__}{$ENDIF};
{$EXTERNALSYM SDL_DestroySemaphore}
{ This function suspends the calling thread until the semaphore pointed
to by sem has a positive count. It then atomically decreases the semaphore
count. }
function SDL_SemWait(sem: PSDL_sem): Integer;
cdecl; external {$IFNDEF NDS}{$IFDEF __GPC__}name 'SDL_SemWait'{$ELSE} SDLLibName{$ENDIF __GPC__}{$ENDIF};
{$EXTERNALSYM SDL_SemWait}
{ Non-blocking variant of SDL_SemWait(), returns 0 if the wait succeeds,
SDL_MUTEX_TIMEDOUT if the wait would block, and -1 on error. }
function SDL_SemTryWait(sem: PSDL_sem): Integer;
cdecl; external {$IFNDEF NDS}{$IFDEF __GPC__}name 'SDL_SemTryWait'{$ELSE} SDLLibName{$ENDIF __GPC__}{$ENDIF};
{$EXTERNALSYM SDL_SemTryWait}
{ Variant of SDL_SemWait() with a timeout in milliseconds, returns 0 if
the wait succeeds, SDL_MUTEX_TIMEDOUT if the wait does not succeed in
the allotted time, and -1 on error.
On some platforms this function is implemented by looping with a delay
of 1 ms, and so should be avoided if possible. }
function SDL_SemWaitTimeout(sem: PSDL_sem; ms: UInt32): Integer;
cdecl; external {$IFNDEF NDS}{$IFDEF __GPC__}name 'SDL_SemWaitTimeout'{$ELSE} SDLLibName{$ENDIF __GPC__}{$ENDIF};
{$EXTERNALSYM SDL_SemTryWait}
{ Atomically increases the semaphore's count (not blocking), returns 0,
or -1 on error. }
function SDL_SemPost(sem: PSDL_sem): Integer;
cdecl; external {$IFNDEF NDS}{$IFDEF __GPC__}name 'SDL_SemPost'{$ELSE} SDLLibName{$ENDIF __GPC__}{$ENDIF};
{$EXTERNALSYM SDL_SemTryWait}
{ Returns the current count of the semaphore }
function SDL_SemValue(sem: PSDL_sem): UInt32;
cdecl; external {$IFNDEF NDS}{$IFDEF __GPC__}name 'SDL_SemValue'{$ELSE} SDLLibName{$ENDIF __GPC__}{$ENDIF};
{$EXTERNALSYM SDL_SemValue}
{ * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * }
{ Condition variable functions }
{ * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * }
{ Create a condition variable }
function SDL_CreateCond: PSDL_Cond;
cdecl; external {$IFNDEF NDS}{$IFDEF __GPC__}name 'SDL_CreateCond'{$ELSE} SDLLibName{$ENDIF __GPC__}{$ENDIF};
{$EXTERNALSYM SDL_CreateCond}
{ Destroy a condition variable }
procedure SDL_DestroyCond(cond: PSDL_Cond);
cdecl; external {$IFNDEF NDS}{$IFDEF __GPC__}name 'SDL_DestroyCond'{$ELSE} SDLLibName{$ENDIF __GPC__}{$ENDIF};
{$EXTERNALSYM SDL_DestroyCond}
{ Restart one of the threads that are waiting on the condition variable,
returns 0 or -1 on error. }
function SDL_CondSignal(cond: PSDL_cond): Integer;
cdecl; external {$IFNDEF NDS}{$IFDEF __GPC__}name 'SDL_CondSignal'{$ELSE} SDLLibName{$ENDIF __GPC__}{$ENDIF};
{$EXTERNALSYM SDL_CondSignal}
{ Restart all threads that are waiting on the condition variable,
returns 0 or -1 on error. }
function SDL_CondBroadcast(cond: PSDL_cond): Integer;
cdecl; external {$IFNDEF NDS}{$IFDEF __GPC__}name 'SDL_CondBroadcast'{$ELSE} SDLLibName{$ENDIF __GPC__}{$ENDIF};
{$EXTERNALSYM SDL_CondBroadcast}
{ Wait on the condition variable, unlocking the provided mutex.
The mutex must be locked before entering this function!
Returns 0 when it is signaled, or -1 on error. }
function SDL_CondWait(cond: PSDL_cond; mut: PSDL_mutex): Integer;
cdecl; external {$IFNDEF NDS}{$IFDEF __GPC__}name 'SDL_CondWait'{$ELSE} SDLLibName{$ENDIF __GPC__}{$ENDIF};
{$EXTERNALSYM SDL_CondWait}
{ Waits for at most 'ms' milliseconds, and returns 0 if the condition
variable is signaled, SDL_MUTEX_TIMEDOUT if the condition is not
signaled in the allotted time, and -1 on error.
On some platforms this function is implemented by looping with a delay
of 1 ms, and so should be avoided if possible. }
function SDL_CondWaitTimeout(cond: PSDL_cond; mut: PSDL_mutex; ms: UInt32) : Integer;
cdecl; external {$IFNDEF NDS}{$IFDEF __GPC__}name 'SDL_CondWaitTimeout'{$ELSE} SDLLibName{$ENDIF __GPC__}{$ENDIF};
{$EXTERNALSYM SDL_CondWaitTimeout}
{ * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * }
{ Condition variable functions }
{ * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * }
{ Create a thread }
function SDL_CreateThread(fn: PInt; data: Pointer): PSDL_Thread;
cdecl; external {$IFNDEF NDS}{$IFDEF __GPC__}name 'SDL_CreateThread'{$ELSE} SDLLibName{$ENDIF __GPC__}{$ENDIF};
{$EXTERNALSYM SDL_CreateThread}
{ Get the 32-bit thread identifier for the current thread }
function SDL_ThreadID: UInt32;
cdecl; external {$IFNDEF NDS}{$IFDEF __GPC__}name 'SDL_ThreadID'{$ELSE} SDLLibName{$ENDIF __GPC__}{$ENDIF};
{$EXTERNALSYM SDL_ThreadID}
{ Get the 32-bit thread identifier for the specified thread,
equivalent to SDL_ThreadID() if the specified thread is NULL. }
function SDL_GetThreadID(thread: PSDL_Thread): UInt32;
cdecl; external {$IFNDEF NDS}{$IFDEF __GPC__}name 'SDL_GetThreadID'{$ELSE} SDLLibName{$ENDIF __GPC__}{$ENDIF};
{$EXTERNALSYM SDL_GetThreadID}
{ Wait for a thread to finish.
The return code for the thread function is placed in the area
pointed to by 'status', if 'status' is not NULL. }
procedure SDL_WaitThread(thread: PSDL_Thread; var status: Integer);
cdecl; external {$IFNDEF NDS}{$IFDEF __GPC__}name 'SDL_WaitThread'{$ELSE} SDLLibName{$ENDIF __GPC__}{$ENDIF};
{$EXTERNALSYM SDL_WaitThread}
{ Forcefully kill a thread without worrying about its state }
procedure SDL_KillThread(thread: PSDL_Thread);
cdecl; external {$IFNDEF NDS}{$IFDEF __GPC__}name 'SDL_KillThread'{$ELSE} SDLLibName{$ENDIF __GPC__}{$ENDIF};
{$EXTERNALSYM SDL_KillThread}
{------------------------------------------------------------------------------}
{ Get Environment Routines }
{------------------------------------------------------------------------------}
{$IFDEF WINDOWS}
function _putenv( const variable : Pchar ): integer;
cdecl;
{$ENDIF}
{$IFDEF Unix}
{$IFDEF FPC}
function _putenv( const variable : Pchar ): integer;
cdecl; external 'libc.so' name 'putenv';
{$ENDIF}
{$ENDIF}
{ Put a variable of the form "name=value" into the environment }
//function SDL_putenv(const variable: PChar): integer; cdecl; external {$IFNDEF NDS}{$IFDEF __GPC__}name 'SDL_Init'{$ELSE} SDLLibName{$ENDIF __GPC__}SDLLibName name '';
function SDL_putenv(const variable: PChar): integer;
{$EXTERNALSYM SDL_putenv}
// The following function has been commented out to encourage developers to use
// SDL_putenv as it it more portable
//function putenv(const variable: PChar): integer;
//{$EXTERNALSYM putenv}
{$IFDEF WINDOWS}
{$IFNDEF __GPC__}
function getenv( const name : Pchar ): PChar; cdecl;
{$ENDIF}
{$ENDIF}
{* Retrieve a variable named "name" from the environment }
//function SDL_getenv(const name: PChar): PChar; cdecl; external {$IFNDEF NDS}{$IFDEF __GPC__}name 'SDL_Init'{$ELSE} SDLLibName{$ENDIF __GPC__}SDLLibName name '';
function SDL_getenv(const name: PChar): PChar;
{$EXTERNALSYM SDL_getenv}
// The following function has been commented out to encourage developers to use
// SDL_getenv as it it more portable
//function getenv(const name: PChar): PChar;
//{$EXTERNALSYM getenv}
{*
* This function gives you custom hooks into the window manager information.
* It fills the structure pointed to by 'info' with custom information and
* returns 1 if the function is implemented. If it's not implemented, or
* the version member of the 'info' structure is invalid, it returns 0.
*}
function SDL_GetWMInfo(info : PSDL_SysWMinfo) : integer;
cdecl; external {$IFNDEF NDS}{$IFDEF __GPC__}name 'SDL_GetWMInfo'{$ELSE} SDLLibName{$ENDIF __GPC__}{$ENDIF};
{$EXTERNALSYM SDL_GetWMInfo}
{------------------------------------------------------------------------------}
//SDL_loadso.h
{* This function dynamically loads a shared object and returns a pointer
* to the object handle (or NULL if there was an error).
* The 'sofile' parameter is a system dependent name of the object file.
*}
function SDL_LoadObject( const sofile : PChar ) : Pointer;
cdecl; external {$IFNDEF NDS}{$IFDEF __GPC__}name 'SDL_LoadObject'{$ELSE} SDLLibName{$ENDIF __GPC__}{$ENDIF};
{$EXTERNALSYM SDL_LoadObject}
{* Given an object handle, this function looks up the address of the
* named function in the shared object and returns it. This address
* is no longer valid after calling SDL_UnloadObject().
*}
function SDL_LoadFunction( handle : Pointer; const name : PChar ) : Pointer;
cdecl; external {$IFNDEF NDS}{$IFDEF __GPC__}name 'SDL_LoadFunction'{$ELSE} SDLLibName{$ENDIF __GPC__}{$ENDIF};
{$EXTERNALSYM SDL_LoadFunction}
{* Unload a shared object from memory *}
procedure SDL_UnloadObject( handle : Pointer );
cdecl; external {$IFNDEF NDS}{$IFDEF __GPC__}name 'SDL_UnloadObject'{$ELSE} SDLLibName{$ENDIF __GPC__}{$ENDIF};
{$EXTERNALSYM SDL_UnloadObject}
{------------------------------------------------------------------------------}
function SDL_Swap32(D: Uint32): Uint32;
{$EXTERNALSYM SDL_Swap32}
{ FreeAndNil frees the given TObject instance and sets the variable reference
to nil. Be careful to only pass TObjects to this routine. }
procedure FreeAndNil(var Obj);
{ Exit procedure handling }
{ AddExitProc adds the given procedure to the run-time library's exit
procedure list. When an application terminates, its exit procedures are
executed in reverse order of definition, i.e. the last procedure passed
to AddExitProc is the first one to get executed upon termination. }
procedure AddExitProc(Proc: TProcedure);
// Bitwise Checking functions
function IsBitOn( value : integer; bit : Byte ) : boolean;
function TurnBitOn( value : integer; bit : Byte ) : integer;
function TurnBitOff( value : integer; bit : Byte ) : integer;
implementation
{$IFDEF __GPC__}
{$L 'sdl'} { link sdl.dll.a or libsdl.so or libsdl.a }
{$ENDIF}
function SDL_TABLESIZE(table: PChar): Integer;
begin
Result := SizeOf(table) div SizeOf(table[0]);
end;
procedure SDL_OutOfMemory;
begin
{$IFNDEF WINDOWS}
SDL_Error(SDL_ENOMEM);
{$ENDIF}
end;
function SDL_RWSeek(context: PSDL_RWops; offset: Integer; whence: Integer) : Integer;
begin
Result := context^.seek(context, offset, whence);
end;
function SDL_RWTell(context: PSDL_RWops): Integer;
begin
Result := context^.seek(context, 0, 1);
end;
function SDL_RWRead(context: PSDL_RWops; ptr: Pointer; size: Integer; n: Integer): Integer;
begin
Result := context^.read(context, ptr, size, n);
end;
function SDL_RWWrite(context: PSDL_RWops; ptr: Pointer; size: Integer; n: Integer): Integer;
begin
Result := context^.write(context, ptr, size, n);
end;
function SDL_RWClose(context: PSDL_RWops): Integer;
begin
Result := context^.close(context);
end;
function SDL_LoadWAV(filename: PChar; spec: PSDL_AudioSpec; audio_buf: PUInt8; audiolen: PUInt32): PSDL_AudioSpec;
begin
Result := SDL_LoadWAV_RW(SDL_RWFromFile(filename, 'rb'), 1, spec, audio_buf, audiolen);
end;
function SDL_CDInDrive( status : TSDL_CDStatus ): LongBool;
begin
Result := ord( status ) > ord( CD_ERROR );
end;
procedure FRAMES_TO_MSF(frames: Integer; var M: Integer; var S: Integer; var
F: Integer);
var
value: Integer;
begin
value := frames;
F := value mod CD_FPS;
value := value div CD_FPS;
S := value mod 60;
value := value div 60;
M := value;
end;
function MSF_TO_FRAMES(M: Integer; S: Integer; F: Integer): Integer;
begin
Result := M * 60 * CD_FPS + S * CD_FPS + F;
end;
procedure SDL_VERSION(var X: TSDL_Version);
begin
X.major := SDL_MAJOR_VERSION;
X.minor := SDL_MINOR_VERSION;
X.patch := SDL_PATCHLEVEL;
end;
function SDL_VERSIONNUM(X, Y, Z: Integer): Integer;
begin
Result := X * 1000 + Y * 100 + Z;
end;
function SDL_COMPILEDVERSION: Integer;
begin
Result := SDL_VERSIONNUM(SDL_MAJOR_VERSION, SDL_MINOR_VERSION, SDL_PATCHLEVEL
);
end;
function SDL_VERSION_ATLEAST(X, Y, Z: Integer): LongBool;
begin
Result := (SDL_COMPILEDVERSION >= SDL_VERSIONNUM(X, Y, Z));
end;
function SDL_LoadBMP(filename: PChar): PSDL_Surface;
begin
Result := SDL_LoadBMP_RW(SDL_RWFromFile(filename, 'rb'), 1);
end;
function SDL_SaveBMP(surface: PSDL_Surface; filename: PChar): Integer;
begin
Result := SDL_SaveBMP_RW(surface, SDL_RWFromFile(filename, 'wb'), 1);
end;
function SDL_BlitSurface(src: PSDL_Surface; srcrect: PSDL_Rect; dst:
PSDL_Surface;
dstrect: PSDL_Rect): Integer;
begin
Result := SDL_UpperBlit(src, srcrect, dst, dstrect);
end;
function SDL_AllocSurface(flags: UInt32; width, height, depth: Integer;
RMask, GMask, BMask, AMask: UInt32): PSDL_Surface;
begin
Result := SDL_CreateRGBSurface(flags, width, height, depth, RMask, GMask,
BMask, AMask);
end;
function SDL_MustLock(Surface: PSDL_Surface): Boolean;
begin
Result := ( ( surface^.offset <> 0 ) or
( ( surface^.flags and ( SDL_HWSURFACE or SDL_ASYNCBLIT or SDL_RLEACCEL ) ) <> 0 ) );
end;
function SDL_LockMutex(mutex: PSDL_mutex): Integer;
begin
Result := SDL_mutexP(mutex);
end;
function SDL_UnlockMutex(mutex: PSDL_mutex): Integer;
begin
Result := SDL_mutexV(mutex);
end;
{$IFDEF WINDOWS}
function _putenv( const variable : Pchar ): Integer;
cdecl; external {$IFDEF __GPC__}name '_putenv'{$ELSE} 'MSVCRT.DLL'{$ENDIF __GPC__};
{$ENDIF}
function SDL_putenv(const variable: PChar): Integer;
begin
{$IFDEF WINDOWS}
Result := _putenv(variable);
{$ENDIF}
{$IFDEF UNIX}
{$IFDEF FPC}
Result := _putenv(variable);
{$ELSE}
Result := libc.putenv(variable);
{$ENDIF}
{$ENDIF}
end;
{$IFDEF WINDOWS}
{$IFNDEF __GPC__}
function getenv( const name : Pchar ): PChar;
cdecl; external {$IFDEF __GPC__}name 'getenv'{$ELSE} 'MSVCRT.DLL'{$ENDIF};
{$ENDIF}
{$ENDIF}
function SDL_getenv(const name: PChar): PChar;
begin
{$IFDEF WINDOWS}
{$IFDEF __GPC__}
Result := getenv( string( name ) );
{$ELSE}
Result := getenv( name );
{$ENDIF}
{$ELSE}
{$IFDEF UNIX}
{$IFDEF FPC}
Result := fpgetenv(name);
{$ELSE}
Result := libc.getenv(name);
{$ENDIF}
{$ENDIF}
{$ENDIF}
end;
function SDL_BUTTON( Button : Integer ) : Integer;
begin
Result := SDL_PRESSED shl ( Button - 1 );
end;
function SDL_Swap32(D: Uint32): Uint32;
begin
Result := ((D shl 24) or ((D shl 8) and $00FF0000) or ((D shr 8) and $0000FF00) or (D shr 24));
end;
procedure FreeAndNil(var Obj);
{$IFNDEF __GPC__}
{$IFNDEF __TMT__}
var
Temp: TObject;
{$ENDIF}
{$ENDIF}
begin
{$IFNDEF __GPC__}
{$IFNDEF __TMT__}
Temp := TObject(Obj);
Pointer(Obj) := nil;
Temp.Free;
{$ENDIF}
{$ENDIF}
end;
{ Exit procedure handling }
type
PExitProcInfo = ^TExitProcInfo;
TExitProcInfo = record
Next: PExitProcInfo;
SaveExit: Pointer;
Proc: TProcedure;
end;
var
ExitProcList: PExitProcInfo = nil;
procedure DoExitProc;
var
P: PExitProcInfo;
Proc: TProcedure;
begin
P := ExitProcList;
ExitProcList := P^.Next;
ExitProc := P^.SaveExit;
Proc := P^.Proc;
Dispose(P);
Proc;
end;
procedure AddExitProc(Proc: TProcedure);
var
P: PExitProcInfo;
begin
New(P);
P^.Next := ExitProcList;
P^.SaveExit := ExitProc;
P^.Proc := Proc;
ExitProcList := P;
ExitProc := @DoExitProc;
end;
function IsBitOn( value : integer; bit : Byte ) : boolean;
begin
result := ( ( value and ( 1 shl bit ) ) <> 0 );
end;
function TurnBitOn( value : integer; bit : Byte ) : integer;
begin
result := ( value or ( 1 shl bit ) );
end;
function TurnBitOff( value : integer; bit : Byte ) : integer;
begin
result := ( value and not ( 1 shl bit ) );
end;
end.