/*
===========================================================================
Doom 3 BFG Edition GPL Source Code
Copyright (C) 1993-2012 id Software LLC, a ZeniMax Media company.
This file is part of the Doom 3 BFG Edition GPL Source Code ("Doom 3 BFG Edition Source Code").
Doom 3 BFG Edition Source Code is free software: you can redistribute it and/or modify
it under the terms of the GNU General Public License as published by
the Free Software Foundation, either version 3 of the License, or
(at your option) any later version.
Doom 3 BFG Edition Source Code is distributed in the hope that it will be useful,
but WITHOUT ANY WARRANTY; without even the implied warranty of
MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
GNU General Public License for more details.
You should have received a copy of the GNU General Public License
along with Doom 3 BFG Edition Source Code. If not, see .
In addition, the Doom 3 BFG Edition Source Code is also subject to certain additional terms. You should have received a copy of these additional terms immediately following the terms and conditions of the GNU General Public License which accompanied the Doom 3 BFG Edition Source Code. If not, please request a copy in writing from id Software at the address below.
If you have questions concerning this license or the applicable additional terms, you may contact in writing id Software LLC, c/o ZeniMax Media Inc., Suite 120, Rockville, Maryland 20850 USA.
===========================================================================
*/
#pragma hdrstop
#include "../../idlib/precompiled.h"
#include "../sys_session_local.h"
#include "win_local.h"
#define DINPUT_BUFFERSIZE 256
/*
============================================================
DIRECT INPUT KEYBOARD CONTROL
============================================================
*/
bool IN_StartupKeyboard() {
HRESULT hr;
bool bExclusive;
bool bForeground;
bool bImmediate;
bool bDisableWindowsKey;
DWORD dwCoopFlags;
if (!win32.g_pdi) {
common->Printf("keyboard: DirectInput has not been started\n");
return false;
}
if (win32.g_pKeyboard) {
win32.g_pKeyboard->Release();
win32.g_pKeyboard = NULL;
}
// Detrimine where the buffer would like to be allocated
bExclusive = false;
bForeground = true;
bImmediate = false;
bDisableWindowsKey = true;
if( bExclusive )
dwCoopFlags = DISCL_EXCLUSIVE;
else
dwCoopFlags = DISCL_NONEXCLUSIVE;
if( bForeground )
dwCoopFlags |= DISCL_FOREGROUND;
else
dwCoopFlags |= DISCL_BACKGROUND;
// Disabling the windows key is only allowed only if we are in foreground nonexclusive
if( bDisableWindowsKey && !bExclusive && bForeground )
dwCoopFlags |= DISCL_NOWINKEY;
// Obtain an interface to the system keyboard device.
if( FAILED( hr = win32.g_pdi->CreateDevice( GUID_SysKeyboard, &win32.g_pKeyboard, NULL ) ) ) {
common->Printf("keyboard: couldn't find a keyboard device\n");
return false;
}
// Set the data format to "keyboard format" - a predefined data format
//
// A data format specifies which controls on a device we
// are interested in, and how they should be reported.
//
// This tells DirectInput that we will be passing an array
// of 256 bytes to IDirectInputDevice::GetDeviceState.
if( FAILED( hr = win32.g_pKeyboard->SetDataFormat( &c_dfDIKeyboard ) ) )
return false;
// Set the cooperativity level to let DirectInput know how
// this device should interact with the system and with other
// DirectInput applications.
hr = win32.g_pKeyboard->SetCooperativeLevel( win32.hWnd, dwCoopFlags );
if( hr == DIERR_UNSUPPORTED && !bForeground && bExclusive ) {
common->Printf("keyboard: SetCooperativeLevel() returned DIERR_UNSUPPORTED.\nFor security reasons, background exclusive keyboard access is not allowed.\n");
return false;
}
if( FAILED(hr) ) {
return false;
}
if( !bImmediate ) {
// IMPORTANT STEP TO USE BUFFERED DEVICE DATA!
//
// DirectInput uses unbuffered I/O (buffer size = 0) by default.
// If you want to read buffered data, you need to set a nonzero
// buffer size.
//
// Set the buffer size to DINPUT_BUFFERSIZE (defined above) elements.
//
// The buffer size is a DWORD property associated with the device.
DIPROPDWORD dipdw;
dipdw.diph.dwSize = sizeof(DIPROPDWORD);
dipdw.diph.dwHeaderSize = sizeof(DIPROPHEADER);
dipdw.diph.dwObj = 0;
dipdw.diph.dwHow = DIPH_DEVICE;
dipdw.dwData = DINPUT_BUFFERSIZE; // Arbitary buffer size
if( FAILED( hr = win32.g_pKeyboard->SetProperty( DIPROP_BUFFERSIZE, &dipdw.diph ) ) )
return false;
}
// Acquire the newly created device
win32.g_pKeyboard->Acquire();
common->Printf( "keyboard: DirectInput initialized.\n");
return true;
}
/*
==========================
IN_DeactivateKeyboard
==========================
*/
void IN_DeactivateKeyboard() {
if (!win32.g_pKeyboard) {
return;
}
win32.g_pKeyboard->Unacquire( );
}
/*
============================================================
DIRECT INPUT MOUSE CONTROL
============================================================
*/
/*
========================
IN_InitDirectInput
========================
*/
void IN_InitDirectInput() {
HRESULT hr;
common->Printf( "Initializing DirectInput...\n" );
if ( win32.g_pdi != NULL ) {
win32.g_pdi->Release(); // if the previous window was destroyed we need to do this
win32.g_pdi = NULL;
}
// Register with the DirectInput subsystem and get a pointer
// to a IDirectInput interface we can use.
// Create the base DirectInput object
if ( FAILED( hr = DirectInput8Create( GetModuleHandle(NULL), DIRECTINPUT_VERSION, IID_IDirectInput8, (void**)&win32.g_pdi, NULL ) ) ) {
common->Printf ("DirectInputCreate failed\n");
}
}
/*
========================
IN_InitDIMouse
========================
*/
bool IN_InitDIMouse() {
HRESULT hr;
if ( win32.g_pdi == NULL) {
return false;
}
// obtain an interface to the system mouse device.
hr = win32.g_pdi->CreateDevice( GUID_SysMouse, &win32.g_pMouse, NULL);
if (FAILED(hr)) {
common->Printf ("mouse: Couldn't open DI mouse device\n");
return false;
}
// Set the data format to "mouse format" - a predefined data format
//
// A data format specifies which controls on a device we
// are interested in, and how they should be reported.
//
// This tells DirectInput that we will be passing a
// DIMOUSESTATE2 structure to IDirectInputDevice::GetDeviceState.
if( FAILED( hr = win32.g_pMouse->SetDataFormat( &c_dfDIMouse2 ) ) ) {
common->Printf ("mouse: Couldn't set DI mouse format\n");
return false;
}
// set the cooperativity level.
hr = win32.g_pMouse->SetCooperativeLevel( win32.hWnd, DISCL_EXCLUSIVE | DISCL_FOREGROUND);
if (FAILED(hr)) {
common->Printf ("mouse: Couldn't set DI coop level\n");
return false;
}
// IMPORTANT STEP TO USE BUFFERED DEVICE DATA!
//
// DirectInput uses unbuffered I/O (buffer size = 0) by default.
// If you want to read buffered data, you need to set a nonzero
// buffer size.
//
// Set the buffer size to SAMPLE_BUFFER_SIZE (defined above) elements.
//
// The buffer size is a DWORD property associated with the device.
DIPROPDWORD dipdw;
dipdw.diph.dwSize = sizeof(DIPROPDWORD);
dipdw.diph.dwHeaderSize = sizeof(DIPROPHEADER);
dipdw.diph.dwObj = 0;
dipdw.diph.dwHow = DIPH_DEVICE;
dipdw.dwData = DINPUT_BUFFERSIZE; // Arbitary buffer size
if( FAILED( hr = win32.g_pMouse->SetProperty( DIPROP_BUFFERSIZE, &dipdw.diph ) ) ) {
common->Printf ("mouse: Couldn't set DI buffersize\n");
return false;
}
IN_ActivateMouse();
// clear any pending samples
int mouseEvents[MAX_MOUSE_EVENTS][2];
Sys_PollMouseInputEvents( mouseEvents );
common->Printf( "mouse: DirectInput initialized.\n");
return true;
}
/*
==========================
IN_ActivateMouse
==========================
*/
void IN_ActivateMouse() {
int i;
HRESULT hr;
if ( !win32.in_mouse.GetBool() || win32.mouseGrabbed || !win32.g_pMouse ) {
return;
}
win32.mouseGrabbed = true;
for ( i = 0; i < 10; i++ ) {
if ( ::ShowCursor( false ) < 0 ) {
break;
}
}
// we may fail to reacquire if the window has been recreated
hr = win32.g_pMouse->Acquire();
if (FAILED(hr)) {
return;
}
// set the cooperativity level.
hr = win32.g_pMouse->SetCooperativeLevel( win32.hWnd, DISCL_EXCLUSIVE | DISCL_FOREGROUND);
}
/*
==========================
IN_DeactivateMouse
==========================
*/
void IN_DeactivateMouse() {
int i;
if (!win32.g_pMouse || !win32.mouseGrabbed ) {
return;
}
win32.g_pMouse->Unacquire();
for ( i = 0; i < 10; i++ ) {
if ( ::ShowCursor( true ) >= 0 ) {
break;
}
}
win32.mouseGrabbed = false;
}
/*
==========================
IN_DeactivateMouseIfWindowed
==========================
*/
void IN_DeactivateMouseIfWindowed() {
if ( !win32.cdsFullscreen ) {
IN_DeactivateMouse();
}
}
/*
============================================================
MOUSE CONTROL
============================================================
*/
/*
===========
Sys_ShutdownInput
===========
*/
void Sys_ShutdownInput() {
IN_DeactivateMouse();
IN_DeactivateKeyboard();
if ( win32.g_pKeyboard ) {
win32.g_pKeyboard->Release();
win32.g_pKeyboard = NULL;
}
if ( win32.g_pMouse ) {
win32.g_pMouse->Release();
win32.g_pMouse = NULL;
}
if ( win32.g_pdi ) {
win32.g_pdi->Release();
win32.g_pdi = NULL;
}
}
/*
===========
Sys_InitInput
===========
*/
void Sys_InitInput() {
common->Printf ("\n------- Input Initialization -------\n");
IN_InitDirectInput();
if ( win32.in_mouse.GetBool() ) {
IN_InitDIMouse();
// don't grab the mouse on initialization
Sys_GrabMouseCursor( false );
} else {
common->Printf ("Mouse control not active.\n");
}
IN_StartupKeyboard();
common->Printf ("------------------------------------\n");
win32.in_mouse.ClearModified();
}
/*
==================
IN_Frame
Called every frame, even if not generating commands
==================
*/
void IN_Frame() {
bool shouldGrab = true;
if ( !win32.in_mouse.GetBool() ) {
shouldGrab = false;
}
// if fullscreen, we always want the mouse
if ( !win32.cdsFullscreen ) {
if ( win32.mouseReleased ) {
shouldGrab = false;
}
if ( win32.movingWindow ) {
shouldGrab = false;
}
if ( !win32.activeApp ) {
shouldGrab = false;
}
}
if ( shouldGrab != win32.mouseGrabbed ) {
if ( usercmdGen != NULL ) {
usercmdGen->Clear();
}
if ( win32.mouseGrabbed ) {
IN_DeactivateMouse();
} else {
IN_ActivateMouse();
#if 0 // if we can't reacquire, try reinitializing
if ( !IN_InitDIMouse() ) {
win32.in_mouse.SetBool( false );
return;
}
#endif
}
}
}
void Sys_GrabMouseCursor( bool grabIt ) {
win32.mouseReleased = !grabIt;
if ( !grabIt ) {
// release it right now
IN_Frame();
}
}
//=====================================================================================
static DIDEVICEOBJECTDATA polled_didod[ DINPUT_BUFFERSIZE ]; // Receives buffered data
static int diFetch;
static byte toggleFetch[2][ 256 ];
#if 1
// I tried doing the full-state get to address a keyboard problem on one system,
// but it didn't make any difference
/*
====================
Sys_PollKeyboardInputEvents
====================
*/
int Sys_PollKeyboardInputEvents() {
DWORD dwElements;
HRESULT hr;
if( win32.g_pKeyboard == NULL ) {
return 0;
}
dwElements = DINPUT_BUFFERSIZE;
hr = win32.g_pKeyboard->GetDeviceData( sizeof(DIDEVICEOBJECTDATA),
polled_didod, &dwElements, 0 );
if( hr != DI_OK )
{
// We got an error or we got DI_BUFFEROVERFLOW.
//
// Either way, it means that continuous contact with the
// device has been lost, either due to an external
// interruption, or because the buffer overflowed
// and some events were lost.
hr = win32.g_pKeyboard->Acquire();
// nuke the garbage
if (!FAILED(hr)) {
//Bug 951: The following command really clears the garbage input.
//The original will still process keys in the buffer and was causing
//some problems.
win32.g_pKeyboard->GetDeviceData( sizeof(DIDEVICEOBJECTDATA), NULL, &dwElements, 0 );
dwElements = 0;
}
// hr may be DIERR_OTHERAPPHASPRIO or other errors. This
// may occur when the app is minimized or in the process of
// switching, so just try again later
}
if( FAILED(hr) ) {
return 0;
}
return dwElements;
}
#else
/*
====================
Sys_PollKeyboardInputEvents
Fake events by getting the entire device state
and checking transitions
====================
*/
int Sys_PollKeyboardInputEvents() {
HRESULT hr;
if( win32.g_pKeyboard == NULL ) {
return 0;
}
hr = win32.g_pKeyboard->GetDeviceState( sizeof( toggleFetch[ diFetch ] ), toggleFetch[ diFetch ] );
if( hr != DI_OK )
{
// We got an error or we got DI_BUFFEROVERFLOW.
//
// Either way, it means that continuous contact with the
// device has been lost, either due to an external
// interruption, or because the buffer overflowed
// and some events were lost.
hr = win32.g_pKeyboard->Acquire();
// nuke the garbage
if (!FAILED(hr)) {
hr = win32.g_pKeyboard->GetDeviceState( sizeof( toggleFetch[ diFetch ] ), toggleFetch[ diFetch ] );
}
// hr may be DIERR_OTHERAPPHASPRIO or other errors. This
// may occur when the app is minimized or in the process of
// switching, so just try again later
}
if( FAILED(hr) ) {
return 0;
}
// build faked events
int numChanges = 0;
for ( int i = 0 ; i < 256 ; i++ ) {
if ( toggleFetch[0][i] != toggleFetch[1][i] ) {
polled_didod[ numChanges ].dwOfs = i;
polled_didod[ numChanges ].dwData = toggleFetch[ diFetch ][i] ? 0x80 : 0;
numChanges++;
}
}
diFetch ^= 1;
return numChanges;
}
#endif
/*
====================
Sys_PollKeyboardInputEvents
====================
*/
int Sys_ReturnKeyboardInputEvent( const int n, int &ch, bool &state ) {
ch = polled_didod[ n ].dwOfs;
state = ( polled_didod[ n ].dwData & 0x80 ) == 0x80;
if ( ch == K_PRINTSCREEN || ch == K_LCTRL || ch == K_LALT || ch == K_RCTRL || ch == K_RALT ) {
// for windows, add a keydown event for print screen here, since
// windows doesn't send keydown events to the WndProc for this key.
// ctrl and alt are handled here to get around windows sending ctrl and
// alt messages when the right-alt is pressed on non-US 102 keyboards.
Sys_QueEvent( SE_KEY, ch, state, 0, NULL, 0 );
}
return ch;
}
void Sys_EndKeyboardInputEvents() {
}
//=====================================================================================
int Sys_PollMouseInputEvents( int mouseEvents[MAX_MOUSE_EVENTS][2] ) {
DWORD dwElements;
HRESULT hr;
if ( !win32.g_pMouse || !win32.mouseGrabbed ) {
return 0;
}
dwElements = DINPUT_BUFFERSIZE;
hr = win32.g_pMouse->GetDeviceData( sizeof(DIDEVICEOBJECTDATA), polled_didod, &dwElements, 0 );
if( hr != DI_OK ) {
hr = win32.g_pMouse->Acquire();
// clear the garbage
if (!FAILED(hr)) {
win32.g_pMouse->GetDeviceData( sizeof(DIDEVICEOBJECTDATA), polled_didod, &dwElements, 0 );
}
}
if( FAILED(hr) ) {
return 0;
}
if ( dwElements > MAX_MOUSE_EVENTS ) {
dwElements = MAX_MOUSE_EVENTS;
}
for( DWORD i = 0; i < dwElements; i++ ) {
mouseEvents[i][0] = M_INVALID;
mouseEvents[i][1] = 0;
if ( polled_didod[i].dwOfs >= DIMOFS_BUTTON0 && polled_didod[i].dwOfs <= DIMOFS_BUTTON7 ) {
const int mouseButton = ( polled_didod[i].dwOfs - DIMOFS_BUTTON0 );
const bool mouseDown = (polled_didod[i].dwData & 0x80) == 0x80;
mouseEvents[i][0] = M_ACTION1 + mouseButton;
mouseEvents[i][1] = mouseDown;
Sys_QueEvent( SE_KEY, K_MOUSE1 + mouseButton, mouseDown, 0, NULL, 0 );
} else {
switch (polled_didod[i].dwOfs) {
case DIMOFS_X:
mouseEvents[i][0] = M_DELTAX;
mouseEvents[i][1] = polled_didod[i].dwData;
Sys_QueEvent( SE_MOUSE, polled_didod[i].dwData, 0, 0, NULL, 0 );
break;
case DIMOFS_Y:
mouseEvents[i][0] = M_DELTAY;
mouseEvents[i][1] = polled_didod[i].dwData;
Sys_QueEvent( SE_MOUSE, 0, polled_didod[i].dwData, 0, NULL, 0 );
break;
case DIMOFS_Z:
mouseEvents[i][0] = M_DELTAZ;
mouseEvents[i][1] = (int)polled_didod[i].dwData / WHEEL_DELTA;
{
const int value = (int)polled_didod[i].dwData / WHEEL_DELTA;
const int key = value < 0 ? K_MWHEELDOWN : K_MWHEELUP;
const int iterations = abs( value );
for ( int i = 0; i < iterations; i++ ) {
Sys_QueEvent( SE_KEY, key, true, 0, NULL, 0 );
Sys_QueEvent( SE_KEY, key, false, 0, NULL, 0 );
}
}
break;
}
}
}
return dwElements;
}
//=====================================================================================
// Joystick Input Handling
//=====================================================================================
void Sys_SetRumble( int device, int low, int hi ) {
return win32.g_Joystick.SetRumble( device, low, hi );
}
int Sys_PollJoystickInputEvents( int deviceNum ) {
return win32.g_Joystick.PollInputEvents( deviceNum );
}
int Sys_ReturnJoystickInputEvent( const int n, int &action, int &value ) {
return win32.g_Joystick.ReturnInputEvent( n, action, value );
}
void Sys_EndJoystickInputEvents() {
}
/*
========================
JoystickSamplingThread
========================
*/
static int threadTimeDeltas[256];
static int threadPacket[256];
static int threadCount;
void JoystickSamplingThread( void *data ) {
static int prevTime = 0;
static uint64 nextCheck[MAX_JOYSTICKS] = { 0 };
const uint64 waitTime = 5000000; // poll every 5 seconds to see if a controller was connected
while( 1 ) {
// hopefully we see close to 4000 usec each loop
int now = Sys_Microseconds();
int delta;
if ( prevTime == 0 ) {
delta = 4000;
} else {
delta = now - prevTime;
}
prevTime = now;
threadTimeDeltas[threadCount&255] = delta;
threadCount++;
{
XINPUT_STATE joyData[MAX_JOYSTICKS];
bool validData[MAX_JOYSTICKS];
for ( int i = 0 ; i < MAX_JOYSTICKS ; i++ ) {
if ( now >= nextCheck[i] ) {
// XInputGetState might block... for a _really_ long time..
validData[i] = XInputGetState( i, &joyData[i] ) == ERROR_SUCCESS;
// allow an immediate data poll if the input device is connected else
// wait for some time to see if another device was reconnected.
// Checking input state infrequently for newly connected devices prevents
// severe slowdowns on PC, especially on WinXP64.
if ( validData[i] ) {
nextCheck[i] = 0;
} else {
nextCheck[i] = now + waitTime;
}
}
}
// do this short amount of processing inside a critical section
idScopedCriticalSection cs( win32.g_Joystick.mutexXis );
for ( int i = 0 ; i < MAX_JOYSTICKS ; i++ ) {
controllerState_t * cs = &win32.g_Joystick.controllers[i];
if ( !validData[i] ) {
cs->valid = false;
continue;
}
cs->valid = true;
XINPUT_STATE& current = joyData[i];
cs->current = current;
// Switch from using cs->current to current to reduce chance of Load-Hit-Store on consoles
threadPacket[threadCount&255] = current.dwPacketNumber;
#if 0
if ( xis.dwPacketNumber == oldXis[ inputDeviceNum ].dwPacketNumber ) {
return numEvents;
}
#endif
cs->buttonBits |= current.Gamepad.wButtons;
}
}
// we want this to be processed at least 250 times a second
WaitForSingleObject( win32.g_Joystick.timer, INFINITE );
}
}
/*
========================
idJoystickWin32::idJoystickWin32
========================
*/
idJoystickWin32::idJoystickWin32() {
numEvents = 0;
memset( &events, 0, sizeof( events ) );
memset( &controllers, 0, sizeof( controllers ) );
memset( buttonStates, 0, sizeof( buttonStates ) );
memset( joyAxis, 0, sizeof( joyAxis ) );
}
/*
========================
idJoystickWin32::Init
========================
*/
bool idJoystickWin32::Init() {
idJoystick::Init();
// setup the timer that the high frequency thread will wait on
// to fire every 4 msec
timer = CreateWaitableTimer( NULL, FALSE, "JoypadTimer" );
LARGE_INTEGER dueTime;
dueTime.QuadPart = -1;
if ( !SetWaitableTimer( timer, &dueTime, 4, NULL, NULL, FALSE ) ) {
idLib::FatalError( "SetWaitableTimer for joystick failed" );
}
// spawn the high frequency joystick reading thread
Sys_CreateThread( (xthread_t)JoystickSamplingThread, NULL, THREAD_HIGHEST, "Joystick", CORE_1A );
return false;
}
/*
========================
idJoystickWin32::SetRumble
========================
*/
void idJoystickWin32::SetRumble( int inputDeviceNum, int rumbleLow, int rumbleHigh ) {
if ( inputDeviceNum < 0 || inputDeviceNum >= MAX_JOYSTICKS ) {
return;
}
if ( !controllers[inputDeviceNum].valid ) {
return;
}
XINPUT_VIBRATION vibration;
vibration.wLeftMotorSpeed = idMath::ClampInt( 0, 65535, rumbleLow );
vibration.wRightMotorSpeed = idMath::ClampInt( 0, 65535, rumbleHigh );
DWORD err = XInputSetState( inputDeviceNum, &vibration );
if ( err != ERROR_SUCCESS ) {
idLib::Warning( "XInputSetState error: 0x%x", err );
}
}
/*
========================
idJoystickWin32::PostInputEvent
========================
*/
void idJoystickWin32::PostInputEvent( int inputDeviceNum, int event, int value, int range ) {
// These events are used for GUI button presses
if ( ( event >= J_ACTION1 ) && ( event <= J_ACTION_MAX ) ) {
PushButton( inputDeviceNum, K_JOY1 + ( event - J_ACTION1 ), value != 0 );
} else if ( event == J_AXIS_LEFT_X ) {
PushButton( inputDeviceNum, K_JOY_STICK1_LEFT, ( value < -range ) );
PushButton( inputDeviceNum, K_JOY_STICK1_RIGHT, ( value > range ) );
} else if ( event == J_AXIS_LEFT_Y ) {
PushButton( inputDeviceNum, K_JOY_STICK1_UP, ( value < -range ) );
PushButton( inputDeviceNum, K_JOY_STICK1_DOWN, ( value > range ) );
} else if ( event == J_AXIS_RIGHT_X ) {
PushButton( inputDeviceNum, K_JOY_STICK2_LEFT, ( value < -range ) );
PushButton( inputDeviceNum, K_JOY_STICK2_RIGHT, ( value > range ) );
} else if ( event == J_AXIS_RIGHT_Y ) {
PushButton( inputDeviceNum, K_JOY_STICK2_UP, ( value < -range ) );
PushButton( inputDeviceNum, K_JOY_STICK2_DOWN, ( value > range ) );
} else if ( ( event >= J_DPAD_UP ) && ( event <= J_DPAD_RIGHT ) ) {
PushButton( inputDeviceNum, K_JOY_DPAD_UP + ( event - J_DPAD_UP ), value != 0 );
} else if ( event == J_AXIS_LEFT_TRIG ) {
PushButton( inputDeviceNum, K_JOY_TRIGGER1, ( value > range ) );
} else if ( event == J_AXIS_RIGHT_TRIG ) {
PushButton( inputDeviceNum, K_JOY_TRIGGER2, ( value > range ) );
}
if ( event >= J_AXIS_MIN && event <= J_AXIS_MAX ) {
int axis = event - J_AXIS_MIN;
int percent = ( value * 16 ) / range;
if ( joyAxis[inputDeviceNum][axis] != percent ) {
joyAxis[inputDeviceNum][axis] = percent;
Sys_QueEvent( SE_JOYSTICK, axis, percent, 0, NULL, inputDeviceNum );
}
}
// These events are used for actual game input
events[numEvents].event = event;
events[numEvents].value = value;
numEvents++;
}
/*
========================
idJoystickWin32::PollInputEvents
========================
*/
int idJoystickWin32::PollInputEvents( int inputDeviceNum ) {
numEvents = 0;
if ( !win32.activeApp ) {
return numEvents;
}
assert( inputDeviceNum < 4 );
// if ( inputDeviceNum > in_joystick.GetInteger() ) {
// return numEvents;
// }
controllerState_t *cs = &controllers[ inputDeviceNum ];
// grab the current packet under a critical section
XINPUT_STATE xis;
XINPUT_STATE old;
int orBits;
{
idScopedCriticalSection crit( mutexXis );
xis = cs->current;
old = cs->previous;
cs->previous = xis;
// fetch or'd button bits
orBits = cs->buttonBits;
cs->buttonBits = 0;
}
#if 0
if ( XInputGetState( inputDeviceNum, &xis ) != ERROR_SUCCESS ) {
return numEvents;
}
#endif
for ( int i = 0 ; i < 32 ; i++ ) {
int bit = 1<IsSystemUIShowing() ) {
// memset xis so the current input does not get latched if the UI is showing
memset( &xis, 0, sizeof( XINPUT_STATE ) );
}
int joyRemap[16] = {
J_DPAD_UP, J_DPAD_DOWN, // Up, Down
J_DPAD_LEFT, J_DPAD_RIGHT, // Left, Right
J_ACTION9, J_ACTION10, // Start, Back
J_ACTION7, J_ACTION8, // Left Stick Down, Right Stick Down
J_ACTION5, J_ACTION6, // Black, White (Left Shoulder, Right Shoulder)
0, 0, // Unused
J_ACTION1, J_ACTION2, // A, B
J_ACTION3, J_ACTION4, // X, Y
};
// Check the digital buttons
for ( int i = 0; i < 16; i++ ) {
int mask = ( 1 << i );
if ( ( xis.Gamepad.wButtons & mask ) != ( old.Gamepad.wButtons & mask ) ) {
PostInputEvent( inputDeviceNum, joyRemap[i], ( xis.Gamepad.wButtons & mask ) > 0 );
}
}
// Check the triggers
if ( xis.Gamepad.bLeftTrigger != old.Gamepad.bLeftTrigger ) {
PostInputEvent( inputDeviceNum, J_AXIS_LEFT_TRIG, xis.Gamepad.bLeftTrigger * 128 );
}
if ( xis.Gamepad.bRightTrigger != old.Gamepad.bRightTrigger ) {
PostInputEvent( inputDeviceNum, J_AXIS_RIGHT_TRIG, xis.Gamepad.bRightTrigger * 128 );
}
if ( xis.Gamepad.sThumbLX != old.Gamepad.sThumbLX ) {
PostInputEvent( inputDeviceNum, J_AXIS_LEFT_X, xis.Gamepad.sThumbLX );
}
if ( xis.Gamepad.sThumbLY != old.Gamepad.sThumbLY ) {
PostInputEvent( inputDeviceNum, J_AXIS_LEFT_Y, -xis.Gamepad.sThumbLY );
}
if ( xis.Gamepad.sThumbRX != old.Gamepad.sThumbRX ) {
PostInputEvent( inputDeviceNum, J_AXIS_RIGHT_X, xis.Gamepad.sThumbRX );
}
if ( xis.Gamepad.sThumbRY != old.Gamepad.sThumbRY ) {
PostInputEvent( inputDeviceNum, J_AXIS_RIGHT_Y, -xis.Gamepad.sThumbRY );
}
return numEvents;
}
/*
========================
idJoystickWin32::ReturnInputEvent
========================
*/
int idJoystickWin32::ReturnInputEvent( const int n, int & action, int &value ) {
if ( ( n < 0 ) || ( n >= MAX_JOY_EVENT ) ) {
return 0;
}
action = events[ n ].event;
value = events[ n ].value;
return 1;
}
/*
========================
idJoystickWin32::PushButton
========================
*/
void idJoystickWin32::PushButton( int inputDeviceNum, int key, bool value ) {
// So we don't keep sending the same SE_KEY message over and over again
if ( buttonStates[inputDeviceNum][key] != value ) {
buttonStates[inputDeviceNum][key] = value;
Sys_QueEvent( SE_KEY, key, value, 0, NULL, inputDeviceNum );
}
}