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windows-nt/Source/XPSP1/NT/multimedia/directx/dinput/dx8/dll/digenj.c
CryptoAlgo Inc b3cac27891 Add source files
2020-09-26 16:20:57 +08:00

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/*****************************************************************************
*
* DIGenJ.c
*
* Copyright (c) 1996 - 2000 Microsoft Corporation. All Rights Reserved.
*
* Abstract:
*
* Generic IDirectInputDevice callback for joystick.
*
* Contents:
*
* CJoy_CreateInstance
*
*****************************************************************************/
#include "dinputpr.h"
#ifndef WINNT
/*****************************************************************************
*
* The sqiffle for this file.
*
*****************************************************************************/
#define sqfl sqflJoy
/*****************************************************************************
*
* Declare the interfaces we will be providing.
*
* WARNING! If you add a secondary interface, you must also change
* CJoy_New!
*
*****************************************************************************/
Primary_Interface(CJoy, IDirectInputDeviceCallback);
/*****************************************************************************
*
* Macro "lookup tables".
*
* iJoyStateAxis# converts an axis name to an axis number in the
* DIJOYSTATE structure.
*
* ibJoyStateAxis# converts the name to an offset.
*
* Note that the extra axes in DIJOYSTATE2 are arranged in relative
* positions just like a DIJOYSTATE. We will exploit this
* arrangement frequently.
*
*****************************************************************************/
#define iJoyStateAxisX 0
#define iJoyStateAxisY 1
#define iJoyStateAxisZ 2
#define iJoyStateAxisRx 3
#define iJoyStateAxisRy 4
#define iJoyStateAxisRz 5
#define iJoyStateAxisS0 6
#define iJoyStateAxisS1 7
#define cJoyStateAxisMax 8
#define iJoyStateAxisSlider iJoyStateAxisS0 /* Hack for macros */
#define cJoyStateAxis 8
#define iobjPositions (cJoyStateAxis * 0)
#define iobjVelocities (cJoyStateAxis * 1)
#define iobjAccels (cJoyStateAxis * 2)
#define iobjForces (cJoyStateAxis * 3)
#define cJoyStateAxisTotal (cJoyStateAxis * 4)
#define ibJoyStateAxisX (iJoyStateAxisX * cbX(LONG))
#define ibJoyStateAxisY (iJoyStateAxisY * cbX(LONG))
#define ibJoyStateAxisZ (iJoyStateAxisZ * cbX(LONG))
#define ibJoyStateAxisRx (iJoyStateAxisRx * cbX(LONG))
#define ibJoyStateAxisRy (iJoyStateAxisRy * cbX(LONG))
#define ibJoyStateAxisRz (iJoyStateAxisRz * cbX(LONG))
#define ibJoyStateAxisS0 (iJoyStateAxisS0 * cbX(LONG))
#define ibJoyStateAxisS1 (iJoyStateAxisS1 * cbX(LONG))
#define ibJoyStateAxisSlider ibJoyStateAxisS0 /* Hack for macros */
#define cJoyStatePOVTotal 4
#define cJoyStateButtonTotal 128
#define cJoyStateObjTotal (cJoyStateAxisTotal + \
cJoyStatePOVTotal + \
cJoyStateButtonTotal)
/*
* The worst-case data format for joysticks. (Christmas-tree)
*/
VXDAXISCAPS c_vacMax = {
JOYPF_ALLCAPS | JOYPF_POSITION, /* dwPos */
JOYPF_ALLCAPS | JOYPF_VELOCITY, /* dwVel */
JOYPF_ALLCAPS | JOYPF_ACCELERATION, /* dwAccel */
JOYPF_ALLCAPS | JOYPF_FORCE, /* dwForce */
};
/*****************************************************************************
*
* @doc INTERNAL
*
* @func UINT | ibJoyStateAxisFromPosAxis |
*
* Returns the offset of the <p iPosAxis>'th joystick axis
* in the <t DIJOYSTATE> structure.
*
* @parm UINT | uiStateAxis |
*
* The index of the requested <t JOYPOS> axis.
* X, Y, Z, R, U and V are respectively zero through five.
*
* Remember that we map R to Rz, U to Slider0 and V to Slider1.
*
* @returns
*
* The offset relative to the structure.
*
*****************************************************************************/
const int c_rgibJoyStateAxisFromPosAxis[6] = {
FIELD_OFFSET(DIJOYSTATE, lX), /* X */
FIELD_OFFSET(DIJOYSTATE, lY), /* Y */
FIELD_OFFSET(DIJOYSTATE, lZ), /* Z */
FIELD_OFFSET(DIJOYSTATE, lRz), /* R */
FIELD_OFFSET(DIJOYSTATE, rglSlider[0]), /* U */
FIELD_OFFSET(DIJOYSTATE, rglSlider[1]), /* V */
};
UINT INLINE
ibJoyStateAxisFromPosAxis(UINT uiPosAxis)
{
AssertF(uiPosAxis < cA(c_rgibJoyStateAxisFromPosAxis));
return c_rgibJoyStateAxisFromPosAxis[uiPosAxis];
}
/*****************************************************************************
*
* @doc INTERNAL
*
* @func UINT | iJoyStateAxisFromPosAxis |
*
* Returns the index of the <p iPosAxis>'th joystick axis
* in the <t DIJOYSTATE> structure.
*
* @parm UINT | uiStateAxis |
*
* The index of the requested <t JOYPOS> axis.
* X, Y, Z, R, U and V are respectively zero through five.
*
* Remember that we map R to Rz, U to Slider0 and V to Slider1.
*
* @returns
*
* The offset relative to the structure.
*
*****************************************************************************/
const int c_rgiJoyStateAxisFromPosAxis[6] = {
iJoyStateAxisX, /* X */
iJoyStateAxisY, /* Y */
iJoyStateAxisZ, /* Z */
iJoyStateAxisRz, /* R */
iJoyStateAxisS0, /* U */
iJoyStateAxisS1, /* V */
};
UINT INLINE
iJoyStateAxisFromPosAxis(UINT uiPosAxis)
{
AssertF(uiPosAxis < cA(c_rgiJoyStateAxisFromPosAxis));
return c_rgiJoyStateAxisFromPosAxis[uiPosAxis];
}
/*****************************************************************************
*
* @doc INTERNAL
*
* @func UINT | ibJoyStateAxisFromStateAxis |
*
* Returns the offset of the <p iStateAxis>'th joystick axis
* in the <t DIJOYSTATE> structure.
*
* @parm UINT | uiStateAxis |
*
* The index of the requested <t JOYSTATE> axis.
* The first eight axes live at the top, and the
* later ones (corresponding to velocity, etc.)
* live down at the bottom.
*
* @returns
*
* The offset relative to the structure.
*
*****************************************************************************/
const int c_rgibJoyStateAxisFromStateAxis[cJoyStateAxisMax] = {
FIELD_OFFSET(DIJOYSTATE, lX), /* X */
FIELD_OFFSET(DIJOYSTATE, lY), /* Y */
FIELD_OFFSET(DIJOYSTATE, lZ), /* Z */
FIELD_OFFSET(DIJOYSTATE, lRx), /* Rx */
FIELD_OFFSET(DIJOYSTATE, lRy), /* Ry */
FIELD_OFFSET(DIJOYSTATE, lRz), /* Rz */
FIELD_OFFSET(DIJOYSTATE, rglSlider[0]), /* S0 */
FIELD_OFFSET(DIJOYSTATE, rglSlider[1]), /* S1 */
};
UINT INLINE
ibJoyStateAxisFromStateAxis(UINT uiStateAxis)
{
AssertF(uiStateAxis < cA(c_rgibJoyStateAxisFromStateAxis));
return c_rgibJoyStateAxisFromStateAxis[uiStateAxis];
}
/*****************************************************************************
*
* @doc INTERNAL
*
* @func UINT | iJoyPosAxisFromStateAxis |
*
* Convert a <t DIJOYSTATE> axis number back to
* a <t JOYPOS> axis number.
*
* @parm UINT | uiPosAxis |
*
* The index of the requested <t JOYSTATE> axis.
*
* @returns
*
* The corresponding <t JOYPOS> axis number.
*
*****************************************************************************/
const int c_rgiJoyPosAxisFromStateAxis[8] = {
iJoyPosAxisX, /* X */
iJoyPosAxisY, /* Y */
iJoyPosAxisZ, /* Z */
-1, /* Rx */
-1, /* Ry */
iJoyPosAxisR, /* Rz */
iJoyPosAxisU, /* S0 */
iJoyPosAxisV, /* S1 */
};
UINT INLINE
iJoyPosAxisFromStateAxis(UINT uiStateAxis)
{
AssertF(uiStateAxis < cA(c_rgiJoyPosAxisFromStateAxis));
return c_rgiJoyPosAxisFromStateAxis[uiStateAxis];
}
/*****************************************************************************
*
* @doc INTERNAL
*
* @topic Cooking Joystick Data |
*
* We always fetch joystick data raw, then cook it before
* returning it to the application.
*
* If the app is in "raw" mode, then we don't cook anything.
*
* If the app is in "cooked" mode, then things get interesting.
*
* If there is `centered' cooking, then the center point of the
* joystick is reported in the center of the virtual range.
*
*
* Joystick properties work like this:
*
* <c DIPROP_BUFFERSIZE> - No special semantics.
*
* <c DIPROP_CALIBRATIONMODE> - Specifies whether
* cooked or raw data should be returned. If raw data
* is requested, then most other properties have no effect.
*
* The default is cooked.
*
* <c DIPROP_GRANULARITY> - No special semantics.
*
* <c DIPROP_RANGE> - This returns the range of values that
* can be returned by the axis. For joysticks, this is a
* read/write property. (For most devices, it is a read-only
* property.) If you change the property, it affects only
* your device instance; it does not affect the ranges of other
* devices.
*
* If the axis is in calibration mode, then setting this value
* has no immediate effect.
*
* We also define a few new properties:
*
* <c DIPROP_CENTER> - This returns the joystick center (neutral)
* position. In other words, this is the position that
* DirectInput returns when the user has released the joystick
* and allowed it to self-center.
* When a joystick device is created, the center position is
* initially set to midway between the lower and
* upper bounds of the range. An application may change the
* center position (although I don't see any reason why).
*
* If the axis is in calibration mode, then setting this value
* has no immediate effect.
*
* <c DIPROP_DEADZONE> - This returns the size of the joystick
* dead zone, as a percentage of total range.
*
* If the axis is in calibration mode, then setting this value
* has no immediate effect.
*
*****************************************************************************/
/*****************************************************************************
*
* @doc INTERNAL
*
* @struct CJoy |
*
* The <i IDirectInputDeviceCallback> object for the
* generic joystick.
*
* @field IDirectInputDeviceCallback | didc |
*
* The object (containing vtbl).
*
* @field PDIJOYSTATE2 | pjsPhys |
*
* Pointer to physical joystick status information kept down in the
* VxD.
*
* @field UINT | idJoy |
*
* Joystick identifier for <f joyGetPosEx> and friends.
*
* @field DWORD | dwPOVGranularity |
*
* Granularity of the POV control.
*
* @field HWND | hwnd |
*
* The window which we have subclassed in order to watch
* for joystick reconfiguration messages.
*
* @field HKEY | hkType |
*
* The joystick type key opened with <c MAXIMUM_ALLOWED> access.
*
* @field VXDINSTANCE * | pvi |
*
* The DirectInput instance handle.
*
* @field DIDEVCAPS | dc |
*
* Device capability information.
*
* @field DIDATAFORMAT | df |
*
* The dynamically-generated data format based on the
* joystick type.
*
* @field JOYRANGECONVERT | rgjrc |
*
* Range conversion structures for each axis.
*
* @field DIJOYCONFIG | cfg |
*
* Joystick configuration information.
*
* @field DIJOYTYPEINFO | typi |
*
* Joystick type information.
*
* @field PDIDOBJDEFSEM | rgObjSem |
*
* Pointer to array of semantics mapped to this device,
* calculated during init.
*
* @field DWORD | dwVersion |
*
* DirectInput version requested by application
*
* @field DIAPPHACKS | diHacks |
*
* Application hack flags
*
* @field HKEY | hkProp |
*
* Extended properties for device type. Currently we keep
* OEMMapFile under this key.
*
* @comm
*
* It is the caller's responsibility to serialize access as
* necessary.
*
*****************************************************************************/
typedef struct CJoy {
/* Supported interfaces */
IDirectInputDeviceCallback dcb;
LPDIJOYSTATE2 pjsPhys;
UINT idJoy;
DWORD dwPOVGranularity;
HWND hwnd;
HKEY hkType;
VXDINSTANCE *pvi;
DIDEVCAPS dc;
DIDATAFORMAT df;
JOYRANGECONVERT rgjrc[cJoyStateAxisMax];
DIJOYCONFIG cfg;
DIJOYTYPEINFO typi;
PDIDOBJDEFSEM rgObjSem;
DWORD dwVersion;
DIAPPHACKS diHacks;
HKEY hkProp;
} CJoy, DJ, *PDJ;
#define ThisClass CJoy
#define ThisInterface IDirectInputDeviceCallback
#define riidExpected &IID_IDirectInputDeviceCallback
/*****************************************************************************
*
* Forward declarations
*
* These are out of laziness, not out of necessity.
*
*****************************************************************************/
STDMETHODIMP CJoy_GetFFConfigKey(PDICB pdcb, DWORD sam, PHKEY phk);
void INTERNAL CJoy_InitPhysRanges(PDJ this, LPJOYREGHWCONFIG phwc);
LRESULT CALLBACK
CJoy_SubclassProc(HWND hwnd, UINT wm, WPARAM wp, LPARAM lp,
UINT uid, ULONG_PTR dwRef);
/*****************************************************************************
*
* CJoy::QueryInterface (from IUnknown)
* CJoy::AddRef (from IUnknown)
* CJoy::Release (from IUnknown)
*
*****************************************************************************/
/*****************************************************************************
*
* @doc INTERNAL
*
* @method HRESULT | CJoy | QueryInterface |
*
* Gives a client access to other interfaces on an object.
*
* @parm IN REFIID | riid |
*
* The requested interface's IID.
*
* @parm OUT LPVOID * | ppvObj |
*
* Receives a pointer to the obtained interface.
*
* @returns
*
* Returns a COM error code.
*
* @xref OLE documentation for <mf IUnknown::QueryInterface>.
*
*****************************************************************************
*
* @doc INTERNAL
*
* @method HRESULT | CJoy | AddRef |
*
* Increments the reference count for the interface.
*
* @returns
*
* Returns the object reference count.
*
* @xref OLE documentation for <mf IUnknown::AddRef>.
*
*****************************************************************************
*
* @doc INTERNAL
*
* @method HRESULT | CJoy | Release |
*
* Decrements the reference count for the interface.
* If the reference count on the object falls to zero,
* the object is freed from memory.
*
* @returns
*
* Returns the object reference count.
*
* @xref OLE documentation for <mf IUnknown::Release>.
*
*****************************************************************************
*
* @doc INTERNAL
*
* @method HRESULT | CJoy | QIHelper |
*
* We don't have any dynamic interfaces and simply forward
* to <f Common_QIHelper>.
*
* @parm IN REFIID | riid |
*
* The requested interface's IID.
*
* @parm OUT LPVOID * | ppvObj |
*
* Receives a pointer to the obtained interface.
*
*****************************************************************************
*
* @doc INTERNAL
*
* @method HRESULT | CJoy | AppFinalize |
*
* We don't have any weak pointers, so we can just
* forward to <f Common_Finalize>.
*
* @parm PV | pvObj |
*
* Object being released from the application's perspective.
*
*****************************************************************************/
#ifdef DEBUG
Default_QueryInterface(CJoy)
Default_AddRef(CJoy)
Default_Release(CJoy)
#else
#define CJoy_QueryInterface Common_QueryInterface
#define CJoy_AddRef Common_AddRef
#define CJoy_Release Common_Release
#endif
#define CJoy_QIHelper Common_QIHelper
/*****************************************************************************
*
* @doc INTERNAL
*
* @method void | CJoy | RemoveSubclass |
*
* Remove our subclass hook on the window.
*
* The parameter is intentionally misdeclared as a <t PV>
* so that this function can double as the <f CJoy_AppFinalize>.
*
*****************************************************************************/
void INTERNAL
CJoy_RemoveSubclass(PV pvObj)
{
PDJ this = pvObj;
/*
* If there was an old window, then un-subclass it
* and release the hold associated with it.
*
* You might think that there's a race condition here, where
* we might unhold the device while the subclass procedure is
* still using it.
*
* Ah, but that's not a problem, because the only message that
* the subclass procedure cares about is the joystick
* reconfiguration message, and when it is processing that message,
* it does its own artificial hold/unhold to keep the device alive
* while it dorks on the device.
*
* Okay, so there *is* a really tiny race condition where we
* might nuke the device while the window procedure is studying
* the message to decide whether it cares or not.
*
* Since that is so extremely rare, we close that window by
* hacking it: We revalidate the device before partying on it.
* Note that the hack is not perfect, but the race window becomes
* only a few instructions long that I'm not going to worry about it.
*
* By wiping out this->hwnd before removing the subclass, we
* can reduce the window to very small indeed.
*/
if (this->hwnd) {
HWND hwnd = this->hwnd;
this->hwnd = 0;
if (!RemoveWindowSubclass(hwnd, CJoy_SubclassProc, 0)) {
/*
* The RemoveWindowSubclass can fail if the window
* was destroyed behind our back.
*/
// AssertF(!IsWindow(hwnd));
}
Sleep(0); /* Let the worker thread drain */
Common_Unhold(this);
}
}
/*****************************************************************************
*
* @doc INTERNAL
*
* @func void | CJoy_Finalize |
*
* Releases the resources of the device.
*
* @parm PV | pvObj |
*
* Object being released. Note that it may not have been
* completely initialized, so everything should be done
* carefully.
*
*****************************************************************************/
void INTERNAL
CJoy_Finalize(PV pvObj)
{
PDJ this = pvObj;
if (this->pvi) {
HRESULT hres;
hres = Hel_DestroyInstance(this->pvi);
AssertF(SUCCEEDED(hres));
FreePpv(&this->df.rgodf);
FreePpv(&this->rgObjSem );
if (this->hkType) {
RegCloseKey(this->hkType);
}
if( this->hkProp) {
RegCloseKey(this->hkProp);
}
}
}
/*****************************************************************************
*
* @doc INTERNAL
*
* @func void | CJoy_AppFinalize |
*
* The application has performed its final release.
* Remove our window subclass at this point.
*
* @parm PV | pvObj |
*
* Object being released. Note that it may not have been
* completely initialized, so everything should be done
* carefully.
*
*****************************************************************************/
#define CJoy_AppFinalize CJoy_RemoveSubclass
/*****************************************************************************
*
* @doc INTERNAL
*
* @func LRESULT | CJoy_SubclassProc |
*
* Window subclass procedure which watches for
* joystick configuration change notifications.
*
* @parm HWND | hwnd |
*
* The victim window.
*
* @parm UINT | wm |
*
* Window message.
*
* @parm WPARAM | wp |
*
* Message-specific data.
*
* @parm LPARAM | lp |
*
* Message-specific data.
*
* @parm UINT | uid |
*
* Callback identification number, always zero.
*
* @parm DWORD | dwRef |
*
* Reference data, a pointer to our joystick device callback.
*
*****************************************************************************/
LRESULT CALLBACK
CJoy_SubclassProc(HWND hwnd, UINT wm, WPARAM wp, LPARAM lp,
UINT uid, ULONG_PTR dwRef)
{
#ifdef XDEBUG
static CHAR s_szProc[] = "";
#endif
AssertF(uid == 0);
if (wm == g_wmJoyChanged) {
PDJ this = (PDJ)dwRef;
/*
* Wacky subtlety going on here to avoid race conditions.
* See the mondo comment block in CJoy_RemoveSubclass
* for details.
*
* We can get faked out if the memory associated with the
* CJoy is still physically allocated, the vtbl is magically
* still there and the hwnd field somehow matches our hwnd.
*/
if (SUCCEEDED(hresPv(this)) && this->hwnd == hwnd) {
HRESULT hres;
Common_Hold(this);
/*
* We must ask for DIJC_CALLOUT even though we don't care,
* because that will trigger the Microsoft Gamepad hack-o-rama.
*
* Also, make sure we don't decide that we tried recently
*/
#ifndef WINNT
g_dwLastBonusPoll = GetTickCount() ^ 0x80000000;
#endif
hres = JoyReg_GetConfig(this->idJoy, &this->cfg,
DIJC_REGHWCONFIGTYPE | DIJC_CALLOUT);
if (SUCCEEDED(hres)) {
CJoy_InitPhysRanges(this, &this->cfg.hwc);
}
Common_Unhold(this);
}
}
return DefSubclassProc(hwnd, wm, wp, lp);
}
/*****************************************************************************
*
* @doc INTERNAL
*
* @method HRESULT | CJoy | GetInstance |
*
* Obtains the DirectInput instance handle.
*
* @parm OUT PPV | ppvi |
*
* Receives the instance handle.
*
*****************************************************************************/
STDMETHODIMP
CJoy_GetInstance(PDICB pdcb, PPV ppvi)
{
HRESULT hres;
PDJ this;
EnterProcI(IDirectInputDeviceCallback::Joy::GetInstance, (_ "p", pdcb));
/*
* This is an internal interface, so we can skimp on validation.
*/
this = _thisPvNm(pdcb, dcb);
*ppvi = (PV)this->pvi;
hres = S_OK;
ExitOleProcPpvR(ppvi);
return hres;
}
/*****************************************************************************
*
* @doc INTERNAL
*
* @method HRESULT | CJoy | GetDataFormat |
*
* Obtains the device's preferred data format.
*
* @parm OUT LPDIDEVICEFORMAT * | ppdf |
*
* <t LPDIDEVICEFORMAT> to receive pointer to device format.
*
* @returns
*
* Returns a COM error code. The following error codes are
* intended to be illustrative and not necessarily comprehensive.
*
* <c DI_OK> = <c S_OK>: The operation completed successfully.
*
* <c DIERR_INVALIDPARAM> = <c E_INVALIDARG>: The
* <p lpmdr> parameter is not a valid pointer.
*
*****************************************************************************/
STDMETHODIMP
CJoy_GetDataFormat(PDICB pdcb, LPDIDATAFORMAT *ppdf)
{
HRESULT hres;
PDJ this;
EnterProcI(IDirectInputDeviceCallback::Joy::GetDataFormat,
(_ "p", pdcb));
/*
* This is an internal interface, so we can skimp on validation.
*/
this = _thisPvNm(pdcb, dcb);
*ppdf = &this->df;
hres = S_OK;
ExitOleProcPpvR(ppdf);
return hres;
}
/*****************************************************************************
*
* @doc INTERNAL
*
* @method HRESULT | CJoy | GetDeviceInfo |
*
* Obtain general information about the device.
*
* @parm OUT LPDIDEVICEINSTANCEW | pdiW |
*
* <t DEVICEINSTANCE> to be filled in. The
* <e DEVICEINSTANCE.dwSize> and <e DEVICEINSTANCE.guidInstance>
* have already been filled in.
*
* Secret convenience: <e DEVICEINSTANCE.guidProduct> is equal
* to <e DEVICEINSTANCE.guidInstance>.
*
*****************************************************************************/
STDMETHODIMP
CJoy_GetDeviceInfo(PDICB pdcb, LPDIDEVICEINSTANCEW pdiW)
{
HRESULT hres;
PDJ this;
EnterProcI(IDirectInputDeviceCallback::Joy::GetDeviceInfo,
(_ "pp", pdcb, pdiW));
/*
* This is an internal interface, so we can skimp on validation.
*/
this = _thisPvNm(pdcb, dcb);
AssertF(IsValidSizeDIDEVICEINSTANCEW(pdiW->dwSize));
/*
* Unlike mouse and keyboard, there can be multiple instances of
* the same joystick product, so we can't just leave guidProduct
* equal to guidInstance.
*/
pdiW->guidProduct = GUID_Joystick;
AssertF(pdiW->guidInstance.Data1 ==
(pdiW->guidProduct.Data1 | this->idJoy));
pdiW->dwDevType = this->dc.dwDevType;
#ifdef UNICODE
lstrcpyn(pdiW->tszProductName, this->typi.wszDisplayName,
cA(pdiW->tszProductName));
#else
CAssertF(cA(pdiW->tszProductName) >= cA(this->typi.wszDisplayName));
CopyMemory(pdiW->tszProductName, this->typi.wszDisplayName,
cbX(this->typi.wszDisplayName));
#endif
/*
* Since we use HID path, there is no meaning to distinguish
* the devices by using "Joystick x" name.
* We'd better use the same DisplayName for InstanceName.
* Shall we do this?
*
LoadString(g_hinst, IDS_STDJOYSTICK, tszFormat, cA(tszFormat));
#ifdef UNICODE
wsprintf(pdiW->tszInstanceName, tszFormat, this->idJoy + 1);
#else
wsprintf(tszName, tszFormat, this->idJoy + 1);
AToU(pdiW->tszInstanceName, cA(pdiW->tszInstanceName), tszName);
#endif
*/
#ifdef UNICODE
lstrcpyn(pdiW->tszInstanceName, this->typi.wszDisplayName,
cA(pdiW->tszInstanceName));
#else
CAssertF(cA(pdiW->tszInstanceName) >= cA(this->typi.wszDisplayName));
CopyMemory(pdiW->tszInstanceName, this->typi.wszDisplayName,
cbX(this->typi.wszDisplayName));
#endif
if (pdiW->dwSize >= cbX(DIDEVICEINSTANCE_DX5W)) {
HKEY hkFF;
/*
* If there is a force feedback driver, then fetch the driver CLSID
* as the FF GUID.
*/
hres = CJoy_GetFFConfigKey(pdcb, KEY_QUERY_VALUE, &hkFF);
if (SUCCEEDED(hres)) {
LONG lRc;
TCHAR tszClsid[ctchGuid];
lRc = RegQueryString(hkFF, TEXT("CLSID"), tszClsid, cA(tszClsid));
if (lRc == ERROR_SUCCESS &&
ParseGUID(&pdiW->guidFFDriver, tszClsid)) {
} else {
ZeroX(pdiW->guidFFDriver);
}
RegCloseKey(hkFF);
}
}
hres = S_OK;
ExitOleProcR();
return hres;
}
/*****************************************************************************
*
* @doc INTERNAL
*
* @method void | CJoy | SetAxisProperty |
*
* If the request is to set a property on the device,
* then convert it into separate requests, one for each
* axis.
*
* @parm PDJ | this |
*
* The device object.
*
* @parm GETSETJOYPROP | GetSetJoyProp |
*
* Callback function that gets or sets the property.
*
* @parm IN LPCDIPROPINFO | ppropi |
*
* Information describing the property being set.
*
* @parm LPCDIPROPHEADER | pdiph |
*
* Structure containing property value.
*
* @parm int | ibField |
*
* Offset to field being set. (Really: Reference data to
* pass to callback.)
*
*****************************************************************************/
STDMETHODIMP
CJoy_SetAxisProperty(PDJ this, LPCDIPROPINFO ppropi, LPCDIPROPHEADER pdiph)
{
HRESULT hres;
/*
* Note that we never pass the type key to CCal_SetProperty
* because we keep our calibration data elsewhere.
*/
if (ppropi->dwDevType == 0) { /* For device */
int iAxis;
for (iAxis = 0; iAxis < cA(this->rgjrc); iAxis++) {
PJOYRANGECONVERT pjrc = &this->rgjrc[iAxis];
hres = CCal_SetProperty(pjrc, ppropi, pdiph, NULL);
if (FAILED(hres)) {
goto done;
}
}
hres = S_OK;
} else if ((ppropi->dwDevType & DIDFT_ABSAXIS) &&
DIDFT_GETINSTANCE(ppropi->dwDevType) < cA(this->rgjrc)) {
PJOYRANGECONVERT pjrc;
pjrc = &this->rgjrc[DIDFT_GETINSTANCE(ppropi->dwDevType)];
hres = CCal_SetProperty(pjrc, ppropi, pdiph, NULL);
} else {
hres = E_NOTIMPL;
}
done:;
return hres;
}
/*****************************************************************************
*
* @doc INTERNAL
*
* @method void | CJoy | UpdateAxisCalibration |
*
* Take our cached calibration information and smash it into
* the configuration section of the registry.
*
* @parm PDJ | this |
*
* The device object.
*
*****************************************************************************/
STDMETHODIMP
CJoy_UpdateAxisCalibration(PDJ this)
{
HRESULT hres;
DIJOYCONFIG cfg;
hres = JoyReg_GetConfig(this->idJoy, &cfg, DIJC_REGHWCONFIGTYPE);
if (SUCCEEDED(hres)) {
UINT uiPosAxis;
#define JoyPosValue(phwc, f, i) \
*(LPDWORD)pvAddPvCb(&(phwc)->hwv.jrvHardware.f, \
ibJoyPosAxisFromPosAxis(i)) \
for (uiPosAxis = 0; uiPosAxis < cJoyPosAxisMax; uiPosAxis++) {
PJOYRANGECONVERT pjrc;
UINT uiStateAxis;
uiStateAxis = iJoyStateAxisFromPosAxis(uiPosAxis);
pjrc = &this->rgjrc[uiStateAxis];
JoyPosValue(&cfg.hwc, jpMin, uiPosAxis) = pjrc->dwPmin;
JoyPosValue(&cfg.hwc, jpMax, uiPosAxis) = pjrc->dwPmax;
JoyPosValue(&cfg.hwc, jpCenter, uiPosAxis) = pjrc->dwPc;
#undef JoyPosValue
}
hres = JoyReg_SetConfig(this->idJoy, &cfg.hwc, &cfg,
DIJC_UPDATEALIAS | DIJC_REGHWCONFIGTYPE);
}
if (FAILED(hres)) {
RPF("Joystick::SetProperty::Calibration: "
"Unable to update calibration in registry");
}
return hres;
}
/*****************************************************************************
*
* @doc INTERNAL
*
* @method HRESULT | CJoy | SetProperty |
*
* Set a device property.
*
* @parm PDJ | this |
*
* The device object.
*
* @parm IN LPCDIPROPINFO | ppropi |
*
* Information describing the property being set.
*
* @parm LPCDIPROPHEADER | pdiph |
*
* Structure containing property value.
*
* @returns
*
* <c E_NOTIMPL> for something we didn't handle natively.
* The caller will do
* the default thing in response to <c E_NOTIMPL>.
*
*****************************************************************************/
STDMETHODIMP
CJoy_SetProperty(PDICB pdcb, LPCDIPROPINFO ppropi, LPCDIPROPHEADER pdiph)
{
HRESULT hres;
PDJ this;
EnterProcI(IDirectInputDeviceCallback::Joy::SetProperty,
(_ "pxxp", pdcb, ppropi->pguid, ppropi->iobj, pdiph));
/*
* This is an internal interface, so we can skimp on validation.
*/
this = _thisPvNm(pdcb, dcb);
switch ((DWORD)(UINT_PTR)ppropi->pguid) {
case (DWORD)(UINT_PTR)DIPROP_RANGE:
case (DWORD)(UINT_PTR)DIPROP_DEADZONE:
case (DWORD)(UINT_PTR)DIPROP_SATURATION:
case (DWORD)(UINT_PTR)DIPROP_CALIBRATIONMODE:
case (DWORD)(UINT_PTR)DIPROP_CALIBRATION:
hres = CJoy_SetAxisProperty(this, ppropi, pdiph);
if (SUCCEEDED(hres) && ppropi->pguid == DIPROP_CALIBRATION) {
hres = CJoy_UpdateAxisCalibration(this);
}
break;
case (DWORD)(UINT_PTR)DIPROP_INSTANCENAME:
case (DWORD)(UINT_PTR)DIPROP_PRODUCTNAME:
{
USHORT uVid, uPid;
/*
* Friendly names cause all manner of problems with devices that
* use auto detection so only allow non-predefined analog devices
* to use them.
*
* Prefix warns (240487) that ParseVIDPID could leave uVid
* uninitialized and succeed but it won't.
* See the comment in _ParseHex for more details.
*/
if( ParseVIDPID( &uVid, &uPid, this->cfg.wszType ) &&
( uVid == MSFT_SYSTEM_VID ) &&
( uPid >= MSFT_SYSTEM_PID + JOY_HW_PREDEFMAX ) &&
( ( uPid & 0xff00 ) == MSFT_SYSTEM_PID ) )
{
AssertF(this->hkType);
if( this->hkType )
{
LPDIPROPSTRING pstr = (PV)pdiph;
hres = JoyReg_SetValue(this->hkType,
REGSTR_VAL_JOYOEMNAME, REG_SZ,
pstr->wsz,
cbX(pstr->wsz));
if( SUCCEEDED(hres ) )
{
hres = S_OK;
} else {
hres = E_FAIL;
}
}
}
else
{
hres = E_NOTIMPL;
}
break;
}
default:
SquirtSqflPtszV(sqflJoy,
TEXT("CJoy_SetProperty: E_NOTIMPL on guid: %08x"),
ppropi->pguid);
hres = E_NOTIMPL;
break;
}
ExitOleProcR();
return hres;
}
/*****************************************************************************
*
* @doc INTERNAL
*
* @method HRESULT | CJoy | GetAxisProperty |
*
* Handle an axis property.
*
* @cwrap PDJ | this
*
* @parm IN LPCDIPROPINFO | ppropi |
*
* Information describing the property being retrieved.
*
* @parm OUT LPDIPROPHEADER | pdiph |
*
* Structure to receive property value.
*
* @returns
*
* <c S_OK> if the operation completed successfully.
*
* <c E_NOTIMPL> nothing happened. The caller will do
* the default thing in response to <c E_NOTIMPL>.
*
*****************************************************************************/
STDMETHODIMP
CJoy_GetAxisProperty(PDJ this, LPCDIPROPINFO ppropi, LPDIPROPHEADER pdiph)
{
LPDIPROPRANGE pdiprg = (PV)pdiph;
HRESULT hres;
if ((ppropi->dwDevType & DIDFT_ABSAXIS) &&
DIDFT_GETINSTANCE(ppropi->dwDevType) < cA(this->rgjrc)) {
PJOYRANGECONVERT pjrc;
pjrc = &this->rgjrc[DIDFT_GETINSTANCE(ppropi->dwDevType)];
hres = CCal_GetProperty(pjrc, ppropi->pguid, pdiph);
} else {
SquirtSqflPtszV(sqflJoy,
TEXT("CJoy_GetProperty: E_NOTIMPL on guid: %08x"),
ppropi->pguid);
hres = E_NOTIMPL;
}
return hres;
}
/*****************************************************************************
*
* @doc INTERNAL
*
* @method void | CJoy | GetGuidAndPath |
*
* Get a Joy device's class GUID (namely, the MEDIA guid)
* and device interface (path). The path is for the equivalent
* HID device if possible, otherwise a NULL string.
*
* @parm PCHID | this |
*
* The Joy object.
*
* @parm LPDIPROPHEADER | pdiph |
*
* Structure to receive property value.
*
*****************************************************************************/
VOID INTERNAL
CJoy_GetGuidAndPath(PDJ this, LPDIPROPHEADER pdiph)
{
/*
* This should never happen on Win2k because all devices are HID
* but just in case we build an NT4 SP5 version or something...
*/
#ifdef WINNT
LPDIPROPGUIDANDPATH pgp = (PV)pdiph;
UNREFERENCED_PARAMETER( this );
pgp->guidClass = GUID_MediaClass;
pgp->wszPath[0] = TEXT( '\0' );
#else
LPDIPROPGUIDANDPATH pgp = (PV)pdiph;
VXDINITPARMS vip;
TCHAR szPath[MAX_PATH];
PTCHAR pszPath;
pgp->guidClass = GUID_MediaClass;
pszPath = JoyReg_JoyIdToDeviceInterface_95( this->idJoy, &vip, szPath );
if( pszPath )
{
TToU( pgp->wszPath, cA(pgp->wszPath), pszPath );
}
else
{
pgp->wszPath[0] = TEXT( '\0' );
}
#endif
}
/*****************************************************************************
*
* @doc INTERNAL
*
* @method HRESULT | CJoy | GetProperty |
*
* Retrieve a device property.
*
* @parm PDJ | this |
*
* The device object.
*
* @parm IN LPCDIPROPINFO | ppropi |
*
* Information describing the property being retrieved.
*
* @parm LPDIPROPHEADER | pdiph |
*
* Structure to receive property value.
*
* @returns
*
* <c S_OK> if the operation completed successfully.
*
* <c E_NOTIMPL> nothing happened. The caller will do
* the default thing in response to <c E_NOTIMPL>.
*
*****************************************************************************/
STDMETHODIMP
CJoy_GetProperty(PDICB pdcb, LPCDIPROPINFO ppropi, LPDIPROPHEADER pdiph)
{
HRESULT hres = E_NOTIMPL;
PDJ this;
EnterProcI(IDirectInputDeviceCallback::Joy::GetProperty,
(_ "pxxp", pdcb, ppropi->pguid, ppropi->iobj, pdiph));
/*
* This is an internal interface, so we can skimp on validation.
*/
this = _thisPvNm(pdcb, dcb);
switch ((DWORD)(UINT_PTR)ppropi->pguid) {
case (DWORD)(UINT_PTR)DIPROP_GRANULARITY:
/*
* ISSUE-2001/03/29-timgill All POVs have the same granularity
*/
if (ppropi->dwDevType & DIDFT_POV) {
LPDIPROPDWORD pdipdw = (PV)pdiph;
pdipdw->dwData = this->dwPOVGranularity;
hres = S_OK;
}
break;
case (DWORD)(UINT_PTR)DIPROP_GUIDANDPATH:
if(ppropi->iobj == 0xFFFFFFFF)
{
CJoy_GetGuidAndPath(this, pdiph);
hres = S_OK;
}
break;
/*
* In DX7, INSTANCENAME and PRODUCTNAME are the same for VJOYD devices.
* It is different before DX7. Probably we need make them different again
* after DX7.
*/
case (DWORD)(UINT_PTR)DIPROP_INSTANCENAME:
case (DWORD)(UINT_PTR)DIPROP_PRODUCTNAME:
{
LPDIPROPSTRING pdipstr = (PV)pdiph;
/*
* lstrcpW doesn't work in Win95. We have to use memcpy instead.
*/
//lstrcpyW(pstr->wsz, this->typi.wszDisplayName);
if( cbX(pdipstr->wsz) > cbX(this->typi.wszDisplayName) )
{
memset( &pdipstr->wsz[cA(this->typi.wszDisplayName)], 0, cbX(pdipstr->wsz) - cbX(this->typi.wszDisplayName) );
}
CAssertF( cbX(pdipstr->wsz) >= cbX(this->typi.wszDisplayName) );
memcpy( pdipstr->wsz, this->typi.wszDisplayName, cbX(this->typi.wszDisplayName));
if( this->diHacks.nMaxDeviceNameLength < lstrlenW(pdipstr->wsz) ) {
pdipstr->wsz[this->diHacks.nMaxDeviceNameLength] = L'\0';
}
hres = S_OK;
break;
}
case (DWORD)(UINT_PTR)DIPROP_JOYSTICKID:
if(ppropi->iobj == 0xFFFFFFFF)
{
LPDIPROPDWORD pdipdw = (PV)pdiph;
pdipdw->dwData = this->idJoy;
hres = S_OK;
}
break;
case (DWORD)(UINT_PTR)(DIPROP_MAPFILE):
AssertF( ppropi->iobj == 0xFFFFFFFF );
{
LPDIPROPSTRING pdipstr = (PV)pdiph;
LONG lRes;
DWORD dwBufferSize = cbX(pdipstr->wsz);
lRes = RegQueryStringValueW( this->hkProp, REGSTR_VAL_JOYOEMMAPFILE, pdipstr->wsz, &dwBufferSize );
hres = ( pdipstr->wsz[0] && ( lRes == ERROR_SUCCESS ) ) ? S_OK : DIERR_OBJECTNOTFOUND;
}
break;
case (DWORD)(UINT_PTR)(DIPROP_TYPENAME):
AssertF( ppropi->iobj == 0xFFFFFFFF );
{
LPDIPROPSTRING pdipstr = (PV)pdiph;
if( this->cfg.hwc.dwType >= JOY_HW_PREDEFMIN && this->cfg.hwc.dwType < JOY_HW_PREDEFMAX ) {
pdipstr->wsz[0] = L'#';
pdipstr->wsz[1] = L'0' + (WCHAR)this->cfg.hwc.dwType;
pdipstr->wsz[2] = L'\0';
hres = S_OK;
}
else if( this->cfg.wszType[0] != L'\0' )
{
/*
* The type MUST be NULL terminated
*/
#ifdef WINNT
lstrcpyW( pdipstr->wsz, this->cfg.wszType );
#else
UINT uiLen;
uiLen = lstrlenW( this->cfg.wszType ) + 1;
AssertF( uiLen <= cA( pdipstr->wsz ) );
memcpy( pdipstr->wsz, this->cfg.wszType, uiLen * cbX(this->cfg.wszType[0]) );
#endif
hres = S_OK;
}
else
{
/*
* Don't think this should ever happen so Assert for now
* Assert that the hres is a failure (if not quite right)
*/
AssertF( hres == E_NOTIMPL );
AssertF( !"No type name available in GetProperty" );
}
}
break;
/*
* Else, it might be something axis-specific.
*/
default:
hres = CJoy_GetAxisProperty(this, ppropi, pdiph);
break;
}
ExitOleProcR();
return hres;
}
/*****************************************************************************
*
* @doc INTERNAL
*
* @method void | CJoy | GetCapabilities |
*
* Get joystick device capabilities.
*
* @parm PDJ | this |
*
* The joystick object.
*
* @parm LPDIDEVCAPS | pdc |
*
* Device capabilities structure to receive result.
*
* @returns
* <c S_OK> on success.
*
*****************************************************************************/
STDMETHODIMP
CJoy_GetCapabilities(PDICB pdcb, LPDIDEVCAPS pdc)
{
HRESULT hres;
PDJ this;
JOYINFOEX jix;
MMRESULT mmrc = MMSYSERR_ERROR;
EnterProcI(IDirectInputDeviceCallback::Joy::GetCapabilities,
(_ "pp", pdcb, pdc));
/*
* This is an internal interface, so we can skimp on validation.
*/
this = _thisPvNm(pdcb, dcb);
AssertF(IsValidSizeDIDEVCAPS(pdc->dwSize));
CopyMemory(pvAddPvCb(pdc, cbX(DWORD)),
pvAddPvCb(&this->dc, cbX(DWORD)),
pdc->dwSize - cbX(DWORD));
/*
* Joysticks can come and go. Re-query each time.
*/
/*
* Determine if joystick is physically attached
* or is possibly even phantom.
*
* JOYERR_ATTACHED - Is attached
* JOYERR_UNPLUGGED - Is not attached
* Anything else - Is phantom
*/
jix.dwSize = sizeof(JOYINFOEX);
jix.dwFlags = JOY_CAL_READALWAYS | JOY_RETURNALL;
mmrc = joyGetPosEx(this->idJoy, &jix);
pdc->dwFlags &= ~DIDC_ATTACHED;
if (mmrc == JOYERR_NOERROR) {
pdc->dwFlags |= DIDC_ATTACHED;
} else if (mmrc == JOYERR_UNPLUGGED) {
} else {
pdc->dwFlags |= DIDC_PHANTOM;
}
hres = S_OK;
ExitOleProcR();
return hres;
}
/*****************************************************************************
*
* @doc INTERNAL
*
* @method void | CJoy | GetPhysicalState |
*
* Read the physical joystick state into <p pjsOut>.
*
* After getting the physical data,
* we cook the axes as necessary.
*
* @parm LPDIJOYSTATE2 | pjsOut |
*
* Where to put the joystick state.
*
* @returns
*
* None.
*
*****************************************************************************/
void INLINE
CJoy_GetPhysicalState(PDJ this, LPDIJOYSTATE2 pjsOut)
{
UINT uiStateAxis;
AssertF(this->pjsPhys);
*pjsOut = *this->pjsPhys;
/*
* Note only absolute positional data gets calibrated
*/
if( ( this->pvi->fl & VIFL_RELATIVE ) == 0 )
{
for (uiStateAxis = 0; uiStateAxis < cA(this->rgjrc); uiStateAxis++) {
PLONG pl = pvAddPvCb(pjsOut,
ibJoyStateAxisFromStateAxis(uiStateAxis));
CCal_CookRange(&this->rgjrc[uiStateAxis], pl);
}
}
}
/*****************************************************************************
*
* @doc INTERNAL
*
* @method HRESULT | CJoy | Poll |
*
* Ping down into the driver to get the latest data.
*
* @returns
*
* <c S_OK> if we pinged okay.
* <c DIERR_UNPLUGGED> if we did not
*
*****************************************************************************/
STDMETHODIMP
CJoy_Poll(PDICB pdcb)
{
HRESULT hres;
PDJ this;
EnterProcI(IDirectInputDeviceCallback::Joy::Poll, (_ "p", pdcb));
/*
* This is an internal interface, so we can skimp on validation.
*/
this = _thisPvNm(pdcb, dcb);
hres = Hel_Joy_Ping(this->pvi);
if (FAILED(hres)) {
AssertF(hres ==
MAKE_HRESULT(SEVERITY_ERROR, FACILITY_WIN32,
ERROR_DEV_NOT_EXIST));
hres = DIERR_UNPLUGGED;
}
/*
* Note, we don't keep this->pvi->fl:VIFL_UNPLUGGED up-to-date because
* we don't use the flag and always retest the connectivity in GetCaps.
*/
return hres;
}
/*****************************************************************************
*
* @doc INTERNAL
*
* @method HRESULT | CJoy | GetDeviceState |
*
* Obtains the state of the joystick device.
*
* It is the caller's responsibility to have validated all the
* parameters and ensure that the device has been acquired.
*
* @parm OUT LPVOID | lpvData |
*
* joystick data in the preferred data format.
*
* @returns
*
* Returns a COM error code. The following error codes are
* intended to be illustrative and not necessarily comprehensive.
*
* <c DI_OK> = <c S_OK>: The operation completed successfully.
*
* <c DIERR_INVALIDPARAM> = <c E_INVALIDARG>: The
* <p lpmdr> parameter is not a valid pointer.
*
*****************************************************************************/
STDMETHODIMP
CJoy_GetDeviceState(PDICB pdcb, LPVOID pvData)
{
HRESULT hres;
PDJ this;
LPDIJOYSTATE2 pjsOut = pvData;
EnterProcI(IDirectInputDeviceCallback::Joy::GetDeviceState,
(_ "pp", pdcb, pvData));
/*
* This is an internal interface, so we can skimp on validation.
*/
this = _thisPvNm(pdcb, dcb);
AssertF(this->pvi);
AssertF(this->pjsPhys);
if (this->pvi->fl & VIFL_ACQUIRED) {
CJoy_GetPhysicalState(this, pjsOut);
hres = S_OK;
} else {
hres = DIERR_INPUTLOST;
}
ExitOleProcR();
return hres;
}
/*****************************************************************************
*
* @doc INTERNAL
*
* @method HRESULT | CJoy | CookDeviceData |
*
* Manipulate buffered device data.
*
* If the item describe an axis, we need to cook it.
*
* @parm DWORD | cdod |
*
* Number of objects to cook; zero is a valid value.
*
* @parm LPDIDEVICEOBJECTDATA | pdod |
*
* Array of object data to cook.
*
* @returns
*
* Returns a COM error code. The following error codes are
* intended to be illustrative and not necessarily comprehensive.
*
* <c DI_OK> = <c S_OK>: The operation completed successfully.
*
* <c DIERR_UNSUPPORTED> = <c E_NOTIMPL>: The callback does
* not cook device data.
*
* <c DIERR_NOTACQUIRED>: The device could not be acquired.
*
***************************************************************************/
STDMETHODIMP
CJoy_CookDeviceData
(
PDICB pdcb,
DWORD cdod,
LPDIDEVICEOBJECTDATA pdod
)
{
HRESULT hres;
PDJ this;
EnterProcI(IDirectInputDeviceCallback::Joy::CookDeviceData,
(_ "pxp", pdcb, cdod, pdod));
/*
* This is an internal interface, so we can skimp on validation.
*/
this = _thisPvNm(pdcb, dcb);
/*
* Step through array of either element size cooking the data.
*/
for( ; cdod; cdod-- )
{
DWORD dwType = this->df.rgodf[pdod->dwOfs].dwType;
if( dwType & DIDFT_ABSAXIS )
{
PJOYRANGECONVERT pjrc;
AssertF( DIDFT_GETINSTANCE( dwType ) < cA( this->rgjrc ) );
pjrc = &this->rgjrc[DIDFT_GETINSTANCE( dwType )];
CCal_CookRange(pjrc, (PV)&pdod->dwData);
}
pdod++;
}
hres = S_OK;
return hres;
}
/*****************************************************************************
*
* @doc INTERNAL
*
* @method HRESULT | CJoy | OpenIdSubkey |
*
* Given an object ID, attempt to open the subkey that
* corresponds to it.
*
* @cwrap PDJ | this
*
* @parm DWORD | dwId |
*
* Object id.
*
* @parm PHKEY | phk |
*
* Receives the key on success.
*
* @returns
*
* Returns a COM error code.
*
*****************************************************************************/
HRESULT INLINE
CJoy_OpenIdSubkey(PDJ this, DWORD dwId, PHKEY phk)
{
return CType_OpenIdSubkey(this->hkType, dwId, KEY_QUERY_VALUE, phk);
}
/*****************************************************************************
*
* @doc INTERNAL
*
* @method HRESULT | CJoy | GetObjectInfo |
*
* Obtain the friendly name and FF/HID information
* of an object.
*
* @parm IN LPCDIPROPINFO | ppropi |
*
* Information describing the object being accessed.
*
* @parm IN OUT LPDIDEVICEOBJECTINSTANCEW | pdidioiW |
*
* Structure to receive information. The
* <e DIDEVICEOBJECTINSTANCE.guidType>,
* <e DIDEVICEOBJECTINSTANCE.dwOfs>,
* and
* <e DIDEVICEOBJECTINSTANCE.dwType>
* <e DIDEVICEOBJECTINSTANCE.dwFlags>
* fields have already been filled in.
*
* @returns
*
* Returns a COM error code.
*
*****************************************************************************/
STDMETHODIMP
CJoy_GetObjectInfo(PDICB pdcb, LPCDIPROPINFO ppropi,
LPDIDEVICEOBJECTINSTANCEW pdidoiW)
{
HRESULT hres;
PDJ this;
EnterProcI(IDirectInputDeviceCallback::Joy::GetObjectInfo,
(_ "pxp", pdcb, ppropi->iobj, pdidoiW));
/*
* This is an internal interface, so we can skimp on validation.
*/
this = _thisPvNm(pdcb, dcb);
AssertF(IsValidSizeDIDEVICEOBJECTINSTANCEW(pdidoiW->dwSize));
if (ppropi->iobj < this->df.dwNumObjs) {
AssertF(ppropi->dwDevType == this->df.rgodf[ppropi->iobj].dwType);
CType_RegGetObjectInfo(this->hkType, ppropi->dwDevType, pdidoiW);
/*
* If we couldn't get a name from the registry,
* then grab one of the standard names.
*/
if (pdidoiW->tszName[0] == L'\0') {
UINT dids;
if (ppropi->dwDevType & DIDFT_AXIS) {
dids = 0;
LoadStringW(g_hinst, IDS_JOYSTICKOBJECT + dids +
DIDFT_GETINSTANCE(ppropi->dwDevType),
pdidoiW->tszName, cA(pdidoiW->tszName));
} else if (ppropi->dwDevType & DIDFT_BUTTON) {
GetNthButtonString(pdidoiW->tszName,
DIDFT_GETINSTANCE(ppropi->dwDevType));
} else {
AssertF(ppropi->dwDevType & DIDFT_POV);
GetNthPOVString(pdidoiW->tszName,
DIDFT_GETINSTANCE(ppropi->dwDevType));
}
}
/*
* ISSUE-2001/03/29-timgill Need a faster way of checking VJoyD devices
* On Win9x, many HID devices cannot use our ring 3 HID path so try
* to get any axis or POV usage from VJoyD
* This is not cheap to get but until we have a better way to
* make sure the VJoyD device has not changed under us this is better
* than caching it. This is not inner loop code anyway.
*/
#ifndef WINNT
if( pdidoiW->dwSize >= cbX(DIDEVICEOBJECTINSTANCE_DX5W) )
{
VXDINITPARMS vip;
hres = Hel_Joy_GetInitParms(this->idJoy, &vip);
if( SUCCEEDED( hres ) && ( vip.dwFlags & VIP_ISHID ) )
{
if( ppropi->dwDevType & DIDFT_AXIS )
{
int AxisIdx;
AxisIdx = c_rgiJoyPosAxisFromStateAxis[DIDFT_GETINSTANCE(ppropi->dwDevType)];
pdidoiW->wUsagePage = HIWORD( vip.Usages[AxisIdx] );
pdidoiW->wUsage = LOWORD( vip.Usages[AxisIdx] );
}
else if( ppropi->dwDevType & DIDFT_BUTTON )
{
/*
* Only JoyHID uses this interface and it only counts
* button page buttons so assume the simplest case.
*/
pdidoiW->wUsagePage = HID_USAGE_PAGE_BUTTON;
pdidoiW->wUsage = 1 + DIDFT_GETINSTANCE( ppropi->dwDevType );
}
else
{
AssertF(ppropi->dwDevType & DIDFT_POV);
pdidoiW->wUsagePage = HIWORD( ((PDWORD)(&vip.dwPOV0usage))[DIDFT_GETINSTANCE(ppropi->dwDevType)] );
pdidoiW->wUsage = LOWORD( ((PDWORD)(&vip.dwPOV0usage))[DIDFT_GETINSTANCE(ppropi->dwDevType)] );
}
}
}
/*
* Ignore any errors getting params.
*/
#endif
hres = S_OK;
} else {
hres = E_INVALIDARG;
}
ExitOleProcR();
return hres;
}
/*****************************************************************************
*
* @doc INTERNAL
*
* @method HRESULT | CJoy | SetCooperativeLevel |
*
* The app changed the cooperative level.
* Un-subclass the old window and en-subclass the new window.
*
* @parm IN HWND | hwnd |
*
* The window handle.
*
* @parm IN DWORD | dwFlags |
*
* The cooperativity level.
*
*****************************************************************************/
STDMETHODIMP
CJoy_SetCooperativeLevel(PDICB pdcb, HWND hwnd, DWORD dwFlags)
{
HRESULT hres;
PDJ this;
EnterProcI(IDirectInputDeviceCallback::Joy::SetCooperativityLevel,
(_ "pxx", pdcb, hwnd, dwFlags));
/*
* This is an internal interface, so we can skimp on validation.
*/
this = _thisPvNm(pdcb, dcb);
/*
* First get out of the old window.
*/
CJoy_RemoveSubclass(this);
/*
* Prefix warns that "this" may have been freed (mb:34574) however
* If you're in SetCooperativeLevel and you have a window subclassed
* then there must be a hold for the subclassed window as well as
* one for the unreleased interface so the Common_Unhold won't free
* the pointer.
*/
/*
* If a new window is passed, then subclass it so we can
* watch for joystick configuration change messages.
*
* If we can't, don't worry. All it means that we won't
* be able to catch when the user recalibrates the joystick,
* which isn't very often.
*/
if (hwnd) {
if (SetWindowSubclass(hwnd, CJoy_SubclassProc, 0, (ULONG_PTR)this)) {
this->hwnd = hwnd;
Common_Hold(this);
}
} else {
RPF("SetCooperativeLevel: You really shouldn't pass hwnd = 0; "
"joystick calibration may be dodgy");
}
hres = S_OK;
ExitOleProcR();
return hres;
}
/*****************************************************************************
*
* @doc INTERNAL
*
* @method HRESULT | CJoy | RunControlPanel |
*
* Run the joystick control panel.
*
* @parm IN HWND | hwndOwner |
*
* The owner window.
*
* @parm DWORD | dwFlags |
*
* Flags.
*
*****************************************************************************/
TCHAR c_tszJoyCpl[] = TEXT("joy.cpl");
STDMETHODIMP
CJoy_RunControlPanel(PDICB pdcb, HWND hwnd, DWORD dwFlags)
{
HRESULT hres;
PDJ this;
EnterProcI(IDirectInputDeviceCallback::Joy::RunControlPanel,
(_ "pxx", pdcb, hwnd, dwFlags));
/*
* This is an internal interface, so we can skimp on validation.
*/
this = _thisPvNm(pdcb, dcb);
hres = hresRunControlPanel(c_tszJoyCpl);
ExitOleProcR();
return hres;
}
/*****************************************************************************
*
* @doc INTERNAL
*
* @method HRESULT | CJoy | GetFFConfigKey |
*
* Open and return the registry key that contains
* force feedback configuration information.
*
* @parm DWORD | sam |
*
* Security access mask.
*
* @parm PHKEY | phk |
*
* Receives the registry key.
*
*****************************************************************************/
STDMETHODIMP
CJoy_GetFFConfigKey(PDICB pdcb, DWORD sam, PHKEY phk)
{
HRESULT hres;
PDJ this;
EnterProcI(IDirectInputDeviceCallback::Joy::GetFFConfigKey,
(_ "px", pdcb, sam));
/*
* This is an internal interface, so we can skimp on validation.
*/
this = _thisPvNm(pdcb, dcb);
hres = JoyReg_OpenFFKey(this->hkType, sam, phk);
AssertF(fLeqvFF(SUCCEEDED(hres), *phk));
ExitBenignOleProcPpvR(phk);
return hres;
}
/*****************************************************************************
*
* @doc INTERNAL
*
* @method HRESULT | CJoy | CreateEffect |
*
* Create an <i IDirectInputEffectDriver> interface.
*
* @parm LPDIRECTINPUTEFFECTSHEPHERD * | ppes |
*
* Receives the shepherd for the effect driver.
*
*****************************************************************************/
STDMETHODIMP
CJoy_CreateEffect(PDICB pdcb, LPDIRECTINPUTEFFECTSHEPHERD *ppes)
{
HRESULT hres;
PDJ this;
HKEY hk;
EnterProcI(IDirectInputDeviceCallback::Joy::CreateEffect, (_ "p", pdcb));
/*
* This is an internal interface, so we can skimp on validation.
*/
this = _thisPvNm(pdcb, dcb);
hres = CJoy_GetFFConfigKey(pdcb, KEY_QUERY_VALUE, &hk);
if (SUCCEEDED(hres)) {
hres = CEShep_New(hk, 0, &IID_IDirectInputEffectShepherd, ppes);
if (SUCCEEDED(hres)) {
#ifndef WINNT
VXDINITPARMS vip;
CHAR szPath[MAX_PATH];
PCHAR pszPath;
pszPath = JoyReg_JoyIdToDeviceInterface_95( this->idJoy, &vip, szPath );
if( pszPath )
{
DIHIDFFINITINFO init;
WCHAR wszPath[MAX_PATH];
ZeroX(init);
init.dwSize = cbX(init);
TToU( wszPath, cA(wszPath), pszPath );
init.pwszDeviceInterface = wszPath;
hresFindHIDDeviceInterface(pszPath, &init.GuidInstance);
hres = (*ppes)->lpVtbl->DeviceID((*ppes), this->idJoy, TRUE, &init);
}
else
#endif
{
hres = (*ppes)->lpVtbl->DeviceID((*ppes), this->idJoy, TRUE, 0);
}
}
if (SUCCEEDED(hres)) {
} else {
Invoke_Release(ppes);
}
RegCloseKey(hk);
} else {
hres = E_NOTIMPL;
*ppes = 0;
}
ExitOleProcPpvR(ppes);
return hres;
}
/*****************************************************************************
*
* @doc INTERNAL
*
* @method HRESULT | CJoy | GetVersions |
*
* Ping down into the driver to get the driver version info.
*
* @parm LPDIDRIVERVERSIONS | pvers |
*
* A structure which should be filled in with version information
* describing the hardware, firmware, and driver.
*
* DirectInput will set the <e DIDRIVERVERSIONS.dwSize> field
* to sizeof(DIDRIVERVERSIONS) before calling this method.
*
* @returns
*
* <c S_OK> if we succeeded.
*
*****************************************************************************/
STDMETHODIMP
CJoy_GetVersions(PDICB pdcb, LPDIDRIVERVERSIONS pvers)
{
HRESULT hres;
PDJ this;
VXDINITPARMS vip;
EnterProcI(IDirectInputDeviceCallback::Joy::GetVersions, (_ "p", pdcb));
/*
* This is an internal interface, so we can skimp on validation.
*/
this = _thisPvNm(pdcb, dcb);
AssertF(pvers->dwSize == cbX(*pvers));
hres = Hel_Joy_GetInitParms(this->idJoy, &vip);
if (SUCCEEDED(hres)) {
pvers->dwFirmwareRevision = vip.dwFirmwareRevision;
pvers->dwHardwareRevision = vip.dwHardwareRevision;
pvers->dwFFDriverVersion = vip.dwFFDriverVersion;
}
return hres;
}
/*****************************************************************************
*
* Joystick registry usage
*
*****************************************************************************
*
* Global joystick information is kept under
*
* HKEY_LOCAL_MACHINE\
* System\
* CurrentControlSet\
* Control\
* MediaProperties\
* Joystick\
* OEM
*
* Under this key is a number of subkeys, each corresponding to a brand
* of joystick.
*
* Under each OEM\<name> key, you can find the following values:
*
* OEMData
*
* This is a binary value containing a structure of two dwords.
* The first is the JOYREGHWCONFIG.hws.dwFlags and the second
* is the JOYREGHWCONFIG.hws.dwNumButtons.
*
* OEMName
*
* This is a string which gives a friendly name for the unit.
*
*
*****************************************************************************
*
* Under the driver key is kept information about the particular joystick.
*
* HKEY_LOCAL_MACHINE\
* System\
* CurrentControlSet\
* Control\
* MediaResources\
* Joystick\
* <driver key name>\
* CurrentJoystickSettings
*
* Under this key, there are a bunch of values named
* Joystick##Configuration, where ## is the joystick number
* (1 through 16). Each value contains binary data in the form
* of a JOYREGHWCONFIG, which looks like this:
*
* DWORD hws.dwFlags; // JOY_HWS_* \
* DWORD hws.dwNumButtons; _\ JOYREGHWSETTINGS
* DWORD dwUsageSettings;// JOY_US_* _____
* DWORD hwv.jrvHardware.jpMin.dwX; \ |
* DWORD hwv.jrvHardware.jpMin.dwY; \ |
* DWORD hwv.jrvHardware.jpMin.dwZ; \
* DWORD hwv.jrvHardware.jpMin.dwR; |
* DWORD hwv.jrvHardware.jpMin.dwU; > JOYREGHWVALUES.JOYRANGE
* DWORD hwv.jrvHardware.jpMin.dwV; |
* DWORD hwv.jrvHardware.jpMax.dwX; | |
* DWORD hwv.jrvHardware.jpMax.dwY; | |
* DWORD hwv.jrvHardware.jpMax.dwZ; | \
* DWORD hwv.jrvHardware.jpMax.dwR; | > JOYREGHWVALUES
* DWORD hwv.jrvHardware.jpMax.dwU; | /
* DWORD hwv.jrvHardware.jpMax.dwV; | |
* DWORD hwv.jrvHardware.jpCenter.dwX; | |
* DWORD hwv.jrvHardware.jpCenter.dwY; | |
* DWORD hwv.jrvHardware.jpCenter.dwZ; | |
* DWORD hwv.jrvHardware.jpCenter.dwR; / |
* DWORD hwv.jrvHardware.jpCenter.dwU; / |
* DWORD hwv.jrvHardware.jpCenter.dwV; / |
* DWORD hwv.dwPOVValues[4]; |
* DWORD hwv.dwCalFlags; ______|
* DWORD dwType; // JOY_HW_*
* DWORD dwReserved;
*
*
* Also under this key are optional values named Joystick##OEMName.
* If present, it is a string-data key whose contents are the name
* of another key that describes the joystick, stored in the global
* section described above.
*
* Meanwhile, under the key
*
* HKEY_LOCAL_MACHINE\
* System\
* CurrentControlSet\
* Control\
* MediaResources\
* Joystick\
* <driver key name>
*
* is a value called "JoystickUserValues". This is a binary key
* that contains a JOYREGUSERVALUES structure:
*
* DWORD dwTimeOut;
* DWORD jrvRanges.jpMin.dwX; \
* DWORD jrvRanges.jpMin.dwY; \
* DWORD jrvRanges.jpMin.dwZ; \
* DWORD jrvRanges.jpMin.dwR; |
* DWORD jrvRanges.jpMin.dwU; > JOYRANGE
* DWORD jrvRanges.jpMin.dwV; |
* DWORD jrvRanges.jpMax.dwX; |
* DWORD jrvRanges.jpMax.dwY; |
* DWORD jrvRanges.jpMax.dwZ; |
* DWORD jrvRanges.jpMax.dwR; |
* DWORD jrvRanges.jpMax.dwU; |
* DWORD jrvRanges.jpMax.dwV; |
* DWORD jrvRanges.jpCenter.dwX; | (ignored)
* DWORD jrvRanges.jpCenter.dwY; | (ignored)
* DWORD jrvRanges.jpCenter.dwZ; | (ignored)
* DWORD jrvRanges.jpCenter.dwR; / (ignored)
* DWORD jrvRanges.jpCenter.dwU; / (ignored)
* DWORD jrvRanges.jpCenter.dwV; / (ignored)
* DWORD jpDeadZone.dwX; \
* DWORD jpDeadZone.dwY; \
* DWORD jpDeadZone.dwZ; \ JOYPOS
* DWORD jpDeadZone.dwR; / Dead zone is recorded as a
* DWORD jpDeadZone.dwU; / percentage of total range
* DWORD jpDeadZone.dwV; /
*
* If there is no JoystickUserValues, then the following defaults
* are used:
*
* jpMin.dw# = 0;
* jpMax.dw# = 65535;
* jpCenter.dw# = jpMax.dw# / 2;
* jrvDeadZone.dw# = 5;
*
* (See ibmjoy\msjstick.c, function jsReadRegistry for the code that
* sets the defaults.)
*
* We will also use the defaults if Min > Max or if Max >= 0x80000000
* or if DeadZone > 100.
*
*****************************************************************************/
/*****************************************************************************
*
* @doc INTERNAL
*
* @method void | CJoy | InitPhysRanges |
*
* Initialize (or re-initialize)
* the physical min/max/center values. This is
* done as part of device initialization as well as in response
* to a notification that the Joystick control panel has been
* dinked with.
*
* It is assumed that the <e DJ.hwc> already contains the
* registry hardware settings.
*
* After the phys ranges are set, the ramps are recalculated.
*
*
*****************************************************************************/
void INTERNAL
CJoy_InitPhysRanges(PDJ this, LPJOYREGHWCONFIG phwc)
{
UINT uiPosAxis;
UINT uiStateAxis;
#define GetJoyPosValue(phwc, f, i) \
*(LPDWORD)pvAddPvCb(&phwc->hwv.jrvHardware.f, \
ibJoyPosAxisFromPosAxis(i)) \
for (uiPosAxis = 0; uiPosAxis < cJoyPosAxisMax; uiPosAxis++) {
DWORD dwMax, dwC;
PJOYRANGECONVERT pjrc;
uiStateAxis = iJoyStateAxisFromPosAxis(uiPosAxis);
pjrc = &this->rgjrc[uiStateAxis];
pjrc->dwPmin = GetJoyPosValue(phwc, jpMin, uiPosAxis);
/*
* HACKHACK - Uncalibrated joysticks will have max == 0, in which
* case we use a fake max of 655, just like VJOYD.
*/
dwMax = GetJoyPosValue(phwc, jpMax, uiPosAxis);
if (dwMax == 0) {
dwMax = 655;
}
pjrc->dwPmax = dwMax;
/*
* HACKHACK - Uncalibrated joysticks will have center == 0,
* in which case we use a fake center of midway between min and
* max, just like VJOYD.
*
* Quirk - Z, R, U, and V typically are not center-calibrated,
* so if the jpCenter value is not strictly between min and
* max, then assume it's one of the bogus cases and slam it
* into the middle of the range.
*/
dwC = GetJoyPosValue(phwc, jpCenter, uiPosAxis);
if (dwC <= pjrc->dwPmin || dwC >= pjrc->dwPmax) {
dwC = (pjrc->dwPmin + pjrc->dwPmax) / 2;
}
pjrc->dwPc = dwC;
if( pjrc->dwCPointsNum == 0 ) {
//use two control points by default
pjrc->dwCPointsNum = 2;
pjrc->cp[0].lP = pjrc->dwPmin;
pjrc->cp[0].dwLog = 0;
pjrc->cp[1].lP = pjrc->dwPmax;
pjrc->cp[1].dwLog = RANGEDIVISIONS;
} else {
pjrc->cp[0].lP = pjrc->dwPmin;
pjrc->cp[pjrc->dwCPointsNum-1].lP = pjrc->dwPmax;
}
SquirtSqflPtszV(sqfl,
TEXT("CJoy_PhysRange %d -> %d: %08x / %08x / %08x"),
uiPosAxis,
uiStateAxis,
pjrc->dwPmin,
pjrc->dwPc,
pjrc->dwPmax);
}
#undef GetJoyValue
/*
* These two phantom axes are always raw because they don't exist.
*/
this->rgjrc[iJoyStateAxisRx].fRaw = TRUE;
this->rgjrc[iJoyStateAxisRy].fRaw = TRUE;
/*
* Now compute all the dependent variables.
*/
for (uiStateAxis = 0; uiStateAxis < cA(this->rgjrc); uiStateAxis++) {
CCal_RecalcRange(&this->rgjrc[uiStateAxis]);
}
}
/*****************************************************************************
*
* @doc INTERNAL
*
* @method void | CJoy | InitLogRanges |
*
* Initialize the logical ranges from the user values.
*
*****************************************************************************/
void INLINE
CJoy_InitLogRanges(PDJ this)
{
HRESULT hres;
UINT uiPosAxis;
UINT uiStateAxis;
DIJOYUSERVALUES juv;
hres = JoyReg_GetUserValues(&juv, DIJU_USERVALUES);
AssertF(SUCCEEDED(hres));
#define pJoyValue(jp, i) \
(LPDWORD)pvAddPvCb(&(jp), ibJoyPosAxisFromPosAxis(i)) \
for (uiPosAxis = 0; uiPosAxis < cJoyPosAxisMax; uiPosAxis++) {
PJOYRANGECONVERT pjrc;
AssertF((int)*pJoyValue(juv.ruv.jrvRanges.jpMax, uiPosAxis) >= 0);
AssertF(*pJoyValue(juv.ruv.jrvRanges.jpMin, uiPosAxis) <
*pJoyValue(juv.ruv.jrvRanges.jpMax, uiPosAxis));
uiStateAxis = iJoyStateAxisFromPosAxis(uiPosAxis);
pjrc = &this->rgjrc[uiStateAxis];
pjrc->lMin = *pJoyValue(juv.ruv.jrvRanges.jpMin, uiPosAxis);
pjrc->lMax = *pJoyValue(juv.ruv.jrvRanges.jpMax, uiPosAxis);
/*
* Note that we do *not* use the jpCenter value. Strange
* but true.
*
* The sum cannot overflow due to the sanity checks we did above.
*/
pjrc->lC = CCal_Midpoint(pjrc->lMin, pjrc->lMax);
/*
* Now do the dead zone. Convert from percent to range units.
*/
pjrc->dwDz = *pJoyValue(juv.ruv.jpDeadZone, uiPosAxis) *
(RANGEDIVISIONS / 100);
if (pjrc->dwDz > RANGEDIVISIONS) {
pjrc->dwDz = 5 * (RANGEDIVISIONS / 100);
}
/*
* Now do the saturation level. It always defaults to 100%.
*/
pjrc->dwSat = RANGEDIVISIONS;
}
}
#undef pJoyValue
/*****************************************************************************
*
* @doc INTERNAL
*
* @method void | CJoy | BuildAxes |
*
* Study a single capabilities flag and add axis items to the data
* format accordingly.
*
* @parm DWORD | dwCaps |
*
* Collection of <c JOYPF_*> flags describing the axes supported.
*
* @parm UINT | ib |
*
* Data format offset at which this data is provided.
*
* @parm UINT | uiObj |
*
* Instance index for the first item.
*
* @parm DWORD | dwAspect |
*
* <c DIDOI_ASPECT*> for these axes.
*
*****************************************************************************/
typedef struct AXISATTRIBUTES {
DWORD dwMask; /* Mask that identifies the axis */
UINT uidObj; /* Object index delta from X axis */
} AXISATTRIBUTES, *PAXISATTRIBUTES;
typedef const AXISATTRIBUTES *PCAXISATTRIBUTES;
typedef struct AXISMAPPINGS {
PCGUID pguid; /* GUID for the object */
DWORD dwSemantic; /* Default semantic map */
} AXISMAPPINGS, *PAXISMAPPINGS;
typedef const AXISMAPPINGS *PCAXISMAPPINGS;
const AXISATTRIBUTES c_rgaattrJoy[] = {
{ JOYPF_X, iJoyStateAxisX, },
{ JOYPF_Y, iJoyStateAxisY, },
{ JOYPF_Z, iJoyStateAxisZ, },
{ JOYPF_R, iJoyStateAxisRz, },
{ JOYPF_U, iJoyStateAxisS0, },
{ JOYPF_V, iJoyStateAxisS1, },
};
const AXISMAPPINGS c_rgamapJoy[6] = {
{ &GUID_XAxis, DISEM_FLAGS_X | DISEM_TYPE_AXIS },
{ &GUID_YAxis, DISEM_FLAGS_Y | DISEM_TYPE_AXIS },
{ &GUID_Slider, DISEM_FLAGS_S | DISEM_TYPE_AXIS },
{ &GUID_RzAxis, DISEM_FLAGS_R | DISEM_TYPE_AXIS },
{ &GUID_Slider, DISEM_FLAGS_S | DISEM_TYPE_AXIS },
{ &GUID_Slider, DISEM_FLAGS_S | DISEM_TYPE_AXIS },
};
const AXISMAPPINGS c_rgamap6DOF[6] = {
{ &GUID_XAxis, DISEM_FLAGS_X | DISEM_TYPE_AXIS },
{ &GUID_YAxis, DISEM_FLAGS_Y | DISEM_TYPE_AXIS },
{ &GUID_ZAxis, DISEM_FLAGS_Z | DISEM_TYPE_AXIS },
{ &GUID_RzAxis, DISEM_FLAGS_R | DISEM_TYPE_AXIS },
{ &GUID_RyAxis, DISEM_FLAGS_U | DISEM_TYPE_AXIS },
{ &GUID_RxAxis, DISEM_FLAGS_V | DISEM_TYPE_AXIS },
};
const AXISMAPPINGS c_rgamapZJoy[6] = {
{ &GUID_XAxis, DISEM_FLAGS_X | DISEM_TYPE_AXIS },
{ &GUID_YAxis, DISEM_FLAGS_Y | DISEM_TYPE_AXIS },
{ &GUID_ZAxis, DISEM_FLAGS_Z | DISEM_TYPE_AXIS },
{ &GUID_RzAxis, DISEM_FLAGS_R | DISEM_TYPE_AXIS },
{ &GUID_Slider, DISEM_FLAGS_S | DISEM_TYPE_AXIS },
{ &GUID_Slider, DISEM_FLAGS_S | DISEM_TYPE_AXIS },
};
/*
* Since default HID mapping maps accel to Y and brake to Rz
* use the GUIDs to match the correct axis to those mappings
* and set appropriate semantics.
*/
const AXISMAPPINGS c_rgamapCarZY[6] = {
{ &GUID_XAxis, DISEM_FLAGS_X | DISEM_TYPE_AXIS },
{ &GUID_RzAxis, DISEM_FLAGS_B | DISEM_TYPE_AXIS },
{ &GUID_YAxis, DISEM_FLAGS_A | DISEM_TYPE_AXIS },
{ &GUID_Slider, DISEM_FLAGS_S | DISEM_TYPE_AXIS },
{ &GUID_Slider, DISEM_FLAGS_S | DISEM_TYPE_AXIS },
{ &GUID_Slider, DISEM_FLAGS_S | DISEM_TYPE_AXIS },
};
const AXISMAPPINGS c_rgamapCarYR[6] = {
{ &GUID_XAxis, DISEM_FLAGS_X | DISEM_TYPE_AXIS },
{ &GUID_YAxis, DISEM_FLAGS_A | DISEM_TYPE_AXIS },
{ &GUID_ZAxis, DISEM_FLAGS_Z | DISEM_TYPE_AXIS },
{ &GUID_RzAxis, DISEM_FLAGS_B | DISEM_TYPE_AXIS },
{ &GUID_Slider, DISEM_FLAGS_S | DISEM_TYPE_AXIS },
{ &GUID_Slider, DISEM_FLAGS_S | DISEM_TYPE_AXIS },
};
const AXISMAPPINGS c_rgamapCarZR[6] = {
{ &GUID_XAxis, DISEM_FLAGS_X | DISEM_TYPE_AXIS },
{ &GUID_Slider, DISEM_FLAGS_S | DISEM_TYPE_AXIS },
{ &GUID_YAxis, DISEM_FLAGS_A | DISEM_TYPE_AXIS },
{ &GUID_RzAxis, DISEM_FLAGS_B | DISEM_TYPE_AXIS },
{ &GUID_Slider, DISEM_FLAGS_S | DISEM_TYPE_AXIS },
{ &GUID_Slider, DISEM_FLAGS_S | DISEM_TYPE_AXIS },
};
/*****************************************************************************
*
* @doc INTERNAL
*
* @method HRESULT | CJoy | InitFromHwc |
*
* Initialize the information that is kept in the
* <t JOYREGHWCONFIG>.
*
* Broken out from CJoy_InitRing3 to make things less monolithic.
*
* The <e CJoy.cfg> structure already contains joystick
* configuration information.
*
*****************************************************************************/
HRESULT INLINE
CJoy_InitFromHwc(PDJ this)
{
HRESULT hres;
DWORD dwTestType;
if( this->cfg.hwc.dwType >= JOY_HW_PREDEFMIN && this->cfg.hwc.dwType < JOY_HW_PREDEFMAX ) {
WCHAR wszType[4];
wszType[0] = L'#';
wszType[1] = L'0' + (WCHAR)this->cfg.hwc.dwType;
wszType[2] = L'\0';
hres = JoyReg_GetPredefTypeInfo( wszType, &this->typi, DITC_DISPLAYNAME);
} else if (this->cfg.wszType[0] != L'\0' ) {
hres = JoyReg_GetTypeInfo(this->cfg.wszType, &this->typi, DITC_DISPLAYNAME | DITC_FLAGS2 );
if (SUCCEEDED(hres)) {
} else {
#ifdef WINNT
ZeroMemory(&this->typi, cbX(this->typi));
#else
//lstrcpyW( this->typi.wszDisplayName, this->cfg.wszType );
memset( &this->typi.wszDisplayName[0], 0, sizeof(this->typi.wszDisplayName) );
memcpy( &this->typi.wszDisplayName[0], &this->cfg.wszType[0], sizeof(this->cfg.wszType));
#endif
}
} else {
ZeroMemory(&this->typi, cbX(this->typi));
}
#define hwc this->cfg.hwc
if( ( this->typi.dwFlags2 & ( JOYTYPE_HIDEACTIVE | JOYTYPE_GAMEHIDE ) )
== ( JOYTYPE_HIDEACTIVE | JOYTYPE_GAMEHIDE ) )
{
this->dc.dwFlags |= DIDC_HIDDEN;
}
dwTestType = GetValidDI8DevType( this->typi.dwFlags2, this->dc.dwButtons, hwc.hws.dwFlags );
if( dwTestType )
{
/*
* If a valid override exists just use it
*/
this->dc.dwDevType = dwTestType;
}
else
{
#ifdef XDEBUG
if( GET_DIDEVICE_TYPEANDSUBTYPE( this->typi.dwFlags2 ) )
{
RPF( "Ignoring invalid type/subtype Flags2 value 0x%08x for joystick", this->typi.dwFlags2 );
}
#endif
if (hwc.hws.dwFlags & JOY_HWS_ISYOKE)
{
dwTestType = MAKE_DIDEVICE_TYPE(DI8DEVTYPE_FLIGHT, DI8DEVTYPEFLIGHT_STICK);
}
else if (hwc.hws.dwFlags & JOY_HWS_ISGAMEPAD)
{
dwTestType = MAKE_DIDEVICE_TYPE(DI8DEVTYPE_GAMEPAD, DI8DEVTYPEGAMEPAD_STANDARD);
}
else if (hwc.hws.dwFlags & JOY_HWS_ISCARCTRL)
{
AssertF( this->dc.dwAxes > 1 );
if ( this->dc.dwAxes <= 2 )
{
dwTestType = MAKE_DIDEVICE_TYPE(DI8DEVTYPE_DRIVING, DI8DEVTYPEDRIVING_COMBINEDPEDALS );
}
else
{
dwTestType = MAKE_DIDEVICE_TYPE(DI8DEVTYPE_DRIVING, DI8DEVTYPEDRIVING_DUALPEDALS );
}
}
else if (hwc.hws.dwFlags & JOY_HWS_ISHEADTRACKER)
{
dwTestType = MAKE_DIDEVICE_TYPE(DI8DEVTYPE_SUPPLEMENTAL, DI8DEVTYPESUPPLEMENTAL_HEADTRACKER);
}
else
{
dwTestType = MAKE_DIDEVICE_TYPE(DI8DEVTYPE_JOYSTICK, DI8DEVTYPEJOYSTICK_STANDARD);
}
/*
* Use the common function to make this a limited type if the
* number of buttons or flags dictate it.
* Since the type and subtype are known to be valid, the return
* value should never be a failure (zero).
*/
this->dc.dwDevType = GetValidDI8DevType( dwTestType, this->dc.dwButtons, hwc.hws.dwFlags );
AssertF( this->dc.dwDevType );
}
#undef hwc
/*
* Now that we know the type, then make up a name ourselves if we
* previously failed to do so.
*/
if (this->typi.wszDisplayName[0] == TEXT('\0'))
{
CType_MakeGameCtrlName( this->typi.wszDisplayName,
this->dc.dwDevType, this->dc.dwAxes, this->dc.dwButtons, this->dc.dwPOVs );
}
hres = S_OK;
return hres;
}
/*****************************************************************************
*
* @doc INTERNAL
*
* @method void | CJoy | AddObject |
*
* Add one object to the device format.
*
* If the device is polled, then the object is polled, too.
*
* @cwrap PDJ | this
*
* @parm PCGUID | pguid |
*
* The <t GUID> that classifies the device.
*
* @parm DWORD | dwOfs |
*
* Data offset.
*
* @parm DWORD | dwDevType |
*
* Device type flags to apply to the object.
*
* @parm UINT | uiObj |
*
* Object instance number.
*
* @parm DWORD | dwAspect |
*
* Optional <c DIDOI_ASPECT*> flag.
*
*****************************************************************************/
void INTERNAL
CJoy_AddObject(PDJ this, PCGUID pguid, DWORD dwOfs,
DWORD dwDevType, UINT uiObj, DWORD dwAspect, BOOL fReal)
{
LPDIOBJECTDATAFORMAT podf;
podf = &this->df.rgodf[this->df.dwNumObjs++];
podf->pguid = pguid;
podf->dwOfs = dwOfs;
podf->dwType = dwDevType | DIDFT_MAKEINSTANCE(uiObj);
podf->dwFlags = dwAspect;
if (this->dc.dwFlags & DIDC_POLLEDDEVICE) {
podf->dwFlags |= DIDOI_POLLED;
}
if( fReal )
{
CType_RegGetTypeInfo(this->hkType, podf, FALSE);
if( ( GET_DIDEVICE_TYPE( this->dc.dwDevType ) == DI8DEVTYPE_DRIVING )
&& ( podf->dwFlags & DIDOI_FFACTUATOR )
&& ( podf->pguid != &GUID_XAxis ) )
{
/*
* IHVs set FF attributes on non-FF axes for wheels because
* first generation FF apps were only written to support joysticks.
* Since we now munge the various configurations of pedal axes to
* report all split pedals in the same way, the fake Y axis can
* land up on different axes, usually Slider0. Rather than have
* people code to these different fake axes, strip out actuator
* status from any driving axis except the wheel.
*/
podf->dwFlags &= ~DIDOI_FFACTUATOR;
podf->dwType &= ~DIDFT_FFACTUATOR;
}
}
}
void INTERNAL
CJoy_BuildAxes(PDJ this, DWORD dwCaps, UINT ib, UINT uiObj,
DWORD dwAspect, PCAXISMAPPINGS pamap, BOOL fReal )
{
int iaattr;
for (iaattr = 0; iaattr < cA(c_rgaattrJoy); iaattr++) {
PCAXISATTRIBUTES paattr = &c_rgaattrJoy[iaattr];
if (dwCaps & paattr->dwMask) {
CJoy_AddObject(this, pamap[iaattr].pguid, (cbX(LONG)*paattr->uidObj) + ib,
DIDFT_ABSAXIS, paattr->uidObj + uiObj, dwAspect, fReal);
}
}
}
/*****************************************************************************
*
* @doc INTERNAL
*
* @method void | CJoy | BuildDataFormat |
*
* Study the device capabilities and build the device
* data format.
*
*****************************************************************************/
void INTERNAL
CJoy_BuildDataFormat(PDJ this, PVXDAXISCAPS pvac, DWORD dwButtons, PCAXISMAPPINGS pamap, BOOL fReal)
{
DWORD dw;
this->dc.dwAxes = 0;
this->dc.dwButtons = 0;
this->dc.dwPOVs = 0;
this->df.dwSize = cbX(DIDATAFORMAT);
this->df.dwObjSize = cbX(DIOBJECTDATAFORMAT);
this->df.dwDataSize = sizeof(DIJOYSTATE2);
AssertF(this->df.dwFlags == 0);
this->df.dwNumObjs = 0;
/*
* Repeat for each set of axes.
*/
#define CheckAxisOrder(fStart, p, f) \
CAssertF(FIELD_OFFSET(DIJOYSTATE2, p##f) == \
FIELD_OFFSET(DIJOYSTATE2, fStart) + ibJoyStateAxis##f) \
CheckAxisOrder(lX, l, X);
CheckAxisOrder(lX, l, Y);
CheckAxisOrder(lX, l, Z);
CheckAxisOrder(lX, l, Rx);
CheckAxisOrder(lX, l, Ry);
CheckAxisOrder(lX, l, Rz);
CheckAxisOrder(lX, rgl, Slider);
if (pvac->dwPos & JOYPF_POSITION) {
CJoy_BuildAxes(this, pvac->dwPos, FIELD_OFFSET(DIJOYSTATE2, lX),
iobjPositions, DIDOI_ASPECTPOSITION, pamap, fReal);
}
CheckAxisOrder(lVX, lV, X);
CheckAxisOrder(lVX, lV, Y);
CheckAxisOrder(lVX, lV, Z);
CheckAxisOrder(lVX, lV, Rx);
CheckAxisOrder(lVX, lV, Ry);
CheckAxisOrder(lVX, lV, Rz);
CheckAxisOrder(lVX, rglV, Slider);
if (pvac->dwPos & JOYPF_VELOCITY) {
CJoy_BuildAxes(this, pvac->dwVel, FIELD_OFFSET(DIJOYSTATE2, lVX),
iobjVelocities, DIDOI_ASPECTVELOCITY, pamap, fReal);
}
CheckAxisOrder(lAX, lA, X);
CheckAxisOrder(lAX, lA, Y);
CheckAxisOrder(lAX, lA, Z);
CheckAxisOrder(lAX, lA, Rx);
CheckAxisOrder(lAX, lA, Ry);
CheckAxisOrder(lAX, lA, Rz);
CheckAxisOrder(lAX, rglA, Slider);
if (pvac->dwPos & JOYPF_ACCELERATION) {
CJoy_BuildAxes(this, pvac->dwAccel, FIELD_OFFSET(DIJOYSTATE2, lAX),
iobjAccels, DIDOI_ASPECTACCEL, pamap, fReal);
}
CheckAxisOrder(lFX, lF, X);
CheckAxisOrder(lFX, lF, Y);
CheckAxisOrder(lFX, lF, Z);
CheckAxisOrder(lFX, lF, Rx);
CheckAxisOrder(lFX, lF, Ry);
CheckAxisOrder(lFX, lF, Rz);
CheckAxisOrder(lFX, rglF, Slider);
if (pvac->dwPos & JOYPF_FORCE) {
CJoy_BuildAxes(this, pvac->dwForce, FIELD_OFFSET(DIJOYSTATE2, lFX),
iobjForces, DIDOI_ASPECTFORCE, pamap, fReal);
}
#undef CheckAxisOrder
this->dc.dwAxes = this->df.dwNumObjs;
/*
* Doing the POVs is a bit tricky but not that bad.
*/
for (dw = 0; dw < cJoyStatePOVTotal; dw++) {
if (pvac->dwPos & JOYPF_POV(dw)) {
CJoy_AddObject(this, &GUID_POV,
FIELD_OFFSET(DIJOYSTATE2, rgdwPOV[dw]),
DIDFT_POV, dw, DIDOI_ASPECTUNKNOWN, fReal);
this->dc.dwPOVs++;
}
}
/*
* Doing the buttons is easy since they don't have
* any interesting attributes.
*/
this->dc.dwButtons = min(dwButtons, cJoyStateButtonTotal);
for (dw = 0; dw < this->dc.dwButtons; dw++) {
CJoy_AddObject(this, &GUID_Button,
FIELD_OFFSET(DIJOYSTATE2, rgbButtons[dw]),
DIDFT_PSHBUTTON, dw, DIDOI_ASPECTUNKNOWN, fReal);
}
AssertF(this->df.dwNumObjs <= cJoyStateObjTotal);
}
/*****************************************************************************
*
* @doc INTERNAL
*
* @method HRESULT | CJoy | PreInit |
*
* Preallocate all the memory we will need up front, so we
* don't waste time reallocating later.
*
*****************************************************************************/
HRESULT INLINE
CJoy_PreInit(PDJ this)
{
HRESULT hres;
hres = ReallocCbPpv(cbCxX(cJoyStateObjTotal, DIOBJECTDATAFORMAT),
&this->df.rgodf);
return hres;
}
/*****************************************************************************
*
* @doc INTERNAL
*
* @method HRESULT | CJoy | InitRing0 |
*
* Initialize the ring 0 information maintained about the object.
*
* Broken out from CJoy_Init to make things less monolithic.
*
*****************************************************************************/
HRESULT INTERNAL
CJoy_InitRing0(PDJ this)
{
HRESULT hres;
VXDDEVICEFORMAT devf;
/*
* Note that we now allow the device to be created even if
* the joystick doesn't physically exist. This is necessary
* so that IDirectInputJoyConfig8 can calibrate the joystick
* that doesn't exist yet.
*
* This won't confuse applications, however, because
* IDirectInput::EnumDevices will not return phantom devices
* unless the application explicitly asks for phantom devices
* to be included.
*/
/*
* See if this joystick supports fancy notifications.
* The default is "no".
*
* Also see if this is really a HID device (and hence our
* interface is an alias).
*
* These things are all 9x-specific.
*/
#ifdef WINNT
this->dc.dwFlags |= DIDC_POLLEDDEVICE;
#else
VXDINITPARMS vip;
this->dc.dwFlags |= DIDC_POLLEDDEVICE;
hres = Hel_Joy_GetInitParms(this->idJoy, &vip);
if (SUCCEEDED(hres))
{
if (vip.dwFlags & VIP_SENDSNOTIFY)
{
this->dc.dwFlags &= ~DIDC_POLLEDDEVICE;
}
if (vip.dwFlags & VIP_ISHID)
{
/*
* Use VJOYD as Alias if the device is HID
* (the may be revised in CJoy_InitRing3).
*/
this->dc.dwFlags |= DIDC_ALIAS;
}
}
#endif /* WINNT */
this->dc.dwSize = cbX(DIDEVCAPS);
/*
* Build the worst-case data format for the VxD.
*
* We must always build worst-case because sometime
* later, a newer more capable joystick might show up,
* with more objects than the one we imprinted on.
*
* Use the GUIDs for a joystick for now, and pass the flag
* indicating that there is no need to check registry settings.
*/
CJoy_BuildDataFormat(this, &c_vacMax, cJoyStateButtonTotal, c_rgamapJoy, FALSE);
/*
* It won't actually get that high because of the
* nonexistent Rx and Ry axes.
*/
AssertF(this->df.dwNumObjs <= cJoyStateObjTotal);
devf.cbData = cbX(DIJOYSTATE2);
devf.dwExtra = this->idJoy;
devf.cObj = this->df.dwNumObjs;
devf.rgodf = this->df.rgodf;
devf.dwEmulation = 0;
hres = Hel_Joy_CreateInstance(&devf, &this->pvi);
if (SUCCEEDED(hres)) {
AssertF(this->pvi);
this->pjsPhys = this->pvi->pState;
} else { /* IOCTL failed; hres already set */
}
return hres;
}
/*****************************************************************************
*
* @doc INTERNAL
*
* @method HRESULT | CJoy | InitSemanticMap |
*
* Initialize the semantic mapping information.
*
*****************************************************************************/
void INLINE
CJoy_GetAxisMap( PDJ this, PCAXISMAPPINGS* ppamap )
{
if( GET_DIDEVICE_TYPEANDSUBTYPE( this->dc.dwDevType )
== MAKE_DIDEVICE_TYPE( DI8DEVTYPE_1STPERSON, DI8DEVTYPE1STPERSON_SIXDOF ) )
{
*ppamap = &c_rgamap6DOF[0];
}
else if( ( GET_DIDEVICE_TYPE( this->dc.dwDevType ) == DI8DEVTYPE_DRIVING )
&& ( this->dc.dwAxes > 2 ) )
{
/*
* There are three common forms of pedals
* a. Split Y axis, below center accel, above brake
* b. Y break, Z accel
* c. Y accel, R brake
* a. is just like a joystick but b and c need their own look ups
*
* Use a registry flag if one is set, otherwise, select using HASR
* as there is at least one case of an X,Y,R device that reports
* the presence of a bogus Z axis.
*/
switch( this->typi.dwFlags2 & JOYTYPE_INFOMASK )
{
case JOYTYPE_INFOYYPEDALS:
*ppamap = &c_rgamapJoy[0];
break;
case JOYTYPE_INFOZYPEDALS:
*ppamap = &c_rgamapCarZY[0];
break;
case JOYTYPE_INFOYRPEDALS:
*ppamap = &c_rgamapCarYR[0];
break;
case JOYTYPE_INFOZRPEDALS:
*ppamap = &c_rgamapCarZR[0];
break;
default:
if( ( this->cfg.hwc.hws.dwFlags & JOY_HWS_HASR )
&& ( this->cfg.hwc.hws.dwFlags & JOY_HWS_HASZ ) )
{
*ppamap = &c_rgamapCarZR[0];
}
else if( this->cfg.hwc.hws.dwFlags & JOY_HWS_HASR )
{
*ppamap = &c_rgamapCarYR[0];
}
else if( this->cfg.hwc.hws.dwFlags & JOY_HWS_HASZ )
{
*ppamap = &c_rgamapCarZY[0];
}
else
{
*ppamap = &c_rgamapJoy[0];
}
}
}
else
{
/*
* The default map is joystick
*
* Check for Z axis behavior override
* Since the default behavior is to use Z as a slider,
* only the override to a Z axis is needed here.
*/
if( this->typi.dwFlags2 & JOYTYPE_INFOZISZ )
{
*ppamap = &c_rgamapZJoy[0];
}
else
{
*ppamap = &c_rgamapJoy[0];
}
}
}
/*****************************************************************************
*
* @doc INTERNAL
*
* @method HRESULT | CJoy | InitSemanticMap |
*
* Initialize the semantic mapping information.
*
*****************************************************************************/
HRESULT INLINE
CJoy_InitSemanticMap( PDJ this, DWORD dwAxisMask, PCAXISMAPPINGS pamap )
{
HRESULT hres;
/*
* Prefix warns (mb:34681) that the pointer would be null if the
* number of objects on the device is zero.
* This cannot be, so assert it but don't check in retail.
*/
AssertF( this->dc.dwAxes + this->dc.dwPOVs + this->dc.dwButtons != 0 );
if( SUCCEEDED( hres = AllocCbPpv(cbCxX(
(this->dc.dwAxes + this->dc.dwPOVs + this->dc.dwButtons ), DIDOBJDEFSEM),
&this->rgObjSem) ) )
{
UINT Idx;
PDIDOBJDEFSEM pObjSem = this->rgObjSem;
LPDIOBJECTDATAFORMAT podf;
/*
* The axis mapping table does most of the work
*/
for( Idx = 0; Idx < cA(c_rgaattrJoy); Idx++ )
{
PCAXISATTRIBUTES paattr = &c_rgaattrJoy[Idx];
if( dwAxisMask & c_rgaattrJoy[Idx].dwMask)
{
pObjSem->dwID = DIDFT_ABSAXIS | DIDFT_MAKEINSTANCE(c_rgaattrJoy[Idx].uidObj);
pObjSem->dwSemantic = pamap[Idx].dwSemantic;
pObjSem++;
}
}
AssertF( pObjSem == &this->rgObjSem[this->dc.dwAxes] );
/*
* POVs and buttons require no look ups.
*/
for( Idx = 0; Idx < this->dc.dwPOVs; Idx++ )
{
pObjSem->dwID = DIDFT_POV | DIDFT_MAKEINSTANCE(Idx);
pObjSem->dwSemantic = DISEM_TYPE_POV | DISEM_INDEX_SET(Idx+1);
pObjSem++;
}
AssertF( pObjSem == &this->rgObjSem[this->dc.dwAxes + this->dc.dwPOVs] );
for( Idx = 0; Idx < this->dc.dwButtons; Idx++ )
{
pObjSem->dwID = DIDFT_PSHBUTTON | DIDFT_MAKEINSTANCE(Idx);
pObjSem->dwSemantic = DISEM_TYPE_BUTTON | DISEM_INDEX_SET(Idx+1);
pObjSem++;
}
AssertF( pObjSem == &this->rgObjSem[this->dc.dwAxes + this->dc.dwPOVs + this->dc.dwButtons] );
/*
* Now go back to pick up any extra type bits, such as FF.
* Because we use the same order in creating the semantic table as
* is used to create the data format, this is optimized to only
* search from where the previous match was found. We cannot rely
* on a one-to-one mapping because of the non-positional axes.
*/
podf = &this->df.rgodf[this->df.dwNumObjs];
for( pObjSem--; pObjSem >= this->rgObjSem; pObjSem-- )
{
do
{
podf--;
if( ( podf->dwType & (DIDFT_INSTANCEMASK | DIDFT_TYPEMASK) )
== pObjSem->dwID )
{
pObjSem->dwID = podf->dwType;
break;
}
} while( podf >= this->df.rgodf );
AssertF( podf >= this->df.rgodf );
}
}
return hres;
}
/*****************************************************************************
*
* @doc INTERNAL
*
* @method HRESULT | CJoy | InitRing3 |
*
* Initialize the ring 3 information maintained about the object.
*
* Broken out from CJoy_Init to make things less monolithic.
*
*****************************************************************************/
HRESULT INTERNAL
CJoy_InitRing3(PDJ this )
{
HRESULT hres;
VXDAXISCAPS vac;
PCAXISMAPPINGS pamap;
/*
* We must ask for DIJC_CALLOUT even though we don't care,
* because that will trigger the Microsoft Gamepad hack-o-rama.
*/
hres = JoyReg_GetConfig(this->idJoy, &this->cfg,
DIJC_REGHWCONFIGTYPE | DIJC_CALLOUT );
if (SUCCEEDED(hres)) {
/*
* Fix phantom devices bug. See manbug: 23186
*/
if( this->cfg.hwc.dwType == JOY_HW_NONE ) {
hres = E_FAIL;
goto done;
}
/*
* Open the type key so we can grovel into the type info.
* If the RegOpenKeyEx fails, the value of this->hkType
* will stay zero so we won't run with garbage.
*
* Note that failure to open the type key is not an error.
*
* We need to do this before building the data format, because
* BuildDataFormat needs the hkType to get the attributes.
*/
AssertF(this->hkType == 0);
/*
* Only open the key if it is intended to exist
*/
if( this->cfg.hwc.dwUsageSettings & JOY_US_ISOEM )
{
JoyReg_OpenTypeKey(this->cfg.wszType, MAXIMUM_ALLOWED,
REG_OPTION_NON_VOLATILE, &this->hkType);
}
if FAILED (JoyReg_OpenPropKey(this->cfg.wszType, MAXIMUM_ALLOWED, REG_OPTION_NON_VOLATILE, &this->hkProp))
{
/*
* If we fail to open the prop key - we will continue to function with loss in functionality
* Specifically no device images, etc
*/
}
hres = Hel_Joy_GetAxisCaps(this->idJoy, &vac, &this->cfg.hwc );
/*
* HACKHACK
* In the case of a DX5 VJoyD, the POV0 flag can be stripped out of
* the vac if the poll returns a POV0 value other than (DWORD)-1.
* So add it back if the registry says we have it.
*/
if( this->cfg.hwc.hws.dwFlags & JOY_HWS_HASPOV )
{
DWORD dwVersion = GetVersion();
/*
* Check for any Win95 version
*/
if( ( LOBYTE( dwVersion ) == 4 )
&& ( HIBYTE( LOWORD( dwVersion ) ) < 10 ) )
{
vac.dwPos |= JOYPF_POV0;
}
}
AssertF(SUCCEEDED(hres));
/*
* Previous versions of DInput allow a POV granularity of 1 if
* joyGetCaps returned a wCaps with JOYCAPS_POV4DIR set.
* This does no good as neither drivers nor WinMM really
* support this.
*/
this->dwPOVGranularity = 9000;
/*
* Logical ranges must be done before physical ranges,
* because initializing the physical ranges will also
* recompute the ramp conversion parameters.
*/
CJoy_InitLogRanges(this);
CJoy_InitPhysRanges(this, &this->cfg.hwc);
/*
* Need to init from HWC before building real data format so type
* overrides can be taken into account. Unfortunately, until the
* data format is built, we don't know what axes are available.
* Since the code is already here, build the data format again.
* Use the joystick look-ups and don't bother with registry flags.
*/
CJoy_BuildDataFormat(this, &vac, this->cfg.hwc.hws.dwNumButtons, c_rgamapJoy, FALSE );
hres = CJoy_InitFromHwc( this );
if( SUCCEEDED( hres ) )
{
CJoy_GetAxisMap( this, &pamap );
/*
* At last, time to build the data format for real
*/
CJoy_BuildDataFormat(this, &vac, this->cfg.hwc.hws.dwNumButtons, pamap, TRUE );
hres = CJoy_InitSemanticMap( this, vac.dwPos, pamap );
}
#ifndef WINNT
if( this->hkType )
{
DWORD dwFlags1;
if( SUCCEEDED( JoyReg_GetValue( this->hkType,
REGSTR_VAL_FLAGS1, REG_BINARY,
&dwFlags1,
cbX(dwFlags1) ) ) )
{
if( dwFlags1 & JOYTYPE_NOHIDDIRECT )
{
this->dc.dwFlags &= ~DIDC_ALIAS;
}
}
}
#endif
this->diHacks.nMaxDeviceNameLength = MAX_PATH;
} else {
RPF("Unexpected error 0x%08x obtaining joystick capabilities",hres);
hres = E_FAIL;
}
done:
return hres;
}
/*****************************************************************************
*
* @doc INTERNAL
*
* @method HRESULT | CJoy | Init |
*
* Initialize the object by establishing the data format
* based on the joystick capabilities.
*
*****************************************************************************/
HRESULT INTERNAL
CJoy_Init(PDJ this, REFGUID rguid)
{
HRESULT hres;
EnterProc(CJoy_Init, (_ "pG", this, rguid));
this->idJoy = rguid->Data1 & 0xF;
/* If joystick number is vaguely valid */
if (this->idJoy < cJoyMax) {
if (SUCCEEDED(hres = CJoy_PreInit(this)) &&
SUCCEEDED(hres = CJoy_InitRing0(this)) &&
SUCCEEDED(hres = CJoy_InitRing3(this))) {
}
} else {
hres = DIERR_DEVICENOTREG;
}
ExitOleProc();
return hres;
}
/*****************************************************************************
*
* CJoy_New (constructor)
*
*****************************************************************************/
STDMETHODIMP
CJoy_New(PUNK punkOuter, REFGUID rguid, RIID riid, PPV ppvObj)
{
HRESULT hres;
EnterProcI(IDirectInputDeviceCallback::Joy::<constructor>,
(_ "Gp", riid, ppvObj));
hres = Common_NewRiid(CJoy, punkOuter, riid, ppvObj);
if (SUCCEEDED(hres)) {
/* Must use _thisPv in case of aggregation */
PDJ this = _thisPv(*ppvObj);
if (SUCCEEDED(hres = CJoy_Init(this, rguid))) {
} else {
Invoke_Release(ppvObj);
}
}
ExitOleProcPpvR(ppvObj);
return hres;
}
/*****************************************************************************
*
* @doc INTERNAL
*
* @method HRESULT | CJoy | SetDIData |
*
* Set DirectInput version and apphack data from CDIDev *.
*
* @parm DWORD | dwVer |
*
* DirectInput version
*
* @parm LPVOID | lpdihacks |
*
* AppHack data
*
* @returns
*
* <c S_OK> because we cannot fail.
*
*****************************************************************************/
STDMETHODIMP
CJoy_SetDIData(PDICB pdcb, DWORD dwVer, LPVOID lpdihacks)
{
PDJ this;
EnterProcI(IDirectInputDeviceCallback::Joy::SetDIData,
(_ "pup", pdcb, dwVer, lpdihacks));
/*
* This is an internal interface, so we can skimp on validation.
*/
this = _thisPvNm(pdcb, dcb);
this->dwVersion = dwVer;
CopyMemory(&this->diHacks, (LPDIAPPHACKS)lpdihacks, sizeof(this->diHacks));
ExitProcR();
return S_OK;
}
/*****************************************************************************
*
* @doc INTERNAL
*
* @method HRESULT | CJoy | BuildDefaultActionMap |
*
* Generate default mappings for the objects on this device.
*
* @parm LPDIACTIONFORMATW | pActionFormat |
*
* Actions to map.
*
* @parm DWORD | dwFlags |
*
* Flags used to indicate mapping preferences.
*
* @parm REFGUID | guidInst |
*
* Device instance GUID.
*
* @returns
*
* <c E_NOTIMPL>
*
*****************************************************************************/
STDMETHODIMP
CJoy_BuildDefaultActionMap
(
PDICB pdcb,
LPDIACTIONFORMATW paf,
DWORD dwFlags,
REFGUID guidInst
)
{
HRESULT hres;
PDJ this;
PDIDOBJDEFSEM pObjDefSemTemp;
/*
* This is an internal interface, so we can skimp on validation.
*/
EnterProcI(IDirectInputDeviceCallback::Joy::BuildDefaultActionMap,
(_ "ppxG", pdcb, paf, dwFlags, guidInst));
this = _thisPvNm(pdcb, dcb);
/*
* Prefix warns (win:199090) that the pointer would be null if the
* size of the semantic object list is zero.
* This cannot be, so assert it but don't check in retail.
*/
AssertF( cbCxX( this->dc.dwAxes + this->dc.dwPOVs + this->dc.dwButtons, DIDOBJDEFSEM ) );
hres = AllocCbPpv( cbCxX(
( this->dc.dwAxes + this->dc.dwPOVs + this->dc.dwButtons ), DIDOBJDEFSEM ),
&pObjDefSemTemp );
if( SUCCEEDED( hres ) )
{
memcpy( pObjDefSemTemp, this->rgObjSem, cbCxX(
( this->dc.dwAxes + this->dc.dwPOVs + this->dc.dwButtons ), DIDOBJDEFSEM ) );
hres = CMap_BuildDefaultDevActionMap( paf, dwFlags, guidInst,
pObjDefSemTemp, this->dc.dwAxes, this->dc.dwPOVs, this->dc.dwButtons );
FreePv( pObjDefSemTemp );
}
ExitOleProcR();
return hres;
}
/*****************************************************************************
*
* The long-awaited vtbls and templates
*
*****************************************************************************/
#define CJoy_Signature 0x2044424B /* "Joy " */
Interface_Template_Begin(CJoy)
Primary_Interface_Template(CJoy, IDirectInputDeviceCallback)
Interface_Template_End(CJoy)
Primary_Interface_Begin(CJoy, IDirectInputDeviceCallback)
CJoy_GetInstance,
CJoy_GetVersions,
CJoy_GetDataFormat,
CJoy_GetObjectInfo,
CJoy_GetCapabilities,
CDefDcb_Acquire,
CDefDcb_Unacquire,
CJoy_GetDeviceState,
CJoy_GetDeviceInfo,
CJoy_GetProperty,
CJoy_SetProperty,
CDefDcb_SetEventNotification,
CJoy_SetCooperativeLevel,
CJoy_RunControlPanel,
CJoy_CookDeviceData,
CJoy_CreateEffect,
CJoy_GetFFConfigKey,
CDefDcb_SendDeviceData,
CJoy_Poll,
CDefDcb_GetUsage,
CDefDcb_MapUsage,
CJoy_SetDIData,
CJoy_BuildDefaultActionMap,
Primary_Interface_End(CJoy, IDirectInputDeviceCallback)
#endif
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