Yucom/vrclient_x64/openvr_v0.9.17/openvr.h

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2018-01-18 20:29:49 +01:00
// openvr.h
//========= Copyright Valve Corporation ============//
// Dynamically generated file. Do not modify this file directly.
#ifndef _OPENVR_API
#define _OPENVR_API
#include <stdint.h>
// vrtypes.h
#ifndef _INCLUDE_VRTYPES_H
#define _INCLUDE_VRTYPES_H
namespace vr
{
#if defined(__linux__) || defined(__APPLE__)
// The 32-bit version of gcc has the alignment requirement for uint64 and double set to
// 4 meaning that even with #pragma pack(8) these types will only be four-byte aligned.
// The 64-bit version of gcc has the alignment requirement for these types set to
// 8 meaning that unless we use #pragma pack(4) our structures will get bigger.
// The 64-bit structure packing has to match the 32-bit structure packing for each platform.
#pragma pack( push, 4 )
#else
#pragma pack( push, 8 )
#endif
typedef void* glSharedTextureHandle_t;
typedef int32_t glInt_t;
typedef uint32_t glUInt_t;
// right-handed system
// +y is up
// +x is to the right
// -z is going away from you
// Distance unit is meters
struct HmdMatrix34_t
{
float m[3][4];
};
struct HmdMatrix44_t
{
float m[4][4];
};
struct HmdVector3_t
{
float v[3];
};
struct HmdVector4_t
{
float v[4];
};
struct HmdVector3d_t
{
double v[3];
};
struct HmdVector2_t
{
float v[2];
};
struct HmdQuaternion_t
{
double w, x, y, z;
};
struct HmdColor_t
{
float r, g, b, a;
};
struct HmdQuad_t
{
HmdVector3_t vCorners[ 4 ];
};
struct HmdRect2_t
{
HmdVector2_t vTopLeft;
HmdVector2_t vBottomRight;
};
/** Used to return the post-distortion UVs for each color channel.
* UVs range from 0 to 1 with 0,0 in the upper left corner of the
* source render target. The 0,0 to 1,1 range covers a single eye. */
struct DistortionCoordinates_t
{
float rfRed[2];
float rfGreen[2];
float rfBlue[2];
};
enum EVREye
{
Eye_Left = 0,
Eye_Right = 1
};
enum EGraphicsAPIConvention
{
API_DirectX = 0, // Normalized Z goes from 0 at the viewer to 1 at the far clip plane
API_OpenGL = 1, // Normalized Z goes from 1 at the viewer to -1 at the far clip plane
};
enum EColorSpace
{
ColorSpace_Auto = 0, // Assumes 'gamma' for 8-bit per component formats, otherwise 'linear'. This mirrors the DXGI formats which have _SRGB variants.
ColorSpace_Gamma = 1, // Texture data can be displayed directly on the display without any conversion (a.k.a. display native format).
ColorSpace_Linear = 2, // Same as gamma but has been converted to a linear representation using DXGI's sRGB conversion algorithm.
};
struct Texture_t
{
void* handle; // Native d3d texture pointer or GL texture id.
EGraphicsAPIConvention eType;
EColorSpace eColorSpace;
};
enum ETrackingResult
{
TrackingResult_Uninitialized = 1,
TrackingResult_Calibrating_InProgress = 100,
TrackingResult_Calibrating_OutOfRange = 101,
TrackingResult_Running_OK = 200,
TrackingResult_Running_OutOfRange = 201,
};
static const uint32_t k_unTrackingStringSize = 32;
static const uint32_t k_unMaxDriverDebugResponseSize = 32768;
/** Used to pass device IDs to API calls */
typedef uint32_t TrackedDeviceIndex_t;
static const uint32_t k_unTrackedDeviceIndex_Hmd = 0;
static const uint32_t k_unMaxTrackedDeviceCount = 16;
static const uint32_t k_unTrackedDeviceIndexInvalid = 0xFFFFFFFF;
/** Describes what kind of object is being tracked at a given ID */
enum ETrackedDeviceClass
{
TrackedDeviceClass_Invalid = 0, // the ID was not valid.
TrackedDeviceClass_HMD = 1, // Head-Mounted Displays
TrackedDeviceClass_Controller = 2, // Tracked controllers
TrackedDeviceClass_TrackingReference = 4, // Camera and base stations that serve as tracking reference points
TrackedDeviceClass_Other = 1000,
};
/** Describes what specific role associated with a tracked device */
enum ETrackedControllerRole
{
TrackedControllerRole_Invalid = 0, // Invalid value for controller type
TrackedControllerRole_LeftHand = 1, // Tracked device associated with the left hand
TrackedControllerRole_RightHand = 2, // Tracked device associated with the right hand
};
/** describes a single pose for a tracked object */
struct TrackedDevicePose_t
{
HmdMatrix34_t mDeviceToAbsoluteTracking;
HmdVector3_t vVelocity; // velocity in tracker space in m/s
HmdVector3_t vAngularVelocity; // angular velocity in radians/s (?)
ETrackingResult eTrackingResult;
bool bPoseIsValid;
// This indicates that there is a device connected for this spot in the pose array.
// It could go from true to false if the user unplugs the device.
bool bDeviceIsConnected;
};
/** Identifies which style of tracking origin the application wants to use
* for the poses it is requesting */
enum ETrackingUniverseOrigin
{
TrackingUniverseSeated = 0, // Poses are provided relative to the seated zero pose
TrackingUniverseStanding = 1, // Poses are provided relative to the safe bounds configured by the user
TrackingUniverseRawAndUncalibrated = 2, // Poses are provided in the coordinate system defined by the driver. You probably don't want this one.
};
/** Each entry in this enum represents a property that can be retrieved about a
* tracked device. Many fields are only valid for one ETrackedDeviceClass. */
enum ETrackedDeviceProperty
{
// general properties that apply to all device classes
Prop_TrackingSystemName_String = 1000,
Prop_ModelNumber_String = 1001,
Prop_SerialNumber_String = 1002,
Prop_RenderModelName_String = 1003,
Prop_WillDriftInYaw_Bool = 1004,
Prop_ManufacturerName_String = 1005,
Prop_TrackingFirmwareVersion_String = 1006,
Prop_HardwareRevision_String = 1007,
Prop_AllWirelessDongleDescriptions_String = 1008,
Prop_ConnectedWirelessDongle_String = 1009,
Prop_DeviceIsWireless_Bool = 1010,
Prop_DeviceIsCharging_Bool = 1011,
Prop_DeviceBatteryPercentage_Float = 1012, // 0 is empty, 1 is full
Prop_StatusDisplayTransform_Matrix34 = 1013,
Prop_Firmware_UpdateAvailable_Bool = 1014,
Prop_Firmware_ManualUpdate_Bool = 1015,
Prop_Firmware_ManualUpdateURL_String = 1016,
Prop_HardwareRevision_Uint64 = 1017,
Prop_FirmwareVersion_Uint64 = 1018,
Prop_FPGAVersion_Uint64 = 1019,
Prop_VRCVersion_Uint64 = 1020,
Prop_RadioVersion_Uint64 = 1021,
Prop_DongleVersion_Uint64 = 1022,
Prop_BlockServerShutdown_Bool = 1023,
Prop_CanUnifyCoordinateSystemWithHmd_Bool = 1024,
Prop_ContainsProximitySensor_Bool = 1025,
Prop_DeviceProvidesBatteryStatus_Bool = 1026,
Prop_DeviceCanPowerOff_Bool = 1027,
Prop_Firmware_ProgrammingTarget_String = 1028,
Prop_DeviceClass_Int32 = 1029,
Prop_HasCamera_Bool = 1030,
// Properties that are unique to TrackedDeviceClass_HMD
Prop_ReportsTimeSinceVSync_Bool = 2000,
Prop_SecondsFromVsyncToPhotons_Float = 2001,
Prop_DisplayFrequency_Float = 2002,
Prop_UserIpdMeters_Float = 2003,
Prop_CurrentUniverseId_Uint64 = 2004,
Prop_PreviousUniverseId_Uint64 = 2005,
Prop_DisplayFirmwareVersion_Uint64 = 2006,
Prop_IsOnDesktop_Bool = 2007,
Prop_DisplayMCType_Int32 = 2008,
Prop_DisplayMCOffset_Float = 2009,
Prop_DisplayMCScale_Float = 2010,
Prop_EdidVendorID_Int32 = 2011,
Prop_DisplayMCImageLeft_String = 2012,
Prop_DisplayMCImageRight_String = 2013,
Prop_DisplayGCBlackClamp_Float = 2014,
Prop_EdidProductID_Int32 = 2015,
Prop_CameraToHeadTransform_Matrix34 = 2016,
Prop_DisplayGCType_Int32 = 2017,
Prop_DisplayGCOffset_Float = 2018,
Prop_DisplayGCScale_Float = 2019,
Prop_DisplayGCPrescale_Float = 2020,
Prop_DisplayGCImage_String = 2021,
Prop_LensCenterLeftU_Float = 2022,
Prop_LensCenterLeftV_Float = 2023,
Prop_LensCenterRightU_Float = 2024,
Prop_LensCenterRightV_Float = 2025,
Prop_UserHeadToEyeDepthMeters_Float = 2026,
Prop_CameraFirmwareVersion_Uint64 = 2027,
Prop_CameraFirmwareDescription_String = 2028,
Prop_DisplayFPGAVersion_Uint64 = 2029,
Prop_DisplayBootloaderVersion_Uint64 = 2030,
Prop_DisplayHardwareVersion_Uint64 = 2031,
Prop_AudioFirmwareVersion_Uint64 = 2032,
// Properties that are unique to TrackedDeviceClass_Controller
Prop_AttachedDeviceId_String = 3000,
Prop_SupportedButtons_Uint64 = 3001,
Prop_Axis0Type_Int32 = 3002, // Return value is of type EVRControllerAxisType
Prop_Axis1Type_Int32 = 3003, // Return value is of type EVRControllerAxisType
Prop_Axis2Type_Int32 = 3004, // Return value is of type EVRControllerAxisType
Prop_Axis3Type_Int32 = 3005, // Return value is of type EVRControllerAxisType
Prop_Axis4Type_Int32 = 3006, // Return value is of type EVRControllerAxisType
// Properties that are unique to TrackedDeviceClass_TrackingReference
Prop_FieldOfViewLeftDegrees_Float = 4000,
Prop_FieldOfViewRightDegrees_Float = 4001,
Prop_FieldOfViewTopDegrees_Float = 4002,
Prop_FieldOfViewBottomDegrees_Float = 4003,
Prop_TrackingRangeMinimumMeters_Float = 4004,
Prop_TrackingRangeMaximumMeters_Float = 4005,
Prop_ModeLabel_String = 4006,
// Vendors are free to expose private debug data in this reserved region
Prop_VendorSpecific_Reserved_Start = 10000,
Prop_VendorSpecific_Reserved_End = 10999,
};
/** No string property will ever be longer than this length */
static const uint32_t k_unMaxPropertyStringSize = 32 * 1024;
/** Used to return errors that occur when reading properties. */
enum ETrackedPropertyError
{
TrackedProp_Success = 0,
TrackedProp_WrongDataType = 1,
TrackedProp_WrongDeviceClass = 2,
TrackedProp_BufferTooSmall = 3,
TrackedProp_UnknownProperty = 4,
TrackedProp_InvalidDevice = 5,
TrackedProp_CouldNotContactServer = 6,
TrackedProp_ValueNotProvidedByDevice = 7,
TrackedProp_StringExceedsMaximumLength = 8,
TrackedProp_NotYetAvailable = 9, // The property value isn't known yet, but is expected soon. Call again later.
};
/** Allows the application to control what part of the provided texture will be used in the
* frame buffer. */
struct VRTextureBounds_t
{
float uMin, vMin;
float uMax, vMax;
};
/** Allows the applicaiton to control how scene textures are used by the compositor when calling Submit. */
enum EVRSubmitFlags
{
// Simple render path. App submits rendered left and right eye images with no lens distortion correction applied.
Submit_Default = 0x00,
// App submits final left and right eye images with lens distortion already applied (lens distortion makes the images appear
// barrel distorted with chromatic aberration correction applied). The app would have used the data returned by
// vr::IVRSystem::ComputeDistortion() to apply the correct distortion to the rendered images before calling Submit().
Submit_LensDistortionAlreadyApplied = 0x01,
// If the texture pointer passed in is actually a renderbuffer (e.g. for MSAA in OpenGL) then set this flag.
Submit_GlRenderBuffer = 0x02
};
/** Status of the overall system or tracked objects */
enum EVRState
{
VRState_Undefined = -1,
VRState_Off = 0,
VRState_Searching = 1,
VRState_Searching_Alert = 2,
VRState_Ready = 3,
VRState_Ready_Alert = 4,
VRState_NotReady = 5,
};
/** The types of events that could be posted (and what the parameters mean for each event type) */
enum EVREventType
{
VREvent_None = 0,
VREvent_TrackedDeviceActivated = 100,
VREvent_TrackedDeviceDeactivated = 101,
VREvent_TrackedDeviceUpdated = 102,
VREvent_TrackedDeviceUserInteractionStarted = 103,
VREvent_TrackedDeviceUserInteractionEnded = 104,
VREvent_IpdChanged = 105,
VREvent_EnterStandbyMode = 106,
VREvent_LeaveStandbyMode = 107,
VREvent_TrackedDeviceRoleChanged = 108,
VREvent_ButtonPress = 200, // data is controller
VREvent_ButtonUnpress = 201, // data is controller
VREvent_ButtonTouch = 202, // data is controller
VREvent_ButtonUntouch = 203, // data is controller
VREvent_MouseMove = 300, // data is mouse
VREvent_MouseButtonDown = 301, // data is mouse
VREvent_MouseButtonUp = 302, // data is mouse
VREvent_FocusEnter = 303, // data is overlay
VREvent_FocusLeave = 304, // data is overlay
VREvent_Scroll = 305, // data is mouse
VREvent_TouchPadMove = 306, // data is mouse
VREvent_InputFocusCaptured = 400, // data is process
VREvent_InputFocusReleased = 401, // data is process
VREvent_SceneFocusLost = 402, // data is process
VREvent_SceneFocusGained = 403, // data is process
VREvent_SceneApplicationChanged = 404, // data is process - The App actually drawing the scene changed (usually to or from the compositor)
VREvent_SceneFocusChanged = 405, // data is process - New app got access to draw the scene
VREvent_HideRenderModels = 410, // Sent to the scene application to request hiding render models temporarily
VREvent_ShowRenderModels = 411, // Sent to the scene application to request restoring render model visibility
VREvent_OverlayShown = 500,
VREvent_OverlayHidden = 501,
VREvent_DashboardActivated = 502,
VREvent_DashboardDeactivated = 503,
VREvent_DashboardThumbSelected = 504, // Sent to the overlay manager - data is overlay
VREvent_DashboardRequested = 505, // Sent to the overlay manager - data is overlay
VREvent_ResetDashboard = 506, // Send to the overlay manager
VREvent_RenderToast = 507, // Send to the dashboard to render a toast - data is the notification ID
VREvent_ImageLoaded = 508, // Sent to overlays when a SetOverlayRaw or SetOverlayFromFile call finishes loading
VREvent_ShowKeyboard = 509, // Sent to keyboard renderer in the dashboard to invoke it
VREvent_HideKeyboard = 510, // Sent to keyboard renderer in the dashboard to hide it
VREvent_OverlayGamepadFocusGained = 511, // Sent to an overlay when IVROverlay::SetFocusOverlay is called on it
VREvent_OverlayGamepadFocusLost = 512, // Send to an overlay when it previously had focus and IVROverlay::SetFocusOverlay is called on something else
VREvent_Notification_Shown = 600,
VREvent_Notification_Hidden = 601,
VREvent_Notification_BeginInteraction = 602,
VREvent_Notification_Destroyed = 603,
VREvent_Quit = 700, // data is process
VREvent_ProcessQuit = 701, // data is process
VREvent_QuitAborted_UserPrompt = 702, // data is process
VREvent_QuitAcknowledged = 703, // data is process
VREvent_ChaperoneDataHasChanged = 800,
VREvent_ChaperoneUniverseHasChanged = 801,
VREvent_ChaperoneTempDataHasChanged = 802,
VREvent_ChaperoneSettingsHaveChanged = 803,
VREvent_BackgroundSettingHasChanged = 850,
VREvent_CameraSettingsHaveChanged = 851,
VREvent_StatusUpdate = 900,
VREvent_MCImageUpdated = 1000,
VREvent_FirmwareUpdateStarted = 1100,
VREvent_FirmwareUpdateFinished = 1101,
VREvent_KeyboardClosed = 1200,
VREvent_KeyboardCharInput = 1201,
VREvent_KeyboardDone = 1202, // Sent when DONE button clicked on keyboard
VREvent_ApplicationTransitionStarted = 1300,
VREvent_ApplicationTransitionAborted = 1301,
VREvent_ApplicationTransitionNewAppStarted = 1302,
VREvent_Compositor_MirrorWindowShown = 1400,
VREvent_Compositor_MirrorWindowHidden = 1401,
VREvent_TrackedCamera_StartVideoStream = 1500,
VREvent_TrackedCamera_StopVideoStream = 1501,
VREvent_TrackedCamera_PauseVideoStream = 1502,
VREvent_TrackedCamera_ResumeVideoStream = 1503,
VREvent_PerformanceTest_EnableCapture = 1600,
VREvent_PerformanceTest_DisableCapture = 1601,
VREvent_PerformanceTest_FidelityLevel = 1602,
// Vendors are free to expose private events in this reserved region
VREvent_VendorSpecific_Reserved_Start = 10000,
VREvent_VendorSpecific_Reserved_End = 19999,
};
/** Level of Hmd activity */
enum EDeviceActivityLevel
{
k_EDeviceActivityLevel_Unknown = -1,
k_EDeviceActivityLevel_Idle = 0,
k_EDeviceActivityLevel_UserInteraction = 1,
k_EDeviceActivityLevel_UserInteraction_Timeout = 2,
k_EDeviceActivityLevel_Standby = 3,
};
/** VR controller button and axis IDs */
enum EVRButtonId
{
k_EButton_System = 0,
k_EButton_ApplicationMenu = 1,
k_EButton_Grip = 2,
k_EButton_DPad_Left = 3,
k_EButton_DPad_Up = 4,
k_EButton_DPad_Right = 5,
k_EButton_DPad_Down = 6,
k_EButton_A = 7,
k_EButton_Axis0 = 32,
k_EButton_Axis1 = 33,
k_EButton_Axis2 = 34,
k_EButton_Axis3 = 35,
k_EButton_Axis4 = 36,
// aliases for well known controllers
k_EButton_SteamVR_Touchpad = k_EButton_Axis0,
k_EButton_SteamVR_Trigger = k_EButton_Axis1,
k_EButton_Dashboard_Back = k_EButton_Grip,
k_EButton_Max = 64
};
inline uint64_t ButtonMaskFromId( EVRButtonId id ) { return 1ull << id; }
/** used for controller button events */
struct VREvent_Controller_t
{
uint32_t button; // EVRButtonId enum
};
/** used for simulated mouse events in overlay space */
enum EVRMouseButton
{
VRMouseButton_Left = 0x0001,
VRMouseButton_Right = 0x0002,
VRMouseButton_Middle = 0x0004,
};
/** used for simulated mouse events in overlay space */
struct VREvent_Mouse_t
{
float x, y; // co-ords are in GL space, bottom left of the texture is 0,0
uint32_t button; // EVRMouseButton enum
};
/** used for simulated mouse wheel scroll in overlay space */
struct VREvent_Scroll_t
{
float xdelta, ydelta; // movement in fraction of the pad traversed since last delta, 1.0 for a full swipe
uint32_t repeatCount;
};
/** when in mouse input mode you can receive data from the touchpad, these events are only sent if the users finger
is on the touchpad (or just released from it)
**/
struct VREvent_TouchPadMove_t
{
// true if the users finger is detected on the touch pad
bool bFingerDown;
// How long the finger has been down in seconds
float flSecondsFingerDown;
// These values indicate the starting finger position (so you can do some basic swipe stuff)
float fValueXFirst;
float fValueYFirst;
// This is the raw sampled coordinate without deadzoning
float fValueXRaw;
float fValueYRaw;
};
/** notification related events. Details will still change at this point */
struct VREvent_Notification_t
{
uint64_t ulUserValue;
uint32_t notificationId;
};
/** Used for events about processes */
struct VREvent_Process_t
{
uint32_t pid;
uint32_t oldPid;
bool bForced;
};
/** Used for a few events about overlays */
struct VREvent_Overlay_t
{
uint64_t overlayHandle;
};
/** Used for a few events about overlays */
struct VREvent_Status_t
{
uint32_t statusState; // EVRState enum
};
/** Used for keyboard events **/
struct VREvent_Keyboard_t
{
char cNewInput[8]; // Up to 11 bytes of new input
uint64_t uUserValue; // Possible flags about the new input
};
struct VREvent_Ipd_t
{
float ipdMeters;
};
struct VREvent_Chaperone_t
{
uint64_t m_nPreviousUniverse;
uint64_t m_nCurrentUniverse;
};
/** Not actually used for any events */
struct VREvent_Reserved_t
{
uint64_t reserved0;
uint64_t reserved1;
};
struct VREvent_PerformanceTest_t
{
uint32_t m_nFidelityLevel;
};
/** If you change this you must manually update openvr_interop.cs.py */
typedef union
{
VREvent_Reserved_t reserved;
VREvent_Controller_t controller;
VREvent_Mouse_t mouse;
VREvent_Scroll_t scroll;
VREvent_Process_t process;
VREvent_Notification_t notification;
VREvent_Overlay_t overlay;
VREvent_Status_t status;
VREvent_Keyboard_t keyboard;
VREvent_Ipd_t ipd;
VREvent_Chaperone_t chaperone;
VREvent_PerformanceTest_t performanceTest;
VREvent_TouchPadMove_t touchPadMove;
} VREvent_Data_t;
/** An event posted by the server to all running applications */
struct VREvent_t
{
uint32_t eventType; // EVREventType enum
TrackedDeviceIndex_t trackedDeviceIndex;
float eventAgeSeconds;
// event data must be the end of the struct as its size is variable
VREvent_Data_t data;
};
/** The mesh to draw into the stencil (or depth) buffer to perform
* early stencil (or depth) kills of pixels that will never appear on the HMD.
* This mesh draws on all the pixels that will be hidden after distortion.
*
* If the HMD does not provide a visible area mesh pVertexData will be
* NULL and unTriangleCount will be 0. */
struct HiddenAreaMesh_t
{
const HmdVector2_t *pVertexData;
uint32_t unTriangleCount;
};
/** Identifies what kind of axis is on the controller at index n. Read this type
* with pVRSystem->Get( nControllerDeviceIndex, Prop_Axis0Type_Int32 + n );
*/
enum EVRControllerAxisType
{
k_eControllerAxis_None = 0,
k_eControllerAxis_TrackPad = 1,
k_eControllerAxis_Joystick = 2,
k_eControllerAxis_Trigger = 3, // Analog trigger data is in the X axis
};
/** contains information about one axis on the controller */
struct VRControllerAxis_t
{
float x; // Ranges from -1.0 to 1.0 for joysticks and track pads. Ranges from 0.0 to 1.0 for triggers were 0 is fully released.
float y; // Ranges from -1.0 to 1.0 for joysticks and track pads. Is always 0.0 for triggers.
};
/** the number of axes in the controller state */
static const uint32_t k_unControllerStateAxisCount = 5;
/** Holds all the state of a controller at one moment in time. */
struct VRControllerState001_t
{
// If packet num matches that on your prior call, then the controller state hasn't been changed since
// your last call and there is no need to process it
uint32_t unPacketNum;
// bit flags for each of the buttons. Use ButtonMaskFromId to turn an ID into a mask
uint64_t ulButtonPressed;
uint64_t ulButtonTouched;
// Axis data for the controller's analog inputs
VRControllerAxis_t rAxis[ k_unControllerStateAxisCount ];
};
typedef VRControllerState001_t VRControllerState_t;
/** determines how to provide output to the application of various event processing functions. */
enum EVRControllerEventOutputType
{
ControllerEventOutput_OSEvents = 0,
ControllerEventOutput_VREvents = 1,
};
/** Collision Bounds Style */
enum ECollisionBoundsStyle
{
COLLISION_BOUNDS_STYLE_BEGINNER = 0,
COLLISION_BOUNDS_STYLE_INTERMEDIATE,
COLLISION_BOUNDS_STYLE_SQUARES,
COLLISION_BOUNDS_STYLE_ADVANCED,
COLLISION_BOUNDS_STYLE_NONE,
COLLISION_BOUNDS_STYLE_COUNT
};
/** Allows the application to customize how the overlay appears in the compositor */
struct Compositor_OverlaySettings
{
uint32_t size; // sizeof(Compositor_OverlaySettings)
bool curved, antialias;
float scale, distance, alpha;
float uOffset, vOffset, uScale, vScale;
float gridDivs, gridWidth, gridScale;
HmdMatrix44_t transform;
};
/** used to refer to a single VR overlay */
typedef uint64_t VROverlayHandle_t;
static const VROverlayHandle_t k_ulOverlayHandleInvalid = 0;
/** Errors that can occur around VR overlays */
enum EVROverlayError
{
VROverlayError_None = 0,
VROverlayError_UnknownOverlay = 10,
VROverlayError_InvalidHandle = 11,
VROverlayError_PermissionDenied = 12,
VROverlayError_OverlayLimitExceeded = 13, // No more overlays could be created because the maximum number already exist
VROverlayError_WrongVisibilityType = 14,
VROverlayError_KeyTooLong = 15,
VROverlayError_NameTooLong = 16,
VROverlayError_KeyInUse = 17,
VROverlayError_WrongTransformType = 18,
VROverlayError_InvalidTrackedDevice = 19,
VROverlayError_InvalidParameter = 20,
VROverlayError_ThumbnailCantBeDestroyed = 21,
VROverlayError_ArrayTooSmall = 22,
VROverlayError_RequestFailed = 23,
VROverlayError_InvalidTexture = 24,
VROverlayError_UnableToLoadFile = 25,
VROVerlayError_KeyboardAlreadyInUse = 26,
VROverlayError_NoNeighbor = 27,
};
/** enum values to pass in to VR_Init to identify whether the application will
* draw a 3D scene. */
enum EVRApplicationType
{
VRApplication_Other = 0, // Some other kind of application that isn't covered by the other entries
VRApplication_Scene = 1, // Application will submit 3D frames
VRApplication_Overlay = 2, // Application only interacts with overlays
VRApplication_Background = 3, // Application should not start SteamVR if it's not already running, and should not
// keep it running if everything else quits.
VRApplication_Utility = 4, // Init should not try to load any drivers. The application needs access to utility
// interfaces (like IVRSettings and IVRApplications) but not hardware.
};
/** error codes for firmware */
enum EVRFirmwareError
{
VRFirmwareError_None = 0,
VRFirmwareError_Success = 1,
VRFirmwareError_Fail = 2,
};
/** error codes for notifications */
enum EVRNotificationError
{
VRNotificationError_OK = 0,
VRNotificationError_InvalidNotificationId = 100,
VRNotificationError_NotificationQueueFull = 101,
VRNotificationError_InvalidOverlayHandle = 102,
};
/** error codes returned by Vr_Init */
// Please add adequate error description to https://developer.valvesoftware.com/w/index.php?title=Category:SteamVRHelp
enum EVRInitError
{
VRInitError_None = 0,
VRInitError_Unknown = 1,
VRInitError_Init_InstallationNotFound = 100,
VRInitError_Init_InstallationCorrupt = 101,
VRInitError_Init_VRClientDLLNotFound = 102,
VRInitError_Init_FileNotFound = 103,
VRInitError_Init_FactoryNotFound = 104,
VRInitError_Init_InterfaceNotFound = 105,
VRInitError_Init_InvalidInterface = 106,
VRInitError_Init_UserConfigDirectoryInvalid = 107,
VRInitError_Init_HmdNotFound = 108,
VRInitError_Init_NotInitialized = 109,
VRInitError_Init_PathRegistryNotFound = 110,
VRInitError_Init_NoConfigPath = 111,
VRInitError_Init_NoLogPath = 112,
VRInitError_Init_PathRegistryNotWritable = 113,
VRInitError_Init_AppInfoInitFailed = 114,
VRInitError_Init_Retry = 115, // Used internally to cause retries to vrserver
VRInitError_Init_InitCanceledByUser = 116, // The calling application should silently exit. The user canceled app startup
VRInitError_Init_AnotherAppLaunching = 117,
VRInitError_Init_SettingsInitFailed = 118,
VRInitError_Init_ShuttingDown = 119,
VRInitError_Init_TooManyObjects = 120,
VRInitError_Init_NoServerForBackgroundApp = 121,
VRInitError_Init_NotSupportedWithCompositor = 122,
VRInitError_Init_NotAvailableToUtilityApps = 123,
VRInitError_Driver_Failed = 200,
VRInitError_Driver_Unknown = 201,
VRInitError_Driver_HmdUnknown = 202,
VRInitError_Driver_NotLoaded = 203,
VRInitError_Driver_RuntimeOutOfDate = 204,
VRInitError_Driver_HmdInUse = 205,
VRInitError_Driver_NotCalibrated = 206,
VRInitError_Driver_CalibrationInvalid = 207,
VRInitError_Driver_HmdDisplayNotFound = 208,
VRInitError_IPC_ServerInitFailed = 300,
VRInitError_IPC_ConnectFailed = 301,
VRInitError_IPC_SharedStateInitFailed = 302,
VRInitError_IPC_CompositorInitFailed = 303,
VRInitError_IPC_MutexInitFailed = 304,
VRInitError_IPC_Failed = 305,
VRInitError_Compositor_Failed = 400,
VRInitError_Compositor_D3D11HardwareRequired = 401,
VRInitError_VendorSpecific_UnableToConnectToOculusRuntime = 1000,
VRInitError_VendorSpecific_HmdFound_CantOpenDevice = 1101,
VRInitError_VendorSpecific_HmdFound_UnableToRequestConfigStart = 1102,
VRInitError_VendorSpecific_HmdFound_NoStoredConfig = 1103,
VRInitError_VendorSpecific_HmdFound_ConfigTooBig = 1104,
VRInitError_VendorSpecific_HmdFound_ConfigTooSmall = 1105,
VRInitError_VendorSpecific_HmdFound_UnableToInitZLib = 1106,
VRInitError_VendorSpecific_HmdFound_CantReadFirmwareVersion = 1107,
VRInitError_VendorSpecific_HmdFound_UnableToSendUserDataStart = 1108,
VRInitError_VendorSpecific_HmdFound_UnableToGetUserDataStart = 1109,
VRInitError_VendorSpecific_HmdFound_UnableToGetUserDataNext = 1110,
VRInitError_VendorSpecific_HmdFound_UserDataAddressRange = 1111,
VRInitError_VendorSpecific_HmdFound_UserDataError = 1112,
VRInitError_VendorSpecific_HmdFound_ConfigFailedSanityCheck = 1113,
VRInitError_Steam_SteamInstallationNotFound = 2000,
};
#pragma pack( pop )
// figure out how to import from the VR API dll
#if defined(_WIN32)
#ifdef VR_API_EXPORT
#define VR_INTERFACE extern "C" __declspec( dllexport )
#else
#define VR_INTERFACE extern "C" __declspec( dllimport )
#endif
#elif defined(GNUC) || defined(COMPILER_GCC) || defined(__APPLE__)
#ifdef VR_API_EXPORT
#define VR_INTERFACE extern "C" __attribute__((visibility("default")))
#else
#define VR_INTERFACE extern "C"
#endif
#else
#error "Unsupported Platform."
#endif
#if defined( _WIN32 )
#define VR_CALLTYPE __cdecl
#else
#define VR_CALLTYPE
#endif
}
#endif // _INCLUDE_VRTYPES_H
// vrannotation.h
#ifdef API_GEN
# define VR_CLANG_ATTR(ATTR) __attribute__((annotate( ATTR )))
#else
# define VR_CLANG_ATTR(ATTR)
#endif
#define VR_METHOD_DESC(DESC) VR_CLANG_ATTR( "desc:" #DESC ";" )
#define VR_IGNOREATTR() VR_CLANG_ATTR( "ignore" )
#define VR_OUT_STRUCT() VR_CLANG_ATTR( "out_struct: ;" )
#define VR_OUT_STRING() VR_CLANG_ATTR( "out_string: ;" )
#define VR_OUT_ARRAY_CALL(COUNTER,FUNCTION,PARAMS) VR_CLANG_ATTR( "out_array_call:" #COUNTER "," #FUNCTION "," #PARAMS ";" )
#define VR_OUT_ARRAY_COUNT(COUNTER) VR_CLANG_ATTR( "out_array_count:" #COUNTER ";" )
#define VR_ARRAY_COUNT(COUNTER) VR_CLANG_ATTR( "array_count:" #COUNTER ";" )
#define VR_ARRAY_COUNT_D(COUNTER, DESC) VR_CLANG_ATTR( "array_count:" #COUNTER ";desc:" #DESC )
#define VR_BUFFER_COUNT(COUNTER) VR_CLANG_ATTR( "buffer_count:" #COUNTER ";" )
#define VR_OUT_BUFFER_COUNT(COUNTER) VR_CLANG_ATTR( "out_buffer_count:" #COUNTER ";" )
#define VR_OUT_STRING_COUNT(COUNTER) VR_CLANG_ATTR( "out_string_count:" #COUNTER ";" )
// ivrsystem.h
namespace vr
{
class IVRSystem
{
public:
// ------------------------------------
// Display Methods
// ------------------------------------
/** Suggested size for the intermediate render target that the distortion pulls from. */
virtual void GetRecommendedRenderTargetSize( uint32_t *pnWidth, uint32_t *pnHeight ) = 0;
/** The projection matrix for the specified eye */
virtual HmdMatrix44_t GetProjectionMatrix( EVREye eEye, float fNearZ, float fFarZ, EGraphicsAPIConvention eProjType ) = 0;
/** The components necessary to build your own projection matrix in case your
* application is doing something fancy like infinite Z */
virtual void GetProjectionRaw( EVREye eEye, float *pfLeft, float *pfRight, float *pfTop, float *pfBottom ) = 0;
/** Returns the result of the distortion function for the specified eye and input UVs. UVs go from 0,0 in
* the upper left of that eye's viewport and 1,1 in the lower right of that eye's viewport. */
virtual DistortionCoordinates_t ComputeDistortion( EVREye eEye, float fU, float fV ) = 0;
/** Returns the transform from eye space to the head space. Eye space is the per-eye flavor of head
* space that provides stereo disparity. Instead of Model * View * Projection the sequence is Model * View * Eye^-1 * Projection.
* Normally View and Eye^-1 will be multiplied together and treated as View in your application.
*/
virtual HmdMatrix34_t GetEyeToHeadTransform( EVREye eEye ) = 0;
/** Returns the number of elapsed seconds since the last recorded vsync event. This
* will come from a vsync timer event in the timer if possible or from the application-reported
* time if that is not available. If no vsync times are available the function will
* return zero for vsync time and frame counter and return false from the method. */
virtual bool GetTimeSinceLastVsync( float *pfSecondsSinceLastVsync, uint64_t *pulFrameCounter ) = 0;
/** [D3D9 Only]
* Returns the adapter index that the user should pass into CreateDevice to set up D3D9 in such
* a way that it can go full screen exclusive on the HMD. Returns -1 if there was an error.
*/
virtual int32_t GetD3D9AdapterIndex() = 0;
/** [D3D10/11 Only]
* Returns the adapter index and output index that the user should pass into EnumAdapters and EnumOutputs
* to create the device and swap chain in DX10 and DX11. If an error occurs both indices will be set to -1.
*/
virtual void GetDXGIOutputInfo( int32_t *pnAdapterIndex ) = 0;
// ------------------------------------
// Display Mode methods
// ------------------------------------
/** Use to determine if the headset display is part of the desktop (i.e. extended) or hidden (i.e. direct mode). */
virtual bool IsDisplayOnDesktop() = 0;
/** Set the display visibility (true = extended, false = direct mode). Return value of true indicates that the change was successful. */
virtual bool SetDisplayVisibility( bool bIsVisibleOnDesktop ) = 0;
// ------------------------------------
// Tracking Methods
// ------------------------------------
/** The pose that the tracker thinks that the HMD will be in at the specified number of seconds into the
* future. Pass 0 to get the state at the instant the method is called. Most of the time the application should
* calculate the time until the photons will be emitted from the display and pass that time into the method.
*
* This is roughly analogous to the inverse of the view matrix in most applications, though
* many games will need to do some additional rotation or translation on top of the rotation
* and translation provided by the head pose.
*
* For devices where bPoseIsValid is true the application can use the pose to position the device
* in question. The provided array can be any size up to k_unMaxTrackedDeviceCount.
*
* Seated experiences should call this method with TrackingUniverseSeated and receive poses relative
* to the seated zero pose. Standing experiences should call this method with TrackingUniverseStanding
* and receive poses relative to the Chaperone Play Area. TrackingUniverseRawAndUncalibrated should
* probably not be used unless the application is the Chaperone calibration tool itself, but will provide
* poses relative to the hardware-specific coordinate system in the driver.
*/
virtual void GetDeviceToAbsoluteTrackingPose( ETrackingUniverseOrigin eOrigin, float fPredictedSecondsToPhotonsFromNow, VR_ARRAY_COUNT(unTrackedDevicePoseArrayCount) TrackedDevicePose_t *pTrackedDevicePoseArray, uint32_t unTrackedDevicePoseArrayCount ) = 0;
/** Sets the zero pose for the seated tracker coordinate system to the current position and yaw of the HMD. After
* ResetSeatedZeroPose all GetDeviceToAbsoluteTrackingPose calls that pass TrackingUniverseSeated as the origin
* will be relative to this new zero pose. The new zero coordinate system will not change the fact that the Y axis
* is up in the real world, so the next pose returned from GetDeviceToAbsoluteTrackingPose after a call to
* ResetSeatedZeroPose may not be exactly an identity matrix.
*
* NOTE: This function overrides the user's previously saved seated zero pose and should only be called as the result of a user action.
* Users are also able to set their seated zero pose via the OpenVR Dashboard.
**/
virtual void ResetSeatedZeroPose() = 0;
/** Returns the transform from the seated zero pose to the standing absolute tracking system. This allows
* applications to represent the seated origin to used or transform object positions from one coordinate
* system to the other.
*
* The seated origin may or may not be inside the Play Area or Collision Bounds returned by IVRChaperone. Its position
* depends on what the user has set from the Dashboard settings and previous calls to ResetSeatedZeroPose. */
virtual HmdMatrix34_t GetSeatedZeroPoseToStandingAbsoluteTrackingPose() = 0;
/** Returns the transform from the tracking origin to the standing absolute tracking system. This allows
* applications to convert from raw tracking space to the calibrated standing coordinate system. */
virtual HmdMatrix34_t GetRawZeroPoseToStandingAbsoluteTrackingPose() = 0;
/** Get a sorted array of device indices of a given class of tracked devices (e.g. controllers). Devices are sorted right to left
* relative to the specified tracked device (default: hmd -- pass in -1 for absolute tracking space). Returns the number of devices
* in the list, or the size of the array needed if not large enough. */
virtual uint32_t GetSortedTrackedDeviceIndicesOfClass( ETrackedDeviceClass eTrackedDeviceClass, VR_ARRAY_COUNT(unTrackedDeviceIndexArrayCount) vr::TrackedDeviceIndex_t *punTrackedDeviceIndexArray, uint32_t unTrackedDeviceIndexArrayCount, vr::TrackedDeviceIndex_t unRelativeToTrackedDeviceIndex = k_unTrackedDeviceIndex_Hmd ) = 0;
/** Returns the level of activity on the device. */
virtual EDeviceActivityLevel GetTrackedDeviceActivityLevel( vr::TrackedDeviceIndex_t unDeviceId ) = 0;
/** Convenience utility to apply the specified transform to the specified pose.
* This properly transforms all pose components, including velocity and angular velocity
*/
virtual void ApplyTransform( TrackedDevicePose_t *pOutputPose, const TrackedDevicePose_t *pTrackedDevicePose, const HmdMatrix34_t *pTransform ) = 0;
/** Returns the device index associated with a specific role, for example the left hand or the right hand. */
virtual vr::TrackedDeviceIndex_t GetTrackedDeviceIndexForControllerRole( vr::ETrackedControllerRole unDeviceType ) = 0;
/** Returns the controller type associated with a device index. */
virtual vr::ETrackedControllerRole GetControllerRoleForTrackedDeviceIndex( vr::TrackedDeviceIndex_t unDeviceIndex ) = 0;
// ------------------------------------
// Property methods
// ------------------------------------
/** Returns the device class of a tracked device. If there has not been a device connected in this slot
* since the application started this function will return TrackedDevice_Invalid. For previous detected
* devices the function will return the previously observed device class.
*
* To determine which devices exist on the system, just loop from 0 to k_unMaxTrackedDeviceCount and check
* the device class. Every device with something other than TrackedDevice_Invalid is associated with an
* actual tracked device. */
virtual ETrackedDeviceClass GetTrackedDeviceClass( vr::TrackedDeviceIndex_t unDeviceIndex ) = 0;
/** Returns true if there is a device connected in this slot. */
virtual bool IsTrackedDeviceConnected( vr::TrackedDeviceIndex_t unDeviceIndex ) = 0;
/** Returns a bool property. If the device index is not valid or the property is not a bool type this function will return false. */
virtual bool GetBoolTrackedDeviceProperty( vr::TrackedDeviceIndex_t unDeviceIndex, ETrackedDeviceProperty prop, ETrackedPropertyError *pError = 0L ) = 0;
/** Returns a float property. If the device index is not valid or the property is not a float type this function will return 0. */
virtual float GetFloatTrackedDeviceProperty( vr::TrackedDeviceIndex_t unDeviceIndex, ETrackedDeviceProperty prop, ETrackedPropertyError *pError = 0L ) = 0;
/** Returns an int property. If the device index is not valid or the property is not a int type this function will return 0. */
virtual int32_t GetInt32TrackedDeviceProperty( vr::TrackedDeviceIndex_t unDeviceIndex, ETrackedDeviceProperty prop, ETrackedPropertyError *pError = 0L ) = 0;
/** Returns a uint64 property. If the device index is not valid or the property is not a uint64 type this function will return 0. */
virtual uint64_t GetUint64TrackedDeviceProperty( vr::TrackedDeviceIndex_t unDeviceIndex, ETrackedDeviceProperty prop, ETrackedPropertyError *pError = 0L ) = 0;
/** Returns a matrix property. If the device index is not valid or the property is not a matrix type, this function will return identity. */
virtual HmdMatrix34_t GetMatrix34TrackedDeviceProperty( vr::TrackedDeviceIndex_t unDeviceIndex, ETrackedDeviceProperty prop, ETrackedPropertyError *pError = 0L ) = 0;
/** Returns a string property. If the device index is not valid or the property is not a string type this function will
* return 0. Otherwise it returns the length of the number of bytes necessary to hold this string including the trailing
* null. Strings will generally fit in buffers of k_unTrackingStringSize characters. */
virtual uint32_t GetStringTrackedDeviceProperty( vr::TrackedDeviceIndex_t unDeviceIndex, ETrackedDeviceProperty prop, VR_OUT_STRING() char *pchValue, uint32_t unBufferSize, ETrackedPropertyError *pError = 0L ) = 0;
/** returns a string that corresponds with the specified property error. The string will be the name
* of the error enum value for all valid error codes */
virtual const char *GetPropErrorNameFromEnum( ETrackedPropertyError error ) = 0;
// ------------------------------------
// Event methods
// ------------------------------------
/** Returns true and fills the event with the next event on the queue if there is one. If there are no events
* this method returns false. uncbVREvent should be the size in bytes of the VREvent_t struct */
virtual bool PollNextEvent( VREvent_t *pEvent, uint32_t uncbVREvent ) = 0;
/** Returns true and fills the event with the next event on the queue if there is one. If there are no events
* this method returns false. Fills in the pose of the associated tracked device in the provided pose struct.
* This pose will always be older than the call to this function and should not be used to render the device.
uncbVREvent should be the size in bytes of the VREvent_t struct */
virtual bool PollNextEventWithPose( ETrackingUniverseOrigin eOrigin, vr::VREvent_t *pEvent, uint32_t uncbVREvent, vr::TrackedDevicePose_t *pTrackedDevicePose ) = 0;
/** returns the name of an EVREvent enum value */
virtual const char *GetEventTypeNameFromEnum( EVREventType eType ) = 0;
// ------------------------------------
// Rendering helper methods
// ------------------------------------
/** Returns the stencil mesh information for the current HMD. If this HMD does not have a stencil mesh the vertex data and count will be
* NULL and 0 respectively. This mesh is meant to be rendered into the stencil buffer (or into the depth buffer setting nearz) before rendering
* each eye's view. The pixels covered by this mesh will never be seen by the user after the lens distortion is applied and based on visibility to the panels.
* This will improve perf by letting the GPU early-reject pixels the user will never see before running the pixel shader.
* NOTE: Render this mesh with backface culling disabled since the winding order of the vertices can be different per-HMD or per-eye.
*/
virtual HiddenAreaMesh_t GetHiddenAreaMesh( EVREye eEye ) = 0;
// ------------------------------------
// Controller methods
// ------------------------------------
/** Fills the supplied struct with the current state of the controller. Returns false if the controller index
* is invalid. */
virtual bool GetControllerState( vr::TrackedDeviceIndex_t unControllerDeviceIndex, vr::VRControllerState_t *pControllerState ) = 0;
/** fills the supplied struct with the current state of the controller and the provided pose with the pose of
* the controller when the controller state was updated most recently. Use this form if you need a precise controller
* pose as input to your application when the user presses or releases a button. */
virtual bool GetControllerStateWithPose( ETrackingUniverseOrigin eOrigin, vr::TrackedDeviceIndex_t unControllerDeviceIndex, vr::VRControllerState_t *pControllerState, TrackedDevicePose_t *pTrackedDevicePose ) = 0;
/** Trigger a single haptic pulse on a controller. After this call the application may not trigger another haptic pulse on this controller
* and axis combination for 5ms. */
virtual void TriggerHapticPulse( vr::TrackedDeviceIndex_t unControllerDeviceIndex, uint32_t unAxisId, unsigned short usDurationMicroSec ) = 0;
/** returns the name of an EVRButtonId enum value */
virtual const char *GetButtonIdNameFromEnum( EVRButtonId eButtonId ) = 0;
/** returns the name of an EVRControllerAxisType enum value */
virtual const char *GetControllerAxisTypeNameFromEnum( EVRControllerAxisType eAxisType ) = 0;
/** Tells OpenVR that this process wants exclusive access to controller button states and button events. Other apps will be notified that
* they have lost input focus with a VREvent_InputFocusCaptured event. Returns false if input focus could not be captured for
* some reason. */
virtual bool CaptureInputFocus() = 0;
/** Tells OpenVR that this process no longer wants exclusive access to button states and button events. Other apps will be notified
* that input focus has been released with a VREvent_InputFocusReleased event. */
virtual void ReleaseInputFocus() = 0;
/** Returns true if input focus is captured by another process. */
virtual bool IsInputFocusCapturedByAnotherProcess() = 0;
// ------------------------------------
// Debug Methods
// ------------------------------------
/** Sends a request to the driver for the specified device and returns the response. The maximum response size is 32k,
* but this method can be called with a smaller buffer. If the response exceeds the size of the buffer, it is truncated.
* The size of the response including its terminating null is returned. */
virtual uint32_t DriverDebugRequest( vr::TrackedDeviceIndex_t unDeviceIndex, const char *pchRequest, char *pchResponseBuffer, uint32_t unResponseBufferSize ) = 0;
// ------------------------------------
// Firmware methods
// ------------------------------------
/** Performs the actual firmware update if applicable.
* The following events will be sent, if VRFirmwareError_None was returned: VREvent_FirmwareUpdateStarted, VREvent_FirmwareUpdateFinished
* Use the properties Prop_Firmware_UpdateAvailable_Bool, Prop_Firmware_ManualUpdate_Bool, and Prop_Firmware_ManualUpdateURL_String
* to figure our whether a firmware update is available, and to figure out whether its a manual update
* Prop_Firmware_ManualUpdateURL_String should point to an URL describing the manual update process */
virtual vr::EVRFirmwareError PerformFirmwareUpdate( vr::TrackedDeviceIndex_t unDeviceIndex ) = 0;
// ------------------------------------
// Application life cycle methods
// ------------------------------------
/** Call this to acknowledge to the system that VREvent_Quit has been received and that the process is exiting.
* This extends the timeout until the process is killed. */
virtual void AcknowledgeQuit_Exiting() = 0;
/** Call this to tell the system that the user is being prompted to save data. This
* halts the timeout and dismisses the dashboard (if it was up). Applications should be sure to actually
* prompt the user to save and then exit afterward, otherwise the user will be left in a confusing state. */
virtual void AcknowledgeQuit_UserPrompt() = 0;
// ------------------------------------
// Performance Test methods
// ------------------------------------
/** Performance Testing applications can call this to enable/disable when frame timing data should be
* captured for the Perf Test Report. */
virtual void PerformanceTestEnableCapture( bool bEnable ) = 0;
/** Performance Testing applications can call this to note on the Perf Test Report when they've shifted
* their fidelity to a new mode. */
virtual void PerformanceTestReportFidelityLevelChange( int nFidelityLevel ) = 0;
};
static const char * const IVRSystem_Version = "IVRSystem_011";
}
// ivrapplications.h
namespace vr
{
/** Used for all errors reported by the IVRApplications interface */
enum EVRApplicationError
{
VRApplicationError_None = 0,
VRApplicationError_AppKeyAlreadyExists = 100, // Only one application can use any given key
VRApplicationError_NoManifest = 101, // the running application does not have a manifest
VRApplicationError_NoApplication = 102, // No application is running
VRApplicationError_InvalidIndex = 103,
VRApplicationError_UnknownApplication = 104, // the application could not be found
VRApplicationError_IPCFailed = 105, // An IPC failure caused the request to fail
VRApplicationError_ApplicationAlreadyRunning = 106,
VRApplicationError_InvalidManifest = 107,
VRApplicationError_InvalidApplication = 108,
VRApplicationError_LaunchFailed = 109, // the process didn't start
VRApplicationError_ApplicationAlreadyStarting = 110, // the system was already starting the same application
VRApplicationError_LaunchInProgress = 111, // The system was already starting a different application
VRApplicationError_OldApplicationQuitting = 112,
VRApplicationError_TransitionAborted = 113,
VRApplicationError_BufferTooSmall = 200, // The provided buffer was too small to fit the requested data
VRApplicationError_PropertyNotSet = 201, // The requested property was not set
VRApplicationError_UnknownProperty = 202,
};
/** The maximum length of an application key */
static const uint32_t k_unMaxApplicationKeyLength = 128;
/** these are the properties available on applications. */
enum EVRApplicationProperty
{
VRApplicationProperty_Name_String = 0,
VRApplicationProperty_LaunchType_String = 11,
VRApplicationProperty_WorkingDirectory_String = 12,
VRApplicationProperty_BinaryPath_String = 13,
VRApplicationProperty_Arguments_String = 14,
VRApplicationProperty_URL_String = 15,
VRApplicationProperty_Description_String = 50,
VRApplicationProperty_NewsURL_String = 51,
VRApplicationProperty_ImagePath_String = 52,
VRApplicationProperty_Source_String = 53,
VRApplicationProperty_IsDashboardOverlay_Bool = 60,
VRApplicationProperty_LastLaunchTime_Uint64 = 70,
};
/** These are states the scene application startup process will go through. */
enum EVRApplicationTransitionState
{
VRApplicationTransition_None = 0,
VRApplicationTransition_OldAppQuitSent = 10,
VRApplicationTransition_WaitingForExternalLaunch = 11,
VRApplicationTransition_NewAppLaunched = 20,
};
class IVRApplications
{
public:
// --------------- Application management --------------- //
/** Adds an application manifest to the list to load when building the list of installed applications.
* Temporary manifests are not automatically loaded */
virtual EVRApplicationError AddApplicationManifest( const char *pchApplicationManifestFullPath, bool bTemporary = false ) = 0;
/** Removes an application manifest from the list to load when building the list of installed applications. */
virtual EVRApplicationError RemoveApplicationManifest( const char *pchApplicationManifestFullPath ) = 0;
/** Returns true if an application is installed */
virtual bool IsApplicationInstalled( const char *pchAppKey ) = 0;
/** Returns the number of applications available in the list */
virtual uint32_t GetApplicationCount() = 0;
/** Returns the key of the specified application. The index is at least 0 and is less than the return
* value of GetApplicationCount(). The buffer should be at least k_unMaxApplicationKeyLength in order to
* fit the key. */
virtual EVRApplicationError GetApplicationKeyByIndex( uint32_t unApplicationIndex, char *pchAppKeyBuffer, uint32_t unAppKeyBufferLen ) = 0;
/** Returns the key of the application for the specified Process Id. The buffer should be at least
* k_unMaxApplicationKeyLength in order to fit the key. */
virtual EVRApplicationError GetApplicationKeyByProcessId( uint32_t unProcessId, char *pchAppKeyBuffer, uint32_t unAppKeyBufferLen ) = 0;
/** Launches the application. The existing scene application will exit and then the new application will start.
* This call is not valid for dashboard overlay applications. */
virtual EVRApplicationError LaunchApplication( const char *pchAppKey ) = 0;
/** Launches the dashboard overlay application if it is not already running. This call is only valid for
* dashboard overlay applications. */
virtual EVRApplicationError LaunchDashboardOverlay( const char *pchAppKey ) = 0;
/** Cancel a pending launch for an application */
virtual bool CancelApplicationLaunch( const char *pchAppKey ) = 0;
/** Identifies a running application. OpenVR can't always tell which process started in response
* to a URL. This function allows a URL handler (or the process itself) to identify the app key
* for the now running application. Passing a process ID of 0 identifies the calling process.
* The application must be one that's known to the system via a call to AddApplicationManifest. */
virtual EVRApplicationError IdentifyApplication( uint32_t unProcessId, const char *pchAppKey ) = 0;
/** Returns the process ID for an application. Return 0 if the application was not found or is not running. */
virtual uint32_t GetApplicationProcessId( const char *pchAppKey ) = 0;
/** Returns a string for an applications error */
virtual const char *GetApplicationsErrorNameFromEnum( EVRApplicationError error ) = 0;
// --------------- Application properties --------------- //
/** Returns a value for an application property. The required buffer size to fit this value will be returned. */
virtual uint32_t GetApplicationPropertyString( const char *pchAppKey, EVRApplicationProperty eProperty, char *pchPropertyValueBuffer, uint32_t unPropertyValueBufferLen, EVRApplicationError *peError = nullptr ) = 0;
/** Returns a bool value for an application property. Returns false in all error cases. */
virtual bool GetApplicationPropertyBool( const char *pchAppKey, EVRApplicationProperty eProperty, EVRApplicationError *peError = nullptr ) = 0;
/** Returns a uint64 value for an application property. Returns 0 in all error cases. */
virtual uint64_t GetApplicationPropertyUint64( const char *pchAppKey, EVRApplicationProperty eProperty, EVRApplicationError *peError = nullptr ) = 0;
/** Sets the application auto-launch flag. This is only valid for applications which return true for VRApplicationProperty_IsDashboardOverlay_Bool. */
virtual EVRApplicationError SetApplicationAutoLaunch( const char *pchAppKey, bool bAutoLaunch ) = 0;
/** Gets the application auto-launch flag. This is only valid for applications which return true for VRApplicationProperty_IsDashboardOverlay_Bool. */
virtual bool GetApplicationAutoLaunch( const char *pchAppKey ) = 0;
// --------------- Transition methods --------------- //
/** Returns the app key for the application that is starting up */
virtual EVRApplicationError GetStartingApplication( char *pchAppKeyBuffer, uint32_t unAppKeyBufferLen ) = 0;
/** Returns the application transition state */
virtual EVRApplicationTransitionState GetTransitionState() = 0;
/** Returns errors that would prevent the specified application from launching immediately. Calling this function will
* cause the current scene application to quit, so only call it when you are actually about to launch something else.
* What the caller should do about these failures depends on the failure:
* VRApplicationError_OldApplicationQuitting - An existing application has been told to quit. Wait for a VREvent_ProcessQuit
* and try again.
* VRApplicationError_ApplicationAlreadyStarting - This application is already starting. This is a permanent failure.
* VRApplicationError_LaunchInProgress - A different application is already starting. This is a permanent failure.
* VRApplicationError_None - Go ahead and launch. Everything is clear.
*/
virtual EVRApplicationError PerformApplicationPrelaunchCheck( const char *pchAppKey ) = 0;
/** Returns a string for an application transition state */
virtual const char *GetApplicationsTransitionStateNameFromEnum( EVRApplicationTransitionState state ) = 0;
/** Returns true if the outgoing scene app has requested a save prompt before exiting */
virtual bool IsQuitUserPromptRequested() = 0;
};
static const char * const IVRApplications_Version = "IVRApplications_004";
} // namespace vr
// ivrsettings.h
namespace vr
{
enum EVRSettingsError
{
VRSettingsError_None = 0,
VRSettingsError_IPCFailed = 1,
VRSettingsError_WriteFailed = 2,
VRSettingsError_ReadFailed = 3,
};
// The maximum length of a settings key
static const uint32_t k_unMaxSettingsKeyLength = 128;
class IVRSettings
{
public:
virtual const char *GetSettingsErrorNameFromEnum( EVRSettingsError eError ) = 0;
// Returns true if file sync occurred (force or settings dirty)
virtual bool Sync( bool bForce = false, EVRSettingsError *peError = nullptr ) = 0;
virtual bool GetBool( const char *pchSection, const char *pchSettingsKey, bool bDefaultValue, EVRSettingsError *peError = nullptr ) = 0;
virtual void SetBool( const char *pchSection, const char *pchSettingsKey, bool bValue, EVRSettingsError *peError = nullptr ) = 0;
virtual int32_t GetInt32( const char *pchSection, const char *pchSettingsKey, int32_t nDefaultValue, EVRSettingsError *peError = nullptr ) = 0;
virtual void SetInt32( const char *pchSection, const char *pchSettingsKey, int32_t nValue, EVRSettingsError *peError = nullptr ) = 0;
virtual float GetFloat( const char *pchSection, const char *pchSettingsKey, float flDefaultValue, EVRSettingsError *peError = nullptr ) = 0;
virtual void SetFloat( const char *pchSection, const char *pchSettingsKey, float flValue, EVRSettingsError *peError = nullptr ) = 0;
virtual void GetString( const char *pchSection, const char *pchSettingsKey, char *pchValue, uint32_t unValueLen, const char *pchDefaultValue, EVRSettingsError *peError = nullptr ) = 0;
virtual void SetString( const char *pchSection, const char *pchSettingsKey, const char *pchValue, EVRSettingsError *peError = nullptr ) = 0;
virtual void RemoveSection( const char *pchSection, EVRSettingsError *peError = nullptr ) = 0;
virtual void RemoveKeyInSection( const char *pchSection, const char *pchSettingsKey, EVRSettingsError *peError = nullptr ) = 0;
};
//-----------------------------------------------------------------------------
// steamvr keys
static const char * const k_pch_SteamVR_Section = "steamvr";
static const char * const k_pch_SteamVR_RequireHmd_String = "requireHmd";
static const char * const k_pch_SteamVR_ForcedDriverKey_String = "forcedDriver";
static const char * const k_pch_SteamVR_ForcedHmdKey_String = "forcedHmd";
static const char * const k_pch_SteamVR_DisplayDebug_Bool = "displayDebug";
static const char * const k_pch_SteamVR_EnableDistortion_Bool = "enableDistortion";
static const char * const k_pch_SteamVR_DisplayDebugX_Int32 = "displayDebugX";
static const char * const k_pch_SteamVR_DisplayDebugY_Int32 = "displayDebugY";
static const char * const k_pch_SteamVR_SendSystemButtonToAllApps_Bool= "sendSystemButtonToAllApps";
static const char * const k_pch_SteamVR_LogLevel_Int32 = "loglevel";
static const char * const k_pch_SteamVR_IPD_Float = "ipd";
static const char * const k_pch_SteamVR_Background_String = "background";
static const char * const k_pch_SteamVR_GridColor_String = "gridColor";
static const char * const k_pch_SteamVR_PlayAreaColor_String = "playAreaColor";
static const char * const k_pch_SteamVR_ActivateMultipleDrivers_Bool = "activateMultipleDrivers";
static const char * const k_pch_SteamVR_PowerOffOnExit_Bool = "powerOffOnExit";
static const char * const k_pch_SteamVR_StandbyAppRunningTimeout_Float = "standbyAppRunningTimeout";
static const char * const k_pch_SteamVR_StandbyNoAppTimeout_Float = "standbyNoAppTimeout";
static const char * const k_pch_SteamVR_AutomaticDirectModeEnabled_Bool = "automaticDirectModeEnabled";
static const char * const k_pch_SteamVR_RequestDirectModeEnabled_Bool = "requestDirectModeEnabled";
static const char * const k_pch_SteamVR_RequestDirectModeDisabled_Bool = "requestDirectModeDisabled";
static const char * const k_pch_SteamVR_RequestDirectModeEdidVid_Int32 = "requestDirectModeEdidVid";
static const char * const k_pch_SteamVR_RequestDirectModeEdidPid_Int32 = "requestDirectModeEdidPid";
static const char * const k_pch_SteamVR_UsingSpeakers_Bool = "usingSpeakers";
static const char * const k_pch_SteamVR_SpeakersForwardYawOffsetDegrees_Float = "speakersForwardYawOffsetDegrees";
//-----------------------------------------------------------------------------
// lighthouse keys
static const char * const k_pch_Lighthouse_Section = "driver_lighthouse";
static const char * const k_pch_Lighthouse_DisableIMU_Bool = "disableimu";
static const char * const k_pch_Lighthouse_UseDisambiguation_String = "usedisambiguation";
static const char * const k_pch_Lighthouse_DisambiguationDebug_Int32 = "disambiguationdebug";
static const char * const k_pch_Lighthouse_PrimaryBasestation_Int32 = "primarybasestation";
static const char * const k_pch_Lighthouse_LighthouseName_String = "lighthousename";
static const char * const k_pch_Lighthouse_MaxIncidenceAngleDegrees_Float = "maxincidenceangledegrees";
static const char * const k_pch_Lighthouse_UseLighthouseDirect_Bool = "uselighthousedirect";
static const char * const k_pch_Lighthouse_DBHistory_Bool = "dbhistory";
static const char * const k_pch_Lighthouse_OriginOffsetX_Float = "originoffsetx";
static const char * const k_pch_Lighthouse_OriginOffsetY_Float = "originoffsety";
static const char * const k_pch_Lighthouse_OriginOffsetZ_Float = "originoffsetz";
static const char * const k_pch_Lighthouse_HeadingOffset_Float = "headingoffset";
//-----------------------------------------------------------------------------
// null keys
static const char * const k_pch_Null_Section = "driver_null";
static const char * const k_pch_Null_EnableNullDriver_Bool = "enable";
static const char * const k_pch_Null_SerialNumber_String = "serialNumber";
static const char * const k_pch_Null_ModelNumber_String = "modelNumber";
static const char * const k_pch_Null_WindowX_Int32 = "windowX";
static const char * const k_pch_Null_WindowY_Int32 = "windowY";
static const char * const k_pch_Null_WindowWidth_Int32 = "windowWidth";
static const char * const k_pch_Null_WindowHeight_Int32 = "windowHeight";
static const char * const k_pch_Null_RenderWidth_Int32 = "renderWidth";
static const char * const k_pch_Null_RenderHeight_Int32 = "renderHeight";
static const char * const k_pch_Null_SecondsFromVsyncToPhotons_Float = "secondsFromVsyncToPhotons";
static const char * const k_pch_Null_DisplayFrequency_Float = "displayFrequency";
//-----------------------------------------------------------------------------
// user interface keys
static const char * const k_pch_UserInterface_Section = "userinterface";
static const char * const k_pch_UserInterface_StatusAlwaysOnTop_Bool = "StatusAlwaysOnTop";
//-----------------------------------------------------------------------------
// notification keys
static const char * const k_pch_Notifications_Section = "notifications";
static const char * const k_pch_Notifications_DoNotDisturb_Bool = "DoNotDisturb";
//-----------------------------------------------------------------------------
// keyboard keys
static const char * const k_pch_Keyboard_Section = "keyboard";
static const char * const k_pch_Keyboard_TutorialCompletions = "TutorialCompletions";
//-----------------------------------------------------------------------------
// perf keys
static const char * const k_pch_Perf_Section = "perfcheck";
static const char * const k_pch_Perf_HeuristicActive_Bool = "heuristicActive";
static const char * const k_pch_Perf_NotifyInHMD_Bool = "warnInHMD";
static const char * const k_pch_Perf_NotifyOnlyOnce_Bool = "warnOnlyOnce";
static const char * const k_pch_Perf_AllowTimingStore_Bool = "allowTimingStore";
static const char * const k_pch_Perf_SaveTimingsOnExit_Bool = "saveTimingsOnExit";
static const char * const k_pch_Perf_TestData_Float = "perfTestData";
//-----------------------------------------------------------------------------
// camera keys
static const char * const k_pch_Camera_Section = "camera";
//-----------------------------------------------------------------------------
static const char * const IVRSettings_Version = "IVRSettings_001";
} // namespace vr
// ivrchaperone.h
namespace vr
{
#if defined(__linux__) || defined(__APPLE__)
// The 32-bit version of gcc has the alignment requirement for uint64 and double set to
// 4 meaning that even with #pragma pack(8) these types will only be four-byte aligned.
// The 64-bit version of gcc has the alignment requirement for these types set to
// 8 meaning that unless we use #pragma pack(4) our structures will get bigger.
// The 64-bit structure packing has to match the 32-bit structure packing for each platform.
#pragma pack( push, 4 )
#else
#pragma pack( push, 8 )
#endif
enum ChaperoneCalibrationState
{
// OK!
ChaperoneCalibrationState_OK = 1, // Chaperone is fully calibrated and working correctly
// Warnings
ChaperoneCalibrationState_Warning = 100,
ChaperoneCalibrationState_Warning_BaseStationMayHaveMoved = 101, // A base station thinks that it might have moved
ChaperoneCalibrationState_Warning_BaseStationRemoved = 102, // There are less base stations than when calibrated
ChaperoneCalibrationState_Warning_SeatedBoundsInvalid = 103, // Seated bounds haven't been calibrated for the current tracking center
// Errors
ChaperoneCalibrationState_Error = 200, // The UniverseID is invalid
ChaperoneCalibrationState_Error_BaseStationUninitalized = 201, // Tracking center hasn't be calibrated for at least one of the base stations
ChaperoneCalibrationState_Error_BaseStationConflict = 202, // Tracking center is calibrated, but base stations disagree on the tracking space
ChaperoneCalibrationState_Error_PlayAreaInvalid = 203, // Play Area hasn't been calibrated for the current tracking center
ChaperoneCalibrationState_Error_CollisionBoundsInvalid = 204, // Collision Bounds haven't been calibrated for the current tracking center
};
/** HIGH LEVEL TRACKING SPACE ASSUMPTIONS:
* 0,0,0 is the preferred standing area center.
* 0Y is the floor height.
* -Z is the preferred forward facing direction. */
class IVRChaperone
{
public:
/** Get the current state of Chaperone calibration. This state can change at any time during a session due to physical base station changes. **/
virtual ChaperoneCalibrationState GetCalibrationState() = 0;
/** Returns the width and depth of the Play Area (formerly named Soft Bounds) in X and Z.
* Tracking space center (0,0,0) is the center of the Play Area. **/
virtual bool GetPlayAreaSize( float *pSizeX, float *pSizeZ ) = 0;
/** Returns the 4 corner positions of the Play Area (formerly named Soft Bounds).
* Corners are in counter-clockwise order.
* Standing center (0,0,0) is the center of the Play Area.
* It's a rectangle.
* 2 sides are parallel to the X axis and 2 sides are parallel to the Z axis.
* Height of every corner is 0Y (on the floor). **/
virtual bool GetPlayAreaRect( HmdQuad_t *rect ) = 0;
/** Reload Chaperone data from the .vrchap file on disk. */
virtual void ReloadInfo( void ) = 0;
/** Optionally give the chaperone system a hit about the color and brightness in the scene **/
virtual void SetSceneColor( HmdColor_t color ) = 0;
/** Get the current chaperone bounds draw color and brightness **/
virtual void GetBoundsColor( HmdColor_t *pOutputColorArray, int nNumOutputColors, float flCollisionBoundsFadeDistance, HmdColor_t *pOutputCameraColor ) = 0;
/** Determine whether the bounds are showing right now **/
virtual bool AreBoundsVisible() = 0;
/** Force the bounds to show, mostly for utilities **/
virtual void ForceBoundsVisible( bool bForce ) = 0;
};
static const char * const IVRChaperone_Version = "IVRChaperone_003";
#pragma pack( pop )
}
// ivrchaperonesetup.h
namespace vr
{
enum EChaperoneConfigFile
{
EChaperoneConfigFile_Live = 1, // The live chaperone config, used by most applications and games
EChaperoneConfigFile_Temp = 2, // The temporary chaperone config, used to live-preview collision bounds in room setup
};
/** Manages the working copy of the chaperone info. By default this will be the same as the
* live copy. Any changes made with this interface will stay in the working copy until
* CommitWorkingCopy() is called, at which point the working copy and the live copy will be
* the same again. */
class IVRChaperoneSetup
{
public:
/** Saves the current working copy to disk */
virtual bool CommitWorkingCopy( EChaperoneConfigFile configFile ) = 0;
/** Reverts the working copy to match the live chaperone calibration.
* To modify existing data this MUST be do WHILE getting a non-error ChaperoneCalibrationStatus.
* Only after this should you do gets and sets on the existing data. */
virtual void RevertWorkingCopy() = 0;
/** Returns the width and depth of the Play Area (formerly named Soft Bounds) in X and Z from the working copy.
* Tracking space center (0,0,0) is the center of the Play Area. */
virtual bool GetWorkingPlayAreaSize( float *pSizeX, float *pSizeZ ) = 0;
/** Returns the 4 corner positions of the Play Area (formerly named Soft Bounds) from the working copy.
* Corners are in clockwise order.
* Tracking space center (0,0,0) is the center of the Play Area.
* It's a rectangle.
* 2 sides are parallel to the X axis and 2 sides are parallel to the Z axis.
* Height of every corner is 0Y (on the floor). **/
virtual bool GetWorkingPlayAreaRect( HmdQuad_t *rect ) = 0;
/** Returns the number of Quads if the buffer points to null. Otherwise it returns Quads
* into the buffer up to the max specified from the working copy. */
virtual bool GetWorkingCollisionBoundsInfo( VR_OUT_ARRAY_COUNT(punQuadsCount) HmdQuad_t *pQuadsBuffer, uint32_t* punQuadsCount ) = 0;
/** Returns the number of Quads if the buffer points to null. Otherwise it returns Quads
* into the buffer up to the max specified. */
virtual bool GetLiveCollisionBoundsInfo( VR_OUT_ARRAY_COUNT(punQuadsCount) HmdQuad_t *pQuadsBuffer, uint32_t* punQuadsCount ) = 0;
/** Returns the preferred seated position from the working copy. */
virtual bool GetWorkingSeatedZeroPoseToRawTrackingPose( HmdMatrix34_t *pmatSeatedZeroPoseToRawTrackingPose ) = 0;
/** Returns the standing origin from the working copy. */
virtual bool GetWorkingStandingZeroPoseToRawTrackingPose( HmdMatrix34_t *pmatStandingZeroPoseToRawTrackingPose ) = 0;
/** Sets the Play Area in the working copy. */
virtual void SetWorkingPlayAreaSize( float sizeX, float sizeZ ) = 0;
/** Sets the Collision Bounds in the working copy. */
virtual void SetWorkingCollisionBoundsInfo( VR_ARRAY_COUNT(unQuadsCount) HmdQuad_t *pQuadsBuffer, uint32_t unQuadsCount ) = 0;
/** Sets the preferred seated position in the working copy. */
virtual void SetWorkingSeatedZeroPoseToRawTrackingPose( const HmdMatrix34_t *pMatSeatedZeroPoseToRawTrackingPose ) = 0;
/** Sets the preferred standing position in the working copy. */
virtual void SetWorkingStandingZeroPoseToRawTrackingPose( const HmdMatrix34_t *pMatStandingZeroPoseToRawTrackingPose ) = 0;
/** Tear everything down and reload it from the file on disk */
virtual void ReloadFromDisk( EChaperoneConfigFile configFile ) = 0;
/** Returns the preferred seated position. */
virtual bool GetLiveSeatedZeroPoseToRawTrackingPose( HmdMatrix34_t *pmatSeatedZeroPoseToRawTrackingPose ) = 0;
virtual void SetWorkingCollisionBoundsTagsInfo( VR_ARRAY_COUNT(unTagCount) uint8_t *pTagsBuffer, uint32_t unTagCount ) = 0;
virtual bool GetLiveCollisionBoundsTagsInfo( VR_OUT_ARRAY_COUNT(punTagCount) uint8_t *pTagsBuffer, uint32_t *punTagCount ) = 0;
virtual bool SetWorkingPhysicalBoundsInfo( VR_ARRAY_COUNT(unQuadsCount) HmdQuad_t *pQuadsBuffer, uint32_t unQuadsCount ) = 0;
virtual bool GetLivePhysicalBoundsInfo( VR_OUT_ARRAY_COUNT(punQuadsCount) HmdQuad_t *pQuadsBuffer, uint32_t* punQuadsCount ) = 0;
};
static const char * const IVRChaperoneSetup_Version = "IVRChaperoneSetup_005";
}
// ivrcompositor.h
namespace vr
{
#if defined(__linux__) || defined(__APPLE__)
// The 32-bit version of gcc has the alignment requirement for uint64 and double set to
// 4 meaning that even with #pragma pack(8) these types will only be four-byte aligned.
// The 64-bit version of gcc has the alignment requirement for these types set to
// 8 meaning that unless we use #pragma pack(4) our structures will get bigger.
// The 64-bit structure packing has to match the 32-bit structure packing for each platform.
#pragma pack( push, 4 )
#else
#pragma pack( push, 8 )
#endif
/** Errors that can occur with the VR compositor */
enum EVRCompositorError
{
VRCompositorError_None = 0,
VRCompositorError_IncompatibleVersion = 100,
VRCompositorError_DoNotHaveFocus = 101,
VRCompositorError_InvalidTexture = 102,
VRCompositorError_IsNotSceneApplication = 103,
VRCompositorError_TextureIsOnWrongDevice = 104,
VRCompositorError_TextureUsesUnsupportedFormat = 105,
VRCompositorError_SharedTexturesNotSupported = 106,
VRCompositorError_IndexOutOfRange = 107,
};
/** Provides a single frame's timing information to the app */
struct Compositor_FrameTiming
{
uint32_t m_nSize; // Set to sizeof( Compositor_FrameTiming )
uint32_t m_nFrameIndex;
uint32_t m_nNumFramePresents; // number of times this frame was presented
uint32_t m_nNumDroppedFrames; // number of additional times previous frame was scanned out
/** Absolute time reference for comparing frames. This aligns with the vsync that running start is relative to. */
double m_flSystemTimeInSeconds;
/** These times may include work from other processes due to OS scheduling.
* The fewer packets of work these are broken up into, the less likely this will happen.
* GPU work can be broken up by calling Flush. This can sometimes be useful to get the GPU started
* processing that work earlier in the frame. */
float m_flSceneRenderGpuMs; // time spent rendering the scene
float m_flTotalRenderGpuMs; // time between work submitted immediately after present (ideally vsync) until the end of compositor submitted work
float m_flCompositorRenderGpuMs; // time spend performing distortion correction, rendering chaperone, overlays, etc.
float m_flCompositorRenderCpuMs; // time spent on cpu submitting the above work for this frame
float m_flCompositorIdleCpuMs; // time spent waiting for running start (application could have used this much more time)
/** Miscellaneous measured intervals. */
float m_flClientFrameIntervalMs; // time between calls to WaitGetPoses
float m_flPresentCallCpuMs; // time blocked on call to present (usually 0.0, but can go long)
float m_flWaitForPresentCpuMs; // time spent spin-waiting for frame index to change (not near-zero indicates wait object failure)
float m_flSubmitFrameMs; // time spent in IVRCompositor::Submit (not near-zero indicates driver issue)
/** The following are all relative to this frame's SystemTimeInSeconds */
float m_flWaitGetPosesCalledMs;
float m_flNewPosesReadyMs;
float m_flNewFrameReadyMs; // second call to IVRCompositor::Submit
float m_flCompositorUpdateStartMs;
float m_flCompositorUpdateEndMs;
float m_flCompositorRenderStartMs;
vr::TrackedDevicePose_t m_HmdPose; // pose used by app to render this frame
int32_t m_nFidelityLevel; // app reported value
};
#pragma pack( pop )
/** Allows the application to interact with the compositor */
class IVRCompositor
{
public:
/** Sets tracking space returned by WaitGetPoses */
virtual void SetTrackingSpace( ETrackingUniverseOrigin eOrigin ) = 0;
/** Gets current tracking space returned by WaitGetPoses */
virtual ETrackingUniverseOrigin GetTrackingSpace() = 0;
/** Returns pose(s) to use to render scene (and optionally poses predicted two frames out for gameplay). */
virtual EVRCompositorError WaitGetPoses( VR_ARRAY_COUNT(unRenderPoseArrayCount) TrackedDevicePose_t* pRenderPoseArray, uint32_t unRenderPoseArrayCount,
VR_ARRAY_COUNT(unGamePoseArrayCount) TrackedDevicePose_t* pGamePoseArray, uint32_t unGamePoseArrayCount ) = 0;
/** Get the last set of poses returned by WaitGetPoses. */
virtual EVRCompositorError GetLastPoses( VR_ARRAY_COUNT( unRenderPoseArrayCount ) TrackedDevicePose_t* pRenderPoseArray, uint32_t unRenderPoseArrayCount,
VR_ARRAY_COUNT( unGamePoseArrayCount ) TrackedDevicePose_t* pGamePoseArray, uint32_t unGamePoseArrayCount ) = 0;
/** Interface for accessing last set of poses returned by WaitGetPoses one at a time.
* Returns VRCompositorError_IndexOutOfRange if unDeviceIndex not less than k_unMaxTrackedDeviceCount otherwise VRCompositorError_None.
* It is okay to pass NULL for either pose if you only want one of the values. */
virtual EVRCompositorError GetLastPoseForTrackedDeviceIndex( TrackedDeviceIndex_t unDeviceIndex, TrackedDevicePose_t *pOutputPose, TrackedDevicePose_t *pOutputGamePose ) = 0;
/** Updated scene texture to display. If pBounds is NULL the entire texture will be used. If called from an OpenGL app, consider adding a glFlush after
* Submitting both frames to signal the driver to start processing, otherwise it may wait until the command buffer fills up, causing the app to miss frames.
*
* OpenGL dirty state:
* glBindTexture
*/
virtual EVRCompositorError Submit( EVREye eEye, const Texture_t *pTexture, const VRTextureBounds_t* pBounds = 0, EVRSubmitFlags nSubmitFlags = Submit_Default ) = 0;
/** Clears the frame that was sent with the last call to Submit. This will cause the
* compositor to show the grid until Submit is called again. */
virtual void ClearLastSubmittedFrame() = 0;
/** Call immediately after presenting your app's window (i.e. companion window) to unblock the compositor.
* This is an optional call, which only needs to be used if you can't instead call WaitGetPoses immediately after Present.
* For example, if your engine's render and game loop are not on separate threads, or blocking the render thread until 3ms before the next vsync would
* introduce a deadlock of some sort. This function tells the compositor that you have finished all rendering after having Submitted buffers for both
* eyes, and it is free to start its rendering work. This should only be called from the same thread you are rendering on. */
virtual void PostPresentHandoff() = 0;
/** Returns true if timing data is filled it. Sets oldest timing info if nFramesAgo is larger than the stored history.
* Be sure to set timing.size = sizeof(Compositor_FrameTiming) on struct passed in before calling this function. */
virtual bool GetFrameTiming( Compositor_FrameTiming *pTiming, uint32_t unFramesAgo = 0 ) = 0;
/** Returns the time in seconds left in the current (as identified by FrameTiming's frameIndex) frame.
* Due to "running start", this value may roll over to the next frame before ever reaching 0.0. */
virtual float GetFrameTimeRemaining() = 0;
/** Fades the view on the HMD to the specified color. The fade will take fSeconds, and the color values are between
* 0.0 and 1.0. This color is faded on top of the scene based on the alpha parameter. Removing the fade color instantly
* would be FadeToColor( 0.0, 0.0, 0.0, 0.0, 0.0 ). Values are in un-premultiplied alpha space. */
virtual void FadeToColor( float fSeconds, float fRed, float fGreen, float fBlue, float fAlpha, bool bBackground = false ) = 0;
/** Fading the Grid in or out in fSeconds */
virtual void FadeGrid( float fSeconds, bool bFadeIn ) = 0;
/** Override the skybox used in the compositor (e.g. for during level loads when the app can't feed scene images fast enough)
* Order is Front, Back, Left, Right, Top, Bottom. If only a single texture is passed, it is assumed in lat-long format.
* If two are passed, it is assumed a lat-long stereo pair. */
virtual EVRCompositorError SetSkyboxOverride( VR_ARRAY_COUNT( unTextureCount ) const Texture_t *pTextures, uint32_t unTextureCount ) = 0;
/** Resets compositor skybox back to defaults. */
virtual void ClearSkyboxOverride() = 0;
/** Brings the compositor window to the front. This is useful for covering any other window that may be on the HMD
* and is obscuring the compositor window. */
virtual void CompositorBringToFront() = 0;
/** Pushes the compositor window to the back. This is useful for allowing other applications to draw directly to the HMD. */
virtual void CompositorGoToBack() = 0;
/** Tells the compositor process to clean up and exit. You do not need to call this function at shutdown. Under normal
* circumstances the compositor will manage its own life cycle based on what applications are running. */
virtual void CompositorQuit() = 0;
/** Return whether the compositor is fullscreen */
virtual bool IsFullscreen() = 0;
/** Returns the process ID of the process that is currently rendering the scene */
virtual uint32_t GetCurrentSceneFocusProcess() = 0;
/** Returns the process ID of the process that rendered the last frame (or 0 if the compositor itself rendered the frame.)
* Returns 0 when fading out from an app and the app's process Id when fading into an app. */
virtual uint32_t GetLastFrameRenderer() = 0;
/** Returns true if the current process has the scene focus */
virtual bool CanRenderScene() = 0;
/** Creates a window on the primary monitor to display what is being shown in the headset. */
virtual void ShowMirrorWindow() = 0;
/** Closes the mirror window. */
virtual void HideMirrorWindow() = 0;
/** Returns true if the mirror window is shown */
virtual bool IsMirrorWindowVisible() = 0;
/** Writes all images that the compositor knows about (including overlays) to a 'screenshots' folder in the SteamVR runtime root. */
virtual void CompositorDumpImages() = 0;
/** Let an app know it should be rendering with low resources */
virtual bool ShouldAppRenderWithLowResources() = 0;
};
static const char * const IVRCompositor_Version = "IVRCompositor_012";
} // namespace vr
// ivrnotifications.h
namespace vr
{
#if defined(__linux__) || defined(__APPLE__)
// The 32-bit version of gcc has the alignment requirement for uint64 and double set to
// 4 meaning that even with #pragma pack(8) these types will only be four-byte aligned.
// The 64-bit version of gcc has the alignment requirement for these types set to
// 8 meaning that unless we use #pragma pack(4) our structures will get bigger.
// The 64-bit structure packing has to match the 32-bit structure packing for each platform.
#pragma pack( push, 4 )
#else
#pragma pack( push, 8 )
#endif
// Used for passing graphic data
struct NotificationBitmap_t
{
void *bytes;
int32_t width;
int32_t height;
int32_t depth;
};
enum EVRNotificationType
{
/** Transient notifications are automatically hidden after a period of time set by the user.
* They are used for things like information and chat messages that do not require user interaction. */
EVRNotificationType_Transient = 0,
/** Persistent notifications are shown to the user until they are hidden by calling RemoveNotification().
* They are used for things like phone calls and alarms that require user interaction. */
EVRNotificationType_Persistent = 1,
};
enum EVRNotificationStyle
{
/** Creates a notification with minimal external styling. */
EVRNotificationStyle_None = 0,
/** Used for notifications about overlay-level status. In Steam this is used for events like downloads completing. */
EVRNotificationStyle_Application = 100,
/** Used for notifications about contacts that are unknown or not available. In Steam this is used for friend invitations and offline friends. */
EVRNotificationStyle_Contact_Disabled = 200,
/** Used for notifications about contacts that are available but inactive. In Steam this is used for friends that are online but not playing a game. */
EVRNotificationStyle_Contact_Enabled = 201,
/** Used for notifications about contacts that are available and active. In Steam this is used for friends that are online and currently running a game. */
EVRNotificationStyle_Contact_Active = 202,
};
static const uint32_t k_unNotificationTextMaxSize = 256;
typedef uint32_t VRNotificationId;
#pragma pack( pop )
/** Allows notification sources to interact with the VR system
This current interface is not yet implemented. Do not use yet. */
class IVRNotifications
{
public:
/** Create a notification and enqueue it to be shown to the user.
* An overlay handle is required to create a notification, as otherwise it would be impossible for a user to act on it.
* To create a two-line notification, use a line break ('\n') to split the text into two lines.
* The pImage argument may be NULL, in which case the specified overlay's icon will be used instead. */
virtual EVRNotificationError CreateNotification( VROverlayHandle_t ulOverlayHandle, uint64_t ulUserValue, EVRNotificationType type, const char *pchText, EVRNotificationStyle style, const NotificationBitmap_t *pImage, /* out */ VRNotificationId *pNotificationId ) = 0;
/** Destroy a notification, hiding it first if it currently shown to the user. */
virtual EVRNotificationError RemoveNotification( VRNotificationId notificationId ) = 0;
};
static const char * const IVRNotifications_Version = "IVRNotifications_002";
} // namespace vr
// ivroverlay.h
namespace vr
{
/** The maximum length of an overlay key in bytes, counting the terminating null character. */
static const uint32_t k_unVROverlayMaxKeyLength = 128;
/** The maximum length of an overlay name in bytes, counting the terminating null character. */
static const uint32_t k_unVROverlayMaxNameLength = 128;
/** The maximum number of overlays that can exist in the system at one time. */
static const uint32_t k_unMaxOverlayCount = 32;
/** Types of input supported by VR Overlays */
enum VROverlayInputMethod
{
VROverlayInputMethod_None = 0, // No input events will be generated automatically for this overlay
VROverlayInputMethod_Mouse = 1, // Tracked controllers will get mouse events automatically
};
/** Allows the caller to figure out which overlay transform getter to call. */
enum VROverlayTransformType
{
VROverlayTransform_Absolute = 0,
VROverlayTransform_TrackedDeviceRelative = 1,
VROverlayTransform_SystemOverlay = 2,
VROverlayTransform_TrackedComponent = 3,
};
/** Overlay control settings */
enum VROverlayFlags
{
VROverlayFlags_None = 0,
// The following only take effect when rendered using the high quality render path (see SetHighQualityOverlay).
VROverlayFlags_Curved = 1,
VROverlayFlags_RGSS4X = 2,
// Set this flag on a dashboard overlay to prevent a tab from showing up for that overlay
VROverlayFlags_NoDashboardTab = 3,
// Set this flag on a dashboard that is able to deal with gamepad focus events
VROverlayFlags_AcceptsGamepadEvents = 4,
// Indicates that the overlay should dim/brighten to show gamepad focus
VROverlayFlags_ShowGamepadFocus = 5,
// When in VROverlayInputMethod_Mouse you can optionally enable sending VRScroll_t
VROverlayFlags_SendVRScrollEvents = 6,
VROverlayFlags_SendVRTouchpadEvents = 7,
};
struct VROverlayIntersectionParams_t
{
HmdVector3_t vSource;
HmdVector3_t vDirection;
ETrackingUniverseOrigin eOrigin;
};
struct VROverlayIntersectionResults_t
{
HmdVector3_t vPoint;
HmdVector3_t vNormal;
HmdVector2_t vUVs;
float fDistance;
};
// Input modes for the Big Picture gamepad text entry
enum EGamepadTextInputMode
{
k_EGamepadTextInputModeNormal = 0,
k_EGamepadTextInputModePassword = 1,
k_EGamepadTextInputModeSubmit = 2,
};
// Controls number of allowed lines for the Big Picture gamepad text entry
enum EGamepadTextInputLineMode
{
k_EGamepadTextInputLineModeSingleLine = 0,
k_EGamepadTextInputLineModeMultipleLines = 1
};
/** Directions for changing focus between overlays with the gamepad */
enum EOverlayDirection
{
OverlayDirection_Up = 0,
OverlayDirection_Down = 1,
OverlayDirection_Left = 2,
OverlayDirection_Right = 3,
OverlayDirection_Count = 4,
};
class IVROverlay
{
public:
// ---------------------------------------------
// Overlay management methods
// ---------------------------------------------
/** Finds an existing overlay with the specified key. */
virtual EVROverlayError FindOverlay( const char *pchOverlayKey, VROverlayHandle_t * pOverlayHandle ) = 0;
/** Creates a new named overlay. All overlays start hidden and with default settings. */
virtual EVROverlayError CreateOverlay( const char *pchOverlayKey, const char *pchOverlayFriendlyName, VROverlayHandle_t * pOverlayHandle ) = 0;
/** Destroys the specified overlay. When an application calls VR_Shutdown all overlays created by that app are
* automatically destroyed. */
virtual EVROverlayError DestroyOverlay( VROverlayHandle_t ulOverlayHandle ) = 0;
/** Specify which overlay to use the high quality render path. This overlay will be composited in during the distortion pass which
* results in it drawing on top of everything else, but also at a higher quality as it samples the source texture directly rather than
* rasterizing into each eye's render texture first. Because if this, only one of these is supported at any given time. It is most useful
* for overlays that are expected to take up most of the user's view (e.g. streaming video). */
virtual EVROverlayError SetHighQualityOverlay( VROverlayHandle_t ulOverlayHandle ) = 0;
/** Returns the overlay handle of the current overlay being rendered using the single high quality overlay render path.
* Otherwise it will return k_ulOverlayHandleInvalid. */
virtual vr::VROverlayHandle_t GetHighQualityOverlay() = 0;
/** Fills the provided buffer with the string key of the overlay. Returns the size of buffer required to store the key, including
* the terminating null character. k_unVROverlayMaxKeyLength will be enough bytes to fit the string. */
virtual uint32_t GetOverlayKey( VROverlayHandle_t ulOverlayHandle, VR_OUT_STRING() char *pchValue, uint32_t unBufferSize, EVROverlayError *pError = 0L ) = 0;
/** Fills the provided buffer with the friendly name of the overlay. Returns the size of buffer required to store the key, including
* the terminating null character. k_unVROverlayMaxNameLength will be enough bytes to fit the string. */
virtual uint32_t GetOverlayName( VROverlayHandle_t ulOverlayHandle, VR_OUT_STRING() char *pchValue, uint32_t unBufferSize, EVROverlayError *pError = 0L ) = 0;
/** Gets the raw image data from an overlay. Overlay image data is always returned as RGBA data, 4 bytes per pixel. If the buffer is not large enough, width and height
* will be set and VROverlayError_ArrayTooSmall is returned. */
virtual EVROverlayError GetOverlayImageData( VROverlayHandle_t ulOverlayHandle, void *pvBuffer, uint32_t unBufferSize, uint32_t *punWidth, uint32_t *punHeight ) = 0;
/** returns a string that corresponds with the specified overlay error. The string will be the name
* of the error enum value for all valid error codes */
virtual const char *GetOverlayErrorNameFromEnum( EVROverlayError error ) = 0;
// ---------------------------------------------
// Overlay rendering methods
// ---------------------------------------------
/** Specify flag setting for a given overlay */
virtual EVROverlayError SetOverlayFlag( VROverlayHandle_t ulOverlayHandle, VROverlayFlags eOverlayFlag, bool bEnabled ) = 0;
/** Sets flag setting for a given overlay */
virtual EVROverlayError GetOverlayFlag( VROverlayHandle_t ulOverlayHandle, VROverlayFlags eOverlayFlag, bool *pbEnabled ) = 0;
/** Sets the color tint of the overlay quad. Use 0.0 to 1.0 per channel. */
virtual EVROverlayError SetOverlayColor( VROverlayHandle_t ulOverlayHandle, float fRed, float fGreen, float fBlue ) = 0;
/** Gets the color tint of the overlay quad. */
virtual EVROverlayError GetOverlayColor( VROverlayHandle_t ulOverlayHandle, float *pfRed, float *pfGreen, float *pfBlue ) = 0;
/** Sets the alpha of the overlay quad. Use 1.0 for 100 percent opacity to 0.0 for 0 percent opacity. */
virtual EVROverlayError SetOverlayAlpha( VROverlayHandle_t ulOverlayHandle, float fAlpha ) = 0;
/** Gets the alpha of the overlay quad. By default overlays are rendering at 100 percent alpha (1.0). */
virtual EVROverlayError GetOverlayAlpha( VROverlayHandle_t ulOverlayHandle, float *pfAlpha ) = 0;
/** Sets the width of the overlay quad in meters. By default overlays are rendered on a quad that is 1 meter across */
virtual EVROverlayError SetOverlayWidthInMeters( VROverlayHandle_t ulOverlayHandle, float fWidthInMeters ) = 0;
/** Returns the width of the overlay quad in meters. By default overlays are rendered on a quad that is 1 meter across */
virtual EVROverlayError GetOverlayWidthInMeters( VROverlayHandle_t ulOverlayHandle, float *pfWidthInMeters ) = 0;
/** For high-quality curved overlays only, sets the distance range in meters from the overlay used to automatically curve
* the surface around the viewer. Min is distance is when the surface will be most curved. Max is when least curved. */
virtual EVROverlayError SetOverlayAutoCurveDistanceRangeInMeters( VROverlayHandle_t ulOverlayHandle, float fMinDistanceInMeters, float fMaxDistanceInMeters ) = 0;
/** For high-quality curved overlays only, gets the distance range in meters from the overlay used to automatically curve
* the surface around the viewer. Min is distance is when the surface will be most curved. Max is when least curved. */
virtual EVROverlayError GetOverlayAutoCurveDistanceRangeInMeters( VROverlayHandle_t ulOverlayHandle, float *pfMinDistanceInMeters, float *pfMaxDistanceInMeters ) = 0;
/** Sets the colorspace the overlay texture's data is in. Defaults to 'auto'.
* If the texture needs to be resolved, you should call SetOverlayTexture with the appropriate colorspace instead. */
virtual EVROverlayError SetOverlayTextureColorSpace( VROverlayHandle_t ulOverlayHandle, EColorSpace eTextureColorSpace ) = 0;
/** Gets the overlay's current colorspace setting. */
virtual EVROverlayError GetOverlayTextureColorSpace( VROverlayHandle_t ulOverlayHandle, EColorSpace *peTextureColorSpace ) = 0;
/** Sets the part of the texture to use for the overlay. UV Min is the upper left corner and UV Max is the lower right corner. */
virtual EVROverlayError SetOverlayTextureBounds( VROverlayHandle_t ulOverlayHandle, const VRTextureBounds_t *pOverlayTextureBounds ) = 0;
/** Gets the part of the texture to use for the overlay. UV Min is the upper left corner and UV Max is the lower right corner. */
virtual EVROverlayError GetOverlayTextureBounds( VROverlayHandle_t ulOverlayHandle, VRTextureBounds_t *pOverlayTextureBounds ) = 0;
/** Returns the transform type of this overlay. */
virtual EVROverlayError GetOverlayTransformType( VROverlayHandle_t ulOverlayHandle, VROverlayTransformType *peTransformType ) = 0;
/** Sets the transform to absolute tracking origin. */
virtual EVROverlayError SetOverlayTransformAbsolute( VROverlayHandle_t ulOverlayHandle, ETrackingUniverseOrigin eTrackingOrigin, const HmdMatrix34_t *pmatTrackingOriginToOverlayTransform ) = 0;
/** Gets the transform if it is absolute. Returns an error if the transform is some other type. */
virtual EVROverlayError GetOverlayTransformAbsolute( VROverlayHandle_t ulOverlayHandle, ETrackingUniverseOrigin *peTrackingOrigin, HmdMatrix34_t *pmatTrackingOriginToOverlayTransform ) = 0;
/** Sets the transform to relative to the transform of the specified tracked device. */
virtual EVROverlayError SetOverlayTransformTrackedDeviceRelative( VROverlayHandle_t ulOverlayHandle, TrackedDeviceIndex_t unTrackedDevice, const HmdMatrix34_t *pmatTrackedDeviceToOverlayTransform ) = 0;
/** Gets the transform if it is relative to a tracked device. Returns an error if the transform is some other type. */
virtual EVROverlayError GetOverlayTransformTrackedDeviceRelative( VROverlayHandle_t ulOverlayHandle, TrackedDeviceIndex_t *punTrackedDevice, HmdMatrix34_t *pmatTrackedDeviceToOverlayTransform ) = 0;
/** Sets the transform to draw the overlay on a rendermodel component mesh instead of a quad. This will only draw when the system is
* drawing the device. Overlays with this transform type cannot receive mouse events. */
virtual EVROverlayError SetOverlayTransformTrackedDeviceComponent( VROverlayHandle_t ulOverlayHandle, TrackedDeviceIndex_t unDeviceIndex, const char *pchComponentName ) = 0;
/** Gets the transform information when the overlay is rendering on a component. */
virtual EVROverlayError GetOverlayTransformTrackedDeviceComponent( VROverlayHandle_t ulOverlayHandle, TrackedDeviceIndex_t *punDeviceIndex, char *pchComponentName, uint32_t unComponentNameSize ) = 0;
/** Shows the VR overlay. For dashboard overlays, only the Dashboard Manager is allowed to call this. */
virtual EVROverlayError ShowOverlay( VROverlayHandle_t ulOverlayHandle ) = 0;
/** Hides the VR overlay. For dashboard overlays, only the Dashboard Manager is allowed to call this. */
virtual EVROverlayError HideOverlay( VROverlayHandle_t ulOverlayHandle ) = 0;
/** Returns true if the overlay is visible. */
virtual bool IsOverlayVisible( VROverlayHandle_t ulOverlayHandle ) = 0;
/** Get the transform in 3d space associated with a specific 2d point in the overlay's coordinate space (where 0,0 is the lower left). -Z points out of the overlay */
virtual EVROverlayError GetTransformForOverlayCoordinates( VROverlayHandle_t ulOverlayHandle, ETrackingUniverseOrigin eTrackingOrigin, HmdVector2_t coordinatesInOverlay, HmdMatrix34_t *pmatTransform ) = 0;
// ---------------------------------------------
// Overlay input methods
// ---------------------------------------------
/** Returns true and fills the event with the next event on the overlay's event queue, if there is one.
* If there are no events this method returns false. uncbVREvent should be the size in bytes of the VREvent_t struct */
virtual bool PollNextOverlayEvent( VROverlayHandle_t ulOverlayHandle, VREvent_t *pEvent, uint32_t uncbVREvent ) = 0;
/** Returns the current input settings for the specified overlay. */
virtual EVROverlayError GetOverlayInputMethod( VROverlayHandle_t ulOverlayHandle, VROverlayInputMethod *peInputMethod ) = 0;
/** Sets the input settings for the specified overlay. */
virtual EVROverlayError SetOverlayInputMethod( VROverlayHandle_t ulOverlayHandle, VROverlayInputMethod eInputMethod ) = 0;
/** Gets the mouse scaling factor that is used for mouse events. The actual texture may be a different size, but this is
* typically the size of the underlying UI in pixels. */
virtual EVROverlayError GetOverlayMouseScale( VROverlayHandle_t ulOverlayHandle, HmdVector2_t *pvecMouseScale ) = 0;
/** Sets the mouse scaling factor that is used for mouse events. The actual texture may be a different size, but this is
* typically the size of the underlying UI in pixels. */
virtual EVROverlayError SetOverlayMouseScale( VROverlayHandle_t ulOverlayHandle, const HmdVector2_t *pvecMouseScale ) = 0;
/** Computes the overlay-space pixel coordinates of where the ray intersects the overlay with the
* specified settings. Returns false if there is no intersection. */
virtual bool ComputeOverlayIntersection( VROverlayHandle_t ulOverlayHandle, const VROverlayIntersectionParams_t *pParams, VROverlayIntersectionResults_t *pResults ) = 0;
/** Processes mouse input from the specified controller as though it were a mouse pointed at a compositor overlay with the
* specified settings. The controller is treated like a laser pointer on the -z axis. The point where the laser pointer would
* intersect with the overlay is the mouse position, the trigger is left mouse, and the track pad is right mouse.
*
* Return true if the controller is pointed at the overlay and an event was generated. */
virtual bool HandleControllerOverlayInteractionAsMouse( VROverlayHandle_t ulOverlayHandle, TrackedDeviceIndex_t unControllerDeviceIndex ) = 0;
/** Returns true if the specified overlay is the hover target. An overlay is the hover target when it is the last overlay "moused over"
* by the virtual mouse pointer */
virtual bool IsHoverTargetOverlay( VROverlayHandle_t ulOverlayHandle ) = 0;
/** Returns the current Gamepad focus overlay */
virtual vr::VROverlayHandle_t GetGamepadFocusOverlay() = 0;
/** Sets the current Gamepad focus overlay */
virtual EVROverlayError SetGamepadFocusOverlay( VROverlayHandle_t ulNewFocusOverlay ) = 0;
/** Sets an overlay's neighbor. This will also set the neighbor of the "to" overlay
* to point back to the "from" overlay. If an overlay's neighbor is set to invalid both
* ends will be cleared */
virtual EVROverlayError SetOverlayNeighbor( EOverlayDirection eDirection, VROverlayHandle_t ulFrom, VROverlayHandle_t ulTo ) = 0;
/** Changes the Gamepad focus from one overlay to one of its neighbors. Returns VROverlayError_NoNeighbor if there is no
* neighbor in that direction */
virtual EVROverlayError MoveGamepadFocusToNeighbor( EOverlayDirection eDirection, VROverlayHandle_t ulFrom ) = 0;
// ---------------------------------------------
// Overlay texture methods
// ---------------------------------------------
/** Texture to draw for the overlay. IVRCompositor::SetGraphicsDevice must be called before
* this function. This function can only be called by the overlay's renderer process.
*
* If pBounds is NULL the entire texture will be used.
*
* OpenGL dirty state:
* glBindTexture
*/
virtual EVROverlayError SetOverlayTexture( VROverlayHandle_t ulOverlayHandle, const Texture_t *pTexture ) = 0;
/** Use this to tell the overlay system to release the texture set for this overlay. */
virtual EVROverlayError ClearOverlayTexture( VROverlayHandle_t ulOverlayHandle ) = 0;
/** Separate interface for providing the data as a stream of bytes, but there is an upper bound on data
* that can be sent. This function can only be called by the overlay's renderer process. */
virtual EVROverlayError SetOverlayRaw( VROverlayHandle_t ulOverlayHandle, void *pvBuffer, uint32_t unWidth, uint32_t unHeight, uint32_t unDepth ) = 0;
/** Separate interface for providing the image through a filename: can be png or jpg, and should not be bigger than 1920x1080.
* This function can only be called by the overlay's renderer process */
virtual EVROverlayError SetOverlayFromFile( VROverlayHandle_t ulOverlayHandle, const char *pchFilePath ) = 0;
// ----------------------------------------------
// Dashboard Overlay Methods
// ----------------------------------------------
/** Creates a dashboard overlay and returns its handle */
virtual EVROverlayError CreateDashboardOverlay( const char *pchOverlayKey, const char *pchOverlayFriendlyName, VROverlayHandle_t * pMainHandle, VROverlayHandle_t *pThumbnailHandle ) = 0;
/** Returns true if the dashboard is visible */
virtual bool IsDashboardVisible() = 0;
/** returns true if the dashboard is visible and the specified overlay is the active system Overlay */
virtual bool IsActiveDashboardOverlay( VROverlayHandle_t ulOverlayHandle ) = 0;
/** Sets the dashboard overlay to only appear when the specified process ID has scene focus */
virtual EVROverlayError SetDashboardOverlaySceneProcess( VROverlayHandle_t ulOverlayHandle, uint32_t unProcessId ) = 0;
/** Gets the process ID that this dashboard overlay requires to have scene focus */
virtual EVROverlayError GetDashboardOverlaySceneProcess( VROverlayHandle_t ulOverlayHandle, uint32_t *punProcessId ) = 0;
/** Shows the dashboard. */
virtual void ShowDashboard( const char *pchOverlayToShow ) = 0;
/** Returns the tracked device that has the laser pointer in the dashboard */
virtual vr::TrackedDeviceIndex_t GetPrimaryDashboardDevice() = 0;
// ---------------------------------------------
// Keyboard methods
// ---------------------------------------------
/** Show the virtual keyboard to accept input **/
virtual EVROverlayError ShowKeyboard( EGamepadTextInputMode eInputMode, EGamepadTextInputLineMode eLineInputMode, const char *pchDescription, uint32_t unCharMax, const char *pchExistingText, bool bUseMinimalMode, uint64_t uUserValue ) = 0;
virtual EVROverlayError ShowKeyboardForOverlay( VROverlayHandle_t ulOverlayHandle, EGamepadTextInputMode eInputMode, EGamepadTextInputLineMode eLineInputMode, const char *pchDescription, uint32_t unCharMax, const char *pchExistingText, bool bUseMinimalMode, uint64_t uUserValue ) = 0;
/** Get the text that was entered into the text input **/
virtual uint32_t GetKeyboardText( VR_OUT_STRING() char *pchText, uint32_t cchText ) = 0;
/** Hide the virtual keyboard **/
virtual void HideKeyboard() = 0;
/** Set the position of the keyboard in world space **/
virtual void SetKeyboardTransformAbsolute( ETrackingUniverseOrigin eTrackingOrigin, const HmdMatrix34_t *pmatTrackingOriginToKeyboardTransform ) = 0;
/** Set the position of the keyboard in overlay space by telling it to avoid a rectangle in the overlay. Rectangle coords have (0,0) in the bottom left **/
virtual void SetKeyboardPositionForOverlay( VROverlayHandle_t ulOverlayHandle, HmdRect2_t avoidRect ) = 0;
};
static const char * const IVROverlay_Version = "IVROverlay_010";
} // namespace vr
// ivrrendermodels.h
namespace vr
{
static const char * const k_pch_Controller_Component_GDC2015 = "gdc2015"; // Canonical coordinate system of the gdc 2015 wired controller, provided for backwards compatibility
static const char * const k_pch_Controller_Component_Base = "base"; // For controllers with an unambiguous 'base'.
static const char * const k_pch_Controller_Component_Tip = "tip"; // For controllers with an unambiguous 'tip' (used for 'laser-pointing')
static const char * const k_pch_Controller_Component_HandGrip = "handgrip"; // Neutral, ambidextrous hand-pose when holding controller. On plane between neutrally posed index finger and thumb
static const char * const k_pch_Controller_Component_Status = "status"; // 1:1 aspect ratio status area, with canonical [0,1] uv mapping
#if defined(__linux__) || defined(__APPLE__)
// The 32-bit version of gcc has the alignment requirement for uint64 and double set to
// 4 meaning that even with #pragma pack(8) these types will only be four-byte aligned.
// The 64-bit version of gcc has the alignment requirement for these types set to
// 8 meaning that unless we use #pragma pack(4) our structures will get bigger.
// The 64-bit structure packing has to match the 32-bit structure packing for each platform.
#pragma pack( push, 4 )
#else
#pragma pack( push, 8 )
#endif
/** Errors that can occur with the VR compositor */
enum EVRRenderModelError
{
VRRenderModelError_None = 0,
VRRenderModelError_Loading = 100,
VRRenderModelError_NotSupported = 200,
VRRenderModelError_InvalidArg = 300,
VRRenderModelError_InvalidModel = 301,
VRRenderModelError_NoShapes = 302,
VRRenderModelError_MultipleShapes = 303,
VRRenderModelError_TooManyIndices = 304,
VRRenderModelError_MultipleTextures = 305,
VRRenderModelError_InvalidTexture = 400,
};
typedef uint32_t VRComponentProperties;
enum EVRComponentProperty
{
VRComponentProperty_IsStatic = (1 << 0),
VRComponentProperty_IsVisible = (1 << 1),
VRComponentProperty_IsTouched = (1 << 2),
VRComponentProperty_IsPressed = (1 << 3),
VRComponentProperty_IsScrolled = (1 << 4),
};
/** Describes state information about a render-model component, including transforms and other dynamic properties */
struct RenderModel_ComponentState_t
{
HmdMatrix34_t mTrackingToComponentRenderModel; // Transform required when drawing the component render model
HmdMatrix34_t mTrackingToComponentLocal; // Transform available for attaching to a local component coordinate system (-Z out from surface )
VRComponentProperties uProperties;
};
/** A single vertex in a render model */
struct RenderModel_Vertex_t
{
HmdVector3_t vPosition; // position in meters in device space
HmdVector3_t vNormal;
float rfTextureCoord[2];
};
/** A texture map for use on a render model */
struct RenderModel_TextureMap_t
{
uint16_t unWidth, unHeight; // width and height of the texture map in pixels
const uint8_t *rubTextureMapData; // Map texture data. All textures are RGBA with 8 bits per channel per pixel. Data size is width * height * 4ub
};
/** Session unique texture identifier. Rendermodels which share the same texture will have the same id.
IDs <0 denote the texture is not present */
typedef int32_t TextureID_t;
struct RenderModel_t
{
const RenderModel_Vertex_t *rVertexData; // Vertex data for the mesh
uint32_t unVertexCount; // Number of vertices in the vertex data
const uint16_t *rIndexData; // Indices into the vertex data for each triangle
uint32_t unTriangleCount; // Number of triangles in the mesh. Index count is 3 * TriangleCount
TextureID_t diffuseTextureId; // Session unique texture identifier. Rendermodels which share the same texture will have the same id. <0 == texture not present
};
struct RenderModel_ControllerMode_State_t
{
bool bScrollWheelVisible; // is this controller currently set to be in a scroll wheel mode
};
#pragma pack( pop )
class IVRRenderModels
{
public:
/** Loads and returns a render model for use in the application. pchRenderModelName should be a render model name
* from the Prop_RenderModelName_String property or an absolute path name to a render model on disk.
*
* The resulting render model is valid until VR_Shutdown() is called or until FreeRenderModel() is called. When the
* application is finished with the render model it should call FreeRenderModel() to free the memory associated
* with the model.
*
* The method returns VRRenderModelError_Loading while the render model is still being loaded.
* The method returns VRRenderModelError_None once loaded successfully, otherwise will return an error. */
virtual EVRRenderModelError LoadRenderModel_Async( const char *pchRenderModelName, RenderModel_t **ppRenderModel ) = 0;
/** Frees a previously returned render model
* It is safe to call this on a null ptr. */
virtual void FreeRenderModel( RenderModel_t *pRenderModel ) = 0;
/** Loads and returns a texture for use in the application. */
virtual EVRRenderModelError LoadTexture_Async( TextureID_t textureId, RenderModel_TextureMap_t **ppTexture ) = 0;
/** Frees a previously returned texture
* It is safe to call this on a null ptr. */
virtual void FreeTexture( RenderModel_TextureMap_t *pTexture ) = 0;
/** Creates a D3D11 texture and loads data into it. */
virtual EVRRenderModelError LoadTextureD3D11_Async( TextureID_t textureId, void *pD3D11Device, void **ppD3D11Texture2D ) = 0;
/** Use this to free textures created with LoadTextureD3D11_Async instead of calling Release on them. */
virtual void FreeTextureD3D11( void *pD3D11Texture2D ) = 0;
/** Use this to get the names of available render models. Index does not correlate to a tracked device index, but
* is only used for iterating over all available render models. If the index is out of range, this function will return 0.
* Otherwise, it will return the size of the buffer required for the name. */
virtual uint32_t GetRenderModelName( uint32_t unRenderModelIndex, VR_OUT_STRING() char *pchRenderModelName, uint32_t unRenderModelNameLen ) = 0;
/** Returns the number of available render models. */
virtual uint32_t GetRenderModelCount() = 0;
/** Returns the number of components of the specified render model.
* Components are useful when client application wish to draw, label, or otherwise interact with components of tracked objects.
* Examples controller components:
* renderable things such as triggers, buttons
* non-renderable things which include coordinate systems such as 'tip', 'base', a neutral controller agnostic hand-pose
* If all controller components are enumerated and rendered, it will be equivalent to drawing the traditional render model
* Returns 0 if components not supported, >0 otherwise */
virtual uint32_t GetComponentCount( const char *pchRenderModelName ) = 0;
/** Use this to get the names of available components. Index does not correlate to a tracked device index, but
* is only used for iterating over all available components. If the index is out of range, this function will return 0.
* Otherwise, it will return the size of the buffer required for the name. */
virtual uint32_t GetComponentName( const char *pchRenderModelName, uint32_t unComponentIndex, VR_OUT_STRING( ) char *pchComponentName, uint32_t unComponentNameLen ) = 0;
/** Get the button mask for all buttons associated with this component
* If no buttons (or axes) are associated with this component, return 0
* Note: multiple components may be associated with the same button. Ex: two grip buttons on a single controller.
* Note: A single component may be associated with multiple buttons. Ex: A trackpad which also provides "D-pad" functionality */
virtual uint64_t GetComponentButtonMask( const char *pchRenderModelName, const char *pchComponentName ) = 0;
/** Use this to get the render model name for the specified rendermode/component combination, to be passed to LoadRenderModel.
* If the component name is out of range, this function will return 0.
* Otherwise, it will return the size of the buffer required for the name. */
virtual uint32_t GetComponentRenderModelName( const char *pchRenderModelName, const char *pchComponentName, VR_OUT_STRING( ) char *pchComponentRenderModelName, uint32_t unComponentRenderModelNameLen ) = 0;
/** Use this to query information about the component, as a function of the controller state.
*
* For dynamic controller components (ex: trigger) values will reflect component motions
* For static components this will return a consistent value independent of the VRControllerState_t
*
* If the pchRenderModelName or pchComponentName is invalid, this will return false (and transforms will be set to identity).
* Otherwise, return true
* Note: For dynamic objects, visibility may be dynamic. (I.e., true/false will be returned based on controller state and controller mode state ) */
virtual bool GetComponentState( const char *pchRenderModelName, const char *pchComponentName, const vr::VRControllerState_t *pControllerState, const RenderModel_ControllerMode_State_t *pState, RenderModel_ComponentState_t *pComponentState ) = 0;
/** Returns true if the render model has a component with the specified name */
virtual bool RenderModelHasComponent( const char *pchRenderModelName, const char *pchComponentName ) = 0;
};
static const char * const IVRRenderModels_Version = "IVRRenderModels_004";
}
// ivrextendeddisplay.h
namespace vr
{
/** NOTE: Use of this interface is not recommended in production applications. It will not work for displays which use
* direct-to-display mode. It is also incompatible with the VR compositor and is not available when the compositor is running. */
class IVRExtendedDisplay
{
public:
/** Size and position that the window needs to be on the VR display. */
virtual void GetWindowBounds( int32_t *pnX, int32_t *pnY, uint32_t *pnWidth, uint32_t *pnHeight ) = 0;
/** Gets the viewport in the frame buffer to draw the output of the distortion into */
virtual void GetEyeOutputViewport( EVREye eEye, uint32_t *pnX, uint32_t *pnY, uint32_t *pnWidth, uint32_t *pnHeight ) = 0;
/** [D3D10/11 Only]
* Returns the adapter index and output index that the user should pass into EnumAdapters and EnumOutputs
* to create the device and swap chain in DX10 and DX11. If an error occurs both indices will be set to -1.
*/
virtual void GetDXGIOutputInfo( int32_t *pnAdapterIndex, int32_t *pnAdapterOutputIndex ) = 0;
};
static const char * const IVRExtendedDisplay_Version = "IVRExtendedDisplay_001";
}
// End
#endif // _OPENVR_API
namespace vr
{
/** Finds the active installation of the VR API and initializes it. The provided path must be absolute
* or relative to the current working directory. These are the local install versions of the equivalent
* functions in steamvr.h and will work without a local Steam install.
*
* This path is to the "root" of the VR API install. That's the directory with
* the "drivers" directory and a platform (i.e. "win32") directory in it, not the directory with the DLL itself.
*/
inline IVRSystem *VR_Init( EVRInitError *peError, EVRApplicationType eApplicationType );
/** unloads vrclient.dll. Any interface pointers from the interface are
* invalid after this point */
inline void VR_Shutdown();
/** Returns true if there is an HMD attached. This check is as lightweight as possible and
* can be called outside of VR_Init/VR_Shutdown. It should be used when an application wants
* to know if initializing VR is a possibility but isn't ready to take that step yet.
*/
VR_INTERFACE bool VR_CALLTYPE VR_IsHmdPresent();
/** Returns true if the OpenVR runtime is installed. */
VR_INTERFACE bool VR_CALLTYPE VR_IsRuntimeInstalled();
/** Returns where the OpenVR runtime is installed. */
VR_INTERFACE const char *VR_CALLTYPE VR_RuntimePath();
/** Returns the name of the enum value for an EVRInitError. This function may be called outside of VR_Init()/VR_Shutdown(). */
VR_INTERFACE const char *VR_CALLTYPE VR_GetVRInitErrorAsSymbol( EVRInitError error );
/** Returns an english string for an EVRInitError. Applications should call VR_GetVRInitErrorAsSymbol instead and
* use that as a key to look up their own localized error message. This function may be called outside of VR_Init()/VR_Shutdown(). */
VR_INTERFACE const char *VR_CALLTYPE VR_GetVRInitErrorAsEnglishDescription( EVRInitError error );
/** Returns the interface of the specified version. This method must be called after VR_Init. The
* pointer returned is valid until VR_Shutdown is called.
*/
VR_INTERFACE void *VR_CALLTYPE VR_GetGenericInterface( const char *pchInterfaceVersion, EVRInitError *peError );
/** Returns whether the interface of the specified version exists.
*/
VR_INTERFACE bool VR_CALLTYPE VR_IsInterfaceVersionValid( const char *pchInterfaceVersion );
/** Returns a token that represents whether the VR interface handles need to be reloaded */
VR_INTERFACE uint32_t VR_CALLTYPE VR_GetInitToken();
// These typedefs allow old enum names from SDK 0.9.11 to be used in applications.
// They will go away in the future.
typedef EVRInitError HmdError;
typedef EVREye Hmd_Eye;
typedef EGraphicsAPIConvention GraphicsAPIConvention;
typedef EColorSpace ColorSpace;
typedef ETrackingResult HmdTrackingResult;
typedef ETrackedDeviceClass TrackedDeviceClass;
typedef ETrackingUniverseOrigin TrackingUniverseOrigin;
typedef ETrackedDeviceProperty TrackedDeviceProperty;
typedef ETrackedPropertyError TrackedPropertyError;
typedef EVRSubmitFlags VRSubmitFlags_t;
typedef EVRState VRState_t;
typedef ECollisionBoundsStyle CollisionBoundsStyle_t;
typedef EVROverlayError VROverlayError;
typedef EVRFirmwareError VRFirmwareError;
typedef EVRCompositorError VRCompositorError;
inline uint32_t &VRToken()
{
static uint32_t token;
return token;
}
class COpenVRContext
{
public:
COpenVRContext() { Clear(); }
void Clear();
inline void CheckClear()
{
if ( VRToken() != VR_GetInitToken() )
{
Clear();
VRToken() = VR_GetInitToken();
}
}
IVRSystem *VRSystem()
{
CheckClear();
if ( m_pVRSystem == nullptr )
{
EVRInitError eError;
m_pVRSystem = ( IVRSystem * )VR_GetGenericInterface( IVRSystem_Version, &eError );
}
return m_pVRSystem;
}
IVRChaperone *VRChaperone()
{
CheckClear();
if ( m_pVRChaperone == nullptr )
{
EVRInitError eError;
m_pVRChaperone = ( IVRChaperone * )VR_GetGenericInterface( IVRChaperone_Version, &eError );
}
return m_pVRChaperone;
}
IVRChaperoneSetup *VRChaperoneSetup()
{
CheckClear();
if ( m_pVRChaperoneSetup == nullptr )
{
EVRInitError eError;
m_pVRChaperoneSetup = ( IVRChaperoneSetup * )VR_GetGenericInterface( IVRChaperoneSetup_Version, &eError );
}
return m_pVRChaperoneSetup;
}
IVRCompositor *VRCompositor()
{
CheckClear();
if ( m_pVRCompositor == nullptr )
{
EVRInitError eError;
m_pVRCompositor = ( IVRCompositor * )VR_GetGenericInterface( IVRCompositor_Version, &eError );
}
return m_pVRCompositor;
}
IVROverlay *VROverlay()
{
CheckClear();
if ( m_pVROverlay == nullptr )
{
EVRInitError eError;
m_pVROverlay = ( IVROverlay * )VR_GetGenericInterface( IVROverlay_Version, &eError );
}
return m_pVROverlay;
}
IVRRenderModels *VRRenderModels()
{
CheckClear();
if ( m_pVRRenderModels == nullptr )
{
EVRInitError eError;
m_pVRRenderModels = ( IVRRenderModels * )VR_GetGenericInterface( IVRRenderModels_Version, &eError );
}
return m_pVRRenderModels;
}
IVRExtendedDisplay *VRExtendedDisplay()
{
CheckClear();
if ( m_pVRExtendedDisplay == nullptr )
{
EVRInitError eError;
m_pVRExtendedDisplay = ( IVRExtendedDisplay * )VR_GetGenericInterface( IVRExtendedDisplay_Version, &eError );
}
return m_pVRExtendedDisplay;
}
IVRSettings *VRSettings()
{
CheckClear();
if ( m_pVRSettings == nullptr )
{
EVRInitError eError;
m_pVRSettings = ( IVRSettings * )VR_GetGenericInterface( IVRSettings_Version, &eError );
}
return m_pVRSettings;
}
IVRApplications *VRApplications()
{
CheckClear();
if ( m_pVRApplications == nullptr )
{
EVRInitError eError;
m_pVRApplications = ( IVRApplications * )VR_GetGenericInterface( IVRApplications_Version, &eError );
}
return m_pVRApplications;
}
private:
IVRSystem *m_pVRSystem;
IVRChaperone *m_pVRChaperone;
IVRChaperoneSetup *m_pVRChaperoneSetup;
IVRCompositor *m_pVRCompositor;
IVROverlay *m_pVROverlay;
IVRRenderModels *m_pVRRenderModels;
IVRExtendedDisplay *m_pVRExtendedDisplay;
IVRSettings *m_pVRSettings;
IVRApplications *m_pVRApplications;
};
inline COpenVRContext &OpenVRInternal_ModuleContext()
{
static void *ctx[ sizeof( COpenVRContext ) / sizeof( void * ) ];
return *( COpenVRContext * )ctx; // bypass zero-init constructor
}
inline IVRSystem *VR_CALLTYPE VRSystem() { return OpenVRInternal_ModuleContext().VRSystem(); }
inline IVRChaperone *VR_CALLTYPE VRChaperone() { return OpenVRInternal_ModuleContext().VRChaperone(); }
inline IVRChaperoneSetup *VR_CALLTYPE VRChaperoneSetup() { return OpenVRInternal_ModuleContext().VRChaperoneSetup(); }
inline IVRCompositor *VR_CALLTYPE VRCompositor() { return OpenVRInternal_ModuleContext().VRCompositor(); }
inline IVROverlay *VR_CALLTYPE VROverlay() { return OpenVRInternal_ModuleContext().VROverlay(); }
inline IVRRenderModels *VR_CALLTYPE VRRenderModels() { return OpenVRInternal_ModuleContext().VRRenderModels(); }
inline IVRApplications *VR_CALLTYPE VRApplications() { return OpenVRInternal_ModuleContext().VRApplications(); }
inline IVRSettings *VR_CALLTYPE VRSettings() { return OpenVRInternal_ModuleContext().VRSettings(); }
inline IVRExtendedDisplay *VR_CALLTYPE VRExtendedDisplay() { return OpenVRInternal_ModuleContext().VRExtendedDisplay(); }
inline void COpenVRContext::Clear()
{
m_pVRSystem = nullptr;
m_pVRChaperone = nullptr;
m_pVRChaperoneSetup = nullptr;
m_pVRCompositor = nullptr;
m_pVROverlay = nullptr;
m_pVRRenderModels = nullptr;
m_pVRExtendedDisplay = nullptr;
m_pVRSettings = nullptr;
m_pVRApplications = nullptr;
}
VR_INTERFACE uint32_t VR_CALLTYPE VR_InitInternal( EVRInitError *peError, EVRApplicationType eApplicationType );
VR_INTERFACE void VR_CALLTYPE VR_ShutdownInternal();
/** Finds the active installation of vrclient.dll and initializes it */
inline IVRSystem *VR_Init( EVRInitError *peError, EVRApplicationType eApplicationType )
{
IVRSystem *pVRSystem = nullptr;
EVRInitError eError;
VRToken() = VR_InitInternal( &eError, eApplicationType );
COpenVRContext &ctx = OpenVRInternal_ModuleContext();
ctx.Clear();
if ( eError == VRInitError_None )
{
if ( VR_IsInterfaceVersionValid( IVRSystem_Version ) )
{
pVRSystem = VRSystem();
}
else
{
VR_ShutdownInternal();
eError = VRInitError_Init_InterfaceNotFound;
}
}
if ( peError )
*peError = eError;
return pVRSystem;
}
/** unloads vrclient.dll. Any interface pointers from the interface are
* invalid after this point */
inline void VR_Shutdown()
{
VR_ShutdownInternal();
}
}