2020-04-22 16:56:21 +00:00
//========= Copyright Valve Corporation, All rights reserved. ============//
//
// Purpose:
//
// $NoKeywords: $
//===========================================================================//
# include "cbase.h"
# include "client_virtualreality.h"
# include "materialsystem/itexture.h"
# include "materialsystem/materialsystem_config.h"
# include "view_shared.h"
# include "view_scene.h"
# include "VGuiMatSurface/IMatSystemSurface.h"
# include "vgui_controls/Controls.h"
# include "sourcevr/isourcevirtualreality.h"
# include "ienginevgui.h"
# include "cdll_client_int.h"
# include "vgui/IVGui.h"
# include "vgui_controls/Controls.h"
# include "tier0/vprof_telemetry.h"
# include <time.h>
# include "steam/steam_api.h"
const char * COM_GetModDirectory ( ) ; // return the mod dir (rather than the complete -game param, which can be a path)
CClientVirtualReality g_ClientVirtualReality ;
EXPOSE_SINGLE_INTERFACE_GLOBALVAR ( CClientVirtualReality , IClientVirtualReality ,
CLIENTVIRTUALREALITY_INTERFACE_VERSION , g_ClientVirtualReality ) ;
// --------------------------------------------------------------------
// A huge pile of VR convars
// --------------------------------------------------------------------
ConVar vr_activate_default ( " vr_activate_default " , " 0 " , FCVAR_ARCHIVE , " If this is true the game will switch to VR mode once startup is complete. " ) ;
ConVar vr_moveaim_mode ( " vr_moveaim_mode " , " 3 " , FCVAR_ARCHIVE , " 0=move+shoot from face. 1=move with torso. 2,3,4=shoot with face+mouse cursor. 5+ are probably not that useful. " ) ;
ConVar vr_moveaim_mode_zoom ( " vr_moveaim_mode_zoom " , " 3 " , FCVAR_ARCHIVE , " 0=move+shoot from face. 1=move with torso. 2,3,4=shoot with face+mouse cursor. 5+ are probably not that useful. " ) ;
ConVar vr_moveaim_reticle_yaw_limit ( " vr_moveaim_reticle_yaw_limit " , " 10 " , FCVAR_ARCHIVE , " Beyond this number of degrees, the mouse drags the torso " ) ;
ConVar vr_moveaim_reticle_pitch_limit ( " vr_moveaim_reticle_pitch_limit " , " 30 " , FCVAR_ARCHIVE , " Beyond this number of degrees, the mouse clamps " ) ;
// Note these are scaled by the zoom factor.
ConVar vr_moveaim_reticle_yaw_limit_zoom ( " vr_moveaim_reticle_yaw_limit_zoom " , " 0 " , FCVAR_ARCHIVE , " Beyond this number of degrees, the mouse drags the torso " ) ;
ConVar vr_moveaim_reticle_pitch_limit_zoom ( " vr_moveaim_reticle_pitch_limit_zoom " , " -1 " , FCVAR_ARCHIVE , " Beyond this number of degrees, the mouse clamps " ) ;
// This are somewhat obsolete.
ConVar vr_aim_yaw_offset ( " vr_aim_yaw_offset " , " 90 " , 0 , " This value is added to Yaw when returning the vehicle aim angles to Source. " ) ;
ConVar vr_stereo_swap_eyes ( " vr_stereo_swap_eyes " , " 0 " , 0 , " 1=swap eyes. " ) ;
// Useful for debugging wacky-projection problems, separate from multi-rendering problems.
ConVar vr_stereo_mono_set_eye ( " vr_stereo_mono_set_eye " , " 0 " , 0 , " 0=off, Set all eyes to 1=left, 2=right, 3=middle eye " ) ;
// Useful for examining anims, etc.
ConVar vr_debug_remote_cam ( " vr_debug_remote_cam " , " 0 " ) ;
ConVar vr_debug_remote_cam_pos_x ( " vr_debug_remote_cam_pos_x " , " 150.0 " ) ;
ConVar vr_debug_remote_cam_pos_y ( " vr_debug_remote_cam_pos_y " , " 0.0 " ) ;
ConVar vr_debug_remote_cam_pos_z ( " vr_debug_remote_cam_pos_z " , " 0.0 " ) ;
ConVar vr_debug_remote_cam_target_x ( " vr_debug_remote_cam_target_x " , " 0.0 " ) ;
ConVar vr_debug_remote_cam_target_y ( " vr_debug_remote_cam_target_y " , " 0.0 " ) ;
ConVar vr_debug_remote_cam_target_z ( " vr_debug_remote_cam_target_z " , " -50.0 " ) ;
ConVar vr_translation_limit ( " vr_translation_limit " , " 10.0 " , 0 , " How far the in-game head will translate before being clamped. " ) ;
// HUD config values
ConVar vr_render_hud_in_world ( " vr_render_hud_in_world " , " 1 " ) ;
ConVar vr_hud_max_fov ( " vr_hud_max_fov " , " 60 " , FCVAR_ARCHIVE , " Max FOV of the HUD " ) ;
ConVar vr_hud_forward ( " vr_hud_forward " , " 500 " , FCVAR_ARCHIVE , " Apparent distance of the HUD in inches " ) ;
ConVar vr_hud_display_ratio ( " vr_hud_display_ratio " , " 0.95 " , FCVAR_ARCHIVE ) ;
ConVar vr_hud_never_overlay ( " vr_hud_never_overlay " , " 0 " ) ;
ConVar vr_hud_axis_lock_to_world ( " vr_hud_axis_lock_to_world " , " 0 " , FCVAR_ARCHIVE , " Bitfield - locks HUD axes to the world - 0=pitch, 1=yaw, 2=roll " ) ;
// Default distance clips through rocketlauncher, heavy's body, etc.
ConVar vr_projection_znear_multiplier ( " vr_projection_znear_multiplier " , " 0.3 " , 0 , " Allows moving the ZNear plane to deal with body clipping " ) ;
// Should the viewmodel (weapon) translate with the HMD, or remain fixed to the in-world body (but still rotate with the head)? Purely a graphics effect - no effect on actual bullet aiming.
// Has no effect in aim modes where aiming is not controlled by the head.
ConVar vr_viewmodel_translate_with_head ( " vr_viewmodel_translate_with_head " , " 0 " , 0 , " 1=translate the viewmodel with the head motion. " ) ;
ConVar vr_zoom_multiplier ( " vr_zoom_multiplier " , " 2.0 " , FCVAR_ARCHIVE , " When zoomed, how big is the scope on your HUD? " ) ;
ConVar vr_zoom_scope_scale ( " vr_zoom_scope_scale " , " 6.0 " , 0 , " Something to do with the default scope HUD overlay size. " ) ; // Horrible hack - should work out the math properly, but we need to ship.
ConVar vr_viewmodel_offset_forward ( " vr_viewmodel_offset_forward " , " -8 " , 0 ) ;
ConVar vr_viewmodel_offset_forward_large ( " vr_viewmodel_offset_forward_large " , " -15 " , 0 ) ;
ConVar vr_force_windowed ( " vr_force_windowed " , " 0 " , FCVAR_ARCHIVE ) ;
ConVar vr_first_person_uses_world_model ( " vr_first_person_uses_world_model " , " 1 " , 0 , " Causes the third person model to be drawn instead of the view model " ) ;
// --------------------------------------------------------------------
// Purpose: Cycle through the aim & move modes.
// --------------------------------------------------------------------
void CC_VR_Cycle_Aim_Move_Mode ( const CCommand & args )
{
int hmmCurrentMode = vr_moveaim_mode . GetInt ( ) ;
if ( g_ClientVirtualReality . CurrentlyZoomed ( ) )
{
hmmCurrentMode = vr_moveaim_mode_zoom . GetInt ( ) ;
}
hmmCurrentMode + + ;
if ( hmmCurrentMode > = HMM_LAST )
{
hmmCurrentMode = 0 ;
}
if ( g_ClientVirtualReality . CurrentlyZoomed ( ) )
{
vr_moveaim_mode_zoom . SetValue ( hmmCurrentMode ) ;
Warning ( " Headtrack mode (zoomed) %d \n " , hmmCurrentMode ) ;
}
else
{
vr_moveaim_mode . SetValue ( hmmCurrentMode ) ;
Warning ( " Headtrack mode %d \n " , hmmCurrentMode ) ;
}
}
static ConCommand vr_cycle_aim_move_mode ( " vr_cycle_aim_move_mode " , CC_VR_Cycle_Aim_Move_Mode , " Cycle through the aim & move modes. " ) ;
// --------------------------------------------------------------------
// Purpose: Switch to/from VR mode.
// --------------------------------------------------------------------
CON_COMMAND ( vr_activate , " Switch to VR mode " )
{
g_ClientVirtualReality . Activate ( ) ;
}
CON_COMMAND ( vr_deactivate , " Switch from VR mode to normal mode " )
{
g_ClientVirtualReality . Deactivate ( ) ;
}
CON_COMMAND ( vr_toggle , " Toggles VR mode " )
{
if ( g_pSourceVR )
{
if ( g_pSourceVR - > ShouldRunInVR ( ) )
g_ClientVirtualReality . Deactivate ( ) ;
else
g_ClientVirtualReality . Activate ( ) ;
}
else
{
Msg ( " VR Mode is not enabled. \n " ) ;
}
}
// --------------------------------------------------------------------
// Purpose: Returns true if the matrix is orthonormal
// --------------------------------------------------------------------
bool IsOrthonormal ( VMatrix Mat , float fTolerance )
{
float LenFwd = Mat . GetForward ( ) . Length ( ) ;
float LenUp = Mat . GetUp ( ) . Length ( ) ;
float LenLeft = Mat . GetLeft ( ) . Length ( ) ;
float DotFwdUp = Mat . GetForward ( ) . Dot ( Mat . GetUp ( ) ) ;
float DotUpLeft = Mat . GetUp ( ) . Dot ( Mat . GetLeft ( ) ) ;
float DotLeftFwd = Mat . GetLeft ( ) . Dot ( Mat . GetForward ( ) ) ;
if ( fabsf ( LenFwd - 1.0f ) > fTolerance )
{
return false ;
}
if ( fabsf ( LenUp - 1.0f ) > fTolerance )
{
return false ;
}
if ( fabsf ( LenLeft - 1.0f ) > fTolerance )
{
return false ;
}
if ( fabsf ( DotFwdUp ) > fTolerance )
{
return false ;
}
if ( fabsf ( DotUpLeft ) > fTolerance )
{
return false ;
}
if ( fabsf ( DotLeftFwd ) > fTolerance )
{
return false ;
}
return true ;
}
// --------------------------------------------------------------------
// Purpose: Computes the FOV from the projection matrix
// --------------------------------------------------------------------
void CalcFovFromProjection ( float * pFov , const VMatrix & proj )
{
// The projection matrices should be of the form:
// p0 0 z1 p1
// 0 p2 z2 p3
// 0 0 z3 1
// (p0 = X fov, p1 = X offset, p2 = Y fov, p3 = Y offset )
// TODO: cope with more complex projection matrices?
float xscale = proj . m [ 0 ] [ 0 ] ;
Assert ( proj . m [ 0 ] [ 1 ] = = 0.0f ) ;
float xoffset = proj . m [ 0 ] [ 2 ] ;
Assert ( proj . m [ 0 ] [ 3 ] = = 0.0f ) ;
Assert ( proj . m [ 1 ] [ 0 ] = = 0.0f ) ;
float yscale = proj . m [ 1 ] [ 1 ] ;
float yoffset = proj . m [ 1 ] [ 2 ] ;
Assert ( proj . m [ 1 ] [ 3 ] = = 0.0f ) ;
// Row 2 determines Z-buffer values - don't care about those for now.
Assert ( proj . m [ 3 ] [ 0 ] = = 0.0f ) ;
Assert ( proj . m [ 3 ] [ 1 ] = = 0.0f ) ;
Assert ( proj . m [ 3 ] [ 2 ] = = - 1.0f ) ;
Assert ( proj . m [ 3 ] [ 3 ] = = 0.0f ) ;
// The math here:
// A view-space vector (x,y,z,1) is transformed by the projection matrix
/ / / xscale 0 xoffset 0 \
// | 0 yscale yoffset 0 |
// | ? ? ? ? |
// \ 0 0 -1 0 /
//
// Then the result is normalized (i.e. divide by w) and the result clipped to the [-1,+1] unit cube.
// (ignore Z for now, and the clipping is slightly different).
// So, we want to know what vectors produce a clip value of -1 and +1 in each direction, e.g. in the X direction:
// +-1 = ( xscale*x + xoffset*z ) / (-1*z)
// = xscale*(x/z) + xoffset (I flipped the signs of both sides)
// => (+-1 - xoffset)/xscale = x/z
// ...and x/z is tan(theta), and theta is the half-FOV.
float fov_px = 2.0f * RAD2DEG ( atanf ( fabsf ( ( 1.0f - xoffset ) / xscale ) ) ) ;
float fov_nx = 2.0f * RAD2DEG ( atanf ( fabsf ( ( - 1.0f - xoffset ) / xscale ) ) ) ;
float fov_py = 2.0f * RAD2DEG ( atanf ( fabsf ( ( 1.0f - yoffset ) / yscale ) ) ) ;
float fov_ny = 2.0f * RAD2DEG ( atanf ( fabsf ( ( - 1.0f - yoffset ) / yscale ) ) ) ;
* pFov = Max ( Max ( fov_px , fov_nx ) , Max ( fov_py , fov_ny ) ) ;
// FIXME: hey you know, I could do the Max() series before I call all those expensive atanf()s...
}
// --------------------------------------------------------------------
// construction/destruction
// --------------------------------------------------------------------
CClientVirtualReality : : CClientVirtualReality ( )
{
m_PlayerTorsoOrigin . Init ( ) ;
m_PlayerTorsoAngle . Init ( ) ;
m_WorldFromWeapon . Identity ( ) ;
m_WorldFromMidEye . Identity ( ) ;
m_bOverrideTorsoAngle = false ;
m_OverrideTorsoOffset . Init ( ) ;
// Also reset our model of the player's torso orientation
m_PlayerTorsoAngle . Init ( 0.0f , 0.0f , 0.0f ) ;
m_WorldZoomScale = 1.0f ;
m_hmmMovementActual = HMM_SHOOTFACE_MOVEFACE ;
m_iAlignTorsoAndViewToWeaponCountdown = 0 ;
m_rtLastMotionSample = 0 ;
m_bMotionUpdated = false ;
# if defined( USE_SDL )
m_nNonVRSDLDisplayIndex = 0 ;
# endif
}
CClientVirtualReality : : ~ CClientVirtualReality ( )
{
}
// --------------------------------------------------------------------
// Purpose:
// --------------------------------------------------------------------
bool CClientVirtualReality : : Connect ( CreateInterfaceFn factory )
{
if ( ! factory )
return false ;
if ( ! BaseClass : : Connect ( factory ) )
return false ;
return true ;
}
// --------------------------------------------------------------------
// Purpose:
// --------------------------------------------------------------------
void CClientVirtualReality : : Disconnect ( )
{
BaseClass : : Disconnect ( ) ;
}
// --------------------------------------------------------------------
// Purpose:
// --------------------------------------------------------------------
void * CClientVirtualReality : : QueryInterface ( const char * pInterfaceName )
{
CreateInterfaceFn factory = Sys_GetFactoryThis ( ) ; // This silly construction is necessary
return factory ( pInterfaceName , NULL ) ; // to prevent the LTCG compiler from crashing.
}
// --------------------------------------------------------------------
// Purpose:
// --------------------------------------------------------------------
InitReturnVal_t CClientVirtualReality : : Init ( )
{
InitReturnVal_t nRetVal = BaseClass : : Init ( ) ;
if ( nRetVal ! = INIT_OK )
return nRetVal ;
return INIT_OK ;
}
// --------------------------------------------------------------------
// Purpose:
// --------------------------------------------------------------------
void CClientVirtualReality : : Shutdown ( )
{
BaseClass : : Shutdown ( ) ;
}
// --------------------------------------------------------------------
// Purpose: Draws the main menu in Stereo
// --------------------------------------------------------------------
void CClientVirtualReality : : DrawMainMenu ( )
{
// have to draw the UI in stereo via the render texture or it won't fuse properly
// Draw it into the render target first
ITexture * pTexture = materials - > FindTexture ( " _rt_gui " , NULL , false ) ;
Assert ( pTexture ) ;
if ( ! pTexture )
return ;
CMatRenderContextPtr pRenderContext ( materials ) ;
int viewActualWidth = pTexture - > GetActualWidth ( ) ;
int viewActualHeight = pTexture - > GetActualHeight ( ) ;
int viewWidth , viewHeight ;
vgui : : surface ( ) - > GetScreenSize ( viewWidth , viewHeight ) ;
// clear depth in the backbuffer before we push the render target
pRenderContext - > ClearBuffers ( false , true , true ) ;
// constrain where VGUI can render to the view
pRenderContext - > PushRenderTargetAndViewport ( pTexture , NULL , 0 , 0 , viewActualWidth , viewActualHeight ) ;
pRenderContext - > OverrideAlphaWriteEnable ( true , true ) ;
// clear the render target
pRenderContext - > ClearColor4ub ( 0 , 0 , 0 , 0 ) ;
pRenderContext - > ClearBuffers ( true , false ) ;
tmZone ( TELEMETRY_LEVEL0 , TMZF_NONE , " VGui_DrawHud " , __FUNCTION__ ) ;
// Make sure the client .dll root panel is at the proper point before doing the "SolveTraverse" calls
vgui : : VPANEL root = enginevgui - > GetPanel ( PANEL_CLIENTDLL ) ;
if ( root ! = 0 )
{
vgui : : ipanel ( ) - > SetSize ( root , viewWidth , viewHeight ) ;
}
// Same for client .dll tools
root = enginevgui - > GetPanel ( PANEL_CLIENTDLL_TOOLS ) ;
if ( root ! = 0 )
{
vgui : : ipanel ( ) - > SetSize ( root , viewWidth , viewHeight ) ;
}
// paint the main menu and cursor
render - > VGui_Paint ( ( PaintMode_t ) ( PAINT_UIPANELS | PAINT_CURSOR ) ) ;
pRenderContext - > OverrideAlphaWriteEnable ( false , true ) ;
pRenderContext - > PopRenderTargetAndViewport ( ) ;
pRenderContext - > Flush ( ) ;
int leftX , leftY , leftW , leftH , rightX , rightY , rightW , rightH ;
g_pSourceVR - > GetViewportBounds ( ISourceVirtualReality : : VREye_Left , & leftX , & leftY , & leftW , & leftH ) ;
g_pSourceVR - > GetViewportBounds ( ISourceVirtualReality : : VREye_Right , & rightX , & rightY , & rightW , & rightH ) ;
// render the main view
CViewSetup viewEye [ STEREO_EYE_MAX ] ;
viewEye [ STEREO_EYE_MONO ] . zNear = 0.1 ;
viewEye [ STEREO_EYE_MONO ] . zFar = 10000.f ;
viewEye [ STEREO_EYE_MONO ] . angles . Init ( ) ;
viewEye [ STEREO_EYE_MONO ] . origin . Zero ( ) ;
viewEye [ STEREO_EYE_MONO ] . x = viewEye [ STEREO_EYE_MONO ] . m_nUnscaledX = leftX ;
viewEye [ STEREO_EYE_MONO ] . y = viewEye [ STEREO_EYE_MONO ] . m_nUnscaledY = leftY ;
viewEye [ STEREO_EYE_MONO ] . width = viewEye [ STEREO_EYE_MONO ] . m_nUnscaledWidth = leftW ;
viewEye [ STEREO_EYE_MONO ] . height = viewEye [ STEREO_EYE_MONO ] . m_nUnscaledHeight = leftH ;
viewEye [ STEREO_EYE_LEFT ] = viewEye [ STEREO_EYE_RIGHT ] = viewEye [ STEREO_EYE_MONO ] ;
viewEye [ STEREO_EYE_LEFT ] . m_eStereoEye = STEREO_EYE_LEFT ;
viewEye [ STEREO_EYE_RIGHT ] . x = rightX ;
viewEye [ STEREO_EYE_RIGHT ] . y = rightY ;
viewEye [ STEREO_EYE_RIGHT ] . m_eStereoEye = STEREO_EYE_RIGHT ;
// let sourcevr.dll tell us where to put the cameras
ProcessCurrentTrackingState ( 0 ) ;
Vector vViewModelOrigin ;
QAngle qViewModelAngles ;
OverrideView ( & viewEye [ STEREO_EYE_MONO ] , & vViewModelOrigin , & qViewModelAngles , HMM_NOOVERRIDE ) ;
g_ClientVirtualReality . OverrideStereoView ( & viewEye [ STEREO_EYE_MONO ] , & viewEye [ STEREO_EYE_LEFT ] , & viewEye [ STEREO_EYE_RIGHT ] ) ;
// render both eyes
for ( int nView = STEREO_EYE_LEFT ; nView < = STEREO_EYE_RIGHT ; nView + + )
{
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CMatRenderContextPtr pRenderContext ( materials ) ;
PIXEvent pixEvent ( pRenderContext , nView = = STEREO_EYE_LEFT ? " left eye " : " right eye " ) ;
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ITexture * pColor = g_pSourceVR - > GetRenderTarget ( ( ISourceVirtualReality : : VREye ) ( nView - 1 ) , ISourceVirtualReality : : RT_Color ) ;
ITexture * pDepth = g_pSourceVR - > GetRenderTarget ( ( ISourceVirtualReality : : VREye ) ( nView - 1 ) , ISourceVirtualReality : : RT_Depth ) ;
render - > Push3DView ( viewEye [ nView ] , VIEW_CLEAR_DEPTH | VIEW_CLEAR_COLOR , pColor , NULL , pDepth ) ;
RenderHUDQuad ( false , false ) ;
render - > PopView ( NULL ) ;
PostProcessFrame ( ( StereoEye_t ) nView ) ;
OverlayHUDQuadWithUndistort ( viewEye [ nView ] , true , true , false ) ;
}
}
// --------------------------------------------------------------------
// Purpose:
// Offset the incoming view appropriately.
// Set up the "middle eye" from that.
// --------------------------------------------------------------------
bool CClientVirtualReality : : OverrideView ( CViewSetup * pViewMiddle , Vector * pViewModelOrigin , QAngle * pViewModelAngles , HeadtrackMovementMode_t hmmMovementOverride )
{
if ( ! UseVR ( ) )
{
return false ;
}
if ( hmmMovementOverride = = HMM_NOOVERRIDE )
{
if ( CurrentlyZoomed ( ) )
{
m_hmmMovementActual = static_cast < HeadtrackMovementMode_t > ( vr_moveaim_mode_zoom . GetInt ( ) ) ;
}
else
{
m_hmmMovementActual = static_cast < HeadtrackMovementMode_t > ( vr_moveaim_mode . GetInt ( ) ) ;
}
}
else
{
m_hmmMovementActual = hmmMovementOverride ;
}
// Incoming data may or may not be useful - it is the origin and aim of the "player", i.e. where bullets come from.
// In some modes it is an independent thing, guided by the mouse & keyboard = useful.
// In other modes it's just where the HMD was pointed last frame, modified slightly by kbd+mouse.
// In those cases, we should use our internal reference (which keeps track thanks to OverridePlayerMotion)
QAngle originalMiddleAngles = pViewMiddle - > angles ;
Vector originalMiddleOrigin = pViewMiddle - > origin ;
// Figure out the in-game "torso" concept, which corresponds to the player's physical torso.
m_PlayerTorsoOrigin = pViewMiddle - > origin ;
// Ignore what was passed in - it's just the direction the weapon is pointing, which was determined by last frame's HMD orientation!
// Instead use our cached value.
QAngle torsoAngles = m_PlayerTorsoAngle ;
VMatrix worldFromTorso ;
worldFromTorso . SetupMatrixOrgAngles ( m_PlayerTorsoOrigin , torsoAngles ) ;
//// Scale translation e.g. to allow big in-game leans with only a small head movement.
//// Clamp HMD movement to a reasonable amount to avoid wallhacks, vis problems, etc.
float limit = vr_translation_limit . GetFloat ( ) ;
VMatrix matMideyeZeroFromMideyeCurrent = g_pSourceVR - > GetMideyePose ( ) ;
Vector viewTranslation = matMideyeZeroFromMideyeCurrent . GetTranslation ( ) ;
if ( viewTranslation . IsLengthGreaterThan ( limit ) )
{
viewTranslation . NormalizeInPlace ( ) ;
viewTranslation * = limit ;
matMideyeZeroFromMideyeCurrent . SetTranslation ( viewTranslation ) ;
}
// Now figure out the three principal matrices: m_TorsoFromMideye, m_WorldFromMidEye, m_WorldFromWeapon
// m_TorsoFromMideye is done so that OverridePlayerMotion knows what to do with WASD.
switch ( m_hmmMovementActual )
{
case HMM_SHOOTFACE_MOVEFACE :
case HMM_SHOOTFACE_MOVETORSO :
// Aim point is down your nose, i.e. same as the view angles.
m_TorsoFromMideye = matMideyeZeroFromMideyeCurrent ;
m_WorldFromMidEye = worldFromTorso * matMideyeZeroFromMideyeCurrent ;
m_WorldFromWeapon = m_WorldFromMidEye ;
break ;
case HMM_SHOOTBOUNDEDMOUSE_LOOKFACE_MOVEFACE :
case HMM_SHOOTBOUNDEDMOUSE_LOOKFACE_MOVEMOUSE :
case HMM_SHOOTMOUSE_MOVEFACE :
case HMM_SHOOTMOVEMOUSE_LOOKFACE :
// Aim point is independent of view - leave it as it was, just copy it into m_WorldFromWeapon for our use.
m_TorsoFromMideye = matMideyeZeroFromMideyeCurrent ;
m_WorldFromMidEye = worldFromTorso * matMideyeZeroFromMideyeCurrent ;
m_WorldFromWeapon . SetupMatrixOrgAngles ( originalMiddleOrigin , originalMiddleAngles ) ;
break ;
case HMM_SHOOTMOVELOOKMOUSE :
// HMD is ignored completely, mouse does everything.
m_PlayerTorsoAngle = originalMiddleAngles ;
worldFromTorso . SetupMatrixOrgAngles ( m_PlayerTorsoOrigin , originalMiddleAngles ) ;
m_TorsoFromMideye . Identity ( ) ;
m_WorldFromMidEye = worldFromTorso ;
m_WorldFromWeapon = worldFromTorso ;
break ;
case HMM_SHOOTMOVELOOKMOUSEFACE :
// mouse does everything, and then we add head tracking on top of that
worldFromTorso = worldFromTorso * matMideyeZeroFromMideyeCurrent ;
m_TorsoFromMideye = matMideyeZeroFromMideyeCurrent ;
m_WorldFromWeapon = worldFromTorso ;
m_WorldFromMidEye = worldFromTorso ;
break ;
default : Assert ( false ) ; break ;
}
// Finally convert back to origin+angles that the game understands.
pViewMiddle - > origin = m_WorldFromMidEye . GetTranslation ( ) ;
VectorAngles ( m_WorldFromMidEye . GetForward ( ) , m_WorldFromMidEye . GetUp ( ) , pViewMiddle - > angles ) ;
* pViewModelAngles = pViewMiddle - > angles ;
if ( vr_viewmodel_translate_with_head . GetBool ( ) )
{
* pViewModelOrigin = pViewMiddle - > origin ;
}
else
{
* pViewModelOrigin = originalMiddleOrigin ;
}
m_WorldFromMidEyeNoDebugCam = m_WorldFromMidEye ;
if ( vr_debug_remote_cam . GetBool ( ) )
{
Vector vOffset ( vr_debug_remote_cam_pos_x . GetFloat ( ) , vr_debug_remote_cam_pos_y . GetFloat ( ) , vr_debug_remote_cam_pos_z . GetFloat ( ) ) ;
Vector vLookat ( vr_debug_remote_cam_target_x . GetFloat ( ) , vr_debug_remote_cam_target_y . GetFloat ( ) , vr_debug_remote_cam_target_z . GetFloat ( ) ) ;
pViewMiddle - > origin + = vOffset ;
Vector vView = vLookat - vOffset ;
VectorAngles ( vView , m_WorldFromMidEye . GetUp ( ) , pViewMiddle - > angles ) ;
m_WorldFromMidEye . SetupMatrixOrgAngles ( pViewMiddle - > origin , pViewMiddle - > angles ) ;
m_TorsoFromMideye . Identity ( ) ;
}
// set the near clip plane so the local player clips less
pViewMiddle - > zNear * = vr_projection_znear_multiplier . GetFloat ( ) ;
return true ;
}
// --------------------------------------------------------------------
// Purpose:
// In some aim/move modes, the HUD aim reticle lags because it's
// using slightly stale data. This will feed it the newest data.
// --------------------------------------------------------------------
bool CClientVirtualReality : : OverrideWeaponHudAimVectors ( Vector * pAimOrigin , Vector * pAimDirection )
{
if ( ! UseVR ( ) )
{
return false ;
}
Assert ( pAimOrigin ! = NULL ) ;
Assert ( pAimDirection ! = NULL ) ;
// So give it some nice high-fps numbers, not the low-fps ones we get from the game.
* pAimOrigin = m_WorldFromWeapon . GetTranslation ( ) ;
* pAimDirection = m_WorldFromWeapon . GetForward ( ) ;
return true ;
}
// --------------------------------------------------------------------
// Purpose:
// Set up the left and right eyes from the middle eye if stereo is on.
// Advise calling soonish after OverrideView().
// --------------------------------------------------------------------
bool CClientVirtualReality : : OverrideStereoView ( CViewSetup * pViewMiddle , CViewSetup * pViewLeft , CViewSetup * pViewRight )
{
// Everything in here is in Source coordinate space.
if ( ! UseVR ( ) )
{
return false ;
}
VMatrix matOffsetLeft = g_pSourceVR - > GetMidEyeFromEye ( ISourceVirtualReality : : VREye_Left ) ;
VMatrix matOffsetRight = g_pSourceVR - > GetMidEyeFromEye ( ISourceVirtualReality : : VREye_Right ) ;
// Move eyes to IPD positions.
VMatrix worldFromLeftEye = m_WorldFromMidEye * matOffsetLeft ;
VMatrix worldFromRightEye = m_WorldFromMidEye * matOffsetRight ;
Assert ( IsOrthonormal ( worldFromLeftEye , 0.001f ) ) ;
Assert ( IsOrthonormal ( worldFromRightEye , 0.001f ) ) ;
// Finally convert back to origin+angles.
MatrixAngles ( worldFromLeftEye . As3x4 ( ) , pViewLeft - > angles , pViewLeft - > origin ) ;
MatrixAngles ( worldFromRightEye . As3x4 ( ) , pViewRight - > angles , pViewRight - > origin ) ;
// Find the projection matrices.
// TODO: this isn't the fastest thing in the world. Cache them?
float headtrackFovScale = m_WorldZoomScale ;
pViewLeft - > m_bViewToProjectionOverride = true ;
pViewRight - > m_bViewToProjectionOverride = true ;
g_pSourceVR - > GetEyeProjectionMatrix ( & pViewLeft - > m_ViewToProjection , ISourceVirtualReality : : VREye_Left , pViewMiddle - > zNear , pViewMiddle - > zFar , 1.0f / headtrackFovScale ) ;
g_pSourceVR - > GetEyeProjectionMatrix ( & pViewRight - > m_ViewToProjection , ISourceVirtualReality : : VREye_Right , pViewMiddle - > zNear , pViewMiddle - > zFar , 1.0f / headtrackFovScale ) ;
// And bodge together some sort of average for our cyclops friends.
pViewMiddle - > m_bViewToProjectionOverride = true ;
for ( int i = 0 ; i < 4 ; i + + )
{
for ( int j = 0 ; j < 4 ; j + + )
{
pViewMiddle - > m_ViewToProjection . m [ i ] [ j ] = ( pViewLeft - > m_ViewToProjection . m [ i ] [ j ] + pViewRight - > m_ViewToProjection . m [ i ] [ j ] ) * 0.5f ;
}
}
switch ( vr_stereo_mono_set_eye . GetInt ( ) )
{
case 0 :
// ... nothing.
break ;
case 1 :
// Override all eyes with left
* pViewMiddle = * pViewLeft ;
* pViewRight = * pViewLeft ;
pViewRight - > m_eStereoEye = STEREO_EYE_RIGHT ;
break ;
case 2 :
// Override all eyes with right
* pViewMiddle = * pViewRight ;
* pViewLeft = * pViewRight ;
pViewLeft - > m_eStereoEye = STEREO_EYE_LEFT ;
break ;
case 3 :
// Override all eyes with middle
* pViewRight = * pViewMiddle ;
* pViewLeft = * pViewMiddle ;
pViewLeft - > m_eStereoEye = STEREO_EYE_LEFT ;
pViewRight - > m_eStereoEye = STEREO_EYE_RIGHT ;
break ;
}
// To make culling work correctly, calculate the widest FOV of each projection matrix.
CalcFovFromProjection ( & ( pViewLeft - > fov ) , pViewLeft - > m_ViewToProjection ) ;
CalcFovFromProjection ( & ( pViewRight - > fov ) , pViewRight - > m_ViewToProjection ) ;
CalcFovFromProjection ( & ( pViewMiddle - > fov ) , pViewMiddle - > m_ViewToProjection ) ;
// if we don't know the HUD FOV, figure that out now
if ( m_fHudHorizontalFov = = 0.f )
{
// Figure out the current HUD FOV.
m_fHudHorizontalFov = pViewLeft - > fov * vr_hud_display_ratio . GetFloat ( ) ;
if ( m_fHudHorizontalFov > vr_hud_max_fov . GetFloat ( ) )
{
m_fHudHorizontalFov = vr_hud_max_fov . GetFloat ( ) ;
}
}
// remember the view angles so we can limit the weapon to something near those
m_PlayerViewAngle = pViewMiddle - > angles ;
m_PlayerViewOrigin = pViewMiddle - > origin ;
// Figure out the HUD vectors and frustum.
// The aspect ratio of the HMD may be something bizarre (e.g. Rift is 640x800), and the pixels may not be square, so don't use that!
static const float fAspectRatio = 4.f / 3.f ;
float fHFOV = m_fHudHorizontalFov ;
float fVFOV = m_fHudHorizontalFov / fAspectRatio ;
const float fHudForward = vr_hud_forward . GetFloat ( ) ;
m_fHudHalfWidth = tan ( DEG2RAD ( fHFOV * 0.5f ) ) * fHudForward * m_WorldZoomScale ;
m_fHudHalfHeight = tan ( DEG2RAD ( fVFOV * 0.5f ) ) * fHudForward * m_WorldZoomScale ;
QAngle HudAngles ;
switch ( m_hmmMovementActual )
{
case HMM_SHOOTFACE_MOVETORSO :
// Put the HUD in front of the player's torso.
// This helps keep you oriented about where "forwards" is, which is otherwise surprisingly tricky!
// TODO: try preserving roll and/or pitch from the view?
HudAngles = m_PlayerTorsoAngle ;
break ;
case HMM_SHOOTFACE_MOVEFACE :
case HMM_SHOOTMOUSE_MOVEFACE :
case HMM_SHOOTMOVEMOUSE_LOOKFACE :
case HMM_SHOOTMOVELOOKMOUSE :
case HMM_SHOOTMOVELOOKMOUSEFACE :
case HMM_SHOOTBOUNDEDMOUSE_LOOKFACE_MOVEFACE :
case HMM_SHOOTBOUNDEDMOUSE_LOOKFACE_MOVEMOUSE :
// Put the HUD in front of wherever the player is looking.
HudAngles = m_PlayerViewAngle ;
break ;
default : Assert ( false ) ; break ;
}
// This is a bitfield. A set bit means lock to the world, a clear bit means don't.
int iVrHudAxisLockToWorld = vr_hud_axis_lock_to_world . GetInt ( ) ;
if ( ( iVrHudAxisLockToWorld & ( 1 < < ROLL ) ) ! = 0 )
{
HudAngles [ ROLL ] = 0.0f ;
}
if ( ( iVrHudAxisLockToWorld & ( 1 < < PITCH ) ) ! = 0 )
{
HudAngles [ PITCH ] = 0.0f ;
}
if ( ( iVrHudAxisLockToWorld & ( 1 < < YAW ) ) ! = 0 )
{
// Locking the yaw to the world is not particularly helpful, so what it actually means is lock it to the weapon.
QAngle aimAngles ;
MatrixAngles ( m_WorldFromWeapon . As3x4 ( ) , aimAngles ) ;
HudAngles [ YAW ] = aimAngles [ YAW ] ;
}
m_WorldFromHud . SetupMatrixOrgAngles ( m_PlayerViewOrigin , HudAngles ) ;
// Remember in source X forwards, Y left, Z up.
// We need to transform to a more conventional X right, Y up, Z backwards before doing the projection.
VMatrix WorldFromHudView ;
WorldFromHudView . /*X vector*/ SetForward ( - m_WorldFromHud . GetLeft ( ) ) ;
WorldFromHudView . /*Y vector*/ SetLeft ( m_WorldFromHud . GetUp ( ) ) ;
WorldFromHudView . /*Z vector*/ SetUp ( - m_WorldFromHud . GetForward ( ) ) ;
WorldFromHudView . SetTranslation ( m_PlayerViewOrigin ) ;
VMatrix HudProjection ;
HudProjection . Identity ( ) ;
HudProjection . m [ 0 ] [ 0 ] = fHudForward / m_fHudHalfWidth ;
HudProjection . m [ 1 ] [ 1 ] = fHudForward / m_fHudHalfHeight ;
// Z vector is not used/valid, but w is for projection.
HudProjection . m [ 3 ] [ 2 ] = - 1.0f ;
// This will transform a world point into a homogeneous vector that
// when projected (i.e. divide by w) maps to HUD space [-1,1]
m_HudProjectionFromWorld = HudProjection * WorldFromHudView . InverseTR ( ) ;
return true ;
}
// --------------------------------------------------------------------
// Purpose: Updates player orientation, position and motion according
// to HMD status.
// --------------------------------------------------------------------
bool CClientVirtualReality : : OverridePlayerMotion ( float flInputSampleFrametime , const QAngle & oldAngles , const QAngle & curAngles , const Vector & curMotion , QAngle * pNewAngles , Vector * pNewMotion )
{
Assert ( pNewAngles ! = NULL ) ;
Assert ( pNewMotion ! = NULL ) ;
* pNewAngles = curAngles ;
* pNewMotion = curMotion ;
if ( ! UseVR ( ) )
{
return false ;
}
m_bMotionUpdated = true ;
// originalAngles tells us what the weapon angles were before whatever mouse, joystick, etc thing changed them - called "old"
// curAngles holds the new weapon angles after mouse, joystick, etc. applied.
// We need to compute what weapon angles WE want and return them in *pNewAngles - called "new"
VMatrix worldFromTorso ;
// Whatever position is already here (set up by OverrideView) needs to be preserved.
Vector vWeaponOrigin = m_WorldFromWeapon . GetTranslation ( ) ;
switch ( m_hmmMovementActual )
{
case HMM_SHOOTFACE_MOVEFACE :
case HMM_SHOOTFACE_MOVETORSO :
{
// Figure out what changes were made to the WEAPON by mouse/joystick/etc
VMatrix worldFromOldWeapon , worldFromCurWeapon ;
worldFromOldWeapon . SetupMatrixAngles ( oldAngles ) ;
worldFromCurWeapon . SetupMatrixAngles ( curAngles ) ;
// We ignore mouse pitch, the mouse can't do rolls, so it's just yaw changes.
if ( ! m_bOverrideTorsoAngle )
{
m_PlayerTorsoAngle [ YAW ] + = curAngles [ YAW ] - oldAngles [ YAW ] ;
m_PlayerTorsoAngle [ ROLL ] = 0.0f ;
m_PlayerTorsoAngle [ PITCH ] = 0.0f ;
}
worldFromTorso . SetupMatrixAngles ( m_PlayerTorsoAngle ) ;
// Weapon view = mideye view, so apply that to the torso to find the world view direction.
m_WorldFromWeapon = worldFromTorso * m_TorsoFromMideye ;
// ...and we return this new weapon direction as the player's orientation.
MatrixAngles ( m_WorldFromWeapon . As3x4 ( ) , * pNewAngles ) ;
// Restore the translation.
m_WorldFromWeapon . SetTranslation ( vWeaponOrigin ) ;
}
break ;
case HMM_SHOOTMOVELOOKMOUSEFACE :
case HMM_SHOOTMOVEMOUSE_LOOKFACE :
case HMM_SHOOTMOVELOOKMOUSE :
{
// The mouse just controls the weapon directly.
* pNewAngles = curAngles ;
* pNewMotion = curMotion ;
// Move the torso by the yaw angles - torso should not have roll or pitch or you'll make folks ill.
if ( ! m_bOverrideTorsoAngle & & m_hmmMovementActual ! = HMM_SHOOTMOVELOOKMOUSEFACE )
{
m_PlayerTorsoAngle [ YAW ] = curAngles [ YAW ] ;
m_PlayerTorsoAngle [ ROLL ] = 0.0f ;
m_PlayerTorsoAngle [ PITCH ] = 0.0f ;
}
// Let every other system know.
m_WorldFromWeapon . SetupMatrixOrgAngles ( vWeaponOrigin , * pNewAngles ) ;
worldFromTorso . SetupMatrixAngles ( m_PlayerTorsoAngle ) ;
}
break ;
case HMM_SHOOTBOUNDEDMOUSE_LOOKFACE_MOVEFACE :
case HMM_SHOOTBOUNDEDMOUSE_LOOKFACE_MOVEMOUSE :
{
// The mouse controls the weapon directly.
* pNewAngles = curAngles ;
* pNewMotion = curMotion ;
float fReticleYawLimit = vr_moveaim_reticle_yaw_limit . GetFloat ( ) ;
float fReticlePitchLimit = vr_moveaim_reticle_pitch_limit . GetFloat ( ) ;
if ( CurrentlyZoomed ( ) )
{
fReticleYawLimit = vr_moveaim_reticle_yaw_limit_zoom . GetFloat ( ) * m_WorldZoomScale ;
fReticlePitchLimit = vr_moveaim_reticle_pitch_limit_zoom . GetFloat ( ) * m_WorldZoomScale ;
if ( fReticleYawLimit > 180.0f )
{
fReticleYawLimit = 180.0f ;
}
if ( fReticlePitchLimit > 180.0f )
{
fReticlePitchLimit = 180.0f ;
}
}
if ( fReticlePitchLimit > = 0.0f )
{
// Clamp pitch to within the limits.
( * pNewAngles ) [ PITCH ] = Clamp ( curAngles [ PITCH ] , m_PlayerViewAngle [ PITCH ] - fReticlePitchLimit , m_PlayerViewAngle [ PITCH ] + fReticlePitchLimit ) ;
}
// For yaw the concept here is the torso stays within a set number of degrees of the weapon in yaw.
// However, with drifty tracking systems (e.g. IMUs) the concept of "torso" is hazy.
// Really it's just a mechanism to turn the view without moving the head - its absolute
// orientation is not that useful.
// So... if the mouse is to the right greater than the chosen angle from the view, and then
// moves more right, it will drag the torso (and thus the view) right, so it stays on the edge of the view.
// But if it moves left towards the view, it does no dragging.
// Note that if the mouse does not move, but the view moves, it will NOT drag at all.
// This allows people to mouse-aim within their view, but also to flick-turn with the mouse,
// and to flick-glance with the head.
if ( fReticleYawLimit > = 0.0f )
{
float fViewToWeaponYaw = AngleDiff ( curAngles [ YAW ] , m_PlayerViewAngle [ YAW ] ) ;
float fWeaponYawMovement = AngleDiff ( curAngles [ YAW ] , oldAngles [ YAW ] ) ;
if ( fViewToWeaponYaw > fReticleYawLimit )
{
if ( fWeaponYawMovement > 0.0f )
{
m_PlayerTorsoAngle [ YAW ] + = fWeaponYawMovement ;
}
}
else if ( fViewToWeaponYaw < - fReticleYawLimit )
{
if ( fWeaponYawMovement < 0.0f )
{
m_PlayerTorsoAngle [ YAW ] + = fWeaponYawMovement ;
}
}
}
// Let every other system know.
m_WorldFromWeapon . SetupMatrixOrgAngles ( vWeaponOrigin , * pNewAngles ) ;
worldFromTorso . SetupMatrixAngles ( m_PlayerTorsoAngle ) ;
}
break ;
case HMM_SHOOTMOUSE_MOVEFACE :
{
( * pNewAngles ) [ PITCH ] = clamp ( ( * pNewAngles ) [ PITCH ] , m_PlayerViewAngle [ PITCH ] - 15.f , m_PlayerViewAngle [ PITCH ] + 15.f ) ;
float fDiff = AngleDiff ( ( * pNewAngles ) [ YAW ] , m_PlayerViewAngle [ YAW ] ) ;
if ( fDiff > 15.f )
{
( * pNewAngles ) [ YAW ] = AngleNormalize ( m_PlayerViewAngle [ YAW ] + 15.f ) ;
if ( ! m_bOverrideTorsoAngle )
m_PlayerTorsoAngle [ YAW ] + = fDiff - 15.f ;
}
else if ( fDiff < - 15.f )
{
( * pNewAngles ) [ YAW ] = AngleNormalize ( m_PlayerViewAngle [ YAW ] - 15.f ) ;
if ( ! m_bOverrideTorsoAngle )
m_PlayerTorsoAngle [ YAW ] + = fDiff + 15.f ;
}
else
{
m_PlayerTorsoAngle [ YAW ] + = AngleDiff ( curAngles [ YAW ] , oldAngles [ YAW ] ) / 2.f ;
}
m_WorldFromWeapon . SetupMatrixOrgAngles ( vWeaponOrigin , * pNewAngles ) ;
worldFromTorso . SetupMatrixAngles ( m_PlayerTorsoAngle ) ;
}
break ;
default : Assert ( false ) ; break ;
}
// Figure out player motion.
switch ( m_hmmMovementActual )
{
case HMM_SHOOTBOUNDEDMOUSE_LOOKFACE_MOVEFACE :
{
// The motion passed in is meant to be relative to the face, so jimmy it to be relative to the new weapon aim.
VMatrix mideyeFromWorld = m_WorldFromMidEye . InverseTR ( ) ;
VMatrix newMidEyeFromWeapon = mideyeFromWorld * m_WorldFromWeapon ;
newMidEyeFromWeapon . SetTranslation ( Vector ( 0.0f , 0.0f , 0.0f ) ) ;
* pNewMotion = newMidEyeFromWeapon * curMotion ;
}
break ;
case HMM_SHOOTFACE_MOVETORSO :
{
// The motion passed in is meant to be relative to the torso, so jimmy it to be relative to the new weapon aim.
VMatrix torsoFromWorld = worldFromTorso . InverseTR ( ) ;
VMatrix newTorsoFromWeapon = torsoFromWorld * m_WorldFromWeapon ;
newTorsoFromWeapon . SetTranslation ( Vector ( 0.0f , 0.0f , 0.0f ) ) ;
* pNewMotion = newTorsoFromWeapon * curMotion ;
}
break ;
case HMM_SHOOTBOUNDEDMOUSE_LOOKFACE_MOVEMOUSE :
case HMM_SHOOTMOVELOOKMOUSEFACE :
case HMM_SHOOTFACE_MOVEFACE :
case HMM_SHOOTMOUSE_MOVEFACE :
case HMM_SHOOTMOVEMOUSE_LOOKFACE :
case HMM_SHOOTMOVELOOKMOUSE :
// Motion is meant to be relative to the weapon, so we're fine.
* pNewMotion = curMotion ;
break ;
default : Assert ( false ) ; break ;
}
// If the game told us to, recenter the torso yaw to match the weapon
if ( m_iAlignTorsoAndViewToWeaponCountdown > 0 )
{
m_iAlignTorsoAndViewToWeaponCountdown - - ;
// figure out the angles from the torso to the head
QAngle torsoFromHeadAngles ;
MatrixAngles ( m_TorsoFromMideye . As3x4 ( ) , torsoFromHeadAngles ) ;
QAngle weaponAngles ;
MatrixAngles ( m_WorldFromWeapon . As3x4 ( ) , weaponAngles ) ;
m_PlayerTorsoAngle [ YAW ] = weaponAngles [ YAW ] - torsoFromHeadAngles [ YAW ] ;
NormalizeAngles ( m_PlayerTorsoAngle ) ;
}
// remember the motion for stat tracking
m_PlayerLastMovement = * pNewMotion ;
return true ;
}
// --------------------------------------------------------------------
// Purpose: Returns true if the world is zoomed
// --------------------------------------------------------------------
bool CClientVirtualReality : : CurrentlyZoomed ( )
{
return ( m_WorldZoomScale ! = 1.0f ) ;
}
// --------------------------------------------------------------------
// Purpose: Tells the headtracker to keep the torso angle of the player
// fixed at this point until the game tells us something
// different.
// --------------------------------------------------------------------
void CClientVirtualReality : : OverrideTorsoTransform ( const Vector & position , const QAngle & angles )
{
if ( m_iAlignTorsoAndViewToWeaponCountdown > 0 )
{
m_iAlignTorsoAndViewToWeaponCountdown - - ;
// figure out the angles from the torso to the head
QAngle torsoFromHeadAngles ;
MatrixAngles ( m_TorsoFromMideye . As3x4 ( ) , torsoFromHeadAngles ) ;
// this is how far off the torso we actually set will need to be to keep the current "forward"
// vector while the torso angle is being overridden.
m_OverrideTorsoOffset [ YAW ] = - torsoFromHeadAngles [ YAW ] ;
}
m_bOverrideTorsoAngle = true ;
m_OverrideTorsoAngle = angles + m_OverrideTorsoOffset ;
// overriding pitch and roll isn't allowed to avoid making people sick
m_OverrideTorsoAngle [ PITCH ] = 0 ;
m_OverrideTorsoAngle [ ROLL ] = 0 ;
NormalizeAngles ( m_OverrideTorsoAngle ) ;
m_PlayerTorsoAngle = m_OverrideTorsoAngle ;
}
// --------------------------------------------------------------------
// Purpose: Tells the headtracker to resume using its own notion of
// where the torso is pointed.
// --------------------------------------------------------------------
void CClientVirtualReality : : CancelTorsoTransformOverride ( )
{
m_bOverrideTorsoAngle = false ;
}
bool CClientVirtualReality : : CanOverlayHudQuad ( )
{
bool bCanOverlay = true ;
bCanOverlay = bCanOverlay & & vr_render_hud_in_world . GetBool ( ) ;
bCanOverlay = bCanOverlay & & ( ! vr_hud_never_overlay . GetBool ( ) ) ;
bCanOverlay = bCanOverlay & & ( vr_hud_axis_lock_to_world . GetInt ( ) = = 0 ) ;
bCanOverlay = bCanOverlay & & ( m_hmmMovementActual ! = HMM_SHOOTFACE_MOVETORSO ) ;
return bCanOverlay ;
}
// --------------------------------------------------------------------
// Purpose: Returns the bounds in world space where the game should
// position the HUD.
// --------------------------------------------------------------------
void CClientVirtualReality : : GetHUDBounds ( Vector * pViewer , Vector * pUL , Vector * pUR , Vector * pLL , Vector * pLR )
{
Vector vHalfWidth = m_WorldFromHud . GetLeft ( ) * - m_fHudHalfWidth ;
Vector vHalfHeight = m_WorldFromHud . GetUp ( ) * m_fHudHalfHeight ;
Vector vHUDOrigin = m_PlayerViewOrigin + m_WorldFromHud . GetForward ( ) * vr_hud_forward . GetFloat ( ) ;
* pViewer = m_PlayerViewOrigin ;
* pUL = vHUDOrigin - vHalfWidth + vHalfHeight ;
* pUR = vHUDOrigin + vHalfWidth + vHalfHeight ;
* pLL = vHUDOrigin - vHalfWidth - vHalfHeight ;
* pLR = vHUDOrigin + vHalfWidth - vHalfHeight ;
}
// --------------------------------------------------------------------
// Purpose: Renders the HUD in the world.
// --------------------------------------------------------------------
void CClientVirtualReality : : RenderHUDQuad ( bool bBlackout , bool bTranslucent )
{
// If we can overlay the HUD directly onto the target later, we'll do that instead (higher image quality).
if ( CanOverlayHudQuad ( ) )
return ;
Vector vHead , vUL , vUR , vLL , vLR ;
GetHUDBounds ( & vHead , & vUL , & vUR , & vLL , & vLR ) ;
CMatRenderContextPtr pRenderContext ( materials ) ;
{
IMaterial * mymat = NULL ;
if ( bTranslucent )
{
mymat = materials - > FindMaterial ( " vgui/inworldui " , TEXTURE_GROUP_VGUI ) ;
}
else
{
mymat = materials - > FindMaterial ( " vgui/inworldui_opaque " , TEXTURE_GROUP_VGUI ) ;
}
Assert ( ! mymat - > IsErrorMaterial ( ) ) ;
IMesh * pMesh = pRenderContext - > GetDynamicMesh ( true , NULL , NULL , mymat ) ;
CMeshBuilder meshBuilder ;
meshBuilder . Begin ( pMesh , MATERIAL_TRIANGLE_STRIP , 2 ) ;
meshBuilder . Position3fv ( vLR . Base ( ) ) ;
meshBuilder . TexCoord2f ( 0 , 1 , 1 ) ;
meshBuilder . AdvanceVertexF < VTX_HAVEPOS , 1 > ( ) ;
meshBuilder . Position3fv ( vLL . Base ( ) ) ;
meshBuilder . TexCoord2f ( 0 , 0 , 1 ) ;
meshBuilder . AdvanceVertexF < VTX_HAVEPOS , 1 > ( ) ;
meshBuilder . Position3fv ( vUR . Base ( ) ) ;
meshBuilder . TexCoord2f ( 0 , 1 , 0 ) ;
meshBuilder . AdvanceVertexF < VTX_HAVEPOS , 1 > ( ) ;
meshBuilder . Position3fv ( vUL . Base ( ) ) ;
meshBuilder . TexCoord2f ( 0 , 0 , 0 ) ;
meshBuilder . AdvanceVertexF < VTX_HAVEPOS , 1 > ( ) ;
meshBuilder . End ( ) ;
pMesh - > Draw ( ) ;
}
if ( bBlackout )
{
Vector vbUL , vbUR , vbLL , vbLR ;
// "Reflect" the HUD bounds through the viewer to find the ones behind the head.
vbUL = 2 * vHead - vLR ;
vbUR = 2 * vHead - vLL ;
vbLL = 2 * vHead - vUR ;
vbLR = 2 * vHead - vUL ;
IMaterial * mymat = materials - > FindMaterial ( " vgui/black " , TEXTURE_GROUP_VGUI ) ;
IMesh * pMesh = pRenderContext - > GetDynamicMesh ( true , NULL , NULL , mymat ) ;
// Tube around the outside.
CMeshBuilder meshBuilder ;
meshBuilder . Begin ( pMesh , MATERIAL_TRIANGLE_STRIP , 8 ) ;
meshBuilder . Position3fv ( vLR . Base ( ) ) ;
meshBuilder . AdvanceVertexF < VTX_HAVEPOS , 0 > ( ) ;
meshBuilder . Position3fv ( vbLR . Base ( ) ) ;
meshBuilder . AdvanceVertexF < VTX_HAVEPOS , 0 > ( ) ;
meshBuilder . Position3fv ( vLL . Base ( ) ) ;
meshBuilder . AdvanceVertexF < VTX_HAVEPOS , 0 > ( ) ;
meshBuilder . Position3fv ( vbLL . Base ( ) ) ;
meshBuilder . AdvanceVertexF < VTX_HAVEPOS , 0 > ( ) ;
meshBuilder . Position3fv ( vUL . Base ( ) ) ;
meshBuilder . AdvanceVertexF < VTX_HAVEPOS , 0 > ( ) ;
meshBuilder . Position3fv ( vbUL . Base ( ) ) ;
meshBuilder . AdvanceVertexF < VTX_HAVEPOS , 0 > ( ) ;
meshBuilder . Position3fv ( vUR . Base ( ) ) ;
meshBuilder . AdvanceVertexF < VTX_HAVEPOS , 0 > ( ) ;
meshBuilder . Position3fv ( vbUR . Base ( ) ) ;
meshBuilder . AdvanceVertexF < VTX_HAVEPOS , 0 > ( ) ;
meshBuilder . Position3fv ( vLR . Base ( ) ) ;
meshBuilder . AdvanceVertexF < VTX_HAVEPOS , 0 > ( ) ;
meshBuilder . Position3fv ( vbLR . Base ( ) ) ;
meshBuilder . AdvanceVertexF < VTX_HAVEPOS , 0 > ( ) ;
meshBuilder . End ( ) ;
pMesh - > Draw ( ) ;
// Cap behind the viewer.
meshBuilder . Begin ( pMesh , MATERIAL_TRIANGLE_STRIP , 2 ) ;
meshBuilder . Position3fv ( vbUR . Base ( ) ) ;
meshBuilder . AdvanceVertexF < VTX_HAVEPOS , 0 > ( ) ;
meshBuilder . Position3fv ( vbUL . Base ( ) ) ;
meshBuilder . AdvanceVertexF < VTX_HAVEPOS , 0 > ( ) ;
meshBuilder . Position3fv ( vbLR . Base ( ) ) ;
meshBuilder . AdvanceVertexF < VTX_HAVEPOS , 0 > ( ) ;
meshBuilder . Position3fv ( vbLL . Base ( ) ) ;
meshBuilder . AdvanceVertexF < VTX_HAVEPOS , 0 > ( ) ;
meshBuilder . End ( ) ;
pMesh - > Draw ( ) ;
}
}
// --------------------------------------------------------------------
// Purpose: Gets the amount of zoom to apply
// --------------------------------------------------------------------
float CClientVirtualReality : : GetZoomedModeMagnification ( )
{
return m_WorldZoomScale * vr_zoom_scope_scale . GetFloat ( ) ;
}
// --------------------------------------------------------------------
// Purpose: Does some client-side tracking work and then tells headtrack
// to do its own work.
// --------------------------------------------------------------------
bool CClientVirtualReality : : ProcessCurrentTrackingState ( float fGameFOV )
{
m_WorldZoomScale = 1.0f ;
if ( fGameFOV ! = 0.0f )
{
// To compensate for the lack of pixels on most HUDs, let's grow this a bit.
// Remember that MORE zoom equals LESS fov!
fGameFOV * = ( 1.0f / vr_zoom_multiplier . GetFloat ( ) ) ;
fGameFOV = Min ( fGameFOV , 170.0f ) ;
// The game has overridden the FOV, e.g. because of a sniper scope. So we need to match this view with whatever actual FOV the HUD has.
float wantedGameTanfov = tanf ( DEG2RAD ( fGameFOV * 0.5f ) ) ;
// OK, so now in stereo mode, we're going to also draw an overlay, but that overlay usually covers more of the screen (because in a good HMD usually our actual FOV is much wider)
float overlayActualPhysicalTanfov = tanf ( DEG2RAD ( m_fHudHorizontalFov * 0.5f ) ) ;
// Therefore... (remembering that a zoom > 1.0 means you zoom *out*)
m_WorldZoomScale = wantedGameTanfov / overlayActualPhysicalTanfov ;
}
return g_pSourceVR - > SampleTrackingState ( fGameFOV , 0.f /* seconds to predict */ ) ;
}
// --------------------------------------------------------------------
// Purpose: Returns the projection matrix to use for the HUD
// --------------------------------------------------------------------
const VMatrix & CClientVirtualReality : : GetHudProjectionFromWorld ( )
{
// This matrix will transform a world-space position into a homogenous HUD-space vector.
// So if you divide x+y by w, you will get the position on the HUD in [-1,1] space.
return m_HudProjectionFromWorld ;
}
// --------------------------------------------------------------------
// Purpose: Returns the aim vector relative to the torso
// --------------------------------------------------------------------
void CClientVirtualReality : : GetTorsoRelativeAim ( Vector * pPosition , QAngle * pAngles )
{
MatrixAngles ( m_TorsoFromMideye . As3x4 ( ) , * pAngles , * pPosition ) ;
pAngles - > y + = vr_aim_yaw_offset . GetFloat ( ) ;
}
// --------------------------------------------------------------------
// Purpose: Returns distance of the HUD in front of the eyes.
// --------------------------------------------------------------------
float CClientVirtualReality : : GetHUDDistance ( )
{
return vr_hud_forward . GetFloat ( ) ;
}
// --------------------------------------------------------------------
// Purpose: Returns true if the HUD should be rendered into a render
// target and then into the world on a quad.
// --------------------------------------------------------------------
bool CClientVirtualReality : : ShouldRenderHUDInWorld ( )
{
return UseVR ( ) & & vr_render_hud_in_world . GetBool ( ) ;
}
// --------------------------------------------------------------------
// Purpose: Lets headtrack tweak the view model origin and angles to match
// aim angles and handle strange viewmode FOV stuff
// --------------------------------------------------------------------
void CClientVirtualReality : : OverrideViewModelTransform ( Vector & vmorigin , QAngle & vmangles , bool bUseLargeOverride )
{
Vector vForward , vRight , vUp ;
AngleVectors ( vmangles , & vForward , & vRight , & vUp ) ;
float fForward = bUseLargeOverride ? vr_viewmodel_offset_forward_large . GetFloat ( ) : vr_viewmodel_offset_forward . GetFloat ( ) ;
vmorigin + = vForward * fForward ;
MatrixAngles ( m_WorldFromWeapon . As3x4 ( ) , vmangles ) ;
}
// --------------------------------------------------------------------
// Purpose: Tells the head tracker to reset the torso position in case
// we're on a drifty tracker.
// --------------------------------------------------------------------
void CClientVirtualReality : : AlignTorsoAndViewToWeapon ( )
{
if ( ! UseVR ( ) )
return ;
if ( g_pSourceVR - > WillDriftInYaw ( ) )
{
m_iAlignTorsoAndViewToWeaponCountdown = 2 ;
}
}
// --------------------------------------------------------------------
// Purpose: Lets VR do stuff at the very end of the rendering process
// --------------------------------------------------------------------
void CClientVirtualReality : : PostProcessFrame ( StereoEye_t eEye )
{
if ( ! UseVR ( ) )
return ;
g_pSourceVR - > DoDistortionProcessing ( eEye = = STEREO_EYE_LEFT ? ISourceVirtualReality : : VREye_Left : ISourceVirtualReality : : VREye_Right ) ;
}
// --------------------------------------------------------------------
// Pastes the HUD directly onto the backbuffer / render target.
// (higher quality than the RenderHUDQuad() path but can't always be used)
// --------------------------------------------------------------------
void CClientVirtualReality : : OverlayHUDQuadWithUndistort ( const CViewSetup & eyeView , bool bDoUndistort , bool bBlackout , bool bTranslucent )
{
if ( ! UseVR ( ) )
return ;
// If we can't overlay the HUD, it will be handled on another path (rendered into the scene with RenderHUDQuad()).
if ( ! CanOverlayHudQuad ( ) )
return ;
// Get the position of the HUD quad in world space as used by RenderHUDQuad(). Then convert to a rectangle in normalized
// device coordinates.
Vector vHead , vUL , vUR , vLL , vLR ;
GetHUDBounds ( & vHead , & vUL , & vUR , & vLL , & vLR ) ;
VMatrix worldToView , viewToProjection , worldToProjection , worldToPixels ;
render - > GetMatricesForView ( eyeView , & worldToView , & viewToProjection , & worldToProjection , & worldToPixels ) ;
Vector pUL , pUR , pLL , pLR ;
worldToProjection . V3Mul ( vUL , pUL ) ;
worldToProjection . V3Mul ( vUR , pUR ) ;
worldToProjection . V3Mul ( vLL , pLL ) ;
worldToProjection . V3Mul ( vLR , pLR ) ;
float ndcHudBounds [ 4 ] ;
ndcHudBounds [ 0 ] = Min ( Min ( pUL . x , pUR . x ) , Min ( pLL . x , pLR . x ) ) ;
ndcHudBounds [ 1 ] = Min ( Min ( pUL . y , pUR . y ) , Min ( pLL . y , pLR . y ) ) ;
ndcHudBounds [ 2 ] = Max ( Max ( pUL . x , pUR . x ) , Max ( pLL . x , pLR . x ) ) ;
ndcHudBounds [ 3 ] = Max ( Max ( pUL . y , pUR . y ) , Max ( pLL . y , pLR . y ) ) ;
ISourceVirtualReality : : VREye sourceVrEye = ( eyeView . m_eStereoEye = = STEREO_EYE_LEFT ) ? ISourceVirtualReality : : VREye_Left : ISourceVirtualReality : : VREye_Right ;
g_pSourceVR - > CompositeHud ( sourceVrEye , ndcHudBounds , bDoUndistort , bBlackout , bTranslucent ) ;
}
// --------------------------------------------------------------------
// Purpose: Switches to VR mode
// --------------------------------------------------------------------
void CClientVirtualReality : : Activate ( )
{
// we can only do this if a headtrack DLL is loaded
if ( ! g_pSourceVR )
return ;
// These checks don't apply if we're in VR mode because Steam said so.
if ( ! ShouldForceVRActive ( ) )
{
// see if VR mode is even enabled
if ( materials - > GetCurrentConfigForVideoCard ( ) . m_nVRModeAdapter = = - 1 )
{
Warning ( " Enable VR mode in the video options before trying to use it. \n " ) ;
return ;
}
// See if we have an actual adapter
int32 nVRModeAdapter = g_pSourceVR - > GetVRModeAdapter ( ) ;
if ( nVRModeAdapter = = - 1 )
{
Warning ( " Unable to get VRMode adapter from OpenVR. VR mode cannot be enabled. Try restarting and then enabling VR again. \n " ) ;
return ;
}
// we can only activate if we've got a VR device
if ( materials - > GetCurrentConfigForVideoCard ( ) . m_nVRModeAdapter ! = nVRModeAdapter )
{
Warning ( " VR Mode expects adapter %d which is different from %d which we are currently using. Try restarting and enabling VR mode again. \n " ,
nVRModeAdapter , materials - > GetCurrentConfigForVideoCard ( ) . m_nVRModeAdapter ) ;
engine - > ExecuteClientCmd ( " mat_enable_vrmode 0 \n " ) ;
return ;
}
}
// can't activate twice
if ( UseVR ( ) )
return ;
// remember where we were
m_bNonVRWindowed = g_pMaterialSystem - > GetCurrentConfigForVideoCard ( ) . Windowed ( ) ;
vgui : : surface ( ) - > GetScreenSize ( m_nNonVRWidth , m_nNonVRHeight ) ;
# if defined( USE_SDL )
static ConVarRef sdl_displayindex ( " sdl_displayindex " ) ;
m_nNonVRSDLDisplayIndex = sdl_displayindex . GetInt ( ) ;
# endif
if ( ! g_pSourceVR - > Activate ( ) )
{
// we couldn't activate, so just punt on this whole thing
return ;
}
// general all-game stuff
engine - > ExecuteClientCmd ( " mat_reset_rendertargets \n " ) ;
// game specific VR config
CUtlString sCmd ;
sCmd . Format ( " exec sourcevr_%s.cfg \n " , COM_GetModDirectory ( ) ) ;
engine - > ExecuteClientCmd ( sCmd . Get ( ) ) ;
vgui : : surface ( ) - > SetSoftwareCursor ( true ) ;
# if defined(POSIX)
ConVarRef m_rawinput ( " m_rawinput " ) ;
m_bNonVRRawInput = m_rawinput . GetBool ( ) ;
m_rawinput . SetValue ( 1 ) ;
ConVarRef mat_vsync ( " mat_vsync " ) ;
mat_vsync . SetValue ( 0 ) ;
# endif
g_pMatSystemSurface - > ForceScreenSizeOverride ( true , 640 , 480 ) ;
int nViewportWidth , nViewportHeight ;
g_pSourceVR - > GetViewportBounds ( ISourceVirtualReality : : VREye_Left , NULL , NULL , & nViewportWidth , & nViewportHeight ) ;
g_pMatSystemSurface - > SetFullscreenViewportAndRenderTarget ( 0 , 0 , nViewportWidth , nViewportHeight , g_pSourceVR - > GetRenderTarget ( ISourceVirtualReality : : VREye_Left , ISourceVirtualReality : : RT_Color ) ) ;
vgui : : ivgui ( ) - > SetVRMode ( true ) ;
// we can skip this extra mode change if we've always been in VR mode
if ( ! ShouldForceVRActive ( ) )
{
VRRect_t rect ;
if ( g_pSourceVR - > GetDisplayBounds ( & rect ) )
{
// set mode
char szCmd [ 256 ] ;
Q_snprintf ( szCmd , sizeof ( szCmd ) , " mat_setvideomode %i %i %i \n " , rect . nWidth , rect . nHeight , vr_force_windowed . GetBool ( ) ? 1 : 0 ) ;
engine - > ClientCmd_Unrestricted ( szCmd ) ;
}
}
}
void CClientVirtualReality : : Deactivate ( )
{
// can't deactivate when we aren't active
if ( ! UseVR ( ) )
return ;
g_pSourceVR - > Deactivate ( ) ;
g_pMatSystemSurface - > ForceScreenSizeOverride ( false , 0 , 0 ) ;
g_pMaterialSystem - > GetRenderContext ( ) - > Viewport ( 0 , 0 , m_nNonVRWidth , m_nNonVRHeight ) ;
g_pMatSystemSurface - > SetFullscreenViewportAndRenderTarget ( 0 , 0 , m_nNonVRWidth , m_nNonVRHeight , NULL ) ;
static ConVarRef cl_software_cursor ( " cl_software_cursor " ) ;
vgui : : surface ( ) - > SetSoftwareCursor ( cl_software_cursor . GetBool ( ) ) ;
# if defined( USE_SDL )
static ConVarRef sdl_displayindex ( " sdl_displayindex " ) ;
sdl_displayindex . SetValue ( m_nNonVRSDLDisplayIndex ) ;
# endif
# if defined(POSIX)
ConVarRef m_rawinput ( " m_rawinput " ) ;
m_rawinput . SetValue ( m_bNonVRRawInput ) ;
# endif
// Make sure the client .dll root panel is at the proper point before doing the "SolveTraverse" calls
vgui : : VPANEL root = enginevgui - > GetPanel ( PANEL_CLIENTDLL ) ;
if ( root ! = 0 )
{
vgui : : ipanel ( ) - > SetSize ( root , m_nNonVRWidth , m_nNonVRHeight ) ;
}
// Same for client .dll tools
root = enginevgui - > GetPanel ( PANEL_CLIENTDLL_TOOLS ) ;
if ( root ! = 0 )
{
vgui : : ipanel ( ) - > SetSize ( root , m_nNonVRWidth , m_nNonVRHeight ) ;
}
int viewWidth , viewHeight ;
vgui : : surface ( ) - > GetScreenSize ( viewWidth , viewHeight ) ;
engine - > ExecuteClientCmd ( " mat_reset_rendertargets \n " ) ;
// set mode
char szCmd [ 256 ] ;
Q_snprintf ( szCmd , sizeof ( szCmd ) , " mat_setvideomode %i %i %i \n " , m_nNonVRWidth , m_nNonVRHeight , m_bNonVRWindowed ? 1 : 0 ) ;
engine - > ClientCmd_Unrestricted ( szCmd ) ;
}
// Called when startup is complete
void CClientVirtualReality : : StartupComplete ( )
{
if ( vr_activate_default . GetBool ( ) | | ShouldForceVRActive ( ) )
Activate ( ) ;
}