halflife-thewastes-sdk/cl_dll/view.cpp

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//========= Copyright © 1996-2001, Valve LLC, All rights reserved. ============
//
// Purpose:
//
// $NoKeywords: $
//=============================================================================
// view/refresh setup functions
#include "hud.h"
#include "cl_util.h"
#include "cvardef.h"
#include "usercmd.h"
#include "const.h"
#include "entity_state.h"
#include "cl_entity.h"
#include "ref_params.h"
#include "in_defs.h" // PITCH YAW ROLL
#include "pm_movevars.h"
#include "pm_shared.h"
#include "pmtrace.h"
#include "screenfade.h"
#include "shake.h"
ref_params_t *g_pparams; // pointer from V_CalcRefDef
// Spectator Mode
extern "C"
{
float vecNewViewAngles[3];
int iHasNewViewAngles;
float vecNewViewOrigin[3];
int iHasNewViewOrigin;
int iIsSpectator;
}
#ifndef M_PI
#define M_PI 3.14159265358979323846 // matches value in gcc v2 math.h
#endif
extern "C"
{
int CL_IsThirdPerson( void );
void CL_CameraOffset( float *ofs );
void DLLEXPORT V_CalcRefdef( struct ref_params_s *pparams );
void PM_ParticleLine( float *start, float *end, int pcolor, float life, float vert);
int PM_GetInfo( int ent );
void InterpolateAngles( float *start, float *end, float *output, float frac );
float AngleBetweenVectors( float * v1, float * v2 );
}
void V_DropPunchAngle ( float frametime, float *ev_punchangle );
void V_Sway(struct ref_params_s *pparams);
void V_StopSway();
void V_DisableFade();
void VectorAngles( const float *forward, float *angles );
/*
The view is allowed to move slightly from it's true position for bobbing,
but if it exceeds 8 pixels linear distance (spherical, not box), the list of
entities sent from the server may not include everything in the pvs, especially
when crossing a water boudnary.
*/
extern cvar_t *cl_forwardspeed;
extern cvar_t *chase_active;
extern cvar_t *scr_ofsx, *scr_ofsy, *scr_ofsz;
extern cvar_t *cl_vsmoothing;
vec3_t v_origin, v_angles;
vec3_t ev_punchangle;
extern float g_lastFOV; // If this is set we dont render a view mdl
// Thermal
int ev_thermal = 0;
// Swaying
float ev_swayscale = 0;
float ev_scaleclamp;
int ev_swayenabled = 0;
cvar_t *scr_ofsx;
cvar_t *scr_ofsy;
cvar_t *scr_ofsz;
cvar_t *v_centermove;
cvar_t *v_centerspeed;
cvar_t *cl_bobcycle;
cvar_t *cl_bob;
cvar_t *cl_bobup;
cvar_t *cl_waterdist;
// These cvars are not registered (so users can't cheat), so set the ->value field directly
// Register these cvars in V_Init() if needed for easy tweaking
cvar_t v_iyaw_cycle = {"v_iyaw_cycle", "2", 0, 2};
cvar_t v_iroll_cycle = {"v_iroll_cycle", "0.5", 0, 0.5};
cvar_t v_ipitch_cycle = {"v_ipitch_cycle", "1", 0, 1};
cvar_t v_iyaw_level = {"v_iyaw_level", "0.3", 0, 0.3};
cvar_t v_iroll_level = {"v_iroll_level", "0.1", 0, 0.1};
cvar_t v_ipitch_level = {"v_ipitch_level", "0.3", 0, 0.3};
float v_idlescale; // used by TFC for concussion grenade effect
/*
//=============================================================================
void V_NormalizeAngles( float *angles )
{
int i;
// Normalize angles
for ( i = 0; i < 3; i++ )
{
if ( angles[i] > 180.0 )
{
angles[i] -= 360.0;
}
else if ( angles[i] < -180.0 )
{
angles[i] += 360.0;
}
}
}
/*
===================
V_InterpolateAngles
Interpolate Euler angles.
FIXME: Use Quaternions to avoid discontinuities
Frac is 0.0 to 1.0 ( i.e., should probably be clamped, but doesn't have to be )
===================
void V_InterpolateAngles( float *start, float *end, float *output, float frac )
{
int i;
float ang1, ang2;
float d;
V_NormalizeAngles( start );
V_NormalizeAngles( end );
for ( i = 0 ; i < 3 ; i++ )
{
ang1 = start[i];
ang2 = end[i];
d = ang2 - ang1;
if ( d > 180 )
{
d -= 360;
}
else if ( d < -180 )
{
d += 360;
}
output[i] = ang1 + d * frac;
}
V_NormalizeAngles( output );
} */
// Quakeworld bob code, this fixes jitters in the mutliplayer since the clock (pparams->time) isn't quite linear
float V_CalcBob ( struct ref_params_s *pparams )
{
static double bobtime;
static float bob;
float cycle;
static float lasttime;
vec3_t vel;
if ( pparams->spectator || iIsSpectator )
return 0;
if ( pparams->onground == -1 ||
pparams->time == lasttime )
{
// just use old value
return bob;
}
lasttime = pparams->time;
bobtime += pparams->frametime;
cycle = bobtime - (int)( bobtime / cl_bobcycle->value ) * cl_bobcycle->value;
cycle /= cl_bobcycle->value;
if ( cycle < cl_bobup->value )
{
cycle = M_PI * cycle / cl_bobup->value;
}
else
{
cycle = M_PI + M_PI * ( cycle - cl_bobup->value )/( 1.0 - cl_bobup->value );
}
// bob is proportional to simulated velocity in the xy plane
// (don't count Z, or jumping messes it up)
VectorCopy( pparams->simvel, vel );
vel[2] = 0;
bob = sqrt( vel[0] * vel[0] + vel[1] * vel[1] ) * cl_bob->value;
bob = bob * 0.3 + bob * 0.7 * sin(cycle);
bob = Q_min( bob, 4 );
bob = Q_max( bob, -7 );
return bob;
}
/*
===============
V_CalcRoll
Used by view and sv_user
===============
*/
float V_CalcRoll (vec3_t angles, vec3_t velocity, float rollangle, float rollspeed )
{
float sign;
float side;
float value;
vec3_t forward, right, up;
AngleVectors ( angles, forward, right, up );
side = DotProduct (velocity, right);
sign = side < 0 ? -1 : 1;
side = fabs( side );
value = rollangle;
if (side < rollspeed)
{
side = side * value / rollspeed;
}
else
{
side = value;
}
return side * sign;
}
typedef struct pitchdrift_s
{
float pitchvel;
int nodrift;
float driftmove;
double laststop;
} pitchdrift_t;
static pitchdrift_t pd;
void V_StartPitchDrift( void )
{
if ( pd.laststop == gEngfuncs.GetClientTime() )
{
return; // something else is keeping it from drifting
}
if ( pd.nodrift || !pd.pitchvel )
{
pd.pitchvel = v_centerspeed->value;
pd.nodrift = 0;
pd.driftmove = 0;
}
}
void V_StopPitchDrift ( void )
{
pd.laststop = gEngfuncs.GetClientTime();
pd.nodrift = 1;
pd.pitchvel = 0;
}
/*
===============
V_DriftPitch
Moves the client pitch angle towards idealpitch sent by the server.
If the user is adjusting pitch manually, either with lookup/lookdown,
mlook and mouse, or klook and keyboard, pitch drifting is constantly stopped.
===============
*/
void V_DriftPitch ( struct ref_params_s *pparams )
{
float delta, move;
if ( gEngfuncs.IsNoClipping() || !pparams->onground || pparams->demoplayback || pparams->spectator )
{
pd.driftmove = 0;
pd.pitchvel = 0;
return;
}
// don't count small mouse motion
if (pd.nodrift)
{
if ( fabs( pparams->cmd->forwardmove ) < cl_forwardspeed->value )
pd.driftmove = 0;
else
pd.driftmove += pparams->frametime;
if ( pd.driftmove > v_centermove->value)
{
V_StartPitchDrift ();
}
return;
}
delta = pparams->idealpitch - pparams->cl_viewangles[PITCH];
if (!delta)
{
pd.pitchvel = 0;
return;
}
move = pparams->frametime * pd.pitchvel;
pd.pitchvel += pparams->frametime * v_centerspeed->value;
//Con_Printf ("move: %f (%f)\n", move, pparams->frametime);
if (delta > 0)
{
if (move > delta)
{
pd.pitchvel = 0;
move = delta;
}
pparams->cl_viewangles[PITCH] += move;
}
else if (delta < 0)
{
if (move > -delta)
{
pd.pitchvel = 0;
move = -delta;
}
pparams->cl_viewangles[PITCH] -= move;
}
}
/*
==============================================================================
VIEW RENDERING
==============================================================================
*/
/*
==================
V_CalcGunAngle
==================
*/
void V_CalcGunAngle ( struct ref_params_s *pparams )
{
cl_entity_t *viewent;
viewent = gEngfuncs.GetViewModel();
if ( !viewent )
return;
viewent->angles[YAW] = pparams->viewangles[YAW] + pparams->crosshairangle[YAW];
viewent->angles[PITCH] = -pparams->viewangles[PITCH] + pparams->crosshairangle[PITCH] * 0.25;
viewent->angles[ROLL] -= v_idlescale * sin(pparams->time*v_iroll_cycle.value) * v_iroll_level.value;
// don't apply all of the v_ipitch to prevent normally unseen parts of viewmodel from coming into view.
viewent->angles[PITCH] -= v_idlescale * sin(pparams->time*v_ipitch_cycle.value) * (v_ipitch_level.value * 0.5);
viewent->angles[YAW] -= v_idlescale * sin(pparams->time*v_iyaw_cycle.value) * v_iyaw_level.value;
VectorCopy( viewent->angles, viewent->curstate.angles );
VectorCopy( viewent->angles, viewent->latched.prevangles );
}
/*
==============
V_AddIdle
Idle swaying
==============
*/
void V_AddIdle ( struct ref_params_s *pparams )
{
pparams->viewangles[ROLL] += v_idlescale * sin(pparams->time*v_iroll_cycle.value) * v_iroll_level.value;
pparams->viewangles[PITCH] += v_idlescale * sin(pparams->time*v_ipitch_cycle.value) * v_ipitch_level.value;
pparams->viewangles[YAW] += v_idlescale * sin(pparams->time*v_iyaw_cycle.value) * v_iyaw_level.value;
}
/*
==============
V_CalcViewRoll
Roll is induced by movement and damage
==============
*/
void V_CalcViewRoll ( struct ref_params_s *pparams )
{
float side;
cl_entity_t *viewentity;
viewentity = gEngfuncs.GetEntityByIndex( pparams->viewentity );
if ( !viewentity )
return;
side = V_CalcRoll ( viewentity->angles, pparams->simvel, pparams->movevars->rollangle, pparams->movevars->rollspeed );
pparams->viewangles[ROLL] += side;
if ( pparams->health <= 0 && ( pparams->viewheight[2] != 0 ) )
{
// only roll the view if the player is dead and the viewheight[2] is nonzero
// this is so deadcam in multiplayer will work.
pparams->viewangles[ROLL] = 80; // dead view angle
return;
}
}
/*
==================
V_CalcIntermissionRefdef
==================
*/
void V_CalcIntermissionRefdef ( struct ref_params_s *pparams )
{
cl_entity_t *ent, *view;
float old;
// don't allow cheats in multiplayer
#if !defined( _DEBUG )
if ( pparams->maxclients > 1 )
{
gEngfuncs.Cvar_SetValue ("scr_ofsx", 0);
gEngfuncs.Cvar_SetValue ("scr_ofsy", 0);
gEngfuncs.Cvar_SetValue ("scr_ofsz", 0);
}
#endif
// ent is the player model ( visible when out of body )
ent = gEngfuncs.GetLocalPlayer();
// view is the weapon model (only visible from inside body )
view = gEngfuncs.GetViewModel();
VectorCopy ( pparams->simorg, pparams->vieworg );
VectorCopy ( pparams->cl_viewangles, pparams->viewangles );
view->model = NULL;
// allways idle in intermission
old = v_idlescale;
v_idlescale = 1;
V_AddIdle ( pparams );
v_idlescale = old;
v_origin = pparams->vieworg;
v_angles = pparams->viewangles;
}
#define ORIGIN_BACKUP 64
#define ORIGIN_MASK ( ORIGIN_BACKUP - 1 )
typedef struct
{
float Origins[ ORIGIN_BACKUP ][3];
float OriginTime[ ORIGIN_BACKUP ];
float Angles[ ORIGIN_BACKUP ][3];
float AngleTime[ ORIGIN_BACKUP ];
int CurrentOrigin;
int CurrentAngle;
} viewinterp_t;
/*
==================
V_CalcRefdef
==================
*/
void V_CalcNormalRefdef ( struct ref_params_s *pparams )
{
cl_entity_t *ent, *view;
int i;
vec3_t angles;
float bob, waterOffset;
static viewinterp_t ViewInterp;
static float oldz = 0;
static float lasttime;
static float lastang[3];
vec3_t angdelta;
vec3_t camAngles, camForward, camRight, camUp;
cl_entity_t *pwater;
// don't allow cheats in multiplayer
if ( pparams->maxclients > 1 )
{
scr_ofsx->value = 0.0;
scr_ofsy->value = 0.0;
scr_ofsz->value = 0.0;
}
V_DriftPitch ( pparams );
// ent is the player model ( visible when out of body )
ent = gEngfuncs.GetLocalPlayer();
// view is the weapon model (only visible from inside body )
view = gEngfuncs.GetViewModel();
// transform the view offset by the model's matrix to get the offset from
// model origin for the view
bob = V_CalcBob ( pparams );
// Observer angle capturing and smoothing
if ( iHasNewViewOrigin )
{
// Get the angles from the physics code
VectorCopy( vecNewViewOrigin, pparams->vieworg );
VectorCopy( vecNewViewOrigin, pparams->simorg );
}
// refresh position
VectorCopy ( pparams->simorg, pparams->vieworg );
pparams->vieworg[2] += ( bob );
VectorAdd( pparams->vieworg, pparams->viewheight, pparams->vieworg );
// Observer angle capturing and smoothing
if ( iHasNewViewAngles )
{
// Get the angles from the physics code
VectorCopy( vecNewViewAngles, pparams->cl_viewangles );
}
VectorSubtract( pparams->cl_viewangles, lastang, angdelta );
if ( Length( angdelta ) != 0.0 )
{
VectorCopy( pparams->cl_viewangles, ViewInterp.Angles[ ViewInterp.CurrentAngle & ORIGIN_MASK ] );
ViewInterp.AngleTime[ ViewInterp.CurrentAngle & ORIGIN_MASK ] = pparams->time;
ViewInterp.CurrentAngle++;
VectorCopy( pparams->cl_viewangles, lastang );
}
if ( cl_vsmoothing && cl_vsmoothing->value && ( iIsSpectator & SPEC_SMOOTH_ANGLES ) )
{
int foundidx;
int i;
float t;
if ( cl_vsmoothing->value < 0.0 )
{
gEngfuncs.Cvar_SetValue( "cl_vsmoothing", 0.0 );
}
t = pparams->time - cl_vsmoothing->value;
for ( i = 1; i < ORIGIN_MASK; i++ )
{
foundidx = ViewInterp.CurrentAngle - 1 - i;
if ( ViewInterp.AngleTime[ foundidx & ORIGIN_MASK ] <= t )
break;
}
if ( i < ORIGIN_MASK && ViewInterp.AngleTime[ foundidx & ORIGIN_MASK ] != 0.0 )
{
// Interpolate
double dt;
dt = ViewInterp.AngleTime[ (foundidx + 1) & ORIGIN_MASK ] - ViewInterp.AngleTime[ foundidx & ORIGIN_MASK ];
if ( dt > 0.0 )
{
double frac;
frac = ( t - ViewInterp.AngleTime[ foundidx & ORIGIN_MASK] ) / dt;
frac = Q_min( 1.0, frac );
// interpolate angles
InterpolateAngles( ViewInterp.Angles[ foundidx & ORIGIN_MASK ], ViewInterp.Angles[ (foundidx + 1) & ORIGIN_MASK ], pparams->cl_viewangles, frac );
VectorCopy( pparams->cl_viewangles, vecNewViewAngles );
}
}
}
VectorCopy ( pparams->cl_viewangles, pparams->viewangles );
gEngfuncs.V_CalcShake();
gEngfuncs.V_ApplyShake( pparams->vieworg, pparams->viewangles, 1.0 );
// never let view origin sit exactly on a node line, because a water plane can
// dissapear when viewed with the eye exactly on it.
// FIXME, we send origin at 1/128 now, change this?
// the server protocol only specifies to 1/16 pixel, so add 1/32 in each axis
pparams->vieworg[0] += 1.0/32;
pparams->vieworg[1] += 1.0/32;
pparams->vieworg[2] += 1.0/32;
// Check for problems around water, move the viewer artificially if necessary
// -- this prevents drawing errors in GL due to waves
waterOffset = 0;
if ( pparams->waterlevel >= 2 )
{
int i, contents, waterDist, waterEntity;
vec3_t point;
waterDist = cl_waterdist->value;
if ( pparams->hardware )
{
waterEntity = gEngfuncs.PM_WaterEntity( pparams->simorg );
if ( waterEntity >= 0 && waterEntity < pparams->max_entities )
{
pwater = gEngfuncs.GetEntityByIndex( waterEntity );
if ( pwater && ( pwater->model != NULL ) )
{
waterDist += ( pwater->curstate.scale * 16 ); // Add in wave height
}
}
}
else
{
waterEntity = 0; // Don't need this in software
}
VectorCopy( pparams->vieworg, point );
// Eyes are above water, make sure we're above the waves
if ( pparams->waterlevel == 2 )
{
point[2] -= waterDist;
for ( i = 0; i < waterDist; i++ )
{
contents = gEngfuncs.PM_PointContents( point, NULL );
if ( contents > CONTENTS_WATER )
break;
point[2] += 1;
}
waterOffset = (point[2] + waterDist) - pparams->vieworg[2];
}
else
{
// eyes are under water. Make sure we're far enough under
point[2] += waterDist;
for ( i = 0; i < waterDist; i++ )
{
contents = gEngfuncs.PM_PointContents( point, NULL );
if ( contents <= CONTENTS_WATER )
break;
point[2] -= 1;
}
waterOffset = (point[2] - waterDist) - pparams->vieworg[2];
}
}
pparams->vieworg[2] += waterOffset;
V_CalcViewRoll ( pparams );
V_AddIdle ( pparams );
// offsets
VectorCopy( pparams->cl_viewangles, angles );
AngleVectors ( angles, pparams->forward, pparams->right, pparams->up );
for ( i=0 ; i<3 ; i++ )
{
pparams->vieworg[i] += scr_ofsx->value*pparams->forward[i] + scr_ofsy->value*pparams->right[i] + scr_ofsz->value*pparams->up[i];
}
// Treating cam_ofs[2] as the distance
if( CL_IsThirdPerson() )
{
vec3_t ofs;
ofs[0] = ofs[1] = ofs[2] = 0.0;
CL_CameraOffset( (float *)&ofs );
VectorCopy( ofs, camAngles );
camAngles[ ROLL ] = 0;
AngleVectors( camAngles, camForward, camRight, camUp );
for ( i = 0; i < 3; i++ )
{
pparams->vieworg[ i ] += -ofs[2] * camForward[ i ];
}
}
// Give gun our viewangles
VectorCopy ( pparams->cl_viewangles, view->angles );
// set up gun position
V_CalcGunAngle ( pparams );
// Use predicted origin as view origin.
VectorCopy ( pparams->simorg, view->origin );
view->origin[2] += ( waterOffset );
VectorAdd( view->origin, pparams->viewheight, view->origin );
// Let the viewmodel shake at about 10% of the amplitude
gEngfuncs.V_ApplyShake( view->origin, view->angles, 0.9 );
for ( i = 0; i < 3; i++ )
{
view->origin[ i ] += bob * 0.4 * pparams->forward[ i ];
}
view->origin[2] += bob;
// throw in a little tilt.
view->angles[YAW] -= bob * 0.5;
view->angles[ROLL] -= bob * 1;
view->angles[PITCH] -= bob * 0.3;
// pushing the view origin down off of the same X/Z plane as the ent's origin will give the
// gun a very nice 'shifting' effect when the player looks up/down. If there is a problem
// with view model distortion, this may be a cause. (SJB).
view->origin[2] -= 1;
// fudge position around to keep amount of weapon visible
// roughly equal with different FOV
if (pparams->viewsize == 110)
{
view->origin[2] += 1;
}
else if (pparams->viewsize == 100)
{
view->origin[2] += 2;
}
else if (pparams->viewsize == 90)
{
view->origin[2] += 1;
}
else if (pparams->viewsize == 80)
{
view->origin[2] += 0.5;
}
// Add in the punchangle, if any
VectorAdd ( pparams->viewangles, pparams->punchangle, pparams->viewangles );
// Include client side punch, too
VectorAdd ( pparams->viewangles, (float *)&ev_punchangle, pparams->viewangles);
V_DropPunchAngle ( pparams->frametime, (float *)&ev_punchangle );
// Client side sway, if any
// Clear sway if player is dead
if(ev_swayenabled && pparams->health)
V_Sway(pparams);
else
V_StopSway(); // reset swayangle
// smooth out stair step ups
#if 1
if ( !pparams->smoothing && pparams->onground && pparams->simorg[2] - oldz > 0)
{
float steptime;
steptime = pparams->time - lasttime;
if (steptime < 0)
//FIXME I_Error ("steptime < 0");
steptime = 0;
oldz += steptime * 150;
if (oldz > pparams->simorg[2])
oldz = pparams->simorg[2];
if (pparams->simorg[2] - oldz > 18)
oldz = pparams->simorg[2]- 18;
pparams->vieworg[2] += oldz - pparams->simorg[2];
view->origin[2] += oldz - pparams->simorg[2];
}
else
{
oldz = pparams->simorg[2];
}
#endif
{
static float lastorg[3];
vec3_t delta;
VectorSubtract( pparams->simorg, lastorg, delta );
if ( Length( delta ) != 0.0 )
{
VectorCopy( pparams->simorg, ViewInterp.Origins[ ViewInterp.CurrentOrigin & ORIGIN_MASK ] );
ViewInterp.OriginTime[ ViewInterp.CurrentOrigin & ORIGIN_MASK ] = pparams->time;
ViewInterp.CurrentOrigin++;
VectorCopy( pparams->simorg, lastorg );
}
}
// Smooth out whole view in multiplayer when on trains, lifts
if ( cl_vsmoothing && cl_vsmoothing->value &&
( ( iIsSpectator & SPEC_SMOOTH_ORIGIN ) || (pparams->smoothing && ( pparams->maxclients > 1 ) ) ) )
{
int foundidx;
int i;
float t;
if ( cl_vsmoothing->value < 0.0 )
{
gEngfuncs.Cvar_SetValue( "cl_vsmoothing", 0.0 );
}
t = pparams->time - cl_vsmoothing->value;
for ( i = 1; i < ORIGIN_MASK; i++ )
{
foundidx = ViewInterp.CurrentOrigin - 1 - i;
if ( ViewInterp.OriginTime[ foundidx & ORIGIN_MASK ] <= t )
break;
}
if ( i < ORIGIN_MASK && ViewInterp.OriginTime[ foundidx & ORIGIN_MASK ] != 0.0 )
{
// Interpolate
vec3_t delta;
double frac;
double dt;
vec3_t neworg;
dt = ViewInterp.OriginTime[ (foundidx + 1) & ORIGIN_MASK ] - ViewInterp.OriginTime[ foundidx & ORIGIN_MASK ];
if ( dt > 0.0 )
{
frac = ( t - ViewInterp.OriginTime[ foundidx & ORIGIN_MASK] ) / dt;
frac = Q_min( 1.0, frac );
VectorSubtract( ViewInterp.Origins[ ( foundidx + 1 ) & ORIGIN_MASK ], ViewInterp.Origins[ foundidx & ORIGIN_MASK ], delta );
VectorMA( ViewInterp.Origins[ foundidx & ORIGIN_MASK ], frac, delta, neworg );
// Dont interpolate large changes
if ( Length( delta ) < 64 )
{
VectorSubtract( neworg, pparams->simorg, delta );
VectorAdd( pparams->simorg, delta, pparams->simorg );
VectorAdd( pparams->vieworg, delta, pparams->vieworg );
VectorAdd( view->origin, delta, view->origin );
VectorCopy( pparams->simorg, vecNewViewOrigin );
}
}
}
}
// Store off v_angles before munging for third person
v_angles = pparams->viewangles;
if ( CL_IsThirdPerson() )
{
VectorCopy( camAngles, pparams->viewangles);
float pitch = camAngles[ 0 ];
// Normalize angles
if ( pitch > 180 )
pitch -= 360.0;
else if ( pitch < -180 )
pitch += 360;
// Player pitch is inverted
pitch /= -3.0;
// Slam local player's pitch value
ent->angles[ 0 ] = pitch;
ent->curstate.angles[ 0 ] = pitch;
ent->prevstate.angles[ 0 ] = pitch;
ent->latched.prevangles[ 0 ] = pitch;
}
// override all previous settings if the viewent isn't the client
if ( pparams->viewentity > pparams->maxclients )
{
cl_entity_t *viewentity;
viewentity = gEngfuncs.GetEntityByIndex( pparams->viewentity );
if ( viewentity )
{
VectorCopy( viewentity->origin, pparams->vieworg );
VectorCopy( viewentity->angles, pparams->viewangles );
// Store off overridden viewangles
v_angles = pparams->viewangles;
}
}
lasttime = pparams->time;
v_origin = pparams->vieworg;
// There is a bug with removing
// the view model, being it plays
// The current animation over again.
// So instead we just move the viewmodel
// so far away that the player will never see it.
// TODO: Do this without letting the player see his vmdl.
if(g_lastFOV)
{
view->model = NULL;
// view->origin[2] = v_origin[2] - 64;
// view->origin[1] = v_origin[1] - 64;
// view->origin[0] = v_origin[0];
}
}
void V_GetInEyePos(int entity, float * origin, float * angles )
{
cl_entity_t * ent = gEngfuncs.GetEntityByIndex( entity );
if ( !ent )
return;
if ( !ent->player || g_PlayerInfoList[entity].name == NULL )
return;
VectorCopy ( ent->origin, origin );
VectorCopy ( ent->angles, angles );
angles[0]*=-M_PI;
if ( ent->curstate.solid == SOLID_NOT )
{
angles[ROLL] = 80; // dead view angle
origin[2]+= -8 ; // PM_DEAD_VIEWHEIGHT
}
else if (ent->curstate.usehull == 1 )
origin[2]+= 12; // VEC_DUCK_VIEW;
else
// exacty eye position can't be caluculated since it depends on
// client values like cl_bobcycle, this offset matches the default values
origin[2]+= 28; // DEFAULT_VIEWHEIGHT
}
/*
==================
V_CalcSpectatorRefdef
==================
*/
void V_CalcSpectatorRefdef ( struct ref_params_s *pparams )
{
cl_entity_t *ent, *view;
vec3_t angles;
static viewinterp_t ViewInterp;
static float lasttime;
static float lastang[3];
static float lastorg[3];
vec3_t delta;
// ent is the player model ( visible when out of body )
ent = gEngfuncs.GetLocalPlayer();
// view is the weapon model (only visible from inside body )
view = gEngfuncs.GetViewModel();
// refresh position
VectorCopy ( pparams->simorg, pparams->vieworg );
// done all the spectator smoothing only once in the first frame
// Observer angle capturing and smoothing
if ( iHasNewViewOrigin )
{
// Get the angles from the physics code
VectorCopy( vecNewViewOrigin, pparams->vieworg );
}
else
{
// otherwise copy normal vieworigin into vecNewViewOrigin
VectorCopy( pparams->vieworg, vecNewViewOrigin );
}
VectorCopy ( pparams->cl_viewangles, pparams->viewangles );
// Observer angle capturing and smoothing
if ( iHasNewViewAngles )
{
// Get the angles from the physics code
VectorCopy( vecNewViewAngles, pparams->viewangles );
}
else
{
// otherwise copy normal viewangle into vewNewViewAngles
VectorCopy( pparams->viewangles, vecNewViewAngles);
}
// do the smoothing only once per frame
if (pparams->nextView == 0)
{
// smooth angles
VectorSubtract( pparams->viewangles, lastang, delta );
if ( Length( delta ) != 0.0f )
{
VectorCopy( pparams->viewangles, ViewInterp.Angles[ ViewInterp.CurrentAngle & ORIGIN_MASK ] );
ViewInterp.AngleTime[ ViewInterp.CurrentAngle & ORIGIN_MASK ] = pparams->time;
ViewInterp.CurrentAngle++;
VectorCopy( pparams->viewangles, lastang );
}
if ( cl_vsmoothing && cl_vsmoothing->value && ( iIsSpectator & SPEC_SMOOTH_ANGLES ) )
{
int foundidx;
int i;
float t;
t = pparams->time - cl_vsmoothing->value;
for ( i = 1; i < ORIGIN_MASK; i++ )
{
foundidx = ViewInterp.CurrentAngle - 1 - i;
if ( ViewInterp.AngleTime[ foundidx & ORIGIN_MASK ] <= t )
break;
}
if ( i < ORIGIN_MASK && ViewInterp.AngleTime[ foundidx & ORIGIN_MASK ] != 0.0 )
{
// Interpolate
double dt;
float da;
vec3_t v1,v2;
AngleVectors( ViewInterp.Angles[ foundidx & ORIGIN_MASK ], v1, NULL, NULL );
AngleVectors( ViewInterp.Angles[ (foundidx + 1) & ORIGIN_MASK ], v2, NULL, NULL );
da = AngleBetweenVectors( v1, v2 );
dt = ViewInterp.AngleTime[ (foundidx + 1) & ORIGIN_MASK ] - ViewInterp.AngleTime[ foundidx & ORIGIN_MASK ];
if ( dt > 0.0 && ( da < 22.5f) )
{
double frac;
frac = ( t - ViewInterp.AngleTime[ foundidx & ORIGIN_MASK] ) / dt;
frac = Q_min( 1.0, frac );
// interpolate angles
InterpolateAngles( ViewInterp.Angles[ foundidx & ORIGIN_MASK ], ViewInterp.Angles[ (foundidx + 1) & ORIGIN_MASK ], vecNewViewAngles, frac );
VectorCopy( vecNewViewAngles, pparams->viewangles );
}
}
}
// smooth origin
VectorSubtract( pparams->vieworg, lastorg, delta );
if ( Length( delta ) != 0.0 )
{
VectorCopy( pparams->vieworg, ViewInterp.Origins[ ViewInterp.CurrentOrigin & ORIGIN_MASK ] );
ViewInterp.OriginTime[ ViewInterp.CurrentOrigin & ORIGIN_MASK ] = pparams->time;
ViewInterp.CurrentOrigin++;
VectorCopy( pparams->vieworg, lastorg );
}
if ( cl_vsmoothing && cl_vsmoothing->value && ( iIsSpectator & SPEC_SMOOTH_ORIGIN ) )
{
int foundidx;
int i;
float t;
t = pparams->time - cl_vsmoothing->value;
for ( i = 1; i < ORIGIN_MASK; i++ )
{
foundidx = ViewInterp.CurrentOrigin - 1 - i;
if ( ViewInterp.OriginTime[ foundidx & ORIGIN_MASK ] <= t )
break;
}
if ( i < ORIGIN_MASK && ViewInterp.OriginTime[ foundidx & ORIGIN_MASK ] != 0.0 )
{
// Interpolate
vec3_t delta;
double frac;
double dt;
vec3_t neworg;
dt = ViewInterp.OriginTime[ (foundidx + 1) & ORIGIN_MASK ] - ViewInterp.OriginTime[ foundidx & ORIGIN_MASK ];
if ( dt > 0.0 )
{
frac = ( t - ViewInterp.OriginTime[ foundidx & ORIGIN_MASK] ) / dt;
frac = Q_min( 1.0, frac );
VectorSubtract( ViewInterp.Origins[ ( foundidx + 1 ) & ORIGIN_MASK ], ViewInterp.Origins[ foundidx & ORIGIN_MASK ], delta );
VectorMA( ViewInterp.Origins[ foundidx & ORIGIN_MASK ], frac, delta, neworg );
// Dont interpolate large changes
if ( Length( delta ) < 64 )
{
VectorSubtract( neworg, pparams->simorg, delta );
VectorAdd( pparams->vieworg, delta, pparams->vieworg );
VectorCopy( pparams->vieworg, vecNewViewOrigin );
}
}
}
}
}
lasttime = pparams->time;
view->model = NULL;
if ( pparams->nextView == 0 )
{
// first renderer cycle
switch (gHUD.m_Spectator.m_iMainMode)
{
case MAIN_MAP_FREE : pparams->onlyClientDraw = true;
angles = pparams->cl_viewangles;
angles[0] = 51.25f + 38.75f*(angles[0]/90.0f);
VectorCopy ( angles, gHUD.m_Spectator.m_mapAngles );
gHUD.m_Spectator.GetMapPosition( pparams->vieworg );
VectorCopy ( angles, pparams->viewangles );
break;
case MAIN_IN_EYE : V_GetInEyePos( gHUD.m_Spectator.m_iObserverTarget,
pparams->vieworg, pparams->viewangles );
break;
default : pparams->onlyClientDraw = false;
break;
}
if ( gHUD.m_Spectator.m_iInsetMode != INSET_OFF )
pparams->nextView = 1; // force a second renderer view
gHUD.m_Spectator.m_iDrawCycle = 0;
}
else
{
// second renderer cycle
// set inset parameters
pparams->viewport[0] = XRES(gHUD.m_Spectator.m_OverviewData.insetWindowX); // change viewport to inset window
pparams->viewport[1] = YRES(gHUD.m_Spectator.m_OverviewData.insetWindowY);
pparams->viewport[2] = XRES(gHUD.m_Spectator.m_OverviewData.insetWindowWidth);
pparams->viewport[3] = YRES(gHUD.m_Spectator.m_OverviewData.insetWindowHeight);
pparams->nextView = 0; // on further view
pparams->onlyClientDraw = false;
// override some settings in certain modes
switch (gHUD.m_Spectator.m_iInsetMode)
{
case INSET_MAP_FREE : pparams->onlyClientDraw = true;
angles = pparams->cl_viewangles;
angles[0] = 51.25f + 38.75f*(angles[0]/90.0f);
VectorCopy ( angles, gHUD.m_Spectator.m_mapAngles );
gHUD.m_Spectator.GetMapPosition( pparams->vieworg );
VectorCopy ( angles, pparams->viewangles );
break;
case INSET_IN_EYE : V_GetInEyePos( gHUD.m_Spectator.m_iObserverTarget,
pparams->vieworg, pparams->viewangles );
break;
}
gHUD.m_Spectator.m_iDrawCycle = 1;
}
v_angles = pparams->viewangles;
v_origin = pparams->vieworg;
}
void DLLEXPORT V_CalcRefdef( struct ref_params_s *pparams )
{
g_pparams = pparams; // set global pointer
// intermission / finale rendering
if ( pparams->intermission )
{
V_CalcIntermissionRefdef ( pparams );
}
else if ( pparams->spectator )
{
V_CalcSpectatorRefdef ( pparams );
}
else if ( !pparams->paused )
{
V_CalcNormalRefdef ( pparams );
}
// H&K G11 Thermal Scope
if(ev_thermal)
{
screenfade_t sf;
gEngfuncs.pfnGetScreenFade(&sf);
sf.fader = 255;
sf.fadeg = 0;
sf.fadeb = 0;
sf.fadealpha = 225;
sf.fadeFlags = FFADE_MODULATE|FFADE_STAYOUT|FFADE_OUT;
gEngfuncs.pfnSetScreenFade(&sf);
}
}
/*
=============
V_DropPunchAngle
=============
*/
void V_DropPunchAngle ( float frametime, float *ev_punchangle )
{
float len;
len = VectorNormalize ( ev_punchangle );
len -= (10.0 + len * 0.5) * frametime;
len = Q_max( len, 0.0 );
VectorScale ( ev_punchangle, len, ev_punchangle );
}
/*
=============
V_PunchAxis
Client side punch effect
=============
*/
void V_PunchAxis( int axis, float punch )
{
ev_punchangle[ axis ] = punch;
}
void V_DisableFade()
{
screenfade_t sf;
gEngfuncs.pfnGetScreenFade(&sf);
sf.fader = 0;
sf.fadeg = 0;
sf.fadeb = 0;
sf.fadealpha = 0;
sf.fadeFlags = FFADE_IN;
gEngfuncs.pfnSetScreenFade(&sf);
ev_thermal = 0;
}
/*
=============
V_SetSway
Client side crosshair sway
=============
*/
void V_SetSway(float scale)
{
// Settings
ev_swayscale = scale;
ev_scaleclamp = scale * 0.1; // 1/10th of the original scale
// Tell view logic to sway
ev_swayenabled = 1;
}
/*
=============
V_StopSway
Kill the sway
=============
*/
void V_StopSway()
{
// No more sway
ev_swayenabled = 0;
}
/*
=============
V_Sway
Portray sway on clients screen
=============
*/
void V_Sway(struct ref_params_s *pparams)
{
pparams->viewangles[ROLL] += ev_swayscale * sin(pparams->time*v_iroll_cycle.value) * v_iroll_level.value;
pparams->viewangles[PITCH] += ev_swayscale * sin(pparams->time*v_ipitch_cycle.value) * v_ipitch_level.value;
pparams->viewangles[YAW] += ev_swayscale * sin(pparams->time*v_iyaw_cycle.value) * v_iyaw_level.value;
// start to reduce sway
ev_swayscale -= 0.35*pparams->frametime;
if(ev_swayscale < ev_scaleclamp)
ev_swayscale = ev_scaleclamp;
}
/*
=============
V_Init
=============
*/
void V_Init (void)
{
gEngfuncs.pfnAddCommand ("centerview", V_StartPitchDrift );
scr_ofsx = gEngfuncs.pfnRegisterVariable( "scr_ofsx","0", 0 );
scr_ofsy = gEngfuncs.pfnRegisterVariable( "scr_ofsy","0", 0 );
scr_ofsz = gEngfuncs.pfnRegisterVariable( "scr_ofsz","0", 0 );
v_centermove = gEngfuncs.pfnRegisterVariable( "v_centermove", "0.15", 0 );
v_centerspeed = gEngfuncs.pfnRegisterVariable( "v_centerspeed","500", 0 );
cl_bobcycle = gEngfuncs.pfnRegisterVariable( "cl_bobcycle","0.8", 0 );// best default for my experimental gun wag (sjb)
cl_bob = gEngfuncs.pfnRegisterVariable( "cl_bob","0.01", 0 );// best default for my experimental gun wag (sjb)
cl_bobup = gEngfuncs.pfnRegisterVariable( "cl_bobup","0.5", 0 );
cl_waterdist = gEngfuncs.pfnRegisterVariable( "cl_waterdist","4", 0 );
}
//#define TRACE_TEST
#if defined( TRACE_TEST )
extern float in_fov;
/*
====================
CalcFov
====================
*/
float CalcFov (float fov_x, float width, float height)
{
float a;
float x;
if (fov_x < 1 || fov_x > 179)
fov_x = 90; // error, set to 90
x = width/tan(fov_x/360*M_PI);
a = atan (height/x);
a = a*360/M_PI;
return a;
}
int hitent = -1;
void V_Move( int mx, int my )
{
float fov;
float fx, fy;
float dx, dy;
float c_x, c_y;
float dX, dY;
vec3_t forward, up, right;
vec3_t newangles;
vec3_t farpoint;
pmtrace_t tr;
fov = CalcFov( in_fov, (float)ScreenWidth, (float)ScreenHeight );
c_x = (float)ScreenWidth / 2.0;
c_y = (float)ScreenHeight / 2.0;
dx = (float)mx - c_x;
dy = (float)my - c_y;
// Proportion we moved in each direction
fx = dx / c_x;
fy = dy / c_y;
dX = fx * in_fov / 2.0 ;
dY = fy * fov / 2.0;
newangles = v_angles;
newangles[ YAW ] -= dX;
newangles[ PITCH ] += dY;
// Now rotate v_forward around that point
AngleVectors ( newangles, forward, right, up );
farpoint = v_origin + 8192 * forward;
// Trace
tr = *(gEngfuncs.PM_TraceLine( (float *)&v_origin, (float *)&farpoint, PM_TRACELINE_PHYSENTSONLY, 2 /*point sized hull*/, -1 ));
if ( tr.fraction != 1.0 && tr.ent != 0 )
{
hitent = PM_GetInfo( tr.ent );
PM_ParticleLine( (float *)&v_origin, (float *)&tr.endpos, 5, 1.0, 0.0 );
}
else
{
hitent = -1;
}
}
#endif