//------------------------------------------------------------------------------
// Input values
//------------------------------------------------------------------------------
void CGlobalLight::InputSetAngles( inputdata_t &inputdata )
{
const char *pAngles = inputdata.value.String();
QAngle angles;
UTIL_StringToVector( angles.Base(), pAngles );
Vector vTemp;
AngleVectors( angles, &vTemp );
m_shadowDirection = vTemp;
}
bool Serialize( CUtlBuffer &buf, const QAngle &src )
{
if ( buf.IsText() )
{
SerializeFloats( buf, 3, src.Base() );
}
else
{
buf.PutFloat( src.x );
buf.PutFloat( src.y );
buf.PutFloat( src.z );
}
return buf.IsValid();
}
//------------------------------------------------------------------------------
// Purpose: Sets the angles to use for the secondary fog direction.
//------------------------------------------------------------------------------
void CFogController::InputSetAngles( inputdata_t &inputdata )
{
const char *pAngles = inputdata.value.String();
QAngle angles;
UTIL_StringToVector( angles.Base(), pAngles );
Vector vTemp;
AngleVectors( angles, &vTemp );
SetAbsAngles( angles );
AngleVectors( GetAbsAngles(), &m_fog.dirPrimary.GetForModify() );
m_fog.dirPrimary.GetForModify() *= -1.0f;
}
bool CGlobalLight::KeyValue( const char *szKeyName, const char *szValue )
{
if ( FStrEq( szKeyName, "color" ) )
{
float tmp[4];
UTIL_StringToFloatArray( tmp, 4, szValue );
m_LightColor.SetR( tmp[0] );
m_LightColor.SetG( tmp[1] );
m_LightColor.SetB( tmp[2] );
m_LightColor.SetA( tmp[3] );
}
else if ( FStrEq( szKeyName, "angles" ) )
{
QAngle angles;
UTIL_StringToVector( angles.Base(), szValue );
if (angles == vec3_angle)
{
angles.Init( 80, 30, 0 );
}
Vector vForward;
AngleVectors( angles, &vForward );
m_shadowDirection = vForward;
return true;
}
else if ( FStrEq( szKeyName, "texturename" ) )
{
#if defined( _X360 )
if ( Q_strcmp( szValue, "effects/flashlight001" ) == 0 )
{
// Use this as the default for Xbox
Q_strcpy( m_TextureName.GetForModify(), "effects/flashlight_border" );
}
else
{
Q_strcpy( m_TextureName.GetForModify(), szValue );
}
#else
Q_strcpy( m_TextureName.GetForModify(), szValue );
#endif
}
return BaseClass::KeyValue( szKeyName, szValue );
}
void CDeferredLight::ClientThink()
{
if ( m_pLight == NULL )
return;
Vector curOrig = GetRenderOrigin();
QAngle curAng = GetRenderAngles();
if ( VectorCompare( curOrig.Base(), m_pLight->pos.Base() ) == 0 ||
VectorCompare( curAng.Base(), m_pLight->ang.Base() ) == 0 )
{
ApplyDataToLight();
if ( m_pLight->flSpotCone_Outer != GetSpotCone_Outer() )
m_pLight->MakeDirtyAll();
else
m_pLight->MakeDirtyXForms();
}
}
//-----------------------------------------------------------------------------
// Read in worldcraft data...
//-----------------------------------------------------------------------------
bool CVGuiScreen::KeyValue( const char *szKeyName, const char *szValue )
{
//!! temp hack, until worldcraft is fixed
// strip the # tokens from (duplicate) key names
char *s = (char *)strchr( szKeyName, '#' );
if ( s )
{
*s = '\0';
}
if ( FStrEq( szKeyName, "panelname" ))
{
SetPanelName( szValue );
return true;
}
// NOTE: Have to do these separate because they set two values instead of one
if( FStrEq( szKeyName, "angles" ) )
{
Assert( GetMoveParent() == NULL );
QAngle angles;
UTIL_StringToVector( angles.Base(), szValue );
// Because the vgui screen basis is strange (z is front, y is up, x is right)
// we need to rotate the typical basis before applying it
VMatrix mat, rotation, tmp;
MatrixFromAngles( angles, mat );
MatrixBuildRotationAboutAxis( rotation, Vector( 0, 1, 0 ), 90 );
MatrixMultiply( mat, rotation, tmp );
MatrixBuildRotateZ( rotation, 90 );
MatrixMultiply( tmp, rotation, mat );
MatrixToAngles( mat, angles );
SetAbsAngles( angles );
return true;
}
return BaseClass::KeyValue( szKeyName, szValue );
}
//-----------------------------------------------------------------------------
// Purpose: Tesla effect
//-----------------------------------------------------------------------------
void C_EntityDissolve::BuildTeslaEffect( mstudiobbox_t *pHitBox, const matrix3x4_t &hitboxToWorld, bool bRandom, float flYawOffset )
{
Vector vecOrigin;
QAngle vecAngles;
MatrixGetColumn( hitboxToWorld, 3, vecOrigin );
MatrixAngles( hitboxToWorld, vecAngles.Base() );
C_BaseEntity *pEntity = GetMoveParent();
// Make a couple of tries at it
int iTries = -1;
Vector vecForward;
trace_t tr;
do
{
iTries++;
// Some beams are deliberatly aimed around the point, the rest are random.
if ( !bRandom )
{
QAngle vecTemp = vecAngles;
vecTemp[YAW] += flYawOffset;
AngleVectors( vecTemp, &vecForward );
// Randomly angle it up or down
vecForward.z = RandomFloat( -1, 1 );
}
else
{
vecForward = RandomVector( -1, 1 );
}
UTIL_TraceLine( vecOrigin, vecOrigin + (vecForward * 192), MASK_SHOT, pEntity, COLLISION_GROUP_NONE, &tr );
} while ( tr.fraction >= 1.0 && iTries < 3 );
Vector vecEnd = tr.endpos - (vecForward * 8);
// Only spark & glow if we hit something
if ( tr.fraction < 1.0 )
{
if ( !EffectOccluded( tr.endpos ) )
{
// Move it towards the camera
Vector vecFlash = tr.endpos;
Vector vecForward;
AngleVectors( MainViewAngles(), &vecForward );
vecFlash -= (vecForward * 8);
g_pEffects->EnergySplash( vecFlash, -vecForward, false );
// End glow
CSmartPtr<CSimpleEmitter> pSimple = CSimpleEmitter::Create( "dust" );
pSimple->SetSortOrigin( vecFlash );
SimpleParticle *pParticle;
pParticle = (SimpleParticle *) pSimple->AddParticle( sizeof( SimpleParticle ), pSimple->GetPMaterial( "effects/tesla_glow_noz" ), vecFlash );
if ( pParticle != NULL )
{
pParticle->m_flLifetime = 0.0f;
pParticle->m_flDieTime = RandomFloat( 0.5, 1 );
pParticle->m_vecVelocity = vec3_origin;
Vector color( 1,1,1 );
float colorRamp = RandomFloat( 0.75f, 1.25f );
pParticle->m_uchColor[0] = MIN( 1.0f, color[0] * colorRamp ) * 255.0f;
pParticle->m_uchColor[1] = MIN( 1.0f, color[1] * colorRamp ) * 255.0f;
pParticle->m_uchColor[2] = MIN( 1.0f, color[2] * colorRamp ) * 255.0f;
pParticle->m_uchStartSize = RandomFloat( 6,13 );
pParticle->m_uchEndSize = pParticle->m_uchStartSize - 2;
pParticle->m_uchStartAlpha = 255;
pParticle->m_uchEndAlpha = 10;
pParticle->m_flRoll = RandomFloat( 0,360 );
pParticle->m_flRollDelta = 0;
}
}
}
// Build the tesla
FX_BuildTesla( pEntity, vecOrigin, tr.endpos );
}
void CRagdollProp::InitRagdoll( const Vector &forceVector, int forceBone, const Vector &forcePos, matrix3x4_t *pPrevBones, matrix3x4_t *pBoneToWorld, float dt, int collisionGroup, bool activateRagdoll )
{
SetCollisionGroup( collisionGroup );
// Make sure it's interactive debris for at most 5 seconds
if ( collisionGroup == COLLISION_GROUP_INTERACTIVE_DEBRIS )
{
SetContextThink( &CRagdollProp::SetDebrisThink, gpGlobals->curtime + 5, s_pDebrisContext );
}
SetMoveType( MOVETYPE_VPHYSICS );
SetSolid( SOLID_VPHYSICS );
AddSolidFlags( FSOLID_CUSTOMRAYTEST | FSOLID_CUSTOMBOXTEST );
m_takedamage = DAMAGE_EVENTS_ONLY;
ragdollparams_t params;
params.pGameData = static_cast<void *>( static_cast<CBaseEntity *>(this) );
params.modelIndex = GetModelIndex();
params.pCollide = modelinfo->GetVCollide( params.modelIndex );
params.pStudioHdr = GetModelPtr();
params.forceVector = forceVector;
params.forceBoneIndex = forceBone;
params.forcePosition = forcePos;
params.pPrevBones = pPrevBones;
params.pCurrentBones = pBoneToWorld;
params.boneDt = dt;
params.jointFrictionScale = 1.0;
RagdollCreate( m_ragdoll, params, physenv );
if ( m_anglesOverrideString != NULL_STRING && Q_strlen(m_anglesOverrideString.ToCStr()) > 0 )
{
char szToken[2048];
const char *pStr = nexttoken(szToken, STRING(m_anglesOverrideString), ',');
// anglesOverride is index,angles,index,angles (e.g. "1, 22.5 123.0 0.0, 2, 0 0 0, 3, 0 0 180.0")
while ( szToken[0] != 0 )
{
int objectIndex = atoi(szToken);
// sanity check to make sure this token is an integer
Assert( atof(szToken) == ((float)objectIndex) );
pStr = nexttoken(szToken, pStr, ',');
Assert( szToken[0] );
if ( objectIndex >= m_ragdoll.listCount )
{
Warning("Bad ragdoll pose in entity %s, model (%s) at %s, model changed?\n", GetDebugName(), GetModelName().ToCStr(), VecToString(GetAbsOrigin()) );
}
else if ( szToken[0] != 0 )
{
QAngle angles;
Assert( objectIndex >= 0 && objectIndex < RAGDOLL_MAX_ELEMENTS );
UTIL_StringToVector( angles.Base(), szToken );
int boneIndex = m_ragdoll.boneIndex[objectIndex];
AngleMatrix( angles, pBoneToWorld[boneIndex] );
const ragdollelement_t &element = m_ragdoll.list[objectIndex];
Vector out;
if ( element.parentIndex >= 0 )
{
int parentBoneIndex = m_ragdoll.boneIndex[element.parentIndex];
VectorTransform( element.originParentSpace, pBoneToWorld[parentBoneIndex], out );
}
else
{
out = GetAbsOrigin();
}
MatrixSetColumn( out, 3, pBoneToWorld[boneIndex] );
element.pObject->SetPositionMatrix( pBoneToWorld[boneIndex], true );
}
pStr = nexttoken(szToken, pStr, ',');
}
}
if ( activateRagdoll )
{
MEM_ALLOC_CREDIT();
RagdollActivate( m_ragdoll, params.pCollide, GetModelIndex() );
}
for ( int i = 0; i < m_ragdoll.listCount; i++ )
{
UpdateNetworkDataFromVPhysics( m_ragdoll.list[i].pObject, i );
g_pPhysSaveRestoreManager->AssociateModel( m_ragdoll.list[i].pObject, GetModelIndex() );
physcollision->CollideGetAABB( m_ragdollMins[i], m_ragdollMaxs[i], m_ragdoll.list[i].pObject->GetCollide(), vec3_origin, vec3_angle );
}
VPhysicsSetObject( m_ragdoll.list[0].pObject );
CalcRagdollSize();
}
