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more CBike

This commit is contained in:
aap 2020-06-05 00:24:42 +02:00
parent 7f0474e9de
commit 647fd951ec
4 changed files with 159 additions and 63 deletions

View file

@ -462,6 +462,8 @@ DebugMenuPopulate(void)
DebugMenuAddCmd("Spawn", "Spawn Firetruck", [](){ SpawnCar(MI_FIRETRUCK); }); DebugMenuAddCmd("Spawn", "Spawn Firetruck", [](){ SpawnCar(MI_FIRETRUCK); });
DebugMenuAddCmd("Spawn", "Spawn Predator", [](){ SpawnCar(MI_PREDATOR); }); DebugMenuAddCmd("Spawn", "Spawn Predator", [](){ SpawnCar(MI_PREDATOR); });
DebugMenuAddCmd("Spawn", "Spawn PCJ 600", [](){ SpawnCar(MI_PCJ600); }); DebugMenuAddCmd("Spawn", "Spawn PCJ 600", [](){ SpawnCar(MI_PCJ600); });
DebugMenuAddCmd("Spawn", "Spawn Faggio", [](){ SpawnCar(MI_FAGGIO); });
DebugMenuAddCmd("Spawn", "Spawn Freeway", [](){ SpawnCar(MI_FREEWAY); });
DebugMenuAddVarBool8("Render", "Draw hud", &CHud::m_Wants_To_Draw_Hud, nil); DebugMenuAddVarBool8("Render", "Draw hud", &CHud::m_Wants_To_Draw_Hud, nil);
DebugMenuAddVarBool8("Render", "Backface Culling", &gBackfaceCulling, nil); DebugMenuAddVarBool8("Render", "Backface Culling", &gBackfaceCulling, nil);

View file

@ -1595,7 +1595,7 @@ CAutomobile::ProcessControl(void)
if(this == FindPlayerVehicle()) if(this == FindPlayerVehicle())
// BUG: this only observes one of the wheels // BUG: this only observes one of the wheels
TheCamera.m_bVehicleSuspenHigh = suspChange > 0.05f; TheCamera.m_bVehicleSuspenHigh = Abs(suspChange) > 0.05f;
m_aSuspensionSpringRatioPrev[i] = m_aSuspensionSpringRatio[i]; m_aSuspensionSpringRatioPrev[i] = m_aSuspensionSpringRatio[i];
m_aSuspensionSpringRatio[i] = 1.0f; m_aSuspensionSpringRatio[i] = 1.0f;

View file

@ -95,12 +95,12 @@ CBike::CBike(int32 id, uint8 CreatedBy)
bWaterTight = false; bWaterTight = false;
m_bike_flag08 = false; m_bike_flag08 = false;
bIsStanding = false; bIsStanding = false;
m_bike_flag20 = false; bExtraSpeed = false;
m_bike_flag40 = false; m_bike_flag40 = false;
m_bike_flag80 = false; m_bike_flag80 = false;
m_fTireTemperature = 0.0f; m_fTireTemperature = 0.0f;
someAngle = 0.0f; m_fBrakeDestabilization = 0.0f;
field_490 = 0; field_490 = 0;
for(i = 0; i < 2; i++){ for(i = 0; i < 2; i++){
@ -183,7 +183,7 @@ CBike::ProcessControl(void)
bWarnedPeds = false; bWarnedPeds = false;
bLeanMatrixClean = false; bLeanMatrixClean = false;
m_doingBurnout = 0; m_doingBurnout = 0;
m_bike_flag20 = false; bExtraSpeed = false;
bRestingOnPhysical = false; bRestingOnPhysical = false;
if(CReplay::IsPlayingBack()) if(CReplay::IsPlayingBack())
@ -204,18 +204,18 @@ CBike::ProcessControl(void)
case STATUS_PLAYER: case STATUS_PLAYER:
bCanStand = true; bCanStand = true;
m_bike_flag08 = false; m_bike_flag08 = false;
if(pDriver && pDriver->GetPedState() != PED_EXIT_CAR && pDriver->GetPedState() != PED_DRAG_FROM_CAR){ if(FindPlayerPed()->GetPedState() != PED_EXIT_CAR && FindPlayerPed()->GetPedState() != PED_DRAG_FROM_CAR){
ProcessControlInputs(0); ProcessControlInputs(0);
if(m_fLeanInput < 0.0f){ if(m_fLeanInput < 0.0f){
m_vecCentreOfMass.y = pHandling->CentreOfMass.y + pBikeHandling->fLeanBakCOM*m_fLeanInput; m_vecCentreOfMass.y = pHandling->CentreOfMass.y + pBikeHandling->fLeanBakCOM*m_fLeanInput;
if(m_fBrakePedal == 0.0f && !bIsHandbrakeOn || m_nWheelsOnGround == 0){ if(m_fBrakePedal == 0.0f && !bIsHandbrakeOn || m_nWheelsOnGround == 0){
if(GetModelIndex() == MI_SANCHEZ){ if(GetModelIndex() == MI_SANCHEZ){
float force = m_fLeanInput*m_fTurnMass*pBikeHandling->fLeanBackForce*Min(m_vecMoveSpeed.MagnitudeSqr(), 0.1f); float force = m_fLeanInput*m_fTurnMass*pBikeHandling->fLeanBackForce*Min(m_vecMoveSpeed.Magnitude(), 0.1f);
force *= 0.7f*m_fGasPedal + 0.3f; force *= 0.7f*m_fGasPedal + 0.3f;
ApplyTurnForce(-force*CTimer::GetTimeStep()*GetUp(), m_vecCentreOfMass+GetForward()); ApplyTurnForce(-force*CTimer::GetTimeStep()*GetUp(), m_vecCentreOfMass+GetForward());
}else{ }else{
float force = m_fLeanInput*m_fTurnMass*pBikeHandling->fLeanBackForce*Min(m_vecMoveSpeed.MagnitudeSqr(), 0.1f); float force = m_fLeanInput*m_fTurnMass*pBikeHandling->fLeanBackForce*Min(m_vecMoveSpeed.Magnitude(), 0.1f);
force *= 0.5f*m_fGasPedal + 0.5f; force *= 0.5f*m_fGasPedal + 0.5f;
ApplyTurnForce(-force*CTimer::GetTimeStep()*GetUp(), m_vecCentreOfMass+GetForward()); ApplyTurnForce(-force*CTimer::GetTimeStep()*GetUp(), m_vecCentreOfMass+GetForward());
} }
@ -223,7 +223,7 @@ CBike::ProcessControl(void)
}else{ }else{
m_vecCentreOfMass.y = pHandling->CentreOfMass.y + pBikeHandling->fLeanFwdCOM*m_fLeanInput; m_vecCentreOfMass.y = pHandling->CentreOfMass.y + pBikeHandling->fLeanFwdCOM*m_fLeanInput;
if(m_fBrakePedal < 0.0f || m_nWheelsOnGround == 0){ if(m_fBrakePedal < 0.0f || m_nWheelsOnGround == 0){
float force = m_fLeanInput*m_fTurnMass*pBikeHandling->fLeanFwdForce*Min(m_vecMoveSpeed.MagnitudeSqr(), 0.1f); float force = m_fLeanInput*m_fTurnMass*pBikeHandling->fLeanFwdForce*Min(m_vecMoveSpeed.Magnitude(), 0.1f);
ApplyTurnForce(-force*CTimer::GetTimeStep()*GetUp(), m_vecCentreOfMass+GetForward()); ApplyTurnForce(-force*CTimer::GetTimeStep()*GetUp(), m_vecCentreOfMass+GetForward());
} }
} }
@ -237,7 +237,7 @@ CBike::ProcessControl(void)
m_aSuspensionSpringRatio[1] < 1.0f && CSurfaceTable::GetAdhesionGroup(m_aWheelColPoints[1].surfaceB) == ADHESIVE_SAND || m_aSuspensionSpringRatio[1] < 1.0f && CSurfaceTable::GetAdhesionGroup(m_aWheelColPoints[1].surfaceB) == ADHESIVE_SAND ||
m_aSuspensionSpringRatio[2] < 1.0f && CSurfaceTable::GetAdhesionGroup(m_aWheelColPoints[2].surfaceB) == ADHESIVE_SAND || m_aSuspensionSpringRatio[2] < 1.0f && CSurfaceTable::GetAdhesionGroup(m_aWheelColPoints[2].surfaceB) == ADHESIVE_SAND ||
m_aSuspensionSpringRatio[3] < 1.0f && CSurfaceTable::GetAdhesionGroup(m_aWheelColPoints[3].surfaceB) == ADHESIVE_SAND){ m_aSuspensionSpringRatio[3] < 1.0f && CSurfaceTable::GetAdhesionGroup(m_aWheelColPoints[3].surfaceB) == ADHESIVE_SAND){
CVector parallelSpeed = m_vecMoveSpeed - DotProduct(m_vecMoveSpeed, GetUp())*m_vecMoveSpeed; CVector parallelSpeed = m_vecMoveSpeed - DotProduct(m_vecMoveSpeed, GetUp())*GetUp();
if(m_fGasPedal > 0.3f){ if(m_fGasPedal > 0.3f){
if(parallelSpeed.MagnitudeSqr() < SQR(0.3f)) if(parallelSpeed.MagnitudeSqr() < SQR(0.3f))
bStuckInSand = true; bStuckInSand = true;
@ -265,7 +265,7 @@ CBike::ProcessControl(void)
pHandling->Transmission.CalculateGearForSimpleCar(AutoPilot.m_fMaxTrafficSpeed/50.0f, m_nCurrentGear); pHandling->Transmission.CalculateGearForSimpleCar(AutoPilot.m_fMaxTrafficSpeed/50.0f, m_nCurrentGear);
wheelRot = ProcessWheelRotation(WHEEL_STATE_NORMAL, GetForward(), m_vecMoveSpeed, 0.35f); wheelRot = ProcessWheelRotation(WHEEL_STATE_NORMAL, GetForward(), m_vecMoveSpeed, 0.5f*wheelScale);
for(i = 0; i < 2; i++) for(i = 0; i < 2; i++)
m_aWheelRotation[i] += wheelRot; m_aWheelRotation[i] += wheelRot;
@ -384,8 +384,8 @@ CBike::ProcessControl(void)
res.y *= 1.0f/(fDAxisY*SQR(localTurnSpeed.y) + 1.0f); res.y *= 1.0f/(fDAxisY*SQR(localTurnSpeed.y) + 1.0f);
res.x = Pow(res.x, CTimer::GetTimeStep()); res.x = Pow(res.x, CTimer::GetTimeStep());
res.y = Pow(res.y, CTimer::GetTimeStep()); res.y = Pow(res.y, CTimer::GetTimeStep());
float turnX = localTurnSpeed.x*res.x - localTurnSpeed.x; float turnX = localTurnSpeed.x*(res.x - 1.0f);
float turnY = localTurnSpeed.y*res.y - localTurnSpeed.y; float turnY = localTurnSpeed.y*(res.y - 1.0f);
res = -GetUp() * turnY * m_fTurnMass; res = -GetUp() * turnY * m_fTurnMass;
// BUG? matrix multiplication // BUG? matrix multiplication
@ -485,7 +485,7 @@ CBike::ProcessControl(void)
m_fWheelAngle += DEGTORAD(1.0f)*CTimer::GetTimeStep(); m_fWheelAngle += DEGTORAD(1.0f)*CTimer::GetTimeStep();
if(bIsStanding){ if(bIsStanding){
float f = Pow(0.97f, CTimer::GetTimeStep()); float f = Pow(0.97f, CTimer::GetTimeStep());
m_fLeanLRAngle2 = m_fLeanLRAngle2*f + (Asin(clamp(GetRight().z,-1.0f,1.0f))+DEGTORAD(15.0f))*(1.0f-f); m_fLeanLRAngle2 = m_fLeanLRAngle2*f - (Asin(clamp(GetRight().z,-1.0f,1.0f))+DEGTORAD(15.0f))*(1.0f-f);
m_fLeanLRAngle = m_fLeanLRAngle2; m_fLeanLRAngle = m_fLeanLRAngle2;
} }
}else{ }else{
@ -522,15 +522,24 @@ CBike::ProcessControl(void)
} }
} }
// TODO: lean forward speed up // Lean forward speed up
float savedAirResistance = m_fAirResistance; float savedAirResistance = m_fAirResistance;
// ... if(GetStatus() == STATUS_PLAYER && pDriver){
CAnimBlendAssociation *assoc = RpAnimBlendClumpGetAssociation(pDriver->GetClump(), ANIM_BIKE_FWD);
if(assoc && assoc->blendAmount > 0.5f &&
assoc->currentTime > 0.06f && assoc->currentTime < 0.14f){
m_fAirResistance *= 0.6f;
if(m_fGasPedal > 0.5f && DotProduct(m_vecMoveSpeed, GetForward()) > 0.25f){
ApplyMoveForce(0.2f*m_fMass*GRAVITY*CTimer::GetTimeStep()*GetForward());
bExtraSpeed = true;
}
}
}
CPhysical::ProcessControl(); CPhysical::ProcessControl();
m_fAirResistance = savedAirResistance; m_fAirResistance = savedAirResistance;
ProcessBuoyancy(); ProcessBuoyancy();
// Rescale spring ratios, i.e. subtract wheel radius // Rescale spring ratios, i.e. subtract wheel radius
for(i = 0; i < 4; i++){ for(i = 0; i < 4; i++){
// wheel radius in relation to suspension line // wheel radius in relation to suspension line
@ -703,26 +712,24 @@ CBike::ProcessControl(void)
} }
// Find contact points for wheel processing // Find contact points for wheel processing
i = m_aSuspensionSpringRatio[BIKESUSP_F1] < m_aSuspensionSpringRatio[BIKESUSP_F2] ? int frontLine = m_aSuspensionSpringRatio[BIKESUSP_F1] < m_aSuspensionSpringRatio[BIKESUSP_F2] ?
BIKESUSP_F1 : BIKESUSP_F2; BIKESUSP_F1 : BIKESUSP_F2;
int frontLine = i;
CVector frontContact(0.0f, CVector frontContact(0.0f,
colModel->lines[BIKESUSP_F1].p0.y, colModel->lines[BIKESUSP_F1].p0.y,
colModel->lines[BIKESUSP_F1].p0.z - m_aSuspensionSpringRatio[i]*m_aSuspensionSpringLength[BIKESUSP_F1] - 0.5f*wheelScale); colModel->lines[BIKESUSP_F1].p0.z - m_aSuspensionSpringRatio[frontLine]*m_aSuspensionSpringLength[BIKESUSP_F1] - 0.5f*wheelScale);
frontContact = Multiply3x3(GetMatrix(), frontContact); frontContact = Multiply3x3(GetMatrix(), frontContact);
i = m_aSuspensionSpringRatio[BIKESUSP_R1] < m_aSuspensionSpringRatio[BIKESUSP_R2] ? int rearLine = m_aSuspensionSpringRatio[BIKESUSP_R1] < m_aSuspensionSpringRatio[BIKESUSP_R2] ?
BIKESUSP_R1 : BIKESUSP_R2; BIKESUSP_R1 : BIKESUSP_R2;
int rearLine = i;
CVector rearContact(0.0f, CVector rearContact(0.0f,
colModel->lines[BIKESUSP_R1].p0.y, colModel->lines[BIKESUSP_R1].p0.y,
colModel->lines[BIKESUSP_R1].p0.z - m_aSuspensionSpringRatio[i]*m_aSuspensionSpringLength[BIKESUSP_R1] - 0.5f*wheelScale); colModel->lines[BIKESUSP_R1].p0.z - m_aSuspensionSpringRatio[rearLine]*m_aSuspensionSpringLength[BIKESUSP_R1] - 0.5f*wheelScale);
rearContact = Multiply3x3(GetMatrix(), rearContact); rearContact = Multiply3x3(GetMatrix(), rearContact);
float traction = 0.004f * m_fTraction; float traction = 0.004f * m_fTraction;
traction *= pHandling->fTractionMultiplier / 4.0f; traction *= pHandling->fTractionMultiplier / 4.0f;
// TODO: what is this? // Turn wheel
if(GetStatus() == STATUS_PLAYER || !bIsStanding || m_bike_flag08){ if(GetStatus() == STATUS_PLAYER || !bIsStanding || m_bike_flag08){
if(Abs(m_vecMoveSpeed.x) < 0.01f && Abs(m_vecMoveSpeed.y) < 0.01f && m_fSteerAngle == 0.0f){ if(Abs(m_vecMoveSpeed.x) < 0.01f && Abs(m_vecMoveSpeed.y) < 0.01f && m_fSteerAngle == 0.0f){
m_fWheelAngle *= Pow(0.96f, CTimer::GetTimeStep()); m_fWheelAngle *= Pow(0.96f, CTimer::GetTimeStep());
@ -732,11 +739,11 @@ CBike::ProcessControl(void)
CColPoint point; CColPoint point;
point.surfaceA = SURFACE_WHEELBASE; point.surfaceA = SURFACE_WHEELBASE;
point.surfaceB = SURFACE_TARMAC; point.surfaceB = SURFACE_TARMAC;
float foo = CSurfaceTable::GetAdhesiveLimit(point)*4.0f*pBikeHandling->fSpeedSteer*traction; float steer = CSurfaceTable::GetAdhesiveLimit(point)*4.0f*pBikeHandling->fSpeedSteer*traction;
if(CSurfaceTable::GetAdhesionGroup(m_aWheelColPoints[rearLine].surfaceB) == ADHESIVE_LOOSE || if(CSurfaceTable::GetAdhesionGroup(m_aWheelColPoints[rearLine].surfaceB) == ADHESIVE_LOOSE ||
CSurfaceTable::GetAdhesionGroup(m_aWheelColPoints[rearLine].surfaceB) == ADHESIVE_SAND) CSurfaceTable::GetAdhesionGroup(m_aWheelColPoints[rearLine].surfaceB) == ADHESIVE_SAND)
foo *= pBikeHandling->fSlipSteer; steer *= pBikeHandling->fSlipSteer;
f = Asin(Min(foo/SQR(fwdSpeed), 1.0))/DEGTORAD(pHandling->fSteeringLock); f = Asin(Min(steer/SQR(fwdSpeed), 1.0))/DEGTORAD(pHandling->fSteeringLock);
if(m_fSteerAngle < 0.0f && m_fLeanLRAngle < 0.0f && if(m_fSteerAngle < 0.0f && m_fLeanLRAngle < 0.0f &&
m_fSteerAngle > 0.0f && m_fLeanLRAngle > 0.0f) m_fSteerAngle > 0.0f && m_fLeanLRAngle > 0.0f)
f *= 2.0f; f *= 2.0f;
@ -775,15 +782,15 @@ CBike::ProcessControl(void)
fThrust = 0.0f; fThrust = 0.0f;
m_aWheelColPoints[frontLine].surfaceA = SURFACE_WHEELBASE; m_aWheelColPoints[frontLine].surfaceA = SURFACE_WHEELBASE;
float adhesion = CSurfaceTable::GetAdhesiveLimit(m_aWheelColPoints[frontLine])*traction; float adhesion = CSurfaceTable::GetAdhesiveLimit(m_aWheelColPoints[frontLine])*traction;
float adhesion2 = 1.0f; float adhesionDestab = 1.0f;
if(someAngle > 0.0f) if(m_fBrakeDestabilization > 0.0f)
switch(CSurfaceTable::GetAdhesionGroup(m_aWheelColPoints[frontLine].surfaceB)){ switch(CSurfaceTable::GetAdhesionGroup(m_aWheelColPoints[frontLine].surfaceB)){
case ADHESIVE_HARD: case ADHESIVE_HARD:
case ADHESIVE_LOOSE: case ADHESIVE_LOOSE:
adhesion2 = 0.9f; adhesionDestab = 0.9f;
break; break;
case ADHESIVE_ROAD: case ADHESIVE_ROAD:
adhesion2 = 0.7f; adhesionDestab = 0.7f;
break; break;
} }
if(GetStatus() == STATUS_PLAYER) if(GetStatus() == STATUS_PLAYER)
@ -791,12 +798,12 @@ CBike::ProcessControl(void)
if(m_wheelStatus[BIKEWHEEL_FRONT] == WHEEL_STATUS_BURST) if(m_wheelStatus[BIKEWHEEL_FRONT] == WHEEL_STATUS_BURST)
adhesion *= 0.4f; adhesion *= 0.4f;
WheelState[BIKEWHEEL_FRONT] = m_aWheelState[BIKEWHEEL_FRONT]; WheelState[BIKEWHEEL_FRONT] = m_aWheelState[BIKEWHEEL_FRONT];
CVector contactSpeed = GetSpeed(frontContact);
ProcessBikeWheel(wheelFwd, wheelRight, ProcessBikeWheel(wheelFwd, wheelRight,
GetSpeed(frontContact), frontContact, contactSpeed, frontContact,
2, fThrust, 2, fThrust,
brake*brakeBiasFront, brake*brakeBiasFront,
adhesion*tractionBiasFront, adhesion*tractionBiasFront, adhesionDestab,
adhesion2,
BIKEWHEEL_FRONT, BIKEWHEEL_FRONT,
&m_aWheelSpeed[BIKEWHEEL_FRONT], &m_aWheelSpeed[BIKEWHEEL_FRONT],
&WheelState[BIKEWHEEL_FRONT], &WheelState[BIKEWHEEL_FRONT],
@ -847,15 +854,15 @@ CBike::ProcessControl(void)
fThrust = acceleration; fThrust = acceleration;
m_aWheelColPoints[rearLine].surfaceA = SURFACE_WHEELBASE; m_aWheelColPoints[rearLine].surfaceA = SURFACE_WHEELBASE;
float adhesion = CSurfaceTable::GetAdhesiveLimit(m_aWheelColPoints[rearLine])*rearTraction; float adhesion = CSurfaceTable::GetAdhesiveLimit(m_aWheelColPoints[rearLine])*rearTraction;
float adhesion2 = 1.0f; float adhesionDestab = 1.0f;
if(someAngle > 0.0f) if(m_fBrakeDestabilization > 0.0f)
switch(CSurfaceTable::GetAdhesionGroup(m_aWheelColPoints[rearLine].surfaceB)){ switch(CSurfaceTable::GetAdhesionGroup(m_aWheelColPoints[rearLine].surfaceB)){
case ADHESIVE_HARD: case ADHESIVE_HARD:
case ADHESIVE_LOOSE: case ADHESIVE_LOOSE:
adhesion2 = 0.9f; adhesionDestab = 0.9f;
break; break;
case ADHESIVE_ROAD: case ADHESIVE_ROAD:
adhesion2 = 0.7f; adhesionDestab = 0.7f;
break; break;
} }
if(GetStatus() == STATUS_PLAYER) if(GetStatus() == STATUS_PLAYER)
@ -863,12 +870,12 @@ CBike::ProcessControl(void)
if(m_wheelStatus[BIKEWHEEL_REAR] == WHEEL_STATUS_BURST) if(m_wheelStatus[BIKEWHEEL_REAR] == WHEEL_STATUS_BURST)
adhesion *= 0.4f; adhesion *= 0.4f;
WheelState[BIKEWHEEL_REAR] = m_aWheelState[BIKEWHEEL_REAR]; WheelState[BIKEWHEEL_REAR] = m_aWheelState[BIKEWHEEL_REAR];
CVector contactSpeed = GetSpeed(rearContact);
ProcessBikeWheel(wheelFwd, wheelRight, ProcessBikeWheel(wheelFwd, wheelRight,
GetSpeed(rearContact), rearContact, contactSpeed, rearContact,
2, fThrust, 2, fThrust,
rearBrake*brakeBiasFront, rearBrake*brakeBiasRear,
adhesion*tractionBiasFront, adhesion*tractionBiasRear, adhesionDestab,
adhesion2,
BIKEWHEEL_REAR, BIKEWHEEL_REAR,
&m_aWheelSpeed[BIKEWHEEL_REAR], &m_aWheelSpeed[BIKEWHEEL_REAR],
&WheelState[BIKEWHEEL_REAR], &WheelState[BIKEWHEEL_REAR],
@ -919,15 +926,15 @@ CBike::ProcessControl(void)
fThrust = 0.0f; fThrust = 0.0f;
m_aWheelColPoints[frontLine].surfaceA = SURFACE_WHEELBASE; m_aWheelColPoints[frontLine].surfaceA = SURFACE_WHEELBASE;
float adhesion = CSurfaceTable::GetAdhesiveLimit(m_aWheelColPoints[frontLine])*traction; float adhesion = CSurfaceTable::GetAdhesiveLimit(m_aWheelColPoints[frontLine])*traction;
float adhesion2 = 1.0f; float adhesionDestab = 1.0f;
if(someAngle > 0.0f) if(m_fBrakeDestabilization > 0.0f)
switch(CSurfaceTable::GetAdhesionGroup(m_aWheelColPoints[frontLine].surfaceB)){ switch(CSurfaceTable::GetAdhesionGroup(m_aWheelColPoints[frontLine].surfaceB)){
case ADHESIVE_HARD: case ADHESIVE_HARD:
case ADHESIVE_LOOSE: case ADHESIVE_LOOSE:
adhesion2 = 0.9f; adhesionDestab = 0.9f;
break; break;
case ADHESIVE_ROAD: case ADHESIVE_ROAD:
adhesion2 = 0.7f; adhesionDestab = 0.7f;
break; break;
} }
if(GetStatus() == STATUS_PLAYER) if(GetStatus() == STATUS_PLAYER)
@ -935,12 +942,12 @@ CBike::ProcessControl(void)
if(m_wheelStatus[BIKEWHEEL_FRONT] == WHEEL_STATUS_BURST) if(m_wheelStatus[BIKEWHEEL_FRONT] == WHEEL_STATUS_BURST)
adhesion *= 0.4f; adhesion *= 0.4f;
WheelState[BIKEWHEEL_FRONT] = m_aWheelState[BIKEWHEEL_FRONT]; WheelState[BIKEWHEEL_FRONT] = m_aWheelState[BIKEWHEEL_FRONT];
CVector contactSpeed = GetSpeed(frontContact);
ProcessBikeWheel(wheelFwd, wheelRight, ProcessBikeWheel(wheelFwd, wheelRight,
GetSpeed(frontContact), frontContact, contactSpeed, frontContact,
2, fThrust, 2, fThrust,
brake*brakeBiasFront, brake*brakeBiasFront,
adhesion*tractionBiasFront, adhesion*tractionBiasFront, adhesionDestab,
adhesion2,
BIKEWHEEL_FRONT, BIKEWHEEL_FRONT,
&m_aWheelSpeed[BIKEWHEEL_FRONT], &m_aWheelSpeed[BIKEWHEEL_FRONT],
&WheelState[BIKEWHEEL_FRONT], &WheelState[BIKEWHEEL_FRONT],
@ -966,9 +973,9 @@ CBike::ProcessControl(void)
m_vecAvgSurfaceRight = CrossProduct(GetForward(), m_vecAvgSurfaceNormal); m_vecAvgSurfaceRight = CrossProduct(GetForward(), m_vecAvgSurfaceNormal);
m_vecAvgSurfaceRight.Normalise(); m_vecAvgSurfaceRight.Normalise();
float lean; float lean;
if(m_nWheelsOnGround == 0){ if(m_nWheelsOnGround == 0)
lean = -m_fSteerAngle/DEGTORAD(pHandling->fSteeringLock)*0.5f*GRAVITY*CTimer::GetTimeStep(); lean = -m_fSteerAngle/DEGTORAD(pHandling->fSteeringLock)*0.5f*GRAVITY*CTimer::GetTimeStep();
}else else
lean = DotProduct(m_vecMoveSpeed-initialMoveSpeed, m_vecAvgSurfaceRight); lean = DotProduct(m_vecMoveSpeed-initialMoveSpeed, m_vecAvgSurfaceRight);
lean /= GRAVITY*Max(CTimer::GetTimeStep(), 0.01f); lean /= GRAVITY*Max(CTimer::GetTimeStep(), 0.01f);
if(m_wheelStatus[BIKEWHEEL_FRONT] == WHEEL_STATUS_BURST) if(m_wheelStatus[BIKEWHEEL_FRONT] == WHEEL_STATUS_BURST)
@ -988,23 +995,23 @@ CBike::ProcessControl(void)
} }
m_fLeanLRAngle = m_fLeanLRAngle2; m_fLeanLRAngle = m_fLeanLRAngle2;
// TODO: what is this? // Destabilize steering when braking
if((m_aSuspensionSpringRatio[BIKESUSP_F1] < 1.0f || m_aSuspensionSpringRatio[BIKESUSP_F2] < 1.0f) && if((m_aSuspensionSpringRatio[BIKESUSP_F1] < 1.0f || m_aSuspensionSpringRatio[BIKESUSP_F2] < 1.0f) &&
m_fBrakePedal - m_fGasPedal > 0.9f && m_fBrakePedal - m_fGasPedal > 0.9f &&
fwdSpeed > 0.02f && fwdSpeed > 0.02f &&
!bIsHandbrakeOn){ !bIsHandbrakeOn){
someAngle += CGeneral::GetRandomNumberInRange(0.5f, 1.0f)*0.2f*CTimer::GetTimeStep(); m_fBrakeDestabilization += CGeneral::GetRandomNumberInRange(0.5f, 1.0f)*0.2f*CTimer::GetTimeStep();
if(m_aSuspensionSpringRatio[BIKESUSP_R1] < 1.0f || m_aSuspensionSpringRatio[BIKESUSP_R2] < 1.0f){ if(m_aSuspensionSpringRatio[BIKESUSP_R1] < 1.0f || m_aSuspensionSpringRatio[BIKESUSP_R2] < 1.0f){
// BUG: this clamp makes no sense and the arguments seem swapped too // BUG: this clamp makes no sense and the arguments seem swapped too
ApplyTurnForce(contactPoints[BIKESUSP_R1], ApplyTurnForce(contactPoints[BIKESUSP_R1],
m_fTurnMass*Sin(someAngle)*clamp(fwdSpeed, 0.5f, 0.2f)*0.013f*GetRight()*CTimer::GetTimeStep()); m_fTurnMass*Sin(m_fBrakeDestabilization)*clamp(fwdSpeed, 0.5f, 0.2f)*0.013f*GetRight()*CTimer::GetTimeStep());
}else{ }else{
// BUG: this clamp makes no sense and the arguments seem swapped too // BUG: this clamp makes no sense and the arguments seem swapped too
ApplyTurnForce(contactPoints[BIKESUSP_R1], ApplyTurnForce(contactPoints[BIKESUSP_R1],
m_fTurnMass*Sin(someAngle)*clamp(fwdSpeed, 0.5f, 0.2f)*0.003f*GetRight()*CTimer::GetTimeStep()); m_fTurnMass*Sin(m_fBrakeDestabilization)*clamp(fwdSpeed, 0.5f, 0.2f)*0.003f*GetRight()*CTimer::GetTimeStep());
} }
}else }else
someAngle = 0.0f; m_fBrakeDestabilization = 0.0f;
// Update wheel positions from suspension // Update wheel positions from suspension
float frontWheelPos = colModel->lines[frontLine].p0.z; float frontWheelPos = colModel->lines[frontLine].p0.z;
@ -1043,12 +1050,69 @@ CBike::ProcessControl(void)
} }
} }
// TODO: pad shaking ProcessDelayedExplosion();
// Find out how much to shake the pad depending on suspension and ground surface
float suspShake = 0.0f;
float surfShake = 0.0f;
float speedsq = m_vecMoveSpeed.MagnitudeSqr();
for(i = 0; i < 4; i++){ for(i = 0; i < 4; i++){
float suspChange = m_aSuspensionSpringRatioPrev[i] - m_aSuspensionSpringRatio[i];
if(suspChange > 0.3f && (i == BIKESUSP_F1 || i == BIKESUSP_R1) && speedsq > 0.04f){
if(GetStatus() == STATUS_PLAYER || GetStatus() == STATUS_PHYSICS){
if(m_wheelStatus[i] == WHEEL_STATUS_BURST)
DMAudio.PlayOneShot(m_audioEntityId, SOUND_CAR_JUMP_2, suspChange);
else
DMAudio.PlayOneShot(m_audioEntityId, SOUND_CAR_JUMP, suspChange);
if(suspChange > suspShake)
suspShake = suspChange;
}
}
if(this == FindPlayerVehicle()){
uint8 surf = m_aWheelColPoints[i].surfaceB;
if(surf == SURFACE_GRAVEL || surf == SURFACE_WATER || surf == SURFACE_HEDGE){
if(surfShake < 0.2f)
surfShake = 0.3f;
}else if(surf == SURFACE_MUD_DRY || surf == SURFACE_SAND || surf == SURFACE_SAND_BEACH){
if(surfShake < 0.1f)
surfShake = 0.2f;
}else if(surf == SURFACE_GRASS){
if(surfShake < 0.05f)
surfShake = 0.1f;
}
// BUG: this only observes one of the wheels
TheCamera.m_bVehicleSuspenHigh = Abs(suspChange) > 0.05f;
}
m_aSuspensionSpringRatioPrev[i] = m_aSuspensionSpringRatio[i]; m_aSuspensionSpringRatioPrev[i] = m_aSuspensionSpringRatio[i];
m_aSuspensionSpringRatio[i] = 1.0f; m_aSuspensionSpringRatio[i] = 1.0f;
} }
// Shake pad
if((suspShake > 0.0f || surfShake > 0.0f) && GetStatus() == STATUS_PLAYER){
float speed = m_vecMoveSpeed.MagnitudeSqr();
if(speed > sq(0.1f)){
speed = Sqrt(speed);
if(suspShake > 0.0f){
uint8 freq = Min(200.0f*suspShake*speed*2000.0f/m_fMass + 100.0f, 250.0f);
CPad::GetPad(0)->StartShake(20000.0f*CTimer::GetTimeStep()/freq, freq);
}else{
uint8 freq = Min(200.0f*surfShake*speed*2000.0f/m_fMass + 40.0f, 150.0f);
CPad::GetPad(0)->StartShake(5000.0f*CTimer::GetTimeStep()/freq, freq);
}
}
}
bVehicleColProcessed = false;
bAudioChangingGear = false;
if(!bWarnedPeds)
CCarCtrl::ScanForPedDanger(this);
if(bInfiniteMass){ if(bInfiniteMass){
m_vecMoveSpeed = CVector(0.0f, 0.0f, 0.0f); m_vecMoveSpeed = CVector(0.0f, 0.0f, 0.0f);
m_vecTurnSpeed = CVector(0.0f, 0.0f, 0.0f); m_vecTurnSpeed = CVector(0.0f, 0.0f, 0.0f);
@ -1068,13 +1132,44 @@ CBike::ProcessControl(void)
if(bCanStand || m_bike_flag08 || bIsStanding){ if(bCanStand || m_bike_flag08 || bIsStanding){
float onSideness = clamp(DotProduct(GetRight(), m_vecAvgSurfaceNormal), -1.0f, 1.0f); float onSideness = clamp(DotProduct(GetRight(), m_vecAvgSurfaceNormal), -1.0f, 1.0f);
CVector worldCOM = Multiply3x3(GetMatrix(), m_vecCentreOfMass); CVector worldCOM = Multiply3x3(GetMatrix(), m_vecCentreOfMass);
// Keep bike upright
if(bCanStand){ if(bCanStand){
ApplyTurnForce(-0.07f*onSideness*m_fTurnMass*GetUp()*CTimer::GetTimeStep(), worldCOM+GetRight()); ApplyTurnForce(-0.07f*onSideness*m_fTurnMass*GetUp()*CTimer::GetTimeStep(), worldCOM+GetRight());
bIsStanding = false; bIsStanding = false;
}else{ }else
ApplyTurnForce(-0.1f*onSideness*m_fTurnMass*GetUp()*CTimer::GetTimeStep(), worldCOM+GetRight()); ApplyTurnForce(-0.1f*onSideness*m_fTurnMass*GetUp()*CTimer::GetTimeStep(), worldCOM+GetRight());
// Wheelie/Stoppie stabilization
if(GetStatus() == STATUS_PLAYER){
if(m_aWheelTimer[BIKESUSP_F1] == 0.0f && m_aWheelTimer[BIKESUSP_F2] == 0.0f && GetForward().z > 0.0 &&
!(m_aWheelTimer[BIKESUSP_R1] == 0.0f && m_aWheelTimer[BIKESUSP_R2] == 0.0f)){
// Wheelie
float wheelie = pBikeHandling->fWheelieAng - GetForward().z;
if(wheelie > 0.15f)
// below wheelie angle
wheelie = Max(0.3f - wheelie, 0.0f);
else if(wheelie < -0.08f)
// above wheelie angle
wheelie = Min(-0.15f - wheelie, 0.0f);
float wheelieStab = pBikeHandling->fWheelieStabMult * Min(m_vecMoveSpeed.Magnitude(), 0.1f) * wheelie;
ApplyTurnForce(0.5f*CTimer::GetTimeStep()*wheelieStab*m_fTurnMass*GetUp(), worldCOM+GetForward());
ApplyTurnForce(0.5f*CTimer::GetTimeStep()*m_fWheelAngle*pBikeHandling->fWheelieSteer*m_fTurnMass*GetRight(), worldCOM+GetForward());
}else if(m_aWheelTimer[BIKESUSP_R1] == 0.0f && m_aWheelTimer[BIKESUSP_R2] == 0.0f && GetForward().z < 0.0 &&
!(m_aWheelTimer[BIKESUSP_F1] == 0.0f && m_aWheelTimer[BIKESUSP_F2] == 0.0f)){
// Stoppie
float stoppie = pBikeHandling->fStoppieAng - GetForward().z;
if(stoppie > 0.15f)
// below stoppie angle
stoppie = Max(0.3f - stoppie, 0.0f);
else if(stoppie < -0.15f)
// above stoppie angle
stoppie = Min(-0.3f - stoppie, 0.0f);
float speed = m_vecMoveSpeed.Magnitude();
float stoppieStab = pBikeHandling->fStoppieStabMult * Min(speed, 0.1f) * stoppie;
ApplyTurnForce(0.5f*CTimer::GetTimeStep()*stoppieStab*m_fTurnMass*GetUp(), worldCOM+GetForward());
ApplyTurnForce(0.5f*Min(5.0f*speed,1.0f)*CTimer::GetTimeStep()*m_fWheelAngle*pBikeHandling->fWheelieSteer*m_fTurnMass*GetRight(), worldCOM+GetForward());
}
} }
// TODO
} }
} }
@ -1126,7 +1221,7 @@ CBike::PreRender(void)
m_aWheelRotation[BIKEWHEEL_REAR] += m_aWheelSpeed[BIKEWHEEL_REAR]; m_aWheelRotation[BIKEWHEEL_REAR] += m_aWheelSpeed[BIKEWHEEL_REAR];
} }
// Rear fork // Front fork
if(m_aBikeNodes[BIKE_FORKS_FRONT]){ if(m_aBikeNodes[BIKE_FORKS_FRONT]){
mat.Attach(RwFrameGetMatrix(m_aBikeNodes[BIKE_FORKS_FRONT])); mat.Attach(RwFrameGetMatrix(m_aBikeNodes[BIKE_FORKS_FRONT]));
pos = mat.GetPosition(); pos = mat.GetPosition();
@ -1166,7 +1261,7 @@ CBike::PreRender(void)
} }
} }
// Front fork // Rear fork
if(m_aBikeNodes[BIKE_FORKS_REAR]){ if(m_aBikeNodes[BIKE_FORKS_REAR]){
float sine = (m_aWheelPosition[BIKEWHEEL_REAR] - m_aWheelBasePosition[BIKEWHEEL_REAR])/m_fRearForkLength; float sine = (m_aWheelPosition[BIKEWHEEL_REAR] - m_aWheelBasePosition[BIKEWHEEL_REAR])/m_fRearForkLength;
mat.Attach(RwFrameGetMatrix(m_aBikeNodes[BIKE_FORKS_REAR])); mat.Attach(RwFrameGetMatrix(m_aBikeNodes[BIKE_FORKS_REAR]));
@ -1254,7 +1349,6 @@ CBike::ProcessEntityCollision(CEntity *ent, CColPoint *colpoints)
// m_aSuspensionSpringRatio are now set to the point where the tyre touches ground. // m_aSuspensionSpringRatio are now set to the point where the tyre touches ground.
// In ProcessControl these will be re-normalized to ignore the tyre radius. // In ProcessControl these will be re-normalized to ignore the tyre radius.
if(colModel->numLines){ if(colModel->numLines){
for(i = 0; i < 4; i++){ for(i = 0; i < 4; i++){
if(m_aSuspensionSpringRatio[i] < 1.0f && m_aSuspensionSpringRatio[i] < prevRatios[i]){ if(m_aSuspensionSpringRatio[i] < 1.0f && m_aSuspensionSpringRatio[i] < prevRatios[i]){

View file

@ -71,12 +71,12 @@ public:
uint8 bWaterTight : 1; uint8 bWaterTight : 1;
uint8 m_bike_flag08 : 1; uint8 m_bike_flag08 : 1;
uint8 bIsStanding : 1; uint8 bIsStanding : 1;
uint8 m_bike_flag20 : 1; uint8 bExtraSpeed : 1; // leaning forward
uint8 m_bike_flag40 : 1; uint8 m_bike_flag40 : 1;
uint8 m_bike_flag80 : 1; uint8 m_bike_flag80 : 1;
int16 m_doingBurnout; int16 m_doingBurnout;
float m_fTireTemperature; float m_fTireTemperature;
float someAngle; float m_fBrakeDestabilization;
uint32 field_490; uint32 field_490;
float m_fFireBlowUpTimer; float m_fFireBlowUpTimer;
CPhysical *m_aGroundPhysical[4]; CPhysical *m_aGroundPhysical[4];