kingpin-sdk/gamesrc/VEHICLES.C

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2000-03-27 00:00:00 +00:00
//======================================================================
// Vehicle Physics/Simulation
#include "g_local.h"
#include "veh_defs.h"
/*
Veh_ProcessFrame
Handles everything from input acceleration/braking, through world physics and dynamics.
*/
void Veh_ProcessFrame( edict_t *ent, usercmd_t *ucmd, pmove_t *pm )
{
vehicle_t *vehicle;
// find the vehicle structure
if (ent->vehicle_index)
{
vehicle = &global_vehicles[ent->vehicle_index - 1];
}
else // need to assign them one
{
int i;
for (i=0; i< MAX_VEHICLES; i++)
{
if (!global_vehicles[i].driver)
{
vehicle = &global_vehicles[i];
ent->vehicle_index = i + 1;
vehicle->driver = ent;
// this will eventually be setup inside the map, but for now just do it here
vehicle->def = &vehicle_defines[0];
Veh_InitVehicle( vehicle );
}
}
}
VectorCopy( vehicle->origin, vehicle->oldorigin );
VectorCopy( vehicle->angles, vehicle->oldangles );
// Process the controls
Veh_ProcessControls( vehicle, ucmd );
// Set steering avelocity
Veh_SetSteeringAngleVelocity( vehicle );
// Do Angular Velocities
Veh_PerformAngleVelocity( vehicle, 0.001 * ((float)ucmd->msec), pm );
// Move the vehicle according to it's velocity
Veh_PerformMove( vehicle, pm );
// Examine movement, adjusting velocity accordingly
// Set the position of the owner to the middle of the front and rear positions, with angles:
// PITCH: according to front/rear positions
// ROLL: use interpolated roll angles from downward traces at each wheel(??)
// Show the vehicle
Veh_PositionModels( vehicle );
}
/*
==================
Veh_InitVehicle
Initializes a vehicle ready for placing into the game
==================
*/
void Veh_InitVehicle ( vehicle_t *vehicle )
{
vehicle->front_traction = 1.0;
vehicle->rear_traction = 1.0;
vehicle->front_weight_ratio = 0.5;
vehicle->front_onground = true;
vehicle->rear_onground = true;
VectorClear( vehicle->velocity );
VectorClear( vehicle->avelocity );
VectorCopy( vehicle->driver->s.origin, vehicle->origin );
VectorCopy( vehicle->driver->s.angles, vehicle->angles );
vehicle->gear = 1; // neutral
vehicle->rpm = 0;
vehicle->throttle = 0;
vehicle->steer_yaw = 0;
vehicle->fl = G_Spawn();
vehicle->fl->s.modelindex = gi.modelindex( vehicle->def->wheel_model );
vehicle->fr = G_Spawn();
vehicle->fr->s.modelindex = gi.modelindex( vehicle->def->wheel_model );
vehicle->rl = G_Spawn();
vehicle->rl->s.modelindex = gi.modelindex( vehicle->def->wheel_model );
vehicle->rr = G_Spawn();
vehicle->rr->s.modelindex = gi.modelindex( vehicle->def->wheel_model );
}
/*
=====================
Veh_ProcessControls
Process all inputs and adjust velocities and traction levels
=====================
*/
void Veh_ProcessControls ( vehicle_t *vehicle, usercmd_t *ucmd )
{
#define THROTTLE_ACCELERATION 20000.0 // increase this amount per second
#define THROTTLE_DECCELERATION 20000.0
#define STEERING_ACCELERATION 75.0
float throttle_add, throttle_ideal, throttle_max, throttle_rate;
float steering_ideal, steering_add, steering_max, steer_rate;
vec3_t forward, unit_vel;
float frametime;
float current_speed;
float new_rpm;
float wheel_torque, max_wheel_torque;
float ideal_speed, rear_speed;
float accel_force = 0; // force applied by ground
float accel_speed = 0; // transferred velocity increase to vehicle
AngleVectors( vehicle->angles, forward, NULL, NULL );
if (vehicle->velocity[0] || vehicle->velocity[1] || vehicle->velocity[2])
{
current_speed = VectorNormalize2( vehicle->velocity, unit_vel );
}
else
{
VectorCopy( forward, unit_vel );
current_speed = 0;
}
frametime = (0.001 * ucmd->msec);
// adjust throttle
throttle_ideal = ((float)(ucmd->forwardmove) / 400.0) * (THROTTLE_MAX - IDLE_THROTTLE) + IDLE_THROTTLE;
if (throttle_ideal < 0)
throttle_ideal = 0; // TODO: this would be brakes
throttle_add = throttle_ideal - vehicle->throttle;
if ((throttle_add < 0) && (ucmd->forwardmove >= 0) && (vehicle->gear == 1))
throttle_rate = THROTTLE_DECCELERATION;
else
throttle_rate = THROTTLE_ACCELERATION;
if (fabs( throttle_add ) > (throttle_max = (throttle_rate * frametime) ) )
{
if (throttle_add < 0)
throttle_add = -throttle_max;
else
throttle_add = throttle_max;
}
vehicle->throttle = vehicle->throttle + throttle_add;
Veh_Debug( "Thr=%4i ", (int)vehicle->throttle );
// adjust steering
steering_ideal = -((float)(ucmd->sidemove) / 400.0) * vehicle->def->max_steer * (0.5 + 0.5 * ((VEH_MAX_SPEED - current_speed) / VEH_MAX_SPEED));
// turn faster if changing directions
steer_rate = STEERING_ACCELERATION;
if (steering_ideal == 0)
steer_rate *= 2;
if (steering_ideal < 0)
{
if (vehicle->steer_yaw > 0)
steer_rate *= 2;
}
else
{
if (vehicle->steer_yaw < 0)
steer_rate *= 2;
}
steering_add = steering_ideal - vehicle->steer_yaw;
if (fabs( steering_add ) > (steering_max = (steer_rate * frametime) ) )
{
if (steering_add < 0)
steering_add = -steering_max;
else
steering_add = steering_max;
}
vehicle->steer_yaw += steering_add;
Veh_Debug( "Str=%2i ", (int)vehicle->steer_yaw );
Veh_Debug( "G=%s ", vehicle->def->gearbox->gears[vehicle->gear].name );
// Do engine acceleration
// if (vehicle->throttle > vehicle->rpm)
{
// Get the new engine RPM, which is effected by the current throttle, and drivetrain resistance
if (vehicle->def->gearbox->gears[vehicle->gear].ratio) // current gear isn't neutral
{
// Get the "force" applied by the acceleration on the drivetrain
// We use this to determine whether or not the rear wheels will hold traction
// get the amount of torque applied at the rear wheels
wheel_torque = Veh_WheelTorqueAtRPM( vehicle, vehicle->throttle - vehicle->rpm );
Veh_Debug( "Tw=%i ", (int)wheel_torque );
// get the maximum amount of torque the rear wheels will take
max_wheel_torque =
(1.0 - vehicle->front_weight_ratio)
* (vehicle->def->weight * KG_TO_LBS)
* ((vehicle->rear_traction + 1.0) / 2.0);
Veh_Debug( "TwM=%i ", (int)max_wheel_torque );
// get the speed we should be doing at the new rpm
ideal_speed = Veh_SpeedAtRPM( vehicle, vehicle->throttle );
Veh_Debug( "iSpd=%i ", (int)ideal_speed );
rear_speed = current_speed;
if (rear_speed > 0)
// rear_speed *= ((fabs(DotProduct( forward, unit_vel )) + 1.0) / 2.0);
rear_speed *= DotProduct( forward, unit_vel );
Veh_Debug( "cSpd=%i ", (int)rear_speed );
if ( ((ideal_speed > 0) && (ideal_speed > rear_speed))
|| ((ideal_speed < 0) && (ideal_speed < rear_speed)))
{
if (wheel_torque > max_wheel_torque)
{
vehicle->rear_traction -= (wheel_torque / max_wheel_torque) * frametime;
}
else if (vehicle->rear_traction < 1.0)
{
vehicle->rear_traction += ((max_wheel_torque - wheel_torque) / max_wheel_torque) * frametime * 7.0;
if (vehicle->rear_traction > 1.0)
vehicle->rear_traction = 1.0;
}
// cap min traction (TODO: use current surface as factor of minimum)
if (vehicle->rear_traction < 0.1) // HACK
vehicle->rear_traction = 0.1;
// get the amount of force applied to the vehicle at the new throttle
accel_force =
(wheel_torque) * LBS_TO_KG
* FT_TO_CM * CM_TO_UNITS
* vehicle->rear_traction
* 2.0 // HACK, fudge factor
/ frametime; // convert to force per second
if (ideal_speed < 0)
accel_force *= -1;
}
else // slowing down
{
// if we're going faster than the maximum revs of the engine will take us
if ( Veh_SpeedAtRPM( vehicle, THROTTLE_MAX ) < rear_speed )
{
// lose traction, but still grip
vehicle->rear_traction -= 2 * frametime; // ???
// cap min traction (TODO: use current surface as factor of minimum)
if (vehicle->rear_traction < 0.5) // HACK
vehicle->rear_traction = 0.5;
}
else if (vehicle->rear_traction < 1.0)
{
// regain traction
vehicle->rear_traction += 5 * frametime; // ???
if (vehicle->rear_traction > 1.0)
vehicle->rear_traction = 1.0;
}
// Decompression braking!
wheel_torque = Veh_WheelTorqueAtRPM( vehicle, vehicle->rpm );
accel_force =
(wheel_torque) * LBS_TO_KG
* -0.5
* FT_TO_CM * CM_TO_UNITS
* vehicle->rear_traction
/ frametime; // convert to force per second
}
Veh_Debug( "Tr=%1.2f ", vehicle->rear_traction );
Veh_Debug( "Af=%i ", (int)accel_force );
accel_speed = accel_force / vehicle->def->weight;
// factor in rolling resistance
accel_speed -= current_speed * 0.0007656;
// factor in drag resistance
accel_speed -= (0.5 * 0.3 * 20 * 0.00025 * ((current_speed*UNITS_TO_CM*CM_TO_FT) * (current_speed*UNITS_TO_CM*CM_TO_FT))) * FT_TO_CM * CM_TO_UNITS
* 0.05; // Fudge factor
Veh_Debug( "As=%i ", (int)accel_speed );
}
}
// Calculate the transferred velocity to the vehicle
VectorMA( vehicle->velocity, accel_speed * frametime, forward, vehicle->velocity );
current_speed = VectorLength( vehicle->velocity );
Veh_Debug( "Spd=%i ", (int)current_speed );
// get the new engine RPM
if (vehicle->gear != 1)
{
rear_speed = current_speed;
if (rear_speed > 0)
rear_speed *= ((fabs(DotProduct( forward, unit_vel )) + 1.0) / 2.0);
new_rpm = Veh_RPMatSpeed( vehicle, rear_speed );
if (new_rpm > THROTTLE_MAX)
new_rpm = THROTTLE_MAX;
if (vehicle->rear_traction >= 1)
{
vehicle->rpm = new_rpm;
if (vehicle->rear_traction > 1.0)
vehicle->rear_traction = 1.0;
}
else // use new_rpm, but adjust for throttle
{
vehicle->rpm = new_rpm + (vehicle->throttle - new_rpm) * (1.0 - vehicle->rear_traction);
}
}
else
{
vehicle->rpm = vehicle->throttle;
}
Veh_Debug( "Erpm=%4.0f ", vehicle->rpm );
Veh_Debug( "\n" );
}
/*
=================
Veh_Debug
=================
*/
void Veh_Debug( char *fmt, ...)
{
int len;
va_list argptr;
char bigbuffer[0x10000];
va_start (argptr,fmt);
len = vsprintf (bigbuffer,fmt,argptr);
va_end (argptr);
gi.dprintf( bigbuffer );
}
/*
=================
Veh_SpeedAtRPM
=================
*/
float Veh_SpeedAtRPM( vehicle_t *veh, float rpm )
{
float speed;
speed =
(rpm)
* (1.0 / veh->def->gearbox->gears[veh->gear].ratio)
* (1.0 / veh->def->diff_ratio)
* (M_PI * veh->def->wheels->radius * 2 * CM_TO_UNITS)
* MIN_PER_SEC;
return speed;
}
/*
=================
Veh_RPMatSpeed
=================
*/
float Veh_RPMatSpeed( vehicle_t *veh, float speed )
{
float rpm;
rpm =
(speed)
* (veh->def->gearbox->gears[veh->gear].ratio)
* (veh->def->diff_ratio)
* (1.0 / (M_PI * veh->def->wheels->radius * 2 * CM_TO_UNITS))
* SEC_PER_MIN;
if (rpm < 0) // reversing
rpm = -rpm;
return rpm;
}
/*
=================
Veh_SpeedAtRPM
=================
*/
float Veh_WheelTorqueAtRPM( vehicle_t *veh, float rpm )
{
float torque;
torque =
(veh->def->engine_power * 1.5) // translate roughly to foot-pounds of engine torque
* (rpm / THROTTLE_MAX)
* (veh->def->gearbox->gears[veh->gear].ratio)
* (veh->def->gearbox->gears[veh->gear].ratio) // Fudge factor
* (veh->def->diff_ratio)
* (1.0 / (veh->def->wheels->radius * CM_TO_FT));
return torque;
}
/*
=================
Veh_PerformMove
=================
*/
void Veh_PerformMove( vehicle_t *vehicle, pmove_t *pm )
{
int i;
gclient_t *client;
edict_t *ent;
ent = vehicle->driver;
client = vehicle->driver->client;
for (i=0 ; i<3 ; i++)
{
pm->s.origin[i] = vehicle->origin[i]*8;
pm->s.velocity[i] = vehicle->velocity[i]*8;
}
// perform a pmove
gi.Pmove (pm);
// save results of pmove
client->ps.pmove = pm->s;
client->old_pmove = pm->s;
for (i=0 ; i<3 ; i++)
{
vehicle->origin[i] = pm->s.origin[i]*0.125;
vehicle->velocity[i] = pm->s.velocity[i]*0.125;
}
// VectorCopy (pm->mins, ent->mins);
// VectorCopy (pm->maxs, ent->maxs);
// client->resp.cmd_angles[0] = SHORT2ANGLE(ucmd->angles[0]);
// client->resp.cmd_angles[1] = SHORT2ANGLE(ucmd->angles[1]);
// client->resp.cmd_angles[2] = SHORT2ANGLE(ucmd->angles[2]);
VectorCopy( vehicle->angles, client->ps.viewangles );
VectorCopy( vehicle->angles, client->v_angle );
client->ps.pmove.pm_type = PM_FREEZE;
ent->viewheight = pm->viewheight;
ent->waterlevel = pm->waterlevel;
ent->watertype = pm->watertype;
ent->groundentity = pm->groundentity;
if (pm->groundentity)
ent->groundentity_linkcount = pm->groundentity->linkcount;
VectorCopy( vehicle->origin, ent->s.origin );
}
void Veh_PerformAngleVelocity( vehicle_t *vehicle, float frametime, pmove_t *pm )
{
float speed;
vec3_t unitvel, forward, up;
VectorMA( vehicle->angles, frametime, vehicle->avelocity, vehicle->angles );
// adjust velocity
if (vehicle->velocity[0] || vehicle->velocity[1] || vehicle->velocity[2])
{
AngleVectors( vehicle->angles, forward, NULL, up );
speed = VectorNormalize2( vehicle->velocity, unitvel );
VectorScale( forward, speed * (vehicle->rear_traction + vehicle->front_traction) / 2.0, vehicle->velocity );
VectorMA( vehicle->velocity, speed * (1.0 - ((vehicle->rear_traction + vehicle->front_traction) / 2.0)), unitvel, vehicle->velocity );
}
// According to traction levels, we should move the CG (center of gravity), such that:
//
// * Under FULL traction of the REAR wheels, rotate about the rear axle center
// * Under ZERO traction of the REAR wheels, rotate about the front axle center
// Just calculate this as a movement of the center of the vehicle / second, and add to velocity
if (vehicle->avelocity[YAW])
{
vec3_t dst, pnt, rear_pnt, move;
vec3_t velback;
VectorMA( vehicle->origin, (-vehicle->def->wheelspan_length*0.5 + (vehicle->def->wheelspan_length * (1.0 - vehicle->rear_traction) * (vehicle->front_traction*0.5 + 0.5))), forward, rear_pnt );
VectorSubtract( vehicle->origin, rear_pnt, pnt );
RotatePointAroundVector( dst, up, pnt, vehicle->avelocity[YAW] * frametime );
VectorSubtract( dst, pnt, move );
// convert to per second, since it'll get converted back in Pmove();
VectorScale( move, 0.3 / frametime, move ); // 0.3 is a HACK, should be 1.0
// save the velocity
VectorCopy( vehicle->velocity, velback );
VectorCopy( move, vehicle->velocity );
// move the vehicle to account for the change in CG
Veh_PerformMove( vehicle, pm );
// set the velocity back
VectorCopy( velback, vehicle->velocity );
Veh_Debug( "YawAdjust=%3.0f ", VectorLength(move) );
}
}
void Veh_SetSteeringAngleVelocity( vehicle_t *vehicle )
{
float speed, dot, yaw_change;
vec3_t forward, unitvel;
AngleVectors( vehicle->angles, forward, NULL, NULL );
if (vehicle->velocity[0] || vehicle->velocity[1] || vehicle->velocity[2])
{
speed = VectorNormalize2( vehicle->velocity, unitvel );
yaw_change =
( (vehicle->steer_yaw)
* (speed / (vehicle->def->wheelspan_length * CM_TO_UNITS))
* (vehicle->front_traction))
- vehicle->avelocity[YAW];
dot = DotProduct( forward, unitvel );
yaw_change *= dot; // this works for reverse, since yaw is just the opposite
}
else
{
speed = 0;
VectorClear( unitvel );
yaw_change = -vehicle->avelocity[YAW] * vehicle->front_traction;
}
vehicle->avelocity[YAW] += yaw_change;
Veh_Debug( "YawVel=%3.0f\n", vehicle->avelocity[YAW] );
}
void Veh_HoldRearWheels( vehicle_t *vehicle )
{
vec3_t old_rear, new_rear;
vec3_t old_fwd, new_fwd;
vec3_t ideal_rear, ideal_vec, end_rear;
vec3_t new_vec, old_vec;
AngleVectors( vehicle->oldangles, old_fwd, NULL, NULL );
VectorMA( vehicle->oldorigin, -vehicle->def->wheelspan_length * 0.5, old_fwd, old_rear );
AngleVectors( vehicle->angles, new_fwd, NULL, NULL );
VectorMA( vehicle->origin, -vehicle->def->wheelspan_length * 0.5, new_fwd, new_rear );
VectorSubtract( old_rear, vehicle->origin, old_vec );
VectorNormalize( old_vec );
VectorMA( vehicle->origin, vehicle->def->wheelspan_length * 0.5, old_vec, ideal_rear );
// now move to it depending on traction
VectorSubtract( ideal_rear, new_rear, ideal_vec );
VectorMA( new_rear, vehicle->rear_traction, ideal_vec, end_rear );
VectorSubtract( vehicle->origin, end_rear, new_vec );
VectorNormalize( new_vec );
vehicle->angles[YAW] = vectoyaw( new_vec );
}
// this is hacked together just for debugging
void Veh_PositionModels( vehicle_t *vehicle )
{
vec3_t fwd, right, up;
AngleVectors( vehicle->angles, fwd, right, up );
VectorMA( vehicle->origin, 0.5 * CM_TO_UNITS * vehicle->def->wheelspan_length, fwd, vehicle->fl->s.origin );
VectorMA( vehicle->fl->s.origin, -0.5 * CM_TO_UNITS * vehicle->def->wheelspan_width, right, vehicle->fl->s.origin );
VectorMA( vehicle->fl->s.origin, -24 + CM_TO_UNITS * vehicle->def->wheels->radius, up, vehicle->fl->s.origin );
VectorCopy( vehicle->angles, vehicle->fl->s.angles );
vehicle->fl->s.angles[YAW] += vehicle->steer_yaw;
gi.linkentity( vehicle->fl );
VectorMA( vehicle->origin, 0.5 * CM_TO_UNITS * vehicle->def->wheelspan_length, fwd, vehicle->fr->s.origin );
VectorMA( vehicle->fr->s.origin, 0.5 * CM_TO_UNITS * vehicle->def->wheelspan_width, right, vehicle->fr->s.origin );
VectorMA( vehicle->fr->s.origin, -24 + CM_TO_UNITS * vehicle->def->wheels->radius, up, vehicle->fr->s.origin );
VectorCopy( vehicle->angles, vehicle->fr->s.angles );
vehicle->fr->s.angles[YAW] += vehicle->steer_yaw;
gi.linkentity( vehicle->fr );
VectorMA( vehicle->origin, -0.5 * CM_TO_UNITS * vehicle->def->wheelspan_length, fwd, vehicle->rl->s.origin );
VectorMA( vehicle->rl->s.origin, -0.5 * CM_TO_UNITS * vehicle->def->wheelspan_width, right, vehicle->rl->s.origin );
VectorMA( vehicle->rl->s.origin, -24 + CM_TO_UNITS * vehicle->def->wheels->radius, up, vehicle->rl->s.origin );
VectorCopy( vehicle->angles, vehicle->rl->s.angles );
gi.linkentity( vehicle->rl );
VectorMA( vehicle->origin, -0.5 * CM_TO_UNITS * vehicle->def->wheelspan_length, fwd, vehicle->rr->s.origin );
VectorMA( vehicle->rr->s.origin, 0.5 * CM_TO_UNITS * vehicle->def->wheelspan_width, right, vehicle->rr->s.origin );
VectorMA( vehicle->rr->s.origin, -24 + CM_TO_UNITS * vehicle->def->wheels->radius, up, vehicle->rr->s.origin );
VectorCopy( vehicle->angles, vehicle->rr->s.angles );
gi.linkentity( vehicle->rr );
}