.int disableclientprediction;
void sys_phys_simulate(entity this, float dt);
+void sys_phys_simulate_simple(entity this, float dt);
void sys_phys_update(entity this, float dt)
{
+ if (!IS_CLIENT(this)) {
+ sys_phys_simulate_simple(this, dt);
+ return;
+ }
sys_in_update(this, dt);
sys_phys_fix(this, dt);
- if (sys_phys_override(this)) { return; } sys_phys_monitor(this);
+ if (sys_phys_override(this, dt)) { return; } sys_phys_monitor(this, dt);
- int buttons_prev = this.buttons_old;
this.buttons_old = PHYS_INPUT_BUTTON_MASK(this);
this.movement_old = this.movement;
this.v_angle_old = this.v_angle;
sys_phys_pregame_hold(this);
if (IS_SVQC) {
- if (PHYS_MOVETYPE(this) == MOVETYPE_NONE) { return; }
+ if (this.move_movetype == MOVETYPE_NONE) { return; }
// when we get here, disableclientprediction cannot be 2
- this.disableclientprediction = 0;
+ this.disableclientprediction = (this.move_qcphysics) ? -1 : 0;
}
viewloc_PlayerPhysics(this);
// conveyors: first fix velocity
if (this.conveyor.state) { this.velocity -= this.conveyor.movedir; }
- MUTATOR_CALLHOOK(PlayerPhysics, this);
+ MUTATOR_CALLHOOK(PlayerPhysics, this, dt);
if (!IS_PLAYER(this)) {
sys_phys_spectator_control(this);
goto end;
}
+ PM_check_slick(this);
+
if (IS_SVQC && !PHYS_FIXANGLE(this)) { this.angles = '0 1 0' * this.v_angle.y; }
if (IS_PLAYER(this)) {
if (IS_ONGROUND(this)) {
if (this.flags & FL_WATERJUMP) {
this.velocity_x = this.movedir.x;
this.velocity_y = this.movedir.y;
- if (time > PHYS_TELEPORT_TIME(this)
- || this.waterlevel == WATERLEVEL_NONE
+ if (this.waterlevel == WATERLEVEL_NONE
+ || time > PHYS_TELEPORT_TIME(this)
|| PHYS_WATERJUMP_TIME(this) <= 0
) {
this.flags &= ~FL_WATERJUMP;
PHYS_TELEPORT_TIME(this) = 0;
PHYS_WATERJUMP_TIME(this) = 0;
}
- } else if (MUTATOR_CALLHOOK(PM_Physics, this, maxspeed_mod)) {
+ } else if (MUTATOR_CALLHOOK(PM_Physics, this, maxspeed_mod, dt)) {
// handled
- } else if (PHYS_MOVETYPE(this) == MOVETYPE_NOCLIP
- || PHYS_MOVETYPE(this) == MOVETYPE_FLY
- || PHYS_MOVETYPE(this) == MOVETYPE_FLY_WORLDONLY
+ } else if (this.move_movetype == MOVETYPE_NOCLIP
+ || this.move_movetype == MOVETYPE_FLY
+ || this.move_movetype == MOVETYPE_FLY_WORLDONLY
|| MUTATOR_CALLHOOK(IsFlying, this)) {
this.com_phys_friction = PHYS_FRICTION(this);
this.com_phys_vel_max = PHYS_MAXSPEED(this) * maxspeed_mod;
this.com_phys_acc_rate = PHYS_ACCELERATE(this) * maxspeed_mod;
+ this.com_phys_friction_air = true;
sys_phys_simulate(this, dt);
+ this.com_phys_friction_air = false;
} else if (this.waterlevel >= WATERLEVEL_SWIMMING) {
- PM_swim(this, maxspeed_mod);
+ this.com_phys_vel_max = PHYS_MAXSPEED(this) * maxspeed_mod;
+ this.com_phys_acc_rate = PHYS_ACCELERATE(this) * maxspeed_mod;
+ this.com_phys_water = true;
+ sys_phys_simulate(this, dt);
+ this.com_phys_water = false;
} else if (time < this.ladder_time) {
this.com_phys_friction = PHYS_FRICTION(this);
this.com_phys_vel_max = PHYS_MAXSPEED(this) * maxspeed_mod;
this.com_phys_gravity = '0 0 -1' * PHYS_GRAVITY(this) * dt;
if (PHYS_ENTGRAVITY(this)) { this.com_phys_gravity *= PHYS_ENTGRAVITY(this); }
this.com_phys_ladder = true;
+ this.com_phys_friction_air = true;
sys_phys_simulate(this, dt);
+ this.com_phys_friction_air = false;
this.com_phys_ladder = false;
this.com_phys_gravity = '0 0 0';
} else if (ITEMS_STAT(this) & IT_USING_JETPACK) {
- PM_jetpack(this, maxspeed_mod);
+ PM_jetpack(this, maxspeed_mod, dt);
} else if (IS_ONGROUND(this)) {
if (!WAS_ONGROUND(this)) {
emit(phys_land, this);
this.com_phys_ground = false;
this.com_phys_gravity = '0 0 0';
} else {
- PM_air(this, buttons_prev, maxspeed_mod);
+ this.com_phys_acc_rate_air = PHYS_AIRACCELERATE(this) * min(maxspeed_mod, 1);
+ this.com_phys_acc_rate_air_stop = PHYS_AIRSTOPACCELERATE(this) * maxspeed_mod;
+ this.com_phys_acc_rate_air_strafe = PHYS_AIRSTRAFEACCELERATE(this) * maxspeed_mod;
+ this.com_phys_vel_max_air_strafe = PHYS_MAXAIRSTRAFESPEED(this) * maxspeed_mod;
+ this.com_phys_vel_max_air = PHYS_MAXAIRSPEED(this) * maxspeed_mod;
+ this.com_phys_vel_max = PHYS_MAXAIRSPEED(this) * min(maxspeed_mod, 1);
+ this.com_phys_air = true;
+ this.com_phys_vel_2d = true;
+ sys_phys_simulate(this, dt);
+ this.com_phys_vel_2d = false;
+ this.com_phys_air = false;
}
LABEL(end)
this.lastclassname = this.classname;
}
+/** for players */
void sys_phys_simulate(entity this, float dt)
{
- const float g = -this.com_phys_gravity.z;
- if (!this.com_phys_ground) {
+ if (!this.com_phys_ground && !this.com_phys_air) {
// noclipping
// flying
// on a spawnfunc_func_ladder
// swimming in spawnfunc_func_water
+ // swimming
UNSET_ONGROUND(this);
- this.velocity_z += g / 2;
- this.velocity = this.velocity * (1 - dt * this.com_phys_friction);
- this.velocity_z += g / 2;
+ if (this.com_phys_friction_air) {
+ const vector g = -this.com_phys_gravity;
+ this.velocity_z += g.z / 2;
+ this.velocity = this.velocity * (1 - dt * this.com_phys_friction);
+ this.velocity_z += g.z / 2;
+ }
}
+ if (this.com_phys_water) {
+ // water jump only in certain situations
+ // this mimics quakeworld code
+ if (this.com_in_jump && this.waterlevel == WATERLEVEL_SWIMMING && this.velocity_z >= -180 && !this.viewloc) {
+ vector yawangles = '0 1 0' * this.v_angle.y;
+ makevectors(yawangles);
+ vector forward = v_forward;
+ vector spot = this.origin + 24 * forward;
+ spot_z += 8;
+ traceline(spot, spot, MOVE_NOMONSTERS, this);
+ if (trace_startsolid) {
+ spot_z += 24;
+ traceline(spot, spot, MOVE_NOMONSTERS, this);
+ if (!trace_startsolid) {
+ this.velocity = forward * 50;
+ this.velocity_z = 310;
+ UNSET_ONGROUND(this);
+ SET_JUMP_HELD(this);
+ }
+ }
+ }
+ }
makevectors(vmul(this.v_angle, (this.com_phys_vel_2d ? '0 1 0' : '1 1 1')));
// wishvel = v_forward * this.movement.x + v_right * this.movement.y + v_up * this.movement.z;
vector wishvel = v_forward * this.movement.x
+ v_right * this.movement.y
+ '0 0 1' * this.movement.z * (this.com_phys_vel_2d ? 0 : 1);
+ if (this.com_phys_water) {
+ if (PHYS_INPUT_BUTTON_CROUCH(this)) {
+ wishvel.z = -PHYS_MAXSPEED(this);
+ }
+ if (this.viewloc) {
+ wishvel.z = -160; // drift anyway
+ } else if (wishvel == '0 0 0') {
+ wishvel = '0 0 -60'; // drift towards bottom
+ }
+ }
if (this.com_phys_ladder) {
if (this.viewloc) {
- wishvel.z = this.oldmovement.x;
+ wishvel.z = this.movement_old.x;
}
if (this.ladder_entity.classname == "func_water") {
float f = vlen(wishvel);
const vector wishdir = normalize(wishvel);
float wishspeed = min(vlen(wishvel), this.com_phys_vel_max);
- if (this.com_phys_ground) {
- if (IS_DUCKED(this)) { wishspeed *= 0.5; }
-
- // apply edge friction
- const float f2 = vlen2(vec2(this.velocity));
- if (f2 > 0) {
- trace_dphitq3surfaceflags = 0;
- tracebox(this.origin, this.mins, this.maxs, this.origin - '0 0 1', MOVE_NOMONSTERS, this);
- // TODO: apply edge friction
- // apply ground friction
- const int realfriction = (trace_dphitq3surfaceflags & Q3SURFACEFLAG_SLICK)
- ? PHYS_FRICTION_SLICK(this)
- : PHYS_FRICTION(this);
-
- float f = sqrt(f2);
- f = 1 - PHYS_INPUT_TIMELENGTH * realfriction
- * ((f < PHYS_STOPSPEED(this)) ? (PHYS_STOPSPEED(this) / f) : 1);
- f = max(0, f);
- this.velocity *= f;
- /*
- Mathematical analysis time!
-
- Our goal is to invert this mess.
-
- For the two cases we get:
- v = v0 * (1 - PHYS_INPUT_TIMELENGTH * (PHYS_STOPSPEED(this) / v0) * PHYS_FRICTION(this))
- = v0 - PHYS_INPUT_TIMELENGTH * PHYS_STOPSPEED(this) * PHYS_FRICTION(this)
- v0 = v + PHYS_INPUT_TIMELENGTH * PHYS_STOPSPEED(this) * PHYS_FRICTION(this)
- and
- v = v0 * (1 - PHYS_INPUT_TIMELENGTH * PHYS_FRICTION(this))
- v0 = v / (1 - PHYS_INPUT_TIMELENGTH * PHYS_FRICTION(this))
-
- These cases would be chosen ONLY if:
- v0 < PHYS_STOPSPEED(this)
- v + PHYS_INPUT_TIMELENGTH * PHYS_STOPSPEED(this) * PHYS_FRICTION(this) < PHYS_STOPSPEED(this)
- v < PHYS_STOPSPEED(this) * (1 - PHYS_INPUT_TIMELENGTH * PHYS_FRICTION(this))
- and, respectively:
- v0 >= PHYS_STOPSPEED(this)
- v / (1 - PHYS_INPUT_TIMELENGTH * PHYS_FRICTION(this)) >= PHYS_STOPSPEED(this)
- v >= PHYS_STOPSPEED(this) * (1 - PHYS_INPUT_TIMELENGTH * PHYS_FRICTION(this))
- */
+ if (this.com_phys_air) {
+ if ((IS_SVQC && time >= PHYS_TELEPORT_TIME(this))
+ || (IS_CSQC && PHYS_WATERJUMP_TIME(this) <= 0)) {
+ // apply air speed limit
+ float airaccelqw = PHYS_AIRACCEL_QW(this);
+ float wishspeed0 = wishspeed;
+ const float maxairspd = this.com_phys_vel_max;
+ wishspeed = min(wishspeed, maxairspd);
+ if (IS_DUCKED(this)) {
+ wishspeed *= 0.5;
+ }
+ float airaccel = this.com_phys_acc_rate_air;
+
+ float accelerating = (this.velocity * wishdir > 0);
+ float wishspeed2 = wishspeed;
+
+ // CPM: air control
+ if (PHYS_AIRSTOPACCELERATE(this)) {
+ vector curdir = normalize(vec2(this.velocity));
+ airaccel += (this.com_phys_acc_rate_air_stop - airaccel) * max(0, -(curdir * wishdir));
+ }
+ // note that for straight forward jumping:
+ // step = accel * dt * wishspeed0;
+ // accel = bound(0, wishspeed - vel_xy_current, step) * accelqw + step * (1 - accelqw);
+ // -->
+ // dv/dt = accel * maxspeed (when slow)
+ // dv/dt = accel * maxspeed * (1 - accelqw) (when fast)
+ // log dv/dt = logaccel + logmaxspeed (when slow)
+ // log dv/dt = logaccel + logmaxspeed + log(1 - accelqw) (when fast)
+ float strafity = IsMoveInDirection(this.movement, -90) + IsMoveInDirection(this.movement, +90); // if one is nonzero, other is always zero
+ if (PHYS_MAXAIRSTRAFESPEED(this)) {
+ wishspeed =
+ min(wishspeed,
+ GeomLerp(this.com_phys_vel_max_air, strafity, this.com_phys_vel_max_air_strafe));
+ }
+ if (PHYS_AIRSTRAFEACCELERATE(this)) {
+ airaccel = GeomLerp(airaccel, strafity, this.com_phys_acc_rate_air_strafe);
+ }
+ if (PHYS_AIRSTRAFEACCEL_QW(this)) {
+ airaccelqw =
+ (((strafity > 0.5 ? PHYS_AIRSTRAFEACCEL_QW(this) : PHYS_AIRACCEL_QW(this)) >= 0) ? +1 : -1)
+ *
+ (1 - GeomLerp(1 - fabs(PHYS_AIRACCEL_QW(this)), strafity, 1 - fabs(PHYS_AIRSTRAFEACCEL_QW(this))));
+ }
+ // !CPM
+
+ if (PHYS_WARSOWBUNNY_TURNACCEL(this) && accelerating && this.movement.y == 0 && this.movement.x != 0) {
+ PM_AirAccelerate(this, dt, wishdir, wishspeed2);
+ } else {
+ float sidefric = maxairspd ? (PHYS_AIRACCEL_SIDEWAYS_FRICTION(this) / maxairspd) : 0;
+ PM_Accelerate(this, dt, wishdir, wishspeed, wishspeed0, airaccel, airaccelqw,
+ PHYS_AIRACCEL_QW_STRETCHFACTOR(this), sidefric, PHYS_AIRSPEEDLIMIT_NONQW(this));
+ }
+
+ if (PHYS_AIRCONTROL(this)) {
+ CPM_PM_Aircontrol(this, dt, wishdir, wishspeed2);
+ }
}
- const float addspeed = wishspeed - this.velocity * wishdir;
- if (addspeed > 0) {
- const float accelspeed = min(PHYS_ACCELERATE(this) * PHYS_INPUT_TIMELENGTH * wishspeed, addspeed);
- this.velocity += accelspeed * wishdir;
+ } else {
+ if (this.com_phys_ground && IS_DUCKED(this)) { wishspeed *= 0.5; }
+ if (this.com_phys_water) {
+ wishspeed *= 0.7;
+
+ // if (PHYS_WATERJUMP_TIME(this) <= 0) // TODO: use
+ {
+ // water friction
+ float f = 1 - dt * PHYS_FRICTION(this);
+ f = min(max(0, f), 1);
+ this.velocity *= f;
+
+ f = wishspeed - this.velocity * wishdir;
+ if (f > 0) {
+ float accelspeed = min(PHYS_ACCELERATE(this) * dt * wishspeed, f);
+ this.velocity += accelspeed * wishdir;
+ }
+
+ // holding jump button swims upward slowly
+ if (this.com_in_jump && !this.viewloc) {
+ // was:
+ // lava: 50
+ // slime: 80
+ // water: 100
+ // idea: double those
+ this.velocity_z = 200;
+ if (this.waterlevel >= WATERLEVEL_SUBMERGED) {
+ this.velocity_z = PHYS_MAXSPEED(this) * 0.7;
+ }
+ }
+ }
+ if (this.viewloc) {
+ const float addspeed = wishspeed - this.velocity * wishdir;
+ if (addspeed > 0) {
+ const float accelspeed = min(PHYS_ACCELERATE(this) * dt * wishspeed, addspeed);
+ this.velocity += accelspeed * wishdir;
+ }
+ } else {
+ // water acceleration
+ PM_Accelerate(this, dt, wishdir, wishspeed, wishspeed, this.com_phys_acc_rate, 1, 0, 0, 0);
+ }
+ return;
}
- if (IS_CSQC && vdist(this.velocity, >, 0)) {
- PM_ClientMovement_Move(this);
+ if (this.com_phys_ground) {
+ // apply edge friction
+ const float f2 = vlen2(vec2(this.velocity));
+ if (f2 > 0) {
+ trace_dphitq3surfaceflags = 0;
+ tracebox(this.origin, this.mins, this.maxs, this.origin - '0 0 1', MOVE_NOMONSTERS, this);
+ // TODO: apply edge friction
+ // apply ground friction
+ const int realfriction = (trace_dphitq3surfaceflags & Q3SURFACEFLAG_SLICK)
+ ? PHYS_FRICTION_SLICK(this)
+ : PHYS_FRICTION(this);
+
+ float f = sqrt(f2);
+ f = 1 - dt * realfriction
+ * ((f < PHYS_STOPSPEED(this)) ? (PHYS_STOPSPEED(this) / f) : 1);
+ f = max(0, f);
+ this.velocity *= f;
+ /*
+ Mathematical analysis time!
+
+ Our goal is to invert this mess.
+
+ For the two cases we get:
+ v = v0 * (1 - dt * (PHYS_STOPSPEED(this) / v0) * PHYS_FRICTION(this))
+ = v0 - dt * PHYS_STOPSPEED(this) * PHYS_FRICTION(this)
+ v0 = v + dt * PHYS_STOPSPEED(this) * PHYS_FRICTION(this)
+ and
+ v = v0 * (1 - dt * PHYS_FRICTION(this))
+ v0 = v / (1 - dt * PHYS_FRICTION(this))
+
+ These cases would be chosen ONLY if:
+ v0 < PHYS_STOPSPEED(this)
+ v + dt * PHYS_STOPSPEED(this) * PHYS_FRICTION(this) < PHYS_STOPSPEED(this)
+ v < PHYS_STOPSPEED(this) * (1 - dt * PHYS_FRICTION(this))
+ and, respectively:
+ v0 >= PHYS_STOPSPEED(this)
+ v / (1 - dt * PHYS_FRICTION(this)) >= PHYS_STOPSPEED(this)
+ v >= PHYS_STOPSPEED(this) * (1 - dt * PHYS_FRICTION(this))
+ */
+ }
+ const float addspeed = wishspeed - this.velocity * wishdir;
+ if (addspeed > 0) {
+ const float accelspeed = min(PHYS_ACCELERATE(this) * dt * wishspeed, addspeed);
+ this.velocity += accelspeed * wishdir;
+ }
+ return;
+ }
+
+ if (IS_CSQC ? PHYS_WATERJUMP_TIME(this) <= 0 : time >= PHYS_TELEPORT_TIME(this)) {
+ PM_Accelerate(this, dt, wishdir, wishspeed, wishspeed, this.com_phys_acc_rate, 1, 0, 0, 0);
}
- return;
}
+}
+
+.entity groundentity;
+/** for other entities */
+void sys_phys_simulate_simple(entity this, float dt)
+{
+ vector mn = this.mins;
+ vector mx = this.maxs;
+
+ vector g = '0 0 0';
+ if (this.com_phys_gravity_factor && !g) g = '0 0 -1' * PHYS_GRAVITY(NULL);
+
+ vector acc = this.com_phys_acc;
+ vector vel = this.com_phys_vel;
+ vector pos = this.com_phys_pos;
+
+ // SV_Physics_Toss
+
+ vel += g * dt;
- if (IS_CSQC || time >= PHYS_TELEPORT_TIME(this)) {
- PM_Accelerate(this, wishdir, wishspeed, wishspeed, this.com_phys_acc_rate, 1, 0, 0, 0);
+ this.angles += dt * this.avelocity;
+ float movetime = dt;
+ for (int i = 0; i < MAX_CLIP_PLANES && movetime > 0; i++) {
+ vector push = vel * movetime;
+ vector p0 = pos;
+ vector p1 = p0 + push;
+ // SV_PushEntity
+ tracebox(p0, mn, mx, p1, MOVE_NORMAL, this);
+ if (!trace_startsolid) {
+ bool hit = trace_fraction < 1;
+ pos = trace_endpos;
+ entity ent = trace_ent;
+ // SV_LinkEdict_TouchAreaGrid
+ if (this.solid != SOLID_NOT) {
+ FOREACH_ENTITY_RADIUS_ORDERED(0.5 * (this.absmin + this.absmax), 0.5 * vlen(this.absmax - this.absmin), true, {
+ if (it.solid != SOLID_TRIGGER || it == this) continue;
+ if (gettouch(it) && boxesoverlap(it.absmin, it.absmax, this.absmin, this.absmax)) {
+ // SV_LinkEdict_TouchAreaGrid_Call
+ trace_allsolid = false;
+ trace_startsolid = false;
+ trace_fraction = 1;
+ trace_inwater = false;
+ trace_inopen = true;
+ trace_endpos = it.origin;
+ trace_plane_normal = '0 0 1';
+ trace_plane_dist = 0;
+ trace_ent = this;
+ trace_dpstartcontents = 0;
+ trace_dphitcontents = 0;
+ trace_dphitq3surfaceflags = 0;
+ trace_dphittexturename = string_null;
+ gettouch(it)(this, it);
+ vel = this.velocity;
+ }
+ });
+ }
+ if (hit && this.solid >= SOLID_TRIGGER && (!IS_ONGROUND(this) || this.groundentity != ent)) {
+ // SV_Impact (ent, trace);
+ tracebox(p0, mn, mx, p1, MOVE_NORMAL, this);
+ void(entity, entity) touched = gettouch(this);
+ if (touched && this.solid != SOLID_NOT) {
+ touched(ent, this);
+ }
+ void(entity, entity) touched2 = gettouch(ent);
+ if (this && ent && touched2 && ent.solid != SOLID_NOT) {
+ trace_endpos = ent.origin;
+ trace_plane_normal *= -1;
+ trace_plane_dist *= -1;
+ trace_ent = this;
+ trace_dpstartcontents = 0;
+ trace_dphitcontents = 0;
+ trace_dphitq3surfaceflags = 0;
+ trace_dphittexturename = string_null;
+ touched2(this, ent);
+ }
+ }
+ }
+ // end SV_PushEntity
+ if (wasfreed(this)) { return; }
+ tracebox(p0, mn, mx, p1, MOVE_NORMAL, this);
+ if (trace_fraction == 1) { break; }
+ movetime *= 1 - min(1, trace_fraction);
+ ClipVelocity(vel, trace_plane_normal, vel, 1);
}
- PM_ClientMovement_Move(this);
+
+ this.com_phys_acc = acc;
+ this.com_phys_vel = vel;
+ this.com_phys_pos = pos;
+ setorigin(this, this.com_phys_pos);
+}
+
+void sys_phys_update_single(entity this)
+{
+ sys_phys_simulate_simple(this, frametime);
}