return autocvar_g_physics_clientselect && strhasword(autocvar_g_physics_clientselect_options, thecvar);
}
-float Physics_ClientOption(entity this, string option)
+float Physics_ClientOption(entity this, string option, float defaultval)
{
if(Physics_Valid(this.cvar_cl_physics))
{
if(cvar_type(s) & CVAR_TYPEFLAG_EXISTS)
return cvar(s);
}
- return cvar(strcat("sv_", option));
+ return defaultval;
}
void Physics_UpdateStats(entity this, float maxspd_mod)
{
- STAT(MOVEVARS_AIRACCEL_QW, this) = AdjustAirAccelQW(Physics_ClientOption(this, "airaccel_qw"), maxspd_mod);
- STAT(MOVEVARS_AIRSTRAFEACCEL_QW, this) = (Physics_ClientOption(this, "airstrafeaccel_qw"))
- ? AdjustAirAccelQW(Physics_ClientOption(this, "airstrafeaccel_qw"), maxspd_mod)
+ STAT(MOVEVARS_AIRACCEL_QW, this) = AdjustAirAccelQW(Physics_ClientOption(this, "airaccel_qw", autocvar_sv_airaccel_qw), maxspd_mod);
+ STAT(MOVEVARS_AIRSTRAFEACCEL_QW, this) = (Physics_ClientOption(this, "airstrafeaccel_qw", autocvar_sv_airstrafeaccel_qw))
+ ? AdjustAirAccelQW(Physics_ClientOption(this, "airstrafeaccel_qw", autocvar_sv_airstrafeaccel_qw), maxspd_mod)
: 0;
- STAT(MOVEVARS_AIRSPEEDLIMIT_NONQW, this) = Physics_ClientOption(this, "airspeedlimit_nonqw") * maxspd_mod;
- STAT(MOVEVARS_MAXSPEED, this) = Physics_ClientOption(this, "maxspeed") * maxspd_mod; // also slow walking
+ STAT(MOVEVARS_AIRSPEEDLIMIT_NONQW, this) = Physics_ClientOption(this, "airspeedlimit_nonqw", autocvar_sv_airspeedlimit_nonqw) * maxspd_mod;
+ STAT(MOVEVARS_MAXSPEED, this) = Physics_ClientOption(this, "maxspeed", autocvar_sv_maxspeed) * maxspd_mod; // also slow walking
// old stats
// fix some new settings
- STAT(MOVEVARS_AIRACCEL_QW_STRETCHFACTOR, this) = Physics_ClientOption(this, "airaccel_qw_stretchfactor");
- STAT(MOVEVARS_MAXAIRSTRAFESPEED, this) = Physics_ClientOption(this, "maxairstrafespeed");
- STAT(MOVEVARS_MAXAIRSPEED, this) = Physics_ClientOption(this, "maxairspeed");
- STAT(MOVEVARS_AIRSTRAFEACCELERATE, this) = Physics_ClientOption(this, "airstrafeaccelerate");
- STAT(MOVEVARS_WARSOWBUNNY_TURNACCEL, this) = Physics_ClientOption(this, "warsowbunny_turnaccel");
- STAT(MOVEVARS_AIRACCEL_SIDEWAYS_FRICTION, this) = Physics_ClientOption(this, "airaccel_sideways_friction");
- STAT(MOVEVARS_AIRCONTROL, this) = Physics_ClientOption(this, "aircontrol");
- STAT(MOVEVARS_AIRCONTROL_POWER, this) = Physics_ClientOption(this, "aircontrol_power");
- STAT(MOVEVARS_AIRCONTROL_PENALTY, this) = Physics_ClientOption(this, "aircontrol_penalty");
- STAT(MOVEVARS_WARSOWBUNNY_AIRFORWARDACCEL, this) = Physics_ClientOption(this, "warsowbunny_airforwardaccel");
- STAT(MOVEVARS_WARSOWBUNNY_TOPSPEED, this) = Physics_ClientOption(this, "warsowbunny_topspeed");
- STAT(MOVEVARS_WARSOWBUNNY_ACCEL, this) = Physics_ClientOption(this, "warsowbunny_accel");
- STAT(MOVEVARS_WARSOWBUNNY_BACKTOSIDERATIO, this) = Physics_ClientOption(this, "warsowbunny_backtosideratio");
- STAT(MOVEVARS_FRICTION, this) = Physics_ClientOption(this, "friction");
- STAT(MOVEVARS_ACCELERATE, this) = Physics_ClientOption(this, "accelerate");
- STAT(MOVEVARS_STOPSPEED, this) = Physics_ClientOption(this, "stopspeed");
- STAT(MOVEVARS_AIRACCELERATE, this) = Physics_ClientOption(this, "airaccelerate");
- STAT(MOVEVARS_AIRSTOPACCELERATE, this) = Physics_ClientOption(this, "airstopaccelerate");
- STAT(MOVEVARS_JUMPVELOCITY, this) = Physics_ClientOption(this, "jumpvelocity");
- STAT(MOVEVARS_TRACK_CANJUMP, this) = Physics_ClientOption(this, "track_canjump");
+ STAT(MOVEVARS_AIRACCEL_QW_STRETCHFACTOR, this) = Physics_ClientOption(this, "airaccel_qw_stretchfactor", autocvar_sv_airaccel_qw_stretchfactor);
+ STAT(MOVEVARS_MAXAIRSTRAFESPEED, this) = Physics_ClientOption(this, "maxairstrafespeed", autocvar_sv_maxairstrafespeed);
+ STAT(MOVEVARS_MAXAIRSPEED, this) = Physics_ClientOption(this, "maxairspeed", autocvar_sv_maxairspeed);
+ STAT(MOVEVARS_AIRSTRAFEACCELERATE, this) = Physics_ClientOption(this, "airstrafeaccelerate", autocvar_sv_airstrafeaccelerate);
+ STAT(MOVEVARS_WARSOWBUNNY_TURNACCEL, this) = Physics_ClientOption(this, "warsowbunny_turnaccel", autocvar_sv_warsowbunny_turnaccel);
+ STAT(MOVEVARS_AIRACCEL_SIDEWAYS_FRICTION, this) = Physics_ClientOption(this, "airaccel_sideways_friction", autocvar_sv_airaccel_sideways_friction);
+ STAT(MOVEVARS_AIRCONTROL, this) = Physics_ClientOption(this, "aircontrol", autocvar_sv_aircontrol);
+ STAT(MOVEVARS_AIRCONTROL_POWER, this) = Physics_ClientOption(this, "aircontrol_power", autocvar_sv_aircontrol_power);
+ STAT(MOVEVARS_AIRCONTROL_PENALTY, this) = Physics_ClientOption(this, "aircontrol_penalty", autocvar_sv_aircontrol_penalty);
+ STAT(MOVEVARS_WARSOWBUNNY_AIRFORWARDACCEL, this) = Physics_ClientOption(this, "warsowbunny_airforwardaccel", autocvar_sv_warsowbunny_airforwardaccel);
+ STAT(MOVEVARS_WARSOWBUNNY_TOPSPEED, this) = Physics_ClientOption(this, "warsowbunny_topspeed", autocvar_sv_warsowbunny_topspeed);
+ STAT(MOVEVARS_WARSOWBUNNY_ACCEL, this) = Physics_ClientOption(this, "warsowbunny_accel", autocvar_sv_warsowbunny_accel);
+ STAT(MOVEVARS_WARSOWBUNNY_BACKTOSIDERATIO, this) = Physics_ClientOption(this, "warsowbunny_backtosideratio", autocvar_sv_warsowbunny_backtosideratio);
+ STAT(MOVEVARS_FRICTION, this) = Physics_ClientOption(this, "friction", autocvar_sv_friction);
+ STAT(MOVEVARS_ACCELERATE, this) = Physics_ClientOption(this, "accelerate", autocvar_sv_accelerate);
+ STAT(MOVEVARS_STOPSPEED, this) = Physics_ClientOption(this, "stopspeed", autocvar_sv_stopspeed);
+ STAT(MOVEVARS_AIRACCELERATE, this) = Physics_ClientOption(this, "airaccelerate", autocvar_sv_airaccelerate);
+ STAT(MOVEVARS_AIRSTOPACCELERATE, this) = Physics_ClientOption(this, "airstopaccelerate", autocvar_sv_airstopaccelerate);
+ STAT(MOVEVARS_JUMPVELOCITY, this) = Physics_ClientOption(this, "jumpvelocity", autocvar_sv_jumpvelocity);
+ STAT(MOVEVARS_TRACK_CANJUMP, this) = Physics_ClientOption(this, "track_canjump", autocvar_sv_track_canjump);
}
#endif
return ang > 1 ? 0 : ang < -1 ? 0 : 1 - fabs(ang);
}
-float GeomLerp(float a, float lerp, float b)
+float GeomLerp(float a, float _lerp, float b)
{
- return a == 0 ? (lerp < 1 ? 0 : b)
- : b == 0 ? (lerp > 0 ? 0 : a)
- : a * pow(fabs(b / a), lerp);
+ return a == 0 ? (_lerp < 1 ? 0 : b)
+ : b == 0 ? (_lerp > 0 ? 0 : a)
+ : a * pow(fabs(b / a), _lerp);
}
-#define unstick_offsets(X) \
-/* 1 no nudge (just return the original if this test passes) */ \
- X(' 0.000 0.000 0.000') \
-/* 6 simple nudges */ \
- X(' 0.000 0.000 0.125') X('0.000 0.000 -0.125') \
- X('-0.125 0.000 0.000') X('0.125 0.000 0.000') \
- X(' 0.000 -0.125 0.000') X('0.000 0.125 0.000') \
-/* 4 diagonal flat nudges */ \
- X('-0.125 -0.125 0.000') X('0.125 -0.125 0.000') \
- X('-0.125 0.125 0.000') X('0.125 0.125 0.000') \
-/* 8 diagonal upward nudges */ \
- X('-0.125 0.000 0.125') X('0.125 0.000 0.125') \
- X(' 0.000 -0.125 0.125') X('0.000 0.125 0.125') \
- X('-0.125 -0.125 0.125') X('0.125 -0.125 0.125') \
- X('-0.125 0.125 0.125') X('0.125 0.125 0.125') \
-/* 8 diagonal downward nudges */ \
- X('-0.125 0.000 -0.125') X('0.125 0.000 -0.125') \
- X(' 0.000 -0.125 -0.125') X('0.000 0.125 -0.125') \
- X('-0.125 -0.125 -0.125') X('0.125 -0.125 -0.125') \
- X('-0.125 0.125 -0.125') X('0.125 0.125 -0.125') \
-/**/
-
-void PM_ClientMovement_Unstick(entity this)
-{
- #define X(unstick_offset) \
- { \
- vector neworigin = unstick_offset + this.origin; \
- tracebox(neworigin, STAT(PL_CROUCH_MIN, NULL), STAT(PL_CROUCH_MAX, NULL), neworigin, MOVE_NORMAL, this); \
- if (!trace_startsolid) \
- { \
- setorigin(this, neworigin); \
- return; \
- } \
- }
- unstick_offsets(X);
- #undef X
-}
-
-void PM_ClientMovement_UpdateStatus(entity this, bool ground)
+void PM_ClientMovement_UpdateStatus(entity this)
{
#ifdef CSQC
if(!IS_PLAYER(this))
return;
- // make sure player is not stuck
- if(autocvar_cl_movement == 3)
- PM_ClientMovement_Unstick(this);
// set crouched
bool do_crouch = PHYS_INPUT_BUTTON_CROUCH(this);
if(this.hook && !wasfreed(this.hook))
do_crouch = false;
+ if(this.waterlevel >= WATERLEVEL_SWIMMING)
+ do_crouch = false;
if(hud != HUD_NORMAL)
do_crouch = false;
if(STAT(FROZEN, this))
do_crouch = false;
- if((activeweapon == WEP_SHOCKWAVE || activeweapon == WEP_SHOTGUN) && viewmodel.animstate_startframe == viewmodel.anim_fire2_x && time < viewmodel.weapon_nextthink)
- do_crouch = false;
if (do_crouch)
{
}
}
- // set onground
- vector origin1 = this.origin + '0 0 1';
- vector origin2 = this.origin - '0 0 1';
-
- if (ground && autocvar_cl_movement == 3)
- {
- tracebox(origin1, this.mins, this.maxs, origin2, MOVE_NORMAL, this);
- if (trace_fraction < 1.0 && trace_plane_normal.z > 0.7)
- {
- SET_ONGROUND(this);
-
- // this code actually "predicts" an impact; so let's clip velocity first
- this.velocity -= this.velocity * trace_plane_normal * trace_plane_normal;
- }
- else
- UNSET_ONGROUND(this);
- }
-
- if(autocvar_cl_movement == 3)
- {
- // set watertype/waterlevel
- origin1 = this.origin;
- origin1.z += this.mins_z + 1;
- this.waterlevel = WATERLEVEL_NONE;
-
- int thepoint = pointcontents(origin1);
-
- this.watertype = (thepoint == CONTENT_WATER || thepoint == CONTENT_LAVA || thepoint == CONTENT_SLIME);
-
- if (this.watertype)
- {
- this.waterlevel = WATERLEVEL_WETFEET;
- origin1.z = this.origin.z + (this.mins.z + this.maxs.z) * 0.5;
- thepoint = pointcontents(origin1);
- if (thepoint == CONTENT_WATER || thepoint == CONTENT_LAVA || thepoint == CONTENT_SLIME)
- {
- this.waterlevel = WATERLEVEL_SWIMMING;
- origin1.z = this.origin.z + 22;
- thepoint = pointcontents(origin1);
- if (thepoint == CONTENT_WATER || thepoint == CONTENT_LAVA || thepoint == CONTENT_SLIME)
- this.waterlevel = WATERLEVEL_SUBMERGED;
- }
- }
- }
-
if (IS_ONGROUND(this) || this.velocity.z <= 0 || PHYS_WATERJUMP_TIME(this) <= 0)
PHYS_WATERJUMP_TIME(this) = 0;
#endif
}
-void PM_ClientMovement_Move(entity this)
-{
-#ifdef CSQC
-
- PM_ClientMovement_UpdateStatus(this, false);
- if(autocvar_cl_movement == 1)
- return;
-
- int bump;
- float t;
- float f;
- vector neworigin;
- vector currentorigin2;
- vector neworigin2;
- vector primalvelocity;
-
- vector trace1_endpos = '0 0 0';
- vector trace2_endpos = '0 0 0';
- vector trace3_endpos = '0 0 0';
- float trace1_fraction = 0;
- float trace2_fraction = 0;
- float trace3_fraction = 0;
- vector trace1_plane_normal = '0 0 0';
- vector trace2_plane_normal = '0 0 0';
- vector trace3_plane_normal = '0 0 0';
-
- primalvelocity = this.velocity;
- for(bump = 0, t = PHYS_INPUT_TIMELENGTH; bump < 8 && (this.velocity * this.velocity) > 0; bump++)
- {
- neworigin = this.origin + t * this.velocity;
- tracebox(this.origin, this.mins, this.maxs, neworigin, MOVE_NORMAL, this);
- trace1_endpos = trace_endpos;
- trace1_fraction = trace_fraction;
- trace1_plane_normal = trace_plane_normal;
- if(trace1_fraction < 1 && trace1_plane_normal_z == 0)
- {
- // may be a step or wall, try stepping up
- // first move forward at a higher level
- currentorigin2 = this.origin;
- currentorigin2_z += PHYS_STEPHEIGHT(this);
- neworigin2 = neworigin;
- neworigin2_z += PHYS_STEPHEIGHT(this);
- tracebox(currentorigin2, this.mins, this.maxs, neworigin2, MOVE_NORMAL, this);
- trace2_endpos = trace_endpos;
- trace2_fraction = trace_fraction;
- trace2_plane_normal = trace_plane_normal;
- if(!trace_startsolid)
- {
- // then move down from there
- currentorigin2 = trace2_endpos;
- neworigin2 = trace2_endpos;
- neworigin2_z = this.origin_z;
- tracebox(currentorigin2, this.mins, this.maxs, neworigin2, MOVE_NORMAL, this);
- trace3_endpos = trace_endpos;
- trace3_fraction = trace_fraction;
- trace3_plane_normal = trace_plane_normal;
- // accept the new trace if it made some progress
- if(fabs(trace3_endpos_x - trace1_endpos_x) >= 0.03125 || fabs(trace3_endpos_y - trace1_endpos_y) >= 0.03125)
- {
- trace1_endpos = trace2_endpos;
- trace1_fraction = trace2_fraction;
- trace1_plane_normal = trace2_plane_normal;
- trace1_endpos = trace3_endpos;
- }
- }
- }
-
- // check if it moved at all
- if(trace1_fraction >= 0.001)
- setorigin(this, trace1_endpos);
-
- // check if it moved all the way
- if(trace1_fraction == 1)
- break;
-
- // this is only really needed for nogravityonground combined with gravityunaffectedbyticrate
- // <LordHavoc> I'm pretty sure I commented it out solely because it seemed redundant
- // this got commented out in a change that supposedly makes the code match QW better
- // so if this is broken, maybe put it in an if(cls.protocol != PROTOCOL_QUAKEWORLD) block
- if(trace1_plane_normal_z > 0.7)
- SET_ONGROUND(this);
-
- t -= t * trace1_fraction;
-
- f = (this.velocity * trace1_plane_normal);
- this.velocity = this.velocity + -f * trace1_plane_normal;
- }
- if(PHYS_TELEPORT_TIME(this) > 0)
- this.velocity = primalvelocity;
-#endif
-}
-
-void CPM_PM_Aircontrol(entity this, vector wishdir, float wishspeed)
+void CPM_PM_Aircontrol(entity this, float dt, vector wishdir, float wishspeed)
{
float k = 32 * (2 * IsMoveInDirection(this.movement, 0) - 1);
if (k <= 0)
if (dot > 0) // we can't change direction while slowing down
{
- k *= pow(dot, PHYS_AIRCONTROL_POWER(this)) * PHYS_INPUT_TIMELENGTH;
+ k *= pow(dot, PHYS_AIRCONTROL_POWER(this)) * dt;
xyspeed = max(0, xyspeed - PHYS_AIRCONTROL_PENALTY(this) * sqrt(max(0, 1 - dot*dot)) * k/32);
k *= PHYS_AIRCONTROL(this);
this.velocity = normalize(this.velocity * xyspeed + wishdir * k);
// sv_airaccel_sideways_friction 0
// prvm_globalset server speedclamp_mode 1
// (or 2)
-void PM_Accelerate(entity this, vector wishdir, float wishspeed, float wishspeed0, float accel, float accelqw, float stretchfactor, float sidefric, float speedlimit)
+void PM_Accelerate(entity this, float dt, vector wishdir, float wishspeed, float wishspeed0, float accel, float accelqw, float stretchfactor, float sidefric, float speedlimit)
{
float speedclamp = stretchfactor > 0 ? stretchfactor
: accelqw < 0 ? 1 // full clamping, no stretch
vector vel_xy = vec2(this.velocity);
vector vel_perpend = vel_xy - vel_straight * wishdir;
- float step = accel * PHYS_INPUT_TIMELENGTH * wishspeed0;
+ float step = accel * dt * wishspeed0;
float vel_xy_current = vlen(vel_xy);
if (speedlimit)
if (sidefric < 0 && (vel_perpend*vel_perpend))
// negative: only apply so much sideways friction to stay below the speed you could get by "braking"
{
- float f = max(0, 1 + PHYS_INPUT_TIMELENGTH * wishspeed * sidefric);
+ float f = max(0, 1 + dt * wishspeed * sidefric);
float themin = (vel_xy_backward * vel_xy_backward - vel_straight * vel_straight) / (vel_perpend * vel_perpend);
// assume: themin > 1
// vel_xy_backward*vel_xy_backward - vel_straight*vel_straight > vel_perpend*vel_perpend
}
}
else
- vel_perpend *= max(0, 1 - PHYS_INPUT_TIMELENGTH * wishspeed * sidefric);
+ vel_perpend *= max(0, 1 - dt * wishspeed * sidefric);
vel_xy = vel_straight * wishdir + vel_perpend;
this.velocity = vel_xy + vel_z * '0 0 1';
}
-void PM_AirAccelerate(entity this, vector wishdir, float wishspeed)
+void PM_AirAccelerate(entity this, float dt, vector wishdir, float wishspeed)
{
if (wishspeed == 0)
return;
float curspeed = vlen(curvel);
if (wishspeed > curspeed * 1.01)
- wishspeed = min(wishspeed, curspeed + PHYS_WARSOWBUNNY_AIRFORWARDACCEL(this) * PHYS_MAXSPEED(this) * PHYS_INPUT_TIMELENGTH);
+ wishspeed = min(wishspeed, curspeed + PHYS_WARSOWBUNNY_AIRFORWARDACCEL(this) * PHYS_MAXSPEED(this) * dt);
else
{
float f = max(0, (PHYS_WARSOWBUNNY_TOPSPEED(this) - curspeed) / (PHYS_WARSOWBUNNY_TOPSPEED(this) - PHYS_MAXSPEED(this)));
- wishspeed = max(curspeed, PHYS_MAXSPEED(this)) + PHYS_WARSOWBUNNY_ACCEL(this) * f * PHYS_MAXSPEED(this) * PHYS_INPUT_TIMELENGTH;
+ wishspeed = max(curspeed, PHYS_MAXSPEED(this)) + PHYS_WARSOWBUNNY_ACCEL(this) * f * PHYS_MAXSPEED(this) * dt;
}
vector wishvel = wishdir * wishspeed;
vector acceldir = wishvel - curvel;
float addspeed = vlen(acceldir);
acceldir = normalize(acceldir);
- float accelspeed = min(addspeed, PHYS_WARSOWBUNNY_TURNACCEL(this) * PHYS_MAXSPEED(this) * PHYS_INPUT_TIMELENGTH);
+ float accelspeed = min(addspeed, PHYS_WARSOWBUNNY_TURNACCEL(this) * PHYS_MAXSPEED(this) * dt);
if (PHYS_WARSOWBUNNY_BACKTOSIDERATIO(this) < 1)
{
{
#ifdef SVQC
if(autocvar_speedmeter)
- LOG_TRACE(strcat("landing velocity: ", vtos(this.velocity), " (abs: ", ftos(vlen(this.velocity)), ")\n"));
+ LOG_TRACE("landing velocity: ", vtos(this.velocity), " (abs: ", ftos(vlen(this.velocity)), ")");
#endif
if(this.lastground < time - 0.3)
{
}
#ifdef SVQC
if(this.jumppadcount > 1)
- LOG_TRACE(strcat(ftos(this.jumppadcount), "x jumppad combo\n"));
+ LOG_TRACE(ftos(this.jumppadcount), "x jumppad combo");
this.jumppadcount = 0;
#endif
}
animdecide_setaction(this, ANIMACTION_JUMP, true);
if (autocvar_g_jump_grunt)
- PlayerSound(this, playersound_jump, CH_PLAYER, VOICETYPE_PLAYERSOUND);
+ PlayerSound(this, playersound_jump, CH_PLAYER, VOL_BASE, VOICETYPE_PLAYERSOUND);
#endif
return true;
}
#endif
}
-void PM_check_punch(entity this)
+void PM_check_punch(entity this, float dt)
{
#ifdef SVQC
if (this.punchangle != '0 0 0')
{
- float f = vlen(this.punchangle) - 10 * PHYS_INPUT_TIMELENGTH;
+ float f = vlen(this.punchangle) - 10 * dt;
if (f > 0)
this.punchangle = normalize(this.punchangle) * f;
else
if (this.punchvector != '0 0 0')
{
- float f = vlen(this.punchvector) - 30 * PHYS_INPUT_TIMELENGTH;
+ float f = vlen(this.punchvector) - 30 * dt;
if (f > 0)
this.punchvector = normalize(this.punchvector) * f;
else
entity gs = (trace_dphitq3surfaceflags & Q3SURFACEFLAG_METALSTEPS)
? GS_FALL_METAL
: GS_FALL;
- GlobalSound(this, gs, CH_PLAYER, VOICETYPE_PLAYERSOUND);
+ float vol = ((IS_DUCKED(this)) ? VOL_MUFFLED : VOL_BASE);
+ GlobalSound(this, gs, CH_PLAYER, vol, VOICETYPE_PLAYERSOUND);
#endif
}
entity gs = (trace_dphitq3surfaceflags & Q3SURFACEFLAG_METALSTEPS)
? GS_STEP_METAL
: GS_STEP;
- GlobalSound(this, gs, CH_PLAYER, VOICETYPE_PLAYERSOUND);
+ GlobalSound(this, gs, CH_PLAYER, VOL_BASE, VOICETYPE_PLAYERSOUND);
}
#endif
}
#endif
}
-void PM_swim(entity this, float maxspd_mod)
-{
- // swimming
- UNSET_ONGROUND(this);
-
- float jump = PHYS_INPUT_BUTTON_JUMP(this);
- // water jump only in certain situations
- // this mimics quakeworld code
- if (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;
- #ifdef CSQC
- PHYS_WATERJUMP_TIME(this) = 2;
- #endif
- UNSET_ONGROUND(this);
- SET_JUMP_HELD(this);
- }
- }
- }
- makevectors(this.v_angle);
- //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;
- if(this.viewloc)
- wishvel.z = -160; // drift anyway
- else if (wishvel == '0 0 0')
- wishvel = '0 0 -60'; // drift towards bottom
-
-
- vector wishdir = normalize(wishvel);
- float wishspeed = min(vlen(wishvel), PHYS_MAXSPEED(this) * maxspd_mod) * 0.7;
-
- if (IS_DUCKED(this))
- wishspeed *= 0.5;
-
-// if (PHYS_WATERJUMP_TIME(this) <= 0) // TODO: use
- {
- // water friction
- float f = 1 - PHYS_INPUT_TIMELENGTH * 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) * PHYS_INPUT_TIMELENGTH * wishspeed, f);
- this.velocity += accelspeed * wishdir;
- }
-
- // holding jump button swims upward slowly
- if (jump && !this.viewloc)
- {
-#if 0
- if (this.watertype & CONTENT_LAVA)
- this.velocity_z = 50;
- else if (this.watertype & CONTENT_SLIME)
- this.velocity_z = 80;
- else
- {
- if (IS_NEXUIZ_DERIVED(gamemode))
-#endif
- this.velocity_z = 200;
-#if 0
- else
- this.velocity_z = 100;
- }
-#endif
- }
- }
- if(this.viewloc)
- {
- 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
- {
- // water acceleration
- PM_Accelerate(this, wishdir, wishspeed, wishspeed, PHYS_ACCELERATE(this) * maxspd_mod, 1, 0, 0, 0);
- PM_ClientMovement_Move(this);
- }
-}
-
.vector oldmovement;
-void PM_ladder(entity this, float maxspd_mod)
-{
- // on a spawnfunc_func_ladder or swimming in spawnfunc_func_water
- UNSET_ONGROUND(this);
- float g;
- g = PHYS_GRAVITY(this) * PHYS_INPUT_TIMELENGTH;
- if (PHYS_ENTGRAVITY(this))
- g *= PHYS_ENTGRAVITY(this);
- if (GAMEPLAYFIX_GRAVITYUNAFFECTEDBYTICRATE)
- {
- g *= 0.5;
- this.velocity_z += g;
- }
-
- this.velocity = this.velocity * (1 - PHYS_INPUT_TIMELENGTH * PHYS_FRICTION(this));
- makevectors(this.v_angle);
- //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;
- if(this.viewloc)
- wishvel.z = this.oldmovement.x;
- this.velocity_z += g;
- if (this.ladder_entity.classname == "func_water")
- {
- float f = vlen(wishvel);
- if (f > this.ladder_entity.speed)
- wishvel *= (this.ladder_entity.speed / f);
-
- this.watertype = this.ladder_entity.skin;
- f = this.ladder_entity.origin_z + this.ladder_entity.maxs_z;
- if ((this.origin_z + this.view_ofs_z) < f)
- this.waterlevel = WATERLEVEL_SUBMERGED;
- else if ((this.origin_z + (this.mins_z + this.maxs_z) * 0.5) < f)
- this.waterlevel = WATERLEVEL_SWIMMING;
- else if ((this.origin_z + this.mins_z + 1) < f)
- this.waterlevel = WATERLEVEL_WETFEET;
- else
- {
- this.waterlevel = WATERLEVEL_NONE;
- this.watertype = CONTENT_EMPTY;
- }
- }
- // acceleration
- vector wishdir = normalize(wishvel);
- float wishspeed = min(vlen(wishvel), PHYS_MAXSPEED(this) * maxspd_mod);
- if(time >= PHYS_TELEPORT_TIME(this))
- // water acceleration
- PM_Accelerate(this, wishdir, wishspeed, wishspeed, PHYS_ACCELERATE(this)*maxspd_mod, 1, 0, 0, 0);
- PM_ClientMovement_Move(this);
-}
-
-void PM_jetpack(entity this, float maxspd_mod)
+void PM_jetpack(entity this, float maxspd_mod, float dt)
{
//makevectors(this.v_angle.y * '0 1 0');
makevectors(this.v_angle);
float a_up = PHYS_JETPACK_ACCEL_UP(this);
float a_add = PHYS_JETPACK_ANTIGRAVITY(this) * PHYS_GRAVITY(this);
+ if(PHYS_JETPACK_REVERSE_THRUST(this) && PHYS_INPUT_BUTTON_CROUCH(self)) { a_up = PHYS_JETPACK_REVERSE_THRUST(this); }
+
wishvel_x *= a_side;
wishvel_y *= a_side;
wishvel_z *= a_up;
wishvel_z += a_add;
+ if(PHYS_JETPACK_REVERSE_THRUST(this) && PHYS_INPUT_BUTTON_CROUCH(self)) { wishvel_z *= -1; }
+
float best = 0;
//////////////////////////////////////////////////////////////////////////////////////
// finding the maximum over all vectors of above form
fvel = min(1, vlen(wishvel) / best);
if (PHYS_JETPACK_FUEL(this) && !(ITEMS_STAT(this) & IT_UNLIMITED_WEAPON_AMMO))
- f = min(1, PHYS_AMMO_FUEL(this) / (PHYS_JETPACK_FUEL(this) * PHYS_INPUT_TIMELENGTH * fvel));
+ f = min(1, PHYS_AMMO_FUEL(this) / (PHYS_JETPACK_FUEL(this) * dt * fvel));
else
f = 1;
if (f > 0 && wishvel != '0 0 0')
{
- this.velocity = this.velocity + wishvel * f * PHYS_INPUT_TIMELENGTH;
+ this.velocity = this.velocity + wishvel * f * dt;
UNSET_ONGROUND(this);
#ifdef SVQC
if (!(ITEMS_STAT(this) & IT_UNLIMITED_WEAPON_AMMO))
- this.ammo_fuel -= PHYS_JETPACK_FUEL(this) * PHYS_INPUT_TIMELENGTH * fvel * f;
+ this.ammo_fuel -= PHYS_JETPACK_FUEL(this) * dt * fvel * f;
ITEMS_STAT(this) |= IT_USING_JETPACK;
this.pauseregen_finished = max(this.pauseregen_finished, time + autocvar_g_balance_pause_fuel_regen);
#endif
}
-
-#ifdef CSQC
- float g = PHYS_GRAVITY(this) * PHYS_ENTGRAVITY(this) * PHYS_INPUT_TIMELENGTH;
- if(autocvar_cl_movement == 3)
- {
- if (GAMEPLAYFIX_GRAVITYUNAFFECTEDBYTICRATE)
- this.velocity_z -= g * 0.5;
- else
- this.velocity_z -= g;
- }
- PM_ClientMovement_Move(this);
- if(autocvar_cl_movement == 3)
- {
- if (!IS_ONGROUND(this) || !(GAMEPLAYFIX_NOGRAVITYONGROUND))
- if (GAMEPLAYFIX_GRAVITYUNAFFECTEDBYTICRATE)
- this.velocity_z -= g * 0.5;
- }
-#endif
-}
-
-void PM_walk(entity this, float maxspd_mod)
-{
- if (!WAS_ONGROUND(this))
- {
-#ifdef SVQC
- if (autocvar_speedmeter)
- LOG_TRACE(strcat("landing velocity: ", vtos(this.velocity), " (abs: ", ftos(vlen(this.velocity)), ")\n"));
-#endif
- if (this.lastground < time - 0.3)
- this.velocity *= (1 - PHYS_FRICTION_ONLAND(this));
-#ifdef SVQC
- if (this.jumppadcount > 1)
- LOG_TRACE(strcat(ftos(this.jumppadcount), "x jumppad combo\n"));
- this.jumppadcount = 0;
-#endif
- }
-
- // walking
- makevectors(this.v_angle.y * '0 1 0');
- const vector wishvel = v_forward * this.movement.x
- + v_right * this.movement.y;
- // acceleration
- const vector wishdir = normalize(wishvel);
- float wishspeed = vlen(wishvel);
- wishspeed = min(wishspeed, PHYS_MAXSPEED(this) * maxspd_mod);
- 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))
- */
- }
- 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;
- }
-#ifdef CSQC
- float g = PHYS_GRAVITY(this) * PHYS_ENTGRAVITY(this) * PHYS_INPUT_TIMELENGTH;
- if(autocvar_cl_movement == 3)
- {
- if (!(GAMEPLAYFIX_NOGRAVITYONGROUND))
- this.velocity_z -= g * (GAMEPLAYFIX_GRAVITYUNAFFECTEDBYTICRATE ? 0.5 : 1);
- }
- if (vdist(this.velocity, >, 0))
- PM_ClientMovement_Move(this);
- if(autocvar_cl_movement == 3)
- {
- if (GAMEPLAYFIX_GRAVITYUNAFFECTEDBYTICRATE)
- if (!IS_ONGROUND(this) || !GAMEPLAYFIX_NOGRAVITYONGROUND)
- this.velocity_z -= g * 0.5;
- }
-#endif
-}
-
-void PM_air(entity this, float buttons_prev, float maxspd_mod)
-{
- makevectors(this.v_angle.y * '0 1 0');
- vector wishvel = v_forward * this.movement.x
- + v_right * this.movement.y;
- // acceleration
- vector wishdir = normalize(wishvel);
- float wishspeed = vlen(wishvel);
-
-#ifdef SVQC
- if(time >= PHYS_TELEPORT_TIME(this))
-#elif defined(CSQC)
- if(PHYS_WATERJUMP_TIME(this) <= 0)
-#endif
- {
- float maxairspd = PHYS_MAXAIRSPEED(this) * min(maxspd_mod, 1);
-
- // apply air speed limit
- float airaccelqw = PHYS_AIRACCEL_QW(this);
- float wishspeed0 = wishspeed;
- wishspeed = min(wishspeed, maxairspd);
- if (IS_DUCKED(this))
- wishspeed *= 0.5;
- float airaccel = PHYS_AIRACCELERATE(this) * min(maxspd_mod, 1);
-
- float accelerating = (this.velocity * wishdir > 0);
- float wishspeed2 = wishspeed;
-
- // CPM: air control
- if (PHYS_AIRSTOPACCELERATE(this))
- {
- vector curdir = normalize(vec2(this.velocity));
- airaccel += (PHYS_AIRSTOPACCELERATE(this)*maxspd_mod - airaccel) * max(0, -(curdir * wishdir));
- }
- // note that for straight forward jumping:
- // step = accel * PHYS_INPUT_TIMELENGTH * 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(PHYS_MAXAIRSPEED(this)*maxspd_mod, strafity, PHYS_MAXAIRSTRAFESPEED(this)*maxspd_mod));
- if (PHYS_AIRSTRAFEACCELERATE(this))
- airaccel = GeomLerp(airaccel, strafity, PHYS_AIRSTRAFEACCELERATE(this)*maxspd_mod);
- 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, wishdir, wishspeed2);
- else {
- float sidefric = maxairspd ? (PHYS_AIRACCEL_SIDEWAYS_FRICTION(this) / maxairspd) : 0;
- PM_Accelerate(this, wishdir, wishspeed, wishspeed0, airaccel, airaccelqw, PHYS_AIRACCEL_QW_STRETCHFACTOR(this), sidefric, PHYS_AIRSPEEDLIMIT_NONQW(this));
- }
-
- if (PHYS_AIRCONTROL(this))
- CPM_PM_Aircontrol(this, wishdir, wishspeed2);
- }
-#ifdef CSQC
- float g = PHYS_GRAVITY(this) * PHYS_ENTGRAVITY(this) * PHYS_INPUT_TIMELENGTH;
- if(autocvar_cl_movement == 3)
- if (GAMEPLAYFIX_GRAVITYUNAFFECTEDBYTICRATE)
- this.velocity_z -= g * 0.5;
- else
- this.velocity_z -= g;
-#endif
- PM_ClientMovement_Move(this);
-#ifdef CSQC
- if(autocvar_cl_movement == 3)
- if (!IS_ONGROUND(this) || !(GAMEPLAYFIX_NOGRAVITYONGROUND))
- if (GAMEPLAYFIX_GRAVITYUNAFFECTEDBYTICRATE)
- this.velocity_z -= g * 0.5;
-#endif
}
// used for calculating airshots
#endif
{
sys_phys_update(this, PHYS_INPUT_TIMELENGTH);
+
+#ifdef SVQC
+ this.pm_frametime = frametime;
+#endif
}