s/ammo/fuel/ :P

[divverent/nexuiz.git] / data / qcsrc / server / cl_physics.qc

float sv_accelerate;
float sv_friction;
float sv_maxspeed;
float sv_airaccelerate;
float sv_maxairspeed;
float sv_stopspeed;
float sv_gravity;
float sv_airaccel_sideways_friction;
float sv_airaccel_qw;
.float ladder_time;
.entity ladder_entity;
.float gravity;
.float swamp_slowdown;
.float lastflags;
.float lastground;
.float wasFlying;
.float spectatorspeed;

#define SHTEST_DELTA 10
#define SHTEST_THRESHOLD 1.1
.float shtest_next;
.float shtest_accumulator;

/*
=============
PlayerJump

When you press the jump key
=============
*/
void PlayerJump (void)
{
        float mjumpheight;

        mjumpheight = cvar("sv_jumpvelocity");
        if (self.waterlevel >= WATERLEVEL_SWIMMING)
        {
                if (self.watertype == CONTENT_WATER)
                        self.velocity_z = 200;
                else if (self.watertype == CONTENT_SLIME)
                        self.velocity_z = 80;
                else
                        self.velocity_z = 50;

                return;
        }


        if (!(self.flags & FL_ONGROUND))
                return;

        if(!sv_pogostick)
                if (!(self.flags & FL_JUMPRELEASED))
                        return;
                        
        if(self.health <= g_bloodloss)
                return;

        if(g_runematch)
        {
                if(self.runes & RUNE_SPEED)
                {
                        if(self.runes & CURSE_SLOW)
                                mjumpheight = mjumpheight * cvar("g_balance_rune_speed_combo_jumpheight");
                        else
                                mjumpheight = mjumpheight * cvar("g_balance_rune_speed_jumpheight");
                }
                else if(self.runes & CURSE_SLOW)
                {
                        mjumpheight = mjumpheight * cvar("g_balance_curse_slow_jumpheight");
                }
        }

        if(g_minstagib && (self.items & IT_INVINCIBLE))
        {
                mjumpheight = mjumpheight * cvar("g_minstagib_speed_jumpheight");
        }

        self.velocity_z = self.velocity_z + mjumpheight;
        self.oldvelocity_z = self.velocity_z;

        self.flags &~= FL_ONGROUND;
        self.flags &~= FL_JUMPRELEASED;

        if (self.crouch)
                setanim(self, self.anim_duckjump, FALSE, TRUE, TRUE);
        else
                setanim(self, self.anim_jump, FALSE, TRUE, TRUE);

        if(g_jump_grunt)
                PlayerSound(playersound_jump, CHAN_PLAYER, VOICETYPE_PLAYERSOUND);
}

void CheckWaterJump()
{
        local vector start, end;

// check for a jump-out-of-water
        makevectors (self.angles);
        start = self.origin;
        start_z = start_z + 8;
        v_forward_z = 0;
        normalize(v_forward);
        end = start + v_forward*24;
        traceline (start, end, TRUE, self);
        if (trace_fraction < 1)
        {       // solid at waist
                start_z = start_z + self.maxs_z - 8;
                end = start + v_forward*24;
                self.movedir = trace_plane_normal * -50;
                traceline (start, end, TRUE, self);
                if (trace_fraction == 1)
                {       // open at eye level
                        self.flags |= FL_WATERJUMP;
                        self.velocity_z = 225;
                        self.flags &~= FL_JUMPRELEASED;
                        self.teleport_time = time + 2;  // safety net
                        return;
                }
        }
};

float racecar_angle(float forward, float down)
{
        float ret, angle_mult;

        if(forward < 0)
        {
                forward = -forward;
                down = -down;
        }

        ret = vectoyaw('0 1 0' * down + '1 0 0' * forward);

        angle_mult = forward / (800 + forward);

        if(ret > 180)
                return ret * angle_mult + 360 * (1 - angle_mult);
        else
                return ret * angle_mult;
}

void RaceCarPhysics()
{
        // using this move type for "big rigs"
        // the engine does not push the entity!

        float accel, steer, f;
        vector angles_save, rigvel;

        angles_save = self.angles;
        accel = bound(-1, self.movement_x / sv_maxspeed, 1);
        steer = bound(-1, self.movement_y / sv_maxspeed, 1);

        if(g_bugrigs_reverse_speeding)
        {
                if(accel < 0)
                {
                        // back accel is DIGITAL
                        // to prevent speedhack
                        if(accel < -0.5)
                                accel = -1;
                        else
                                accel = 0;
                }
        }

        self.angles_x = 0;
        self.angles_z = 0;
        makevectors(self.angles); // new forward direction!

        if(self.flags & FL_ONGROUND || g_bugrigs_air_steering)
        {
                float myspeed, upspeed, steerfactor, accelfactor;

                myspeed = self.velocity * v_forward;
                upspeed = self.velocity * v_up;

                // responsiveness factor for steering and acceleration
                f = 1 / (1 + pow(max(-myspeed, myspeed) / g_bugrigs_speed_ref, g_bugrigs_speed_pow));
                //MAXIMA: f(v) := 1 / (1 + (v / g_bugrigs_speed_ref) ^ g_bugrigs_speed_pow);

                if(myspeed < 0 && g_bugrigs_reverse_spinning)
                        steerfactor = -myspeed * g_bugrigs_steer;
                else
                        steerfactor = -myspeed * f * g_bugrigs_steer;

                if(myspeed < 0 && g_bugrigs_reverse_speeding)
                        accelfactor = g_bugrigs_accel;
                else
                        accelfactor = f * g_bugrigs_accel;
                //MAXIMA: accel(v) := f(v) * g_bugrigs_accel;

                if(accel < 0)
                {
                        if(myspeed > 0)
                        {
                                myspeed = max(0, myspeed - frametime * (g_bugrigs_friction_floor - g_bugrigs_friction_brake * accel));
                        }
                        else
                        {
                                if(!g_bugrigs_reverse_speeding)
                                        myspeed = min(0, myspeed + frametime * g_bugrigs_friction_floor);
                        }
                }
                else
                {
                        if(myspeed >= 0)
                        {
                                myspeed = max(0, myspeed - frametime * g_bugrigs_friction_floor);
                        }
                        else
                        {
                                if(g_bugrigs_reverse_stopping)
                                        myspeed = 0;
                                else
                                        myspeed = min(0, myspeed + frametime * (g_bugrigs_friction_floor + g_bugrigs_friction_brake * accel));
                        }
                }
                // terminal velocity = velocity at which 50 == accelfactor, that is, 1549 units/sec
                //MAXIMA: friction(v) := g_bugrigs_friction_floor;

                self.angles_y += steer * frametime * steerfactor; // apply steering
                makevectors(self.angles); // new forward direction!

                myspeed += accel * accelfactor * frametime;

                rigvel = myspeed * v_forward + '0 0 1' * upspeed;
        }
        else
        {
                myspeed = vlen(self.velocity);

                // responsiveness factor for steering and acceleration
                f = 1 / (1 + pow(max(0, myspeed / g_bugrigs_speed_ref), g_bugrigs_speed_pow));
                steerfactor = -myspeed * f;
                self.angles_y += steer * frametime * steerfactor; // apply steering

                rigvel = self.velocity;
                makevectors(self.angles); // new forward direction!
        }

        rigvel = rigvel * max(0, 1 - vlen(rigvel) * g_bugrigs_friction_air * frametime);
        //MAXIMA: airfriction(v) := v * v * g_bugrigs_friction_air;
        //MAXIMA: total_acceleration(v) := accel(v) - friction(v) - airfriction(v);
        //MAXIMA: solve(total_acceleration(v) = 0, v);

        if(g_bugrigs_planar_movement)
        {
                vector rigvel_xy, neworigin, up;
                float mt;

                rigvel_z -= frametime * sv_gravity; // 4x gravity plays better
                rigvel_xy = rigvel;
                rigvel_xy_z = 0;

                if(g_bugrigs_planar_movement_car_jumping && !g_touchexplode) // touchexplode is a better way to handle collisions
                        mt = MOVE_NORMAL;
                else
                        mt = MOVE_NOMONSTERS;

                tracebox(self.origin, self.mins, self.maxs, self.origin + '0 0 1024', mt, self);
                up = trace_endpos - self.origin;

                // BUG RIGS: align the move to the surface instead of doing collision testing
                // can we move?
                tracebox(trace_endpos, self.mins, self.maxs, trace_endpos + rigvel_xy * frametime, mt, self);

                // align to surface
                tracebox(trace_endpos, self.mins, self.maxs, trace_endpos - up + '0 0 1' * rigvel_z * frametime, mt, self);

                if(trace_fraction < 0.5)
                {
                        trace_fraction = 1;
                        neworigin = self.origin;
                }
                else
                        neworigin = trace_endpos;

                if(trace_fraction < 1)
                {
                        // now set angles_x so that the car points parallel to the surface
                        self.angles = vectoangles(
                                        '1 0 0' * v_forward_x * trace_plane_normal_z
                                        +
                                        '0 1 0' * v_forward_y * trace_plane_normal_z
                                        +
                                        '0 0 1' * -(v_forward_x * trace_plane_normal_x + v_forward_y * trace_plane_normal_y)
                                        );
                        self.flags |= FL_ONGROUND;
                }
                else
                {
                        // now set angles_x so that the car points forward, but is tilted in velocity direction
                        self.flags &~= FL_ONGROUND;
                }

                self.velocity = (neworigin - self.origin) * (1.0 / frametime);
                self.movetype = MOVETYPE_NOCLIP;
        }
        else
        {
                rigvel_z -= frametime * sv_gravity; // 4x gravity plays better
                self.velocity = rigvel;
                self.movetype = MOVETYPE_FLY;
        }

        trace_fraction = 1;
        tracebox(self.origin, self.mins, self.maxs, self.origin - '0 0 4', MOVE_NORMAL, self);
        if(trace_fraction != 1)
        {
                self.angles = vectoangles2(
                                '1 0 0' * v_forward_x * trace_plane_normal_z
                                +
                                '0 1 0' * v_forward_y * trace_plane_normal_z
                                +
                                '0 0 1' * -(v_forward_x * trace_plane_normal_x + v_forward_y * trace_plane_normal_y),
                                trace_plane_normal
                                );
        }
        else
        {
                vector vel_local;

                vel_local_x = v_forward * self.velocity;
                vel_local_y = v_right * self.velocity;
                vel_local_z = v_up * self.velocity;

                self.angles_x = racecar_angle(vel_local_x, vel_local_z);
                self.angles_z = racecar_angle(-vel_local_y, vel_local_z);
        }

        // smooth the angles
        vector vf1, vu1, smoothangles;
        makevectors(self.angles);
        f = bound(0, frametime * g_bugrigs_angle_smoothing, 1);
        if(f == 0)
                f = 1;
        vf1 = v_forward * f;
        vu1 = v_up * f;
        makevectors(angles_save);
        vf1 = vf1 + v_forward * (1 - f);
        vu1 = vu1 + v_up * (1 - f);
        smoothangles = vectoangles2(vf1, vu1);
        self.angles_x = -smoothangles_x;
        self.angles_z =  smoothangles_z;
}

.vector movement_old;
.float buttons_old;
.vector v_angle_old;

void Nixnex_GiveCurrentWeapon();
void SV_PlayerPhysics()
{
        local vector wishvel, wishdir, v;
        local float wishspeed, f, maxspd_mod, spd, maxairspd, airaccel, swampspd_mod, shtest_score, buttons;
        string temps;

        buttons = self.BUTTON_ATCK + 2 * self.BUTTON_JUMP + 4 * self.BUTTON_ATCK2 + 8 * self.BUTTON_ZOOM + 16 * self.BUTTON_CROUCH + 32 * self.BUTTON_HOOK + 64 * self.BUTTON_USE;
        if(!sv_maxidle_spectatorsareidle || self.movetype == MOVETYPE_WALK)
        {
                if(buttons != self.buttons_old || self.movement != self.movement_old || self.v_angle != self.v_angle_old)
                        self.parm_idlesince = time;
        }
        self.buttons_old = buttons;
        self.movement_old = self.movement;
        self.v_angle_old = self.v_angle;

        if(time > self.shtest_next)
        {
                if(self.shtest_next > 0)
                {
                        // self.shtest_accumulator:
                        //   started at time - SHTEST_DELTA
                        //   should be at SHTEST_DELTA
                        shtest_score = self.shtest_accumulator / (SHTEST_DELTA + time - self.shtest_next);
                        if(shtest_score > SHTEST_THRESHOLD)
                                print("TIME PARADOX: shtest for ", self.netname, " said ", ftos(shtest_score), "\n");
                        else if(cvar("developer_shtest"))
                                dprint("okay: shtest for ", self.netname, " said ", ftos(shtest_score), "\n");
                }
                self.shtest_next = time + SHTEST_DELTA;
                self.shtest_accumulator = 0;
        }
        self.shtest_accumulator += frametime;

        if (clienttype(self) == CLIENTTYPE_BOT)
                bot_think();

        if (self.movetype == MOVETYPE_NONE && self.disableclientprediction != 2)
                return;

        if (self.punchangle != '0 0 0')
        {
                f = vlen(self.punchangle) - 10 * frametime;
                if (f > 0)
                        self.punchangle = normalize(self.punchangle) * f;
                else
                        self.punchangle = '0 0 0';
        }

        if (self.punchvector != '0 0 0')
        {
                f = vlen(self.punchvector) - 30 * frametime;
                if (f > 0)
                        self.punchvector = normalize(self.punchvector) * f;
                else
                        self.punchvector = '0 0 0';
        }

        maxspd_mod = 1;

        if(g_runematch)
        {
                if(self.runes & RUNE_SPEED)
                {
                        if(self.runes & CURSE_SLOW)
                                maxspd_mod = maxspd_mod * cvar("g_balance_rune_speed_combo_moverate");
                        else
                                maxspd_mod = maxspd_mod * cvar("g_balance_rune_speed_moverate");
                }
                else if(self.runes & CURSE_SLOW)
                {
                        maxspd_mod = maxspd_mod * cvar("g_balance_curse_slow_moverate");
                }
        }

        if(g_minstagib && (self.items & IT_INVINCIBLE))
        {
                maxspd_mod = cvar("g_minstagib_speed_moverate");
        }

        swampspd_mod = 1;
        if(self.in_swamp) {
                swampspd_mod = self.swamp_slowdown; //cvar("g_balance_swamp_moverate");
        }

        if(self.flags & FL_NOTARGET)
        {
                maxspd_mod = cvar("sv_spectator_speed_multiplier");
                if(!self.spectatorspeed)
                        self.spectatorspeed = maxspd_mod;
                if(self.impulse && self.impulse <= 19)
                {
                        if(self.lastflags & FL_NOTARGET)
                        {
                                if(self.impulse == 10 || self.impulse == 15 || self.impulse == 18)
                                        self.spectatorspeed = bound(1, self.spectatorspeed + 0.5, 5);
                                else if(self.impulse == 11)
                                        self.spectatorspeed = maxspd_mod;
                                else if(self.impulse == 12 || self.impulse == 16  || self.impulse == 19)
                                        self.spectatorspeed = bound(1, self.spectatorspeed - 0.5, 5);
                                else if(self.impulse >= 1 && self.impulse <= 9)
                                        self.spectatorspeed = 1 + 0.5 * (self.impulse - 1);
                        } // otherwise just clear
                        self.impulse = 0;
                }
                maxspd_mod = self.spectatorspeed;
        }

        spd = sv_maxspeed * maxspd_mod * swampspd_mod;

        if(self.speed != spd)
        {
                self.speed = spd;
                temps = ftos(spd);
                stuffcmd(self, strcat("cl_forwardspeed ", temps, "\n"));
                stuffcmd(self, strcat("cl_backspeed ", temps, "\n"));
                stuffcmd(self, strcat("cl_sidespeed ", temps, "\n"));
                stuffcmd(self, strcat("cl_upspeed ", temps, "\n"));

                temps = ftos(sv_accelerate * maxspd_mod);
                stuffcmd(self, strcat("cl_movement_accelerate ", temps, "\n"));
        }

        // if dead, behave differently
        if (self.deadflag)
                return;

        if (!self.fixangle && !g_bugrigs)
        {
                self.angles_x = 0;
                self.angles_y = self.v_angle_y;
                self.angles_z = 0;
        }

        if(self.flags & FL_ONGROUND)
        if(self.wasFlying)
        {
                self.wasFlying = 0;

                if(self.waterlevel < WATERLEVEL_SWIMMING)
                if(time >= self.ladder_time)
                if not(self.hook)
                {
                        self.nextstep = time + 0.3 + random() * 0.1;
                        trace_dphitq3surfaceflags = 0;
                        tracebox(self.origin, self.mins, self.maxs, self.origin - '0 0 1', MOVE_NOMONSTERS, self);
                        if not(trace_dphitq3surfaceflags & Q3SURFACEFLAG_NOSTEPS)
                        {
                                if(trace_dphitq3surfaceflags & Q3SURFACEFLAG_METALSTEPS)
                                        GlobalSound(globalsound_metalfall, CHAN_PLAYER, VOICETYPE_PLAYERSOUND);
                                else
                                        GlobalSound(globalsound_fall, CHAN_PLAYER, VOICETYPE_PLAYERSOUND);
                        }
                }
        }

        if(IsFlying(self))
                self.wasFlying = 1;

        if(self.classname == "player")
        {
                if(sv_doublejump)
                {
                        self.flags &~= FL_ONGROUND;
                        tracebox(self.origin + '0 0 1', self.mins, self.maxs, self.origin - '0 0 2', MOVE_NORMAL, self);
                        if(trace_fraction < 1 && trace_plane_normal_z > 0.7)
                                self.flags |= FL_ONGROUND;
                }

                if (self.BUTTON_JUMP)
                        PlayerJump ();
                else
                        self.flags |= FL_JUMPRELEASED;

                if (self.waterlevel == WATERLEVEL_SWIMMING)
                        CheckWaterJump ();

                if (g_jetpack && self.BUTTON_HOOK)
                {
                        //makevectors(self.v_angle_y * '0 1 0');
                        makevectors(self.v_angle);
                        wishvel = v_forward * self.movement_x + v_right * self.movement_y;
                        // add remaining speed as Z component
                        maxairspd = sv_maxairspeed*max(1, maxspd_mod);
                        wishvel_x *= 1 / maxairspd;
                        wishvel_y *= 1 / maxairspd;
                        wishvel_z = 0;
                        wishvel_z += sqrt(max(0, 1 - wishvel * wishvel));
                        wishvel_z += cvar("g_jetpack_accel_upadjust");
                        wishvel = normalize(wishvel);
                        wishvel_x *= cvar("g_jetpack_accel_side");
                        wishvel_y *= cvar("g_jetpack_accel_side");
                        wishvel_z *= cvar("g_jetpack_accel_up");

                        wishdir = normalize(wishvel);
                        wishspeed = vlen(wishvel);

                        f = (1 - (self.velocity * wishdir) / cvar("g_jetpack_maxspeed"));
                        if(cvar("g_jetpack_ammo"))
                        {
                                if(self.ammo_cells < 0.01)
                                        f = 0;
                                else
                                        f = min(f, self.ammo_cells / (cvar("g_jetpack_ammo") * frametime));
                        }
                        if (f > 0)
                        {
                                self.velocity = self.velocity + wishvel * f * frametime;
                                float c;
                                c = self.ammo_cells;
                                self.ammo_cells -= frametime * cvar("g_jetpack_ammo") * f;
                                if(floor(c / 5) != floor(self.ammo_cells / 5))
                                        sprint(self, "jetpack: less than ", ftos(floor(c)), " cells left\n");
                                else if(self.ammo_cells < 0.01 && cvar("g_jetpack_ammo"))
                                        sprint(self, "jetpack: out of fuel\n");
                                self.flags &~= FL_ONGROUND;
                                self.modelflags |= MF_ROCKET;
                        }
                        else
                                self.modelflags &~= MF_ROCKET;
                }
                else
                        self.modelflags &~= MF_ROCKET;
        }

        if (self.flags & FL_WATERJUMP )
        {
                self.velocity_x = self.movedir_x;
                self.velocity_y = self.movedir_y;
                if (time > self.teleport_time || self.waterlevel == WATERLEVEL_NONE)
                {
                        self.flags &~= FL_WATERJUMP;
                        self.teleport_time = 0;
                }
        }
        else if (g_bugrigs && self.classname == "player")
        {
                RaceCarPhysics();
        }
        else if (self.movetype == MOVETYPE_NOCLIP || self.movetype == MOVETYPE_FLY)
        {
                // noclipping or flying
                self.flags &~= FL_ONGROUND;

                self.velocity = self.velocity * (1 - frametime * sv_friction);
                makevectors(self.v_angle);
                //wishvel = v_forward * self.movement_x + v_right * self.movement_y + v_up * self.movement_z;
                wishvel = v_forward * self.movement_x + v_right * self.movement_y + '0 0 1' * self.movement_z;
                // acceleration
                wishdir = normalize(wishvel);
                wishspeed = vlen(wishvel);
                if (wishspeed > sv_maxspeed*maxspd_mod)
                        wishspeed = sv_maxspeed*maxspd_mod;
                if (time >= self.teleport_time)
                {
                        f = wishspeed - (self.velocity * wishdir);
                        if (f > 0)
                                self.velocity = self.velocity + wishdir * min(f, sv_accelerate*maxspd_mod * frametime * wishspeed);
                }
        }
        else if (self.waterlevel >= WATERLEVEL_SWIMMING)
        {
                // swimming
                self.flags &~= FL_ONGROUND;

                makevectors(self.v_angle);
                //wishvel = v_forward * self.movement_x + v_right * self.movement_y + v_up * self.movement_z;
                wishvel = v_forward * self.movement_x + v_right * self.movement_y + '0 0 1' * self.movement_z;
                if (wishvel == '0 0 0')
                        wishvel = '0 0 -60'; // drift towards bottom

                wishdir = normalize(wishvel);
                wishspeed = vlen(wishvel);
                if (wishspeed > sv_maxspeed*maxspd_mod)
                        wishspeed = sv_maxspeed*maxspd_mod;
                wishspeed = wishspeed * 0.7;

                // water friction
                self.velocity = self.velocity * (1 - frametime * sv_friction);

                // water acceleration
                f = wishspeed - (self.velocity * wishdir);
                if (f > 0)
                        self.velocity = self.velocity + wishdir * min(f, sv_accelerate*maxspd_mod * frametime * wishspeed);
        }
        else if (time < self.ladder_time)
        {
                // on a spawnfunc_func_ladder or swimming in spawnfunc_func_water
                self.flags &~= FL_ONGROUND;

                self.velocity = self.velocity * (1 - frametime * sv_friction);
                makevectors(self.v_angle);
                //wishvel = v_forward * self.movement_x + v_right * self.movement_y + v_up * self.movement_z;
                wishvel = v_forward * self.movement_x + v_right * self.movement_y + '0 0 1' * self.movement_z;
                if (self.gravity)
                        self.velocity_z = self.velocity_z + self.gravity * sv_gravity * frametime;
                else
                        self.velocity_z = self.velocity_z + sv_gravity * frametime;
                if (self.ladder_entity.classname == "func_water")
                {
                        f = vlen(wishvel);
                        if (f > self.ladder_entity.speed)
                                wishvel = wishvel * (self.ladder_entity.speed / f);

                        self.watertype = self.ladder_entity.skin;
                        f = self.ladder_entity.origin_z + self.ladder_entity.maxs_z;
                        if ((self.origin_z + self.view_ofs_z) < f)
                                self.waterlevel = WATERLEVEL_SUBMERGED;
                        else if ((self.origin_z + (self.mins_z + self.maxs_z) * 0.5) < f)
                                self.waterlevel = WATERLEVEL_SWIMMING;
                        else if ((self.origin_z + self.mins_z + 1) < f)
                                self.waterlevel = WATERLEVEL_WETFEET;
                        else
                        {
                                self.waterlevel = WATERLEVEL_NONE;
                                self.watertype = CONTENT_EMPTY;
                        }
                }
                // acceleration
                wishdir = normalize(wishvel);
                wishspeed = vlen(wishvel);
                if (wishspeed > sv_maxspeed)
                        wishspeed = sv_maxspeed;
                if (time >= self.teleport_time)
                {
                        f = wishspeed - (self.velocity * wishdir);
                        if (f > 0)
                                self.velocity = self.velocity + wishdir * min(f, sv_accelerate*maxspd_mod * frametime * wishspeed);
                }
        }
        else if (self.flags & FL_ONGROUND)
        {
                // walking
                makevectors(self.v_angle_y * '0 1 0');
                wishvel = v_forward * self.movement_x + v_right * self.movement_y;

                if(!(self.lastflags & FL_ONGROUND))
                {
                        if(cvar("speedmeter"))
                                dprint(strcat("landing velocity: ", vtos(self.velocity), " (abs: ", ftos(vlen(self.velocity)), ")\n"));
                        if(self.lastground < time - 0.3)
                                self.velocity = self.velocity * (1 - cvar("sv_friction_on_land"));
                        if(self.jumppadcount > 1)
                                dprint(strcat(ftos(self.jumppadcount), "x jumppad combo\n"));
                        self.jumppadcount = 0;
                }

                if (self.velocity_x || self.velocity_y)
                if (!(self.flags & FL_JUMPRELEASED) || !self.BUTTON_JUMP)
                {
                        v = self.velocity;
                        v_z = 0;
                        f = vlen(v);
                        if (f < sv_stopspeed)
                                f = 1 - frametime * (sv_stopspeed / f) * sv_friction;
                        else
                                f = 1 - frametime * sv_friction;
                        if (f > 0)
                                self.velocity = self.velocity * f;
                        else
                                self.velocity = '0 0 0';
                }
                // acceleration
                wishdir = normalize(wishvel);
                wishspeed = vlen(wishvel);
                if (wishspeed > sv_maxspeed*maxspd_mod)
                        wishspeed = sv_maxspeed*maxspd_mod;
                if (self.crouch)
                        wishspeed = wishspeed * 0.5;
                if (time >= self.teleport_time)
                {
                        f = wishspeed - (self.velocity * wishdir);
                        if (f > 0)
                                self.velocity = self.velocity + wishdir * min(f, sv_accelerate*maxspd_mod * frametime * wishspeed);
                }
        }
        else
        {
                if(maxspd_mod < 1)
                {
                        maxairspd = sv_maxairspeed*maxspd_mod;
                        airaccel = sv_airaccelerate*maxspd_mod;
                }
                else
                {
                        maxairspd = sv_maxairspeed;
                        airaccel = sv_airaccelerate;
                }
                // airborn
                makevectors(self.v_angle_y * '0 1 0');
                wishvel = v_forward * self.movement_x + v_right * self.movement_y;
                // acceleration
                wishdir = normalize(wishvel);
                wishspeed = vlen(wishvel);
                if (wishspeed > maxairspd)
                        wishspeed = maxairspd;
                if (self.crouch)
                        wishspeed = wishspeed * 0.5;
                if (time >= self.teleport_time)
                {
                        // NOTE: this does the same as the commented out old code if:
                        //   sv_airaccel_qw 0
                        //   sv_airaccel_sideways_friction 0
                        
                        float vel_straight;
                        float vel_z;
                        vector vel_perpend;
                        vel_straight = self.velocity * wishdir;
                        vel_z = self.velocity_z;
                        vel_perpend = self.velocity - vel_straight * wishdir - vel_z * '0 0 1';

                        f = wishspeed - vel_straight;
                        if(f > 0)
                                vel_straight = vel_straight + min(f, airaccel * frametime * wishspeed) * sv_airaccel_qw;
                        if(wishspeed > 0)
                                vel_straight = vel_straight + min(wishspeed, airaccel * frametime * wishspeed) * (1 - sv_airaccel_qw);

                        // anti-sideways friction to fix QW-style bunnyhopping
                        vel_perpend = vel_perpend * (1 - frametime * (wishspeed / maxairspd) * sv_airaccel_sideways_friction);

                        self.velocity = vel_straight * wishdir + vel_z * '0 0 1' + vel_perpend;

                        /*
                        f = wishspeed;// - (self.velocity * wishdir);
                        if (f > 0)
                                self.velocity = self.velocity + wishdir * min(f, airaccel * frametime * wishspeed);
                        */
                }
        }

        if(self.flags & FL_ONGROUND)
                self.lastground = time;

        self.lastflags = self.flags;
};