Weapons: remove WEP_ACTION

[xonotic/xonotic-data.pk3dir.git] / qcsrc / common / weapons / weapon / arc.qc

#ifndef IMPLEMENTATION
CLASS(Arc, Weapon)
/* ammotype  */ ATTRIB(Arc, ammo_field, .int, ammo_cells)
/* impulse   */ ATTRIB(Arc, impulse, int, 3)
/* flags     */ ATTRIB(Arc, spawnflags, int, WEP_FLAG_NORMAL);
/* rating    */ ATTRIB(Arc, bot_pickupbasevalue, float, BOT_PICKUP_RATING_HIGH);
/* color     */ ATTRIB(Arc, wpcolor, vector, '1 1 1');
/* modelname */ ATTRIB(Arc, mdl, string, "arc");
#ifndef MENUQC
/* model     */ ATTRIB(Arc, m_model, Model, MDL_ARC_ITEM);
#endif
/* crosshair */ ATTRIB(Arc, w_crosshair, string, "gfx/crosshairhlac");
/* crosshair */ ATTRIB(Arc, w_crosshair_size, float, 0.7);
/* wepimg    */ ATTRIB(Arc, model2, string, "weaponarc");
/* refname   */ ATTRIB(Arc, netname, string, "arc");
/* wepname   */ ATTRIB(Arc, message, string, _("Arc"));
ENDCLASS(Arc)
REGISTER_WEAPON(ARC, NEW(Arc));

#define ARC_SETTINGS(w_cvar,w_prop) ARC_SETTINGS_LIST(w_cvar, w_prop, ARC, arc)
#define ARC_SETTINGS_LIST(w_cvar,w_prop,id,sn) \
        w_cvar(id, sn, NONE, beam_ammo) \
        w_cvar(id, sn, NONE, beam_animtime) \
        w_cvar(id, sn, NONE, beam_botaimspeed) \
        w_cvar(id, sn, NONE, beam_botaimlifetime) \
        w_cvar(id, sn, NONE, beam_damage) \
        w_cvar(id, sn, NONE, beam_degreespersegment) \
        w_cvar(id, sn, NONE, beam_distancepersegment) \
        w_cvar(id, sn, NONE, beam_falloff_halflifedist) \
        w_cvar(id, sn, NONE, beam_falloff_maxdist) \
        w_cvar(id, sn, NONE, beam_falloff_mindist) \
        w_cvar(id, sn, NONE, beam_force) \
        w_cvar(id, sn, NONE, beam_healing_amax) \
        w_cvar(id, sn, NONE, beam_healing_aps) \
        w_cvar(id, sn, NONE, beam_healing_hmax) \
        w_cvar(id, sn, NONE, beam_healing_hps) \
        w_cvar(id, sn, NONE, beam_maxangle) \
        w_cvar(id, sn, NONE, beam_nonplayerdamage) \
        w_cvar(id, sn, NONE, beam_range) \
        w_cvar(id, sn, NONE, beam_refire) \
        w_cvar(id, sn, NONE, beam_returnspeed) \
        w_cvar(id, sn, NONE, beam_tightness) \
        w_cvar(id, sn, NONE, burst_ammo) \
        w_cvar(id, sn, NONE, burst_damage) \
        w_cvar(id, sn, NONE, burst_healing_aps) \
        w_cvar(id, sn, NONE, burst_healing_hps) \
        w_cvar(id, sn, NONE, overheat_max)/* maximum heat before jamming */ \
        w_cvar(id, sn, NONE, overheat_min)/* minimum heat to wait for cooldown */ \
        w_cvar(id, sn, NONE, beam_heat)   /* heat increase per second (primary) */ \
        w_cvar(id, sn, NONE, burst_heat)  /* heat increase per second (secondary) */ \
        w_cvar(id, sn, NONE, cooldown)    /* heat decrease per second when resting */ \
        w_prop(id, sn, float,  switchdelay_raise, switchdelay_raise) \
        w_prop(id, sn, float,  switchdelay_drop, switchdelay_drop) \
        w_prop(id, sn, string, weaponreplace, weaponreplace) \
        w_prop(id, sn, float,  weaponstart, weaponstart) \
        w_prop(id, sn, float,  weaponstartoverride, weaponstartoverride) \
        w_prop(id, sn, float,  weaponthrowable, weaponthrowable)

#ifndef MENUQC
const float ARC_MAX_SEGMENTS = 20;
vector arc_shotorigin[4];
.vector beam_start;
.vector beam_dir;
.vector beam_wantdir;
.int beam_type;

const int ARC_BT_MISS =        0x00;
const int ARC_BT_WALL =        0x01;
const int ARC_BT_HEAL =        0x02;
const int ARC_BT_HIT =         0x03;
const int ARC_BT_BURST_MISS =  0x10;
const int ARC_BT_BURST_WALL =  0x11;
const int ARC_BT_BURST_HEAL =  0x12;
const int ARC_BT_BURST_HIT =   0x13;
const int ARC_BT_BURSTMASK =   0x10;

const int ARC_SF_SETTINGS =    1;
const int ARC_SF_START =       2;
const int ARC_SF_WANTDIR =     4;
const int ARC_SF_BEAMDIR =     8;
const int ARC_SF_BEAMTYPE =    16;
const int ARC_SF_LOCALMASK =   14;
#endif
#ifdef SVQC
ARC_SETTINGS(WEP_ADD_CVAR, WEP_ADD_PROP)
.entity arc_beam;
.bool arc_BUTTON_ATCK_prev; // for better animation control
.float beam_prev;
.float beam_initialized;
.float beam_bursting;
.float beam_teleporttime;
.float beam_heat; // (beam) amount of heat produced
.float arc_overheat; // (dropped arc/player) time during which it's too hot
.float arc_cooldown; // (dropped arc/player) cooling speed
.float arc_heat_percent; // (player) arc heat in [0,1] (stat)
.float arc_smoke_sound;
#endif
#ifdef CSQC
void Ent_ReadArcBeam(float isnew);

.vector beam_color;
.float beam_alpha;
.float beam_thickness;
.float beam_traileffect;
.float beam_hiteffect;
.float beam_hitlight[4]; // 0: radius, 123: rgb
.float beam_muzzleeffect;
.float beam_muzzlelight[4]; // 0: radius, 123: rgb
.string beam_image;

.entity beam_muzzleentity;

.float beam_degreespersegment;
.float beam_distancepersegment;
.float beam_usevieworigin;
.float beam_initialized;
.float beam_maxangle;
.float beam_range;
.float beam_returnspeed;
.float beam_tightness;
.vector beam_shotorigin;

entity Draw_ArcBeam_callback_entity;
float Draw_ArcBeam_callback_last_thickness;
vector Draw_ArcBeam_callback_last_top; // NOTE: in same coordinate system as player.
vector Draw_ArcBeam_callback_last_bottom; // NOTE: in same coordinate system as player.
#endif
#endif
#ifdef IMPLEMENTATION
#ifdef SVQC
void spawnfunc_weapon_arc(void) { weapon_defaultspawnfunc(WEP_ARC.m_id); }

float W_Arc_Beam_Send(entity to, int sf)
{SELFPARAM();
        WriteByte(MSG_ENTITY, ENT_CLIENT_ARC_BEAM);

        // Truncate information when this beam is displayed to the owner client
        // - The owner client has no use for beam start position or directions,
        //    it always figures this information out for itself with csqc code.
        // - Spectating the owner also truncates this information.
        float drawlocal = ((to == self.owner) || ((to.enemy == self.owner) && IS_SPEC(to)));
        if(drawlocal) { sf &= ~ARC_SF_LOCALMASK; }

        WriteByte(MSG_ENTITY, sf);

        if(sf & ARC_SF_SETTINGS) // settings information
        {
                WriteShort(MSG_ENTITY, WEP_CVAR(arc, beam_degreespersegment));
                WriteShort(MSG_ENTITY, WEP_CVAR(arc, beam_distancepersegment));
                WriteShort(MSG_ENTITY, WEP_CVAR(arc, beam_maxangle));
                WriteCoord(MSG_ENTITY, WEP_CVAR(arc, beam_range));
                WriteShort(MSG_ENTITY, WEP_CVAR(arc, beam_returnspeed));
                WriteByte(MSG_ENTITY, WEP_CVAR(arc, beam_tightness) * 10);

                WriteByte(MSG_ENTITY, drawlocal);
        }
        if(sf & ARC_SF_START) // starting location
        {
                WriteCoord(MSG_ENTITY, self.beam_start.x);
                WriteCoord(MSG_ENTITY, self.beam_start.y);
                WriteCoord(MSG_ENTITY, self.beam_start.z);
        }
        if(sf & ARC_SF_WANTDIR) // want/aim direction
        {
                WriteCoord(MSG_ENTITY, self.beam_wantdir.x);
                WriteCoord(MSG_ENTITY, self.beam_wantdir.y);
                WriteCoord(MSG_ENTITY, self.beam_wantdir.z);
        }
        if(sf & ARC_SF_BEAMDIR) // beam direction
        {
                WriteCoord(MSG_ENTITY, self.beam_dir.x);
                WriteCoord(MSG_ENTITY, self.beam_dir.y);
                WriteCoord(MSG_ENTITY, self.beam_dir.z);
        }
        if(sf & ARC_SF_BEAMTYPE) // beam type
        {
                WriteByte(MSG_ENTITY, self.beam_type);
        }

        return true;
}

void Reset_ArcBeam(entity player, vector forward)
{
        if (!player.arc_beam) {
                return;
        }
        player.arc_beam.beam_dir = forward;
        player.arc_beam.beam_teleporttime = time;
}

float Arc_GetHeat_Percent(entity player)
{
        if ( WEP_CVAR(arc, overheat_max) <= 0 ||  WEP_CVAR(arc, overheat_max) <= 0 )
        {
                player.arc_overheat = 0;
                return 0;
        }

        if ( player.arc_beam )
                return player.arc_beam.beam_heat/WEP_CVAR(arc, overheat_max);

        if ( player.arc_overheat > time )
        {
                return (player.arc_overheat-time) / WEP_CVAR(arc, overheat_max)
                        * player.arc_cooldown;
        }

        return 0;
}
void Arc_Player_SetHeat(entity player)
{
        player.arc_heat_percent = Arc_GetHeat_Percent(player);
        //dprint("Heat: ",ftos(player.arc_heat_percent*100),"%\n");
}

void W_Arc_Beam_Think(void)
{SELFPARAM();
        if(self != self.owner.arc_beam)
        {
                remove(self);
                return;
        }


        float burst = 0;
        if( self.owner.BUTTON_ATCK2 || self.beam_bursting)
        {
                if(!self.beam_bursting)
                        self.beam_bursting = true;
                burst = ARC_BT_BURSTMASK;
        }

        if(
                !IS_PLAYER(self.owner)
                ||
                (self.owner.WEP_AMMO(ARC) <= 0 && !(self.owner.items & IT_UNLIMITED_WEAPON_AMMO))
                ||
                self.owner.deadflag != DEAD_NO
                ||
                (!self.owner.BUTTON_ATCK && !burst )
                ||
                self.owner.frozen
                ||
                self.owner.vehicle
                ||
                (WEP_CVAR(arc, overheat_max) > 0 && self.beam_heat >= WEP_CVAR(arc, overheat_max))
        )
        {
                if ( WEP_CVAR(arc, cooldown) > 0 )
                {
                        float cooldown_speed = 0;
                        if ( self.beam_heat > WEP_CVAR(arc, overheat_min) && WEP_CVAR(arc, cooldown) > 0 )
                        {
                                cooldown_speed = WEP_CVAR(arc, cooldown);
                        }
                        else if ( !burst )
                        {
                                cooldown_speed = self.beam_heat / WEP_CVAR(arc, beam_refire);
                        }

                        if ( cooldown_speed )
                        {
                                self.owner.arc_overheat = time + self.beam_heat / cooldown_speed;
                                self.owner.arc_cooldown = cooldown_speed;
                        }

                        if ( WEP_CVAR(arc, overheat_max) > 0 && self.beam_heat >= WEP_CVAR(arc, overheat_max) )
                        {
                                Send_Effect_("arc_overheat",
                                        self.beam_start, self.beam_wantdir, 1 );
                                sound(self, CH_WEAPON_A, SND_ARC_STOP, VOL_BASE, ATTN_NORM);
                        }
                }

                if(self == self.owner.arc_beam) { self.owner.arc_beam = world; }
                setself(self.owner);
                Weapon w = WEP_ARC;
                if(!w.wr_checkammo1(w) && !w.wr_checkammo2(w))
                if(!(self.items & IT_UNLIMITED_WEAPON_AMMO))
                {
                        // note: this doesn't force the switch
                        W_SwitchToOtherWeapon(self);
                }
                setself(this);
                remove(self);
                return;
        }

        // decrease ammo
        float coefficient = frametime;
        if(!(self.owner.items & IT_UNLIMITED_WEAPON_AMMO))
        {
                float rootammo;
                if(burst)
                        { rootammo = WEP_CVAR(arc, burst_ammo); }
                else
                        { rootammo = WEP_CVAR(arc, beam_ammo); }

                if(rootammo)
                {
                        coefficient = min(coefficient, self.owner.WEP_AMMO(ARC) / rootammo);
                        self.owner.WEP_AMMO(ARC) = max(0, self.owner.WEP_AMMO(ARC) - (rootammo * frametime));
                }
        }
        float heat_speed = burst ? WEP_CVAR(arc, burst_heat) : WEP_CVAR(arc, beam_heat);
        self.beam_heat = min( WEP_CVAR(arc, overheat_max), self.beam_heat + heat_speed*frametime );

        makevectors(self.owner.v_angle);

        W_SetupShot_Range(
                self.owner,
                true,
                0,
                "",
                0,
                WEP_CVAR(arc, beam_damage) * coefficient,
                WEP_CVAR(arc, beam_range)
        );

        // After teleport, "lock" the beam until the teleport is confirmed.
        if (time < self.beam_teleporttime + ANTILAG_LATENCY(self.owner)) {
                w_shotdir = self.beam_dir;
        }

        // network information: shot origin and want/aim direction
        if(self.beam_start != w_shotorg)
        {
                self.SendFlags |= ARC_SF_START;
                self.beam_start = w_shotorg;
        }
        if(self.beam_wantdir != w_shotdir)
        {
                self.SendFlags |= ARC_SF_WANTDIR;
                self.beam_wantdir = w_shotdir;
        }

        if(!self.beam_initialized)
        {
                self.beam_dir = w_shotdir;
                self.beam_initialized = true;
        }

        // WEAPONTODO: Detect player velocity so that the beam curves when moving too
        // idea: blend together self.beam_dir with the inverted direction the player is moving in
        // might have to make some special accomodation so that it only uses view_right and view_up

        // note that if we do this, it'll always be corrected to a maximum angle by beam_maxangle handling

        float segments;
        if(self.beam_dir != w_shotdir)
        {
                // calculate how much we're going to move the end of the beam to the want position
                // WEAPONTODO (server and client):
                // blendfactor never actually becomes 0 in this situation, which is a problem
                // regarding precision... this means that self.beam_dir and w_shotdir approach
                // eachother, however they never actually become the same value with this method.
                // Perhaps we should do some form of rounding/snapping?
                float angle = vlen(w_shotdir - self.beam_dir) * RAD2DEG;
                if(angle && (angle > WEP_CVAR(arc, beam_maxangle)))
                {
                        // if the angle is greater than maxangle, force the blendfactor to make this the maximum factor
                        float blendfactor = bound(
                                0,
                                (1 - (WEP_CVAR(arc, beam_returnspeed) * frametime)),
                                min(WEP_CVAR(arc, beam_maxangle) / angle, 1)
                        );
                        self.beam_dir = normalize((w_shotdir * (1 - blendfactor)) + (self.beam_dir * blendfactor));
                }
                else
                {
                        // the radius is not too far yet, no worries :D
                        float blendfactor = bound(
                                0,
                                (1 - (WEP_CVAR(arc, beam_returnspeed) * frametime)),
                                1
                        );
                        self.beam_dir = normalize((w_shotdir * (1 - blendfactor)) + (self.beam_dir * blendfactor));
                }

                // network information: beam direction
                self.SendFlags |= ARC_SF_BEAMDIR;

                // calculate how many segments are needed
                float max_allowed_segments;

                if(WEP_CVAR(arc, beam_distancepersegment))
                {
                        max_allowed_segments = min(
                                ARC_MAX_SEGMENTS,
                                1 + (vlen(w_shotdir / WEP_CVAR(arc, beam_distancepersegment)))
                        );
                }
                else { max_allowed_segments = ARC_MAX_SEGMENTS; }

                if(WEP_CVAR(arc, beam_degreespersegment))
                {
                        segments = bound(
                                1,
                                (
                                        min(
                                                angle,
                                                WEP_CVAR(arc, beam_maxangle)
                                        )
                                        /
                                        WEP_CVAR(arc, beam_degreespersegment)
                                ),
                                max_allowed_segments
                        );
                }
                else { segments = 1; }
        }
        else { segments = 1; }

        vector beam_endpos = (w_shotorg + (self.beam_dir * WEP_CVAR(arc, beam_range)));
        vector beam_controlpoint = w_shotorg + w_shotdir * (WEP_CVAR(arc, beam_range) * (1 - WEP_CVAR(arc, beam_tightness)));

        float i;
        float new_beam_type = 0;
        vector last_origin = w_shotorg;
        for(i = 1; i <= segments; ++i)
        {
                // WEAPONTODO (client):
                // In order to do nice fading and pointing on the starting segment, we must always
                // have that drawn as a separate triangle... However, that is difficult to do when
                // keeping in mind the above problems and also optimizing the amount of segments
                // drawn on screen at any given time. (Automatic beam quality scaling, essentially)

                vector new_origin = bezier_quadratic_getpoint(
                        w_shotorg,
                        beam_controlpoint,
                        beam_endpos,
                        i / segments);
                vector new_dir = normalize(new_origin - last_origin);

                WarpZone_traceline_antilag(
                        self.owner,
                        last_origin,
                        new_origin,
                        MOVE_NORMAL,
                        self.owner,
                        ANTILAG_LATENCY(self.owner)
                );

                // Do all the transforms for warpzones right now, as we already
                // "are" in the post-trace system (if we hit a player, that's
                // always BEHIND the last passed wz).
                last_origin = trace_endpos;
                w_shotorg = WarpZone_TransformOrigin(WarpZone_trace_transform, w_shotorg);
                beam_controlpoint = WarpZone_TransformOrigin(WarpZone_trace_transform, beam_controlpoint);
                beam_endpos = WarpZone_TransformOrigin(WarpZone_trace_transform, beam_endpos);
                new_dir = WarpZone_TransformVelocity(WarpZone_trace_transform, new_dir);

                float is_player = (
                        IS_PLAYER(trace_ent)
                        ||
                        trace_ent.classname == "body"
                        ||
                        IS_MONSTER(trace_ent)
                );

                if(trace_ent && trace_ent.takedamage && (is_player || WEP_CVAR(arc, beam_nonplayerdamage)))
                {
                        // calculate our own hit origin as trace_endpos tends to jump around annoyingly (to player origin?)
                        // NO. trace_endpos should be just fine. If not,
                        // that's an engine bug that needs proper debugging.
                        vector hitorigin = trace_endpos;

                        float falloff = ExponentialFalloff(
                                WEP_CVAR(arc, beam_falloff_mindist),
                                WEP_CVAR(arc, beam_falloff_maxdist),
                                WEP_CVAR(arc, beam_falloff_halflifedist),
                                vlen(WarpZone_UnTransformOrigin(WarpZone_trace_transform, hitorigin) - w_shotorg)
                        );

                        if(is_player && SAME_TEAM(self.owner, trace_ent))
                        {
                                float roothealth, rootarmor;
                                if(burst)
                                {
                                        roothealth = WEP_CVAR(arc, burst_healing_hps);
                                        rootarmor = WEP_CVAR(arc, burst_healing_aps);
                                }
                                else
                                {
                                        roothealth = WEP_CVAR(arc, beam_healing_hps);
                                        rootarmor = WEP_CVAR(arc, beam_healing_aps);
                                }

                                if(trace_ent.health <= WEP_CVAR(arc, beam_healing_hmax) && roothealth)
                                {
                                        trace_ent.health = min(
                                                trace_ent.health + (roothealth * coefficient),
                                                WEP_CVAR(arc, beam_healing_hmax)
                                        );
                                }
                                if(trace_ent.armorvalue <= WEP_CVAR(arc, beam_healing_amax) && rootarmor)
                                {
                                        trace_ent.armorvalue = min(
                                                trace_ent.armorvalue + (rootarmor * coefficient),
                                                WEP_CVAR(arc, beam_healing_amax)
                                        );
                                }

                                // stop rot, set visual effect
                                if(roothealth || rootarmor)
                                {
                                        trace_ent.pauserothealth_finished = max(
                                                trace_ent.pauserothealth_finished,
                                                time + autocvar_g_balance_pause_health_rot
                                        );
                                        trace_ent.pauserotarmor_finished = max(
                                                trace_ent.pauserotarmor_finished,
                                                time + autocvar_g_balance_pause_armor_rot
                                        );
                                        new_beam_type = ARC_BT_HEAL;
                                }
                        }
                        else
                        {
                                float rootdamage;
                                if(is_player)
                                {
                                        if(burst)
                                                { rootdamage = WEP_CVAR(arc, burst_damage); }
                                        else
                                                { rootdamage = WEP_CVAR(arc, beam_damage); }
                                }
                                else
                                        { rootdamage = WEP_CVAR(arc, beam_nonplayerdamage); }

                                if(accuracy_isgooddamage(self.owner, trace_ent))
                                {
                                        accuracy_add(
                                                self.owner,
                                                WEP_ARC.m_id,
                                                0,
                                                rootdamage * coefficient * falloff
                                        );
                                }

                                Damage(
                                        trace_ent,
                                        self.owner,
                                        self.owner,
                                        rootdamage * coefficient * falloff,
                                        WEP_ARC.m_id,
                                        hitorigin,
                                        WEP_CVAR(arc, beam_force) * new_dir * coefficient * falloff
                                );

                                new_beam_type = ARC_BT_HIT;
                        }
                        break;
                }
                else if(trace_fraction != 1)
                {
                        // we collided with geometry
                        new_beam_type = ARC_BT_WALL;
                        break;
                }
        }

        // te_explosion(trace_endpos);

        // if we're bursting, use burst visual effects
        new_beam_type |= burst;

        // network information: beam type
        if(new_beam_type != self.beam_type)
        {
                self.SendFlags |= ARC_SF_BEAMTYPE;
                self.beam_type = new_beam_type;
        }

        self.owner.beam_prev = time;
        self.nextthink = time;
}

void W_Arc_Beam(float burst)
{SELFPARAM();

        // only play fire sound if 1 sec has passed since player let go the fire button
        if(time - self.beam_prev > 1)
                sound(self, CH_WEAPON_A, SND_ARC_FIRE, VOL_BASE, ATTN_NORM);

        entity beam = self.arc_beam = spawn();
        beam.classname = "W_Arc_Beam";
        beam.solid = SOLID_NOT;
        beam.think = W_Arc_Beam_Think;
        beam.owner = self;
        beam.movetype = MOVETYPE_NONE;
        beam.bot_dodge = true;
        beam.bot_dodgerating = WEP_CVAR(arc, beam_damage);
        beam.beam_bursting = burst;
        Net_LinkEntity(beam, false, 0, W_Arc_Beam_Send);

        WITH(entity, self, beam, beam.think());
}

void Arc_Smoke()
{SELFPARAM();
        makevectors(self.v_angle);
        W_SetupShot_Range(self,true,0,"",0,0,0);

        vector smoke_origin = w_shotorg + self.velocity*frametime;
        if ( self.arc_overheat > time )
        {
                if ( random() < self.arc_heat_percent )
                        Send_Effect_("arc_smoke", smoke_origin, '0 0 0', 1 );
                if ( self.BUTTON_ATCK || self.BUTTON_ATCK2 )
                {
                        Send_Effect_("arc_overheat_fire", smoke_origin, w_shotdir, 1 );
                        if ( !self.arc_smoke_sound )
                        {
                                self.arc_smoke_sound = 1;
                                sound(self, CH_SHOTS_SINGLE, SND_ARC_LOOP_OVERHEAT, VOL_BASE, ATTN_NORM);
                        }
                }
        }
        else if ( self.arc_beam && WEP_CVAR(arc, overheat_max) > 0 &&
                        self.arc_beam.beam_heat > WEP_CVAR(arc, overheat_min) )
        {
                if ( random() < (self.arc_beam.beam_heat-WEP_CVAR(arc, overheat_min)) /
                                ( WEP_CVAR(arc, overheat_max)-WEP_CVAR(arc, overheat_min) ) )
                        Send_Effect_("arc_smoke", smoke_origin, '0 0 0', 1 );
        }

        if (  self.arc_smoke_sound && ( self.arc_overheat <= time ||
                !( self.BUTTON_ATCK || self.BUTTON_ATCK2 ) ) || self.switchweapon != WEP_ARC.m_id )
        {
                self.arc_smoke_sound = 0;
                sound(self, CH_SHOTS_SINGLE, SND_Null, VOL_BASE, ATTEN_NORM);
        }
}

                METHOD(Arc, wr_aim, bool(entity thiswep))
                {
                        SELFPARAM();
                        if(WEP_CVAR(arc, beam_botaimspeed))
                        {
                                self.BUTTON_ATCK = bot_aim(
                                        WEP_CVAR(arc, beam_botaimspeed),
                                        0,
                                        WEP_CVAR(arc, beam_botaimlifetime),
                                        false
                                );
                        }
                        else
                        {
                                self.BUTTON_ATCK = bot_aim(
                                        1000000,
                                        0,
                                        0.001,
                                        false
                                );
                        }
                        return true;
                }
                METHOD(Arc, wr_think, bool(entity thiswep, bool fire1, bool fire2))
                {
                        SELFPARAM();
                        Arc_Player_SetHeat(self);
                        Arc_Smoke();

                        if (time >= self.arc_overheat)
                        if (fire1 || fire2 || self.arc_beam.beam_bursting)
                        {

                                if(self.arc_BUTTON_ATCK_prev)
                                {
                                        #if 0
                                        if(self.animstate_startframe == self.anim_shoot.x && self.animstate_numframes == self.anim_shoot.y)
                                                weapon_thinkf(WFRAME_DONTCHANGE, autocvar_g_balance_arc_primary_animtime, w_ready);
                                        else
                                        #endif
                                                weapon_thinkf(WFRAME_FIRE1, WEP_CVAR(arc, beam_animtime), w_ready);
                                }

                                if((!self.arc_beam) || wasfreed(self.arc_beam))
                                {
                                        if(weapon_prepareattack(fire2, 0))
                                        {
                                                W_Arc_Beam(fire2);

                                                if(!self.arc_BUTTON_ATCK_prev)
                                                {
                                                        weapon_thinkf(WFRAME_FIRE1, WEP_CVAR(arc, beam_animtime), w_ready);
                                                        self.arc_BUTTON_ATCK_prev = true;
                                                }
                                        }
                                }

                                return true;
                        }

                        if(self.arc_BUTTON_ATCK_prev)
                        {
                                sound(self, CH_WEAPON_A, SND_ARC_STOP, VOL_BASE, ATTN_NORM);
                                weapon_thinkf(WFRAME_FIRE1, WEP_CVAR(arc, beam_animtime), w_ready);
                                ATTACK_FINISHED(self) = time + WEP_CVAR(arc, beam_refire) * W_WeaponRateFactor();
                        }
                        self.arc_BUTTON_ATCK_prev = false;

                        #if 0
                        if(fire2)
                        if(weapon_prepareattack(true, autocvar_g_balance_arc_secondary_refire))
                        {
                                W_Arc_Attack2();
                                self.arc_count = autocvar_g_balance_arc_secondary_count;
                                weapon_thinkf(WFRAME_FIRE2, autocvar_g_balance_arc_secondary_animtime, w_arc_checkattack);
                                self.arc_secondarytime = time + autocvar_g_balance_arc_secondary_refire2 * W_WeaponRateFactor();
                        }
                        #endif

                        return true;
                }
                METHOD(Arc, wr_init, bool(entity thiswep))
                {
                        if(!arc_shotorigin[0])
                        {
                                arc_shotorigin[0] = shotorg_adjust_values(CL_Weapon_GetShotOrg(WEP_ARC.m_id), false, false, 1);
                                arc_shotorigin[1] = shotorg_adjust_values(CL_Weapon_GetShotOrg(WEP_ARC.m_id), false, false, 2);
                                arc_shotorigin[2] = shotorg_adjust_values(CL_Weapon_GetShotOrg(WEP_ARC.m_id), false, false, 3);
                                arc_shotorigin[3] = shotorg_adjust_values(CL_Weapon_GetShotOrg(WEP_ARC.m_id), false, false, 4);
                        }
                        ARC_SETTINGS(WEP_SKIP_CVAR, WEP_SET_PROP);
                        return true;
                }
                METHOD(Arc, wr_checkammo1, bool(entity thiswep))
                {
                        SELFPARAM();
                        return ((!WEP_CVAR(arc, beam_ammo)) || (self.WEP_AMMO(ARC) > 0));
                }
                METHOD(Arc, wr_checkammo2, bool(entity thiswep))
                {
                        SELFPARAM();
                        return WEP_CVAR(arc, overheat_max) > 0 &&
                                ((!WEP_CVAR(arc, burst_ammo)) || (self.WEP_AMMO(ARC) > 0));
                }
                METHOD(Arc, wr_config, bool(entity thiswep))
                {
                        ARC_SETTINGS(WEP_CONFIG_WRITE_CVARS, WEP_CONFIG_WRITE_PROPS);
                        return true;
                }
                METHOD(Arc, wr_killmessage, bool(entity thiswep))
                {
                        return WEAPON_ARC_MURDER;
                }
                METHOD(Arc, wr_drop, bool(entity thiswep))
                {
                        weapon_dropevent_item.arc_overheat = self.arc_overheat;
                        weapon_dropevent_item.arc_cooldown = self.arc_cooldown;
                        self.arc_overheat = 0;
                        self.arc_cooldown = 0;
                        return true;
                }
                METHOD(Arc, wr_pickup, bool(entity thiswep))
                {
                        if ( !client_hasweapon(self, WEP_ARC.m_id, false, false) &&
                                weapon_dropevent_item.arc_overheat > time )
                        {
                                self.arc_overheat = weapon_dropevent_item.arc_overheat;
                                self.arc_cooldown = weapon_dropevent_item.arc_cooldown;
                        }
                        return true;
                }
#endif
#ifdef CSQC
void Draw_ArcBeam_callback(vector start, vector hit, vector end)
{
        entity beam = Draw_ArcBeam_callback_entity;
        vector transformed_view_org;
        transformed_view_org = WarpZone_TransformOrigin(WarpZone_trace_transform, view_origin);

        // Thickdir shall be perpendicular to the beam and to the view-to-beam direction (WEAPONTODO: WHY)
        // WEAPONTODO: Wouldn't it be better to be perpendicular to the beam and to the view FORWARD direction?
        vector thickdir = normalize(cross(normalize(start - hit), transformed_view_org - start));

        vector hitorigin;

        // draw segment
        #if 0
        if(trace_fraction != 1)
        {
                // calculate our own hit origin as trace_endpos tends to jump around annoyingly (to player origin?)
                hitorigin = start + (Draw_ArcBeam_callback_new_dir * Draw_ArcBeam_callback_segmentdist * trace_fraction);
                hitorigin = WarpZone_TransformOrigin(WarpZone_trace_transform, hitorigin);
        }
        else
        {
                hitorigin = hit;
        }
        #else
        hitorigin = hit;
        #endif

        // decide upon thickness
        float thickness = beam.beam_thickness;

        // draw primary beam render
        vector top    = hitorigin + (thickdir * thickness);
        vector bottom = hitorigin - (thickdir * thickness);

        vector last_top = WarpZone_TransformOrigin(WarpZone_trace_transform, Draw_ArcBeam_callback_last_top);
        vector last_bottom = WarpZone_TransformOrigin(WarpZone_trace_transform, Draw_ArcBeam_callback_last_bottom);

        R_BeginPolygon(beam.beam_image, DRAWFLAG_NORMAL); // DRAWFLAG_ADDITIVE
        R_PolygonVertex(
                top,
                '0 0.5 0' + ('0 0.5 0' * (thickness / beam.beam_thickness)),
                beam.beam_color,
                beam.beam_alpha
        );
        R_PolygonVertex(
                last_top,
                '0 0.5 0' + ('0 0.5 0' * (Draw_ArcBeam_callback_last_thickness / beam.beam_thickness)),
                beam.beam_color,
                beam.beam_alpha
        );
        R_PolygonVertex(
                last_bottom,
                '0 0.5 0' * (1 - (Draw_ArcBeam_callback_last_thickness / beam.beam_thickness)),
                beam.beam_color,
                beam.beam_alpha
        );
        R_PolygonVertex(
                bottom,
                '0 0.5 0' * (1 - (thickness / beam.beam_thickness)),
                beam.beam_color,
                beam.beam_alpha
        );
        R_EndPolygon();

        // draw trailing particles
        // NOTES:
        //  - Don't use spammy particle counts here, use a FEW small particles around the beam
        //  - We're not using WarpZone_TrailParticles here because we will handle warpzones ourselves.
        if(beam.beam_traileffect)
        {
                trailparticles(beam, beam.beam_traileffect, start, hitorigin);
        }

        // set up for the next
        Draw_ArcBeam_callback_last_thickness = thickness;
        Draw_ArcBeam_callback_last_top = WarpZone_UnTransformOrigin(WarpZone_trace_transform, top);
        Draw_ArcBeam_callback_last_bottom = WarpZone_UnTransformOrigin(WarpZone_trace_transform, bottom);
}

void Reset_ArcBeam(void)
{
        entity e;
        for (e = world; (e = findfloat(e, beam_usevieworigin, 1)); ) {
                e.beam_initialized = false;
        }
        for (e = world; (e = findfloat(e, beam_usevieworigin, 2)); ) {
                e.beam_initialized = false;
        }
}

void Draw_ArcBeam(void)
{SELFPARAM();
        float dt = time - self.move_time;
        self.move_time = time;
        if(dt <= 0) { return; }

        if(!self.beam_usevieworigin)
        {
                InterpolateOrigin_Do();
        }

        // origin = beam starting origin
        // v_angle = wanted/aim direction
        // angles = current direction of beam

        vector start_pos;
        vector wantdir; //= view_forward;
        vector beamdir; //= self.beam_dir;

        float segments;
        if(self.beam_usevieworigin)
        {
                // WEAPONTODO:
                // Currently we have to replicate nearly the same method of figuring
                // out the shotdir that the server does... Ideally in the future we
                // should be able to acquire this from a generalized function built
                // into a weapon system for client code.

                // find where we are aiming
                makevectors(warpzone_save_view_angles);
                vector forward = v_forward;
                vector right = v_right;
                vector up = v_up;

                // decide upon start position
                if(self.beam_usevieworigin == 2)
                        { start_pos = warpzone_save_view_origin; }
                else
                        { start_pos = self.origin; }

                // trace forward with an estimation
                WarpZone_TraceLine(
                        start_pos,
                        start_pos + forward * self.beam_range,
                        MOVE_NOMONSTERS,
                        self
                );

                // untransform in case our trace went through a warpzone
                vector end_pos = WarpZone_UnTransformOrigin(WarpZone_trace_transform, trace_endpos);

                // un-adjust trueaim if shotend is too close
                if(vlen(end_pos - start_pos) < g_trueaim_minrange)
                        end_pos = start_pos + (forward * g_trueaim_minrange);

                // move shot origin to the actual gun muzzle origin
                vector origin_offset =
                          right * -self.beam_shotorigin.y
                        + up * self.beam_shotorigin.z;

                start_pos = start_pos + origin_offset;

                // Move it also forward, but only as far as possible without hitting anything. Don't poke into walls!
                traceline(start_pos, start_pos + forward * self.beam_shotorigin.x, MOVE_NORMAL, self);
                start_pos = trace_endpos;

                // calculate the aim direction now
                wantdir = normalize(end_pos - start_pos);

                if(!self.beam_initialized)
                {
                        self.beam_dir = wantdir;
                        self.beam_initialized = true;
                }

                if(self.beam_dir != wantdir)
                {
                        // calculate how much we're going to move the end of the beam to the want position
                        // WEAPONTODO (server and client):
                        // blendfactor never actually becomes 0 in this situation, which is a problem
                        // regarding precision... this means that self.beam_dir and w_shotdir approach
                        // eachother, however they never actually become the same value with this method.
                        // Perhaps we should do some form of rounding/snapping?
                        float angle = vlen(wantdir - self.beam_dir) * RAD2DEG;
                        if(angle && (angle > self.beam_maxangle))
                        {
                                // if the angle is greater than maxangle, force the blendfactor to make this the maximum factor
                                float blendfactor = bound(
                                        0,
                                        (1 - (self.beam_returnspeed * frametime)),
                                        min(self.beam_maxangle / angle, 1)
                                );
                                self.beam_dir = normalize((wantdir * (1 - blendfactor)) + (self.beam_dir * blendfactor));
                        }
                        else
                        {
                                // the radius is not too far yet, no worries :D
                                float blendfactor = bound(
                                        0,
                                        (1 - (self.beam_returnspeed * frametime)),
                                        1
                                );
                                self.beam_dir = normalize((wantdir * (1 - blendfactor)) + (self.beam_dir * blendfactor));
                        }

                        // calculate how many segments are needed
                        float max_allowed_segments;

                        if(self.beam_distancepersegment)
                        {
                                max_allowed_segments = min(
                                        ARC_MAX_SEGMENTS,
                                        1 + (vlen(wantdir / self.beam_distancepersegment))
                                );
                        }
                        else { max_allowed_segments = ARC_MAX_SEGMENTS; }

                        if(self.beam_degreespersegment)
                        {
                                segments = bound(
                                        1,
                                        (
                                                min(
                                                        angle,
                                                        self.beam_maxangle
                                                )
                                                /
                                                self.beam_degreespersegment
                                        ),
                                        max_allowed_segments
                                );
                        }
                        else { segments = 1; }
                }
                else { segments = 1; }

                // set the beam direction which the rest of the code will refer to
                beamdir = self.beam_dir;

                // finally, set self.angles to the proper direction so that muzzle attachment points in proper direction
                self.angles = fixedvectoangles2(forward, up); // TODO(Samual): is this == warpzone_save_view_angles?
        }
        else
        {
                // set the values from the provided info from the networked entity
                start_pos = self.origin;
                wantdir = self.v_angle;
                beamdir = self.angles;

                if(beamdir != wantdir)
                {
                        float angle = vlen(wantdir - beamdir) * RAD2DEG;

                        // calculate how many segments are needed
                        float max_allowed_segments;

                        if(self.beam_distancepersegment)
                        {
                                max_allowed_segments = min(
                                        ARC_MAX_SEGMENTS,
                                        1 + (vlen(wantdir / self.beam_distancepersegment))
                                );
                        }
                        else { max_allowed_segments = ARC_MAX_SEGMENTS; }

                        if(self.beam_degreespersegment)
                        {
                                segments = bound(
                                        1,
                                        (
                                                min(
                                                        angle,
                                                        self.beam_maxangle
                                                )
                                                /
                                                self.beam_degreespersegment
                                        ),
                                        max_allowed_segments
                                );
                        }
                        else { segments = 1; }
                }
                else { segments = 1; }
        }

        setorigin(self, start_pos);
        self.beam_muzzleentity.angles_z = random() * 360; // WEAPONTODO: use avelocity instead?

        vector beam_endpos = (start_pos + (beamdir * self.beam_range));
        vector beam_controlpoint = start_pos + wantdir * (self.beam_range * (1 - self.beam_tightness));

        Draw_ArcBeam_callback_entity = self;
        Draw_ArcBeam_callback_last_thickness = 0;
        Draw_ArcBeam_callback_last_top = start_pos;
        Draw_ArcBeam_callback_last_bottom = start_pos;

        vector last_origin = start_pos;
        vector original_start_pos = start_pos;

        float i;
        for(i = 1; i <= segments; ++i)
        {
                // WEAPONTODO (client):
                // In order to do nice fading and pointing on the starting segment, we must always
                // have that drawn as a separate triangle... However, that is difficult to do when
                // keeping in mind the above problems and also optimizing the amount of segments
                // drawn on screen at any given time. (Automatic beam quality scaling, essentially)

                vector new_origin = bezier_quadratic_getpoint(
                        start_pos,
                        beam_controlpoint,
                        beam_endpos,
                        i / segments);

                WarpZone_TraceBox_ThroughZone(
                        last_origin,
                        '0 0 0',
                        '0 0 0',
                        new_origin,
                        MOVE_NORMAL,
                        world,
                        world,
                        Draw_ArcBeam_callback
                );

                // Do all the transforms for warpzones right now, as we already "are" in the post-trace
                // system (if we hit a player, that's always BEHIND the last passed wz).
                last_origin = trace_endpos;
                start_pos = WarpZone_TransformOrigin(WarpZone_trace_transform, start_pos);
                beam_controlpoint = WarpZone_TransformOrigin(WarpZone_trace_transform, beam_controlpoint);
                beam_endpos = WarpZone_TransformOrigin(WarpZone_trace_transform, beam_endpos);
                beamdir = WarpZone_TransformVelocity(WarpZone_trace_transform, beamdir);
                Draw_ArcBeam_callback_last_top = WarpZone_TransformOrigin(WarpZone_trace_transform, Draw_ArcBeam_callback_last_top);
                Draw_ArcBeam_callback_last_bottom = WarpZone_TransformOrigin(WarpZone_trace_transform, Draw_ArcBeam_callback_last_bottom);

                if(trace_fraction < 1) { break; }
        }

        // visual effects for startpoint and endpoint
        if(self.beam_hiteffect)
        {
                // FIXME we really should do this on the server so it actually
                // matches gameplay. What this client side stuff is doing is no
                // more than guesswork.
                if((trace_ent || trace_fraction < 1) && !(trace_dphitq3surfaceflags & Q3SURFACEFLAG_NOIMPACT))
                pointparticles(
                        self.beam_hiteffect,
                        last_origin,
                        beamdir * -1,
                        frametime * 2
                );
        }
        if(self.beam_hitlight[0])
        {
                adddynamiclight(
                        last_origin,
                        self.beam_hitlight[0],
                        vec3(
                                self.beam_hitlight[1],
                                self.beam_hitlight[2],
                                self.beam_hitlight[3]
                        )
                );
        }
        if(self.beam_muzzleeffect)
        {
                pointparticles(
                        self.beam_muzzleeffect,
                        original_start_pos + wantdir * 20,
                        wantdir * 1000,
                        frametime * 0.1
                );
        }
        if(self.beam_muzzlelight[0])
        {
                adddynamiclight(
                        original_start_pos + wantdir * 20,
                        self.beam_muzzlelight[0],
                        vec3(
                                self.beam_muzzlelight[1],
                                self.beam_muzzlelight[2],
                                self.beam_muzzlelight[3]
                        )
                );
        }

        // cleanup
        Draw_ArcBeam_callback_entity = world;
        Draw_ArcBeam_callback_last_thickness = 0;
        Draw_ArcBeam_callback_last_top = '0 0 0';
        Draw_ArcBeam_callback_last_bottom = '0 0 0';
}

void Remove_ArcBeam(void)
{SELFPARAM();
        remove(self.beam_muzzleentity);
        sound(self, CH_SHOTS_SINGLE, SND_Null, VOL_BASE, ATTEN_NORM);
}

void Ent_ReadArcBeam(float isnew)
{SELFPARAM();
        int sf = ReadByte();
        entity flash;

        if(isnew)
        {
                // calculate shot origin offset from gun alignment
                int gunalign = autocvar_cl_gunalign;
                if(gunalign != 1 && gunalign != 2 && gunalign != 4)
                        gunalign = 3; // default value
                --gunalign;

                self.beam_shotorigin = arc_shotorigin[gunalign];

                // set other main attributes of the beam
                self.draw = Draw_ArcBeam;
                self.entremove = Remove_ArcBeam;
                self.move_time = time;
                loopsound(self, CH_SHOTS_SINGLE, SND(ARC_LOOP), VOL_BASE, ATTEN_NORM);

                flash = spawn();
                flash.owner = self;
                flash.effects = EF_ADDITIVE | EF_FULLBRIGHT;
                flash.drawmask = MASK_NORMAL;
                flash.solid = SOLID_NOT;
                flash.avelocity_z = 5000;
                setattachment(flash, self, "");
                setorigin(flash, '0 0 0');

                self.beam_muzzleentity = flash;
        }
        else
        {
                flash = self.beam_muzzleentity;
        }

        if(sf & ARC_SF_SETTINGS) // settings information
        {
                self.beam_degreespersegment = ReadShort();
                self.beam_distancepersegment = ReadShort();
                self.beam_maxangle = ReadShort();
                self.beam_range = ReadCoord();
                self.beam_returnspeed = ReadShort();
                self.beam_tightness = (ReadByte() / 10);

                if(ReadByte())
                {
                        if(autocvar_chase_active)
                                { self.beam_usevieworigin = 1; }
                        else // use view origin
                                { self.beam_usevieworigin = 2; }
                }
                else
                {
                        self.beam_usevieworigin = 0;
                }
        }

        if(!self.beam_usevieworigin)
        {
                // self.iflags = IFLAG_ORIGIN | IFLAG_ANGLES | IFLAG_V_ANGLE; // why doesn't this work?
                self.iflags = IFLAG_ORIGIN;

                InterpolateOrigin_Undo();
        }

        if(sf & ARC_SF_START) // starting location
        {
                self.origin_x = ReadCoord();
                self.origin_y = ReadCoord();
                self.origin_z = ReadCoord();
        }
        else if(self.beam_usevieworigin) // infer the location from player location
        {
                if(self.beam_usevieworigin == 2)
                {
                        // use view origin
                        self.origin = view_origin;
                }
                else
                {
                        // use player origin so that third person display still works
                        self.origin = getplayerorigin(player_localnum) + ('0 0 1' * getstati(STAT_VIEWHEIGHT));
                }
        }

        setorigin(self, self.origin);

        if(sf & ARC_SF_WANTDIR) // want/aim direction
        {
                self.v_angle_x = ReadCoord();
                self.v_angle_y = ReadCoord();
                self.v_angle_z = ReadCoord();
        }

        if(sf & ARC_SF_BEAMDIR) // beam direction
        {
                self.angles_x = ReadCoord();
                self.angles_y = ReadCoord();
                self.angles_z = ReadCoord();
        }

        if(sf & ARC_SF_BEAMTYPE) // beam type
        {
                self.beam_type = ReadByte();
                switch(self.beam_type)
                {
                        case ARC_BT_MISS:
                        {
                                self.beam_color = '1 1 1';
                                self.beam_alpha = 0.5;
                                self.beam_thickness = 8;
                                self.beam_traileffect = particleeffectnum(EFFECT_ARC_BEAM);
                                self.beam_hiteffect = particleeffectnum(EFFECT_ARC_LIGHTNING);
                                self.beam_hitlight[0] = 0;
                                self.beam_hitlight[1] = 1;
                                self.beam_hitlight[2] = 1;
                                self.beam_hitlight[3] = 1;
                                self.beam_muzzleeffect = -1; //particleeffectnum(EFFECT_VORTEX_MUZZLEFLASH);
                                self.beam_muzzlelight[0] = 0;
                                self.beam_muzzlelight[1] = 1;
                                self.beam_muzzlelight[2] = 1;
                                self.beam_muzzlelight[3] = 1;
                                if(self.beam_muzzleeffect >= 0)
                                {
                                        setmodel(flash, MDL_ARC_MUZZLEFLASH);
                                        flash.alpha = self.beam_alpha;
                                        flash.colormod = self.beam_color;
                                        flash.scale = 0.5;
                                }
                                break;
                        }
                        case ARC_BT_WALL: // grenadelauncher_muzzleflash healray_muzzleflash
                        {
                                self.beam_color = '1 1 1';
                                self.beam_alpha = 0.5;
                                self.beam_thickness = 8;
                                self.beam_traileffect = particleeffectnum(EFFECT_ARC_BEAM);
                                self.beam_hiteffect = particleeffectnum(EFFECT_ARC_LIGHTNING);
                                self.beam_hitlight[0] = 0;
                                self.beam_hitlight[1] = 1;
                                self.beam_hitlight[2] = 1;
                                self.beam_hitlight[3] = 1;
                                self.beam_muzzleeffect = -1; // particleeffectnum(EFFECT_GRENADE_MUZZLEFLASH);
                                self.beam_muzzlelight[0] = 0;
                                self.beam_muzzlelight[1] = 1;
                                self.beam_muzzlelight[2] = 1;
                                self.beam_muzzlelight[3] = 1;
                                self.beam_image = "particles/lgbeam";
                                if(self.beam_muzzleeffect >= 0)
                                {
                                        setmodel(flash, MDL_ARC_MUZZLEFLASH);
                                        flash.alpha = self.beam_alpha;
                                        flash.colormod = self.beam_color;
                                        flash.scale = 0.5;
                                }
                                break;
                        }
                        case ARC_BT_HEAL:
                        {
                                self.beam_color = '1 1 1';
                                self.beam_alpha = 0.5;
                                self.beam_thickness = 8;
                                self.beam_traileffect = particleeffectnum(EFFECT_ARC_BEAM_HEAL);
                                self.beam_hiteffect = particleeffectnum(EFFECT_ARC_BEAM_HEAL_IMPACT);
                                self.beam_hitlight[0] = 0;
                                self.beam_hitlight[1] = 1;
                                self.beam_hitlight[2] = 1;
                                self.beam_hitlight[3] = 1;
                                self.beam_muzzleeffect = -1; //particleeffectnum(EFFECT_VORTEX_MUZZLEFLASH);
                                self.beam_muzzlelight[0] = 0;
                                self.beam_muzzlelight[1] = 1;
                                self.beam_muzzlelight[2] = 1;
                                self.beam_muzzlelight[3] = 1;
                                self.beam_image = "particles/lgbeam";
                                if(self.beam_muzzleeffect >= 0)
                                {
                                        setmodel(flash, MDL_ARC_MUZZLEFLASH);
                                        flash.alpha = self.beam_alpha;
                                        flash.colormod = self.beam_color;
                                        flash.scale = 0.5;
                                }
                                break;
                        }
                        case ARC_BT_HIT:
                        {
                                self.beam_color = '1 1 1';
                                self.beam_alpha = 0.5;
                                self.beam_thickness = 8;
                                self.beam_traileffect = particleeffectnum(EFFECT_ARC_BEAM);
                                self.beam_hiteffect = particleeffectnum(EFFECT_ARC_LIGHTNING);
                                self.beam_hitlight[0] = 20;
                                self.beam_hitlight[1] = 1;
                                self.beam_hitlight[2] = 0;
                                self.beam_hitlight[3] = 0;
                                self.beam_muzzleeffect = -1; //particleeffectnum(EFFECT_VORTEX_MUZZLEFLASH);
                                self.beam_muzzlelight[0] = 50;
                                self.beam_muzzlelight[1] = 1;
                                self.beam_muzzlelight[2] = 0;
                                self.beam_muzzlelight[3] = 0;
                                self.beam_image = "particles/lgbeam";
                                if(self.beam_muzzleeffect >= 0)
                                {
                                        setmodel(flash, MDL_ARC_MUZZLEFLASH);
                                        flash.alpha = self.beam_alpha;
                                        flash.colormod = self.beam_color;
                                        flash.scale = 0.5;
                                }
                                break;
                        }
                        case ARC_BT_BURST_MISS:
                        {
                                self.beam_color = '1 1 1';
                                self.beam_alpha = 0.5;
                                self.beam_thickness = 14;
                                self.beam_traileffect = particleeffectnum(EFFECT_ARC_BEAM);
                                self.beam_hiteffect = particleeffectnum(EFFECT_ARC_LIGHTNING);
                                self.beam_hitlight[0] = 0;
                                self.beam_hitlight[1] = 1;
                                self.beam_hitlight[2] = 1;
                                self.beam_hitlight[3] = 1;
                                self.beam_muzzleeffect = -1; //particleeffectnum(EFFECT_VORTEX_MUZZLEFLASH);
                                self.beam_muzzlelight[0] = 0;
                                self.beam_muzzlelight[1] = 1;
                                self.beam_muzzlelight[2] = 1;
                                self.beam_muzzlelight[3] = 1;
                                self.beam_image = "particles/lgbeam";
                                if(self.beam_muzzleeffect >= 0)
                                {
                                        setmodel(flash, MDL_ARC_MUZZLEFLASH);
                                        flash.alpha = self.beam_alpha;
                                        flash.colormod = self.beam_color;
                                        flash.scale = 0.5;
                                }
                                break;
                        }
                        case ARC_BT_BURST_WALL:
                        {
                                self.beam_color = '1 1 1';
                                self.beam_alpha = 0.5;
                                self.beam_thickness = 14;
                                self.beam_traileffect = particleeffectnum(EFFECT_ARC_BEAM);
                                self.beam_hiteffect = particleeffectnum(EFFECT_ARC_LIGHTNING);
                                self.beam_hitlight[0] = 0;
                                self.beam_hitlight[1] = 1;
                                self.beam_hitlight[2] = 1;
                                self.beam_hitlight[3] = 1;
                                self.beam_muzzleeffect = -1; //particleeffectnum(EFFECT_VORTEX_MUZZLEFLASH);
                                self.beam_muzzlelight[0] = 0;
                                self.beam_muzzlelight[1] = 1;
                                self.beam_muzzlelight[2] = 1;
                                self.beam_muzzlelight[3] = 1;
                                self.beam_image = "particles/lgbeam";
                                if(self.beam_muzzleeffect >= 0)
                                {
                                        setmodel(flash, MDL_ARC_MUZZLEFLASH);
                                        flash.alpha = self.beam_alpha;
                                        flash.colormod = self.beam_color;
                                        flash.scale = 0.5;
                                }
                                break;
                        }
                        case ARC_BT_BURST_HEAL:
                        {
                                self.beam_color = '1 1 1';
                                self.beam_alpha = 0.5;
                                self.beam_thickness = 14;
                                self.beam_traileffect = particleeffectnum(EFFECT_ARC_BEAM_HEAL);
                                self.beam_hiteffect = particleeffectnum(EFFECT_ARC_BEAM_HEAL_IMPACT2);
                                self.beam_hitlight[0] = 0;
                                self.beam_hitlight[1] = 1;
                                self.beam_hitlight[2] = 1;
                                self.beam_hitlight[3] = 1;
                                self.beam_muzzleeffect = -1; //particleeffectnum(EFFECT_VORTEX_MUZZLEFLASH);
                                self.beam_muzzlelight[0] = 0;
                                self.beam_muzzlelight[1] = 1;
                                self.beam_muzzlelight[2] = 1;
                                self.beam_muzzlelight[3] = 1;
                                self.beam_image = "particles/lgbeam";
                                if(self.beam_muzzleeffect >= 0)
                                {
                                        setmodel(flash, MDL_ARC_MUZZLEFLASH);
                                        flash.alpha = self.beam_alpha;
                                        flash.colormod = self.beam_color;
                                        flash.scale = 0.5;
                                }
                                break;
                        }
                        case ARC_BT_BURST_HIT:
                        {
                                self.beam_color = '1 1 1';
                                self.beam_alpha = 0.5;
                                self.beam_thickness = 14;
                                self.beam_traileffect = particleeffectnum(EFFECT_ARC_BEAM);
                                self.beam_hiteffect = particleeffectnum(EFFECT_ARC_LIGHTNING);
                                self.beam_hitlight[0] = 0;
                                self.beam_hitlight[1] = 1;
                                self.beam_hitlight[2] = 1;
                                self.beam_hitlight[3] = 1;
                                self.beam_muzzleeffect = -1; //particleeffectnum(EFFECT_VORTEX_MUZZLEFLASH);
                                self.beam_muzzlelight[0] = 0;
                                self.beam_muzzlelight[1] = 1;
                                self.beam_muzzlelight[2] = 1;
                                self.beam_muzzlelight[3] = 1;
                                self.beam_image = "particles/lgbeam";
                                if(self.beam_muzzleeffect >= 0)
                                {
                                        setmodel(flash, MDL_ARC_MUZZLEFLASH);
                                        flash.alpha = self.beam_alpha;
                                        flash.colormod = self.beam_color;
                                        flash.scale = 0.5;
                                }
                                break;
                        }

                        // shouldn't be possible, but lets make it colorful if it does :D
                        default:
                        {
                                self.beam_color = randomvec();
                                self.beam_alpha = 1;
                                self.beam_thickness = 8;
                                self.beam_traileffect = false;
                                self.beam_hiteffect = false;
                                self.beam_hitlight[0] = 0;
                                self.beam_hitlight[1] = 1;
                                self.beam_hitlight[2] = 1;
                                self.beam_hitlight[3] = 1;
                                self.beam_muzzleeffect = -1; //particleeffectnum(EFFECT_VORTEX_MUZZLEFLASH);
                                self.beam_muzzlelight[0] = 0;
                                self.beam_muzzlelight[1] = 1;
                                self.beam_muzzlelight[2] = 1;
                                self.beam_muzzlelight[3] = 1;
                                self.beam_image = "particles/lgbeam";
                                if(self.beam_muzzleeffect >= 0)
                                {
                                        setmodel(flash, MDL_ARC_MUZZLEFLASH);
                                        flash.alpha = self.beam_alpha;
                                        flash.colormod = self.beam_color;
                                        flash.scale = 0.5;
                                }
                                break;
                        }
                }
        }

        if(!self.beam_usevieworigin)
        {
                InterpolateOrigin_Note();
        }
}

                METHOD(Arc, wr_impacteffect, bool(entity thiswep))
                {
                        // todo
                        return true;
                }
                METHOD(Arc, wr_init, bool(entity thiswep))
                {
                        return true;
                }
                METHOD(Arc, wr_zoomreticle, bool(entity thiswep))
                {
                        // no weapon specific image for this weapon
                        return false;
                }
#endif
#endif