Merge branch 'master' into samual/weapons

[xonotic/xonotic-data.pk3dir.git] / qcsrc / client / particles.qc

.float dphitcontentsmask;

.float cnt; // effect number
.vector velocity; // particle velocity
.float waterlevel; // direction jitter
.float count; // count multiplier
.float impulse; // density
.string noise; // sound
.float atten;
.float volume;
.float absolute; // 1 = count per second is absolute, 2 = only spawn at toggle
.vector movedir; // trace direction

void Draw_PointParticles()
{
        float n, i, fail;
        vector p;
        vector sz;
        vector o;
        o = self.origin;
        sz = self.maxs - self.mins;
        n = BGMScript(self);
        if(self.absolute == 2)
        {
                if(n >= 0)
                        n = self.just_toggled ? self.impulse : 0;
                else
                        n = self.impulse * drawframetime;
        }
        else
        {
                n *= self.impulse * drawframetime;
                if(self.just_toggled)
                        if(n < 1)
                                n = 1;
        }
        if(n == 0)
                return;
        fail = 0;
        for(i = random(); i <= n && fail <= 64*n; ++i)
        {
                p = o + self.mins;
                p_x += random() * sz_x;
                p_y += random() * sz_y;
                p_z += random() * sz_z;
                if(WarpZoneLib_BoxTouchesBrush(p, p, self, world))
                {
                        if(self.movedir != '0 0 0')
                        {
                                traceline(p, p + normalize(self.movedir) * 4096, 0, world);
                                p = trace_endpos;
                                pointparticles(self.cnt, p, trace_plane_normal * vlen(self.movedir) + self.velocity + randomvec() * self.waterlevel, self.count);
                        }
                        else
                        {
                                pointparticles(self.cnt, p, self.velocity + randomvec() * self.waterlevel, self.count);
                        }
                        if(self.noise != "")
                        {
                                setorigin(self, p);
                                sound(self, CH_AMBIENT, self.noise, VOL_BASE * self.volume, self.atten);
                        }
                        self.just_toggled = 0;
                }
                else if(self.absolute)
                {
                        ++fail;
                        --i;
                }
        }
        setorigin(self, o);
}

void Ent_PointParticles_Remove()
{
        if(self.noise)
                strunzone(self.noise);
        self.noise = string_null;
        if(self.bgmscript)
                strunzone(self.bgmscript);
        self.bgmscript = string_null;
}

void Ent_PointParticles()
{
        float f, i;
        vector v;
        f = ReadByte();
        if(f & 2)
        {
                i = ReadCoord(); // density (<0: point, >0: volume)
                if(i && !self.impulse && self.cnt) // self.cnt check is so it only happens if the ent already existed
                        self.just_toggled = 1;
                self.impulse = i;
        }
        if(f & 4)
        {
                self.origin_x = ReadCoord();
                self.origin_y = ReadCoord();
                self.origin_z = ReadCoord();
        }
        if(f & 1)
        {
                self.modelindex = ReadShort();
                if(f & 0x80)
                {
                        if(self.modelindex)
                        {
                                self.mins_x = ReadCoord();
                                self.mins_y = ReadCoord();
                                self.mins_z = ReadCoord();
                                self.maxs_x = ReadCoord();
                                self.maxs_y = ReadCoord();
                                self.maxs_z = ReadCoord();
                        }
                        else
                        {
                                self.mins    = '0 0 0';
                                self.maxs_x = ReadCoord();
                                self.maxs_y = ReadCoord();
                                self.maxs_z = ReadCoord();
                        }
                }
                else
                {
                        self.mins = self.maxs = '0 0 0';
                }

                self.cnt = ReadShort(); // effect number

                if(f & 0x20)
                {
                        self.velocity = decompressShortVector(ReadShort());
                        self.movedir = decompressShortVector(ReadShort());
                }
                else
                {
                        self.velocity = self.movedir = '0 0 0';
                }
                if(f & 0x40)
                {
                        self.waterlevel = ReadShort() / 16.0;
                        self.count = ReadByte() / 16.0;
                }
                else
                {
                        self.waterlevel = 0;
                        self.count = 1;
                }
                if(self.noise)
                        strunzone(self.noise);
                if(self.bgmscript)
                        strunzone(self.bgmscript);
                self.noise = strzone(ReadString());
                if(self.noise != "")
                {
                        self.atten = ReadByte() / 64.0;
                        self.volume = ReadByte() / 255.0;
                }
                self.bgmscript = strzone(ReadString());
                if(self.bgmscript != "")
                {
                        self.bgmscriptattack = ReadByte() / 64.0;
                        self.bgmscriptdecay = ReadByte() / 64.0;
                        self.bgmscriptsustain = ReadByte() / 255.0;
                        self.bgmscriptrelease = ReadByte() / 64.0;
                }
                BGMScript_InitEntity(self);
        }

        if(f & 2)
        {
                self.absolute = (self.impulse >= 0);
                if(!self.absolute)
                {
                        v = self.maxs - self.mins;
                        self.impulse *= -v_x * v_y * v_z / 262144; // relative: particles per 64^3 cube
                }
        }

        if(f & 0x10)
                self.absolute = 2;

        setorigin(self, self.origin);
        setsize(self, self.mins, self.maxs);
        self.solid = SOLID_NOT;
        self.draw = Draw_PointParticles;
        self.entremove = Ent_PointParticles_Remove;
}

.float glow_color; // palette index
void Draw_Rain()
{
    te_particlerain(self.origin + self.mins, self.origin + self.maxs, self.velocity, floor(self.count * drawframetime + random()), self.glow_color);
}

void Draw_Snow()
{
    te_particlesnow(self.origin + self.mins, self.origin + self.maxs, self.velocity, floor(self.count * drawframetime + random()), self.glow_color);
}

void Ent_RainOrSnow()
{
        self.impulse = ReadByte(); // Rain, Snow, or Whatever
        self.origin_x = ReadCoord();
        self.origin_y = ReadCoord();
        self.origin_z = ReadCoord();
        self.maxs_x = ReadCoord();
        self.maxs_y = ReadCoord();
        self.maxs_z = ReadCoord();
        self.velocity = decompressShortVector(ReadShort());
        self.count = ReadShort() * 10;
        self.glow_color = ReadByte(); // color

        self.mins    = -0.5 * self.maxs;
        self.maxs    =  0.5 * self.maxs;
        self.origin  = self.origin - self.mins;

        setorigin(self, self.origin);
        setsize(self, self.mins, self.maxs);
        self.solid = SOLID_NOT;
        if(self.impulse)
                self.draw = Draw_Rain;
        else
                self.draw = Draw_Snow;
}

void Net_ReadVortexBeamParticle()
{
        vector shotorg, endpos;
        float charge;
        shotorg_x = ReadCoord(); shotorg_y = ReadCoord(); shotorg_z = ReadCoord();
        endpos_x = ReadCoord(); endpos_y = ReadCoord(); endpos_z = ReadCoord();
        charge = ReadByte() / 255.0;

        pointparticles(particleeffectnum("nex_muzzleflash"), shotorg, normalize(endpos - shotorg) * 1000, 1);

        //draw either the old v2.3 beam or the new beam
        charge = sqrt(charge); // divide evenly among trail spacing and alpha
        particles_alphamin = particles_alphamax = particles_fade = charge;

        if (autocvar_cl_particles_oldnexbeam && (getstati(STAT_ALLOW_OLDNEXBEAM) || isdemo()))
                WarpZone_TrailParticles_WithMultiplier(world, particleeffectnum("TE_TEI_G3"), shotorg, endpos, 1, PARTICLES_USEALPHA | PARTICLES_USEFADE);
        else
                WarpZone_TrailParticles_WithMultiplier(world, particleeffectnum("nex_beam"), shotorg, endpos, 1, PARTICLES_USEALPHA | PARTICLES_USEFADE);
}

.vector sw_shotorg;
.vector sw_endpos;
.float sw_spread_max;
.float sw_spread_min;
.float sw_time;

void Draw_Shockwave()
{
        float a = bound(0, (0.5 - ((time - self.sw_time) / 0.4)), 0.5);

        if(!a) { remove(self); }
        
        vector deviation, angle;

        vector sw_color = getcsqcplayercolor(self.sv_entnum); // GetTeamRGB(GetPlayerColor(self.sv_entnum));

        vector first_min_end = '0 0 0', prev_min_end = '0 0 0', new_min_end = '0 0 0';
        vector first_max_end = '0 0 0', prev_max_end = '0 0 0', new_max_end = '0 0 0';

        float new_max_dist, new_min_dist;
        
        vector shotdir = normalize(self.sw_endpos - self.sw_shotorg);
        vectorvectors(shotdir);
        vector right = v_right;
        vector up = v_up;
        
        float counter, dist_before_normal = 200, shots = 20;
        
        vector min_end = ((self.sw_shotorg + (shotdir * dist_before_normal)) + (up * self.sw_spread_min));
        vector max_end = (self.sw_endpos + (up * self.sw_spread_max));
        
        float spread_to_min = vlen(normalize(min_end - self.sw_shotorg) - shotdir);
        float spread_to_max = vlen(normalize(max_end - min_end) - shotdir);
        
        for(counter = 0; counter < shots; ++counter)
        {
                // perfect circle effect lines
                angle = '0 0 0';
                makevectors('0 360 0' * (0.75 + (counter - 0.5) / shots));
                angle_y = v_forward_x;
                angle_z = v_forward_y;

                // first do the spread_to_min effect
                deviation = angle * spread_to_min;
                deviation = ((shotdir + (right * deviation_y) + (up * deviation_z)));
                new_min_dist = dist_before_normal;
                new_min_end = (self.sw_shotorg + (deviation * new_min_dist));
                //te_lightning2(world, new_min_end, self.sw_shotorg);

                // then calculate spread_to_max effect
                deviation = angle * spread_to_max;
                deviation = ((shotdir + (right * deviation_y) + (up * deviation_z)));
                new_max_dist = vlen(new_min_end - self.sw_endpos);
                new_max_end = (new_min_end + (deviation * new_max_dist));
                //te_lightning2(world, new_end, prev_min_end);
                

                if(counter == 0)
                {
                        first_min_end = new_min_end;
                        first_max_end = new_max_end;
                }

                if(counter >= 1)
                {
                        R_BeginPolygon("", DRAWFLAG_NORMAL);
                        R_PolygonVertex(prev_min_end, '0 0 0', sw_color, a);
                        R_PolygonVertex(new_min_end, '0 0 0', sw_color, a);
                        R_PolygonVertex(self.sw_shotorg, '0 0 0', sw_color, a);
                        R_EndPolygon();

                        R_BeginPolygon("", DRAWFLAG_NORMAL);
                        R_PolygonVertex(new_min_end, '0 0 0', sw_color, a);
                        R_PolygonVertex(prev_min_end, '0 0 0', sw_color, a);
                        R_PolygonVertex(prev_max_end, '0 0 0', sw_color, a);
                        R_PolygonVertex(new_max_end, '0 0 0', sw_color, a);
                        R_EndPolygon();
                }

                prev_min_end = new_min_end;
                prev_max_end = new_max_end;

                if((counter + 1) == shots)
                {
                        R_BeginPolygon("", DRAWFLAG_NORMAL);
                        R_PolygonVertex(prev_min_end, '0 0 0', sw_color, a);
                        R_PolygonVertex(first_min_end, '0 0 0', sw_color, a);
                        R_PolygonVertex(self.sw_shotorg, '0 0 0', sw_color, a);
                        R_EndPolygon();

                        R_BeginPolygon("", DRAWFLAG_NORMAL);
                        R_PolygonVertex(first_min_end, '0 0 0', sw_color, a);
                        R_PolygonVertex(prev_min_end, '0 0 0', sw_color, a);
                        R_PolygonVertex(prev_max_end, '0 0 0', sw_color, a);
                        R_PolygonVertex(first_max_end, '0 0 0', sw_color, a);
                        R_EndPolygon();
                }
        }
}

void Net_ReadShockwaveParticle()
{
        entity shockwave;
        shockwave = spawn();
        shockwave.draw = Draw_Shockwave;
        
        shockwave.sw_shotorg_x = ReadCoord(); shockwave.sw_shotorg_y = ReadCoord(); shockwave.sw_shotorg_z = ReadCoord();
        shockwave.sw_endpos_x  = ReadCoord(); shockwave.sw_endpos_y  = ReadCoord(); shockwave.sw_endpos_z  = ReadCoord();
        
        shockwave.sw_spread_max = ReadByte();
        shockwave.sw_spread_min = ReadByte();

        shockwave.sv_entnum = ReadByte();

        shockwave.sw_time = time;
}