Difference between revisions of "Template:LSL Function/ParticleSystem"

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(Add reference to PSYS_PART_RIBBON_MASK)
(clarified that the ribbon particle y-size *is* used, but only for purposes of distance culling)
 
(20 intermediate revisions by 5 users not shown)
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{{LSL Const/Signature|PSYS_PART_INTERP_COLOR_MASK|integer|hex=0x001|1}}
{{LSL Const/Signature|PSYS_PART_INTERP_COLOR_MASK|integer|hex=0x001|1}}
{{LSL Const/Signature|PSYS_PART_INTERP_SCALE_MASK|integer|hex=0x002|2}}
{{LSL Const/Signature|PSYS_PART_INTERP_SCALE_MASK|integer|hex=0x002|2}}
{{LSL Const/Signature|PSYS_PART_RIBBON_MASK|integer|hex=0x400|1024}}
{{LSL Const/Signature|PSYS_PART_TARGET_LINEAR_MASK|integer|hex=0x080|128}}
{{LSL Const/Signature|PSYS_PART_TARGET_LINEAR_MASK|integer|hex=0x080|128}}
{{LSL Const/Signature|PSYS_PART_TARGET_POS_MASK|integer|hex=0x040|64}}
{{LSL Const/Signature|PSYS_PART_TARGET_POS_MASK|integer|hex=0x040|64}}
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{{LSL Const/Signature|PSYS_PART_END_SCALE|integer|6}}
{{LSL Const/Signature|PSYS_PART_END_SCALE|integer|6}}
{{LSL Const/Signature|PSYS_SRC_TEXTURE|integer|12}}
{{LSL Const/Signature|PSYS_SRC_TEXTURE|integer|12}}
{{LSL Const/Signature|PSYS_PART_START_GLOW|integer|26}}
{{LSL Const/Signature|PSYS_PART_END_GLOW|integer|27}}
{{LSL Const/Signature|PSYS_SRC_MAX_AGE|integer|19}}
{{LSL Const/Signature|PSYS_SRC_MAX_AGE|integer|19}}
{{LSL Const/Signature|PSYS_PART_MAX_AGE|integer|7}}
{{LSL Const/Signature|PSYS_PART_MAX_AGE|integer|7}}
Line 52: Line 55:
{{LSL Function/color}}
{{LSL Function/color}}
{{LSL Function/alpha}}
{{LSL Function/alpha}}
{{#vardefine:p_rules_desc|Particle system rules list in the format [ rule1, data1, rule2, data2 . . . rule'''n''', data'''n''' ]}}
{{#vardefine:p_rules_hover|Particle system rules list in the format [ rule1, data1, rule2, data2 . . . rulen, datan ]}}
}}<noinclude>
===spec===
</noinclude>{{#if:
{{#vardefine:spec|{{{2|}}}
Each prim has only '''one (1)''' particle emitter, located at its [[geometric center]], and aligned along the prim's [[Viewer coordinate frames#Local|local]] Z-axis, pointing in the positive Z direction.
This is the one of the only {{LSLGC|Particles|functions}} which alters the state of the prim's particle emitter; thus, if you wish to change the emitter to a different state (i.e., emitting a different particle system entirely, or shut off the emitter completely), just call the function with the parameters of the new particle system you wish to render instead. Specifying an empty list (i.e., <code>{{{1}}}</code>; ) turns the emitter off.
Particles are essentially 2D {{Wikipedia|Sprite (computer graphics)|sprites}} and are always rendered facing the viewer's camera.
The  rule / data values are defined below.
{{#var:spec}}}}
}}<noinclude>
{{#var:spec}}
</noinclude>{{#if:
}}<noinclude>
===caveats===
</noinclude>{{#if:
{{#vardefine:caveats|
# When using particle systems that have a non-zero emitter age (PSYS_SRC_MAX_AGE) setting, you may notice that the particle system may restart without any scripted trigger going off. This is due to a bug which causes the emitter to "reset" when any of the prim properties are updated or otherwise sent to the viewer. As a result, you may have to use a [[timer]] or a forced [[llSleep|sleep]] and then clear the particle system once the age has expired. Debbie Trilling has posted a work-around here: http://forums-archive.secondlife.com/54/fa/260031/1.html#post1996465
# The spin defined by PSYS_SRC_OMEGA is relative to the [[Viewer coordinate frames#Region|region]] coordinate system, NOT the prim's [[Viewer coordinate frames#Local|local]] coordinate system.
# When freshly created a prims emitter is set to ZERO_ROTATION within the prim. If whilst designing a particle display you use PSYS_SRC_OMEGA the emitter will be rotated. If then you change the PSYS_SRC_OMEGA vector the emitter will not be reset to ZERO_ROTATION but will remain rotated to whatever axis it was at when stopped or altered. This can result in particles being displayed quite differently in the corrupted prim than they would be using the same script in a fresh prim (with a fresh emitter).
# Particles moving towards a humanoid avatar, specified by PSYS_SRC_TARGET_KEY rule and setting the PSYS_PART_TARGET_POS_MASK flag, will end up at the geometric center of the avatar's bounding box which, unfortunately, make them appear to be striking the person in the groin area. If you want them to end up at another point on a target avatar, you instead have to place a target prim that is moved to the position where you wish them to end up, and use the key of that prim for the value of the PSYS_SRC_TARGET_KEY rule.
# The Second Life viewer uses optimizations in culling objects which are too small to see at certain distances. If your emitter is very small, and is culled due to distance, the particle system associated with it will not be rendered either.
{{#var:caveats}}}}
}}<noinclude>
{{#var:caveats}}
</noinclude>{{#if:
}}<noinclude>
===notes===
</noinclude>{{#if:
{{#vardefine:notes|
* The default particle count for the client is normally set at 4096. That is the max particle count the client will render for ALL active particle systems within view range. Good particle system design is key to avoid "spamming" everyone with your particles, and starving out other people's particle systems. As such, if you are experiencing trouble getting your particle emitter to emit as many particles as you like, it may be the victim of particle starvation. Client/viewer lag (low frame rates) can also cause this issue, as particles are a rather low priority for rendering. The best solution for this is to move to a less laggy environment relatively free of other particle systems when designing and testing your own.
* Once particles are emitted, their direction of motion can only be affected by PSYS_SRC_ACCEL, the PSYS_PART_TARGET_POS_MASK flag, or the PSYS_PART_FOLLOW_SRC_MASK flag. As such, there is no good way to create the "swirling vortex" effect (like the one used in the viewer to indicate an object talking, begin derezzed, or when an avatar leaves the sim/grid). The effect can be created with a moving particle source (E.G. An orbiting script.)
{{#var:notes}}}}
}}<noinclude>
{{#var:notes}}
</noinclude>{{#if:
}}<noinclude>
===helpers===
</noinclude>{{#if:
{{#vardefine:helpers|
'''Useful functions for storing/retrieving color and alpha values to/from integers:'''<br />
<lsl>integer ColorAlphatoRGBA(vector color, float alpha) {
    return (((integer)(alpha  * 255.0) & 0xFF) << 24) |
          (((integer)(color.x * 255.0) & 0xFF) << 16) |
          (((integer)(color.y * 255.0) & 0xFF) <<  8) |
            ((integer)(color.z * 255.0) & 0xFF);
}
vector RGBAtoColor(integer rgba) {
    return < ((rgba >> 16) & 0xFF) / 255.0, ((rgba >> 8) & 0xFF) / 255.0, (rgba & 0xFF) / 255.0 >;
}
float RGBAtoAlpha(integer rgba) {
    return ((rgba >> 24) & 0xFF) / 255.0;
}</lsl>
{{#var:helpers}}}}
}}<noinclude>
{{#var:helpers}}
</noinclude>{{#if:


}}<noinclude>
}}<noinclude>
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{{!}}align="center"{{!}}0
{{!}}align="center"{{!}}0
{{!}}- style="background-color:#e0e0e0;" id="PSYS_PART_BOUNCE_MASK"
{{!}}- style="background-color:#e0e0e0;" id="PSYS_PART_BOUNCE_MASK"
{{!}}rowspan="15" style="background-color:#c0c0c0;" align="center" valign="center"{{!}}'''V<br />a<br />l<br />u<br />e<br />s'''
{{!}}rowspan="13" style="background-color:#c0c0c0;" align="center" valign="center"{{!}}'''V<br />a<br />l<br />u<br />e<br />s'''
{{!}}colspan="2"{{!}}PSYS_PART_BOUNCE_MASK
{{!}}colspan="2"{{!}}PSYS_PART_BOUNCE_MASK
{{!!}}When set, specifies particles will bounce off a plane at the [[Viewer coordinate frames#Region|region]] Z height of the emitter. On "bounce", each particle reverses velocity and angle. This only works for particles above the plane falling down on it.
{{!!}}When set, specifies particles will bounce off a plane at the [[Viewer coordinate frames#Region|region]] Z height of the emitter. On "bounce", each particle reverses its Z-velocity. Particles spawned below the plane will reflect to an equivalent distance above the plane.
{{!}}align="center"{{!}}{{LSL_Hex|0x004|4}}
{{!}}align="center"{{!}}{{LSL_Hex|0x004|4}}
{{!}}- style="background-color:#e0e0e0;" id="PSYS_PART_EMISSIVE_MASK"
{{!}}- style="background-color:#e0e0e0;" id="PSYS_PART_EMISSIVE_MASK"
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{{!!}}When set, particle size/scale transitions from its START setting to its END setting during the particle's lifetime.
{{!!}}When set, particle size/scale transitions from its START setting to its END setting during the particle's lifetime.
{{!}}align="center"{{!}}{{LSL_Hex|0x002|2}}
{{!}}align="center"{{!}}{{LSL_Hex|0x002|2}}
{{!}}- style="background-color:#e0e0e0;" id="PSYS_PART_RIBBON_MASK"
{{!}} colspan="2"{{!}}PSYS_PART_RIBBON_MASK
{{!!}}Joins a stream of particles together into a continuous strip.  Particle textures are stretched (or squeezed) to join their right edges to their predecessor's left.  Ribbon 'width' is controlled by the 'x' values of start and end scale.  The 'y' values are used only for computing the maximum visibility distance of the particles, and the distance between particles controls the 'length' of each ribbon segment instead.  Unlike other particle effects, ribbon segments are not rendered facing the viewer's camera.  The Z axis of each new particle mimics the Z axis of the emitter prim.  Ribbon segments will not render if they have no 'length' - this happens when particles move only 'up' or 'down' the local Z-axis of their emitter prim.  PSYS_PART_FOLLOW_VELOCITY_MASK has no effect on ribbons.  For a simple ribbon effect, try using the DROP pattern, TEXTURE_BLANK, ACCEL and/or WIND.
{{!}}align="center"{{!}}{{LSL_Hex|0x400|1024}}
{{!}}- style="background-color:#e0e0e0;" id="PSYS_PART_TARGET_LINEAR_MASK"
{{!}}- style="background-color:#e0e0e0;" id="PSYS_PART_TARGET_LINEAR_MASK"
{{!}} colspan="2"{{!}}PSYS_PART_TARGET_LINEAR_MASK
{{!}} colspan="2"{{!}}PSYS_PART_TARGET_LINEAR_MASK
{{!!}} When set, emitted particles move in a straight line towards the target specified by the PSYS_SRC_TARGET_KEY rule. In this mode, PSYS_SRC_ACCEL, PSYS_SRC_BURST_RADIUS, and possibly other rules are ignored.
{{!!}} When set, emitted particles move in a straight evenly-spaced line towards the target specified by the PSYS_SRC_TARGET_KEY rule. This option ignores all Non-DROP patterns and their dependent attributes (radius, burst speeds, angles, and omega).  PSYS_SRC_ACCEL and PSYS_PART_WIND_MASK are ignored as well.  Using PSYS_PART_BOUNCE_MASK while the target is 'below' the emitter will cause the linear particle stream to deflect upwards, terminating above the target.
{{!}}align="center"{{!}}{{LSL_Hex|0x080|128}}
{{!}}align="center"{{!}}{{LSL_Hex|0x080|128}}
{{!}}- style="background-color:#e0e0e0;" id="PSYS_PART_TARGET_POS_MASK"
{{!}}- style="background-color:#e0e0e0;" id="PSYS_PART_TARGET_POS_MASK"
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{{!!}}(''unimplemented'') mask but in the enum  
{{!!}}(''unimplemented'') mask but in the enum  
{{!}}align="center"{{!}}{{LSL_Hex|0x200|}}
{{!}}align="center"{{!}}{{LSL_Hex|0x200|}}
{{!}}-
{{!}}- style="background-color:#e0e0e0;" id="PSYS_PART_RIBBON_MASK"
{{!}} colspan="2"{{!}}PSYS_PART_RIBBON_MASK
{{!!}}When set, particles are joined together into one continuous triangle strip
{{!}}align="center"{{!}}{{LSL_Hex|0x400|1024}}
{{!}}-
{{!}}-


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{{!}}-
{{!}}-


<!-- No point in displaying these.
{{!}}- style="background-color:#e0e0e0;" id="LL_PART_RANDOM_ACCEL_MASK"
{{!}}- style="background-color:#e0e0e0;" id="LL_PART_RANDOM_ACCEL_MASK"
{{!}} colspan="2"{{!}}<s style="color:darkred;">LL_PART_RANDOM_ACCEL_MASK</s>
{{!}} colspan="2"{{!}}<s style="color:darkred;">LL_PART_RANDOM_ACCEL_MASK</s>
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{{!}}align="center"{{!}} -
{{!}}align="center"{{!}} -
{{!}}-
{{!}}-
-->


{{!}}- style="background-color:#ccffcc;" id="{{anchorencode:System Presentation}}"
{{!}}- style="background-color:#ccffcc;" id="{{anchorencode:System Presentation}}"
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{{!!}}Specifies the name of a texture in the emitter prim's inventory to use for each particle. Alternatively, you may specify an asset key [[UUID]] for a texture. If using [[llLinkParticleSystem]] and texture is not a UUID, texture must be in the emitter prim (not necessarily with the script).
{{!!}}Specifies the name of a texture in the emitter prim's inventory to use for each particle. Alternatively, you may specify an asset key [[UUID]] for a texture. If using [[llLinkParticleSystem]] and texture is not a UUID, texture must be in the emitter prim (not necessarily with the script).
{{!}}align="center"{{!}}12
{{!}}align="center"{{!}}12
{{!}}- id="PSYS_PART_START_GLOW"
{{!}}colspan="2"{{!}}PSYS_PART_START_GLOW
{{!!}}[[float]] {{LSL Param|glow_start}}
{{!!}}Specifies the glow of the particles upon emission. Valid values are in the range of 0.0 (no glow) to 1.0 (full glow).
{{!}}align="center"{{!}}26
{{!}}- id="PSYS_PART_END_GLOW"
{{!}}colspan="2"{{!}}PSYS_PART_END_GLOW
{{!!}}[[float]] {{LSL Param|glow_end}}
{{!!}}Specifies the glow that the particles transition to during their lifetime. Valid values are the same as PSYS_PART_START_GLOW.
{{!}}align="center"{{!}}27
{{!}}- style="background-color:#ccffcc;" id="{{anchorencode:Particle Blending}}"
{{!}} colspan="5" align="left"{{!}}'''Particle Blending'''
{{!}}- style="background-color:#ffcccc;"
{{!}} colspan="5" align="left"{{!}}'''Note:''' The particle system blend parameters wrap directly to OpenGL's glBlendFunc.  Detailed documentation for glBlendFunc, including formulas, can be found in the [http://www.opengl.org/sdk/docs/man/html/glBlendFunc.xhtml official glBlendFunc documentation]
{{!}}- id="PSYS_PART_BLEND_FUNC_SOURCE"
{{!}} colspan="2"{{!}}PSYS_PART_BLEND_FUNC_SOURCE
{{!!}}[[integer]] {{LSL Param|bf_source}}
{{!!}}Specifies how blending function uses the incoming particle's color and alpha information to produce the rendered result. Defaults to PSYS_PART_BF_SOURCE_ALPHA.
{{!}}align="center"{{!}}24
{{!}}- id="PSYS_PART_BLEND_FUNC_DEST"
{{!}} colspan="2"{{!}}PSYS_PART_BLEND_FUNC_DEST
{{!!}}[[integer]] {{LSL Param|bf_dest}}
{{!!}}Specifies how blending function uses the current framebuffer's color and alpha information to produce the rendered result. Defaults to PSYS_PART_BF_ONE_MINUS_SOURCE_ALPHA.  To make particles blend with the background in a less opaque and more luminescent way use PSYS_PART_BF_ONE for dest and the default for source.  Most other blending combinations will render the invisible/alpha portion of your particle texture, unless the invisible area of your texture is all black (or, in some cases, unless it is all white).
{{!}}align="center"{{!}}25
{{!}}- style="background-color:#e0e0e0;" id="PSYS_PART_BF_ONE"
{{!}}rowspan="8" style="background-color:#c0c0c0;" align="center" valign="center"{{!}}'''V<br />a<br />l<br />u<br />e<br />s'''
{{!}}colspan="2"{{!}}PSYS_PART_BF_ONE
{{!!}}Do not scale the source or destination RGBA values.
{{!}}align="center"{{!}}{{LSL_Hex|0x0|0}}
{{!}}- style="background-color:#e0e0e0;" id="PSYS_PART_BF_ZERO"
{{!}}colspan="2"{{!}}PSYS_PART_BF_ZERO
{{!!}}Zero out the source or destination RGBA values.
{{!}}align="center"{{!}}{{LSL_Hex|0x1|1}}
{{!}}- style="background-color:#e0e0e0;" id="PSYS_PART_BF_DEST_COLOR"
{{!}}colspan="2"{{!}}PSYS_PART_BF_DEST_COLOR
{{!!}}Scale the RGBA values by the RGBA values of the destination.
{{!}}align="center"{{!}}{{LSL_Hex|0x2|2}}
{{!}}- style="background-color:#e0e0e0;" id="PSYS_PART_BF_SOURCE_COLOR"
{{!}}colspan="2"{{!}}PSYS_PART_BF_SOURCE_COLOR
{{!!}}Scale the RGBA values by the RGBA values of the particle source.
{{!}}align="center"{{!}}{{LSL_Hex|0x3|3}}
{{!}}- style="background-color:#e0e0e0;" id="PSYS_PART_BF_ONE_MINUS_DEST_COLOR"
{{!}}colspan="2"{{!}}PSYS_PART_BF_ONE_MINUS_DEST_COLOR
{{!!}}Scale the RGBA values by the inverted RGBA values of the destination.
{{!}}align="center"{{!}}{{LSL_Hex|0x4|4}}
{{!}}- style="background-color:#e0e0e0;" id="PSYS_PART_BF_ONE_MINUS_SOURCE_COLOR"
{{!}}colspan="2"{{!}}PSYS_PART_BF_ONE_MINUS_SOURCE_COLOR
{{!!}}Scale the RGBA values by the inverted RGBA values of the particle source.
{{!}}align="center"{{!}}{{LSL_Hex|0x5|5}}
{{!}}- style="background-color:#e0e0e0;" id="PSYS_PART_BF_SOURCE_ALPHA"
{{!}}colspan="2"{{!}}PSYS_PART_BF_SOURCE_ALPHA
{{!!}}Scale the RGBA values by the alpha values of the particle source.
{{!}}align="center"{{!}}{{LSL_Hex|0x7|7}}
{{!}}- style="background-color:#e0e0e0;" id="PSYS_PART_BF_ONE_MINUS_SOURCE_ALPHA"
{{!}}colspan="2"{{!}}PSYS_PART_BF_ONE_MINUS_SOURCE_ALPHA
{{!!}}Scale the RGBA values by the inverted alpha values of the particle source.
{{!}}align="center"{{!}}{{LSL_Hex|0x9|9}}
{{!}}- style="background-color:#ccffcc;" id="{{anchorencode:Particle Flow}}"
{{!}}- style="background-color:#ccffcc;" id="{{anchorencode:Particle Flow}}"
{{!}}colspan="5" align="left"{{!}}'''Particle Flow'''
{{!}}colspan="5" align="left"{{!}}'''Particle Flow'''
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{{!}}colspan="2"{{!}}PSYS_SRC_OMEGA
{{!}}colspan="2"{{!}}PSYS_SRC_OMEGA
{{!!}}[[vector]] {{LSL Param|omega}}
{{!!}}[[vector]] {{LSL Param|omega}}
{{!!}}Specifies the rotational spin of the emitter in radians per second along each axis. This "unsticks" the emitter facing from the prim's positive Z axis and is noticeable in directional presentations. Prim spin (via [[llTargetOmega]]) has no effect on emitter spin. ([[#Caveats|caveat 2]] and [[#Caveats|caveat 3]])
{{!!}}Sets how far to rotate the "pattern" after each particle burst.  (Burst frequency is set with PSYS_SRC_BURST_RATE.)  Omega values are approximately 'radians per burst' around the prim's global (not local) X,Y,Z axes.  For precise and predictable pattern rotation, rotate the prim instead of using PSYS_SRC_OMEGA. Omega has no visible effect on drop, explode and certain specific angle and angle cone patterns, depending on prim orientation.  Pattern rotation can be used with prim orientation and llTargetOmega() but won't produce consistent results. ([[#Caveats|caveat 2]] and [[#Caveats|caveat 3]])
{{!}}align="center"{{!}}21
{{!}}align="center"{{!}}21
{{!}}- id="PSYS_SRC_BURST_SPEED_MIN"
{{!}}- id="PSYS_SRC_BURST_SPEED_MIN"
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{{!!}}Specifies the maximum value of a random range of values which is selected for each particle in a burst as its initial speed upon emission, in meters per second. Note that the value of this parameter and PSYS_SRC_BURST_SPEED_MIN are internally re-ordered such that this parameter gets the larger of the two values.
{{!!}}Specifies the maximum value of a random range of values which is selected for each particle in a burst as its initial speed upon emission, in meters per second. Note that the value of this parameter and PSYS_SRC_BURST_SPEED_MIN are internally re-ordered such that this parameter gets the larger of the two values.
{{!}}align="center"{{!}}18
{{!}}align="center"{{!}}18
{{!}}-
<!--
{{!}}- id="{{anchorencode:Constant Footnotes}}"
{{!}}- id="{{anchorencode:Constant Footnotes}}"
{{!}} style="font-size:80%" colspan="5" {{!}} LL_PART_* constants are only found in {{SourceLink|indra/llmessage/llpartdata.h|rev=1681|line=99}}, those flags in <span style="color:darkred;">red</span> have been commented out.
{{!}} style="font-size:80%" colspan="5" {{!}} LL_PART_* constants are only found in {{SourceLink|indra/llmessage/llpartdata.h|rev=1681|line=99}}, those flags in <span style="color:darkred;">red</span> have been commented out.
{{!}}-
-->
{{!}}-
{{!}}} }}
{{!}}} }}
}}<noinclude>
}}<noinclude>
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}}<noinclude>
}}<noinclude>
===deepnotes===
</noinclude>{{#if:
{{#vardefine:deepnotes|
===Missing 14===
There is a missing constant which would have the value 14, the underlying enumeration {{SourceLink|indra/llmessage/llpartdata.h|rev=1681|line=51|text=LLPSScriptFlags}} has that as {{SourceLink|indra/llmessage/llpartdata.h|rev=1681|line=70|text=LLPS_SRC_BURST_DURATION}}, the value is used nowhere else in the client source. This isn't surprising considering that the burst duration is dependent on the values of PSYS_SRC_BURST_PART_COUNT and PSYS_SRC_BURST_RATE.
{{#var:deepnotes}}}}
}}<noinclude>
{{#var:deepnotes}}


====Signature====
====Signature====

Latest revision as of 10:13, 5 November 2023

constants_nb

Rule / Value Constant Rule Parameter Description Value
System Behavior
PSYS_PART_FLAGS integer flags Various flags controlling the behavior of the particle system. The value may be specified as an integer in decimal or hex format, or by ORing together (using the | operator) one or more of the following flag constants: 0
V
a
l
u
e
s 		PSYS_PART_BOUNCE_MASK When set, specifies particles will bounce off a plane at the region Z height of the emitter. On "bounce", each particle reverses its Z-velocity. Particles spawned below the plane will reflect to an equivalent distance above the plane. 0x004
PSYS_PART_EMISSIVE_MASK When set, particles are full-bright and are unaffected by global lighting (sunlight). Otherwise, particles will be lit depending on the current global lighting conditions. Note that point lights do illuminate non-emissive particles. 0x100
PSYS_PART_FOLLOW_SRC_MASK When set, particles move relative to the position of the emitter. Otherwise, particle position and movement are unaffected by the position/movement of the emitter. This flag disables the PSYS_SRC_BURST_RADIUS rule. 0x010
PSYS_PART_FOLLOW_VELOCITY_MASK When set, particles rotate to orient their "top" towards the direction of movement or emission. Otherwise, particles are oriented vertically as their textures would appear (top of texture at top, left at left). 0x020
PSYS_PART_INTERP_COLOR_MASK When set, particle color and alpha transition from their START settings to their END settings during the particle's lifetime. The transition is a smooth interpolation. 0x001
PSYS_PART_INTERP_SCALE_MASK When set, particle size/scale transitions from its START setting to its END setting during the particle's lifetime. 0x002
PSYS_PART_RIBBON_MASK Joins a stream of particles together into a continuous strip. Particle textures are stretched (or squeezed) to join their right edges to their predecessor's left. Ribbon 'width' is controlled by the 'x' values of start and end scale. The 'y' values are used only for computing the maximum visibility distance of the particles, and the distance between particles controls the 'length' of each ribbon segment instead. Unlike other particle effects, ribbon segments are not rendered facing the viewer's camera. The Z axis of each new particle mimics the Z axis of the emitter prim. Ribbon segments will not render if they have no 'length' - this happens when particles move only 'up' or 'down' the local Z-axis of their emitter prim. PSYS_PART_FOLLOW_VELOCITY_MASK has no effect on ribbons. For a simple ribbon effect, try using the DROP pattern, TEXTURE_BLANK, ACCEL and/or WIND. 0x400
PSYS_PART_TARGET_LINEAR_MASK When set, emitted particles move in a straight evenly-spaced line towards the target specified by the PSYS_SRC_TARGET_KEY rule. This option ignores all Non-DROP patterns and their dependent attributes (radius, burst speeds, angles, and omega). PSYS_SRC_ACCEL and PSYS_PART_WIND_MASK are ignored as well. Using PSYS_PART_BOUNCE_MASK while the target is 'below' the emitter will cause the linear particle stream to deflect upwards, terminating above the target. 0x080
PSYS_PART_TARGET_POS_MASK When set, emitted particles change course during their lifetime, attempting to move towards the target specified by the PSYS_SRC_TARGET_KEY rule by the time they expire. Note that if no target is specified, the target moves out of range, or an invalid target is specified, the particles target the prim itself. 0x040
PSYS_PART_WIND_MASK When set, particle movement is affected by the wind. It is applied as a secondary force on the particles. 0x008
PSYS_PART_BEAM_MASK (unimplemented) mask but in the enum 0x200
LL_PART_HUD Used by the viewer to keep HUD and World particle sources separate. 0x40000000
LL_PART_DEAD_MASK Removes particles, not compatible with any other PSYS_PART_*_MASK 0x80000000
System Presentation
PSYS_SRC_PATTERN integer pattern Specifies the general emission pattern. 9
V
a
l
u
e
s 		PSYS_SRC_PATTERN_EXPLODE Sprays particles outwards in a spherical area. The Initial velocity of each particle is determined by PSYS_SRC_BURST_SPEED_MIN and PSYS_SRC_BURST_SPEED_MAX. The EXPLODE pattern ignores the ANGLE parameters. 0x02
PSYS_SRC_PATTERN_ANGLE_CONE Sprays particles outwards in a spherical, sub-spherical, conical or ring shaped area, as defined by the ANGLE parameters PSYS_SRC_ANGLE_BEGIN and PSYS_SRC_ANGLE_END. The ANGLE_CONE pattern can be used to imitate the EXPLODE pattern by explicitly setting PSYS_SRC_ANGLE_BEGIN to 0.00000 and PSYS_SRC_ANGLE_END to 3.14159 (or PI) (or vice versa). 0x08
PSYS_SRC_PATTERN_ANGLE Sprays particles outward in a flat circular, semi-circular, arc or ray shaped areas, as defined by PSYS_SRC_ANGLE_BEGIN and PSYS_SRC_ANGLE_END. The circular pattern radiates outwards around the prim's local X axis line. 0x04
PSYS_SRC_PATTERN_DROP Creates particles with no initial velocity. The DROP pattern will override any values given for PSYS_SRC_BURST_RADIUS, PSYS_SRC_BURST_SPEED_MIN, and PSYS_SRC_BURST_SPEED_MAX, setting each to 0.00000. (All patterns will behave like the DROP pattern, if RADIUS, SPEED_MIN and SPEED_MAX are explicitly set to 0.0000.) 0x01
PSYS_SRC_PATTERN_ANGLE_CONE_EMPTY (incomplete implementation) acts the same as the PSYS_SRC_PATTERN_DROP pattern, it is believed that the original intention for this pattern was to invert the effect of the ANGLE parameters, making them delineate an area where particles were NOT to be sprayed. (effectively the inverse or opposite of the behavior of the ANGLE_CONE pattern). 0x10
PSYS_SRC_BURST_RADIUS float radius Specifies the distance from the emitter where particles will be created. This rule is ignored when the PSYS_PART_FOLLOW_SRC_MASK flag is set. A test in http://forums-archive.secondlife.com/327/f5/226722/1.html indicates that the maximum value is 50.00 16
PSYS_SRC_ANGLE_BEGIN float angle_begin Specifies a half angle, in radians, of a circular or spherical "dimple" or conic section (starting from the emitter facing) within which particles will NOT be emitted. Valid values are the same as for PSYS_SRC_ANGLE_END, though the effects are reversed accordingly. If the pattern is PSYS_SRC_PATTERN_ANGLE, the presentation is a 2D flat circular section. If PSYS_SRC_PATTERN_ANGLE_CONE or PSYS_SRC_PATTERN_ANGLE_CONE_EMPTY is used, the presentation is a 3D spherical section. Note that the value of this parameter and PSYS_SRC_ANGLE_END are internally re-ordered such that this parameter gets the smaller of the two values. 22
PSYS_SRC_ANGLE_END float angle_end Specifies a half angle, in radians, of a circular or spherical "dimple" or conic section (starting from the emitter facing) within which particles WILL be emitted. Valid values are 0.0, which will result in particles being emitted in a straight line in the direction of the emitter facing, to PI, which will result in particles being emitted in a full circular or spherical arc around the emitter, not including the "dimple" or conic section defined by PSYS_SRC_ANGLE_BEGIN. If the pattern is PSYS_SRC_PATTERN_ANGLE, the presentation is a 2D flat circular section. If PSYS_SRC_PATTERN_ANGLE_CONE or PSYS_SRC_PATTERN_ANGLE_CONE_EMPTY is used, the presentation is a 3D spherical section. Note that the value of this parameter and PSYS_SRC_ANGLE_BEGIN are internally re-ordered such that this parameter gets the larger of the two values. 23
PSYS_SRC_INNERANGLE float angle_inner DEPRECATED: Use PSYS_SRC_ANGLE_BEGIN instead. Works similar to its replacement rule, except the edge of the section is aligned with the emitter facing, rather than its center. 10
PSYS_SRC_OUTERANGLE float angle_outer DEPRECATED: Use PSYS_SRC_ANGLE_END instead. Works similar to its replacement rule, except the edge of the section is aligned with the emitter facing, rather than the section's center. 11
PSYS_SRC_TARGET_KEY key target Specifies the key of a target object, prim, or agent towards which the particles will change course and move (if PSYS_PART_TARGET_POS_MASK is specified) or will move in a straight line (if PSYS_PART_TARGET_LINEAR_MASK is specified). They will attempt to end up at the geometric center of the target at the end of their lifetime. Requires the PSYS_PART_TARGET_POS_MASK or PSYS_PART_TARGET_LINEAR_MASK flag be set. caveat 4 20
Particle Appearance
PSYS_PART_START_COLOR vector color_start A vector specifying the color of the particles upon emission. 1
PSYS_PART_END_COLOR vector color_end A vector specifying the color the particles transition to during their lifetime. Only used if the PSYS_PART_INTERP_COLOR_MASK flag is set. 3
PSYS_PART_START_ALPHA float alpha_start Specifies the alpha of the particles upon emission. Valid values are in the range 0.0 to 1.0. Lower values are more transparent; higher ones are more opaque. 2
PSYS_PART_END_ALPHA float alpha_end Specifies the alpha the particles transition to during their lifetime. Only used if the PSYS_PART_INTERP_COLOR_MASK flag is set. Valid values are the same as PSYS_PART_START_ALPHA. 4
PSYS_PART_START_SCALE vector scale_start Specifies the scale or size of the particles upon emission. Valid values for each direction are 0.03125 to 4.0, in meters. The actual particle size is always a multiple of 0.03125. Smaller changes don't have any effect. Since particles are essentially 2D sprites, the Z component of the vector is ignored and can be set to 0.0. 5
PSYS_PART_END_SCALE vector scale_end Specifies the scale or size the particles transition to during their lifetime. Only used if the PSYS_PART_INTERP_SCALE_MASK flag is set. Valid values are the same as PSYS_PART_START_SCALE. 6
PSYS_SRC_TEXTURE string texture Specifies the name of a texture in the emitter prim's inventory to use for each particle. Alternatively, you may specify an asset key UUID for a texture. If using llLinkParticleSystem and texture is not a UUID, texture must be in the emitter prim (not necessarily with the script). 12
PSYS_PART_START_GLOW float glow_start Specifies the glow of the particles upon emission. Valid values are in the range of 0.0 (no glow) to 1.0 (full glow). 26
PSYS_PART_END_GLOW float glow_end Specifies the glow that the particles transition to during their lifetime. Valid values are the same as PSYS_PART_START_GLOW. 27
Particle Blending
Note: The particle system blend parameters wrap directly to OpenGL's glBlendFunc. Detailed documentation for glBlendFunc, including formulas, can be found in the official glBlendFunc documentation
PSYS_PART_BLEND_FUNC_SOURCE integer bf_source Specifies how blending function uses the incoming particle's color and alpha information to produce the rendered result. Defaults to PSYS_PART_BF_SOURCE_ALPHA. 24
PSYS_PART_BLEND_FUNC_DEST integer bf_dest Specifies how blending function uses the current framebuffer's color and alpha information to produce the rendered result. Defaults to PSYS_PART_BF_ONE_MINUS_SOURCE_ALPHA. To make particles blend with the background in a less opaque and more luminescent way use PSYS_PART_BF_ONE for dest and the default for source. Most other blending combinations will render the invisible/alpha portion of your particle texture, unless the invisible area of your texture is all black (or, in some cases, unless it is all white). 25
V
a
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s 		PSYS_PART_BF_ONE Do not scale the source or destination RGBA values. 0x0
PSYS_PART_BF_ZERO Zero out the source or destination RGBA values. 0x1
PSYS_PART_BF_DEST_COLOR Scale the RGBA values by the RGBA values of the destination. 0x2
PSYS_PART_BF_SOURCE_COLOR Scale the RGBA values by the RGBA values of the particle source. 0x3
PSYS_PART_BF_ONE_MINUS_DEST_COLOR Scale the RGBA values by the inverted RGBA values of the destination. 0x4
PSYS_PART_BF_ONE_MINUS_SOURCE_COLOR Scale the RGBA values by the inverted RGBA values of the particle source. 0x5
PSYS_PART_BF_SOURCE_ALPHA Scale the RGBA values by the alpha values of the particle source. 0x7
PSYS_PART_BF_ONE_MINUS_SOURCE_ALPHA Scale the RGBA values by the inverted alpha values of the particle source. 0x9
Particle Flow
PSYS_SRC_MAX_AGE float duration_system Specifies the length of time, in seconds, that the emitter will operate upon coming into view range (if the particle system is already set) or upon execution of this function (if already in view range). Upon expiration, no more particles will be emitted, except as specified above. Zero will give the particle system an infinite duration. (caveat 1) 19
PSYS_PART_MAX_AGE float duration_particle Specifies the lifetime of each particle emitted, in seconds. Maximum is 30.0 seconds. During this time, the particle will appear, change appearance and move according to the parameters specified in the other sections, and then disappear. 7
PSYS_SRC_BURST_RATE float burst_sleep Specifies the time interval, in seconds, between "bursts" of particles being emitted. Specifying a value of 0.0 will cause the emission of particles as fast as the viewer can do so. 13
PSYS_SRC_BURST_PART_COUNT integer burst_particle_count Specifies the number of particles emitted in each "burst". 15
Particle Motion
PSYS_SRC_ACCEL vector acceleration Specifies a directional acceleration vector applied to each particle as it is emitted, in meters per second squared. Valid values are 0.0 to 100.0 for each direction both positive and negative, as region coordinates. 8
PSYS_SRC_OMEGA vector omega Sets how far to rotate the "pattern" after each particle burst. (Burst frequency is set with PSYS_SRC_BURST_RATE.) Omega values are approximately 'radians per burst' around the prim's global (not local) X,Y,Z axes. For precise and predictable pattern rotation, rotate the prim instead of using PSYS_SRC_OMEGA. Omega has no visible effect on drop, explode and certain specific angle and angle cone patterns, depending on prim orientation. Pattern rotation can be used with prim orientation and llTargetOmega() but won't produce consistent results. (caveat 2 and caveat 3) 21
PSYS_SRC_BURST_SPEED_MIN float speed_min Specifies the minimum value of a random range of values which is selected for each particle in a burst as its initial speed upon emission, in meters per second. Note that the value of this parameter and PSYS_SRC_BURST_SPEED_MAX are internally re-ordered such that this parameter gets the smaller of the two values. 17
PSYS_SRC_BURST_SPEED_MAX float speed_max Specifies the maximum value of a random range of values which is selected for each particle in a burst as its initial speed upon emission, in meters per second. Note that the value of this parameter and PSYS_SRC_BURST_SPEED_MIN are internally re-ordered such that this parameter gets the larger of the two values. 18


Signature

integer PSYS_PART_FLAGS = 0;
integer PSYS_PART_BOUNCE_MASK = 0x004;
integer PSYS_PART_EMISSIVE_MASK = 0x100;
integer PSYS_PART_FOLLOW_SRC_MASK = 0x010;
integer PSYS_PART_FOLLOW_VELOCITY_MASK = 0x020;
integer PSYS_PART_INTERP_COLOR_MASK = 0x001;
integer PSYS_PART_INTERP_SCALE_MASK = 0x002;
integer PSYS_PART_RIBBON_MASK = 0x400;
integer PSYS_PART_TARGET_LINEAR_MASK = 0x080;
integer PSYS_PART_TARGET_POS_MASK = 0x040;
integer PSYS_PART_WIND_MASK = 0x008;
integer PSYS_SRC_PATTERN = 9;
integer PSYS_SRC_PATTERN_EXPLODE = 0x02;
integer PSYS_SRC_PATTERN_ANGLE_CONE = 0x08;  
integer PSYS_SRC_PATTERN_ANGLE = 0x04;
integer PSYS_SRC_PATTERN_DROP = 0x01;
integer PSYS_SRC_PATTERN_ANGLE_CONE_EMPTY = 0x10;
integer PSYS_SRC_BURST_RADIUS = 16;
integer PSYS_SRC_ANGLE_BEGIN = 22;
integer PSYS_SRC_ANGLE_END = 23;
integer PSYS_SRC_INNERANGLE = 10;//deprecated
integer PSYS_SRC_OUTERANGLE = 11;//deprecated
integer PSYS_SRC_TARGET_KEY = 20;
integer PSYS_PART_START_COLOR = 1;
integer PSYS_PART_END_COLOR = 3;
integer PSYS_PART_START_ALPHA = 2;
integer PSYS_PART_END_ALPHA = 4;
integer PSYS_PART_START_SCALE = 5;
integer PSYS_PART_END_SCALE = 6;
integer PSYS_SRC_TEXTURE = 12;
integer PSYS_PART_START_GLOW = 26;
integer PSYS_PART_END_GLOW = 27;
integer PSYS_SRC_MAX_AGE = 19;
integer PSYS_PART_MAX_AGE = 7;
integer PSYS_SRC_BURST_RATE = 13;
integer PSYS_SRC_BURST_PART_COUNT = 15;
integer PSYS_SRC_ACCEL = 8;
integer PSYS_SRC_OMEGA = 21;
integer PSYS_SRC_BURST_SPEED_MIN = 17;
integer PSYS_SRC_BURST_SPEED_MAX = 18;


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