Difference between revisions of "LlCastRay"

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|func_energy
|func_energy


|func_desc=Cast a ray from '''{{LSL Param|start}}''' to '''{{LSL Param|end}}''' and report collision data for intersections with objects
|func_desc=Cast a line from {{LSLP|start}} to {{LSLP|end}} and report collision data for intersections with objects.


|return_type=list
|return_type=list
|return_text=of strided values with an additional integer '''[[#status_code|{{LSL Param|status_code}}]]''' on the end. Each stride consists of two mandatory values {[[key]] '''{{LSL Param|uuid}}''', [[vector]] '''{{LSL Param|position}}'''} and possibly some optional values {[[integer]] '''{{LSL Param|link_number}}''', [[vector]] '''{{LSL Param|normal}}'''} see [[#RC_DATA_FLAGS|RC_DATA_FLAGS]] for details. The '''{{LSL Param|status_code}}''' if it is negative is an [[#error_code|error code]], otherwise it is the number of hits (and strides) returned.
|return_text=of strided values on a successful hit, with an additional integer [[#status_code|status_code]] at the end.
|func_footnote


Each stride consists of two mandatory values {[[key]] {{LSLP|uuid}}, [[vector]] {{LSLP|position}}} and optionally {[[integer]] {{LSLP|link_number}}, [[vector]] {{LSLP|normal}}}. (See [[#RC_DATA_FLAGS|RC_DATA_FLAGS]] for details.)
A negative {{LSLP|status_code}} is an [[#error_code|error code]], otherwise it is the number of hits (and strides) returned.
|func_footnote=
Example return of successful raycast, using the default options:
<syntaxhighlight lang="lsl2">
[key object_uuid, vector hit_position, integer status_code]
</syntaxhighlight>
In the case of an error, or if the ray hits nothing, the resulting list only contains the status code:
<syntaxhighlight lang="lsl2">
[integer status_code]
</syntaxhighlight>
|p1_type=vector|p1_name=start|p1_desc=starting location  
|p1_type=vector|p1_name=start|p1_desc=starting location  
|p2_type=vector|p2_name=end|p2_desc=ending location  
|p2_type=vector|p2_name=end|p2_desc=ending location  
|p3_type=list|p3_name=options|p3_desc=can consists of any number of [[#options|option flag]]s and their parameters.
|p3_type=list|p3_subtype=instructions|p3_name=options|p3_desc=can consists of any number of [[#options|option flag]]s and their parameters.
|constants
|constants
|caveats=*Depending upon the value of '''{{LSL Param|flags}}''' (provided via [[#RC_DATA_FLAGS|RC_DATA_FLAGS]]), the number and types of values in the strides will vary. See [[#RC_DATA_FLAGS|RC_DATA_FLAGS]] for details.
|caveats=*Depending upon the value of {{LSLP|flags}} (provided via [[#RC_DATA_FLAGS|RC_DATA_FLAGS]]), the number and types of values in the strides will vary. See [[#RC_DATA_FLAGS|RC_DATA_FLAGS]] for details.
*Due to an accuracy issue with an avatar's visible rotation in the viewer (see {{jira|VWR-1331}}), any line traced using an avatar's current position and rotation may not match what a viewer sees, and may not match the direction of any particles emitted by that avatar's attachments. The result is that particle effects or avatar direction may appear up to 15º out from the line a ray-cast will trace, requiring objects to be rezzed to produce accurate visual effects for ray-cast operation.
*[[llGetRot]] will not return an avatar's exact visual rotation because the viewer doesn't update the avatar's rotation under a threshold (see {{jira|VWR-1331}}). To get an avatar's exact looking direction while in mouselook, use [[llGetCameraRot]] instead.
*[[llCastRay]] will not detect prims having no physics shape ([[PRIM_PHYSICS_SHAPE_TYPE]] = [[PRIM_PHYSICS_SHAPE_NONE]]).
*[[llCastRay]] will not detect a prim if the line starts inside the prim. This makes it safe to use the prim position as the start location.
*[[llCastRay]] can detect the prim the script is in, if the start location is outside the prim.
* The result of this function has been noted to be '''unreliable when the end point is out-of-bounds''' (Occasionally returns status code 0 regardless of amount of objects hit). (See [https://community.secondlife.com/forums/topic/486603-llcastray-returning-zero-hits-seemingly-at-random/ this forum post])
** The random failures seem to happen if the ray begins or ends more than 8 meters outside of current region bounds. Changes in only the ray's angle, or only in its position, may change the result. The result does not change if the exact same ray is cast again.
|spec=
|spec=
===={{LSL Param|status_code}}====
===={{LSL Param|status_code}}====


'''{{LSL Param|status_code}}''' is a number tacked onto the end of the strided list to give you extra information about the ray cast. If the cast succeeded, it will be &gt;=0 and will indicate the number of hits. If the ray cast failed (which should only happen right now if the simulator performance is running low), you'll get a negative status code. [[RCERR_SIM_PERF_LOW]] will be used as the status code if the overall physics time in the simulator is too high to perform raycasts. The idea is that you will know to try your cast again in a few frames.
{{LSLP|status_code}} is a number tacked onto the end of the strided list to give you extra information about the ray cast.
 
If the cast succeeded, it will be &gt;=0 and will indicate the number of hits.
 
If the ray cast failed (which should only happen right now if the simulator performance is running low), you'll get a negative status code. [[RCERR_SIM_PERF_LOW]] will be used as the status code if the overall physics time in the simulator is too high to perform raycasts. The idea is that you will know to try your cast again in a few frames.


<table class="lltable" border="1" id="error_code">
<table class="lltable" border="1" id="error_code">
Line 30: Line 50:
<th>Description</th>
<th>Description</th>
</tr>
</tr>
<tr><td>{{LSL Const|RCERR_UNKNOWN|integer}}</td><td>{{#var:value}}</td><td>The raycast failed for an unspecified reason. Please submit a bug report.</td></tr>
<tr><td>{{LSL Const|RCERR_UNKNOWN|integer|-1}}</td><td>{{#var:value}}</td><td>The raycast failed for an unspecified reason. Please submit a bug report.</td></tr>
<tr><td>{{LSL Const|RCERR_SIM_PERF_LOW|integer}}</td><td>{{#var:value}}</td><td>The raycast failed because simulator performance is low. Wait a while and then try again. If possible reduce the scene complexity.</td></tr>
<tr><td>{{LSL Const|RCERR_SIM_PERF_LOW|integer|-2}}</td><td>{{#var:value}}</td><td>The raycast failed because simulator performance is low. Wait a while and then try again. If possible reduce the scene complexity.</td></tr>
<tr><td>{{LSL Const|RCERR_CAST_TIME_EXCEEDED|integer}}</td><td>{{#var:value}}</td><td>The raycast failed because the parcel or agent has exceeded the maximum time allowed for raycasting. This resource pool is continually replenished, so waiting a few frames and retrying is likely to succeed.</td></tr>
<tr><td>{{LSL Const|RCERR_CAST_TIME_EXCEEDED|integer|-3}}</td><td>{{#var:value}}</td><td>The raycast failed because the parcel or agent has exceeded the maximum time allowed for raycasting. This resource pool is continually replenished, so waiting a few frames and retrying is likely to succeed.</td></tr>
</table>
</table>


=====[[RCERR_CAST_TIME_EXCEEDED]]=====
=====[[RCERR_CAST_TIME_EXCEEDED]]=====
Ray casts are throttled by the amount of time actually taken to perform the cast. Each region is allotted a 2ms pool, divided proportionally over parcels the same way prim limits are. Each agent is allotted 50us. All scripts in attachments and, objects on which an avatar is seated, use the agent pool whereas all scripts use the parcel pool. A ray cast can be performed if at least 30us of raycast time remain in the appropriate pool. If there is insufficient time remaining, [[RCERR_CAST_TIME_EXCEEDED]] is returned as the status code. The exact time used by the ray cast is measured when it is performed and that number (in microseconds) is subtracted from the pool. (The time remaining can be a negative number.) Over time, the pool is automatically replenished (at a rate of 25% of the max time per frame).
'''Note:''' [https://jira.secondlife.com/browse/SCR-199 SCR-199] indicates that pools have been removed from the main grid, so this return code should not appear.
 
For example, if you start out with 100us and perform a 50us raycast, 50us will be remain. If you then a 70us raycast during the same frame, you will have -20us remaining. Subsequent calls to llCastRay that frame will fail with status code [[RCERR_CAST_TIME_EXCEEDED]]. At the start of the next frame, you will have 5us available (25us are restored each frame) and any attempt to call llCastRay will again fail as you need 30us to execute a raycast. One frame after that, 30us will be available and a raycast can once again be performed.
 
This method of throttling puts the scripter "closer to the machine". That is, you're only being charged for what you use, and more efficient raycast techniques will automatically be charged less than less efficient ones. The exact throttle values are subject to change at any time. To ensure robust results, be sure to check for [[RCERR_CAST_TIME_EXCEEDED]] and [[RCERR_SIM_PERF_LOW]] and sleep or do other work for a while before trying again.


'''Tips for Efficient Raycasts:'''
'''Tips for Efficient Raycasts:'''
Line 50: Line 66:


<table class=lltable border=1 id="options">
<table class=lltable border=1 id="options">
<caption>'''{{LSL Param|options}}''' flags and their parameters</caption>
<caption>{{LSLP|options}} flags and their parameters</caption>
<tr>
<tr>
<th>Flag</th>
<th>Flag</th>
Line 58: Line 74:
<th>Description</th>
<th>Description</th>
</tr>
</tr>
<tr><td>[&nbsp;{{LSL Const|RC_REJECT_TYPES|integer}}&nbsp;] </td>
<tr><td>[&nbsp;{{LSL Const|RC_REJECT_TYPES|integer|0}}&nbsp;] </td>
<td>{{#var:value}}</td>
<td>{{#var:value}}</td>
<td>[&nbsp;[[integer]]&nbsp;{{LSL Param|filter}}&nbsp;]</td>
<td>[&nbsp;[[integer]]&nbsp;{{LSLPT|filter}}&nbsp;]</td>
<td>[ 0 ]</td>
<td>[ 0 ]</td>
<td> Mask used to ignore specific types of objects (and avatars). </td>
<td> Mask used to ignore specific types of objects (and avatars). </td>
</tr>
</tr>
<tr><td>[&nbsp;{{LSL Const|RC_DATA_FLAGS|integer}}&nbsp;] </td>
<tr><td>[&nbsp;{{LSL Const|RC_DATA_FLAGS|integer|2}}&nbsp;] </td>
<td>{{#var:value}}</td>
<td>{{#var:value}}</td>
<td>[&nbsp;[[integer]]&nbsp;{{LSL Param|flags}}&nbsp;]</td>
<td>[&nbsp;[[integer]]&nbsp;{{LSLPT|flags}}&nbsp;]</td>
<td>[ 0 ]</td>
<td>[ 0 ]</td>
<td> Described in the [[#RC_DATA_FLAGS|RC_DATA_FLAGS]] section. </td>
<td> Described in the [[#RC_DATA_FLAGS|RC_DATA_FLAGS]] section. </td>
</tr>
</tr>
<tr><td>[&nbsp;{{LSL Const|RC_MAX_HITS|integer}}&nbsp;] </td>
<tr><td>[&nbsp;{{LSL Const|RC_MAX_HITS|integer|3}}&nbsp;] </td>
<td>{{#var:value}}</td>
<td>{{#var:value}}</td>
<td>[&nbsp;[[integer]]&nbsp;{{LSL Param|max_hits}}&nbsp;]</td>
<td>[&nbsp;[[integer]]&nbsp;{{LSLPT|max_hits}}&nbsp;]</td>
<td>[ 1 ]</td>
<td>[ 1 ]</td>
<td> Maximum number of hits to return. Maximum value is 256. ''To avoid performance issues, keep it small.''</td>
<td> Maximum number of hits to return. Maximum value is 256. ''To avoid performance issues, keep it small.''</td>
</tr>
</tr>
<tr><td>[&nbsp;{{LSL Const|RC_DETECT_PHANTOM|integer}}&nbsp;] </td>
<tr><td>[&nbsp;{{LSL Const|RC_DETECT_PHANTOM|integer|1}}&nbsp;] </td>
<td>{{#var:value}}</td>
<td>{{#var:value}}</td>
<td>[&nbsp;[[integer]]&nbsp;{{LSL Param|detect_phantom}}&nbsp;]</td>
<td>[&nbsp;[[integer]]&nbsp;{{LSLPT|detect_phantom}}&nbsp;]</td>
<td>[ [[FALSE]] ]</td>
<td>[ [[FALSE]] ]</td>
<td>Set to [[TRUE]] (or nonzero) to detect phantom AND volume detect objects. It is not possible to detect only phantom objects or only volume detect objects. If set to [[TRUE]], phantom and volume detect objects will always be detected, even if [[RC_REJECT_NONPHYSICAL]] and [[RC_REJECT_PHYSICAL]] are set in [[RC_REJECT_TYPES]].</td>
<td>Set to [[TRUE]] (or nonzero) to detect phantom AND volume detect objects. It is not possible to detect only phantom objects or only volume detect objects. If set to [[TRUE]], phantom and volume detect objects will always be detected, even if [[RC_REJECT_NONPHYSICAL]] and [[RC_REJECT_PHYSICAL]] are set in [[RC_REJECT_TYPES]].</td>
Line 86: Line 102:
=====[[RC_REJECT_TYPES]]=====
=====[[RC_REJECT_TYPES]]=====


'''{{LSL Param|filter}}''' is a bitwise-or combination of the following constants: [[RC_REJECT_AGENTS]], [[RC_REJECT_PHYSICAL]], [[RC_REJECT_NONPHYSICAL]], and [[RC_REJECT_LAND]] except that if you select all four of them, a script runtime error will be generated (it makes no sense to cast a ray and reject everything!). Note that phantom and volume detect objects are never returned and that seated agents are treated like unseated agents. I.e., you either get seated and unseated agents in your results, or you use [[RC_REJECT_AGENTS]] and get neither. Using 0 as the filter value will return all hits.
{{LSLP|filter}} is a bitwise-or combination of the following constants: [[RC_REJECT_AGENTS]], [[RC_REJECT_PHYSICAL]], [[RC_REJECT_NONPHYSICAL]], and [[RC_REJECT_LAND]].
 
<table class="lltable" border="1" id="rc_reject_flags">
<caption>'''RC_REJECT_TYPES''' and their meanings.</caption>
<tr>
<th>Reject Type</th>
<th title='Value'>V</th>
<th>Description</th>
</tr>
<tr><td>{{LSL Const|RC_REJECT_AGENTS|integer|1}}</td><td>{{#var:value}}</td><td>Avatars won't be detected.</td></tr>
<tr><td>{{LSL Const|RC_REJECT_PHYSICAL|integer|2}}</td><td>{{#var:value}}</td><td>[https://wiki.secondlife.com/wiki/Physical Physical] objects won't be detected.</td></tr>
<tr><td>{{LSL Const|RC_REJECT_NONPHYSICAL|integer|4}}</td><td>{{#var:value}}</td><td>The opposite of the above flag. Objects without physics won't be detected. For phantom objects, see [[RC_DETECT_PHANTOM]].</td></tr>
<tr><td>{{LSL Const|RC_REJECT_LAND|integer|8}}</td><td>{{#var:value}}</td><td>Land won't be detected. This refers to actual [https://wiki.secondlife.com/wiki/LlGround ground] only.</td></tr>
</table>
 
If you reject everything, a script runtime error will be generated (as it makes no sense to do this). Using 0 as the filter value will accept all types (default).
 
Also note that seated agents are treated like unseated agents. As in, you either get seated and unseated agents in your results, or you use [[RC_REJECT_AGENTS]] and get neither.


=====[[RC_DATA_FLAGS]]=====
=====[[RC_DATA_FLAGS]]=====


'''{{LSL Param|flags}}''' is a bitwise-or combination of: [[RC_GET_NORMAL]], [[RC_GET_ROOT_KEY]], and [[RC_GET_LINK_NUM]]. These select whether you want link numbers and hit normals in your results list. By default, you will get the UUID ('key') of the exact child prim hit. If instead you want the key of the root prim, set [[RC_GET_ROOT_KEY]]. A terrain hit will register as [[NULL_KEY]].
{{LSLP|flags}} is a bitwise-or combination of: [[RC_GET_NORMAL]], [[RC_GET_ROOT_KEY]], and [[RC_GET_LINK_NUM]].
 
<table class="lltable" border="1" id="rc_data_flags">
<caption>'''RC_DATA_FLAGS''' and their meanings.</caption>
<tr>
<th>Data Flag</th>
<th title='Value'>V</th>
<th>Description</th>
</tr>
<tr><td>{{LSL Const|RC_GET_NORMAL|integer|1}}</td><td>{{#var:value}}</td><td>Stride includes the surface normal that was hit.</td></tr>
<tr><td>{{LSL Const|RC_GET_ROOT_KEY|integer|2}}</td><td>{{#var:value}}</td><td>The hit {{LSLP|uuid}} will be replaced by the object's root instead of any child.</td></tr>
<tr><td>{{LSL Const|RC_GET_LINK_NUM|integer|4}}</td><td>{{#var:value}}</td><td>Stride includes the link number that was hit.</td></tr>
</table>


|examples=
|examples=
<lsl>
This basic example will cast a ray from the center of the object, 10 meters forward, depending on the object's rotation.
integer filter = 0;
<syntaxhighlight lang="lsl2">
default
{
    touch_start(integer total_number)
    {
        vector start = llGetPos();
        vector end = start + <10,0,0> * llGetRot();
 
        list data = llCastRay(start, end, []);
        llOwnerSay(llList2CSV(data));
    }
}
</syntaxhighlight>
 
This is an example attachment that casts a ray based on the owner's camera in mouselook. It has many applications for things like weapons, scripted interactions with the world (like allowing a HUD to display information about things the user is looking at), etc.
<syntaxhighlight lang="lsl2">
integer gTargetChan = -9934917;
 
default
{
    attach(key id)
    {
        if (id != NULL_KEY)
        {
            llRequestPermissions(id,PERMISSION_TAKE_CONTROLS|PERMISSION_TRACK_CAMERA);
        }
    }
 
    run_time_permissions (integer perm)
    {
        if (perm & PERMISSION_TAKE_CONTROLS|PERMISSION_TRACK_CAMERA)
        {
            llTakeControls(CONTROL_LBUTTON|CONTROL_ML_LBUTTON,TRUE,FALSE);
        }
    }
 
    control (key id, integer level, integer edge)
    {
        // User must be in mouselook to aim the weapon
        if (level & edge & CONTROL_LBUTTON)
        {
            llSay(0,"You must be in Mouselook to shoot.  Type \"CTRL + M\" or type \"Esc\" and scroll your mouse wheel forward to enter Mouselook.");
        }
        // User IS in mouselook       
        if (level & edge & CONTROL_ML_LBUTTON)
        {
            vector start = llGetCameraPos();
            // Detect only a non-physical, non-phantom object. Report its root prim's UUID.
            list results = llCastRay(start, start+<60.0,0.0,0.0>*llGetCameraRot(),[RC_REJECT_TYPES,RC_REJECT_PHYSICAL|RC_REJECT_AGENTS|RC_REJECT_LAND,RC_DETECT_PHANTOM,FALSE,RC_DATA_FLAGS,RC_GET_ROOT_KEY,RC_MAX_HITS,1]);
            llTriggerSound(llGetInventoryName(INVENTORY_SOUND,0),1.0);
            llSleep(0.03);
            key target = llList2Key(results,0);
            // Tell target that it has been hit.
            llRegionSayTo(target,gTargetChan,"HIT");
            // Target, scripted to listen on gTargetChan, can explode, change color, fall over .....
        }
    }           
}
</syntaxhighlight>
 
This example handles the caveat about rays extending outside of region bounds by calculating the point where the ray intersects with the region's edge.
<syntaxhighlight lang="lsl2">
vector GetRegionEdge(vector start, vector dir)
{
    float scaleGuess;
    float scaleFactor = 4095.99;
    if (dir.x)
    {
        scaleFactor = ((dir.x > 0) * 255.99 -start.x) / dir.x;
    }
    if (dir.y)
    {
        scaleGuess = ((dir.y > 0) * 255.99 - start.y) / dir.y;
        if (scaleGuess < scaleFactor) scaleFactor = scaleGuess;
    }
    if (dir.z)
    {
        scaleGuess = ((dir.z > 0) * 4095.99 - start.z) / dir.z;
        if (scaleGuess < scaleFactor) scaleFactor = scaleGuess;
    }
    return start + dir * scaleFactor;
}
 
default
{
    touch_start(integer total_number)
    {
        vector start = llGetPos();
        vector direction = <1,0,0> * llGetRot();
        vector end = GetRegionEdge(start, direction);
 
        list data = llCastRay(start, end, []);
        llOwnerSay(llList2CSV(data));
    }
}
</syntaxhighlight>
 
This example casts a ray from the center of the object, 25 meters north, while applying different [[RC_REJECT_TYPES]] each time.
<syntaxhighlight lang="lsl2">
integer filter;// default is 0


default
default
Line 100: Line 244:
     state_entry()
     state_entry()
     {
     {
         llSay(0, "Hello, Avatar!");
         string ownerName = llKey2Name(llGetOwner());
        llOwnerSay("Hello, " + ownerName + "!");
     }
     }


Line 106: Line 251:
     {
     {
         vector start = llGetPos();
         vector start = llGetPos();
         vector end = start - <0,-25,0>;
         vector end = start - <0.0, -25.0, 0.0>;
       
 
         if ( filter > 8 )
         if ( filter > 8 )
        {
             filter = 0;
             filter = 0;
        }
 
       
         llOwnerSay("Filter " + (string)filter);
         llOwnerSay("Filter " + (string)filter);


         list results = llCastRay(start, end, [RC_REJECT_TYPES, filter, RC_MAX_HITS, 4] );
         list results = llCastRay(start, end, [RC_REJECT_TYPES, filter, RC_MAX_HITS, 4] );
       
 
         integer hitNum = 0;
         integer hitNum = 0;
         // Handle error conditions here by checking llList2Integer(results, -1) >= 0
         // Handle error conditions here by checking llList2Integer(results, -1) >= 0
         for ( hitNum = 0; hitNum < llList2Integer(results, -1); hitNum++ )
         while (hitNum < llList2Integer(results, -1))
         {
         {
             // Stride is 2 because we didn't request normals or link numbers
             // Stride is 2 because we didn't request normals or link numbers
             key uuid = llList2Key(results, 2*hitNum);
             key uuid = llList2Key(results, 2*hitNum);
             string name;
 
            if ( uuid == NULL_KEY )
             string name = "Land"; // if (uuid == NULL_KEY)
             {
 
                name = "Land";
             if (uuid != NULL_KEY)
            }               
            else
            {
                 name = llKey2Name(uuid);
                 name = llKey2Name(uuid);
            }
 
             llOwnerSay("Hit " + name);
             llOwnerSay("Hit " + name + ".");
 
            ++hitNum;
         }
         }
       
 
         filter += 1;
         ++filter;
     }
     }
}
}
</lsl>
</syntaxhighlight>
 
|notes=
|notes=
Use [[llDumpList2String]] to see what the output looks like when you try a new set of flags.
Use [[llDumpList2String]] to see what the output looks like when you try a new set of flags.
Line 150: Line 291:
* '''AI Objects''' - Line-of-sight detection of avatars and other objects, or for navigating an environment by tracing rays about themselves. For example; casting rays directly downwards to determine the height and angle (normal) of the current floor surface, useful for non-physical object movement.
* '''AI Objects''' - Line-of-sight detection of avatars and other objects, or for navigating an environment by tracing rays about themselves. For example; casting rays directly downwards to determine the height and angle (normal) of the current floor surface, useful for non-physical object movement.
* '''Intelligent Object Placement''' - Static objects can be placed in-scene, but adjust themselves to their environment. For example; an object rezzed too high up may adjust its height to floor-level, or a computer console placed low down may cause an avatar to kneel to use it rather than standing.
* '''Intelligent Object Placement''' - Static objects can be placed in-scene, but adjust themselves to their environment. For example; an object rezzed too high up may adjust its height to floor-level, or a computer console placed low down may cause an avatar to kneel to use it rather than standing.
* '''Environment Analysis''' - Can be used to determine the limitations of a surrounding area, such as determining if an object has been placed within a closed room. Not a test to be performed frequently due to quantity of rays required, but could be used by objects to switch off effects if unobserved (no-one within the room).
* '''Environment Analysis''' - Can be used to determine the limitations of a surrounding area, such as determining if an object has been placed within a closed room. Not a test to be performed frequently due to quantity of rays required, but could be used by objects to switch off effects if unobserved (no-one within the room). Auto-adjusting furniture or objects to snap to walls, floors, and ceilings.
|cat1=Physics
|cat1=Physics
|cat2=Light
|cat2=Light
|history = *Date of Release  [[ Release_Notes/Second_Life_Server/11#11.09.23.241511 | 23/09/2011 ]]
* {{jira|SCR-199}} - fixed - The throttle was too low and thus rendered the function not as useful as it could be.
}}
}}

Latest revision as of 08:48, 5 November 2023

Summary

Function: list llCastRay( vector start, vector end, list options );

Cast a line from start to end and report collision data for intersections with objects.
Returns a list of strided values on a successful hit, with an additional integer status_code at the end.

Each stride consists of two mandatory values {key uuid, vector position} and optionally {integer link_number, vector normal}. (See RC_DATA_FLAGS for details.)

A negative status_code is an error code, otherwise it is the number of hits (and strides) returned.

• vector start starting location
• vector end ending location
• list options can consists of any number of option flags and their parameters.

Example return of successful raycast, using the default options:

[key object_uuid, vector hit_position, integer status_code]

In the case of an error, or if the ray hits nothing, the resulting list only contains the status code:

[integer status_code]

Specification

status_code

status_code is a number tacked onto the end of the strided list to give you extra information about the ray cast.

If the cast succeeded, it will be >=0 and will indicate the number of hits.

If the ray cast failed (which should only happen right now if the simulator performance is running low), you'll get a negative status code. RCERR_SIM_PERF_LOW will be used as the status code if the overall physics time in the simulator is too high to perform raycasts. The idea is that you will know to try your cast again in a few frames.

status_code error codes and their meanings.
Status Code V Description
RCERR_UNKNOWN-1The raycast failed for an unspecified reason. Please submit a bug report.
RCERR_SIM_PERF_LOW-2The raycast failed because simulator performance is low. Wait a while and then try again. If possible reduce the scene complexity.
RCERR_CAST_TIME_EXCEEDED-3The raycast failed because the parcel or agent has exceeded the maximum time allowed for raycasting. This resource pool is continually replenished, so waiting a few frames and retrying is likely to succeed.
RCERR_CAST_TIME_EXCEEDED

Note: SCR-199 indicates that pools have been removed from the main grid, so this return code should not appear.

Tips for Efficient Raycasts:

  • Keep the max number of hits returned as small as possible
  • Set as many RC_REJECT_TYPES as possible (of factors you can control, this will likely have the largest impact). For example, if you only want to know where the nearest agent is along a ray, use RC_REJECT_LAND | RC_REJECT_PHYSICAL | RC_REJECT_NONPHYSICAL
  • When possible, avoid raycasting through piles of prims and avoid raycasting against concave physics objects (anything with cut, hollow, twist, and so on, and any mesh object that has no decomposition and has physics type "prim"). Obviously this can't always be avoided, so some casts may take significantly longer than others. Plan for that with robust scripts that handle RCERR_CAST_TIME_EXCEEDED responsibly, namely by sleeping briefly after the call and waiting for a few frames to go by before trying again.

options parameter

options flags and their parameters
Flag V Parameters Default Value Description
RC_REJECT_TYPES ] 0 integer filter ] [ 0 ] Mask used to ignore specific types of objects (and avatars).
RC_DATA_FLAGS ] 2 integer flags ] [ 0 ] Described in the RC_DATA_FLAGS section.
RC_MAX_HITS ] 3 integer max_hits ] [ 1 ] Maximum number of hits to return. Maximum value is 256. To avoid performance issues, keep it small.
RC_DETECT_PHANTOM ] 1 integer detect_phantom ] [ FALSE ] Set to TRUE (or nonzero) to detect phantom AND volume detect objects. It is not possible to detect only phantom objects or only volume detect objects. If set to TRUE, phantom and volume detect objects will always be detected, even if RC_REJECT_NONPHYSICAL and RC_REJECT_PHYSICAL are set in RC_REJECT_TYPES.
RC_REJECT_TYPES

filter is a bitwise-or combination of the following constants: RC_REJECT_AGENTS, RC_REJECT_PHYSICAL, RC_REJECT_NONPHYSICAL, and RC_REJECT_LAND.

RC_REJECT_TYPES and their meanings.
Reject Type V Description
RC_REJECT_AGENTS1Avatars won't be detected.
RC_REJECT_PHYSICAL2Physical objects won't be detected.
RC_REJECT_NONPHYSICAL4The opposite of the above flag. Objects without physics won't be detected. For phantom objects, see RC_DETECT_PHANTOM.
RC_REJECT_LAND8Land won't be detected. This refers to actual ground only.

If you reject everything, a script runtime error will be generated (as it makes no sense to do this). Using 0 as the filter value will accept all types (default).

Also note that seated agents are treated like unseated agents. As in, you either get seated and unseated agents in your results, or you use RC_REJECT_AGENTS and get neither.

RC_DATA_FLAGS

flags is a bitwise-or combination of: RC_GET_NORMAL, RC_GET_ROOT_KEY, and RC_GET_LINK_NUM.

RC_DATA_FLAGS and their meanings.
Data Flag V Description
RC_GET_NORMAL1Stride includes the surface normal that was hit.
RC_GET_ROOT_KEY2The hit uuid will be replaced by the object's root instead of any child.
RC_GET_LINK_NUM4Stride includes the link number that was hit.

Caveats

  • Depending upon the value of flags (provided via RC_DATA_FLAGS), the number and types of values in the strides will vary. See RC_DATA_FLAGS for details.
  • llGetRot will not return an avatar's exact visual rotation because the viewer doesn't update the avatar's rotation under a threshold (see VWR-1331). To get an avatar's exact looking direction while in mouselook, use llGetCameraRot instead.
  • llCastRay will not detect prims having no physics shape (PRIM_PHYSICS_SHAPE_TYPE = PRIM_PHYSICS_SHAPE_NONE).
  • llCastRay will not detect a prim if the line starts inside the prim. This makes it safe to use the prim position as the start location.
  • llCastRay can detect the prim the script is in, if the start location is outside the prim.
  • The result of this function has been noted to be unreliable when the end point is out-of-bounds (Occasionally returns status code 0 regardless of amount of objects hit). (See this forum post)
    • The random failures seem to happen if the ray begins or ends more than 8 meters outside of current region bounds. Changes in only the ray's angle, or only in its position, may change the result. The result does not change if the exact same ray is cast again.

Examples

This basic example will cast a ray from the center of the object, 10 meters forward, depending on the object's rotation.

default
{
    touch_start(integer total_number)
    {
        vector start = llGetPos();
        vector end = start + <10,0,0> * llGetRot();

        list data = llCastRay(start, end, []);
        llOwnerSay(llList2CSV(data));
    }
}

This is an example attachment that casts a ray based on the owner's camera in mouselook. It has many applications for things like weapons, scripted interactions with the world (like allowing a HUD to display information about things the user is looking at), etc.

integer gTargetChan = -9934917;

default
{
    attach(key id)
    {
        if (id != NULL_KEY)
        { 
            llRequestPermissions(id,PERMISSION_TAKE_CONTROLS|PERMISSION_TRACK_CAMERA);
        }
    }

    run_time_permissions (integer perm)
    {
        if (perm & PERMISSION_TAKE_CONTROLS|PERMISSION_TRACK_CAMERA) 
        {
            llTakeControls(CONTROL_LBUTTON|CONTROL_ML_LBUTTON,TRUE,FALSE);
        }
    }

    control (key id, integer level, integer edge)
    {
        // User must be in mouselook to aim the weapon
        if (level & edge & CONTROL_LBUTTON)
        {
            llSay(0,"You must be in Mouselook to shoot.  Type \"CTRL + M\" or type \"Esc\" and scroll your mouse wheel forward to enter Mouselook.");
        }
        // User IS in mouselook        
        if (level & edge & CONTROL_ML_LBUTTON)
        {
            vector start = llGetCameraPos();
            // Detect only a non-physical, non-phantom object. Report its root prim's UUID.
            list results = llCastRay(start, start+<60.0,0.0,0.0>*llGetCameraRot(),[RC_REJECT_TYPES,RC_REJECT_PHYSICAL|RC_REJECT_AGENTS|RC_REJECT_LAND,RC_DETECT_PHANTOM,FALSE,RC_DATA_FLAGS,RC_GET_ROOT_KEY,RC_MAX_HITS,1]);
            llTriggerSound(llGetInventoryName(INVENTORY_SOUND,0),1.0);
            llSleep(0.03);
            key target = llList2Key(results,0);
            // Tell target that it has been hit. 
            llRegionSayTo(target,gTargetChan,"HIT");
            // Target, scripted to listen on gTargetChan, can explode, change color, fall over .....
        }
    }            
}

This example handles the caveat about rays extending outside of region bounds by calculating the point where the ray intersects with the region's edge.

vector GetRegionEdge(vector start, vector dir)
{
    float scaleGuess;
    float scaleFactor = 4095.99;
    if (dir.x)
    {
        scaleFactor = ((dir.x > 0) * 255.99 -start.x) / dir.x;
    }
    if (dir.y)
    {
        scaleGuess = ((dir.y > 0) * 255.99 - start.y) / dir.y;
        if (scaleGuess < scaleFactor) scaleFactor = scaleGuess;
    }
    if (dir.z)
    {
        scaleGuess = ((dir.z > 0) * 4095.99 - start.z) / dir.z;
        if (scaleGuess < scaleFactor) scaleFactor = scaleGuess;
    }
    return start + dir * scaleFactor;
}

default
{
    touch_start(integer total_number)
    {
        vector start = llGetPos();
        vector direction = <1,0,0> * llGetRot();
        vector end = GetRegionEdge(start, direction);

        list data = llCastRay(start, end, []);
        llOwnerSay(llList2CSV(data));
    }
}

This example casts a ray from the center of the object, 25 meters north, while applying different RC_REJECT_TYPES each time.

integer filter;// default is 0

default
{
    state_entry()
    {
        string ownerName = llKey2Name(llGetOwner());
        llOwnerSay("Hello, " + ownerName + "!");
    }

    touch_start(integer total_number)
    {
        vector start = llGetPos();
        vector end = start - <0.0, -25.0, 0.0>;

        if ( filter > 8 )
            filter = 0;

        llOwnerSay("Filter " + (string)filter);

        list results = llCastRay(start, end, [RC_REJECT_TYPES, filter, RC_MAX_HITS, 4] );

        integer hitNum = 0;
        // Handle error conditions here by checking llList2Integer(results, -1) >= 0
        while (hitNum < llList2Integer(results, -1))
        {
            // Stride is 2 because we didn't request normals or link numbers
            key uuid = llList2Key(results, 2*hitNum);

            string name = "Land"; // if (uuid == NULL_KEY)

            if (uuid != NULL_KEY)
                name = llKey2Name(uuid);

            llOwnerSay("Hit " + name + ".");

            ++hitNum;
        }

        ++filter;
    }
}

Notes

Use llDumpList2String to see what the output looks like when you try a new set of flags.

To quickly get the status code use llList2Integer(result, -1).

Ideas for uses:

  • Weapons - Raycasts are the traditional tool used in game development for simulating projectile weapons. They are orders of magnitude more efficient than rezzing a prim and launching it from a weapon.
  • AI Objects - Line-of-sight detection of avatars and other objects, or for navigating an environment by tracing rays about themselves. For example; casting rays directly downwards to determine the height and angle (normal) of the current floor surface, useful for non-physical object movement.
  • Intelligent Object Placement - Static objects can be placed in-scene, but adjust themselves to their environment. For example; an object rezzed too high up may adjust its height to floor-level, or a computer console placed low down may cause an avatar to kneel to use it rather than standing.
  • Environment Analysis - Can be used to determine the limitations of a surrounding area, such as determining if an object has been placed within a closed room. Not a test to be performed frequently due to quantity of rays required, but could be used by objects to switch off effects if unobserved (no-one within the room). Auto-adjusting furniture or objects to snap to walls, floors, and ceilings.

Deep Notes

History

  • Date of Release 23/09/2011
  • SCR-199 - fixed - The throttle was too low and thus rendered the function not as useful as it could be.

Signature

function list llCastRay( vector start, vector end, list options );