Difference between revisions of "Mugic/protocol"
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By convention, CalVR uses a coordinate system in which x extends to the right, y goes forward, and z is up. If a different coordinate system should be used, the ScreenConfig values in CalVR have to be changed accordingly. | By convention, CalVR uses a coordinate system in which x extends to the right, y goes forward, and z is up. If a different coordinate system should be used, the ScreenConfig values in CalVR have to be changed accordingly. | ||
| + | |||
| + | In this specification, 3D positions will be abbreviated by POSITION and can be specified as one of: | ||
| + | |||
| + | ;Syntax | ||
| + | :x=<xpos> | ||
| + | :y=<ypos> | ||
| + | :z=<zpos> | ||
| + | :xyz=<xpos>,<ypos>,<zpos> | ||
| + | |||
| + | ;Parameters | ||
| + | :x, y, z: coordinate in millimeters | ||
| + | :xyz: GLSL-style compact form to set all three coordinates at once | ||
===Point=== | ===Point=== | ||
Revision as of 21:35, 14 November 2012
Contents |
Overview
MUGIC defines a protocol for a standard display-independent client/server model for the generation, control, and management of graphics rendering within a multi-user environment. The first implementation for the CalVR system used on the state-of-the-art visualisation technologies developed at Calit2. This protocol will provide ease of access and an integrated development environment for research, education, performance, interaction, and presentations. It will provide an easily accessible format for integration of real-time programming softwares (e.g., Touch Designer, Pure Data, Max/MSP, Quartz, Processing, etc.) which in turn will facilitate the incorporation of state-of-the-art gesture control and algorithmic/generative processes for control of graphics on multiple displays. The protocol will also provide multi-user management and access support, as well as real-time telematic connection between multiple servers materializing an enormous potential for development of multi-site virtual reality game and performance productions.
-Server listens to both tcp and udp
-UDP and TCP streams will work in conjunction and in collaboration with each other
-UDP commands have a 1400 byte limit (or whatever the lower limit is of the client and server MAClayer)
User management every tcp connection has a ttl after the ttl time, the scene associated with user will be deleted
Object managment every object has an owner object can be a collection of objects
Syntax
cmd name [parameter={value,`expr`} ...]
expr is a c-style expression
Parameters
cx cy cz
red green blue alpha r g b a
Gradient { circular,linear,exp}
red2 green2 blue2 alpha2
(for linear gradient). gx gy gz (defined as a vector)
rotx roty rotz
scale
scalex scaley scalez
Variables
var name type={float,array} {value,`expr`}
variables can be used in expressions
variables of other users can also be accessed as user:variable
parameters of objects can be accessed as variables ObjectName:parameter
the value of a parameter of an object of another user is accessed as
User:ObjectName:parameter
Connections
connect <username>
[shouldn't this rather be something like 'user' to set the user name? This would allow: changing the user name, and using the API without a user name if the command is never called -- jurgen]
User Management and Preferences
pref [cmd] [parameter=value]
default object [parameter=[value,`expr`]
Draw Commands
All geometry lives in a 3D space. To keep the geometry in a plane to emulate 2D, set one of the three coordinates to zero.
By convention, CalVR uses a coordinate system in which x extends to the right, y goes forward, and z is up. If a different coordinate system should be used, the ScreenConfig values in CalVR have to be changed accordingly.
In this specification, 3D positions will be abbreviated by POSITION and can be specified as one of:
- Syntax
- x=<xpos>
- y=<ypos>
- z=<zpos>
- xyz=<xpos>,<ypos>,<zpos>
- Parameters
- x, y, z: coordinate in millimeters
- xyz: GLSL-style compact form to set all three coordinates at once
Point
Draws a point (single pixel).
- Syntax
- point name=<name> x=<xpos> y=<ypos> z=<zpos> r=<red> g=<green> b=<blue> a=<alpha>
- point name=<name> xyz=<xpos>,<ypos>,<zpos> rgba=<red>,<green>,<blue>,<alpha>
- Parameters
- x, y, z: point coordinates in millimeters
- r, g, b: color values for red, green, blue; floating point values in range 0 to 1
- a: alpha (opacity) value [0..1]
- xyz: GLSL-style compact form to set all three coordinates at once
- rgba: GLSL-style compact form to set all three color components at once
Triangle
Defines vertex coordinates and per-vertex colors for a triangle.
- Syntax
- triangle name=<name> xyz1=<xpos1>,<ypos1>,<zpos1> xyz2=<xpos2>,<ypos2>,<zpos2>, xyz3=<xpos3>,<ypos3>,<zpos3> rgb=<red>,<green>,<blue>
- triangle name=<name> xyz1=<xpos1>,<ypos1>,<zpos1> xyz2=<xpos2>,<ypos2>,<zpos2>, xyz3=<xpos3>,<ypos3>,<zpos3> rgb1=<red1>,<green1>,<blue1> rgb2=<red2>,<green2>,<blue2> rgb3=<red3>,<green3>,<blue3>
- Parameters
- xyz1,xyz2,xyz3: GLSL-style compact form to set all three coordinates for each vertex
- rgb: GLSL-style compact form to set all three color components to be applied to all three vertices (produces single-colored triangle)
- rgb1,rgb2,rgb3: GLSL-style compact form to set all three color components for each vertex
Quad
Draws a quadrangle by creating an OpenGL GL_QUAD object. Note that if all four vertices are not in one plane, intersections of the quad with other geometry might produce unexpected results.
- Syntax
- quad name=<name> xyz1=<xpos1>,<ypos1>,<zpos1> xyz2=<xpos2>,<ypos2>,<zpos2>, xyz3=<xpos3>,<ypos3>,<zpos3> xyz4=<xpos4>,<ypos4>,<zpos4> rgb=<red>,<green>,<blue>
Rectangle
Draws an axis parallel 2D rectangle. Its origin is in its geometrical center.
- Syntax
- rectangle name=<name> xyz=<xpos>,<ypos>,<zpos> width=<width> height=<height> r=<red> g=<green> b=<blue>
- Parameters
- width: extends along x axis [millimeters]
- height: extends along y axis [millimeters]
- r,g,b: fill color components red, green, blue [0..1]
Circle
- Syntax
- circle name=<name> xyz=<xpos>,<ypos>,<zpos> radius=<radius> rgba=<red>,<green>,<blue>,<alpha>
- Parameters
- xyz: location of center point of circle [millimeters]
- radius: circle radius [millimeters]
- rgb: fill color components red, green, blue [0..1]
Ellipse
c2x c2y c2z
Box
Draws an axis-parallel rectangular box. Its origin is in its geometrical center.
- Syntax
- box name=<name> xyz=<xpos>,<ypos>,<zpos> width=<width> height=<height> depth=<depth> r=<red> g=<green> b=<blue>
- Parameters
- width: extends along x axis [millimeters]
- height: extends along y axis [millimeters]
- depth: extends along z axis [millimeters]
- r,g,b: box color components red, green, blue [0..1]
Sphere
Draws a 3D sphere. The xyz coordinates are for its center point.
- Syntax
- sphere name=<name> xyz=<xpos>,<ypos>,<zpos> radius=<radius> rgba=<red>,<green>,<blue>,<alpha>
- Parameters
- xyz: location of center point of sphere [millimeters]
- radius: circle radius [millimeters]
- rgba: sphere color components red, green, blue, alpha [0..1]
Cylinder
Pyramid
Update
group
group name [names ... ]
Examples
Example 1
connect user1
circle name=cir1 cx=1000 cy=2000 radius=3000
sphere name=xph1 cx=1000 cy=2000 cz=3000 radius=1000
Example 2
connect user1
var var1=2
circle name=x1 cx=`-var1` radius=`10000/var1`
update var1=3000
update var1=5000
update var1=10000
update x1 cx=`var*1.5`
Example 3
connect user1
var var1=2000; var var2=2500
circle name=c1 cx=`-var1` cy=0 radius=`10000/var1`
square name=s1 cx=`var1` cy=0 width=`abs((2*var-10000/var1)/2)`
group x1 c1 s1
update x1 cx=5000
update x1 cx=7000
Next Phase
alias (e.g. alias square quad ....... )
move dur=
delete dur=
scale
rotate
sheer
copy name= src= link name= src= transformation=
Camera Management
Lighting Management
Quad ID=X p1=0,0 p2=1,0 p3=1,1 P4=0,0
link ID=A src=X
scale id=A factor=0.2
move ID= dx=.1 dy=.5
group iD=C A,B
