Triangle strip

In computer graphics, a triangle strip is a subset of triangles in a triangle mesh with shared vertices, and is a more memory-efficient method of storing information about the mesh. They are more efficient than un-indexed lists of triangles, but usually equally fast or slower than indexed triangle lists.[1][2] The primary reason to use triangle strips is to reduce the amount of data needed to create a series of triangles. The number of vertices stored in memory is reduced from 3N to N + 2, where N is the number of triangles to be drawn. This allows for less use of disk space, as well as making them faster to load into RAM.

Diagram of four triangles, 1, 2, 3, and 4, with vertices A, B, C, D, E, and F.

For example, the four triangles in the diagram, without using triangle strips, would have to be stored and interpreted as four separate triangles: ABC, CBD, CDE, and EDF. However, using a triangle strip, they can be stored simply as a sequence of vertices ABCDEF. This sequence would be decoded as a set of triangles with vertices at ABC, BCD, CDE and DEF - although the exact order that the vertices are read will not be in left-to-right order as this would result in adjacent triangles facing alternating directions.

OpenGL implementation

Model of two triangles drawn in OpenGL using triangle strips.

OpenGL has built-in support for triangle strips. Fixed function OpenGL (deprecated in OpenGL 3.0) has support for triangle strips using immediate mode and the glBegin(), glVertex*(), and glEnd() functions. Newer versions support triangle strips using glDrawElements and glDrawArrays.

To draw a triangle strip using immediate mode OpenGL, glBegin() must be passed the argument GL_TRIANGLE_STRIP, which notifies OpenGL a triangle strip is about to be drawn. The glVertex*() family of functions specify the coordinates for each vertex in the triangle strip. For more information, consult The OpenGL Redbook.[3]

To draw the triangle strip in the diagram using immediate mode OpenGL, the code is as follows:

 //Vertices below are in Clockwise orientation
 //Default setting for glFrontFace is Counter-clockwise
 glFrontFace(GL_CW);

 glBegin(GL_TRIANGLE_STRIP);	
 glVertex3f( 0.0f, 0.0f, 0.0f ); //vertex 1
 glVertex3f( 0.0f, 0.5f, 0.0f ); //vertex 2
 glVertex3f( 0.5f, 0.0f, 0.0f ); //vertex 3
 glVertex3f( 1.0f, 0.5f, 0.0f ); //vertex 4
 glEnd();

Note that only one additional vertex is needed to draw the second triangle. In OpenGL, the order in which the vertices are specified is important so that surface normals are consistent.

Quoting directly from the OpenGL Programming Guide:

GL_TRIANGLE_STRIP

Draws a series of triangles (three-sided polygons) using vertices v0, v1, v2, then v2, v1, v3 (note the order), then v2, v3, v4, and so on. The ordering is to ensure that the triangles are all drawn with the same orientation so that the strip can correctly form part of a surface.

It's even clearer within the manual pages:[4]

Draws a connected group of triangles. One triangle is defined for each vertex presented after the first two vertices. For odd n, vertices n, n + 1, and n + 2 define triangle n. For even n, vertices n + 1, n, and n + 2 define triangle n. n – 2 triangles are drawn.

Note that n starts at 1. The above code sample and diagram demonstrate triangles drawn in a clockwise orientation. For those to be considered front-facing, a preceding call to glFrontFace(GL_CW) is necessary, which otherwise has an initial value of GL_CCW (meaning that triangles drawn counter-clockwise are front-facing by default).[5] This is significant if glEnable(GL_CULL_FACE) and glCullFace(GL_BACK) are already active (GL_BACK by default[6]), because back-facing triangles will be culled, so will not be drawn and will not appear on-screen at all.[7]

Properties and construction

It follows from definition that a subsequence of vertices of a triangle strip also represents a triangle strip. However, if this substrip starts at an even (with 1-based counting) vertex, then the resulting triangles will change their orientation. For example a substrip BCDEF would represent triangles: BCD,CED,DEF.

Similarly, reversal of strips’ vertices will result in the same set of triangles if the strip has an even number of vertices. (e.g. strip FEDCBA will represent the same triangles FED,ECD,DCB,CAB as the original strip). However, if a strip has an odd number of vertices then the reversed strip will represent triangles with opposite orientation. For example, reversal of a strip ABCDE will result in strip EDCBA which represents triangles EDC, DBC, CBA).

Converting a general polygon mesh to a single long strip was until recently generally not possible. Usually the triangle strips are analogous to a set of edge loops, and poles on the model are represented by triangle fans. Tools such as Stripe[8] or FTSG[9] represent the model as several strips. Optimally grouping a set of triangles into sequential strips has been proven NP-complete.[10]

Alternatively, a complete object can be described as a degenerate strip, which contains zero-area triangles that the processing software or hardware will discard. The degenerate triangles effectively introduce discontinuities or "jumps" to the strip. For example, the mesh in the diagram could also be represented as ABCDDFFEDC, which would be interpreted as triangles ABC CBD CDD DDF DFF FFE FED DEC (degenerate triangles marked with italics). Notice how this strip first builds two triangles from the left, then restarts and builds the remaining two from the right.

While discontinuities in triangle strips can always be implemented by resending vertices, APIs sometimes explicitly support this feature. IRIS GL supported Swaps (flipping two subsequent vertices in a strip), a feature relied on by early algorithms such as the SGI algorithm. Recently OpenGL/DirectX can render multiple triangle strips without degenerated triangles using Primitive Restart feature.

Curve tracing using triangle strip

References

  1. "Documentation Archive".
  2. "The Hacks of Life: To Strip or Not to Strip". 31 January 2010.
  3. The OpenGL Redbook
  4. "GlBegin".
  5. glFrontFace
  6. glCullFace
  7. OpenGL FAQ / 10 Clipping, Culling, and Visibility Testing
  8. Azanli, Elvir. Stripe, retrieved on March 28, 2007.
  9. Xiang, Xinyu. FTSG, retrieved on January 21, 2011. (link is no longer valid)
  10. Regina Estkowski, Joseph S. B. Mitchell, Xinyu Xiang. Optimal decomposition of polygonal models into triangle strips. In Proceedings of Symposium on Computational Geometry'2002. pp.254~263 url=http://www.ams.sunysb.edu/~jsbm/papers/p151-mitchell.pdf url=http://portal.acm.org/citation.cfm?id=513431

See also

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