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I wonder whether we can formulate the performance of ray-tracing. In my primitive ray-tracer, performance depends on this formula mostly: width x height x number of sampler x (number of objects + number of lights)

So for example, in Pixar or any other big companies, do they follow such formula for performance evaluation. Isn't performance depends on triangle count of the objects? For example if I want to calculate roughly the maximum render time of the frame of 1000x1000 with average 500 objects that consists 5.000.000 triangles, would it be possible?

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But the calculations per pixel aren't O(1), so you can't simply put it like that! Also, number of triangles comes into play when raytracing (when using models with triangles), but as a complex part of the time you'll need per pixel... –  Jasper Oct 30 '12 at 12:23
So you say that we cant say anything about maximum time by looking at triangles and pixels? –  Mert Toka Oct 30 '12 at 12:29
You can say things about for example the upper bound (though I guess you would need some more details about the specific ray tracer), but I don't think you can actually extrapolate any useful info. –  Jasper Oct 30 '12 at 12:32
A well-designed ray tracer will use acceleration datastructures that improve on the performance of a naive ray tracer. The general consensus is that performance can scale like log(scene complexity) per sample due to your acceleration structure -- although you also need to build and maintain the acceleration structure! –  comingstorm Oct 30 '12 at 22:39
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Ray tracers used for serious work use various acceleration methods that make them proportional to log(triangles), not number of triangles. And sometimes sublinear with respect to the number of lights as well (excluding lights that can't affect parts of the scene, collectively sampling all lights at once, that sort of thing).

On the other hand, material changes (even with a fixed resolution and scene geometry) can make a big change as well. For example, making things more or less reflective/refractive can have big changes in the average "ray depth" of the scene.

Generally speaking, for a given set of geometry, lights, and materials, time should be linearly proportional to the total number of rays (i.e. resolution and sampling rate), but that can be thrown off for really big scenes that are partially serialized on reading the scene input (which may be GB and GB of parsing) and reading of texture from disk or network (we routinely have scenes that reference >> 1 TB of texture).

So overall, you would expect time to be somewhat related to:

scene_I/O + xres * yres * samples * (shading_factor + texture_factor + log(triangles)) + texture_I/O

The I/O numbers and arbitrary shading and texture factors that have to do with your materials can make it all hard to predict accurately.

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You can only have the upper boundary of the performance.
for example, the calculation would be very fast if all polygons (triangles or others) are not in the view.
But if you wish to calculate the upper boundary you need to define the algorithm specifics: are you using marching-cubes? do you remove back-face polygons, etc...
but for a specific algorithm, the calculation should be pretty straight forward.

p.s. the number of objects is irrelevant only the sum of all their polygons.

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The number of objects is not necessary irrelevant. Many ray tracers use a 2-level acceleration structure where there's one bounding hierarchy for objects, and then for each a separate hierarchy for each object containing its tessellated triangles. –  Larry Gritz Mar 19 '13 at 17:25
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