Add Another Core for Faster Graphics

Dzonatas writes "Need a reason for extra cores inside your box? How about faster graphics. Unlike traditional faster GPUs, raytraced graphics scale with extra cores. Brett Thomas writes in his article Parallel Worlds on Bit-Tech, 'But rather than working on that advancement, most of the commercial graphics industry has been intent on pushing raster-based graphics as far as they could go. Research has been slow in raytracing, whereas raster graphic research has continued to be milked for every approximate drop it closely resembles being worth. Of course, it is to be expected that current technology be pushed, and it was a bit of a pipe dream to think that the whole industry should redesign itself over raytracing.' A report by Intel about Ray Tracing shows that a single P4 3.2Ghz is capable of 100 million raysegs, which gives a comfortable 30fps. Intel further states 450 million raysegs is when it gets 'interesting.' Also, quad cores are dated to be available around the turn of the year. Would octacores bring us dual screen or separate right/left real-time raytraced 3D?"

need a reason

[b1ufox]

Need a reason for extra cores inside your box? No :)

How many do I need

[Moraelin]

Lemme see, at this rate I'll need: 9 cores for the raytracer, 7 cores for the physics simulation, 5 for the AI, 3 for the OS, and of course

One core to rule them all
One core to find them
One core to bring them all
And in the darkness bind them ;)

Re:How many do I need

[Freaky+Spook]

One core to rule them all

One core to find them

One core to bring them all

And in the darkness bind them

You just installed Vista onto that rig didn't you

*Ducks*

Re:How many do I need

[legoburner]

Lemme see, at this rate I'll need: 9 cores for the raytracer, 7 cores for the physics simulation, 5 for the AI, 3 for the OS

Yeah, but asteroids will look AMAZING!

Gaming

There are already ray traced games. :O

http://graphics.cs.uni-sb.de/~morfiel/oasen/

Re:Gaming

[Vario]

They managed to get reasonable frame rates with a FPGA board, which is rather slow compared to modern GPUs. A lot of special effects like diffraction are included and don't kill the framerate. This might be a very interesting alternative to more texels/s and shaders.
It just looks good as well: http://graphics.cs.uni-sb.de/~woop/rpu/rpu.html

It's been done...

[SigILL]

F.A.N. released a real-time raytraced demo at breakpoint back in 2003. It does no more than 10 fps on my lowly 1GHz P3, but I'm sure it runs quite smooth on a nice modern CPU (though I don't think it's multithreaded).

Put it on the GPU

[TheRaven64]

The thing about ray tracing is that it's the archetypal embarrassingly parallel problem that makes heavy use of floating point arithmetic. The thing about GPUs is that they are incredibly parallel processors optimised for for floating point operations.

Take a look at the proceedings from any graphics conference in the last three or four years, and you will see several papers which involve ray-tracing on a GPU. Actually, not so many recently, because it's been done to death. The most impressive one I saw was at Eurographics in 2004 running non-linear ray tracing. As the rays advanced, their direction was adjusted based on the gravity of objects in the scene. The demo (rendered in realtime) showed a black hole moving in front of a stellar scene and all of the light effects this caused.

Re:Put it on the GPU

[smallfries]

The problem with raytracing researchers is that they are incredibly myopic. *Everybody* should use raytracing for *everything* because it is superior to raster in *every case*. Well, bullshit. Take a look at the raytracing results people have posted links to, and then watch the video of Crysis. The problem is not raytracing, but geometric complexity. Raytracing does not scale nicely with the amount of geometry - mainly because of the shadow rays that have to be scattered from each intersection. The 100mil figure assumes about 100 rays per pixel. Well, you need 64 of them just to get around aliasing, and that doesn't leave many for ambient and shadow bounces.

But the GPU is interesting for raytracing. As it moves closer towards a giant floating point vector machine the motivating application will become raytracing. So at the moment a 7800gtx can push 280Gflops. That is 2800 cycles per ray for a single frame. (BTW Intels figures in the article are bullshit. 100mil rays at 30fps = 3 billion rays per second. Roughly one ray per cycle on averge. They are counting a huge number of rays that have been optimised out of the scene, eg shadows or interpolated from pervious frames using a cache).

The raw horsepower is getting there on the card but at the moment the communication soaks up all of the time. Raytracing is the poster-child problem for parallelisation - assuming that you have random access (readable) global memory. If you need to partition the memory into the compute nodes it begins to get harder. In a GPU building datastructures to hold the information is the bottleneck, and it drops the speed by factors of 100s or 1000s. Nvidia and ATi have given the general-purpose community hints that they will improve performance in reading data-structures so this particular roadblock may disappear. A real scatter operation in the fragment shader would be nice, but you would have to gut the ROPs in order to do it. This may happen anyway as the local-area operations that the ROPs compute could fold into fragment operations. To increase the write bandwidth in the card the retirement logic needs to start retiring 'pages' of pixels anyway, over a much wider bus. Otherwise the number of feasible passes per pixel will always be capped by the speed that the ROPs can retire the data.

So given how hard it would be to *efficiently* raytrace on a GPU - why bother when you can throw so much more raw horsepower at faking it with cheap raster techniques?

Not quite

[Aceticon]

If i remember it correctly from my days of playing with POVRay (free raytracing app), the time it took to raytrace an image depended on things like the presence (or not) of semi-transparent, semi-reflective surfaces and on the number of light sources.

If this is still the case, then going from the current rendering techniques in games to raytracing would result in images with more realistic reflections and lighting but, due to performance tradeoffs, few reflective surfaces and light sources.

Besides, at the moment what games need the most is beter AIs and procedurally generated content, not yet another layer of eyecandy that requires gamers to upgrade their hardware (again).

Re:Not quite

[tgd]

Thats because a reflection creates another ray segment, and a refraction creates two.

Considering a non-reflective ray traced world at 800x600 needs 320,000 rays to be cast to calculate an image, so 9,600,000 at 30fps, the claim of 450 million ray segments makes sense... thats 45+ per pixel at 800x600, which is a lot of reflections. Usually you'd limit the number to a fairly low because 100 deep reflections don't add noticable detail, especially in motion. Thats a lot of room for both refractive and reflective objects to be in the scenes.

Re:Not quite

[TheRaven64]

You probably wouldn't just use one ray per pixel. It is typical to fire a number of rays and then average the result. This is because rays diverge quite quickly after passing through the display port, and so you get quite an uneven image. There is a noticeable difference between 1 and 4 rays per pixel, and between 4 and 9. After 9, you start to get into diminishing returns, and beyond about 25 it becomes harder to spot the difference (note that it is common to use a square number of rays, since that makes it easy calculate where they should go).

Re:Not quite

[TheRaven64]

What really needs to be done is to track motion the way you would encoding for mpeg, and focus more ray casts in areas of low motion

There was a paper published a couple of years ago (at Eurographics?) about this. Each ray was independent, and would return a value at each intersection (i.e. you get the primary ray value quickly, and then refine it further with secondary, tertiary, etc ray data). When a ray was no longer lined up with a pixel, it was interrupted and terminated. This meant that you got a fairly low quality image while moving quickly, but a much better one when you let they rays run longer. I found it particularly interesting, since it completely removed the concept of a frame; each pixel was updated independently when a better approximation of its correct value was ready, giving a much better degradation.

rabbit rabbit rabbit

[RuBLed]

FTA

"Oh, blast. Rabbit, I seem to have forgotten my pocketwatch. May I borrow yours?"

Rabbit: I'm late, I'm late, I'm late...

---

anyway, if these technology becomes a reality in the 3-5 years and if I read the article right, the whole graphics architecture would change, there would only be a need for a super graphics processor and less need for too much memory and those graphics pipeline/shader thingies...

The reason that they might want it in a CPU is that, why have a separate add on GPU to handle the job while the CPU could do it alone by that time. You would then only need a "basic" video card that would just do the display.

Hmmm... could this be one of the reasons why ATI and AMD merged?

Quake 3: Raytraced

Just found that game using raytracing - Quake 3: Raytraced.
http://graphics.cs.uni-sb.de/~sidapohl/egoshooter/

Rumors are there's a q4 version on the way.

"entirely vectors"

[Joce640k]

Raytracing is pretty much entirely vectors isn't it?

No, ray tracing is all about searching databases for ray-object intersections. That's what GPUs can't do at all.

It's not JUST FP that's the issue

[N+Monkey]

The thing about ray tracing is that it's the archetypal embarrassingly parallel problem that makes heavy use of floating point arithmetic. The thing about GPUs is that they are incredibly parallel processors optimised for for floating point operations.

It's not just the sheer number of FP calculations that can be the problem. Once you get away from the first (or perhaps even second) level of rays, you end up losing coherence between neighbouring rays which causes memory page/cache thrashing. This is not a nice thing on a GPU.

Won't happen soon.

[midkay]

It's extremely unlikely that anything will go anywhere with raytracing in the near future. Raytracing takes a tremendous amount of power - apps that demonstrate it in realtime usually run quite choppy, and they're very minimalistic to boot; ugly textures, very simple geometry, very confined areas...

The main benefits of raytracing in games would be:
1) Shadows; they'd be Doom 3-like. Several games have full stencil shadows and that's just how raytraced ones would look: sharp and straight. The difference? Raytraced ones would take a ton more power and time to compute.
2) True reflection and refraction. We can "fake" this well enough - for example, see the Source engine's water, incorporating realtime fresnel reflections and refractions. Though Source's water's "fake" refraction/reflection aren't pixel-perfect, and are only distorted by a bump-map, it certainly looks great.

Honestly, considering the small gain in visual quality (although a major gain in accuracy) - it's like going after a fly with a bazooka. Sure, once we get to the point where there's enough processing power to deal with this well enough in realtime, it will happen - but don't expect it soon, and don't expect that huge a difference. Nicer reflections and refractions (which already look good today) and pixel-perfect shadows (looking just the same as stencil shadows in some newer games).

Re:Won't happen soon.

[CTho9305]

Raytracing takes a tremendous amount of power - apps that demonstrate it in realtime usually run quite choppy
If you read the Intel paper that inspired TFA's author to write his ill-informed article, you'll see that raytracing scales better with scene complexity, and Intel did benchmarks to show that after about 1M triangles per scene, software raytracers will outperform hardware GPUs using triangle pipelines (e.g. openGL, directX, shaders).

Sure, once we get to the point where there's enough processing power to deal with this well enough in realtime, it will happen
The benchmarks in the Intel paper show that we are very close to that point right now.

30 fps - unlikely

[DrXym]

Ray tracing works by tracing a hypothetical ray(s) of light back from a screen pixel, and following it as it bounces and splits off various objects which may or may not be opaque, shiny, textured etc. to the light source. So a ray might first hit a sphere so you calculate the light at that point and recursively to trace the light as it bounces off other objects. To get any level of realism you're talking about multiple recursion which takes an enormous amount of time in any complex scene. Transparency also requires the relected and refracted ray to be traced so the number of rays can increase dramatically.

Ray tracing also suffers terribly from "jaggies". Edges look bad because rays can just miss an object and cause really bad stepping on the edges of objects. To eliminate jaggies and do anti-aliasing, you need to do sub-pixel rendering with jitter (slight randomness) to produce an average value for the pixel. So you might have to trace 4 or more rays in a pixel for acceptable anti-aliasing. Effects like focal length, fog, bump mapping etc. cause things to get even more complex. Most pictures rendered with high quality on Blender, POVRay etc. would take minutes if not hours even on a fast / dual core processor.

The only way you'd get 30fps is if cut your ray trace depth to 1 or 2, used a couple of lights, cut the screen res down and forgot about fixing jaggies. It would look terrible. Oh and find time for all the other things that apps and games must do.

Raytracing vs. Scanline for Realtime

[greazer]

I've seen the topic of realtime ray-tracing and hardware accelerated ray-tracing come up countless times over the past 15 years. In the 80's and 90's, a realtime ray-tracing acceleration chip was always around the corner. Some products did actually emerge, but never quite caught on. The reason for this is not because "commercial graphics industry has been intent on pushing raster-based graphics as far as they could go". Quite the contrary; it's much more elegant algorithmically (and hence 'easier') to implement a ray-tracer than a scanline based renderer. However, there's a fundamental limitation of ray-tracing that make it unappealing performance-wise. Cache coherence for ray-tracers suck.

All rendering algorithms boil down to a sorting problem, where all the geometry in the scene is sorted in the Z dimension per pixel or sample. Fundamentally, scanline algorithms and ray-tracing algorithms are the same. For primary rays, here's some simpliefied pseudocode:

      foreach pixel in image
        trace ray through pixel
        shade frontmost geometry

The trace essentially sorts all the geometrty along its path.

A scanline algorithm looks like this:

      foreach geometry object in the scene
        foreach pixel geometry is in
          if geometry is in front of whatever is in the pixel already
            shade fragement of geometry in pixel
            replace pixel with new shaded fragment

As you can see, the only distinction is the order of the two loops. For ray-tracing, traversing the pixels is in the outer loop, and the geometry in the inner loop. For scanline rendering, it's the opposite. This has huge consequences in terms of cache coherency. With scanline methods, since the same object is being shaded in the inner loop, and neighboring fragments of the same object are being shaded, cache coherency tends to be extermely high. The same shader program is used, and likelyhood of the texture being accessed from cache is very good. The same can't be said for ray-tracing. You can shoot two almost identical rays but touch wildly different parts of the scene. Cache coherency relative to scanline rendering is abysmal.

This one performance side-effect of ray-tracing is the only reason we haven't seen any serious ray-tracing for realtime applications. Even in offline rendering, scanline rendering dominates even though software ray-tracing has been available from the beginning of CG. For ray-tracing to become viable, we need more than just more CPU cores. We need buses fast enough to feed all the cores in situations where we have an extremely high ratio of cache misses. Unfortunately, the speed gap between memory speeds and compute power seems to be increasing in recent years.

Film at 11

[jalefkowit]

A report by Intel about Ray Tracing shows that a single P4 3.2Ghz is capable of 100 million raysegs, which gives a comfortable 30fps.

Extra, extra! This just in! Report from CPU vendor discovers that you should spend more money on your CPU and less on your graphics card!

Shocking, I tells ya. Shocking.

Lies, Damned Lies and RT Raytracing

[adam31]

If there's one thing the RT raytracing community is good at, it's explaining how good it works in theory. Take some numbers, extrapolate a little one dimension, then another and BOOM-- The Future. There are several problems with raytracing in real-time:

1) Static Objects Only. The huge majority of computation time is traversing a spatial subdivision structure. It happens that K-d trees offer the best characteristic (typically, fewest primitive per leaf for a given memory limit). However, these are really heinous to dynamically update. You can cheaply re-create it with median partitioning, but your trees are crappy. You can do a much nicer SAH (surface area heuristic), but to do this per frame blows out your CPU budget.

2) Bandwidth. Even if you could update your subdivision structure very cheaply, that structure still needs to be propogated out to all the CPUs participating in the raytrace. For the 1.87 MTri model they list on page 6, their spatial structure was 127 MB. Say you have a bandwidth of 6 GB/s, it takes 20ms just to transfer the structure (and there are other problems here). So your ceiling is 50 Fps before you trace your first ray.

3) Slower than a GPU. Even though they give you some little graph showing that raytracing (a static model, with static partitioning) beats a GPU at a MTri in the frame, this is very deceiving. The GPU pipeline works such that zillions of sub-pixel triangles simply can't get into pixel shaders fast enough, and force the pixel shader to be run many times extra. Double the resolution, however and the GPU won't take a cycle longer... with raytracing, performance will halve. So they found a bottleneck in the GPU which is totally unrepresentative of a game in every single sense, and said LOOK! BETTER! (in theory).

4) Hey, Where's my Features? All the cool things about raytracing (nice shadows, refraction, implicit surfaces, reflection, subsurface scattering) all get tossed out the window to make it real-time! What's the point, then? Given all the pixel shader hacks invented to make a GPU frame look interesting, the quality that can be achieved in a real-time raytrace is sadly tame. Especially when you consider that quality is the supposed advantage of raytracing.

And c'mon. It's Gameplay that counts anyway :P