[yt-dev] RFC: SPH plan in yt 3.0
Matthew Turk
matthewturk at gmail.com
Tue Jan 8 09:07:06 PST 2013
Hi Elizabeth,
Thanks for the info! Looks like we could learn from them.
-Matt
On Tue, Jan 8, 2013 at 10:45 AM, Elizabeth Tasker
<tasker at astro1.sci.hokudai.ac.jp> wrote:
> Ah, found it:
>
> http://code.google.com/p/pynbody/
>
> Apparently, they now suppose AMR too. Let's take them out…. uh, I mean, look at their code with interest.
>
>
> Elizabeth
>
>
> On Jan 9, 2013, at 12:41 AM, Elizabeth Tasker <tasker at astro1.sci.hokudai.ac.jp> wrote:
>
>> Hi,
>>
>> Just something to consider:
>>
>> While I was at McMaster, there was quite a bit of talk about a python visualisation tool called 'pin body'. I think this might have been developed by Greg Stinson to work with GASOLINE.
>>
>> I'm unsure how far this progressed; grad students at Mac were definitely using it to create slices but I can't find any mention of it on the web.
>>
>> Potentially, this might be worth checking out, either as a possible incorporation or comparison?
>>
>> I can ask McMaster what the situation is if that would be helpful?
>>
>> As a side line, I'd find this very useful as a way of converting between simulation code formats, combined with it's new initial condition generator.
>>
>> Elizabeth
>>
>>
>> On Jan 9, 2013, at 12:18 AM, Matthew Turk <matthewturk at gmail.com> wrote:
>>
>>> Hi all,
>>>
>>> I am writing today to request comments and suggestions for supporting
>>> SPH data in yt. This is part of a broader effort -- which includes
>>> the native Octree support -- in yt 3.0 to correctly support
>>> non-gridpatch data.
>>>
>>> This email contains a lot of information about where we are, and I was
>>> hoping to get some feedback from people who have more experience with
>>> SPH data, Gadget, AREPO, etc. In particular, (if they're around and
>>> have the time) it'd be great to hear from Marcel Haas, Michael J.
>>> Roberts, and Chris Moody.
>>>
>>> Additionally, I am very interested in approaching this as an
>>> iterative, incremental process. Minimum Viable Product (MVP) first,
>>> then improving as we learn and go along.
>>>
>>> = Background =
>>>
>>> As seen in this pull request:
>>>
>>> https://bitbucket.org/yt_analysis/yt-3.0/pull-request/11/initial-n-body-data-support
>>>
>>> I've implemented a first pass at N-body data support. This proceeds
>>> through the following steps:
>>>
>>> * Read header
>>> * Create octree
>>> * For each file in output:
>>> * Add particles to octree
>>> * When a cell crests a certain number of particles (or when
>>> particles from more than one file are co-located) refine
>>> * Directly query particles to get data.
>>>
>>> As it stands, for N-body data this is very poor at memory
>>> conservation. In fact, it's extremely poor. I have however written
>>> it so that in the future, we can move to a distributed memory octree,
>>> which should alleviate difficulties.
>>>
>>> For quantitative analysis of quantities that are *in the output*, this
>>> already works. It does not yet provide any kind of kernel or density
>>> estimator. By mandating refinement based on file that the particles
>>> are in, load on demand operations can (more) efficiently read data.
>>>
>>> Many of the related items are outlined in the corresponding YTEP:
>>>
>>> https://yt.readthedocs.org/projects/ytep/en/latest/YTEPs/YTEP-0005.html
>>>
>>> Currently, it works for OWLS data. However, since there has been
>>> something of a Gadget fragmentation, there is considerable difficulty
>>> in "supporting Gadget" when that includes supporting the binary
>>> format. I've instead taken the approach of attempting to isolate
>>> nearly all the functionality into classes so that, at worst, someone
>>> could implement a couple functions, supply them to the Gadget
>>> interface, and it will use those to read data from disk. Some
>>> integration work on this is still to come, but on some level it will
>>> be a 'build your own' system for some particle codes. OWLS data
>>> (which was run with Gadget) on the other hand is in HDF5, is
>>> self-describing, has a considerable number of metadata items
>>> affiliated with it, and even outputs the Density estimate for the
>>> hydro particles.
>>>
>>> Where I'm now stuck is how to proceed with handling SPH data. By
>>> extension, this also applies somewhat to handling tesselation codes
>>> like AREPO and PHURBAS.
>>>
>>> = Challenges =
>>>
>>> Analyzing quantitative data, where fields can be generated from
>>> fully-local information, is not difficult. We can in fact largely
>>> consider this to be done. This includes anything that does not
>>> require applying a smoothing kernel.
>>>
>>> The hard part comes in in two areas:
>>>
>>> * Processing SPH particles as fluid quantities
>>> * Visualizing results
>>>
>>> Here are a few of our tools:
>>>
>>> * Data selection and reading: we can get rectangular prisms and read
>>> them from disk relatively quickly. Same for spheres. We can also get
>>> boolean regions of these and read them from disk.
>>> * Neighbor search in octrees. Given Oct A at Level N, we can get
>>> all M (<=26) Octs that neighbor A at Levels <= N.
>>> * Voronoi tesselations: we have a wrapper for Voro++ which is
>>> relatively performant, but not amazing. The DTFE method provides a
>>> way to use this to our advantage, although this requires non-local
>>> information. (The naive approach, of getting density by dividing the
>>> particle mass by the volume of the voronoi cell, does not give good
>>> agreement at least for the OWLS data.)
>>>
>>> Here's what we want to support:
>>>
>>> * Quantitative analysis (profiles, etc)
>>> * Visualization (Projections, slices, probably not VR yet)
>>> * Speed
>>>
>>> == Gridding Data ==
>>>
>>> In the past, one approach we have explored has been to simply grid all
>>> of the values. Assuming you have a well-behaved kernel and a large
>>> number of particles, you can calculate at every cell-center the value
>>> of the necessary fields. If this were done, we could reduce the
>>> complexity of the problem *after* gridding the data, but it could
>>> potentially increase the complexity of the problem *before* gridding
>>> the data.
>>>
>>> For instance, presupposing we took our Octree and created blocks of
>>> 8^3 (like FLASH), we could then analyze the resultant eulerian grid
>>> identically to other codes -- projections, slices, and so on would be
>>> done exactly as elsewhere.
>>>
>>> This does bring with it the challenge of conducting the smoothing
>>> kernel. Not only are there a handful of free parameters in the
>>> smoothing kernel, but it also requires handling edge effects.
>>> Individual octs are confined to a single domain; neighbors, however,
>>> are not. So we'd potentially be in a situation where to calculate the
>>> values inside a single Oct, we would have to read from many different
>>> files. From the standpoint of implementing in yt, though, we could
>>> very simply implement this using the new IO functions in 3.0. We
>>> already have a _read_particles function, so the _read_fluid function
>>> would identify the necessary region, read the particles, and then
>>> proceed to smooth them. We would need to ensure that we were not
>>> subject to edge effects (something Daniel Price goes into some detail
>>> about in the SPLASH paper) which may prove tricky.
>>>
>>> It's been impressed upon me numerous times, however, that this is a
>>> sub-optimal solution. So perhaps we should avoid it.
>>>
>>> == Not Gridding Data ==
>>>
>>> I spent some time thinking about this over the last little while, and
>>> it's no longer obvious to me that we need to grid the data at all even
>>> to live within the yt infrastructure. What gridded data buys us is a
>>> clear "extent" of fluid influence (i.e., a particle's influence may
>>> extend beyond its center) and an easy way of transforming a fluid into
>>> an image. The former is hard. But I think the latter is easier than
>>> I realized before.
>>>
>>> Recent, still percolating changes in how yt handles pixelization and
>>> ray traversal should allow a simple mechanism for swapping out
>>> pixelization functions based on characteristics of the dataset. A
>>> pixelization function takes a slice or projection data object (which
>>> is, in fact, an *actual* data object and not an image) and then
>>> converts them to an image. For SPH datasets, we could mandate that
>>> the pixelization object be swapped out for something that can apply an
>>> SPH-appropriate method of pixelization (see Daniel Price's SPLASH
>>> paper, or the GigaPan paper, for a few examples). We would likely
>>> also want to change out the Projection object, as well, and we may
>>> need to eliminate the ability to avoid IO during the pixelization
>>> procedure (i.e., the project-once-pixelize-many advantage of grid
>>> data). But I think it would be do-able.
>>>
>>> So we could do this. I think this is the harder road, but I think it
>>> is also possible. We would *still* need to come up with a mechanism
>>> for applying the smoothing kernel.
>>>
>>> = Conclusions and Contributions =
>>>
>>> So I think we have two main paths forward -- gridding, and not
>>> gridding. I would very, very much appreciate comments or feedback on
>>> either of these approaches. I believe that, regardless of what we
>>> choose to do, we'll need to figure out how to best apply a smoothing
>>> kernel to data; I think this is probably going to be difficult. But I
>>> am optimistic we are nearing the point of usability. For pure N-body
>>> data, we are already there -- the trick is now to look at the data as
>>> fluids, not just particles.
>>>
>>> The best way to contribute help right now is to brainstorm and give
>>> feedback. I'd love to hear ideas, criticisms, flaws in my logic, ways
>>> to improve things, and so on and so forth. I think once we have an
>>> MVP, we will be better set up to move forward.
>>>
>>> If you'd like to add a reader for your own flavor of particle data, we
>>> should do that as well -- especially if you are keen to start
>>> exploring and experimenting. The code so far can be found in the
>>> repository linked above. I'd also appreciate comments (or acceptance)
>>> of the pull request. I am also happy to hold a Hangout to discuss
>>> this, go over things, help set up readers or whatever. I consider
>>> this a relatively high-priority project. It will be a key feature of
>>> yt 3.0.
>>>
>>> (Speaking of which, today I've allotted time to focus on getting the
>>> last major patch-refinement feature done -- covering grids. Hopefully
>>> patch-refinement people can test it out after that's done!)
>>>
>>> Thanks for your patience with such a long email! :)
>>>
>>> -Matt
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