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Some more notes on limitations

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Chris Hodapp 2020-05-11 14:32:47 -04:00
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@ -4,12 +4,31 @@
- Make a series of guidelines for *exactly* how to order - Make a series of guidelines for *exactly* how to order
transformations so that I'm actually constructing things to be transformations so that I'm actually constructing things to be
correct instead of just throwing shit at the wall correct instead of just throwing shit at the wall.
See my "Composing Transformations" link in log.org.
- My "Barbs" example revealed another pesky limitation: a parent vertex
cannot refer to a parent vertex of the parent itself. This came up
because I had a rule inheriting 4 vertices (one side of a cube), and
creating 4 new vertices (the opposite side of a cube). I wanted its
child rules to be able to create faces that had 2 vertices of the
parent and 2 vertices that the parent inherited (basically grandparent
vertices) - think of one of the remaining 4 sides of the cube. I have
no way to do this and no easy workarounds I can see, given that the
rule does not have access to the exact vertex positions (so just making
new vertices that are 'close' and connecting them isn't an option).
- Adaptive subdivision - which means having to generalize past some - Adaptive subdivision - which means having to generalize past some
`vmap` stuff. `vmap` stuff.
- Try some non-deterministic examples - Try some non-deterministic examples.
- Get identical or near-identical meshes to `ramhorn_branch` from - Get identical or near-identical meshes to `ramhorn_branch` from
Python. (Should just be a matter of tweaking parameters.) Python. (Should just be a matter of tweaking parameters.)
- Look at performance.
- Start at `to_mesh_iter()`. The cost of small appends/connects
seems to be killing performance.
- `connect()` is a big performance hot-spot: 85% of total time in
one test, around 51% in `extend()`, 33% in `clone()`. It seems
like I should be able to share geometry with the `Rc` (like noted
above), defer copying until actually needed, and pre-allocate the
vector to its size (which should be easy to compute).
- See `automata_scratch/examples.py` and implement some of the tougher - See `automata_scratch/examples.py` and implement some of the tougher
examples. examples.
- `twisty_torus`, `spiral_nested_2`, & `spiral_nested_3` are all - `twisty_torus`, `spiral_nested_2`, & `spiral_nested_3` are all
@ -20,14 +39,6 @@
## Important but less critical: ## Important but less critical:
- Look at performance.
- Start at `to_mesh_iter()`. The cost of small appends/connects
seems to be killing performance.
- `connect()` is a big performance hot-spot: 85% of total time in
one test, around 51% in `extend()`, 33% in `clone()`. It seems
like I should be able to share geometry with the `Rc` (like noted
above), defer copying until actually needed, and pre-allocate the
vector to its size (which should be easy to compute).
- Elegance & succinctness: - Elegance & succinctness:
- Clean up `ramhorn_branch` because it's ugly. - Clean up `ramhorn_branch` because it's ugly.
- What patterns can I factor out? I do some things regularly, like: - What patterns can I factor out? I do some things regularly, like:
@ -43,7 +54,10 @@
- Compute global scale factor, and perhaps pass it to a rule (to - Compute global scale factor, and perhaps pass it to a rule (to
eventually be used for, perhaps, adaptive subdivision) eventually be used for, perhaps, adaptive subdivision)
- swept-isocontour stuff from - swept-isocontour stuff from
`/mnt/dev/graphics_misc/isosurfaces_2018_2019/spiral*.py` `/mnt/dev/graphics_misc/isosurfaces_2018_2019/spiral*.py`. This
will probably require that I figure out parametric curves
- Make an example that is more discrete-automata, less
approximation-of-space-curve.
- Catch-alls: - Catch-alls:
- Grep for all TODOs in code, really. - Grep for all TODOs in code, really.
@ -64,3 +78,29 @@
pretty cool. pretty cool.
- How can I take tangled things like the cinquefoil and produce more - How can I take tangled things like the cinquefoil and produce more
'iterative' versions that still weave around? 'iterative' versions that still weave around?
## Research Areas
- When I have an iterated transform, that is basically transforming by
M, MM=M^2, MMM=M^3, ..., and it seems to me that I should be able to
compute its eigendecomposition and use this to compute fractional
powers of the matrix. Couldn't I then determine the continuous
function I'm approximating by taking the `d/di (M^i)V` - i.e. the
partial derivative of the result of transforming a vector `V` with
`M^i`? (See also:
https://en.wikipedia.org/wiki/Eigendecomposition_of_a_matrix#Functional_calculus
and my 2020-04-20 paper notes. My 2020-04-24 org notes have some
things too - this relates to dynamical systems and eigenvalues.)
Later note: I have a feeling I was dead wrong about a bunch of this.
## Reflections
- My old Python version composed rules in the opposite order and I
think this made things more complicated. I didn't realize that I
did it differently in this code, but it became much easier -
particularly, more "inner" transformations are much easier to write
because all that matters is that they work properly in the
coordinate space they inherit.
- Generalizing to space curves moves this away from the "discrete
automata" roots, but it still ends up needing the machinery I made
for discrete automata.