Differentiable rasterisation of point clouds in julia
This package provides a rasterisation routine for arbitrary-dimensional point cloud data that is fully (auto-)differentiable. The implementation uses multiple threads on CPU or GPU hardware if available.
The roots of this package are in single-particle 3d reconstruction from tomographic data, and as such it comes with the following ins and out:
- Currently only a single "channel" (e.g gray scale) is supported
- If data is projected to a lower dimension (meaning the dimensionality of the output grid is lower than the dimensionality of the points)
- Projections are always orthographic (currently no support for perspective projection)
- no "z-blending": The contribution of each point to its output voxel is independent of the point's coordinate along the projection axis.
The interface consists of a single function raster that accepts a point cloud (as a vector of m-dimensional vectors) and pose/projection parameters, (as well as optional weight and background parameters) and returns a n-dimensional (n <= m) array into which the points are rasterized, each point by default with a weight of 1 that is mulit-linearly interpolated into the neighboring grid cells.
julia> using DiffPointRasterisation, LinearAlgebra
julia> grid_size = (5, 5) # 2d grid with 5 x 5 pixels
(5, 5)
julia> rotation, translation = I(2), zeros(2) # pose parameters
(Bool[1 0; 0 1], [0.0, 0.0])
julia> raster(grid_size, [zeros(2)], rotation, translation) # single point at center
5×5 Matrix{Float64}:
0.0 0.0 0.0 0.0 0.0
0.0 0.0 0.0 0.0 0.0
0.0 0.0 1.0 0.0 0.0
0.0 0.0 0.0 0.0 0.0
0.0 0.0 0.0 0.0 0.0
julia> raster(grid_size, [[0.2, 0.0]], rotation, translation) # single point half a pixel below center
5×5 Matrix{Float64}:
0.0 0.0 0.0 0.0 0.0
0.0 0.0 0.0 0.0 0.0
0.0 0.0 0.5 0.0 0.0
0.0 0.0 0.5 0.0 0.0
0.0 0.0 0.0 0.0 0.0
julia> raster(grid_size, [[0.2, -0.2]], I(2), zeros(2)) # single point half a pixel below and left of center
5×5 Matrix{Float64}:
0.0 0.0 0.0 0.0 0.0
0.0 0.0 0.0 0.0 0.0
0.0 0.25 0.25 0.0 0.0
0.0 0.25 0.25 0.0 0.0
0.0 0.0 0.0 0.0 0.0
Both, an explicit function that calculates derivatives of raster, as well as an integration to common automatic differentiation libraries in julia are provided.
This package provides rules for reverse-mode automatic differentiation libraries that are based on the ChainRules.jl ecosystem. So using raster(args...) in a program that uses any of the ChainRules-based reverse-mode autodiff libraries should just work™. Gradients with respect to all parameters (except grid_size) are supported:
we define a simple scalar "loss" that we want to differentiate:
julia> using Zygote
julia> target_image = rand(grid_size...)
5×5 Matrix{Float64}:
0.345889 0.032283 0.589178 0.0625972 0.310929
0.404836 0.573265 0.350633 0.0417926 0.895955
0.174528 0.127555 0.0906833 0.639844 0.832502
0.189836 0.360597 0.243664 0.825484 0.667319
0.672631 0.520593 0.341701 0.101026 0.182172
julia> loss(params...) = sum((target_image .- raster(grid_size, params...)).^2)
loss (generic function with 1 method)
some input parameters to raster:
julia> points = [2 * rand(2) .- 1 for _ in 1:5] # 5 random points
5-element Vector{Vector{Float64}}:
[0.8457397177007744, 0.3482756109584688]
[-0.6028188536164718, -0.612801322279686]
[-0.47141692007256464, 0.6098964840013308]
[-0.74526926786903, 0.6480225109030409]
[-0.4044384373422192, -0.13171854413805173]
julia> rotation = [ # explicit matrix for rotation (to satisfy Zygote)
1.0 0.0
0.0 1.0
]
2×2 Matrix{Float64}:
1.0 0.0
0.0 1.0
and let Zygote calculate the gradient of loss with respect to those parameters
julia> d_points, d_rotation, d_translation = Zygote.gradient(loss, points, rotation, translation);
ulia> d_points
5-element Vector{StaticArraysCore.SVector{2, Float64}}:
[-2.7703628931165025, 3.973371400200988]
[-0.70462225282373, 1.0317734946448016]
[-1.7117138793471494, -3.235178706903591]
[-2.0683933141077886, -0.6732149105779637]
[2.6278388385655904, 1.585621066861592]
julia> d_rotation
2×2 reshape(::StaticArraysCore.SMatrix{2, 2, Float64, 4}, 2, 2) with eltype Float64:
-0.632605 -3.26353
4.12402 -1.86668
julia> d_translation
2-element StaticArraysCore.SVector{2, Float64} with indices SOneTo(2):
-4.62725350082958
2.6823723442258274
The explicit interface for calculating derivatives of raster with respect to its arguments again consists of a single function called raster_pullback!:
The function raster_pullback!(ds_dout, raster_args...) takes as input the sensitivity of some scalar quantity to the output of raster(grid_size, raster_args...), ds_dout, and returns the sensitivity of said quantity to the input arguments raster_args of raster (hence the name pullback).
We can repeat the above calculation using the explicit interface.
To do that, we first have to calculate the sensitivity of the scalar output of loss to the output of raster. This could be done using an autodiff library, but here we do it manually:
julia> ds_dout = 2 .* (target_image .- raster(grid_size, points, rotation, translation)) # gradient of loss \w respect to output of raster
5×5 Matrix{Float64}:
0.152276 -0.417335 1.16347 -0.700428 -0.63595
0.285167 0.033845 -0.625258 -0.801198 0.760124
0.349055 0.25511 0.181367 1.27969 1.665
0.379672 0.721194 0.487329 1.65097 1.33464
1.34526 1.04119 0.454354 -1.3402 0.364343
Then we can feed that into raster_pullback! together with the same arguments that were fed to raster:
julia> ds_din = raster_pullback!(ds_dout, points, rotation, translation);
We see that the result is the same as obtained via Zygote:
julia> ds_din.points
2×5 Matrix{Float64}:
2.77036 0.704622 1.71171 2.06839 -2.62784
-3.97337 -1.03177 3.23518 0.673215 -1.58562
julia> ds_din.rotation
2×2 StaticArraysCore.SMatrix{2, 2, Float64, 4} with indices SOneTo(2)×SOneTo(2):
0.632605 3.26353
-4.12402 1.86668
julia> ds_din.translation
2-element StaticArraysCore.SVector{2, Float64} with indices SOneTo(2):
4.62725350082958
-2.6823723442258274
| Points | Images | Pixel | Mode | Fwd time CPU | Fwd time CPUx8* | Fwd time GPU | Bwd time CPU | Bwd time CPUx8* | Bwd time GPU** |
|---|---|---|---|---|---|---|---|---|---|
| 10⁴ | 64 | 128² | 3D → 2D | 341 ms | 73 ms | 15 ms | 37 ms | 10 ms | 1 ms |
| 10⁴ | 64 | 1024² | 3D → 2D | 387 ms | 101 ms | 16 ms | 78 ms | 24 ms | 2 ms |
| 10⁵ | 64 | 128² | 3D → 2D | 3313 ms | 741 ms | 153 ms | 374 ms | 117 ms | 9 ms |
| 10⁵ | 64 | 1024² | 3D → 2D | 3499 ms | 821 ms | 154 ms | 469 ms | 173 ms | 10 ms |
| 10⁵ | 1 | 1024³ | 3D → 3D | 493 ms | 420 ms | 24 ms | 265 ms | 269 ms | 17 ms |
* 8 julia threads on 4 hardware threads with hyperthreading
** 1 Nvidia HGX A100 GPU