Virtual brains w/ JAX
Project description
vbjax
vbjax
is a Jax-based package for working with virtual brain style models.
Installation
Installs with pip install "vbjax"
, but for the latest features,
you can use the source,
git clone https://github.com/ins-amu/vbjax
cd vbjax
pip install -e ".[dev]"
You're encouraged to have the source handy to consult and change, but you can also just
pip install git+https://github.com/ins-amu/vbjax
The primary additional dependency of vbjax is JAX, which itself depends only on NumPy, SciPy & opt-einsum, so it should be safe to add to your existing projects.
gee pee you
CUDA
If you have a CUDA-enabled GPU, you install the requisite dependencies like so
pip install --upgrade "jax[cuda11_pip]" -f https://storage.googleapis.com/jax-releases/jax_cuda_releases.html
M1/M2 🍎
On newer Apple machines w/ M1 or M2 GPUs, JAX supports using the GPU experimentally by installing just two extra packages:
pip install ml-dtypes==0.2.0 jax-metal
About a third of vbjax tests fail due to absence of certain operations like n-dim scatter/gather & FFTs, and it may not be faster because these CPUs already have excellent memory bandwidth & latency hiding.
CUDA 🐳
BUT because GPU software stack versions make aligning stars look like child's play, container images are available and auto-built w/ GitHub Actions, so you can use w/ Docker
docker run --rm -it ghcr.io/ins-amu/vbjax:main python3 -c 'import vbjax; print(vbjax.__version__)'
The images are built on Nvidia runtime images, so --gpus all
is enough
for Jax to discover the GPU(s).
Examples
Here are some examples of simulations which show what you can do with the library. Because they are implemented atop Jax, it is easy to take gradients for optimization or MCMC, or do efficient GPU parallel batching. Or both ಠ_ರೃ
Simple network
Here's the smallest simulation you might want to do: an all-to-all connected network with Montbrio-Pazo-Roxin mass model dynamics,
import vbjax as vb
import jax.numpy as np
def network(x, p):
c = 0.03*x.sum(axis=1)
return vb.mpr_dfun(x, c, p)
_, loop = vb.make_sde(dt=0.01, dfun=network, gfun=0.1)
zs = vb.randn(500, 2, 32)
xs = loop(zs[0], zs[1:], vb.mpr_default_theta)
vb.plot_states(xs, 'rV', jpg='example1', show=True)
While integrators and mass models tend to be the same across publications, but
the network model itself varies (regions vs surface, stimulus etc), vbjax allows
user to focus on defining the network
and then getting time series.
Parallel parameter space exploration
One of the key tools in use of these models is to run parameter sweeps, which can be done easily with vbjax and parallelized with builtin Jax tools.
import jax, jax.numpy as np
import vbjax as vb
Let's
look at the effect of coupling, noise and excitability in a small network model,
where the p
parameter is a tuple of coupling scaling, noise scaling and the
base MPR parameters:
def net(x, p):
r, v = x
k, _, mpr_p = p
c = k*r.sum(), k*v.sum()
return vb.mpr_dfun(x, c, mpr_p)
to ensure noise is a parameter we can tune later, we'll define the SDE with
a dynamic noise scaled by the second element of the parameter tuple p
,
def noise(_, p):
_, sigma, _ = p
return sigma
turn that into an SDE, choose network size (8 nodes here), with random initial conditions and realize an appropriate sample of noise for SDE integration:
_, loop = vb.make_sde(0.01, net, noise)
n_nodes = 8
rv0 = vb.randn(2, n_nodes)
zs = vb.randn(1000, *rv0.shape)
to run map parameters of interest to some metric of interest, we write a function, where we've chosen the standard deviation after a certain time as a index on the steady state of the network dynamics,
def run(pars, mpr_p=vb.mpr_default_theta):
k, sig, eta = pars # explored pars
p = k, sig, mpr_p._replace(eta=eta) # set mpr
xs = loop(rv0, zs, p) # run sim
std = xs[400:, 0].std() # eval metric
return std # done
all that is plain virtual brain equations, but to enable efficient & parallel
sweeps, we can pull in jax primitives jax.pmap
to parallelize over compute
devices (by default, cores of the CPU) and jax.vmap
to vectorize the function run
,
or just a jax.vmap
if using a GPU,
using_cpu = jax.local_devices()[0].platform == 'cpu'
if using_cpu:
run_batches = jax.pmap(jax.vmap(run, in_axes=1), in_axes=0)
else:
run_batches = jax.vmap(run, in_axes=1)
now we run this over a parameter space (adapting for number of cores)
# sweep sigma but just a few values are enough
sigmas = [0.0, 0.2, 0.3, 0.4]
results = []
ng = vb.cores*4 if using_cpu else 32
for i, sig_i in enumerate(sigmas):
# create grid of k (on logarithmic scale) and eta
log_ks, etas = np.mgrid[-9.0:-2.0:1j*ng, -4.0:-6.0:1j*ng]
# reshape grid to big batch of values
pars = np.c_[
np.exp(log_ks.ravel()),
np.ones(log_ks.size)*sig_i,
etas.ravel()].T.copy()
# cpu w/ pmap expects a chunk for each core
if using_cpu:
pars = pars.reshape((3, vb.cores, -1)).transpose((1, 0, 2))
# now run
result = run_batches(pars).block_until_ready()
results.append(result)
and plot the results,
import pylab as pl
pl.figure(figsize=(8,2))
for i, (sig_i, result) in enumerate(zip(sigmas, results)):
pl.subplot(1, 4, i + 1)
pl.imshow(result.reshape(log_ks.shape), vmin=0.2, vmax=0.7)
pl.ylabel('k') if i==0 else (), pl.xlabel('eta')
pl.title(f'sig = {sig_i:0.1f}')
pl.show()
pl.savefig('example3.jpg')
A full runnable script is in examples/parsweep.py
.
Performance notes
Is (vb)jax fast? Single threaded C/C++ code typically reaches 50 to 200 thousand iterations per second on a single CPU core, for network sizes of e.g. 164 (e.g. Destrieux atlas from FreeSurfer). Let's check efficiency of the Jax code for some hardware on my desk:
- Xeon W-2133 (2017 14 nm Skylake) uses 88 W to do 5.7 Miter/s = 65 Kiter/W
- Quadro RTX 5000 (2018 12 nm Turing) uses 200 W to do 26 Miter/s = 130 Kiter/W
- M1 Air (2020 5 nm M1) uses 18 W to do 3.7 Miter/s = 205 Kiter/W
You can tweak this script to see what you might expect on your hardware.
Distributed
If you are using a system like Dask or Slurm, you can then invoke
that run_batches
function in a distributed setting as required,
without needing to manage a per core or per node for loop.
Simplest neural field
Here's a neural field,
import jax.numpy as np
import vbjax as vb
# setup local connectivity
lmax, nlat, nlon = 16, 32, 64
lc = vb.make_shtdiff(lmax=lmax, nlat=nlat, nlon=nlon)
# network dynamics
def net(x, p):
c = lc(x[0]), 0.0
return vb.mpr_dfun(x, c, p)
# solution + plot
x0 = vb.randn(2, nlat, nlon)*0.5 + np.r_[0.2,-2.0][:,None,None]
_, loop = vb.make_sde(0.1, net, 0.2)
zs = vb.randn(500, 2, nlat, nlon)
xt = loop(x0, zs, vb.mpr_default_theta._replace(eta=-3.9, cr=5.0))
vb.make_field_gif(xt[::10], 'example2.gif')
This example shows how the field forms patterns gradually despite the noise in the simulation, due to the effect of local connectivity
MCMC estimation of neural field activity
For MCMC estimates with NumPyro we define a function to compute
posterior log probability p(theta | x)
,
def logp(xt=None):
x0h = numpyro.sample('x0h', dist.Normal(jnp.zeros((nlat, nlon)), 1))
xth_mu = loop(x0h, ts, k)
numpyro.sample('xth', dist.Normal(xth_mu, 1), obs=xt)
run MCMC w/ NUTS,
mcmc = MCMC(NUTS(logp), num_warmup=500, num_samples=500)
mcmc.run(jax.random.PRNGKey(0), xt=xt)
x0h = mcmc.get_samples()['x0h']
check diagnostics like estimated sample size, shrinkage and z-score,
ess = numpyro.diagnostics.effective_sample_size(x0h.reshape((1, 500, -1)))
assert ess.min() > 100
shrinkage, zscore = vbjax.shrinkage_zscore(x0, x0h, 1)
assert shrinkage.min() > 0.7
assert zscore.max() < 1.5
Full code is in the test suite, can
be run pytest -m slow
, since it takes about 5 minutes to run on a GPU, 7 min on m1 CPU core and
12 minutes on an x86_64 CPU core.
Fitting an autoregressive process
Here's a 1-lag MVAR
import jax
import jax.numpy as np
import vbjax as vb
nn = 8
true_A = vb.randn(nn,nn)
_, loop = vb.make_sde(1, lambda x,A: -x+(A*x).mean(axis=1), 1)
x0 = vb.randn(nn)
zs = vb.randn(1000, nn)
xt = loop(x0, zs, true_A)
xt
and true_A
are the simulated time series and ground truth
interaction matrices.
To fit anything we need a loss function & gradient descent,
def loss(est_A):
return np.sum(np.square(xt - loop(x0, zs, est_A)))
grad_loss = jax.grad(loss)
est_A = np.ones((nn, nn))*0.3 # wrong
for i in range(51):
est_A = est_A - 0.01*grad_loss(est_A)
if i % 10 == 0:
print('step', i, 'log loss', np.log(loss(est_A)))
print('mean sq err', np.square(est_A - true_A).mean())
which prints
step 0 log loss 5.8016257
step 10 log loss 3.687574
step 20 log loss 1.7174681
step 30 log loss -0.15798996
step 40 log loss -1.9851608
step 50 log loss -3.7805486
mean sq err 8.422789e-05
This is a pretty simple example but it's meant to show that any model you build with vbjax like this is usable with optimization or NumPyro's MCMC algorithms.
ƪ(ړײ)ƪ moar examples‽
More complex examples are in the examples folder:
- high resolution connectome neural field simulation & inference
- parameter sweep example
- more examples cooking 🍩
HPC usage
We use this on HPC systems, most easily with container images. Open an issue if it doesn't work.
CSCS Piz Daint
Useful modules
module load daint-gpu
module load cudatoolkit/11.2.0_3.39-2.1__gf93aa1c
module load TensorFlow
then install in some Python environment; the default works fine
pip3 install "jax[cuda]==0.3.8" -f https://storage.googleapis.com/jax-releases/jax_cuda_releases.html
pip3 install "jaxlib==0.3.8+cuda11.cudnn805" -U -f https://storage.googleapis.com/jax-releases/jax_cuda_releases.html
This provides an older version of JAX unfortunately.
The Sarus runtime can be used to make use of latest versions of vbjax and jax:
$ module load daint-gpu
$ module load sarus
$ sarus pull ghcr.io/ins-amu/vbjax:main
...
$ srun -p debug -A ich042 -C gpu --pty sarus run ghcr.io/ins-amu/vbjax:main python3 -c 'import jax; print(jax.numpy.zeros(32).device())'
...
gpu:0
JSC JUSUF
A nice module is available to get CUDA libs
module load cuDNN/8.6.0.163-CUDA-11.7
then you might set up a conda env,
wget https://repo.anaconda.com/miniconda/Miniconda3-latest-Linux-x86_64.sh
bash Miniconda3-latest-Linux-x86_64.sh -b -p ~/conda
. ~/conda/bin/activate
conda create -n jax python=3.9 numpy scipy
source activate jax
once you have an env, install the CUDA-enabled JAX
pip3 install --upgrade "jax[cuda]" -f https://storage.googleapis.com/jax-releases/jax_cuda_releases.html
and check it works
(jax) [woodman1@jsfl02 ~]$ srun -A icei-hbp-2021-0002 -p develgpus --pty python3 -c 'import jax.numpy as np ; print(np.zeros(32).device())'
gpu:0
JSC also makes Singularity available, so the prebuilt image can be used
TODO
CEA
The prebuilt image is the best route:
TODO
Development
New ideas or even documenting tricks (like how Jax works) should go into the test suite, and there are some ideas floating there before making it into the library itself.
git clone https://github.com/ins-amu/vbjax
cd vbjax
pip install '.[dev]'
pytest
Installing SHTns
This library is used for some testing. It is impossible to install on Windows natively, so WSLx is required.
On macOS,
brew install fftw
git clone https://bitbucket.org/nschaeff/shtns
./configure --enable-python --disable-simd --prefix=/opt/homebrew
make -j && make install && python setup.py install
Releases
a release of version v1.2.3
requires following steps
-
git checkout main
: tag releases from main for now - edit
_version.py
to have correct release number -
python -m vbjax._version tag
to create and push new tag - use GitHub UI to create new release
Project details
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