JaxPM_highres/tests/conftest.py

# Parameterized fixture for mesh_shape
import os

import pytest

os.environ["EQX_ON_ERROR"] = "nan"
setup_done = False
on_cluster = False


def is_on_cluster():
    global on_cluster
    return on_cluster


def initialize_distributed():
    global setup_done
    global on_cluster
    if not setup_done:
        if "SLURM_JOB_ID" in os.environ:
            on_cluster = True
            print("Running on cluster")
            import jax
            jax.distributed.initialize()
            setup_done = True
            on_cluster = True
        else:
            print("Running locally")
            setup_done = True
            on_cluster = False
            os.environ["JAX_PLATFORM_NAME"] = "cpu"
            os.environ[
                "XLA_FLAGS"] = "--xla_force_host_platform_device_count=8"
            import jax


@pytest.fixture(
    scope="session",
    params=[
        ((32, 32, 32), (256., 256., 256.)),  # BOX
        ((32, 32, 64), (256., 256., 512.)),  # RECTANGULAR
    ])
def simulation_config(request):
    return request.param


@pytest.fixture(scope="session", params=[0.1, 0.5, 0.8])
def lpt_scale_factor(request):
    return request.param


@pytest.fixture(scope="session")
def cosmo():
    from functools import partial

    from jax_cosmo import Cosmology
    Planck18 = partial(
        Cosmology,
        # Omega_m = 0.3111
        Omega_c=0.2607,
        Omega_b=0.0490,
        Omega_k=0.0,
        h=0.6766,
        n_s=0.9665,
        sigma8=0.8102,
        w0=-1.0,
        wa=0.0,
    )

    return Planck18()


@pytest.fixture(scope="session")
def particle_mesh(simulation_config):
    from pmesh.pm import ParticleMesh
    mesh_shape, box_shape = simulation_config
    return ParticleMesh(BoxSize=box_shape, Nmesh=mesh_shape, dtype='f4')


@pytest.fixture(scope="session")
def fpm_initial_conditions(cosmo, particle_mesh):
    import jax_cosmo as jc
    import numpy as np
    from jax import numpy as jnp

    # Generate initial particle positions
    grid = particle_mesh.generate_uniform_particle_grid(shift=0).astype(
        np.float32)
    # Interpolate with linear_matter spectrum to get initial density field
    k = jnp.logspace(-4, 1, 128)
    pk = jc.power.linear_matter_power(cosmo, k)

    def pk_fn(x):
        return jnp.interp(x.reshape([-1]), k, pk).reshape(x.shape)

    whitec = particle_mesh.generate_whitenoise(42,
                                               type='complex',
                                               unitary=False)
    lineark = whitec.apply(lambda k, v: pk_fn(sum(ki**2 for ki in k)**0.5)**0.5
                           * v * (1 / v.BoxSize).prod()**0.5)
    init_mesh = lineark.c2r().value  # XXX

    return lineark, grid, init_mesh


@pytest.fixture(scope="session")
def initial_conditions(fpm_initial_conditions):
    _, _, init_mesh = fpm_initial_conditions
    return init_mesh


@pytest.fixture(scope="session")
def solver(cosmo, particle_mesh):
    from fastpm.core import Cosmology as FastPMCosmology
    from fastpm.core import Solver
    ref_cosmo = FastPMCosmology(cosmo)
    return Solver(particle_mesh, ref_cosmo, B=1)


@pytest.fixture(scope="session")
def fpm_lpt1(solver, fpm_initial_conditions, lpt_scale_factor):

    lineark, grid, _ = fpm_initial_conditions
    statelpt = solver.lpt(lineark, grid, lpt_scale_factor, order=1)
    return statelpt


@pytest.fixture(scope="session")
def fpm_lpt1_field(fpm_lpt1, particle_mesh):
    return particle_mesh.paint(fpm_lpt1.X).value


@pytest.fixture(scope="session")
def fpm_lpt2(solver, fpm_initial_conditions, lpt_scale_factor):

    lineark, grid, _ = fpm_initial_conditions
    statelpt = solver.lpt(lineark, grid, lpt_scale_factor, order=2)
    return statelpt


@pytest.fixture(scope="session")
def fpm_lpt2_field(fpm_lpt2, particle_mesh):
    return particle_mesh.paint(fpm_lpt2.X).value


@pytest.fixture(scope="session")
def nbody_from_lpt1(solver, fpm_lpt1, particle_mesh, lpt_scale_factor):
    import numpy as np
    from fastpm.core import leapfrog

    if lpt_scale_factor == 0.8:
        pytest.skip("Do not run nbody simulation from scale factor 0.8")

    stages = np.linspace(lpt_scale_factor, 1.0, 10, endpoint=True)

    finalstate = solver.nbody(fpm_lpt1, leapfrog(stages))
    fpm_mesh = particle_mesh.paint(finalstate.X).value

    return fpm_mesh


@pytest.fixture(scope="session")
def nbody_from_lpt2(solver, fpm_lpt2, particle_mesh, lpt_scale_factor):
    import numpy as np
    from fastpm.core import leapfrog

    if lpt_scale_factor == 0.8:
        pytest.skip("Do not run nbody simulation from scale factor 0.8")

    stages = np.linspace(lpt_scale_factor, 1.0, 10, endpoint=True)

    finalstate = solver.nbody(fpm_lpt2, leapfrog(stages))
    fpm_mesh = particle_mesh.paint(finalstate.X).value

    return fpm_mesh
jaxdecomp proto (#21) * adding example of distributed solution * put back old functgion * update formatting * add halo exchange and slice pad * apply formatting * implement distributed optimized cic_paint * Use new cic_paint with halo * Fix seed for distributed normal * Wrap interpolation function to avoid all gather * Return normal order frequencies for single GPU * add example * format * add optimised bench script * times in ms * add lpt2 * update benchmark and add slurm * Visualize only final field * Update scripts/distributed_pm.py Co-authored-by: Francois Lanusse <EiffL@users.noreply.github.com> * Adjust pencil type for frequencies * fix painting issue with slabs * Shared operation in fourrier space now take inverted sharding axis for slabs * add assert to make pyright happy * adjust test for hpc-plotter * add PMWD test * bench * format * added github workflow * fix formatting from main * Update for jaxDecomp pure JAX * revert single halo extent change * update for latest jaxDecomp * remove fourrier_space in autoshmap * make normal_field work with single controller * format * make distributed pm work in single controller * merge bench_pm * update to leapfrog * add a strict dependency on jaxdecomp * global mesh no longer needed * kernels.py no longer uses global mesh * quick fix in distributed * pm.py no longer uses global mesh * painting.py no longer uses global mesh * update demo script * quick fix in kernels * quick fix in distributed * update demo * merge hugos LPT2 code * format * Small fix * format * remove duplicate get_ode_fn * update visualizer * update compensate CIC * By default check_rep is false for shard_map * remove experimental distributed code * update PGDCorrection and neural ode to use new fft3d * jaxDecomp pfft3d promotes to complex automatically * remove deprecated stuff * fix painting issue with read_cic * use jnp interp instead of jc interp * delete old slurms * add notebook examples * apply formatting * add distributed zeros * fix code in LPT2 * jit cic_paint * update notebooks * apply formating * get local shape and zeros can be used by users * add a user facing function to create uniform particle grid * use jax interp instead of jax_cosmo * use float64 for enmeshing * Allow applying weights with relative cic paint * Weights can be traced * remove script folder * update example notebooks * delete outdated design file * add readme for tutorials * update readme * fix small error * forgot particles in multi host * clarifying why cic_paint_dx is slower * clarifying the halo size dependence on the box size * ability to choose snapshots number with MultiHost script * Adding animation notebook * Put plotting in package * Add finite difference laplace kernel + powerspec functions from Hugo Co-authored-by: Hugo Simonfroy <hugo.simonfroy@gmail.com> * Put plotting utils in package * By default use absoulute painting with * update code * update notebooks * add tests * Upgrade setup.py to pyproject * Format * format tests * update test dependencies * add test workflow * fix deprecated FftType in jaxpm.kernels * Add aboucaud comments * JAX version is 0.4.35 until Diffrax new release * add numpy explicitly as dependency for tests * fix install order for tests * add numpy to be installed * enforce no build isolation for fastpm * pip install jaxpm test without build isolation * bump jaxdecomp version * revert test workflow * remove outdated tests --------- Co-authored-by: EiffL <fr.eiffel@gmail.com> Co-authored-by: Francois Lanusse <EiffL@users.noreply.github.com> Co-authored-by: Wassim KABALAN <wassim@apc.in2p3.fr> Co-authored-by: Hugo Simonfroy <hugo.simonfroy@gmail.com> Former-commit-id: 8c2e823d4669eac712089bf7f85ffb7912e8232d 2024-12-20 11:44:02 +01:00			`# Parameterized fixture for mesh_shape`
			`import os`

			`import pytest`

			`os.environ["EQX_ON_ERROR"] = "nan"`
			`setup_done = False`
			`on_cluster = False`


			`def is_on_cluster():`
			`global on_cluster`
			`return on_cluster`


			`def initialize_distributed():`
			`global setup_done`
			`global on_cluster`
			`if not setup_done:`
			`if "SLURM_JOB_ID" in os.environ:`
			`on_cluster = True`
			`print("Running on cluster")`
			`import jax`
			`jax.distributed.initialize()`
			`setup_done = True`
			`on_cluster = True`
			`else:`
			`print("Running locally")`
			`setup_done = True`
			`on_cluster = False`
			`os.environ["JAX_PLATFORM_NAME"] = "cpu"`
			`os.environ[`
			`"XLA_FLAGS"] = "--xla_force_host_platform_device_count=8"`
			`import jax`


			`@pytest.fixture(`
			`scope="session",`
			`params=[`
			`((32, 32, 32), (256., 256., 256.)), # BOX`
			`((32, 32, 64), (256., 256., 512.)), # RECTANGULAR`
			`])`
			`def simulation_config(request):`
			`return request.param`


			`@pytest.fixture(scope="session", params=[0.1, 0.5, 0.8])`
			`def lpt_scale_factor(request):`
			`return request.param`


			`@pytest.fixture(scope="session")`
			`def cosmo():`
			`from functools import partial`

			`from jax_cosmo import Cosmology`
			`Planck18 = partial(`
			`Cosmology,`
			`# Omega_m = 0.3111`
			`Omega_c=0.2607,`
			`Omega_b=0.0490,`
			`Omega_k=0.0,`
			`h=0.6766,`
			`n_s=0.9665,`
			`sigma8=0.8102,`
			`w0=-1.0,`
			`wa=0.0,`
			`)`

			`return Planck18()`


			`@pytest.fixture(scope="session")`
			`def particle_mesh(simulation_config):`
			`from pmesh.pm import ParticleMesh`
			`mesh_shape, box_shape = simulation_config`
			`return ParticleMesh(BoxSize=box_shape, Nmesh=mesh_shape, dtype='f4')`


			`@pytest.fixture(scope="session")`
			`def fpm_initial_conditions(cosmo, particle_mesh):`
			`import jax_cosmo as jc`
			`import numpy as np`
			`from jax import numpy as jnp`

			`# Generate initial particle positions`
			`grid = particle_mesh.generate_uniform_particle_grid(shift=0).astype(`
			`np.float32)`
			`# Interpolate with linear_matter spectrum to get initial density field`
			`k = jnp.logspace(-4, 1, 128)`
			`pk = jc.power.linear_matter_power(cosmo, k)`

			`def pk_fn(x):`
			`return jnp.interp(x.reshape([-1]), k, pk).reshape(x.shape)`

			`whitec = particle_mesh.generate_whitenoise(42,`
			`type='complex',`
			`unitary=False)`
			`lineark = whitec.apply(lambda k, v: pk_fn(sum(ki2 for ki in k)0.5)**0.5`
			`* v * (1 / v.BoxSize).prod()**0.5)`
			`init_mesh = lineark.c2r().value # XXX`

			`return lineark, grid, init_mesh`


			`@pytest.fixture(scope="session")`
			`def initial_conditions(fpm_initial_conditions):`
			`_, _, init_mesh = fpm_initial_conditions`
			`return init_mesh`


			`@pytest.fixture(scope="session")`
			`def solver(cosmo, particle_mesh):`
			`from fastpm.core import Cosmology as FastPMCosmology`
			`from fastpm.core import Solver`
			`ref_cosmo = FastPMCosmology(cosmo)`
			`return Solver(particle_mesh, ref_cosmo, B=1)`


			`@pytest.fixture(scope="session")`
			`def fpm_lpt1(solver, fpm_initial_conditions, lpt_scale_factor):`

			`lineark, grid, _ = fpm_initial_conditions`
			`statelpt = solver.lpt(lineark, grid, lpt_scale_factor, order=1)`
			`return statelpt`


			`@pytest.fixture(scope="session")`
			`def fpm_lpt1_field(fpm_lpt1, particle_mesh):`
			`return particle_mesh.paint(fpm_lpt1.X).value`


			`@pytest.fixture(scope="session")`
			`def fpm_lpt2(solver, fpm_initial_conditions, lpt_scale_factor):`

			`lineark, grid, _ = fpm_initial_conditions`
			`statelpt = solver.lpt(lineark, grid, lpt_scale_factor, order=2)`
			`return statelpt`


			`@pytest.fixture(scope="session")`
			`def fpm_lpt2_field(fpm_lpt2, particle_mesh):`
			`return particle_mesh.paint(fpm_lpt2.X).value`


			`@pytest.fixture(scope="session")`
			`def nbody_from_lpt1(solver, fpm_lpt1, particle_mesh, lpt_scale_factor):`
			`import numpy as np`
			`from fastpm.core import leapfrog`

			`if lpt_scale_factor == 0.8:`
			`pytest.skip("Do not run nbody simulation from scale factor 0.8")`

			`stages = np.linspace(lpt_scale_factor, 1.0, 10, endpoint=True)`

			`finalstate = solver.nbody(fpm_lpt1, leapfrog(stages))`
			`fpm_mesh = particle_mesh.paint(finalstate.X).value`

			`return fpm_mesh`


			`@pytest.fixture(scope="session")`
			`def nbody_from_lpt2(solver, fpm_lpt2, particle_mesh, lpt_scale_factor):`
			`import numpy as np`
			`from fastpm.core import leapfrog`

			`if lpt_scale_factor == 0.8:`
			`pytest.skip("Do not run nbody simulation from scale factor 0.8")`

			`stages = np.linspace(lpt_scale_factor, 1.0, 10, endpoint=True)`

			`finalstate = solver.nbody(fpm_lpt2, leapfrog(stages))`
			`fpm_mesh = particle_mesh.paint(finalstate.X).value`

			`return fpm_mesh`