bench

benchmarks/bench_pm.py

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+import os
+
+os.environ["EQX_ON_ERROR"] = "nan"  # avoid an allgather caused by diffrax
+import jax
+
+jax.distributed.initialize()
+
+rank = jax.process_index()
+size = jax.process_count()
+
+import argparse
+import time
+from hpc_plotter.timer import Timer
+import jax.numpy as jnp
+import jax_cosmo as jc
+import numpy as np
+from cupy.cuda.nvtx import RangePop, RangePush
+from diffrax import (ConstantStepSize, Dopri5, LeapfrogMidpoint, ODETerm,
+                     PIDController, SaveAt, Tsit5, diffeqsolve)
+from jax.experimental import mesh_utils
+from jax.experimental.multihost_utils import sync_global_devices
+from jax.sharding import Mesh, NamedSharding
+from jax.sharding import PartitionSpec as P
+
+from jaxpm.kernels import interpolate_power_spectrum
+from jaxpm.painting import cic_paint_dx
+from jaxpm.pm import linear_field, lpt, make_ode_fn
+
+
+
+def run_simulation(mesh_shape,
+                   box_size,
+                   halo_size,
+                   solver_choice,
+                   iterations,
+                   pdims=None):
+
+    @jax.jit
+    def simulate(omega_c, sigma8):
+        # Create a small function to generate the matter power spectrum
+        k = jnp.logspace(-4, 1, 128)
+        pk = jc.power.linear_matter_power(
+            jc.Planck15(Omega_c=omega_c, sigma8=sigma8), k)
+        pk_fn = lambda x: interpolate_power_spectrum(x, k, pk)
+
+        # Create initial conditions
+        initial_conditions = linear_field(mesh_shape,
+                                          box_size,
+                                          pk_fn,
+                                          seed=jax.random.PRNGKey(0))
+
+        # Create particles
+        cosmo = jc.Planck15(Omega_c=omega_c, sigma8=sigma8)
+        dx, p, _ = lpt(cosmo, initial_conditions, 0.1, halo_size=halo_size)
+        if solver_choice == "Dopri5":
+            solver = Dopri5()
+        elif solver_choice == "LeapfrogMidpoint":
+            solver = LeapfrogMidpoint()
+        elif solver_choice == "Tsit5":
+            solver = Tsit5()
+        elif solver_choice == "lpt":
+            lpt_field = cic_paint_dx(dx, halo_size=halo_size)
+            print(f"TYPE of lpt_field: {type(lpt_field)}")
+            return lpt_field, {"num_steps": 0}
+        else:
+            raise ValueError(
+                "Invalid solver choice. Use 'Dopri5' or 'LeapfrogMidpoint'.")
+        # Evolve the simulation forward
+        ode_fn = make_ode_fn(mesh_shape, halo_size=halo_size)
+        term = ODETerm(
+            lambda t, state, args: jnp.stack(ode_fn(state, t, args), axis=0))
+        
+        if solver_choice == "Dopri5" or solver_choice == "Tsit5":
+            stepsize_controller = PIDController(rtol=1e-4, atol=1e-4)
+        elif solver_choice == "LeapfrogMidpoint" or solver_choice == "Euler":
+            stepsize_controller = ConstantStepSize()
+        res = diffeqsolve(term,
+                          solver,
+                          t0=0.1,
+                          t1=1.,
+                          dt0=0.01,
+                          y0=jnp.stack([dx, p], axis=0),
+                          args=cosmo,
+                          saveat=SaveAt(t1=True),
+                          stepsize_controller=stepsize_controller)
+
+        # Return the simulation volume at requested
+        state = res.ys[-1]
+        final_field = cic_paint_dx(state[0], halo_size=halo_size)
+
+        return final_field, res.stats
+
+    def run():
+        # Warm start
+        chrono_fun = Timer()
+        RangePush("warmup")
+        final_field, stats = chrono_fun.chrono_jit(simulate, 0.32, 0.8 , ndarray_arg = 0)
+        RangePop()
+        sync_global_devices("warmup")
+        for i in range(iterations):
+            RangePush(f"sim iter {i}")
+            final_field, stats = chrono_fun.chrono_fun(simulate, 0.32, 0.8 , ndarray_arg = 0)
+            RangePop()
+        return final_field, stats, chrono_fun
+
+    if jax.device_count() > 1:
+        devices = mesh_utils.create_device_mesh(pdims)
+        mesh = Mesh(devices.T, axis_names=('x', 'y'))
+        with mesh:
+            # Warm start
+            final_field, stats, chrono_fun = run()
+    else:
+        final_field, stats, chrono_fun = run()
+
+    return final_field, stats, chrono_fun
+
+
+if __name__ == "__main__":
+
+    parser = argparse.ArgumentParser(
+        description='JAX Cosmo Simulation Benchmark')
+    parser.add_argument('-m',
+                        '--mesh_size',
+                        type=int,
+                        help='Mesh size',
+                        required=True)
+    parser.add_argument('-b',
+                        '--box_size',
+                        type=float,
+                        help='Box size',
+                        required=True)
+    parser.add_argument('-p',
+                        '--pdims',
+                        type=str,
+                        help='Processor dimensions',
+                        default=None)
+    parser.add_argument('-pr',
+                        '--precision',
+                        type=str,
+                        help='Precision',
+                        choices=["float32", "float64"],)
+    parser.add_argument('-hs',
+                        '--halo_size',
+                        type=int,
+                        help='Halo size',
+                        required=True)
+    parser.add_argument('-s',
+                        '--solver',
+                        type=str,
+                        help='Solver',
+                        choices=[
+                            "Dopri5", "dopri5", "d5", "Tsit5", "tsit5", "t5",
+                            "LeapfrogMidpoint", "leapfrogmidpoint", "lfm",
+                            "lpt"
+                        ],
+                        required=True)
+    parser.add_argument('-i',
+                        '--iterations',
+                        type=int,
+                        help='Number of iterations',
+                        default=10)
+    parser.add_argument('-o',
+                        '--output_path',
+                        type=str,
+                        help='Output path',
+                        default=".")
+    parser.add_argument('-f',
+                        '--save_fields',
+                        action='store_true',
+                        help='Save fields')
+    parser.add_argument('-n',
+                        '--nodes',
+                        type=int,
+                        help='Number of nodes',
+                        default=1)
+    
+    args = parser.parse_args()
+    mesh_size = args.mesh_size
+    box_size = [args.box_size] * 3
+    halo_size = args.halo_size
+    solver_choice = args.solver
+    iterations = args.iterations
+    output_path = args.output_path
+    os.makedirs(output_path, exist_ok=True)
+    
+    print(f"solver choice: {solver_choice}")
+    match solver_choice:
+        case "Dopri5" | "dopri5"| "d5":
+            solver_choice = "Dopri5"
+        case "Tsit5"| "tsit5"| "t5":
+            solver_choice = "Tsit5"
+        case "LeapfrogMidpoint"| "leapfrogmidpoint"| "lfm":
+            solver_choice = "LeapfrogMidpoint"
+        case "lpt":
+            solver_choice = "lpt"
+        case _:
+            raise ValueError(
+                "Invalid solver choice. Use 'Dopri5', 'Tsit5', 'LeapfrogMidpoint' or 'lpt"
+            )
+    if args.precision == "float32":
+        jax.config.update("jax_enable_x64", False)
+    elif args.precision == "float64":  
+        jax.config.update("jax_enable_x64", True)
+
+    if args.pdims:
+        pdims = tuple(map(int, args.pdims.split("x")))
+    else:
+        pdims = (1, 1)
+
+    mesh_shape = [mesh_size] * 3
+
+    final_field , stats, chrono_fun = run_simulation(mesh_shape, box_size, halo_size, solver_choice, iterations, pdims)
+    
+    print(f"shape of final_field {final_field.shape} and sharding spec {final_field.sharding} and local shape {final_field.addressable_data(0).shape}")
+
+    metadata = {
+      'rank': rank,
+      'function_name': f'JAXPM-{solver_choice}',
+      'precision': args.precision,
+      'x': str(mesh_size),
+      'y': str(mesh_size),
+      'z': str(stats["num_steps"]),
+      'px': str(pdims[0]),
+      'py': str(pdims[1]),
+      'backend': 'NCCL',
+      'nodes': str(args.nodes)
+  }
+    # Print the results to a CSV file
+    chrono_fun.print_to_csv(f'{output_path}/jaxpm_benchmark.csv', **metadata)
+
+    # Save the final field
+    nb_gpus = jax.device_count()
+    pdm_str = f"{pdims[0]}x{pdims[1]}"
+    field_folder = f"{output_path}/final_field/jaxpm/{nb_gpus}/{mesh_size}_{int(box_size[0])}/{pdm_str}/{solver_choice}/halo_{halo_size}"
+    os.makedirs(field_folder, exist_ok=True)
+    with open(f'{field_folder}/jaxpm.log', 'w') as f:
+        f.write(f"Args: {args}\n")
+        f.write(f"JIT time: {chrono_fun.jit_time:.4f} ms\n")
+        for i , time in enumerate(chrono_fun.times):
+          f.write(f"Time {i}: {time:.4f} ms\n")
+        f.write(f"Stats: {stats}\n")
+    if args.save_fields:
+        np.save(f'{field_folder}/final_field_0_{rank}.npy',
+                final_field.addressable_data(0))
+
+    print(f"Finished! ")
+    print(f"Stats {stats}")
+    print(f"Saving to {output_path}/jax_pm_benchmark.csv")
+    print(f"Saving field and logs in {field_folder}")