# Copyright 2021 The JAX Authors. # # Licensed under the Apache License, Version 2.0 (the "License"); # you may not use this file except in compliance with the License. # You may obtain a copy of the License at # # https://www.apache.org/licenses/LICENSE-2.0 # # Unless required by applicable law or agreed to in writing, software # distributed under the License is distributed on an "AS IS" BASIS, # WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. # See the License for the specific language governing permissions and # limitations under the License. from collections import OrderedDict, namedtuple import contextlib import re from functools import partial import logging import math import textwrap import threading import unittest from absl.testing import absltest from absl.testing import parameterized import numpy as np import concurrent.futures import jax import jax.numpy as jnp from jax._src import core from jax._src import config from jax._src import test_util as jtu from jax import dtypes from jax import stages from jax import lax from jax._src.lax import lax as lax_internal from jax.lax import with_sharding_constraint from jax._src import prng from jax.sharding import PartitionSpec as P, Mesh from jax.experimental import multihost_utils from jax.experimental.custom_partitioning import custom_partitioning from jax._src import array from jax._src.sharding import Sharding, common_devices_indices_map from jax._src import op_shardings from jax._src import sharding_impls from jax._src.sharding_impls import ( AUTO, UNSPECIFIED, NamedSharding, GSPMDSharding, PositionalSharding, SingleDeviceSharding, parse_flatten_op_sharding) import jax._src.pjit as pjit_lib from jax._src.pjit import pjit from jax._src import mesh as mesh_lib from jax._src.interpreters import pxla from jax._src.lib.mlir import dialects from jax._src import xla_bridge from jax._src.lib import xla_client as xc from jax._src.lib import xla_extension from jax._src.util import curry, unzip2 config.parse_flags_with_absl() # Run all tests with 8 CPU devices. _exit_stack = contextlib.ExitStack() def setUpModule(): _exit_stack.enter_context(jtu.set_host_platform_device_count(8)) def tearDownModule(): _exit_stack.close() def create_array(global_shape, global_mesh, mesh_axes, global_data=None, dtype=np.float32): if global_data is None: global_data = np.arange( math.prod(global_shape), dtype=dtype).reshape(global_shape) if isinstance(mesh_axes, Sharding): sharding = mesh_axes else: sharding = NamedSharding(global_mesh, mesh_axes) return array.make_array_from_callback( global_shape, sharding, lambda idx: global_data[idx]), global_data def _check_instance(self, x): self.assertIsInstance(x, array.ArrayImpl) @curry def check_1d_2d_mesh(f, set_mesh): return parameterized.named_parameters( {"testcase_name": "_" + name, "mesh": mesh, "resources": resources} for name, mesh, resources in ( ("2", (("x", 2),), "x"), ("2x1", (("x", 2), ("y", 1)), ("x", "y")), ("2x2", (("x", 2), ("y", 2)), ("x", "y")), ))(jtu.with_mesh_from_kwargs(f) if set_mesh else f) # TODO(skye): make the buffer donation utils part of JaxTestCase @jtu.pytest_mark_if_available('multiaccelerator') class PJitTest(jtu.BufferDonationTestCase): @jtu.with_mesh([('x', 1)]) def testDeviceBufferAval(self): @partial(pjit, in_shardings=None, out_shardings=P('x')) def f(x): return x shape = (2, 2) x = np.arange(math.prod(shape), dtype=np.float32).reshape(shape) actual = f(x) expected = x self.assertAllClose(actual, expected, check_dtypes=False) _check_instance(self, actual) self.assertLen(actual.addressable_shards, 1) self.assertAllClose( np.asarray(actual.addressable_shards[0].data), expected, check_dtypes=False) # Repro for a bug on addressable_shards aval _ = repr(actual.addressable_shards) @jtu.with_mesh([('x', 2)]) def testBasic1D(self): @partial(pjit, in_shardings=(P('x'), P('x')), out_shardings=None) def f(x, y): return x + y shape = (8, 8) x = np.arange(math.prod(shape), dtype=np.float32).reshape(shape) actual = f(x, x + 1) expected = x + (x + 1) self.assertAllClose(actual, expected, check_dtypes=False) _check_instance(self, actual) self.assertLen(actual.addressable_shards, 2) self.assertAllClose(np.asarray(actual.addressable_shards[0].data), expected, check_dtypes=False) @jtu.with_mesh([('x', 2)]) def testJitOfPjitDisallowed(self): @partial(pjit, in_shardings=(P('x'), P('x')), out_shardings=None) def f(x, y): return x + y shape = (8, 8) x = np.arange(math.prod(shape), dtype=np.float32).reshape(shape) out = jax.jit(f)(x, x + 1) self.assertArraysEqual(out, x + x + 1) @jtu.with_mesh([('x', 2)]) def testUnevenShardingConstraint(self): @partial(pjit, in_shardings=(P('x'), P('x')), out_shardings=None) def f(x, y): x = x[:3] y = y[:3] x = with_sharding_constraint(x, P('x')) y = with_sharding_constraint(y, P('x')) out = x + y return jnp.pad(out, [[0, 1]]) shape = (4,) x = np.arange(math.prod(shape), dtype=np.float32).reshape(shape) actual = f(x, x + 1) expected = x + (x + 1) self.assertAllClose(actual[:3], expected[:3], check_dtypes=False) _check_instance(self, actual) self.assertLen(actual.addressable_shards, 2) self.assertAllClose(np.asarray(actual.addressable_shards[0].data)[:3], expected[:3], check_dtypes=False) def testBasic1DWithMeshContextManager(self): @partial(pjit, in_shardings=(P('x'), P('x')), out_shardings=None) def f(x, y): return x + y shape = (8, 8) x = np.arange(math.prod(shape), dtype=np.float32).reshape(shape) with jtu.create_global_mesh((2,), ('x')) as mesh: actual = f(x, x + 1) expected = x + (x + 1) self.assertEqual(mesh, jtu.create_global_mesh((2,), ('x'))) self.assertAllClose(actual, expected, check_dtypes=False) _check_instance(self, actual) self.assertLen(actual.addressable_shards, 2) self.assertAllClose(np.asarray(actual.addressable_shards[0].data), expected, check_dtypes=False) @jtu.with_mesh([('x', 2), ('y', 2)]) def testBasic2D(self): @partial(pjit, in_shardings=(P(None, 'x', 'y'), P('y')), out_shardings=P('x')) def f(x, y): return x @ y x_shape = (8, 6, 4) y_shape = (4, 2) x = jnp.arange(math.prod(x_shape)).reshape(x_shape) y = jnp.arange(math.prod(y_shape)).reshape(y_shape) actual = f(x, y) expected = x @ y self.assertAllClose(actual, expected, check_dtypes=False) _check_instance(self, actual) self.assertLen(actual.addressable_shards, 4) split0, split1 = np.split(expected, 2) self.assertAllClose(np.asarray(actual.addressable_shards[0].data), split0, check_dtypes=False) self.assertAllClose(np.asarray(actual.addressable_shards[1].data), split0, check_dtypes=False) self.assertAllClose(np.asarray(actual.addressable_shards[2].data), split1, check_dtypes=False) self.assertAllClose(np.asarray(actual.addressable_shards[3].data), split1, check_dtypes=False) def testDifferentNestedMesh(self): with jtu.create_global_mesh((2, 1), ("x", "y")) as m1: with jtu.create_global_mesh((2, 2), ("a", "b")) as m2: self.assertEqual(mesh_lib.thread_resources.env.physical_mesh, m2) self.assertEqual(mesh_lib.thread_resources.env.physical_mesh, m1) self.assertEqual(mesh_lib.thread_resources.env.physical_mesh, mesh_lib.EMPTY_ENV.physical_mesh) def testSameNestedMesh(self): mesh = jtu.create_global_mesh((2, 1), ("a", "b")) thread_resources = mesh_lib.thread_resources with mesh as m1: with mesh as m2: self.assertEqual(thread_resources.env.physical_mesh, m2) self.assertEqual(thread_resources.env.physical_mesh, m1) self.assertEqual(thread_resources.env.physical_mesh, mesh_lib.EMPTY_ENV.physical_mesh) def testMeshDecorator(self): x = jnp.arange(8) mesh_shape = (2, 2) size = math.prod(mesh_shape) if len(jax.devices()) < size: raise unittest.SkipTest(f"Test requires {size} global devices.") mesh_devices = np.array(jax.devices()[:size]).reshape(mesh_shape) @jax.sharding.Mesh(mesh_devices, ('x', 'y')) def dec(): return pjit(lambda x: x, in_shardings=P('x'), out_shardings=None)(x) out = dec() self.assertArraysEqual(out, x) def testMeshHashRace(self): mesh = jtu.create_global_mesh((2, 1), ('a', 'testMeshHashRace')) self.assertFalse(hasattr(mesh, '_hash')) with concurrent.futures.ThreadPoolExecutor(max_workers=5) as pool: fs = [] for _ in range(5): fs.append(pool.submit(lambda: hash(mesh))) for f in concurrent.futures.as_completed(fs): f.result() self.assertTrue(hasattr(mesh, '_hash')) @jtu.with_mesh([('x', 2), ('y', 2)]) def testTwoMeshAxisSharding(self): @partial(pjit, in_shardings=P(('x', 'y'),), out_shardings=jax.sharding.PartitionSpec(('x', 'y'),)) def f(x, y): return x @ y shape = (8, 8) x = jnp.arange(math.prod(shape)).reshape(shape) actual = f(x, x + 1) expected = x @ (x + 1) self.assertAllClose(actual, expected, check_dtypes=False) _check_instance(self, actual) self.assertLen(actual.addressable_shards, 4) splits = np.split(expected, 4) self.assertAllClose(np.asarray(actual.addressable_shards[0].data), splits[0], check_dtypes=False) self.assertAllClose(np.asarray(actual.addressable_shards[1].data), splits[1], check_dtypes=False) self.assertAllClose(np.asarray(actual.addressable_shards[2].data), splits[2], check_dtypes=False) self.assertAllClose(np.asarray(actual.addressable_shards[3].data), splits[3], check_dtypes=False) @jtu.with_mesh([('x', 2)]) @jtu.run_on_devices('cpu', 'gpu', 'tpu') def testBufferDonation(self): @partial(pjit, in_shardings=P('x'), out_shardings=P('x'), donate_argnums=0) def f(x, y): return x + y shard = pjit(lambda x: x, in_shardings=P('x'), out_shardings=P('x')) x = shard(jnp.ones((2, 5)) * 4) y = shard(jnp.ones((2, 5)) * 2) expected = x + y self.assertAllClose(f(x, y), expected) self.assertNotDeleted(y) self.assertDeleted(x) @jtu.run_on_devices('cpu', 'gpu', 'tpu') def testBufferDonationWithNames(self): mesh = jtu.create_global_mesh((2,), ('x')) s = NamedSharding(mesh, P('x')) @partial(pjit, out_shardings=s, donate_argnames='inp2') def f(inp1, inp2): return inp1 + inp2 x = jax.device_put(np.ones((2, 5)) * 4, s) y = jax.device_put(np.ones((2, 5)) * 2, s) expected = x + y self.assertAllClose(f(x, y), expected) self.assertNotDeleted(x) self.assertDeleted(y) @jtu.run_on_devices('cpu', 'gpu', 'tpu') def testBufferDonationWithKwargs(self): mesh = jtu.create_global_mesh((2,), ('x')) s = NamedSharding(mesh, P('x')) @partial(pjit, out_shardings=s, donate_argnames=('inp2', 'inp3')) def f(inp1, inp2, inp3): return inp1 + inp2 + inp3, inp3 x = jax.device_put(np.ones((2, 5)) * 4, s) y = jax.device_put(np.ones((2, 5)) * 2, s) z = jax.device_put(np.ones((2, 5)), s) expected = x + y + z self.assertAllClose(f(x, inp2=y, inp3=z)[0], expected) self.assertNotDeleted(x) self.assertDeleted(y) self.assertDeleted(z) @jtu.run_on_devices('cpu', 'gpu', 'tpu') def testBufferDonationWithPyTreeKwargs(self): mesh = jtu.create_global_mesh((2,), ('x')) s = NamedSharding(mesh, P('x')) @partial(pjit, out_shardings=s, donate_argnames='inp2') def f(inp1, inp2, inp3): return jax.tree.map(lambda x, y, z: x + y + z, inp1, inp2, inp3) x = np.ones((2, 5)) * 4 x_tree = jax.device_put({"a": {"b": x}, "c": x}, s) y = np.ones((2, 5)) * 2 y_tree = jax.device_put({"a": {"b": y}, "c": y}, s) z = np.ones((2, 5)) z_tree = jax.device_put({"a": {"b": z}, "c": z}, s) expected = x + y + z out = f(x_tree, inp2=y_tree, inp3=z_tree) jax.tree.map(lambda o: self.assertAllClose(o, expected), out) jax.tree.map(self.assertNotDeleted, x_tree) jax.tree.map(self.assertDeleted, y_tree) jax.tree.map(self.assertNotDeleted, z_tree) @jtu.run_on_devices('tpu', 'cpu', 'gpu') def testBufferDonationWithOutputShardingInference(self): mesh = jtu.create_global_mesh((2,), 'x') s = NamedSharding(mesh, P('x')) rs = NamedSharding(mesh, P()) @partial(pjit, donate_argnames=('inp2', 'inp3')) def f(inp1, inp2, inp3): return ( jax.lax.with_sharding_constraint(inp1, rs), inp1, jax.lax.with_sharding_constraint(inp2, rs), inp2, jax.lax.with_sharding_constraint(inp3, rs), inp3, ) x = np.ones((2, 5)) * 4 x_tree = jax.device_put({'a': {'b': x}, 'c': x}, s) y = np.ones((2, 7)) * 2 y_tree = jax.device_put({'a': {'b': y}, 'c': y}, s) z = np.ones((2, 11)) z_tree = jax.device_put({'a': {'b': z}, 'c': z}, s) out = f(x_tree, y_tree, z_tree) jax.tree.map(self.assertNotDeleted, x_tree) jax.tree.map(self.assertDeleted, y_tree) jax.tree.map(self.assertDeleted, z_tree) @jtu.run_on_devices('tpu') def testBufferDonationWithOutputShardingInferenceAndTokens(self): mesh = jtu.create_global_mesh((2,), 'x') s = NamedSharding(mesh, P('x')) def _callback(x): self.assertIsInstance(x, jax.Array) @partial(pjit, donate_argnames=('x')) def f(x): # Just to get tokens. jax.experimental.io_callback(_callback, None, x, ordered=True) jax.experimental.io_callback(_callback, None, x, ordered=True) return x * x x = np.ones((2, 5)) * 4 x = jax.device_put(x, s) f(x) jax.effects_barrier() self.assertDeleted(x) @jtu.run_on_devices('tpu', 'cpu', 'gpu') def testBufferDonationNotDonated(self): mesh = jtu.create_global_mesh((2,), 'x') s = NamedSharding(mesh, P('x')) @partial(pjit, donate_argnames=('x')) def f(x): return x @ x.T x = jax.device_put(np.arange(16).reshape(8, 2), s) f(x) self.assertNotDeleted(x) @jtu.with_mesh([('x', 2), ('y', 1)]) def testShardingConstraintStablehlo(self): @partial(pjit, in_shardings=None, out_shardings=None) def f(x): y = x + 1 y = with_sharding_constraint(y, P('x', 'y')) return y * 2 shape = (8, 8) x = np.arange(math.prod(shape)).reshape(shape) expected = (x + 1) * 2 actual = f(x) self.assertAllClose(actual, expected, check_dtypes=False) _check_instance(self, actual) self.assertLen(actual.addressable_shards, 2) self.assertAllClose(np.asarray(actual.addressable_shards[0].data), expected, check_dtypes=False) hlo = f.lower(np.ones(shape)).compiler_ir() # Annotation from with_sharding_constraint self.assertIn('sharding = "{devices=[2,1]<=[2]}"', str(hlo)) # Annotation from pjit self.assertIn('sharding = "{replicated}"', str(hlo)) def testShardingConstraintWithArray(self): mesh = jtu.create_global_mesh((2, 1), ('x', 'y')) s = NamedSharding(mesh, P(None)) @partial(pjit, in_shardings=s, out_shardings=s) def f(x): y = x + 1 y = with_sharding_constraint(y, NamedSharding(mesh, P('x', 'y'))) return y * 2 shape = (8, 8) x = np.arange(math.prod(shape)).reshape(shape) expected = (x + 1) * 2 actual = f(x) self.assertAllClose(actual, expected, check_dtypes=False) self.assertIsInstance(actual, array.ArrayImpl) self.assertLen(actual.addressable_shards, 2) self.assertAllClose(actual, expected, check_dtypes=False) hlo = f.lower(np.ones(shape)).compiler_ir(dialect="hlo") # Annotation from with_sharding_constraint self.assertIn('sharding={devices=[2,1]<=[2]}', hlo.as_hlo_text()) # Annotation from pjit self.assertIn("sharding={replicated}", hlo.as_hlo_text()) def testShardingConstraintWithArrayOpSharding(self): shape = (8, 8) mesh = jtu.create_global_mesh((2, 1), ('x', 'y')) s = NamedSharding(mesh, P(None)) ops = pxla.to_gspmd_sharding( NamedSharding(mesh, P('x', 'y')), len(shape)) @partial(pjit, in_shardings=s, out_shardings=s) def f(x): y = x + 1 y = with_sharding_constraint(y, ops) return y * 2 x = np.arange(math.prod(shape)).reshape(shape) expected = (x + 1) * 2 actual = f(x) self.assertAllClose(actual, expected, check_dtypes=False) self.assertIsInstance(actual, array.ArrayImpl) self.assertLen(actual.addressable_shards, 2) self.assertAllClose(actual, expected, check_dtypes=False) hlo = f.lower(np.ones(shape)).compiler_ir(dialect="hlo") # Annotation from with_sharding_constraint self.assertIn('sharding={devices=[2,1]<=[2]}', hlo.as_hlo_text()) # Annotation from pjit self.assertIn("sharding={replicated}", hlo.as_hlo_text()) def testShardingConstraintPyTreeWithArray(self): mesh = jtu.create_global_mesh((2, 1), ('x', 'y')) @jax.jit def f(x): return with_sharding_constraint(x, NamedSharding(mesh, P('x', 'y'))) shape = (8, 8) v = np.arange(math.prod(shape)).reshape(shape) x = [v, v * 2] out = f(x) self.assertArraysEqual(out[0], v) self.assertArraysEqual(out[1], v * 2) self.assertLen(out[0].addressable_shards, 2) self.assertLen(out[1].addressable_shards, 2) hlo = f.lower(x).compiler_ir(dialect="hlo") # Annotations from with_sharding_constraint self.assertIn('sharding={devices=[2,1]<=[2]}', hlo.as_hlo_text()) self.assertIn('sharding={devices=[2,1]<=[2]}', hlo.as_hlo_text()) def testShardingConstraintPyTreeWithUnconstrainedDimsWithJit(self): mesh = jtu.create_global_mesh((2, 2), ('x', 'y')) @jax.jit def f(x): x = with_sharding_constraint( x, [NamedSharding(mesh, P(P.UNCONSTRAINED, 'y', None)), NamedSharding(mesh, P('x', P.UNCONSTRAINED, None))]) x = x.copy() x[0]['a'] *= 2 return x shape = (2, 8, 8) v = np.arange(math.prod(shape)).reshape(shape) x = [{'a': v, 'b': v * 2}, v * 3] actual = f(x) expected = x.copy() expected[0]['a'] *= 2 self.assertAllClose(actual, expected, check_dtypes=False) self.assertLen(actual[0]['a'].addressable_shards, 4) mlir_str = str(f.lower(x).compiler_ir()) self.assertIn("unspecified_dims=[0]", mlir_str) self.assertIn("unspecified_dims=[1]", mlir_str) @jtu.with_mesh([('x', 2), ('y', 2)]) def testShardingConstraintPyTreeVmapWithUnconstrainedDims(self): @partial(pjit, in_shardings=None, out_shardings=None) def f(x): x = jax.vmap(lambda x: with_sharding_constraint( x, [P(P.UNCONSTRAINED, 'y'), P('x', P.UNCONSTRAINED)]))(x) x = x.copy() x[0]['a'] *= 2 return x shape = (2, 8, 8) v = np.arange(math.prod(shape)).reshape(shape) x = [{'a': v, 'b': v * 2}, v * 3] mlir_str = str(f.lower(x).compiler_ir()) self.assertIn("unspecified_dims=[0,1]", mlir_str) self.assertIn("unspecified_dims=[0,2]", mlir_str) def testCaching(self): def f(x): assert should_be_tracing return jnp.sin(x) * 2 x = np.arange(16).reshape(4, 4) devices = np.array(list(jax.local_devices())[:4]) if devices.size < 4: raise unittest.SkipTest("Test requires 4 devices") devices = devices.reshape((2, 2)) with jax.sharding.Mesh(devices, ('x', 'y')): should_be_tracing = True pjit(f, in_shardings=P(('x', 'y')), out_shardings=None)(x) should_be_tracing = False pjit(f, in_shardings=P(('x', 'y')), out_shardings=None)(x) # Re-create the mesh to make sure that has no influence on caching with jax.sharding.Mesh(devices, ('x', 'y')): should_be_tracing = False pjit(f, in_shardings=P(('x', 'y')), out_shardings=None)(x) @jtu.with_mesh([('x', 2), ('y', 1)]) def testNested(self): # Add a constant captured by the nested pjit to make things more complicated h = jnp.arange(4.) f = pjit( lambda x: x.sum() + h.sum(), in_shardings=P('x', 'y'), out_shardings=None, ) g = pjit( lambda x: f(jnp.sin(x)), in_shardings=P('x', None), out_shardings=None ) x = jnp.arange(16.).reshape((4, 4)) y = g(x) self.assertAllClose(y, jnp.sin(x).sum() + h.sum()) _check_instance(self, y) @check_1d_2d_mesh(set_mesh=True) def testAutodiff(self, mesh, resources): if len(mesh) != 2: return assert resources == ('x', 'y') # Add a constant captured by the nested pjit to make things more complicated h = jnp.arange(4.) f = pjit( lambda x: x.sum(1) * h.sum(), in_shardings=P('x', 'y'), out_shardings=P(('x', 'y')), ) g = pjit( lambda x: f(jnp.sin(x * 4 + 2)), in_shardings=P('x', None), out_shardings=P(('x', 'y')), ) jtu.check_grads(g, (jnp.arange(16.).reshape((4, 4)) / 100,), order=2) @jtu.with_mesh([('x', 2), ('y', 1)]) def testAutodiffCache(self): f = pjit( lambda x: jnp.sin(x).sum(), in_shardings=P('x'), out_shardings=None ) x = jnp.arange(16, dtype=jnp.float32) jax.grad(f)(x) # Warm up the cache. before = pjit_lib._pjit_lower_cached.cache_info() jax.grad(f)(x) after = pjit_lib._pjit_lower_cached.cache_info() # One hit for the forward pass, one hit for backward. self.assertEqual(after.hits, before.hits + 2) self.assertEqual(after.misses, before.misses) @jtu.with_mesh([('x', 2), ('y', 1)]) def testEvalJaxpr(self): x, y = jnp.arange(4.), jnp.arange(5.) f = pjit( lambda x, y: x.sum() + jnp.sin(y), in_shardings=(P('x'), P('y')), out_shardings=P('y'), ) f_jaxpr = jax.make_jaxpr(f)(x, y) f_eval = core.jaxpr_as_fun(f_jaxpr) r, = f_eval(x, y) self.assertAllClose(r, x.sum() + jnp.sin(y)) @jtu.with_mesh([('x', 2)]) def testNonArrayArg(self): self.assertEqual( pjit(lambda x: x + 2, in_shardings=None, out_shardings=None)(1), 3 ) @jtu.with_mesh([('x', 2)]) def testNonHashableAxisResources(self): x = jnp.arange(4) y = pjit( lambda x: {'b': x['a'] + 2}, in_shardings=({'a': P('x')},), out_shardings={'b': P('x')}, )({'a': x}) self.assertAllClose(y, {'b': x + 2}) @jtu.with_mesh([('x', 2)]) def testGradOfConstraint(self): # Make sure that we can compute grads through sharding constraints h = lambda x: jnp.sin(with_sharding_constraint(x, P('x'))).sum() f = pjit(lambda x: jax.grad(h)(x), in_shardings=None, out_shardings=None) x = jnp.arange(8, dtype=jnp.float32) out = f(x) self.assertAllClose(out, jnp.cos(x)) self.assertLen(out.devices(), 2) @jtu.with_mesh([('x', 2)]) def testNoopPartitionSpecs(self): noops = [P(), P(None), P(()), P((), None), P(None, None, ())] x = jnp.arange(8).reshape((2, 2, 2)) for spec in noops: y = pjit(lambda x: x * 2, in_shardings=spec, out_shardings=spec)(x) self.assertAllClose(y, x * 2) @jtu.with_mesh([('x', 2)]) def testVMap(self): f = pjit(lambda x, y: (x + y, x), in_shardings=P('x'), out_shardings=P('x')) x = jnp.arange(4) y = jnp.arange(5*4).reshape((5, 4)) z, w = jax.vmap(f, in_axes=(None, 0), out_axes=(0, None))(x, y) self.assertAllClose(z, x[jnp.newaxis] + y) self.assertAllClose(w, x) self.assertEqual( z.sharding._to_xla_hlo_sharding(z.ndim).tile_assignment_dimensions(), [1, 2]) self.assertEqual( w.sharding._to_xla_hlo_sharding(w.ndim).tile_assignment_dimensions(), [2]) @jtu.with_mesh([('x', 2)]) def testVMapShardingConstraint(self): f = pjit( lambda x: with_sharding_constraint(x, P('x')), in_shardings=P(), out_shardings=P('x'), ) x = jnp.arange(5*4).reshape((5, 4)) jaxpr = jax.make_jaxpr(jax.vmap(f))(x) pjit_eqn, = jaxpr.eqns constraint_eqn, = pjit_eqn.params['jaxpr'].eqns op = constraint_eqn.params['sharding']._to_xla_hlo_sharding(x.ndim) self.assertTrue(op.is_tiled()) self.assertListEqual(op.tile_assignment_dimensions(), [1, 2]) self.assertListEqual(op.tile_assignment_devices(), [0, 1]) self.assertFalse(op_shardings.is_op_sharding_replicated(op)) @jtu.with_mesh([('x', 2)]) def testVMapShardingConstraintWithSpmdAxis(self): f = pjit( jax.vmap( lambda x: with_sharding_constraint(x, P(None)), spmd_axis_name='x', ), in_shardings=P('x'), out_shardings=P('x'), ) x = jnp.arange(16 * 4).reshape((16, 4)) jaxpr = jax.make_jaxpr(f)(x) pjit_eqn, = jaxpr.eqns constraint_eqn, = pjit_eqn.params['jaxpr'].eqns op = constraint_eqn.params['sharding']._to_xla_hlo_sharding(x.ndim) self.assertTrue(op.is_tiled()) self.assertListEqual(op.tile_assignment_dimensions(), [2, 1]) self.assertListEqual(op.tile_assignment_devices(), [0, 1]) self.assertFalse(op_shardings.is_op_sharding_replicated(op)) @jtu.with_mesh([('x', 2)]) def testLowerWithDuckTyping(self): x = jax.ShapeDtypeStruct((2, 2), jnp.float32) # Make sure this doesn't crash pjit(lambda x: x + 4, in_shardings=P('x'), out_shardings=P('x')).lower(x) @jtu.with_mesh([('x', 2)]) def testLowerDonateArgnumsAvailable(self): x = jax.ShapeDtypeStruct((2, 2), jnp.float32) def f(*args): x, *_ = args return x f_low = pjit(f, donate_argnums=(0,), in_shardings=P('x'), out_shardings=P('x')).lower(x) f_com = f_low.compile() f_low.donate_argnums == f_com.donate_argnums == (0,) @jtu.with_mesh([('x', 2)]) def testLowerDonateArgnumsAvailableWithNames(self): x = jax.ShapeDtypeStruct((2, 2), jnp.float32) def f(inp1): return inp1 f_low = pjit(f, in_shardings=P('x'), out_shardings=P('x'), donate_argnames=('inp1',)).lower(x) f_com = f_low.compile() f_low.donate_argnums == f_com.donate_argnums == (0,) @unittest.skip('Fails in OSS builds on GPU with jax at HEAD and latest ' 'jaxlib on pypi.') def testInfeed(self): devices = np.array(jax.local_devices()) nr_devices = len(devices) shape = (nr_devices * 3, nr_devices * 5) def f_for_jit(x): token = lax.create_token(x) (y,), token = lax.infeed( token, shape=(core.ShapedArray(x.shape, np.float32),)) (z,), token = lax.infeed( token, shape=(core.ShapedArray(x.shape, np.float32),)) (w,), token = lax.infeed( token, shape=(core.ShapedArray(x.shape, np.float32),)) return x + y + z + w x = np.arange(math.prod(shape), dtype=np.float32).reshape(shape) y = x * 2. z = x * 3. w = x * 4. # Transfer data to infeed before executing the function. For GPUs, the # execution of the compiled function is blocking, so transferring data # to infeed before executing ensures that the execution does not deadlock # waiting for the infeed data. logging.info('Transferring to infeed for the jit call') d = devices[0] d.transfer_to_infeed((y,)) d.transfer_to_infeed((z,)) d.transfer_to_infeed((w,)) # JIT logging.info('Making jit call') res0 = jax.jit(f_for_jit)(x) self.assertAllClose(res0, x + y + z + w, check_dtypes=True) # PJIT def f_for_pjit(x): token = lax.create_token(x) # A replicated infeed (y,), token = lax.infeed( token, shape=(core.ShapedArray(x.shape, np.float32),), partitions=(None,)) # An infeed sharded on first axis (z,), token = lax.infeed( token, shape=(core.ShapedArray(x.shape, np.float32),), partitions=(P(nr_devices, 1),)) # An infeed sharded on second axis (w,), token = lax.infeed( token, shape=(core.ShapedArray(x.shape, np.float32),), partitions=(P(1, nr_devices),)) return x + y + z + w logging.info('Transferring to infeed for the pjit call') for didx, d in enumerate(devices): # Transfer the whole array to all devices for replicated. d.transfer_to_infeed((y,)) # For sharded infeed, transfer only the needed slices to each device. d.transfer_to_infeed(z[3 * didx:3 * didx + 3, :]) d.transfer_to_infeed((w[:, 5 * didx:5 * didx + 5],)) with jax.sharding.Mesh(devices, ['d']): logging.info('Making pjit call') res = pjit(f_for_pjit, in_shardings=(P('d'),), out_shardings=P('d'))(x) self.assertAllClose(res0, res, check_dtypes=True) def testOutfeed(self): if xla_bridge.using_pjrt_c_api(): raise unittest.SkipTest('outfeed not implemented in PJRT C API') devices = np.array(jax.local_devices()) nr_devices = len(devices) shape = (nr_devices * 3, nr_devices * 5) def f(x): token = lax.create_token(x) token = lax.outfeed(token, x, partitions=(None,)) token = lax.outfeed(token, x, partitions=(P(nr_devices, 1),)) token = lax.outfeed(token, x, partitions=(P(1, nr_devices),)) return x x = np.arange(math.prod(shape), dtype=np.float32).reshape(shape) def _dispatch(): with jax.sharding.Mesh(devices, ['d']): logging.info('Making pjit call') pjit(f, in_shardings=(P('d'),), out_shardings=P('d'))(x) execution = threading.Thread(target=_dispatch) execution.start() # Check the expected outfeed for all devices. def check_outfeed(x_fn): for didx, d in enumerate(devices): x = x_fn(didx) y, = d.transfer_from_outfeed( xc.shape_from_pyval((x,)).with_major_to_minor_layout_if_absent()) self.assertAllClose(x, y, check_dtypes=True) logging.info('Transferring from outfeed for the pjit call') # Note, when checking results of multiple outfeeds, the loop structure # should be such that we check a given outfeed for all devices before # moving on to the next outfeed. If there are any collectives generated # by pjit, a loop structutre like: # for each device: # check outfeed#0; # check outfeed#1; # # Could cause a deadlock if there is a collective scheduled between the # 2 outfeeds, as device #0, after processing outfeed#0 will execute the # collective, waiting for other devices to join, but other devices won't # execute their collective until their outfeed#0 is executed. This is # because, for GPU for example, execution of an outfeed on GPU is blocked # till the corresponding `transfer_from_outfeed` is executed on the host. # Transfer the whole array from all devices for replicated. check_outfeed(lambda didx: x) # For sharded outfeed, the results are sliced. check_outfeed(lambda didx: x[3 * didx:3 * didx + 3, :]) check_outfeed(lambda didx: x[:, 5 * didx:5 * didx + 5]) execution.join() @jtu.with_mesh([('x', 2)]) def testWithCustomPRNGKey(self): if not config.enable_custom_prng.value: raise unittest.SkipTest("test requires jax_enable_custom_prng") key = prng.random_seed(87, impl=prng.rbg_prng_impl) # Make sure this doesn't crash pjit(lambda x: x, in_shardings=None, out_shardings=None)(key) @jtu.with_mesh([('x', 2), ('y', 2)]) def testLowerCompile(self): @partial(pjit, in_shardings=P(('x', 'y'),), out_shardings=P(('x', 'y'),)) def f(x, y): return x @ y shape = (8, 8) x = jnp.arange(math.prod(shape)).reshape(shape) expected = x @ (x + 1) lowered = f.lower(x, x + 1) compiled = lowered.compile() actual = compiled(x, x + 1) self.assertEqual(lowered.in_avals, compiled.in_avals) self.assertEqual( lowered.in_avals, ((core.ShapedArray(x.shape, x.dtype, weak_type=False),) * 2, {})) splits = np.split(expected, 4) self.assertAllClose(np.asarray(actual.addressable_shards[0].data), splits[0], check_dtypes=False) self.assertAllClose(np.asarray(actual.addressable_shards[1].data), splits[1], check_dtypes=False) self.assertAllClose(np.asarray(actual.addressable_shards[2].data), splits[2], check_dtypes=False) self.assertAllClose(np.asarray(actual.addressable_shards[3].data), splits[3], check_dtypes=False) for obj in [lowered, compiled]: self.assertFalse(obj._no_kwargs) self.assertEqual(obj.in_tree, jax.tree.flatten(((0, 0), {}))[1]) @jtu.with_mesh([('x', 2), ('y', 2)]) def testLowerCompileWithKwargs(self): @pjit def f(x, y, **kwargs): return x @ y shape = (8, 8) x = jnp.arange(math.prod(shape)).reshape(shape) exe = f.lower(x, x + 1, a=1, b=2).compile() out = exe(x, x + 1, a=1, b=2) self.assertArraysEqual(out, x @ (x + 1)) @jtu.with_mesh([('x', 2), ('y', 2)]) def testLowerCompileInTreeMismatch(self): @partial(pjit, in_shardings=P(('x', 'y'),), out_shardings=P(('x', 'y'),)) def f(x, y): return x @ y shape = (8, 8) x = jnp.arange(math.prod(shape)).reshape(shape) exe = f.lower(x, x + 1).compile() self.assertRaisesRegex( TypeError, 'Function compiled with input pytree does not match the input pytree it' ' was called with', lambda: exe([x], [x + 1]), ) @jtu.with_mesh([('x', 2), ('y', 2)]) def testLowerCompileArgTypeMismatch(self): @partial(pjit, in_shardings=P(('x', 'y'),), out_shardings=P(('x', 'y'),)) def f(x, y): return x @ y shape = (8, 8) x = jnp.arange(math.prod(shape)).reshape(shape) x_f32 = x.astype(jnp.float32) x_i32 = x.astype(jnp.int32) exe = f.lower(x_f32, x_f32).compile() with self.assertRaisesRegex( TypeError, r"Argument types differ .*" r"The mismatches are:\n" r"Argument 'x' compiled with.*float32.*and called with.*int32.*\n" r"Argument 'y' compiled with.*float32.*and called with.*int32.*"): exe(x_i32, x_i32) @jtu.with_mesh([('x', 2), ('y', 2)]) def testLowerAsText(self): @partial(pjit, in_shardings=P(('x', 'y'),), out_shardings=P(('x', 'y'),)) def f(x, y): return x @ y shape = (8, 8) x = jnp.arange(math.prod(shape)).reshape(shape) f = f.lower(x, x + 1) self.assertIsInstance(f.as_text(), str) self.assertIsInstance(f.as_text(dialect='hlo'), str) self.assertIsInstance(f.as_text(dialect='stablehlo'), str) @jtu.with_mesh([('x', 2), ('y', 2)]) def testLowerCompilerIR(self): @partial(pjit, in_shardings=P(('x', 'y'),), out_shardings=P(('x', 'y'),)) def f(x, y): return x @ y shape = (8, 8) x = jnp.arange(math.prod(shape)).reshape(shape) f = f.lower(x, x + 1) self.assertIsNotNone(f.compiler_ir()) self.assertIsNotNone(f.compiler_ir(dialect='hlo')) self.assertIsNotNone(f.compiler_ir(dialect='stablehlo')) @jtu.with_mesh([('x', 2)]) def testLowerPartitionsAttribute(self): @partial(pjit, in_shardings=(P('x'), P('x')), out_shardings=None) def f(x, y): return x + y shape = (8, 8) x = np.arange(math.prod(shape), dtype=np.float32).reshape(shape) hlo = f.lower(x, x + 1).as_text("stablehlo") self.assertIn("mhlo.num_replicas = 1", hlo) self.assertIn("mhlo.num_partitions = 2", hlo) @jtu.with_mesh([('x', 2), ('y', 2)]) def testLowerCompileCompilerIR(self): @partial(pjit, in_shardings=P(('x', 'y'),), out_shardings=P(('x', 'y'),)) def f(x, y): return x @ y shape = (8, 8) x = jnp.arange(math.prod(shape)).reshape(shape) f = f.lower(x, x + 1).compile() self.assertIsNotNone(f.runtime_executable()) @jtu.with_mesh([('x', 2), ('y', 2)]) def testLowerCompileAsText(self): @partial(pjit, in_shardings=P(('x', 'y'),), out_shardings=P(('x', 'y'),)) def f(x, y): return x @ y shape = (8, 8) x = jnp.arange(math.prod(shape)).reshape(shape) f = f.lower(x, x + 1).compile() self.assertIsInstance(f.as_text(), (str, type(None))) @jtu.with_mesh([('x', 2), ('y', 2)]) def testLowerCostAnalysis(self): @partial(pjit, in_shardings=P(('x', 'y'),), out_shardings=P(('x', 'y'),)) def f(x, y): return x @ y shape = (8, 8) x = jnp.arange(math.prod(shape)).reshape(shape) f = f.lower(x, x + 1) f.cost_analysis() # doesn't raise @jtu.with_mesh([('x', 2), ('y', 2)]) def testLowerCompileCostAnalysis(self): @partial(pjit, in_shardings=P(('x', 'y'),), out_shardings=P(('x', 'y'),)) def f(x, y): return x @ y shape = (8, 8) x = jnp.arange(math.prod(shape)).reshape(shape) f = f.lower(x, x + 1).compile() f.cost_analysis() # doesn't raise @jtu.with_mesh([('x', 2), ('y', 2)]) def testLowerCompileMemoryAnalysis(self): @partial(pjit, in_shardings=P(('x', 'y'),), out_shardings=P(('x', 'y'),)) def f(x, y): return x @ y shape = (8, 8) x = jnp.arange(math.prod(shape)).reshape(shape) f = f.lower(x, x + 1).compile() f.memory_analysis() # doesn't raise @jtu.with_mesh([('x', 2), ('y', 2)]) def testLowerCompileExecutable(self): @partial(pjit, in_shardings=P(('x', 'y'),), out_shardings=P(('x', 'y'),)) def f(x, y): return x @ y shape = (8, 8) x = jnp.arange(math.prod(shape)).reshape(shape) f = f.lower(x, x + 1).compile() self.assertIsNotNone(f.runtime_executable()) @jtu.with_mesh([('x', 2)]) def test_static_argnums(self): @partial(pjit, in_shardings=None, out_shardings=None, static_argnums=(1,)) def f(x, y): return x + (3 if y == 'hi' else 4) self.assertEqual(f(1, 'hi' ), 4) self.assertEqual(f(1, 'bye'), 5) @jtu.with_mesh([('x', 4), ('y', 2)]) def testLowerCompileWithAvals(self): @partial(pjit, in_shardings=P(('x', 'y'),), out_shardings=P(('x', 'y'),)) def f(x, y): return x @ y shape = (8, 8) aval = core.ShapedArray(shape, dtypes.canonicalize_dtype(jnp.int64)) x = jnp.arange(math.prod(shape)).reshape(shape) exe = f.lower(aval, x).compile() self.assertIsInstance(exe, stages.Compiled) self.assertArraysEqual(exe(x, x), x @ x) def test_local_sharded_key_array_sda(self): input_shape = (8, 4) mesh = jtu.create_global_mesh((4, 2), ('x', 'y')) seeds = jnp.arange( math.prod(input_shape), dtype=np.uint32).reshape(input_shape) with mesh: def make_keys(seeds): make_key = partial(prng.random_seed, impl=prng.threefry_prng_impl) return make_key(seeds) f = pjit(make_keys, in_shardings=P(None), out_shardings=P(None)) out = f(seeds) self.assertTrue(jax.dtypes.issubdtype(out.dtype, jax.dtypes.prng_key)) self.assertEqual(out.shape, input_shape) jax.random.key_data(out) # doesn't crash def test_with_sharding_constraint_is_compatible_error(self): mesh = jtu.create_global_mesh((1, 1, 2), ('replica', 'data', 'mdl')) with mesh: def f(x): y = with_sharding_constraint(x, P(None, ('mdl',), None, None)) z = y + 2 return z pjit_f = pjit(f, in_shardings=P(None), out_shardings=P(None)) with self.assertRaisesRegex( ValueError, r"One of with_sharding_constraint.*Sharding " r"NamedSharding\(mesh=Mesh\('replica': 1, 'data': 1, 'mdl': 2\), " r"spec=PartitionSpec\(None, \('mdl',\), None, None\).*\) is only " "valid for values of rank at least 4, but was applied to a value of rank 1"): pjit_f(jnp.array([1, 2, 3])) def test_pretty_print(self): f = pjit(lambda x: x**2) g = pjit(lambda x: f(x) + f(x)) x = jnp.array([4.2], dtype=jnp.float32) jaxpr = jax.make_jaxpr(g)(x) self.assertEqual( jaxpr.pretty_print(), textwrap.dedent(""" let lambda = { lambda ; a:f32[1]. let b:f32[1] = integer_pow[y=2] a in (b,) } in { lambda ; c:f32[1]. let d:f32[1] = pjit[ name= jaxpr={ lambda ; e:f32[1]. let f:f32[1] = pjit[name= jaxpr=lambda] e g:f32[1] = pjit[name= jaxpr=lambda] e h:f32[1] = add f g in (h,) } ] c in (d,) } """).strip(), ) def test_pretty_print_with_closure(self): @pjit def g(x, y): @pjit def f(x): return x * y return f(x) + f(y) x = jnp.array([4.2], dtype=jnp.float32) jaxpr = jax.make_jaxpr(g)(x, x) self.assertEqual( jaxpr.pretty_print(), textwrap.dedent(""" let f = { lambda ; a:f32[1] b:f32[1]. let c:f32[1] = mul b a in (c,) } in { lambda ; d:f32[1] e:f32[1]. let g:f32[1] = pjit[ name=g jaxpr={ lambda ; h:f32[1] i:f32[1]. let j:f32[1] = pjit[name=f jaxpr=f] i h k:f32[1] = pjit[name=f jaxpr=f] i i l:f32[1] = add j k in (l,) } ] d e in (g,) } """).strip(), ) def test_pretty_print_with_name_clash(self): @pjit def g(x, y): @pjit def f(x): return x return f(x)*f(x) + f(y)*f(y) x = jnp.array([4.2], dtype=jnp.float32) y = jnp.array([4.2, 2.4], dtype=jnp.float32) jaxpr = jax.make_jaxpr(g)(x, y) self.assertEqual( jaxpr.pretty_print(use_color=False), textwrap.dedent(""" let f = { lambda ; a:f32[1]. let in () } in let f1 = { lambda ; b:f32[2]. let in () } in { lambda ; c:f32[1] d:f32[2]. let e:f32[2] = pjit[ name=g jaxpr={ lambda ; g:f32[1] h:f32[2]. let pjit[name=f jaxpr=f] g pjit[name=f jaxpr=f] g i:f32[1] = mul g g pjit[name=f jaxpr=f1] h pjit[name=f jaxpr=f1] h j:f32[2] = mul h h k:f32[2] = add i j in (k,) } ] c d in (e,) } """).strip(), ) def test_with_sharding_constraint_vmap_spmd_axis_name_error(self): mesh = jtu.create_global_mesh((2, 2), ('x', 'y')) def f(x): return jax.lax.with_sharding_constraint(x, NamedSharding(mesh, P('x'))) xs = jnp.arange(4 * 16.).reshape(4, 16) with self.assertRaisesRegex(ValueError, "spmd_axis_name"): jax.vmap(f, spmd_axis_name='x')(xs) @jtu.pytest_mark_if_available('multiaccelerator') class CustomPartitionerTest(jtu.JaxTestCase): def skip_if_custom_partitioning_not_supported(self): if jtu.is_cloud_tpu(): raise unittest.SkipTest("Custom partitioning is not supported on libtpu.") @jtu.skip_on_devices('cpu') # Collectives don't seem to work on CPU. @jtu.with_mesh([('x', 4), ('y', 2)]) def test_custom_partitioner(self): self.skip_if_custom_partitioning_not_supported() def partition(precision, mesh, arg_shapes, result_shape): arg_shardings = jax.tree.map(lambda s: s.sharding, arg_shapes) result_sharding = result_shape[0].sharding self.assertEqual(arg_shardings[0], result_sharding) self.assertEqual(P('x', None), result_sharding.spec) self.assertEqual(P('y', None), arg_shardings[1].spec) def lower_fn(x, y): axis_name = arg_shardings[1].spec[0][0] i = jax.lax.axis_index(axis_name) z = jax.lax.psum( jax.lax.dynamic_slice(x, (0, i * 8), (8, 8)) @ y, (axis_name) ) return z, z * z return mesh, lower_fn, (result_sharding, result_sharding), arg_shardings def infer_sharding_from_operands(precision, mesh, arg_shapes, result_shape): arg_shardings = jax.tree.map(lambda s: s.sharding, arg_shapes) x_shard, y_shard = arg_shardings x_shape, y_shape = arg_shapes x_names = tuple(x_shard.spec) + tuple( None for _ in range(len(x_shape.shape) - len(x_shard.spec))) y_names = tuple(y_shard.spec) + tuple( None for _ in range(len(y_shape.shape) - len(y_shard.spec))) z_shard = NamedSharding(y_shard.mesh, P(*(x_names[:-1] + y_names[1:]))) return z_shard, z_shard @partial(custom_partitioning, static_argnums=(2,)) def f(x, y, precision=None): z = jnp.matmul(x, y, precision=precision) return z, z * z f.def_partition( infer_sharding_from_operands=infer_sharding_from_operands, partition=partition) pjit_f = pjit(f, in_shardings=(P('x'), P('y')), out_shardings=P('x')) x = np.asarray(np.random.randint(0, 20, (32, 16)), dtype=np.float32) y = np.asarray(np.random.randint(0, 20, (16, 32)), dtype=np.float32) result1 = jax.jit(f)(x, y) result2 = f(x, y) result0 = pjit_f(x, y) self.assertArraysEqual(result0, result1) self.assertArraysEqual(result1, result2) @jtu.with_mesh([('x', 4), ('y', 2)]) def test_custom_partitioner_propagate_user_sharding(self): self.skip_if_custom_partitioning_not_supported() def partition(mesh, arg_shapes, result_shape): def lower_fn(x): return x return ( mesh, lower_fn, arg_shapes[0].sharding, (arg_shapes[0].sharding,), ) def infer_sharding_from_operands(mesh, arg_shapes, result_shape): return arg_shapes[0].sharding def propagate_user_sharding(mesh, user_shape): return user_shape.sharding @custom_partitioning def f(x): return x f.def_partition( infer_sharding_from_operands=infer_sharding_from_operands, partition=partition, propagate_user_sharding=propagate_user_sharding, ) def f2(a): return a + f(a) pjit_f = pjit(f2, in_shardings=(P(None, 'x')), out_shardings=P('x')) x = np.asarray(np.random.randint(0, 20, (32, 16)), dtype=np.float32) self.assertArraysEqual(x + x, pjit_f(x)) @jtu.with_mesh([('x', 4), ('y', 2)]) def test_custom_partitioner_sharding_override(self): self.skip_if_custom_partitioning_not_supported() def partition(mesh, arg_shapes, result_shape): def lower_fn(x): return x y_shard = arg_shapes[0].sharding return ( mesh, lower_fn, NamedSharding(y_shard.mesh, P(None)), (NamedSharding(y_shard.mesh, P(None)),), ) def infer_sharding_from_operands(mesh, arg_shapes, result_shape): y_shard = arg_shapes[0].sharding return NamedSharding(y_shard.mesh, P('x')) @custom_partitioning def f(x): return x f.def_partition( infer_sharding_from_operands=infer_sharding_from_operands, partition=partition, ) pjit_f = pjit(f, in_shardings=(P(None, 'x')), out_shardings=P('x')) x = np.asarray(np.random.randint(0, 20, (32, 16)), dtype=np.float32) self.assertArraysEqual(x, pjit_f(x)) @jtu.with_mesh([('x', 4), ('y', 2)]) def test_custom_partitioner_invalid_sharding(self): self.skip_if_custom_partitioning_not_supported() def partition(mesh, arg_shapes, result_shape): def lower_fn(x): return x y_shard = arg_shapes[0].sharding return ( mesh, lower_fn, NamedSharding(y_shard.mesh, P(None)), (NamedSharding(y_shard.mesh, P(None, 'x')),), ) def infer_sharding_from_operands(mesh, arg_shapes, result_shape): y_shard = arg_shapes[0].sharding return NamedSharding(y_shard.mesh, P('x')) @custom_partitioning def f(x): return x f.def_partition( infer_sharding_from_operands=infer_sharding_from_operands, partition=partition, ) pjit_f = pjit(f, in_shardings=(P(None, 'x')), out_shardings=P('x')) x = np.asarray(np.random.randint(0, 20, (32, 16)), dtype=np.float32) with self.assertRaisesRegex(Exception, 'Mismatch in result shapes.'): pjit_f(x).block_until_ready() @jtu.with_mesh([('x', 4)]) def test_custom_partitioner_jit_annotated_function(self): """Test correct lowering of function with a @jax.jit annotated callee. Annotating a callee with @jax.jit results in a module with a HLO CallOp. This test is makes sure that the custom partitioner lowering supports CallOps. """ self.skip_if_custom_partitioning_not_supported() @custom_partitioning def f(x): return x def partition(mesh, arg_shapes, result_shape): def lower_fn(x): @jax.jit def g(y): return y return g(x) x_shard = arg_shapes[0].sharding return ( mesh, lower_fn, NamedSharding(x_shard.mesh, P('x')), (NamedSharding(x_shard.mesh, P('x')),), ) def infer_sharding_from_operands(mesh, arg_shapes, result_shape): x_shard = arg_shapes[0].sharding return NamedSharding(x_shard.mesh, P('x')) f.def_partition( infer_sharding_from_operands=infer_sharding_from_operands, partition=partition, ) jit_f = jax.jit(f) x = np.asarray(np.random.randint(0, 20, (32,)), dtype=np.float32) pjit_f = pjit(jit_f, in_shardings=(P('x')), out_shardings=P('x')) self.assertArraysEqual(x, pjit_f(x)) def test_custom_partitioning_no_mesh_context(self): self.skip_if_custom_partitioning_not_supported() @custom_partitioning def f(x): return x def partition(mesh, arg_shapes, result_shape): def lower_fn(x): @jax.jit def g(y): return y return g(x) x_shard = arg_shapes[0].sharding return ( mesh, lower_fn, NamedSharding(x_shard.mesh, P('x')), (NamedSharding(x_shard.mesh, P('x')),), ) def infer_sharding_from_operands(mesh, arg_shapes, result_shape): x_shard = arg_shapes[0].sharding return NamedSharding(x_shard.mesh, P('x')) f.def_partition( infer_sharding_from_operands=infer_sharding_from_operands, partition=partition, ) mesh = jtu.create_global_mesh((4,), ('x',)) x = np.asarray(np.random.randint(0, 20, (32,)), dtype=np.float32) s = NamedSharding(mesh, P('x')) pjit_f = jax.jit(f, in_shardings=s, out_shardings=s) self.assertArraysEqual(x, pjit_f(x)) @jtu.with_mesh([('x', 4)]) def test_custom_partitioner_with_scan(self): self.skip_if_custom_partitioning_not_supported() # This is a reproducer from https://github.com/google/jax/issues/20864. @custom_partitioning def f(x): return jnp.sum(x) def partition(mesh, arg_shapes, result_shape): def lower_fn(xs): def f(carry, x): return carry + jax.lax.psum(jnp.sum(x), axis_name='x'), None carry, _ = jax.lax.scan(f, 0, xs) return carry result_shardings = jax.tree.map(lambda x: x.sharding, result_shape) arg_shardings = jax.tree.map(lambda x: x.sharding, arg_shapes) return mesh, lower_fn, result_shardings, arg_shardings f.def_partition( partition, infer_sharding_from_operands=lambda mesh, *_: NamedSharding(mesh, P()), propagate_user_sharding=lambda _, user_shape: user_shape.sharding) pjit_f = pjit(f, in_shardings=P(None, 'x')) xs = jnp.ones([32, 16]) self.assertEqual(pjit_f(xs), xs.sum()) @jtu.pytest_mark_if_available('multiaccelerator') class AutoShardingPjitTest(jtu.JaxTestCase): @parameterized.named_parameters( ('2d_array', (4, 2), (4, 2), ('x', 'y')), # TODO(b/226977360): Support 3D mesh shape for example (2, 2, 2). ('3d_array', (1, 4, 2), (2, 4, 8, 4), ('x', 'y', 'z')), ('1d_array', (8,), (8, 2), ('x')), ) def test_pjit_arr_auto_sharding_array(self, mesh_shape, global_input_shape, mesh_axis_names): global_mesh = jtu.create_global_mesh(mesh_shape, mesh_axis_names) input_data = np.arange( math.prod(global_input_shape), dtype=np.float32).reshape(global_input_shape) f = jax.jit(lambda x: x, in_shardings=AUTO(global_mesh), out_shardings=AUTO(global_mesh)) inp = core.ShapedArray(input_data.shape, input_data.dtype) compiled = f.lower(inp).compile() inputs = [create_array(global_input_shape, global_mesh, ip, input_data)[0] for ip in compiled.input_shardings[0]] out = compiled(*inputs) self.assertIsInstance(out, array.ArrayImpl) self.assertArraysEqual(out._value, input_data) def test_xla_arr_sharding_mismatch(self): global_mesh = jtu.create_global_mesh((2, 2), ('x', 'y')) global_input_shape = (6, 2) input_data = np.arange( math.prod(global_input_shape), dtype=np.float32).reshape(global_input_shape) with global_mesh: f = pjit(lambda x: x, in_shardings=AUTO(global_mesh), out_shardings=AUTO(global_mesh)) inp = core.ShapedArray(input_data.shape, input_data.dtype) compiled = f.lower(inp).compile() different_pspec = ( P('y', 'x') if compiled.input_shardings[0][0].is_equivalent_to( NamedSharding(global_mesh, P('x', 'y')), len(global_input_shape) ) else P('x', 'y') ) arr, _ = create_array(global_input_shape, global_mesh, different_pspec, input_data) with self.assertRaisesRegex( ValueError, r"Compiled object called with input sharding\(s\) does not match the " r"sharding\(s\) the computation was compiled with.*\n.*for arg x"): compiled(arr) def test_gda_auto_shardings_len(self): global_mesh = jtu.create_global_mesh((2, 2), ('x', 'y')) global_input_shape = (4, 2) input_data = np.arange( math.prod(global_input_shape), dtype=np.float32).reshape(global_input_shape) with global_mesh: f = pjit(lambda x, y, z: (x, y, z), in_shardings=AUTO(global_mesh), out_shardings=AUTO(global_mesh)) inp = core.ShapedArray(input_data.shape, input_data.dtype) compiled = f.lower(inp, inp, inp).compile() self.assertLen(compiled.output_shardings, 3) self.assertLen(compiled.input_shardings[0], 3) @parameterized.named_parameters( ('3d_array', (1, 1, 2), ('x', 'y', 'z'), P(('x', 'y', 'z'))), ('2d_array', (4, 2), ('x', 'y'), P('y', 'x')), ('1d_array', (8,), ('x'), P('x')), ) def test_jit_arr_partial_auto_sharding_array( self, mesh_shape, mesh_axis_names, pspec): mesh = jtu.create_global_mesh(mesh_shape, mesh_axis_names) global_input_shape = (8, 4) input_data = np.arange( math.prod(global_input_shape), dtype=np.float32).reshape(global_input_shape) inp_s = NamedSharding(mesh, pspec) f = jax.jit( lambda x, y: (x, y), in_shardings=(inp_s, AUTO(mesh)), out_shardings=AUTO(mesh)) inp = core.ShapedArray(input_data.shape, input_data.dtype) compiled = f.lower(inp, inp).compile() inputs = [create_array(global_input_shape, mesh, ip, input_data)[0] for ip in compiled.input_shardings[0]] self.assertEqual(compiled.input_shardings[0][0], inp_s) out1, out2 = compiled(*inputs) for o in [out1, out2]: self.assertIsInstance(o, array.ArrayImpl) self.assertArraysEqual(o._value, input_data) def test_jit_different_mesh_in_auto(self): mesh1 = jtu.create_global_mesh((4,), ('x',)) dev = jax.devices() mesh2 = jax.sharding.Mesh([dev[0], dev[3], dev[2], dev[1]], 'x') f = jax.jit(lambda x, y: (x, y), in_shardings=(NamedSharding(mesh2, P('x')), AUTO(mesh1))) inp = core.ShapedArray((8, 2), np.float32) with self.assertRaisesRegex( ValueError, "Received incompatible devices for jitted computation"): f.lower(inp, inp).compile() @parameterized.named_parameters( ('2d_array', (4, 2), ('x', 'y')), ('1d_array', (8,), ('x')), ) def test_jit_auto_sharding_partial_tuple_input_shardings( self, mesh_shape, mesh_axis_names): if not jtu.test_device_matches(["tpu"]): self.skipTest('Parameters are tupled only on TPU if >2000 parameters') mesh = jtu.create_global_mesh(mesh_shape, mesh_axis_names) global_input_shape = (8, 4) input_data = np.arange( math.prod(global_input_shape), dtype=np.float32).reshape(global_input_shape) input_sharding = NamedSharding(mesh, P(mesh_axis_names)) # sharded input_sharding_annotations = [AUTO(mesh)] * 2001 output_sharding = NamedSharding(mesh, P()) # replicated output_sharding_annotations = [AUTO(mesh)] * 2001 for i in range(1000): input_sharding_annotations[2*i] = input_sharding output_sharding_annotations[2*i] = output_sharding jit_tuple_identity_fn = jax.jit( lambda *x: x, in_shardings=input_sharding_annotations, out_shardings=tuple(output_sharding_annotations)) inp = core.ShapedArray(input_data.shape, input_data.dtype) compiled = jit_tuple_identity_fn.lower(*([inp] * 2001)).compile() # Check sharding preservation for even numbered inputs. for i in range(1000): self.assertEqual(compiled.input_shardings[0][2*i], input_sharding) self.assertEqual(compiled.output_shardings[2*i], output_sharding) @unittest.skip('The error is not raised yet. Enable this back once we raise ' 'the error in pjit again.') def test_pjit_array_error(self): global_mesh = jtu.create_global_mesh((4, 2), ('x', 'y')) global_input_shape = (8, 2) input_data = np.arange( math.prod(global_input_shape), dtype=np.float32).reshape(global_input_shape) with global_mesh: f = pjit(lambda x: x, in_shardings=AUTO(global_mesh), out_shardings=AUTO(global_mesh)) inp = core.ShapedArray(input_data.shape, input_data.dtype) compiled = f.lower(inp).compile() inputs = [create_array(global_input_shape, global_mesh, ip, input_data)[0] for ip in compiled.input_shardings[0]] with self.assertRaisesRegex( ValueError, ('Passing sharding on pjit and on args while using the ' 'auto spmd partitioner is not allowed. Please call the ' 'compiled object on the inputs.')): f(*inputs) @jtu.pytest_mark_if_available('multiaccelerator') class ArrayPjitTest(jtu.JaxTestCase): @parameterized.named_parameters( ('fully_sharded_output', P('x', 'y'), (2, 4)), ('fully_replicated_output', P(None), (8, 8)), ) def test_pjit_array_single_output(self, out_axis_resources, shard_shape): global_input_shape = (8, 2) global_mesh = jtu.create_global_mesh((4, 2), ('x', 'y')) mesh_axes = P('x', 'y') input_array, input_data = create_array(global_input_shape, global_mesh, mesh_axes) f = pjit(lambda x: x @ x.T, out_shardings=NamedSharding( global_mesh, out_axis_resources)) expected_matrix_mul = input_data @ input_data.T out = f(input_array) self.assertIsInstance(out, array.ArrayImpl) self.assertTrue(out._committed) self.assertEqual(out.shape, (8, 8)) self.assertEqual(out.addressable_shards[0].data.shape, shard_shape) for s in out.addressable_shards: self.assertLen(s.data.devices(), 1) self.assertArraysEqual(s.data, expected_matrix_mul[s.index]) self.assertArraysEqual(out._value, expected_matrix_mul) @parameterized.named_parameters( ('fully_sharded_output', P('x', 'y'), (2, 4)), ('fully_replicated_output', P(None), (8, 8)), ) def test_pjit_array_single_output_with_mesh_context_manager( self, out_axis_resources, shard_shape): global_input_shape = (8, 2) global_mesh = jtu.create_global_mesh((4, 2), ('x', 'y')) mesh_axes = P('x', 'y') input_array, input_data = create_array(global_input_shape, global_mesh, mesh_axes) with global_mesh: f = pjit(lambda x: x @ x.T, out_shardings=NamedSharding( global_mesh, out_axis_resources)) expected_matrix_mul = input_data @ input_data.T out = f(input_array) self.assertIsInstance(out, array.ArrayImpl) self.assertEqual(out.shape, (8, 8)) self.assertEqual(out.addressable_shards[0].data.shape, shard_shape) for s in out.addressable_shards: self.assertLen(s.data.devices(), 1) self.assertArraysEqual(s.data, expected_matrix_mul[s.index]) self.assertArraysEqual(out._value, expected_matrix_mul) def test_numpy_array_input_assume_fully_replicated(self): input_shape = (8, 2) global_mesh = jtu.create_global_mesh((4, 2), ('x', 'y')) input_data = np.arange( math.prod(input_shape)).reshape(input_shape) f = pjit(lambda x: x, out_shardings=NamedSharding(global_mesh, P('x', 'y'))) out = f(input_data) self.assertIsInstance(out, array.ArrayImpl) self.assertArraysEqual(out, input_data) for s in out.addressable_shards: self.assertEqual(s.data.shape, (2, 1)) self.assertArraysEqual(s.data, input_data[s.index]) def test_numpy_array_input(self): input_shape = (8, 2) global_mesh = jtu.create_global_mesh((4, 2), ('x', 'y')) input_data = np.arange( math.prod(input_shape), dtype=np.float32).reshape(input_shape) with global_mesh: f = pjit( lambda x: x, in_shardings=NamedSharding(global_mesh, P(None)), out_shardings=NamedSharding(global_mesh, P('x', 'y')), ) out = f(input_data) self.assertIsInstance(out, array.ArrayImpl) for s in out.addressable_shards: self.assertEqual(s.data.shape, (2, 1)) self.assertArraysEqual(s.data, input_data[s.index]) self.assertArraysEqual(out._value, input_data) def test_unspecified_out_axis_resources(self): def _checks(out, input_data): self.assertIsInstance(out, array.ArrayImpl) self.assertIsInstance(out.sharding, NamedSharding) self.assertEqual(out.shape, (8, 2)) self.assertEqual(out.addressable_shards[0].data.shape, (2, 1)) for s in out.addressable_shards: self.assertLen(s.data.devices(), 1) self.assertArraysEqual(s.data, input_data[s.index]) self.assertArraysEqual(out._value, input_data) global_input_shape = (8, 2) global_mesh = jtu.create_global_mesh((4, 2), ('x', 'y')) mesh_axes = P('x', 'y') input_array, input_data = create_array(global_input_shape, global_mesh, mesh_axes) f = pjit(lambda x: x * 2) out = f(input_array) _checks(out, input_data * 2) out2 = f(out) _checks(out2, input_data * 4) @parameterized.named_parameters( ('mesh1', (4, 2), (2, 8), (2, 2), (1, 2), (8, 2)), ('mesh2', (2, 2), (4, 8), (4, 2), (2, 2), (8, 2)), ('mesh3', (2, 1), (4, 8), (4, 2), (4, 2), (8, 2)), ) def test_pjit_array_multi_input_multi_output(self, mesh_shape, s1_shape, s2_shape, s3_shape, s4_shape): global_mesh = jtu.create_global_mesh(mesh_shape, ('x', 'y')) global_input_shape = (8, 2) spec1 = P('x', 'y') a1, input_data = create_array(global_input_shape, global_mesh, spec1) spec2 = P('x') a2, _ = create_array(global_input_shape, global_mesh, spec2) spec3 = P(('x', 'y')) a3, _ = create_array(global_input_shape, global_mesh, spec3) spec4 = P(None) a4, _ = create_array(global_input_shape, global_mesh, spec4) @pjit def f(tree): return tree out_tree = f((a1 @ a1.T, (a2, (a3 * 2, a4)))) (out1, out2, out3, out4), _ = jax.tree.flatten(out_tree) self.assertIsInstance(out1, array.ArrayImpl) self.assertEqual(out1.shape, (8, 8)) self.assertEqual(out1.addressable_shards[0].data.shape, s1_shape) for s in out1.addressable_shards: self.assertArraysEqual( s.data, (input_data @ input_data.T)[s.index]) self.assertIsInstance(out2, array.ArrayImpl) self.assertEqual(out2.shape, (8, 2)) self.assertEqual(out2.addressable_shards[0].data.shape, s2_shape) for s in out2.addressable_shards: self.assertArraysEqual(s.data, input_data[s.index]) self.assertIsInstance(out3, array.ArrayImpl) self.assertEqual(out3.shape, (8, 2)) self.assertEqual(out3.addressable_shards[0].data.shape, s3_shape) for s in out3.addressable_shards: self.assertArraysEqual(s.data, (input_data * 2)[s.index]) self.assertIsInstance(out4, array.ArrayImpl) self.assertEqual(out4.shape, (8, 2)) self.assertEqual(out4.addressable_shards[0].data.shape, s4_shape) for s in out4.addressable_shards: self.assertArraysEqual(s.data, input_data) def test_sds_full_like(self): # https://github.com/google/jax/issues/20390 mesh = jtu.create_global_mesh((2, 1), ('x', 'y')) s = NamedSharding(mesh, P('x', 'y')) x = jax.ShapeDtypeStruct((4, 4), jnp.float32, sharding=s) y = jnp.zeros_like(x) z = jnp.zeros_like(x, device=y.sharding) self.assertEqual(x.sharding, s) self.assertEqual(y.sharding, s) self.assertEqual(z.sharding, s) def test_in_axis_resources_mismatch_error(self): global_input_shape = (8, 2) global_mesh = jtu.create_global_mesh((4, 2), ('x', 'y')) mesh_axes = P('x', 'y') input_array, _ = create_array(global_input_shape, global_mesh, mesh_axes) with global_mesh: f = pjit(lambda x: x, in_shardings=NamedSharding(global_mesh, P('x'))) err_msg = re.compile( "Sharding passed to pjit does not match the sharding on the " r"respective arg.*arg shape.*\[8,2\]", re.M | re.S) with self.assertRaisesRegex(ValueError, err_msg): f(input_array) def test_in_axis_resources_same_as_array_sharding(self): global_input_shape = (8, 2) global_mesh = jtu.create_global_mesh((4, 2), ('x', 'y')) mesh_axes = P('x', 'y') input_array, _ = create_array(global_input_shape, global_mesh, mesh_axes) with global_mesh: out = pjit( lambda x: x, in_shardings=NamedSharding(global_mesh, P('x' ,'y')))(input_array) self.assertIsInstance(out, array.ArrayImpl) def test_no_input_output(self): def f(): pass pjit(f) def test_array_device_assignment_mismatch_with_mesh(self): global_input_shape = (8, 2) global_mesh = jtu.create_global_mesh((4, 2), ('x', 'y')) mesh_axes = P('x', 'y') input_array, _ = create_array( global_input_shape, jtu.create_global_mesh((2, 2), ('x', 'y')), mesh_axes) with global_mesh: with self.assertRaisesRegex( ValueError, "Received incompatible devices for pjitted computation"): pjit(lambda x: x)(input_array) def test_array_lower_compile(self): global_input_shape = (8, 2) global_mesh = jtu.create_global_mesh((4, 2), ('x', 'y')) a1, input_data = create_array(global_input_shape, global_mesh, P('x', 'y')) a2, _ = create_array(global_input_shape, global_mesh, P('x')) aval = core.ShapedArray(global_input_shape, np.float32) with global_mesh: f = pjit( lambda x, y, z, a, b, c: (x @ y.T, y, z, a, b, c), in_shardings=NamedSharding(global_mesh, P('x' ,'y'))) compiled = f.lower(aval, aval, aval, aval, aval, aval).compile() out, *_ = compiled(a1, a1, a1, a1, a1, a1) self.assertIsInstance(out, array.ArrayImpl) self.assertArraysEqual(out._value, input_data @ input_data.T) with self.assertRaisesRegex( ValueError, r"Compiled object called with input sharding.*does not match the " r"sharding.*the computation was compiled with. " "Here are.*mismatches.*"): compiled(a2, a2, a2, a2, a2, a2) with global_mesh: f = pjit(lambda a: a, in_shardings=NamedSharding(global_mesh, P('x' ,'y'))) abstract_inp = {'x': aval, 'y': {'y1': aval}} inp1 = {'x': a1, 'y': {'y1': a1}} compiled = f.lower(abstract_inp).compile() compiled(inp1) inp2 = {'x': a2, 'y': {'y1': a2}} with self.assertRaisesRegex( ValueError, r"Compiled object called with input sharding.*does not match the " r"sharding.*the computation was compiled with. " "Here are the.*mismatches"): compiled(inp2) def test_globally_sharded_key_array_result_8x4_single_device(self): input_shape = (8, 4) seeds = jnp.arange( math.prod(input_shape), dtype=np.uint32).reshape(input_shape) @pjit def make_keys(seeds): make_key = partial(prng.random_seed, impl=prng.threefry_prng_impl) return make_key(seeds) out = make_keys(seeds) self.assertTrue(jax.dtypes.issubdtype(out.dtype, jax.dtypes.prng_key)) self.assertEqual(out.shape, input_shape) jax.random.key_data(out) # doesn't crash def test_globally_sharded_key_array_8x4_multi_device_with_out_sharding(self): input_shape = (8, 4) mesh = jtu.create_global_mesh((4, 2), ('x', 'y')) spec = P('x', 'y') seeds, _ = create_array(input_shape, mesh, spec, dtype=np.uint32) @partial(pjit, out_shardings=NamedSharding(mesh, P('x', 'y'))) def make_keys(seeds): make_key = partial(prng.random_seed, impl=prng.threefry_prng_impl) return make_key(seeds) out = make_keys(seeds) self.assertTrue(jax.dtypes.issubdtype(out.dtype, jax.dtypes.prng_key)) self.assertEqual(out.shape, input_shape) jax.random.key_data(out) # doesn't crash def test_globally_sharded_key_array_8x4_multi_device(self): input_shape = (8, 4) mesh = jtu.create_global_mesh((4, 2), ('x', 'y')) spec = P('x', 'y') seeds, _ = create_array(input_shape, mesh, spec, dtype=np.uint32) @pjit def make_keys(seeds): make_key = partial(prng.random_seed, impl=prng.threefry_prng_impl) return make_key(seeds) out = make_keys(seeds) self.assertTrue(jax.dtypes.issubdtype(out.dtype, jax.dtypes.prng_key)) self.assertEqual(out.shape, input_shape) jax.random.key_data(out) # doesn't crash def test_array_device_assignment_mismatch_out_shardings(self): input_shape = (8, 2) m1 = jtu.create_global_mesh((4, 2), ('x', 'y')) m2 = jtu.create_global_mesh((2, 2), ('x', 'y')) spec = P('x', 'y') a1 = jnp.arange(math.prod(input_shape)).reshape(input_shape) with m1: with self.assertRaisesRegex( ValueError, "Received incompatible devices for pjitted computation"): pjit(lambda x, y: (x, y), out_shardings=(NamedSharding(m1, spec), NamedSharding(m2, spec)))(a1, a1) def test_array_device_assignment_mismatch_in_and_out_shardings(self): input_shape = (8, 2) m1 = jtu.create_global_mesh((4, 2), ('x', 'y')) m2 = jtu.create_global_mesh((2, 2), ('x', 'y')) spec = P('x', 'y') a1 = jnp.arange(math.prod(input_shape)).reshape(input_shape) with m1: with self.assertRaisesRegex( ValueError, "Received incompatible devices for pjitted computation"): pjit( lambda x, y: (x, y), in_shardings=NamedSharding(m2, spec), out_shardings=NamedSharding(m1, spec), )(a1, a1) def test_mixed_inputs(self): input_shape = (8, 2) global_mesh = jtu.create_global_mesh((4, 2), ('x', 'y')) spec = P('x', 'y') a1, input_data = create_array(input_shape, global_mesh, spec) with global_mesh: f = pjit(lambda x, y: (x, y), in_shardings=NamedSharding(global_mesh, P(None))) with self.assertRaisesRegex( ValueError, ('Sharding passed to pjit does not match the sharding on the ' 'respective arg')): f(input_data, a1) def test_pjit_array_same_sharding_aot(self): global_mesh = jtu.create_global_mesh((4, 2), ('x', 'y')) input_shape = (8, 2) a1, _ = create_array(input_shape, global_mesh, P(None,)) with global_mesh: f = pjit(lambda x: x, in_shardings=NamedSharding(global_mesh, P(None,))) compiled = f.lower(core.ShapedArray(input_shape, jnp.float32)).compile() compiled(a1) # no error def test_pjit_single_device_sharding_add(self): a = np.array([1, 2, 3], dtype=jnp.float32) b = np.array([4, 5, 6], dtype=jnp.float32) @pjit def add(x, y): return x + y out = add(a, b) cache_info1 = pjit_lib._pjit_lower_cached.cache_info() self.assertIsInstance(out, array.ArrayImpl) self.assertArraysEqual(out, a + b) self.assertFalse(out._committed) out2 = add(out, out) cache_info2 = pjit_lib._pjit_lower_cached.cache_info() self.assertIsInstance(out2, array.ArrayImpl) self.assertArraysEqual(out2, 2 * (a + b)) self.assertFalse(out2._committed) self.assertEqual(cache_info2.hits, cache_info1.hits + 1) self.assertEqual(cache_info2.misses, cache_info1.misses) c = jax.device_put(a, jax.devices()[0]) out3 = add(c, c) cache_info3 = pjit_lib._pjit_lower_cached.cache_info() self.assertArraysEqual(out3, 2 * c) self.assertTrue(out3._committed) self.assertEqual(cache_info3.hits, cache_info2.hits) self.assertEqual(cache_info3.misses, cache_info2.misses + 1) out4 = add(out3, out3) self.assertArraysEqual(out4, 4 * c) self.assertTrue(out4._committed) def test_pjit_single_device_sharding_mul(self): a = jnp.arange(16).reshape((8, 2)) @pjit def mul(x): return x @ x.T out = mul(a) self.assertIsInstance(out, array.ArrayImpl) self.assertArraysEqual(out, a @ a.T) def test_pjit_single_device_sharding_cache(self): a = jnp.arange(16).reshape((8, 2)) f = pjit(lambda x: x) with jtu.count_pjit_cpp_cache_miss() as count: out = f(a) _ = f(out) self.assertEqual(count[0], 1) def test_pjit_different_device_recompilation(self): if jax.device_count() < 2: raise unittest.SkipTest('Requires 2 or more devices.') val1 = jnp.array([1, 2, 3], dtype=jnp.float32) a = jax.device_put(val1, jax.devices()[0]) val2 = jnp.array([4, 5, 6], dtype=jnp.float32) b = jax.device_put(val2, jax.devices()[1]) f = pjit(lambda x: x) out1 = f(a) cache_info1 = pjit_lib._pjit_lower_cached.cache_info() out2 = f(b) cache_info2 = pjit_lib._pjit_lower_cached.cache_info() self.assertEqual(cache_info2.hits, cache_info1.hits) self.assertEqual(cache_info2.misses, cache_info1.misses + 1) self.assertArraysEqual(out1, val1) self.assertArraysEqual(out2, val2) def test_grad_of_pjit_single_device_sharding(self): a = jnp.array(16, dtype=jnp.float32) f = lambda x: x * 3 out = jax.grad(pjit(f))(a) self.assertIsInstance(out, array.ArrayImpl) self.assertArraysEqual(out, jax.grad(f)(a)) def test_autodiff_with_single_device_sharding(self): # Add a constant captured by the nested pjit to make things more complicated h = jnp.arange(4.) f = pjit(lambda x: x.sum(1) * h.sum()) g = pjit(lambda x: f(jnp.sin(x * 4 + 2))) jtu.check_grads(g, (jnp.arange(16.).reshape((4, 4)) / 100,), order=2) def test_fast_path_array(self): devices = jax.devices() if len(devices) < 8: raise unittest.SkipTest("Test requires 8 global devices.") mesh_devices = np.array([[devices[0], devices[2]], [devices[3], devices[1]], [devices[4], devices[6]], [devices[7], devices[5]]]) shape = (8, 2) mesh = jax.sharding.Mesh(mesh_devices, ('x', 'y')) s = NamedSharding(mesh, P('x', 'y')) inp_data = np.arange(math.prod(shape), dtype=np.float32).reshape(shape) # Explicitly put on the ordering of devices which does not match the mesh # ordering to make sure we reorder them in the constructor and the output # is correct. local_devices = jax.local_devices()[:8] # Take 8 local devices di_map = s.devices_indices_map(shape) bufs = [jax.device_put(inp_data[di_map[d]], d) for d in local_devices] arr = array.ArrayImpl(core.ShapedArray(shape, np.float32), s, bufs, committed=True) f = pjit(lambda x: x, out_shardings=s) out = f(arr) self.assertTrue(out.sharding.is_equivalent_to(arr.sharding, arr.ndim)) self.assertArraysEqual(out, inp_data) out2 = f(out) self.assertTrue(out2.sharding.is_equivalent_to(out.sharding, out.ndim)) self.assertArraysEqual(out2, inp_data) def test_array_enabled_non_empty_mesh_with_pspec(self): arr = jnp.array([1, 2, 3]) with self.assertRaisesRegex( RuntimeError, r'pjit requires a non-empty mesh if you are passing `PartitionSpec`s or' r' `None` to in_shardings.*'): pjit(lambda x: x, in_shardings=P('x'))(arr) with self.assertRaisesRegex( TypeError, "in_shardings leaf specifications are expected to be PartitionSpec " "instances or None, but got x"): pjit(lambda x: x, in_shardings='x') def test_pjit_uncommitted_array_reshard(self): arr = jnp.array([[1, 2, 3]]) mesh = jtu.create_global_mesh((4, 2), ('x', 'y')) with mesh: out = pjit(lambda x: x)(arr) self.assertArraysEqual(out, arr) self.assertLen(out.addressable_shards, 8) def test_pjit_uncommitted_array_in_axis_resources_reshard(self): arr = jnp.arange(16).reshape(8, 2) mesh = jtu.create_global_mesh((4, 2), ('x', 'y')) with mesh: out = pjit(lambda x: x, in_shardings=P('x', 'y'))(arr) self.assertArraysEqual(out, arr) self.assertLen(out.addressable_shards, 8) for s in out.addressable_shards: self.assertArraysEqual(s.data, arr[s.index]) self.assertEqual(s.replica_id, 0) def test_pjit_uncommitted_array_and_committed_array(self): shape = (8, 2) uarr = jnp.arange(math.prod(shape), dtype=np.float32).reshape(shape) mesh = jtu.create_global_mesh((4, 2), ('x', 'y')) carr, inp_data = create_array(shape, mesh, P('x', 'y')) with mesh: out1, out2 = pjit(lambda x, y: (x, y))(uarr, carr) self.assertArraysEqual(out1, inp_data) self.assertArraysEqual(out2, inp_data) self.assertLen(out1.addressable_shards, 8) self.assertLen(out2.addressable_shards, 8) mul_out = pjit(lambda x, y: x @ y.T)(uarr, carr) self.assertEqual(mul_out.shape, (8, 8)) self.assertLen(mul_out.addressable_shards, 8) with jtu.create_global_mesh((2, 2), ('x', 'y')): with self.assertRaisesRegex( ValueError, "Received incompatible devices for pjitted computation"): pjit(lambda x, y: (x, y))(uarr, carr) def test_pjit_uncommitted_array_multi_devices(self): shape = (8, 2) mesh = jtu.create_global_mesh((4, 2), ('x', 'y')) inp = np.arange(math.prod(shape), dtype=np.int32).reshape(shape) arr = array.ArrayImpl( core.ShapedArray(shape, np.int32), NamedSharding(mesh, P(None)), [jax.device_put(inp, d) for d in mesh.devices.flat], committed=False) with self.assertRaisesRegex( NotImplementedError, "Having uncommitted Array sharded on multiple devices is not supported."): pjit(lambda x: x)(arr) def test_pjit_committed_array_different_devices(self): if jax.device_count() < 2: self.skipTest('Test requires >= 2 devices') a = jax.device_put(np.array([1, 2, 3]), jax.devices()[0]) b = jax.device_put(np.array([4, 5, 6]), jax.devices()[1]) with self.assertRaisesRegex( ValueError, "Received incompatible devices for pjitted computation. Got argument " r"x of.*\ with shape int.*\[3\] and device ids \[0\].*and " r"argument y of.*\ with shape int.*\[3\] and device ids \[1\].*"): pjit(lambda x, y: (x, y))(a, b) def test_pjit_committed_array_different_devices_variadic_args(self): if jax.device_count() < 2: self.skipTest('Test requires >= 2 devices') a = jax.device_put(np.array([1, 2, 3]), jax.devices()[0]) b = jax.device_put(np.array([4, 5, 6]), jax.devices()[1]) with self.assertRaisesRegex( ValueError, "Received incompatible devices for pjitted computation. Got argument " r"x\[0\] of.*\ with shape int.*\[3\] and device ids \[0\].*and " r"argument x\[1\] of.*\ with shape int.*\[3\] and device ids " r"\[1\].*"): pjit(lambda *x: x)(a, b) def test_pjit_pytree_inp_device_assignment_mismatch(self): mesh = jtu.create_global_mesh((2, 2), ('x', 'y')) a = jax.device_put(np.array([1, 2, 3]), jax.devices()[0]) b = jax.device_put(np.array([4, 5, 6]), jax.devices()[1]) c = jax.device_put(np.arange(16).reshape(8, 2), NamedSharding(mesh, P('x', 'y'))) msg = ("Received incompatible devices for pjitted computation. Got " r"argument {} of.* with shape int.*\[3\] and device ids " r"\[0\].*and argument {} of.* with shape int.*\[8,2\] and " r"device ids \[0, 1, 2, 3\].*") with self.assertRaisesRegex( ValueError, msg.format(r'tuple_inp\[0\]', r'tuple_inp\[1\]\[0\]')): pjit(lambda tuple_inp: tuple_inp)((a, (c, (b)))) with self.assertRaisesRegex( ValueError, msg.format(r"dict_inp\['a'\]\['b'\]\['c'\]", r"dict_inp\['a'\]\['b'\]\['g'\]")): inp = {'d': a, 'z': a, 'a': {'f': a, 'y': b, 'b': {'g': c, 'c': a}}} pjit(lambda dict_inp: dict_inp)(inp) def test_same_out_sharding_id(self): shape = (8, 2) mesh = jtu.create_global_mesh((4, 2), ('x', 'y')) arr, inp_data = create_array(shape, mesh, P('x', 'y')) f = pjit(lambda x: x) out1 = f(arr) self.assertArraysEqual(out1, inp_data) out1_sharding_id = id(out1.sharding) out2 = f(out1) self.assertArraysEqual(out2, inp_data) out2_sharding_id = id(out2.sharding) out3 = f(out2) self.assertArraysEqual(out3, inp_data) out3_sharding_id = id(out3.sharding) self.assertEqual(out1_sharding_id, out2_sharding_id) self.assertEqual(out1_sharding_id, out3_sharding_id) self.assertEqual(out2_sharding_id, out3_sharding_id) def test_out_sharding_indices_id_cache_hit(self): shape = (8, 2) mesh = jtu.create_global_mesh((4, 2), ('x', 'y')) arr, _ = create_array(shape, mesh, P('x', 'y')) f = pjit(lambda x: x) out1 = f(arr) self.assertIsInstance(out1.sharding, NamedSharding) out1.sharding.devices_indices_map(shape) cache_info1 = common_devices_indices_map.cache_info() out2 = f(out1) self.assertIsInstance(out2.sharding, NamedSharding) out2.sharding.devices_indices_map(shape) cache_info2 = common_devices_indices_map.cache_info() self.assertEqual(cache_info2.hits, cache_info1.hits + 1) out3 = f(out2) self.assertIsInstance(out3.sharding, NamedSharding) out3.sharding.devices_indices_map(shape) cache_info3 = common_devices_indices_map.cache_info() self.assertEqual(cache_info3.hits, cache_info2.hits + 1) def test_aot_compile_in_tree_mismatch(self): @jax.jit def f(tree): return tree tree1 = {'a': {'c': 5, 'd': 6}} tree2 = {'a': 1, 'c': {'b': 5, 'e': 7}} with self.assertRaisesRegex( TypeError, 'Function compiled with input pytree does not match the input pytree it' ' was called with'): f.lower(tree1).compile()(tree2) @jax.enable_custom_prng() def test_device_put_sharding_prng(self): mesh = jtu.create_global_mesh((8,), ('x',)) s = NamedSharding(mesh, P('x')) x = jax.random.split(jax.random.PRNGKey(0), len(jax.devices())) y = jax.device_put(x, s) self.assertTrue(jax.dtypes.issubdtype(y.dtype, jax.dtypes.prng_key)) self.assertEqual(y.sharding, s) s1 = SingleDeviceSharding(jax.devices()[1]) z = jax.device_put(x, s1) self.assertTrue(jax.dtypes.issubdtype(z.dtype, jax.dtypes.prng_key)) self.assertEqual(z.sharding, s1) out_p = jax.pmap(lambda x: x)(np.arange(jax.device_count())) a = jax.device_put(x, out_p.sharding) self.assertTrue(jax.dtypes.issubdtype(a.dtype, jax.dtypes.prng_key)) self.assertEqual(a.sharding, out_p.sharding) op = xc.OpSharding() op.type = xc.OpSharding.Type.OTHER op.tile_assignment_dimensions = [8] op.tile_assignment_devices = [0, 1, 2, 3, 4, 5, 6, 7] gs = GSPMDSharding(tuple(mesh.devices.flat), op) b = jax.device_put(x, gs) self.assertTrue(jax.dtypes.issubdtype(b.dtype, jax.dtypes.prng_key)) self.assertEqual(b.sharding, gs) def test_device_put_on_different_sharding(self): mesh = jtu.create_global_mesh((4, 2), ('x', 'y')) x = jnp.arange(8).reshape(4, 2) s1 = NamedSharding(mesh, P('x')) a = jax.device_put(x, s1) self.assertEqual(a.sharding, s1) s2 = NamedSharding(mesh, P('x', 'y')) b = jax.device_put(a, s2) self.assertEqual(b.sharding, s2) def test_with_sharding_constraint_jit(self): mesh = jtu.create_global_mesh((2, 2), ('x', 'y')) @partial(jax.jit, static_argnums=(0, 1)) def sharded_zeros(shape, pspec): out = jnp.zeros(shape, jnp.bfloat16) return jax.lax.with_sharding_constraint(out, NamedSharding(mesh, pspec)) out = sharded_zeros((4096, 3072), P('x', 'y')) out_s = NamedSharding(mesh, P('x', 'y')) self.assertTrue(op_shardings.are_op_shardings_equal( out.sharding._to_xla_hlo_sharding(out.ndim), out_s._to_xla_hlo_sharding(out.ndim))) def test_with_sharding_constraint_pjit(self): mesh = jtu.create_global_mesh((2, 2), ('x', 'y')) @partial(pjit, static_argnums=(0, 1)) def sharded_zeros(shape, pspec): out = jnp.zeros(shape, jnp.bfloat16) return jax.lax.with_sharding_constraint(out, NamedSharding(mesh, pspec)) out = sharded_zeros((4096, 3072), P('x', 'y')) out_s = NamedSharding(mesh, P('x', 'y')) self.assertTrue(op_shardings.are_op_shardings_equal( out.sharding._to_xla_hlo_sharding(out.ndim), out_s._to_xla_hlo_sharding(out.ndim))) def test_jit_with_sharding_constraint_committed_inp_error(self): mesh = jtu.create_global_mesh((2, 2), ('x', 'y')) s = NamedSharding(mesh, P('x', 'y')) @jax.jit def sharded_inp(inp): return jax.lax.with_sharding_constraint( inp, NamedSharding(mesh, P('x', 'y'))) committed_inp = jax.device_put(jnp.zeros((8, 2), jnp.bfloat16), jax.devices()[0]) with self.assertRaisesRegex( ValueError, "Received incompatible devices for jitted computation. Got argument " r"inp of.*sharded_inp with shape bfloat16\[8,2\] and device ids \[0\].*" r"sharding_constraint inside jit with device ids \[0, 1, 2, 3\].*"): sharded_inp(committed_inp) @pjit def my_nested_pjit(inp1, inp2, inp3): @partial(pjit, in_shardings=(s, s, s), out_shardings=(s, s, s)) def f(x, y, z): return x * 2, y * 2, z * 2 return f(inp1, inp2, inp3) with self.assertRaisesRegex( ValueError, "Received incompatible devices for pjitted computation. Got argument " r"inp1 of.*my_nested_pjit with shape bfloat16\[8,2\] and device ids \[0\].*" r"pjit inside pjit with device ids \[0, 1, 2, 3\].*"): my_nested_pjit(committed_inp, committed_inp, committed_inp) @jtu.ignore_warning(category=DeprecationWarning, message="backend and device argument") def test_jit_device_with_sharding_constraint_error(self): mesh = jtu.create_global_mesh((2, 2), ('x', 'y')) @partial(jax.jit, static_argnums=(0, 1), device=jax.devices()[0]) def sharded_zeros(shape, pspec): out = jnp.zeros(shape, jnp.bfloat16) return jax.lax.with_sharding_constraint(out, NamedSharding(mesh, pspec)) with self.assertRaisesRegex( ValueError, "Received incompatible devices for jitted computation. Got explicit " r"output sharding with device ids \[0\].*sharding_constraint inside " r"jit with device ids \[0, 1, 2, 3\].*"): sharded_zeros((4096, 3072), P('x', 'y')) def test_concurrent_pjit(self): global_mesh = jtu.create_global_mesh((1,), ('x',)) sharding = NamedSharding(global_mesh, P('x',)) n = 10 with global_mesh: fs = [pjit(lambda x, i: x + i, static_argnums=1) for _ in range(n)] def _invoke_with_mesh_twice(arg_tuple): f, x, i = arg_tuple with global_mesh: f(x, i) return f(x, i) xs = [ array.make_array_from_callback( (i,), sharding, lambda idx: np.arange(i, dtype=np.float32)) for i in range(n) ] with concurrent.futures.ThreadPoolExecutor() as executor: ys = executor.map(_invoke_with_mesh_twice, [(fs[i], x, i) for i, x in enumerate(xs)]) for i, x, y in zip(range(n), xs, ys): self.assertAllClose(x + i, y) def test_trivial_computation(self): shape = (8, 2) mesh = jtu.create_global_mesh((2, 2), ('x', 'y')) s = NamedSharding(mesh, P('x', 'y')) inp_data = np.arange(math.prod(shape)).reshape(shape) arr = jax.device_put(inp_data, s) out = pjit(lambda x: x)(arr) self.assertArraysEqual(out, inp_data) def test_trivial_computation_with_sharded_const(self): mesh = jtu.create_global_mesh((2, 1), ('x', 'y')) const = jax.device_put(np.arange(16).reshape(8, 2), NamedSharding(mesh, P('x', 'y'))) with mesh: out = pjit(lambda: const)() self.assertIsInstance(out, array.ArrayImpl) self.assertArraysEqual(out, np.arange(16).reshape(8, 2)) def test_trivial_computation_with_sharded_const_using_transposed_mesh(self): mesh = jtu.create_global_mesh((2, 1), ('x', 'y')) const = jax.device_put(np.arange(16).reshape(8, 2), NamedSharding(mesh, P('x', 'y'))) mesh2 = jtu.create_global_mesh((1, 2), ('x', 'y')) with mesh2: out = pjit(lambda: const)() self.assertIsInstance(out, array.ArrayImpl) self.assertArraysEqual(out, np.arange(16).reshape(8, 2)) def test_trivial_computation_with_replicated_literal(self): mesh = jtu.create_global_mesh((2, 1), ('x', 'y')) with mesh: out = pjit(lambda: 1)() self.assertEqual(out.sharding, NamedSharding(mesh, P())) self.assertIsInstance(out, array.ArrayImpl) self.assertEqual(out, 1) def test_multi_device_pjit_mul(self): shape = (8, 2) mesh = jtu.create_global_mesh((4, 2), ('x', 'y')) inp_data = np.arange(math.prod(shape)).reshape(shape) arr1 = jax.device_put(inp_data, NamedSharding(mesh, P('x', 'y'))) arr2 = jax.device_put(inp_data, NamedSharding(mesh, P(None, 'y'))) out1, out2 = pjit(lambda x, y: (x @ x.T, y * 2))(arr1, arr2) self.assertArraysEqual(out1, inp_data @ inp_data.T) self.assertEqual(out1.shape, (8, 8)) self.assertArraysEqual(out2, inp_data * 2) self.assertEqual(out2.shape, (8, 2)) def test_single_device_pjit_cpp_dispatch(self): shape = (8, 2) mesh = jtu.create_global_mesh((1,), ('x',)) inp_data = np.arange(math.prod(shape)).reshape(shape) f = pjit(lambda x: x @ x.T, in_shardings=None, out_shardings=None) with jtu.count_pjit_cpp_cache_miss() as count: for _ in range(10): arr1 = jax.device_put( inp_data, jax.sharding.NamedSharding(mesh, P('x'))) with mesh: f(arr1) self.assertEqual(count[0], 1) def test_single_device_add_single_compile(self): f1 = pjit(lambda x, y: x + y) a = jax.device_put(jnp.array([1, 2, 3], dtype=jnp.float32), jax.devices()[0]) b = jax.device_put(jnp.array([4, 5, 6], dtype=jnp.float32), jax.devices()[0]) with jtu.count_pjit_cpp_cache_miss() as count: for _ in range(2): f1(a, b) self.assertEqual(count[0], 1) def test_global_array_to_host_local_array_already_host_local(self): inp_shape = (8, 2) mesh = jtu.create_global_mesh((4, 2), ('x', 'y')) pspec = P('x', 'y') arr, _ = create_array(inp_shape, mesh, pspec) out = multihost_utils.global_array_to_host_local_array(arr, mesh, pspec) self.assertEqual(id(arr), id(out)) @jtu.with_mesh([('x', 2), ('y', 2)]) def testLowerCompileWithStaticArguments(self): @partial(pjit, in_shardings=P(('x', 'y'),), out_shardings=P(('x', 'y'),), static_argnums=0) def f(c, x): return x if c == 0 else x + 1 shape = (8, 8) x = jnp.arange(math.prod(shape)).reshape(shape) exe = f.lower(1, x).compile() self.assertAllClose(exe(x), x + 1, check_dtypes=False) def test_vmap_of_jvp_pjit_no_axis_resources(self): mesh = jtu.create_global_mesh((2, 2), ('x', 'y')) pjit_inp1 = jax.device_put( jnp.arange(8.), jax.sharding.NamedSharding(mesh, P('x'))) pjit_inp2 = jax.device_put( jnp.arange(8.), jax.sharding.NamedSharding(mesh, P(('x', 'y')))) def f_(x, n): if n == 0: return x * 2. return jax.jit(partial(f_, n=n-1))(x - 1) f = jax.jit(partial(f_, n=5)) jit_out1, jit_out2 = jax.vmap(lambda xs, ts: jax.jvp(f, xs, ts))( (jnp.arange(8.),), (jnp.arange(8.),)) def g_(x, n): if n == 0: return x * 2. return pjit(partial(g_, n=n - 1))(x - 1) g = pjit(partial(g_, n=5)) pjit_out1, pjit_out2 = jax.vmap(lambda xs, ts: jax.jvp(g, xs, ts))( (pjit_inp1,), (pjit_inp2,)) self.assertArraysEqual(pjit_out1, jit_out1) self.assertArraysEqual(pjit_out2, jit_out2) def test_vmap_of_jvp_pjit_no_axis_resources_2d(self): mesh = jtu.create_global_mesh((2, 2), ('x', 'y')) f_inp = jnp.arange(8.).reshape(2, 2, 2) # g_inp is sharded with P(None, 'x') because f_inp is sharded with P('x') # and then `f` will get vmapped and pjit's batching rule will insert a # replicated axis for the batched dimension converting it into P(None, 'x') g_inp = jax.device_put(f_inp, jax.sharding.NamedSharding(mesh, P(None, 'x'))) # Reference pjit with axis_resources def f_(x, n): if n == 0: return x * 2. return pjit( partial(f_, n=n - 1), in_shardings=P('x'), out_shardings=P('x') )(x - 1) f = pjit(partial(f_, n=5), in_shardings=P('x'), out_shardings=P('x')) with mesh: f_out1, f_out2 = jax.vmap(lambda xs, ts: jax.jvp(f, xs, ts))( (f_inp,), (f_inp,)) # pjit with no axis_resources def g_(x, n): if n == 0: return x * 2. return pjit(partial(g_, n=n - 1))(x - 1) g = pjit(partial(g_, n=5)) g_out1, g_out2 = jax.vmap(lambda xs, ts: jax.jvp(g, xs, ts))( (g_inp,), (g_inp,)) self.assertArraysEqual(f_out1, g_out1) self.assertArraysEqual(f_out2, g_out2) self.assertEqual(f_out1.sharding, g_out1.sharding) self.assertEqual(f_out2.sharding, g_out2.sharding) def test_pjit_on_different_default_device_with_uncommitted_inputs(self): if jax.device_count() < 2: self.skipTest('Test requires >= 2 devices') @pjit def f(x, y): return x + y a = jnp.array([1, 2, 3], dtype=jnp.float32) self.assertFalse(a._committed) out = f(a, a) self.assertFalse(out._committed) self.assertEqual(out.devices(), {jax.devices()[0]}) self.assertArraysEqual(out, a * 2) with jax.default_device(jax.devices()[1]): b = jnp.array([4, 5, 6], dtype=jnp.float32) self.assertFalse(b._committed) out2 = f(b, b) self.assertFalse(out2._committed) self.assertEqual(out2.devices(), {jax.devices()[1]}) self.assertArraysEqual(out2, b * 2) def test_pjit_with_static_argnames(self): def f(x: str) -> int: assert x == 'foo' return 1 f_nums = pjit(f, static_argnums=0) assert f_nums('foo') == 1 assert f_nums(x='foo') == 1 f_names = pjit(f, static_argnames='x') assert f_names('foo') == 1 assert f_names(x='foo') == 1 def test_pjit_with_static_argnames_cpp_dispatch(self): def f(y, **kwargs): self.assertEqual(kwargs, {'x': 'foo'}) return y * y y = jnp.arange(8.) with jtu.count_pjit_cpp_cache_miss() as count: f_names = pjit(f, static_argnames='x') f_names(y, x='foo') f_names(y, x='foo') self.assertEqual(count[0], 1) def test_new_static_argnum_on_keyword_arguments(self): f = pjit(lambda x: x, static_argnums=0) y = f(x=4) assert y == 4 def test_new_static_argnum_with_default_arguments(self): f = pjit(lambda x=4: x, static_argnums=0) y = f() assert y == 4 def test_pjit_different_default_device(self): if jax.device_count() <= 1: self.skipTest('Test requires more >1 device.') system_default_device = list(jnp.add(1, 1).devices())[0] test_device = jax.devices()[-1] f = pjit(lambda x: x + 1) f(1) with jax.default_device(system_default_device): f(1) with jax.default_device(test_device): f(1) with jtu.count_pjit_cpp_cache_miss() as count: f(1) with jax.default_device(system_default_device): f(1) with jax.default_device(test_device): f(1) with jax.default_device(test_device): with jax.default_device(system_default_device): f(1) # The count here is 0 because before `count_pjit_cpp_cache_miss`, `f` was # called with `system_default_device` and `test_device` so it was added # to the cache. Subsequent calls hit the C++ cache. self.assertEqual(count[0], 0) def test_pjit_with_mismatched_static_argnames(self): x_is_tracer, y_is_tracer = False, False def f(x, y): assert isinstance(x, core.Tracer) == x_is_tracer assert isinstance(y, core.Tracer) == y_is_tracer return 1 # If both static_argnums and static_argnames are provided, they are allowed # to disagree and `jit` will respect the user's choices. f_nums = pjit(f, static_argnums=1, static_argnames=()) x_is_tracer, y_is_tracer = True, False assert f_nums(2, 3) == 1 x_is_tracer, y_is_tracer = True, True assert f_nums(1, y=2) == 1 f_names = pjit(f, static_argnums=(), static_argnames='y') x_is_tracer, y_is_tracer = True, True assert f_names(2, 3) == 1 x_is_tracer, y_is_tracer = True, False assert f_names(1, y=3) == 1 f_mixed = pjit(f, static_argnums=(1,), static_argnames='x') x_is_tracer, y_is_tracer = True, False assert f_mixed(2, 3) == 1 x_is_tracer, y_is_tracer = True, True assert f_mixed(1, y=3) == 1 x_is_tracer, y_is_tracer = False, True assert f_mixed(x=2, y=3) == 1 def test_pjit_kwargs(self): a = jnp.arange(8.) b = jnp.arange(4.) c = jnp.arange(2.) @pjit def f(x, y, z): return x, y, z o1, o2, o3 = f(a, y=b, z=c) cache_info1 = pjit_lib._pjit_lower_cached.cache_info() self.assertArraysEqual(o1, a) self.assertArraysEqual(o2, b) self.assertArraysEqual(o3, c) o4, o5, o6 = f(x=a, y=b, z=c) cache_info2 = pjit_lib._pjit_lower_cached.cache_info() self.assertArraysEqual(o4, a) self.assertArraysEqual(o5, b) self.assertArraysEqual(o6, c) self.assertEqual(cache_info2.hits, cache_info1.hits) self.assertEqual(cache_info2.misses, cache_info1.misses + 1) o7, o8, o9 = f(a, b, c) cache_info3 = pjit_lib._pjit_lower_cached.cache_info() self.assertArraysEqual(o7, a) self.assertArraysEqual(o8, b) self.assertArraysEqual(o9, c) self.assertEqual(cache_info3.hits, cache_info2.hits) self.assertEqual(cache_info3.misses, cache_info2.misses + 1) def test_pjit_kwargs_axis_resources_error(self): with self.assertRaisesRegex( ValueError, "pjit does not support kwargs when in_shardings is specified."): pjit(lambda x: x, in_shardings=SingleDeviceSharding(jax.devices()[0]))(x=jnp.arange(8.)) def test_pjit_keep_unused_true(self): @partial(pjit, keep_unused=True) def f(x, y, z, a, b, c): # pylint: disable=unused-argument return c @ c.T inp = jnp.arange(4) unused_inp = jnp.arange(8) out = f(unused_inp, unused_inp, unused_inp, unused_inp, unused_inp, inp) # Run it again to take the C++ dispatch. out_again = f(unused_inp, unused_inp, unused_inp, unused_inp, unused_inp, inp) self.assertArraysEqual(out, inp @ inp.T) self.assertArraysEqual(out_again, inp @ inp.T) compiled = f.lower( unused_inp, unused_inp, unused_inp, unused_inp, unused_inp, inp).compile() self.assertEqual(compiled._executable._kept_var_idx, {0, 1, 2, 3, 4, 5}) self.assertLen(compiled._executable.in_avals, 6) def test_pjit_keep_unused_default_false(self): @pjit def f(x, y, z, a, b, c): # pylint: disable=unused-argument return c @ c.T inp = jax.device_put(jnp.arange(4), jax.devices()[0]) unused_inp = jax.device_put(jnp.arange(8), jax.devices()[0]) out = f(unused_inp, unused_inp, unused_inp, unused_inp, unused_inp, inp) # Run it again to take the C++ dispatch. out_again = f(unused_inp, unused_inp, unused_inp, unused_inp, unused_inp, inp) self.assertArraysEqual(out, inp @ inp.T) self.assertArraysEqual(out_again, inp @ inp.T) compiled = f.lower( unused_inp, unused_inp, unused_inp, unused_inp, unused_inp, inp).compile() self.assertEqual(compiled._executable._kept_var_idx, {5}) self.assertLen(compiled._executable.in_avals, 1) def test_pjit_relayout_multi_slice(self): mesh = jtu.create_global_mesh((2, 2), ('x', 'y')) @jax.jit def mul(x): return x @ x.T x = jnp.arange(8).reshape(4, 2) y = jax.device_put(x, jax.sharding.NamedSharding(mesh, P('x', 'y'))) compiled = mul.lower(jax.ShapeDtypeStruct( y.shape, y.dtype, sharding=y.sharding)).compile() out = compiled(y) self.assertArraysEqual(out, x @ x.T) def test_pjit_with_device_arg(self): def mul(x): return x @ x.T def _check(out, expected_device, expected_out): self.assertEqual(out.devices(), {expected_device}) self.assertLen(out.sharding.device_set, 1) self.assertArraysEqual(out, expected_out @ expected_out.T) mesh = jtu.create_global_mesh((2, 2), ('x', 'y')) with jtu.ignore_warning(category=DeprecationWarning, message="backend and device argument"): f = pjit(mul, device=jax.devices()[1]) x = jnp.arange(8).reshape(4, 2) f_out = f(x) f_out2 = f(f_out) cache_info1 = pjit_lib._pjit_lower_cached.cache_info() _check(f_out, jax.devices()[1], x) _check(f_out2, jax.devices()[1], f_out) y = jax.device_put(x, jax.sharding.NamedSharding(mesh, P('x', 'y'))) out2 = f(y) cache_info2 = pjit_lib._pjit_lower_cached.cache_info() _check(out2, jax.devices()[1], y) self.assertEqual(cache_info2.hits, cache_info1.hits + 1) with jtu.ignore_warning(category=DeprecationWarning, message="backend and device argument"): h = pjit(mul, device=jax.devices()[-1]) h_out = h(y) cache_info3 = pjit_lib._pjit_lower_cached.cache_info() _check(h_out, jax.devices()[-1], y) self.assertEqual(cache_info3.hits, cache_info2.hits) # AOT test compiled = f.lower(core.ShapedArray(y.shape, y.dtype)).compile() out3 = compiled(y) _check(out3, jax.devices()[1], y) def test_pjit_with_device_arg_input_from_another_pjit(self): mesh = jtu.create_global_mesh((2, 2), ('x', 'y')) inp = np.arange(8).reshape(4, 2) y = jax.device_put(inp, jax.sharding.NamedSharding(mesh, P('x', 'y'))) out = pjit(lambda x: x * 2)(y) expected_device = jax.devices()[2] with jtu.ignore_warning(category=DeprecationWarning, message="backend and device argument"): final_out = pjit(lambda x: x * 3, device=expected_device)(out) self.assertEqual(final_out.devices(), {expected_device}) self.assertLen(final_out.sharding.device_set, 1) self.assertArraysEqual(final_out, inp * 6) @jtu.run_on_devices("tpu") def test_pjit_with_backend_arg(self): def _check(out, expected_device, expected_out): self.assertEqual(out.devices(), {expected_device}) self.assertLen(out.sharding.device_set, 1) self.assertArraysEqual(out, expected_out) x = jnp.arange(8) with jtu.ignore_warning(category=DeprecationWarning, message="backend and device argument"): g = pjit(lambda x: x, backend='tpu') g_out = g(x) _check(g_out, jax.devices()[0], x) compiled = g.lower(core.ShapedArray(x.shape, x.dtype)).compile() out4 = compiled(x) _check(out4, jax.devices()[0], x) def test_autodiff_with_device_arg(self): if jax.device_count() <= 1: self.skipTest('Test requires more >1 device.') # Add a constant captured by the nested pjit to make things more complicated h = jnp.arange(4.) with jtu.ignore_warning(category=DeprecationWarning, message="backend and device argument"): f = pjit(lambda x: x.sum(1) * h.sum(), device=jax.devices()[1]) g = pjit(lambda x: f(jnp.sin(x * 4 + 2)), device=jax.devices()[1]) jtu.check_grads(g, (jnp.arange(16.).reshape((4, 4)) / 100,), order=2) def test_pjit_device_backend_axis_resources_error(self): s = SingleDeviceSharding(jax.devices()[0]) with self.assertRaisesRegex( ValueError, 'If backend or device is specified on jit, then ' 'in_shardings should not be specified.'): with jtu.ignore_warning(category=DeprecationWarning, message="backend and device argument"): pjit(lambda x: x, in_shardings=s, backend='cpu') with self.assertRaisesRegex( ValueError, 'If backend or device is specified on jit, then ' 'out_shardings should not be specified.'): with jtu.ignore_warning(category=DeprecationWarning, message="backend and device argument"): pjit(lambda x: x, out_shardings=s, device=jax.devices()[0]) def test_check_arg_error(self): sds = jax.ShapeDtypeStruct((4, 2), np.int32) inp = np.arange(8).reshape(4, 2) with self.assertRaisesRegex( TypeError, r"Argument 'x\['b'\]\['c'\]' of shape int32\[4,2\] of " "type.*ShapeDtypeStruct.*is not a valid JAX type."): jax.jit(lambda x: x)({'a': inp, 'b': {'c': sds}}) def test_pjit_device_backend_both_error(self): with self.assertRaisesRegex( ValueError, "can't specify both a device and a backend for jit"): with jtu.ignore_warning(category=DeprecationWarning, message="backend and device argument"): pjit(lambda x: x, device=jax.devices()[0], backend='cpu') def test_pjit_mesh_with_device_or_backend_error(self): mesh = jtu.create_global_mesh((1,), ('x',)) with mesh: with self.assertRaisesRegex( ValueError, "Mesh context manager should not be used with jit when backend or " "device is also specified as an argument to jit."): with jtu.ignore_warning(category=DeprecationWarning, message="backend and device argument"): pjit(lambda x: x, device=jax.devices()[0])(jnp.arange(8)) def test_pjit_inline(self): @partial(pjit, inline=False) def f(x): return x * 2 jaxpr = jax.make_jaxpr(f)(3) self.assertIn('pjit', str(jaxpr)) @partial(pjit, inline=True) def g(x): return x * 2 jaxpr = jax.make_jaxpr(g)(3) self.assertNotIn('pjit', str(jaxpr)) def test_pmap_in_axis_resources_error(self): pmap_out = jax.pmap(lambda x: x)(jnp.arange(jax.device_count())) self.assertIsInstance(pmap_out.sharding, jax.sharding.PmapSharding) with self.assertRaisesRegex( ValueError, r"One of in_shardings.*got sharding.*which is not allowed."): pjit(lambda x: x, in_shardings=pmap_out.sharding) with self.assertRaisesRegex( ValueError, r"One of out_shardings.*got sharding.*which is not allowed."): pjit(lambda x: x, out_shardings=pmap_out.sharding) def test_pmap_sharding_input_to_pjit_single_device(self): pmap_out = jax.pmap(lambda x: x)(jnp.arange(jax.device_count())) self.assertIsInstance(pmap_out.sharding, jax.sharding.PmapSharding) self.assertLen(pmap_out.devices(), jax.device_count()) out = pjit(lambda x: x * 3)(pmap_out) self.assertArraysEqual(out, pmap_out * 3) # Even though pmap out is on jax.device_count() number of devices, the # output will be 1 device since it will be resharded. self.assertLen(out.devices(), 1) def test_pmap_sharding_input_to_pjit_multi_device(self): mesh = jtu.create_global_mesh((2, 2), ('x', 'y')) pmap_out = jax.pmap(lambda x: x)(jnp.arange(jax.device_count())) self.assertIsInstance(pmap_out.sharding, jax.sharding.PmapSharding) inp2 = jnp.arange(4) with mesh: out1, out2 = pjit(lambda x, y: (x * 2, y * 2))(pmap_out, inp2) self.assertArraysEqual(out1, pmap_out * 2) self.assertArraysEqual(out2, inp2 * 2) self.assertLen(out1.devices(), 4) self.assertLen(out2.devices(), 4) self.assertTrue(op_shardings.is_op_sharding_replicated( out1.sharding._to_xla_hlo_sharding(pmap_out.ndim))) self.assertTrue(op_shardings.is_op_sharding_replicated( out2.sharding._to_xla_hlo_sharding(inp2.ndim))) def test_pmap_sharding_input_pjit_in_axis_resources(self): mesh = jtu.create_global_mesh((2, 2), ('x', 'y')) pmap_out = jax.pmap(lambda x: x)(jnp.arange(jax.device_count())) self.assertIsInstance(pmap_out.sharding, jax.sharding.PmapSharding) out = pjit(lambda x: x * 2, in_shardings=NamedSharding(mesh, P('x')))(pmap_out) self.assertArraysEqual(out, pmap_out * 2) self.assertLen(out.devices(), 4) def test_nested_pjit_closing_over_tracer(self): @pjit def f(x): y = jnp.float32(2) * x @pjit def g(z): return jax.pmap(lambda x: x[jnp.newaxis] * y)(z) return g(x) f(np.arange(1., dtype='float32').reshape((1, 1))) # doesn't crash # Second call is to trigger C++ dispatch. f(np.arange(1., dtype='float32').reshape((1, 1))) # doesn't crash def test_aot_nested_pjit_closing_over_const_top_level(self): const = jnp.arange(8.) @pjit def f(x): return const * 2 + x inp = jnp.arange(8.) compiled = f.lower(inp).compile() self.assertArraysEqual(compiled(inp), const * 2 + inp) def test_nested_pjit_closing_over_const_top_level_and_tracer(self): const = jnp.arange(8.) @pjit def f(x): y = jnp.arange(8., 16.) * x + const @pjit def g(z): return z + y * 2 + const return g(x) f(jnp.arange(8.)) # doesn't crash # Second call is to trigger C++ dispatch. f(jnp.arange(8.)) # doesn't crash def test_nested_pjit_closing_over_top_level_const(self): const = jnp.arange(8.) @pjit def f(x): @pjit def g(z): return z + const return g(x) inp = jnp.arange(8., 16.) f(inp) # doesn't crash # Second call is to trigger C++ dispatch. f(inp) # doesn't crash def test_pjit_sin_nested(self): mesh = jtu.create_global_mesh((4, 2), ('x', 'y')) @pjit def f(x): return jnp.sin(x) with mesh: inp = jnp.arange(8.) out = f(inp) self.assertArraysAllClose(out, np.sin(inp)) self.assertLen(out.devices(), 8) def test_jit_with_mesh_context_manager(self): mesh = jtu.create_global_mesh((1,), ('x',)) with self.assertRaisesRegex( RuntimeError, "jax.jit only supports `Sharding`s being passed to " "in_shardings"): with mesh: jax.jit(lambda x: x, in_shardings=P('x'), out_shardings=P('x'))(jnp.arange(8)) def test_pjit_nested_uncommitted_output(self): @pjit def f(x): @pjit def g(y): return y * 2 return g(x) out = f(jnp.arange(8)) self.assertFalse(out._committed) self.assertArraysEqual(out, np.arange(8) * 2) def test_pjit_disable_jit(self): sideeffect = [] def f(x): sideeffect.append(None) return x + 1 f = jax.jit(f) for _ in range(2): f(1) self.assertLen(sideeffect, 1) with jax.disable_jit(): f(1) self.assertLen(sideeffect, 2) def test_pmap_pjit_axis_index(self): @partial(jax.pmap, axis_name='data') def _pmapped_fun(inputs): del inputs return jax.lax.axis_index('data') inputs = jnp.zeros(shape=[jax.device_count()]) with jtu.ignore_warning( message=".*Using jit-of-pmap can lead to inefficient data movement"): pjit(_pmapped_fun)(inputs) # doesn't crash jax.jit(_pmapped_fun)(inputs) # doesn't crash def test_pjit_function_cache_cpp(self): def f(x): return x * 2 inp = jnp.arange(3.) with jtu.count_pjit_cpp_cache_miss() as count: for _ in range(10): pjit(f)(inp) self.assertEqual(count[0], 1) def test_pjit_no_global_cache_hit_axis_resources(self): mesh = jtu.create_global_mesh((1,), ('x',)) s = NamedSharding(mesh, P('x')) inp = jnp.arange(8.0) with jtu.count_pjit_cpp_cache_miss() as count: for _ in range(10): pjit(lambda x: x * 2, in_shardings=s, out_shardings=s)(inp) self.assertEqual(count[0], 10) with jtu.count_pjit_cpp_cache_miss() as count: for _ in range(10): with jtu.ignore_warning(category=DeprecationWarning, message="backend and device argument"): pjit(lambda x: x * 2, device=jax.devices()[0])(inp) self.assertEqual(count[0], 10) pf = pjit(lambda x: x * 2, in_shardings=s, out_shardings=s) with jtu.count_pjit_cpp_cache_miss() as count: for _ in range(10): pf(inp) self.assertEqual(count[0], 1) with jtu.ignore_warning(category=DeprecationWarning, message="backend and device argument"): pf1 = pjit(lambda x: x * 2, device=jax.devices()[0]) with jtu.count_pjit_cpp_cache_miss() as count: for _ in range(10): pf1(inp) self.assertEqual(count[0], 1) def test_with_sharding_constraint_spmd_axis_name(self): mesh = jtu.create_global_mesh((2, 2, 2), ('replica', 'data', 'mdl')) shape = (8, 4, 2, 2) x = jnp.arange(math.prod(shape)).reshape(shape) def f(inp): sharding = NamedSharding(mesh, P('data', None, None)) return with_sharding_constraint(inp, sharding) out = jax.vmap(jax.jit(f), spmd_axis_name='mdl')(x) ns, _ = op_shardings.get_num_ways_dim_sharded( out.sharding._to_xla_hlo_sharding(out.ndim)) self.assertListEqual(ns, [2, 2, 1, 1]) def apply_with_scan(x): x, _ = jax.lax.scan(lambda x, _: (f(x), None), x, None, length=1) return x out2 = jax.vmap(apply_with_scan, spmd_axis_name='mdl')(x) ns2, _ = op_shardings.get_num_ways_dim_sharded( out2.sharding._to_xla_hlo_sharding(out2.ndim)) self.assertListEqual(ns2, [2, 2, 1, 1]) def test_device_put_sharding_nondivisible_sharding_error(self): mesh = jtu.create_global_mesh((2,), ('x',)) s = NamedSharding(mesh, P('x')) x = jnp.ones((1,)) with self.assertRaisesRegex( ValueError, 'implies that the global size of its dimension 0 should be ' 'divisible by 2, but it is equal to 1 '): jax.device_put(x, s) y = jnp.ones((2,)) with self.assertRaisesRegex( ValueError, 'implies that the global size of its dimension 0 should be ' 'divisible by 2, but it is equal to 1 '): jax.device_put((y, x), s) with self.assertRaisesRegex( ValueError, "The sharded dimension must be equal to the number of " "devices passed to PmapSharding. Got sharded dimension 0 with value 1 " r"in shape \(1,\) and the number of devices=2"): s2 = jax.pmap(lambda x: x, devices=list(mesh.devices.flat))(jnp.arange(2)).sharding jax.device_put(x, s2) jax.device_put(2., NamedSharding(mesh, P())) # doesn't crash def test_with_sharding_constraint_with_two_meshes(self): if jax.device_count() < 4: self.skipTest("Requires more than 4 devices.") dev0 = jax.devices()[:2] mesh0 = jax.sharding.Mesh(dev0, ('x')) dev1 = jax.devices()[2:4] mesh1 = jax.sharding.Mesh(dev1, ('x')) def f(x): y = x * 2 y = jax.lax.with_sharding_constraint(y, P('x')) return y + 2 with mesh0: x = np.ones((32, 4)) out0 = pjit(f)(x) self.assertListEqual(sorted([d.id for d in out0.devices()]), [d.id for d in dev0]) with mesh1: x = np.ones((32, 4)) out1 = pjit(f)(x) self.assertListEqual(sorted([d.id for d in out1.devices()]), [d.id for d in dev1]) def test_device_assignment_mismatch_apply_primitive(self): if jax.device_count() < 2: self.skipTest("Requires >=2 devices.") arr = jax.device_put(np.arange(8), jax.devices()[0]) arr2 = jax.device_put(np.arange(8), jax.devices()[1]) with self.assertRaisesRegex( ValueError, "Received incompatible devices for jitted computation. Got argument.*" r"of concatenate with shape int.*\[8\].*and argument.*"): jnp.concatenate([arr, arr2]) def test_device_put_grad(self): if jax.device_count() < 8: self.skipTest("Requires >=8 devices.") def _test(fun, inp, np_inp, in_s): out = fun(inp) self.assertArraysEqual(out, np.sum(np_inp ** 2 * 3)) self.assertArraysEqual( [d.id for d in out.sharding._device_assignment], [4, 5, 6, 7]) gout = jax.grad(fun)(inp) self.assertTrue(gout.sharding.is_equivalent_to(in_s, gout.ndim)) self.assertArraysEqual( [d.id for d in gout.sharding._device_assignment], [0, 1, 2, 3]) self.assertArraysEqual(gout, jax.grad(fun)(np_inp)) mesh1 = jax.sharding.Mesh(jax.devices()[:4], 'x') mesh2 = jax.sharding.Mesh(jax.devices()[4:8], 'x') @pjit def stage1(x): return x ** 2 @pjit def stage2(x): return x * 3 def f(x): y = stage1(x) y = jax.device_put(y, device=NamedSharding(mesh2, P('x'))) z = stage2(y) return jnp.sum(z) def g(x): y = stage1(x) y = jax.device_put(y, src=NamedSharding(mesh1, P('x')), device=NamedSharding(mesh2, P('x'))) z = stage2(y) return jnp.sum(z) np_inp = np.arange(4.) in_s = NamedSharding(mesh1, P('x')) arr = jax.device_put(np_inp, in_s) _test(f, arr, np_inp, in_s) _test(g, arr, np_inp, in_s) # Test second order autodiff with src argument specified in device_put. jtu.check_grads(g, (arr,), order=2) def test_pjit_out_sharding_preserved(self): mesh = jtu.create_global_mesh((2, 1), ('x', 'y')) ns = NamedSharding(mesh, P('x')) ps = PositionalSharding(jax.devices()[:2]).reshape(2, 1) arr = jax.device_put(np.arange(8).reshape(8, 1), ns) arr2 = jax.device_put(np.arange(8).reshape(8, 1), ps) def mul(x): return x * 2 f = pjit(mul, out_shardings=ns) f2 = pjit(mul, out_shardings=ps) with jtu.count_pjit_cpp_cache_miss() as count: out = f(arr) cache_info1 = pxla._cached_compilation.cache_info() self.assertIsInstance(out.sharding, NamedSharding) out = f(arr) self.assertIsInstance(out.sharding, NamedSharding) self.assertEqual(count[0], 1) with jtu.count_pjit_cpp_cache_miss() as count: out2 = f2(arr) cache_info2 = pxla._cached_compilation.cache_info() self.assertIsInstance(out2.sharding, PositionalSharding) out2 = f2(arr) self.assertIsInstance(out2.sharding, PositionalSharding) self.assertEqual(count[0], 1) self.assertEqual(cache_info2.hits, cache_info1.hits + 1) self.assertEqual(cache_info2.misses, cache_info1.misses) out3 = jnp.squeeze(arr, axis=-1) cache_info3 = pxla._cached_compilation.cache_info() self.assertIsInstance(out3.sharding, NamedSharding) out4 = jnp.squeeze(arr2, axis=-1) cache_info4 = pxla._cached_compilation.cache_info() self.assertIsInstance(out4.sharding, PositionalSharding) self.assertEqual(cache_info4.hits, cache_info3.hits) self.assertEqual(cache_info4.misses, cache_info3.misses + 1) def test_cache_hit_pjit_lower_with_cpp_cache_miss(self): mesh = jtu.create_global_mesh((2, 1), ('x', 'y')) ns = NamedSharding(mesh, P('x')) np_arr = np.arange(8, dtype=np.float32).reshape(8, 1) arr = jax.device_put(np_arr, ns) def mul(x): return x * 2 f = pjit(mul, in_shardings=ns, out_shardings=ns) with jtu.count_pjit_cpp_cache_miss() as count: out = f(arr) cache_info1 = pjit_lib._pjit_lower_cached.cache_info() self.assertIsInstance(out.sharding, NamedSharding) out2 = f(np_arr) cache_info2 = pjit_lib._pjit_lower_cached.cache_info() self.assertIsInstance(out2.sharding, NamedSharding) # Drops out of C++ cache i.e. cache miss self.assertEqual(count[0], 2) # Still gets a hit on pjit_lower cache. self.assertEqual(cache_info2.hits, cache_info1.hits + 1) self.assertEqual(cache_info2.misses, cache_info1.misses) def test_list_in_pspec(self): mesh = jtu.create_global_mesh((2,), ('x',)) with mesh: out = with_sharding_constraint(jnp.arange(8), P(['x'])) self.assertEqual(out.sharding, NamedSharding(mesh, P('x'))) def test_sharding_preserved_trivial(self): mesh = jtu.create_global_mesh((2, 1), ('x', 'y')) ns = NamedSharding(mesh, P('x')) ps = PositionalSharding(jax.devices()[:2]).reshape(2, 1) arr = jax.device_put(np.arange(8).reshape(8, 1), ns) arr2 = jax.device_put(np.arange(8).reshape(8, 1), ps) def identity(x): return x out = pjit(identity)(arr) self.assertIsInstance(out.sharding, NamedSharding) out2 = pjit(identity)(arr2) self.assertIsInstance(out2.sharding, PositionalSharding) def test_sharding_preserved_aot(self): mesh = jtu.create_global_mesh((2, 1), ('x', 'y')) ns = NamedSharding(mesh, P('x')) ps = PositionalSharding(jax.devices()[:2]).reshape(2, 1) arr = jax.device_put(np.arange(8).reshape(8, 1), ns) arr2 = jax.device_put(np.arange(8).reshape(8, 1), ps) compiled = pjit(lambda x: x * 2).lower(arr).compile() out = compiled(arr) self.assertIsInstance(out.sharding, NamedSharding) out2 = compiled(arr2) # The sharding won't be PositionalSharding since the pjit was already # Compiled which bakes in the output sharding. self.assertIsInstance(out2.sharding, NamedSharding) def test_sharding_on_output_with_vmap(self): mesh = jtu.create_global_mesh((2, 1), ('x', 'y')) ns = NamedSharding(mesh, P('x')) arr = jax.device_put( np.arange(16).reshape(8, 2), NamedSharding(mesh, P(None, 'x'))) with jtu.count_jit_and_pmap_compiles() as count: vf = jax.vmap(pjit(lambda x: x * 2, in_shardings=ns)) out = vf(arr) self.assertIsInstance(out.sharding, NamedSharding) out2 = vf(out) self.assertIsInstance(out2.sharding, NamedSharding) out3 = vf(out2) self.assertIsInstance(out3.sharding, NamedSharding) self.assertEqual(count[0], 1) def test_jit_mul_sum_sharding_preserved(self): mesh = jtu.create_global_mesh((2, 1), ('x', 'y')) ns = NamedSharding(mesh, P('x')) ps = PositionalSharding(jax.devices()[:2]).reshape(2, 1) arr = jax.device_put(np.arange(8).reshape(8, 1), ns) arr2 = jax.device_put(np.arange(8).reshape(8, 1), ps) f = jax.jit(lambda x: x * 2) out = f(arr) cache_info1 = pxla._cached_compilation.cache_info() pl_cache_info1 = pjit_lib._pjit_lower_cached.cache_info() self.assertIsInstance(out.sharding, NamedSharding) with jtu.count_pjit_cpp_cache_miss() as count: out2 = f(arr2) cache_info2 = pxla._cached_compilation.cache_info() pl_cache_info2 = pjit_lib._pjit_lower_cached.cache_info() self.assertIsInstance(out2.sharding, PositionalSharding) # This will hit the cpp cache. out3 = f(out2) self.assertIsInstance(out3.sharding, PositionalSharding) self.assertEqual(count[0], 1) self.assertEqual(cache_info2.hits, cache_info1.hits) self.assertEqual(cache_info2.misses, cache_info1.misses + 1) self.assertEqual(pl_cache_info2.hits, pl_cache_info1.hits) self.assertEqual(pl_cache_info2.misses, pl_cache_info1.misses + 1) out4 = jnp.sum(arr) self.assertIsInstance(out4.sharding, NamedSharding) def test_single_device_sharding_preserved(self): if jax.device_count() < 2: self.skipTest('Test requires >=2 devices') x = jnp.arange(8) # trivial computation out = jax.jit(lambda x: x)(x) self.assertIsInstance(out.sharding, SingleDeviceSharding) # trivial computation with committed inp y = jax.device_put(x, jax.devices()[1]) out2 = jax.jit(lambda x: x)(y) self.assertIsInstance(out2.sharding, SingleDeviceSharding) self.assertEqual(out2.devices(), {jax.devices()[1]}) out3 = jax.jit(lambda x: x * 2)(x) self.assertIsInstance(out3.sharding, SingleDeviceSharding) out4 = jax.jit(lambda x: x * 3, out_shardings=SingleDeviceSharding(jax.devices()[1]))(x) self.assertIsInstance(out4.sharding, SingleDeviceSharding) self.assertEqual(out4.devices(), {jax.devices()[1]}) def test_none_out_sharding(self): mesh = jtu.create_global_mesh((2, 1), ('x', 'y')) x = jnp.arange(8) with mesh: out = pjit(lambda x: x * 2, out_shardings=None)(x) self.assertEqual(out.sharding.mesh, mesh) self.assertIsInstance(out.sharding, NamedSharding) self.assertEqual(out.sharding.spec, P()) x2 = jax.device_put(x, NamedSharding(mesh, P())) out2 = pjit(lambda x: x * 2)(x2) self.assertIsInstance(out2.sharding, NamedSharding) self.assertEqual(out2.sharding.mesh, mesh) self.assertEqual(out2.sharding.spec, P()) def test_sharding_preserved_apply_primitive(self): mesh = jtu.create_global_mesh((2, 1), ('x', 'y')) ns = NamedSharding(mesh, P('x')) arr = jax.device_put(np.arange(8).reshape(8, 1), ns) out = jnp.copy(arr) self.assertIsInstance(out.sharding, NamedSharding) ps = PositionalSharding(jax.devices()[:2]).reshape(2, 1) arr2 = jax.device_put(np.arange(8).reshape(8, 1), ps) out2 = jnp.copy(arr2) self.assertIsInstance(out2.sharding, PositionalSharding) arr3 = jnp.arange(8) out3 = jnp.copy(arr3) self.assertIsInstance(out3.sharding, SingleDeviceSharding) arr4 = jax.device_put(jnp.arange(8), jax.devices()[1]) out4 = jnp.copy(arr4) self.assertIsInstance(out4.sharding, SingleDeviceSharding) self.assertEqual(out4.devices(), {jax.devices()[1]}) def test_same_named_sharding_pspec_on_eager_ops(self): mesh = jtu.create_global_mesh((1, 8, 1), ('x', 'y', 'z')) sharding = jax.sharding.NamedSharding(mesh, P('x', 'y', 'z')) x = jax.device_put(jnp.arange(32).reshape(1, -1, 1), sharding) y = x + 1 self.assertEqual(x.sharding, y.sharding) def test_different_named_sharding_object_replicated(self): mesh = jtu.create_global_mesh((1, 2), ('x', 'y')) sharding = jax.sharding.NamedSharding(mesh, P('x')) x = jax.device_put(np.arange(16).reshape(8, 2), sharding) y = jnp.sum(x) self.assertNotEqual(x.sharding, y.sharding) def test_vmap_pjit_single_device(self): with jtu.ignore_warning(category=DeprecationWarning, message="backend and device argument"): jf = pjit(lambda x: x, device=jax.devices()[0]) out = jax.vmap(jf)(jnp.ones((3,))) # doesn't crash self.assertIsInstance(out.sharding, SingleDeviceSharding) def test_to_gspmd_sharding_cache_with_and_without_device(self): mesh = jtu.create_global_mesh((2,), ('x',)) np_inp = jnp.arange(4) def identity(x): return x # Fill up the to_gspmd_sharding cache so that the next jit will miss it. out = jax.jit(identity, in_shardings=SingleDeviceSharding(jax.devices()[0]))(np_inp) self.assertEqual(out.devices(), {jax.devices()[0]}) self.assertArraysEqual(out, np_inp) with jtu.ignore_warning(category=DeprecationWarning, message="backend and device argument"): out2 = jax.jit(identity, device=jax.devices()[0])( jax.device_put(np_inp, NamedSharding(mesh, P('x')))) self.assertEqual(out2.devices(), {jax.devices()[0]}) self.assertArraysEqual(out2, np_inp) def test_jit_submhlo_cached(self): @jax.jit def nest(x): return x * 2 @jax.jit def top(x): y = nest(x) z = nest(y) a = nest(z) b = nest(a) return b with jtu.count_subjaxpr_to_hlo_conversion(fun_name='nest') as count: top(jnp.arange(8)) # The count should be 1 because `nest`'s lowering to MHLO should be cached. self.assertEqual(count[0], 1) def test_wsc_eager(self): mesh = jtu.create_global_mesh((2,), ('x',)) np_inp = np.arange(8) inp = jax.device_put(np_inp, NamedSharding(mesh, P())) out = with_sharding_constraint(inp, NamedSharding(mesh, P('x'))) self.assertArraysEqual(out, np_inp) self.assertEqual(out.sharding, NamedSharding(mesh, P('x'))) for s in out.addressable_shards: self.assertArraysEqual(s.data, np_inp[s.index]) def test_wsc_eager_no_resharding(self): mesh = jtu.create_global_mesh((2,), ('x',)) np_inp = np.arange(8) inp = jax.device_put(np_inp, NamedSharding(mesh, P('x'))) out = with_sharding_constraint(inp, NamedSharding(mesh, P('x'))) self.assertEqual(id(out), id(inp)) def test_wsc_eager_different_order_devices(self): mesh1 = jtu.create_global_mesh((2,), ('x',)) mesh2 = jax.sharding.Mesh([jax.devices()[1], jax.devices()[0]], 'x') inp = jax.device_put(np.arange(8), NamedSharding(mesh1, P())) with self.assertRaisesRegex( ValueError, "Received incompatible devices for jitted computation"): with_sharding_constraint(inp, NamedSharding(mesh2, P('x'))) def test_jaxpr_as_fun_fast_path(self): @jax.jit def f(x): return x * 2 inp = jax.device_put(jnp.arange(8), jax.devices()[0]) jaxpr = jax.make_jaxpr(f)(inp) with jtu.count_pjit_cpp_cache_miss() as count: out1 = core.jaxpr_as_fun(jaxpr)(inp) out2 = core.jaxpr_as_fun(jaxpr)(inp) self.assertEqual(count[0], 1) self.assertArraysEqual(out1[0], inp * 2) self.assertArraysEqual(out2[0], inp * 2) def test_most_recent_executable_outer_inner_cache(self): x = np.zeros((20, 20), dtype=jnp.float64) def trace_to_jaxpr(x): jnp.pad(x, [(0, 1), (0, 0)], mode= 'wrap') jnp.pad(x, [(0, 0), (1, 0)], mode= 'constant', constant_values= ((0.0, 0.0), (0.0, 0.0))) jaxpr = jax.make_jaxpr(trace_to_jaxpr)(x) jax.core.jaxpr_as_fun(jaxpr)(x) jnp.pad(x, [(0, 1), (0, 0)], mode= 'wrap') jnp.pad(x, [(0, 1), (0, 0)], mode= 'wrap') # doesn't crash def test_shape_dtype_struct_as_const_error(self): const = jax.ShapeDtypeStruct((8,), jnp.int32) with self.assertRaisesRegex(TypeError, r"Argument.*is not a valid JAX type"): jax.jit(lambda x: (x, const))(jnp.arange(8)) def test_jit_out_shardings_none(self): mesh = jtu.create_global_mesh((4, 2), ('x', 'y')) np_inp = np.arange(16).reshape(8, 2) s = NamedSharding(mesh, P('x', 'y')) inp = jax.device_put(np_inp, s) out = jax.jit(lambda x: x * 2, out_shardings=None)(inp) self.assertArraysEqual(out, np_inp * 2) self.assertEqual(out.sharding, s) def test_jit_in_shardings_none(self): mesh = jtu.create_global_mesh((4, 2), ('x', 'y')) np_inp = np.arange(16).reshape(8, 2) s = NamedSharding(mesh, P('x', 'y')) inp = jax.device_put(np_inp, s) out = jax.jit(lambda x: x * 2, in_shardings=None)(inp) self.assertArraysEqual(out, np_inp * 2) self.assertEqual(out.sharding, s) out2 = jax.jit(lambda x: x * 2, in_shardings=None)(np_inp) self.assertArraysEqual(out2, np_inp * 2) self.assertEqual(out2.sharding, SingleDeviceSharding(jax.devices()[0])) def test_jit_both_shardings_none(self): mesh = jtu.create_global_mesh((4, 2), ('x', 'y')) np_inp = np.arange(16).reshape(8, 2) s = NamedSharding(mesh, P('x', 'y')) inp = jax.device_put(np_inp, s) out = jax.jit(lambda x: x * 2, in_shardings=None, out_shardings=None)(inp) self.assertArraysEqual(out, np_inp * 2) self.assertEqual(out.sharding, s) out2 = jax.jit(lambda x: x * 2, in_shardings=None, out_shardings=None)(np_inp) self.assertArraysEqual(out2, np_inp * 2) self.assertEqual(out2.sharding, SingleDeviceSharding(jax.devices()[0])) def test_jit_lower_shape_dtype_struct_sharding_none(self): mesh = jtu.create_global_mesh((4, 2), ('x', 'y')) s = NamedSharding(mesh, P('x', 'y')) lower_inp1 = jax.ShapeDtypeStruct((8, 2), np.int32, sharding=s) # Will be considered as uncommitted and resharded over all the devices of # the mesh. lower_inp2 = jax.ShapeDtypeStruct((8, 2), np.int32) compiled = jax.jit(lambda x, y: (x * 2, y * 2)).lower( lower_inp1, lower_inp2).compile() np_inp = np.arange(16, dtype=np.int32).reshape(8, 2) inp = jax.device_put(np_inp, s) out1, out2 = compiled(inp, np_inp) self.assertArraysEqual(out1, np_inp * 2) self.assertArraysEqual(out2, np_inp * 2) self.assertTupleEqual(out1.sharding._device_assignment, s.mesh._flat_devices_tuple) self.assertTupleEqual(out2.sharding._device_assignment, s.mesh._flat_devices_tuple) def test_vmap_spmd_axis_name_error(self): s = SingleDeviceSharding(jax.devices()[0]) def f(inp): return with_sharding_constraint(inp, s) arr = jax.device_put(np.arange(8), s) with self.assertRaisesRegex( ValueError, 'If you are using spmd_axis_name parameter of jax.vmap, please' ' make sure to run your jitted function inside the mesh context' ' manager.*SingleDeviceSharding'): jax.jit(jax.vmap(f, spmd_axis_name='x'))(arr) def test_no_output_multiple_devices(self): mesh = jtu.create_global_mesh((2,), ('x',)) @pjit def f(): return with mesh: f() # doesn't crash def test_lowering_cache_hit_different_devices(self): if jax.device_count() < 4: self.skipTest('Requires >=4 devices') mesh1 = jax.sharding.Mesh(jax.devices()[:2], 'x') mesh2 = jax.sharding.Mesh(jax.devices()[2:4], 'x') @jax.jit def f(x): return x * 2 def g(a): a = jax.device_put(a, NamedSharding(mesh1, P('x'))) out_a = f(a) # lowering cached # same num_devices but different devices. b = jax.device_put(out_a, NamedSharding(mesh2, P('x'))) f(b) # lowering cache *hit* with jtu.count_jit_and_pmap_compiles() as count: g(np.arange(8)) self.assertEqual(count[0], 1) def test_lowering_cache_miss_different_devices_and_sharding(self): if jax.device_count() < 4: self.skipTest('Requires >=4 devices') mesh1 = jax.sharding.Mesh(jax.devices()[:2], 'x') mesh2 = jax.sharding.Mesh(jax.devices()[2:4], 'y') @jax.jit def f(x): return x * 2 def g(a): a = jax.device_put(a, NamedSharding(mesh1, P('x'))) out_a = f(a) # lowering cached # same num_devices but different devices and sharding b = jax.device_put(out_a, NamedSharding(mesh2, P())) f(b) # lowering cache *miss* with jtu.count_jit_and_pmap_compiles() as count: g(np.arange(8)) self.assertEqual(count[0], 2) def test_single_device_named_sharding_preserved(self): mesh = jax.sharding.Mesh([jax.devices()[0]], 'x') s = NamedSharding(mesh, P('x')) np_inp = np.arange(8) inp = jax.device_put(np_inp, s) out = jax.jit(lambda x: x)(inp) self.assertEqual(out.sharding, s) self.assertArraysEqual(out, np_inp) def test_mpmd_device_put_fast_path(self): if jax.device_count() < 4: self.skipTest('Needs >= 4 devices') dev_count = jax.device_count() mesh1 = jax.sharding.Mesh(jax.devices()[:dev_count//2], 'x') mesh2 = jax.sharding.Mesh(jax.devices()[dev_count//2:], 'x') inp = np.arange(8) arr1 = jax.device_put(inp, NamedSharding(mesh1, P('x'))) # This is to prevent changes to shard_arg_handler of Array which checks for # indices to take the fast path for resharding. Changes made to the handler # to check for shardings instead of indices will cause this test to fail and # that is expected. with jtu.count_device_put_fast_path_hit() as count: out = jax.device_put(arr1, NamedSharding(mesh2, P('x'))) self.assertEqual(count[0], 1) self.assertTupleEqual(out.sharding._device_assignment, mesh2._flat_devices_tuple) self.assertArraysEqual(out, inp) def test_prng_sharding_propagation(self): input_shape = (8, 2) mesh = jtu.create_global_mesh((4, 2), ('x', 'y')) spec = P('x', 'y') seeds, _ = create_array(input_shape, mesh, spec, dtype=np.uint32) @jax.jit def make_keys(seeds): make_key = partial(prng.random_seed, impl=prng.threefry_prng_impl) key = make_key(seeds) return key.T out = make_keys(seeds) self.assertEqual(out.sharding, NamedSharding(mesh, P('y', 'x'))) base_array = jax.random.key_data(out) self.assertEqual(base_array.shape, (2, 8, 2)) self.assertEqual(base_array.sharding, NamedSharding(mesh, P('y', 'x', None))) lowered_text = make_keys.lower(seeds).as_text() self.assertIn('unspecified_dims=[0,1]', lowered_text) def test_prng_sharding_propagation_with_nested_jit(self): input_shape = (8, 2) mesh = jtu.create_global_mesh((4, 2), ('x', 'y')) spec = P('x', 'y') seeds, _ = create_array(input_shape, mesh, spec, dtype=np.uint32) @jax.jit def make_keys(seeds): @partial(jax.jit, out_shardings=NamedSharding(mesh, P('y'))) def f(): make_key = partial(prng.random_seed, impl=prng.threefry_prng_impl) return make_key(seeds) x = f() return x.T out = make_keys(seeds) self.assertEqual(out.sharding, NamedSharding(mesh, P(None, 'y'))) base_array = jax.random.key_data(out) self.assertEqual(base_array.shape, (2, 8, 2)) self.assertEqual(base_array.sharding, NamedSharding(mesh, P(None, 'y', None))) lowered_text = make_keys.lower(seeds).as_text() self.assertIn('unspecified_dims=[0,1]', lowered_text) def test_partial_sharded_prng_key_inp(self): input_shape = (8, 2, 2) mesh = jtu.create_global_mesh((2, 2, 2), ('x', 'y', 'z')) spec = P('x', 'y', None) seeds, _ = create_array(input_shape, mesh, spec, dtype=np.uint32) @jax.jit def make_keys(seeds): make_key = partial(prng.random_seed, impl=prng.threefry_prng_impl) key = make_key(seeds) return key.T make_keys(seeds) out = make_keys(seeds) # cpp dispatch self.assertEqual(out.sharding, NamedSharding(mesh, P(None, 'y', 'x'))) base_array = jax.random.key_data(out) self.assertEqual(base_array.shape, (2, 2, 8, 2)) self.assertEqual(base_array.sharding, NamedSharding(mesh, P(None, 'y', 'x'))) lowered_text = make_keys.lower(seeds).as_text() self.assertIn('unspecified_dims=[0,1,2]', lowered_text) def test_jit_partially_specified_shardings(self): mesh = jtu.create_global_mesh((2, 2), ('x', 'y')) np_inp = np.arange(16).reshape(8, 2) s = NamedSharding(mesh, P('x', 'y')) s2 = NamedSharding(mesh, P('x')) arr = jax.device_put(np_inp, s) arr2 = jax.device_put(np_inp, s2) @partial(jax.jit, in_shardings=(s, None, s2, UNSPECIFIED, UNSPECIFIED), out_shardings=(s2, None, None, s, None)) def f(x, y, z, a, b): return x * 2, y @ y.T, z ** 2, a * 3, b.T out1, out2, out3, out4, out5 = f(arr, np_inp, arr2, np_inp, arr) self.assertArraysEqual(out1, np_inp * 2) self.assertArraysEqual(out2, np_inp @ np_inp.T) self.assertArraysEqual(out3, np_inp ** 2) self.assertArraysEqual(out4, np_inp * 3) self.assertArraysEqual(out5, np_inp.T) def test_input_shardings_aot(self): mesh = jtu.create_global_mesh((2, 1), ('x', 'y')) np_inp = np.arange(16).reshape(8, 2) arr = jax.device_put(np_inp, NamedSharding(mesh, P('x'))) @jax.jit def f(x, y): return x * 2, y.T arg_shardings, _ = f.lower(arr, np_inp).compile().input_shardings for s in arg_shardings: self.assertIsInstance(s, NamedSharding) def test_parameter_tupled_jit(self): if not jtu.test_device_matches(["tpu"]): self.skipTest('Parameters are tupled only on TPU if >2000 parameters') mesh = jtu.create_global_mesh((2, 2), ('x', 'y')) s = NamedSharding(mesh, P('x')) @jax.jit def f(*args): return args * 2 inp = np.arange(8) arr = jax.device_put(inp, s) inps = [arr, *[inp] * 2001] f(inps) # doesn't crash def test_spmd_preserves_input_sharding_vmap_grad(self): # https://github.com/google/jax/issues/20710 n_devices = jax.device_count() sharding = PositionalSharding(jax.devices()) def model(params, x): return x @ params feature_dim = 3 batch_size_total = 8 # Get example data x = jnp.ones((batch_size_total, feature_dim)) params = jnp.ones(feature_dim) # Shard data, replicate params x = jax.device_put(x, sharding.reshape(n_devices, 1)) params = jax.device_put(params, sharding.replicate(axis=0)) model(params, x) # doesn't crash jax.vmap(model, in_axes=(None, 0))(params, x) # doesn't crash jax.grad(lambda p: model(p, x).sum())(params) # doesn't crash jax.vmap(jax.grad(model), in_axes=(None, 0))(params, x) # doesn't crash def test_jit_token_input(self): x = jnp.arange(8) token = jax.lax.create_token(None) device = jax.devices()[0] x = jax.device_put(x, device=device) out1, out2 = jax.jit(lambda x, t: (x, t))(x, token) self.assertArraysEqual(out1, x) self.assertIsInstance(out2, core.Token) def test_uneven_sharding_wsc(self): mesh = jtu.create_global_mesh( (2, 1, 1, 1, 1), ('data', 'expert', 'fsdp', 'seq', 'model') ) @jax.jit def fn(key): x = jnp.arange(113003) x = with_sharding_constraint(x, P('data')) y = jnp.arange(65536) y = with_sharding_constraint(y.reshape(-1), P('data')) z = jnp.concatenate([x, y], axis=0) z = with_sharding_constraint(z, P('data')) return x, y, z with mesh: x, y, z = fn(jax.random.key(42)) expected_x = np.arange(113003) expected_y = np.arange(65536) expected_z = np.concatenate([x, y], axis=0) self.assertArraysEqual(expected_x.max(), x.max()) self.assertArraysEqual(expected_y.max(), y.max()) self.assertArraysEqual(expected_z.max(), z.max()) def test_threefry_partitionable_context_within_jit(self): with jax.threefry_partitionable(False): def f(x): return x + jax.random.randint(jax.random.key(72), (), 0, 10) def g(x): with jax.threefry_partitionable(True): # False by default return x + jax.random.randint(jax.random.key(72), (), 0, 10) h = jax.jit(g) self.assertNotEqual(f(1), g(1)) self.assertEqual(g(1), h(1)) def test_wsc_vmap_unconstrained_spmd_axis_name(self): def get_wsc_eqn_sharding(jaxpr): for eqn in jaxpr.eqns: if str(eqn.primitive) == 'sharding_constraint': return eqn.params['sharding'], eqn.params['unconstrained_dims'] for s in core.subjaxprs(jaxpr): return get_wsc_eqn_sharding(s) mesh = jtu.create_global_mesh((2, 1), ('x', 'y')) inp = jnp.ones((10, 10)) def a_function(x): return with_sharding_constraint(x, NamedSharding(mesh, P(P.UNCONSTRAINED))) def vmap_the_function_spmd(y): return jax.vmap(a_function, spmd_axis_name='x')(y) f1 = jax.jit(vmap_the_function_spmd) f1(inp) # doesn't crash jaxpr1 = jax.make_jaxpr(f1)(inp) s1, u1 = get_wsc_eqn_sharding(jaxpr1) self.assertEqual(s1.spec, P('x', P.UNCONSTRAINED)) self.assertEqual(u1, {1}) def vmap_the_function_no_spmd(y): return jax.vmap(a_function)(y) f2 = jax.jit(vmap_the_function_no_spmd) f2(inp) # doesn't crash jaxpr2 = jax.make_jaxpr(f2)(inp) s2, u2 = get_wsc_eqn_sharding(jaxpr2) self.assertEqual(s2.spec, P(P.UNCONSTRAINED, P.UNCONSTRAINED)) self.assertEqual(u2, {0, 1}) def test_aot_sharding_dce(self): inp = np.arange(8) @jax.jit def f(x, y): return x input_shardings, _ = f.lower(inp, inp).compile().input_shardings self.assertLen(input_shardings, 2) def test_aot_out_info(self): inp = np.arange(8, dtype=np.int32) out_info = jax.jit(lambda x: x).lower((inp, inp)).out_info self.assertEqual(out_info[0].shape, (8,)) self.assertEqual(out_info[1].shape, (8,)) self.assertEqual(out_info[0].dtype, np.int32) self.assertEqual(out_info[1].dtype, np.int32) self.assertEqual(out_info[0].sharding, None) self.assertEqual(out_info[1].sharding, None) def test_jit_trace(self): def f(x): return x * 2 traced = jax.jit(f).trace(jnp.arange(8, dtype=jnp.int32)) self.assertLen(traced.jaxpr.eqns, 1) self.assertEqual(jax.tree.structure(traced.out_info).num_leaves, 1) self.assertEqual(traced.out_info.shape, (8,)) self.assertEqual(traced.out_info.dtype, jnp.int32) # one for args, one for kwargs (though kwargs is empty) self.assertLen(traced.in_avals, 2) self.assertLen(traced.in_avals[0], 1) self.assertLen(traced.in_avals[1], 0) # empty kwarg def test_jit_trace_lower_and_compile(self): def f(x): return x * 2 lowered = jax.jit(f).trace(jnp.arange(8)).lower() self.assertEqual(lowered.args_info[0][0].shape, (8,)) compiled = lowered.compile() out = compiled(jnp.arange(8)) self.assertArraysEqual(out, np.arange(8) * 2) # fast-forward lowered2 = jax.jit(f).lower(jnp.arange(8)) self.assertEqual(lowered2.args_info[0][0].shape, (8,)) compiled2 = lowered2.compile() out2 = compiled2(jnp.arange(8)) self.assertArraysEqual(out2, np.arange(8) * 2) def test_device_put_efficient_reshard_single_host(self): if jax.device_count() < 4: self.skipTest('Requires >= 4 devices') dev = jax.devices() mesh1 = Mesh(np.array([dev[0], dev[1], dev[2], dev[3]]).reshape(2, 2), ('x', 'y')) mesh2 = Mesh(np.array([dev[3], dev[2], dev[1], dev[0]]).reshape(2, 2), ('x', 'y')) np_inp = np.arange(16).reshape(8, 2) s1 = NamedSharding(mesh1, P('x', 'y')) s2 = NamedSharding(mesh2, P('x')) x_s1 = jax.device_put(np_inp, s1) with jax.transfer_guard('disallow_explicit'): out = jax.device_put(x_s1, s2) self.assertArraysEqual(out, np_inp) self.assertEqual(out.sharding, s2) @parameterized.named_parameters( ("8_2", (8, 2)), ("8_384", (8, 384)), ) def test_device_put_efficient_reshard_complex_mesh(self, shape): if jax.device_count() < 8: self.skipTest('Requires >= 8 devices') dev = jax.devices() mesh1 = jax.sharding.Mesh( np.asarray(dev).reshape([1, 2, 2, 2]), ('replica', 'data', 'seq', 'model')) mesh2 = jax.sharding.Mesh( np.asarray(jax.devices()) .reshape([1, 1, 2, 2, 2, 1]) .swapaxes(2, 3) .reshape([1, 1, 4, 2, 1]), ('replica', 'data', 'seq', 'model_q', 'model_kv')) np_inp = jnp.arange(math.prod(shape)).reshape(shape) s1 = NamedSharding(mesh1, P('model')) s2 = NamedSharding(mesh2, P()) x_s1 = jax.device_put(np_inp, s1) # Reshard! out = jax.device_put(x_s1, s2) self.assertArraysEqual(out, np_inp) self.assertEqual(out.sharding, s2) del out s3 = NamedSharding(mesh2, P('model_q')) x_s3 = jax.device_put(np_inp, s3) # Reshard to iota device assignment! out2 = jax.device_put(x_s3, s1) self.assertArraysEqual(out2, np_inp) self.assertEqual(out2.sharding, s1) def test_convert_element_type_sharding(self): mesh = jtu.create_global_mesh((2, 2), ('x', 'y')) s = NamedSharding(mesh, P('x', 'y')) inp = np.arange(16).reshape(8, 2) out = lax_internal._convert_element_type( inp, new_dtype=np.float32, weak_type=False, sharding=s) self.assertArraysEqual(out, inp.astype('float32')) self.assertEqual(out.dtype, np.float32) self.assertEqual(out.sharding, s) def test_jnp_array_sharding(self): mesh = jtu.create_global_mesh((2, 2), ('x', 'y')) s = NamedSharding(mesh, P('x', 'y')) inp = np.arange(16).reshape(8, 2) out = jnp.array(inp, device=s) self.assertArraysEqual(out, inp) self.assertEqual(out.sharding, s) def test_jnp_array_inside_jit_sharding(self): mesh = jtu.create_global_mesh((2, 2), ('x', 'y')) s = NamedSharding(mesh, P('x', 'y')) inp = np.arange(16).reshape(8, 2) @jax.jit def f(): return jnp.array(inp, dtype=np.float32, device=s) out = f() print(f.trace().jaxpr) self.assertArraysEqual(out, inp.astype('float32')) self.assertEqual(out.sharding, s) self.assertEqual(out.dtype, np.float32) @jax.jit def g(x): return jnp.array(x, dtype=np.float32, device=s) out2 = g(inp) self.assertArraysEqual(out2, inp.astype('float32')) self.assertEqual(out2.sharding, s) self.assertEqual(out2.dtype, np.float32) def test_jnp_array_reshard_error(self): if jax.device_count() < 2: self.skipTest('Requires >=2 devices') arr = jax.device_put(np.arange(8), jax.devices()[0]) with self.assertRaisesRegex(ValueError, "Received incompatible devices.*"): jnp.array(arr, device=jax.devices()[1]) def test_jnp_array_sharded_array_no_op(self): inp = np.arange(16).reshape(8, 2) arr = jax.device_put(inp, jax.devices()[0]) out = lax_internal._convert_element_type( arr, sharding=SingleDeviceSharding(jax.devices()[0])) self.assertArraysEqual(out, inp) self.assertEqual(out.unsafe_buffer_pointer(), arr.unsafe_buffer_pointer()) def test_wsc_named_sharding_nullary(self): mesh = jtu.create_global_mesh((2,), ('x',)) s = NamedSharding(mesh, P()) @jax.jit def f(): return jax.lax.with_sharding_constraint(jnp.arange(8), s) out = f() self.assertEqual(out.sharding, s) @jtu.run_on_devices('tpu', 'gpu') def test_aot_device_mismatch(self): mesh = jtu.create_global_mesh((1,), 'x') np_inp = np.arange(8) arr = jax.device_put(np_inp, NamedSharding(mesh, P())) @jax.jit def f(x): return x * 2 compiled = f.lower(arr).compile() cpu_arr = jax.device_put(np_inp, jax.devices('cpu')[0]) with self.assertRaisesRegex( ValueError, "Compiled object called with input sharding.*does not match"): compiled(cpu_arr) def spec_regex(s): return str(s).replace(r"(", r"\(").replace(r")", r"\)") @jtu.pytest_mark_if_available('multiaccelerator') class PJitErrorTest(jtu.JaxTestCase): @check_1d_2d_mesh(set_mesh=True) def testNonDivisibleArgs(self, mesh, resources): x = jnp.ones((3, 2)) spec = P(resources, None) mesh_size = str(math.prod([dim[1] for dim in mesh])) error = re.compile( r"One of pjit arguments with pytree key path x.*" + spec_regex(spec) + r".*" r"implies that the global size of its dimension 0 should be " r"divisible by " + mesh_size + r", but it is equal to 3 " r"\(full shape: \(3, 2\)\)", re.M | re.S) with self.assertRaisesRegex(ValueError, error): pjit(lambda x: x, in_shardings=spec, out_shardings=None)(x) @check_1d_2d_mesh(set_mesh=True) def testNonDivisibleOuts(self, mesh, resources): x = jnp.ones((3, 2)) spec = P(resources, None) mesh_size = str(math.prod([dim[1] for dim in mesh])) error = re.compile( r"One of pjit outputs with pytree key path \['rrr'\].*" + spec_regex(spec) + r".*" r"implies that the global size of its dimension 0 should be " r"divisible by " + mesh_size + r", but it is equal to 3", re.M | re.S) with self.assertRaisesRegex(ValueError, error): pjit(lambda x: {'rrr': x}, in_shardings=None, out_shardings=P(resources, None))(x) @check_1d_2d_mesh(set_mesh=False) @jtu.with_mesh([('z', 1)]) def testUndefinedResourcesArgs(self, mesh, resources): x = jnp.ones((2, 2)) spec = P(resources,) with self.assertRaisesRegex( ValueError, r"Resource axis: x of.*" + spec_regex(spec) + " is undefined"): pjit(lambda x: x, in_shardings=spec, out_shardings=None)(x) @check_1d_2d_mesh(set_mesh=False) @jtu.with_mesh([('z', 1)]) def testUndefinedResourcesOuts(self, mesh, resources): x = jnp.ones((2, 2)) spec = P(resources,) with self.assertRaisesRegex( ValueError, r"Resource axis: x of.*" + spec_regex(spec) + " is undefined"): pjit(lambda x: x, in_shardings=None, out_shardings=spec)(x) @check_1d_2d_mesh(set_mesh=False) @jtu.with_mesh([('z', 1)]) def testUndefinedResourcesConstraint(self, mesh, resources): x = jnp.ones((2, 2)) spec = P(resources,) with self.assertRaisesRegex( ValueError, r"Resource axis: x of.*" + spec_regex(spec) + " is undefined"): pjit( lambda x: with_sharding_constraint(x, spec), in_shardings=None, out_shardings=None, )(x) @jtu.with_mesh([('x', 2), ('y', 1)]) def testRankTooLowArgs(self): x = jnp.arange(2) spec = P('x', 'y') error = re.compile( r"One of pjit arguments.*" + spec_regex(spec) + r".*rank at least 2, but was applied to a value of rank 1", re.M | re.S) with self.assertRaisesRegex(ValueError, error): pjit(lambda x: x.sum(), in_shardings=spec, out_shardings=None)(x) @jtu.with_mesh([('x', 2), ('y', 1)]) def testRankTooLowArgsAxisResourcesNone(self): x = jnp.arange(2) spec = P(None, None) error = re.compile( r"One of pjit arguments.*" + spec_regex(spec) + r".*rank at least 2, but was applied to a value of rank 1", re.M | re.S) with self.assertRaisesRegex(ValueError, error): pjit(lambda x: x.sum(), in_shardings=spec, out_shardings=None)(x) @jtu.with_mesh([('x', 2), ('y', 1)]) def testRankTooLowOuts(self): x = jnp.arange(2) spec = P('x', 'y') error = re.compile( r"One of pjit outputs.*" + spec_regex(spec) + r".*rank at least 2, but was applied to a value of rank 0", re.M | re.S) with self.assertRaisesRegex(ValueError, error): pjit(lambda x: x.sum(), in_shardings=None, out_shardings=spec)(x) @jtu.with_mesh([('x', 2), ('y', 1)]) def testRankTooLowConstraint(self): x = jnp.arange(2) spec = P('x', 'y') error = re.compile( r"One of with_sharding_constraint arguments" + r".*" + spec_regex(spec) + r".*rank at least 2, but was applied to a value of rank 1", re.M | re.S) with self.assertRaisesRegex(ValueError, error): pjit( lambda x: with_sharding_constraint(x, spec), in_shardings=None, out_shardings=None, )(x) @jtu.with_mesh([('x', 2), ('y', 1)]) def testRepeatedInResources(self): x = jnp.arange(2) for spec in [P('x', 'x'), P('x', ('y', 'x'))]: error = (r"A single in_shardings specification can map every mesh " r"axis to at most one positional dimension, but " + spec_regex(spec) + " has duplicate entries for `x`") with self.assertRaisesRegex(ValueError, error): pjit(lambda x: x, in_shardings=spec, out_shardings=None)(x) @jtu.with_mesh([('x', 2), ('y', 1)]) def testRepeatedOutResources(self): x = jnp.arange(2) for spec in [P('x', 'x'), P('x', ('y', 'x'))]: error = (r"A single out_shardings specification can map every mesh " r"axis to at most one positional dimension, but " + spec_regex(spec) + " has duplicate entries for `x`") with self.assertRaisesRegex(ValueError, error): pjit(lambda x: x, in_shardings=None, out_shardings=spec)(x) def testEmptyMesh(self): out = pjit(lambda x: x, in_shardings=None, out_shardings=None)(jnp.arange(4)) self.assertEqual(out.sharding, SingleDeviceSharding(jax.devices()[0])) def test_pspec_to_wsc_without_mesh(self): error = ( r'with_sharding_constraint requires a non-empty mesh if you are ' r'passing `PartitionSpec`s or `None` to shardings.*') with self.assertRaisesRegex(RuntimeError, error): pjit(lambda x: with_sharding_constraint(x, P('x')))(jnp.arange(4)) @jtu.with_mesh([('x', 2)]) def testAxisResourcesMismatch(self): x = jnp.ones([]) p = [None, None, None] pjit(lambda x: x, (p,), p)([x, x, x]) # OK error = re.escape( "pjit in_shardings specification must be a tree prefix of the " "positional arguments tuple passed to the `pjit`-decorated function. " "In particular, pjit in_shardings must either be a None, a " "PartitionSpec, or a tuple of length equal to the number of positional " "arguments. But pjit in_shardings is the wrong length: got a " "tuple or list of length 3 for an args tuple of length 2.") with self.assertRaisesRegex(ValueError, error): pjit(lambda x, y: x, p, p)(x, x) Foo = namedtuple('Foo', ['x']) error = "in_shardings is not a tuple.*might need to be wrapped" with self.assertRaisesRegex(ValueError, error): pjit(lambda x: x, Foo(None), Foo(None))(Foo(x)) pjit(lambda x: x, (Foo(None),), Foo(None))(Foo(x)) # OK w/ singleton tuple # TODO(apaszke,mattjj): Disable implicit list casts and enable this # error = ("it looks like pjit in_axis_resources might need to be wrapped in " # "a singleton tuple.") # with self.assertRaisesRegex(ValueError, error): # pjit(lambda x, y: x, p, p)([x, x, x]) # TODO(apaszke): Disable implicit list casts and enable this # error = re.escape( # r"pjit in_axis_resources specification must be a tree prefix of the " # r"corresponding value, got specification (None, None, None) for value " # r"tree PyTreeDef(([*, *, *],)). Note that pjit in_axis_resources that " # r"are non-trivial pytrees should always be wrapped in a tuple representing " # r"the argument list. In particular, you're passing in a single argument " # r"which means that pjit in_axis_resources might need to be wrapped in a " # r"singleton tuple.") # with self.assertRaisesRegex(ValueError, error): # pjit(lambda x: x, p, p)([x, x, x]) # Error, but make sure we hint at singleton tuple error = re.escape( "pytree structure error: different lengths of list at " "key path\n" " pjit out_shardings\n") with self.assertRaisesRegex(ValueError, error): pjit(lambda x: x, (p,), [p, None])([x, x, x]) # Error, we raise a generic tree mismatch message @jtu.with_mesh([('x', 2)]) def testNestedDifferentResources(self): @partial(pjit, in_shardings=P('x'), out_shardings=None) def f(x): with jax.sharding.Mesh(np.array([jax.local_devices()[0]]), ('x')): @partial(pjit, in_shardings=P('x'), out_shardings=None) def h(x): return x return h(x) xshape = (2, 5, 6) x = jnp.arange(math.prod(xshape)).reshape(xshape) with self.assertRaisesRegex( ValueError, "Received incompatible devices for pjitted computation.*"): f(x) @parameterized.named_parameters( ("committed", True), ("uncommitted", False), ) def test_pjit_with_deleted_input_at_first_call(self, committed): shape = (8,) mesh = jtu.create_global_mesh((1,), ('x',)) inp_data = np.arange(math.prod(shape)).reshape(shape) if committed: s = NamedSharding(mesh, P('x',)) x = jax.device_put(inp_data, s) else: x = jax.device_put(inp_data) f = pjit(lambda x: x + 1) with self.assertRaisesRegex(RuntimeError, 'Array has been deleted.'): x.delete() _ = f(x) @parameterized.named_parameters( ("committed", True), ("uncommitted", False), ) def test_pjit_with_deleted_input_at_subsequent_call(self, committed): shape = (8,) mesh = jtu.create_global_mesh((1,), ('x',)) inp_data = np.arange(math.prod(shape)).reshape(shape) if committed: s = NamedSharding(mesh, P('x',)) x = jax.device_put(inp_data, s) else: x = jax.device_put(inp_data) f = pjit(lambda x: x + 1) _ = f(x) with self.assertRaisesRegex((RuntimeError, ValueError), '.*(Array|buffer|Buffer) has been deleted.*'): x.delete() _ = f(x) def test_aot_error_on_dced_avals_mismatch(self): x, y1, y2 = jnp.ones(4), jnp.ones(4), jnp.ones(1) @jax.jit def f(x, y): return x + 1 if y.shape[0] > 2 else x + 2 f_out1 = f(x, y1) f(x, y2) g = f.lower(x, y1).compile() g_out1 = g(x, y1) self.assertArraysEqual(f_out1, g_out1) with self.assertRaisesRegex( TypeError, 'Argument types differ from the types for which this computation was' ' compiled'): g(x, y2) def test_dce_no_array(self): mesh = jtu.create_global_mesh((2,), ('x',)) arr = jax.device_put(np.arange(8.), NamedSharding(mesh, P('x'))) @jax.jit def f(a, b, c): return a, c f(arr, 2., 3.) f(arr, 2., 3.) # doesn't crash @jtu.pytest_mark_if_available('multiaccelerator') class UtilTest(jtu.JaxTestCase): def testOpShardingRoundTrip(self): FakeDevice = namedtuple('FakeDevice', ['id']) mesh_named_shape = OrderedDict([('a', 2), ('b', 3), ('c', 4), ('d', 7), ('e', 4)]) mesh_axes, mesh_shape = unzip2(mesh_named_shape.items()) devices = [FakeDevice(i) for i in range(math.prod(mesh_shape))] mesh = pxla.Mesh(np.array(devices).reshape(*mesh_shape), tuple(mesh_axes)) dims = 5 aval = core.ShapedArray((len(devices),) * dims, jnp.float32) def roundtrip(spec): hlo_sharding = NamedSharding(mesh, spec)._to_xla_hlo_sharding(aval.ndim) parsed_spec = parse_flatten_op_sharding(hlo_sharding, mesh)[0].partitions self.assertEqual(parsed_spec[:len(spec)], spec) self.assertEqual(parsed_spec[len(spec):], ((),) * (len(parsed_spec) - len(spec))) special_specs = [P()] for spec in special_specs: roundtrip(spec) rng = self.rng() for i in range(100): spec = [()] * dims for axis in rng.permutation(mesh_axes)[:rng.randint(low=1, high=len(mesh_axes) + 1)]: spec[rng.choice(dims)] += (axis,) while spec and spec[-1] == (): spec.pop() roundtrip(P(*spec)) @parameterized.named_parameters( ("linear", {'x': 0, 'y': 1, 'z': 2}, P('x', 'y', 'z')), ("combine", {'x': 0, 'y': 0, 'z': 1}, P(('x', 'y'), 'z')), ("skip", {'x': 0, 'y': 0, 'z': 2}, P(('x', 'y'), None, 'z')), ("multi_skip", {'x': 0, 'y': 1, 'z': 3}, P('x', 'y', None, 'z')), ) def test_array_mapping_to_axis_resources(self, inp, expected_out): self.assertEqual( sharding_impls.array_mapping_to_axis_resources(inp), expected_out ) def test_op_sharding_equality_and_hash_equality(self): op1 = xc.OpSharding() op1.type = xc.OpSharding.Type.OTHER op1.tile_assignment_dimensions = [2, 2] op1.tile_assignment_devices = [0, 1, 2, 3] op2 = xc.OpSharding() op2.type = xc.OpSharding.Type.OTHER op2.tile_assignment_dimensions = [2, 2] op2.tile_assignment_devices = [0, 1, 2, 3] op3 = xc.OpSharding() op3.type = xc.OpSharding.Type.OTHER op3.tile_assignment_dimensions = [4, 2] op3.tile_assignment_devices = [0, 1, 2, 3, 4, 5, 6, 7] self.assertTrue(op_shardings.are_op_shardings_equal(op1, op2)) self.assertFalse(op_shardings.are_op_shardings_equal(op1, op3)) self.assertFalse(op_shardings.are_op_shardings_equal(op2, op3)) hs1 = xc.HloSharding.from_proto(op1) hs2 = xc.HloSharding.from_proto(op2) hs3 = xc.HloSharding.from_proto(op3) self.assertEqual(hs1, xc.HloSharding.iota_tile((2, 2))) self.assertEqual(hs2, xc.HloSharding.iota_tile((2, 2))) self.assertEqual(hs3, xc.HloSharding.iota_tile((4, 2))) self.assertEqual(hs1.num_devices(), 4) self.assertEqual(hs1.num_dimensions(), 2) self.assertEqual(hs1.tile_assignment_dimensions(), [2, 2]) self.assertEqual(hs1.tile_assignment_devices(), [0, 1, 2, 3]) self.assertTrue(hs1.is_tiled()) self.assertFalse(hs1.replicate_on_last_tile_dim()) self.assertEqual(hash(hs1), hash(hs2)) self.assertNotEqual(hash(hs1), hash(hs3)) self.assertNotEqual(hash(hs2), hash(hs3)) def test_op_sharding_partial_sharding(self): op1 = xc.OpSharding() op1.type = xc.OpSharding.Type.OTHER op1.tile_assignment_dimensions = [4, 1] op1.tile_assignment_devices = [0, 2, 1, 3] op1.last_tile_dims = [xc.OpSharding.Type.REPLICATED] op2 = xc.OpSharding() op2.type = xc.OpSharding.Type.OTHER op2.tile_assignment_dimensions = [4, 1] op2.tile_assignment_devices = [0, 2, 1, 3] op2.last_tile_dims = [xc.OpSharding.Type.REPLICATED] self.assertTrue(op_shardings.are_op_shardings_equal(op1, op2)) hs1 = xc.HloSharding.from_proto(op1) hs2 = xc.HloSharding.from_proto(op2) self.assertEqual( hs1, xc.HloSharding.iota_tile( (4, 1), reshape_dims=(2, 2), transpose_perm=(1, 0), subgroup_types=[xc.OpSharding.Type.REPLICATED], ), ) self.assertFalse(hs1.subgroup_types()) self.assertTrue(hs1.is_tiled()) self.assertEqual( hs2, xc.HloSharding.iota_tile( (4, 1), reshape_dims=(2, 2), transpose_perm=(1, 0), subgroup_types=[xc.OpSharding.Type.REPLICATED], ), ) self.assertFalse(hs2.subgroup_types()) self.assertTrue(hs2.is_tiled()) self.assertEqual(hash(hs1), hash(hs2)) def test_op_sharding_tuple_shardings(self): top1 = xc.OpSharding() top1.type = xc.OpSharding.Type.OTHER top1.tile_assignment_dimensions = [4, 1] top1.tile_assignment_devices = [0, 1, 2, 3] top1.replicate_on_last_tile_dim = True top2 = xc.OpSharding() top2.type = xc.OpSharding.Type.OTHER top2.tile_assignment_dimensions = [2, 2] top2.tile_assignment_devices = [0, 1, 2, 3] top2.replicate_on_last_tile_dim = True op1 = xc.OpSharding() op1.type = xc.OpSharding.Type.TUPLE op1.tuple_shardings = [top1, top2] op2 = xc.OpSharding() op2.type = xc.OpSharding.Type.TUPLE op2.tuple_shardings = [top2, top1] self.assertFalse(op_shardings.are_op_shardings_equal(op1, op2)) hs1 = xc.HloSharding.from_proto(op1) hs2 = xc.HloSharding.from_proto(op2) self.assertNotEqual(hash(hs1), hash(hs2)) def test_hlo_sharding_iota_tile_error(self): self.assertRaisesRegex( xla_extension.XlaRuntimeError, 'INVALID_ARGUMENT: `dims` should not be empty.', lambda: xc.HloSharding.iota_tile(()) ) self.assertRaisesRegex( xla_extension.XlaRuntimeError, 'INVALID_ARGUMENT: Cannot reshape from', lambda: xc.HloSharding.iota_tile( (2, 2), reshape_dims=(2, 4), transpose_perm=(1, 0), ), ) self.assertRaisesRegex( xla_extension.XlaRuntimeError, 'INVALID_ARGUMENT: `reshape_dims` and `transpose_perm` should have the' ' same size', lambda: xc.HloSharding.iota_tile( (2, 2), transpose_perm=(1, 0), ), ) self.assertRaisesWithLiteralMatch( xla_extension.XlaRuntimeError, 'INVALID_ARGUMENT: `subgroup_types`(3) should not have more dimensions ' 'than `dims`(2).', lambda: xc.HloSharding.iota_tile( (2, 2), subgroup_types=( xc.OpSharding.Type.REPLICATED, xc.OpSharding.Type.MANUAL, xc.OpSharding.Type.REPLICATED, ), ), ) def test_device_indices_cache(self): op1 = xc.OpSharding() op1.type = xc.OpSharding.Type.OTHER op1.tile_assignment_dimensions = [1, 1, 2, 1] op1.tile_assignment_devices = [0, 1] op1.last_tile_dims = [xc.OpSharding.Type.REPLICATED, xc.OpSharding.Type.MANUAL] op2 = xc.OpSharding() op2.type = xc.OpSharding.Type.REPLICATED shape = (8, 4) devices = jax.devices() ops = GSPMDSharding(devices, op1) ops.devices_indices_map(shape) cache_info1 = common_devices_indices_map.cache_info() ops.devices_indices_map(shape) cache_info2 = common_devices_indices_map.cache_info() self.assertEqual(cache_info2.hits, cache_info1.hits + 1) ops = GSPMDSharding(devices, op2) ops.devices_indices_map(shape) cache_info3 = common_devices_indices_map.cache_info() self.assertEqual(cache_info3.hits, cache_info2.hits + 1) ops.devices_indices_map(shape) cache_info4 = common_devices_indices_map.cache_info() self.assertEqual(cache_info4.hits, cache_info3.hits + 1) def test_op_sharding_semantically_replicated(self): op1 = xc.OpSharding() op1.type = xc.OpSharding.Type.OTHER op1.tile_assignment_dimensions = [1, 1, 2] op1.tile_assignment_devices = [0, 1] op1.last_tile_dims = [xc.OpSharding.Type.REPLICATED] op2 = xc.OpSharding() op2.type = xc.OpSharding.Type.REPLICATED op3 = xc.OpSharding() op3.type = xc.OpSharding.Type.OTHER op3.tile_assignment_dimensions = [1, 1, 1, 1] op3.tile_assignment_devices = [0] op3.last_tile_dims = [xc.OpSharding.Type.REPLICATED] op4 = xc.OpSharding() op4.type = xc.OpSharding.Type.OTHER op4.tile_assignment_dimensions = [1] op4.tile_assignment_devices = [0] self.assertTrue(op_shardings.is_op_sharding_replicated(op1)) self.assertTrue(op_shardings.is_op_sharding_replicated(op2)) self.assertTrue(op_shardings.is_op_sharding_replicated(op3)) self.assertTrue(op_shardings.is_op_sharding_replicated(op4)) self.assertTrue(op_shardings.are_op_shardings_equal(op1, op2)) self.assertTrue(op_shardings.are_op_shardings_equal(op2, op3)) self.assertTrue(op_shardings.are_op_shardings_equal(op3, op4)) def test_op_sharding_manual_replicated(self): op1 = xc.OpSharding() op1.type = xc.OpSharding.Type.OTHER op1.tile_assignment_dimensions = [1, 1, 2, 1] op1.tile_assignment_devices = [0, 1] op1.last_tile_dims = [xc.OpSharding.Type.REPLICATED, xc.OpSharding.Type.MANUAL] op2 = xc.OpSharding() op2.type = xc.OpSharding.Type.OTHER op2.tile_assignment_dimensions = [1, 1, 1, 2] op2.tile_assignment_devices = [0, 1] op2.last_tile_dims = [xc.OpSharding.Type.MANUAL, xc.OpSharding.Type.REPLICATED] op3 = xc.OpSharding() op3.type = xc.OpSharding.Type.REPLICATED self.assertTrue(op_shardings.is_op_sharding_replicated(op1)) self.assertTrue(op_shardings.is_op_sharding_replicated(op2)) self.assertTrue(op_shardings.are_op_shardings_equal(op1, op2)) self.assertTrue(op_shardings.are_op_shardings_equal(op1, op3)) hs1 = xc.HloSharding.from_proto(op1) self.assertEqual( hs1, xc.HloSharding.iota_tile( (1, 1, 2, 1), subgroup_types=( xc.OpSharding.Type.REPLICATED, xc.OpSharding.Type.MANUAL, ), ) ) self.assertTrue(hs1.is_replicated()) self.assertFalse(hs1.replicate_on_last_tile_dim()) hs2 = xc.HloSharding.from_proto(op2) self.assertEqual( xc.HloSharding.from_proto(op2), xc.HloSharding.iota_tile( (1, 1, 1, 2), subgroup_types=( xc.OpSharding.Type.MANUAL, xc.OpSharding.Type.REPLICATED, ), ) ) self.assertTrue(hs2.is_replicated()) self.assertFalse(hs2.replicate_on_last_tile_dim()) self.assertEqual( xc.HloSharding.from_proto(op3), xc.HloSharding.replicate() ) def test_hlo_sharding_manual_replicated(self): hs1 = xc.HloSharding.manual() self.assertTrue(hs1.is_manual()) self.assertFalse(hs1.tile_assignment_devices()) hs2 = xc.HloSharding.replicate() self.assertTrue(hs2.is_replicated()) self.assertFalse(hs2.tile_assignment_devices()) hs3 = xc.HloSharding.iota_tile( (3, 3), subgroup_types=( xc.OpSharding.Type.MANUAL, xc.OpSharding.Type.REPLICATED, ), ) self.assertFalse(hs3.is_manual()) self.assertFalse(hs3.is_replicated()) self.assertEqual(hs3.num_dimensions(), 2) self.assertEqual(hs3.tile_assignment_dimensions(), [3, 3]) self.assertEqual(hs3.num_devices(), 9) self.assertEqual(hs3.tile_assignment_devices(), list(range(0, 9))) self.assertEqual( hs3.subgroup_types(), [xc.OpSharding.Type.MANUAL, xc.OpSharding.Type.REPLICATED], ) self.assertFalse(hs3.replicate_on_last_tile_dim()) self.assertTrue(hs3.is_tiled()) hs4 = xc.HloSharding.iota_tile( (3, 4), subgroup_types=[xc.OpSharding.Type.REPLICATED] ) self.assertTrue(hs4.replicate_on_last_tile_dim()) self.assertFalse(hs4.subgroup_types()) self.assertTrue(hs4.is_tiled()) def test_op_sharding_cache_on_mesh_pspec_sharding(self): ndim = 2 mesh = jtu.create_global_mesh((4, 2), ('x', 'y')) mps1 = NamedSharding(mesh, P('x', 'y')) op1 = mps1._to_xla_hlo_sharding(ndim) cache_info1 = sharding_impls.named_sharding_to_xla_hlo_sharding.cache_info() mps2 = NamedSharding(mesh, P('x', 'y')) op2 = mps2._to_xla_hlo_sharding(ndim) cache_info2 = sharding_impls.named_sharding_to_xla_hlo_sharding.cache_info() self.assertEqual(id(op1), id(op2)) self.assertEqual(cache_info2.hits, cache_info1.hits + 1) self.assertEqual(cache_info2.misses, cache_info1.misses) self.assertEqual(cache_info2.currsize, cache_info1.currsize) def test_get_partition_spec(self): mesh = jtu.create_global_mesh((4, 2), ('x', 'y')) s = NamedSharding(mesh, P('x', 'y', None)) self.assertEqual(s._parsed_pspec.get_partition_spec(), P('x', 'y', None)) recovered_parsed_pspec = parse_flatten_op_sharding( s._to_xla_hlo_sharding(3), mesh) self.assertEqual(recovered_parsed_pspec[0].get_partition_spec(), P('x', 'y')) out_of_sync_parsed_pspec = sharding_impls.ParsedPartitionSpec( P('x', 'y'), ('x', 'y'), sharding_impls.SpecSync.OUT_OF_SYNC) self.assertEqual(out_of_sync_parsed_pspec.get_partition_spec(), P('x', 'y')) def test_mesh_with_list_devices(self): mesh = jax.sharding.Mesh(jax.devices(), ('x',)) self.assertIsInstance(mesh.devices, np.ndarray) self.assertEqual(mesh.size, jax.device_count()) def test_mesh_with_string_axis_names(self): mesh = jax.sharding.Mesh(jax.devices(), 'dp') self.assertTupleEqual(mesh.axis_names, ('dp',)) @jtu.with_config(jax_use_shardy_partitioner=True) class SdyIntegrationTest(jtu.JaxTestCase): # TODO(bartchr): Once JAX is released with SDY, remove setUp. def setUp(self): if not dialects.sdy: raise unittest.SkipTest('Shardy is not available.') def test_lowering_input_output_sharding(self): mesh = jtu.create_global_mesh((4, 2), ('x', 'y')) np_inp = np.arange(16).reshape(8, 2) s = jax.sharding.NamedSharding(mesh, P('x', 'y')) arr = jax.device_put(np_inp, s) @partial(jax.jit, out_shardings=s) def f(x): return x * 2 self.assertIn('sdy.sharding = #sdy.sharding', f.lower(arr).as_text()) def test_lowering_with_sharding_constraint(self): mesh = jtu.create_global_mesh((2, 2), ('x', 'y')) arr = np.arange(16).reshape(4, 2, 2) @jax.jit def f(x): return jax.lax.with_sharding_constraint( x, NamedSharding(mesh, P('x', None, 'y'))) lowered_str = jax.jit(f).lower(arr).as_text() self.assertIn('sdy.sharding_constraint', lowered_str) self.assertIn('<@mesh, [{"x"}, {}, {"y"}]>', lowered_str) def test_lowering_with_sharding_constraint_unconstrained(self): mesh = jtu.create_global_mesh((4, 2), ('x', 'y')) arr = np.arange(16).reshape(4, 2, 2) @jax.jit def f(x): return jax.lax.with_sharding_constraint( x, NamedSharding(mesh, P('x', P.UNCONSTRAINED, 'y'))) lowered_str = f.lower(arr).as_text() self.assertIn('sdy.sharding_constraint', lowered_str) self.assertIn('<@mesh, [{"x"}, {?}, {"y"}]>', lowered_str) # TODO(bartchr): run on CPU once Shardy is added to the XLA CPU pipeline. @jtu.skip_on_devices('cpu') def test_compile_with_inferred_out_sharding(self): mesh = jtu.create_global_mesh((2, 2), ('x', 'y')) x = jax.device_put(np.arange(8 * 4).reshape(8, 4), jax.sharding.NamedSharding(mesh, P('x', 'y'))) y = jax.device_put(np.arange(4 * 16).reshape(4, 16), jax.sharding.NamedSharding(mesh, P('y'))) @jax.jit def f(x, y): return x @ y out = f(x, y) self.assertArraysEqual(out, x @ y) self.assertEqual(out.sharding, jax.sharding.NamedSharding(mesh, P('x'))) if __name__ == '__main__': absltest.main(testLoader=jtu.JaxTestLoader())