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|
from __future__ import absolute_import
from __future__ import division
from __future__ import print_function
from __future__ import unicode_literals
import unittest
import torch
import torch.nn as nn
import torch.nn.functional as F
from torch import Tensor
from torch.testing import FileCheck
from common_utils import run_tests, IS_WINDOWS, skipIfRocm, IS_SANDCASTLE
from textwrap import dedent
from itertools import product, permutations
from test_jit import JitTestCase, enable_cpu_fuser, RUN_CUDA, RUN_CUDA_HALF, RUN_CUDA_MULTI_GPU, \
backward_graph, get_lstm_inputs, get_milstm_inputs, LSTMCellC, LSTMCellF, LSTMCellS, MiLSTMCell
class TestFuser(JitTestCase):
def assertAllFused(self, graph, except_for=()):
if [n.kind() for n in graph.nodes()] == ['prim::DifferentiableGraph']:
graph = next(graph.nodes()).g('Subgraph')
allowed_nodes = {'prim::Constant', 'prim::FusionGroup'} | set(except_for)
self.assertTrue(all(node.kind() in allowed_nodes for node in graph.nodes()),
'got {}'.format(graph))
self.assertTrue([node.kind() for node in graph.nodes()].count('prim::FusionGroup') == 1)
def _test_fused_abs(self, device='cpu'):
@torch.jit.script
def func(x):
return x.abs() * 2
a = torch.randn(5, device=device)
self.assertEqual(func(a), a.abs() * 2)
self.assertAllFused(func.graph_for(a))
@unittest.skipIf(IS_WINDOWS or IS_SANDCASTLE, "NYI: fuser support for Windows or Sandcastle")
@enable_cpu_fuser
def test_abs_cpu(self):
self._test_fused_abs()
@unittest.skipIf(IS_WINDOWS, "NYI: fuser support for Windows")
@unittest.skipIf(not RUN_CUDA, "requires CUDA")
@skipIfRocm
def test_abs_cuda(self):
self._test_fused_abs(device="cuda")
@unittest.skipIf(IS_WINDOWS, "NYI: fuser support for Windows")
@unittest.skipIf(not RUN_CUDA, "fuser requires CUDA")
def test_arg_configurations_smoke_cuda(self):
# A smoke test to make sure we won't use the same kernel for contiguous
# and non-contiguous arguments.
# TODO: add optionally enabled debug counters to the fuser to verify
# that we really can tell the difference between configurations
def f(x, y):
z1, z2 = (x + y).chunk(2, dim=1)
return z1 * z2
x = torch.randn(4, 4, dtype=torch.float, device='cuda')
y = torch.randn(4, 4, dtype=torch.float, device='cuda')
traced_f = torch.jit.trace(f, (x, y,))
self.assertEqual(traced_f(x.t().contiguous(), y), traced_f(x.t(), y))
@unittest.skipIf(IS_WINDOWS, "NYI: fuser support for Windows")
@unittest.skipIf(not RUN_CUDA, "fuser requires CUDA")
@skipIfRocm
def test_broadcast_cuda(self):
def scaleshift(x, scale, shift):
return x * scale + shift
inputs = [
torch.randn(4, 4, dtype=torch.float, device='cuda'),
torch.randn(4, dtype=torch.float, device='cuda'),
torch.randn(4, dtype=torch.float, device='cuda'),
]
ge = self.checkTrace(scaleshift, inputs)
self.assertAllFused(ge.graph_for(*inputs))
@unittest.skipIf(IS_WINDOWS, "NYI: fuser support for Windows")
@unittest.skipIf(not RUN_CUDA, "fuser requires CUDA")
@unittest.skipIf(not RUN_CUDA_HALF, "no half support")
def test_cuda_half(self):
x = torch.randn(4, 4, dtype=torch.half, device='cuda')
y = torch.randn(4, 4, dtype=torch.half, device='cuda')
funcs = [
self.fn_test_comparison_gt_lt,
self.fn_test_relu,
self.fn_test_exp
]
# Note: Non fused inputs must be float to prevent loss of precision
inputs = (x.float(), y.float())
fusion_inputs = (x, y)
for fn in funcs:
local_inputs = [t.clone().requires_grad_() for t in inputs]
local_fusion_inputs = [t.clone().requires_grad_() for t in fusion_inputs]
# Verifies outputs
fusion = torch.jit.trace(fn, local_fusion_inputs, check_trace=False, optimize=True)
outputs = fn(*local_inputs)
fusion_outputs = fusion(*local_fusion_inputs)
outputs_half = [t.half() for t in outputs]
self.assertEqual(outputs_half, fusion_outputs)
# Verifies gradients
for output, fusion_output in zip(outputs_half, fusion_outputs):
grads = torch.autograd.grad(
output.float().sum(), local_inputs, allow_unused=True, retain_graph=True)
fusion_grads = torch.autograd.grad(
fusion_output.sum(), local_fusion_inputs, allow_unused=True, retain_graph=True)
grads_half = [t.half() for t in grads]
self.assertEqual(grads_half, fusion_grads)
@unittest.skipIf(IS_WINDOWS, "NYI: fuser support for Windows")
@unittest.skipIf(not RUN_CUDA, "fuser requires CUDA")
@skipIfRocm
def test_checks_cat_inputs(self):
# We shouldn't treat cat nodes as broadcasting. All their inputs
# need to be checked for having the same map size, before we can
# run the kernel.
@torch.jit.script
def f(x, y):
return torch.cat([x + 2 * x + x ** 2, y + 4 * y + y ** 3], dim=0)
# NOTE: y is broadcastable to x, but output of f(x, y) should have
# shape 3x4, and not 4x4.
x = torch.randn(2, 4, dtype=torch.float, device='cuda')
y = torch.randn(1, 4, dtype=torch.float, device='cuda')
self.assertEqual(f(x, y).shape, (3, 4))
self.assertAllFused(f.graph_for(x, y))
@unittest.skipIf(IS_WINDOWS, "NYI: fuser support for Windows")
@unittest.skipIf(not RUN_CUDA, "No CUDA")
@skipIfRocm
def test_chunk_cuda(self):
def fn(x):
a, b, c = x.chunk(3, 1)
return a * b + c
inputs = [torch.randn(10, 6, dtype=torch.float, device='cuda')]
ge = self.checkScript(fn, inputs)
graph = ge.graph_for(*inputs)
self.assertAllFused(graph)
FileCheck().check("prim::ConstantChunk[chunks=3, dim=1]").run(str(graph))
@staticmethod
def _test_chunk_correctness(self, device='cpu'):
def chunk_4_0(x):
x0, x1, x2, x3 = x.chunk(4, 0)
return x0 + x1 + x2 + x3
def chunk_4_1(x):
x0, x1, x2, x3 = x.chunk(4, 1)
return x0 + x1 + x2 + x3
def chunk_4_last(x):
x0, x1, x2, x3 = x.chunk(4, 2)
return x0 + x1 + x2 + x3
fns = [chunk_4_0, chunk_4_1, chunk_4_last]
tensors = [
# splitSize = 1
torch.randn(4, 4, 4, dtype=torch.float, device=device),
# contiguous case
torch.randn(12, 8, 16, dtype=torch.float, device=device),
# non-contiguous case
torch.randn(12, 8, 16, dtype=torch.float, device=device).transpose(1, 2),
]
for tensor in tensors:
for fn in fns:
self.checkScript(fn, [tensor])
@unittest.skipIf(IS_WINDOWS or IS_SANDCASTLE, "NYI: fuser support for Windows or Sandcastle")
@enable_cpu_fuser
def test_chunk_correctness(self):
return self._test_chunk_correctness(self, 'cpu')
@unittest.skipIf(IS_WINDOWS, "NYI: fuser support for Windows")
@unittest.skipIf(not RUN_CUDA, "No CUDA")
def test_chunk_correctness_cuda(self):
return self._test_chunk_correctness(self, 'cuda')
@unittest.skipIf(IS_WINDOWS, "NYI: fuser support for Windows")
@unittest.skipIf(not RUN_CUDA, "fuser requires CUDA")
@skipIfRocm
def test_chunk_distributes_cuda(self):
def f(x, y):
z1, z2 = (x + y).chunk(2, dim=1)
return z1 * z2
x = torch.randn(4, 4, dtype=torch.float, device='cuda')
y = torch.randn(4, 4, dtype=torch.float, device='cuda')
ge = self.checkTrace(f, (x, y))
graph = ge.graph_for(x, y)
FileCheck().check("broadcast_tensors").check('with prim::FusionGroup_0') \
.check_count('ConstantChunk', 2, exactly=True).run(str(graph))
@unittest.skipIf(IS_WINDOWS, "NYI: fuser support for Windows")
@unittest.skipIf(not RUN_CUDA, "fuser requires CUDA")
@skipIfRocm
def test_chunk_motion_deduplicates_inputs(self):
def func1(x):
z = x * x
z0, z1 = z.chunk(2)
return z0 * z1
def func2(x):
z = x * x * x
z0, z1 = z.chunk(2)
return z0 * z1
inputs = [
torch.tensor([1.1, 1.2], device='cuda', dtype=torch.float),
]
for func in [func1, func2]:
module = self.checkScript(func, inputs)
forward_graph = module.graph_for(*inputs)
self.assertGraphContainsExactly(forward_graph, 'prim::FusionGroup', 1)
fusion_group = list(forward_graph.nodes())[-1]
self.assertEqual(len(list(fusion_group.inputs())), 1)
@unittest.skipIf(IS_WINDOWS, "NYI: fuser support for Windows")
@unittest.skipIf(not RUN_CUDA, "No CUDA")
@skipIfRocm
def test_chunk_multiple_cuda(self):
# The arguments are intentionally used out of order as a test to see
# if the fusion compiler adds extra args in the correct order
def fn(s, x, y, z):
z1, z2 = z.chunk(2, 2)
x1, x2, x3 = x.chunk(3, 1)
y1, y2 = y.chunk(2, 0)
return s + x1 + x2 + x3 + y1 + y2 + z1 + z2
inputs = [
torch.randn(5, 2, 3, dtype=torch.float, device='cuda'),
torch.randn(5, 6, 3, dtype=torch.float, device='cuda'),
torch.randn(10, 2, 3, dtype=torch.float, device='cuda'),
torch.randn(5, 2, 6, dtype=torch.float, device='cuda'),
]
ge = self.checkScript(fn, inputs)
self.assertAllFused(ge.graph_for(*inputs))
@unittest.skipIf(IS_WINDOWS, "NYI: fuser support for Windows")
@unittest.skipIf(not RUN_CUDA, "fuser requires CUDA")
@skipIfRocm
def test_clamp(self):
def func2(a, b):
return torch.clamp(a + b, min=0, max=2)
def funcInf(a, b):
return torch.clamp(a + b, min=0, max=float('inf'))
def funcOptMin(a, b):
return torch.clamp(a + b, max=2)
def funcOptMax(a, b):
return torch.clamp(a + b, min=0)
a = torch.randn(4, 4, dtype=torch.float, device='cuda', requires_grad=True)
b = torch.randn(4, 4, dtype=torch.float, device='cuda')
nan = torch.tensor(float('nan'))
funcs = (func2, funcInf, funcOptMin, funcOptMax)
for f, inputs in product(funcs, [[a, b], [a, nan]]):
inp1, inp2 = inputs
s = self.checkScript(f, (inp1, inp2))
self.assertAllFused(s.graph_for(inp1, inp2), except_for={'aten::size'})
c = s(inp1, inp2)
c.sum().backward()
graph = backward_graph(s)
self.assertAllFused(graph)
@unittest.skipIf(IS_WINDOWS, "NYI: fuser support for Windows")
@unittest.skipIf(not RUN_CUDA, "fuser requires CUDA")
@skipIfRocm
def test_comparison_eq_ne(self):
def f(x, y):
mask = (x == 0).type_as(x)
z = x * mask + y
mask = (x != 0).type_as(x)
z = z * mask + y
return z
x = torch.randn(4, 4, dtype=torch.float, device='cuda')
y = torch.randn(4, 4, dtype=torch.float, device='cuda')
ge = self.checkTrace(f, (x, y))
self.assertAllFused(ge.graph_for(x, y))
@staticmethod
def fn_test_comparison_gt_lt(x, y):
mask = (x > 0).type_as(x)
z = x * mask + y
mask = (x < 0).type_as(x)
z = z * mask + y
return z
@unittest.skipIf(IS_WINDOWS, "NYI: fuser support for Windows")
@unittest.skipIf(not RUN_CUDA, "fuser requires CUDA")
@skipIfRocm
def test_comparison_gt_lt_cuda(self):
x = torch.randn(4, 4, dtype=torch.float, device='cuda')
y = torch.randn(4, 4, dtype=torch.float, device='cuda')
ge = self.checkTrace(self.fn_test_comparison_gt_lt, (x, y))
self.assertAllFused(ge.graph_for(x, y))
@unittest.skipIf(IS_WINDOWS, "NYI: fuser support for Windows")
@unittest.skipIf(not RUN_CUDA, "fuser requires CUDA")
@skipIfRocm
def test_comparison_ge_le_cuda(self):
def f(x, y):
mask = (x >= 0).type_as(x)
z = x * mask + y
mask = (x <= 0).type_as(x)
z = z * mask + y
return z
x = torch.randn(4, 4, dtype=torch.float, device='cuda')
y = torch.randn(4, 4, dtype=torch.float, device='cuda')
ge = self.checkTrace(f, (x, y))
self.assertAllFused(ge.graph_for(x, y))
x.requires_grad_(True)
y.requires_grad_(True)
self.assertAllFused(ge.graph_for(x, y), except_for=("aten::size", "prim::BroadcastSizes"))
@unittest.skipIf(IS_WINDOWS, "NYI: fuser support for Windows")
@unittest.skipIf(not RUN_CUDA, "fuser requires CUDA")
@skipIfRocm
def test_addcmul_cuda(self):
t = torch.randn(1, 4, dtype=torch.float, device='cuda')
t1 = torch.randn(4, 1, dtype=torch.float, device='cuda')
t2 = torch.randn(1, 4, dtype=torch.float, device='cuda')
def foo(t, t1, t2):
return t.addcmul(t + 1, t2, value=0.1)
ge = self.checkTrace(foo, (t, t1, t2), allow_unused=True)
graph = ge.graph_for(t, t1, t2)
self.assertAllFused(graph)
@unittest.skipIf(IS_WINDOWS, "NYI: fuser support for Windows")
@unittest.skipIf(not RUN_CUDA, "fuser requires CUDA")
@skipIfRocm
def test_lerp_cuda(self):
start = torch.randn(4, 1, dtype=torch.float, device='cuda')
end = torch.randn(1, 4, dtype=torch.float, device='cuda')
weight = torch.tensor(0.5, dtype=torch.float, device='cuda')
# scalar weight overload
def foo_weight_scalar(start, end):
return torch.lerp(start + 1, end, 0.5)
# tensor weight overload
def foo_weight_tensor(start, end):
return torch.lerp(start + 1, end, weight)
ge_weight_scalar = self.checkTrace(foo_weight_scalar, (start, end))
graph = ge_weight_scalar.graph_for(start, end)
self.assertAllFused(graph)
ge_weight_tensor = self.checkTrace(foo_weight_tensor, (start, end))
graph = ge_weight_tensor.graph_for(start, end)
self.assertAllFused(graph)
@unittest.skipIf(IS_WINDOWS, "NYI: fuser support for Windows")
@unittest.skipIf(not RUN_CUDA, "fuser requires CUDA")
@skipIfRocm
def test_concat_cuda(self):
hx = torch.randn(3, 20, dtype=torch.float, device='cuda')
cx = torch.randn(3, 20, dtype=torch.float, device='cuda')
def foo(hx, cx):
return torch.cat((hx + cx, hx * cx))
ge = self.checkTrace(foo, (hx, cx))
graph = ge.graph_for(hx, cx)
self.assertAllFused(graph)
FileCheck().check("FusedConcat").check_next("return").run(str(graph))
@unittest.skipIf(IS_WINDOWS, "NYI: fuser support for Windows")
@unittest.skipIf(not RUN_CUDA, "fuser requires CUDA")
@skipIfRocm
def test_concat_invariant_cuda(self):
# Invariant: the output of prim::FusedConcat may
# not be an input to any node inside the FusionGroup.
def fn(x, y, z):
x1 = x + y
y1 = x - y
w = torch.cat([x1, y1])
return w + z
x = torch.randn(2, 2, dtype=torch.float, device='cuda')
y = torch.randn(2, 2, dtype=torch.float, device='cuda')
z = torch.randn(4, 2, dtype=torch.float, device='cuda')
ge = self.checkTrace(fn, (x, y, z))
graph = ge.graph_for(x, y, z)
self.assertAllFused(graph, except_for={'aten::add'})
FileCheck().check("FusedConcat").check_next("return").run(str(graph))
@staticmethod
def fn_test_exp(x, y):
return (x + .5 * y).exp()
@unittest.skipIf(IS_WINDOWS, "NYI: fuser support for Windows")
@unittest.skipIf(not RUN_CUDA, "fuser requires CUDA")
@skipIfRocm
def test_exp_cuda(self):
x = torch.randn(4, 4, dtype=torch.float, device='cuda')
y = torch.randn(4, 4, dtype=torch.float, device='cuda')
ge = self.checkTrace(self.fn_test_exp, (x, y))
self.assertAllFused(ge.graph_for(x, y))
@unittest.skipIf(IS_WINDOWS, "NYI: fuser support for Windows")
@unittest.skipIf(not RUN_CUDA, "fuser requires CUDA")
@skipIfRocm
def test_fuse_decompose_normalization(self):
class ResLike(torch.jit.ScriptModule):
def __init__(self, norm_module, optimize=True):
super(ResLike, self).__init__(optimize)
self.nm = norm_module
@torch.jit.script_method
def forward(self, x, y):
return y + torch.relu(self.nm(x))
def test_norm_decompose(nm, in_opt_graph, not_in_opt_graph, in_fusegraph):
model = ResLike(nm).cuda()
model_noopt = ResLike(nm, optimize=False).cuda()
model_noopt.load_state_dict(model.state_dict())
x = torch.randn(2, 16, 8, 8, device='cuda')
y = torch.randn(2, 16, 8, 8, device='cuda')
# FIXME: We need differentiation for CNNs for this optimization to trigger
with torch.no_grad():
out = model(x, y)
graph = model.graph_for(x, y)
rep = str(graph)
out_noopt = model_noopt(x, y)
rep_noopt = str(model_noopt.graph_for(x, y))
self.assertEqual(out, out_noopt, prec=3e-5)
# Check that normalization op has really been decomposed
for node_in_graph in in_opt_graph:
self.assertIn(node_in_graph, rep)
for node_not_in_graph in not_in_opt_graph:
self.assertNotIn(node_not_in_graph, rep)
self.assertIn(node_not_in_graph, rep_noopt)
fusion_groups = [node for node in graph.nodes() if node.kind() == 'prim::FusionGroup']
self.assertEqual(len(fusion_groups), 1)
fused_graph = str(fusion_groups[0].g('Subgraph'))
for node_in_fusegraph in in_fusegraph:
self.assertIn(node_in_fusegraph, fused_graph)
# test for batchnorm decompose
bm = nn.BatchNorm2d(16)
test_norm_decompose(bm, ['aten::batch_norm_update_stats'],
['aten::batch_norm('], ['aten::sqrt'])
# test for layernorm decompose
lm = nn.LayerNorm(8)
test_norm_decompose(lm, ['aten::batch_norm_stats'],
['aten::layer_norm('], ['aten::sub', 'aten::mul', 'aten::addcmul'])
@unittest.skipIf(IS_WINDOWS, "NYI: fuser support for Windows")
@unittest.skipIf(not RUN_CUDA, "fuser requires CUDA")
@skipIfRocm
def test_threshold(self):
def f(x):
return torch.threshold(x, 0, -10) + x + x + x
x = torch.tensor([-1, -0.5, 0, 1, 2, 3], device='cuda')
scripted = torch.jit.script(f)
self.assertEqual(f(x), scripted(x))
self.assertAllFused(scripted.graph_for(x))
@unittest.skipIf(IS_WINDOWS, "NYI: fuser support for Windows")
@unittest.skipIf(not RUN_CUDA, "fuser requires CUDA")
@skipIfRocm
def test_scalar_arg_cuda(self):
def fn_test_scalar_arg(x, p):
# type: (Tensor, float) -> Tensor
return p * (x * x + x)
x = torch.randn(4, 4, dtype=torch.float, device='cuda')
p = 3
scripted = torch.jit.script(fn_test_scalar_arg, (x, p))
self.assertEqual(fn_test_scalar_arg(x, p), scripted(x, p))
self.assertAllFused(scripted.graph_for(x, p))
x.requires_grad_(True)
out = scripted(x, p)
self.assertAllFused(scripted.graph_for(x, p), except_for=("aten::size", "prim::BroadcastSizes"))
@unittest.skipIf(IS_WINDOWS or IS_SANDCASTLE, "NYI: fuser support for Windows or Sandcastle")
@enable_cpu_fuser
def test_fuser_deduplication(self):
# See that fusion kernel outputs are deduplicated when removing _grad_sum_to_size in the fuser's compilation
# see the discussion in PR #14957.
def f(x, y):
return torch.sigmoid(x + y)
b = torch.randn(5, 5, requires_grad=True)
a = torch.randn(5, 5, requires_grad=True)
s = self.checkScript(f, (a, b))
self.assertAllFused(s.graph_for(a, b), except_for={'aten::size'})
c = s(a, b)
ga, gb = torch.autograd.grad(c.sum(), [a, b])
graph = backward_graph(s)
self.assertAllFused(graph)
# check that a, b share storage, i.e. were generated as a single output in the fuser
self.assertEqual(ga.data_ptr(), gb.data_ptr())
@unittest.skipIf(IS_WINDOWS or IS_SANDCASTLE, "NYI: fuser support for Windows or Sandcastle")
@enable_cpu_fuser
def test_fuser_iou(self):
# This checks if most of Intersection over Union is fused.
# In particular, the backward contains many _grad_sum_to_size.
def iou(b1x1, b1y1, b1x2, b1y2, b2x1, b2y1, b2x2, b2y2):
ltx = torch.max(b1x1, b2x1) # [N,M]
lty = torch.max(b1y1, b2y1)
rbx = torch.min(b1x2, b2x2)
rby = torch.min(b1y2, b2y2)
w = (rbx - ltx).clamp(min=0, max=float('inf')) # [N,M]
h = (rby - lty).clamp(min=0, max=float('inf')) # [N,M]
inter = w * h # [N,M]
area1 = (b1x2 - b1x1) * (b1y2 - b1y2) # [N,1]
area2 = (b2x2 - b2x1) * (b2y2 - b2y2) # [1,M]
iou = inter / (area1 + area2 - inter)
return iou
box1 = torch.randn(5, 4, requires_grad=True)
box2 = torch.randn(5, 4, requires_grad=True)
# unsqueezing can currently not be fused
b1x1 = box1[:, 0].unsqueeze(1) # [N,1]
b1y1 = box1[:, 1].unsqueeze(1)
b1x2 = box1[:, 2].unsqueeze(1)
b1y2 = box1[:, 3].unsqueeze(1)
b2x1 = box2[:, 0].unsqueeze(0) # [1,N]
b2y1 = box2[:, 1].unsqueeze(0)
b2x2 = box2[:, 2].unsqueeze(0)
b2y2 = box2[:, 3].unsqueeze(0)
s = self.checkScript(iou, (b1x1, b1y1, b1x2, b1y2, b2x1, b2y1, b2x2, b2y2))
self.assertAllFused(s.graph_for(b1x1, b1y1, b1x2, b1y2, b2x1, b2y1, b2x2, b2y2),
except_for={'aten::size', 'prim::BroadcastSizes'})
c = s(b1x1, b1y1, b1x2, b1y2, b2x1, b2y1, b2x2, b2y2)
torch.autograd.grad(c.sum(), [b1x1, b1y1, b1x2, b1y2, b2x1, b2y1, b2x2, b2y2])
graph = backward_graph(s)
self.assertAllFused(graph, except_for={'aten::size', 'prim::BroadcastSizes'})
@unittest.skipIf(IS_WINDOWS, "NYI: fuser support for Windows")
@unittest.skipIf(not RUN_CUDA, "fuser requires CUDA")
@unittest.skipIf(not RUN_CUDA_MULTI_GPU, "needs non-zero device")
@skipIfRocm
@enable_cpu_fuser
def test_fusion_reuse_multi_gpu(self):
def fn(x, y):
return x * y * x * y
inputs_cpu = [
torch.randn(4, 4, dtype=torch.float),
torch.randn(4, 4, dtype=torch.float),
]
inputs_cuda0 = [x.cuda(0) for x in inputs_cpu]
inputs_cuda1 = [y.cuda(1) for y in inputs_cpu]
# Should not crash; these should compile different kernels.
ge = self.checkScript(fn, inputs_cpu)
self.assertAllFused(ge.graph_for(*inputs_cpu))
ge(*inputs_cuda0)
ge(*inputs_cuda1)
@unittest.skipIf(IS_WINDOWS, "NYI: fuser support for Windows")
@unittest.skipIf(not RUN_CUDA, "fuser requires CUDA")
@unittest.skipIf(not RUN_CUDA_MULTI_GPU, "needs non-zero device")
@skipIfRocm
@enable_cpu_fuser
def test_kernel_cache_multi_gpu(self):
def not_fusible(x):
return x
def fn(x, y, z):
x_out = x * x * x * x * x # fusion: lambda x. x * x * x * x * x
y_out = y * y * y * y * y
z_out = z * z * z * z * z
return not_fusible(x_out), not_fusible(y_out), not_fusible(z_out)
inputs = [
torch.randn(4, 4, dtype=torch.float),
torch.randn(4, 4, dtype=torch.float, device='cuda:0'),
torch.randn(4, 4, dtype=torch.float, device='cuda:1'),
]
prev_cache_size = torch._C._jit_debug_fuser_num_cached_kernel_specs()
# There are 3 FusionGroups. Because they have the same graph, they
# should reuse the same KernelSpec in the KernelSpec cache.
ge = self.checkScript(fn, inputs)
self.assertGraphContainsExactly(
ge.graph_for(*inputs), 'prim::FusionGroup', 3, True)
new_cache_size = torch._C._jit_debug_fuser_num_cached_kernel_specs()
# XXX: This assumes that the same kernel isn't already used by another test
self.assertEqual(new_cache_size - prev_cache_size, 1)
@unittest.skipIf(IS_WINDOWS, "NYI: fuser support for Windows")
@unittest.skipIf(not RUN_CUDA_MULTI_GPU, "needs non-zero device")
@skipIfRocm
def test_nonzero_device_cuda(self):
device = 'cuda:' + str(1)
x = torch.tensor([0.4], dtype=torch.float, device=device)
y = torch.tensor([0.7], dtype=torch.float, device=device)
def doit(x, y):
return torch.sigmoid(torch.tanh(x * (x + y) + x))
ge = self.checkTrace(doit, (x, y))
self.assertAllFused(ge.graph_for(x, y))
@unittest.skipIf(IS_WINDOWS, "NYI: fuser support for Windows")
@unittest.skipIf(not RUN_CUDA, "fuser requires CUDA")
@skipIfRocm
def test_lstm_cuda(self):
inputs = get_lstm_inputs('cuda', training=True)
module = self.checkScript(LSTMCellS, inputs)
forward_graph = module.graph_for(*inputs)
self.assertGraphContainsExactly(
forward_graph, 'prim::FusionGroup', 1, consider_subgraphs=True)
self.assertTrue(len(list(forward_graph.nodes())) == 2)
# Everything is differentiable but TupleConstruct return
FileCheck().check("DifferentiableGraph").check_next("TupleConstruct") \
.check_next("return").run(str(forward_graph))
hy, cy = module(*inputs)
(hy + cy).sum().backward()
backward = backward_graph(module)
FileCheck().check("FusionGroup_0").check_next("FusionGroup_1") \
.check_not("FusionGroup_2").run(str(backward))
@unittest.skipIf(IS_WINDOWS, "NYI: fuser support for Windows")
@unittest.skipIf(not RUN_CUDA, "fuser requires CUDA")
@skipIfRocm
def test_lstm_concat_cuda(self):
inputs = get_lstm_inputs('cuda')
ge = self.checkTrace(LSTMCellC, inputs)
graph = ge.graph_for(*inputs)
FileCheck().check("FusedConcat").check_next("return").run(str(graph))
@unittest.skipIf(IS_WINDOWS, "NYI: fuser support for Windows")
@unittest.skipIf(not RUN_CUDA, "fuser requires CUDA")
@skipIfRocm
def test_lstm_gates_permutations_cuda(self):
# lstm has gates = x.mm(w_ih.t()) + hx.mm(w_hh.t()) + b_ih + b_hh.
# Test that any permutation of this will still result in one FusionGroup.
choices = ['x.mm(w_ih.t())', 'hx.mm(w_hh.t())', 'b_ih', 'b_hh']
template = dedent('''
def cell(x, hx, cx, w_ih, w_hh, b_ih, b_hh):
gates = {} + {} + {} + {}
ingate, forgetgate, cellgate, outgate = gates.chunk(4, 1)
return ingate * forgetgate * cellgate * outgate
''')
for permutation in permutations(choices, len(choices)):
code = template.format(*permutation)
scope = {}
exec(code, globals(), scope)
cu = torch.jit.CompilationUnit(code)
inputs = get_lstm_inputs('cuda', training=False)
self.assertEqual(cu.cell(*inputs), scope['cell'](*inputs))
forward_graph = cu.cell.graph_for(*inputs)
self.assertGraphContainsExactly(forward_graph, 'prim::FusionGroup', 1)
# TODO: Fuser doesn't work at all when inputs require grad. Fix that
@unittest.skipIf(IS_WINDOWS, "NYI: fuser support for Windows")
@unittest.skipIf(not RUN_CUDA, "fuser requires CUDA")
@skipIfRocm
def test_lstm_traced_cuda(self):
inputs = get_lstm_inputs('cuda')
ge = self.checkTrace(LSTMCellF, inputs)
graph = ge.graph_for(*inputs)
FileCheck().check_not("Chunk").check_not("aten::add").check_not("aten::sigmoid") \
.check_not("aten::tanh").check("FusionGroup").check_next("TupleConstruct") \
.check_next("return").check_not("FusionGroup_1").run(str(graph))
@unittest.skipIf(IS_WINDOWS or IS_SANDCASTLE, "NYI: fuser support for Windows or Sandcastle")
@unittest.skip("Test is flaky, see https://github.com/pytorch/pytorch/issues/8746")
@enable_cpu_fuser
def test_lstm_traced_cpu(self):
inputs = get_lstm_inputs('cpu')
try:
ge = self.checkTrace(LSTMCellF, inputs)
graph = ge.graph_for(*inputs)
FileCheck.check("FusionGroup").run(str(graph))
except RuntimeError as e:
if 'Failed to compile' in e.args[0]:
warnings.warn('CPU fuser test has failed! This is not a hard failure, '
'because the kernels sometimes trigger bugs in compilers '
'(most notably GCC 7.2).')
raise unittest.SkipTest('Failed to compile')
else:
raise
@unittest.skipIf(IS_WINDOWS, "NYI: fuser support for Windows")
@unittest.skipIf(not RUN_CUDA, "fuser requires CUDA")
@skipIfRocm
def test_milstm_cuda(self):
inputs = get_milstm_inputs('cuda', training=True)
module = self.checkScript(MiLSTMCell, inputs)
forward_graph = module.graph_for(*inputs)
self.assertGraphContainsExactly(
forward_graph, 'prim::FusionGroup', 1, consider_subgraphs=True)
FileCheck().check("DifferentiableGraph").check_next("TupleConstruct") \
.check_next("return").check("FusionGroup").run(str(forward_graph))
hy, cy = module(*inputs)
(hy + cy).sum().backward()
@unittest.skipIf(IS_WINDOWS, "NYI: fuser support for Windows")
@unittest.skipIf(not RUN_CUDA, "fuser requires CUDA")
@skipIfRocm
def test_rand_cuda(self):
class M(torch.jit.ScriptModule):
__constants__ = ['d']
def __init__(self):
self.d = torch.device('cuda')
@torch.jit.script_method
def create(self, x):
return x * x + x + torch.rand_like(x)
x = torch.zeros([3, 4, 5], dtype=torch.float, device='cuda')
m = M()
out1 = m.create(x)
out2 = m.create(x)
self.assertNotEqual(out1, out2)
self.assertTrue(torch.all(out1 >= 0))
self.assertTrue(torch.all(out1 < 1))
self.assertTrue(torch.all(out2 >= 0))
self.assertTrue(torch.all(out2 < 1))
self.assertAllFused(m.create.graph_for(x))
@staticmethod
def fn_test_relu(x, y):
return F.relu(x + .5 * y)
@unittest.skipIf(IS_WINDOWS, "NYI: fuser support for Windows")
@unittest.skipIf(not RUN_CUDA, "fuser requires CUDA")
@skipIfRocm
def test_relu_cuda(self):
x = torch.randn(4, 4, dtype=torch.float, device='cuda')
y = torch.randn(4, 4, dtype=torch.float, device='cuda')
ge = self.checkTrace(self.fn_test_relu, (x, y))
self.assertAllFused(ge.graph_for(x, y))
@unittest.skipIf(IS_WINDOWS, "NYI: fuser support for Windows")
@unittest.skipIf(not RUN_CUDA, "fuser requires CUDA")
@skipIfRocm
def test_erf_cuda(self):
def fn_test_erf(x):
return F.relu(torch.erf(x) - torch.erfc(x))
x = torch.randn(4, 4, dtype=torch.float, device='cuda')
ge = self.checkTrace(fn_test_erf, (x,))
self.assertAllFused(ge.graph_for(x))
x.requires_grad_(True)
self.assertAllFused(ge.graph_for(x), except_for=("aten::size", "prim::BroadcastSizes"))
@unittest.skipIf(IS_WINDOWS, "NYI: fuser support for Windows")
@unittest.skipIf(not RUN_CUDA, "fuser requires CUDA")
@skipIfRocm
def test_rand_broadcast_cuda(self):
def fn_test_rand(x, y):
r = torch.rand_like(y)
return r * x + x
x = torch.randn(4, 4, dtype=torch.float, device='cuda')
y = torch.randn(4, 4, dtype=torch.float, device='cuda')
script_f = torch.jit.script(fn_test_rand, (x, y))
out = script_f(x, y)
self.assertAllFused(script_f.graph_for(x, y))
x.requires_grad_(True)
out = script_f(x, y)
self.assertAllFused(script_f.graph_for(x, y), except_for=("aten::size", "prim::BroadcastSizes"))
# test that broadcasting random produces correct results
x = torch.ones(4, 4, dtype=torch.float, device='cuda')
y = torch.ones(4, dtype=torch.float, device='cuda')
out = script_f(x, y)
self.assertEqual(out[0], out[1])
@unittest.skipIf(IS_WINDOWS or IS_SANDCASTLE, "NYI: fuser support for Windows or Sandcastle")
@enable_cpu_fuser
def test_scalar(self):
def fn(x, y):
return 2 * x + y
x = torch.tensor(0.1, dtype=torch.float, device='cpu')
y = torch.tensor(1, dtype=torch.float, device='cpu')
ge = self.checkScript(fn, (x, y))
self.assertAllFused(ge.graph_for(x, y))
@unittest.skipIf(IS_WINDOWS, "NYI: fuser support for Windows")
@unittest.skipIf(not RUN_CUDA, "fuser requires CUDA")
@skipIfRocm
def test_small_constant_cuda(self):
def fn_test_small_constant(x, y):
return (1e-8 * x + 5e-9 * y) * 1e8
x = torch.randn(4, 4, dtype=torch.float, device='cuda')
y = torch.randn(4, 4, dtype=torch.float, device='cuda')
ge = self.checkTrace(fn_test_small_constant, (x, y))
self.assertAllFused(ge.graph_for(x, y))
@unittest.skipIf(IS_WINDOWS, "NYI: fuser support for Windows")
@unittest.skipIf(not RUN_CUDA, "fuser requires CUDA")
@skipIfRocm
def test_tensor_scalar_ops_cuda(self):
def should_fuse(x):
z = 3.
y = x + z
return x * y
# XXX: right now we only support fusing scalars if
# they're constant (#9940)
def should_not_fuse(x, z):
y = x + int(z)
return x * y
inputs = [torch.randn(2, 2, dtype=torch.float, device='cuda')]
ge = self.checkScript(should_fuse, inputs)
self.assertAllFused(ge.graph_for(*inputs))
inputs = [
torch.randn(2, 2, dtype=torch.float, device='cuda'),
torch.tensor(3., dtype=torch.float, device='cuda'),
]
ge = self.checkScript(should_not_fuse, inputs)
self.assertGraphContainsExactly(
ge.graph_for(*inputs), 'prim::FusionGroup', 0, consider_subgraphs=True)
@unittest.skipIf(IS_WINDOWS or IS_SANDCASTLE, "NYI: fuser support for Windows or Sandcastle")
@enable_cpu_fuser
def test_where_and_typing(self):
def f(x, y):
mask = x > y
res = torch.where(mask, x, y)
return mask, res
script_f = torch.jit.script(f)
x = torch.randn(4, 4, dtype=torch.double)
y = torch.randn(4, 4, dtype=torch.double)
result1, result2 = script_f(x, y)
expected1, expected2 = f(x, y)
self.assertEqual(result1, expected1)
self.assertEqual(result2, expected2)
self.assertAllFused(script_f.graph_for(x, y), except_for={'prim::TupleConstruct'})
@unittest.skipIf(not IS_WINDOWS, "Test that the fuser is disabled on Windows")
@unittest.skipIf(not RUN_CUDA, "fuser requires CUDA")
def test_windows_cuda(self):
def scaleshift(x, scale, shift):
return x * scale + shift
inputs = [
torch.randn(4, 4, dtype=torch.float, device='cuda'),
torch.randn(4, dtype=torch.float, device='cuda'),
torch.randn(4, dtype=torch.float, device='cuda'),
]
ge = self.checkScript(scaleshift, inputs)
self.assertGraphContainsExactly(
ge.graph_for(*inputs), 'prim::FusionGroup', 0, consider_subgraphs=True)
if __name__ == '__main__':
run_tests()
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