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"""Benchmarking Relay VM using models from MXNet."""
import numpy as np
import tvm
from tvm.contrib import graph_runtime
from tvm import relay
from tvm.relay import testing
def benchmark_execution(mod,
params,
measure=False,
data_shape=(1, 3, 224, 224),
out_shape=(1, 1000),
dtype='float32'):
def get_tvm_output(mod, data, params, target, ctx, dtype='float32'):
with relay.build_config(opt_level=1):
graph, lib, params = relay.build(mod, target, params=params)
m = graph_runtime.create(graph, lib, ctx)
# set inputs
m.set_input("data", data)
m.set_input(**params)
m.run()
out = m.get_output(0, tvm.nd.empty(out_shape, dtype))
if measure:
print("Evaluate graph runtime inference time cost...")
ftimer = m.module.time_evaluator("run", ctx, number=1, repeat=20)
# Measure in millisecond.
prof_res = np.array(ftimer().results) * 1000
print("Mean inference time (std dev): %.2f ms (%.2f ms)" %
(np.mean(prof_res), np.std(prof_res)))
return out.asnumpy()
def get_tvm_vm_output(mod, data, params, target, ctx, dtype='float32'):
ex = relay.create_executor('vm', mod=mod, ctx=ctx)
result = ex.evaluate()(data, **params)
return result.asnumpy().astype(dtype)
# random input
data = np.random.uniform(size=data_shape).astype(dtype)
target = "llvm"
ctx = tvm.cpu(0)
tvm_out = get_tvm_output(mod, tvm.nd.array(data.astype(dtype)), params,
target, ctx, dtype)
vm_out = get_tvm_vm_output(mod, tvm.nd.array(data.astype(dtype)), params,
target, ctx, dtype)
tvm.testing.assert_allclose(vm_out, tvm_out, rtol=1e-5, atol=1e-5)
def test_mlp():
image_shape = (1, 1, 28, 28)
mod, params = testing.mlp.get_workload(1)
benchmark_execution(mod, params, data_shape=image_shape, out_shape=(1, 10))
def test_vgg():
for n in [11, 16]:
mod, params = testing.vgg.get_workload(1, num_layers=n)
benchmark_execution(mod, params)
def test_resnet():
for n in [18, 50]:
mod, params = testing.resnet.get_workload(batch_size=1, num_layers=n)
benchmark_execution(mod, params, True)
def test_squeezenet():
for version in ['1.0', '1.1']:
mod, params = testing.squeezenet.get_workload(version=version)
benchmark_execution(mod, params)
def test_inception_v3():
image_shape = (3, 299, 299)
mod, params = testing.inception_v3.get_workload(image_shape=image_shape)
benchmark_execution(mod, params, data_shape=(1, 3, 299, 299))
def test_dqn():
image_shape = (1, 4, 84, 84)
mod, params = testing.dqn.get_workload(
batch_size=1, image_shape=image_shape)
benchmark_execution(mod, params, data_shape=image_shape, out_shape=(1, 18))
def test_dcgan():
image_shape = (1, 100)
mod, params = testing.dcgan.get_workload(batch_size=1)
benchmark_execution(mod, params, data_shape=image_shape, out_shape=(1, 3, 64, 64))
def test_mobilenet():
mod, params = testing.mobilenet.get_workload(batch_size=1)
benchmark_execution(mod, params)
def test_densenet():
mod, params = testing.densenet.get_workload(batch_size=1)
benchmark_execution(mod, params)
if __name__ == '__main__':
test_resnet()
test_vgg()
test_squeezenet()
test_mobilenet()
test_densenet()
test_inception_v3()
test_mlp()
test_dqn()
test_dcgan()