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apache--tvm/tests/python/relax/test_analysis_computable_at_compile_time.py
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chore: import upstream snapshot with attribution
2026-07-13 13:36:25 +08:00

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Python

# Licensed to the Apache Software Foundation (ASF) under one
# or more contributor license agreements. See the NOTICE file
# distributed with this work for additional information
# regarding copyright ownership. The ASF licenses this file
# to you 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
#
# http://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.
# ruff: noqa: F841
import tvm
import tvm.testing
from tvm.script import relax as R
from tvm.script import tirx as T
def _analyze_func(func: tvm.relax.Function) -> list[str]:
return [var.name_hint for var in tvm.relax.analysis.computable_at_compile_time(func)]
def test_no_num_input_attribute():
"""Without the "num_input" attribute, all params are runtime"""
@R.function
def func(A: R.Tensor([16], "int32"), B: R.Tensor([16], "int32")):
C = R.add(A, B)
return C
assert _analyze_func(func) == []
def test_compile_time_param():
"""Parameters after "num_input" are known at compile-time"""
@R.function
def func(A: R.Tensor([16], "int32"), B: R.Tensor([16], "int32")):
R.func_attr({"num_input": 1})
return ()
assert _analyze_func(func) == ["B"]
def test_binding_using_one_param():
"""Bindings may be computable at compile-time"""
@R.function
def func(A: R.Tensor([16], "int32"), B: R.Tensor([16], "int32")):
R.func_attr({"num_input": 1})
C = R.add(B, B)
D = R.add(A, C)
return D
assert _analyze_func(func) == ["B", "C"]
def test_binding_using_multiple_params():
"""Compile-time bindings may use multiple parameters"""
@R.function
def func(A: R.Tensor([16], "int32"), B: R.Tensor([16], "int32"), C: R.Tensor([16], "int32")):
R.func_attr({"num_input": 1})
D = R.add(B, C)
E = R.add(A, D)
return E
assert _analyze_func(func) == ["B", "C", "D"]
def test_compile_time_binding_after_run_time():
"""Compile-time bindings may occur after run-time
A binding being computable at compile-time only depends on the
arguments used for it. A value that is computable at compile-time
may occur after a value that is only computable at run-time.
"""
@R.function
def func(A: R.Tensor([16], "int32"), B: R.Tensor([16], "int32")):
R.func_attr({"num_input": 1})
C = R.add(A, A)
D = R.add(B, B)
E = R.add(C, D)
return E
assert _analyze_func(func) == ["B", "D"]
def test_sequential_compile_time_bindings():
"""Compile-time bindings may occur after run-time
A compile-time value may depend on variables defined within the
function, so long as those variables are themselves computable at
compile-time.
"""
@R.function
def func(A: R.Tensor([16], "int32"), B: R.Tensor([16], "int32")):
R.func_attr({"num_input": 1})
C = R.add(B, B)
D = R.add(C, C)
E = R.add(D, D)
F = R.add(E, A)
return F
assert _analyze_func(func) == ["B", "C", "D", "E"]
def test_dataflow_vars():
"""Compile-time bindings may occur in dataflow blocks"""
@R.function
def func(A: R.Tensor([16], "int32"), B: R.Tensor([16], "int32")):
R.func_attr({"num_input": 1})
with R.dataflow():
C = R.add(B, B)
D = R.add(C, C)
E = R.add(D, D)
F = R.add(E, A)
R.output(F)
return F
assert _analyze_func(func) == ["B", "C", "D", "E"]
def test_compile_time_symbolic_shape():
"""Compile-time bindings may contain symbolic shapes"""
@R.function
def func(A: R.Tensor([1], "int32"), B: R.Tensor(["n"], "int32")):
R.func_attr({"num_input": 1})
n = T.int64()
C: R.Tensor([n], "int32") = R.add(B, B)
D: R.Tensor([], "int32") = R.max(C, axis=0)
E: R.Tensor([1], "int32") = R.add(A, D)
return E
assert _analyze_func(func) == ["B", "C", "D"]
def test_symbolic_variables_from_match_binding():
"""Symbolic vars may be inferred from compile-time bindings"""
@R.function
def func(A: R.Tensor(ndim=1, dtype="int32"), B: R.Tensor(ndim=1, dtype="int32")):
R.func_attr({"num_input": 1})
n = T.int64()
m = T.int64()
A2 = R.match_cast(A, R.Tensor([n], "int32"))
B2 = R.match_cast(B, R.Tensor([m], "int32"))
C = R.add(B2, B2)
D = R.max(C, axis=0)
E = R.max(A2, axis=0)
F = R.add(D, E)
return F
assert _analyze_func(func) == ["B", "B2", "C", "D"]
def test_compile_time_expressions_may_not_use_runtime_symbolic_variables():
"""Symbolic vars may be inferred from compile-time bindings
Here, `C` uses the symbolic variable `m`, which can be inferred
from the shape of `B` and is known at compile-time. However, `D`
uses the symbolic variable `n`, which cannot be inferred without
first knowing `A`, and is therefore unknown at compile-time.
"""
@R.function
def func(A: R.Tensor(["n"], "int32"), B: R.Tensor(["m"], "int32")):
R.func_attr({"num_input": 1})
n = T.int64()
m = T.int64()
C = R.ones([m], "int32")
D = R.ones([n], "int32")
E = (C, D)
return E
assert _analyze_func(func) == ["B", "C"]
def test_compile_time_expressions_may_infer_same_variable_as_run_time():
"""Symbolic vars may be inferred from compile-time bindings
A symbolic variable may be inferrable from multiple sources.
Here, while `n` can be inferred from the runtime parameter `A`, it
can also be inferred from the compile-time parameter `B`.
"""
@R.function
def func(A: R.Tensor(["n"], "int32"), B: R.Tensor(["n"], "int32")):
R.func_attr({"num_input": 1})
n = T.int64()
C = R.ones([n], "int32")
D = R.ones([n], "int32")
E = (C, D)
return E
assert _analyze_func(func) == ["B", "C", "D", "E"]
def test_compile_time_expressions_may_use_variables_from_match_cast():
"""Symbolic vars may be inferred from compile-time bindings
Here, `C` uses the symbolic variable `m`, which can be inferred
from the shape of `B` and is known at compile-time. However, `D`
uses the symbolic variable `n`, which cannot be inferred without
first knowing `A`, and is therefore unknown at compile-time.
"""
@R.function
def func(A: R.Tensor(["n"], "int32"), B: R.Tensor(ndim=1, dtype="int32")):
R.func_attr({"num_input": 1})
n = T.int64()
m = T.int64()
B2 = R.match_cast(B, R.Tensor([m], "int32"))
C = R.ones([m], "int32")
D = R.ones([n], "int32")
E = (C, D)
return E
assert _analyze_func(func) == ["B", "B2", "C"]
if __name__ == "__main__":
tvm.testing.main()