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onnx--onnx/onnx/test/cpp/shape_inference_test.cc
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chore: import upstream snapshot with attribution
2026-07-13 12:41:19 +08:00

661 lines
20 KiB
C++

// Copyright (c) ONNX Project Contributors
//
// SPDX-License-Identifier: Apache-2.0
#include <iostream>
#include <string>
#include <unordered_map>
#include <vector>
#include "gtest/gtest.h"
#include "onnx/defs/parser.h"
#include "onnx/defs/schema.h"
#include "onnx/defs/shape_inference.h"
#include "onnx/shape_inference/implementation.h"
namespace ONNX_NAMESPACE {
// onnx/defs/controlflow/old.cc
// NOLINTNEXTLINE(misc-use-internal-linkage)
void ScanInferenceFunction_opset8(InferenceContext& ctx);
// onnx/defs/controlflow/defs.cc
// NOLINTNEXTLINE(misc-use-internal-linkage)
void ScanInferenceFunction(InferenceContext& ctx);
namespace Test {
template <class Type>
static void CreateDims(Type& proto, int num_dims) {
auto mutable_shape = proto.mutable_shape();
mutable_shape->clear_dim();
for (int i = 0; i < num_dims; ++i)
mutable_shape->add_dim();
}
template <class Type>
static void SetDimValues(Type& proto, const std::vector<int>& values) {
auto mutable_shape = proto.mutable_shape();
EXPECT_EQ(static_cast<size_t>(mutable_shape->dim_size()), values.size());
int idx = 0;
for (auto value : values) {
auto mutable_dim = mutable_shape->mutable_dim(idx++);
if (value != -1)
mutable_dim->set_dim_value(value);
}
}
template <class Type>
static void SetDimParams(Type& proto, const std::vector<const std::string*>& values) {
auto mutable_shape = proto.mutable_shape();
EXPECT_EQ(static_cast<size_t>(mutable_shape->dim_size()), values.size());
int idx = 0;
for (const auto* const value : values) {
auto mutable_dim = mutable_shape->mutable_dim(idx++);
if (value)
mutable_dim->set_dim_param(*value);
}
}
template <class Type>
static void Dump(const Type& t) {
auto& s_shape = t.shape();
auto num_dims = s_shape.dim_size();
std::cout << num_dims << " dims. ";
for (int i = 0; i < num_dims; ++i) {
const auto& x = s_shape.dim(0);
auto y = x.has_dim_value();
auto z = x.has_dim_param();
std::cout << "Dim " << i << " Value:" << (y ? ONNX_NAMESPACE::to_string(x.dim_value()) : "<unset>")
<< ", Param:" << (z ? x.dim_param() : "<unset>") << "\n";
}
}
TEST(ShapeInferenceTest, mergeShapeInfo_HasShape) {
// source has shape, target doesn't
{
TypeProto_Tensor source;
TypeProto_Tensor target;
CreateDims(source, 1);
SetDimValues(source, {1});
mergeInShapeInfo(source, target);
Dump(target);
const auto& shape = target.shape();
EXPECT_TRUE(shape.dim_size() == 1 && shape.dim(0).dim_value() == 1);
}
// source has no shape, target does
{
TypeProto_Tensor source;
TypeProto_Tensor target;
CreateDims(target, 1);
SetDimValues(target, {1});
mergeInShapeInfo(source, target);
Dump(target);
const auto& shape = target.shape();
EXPECT_EQ(shape.dim_size() == 1 && shape.dim(0).dim_value(), 1);
}
// source has shape, target doesn't
{
TypeProto_SparseTensor source;
TypeProto_SparseTensor target;
CreateDims(source, 1);
SetDimValues(source, {1});
mergeInShapeInfo(source, target);
Dump(target);
const auto& shape = target.shape();
EXPECT_EQ(shape.dim_size() == 1 && shape.dim(0).dim_value(), 1);
}
// source has no shape, target does
{
TypeProto_SparseTensor source;
TypeProto_SparseTensor target;
CreateDims(target, 1);
SetDimValues(target, {1});
mergeInShapeInfo(source, target);
Dump(target);
const auto& shape = target.shape();
EXPECT_TRUE(shape.dim_size() == 1 && shape.dim(0).dim_value() == 1);
}
}
TEST(ShapeInferenceTest, mergeShapeInfo_PreferValueOverParam) {
std::string param = "A";
// source has value, target has param. prefer value
{
TypeProto_Tensor source;
TypeProto_Tensor target;
CreateDims(source, 1);
SetDimValues(source, {1});
CreateDims(target, 1);
SetDimParams(target, {&param});
mergeInShapeInfo(source, target);
Dump(target);
const auto& shape = target.shape();
EXPECT_TRUE(shape.dim_size() == 1 && shape.dim(0).dim_value() == 1);
}
// source has param, target has value.
{
TypeProto_Tensor source;
TypeProto_Tensor target;
CreateDims(source, 1);
SetDimParams(source, {&param});
CreateDims(target, 1);
SetDimValues(target, {1});
mergeInShapeInfo(source, target);
Dump(target);
const auto& shape = target.shape();
EXPECT_EQ(shape.dim_size() == 1 && shape.dim(0).dim_value(), 1);
}
}
TEST(ShapeInferenceTest, mergeShapeInfo_CombineShapes) {
// merge from both sides, preferring real value over -1
{
TypeProto_Tensor source;
TypeProto_Tensor target;
CreateDims(source, 2);
SetDimValues(source, {-1, 2});
CreateDims(target, 2);
SetDimValues(target, {1, -1});
mergeInShapeInfo(source, target);
Dump(target);
const auto& shape = target.shape();
EXPECT_TRUE(shape.dim(0).dim_value() == 1 && shape.dim(1).dim_value() == 2);
}
{
TypeProto_SparseTensor source;
TypeProto_SparseTensor target;
CreateDims(source, 2);
SetDimValues(source, {-1, 2});
CreateDims(target, 2);
SetDimValues(target, {1, -1});
mergeInShapeInfo(source, target);
Dump(target);
const auto& shape = target.shape();
EXPECT_TRUE(shape.dim(0).dim_value() == 1 && shape.dim(1).dim_value() == 2);
}
// prefer value over param,
{
TypeProto_Tensor source;
TypeProto_Tensor target;
CreateDims(source, 2);
SetDimValues(source, {-1, 2});
CreateDims(target, 2);
SetDimValues(target, {1, 0});
// replace second dim with a param. the value from the source should be
// preferred
const std::string param = "A";
target.mutable_shape()->mutable_dim(1)->set_dim_param(param);
mergeInShapeInfo(source, target);
Dump(target);
const auto& shape = target.shape();
EXPECT_TRUE(shape.dim(0).dim_value() == 1 && shape.dim(1).dim_value() == 2);
}
{
TypeProto_SparseTensor source;
TypeProto_SparseTensor target;
CreateDims(source, 2);
SetDimValues(source, {-1, 2});
CreateDims(target, 2);
SetDimValues(target, {1, 0});
// replace second dim with a param. the value from the source should be
// preferred
const std::string param = "A";
target.mutable_shape()->mutable_dim(1)->set_dim_param(param);
mergeInShapeInfo(source, target);
Dump(target);
const auto& shape = target.shape();
EXPECT_TRUE(shape.dim(0).dim_value() == 1 && shape.dim(1).dim_value() == 2);
}
}
TEST(ShapeInferenceTest, mergeShapeInfo_Mismatches) {
#ifndef ONNX_NO_EXCEPTIONS
// mismatched num dims
{
TypeProto_Tensor source;
TypeProto_Tensor target;
CreateDims(source, 2);
SetDimValues(source, {-1, 2});
CreateDims(target, 3);
SetDimValues(target, {1, -1, 1});
EXPECT_THROW(mergeInShapeInfo(source, target), ONNX_NAMESPACE::InferenceError);
}
{
TypeProto_SparseTensor source;
TypeProto_SparseTensor target;
CreateDims(source, 2);
SetDimValues(source, {-1, 2});
CreateDims(target, 3);
SetDimValues(target, {1, -1, 1});
EXPECT_THROW(mergeInShapeInfo(source, target), ONNX_NAMESPACE::InferenceError);
}
// mismatched dim values
{
TypeProto_Tensor source;
TypeProto_Tensor target;
CreateDims(source, 2);
SetDimValues(source, {2, 2});
CreateDims(target, 2);
SetDimValues(target, {2, 1});
EXPECT_THROW(mergeInShapeInfo(source, target), ONNX_NAMESPACE::InferenceError);
}
{
TypeProto_SparseTensor source;
TypeProto_SparseTensor target;
CreateDims(source, 2);
SetDimValues(source, {2, 2});
CreateDims(target, 2);
SetDimValues(target, {2, 1});
EXPECT_THROW(mergeInShapeInfo(source, target), ONNX_NAMESPACE::InferenceError);
}
#endif
// mismatched param value. prefer target
{
TypeProto_Tensor source;
TypeProto_Tensor target;
const std::string param_a = "A";
const std::string param_b = "B";
CreateDims(source, 1);
SetDimParams(source, {&param_a});
CreateDims(target, 1);
SetDimParams(target, {&param_b});
mergeInShapeInfo(source, target);
const auto& shape = target.shape();
EXPECT_EQ(shape.dim(0).dim_param(), "B");
}
{
TypeProto_SparseTensor source;
TypeProto_SparseTensor target;
const std::string param_a = "A";
const std::string param_b = "B";
CreateDims(source, 1);
SetDimParams(source, {&param_a});
CreateDims(target, 1);
SetDimParams(target, {&param_b});
mergeInShapeInfo(source, target);
const auto& shape = target.shape();
EXPECT_EQ(shape.dim(0).dim_param(), "B");
}
}
// Check subgraph inferencing via GraphInferencer using a Scan
static void doInferencingTest(bool use_scan_opset8) {
OpSchemaRegistry::Instance();
GraphProto subgraph;
// simple tensor without shape info
TypeProto simple_tensor_no_shape;
auto* tensor_type = simple_tensor_no_shape.mutable_tensor_type();
tensor_type->set_elem_type(TensorProto_DataType_FLOAT);
// simple tensor with shape info
TypeProto simple_tensor = simple_tensor_no_shape;
simple_tensor.mutable_tensor_type()->mutable_shape()->add_dim()->set_dim_value(2);
// setup simple graph that can be used with Scan containing two Identity
// nodes. one for the loop state variable. one for the scan output.
{
NodeProto loop_state_identity;
loop_state_identity.set_name("loop_state_identity");
loop_state_identity.set_domain(ONNX_DOMAIN);
loop_state_identity.set_op_type("Identity");
loop_state_identity.set_doc_string("loop state identity");
loop_state_identity.add_input("loop_state_in");
loop_state_identity.add_output("loop_state_out");
*subgraph.add_node() = loop_state_identity;
NodeProto scan_in_out_identity;
scan_in_out_identity.set_name("scan_in_out_identity");
scan_in_out_identity.set_domain(ONNX_DOMAIN);
scan_in_out_identity.set_op_type("Identity");
scan_in_out_identity.set_doc_string("scan identity");
scan_in_out_identity.add_input("scan_in");
scan_in_out_identity.add_output("scan_out");
*subgraph.add_node() = scan_in_out_identity;
ValueInfoProto loop_state_in;
loop_state_in.set_name("loop_state_in");
*loop_state_in.mutable_type() = simple_tensor;
*subgraph.add_input() = loop_state_in;
ValueInfoProto scan_in;
scan_in.set_name("scan_in");
*scan_in.mutable_type() = simple_tensor;
*subgraph.add_input() = scan_in;
ValueInfoProto loop_state_out = loop_state_in;
loop_state_out.set_name("loop_state_out");
*loop_state_out.mutable_type() = simple_tensor_no_shape;
*subgraph.add_output() = loop_state_out;
ValueInfoProto scan_state_out = scan_in;
scan_state_out.set_name("scan_out");
*scan_state_out.mutable_type() = simple_tensor_no_shape;
*subgraph.add_output() = scan_state_out;
}
std::unordered_map<std::string, int> opset_imports;
opset_imports[ONNX_DOMAIN] = 8; // Scan is v8
const std::unordered_map<std::string, TypeProto*> outer_scope_value_types;
shape_inference::SymbolTableImpl symbolTable;
symbolTable.addFromGraph(subgraph);
shape_inference::GraphInferenceContext graphInfCtx(outer_scope_value_types, opset_imports, &symbolTable);
shape_inference::GraphInferencerImpl graphInferencer(subgraph, graphInfCtx);
// loop_state_in and scan_in are the two inputs.
// order in subgraphInputTypes matches their order as graph inputs.
std::vector<const TypeProto*> subgraphInputTypes = {&simple_tensor, &simple_tensor};
std::vector<const TensorProto*> subgraphInputData = {};
ShapeInferenceOptions options{false, 0, false};
auto output = graphInferencer.doInferencing(subgraphInputTypes, subgraphInputData);
// check the subgraph outputs had their shape inferred when we called
// doInferencing directly
EXPECT_EQ(output.size(), 2);
auto checkType = [](const TypeProto& type, const TypeProto_Tensor& expect) {
auto checkDims = [](const TensorShapeProto& l, const TensorShapeProto& r) {
EXPECT_EQ(l.dim_size(), r.dim_size());
for (int i = 0, end = l.dim_size(); i < end; ++i) {
// if (l.dim().Get(i).dim_value() != r.dim().Get(i).dim_value())
// break;
EXPECT_EQ(l.dim().Get(i).dim_value(), r.dim().Get(i).dim_value());
}
};
EXPECT_TRUE(type.has_tensor_type());
EXPECT_EQ(type.tensor_type().elem_type(), expect.elem_type());
checkDims(type.tensor_type().shape(), expect.shape());
};
checkType(*output[0], simple_tensor.tensor_type());
checkType(*output[1], simple_tensor.tensor_type());
// setup Scan node to test subgraph inferencing works as expected when called
// from the operators type/shape inferencing function
NodeProto scan;
{
AttributeProto num_scan_inputs;
num_scan_inputs.set_name("num_scan_inputs");
num_scan_inputs.set_i(1);
AttributeProto body;
body.set_name("body");
*body.mutable_g() = subgraph;
*scan.add_attribute() = num_scan_inputs;
*scan.add_attribute() = body;
scan.set_name("Scan");
scan.set_domain(ONNX_DOMAIN);
scan.set_doc_string("Scan node");
scan.set_op_type("Scan");
if (use_scan_opset8)
scan.add_input(""); // optional sequence lens
scan.add_input("loop_state_start");
scan.add_input("scan_op_in");
scan.add_output("loop_state_final");
scan.add_output("scan_op_out");
}
TypeProto loop_state_in_tensor = simple_tensor_no_shape;
auto* shape = loop_state_in_tensor.mutable_tensor_type()->mutable_shape();
if (use_scan_opset8)
shape->add_dim()->set_dim_value(1); // batch size
shape->add_dim()->set_dim_value(2); // input size. must match subgraph
TypeProto loop_state_out_tensor = loop_state_in_tensor; // should be unchanged
TypeProto scan_in_tensor = simple_tensor_no_shape;
shape = scan_in_tensor.mutable_tensor_type()->mutable_shape();
if (use_scan_opset8)
shape->add_dim()->set_dim_value(1); // batch size
shape->add_dim()->set_dim_value(1); // sequence length
shape->add_dim()->set_dim_value(2); // input size. must match subgraph
TypeProto scan_out_tensor = scan_in_tensor; // should be unchanged
std::unordered_map<std::string, TypeProto*> valueTypesByName;
valueTypesByName["loop_state_start"] = &loop_state_in_tensor;
valueTypesByName["scan_op_in"] = &scan_in_tensor;
shape_inference::InferenceContextImpl ctx(scan, valueTypesByName, {}, {}, options, {}, &graphInfCtx);
if (use_scan_opset8)
ScanInferenceFunction_opset8(ctx);
else
ScanInferenceFunction(ctx);
EXPECT_EQ(ctx.getNumOutputs(), 2);
checkType(*ctx.getOutputType(0), loop_state_out_tensor.tensor_type());
checkType(*ctx.getOutputType(1), scan_out_tensor.tensor_type());
}
// Check subgraph inferencing via GraphInferencer using a Scan (from opset 8)
TEST(GraphInferencerImplTest, Scan8_BasicTest) {
doInferencingTest(true);
}
// Check subgraph inferencing via GraphInferencer using a Scan (from opset 9)
TEST(GraphInferencerImplTest, Scan9_BasicTest) {
doInferencingTest(false);
}
static void ParseAndInfer(ModelProto& model, const char* modelStr) {
OnnxParser parser(modelStr);
auto status = parser.Parse(model);
EXPECT_TRUE(status.IsOK()) << status.ErrorMessage();
EXPECT_TRUE(parser.EndOfInput()) << "Extra unparsed input unexpected.";
ShapeInferenceOptions options{true, 1, true};
ONNX_NAMESPACE::shape_inference::InferShapes(model, ONNX_NAMESPACE::OpSchemaRegistry::Instance(), options);
}
static void RunReshapeShapeInfTest(const char* modelStr, TensorShapeProto& expectedShape) {
ModelProto model;
ParseAndInfer(model, modelStr);
const auto inferredShape = model.graph().output(0).type().tensor_type().shape();
EXPECT_EQ(inferredShape.dim_size(), expectedShape.dim_size());
for (int i = 0; i < inferredShape.dim_size(); i++) {
EXPECT_TRUE(
(inferredShape.dim(i).has_dim_value() && expectedShape.dim(i).has_dim_value()) ||
(inferredShape.dim(i).has_dim_param() && expectedShape.dim(i).has_dim_param()));
EXPECT_TRUE(
inferredShape.dim(i).has_dim_value() ? inferredShape.dim(i).dim_value() == expectedShape.dim(i).dim_value()
: inferredShape.dim(i).dim_param() == expectedShape.dim(i).dim_param());
}
}
TEST(ShapeInferenceTest, ReshapeTestWithShapeAsSymInput) {
const char* modelStr = R"ONNX(
<
ir_version: 8,
opset_import: [ "" : 15],
producer_name: "DataPropagationTest",
producer_version: "1.0",
model_version: 1,
doc_string: "A test model for data propagation."
>
agraph (float[batch_size, 256, 768, 3] x, float[batch_size, 196608] m) => (float[?, ?, ?] z)
{
y = Shape<start = 0, end = 3>(x)
z = Reshape(m, y)
}
)ONNX";
TensorShapeProto expectedShape;
expectedShape.mutable_dim()->Add()->set_dim_param("batch_size");
expectedShape.mutable_dim()->Add()->set_dim_value(256);
expectedShape.mutable_dim()->Add()->set_dim_value(768);
RunReshapeShapeInfTest(modelStr, expectedShape);
}
TEST(ShapeInferenceTest, ReshapeTestWithShapeAsInitializer) {
const char* modelStr = R"ONNX(
<
ir_version: 8,
opset_import: [ "" : 15],
producer_name: "DataPropagationTest",
producer_version: "1.0",
model_version: 1,
doc_string: "A test model for data propagation."
>
agraph (float[1, 196608] m) => (float[?, ?, ?] z)
<int64[3] shape = {1, 768, 256}>
{
z = Reshape(m, shape)
}
)ONNX";
TensorShapeProto expectedShape;
expectedShape.mutable_dim()->Add()->set_dim_value(1);
expectedShape.mutable_dim()->Add()->set_dim_value(768);
expectedShape.mutable_dim()->Add()->set_dim_value(256);
RunReshapeShapeInfTest(modelStr, expectedShape);
}
TEST(ShapeInferenceTest, ReshapeTestWithShapeAsInitializer1) {
const char* modelStr = R"ONNX(
<
ir_version: 8,
opset_import: [ "" : 15],
producer_name: "DataPropagationTest",
producer_version: "1.0",
model_version: 1,
doc_string: "A test model for data propagation."
>
agraph (float[1, 196608] m) => (float[?, ?, ?] z)
<int64[3] shape = {1, -1, 256}>
{
z = Reshape(m, shape)
}
)ONNX";
TensorShapeProto expectedShape;
expectedShape.mutable_dim()->Add()->set_dim_value(1);
expectedShape.mutable_dim()->Add()->set_dim_value(768);
expectedShape.mutable_dim()->Add()->set_dim_value(256);
RunReshapeShapeInfTest(modelStr, expectedShape);
}
TEST(ShapeInferenceTest, CheckShapesAndTypesTest) {
#ifndef ONNX_NO_EXCEPTIONS
// Tensor element types mismatch should cause an exception.
TypeProto tensor_infer;
auto* tensor_infer_type = tensor_infer.mutable_tensor_type();
tensor_infer_type->set_elem_type(TensorProto_DataType_FLOAT);
TypeProto tensor_exist;
auto* tensor_exist_type = tensor_exist.mutable_tensor_type();
tensor_exist_type->set_elem_type(TensorProto_DataType_UINT8);
EXPECT_THROW(shape_inference::checkShapesAndTypes(tensor_infer, tensor_exist), ONNX_NAMESPACE::InferenceError);
#endif
}
TEST(ShapeInferenceTest, CustomOpTest) {
const char* modelStr = R"ONNX(
<ir_version: 8, opset_import: ["" : 15, "custom.domain" : 1]>
agraph (float[256, 768, 3] x) => (z1, z2)
{
z1 = custom.domain.CustomOp (x)
# Inference cannot determine the type/shape of z1
z2 = Abs(x)
# Inference SHOULD determine the type/shape of z2 (same as that of x)
}
)ONNX";
ModelProto model;
ParseAndInfer(model, modelStr);
const auto& z1_value_info = model.graph().output(0);
// Check no inferred type for z1 (It's a quirk of the implementation that it
// has a dummy TypeProto, but it should have no values filled in.)
ASSERT_TRUE(z1_value_info.has_type());
ASSERT_FALSE(z1_value_info.type().has_tensor_type());
// Check inferred type for z2:
const auto& z2_value_info = model.graph().output(1);
ASSERT_TRUE(z2_value_info.has_type());
ASSERT_TRUE(z2_value_info.type().has_tensor_type());
EXPECT_EQ(z2_value_info.type().tensor_type().elem_type(), TensorProto_DataType_FLOAT);
EXPECT_EQ(z2_value_info.type().tensor_type().shape().dim_size(), 3);
EXPECT_EQ(z2_value_info.type().tensor_type().shape().dim(0).dim_value(), 256);
EXPECT_EQ(z2_value_info.type().tensor_type().shape().dim(1).dim_value(), 768);
EXPECT_EQ(z2_value_info.type().tensor_type().shape().dim(2).dim_value(), 3);
}
} // namespace Test
} // namespace ONNX_NAMESPACE