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/* Apache License, Version 2.0 */
#include "testing/testing.h"
#include "FN_multi_function_builder.hh"
#include "FN_multi_function_network.hh"
#include "FN_multi_function_network_evaluation.hh"
namespace blender::fn::tests {
namespace {
TEST(multi_function_network, Test1)
{
CustomMF_SI_SO<int, int> add_10_fn("add 10", [](int value) { return value + 10; });
CustomMF_SI_SI_SO<int, int, int> multiply_fn("multiply", [](int a, int b) { return a * b; });
MFNetwork network;
MFNode &node1 = network.add_function(add_10_fn);
MFNode &node2 = network.add_function(multiply_fn);
MFOutputSocket &input_socket = network.add_input("Input", MFDataType::ForSingle<int>());
MFInputSocket &output_socket = network.add_output("Output", MFDataType::ForSingle<int>());
network.add_link(node1.output(0), node2.input(0));
network.add_link(node1.output(0), node2.input(1));
network.add_link(node2.output(0), output_socket);
network.add_link(input_socket, node1.input(0));
MFNetworkEvaluator network_fn{{&input_socket}, {&output_socket}};
{
Array<int> values = {4, 6, 1, 2, 0};
Array<int> results(values.size(), 0);
MFParamsBuilder params(network_fn, values.size());
params.add_readonly_single_input(values.as_span());
params.add_uninitialized_single_output(results.as_mutable_span());
MFContextBuilder context;
network_fn.call({0, 2, 3, 4}, params, context);
EXPECT_EQ(results[0], 14 * 14);
EXPECT_EQ(results[1], 0);
EXPECT_EQ(results[2], 11 * 11);
EXPECT_EQ(results[3], 12 * 12);
EXPECT_EQ(results[4], 10 * 10);
}
{
int value = 3;
Array<int> results(5, 0);
MFParamsBuilder params(network_fn, results.size());
params.add_readonly_single_input(&value);
params.add_uninitialized_single_output(results.as_mutable_span());
MFContextBuilder context;
network_fn.call({1, 2, 4}, params, context);
EXPECT_EQ(results[0], 0);
EXPECT_EQ(results[1], 13 * 13);
EXPECT_EQ(results[2], 13 * 13);
EXPECT_EQ(results[3], 0);
EXPECT_EQ(results[4], 13 * 13);
}
}
class ConcatVectorsFunction : public MultiFunction {
public:
ConcatVectorsFunction()
{
static MFSignature signature = create_signature();
this->set_signature(&signature);
}
static MFSignature create_signature()
{
MFSignatureBuilder signature{"Concat Vectors"};
signature.vector_mutable<int>("A");
signature.vector_input<int>("B");
return signature.build();
}
void call(IndexMask mask, MFParams params, MFContext UNUSED(context)) const override
{
GVectorArray &a = params.vector_mutable(0);
const GVVectorArray &b = params.readonly_vector_input(1);
a.extend(mask, b);
}
};
class AppendFunction : public MultiFunction {
public:
AppendFunction()
{
static MFSignature signature = create_signature();
this->set_signature(&signature);
}
static MFSignature create_signature()
{
MFSignatureBuilder signature{"Append"};
signature.vector_mutable<int>("Vector");
signature.single_input<int>("Value");
return signature.build();
}
void call(IndexMask mask, MFParams params, MFContext UNUSED(context)) const override
{
GVectorArray_TypedMutableRef<int> vectors = params.vector_mutable<int>(0);
const VArray<int> &values = params.readonly_single_input<int>(1);
for (int64_t i : mask) {
vectors.append(i, values[i]);
}
}
};
class SumVectorFunction : public MultiFunction {
public:
SumVectorFunction()
{
static MFSignature signature = create_signature();
this->set_signature(&signature);
}
static MFSignature create_signature()
{
MFSignatureBuilder signature{"Sum Vectors"};
signature.vector_input<int>("Vector");
signature.single_output<int>("Sum");
return signature.build();
}
void call(IndexMask mask, MFParams params, MFContext UNUSED(context)) const override
{
const VVectorArray<int> &vectors = params.readonly_vector_input<int>(0);
MutableSpan<int> sums = params.uninitialized_single_output<int>(1);
for (int64_t i : mask) {
int sum = 0;
for (int j : IndexRange(vectors.get_vector_size(i))) {
sum += vectors.get_vector_element(i, j);
}
sums[i] = sum;
}
}
};
class CreateRangeFunction : public MultiFunction {
public:
CreateRangeFunction()
{
static MFSignature signature = create_signature();
this->set_signature(&signature);
}
static MFSignature create_signature()
{
MFSignatureBuilder signature{"Create Range"};
signature.single_input<int>("Size");
signature.vector_output<int>("Range");
return signature.build();
}
void call(IndexMask mask, MFParams params, MFContext UNUSED(context)) const override
{
const VArray<int> &sizes = params.readonly_single_input<int>(0, "Size");
GVectorArray_TypedMutableRef<int> ranges = params.vector_output<int>(1, "Range");
for (int64_t i : mask) {
int size = sizes[i];
for (int j : IndexRange(size)) {
ranges.append(i, j);
}
}
}
};
TEST(multi_function_network, Test2)
{
CustomMF_SI_SO<int, int> add_3_fn("add 3", [](int value) { return value + 3; });
ConcatVectorsFunction concat_vectors_fn;
AppendFunction append_fn;
SumVectorFunction sum_fn;
CreateRangeFunction create_range_fn;
MFNetwork network;
MFOutputSocket &input1 = network.add_input("Input 1", MFDataType::ForVector<int>());
MFOutputSocket &input2 = network.add_input("Input 2", MFDataType::ForSingle<int>());
MFInputSocket &output1 = network.add_output("Output 1", MFDataType::ForVector<int>());
MFInputSocket &output2 = network.add_output("Output 2", MFDataType::ForSingle<int>());
MFNode &node1 = network.add_function(add_3_fn);
MFNode &node2 = network.add_function(create_range_fn);
MFNode &node3 = network.add_function(concat_vectors_fn);
MFNode &node4 = network.add_function(sum_fn);
MFNode &node5 = network.add_function(append_fn);
MFNode &node6 = network.add_function(sum_fn);
network.add_link(input2, node1.input(0));
network.add_link(node1.output(0), node2.input(0));
network.add_link(node2.output(0), node3.input(1));
network.add_link(input1, node3.input(0));
network.add_link(input1, node4.input(0));
network.add_link(node4.output(0), node5.input(1));
network.add_link(node3.output(0), node5.input(0));
network.add_link(node5.output(0), node6.input(0));
network.add_link(node3.output(0), output1);
network.add_link(node6.output(0), output2);
// std::cout << network.to_dot() << "\n\n";
MFNetworkEvaluator network_fn{{&input1, &input2}, {&output1, &output2}};
{
Array<int> input_value_1 = {3, 6};
int input_value_2 = 4;
GVectorArray output_value_1(CPPType::get<int32_t>(), 5);
Array<int> output_value_2(5, -1);
MFParamsBuilder params(network_fn, 5);
GVVectorArray_For_SingleGSpan inputs_1{input_value_1.as_span(), 5};
params.add_readonly_vector_input(inputs_1);
params.add_readonly_single_input(&input_value_2);
params.add_vector_output(output_value_1);
params.add_uninitialized_single_output(output_value_2.as_mutable_span());
MFContextBuilder context;
network_fn.call({1, 2, 4}, params, context);
EXPECT_EQ(output_value_1[0].size(), 0);
EXPECT_EQ(output_value_1[1].size(), 9);
EXPECT_EQ(output_value_1[2].size(), 9);
EXPECT_EQ(output_value_1[3].size(), 0);
EXPECT_EQ(output_value_1[4].size(), 9);
EXPECT_EQ(output_value_2[0], -1);
EXPECT_EQ(output_value_2[1], 39);
EXPECT_EQ(output_value_2[2], 39);
EXPECT_EQ(output_value_2[3], -1);
EXPECT_EQ(output_value_2[4], 39);
}
{
GVectorArray input_value_1(CPPType::get<int32_t>(), 3);
GVectorArray_TypedMutableRef<int> input_value_1_ref{input_value_1};
input_value_1_ref.extend(0, {3, 4, 5});
input_value_1_ref.extend(1, {1, 2});
Array<int> input_value_2 = {4, 2, 3};
GVectorArray output_value_1(CPPType::get<int32_t>(), 3);
Array<int> output_value_2(3, -1);
MFParamsBuilder params(network_fn, 3);
params.add_readonly_vector_input(input_value_1);
params.add_readonly_single_input(input_value_2.as_span());
params.add_vector_output(output_value_1);
params.add_uninitialized_single_output(output_value_2.as_mutable_span());
MFContextBuilder context;
network_fn.call({0, 1, 2}, params, context);
EXPECT_EQ(output_value_1[0].size(), 10);
EXPECT_EQ(output_value_1[1].size(), 7);
EXPECT_EQ(output_value_1[2].size(), 6);
EXPECT_EQ(output_value_2[0], 45);
EXPECT_EQ(output_value_2[1], 16);
EXPECT_EQ(output_value_2[2], 15);
}
}
} // namespace
} // namespace blender::fn::tests
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