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android / platform / packages / modules / NeuralNetworks / c49850065cf80a64f1a99307fdd68f1301fe2582 / . / runtime / test / generated / spec_V1_2 / cts / pad_all_dims.model.cpp
blob: 6973246f2bfa20cfa2a28946a5f8e39c12641056 [file] [log] [blame]
// Generated from pad_all_dims.mod.py
// DO NOT EDIT
// clang-format off
#include "TestGenerated.h"
namespace generated_tests::pad_all_dims {
void CreateModel(Model *model) {
OperandType type0(Type::TENSOR_FLOAT32, {1, 1, 2, 3});
OperandType type1(Type::TENSOR_INT32, {4, 2});
OperandType type2(Type::TENSOR_FLOAT32, {4, 8, 8, 6});
// Phase 1, operands
auto input0 = model->addOperand(&type0);
auto paddings = model->addOperand(&type1);
auto output0 = model->addOperand(&type2);
// Phase 2, operations
static int32_t paddings_init[] = {1, 2, 3, 4, 3, 3, 2, 1};
model->setOperandValue(paddings, paddings_init, sizeof(int32_t) * 8);
model->addOperation(ANEURALNETWORKS_PAD, {input0, paddings}, {output0});
// Phase 3, inputs and outputs
model->identifyInputsAndOutputs(
{input0},
{output0});
assert(model->isValid());
}
bool is_ignored(int i) {
static std::set<int> ignore = {};
return ignore.find(i) != ignore.end();
}
} // namespace generated_tests::pad_all_dims
namespace generated_tests::pad_all_dims {
void CreateModel_dynamic_output_shape(Model *model) {
OperandType type0(Type::TENSOR_FLOAT32, {1, 1, 2, 3});
OperandType type1(Type::TENSOR_INT32, {4, 2});
OperandType type3(Type::TENSOR_FLOAT32, {0, 0, 0, 0});
// Phase 1, operands
auto input0 = model->addOperand(&type0);
auto paddings = model->addOperand(&type1);
auto output0 = model->addOperand(&type3);
// Phase 2, operations
static int32_t paddings_init[] = {1, 2, 3, 4, 3, 3, 2, 1};
model->setOperandValue(paddings, paddings_init, sizeof(int32_t) * 8);
model->addOperation(ANEURALNETWORKS_PAD, {input0, paddings}, {output0});
// Phase 3, inputs and outputs
model->identifyInputsAndOutputs(
{input0},
{output0});
assert(model->isValid());
}
bool is_ignored_dynamic_output_shape(int i) {
static std::set<int> ignore = {};
return ignore.find(i) != ignore.end();
}
} // namespace generated_tests::pad_all_dims
namespace generated_tests::pad_all_dims {
void CreateModel_all_inputs_as_internal(Model *model) {
OperandType type0(Type::TENSOR_FLOAT32, {1, 1, 2, 3});
OperandType type1(Type::TENSOR_INT32, {4, 2});
OperandType type2(Type::TENSOR_FLOAT32, {4, 8, 8, 6});
OperandType type4(Type::TENSOR_FLOAT32, {1});
OperandType type5(Type::INT32, {});
// Phase 1, operands
auto input0 = model->addOperand(&type0);
auto paddings = model->addOperand(&type1);
auto output0 = model->addOperand(&type2);
auto input0_tmp = model->addOperand(&type0);
auto dummy = model->addOperand(&type4);
auto param = model->addOperand(&type5);
// Phase 2, operations
static int32_t paddings_init[] = {1, 2, 3, 4, 3, 3, 2, 1};
model->setOperandValue(paddings, paddings_init, sizeof(int32_t) * 8);
static float dummy_init[] = {0.0f};
model->setOperandValue(dummy, dummy_init, sizeof(float) * 1);
static int32_t param_init[] = {0};
model->setOperandValue(param, param_init, sizeof(int32_t) * 1);
model->addOperation(ANEURALNETWORKS_ADD, {input0_tmp, dummy, param}, {input0});
model->addOperation(ANEURALNETWORKS_PAD, {input0, paddings}, {output0});
// Phase 3, inputs and outputs
model->identifyInputsAndOutputs(
{input0_tmp},
{output0});
assert(model->isValid());
}
bool is_ignored_all_inputs_as_internal(int i) {
static std::set<int> ignore = {};
return ignore.find(i) != ignore.end();
}
} // namespace generated_tests::pad_all_dims
namespace generated_tests::pad_all_dims {
void CreateModel_all_inputs_as_internal_dynamic_output_shape(Model *model) {
OperandType type0(Type::TENSOR_FLOAT32, {1, 1, 2, 3});
OperandType type1(Type::TENSOR_INT32, {4, 2});
OperandType type3(Type::TENSOR_FLOAT32, {0, 0, 0, 0});
OperandType type4(Type::TENSOR_FLOAT32, {1});
OperandType type5(Type::INT32, {});
// Phase 1, operands
auto input0 = model->addOperand(&type0);
auto paddings = model->addOperand(&type1);
auto output0 = model->addOperand(&type3);
auto input0_tmp = model->addOperand(&type0);
auto dummy1 = model->addOperand(&type4);
auto param1 = model->addOperand(&type5);
// Phase 2, operations
static int32_t paddings_init[] = {1, 2, 3, 4, 3, 3, 2, 1};
model->setOperandValue(paddings, paddings_init, sizeof(int32_t) * 8);
static float dummy1_init[] = {0.0f};
model->setOperandValue(dummy1, dummy1_init, sizeof(float) * 1);
static int32_t param1_init[] = {0};
model->setOperandValue(param1, param1_init, sizeof(int32_t) * 1);
model->addOperation(ANEURALNETWORKS_ADD, {input0_tmp, dummy1, param1}, {input0});
model->addOperation(ANEURALNETWORKS_PAD, {input0, paddings}, {output0});
// Phase 3, inputs and outputs
model->identifyInputsAndOutputs(
{input0_tmp},
{output0});
assert(model->isValid());
}
bool is_ignored_all_inputs_as_internal_dynamic_output_shape(int i) {
static std::set<int> ignore = {};
return ignore.find(i) != ignore.end();
}
} // namespace generated_tests::pad_all_dims
namespace generated_tests::pad_all_dims {
void CreateModel_all_tensors_as_inputs(Model *model) {
OperandType type0(Type::TENSOR_FLOAT32, {1, 1, 2, 3});
OperandType type1(Type::TENSOR_INT32, {4, 2});
OperandType type2(Type::TENSOR_FLOAT32, {4, 8, 8, 6});
// Phase 1, operands
auto input0 = model->addOperand(&type0);
auto paddings = model->addOperand(&type1);
auto output0 = model->addOperand(&type2);
// Phase 2, operations
model->addOperation(ANEURALNETWORKS_PAD, {input0, paddings}, {output0});
// Phase 3, inputs and outputs
model->identifyInputsAndOutputs(
{input0, paddings},
{output0});
assert(model->isValid());
}
bool is_ignored_all_tensors_as_inputs(int i) {
static std::set<int> ignore = {};
return ignore.find(i) != ignore.end();
}
} // namespace generated_tests::pad_all_dims
namespace generated_tests::pad_all_dims {
void CreateModel_all_tensors_as_inputs_dynamic_output_shape(Model *model) {
OperandType type0(Type::TENSOR_FLOAT32, {1, 1, 2, 3});
OperandType type1(Type::TENSOR_INT32, {4, 2});
OperandType type3(Type::TENSOR_FLOAT32, {0, 0, 0, 0});
// Phase 1, operands
auto input0 = model->addOperand(&type0);
auto paddings = model->addOperand(&type1);
auto output0 = model->addOperand(&type3);
// Phase 2, operations
model->addOperation(ANEURALNETWORKS_PAD, {input0, paddings}, {output0});
// Phase 3, inputs and outputs
model->identifyInputsAndOutputs(
{input0, paddings},
{output0});
assert(model->isValid());
}
bool is_ignored_all_tensors_as_inputs_dynamic_output_shape(int i) {
static std::set<int> ignore = {};
return ignore.find(i) != ignore.end();
}
} // namespace generated_tests::pad_all_dims
namespace generated_tests::pad_all_dims {
void CreateModel_all_tensors_as_inputs_all_inputs_as_internal(Model *model) {
OperandType type0(Type::TENSOR_FLOAT32, {1, 1, 2, 3});
OperandType type1(Type::TENSOR_INT32, {4, 2});
OperandType type2(Type::TENSOR_FLOAT32, {4, 8, 8, 6});
OperandType type4(Type::TENSOR_FLOAT32, {1});
OperandType type5(Type::INT32, {});
// Phase 1, operands
auto input0 = model->addOperand(&type0);
auto paddings = model->addOperand(&type1);
auto output0 = model->addOperand(&type2);
auto input0_tmp = model->addOperand(&type0);
auto dummy2 = model->addOperand(&type4);
auto param2 = model->addOperand(&type5);
// Phase 2, operations
static float dummy2_init[] = {0.0f};
model->setOperandValue(dummy2, dummy2_init, sizeof(float) * 1);
static int32_t param2_init[] = {0};
model->setOperandValue(param2, param2_init, sizeof(int32_t) * 1);
model->addOperation(ANEURALNETWORKS_ADD, {input0_tmp, dummy2, param2}, {input0});
model->addOperation(ANEURALNETWORKS_PAD, {input0, paddings}, {output0});
// Phase 3, inputs and outputs
model->identifyInputsAndOutputs(
{paddings, input0_tmp},
{output0});
assert(model->isValid());
}
bool is_ignored_all_tensors_as_inputs_all_inputs_as_internal(int i) {
static std::set<int> ignore = {};
return ignore.find(i) != ignore.end();
}
} // namespace generated_tests::pad_all_dims
namespace generated_tests::pad_all_dims {
void CreateModel_all_tensors_as_inputs_all_inputs_as_internal_dynamic_output_shape(Model *model) {
OperandType type0(Type::TENSOR_FLOAT32, {1, 1, 2, 3});
OperandType type1(Type::TENSOR_INT32, {4, 2});
OperandType type3(Type::TENSOR_FLOAT32, {0, 0, 0, 0});
OperandType type4(Type::TENSOR_FLOAT32, {1});
OperandType type5(Type::INT32, {});
// Phase 1, operands
auto input0 = model->addOperand(&type0);
auto paddings = model->addOperand(&type1);
auto output0 = model->addOperand(&type3);
auto input0_tmp = model->addOperand(&type0);
auto dummy3 = model->addOperand(&type4);
auto param3 = model->addOperand(&type5);
// Phase 2, operations
static float dummy3_init[] = {0.0f};
model->setOperandValue(dummy3, dummy3_init, sizeof(float) * 1);
static int32_t param3_init[] = {0};
model->setOperandValue(param3, param3_init, sizeof(int32_t) * 1);
model->addOperation(ANEURALNETWORKS_ADD, {input0_tmp, dummy3, param3}, {input0});
model->addOperation(ANEURALNETWORKS_PAD, {input0, paddings}, {output0});
// Phase 3, inputs and outputs
model->identifyInputsAndOutputs(
{paddings, input0_tmp},
{output0});
assert(model->isValid());
}
bool is_ignored_all_tensors_as_inputs_all_inputs_as_internal_dynamic_output_shape(int i) {
static std::set<int> ignore = {};
return ignore.find(i) != ignore.end();
}
} // namespace generated_tests::pad_all_dims
namespace generated_tests::pad_all_dims {
void CreateModel_float16(Model *model) {
OperandType type1(Type::TENSOR_INT32, {4, 2});
OperandType type6(Type::TENSOR_FLOAT16, {1, 1, 2, 3});
OperandType type7(Type::TENSOR_FLOAT16, {4, 8, 8, 6});
// Phase 1, operands
auto input0 = model->addOperand(&type6);
auto paddings = model->addOperand(&type1);
auto output0 = model->addOperand(&type7);
// Phase 2, operations
static int32_t paddings_init[] = {1, 2, 3, 4, 3, 3, 2, 1};
model->setOperandValue(paddings, paddings_init, sizeof(int32_t) * 8);
model->addOperation(ANEURALNETWORKS_PAD, {input0, paddings}, {output0});
// Phase 3, inputs and outputs
model->identifyInputsAndOutputs(
{input0},
{output0});
assert(model->isValid());
}
bool is_ignored_float16(int i) {
static std::set<int> ignore = {};
return ignore.find(i) != ignore.end();
}
} // namespace generated_tests::pad_all_dims
namespace generated_tests::pad_all_dims {
void CreateModel_float16_dynamic_output_shape(Model *model) {
OperandType type1(Type::TENSOR_INT32, {4, 2});
OperandType type6(Type::TENSOR_FLOAT16, {1, 1, 2, 3});
OperandType type8(Type::TENSOR_FLOAT16, {0, 0, 0, 0});
// Phase 1, operands
auto input0 = model->addOperand(&type6);
auto paddings = model->addOperand(&type1);
auto output0 = model->addOperand(&type8);
// Phase 2, operations
static int32_t paddings_init[] = {1, 2, 3, 4, 3, 3, 2, 1};
model->setOperandValue(paddings, paddings_init, sizeof(int32_t) * 8);
model->addOperation(ANEURALNETWORKS_PAD, {input0, paddings}, {output0});
// Phase 3, inputs and outputs
model->identifyInputsAndOutputs(
{input0},
{output0});
assert(model->isValid());
}
bool is_ignored_float16_dynamic_output_shape(int i) {
static std::set<int> ignore = {};
return ignore.find(i) != ignore.end();
}
} // namespace generated_tests::pad_all_dims
namespace generated_tests::pad_all_dims {
void CreateModel_float16_all_inputs_as_internal(Model *model) {
OperandType type1(Type::TENSOR_INT32, {4, 2});
OperandType type10(Type::TENSOR_FLOAT16, {1});
OperandType type5(Type::INT32, {});
OperandType type7(Type::TENSOR_FLOAT16, {4, 8, 8, 6});
OperandType type9(Type::TENSOR_FLOAT16, {1, 1, 2, 3});
// Phase 1, operands
auto input0 = model->addOperand(&type9);
auto paddings = model->addOperand(&type1);
auto output0 = model->addOperand(&type7);
auto input0_tmp = model->addOperand(&type9);
auto dummy4 = model->addOperand(&type10);
auto param4 = model->addOperand(&type5);
// Phase 2, operations
static int32_t paddings_init[] = {1, 2, 3, 4, 3, 3, 2, 1};
model->setOperandValue(paddings, paddings_init, sizeof(int32_t) * 8);
static _Float16 dummy4_init[] = {0.0f};
model->setOperandValue(dummy4, dummy4_init, sizeof(_Float16) * 1);
static int32_t param4_init[] = {0};
model->setOperandValue(param4, param4_init, sizeof(int32_t) * 1);
model->addOperation(ANEURALNETWORKS_ADD, {input0_tmp, dummy4, param4}, {input0});
model->addOperation(ANEURALNETWORKS_PAD, {input0, paddings}, {output0});
// Phase 3, inputs and outputs
model->identifyInputsAndOutputs(
{input0_tmp},
{output0});
assert(model->isValid());
}
bool is_ignored_float16_all_inputs_as_internal(int i) {
static std::set<int> ignore = {};
return ignore.find(i) != ignore.end();
}
} // namespace generated_tests::pad_all_dims
namespace generated_tests::pad_all_dims {
void CreateModel_float16_all_inputs_as_internal_dynamic_output_shape(Model *model) {
OperandType type1(Type::TENSOR_INT32, {4, 2});
OperandType type10(Type::TENSOR_FLOAT16, {1});
OperandType type5(Type::INT32, {});
OperandType type8(Type::TENSOR_FLOAT16, {0, 0, 0, 0});
OperandType type9(Type::TENSOR_FLOAT16, {1, 1, 2, 3});
// Phase 1, operands
auto input0 = model->addOperand(&type9);
auto paddings = model->addOperand(&type1);
auto output0 = model->addOperand(&type8);
auto input0_tmp = model->addOperand(&type9);
auto dummy5 = model->addOperand(&type10);
auto param5 = model->addOperand(&type5);
// Phase 2, operations
static int32_t paddings_init[] = {1, 2, 3, 4, 3, 3, 2, 1};
model->setOperandValue(paddings, paddings_init, sizeof(int32_t) * 8);
static _Float16 dummy5_init[] = {0.0f};
model->setOperandValue(dummy5, dummy5_init, sizeof(_Float16) * 1);
static int32_t param5_init[] = {0};
model->setOperandValue(param5, param5_init, sizeof(int32_t) * 1);
model->addOperation(ANEURALNETWORKS_ADD, {input0_tmp, dummy5, param5}, {input0});
model->addOperation(ANEURALNETWORKS_PAD, {input0, paddings}, {output0});
// Phase 3, inputs and outputs
model->identifyInputsAndOutputs(
{input0_tmp},
{output0});
assert(model->isValid());
}
bool is_ignored_float16_all_inputs_as_internal_dynamic_output_shape(int i) {
static std::set<int> ignore = {};
return ignore.find(i) != ignore.end();
}
} // namespace generated_tests::pad_all_dims
namespace generated_tests::pad_all_dims {
void CreateModel_float16_all_tensors_as_inputs(Model *model) {
OperandType type1(Type::TENSOR_INT32, {4, 2});
OperandType type6(Type::TENSOR_FLOAT16, {1, 1, 2, 3});
OperandType type7(Type::TENSOR_FLOAT16, {4, 8, 8, 6});
// Phase 1, operands
auto input0 = model->addOperand(&type6);
auto paddings = model->addOperand(&type1);
auto output0 = model->addOperand(&type7);
// Phase 2, operations
model->addOperation(ANEURALNETWORKS_PAD, {input0, paddings}, {output0});
// Phase 3, inputs and outputs
model->identifyInputsAndOutputs(
{input0, paddings},
{output0});
assert(model->isValid());
}
bool is_ignored_float16_all_tensors_as_inputs(int i) {
static std::set<int> ignore = {};
return ignore.find(i) != ignore.end();
}
} // namespace generated_tests::pad_all_dims
namespace generated_tests::pad_all_dims {
void CreateModel_float16_all_tensors_as_inputs_dynamic_output_shape(Model *model) {
OperandType type1(Type::TENSOR_INT32, {4, 2});
OperandType type6(Type::TENSOR_FLOAT16, {1, 1, 2, 3});
OperandType type8(Type::TENSOR_FLOAT16, {0, 0, 0, 0});
// Phase 1, operands
auto input0 = model->addOperand(&type6);
auto paddings = model->addOperand(&type1);
auto output0 = model->addOperand(&type8);
// Phase 2, operations
model->addOperation(ANEURALNETWORKS_PAD, {input0, paddings}, {output0});
// Phase 3, inputs and outputs
model->identifyInputsAndOutputs(
{input0, paddings},
{output0});
assert(model->isValid());
}
bool is_ignored_float16_all_tensors_as_inputs_dynamic_output_shape(int i) {
static std::set<int> ignore = {};
return ignore.find(i) != ignore.end();
}
} // namespace generated_tests::pad_all_dims
namespace generated_tests::pad_all_dims {
void CreateModel_float16_all_tensors_as_inputs_all_inputs_as_internal(Model *model) {
OperandType type1(Type::TENSOR_INT32, {4, 2});
OperandType type10(Type::TENSOR_FLOAT16, {1});
OperandType type5(Type::INT32, {});
OperandType type7(Type::TENSOR_FLOAT16, {4, 8, 8, 6});
OperandType type9(Type::TENSOR_FLOAT16, {1, 1, 2, 3});
// Phase 1, operands
auto input0 = model->addOperand(&type9);
auto paddings = model->addOperand(&type1);
auto output0 = model->addOperand(&type7);
auto input0_tmp = model->addOperand(&type9);
auto dummy6 = model->addOperand(&type10);
auto param6 = model->addOperand(&type5);
// Phase 2, operations
static _Float16 dummy6_init[] = {0.0f};
model->setOperandValue(dummy6, dummy6_init, sizeof(_Float16) * 1);
static int32_t param6_init[] = {0};
model->setOperandValue(param6, param6_init, sizeof(int32_t) * 1);
model->addOperation(ANEURALNETWORKS_ADD, {input0_tmp, dummy6, param6}, {input0});
model->addOperation(ANEURALNETWORKS_PAD, {input0, paddings}, {output0});
// Phase 3, inputs and outputs
model->identifyInputsAndOutputs(
{paddings, input0_tmp},
{output0});
assert(model->isValid());
}
bool is_ignored_float16_all_tensors_as_inputs_all_inputs_as_internal(int i) {
static std::set<int> ignore = {};
return ignore.find(i) != ignore.end();
}
} // namespace generated_tests::pad_all_dims
namespace generated_tests::pad_all_dims {
void CreateModel_float16_all_tensors_as_inputs_all_inputs_as_internal_dynamic_output_shape(Model *model) {
OperandType type1(Type::TENSOR_INT32, {4, 2});
OperandType type10(Type::TENSOR_FLOAT16, {1});
OperandType type5(Type::INT32, {});
OperandType type8(Type::TENSOR_FLOAT16, {0, 0, 0, 0});
OperandType type9(Type::TENSOR_FLOAT16, {1, 1, 2, 3});
// Phase 1, operands
auto input0 = model->addOperand(&type9);
auto paddings = model->addOperand(&type1);
auto output0 = model->addOperand(&type8);
auto input0_tmp = model->addOperand(&type9);
auto dummy7 = model->addOperand(&type10);
auto param7 = model->addOperand(&type5);
// Phase 2, operations
static _Float16 dummy7_init[] = {0.0f};
model->setOperandValue(dummy7, dummy7_init, sizeof(_Float16) * 1);
static int32_t param7_init[] = {0};
model->setOperandValue(param7, param7_init, sizeof(int32_t) * 1);
model->addOperation(ANEURALNETWORKS_ADD, {input0_tmp, dummy7, param7}, {input0});
model->addOperation(ANEURALNETWORKS_PAD, {input0, paddings}, {output0});
// Phase 3, inputs and outputs
model->identifyInputsAndOutputs(
{paddings, input0_tmp},
{output0});
assert(model->isValid());
}
bool is_ignored_float16_all_tensors_as_inputs_all_inputs_as_internal_dynamic_output_shape(int i) {
static std::set<int> ignore = {};
return ignore.find(i) != ignore.end();
}
} // namespace generated_tests::pad_all_dims
namespace generated_tests::pad_all_dims {
void CreateModel_relaxed(Model *model) {
OperandType type0(Type::TENSOR_FLOAT32, {1, 1, 2, 3});
OperandType type1(Type::TENSOR_INT32, {4, 2});
OperandType type2(Type::TENSOR_FLOAT32, {4, 8, 8, 6});
// Phase 1, operands
auto input0 = model->addOperand(&type0);
auto paddings = model->addOperand(&type1);
auto output0 = model->addOperand(&type2);
// Phase 2, operations
static int32_t paddings_init[] = {1, 2, 3, 4, 3, 3, 2, 1};
model->setOperandValue(paddings, paddings_init, sizeof(int32_t) * 8);
model->addOperation(ANEURALNETWORKS_PAD, {input0, paddings}, {output0});
// Phase 3, inputs and outputs
model->identifyInputsAndOutputs(
{input0},
{output0});
// Phase 4: set relaxed execution
model->relaxComputationFloat32toFloat16(true);
assert(model->isValid());
}
bool is_ignored_relaxed(int i) {
static std::set<int> ignore = {};
return ignore.find(i) != ignore.end();
}
} // namespace generated_tests::pad_all_dims
namespace generated_tests::pad_all_dims {
void CreateModel_relaxed_dynamic_output_shape(Model *model) {
OperandType type0(Type::TENSOR_FLOAT32, {1, 1, 2, 3});
OperandType type1(Type::TENSOR_INT32, {4, 2});
OperandType type3(Type::TENSOR_FLOAT32, {0, 0, 0, 0});
// Phase 1, operands
auto input0 = model->addOperand(&type0);
auto paddings = model->addOperand(&type1);
auto output0 = model->addOperand(&type3);
// Phase 2, operations
static int32_t paddings_init[] = {1, 2, 3, 4, 3, 3, 2, 1};
model->setOperandValue(paddings, paddings_init, sizeof(int32_t) * 8);
model->addOperation(ANEURALNETWORKS_PAD, {input0, paddings}, {output0});
// Phase 3, inputs and outputs
model->identifyInputsAndOutputs(
{input0},
{output0});
// Phase 4: set relaxed execution
model->relaxComputationFloat32toFloat16(true);
assert(model->isValid());
}
bool is_ignored_relaxed_dynamic_output_shape(int i) {
static std::set<int> ignore = {};
return ignore.find(i) != ignore.end();
}
} // namespace generated_tests::pad_all_dims
namespace generated_tests::pad_all_dims {
void CreateModel_relaxed_all_inputs_as_internal(Model *model) {
OperandType type0(Type::TENSOR_FLOAT32, {1, 1, 2, 3});
OperandType type1(Type::TENSOR_INT32, {4, 2});
OperandType type2(Type::TENSOR_FLOAT32, {4, 8, 8, 6});
OperandType type4(Type::TENSOR_FLOAT32, {1});
OperandType type5(Type::INT32, {});
// Phase 1, operands
auto input0 = model->addOperand(&type0);
auto paddings = model->addOperand(&type1);
auto output0 = model->addOperand(&type2);
auto input0_tmp = model->addOperand(&type0);
auto dummy8 = model->addOperand(&type4);
auto param8 = model->addOperand(&type5);
// Phase 2, operations
static int32_t paddings_init[] = {1, 2, 3, 4, 3, 3, 2, 1};
model->setOperandValue(paddings, paddings_init, sizeof(int32_t) * 8);
static float dummy8_init[] = {0.0f};
model->setOperandValue(dummy8, dummy8_init, sizeof(float) * 1);
static int32_t param8_init[] = {0};
model->setOperandValue(param8, param8_init, sizeof(int32_t) * 1);
model->addOperation(ANEURALNETWORKS_ADD, {input0_tmp, dummy8, param8}, {input0});
model->addOperation(ANEURALNETWORKS_PAD, {input0, paddings}, {output0});
// Phase 3, inputs and outputs
model->identifyInputsAndOutputs(
{input0_tmp},
{output0});
// Phase 4: set relaxed execution
model->relaxComputationFloat32toFloat16(true);
assert(model->isValid());
}
bool is_ignored_relaxed_all_inputs_as_internal(int i) {
static std::set<int> ignore = {};
return ignore.find(i) != ignore.end();
}
} // namespace generated_tests::pad_all_dims
namespace generated_tests::pad_all_dims {
void CreateModel_relaxed_all_inputs_as_internal_dynamic_output_shape(Model *model) {
OperandType type0(Type::TENSOR_FLOAT32, {1, 1, 2, 3});
OperandType type1(Type::TENSOR_INT32, {4, 2});
OperandType type3(Type::TENSOR_FLOAT32, {0, 0, 0, 0});
OperandType type4(Type::TENSOR_FLOAT32, {1});
OperandType type5(Type::INT32, {});
// Phase 1, operands
auto input0 = model->addOperand(&type0);
auto paddings = model->addOperand(&type1);
auto output0 = model->addOperand(&type3);
auto input0_tmp = model->addOperand(&type0);
auto dummy9 = model->addOperand(&type4);
auto param9 = model->addOperand(&type5);
// Phase 2, operations
static int32_t paddings_init[] = {1, 2, 3, 4, 3, 3, 2, 1};
model->setOperandValue(paddings, paddings_init, sizeof(int32_t) * 8);
static float dummy9_init[] = {0.0f};
model->setOperandValue(dummy9, dummy9_init, sizeof(float) * 1);
static int32_t param9_init[] = {0};
model->setOperandValue(param9, param9_init, sizeof(int32_t) * 1);
model->addOperation(ANEURALNETWORKS_ADD, {input0_tmp, dummy9, param9}, {input0});
model->addOperation(ANEURALNETWORKS_PAD, {input0, paddings}, {output0});
// Phase 3, inputs and outputs
model->identifyInputsAndOutputs(
{input0_tmp},
{output0});
// Phase 4: set relaxed execution
model->relaxComputationFloat32toFloat16(true);
assert(model->isValid());
}
bool is_ignored_relaxed_all_inputs_as_internal_dynamic_output_shape(int i) {
static std::set<int> ignore = {};
return ignore.find(i) != ignore.end();
}
} // namespace generated_tests::pad_all_dims
namespace generated_tests::pad_all_dims {
void CreateModel_relaxed_all_tensors_as_inputs(Model *model) {
OperandType type0(Type::TENSOR_FLOAT32, {1, 1, 2, 3});
OperandType type1(Type::TENSOR_INT32, {4, 2});
OperandType type2(Type::TENSOR_FLOAT32, {4, 8, 8, 6});
// Phase 1, operands
auto input0 = model->addOperand(&type0);
auto paddings = model->addOperand(&type1);
auto output0 = model->addOperand(&type2);
// Phase 2, operations
model->addOperation(ANEURALNETWORKS_PAD, {input0, paddings}, {output0});
// Phase 3, inputs and outputs
model->identifyInputsAndOutputs(
{input0, paddings},
{output0});
// Phase 4: set relaxed execution
model->relaxComputationFloat32toFloat16(true);
assert(model->isValid());
}
bool is_ignored_relaxed_all_tensors_as_inputs(int i) {
static std::set<int> ignore = {};
return ignore.find(i) != ignore.end();
}
} // namespace generated_tests::pad_all_dims
namespace generated_tests::pad_all_dims {
void CreateModel_relaxed_all_tensors_as_inputs_dynamic_output_shape(Model *model) {
OperandType type0(Type::TENSOR_FLOAT32, {1, 1, 2, 3});
OperandType type1(Type::TENSOR_INT32, {4, 2});
OperandType type3(Type::TENSOR_FLOAT32, {0, 0, 0, 0});
// Phase 1, operands
auto input0 = model->addOperand(&type0);
auto paddings = model->addOperand(&type1);
auto output0 = model->addOperand(&type3);
// Phase 2, operations
model->addOperation(ANEURALNETWORKS_PAD, {input0, paddings}, {output0});
// Phase 3, inputs and outputs
model->identifyInputsAndOutputs(
{input0, paddings},
{output0});
// Phase 4: set relaxed execution
model->relaxComputationFloat32toFloat16(true);
assert(model->isValid());
}
bool is_ignored_relaxed_all_tensors_as_inputs_dynamic_output_shape(int i) {
static std::set<int> ignore = {};
return ignore.find(i) != ignore.end();
}
} // namespace generated_tests::pad_all_dims
namespace generated_tests::pad_all_dims {
void CreateModel_relaxed_all_tensors_as_inputs_all_inputs_as_internal(Model *model) {
OperandType type0(Type::TENSOR_FLOAT32, {1, 1, 2, 3});
OperandType type1(Type::TENSOR_INT32, {4, 2});
OperandType type2(Type::TENSOR_FLOAT32, {4, 8, 8, 6});
OperandType type4(Type::TENSOR_FLOAT32, {1});
OperandType type5(Type::INT32, {});
// Phase 1, operands
auto input0 = model->addOperand(&type0);
auto paddings = model->addOperand(&type1);
auto output0 = model->addOperand(&type2);
auto input0_tmp = model->addOperand(&type0);
auto dummy10 = model->addOperand(&type4);
auto param10 = model->addOperand(&type5);
// Phase 2, operations
static float dummy10_init[] = {0.0f};
model->setOperandValue(dummy10, dummy10_init, sizeof(float) * 1);
static int32_t param10_init[] = {0};
model->setOperandValue(param10, param10_init, sizeof(int32_t) * 1);
model->addOperation(ANEURALNETWORKS_ADD, {input0_tmp, dummy10, param10}, {input0});
model->addOperation(ANEURALNETWORKS_PAD, {input0, paddings}, {output0});
// Phase 3, inputs and outputs
model->identifyInputsAndOutputs(
{paddings, input0_tmp},
{output0});
// Phase 4: set relaxed execution
model->relaxComputationFloat32toFloat16(true);
assert(model->isValid());
}
bool is_ignored_relaxed_all_tensors_as_inputs_all_inputs_as_internal(int i) {
static std::set<int> ignore = {};
return ignore.find(i) != ignore.end();
}
} // namespace generated_tests::pad_all_dims
namespace generated_tests::pad_all_dims {
void CreateModel_relaxed_all_tensors_as_inputs_all_inputs_as_internal_dynamic_output_shape(Model *model) {
OperandType type0(Type::TENSOR_FLOAT32, {1, 1, 2, 3});
OperandType type1(Type::TENSOR_INT32, {4, 2});
OperandType type3(Type::TENSOR_FLOAT32, {0, 0, 0, 0});
OperandType type4(Type::TENSOR_FLOAT32, {1});
OperandType type5(Type::INT32, {});
// Phase 1, operands
auto input0 = model->addOperand(&type0);
auto paddings = model->addOperand(&type1);
auto output0 = model->addOperand(&type3);
auto input0_tmp = model->addOperand(&type0);
auto dummy11 = model->addOperand(&type4);
auto param11 = model->addOperand(&type5);
// Phase 2, operations
static float dummy11_init[] = {0.0f};
model->setOperandValue(dummy11, dummy11_init, sizeof(float) * 1);
static int32_t param11_init[] = {0};
model->setOperandValue(param11, param11_init, sizeof(int32_t) * 1);
model->addOperation(ANEURALNETWORKS_ADD, {input0_tmp, dummy11, param11}, {input0});
model->addOperation(ANEURALNETWORKS_PAD, {input0, paddings}, {output0});
// Phase 3, inputs and outputs
model->identifyInputsAndOutputs(
{paddings, input0_tmp},
{output0});
// Phase 4: set relaxed execution
model->relaxComputationFloat32toFloat16(true);
assert(model->isValid());
}
bool is_ignored_relaxed_all_tensors_as_inputs_all_inputs_as_internal_dynamic_output_shape(int i) {
static std::set<int> ignore = {};
return ignore.find(i) != ignore.end();
}
} // namespace generated_tests::pad_all_dims
namespace generated_tests::pad_all_dims {
void CreateModel_quant8(Model *model) {
OperandType type1(Type::TENSOR_INT32, {4, 2});
OperandType type11(Type::TENSOR_QUANT8_ASYMM, {1, 1, 2, 3}, 2.3f, 0);
OperandType type12(Type::TENSOR_QUANT8_ASYMM, {4, 8, 8, 6}, 2.3f, 0);
// Phase 1, operands
auto input0 = model->addOperand(&type11);
auto paddings = model->addOperand(&type1);
auto output0 = model->addOperand(&type12);
// Phase 2, operations
static int32_t paddings_init[] = {1, 2, 3, 4, 3, 3, 2, 1};
model->setOperandValue(paddings, paddings_init, sizeof(int32_t) * 8);
model->addOperation(ANEURALNETWORKS_PAD, {input0, paddings}, {output0});
// Phase 3, inputs and outputs
model->identifyInputsAndOutputs(
{input0},
{output0});
assert(model->isValid());
}
bool is_ignored_quant8(int i) {
static std::set<int> ignore = {};
return ignore.find(i) != ignore.end();
}
} // namespace generated_tests::pad_all_dims
namespace generated_tests::pad_all_dims {
void CreateModel_quant8_dynamic_output_shape(Model *model) {
OperandType type1(Type::TENSOR_INT32, {4, 2});
OperandType type11(Type::TENSOR_QUANT8_ASYMM, {1, 1, 2, 3}, 2.3f, 0);
OperandType type13(Type::TENSOR_QUANT8_ASYMM, {0, 0, 0, 0}, 2.3f, 0);
// Phase 1, operands
auto input0 = model->addOperand(&type11);
auto paddings = model->addOperand(&type1);
auto output0 = model->addOperand(&type13);
// Phase 2, operations
static int32_t paddings_init[] = {1, 2, 3, 4, 3, 3, 2, 1};
model->setOperandValue(paddings, paddings_init, sizeof(int32_t) * 8);
model->addOperation(ANEURALNETWORKS_PAD, {input0, paddings}, {output0});
// Phase 3, inputs and outputs
model->identifyInputsAndOutputs(
{input0},
{output0});
assert(model->isValid());
}
bool is_ignored_quant8_dynamic_output_shape(int i) {
static std::set<int> ignore = {};
return ignore.find(i) != ignore.end();
}
} // namespace generated_tests::pad_all_dims
namespace generated_tests::pad_all_dims {
void CreateModel_quant8_all_inputs_as_internal(Model *model) {
OperandType type1(Type::TENSOR_INT32, {4, 2});
OperandType type11(Type::TENSOR_QUANT8_ASYMM, {1, 1, 2, 3}, 2.3f, 0);
OperandType type12(Type::TENSOR_QUANT8_ASYMM, {4, 8, 8, 6}, 2.3f, 0);
OperandType type14(Type::TENSOR_QUANT8_ASYMM, {1}, 2.3f, 0);
OperandType type5(Type::INT32, {});
// Phase 1, operands
auto input0 = model->addOperand(&type11);
auto paddings = model->addOperand(&type1);
auto output0 = model->addOperand(&type12);
auto input0_tmp = model->addOperand(&type11);
auto dummy12 = model->addOperand(&type14);
auto param12 = model->addOperand(&type5);
// Phase 2, operations
static int32_t paddings_init[] = {1, 2, 3, 4, 3, 3, 2, 1};
model->setOperandValue(paddings, paddings_init, sizeof(int32_t) * 8);
static uint8_t dummy12_init[] = {0};
model->setOperandValue(dummy12, dummy12_init, sizeof(uint8_t) * 1);
static int32_t param12_init[] = {0};
model->setOperandValue(param12, param12_init, sizeof(int32_t) * 1);
model->addOperation(ANEURALNETWORKS_ADD, {input0_tmp, dummy12, param12}, {input0});
model->addOperation(ANEURALNETWORKS_PAD, {input0, paddings}, {output0});
// Phase 3, inputs and outputs
model->identifyInputsAndOutputs(
{input0_tmp},
{output0});
assert(model->isValid());
}
bool is_ignored_quant8_all_inputs_as_internal(int i) {
static std::set<int> ignore = {};
return ignore.find(i) != ignore.end();
}
} // namespace generated_tests::pad_all_dims
namespace generated_tests::pad_all_dims {
void CreateModel_quant8_all_inputs_as_internal_dynamic_output_shape(Model *model) {
OperandType type1(Type::TENSOR_INT32, {4, 2});
OperandType type11(Type::TENSOR_QUANT8_ASYMM, {1, 1, 2, 3}, 2.3f, 0);
OperandType type13(Type::TENSOR_QUANT8_ASYMM, {0, 0, 0, 0}, 2.3f, 0);
OperandType type14(Type::TENSOR_QUANT8_ASYMM, {1}, 2.3f, 0);
OperandType type5(Type::INT32, {});
// Phase 1, operands
auto input0 = model->addOperand(&type11);
auto paddings = model->addOperand(&type1);
auto output0 = model->addOperand(&type13);
auto input0_tmp = model->addOperand(&type11);
auto dummy13 = model->addOperand(&type14);
auto param13 = model->addOperand(&type5);
// Phase 2, operations
static int32_t paddings_init[] = {1, 2, 3, 4, 3, 3, 2, 1};
model->setOperandValue(paddings, paddings_init, sizeof(int32_t) * 8);
static uint8_t dummy13_init[] = {0};
model->setOperandValue(dummy13, dummy13_init, sizeof(uint8_t) * 1);
static int32_t param13_init[] = {0};
model->setOperandValue(param13, param13_init, sizeof(int32_t) * 1);
model->addOperation(ANEURALNETWORKS_ADD, {input0_tmp, dummy13, param13}, {input0});
model->addOperation(ANEURALNETWORKS_PAD, {input0, paddings}, {output0});
// Phase 3, inputs and outputs
model->identifyInputsAndOutputs(
{input0_tmp},
{output0});
assert(model->isValid());
}
bool is_ignored_quant8_all_inputs_as_internal_dynamic_output_shape(int i) {
static std::set<int> ignore = {};
return ignore.find(i) != ignore.end();
}
} // namespace generated_tests::pad_all_dims
namespace generated_tests::pad_all_dims {
void CreateModel_quant8_all_tensors_as_inputs(Model *model) {
OperandType type1(Type::TENSOR_INT32, {4, 2});
OperandType type11(Type::TENSOR_QUANT8_ASYMM, {1, 1, 2, 3}, 2.3f, 0);
OperandType type12(Type::TENSOR_QUANT8_ASYMM, {4, 8, 8, 6}, 2.3f, 0);
// Phase 1, operands
auto input0 = model->addOperand(&type11);
auto paddings = model->addOperand(&type1);
auto output0 = model->addOperand(&type12);
// Phase 2, operations
model->addOperation(ANEURALNETWORKS_PAD, {input0, paddings}, {output0});
// Phase 3, inputs and outputs
model->identifyInputsAndOutputs(
{input0, paddings},
{output0});
assert(model->isValid());
}
bool is_ignored_quant8_all_tensors_as_inputs(int i) {
static std::set<int> ignore = {};
return ignore.find(i) != ignore.end();
}
} // namespace generated_tests::pad_all_dims
namespace generated_tests::pad_all_dims {
void CreateModel_quant8_all_tensors_as_inputs_dynamic_output_shape(Model *model) {
OperandType type1(Type::TENSOR_INT32, {4, 2});
OperandType type11(Type::TENSOR_QUANT8_ASYMM, {1, 1, 2, 3}, 2.3f, 0);
OperandType type13(Type::TENSOR_QUANT8_ASYMM, {0, 0, 0, 0}, 2.3f, 0);
// Phase 1, operands
auto input0 = model->addOperand(&type11);
auto paddings = model->addOperand(&type1);
auto output0 = model->addOperand(&type13);
// Phase 2, operations
model->addOperation(ANEURALNETWORKS_PAD, {input0, paddings}, {output0});
// Phase 3, inputs and outputs
model->identifyInputsAndOutputs(
{input0, paddings},
{output0});
assert(model->isValid());
}
bool is_ignored_quant8_all_tensors_as_inputs_dynamic_output_shape(int i) {
static std::set<int> ignore = {};
return ignore.find(i) != ignore.end();
}
} // namespace generated_tests::pad_all_dims
namespace generated_tests::pad_all_dims {
void CreateModel_quant8_all_tensors_as_inputs_all_inputs_as_internal(Model *model) {
OperandType type1(Type::TENSOR_INT32, {4, 2});
OperandType type11(Type::TENSOR_QUANT8_ASYMM, {1, 1, 2, 3}, 2.3f, 0);
OperandType type12(Type::TENSOR_QUANT8_ASYMM, {4, 8, 8, 6}, 2.3f, 0);
OperandType type14(Type::TENSOR_QUANT8_ASYMM, {1}, 2.3f, 0);
OperandType type5(Type::INT32, {});
// Phase 1, operands
auto input0 = model->addOperand(&type11);
auto paddings = model->addOperand(&type1);
auto output0 = model->addOperand(&type12);
auto input0_tmp = model->addOperand(&type11);
auto dummy14 = model->addOperand(&type14);
auto param14 = model->addOperand(&type5);
// Phase 2, operations
static uint8_t dummy14_init[] = {0};
model->setOperandValue(dummy14, dummy14_init, sizeof(uint8_t) * 1);
static int32_t param14_init[] = {0};
model->setOperandValue(param14, param14_init, sizeof(int32_t) * 1);
model->addOperation(ANEURALNETWORKS_ADD, {input0_tmp, dummy14, param14}, {input0});
model->addOperation(ANEURALNETWORKS_PAD, {input0, paddings}, {output0});
// Phase 3, inputs and outputs
model->identifyInputsAndOutputs(
{paddings, input0_tmp},
{output0});
assert(model->isValid());
}
bool is_ignored_quant8_all_tensors_as_inputs_all_inputs_as_internal(int i) {
static std::set<int> ignore = {};
return ignore.find(i) != ignore.end();
}
} // namespace generated_tests::pad_all_dims
namespace generated_tests::pad_all_dims {
void CreateModel_quant8_all_tensors_as_inputs_all_inputs_as_internal_dynamic_output_shape(Model *model) {
OperandType type1(Type::TENSOR_INT32, {4, 2});
OperandType type11(Type::TENSOR_QUANT8_ASYMM, {1, 1, 2, 3}, 2.3f, 0);
OperandType type13(Type::TENSOR_QUANT8_ASYMM, {0, 0, 0, 0}, 2.3f, 0);
OperandType type14(Type::TENSOR_QUANT8_ASYMM, {1}, 2.3f, 0);
OperandType type5(Type::INT32, {});
// Phase 1, operands
auto input0 = model->addOperand(&type11);
auto paddings = model->addOperand(&type1);
auto output0 = model->addOperand(&type13);
auto input0_tmp = model->addOperand(&type11);
auto dummy15 = model->addOperand(&type14);
auto param15 = model->addOperand(&type5);
// Phase 2, operations
static uint8_t dummy15_init[] = {0};
model->setOperandValue(dummy15, dummy15_init, sizeof(uint8_t) * 1);
static int32_t param15_init[] = {0};
model->setOperandValue(param15, param15_init, sizeof(int32_t) * 1);
model->addOperation(ANEURALNETWORKS_ADD, {input0_tmp, dummy15, param15}, {input0});
model->addOperation(ANEURALNETWORKS_PAD, {input0, paddings}, {output0});
// Phase 3, inputs and outputs
model->identifyInputsAndOutputs(
{paddings, input0_tmp},
{output0});
assert(model->isValid());
}
bool is_ignored_quant8_all_tensors_as_inputs_all_inputs_as_internal_dynamic_output_shape(int i) {
static std::set<int> ignore = {};
return ignore.find(i) != ignore.end();
}
} // namespace generated_tests::pad_all_dims