python/pyarmnn/test/test_const_tensor.py - platform/external/armnn - Git at Google

 # Copyright © 2020 Arm Ltd. All rights reserved.
 # SPDX-License-Identifier: MIT
 import pytest
 import numpy as np

 import pyarmnn as ann


 def _get_tensor_info(dt):
     tensor_info = ann.TensorInfo(ann.TensorShape((2, 3)), dt)

     return tensor_info


 @pytest.mark.parametrize("dt, data",
                          [
                              (ann.DataType_Float32, np.random.randint(1, size=(2, 4)).astype(np.float32)),
                              (ann.DataType_Float16, np.random.randint(1, size=(2, 4)).astype(np.float16)),
                              (ann.DataType_QAsymmU8, np.random.randint(1, size=(2, 4)).astype(np.uint8)),
                              (ann.DataType_QAsymmS8, np.random.randint(1, size=(2, 4)).astype(np.int8)),
                              (ann.DataType_QSymmS8, np.random.randint(1, size=(2, 4)).astype(np.int8)),
                              (ann.DataType_Signed32, np.random.randint(1, size=(2, 4)).astype(np.int32)),
                              (ann.DataType_QSymmS16, np.random.randint(1, size=(2, 4)).astype(np.int16))
                          ], ids=['float32', 'float16', 'unsigned int8', 'signed int8', 'signed int8', 'int32', 'int16'])
 def test_const_tensor_too_many_elements(dt, data):
     tensor_info = _get_tensor_info(dt)
     num_bytes = tensor_info.GetNumBytes()

     with pytest.raises(ValueError) as err:
         ann.ConstTensor(tensor_info, data)

     assert 'ConstTensor requires {} bytes, {} provided.'.format(num_bytes, data.nbytes) in str(err.value)


 @pytest.mark.parametrize("dt, data",
                          [
                              (ann.DataType_Float32, np.random.randint(1, size=(2, 2)).astype(np.float32)),
                              (ann.DataType_Float16, np.random.randint(1, size=(2, 2)).astype(np.float16)),
                              (ann.DataType_QAsymmU8, np.random.randint(1, size=(2, 2)).astype(np.uint8)),
                              (ann.DataType_QAsymmS8, np.random.randint(1, size=(2, 2)).astype(np.int8)),
                              (ann.DataType_QSymmS8, np.random.randint(1, size=(2, 2)).astype(np.int8)),
                              (ann.DataType_Signed32, np.random.randint(1, size=(2, 2)).astype(np.int32)),
                              (ann.DataType_QSymmS16, np.random.randint(1, size=(2, 2)).astype(np.int16))
                          ], ids=['float32', 'float16', 'unsigned int8', 'signed int8', 'signed int8', 'int32', 'int16'])
 def test_const_tensor_too_little_elements(dt, data):
     tensor_info = _get_tensor_info(dt)
     num_bytes = tensor_info.GetNumBytes()

     with pytest.raises(ValueError) as err:
         ann.ConstTensor(tensor_info, data)

     assert 'ConstTensor requires {} bytes, {} provided.'.format(num_bytes, data.nbytes) in str(err.value)


 @pytest.mark.parametrize("dt, data",
                          [
                              (ann.DataType_Float32, np.random.randint(1, size=(2, 2, 3, 3)).astype(np.float32)),
                              (ann.DataType_Float16, np.random.randint(1, size=(2, 2, 3, 3)).astype(np.float16)),
                              (ann.DataType_QAsymmU8, np.random.randint(1, size=(2, 2, 3, 3)).astype(np.uint8)),
                              (ann.DataType_QAsymmS8, np.random.randint(1, size=(2, 2, 3, 3)).astype(np.int8)),
                              (ann.DataType_QSymmS8, np.random.randint(1, size=(2, 2, 3, 3)).astype(np.int8)),
                              (ann.DataType_Signed32, np.random.randint(1, size=(2, 2, 3, 3)).astype(np.int32)),
                              (ann.DataType_QSymmS16, np.random.randint(1, size=(2, 2, 3, 3)).astype(np.int16))
                          ], ids=['float32', 'float16', 'unsigned int8', 'signed int8', 'signed int8', 'int32', 'int16'])
 def test_const_tensor_multi_dimensional_input(dt, data):
     tensor = ann.ConstTensor(ann.TensorInfo(ann.TensorShape((2, 2, 3, 3)), dt), data)

     assert data.size == tensor.GetNumElements()
     assert data.nbytes == tensor.GetNumBytes()
     assert dt == tensor.GetDataType()
     assert tensor.get_memory_area().data


 def test_create_const_tensor_from_tensor():
     tensor_info = ann.TensorInfo(ann.TensorShape((2, 3)), ann.DataType_Float32)
     tensor = ann.Tensor(tensor_info)
     copied_tensor = ann.ConstTensor(tensor)

     assert copied_tensor != tensor, "Different objects"
     assert copied_tensor.GetInfo() != tensor.GetInfo(), "Different objects"
     assert copied_tensor.get_memory_area().ctypes.data == tensor.get_memory_area().ctypes.data, "Same memory area"
     assert copied_tensor.GetNumElements() == tensor.GetNumElements()
     assert copied_tensor.GetNumBytes() == tensor.GetNumBytes()
     assert copied_tensor.GetDataType() == tensor.GetDataType()


 def test_const_tensor_from_tensor_has_memory_area_access_after_deletion_of_original_tensor():
     tensor_info = ann.TensorInfo(ann.TensorShape((2, 3)), ann.DataType_Float32)
     tensor = ann.Tensor(tensor_info)

     tensor.get_memory_area()[0] = 100

     copied_mem = tensor.get_memory_area().copy()

     assert 100 == copied_mem[0], "Memory was copied correctly"

     copied_tensor = ann.ConstTensor(tensor)

     tensor.get_memory_area()[0] = 200

     assert 200 == tensor.get_memory_area()[0], "Tensor and copied Tensor point to the same memory"
     assert 200 == copied_tensor.get_memory_area()[0], "Tensor and copied Tensor point to the same memory"

     assert 100 == copied_mem[0], "Copied test memory not affected"

     copied_mem[0] = 200  # modify test memory to equal copied Tensor

     del tensor
     np.testing.assert_array_equal(copied_tensor.get_memory_area(), copied_mem), "After initial tensor was deleted, " \
                                                                                 "copied Tensor still has " \
                                                                                 "its memory as expected"


 def test_create_const_tensor_incorrect_args():
     with pytest.raises(ValueError) as err:
         ann.ConstTensor('something', 'something')

     expected_error_message = "Incorrect number of arguments or type of arguments provided to create Const Tensor."
     assert expected_error_message in str(err.value)


 @pytest.mark.parametrize("dt, data",
                          [
                              # -1 not in data type enum
                              (-1, np.random.randint(1, size=(2, 3)).astype(np.float32)),
                          ], ids=['unknown'])
 def test_const_tensor_unsupported_datatype(dt, data):
     tensor_info = _get_tensor_info(dt)

     with pytest.raises(ValueError) as err:
         ann.ConstTensor(tensor_info, data)

     assert 'The data type provided for this Tensor is not supported: -1' in str(err.value)


 @pytest.mark.parametrize("dt, data",
                          [
                              (ann.DataType_Float32, [[1, 1, 1], [1, 1, 1]]),
                              (ann.DataType_Float16, [[1, 1, 1], [1, 1, 1]]),
                              (ann.DataType_QAsymmU8, [[1, 1, 1], [1, 1, 1]]),
                              (ann.DataType_QAsymmS8, [[1, 1, 1], [1, 1, 1]]),
                              (ann.DataType_QSymmS8, [[1, 1, 1], [1, 1, 1]])
                          ], ids=['float32', 'float16', 'unsigned int8', 'signed int8', 'signed int8'])
 def test_const_tensor_incorrect_input_datatype(dt, data):
     tensor_info = _get_tensor_info(dt)

     with pytest.raises(TypeError) as err:
         ann.ConstTensor(tensor_info, data)

     assert 'Data must be provided as a numpy array.' in str(err.value)


 @pytest.mark.parametrize("dt, data",
                          [
                              (ann.DataType_Float32, np.random.randint(1, size=(2, 3)).astype(np.float32)),
                              (ann.DataType_Float16, np.random.randint(1, size=(2, 3)).astype(np.float16)),
                              (ann.DataType_QAsymmU8, np.random.randint(1, size=(2, 3)).astype(np.uint8)),
                              (ann.DataType_QAsymmS8, np.random.randint(1, size=(2, 3)).astype(np.int8)),
                              (ann.DataType_QSymmS8, np.random.randint(1, size=(2, 3)).astype(np.int8)),
                              (ann.DataType_Signed32, np.random.randint(1, size=(2, 3)).astype(np.int32)),
                              (ann.DataType_QSymmS16, np.random.randint(1, size=(2, 3)).astype(np.int16))
                          ], ids=['float32', 'float16', 'unsigned int8', 'signed int8', 'signed int8', 'int32', 'int16'])
 class TestNumpyDataTypes:

     def test_copy_const_tensor(self, dt, data):
         tensor_info = _get_tensor_info(dt)
         tensor = ann.ConstTensor(tensor_info, data)
         copied_tensor = ann.ConstTensor(tensor)

         assert copied_tensor != tensor, "Different objects"
         assert copied_tensor.GetInfo() != tensor.GetInfo(), "Different objects"
         assert copied_tensor.get_memory_area().ctypes.data == tensor.get_memory_area().ctypes.data, "Same memory area"
         assert copied_tensor.GetNumElements() == tensor.GetNumElements()
         assert copied_tensor.GetNumBytes() == tensor.GetNumBytes()
         assert copied_tensor.GetDataType() == tensor.GetDataType()

     def test_const_tensor__str__(self, dt, data):
         tensor_info = _get_tensor_info(dt)
         d_type = tensor_info.GetDataType()
         num_dimensions = tensor_info.GetNumDimensions()
         num_bytes = tensor_info.GetNumBytes()
         num_elements = tensor_info.GetNumElements()
         tensor = ann.ConstTensor(tensor_info, data)

         assert str(tensor) == "ConstTensor{{DataType: {}, NumBytes: {}, NumDimensions: " \
                               "{}, NumElements: {}}}".format(d_type, num_bytes, num_dimensions, num_elements)

     def test_const_tensor_with_info(self, dt, data):
         tensor_info = _get_tensor_info(dt)
         elements = tensor_info.GetNumElements()
         num_bytes = tensor_info.GetNumBytes()
         d_type = dt

         tensor = ann.ConstTensor(tensor_info, data)

         assert tensor_info != tensor.GetInfo(), "Different objects"
         assert elements == tensor.GetNumElements()
         assert num_bytes == tensor.GetNumBytes()
         assert d_type == tensor.GetDataType()

     def test_immutable_memory(self, dt, data):
         tensor_info = _get_tensor_info(dt)

         tensor = ann.ConstTensor(tensor_info, data)

         with pytest.raises(ValueError) as err:
             tensor.get_memory_area()[0] = 0

         assert 'is read-only' in str(err.value)

     def test_numpy_dtype_matches_ann_dtype(self, dt, data):
         np_data_type_mapping = {ann.DataType_QAsymmU8: np.uint8,
                                 ann.DataType_QAsymmS8: np.int8,
                                 ann.DataType_QSymmS8: np.int8,
                                 ann.DataType_Float32: np.float32,
                                 ann.DataType_QSymmS16: np.int16,
                                 ann.DataType_Signed32: np.int32,
                                 ann.DataType_Float16: np.float16}

         tensor_info = _get_tensor_info(dt)
         tensor = ann.ConstTensor(tensor_info, data)
         assert np_data_type_mapping[tensor.GetDataType()] == data.dtype


 # This test checks that mismatched numpy and PyArmNN datatypes with same number of bits raises correct error.
 @pytest.mark.parametrize("dt, data",
                          [
                              (ann.DataType_Float32, np.random.randint(1, size=(2, 3)).astype(np.int32)),
                              (ann.DataType_Float16, np.random.randint(1, size=(2, 3)).astype(np.int16)),
                              (ann.DataType_QAsymmU8, np.random.randint(1, size=(2, 3)).astype(np.int8)),
                              (ann.DataType_QAsymmS8, np.random.randint(1, size=(2, 3)).astype(np.uint8)),
                              (ann.DataType_QSymmS8, np.random.randint(1, size=(2, 3)).astype(np.uint8)),
                              (ann.DataType_Signed32, np.random.randint(1, size=(2, 3)).astype(np.float32)),
                              (ann.DataType_QSymmS16, np.random.randint(1, size=(2, 3)).astype(np.float16))
                          ], ids=['float32', 'float16', 'unsigned int8', 'signed int8', 'signed int8', 'int32', 'int16'])
 def test_numpy_dtype_mismatch_ann_dtype(dt, data):
     np_data_type_mapping = {ann.DataType_QAsymmU8: np.uint8,
                             ann.DataType_QAsymmS8: np.int8,
                             ann.DataType_QSymmS8: np.int8,
                             ann.DataType_Float32: np.float32,
                             ann.DataType_QSymmS16: np.int16,
                             ann.DataType_Signed32: np.int32,
                             ann.DataType_Float16: np.float16}

     tensor_info = _get_tensor_info(dt)
     with pytest.raises(TypeError) as err:
         ann.ConstTensor(tensor_info, data)

     assert str(err.value) == "Expected data to have type {} for type {} but instead got numpy.{}".format(
         np_data_type_mapping[dt], dt, data.dtype)
	# Copyright © 2020 Arm Ltd. All rights reserved.
	# SPDX-License-Identifier: MIT
	import pytest
	import numpy as np

	import pyarmnn as ann


	def _get_tensor_info(dt):
	tensor_info = ann.TensorInfo(ann.TensorShape((2, 3)), dt)

	return tensor_info


	@pytest.mark.parametrize("dt, data",
	[
	(ann.DataType_Float32, np.random.randint(1, size=(2, 4)).astype(np.float32)),
	(ann.DataType_Float16, np.random.randint(1, size=(2, 4)).astype(np.float16)),
	(ann.DataType_QAsymmU8, np.random.randint(1, size=(2, 4)).astype(np.uint8)),
	(ann.DataType_QAsymmS8, np.random.randint(1, size=(2, 4)).astype(np.int8)),
	(ann.DataType_QSymmS8, np.random.randint(1, size=(2, 4)).astype(np.int8)),
	(ann.DataType_Signed32, np.random.randint(1, size=(2, 4)).astype(np.int32)),
	(ann.DataType_QSymmS16, np.random.randint(1, size=(2, 4)).astype(np.int16))
	], ids=['float32', 'float16', 'unsigned int8', 'signed int8', 'signed int8', 'int32', 'int16'])
	def test_const_tensor_too_many_elements(dt, data):
	tensor_info = _get_tensor_info(dt)
	num_bytes = tensor_info.GetNumBytes()

	with pytest.raises(ValueError) as err:
	ann.ConstTensor(tensor_info, data)

	assert 'ConstTensor requires {} bytes, {} provided.'.format(num_bytes, data.nbytes) in str(err.value)


	@pytest.mark.parametrize("dt, data",
	[
	(ann.DataType_Float32, np.random.randint(1, size=(2, 2)).astype(np.float32)),
	(ann.DataType_Float16, np.random.randint(1, size=(2, 2)).astype(np.float16)),
	(ann.DataType_QAsymmU8, np.random.randint(1, size=(2, 2)).astype(np.uint8)),
	(ann.DataType_QAsymmS8, np.random.randint(1, size=(2, 2)).astype(np.int8)),
	(ann.DataType_QSymmS8, np.random.randint(1, size=(2, 2)).astype(np.int8)),
	(ann.DataType_Signed32, np.random.randint(1, size=(2, 2)).astype(np.int32)),
	(ann.DataType_QSymmS16, np.random.randint(1, size=(2, 2)).astype(np.int16))
	], ids=['float32', 'float16', 'unsigned int8', 'signed int8', 'signed int8', 'int32', 'int16'])
	def test_const_tensor_too_little_elements(dt, data):
	tensor_info = _get_tensor_info(dt)
	num_bytes = tensor_info.GetNumBytes()

	with pytest.raises(ValueError) as err:
	ann.ConstTensor(tensor_info, data)

	assert 'ConstTensor requires {} bytes, {} provided.'.format(num_bytes, data.nbytes) in str(err.value)


	@pytest.mark.parametrize("dt, data",
	[
	(ann.DataType_Float32, np.random.randint(1, size=(2, 2, 3, 3)).astype(np.float32)),
	(ann.DataType_Float16, np.random.randint(1, size=(2, 2, 3, 3)).astype(np.float16)),
	(ann.DataType_QAsymmU8, np.random.randint(1, size=(2, 2, 3, 3)).astype(np.uint8)),
	(ann.DataType_QAsymmS8, np.random.randint(1, size=(2, 2, 3, 3)).astype(np.int8)),
	(ann.DataType_QSymmS8, np.random.randint(1, size=(2, 2, 3, 3)).astype(np.int8)),
	(ann.DataType_Signed32, np.random.randint(1, size=(2, 2, 3, 3)).astype(np.int32)),
	(ann.DataType_QSymmS16, np.random.randint(1, size=(2, 2, 3, 3)).astype(np.int16))
	], ids=['float32', 'float16', 'unsigned int8', 'signed int8', 'signed int8', 'int32', 'int16'])
	def test_const_tensor_multi_dimensional_input(dt, data):
	tensor = ann.ConstTensor(ann.TensorInfo(ann.TensorShape((2, 2, 3, 3)), dt), data)

	assert data.size == tensor.GetNumElements()
	assert data.nbytes == tensor.GetNumBytes()
	assert dt == tensor.GetDataType()
	assert tensor.get_memory_area().data


	def test_create_const_tensor_from_tensor():
	tensor_info = ann.TensorInfo(ann.TensorShape((2, 3)), ann.DataType_Float32)
	tensor = ann.Tensor(tensor_info)
	copied_tensor = ann.ConstTensor(tensor)

	assert copied_tensor != tensor, "Different objects"
	assert copied_tensor.GetInfo() != tensor.GetInfo(), "Different objects"
	assert copied_tensor.get_memory_area().ctypes.data == tensor.get_memory_area().ctypes.data, "Same memory area"
	assert copied_tensor.GetNumElements() == tensor.GetNumElements()
	assert copied_tensor.GetNumBytes() == tensor.GetNumBytes()
	assert copied_tensor.GetDataType() == tensor.GetDataType()


	def test_const_tensor_from_tensor_has_memory_area_access_after_deletion_of_original_tensor():
	tensor_info = ann.TensorInfo(ann.TensorShape((2, 3)), ann.DataType_Float32)
	tensor = ann.Tensor(tensor_info)

	tensor.get_memory_area()[0] = 100

	copied_mem = tensor.get_memory_area().copy()

	assert 100 == copied_mem[0], "Memory was copied correctly"

	copied_tensor = ann.ConstTensor(tensor)

	tensor.get_memory_area()[0] = 200

	assert 200 == tensor.get_memory_area()[0], "Tensor and copied Tensor point to the same memory"
	assert 200 == copied_tensor.get_memory_area()[0], "Tensor and copied Tensor point to the same memory"

	assert 100 == copied_mem[0], "Copied test memory not affected"

	copied_mem[0] = 200 # modify test memory to equal copied Tensor

	del tensor
	np.testing.assert_array_equal(copied_tensor.get_memory_area(), copied_mem), "After initial tensor was deleted, " \
	"copied Tensor still has " \
	"its memory as expected"


	def test_create_const_tensor_incorrect_args():
	with pytest.raises(ValueError) as err:
	ann.ConstTensor('something', 'something')

	expected_error_message = "Incorrect number of arguments or type of arguments provided to create Const Tensor."
	assert expected_error_message in str(err.value)


	@pytest.mark.parametrize("dt, data",
	[
	# -1 not in data type enum
	(-1, np.random.randint(1, size=(2, 3)).astype(np.float32)),
	], ids=['unknown'])
	def test_const_tensor_unsupported_datatype(dt, data):
	tensor_info = _get_tensor_info(dt)

	with pytest.raises(ValueError) as err:
	ann.ConstTensor(tensor_info, data)

	assert 'The data type provided for this Tensor is not supported: -1' in str(err.value)


	@pytest.mark.parametrize("dt, data",
	[
	(ann.DataType_Float32, [[1, 1, 1], [1, 1, 1]]),
	(ann.DataType_Float16, [[1, 1, 1], [1, 1, 1]]),
	(ann.DataType_QAsymmU8, [[1, 1, 1], [1, 1, 1]]),
	(ann.DataType_QAsymmS8, [[1, 1, 1], [1, 1, 1]]),
	(ann.DataType_QSymmS8, [[1, 1, 1], [1, 1, 1]])
	], ids=['float32', 'float16', 'unsigned int8', 'signed int8', 'signed int8'])
	def test_const_tensor_incorrect_input_datatype(dt, data):
	tensor_info = _get_tensor_info(dt)

	with pytest.raises(TypeError) as err:
	ann.ConstTensor(tensor_info, data)

	assert 'Data must be provided as a numpy array.' in str(err.value)


	@pytest.mark.parametrize("dt, data",
	[
	(ann.DataType_Float32, np.random.randint(1, size=(2, 3)).astype(np.float32)),
	(ann.DataType_Float16, np.random.randint(1, size=(2, 3)).astype(np.float16)),
	(ann.DataType_QAsymmU8, np.random.randint(1, size=(2, 3)).astype(np.uint8)),
	(ann.DataType_QAsymmS8, np.random.randint(1, size=(2, 3)).astype(np.int8)),
	(ann.DataType_QSymmS8, np.random.randint(1, size=(2, 3)).astype(np.int8)),
	(ann.DataType_Signed32, np.random.randint(1, size=(2, 3)).astype(np.int32)),
	(ann.DataType_QSymmS16, np.random.randint(1, size=(2, 3)).astype(np.int16))
	], ids=['float32', 'float16', 'unsigned int8', 'signed int8', 'signed int8', 'int32', 'int16'])
	class TestNumpyDataTypes:

	def test_copy_const_tensor(self, dt, data):
	tensor_info = _get_tensor_info(dt)
	tensor = ann.ConstTensor(tensor_info, data)
	copied_tensor = ann.ConstTensor(tensor)

	assert copied_tensor != tensor, "Different objects"
	assert copied_tensor.GetInfo() != tensor.GetInfo(), "Different objects"
	assert copied_tensor.get_memory_area().ctypes.data == tensor.get_memory_area().ctypes.data, "Same memory area"
	assert copied_tensor.GetNumElements() == tensor.GetNumElements()
	assert copied_tensor.GetNumBytes() == tensor.GetNumBytes()
	assert copied_tensor.GetDataType() == tensor.GetDataType()

	def test_const_tensor__str__(self, dt, data):
	tensor_info = _get_tensor_info(dt)
	d_type = tensor_info.GetDataType()
	num_dimensions = tensor_info.GetNumDimensions()
	num_bytes = tensor_info.GetNumBytes()
	num_elements = tensor_info.GetNumElements()
	tensor = ann.ConstTensor(tensor_info, data)

	assert str(tensor) == "ConstTensor{{DataType: {}, NumBytes: {}, NumDimensions: " \
	"{}, NumElements: {}}}".format(d_type, num_bytes, num_dimensions, num_elements)

	def test_const_tensor_with_info(self, dt, data):
	tensor_info = _get_tensor_info(dt)
	elements = tensor_info.GetNumElements()
	num_bytes = tensor_info.GetNumBytes()
	d_type = dt

	tensor = ann.ConstTensor(tensor_info, data)

	assert tensor_info != tensor.GetInfo(), "Different objects"
	assert elements == tensor.GetNumElements()
	assert num_bytes == tensor.GetNumBytes()
	assert d_type == tensor.GetDataType()

	def test_immutable_memory(self, dt, data):
	tensor_info = _get_tensor_info(dt)

	tensor = ann.ConstTensor(tensor_info, data)

	with pytest.raises(ValueError) as err:
	tensor.get_memory_area()[0] = 0

	assert 'is read-only' in str(err.value)

	def test_numpy_dtype_matches_ann_dtype(self, dt, data):
	np_data_type_mapping = {ann.DataType_QAsymmU8: np.uint8,
	ann.DataType_QAsymmS8: np.int8,
	ann.DataType_QSymmS8: np.int8,
	ann.DataType_Float32: np.float32,
	ann.DataType_QSymmS16: np.int16,
	ann.DataType_Signed32: np.int32,
	ann.DataType_Float16: np.float16}

	tensor_info = _get_tensor_info(dt)
	tensor = ann.ConstTensor(tensor_info, data)
	assert np_data_type_mapping[tensor.GetDataType()] == data.dtype


	# This test checks that mismatched numpy and PyArmNN datatypes with same number of bits raises correct error.
	@pytest.mark.parametrize("dt, data",
	[
	(ann.DataType_Float32, np.random.randint(1, size=(2, 3)).astype(np.int32)),
	(ann.DataType_Float16, np.random.randint(1, size=(2, 3)).astype(np.int16)),
	(ann.DataType_QAsymmU8, np.random.randint(1, size=(2, 3)).astype(np.int8)),
	(ann.DataType_QAsymmS8, np.random.randint(1, size=(2, 3)).astype(np.uint8)),
	(ann.DataType_QSymmS8, np.random.randint(1, size=(2, 3)).astype(np.uint8)),
	(ann.DataType_Signed32, np.random.randint(1, size=(2, 3)).astype(np.float32)),
	(ann.DataType_QSymmS16, np.random.randint(1, size=(2, 3)).astype(np.float16))
	], ids=['float32', 'float16', 'unsigned int8', 'signed int8', 'signed int8', 'int32', 'int16'])
	def test_numpy_dtype_mismatch_ann_dtype(dt, data):
	np_data_type_mapping = {ann.DataType_QAsymmU8: np.uint8,
	ann.DataType_QAsymmS8: np.int8,
	ann.DataType_QSymmS8: np.int8,
	ann.DataType_Float32: np.float32,
	ann.DataType_QSymmS16: np.int16,
	ann.DataType_Signed32: np.int32,
	ann.DataType_Float16: np.float16}

	tensor_info = _get_tensor_info(dt)
	with pytest.raises(TypeError) as err:
	ann.ConstTensor(tensor_info, data)

	assert str(err.value) == "Expected data to have type {} for type {} but instead got numpy.{}".format(
	np_data_type_mapping[dt], dt, data.dtype)